Intel® 82801BA I/O Controller
Hub 2 (ICH2) and Intel® 82801BAM
I/O Controller Hub 2 Mobile
(ICH2-M)
Datasheet
October 2000
Order Number: 290687-002
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property rights is granted by this document. Except as provided in Intel's Terms and Conditions of Sale for such products, Intel assumes no liability
whatsoever, and Intel disclaims any express or implied warranty, relating to sale and/or use of Intel products including liability or warranties relating to
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intended for use in medical, life saving, or life sustaining applications.
Intel may make changes to specifications and product descriptions at any time, without notice.
Contact your local Intel sales office or your distributor to obtain the latest specifications and before placing your product order.
The Intel 82801BA I/O Controller Hub 2 (ICH2) and Intel 82801BAM I/O Controller Hub 2 (ICH2-M) may contain design defects or errors known as
errata which may cause the product to deviate from published specifications. Current characterized errata are available on request.
I2C is a two-wire communications bus/protocol developed by Philips. SMBus is a subset of the I 2C bus/protocol and was developed by Intel.
Implementations of the I2C bus/protocol or the SMBus bus/protocol may require licenses from various entities, including Philips Electronics N.V. and
North American Philips Corporation.
Alert on LAN and Wake on LAN are results of the IBM/Intel Advanced Manageability Alliance and are trademarks of IBM Corporation.
Copies of documents which have an ordering number and are referenced in this document, or other Intel literature may be obtained by:
calling 1-800-548-4725 or
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Copyright © Intel Corporation, 2000
*Third-party brands and names are the property of their respective owners.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Intel® 82801BA/M ICH2/ICH2-M Features
■
■
■
■
■
■
■
■
■
PCI Bus I/F
— Supports PCI at 33 MHz
— Supports PCI Rev 2.2 Specification
— 133 MByte/sec maximum throughput
— Supports up to 6 master devices on PCI
— One PCI REQ/GNT pair can be given higher
arbitration priority (intended for external
1394 host controller)
Integrated LAN Controller
— WfM 2.0 Compliant
— Interface to discrete LAN Connect
component
— 10/100 Mbit/sec Ethernet support
— 1 Mbit/sec HomePNA* support
Integrated IDE Controller
— Independent timing of up to 4 drives
— Ultra ATA/100/66/33, BMIDE and PIO
modes
— Read transfers up to 100MB/s, Writes to
89 MB/s
— Separate IDE connections for Primary and
Secondary cables
— Implements Write Ping-Pong Buffer for
faster write performance
— Tri-state modes to enable mobile swap bay
(82801BAM ICH2-M)
■
USB
— 2 UHCI Host Controllers with a total of
4 ports
— USB 1.1 compliant
— Supports wake-up from sleeping states
S1–S4
— Supports legacy Keyboard/Mouse software
AC'97 Link for Audio and Telephony CODECs
— AC’97 2.1 compliant
— Independent bus master logic for 5 channels
(PCM In/Out, Mic Input, Modem In/Out)
— Separate independent PCI functions for
Audio and Modem
— Support for up to six channels of PCM audio
output (full AC3 decode)
— Supports wake-up events
Interrupt Controller
— Support up to 8 PCI interrupt pins
— Supports PCI 2.2 Message-Based Interrupts
— Two cascaded 82C59
— Integrated I/O APIC capability
— 15 interrupts supported in 8259 mode, 24
supported in I/O APIC mode
— Supports Serial Interrupt Protocol
— Supports Front-Side Bus interrupt delivery
1.8 V operation with 3.3 V I/O
— 5V tolerant buffers on IDE, PCI, USB Overcurrent and Legacy signals
GPIO
— TTL, Open-Drain, Inversion
Timers Based on 82C54
— System timer, Refresh request, Speaker tone
output
■
■
■
■
■
■
■
■
■
■
Power Management Logic
— ACPI 1.0 compliant
— ACPI-defined power states
- C1–C2, S3–S5 (82801BA ICH2)
- C1–C3, S1, S3–S5 (82801BAM ICH2-M)
— Support for “Intel® SpeedStep™
technology” processor power control
(82801BAM ICH2-M)
— PCI CLKRUN# support
(82801BAM ICH2-M)
— ACPI Power Management Timer
— PCI PME# support
— SMI# generation
— All registers readable/restorable for proper
resume from 0V suspend states
— Support for APM-based legacy power
management for non-ACPI implementations
External Glue Integration
— Integrated Pull-up, Pull-down and Series
Termination resistors on IDE and processor
interface
Enhanced Hub I/F buffers improve routing
flexibility (Not available with all Memory
Controller Hubs)
Firmware Hub (FWH) I/F supports BIOS
memory size up to 8 MBs
Low Pin count (LPC) I/F
— Allows connection of legacy ISA and X-Bus
devices such as Super I/O
— Supports two Master/DMA devices.
Enhanced DMA Controller
— Two cascaded 8237 DMA controllers
— PCI DMA: Supports PC/PCI — Includes
two PC/PCI REQ#/GNT# pairs
— Supports LPC DMA
— Supports DMA Collection Buffer to provide
Type-F DMA performance for all DMA
channels
Real-Time Clock
— 256-byte battery-backed CMOS RAM
— Hardware implementation to indicate century
rollover
System TCO Reduction Circuits
— Timers to generate SMI# and Reset upon
detection of system hang
— Timers to detect improper processor reset
— Integrated processor frequency strap logic
SM Bus
— Host interface allows processor to
communicate via SM Bus
— Slave interface allows an external
Microcontroller to access system resources
— Compatible with most 2-Wire components
that are also I2C compatible
Supports ISA bus via external PCI-ISA Bridge
360-pin EBGA package
Shading,as is shown here, indicates differences between the two components.
The Intel® 82801BA ICH2 and 82801BAM ICH2-M may contain design defects or errors known as errata which may cause the
products to deviate from published specifications. Current characterized errata are available on request.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
iii
Intel® 82801BA (ICH2) and 82801BAM (ICH2-M) Simplified Block Diagram
AD[31:0]
C/BE[3:0]#
DEVSEL#
FRAME#
IRDY#
TRDY#
STOP#
PAR
PERR#
REQ[0:4]#
REQ5#/REQB#/GPIO1
REQA#/GPIO0
GNT[0:4]#
GNT5#/GNTB#/GPIO17
GNTA#/GPIO16
PCICLK
PCIRST#
PLOCK#
SERR#
PME#
(ICH2-M)CLKRUN#
A20M#
CPUSLP#
FERR#
IGNNE#
INIT#
INTR
NMI
SMI#
STPCLK#
RCIN#
A20GATE
CPUPWRGD
SERIRQ
PIRQ[A:D]#
PIRQ[H:E]/GPIO[5:2]
IRQ[14:15]
APICCLK
APICD[1:0]
USBP1P
USBP1N
USBP0P
USBP0N
OC[3:0]#
RTCX1
RTCX2
CLK14
CLK48
CLK66
IDE
Interface
PCI
Interface
Processor
Interface
Power
Mgnt.
Interrupt
AC'97
Link
PDCS1#
SDCS1#
PDCS3#
SDCS3#
PDA[2:0]
SDA[2:0]
PDD[15:0]
SDD[15:0]
PDDREQ
SDDREQ
PDDACK#
SDDACK#
PDIOR#
SDIOR#
PDIOW#
SDIOW#
PIORDY
SIORDY
THRM#
SLP_S3
SLP_S5#
PWROK
PWRBTN#
RI#
RSMRST#
SUS_STAT#/LPCPD#
SUSCLK
RSM_PWROK (ICH2) or LAN_PWROK (ICH2-M)
VRMPWRGD / VGATE (ICH2-M)
SLP_S1# (ICH2-M)
C3_STAT#/GPIO[21] (ICH2-M)
AGPBUSY# (ICH2-M)
STP_PCI# (ICH2-M)
STP_CPU# (ICH2-M)
BATLOW# (ICH2-M)
CPUPERF# (ICH2-M)
SSMUXSEL (ICH2-M)
AC_RST#
AC_SYNC
AC_BIT_CLK
AC_SDOUT
AC_SDIN0
AC_SDIN1
USB
RTC
Hub
Interface
HL11:0]
HL_STB
HL_STB#
HLCOMP
Firmware
Hub
FWH[3:0]/LAD[3:0]
FWH[4]/LFRAME#
LPC
Interface
LAD[3:0]/FWH[4]
LFRAME#/FWH[4]
LDRQ[0:1]#
SMBus
Interface
SMBDATA
SMBCLK
SMBALERT#/GPIO[11]
Clocks
SPKR
RTCRST#
(ICH2) TP0
FS0
Misc.
Signals
GPIO[13:11,8:6,4:3,1:0]
GPIO[23:16]
GPIO[28:24]
General
Purpose
I/O
System
Mgnt.
INTRUDER#
SMLINK[1:0]
EE_SHCLK
EE_DIN
EE_DOUT
EE_CS
System
Mgnt.
System
Mgnt.
LAN_CLK
LAN_RXD[2:0]
LAN_TXD[2:0]
LAN_RSTSYNC
Note:
1. The GPIO signals listed above represent the GPIO signals for the 82801BA ICH2. Some of
these signals are not implemented in the 82801BAM ICH2-M. See Signal Description Chapter for details.
blk_ich2-ich2m
iv
82801BA ICH2 and 82801BAM ICH2-M Datasheet
System Configuration
Processor
G raphics
C ontroller
M ain
M em ory
H ost
C ontroller
H ub Interface
PCI Slots
SM Bus
D evice(s)
AC '97 C odec(s)
(optional)
SM Bus
PCI Bus
AC '97 2.1
I/O C ontroller H ub 2
PC I Agent
82801BA (ICH 2)
and
82801BAM (ICH 2-M )
ATA/100/66/33
4 ID E D rives
ISA Bridge
(optional)
M oon2
D ocking Bridge
(optional) (ICH 2-M )
4xUSB
G PIO
LPC I/F
LAN
C ontroller
Super I/O
(required)
FW H
82801BA ICH2 and 82801BAM ICH2-M Datasheet
v
Contents
1
Introduction ................................................................................................................1-1
1.1
1.2
2
Signal Description......................................................................................................2-1
2.1
2.2
2.3
2.4
2.5
2.6
2.7
2.8
2.9
2.10
2.11
2.12
2.13
2.14
2.15
2.16
2.17
2.18
2.19
2.20
3
About this Document ....................................................................................1-1
Overview.......................................................................................................1-3
Hub Interface to Host Controller ...................................................................2-1
Link to LAN Connect.....................................................................................2-1
EEPROM Interface .......................................................................................2-2
Firmware Hub Interface ................................................................................2-2
PCI Interface.................................................................................................2-2
IDE Interface.................................................................................................2-5
LPC Interface................................................................................................2-6
Interrupt Interface .........................................................................................2-6
USB Interface ...............................................................................................2-7
Power Management Interface.......................................................................2-7
Processor Interface.......................................................................................2-9
SMBus Interface .........................................................................................2-10
System Management Interface...................................................................2-10
Real Time Clock Interface ..........................................................................2-11
Other Clocks ...............................................................................................2-11
Miscellaneous Signals ................................................................................2-11
AC’97 Link ..................................................................................................2-12
General Purpose I/O...................................................................................2-12
Power and Ground......................................................................................2-13
Pin Straps ...................................................................................................2-14
2.20.1 Functional Straps ...........................................................................2-14
2.20.2 Test Signals ...................................................................................2-15
2.20.2.1 Test Mode Selection.......................................................2-15
2.20.2.2 Test Straps (82801BA ICH2 only) ..................................2-15
2.20.3 External RTC Circuitry ...................................................................2-16
2.20.4 V5REF / Vcc3_3 Sequencing Requirements .................................2-16
Power Planes and Pin States ....................................................................................3-1
3.1
3.2
3.3
3.4
3.5
Power Planes................................................................................................3-1
Integrated Pull-Ups and Pull-Downs.............................................................3-1
IDE Integrated Series Termination Resistors ...............................................3-2
Output and I/O Signals Planes and States ...................................................3-2
Power Planes for Input Signals.....................................................................3-6
4
System Clock Domains..............................................................................................4-1
vi
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5
Functional Description ...............................................................................................5-1
5.1
5.2
5.3
5.4
5.5
Hub Interface to PCI Bridge (D30:F0)...........................................................5-1
5.1.1 PCI Bus Interface.............................................................................5-1
5.1.2 PCI-to-PCI Bridge Model .................................................................5-2
5.1.3 IDSEL to Device Number Mapping ..................................................5-2
5.1.4 SERR# Functionality........................................................................5-2
5.1.5 Parity Error Detection.......................................................................5-4
5.1.6 Standard PCI Bus Configuration Mechanism ..................................5-5
5.1.7 PCI Dual Address Cycle (DAC) Support
(82801BA ICH2 only) .......................................................................5-6
LAN Controller (B1:D8:F0)............................................................................5-6
5.2.1 LAN Controller Architectural Overview ............................................5-7
5.2.2 LAN Controller PCI Bus Interface ....................................................5-9
5.2.2.1 Bus Slave Operation.........................................................5-9
5.2.2.2 Bus Master Operation.....................................................5-10
5.2.3 CLOCKRUN# Signal (82801BAM ICH2-M only)............................5-13
5.2.3.1 PCI Power Management ................................................5-13
5.2.3.2 PCI Reset Signal ............................................................5-15
5.2.3.3 Wake-up Events .............................................................5-15
5.2.3.4 Wake on LAN (Preboot Wake-up) ..................................5-16
5.2.4 Serial EEPROM Interface ..............................................................5-17
5.2.5 CSMA/CD Unit ...............................................................................5-19
5.2.6 Media Management Interface ........................................................5-20
5.2.7 TCO Functionality ..........................................................................5-20
LPC Bridge (w/ System and Management Functions) (D31:F0).................5-20
5.3.1 LPC Interface .................................................................................5-21
5.3.1.1 LPC Cycle Types............................................................5-21
5.3.1.2 Start Field Definition .......................................................5-22
5.3.1.3 Cycle Type / Direction (CYCTYPE + DIR)......................5-22
5.3.1.4 Size.................................................................................5-22
5.3.1.5 SYNC..............................................................................5-23
5.3.1.6 SYNC Time-out ..............................................................5-23
5.3.1.7 SYNC Error Indication ....................................................5-23
5.3.1.8 LFRAME# Usage............................................................5-24
5.3.1.9 I/O Cycles .......................................................................5-25
5.3.1.10 Bus Master Cycles..........................................................5-25
5.3.1.11 LPC Power Management ...............................................5-25
5.3.1.12 Configuration and ICH2 Implications ..............................5-25
DMA Operation (D31:F0) ............................................................................5-26
5.4.1 Channel Priority .............................................................................5-26
5.4.2 Address Compatibility Mode ..........................................................5-27
5.4.3 Summary of DMA Transfer Sizes ..................................................5-27
5.4.4 Autoinitialize...................................................................................5-28
5.4.5 Software Commands .....................................................................5-29
PCI DMA .....................................................................................................5-30
5.5.1 PCI DMA Expansion Protocol ........................................................5-30
5.5.2 PCI DMA Expansion Cycles ..........................................................5-32
5.5.3 DMA Addresses .............................................................................5-32
5.5.4 DMA Data Generation....................................................................5-32
5.5.5 DMA Byte Enable Generation........................................................5-33
5.5.6 DMA Cycle Termination .................................................................5-33
5.5.7 LPC DMA .......................................................................................5-33
82801BA ICH2 and 82801BAM ICH2-M Datasheet
vii
5.6
5.7
5.8
5.9
5.10
viii
5.5.8 Asserting DMA Requests...............................................................5-33
5.5.9 Abandoning DMA Requests ..........................................................5-34
5.5.10 General Flow of DMA Transfers ....................................................5-35
5.5.11 Terminal Count ..............................................................................5-35
5.5.12 Verify Mode....................................................................................5-35
5.5.13 DMA Request Deassertion ............................................................5-36
5.5.14 SYNC Field / LDRQ# Rules ...........................................................5-37
8254 Timers (D31:F0).................................................................................5-38
5.6.1 Timer Programming .......................................................................5-38
5.6.2 Reading from the Interval Timer ....................................................5-39
8259 Interrupt Controllers (PIC) (D31:F0) ..................................................5-41
5.7.1 Interrupt Handling ..........................................................................5-42
5.7.1.1 Generating Interrupts .....................................................5-42
5.7.1.2 Acknowledging Interrupts ...............................................5-42
5.7.1.3 Hardware/Software Interrupt Sequence .........................5-43
5.7.2 Initialization Command Words (ICWx) ...........................................5-43
5.7.3 Operation Command Words (OCW) ..............................................5-44
5.7.4 Modes of Operation .......................................................................5-45
5.7.5 Masking Interrupts .........................................................................5-47
5.7.6 Steering PCI Interrupts ..................................................................5-47
Advanced Interrupt Controller (APIC) (D31:F0) ..........................................5-48
5.8.1 Interrupt Handling ..........................................................................5-48
5.8.2 Interrupt Mapping...........................................................................5-49
5.8.3 APIC Bus Functional Description...................................................5-50
5.8.3.1 Physical Characteristics of APIC....................................5-50
5.8.3.2 APIC Bus Arbitration ......................................................5-50
5.8.3.3 Bus Message Formats ...................................................5-51
5.8.4 PCI Message-Based Interrupts......................................................5-56
5.8.4.1 Theory of Operation .......................................................5-56
5.8.4.2 Registers and Bits Associated with PCI Interrupt
Delivery ..........................................................................5-56
5.8.5 Front-Side Interrupt Delivery..........................................................5-57
5.8.5.1 Theory of Operation .......................................................5-57
5.8.5.2 Edge-Triggered Operation..............................................5-57
5.8.5.3 Level-Triggered Operation .............................................5-57
5.8.5.4 Registers Associated with Front-Side Bus Interrupt
Delivery ..........................................................................5-58
5.8.5.5 Interrupt Message Format ..............................................5-58
Serial Interrupt (D31:F0) .............................................................................5-60
5.9.1 Start Frame....................................................................................5-60
5.9.2 Data Frames ..................................................................................5-60
5.9.3 Stop Frame ....................................................................................5-61
5.9.4 Specific Interrupts not Supported via SERIRQ ..............................5-61
5.9.5 Data Frame Format .......................................................................5-62
Real Time Clock (D31:F0) ..........................................................................5-63
5.10.1 Update Cycles ...............................................................................5-63
5.10.2 Interrupts........................................................................................5-64
5.10.3 Lockable RAM Ranges ..................................................................5-64
5.10.4 Century Rollover ............................................................................5-64
5.10.5 Clearing Battery-Backed RTC RAM...............................................5-64
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5.11
5.12
Processor Interface (D31:F0)......................................................................5-66
5.11.1 Processor Interface Signals ...........................................................5-66
5.11.1.1 A20M# ............................................................................5-66
5.11.1.2 INIT#...............................................................................5-66
5.11.1.3 FERR#/IGNNE# (Coprocessor Error).............................5-67
5.11.1.4 NMI .................................................................................5-67
5.11.1.5 STPCLK# and CPUSLP# Signals ..................................5-68
5.11.1.6 CPUPWRGOOD Signal..................................................5-68
5.11.2 Dual Processor Issues (82801BA ICH2 only) ................................5-68
5.11.2.1 Signal Differences (82801BA ICH2 only) .......................5-68
5.11.2.2 Power Management (82801BA ICH2 only) ....................5-68
5.11.3 Speed Strapping for Processor......................................................5-69
Power Management (D31:F0).....................................................................5-71
5.12.1 ICH2 and System Power States ....................................................5-72
5.12.2 System Power Planes....................................................................5-74
5.12.3 ICH2 Power Planes........................................................................5-74
5.12.4 SMI#/SCI Generation.....................................................................5-74
5.12.5 Dynamic Processor Clock Control .................................................5-77
5.12.5.1 Throttling Using STPCLK# .............................................5-78
5.12.5.2 Transition Rules Among S0/Cx and Throttling States ....5-78
5.12.6 Dynamic PCI Clock Control (82801BAM ICH2-M) .........................5-79
5.12.6.1 Conditions for Stopping the PCI Clock
(82801BAM ICH2-M) ......................................................5-79
5.12.6.2 Conditions for Maintaining the PCI Clock
(82801BAM ICH2-M) ......................................................5-79
5.12.6.3 Conditions for Stopping the PCI Clock
(82801BAM ICH2-M) ......................................................5-79
5.12.6.4 Conditions for Re-Starting the PCI Clock
(82801BAM ICH2-M) ......................................................5-80
5.12.6.5 Other Causes of CLKRUN# Going Active
(82801BAM ICH2-M) ......................................................5-80
5.12.6.6 LPC Devices and CLKRUN# (82801BAM ICH2-M) .......5-80
5.12.7 Sleep States...................................................................................5-81
5.12.7.1 Initiating Sleep State.......................................................5-81
5.12.7.2 Exiting Sleep States .......................................................5-81
5.12.7.3 Sx–G3–Sx, Handling Power Failures .............................5-83
5.12.8 Thermal Management....................................................................5-84
5.12.8.1 THRM# Signal ................................................................5-84
5.12.8.2 THRM# Initiated Passive Cooling...................................5-84
5.12.8.3 THRM# Override Software Bit ........................................5-84
5.12.8.4 Processor-Initiated Passive Cooling
(Via Programmed Duty Cycle on STPCLK#)..................5-85
5.12.8.5 Active Cooling.................................................................5-85
5.12.9 Intel® SpeedStep™ Technology Protocol
(82801BAM ICH2-M only)..............................................................5-85
5.12.9.1 Intel® SpeedStep™ Technology Processor
Requirements (82801BAM ICH2-M)...............................5-86
5.12.9.2 Intel® SpeedStep™ Technology States
(82801BAM ICH2-M) ......................................................5-86
5.12.9.3 Voltage Regulator Interface (82801BAM ICH2-M) .........5-87
82801BA ICH2 and 82801BAM ICH2-M Datasheet
ix
5.13
5.14
5.15
5.16
x
5.12.10 Event Input Signals and Their Usage ............................................5-87
5.12.10.1 PWRBTN# — Power Button...........................................5-87
5.12.10.2 RI# — Ring Indicate .......................................................5-88
5.12.10.3 PME# — PCI Power Management Event.......................5-88
5.12.10.4 AGPBUSY# (82801BAM ICH2-M) .................................5-88
5.12.11 Alt Access Mode ............................................................................5-89
5.12.11.1 Write Only Registers with Read Paths in
Alternate Access Mode ..................................................5-89
5.12.11.2 PIC Reserved Bits ..........................................................5-91
5.12.11.3 Read Only Registers with Write Paths in
Alternate Access Mode ..................................................5-91
5.12.12 System Power Supplies, Planes, and Signals ...............................5-91
5.12.13 Clock Generators ...........................................................................5-93
5.12.13.1 Clock Control Signals from ICH2-M to Clock
Synthesizer (82801BAM ICH2-M only) ..........................5-93
5.12.14 Legacy Power Management Theory of Operation .........................5-94
5.12.14.1 Desktop APM Power Management
(82801BA ICH2 only) .....................................................5-94
5.12.14.2 Mobile APM Power Management
(82801BAM ICH2-M only) ..............................................5-94
System Management (D31:F0)...................................................................5-95
5.13.1 Theory of Operation.......................................................................5-95
5.13.2 Alert on LAN* .................................................................................5-96
General Purpose I/O...................................................................................5-98
IDE Controller (D31:F1) ..............................................................................5-99
5.15.1 PIO Transfers ................................................................................5-99
5.15.2 Bus Master Function ....................................................................5-101
5.15.3 Ultra ATA/33 Protocol ..................................................................5-105
5.15.4 Ultra ATA/66 Protocol ..................................................................5-107
5.15.5 Ultra ATA/100 Protocol ................................................................5-107
5.15.6 Ultra ATA/33/66/100 Timing ........................................................5-107
5.15.7 Mobile IDE Swap Bay (82801BAM ICH2-M only) ........................5-107
USB Controller (Device 31:Functions 2 and 4) .........................................5-108
5.16.1 Data Structures in Main memory .................................................5-108
5.16.1.1 Frame List Pointer ........................................................5-108
5.16.1.2 Transfer Descriptor (TD) ..............................................5-109
5.16.1.3 Queue Head (QH) ........................................................5-113
5.16.2 Data Transfers To/From Main Memory........................................5-114
5.16.2.1 Executing the Schedule................................................5-114
5.16.2.2 Processing Transfer Descriptors ..................................5-114
5.16.2.3 Command Register, Status Register, and TD
Status Bit Interaction ....................................................5-115
5.16.2.4 Transfer Queuing .........................................................5-116
5.16.3 Data Encoding and Bit Stuffing....................................................5-119
5.16.4 Bus Protocol ................................................................................5-120
5.16.4.1 Bit Ordering ..................................................................5-120
5.16.4.2 SYNC Field...................................................................5-120
5.16.4.3 Packet Field Formats ...................................................5-120
5.16.4.4 Address Fields..............................................................5-121
5.16.4.5 Frame Number Field ....................................................5-122
5.16.4.6 Data Field .....................................................................5-122
5.16.4.7 Cyclic Redundancy Check (CRC) ................................5-122
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5.17
5.18
5.19
6
Register and Memory Mapping..................................................................................6-1
6.1
6.2
6.3
6.4
7
5.16.5 Packet Formats............................................................................5-123
5.16.5.1 Token Packets..............................................................5-123
5.16.5.2 Start of Frame Packets.................................................5-123
5.16.5.3 Data Packets ................................................................5-124
5.16.5.4 Handshake Packets......................................................5-124
5.16.5.5 Handshake Responses ................................................5-125
5.16.6 USB Interrupts .............................................................................5-125
5.16.6.1 Transaction Based Interrupts .......................................5-125
5.16.6.2 Non-Transaction Based Interrupts................................5-127
5.16.7 USB Power Management ............................................................5-127
5.16.8 USB Legacy Keyboard Operation................................................5-128
SMBus Controller Functional Description (D31:F3) ..................................5-130
5.17.1 Host Controller .............................................................................5-130
5.17.1.1 Command Protocols .....................................................5-131
5.17.1.2 I2C Behavior .................................................................5-136
5.17.1.3 Heartbeat for Use With the External LAN Controller ....5-136
5.17.2 Bus Arbitration .............................................................................5-137
5.17.3 Interrupts / SMI# ..........................................................................5-137
5.17.4 SMBALERT#................................................................................5-138
5.17.5 SMBus Slave Interface ................................................................5-138
AC’97 Controller Functional Description
(Audio D31:F5, Modem D31:F6)5-142
5.18.1 AC-link Overview .........................................................................5-143
5.18.2 AC-Link Low Power Mode ...........................................................5-151
5.18.3 AC‘97 Cold Reset ........................................................................5-152
5.18.4 AC‘97 Warm Reset ......................................................................5-152
5.18.5 System Reset...............................................................................5-153
Firmware Hub Interface ............................................................................5-154
5.19.1 Field Definitions ...........................................................................5-154
5.19.2 Protocol........................................................................................5-155
PCI Devices and Functions...........................................................................6-1
PCI Configuration Map..................................................................................6-2
I/O Map .........................................................................................................6-2
6.3.1 Fixed I/O Address Ranges...............................................................6-3
6.3.2 Variable I/O Decode Ranges ...........................................................6-5
Memory Map .................................................................................................6-6
6.4.1 Boot-Block Update Scheme.............................................................6-7
LAN Controller Registers (B1:D8:F0).........................................................................7-1
7.1
PCI Configuration Registers (B1:D8:F0).......................................................7-1
7.1.1 VID—Vendor ID Register (LAN Controller—B1:D8:F0) ...................7-2
7.1.2 DID—Device ID Register (LAN Controller—B1:D8:F0) ...................7-2
7.1.3 PCICMD—PCI Command Register
(LAN Controller—B1:D8:F0) ............................................................7-2
7.1.4 PCISTS—PCI Status Register (LAN Controller—B1:D8:F0) ...........7-3
7.1.5 REVID—Revision ID Register (LAN Controller—B1:D8:F0) ............7-3
7.1.6 SCC—Sub-Class Code Register
(LAN Controller—B1:D8:F0) ............................................................7-4
7.1.7 BCC—Base-Class Code Register
(LAN Controller—B1:D8:F0) ............................................................7-4
7.1.8 CLS—Cache Line Size Register (LAN Controller—B1:D8:F0) ........7-4
82801BA ICH2 and 82801BAM ICH2-M Datasheet
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7.1.9
7.2
8
Hub Interface to PCI Bridge Registers (D30:F0) .......................................................8-1
8.1
xii
PMLT—PCI Master Latency Timer Register
(LAN Controller—B1:D8:F0) ............................................................7-4
7.1.10 HEADTYP—Header Type Register
(LAN Controller—B1:D8:F0) ............................................................7-5
7.1.11 CSR_MEM_BASE CSR—Memory-Mapped Base Address
Register (LAN Controller—B1:D8:F0)..............................................7-5
7.1.12 CSR_IO_BASE—CSR I/O-Mapped Base Address Register
(LAN Controller—B1:D8:F0) ............................................................7-5
7.1.13 SVID—Subsystem Vendor ID (LAN Controller—B1:D8:F0) ............7-6
7.1.14 SID—Subsystem ID (LAN Controller—B1:D8:F0) ...........................7-6
7.1.15 CAP_PTR—Capabilities Pointer (LAN Controller—B1:D8:F0) ........7-6
7.1.16 INT_LN—Interrupt Line Register (LAN Controller—B1:D8:F0)........7-7
7.1.17 INT_PN—Interrupt Pin Register (LAN Controller—B1:D8:F0).........7-7
7.1.18 MIN_GNT—Minimum Grant Register
(LAN Controller—B1:D8:F0) ............................................................7-7
7.1.19 MAX_LAT—Maximum Latency Register
(LAN Controller—B1:D8:F0) ............................................................7-7
7.1.20 CAP_ID—Capability ID Register (LAN Controller—B1:D8:F0)........7-8
7.1.21 NXT_PTR—Next Item Pointer (LAN Controller—B1:D8:F0) ...........7-8
7.1.22 PM_CAP—Power Management Capabilities
(LAN Controller—B1:D8:F0) ............................................................7-8
7.1.23 PMCSR—Power Management Control/Status Register
(LAN Controller—B1:D8:F0) ............................................................7-9
7.1.24 DATA—Data Register (LAN Controller—B1:D8:F0) ........................7-9
LAN Control / Status Registers (CSR) ........................................................7-10
7.2.1 System Control Block Status Word Register .................................7-11
7.2.2 System Control Block Command Word Register ...........................7-12
7.2.3 System Control Block General Pointer Register ............................7-14
7.2.4 PORT Register ..............................................................................7-14
7.2.5 EEPROM Control Register ............................................................7-15
7.2.6 Management Data Interface (MDI) Control Register .....................7-16
7.2.7 Receive DMA Byte Count Register................................................7-16
7.2.8 Early Receive Interrupt Register ....................................................7-17
7.2.9 Flow Control Register ....................................................................7-18
7.2.10 Power Management Driver (PMDR) Register................................7-19
7.2.11 General Control Register ...............................................................7-19
7.2.12 General Status Register ................................................................7-20
7.2.13 Statistical Counters ........................................................................7-20
PCI Configuration Registers (D30:F0) ..........................................................8-1
8.1.1 VID—Vendor ID Register (HUB-PCI—D30:F0) ...............................8-2
8.1.2 DID—Device ID Register (HUB-PCI—D30:F0)................................8-2
8.1.3 CMD—Command Register (HUB-PCI—D30:F0).............................8-3
8.1.4 PD_STS—Primary Device Status Register
(HUB-PCI—D30:F0) ........................................................................8-4
8.1.5 REVID—Revision ID Register (HUB-PCI—D30:F0) ........................8-4
8.1.6 SCC—Sub-Class Code Register (HUB-PCI—D30:F0)....................8-5
8.1.7 BCC—Base-Class Code Register (HUB-PCI—D30:F0)..................8-5
8.1.8 PMLT—Primary Master Latency Timer Register
(HUB-PCI—D30:F0) ........................................................................8-5
8.1.9 HEADTYP—Header Type Register (HUB-PCI—D30:F0)................8-5
82801BA ICH2 and 82801BAM ICH2-M Datasheet
8.1.10 PBUS_NUM—Primary Bus Number Register
(HUB-PCI—D30:F0) ........................................................................8-6
8.1.11 SBUS_NUM—Secondary Bus Number Register
(HUB-PCI—D30:F0) ........................................................................8-6
8.1.12 SUB_BUS_NUM—Subordinate Bus Number Register
(HUB-PCI—D30:F0) ........................................................................8-6
8.1.13 SMLT—Secondary Master Latency Timer Register
(HUB-PCI—D30:F0) ........................................................................8-6
8.1.14 IOBASE—I/O Base Register (HUB-PCI—D30:F0) ..........................8-7
8.1.15 IOLIM—I/O Limit Register (HUB-PCI—D30:F0) ..............................8-7
8.1.16 SECSTS—Secondary Status Register (HUB-PCI—D30:F0)...........8-8
8.1.17 MEMBASE—Memory Base Register (HUB-PCI—D30:F0) .............8-9
8.1.18 MEMLIM—Memory Limit Register (HUB-PCI—D30:F0) .................8-9
8.1.19 PREF_MEM_BASE—Prefetchable Memory Base Register
(HUB-PCI—D30:F0) ........................................................................8-9
8.1.20 PREF_MEM_MLT—Prefetchable Memory Limit Register
(HUB-PCI—D30:F0) ......................................................................8-10
8.1.21 IOBASE_HI—I/O Base Upper 16 Bits Register
(HUB-PCI—D30:F0) ......................................................................8-10
8.1.22 IOLIM_HI—I/O Limit Upper 16 Bits Register
(HUB-PCI—D30:F0) ......................................................................8-10
8.1.23 INT_LINE—Interrupt Line Register (HUB-PCI—D30:F0) ..............8-10
8.1.24 BRIDGE_CNT—Bridge Control Register (HUB-PCI—D30:F0) .....8-11
8.1.25 BRIDGE_CNT2—Bridge Control Register 2
(HUB-PCI—D30:F0) ......................................................................8-11
8.1.26 CNF—ICH2 Configuration Register (HUB-PCI—D30:F0) .............8-12
8.1.27 MTT—Multi-Transaction Timer Register (HUB-PCI—D30:F0) ......8-12
8.1.28 PCI_MAST_STS—PCI Master Status Register
(HUB-PCI—D30:F0) ......................................................................8-13
8.1.29 ERR_CMD—Error Command Register (HUB-PCI—D30:F0) ........8-13
8.1.30 ERR_STS—Error Status Register (HUB-PCI—D30:F0)................8-14
9
LPC Interface Bridge Registers (D31:F0) ..................................................................9-1
9.1
PCI Configuration Registers (D31:F0) ..........................................................9-1
9.1.1 VID—Vendor ID Register (LPC I/F—D31:F0) ..................................9-2
9.1.2 DID—Device ID Register (LPC I/F—D31:F0) ..................................9-2
9.1.3 PCICMD—PCI COMMAND Register (LPC I/F—D31:F0) ................9-3
9.1.4 PCISTS—PCI Device Status (LPC I/F—D31:F0) ............................9-4
9.1.5 REVID—Revision ID Register (LPC I/F—D31:F0)...........................9-4
9.1.6 PI—Programming Interface (LPC I/F—D31:F0) ..............................9-5
9.1.7 SCC—Sub-Class Code Register (LPC I/F—D31:F0) ......................9-5
9.1.8 BCC—Base-Class Code Register (LPC I/F—D31:F0) ....................9-5
9.1.9 HEADTYP—Header Type Register (LPC I/F—D31:F0) ..................9-5
9.1.10 PMBASE—ACPI Base Address (LPC I/F—D31:F0)........................9-6
9.1.11 ACPI_CNTL—ACPI Control (LPC I/F—D31:F0)..............................9-6
9.1.12 BIOS_CNTL (LPC I/F—D31:F0) ......................................................9-7
9.1.13 TCO_CNTL—TCO Control (LPC I/F—D31:F0) ...............................9-7
9.1.14 GPIOBASE—GPIO Base Address (LPC I/F—D31:F0) ...................9-8
9.1.15 GPIO_CNTL—GPIO Control (LPC I/F—D31:F0) ............................9-8
9.1.16 PIRQ[n]_ROUT—PIRQ[A,B,C,D] Routing Control
(LPC I/F—D31:F0) ...........................................................................9-8
9.1.17 SERIRQ_CNTL—Serial IRQ Control (LPC I/F—D31:F0) ................9-9
82801BA ICH2 and 82801BAM ICH2-M Datasheet
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9.2
9.3
9.4
xiv
9.1.18 PIRQ[n]_ROUT—PIRQ[E,F,G,H] Routing Control
(LPC I/F—D31:F0) ...........................................................................9-9
9.1.19 D31_ERR_CFG—Device 31 Error Configuration Register
(LPC I/F—D31:F0) .........................................................................9-10
9.1.20 D31_ERR_STS—Device 31 Error Status Register
(LPC I/F—D31:F0) .........................................................................9-10
9.1.21 PCI_DMA_CFG—PCI DMA Configuration (LPC I/F—D31:F0) .....9-11
9.1.22 GEN_CNTL—General Control Register (LPC I/F—D31:F0) .........9-11
9.1.23 GEN_STS—General Status (LPC I/F—D31:F0)............................9-13
9.1.24 RTC_CONF—RTC Configuration Register (LPC I/F—D31:F0).....9-14
9.1.25 COM_DEC—LPC I/F Communication Port Decode Ranges
(LPC I/F—D31:F0) .........................................................................9-14
9.1.26 FDD/LPT_DEC—LPC I/F FDD & LPT Decode Ranges
(LPC I/F—D31:F0) .........................................................................9-15
9.1.27 SND_DEC—LPC I/F Sound Decode Ranges
(LPC I/F—D31:F0) .........................................................................9-15
9.1.28 FWH_DEC_EN1—FWH Decode Enable 1 Register
(LPC I/F—D31:F0) .........................................................................9-16
9.1.29 GEN1_DEC—LPC I/F Generic Decode Range 1
(LPC I/F—D31:F0) .........................................................................9-17
9.1.30 LPC_EN—LPC I/F Enables (LPC I/F—D31:F0) ............................9-17
9.1.31 FWH_SEL1—FWH Select 1 Register (LPC I/F—D31:F0).............9-19
9.1.32 GEN2_DEC—LPC I/F Generic Decode Range 2
(LPC I/F—D31:F0) .........................................................................9-20
9.1.33 FWH_SEL2—FWH Select 2 Register (LPC I/F—D31:F0).............9-20
9.1.34 FWH_DEC_EN2—FWH Decode Enable 2 Register
(LPC I/F—D31:F0) .........................................................................9-21
9.1.35 FUNC_DIS—Function Disable Register (LPC I/F—D31:F0) .........9-22
DMA I/O Registers......................................................................................9-23
9.2.1 DMABASE_CA—DMA Base and Current Address Registers .......9-24
9.2.2 DMABASE_CC—DMA Base and Current Count Registers...........9-25
9.2.3 DMAMEM_LP—DMA Memory Low Page Registers .....................9-25
9.2.4 DMACMD—DMA Command Register ...........................................9-26
9.2.5 DMASTS—DMA Status Register...................................................9-26
9.2.6 DMA_WRSMSK—DMA Write Single Mask Register.....................9-27
9.2.7 DMACH_MODE—DMA Channel Mode Register...........................9-27
9.2.8 DMA Clear Byte Pointer Register ..................................................9-28
9.2.9 DMA Master Clear Register ...........................................................9-28
9.2.10 DMA_CLMSK—DMA Clear Mask Register ...................................9-28
9.2.11 DMA_WRMSK—DMA Write All Mask Register .............................9-29
Timer I/O Registers.....................................................................................9-30
9.3.1 TCW—Timer Control Word Register .............................................9-30
9.3.1.1 RDBK_CMD—Read Back Command ............................9-31
9.3.1.2 LTCH_CMD—Counter Latch Command ........................9-31
9.3.2 SBYTE_FMT—Interval Timer Status Byte Format Register ..........9-32
9.3.3 Counter Access Ports Register......................................................9-32
8259 Interrupt Controller (PIC) Registers ...................................................9-33
9.4.1 Interrupt Controller I/O MAP ..........................................................9-33
9.4.2 ICW1—Initialization Command Word 1 Register ...........................9-34
9.4.3 ICW2—Initialization Command Word 2 Register ...........................9-35
9.4.4 ICW3—Master Controller Initialization Command Word 3
Register .........................................................................................9-35
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9.4.5
9.5
9.6
9.7
9.8
ICW3—Slave Controller Initialization Command Word 3
Register..........................................................................................9-36
9.4.6 ICW4—Initialization Command Word 4 Register ...........................9-36
9.4.7 OCW1—Operational Control Word 1 (Interrupt Mask) Register ....9-36
9.4.8 OCW2—Operational Control Word 2 Register ..............................9-37
9.4.9 OCW3—Operational Control Word 3 Register ..............................9-38
9.4.10 ELCR1—Master Controller Edge/Level Triggered Register ..........9-39
9.4.11 ELCR2—Slave Controller Edge/Level Triggered Register ............9-40
Advanced Interrupt Controller (APIC) .........................................................9-41
9.5.1 APIC Register Map ........................................................................9-41
9.5.2 IND—Index Register ......................................................................9-41
9.5.3 DAT—Data Register ......................................................................9-42
9.5.4 IRQPA—IRQ Pin Assertion Register .............................................9-42
9.5.5 EOIR—EOI Register ......................................................................9-43
9.5.6 ID—Identification Register .............................................................9-43
9.5.7 VER—Version Register .................................................................9-44
9.5.8 ARBID—Arbitration ID Register .....................................................9-44
9.5.9 BOOT_CONFIG—Boot Configuration Register .............................9-44
9.5.10 Redirection Table...........................................................................9-45
Real Time Clock Registers .........................................................................9-47
9.6.1 I/O Register Address Map..............................................................9-47
9.6.2 Indexed Registers ..........................................................................9-47
9.6.2.1 RTC_REGA—Register A................................................9-48
9.6.2.2 RTC_REGB—Register B (General Configuration) .........9-49
9.6.2.3 RTC_REGC—Register C (Flag Register) ......................9-50
9.6.2.4 RTC_REGD—Register D (Flag Register) ......................9-50
Processor Interface Registers.....................................................................9-51
9.7.1 NMI_SC—NMI Status and Control Register ..................................9-51
9.7.2 NMI_EN—NMI Enable (and Real Time Clock Index) ....................9-52
9.7.3 PORT92—Fast A20 and Init Register............................................9-52
9.7.4 COPROC_ERR—Coprocessor Error Register ..............................9-52
9.7.5 RST_CNT—Reset Control Register ..............................................9-53
Power Management Registers (D31:F0) ....................................................9-54
9.8.1 Power Management PCI Configuration Registers (D31:F0) ..........9-54
9.8.1.1 GEN_PMCON_1—General PM Configuration 1
Register (PM—D31:F0) ..................................................9-54
9.8.1.2 GEN_PMCON_2—General PM Configuration 2
Register (PM—D31:F0) ..................................................9-56
9.8.1.3 GEN_PMCON_3—General PM Configuration 3
Register (PM—D31:F0) ..................................................9-57
9.8.1.4 GPI_ROUT—GPI Routing Control Register
(PM—D31:F0) ................................................................9-57
9.8.1.5 TRP_FWD_EN—IO Monitor Trap Forwarding
Enable Register (PM—D31:F0)......................................9-58
9.8.1.6 MON[n]_TRP_RNG—I/O Monitor [4:7] Trap Range
Register for Devices 4–7 (PM—D31:F0) ........................9-59
9.8.1.7 MON_TRP_MSK—I/O Monitor Trap Range Mask
Register for Devices 4–7 (PM—D31:F0) ........................9-59
9.8.2 APM I/O Decode ............................................................................9-60
9.8.2.1 APM_CNT—Advanced Power Management
Control Port Register ......................................................9-60
9.8.2.2 APM_STS—Advanced Power Management
Status Port Register .......................................................9-60
82801BA ICH2 and 82801BAM ICH2-M Datasheet
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9.8.3
9.9
9.10
xvi
Power Management I/O Registers.................................................9-61
9.8.3.1 PM1_STS—Power Management 1 Status Register.......9-62
9.8.3.2 PM1_EN—Power Management 1 Enable Register........9-64
9.8.3.3 PM1_CNT—Power Management 1 Control Register .....9-65
9.8.3.4 PM1_TMR—Power Management 1 Timer Register .......9-66
9.8.3.5 PROC_CNT—Processor Control Register .....................9-66
9.8.3.6 LV2—Level 2 Register ...................................................9-67
9.8.3.7 LV3—Level 3 Register (82801BAM ICH2-M) .................9-67
9.8.3.8 PM2_CNT—Power Management 2 Control
(82801BAM ICH2-M)......................................................9-68
9.8.3.9 GPE0_STS—General Purpose Event 0 Status
Register ..........................................................................9-68
9.8.3.10 GPE0_EN—General Purpose Event 0 Enables
Register ..........................................................................9-70
9.8.3.11 GPE1_STS—General Purpose Event 1 Status
Register ..........................................................................9-71
9.8.3.12 GPE1_EN—General Purpose Event 1 Enable
Register ..........................................................................9-72
9.8.3.13 SMI_EN—SMI Control and Enable Register ..................9-72
9.8.3.14 SMI_STS—SMI Status Register ....................................9-74
9.8.3.15 MON_SMI—Device Monitor SMI Status and Enable
Register ..........................................................................9-75
9.8.3.16 DEVACT_STS—Device Activity Status Register ...........9-76
9.8.3.17 DEVTRAP_EN—Device Trap Enable Register ..............9-77
9.8.3.18 BUS_ADDR_TRACK—Bus Address Tracker Register ..9-78
9.8.3.19 BUS_CYC_TRACK—Bus Cycle Tracker Register .........9-78
9.8.3.20 SS_CNT— SpeedStep™ Control Register
(82801BAM ICH2-M)......................................................9-78
System Management TCO Registers (D31:F0) ..........................................9-79
9.9.1 TCO Register I/O Map ...................................................................9-79
9.9.2 TCO1_RLD—TCO Timer Reload and Current Value Register......9-79
9.9.3 TCO1_TMR—TCO Timer Initial Value Register ............................9-80
9.9.4 TCO1_DAT_IN—TCO Data In Register ........................................9-80
9.9.5 TCO1_DAT_OUT—TCO Data Out Register..................................9-80
9.9.6 TCO1_STS—TCO1 Status Register..............................................9-80
9.9.7 TCO2_STS—TCO2 Status Register..............................................9-82
9.9.8 TCO1_CNT—TCO1 Control Register............................................9-83
9.9.9 TCO2_CNT—TCO2 Control Register............................................9-83
9.9.10 TCO_MESSAGE1 and TCO_MESSAGE2 Registers ....................9-84
9.9.11 TCO_WDSTATUS—TCO2 Control Register .................................9-84
9.9.12 SW_IRQ_GEN—Software IRQ Generation Register.....................9-84
General Purpose I/O Registers (D31:F0) ...................................................9-85
9.10.1 GPIO Register I/O Address Map....................................................9-87
9.10.2 GPIO_USE_SEL—GPIO Use Select Register ..............................9-87
9.10.3 GP_IO_SEL—GPIO Input/Output Select Register ........................9-88
9.10.4 GP_LVL—GPIO Level for Input or Output Register.......................9-89
9.10.5 GPO_BLINK—GPO Blink Enable Register....................................9-90
9.10.6 GPI_INV—GPIO Signal Invert Register.........................................9-91
82801BA ICH2 and 82801BAM ICH2-M Datasheet
10
IDE Controller Registers (D31:F1) ...........................................................................10-1
10.1
10.2
11
PCI Configuration Registers (IDE—D31:F1)...............................................10-1
10.1.1 VID—Vendor ID Register (IDE—D31:F1) ......................................10-2
10.1.2 DID—Device ID Register (IDE—D31:F1) ......................................10-2
10.1.3 CMD—Command Register (IDE—D31:F1) ...................................10-2
10.1.4 STS—Device Status Register (IDE—D31:F1) ...............................10-3
10.1.5 RID—Revision ID Register (HUB-PCI—D30:F0) ...........................10-3
10.1.6 PI—Programming Interface (IDE—D31:F1)...................................10-3
10.1.7 SCC—Sub Class Code (IDE—D31:F1) .........................................10-4
10.1.8 BCC—Base Class Code (IDE—D31:F1) .......................................10-4
10.1.9 MLT—Master Latency Timer (IDE—D31:F1).................................10-4
10.1.10 BM_BASE—Bus Master Base Address Register
(IDE—D31:F1) ...............................................................................10-4
10.1.11 IDE_SVID—Subsystem Vendor ID (IDE—D31:F1) .......................10-5
10.1.12 IDE_SID—Subsystem ID (IDE—D31:F1) ......................................10-5
10.1.13 IDE_TIM—IDE Timing Register (IDE—D31:F1) ............................10-5
10.1.14 SLV_IDETIM—Slave (Drive 1) IDE Timing Register
(IDE—D31:F1) ...............................................................................10-7
10.1.15 SDMA_CNT—Synchronous DMA Control Register
(IDE—D31:F1) ...............................................................................10-8
10.1.16 SDMA_TIM—Synchronous DMA Timing Register
(IDE—D31:F1) ...............................................................................10-8
10.1.17 IDE_CONFIG—IDE I/O Configuration Register.............................10-9
Bus Master IDE I/O Registers (D31:F1)....................................................10-11
10.2.1 BMIC[P,S]—Bus Master IDE Command Register .......................10-11
10.2.2 BMIS[P,S]—Bus Master IDE Status Register ..............................10-12
10.2.3 BMID[P,S]—Bus Master IDE Descriptor Table Pointer Register .10-12
USB Controller Registers.........................................................................................11-1
11.1
11.2
PCI Configuration Registers (D31:F2/F4) ...................................................11-1
11.1.1 VID—Vendor Identification Register (USB—D31:F2/F4) ...............11-1
11.1.2 DID—Device Identification Register (USB—D31:F2/F4) ...............11-2
11.1.3 CMD—Command Register (USB—D31:F2/F4) .............................11-2
11.1.4 STA—Device Status Register (USB—D31:F2/F4) ........................11-3
11.1.5 RID—Revision Identification Register (USB—D31:F2/F4) ............11-3
11.1.6 PI—Programming Interface (USB—D31:F2/F4) ............................11-3
11.1.7 SCC—Sub Class Code Register (USB—D31:F2/F4) ....................11-4
11.1.8 BCC—Base Class Code Register (USB—D31:F2/F4) ..................11-4
11.1.9 BASE—Base Address Register (USB—D31:F2/F4)......................11-4
11.1.10 SVID—Subsystem Vendor ID (USB—D31:F2/F4).........................11-4
11.1.11 SID—Subsystem ID (USB—D31:F2/F4)........................................11-5
11.1.12 INTR_LN—Interrupt Line Register (USB—D31:F2/F4) .................11-5
11.1.13 INTR_PN—Interrupt Pin Register (USB—D31:F2/F4)...................11-5
11.1.14 SB_RELNUM—Serial Bus Release Number Register
(USB—D31:F2/F4).........................................................................11-5
11.1.15 USB_LEGKEY—USB Legacy Keyboard/Mouse Control
Register (USB—D31:F2/F4) ..........................................................11-6
11.1.16 USB_RES—USB Resume Enable Register
(USB—D31:F2/F4).........................................................................11-7
USB I/O Registers.......................................................................................11-8
11.2.1 USBCMD—USB Command Register ............................................11-8
11.2.2 USBSTA—USB Status Register ..................................................11-11
82801BA ICH2 and 82801BAM ICH2-M Datasheet
xvii
11.2.3
11.2.4
11.2.5
11.2.6
11.2.7
12
SMBus Controller Registers (D31:F3) .....................................................................12-1
12.1
12.2
13
PCI Configuration Registers (SMBUS—D31:F3)........................................12-1
12.1.1 VID—Vendor Identification Register (SMBUS—D31:F3)...............12-1
12.1.2 DID—Device Identification Register (SMBUS—D31:F3) ...............12-1
12.1.3 CMD—Command Register (SMBUS—D31:F3).............................12-2
12.1.4 STA—Device Status Register (SMBUS—D31:F3) ........................12-2
12.1.5 RID—Revision ID Register (SMBUS—D31:F3).............................12-3
12.1.6 PI—Programming Interface (SMBUS—D31:F3)............................12-3
12.1.7 SCC—Sub Class Code Register (SMBUS—D31:F3)....................12-3
12.1.8 BCC—Base Class Code Register (SMBUS—D31:F3) ..................12-3
12.1.9 SMB_BASE—SMBus Base Address Register
(SMBUS—D31:F3) ........................................................................12-4
12.1.10 SVID—Subsystem Vendor ID (SMBUS—D31:F2/F4) ...................12-4
12.1.11 SID—Subsystem ID (SMBUS—D31:F2/F4) ..................................12-4
12.1.12 INTR_LN—Interrupt Line Register (SMBUS—D31:F3) .................12-4
12.1.13 INTR_PN—Interrupt Pin Register (SMBUS—D31:F3) ..................12-5
12.1.14 HOSTC—Host Configuration Register (SMBUS—D31:F3) ...........12-5
SMBus I/O Registers ..................................................................................12-6
12.2.1 HST_STS—Host Status Register ..................................................12-7
12.2.2 HST_CNT—Host Control Register ................................................12-8
12.2.3 HST_CMD—Host Command Register...........................................12-9
12.2.4 XMIT_SLVA—Transmit Slave Address Register ...........................12-9
12.2.5 HST_D0—Data 0 Register.............................................................12-9
12.2.6 HST_D1—Data 1 Register.............................................................12-9
12.2.7 BLOCK_DB—Block Data Byte Register ......................................12-10
12.2.8 RCV_SLVA—Receive Slave Address Register ...........................12-10
12.2.9 SLV_DATA—Receive Slave Data Register .................................12-10
12.2.10 SMLINK_PIN_CTL—SMLINK Pin Control Register.....................12-11
12.2.11 SMBUS_PIN_CTL—SMBus Pin Control Register .......................12-11
AC’97 Audio Controller Registers (D31:F5).............................................................13-1
13.1
xviii
USBINTR—Interrupt Enable Register..........................................11-12
FRNUM—Frame Number Register..............................................11-12
FRBASEADD—Frame List Base Address ...................................11-13
SOFMOD—Start of Frame Modify Register.................................11-13
PORTSC[0,1]—Port Status and Control Register........................11-14
AC’97 Audio PCI Configuration Space (D31:F5) ........................................13-1
13.1.1 VID—Vendor Identification Register (Audio—D31:F5) ..................13-1
13.1.2 DID—Device Identification Register (Audio—D31:F5)...................13-2
13.1.3 PCICMD—PCI Command Register (Audio—D31:F5) ...................13-2
13.1.4 PCISTS—PCI Device Status Register (Audio—D31:F5)...............13-3
13.1.5 RID—Revision Identification Register (Audio—D31:F5)................13-3
13.1.6 PI—Programming Interface Register (Audio—D31:F5) .................13-3
13.1.7 SCC—Sub Class Code Register (Audio—D31:F5) .......................13-4
13.1.8 BCC—Base Class Code Register (Audio—D31:F5)......................13-4
13.1.9 HEDT—Header Type Register (Audio—D31:F5) ..........................13-4
13.1.10 NAMBAR—Native Audio Mixer Base Address Register
(Audio—D31:F5) ............................................................................13-5
13.1.11 NABMBAR—Native Audio Bus Mastering Base Address
Register (Audio—D31:F5)..............................................................13-5
13.1.12 SVID—Subsystem Vendor ID Register (Audio—D31:F5)..............13-6
82801BA ICH2 and 82801BAM ICH2-M Datasheet
13.2
14
AC’97 Modem Controller Registers (D31:F6) ..........................................................14-1
14.1
14.2
15
13.1.13 SID—Subsystem ID Register (Audio—D31:F5).............................13-6
13.1.14 INTR_LN—Interrupt Line Register (Audio—D31:F5) .....................13-6
13.1.15 INTR_PN—Interrupt Pin Register (Audio—D31:F5) ......................13-7
AC’97 Audio I/O Space (D31:F5)................................................................13-7
13.2.1 x_BDBAR—Buffer Descriptor Base Address Register ..................13-9
13.2.2 x_CIV—Current Index Value Register .........................................13-10
13.2.3 x_LVI—Last Valid Index Register ................................................13-10
13.2.4 x_SR—Status Register ................................................................13-11
13.2.5 x_PICB—Position In Current Buffer Register ..............................13-12
13.2.6 x_PIV—Prefetched Index Value Register ....................................13-12
13.2.7 x_CR—Control Register ..............................................................13-13
13.2.8 GLOB_CNT—Global Control Register.........................................13-14
13.2.9 GLOB_STA—Global Status Register ..........................................13-15
13.2.10 CAS—Codec Access Semaphore Register .................................13-16
AC’97 Modem PCI Configuration Space (D31:F6) .....................................14-1
14.1.1 VID—Vendor Identification Register (Modem—D31:F6) ...............14-1
14.1.2 DID—Device Identification Register (Modem—D31:F6) ................14-2
14.1.3 PCICMD—PCI Command Register (Modem—D31:F6) ................14-2
14.1.4 PCISTA—Device Status Register (Modem—D31:F6) ...................14-3
14.1.5 RID—Revision Identification Register (Modem—D31:F6) .............14-3
14.1.6 PI—Programming Interface Register (Modem—D31:F6) ..............14-3
14.1.7 SCC—Sub Class Code Register (Modem—D31:F6).....................14-4
14.1.8 BCC—Base Class Code Register (Modem—D31:F6) ...................14-4
14.1.9 HEDT—Header Type Register (Modem—D31:F6)........................14-4
14.1.10 MMBAR—Modem Mixer Base Address Register
(Modem—D31:F6) .........................................................................14-4
14.1.11 MBAR—Modem Base Address Register (Modem—D31:F6) ........14-5
14.1.12 SVID—Subsystem Vendor ID (Modem—D31:F6) .........................14-5
14.1.13 SID—Subsystem ID (Modem—D31:F6) ........................................14-6
14.1.14 INTR_LN—Interrupt Line Register (Modem—D31:F6) ..................14-6
14.1.15 INT_PIN—Interrupt Pin (Modem—D31:F6) ...................................14-6
AC’97 Modem I/O Space (D31:F6) .............................................................14-7
14.2.1 x_BDBAR—Buffer Descriptor List Base Address Register ............14-8
14.2.2 x_CIV—Current Index Value Register ...........................................14-9
14.2.3 x_LVI—Last Valid Index Register ..................................................14-9
14.2.4 x_SR—Status Register ................................................................14-10
14.2.5 x_PICB—Position In Current Buffer Register ..............................14-11
14.2.6 x_PIV—Prefetch Index Value Register ........................................14-11
14.2.7 x_CR—Control Register ..............................................................14-11
14.2.8 GLOB_CNT—Global Control Register.........................................14-12
14.2.9 GLOB_STA—Global Status Register ..........................................14-13
14.2.10 CAS—Codec Access Semaphore Register .................................14-14
Pinout and Package Information..............................................................................15-1
15.1
15.2
Pinout..........................................................................................................15-1
Package Information .................................................................................15-14
82801BA ICH2 and 82801BAM ICH2-M Datasheet
xix
16
Electrical Characteristics .........................................................................................16-1
16.1
16.2
16.3
16.4
16.5
17
Absolute Maximum Ratings ........................................................................16-1
Functional Operating Range.......................................................................16-1
D.C. Characteristics....................................................................................16-2
A.C. Characteristics ....................................................................................16-7
Timing Diagrams.......................................................................................16-18
Testability.................................................................................................................17-1
17.1
17.2
17.3
Test Mode Description................................................................................17-1
Tri-state Mode.............................................................................................17-2
XOR Chain Mode........................................................................................17-2
17.3.1 XOR Chain Testability Algorithm Example ....................................17-2
17.3.1.1 Test Pattern Consideration for XOR Chain 4 .................17-3
A
I/O Register Index..................................................................................................... A-1
B
Register Bit Index ..................................................................................................... B-1
xx
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Figures
2-1
2-2
4-1
4-2
5-1
5-2
5-3
5-4
5-5
5-6
5-7
5-8
5-9
5-10
5-11
5-12
5-13
5-14
5-15
5-16
5-17
5-18
5-19
5-20
5-21
5-22
5-23
5-24
5-25
5-26
5-27
15-1
15-2
15-3
15-4
16-1
16-2
16-3
16-4
16-5
16-6
16-7
16-8
16-9
16-10
16-11
Required External RTC Circuit....................................................................2-16
Example V5REF Sequencing Circuit ..........................................................2-16
ICH2 and System Clock Domains................................................................4-1
Conceptual System Clock Diagram (82801BA ICH2 and
82801BAM ICH2-M)......................................................................................4-2
Primary Device Status Register Error Reporting Logic.................................5-3
Secondary Status Register Error Reporting Logic ........................................5-3
NMI# Generation Logic .................................................................................5-4
Integrated LAN Controller Block Diagram.....................................................5-7
64-Word EEPROM Read Instruction Waveform .........................................5-17
LPC Interface Diagram ...............................................................................5-21
Typical Timing for LFRAME# ......................................................................5-24
Abort Mechanism ........................................................................................5-24
ICH2 DMA Controller ..................................................................................5-26
DMA Serial Channel Passing Protocol .......................................................5-30
DMA Request Assertion Through LDRQ# ..................................................5-34
Coprocessor Error Timing Diagram ............................................................5-67
Signal Strapping..........................................................................................5-70
Intel® SpeedStep™ Block Diagram (82801BAM ICH2-M only) ..................5-85
Physical Region Descriptor Table Entry ...................................................5-101
Transfer Descriptor ...................................................................................5-109
Example Queue Conditions ......................................................................5-116
USB Data Encoding ..................................................................................5-119
USB Legacy Keyboard Flow Diagram ......................................................5-128
ICH2 Based AC’97 2.1..............................................................................5-143
AC’97 2.1 Controller-Codec Connection...................................................5-144
AC-link Protocol ........................................................................................5-145
AC-link Powerdown Timing.......................................................................5-151
SDIN Wake Signaling ...............................................................................5-152
FWH Memory Cycle Preamble .................................................................5-155
Single Byte Read ......................................................................................5-155
Single Byte Write ......................................................................................5-156
ICH2 82801BA and ICH2-M 82801BAM Ballout
(Top view — Left side) ................................................................................15-2
ICH2 82801BA and ICH2-M 82801BAM Ballout
(Top view — Right side)..............................................................................15-3
ICH2 / ICH2-M Package (Top and Side Views) ........................................15-14
ICH2 / ICH2-M Package (Bottom View)....................................................15-15
Clock Timing .............................................................................................16-18
Valid Delay From Rising Clock Edge ........................................................16-18
Setup And Hold Times ..............................................................................16-18
Float Delay................................................................................................16-18
Pulse Width...............................................................................................16-19
Output Enable Delay.................................................................................16-19
IDE PIO Mode...........................................................................................16-19
IDE Multiword DMA...................................................................................16-20
Ultra ATA Mode (Drive Initiating a Burst Read) ........................................16-20
Ultra ATA Mode (Sustained Burst)............................................................16-21
Ultra ATA Mode (Pausing a DMA Burst)...................................................16-21
82801BA ICH2 and 82801BAM ICH2-M Datasheet
xxi
16-12
16-13
16-14
16-15
16-16
16-17
16-18
16-19
16-20
16-21
16-22
16-23
16-24
16-25
16-26
16-27
16-28
17-1
17-2
xxii
Ultra ATA Mode (Terminating a DMA Burst) ............................................16-22
USB Rise and Fall Times..........................................................................16-22
USB Jitter..................................................................................................16-22
USB EOP Width........................................................................................16-23
SMBus Transaction ..................................................................................16-23
SMBus Time-out .......................................................................................16-23
Power Sequencing and Reset Signal Timings
(82801BA ICH2 only)................................................................................16-24
Power Sequencing and Reset Signal Timings
(82801BAM ICH2-M only).........................................................................16-24
1.8V/3.3V Power Sequencing...................................................................16-25
G3 (Mechanical Off) to S0 Timings (82801BA ICH2 only)........................16-25
G3 (Mechanical Off) to S0 Timings (82801BAM ICH2-M only) ................16-26
S0 to S1 to S0 Timings (82801BA ICH2 only) ..........................................16-26
S0 to S1 to S0 Timings (82801BAM ICH2-M only) ...................................16-27
S0 to S5 to S0 Timings (82801BA ICH2 only) ..........................................16-27
S0 to S5 to S0 Timings (82801BAM ICH2-M only) ...................................16-28
C0 to C2 to C0 Timings ............................................................................16-28
C0 to C3 to C0 Timings (82801BAM ICH2-M only) ..................................16-29
Test Mode Entry (XOR Chain Example).....................................................17-1
Example XOR Chain Circuitry ....................................................................17-2
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Tables
1-1
1-2
2-1
2-2
2-3
2-4
2-5
2-6
2-7
2-8
2-9
2-10
2-11
2-12
2-13
2-14
2-15
2-16
2-17
2-18
2-19
2-20
2-21
3-1
3-2
3-3
3-4
3-5
5-1
5-2
5-3
5-4
5-5
5-6
5-7
5-8
5-9
5-10
5-11
5-12
5-13
5-14
5-15
5-16
5-17
5-18
5-19
5-20
5-21
Industry Specifications ..................................................................................1-1
PCI Devices and Functions...........................................................................1-3
Hub Interface Signals....................................................................................2-1
LAN Connect Interface Signals.....................................................................2-1
EEPROM Interface Signals...........................................................................2-2
Firmware Hub Interface Signals....................................................................2-2
PCI Interface Signals ....................................................................................2-2
IDE Interface Signals ....................................................................................2-5
LPC Interface Signals ...................................................................................2-6
Interrupt Signals............................................................................................2-6
USB Interface Signals...................................................................................2-7
Power Management Interface Signals ..........................................................2-7
Processor Interface Signals ..........................................................................2-9
SM Bus Interface Signals............................................................................2-10
System Management Interface Signals ......................................................2-10
Real Time Clock Interface...........................................................................2-11
Other Clocks ...............................................................................................2-11
Miscellaneous Signals ................................................................................2-11
AC’97 Link Signals......................................................................................2-12
General Purpose I/O Signals ......................................................................2-12
Power and Ground Signals .........................................................................2-13
Functional Strap Definitions ........................................................................2-14
Test Mode Selection ...................................................................................2-15
ICH2 Power Planes.......................................................................................3-1
Integrated Pull-Up and Pull-Down Resistors.................................................3-1
IDE Series Termination Resistors.................................................................3-2
Power Plane and States for Output and I/O Signals.....................................3-3
Power Plane for Input Signals.......................................................................3-6
Type 0 Configuration Cycle Device Number Translation ..............................5-5
I/O Control Hub 2 EEPROM Address Map .................................................5-18
LPC Cycle Types Supported.......................................................................5-21
Start Field Bit Definitions.............................................................................5-22
Cycle Type Bit Definitions ...........................................................................5-22
Transfer Size Bit Definition .........................................................................5-22
SYNC Bit Definition.....................................................................................5-23
ICH2 Response to Sync Failures................................................................5-23
DMA Transfer Size......................................................................................5-28
Address Shifting in 16-bit I/O DMA Transfers .............................................5-28
DMA Cycle vs. I/O Address ........................................................................5-32
PCI Data Bus vs. DMA I/O Port Size ..........................................................5-32
DMA I/O Cycle Width vs. BE[3:0]#..............................................................5-33
Counter Operating Modes...........................................................................5-39
Interrupt Controller Core Connections ........................................................5-41
Interrupt Status Registers ...........................................................................5-42
Content of Interrupt Vector Byte .................................................................5-42
APIC Interrupt Mapping ..............................................................................5-49
Arbitration Cycles........................................................................................5-50
APIC Message Formats..............................................................................5-51
EOI Message ..............................................................................................5-51
82801BA ICH2 and 82801BAM ICH2-M Datasheet
xxiii
5-22
5-23
5-24
5-25
5-26
5-27
5-28
5-29
5-30
5-31
5-32
5-33
5-34
5-35
5-36
5-37
5-38
5-39
5-40
5-41
5-42
5-43
5-44
5-45
5-46
5-47
5-48
5-49
5-50
5-51
5-52
5-53
5-54
5-55
5-56
5-57
5-58
5-59
5-60
5-61
5-62
5-63
5-64
5-65
5-66
5-67
5-68
5-69
5-70
5-71
5-72
xxiv
Short Message............................................................................................5-52
APIC Bus Status Cycle Definition ...............................................................5-53
Lowest Priority Message (Without Focus Processor) .................................5-54
Remote Read Message ..............................................................................5-55
Interrupt Message Address Format ............................................................5-58
Interrupt Message Data Format..................................................................5-59
Stop Frame Explanation .............................................................................5-61
Data Frame Format ....................................................................................5-62
Configuration Bits Reset By RTCRST# Assertion ......................................5-65
INIT# Going Active......................................................................................5-67
NMI Sources ...............................................................................................5-67
DP Signal Differences (82801BA ICH2 only)..............................................5-68
Frequency Strap Behavior Based on Exit State .........................................5-69
Frequency Strap Bit Mapping .....................................................................5-69
General Power States for Systems using ICH2..........................................5-72
State Transition Rules for ICH2 ..................................................................5-73
System Power Plane ..................................................................................5-74
Causes of SMI# and SCI ............................................................................5-75
Break Events ..............................................................................................5-77
Sleep Types................................................................................................5-81
Causes of Wake Events .............................................................................5-82
GPI Wake Events .......................................................................................5-82
Sleep State Exit Latencies..........................................................................5-83
Transitions Due To Power Failure ..............................................................5-83
Transitions Due to Power Button ................................................................5-87
Transitions Due to RI# signal......................................................................5-88
Write Only Registers with Read Paths in Alternate Access Mode..............5-89
PIC Reserved Bits Return Values...............................................................5-91
Register Write Accesses in Alternate Access Mode...................................5-91
ICH2 Clock Inputs.......................................................................................5-93
Alert on LAN* Message Data......................................................................5-97
IDE Transaction Timings (PCI Clocks) .....................................................5-100
Interrupt/Active Bit Interaction Definition...................................................5-103
UltraATA/33 Control Signal Redefinitions.................................................5-105
Frame List Pointer Bit Description ............................................................5-108
TD Link Pointer .........................................................................................5-109
TD Control and Status ..............................................................................5-110
TD Token ..................................................................................................5-112
TD Buffer Pointer ......................................................................................5-112
Queue Head Block....................................................................................5-113
Queue Head Link Pointer .........................................................................5-113
Queue Element Link Pointer.....................................................................5-113
Command Register, Status Register and TD Status Bit Interaction .........5-115
Queue Advance Criteria ...........................................................................5-117
USB Schedule List Traversal Decision Table ...........................................5-118
PID Format ...............................................................................................5-120
PID Types .................................................................................................5-121
Address Field............................................................................................5-121
Endpoint Field...........................................................................................5-122
Token Format ...........................................................................................5-123
SOF Packet ..............................................................................................5-123
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-73
5-74
5-75
5-76
5-77
5-78
5-79
5-80
5-81
5-82
5-83
5-84
5-85
5-86
5-87
5-88
5-89
5-90
5-91
5-92
6-1
6-2
6-3
6-4
7-1
7-2
7-3
7-4
7-5
7-6
8-1
9-1
9-2
9-3
9-4
9-5
9-6
9-7
9-8
9-9
9-10
9-11
9-12
9-13
10-1
10-2
11-1
11-2
11-3
12-1
Data Packet Format ..................................................................................5-124
Bits maintained in low power states..........................................................5-127
USB Legacy Keyboard State Transitions..................................................5-129
Quick Protocol...........................................................................................5-131
Send / Receive Byte Protocol ...................................................................5-131
Write Byte/Word Protocol..........................................................................5-132
Read Byte/Word Protocol .........................................................................5-132
Process Call Protocol................................................................................5-133
Block Read/Write Protocol ........................................................................5-135
I2C Block Read .........................................................................................5-136
Slave Write Cycle Format .........................................................................5-139
Slave Write Registers ...............................................................................5-139
Command Types.......................................................................................5-140
Read Cycle Format ...................................................................................5-140
Data Values for Slave Read Registers .....................................................5-141
Featured Supported by ICH2 ....................................................................5-142
AC’97 Signals ...........................................................................................5-144
Input Slot 1 Bit Definitions.........................................................................5-149
Output Tag Slot 0......................................................................................5-150
AC-link state during PCIRST# ..................................................................5-153
PCI Devices and Functions...........................................................................6-2
Fixed I/O Ranges Decoded by ICH2.............................................................6-3
Variable I/O Decode Ranges ........................................................................6-5
Memory Decode Ranges from Processor Perspective .................................6-6
PCI Configuration Map (LAN Controller—B1:D8:F0)....................................7-1
Configuration of Subsystem ID and Subsystem Vendor ID via
EEPROM ......................................................................................................7-6
Data Register Structure ..............................................................................7-10
ICH2 Integrated LAN Controller CSR Space ..............................................7-10
Self-Test Results Format ............................................................................7-15
Statistical Counters .....................................................................................7-20
PCI Configuration Map (HUB-PCI—D30:F0) ................................................8-1
PCI Configuration Map (LPC I/F—D31:F0)...................................................9-1
DMA Registers............................................................................................9-23
PIC Registers..............................................................................................9-33
APIC Direct Registers .................................................................................9-41
APIC Indirect Registers...............................................................................9-41
RTC I/O Registers.......................................................................................9-47
RTC (Standard) RAM Bank ........................................................................9-47
PCI Configuration Map (PM—D31:F0) .......................................................9-54
APM Register Map......................................................................................9-60
ACPI and Legacy I/O Register Map............................................................9-61
TCO I/O Register Map ................................................................................9-79
Summary of GPIO Implementation .............................................................9-85
Registers to Control GPIO ..........................................................................9-87
PCI Configuration Map (IDE—D31:F1).......................................................10-1
Bus Master IDE I/O Registers...................................................................10-11
PCI Configuration Map (USB—D31:F2/F4) ................................................11-1
USB I/O Registers.......................................................................................11-8
Run/Stop, Debug Bit Interaction SWDBG (Bit 5),
Run/Stop (Bit 0) Operation........................................................................11-10
PCI Configuration Registers (SMBUS—D31:F3)........................................12-1
82801BA ICH2 and 82801BAM ICH2-M Datasheet
xxv
12-2
13-1
13-2
13-3
14-1
14-2
14-3
15-1
15-2
16-1
16-2
16-3
16-4
16-5
16-6
16-7
16-8
16-9
16-10
16-11
16-12
16-13
16-14
16-15
16-16
16-17
16-18
16-19
17-1
17-2
17-3
17-4
17-5
17-6
17-7
A-1
A-2
xxvi
SMB I/O Registers ......................................................................................12-6
PCI Configuration Map (Audio—D31:F5) ...................................................13-1
ICH2 Audio Mixer Register Configuration...................................................13-7
Native Audio Bus Master Control Registers ...............................................13-9
PCI Configuration Map (Modem—D31:F6).................................................14-1
ICH2 Modem Mixer Register Configuration ................................................14-7
Modem Registers........................................................................................14-8
ICH2 82801BA Alphabetical Ball List by Signal Name ...............................15-4
ICH2-M 82801BAM Alphabetical Ball List by Signal Name ........................15-9
ICH2-M Power Consumption Measurements .............................................16-2
DC Characteristic Input Signal Association ................................................16-2
DC Input Characteristics.............................................................................16-3
DC Characteristic Output Signal Association .............................................16-4
DC Output Characteristics ..........................................................................16-5
Other DC Characteristics ............................................................................16-6
Clock Timings .............................................................................................16-7
PCI Interface Timing ...................................................................................16-9
IDE PIO & Multiword DMA Mode Timing ..................................................16-10
Ultra ATA Timing (Mode 0, Mode 1, Mode 2) ...........................................16-11
Ultra ATA Timing (Mode 3, Mode 4, Mode 5) ...........................................16-11
Universal Serial Bus Timing......................................................................16-12
IOAPIC Bus Timing...................................................................................16-13
SMBus Timing ..........................................................................................16-13
AC’97 Timing ............................................................................................16-13
LPC Timing ...............................................................................................16-14
Miscellaneous Timings .............................................................................16-14
Power Sequencing and Reset Signal Timings..........................................16-14
Power Management Timings ....................................................................16-16
Test Mode Selection ...................................................................................17-1
XOR Test Pattern Example ........................................................................17-2
XOR Chain #1 (RTCRST# Asserted for 4 PCI Clocks while
PWROK Active) ..........................................................................................17-4
XOR Chain #2 (RTCRST# Asserted for 5 PCI clocks while
PWROK Active) ..........................................................................................17-5
XOR Chain #3 (RTCRST# Asserted for 6 PCI Clocks while
PWROK Active) ..........................................................................................17-6
XOR Chain #4 (RTCRST# Asserted for 7 PCI Clocks while
PWROK Active) ..........................................................................................17-7
Signals Not in XOR Chain ..........................................................................17-8
ICH2 Fixed I/O Registers............................................................................. A-1
ICH2 Variable I/O Registers ........................................................................ A-6
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Revision History
Revision
-001
-002
Description
Initial Release.
• Edits throughout for clarity
• Added ICH2-M: Initial Release
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Date
June 2000
October 2000
xxvii
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xxviii
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Introduction
1
Introduction
The Intel® 82801BA ICH2 and Intel® 82801BAM ICH2-M are a highly integrated multifunctional
I/O Controller Hubs that provide the interface to the PCI Bus and integrate many of the functions
needed in today’s PC platforms. The 82801BA is intended for desktop applications and the
82801BAM is intended for mobile applications. This datasheet provides a detailed description of
the 82801BA and 82801BAM functions and capabilities including, signals, registers, on-chip
functional units, interfaces, pinout, packaging, electrical characteristics, and testability.
Unless otherwise specified, all non-shaded areas describe the functionality of both components. In
the non-shaded areas, the term "ICH2" refers to both the 82801BA and 82801BAM components.
Shading, as is shown here, indicates differences between the two components. In the shaded areas
ICH2 refers to the 82801BA and ICH2-M refers to the 82801BAM.
1.1
About this Document
This datasheet is intended for Original Equipment Manufacturers and BIOS vendors creating
ICH2-based products. This document assumes a working knowledge of the vocabulary and
principles of USB, IDE, AC’97, SMBus, PCI, ACPI, LAN, and LPC. Although some details of
these features are described within this document, refer to the individual industry specifications
listed in Table 1-1 for the complete details.
Table 1-1. Industry Specifications
Specification
LPC
AC’97
WfM
SMBus
Location
http://developer.intel.com/design/pcisets/lpc/
http://developer.intel.com/pc-supp/platform/ac97/
http://developer.intel.com/ial/WfM/usesite.htm
http://www.sbs-forum.org/specs.htm
PCI
http://pcisig.com/specs.htm
USB
http://www.usb.org
ACPI
http://www.teleport.com/~acpi/
Chapter 1. Introduction
Chapter 1 introduces the ICH2 and provides information on document organization. This chapter
also describes the key features of the ICH2 and provides a brief description of the major functions.
Chapter 2. Signal Description
Chapter 2 provides a detailed description of each ICH2 signal. Signals are arranged according to
interface and details are provided as to the drive characteristics (Input/Output, Open Drain, etc.) of
all signals.
Chapter 3. Power Planes and Pin States
Chapter 3 provides a complete list of signals, their associated power well, their logic level in each
suspend state, and their logic level before and after reset.
Chapter 4. System Clock Domains
Chapter 4 provides a list of each clock domain associated with the ICH2 in an ICH2-based system.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
1-1
Introduction
Chapter 5. Functional Description
Chapter 5 provides a detailed description of the functions in the ICH2. All PCI buses, devices and
functions in this manual are abbreviated using the following nomenclature; Bus:Device:Function.
This datasheet abbreviates buses as B0 and B1, devices as D8, D30 and D31 and functions as F0,
F1, F2, F3, F4, F5 and F6. For example Device 31 Function 5 is abbreviated as D31:F5, Bus 1
Device 8 Function 0 is abbreviated as B1:D8:F0. Generally, the bus number will not be used, and
can be considered to be Bus 0. Note that the ICH2’s external PCI bus is typically Bus 1; however, it
may be assigned a different number depending on system configuration.
Chapter 6. Register, Memory and I/O Address Maps
Chapter 6 provides an overview of the registers, fixed I/O ranges, variable I/O ranges and memory
ranges decoded by the ICH2.
Chapter 7. LAN Controller Registers
Chapter 7 provides a detailed description of all registers that reside in the ICH2’s integrated LAN
Controller. The integrated LAN Controller resides on the ICH2’s external PCI bus (typically Bus 1)
at Device 8, Function 0 (B1:D8:F0).
Chapter 8. Hub Interface to PCI Bridge Registers
Chapter 8 provides a detailed description of all registers that reside in the Hub Interface to PCI
bridge. This bridge resides at Device 30, Function 0 (D30:F0).
Chapter 9. LPC Bridge Registers
Chapter 9 provides a detailed description of all registers that reside in the LPC bridge. This bridge
resides at Device 31, Function 0 (D31:F0). This function contains registers for many different units
within the ICH2 including DMA, Timers, Interrupts, CPU Interface, GPIO, Power Management,
System Management and RTC.
Chapter 10. IDE Controller Registers
Chapter 10 provides a detailed description of all registers that reside in the IDE controller. This
controller resides at Device 31, Function 1 (D31:F1).
Chapter 11. USB Controller Registers
Chapter 11 provides a detailed description of all registers that reside in the two USB controllers.
These controllers reside at Device 31, Functions 2 and 4 (D31:F2/F4).
Chapter 12. SMBus Controller Registers
Chapter 12 provides a detailed description of all registers that reside in the SMBus controller. This
controller resides at Device 31, Function 3 (D31:F3).
Chapter 13. AC’97 Audio Controller Registers
Chapter 13 provides a detailed description of all registers that reside in the audio controller. This
controller resides at Device 31, Function 5 (D31:F5). Note that this section of the datasheet does
not include the native audio mixer registers. Accesses to the mixer registers are forwarded over the
AC-link to the codec where the registers reside.
Chapter 14. AC’97 Modem Controller Registers
Chapter 14 provides a detailed description of all registers that reside in the modem controller. This
controller resides at Device 31, Function 6 (D31:F6). Note that this section of the datasheet does
not include the modem mixer registers. Accesses to the mixer registers are forwarded over the
AC-link to the codec where the registers reside.
Chapter 15. Pinout and Package Information
Chapter 15 provides the ball assignment for the 360 EBGA package. The chapter also provides the
physical dimensions and characteristics of the 360 EBGA package.
Chapter 16. Electrical Characteristics
Chapter 16 provides the AC and DC characteristics including timing diagrams.
Chapter 17. Testability
Chapter 17 provides details about the implementation of test modes on the ICH2.
Index
There are indexes listing registers and register bits.
1-2
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Introduction
1.2
Overview
The ICH2 provides extensive I/O support. Functions and capabilities include:
•
•
•
•
•
•
•
•
•
•
•
•
PCI Rev 2.2 compliant with support for 33 MHz PCI operations.
PCI slots ( supports up to 6 Req/Gnt pairs)
ACPI Power Management Logic Support
Enhanced DMA Controller, Interrupt Controller, and Timer Functions
Integrated IDE controller supports Ultra ATA100/66/33)
USB host interface with support for 4 USB ports; 2 host controllers
Integrated LAN Controller
System Management Bus (SMBus) with additional support for I2C devices
AC’97 2.1 Compliant Link for Audio and Telephony codecs (up to 6 channels)
Low Pin Count (LPC) interface
Firmware Hub (FWH) interface support
Alert On LAN* (AOL) and Alert On LAN 2 (AOL2)*
The ICH2 incorporates a variety of PCI functions that are divided into two logical devices
(30 and 31) on PCI Bus 0 and one device on Bus 1. Device 30 is the Hub Interface-To-PCI bridge.
Device 31 contains all the other PCI functions, except the LAN Controller as shown in Table 1-2.
The LAN controller is located on Bus 1.
Table 1-2. PCI Devices and Functions
Bus:Device:Function
Function Description
Bus 0:Device 30:Function 0
Hub Interface to PCI Bridge
Bus 0:Device 31:Function 0
PCI to LPC Bridge
(includes: DMA, Timers, compatible interrupt controller, APIC, RTC,
processor interface control, power management control, System
Management control, and GPIO control)
Bus 0:Device 31:Function 1
IDE Controller
Bus 0:Device 31:Function 2
USB Controller #1
Bus 0:Device 31:Function 3
SMBus Controller
Bus 0:Device 31:Function 4
USB Controller #2
Bus 0:Device 31:Function 5
AC’97 Audio Controller
Bus 0:Device 31:Function 6
AC’97 Modem Controller
Bus 1:Device 8:Function 0
LAN Controller
82801BA ICH2 and 82801BAM ICH2-M Datasheet
1-3
Introduction
The following sub-sections provide an overview of the ICH2 capabilities.
Hub Architecture
As I/O speeds increase, the demand placed on the PCI bus by the I/O bridge has become
significant. With the addition of AC’97 and Ultra ATA/100, coupled with the existing USB, I/O
requirements could impact PCI bus performance. The chipset’s hub interface architecture ensures
that the I/O subsystem; both PCI and the integrated I/O features (IDE, AC’97, USB, etc.), will
receive adequate bandwidth. By placing the I/O bridge on the hub interface (instead of PCI), the
hub architecture ensures that both the I/O functions integrated into the ICH2 and the PCI
peripherals obtain the bandwidth necessary for peak performance.
PCI Interface
The ICH2 PCI interface provides a 33 MHz, Rev. 2.2 compliant implementation. All PCI signals
are 5V tolerant, except PME#. The ICH2 integrates a PCI arbiter that supports up to six external
PCI bus masters in addition to the internal ICH2 requests.
IDE Interface (Bus Master capability and synchronous DMA Mode)
The fast IDE interface supports up to four IDE devices providing an interface for IDE hard disks
and CD ROMs. Each IDE device can have independent timings. The IDE interface supports PIO
IDE transfers up to 14 Mbytes/sec and Bus Master IDE transfers up 100 Mbytes/sec. It does not
consume any ISA DMA resources. The IDE interface integrates 16x32-bit buffers for optimal
transfers.
The ICH2’s IDE system contains two independent IDE signal channels. They can be electrically
isolated independently. They can be configured to the standard primary and secondary channels
(four devices). There are integrated series resistors on the data and control lines (see Section 5.15,
“IDE Controller (D31:F1)” on page 5-99 for details).
Low Pin Count (LPC) Interface
The ICH2 implements an LPC Interface as described in the LPC 1.0 specification. The Low Pin
Count (LPC) Bridge function of the ICH2 resides in PCI Device 31:Function 0. In addition to the
LPC bridge interface function, D31:F0 contains other functional units including DMA, Interrupt
Controllers, Timers, Power Management, System Management, GPIO, and RTC.
Note that in the current chipset platform, the Super I/O (SIO) component has migrated to the Low
Pin Count (LPC) interface. Migration to the LPC interface allows for lower cost Super I/O designs.
1-4
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Introduction
Compatibility Modules (DMA Controller, Timer/Counters, Interrupt
Controller)
The DMA controller incorporates the logic of two 82C37 DMA controllers, with seven
independently programmable channels. Channels 0–3 are hardwired to 8-bit, count-by-byte
transfers, and channels 5–7 are hardwired to 16-bit, count-by-word transfers. Any two of the seven
DMA channels can be programmed to support fast Type-F transfers.
The ICH2 supports two types of DMA (LPC and PC/PCI). DMA via LPC is similar to ISA DMA.
LPC DMA and PC/PCI DMA use the ICH2’s DMA controller. The PC/PCI protocol allows
PCI-based peripherals to initiate DMA cycles by encoding requests and grants via two PC/PCI
REQ#/GNT# pairs.
LPC DMA is handled through the use of the LDRQ# lines from peripherals and special encodings
on LAD[3:0] from the host. Single, Demand, Verify, and Increment modes are supported on the
LPC interface. Channels 0–3 are 8 bit channels. Channels 5–7 are 16 bit channels. Channel 4 is
reserved as a generic bus master request.
The timer/counter block contains three counters that are equivalent in function to those found in
one 82C54 programmable interval timer. These three counters are combined to provide the system
timer function, and speaker tone. The 14.31818-MHz oscillator input provides the clock source for
these three counters.
The ICH2 provides an ISA-Compatible interrupt controller that incorporates the functionality of
two 82C59 interrupt controllers. The two interrupt controllers are cascaded so that 14 external and
two internal interrupts are possible. In addition, the ICH2 supports a serial interrupt scheme.
All of the registers in these modules can be read and restored. This is required to save and restore
system state after power has been removed and restored to the circuit.
Advanced Programmable Interrupt Controller (APIC)
In addition to the standard ISA compatible interrupt controller (PIC) described in the previous
section, the ICH2 incorporates the Advanced Programmable Interrupt Controller (APIC). While
the standard interrupt controller is intended for use in a uni-processor system, APIC can be used in
either a uni-processor or multi-processor system.
Enhanced Universal Serial Bus (USB) Controller
The USB controller provides enhanced support for the Universal Host Controller Interface (UHCI).
This includes support that allows legacy software to use a USB-based keyboard and mouse. The
ICH2 is USB Revision 1.1 compliant. The ICH2 contains two USB Host Controllers. Each Host
Controller includes a root hub with two separate USB ports each, for a total of 4 USB ports. See
Section 5.16, “USB Controller (Device 31:Functions 2 and 4)” on page 5-108 for details.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
1-5
Introduction
LAN Controller
The ICH2’s integrated LAN Controller includes a 32-bit PCI controller that provides enhanced
scatter-gather bus mastering capabilities and enables the LAN Controller to perform high speed
data transfers over the PCI bus. Its bus master capabilities enable the component to process highlevel commands and perform multiple operations; this lowers processor utilization by off-loading
communication tasks from the processor. Two large transmit and receive FIFOs of 3 KB each help
prevent data underruns and overruns while waiting for bus accesses. This enables the integrated
LAN Controller to transmit data with minimum interframe spacing (IFS).
The LAN Controller can operate in either full duplex or half duplex mode. In full duplex mode the
LAN Controller adheres with the IEEE 802.3x Flow Control specification. Half duplex
performance is enhanced by a proprietary collision reduction mechanism. See Section 5.2, “LAN
Controller (B1:D8:F0)” on page 5-6 for details.
RTC
The ICH2 contains a Motorola* MC146818A-compatible real-time clock with 256 bytes of
battery-backed RAM. The real-time clock performs two key functions: keeping track of the time of
day and storing system data, even when the system is powered down. The RTC operates on a
32.768 KHz crystal and a separate 3V lithium battery that provides up to 7 years of protection.
The RTC also supports two lockable memory ranges. By setting bits in the configuration space,
two 8-byte ranges can be locked to read and write accesses. This prevents unauthorized reading of
passwords or other system security information.
The RTC also supports a date alarm that allows for scheduling a wake up event up to 30 days in
advance, rather than just 24 hours in advance.
GPIO
Various general purpose inputs and outputs are provided for custom system design. The number of
inputs and outputs varies depending on ICH2 configuration.
Enhanced Power Management
The ICH2’s power management functions include enhanced clock control, local and global
monitoring support for 14 individual devices, and various low-power (suspend) states
(e.g., Suspend-to-DRAM and Suspend-to-Disk). A hardware-based thermal management circuit
permits software-independent entrance to low-power states. The ICH2 contains full support for the
Advanced Configuration and Power Interface (ACPI) Specification.
For the ICH2-M 82801BAM, the Intel® SpeedStep™ technology feature enables a mobile system
to operate in multiple processor performance/thermal states and to transition smoothly between
them. The internal processor clock setting and processor supply voltage setting determines these
states. The ICH2-M supports one Low Power mode and one High Performance mode.
The ICH2-M’s PCI clock can be dynamically controlled independent of any other low-power state
(Dynamic PCI Clock control).
1-6
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Introduction
System Management Bus (SMBus)
The ICH2 contains an SMBus Host interface that allows the processor to communicate with
SMBus slaves. This interface is compatible with most I2C devices. Special I2C commands are
implemented (e.g., the I2C Read that allows the ICH2 to perform block reads of I2C devices).
The ICH2’s SMBus host controller provides a mechanism for the processor to initiate
communications with SMBus peripherals (slaves). The host controller supports seven SMBus
interface command protocols for communicating with SMBus slave devices (see System
Management Bus Specifications, Rev 1.0): Quick Command, Send Byte, Receive Byte, Write
Byte/Word, Read Byte/Word, Process Call, and Block Read/Write.
Manageability
The ICH2 integrates several functions designed to manage the system and lower the total cost of
ownership (TC0) of the system. These system management functions are designed to report errors,
diagnose the system, and recover from system lockups without the aid of an external
microcontroller.
• TCO Timer. The ICH2’s integrated programmable TC0 Timer is used to detect system locks.
The first expiration of the timer generates an SMI# that the system can use to recover from a
software lock. The second expiration of the timer causes a system reset to recover from a
hardware lock.
• Processor Present Indicator. The ICH2 looks for the processor to fetch the first instruction
after reset. If the processor does not fetch the first instruction, the ICH2 will reboot the system
at the safe-mode frequency multiplier.
• ECC Error Reporting. When detecting an ECC error, the host controller has the ability to
send one of several messages to the ICH2. The host controller can instruct the ICH2 to
generate either an SMI#, NMI, SERR#, or TCO interrupt.
• Function Disable. The ICH2 provides the ability to disable the following functions: AC’97
Modem, AC’97 Audio, IDE, USB, or SMBus. Once disabled, these functions no longer
decode I/O, memory, or PCI configuration space. Also, no interrupts or power management
events are generated from the disable functions.
• Intruder Detect. The ICH2 provides an input signal (INTRUDER#) that can be attached to a
switch that is activated by the system case being opened. The ICH2 can be programmed to
generate an SMI# or TCO interrupt due to an active INTRUDER# signal.
• SMBus. The ICH2 integrates an SMBus controller that provides an interface to manage
peripherals (e.g., serial presence detection (SPD) or RIMMs and thermal sensors).
• Alert-On-LAN*. The ICH2 supports Alert-On-LAN* and Alert-On-LAN* 2. In response to a
TCO event (intruder detect, thermal event, processor not booting) the ICH2 sends a message
over the SMBus. A LAN controller can decode this SMBus message and send a message over
the network to alert the network manager.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
1-7
Introduction
AC’97 2.1 Controller
The Audio Codec ’97 (AC’97) specification defines a digital interface that can be used to attach an
audio codec (AC), a modem codec (MC), an audio/modem codec (AMC) or both an AC and an
MC. The AC’97 specification defines the interface between the system logic and the audio or
modem codec, known as the AC’97 Digital Link.
The ICH2’s AC’97 (with the appropriate codecs) not only replaces ISA audio and modem
functionality, but also improves overall platform integration by incorporating the AC’97 digital
link. The use of the ICH2-integrated AC’97 digital link reduces cost and eases migration from ISA.
By using an audio codec, the AC’97 digital link allows for cost-effective, high-quality, integrated
audio on Intel’s chipset-based platform. In addition, an AC’97 soft modem can be implemented
with the use of a modem codec. Several system options exist when implementing AC’97. The
ICH2-integrated digital link allows several external codecs to be connected to the ICH2. The
system designer can provide audio with an audio codec, a modem with a modem codec, or an
integrated audio/modem codec. The digital link is expanded to support two audio codecs or a
combination of an audio and modem codec.
The modem implementations for different countries must be taken into consideration, because
telephone systems may vary. By using a split design, the audio codec can be on-board and the
modem codec can be placed on a riser. Intel is developing an AC’97 digital link connector. With a
single integrated codec, or AMC, both audio and modem can be routed to a connector near the rear
panel, where the external ports can be located.
The digital link in the ICH2 is compliant with revision 2.1 of the AC’97, so it supports two codecs
with independent PCI functions for audio and modem. Microphone input and left and right audio
channels are supported for a high quality, two-speaker audio solution. Wake on Ring from Suspend
also is supported with the appropriate modem codec.
The ICH2 expands the audio capability with support for up to six channels of PCM audio output
(full AC3 decode). Six-channel audio consists of Front Left, Front Right, Back Left, Back Right,
Center, and Woofer, for a complete surround-sound effect. ICH2 has expanded support for two
audio codecs on the AC’97 digital link.
1-8
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Signal Description
2
Signal Description
This chapter provides a detailed description of each signal. The signals are arranged in functional
groups according to their associated interface.
The “#” symbol at the end of the signal name indicates that the active, or asserted state occurs when
the signal is at a low voltage level. When “#” is not present, the signal is asserted when at the high
voltage level.
The following notations are used to describe the signal type:
2.1
I
Input Pin
O
Output Pin
OD
Open Drain Output Pin.
I/O
Bi-directional Input / Output Pin.
Hub Interface to Host Controller
Table 2-1. Hub Interface Signals
2.2
Name
Type
Description
HL[11:0]
I/O
Hub Interface Signals
HL_STB
I/O
Hub Interface Strobe: One of two differential strobe signals used to transmit and
receive data through the hub interface.
HL_STB#
I/O
Hub Interface Strobe Complement: Second of the two differential strobe
signals.
HLCOMP
I/O
Hub Interface Compensation: Used for hub interface buffer compensation.
Link to LAN Connect
Table 2-2. LAN Connect Interface Signals
Name
Type
Description
LAN_CLK
I
LAN Interface Clock: This signal is driven by the LAN Connect component. The
frequency range is 0.8 MHz to 50 MHz.
LAN_RXD[2:0]
I
Received Data: The LAN Connect component uses these signals to transfer
data and control information to the integrated LAN Controller. These signals have
integrated weak pull-up resistors.
LAN_TXD[2:0]
O
Transmit Data: The integrated LAN Controller uses these signals to transfer
data and control information to the LAN Connect component.
LAN_RSTSYNC
O
LAN Reset/Sync: The LAN Connect component’s Reset and Sync signals are
multiplexed onto this pin.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
2-1
Signal Description
2.3
EEPROM Interface
Table 2-3. EEPROM Interface Signals
2.4
Name
Type
Description
EE_SHCLK
O
EEPROM Shift Clock: EE_SHCLK is the serial shift clock output to the EEPROM.
EE_DIN
I
EEPROM Data In: EE_DIN transfers data from the EEPROM to the ICH2. This
signal has an integrated pull-up resistor.
EE_DOUT
O
EEPROM Data Out: EE_DOUT transfers data from the ICH2 to the EEPROM.
EE_CS
O
EEPROM Chip Select: EE_CS is a chip-select signal to the EEPROM.
Firmware Hub Interface
Table 2-4. Firmware Hub Interface Signals
2.5
Name
Type
Description
FWH[3:0] /
LAD[3:0]
I/O
Firmware Hub Signals: These signals are muxed with LPC address signals.
FWH[4] /
LFRAME#
I/O
Firmware Hub Signals: This signal is muxed with LPC LFRAME# signal.
PCI Interface
Table 2-5. PCI Interface Signals
Name
Type
Description
AD[31:0]
I/O
PCI Address/Data: AD[31:0] is a multiplexed address and data bus. During the first
clock of a transaction, AD[31:0] contain a physical address (32 bits). During
subsequent clocks, AD[31:0] contain data. The ICH2 drives all 0s on AD[31:0]
during the address phase of all PCI Special Cycles.
Bus Command and Byte Enables: The command and byte enable signals are
multiplexed on the same PCI pins. During the address phase of a transaction,
C/BE[3:0]# define the bus command. During the data phase, C/BE[3:0]# define the
Byte Enables.
C/BE[3:0]# Command Type
C/BE[3:0]#
I/O
0000
0001
0010
0011
0110
0111
1010
1011
1100
1110
1111
Interrupt Acknowledge
Special Cycle
I/O Read
I/O Write
Memory Read
Memory Write
Configuration Read
Configuration Write
Memory Read Multiple
Memory Read Line
Memory Write and Invalidate
All command encodings not shown are reserved. The ICH2 does not decode
reserved values, and therefore will not respond if a PCI master generates a cycle
using one of the reserved values.
2-2
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Signal Description
Table 2-5. PCI Interface Signals (Continued)
Name
Type
Description
I/O
Device Select: The ICH2 asserts DEVSEL# to claim a PCI transaction. As an
output, the ICH2 asserts DEVSEL# when a PCI master peripheral attempts an
access to an internal ICH2 address or an address destined for the hub interface
(main memory or AGP). As an input, DEVSEL# indicates the response to an ICH2initiated transaction on the PCI bus. DEVSEL# is tri-stated from the leading edge of
PCIRST#. DEVSEL# remains tri-stated by the ICH2 until driven by a target device.
I/O
Cycle Frame: The current Initiator drives FRAME# to indicate the beginning and
duration of a PCI transaction. While the initiator asserts FRAME#, data transfers
continue. When the initiator negates FRAME#, the transaction is in the final data
phase. FRAME# is an input to the ICH2 when the ICH2 is the target, and FRAME# is
an output from the ICH2 when the ICH2 is the Initiator. FRAME# remains tri-stated
by the ICH2 until driven by an Initiator.
I/O
Initiator Ready: IRDY# indicates the ICH2's ability, as an Initiator, to complete the
current data phase of the transaction. It is used in conjunction with TRDY#. A data
phase is completed on any clock both IRDY# and TRDY# are sampled asserted.
During a write, IRDY# indicates the ICH2 has valid data present on AD[31:0]. During
a read, it indicates the ICH2 is prepared to latch data. IRDY# is an input to the ICH2
when the ICH2 is the Target and an output from the ICH2 when the ICH2 is an
Initiator. IRDY# remains tri-stated by the ICH2 until driven by an Initiator.
I/O
Target Ready: TRDY# indicates the ICH2's ability as a Target to complete the
current data phase of the transaction. TRDY# is used in conjunction with IRDY#. A
data phase is completed when both TRDY# and IRDY# are sampled asserted.
During a read, TRDY# indicates that the ICH2, as a Target, has placed valid data on
AD[31:0]. During a write, TRDY# indicates the ICH2, as a Target is prepared to latch
data. TRDY# is an input to the ICH2 when the ICH2 is the Initiator and an output
from the ICH2 when the ICH2 is a Target. TRDY# is tri-stated from the leading edge
of PCIRST#. TRDY# remains tri-stated by the ICH2 until driven by a target.
I/O
Stop: STOP# indicates that the ICH2, as a Target, is requesting the Initiator to stop
the current transaction. STOP# causes the ICH2, as an Initiatior, to stop the current
transaction. STOP# is an output when the ICH2 is a target and an input when the
ICH2 is an Initiator. STOP# is tri-stated from the leading edge of PCIRST#. STOP#
remains tri-stated until driven by the ICH2.
PAR
I/O
Calculated/Checked Parity: PAR uses "even" parity calculated on 36 bits, AD[31:0]
plus C/BE[3:0]#. "Even" parity means that the ICH2 counts the number of 1s within
the 36 bits plus PAR and the sum is always even. The ICH2 always calculates PAR
on 36 bits, regardless of the valid byte enables. The ICH2 generates PAR for
address and data phases and only guarantees PAR to be valid one PCI clock after
the corresponding address or data phase. The ICH2 drives and tri-states PAR
identically to the AD[31:0] lines except that the ICH2 delays PAR by exactly one PCI
clock. PAR is an output during the address phase (delayed one clock) for all ICH2
initiated transactions. PAR is an output during the data phase (delayed one clock)
when the ICH2 is the Initiator of a PCI write transaction, and when it is the target of a
read transaction. ICH2 checks parity when it is the target of a PCI write transaction.
If a parity error is detected, the ICH2 sets the appropriate internal status bits, and
has the option to generate an NMI# or SMI#.
PERR#
I/O
Parity Error: An external PCI device drives PERR# when it receives data that has a
parity error. The ICH2 drives PERR# when it detects a parity error. The ICH can
either generate an NMI# or SMI# upon detecting a parity error (either detected
internally or reported via the PERR# signal).
DEVSEL#
FRAME#
IRDY#
TRDY#
STOP#
REQ[0:4]#
REQ[5]# /
REQ[B]# /
GPIO[1]
I
PCI Requests: The ICH2 supports up to 6 masters on the PCI bus. REQ[5]# is
muxed with PC/PCI REQ[B]# (must choose one or the other, but not both). If not
used for PCI or PC/PCI, REQ[5]#/REQ[B]# can instead be used as GPIO[1].
Note: REQ[0]# is programmable to have improved arbitration latency for supporting
PCI-based 1394 controllers.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
2-3
Signal Description
Table 2-5. PCI Interface Signals (Continued)
Name
Type
GNT[0:4]#
GNT[5]# /
GNT[B]# /
GPIO[17]#
PCICLK
PCIRST#
PLOCK#
O
Description
PCI Grants: The ICH2 supports up to 6 masters on the PCI bus. GNT[5]# is muxed
with PC/PCI GNT[B]# (must choose one or the other, but not both). If not needed for
PCI or PC/PCI, GNT[5]# can instead be used as a GPIO.
Pull-up resistors are not required on these signals. If pullups are used, they should
be tied to the Vcc3_3 power rail. GNT[B]#/GNT[5]#/GPIO[17] has an internal pullup.
I
PCI Clock: This is a 33 MHz clock. PCICLK provides timing for all transactions on
the PCI Bus. .
Note:For 82801BAM ICH2-M, this clock does not stop based on the STP_PCI#
signal. The PCI Clock only stops based on SLP_S1# or SLP_S3#.
O
PCI Reset: ICH2 asserts PCIRST# to reset devices that reside on the PCI bus. The
ICH2 asserts PCIRST# during power-up and when S/W initiates a hard reset
sequence through the RC (CF9h) register. The ICH2 drives PCIRST# inactive a
minimum of 1 ms after PWROK is driven active. The ICH2 drives PCIRST# active a
minimum of 1 ms when initiated through the RC register.
I/O
PCI Lock: PLOCK# indicates an exclusive bus operation and may require multiple
transactions to complete. ICH2 asserts PLOCK# when it performs non-exclusive
transactions on the PCI bus.
82801BA ICH2: PLOCK# is ignored when PCI masters are granted the bus.
82801BAM ICH2-M: Devices on the PCI bus (other than the ICH2-M) are not
permitted to assert the PLOCK# signal.
I
System Error: SERR# can be pulsed active by any PCI device that detects a
system error condition. Upon sampling SERR# active, the ICH2 has the ability to
generate an NMI, SMI#, or interrupt.
PME#
I
PCI Power Management Event: PCI peripherals drive PME# to wake the system
from low-power states S1–S5. PME# assertion can also be enabled to generate an
SCI from the S0 state. In some cases the ICH2 may drive PME# active due to an
internal wake event. The ICH2 will not drive PME# high, but it will be pulled up to
VccSus3_3 by an internal pull-up resistor.
CLKRUN#
(ICH2-M only)
I/O
PCI Clock Run: For the ICH2-M, CLKRUN# is used to support PCI Clock Run
protocol. This signal connects to PCI devices that need to request clock re-start or
prevention of clock stopping.
SERR#
REQ[A]# /
GPIO[0]
REQ[B]# /
REQ[5]# /
GPIO[1]
I
When not used for PC/PCI requests, these signals can be used as General Purpose
Inputs. Instead, REQ[B]# can be used as the 6th PCI bus request.
GNT[A]# /
GPIO[16]
GNT[B]# /
GNT[5]# /
GPIO[17]
2-4
PC/PCI DMA Request [A:B]: This request serializes ISA-like DMA Requests for the
purpose of running ISA-compatible DMA cycles over the PCI bus. This is used by
devices such as PCI-based Super I/O or audio codecs that need to perform legacy
8237 DMA but have no ISA bus.
O
PC/PCI DMA Acknowledges [A:B]: This grant serializes an ISA-like DACK# for the
purpose of running DMA/ISA master cycles over the PCI bus. This is used by
devices such as PCI-based Super/IO or audio codecs which need to perform legacy
8237 DMA but have no ISA bus.
When not used for PC/PCI, these signals can be used as General Purpose Outputs.
GNTB# can also be used as the 6th PCI bus master grant output. These signal have
internal pull-up resistors.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Signal Description
2.6
IDE Interface
Table 2-6. IDE Interface Signals
Name
PDCS1#,
SDCS1#
PDCS3#,
SDCS3#
PDA[2:0],
SDA[2:0]
PDD[15:0],
SDD[15:0]
PDDREQ,
SDDREQ
PDDACK#,
SDDACK#
Type
Description
O
Primary and Secondary IDE Device Chip Selects for 100 Range: These
signals are for the ATA command register block. This output signal is connected
to the corresponding signal on the primary or secondary IDE connector.
O
Primary and Secondary IDE Device Chip Select for 300 Range: These signals
are for the ATA control register block. This output signal is connected to the
corresponding signal on the primary or secondary IDE connector.
O
Primary and Secondary IDE Device Address: These output signals are
connected to the corresponding signals on the primary or secondary IDE
connectors. They are used to indicate which byte in either the ATA command
block or control block is being addressed.
I/O
Primary and Secondary IDE Device Data: These signals directly drive the
corresponding signals on the primary or secondary IDE connector. There is a
weak internal pull-down resistor on PDD[7] and SDD[7].
I
Primary and Secondary IDE Device DMA Request: These input signals are
directly driven from the DRQ signals on the primary or secondary IDE connector.
It is asserted by the IDE device to request a data transfer, and used in
conjunction with the PCI bus master IDE function. They are not associated with
any AT-compatible DMA channel. There is a weak internal pull-down resistor on
these signals.
O
Primary and Secondary IDE Device DMA Acknowledge: These signals
directly drive the DAK# signals on the primary and secondary IDE connectors.
Each signal is asserted by the ICH2 to indicate to the IDE DMA slave devices that
a given data transfer cycle (assertion of DIOR# or DIOW#) is a DMA data transfer
cycle. This signal is used in conjunction with the PCI bus master IDE function and
are not associated with any AT-compatible DMA channel.
Primary and Secondary Disk I/O Read (PIO and Non-Ultra DMA): This is the
command to the IDE device that it may drive data on the PDD or SDD lines. Data
is latched by the ICH2 on the deassertion edge of PDIOR# or SDIOR#. The IDE
device is selected either by the ATA register file chip selects (PDCS1# or
SDCS1#, PDCS3# or SDCS3#) and the PDA or SDA lines, or the IDE DMA
acknowledge (PDDAK# or SDDAK#).
PDIOR#
O
SDIOR#
Primary and Secondary Disk Write Strobe (Ultra DMA Writes to Disk): This is
the data write strobe for writes to disk. When writing to disk, ICH2 drives valid
data on rising and falling edges of PDWSTB or SDWSTB.
Primary and Secondary Disk DMA Ready (Ultra DMA Reads from Disk): This
is the DMA ready for reads from disk. When reading from disk, ICH2 deasserts
PRDMARDY# or SRDMARDY# to pause burst data transfers.
PDIOW#
O
SDIOW#
Primary and Secondary Disk I/O Write (PIO and Non-Ultra DMA): This is the
command to the IDE device that it may latch data from the PDD or SDD lines.
Data is latched by the IDE device on the deassertion edge of PDIOW# or
SDIOW#. The IDE device is selected either by the ATA register file chip selects
(PDCS1# or SDCS1#, PDCS3# or SDCS3#) and the PDA or SDA lines, or the
IDE DMA acknowledge (PDDAK# or SDDAK#).
Primary and Secondary Disk Stop (Ultra DMA): ICH2 asserts this signal to
terminate a burst.
Primary and Secondary I/O Channel Ready (PIO): This signal keeps the strobe
active (PDIOR# or SDIOR# on reads, PDIOW# or SDIOW# on writes) longer than
the minimum width. It adds wait states to PIO transfers.
PIORDY
I
SIORDY
Primary and Secondary Disk Read Strobe (Ultra DMA Reads from Disk):
When reading from disk, ICH2 latches data on rising and falling edges of this
signal from the disk.
Primary and Secondary Disk DMA Ready (Ultra DMA Writes to Disk): When
writing to disk, this is deasserted by the disk to pause burst data transfers.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
2-5
Signal Description
2.7
LPC Interface
Table 2-7. LPC Interface Signals
2.8
Name
Type
Description
LAD[3:0] /
FWH[3:0]
I/O
LPC Multiplexed Command, Address, Data: Internal pull-ups are provided.
LFRAME# /
FWH[4]
O
LPC Frame: LFRAME# indicates the start of an LPC cycle, or an abort.
LDRQ[1:0]#
I
LPC Serial DMA/Master Request Inputs: These signals are used to request DMA or
bus master access. Typically, they are connected to external Super I/O device. An
internal pull-up resistor is provided on these signals.
Interrupt Interface
Table 2-8. Interrupt Signals
Name
Type
SERIRQ
I/O
PIRQ[D:A]#
I/OD
I/OD
PIRQ[E]#
2-6
Serial Interrupt Request: This pin implements the serial interrupt protocol.
PCI Interrupt Requests: In Non-APIC Mode the PIRQx# signals can be routed to
interrupts 3:7, 9:12, 14, or 15 as described in the Interrupt Steering section. Each
PIRQx# line has a separate Route Control Register.
In APIC mode, these signals are connected to the internal I/O APIC in the following
fashion: PIRQ[A]# is connected to IRQ16, PIRQ[B]# to IRQ17, PIRQ[C]# to IRQ18,
and PIRQ[D]# to IRQ19. This frees the ISA interrupts.
PCI Interrupt Requests: In Non-APIC Mode the PIRQx# signals can be routed to
interrupts 3:7, 9:12, 14 or 15 as described in the Interrupt Steering section. Each
PIRQx# line has a separate Route Control Register.
PIRQ[H]#,
PIRQ[G:F]# /
GPIO[4:3],
Description
In APIC mode, these signals are connected to the internal I/O APIC in the following
fashion: PIRQ[E]# is connected to IRQ20, PIRQ[F]# to IRQ21, PIRQ[G]# to IRQ22,
and PIRQ[H]# to IRQ23. This frees the ISA interrupts. If not needed for interrupts,
PIRQ[G:F] can be used as GPIO.
IRQ[14:15]
I
Interrupt Request 14:15: These interrupt inputs are connected to the IDE drives.
IRQ14 is used by the drives connected to the primary controller and IRQ15 is used
by the drives connected to the secondary controller.
APICCLK
I
APIC Clock: The APIC clock runs at 33.333 MHz.
APICD[1:0]
I/OD
APIC Data: These bi-directional open drain signals are used to send and receive
data over the APIC bus. As inputs, the data is valid on the rising edge of APICCLK.
As outputs, new data is driven from the rising edge of the APICCLK.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Signal Description
2.9
USB Interface
Table 2-9. USB Interface Signals
2.10
Name
Type
Description
USBP0P,
USBP0N,
USBP1P,
USBP1N
I/O
Universal Serial Bus Port 1:0 Differential: These differential pairs are used to
transmit Data/Address/Command signals for ports 0 and 1 (USB Controller 1).
USBP2P,
USBP2N,
USBP3P,
USBP3N
I/O
Universal Serial Bus Port 3:2 Differential: These differential pairs are used to
transmit Data/Address/Command signals for ports 2 and 3
(USB Controller 2).
OC[3:0]#
I
Overcurrent Indicators: These signals set corresponding bits in the USB
controllers to indicate that an overcurrent condition has occurred.
Power Management Interface
Table 2-10. Power Management Interface Signals
Name
Type
Description
THRM#
I
Thermal Alarm: THRM# is an active low signal generated by external hardware to
start the hardware clock throttling mode. This signal can also generate an SMI# or
an SCI.
SLP_S1#
(ICH2-M only)
O
S1 Sleep Control: Clock synthesizer or power plane control. This signal connects
to clock synthesizer’s PWRDWN# signal. An optional use is to shut off power to
non-critical systems when in the S1 (Powered On Suspend), S3 (Suspend To
RAM), S4 (Suspend to Disk), or S5 (Soft Off) states.
SLP_S3#
O
S3 Sleep Control: Power plane control. This signal is used to shut off power to all
non-critical systems when in S3 (Suspend To RAM), S4 (Suspend to Disk) or S5
(Soft Off) states.
SLP_S5#
O
S5 Sleep Control: Power plane control. This signal is used to shut power off to all
non-critical systems when in the S4 (Suspend To Disk) or S5 (Soft Off) states.
PWROK
I
Power OK: When asserted, PWROK is an indication to the ICH2 that core power
and PCICLK have been stable for at least 1 ms. PWROK can be driven
asynchronously. When PWROK is negated, the ICH2 asserts PCIRST#.
RSM_PWROK
(ICH2 0nly)
I
Resume Well Power OK: When asserted, this signal is an indication to the ICH2
that the resume well power (VccSus3_3, VccSus1_8) has been stable for at least
10 ms.
LAN_PWROK
(ICH2-M only)
I
LAN Power OK: When asserted, this signal is an indication to the ICH2-M that the
LAN Controller power (VccLAN3_3, VccLAN1_8) has been stable for at least
10 ms.
PWRBTN#
I
Power Button: The Power Button will cause SMI# or SCI to indicate a system
request to go to a sleep state. If the system is already in a sleep state, this signal
will cause a wake event. If PWRBTN# is pressed for more than 4 seconds, this will
cause an unconditional transition (power button override) to the S5 state with only
the PWRBTN# available as a wake event. Override will occur even if the system is
in the S1-S4 states. This signal has an internal pull-up resistor.
RI#
I
Ring Indicate: From the modem interface. This signal can be enabled as a wake
event; this is preserved across power failures.
RSMRST#
I
Resume Well Reset: RSMRST# is used for resetting the resume power plane
logic.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
2-7
Signal Description
Table 2-10. Power Management Interface Signals
Name
Type
Description
SUS_STAT# /
LPCPD#
O
Suspend Status: This signal is asserted by the ICH2 to indicate that the system
will be entering a low power state soon. This can be monitored by devices with
memory that need to switch from normal refresh to suspend refresh mode. It can
also be used by other peripherals as an indication that they should isolate their
outputs that may be going to powered-off planes. This signal is called LPCPD# on
the LPC interface.
C3_STAT# /
GPIO[21]
(ICH2-M only)
O
C3_STAT#: This ICH2-M signal is typically configured as C3_STAT#. It is used for
indicating to an AGP device that a C3 state transition is beginning or ending. If
C3_STAT# functionality is not required, this signal can be used as a GPO.
SUSCLK
O
Suspend Clock: This signal is an output of the RTC generator circuit and is used
by other chips for the refresh clock.
I
VRM Power Good (ICH2 and ICH2-M): VRMPWRGD should be connected to be
the processor’s VRM Power Good.
VGATE /
VRMPWRGD
(ICH2-M only)
I
VRM Power Good Gate (ICH2-M): VGATE is used for Intel® SpeedStepTM
technology support. It is an output from the processor’s voltage regulator to
indicate that the voltage is stable. This signal can go inactive during a Intel®
SpeedStepTM transition. In non-Intel® SpeedStepTM technology systems this
signal should be connected to the processor VRM Power Good.
AGPBUSY#
(ICH2-M only)
I
AGP Bus Busy: This signal supports the C3 state. It provides an indication that the
AGP device is busy. When this signal is asserted, the BM_STS bit will be set. If this
functionality is not needed, this signal may be configured as a GPI.
STP_PCI#
(ICH2-M only)
O
Stop PCI Clock: This signal is an output to the external clock generator to turn off
the PCI clock. It is used to support PCI CLKRUN# protocol. If this functionality is
not needed, this signal can be configured as a GPO.
STP_CPU#
(ICH2-M only)
O
Stop CPU Clock: Output to the external clock generator to turn off the processor
clock. It is used to support the C3 state. If this functionality is not needed, this
signal can be configured as a GPO.
I
Battery Low: Input from battery to indicate that there is insufficient power to boot
the system. Assertion prevents wake from S1–S5 state. This signal can also be
enabled to cause an SMI# when asserted. In desktop configurations this signal
should be pulled high to VccSUS.
CPUPERF#
(ICH2-M only)
OD
CPU Performance: This signal is used for Intel® SpeedStepTM technology
support. It selects which power state to put the processo in. If this functionality is
not needed, this signal can be configured as a GPO. This is an open-drain output
signal and requires an external pull-up to the processor I/O voltage.
SSMUXSEL
(ICH2-M only)
O
VRMPWRGD
(ICH2)
VRMPWRGD/
VGATE
(ICH2-M)
BATLOW#
(ICH2-M only)
2-8
SpeedStep Mux Select: This signal is used for Intel® SpeedStepTM technology
support. It selects the voltage level for the processor. If this functionality is not
needed, this signal can be configured as a GPO.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Signal Description
2.11
Processor Interface
Table 2-11. Processor Interface Signals
Name
Type
Description
Mask A20: A20M# goes active based on setting the appropriate bit in the Port 92h
register, or based on the A20GATE signal.
A20M#
O
CPUSLP#
O
Processor Sleep: This signal puts the processor into a state that saves
substantial power compared to Stop-Grant state. However, during that time, no
snoops occur. The ICH2 can optionally assert the CPUSLP# signal when going to
the S1 state.
I
Numeric Coprocessor Error: This signal is tied to the coprocessor error signal
on the processor. FERR# is only used if the ICH2 coprocessor error reporting
function is enabled in the General Control Register (Device 31:Function 0, Offset
D0, bit 13). If FERR# is asserted, the ICH2 generates an internal IRQ13 to its
interrupt controller unit. It is also used to gate the IGNNE# signal to ensure that
IGNNE# is not asserted to the processor unless FERR# is active. FERR# requires
an external weak pull-up to ensure a high level when the coprocessor error
function is disabled.
FERR#
IGNNE#
O
Speed Strap: During the reset sequence, ICH2 drives A20M# high if the
corresponding bit is set in the FREQ_STRP register.
Ignore Numeric Error: This signal is connected to the ignore error pin on the
processor. IGNNE# is only used if the ICH2 coprocessor error reporting function is
enabled in the General Control Register (Device 31:Function 0, Offset D0,
bit 13). If FERR# is active, indicating a coprocessor error, a write to the
Coprocessor Error Register (F0h) causes the IGNNE# to be asserted. IGNNE#
remains asserted until FERR# is negated. If FERR# is not asserted when the
Coprocessor Error Register is written, the IGNNE# signal is not asserted.
Speed Strap: During the reset sequence, ICH2 drives IGNNE# high if the
corresponding bit is set in the FREQ_STRP register.
INIT#
INTR
O
O
Initialization: INIT# is asserted by the ICH2 for 16 PCI clocks to reset the
processor. ICH2 can be configured to support processor BIST. In that case, INIT#
will be active when PCIRST# is active.
Processor Interrupt: INTR is asserted by the ICH2 to signal the processor that
an interrupt request is pending and needs to be serviced. It is an asynchronous
output and normally driven low.
Speed Strap: During the reset sequence, ICH2 drives INTR high if the
corresponding bit is set in the FREQ_STRP register.
NMI
O
Non-Maskable Interrupt: NMI is used to force a non-maskable interrupt to the
processor. The ICH2 can generate an NMI when either SERR# or IOCHK# is
asserted. The processor detects an NMI when it detects a rising edge on NMI.
NMI is reset by setting the corresponding NMI source enable/disable bit in the NMI
Status and Control Register.
Speed Strap: During the reset sequence, ICH2 drives NMI high if the
corresponding bit is set in the FREQ_STRP register.
SMI#
O
System Management Interrupt: SMI# is an active low output synchronous to
PCICLK. It is asserted by the ICH2 in response to one of many enabled hardware
or software events.
STPCLK#
O
Stop Clock Request: STPCLK# is an active low output synchronous to PCICLK.
It is asserted by the ICH2 in response to one of many hardware or software
events. When the processor samples STPCLK# asserted, it responds by stopping
its internal clock.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
2-9
Signal Description
Table 2-11. Processor Interface Signals (Continued)
Name
RCIN#
Type
I
Description
Keyboard Controller Reset Processor: The keyboard controller can generate
INIT# to the processor. This saves the external OR gate with the ICH2’s other
sources of INIT#. When the ICH2 detects the assertion of this signal, INIT# is
generated for 16 PCI clocks..
Note
82801BA ICH2: The 82801BA ignores RCIN# assertion during transitions to the
S3, S4 and S5 states.
82801BAM ICH2-M: The 82801BAM ignores RCIN# assertion during transitions
to the S1, S3, S4 and S5 states.
A20GATE
I
A20 Gate: This signal is from the keyboard controller. It acts as an alternative
method to force the A20M# signal active. A20GATE saves the external OR gate
needed with various other PCIsets.
Processor Power Good (82801BA ICH2): This signal should be connected to
the processor’s PWRGOOD input. This is an open-drain output signal (external
pull-up resistor required) that represents a logical AND of the ICH2’s PWROK and
VRMPWRGD signals.
CPUPWRGD
2.12
OD
CPU Power Good (82801BAM ICH2-M): This signal should be connected to the
processor’s PWRGOOD input. For Intel® SpeedStep™ technology support, this
signal is kept high during a Intel® SpeedStep™ technology state transition to
prevent loss of processor context. This is an open-drain output signal (external
pull-up resistor required) that represents a logical AND of the ICH2-M’s PWROK
and VGATE / VRMPWRGD signals.
SMBus Interface
Table 2-12. SM Bus Interface Signals
2.13
Name
Type
Description
SMBDATA
I/OD
SMBus Data: External pull-up is required.
SMBCLK
I/OD
SMBus Clock: External pull-up is required.
SMBALERT#/
GPIO[11]
I
SMBus Alert: This signal is used to wake the system or generate an SMI#. If not
used for SMBALERT#, it can be used as a GPI.
System Management Interface
Table 2-13. System Management Interface Signals
Name
Type
INTRUDER#
I
SMLINK[1:0]
I/OD
Description
Intruder Detect: This signal can be set to disable system if box detected open.
This signal’s status is readable, so it can be used like a GPI if the Intruder
Detection is not needed.
System Management Link: These signals are an SMBus link to an optional
external system management ASIC or LAN controller. External pull-ups are
required.
Note that SMLINK[0] corresponds to an SMBus Clock signal and SMLINK[1]
corresponds to an SMBus Data signal.
2-10
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Signal Description
2.14
Real Time Clock Interface
Table 2-14. Real Time Clock Interface
2.15
Name
Type
Description
RTCX1
Special
Crystal Input 1: This signal is connected to the 32.768 KHz crystal. If no
external crystal is used, then RTCX1 can be driven with the desired clock rate.
RTCX2
Special
Crystal Input 2: This signal is connected to the 32.768 KHz crystal. If no
external crystal is used, then RTCX2 should be left floating.
Other Clocks
Table 2-15. Other Clocks
Name
Type
CLK14
I
Description
Oscillator Clock: CLK14 is used for 8254 timers and runs at 14.31818 MHz.
82801BA ICH2: This clock is permitted to stop during S3 (or lower) states.
82801BAM ICH2-M: This clock is permitted to stop during S1 (or lower) states.
48 MHz Clock: CLK48 is used to for the USB controller and runs at 48 MHz.
CLK48
I
82801BA ICH2: This clock is permitted to stop during S3 (or lower) states.
82801BAM ICH2-M: This clock is permitted to stop during S1 (or lower) states.
66 MHz Clock: CLK66 is used to for the hub interface and runs at 66 MHz.
CLK66
I
82801BA ICH2: This clock is permitted to stop during S3 (or lower) states.
82801BAM ICH2-M: This clock is permitted to stop during S1 (or lower) states.
2.16
Miscellaneous Signals
Table 2-16. Miscellaneous Signals
Name
SPKR
Type
Description
O
Speaker: The SPKR signal is the output of counter 2 and is internally "ANDed"
with Port 61h bit 1 to provide Speaker Data Enable. This signal drives an external
speaker driver device, which in turn drives the system speaker. Upon PCIRST#, its
output state is 1.
Note: SPKR is sampled at the rising edge of PWROK as a functional strap. See
Section 2.20.1for more details.
RTC Reset: When asserted, this signal resets register bits in the RTC well and
sets the RTC_PWR_STS bit (bit 2 in GEN_PMCON3 register). This signal is also
used to enter the test modes documented in Section 2.20.2.
RTCRST#
I
TP0
(ICH2 0nly)
I
Test Point (82801BA ICH2): This signal must have an external pull-up to
VccSus3_3.
FS0
I
Functional Strap: This signal is reserved for future use. There is an internal pullup resistor on this signal.
Note: Clearing CMOS in an ICH2-based platform can be done by using a jumper
on RTCRST# or GPI, or using SAFEMODE strap. Implementations should not
attempt to clear CMOS by using a jumper to pull VccRTC low.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
2-11
Signal Description
2.17
AC’97 Link
Table 2-17. AC’97 Link Signals
Name
Type
Description
AC_RST#
O
AC97 Reset: Master H/W reset to external Codec(s)
AC_SYNC
O
AC97 Sync: 48 KHz fixed rate sample sync to the Codec(s)
AC_BIT_CLK
I
AC97 Bit Clock: 12.288 MHz serial data clock generated by the external
Codec(s). See Note.
AC_SDOUT
O
Note: AC_SDOUT is sampled at the rising edge of PWROK as a functional
strap. See Section 2.20.1 for more details.
AC_SDIN[1:0]
I
AC97 Serial Data In 0: Serial TDM data inputs from the Codecs. See Note.
AC97 Serial Data Out: Serial TDM data output to the Codec(s)
NOTE: If the ACLINK Shutoff bit in the AC’97 Global Control Register (See Section 13.2.8) is set to 1, internal
pull-down resistors will be enabled on AC_BIT_CLK and AC_SDATA_IN[1:0]. If ACLINK Shutoff is
cleared to 0, these pull-down resistors are disabled. If there is no codec down on the system board, the
two signals AC_SDIN[1:0] should be pulled down externally with a resistor to ground.
2.18
General Purpose I/O
Table 2-18. General Purpose I/O Signals
Name
Type
GPIO[31:29]
O
Not implemented.
GPIO[28:27]
I/O
Can be input or output. Resume power well. Unmuxed.
GPIO[26]
I/O
Not implemented.
GPIO[25]
I/O
Can be input or output. Resume power well. Not Muxed.
I/O
Can be input or output. Resume power well.
O
Fixed as Output only. Main power well.
GPIO[24]
(ICH2 only)
GPIO[23]
(ICH2 only)
GPIO[22]
(ICH2 only)
GPIO[21]
Fixed as Output only. Main power well. Open-drain output.
O
Fixed as Output only. Main power well.
O
Fixed as Output only. Main power well.
GPIO[17:16]
O
Fixed as Output only. Main Power Well. Can instead be used for PC/PCI
GNT[A:B]#. GPIO[17] can also alternatively be used for PCI GNT[5]#. Integrated
pull-up resistor.
GPIO[15:14]
I
Not implemented.
GPIO[13:12]
I
Fixed as Input only. Resume Power Well. Not muxed.
GPIO[20:18]
(ICH2 only)
GPIO[11]
I
Fixed as Input only. Resume Power Well. Can instead be used for SMBALERT#.
GPIO[10:9]
I
Not implemented.
GPIO[8]
I
Fixed as Input only. Resume Power Well. Not muxed.
GPIO[7]
I
Fixed as Input only. Main power well. Not muxed.
I
Fixed as Input only. Main power well.
GPIO[6]
(ICH2 only)
2-12
OD
Description
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Signal Description
Table 2-18. General Purpose I/O Signals (Continued)
Name
Type
GPIO[5]
GPIO[4:3]
Not implemented.
I
GPIO[2]
GPIO[1:0]
2.19
Description
Fixed as Input only. Main power well. Can be used instead as PIRQ[G:F]#.
Not implemented.
I
Fixed as Input only. Main Power Well. Can instead be used for PC/PCI
REQ[A:B]#. GPIO[1] can also alternatively be used for PCI REQ[5]#.
Power and Ground
Table 2-19. Power and Ground Signals
Name
Description
Vcc3_3
3.3V supply for Core well I/O buffers. This power may be shut off in S3, S5 or G3 states.
Vcc1_8
1.8V supply for Core well logic. This power may be shut off in S3, S5 or G3 states.
V5REF
Reference for 5V tolerance on Core well inputs. This power may be shut off in S3, S5 or
G3 states.
HUBREF
0.9V reference for the hub interface. This power may be shut off in S3, S5 or G3 states.
3.3V supply for Resume well I/O buffers. This power is not expected to be shut off unless
power is removed.
VccSus3_3
• 82801BA ICH2: The system is unplugged.
• 82801BAM ICH2-M: The main battery is removed or completely drained and AC
power is not available.
1.8V supply for Resume well logic. This power is not expected to be shut off unless power
is removed.
VccSus1_8
• 82801BA ICH2: The system is unplugged.
• 82801BAM ICH2-M: The main battery is removed or completely drained and AC
power is not available.
Reference for 5V tolerance on Resume well inputs. This power is not expected to be shut
off unless power is removed.
V5REF_SUS
• 82801BA ICH2: The system is unplugged. Note that V5REF_SUS only affects 5V
tolerance for the USB OC[3:0]# pins and can be connected to VccSUS3_3 if 5V
tolerance on these signals is not required.
• 82801BAM ICH2-M: The main battery is removed or completely drained and AC
power is not available.
3.3V (can drop to 2.0V min. in G3 state) supply for the RTC well. This power is not
expected to be shut off unless the RTC battery is removed or completely drained.
VccRTC
Note: Implementations should not attempt to clear CMOS by using a jumper to pull
VccRTC low. Clearing CMOS in an ICH2-based platform can be done by using a jumper
on RTCRST# or GPI, or using SAFEMODE strap.
VccLAN3_3
(ICH2-M only)
3.3V supply for LAN Connect interface buffers. This is a separate power plane that may or
may not be energized in S3–S5 states depending upon the presence or absence of AC
power and network connectivity. This plane must be on in S0 and S1.
VccLAN1_8
(ICH2-M only)
1.8V supply for LAN controller logic. This is a separate power plane that may or may not
be energized in S3–S5 states depending upon the presence or absence of AC power and
network connectivity. This plane must be on in S0 and S1.
VBIAS
RTC well bias voltage. The DC reference voltage applied to this pin sets a current that is
mirrored throughout the oscillator and buffer circuitry. See Section 2.20.3.
V_CPU_IO
Powered by the same supply as the processor I/O voltage. This supply is used to drive the
processor interface outputs.
Vss
Grounds.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
2-13
Signal Description
2.20
Pin Straps
2.20.1
Functional Straps
The following signals are used for static configuration. They are sampled at the rising edge of
PWROK to select configurations and then revert later to their normal usage. To invoke the
associated mode, the signal should be driven at least 4 PCI clocks prior to the time it is sampled.
Table 2-20. Functional Strap Definitions
Signal
AC_SDOUT
SAFE
MODE
When
Sampled
Rising
Edge of
PWROK
Comment
The signal has a weak internal pull-down. If the signal is sampled
high, the ICH2 sets the processor speed strap pins for safe mode.
Refer to processor specification for speed strapping definition. The
status of this strap is readable via the SAFE_MODE bit (bit 2, D31:
F0, Offset D4h).
EE_DOUT
Reserved
System designers should include a placeholder for a pull-down
resistor on EE_DOUT but do not populate the resistor.
FS[0]
Reserved
System designers should include a placeholder for a pull-down
resistor on FS[0] but do not populate the resistor.
Rising
Edge of
PWROK
GNT[A]#
Top-Swap
Override
HLCOMP
Enhanced
Hub
Interface
Mode
During
PCIRST#
assertion
No
Reboot
Rising
Edge of
PWROK
SPKR
2-14
Usage
The signal has a weak internal pull-up. If the signal is sampled low,
the system is strapped to the “Top-Swap” mode (ICH2 will invert A16
for all cycles targeting FWH BIOS space). The status of this strap is
readable via the Top-Swap bit (bit 13, D31: F0, Offset D4h). Note that
software will not be able to clear the Top-Swap bit until the system is
rebooted without GNT[A]# being pulled down.
If this signal is sampled high (via an external pull-up to VCC1_8), the
normal hub interface buffer mode will be selected. If this signal is
sampled low (via an external pull-down), the enhanced hub interface
buffer mode will be selected.
See the specific platform design guide for resistor values and routing
guidelines for each hub interface mode.
The signal has a weak internal pull-up. If the signal is sampled low,
the system is strapped to the “No Reboot” mode (ICH2 will disable
the TCO Timer system reboot feature). The status of this strap is
readable via the NO_REBOOT bit (bit 1, D31: F0, Offset D4h).
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Signal Description
2.20.2
Test Signals
2.20.2.1
Test Mode Selection
When PWROK is active (high), driving RTCRST# low for a number of PCI clocks (33 MHz) will
activate a particular test mode as specified in Table 2-21.
Note:
RTCRST# may be driven low any time after PCIRST is inactive. Refer to Chapter 17, “Testability”
for a detailed description of the ICH2 test modes.
Table 2-21. Test Mode Selection
2.20.2.2
Number of PCI Clocks RTCRST#
driven low after PWROK active
Test Mode
<4
No Test Mode Selected
4
XOR Chain 1
5
XOR Chain 2
6
XOR Chain 3
7
XOR Chain 4
8
All “Z”
9–24
Reserved. DO NOT ATTEMPT
>24
No Test Mode Selected
Test Straps (82801BA ICH2 only)
The ICH2’s TP[0] (Test Point) signal must be pulled to VccSus3_3 with an external pull-up
resistor.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
2-15
Signal Description
2.20.3
External RTC Circuitry
To reduce RTC well power consumption, the ICH2 implements an internal oscillator circuit that is
sensitive to step voltage changes in VccRTC and VBIAS. Figure 2-1 shows a schematic diagram of
the circuitry required to condition these voltages to ensure correct operation of the ICH2 RTC.
Figure 2-1. Required External RTC Circuit
3.3V
VCCSUS
VCCRTC
1 µF
1 kΩ
RTCX2
Vbatt
1 kΩ
32768 Hz
Xtal
R1
10 MΩ
RTCX1
C1
0.047 uF
C3
12.5 pF
R2
10 MΩ
VBIAS
C2
12.5 pF
VSSRTC
Note: Capacitor C2 and C3 values are crystal-dependent.
2.20.4
V5REF / Vcc3_3 Sequencing Requirements
V5REF and V5REF_Sus are the reference voltages for 5V tolerance on inputs to the ICH2. V5REF
and V5REF_Sus must power up before or simultaneous to Vcc3_3 and VccSus3_3 respectively,
and must power down after or simultaneous to Vcc3_3 and VccSus3_3 respectively. Refer to
Figure 2-2 for an example circuit schematic that may be used to ensure proper V5REF sequencing.
Note that separate circuits must be implemented for both the Core and Suspend well supplies.
Figure 2-2. Example V5REF Sequencing Circuit
VCC Supply
(3.3V)
5V Supply
1k
Schottky
Diode
To System
2-16
1 uF
5VREF
To System
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Power Planes and Pin States
3
Power Planes and Pin States
3.1
Power Planes
Table 3-1. ICH2 Power Planes
Plane
3.2
Description
Main I/O
(3.3V)
Vcc3_3: Powered by the main power supply (or battery for the ICH2-M). When the
system is in the S3, S4, S5, or G3 state, this plane is assumed to be shut off.
Main Logic
(1.8V)
Vcc1_8: Powered by the main power supply (or battery for the ICH2-M). When the
system is in the S3, S4, S5, or G3 state, this plane is assumed to be shut off.
Resume I/O
(3.3V Standby)
VccSUS3_3: Powered by the main power supply (or battery for the ICH2-M) in S0–S1
states. Powered by the trickle power supply (or battery for the ICH2-M) when the
system is in the S3, S4, S5, state. Assumed to be shut off only when in the G3 state
(system is unplugged for the ICH2 or battery removed for the ICH2-M).
Resume Logic
(1.8V Standby)
VccSUS1_8: Powered by the main power supply (or battery for the ICH2-M) in S0–S1
states. Powered by the trickle power supply (or battery for the ICH2-M) when the
system is in the S3, S4, S5, state. Assumed to be shut off only when in the G3 state
(system is unplugged for the ICH2 or batter removed for the ICH2-M).
Processor Interface
(1.3 ~ 2.5V)
V_CPU_IO: Powered by the main power supply via processor voltage regulator. When
the system is in the S3, S4, S5, or G3 state, this plane is assumed to be shut off.
LAN I/O
(3.3V)
(ICH2-M only)
VccLAN3_3: This is a separate power plane that may or may not be energized in S3 S5 states depending upon the presence or absence of AC power and network
connectivity. This plane must be on in the S0 and S1 states.
LAN Logic
(1.8V)
(ICH2-M only)
VccLAN1_8: This is a separate power plane that may or may not be energized in S3 S5 states depending upon the presence or absence of AC power and network
connectivity. This plane must be on in the S0 and S1 states.
RTC
VccRTC: When other power is available (from the main supply for the ICH2 or battery
for the ICH2-M), external diode coupling will provide power to reduce the drain on the
RTC battery. Assumed to operate from 3.3V down to 2.0V.
Integrated Pull-Ups and Pull-Downs
Table 3-2. Integrated Pull-Up and Pull-Down Resistors
Signal
Resistor Type
Nominal Value
Notes
EE_DIN
pull-up
24 KΩ
1
EE_DOUT
pull-up
24 KΩ
1
GNT[B:A]# / GNT[5]# / GPIO[17:16]
pull-up
24 KΩ
1
LAD[3:0]# / FWH[3:0]#
pull-up
24 KΩ
1
LDRQ[1:0]
pull-up
24 KΩ
1
PME#
pull-up
24 KΩ
1
PWRBTN#
pull-up
24 KΩ
1
SPKR
pull-up
24 KΩ
1, 5
pull-down
20 KΩ
2, 6
AC_BITCLK
82801BA ICH2 and 82801BAM ICH2-M Datasheet
3-1
Power Planes and Pin States
Table 3-2. Integrated Pull-Up and Pull-Down Resistors (Continued)
Signal
Resistor Type
Nominal Value
Notes
AC_SDIN[0]
pull-down
20 KΩ
2, 6
AC_SDIN[1]
pull-down
20 KΩ
2, 6
AC_SDOUT
pull-down
20 KΩ
2, 6
AC_SYNC
pull-down
20 KΩ
2, 6
LAN_RXD[2:0]
pull-up
9 KΩ
3
PDD[7] / SDD[7]
pull-down
5.9 KΩ
4
PDDREQ / SDDREQ
pull-down
5.9 KΩ
4
NOTES:
1. Simulation data shows that these resistor values can range from 18 KΩ to 42 KΩ.
2. Simulation data shows that these resistor values can range from 13 KΩ to 38 KΩ.
3. Simulation data shows that these resistor values can range from 6 KΩ to 14 KΩ.
4. Simulation data shows that these resistor values can range from 4.3 KΩ to 20 KΩ.
5. The pull-up or pull-down on this signal is only enabled at boot/reset for strapping function.
6. This pull-down is only enabled when the ACLINK Shut Off bit in the AC’97 Global Control Register is set to 1.
3.3
IDE Integrated Series Termination Resistors
Table 3-3 shows the ICH2 IDE signals that have integrated series termination resistors.
Table 3-3. IDE Series Termination Resistors
Signal
PDD[15:0], SDD[15:0], PDIOW#, SDIOW#,
PDIOR#, PDIOW#, PDREQ, SDREQ,
PDDACK#, SDDACK#, PIORDY, SIORDY,
PDA[2:0], SDA[2:0], PDCS1#, SDCS1#,
PDCS3#, SDCS3#, IRQ14, IRQ15
Integrated Series Termination Resistor Value
approximately 33 Ω (See Note)
NOTE: Simulation data indicates that the integrated series termination resistors are a nominal 33 Ω but can
range from 31 Ω to 43 Ω.
3.4
Output and I/O Signals Planes and States
Table 3-4 shows the power plane associated with the output and I/O signals, as well as the state at
various times. Within the table, the following terms are used:
“High-Z”
Tri-state. ICH2 not driving the signal high or low.
“High”
ICH2 is driving the signal to a logic ‘1’
“Low”
ICH2 is driving the signal to a logic ‘0’
“Defined”
Driven to a level that is defined by the function (will be high or low)
“Undefined”
ICH2 is driving the signal, but the value is indeterminate.
“Running”
Clock is toggling or signal is transitioning because function not stopping
“Off”
The power plane is off, so ICH2 is not driving
Note that the signal levels are the same in S4 and S5.
3-2
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Power Planes and Pin States
Table 3-4.
Power Plane and States for Output and I/O Signals
Signal Name
Power
Plane
Reset Signal
During Reset
Immediately
after Reset
C3
(ICH2-M)
S1
S3
S4/S5
PCI Bus
AD[31:0]
Main I/O
PCIRST#
High-Z
Undefined
Defined
Defined
Off
Off
Defined
Off
Off
Off
Off
C/BE#[3:0]
Main I/O
PCIRST#
High-Z
Undefined
Defined
CLKRUN# (ICH2-M)
Main I/O
PCIRST#
Low
Low
Defined
DEVSEL#
Main I/O
PCIRST#
High-Z
High-Z
High-Z
High-Z
Off
Off
FRAME#
Main I/O
PCIRST#
High-Z
High-Z
High-Z
High-Z
Off
Off
GNT[0:5]#
Main I/O
PCIRST#
High
High
High
High
Off
Off
GNT[A:B]#
Main I/O
PCIRST#
High-Z
High
High
High
Off
Off
IRDY#, TRDY#
Main I/O
PCIRST#
High-Z
High-Z
High-Z
High-Z
Off
Off
PAR
Main I/O
PCIRST#
High-Z
Undefined
Defined
Defined
Off
Off
PCIRST#
Resume I/O
RSMRST#
Low
High
High
High
Low
Low
PERR#
Main I/O
PCIRST#
High-Z
High-Z
High-Z
High-Z
Off
Off
PLOCK#
Main I/O
PCIRST#
High-Z
High-Z
High-Z
High-Z
Off
Off
STOP#
Main I/O
PCIRST#
High-Z
High-Z
High-Z
High-Z
Off
Off
LPC Interface
LAD[3:0]
Main I/O
PCIRST#
High
High
High
Defined
Off
Off
LFRAME#
Main I/O
PCIRST#
High
High
High
High
Off
Off
LAN Connect and EEPROM Interface
EE_CS
LAN I/O
RSM_PWROK
(ICH2)
LAN_PWROK
(ICH2-M)
Low
Running
Defined
Defined
Note 4
Note 4
EE_DOUT
LAN I/O
RSM_PWROK
(ICH2)
LAN_PWROK
(ICH2-M)
High
Running
Defined
Defined
Note 4
Note 4
EE_SHCLK
LAN I/O
RSM_PWROK
(ICH2)
LAN_PWROK
(ICH2-M)
Low
Running
Defined
Defined
Note 4
Note 4
LAN_RSTSYNC
LAN I/O
RSM_PWROK
(ICH2)
LAN_PWROK
(ICH2-M)
High
Defined
Defined
Defined
Note 4
Note 4
LAN_TXD[2:0]
LAN I/O
RSM_PWROK
(ICH2)
LAN_PWROK
(ICH2-M)
Low
Defined
Defined
Defined
Note 4
Note 4
82801BA ICH2 and 82801BAM ICH2-M Datasheet
3-3
Power Planes and Pin States
Table 3-4.
Power Plane and States for Output and I/O Signals (Continued)
Signal Name
Power
Plane
Reset Signal
During Reset
Immediately
after Reset
C3
(ICH2-M)
S1
S3
S4/S5
Undefined
Driven
Off
Off
IDE Interface
PDA[2:0], SDA[2:0]
Main I/O
PCIRST#
Low
Undefined
PDCS1#, PDCS3#
Main I/O
PCIRST#
High
High
High
High
Off
Off
PDD[15:0], SDD[15:0]
Main I/O
PCIRST#
High-Z
High-Z
Defined
High-Z
Off
Off
PDDACK#, SDDACK#
Main I/O
PCIRST#
High
High
High
Off
Off
Off
PDIOR#, PDIOW#
Main I/O
PCIRST#
High
High
High
Off
Off
Off
SDCS1#, SDCS3#
Main I/O
PCIRST#
High
High
High
Off
Off
Off
SDIOR#, SDIOW#
Main I/O
PCIRST#
High
High
High
Off
Off
Off
Interrupts
PIRQ[A:H]#
Main I/O
PCIRST#
High-Z
High-Z
Defined
High-Z
Off
Off
SERIRQ
Main I/O
PCIRST#
High-Z
High-Z
Running
High-Z
Off
Off
APICD[1:0]
Main I/O
PCIRST#
High-Z
High-Z
Running
High-Z
Off
Off
High-Z
High-Z
High-Z
High-Z
USB Interface
USBP[3:0][P:N]
Resume I/O
RSMRST#
High-Z
High-Z
Power Management
CPUPERF# (ICH2-M)
Main I/O
PCIRST#
High-Z
High-Z
Defined
Defined
Off
Off
C3_STAT# / GPIO[21]
(ICH2-M)
Main I/O
PCIRST#
High
High
Low
Low
Off
Off
SSMUXSEL (ICH2-M)
Main I/O
PCIRST#
Low
Low
Defined
Defined
Off
Off
SLP_S1# (ICH2-M)
Main I/O
PCIRST#
High
High
High
Low
Low
Low
SLP_S3#
Resume I/O
RSMRST#
High
High
High
High
Low
Low
SLP_S5#
Resume I/O
RSMRST#
High
High
High
High
High
Low
STP_PCI# (ICH2-M)
Main I/O
PCIRST#
High
High
Defined
Low
Low
Low
Low
Low
Low
Low
Low
Low
Low
STP_CPU# (ICH2-M)
Main I/O
PCIRST#
High
High
SUS_STAT#
Resume I/O
RSMRST#
High
High
SUSCLK
Resume I/O
RSMRST#
Running
Processor Interface
3-4
A20M#
CPU I/O
PCIRST#
See Note 1
High
Defined
High
Off
Off
CPUPWRGD
Main I/O
PCIRST#
See Note 3
High-Z
High-Z
High-Z
Off
Off
CPUSLP#
CPU I/O
PCIRST#
High
High
High
Defined
(ICH2)
Low (ICH2-M)
Off
Off
IGNNE#
CPU I/O
PCIRST#
See Note 1
High
High
High
Off
Off
INIT#
CPU I/O
PCIRST#
High
High
High
High
Off
Off
INTR
CPU I/O
PCIRST#
See Note 1
Low
Defined
Low
Off
Off
NMI
CPU I/O
PCIRST#
See Note 1
Low
Defined
Low
Off
Off
SMI#
CPU I/O
PCIRST#
High
High
Defined
High
Off
Off
STPCLK#
CPU I/O
PCIRST#
High
High
Low
Low
Off
Off
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Power Planes and Pin States
Table 3-4.
Power Plane and States for Output and I/O Signals (Continued)
Power
Plane
Signal Name
Reset Signal
During Reset
C3
(ICH2-M)
S1
S3
S4/S5
Defined
Defined
Defined
Defined
Defined
Defined
Defined
Defined
Low
Defined
Defined
Off
Off
Immediately
after Reset
SMBus Interface
SMBCLK, SMBDATA
Resume I/O
RSMRST#
High-Z
High-Z
System Management Interface
SMLINK[1:0]
Resume I/O
RSMRST#
High-Z
High-Z
Miscellaneous Signals
SPKR
Main I/O
PCIRST#
High-Z with
internal pull-up
AC’97 Interface
AC_RST#
Resume I/O
RSMRST#
Low
Low
High
Cold Reset Bit
(High)
Low
Low
AC_SDOUT
Main I/O
PCIRST#
Low
Running
Running
Low
Off
Off
AC_SYNC
Main I/O
PCIRST#
Low
Running
Running
Low
Off
Off
Unmuxed GPIO Signals
GPIO[18] (ICH2)
Main I/O
PCIRST#
High
See Note 2
—
Defined
Off
Off
GPIO[19:20] (ICH2)
Main I/O
PCIRST#
High
High
—
Defined
Off
Off
GPIO[21] (ICH2)
Main I/O
PCIRST#
High
High
—
Defined
Off
Off
GPIO[22] (ICH2)
Main I/O
PCIRST#
High-Z
High-Z
—
Defined
Off
Off
GPIO[23] (ICH2)
Main I/O
PCIRST#
Low
Low
—
Defined
Off
Off
GPIO[24] (ICH2)
Resume I/O
RSMRST#
High-Z
High
—
Defined
Defined
Defined
GPIO[25]
Resume I/O
RSMRST#
High-Z
High
Defined
Defined
Defined
Defined
GPIO[27:28]
Resume I/O
RSMRST#
HIgh-Z
High
Defined
Defined
Defined
Defined
.
NOTES:
1. ICH2 and ICH2-M: The ICH2/ICH2-M sets these signals at reset for processor frequency strap.
2. ICH2 and ICH2-M: GPIO[18] will toggle at a frequency of approximately 1 Hz when the ICH2 comes out of reset
3. ICH2 and ICH2-M: CPUPWRGD is an open-drain output that represents a logical AND of the ICH2’s VRMPWRGD
(VGATE / VRMPWRGD for the ICH2-M) and PWROK signals and, thus, are driven low by ICH2/ICH2-M when either
VRMPWRGD (VGATE / VRMPWRGD for the ICH2-M) or PWROK are inactive. During boot, or during a hard reset with power
cycling, CPUPWRGD will be expected to transition from low to High-Z.
4. ICH2-M Only: LAN Connect and EEPROM signals will either be "Defined" or "Off" in S3–S5 states depending on whether or
not the LAN power planes are active.
5. GPIO[24:25, 27:28] for the ICH2 and GPIO[25, 27:28] for the 82801BAM ICH2-M: These signals remain tri-stated for up to
110 ms after RSMRST# deassertion. At this point, they will be driven to their default (High) state.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
3-5
Power Planes and Pin States
3.5
Power Planes for Input Signals
Table 3-5 shows the power plane associated with each input signal, as well as what device drives
the signal at various times. Valid states include:
•
•
•
•
•
High
Low
Static: Will be high or low, but will not change
Driven: Will be high or low, and is allowed to change
Running: For input clocks
Table 3-5. Power Plane for Input Signals
Signal Name
Power Well
Driver During Reset
C3
(ICH2-M)
S1
S3
S5
BATLOW#
(ICH2-M)
Resume I/O
Power Supply
High
High
High
High
A20GATE
Main I/O
External Microcontroller
Static
Static
Low
Low
AC_BIT_CLK
Main I/O
AC’97 Codec
Driven
Low
Low
Low
AC_SDIN[1:0]
Resume I/O
AC’97 Codec
Driven
Low
Low
Low
AGPBUSY#
(ICH2-M)
Main I/O
AGP Component
Driven
High
Low
Low
APICCLK
Main I/O
Clock Generator
Running
Low
Low
Low
CLK14
Main I/O
Clock Generator
Running
Low
Low
Low
CLK48
Main I/O
Clock Generator
Running
Low
Low
Low
CLK66
Main Logic
Clock Generator
Running
Low
Low
Low
EE_DIN
LAN I/O
EEPROM component
Driven
Driven
Note 1
Note 1
FERR#
Main I/O
CPU
Static
Static
Low
Low
INTRUDER#
RTC
External Switch
Driven
Driven
Driven
Driven
IRQ[15:14]
Main I/O
IDE
Driven
Static
Low
Low
LAN_CLK
LAN I/O
LAN Connect component
Driven
Driven
Note 1
Note 1
High
High
Static
Static
RSM_PWROK
(ICH2)
LAN_PWROK
(ICH2-M)
3-6
Resume I/O
External RC Circuit (ICH2)
Power Supply (ICH2-M)
LAN_RXD[2:0]
LAN I/O
LAN Connect component
Driven
Driven
Note 1
Note 1
LDRQ[0]#
Main I/O
LPC Devices
Driven
High
Low
Low
LDRQ[1]#
Main I/O
LPC Devices
Driven
High
Low
Low
OC[3:0]#
Resume I/O
External Pull-Ups
Driven
Driven
Driven
Driven
PCICLK
Main I/O
Clock Generator
Running
Low
Low
Low
PDDREQ
Main I/O
IDE Device
Driven
Static
Low
Low
PIORDY
Main I/O
IDE Device
Static
Static
Low
Low
PME#
Resume I/O
Internal Pull-Up
Driven
Driven
Driven
Driven
PWRBTN#
Resume I/O
Internal Pull-Up
Driven
Driven
Driven
Driven
PWROK
Main I/O
System Power Supply
Driven
Driven
Low
Low
RCIN#
Main I/O
External Microcontroller
High
High
Low
Low
REQ[0:5]#
Main I/O
PCI Master
Driven
Driven
Low
Low
REQ[B:A]#
Main I/O
PC/PCI Devices
Driven
Driven
Low
Low
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Power Planes and Pin States
Table 3-5. Power Plane for Input Signals (Continued)
Signal Name
Power Well
Driver During Reset
C3
(ICH2-M)
S1
S3
S5
RI#
Resume I/O
Serial Port Buffer
Driven
Driven
Driven
Driven
RSMRST#
RTC
External RC circuit
High
High
High
High
RTCRST#
RTC
External RC circuit
High
High
High
High
SDDREQ
Main I/O
IDE Drive
Driven
Static
Low
Low
SERR#
Main I/O
PCI Bus Peripherals
Driven
High
Low
Low
SIORDY
Main I/O
IDE Drive
Driven
Static
Low
Low
SMBALERT#
Resume I/O
External pull-up
Driven
Driven
Driven
Driven
THRM#
Main I/O
Thermal Sensor
Driven
Driven
Low
Low
VRMPWRGD
(ICH2)
Main I/O
CPU Voltage Regulator
Driven
High
Low
Low
VGATE /
VRMPWRGD
(ICH2-M)
Main I/O
CPU Voltage Regulator
Driven
High
Low
Low
.
NOTES:
1. LAN Connect and EEPROM signals will either be "Driven" or "Low" in S3–S5 states depending upon
whether or not the LAN power planes are active.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
3-7
Power Planes and Pin States
This page is intentionally left blank
3-8
82801BA ICH2 and 82801BAM ICH2-M Datasheet
System Clock Domains
4
System Clock Domains
Table 4-1 shows the system clock domains. Figure 4-2 shows the assumed connection of the
various system components, including the clock generator. For complete details of the system
clocking solution, refer to the system’s clock generator component specification.
Figure 4-1. ICH2 and System Clock Domains
Clock
Domain
Frequency
Source
ICH2
CLK66
66 MHz
Main Clock
Generator
Usage
Hub interface, processor interface. AGP.
82801BA ICH2: It is shut off during S3 or below.
82801BAM ICH2-M: It is shut off during S1 or below.
Free-running PCI Clock to ICH2/ICH2-M.
ICH2
PCICLK
33 MHz
Main Clock
Generator
82801BA ICH2: This clock remains on during S0 and S1
state, and is expected to be shut off during S3 or below.
82801BAM ICH2-M: This clock remains on during S0
state, and is expected to be shut off during S1 or below.
System PCI
33 MHz
Main Clock
Generator
PCI Bus, LPC I/F. These only go to external PCI and
LPC devices.
82801BAM ICH2-M: These will stop based on CLKRUN#
(and STP_PCI#)
Super I/O, USB Controller.
ICH2
CLK48
48 MHz
Main Clock
Generator
82801BA ICH2: Expected to be shut off during S3 or
below.
82801BAM ICH2-M: Expected to be shut off during S1
or below.
Used for ACPI timer.
ICH2
CLK14
14.31818 MHz
Main Clock
Generator
82801BA ICH2: Expected to be shut off during S3 or
below.
82801BAM ICH2-M: Expected to be shut off during S1 or
below.
AC’97 Link. Generated by AC’97 CODEC. Can be shut
off by codec in D3.
ICH2
AC_BIT_CLK
12.288 MHz
AC’97 Codec
82801BA ICH2: Expected to be shut off during S3 or
below.
82801BAM ICH2-M: Expected to be shut off during S1 or
below.
RTC
32.768 kHz
ICH2
RTC, Power Management. ICH2 has its own oscillator.
Always running, even in G3 state.
Used for ICH2/ICH2-M processor interrupt messages.
Runs at 33.33 MHz.
ICH2
APICCLK
33.33 MHz
Main Clock
Generator
82801BA ICH2: Expected to be shut off during S3 or
below.
82801BAM ICH2-M: Expected to be shut off during S1 or
below.
Generated by the LAN Connect component.
LAN_CLK
0.8 to 50 MHz
LAN Connect
Component
82801BA ICH2: Expected to be shut off during S3 or
below.
82801BAM ICH2-M: Expected to be shut off during S1 or
below.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
4-1
System Clock Domains
Figure 4-2. Conceptual System Clock Diagram (82801BA ICH2 and 82801BAM ICH2-M)
Hclock(s) (66/100/133 MHz)
Processor(s)
HClock (66/100/133 MHz)
AGP Clock (66 M Hz)
AGP
Host
Controller
AGP Clock (66 M Hz)
RDRAM
Clock
G enerator
Mem ory
66 MHz
2
33 MHz
2 or 3
APIC CLK
Clock
G enerator
14.31818 M Hz
ICH2
48 MHz
PCI Clocks
(33 MHz)
STP_CPU# (ICH2-M only)
14.31818 M Hz
STP_PCI# (ICH2-M only)
48 MHz
SLP_S1# (ICH2-M only)
12.288 MHz
50 MHz
32 kHz
XTAL
4-2
AC'97 Codec(s)
LAN Connect
SUSCLK# (32 kHz)
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
Functional Description
5.1
5
Hub Interface to PCI Bridge (D30:F0)
The hub interface to PCI Bridge resides in PCI Device 30, Function 0 on bus #0. This portion of the
ICH2 implements the buffering and control logic between PCI and the hub interface. The
arbitration for the PCI bus is handled by this PCI device. The PCI decoder in this device must
decode the ranges for the hub interface. All register contents will be lost when core well power is
removed.
5.1.1
PCI Bus Interface
The ICH2 PCI interface provides a 33 MHz, Rev. 2.2 compliant implementation. All PCI signals
are 5V tolerant. The ICH2 integrates a PCI arbiter that supports up to six external PCI bus masters
in addition to the internal ICH2 requests.
Note that most transactions targeted to the ICH2 will first appear on the external PCI bus before
being claimed back by the ICH2. The exceptions are I/O cycles involving USB, IDE, and AC’97.
These transactions will complete over the hub interface without appearing on the external PCI bus.
Configuration cycles targeting USB, IDE or AC’97 will appear on the PCI bus. If the ICH2 is
programmed for positive decode, the ICH2 will claim the cycles appearing on the external PCI bus
in medium decode time. If the ICH2 is programmed for subtractive decode, the ICH2 will claim
these cycles in subtractive time. If the ICH2 is programmed for subtractive decode, these cycles
can be claimed by another positive decode agent out on PCI. This architecture enables the ability to
boot off of a PCI card that positively decodes the boot cycles. To boot off a PCI card it is necessary
to keep the ICH2 in subtractive decode mode. When booting off a PCI card, the BOOT_STS bit
(bit 2, TCO2 Status Register) will be set.
For the 82801BAM ICH2-M, devices on the ICH2-M PCI bus (other than the ICH2-M) are not
permitted to assert the PLOCK# signal.
Note:
The ICH2’s AC’97, IDE, and USB Controllers can not access PCI address ranges.
Note:
PCI devices that cause long latencies (numerous retries) to processor-to-PCI Locked cycles may
starve isochronous transfers between USB or AC’97 devices and memory. This will result in
overrun or underrun, causing reduced quality of the isochronous data (e.g., audio).
Note:
PCI configuration write cycles, initiated by the processor, with the following characteristics will be
converted to a Special Cycle with the Shutdown message type.
•
•
•
•
•
Device Number (AD[15:11]) = ‘11111’
Function Number (AD[10:8]) = ‘111’
Register Number (AD[7:2]) = ‘000000’
Data = 00h
Bus number matches secondary bus number
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-1
Functional Description
5.1.2
Note:
If the processor issues a locked cycle to a resource that is too slow (e.g., PCI), the ICH2 will not
allow upstream requests to be performed until the cycle completion. This may be critical for
isochronous buses that assume certain timing for their data flow (e.g., AC’97 or USB). Devices on
these buses may suffer from underrun if the asynchronous traffic is too heavy. Underrun means that
the same data is sent over the bus while ICH2 is not able to issue a request for the next data. Snoop
cycles are not permitted while the front side bus is locked.
Note:
Locked cycles are assumed to be rare. Locks by PCI targets are assumed to exist for a short
duration (a few microseconds at most). If a system has a very large number of locked cycles and
some that are very long, the system will definitely experience underruns and overruns. The units
most likely to have problems are the AC'97 controller and the USB controller. Other units could get
underruns/overruns, but are much less likely. The IDE controller (due to its stalling capability on
the cable) should not get any underruns or overruns.
Note:
The ICH2 was designed to provide high performance support to PCI peripherals using its data
prefetch capabilities. If a PCI master is burst reading and is disconnected by the ICH2 to pre-fetch
the requested cache line, the ICH2 will Delay Transaction the cycle while it prefetches more data,
and give the bus to another agent. Once the bus is given back to this bus master, if it does not return
with the successive previously requested read address, which was prefetched by the ICH2, the
ICH2 will keep retrying the bus master until either it comes back for the prefetched data, or the
Delayed Transaction Discard Timer expires (1024 PCI clocks) before discarding this prefetched
data and servicing the request. This induces long latencies to PCI bus masters that behave this way.
To reduce this latency, the Discard Timer Mode bit (D30:F0;CNF(50-51h):[bit-2]) can be set to 1.
This will reduce the discard timer from 1024 PCI clocks (32 us) to 128 clocks (4 us) and improve
latency for masters with this behavior.
PCI-to-PCI Bridge Model
From a software perspective, the ICH2 contains a PCI-to-PCI bridge. This bridge connects the hub
interface to the PCI bus. By using the PCI-to-PCI bridge software model, the ICH2 can have its
decode ranges programmed by existing plug-and-play software such that PCI ranges do not
conflict with AGP and graphics aperture ranges in the Host controller.
5.1.3
IDSEL to Device Number Mapping
When addressing devices on the external PCI bus (with the PCI slots), the ICH2 asserts one address
signal as an IDSEL. When accessing device 0, the ICH2 asserts AD16. When accessing Device 1,
the ICH2 asserts AD17. This mapping continues up to device 15 where the ICH2 asserts AD31.
Note that the ICH2’s internal functions (AC’97, IDE, USB, and PCI Bridge) are enumerated like
they are on a separate PCI bus (the hub interface) from the external PCI bus. The integrated LAN
Controller is Device 8 on the ICH2’s PCI bus and, hence, uses AD24 for IDSEL
5.1.4
SERR# Functionality
There are several internal and external sources that can cause SERR#. The ICH2 can be
programmed to cause an NMI based on detecting that an SERR# condition has occurred. The NMI
can also be routed to, instead, cause an SMI#. Note that the ICH2 does not drive the external PCI
bus SERR# signal active onto the PCI bus. The external SERR# signal is an input into the ICH2
driven only by external PCI devices. The conceptual logic diagrams in Figure 5-1 and Figure 5-2
illustrate all sources of SERR#, along with their respective enable and status bits. Figure 5-3 shows
how the ICH2 error reporting logic is configured for NMI# generation.
5-2
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
Figure 5-1. Primary Device Status Register Error Reporting Logic
D30:F0 BRIDGE_CNT
[Parity Error Response Enable]
D30:F0 BRIDGE_CNT
[SERR# Enable]
AND
AND
PCI Address Parity Error
D30:F0 PD_STS
[SSE]
D30:F0 CMD
[SERR_EN]
OR
D30:F0 ERR_STS
[SERR_DTT]
D30:F0 CMD
[SERR_EN]
Delayed Transaction Timeout
D30:F0 ERR_CMD
[SERR_DTT_EN]
AND
AND
SERR# Pin
D30:F0 BRIDGE_CNT
[SERR# Enable]
D30:F0 ERR_CMD
[SERR_RTA_EN]
AND
OR
AND
Received Target Abort
D30:F0 ERR_STS
[SERR_RTA]
Figure 5-2. Secondary Status Register Error Reporting Logic
D30:F0 BRIDGE_CNT
[SERR# Enable]
AND
D30:F0 SECSTS
[SSE]
PCI Delayed Transaction Timeout
D31:F0 D31_ERR_CFG
[SERR_DTT_EN]
AND
LPC Device Signaling an Error
IOCHK# via SERIRQ
OR
TCO1_STS
[HUBERR_STS]
D31:F0 D31_ERR_CFG
[SERR_RTA_EN]
AND
Received Target Abort
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-3
Functional Description
Figure 5-3. NMI# Generation Logic
NMI_SC
[IOCHK_NMI_STS]
IOCHK From SERIRQ Logic
AND
NMI_SC
[IOCHK_NMI_EN]
NMI_SC
[SERR#_NMI_STS]
NMI_SC
[PCI_SERR_EN]
AND
D30:F0 SECSTS
[SSE]
D30:F0 PDSTS
[SSE]
OR
TCO1_STS
[HUBNMI_STS]
TCO1_CNT
[NMI_NOW]
OR
AND
OR
Hub Interface Parity
Error Detected
To NMI#
Output
and
Gating
Logic
AND
D30:F0 CMD
[Parity Error Response]
D30:F0 PD_STS
[DPD]
PCI Parity Error detected
during AC'97, IDE or USB
Master Cycle
AND
D30:F0 BRIDGE_CNT
[Parity Error Response
Enable]
OR
D30:F0 SECSTS
[DPD]
NMI_EN
[NMI_EN]
PCI Parity Error detected
during LPC or Legacy DMA
Master Cycle
D31:F0 PCICMD
[PER]
5.1.5
AND
D31:F0 PCISTA
[DPED]
Parity Error Detection
The ICH2 can detect and report different parity errors in the system. The ICH2 can be programmed
to cause an NMI (or SMI# if NMI is routed to SMI#) based on detecting a parity error. The
conceptual logic diagram in Figure 5-3 details all the parity errors that the ICH2 can detect, along
with their respective enable bits, status bits, and the results.
Note:
5-4
If NMIs are enabled and parity error checking on PCI is also enabled, then parity errors cause an
NMI. Some operating systems will not attempt to recover from this NMI, since it considers the
detection of a PCI error to be a catastrophic event.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.1.6
Standard PCI Bus Configuration Mechanism
The PCI Bus defines a slot based “configuration space” that allows each device to contain up to 8
functions with each function containing up to 256 8-bit configuration registers. The PCI
specification defines two bus cycles to access the PCI configuration space: Configuration Read and
Configuration Write. Memory and I/O spaces are supported directly by the processor.
Configuration space is supported by a mapping mechanism implemented within the ICH2. The PCI
specification defines two mechanisms to access configuration space (Mechanism #1 and
Mechanism #2). The ICH2 only supports Mechanism #1.
Configuration cycles for PCI Bus #0 devices #2 through #31, and for PCI Bus numbers greater than
0 will be sent towards the ICH2 from the host controller. The ICH2 compares the non-zero Bus
Number with the Secondary Bus Number and Subordinate Bus number registers of its P2P bridge
to determine if the configuration cycle is meant for Primary PCI or a downstream PCI bus.
Type 0 to Type 0 Forwarding
When a Type 0 configuration cycle is received on the hub interface, the ICH2 forwards these cycles
to PCI and then reclaims them. The ICH2 uses address bits AD[15:14] to communicate the ICH2
device numbers in Type 0 configuration cycles. If the Type 0 cycle on the hub interface specifies
any device number other than 30 or 31, the ICH2 will not set any address bits in the range
AD[31:11] during the corresponding transaction on PCI. Table 5-1 shows the device number
translation.
Table 5-1. Type 0 Configuration Cycle Device Number Translation
Device # In Hub Interface Type 0
Cycle
AD[31:11] During Address Phase of Type 0 Cycle on PCI
0 through 29
0000000000000000_00000b
30
0000000000000000_01000b
31
0000000000000000_10000b
The ICH2 logic generates single DWord configuration read and write cycles on the PCI bus. The
ICH2 generates a Type 0 configuration cycle for configurations to the bus number matching the
PCI bus. Type 1 configuration cycles are converted to Type 0 cycles in this case. If the cycle is
targeting a device behind an external bridge, the ICH2 runs a Type 1 cycle on the PCI bus.
Type 1 to Type 0 Conversion
When the bus number for the Type 1 configuration cycle matches the PCI (Secondary) bus number,
the ICH2 converts the address as follows:
• For device numbers 0 through 15, only one bit of the PCI address [31:16] is set. If the device
number is 0, AD[16] is set; if the device number is 1, AD[17] is set; etc.
• The ICH2 always drives 0s on bits AD[15:11] when converting Type 1 configurations cycles
to Type 0 configuration cycles on PCI.
• Address bits [10:1] are also passed unchanged to PCI.
• Address bit [0] is changed to 0.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-5
Functional Description
5.1.7
PCI Dual Address Cycle (DAC) Support
(82801BA ICH2 only)
The 82801BA ICH2 supports Dual Address Cycle (DAC) format on PCI for cycles from PCI
initiators to main memory. This allows PCI masters to generate an address up to 44 bits. The size
of the actual supported memory space will be determined by the memory controller and the
processor.
The DAC mode is only supported for PCI adapters and is not supported for any of the internal PCI
masters (IDE, LAN, USB, AC’97, 8237 DMA, etc.). ICH2 does not support DAC for processorinitiated cycles.
When a PCI master wants to initiate a cycle with an address above 4 GB, it follows the following
behavioral rules (See PCI 2.2 Specification, section 3.9 for more details):
1. On the first clock of the cycle (when FRAME# is first active), the peripheral uses the DAC
encoding on the C/BE# signals. This unique encoding is 1101.
2. Also during the first clock, the peripheral drives the AD[31:0] signals with the low address.
3. On the second clock, the peripheral drives AD[31:0] with the high address. The address is
right justified: A[43:32] appear on AD[12:0]. The value of AD[31:13] is expected to be 0,
however the ICH2 will ignore these bits. C/BE# indicate the bus command type (Memory
Read, Memory Write, etc.)
4. The rest of the cycle proceeds normally.
5.2
LAN Controller (B1:D8:F0)
The ICH2’s integrated LAN Controller includes a 32-bit PCI controller that provides enhanced
scatter-gather bus mastering capabilities and enables the LAN Controller to perform high speed
data transfers over the PCI bus. Its bus master capabilities enable the component to process high
level commands and perform multiple operations, which lowers processor utilization by offloading communication tasks from the processor. Two large transmit and receive FIFOs of 3 KB
each help prevent data underruns and overruns while waiting for bus accesses. This enables the
integrated LAN Controller to transmit data with minimum interframe spacing (IFS).
The ICH2 integrated LAN Controller can operate in either full duplex or half duplex mode. In full
duplex mode the LAN Controller adheres with the IEEE 802.3x Flow Control specification. Half
duplex performance is enhanced by a proprietary collision reduction mechanism.
The integrated LAN Controller also includes an interface to a serial (4-pin) EEPROM. The
EEPROM provides power-on initialization for hardware and software configuration parameters.
From a software perspective, the integrated LAN Controller appears to reside on the secondary side
of the ICH2’s virtual PCI-to-PCI Bridge (see Section 5.1.2). This is typically Bus 1; it may be
assigned a different number depending on system configuration.
5-6
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
Feature Summary
• Compliance with Advanced Configuration and Power Interface and PCI Power Management
•
•
•
•
•
•
•
5.2.1
standards
Support for wake-up on interesting packets and link status change
Support for remote power-up using Wake on LAN* (WOL) technology
Deep power-down mode support
Support of Wired for Management (WfM) Rev 2.0
Backward compatible software with 82557, 82558 and 82559
TCP/UDP checksum offload capabilities
Support for Intel’s Adaptive Technology
LAN Controller Architectural Overview
Figure 5-4 is a high level block diagram of the ICH2 integrated LAN Controller. It is divided into
four main subsystems: a Parallel subsystem, a FIFO subsystem and the Carrier-Sense Multiple
Access with Collision Detect (CSMA/CD) unit.
Figure 5-4. Integrated LAN Controller Block Diagram
EEPROM
Interface
PCI Target and
EEPROM Interface
3 Kbyte
Tx FIFO
Four Channel
Addressing Unit DMA
PCI
Interface
PCI Bus
Interface Unit
(BIU)
Data Interface Unit
(DIU)
Micromachine
FIFO Control
Dual
Ported
FIFO
3 Kbyte
Rx FIFO
CSMA/CD
Unit
LAN
Connect
Interface
Parallel Subsystem Overview
The parallel subsystem is divided into several functional blocks: a PCI bus master interface, a
micromachine processing unit and its corresponding microcode ROM, and a PCI Target Control/
EEPROM/ interface. The parallel subsystem also interfaces to the FIFO subsystem, passing data
(e.g., transmit, receive, and configuration data) and command and status parameters between these
two blocks.
The PCI bus master interface provides a complete interface to the PCI bus and is compliant with
the PCI Bus Specification, Revision 2.2. The LAN Controller provides 32 bits of addressing and
data, as well as the complete control interface to operate on the PCI bus. As a PCI target, it follows
the PCI configuration format which allows all accesses to the LAN Controller to be automatically
mapped into free memory and I/O space upon initialization of a PCI system. For processing of
transmit and receive frames, the integrated LAN Controller operates as a master on the PCI bus,
initiating zero wait state transfers for accessing these data parameters.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-7
Functional Description
The LAN Controller Control/Status Register Block is part of the PCI target element. The Control/
Status Register block consists of the following LAN Controller internal control registers: System
Control Block (SCB), PORT, EEPROM Control and Management Data Interface (MDI) Control.
The micromachine is an embedded processing unit contained in the LAN Controller that enables
Adaptive Technology. The micromachine accesses the LAN Controller’s microcode ROM,
working its way through the opcodes (or instructions) contained in the ROM to perform its
functions. Parameters accessed from memory (e.g., pointers to data buffers) are also used by the
micromachine during the processing of transmit or receive frames by the LAN Controller. A
typical micromachine function is to transfer a data buffer pointer field to the LAN Controller’s
DMA unit for direct access to the data buffer. The micromachine is divided into two units, Receive
Unit and Command Unit that includes transmit functions. These two units operate independently
and concurrently. Control is switched between the two units according to the microcode instruction
flow. The independence of the Receive and Command units in the micromachine allows the LAN
Controller to execute commands and receive incoming frames simultaneously, with no real-time
processor intervention.
The LAN Controller contains an interface to an external serial EEPROM. The EEPROM is used to
store relevant information for a LAN connection such as node address, as well as board
manufacturing and configuration information. Both read and write accesses to the EEPROM are
supported by the LAN Controller. Information on the EEPROM interface is detailed in
Section 5.2.4.
FIFO Subsystem Overview
The ICH2 LAN Controller FIFO subsystem consists of a 3 KB transmit FIFO and 3 KB receive
FIFO. Each FIFO is unidirectional and independent of the other. The FIFO subsystem serves as the
interface between the LAN Controller parallel side and the serial CSMA/CD unit. It provides a
temporary buffer storage area for frames as they are either being received or transmitted by the
LAN Controller, which improves performance:
• Transmit frames can be queued within the transmit FIFO, allowing back-to-back transmission
within the minimum Interframe Spacing (IFS).
• The storage area in the FIFO allows the LAN Controller to withstand long PCI bus latencies
without losing incoming data or corrupting outgoing data.
• The ICH2 LAN Controller’s transmit FIFO threshold allows the transmit start threshold to be
tuned to eliminate underruns while concurrent transmits are being performed.
• The FIFO subsection allows extended PCI zero wait state burst accesses to or from the LAN
Controller for both transmit and receive frames since the transfer is to the FIFO storage area
rather than directly to the serial link.
• Transmissions resulting in errors (collision detection or data underrun) are retransmitted
directly from the LAN Controller’s FIFO, increasing performance and eliminating the need to
re-access this data from the host system.
• Incoming runt receive frames (in other words, frames that are less than the legal minimum
frame size) can be discarded automatically by the LAN Controller without transferring this
faulty data to the host system.
Serial CSMA/CD Unit Overview
The CSMA/CD unit of the ICH2 LAN Controller allows it to be connected to the 82562ET/EM
10/100 Mbps Ethernet LAN Connect components or the 82562EH 1 Mbps HomePNA*-compliant
LAN Connect component. The CSMA/CD unit performs all of the functions of the 802.3 protocol
such as frame formatting, frame stripping, collision handling, deferral to link traffic, etc. The
CSMA/CD unit can also be placed in a full duplex mode which allows simultaneous transmission
and reception of frames.
5-8
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.2.2
LAN Controller PCI Bus Interface
As a Fast Ethernet Controller, the role of the ICH2 integrated LAN Controller is to access
transmitted data or deposit received data. The LAN Controller, as a bus master device, initiates
memory cycles via the PCI bus to fetch or deposit the required data.
To perform these actions, the LAN Controller is controlled and examined by the processor via its
control and status structures and registers. Some of these control and status structures reside in the
LAN Controller and some reside in system memory. For access to the LAN Controller’s Control/
Status Registers (CSR), the LAN Controller acts as a slave (in other words, a target device). The
LAN Controller serves as a slave also while the processor accesses the EEPROM.
5.2.2.1
Bus Slave Operation
The ICH2 integrated LAN Controller serves as a target device in one of the following cases:
• Processor accesses to the LAN Controller System Control Block (SCB) Control/Status
Registers (CSR)
•
•
•
•
Processor accesses to the EEPROM through its CSR
Processor accesses to the LAN Controller PORT address via the CSR
Processor accesses to the MDI control register in the CSR
PCI Configuration cycles
The size of the CSR memory space is 4 KB in the memory space and 64 bytes in the I/O space. The
LAN Controller treats accesses to these memory spaces differently.
Control/Status Register (CSR) Accesses
The integrated LAN Controller supports zero wait state single cycle memory or I/O mapped
accesses to its CSR space. Separate BARs request 4 KB of memory space and 64 bytes of I/O
space to accomplish this. Based on its needs, the software driver uses either memory or I/O
mapping to access these registers. The LAN Controller provides 4 KB of CSR space, which
includes the following elements:
•
•
•
•
•
System Control Block (SCB) registers
PORT register
EEPROM control register
MDI control register
Flow control registers
In the case of accessing the Control/Status Registers, the processor is the initiator and the LAN
Controller is the target.
Read Accesses: The processor, as the initiator, drives address lines AD[31:0], the command and
byte enable lines C/BE[3:0]#, and the control lines IRDY# and FRAME#. As a slave, the LAN
Controller controls the TRDY# signal and provides valid data on each data access. The LAN
Controller allows the processor to issue only one read cycle when it accesses the Control/Status
Registers, generating a disconnect by asserting the STOP# signal. The processor can insert wait
states by deasserting IRDY# when it is not ready.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-9
Functional Description
Write Accesses: The processor, as the initiator, drives the address lines AD[31:0], the command
and byte enable lines C/BE[3:0]#, and the control lines IRDY# and FRAME#. It also provides the
LAN Controller with valid data on each data access immediately after asserting IRDY#. The LAN
Controller controls the TRDY# signal and asserts it from the data access. The LAN Controller
allows the processor to issue only one I/O write cycle to the Control/Status Registers, generating a
disconnect by asserting the STOP# signal. This is true for both memory mapped and I/O mapped
accesses.
Retry Premature Accesses
The LAN Controller responds with a retry to any configuration cycle accessing the LAN Controller
before the completion of the automatic read of the EEPROM. The LAN Controller may continue to
Retry any configuration accesses until the EEPROM read is complete. The LAN Controller does
not enforce the rule that the retried master must attempt to access the same address again to
complete any delayed transaction. Any master access to the LAN Controller after the completion of
the EEPROM read will be honored.
Error Handling
Data Parity Errors: The LAN Controller checks for data parity errors while it is the target of the
transaction. If an error was detected, the LAN Controller always sets the Detected Parity Error bit
in the PCI Configuration Status register, bit 15. The LAN Controller also asserts PERR#, if the
Parity Error Response bit is set (PCI Configuration Command register, bit 6). The LAN Controller
does not attempt to terminate a cycle in which a parity error was detected. This gives the initiator
the option of recovery.
Target-Disconnect: The LAN Controller terminates a cycle in the following cases:
• After accesses to its CSR
• After accesses to the configuration space
System Error: The LAN Controller reports parity error during the address phase using the SERR#
pin. If the SERR# Enable bit in the PCI Configuration Command register or the Parity Error
Response bit are not set, the LAN Controller only sets the Detected Parity Error bit (PCI
Configuration Status register, bit 15). If SERR# Enable and Parity Error Response bits are both set,
the LAN Controller sets the Signaled System Error bit (PCI Configuration Status register, bit 14) as
well as the Detected Parity Error bit and asserts SERR# for one clock.
The LAN Controller, when detecting system error, will claim the cycle if it was the target of the
transaction and continue the transaction as if the address was correct.
Note:
5.2.2.2
The LAN Controller reports a system error for any error during an address phase, whether or not it
is involved in the current transaction.
Bus Master Operation
As a PCI Bus Master, the ICH2 integrated LAN Controller initiates memory cycles to fetch data for
transmission or deposit received data and for accessing the memory resident control structures. The
LAN Controller performs zero wait state burst read and write cycles to the host main memory. For
bus master cycles, the LAN Controller is the initiator and the host main memory (or the PCI host
bridge, depending on the configuration of the system) is the target.
The processor provides the LAN Controller with action commands and pointers to the data buffers
that reside in host main memory. The LAN Controller independently manages these structures and
initiates burst memory cycles to transfer data to and from them. The LAN Controller uses the
5-10
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
Memory Read Multiple (MR Multiple) command for burst accesses to data buffers and the
Memory Read Line (MR Line) command for burst accesses to control structures. For all write
accesses to the control structure, the LAN Controller uses the Memory Write (MW) command. For
write accesses to the data structure, the LAN Controller may use either the Memory Write or
Memory Write and Invalidate (MWI) commands.
Read Accesses: The LAN Controller performs block transfers from host system memory to
perform frame transmission on the serial link. In this case, the LAN Controller initiates zero wait
state memory read burst cycles for these accesses. The length of a burst is bounded by the system,
the LAN Controller’s internal FIFO. The length of a read burst may also be bounded by the value
of the Transmit DMA Maximum Byte Count in the Configure command. The transmit DMA
Maximum Byte Count value indicates the maximum number of transmit DMA PCI cycles that will
be completed after a LAN Controller internal arbitration.
The LAN Controller, as the initiator, drives the address lines AD[31:0], the command and byte
enable lines C/BE[3:0]#, and the control lines IRDY# and FRAME#. The LAN Controller asserts
IRDY# to support zero wait state burst cycles. The target signals the LAN Controller that valid data
is ready to be read by asserting the TRDY# signal.
Write Accesses: The LAN Controller performs block transfers to host system memory during
frame reception. In this case, the LAN Controller initiates memory write burst cycles to deposit the
data, usually without wait states. The length of a burst is bounded by the system and the LAN
Controller’s internal FIFO threshold. The length of a write burst may also be bounded by the value
of the Receive DMA Maximum Byte Count in the configure command. The Receive DMA
Maximum Byte Count value indicates the maximum number of receive DMA PCI transfers that
will be completed before the LAN Controller internal arbitration.
The LAN Controller, as the initiator, drives the address lines AD[31:0], the command and byte
enable lines C/BE[3:0]#, and the control lines IRDY# and FRAME#. The LAN Controller asserts
IRDY# to support zero wait state burst cycles. The LAN Controller also drives valid data on
AD[31:0] lines during each data phase (from the first clock and on). The target controls the length
and signal’s completion of a data phase by deassertion and assertion of TRDY#.
Cycle Completion: The LAN Controller completes (terminates) its initiated memory burst cycles
in the following cases:
• Normal Completion: All transaction data has been transferred to or from the target device
(for example, host main memory).
• Backoff: Latency Timer has expired and the bus grant signal (GNT#) was removed from the
•
•
•
•
LAN Controller by the arbiter, indicating that the LAN Controller has been preempted by
another bus master.
Transmit or Receive DMA Maximum Byte Count: The LAN Controller burst has reached
the length specified in the transmit or receive DMA Maximum Byte Count field in the
Configure command block.
Target Termination: The target may request to terminate the transaction with a targetdisconnect, target-retry, or target-abort. In the first two cases, the LAN Controller initiates the
cycle again. In the case of a target-abort, the LAN Controller sets the Received Target-Abort
bit in the PCI Configuration Status field (PCI Configuration Status register, bit 12) and does
not re-initiate the cycle.
Master Abort: The target of the transaction has not responded to the address initiated by the
LAN Controller (in other words, DEVSEL# has not been asserted). The LAN Controller
simply deasserts FRAME# and IRDY# as in the case of normal completion.
Error Condition: In the event of parity or any other system error detection, the LAN
Controller completes its current initiated transaction. Any further action taken by the LAN
Controller depends on the type of error and other conditions.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-11
Functional Description
Memory Write and Invalidate
The LAN Controller has four Direct Memory Access (DMA) channels. Of these four channels (the
receive DMA channel) is used to deposit the large number of data bytes received from the link into
system memory. The receive DMA uses both the Memory Write (MW) and the Memory Write and
Invalidate (MWI) commands. To use MWI, the LAN Controller must guarantee the following:
1. Minimum transfer of one cache line
2. Active byte enable bits (or BE[3:0]# are all low) during MWI access
3. The LAN Controller may cross the cache line boundary only if it intends to transfer the next
cache line too.
To ensure the above conditions, the LAN Controller may use the MWI command only under the
following conditions:
1. The Cache Line Size (CLS) written in the CLS register during PCI configuration is 8 or 16
DWords.
2. The accessed address is cache line aligned.
3. The LAN Controller has at least 8 or 16 DWords of data in its receive FIFO.
4. There are at least 8 or 16 DWords of data space left in the system memory buffer.
5. The MWI Enable bit in the PCI Configuration Command register, bit 4, should is set to 1.
6. The MWI Enable bit in the LAN Controller Configure command should is set to 1.
If any one of the above conditions does not hold, the LAN Controller will use the MW command.
If a MWI cycle has started and one of the conditions is no longer valid (for example, the data space
in the memory buffer is now less than CLS), then the LAN Controller terminates the MWI cycle at
the end of the cache line. The next cycle will be either a MW or MWI cycle depending on the
conditions listed above.
If the LAN Controller started a MW cycle and reached a cache line boundary, it either continues or
terminates the cycle depending on the Terminate Write on Cache Line configuration bit of the LAN
Controller Configure command (byte 3, bit 3). If this bit is set, the LAN Controller terminates the
MW cycle and attempts to start a new cycle. The new cycle is a MWI cycle if this bit is set and all
of the above listed conditions are met. If the bit is not set, the LAN Controller continues the MW
cycle across the cache line boundary if required.
Read Align
The Read Align feature enhances the LAN Controller’s performance in cache line oriented
systems. In these particular systems, starting a PCI transaction on a non-cache line aligned address
may cause low performance.
To resolve this performance anomaly, the LAN Controller attempts to terminate transmit DMA
cycles on a cache line boundary and start the next transaction on a cache line aligned address. This
feature is enabled when the Read Align Enable bit is set in the LAN Controller Configure
command (byte 3, bit 2).
If this bit is set, the LAN Controller operates as follows:
• When the LAN Controller is almost out of resources on the transmit DMA (i.e., the transmit
FIFO is almost full), it attempts to terminate the read transaction on the nearest cache line
boundary when possible.
• When the arbitration counter’s feature is enabled (i.e., the Transmit DMA Maximum Byte
Count value is set in the Configure command), the LAN Controller switches to other pending
DMAs on cache line boundary only.
5-12
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
Note:
This feature is not recommended for use in non-cache line oriented systems since it may cause
shorter bursts and lower performance.
Note:
This feature should be used only when the CLS register in PCI Configuration space is set to 8 or
16.
Note:
The LAN Controller reads all control data structures (including Receive Buffer Descriptors) from
the first DWord (even if it is not required) to maintain cache line alignment.
Error Handling
Data Parity Errors: As an initiator, the LAN Controller checks and detects data parity errors that
occur during a transaction. If the Parity Error Response bit is set (PCI Configuration Command
register, bit 6), the LAN Controller also asserts PERR# and sets the Data Parity Detected bit (PCI
Configuration Status register, bit 8). In addition, if the error was detected by the LAN Controller
during read cycles, it sets the Detected Parity Error bit (PCI Configuration Status register, bit 15).
5.2.3
CLOCKRUN# Signal (82801BAM ICH2-M only)
The ICH2-M receives a free-running 33 MHz clock. It does not stop based on the CLKRUN#
signal and protocol. When the LAN controller runs cycles on the PCI bus, the ICH2-M makes sure
that the STP_PCI# signal is high indictating that the PCI clock is running. This is to make sure that
any PCI tracker will not get confused by transactions on the PCI bus with its PCI clock stopped.
5.2.3.1
PCI Power Management
Enhanced support for the power management standard, PCI specification rev. 2.2, is provided in
the ICH2 integrated LAN Controller. The LAN Controller supports a large set of wake-up packets
and the capability to wake the system from a low power state on a link status change. The LAN
Controller enables the host system to be in a sleep state and remain virtually connected to the
network.
After a power management event or link status change is detected, the LAN Controller will wake
the host system. The sections below describe these events, the LAN Controller power states, and
estimated power consumption at each power state.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-13
Functional Description
Power States
The LAN Controller contains power management registers for PCI and implements all four power
states defined in the Power Management Network Device Class Reference Specification, Rev. 1.0.
The four states, D0 through D3, vary from maximum power consumption at D0 to the minimum
power consumption at D3. PCI transactions are only allowed in the D0 state, except for host
accesses to the LAN Controller’s PCI configuration registers. The D1 and D2 power management
states enable intermediate power savings while providing the system wake-up capabilities. In the
D3 state, the LAN Controller can provide wake-up capabilities. Wake-up indications from the LAN
Controller are provided by the Power Management Event (PME#) signal.
• D0 Power State. As defined in the Network Device Class Reference Specification, the device
is fully functional in the D0 power state. In this state, the LAN Controller receives full power
and should be providing full functionality. In the LAN Controller the D0 state is partitioned
into two substates, D0 Uninitialized (D0u) and D0 Active (D0a).
D0u is the LAN Controller’s initial power state following a PCI RST#. While in the D0u state,
the LAN Controller has PCI slave functionality to support its initialization by the host and
supports Wake on LAN* mode. Initialization of the CSR, Memory, or I/O Base Address
Registers (PCI Configuration space) switches the LAN Controller from D0u state to D0a state.
In the D0a state, the LAN Controller provides its full functionality and consumes its nominal
power. In addition, the LAN Controller supports wake on link status change (see
Section 5.2.3.3). While it is active, the LAN Controller requires a nominal PCI clock signal (in
other words, a clock frequency greater than 16 MHz) for proper operation. The LAN
Controller supports a dynamic standby mode. In this mode, the LAN Controller is able to save
almost as much power as it does in the static power-down states. The transition to or from
standby is done dynamically by the LAN Controller and is transparent to the software.
• D1 Power State. For a device to meet the D1 power state requirements, as specified in the
Advanced Configuration and Power Interface (ACPI) Specification, Revision 1.0, it must not
allow bus transmission or interrupts; however, bus reception is allowed. Therefore, device
context may be lost and the LAN Controller does not initiate any PCI activity. In this state, the
LAN Controller responds only to PCI accesses to its configuration space and system wake-up
events.
The LAN Controller retains link integrity and monitors the link for any wake-up events such
as wake-up packets or link status change. Following a wake-up event, the LAN Controller
asserts the PME# signal.
• D2 Power State. The ACPI D2 power state is similar in functionality to the D1 power state. In
addition to D1 functionality, the LAN Controller can provide a lower power mode with wakeon-link status change capability. The LAN Controller may enter this mode if the link is down
while the LAN Controller is in the D2 state. In this state, the LAN Controller monitors the link
for a transition from an invalid to a valid link.
The sub-10 mA state due to an invalid link can be enabled or disabled by the PME_EN bit in
the Power Management Driver Register (PMDR). The LAN Controller will consume in D2
10 mA regardless of the link status. It is the LAN Connect component that consumes much
less power during link down, hence LAN Controller in this state can consume <10 mA.
• D3 Power State. In the D3 power state, the LAN Controller has the same capabilities and
consumes the same amount of power as it does in the D2 state. However, it enables the PCI
system to be in the B3 state. If the PCI system is in the B3 state (in other words, no PCI power
is present), the LAN Controller provides wake-up capabilities. If PME is disabled, the LAN
Controller does not provide wake-up capability or maintain link integrity. In this mode the
LAN Controller consumes its minimal power (if PME_EN=0).
The LAN Controller enables a system to be in a sub-5 watt state (low power state) and still be
virtually connected. More specifically, the LAN Controller supports full wake-up capabilities
while it is in the D3 cold state. The LAN Controller is in the ICH2 resume well and, thus, is
connected to an auxiliary power source (a separate LAN well). This enables it to provide
wake-up functionality while the PCI power is off.
5-14
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.2.3.2
PCI Reset Signal
The PCIRST# signal may be activated in one of the following cases:
• During S3-S5 states
• Due to a CF9h reset
If PME# is enabled (in the PCI power management registers), PCIRST# assertion does not affect
any PME# related circuits (in other words, PCI power management registers and the wake-up
packet would not be affected). While PCIRST# is active, the LAN Controller ignores other PCI
signals. The configuration of the LAN Controller registers associated with ACPI wake events is not
affected by PCIRST#.
The integrated LAN Controller uses the PCIRST# or the PWROK signal as an indication to ignore
the PCI interface. Following the deassertion of PCIRST#, the LAN Controller PCI Configuration
Space, MAC configuration, and memory structure are initialized while preserving the PME# signal
and its context.
5.2.3.3
Wake-up Events
There are two types of wake-up events: “Interesting” Packets and Link Status Change. These two
events are detailed below.
Note:
If the WOL bit in the EEPROM is not set, wake-up events are supported only if the PME Enable bit
in the Power Management Control/Status Register (PMCSR) is set. However, if the WOL bit in the
EEPROM is set, and Wake on Magic Packet or Wake on Link Status Change are enabled, the
Power Management Enable bit is ignored with respect to these events. In the latter case, PME#
would be asserted by these events.
"Interesting" Packet Event
In the power-down state, the LAN Controller is capable of recognizing “interesting” packets. The
LAN Controller supports pre-defined and programmable packets that can be defined as any of the
following:
•
•
•
•
•
•
ARP Packets (with Multiple IP addresses)
Direct Packets (with or without type qualification)
Magic Packet*
Neighbor Discovery Multicast Address Packet (‘ARP’ in IPv6 environment)
NetBIOS over TCP/IP (NBT) Query Packet (under IPv4)
Internetwork Package Exchange* (IPX) Diagnostic Packet
This allows the LAN Controller to handle various packet types. In general, the LAN Controller
supports programmable filtering of any packet in the first 128 bytes.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-15
Functional Description
When the LAN Controller is in one of the low power states, it searches for a predefined pattern in
the first 128 bytes of the incoming packets. The only exception is the Magic Packet, which is
scanned for the entire frame. The LAN Controller will classify the incoming packets as one of the
following categories:
• No Match: The LAN Controller discards the packet and continues to process the incoming
packets.
• Wake-up Packet: The LAN Controller is capable of recognizing and storing the first
128 bytes of a wake-up packet. If a wake-up packet is larger than 128 bytes, its tail is discarded
by the LAN Controller. After the system is fully powered-up, software has the ability to
determine the cause of the wake-up event via the PMDR and dump the stored data to the host
memory.
Magic Packets are an exception. The magic packets may cause a power management event and
set an indication bit in the PMDR; however, it is not stored by the LAN Controller for use by
the system when it is woken up.
Link Status Change Event
The LAN Controller link status indication circuit is capable of issuing a PME on a link status
change from a valid link to an invalid link condition or vice versa. The LAN Controller reports a
PME link status event in all power states. If the WOL bit in the EEPROM is not set, the PME#
signal is gated by the PME Enable bit in the PMCSR and the CSMA Configure command.
5.2.3.4
Wake on LAN (Preboot Wake-up)
The LAN Controller enters WOL mode after reset if the WOL bit in the EEPROM is set. At this
point, the LAN Controller is in the D0u state.
When the LAN Controller is in WOL mode:
• The LAN Controller scans incoming packets for a Magic Packet and asserts the PME# signal
for 52 ms when a one is detected in Wake on LAN mode.
• The Activity LED changes its functionality to indicates that the received frame passed
Individual Address (IA) filtering or broadcast filtering.
• The PCI Configuration registers are accessible to the host.
The LAN Controller switches from WOL mode to the D0a power state following a setup of the
Memory or I/O Base Address Registers in the PCI configuration space.
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82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.2.4
Serial EEPROM Interface
The serial EEPROM stores configuration data for the ICH2 integrated LAN Controller and is a
serial in/serial out device. The LAN Controller supports a 64 word size or 256 register size
EEPROM and automatically detects the EEPROM’s size. A 256 word EEPROM device is required
for a Cardbus system and contains the CIS information. The EEPROM should operate at a
frequency of at least 1 MHz.
All accesses, either read or write, are preceded by a command instruction to the device. The
address field is six bits for a 64 word EEPROM or eight bits for a 256 register EEPROM. The end
of the address field is indicated by a dummy zero bit from the EEPROM, which indicates the entire
address field has been transferred to the device. An EEPROM read instruction waveform is shown
in Figure 5-5.
Figure 5-5. 64-Word EEPROM Read Instruction Waveform
EE_SHCLKK
EE_CS
A5
A4
A3
A2
AA10
A0
EE_DIN
READ OP code
D15
D0
EE_DOUT
The LAN Controller performs an automatic read of seven words (0h, 1h, 2h, Ah, Bh, Ch and Dh) of
the EEPROM after the deassertion of Reset. The ICH2 integrated LAN Controller’s EEPROM
format is shown below in Table 5-2. For additional information, refer to Application Note AP-409,
"I/O Controller Hub EEPROM Map and Programming Information"
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-17
Functional Description
Table 5-2. I/O Control Hub 2 EEPROM Address Map
Word
HIgh Byte (Bits 15:8)
Low Byte (Bits 7:0)
Used by
00h
Ethernet Individual Address Byte 2
Ethernet Individual Address Byte 1
Hardware
01h
Ethernet Individual Address Byte 4
Ethernet Individual Address Byte 3
Hardware
02h
Ethernet Individual Address Byte 6
Ethernet Individual Address Byte 5
Hardware
03h
Compatibility Byte 1
Compatibility Byte 0
Intel® driver
04h
05h
Reserved
Controller Type (02 for ICH2)
Connector Type
06h
PHY Device Record
07h
Reserved
Intel driver
08h
PWA Number Byte 4
PWA Number Byte 3
Factory
09h
PWA Number Byte 2
PWA Number Byte 1
Factory
0Ah
EEPROM ID
Hardware
0Bh
Subsystem ID
Hardware
0Ch
Subsystem Vendor ID
0Dh
0000b
Heartbeat Packet
Pointer
0Eh–2Fh
SMB Address Field
Hardware
Alert on
LAN* driver
or hardware
Reserved
30h
Reserved for Intel Network Interface Division (NID) Boot Agent ROM Configuration
(PXE and RPL version)
Firmware
31h
Reserved for Intel NID Boot Agent ROM Configuration (PXE and RPL version)
Firmware
32h
Reserved for Intel NID Boot Agent ROM Configuration (PXE and RPL version)
Firmware
33h–3Ah
3Bh
Reserved
Reserved for
Intel®
Architecture Labs (IAL) Boot ROM Configuration (PXE only)
3Ch–3Fh
Reserved
40h–FAh
Alert on LAN alert packet structure
FFh
Checksum
Firmware
Alert on LAN
driver
Driver
Words 00h through 02h are used by the hardware and are common to all controllers.
5-18
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.2.5
CSMA/CD Unit
The ICH2 integrated LAN Controller CSMA/CD unit implements both the IEEE 802.3 Ethernet
10 Mbps and IEEE 802.3u Fast Ethernet 100 Mbps standards. It also supports the 1 Mbps Home
Phoneline Networking Alliance (HomePNA*) specification effort. It performs all the CSMA/CD
protocol functions such as transmission, reception, collision handling, etc. The LAN Controller
CSMA/CD unit interfaces to the 82562ET/EM 10/100 Mbps Ethernet or the 82562EH 1 Mbps
HomePNA*-compliant LAN Connect component through the ICH2’s LAN Connect interface
signals.
Full Duplex
When operating in full duplex mode, the LAN Controller can transmit and receive frames
simultaneously. Transmission starts regardless of the state of the internal receive path. Reception
starts when the LAN Connect component detects a valid frame on its receive differential pair.
When in Full Duplex mode, the ICH2 integrated LAN Controller also supports the IEEE 802.3x
flow control standard.
The LAN Controller operates in either half duplex mode or full duplex mode. For proper operation,
both the LAN Controller CSMA/CD module and the discrete LAN Connect component must be set
to the same duplex mode. The CSMA duplex mode is set by the LAN Controller Configure
command or forced by automatically tracking the mode in the LAN Connect component.
Following reset, the CSMA will default to automatically track the LAN Connect component
duplex mode.
The selection of duplex operation (full or half) and flow control is done in two levels: MAC and
LAN Connect.
Flow Control
The LAN Controller supports IEEE 802.3x frame based flow control frames only in full duplex
switched environments. The LAN Controller flow control feature is not intended to be used in
shared media environments.
Flow control is optional in full duplex mode and is selected through software configuration. There
are three modes of flow control that can be selected: frame-based transmit flow control, framebased receive flow control, and none.
Address Filtering Modifications
The LAN Controller can be configured to ignore one bit when checking for its Individual Address
(IA) on incoming receive frames. The address bit, known as the Upper/Lower (U/L) bit, is the
second least significant bit of the first byte of the IA. This bit may be used, in some cases, as a
priority indication bit. When configured to do so, the LAN Controller passes any frame that
matches all other 47 address bits of its IA, regardless of the U/L bit value.
This configuration only affects the LAN Controller specific IA and not multicast, multi-IA or
broadcast address filtering. The LAN Controller does not attribute any priority to frames with this
bit set, it simply passes them to memory regardless of this bit.
VLAN Support
The LAN Controller supports the IEEE 802.1 standard VLAN. All VLAN flows are implemented
by software. The LAN Controller supports the reception of long frames; specifically frames longer
than 1518 bytes, including the CRC, if software sets the Long Receive OK bit in the Configuration
command. Otherwise, “long” frames are discarded.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-19
Functional Description
5.2.6
Media Management Interface
The management interface allows the processor to control the LAN Connect component via a
control register in the ICH2 integrated LAN Controller. This allows the software driver to place the
LAN Connect in specific modes such as full duplex, loopback, power down, etc., without the need
for specific hardware pins to select the desired mode. This structure allows the LAN Controller to
query the LAN Connect component for status of the link. This register is the MDI Control Register
and resides at offset 10h in the LAN Controller CSR. The MDI registers reside within the LAN
Connect component, and are described in detail in the LAN Connect component’s datasheet. The
processor writes commands to this register and the LAN Controller reads or writes the control/
status parameters to the LAN Connect component through the MDI register.
5.2.7
TCO Functionality
The ICH2-M integrated LAN controller supports management communication to reduce Total Cost
of Ownership (TCO). It has a System Management Bus (SMB) on which the LAN controller is a
slave device. The SMB is used as an interface between the LAN controller and the integrated host
controller. An EEPROM of 256 words is required to support the heartbeat command.
Receive Functionality
In the power-up state, the LAN controller transfers TCO packets to the host as any other packet.
These packets include a new status indication bit in the Receive Frame Descriptor (RFD) status
register and have a specific port number indicating TCO packet recognition. In the power-down
state, the TCO packets are treated as wake-up packets. The ICH2-M integrated LAN controller
asserts the PME# signal and delivers the first 120 bytes of the packet to the host.
Transmit Functionality
The ICH2-M integrated LAN controller supports the Heartbeat (HB) transmission command from
the SMB interface. The send HB packet command includes a system health status issued by the
integrated system controller. The LAN controller computes a matched checksum and CRC and
transmits the HB packet from its serial EEPROM. The HB packet size and structure are not limited
as long as it fits within the EEPROM size. In this case, the EEPROM size is 256 words to enable
the storage of the HB packet (the first 64 words are used for driver specific data).
Note:
5.3
On the SMB, the send heartbeat packet command is not normally used in the D0 power state. The
one exception in which it is used in the D0 state is when the system is hung. In normal operating
mode, the heartbeat packets are transmitted through the ICH2-M integrated LAN controller
software similar to other packets.
LPC Bridge (w/ System and Management Functions)
(D31:F0)
The LPC Bridge function of the ICH2 resides in PCI Device 31:Function 0. In addition to the LPC
bridge function, D31:F0 contains other functional units including DMA, Interrupt Controllers,
Timers, Power Management, System Management, GPIO, and RTC. In this chapter, registers and
functions associated with other functional units (power management, GPIO, USB, IDE, etc.) are
described in their respective sections.
5-20
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.3.1
LPC Interface
The ICH2 implements an LPC interface as described in the LPC 1.0 specification. The LPC
interface to the ICH2 is shown in Figure 5-6. Note that the ICH2 implements all of the signals that
are shown as optional, but peripherals are not required to do so.
Figure 5-6. LPC Interface Diagram
PCI Bus
PCI
CLK
PCI
RST#
PCI
SERIRQ
PCI
PME#
LAD[3:0]
ICH2
ICH
LFRAME#
LDRQ#
(optional)
SUS_STAT#
GPI
5.3.1.1
Super I/O
LPCPD#
(optional)
LSMI#
(optional)
LPC Cycle Types
The ICH2 implements all of the cycle types described in the LPC I/F 1.0 specification. Table 5-3
shows the cycle types supported by the ICH2.
Table 5-3. LPC Cycle Types Supported
Cycle Type
Comment
Memory Read
Single: 1 byte only
Memory Write
Single: 1 byte only
I/O Read
1 byte only. ICH2 breaks up 16 and 32-bit processor cycles into multiple 8-bit
transfers. See Note 1 below.
I/O Write
1 byte only. ICH2 breaks up 16 and 32-bit processor cycles into multiple 8-bit
transfers. See Note 1 below.
DMA Read
Can be 1 or 2 bytes
DMA Write
Can be 1 or 2 bytes
Bus Master Read
Can be 1, 2, or 4 bytes. (See Note 2 below)
Bus Master Write
Can be 1, 2, or 4 bytes. (See Note 2 below)
NOTES:
1. For memory cycles below 16 MB which do not target enabled FWH ranges, the ICH2will perform standard
LPC memory cycles. It will only attempt 8-bit transfers. If the cycle appears on PCI as a 16-bit transfer, it will
appear as two consecutive 8-bit transfers on LPC. Likewise, if the cycle appears as a 32-bit transfer on PCI,
it will appear as four consecutive 8-bit transfers on LPC. If the cycle is not claimed by any peripheral, it will be
subsequently aborted, and the ICH2 will return a value of all 1s to the processor. This is done to maintain
compatibility with ISA memory cycles where pull-up resistors would keep the bus high if no device responds.
2. Bus Master Read or Write cycles must be naturally aligned. For example, a 1-byte transfer can be to any
address. However, the 2-byte transfer must be word aligned (i.e. with an address where A0=0). A DWord
transfer must be DWord aligned (i.e., with an address where A1and A0 are both 0)
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-21
Functional Description
5.3.1.2
Start Field Definition
Table 5-4. Start Field Bit Definitions
Bits[3:0]
Encoding
Definition
0000
Start of cycle for a generic target.
0010
Grant for bus master 0.
0011
Grant for bus master 1.
1111
Stop/Abort: End of a cycle for a target.
NOTE: All other encodings are Reserved.
5.3.1.3
Cycle Type / Direction (CYCTYPE + DIR)
The ICH2 always drives bit 0 of this field to 0. Peripherals running bus master cycles must also
drive bit 0 to 0. Table 5-5 shows the valid bit encodings.
Table 5-5. Cycle Type Bit Definitions
5.3.1.4
Bits[3:2]
Bit[1]
00
0
Definition
I/O Read
00
1
I/O Write
01
0
Memory Read
01
1
Memory Write
10
0
DMA Read
10
1
DMA Write
11
x
Reserved. If a peripheral performing a bus master cycle generates this value, the
ICH2 will abort the cycle.
Size
Bits[3:2] are reserved. The ICH2 always drives them to 00. Peripherals running bus master cycles
are also supposed to drive 00 for bits 3:2; however, the ICH2 ignores those bits. Table 5-6 shows
the bit encodings for Bits[1:0].
Table 5-6. Transfer Size Bit Definition
Bits[1:0]
5-22
Size
00
8 bit transfer (1 byte)
01
16-bit transfer (2 bytes)
10
Reserved. The ICH2 never drives this combination. If a peripheral running a bus master cycle
drives this combination, the ICH2 may abort the transfer.
11
32 bit transfer (4 bytes)
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.3.1.5
SYNC
Valid values for the SYNC field are listed in Table 5-7.
Table 5-7. SYNC Bit Definition
Bits[3:0]
Indication
0000
Ready: SYNC achieved with no error. For DMA transfers, this also indicates DMA request
deassertion and no more transfers desired for that channel.
0101
Short Wait: Part indicating wait states. For bus master cycles, the ICH2 does not use this
encoding. It will instead use the Long Wait encoding (see next encoding below).
0110
Long Wait: Part indicating wait states; many wait states will be added. This encoding driven by
the ICH2 for bus master cycles, rather than the Short Wait (0101).
1001
Ready More (Used only by peripheral for DMA cycle): SYNC achieved with no error and more
DMA transfers desired to continue after this transfer. This value is valid only on DMA transfers
and is not allowed for any other type of cycle.
1010
Error: Sync achieved with error. This is generally used to replace the SERR# or IOCHK# signal
on the PCI/ISA bus. It indicates that the data is to be transferred, but there is a serious error in this
transfer. For DMA transfers, this not only indicates an error, but also indicates DMA request
deassertion and no more transfers desired for that channel.
NOTE: All other combinations are Reserved.
5.3.1.6
SYNC Time-out
There are several error cases that can occur on the LPC interface. Table 5-8 indicates the failing
case and the ICH2 response.
Table 5-8. ICH2 Response to Sync Failures
Possible Sync Failure
ICH2 Response
ICH2 starts a Memory, I/O, or DMA cycle, but no device drives a valid SYNC
after 4 consecutive clocks. This could occur if the processor tries to access an
I/O location to which no device is mapped.
ICH2 aborts the cycle after
the 4th clock.
ICH2 drives a Memory, I/O, or DMA cycle, and a peripheral drives more than 8
consecutive valid SYNC patterns to insert wait states using the Short (‘0101b’)
encoding for SYNC. This could occur if the peripheral is not operating properly.
Continues waiting
ICH2 starts a Memory, I/O, or DMA cycle, and a peripheral drives an invalid
SYNC pattern. This could occur if the peripheral is not operating properly or if
there is excessive noise on the LPC interface.
ICH2 aborts the cycle when
the invalid Sync is
recognized.
NOTE: There may be other peripheral failure conditions; however, these are not handled by the ICH2.
5.3.1.7
SYNC Error Indication
The SYNC protocol allows the peripheral to report an error via the LAD[3:0] = 1010b encoding.
The intent of this encoding is to give peripherals a method of communicating errors to aid higher
layers with more robust error recovery.
If the ICH2 was reading data from a peripheral, data will still be transferred in the next two nibbles.
This data may be invalid; however, it must be transferred by the peripheral. If the ICH2 was writing
data to the peripheral, the data had already been transferred.
In the case of multiple byte cycles (e.g., for memory and DMA cycles) an error SYNC terminates
the cycle. Therefore, if the ICH2 is transferring 4 bytes from a device and the device returns the
error SYNC in the first byte, the other three bytes are not transferred.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-23
Functional Description
When recognizing the SYNC field indicating an error, the ICH2 treats this the same as IOCHK#
going active on the ISA bus.
5.3.1.8
LFRAME# Usage
Start of Cycle
For Memory, I/O, and DMA cycles, the ICH2 asserts LFRAME# for 1 clock at the beginning of the
cycle (Figure 5-7) During that clock, the ICH2 drives LAD[3:0] with the proper START field.
Figure 5-7. Typical Timing for LFRAME#
LCLK
LFRAME#
Start
ADDR
TAR
Sync
Data
2
1-n
Clocks Clocks
2
Clocks
LAD[3:0]#
1
CYCTYPE 1 - 8
Clock Dir & Size Clocks
TAR
2
Clocks
Start
1
Clock
Abort Mechanism
When performing an Abort, the ICH2 drives LFRAME# active for 4 consecutive clocks. On the 4th
clock, the ICH2 drives LAD[3:0] to ‘1111b’.
Figure 5-8. Abort Mechanism
LCLK
LFRAME#
LAD[3:0]#
Start
ADDR
CYCTYPE
Dir & Size
TAR
Sync
Peripheral must
stop driving
Chipset will
drive high
Too many
Syncs causes
timeout
The ICH2 performs an abort for the following cases (possible failure cases):
• ICH2 starts a Memory, I/O, or DMA cycle and no device drives a valid SYNC after 4
consecutive clocks.
• ICH2 starts a Memory, I/O, or DMA cycle, and the peripheral drives an invalid SYNC pattern.
• A peripheral drives an illegal address when performing bus master cycles.
• A peripheral drives an invalid value.
5-24
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.3.1.9
I/O Cycles
For I/O cycles targeting registers specified in the ICH2’s decode ranges, the ICH2 performs I/O
cycles as defined in the LPC specification. These are 8-bit transfers. If the processor attempts a
16-bit or 32-bit transfer, the ICH2 will break the cycle up into multiple 8-bit transfers to
consecutive I/O addresses.
Note:
5.3.1.10
If the cycle is not claimed by any peripheral (and subsequently aborted), the ICH2 returns all
1s (FFh) to the processor. This is to maintain compatibility with ISA I/O cycles where pull-up
resistors would keep the bus high if no device responds.
Bus Master Cycles
The ICH2 supports Bus Master cycles and requests (using LDRQ#) as defined in the LPC
specification. The ICH2 has two LDRQ# inputs; thus, ICH2 supports two separate bus master
devices. It uses the associated START fields for Bus Master 0 (‘0010b’) or Bus Master 1 (‘0011b’).
Note:
5.3.1.11
The ICH2 does not support LPC Bus Masters performing I/O cycles. LPC Bus Masters should only
perform memory read or memory write cycles.
LPC Power Management
LPCPD# Protocol
Same timings as for SUS_STAT#. Upon driving SUS_STAT# low, LPC peripherals will drive
LDRQ# low or tri-state it. ICH2 shuts off the LDRQ# input buffers. After driving SUS_STAT#
active, the ICH2 drives LFRAME# low and tri-states (or drive low) LAD[3:0].
CLKRUN# Protocol (82801BAM ICH2-M only)
For the ICH2-M, the CLKRUN# protocol is the same as the PCI specification. Stopping the PCI
clock stops the LPC clock.
5.3.1.12
Configuration and ICH2 Implications
LPC Interface Decoders
To allow the I/O cycles and memory mapped cycles to go to the LPC I/F, the ICH2 includes several
decoders. During configuration, the ICH2 must be programmed with the same decode ranges as the
peripheral. The decoders are programmed via the Device 31:Function 0 configuration space.
Note:
The ICH2 can not accept PCI write cycles from PCI-to-PCI bridges or devices with similar
characteristics (specifically those with a “Retry Read” feature which is enabled) to an LPC device
if there is an outstanding LPC read cycle towards the same PCI device or bridge. These cycles are
not part of normal system operation; however, they may be encountered as part of platform
validation testing using custom test fixtures.
Bus Master Device Mapping and START Fields
Bus Masters must have a unique START field. In the case of the ICH2, which supports 2 LPC bus
masters, it will drive 0010 for the START field for grants to bus master #0 (requested via
LDRQ[0]#) and 0011 for grants to bus master #1 (requested via LDRQ[1]#.). Thus, no registers are
needed to configure the START fields for a particular bus master.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-25
Functional Description
5.4
DMA Operation (D31:F0)
The ICH2 supports two types of DMA: LPC and PC/PCI. DMA via LPC is similar to ISA DMA.
LPC DMA and PC/PCI DMA use the ICH2’s DMA controller. The DMA controller has registers
that are fixed in the lower 64 KB of I/O space.
The DMA controller is configured using registers in the PCI configuration space. These registers
allow configuration of individual channels for use by LPC or PC/PCI DMA.
The DMA circuitry incorporates the functionality of two 82C37 DMA controllers with seven
independently programmable channels (Figure 5-9). DMA Controller 1 (DMA-1) corresponds to
DMA Channels 0–3 and DMA Controller 2 (DMA-2) corresponds to Channels 5–7. DMA Channel
4 is used to cascade the two controllers and will default to cascade mode in the DMA Channel
Mode (DCM) Register. Channel 4 is not available for any other purpose. In addition to accepting
requests from DMA slaves, the DMA controller also responds to requests that software initiates.
Software may initiate a DMA service request by setting any bit in the DMA Channel Request
Register to a 1.
Figure 5-9. ICH2 DMA Controller
Channel 4
Channel 0
Channel 1
Channel 5
DMA-1
Channel 2
Channel 6
Channel 3
Channel 7
DMA-2
Each DMA channel is hardwired to the compatible settings for DMA device size: channels 3–0 are
hardwired to 8-bit, count-by-bytes transfers and channels 7–5 are hardwired to 16-bit, count-bywords (address shifted) transfers.
ICH2 provides 24-bit addressing in compliance with the ISA-Compatible specification. Each
channel includes a 16-bit ISA-Compatible Current Register which holds the 16 least-significant
bits of the 24-bit address, an ISA-Compatible Page Register which contains the eight next most
significant bits of address.
The DMA controller also features refresh address generation and autoinitialization following a
DMA termination.
5.4.1
Channel Priority
For priority resolution, the DMA consists of two logical channel groups: channels 0–3 and
channels 4–7. Each group may be in either fixed or rotate mode, as determined by the DMA
Command Register.
DMA I/O slaves normally assert their DREQ line to arbitrate for DMA service. However, a
software request for DMA service can be presented through each channel's DMA Request Register.
A software request is subject to the same prioritization as any hardware request. See the detailed
register description for Request Register programming information in the DMA Register
description section.
5-26
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
Fixed Priority
The initial fixed priority structure is as follows:
High priority.....Low priority
(0, 1, 2, 3)
(5, 6, 7)
The fixed priority ordering is 0, 1, 2, 3, 5, 6, and 7. In this scheme, Channel 0 has the highest
priority and channel 7 has the lowest priority. Channels 3–0 of DMA-1 assume the priority position
of Channel 4 in DMA-2, thus taking priority over channels 5, 6, and 7.
Rotating Priority
Rotation allows for "fairness" in priority resolution. The priority chain rotates so that the last
channel serviced is assigned the lowest priority in the channel group (0–3, 5–7).
Channels 0–3 rotate as a group of 4. They are always placed between Channel 5 and Channel 7 in
the priority list.
Channel 5–7 rotate as part of a group of 4. That is, channels (5–7) form the first three positions in
the rotation while channel group (0–3) form the fourth position in the arbitration.
5.4.2
Address Compatibility Mode
When the DMA is operating, the addresses do not increment or decrement through the High and
Low Page Registers. Therefore, if a 24-bit address is 01FFFFh and increments, the next address
will be 010000h, not 020000h. Similarly, if a 24-bit address is 020000h and decrements, the next
address will be 02FFFFh, not 01FFFFh. This is compatible with the 82C37 and Page Register
implementation used in the PC-AT. This mode is set after CPURST is valid.
5.4.3
Summary of DMA Transfer Sizes
Table 5-9 lists each of the DMA device transfer sizes. The column labeled "Current Byte/Word
Count Register" indicates that the register contents represents either the number of bytes to transfer
or the number of 16-bit words to transfer. The column labeled "Current Address Increment/
Decrement" indicates the number added to or taken from the Current Address Register after each
DMA transfer cycle. The DMA Channel Mode Register determines if the Current Address Register
is incremented or decremented.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-27
Functional Description
Address Shifting When Programmed for 16-Bit I/O Count by Words
Table 5-9. DMA Transfer Size
Current Byte/Word Count
Register
Current Address
Increment/Decrement
8-Bit I/O, Count By Bytes
Bytes
1
16-Bit I/O, Count By Words (Address Shifted)
Words
1
DMA Device Date Size And Word Count
The ICH2 maintains compatibility with the implementation of the DMA in the PC-AT that used the
82C37. The DMA shifts the addresses for transfers to/from a 16-bit device count-by-words. Note
that the least significant bit of the Low Page Register is dropped in 16-bit shifted mode. When
programming the Current Address Register (when the DMA channel is in this mode), the current
address must be programmed to an even address with the address value shifted right by one bit. The
address shifting is shown in Table 5-10.
Table 5-10. Address Shifting in 16-bit I/O DMA Transfers
Output
Address
8-Bit I/O Programmed Address
(Ch 0–3)
16-Bit I/O Programmed Address
(Ch 5–7)
(Shifted)
A0
A[16:1]
A[23:17]
A0
A[16:1]
A[23:17]
0
A[15:0]
A[23:17]
NOTE: NOTE: The least significant bit of the Page Register is dropped in 16-bit shifted mode.
5.4.4
Autoinitialize
By programming a bit in the DMA Channel Mode Register, a channel may be set up as an
autoinitialize channel. When a channel undergoes autoinitialization, the original values of the
Current Page, Current Address and Current Byte/Word Count Registers are automatically restored
from the Base Page, Address, and Byte/Word Count Registers of that channel following TC. The
Base Registers are loaded simultaneously with the Current Registers by the processor when the
DMA channel is programmed and remain unchanged throughout the DMA service. The mask bit is
not set when the channel is in autoinitialize. Following autoinitialize, the channel is ready to
perform another DMA service, without processor intervention, as soon as a valid DREQ is
detected.
5-28
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.4.5
Software Commands
There are three additional special software commands that the DMA controller can execute. The
three software commands are:
• Clear Byte Pointer Flip-Flop
• Master Clear
• Clear Mask Register
They do not depend on any specific bit pattern on the data bus.
Clear Byte Pointer Flip-Flop
This command is executed prior to writing or reading new address or word count information
to/from the DMA controller. This initializes the flip-flop to a known state so that subsequent
accesses to register contents by the processor addresses upper and lower bytes in the correct
sequence.
When the Host processor is reading or writing DMA registers, two Byte Pointer flip-flops are used;
one for channels 0–3 and one for channels 4–7. Both of these act independently. There are separate
software commands for clearing each of them (0Ch for channels 0–3, 0D8h for channels 4–7).
DMA Master Clear
This software instruction has the same effect as the hardware reset. The Command, Status,
Request, and Internal First/Last Flip-Flop Registers are cleared and the Mask Register is set. The
DMA controller enters the idle cycle.
There are two independent master clear commands; 0Dh acts on channels 0–3, and 0DAh acts on
channels 4–7.
Clear Mask Register
This command clears the mask bits of all four channels, enabling them to accept DMA requests.
I/O port 00Eh is used for channels 0–3 and I/O port 0DCh is used for channels 4–7.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-29
Functional Description
5.5
PCI DMA
The ICH2 provides support for the PC/PCI DMA protocol. PC/PCI DMA uses dedicated request
and grant signals to permit PCI devices to request transfers associated with specific DMA
channels. Upon receiving a request and getting control of the PCI bus, the ICH2 performs a twocycle transfer. For example, if data is to be moved from the peripheral to main memory, the ICH2
first reads data from the peripheral and then writes the data to main memory. The location in main
memory is the Current Address Registers in the 8237.
ICH2 supports up to 2 PC/PCI REQ/GNT pairs, REQ[A:B]# and GNT[A:B]#.
A 16-bit register is included in the ICH2 Function 0 PCI configuration space at offset 90h. It is
divided into seven 2-bit fields that are used to configure the 7 DMA channels.
Each DMA channel can be configured to one of two options:
• LPC DMA
• PC/PCI style DMA using the REQ/GNT signals
It is not possible for a particular DMA channel to be configured for more than one style of DMA;
however, the seven channels can be programmed independently. For example, channel 3 can be set
up for PC/PCI and channel 5 set up for LPC DMA.
The ICH2 REQ[A:B]# and GNT[A:B]# can be configured for support of a PC/PCI DMA
Expansion agent. The PCI DMA Expansion agent can then provide DMA service or ISA Bus
Master service using the ICH2 DMA controller. The REQ#/GNT# pair must follow the PC/PCI
serial protocol described in the following section.
5.5.1
PCI DMA Expansion Protocol
The PCI expansion agent must support the PCI expansion Channel Passing Protocol defined in
Figure 5-10 for both the REQ# and GNT# pins.
Figure 5-10. DMA Serial Channel Passing Protocol
PCICLK
REQ#
GNT#
Start CH0 CH1 CH2 CH3 CH4 CH5 CH6 CH7
Start Bit0
Bit1
Bit2
The requesting device must encode the channel request information as shown above, where
CH0–CH7 are one clock active high states representing DMA channel requests 0–7.
The ICH2 encodes the granted channel on the GNT# line as shown above where the bits have the
same meaning as shown in Figure 5-10. For example, the sequence
[start, bit 0, bit 1, bit 2]=[0,1,0,0] grants DMA channel 1 to the requesting device, and the sequence
[start, bit 0, bit 1, bit 2]=[0,0,1,1] grants DMA channel 6 to the requesting device.
5-30
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
All PCI DMA expansion agents must use the channel passing protocol described above. They must
also work as follows:
1. If a PCI DMA expansion agent has more than one request active, it must resend the request
serial protocol after one of the requests has been granted the bus and it has completed its
transfer. The expansion device should drive its REQ# inactive for two clocks and then transmit
the serial channel passing protocol again, even if there are no new requests from the PCI
expansion agent to ICH2. For example, if a PCI expansion agent had active requests for DMA
Channel 1 and Channel 5, it would pass this information to the ICH2 through the expansion
channel passing protocol. If, after receiving GNT# (assume for CH5) and having the device
finish its transfer (device stops driving request to PCI expansion agent), it would then need to
re-transmit the expansion channel passing protocol to inform the ICH2 that DMA channel 1
was still requesting the bus, even if that was the only request the expansion device had
pending.
2. If a PCI DMA expansion agent has a request go inactive before ICH2 asserts GNT#, it must
resend the expansion channel passing protocol to update the ICH2 with this new request
information. For example, if a PCI expansion agent has DMA channel 1 and 2 requests
pending, it sends them serially to ICH2 using the expansion channel passing protocol. If,
however, DMA channel 1 goes inactive into the expansion agent before the expansion agent
receives a GNT# from ICH2, the expansion agent must pull its REQ# line high for 1clock and
resend the expansion channel passing information with only DMA channel 2 active. Note that
the ICH2 does not do anything special to catch this case because a DREQ going inactive
before a DACK# is received is not allowed in the ISA DMA protocol and, therefore, does not
need to work properly in this protocol either. This requirement is needed to be able to support
Plug-n-Play ISA devices that toggle DREQ# lines to determine if those lines are free in the
system.
3. If a PCI expansion agent has sent its serial request information and receives a new DMA
request before receiving GNT#, the agent must resend the serial request with the new request
active. For example, if a PCI expansion agent has already passed requests for DMA channel 1
and 2 and detects DREQ 3 active before a GNT is received, the device must pull its REQ# line
high for one clock and resend the expansion channel passing information with all three
channels active.
The three cases above require the following functionality in the PCI DMA expansion device:
• Drive REQ# inactive for one clock to signal new request information.
• Drive REQ# inactive for two clocks to signal that a request that had been granted the bus has
gone inactive.
• The REQ# and GNT# state machines must run independently and concurrently (i.e., a GNT#
could be received while in the middle of sending a serial REQ# or a GNT# could be active
while REQ# is inactive).
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-31
Functional Description
5.5.2
PCI DMA Expansion Cycles
ICH2’s support of the PC/PCI DMA Protocol currently consists of four types of cycles: Memoryto-I/O, I/O-to-Memory, Verify, and ISA Master cycles. ISA Masters are supported through the use
of a DMA channel that has been programmed for cascade mode.
The DMA controller does a two cycle transfer (a load followed by a store) as opposed to the ISA
"fly-by" cycle for PC/PCI DMA agents. The memory portion of the cycle generates a PCI memory
read or memory write bus cycle, its address representing the selected memory.
The I/O portion of the DMA cycle generates a PCI I/O cycle to one of four I/O addresses
(Table 5-11). Note that these cycles must be qualified by an active GNT# signal to the requesting
device.
Table 5-11. DMA Cycle vs. I/O Address
5.5.3
DMA Cycle Type
DMA I/O Address
PCI Cycle Type
Normal
00h
I/O Read/Write
Normal TC
04h
I/O Read/Write
Verify
0C0h
I/O Read
Verify TC
0C4h
I/O Read
DMA Addresses
The memory portion of the cycle generates a PCI memory read or memory write bus cycle; its
address representing the selected memory. The I/O portion of the DMA cycle generates a PCI
I/O cycle to one of the four I/O addresses listed in Table 5-11.
5.5.4
DMA Data Generation
The data generated by PC/PCI devices on I/O reads when they have an active GNT# is on the lower
two bytes of the PCI AD bus. Table 5-12 lists the PCI pins that the data appears for 8 and 16 bit
channels. Each I/O read results in one memory write and each memory read results in one I/O
write. If the I/O device is 8 bit, the ICH2 performs an 8 bit memory write. The ICH2 does not
assemble the I/O read into a DWord for writing to memory. Similarly, the ICH2 does not
disassemble a DWord read from memory to the I/O device.
Table 5-12. PCI Data Bus vs. DMA I/O Port Size
PCI DMA I/O Port Size
5-32
PCI Data Bus Connection
Byte
AD[7:0]
Word
AD[15:0]
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.5.5
DMA Byte Enable Generation
The byte enables generated by the ICH2 on I/O reads and writes must correspond to the size of the
I/O device. Table 5-13 defines the byte enables asserted for 8 and 16 bit DMA cycles.
Table 5-13. DMA I/O Cycle Width vs. BE[3:0]#
BE[3:0]#
Description
1110b
8-bit DMA I/O Cycle: Channels 0-3
1100b
16-bit DMA I/O Cycle: Channels 5-7
NOTE: For verify cycles, the value of the Byte Enables (BEs) are a “don’t care”.
5.5.6
DMA Cycle Termination
DMA cycles are terminated when a terminal count is reached in the DMA controller and the
channel is not in autoinitialize mode or when the PC/PCI device deasserts its request. The PC/PCI
device must follow explicit rules when deasserting its request or the ICH2 may not see it in time
and run an extra I/O and memory cycle.
The PC/PCI device must deassert its request 7 PCICLKs before it generates TRDY# on the I/O
read or write cycle or the ICH2 is allowed to generate another DMA cycle. For transfers to
memory, this means that the memory portion of the cycle will be run without an asserted PC/PCI
REQ#.
5.5.7
LPC DMA
DMA on LPC is handled through the use of the LDRQ# lines from peripherals and special
encodings on LAD[3:0] from the host. Single, Demand, Verify, and Increment modes are supported
on the LPC interface. Channels 0–3 are 8 bit channels. Channels 5–7 are 16 bit channels. Channel 4
is reserved as a generic bus master request.
5.5.8
Asserting DMA Requests
Peripherals that need DMA service encode their requested channel number on the LDRQ# signal.
To simplify the protocol, each peripheral on the LPC I/F has its own dedicated LDRQ# signal (they
may not be shared between two separate peripherals). The ICH2 has two LDRQ# inputs, allowing
at least two devices to support DMA or bus mastering.
LDRQ# is synchronous with LCLK (PCI clock). As shown in Figure 5-11 the peripheral uses the
following serial encoding sequence:
• Peripheral starts the sequence by asserting LDRQ# low (start bit). LDRQ# is high during idle
conditions.
• The next 3 bits contain the encoded DMA channel number (MSB first).
• The next bit (ACT) indicates whether the request for the indicated DMA channel is active or
inactive. The ACT bit will be a 1 (high) to indicate if it is active and 0 (low) if it is inactive.
The case where ACT is low will be rare, and is only used to indicate that a previous request for
that channel is being abandoned.
• After the active/inactive indication, the LDRQ# signal must go high for at least 1 clock. After
that one clock, LDRQ# signal can be brought low to the next encoding sequence.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-33
Functional Description
If another DMA channel also needs to request a transfer, another sequence can be sent on LDRQ#.
For example, if an encoded request is sent for channel 2 and then channel 3 needs a transfer before
the cycle for channel 2 is run on the interface, the peripheral can send the encoded request for
channel 3. This allows multiple DMA agents behind an I/O device to request use of the LPC
interface and the I/O device does not need to self-arbitrate before sending the message.
Figure 5-11. DMA Request Assertion Through LDRQ#
LCLK
LDRQ#
5.5.9
Start
MSB
LSB
ACT
Start
Abandoning DMA Requests
DMA requests can be deasserted in two fashions: on error conditions by sending an LDRQ#
message with the ‘ACT’ bit set to 0, or normally through a SYNC field during the DMA transfer.
This section describes boundary conditions where the DMA request needs to be removed prior to a
data transfer.
There may be some special cases where the peripheral desires to abandon a DMA transfer. The
most likely case of this occurring is due to a floppy disk controller that has overrun or underrun its
FIFO, or software stopping a device prematurely.
In these cases, the peripheral wishes to stop further DMA activity. It may do so by sending an
LDRQ# message with the ACT bit as 0. However, since the DMA request was seen by the ICH2,
there is no guarantee that the cycle has not been granted and will shortly run on LPC. Therefore,
peripherals must take into account that a DMA cycle may still occur. The peripheral can choose not
to respond to this cycle, in which case the host aborts it or the host can choose to complete the
cycle normally with any random data.
This method of DMA deassertion should be prevented when possible to limit boundary conditions
both on the ICH2 and the peripheral.
5-34
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.5.10
General Flow of DMA Transfers
Arbitration for DMA channels is performed through the 8237 within the host. Once the host has
won arbitration on behalf of a DMA channel assigned to LPC, it asserts LFRAME# on the LPC I/F
and begins the DMA transfer. The general flow for a basic DMA transfer is as follows:
1. ICH2 starts transfer by asserting 0000b on LAD[3:0] with LFRAME# asserted.
2. ICH2 asserts ‘cycle type’ of DMA, direction based on DMA transfer direction.
3. ICH2 asserts channel number and, if applicable, terminal count.
4. ICH2 indicates the size of the transfer: 8 or 16 bits.
5. If a DMA read,
— The ICH2 drives the first 8 bits of data and turns the bus around.
— The peripheral acknowledges the data with a valid SYNC.
— If a 16 bit transfer, the process is repeated for the next 8 bits.
6. If a DMA write,
— The ICH2 turns the bus around and waits for data.
— The peripheral indicates data ready through SYNC and transfers the first byte.
— If a 16 bit transfer, the peripheral indicates data ready and transfers the next byte.
7. The peripheral turns around the bus.
5.5.11
Terminal Count
Terminal count is communicated through LAD[3] on the same clock that DMA channel is
communicated on LAD[2:0]. This field is the CHANNEL field. Terminal count indicates the last
byte of transfer, based upon the size of the transfer.
For example, on an 8-bit transfer size (SIZE field is 00b), if the TC bit is set, this is the last byte.
On a 16-bit transfer (SIZE field is 01b), if the TC bit is set, the second byte is the last byte.
Therefore, the peripheral must internalize the TC bit when the CHANNEL field is communicated
and only signal TC when the last byte of that transfer size has been transferred.
5.5.12
Verify Mode
Verify mode is supported on the LPC interface. A verify transfer to the peripheral is similar to a
DMA write where the peripheral is transferring data to main memory. The indication from the host
is the same as a DMA write, so the peripheral will be driving data onto the LPC interface.
However, the host does not transfer this data into main memory.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-35
Functional Description
5.5.13
DMA Request Deassertion
An end of transfer is communicated to the ICH2 through a special SYNC field transmitted by the
peripheral. An LPC device must not attempt to signal the end of a transfer by deasserting
LDREQ#. If a DMA transfer is several bytes (e.g., a transfer from a demand mode device), the
ICH2 needs to know when to deassert the DMA request based on the data currently being
transferred.
The DMA agent uses a SYNC encoding on each byte of data being transferred which indicates to
the ICH2 whether this is the last byte of transfer or if more bytes are requested. To indicate the last
byte of transfer, the peripheral uses a SYNC value of 0000b (ready with no error), or ‘1010b’
(ready with error). These encodings tell the ICH2 that this is the last piece of data transferred on a
DMA read (ICH2 to peripheral), or the byte which follows is the last piece of data transferred on a
DMA write (peripheral to ICH2).
When the ICH2 sees one of these two encodings, it ends the DMA transfer after this byte and
deasserts the DMA request to the 8237. Therefore, if the ICH2 indicated a 16 bit transfer, the
peripheral can end the transfer after one byte by indicating a SYNC value of 0000b or 1010b. The
ICH2 will not attempt to transfer the second byte, and will deassert the DMA request internally.
If the peripheral indicates a 0000b or 1010b SYNC pattern on the last byte of the indicated size,
then the ICH2 will only deassert the DMA request to the 8237 since it does not need to end the
transfer.
If the peripheral wishes to keep the DMA request active, it uses a SYNC value of 1001b (ready
plus more data). This indicates to the 8237 that more data bytes are requested after the current byte
has been transferred; the ICH2 keeps the DMA request active to the 8237. Therefore, on an 8-bit
transfer size, if the peripheral indicates a SYNC value of 1001b to the ICH2, the data will be
transferred and the DMA request remains active to the 8237. At a later time, the ICH2 will then
come back with another START - CYCTYPE - CHANNEL - SIZE etc. combination to initiate
another transfer to the peripheral.
The peripheral must not assume that the next START indication from the ICH2 is another grant to
the peripheral if it had indicated a SYNC value of 1001b. On a single mode DMA device, the 8237
re-arbitrates after every transfer. Only demand mode DMA devices can be guaranteed that they will
receive the next START indication from the ICH2.
5-36
Note:
Indicating a 0000b or ‘1010b’ encoding on the SYNC field of an odd byte of a 16 bit channel (first
byte of a 16 bit transfer) is an error condition.
Note:
The host stops the transfer on the LPC bus as indicated, fill the upper byte with random data on
DMA writes (peripheral to memory), and indicates to the 8237 that the DMA transfer occurred,
incrementing the 8237’s address and decrementing its byte count.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.5.14
SYNC Field / LDRQ# Rules
Since DMA transfers on LPC are requested through an LDRQ# assertion message and are ended
through a SYNC field during the DMA transfer, the peripheral must obey the following rule when
initiating back-to-back transfers from a DMA channel.
The peripheral must not assert another message for 8 LCLKs after a deassertion is indicated
through the SYNC field. This is needed to allow the 8237, which typically runs off a much slower
internal clock, to see a message deasserted before it is re-asserted so that it can arbitrate to the next
agent.
Under default operation, the host will only perform 8-bit transfers on 8-bit channels and 16-bit
transfers on 16-bit channels.
The method by which this communication between host and peripheral through system BIOS is
performed is beyond the scope of this specification. Since the LPC host and LPC peripheral are
motherboard devices, no “plug-n-play” registry is required.
The peripheral must not assume that the host will be able to perform transfer sizes that are larger
than the size allowed for the DMA channel and be willing to accept a SIZE field that is smaller
than what it may currently have buffered.
To that end, it is recommended that future devices which may appear on the LPC bus, which
require higher bandwidth than 8 bit or 16 bit DMA allow, do so with a bus mastering interface and
not rely on the 8237.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-37
Functional Description
5.6
8254 Timers (D31:F0)
The ICH2 contains three counters that have fixed uses. All registers and functions associated with
the 8254 timers are in the Core well. The 8254 unit is clocked by a 14.31818 MHz clock.
Counter 0, System Timer
This counter functions as the system timer by controlling the state of IRQ0 and is typically
programmed for Mode 3 operation. The counter produces a square wave with a period equal to the
product of the counter period (838 ns) and the initial count value. The counter loads the initial
count value one counter period after software writes the count value to the counter I/O address. The
counter initially asserts IRQ0 and decrements the count value by two each counter period. The
counter negates IRQ0 when the count value reaches 0. It then reloads the initial count value and
again decrements the initial count value by two each counter period. The counter then asserts IRQ0
when the count value reaches 0, reloads the initial count value, and repeats the cycle; alternately
asserting and negating IRQ0.
Counter 1, Refresh Request Signal
This counter provides the refresh request signal and is typically programmed for Mode 2 operation.
The counter negates refresh request for one counter period (838 ns) during each count cycle. The
initial count value is loaded one counter period after being written to the counter I/O address. The
counter initially asserts refresh request and negates it for 1 counter period when the count value
reaches 1. The counter then asserts refresh request and continues counting from the initial count
value.
Counter 2, Speaker Tone
This counter provides the speaker tone and is typically programmed for Mode 3 operation. The
counter provides a speaker frequency equal to the counter clock frequency (1.193 MHz) divided by
the initial count value. The speaker must be enabled by a write to port 061h (see NMI Status and
Control ports).
5.6.1
Timer Programming
The counter/timers are programmed in the following fashion:
1. Write a control word to select a counter
2. Write an initial count for that counter.
3. Load the least and/or most significant bytes (as required by Control Word bits 5, 4) of the
16-bit counter.
4. Repeat with other counters
Only two conventions need to be observed when programming the counters. First, for each counter,
the control word must be written before the initial count is written. Second, the initial count must
follow the count format specified in the control word (least significant byte only, most significant
byte only, or least significant byte and then most significant byte).
A new initial count may be written to a counter at any time without affecting the counter's
programmed mode. Counting is affected as described in the mode definitions. The new count must
follow the programmed count format.
Caution:
5-38
If a counter is programmed to read/write two-byte counts, the following applies: A program must
not transfer control between writing the first and second byte to another routine which also writes
into that same counter. Otherwise, the counter will be loaded with an incorrect count.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
The Control Word Register at port 43h controls the operation of all three counters. Several
commands are available:
• Control Word Command. Specifies which counter to read or write, the operating mode, and
the count format (binary or BCD).
• Counter Latch Command. Latches the current count so that it can be read by the system. The
countdown process continues.
• Read Back Command. Reads the count value, programmed mode, the current state of the
OUT pins, and the state of the Null Count Flag of the selected counter.
Table 5-14 lists the six operating modes for the interval counters.
Table 5-14. Counter Operating Modes
Mode
5.6.2
Function
Description
0
Out signal on end of count (=0)
Output is 0’. When count goes to 0, output goes to 1’ and
stays at 1’ until counter is reprogrammed.
1
Hardware retriggerable one-shot
Output is 0’. When count goes to 0, output goes to 1’ for
one clock time.
2
Rate generator (divide by n counter)
Output is 1’. Output goes to 0’ for one clock time, then
back to 1’ and counter is reloaded.
3
Square wave output
Output is 1’. Output goes to 0’ when counter rolls over,
and counter is reloaded. Output goes to 1’ when counter
rolls over, and counter is reloaded, etc.
4
Software triggered strobe
Output is 1’. Output goes to 0’ when count expires for one
clock time.
5
Hardware triggered strobe
Output is 1’. Output goes to 0’ when count expires for one
clock time.
Reading from the Interval Timer
It is often desirable to read the value of a counter without disturbing the count in progress. There
are three methods for reading the counters: a simple read operation, counter Latch Command, and
the Read-Back Command. Each is explained below.
With the simple read and counter latch command methods, the count must be read according to the
programmed format; specifically, if the counter is programmed for two byte counts, two bytes must
be read. The two bytes do not have to be read one right after the other. Read, write, or programming
operations for other counters may be inserted between them.
Simple Read
The first method is to perform a simple read operation. The counter is selected through port 40h
(counter 0), 41h (counter 1), or 42h (counter 2).
Note:
Performing a direct read from the counter will not return a determinate value because the counting
process is asynchronous to read operations. However, in the case of counter 2, the count can be
stopped by writing to the GATE bit in port 61h.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-39
Functional Description
Counter Latch Command
The Counter Latch Command, written to port 43h, latches the count of a specific counter at the
time the command is received. This command is used to ensure that the count read from the counter
is accurate, particularly when reading a two-byte count. The count value is then read from each
counter's Count Register as was programmed by the Control Register.
The count is held in the latch until it is read or the counter is reprogrammed. The count is then
unlatched. This allows reading the contents of the counters on the fly without affecting counting in
progress. Multiple Counter Latch Commands may be used to latch more than one counter. Counter
Latch Commands do not affect the programmed mode of the counter.
If a Counter is latched and then, some time later, latched again before the count is read, the second
Counter Latch Command is ignored. The count read will be the count at the time the first Counter
Latch Command was issued.
Read Back Command
The Read Back Command, written to port 43h, latches the count value, programmed mode, and
current states of the OUT pin and Null Count flag of the selected counter or counters. The value of
the counter and its status may then be read by I/O access to the counter address.
The Read Back Command may be used to latch multiple counter outputs at one time. This single
command is functionally equivalent to several counter latch commands, one for each counter
latched. Each counter's latched count is held until it is read or reprogrammed. Once read, a counter
is unlatched. The other counters remain latched until they are read. If multiple count Read Back
Commands are issued to the same counter without reading the count, all but the first are ignored.
The Read Back Command may additionally be used to latch status information of selected
counters. The status of a counter is accessed by a read from that counter's I/O port address. If
multiple counter status latch operations are performed without reading the status, all but the first
are ignored.
Both count and status of the selected counters may be latched simultaneously. This is functionally
the same as issuing two consecutive, separate Read Back Commands. If multiple count and/or
status Read Back Commands are issued to the same counters without any intervening reads, all but
the first are ignored.
If both count and status of a counter are latched, the first read operation from that counter will
return the latched status, regardless of which was latched first. The next one or two reads,
depending on whether the counter is programmed for one or two type counts, return the latched
count. Subsequent reads return unlatched count.
5-40
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.7
8259 Interrupt Controllers (PIC) (D31:F0)
The ICH2 incorporates the functionality of two 8259 interrupt controllers that provide system
interrupts for the ISA compatible interrupts. These interrupts are: system timer, keyboard
controller, serial ports, parallel ports, floppy disk, IDE, mouse, and DMA channels. In addition,
this interrupt controller can support the PCI-based interrupts, by mapping the PCI interrupt onto the
compatible ISA interrupt line. Each 8259 core supports 8 interrupts, numbered 0–7. Table 5-15
shows how the cores are connected.
.
Table 5-15. Interrupt Controller Core Connections
8259
8259
Input
Typical Interrupt
Source
0
Internal
1
Keyboard
Connected Pin / Function
Internal Timer / Counter 0 output
IRQ1 via SERIRQ
2
Internal
3
Serial Port A
Slave Controller INTR output
IRQ3 via SERIRQ
4
Serial Port B
IRQ4 via SERIRQ
5
Parallel Port / Generic
IRQ5 via SERIRQ
6
Floppy Disk
IRQ6 via SERIRQ
7
Parallel Port / Generic
IRQ7 via SERIRQ
0
Internal Real Time Clock
1
Generic
2
Generic
IRQ10 via SERIRQ
3
Generic
IRQ11 via SERIRQ
4
PS/2 Mouse
IRQ12 via SERIRQ
5
Internal
6
Primary IDE cable
IRQ14 from input signal or via SERIRQ
7
Secondary IDE Cable
IRQ15 from input signal or via SERIRQ
Master
Slave
Internal RTC
IRQ9 via SERIRQ
State Machine output based on processor FERR#
assertion.
The ICH2 cascades the slave controller onto the master controller through master controller
interrupt input 2. This means there are only 15 possible interrupts for the ICH2 PIC. Interrupts can
individually be programmed to be edge or level, except for IRQ[0, 2, 8#, 13].
Note that previous PIIXn devices internally latched IRQ[12 and 1] and required a port 60h read to
clear the latch. The ICH2 can be programmed to latch IRQ[12 or 1] (see bit 11 and bit 12 in
General Control Register, D31:F0, offset D0h).
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-41
Functional Description
5.7.1
Interrupt Handling
5.7.1.1
Generating Interrupts
The PIC interrupt sequence involves three bits, from the IRR, ISR, and IMR for each interrupt
level. These bits are used to determine the interrupt vector returned, and status of any other pending
interrupts. Table 5-16 defines the IRR, ISR, and IMR.
Table 5-16. Interrupt Status Registers
5.7.1.2
Bit
Description
IRR
Interrupt Request Register. This bit is set on a low-to-high transition of the interrupt line in edge
mode and by an active high level in level mode. This bit is set whether or not the interrupt is masked.
However, a masked interrupt will not generate INTR.
ISR
Interrupt Service Register. This bit is set, and the corresponding IRR bit cleared, when an interrupt
acknowledge cycle is seen and the vector returned is for that interrupt.
IMR
Interrupt Mask Register. This bit determines whether an interrupt is masked. Masked interrupts will
not generate INTR.
Acknowledging Interrupts
The processor generates an interrupt acknowledge cycle that is translated by the host bridge into a
PCI Interrupt Acknowledge Cycle to the ICH2. The PIC translates this command into two internal
INTA# pulses expected by the 8259 cores. The PIC uses the first internal INTA# pulse to freeze the
state of the interrupts for priority resolution. On the second INTA# pulse, the master or slave sends
the interrupt vector to the processor with the acknowledged interrupt code. This code is based on
bits [7:3] of the corresponding ICW2 register combined with three bits representing the interrupt
within that controller.
Table 5-17. Content of Interrupt Vector Byte
Master,Slave Interrupt
Bits [7:3]
IRQ[7,15]
Bits [2:0]
111
IRQ[6,14]
110
IRQ[5,13]
101
IRQ[4,12]
100
ICW2[7:3]
5-42
IRQ[3,11]
011
IRQ[2,10]
010
IRQ[1,9]
001
IRQ[0,8]
000
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.7.1.3
Hardware/Software Interrupt Sequence
1. One or more of the Interrupt Request lines (IRQ) are raised high in edge mode, or seen high in
level mode, setting the corresponding IRR bit.
2. The PIC sends INTR active to the processor if an asserted interrupt is not masked.
3. The processor acknowledges the INTR and responds with an interrupt acknowledge cycle. The
cycle is translated into a PCI interrupt acknowledge cycle by the host bridge. This command is
broadcast over PCI by the ICH2.
4. Upon observing its own interrupt acknowledge cycle on PCI, the ICH2 converts it into the two
cycles that the internal 8259 pair can respond. Each cycle appears as an interrupt acknowledge
pulse on the internal INTA# pin of the cascaded interrupt controllers.
5. Upon receiving the first internally generated INTA# pulse, the highest priority ISR bit is set
and the corresponding IRR bit is reset. On the trailing edge of the first pulse a slave
identification code is broadcast by the master to the slave on a private, internal three bit wide
bus. The slave controller uses these bits to determine if it must respond with an interrupt vector
during the second INTA# pulse.
6. Upon receiving the second internally generated INTA# pulse, the PIC returns the interrupt
vector. If no interrupt request is present because the request was too short in duration, the PIC
will return vector 7 from the master controller.
7. This completes the interrupt cycle. In AEOI mode the ISR bit is reset at the end of the second
INTA# pulse. Otherwise, the ISR bit remains set until an appropriate EOI command is issued
at the end of the interrupt subroutine.
5.7.2
Initialization Command Words (ICWx)
Before the operation can begin, each 8259 must be initialized. In the ICH2 this is a four-byte
sequence. The four initialization command words are referred to by their acronyms: ICW1, ICW2,
ICW3, and ICW4.
The base address for each 8259 initialization command word is a fixed location in the I/O memory
space: 20h for the master controller and A0h for the slave controller.
ICW1
An I/O write to the master or slave controller base address with data bit 4 equal to 1 is interpreted
as a write to ICW1. Upon sensing this write, the ICH2 PIC expects three more byte writes to 21h
for the master controller, or A1h for the slave controller, to complete the ICW sequence.
A write to ICW1 starts the initialization sequence during which the following automatically occur:
1. Following initialization, an interrupt request (IRQ) input must make a low-to-high transition to
generate an interrupt.
2. The Interrupt Mask Register is cleared.
3. IRQ7 input is assigned priority 7.
4. The slave mode address is set to 7.
5. Special Mask Mode is cleared and Status Read is set to IRR.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-43
Functional Description
ICW2
The second write in the sequence (ICW2) is programmed to provide bits 7:3 of the interrupt vector
that will be released during an interrupt acknowledge. A different base is selected for each interrupt
controller.
ICW3
The third write in the sequence (ICW3) has a different meaning for each controller.
• For the master controller, ICW3 is used to indicate which IRQ input line is used to cascade the
slave controller. Within the ICH2, IRQ2 is used. Therefore, bit 2 of ICW3 on the master
controller is set to a 1 and the other bits are set to 0s.
• For the slave controller, ICW3 is the slave identification code used during an interrupt
acknowledge cycle. On interrupt acknowledge cycles, the master controller broadcasts a code
to the slave controller if the cascaded interrupt won arbitration on the master controller. The
slave controller compares this identification code to the value stored in its ICW3, and if it
matches, the slave controller assumes responsibility for broadcasting the interrupt vector.
ICW4
The final write in the sequence (ICW4) must be programmed both controllers. At the very least, bit
0 must be set to a 1 to indicate that the controllers are operating in an Intel Architecture-based
system.
5.7.3
Operation Command Words (OCW)
These command words reprogram the Interrupt Controller to operate in various interrupt modes.
• OCW1 masks and unmasks interrupt lines.
• OCW2 controls the rotation of interrupt priorities when in rotating priority mode and controls
the EOI function.
• OCW3 is sets up ISR/IRR reads, enables/disables the Special Mask Mode SMM and enables/
disables polled interrupt mode.
5-44
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.7.4
Modes of Operation
Fully Nested Mode
In this mode, interrupt requests are ordered in priority from 0 through 7, with 0 being the highest.
When an interrupt is acknowledged, the highest priority request is determined and its vector placed
on the bus. Additionally, the ISR for the interrupt is set. This ISR bit remains set until: the
processor issues an EOI command immediately before returning from the service routine; or if in
AEOI mode, on the trailing edge of the second INTA#. While the ISR bit is set, all further
interrupts of the same or lower priority are inhibited; higher levels will generate another interrupt.
Interrupt priorities can be changed in the rotating priority mode.
Special Fully Nested Mode
This mode will be used in the case of a system where cascading is used and the priority has to be
conserved within each slave. In this case, the special fully nested mode will be programmed to the
master controller. This mode is similar to the fully nested mode with the following exceptions:
• When an interrupt request from a certain slave is in service, this slave is not locked out from
•
the master's priority logic and further interrupt requests from higher priority interrupts within
the slave will be recognized by the master and will initiate interrupts to the processor. In the
normal nested mode, a slave is masked out when its request is in service.
When exiting the Interrupt Service routine, software has to check whether the interrupt
serviced was the only one from that slave. This is done by sending a Non-Specific EOI
command to the slave and then reading its ISR. If it is 0, a non-specific EOI can also be sent to
the master.
Automatic Rotation Mode (Equal Priority Devices)
In some applications there are a number of interrupting devices of equal priority. Automatic
rotation mode provides for a sequential 8-way rotation. In this mode a device receives the lowest
priority after being serviced. In the worst case a device requesting an interrupt will have to wait
until each of seven other devices are serviced at most once.
There are two ways to accomplish automatic rotation using OCW2; the Rotation on Non-Specific
EOI Command (R=1, SL=0, EOI=1) and the Rotate in Automatic EOI Mode which is set by
(R=1, SL=0, EOI=0).
Specific Rotation Mode (Specific Priority)
Software can change interrupt priorities by programming the bottom priority. For example, if IRQ5
is programmed as the bottom priority device, IRQ6 will be the highest priority device. The Set
Priority Command is issued in OCW2 to accomplish this, where: R=1, SL=1, and LO-L2 is the
binary priority level code of the bottom priority device.
In this mode, internal status is updated by software control during OCW2. However, it is
independent of the EOI command. Priority changes can be executed during an EOI command by
using the Rotate on Specific EOI Command in OCW2 (R=1, SL=1, EOI=1 and LO–L2=IRQ level
to receive bottom priority.
Poll Mode
Poll Mode can be used to conserve space in the interrupt vector table. Multiple interrupts that can
be serviced by one interrupt service routine do not need separate vectors if the service routine uses
the poll command. Polled Mode can also be used to expand the number of interrupts. The polling
interrupt service routine can call the appropriate service routine, instead of providing the interrupt
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-45
Functional Description
vectors in the vector table. In this mode, the INTR output is not used and the microprocessor
internal Interrupt Enable flip-flop is reset, disabling its interrupt input. Service to devices is
achieved by software using a Poll Command.
The Poll command is issued by setting P=1 in OCW3. The PIC treats its next I/O read as an
interrupt acknowledge, sets the appropriate ISR bit if there is a request, and reads the priority level.
Interrupts are frozen from the OCW3 write to the I/O read. The byte returned during the I/O read
will contain a 1’ in bit 7 if there is an interrupt, and the binary code of the highest priority level in
bits 2:0.
Cascade Mode
The PIC in the ICH2 has one master 8259 and one slave 8259 cascaded onto the master through
IRQ2. This configuration can handle up to 15 separate priority levels. The master controls the
slaves through a 3-bit internal bus. In the ICH2, when the master drives 010b on this bus, the slave
controller takes responsibility for returning the interrupt vector. An EOI Command must be issued
twice: once for the master and once for the slave.
Edge-Triggered and Level-Triggered Mode
In ISA systems this mode is programmed using bit 3 in ICW1, which sets level or edge for the
entire controller. In the ICH2, this bit is disabled and a new register for edge-triggered and leveltriggered mode selection, per interrupt input, is included. This is the Edge/Level control Registers
ELCR1 and ELCR2.
If an ELCR bit is 0’, an interrupt request will be recognized by a low to high transition on the
corresponding IRQ input. The IRQ input can remain high without generating another interrupt. If
an ELCR bit is 1’, an interrupt request will be recognized by a high level on the corresponding IRQ
input and there is no need for an edge detection. The interrupt request must be removed before the
EOI command is issued to prevent a second interrupt from occurring.
In both the edge-triggered and level-triggered modes, the IRQ inputs must remain active until after
the falling edge of the first internal INTA#. If the IRQ input goes inactive before this time, a default
IRQ7 vector will be returned.
End of Interrupt Operations
An EOI can occur in one of two fashions: by a command word write issued to the PIC before
returning from a service routine, the EOI command; or automatically when AEOI bit in ICW4 is
set to 1.
Normal End of Interrupt
In Normal EOI, software writes an EOI command before leaving the interrupt service routine to
mark the interrupt as completed. There are two forms of EOI commands: Specific and NonSpecific. When a Non-Specific EOI command is issued, the PIC will clear the highest ISR bit of
those that are set to 1. Non-Specific EOI is the normal mode of operation of the PIC within the
ICH2, as the interrupt being serviced currently is the interrupt entered with the interrupt
acknowledge. When the PIC is operated in modes which preserve the fully nested structure,
software can determine which ISR bit to clear by issuing a Specific EOI. An ISR bit that is masked
will not be cleared by a Non-Specific EOI if the PIC is in the Special Mask Mode. An EOI
command must be issued for both the master and slave controller.
Automatic End of Interrupt Mode
In this mode, the PIC will automatically perform a Non-Specific EOI operation at the trailing edge
of the last interrupt acknowledge pulse. From a system standpoint, this mode should be used only
when a nested multi-level interrupt structure is not required within a single PIC. The AEOI mode
can only be used in the master controller and not the slave controller.
5-46
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.7.5
Masking Interrupts
Masking on an Individual Interrupt Request
Each interrupt request can be masked individually by the Interrupt Mask Register (IMR). This
register is programmed through OCW1. Each bit in the IMR masks one interrupt channel. Masking
IRQ2 on the master controller will mask all requests for service from the slave controller.
Special Mask Mode
Some applications may require an interrupt service routine to dynamically alter the system priority
structure during its execution under software control. For example, the routine may wish to inhibit
lower priority requests for a portion of its execution but enable some of them for another portion.
The Special Mask Mode enables all interrupts not masked by a bit set in the Mask Register.
Normally, when an interrupt service routine acknowledges an interrupt without issuing an EOI to
clear the ISR bit, the interrupt controller inhibits all lower priority requests. In the Special Mask
Mode, any interrupts may be selectively enabled by loading the Mask Register with the appropriate
pattern. The special Mask Mode is set by OCW3 where: SSMM=1, SMM=1, and cleared where
SSMM=1, SMM=0.
5.7.6
Steering PCI Interrupts
The ICH2 can be programmed to allow PIRQA#–PIRQH# to be internally routed to interrupts
[3:7, 9:12, 14 or 15]. The assignment is programmable through the PIRQx Route Control registers,
located at 60–63h and 68–6Bh in function 0. One or more PIRQx# lines can be routed to the same
IRQx input. If interrupt steering is not required, the Route Registers can be programmed to disable
steering.
The PIRQx# lines are defined as active low, level sensitive to allow multiple interrupts on a PCI
Board to share a single line across the connector. When a PIRQx# is routed to specified IRQ line,
software must change the IRQ's corresponding ELCR bit to level sensitive mode. The ICH2 will
internally invert the PIRQx# line to send an active high level to the PIC. When a PCI interrupt is
routed onto the PIC, the selected IRQ can no longer be used by an ISA device (through SERIRQ).
However, active low non-ISA interrupts can share their interrupt with PCI interrupts.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-47
Functional Description
5.8
Advanced Interrupt Controller (APIC) (D31:F0)
In addition to the standard ISA compatible interrupt controller (PIC) described in the previous
section, the ICH2 incorporates the Advanced Programmable Interrupt Controller (APIC). While
the standard interrupt controller is intended for use in a uni-processor system, APIC can be used in
either a uni-processor or multi-processor system.
5.8.1
Interrupt Handling
The I/O APIC handles interrupts very differently than the 8259. Briefly, these differences are:
• Method of Interrupt Transmission. The I/O APIC transmits interrupts through a 3-wire bus
and interrupts are handled without the need for the processor to run an interrupt acknowledge
cycle.
• Interrupt Priority. The priority of interrupts in the I/O APIC is independent of the interrupt
number. For example, interrupt 10 can be given a higher priority than interrupt 3.
• More Interrupts. The I/O APIC in the ICH2 supports a total of 24 interrupts.
• Multiple Interrupt Controllers. The I/O APIC interrupt transmission protocol has an
arbitration phase that allows for multiple I/O APICs in the system with their own interrupt
vectors. The ICH2 I/O APIC must arbitrate for the APIC bus before transmitting its interrupt
message.
5-48
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.8.2
Interrupt Mapping
The I/O APIC within the ICH2 supports 24 APIC interrupts. Each interrupt has its own unique
vector assigned by software. The interrupt vectors are mapped as follows and match “configuration
6” of the Multi-processor specification.
Table 5-18. APIC Interrupt Mapping
Via
SERIRQ
Direct from
pin
0
No
No
No
1
Yes
No
Yes
2
No
No
No
3
Yes
No
Yes
4
Yes
No
Yes
5
Yes
No
Yes
6
Yes
No
Yes
7
Yes
No
Yes
IRQ #
Via PCI
message
Internal Modules
Cascade from 8259 #1
8254 Counter 0
8
No
No
No
RTC
9
Yes
No
Yes
Option for SCI, TCO
10
Yes
No
Yes
Option for SCI, TCO
11
Yes
No
Yes
Option for SCI, TCO
12
Yes
No
Yes
13
No
No
No
14
Yes
Yes
Yes
15
Yes
Yes
Yes
16
PIRQA
PIRQA
No
17
PIRQB
PIRQB
No
18
PIRQC
PIRQC
No
19
PIRQD
PIRQD
No
20
N/A
PIRQE
Yes
LAN, option for SCI, TCO
21
N/A
PIRQF
Yes
Option for SCI, TCO
22
N/A
PIRQG
Yes
Option for SCI, TCO
23
N/A
PIRQH
Yes
USB #2, option for SCI, TCO
82801BA ICH2 and 82801BAM ICH2-M Datasheet
FERR# logic
AC’97 Audio, Modem, option for SMbus
USB #1
5-49
Functional Description
5.8.3
APIC Bus Functional Description
5.8.3.1
Physical Characteristics of APIC
The APIC bus is a 3-wire synchronous bus connecting all I/O and local APICs. Two of these wires
are used for data transmission and one wire is a clock. For bus arbitration, the APIC uses only one
of the data wires. The bus is logically a wire-OR and electrically an open-drain connection
providing for both bus use arbitration and arbitration for lowest priority. The APIC bus speed can
run from 16.67 MHz to 33 MHz.
5.8.3.2
APIC Bus Arbitration
The I/O APIC uses one wire arbitration to win bus ownership. A rotating priority scheme is used
for APIC bus arbitration. The winner of the arbitration becomes the lowest priority agent and
assumes an arbitration ID of 0. All other agents, except the agent whose arbitration ID is 15,
increment their Arbitration IDs by one. The agent whose ID was 15 will take the winner's
arbitration ID and will increment it by one. Arbitration IDs are changed only for messages that are
transmitted successfully (except for the Low Priority messages). A message is transmitted
successfully if no CS error or acceptance error was reported for that message.
An APIC agent can use two different priority schemes: Normal or EOI. EOI has the highest
priority. EOI priority is used to send EOI messages for level interrupts from a local APIC to an I/O
APIC. When an agent requests the bus with EOI priority, all other agents requesting the bus with
normal priorities will back off.
When ICH2 detects a bus idle condition on the APIC Bus and it has an interrupt to send over the
APIC bus, it drives a start cycle to begin arbitration, by driving bit 0 to a ‘0’ on an APICCLK rising
edge. It then samples bit 1. If Bit 1 was a ‘0’, then a local APIC started arbitration for an EOI
message on the same clock edge that the ICH2 started arbitration. Thus, the ICH2 has lost
arbitration and stops driving the APIC bus.
If the ICH2 did not detect an EOI message start, it will start transferring its arbitration ID, located
in bits [27:24] of its Arbitration ID register (ARBID). Starting in Cycle 2 through Cycle 5, it will
tri-state bit 0, and drive bit 1 to a ‘0’ if ARBID[27] is a ‘1’. If ARBID[27] is a ‘0’, it will also tristate bit 1. At the end of each cycle, the ICH2 samples the state of Bit 1 on the APIC bus. If the
ICH2 did not drive Bit 1 (ARBID[27] = ‘0’) and it samples a ‘0’, then another APIC agent started
arbitration for the APIC bus at the same time as the ICH2, and it has higher priority. The ICH2 will
stop driving the APIC bus. Table 5-19 describes the arbitration cycles.
Table 5-19. Arbitration Cycles
5-50
Cycle
Bit 1
Bit 0
1
EOI
0
2
NOT (ARBID[27])
1
3
NOT (ARBID[26])
1
4
NOT (ARBID[25])
1
5
NOT (ARBID[24])
1
Comment
Bit 1 = 1: Normal, Bit 1 = 0: EOI
Arbitration ID. If ICH2 samples a different value than it sent, it
lost arbitration.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.8.3.3
Bus Message Formats
After bus arbitration, the winner is granted exclusive use of the bus and will drive its message.
APIC messages come in four formats determined by the delivery mode bits. These four messages
are of different length and are known by all APICs on the bus through the transmission of the
Delivery Mode bits.
Table 5-20. APIC Message Formats
Message
# of
Cycles
Delivery Mode
Bits
Comments
EOI
14
xxx
End of Interrupt transmission from Local APIC to I/O APIC
on Level interrupts. EOI is known by the EOI bit at the start
of arbitration.
Short
21
001, 010, 100,
101, 111
I/O APIC delivery on Fixed, NMI, SMI, Reset, ExtINT, and
Lowest Priority with focus processor messages.
Lowest Priority
33
001
Transmission of Lowest Priority interrupts when the status
field indicates that the processor does not have focus.
Remote Read
39
011
Message from one Local APIC to another to read registers.
EOI Message For Level-Triggered Interrupts
EOI messages are used by local APICs to send an EOI cycle occurring for a level-triggered
interrupt to an I/O APIC. This message is needed so that the I/O APIC can differentiate between a
new interrupt on the interrupt line versus the same interrupt on the interrupt line. The target of the
EOI is given by the local APIC through the transmission of the priority vector (V7 through V0) of
the interrupt. Upon receiving this message, the I/O APIC resets the Remote IRR bit for that
interrupt. If the interrupt signal is still active after the IRR bit is reset, the I/O APIC will treat it as a
new interrupt.
Table 5-21. EOI Message
Cycle
Bit 1
Bit 0
Comments
1
0
0
EOI message
2–5
ARBID
1
Arbitration ID
6
NOT(V7)
NOT(V6)
7
NOT(V5)
NOT(V4)
8
NOT(V3)
NOT(V2)
9
NOT(V1)
NOT(V0)
10
NOT(C1)
NOT(C0)
Interrupt vector bits V7 - V0 from redirection table
register
Check Sum from Cycles 6 - 9
11
1
1
12
NOT(A)
NOT(A)
Status Cycle 0
13
NOT(A1)
NOT(A1)
Status Cycle 1
14
1
1
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Postamble
Idle
5-51
Functional Description
Short Message
Short messages are used for the delivery of Fixed, NMI, SMI, Reset, ExtINT and Lowest Priority
with Focus processor interrupts. The delivery mode bits (M2-M0) specify the message. All short
messages take 21 cycles including the idle cycle.
Table 5-22. Short Message
Cycle
Bit 1
Bit 0
Comments
1
1
0
Normal Arbitration
2–5
ARBID
1
Arbitration ID
6
NOT(DM)
NOT(M2)
DM1 = Destination Mode from bit 11 of the redirection table
register
7
NOT(M1)
NOT(M0)
M2-M0 = Delivery Mode from bits 10:8 of the redirection table
register
8
NOT(L)
NOT(TM)
L = Level, TM = Trigger Mode
9
NOT(V7)
NOT(V6)
10
NOT(V5)
NOT(V4)
11
NOT(V3)
NOT(V2)
Interrupt vector bits V7–V0 from redirection table register
12
NOT(V1)
NOT(V0)
13
NOT(D7)
NOT(D6)
14
NOT(D5)
NOT(D4)
15
NOT(D3)
NOT(D2)
16
NOT(D1)
NOT(D0)
17
NOT(C1)
NOT(C0)
18
1
1
19
NOT(A)
NOT(A)
20
NOT(A1)
NOT(A1)
21
1
1
Destination field from bits 63:56 of redirection table register1
Checksum for Cycles 6–162
Postamble3
Status Cycle 0. See Table 5-23.
Status Cycle 1. See Table 5-23.
Idle
NOTES:
1. If DM is 0 (physical mode), then cycles 15 and 16 are the APIC ID and cycles 13 and 14 are sent as ‘1’. If DM
is 1 (logical mode), then cycles 13 through 16 are the 8-bit Destination field. The interpretation of the logical
mode 8-bit Destination field is performed by the local units using the Destination Format Register.
Shorthands of "all-incl-self" and "all-excl-self" both use Physical Destination mode and a destination field
containing APIC ID value of all ones. The sending APIC knows whether it should (incl) or should not (excl)
respond to its own message.
2. The checksum field is the cumulative add (mod 4) of all data bits (DM, M0-3, L, TM, V0-7,D0-7). The APIC
driving the message provides this checksum. This, in essence, is the lower two bits of an adder at the end of
the message.
3. This cycle allows all APICs to perform various internal computations based on the information contained in
the received message. One of the computations takes the checksum of the data received in cycles 6 through
16 and compares it with the value in cycle 18. If any APIC computes a different checksum than the one
passed in cycle 17, then that APIC will signal an error on the APIC bus (“00”) in cycle 19. If this happens, all
APICs will assume the message was never sent and the sender must try sending the message again, which
includes re-arbitrating for the APIC bus. In lowest priority delivery when the interrupt has a focus processor,
the focus processor will signal this by driving a “01” during cycle 19. This tells all the other APICs that the
interrupt has been accepted, the arbitration is preempted, and short message format is used. Cycle 19 and
20 indicates the status of the message (i.e., accepted, check sum error, retry or error). Table 5-23 shows the
status signal combinations and their meanings for all delivery modes.
5-52
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
Table 5-23. APIC Bus Status Cycle Definition
Delivery Mode
A
11
Comments
Checksum OK
A1
Comments
1x
Error
01
Accepted
00
Retry
Fixed, EOI
NMI, SMM, Reset,
ExtINT
10
Error
xx
01
Error
xx
00
Checksum Error
xx
11
Checksum OK
1x
Error
01
Accepted
00
Error
10
Error
xx
01
Error
xx
00
Checksum Error
xx
11
Checksum OK: No Focus
Processor
1x
Error
01
End and Retry
00
Go for Low Priority Arbitration
Lowest Priority
10
Error
xx
01
Checksum OK: Focus
Processor
xx
00
Checksum Error
xx
11
Checksum OK
xx
10
Error
xx
01
Error
xx
00
Checksum Error
xx
Remote Read
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-53
Functional Description
Lowest Priority without Focus Processor (FP) Message
This message format is used to deliver an interrupt in the lowest priority mode in which it does not
have a Focus Process. Cycles 1 through 21 for this message are same as for the short message
discussed above. Status cycle 19 identifies if there is a Focus processor (10) and a status value of
11 in cycle 20 indicates the need for lowest priority arbitration.
Table 5-24. Lowest Priority Message (Without Focus Processor)
Cycle
Bit 1
Bit 0
Comments
1
1
0
Normal Arbitration
Arbitration ID
2–5
ARBID
1
6
NOT(DM)
NOT(M2)
DM = Destination Mode from bit 11 of the redirection table register
7
NOT(M1)
NOT(M0)
M2-M0 = Delivery Mode from bits 10:8 of the redirection table
register
8
NOT(L)
NOT(TM)
L = Level, TM = Trigger Mode
9
NOT(V7)
NOT(V6)
10
NOT(V5)
NOT(V4)
11
NOT(V3)
NOT(V2)
12
NOT(V1)
NOT(V0)
13
NOT(D7)
NOT(D6)
14
NOT(D5)
NOT(D4)
15
NOT(D3)
NOT(D2)
16
NOT(D1)
NOT(D0)
17
NOT(C1)
NOT(C0)
Interrupt vector bits V7–V0 from redirection table register
Destination field from bits 63:56 of redirection table register
Checksum for Cycles 6–16
18
1
1
19
NOT(A)
NOT(A)
Postamble
Status Cycle 0.
20
NOT(A1)
NOT(A1)
Status Cycle 1.
21
P7
1
22
P6
1
23
P5
1
24
P4
1
25
P3
1
26
P2
1
27
P1
1
28
P0
1
29
ArbID3
1
30
ArbID2
1
31
ArbID1
1
32
ArbID0
1
33
S
S
Status
34
1
1
Idle
Inverted Processor Priority P7–P0
NOTES:
1. Cycle 21 through 28 are used to arbitrate for the lowest priority processor. The processor that takes part in
the arbitration drives the processor priority on the bus. Only the local APICs that have "free interrupt slots" will
participate in the lowest priority arbitration.
2. Cycles 29 through 32 are used to break tie in case two more processors have lowest priority. The bus
arbitration IDs are used to break the tie.
5-54
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
Remote Read Message
Remote read message is used when a local APIC wishes to read the register in another local APIC.
The message format is same as short message for the first 21 cycles.
Table 5-25. Remote Read Message
Cycle
Bit 1
Bit 0
1
1
0
Normal Arbitration
Comments
Arbitration ID
2–5
ARBID
1
6
NOT(DM)
NOT(M2)
DM = Destination Mode from bit 11 of the redirection table register
NOT(M1)
NOT(M0)
M2-M0 = Delivery Mode from bits 10:8 of the redirection table
register
8
NOT(L)
NOT(TM)
L = Level, TM = Trigger Mode
9
NOT(V7)
NOT(V6)
10
NOT(V5)
NOT(V4)
11
NOT(V3)
NOT(V2)
7
12
NOT(V1)
NOT(V0)
13
NOT(D7)
NOT(D6)
14
NOT(D5)
NOT(D4)
15
NOT(D3)
NOT(D2)
Interrupt vector bits V7 - V0 from redirection table register
Destination field from bits 63:56 of redirection table register
16
NOT(D1)
NOT(D0)
17
NOT(C1)
NOT(C0)
18
1
1
19
NOT(A)
NOT(A)
Status Cycle 0.
20
NOT(A1)
NOT(A1)
Status Cycle 1.
21
d31
d30
22
d29
d28
23
d27
d26
24
d25
d24
25
d23
d22
26
d21
d20
27
d19
d18
28
d17
d16
29
d15
d14
30
d13
d12
31
d11
d10
32
d09
d08
33
d07
d06
34
d05
d04
35
d03
d02
36
d01
d00
37
S
S
Data Status: 00 = valid, 11 = invalid
38
C
C
Check Sum for data d31-d00
39
1
1
Idle
Checksum for Cycles 6 - 16
Postamble
Remote register data 31-0
NOTE: Cycle 21 through 36 contain the remote register data. The status information in cycle 37 specifies if the
data is good or not. Remote read cycle is always successful (although the data may be valid or invalid)
in that it is never retried. The reason for this is that Remote Read is a debug feature, and a "hung"
remote APIC that is unable to respond should not cause the debugger to hang.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-55
Functional Description
5.8.4
PCI Message-Based Interrupts
5.8.4.1
Theory of Operation
The following scheme is only supported when the internal I/O(x) APIC is used (rather than just the
8259). The ICH2 supports the new method for PCI devices to deliver interrupts as write cycles,
rather than using the traditional PIRQ[A:D] signals. Essentially, the PCI devices are given a write
path directly to a register that will cause the desired interrupt. This mode is only supported when
the ICH2’s internal I/O APIC is enabled. Upon recognizing the write from the peripheral, the ICH2
sends the interrupt message to the processor using the I/O APIC’s serial bus.
The interrupts associated with the PCI Message-based interrupt method must be set up for edgetriggered mode (rather than level-triggered) since the peripheral only does the write to indicate the
edge.
The following sequence is used:
1. During PCI PnP, the PCI peripheral is first programmed with an address
(MESSAGE_ADDRESS) and data value (MESSAGE_DATA) that will be used for the
interrupt message delivery. For the ICH2, the MESSAGE_ADDRESS is the IRQ Pin
Assertion Register, which is mapped to memory location: FEC0_0020h (same as APIC).
2. To cause the interrupt, the PCI peripheral requests the PCI bus and when granted, writes the
MESSAGE_DATA value to the location indicated by the MESSAGE_ADDRESS. The
MESSAGE_DATA value indicates which interrupt occurred. This MESSAGE_DATA value is
a binary encoded. For example, to indicate that interrupt 7 should go active, the peripheral will
write a binary value of 0000111. The MESSAGE_DATA will be a 32-bit value, although only
the lower 5 bits are used.
3. If the PRQ bit in the APIC Version Register is set, the ICH2 positively decodes the cycles (as a
slave) in medium time.
4. The ICH2 decodes the binary value written to MESSAGE_ADDRESS and sets the appropriate
IRR bit in the internal I/O APIC. The corresponding interrupt must be set up for edgetriggered interrupts. The ICH2 supports interrupts 00h through 23h. Binary values outside this
range will not cause any action.
5. After sending the interrupt message to the processor, the ICH2 automatically clears the
interrupt.
Because they are edge-tiggered, the interrupts that are allocated to the PCI bus for this scheme may
not be shared with any other interrupt (e.g., the standard PCI PIRQ[A:D], those received via
SERIRQ#, or the internal level-triggered interrupts such as SCI or TCO).
The ICH2 ignores interrupt messages sent by PCI masters that attempt to use IRQ[0,2,8, or 13].
5.8.4.2
Registers and Bits Associated with PCI Interrupt Delivery
Capabilities Indication
The capability to support PCI interrupt delivery will be indicated via ACPI configuration
techniques. This involves the BIOS creating a data structure that gets reported to the ACPI
configuration software. The operating system reads the PRQ bit in the APIC Version Register to
see if the ICH2 is capable of support PCI-based interrupt messages. As a precaution, the PRQ bit is
not set if the XAPIC_EN bit is not set.
Interrupt Message Register
The PCI devices all write their message into the IRQ Pin Assertion Register, which is a memorymapped register located at the APIC base memory location + 20h.
5-56
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.8.5
Front-Side Interrupt Delivery
5.8.5.1
Theory of Operation
For processors that support Front-Side Bus interrupt delivery, the ICH2 has an option to let the
integrated I/O APIC behave as an I/O (x) APIC. In this case, it delivers interrupt messages to the
processor in a parallel manner, rather than using the I/O APIC serial scheme. The ICH2 is intended
to be compatible with the I/O (x) APIC specification, Revision 1.1.
This is done by the ICH2 writing (via the Hub Interface) directly to a memory location that is
snooped by the processor(s). The processor(s) snoop the cycle to know which one goes active.
The processor enables the mode by setting the I/O APIC Enable (APIC_EN) bit and by setting the
DT bit in the I/O APIC ID register.
The following sequence is used:
1. When the ICH2 detects an interrupt event (active edge for edge-triggered mode or a change for
level-triggered mode), it sets or resets the internal IRR bit associated with that interrupt.
2. Internally, the ICH2 requests to use the bus in a way the automatically flushes upstream
buffers. This can be internally implemented similar to a DMA device request.
3. The ICH2 then delivers the message by performing a write cycle to the appropriate address
with the appropriate data. The address and data formats are described below in Section 5.8.5.5.
Notes:
1. FSB Interrupt Delivery compatibility with processor clock control depends on the processor,
not the ICH2.
2. FSB Interrupt Delivery compatibility with processor clock control depends on the processor,
not the ICH2.
3. 82801BAM (ICH2-M): FSB is not recommended in a mobile environment. For ICH2-M, if
FSB Interrupt Delivery Mode is used, the system cannot support Intel® SpeedStepTM
technology, C2, C3, software clock throttling or hardware thermal throttling.
5.8.5.2
Edge-Triggered Operation
In this case, the “Assert Message” is sent when there is an inactive-to-active edge on the interrupt.
The “Deassert Message” is not used.
5.8.5.3
Level-Triggered Operation
In this case, the “Assert Message” is sent when there is an inactive-to-active edge on the interrupt.
If after the EOI the interrupt is still active, then another “Assert Message” is sent to indicate that the
interrupt is still active.
If the interrupt was active but goes inactive before the EOI is received, the “Deassert Message” is
sent.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-57
Functional Description
5.8.5.4
Registers Associated with Front-Side Bus Interrupt Delivery
Capabilities Indication
The capability to support Front-Side bus interrupt delivery will be indicated via ACPI
configuration techniques. This involves BIOS creating a data structure that gets reported to the
ACPI configuration software.
DT bit in the Boot Configuration Register
This enables the ICH2 to deliver interrupts as memory writes. This bit is ignored if the APIC mode
is not enabled.
5.8.5.5
Interrupt Message Format
ICH2 writes the message to PCI (and to the Host Controller) as a 32-bit memory write cycle. It uses
the formats shown in Table 5-26 and Table 5-27 for the address and data.
:
Table 5-26. Interrupt Message Address Format
Bit
Description
31:20
Will always be FEEh
19:12
Destination ID: This is the same as bits 63:56 of the I/O Redirection Table entry for the interrupt
associated with this message.
11:4
Reserved (will always be 0)
Redirection Hint: This bit is used by the processor host bridge to allow the interrupt message to be
redirected.
0 = The message will be delivered to the agent (processor) listed in bits 19:4.
3
1 = The message will be delivered to an agent with a lower interrupt priority This can be derived from
bits 10:8 in the Data Field (see below).
The Redirection Hint bit = 1 if bits 10:8 in the Delivery Mode field associated with corresponding
interrupt are encoded as 001 (Lowest Priority). Otherwise, the Redirection Hint bit = 0.
2
1:0
5-58
Destination Mode: This bit is used only the Redirection Hint bit = 1. If the Redirection Hint bit and
the Destination Mode bit are both set to 1, the logical destination mode is used and the redirection is
limited only to those processors that are part of the logical group as based on the logical ID.
Will always be 00.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
Table 5-27. Interrupt Message Data Format
Bit
31:16
Description
Will always be 0000h.
Trigger Mode: Same as the corresponding bit in the I/O Redirection Table for that interrupt.
15
1 = Level
0 = Edge.
14
Delivery Status: If using edge-triggered interrupts, then this bit will always be 1, since only the
assertion is sent. If using level-triggered interrupts, then this bit indicates the state of the interrupt
input.
1 = Assert
0 = Deassert
13:12
Will always be 00
Destination Mode: Same as the corresponding bit in the I/O Redirection Table for that interrupt.
11
1 = Logical.
0 = Physical.
Delivery Mode: This is the same as the corresponding bits in the I/O Redirection Table for that
interrupt.
000 = Fixed
10:8
7:0
100 = NMI
001 = Lowest Priority
101 = INIT
010 = SMI/PMI
110 = Reserved
011 = Reserved
111 = ExtINT
Vector: This is the same as the corresponding bits in the I/O Redirection Table for that interrupt.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-59
Functional Description
5.9
Serial Interrupt (D31:F0)
ICH2 supports a serial IRQ scheme. This allows a single signal to be used to report interrupt
requests. The signal (used to transmit this information) is shared between the host, the ICH2, and
all peripherals that support serial interrupts. The signal line (SERIRQ) is synchronous to PCI clock
and follows the sustained tri-state protocol that is used by all PCI signals. This means that if a
device has driven SERIRQ low, it will first drive it high synchronous to PCI clock and release it the
following PCI clock. The serial IRQ protocol defines this sustained tri-state signaling in the
following fashion:
• S - Sample Phase. Signal driven low
• R - Recovery Phase. Signal driven high
• T - Turn-around Phase. Signal released
The ICH2 supports a message for 21 serial interrupts. These represent the 15 ISA interrupts
(IRQ[0,1, 2:15]), the four PCI interrupts, and the SMI# and IOCHK# control signals. The serial
IRQ protocol does not support the additional APIC interrupts (20–23).
5.9.1
Start Frame
The serial IRQ protocol has two modes of operation which affect the start frame. These two modes
are:
• Continuous, where the ICH2 is solely responsible for generating the start frame
• Quiet, where a serial IRQ peripheral is responsible for beginning the start frame.
The mode that must first be entered when enabling the serial IRQ protocol is continuous mode. In
this mode, the ICH2 will assert the start frame. This start frame is 4, 6, or 8 PCI clocks wide based
upon the Serial IRQ Control Register, bits 1:0 at 64h in Device 31:Function 0 configuration space.
This is a polling mode.
When the serial IRQ stream enters quiet mode (signaled in the Stop Frame), the SERIRQ line
remains inactive and pulled up between the Stop and Start Frame until a peripheral drives the
SERIRQ signal low. The ICH2 senses the line low and continues to drive it low for the remainder
of the Start Frame. Since the first PCI clock of the start frame was driven by the peripheral in this
mode, the ICH2 drives the SERIRQ line low for 1 PCI clock less than in continuous mode. This
mode of operation allows for a quiet and, therefore, lower power operation.
5.9.2
Data Frames
Once the Start frame has been initiated, all of the SERIRQ peripherals must start counting frames
based on the rising edge of SERIRQ. Each of the IRQ/DATA frames has exactly 3 phases of
1 clock each:
• Sample Phase. During this phase, the SERIRQ device drives SERIRQ low if the
corresponding interrupt signal is low. If the corresponding interrupt is high, the SERIRQ
devices tri-state the SERIRQ signal. The SERIRQ line remains high due to pull-up resistors. A
low level during the IRQ0-1 and IRQ2-15 frames indicates that an active-high ISA interrupt is
not being requested, but a low level during the PCI INT[A:D], SMI#, and IOCHK# frame
indicates that an active-low interrupt is being requested.
• Recovery Phase. During this phase, the device drives the SERIRQ line high if in the Sample
Phase it was driven low. If it was not driven in the sample phase, it is tri-stated in this phase.
• Turn-around Phase. The device will tri-state the SERIRQ line.
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82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.9.3
Stop Frame
After all data frames, a Stop Frame is driven by ICH2. The SERIRQ signal is driven low by ICH2
for 2 or 3 PCI clocks. The number of clocks is determined by the SERIRQ configuration register.
The number of clocks determines the next mode.
Table 5-28. Stop Frame Explanation
Stop Frame Width
5.9.4
Next Mode
2 PCI clocks
Quiet Mode. Any SERIRQ device may initiate a Start Frame
3 PCI clocks
Continuous Mode. Only the host (ICH2) may initiate a Start Frame
Specific Interrupts not Supported via SERIRQ
There are three interrupts seen through the serial stream that are not supported by the ICH2. These
interrupts are generated internally and are not sharable with other devices within the system. These
interrupts are:
• IRQ0. Heartbeat interrupt generated off of the internal 8254 counter 0.
• IRQ8#. RTC interrupt can only be generated internally.
• IRQ13. Floating point error interrupt generated off of the processor assertion of FERR#.
ICH2 ignores the state of these interrupts in the serial stream, and does not adjust their level based
on the level seen in the serial stream. In addition, the interrupts IRQ14 and IRQ15 from the serial
stream are treated differently than their ISA counterparts. These two frames are not passed to the
Bus Master IDE logic. The Bus Master IDE logic expects IDE to be behind the ICH2.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-61
Functional Description
5.9.5
Data Frame Format
Table 5-29 shows the format of the data frames. For the PCI interrupts (A-D), the output from the
ICH2 is ANDed with the PCI input signal. Thus, the interrupt can be signaled via both the PCI
interrupt input signal and via the SERIRQ signal (they are shared).
Table 5-29. Data Frame Format
Data
Frame #
5-62
Interrupt
Clocks Past
Start Frame
1
IRQ0
2
2
IRQ1
5
3
SMI#
8
4
IRQ3
11
5
IRQ4
14
6
IRQ5
17
7
IRQ6
20
8
IRQ7
23
9
IRQ8
26
10
IRQ9
29
11
IRQ10
32
12
IRQ11
35
Comment
Ignored. IRQ0 can only be generated via the internal 8524
Causes SMI# if low. Sets the SERIRQ_SMI_STS bit.
Ignored. IRQ8# can only be generated internally or on ISA.
13
IRQ12
38
14
IRQ13
41
Ignored. IRQ13 can only be generated from FERR#
15
IRQ14
44
Do not include in BM IDE interrupt logic
16
IRQ15
47
Do not include in BM IDE interrupt logic
17
IOCHCK#
50
Same as ISA IOCHCK# going active.
18
PCI INTA#
53
Drive PIRQA#
19
PCI INTB#
56
Drive PIRQB#
20
PCI INTC#
59
Drive PIRQC#
21
PCI INTD#
62
Drive PIRQD#
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.10
Real Time Clock (D31:F0)
The Real Time Clock (RTC) module provides a battery backed-up date and time keeping device
with two banks of static RAM (128 bytes each); the first bank has 114 bytes for general purpose
usage. Three interrupt features are available: time of day alarm with once a second to once a month
range, periodic rates of 122 us to 500 ms, and end of update cycle notification. Seconds, minutes,
hours, days, day of week, month, and year are counted. Daylight savings compensation is optional.
The hour is represented in twelve or twenty-four hour format, and data can be represented in BCD
or binary format. The design is meant to be functionally compatible with the Motorola*
MS146818B. The time keeping comes from a 32.768 kHz oscillating source, which is divided to
achieve an update every second. The lower 14 bytes on the lower RAM block has very specific
functions. The first ten are for time and date information. The next four (0Ah to 0Dh) are registers
that configure and report RTC functions.
The time and calendar data should match the data mode (BCD or binary) and hour mode
(12 or 24 hour) as selected in register B. It is up to the programmer to make sure that data stored in
these locations is within the reasonable values ranges and represents a possible date and time. The
exception to these ranges is to store a value of C0–FFh in the Alarm bytes to indicate a don’t care
situation. All Alarm conditions must match to trigger an Alarm Flag, which could trigger an Alarm
Interrupt, if enabled. The SET bit must be 1 while programming these locations to avoid clashes
with an update cycle. Access to time and date information is done through the RAM locations. If a
RAM read from the ten time and date bytes is attempted during an update cycle, the value read will
not necessarily represent the true contents of those locations. Any RAM writes under the same
conditions will be ignored.
Note:
The ICH2 supports the ability to generate an SMI# based on year 2000 rollover. See Section 5.10.4
for more information on the century rollover.
The ICH2 does not implement month/year alarms.
5.10.1
Update Cycles
An update cycle occurs once a second, if the SET bit of register B is not asserted and the divide
chain is properly configured. During this procedure, the stored time and date is incremented,
overflow checked, a matching alarm condition checked, and the time and date are rewritten to the
RAM locations. The update cycle starts at least 488 us after the UIP bit of register A is asserted and
the entire cycle does not take more than 1984 us to complete. The time and date RAM locations
(0–9) are disconnected from the external bus during this time.
To avoid update and data corruption conditions, external RAM access to these locations can safely
occur at two times. When a updated-ended interrupt is detected, almost 999 ms is available to read
and write the valid time and date data. If the UIP bit of Register A is detected to be low, there is at
least 488 us before the update cycle begins.
Warning:
The overflow conditions for leap years and daylight savings adjustments are based on more than
one date or time item. To ensure proper operation when adjusting the time, the new time and data
values should be set at least two seconds before one of these conditions (leap year, daylight savings
time adjustments) occurs.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-63
Functional Description
5.10.2
Interrupts
The real-time clock interrupt is internally routed within the ICH2 both to the I/O APIC and the
8259. It is mapped to interrupt vector 8. This interrupt does not leave the ICH2, nor is it shared with
any other interrupt. IRQ8# from the SERIRQ stream is ignored.
5.10.3
Lockable RAM Ranges
The RTC’s battery-backed RAM supports two 8-byte ranges that can be locked via the
configuration space. If the locking bits are set, the corresponding range in the RAM are not
readable or writable. A write cycle to those locations has no effect. A read cycle to those locations
does not return the location’s actual value (may be all 0s or all 1s).
Once a range is locked, the range can be unlocked only by a hard reset, which invokes BIOS and
allows it to relock the RAM range.
5.10.4
Century Rollover
ICH2 detects a rollover when the Year byte (RTC I/O space, index offset 09h) transitions form
99 to 00. Upon detecting the rollover, the ICH2 sets the NEWCENTURY_STS bit
(TCOBASE + 04h, bit 7). If the system is in an S0 state, this causes an SMI#. The SMI# handler
can update registers in the RTC RAM that are associated with century value. If the system is in a
sleep state (S1–S5) when the century rollover occurs, the ICH2 also sets the NEWCENTURY_STS
bit; no SMI# is generated. When the system resumes from the sleep state, BIOS should check the
NEWCENTURY_STS bit and update the century value in the RTC RAM.
5.10.5
Clearing Battery-Backed RTC RAM
Clearing CMOS RAM in an ICH2-based platform can be done by using a jumper on RTCRST# or
GPI or using the SAFEMODE strap. Implementations should not attempt to clear CMOS by using
a jumper to pull VccRTC low.
Using RTCRST# to clear CMOS
A jumper on RTCRST# can be used to clear CMOS values, as well as reset to default, the state of
the configuration bits that reside in the RTC power well. When the RTCRST# is strapped to
ground, the RTC_PWR_STS bit (D31:F0:A4h bit 2) is set and the configuration bits in the RTC
power well are set to their default state. BIOS can monitor the state of this bit and manually clear
the RTC CMOS array once the system is booted. The normal position would cause RTCRST# to be
pulled up through a weak pull-up resistor. Table 5-30 shows which bits are set to their default state
when RTCRST# is asserted.
RTCRST# should be used to reset configuration bits (and signal BIOS to clear CMOS) ONLY in a
G3 state. Additionally, RTCRST# assertion while power is on must ONLY be done to invoke the
test modes, and that it should only be asserted for the specific number of clocks to invoke the
desired test mode. Assertion for any other number of clocks may put the component into an
indeterminate state, which is not supported.
5-64
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
Table 5-30. Configuration Bits Reset By RTCRST# Assertion
Bit Name
Register
Location
Bits
Default Value
FREQ_STRAP[3:0]
GEN_STS
D31:F0:D4h
11:8
1111b
AIE
RTC Reg B
I/O space
5
0
AF
RTC Reg C
I/O space
5
0
PWR_FLR
GEN_PMCON_3
D31:F0:A4h
1
0
AFTERG3_EN
GEN_PMCON_3
D31:F0:A4h
0
0
RTC_PWR_STS
GEN_PMCON_3
D31:F0:A4h
2
1
PRBTNOR_STS
PM1_STS
PMBase + 00h
11
0
PME_EN
GPE0_EN
PMBase + 2Ah
11
0
RI_EN
GPE0_EN
PMBase + 2Ah
8
0
NEW_CENTURY_STS
TCO1_STS
TCOBase + 04h
7
0
INTRD_DET
TCO2_STS
TCOBase + 06h
0
0
TOP_SWAP
GEN_STS
D31:F0:D4h
13
0
RTC_EN
PM1_EN
PMBase + 02h
10
0
BATLOW_EN
(ICH2-M only)
GPE0_EN
PMBase + 2Ah
10
0
Using a GPI to clear CMOS
A jumper on a GPI can also be used to clear CMOS values. BIOS detects the setting of this GPI on
system boot-up and manually clear the CMOS array.
Using the SAFEMODE Strap to clear CMOS
A jumper on AC_SDOUT (SAFEMODE strap) can also be used to clear CMOS values. BIOS
detects the setting of the SAFE_MODE status bit (D31:F0: Offset D4h bit 2) on system boot-up,
and manually clear the CMOS array.
Note:
Both the GPI and SAFEMODE strap techniques to clear CMOS require multiple steps to
implement. The system is booted with the jumper in a new position, then powered back down. The
jumper is replaced back to the normal position, then the system is rebooted again. The RTCRST#
jumper technique allows the jumper to be moved and then replaced, all while the system is
powered off. Then, once booted, the RTC_PWR_STS can be detected in the set state.
Note:
Clearing CMOS, using a jumper on VCCRTC, must NOT be implemented.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-65
Functional Description
5.11
Processor Interface (D31:F0)
The ICH2 interfaces to the processor with a variety of signals:
• Standard outputs to the processor: A20M#, SMI#, NMI, INIT#, INTR, STPCLK#, IGNNE#,
CPUSLP#
• Standard input from the processor: FERR#
• For ICH2-M, Intel® SpeedStepTM Output to the processor: CPUPWRGOOD
Most ICH2 outputs to the processor use standard buffers. The ICH2 has a separate Vcc signal that
is pulled up at the system level to the processor voltage and thus, determines Voh for the outputs to
the processor. Note that this is different than previous generations of chips that have used opendrain outputs. This new method saves up to 12 external pull-up resistors.
The ICH2 also handles the speed setting for the processor by holding specific signals at certain
states just prior to CPURST going inactive. This avoids the glue often required with other chipsets.
The ICH2 does not support the processor’s FRC mode.
5.11.1
Processor Interface Signals
This section describes each of the signals that interface between the ICH2 and the processor(s).
Note that the behavior of some signals may vary during processor reset, as the signals are used for
frequency strapping.
5.11.1.1
A20M#
The A20M# signal is active (low) when both of the following conditions are true:
• The ALT_A20_GATE bit (Bit 1 of PORT92 register) is a 0
• The A20GATE input signal is a 0
The A20GATE input signal is expected to be generated by the external microcontroller (KBC).
5.11.1.2
INIT#
The INIT# signal is active (driven low) based on any one of several events described in Table 5-31.
When any of these events occur, INIT# is driven low for 16 PCI clocks, then driven high.
Note:
5-66
The 16-clock counter for INIT# assertion halts while STPCLK# is active. Therefore, if INIT# is
supposed to go active while STPCLK# is asserted, it actually goes active after STPCLK# goes
inactive.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
Table 5-31. INIT# Going Active
Cause of INIT# Going Active
Comment
Shutdown special cycle from the processor.
PORT92 write, where INIT_NOW (bit 0) transitions
from a 0 to a 1.
PORTCF9 write, where RST_CPU (bit 2) was a 0
and SYS_RST(bit 1) transitions from 0 to 1.
5.11.1.3
RCIN# input signal goes low. RCIN# is expected to
be driven by the external microcontroller (KBC).
0 to 1 transition on RCIN# must occur before the ICH2
arms INIT# to be generated again.
Processor BIST
To enter BIST, the software sets CPU_BIST_EN bit and
then does a full processor reset using the CF9 register.
FERR#/IGNNE# (Coprocessor Error)
The ICH2 supports the coprocessor error function with the FERR#/IGNNE# pins. The function is
enabled via the COPROC_ERR_EN bit (Device 31:Function 0, Offset D0, bit 13). FERR# is tied
directly to the Coprocessor Error signal of the processor. If FERR# is driven active by the
processor, IRQ13 goes active (internally). When it detects a write to the COPROC_ERR register,
the ICH2 negates the internal IRQ13 and drives IGNNE# active. IGNNE# remains active until
FERR# is driven inactive. IGNNE# is never driven active unless FERR# is active.
Figure 5-12. Coprocessor Error Timing Diagram
FERR#
Internal IRQ13
I/O Write to F0h
IGNNE#
If COPROC_ERR_EN is not set, the assertion of FERR# will not generate an internal IRQ13; the
write to F0h will not generate IGNNE#.
5.11.1.4
NMI
Non-Maskable Interrupts (NMIs) can be generated by several sources, as described in Table 5-32.
Table 5-32. NMI Sources
Cause of NMI
Comment
SERR# goes active (either internally, externally
via SERR# signal, or via message from MCH)
Can instead be routed to generate an SCI, through the
NMI2SCI_EN bit (Device 31:Function 0, offset 4E, bit 11).
IOCHK# goes active via SERIRQ# stream
(ISA system Error)
Can instead be routed to generate an SCI, through the
NMI2SCI_EN bit (Device 31:Function 0, offset 4E, bit 11).
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-67
Functional Description
5.11.1.5
STPCLK# and CPUSLP# Signals
The ICH2 power management logic controls these active-low signals. Refer to Section 5.12 for
more information on the functionality of these signals.
5.11.1.6
CPUPWRGOOD Signal
This signal is connected to the processor’s PWRGOOD input. This is an open-drain output signal
(external pull-up resistor required) that represents a logical AND of the ICH2’s PWROK and
VRMPWRGD (VGATE/VRMPWRGD for ICH2-M) signals.
82801BAM ICH2-M: For Intel® SpeedStepTM technology support, this signal is kept high during
a Intel® SpeedStepTM state transition to prevent loss of processor context.
5.11.2
Dual Processor Issues (82801BA ICH2 only)
5.11.2.1
Signal Differences (82801BA ICH2 only)
In dual-processor designs, some of the processor signals are unused or used differently than for
uniprocessor designs.
Table 5-33. DP Signal Differences (82801BA ICH2 only)
Signal
A20M# / A20GATE
Difference
Generally not used, but still supported by the 82801BA ICH2.
Used for S1 State as well as preparation for entry to S3–S5
5.11.2.2
STPCLK#
Also allows for THERM# based throttling (not via ACPI control methods).
Should be connected to both processors.
FERR# / IGNNE#
Generally not used, but still supported by 82801BA ICH2.
Power Management (82801BA ICH2 only)
For the 82801BA ICH2, attempting clock control with more than one processor is not feasible.
This is because the host controller does not provide any indication as to which processor is
executing a particular Stop-Grant cycle. Without this information, there is no way for the ICH2 to
know when it is safe to deassert STPCLK#.
Because the S1 state has the STPCLK# signal active, the STPCLK# signal can be connected to
both processors. However, for ACPI implementations, the ICH2 does not support the C2 state for
both processors, since there are not two processor control blocks. BIOS must indicate that the
ICH2 only supports the C1 state for dual-processor designs. However, the THRM# signal can be
used for overheat conditions to activate thermal throttling.
When entering S1, the ICH2 asserts STPCLK# to both processors. To meet the processor
specifications, the CPUSLP# signal has to be delayed until the 2nd Stop-Grant cycle occurs. To
ensure this, the ICH2 waits a minimum or 60 PCI clocks after receipt of the first Stop-Grant cycle
before asserting CPUSLP# (if the SLP_EN bit is set to 1).
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82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
Both processors must immediately respond to the STPCLK# assertion with stop grant
acknowledge cycles before the 82801BA ICH2 asserts CPUSLP# to meet the processor setup time
for CPUSLP#. Meeting the processor setup time for CPUSLP# is not an issue if both processors
are idle when the system is entering S1. If it cannot be guaranteed that both processors will be idle,
the SLP_EN bit must not be enabled. Note that setting SLP_EN to 1 is not required to support S1
in a dual-processor configuration.
In going to the S3, S4, or S5 states, the system will appear to pass through the S1 state and thus,
STPCLK# and SLP# are also used. During the S3, S4, and S5 states, both processors will lose
power. Upon exit from those states, the processors will have their power restored.
5.11.3
Speed Strapping for Processor
The ICH2 directly sets the speed straps for the processor, saving the external logic that has been
needed with prior PCIsets. Refer to the processor specification for speed strapping definition. The
ICH2 performs the following to set the speed straps for the processor:
1. While PWROK is active, the ICH2 drives A20M#, IGNNE#, NMI, and INTR high.
2. As soon as PWROK goes active, the ICH2 reads the FREQ_STRAP field contents.
3. The next step depends on the power state being exited as described in Table 5-34.
Table 5-34. Frequency Strap Behavior Based on Exit State
State
Exiting
S1
S3, S4, S5,
or G3
ICH2
There is no processor reset, so no frequency strap logic is used.
Based on PWROK going active, the ICH2 deasserts PCIRST#, and based on the value of the
FREQ_STRAP field (D31:F0,Offset D4), the ICH2 drives the intended core frequency values on
A20M#, IGNNE#, NMI, and INTR. The ICH2 holds these signals for 120 ns after CPURST# is
deasserted by the Host controller.
Table 5-35. Frequency Strap Bit Mapping
FREQ_STRAP bits [3:0]
Sets High/Low Level for the Corresponding Signal
3
NMI
2
INTR
1
IGNNE#
0
A20M#
NOTE: The FREQ_STRAP register is in the RTC well. The value in the register can be forced to 1111 via a
pinstrap (AC_SDOUT signal), or the ICH2 can automatically force the speed strapping to 1111 if the
processor fails to boot.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-69
Functional Description
Figure 5-13. Signal Strapping
CPURST#
Host Controller
Processor
CPU
INIT#
A20M#, IGNE#, INTR, NMI
ICH2
ICH
4x 2 to 1
MUX
PCIRST#
Freq.
strap reg
PWROK
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82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.12
Power Management (D31:F0)
Features
• ACPI Power and Thermal Management Support
— ACPI 24-Bit Timer
— Software initiated throttling of processor performance for Thermal and Power Reduction
— Hardware Override to throttle processor performance if system too hot
— SCI and SMI# Generation
• PCI PME# Signal for Wake Up from Low-Power states
• System Clock Control
— ACPI C2 state: Stop-Grant (or Quickstart for the 82801BAM ICH2-M) state (using
STPCLK# signal) halts processor’s instruction stream
— ACPI C3 State (82801BAM ICH2-M): Ability to halt processor clock (but not hub
interface or memory clock)
— 82801BAM ICH2-M: CLKRUN# protocol for PCI clock starting/stopping
• System Sleeping State Control
— ACPI S1 state (82801BA ICH2): Like C2 state (only STPCLK# active, and SLP#
optional)
— ACPI S1 state (82801BAM ICH2-M): Powered On Suspend (POS)
— ACPI S1 state: Like C2 state (only STPCLK# active, and SLP# optional)
— ACPI S3 state - Suspend to RAM (STR)
— ACPI S4 state - Suspend-to-Disk (STD)
— ACPI G2/S5 state - Soft Off (SOFF)
— Power Failure Detection and Recovery
• Streamlined Legacy Power Management Support for APM-Based Systems
• 82801BAM ICH2-M: Intel® SpeedStepTM transition logic
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-71
Functional Description
5.12.1
ICH2 and System Power States
Table 5-36 shows the power states defined for ICH2-based platforms. The state names generally
match the corresponding ACPI states.
Table 5-36. General Power States for Systems using ICH2
State/
Substates
Legacy Name / Description
G0/S0/C0
Full On: Processor operating. Individual devices may be shut down to save power. The
different processor operating levels are defined by Cx states, as shown in Table 5-37. Within
the C0 state, the ICH2 can throttle the STPCLK# signal to reduce power consumption. The
throttling can be initiated by software or by the THRM# input signal.
G0/S0/C1
Auto-Halt: The processor has executed an AutoHalt instruction and is not executing code.
The processor snoops the bus and maintains cache coherency.
G0/S0/C2
Stop-Grant (ICH2) / Quickstart (ICH2-M): The STPCLK# signal goes active to the
processor. The processor performs a Stop-Grant cycle, halts its instruction stream, and
remains in that state until the STPCLK# signal goes inactive. In the Stop-Grant (ICH2) /
Quickstart (ICH2-M) state, the processor snoops the bus and maintains cache coherency.
G0/S0/C3
(ICH2-M only)
G1/S1
(ICH2 only)
Stop-Clock: The STPCLK# signal goes active to the processor. The processor performs a
Stop-Grant cycle, halts its instruction stream. ICH2-M then asserts STP_CPU#, which forces
the clock generator to stop the processor clock. This is also used for Intel® SpeedStepTM
technology support. Accesses to memory (by AGP, PCI, or internal units) is not permitted
while in a C3 state. It is assumed that the ARB_DIS bit is set prior to entering C3 state.
Stop-Grant: Similar to G0/S0/C2 state. The ICH2 also has the option to assert the CPUSLP#
signal to further reduce processor power consumption.
Note: The behavior for this state is slightly different when supporting iA64 processors.
G1/S1
(ICH2-M only)
Powered-On-Suspend (POS): In this state, all clocks (except the 32.768 kHz clock) are
stopped. The system context is maintained in system DRAM. Power is maintained to PCI, the
processor, memory controller, memory, and all other criticial subsystems. Note that this state
does not preclude power being removed from non-essential devices (e.g., disk drives).
G1/S3
Suspend-To-RAM (STR): The system context is maintained in system DRAM, but power is
shut off to non-critical circuits. Memory is retained and refreshes continue. All clocks stop
except RTC clock.
G1/S4
Suspend-To-Disk (STD): The context of the system is maintained on the disk. All power is
then shut off to the system except for the logic required to resume. Externally appears same
as S5, but may have different wake events.
G2/S5
Soft Off (SOFF): System context is not maintained. All power is shut off except for the logic
required to restart. A full boot is required when waking.
G3
Mechanical OFF (MOFF): System context not maintained. All power is shut off except for the
RTC. No “Wake” events are possible, because the system does not have any power. This
state occurs if the user removes the batteries, turns off a mechanical switch, or if the system
power supply is at a level that is insufficient to power the “waking” logic. When system power
returns, transition depends on the state just prior to the entry to G3 and the AFTERG3 bit in
the GEN_PMCON3 register (D31:F0, offset A4). Refer to Table 5-45 for more details.
Table 5-37 shows the transitions rules among the various states. Note that transitions among the
various states may appear to temporarily transition through intermediate states. For example, in
going from S0 to S1, it may appear to pass through the G0/S0/C2 states. These intermediate
transitions and states are not listed in the table.
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82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
Table 5-37. State Transition Rules for ICH2
Present State
G0/S0/C0
G0/S0/C1
G0/S0/C2
G0/S0/C3
(ICH2-M only)
G1/S1,
G1/S3, or
G1/S4
G2/S5
G3
Transition Trigger
Next State
• Processor halt instruction
• G0/S0/C1
• Level 2 Read
• G0/S0/C2
• Level 3 Read
• G0/S0/C3
• SLP_EN bit set
• G1/Sx or G2/S5state
• Power Button Override
• G2/S5
• Mechanical Off/Power Failure
• G3
• Any Enabled Break Event
• G0/S0/C0
• STPCLK# goes active
• G0/S0/C2
• Power Button Override
• G2/S5
• Power Failure
• G3
• Any Enabled Break Event
• G0/S0/C0
• STPCLK# goes inactive and previously
in C1
• G0/S0/C1
• Power Button Override
• G2/S5
• Power Failure
• G3
• Any Enabled Break Event
• G0/S0/C0
• STPCLK# goes inactive and previously
in C1
• G0/S0/C1
• Power Button Override
• G2/S5
• Power Failure
• G3
• Any Enabled Wake Event
• G0/S0/C0 (For ICH2-M, see note 2)
• Power Button Override
• G2/S5
• Power Failure
• G3
• Any Enabled Wake Event
• G0/S0/C0 (For ICH2-M, see note 2)
• Power Failure
• G3
• Power Returns
• Optional to go to S0/C0 (reboot) or G2/
S5 (stay off until power button pressed or
other wake event). (For ICH2 and
ICH2-M, see Note 1) (For ICH2-M, see
note 2)
NOTES:
1. Some wake events can be preserved through power failure.
2. 82801BAM ICH2-M, transitions from the S1-S5 or G3 states to the S0 state are deferred until BATLOW# is
inactive.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-73
Functional Description
5.12.2
System Power Planes
The system has several independent power planes, as described in Table 5-38. Note that when a
particular power plane is shut off, it should go to a 0V level.
s
Table 5-38. System Power Plane
Plane
Controlled
By
Description
CPU
(ICH2-M only)
SLP_S3#
signal
SLP_S1# puts the clock generator into a low-power state, but does not cut
the power to the processor. The SLP_S3# signal can be used to cut the
processor’s power completely.
MAIN
5.12.3
SLP_S3#
signal
MEMORY
SLP_S5#
signal
DEVICE[n]
GPIO
When SLP_S3# goes active, power can be shut off to any circuit not
required to wake the system from the S3 state. Since the S3 state
requires that the memory context be preserved, power must be retained
to the main memory.
The processor, devices on the PCI bus, LPC interface, downstream hub
interface and AGP will typically be shut off when the Main power plane is
shut, although there may be small subsections powered.
When the SLP_S5# goes active, power can be shut off to any circuit not
required to wake the system from the S4 or S5 state. Since the memory
context does not need to be preserved in the S5 state, the power to the
memory can also be shut down.
Individual subsystems may have their own power plane. For example,
GPIO signals may be used to control the power to disk drives, audio
amplifiers, or the display screen.
ICH2 Power Planes
The ICH2 power planes were previously defined in Section 3.1.
Although not specific power planes within the ICH2, there are many interface signals that go to
devices that may be powered down. These include:
• IDE: ICH2 can tri-state or drive low all IDE output signals and shut off input buffers.
• USB: ICH2 can tri-state USB output signals and shut off input buffers if USB wakeup is not
desired
• AC’97: ICH2 can drive low the outputs and shut off inputs
5.12.4
SMI#/SCI Generation
Upon any SMI# event taking place, ICH2 asserts SMI# to the processor which causes it to enter
SMM space. SMI# remains active until the EOS bit is set. When the EOS bit is set, SMI# goes
inactive for a minimum of 4 PCICLKs. If another SMI event occurs, SMI# is driven active again.
The SCI is a level-mode interrupt that is typically handled by an ACPI-aware operating system. In
non-APIC systems (the default), the SCI IRQ is routed to one of the 8259 interrupts
(IRQ[9,10, or 11]). The 8259 interrupt controller must be programmed to level mode for that
interrupt.
In systems using the APIC, the SCI can still be routed to IRQ[9, 10, or 11] or it can be instead
routed to one of the APIC interrupts 20:23. In the case where the SCI is routed to
IRQ[20, 21, 22, or 23], the interrupt generated internally is an active low level. The interrupt
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82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
remains low until all SCI sources are removed. In the case where the SCI is routed to
IRQ[9, 10, or 11], the interrupt generated internally is active high. The interrupt remains high until
all SCI sources are removed.
Table 5-39 shows which events can cause an SMI# and SCI. Note that some events can be
programmed to cause either an SMI# or SCI. The usage of the event for SCI (instead of SMI#) is
typically associated with an ACPI-based system. Each SMI# or SCI source has a corresponding
enable and status bits.
Table 5-39.
Causes of SMI# and SCI
Cause
SCI
SMI
Additional Enables
Where Reported
Comment
PME#
Yes
Yes
PME_EN=1
PME_STS
Can also cause Wake Event
Power Button Press
Yes
Yes
PWRBTN_EN=1
PWRBTN_STS
Can also cause Wake Event
RTC Alarm
Yes
Yes
RTC_EN=1
RTC_STS
Ring Indicate
Yes
Yes
RI_EN=1
RI_STS
AC’97 wakes
Yes
Yes
AC97_EN=1
AC97_STS
USB#1 wakes
Yes
Yes
USB1_EN=1
USB1_STS
USB#2 wakes
Yes
Yes
USB2_EN=1
USB2_STS
THRM# pin active
Yes
Yes
THRM_EN=1
THRM_STS
ACPI Timer overflow
(2.34 sec.)
Yes
Yes
TMROF_EN=1
TMROF_STS
Any GPI
Yes
Yes
GPI[x]_Route=01 (SMI)
GPI[x]_Route=10 (SCI)
GPE1[x]_EN=1
TCO SCI Logic
GPI[x]_STS
GPE1_STS
Yes
No
TCOSCI_EN=1
TCOSCI_STS
Yes
No
none
MCHSCI_STS
No
Yes
TCO_EN=1
TCO_STS
TCO SMI: Year 2000
Rollover
No
Yes
none
NEWCENTURY_STS
TCO SMI: TCO
TIMEROUT
No
Yes
none
TIMEOUT
TCO SMI: OS writes
to TCO_DAT_IN
register
No
Yes
none
OS_TCO_SMI
TCO SMI: Message
from MCH
No
Yes
none
MCHSMI_STS
TCO SMI: NMI
occurred (and NMI’s
mapped to SMI)
No
Yes
NMI2SMI_EN=1
NMI2SMI_STS
TCO SMI:
INTRUDER# signal
goes active
No
Yes
INTRD_SEL=10
INTRD_DET
TCO SCI message
from MCH
TCO SMI Logic
82801BA ICH2 and 82801BAM ICH2-M Datasheet
The THRM# can cause an
SMI# or SCI on either the
rising or falling edge. Causes
SCI if SCI_EN is set, causes
SMI# if SCI_EN not set.
Can also cause IRQ (other
than SCI).
Can also cause IRQ (other
than SCI).
5-75
Functional Description
Table 5-39.
Causes of SMI# and SCI (Continued)
Cause
SCI
SMI
Additional Enables
Where Reported
TCO SMI: Change of
the BIOSWP bit from
0 to 1
No
Yes
BLD=1
BIOSWR_STS
TCO SMI: Write
attempted to BIOS
No
Yes
BIOSWP=1
BIOSWR_STS
Yes
No
GBL_EN=1
GBL_STS
ACPI code in OS sets
GBL_RLS bit to cause
BIOS_STS bit active, which
causes SMI#.
BIOS_RLS writen to
Comment
GBL_RLS written to
No
Yes
BIOS_EN=1
BIOS_STS
This bit is set when the BIOS
sets the BIOS_RLS bit. The
ACPI handler will clear the
bit.
Write to B2h register
No
Yes
none
APM_STS
OS or BIOS writes to the
APMC register. SMM handler
clears.
Periodic timer expires
No
Yes
PERIODIC_EN=1
PERIODIC_STS
64 ms timer expires
No
Yes
SWSMI_TMR_EN=1
SWSMI_TMR_STS
Allows SMM handler to exit
temporarily. Another SMI#
occurs about 64 ms later.
Legacy USB logic
No
Yes
LEGACY_USB_EN=1
LEGACY_USB_STS
Bit set based on address
decode or incoming USB
IRQ.
Serial IRQ SMI reported
No
Yes
none
SERIRQ_SMI_STS
Device Trap: Device
monitors match address
in its range
No
Yes
DEV[n]_TRAP_EN=1
SMBus Host Controller
No
Yes
SMB_SMI_EN
SMBus host status reg.
SMBus Slave SMI
No
Yes
none
SMBUS_SMI_STS
BATLOW# assertion
(ICH2-M)
Yes
Yes
BATLOW_EN=1.
BATLOW_STS
Global Standby Timer
expires in S1 state
(ICH2-M)
Yes
No
Access microcontroller
62h/66h
No
Yes
MCSMI_EN
MCSMI_STS
SLP_EN bit written to 1
No
Yes
SMI_ON_SLP_EN=1
SMI_ON_SLP_EN_STS
DEVMON_STS,
DEV[n]_TRAP_STS
Indicates that subsystems
may need to be powered
back on.
When activated, only counts
when in the S1 state.
Access to Microcontroller
range (62h/66h) with
MCSMI_EN set.
NOTES:
1. SCI_EN must be 1 to enable SCI. SCI_EN must be 0 to enable SMI.
2. SCI can be routed to cause interrupt 9:11 or 20:23 (20:23 only available in APIC mode).
3. GBL_SMI_EN must be 1 to enable SMI.
4. EOS must be written to 1 to re-enable SMI for the next one.
5. The GPI[x]_ Route bits can enable GPIs to generate SMIs regardless of the state of SMI_EN.
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82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.12.5
Dynamic Processor Clock Control
ICH2 has extensive control for dynamically starting and stopping system clocks. The clock control
is used for transitions among the various S0/Cx states and processor throttling. Each dynamic clock
control method is described in this section. The various Sleep states may also perform types of nondynamic clock control.
The ICH2 supports the ACPI C0, C1 and C2 states.
In addition to C0, C1, and C2 states, the 82801BAM ICH2-M supports the ACPI C3 states.
The dynamic processor clock control is handled using the following signals:
• STPCLK#: Used to halt processor instruction stream.
• C3_STAT# (ICH2-M only): Used to signal an AGP device that the system is about to enter, or
has just exited a C3 state.
• STP_CPU# (ICH2-M only): Used to stop CPU’s clock
• CPUSLP#: Must be asserted prior to STP_CPU# (in Stop Grant mode)
The C1 state is entered based on the processor performing an autohalt instruction. The C2 state is
entered based on the processor reading the Level 2 register in the ICH2.
For the ICH2-M, the C3 state is entered based on the processor reading the Level 3 register in the
ICH2-M. Note that a Intel® SpeedStepTM transition may appear to temporarily pass through a C3
state; however, it is a separate transition and documented separately in ??.
A C1 or C2 state (C1, C2, or C3 state for the 82801BAM ICH2-M) ends due to a break event.
Based on the break event, the ICH2-M returns the system to C0 state. Table 5-40 lists the possible
break events from C2 (C2 or C3 for the ICH2-M). The break events from C1 are indicated in the
processor’s datasheet.
Table 5-40. Break Events
Event
Breaks from
Comment
Any unmasked interrupt goes
active
C2 (ICH2)
C2, C2 (ICH2-M)
IRQ[0:15] when using the 8259s, IRQ[0:23] for I/O APIC.
Since SCI is an interrupt, any SCI will also be a break
event.
Any internal event that will
cause an NMI or SMI#
C2, C3 (ICH2-M)
Any internal event that will
cause INIT# to go active
C2, C3 (ICH2-M)
Any bus master request
(internal, external or DMA)
goes active
(ICH2-M only)
C2 (ICH2)
C2 (ICH2)
C3 only
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Many possible sources
Could be indicated by the keyboard controller via the
RCIN input signal.
Need to wake up processor so it can do snoops
5-77
Functional Description
5.12.5.1
Throttling Using STPCLK#
Throttling is used to lower power consumption or reduce heat. The ICH2 asserts STPCLK# to
throttle the processor clock and the processor appears to temporarily enter a C2 state. After a
programmable time, the ICH2 deasserts STPCLK# and the processor appears to return to the C0
state. This allows the processor to operate at reduced average power, with a corresponding decrease
in performance. Two methods are included to start throttling:
• Software enables a timer with a programmable duty cycle. The duty cycle is set by the
THTL_DTY field and the throttling is enabled using the THTL_EN field. This is known as
Manual Throttling. The period is fixed to be in the non-audible range, due to the nature of
switching power supplies.
• A Thermal Override condition (THRM# signal active for >2 seconds) occurs that
unconditionally forces throttling, independent of the THTL_EN bit. The throttling due to
Thermal Override has a separate duty cycle (THRM_DTY) which may vary by field and
system. The Thermal Override condition will end when THRM# goes inactive.
Throttling due to the THRM# signal has higher priority than the software-initiated throttling.
Throttling does not occur when the system is in a C2 state (C2 or C3 for the ICH2-M), even if
Thermal override occurs.
5.12.5.2
Transition Rules Among S0/Cx and Throttling States
The following priority rules and assumptions apply among the various S0/Cx and throttling states:
• Entry to any S0/Cx state is mutually exclusive with entry to any S1–S5 state. This is because
the processor can only perform one register access at a time and Sleep states have higher
priority than thermal throttling.
• When the SLP_EN bit is set (system going to a sleep state (S1–S5), the THTL_EN bit can be
internally treated as being disabled (no throttling while going to sleep state). Note that thermal
throttling (based on THRM# signal) cannot be disabled in an S0 state. However, once the
SLP_EN bit is set, the thermal throttling is shut off (since STPCLK# will be active in S1–S5
states).
• If the THTL_EN bit is set, and a Level 2 (Level 2 or Level 3 for the ICH2-M) read then occurs,
the system should immediately go and stay in a C2 (C2 or C3 for the ICH2-M) state until a
break event occurs. A Level 2 (Level 2 or Level 3 for the ICH2-M) read has higher priority
than the software-initiated throttling or thermal throttling.
• If Thermal Override is causing throttling and a Level 2 (Level 2 or Level 3 for the ICH2-M)
read then occurs, the system will stay in a C2 (C2 or C3 for the ICH2-M) state until a break
event occurs. A Level 2 (Level 2 or Level 3 for the ICH2-M) read has higher priority than the
Thermal Override.
• After an exit from a C2 (C2 or C3 for the ICH2-M) state (due to a Break event), and if the
THTL_EN bit is still set, or if a Thermal Override is still occurring, the system will continue to
throttle STPCLK#. Depending on the time of the break event, the first transition on STPCLK#
active can be delayed by up to one period.
• The Host controller must post Stop-Grant cycles in such a way that the processor gets an
indication of the end of the special cycle prior to the ICH2 observing the Stop-Grant cycle.
This ensures that the STPCLK# signals stays active for a sufficient period after the processor
observes the response phase.
• If in the C1 state and the STPCLK# signal goes active, the processor will generate a StopGrant cycle, and the system should go to the C2 state. When STPCLK# goes inactive, it should
return to the C1 state.
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Functional Description
5.12.6
Dynamic PCI Clock Control (82801BAM ICH2-M)
For the ICH2-M, the PCI clock can be dynamically controlled independent of any other lowpower state. This control is accomplished using the CLKRUN# protocol as described in the PCI
Mobile Design Guide, and is transparent to software.
The Dynamic PCI Clock control is handled using the following signals:
• CLKRUN#: Used by PCI and LPC peripherals to request the system PCI clock to run
• STP_PCI#: Used to stop the system PCI clock
Note: The 33 MHz clock to the ICH2-M is “free-running” and is not affected by the STP_PCI#
signal.
5.12.6.1
Conditions for Stopping the PCI Clock (82801BAM ICH2-M)
When there is a lack of PCI activity, the ICH2-M has the capability to stop the PCI clocks to
conserve power. “PCI activity” is defined as any activity that requires the PCI clock to be running.
Any of the following conditions indicates that it is NOT OK to stop the PCI clock:
•
•
•
•
Cycles on PCI or LPC
Cycles of any internal device that would need to go on the PCI bus
Cycles using PC/PCI DMA
SERIRQ activity
Behavioral Descripion
• When there is a lack of activity (as defined above) for 29 PCI clocks, the ICH2-M deassert
(drive high) CLKRUN# for 1 clock and then tri-state the signal.
5.12.6.2
Conditions for Maintaining the PCI Clock (82801BAM ICH2-M)
PCI master that wish to maintain the PCI clock running will observe the CLKRUN# signal
deasserted, and then must re-assert if (drive it low) within 3 clocks.
Behavioral Description
• When the ICH2-M has tri-stated the CLKRUN# signal after deasserting it, the ICH2-M then
checks to see if the signal has been re-asserted (externally).
• After observing the CLKRUN# signal asserted for 1 clock, the ICH2-M again starts asserting
the signal.
• If an internal device needs the PCI bus, the ICH2-M asserts the CLKRUN# signal.
5.12.6.3
Conditions for Stopping the PCI Clock (82801BAM ICH2-M)
Behavioral Description
• If no device re-asserts CLKRUN# once it has been deasserted for 3 clocks, the ICH2-M stops
the PCI clock by asserting the STP_PCI# signal to the clock synthesizer.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
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Functional Description
5.12.6.4
Conditions for Re-Starting the PCI Clock (82801BAM ICH2-M)
Behavioral Description
• A peripheral asserts CLKRUN# to indicate that it needs the PCI clock re-started.
• When the ICH2-M observes the CLKRUN# signal asserted for 1 (free running) clock, the
ICH2-M deasserts the STP_PCI# signal to the clock synthesizer within 4 (free running)
clocks.
• Observing the CLKRUN# signal asserted externally for 1 (free running) clock, the ICH2-M
again starts driving CLKRUN# asserted.
If an internal source requests the clock to be re-started, the ICH2-M re-asserts CLKRUN#, and
simultaneously deasserts the STP_PCI# signal.
5.12.6.5
Other Causes of CLKRUN# Going Active (82801BAM ICH2-M)
The following causes the ICH2-M to assert and/or maintain the CLKRUN# signal active (low):
• PC/PCI activity, which is started by one of the REQx# signals going active. It is expected that
a PC/PCI device asserts CLKRUN# prior to starting the start bit on the REQ# signal. Once the
start bit is recognized, the ICH2-M makes sure CLKRUN# goes active if it should go inactive
during the sequence.
• SERIRQ activity, which is started by the SERIRQ signal going low (in Quiet mode), or the
SERIRQ logic being in the Continuous Mode. It is expected that a SERIRQ device asserts
CLKRUN# prior to starting the start bit on the SEIRQ signal. Once the start bit is recognized,
the ICH2-M makes sure CLKRUN# goes active if it should go inactive during the sequence.
• Any internal or external bus master request, including LPC masters. Once the master request
is detected (via PCI REQ or LPC LDRQ[1:0]#), the ICH2-M maintains CLKRUN# active
until the end of the sequence. This includes:
— Any PCI REQ# low
— Bus Master or DMA request pending (having come in via LDRQ[1:0]#)
— Any cycle coming down from hub interface1 to PCI
— Any PCI cycle currently in progress. For example, cycle forward by the ICH2-M from
the hub interface to PCI, and then claimed by ICH2-M's PCI-to-LPC logic. That cycle
runs as a Delayed Transaction on PCI. CLKRUN# should stay low until the cycle
completes (without Delayed Transaction).
• Any bus master below PCI that needs to run a cycle. This could include the Front-Side-Bus
interrupt logic for the I/O APIC (if it is downstream of PCI).
5.12.6.6
LPC Devices and CLKRUN# (82801BAM ICH2-M)
If an LPC device (of any type) needs the 33 MHz PCI clock (e.g., for LPC DMA or LPC serial
interrupt), it can assert CLKRUN#. Note that LPC devices running DMA or bus master cycles do
not need to assert CLKRUN#, since the ICH2-M asserts it on their behalf.
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82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.12.7
Sleep States
The ICH2 directly supports different sleep states (S1–S5), which are entered by setting the
SLP_EN bit, or due to a Power Button press. The entry to the Sleep states are based on several
assumptions:
• Entry to a Cx state is mutually exclusive with entry to a Sleep state. This is because the
processor can only perform one register access at a time. A request to Sleep always has higher
priority than throttling.
• Prior to setting the SLP_EN bit, the software turns off processor-controlled throttling. Note
that thermal throttling cannot be disabled, but setting the SLP_EN bit will disable thermal
throttling (since S1–S5 sleep state has higher priority).
• The G3 state cannot be entered via any software mechanism. The G3 state indicates a
complete loss of power.
5.12.7.1
Initiating Sleep State
Sleep states (S1–S5) are initiated by:
• Masking interrupts, turning off all bus master enable bits, setting the desired type in the
SLP_TYP field, and then setting the SLP_EN bit. The hardware will then attempt to gracefully
put the system into the corresponding Sleep state by first going to a C2 (C2 or C3 for the
ICH2-M) state. See Section 5.12.5 for details on going to the C2 (C2 or C3 for the ICH2-M)
state.
• Pressing the PWRBTN# signal for more than 4 seconds to cause a Power Button Override
event. In this case the transition to the S5 state will be less graceful, since there will be no
dependencies on observing Stop-Grant cycles from the processor or on clocks other than the
RTC clock.
Table 5-41. Sleep Types
Sleep Type
S1
(ICH2 only)
S1
(ICH2-M only)
5.12.7.2
Comment
ICH2 asserts the CPUSLP# signal. This lowers the processor’s power consumption. No
snooping is possible in this state.
ICH2-M asserts the SLP_S1# signal. This can be connected to the system clock generator
to either put it into a low-power mode or to remove its power altogether. No snooping is
possible in this state.
S3
ICH2 asserts SLP_S3# (ICH2-M asserts SLP_S1# and SLP_S3#). The SLP_S3# signal
controls the power to non-critical circuits. Power is only be retained to devices needed to
wake from this sleeping state, as well as to the memory.
S4
ICH2 asserts SLP_S3# and SLP_S5# (ICH2-M asserts SLP_S1#, SLP_S3# and
SLP_S5#). The SLP_S5# signal shuts off the power to the memory subsystem. Only
devices needed to wake from this state should be powered.
S5
Same as S4. ICH2 asserts SLP_S3# and SLP_S5# (ICH2-M asserts SLP_S1#, SLP_S3#
and SLP_S5#). The SLP_S5# signal shuts off the power to the memory subsystem. Only
devices needed to wake from this state should be powered.
Exiting Sleep States
Sleep states (S10–S5) are exited based on Wake events. The Wake events will force the system to a
full on state (S0), although some non-critical subsystems might still be shut off and have to be
brought back manually. For example, the hard disk may be shut off during a sleep state, and have to
be enabled via a GPIO pin before it can be used.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-81
Functional Description
Upon exit from the ICH2-controlled Sleep states, the WAK_STS bit will be set. The possible
causes of Wake Events (and their restrictions) are shown in Table 5-42.
Notes:
• If in the S5 state due to a powerbutton override, the only wake event is power button.
• For the ICH2-M, if the BATLOW# signal is asserted, the ICH2-M will not attempt to wake
from an S1 (Mobile) – S5 state, even if the power button is pressed. This prevents the system
from waking when the battery power is insufficient to wake the system. Wake events that
occur while BATLOW# is asserted are latched by the ICH2-M, and the system wakes after
BATLOW# is deasserted.
Table 5-42. Causes of Wake Events
Cause
RTC Alarm
Power Button
GPI[0:n]
States Can
Wake From
S1–S5
(Note 1)
S1–S5
S1–S5
(Note 1)
How Enabled
Set RTC_EN bit in PM1_EN Register
Always enabled as Wake event
GPE1_EN register
USB
S1–S4
Set USB1_EN and USB2_EN bits in GPE0_EN Register
LAN
S1–S5
Will use PME#. Wake enable set with LAN logic.
RI#
S1–S5
(Note 1)
Set RI_EN bit in GPE0_EN Register
AC97
S1–S5
Set AC97_EN bit in GPE0_EN Register
PME#
S1–S5
(Note 1)
Set PME_EN bit in GPE0_EN Register.
GST Timeout
S1M
SMBALERT#
S1–S4
Setting the GST Timeout range to a value other than 00h.
SMB_WAK_EN in the GPE0 Register
SMBus Slave Message
S1–S5
Always enabled as a Wake Event
NOTES:
1. This will be a wake event from S5 only if the sleep state was entered by setting the SLP_EN and SLP_TYP
bits via software.
It is important to understand that the various GPIs have different levels of functionality when used
as wake events. The GPIs that reside in the core power well can only generate wake events from an
S1 state. Also, only certain GPIs are “ACPI Compliant,” meaning that their Status and Enable bits
reside in ACPI I/O space. Table 5-43 summarizes the use of GPIs as wake events.
Table 5-43. GPI Wake Events
GPI
Power Well
Wake From
GPI[7:0], GPI[23:16]
Core
S1
GPI[15:8]
Resume
S1–S5
Notes
ACPI Compliant
The latency to exit the various Sleep states varies greatly and is heavily dependent on power supply
design. Approximations are shown in Table 5-44. The time indicates from when the Wake event
occurs (signal transition) to when the processor is allowed to start its first cycle (CPURST# goes
inactive). There will be very large additional delays for the processor to execute sufficient amounts
of BIOS to invoke the OS (such as coming out of S1–S3) or spinning up the hard drive
(e.g., coming out of S4 or S5).
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82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
Table 5-44. Sleep State Exit Latencies
State
5.12.7.3
Latency
S1
<1 ms. Based on wake event to STPCLK# high + re-enumeration of PCI bus, USB, CardBus,
etc. Must also add PLL spin-up times.
S3
Power Supply ramp + 20 ms
S4
Power Supply ramp + 20 ms
S5
Power Supply ramp + 20 ms
Sx–G3–Sx, Handling Power Failures
82801BAM ICH2-M: A power failure in a mobile system is a rare event, since the power
subsystem should provide sufficient warning when the batteries are low. However, if the user
removes the battery or leaves the system in an STR state for too long, a power failure could occur.
82801BA ICH2: In desktop systems, power failures can occur if the AC power is cut (a real power
failure) or if the system is unplugged. In either case, PWROK and RSMRST# are assumed to go
low.
Depending on when the power failure occurs and how the system is designed, different transitions
can occur due to a power failure.
The AFTER_G3 bit provides the ability to program whether or not the system should boot once
power returns after a power loss event. If the policy is to not boot, the system remains in an S5 state
(unless previously in S4). There are only three possible events that will wake the system after a
power failure.
• PWRBTN#: PWRBTN# is always enabled as a wake event. When RSMRST# is low (G3
state), the PWRBTN_STS bit is reset. When the ICH2 exits G3 after power returns
(RSMRST# goes high), the PWRBTN# signal is already high (because Vcc-standby goes high
before RSMRST# goes high) and the PWRBTN_STS bit is 0.
• RI#: RI# does not have an internal pull-up. Therefore, if this signal is enabled as a wake event,
it is important to keep this signal powered during the power loss event. If this signal goes low
(active), when power returns, the RI_STS bit is set and the system interprets this as a wake
event.
• RTC Alarm: The RTC_EN bit is in the RTC well and is preserved after a power loss. Like
PWRBTN_STS the RTC_STS bit is cleared when RSMRST# goes low.
The ICH2 monitors both PWROK and RSMRST# to detect power failures. If PWROK goes low,
the PWROK_FLR bit is set. If RSMRST# goes low, PWR_FLR is set.
Note:
Although PME_EN is in the RTC well, this signal cannot wake the system after a power loss.
PME_EN and PME_STS bits are cleared by RSMRST#
Table 5-45. Transitions Due To Power Failure
State at Power Failure
AFTERG3_EN bit
Transition When Power Returns
S0, S1, S3
1
0
S5
S0
S4
1
0
S4
S0
S5
1
0
S5
S0
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-83
Functional Description
5.12.8
Thermal Management
The ICH2 has mechanisms to assist with managing thermal problems in the system.
5.12.8.1
THRM# Signal
The THRM# signal is used as a status input for a thermal sensor. Based on the THRM# signal
going active, the ICH2 generates an SMI# or SCI (depending on SCI_EN).
If the THRM_POL bit is set low, when the THRM# signal goes low, the THRM_STS bit will be
set. This is an indicator that the thermal threshold has been exceeded. If the THRM_EN bit is set,
then when THRM_STS goes active, either an SMI# or SCI is generated (depending on the SCI_EN
bit being set).
The power management software (BIOS or ACPI) can then take measures to start reducing the
temperature. Examples include shutting off unwanted subsystems, or halting the processor.
By setting the THRM_POL bit to high, another SMI# or SCI can optionally be generated when the
THRM# signal goes back high. This allows the software (BIOS or ACPI) to turn off the cooling
methods.
5.12.8.2
THRM# Initiated Passive Cooling
If the THRM# signal remains active for some time greater than 2 seconds and the ICH2 is in the
S0/G0/C0 state, then the ICH2 enters an auto-throttling mode, in which it provides a duty cycle on
the STPCLK# signal. This will reduce the overall power consumption by the system, and should
cool the system. The intended result of the cooling is that the THRM# signal should go back
inactive.
For all programmed values (001–111), THRM# going active will result in STPCLK# active for a
minimum time of 12.5% and a maximum of 87.5%. The period is 1024 PCI clocks. Thus, the
STPCLK# signal can be active for as little as 128 PCI clocks or as much as 896 PCI clocks. The
actual slowdown (and cooling) of the processor will depend on the instruction stream, because the
processor is allowed to finish the current instruction. Furthermore, the ICH2 waits for the STOPGRANT cycle before starting the count of the time the STPCLK# signal is active.
When THRM# goes inactive, throttling stops. In case that the ICH2 is already attempting throttling
because the THTL_EN bit is set, the duty cycle associated with the THRM# signal will have higher
priority. If the ICH2 is in the C2 (C2 and C3 for the ICH2-M) or S1–S5 states, then no throttling
will be caused by the THRM# signal being active.
5.12.8.3
THRM# Override Software Bit
The FORCE_THTL bit allows BIOS to force passive cooling, just as if the THRM# signal had
been active for 2 seconds. If this bit is set, the ICH2 starts throttling using the ratio in the
THRM_DTY field.
When this bit is cleared, the ICH2 stops throttling, unless the THRM# signal has been active for
2 seconds or if the THTL_EN bit is set (indicating that ACPI software is attempting throttling).
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82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.12.8.4
Processor-Initiated Passive Cooling (Via Programmed Duty Cycle on
STPCLK#)
Using the THTL_EN and THTL_DTY bits, the ICH2 can force a programmed duty cycle on the
STPCLK# signal. This reduces the effective instruction rate of the processor and cut its power
consumption and heat generation.
5.12.8.5
Active Cooling
Active cooling involves fans. The GPIO signals from the ICH2 can be used to turn on/off a fan.
5.12.9
Intel® SpeedStep™ Technology Protocol
(82801BAM ICH2-M only)
The Intel® SpeedStep™ technology feature enables a mobile system to operate in multiple
processor performance/thermal states and to transition smoothly between them. The internal
processor clock setting and processor supply voltage setting determines these states. The ICH2-M
supports one Low Power mode and one High Performance mode.
Figure 5-14. Intel® SpeedStep™ Block Diagram (82801BAM ICH2-M only)
CPUPERF#
SpeedStep™
Enabled M obile
Intel® Processors
CPUPW RGD
ST PCLK#
VddCore
ICH2-M
VGATE
Processor's
Voltage Regulator
Module (VRM)
PW ROK
GMUX SEL
From Main
Power Supply
5
VRCODE[4:0]
High Voltage
5
5
Low Voltage
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-85
Functional Description
5.12.9.1
Intel® SpeedStep™ Technology Processor Requirements
(82801BAM ICH2-M)
Non-Intel® SpeedStep™ technology processors use the A20M#, IGNNE#, NMI, and INTR input
signals to determine the multiplier used by the processor’s PLL for the internal clock. In firstgeneration Intel® SpeedStep™ technology processors, two multiplier values (one for the high
performance state, a second for the low power state) are hard-wired within the processor. The
ICH2-M CPUPERF signal is used to select the processor state, based on ICH2-M control logic.
The operating bus ratio must be available to the programmer and is, therefore, suggested that it be
read in a processor MSR. Also, the processor must return an indication that it is Intel®
SpeedStep™ technology enabled, which should be in the form of a status bit in a processor MSR
or in the CPUID register.
The ICH2-M is not capable of determining whether it is attached to a Intel® SpeedStep™ or nonIntel® SpeedStep™ processor. When used with a non-Intel® SpeedStep™ processor, software
should not write or read the ICH2-M Intel® SpeedStep™ registers.
5.12.9.2
Intel® SpeedStep™ Technology States (82801BAM ICH2-M)
The ICH2-M supports two system-level performance states: Low Power mode and High
Performance mode. Processor states are defined by valid combinations of core voltage levels and
core clock speeds. These processor states can be used to alter the processor and system
performance to conform to conditions of power and environment.
The Low Power mode is used primarily when the system is powered from the battery, with the
purpose being to maximize battery life. Mobile system performance is limited by thermal design
and battery capacity. To improve thermal capacity, active cooling solutions (e.g., a fan can be
used) in addition to a passive cooling solution.
The High Performance mode assume that the mobile system is powered from an external AC/DC
source. The purpose of this state is to maximize performance subject to thermal constraints. The
ICH2-M does not implement any restrictions on entry into High Performance mode. It will
unconditionally transition into High Performance mode upon software command.
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Functional Description
5.12.9.3
Voltage Regulator Interface (82801BAM ICH2-M)
The voltage regulator interface is critical to the Intel® SpeedStep™ technology concept. The
power dissipation of the processor is proportional to the internal clock speed and to the square of
the core supply voltage. As the internal clock speed of the processor changes, the minimum
required core voltage supply level also changes. The interface signals are designed to allow the
voltage regulator to change settings without causing a power-on reset.
• VRCODE[4:0] is a 5-bit input to the Voltage Regulator. These signals are not outputs from
the ICH2-M; instead, they are outputs from an external muliplexer. Future voltage regulators
may integrate this multiplexer.
• The SSMUXSEL# signal is an ICH2-M output. It can be used directly to control the external
muliplexer that selects the high or low values for VRCODE[4:0].
• VRON (aka PWROK from main power supply) is an input to the regulator. When VRON is
asserted, the regulator turns on and settles to the output defined by VRCODE[4:0].
VGATE is an input from the regulator indicating that all of the outputs from the regulator are on
and within specification. When the system is transitioning between performance states, the voltage
regulator output may be required to change. It is not desirable, however, that CPUPWRGOOD
becomes deasserted during these transitions. Normally, this would indicate to the system that a
power-on reset be performed, which would invalidate the system context. The ICH2-M prevents
this from occurring by maintaining CPUPWRGOOD during the transition. CPUPWRGOOD must
also be maintained during an S1 state.
5.12.10
Event Input Signals and Their Usage
The ICH2 has various input signals that trigger specific events. This section describes those signals
and how they should be used.
5.12.10.1
PWRBTN# — Power Button
The ICH2 PWRBTN# signal operates as a “Fixed Power Button” as described in the ACPI
specification. PWRBTN# signal has a 16 ms de-bounce on the input. The state transition
descriptions are included in the following table. Note that the transitions start as soon as the
PWRBTN# is pressed (but after the debounce logic), and does not depend on when the Power
Button is released.
Table 5-46. Transitions Due to Power Button
Present
State
Event
Transition/Action
Comment
S0/Cx
PWRBTN# goes low
SMI# or SCI generated
(depending on SCI_EN)
Software will typically initiate a
Sleep state.
S1–S5
PWRBTN# goes low
Wake Event. Transitions to S0
state.
Standard wakeup
G3
PWRBTN# pressed
None
PWRBTN# held low for
at least 4 consecutive
seconds
Unconditional transition to S5
state.
S0–S4
82801BA ICH2 and 82801BAM ICH2-M Datasheet
No effect since no power.
Not latched nor detected.
No dependence on processor
(such as Stop-Grant cycles) or
any other subsystem.
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Functional Description
Power Button Override Function
If PWRBTN# is observed active for at least 4 consecutive seconds, the state machine should
unconditionally transition to the G2/S5 state, regardless of present state (S0–S4). In this case, the
transition to the G2/S5 state should not depend on any particular response from the processor
(e.g., a Stop-Grant cycle), nor any similar dependency from any other subsystem.
The PWRBTN# status is readable to check if the button is currently being pressed or has been
released. The status is taken after the de-bounce, and is readable via the PWRBTN_LVL bit.
Note:
The 4-second PWRBTN# assertion should only be used if a system lock-up has occurred. The
4-second timer starts counting when the ICH2 is in a S0 state. If the PWRBTN# signal is asserted
and held active when the system is in a suspend state (S1–S5), the assertion causes a wake event.
Once the system has resumed to the S0 state, the 4-second timer starts.
Sleep Button
The ACPI specification defines an optional Sleep button. It differs from the power button in that it
only is a request to go from S0 to S1–S4 (not S5). Also, in an S5 state, the Power Button can wake
the system, but the Sleep Button cannot.
Although the ICH2 does not include a specific signal designated as a Sleep Button, one of the
GPIO signals can be used to create a “Control Method” Sleep Button. See the ACPI specification
for implementation details.
5.12.10.2
RI# — Ring Indicate
The Ring Indicator can cause a wake event (if enabled) from the S1–S5 states. Table 5-47 shows
when the wake event is generated or ignored in different states. If in the G0/S0/Cx states, the ICH2
generates an interrupt based on RI# active and the interrupt is set up as a break event.
Table 5-47. Transitions Due to RI# signal
Note:
5.12.10.3
Present State
Event
RI_EN
Event
S0
RI# Active
X
Ignored
S1–S5
RI# Active
0
Ignored
1
Wake Event
Filtering/Debounce on RI# will not be done in ICH2. Can be in modem or external.
PME# — PCI Power Management Event
The PME# signal comes from a PCI device to request that the system be restarted. The PME#
signal can generate an SMI#, SCI, or optionally a Wake event. The event occurs when the PME#
signal goes from high to low. No event is caused when it goes from low to high.
5.12.10.4
AGPBUSY# (82801BAM ICH2-M)
The AGPBUSY# signal is an input from the AGP graphics component to indicate if it is busy. If
prior to going to the C3 state the AGPBUSY# signal is active, then the BM_STS bit will be set. If
after going to the C3 state, the AGPBUSY# signal goes back active, the ICH2-M will treat this as
if one of the PCI REQ# signals went active. This will be treated as a break event.
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82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.12.11
Alt Access Mode
Before entering a low power state, several registers from powered down parts may need to be
saved. In the majority of cases, this is not an issue, as registers have read and write paths. However,
several of the ISA compatible registers are either read only or write only. To get data out of writeonly registers and to restore data into read-only registers, the ICH2 implements an alternate access
mode.
5.12.11.1
Write Only Registers with Read Paths in Alternate Access Mode
The registers described in the following table have read paths in alternate access mode. The access
number field in the table indicates which register will be returned per access to that port.
Table 5-48. Write Only Registers with Read Paths in Alternate Access Mode
Restore Data
I/O
Addr
00h
01h
02h
03h
04h
05h
06h
07h
# of
Rds
Access
Restore Data
Data
I/O
Addr
# of
Rds
Access
Data
1
DMA Chan 0 base
address low byte
1
Timer Counter 0 status, bits
[5:0]
2
DMA Chan 0 base
address high byte
2
Timer Counter 0 base count low
byte
1
DMA Chan 0 base count
low byte
3
Timer Counter 0 base count
high byte
2
DMA Chan 0 base count
high byte
4
Timer Counter 1 base count low
byte
1
DMA Chan 1 base
address low byte
5
Timer Counter 1 base count
high byte
2
DMA Chan 1 base
address high byte
6
Timer Counter 2 base count low
byte
1
DMA Chan 1 base count
low byte
7
Timer Counter 2 base count
high byte
2
DMA Chan 1 base count
high byte
41h
1
Timer Counter 1 status, bits
[5:0]
1
DMA Chan 2 base
address low byte
42h
1
Timer Counter 2 status, bits
[5:0]
2
DMA Chan 2 base
address high byte
70h
1
Bit 7 = NMI Enable,
Bits [6:0] = RTC Address
1
DMA Chan 2 base count
low byte
2
DMA Chan 2 base count
high byte
1
DMA Chan 3 base
address low byte
2
DMA Chan 3 base
address high byte
1
DMA Chan 3 base count
low byte
2
DMA Chan 3 base count
high byte
2
2
2
2
2
2
2
2
82801BA ICH2 and 82801BAM ICH2-M Datasheet
40h
C4h
C6h
C8h
7
1
DMA Chan 5 base address low
byte
2
DMA Chan 5 base address high
byte
1
DMA Chan 5 base count low
byte
2
DMA Chan 5 base count high
byte
1
DMA Chan 6 base address low
byte
2
DMA Chan 6 base address high
byte
2
2
2
5-89
Functional Description
Table 5-48. Write Only Registers with Read Paths in Alternate Access Mode (Continued)
Restore Data
I/O
Addr
08h
20h
# of
Rds
Access
Restore Data
Data
1
DMA Chan 0–3
Command2
2
I/O
Addr
# of
Rds
Access
Data
1
DMA Chan 6 base count low
byte
DMA Chan 0–3 Request
2
DMA Chan 6 base count high
byte
3
DMA Chan 0 Mode:
Bits(1:0) = “00”
1
DMA Chan 7 base address low
byte
4
DMA Chan 1 Mode:
Bits(1:0) = “01”
2
DMA Chan 7 base address high
byte
5
DMA Chan 2 Mode:
Bits(1:0) = “10”
1
DMA Chan 7 base count low
byte
6
DMA Chan 3 Mode:
Bits(1:0) = “11”.
2
DMA Chan 7 base count high
byte
1
PIC ICW2 of Master
controller
1
DMA Chan 4–7 Command2
2
PIC ICW3 of Master
controller
2
DMA Chan 4–7 Request
3
PIC ICW4 of Master
controller
3
DMA Chan 4 Mode:
Bits(1:0) = “00”
4
PIC OCW1 of Master
controller1
4
DMA Chan 5 Mode:
Bits(1:0) = “01”
5
PIC OCW2 of Master
controller
5
DMA Chan 6 Mode:
Bits(1:0) = “10”
6
PIC OCW3 of Master
controller
6
DMA Chan 7 Mode:
Bits(1:0) = “11”.
7
PIC ICW2 of Slave
controller
8
PIC ICW3 of Slave
controller
9
PIC ICW4 of Slave
controller
10
PIC OCW1 of Slave
controller1
11
PIC OCW2 of Slave
controller
12
PIC OCW3 of Slave
controller
6
12
CAh
CCh
CEh
D0h
2
2
2
6
NOTE:
1. The OCW1 register must be read before entering Alternate Access Mode.
2. Bits 5, 3, 1, and 0 return 0.
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82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.12.11.2
PIC Reserved Bits
Many bits within the PIC are reserved, and must have certain values written for the PIC to operate
properly. Therefore, there is no need to return these values in alternate access mode. When reading
PIC registers from 20h and A0h, the reserved bits shall return the values listed in Table 5-49.
Table 5-49. PIC Reserved Bits Return Values
5.12.11.3
PIC Reserved Bits
Value Returned
ICW2(2:0)
000
ICW4(7:5)
000
ICW4(3:2)
00
ICW4(0)
0
OCW2(4:3)
00
OCW3(7)
0
OCW3(5)
Reflects bit 6
OCW3(4:3)
01
Read Only Registers with Write Paths in Alternate Access Mode
The registers described in Table 5-50 have write paths alternate access mode. Software restores
these values after returning from a powered down state. These registers must be handled specially
by software. When in normal mode, writing to the Base Address and Count Register also writes to
the Current Address and Count Register. Therefore, the Base Address and Count must be written
first, then the part is put into alternate access mode and the Current Address and Count Register is
written.
Table 5-50. Register Write Accesses in Alternate Access Mode
I/O Address
5.12.12
Register Write Value
08h
DMA Status Register for channels 0–3.
D0h
DMA Status Register for channels 4–7.
System Power Supplies, Planes, and Signals
Power Plane Control with SLP_S3# and SLP_S5#
The SLP_S3# output signal can be used to cut power to the system core supply, since it will only go
active for the STR state (typically mapped to ACPI S3). Power must be maintained to the ICH2
Resume Well, and to any other circuits that need to generate Wake signals from the STR state.
Cutting power to the core may be done via the power supply, or by external FETs to the
motherboard. The SLP_S5# output signal can be used to cut power to the system core supply, as
well as power to the system memory, since the context of the system is saved on the disk. Cutting
power to the memory may be done via the power supply, or by external FETs to the motherboard.
SLP_S1# Signal (82801BAM ICH2-M)
For the ICH2-M, the SLP_S1# output signal will typically be connected to the clock synthesizer’s
PWRDWN# input to stop the clock synthesizer’s PLL. Alternative implementations may use this
signal to cut power to non-critical subsystems while in the S1 state.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-91
Functional Description
PWROK Signal
The PWROK input should go active based on the core supply voltages becoming valid. PWROK
should go active no sooner than 10 ms after Vcc3_3 and VCC1_8 have reached their nominal
values.
Note:
Traditional designs have a reset button logically AND’d with the PWROK signal from the power
supply and the processor’s voltage regulator module. If this is done with the ICH2, the
PWROK_FLR bit will be set. The ICH2 treats this internally as if the RSMRST# signal had gone
active. However, it is not treated as a full power failure. If PWROK goes inactive and then active
(but RSMRST# stays high), the ICH2 reboots (regardless of the state of the AFTERG3 bit). If the
RSMRST# signal also goes low before PWROK goes high, this is a full power failure and the
reboot policy is controlled by the AFTERG3 bit.
VRMPWRGD Signal
This signal is connected to the processor’s VRM and is internally AND’d with the PWROK signal
that comes from the system power supply. This is needed for Intel® SpeedStepTM technology
support in mobile systems (ICH2-M 82801BAM) and saves the external AND gate found in
desktop systems (82801BA ICH2).
BATLOW#—Battery Low (82801BAM ICH2-M)
For the ICH2-M, the BATLOW# input can inhibit waking from a sleep state if there is not
sufficient power. It will also cause an SMI#, if the system is already in an S0 state.
Controlling Leakage and Power Consumption During Low-Power States
To control leakage in the system, various signals will tri-state or go low during some low-power
states.
General principles
• All signals going to powered down planes (either internally or externally) must be either tristated or driven low.
• Signals with pull-up resistors should not be low during low-power states. This is to avoid the
power consumed in the pull-up resistor.
• Buses should be halted (and held) in a known state to avoid a floating input (perhaps to some
other device). Floating inputs can cause extra power consumption.
Based on the above principles, the following measures are taken:
• During C2 or S3 state (C2, S3, or C3 state for ICH2-M), the processor signals that have pullups will be tri-stated or driven low.
• During S3 (STR), all signals attached to powered down planes will be tri-stated or driven low.
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82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.12.13
Clock Generators
The clock generator is expected to provide the frequencies shown in Table 5-51.
Table 5-51. ICH2 Clock Inputs
Clock
Domain
CLK66
Frequency
Source
66 MHz
Main Clock
Generator
Usage
Should be running in all Cx states. Stopped in S3 ~ S5
based on SLP_S3# assertion.
82801BAM ICH2-M: It is also stopped in the S1 state based
on the assertion of SLP_S1# assertion.
Free-running PCI Clock to ICH2. Stopped in S3 ~ S5 based
on SLP_S3# assertion.
PCICLK
CLK48
CLK14
AC_BIT_CLK
APICCLK
LAN_CLK
5.12.13.1
33 MHz
Main Clock
Generator
48 MHz
Main Clock
Generator
14.318 MHz
12.288 MHz
Main Clock
Generator
AC’97 Codec
16.67 MHz
or 33 MHz
Main Clock
Generator
0.8 to
50 MHz
LAN Connect
82801BAM ICH2-M: Free-running (not affected by
STP_PCI#) PCI Clock to ICH2-M. This is not the system PCI
clock. This clock must keep running in S0 while the system
PCI clock may stop based on CLKRUN# protocol . This clock
is stopped in S1 based on SLP_S1# assertion. Stopped in
S3 ~ S5 based on SLP_S3# assertion.
Used by USB Controllers. Stopped in S3 ~ S5 based on
SLP_S3# assertion.
82801BAM ICH2-M: This clock is also stopped in S1 based
on SLP_S1# assertion.
Used by ACPI timers. Stopped in S3 ~ S5 based on
SLP_S3# assertion.
82801BAM ICH2-M: This clock is also stopped in S1 based
on SLP_S1# assertion.
AC’97 Link. Control policy is determined by the clock source.
Used for ICH2-processor interrupt messages. Should be
running in C0, C1 and C2. Stopped in S3 ~ S5 based on
SLP_S3# assertion.
82801BAM ICH2-M: Also stopped in C3 based on
STP_CPU# assertion. Stopped in S1 based on SLP_S1#
assertion.
LAN Connect link. Control policy is determined by the clock
source.
Clock Control Signals from ICH2-M to Clock Synthesizer
(82801BAM ICH2-M only)
The clock generator is assumed to have direct connect from the following ICH2-M signals:
• STP_CPU# Stops CPU clocks in C3 state
• STP_PCI# Stops system PCI clocks (not the ICH2-m free-running 33 MHz clock) due to
CLKRUN# protocol
• SLP_S1# Stops all clocks in S1
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-93
Functional Description
5.12.14
Legacy Power Management Theory of Operation
Instead of relying on ACPI software, legacy power management uses BIOS and various hardware
mechanisms. ICH2 has a greatly simplified method for legacy power management compared with
previous generations (e.g., PIIX4).
The scheme relies on the concept of detecting when individual subsystems are idle, detecting when
the whole system is idle, and detecting when accesses are attempted to idle subsystems.
However, the operating system is assumed to be at least APM enabled. Without APM calls, there is
no quick way to know when the system is idle between keystrokes. The ICH2 does not support the
burst modes found in previous components (e.g., PIIX4).
5.12.14.1
Desktop APM Power Management (82801BA ICH2 only)
The ICH2 has a timer that, when enabled by the 1MIN_EN bit in the SMI Control and Enable
Register, generates an SMI# once per minute. The SMI handler can check for system activity by
reading the DEVACT_STS register. If none of the system bits are set, the SMI handler can
increment a software counter. When the counter reaches a sufficient number of consecutive
minutes with no activity, the SMI handler can then put the system into a lower power state.
If there is activity, various bits in the DEVACT_STS register are set. Software clears the bits by
writing a 1 to the bit position.
The DEVACT_STS Register allows for monitoring various internal devices, or Super I/O devices
(SP, PP, FDC) on LPC or PCI, keyboard controller accesses, or audio functions on LPC or PCI.
Other PCI activity can be monitored by checking the PCI interrupts.
5.12.14.2
Mobile APM Power Management (82801BAM ICH2-M only)
In mobile systems, there are additional requirements associated with device power management.
To handle this, the ICH2-M has specific SMI# traps available. The following algorithm is used:
1. The periodic SMI# timer checks if a device is idle for the require time. If so, it puts to the
device into a low-power states and sets the associated SMI# trap.
2. When software (not the SMI# handler) attempts to access the device, a trap occurs (the cycle
doesn’t really go to the device and an SMI# is generated).
3. The SMI# handler turns on the device and turns off the trap
The SMI# handler exits with an I/O restart. This allows the original software to continue.
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82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.13
System Management (D31:F0)
The ICH2 provides various functions to make a system easier to manage and to lower the Total
Cost of Ownership (TCO) of the system. Features and functions can be augmented via external
A/D converters and GPIO, as well as an external microcontroller. The following features and
functions are supported by the ICH2:
• Processor present detection.
•
•
•
Note:
5.13.1
— Detects if processor fails to fetch the first instruction after reset.
Various Error detection (e.g., ECC Errors) indicated by Host Controller
— Can generate SMI#, SCI, SERR, NMI, or TCO interrupt
Intruder Detect input
— Can generate TCO interrupt or SMI# when the system cover is removed.
— INTRUDER# allowed to go active in any power state, including G3.
Detection of bad FWH programming
— Detects if data on first read is FFh (indicates unprogrammed FWH)
Voltage ID from the processor can be read via GPI signals.
Theory of Operation
The System Management functions are designed to allow the system to diagnose failing
subsystems. The intent of this logic is that some of the system management functionality be
provided without the aid of an external microcontroller.
Detecting a System Lockup
When the processor is reset, it is expected to fetch its first instruction. If the processor fails to fetch
the first instruction after reset, the TCO timer times out twice and the ICH2 asserts PCIRST#.
Handling an Intruder
The ICH2 has an input signal (INTRUDER#) that can be attached to a switch that is activated by
the system’s case being open. This input has a 2 RTC clock debounce. If INTRUDER# goes active
(after the debouncer), this will set the INTRD_DET bit in the TCO_STS register. The INTRD_SEL
bits in the TCO_CNT register can enable the ICH2 to cause an SMI# or interrupt. The BIOS or
interrupt handler can then cause a transition to the S5 state by writing to the SLP_EN bit.
The software can also directly read the status of the INTRUDER# signal (high or low) by clearing
and then reading the INTRD_DET bit. This allows the signal to be used as a GPI if the intruder
function is not required.
Note:
The INTRD_DET bit resides in the ICH2’s RTC well, and is set and cleared synchronously with
the RTC clock. Thus, when software attempts to clear INTRD_DET (by writing a “1” to the bit
location) there may be as much as 2 RTC clocks (about 65 µs) delay before the bit is actually
cleared. Also, the INTRUDER# signal should be asserted for a minimum of 1 ms to guarantee that
the INTRD_DET bit will be set.
Note:
If the INTRUDER# signal is still active when software attempts to clear the INTRD_DET bit, the
bit will remain set and the SMI will be generated again immediately. The SMI handler can clear the
INTRD_SEL bits to avoid further SMIs. However, if the INTRUDER# signal goes inactive and
then active again, there will not be further SMIs, since the INTRD_SEL bits would select that no
SMI# be generated.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-95
Functional Description
Detecting Improper FWH Programming
The ICH2 can detect the case where the FWH is not programmed. This results in the first
instruction fetched to have a value of FFh. If this occurs, the ICH2 sets the BAD_BIOS bit, which
can then be reported via the Heartbeat and Event reporting using an external, Alert on LAN*
enabled LAN Controller (See Section 5.13.2).
Handling an ECC Error or Other Memory Error
The Host Controller provides a message to indicate that it would like to cause an SMI#, SCI,
SERR#, or NMI. The software must check the Host Controller as to the exact cause of the error.
5.13.2
Alert on LAN*
The ICH2 integrated LAN controller supports Alert on LAN* functionality when used with the
82562EM Platform LAN Connect component. This allows the integrated LAN controller to report
messages to a network management console without the aid of the system processor. This is crucial
in cases where the processor is malfunctioning or cannot function due to being in a low-power
state.
The ICH2 also features an independent, dedicated SMBus interface, referred to as the SMLINK
interface that can be used with an external Alert on LAN* (or Alert on LAN 2*) enabled LAN
Controller. This separate interface is required, since devices on the system SMBus will be powered
down during some low power states.
The basic scheme is for the ICH2 integrated LAN Controller to send a prepared Ethernet message
to a network management console. The prepared message is stored in the non-volatile EEPROM
that is connected to the ICH2.
Messages are sent by the LAN Controller either because a specific event has occurred or they are
sent periodically (also known as a heartbeat). The event and heartbeat messages have the exact
same format. The event messages are sent based on events occurring. The heartbeat messages are
sent every 30 to 32 seconds. When an event occurs, the ICH2 sends a new message and increments
the SEQ[3:0] field. For heartbeat messages, the sequence number does not increment.
If the policy is for the ICH2 to reboot the system after a hardware lockup, the ICH2 does not
immediately send an Alert on LAN* message. It first attempts to reboot the processor and let the
BIOS perform the appropriate recovery (and potentially send the message). However, if the boot
fails, the ICH2 sends the message.
If the policy is for the ICH2 not to reboot after a hardware lockup, the ICH2 sends an Alert on
LAN* message with the Watchdog (WD) Event Status bit set. This message is sent as soon as the
lockup is detected. The message is sent with the next incremented sequence number. If a system is
locked, the ICH2 continues sending the Alert on LAN* messages every heartbeat period
(30–32 seconds) unless one of the following occurs:
• The system is suspended via a PowerButton Override.
• The NO_REBOOT bit (D31:F0, offset D4h, bit 1) is set and the system is reset using PWROK,
or the system is reset remotely by SMLINK SMBus Slave write and BIOS clears the
SECOND_TO_STS bit before a TCO timeout can occur.
• The NO_REBOOT bit (D31:F0, offset D4h, bit 1) is not set causing the system to reboot
automatically.
If another event occurs prior to a power button override, the ICH2 will send another Alert on LAN*
message with the next incremented sequence number and appropriate status bit set.
5-96
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
If a boot is unsuccessful (processor does not fetch the first instruction), then the ICH2 will send an
Alert on LAN* message with the processor event status bit set and the next incremented sequence
number. This message will be sent as soon as the lockup is detected (2 TCO timer time-outs).
If the system is in a G1 (S1–S4) state the ICH2 will send a heartbeat message every 30–32 seconds.
If an event occurs prior to the system being shutdown, the ICH2 immediately sends an event
message with the next incremented sequence number. After the event message, the ICH2 resumes
sending heartbeat messages.
Note:
Normally, the ICH2 does not send heartbeat messages while in the G0 state (except in the case of a
lockup). However, if a hardware event (or heartbeat) occurs just as the system is transitioning into
a G0 state, the hardware continues to send the message even though the system is in a G0 state (and
the status bits may indicate this).
When used with an external Alert on LAN* enabled LAN controller, the ICH2 sends these
messages via the SMLINK signals. When sending messages via these signals, the ICH2 abides by
the SMBus rules associated with collision detection. It delays starting a message until the bus is
idle and detects collisions. If a collision is detected, the ICH2 waits until the bus is idle and tries
again. Table 5-52 shows the data included in the Alert on LAN* messages.
Table 5-52. Alert on LAN* Message Data
Field
Comment
Cover Tamper Status
1 = This bit will be set if the intruder detect bit is set (INTRD_DET).
Temp Event Status
1 = This bit will be set if the ICH2THERM# input signal is asserted.
Processor Missing Event
Status
1 = This bit will be set if the processor failed to fetch the first instruction.
TCO Timer Event Status
1 = This bit is set when the TCO timer expires.
Software Event Status
1 = This bit is set when software writes a 1 to the SEND_NOW bit.
Unprogrammed FWH Event
Status
1 = First BIOS fetch returned a value of FFh, indicating that the FWH has not
yet been programmed (still erased).
GPIO Status
1 = This bit is set when GPIO[11] signal is high.
0 = This bit is cleared when GPIO[11] signal is low.
SEQ[3:0]
This is a sequence number. It will initially be 0, and will increment each time the
ICH2 sends a new message. Upon reaching 1111, then the sequence number
will roll over to 0000. MSB (SEQ3) sent first.
System Power State
00 = G0, 01 = G1, 10 = G2, 11 = Pre-Boot. MSB sent first
MESSAGE1
Same as the MESSAGE1 Register. MSB sent first.
MESSAGE2
Same as the MESSAGE2 Register. MSB sent first.
WDSTATUS
Same as the WDSTATUS Register. MSB sent first.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-97
Functional Description
5.14
General Purpose I/O
Power Wells
Some GPIOs exist in the resume power plane. Care must be taken to make sure GPIO signals are
not driven high into powered-down planes.
Some ICH2 GPIOs may be connected to pins on devices that exist in the core well. If these GPIOs
are outputs, there is a danger that a loss of core power (PWROK low) or a Power Button Override
event will result in the ICH2 driving a pin to a logic 1 to another device that is powered down.
SMI# and SCI Routing
The routing bits for GPIO[13:11,8:6,4:3,1:0] (GPIO[13:11,8:7,4:3,1:0] for the ICH2-M) allow an
input to be routed to SMI# or SCI, or neither. Note that a bit can be routed to either an SMI# or an
SCI, but not both.
Power Wells
GPIO[13:11,8:6,4:3,1] (GPIO[13:11,8:7,4:3,1:0] for the ICH2-M) have "sticky" bits on the input.
Refer to the GPE1_STS register. As long as the signal goes active for at least 2 clocks, the ICH2
will keep the sticky status bit active. The active level can be selected in the GP_LVL register.
For the 82801BA ICH2, if the system is in an S0 or an S1 state, the GPI inputs are sampled at
33 MHz, so the signal only needs to be active for about 60 ns to be latched. In the S3–S5 states,
the GPI inputs are sampled at 32.768 KHz, and thus must be active for at least 61 microseconds to
be latched.
For the 82801BAM ICH2-M, if the system is in an S0 state, the GPI inputs are sampled at
33 MHz, so the signal only needs to be active for about 60 ns to be latched. In the S1 or S3–S5
states, the GPI inputs are sampled at 32.768 KHz, and thus must be active for at least
61 microseconds to be latched.
If the input signal is still active when the latch is cleared, it will again be set. Another edge trigger
is not required. This makes these signals "level" triggered inputs.
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82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.15
IDE Controller (D31:F1)
The ICH2 IDE controller features two sets of interface signals (Primary and Secondary) that can be
independently enabled, tri-stated or driven low.
The IDE interfaces of the ICH2 can support several types of data transfers:
• Programmed I/O (PIO): Processor is in control of the data transfer.
• 8237 style DMA: DMA protocol that resembles the DMA on the ISA bus, although it does not
use the 8237 in the ICH2. This protocol off loads the processor from moving data. This allows
higher transfer rate of up to 16 MB/s.
• Ultra ATA/33: DMA protocol that redefines signals on the IDE cable to allow both host and
target throttling of data and transfer rates of up to 33 MB/s.
• Ultra ATA/66: DMA protocol that redefines signals on the IDE cable to allow both host and
target throttling of data and transfer rates of up to 66 MB/s.
• Ultra ATA/100: DMA protocol that redefines signals on the IDE cable to allow both host and
target throttling of data and transfer rates of up to 100 MB/s.
5.15.1
PIO Transfers
The ICH2 IDE controller includes both compatible and fast timing modes. The fast timing modes
can be enabled only for the IDE data ports. All other transactions to the IDE registers are run in
single transaction mode with compatible timings.
Up to 2 IDE devices may be attached per IDE connector (drive 0 and drive 1). The IDETIM and
SIDETIM Registers permit different timing modes to be programmed for drive 0 and drive 1 of the
same connector.
The Ultra ATA/33/66/100 synchronous DMA timing modes can also be applied to each drive by
programming the IDE I/O Configuration register and the Synchronous DMA Control and Timing
registers. When a drive is enabled for synchronous DMA mode operation, the DMA transfers are
executed with the synchronous DMA timings. The PIO transfers are executed using compatible
timings or fast timings if also enabled.
PIO IDE Timing Modes
IDE data port transaction latency consists of startup latency, cycle latency, and shutdown latency:
• Startup latency is incurred when a PCI master cycle targeting the IDE data port is decoded and
the DA[2:0] and CSxx# lines are not set up. Startup latency provides the setup time for the
DA[2:0] and CSxx# lines prior to assertion of the read and write strobes (DIOR# and
DIOW#).
• Cycle latency consists of the I/O command strobe assertion length and recovery time.
Recovery time is provided so that transactions may occur back-to-back on the IDE interface
(without incurring startup and shutdown latency) without violating minimum cycle periods for
the IDE interface. The command strobe assertion width for the enhanced timing mode is
selected by the IDETIM Register and may be set to 2, 3, 4, or 5 PCI clocks. The recovery time
is selected by the IDETIM Register and may be set to 1, 2, 3, or 4 PCI clocks.
If IORDY is asserted when the initial sample point is reached, no wait states are added to the
command strobe assertion length. If IORDY is negated when the initial sample point is
reached, additional wait states are added. Since the rising edge of IORDY must be
synchronized, at least two additional PCI clocks are added.
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5-99
Functional Description
• Shutdown latency is incurred after outstanding scheduled IDE data port transactions (either a
non-empty write post buffer or an outstanding read prefetch cycles) have completed and
before other transactions can proceed. It provides hold time on the DA[2:0] and CSxx# lines
with respect to the read and write strobes (DIOR# and DIOW#). Shutdown latency is 2 PCI
clocks in duration.
The IDE timings for various transaction types are shown in Table 5-53. Note that bit 2 (16 bit I/O
recovery enable) of the ISA I/O Recovery Timer Register does not add wait states to IDE data port
read accesses when any of the fast timing modes are enabled.
Table 5-53. IDE Transaction Timings (PCI Clocks)
Startup
Latency
IORDY Sample
Point (ISP)
Recovery Time
(RCT)
Shutdown
Latency
Non-Data Port Compatible
4
11
22
2
Data Port Compatible
3
6
14
2
Fast Timing Mode
2
2–5
1–4
2
IDE Transaction Type
IORDY Masking
The IORDY signal can be ignored and assumed asserted at the first IORDY Sample Point (ISP) on
a drive by drive basis via the IDETIM Register.
PIO 32 Bit IDE Data Port Accesses
A 32-bit PCI transaction run to the IDE data address (01F0h primary, 0170h secondary) results in
two back-to-back 16-bit transactions to the IDE data port. The 32-bit data port feature is enabled
for all timings, not just enhanced timing. For compatible timings, a shutdown and startup latency is
incurred between the two 16-bit halves of the IDE transaction. This guarantees that the chip selects
will be deasserted for at least 2 PCI clocks between the 2 cycles.
PIO IDE Data Port Prefetching and Posting
The ICH2 can be programmed via the IDETIM registers to allow data to be posted to and
prefetched from the IDE data ports.
Data prefetching is initiated when a data port read occurs. The read prefetch eliminates latency to
the IDE data ports and allows them to be performed back to back for the highest possible PIO data
transfer rates. The first data port read of a sector is called the demand read. Subsequent data port
reads from the sector are called prefetch reads. The demand read and all prefetch reads much be of
the same size (16 or 32 bits).
Data posting is performed for writes to the IDE data ports. The transaction is completed on the PCI
bus after the data is received by the ICH2. The ICH2 then runs the IDE cycle to transfer the data to
the drive. If the ICH2 write buffer is non-empty and an unrelated (non-data or opposite channel)
IDE transaction occurs, that transaction is stalled until all current data in the write buffer is
transferred to the drive.
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Functional Description
5.15.2
Bus Master Function
The ICH2 can act as a PCI Bus master on behalf of an IDE slave device. Two PCI Bus master
channels are provided, one channel for each IDE connector (primary and secondary). By
performing the IDE data transfer as a PCI Bus master, the ICH2 off-loads the processor and
improves system performance in multitasking environments. Both devices attached to a connector
can be programmed for bus master transfers, but only one device per connector can be active at a
time.
Physical Region Descriptor Format
The physical memory region to be transferred is described by a Physical Region Descriptor (PRD).
The PRDs are stored sequentially in a Descriptor Table in memory. The data transfer proceeds until
all regions described by the PRDs in the table have been transferred. Note that the ICH2 bus master
IDE function does not support memory regions or Descriptor tables located on ISA.
Descriptor Tables must be aligned on 64 KB boundaries. Each PRD entry in the table is 8 bytes in
length. The first 4 bytes specify the byte address of a physical memory region. This memory region
must be DWord aligned and must not cross a 64 KB boundary. The next two bytes specify the size
or transfer count of the region in bytes (64 KB limit per region). A value of zero in these two bytes
indicates 64 KB (thus the minimum transfer count is 1). If bit 7 (EOT) of the last byte is a 1, it
indicates that this is the final PRD in the Descriptor table. Bus master operation terminates when
the last descriptor has been retired.
When the Bus Master IDE controller is reading data from the memory regions, bit 1 of the Base
Address is masked and byte enables are asserted for all read transfers. When writing data, bit 1 of
the Base Address is not masked and if set, causes the lower Word byte enables to be deasserted for
the first DWord transfer. The write to PCI typically consists of a 32-byte cache line. If valid data
ends prior to end of the cache line, the byte enables will be deasserted for invalid data.
The total sum of the byte counts in every PRD of the descriptor table must be equal to or greater
than the size of the disk transfer request. If greater than the disk transfer request, the driver must
terminate the bus master transaction (by setting bit 0 in the Bus Master IDE Command Register to
0) when the drive issues an interrupt to signal transfer completion.
Figure 5-15. Physical Region Descriptor Table Entry
Main Memory
Byte 3
Byte 2
Byte 1
Byte 0
Memory Region Physical Base Address [31:1]
EOT
Reserved
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Byte Count [15:1]
Main Region
0
0
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Functional Description
Line Buffer
A single line buffer exists for the ICH2 Bus master IDE interface. This buffer is not shared with
any other function. The buffer is maintained in either the read state or the write state. Memory
writes are typically 4-DWord bursts and invalid DWords have C/BE[3:0]#=0Fh. The line buffer
allows burst data transfers to proceed at peak transfer rates.
The Bus Master IDE Active bit in Bus Master IDE Status register is reset automatically when the
controller has transferred all data associated with a Descriptor Table (as determined by EOT bit in
last PRD). The IDE Interrupt Status bit is set when the IDE device generates an interrupt. These
events may occur prior to line buffer emptying for memory writes. If either of these conditions
exist, all PCI Master non-memory read accesses to ICH2 are retried until all data in the line buffers
has been transferred to memory.
Bus Master IDE Timings
The timing modes used for Bus Master IDE transfers are identical to those for PIO transfers. The
DMA Timing Enable Only bits in IDE Timing register can be used to program fast timing mode for
DMA transactions only. This is useful for IDE devices whose DMA transfer timings are faster that
its PIO transfer timings. The IDE device DMA request signal is sampled on the same PCI clock
that DIOR# or DIOW# is deasserted. If inactive, the DMA Acknowledge signal is deasserted on
the next PCI clock and no more transfers take place until DMA request is asserted again.
Interrupts
The ICH2 is connected to IRQ14 for the primary interrupt and IRQ15 for the secondary interrupt.
This connection is done from the ISA pin, before any mask registers. This implies the following:
• Bus Master IDE is operating under an interrupt based driver. Therefore, it does not operate
under environments where the IDE device drives an interrupt but the interrupt is masked in the
system.
• Bus Master IDE devices are connected directly off of ICH2. IDE interrupts cannot be
communicated through PCI devices or the serial stream.
Bus Master IDE Operation
To initiate a bus master transfer between memory and an IDE device, the following steps are
required:
1. Software prepares a PRD Table in system memory. The PRD Table must be DWord aligned
and must not cross a 64 KB boundary.
2. Software provides the starting address of the PRD Table by loading the PRD Table Pointer
Register. The direction of the data transfer is specified by setting the Read/Write Control bit.
The interrupt bit and Error bit in the Status register are cleared.
3. Software issues the appropriate DMA transfer command to the disk device.
4. The bus master function is engaged by software writing a '1' to the Start bit in the Command
Register. The first entry in the PRD table is fetched and loaded into two registers which are not
visible by software, the Current Base and Current Count registers. These registers hold the
current value of the address and byte count loaded from the PRD table. The value in these
registers is only valid when there is an active command to an IDE device.
5. Once the PRD is loaded internally, the IDE device will receive a DMA acknowledge.
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Functional Description
6. The controller transfers data to/from memory responding to DMA requests from the IDE
device. The IDE device and the host controller may or may not throttle the transfer several
times. When the last data transfer for a region has been completed on the IDE interface, the
next descriptor is fetched from the table. The descriptor contents are loaded into the Current
Base and Current Count registers.
7. At the end of the transfer the IDE device signals an interrupt.
8. In response to the interrupt, software resets the Start/Stop bit in the command register. It then
reads the controller status followed by the drive status to determine if the transfer completed
successfully.
The last PRD in a table has the End of List (EOL) bit set. The PCI bus master data transfers
terminate when the physical region described by the last PRD in the table has been completely
transferred. The active bit in the Status Register is reset and the DDRQ signal masked.
The buffer is flushed (when in the write state) or invalidated (when in the read state) when a
terminal count condition exists (i.e., the current region descriptor has the EOL bit set and that
region has been exhausted). The buffer is also flushed (write state) or invalidated (read state) when
the Interrupt bit in the Bus Master IDE Status register is set. Software that reads the status register
and finds the Error bit reset, and either the Active bit reset or the Interrupt bit set, can be assured
that all data destined for system memory has been transferred and that data is valid in system
memory. Table 5-54 describes how to interpret the Interrupt and Active bits in the Status Register
after a DMA transfer has started.
During concurrent DMA or Ultra ATA transfers, the ICH2 IDE interface arbitrates between the
primary and secondary IDE cables when a PRD expires.
Table 5-54. Interrupt/Active Bit Interaction Definition
Interrupt
Active
Description
0
1
DMA transfer is in progress. No interrupt has been generated by the IDE device.
1
0
The IDE device generated an interrupt. The controller exhausted the Physical
Region Descriptors. This is the normal completion case where the size of the
physical memory regions was equal to the IDE device transfer size.
1
1
The IDE device generated an interrupt. The controller has not reached the end of the
physical memory regions. This is a valid completion case where the size of the
physical memory regions was larger than the IDE device transfer size.
0
0
This bit combination signals an error condition. If the Error bit in the status register is
set, then the controller has some problem transferring data to/from memory.
Specifics of the error have to be determined using bus-specific information. If the
Error bit is not set, then the PRD's specified a smaller size than the IDE transfer size.
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Functional Description
Error Conditions
IDE devices are sector based mass storage devices. The drivers handle errors on a sector basis;
either a sector is transferred successfully or it is not. A sector is 512 bytes.
If the IDE device does not complete the transfer due to a hardware or software error, the command
will eventually be stopped by the driver setting Command Start bit to zero when the driver times
out the disk transaction. Information in the IDE device registers help isolate the cause of the
problem.
If the controller encounters an error while doing the bus master transfers it stops the transfer
(i.e., reset the Active bit in the Command register) and sets the Error bit in the Bus Master IDE
Status register. The controller does not generate an interrupt when this happens. The device driver
can use device specific information (PCI Configuration Space Status register and IDE Drive
Register) to determine what caused the error.
When a requested transfer does not complete properly, information in the IDE device registers
(Sector Count) can be used to determine how much of the transfer was completed and to construct
a new PRD table to complete the requested operation. In most cases the existing PRD table can be
used to complete the operation.
8237-Like Protocol
The 8237 mode DMA is similar in form to DMA used on the ISA bus. This mode uses pins
familiar to the ISA bus, namely a DMA Request, a DMA Acknowledge, and I/O read/write strobes.
These pins have similar characteristics to their ISA counterparts in terms of when data is valid
relative to strobe edges, and the polarity of the strobes, however the ICH2 does not use the 8237 for
this mode.
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Functional Description
5.15.3
Ultra ATA/33 Protocol
Ultra ATA/33 is enabled through configuration register 48h in Device 31:Function 1 for each IDE
device. The IDE signal protocols are significantly different under this mode than for the 8237
mode.
Ultra ATA/33 is a physical protocol used to transfer data between a Ultra ATA/33 capable IDE
controller such as the ICH2 and one or more Ultra ATA/33 capable IDE devices. It utilizes the
standard Bus Master IDE functionality and interface to initiate and control the transfer. Ultra
ATA/33 utilizes a “source synchronous” signaling protocol to transfer data at rates up to 33 MB/s.
The Ultra ATA/33 definition also incorporates a Cyclic Redundancy Checking (CRC-16) error
checking protocol.
Signal Descriptions
The Ultra ATA/33 protocol requires no extra signal pins on the IDE connector. It does redefine a
number of the standard IDE control signals when in Ultra ATA/33 mode. These redefinitions are
shown in Table 5-55. Read cycles are defined as transferring data from the IDE device to the ICH2.
Write cycles are defined as transferring data from ICH2 to IDE device.
Table 5-55. UltraATA/33 Control Signal Redefinitions
Standard IDE
Signal Definition
Ultra ATA/33 Read
Cycle Definition
Ultra ATA/33 Write
Cycle Definition
ICH2 Primary
Channel Signal
ICH2 Secondary
Channel Signal
DIOW#
STOP
STOP
PDIOW#
SDIOW#
DIOR#
DMARDY#
STROBE
PDIOR#
SDIOR#
IORDY
STROBE
DMARDY#
PIORDY
SIORDY
The DIOW# signal is redefined as STOP for both read and write transfers. This is always driven by
the ICH2 and is used to request that a transfer be stopped or as an acknowledgment to stop a
request from the IDE device.
The DIOR# signal is redefined as DMARDY# for transferring data from the IDE device to the
ICH2 (read). It is used by the ICH2 to signal when it is ready to transfer data and to add wait states
to the current transaction. The DIOR# signal is redefined as STROBE for transferring data from the
ICH2 to the IDE device (write). It is the data strobe signal driven by the ICH2 on which data is
transferred during each rising and falling edge transition.
The IORDY signal is redefined as STROBE for transferring data from the IDE device to the ICH2
(read). It is the data strobe signal driven by the IDE device on which data is transferred during each
rising and falling edge transition. The IORDY signal is redefined as DMARDY# for transferring
data from the ICH2 to the IDE device (write). It is used by the IDE device to signal when it is ready
to transfer data and to add wait states to the current transaction.
All other signals on the IDE connector retain their functional definitions during Ultra ATA/33
operation.
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Functional Description
Operation
Initial setup programming consists of enabling and performing the proper configuration of ICH2
and the IDE device for Ultra ATA/33 operation. For ICH2, this consists of enabling Synchronous
DMA mode and setting up appropriate Synchronous DMA timings.
When ready to transfer data to or from an IDE device, the Bus Master IDE programming model is
followed. Once programmed, the drive and ICH2 control the transfer of data via the Ultra ATA/33
protocol. The actual data transfer consists of three phases, a start-up phase, a data transfer phase,
and a burst termination phase.
The IDE device begins the start-up phase by asserting DMARQ signal. When ready to begin the
transfer, the ICH2 asserts the DMACK# signal. When DMACK# signal is asserted, the host
controller drives CS0# and CS1# inactive, DA0–DA2 low. For write cycles, the ICH2 deasserts
STOP, waits for the IDE device to assert DMARDY#, and then drives the first data word and
STROBE signal. For read cycles, the ICH2 tri-states the DD lines, deasserts STOP, and asserts
DMARDY#. The IDE device then sends the first data word and STROBE.
The data transfer phase continues the burst transfers with the data transmitter (ICH2 - writes, IDE
device - reads) providing data and toggling STROBE. Data is transferred (latched by receiver) on
each rising and falling edge of STROBE. The transmitter can pause the burst by holding STROBE
high or low, resuming the burst by again toggling STROBE. The receiver can pause the burst by
deasserting DMARDY# and resumes the transfers by asserting DMARDY#. The ICH2 pauses a
burst transaction to prevent an internal line buffer over or under flow condition, resuming once the
condition has cleared. It may also pause a transaction if the current PRD byte count has expired,
resuming once it has fetched the next PRD.
The current burst can be terminated by either the transmitter or receiver. A burst termination
consists of a Stop Request, Stop Acknowledge and transfer of CRC data. The ICH2 can stop a burst
by asserting STOP; the IDE device acknowledges by deasserting DMARQ. The IDE device stops a
burst by deasserting DMARQ and the ICH2 acknowledges by asserting STOP. The transmitter then
drives the STROBE signal to a high level. The ICH2 then drives the CRC value on the DD lines
and deasserts DMACK#. The IDE device latches the CRC value on the rising edge of DMACK#.
The ICH2 terminates a burst transfer if it needs to service the opposite IDE channel, if a
Programmed I/O (PIO) cycle is executed to the IDE channel currently running the burst, or upon
transferring the last data from the final PRD.
CRC Calculation
Cyclic Redundancy Checking (CRC-16) is used for error checking on Ultra ATA/33 transfers. The
CRC value is calculated for all data by both the ICH2 and the IDE device over the duration of the
Ultra ATA/33 burst transfer segment. This segment is defined as all data transferred with a valid
STROBE edge from DDACK# assertion to DDACK# deassertion. At the end of the transfer burst
segment, the ICH2 drives the CRC value onto the DD[15:0] signals. It is then latched by the IDE
device on deassertion of DDACK#. The IDE device compares the ICH2 CRC value to its own and
reports an error if there is a mismatch.
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Functional Description
5.15.4
Ultra ATA/66 Protocol
In addition to Ultra ATA/33, the ICH2 supports the Ultra ATA/66 protocol. The Ultra ATA/66
protocol is enabled via configuration bits 3:0 at offset 54h. The two protocols are similar, and are
intended to be device driver compatible. The Ultra ATA/66 logic can achieve transfer rates of up to
66 MB/s.
To achieve the higher data rate, the timings are shortened and the quality of the cable is improved
to reduce reflections, noise, and inductive coupling. Note that the improved cable is required and
will still plug into the standard IDE connector. The Ultra ATA/66 protocol also supports a 44 MB/s
mode.
5.15.5
Ultra ATA/100 Protocol
When the ATA_FAST bit is set for any of the 4 IDE devices, the timings for the transfers to and
from the corresponding device run at a higher rate. The ICH2 Ultra ATA/100 logic can achieve
read transfer rates up to 100 MB/s and write transfer rates up to 88.9 MB/s.
The cable improvements required for Ultra ATA/66 are sufficient for Ultra ATA/100, so no further
cable improvements are required when implementing Ultra ATA/100.
5.15.6
Ultra ATA/33/66/100 Timing
The timings for Ultra ATA/33/66/100 modes are programmed via the Synchronous DMA Timing
Register and the IDE Configuration Register. Different timings can be programmed for each drive
in the system. The Base Clock frequency for each drive is selected in the IDE Configuration
Register. The Cycle Time (CT) and Ready to Pause (RP) time (defined as multiples of the Base
Clock) are programmed in the Synchronous DMA Timing Register. The Cycle Time represents the
minimum pulse width of the data strobe (STROBE) signal. The Ready to Pause time represents the
number of Base Clock periods that the ICH2 will wait from deassertion of DMARDY# to the
assertion of STOP when it desires to stop a burst read transaction.
Note:
5.15.7
The internal Base Clock for Ultra ATA/100 (Mode 5) runs at 133 MHz, and the Cycle Time (CT)
must be set for 3 Base Clocks. The ICH2, thus, toggles the write strobe signal every 22.5 ns,
transferring two bytes of data on each strobe edge. This means that the ICH2 performs Mode 5
write transfers at a maximum rate of 88.9 MB/s. For read transfers, the read strobe is driven by the
ATA/100 device; the ICH2 supports reads at the maximum rate of 100 MB/s.
Mobile IDE Swap Bay (82801BAM ICH2-M only)
To support a mobile swap bay, the ICH2-M allows the IDE output signals to be tri-stated and input
buffers to be turned off. This should be done prior to the removal of the drive.
The output signals can also be driven low. This can be used to remove charge built up on the
signals.New configuration bits are included in the IDE I/O Configuration Register, offset 54h in
the IDE PCI configuration space.
WARNING: The software should NOT attempt to control the outputs (either tri-state or driving
low), while an IDE transfer is in progress. Unpredictable results could occur,
including a system lockup.
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Functional Description
5.16
USB Controller (Device 31:Functions 2 and 4)
The ICH2 contains two USB Host Controllers. Each Host Controller includes a root hub with two
separate USB ports each, for a total of 4 USB ports. The ICH2 Host Controllers support the
standard Universal Host Controller Interface (UHCI) Rev 1.1.
Overcurrent detection on all 4 USB ports is supported. The overcurrent inputs are 5V-tolerant, and
can be used as GPIs if not needed.
The ICH2’s USB controllers are arbitrated as differently than standard PCI devices to improve
arbitration latency.
5.16.1
Data Structures in Main memory
This section describes the details of the data structures used to communicate control, status, and
data between software and the ICH2: Frame Lists, Transfer Descriptors, and Queue Heads. Frame
Lists are aligned on 4-KB boundaries. Transfer Descriptors and Queue Heads are aligned on
16-byte boundaries.
5.16.1.1
Frame List Pointer
The frame list pointer contains a link pointer to the first data object to be processed in the frame, as
well as the control bits defined in Table 5-56.
Table 5-56. Frame List Pointer Bit Description
Bit
Description
31:4
Frame List Pointer (FLP). This field contains the address of the first data object to be processed in
the frame and corresponds to memory address signals [31:4], respectively.
3:2
Reserved. These bits must be written as 0.
1
QH/TD Select (Q). This bit indicates to the hardware whether the item referenced by the link pointer
is a TD (Transfer Descriptor) or a QH (Queue Head). This allows the ICH2 to perform the proper type
of processing on the item after it is fetched.
1 = QH
0 = TD
Terminate (T). This bit indicates to the ICH2 whether the schedule for this frame has valid entries in
it.
0
1 = Empty Frame (pointer is invalid).
0 = Pointer is valid (points to a QH or TD).
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Functional Description
5.16.1.2
Transfer Descriptor (TD)
Transfer Descriptors (TDs) express the characteristics of the transaction requested on USB by a
client. TDs are always aligned on 16-byte boundaries, and the elements of the TD are shown in
Figure 5-16. The 4 different USB transfer types are supported by a small number of control bits in
the descriptor that the ICH2 interprets during operation. All Transfer Descriptors have the same
basic, 32-byte structure. During operation, the ICH2 hardware performs consistency checks on
some fields of the TD. If a consistency check fails, the ICH2 halts immediately and issues an
interrupt to the system. This interrupt cannot be masked within the ICH2.
Figure 5-16. Transfer Descriptor
31 30 29 28
27 26 25 24 23
21 20 19 18
16 15 14
11 10
8 7
4 3
2
1
0
0
Vf
Q
T
Link Pointer
R
SPD C_ERR LS ISOISC
Status
MaxLen
R
R
EndPt
D
Device Address
ActLen
PID
Buffer Pointer
R = Reserved
ICH2 Read/Write
ICH2 Read Only
T
f
d
Table 5-57. TD Link Pointer
Bit
Description
31:4
Link Pointer (LP). Bits [31:4] Correspond to memory address signals [31:4], respectively. This field
points to another TD or QH.
3
Reserved. Must be 0 when writing this field.
2
Depth/Breadth Select (VF). This bit is only valid for queued TDs and indicates to the hardware
whether it should process in a depth first or breadth first fashion. When set to depth first, it informs
the ICH2 to process the next transaction in the queue rather than starting a new queue.
1 = Depth first.
0 = Breadth first.
1
QH/TD Select (Q). This bit informs the ICH2 whether the item referenced by the link pointer is
another TD or a QH. This allows the ICH2 to perform the proper type of processing on the item after
it is fetched
1 = QH.
0 = TD.
0
Terminate (T). This bit informs the ICH2 that the link pointer in this TD does not point to another
valid entry. When encountered in a queue context, this bit indicates to the ICH2 that there are no
more valid entries in the queue. A TD encountered outside of a queue context with the T bit set
informs the ICH2 that this is the last TD in the frame.
1 = Link Pointer field not valid.
0 = Link Pointer field is valid.
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5-109
Functional Description
Table 5-58. TD Control and Status
Bit
31:30
29
Description
Reserved.
Short Packet Detect (SPD). When a packet has this bit set to 1 and the packet is an input packet, is
in a queue; and successfully completes with an actual length less than the maximum length then the
TD is marked inactive, the Queue Header is not updated and the USBINT status bit (Status
Register) is set at the end of the frame. In addition, if the interrupt is enabled, the interrupt will be
sent at the end of the frame.
Note that any error (e.g., babble or FIFO error) prevents the short packet from being reported. The
behavior is undefined when this bit is set with output packets or packets outside of queues.
1 = Enable.
0 = Disable.
Error Counter (C_ERR). This field is a 2-bit down counter that keeps track of the number of Errors
detected while executing this TD. If this field is programmed with a non zero value during setup, the
ICH2 decrements the count and writes it back to the TD if the transaction fails. If the counter counts
from one to zero, the ICH2 marks the TD inactive, sets the “STALLED” and error status bit for the
error that caused the transition to zero in the TD. An interrupt will be generated to Host Controller
Driver (HCD) if the decrement to zero was caused by Data Buffer error, Bit stuff error, or if enabled,
a CRC or Timeout error. If HCD programs this field to zero during setup, the ICH2 will not count
errors for this TD and there will be no limit on the retries of this TD.
28:27
Bits[28:27]
00
01
10
11
Error
CRC Error
Timeout Error
NAK Received
Babble Detected
Interrupt After
No Error Limit
1 Error
2 Errors
3 Errors
Decrement Counter
Yes
Yes
No
No*
Error
Data Buffer Error
Stalled
Bit stuff Error
Decrement Counter
Yes
No*
Yes
*Detection of Babble or Stall automatically deactivates the TD. Thus, count is not decremented.
* Detection of Babble or Stall automatically deactivates the TD. Thus, count is not decremented.
26
Low Speed Device (LS). This bit indicates that the target device (USB data source or sink) is a low
speed device, running at 1.5 Mb/s, instead of at full speed (12 Mb/sec). There are special
restrictions on schedule placement for low speed TDs. If an ICH2 root hub port is connected to a full
speed device and this bit is set to a 1 for a low speed transaction, the ICH2 sends out a low speed
preamble on that port before sending the PID. No preamble is sent if a ICH2 root hub port is
connected to a low speed device.
1 = Low Speed Device
0 = Full Speed Device
25
Isochronous Select (IOS). The field specifies the type of the data structure. If this bit is set to a 1,
then the TD is an isochronous transfer. Isochronous TDs are always marked inactive by the
hardware after execution, regardless of the results of the transaction.
1 = Isochronous Transfer Descriptor
0 = Non-isochronous Transfer Descriptor
24
Interrupt on Complete (IOC). This specifies that the ICH2 should issue an interrupt on completion
of the frame in which this Transfer Descriptor is executed. Even if the Active bit in the TD is already
cleared when the TD is fetched (no transaction will occur on USB), an IOC interrupt is generated at
the end of the frame.
1 = Issue IOC
Active. For ICH2 schedule execution operations, see the Data Transfers To/From Main Memory
section.
23
1 = Set to 1 by software to enable the execution of a message transaction by the ICH2.
0 = When the transaction associated with this descriptor is completed, the ICH2 sets this bit to 0
indicating that the descriptor should not be executed when it is next encountered in the
schedule. The Active bit is also set to 0 if a stall handshake is received from the endpoint.
5-110
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
Table 5-58. TD Control and Status (Continued)
Bit
Description
Stalled.
22
21
1 = Set to a 1 by the ICH2 during status updates to indicate that a serious error has occurred at the
device/endpoint addressed by this TD. This can be caused by babble, the error counter
counting down to zero, or reception of the STALL handshake from the device during the
transaction. Any time that a transaction results in the Stalled bit being set, the Active bit is also
cleared (set to 0). If a STALL handshake is received from a SETUP transaction, a Time Out
Error will also be reported.
Data Buffer Error (DBE).
1 = Set to a 1 by the ICH2 during status update to indicate that the ICH2 is unable to keep up with
the reception of incoming data (overrun) or is unable to supply data fast enough during
transmission (underrun). When this occurs, the actual length and Max Length field of the TD will
not match. In the case of an underrun, the ICH2 transmits an incorrect CRC (thus invalidating
the data at the endpoint) and leaves the TD active (unless error count reached zero). If a
overrun condition occurs, the ICH2 forces a timeout condition on the USB, invalidating the
transaction at the source.
20
Babble Detected (BABD).
1 = Set to a 1 by the ICH2 during status update when “babble” is detected during the transaction
generated by this descriptor. Babble is unexpected bus activity for more than a preset amount of
time. In addition to setting this bit, the ICH2 also sets the” STALLED” bit (bit 22) to a 1. Since
”babble” is considered a fatal error for that transfer, setting the” STALLED” bit to a 1 insures that
no more transactions occur as a result of this descriptor. Detection of babble causes immediate
termination of the current frame. No further TDs in the frame are executed. Execution resumes
with the next frame list index.
19
Negative Acknowledgment (NAK) Received (NAKR).
1 = Set to a 1 by the ICH2 during status update when the ICH2 receives a “NAK” packet during the
transaction generated by this descriptor. If a NAK handshake is received from a SETUP
transaction, a Time Out Error is also be reported.
CRC/Time Out Error (CRC_TOUT).
1 = Set to a 1 by the ICH2 as follows:
During a status update in the case that no response is received from the target device/endpoint
within the time specified by the protocol chapter of the USB specification.
18
During a status update when a Cycli Redundancy Check (CRC) error is detected during the
transaction associated with this transfer descriptor.
In the transmit case (OUT or SETUP Command), this is in response to the ICH2 detecting a
timeout from the target device/endpoint.
In the receive case (IN Command), this is in response to the ICH2’s CRC checker circuitry
detecting an error on the data received from the device/endpoint or a NAK or STALL handshake
being received in response to a SETUP transaction.
17
Bit stuff Error (BSE).
1 = This bit is set to a 1 by the ICH2 during status update to indicate that the receive data stream
contained a sequence of more than 6 ones in a row.
Bus Turn Around Time-out (BTTO).
16
1 = This bit is set to a 1 by the ICH2 during status updates to indicate that a bus time-out condition
was detected for this USB transaction. This time-out is specially defined as not detecting an
IDLE-to ‘K’ state Start of Packet (SOP) transition from 16 to 18 bit times after the SE0-to IDE
transition of previous End of Packet (EOP).
15:11
Reserved
10:0
Actual Length (ACTLEN). The Actual Length field is written by the ICH2 at the conclusion of a USB
transaction to indicate the actual number of bytes that were transferred. It can be used by the
software to maintain data integrity. The value programmed in this register is encoded as n-1 (see
Maximum Length field description in the TD Token).
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-111
Functional Description
Table 5-59. TD Token
Bit
Description
Maximum Length (MAXLEN). The Maximum Length field specifies the maximum number of data
bytes allowed for the transfer. The Maximum Length value does not include protocol bytes, such as
Packet ID (PID) and CRC. The maximum data packet is 1280 bytes. The 1280 packet length is the
longest packet theoretically guaranteed to fit into a frame. Actual packet maximum lengths are set
by HCD according to the type and speed of the transfer. Note that the maximum length allowed by
the USB specification is 1023 bytes. The valid encodings for this field are:
0x000 = 1 byte
0x001 = 2 bytes
....
0x3FE = 1023 bytes
31:21
0x3FF = 1024 bytes
....
0x4FF = 1280 bytes
0x7FF = 0 bytes (null data packet)
Note that values from 500h to 7FEh are illegal and cause a consistency check failure.
In the transmit case, the ICH2 uses this value as a terminal count for the number of bytes it fetches
from host memory. In most cases, this is the number of bytes it will actually transmit. In rare cases,
the ICH2 may be unable to access memory (e.g., due to excessive latency) in time to avoid
underrunning the transmitter. In this instance the ICH2 would transmit fewer bytes than specified in
the Maximum Length field.
20
Reserved.
19
Data Toggle (D). This bit is used to synchronize data transfers between a USB endpoint and the
host. This bit determines which data PID is sent or expected (0=DATA0 and 1=DATA1). The Data
Toggle bit provides a 1-bit sequence number to check whether the previous packet completed. This
bit must always be 0 for Isochronous TDs.
18:15
Endpoint (ENDPT). This 4-bit field extends the addressing internal to a particular device by
providing 16 endpoints. This permits more flexible addressing of devices in which more than one
sub-channel is required.
14:8
Device Address. This field identifies the specific device serving as the data source or sink.
7:0
Packet Identification (PID). This field contains the Packet ID to be used for this transaction. Only
the IN (69h), OUT (E1h), and SETUP (2Dh) tokens are allowed. Any other value in this field causes
a consistency check failure resulting in an immediate halt of the ICH2. Bits [3:0] are complements of
bits [7:4].
Table 5-60. TD Buffer Pointer
Bit
31:0
5-112
Description
Buffer Pointer (BUFF_PNT). Bits [31:0] corresponds to memory address [31:0], respectively. It
points to the beginning of the buffer that will be used during this transaction. This buffer must be at
least as long as the value in the Maximum Length field described int the TD Token. The data buffer
may be byte-aligned.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.16.1.3
Queue Head (QH)
Queue heads are special structures used to support the requirements of Control, Bulk and Interrupt
transfers. Since these TDs are not automatically retired after each use, their maintenance
requirements can be reduced by putting them into a queue. Queue Heads must be aligned on a
16-byte boundary; the elements are shown in Table 5-61.
Table 5-61. Queue Head Block
Bytes
Description
Attributes
00:03
Queue Head Link Pointer
RO
04:07
Queue Element Link Pointer
R/W
Table 5-62. Queue Head Link Pointer
Bit
Description
31:4
Queue Head Link Pointer (QHLP). This field contains the address of the next data object to be
processed in the horizontal list and corresponds to memory address signals [31:4], respectively.
3:2
Reserved. These bits must be written as 0s.
1
QH/TD Select (Q). This bit indicates to the hardware whether the item referenced by the link pointer
is another TD or a QH.
1=QH
0=TD
Terminate (T). This bit indicates to the ICH2 that this is the last QH in the schedule. If there are active
TDs in this queue, they are the last to be executed in this frame.
0
1 = Last QH (pointer is invalid).
0 = Pointer is valid (points to a QH or TD).
Table 5-63. Queue Element Link Pointer
Bit
Description
31:4
Queue Element Link Pointer (QELP). This field contains the address of the next TD or QH to be
processed in this queue and corresponds to memory address signals [31:4], respectively.
3:2
Reserved.
QH/TD Select (Q). This bit indicates to the hardware whether the item referenced by the link pointer
is another TD or a QH. For entries in a queue, this bit is typically set to 0.
1
1 = QH
0 = TD
Terminate (T). This bit indicates to the ICH2 that there are no valid TDs in this queue. When HCD
has new queue entries it overwrites this value with a new TD pointer to the queue entry.
0
1 = Terminate (No valid queue entries).
0 = Pointer is valid.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-113
Functional Description
5.16.2
Data Transfers To/From Main Memory
The following sections describe the details on how HCD and the ICH2 communicate via the
Schedule data structures. The discussion is organized in a top-down manner, beginning with the
basics of walking the Frame List, followed by a description of generic processing steps common to
all transfer descriptors, and finally a discussion on Transfer Queuing.
5.16.2.1
Executing the Schedule
Software programs the ICH2 with the starting address of the Frame List and the Frame List index,
then causes the ICH2 to execute the schedule by setting the Run/Stop bit in the Control register to
Run. The ICH2 processes the schedule one entry at a time. The next element in the frame list is not
fetched until the current element in the frame list is retired.
Schedule execution proceeds in the following fashion:
• The ICH2 first fetches an entry from the Frame List. This entry has three fields. Bit 0 indicates
whether the address pointer field is valid. Bit 1 indicates whether the address points to a
Transfer Descriptor or to a queue head. The third field is the pointer itself.
• If isochronous traffic is to be moved in a given frame, the Frame List entry points to a Transfer
Descriptor. If no isochronous data is to be moved in that frame, the entry points to a queue
head or the entry is marked invalid and no transfers are initiated in that frame.
• If the Frame List entry indicates that it points to a Transfer Descriptor, the ICH2 fetches the
entry and begins the operations necessary to initiate a transaction on USB. Each TD contains a
link field that points to the next entry, as well as indicating whether it is a TD or a QH.
• If the Frame List entry contains a pointer to a QH, the ICH2 processes the information from
the QH to determine the address of the next data object that it should process.
• The TD/QH process continues until the millisecond allotted to the current frame expires. At
this point, the ICH2 fetches the next entry from the Frame List. If the ICH2 is not able to
process all of the transfer descriptors during a given frame, those descriptors are retired by
software without having been executed.
5.16.2.2
Processing Transfer Descriptors
The ICH2 executes a TD using the following generalized algorithm. These basic steps are common
across all modes of TDs. Subsequent sections present processing steps unique to each TD mode.
1. ICH2 Fetches TD or QH from the current Link Pointer.
2. If a QH, go to 1 to fetch from the Queue Element Link Pointer. If inactive, go to 12
3. Build Token, actual bits are in TD Token.
4. If (Host-to-Function) then
[PCI Access] issue request for data, (referenced through TD.BufferPointer)
wait for first chunk data arrival
end if
5. [Begin USB Transaction] Issue Token (from token built in 2, above) and begin data transfer.
if (Host-to-Function) then Go to 6
else Go to 7
end if
6. Fetch data from memory (via TD BufferPointer) and transfer over USB until TD Max-Length
bytes have been read and transferred. [Concurrent system memory and USB Accesses]. Go to
8.
5-114
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
7. Wait for data to arrive (from USB). Write incoming bytes into memory beginning at TD
BufferPointer. Internal HC buffer should signal end of data packet. Number of bytes received
must be (TD Max-Length; The length of the memory area referenced by TD BufferPointer
must be (TD Max-Length. [Concurrent system memory and USB Accesses].
8. Issue handshake based on status of data received (Ack or Time-out). Go to 10.
9. Wait for handshake, if required [End of USB Transaction].
10. Update Status [PCI Access] (TD.Status and TD.ActualLength).
If the TD was an isochronous TD, mark the TD inactive. Go to 12.
If not an isochronous TD, and the TD completed successfully, mark the TD inactive. Go to 11.
If not successful, and the error count has not been reached, leave the TD active. If the error
count has been reached, mark the TD inactive. Go to 12.
11. Write the link pointer from the current TD into the element pointer field of the QH structure. If
the Vf bit is set in the TD link pointer, go to 2.
12. Proceed to next entry.
5.16.2.3
Command Register, Status Register, and TD Status Bit Interaction
Table 5-64. Command Register, Status Register and TD Status Bit Interaction
Condition
ICH2 USB Status Register Actions
CRC/Time Out Error
Set USB Error Int bit1, Clear HC Halted bit
Illegal PID, PID Error,
Clear Run/Stop bit in command register
Max Length (illegal)
Set HC Process Error and HC Halted bits
PCI Master/Target
Abort
Clear Run/Stop bit in command register
Suspend Mode
Resume Received and
Suspend Mode = 1
Run/Stop = 0
configuration Flag Set
TD Status Register Actions
Clear Active bit1 and set Stall
bit1
Set Host System Error and HC Halted bits
Clear Run/Stop bit in command register2
Set HC Halted bit
Set Resume received bit
Clear Run/Stop bit in command register
Set HC Halted bit
Set configuration Flag in command register
Clear Run/Stop and configuration Flag in
command register
HC Reset/Global Reset Clear USB Int, USB Error Int, Resume received,
Host System Error, HC Process Error, and HC
Halted bits
IOC = 1 in TD Status
Set USB Int bit
Stall
Set USB Error Int bit
Clear Active bit1 and set Stall bit
Bit Stuff/Data Buffer
Error
Set USB Error Int bit1
Clear Active bit1 and set Stall
bit1
Short Packet Detect
Set USB Int bit
Clear Active bit
NOTES:
1. Only If error counter counted down from 1 to 0
2. Suspend mode can be entered only when Run/Stop bit is 0
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-115
Functional Description
Note that, if a NAK or STALL response is received from a SETUP transaction, a Time Out Error
will be reported. This causes the Error counter to decrement and the CRC/Time-out Error status bit
to be set within the TD Control and Status DWord during write back. If the Error counter changes
from 1 to 0, the Active bit is reset to 0 and Stalled bit to 1 as normal.
5.16.2.4
Transfer Queuing
Transfer Queues are used to implement a guaranteed data delivery stream to a USB Endpoint.
Transfer Queues are composed of two parts: a Queue Header (QH) and a linked list. The linked list
of TDs and QHs has an indeterminate length (0 to n).
The QH contains two link pointers and is organized as two contiguous DWords. The first DWord is
a horizontal pointer (Queue Head Link Pointer), used to link a single transfer queue with either
another transfer queue, or a TD (target data structure depends on Q bit). If the T bit is set, this QH
represents the last data structure in the current Frame. The T bit informs the ICH2 that no further
processing is required until the beginning of the next frame. The second DWord is a vertical pointer
(Queue Element Link Pointer) to the first data structure (TD or QH) being managed by this QH. If
the T bit is set, the queue is empty. This pointer may reference a TD or another QH.
Figure 5-17 illustrates four example queue conditions. The first QH (on far left) is an example of
an “empty” queue; the termination bit (T Bit), in the vertical link pointer field, is set to 1. The
horizontal link pointer references another QH. The next queue is the expected typical
configuration. The horizontal link pointer references another QH, and the vertical link pointer
references a valid TD.
Typically, the vertical pointer in a QH points to a TD. However, as shown in Figure 5-17 (third
example from left side of figure) the vertical pointer could point to another QH. When this occurs,
a new Q Context is entered and the Q Context just exited is NULL (ICH2 does not update the
vertical pointer field).
The far right QH is an example of a frame ‘termination’ node. Since its horizontal link pointer has
its termination bit set, the ICH2 assumes there is no more work to complete for the current Frame.
Figure 5-17. Example Queue Conditions
31
2 1 0
Frame List Pointer
Q T
Indicates "Nil" Next Pointer
31
QH
2 1 0
31
QH
2 1 0
31
QH
2 1 0
31
QH
2 1 0
Link Pointer (Horiz)
Q T
Link Pointer (Horiz)
Q T
Link Pointer (Horiz)
Q T
Link Pointer (Horiz)
Q T
Link Pointer (Vert)
Q T
Link Pointer (Vert)
Q T
Link Pointer (Vert)
Q T
Link Pointer (Vert)
Q T
Link Pointer
Q T
Indicates "Nil" Next Pointer
Indicates "Null" Queue Head
TD
Link Pointer
TD
31
QH
Link Pointer
Q T
2 1 0
Link Pointer (Horiz)
Q T
Link Pointer (Vert)
Q T
Link Pointer
Q T
TD
Q T
TD
Notes:
1. Link Pointer (Horiz) = Queue Head Link Pointer
field in QH DWord 0
2. Link Pointer (Vert) = Queue Element Link Pointer
field in QH DWord 1
Link Pointer
Q T
TD
E
5-116
Q
d
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
Transfer Queues are based on the following characteristics:
• A QH’s vertical link pointer (Queue Element Link Pointer) references the ‘Top’ queue
member. A QH’s horizontal link pointer (Queue Head Link Pointer) references the “next”
work element in the Frame.
• Each queue member’s link pointer references the next element within the queue.
In the simplest model, the ICH2 follows vertical link point to a queue element, then executes the
element. If the completion status of the TD satisfies the advance criteria as shown in Table 5-65,
the ICH2 advances the queue by writing the just-executed TD’s link pointer back into the QH’s
Queue Element link pointer. The next time the queue head is traversed, the next queue element will
be the Top element.
The traversal has two options: Breadth first, or Depth first. A flag bit in each TD (Vf - Vertical
Traversal Flag) controls whether traversal is Breadth or Depth first. The default mode of traversal
is Breadth-First. For Breadth-First, the ICH2 only executes the top element from each queue. The
execution path is shown below:
1. QH (Queue Element Link Pointer)
2. TD
3. Write-Back to QH (Queue Element Link Pointer)
4. QH (Queue Head Link pointer).
Breadth-First is also performed for every transaction execution that fails the advance criteria. This
means that if a queued TD fails, the queue does not advance, and the ICH2 traverses the QH’s
Queue Head Link Pointer.
In a Depth-first traversal, the top queue element must complete successfully to satisfy the advance
criteria for the queue. If the ICH2 is currently processing a queue, and the advance criteria are met,
and the Vf bit is set, the ICH2 follows the TD’s link pointer to the next schedule work item.
Note that regardless of traversal model, when the advance criteria are met, the successful TD’s link
pointer is written back to the QH’s Queue Element link pointer.
When the ICH2 encounters a QH, it caches the QH internally, and sets internal state to indicate it is
in a Q-context. It needs this state to update the correct QH (for auto advancement) and also to make
the correct decisions on how to traverse the Frame List.
Restricting the advancement of queues to advancement criteria implements a guaranteed data
delivery stream.
A queue is never advanced on an error completion status (even in the event the error count was
exhausted).
Table 5-65 lists the general queue advance criteria, which are based on the execution status of the
TD at the "Top" of a currently "active" queue.
Table 5-65. Queue Advance Criteria
Function-to-Host (IN)
Host-to-Function (OUT)
Non-NULL
NULL
Error/NAK
Non-NULL
NULL
Error/NAK
Advance Q
Advance Q
Retry Q Element
Advance Q
Advance Q
Retry Q Element
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-117
Functional Description
Table 5-66 is a decision table illustrating the valid combinations of link pointer bits and the valid
actions taken when advancement criteria for a queued transfer descriptor are met. The column
headings for the link pointer fields are encoded, based on the following list:
TD
QH
QE
QHLP
QELP
Q
Vf
TDLP
T
Vf Q
T
Q T
Legends:
QH.LP = Queue Head Link Pointer (or Horizontal Link Pointer)
QE.LP = Queue Element Link Pointer (or Vertical Link Pointer)
TD.LP = TD Link Pointer
QH.Q = Q bit in QH
QH.T = T bit in QH
QE.Q = Q bit in QE
QE.T = T bit in QE
TD. Vf = Vf bit in TD
TD.Q = Q bit in TD
TD. T = T bit in TD
Table 5-66. USB Schedule List Traversal Decision Table
Q
Context
QH.Q
QH.T
QE.Q
QE.T
TD.Vf
TD.Q
TD.T
0
-
-
-
-
x
0
0
0
-
-
-
-
x
x
1
0
-
-
-
-
x
1
0
Description
• Not in Queue - execute TD.
• Use TD.LP to get next TD
• Not in Queue - execute TD. End of
Frame
• Not in Queue - execute TD.
• Use TD.LP to get next (QH+QE).
• Set Q Context to 1.
• In Queue. Use QE.LP to get TD.
1
0
0
0
0
0
x
x
• Execute TD. Update QE.LP with
TD.LP.
• Use QH.LP to get next TD.
• In Queue. Use QE.LP to get TD.
1
x
x
0
0
1
0
0
• Execute TD. Update QE.LP with
TD.LP.
• Use TD.LP to get next TD.
• In Queue. Use QE.LP to get TD.
1
x
x
0
0
1
1
0
• execute TD. Update QE.LP with
TD.LP.
• Use TD.LP to get next (QH+QE).
1
0
0
x
1
x
x
x
1
x
x
1
0
-
-
-
• In Queue. Empty queue.
• Use QH.LP to get next TD
• In Queue. Use QE.LP to get
(QH+QE)
• In Queue. Use QE.LP to get TD.
1
x
1
0
0
0
x
x
• execute TD. Update QE.LP with
TD.LP.
• End of Frame
1
5-118
x
1
x
1
x
x
x
• In Queue. Empty queue. End of
Frame
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
Table 5-66. USB Schedule List Traversal Decision Table (Continued)
Q
Context
QH.Q
QH.T
QE.Q
QE.T
TD.Vf
TD.Q
TD.T
Description
• In Queue. Use QE.LP to get TD.
1
1
0
0
0
0
x
x
• execute TD. Update QE.LP with
TD.LP.
• Use QH.LP to get next (QH+QE).
1
5.16.3
1
0
x
1
x
x
x
• In Queue. Empty queue.
• Use QH.LP to get next (QH+QE)
Data Encoding and Bit Stuffing
The USB employs NRZI data encoding (Non-Return to Zero Inverted) when transmitting packets.
In NRZI encoding, a 1 is represented by no change in level and a 0 is represented by a change in
level. A string of zeros causes the NRZI data to toggle each bit time. A string of ones causes long
periods with no transitions in the data. To ensure adequate signal transitions, bit stuffing is
employed by the transmitting device when sending a packet on the USB. A 0 is inserted after every
six consecutive 1s in the data stream before the data is NRZI encoded to force a transition in the
NRZI data stream. This gives the receiver logic a data transition at least once every seven bit times
to guarantee the data and clock lock. A waveform of the data encoding is shown in Figure 5-18.
Figure 5-18. USB Data Encoding
CLOCK
Data
Bit Stuffed Data
NRZI Data
Bit stuffing is enabled beginning with the Sync Pattern and throughout the entire transmission. The
data “one” that ends the Sync Pattern is counted as the first one in a sequence. Bit stuffing is always
enforced, without exception. If required by the bit stuffing rules, a zero bit will be inserted even if
it is the last bit before the end-of-packet (EOP) signal.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-119
Functional Description
5.16.4
Bus Protocol
5.16.4.1
Bit Ordering
Bits are sent out onto the bus least significant bit (LSb) first, followed by next LSb, through to the
most significant bit (MSb) last.
5.16.4.2
SYNC Field
All packets begin with a synchronization (SYNC) field, which is a coded sequence that generates a
maximum edge transition density. The SYNC field appears on the bus as IDLE followed by the
binary string “KJKJKJKK,” in its NRZI encoding. It is used by the input circuitry to align
incoming data with the local clock and is defined to be eight bits in length. SYNC serves only as a
synchronization mechanism and is not shown in the following packet diagrams. The last two bits in
the SYNC field are a marker that is used to identify the first bit of the PID. All subsequent bits in
the packet must be indexed from this point.
5.16.4.3
Packet Field Formats
Field formats for the token, data, and handshake packets are described in the following section. The
effects of NRZI coding and bit stuffing have been removed for the sake of clarity. All packets have
distinct start and end of packet delimiters.
Table 5-67. PID Format
Bit
Data Sent
Bit
Data Sent
0
PID 0
4
NOT(PID 0)
1
PID 1
5
NOT(PID 1)
2
PID 2
6
NOT(PID 2)
3
PID 3
7
NOT(PID 3)
Packet Identifier Field
A packet identifier (PID) immediately follows the SYNC field of every USB packet. A PID
consists of a four bit packet type field followed by a four-bit check field as shown in Table 5-67.
The PID indicates the type of packet and, by inference, the format of the packet and the type of
error detection applied to the packet. The four-bit check field of the PID insures reliable decoding
of the PID so that the remainder of the packet is interpreted correctly. The PID check field is
generated by performing a ones complement of the packet type field.
Any PID received with a failed check field or which decodes to a non-defined value is assumed to
be corrupted and the remainder of the packet is assumed to be corrupted and is ignored by the
receiver. PID types, codes, and descriptions are listed in Table 5-68.
5-120
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
Table 5-68. PID Types
PID Type
PID Name
Token
OUT
b0001
Address + endpoint number in host -> function transaction
IN
b1001
Address + endpoint number in function -> host transaction
SOF
b0101
Start of frame marker and frame number
SETUP
b1101
Address + endpoint number in host -> function transaction
for setup to a control endpoint
DATA0
b0011
Data packet PID even
Data
Handshake
Special
PID[3:0]
Description
DATA1
b1011
Data packet PID odd
ACK
b0010
Receiver accepts error free data packet
NAK
b1010
Rx device cannot accept data or Tx device cannot send
data
STALL
b1110
Endpoint is stalled
PRE
b1100
Host-issued preamble. Enables downstream bus traffic to
low speed devices.
PIDs are divided into four coding groups: token, data, handshake, and special, with the first two
transmitted PID bits (PID[1:0]) indicating which group. This accounts for the distribution of PID
codes.
5.16.4.4
Address Fields
Function endpoints are addressed using two fields: the function address field and the endpoint
field.
Table 5-69. Address Field
Bit
Data Sent
Bit
Data Sent
0
ADDR 0
4
ADDR 4
1
ADDR 1
5
ADDR 5
2
ADDR 2
6
ADDR 6
3
ADDR 3
Address Field
The function address (ADDR) field specifies the function, via its address, that is either the source
or destination of a data packet, depending on the value of the token PID. As shown in Table 5-69, a
total of 128 addresses are specified as ADDR[6:0]. The ADDR field is specified for IN, SETUP,
and OUT tokens.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-121
Functional Description
Endpoint Field
An additional four-bit endpoint (ENDP) field, shown in Table 5-70, permits more flexible
addressing of functions in which more than one sub-channel is required. Endpoint numbers are
function specific. The endpoint field is defined for IN, SETUP, and OUT token PIDs only.
Table 5-70. Endpoint Field
5.16.4.5
Bit
Data Sent
0
ENDP 0
1
ENDP 1
2
ENDP 2
3
ENDP 3
Frame Number Field
The frame number field is an 11-bit field that is incremented by the host on a per frame basis. The
frame number field rolls over upon reaching its maximum value of x7FFh and is sent only for SOF
tokens at the start of each frame.
5.16.4.6
Data Field
The data field may range from 0 to 1023 bytes and must be an integral numbers of bytes. Data bits
within each byte are shifted out LSB first.
5.16.4.7
Cyclic Redundancy Check (CRC)
CRC is used to protect the all non-PID fields in token and data packets. In this context, these fields
are considered to be protected fields. The PID is not included in the CRC check of a packet
containing CRC. All CRCs are generated over their respective fields in the transmitter before bit
stuffing is performed. Similarly, CRCs are decoded in the receiver after stuffed bits have been
removed. Token and data packet CRCs provide 100% coverage for all single and double bit errors.
A failed CRC is considered to indicate that one or more of the protected fields is corrupted and
causes the receiver to ignore those fields, and, in most cases, the entire packet.
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Functional Description
5.16.5
Packet Formats
5.16.5.1
Token Packets
Table 5-71 shows the field formats for a token packet. A token consists of a PID, specifying either
IN, OUT, or SETUP packet type, and ADDR and ENDP fields. For OUT and SETUP transactions,
the address and endpoint fields uniquely identify the endpoint that will receive the subsequent data
packet. For IN transactions, these fields uniquely identify which endpoint should transmit a data
packet. Only the ICH2 can issue token packets. IN PIDs define a data transaction from a function
to the ICH2. OUT and SETUP PIDs define data transactions from the ICH2 to a function.
Token packets have a five-bit CRC that covers the address and endpoint fields as shown above. The
CRC does not cover the PID, which has its own check field. Token and SOF packets are delimited
by an EOP after three bytes of packet field data. If a packet decodes as an otherwise valid token or
SOF but does not terminate with an EOP after three bytes, it must be considered invalid and
ignored by the receiver.
Table 5-71. Token Format
5.16.5.2
Packet
Width
PID
8 bits
ADDR
7 bits
ENDP
4 bits
CRC5
5 bits
Start of Frame Packets
Table 5-72 shows a start of frame (SOF) packet. SOF packets are issued by the host at a nominal
rate of once every 1.00 ms. SOF packets consist of a PID indicating packet type followed by an 11bit frame number field.
The SOF token comprises the token-only transaction that distributes a start of frame marker and
accompanying frame number at precisely timed intervals corresponding to the start of each frame.
All full speed functions, including hubs, must receive and decode the SOF packet. The SOF token
does not cause any receiving function to generate a return packet; therefore, SOF delivery to any
given function cannot be guaranteed. The SOF packet delivers two pieces of timing information. A
function is informed that a start of frame has occurred when it detects the SOF PID. Frame timing
sensitive functions, that do not need to keep track of frame number, need only decode the SOF PID;
they can ignore the frame number and its CRC. If a function needs to track frame number, it must
comprehend both the PID and the time stamp.
Table 5-72. SOF Packet
Packet
Width
PID
8 bits
Frame Number
11 bits
CRC5
5 bits
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-123
Functional Description
5.16.5.3
Data Packets
A data packet consists of a PID, a data field, and a CRC as shown in Table 5-73. There are two
types of data packets identified by differing PIDs: DATA0 and DATA1. Two data packet PIDs are
defined to support data toggle synchronization.
Data must always be sent in integral numbers of bytes. The data CRC is computed over only the
data field in the packet and does not include the PID, which has its own check field.
Table 5-73. Data Packet Format
Packet
5.16.5.4
Width
PID
8 bits
DATA
0–1023 bytes
CRC16
16 bits
Handshake Packets
Handshake packets consist of only a PID. Handshake packets are used to report the status of a data
transaction and can return values indicating successful reception of data, flow control, and stall
conditions. Only transaction types that support flow control can return handshakes. Handshakes are
always returned in the handshake phase of a transaction and may be returned, instead of data, in the
data phase. Handshake packets are delimited by an EOP after one byte of packet field. If a packet is
decoded as an otherwise valid handshake but does not terminate with an EOP after one byte, it
must be considered invalid and ignored by the receiver.
There are three types of handshake packets:
• ACK indicates that the data packet was received without bit stuff or CRC errors over the data
field and that the data PID was received correctly. An ACK handshake is applicable only in
transactions in which data has been transmitted and where a handshake is expected. ACK can
be returned by the host for IN transactions and by a function for OUT transactions.
• NAK indicates that a function was unable to accept data from the host (OUT) or that a
function has no data to transmit to the host (IN). NAK can only be returned by functions in the
data phase of IN transactions or the handshake phase of OUT transactions. The host can never
issue a NAK. NAK is used for flow control purposes to indicate that a function is temporarily
unable to transmit or receive data, but will eventually be able to do so without need of host
intervention. NAK is also used by interrupt endpoints to indicate that no interrupt is pending.
• STALL is returned by a function in response to an IN token or after the data phase of an OUT.
STALL indicates that a function is unable to transmit or receive data, and that the condition
requires host intervention to remove the stall. Once a function’s endpoint is stalled, the
function must continue returning STALL until the condition causing the stall has been cleared
through host intervention. The host is not permitted to return a STALL under any condition.
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82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.16.5.5
Handshake Responses
IN Transaction
A function may respond to an IN transaction with a STALL or NAK. If the token received was
corrupted, the function issues no response. If the function can transmit data, it issues the data
packet. The ICH2, as the USB host, can return only one type of handshake on an IN transaction, an
ACK. If it receives a corrupted data or cannot accept data due to a condition such as an internal
buffer overrun, it discards the data and issues no response.
OUT Transaction
A function may respond to an OUT transaction with a STALL, ACK, or NAK. If the transaction
contained corrupted data, it will issue no response.
SETUP Transaction
Setup defines a special type of host to function data transaction which permits the host to initialize
an endpoint’s synchronization bits to those of the host. Upon receiving a Setup transaction, a
function must accept the data. Setup transactions cannot be STALLed or NAKed and the receiving
function must accept the Setup transfer’s data. If a non-control endpoint receives a SETUP PID, it
must ignore the transaction and return no response.
5.16.6
USB Interrupts
There are two general groups of USB interrupt sources, those resulting from execution of
transactions in the schedule, and those resulting from an ICH2 operation error. All transactionbased sources can be masked by software through the ICH2’s Interrupt Enable register.
Additionally, individual transfer descriptors can be marked to generate an interrupt on completion.
When the ICH2 drives an interrupt for USB, it drives the PIRQD# pin active for interrupts
occurring due to ports 0 and 1 until all sources of the interrupt are cleared.
5.16.6.1
Transaction Based Interrupts
These interrupts are not signaled until after the status for the last complete transaction in the frame
has been written back to host memory. This guarantees that software can safely process through
(Frame List Current Index -1) when it is servicing an interrupt.
CRC Error / Time-out
A CRC/Time-out error occurs when a packet transmitted from the ICH2 to a USB device or a
packet transmitted from a USB device to the ICH2 generates a CRC error. The ICH2 is informed of
this event by a time-out from the USB device or by the ICH2’s CRC checker generating an error on
reception of the packet. Additionally, a USB bus time-out occurs when USB devices do not
respond to a transaction phase within 19 bit times of an EOP. Either of these conditions will cause
the C_ERR field of the TD to decrement. When the C_ERR field decrements to zero, the following
occurs:
•
•
•
•
The Active bit in the TD is cleared
The Stalled bit in the TD is set
The CRC/Time-out bit in the TD is set.
At the end of the frame, the USB Error Interrupt bit is set in the HC status register.
If the CRC/Time out interrupt is enabled in the Interrupt Enable register, a hardware interrupt is
signaled to the system.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-125
Functional Description
Interrupt on Completion
Transfer Descriptors contain a bit that can be set to cause an interrupt on their completion. The
completion of the transaction associated with that block causes the USB Interrupt bit in the HC
Status Register to be set at the end of the frame in which the transfer completed. When a TD is
encountered with the IOC bit set to 1, the IOC bit in the HC Status register is set to 1 at the end of
the frame if the active bit in the TD is set to 0 (even if it was set to zero when initially read).
If the IOC Enable bit of Interrupt Enable register (bit 2 of I/O offset 04h) is set, a hardware
interrupt is signaled to the system. The USB Interrupt bit in the HC Status register is set either
when the TD completes successfully or because of errors. If the completion is because of errors,
the USB Error bit in the HC Status register is also set.
Short Packet Detect
A transfer set is a collection of data which requires more than 1 USB transaction to completely
move the data across the USB. An example might be a large print file which requires numerous
TDs in multiple frames to completely transfer the data. Reception of a data packet that is less than
the endpoint’s Max Packet size during Control, Bulk or Interrupt transfers signals the completion
of the transfer set, even if there are active TDs remaining for this transfer set. Setting the SPD bit in
a TD indicates to the HC to set the USB Interrupt bit in the HC Status register at the end of the
frame in which this event occurs. This feature streamlines the processing of input on these transfer
types. If the Short Packet Interrupt Enable bit in the Interrupt Enable register is set, a hardware
interrupt is signaled to the system at the end of the frame where the event occurred.
Serial Bus Babble
When a device transmits on the USB for a time greater than its assigned Max Length, it is said to
be babbling. Since isochrony can be destroyed by a babbling device, this error results in the Active
bit in the TD being cleared to 0 and the Stalled and Babble bits being set to one. The C_ERR field
is not decremented for a babble. The USB Error Interrupt bit in the HC Status register is set to 1 at
the end of the frame. A hardware interrupt is signaled to the system.
If an EOF babble was caused by the ICH2 (due to incorrect schedule for instance), the ICH2 forces
a bit stuff error followed by an EOP and the start of the next frame.
Stalled
This event indicates that a device/endpoint returned a STALL handshake during a transaction or
that the transaction ended in an error condition. The TDs Stalled bit is set and the Active bit is
cleared. Reception of a STALL does not decrement the error counter. A hardware interrupt is
signaled to the system.
Data Buffer Error
This event indicates that an overrun of incoming data or a under-run of outgoing data has occurred
for this transaction. This would generally be caused by the ICH2 not being able to access required
data buffers in memory within necessary latency requirements. Either of these conditions causes
the C_ERR field of the TD to be decremented.
When C_ERR decrements to zero, the Active bit in the TD is cleared, the Stalled bit is set, the USB
Error Interrupt bit in the HC Status register is set to 1 at the end of the frame and a hardware
interrupt is signaled to the system.
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82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
Bit Stuff Error
A bit stuff error results from the detection of a sequence of more that 6 ones in a row within the
incoming data stream. This will cause the C_ERR field of the TD to be decremented. When the
C_ERR field decrements to zero, the Active bit in the TD is cleared to 0, the Stalled bit is set to 1,
the USB Error Interrupt bit in the HC Status register is set to 1 at the end of the frame and a
hardware interrupt is signaled to the system.
5.16.6.2
Non-Transaction Based Interrupts
If an ICH2 process error or system error occur, the ICH2 halts and immediately issues a hardware
interrupt to the system.
Resume Received
This event indicates that the ICH2 received a RESUME signal from a device on the USB bus
during a global suspend. If this interrupt is enabled in the Interrupt Enable register, a hardware
interrupt will be signaled to the system allowing the USB to be brought out of the suspend state and
returned to normal operation.
ICH2 Process Error
The HC monitors certain critical fields during operation to ensure that it does not process corrupted
data structures. These include checking for a valid PID and verifying that the MaxLength field is
less than 1280. If it detects a condition that would indicate that it is processing corrupted data
structures, it immediately halts processing, sets the HC Process Error bit in the HC Status Register
and signals a hardware interrupt to the system.
This interrupt cannot be disabled through the Interrupt Enable Register.
Host System Error
The ICH2 sets this bit to 1 when a PCI Parity error, PCI Master Abort, or PCI Target Abort occurs.
When this error occurs, the ICH2 clears the Run/Stop bit in the Command Register to prevent
further execution of the scheduled TDs. This interrupt cannot be disabled through the Interrupt
Enable Register.
5.16.7
USB Power Management
The Host Controller can be put into a suspended state and its power can be removed. This requires
that certain bits of information are retained in the resume power plane of the ICH2 so that a device
on a port may wake the system. Such a device may be a fax-modem, that wakes up the machine to
receive a fax or takes a voice message. The settings of the following bits in I/O space is maintained
when the ICH2 enters the S3, S4 or S5 states.
Table 5-74. Bits maintained in low power states
Register
Offset
Bit
Description
Command
00h
3
Enter Global Suspend Mode (EGSM)
Status
02h
2
Resume Detect
Port Status and Control
10h & 12h
2
Port Enabled/Disabled
6
Resume Detect
8
Low Speed Device Attached
12
Suspend
When the ICH2 detects a resume event on any of its ports, it sets the corresponding USB_STS bit
in ACPI space. If USB is enabled as a wake/break event, the system wakes up and an SCI is
generated.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-127
Functional Description
5.16.8
USB Legacy Keyboard Operation
When a USB keyboard is plugged into the system and a standard keyboard is not, the system may
not boot and DOS legacy software will not run; this is because the keyboard is not identified. The
ICH2 implements a series of trapping operations which snoop accesses that go to the keyboard
controller and put the expected data from the USB keyboard into the keyboard controller.
Note:
The scheme described below assumes that the keyboard controller (8042 or equivalent) is on the
LPC bus.
This legacy operation is performed through SMM space.
Figure 5-19 shows the Enable and Status path. The latched SMI source (60R, 60W, 64R, 64W) is
available in the Status Register. Because the enable is after the latch, it is possible to check for
other events that didn't necessarily cause an SMI. It is the software's responsibility to logically
AND the value with the appropriate enable bits.
Note also that the SMI is generated before the PCI cycle completes (e.g., before TRDY# goes
active) to ensure that the processor does not complete the cycle before the SMI is observed. This
method is used on MPIIX and has been validated.
The logic will also need to block the accesses to the 8042. If there is an external 8042, this is
accomplished by not activating the 8042 CS. This is done by logically ANDing the 4 enables
(60R, 60W, 64R, 64W) with the 4 types of accesses to determine if the 8042CS should go active.
An additional term is required for the “Pass-through” case. The state table for the diagram is shown
in Table 5-75.
Figure 5-19. USB Legacy Keyboard Flow Diagram
To Individual
"Caused By"
"Bits"
60 READ
KBC Accesses
S
Clear SMI_60_R
Comb.
PCI Config
Read, Write
D
AND
R
Decoder
EN_SMI_ON_60R
SMI
Same for 60W, 64R, 64W
OR
EN_PIRQD#
AND
To PIRQD#
To "Caused By" Bit
USB_IRQ
S
Clear USB_IRQ
D
AND
R
EN_SMI_ON_IRQ
5-128
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
Table 5-75. USB Legacy Keyboard State Transitions
Current State
Action
Data Value
Next State
Comment
IDLE
64h / Write
D1h
GateState1
Standard D1 command. Cycle passed through to
8042. SMI# doesn't go active. PSTATE goes to 1.
IDLE
64h / Write
Not D1h
IDLE
Bit 3 in configuration Register determines if cycle
passed through to 8042 and if SMI# generated.
IDLE
64h / Read
N/A
IDLE
Bit 2 in configuration Register determines if cycle
passed through to 8042 and if SMI# generated.
IDLE
60h / Write
Don't Care
IDLE
Bit 1 in configuration Register determines if cycle
passed through to 8042 and if SMI# generated.
IDLE
60h / Read
N/A
IDLE
Bit 0 in configuration Register determines if cycle
passed through to 8042 and if SMI# generated.
GateState1
60h / Write
XXh
GateState2
Cycle passed through to 8042, even if trap
enabled in Bit 1 in configuration Register. No
SMI# generated. PSTATE remains 1. If data
value is not DFh or DDh then the 8042 may
chose to ignore it.
Cycle passed through to 8042, even if trap
enabled via Bit 3 in configuration Register. No
SMI# generated. PSTATE remains 1. Stay in
GateState1 because this is part of the doubletrigger sequence.
GateState1
64h / Write
D1h
GateState1
GateState1
64h / Write
Not D1h
ILDE
Bit 3 in configuration space determines if cycle
passed through to 8042 and if SMI# generated.
PSTATE goes to 0. If Bit 7 in configuration
Register is set, then SMI# should be generated.
This is an invalid sequence. Bit 0 in configuration
Register determines if cycle passed through to
8042 and if SMI# generated. PSTATE goes to 0.
If Bit 7 in configuration Register is set, then SMI#
should be generated.
GateState1
60h / Read
N/A
IDLE
GateState1
64h / Read
N/A
GateState1
GateState2
64 / Write
FFh
IDLE
Standard end of sequence. Cycle passed through
to 8042. PSTATE goes to 0. Bit 7 in configuration
Space determines if SMI# should be generated.
Improper end of sequence. Bit 3 in configuration
Register determines if cycle passed through to
8042 and if SMI# generated. PSTATE goes to 0.
If Bit 7 in configuration Register is set, then SMI#
should be generated.
GateState2
64h / Write
Not FFh
IDLE
GateState2
64h / Read
N/A
GateState2
GateState2
GateState2
60h / Write
60h / Read
XXh
N/A
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Just stay in same state. Generate an SMI# if
enabled in Bit 2 of configuration Register.
PSTATE remains 1.
Just stay in same state. Generate an SMI# if
enabled in Bit 2 of configuration Register.
PSTATE remains 1.
IDLE
Improper end of sequence. Bit 1 in configuration
Register determines if cycle passed through to
8042 and if SMI# generated. PSTATE goes to 0.
If Bit 7 in configuration Register is set, then SMI#
should be generated.
IDLE
Improper end of sequence. Bit 0 in configuration
Register determines if cycle passed through to
8042 and if SMI# generated. PSTATE goes to 0.
If Bit 7 in configuration Register is set, then SMI#
should be generated.
5-129
Functional Description
5.17
SMBus Controller Functional Description (D31:F3)
The ICH2 provides an SMBus Host Controller as well as an SMBus Slave Interface.
The Host Controller provides a mechanism for the processor to initiate communications with
SMBus peripherals (slaves). The ICH2 is also capable of operating in a mode in which it can
communicate with I2C compatible devices.
The Slave Interface allows an external master to read from or write to the ICH2. Write cycles can
be used to cause certain events or pass messages and the read cycles can be used to determine the
state of various status bits. The ICH2’s internal Host Controller cannot access the ICH2’s internal
Slave Interface.
The ICH2 SMBus logic exists in Device 31:Function 3 configuration space and consists of a
transmit data path and host controller. The transmit data path provides the data flow logic needed to
implement the seven different SMBus command protocols and is controlled by the host controller.
The ICH2 SMBus controller logic is clocked by RTC clock.
The programming model of the host controller is combined into two portions: a PCI configuration
portion and a system I/O mapped portion. All static configuration (e.g., the I/O base address) is
done via the PCI configuration space. Real-time programming of the Host interface is done in
system I/O space.
5.17.1
Host Controller
The SMBus Host Controller is used to send commands to other SMBus slave devices. Software
sets up the host controller with an address, command, and, for writes, data, and then tells the
controller to start. When the controller has finished transmitting data on writes, or receiving data on
reads, it will generate an SMI# or interrupt, if enabled.
The host controller supports 7 command protocols of the SMBus interface (see System
Management Bus Specification, Rev 1.0): Quick Command, Send Byte, Receive Byte, Write Byte/
Word, Read Byte/Word, Process Call, and Block Read/Write.
The SMBus Host Controller requires that the various data and command fields be setup for the type
of command to be sent. When software sets the START bit, the SMBus Host Controller performs
the requested transaction and interrupts the processor (or generate an SMI#) when the transaction is
completed. Once a START command has been issued, the values of the “active registers” (Host
Control, Host Command, Transmit Slave Address, Data 0, Data 1) should not be changed or read
until the interrupt status bit (INTR) has been set (indicating the completion of the command). Any
register values needed for computation purposes should be saved prior to issuing of a new
command, as the SMBus Host Controller will update all registers while completing the new
command.
Using the SMB Host Controller to send commands to the ICH2's SMB slave port is not supported.
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82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.17.1.1
Command Protocols
In all of the following commands, the Host Status Register (offset 00h) is used to determine the
progress of the command. While the command is in operation, the HOST_BUSY bit is set. If the
command completes successfully, the INTR bit is set in the Host Status Register. If the device does
not respond with an acknowledge and the transaction times out, the DEV_ERR bit is set. If
software sets the KILL bit in the Host Control Register while the command is running, the
transaction will stop and the FAILED bit will be set.
Quick Command
When programmed for a Quick Command, the Transmit Slave Address Register is sent. The format
of the protocol is shown in Table 5-76.
Table 5-76. Quick Protocol
Bit
Description
1
Start Condition
2:8
Slave Address - 7 bits
9
Read / Write Direction
10
Acknowledge from slave
11
Stop
Send Byte / Receive Byte
For the Send Byte command, the Transmit Slave Address and Device Command Registers are sent
For the Receive Byte command, the Transmit Slave Address Register is sent. The data received is
stored in the DATA0 register.
The Receive Byte is similar to a Send Byte; the only difference is the direction of data transfer. The
format of the protocol is shown in Table 5-77.
Table 5-77. Send / Receive Byte Protocol
Send Byte Protocol
Bit
1
2:8
Description
Start
Slave Address - 7 bits
Receive Byte Protocol
Bit
1
2:8
Description
Start
Slave Address - 7 bits
9
Write
9
Read
10
Acknowledge from slave
10
Acknowledge from slave
11:18
Command code - 8 bits
11:18
Data byte from slave
19
Acknowledge from slave
19
NOT Acknowledge
20
Stop
20
Stop
Write Byte/Word
The first byte of a Write Byte/Word access is the command code. The next 1 or 2 bytes are the data
to be written. When programmed for a write byte/word command, the Transmit Slave Address,
Device Command and Data0 Registers are sent. In addition, the Data1 Register is sent on a write
word command. The format of the protocol is shown in Table 5-78.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-131
Functional Description
Table 5-78. Write Byte/Word Protocol
Write Byte Protocol
Bit
1
2:8
Description
Start
Write
Bit
1
Slave Address - 7 bits
9
Write Word Protocol
2:8
9
Description
Start
Slave Address - 7 bits
Write
10
Acknowledge from slave
10
Acknowledge from slave
11:18
Command code - 8 bits
11:18
Command code - 8 bits
19
Acknowledge from slave
19
Acknowledge from slave
20:27
Data Byte - 8 bits
28
Acknowledge from Slave
29
Stop
20:27
28
29:36
Data Byte Low - 8 bits
Acknowledge from Slave
Data Byte High - 8 bits
37
Acknowledge from slave
38
Stop
Read Byte/Word
Reading data is slightly more complicated than writing data. First the ICH2 must write a command
to the slave device. Then it must follow that command with a repeated start condition to denote a
read from that device's address. The slave then returns 1 or 2 bytes of data.
When programmed for the read byte/word command, the Transmit Slave Address and Device
Command Registers are sent. Data is received into the DATA0 on the read byte, and the DAT0 and
DATA1 registers on the read word. The format of the protocol is shown in Table 5-79.
Table 5-79. Read Byte/Word Protocol
Read Byte Protocol
Bit
1
2:8
Start
Slave Address - 7 bits
Bit
1
2:8
Description
Start
Slave Address - 7 bits
9
Write
9
Write
10
Acknowledge from slave
10
Acknowledge from slave
11:18
Command code - 8 bits
11:18
Command code - 8 bits
19
Acknowledge from slave
19
Acknowledge from slave
20
21:27
5-132
Description
Read Word Protocol
Repeated Start
Slave Address - 7 bits
20
21:27
Repeated Start
Slave Address - 7 bits
28
Read
28
Read
29
Acknowledge from slave
29
Acknowledge from slave
30:37
Data from slave - 8 bits
30:37
38
NOT acknowledge
39
Stop
38
39:46
Data Byte Low from slave - 8 bits
Acknowledge
Data Byte High from slave - 8 bits
47
NOT acknowledge
48
Stop
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
Process Call
The process call is so named because a command sends data and waits for the slave to return a
value dependent on that data. The protocol is simply a Write Word followed by a Read Word, but
without a second command or stop condition.
When programmed for the Process Call command, the ICH2 transmits the Transmit Slave Address,
Host Command, DATA0 and DATA1 registers. Data received from the device is stored in the
DATA0 and DATA1 registers. The format of the protocol is shown in Table 5-80.
Note:
For process call command, the value written into bit 0 of the Transmit Slave Address Register
(SMB I/O register, offset 04h) needs to be 0.
Table 5-80. Process Call Protocol
Bit
1
2:8
Description
Start
Slave Address - 7 bits
9
Write
10
Acknowledge from Slave
11:18
Command code - 8 bits
19
Acknowledge from slave
20:27
28
29:36
Data byte Low - 8 bits
Acknowledge from slave
Data Byte High - 8 bits
37
Acknowledge from slave
38
Repeated Start
39:45
Slave Address - 7 bits
46
Read
47
Acknowledge from slave
48:55
56
57:64
Data Byte Low from slave - 8 bits
Acknowledge
Data Byte High from slave - 8 bits
65
NOT acknowledge
66
Stop
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-133
Functional Description
Block Read/Write
The Block Write begins with a slave address and a write condition. After the command code, the
ICH2 issues a byte count which describes how many more bytes will follow in the message. If a
slave had 20 bytes to send, the first byte would be the number 20 (14h), followed by the 20 bytes of
data. The byte count may not be 0.
Note that, unlike the PIIX4, which implements 32-byte buffer for Block Read/Write command, the
ICH2 implements the Block Data Byte register (D31:F3, I/O offset 07h) for Block Read/Write
command.
When programmed for a block write command, the Transmit Slave Address, Host Command, and
Data0 (count) registers are sent. Data is then sent from the Block Data Byte register. After the byte
has been sent, the ICH2 sets the BYTE_DONE_STS bit in the Host Status register. If there are
more bytes to send, software writes the next byte to the Block Data Byte register and also clears the
BYTE_DONE_STS bit. The ICH2 then sends the next byte. When doing a block write, first poll
the BYTE_DONE_STS register until it is set, then write the next byte, then clear the
BYTE_DONE_STS register.
On block read commands, after the byte count is stored in the DATA 0 register, the first data byte
goes in the Block Data Byte Register; the ICH2 will then set the BYTE_DONE_STS bit and
generate an SMI# or interrupt. The SMI# or interrupt handler reads the byte and then clears the
BYTE_DONE_STS bit to allow the next byte to be read into the Block Data Byte register. Note
that after receiving data byte N-1 of the block, the software needs to set the LAST_BYTE bit in the
Host Control Register; this allows the ICH2 to send a NOT ACK (instead of an ACK) after
receiving the last data byte (byte N) of the block.
After each byte of a block message the ICH2 sets the BYTE_DONE_STS bit and generates an
interrupt or SMI#. Software clears the BYTE_DONE_STS bit before the next transfer occurs.
When the interrupt handler clears the BYTE_DONE_STS bit after the last byte has been
transferred, the ICH2 sets the INTR bit and generates another interrupt to signal the end of the
block transfer. Thus, for a block message of n bytes, the ICH2 generates n+1 interrupts. The
interrupt handler needs to be implemented to handle all of these interrupts
The format of the Block Read/Write protocol is shown in Table 5-81.
Note:
5-134
For Block Write, if the I2C_EN bit is set, the format of the command changes slightly. The ICH2
still sends the number of bytes indicated in the DATA0 register. However, it does not send the
contents of the Data 0 register as part of the message.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
l
Table 5-81. Block Read/Write Protocol
Block Write Protocol
Bit
1
2:8
Description
Start
Slave Address - 7 bits
9
Write
Block Read Protocol
Bit
1
2:8
9
Description
Start
Slave Address - 7 bits
Write
10
Acknowledge from slave
10
Acknowledge from slave
11:18
Command code - 8 bits
11:18
Command code - 8 bits
19
Acknowledge from slave
19
Acknowledge from slave
20
Repeated Start
20:27
28
29:36
37
38:45
46
...
Byte Count - 8 bits
(Skip this step if I2C_En bit set)
Acknowledge from Slave
(Skip this step if I2C_EN bit set)
21:27
Slave Address - 7 bits
Data Byte 1 - 8 bits
28
Read
Acknowledge from Slave
29
Acknowledge from slave
Data Byte 2–8 bits
Acknowledge from slave
Data Bytes / Slave
Acknowledges...
...
Data Byte N - 8 bits
...
Acknowledge from Slave
...
Stop
30:37
38
39:46
47
48:55
Byte Count from slave - 8 bits
Acknowledge
Data Byte 1 from slave - 8 bits
Acknowledge
Data Byte 2 from slave - 8 bits
56
Acknowledge
...
Data Bytes from slave/Acknowledge
...
Data Byte N from slave - 8 bits
...
NOT Acknowledge
...
Stop
I2C Read
This command allows the ICH2 to perform block reads to certain I2C devices (e.g., serial
E2PROMs). The SMBus Block Read sends both the 7-bit address, as well as the Command field.
This command field could be used as the extended 10-bit address for accessing I2C devices that use
10-bit addressing.
However, this does not allow access to devices using the I2C “Combined Format” that has data
bytes after the address. Typically, these data bytes correspond to an offset (address) within the
serial memory chips.
Note:
This new command is supported independent of the setting of the I2C_EN bit.
For I2C Read command, the value written into bit 0 of the Transmit Slave Address Register (SMB
I/O register, offset 04h) needs to be 0. The format that is used for the new command is shown in
Table 5-82:
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-135
Functional Description
Table 5-82. I2C Block Read
Bit
1
2:8
Description
Start
Slave Address - 7 bits
9
Write
10
Acknowledge from slave
11:18
Command code - 8 bits
19
Acknowledge from slave
20:27
28
29:36
Send DATA0 register
Acknowledge from slave
Send DATA1 register
37
Acknowledge from slave
38
Repeated start
39:45
Slave Address - 7 bits
46
Read
47
Acknowledge from slave
48:55
56
57:64
65
Data byte from slave
Acknowledge
Data byte 2 from slave - 8 bits
Acknowledge
-
Data bytes from slave / Acknowledge
-
Data byte N from slave - 8 bits
-
NOT Acknowledge
-
Stop
The ICH2 continues reading data from the peripheral until the NAK is received.
5.17.1.2
I2C Behavior
When the I2C_EN bit is set, the ICH2 SMBus logic is instead set to communicate with I2C devices.
This forces the following changes:
1. The Process Call command will skip the Command code (and its associated acknowledge)
2. The Block Write command will skip sending the Byte Count (DATA0)
In addition, the ICH2 supports the new I2C Read command. This is independent of the I2C_EN bit.
5.17.1.3
Heartbeat for Use With the External LAN Controller
This method allows the ICH2 to send messages to an external LAN Controller when the processor
is otherwise unable to do so. It uses the SMLINK I/F between the ICH2 and the external LAN
Controller. The actual Heartbeat message is a Block Write. Only 8 bytes are sent.
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82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.17.2
Bus Arbitration
Several masters may attempt to get on the bus at the same time by driving the SMBDATA line low
to signal a start condition. The ICH2 continuously monitors the SMBDATA line. When the ICH2 is
attempting to drive the bus to a 1 by letting go of the SMBDATA line and it samples SMBDATA
low, then some other master is driving the bus and the ICH2 stops transferring data.
If the ICH2 sees that it has lost arbitration, the condition is called a collision. The ICH2 sets the
BUS_ERR bit in the Host Status Register, and, if enabled, generates an interrupt or SMI#. The
processor is responsible for restarting the transaction.
When the ICH2 is a SMBus master, it drives the clock. When the ICH2 is sending address or
command as an SMBus master or data bytes as a master on writes, it drives data relative to the
clock it is also driving. It does not start toggling the clock until the start or stop condition meets
proper setup and hold time. The ICH2 also guarantees minimum time between SMBus transactions
as a master.
The ICH2 supports the same arbitration protocol for both the SMBus and the System Management
(SMLINK) interfaces.
Clock Stretching
Some devices may not be able to handle their clock toggling at the rate that the ICH2, as an SMBus
master, would like. They have the capability of stretching the low time of the clock. When the
ICH2 attempts to release the clock (allowing the clock to go high), the clock will remain low for an
extended period of time.
The ICH2 monitors the SMBus clock line after it releases the bus to determine whether to enable
the counter for the high time of the clock. While the bus is still low, the high time counter must not
be enabled. Similarly, the low period of the clock can be stretched by an SMBus master if it is not
ready to send or receive data.
The ICH2 SMBus Host Controller will never stretch the low period of the clock (SMBCLK). It
always has the data to transfer on writes and it always has a spot for the data on reads.
The SMLINK interface, however, always stretches the low period of the clock, effectively forcing
transfers down to 16 KHz.
Bus Time Out (ICH2 as SMBus Master)
If there is an error in the transaction, such that an SMBus device does not signal an acknowledge or
holds the clock lower than the allowed time-out time, the transaction times out. The ICH2 discards
the cycle and sets the DEV_ERR bit. The time-out minimum is 25 ms. The time-out counter inside
the ICH2 starts after the last bit of data is transferred by the ICH2 and it is waiting for a response.
The 25 ms is a count of 800 RTC clocks.
5.17.3
Interrupts / SMI#
The ICH2 SMBus controller uses PIRQB# as its interrupt pin. However, the system can
alternatively be set up to generate SMI# instead of an interrupt, by setting the SMBUS_SMI_EN
bit.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-137
Functional Description
5.17.4
SMBALERT#
SMBALERT# is multiplexed with GPIO[11]. When enabled and the signal is asserted, the ICH2
can generate an interrupt, an SMI#, or a wake event from S1-S4. To resume using SMBALERT#,
the SMB_SMI_EN bit must be enabled to generate an SMI (see Section 12.1.14, “HOSTC—Host
Configuration Register (SMBUS—D31:F3)” on page 12-5).
Note:
As long as SMBALERT# is enabled and asserted, the ICH2 will continue to assert PIRQ[B]# or
SMI# (depending on the state of the SMB_SMI_EN bit). To avoid continuous SMIs or interrupts,
the interrupt or SMI handler should:
1. Disable SMBALERT# by setting GPIO_USE_SEL[11] (GPIOBase + 00h, bit 11)
2. Use the SMBus Host Controller to service the peripheral that is asserting SMBALERT#
(causing the device to deassert the signal)
3. Re-enable SMBALERT# by clearing GPIO_USE_SEL[11].
5.17.5
SMBus Slave Interface
The ICH2’s SMBus Slave interface is accessed via the SMLINK[1:0] signals. The slave interface
allows the ICH2 to decode cycles and allows an external microcontroller to perform specific
actions. Key features and capabilities include:
• Supports decode of two messages type: Write and Read
• Receive Slave Address register: This is the address that the ICH2 decodes. A default value is
provided so that the slave interface can be used without the processor having to program this
register.
• Receive Slave Data register in the SMBus I/O space that includes the data written by the
external microcontroller
• Registers that the external microcontroller can read to get the state of the ICH2. See Table 5-87
• Status bit to indicate that the SMBus logic caused an SMI# due to the reception of a message
that matched the slave address. See Section 9.8.3.14.
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82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
Format of Slave Write Cycle
The external master performs Byte Write commands to the ICH2 SMBus Slave I/F. The
“Command” field (bits 11-18) indicate which register is being accessed. The Data field (bits 20-27)
indicate the value that should be written to that register.
The Write Cycle format is shown in Table 5-83. Table 5-84 lists the values associated with the
registers.
Table 5-83. Slave Write Cycle Format
Bits
Description
1
Driven by
Comment
Start Condition
External Microcontroller
Slave Address - 7 bits
External Microcontroller
Must match value in Receive Slave Address
register
9
Write
External Microcontroller
Always 0
10
ACK
ICH2
2:8
11:18
Command
External Microcontroller
ACK
ICH2
Register Data
External Microcontroller
28
ACK
ICH2
29
Stop
External Microcontroller
19
20:27
This field indicates which register will be
accessed.
See Table 5-84 below for the register
definitions
See Table 5-84 below for the register
definitions
Table 5-84. Slave Write Registers
Register
0
1–3
Function
Command Register. See Table 65 below for legal values written to this register.
Reserved
4
Data Message Byte 0
5
Data Message Byte 1
6–7
8
9–FFh
Reserved
Frequency Straps will be written on bits 3:0. Bits 7:4 should be 0, but will be ignored.
Reserved
NOTE: The external microcontroller is responsible to make sure that it does not update the contents of the data
byte registers until they have been read by the system processor. The ICH2 overwrites the old value
with any new value received. A race condition is possible where the new value is being written to the
register just at the time it is being read. ICH2 will not attempt to cover this race condition
(i.e., unpredictable results in this case).
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-139
Functional Description
Table 5-85. Command Types
Command
Type
0
Description
Reserved
WAKE/SMI#: Wake system if it is not already awake. If the system is already awake, an
SMI# is generated.
1
Note that the SMB_WAK_STS bit will be set by this command, even if the system is already
awake. The SMI handler should then clear this bit.
2
Unconditional Powerdown: This command sets the PWRBTNOR_STS bit and has the
same effect as the Powerbutton Override occurring. This functionality depends upon the
BIOS having cleared the PWRBTN_STS bit.
3
Hard Reset without Cycling: This causes a hard reset of the system (does not include
cycling of the power supply). This is equivalent to a write to the CF9h register with bits 2:1
set to 1, but bit 3 set to 0.
4
Hard Reset System: This causes a hard reset of the system (including cycling of the power
supply). This is equivalent to a write to the CF9h register with bits 3:1 set to 1.
5
Disable the TCO Messages. This command disables the ICH2 from sending Heartbeat and
Event messages (as described in Section 5.13.2). Once this command has been executed,
Heartbeat and Event message reporting can only be re-enabled by assertion and
deassertion of the RSMRST# signal.
6
WD RELOAD: Reload watchdog timer.
7–FFh
Reserved
Format of Read Command
The external master performs Byte Read commands to the ICH2 SMBus Slave interface. The
“Command” field (bits 11:18) indicate which register is being accessed. The Data field (bits 30:37)
contain the value that should be read from that register. Table 5-86 shows the Read Cycle format.
Table 5-87 shows the register mapping for the data byte.
Table 5-86. Read Cycle Format
Bit
1
Driven by
Comment
Start
External Microcontroller
Slave Address - 7 bits
External Microcontroller
Must match value in Receive Slave Address
register
9
Write
External Microcontroller
Always 0
10
ACK
ICH2
Command code – 8 bits
External Microcontroller
2:8
11:18
Indicates which register is being accessed.
See Table 5-87.
19
ACK
ICH2
20
Repeated Start
External Microcontroller
Slave Address - 7 bits
External Microcontroller
Must match value in Receive Slave Address
register
28
Read
External Microcontroller
Always 1
29
ACK
ICH2
30:37
Data Byte
ICH2
38
NOT ACK
External Microcontroller
39
Stop
ICH2
21:27
5-140
Description
Value depends on register being accessed.
See Table 5-87.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
Table 5-87. Data Values for Slave Read Registers
Register
Bits
0
7:0
1
2:0
Description
Reserved.
System Power State
000 = S0 001 = S1 010 = Reserved 011 = S3
100 = S4 101 = S5 110 = Reserved 111 = Reserved
1
7:3
Reserved
2
3:0
Frequency Strap Register
2
7:4
Reserved
3
5:0
Watchdog Timer current value
3
7:6
Reserved
4
0
1 = The Intruder Detect (INTRD_DET) bit is set. This indicates that the system cover has
probably been opened.
4
1
1 = BTI Temperature Event occurred. This bit is set if the ICH2’s THRM# input signal is
active. Need to take after polarity control.
4
2
DOA processor status. This bit is 1 to indicate that the processor is dead.
4
3
1 = Watchdog timer expired. This bit is set if the ICH2’s TCO timers have timed out.
4
6:4
4
7
Will reflect the state of the ICH2’s GPIO[11].
5
0
Unprogrammed FWH bit. This bit will be 1 to indicate that the first BIOS fetch returned
FFh, which indicates that the FWH is probably blank.
5
7:1
Reserved
6
7:0
Contents of the Message 1 register. See Section 9.9.10.
7
7:0
Contents of the Message 2 register. See Section 9.9.10.
8
7:0
Contents of the WDSTATUS register. See Section 9.9.11.
9–FFh
7:0
Reserved
Reserved.
Behavioral Notes
According to SMBus protocol, Read and Write messages always begin with a
Start bit - Address - Write bit sequence. When the ICH2 detects that the address matches the value
in the Receive Slave Address register, it assumes that the protocol is always followed and ignores
the Write bit (bit 9) and signal an Acknowledge during bit 10 (See Table 5-83 and Table 5-86). In
other words, if a Start - Address - Read occurs (which is illegal for SMBus Read or Write protocol),
and the address matches the ICH2’s Slave Address, the ICH2 will still grab the cycle.
Also according to SMBus protocol, a Read cycle contains a Repeated Start - Address - Read
sequence beginning at bit 20 (See Table 5-86). Once again, if the Address matches the ICH2’s
Receive Slave Address, it will assume that the protocol is followed, ignore bit 28, and proceed with
the Slave Read cycle.
Note:
An external microcontroller must not attempt to access the ICH2’s SMBus Slave logic until at least
1 second after both RTCRST# and RSMRST# are deasserted (high).
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-141
Functional Description
5.18
AC’97 Controller Functional Description
(Audio D31:F5, Modem D31:F6)
Note:
All references to AC’97 in this document refer to the AC’97 2.1 specification. For further
information on the operation of the AC-link protocol, see the AC’97 specification.
The ICH2 AC ‘97 Controller features include:
• Independent PCI functions for audio and modem.
• Independent bus master logic for Mic input, PCM Audio input (2-channel stereo), PCM audio
output (2, 4 or 6-channel stereo), Modem input and Modem output.
•
•
•
•
•
16 bit sample resolution
Multiple sample rates up to 48 KHz
16 GPIOs
Single modem line
Dual codec configuration with two SDIN pins
Table 5-88 shows a detailed list of features supported by the ICH2 AC’97 digital controller.
.
Table 5-88. Featured Supported by ICH2
Feature
Description
• Isochronous low latency bus master memory interface
• Scatter/gather support for word-aligned buffers in memory
(all mono or stereo 16-bit data types are supported, no 8-bit data types are supported)
• Data buffer size in system memory from 3 to 65535 samples per input
System Interface
• Data buffer size in system memory from 0 to 65535 samples per output
• Independent PCI audio and modem functions with configuration and IO spaces
• AC’97 codec registers are shadowed in system memory via driver (not PCI IO space)
• AC’97 codec register accesses are serialized via semaphore bit in PCI IO space (new
accesses are not allowed while a prior access is still in progress)
Power
Management
• Power management via ACPI control methods
Support for audio states: D0, D2, D3hot, D3cold
Support for modem states: D0, D3hot, D3cold
• SCI event generation for PCI modem function with wake-up from D3cold
• Independent codec D3 w/ Link down event, synchronized via two bit semaphore (in
PCI IO Space)
• Read/write access to audio codec registers 00h-3Ah and vendor registers 5Ah–7Eh
• 16-bit stereo PCM output, up to 48 kHz (L,R, Center, Sub-woofer, L-rear and R-rear
channels on slots 3,4,6,7,8.9)
• 16-bit stereo PCM input, up to 48 kHz (L,R channels on slots 3,4)
PCI Audio
Function
• 16-bit mono mic in w/ or w/o mono mix, up to 48 kHz (L,R channel, slots 3,4) (mono
mix supports mono hardware AEC reference for speakerphone)
• 16-bit mono PCM input, up to 48 kHz from dedicated mic ADC (slot 6)
(supports speech recognition or stereo hardware AEC ref for speakerphone)
• During cold reset AC_RST# is held low until after POST and software deassertion of
AC_RST# (supports passive PC_BEEP to speaker connection during POST)
5-142
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
Table 5-88. Featured Supported by ICH2 (Continued)
Feature
Description
• Read/write access to modem codec registers 3Ch-58h and vendor registers 5Ah–7Eh
• 16-bit mono modem line1 output and input, up to 48 kHz (slot 5)
PCI Modem
function
• Low latency GPIO[13:11,8:6,4:3,1:0] (GPIO[13:11,8:7,4:3,1:0] for the ICH2-M) via
hardwired update between slot 12 and PCI IO register
• Programmable PCI interrupt on modem GPIO input changes via slot 12 GPIO_INT
• SCI event generation on primary or secondary SDIN wake-up signal
• AC’97 2.1 compliant AC-link interface
• Variable sample rate output support via AC’97 SLOTREQ protocol
(slots 3,4,5,6,7,8,9)
AC-link
• Variable sample rate input support via monitoring of slot valid tag bits (slots 3,4,5,6)
• 3.3 V digital operation meets AC’97 2.1 DC switching levels
• AC-Link IO driver capability meets AC‘97 2.1 dual codec specifications
• Codec register status reads must be returned with data in the next AC-link frame, per
AC’97 2.1 specification.
Multiple Codec
Note:
• Dual codec addressing: All AC’97 codec register accesses are addressable to codec
ID 00 (primary) or codec ID 01 (secondary)
• Dual codec receive capability via primary and secondary SDIN pins
(primary, secondary SDIN frames are internally validated, synchronized, and OR’d)
Throughout this document, references to D31:F5 indicate that the audio function exists in PCI
Device 31, Function 5. References to D31:F6 indicate that the modem function exists in PCI
Device 31, Function 6.
Figure 5-20. ICH2 Based AC’97 2.1
Audio In (Record)
PC
Audio Out (Playback)
Modem
Mic.
5.18.1
AC-link Overview
The ICH2 is an AC’97 2.1 compliant controller that communicates with companion codecs via a
digital serial link called the AC-link. All digital audio/modem streams and command/status
information is communicated over the AC-link.
The AC-link is a bi-directional, serial PCM digital stream. It handles multiple input and output data
streams, as well as control register accesses, employing a time division multiplexed (TDM)
scheme. The AC-link architecture provides for data transfer through individual frames transmitted
in a serial fashion. Each frame is divided into 12 outgoing and 12 incoming data streams, or slots.
The architecture of the ICH2 AC-link allows a maximum of two codecs to be connected.
Figure 5-21 shows a two codec topology of the AC-link for the ICH2.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
5-143
Functional Description
Figure 5-21. AC’97 2.1 Controller-Codec Connection
Digital AC '97 2.1
Controller
AC '97 / AC' 97 2.1 /
AMC '97 2.1
RESET#
SDOUT
SYNC
AC '97 2.1
controller
section of the
ICH2
Primary
Codec
BIT_CLK
SDIN 0
SDIN 1
AC '97 / MC '97 2.1 /
AMC '97 2.1
Secondary
Codec
The AC-link consists of a five signal interface between the controller and codec. Table 5-89
indicates the AC-link signal pins on the ICH2 and their associated power wells.
Table 5-89. AC’97 Signals
Signal Name
Type
Power Well*
Description
AC_RESET#
Output
Resume
AC_SYNC
Output
Core
48 KHz fixed rate sample sync
AC_BIT_CLK
Input
Core
12.288 MHz Serial data clock
AC_SDOUT
Output
Core
Serial output data
AC_SDIN 0
Input
Resume
Serial input data
AC_SDIN 1
Input
Resume
Serial input data
Master hardware reset
NOTE: Power well voltage levels are 3.3V
ICH2 core well outputs may be used as strapping options for the ICH2, sampled during system
reset. These signals may have weak pull-ups/put-downs; however, this will not interfere with link
operation. ICH2 inputs integrate weak put-downs to prevent floating traces when a secondary
codec is not attached. When the Shut Off bit in the control register is set, all buffers will be turned
off and the pins will be held in a steady state, based on these pull-ups/put-downs.
BIT_CLK is fixed at 12.288 MHz and is sourced by the primary codec. It provides the necessary
clocking to support the twelve 20 bit time slots. AC-link serial data is transitioned on each rising
edge of BIT_CLK. The receiver of AC-link data samples each serial bit on the falling edge of
BIT_CLK.
Synchronization of all AC-link data transactions is signaled by the AC’97 controller via the
AC_SYNC signal, as shown in Figure 5-22. The primary codec drives the serial bit clock onto the
AC-link, which the AC’97 controller then qualifies with the AC_SYNC signal to construct data
frames. AC_SYNC, fixed at 48 KHz, is derived by dividing down BIT_CLK. AC_SYNC remains
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82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
high for a total duration of 16 BIT_CLKs at the beginning of each frame. The portion of the frame
where AC_SYNC is high is defined as the tag phase. The remainder of the frame where AC_SYNC
is low is defined as the data phase. Each data bit is sampled on the falling edge of BIT_CLK.
Figure 5-22. AC-link Protocol
Tag Phase
Data Phase
20.8uS
(48 KHz)
SYNC
12.288 MHz
81.4 nS
BIT_CLK
Codec
Ready
SDIN
End of previous
Audio Frame
slot(1) slot(2)
slot(12) "0"
"0"
Time Slot "Valid"
Bits
("1" = time slot contains valid PCM
"0"
19
0
Slot 1
19
0
Slot 2
19
0
19
Slot 3
0
Slot 12
The ICH2 has two SDIN pins allowing a single or dual codec configuration. When two codecs are
connected, the primary and secondary codecs can be connected to either SDIN line, however it is
recommended that the primary codec be attached to SDIN [0]. The ICH2 does not distinguish
between primary and secondary codecs on its SDIN[1:0] pins; however, the registers do distinguish
between SDIN[0] and SDIN[1] for wake events, etc. The primary codec can be an AC (audio
codec), MC (modem codec), or AMC (audio/modem codec) device. The secondary codec can be
an AC, MC, or AMC device.
The MC can be either on the primary or the secondary codec, while the AC can be either on the
primary or the secondary codec, or BOTH the primary or the secondary codec.
The ICH2 does not support optional test modes as outlined in the AC’97 specification.
AC-link Output Frame (SDOUT)
A new audio output frame begins with a low to high transition of AC_SYNC. AC_SYNC is
synchronous to the rising edge of BIT_CLK. On the immediately following falling edge of
BIT_CLK, the codec samples the assertion of AC_SYNC. This falling edge marks the time when
both sides of AC-link are aware of the start of a new frame. On the next rising edge of BIT_CLK,
the ICH2 transitions SDOUT into the first bit position of slot 0, or the valid frame bit. Each new bit
position is presented to the AC-link on a rising edge of BIT_CLK, and subsequently sampled by
the codec on the following falling edge of BIT_CLK. This sequence ensures that data transitions
and subsequent sample points for both incoming and outgoing data streams are time aligned.
The output frame data phase corresponds to the multiplexed bundles of all digital output data
targeting codec DAC inputs and control registers. Each output frame supports up to twelve
outgoing data time slots. The ICH2 generates 16 bit samples and, in compliance with the AC’97
specification, pads the 4 least significant bits of valid slots with zeros.
The output data stream is sent with the most significant bit first and all invalid slots are stuffed with
0s. When mono audio sample streams are output from the ICH2, software must ensure both left and
right sample stream time slots are filled with the same data.
Output Slot 0: Tag Phase
Slot 0 is considered the tag phase. The tag phase is a special 16 bit time slot wherein each bit
conveys a valid tag for its corresponding time slot within the current frame. A one in a given bit
position of slot 0 indicates that the corresponding time slot within the current frame has been
82801BA ICH2 and 82801BAM ICH2-M Datasheet
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Functional Description
assigned to a data stream and contains valid data. If a slot is tagged invalid with a zero in the
corresponding bit position of slot 0, the ICH2 stuffs the corresponding slot with zeros during that
slot’s active time.
Within slot 0, the first bit is a valid frame bit (slot 0, bit 15) which flags the validity of the entire
frame. If the valid frame bit is set to one, this indicates that the current frame contains at least one
slot with valid data. When there is no transaction in progress, the ICH2 deasserts the frame valid
bit. Note that after a write to slot 12, that slot always stays valid; therefore, the frame valid bit
remains set.
The next 12 bit positions of slot 0 (bits [14:3]) indicate which of the corresponding twelve time
slots contain valid data. Bits [1:0] of slot 0 are used as codec ID bits to distinguish between
separate codecs on the link.
Using the valid bits in the tag phase allows data streams of differing sample rates to be transmitted
across the link at its fixed 48 KHz frame rate. The codec can control the output sample rate of the
ICH2 using the SLOTREQ bits as described in the AC’97 specification.
Output Slot 1: Command Address Port
The command port is used to control features and monitor status of AC‘97 functions including, but
not limited to, mixer settings and power management.
The control interface architecture supports up to 64 16-bit read/write registers, addressable on even
byte boundaries. Only the even registers (00h, 02h, etc.) are valid. Output frame slot 1
communicates control register address and write/read command information.
In the case of the split codec implementation, accesses to the codecs are differentiated by the driver
using address offsets 00h–7Fh for the primary codec and address offsets 80h–FEh for the
secondary codec. The differentiation on the link, however, is done via the codec ID bits. See
Section for further details.
Output Slot 2: Command Data Port
The command data port is used to deliver 16-bit control register write data in the event that the
current command port operation is a write cycle as indicated in slot 1, bit 19. If the current
command port operation is a read then the entire slot time stuffed with 0s by the ICH2. Bits [19:4]
contain the write data. Bits [3:0] are reserved and are stuffed with zeros.
Output Slot 3: PCM Playback Left Channel
Output frame slot 3 is the composite digital audio left playback stream. Typically, this slot is
composed of standard PCM (.wav) output samples digitally mixed by the host processor. The ICH2
transmits sample streams of 16 bits and stuffs the remaining bits with zeros.
Data in output slots 3 and 4 from the ICH2 should be duplicated by software if there is only a single
channel out.
Output Slot 4: PCM Playback Right Channel
Output frame slot 4 is the composite digital audio right playback stream. Typically, this slot is
composed of standard PCM (.wav) output samples digitally mixed by the host processor. The ICH2
transmits sample streams of 16 bits and stuffs the remaining bits with zeros.
Data in output slots 3 and 4 from the ICH2 should be duplicated by software if there is only a single
channel out.
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Functional Description
Output Slot 5: Modem Codec
Output frame slot 5 contains modem DAC data. The modem DAC output supports 16 bit
resolution. At boot time, if the modem codec is supported, the AC’97 controller driver determines
the DAC resolution. During normal runtime operation the ICH2 stuffs trailing bit positions within
this time slot with 0s.
Output Slot 6: PCM Playback Center Front Channel
When set up for 6 channel mode, this slot is used for the front center channel. The format is the
same as Slots 3. If not set up for 6 channel mode, this channel will always be stuffed with 0s by
ICH2.
Output Slots 7–8: PCM Playback Left and Right Rear Channels
When set up for 4 or 6 channel modes, slots 7 and 8 are used for the rear Left and Right channels.
The format for these two channels are the same as Slots 3 and 4.
Output Slot 9: Playback SubWoofer Channel
When set for 6 channel mode, this slot is used for the SubWoofer. The format is the same as Slots 3.
If not set up for 6 channel mode, this channel will always be stuffed with 0s by ICH2.
Output Slots 10–11: Reserved
Output frame slots 10–11 are reserved and are always stuffed with 0s by the ICH2 AC’97
controller.
Output Slot 12: I/O Control
The 16 bits of DAA and GPIO control (output) and status (input) have been directly assigned to
bits on slot 12 to minimize latency of access to changing conditions.
The value of the bits in this slot are the values written to the GPIO control register at offset 54h and
D4h (in the case of a secondary codec) in the modem codec I/O space. The following rules govern
the usage of slot 12.
1. Slot 12 is marked invalid by default on coming out of AC-link reset and will remain invalid
until a register write to 54h/D4h.
2. A write to offset 54h/D4h in codec I/O space will cause the write data to be transmitted on slot
12 in the next frame, with slot 12 marked valid, and the address/data information to also be
transmitted on slots 1 and 2.
3. After the first write to offset 54h/D4h, slot 12 remains valid for all following frames. The data
transmitted on slot 12 is the data last written to offset 54h/D4h. Any subsequent write to the
register will cause the new data to be sent out on the next frame.
4. Slot 12 will get invalidated after the following events: PCI reset, AC'97 cold reset, warm reset,
and hence a wake from S3, S4, or S5. Slot 12 will remain invalid until the next write to offset
54h/D4h.
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Functional Description
AC-link Input Frame (SDIN)
There are two SDIN lines on the ICH2 for use with a primary and secondary codec. Each SDIN pin
can have a codec attached. Depending upon which codec (AC, MC, or AMC) is attached, various
slots will be valid or invalid. The data slots on the two inputs must be completely orthogonal
(except for the tag slot 0), that is, no two data slots at the same location will be valid on both lines.
This precludes the use of two similar codecs (e.g., two ACs or MCs) which use the same time slots.
The input frame data streams correspond to the multiplexed bundles of all digital input data
targeting the AC’97 controller. As in the case for the output frame, each AC-link input frame
consists of twelve time slots.
A new audio input frame begins with a low-to-high transition of AC_SYNC. AC_SYNC is
synchronous to the rising edge of BIT_CLK. On the immediately following falling edge of
BIT_CLK, the receiver samples the assertion of AC_SYNC. This falling edge marks the time when
both sides of AC-link are aware of the start of a new audio frame. On the next rising edge of
BIT_CLK, the codec transitions SDIN into the first bit position of slot 0 (codec ready bit). Each
new bit position is presented to AC-link on a rising edge of BIT_CLK and subsequently sampled
by the ICH2 on the following falling edge of BIT_CLK. This sequence ensures that data transitions
and subsequent sample points for both incoming and outgoing data streams are time aligned.
SDIN data stream must follow the AC’97 specification and be MSB justified with all non-valid bit
positions (for assigned and/or unassigned time slots) stuffed with zeros. SDIN data is sampled by
the ICH2 on the falling edge of BIT_CLK.
Input Slot 0: Tag Phase
Input slot 0 consists of a codec ready bit (bit 15) and slot valid bits for each subsequent slot in the
frame (bits [14:3]).
The codec ready bit within slot 0 (bit 15) indicates whether the codec on the AC-link is ready for
operation. If the codec ready bit in slot 0 is a zero, the codec is not ready for normal operation.
When the AC-link codec ready bit is a 1, it indicates that the AC-link and codec control and status
registers are in a fully operational state. The codec ready bits are visible through the Global Status
register of the ICH2. Software must further probe the Powerdown Control/Status register in the
codec to determine exactly which subsections, if any, are ready.
Bits [14:3] in slot 0 indicate which slots of the input stream to the ICH2 contain valid data, just as
in the output frame. The remaining bits in this slot are stuffed with zeros.
Input Slot 1: Status Address Port / Slot Request Bits
The status port is used to monitor status of codec functions including, but not limited to, mixer
settings and power management.
Slot 1 must echo the control register index, for historical reference, for the data to be returned in
slot 2, assuming that slots 1 and 2 had been tagged valid by the codec in slot 0.
For multiple sample rate output, the codec examines its sample rate control registers, the state of its
FIFOs, and the incoming SDOUT tag bits at the beginning of each audio output frame to determine
which SLOTREQ bits to set active (low). SLOTREQ bits asserted during the current audio input
frame signal which output slots require data from the controller in the next audio output frame. For
fixed 48 kHz operation the SLOTREQ bits are always set active (low) and a sample is transferred
each frame.
For multiple sample rate input, the tag bit for each input slot indicates whether valid data is present
or not.
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82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
Table 5-90. Input Slot 1 Bit Definitions
Bit
19
18:12
Description
Reserved (Set to zero)
Control Register Index (Stuffed with zeros if tagged invalid)
11
Slot 3 Request: PCM Left Channel*
10
Slot 4 Request: PCM Right Channel*
9
Slot 5 Request: Modem Line 1
8
Slot 6 Request: PCM Center Channel*
7
Slot 7 Request: PCM Left Surround*
6
Slot 8 Request: PCM Right Surround*
5
Slot 9 Request: PCM LFE Channel*
4:2
Slot Request 10-12: Not Implemented
1:0
Reserved (Stuffed with zeros)
NOTE: *Slot 3 Request and Slot 4 Request bits must be the same value, i.e. set or cleared in tandem. This is
also true for the Slot 7 and Slot 8 Request bits, as well as the Slot 6 and Slot 9 Request bits.
As shown in Table 5-90, slot 1 delivers codec control register read address and multiple sample rate
slot request flags for all output slots of the controller. When a slot request bit is set by the codec, the
controller returns data in that slot in the next output frame. Slot request bits for slots 3 and 4 are
always set or cleared in tandem (i.e., both are set or cleared).
When set, the input slot 1 tag bit only pertains to Status Address Port data from a previous read.
SLOTREQ bits are always valid independent of the slot 1 tag bit.
Input Slot 2: Status Data Port
The status data port receives 16-bit control register read data.
Bit [19:4]: Control Register Read Data
Bit [3:0]: Reserved.
Input Slot 3: PCM Record Left Channel
Input slot 3 is the left channel input of the codec. ICH2 supports 16 bit sample resolution. Samples
transmitted to the ICH2 must be in left/right channel order.
Input Slot 4: PCM Record Right Channel
Input slot 4 is the right channel input of the codec. The ICH2 supports 16 bit sample resolution.
Samples transmitted to the ICH2 must be in left/right channel order.
Input Slot 5: Modem Line
Input slot 5 contains MSB justified modem data. The ICH2 supports 16 bit sample resolution.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
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Functional Description
Input Slot 6: Optional Dedicated Microphone Record Data
Input slot 6 is a third PCM system input channel available for dedicated use by a microphone. This
input channel supplements a true stereo output that enables more precise echo cancellation
algorithm for speakerphone applications. The ICH2 supports 16 bit resolution for slot 6 input.
Input Slots 7-11: Reserved
Input frame slots 7–11 are reserved for future use and should be stuffed with zeros by the codec,
per the AC’97 specification.
Input Slot 12: I/O status
The status of the GPIOs configured as inputs are to be returned on this slot in every frame. The data
returned on the latest frame is accessible to software by reading the register at offset 54h/D4h in the
codec I/O space. Only the 16 MSBs are used to return GPI status. Bit 0 of this slot indicates the
GPI status. When a GPI changes state, this bit gets set for one frame by the codec. This bit can
cause an interrupt to the processor if enabled via the Global Control register.
Reads from 54h/D4h are not transmitted across the link in slot 1 and 2. The data from the most
recent slot 12 is returned on reads from offset 54h/D4h.
Register Access
In the ICH2 implementation of the AC-link, up to two codecs can be connected to the SDOUT pin.
The following mechanism is used to address the primary and secondary codecs individually.
The primary device uses bit 19 of slot 1 as the direction bit to specify read or write. Bits [18:12] of
slot 1 are used for the register index. For I/O writes to the primary codec, the valid bits [14:13] for
slots 1 and 2 must be set in slot 0, as shown in Table 5-91. Slot 1 is used to transmit the register
address and slot 2 is used to transmit data. For I/O reads to the primary codec, only slot 1 should be
valid since only an address is transmitted. For I/O reads, only slot 1 valid bit is set; for I/O writes,
both slots 1 and 2 valid bits are set.
The secondary codec registers are accessed using slots 1 and 2 as described above, however the slot
valid bits for slots 1 and 2 are marked invalid in slot 0 and the codec ID bit 0 (bit 0 of slot 0) is set
to 1. This allows the secondary codec to monitor the slot valid bits of slots 1and 2, and bit 0 of slot
0 to determine if the access is directed to the secondary codec. If the register access is targeted to
the secondary codec, slot 1 and 2 will contain the address and data for the register access. Since
slots 1 and 2 are marked invalid, the primary codec will ignore these accesses.
Table 5-91. Output Tag Slot 0
Bit
5-150
Primary Access
Example
Secondary Access
Example
Description
15
1
1
Frame Valid
14
1
0
Slot 1 Valid, Command Address bit (Primary codec only)
13
1
0
Slot 2 Valid, Command Data bit (Primary codec only)
12:3
X
X
Slot 3-12 Valid
2
0
0
Reserved
1:0
00
01
Codec ID (00 reserved for primary; 01 indicate secondary)
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
When accessing the codec registers, only one I/O cycle can be pending across the AC-link at any
time. The ICH2 implements write posting on I/O writes across the AC-link (i.e., writes across the
link are indicated as complete before they are actually sent across the link). To prevent a second
I/O write from occurring before the first one is complete, software must monitor the CAS bit in the
Codec Access Semaphore register which indicates that a codec access is pending. Once the CAS
bit is cleared, then another codec access (read or write) can go through. The exception is reads to
offset 54h/D4h (slot 12) which are returned immediately with the most recently received slot 12
data. Writes to offset 54h and D4h (primary and secondary codecs), get transmitted across the
AC-link in slots 1 and 2 as a normal register access. Slot 12 is also updated immediately to reflect
the data being written.
The controller will not issue back-to-back reads. It must get a response to the first read before
issuing a second. In addition, codec reads and writes are only executed once across the link, and are
not repeated.
5.18.2
AC-Link Low Power Mode
The AC-link signals can be placed in a low power mode. When the AC‘97 Powerdown Register
(26h), is programmed to the appropriate value, both BIT_CLK and SDIN will be brought to and
held at a logic low voltage level.
Figure 5-23. AC-link Powerdown Timing
SYNC
BIT_CLK
SDOUT
slot 12
prev. frame
TAG
SDIN
slot 12
prev. frame
TAG
Write to
0x20
Data
PR4
Note:
BIT_CLK not to scale
BIT_CLK and SDIN transition low immediately following a write to the Powerdown Register
(26h) with PR4. When the AC‘97 controller driver is at the point where it is ready to program the
AC-link into its low power mode, slots 1 and 2 are assumed to be the only valid stream in the audio
output frame.
The AC‘97 controller also drives AC_SYNC, and SDOUT low after programming AC‘97 to this
low power, halted mode. Once the codec has been instructed to halt BIT_CLK, a special wake up
protocol must be used to bring the AC-link to the active mode since normal output and input
frames can not be communicated in the absence of BIT_CLK. Once in a low power mode, the
ICH2 provides three methods for waking up the AC-link; external wake event, cold reset and warm
reset.
Note:
Before entering any low power mode where the link interface to the codec is expected to be
powered down while the rest of the system is awake, the software must set the "Shut Off" bit in the
control register.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
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Functional Description
External Wake Event
Codecs can signal the controller to wake the AC-link and wake the system using SDIN. The
minimum SDIN wake up pulse width is 1 us. The rising edge of SDIN[0] or SDIN[1] causes the
ICH2 to sequence through an AC-link warm reset and set the AC97_STS bit in the GPE0_STS
register to wake the system. The primary codec must wait to sample AC_SYNC high and low
before restarting BIT_CLK as diagrammed in Figure 5-24. The codec that signaled the wake event
must keep its SDIN high until it has sampled AC_SYNC having gone high, and then low.
Figure 5-24. SDIN Wake Signaling
Power Down
Frame
Sleep State
New Audio
Frame
Wake Event
SYNC
BIT_CLK
SDOUT
slot 12
prev. frame
TAG
SDIN
slot 12
prev. frame
TAG
Write to
0x20
Data
PR4
TAG
Slot 1
Slot 2
TAG
Slot 1
Slot 2
The AC-link protocol provides for a cold reset and a warm reset. The type of reset used depends on
the system’s current power down state. Unless a cold or register reset (a write to the Reset register
in the codec) is performed, wherein the AC‘97 codec registers are initialized to their default values,
registers are required to keep state during all power down modes.
Once powered down, activation of the AC-link via re-assertion of the AC_SYNC signal must not
occur for a minimum of 4 audio frame times following the frame in which the power down was
triggered. When AC-link powers up, it indicates readiness via the codec ready bit.
5.18.3
AC‘97 Cold Reset
A cold reset is achieved by asserting AC_RST# for 1 us. By driving AC_RST# low, BIT_CLK, and
SDOUT will be activated and all codec registers will be initialized to their default power on reset
values. AC_RST# is an asynchronous AC‘97 input to the codec.
5.18.4
AC‘97 Warm Reset
A warm reset re-activates the AC-link without altering the current codec register values. A warm
reset is signaled by driving AC_SYNC high for a minimum of 1 us in the absence of BIT_CLK.
Within normal frames, AC_SYNC is a synchronous AC‘97 input to the codec. However, in the
absence of BIT_CLK, AC_SYNC is treated as an asynchronous input to the codec used in the
generation of a warm reset.
The codec must not respond with the activation of BIT_CLK until AC_SYNC has been sampled
low again by the codec. This will prevent the false detection of a new frame.
Note:
5-152
On receipt of wake up signalling from the codec, the digital controller will issue an interrupt if
enabled. Software will then have to issue a warm or cold reset to the codec by setting the
appropriate bit in the Global Control Register.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.18.5
System Reset
Table 5-92 indicates the states of the link during various system reset and sleep conditions.
Table 5-92. AC-link state during PCIRST#
Signal
Power Plane
I/O
During
PCIRST#/
After
PCIRST#/
S1
S3
S4/S5
AC_RST#
Resume3
Output
Low
Low
Cold
Reset
bit (Hi)
Low
Low
AC_SDOUT
Core1
Output
Low
Running
Low
Low
Low
AC_SYNC
Core1
Output
Low
Running
Low
Low
Low
BIT_CLK
Core
Input
Driven by
codec
Running
Low2,4
Low2,4
Low2,4
SDIN[1:0]
Resume
Input
Driven by
codec
Running
Low2,4
Low2,4
Low2,4
NOTE:
1. ICH2 core well outputs are used as strapping options for the ICH2. They are sampled during system reset.
These signals may have weak pull-ups/put-downs. The ICH2 outputs are driven to the appropriate level prior
to AC_RST# being deasserted, preventing a codec from entering test mode. Straps are tied to the core well
to prevent leakage during a suspend state.
2. The pull-down resistors on these signals are only enabled when the AC-Link Shut Off bit in the AC’97 Global
Control Register is set to 1. All other times, the pull-down resistor is disabled.
3. AC_RST# will be held low during S3–S5. It cannot be programmed high during a suspend state.
4. BIT_CLK and SDIN[1:0] are driven low by the codecs during normal states. If the codec is powered during
suspend states, it holds these signals low. However, if the codec is not present or not powered in suspend,
external pull-down resistors are required.
The transition of AC_RST# to the deasserted state only occurs under driver control. In the S1sleep
state, the state of the AC_RST# signal is controlled by the AC’97 Cold Reset# bit (bit 1) in the
Global Control register. AC_RST# will be asserted (low) by the ICH2 under the following
conditions:
• RSMRST# (system reset, including the a reset of the resume well and PCIRST#)
• Mechanical power up (causes PCIRST#)
• Write to CF9h hard reset (causes PCIRST#)
• Transition to S3/S4/S5 sleep states (causes PCIRST#)
• Write to AC’97 Cold Reset# bit in the Global Control Register.
Hardware will never deassert AC_RST# (i.e., never deasserts the Cold Reset# bit) automatically.
Only software can deassert the Cold Reset# bit and, hence, the AC_RST# signal. This bit, while it
resides in the core well, remains cleared upon return from S3/S4/S5 sleep states. The AC_RST#
pin remains actively driven from the resume well as indicated.
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Functional Description
5.19
Firmware Hub Interface
This section describes the memory cycle type to be used on the Firmware Hub (FWH) interface.
Below are the various types of cycles that are supported by the product.
Cycle Type
5.19.1
Comment
FWH Memory Read
New chip select and addressing are used.
FWH Memory Write
New chip select and addressing are used.
Field Definitions
START
This one clock field indicates the start of a cycle. It is valid on the last clock that LFRAME# is
sampled low. The two start fields that are used for the cycle are shown in the table below. If the
start field that is sampled is not one of these values, then the cycle attempted is not a FWH Memory
Cycle. It may be a valid memory cycle that the FWH component may wish to decode (i.e., it may
be of the LPC memory cycle variety).
AD[3:0]
Indication
1101
FWH Memory Read
1110
FWH Memory Write
IDSEL (Device Select)
This one clock field is used to indicate which FWH component is being selected. The four bits
transmitted over AD[3:0] during this clock are compared with values strapped onto pins on the
FWH component. If there is a match, the FWH component will continue to decode the cycle to
determine which bytes are requested on a read or which bytes to update on a write. If there is not a
match, the FWH component may discard the rest of the cycle and go into a standby power state.
MSIZE (Memory Size)
The value ‘0000b’ is sent in this field. A value of ‘0000b’ corresponds to a single byte transfer.
Other encodings of this field are reserved for future use.
MADDR (Memory Address)
This is a 7-clock field that provides a 28 bit memory address. This allows for up to 256 MB per
memory device, for a total of a 4 GB addressable space. The address is transferred with the most
significant nibble first.
SYNC
The SYNC protocol is the same as described in the LPC specification.
TAR
The TAR fields are the same as described in the LPC specification. Refer to this specification for
further details.
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82801BA ICH2 and 82801BAM ICH2-M Datasheet
Functional Description
5.19.2
Protocol
The FWH Memory cycles use a sequence of events that start with a START field (LFRAME#
active with appropriate AD[3:0] combination) and end with the data transfer. The following
sections describe the cycles in detail.
Preamble
The initiation of the FWH Memory cycles is shown in Figure 5-25. The FWH Memory transaction
begins with LFRAME# going low and a START field driven on AD[3:0]. For FWH Memory Read
cycles, the START field must be ‘1101b’; for FWH Memory Write cycles, the START field must be
‘1110b’. Following the START field is the IDSEL field. This field acts like a chip select in that it
indicates which device should respond to the current transaction. The next seven clocks are the 28bit address from where to begin reading in the selected device. Next, an MSIZE value of 0
indicates the master is requesting a single byte.
Figure 5-25. FWH Memory Cycle Preamble
T1
T2
T3
START
IDSEL
T4
T5
T6
T7
T8
T9
T10
T11
CLK
FRAME#
AD[3:0]
28 Bit Address
MSIZE
Read Cycle (Single Byte)
For read cycles, after the pre-amble (described above), the host drives a TAR field to give
ownership of the bus to the FWH. After the second clock of the TAR phase, the target device
assumes the bus and begins driving SYNC values. When it is ready, it drives the low nibble, then
the high nibble of data, followed by a TAR to give control back to the host.
Figure 5-26. Single Byte Read
T1
T2
T3
T4
T5
T6
T7
T8
T9
T10
T11
T12
T13
CLK
FRAME#
AD[3:0]
Preamble
TAR
SYNC
D_Lo
D_Hi
TAR
f h
d
Figure 5-26 shows a device that requires 3 SYNC clocks to access data. Since the access time can
begin once the address phase has been completed, the two clocks of the TAR phase can be
considered as part of the access time of the part. For example, a device with a 120 ns access time
could assert ‘0101b’ for clocks 1 and 2 of the SYNC phase and ‘0000b’ for the last clock of the
SYNC phase. This would be equivalent to 5 clocks worth of access time if the device started that
access at the conclusion of the Preamble phase. Once SYNC is achieved, the device returns the
data in two clocks and gives ownership of the bus back to the host with a TAR phase.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
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Functional Description
Write Cycles (Single Byte)
All devices that support FWH memory write cycles must support single byte writes. FWH memory
write cycles use the same preamble as FWH memory read cycles that is described above.
Figure 5-27. Single Byte Write
T1
T2
T3
T4
T5
D_Lo
D_Hi
T6
T7
T8
T9
T10
T11
CLK
FRAME#
AD[3:0]
Preamble
TAR
SYNC
TAR
Figure 5-27 shows an FWH memory write cycle where a single byte is transferred. The master
asserts an MSIZE value of 0. After the address has been transferred, the 2 clock data phase begins.
Following the data phase, bus ownership is transferred to the FWH component with a TAR cycle.
Following the TAR phase, the device must assert a SYNC value of ‘0000b’ (ready) or ‘1010b’
(error) indicating the data has been received. Bus ownership is then given back to the master with
another TAR phase.
FWH Memory Writes only allow one clock for the SYNC phase. The TAR + SYNC + TAR phases
at the end of FWH memory write cycles must be exactly 5 clocks.
Error Reporting
There is no error reporting over the FWH interface for FWH memory cycles. If an error occurs
(e.g., an address out of range or an unsupported memory size), the cycle will continue from the host
unabated. This is because these errors are the result of illegal programming, and there is no
efficient error reporting method that can be done to counter the programming error.
Therefore, the FWH component must not report the error conditions over the FWH interface. It
must only report wait states and the ‘ready’ condition. It may choose to log the error internally to
be debugged, but it must not signal an error through the FWH interface itself
5-156
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Register and Memory Mapping
Register and Memory Mapping
6
The ICH2 contains registers that are located in the processor’s I/O space and memory space and
sets of PCI configuration registers that are located in PCI configuration space. This chapter
describes the ICH2 I/O and memory maps at the register-set level. Register access is also
described. Register-level address maps and Individual register bit descriptions are provided in the
following chapters. The following notations and definitions are used in the register/instruction
description chapters.
6.1
RO
Read Only. In some cases, If a register is read only, writes to this register location have
no effect. However, in other cases, two separate registers are located at the same
location where a read accesses one of the registers and a write accesses the other
register. See the I/O and memory map tables for details.
WO
Write Only. In some cases, If a register is write only, reads to this register location have
no effect. However, in other cases, two separate registers are located at the same
location where a read accesses one of the registers and a write accesses the other
register. See the I/O and memory map tables for details.
R/W
Read/Write. A register with this attribute can be read and written.
R/WC
Read/Write Clear. A register bit with this attribute can be read and written. However,
a write of 1 clears (sets to 0) the corresponding bit and a write of 0 has no effect.
Default
When ICH2 is reset, it sets its registers to predetermined default states. The default
state represents the minimum functionality feature set required to successfully bring
up the system. Hence, it does not represent the optimal system configuration. It is the
responsibility of the system initialization software to determine configuration,
operating parameters, and optional system features that are applicable, and to program
the ICH2 registers accordingly.
Bold
Register bits that are highlighted in bold text indicate that the bit is implemented in the
ICH2. Register bits that are not implemented or are rewired will remain in plain text.
PCI Devices and Functions
The ICH2 incorporates a variety of PCI functions as shown in Table 6-1. These functions are
divided into three logical devices (B0:D30, B0:D31 and B1:D8). D30 is the hub interface-to-PCI
bridge, D31 contains the PCI-to-LPC Bridge, IDE Controller, USB Controllers, SMBus Controller
and the AC’97 Audio and Model Controller functions. B1:D8 is the integrated LAN Controller.
Note:
From a software perspective, the integrated LAN Controller resides on the ICH2’s external PCI bus
(See Section 5.1.2). This is typically Bus 1, but may be assigned a different number depending on
system configuration.
If a particular system platform does not want to support any one of Device 31’s Functions 1–6, they
can individually be disabled. The integrated LAN Controller will be disabled if no Platform LAN
Connect component is detected (See Section 5.2, “LAN Controller (B1:D8:F0)” on page 5-6).
When a function is disabled, it does not appear at all to the software. A disabled function will not
respond to any register reads or writes. This is intended to prevent software from thinking that a
function is present (and reporting it to the end-user).
82801BA ICH2 and 82801BAM ICH2-M Datasheet
6-1
Register and Memory Mapping
Table 6-1. PCI Devices and Functions
Bus:Device:Function
Function Description
Bus 0:Device 30:Function 0
Hub Interface to PCI Bridge
Bus 0:Device 31:Function 0
PCI to LPC Bridge1
Bus 0:Device 31:Function 1
IDE Controller
Bus 0:Device 31:Function 2
USB Controller #1
Bus 0:Device 31:Function 3
SMBus Controller
Bus 0:Device 31:Function 4
USB Controller #2
Bus 0:Device 31:Function 5
AC’97 Audio Controller
Bus 0:Device 31:Function 6
AC’97 Modem Controller
Bus 1:Device 8:Function 0
LAN Controller
NOTES:
1. The PCI to LPC bridge contains registers that control LPC, Power Management, System Management,
GPIO, processor interface, RTC, Interrupts, Timers, DMA.
6.2
PCI Configuration Map
Each PCI function on the ICH2 has a set of PCI configuration registers. The register address map
tables for these register sets are included at the beginning of the chapter for the particular function.
Configuration Space registers are accessed through configuration cycles on the PCI bus by the
Host bridge using configuration mechanism #1 detailed in the PCI 2.1 specification.
Some of the PCI registers contain reserved bits. Software must deal correctly with fields that are
reserved. On reads, software must use appropriate masks to extract the defined bits and not rely on
reserved bits being any particular value. On writes, software must ensure that the values of
reserved bit positions are preserved. That is, the values of reserved bit positions must first be read,
merged with the new values for other bit positions and then written back. Note the software does
not need to perform read, merge, write operation for the configuration address register.
In addition to reserved bits within a register, the configuration space contains reserved locations.
Software should not write to reserved PCI configuration locations in the device-specific region
(above address offset 3Fh).
6.3
I/O Map
The I/O map is divided into Fixed and Variable address ranges. Fixed ranges cannot be moved. In
some cases they can be disabled. Variable ranges can be moved and can also be disabled.
6-2
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Register and Memory Mapping
6.3.1
Fixed I/O Address Ranges
Table 6-2 shows the fixed I/O decode ranges from the processor perspective. Note that for each I/O
range, there may be a separate behavior for reads and writes. The hub interface cycles that go to
target ranges that are marked as “Reserved” are not decoded by the ICH2; they are passed to PCI. If
a PCI master targets one of the fixed I/O target ranges, it will be positively decoded by the ICH2 in
Medium speed.
Refer to Table A-1 for a complete list of all fixed I/O registers. Address ranges that are not listed or
marked “Reserved” are NOT decoded by the ICH2 (unless assigned to one of the variable ranges).
Table 6-2. Fixed I/O Ranges Decoded by ICH2
I/O Address
Read Target
00h–08h
DMA Controller
09h–0Eh
0Fh
Write Target
Internal Unit
DMA Controller
DMA
RESERVED
DMA Controller
DMA
DMA Controller
DMA Controller
DMA
10h–18h
DMA Controller
DMA Controller
DMA
19h–1Eh
RESERVED
DMA Controller
DMA
1Fh
DMA Controller
DMA Controller
DMA
20h–21h
Interrupt Controller
Interrupt Controller
Interrupt
24h–25h
Interrupt Controller
Interrupt Controller
Interrupt
28h–29h
Interrupt Controller
Interrupt Controller
Interrupt
2Ch–2Dh
Interrupt Controller
Interrupt Controller
Interrupt
2Eh–2Fh
LPC SIO
LPC SIO
Forwarded to LPC
30h–31h
Interrupt Controller
Interrupt Controller
Interrupt
34h–35h
Interrupt Controller
Interrupt Controller
Interrupt
38h–39h
Interrupt Controller
Interrupt Controller
Interrupt
3Ch–3Dh
Interrupt Controller
Interrupt Controller
Interrupt
40h–42h
Timer/Counter
Timer/Counter
PIT (8254)
43h
RESERVED
Timer/Counter
PIT
4E–4F
LPC SIO
LPC SIO
Forwarded to LPC
50h–52h
Timer/Counter
Timer/Counter
PIT
53h
RESERVED
Timer/Counter
PIT
60h
Microcontroller
Microcontroller
Forwarded to LPC
61h
NMI Controller
NMI Controller
processor I/F
62h
Microcontroller
Microcontroller
Forwarded to LPC
63h
NMI Controller
NMI Controller
processor I/F
64h
Microcontroller
Microcontroller
Forwarded to LPC
65h
NMI Controller
NMI Controller
processor I/F
66h
Microcontroller
Microcontroller
Forwarded to LPC
67h
NMI Controller
NMI Controller
processor I/F
70h
RESERVED5
NMI and RTC Controller
RTC
71h
RTC Controller
RTC Controller
RTC
72h
RTC Controller
NMI and RTC Controller
RTC
73h
RTC Controller
RTC Controller
RTC
74h
RTC Controller
NMI and RTC Controller
RTC
82801BA ICH2 and 82801BAM ICH2-M Datasheet
6-3
Register and Memory Mapping
Table 6-2. Fixed I/O Ranges Decoded by ICH2 (Continued)
I/O Address
Read Target
Write Target
Internal Unit
75h
RTC Controller
RTC Controller
RTC
76h
RTC Controller
NMI and RTC Controller
RTC
77h
RTC Controller
RTC Controller
RTC
80h
DMA Controller
DMA Controller and LPC or PCI
DMA
81h–83h
DMA Controller
DMA Controller
DMA
84h–86h
DMA Controller
DMA Controller and LPC or PCI
DMA
87h
DMA Controller
DMA Controller
DMA
88h
DMA Controller
DMA Controller and LPC or PCI
DMA
89h–8Bh
DMA Controller
DMA Controller
DMA
8Ch–8Eh
DMA Controller
DMA Controller and LPC or PCI
DMA
08Fh
DMA Controller
DMA Controller
DMA
90h–91h
DMA Controller
DMA Controller
DMA
92h
Reset Generator
Reset Generator
processor I/F
93h–9Fh
DMA Controller
DMA Controller
DMA
A0h–A1h
Interrupt Controller
Interrupt Controller
Interrupt
A4h–A5h
Interrupt Controller
Interrupt Controller
Interrupt
A8h–A9h
Interrupt Controller
Interrupt Controller
Interrupt
ACh–ADh
Interrupt Controller
Interrupt Controller
Interrupt
B0h–B1h
Interrupt Controller
Interrupt Controller
Interrupt
B2h–B3h
Power Management
Power Management
Power Management
B4h–B5h
Interrupt Controller
Interrupt Controller
Interrupt
B8h–B9h
Interrupt Controller
Interrupt Controller
Interrupt
BCh–BDh
Interrupt Controller
Interrupt Controller
Interrupt
C0h–D1h
DMA Controller
DMA Controller
DMA
D2h–DDh
RESERVED
DMA Controller
DMA
DEh–DFh
DMA Controller
DMA Controller
DMA
F0h
See Note 3
FERR#/IGNNE# / Interrupt
Controller
processor interface
170h–177h
IDE Controller2
IDE Controller1
Forwarded to IDE
1F0h–1F7h
IDE Controller1
IDE Controller2
Forwarded to IDE
2
1
Forwarded to IDE
Forwarded to IDE
376h
IDE Controller
3F6h
IDE Controller1
IDE Controller2
4D0h–4D1h
Interrupt Controller
Interrupt Controller
Interrupt
CF9h
Reset Generator
Reset Generator
processor interface
IDE Controller
NOTES:
1. Only if IDE Standard I/O space is enabled for Primary Drive. Otherwise, the target is PCI.
2. Only if IDE Standard I/O space is enabled for Secondary Drive. Otherwise, the target is PCI.
3. If POS_DEC_EN bit is enabled, reads from F0h will not be decoded by the ICH2. If POS_DEC_EN is not
enabled, reads from F0h will forward to LPC.
6-4
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Register and Memory Mapping
6.3.2
Variable I/O Decode Ranges
Table 6-3 shows the Variable I/O Decode Ranges. They are set using Base Address Registers
(BARs) or other configuration bits in the various PCI configuration spaces. The PNP software (PCI
or ACPI) can use their configuration mechanisms to set and adjust these values.
When a cycle is detected on the hub interface, the ICH2 positively decodes the cycle. If the
response is on the behalf of an LPC device, ICH2 will forward the cycle to the LPC interface.
Refer to Table A-2 for a complete list of all variable I/O registers.
Warning:
The Variable I/O Ranges should not be set to conflict with the Fixed I/O Ranges. Unpredictable
results if the configuration software allows conflicts to occur. The ICH2 does not perform any
checks for conflicts.
Table 6-3. Variable I/O Decode Ranges
Range Name
Mappable
Size (Bytes)
Target
ACPI
Anywhere in 64 KB I/O Space
64
Power Management
IDE
Anywhere in 64 KB I/O Space
16
IDE Unit
USB #1
Anywhere in 64 KB I/O Space
32
USB Unit 1
SMBus
Anywhere in 64 KB I/O Space
16
SMB Unit
AC’97 Audio Mixer
Anywhere in 64 KB I/O Space
256
AC’97 Unit
AC’97 Bus Master
Anywhere in 64 KB I/O Space
64
AC’97 Unit
AC’97 Modem Mixer
Anywhere in 64 KB I/O Space
256
AC’97 Unit
TCO
96 Bytes above ACPI Base
32
TCO Unit
GPIO
Anywhere in 64 KB I/O Space
64
GPIO Unit
Parallel Port
3 ranges in 64 KB I/O Space
8
LPC Peripheral
Serial Port 1
8 Ranges in 64 KB I/O Space
8
LPC Peripheral
Serial Port 2
8 Ranges in 64 KB I/O Space
8
LPC Peripheral
Floppy Disk Controller
2 Ranges in 64 KB I/O Space
8
LPC Peripheral
MIDI
4 Ranges in 64 KB I/O Space
2
LPC Peripheral
MSS
4 Ranges in 64 KB I/O Space
8
LPC Peripheral
SoundBlaster
2 Ranges in 64 KB I/O Space
32
LPC Peripheral
LAN
Anywhere in 64 KB I/O Space
64
LAN Unit
USB #2
Anywhere in 64 KB I/O Space
32
USB Unit 2
LPC Generic 1
Anywhere in 64 KB I/O Space
128
LPC Peripheral
LPC Generic 2
Anywhere in 64 KB I/O Space
16
LPC Peripheral
Monitors 4:7
Anywhere in 64 KB I/O Space
16
LPC Peripheral or Trap on
PCI
82801BA ICH2 and 82801BAM ICH2-M Datasheet
6-5
Register and Memory Mapping
6.4
Memory Map
Table 6-4 shows (from the processor perspective) the memory ranges that the ICH2 decodes.
Cycles that arrive from the MCH will first be driven out on PCI. The ICH2 may then claim the
cycle for it to be forwarded to LPC or claimed by the internal APIC. If subtractive decode is
enabled, the cycle can be forwarded to LPC.
PCI cycles generated by an external PCI master will be positively decoded unless it falls in the
PCI-PCI bridge forwarding range (those addresses are reserved for PCI peer-to-peer traffic). If the
cycle is not in the I/O APIC or LPC ranges, it will be forwarded up the hub interface to the Host
Controller.
Table 6-4. Memory Decode Ranges from Processor Perspective
Memory Range
Target
Dependency/Comments
0000 0000h–000D FFFFh
0010 0000–TOM (Top of
Memory)
Main Memory
000E 0000h–000F FFFFh
FWH
FEC0 0000h–FEC0 0100h
I/O APIC inside ICH2
FFC0 0000h–FFC7 FFFFh
FF80 0000h–FF87 FFFFh
FFC8 0000h–FFCF FFFFh
FF88 0000h–FF8F FFFFh
FFD0 0000h–FFD7 FFFFh
FF90 0000h–FF97 FFFFh
FFD8 0000h–FFDF FFFFh
FF98 0000h–FF9F FFFFh
FFE0 000h–FFE7 FFFFh
FFA0 0000h–FFA7 FFFFh
FFE8 0000h–FFEF FFFFh
FFA8 0000h–FFAF FFFFh
FFF0 0000h–FFF7 FFFFh
FFB0 0000h–FFB7 FFFFh
FFF8 0000h–FFFF FFFFh
FFB8 0000h–FFBF FFFFh
FF70 0000h–FF7F FFFFh
FF30 0000h–FF3F FFFFh
FF60 0000h–FF6F FFFFh
FF20 0000h–FF2F FFFFh
FF50 0000h–FF5F FFFFh
FF10 0000h–FF1F FFFFh
FF40 0000h–FF4F FFFFh
FF00 0000h–FF0F FFFFh
6-6
TOM registers in Host Controller
Bit 7 in FWH Decode Enable Register is set
FWH
Bit 0 in FWH Decode Enable Register
FWH
Bit 1 in FWH Decode Enable Register
FWH
Bit 2 in FWH Decode Enable Register is set
FWH
Bit 3 in FWH Decode Enable Register is set
FWH
Bit 4 in FWH Decode Enable Register is set
FWH
Bit 5 in FWH Decode Enable Register is set
FWH
Bit 6 in FWH Decode Enable Register is set.
FWH
Always enabled.
The top two 64 KB blocks of this range can be
swapped as described in Section 6.4.1.
FWH
Bit 3 in FWH Decode Enable 2 Register is set
FWH
Bit 2 in FWH Decode Enable 2 Register is set
FWH
Bit 1 in FWH Decode Enable 2 Register is set
FWH
Bit 0 in FWH Decode Enable 2 Register is set
Anywhere in 4 GB range
D110 LAN Controller
All other
PCI
Enable via BAR in Device 29:Function 0 (D110 LAN
Controller)
None
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Register and Memory Mapping
6.4.1
Boot-Block Update Scheme
The ICH2 supports a “Top-Block Swap” mode that has the ICH2 swap the top block in the FWH
(the boot block) with another location. This allows for safe update of the Boot Block (even if a
power failure occurs). When the “top-swap” enable bit is set, the ICH2 will invert A16 for cycles
targeting FWH BIOS space. When this bit is 0, the ICH2 will not invert A16. This bit is
automatically set to 0 by RTCRST#, but not by PCIRST#.
The scheme is based on the concept that the top block is reserved as the “boot” block, and the block
immediately below the top block is reserved for doing boot-block updates.
The algorithm is:
1. Software copies the top block to the block immediately below the top
2. Software checks that the copied block is correct. This could be done by performing a
checksum calculation.
3. Software sets the “Top-Block Swap” bit. This inverts A16 for cycles going to the FWH.
Processor access to FFFF_0000 through FFFF_FFFF are directed to FFFF_0000 through
FFFE_FFFF in the FWH. Processor accesses to FFFE_0000 through FFFE_FFFF are directed
to FFFF_0000 through FFFF_FFFF.
4. Software erases the top block
5. Software writes the new top block
6. Software checks the new top block
7. Software clears the top-block swap bit
If a power failure occurs at any point after step 3, the system will be able to boot from the copy of
the boot block that is stored in the block below the top. This is because the top-swap bit is backed
in the RTC well.
Note:
The Top-Block Swap mode may be forced by an external strapping option (See Section 2.20.1).
When Top-Block Swap mode is forced in this manner, the Top-Swap bit cannot be cleared by
software. A re-boot with the strap removed will be required to exit a forced Top-Block Swap mode.
Note:
top-Block Swap mode only affects accesses to the FWH BIOS space, not feature space.
Note:
The Top Block Swap mode has no effect on accesses below FFFE_0000.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
6-7
Register and Memory Mapping
This page is intentionally left blank.
6-8
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LAN Controller Registers (B1:D8:F0)
7
LAN Controller Registers (B1:D8:F0)
The ICH2 integrated LAN Controller appears to reside at PCI Device 8, Function 0 on the
secondary side of the ICH2’s virtual PCI-to-PCI Bridge (See Table 5.1.2). This is typically Bus 1,
but may be assigned a different number depending upon system configuration. The LAN
Controller acts as both a master and a slave on the PCI bus. As a master, the LAN Controller
interacts with the system main memory to access data for transmission or deposit received data. As
a slave, some of the LAN Controller’s control structures are accessed by the host processor to read
or write information to the on-chip registers. The processor also provides the LAN Controller with
the necessary commands and pointers that allow it to process receive and transmit data.
7.1
PCI Configuration Registers (B1:D8:F0)
Note:
Registers that are not shown should be treated as Reserved (See Section 6.2 for details).
.
Table 7-1. PCI Configuration Map (LAN Controller—B1:D8:F0)
Offset
Mnemonic
00–01h
VID
Register Name/Function
Vendor ID
Default
Type
8086h
RO
02–03h
DID
Device ID
2449h
RO
04–05h
PCICMD
PCI Device Command Register
0000h
R/W
06–07h
PCISTS
PCI Device Status Register
0290h
R/W
08h
REVID
Revision ID
Note 1
RO
0Ah
SCC
Sub Class Code
00h
RO
0Bh
BCC
Base Class Code
02h
RO
0Dh
PMLT
PCI Master Latency Timer
00h
R/W
0Eh
HEADTYP
Header Type
00h
RO
10–13h
CSR_MEM_BASE
CSR Memory-mapped Base Address
0008h
R/W
14–17h
CSR_IO_BASE
CSR I/O-mapped Base Address
0001h
R/W
2C–2Dh
SVID
Subsystem Vendor ID
0000h
RO
2E–2Fh
SID
Subsystem ID
0000h
RO
34h
CAP_PTR
Capabilities Pointer
DCh
RO
3Ch
INT_LN
Interrupt Line
00h
R/W
3Dh
INT_PN
Interrupt Pin
01h
RO
3Eh
MIN_GNT
Minimum Grant
08h
RO
3Fh
MAX_LAT
DCh
CAP_ID
DDh
NXT_PTR
DE–DFh
PM_CAP
E0–E1h
PMCSR
E3h
DATA
Maximum Latency
38h
RO
Capability ID
01h
RO
00h
RO
Next Item Pointer
Power Management Capabilities
FE21h (ICH2)
7E21 (ICH2-M)
Power Management Control/Status
Data
RO
0000h
R/W
00h
RO
NOTE: Refer to the Specification Update for the value of the Revision ID Register.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
7-1
LAN Controller Registers (B1:D8:F0)
7.1.1
VID—Vendor ID Register (LAN Controller—B1:D8:F0)
Offset Address:
Default Value:
00–01h
8086h
Bit
15:0
7.1.2
RO
16 bits
Description
Vendor Identification Number. This is a 16-bit value assigned to Intel.
DID—Device ID Register (LAN Controller—B1:D8:F0)
Offset Address:
Default Value:
02–03h
2449h
Bit
15:0
7.1.3
Attribute:
Size:
Attribute:
Size:
RO
16 bits
Description
Device Identification Number. This is a 16 bit value assigned to the ICH2 integrated LAN
Controller.
PCICMD—PCI Command Register
(LAN Controller—B1:D8:F0)
Offset Address:
Default Value:
04–05h
0000h
Bit
15:10
9
Attribute:
Size:
RO, R/W
16 bits
Description
Reserved.
Fast Back to Back Enable (FBE)—RO. Hardwired to 0. The integrated LAN Controller will not run
fast back-to-back PCI cycles.
8
SERR# Enable (SERR_EN)—R/W.
1 = Enable. Allow SERR# to be generated.
7
Wait Cycle Control (WCC)—RO. Hardwired to 0. Not implemented.
6
Parity Error Response (PER)—R/W
1 = The integrated LAN Controller will take normal action when a PCI parity error is detected. The
generation of parity is also enabled on the hub interface.
0 = Disable.
0 = The LAN Controller will ignore PCI parity errors.
5
VGA Palette Snoop (VPS)—RO. Hardwired to 0. Not Implemented.
Memory Write and Invalidate Enable (MWIE)—R/W.
4
0 = Disable. The LAN Controller will not use the Memory Write and Invalidate command.
1 = Enable.
3
Special Cycle Enable (SCE)—RO. Hardwired to 0. The LAN Controller ignores special cycles.
2
Bus Master Enable (BME)—R/W.
1 = Enable. The ICH2’s integrated may function as a PCI bus master.
0 = Disable.
1
Memory Space Enable (MSE)—R/W.
1 = Enable. The ICH2’s integrated LAN Controller will respond to the memory space accesses.
0 = Disable.
0
I/O Space Enable (IOE)—R/W.
1 = Enable. The ICH2’s integrated LAN Controller will respond to the I/O space accesses.
0 = Disable.
7-2
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LAN Controller Registers (B1:D8:F0)
7.1.4
PCISTS—PCI Status Register (LAN Controller—B1:D8:F0)
Offset Address:
Default Value:
06–07h
0290h
Attribute:
Size:
Bit
15
RO, R/WC
16 bits
Description
Detected Parity Error (DPE)—R/WC.
1 = The ICH2’s integrated LAN Controller has detected a parity error on the PCI bus (will be set
even if Parity Error Response is disabled in the PCI Command register).
0 = This bit is cleared by writing a 1 to the bit location.
14
Signaled System Error (SSE)—R/WC.
1 = The ICH2’s integrated LAN Controller has asserted SERR#. (SERR# can be routed to cause
NMI, SMI# or interrupt.
0 = This bit is cleared by writing a 1 to the bit location.
13
Master Abort Status (RMA)—R/WC.
1 = The ICH2’s integrated LAN Controller (as a PCI master) has generated a master abort.
0 = This bit is cleared by writing a 1 to the bit location.
12
Received Target Abort (RTA)—R/WC.
1 = The ICH2’s integrated LAN Controller (as a PCI master) has received a target abort.
0 = This bit is cleared by writing a 1 to the bit location.
11
10:9
8
Signaled Target Abort (STA)—RO. Hardwired to 0. The device will never signal Target Abort.
DEVSEL# Timing Status (DEV_STS)—RO.
01h = Medium timing.
Data Parity Error Detected (DPED)—R/WC.
1 = All of the following three conditions have been met:
1.The LAN Controller is acting as bus master
2.The LAN Controller has asserted PERR# (for reads) or detected PERR# asserted (for
writes)
3.The Parity Error Response bit in the LAN Controller’s PCI Command Register is set.
0 = This bit is cleared by writing a 1 to the bit location.
7
6
User Definable Features (UDF)—RO. Hardwired to 0. Not implemented.
5
66 MHz Capable (66MHZ_CAP)—RO. Hardwired to 0. The device does not support 66MHz PCI.
4
3:0
7.1.5
Fast Back to Back (FB2B)—RO. Hardwired to 1. The device can accept fast back-to-back
transactions.
Capabilities List (CAP_LIST)—RO.
1 = The EEPROM indicates that the integrated LAN controller supports PCI Power Management.
0 = The EEPROM indicates that the integrated LAN controller does not support PCI Power
Management.
Reserved.
REVID—Revision ID Register (LAN Controller—B1:D8:F0)
Offset Address:
Default Value:
08h
00h
Attribute:
Size:
RO
8 bits
Bit
Description
7:0
Revision Identification Number. 8-bit value that indicates the revision number for the integrated
LAN Controller. The three least significant bits in this register may be overridden by the ID and REV
ID fields in the EEPROM.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
7-3
LAN Controller Registers (B1:D8:F0)
7.1.6
SCC—Sub-Class Code Register
(LAN Controller—B1:D8:F0)
Offset Address:
Default Value:
0Ah
00h
Bit
7:0
7.1.7
RO
8 bits
Description
Sub-Class Code. 8-bit value that specifies the sub-class of the device as an Ethernet controller.
BCC—Base-Class Code Register
(LAN Controller—B1:D8:F0)
Offset Address:
Default Value:
0Bh
02h
Bit
7:0
7.1.8
Attribute:
Size:
Attribute:
Size:
RO
8 bits
Description
Base Class Code. 8-bit value that specifies the base class of the device as a network controller.
CLS—Cache Line Size Register (LAN Controller—B1:D8:F0)
Offset Address:
Default Value:
0Ch
00h
Bit
7:5
Attribute:
Size:
RW
8 bits
Description
Reserved.
Cache Line Size (CLS)—RW.
00 = Memory Write and Invalidate (MWI) command will not be used by the integrated LAN Controller.
4:3
01 = MWI command will be used with Cache Line Size set to 8 DWords (only set if a value of 08h is
written to this register).
10 = MWI command will be used with Cache Line Size set to 16 DWords (only set if a value of 10h is
written to this register).
11 = Invalid. MWI command will not be used.
2:0
7.1.9
Reserved.
PMLT—PCI Master Latency Timer Register
(LAN Controller—B1:D8:F0)
Offset Address:
Default Value:
Bit
7-4
0Dh
00h
Attribute:
Size:
RW
8 bits
Description
7:3
Master Latency Timer Count (MLTC)—RW. Defines the number of PCI clock cycles that the
integrated LAN Controller may own the bus while acting as bus master.
2:0
Reserved.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LAN Controller Registers (B1:D8:F0)
7.1.10
HEADTYP—Header Type Register
(LAN Controller—B1:D8:F0)
Offset Address:
Default Value:
0Eh
00h
Bit
7
6:0
7.1.11
Multi-function Device—RO. Hardwired to 0 to indicate a single function device.
Header Type—RO. 7-bit field identifies the header layout of the configuration space as an Ethernet
controller.
CSR_MEM_BASE CSR—Memory-Mapped Base Address
Register (LAN Controller—B1:D8:F0)
Attribute:
Size:
R/W, RO
32 bits
Bit
Description
31:12
Base Address—R/W. Upper 20 bits of the base address provides 4 KB of memory-mapped space for
the LAN Controller’s Control/Status Registers.
3
2:1
0
Reserved.
Pre-fetchable—RO. Hardwired to 0 to indicate that this is not a pre-fetchable memory-mapped
address range.
Type—RO. Hardwired to 00b to indicate the memory-mapped address range may be located
anywhere in 32-bit address space.
Memory-Space Indicator—RO. Hardwired to 0 to indicate that this base address maps to memory
space.
CSR_IO_BASE—CSR I/O-Mapped Base Address Register
(LAN Controller—B1:D8:F0)
Offset Address:
Default Value:
Note:
10–13h
0000 0008h
The ICH2’s integrated LAN Controller requires one BAR for memory mapping. Software
determines which BAR (memory or I/O) is used to access the Lan Controller’s CSR registers.
11:4
7.1.12
RO
8 bits
Description
Offset Address:
Default Value:
Note:
Attribute:
Size:
14–17h
0000 0001h
Attribute:
Size:
R/W
32 bits
The ICH2’s integrated LAN Controller requires one BAR for memory mapping. Software
determines which BAR (memory or I/O) is used to access the Lan Controller’s CSR registers.
Bit
Description
31:16
Reserved.
15:6
Base Address—R/W. Provides 64 bytes of I/O-mapped address space for the LAN Controller’s
Control/Status Registers.
5:1
Reserved.
0
I/O Space Indicator—RO. Hardwired to 1 to indicate that this base address maps to I/O space.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
7-5
LAN Controller Registers (B1:D8:F0)
7.1.13
SVID—Subsystem Vendor ID (LAN Controller—B1:D8:F0)
Offset Address:
Default Value:
2C–2D
0000h
Attribute:
Size:
Bit
15:0
7.1.14
Description
Subsystem Vendor ID—RO.
SID—Subsystem ID (LAN Controller—B1:D8:F0)
Offset Address:
Default Value:
2E–2Fh
0000h
Attribute:
Size:
Bit
15:0
Note:
RO
16 bits
RO
16 bits
Description
Subsystem ID—RO.
The ICH2’s integrated LAN Controller provides support for configureable Subsystem ID and
Subsystem Vendor ID fields. After reset, the LAN Controller automatically reads addresses Ah
through Ch of the EEPROM. The LAN Controller checks bits 15:13 in the EEPROM word Ah, and
functions according to Table 7-2.
Table 7-2. Configuration of Subsystem ID and Subsystem Vendor ID via EEPROM
Bits 15:14
Bit 13
Device ID
Vendor ID
Revision ID
Subsystem ID
Subsystem
Vendor ID
11b, 10b,
00b
X
2449h
8086h
00h
0000h
0000h
01b
0b
2449h
8086h
00h
Word Bh
Word Ch
Word Ch
Word Ah,
bits 10:8
Word Bh
Word Ch
01b
7.1.15
1b
CAP_PTR—Capabilities Pointer
(LAN Controller—B1:D8:F0)
Offset Address:
Default Value:
7-6
Word Bh
34h
DCh
Attribute:
Size:
RO
8 bits
Bit
Description
7:0
Capabilities Pointer (CAP_PTR)—RO. Hardwired to DCh to indicate the offset within configuration
space for the location of the Power Management registers.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LAN Controller Registers (B1:D8:F0)
7.1.16
INT_LN—Interrupt Line Register
(LAN Controller—B1:D8:F0)
Offset Address:
Default Value:
3Ch
00h
Bit
7:0
7.1.17
Interrupt Line (INT_LN)—R/W. Identifies the system interrupt line to which the LAN Controller’s
PCI interrupt request pin (as defined in the Interrupt Pin Register) is routed.
INT_PN—Interrupt Pin Register
(LAN Controller—B1:D8:F0)
3Dh
01h
Bit
7:0
Attribute:
Size:
RO
8 bits
Description
Interrupt Pin (INT_PN)—RO. Hardwired to 01h to indicate that the LAN Controller’s interrupt
request is connected to PIRQA#. However, in the ICH2 implementation, when the LAN Controller
interrupt is generated PIRQ[E]# will go active, not PIRQ[A]#.
MIN_GNT—Minimum Grant Register
(LAN Controller—B1:D8:F0)
Offset Address:
Default Value:
3Eh
08h
Bit
7:0
7.1.19
R/W
8 bits
Description
Offset Address:
Default Value:
7.1.18
Attribute:
Size:
Attribute:
Size:
RO
8 bits
Description
Minimum Grant (MIN_GNT)—RO. Indicates the amount of time (in increments of 0.25 µs) that the
LAN Controller needs to retain ownership of the PCI bus when it initiates a transaction.
MAX_LAT—Maximum Latency Register
(LAN Controller—B1:D8:F0)
Offset Address:
Default Value:
3Fh
38h
Bit
7:0
Attribute:
Size:
RO
8 bits
Description
Maximum Latency (MAX_LAT)—RO. Defines how often (in increments of 0.25 µs) the LAN
Controller needs to access the PCI bus.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
7-7
LAN Controller Registers (B1:D8:F0)
7.1.20
CAP_ID—Capability ID Register
(LAN Controller—B1:D8:F0)
Offset Address:
Default Value:
DCh
01h
Bit
7:0
7.1.21
Capability ID (CAP_ID)—RO. Hardwired to 01h to indicate that the ICH2’s integrated LAN
Controller supports PCI Power Management.
NXT_PTR—Next Item Pointer (LAN Controller—B1:D8:F0)
DDh
00h
Bit
7:0
Attribute:
Size:
RO
8 bits
Description
Next Item Pointer (NXT_PTR)—RW. Hardwired to 00b to indicate that power management is the
last item in the Capabilities list.
PM_CAP—Power Management Capabilities
(LAN Controller—B1:D8:F0)
Offset Address:
Default Value:
Bit
15:11
DE–DFh
FE22h
Attribute:
Size:
RO
16 bits
Description
PME Support. Hardwired to 11111b. This 5-bit field indicates the power states in which the LAN
Controller may assert PME#. The LAN Controller supports wake-up in all power states.
10
D2 Support. Hardwired to 1 to indicate that the LAN Controller supports the D2 power state.
9
D1 Support. Hardwired to 1 to indicate that the LAN Controller supports the D1 power state.
8:6
Auxiliary Current. Hardwired to 000b to indicate that the LAN Controller implements the Data
registers. The auxiliary power consumption is the same as the current consumption reported in the
D3 state in the Data register.
5
Device Specific Initialization (DSI). Hardwired to 1 to indicate that special initialization of this
function is required (beyond the standard PCI configuration header) before the generic class device
driver is able to use it. DSI is required for the LAN Controller after D3-to-D0 reset.
4
Reserved
3
PME Clock. Hardwired to 0 to indicate that the LAN Controller does not require a clock to generate
a power management event.
2:0
7-8
RO
8 bits
Description
Offset Address:
Default Value:
7.1.22
Attribute:
Size:
Version. Hardwired to 010b to indicate that the LAN Controller complies with of the PCI Power
Management Specification, Revision 1.1.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LAN Controller Registers (B1:D8:F0)
7.1.23
PMCSR—Power Management Control/Status Register
(LAN Controller—B1:D8:F0)
Offset Address:
Default Value:
E0–E1h
0000h
Bit
Attribute:
Size:
RO, R/W, R/WC
16 bits
Description
PME Status—R/WC.
1 = Set upon occurrence of a wake-up event, independent of the state of the PME Enable bit.
15
0 = Software clears this bit by writing a 1 to the bit location. This also deasserts the PME# signal
and clears the PME status bit in the Power Management Driver Register. When the PME#
signal is enabled, the PME# signal reflects the state of the PME status bit.
14:13
Data Scale—RO. This field indicates the data register scaling factor. It equals 10b for registers zero
through eight and 00b for registers nine through fifteen, as selected by the "Data Select" field.
12:9
Data Select—R/W. This field is used to select which data is reported through the Data register and
Data Scale field.
8
PME Enable—R/W. This bit enables the ICH2’s integrated LAN controller to assert PME#.
1 = Enable PME# assertion when PME Status is set.
0 = The device will not assert PME#.
7:5
4
3:2
Reserved.
Dynamic Data—RO. Hardwired to 0 to indicate that the device does not support the ability to
monitor the power consumption dynamically.
Reserved.
Power State—R/W. This 2-bit field is used to determine the current power state of the integrated
LAN Controller, and to put it into a new power state. The definition of the field values is as follows:
00 = D0
1:0
01 = D1
10 = D2
11 = D3
7.1.24
DATA—Data Register (LAN Controller—B1:D8:F0)
Offset Address:
Default Value:
E3h
00h
Bit
7:0
Note:
Attribute:
Size:
RO
8 bits
Description
Data Value. State dependent power consumption and heat dissipation data.
The data register is an 8-bit read only register that provides a mechanism for the ICH2’s integrated
LAN Controller to report state dependent maximum power consumption and heat dissipation. The
value reported in this register depends on the value written to the Data Select field in the PMCSR
register. The power measurements defined in this register have a dynamic range of 0 to 2.55 W
with 0.01 W resolution, scaled according to the Data Scale field in the PMCSR. The structure of
the Data Register is given in Table 7-3.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
7-9
LAN Controller Registers (B1:D8:F0)
Table 7-3. Data Register Structure
7.2
Data Select
Data Scale
Data Reported
0
2
D0 Power Consumption
1
2
D1 Power Consumption
2
2
D2 Power Consumption
3
2
D3 Power Consumption
4
2
D0 Power Dissipated
5
2
D1 Power Dissipated
6
2
D2 Power Dissipated
7
2
D3 Power Dissipated
8
2
Common Function Power Dissipated
9–15
0
Reserved
LAN Control / Status Registers (CSR)
Table 7-4. ICH2 Integrated LAN Controller CSR Space
Offset
Default
Type
01h–00h
SCB Status Word
0000h
R/WC
03h–02h
SCB Command Word
0000h
R/W
07h–04h
SCB General Pointer
0000 0000h
R/W
0Bh–08h
PORT
0000 0000h
R/W (special)
0Dh–0Ch
Reserved
—
—
0Eh
EEPROM Control Register
00
R/W
0Fh
Reserved
—
—
R/W (special)
13h–10h
MDI Control Register
0000 0000h
17h–14h
Receive DMA Byte Count
0000 0000h
RO
18h
Early Receive Interrupt
00h
R/W
1A–19h
Flow Control Register
0000h
R/W
00h
R/WC
1Bh
PMDR
1Ch
General Control
00
R/W
1Dh
General Status
N/A
RO
—
—
1Eh–3Ch
7-10
Register Name/Function
Reserved
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LAN Controller Registers (B1:D8:F0)
7.2.1
System Control Block Status Word Register
Offset Address:
Default Value:
00–01h
0000h
Attribute:
Size:
R/WC, RO
16 bits
The ICH2’s integrated LAN Controller places the status of its Command and Receive units and
interrupt indications in this register for the processor to read.
Bit
Description
15
Command Unit (CU) Executed (CX)—R/WC.
1 = Interrupt signaled because the CU has completed executing a command with its interrupt bit set.
0 = Software acknowledges the interrupt and clears this bit by writing a 1 to the bit position.
14
Frame Received (FR)—R/WC.
1 = Interrupt signaled because the Receive Unit (RU) has finished receiving a frame
0 = Software acknowledges the interrupt and clears this bit by writing a 1 to the bit position.
13
CU Not Active (CNA)—R/WC.
1 = The Command Unit left the Active state or entered the Idle state. There are 2 distinct states of
the CU. When configured to generate CNA interrupt, the interrupt will be activated when the CU
leaves the Active state and enters either the Idle or the Suspended state. When configured to
generate CI interrupt, an interrupt will be generated only when the CU enters the Idle state.
0 = Software acknowledges the interrupt and clears this bit by writing a 1 to the bit position.
12
Receive Not Ready (RNR)—R/WC.
1 = Interrupt signaled because the Receive Unit left the Ready state. This may be caused by an RU
Abort command, a no resources situation, or set suspend bit due to a filled Receive Frame
Descriptor.
0 = Software acknowledges the interrupt and clears this bit by writing a 1 to the bit position.
11
Management Data Interrupt (MDI)—R/WC.
1 = Set when a Management Data Interface read or write cycle has completed. The management
data interrupt is enabled through the interrupt enable bit (bit 29 in the Management Data
Interface Control register in the CSR).
0 = Software acknowledges the interrupt and clears this bit by writing a 1 to the bit position.
10
Software Interrupt (SWI)—R/WC.
1 = Set when software generates an interrupt.
0 = Software acknowledges the interrupt and clears this bit by writing a 1 to the bit position.
9
Early Receive (ER)—R/WC.
1 = Indicates the occurrence of an Early Receive Interrupt.
0 = Software acknowledges the interrupt and clears this bit by writing a 1 to the bit position.
8
Flow control Pause (FCP)—R/WC.
1 = Indicates Flow Control Pause interrupt.
0 = Software acknowledges the interrupt and clears this bit by writing a 1 to the bit position.
Command Unit Status (CUS)—RO.
7:6
00 = Idle
01 = Suspended
10 = LPQ (Low Priority Queue) active
11 = HPQ (High Priority Queue) active
Receive Unit Status (RUS)—RO.
5:2
1:0
0000 = Idle
0001 = Suspended
0010 = No Resources
0011 = Reserved
0100 = Ready
0101 = Reserved
0110 = Reserved
0111 = Reserved
1000 = Reserved
1001 = Suspended with no more RBDs
1010 = No resources due to no more RBDs
1011 = Reserved
1100 = Ready with no RBDs present
1101 = Reserved
1110 = Reserved
1111 = Reserved
Reserved.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
7-11
LAN Controller Registers (B1:D8:F0)
7.2.2
System Control Block Command Word Register
Offset Address:
Default Value:
02–03h
0000h
Attribute:
Size:
R/W
16 bits
The processor places commands for the Command and Receive units in this register. Interrupts are
also acknowledged in this register.
Bit
Description
CX Mask—R/W.
15
0 = Interrupt not masked.
1 = Disable the generation of a CX interrupt.
FR Mask—R/W.
14
0 = Interrupt not masked.
1 = Disable the generation of an FR interrupt.
CNA Mask—R/W.
13
0 = Interrupt not masked.
1 = Disable the generation of a CNA interrupt.
RNR Mask—R/W.
12
0 = Interrupt not masked.
1 = Disable the generation of an RNR interrupt.
ER Mask—R/W.
11
0 = Interrupt not masked.
1 = Disable the generation of an ER interrupt.
FCP Mask—R/W.
10
0 = Interrupt not masked.
1 = Disable the generation of an FCP interrupt.
Software Generated Interrupt (SI)—WO.
9
8
7-12
0 = No Effect.
1 = Setting this bit causes the LAN Controller to generate an interrupt.
Interrupt Mask (IM)—R/W. This bit enables or disables the LAN Controller’s assertion of the INTA#
signal. This bit has higher precedence that the Specific Interrupt Mask bits and the SI bit.
0 = Enable the assertion of INTA#.
1 = Disable the assertion of INTA#.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LAN Controller Registers (B1:D8:F0)
Bit
Description
Command Unit Command (CUC). Valid values are listed below. All other values are Reserved.
0000 = NOP: Does not affect the current state of the unit.
0001 = CU Start: Start execution of the first command on the CBL. A pointer to the first CB of the
CBL should be placed in the SCB General Pointer before issuing this command. The CU
Start command should only be issued when the CU is in the Idle or Suspended states
(never when the CU is in the active state), and all of the previously issued Command
Blocks have been processed and completed by the CU. Sometimes it is only possible to
determine that all Command Blocks are completed by checking that the Complete bit is set
in all previously issued Command Blocks.
0010 = CU Resume: Resume operation of the Command unit by executing the next command.
This command will be ignored if the CU is idle.
0011 = CU HPQ Start: Start execution of the first command on the high priority CBL. A pointer to
the first CB of the HPQ CBL should be placed in the SCB General POinter before issuing
this command.
7:4
0100 = Load Dump Counters Address: Tells the device where to write dump data when using the
Dump Statistical Counters or Dump and Reset Statistical Counters commands. This
command must be executed at least once before any usage of the Dump Statistical
Counters or Dump and Reset Statistical Counters commands. The address of the dump
area must be placed in the General Pointer register.
0101 = Dump Statistical Counters: Tells the device to dump its statistical counters to the area
designated by the Load Dump Counters Address command.
0110 = Load CU Base: The device’s internal CU Base Register is loaded with the value in the
CSB General Pointer.
0111 = Dump and Reset Statistical Counters: Tells the device to dump its statistical counters to
the area designated by the Load Dump Counters Address command, and then to clear
these counters.
1010 = CU Static Resume: Resume operation of the Command unit by executing the next
command. This command will be ignored if the CU is idle. This command should be used
only when the CU is in the Suspended state and has no pending CU Resume commands.
1011 = CU HPQ Resume: Resume execution of the first command on the HPQ CBL. this
command will be ignored if the HPQ was never started.
3
Reserved.
Receive Unit Command (RUC). Valid values are:
000 = NOP: Does not affect the current state of the unit.
001 = RU Start: Enables the receive unit. The pointer to the RFA must be placed in the SCB
General POinter before using this command. The device pre-fetches the first RFD and the
first RBD (if in flexible mode) in preparation to receive incoming frames that pass its address
filtering.
010 = RU Resume: Resume frame reception (only when in suspended state).
011 = RCV DMA Redirect: Resume the RCV DMA when configured to "Direct DMA Mode." The
buffers are indicated by an RBD chain which is pointed to by an offset stored in the General
Pointer Register (this offset will be added to the RU Base).
2:0
100 = RU Abort: Abort RU receive operation immediately.
101 = Load Header Data Size (HDS): This value defines the size of the Header portion of the RFDs
or Receive buffers. The HDS value is defined by the lower 14 bits of the SCB General Pointer,
so bits 31:15 should always be set to zeros when using this command. Once a Load HDS
command is issued, the device expects only to find Header RFDs, or be used in "RCV Direct
DMA mode" until it is reset. Note that the value of HDS should be an even, non-zero number.
110 = Load RU Base: The device’s internal RU Base Register is loaded with the value in the SCB
General Pointer.
111 = RBD Resume: Resume frame reception into the RFA. This command should only be used
when the RU is already in the "No Resources due to no RBDs" state or the "Suspended with
no more RBDs" state.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
7-13
LAN Controller Registers (B1:D8:F0)
7.2.3
System Control Block General Pointer Register
Offset Address:
Default Value:
04–07h
0000 0000h
Bit
15:0
7.2.4
Attribute:
Size:
R/W
32 bits
Description
SCB General Pointer. The SCB General Pointer register is programmed by software to point to
various data structures in main memory depending on the current SCB Command word.
PORT Register
Offset Address:
Default Value:
08–0Bh
0000 0000h
Attribute:
Size:
R/W (special)
32 bits
The PORT interface allows the processor to reset the ICH2’s internal LAN Controller or perform
an internal self test. The PORT DWord may be written as a 32-bit entity, two 16-bit entities, or four
8-bit entities. The LAN Controller will only accept the command after the high byte (offset 0Bh) is
written; therefore, the high byte must be written last.
Bit
Description
31:4
Pointer Field. A 16-byte aligned address must be written to this field when issuing a Self-Test
command to the PORT interface.The results of the Self Test will be written to the address specified
by this field.
PORT Function Selection. Valid values are listed below. All other values are Reserved.
0000 = PORT Software Reset: Completely resets the LAN Controller (all CSR and PCI registers).
This command should not be used when the device is active. If a PORT Software Reset is
desired, software should do a Selective Reset (described below), wait for the PORT
register to be cleared (completion of the Selective Reset) and then issue the PORT
Software Reset command. Software should wait approximately 10 µs after issuing this
command before attempting to access the LAN Controller’s registers again.
3:0
0001 = Self Test: The Self-Test begins by issuing an internal Selective Reset followed by a
general internal self-test of the LAN Controller. The results of the self-test are written to
memory at the address specified in the Pointer field of this register. The format of the selftest result is shown in Table 7-5. After completing the self-test and writing the results to
memory, the LAN Controller will execute a full internal reset and will re-initialize to the
default configuration. Self-Test does not generate an interrupt of similar indicator to the
host processor upon completion.
0010 = Selective Reset: Sets the CU and RU to the Idle state, but otherwise maintains the current
configuration parameters (RU and CU Base, HDSSize, Error Counters, Configure
information and Individual/Multicast Addresses are preserved). Software should wait
approximately 10 µs after issuing this command before attempting to access the LAN
Controller’s registers again.
7-14
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LAN Controller Registers (B1:D8:F0)
Table 7-5. Self-Test Results Format
Bit
31:13
Description
Reserved
General Self-Test Result.
12
0 = Pass
1 = Fail
11:6
Reserved
Diagnose Result. This bit provides the result of an internal diagnostic test of the Serial Subsystem.
5
0 = Pass
1 = Fail
4
Reserved
3
0 = Pass
1 = Fail
Register Result. This bit provides the result of a test of the internal Parallel Subsystem registers.
ROM Content Result. This bit provides the result of a test of the internal microcode ROM.
7.2.5
2
0 = Pass
1 = Fail
1:0
Reserved
EEPROM Control Register
Offset Address:
Default Value:
0Eh
00h
Attribute:
Size:
RO, R/W
8 bits
The EEPROM Control Register is a 16-bit field that enables a read from and a write to the external
EEPROM.
Bit
7:4
3
Description
Reserved
EEPROM Serial Clock (EESK)—R/W. Toggling this bit clocks data into or out of the EEPROM.
Software must ensure that this bit is toggled at a rate that meets the EEPROM component’s
minimum clock frequency specification.
0 = Drives the ICH2’s EE_SHCLK signal low.
1 = Drives the ICH2’s EE_SHCLK signal high.
EEPROM Chip Select (EECS)—R/W.
2
0 = Drives the ICH2’s EE_CS signal low, to disable the EEPROM. this bit must be set to 0 for a
minimum of 1µs between consecutive instruction cycles.
1 = Drives the ICH2’s EE_CS signal high, to enable the EEPROM.
1
EEPROM Serial Data In (EEDI)—WO. Note that this bit represents "Data In" from the perspective
of the EEPROM device. The value of this bit is written to the EEPROM when performing write
operations.
0
EEPROM Serial Data Out (EEDO)—RO. Note that this bit represents "Data Out" from the
perspective of the EEPROM device. This bit contains the value read from the EEPROM when
performing read operations.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
7-15
LAN Controller Registers (B1:D8:F0)
7.2.6
Management Data Interface (MDI) Control Register
Offset Address:
Default Value:
10–13h
0000 0000h
Attribute:
Size:
R/W (special)
32 bits
The Management Data Interface (MDI) Control register is a 32-bit field and is used to read and
write bits from the LAN Connect component. This register may be written as a 32-bit entity, two
16-bit entities, or four 8-bit entities. The LAN Controller will only accept the command after the
high byte (offset 13h) is written; therefore, the high byte must be written last.
Bit
31:30
29
Description
These bits are reserved and should be set to 00b.
Interrupt Enable.
1 = Enables the LAN Controller to assert an interrupt to indicate the end of an MDI cycle.
0 = Disable.
28
Ready.
1 = Set by the LAN Controller at the end of an MDI transaction.
0 = Expected to be reset by software at the same time the command is written.
Opcode. These bits define the opcode:
00 = Reserved
27:26
01 = MDI write
10 = MDI read
11 = Reserved
7.2.7
25:21
LAN Connect Address. This field of bits contains the LAN Connect address.
20:16
LAN Connect Register Address. This field of bits contains the LAN Connect Register Address.
15:0
Data. In a write command, software places the data bits in this field, and the LAN Controller
transfers the data to the external LAN Connect component. During a read command, the LAN
Controller reads these bits serially from the LAN Connect, and software reads the data from this
location.
Receive DMA Byte Count Register
Offset Address:
Default Value:
7-16
14–17h
0000 0000h
Attribute:
Size:
RO
32 bits
Bit
Description
31:0
Receive DMA Byte Count—RO. Keeps track of how many bytes of receive data have been passed
into host memory via DMA.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LAN Controller Registers (B1:D8:F0)
7.2.8
Early Receive Interrupt Register
Offset Address:
Default Value:
18h
00h
Attribute:
Size:
R/W
8 bits
The Early Receive Interrupt register allows the internal LAN Controller to generate an early
interrupt depending on the length of the frame. The LAN Controller will generate an interrupt at
the end of the frame, regardless of whether or not Early Receive Interrupts are enabled.
Note:
It is recommended that software NOT utilize this register unless receive interrupt latency is a
critical performance issue in that particular software environment. Using this feature may reduce
receive interrupt latency, but will also result in the generation of more interrupts, which can
degrade system efficiency and performance in some environments.
Bit
Description
7:0
Early Receive Count—R/W. When some non-zero value x is programmed into this register, the
LAN controller sets the ER bit in the SCB Status Word Register and assert INTA# when the byte
count indicates that there are x quadwords remaining to be received in the current frame (based on
the Type/Length field of the received frame). No Early Receive interrupt will be generated if a value
of 00h (the default value) is programmed into this register.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
7-17
LAN Controller Registers (B1:D8:F0)
7.2.9
Flow Control Register
Offset Address:
Default Value:
19–1Ah
0000h
Attribute:
Size:
Bit
15:13
12
RO, R/W (special)
16 bits
Description
Reserved
FC Paused Low—RO.
1 = Set when the LAN Controller receives a Pause Low command with a value greater than zero.
0 = Cleared when the FC timer reaches zero, or a Pause frame is received.
11
FC Paused—RO.
1 = Set when the LAN Controller receives a Pause command regardless of its cause (FIFO
reaching Flow Control Threshold, fetching a Receive Frame Descriptor with its Flow Control
Pause bit set, or software writing a 1 to the Xoff bit).
0 = Cleared when the FC timer reaches zero.
10
FC Full—RO.
1 = Set when the LAN Controller sends a Pause command with a value greater than zero.
0 = Cleared when the FC timer reaches zero.
9
Xoff—R/W (special). This bit should only be used if the LAN Controller is configured to operate with
IEEE frame-based flow control.
1 = Writing a 1 to this bit forces the Xoff request to 1 and causes the LAN Controller to behave as if
the FIFO extender is full. This bit will also be set to 1 when an Xoff request due to an "RFD
Xoff" bit.
0 = This bit can only be cleared by writing a 1 to the Xon bit (bit 8 in this register).
8
Xon—WO. This bit should only be used if the LAN Controller is configured to operate with IEEE
frame-based flow control.
1 = Writing a 1 to this bit resets the Xoff request to the LAN Controller, clearing bit 9 in this register.
0 = This bit always returns 0 on reads.
7:3
Reserved
Flow Control Threshold—R/W. The LAN Controller can generate a Flow Control Pause frame
when its Receive FIFO is almost full. The value programmed into this field determines the number of
bytes still available in the Receive FIFO when the Pause frame is generated.
Free Bytes
Bits 2:0 in Receive FIFO Comment
2:0
7-18
000
001
010
011
100
101
110
111
0.50 KB
1.00 KB
1.25 KB
1.50 KB
1.75 KB
2.00 KB
2.25 KB
2.50 KB
Fast system (recommended default)
Slow system
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LAN Controller Registers (B1:D8:F0)
7.2.10
Power Management Driver (PMDR) Register
Offset Address:
Default Value:
1Bh
00h
Attribute:
Size:
R/WC
8 bits
The ICH2’s internal LAN Controller provides an indication in the PMDR that a wake-up event has
occurred.
Bit
7
Description
Link Status Change Indication—R/WC.
1 = The link status change bit is set following a change in link status.
0 = Software clears this bit by writing a 1 to the bit location.
6
Magic Packet—R/WC.
1 = This bit is set when a Magic Packet is received regardless of the Magic Packet wake-up disable
bit in the configuration command and the PME Enable bit in the Power Management Control/
Status Register.
0 = Software clears this bit by writing a 1 to the bit location.
5
Interesting Packet—R/WC.
1 = This bit is set when an “interesting” packet is received. Interesting packets are defined by the
LAN Controller packet filters.
0 = Software clears this bit by writing a 1 to the bit location.
4:1
0
Reserved.
PME Status—R/WC. This bit is a reflection of the PME Status bit in the Power Management
Control/Status Register (PMCSR).
1 = Set upon a wake-up event, independent of the PME Enable bit.
0 = Software clears this bit by writing a 1 to the bit location. This also clears the PME Status bit in
the PMCSR and deasserts the PME signal.
7.2.11
General Control Register
Offset Address:
Default Value:
1Ch
00h
Bit
7:4
3
2
1
Attribute:
Size:
R/W
8 bits
Description
Reserved. These bits should be set to 0000b.
LAN Connect Software Reset—R/W.
1 = Software can set this bit to force a reset condition on the LAN Connect interface.
0 = Cleared by software to begin normal LAN Connect operating mode. Software must not attempt
to access the LAN Connect interface for at least 1 ms after clearing this bit.
Reserved. This bit should be set to 0.
Deep Power-Down on Link Down Enable.
1 = Enable. The ICH2’s internal LAN Controller may enter a deep power-down state (sub 3 mA) in
the D2 and D3 power states while the link is down. In this state, the LAN Controller does not
keep link integrity. This state is not supported for point-to-point connection of two end stations.
0 = Disable
0
Reserved.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
7-19
LAN Controller Registers (B1:D8:F0)
7.2.12
General Status Register
Offset Address:
Default Value:
1Dh
N/A
Attribute:
Size:
Bit
7:3
2
RO
8 bits
Description
Reserved.
Duplex Mode. This bit indicates the wire duplex mode.
1 = Full duplex
0 = Half duplex
1
Speed. This bit indicates the wire speed:
1 = 100 Mbps
0 = 10 Mbps
0
Link Status Indication. This bit indicates the status of the link:
1 = Valid
0 = Invalid
7.2.13
Statistical Counters
The ICH2’s integrated LAN Controller provides information for network management statistics by
providing on-chip statistical counters that count a variety of events associated with both transmit
and receive. The counters are updated by the LAN Controller when it completes the processing of a
frame (i.e., when it has completed transmitting a frame on the link or when it has completed
receiving a frame). The Statistical Counters are reported to the software on demand by issuing the
Dump Statistical Counters command or Dump and Reset Statistical Counters command in the SCB
Command Unit Command (CUC) field.
Table 7-6. Statistical Counters
7-20
ID
Counter
Description
0
Transmit Good
Frames
This counter contains the number of frames that were transmitted properly on
the link. It is updated only after the actual transmission on the link is
completed, not when the frame was read from memory as is done for the
Transmit Command Block status.
4
Transmit Maximum
Collisions
(MAXCOL) Errors
This counter contains the number of frames that were not transmitted
because they encountered the configured maximum number of collisions.
8
Transmit Late
Collisions
(LATECOL) Errors
This counter contains the number of frames that were not transmitted since
they encountered a collision later than the configured slot time.
12
Transmit Underrun
Errors
A transmit underrun occurs because the system bus cannot keep up with the
transmission. This counter contains the number of frames that were either
not transmitted or retransmitted due to a transmit DMA underrun. If the LAN
Controller is configured to retransmit on underrun, this counter may be
updated multiple times for a single frame.
16
Transmit Lost
Carrier Sense
(CRS)
This counter contains the number of frames that were transmitted by the LAN
Controller despite the fact that it detected the deassertion of CRS during the
transmission.
20
Transmit Deferred
This counter contains the number of frames that were deferred before
transmission due to activity on the link.
24
Transmit Single
Collisions
This counter contains the number of transmitted frames that encountered
one collision.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LAN Controller Registers (B1:D8:F0)
Table 7-6. Statistical Counters
ID
Counter
Description
28
Transmit Multiple
Collisions
This counter contains the number of transmitted frames that encountered
more than one collision.
32
Transmit Total
Collisions
This counter contains the total number of collisions that were encountered
while attempting to transmit. This count includes late collisions and frames
that encountered MAXCOL.
36
Receive Good
Frames
This counter contains the number of frames that were received properly from
the link. It is updated only after the actual reception from the link is completed
and all the data bytes are stored in memory.
40
Receive CRC Errors
This counter contains the number of aligned frames discarded because of a
CRC error. This counter is updated, if needed, regardless of the Receive Unit
state. The Receive CRC Errors counter is mutually exclusive of the Receive
Alignment Errors and Receive Short Frame Errors counters.
44
Receive Alignment
Errors
This counter contains the number of frames that are both misaligned (for
example, CRS deasserts on a non-octal boundary) and contain a CRC error.
The counter is updated, if needed, regardless of the Receive Unit state. The
Receive Alignment Errors counter is mutually exclusive of the Receive CRC
Errors and Receive Short Frame Errors counters.
48
Receive Resource
Errors
This counter contains the number of good frames discarded due to
unavailability of resources. Frames intended for a host whose Receive Unit is
in the No Resources state fall into this category. If the LAN Controller is
configured to Save Bad Frames and the status of the received frame
indicates that it is a bad frame, the Receive Resource Errors counter is not
updated.
52
Receive Overrun
Errors
This counter contains the number of frames known to be lost because the
local system bus was not available. If the traffic problem persists for more
than one frame, the frames that follow the first are also lost; however,
because there is no lost frame indicator, they are not counted.
56
Receive Collision
Detect (CDT)
This counter contains the number of frames that encountered collisions
during frame reception.
60
Receive Short
Frame Errors
This counter contains the number of received frames that are shorter than
the minimum frame length. The Receive Short Frame Errors counter is
mutually exclusive to the Receive Alignment Errors and Receive CRC Errors
counters. A short frame will always increment only the Receive Short Frame
Errors counter.
64
Flow Control
Transmit Pause
This counter contains the number of Flow Control frames transmitted by the
LAN Controller. This count includes both the Xoff frames transmitted and Xon
(PAUSE(0)) frames transmitted.
68
Flow Control
Receive Pause
This counter contains the number of Flow Control frames received by the
LAN Controller. This count includes both the Xoff frames received and Xon
(PAUSE(0)) frames received.
72
Flow Control
Receive
Unsupported
This counter contains the number of MAC Control frames received by the
LAN Controller that are not Flow Control Pause frames. These frames are
valid MAC control frames that have the predefined MAC control Type value
and a valid address but has an unsupported opcode.
76
Receive TCO
Frames
This counter contains the number of TCO packets received by the LAN
Controller.
78
Transmit TCO
Frames
This counter contains the number of TCO packets transmitted.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
7-21
LAN Controller Registers (B1:D8:F0)
The Statistical Counters are initially set to zero by the ICH2’s integrated LAN Controller after
reset. They cannot be preset to anything other than zero. The LAN Controller increments the
counters by internally reading them, incrementing them and writing them back. This process is
invisible to the processor and PCI bus. In addition, the counters adhere to the following rules:
• The counters are wrap-around counters. After reaching FFFFFFFFh the counters wrap around
to 0.
• The LAN Controller updates the required counters for each frame. It is possible for more than
one counter to be updated as multiple errors can occur in a single frame.
• The counters are 32 bits wide and their behavior is fully compatible with the IEEE 802.1
standard. The LAN Controller supports all mandatory and recommend statistics functions
through the status of the receive header and directly through these Statistical Counters.
The processor can access the counters by issuing a Dump Statistical Counters SCB command. This
provides a “snapshot”, in main memory, of the internal LAN Controller statistical counters. The
LAN Controller supports 21 counters. The dump could consist of the either 16, 19, or all 21
counters, depending on the status of the Extended Statistics Counters and TCO Statistics
configuration bits in the Configuration command.
7-22
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Hub Interface to PCI Bridge Registers (D30:F0)
Hub Interface to PCI Bridge Registers
8
(D30:F0)
The hub interface to PCI Bridge resides in PCI Device 30, Function 0 on bus #0. This portion of the
ICH2 implements the buffering and control logic between PCI and the hub interface. The
arbitration for the PCI bus is handled by this PCI device. The PCI decoder in this device must
decode the ranges for the hub interface. All register contents will be lost when core well power is
removed.
8.1
PCI Configuration Registers (D30:F0)
Note:
Registers that are not shown should be treated as Reserved (See Section 6.2 for details).
.
Table 8-1. PCI Configuration Map (HUB-PCI—D30:F0)
Offset
Mnemonic
00–01h
VID
Register Name/Function
Vendor ID
Default
Type
8086h
RO
244Eh (ICH2)
02–03h
DID
Device ID
04–05h
CMD
PCI Device Command Register
0001h
R/W
06–07h
PD_STS
PCI Device Status Register
0080h
R/W
Revision ID
2448h (ICH2-M)
RO
08h
REVID
See Note
RO
0Ah
SCC
Sub Class Code
04h
RO
0Bh
BCC
Base Class Code
06h
RO
0Dh
PMLT
Primary Master Latency Timer
00h
RO
0Eh
HEADTYP
Header Type
01h
RO
18h
PBUS_NUM
Primary Bus Number
00h
RO
19h
SBUS_NUM
Secondary Bus Number
00h
R/W
1Ah
SUB_BUS_NUM
Subordinate Bus Number
00h
R/W
1Bh
SMLT
Secondary Master Latency Timer
00h
R/W
1Ch
IOBASE
IO Base Register
F0h
R/W
1Dh
IOLIM
IO Limit Register
00h
R/W
1E–1Fh
SECSTS
Secondary Status Register
0280h
R/W
20–21h
MEMBASE
Memory Base
FFF0h
R/W
22–23h
MEMLIM
Memory Limit
0000h
R/W
24–25h
PREF_MEM_BAS
E
Prefetchable Memory Base
0000h
RO
26–27h
PREF_MEM_MLT
Prefetchable Memory Limit
0000h
RO
30–31h
IOBASE_HI
I/O Base Upper 16 Bits
0000h
RO
32–33h
IOLIMIT_HI
I/O Limit Upper 16 Bits
0000h
RO
82801BA ICH2 and 82801BAM ICH2-M Datasheet
8-1
Hub Interface to PCI Bridge Registers (D30:F0)
Table 8-1. PCI Configuration Map (HUB-PCI—D30:F0) (Continued)
Offset
Mnemonic
Register Name/Function
Default
Type
3Ch
INT_LINE
Interrupt Line
00h
RO
3E–3Fh
BRIDGE_CNT
Bridge Control
0000h
R/W
40h
BRIDGE_CNT2
Bridge Control 2
00
R/W
50–51h
CNF
ICH2 Configuration Register
0000h
R/W
70h
MTT
Multi-Transaction Timer
20h
R/W
82h
PCI_MAST_STS
PCI Master Status
00h
R/W
90h
ERR_CMD
Error Command Register
00h
R/W
92h
ERR_STS
Error Status Register
00h
R/W
NOTE: Refer to the Specification Update for the value of the Revision ID Register
8.1.1
VID—Vendor ID Register (HUB-PCI—D30:F0)
Offset Address:
Default Value:
00–01h
8086h
Bit
15:0
8.1.2
RO
16 bits
Description
Vendor Identification Number—RO. This is a 16-bit value assigned to Intel. Intel VID = 8086h.
DID—Device ID Register (HUB-PCI—D30:F0)
Offset Address:
02–03h
Default Value:
244Eh (82801BA ICH2)
2448h (82801BAM ICH2-M)
Bit
15:0
8-2
Attribute:
Size:
Attribute:
Size:
RO
16 bits
Description
Device Identification Number—RO. This is a 16 bit value assigned to the ICH2 hub interface to
PCI bridge (i.e., Device #2).
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Hub Interface to PCI Bridge Registers (D30:F0)
8.1.3
CMD—Command Register (HUB-PCI—D30:F0)
Offset Address:
Default Value:
04–05h
0001h
Bit
15:10
Attribute:
Size:
R/W
16 bits
Description
Reserved.
9
Fast Back to Back Enable (FBE)—RO. Hardwired to 0. The ICH2 does not support this capability.
8
SERR# Enable (SERR_EN)—R/W.
1 = Enable the ICH2 to generate an NMI (or SMI# if NMI routed to SMI#) when the D30:F0 SSE bit
(offset 06h, bit 14) is set.
7
Wait Cycle Control—RO. Hardwired to 0
6
.Parity Error Response—R/W.
1 = The ICH2 is allowed to report parity errors detected on the hub interface.
0 = Disable.
0 = The ICH2 will ignore parity errors on the hub interface.
5
VGA Palette Snoop—RO. Hardwired to 0.
4
Postable Memory Write Enable (PMWE)—RO. Hardwired to 0.
3
Special Cycle Enable (SCE)—RO. Hardwired to 0 by P2P Bridge specification.
2
Bus Master Enable (BME)—R/W.
1 = Allows the Hub interface-to-PCI bridge to accept cycles from PCI to run on the hub interface.
Note: This bit does not affect the CF8h and CFCh I/O accesses.
0 = Disable
1
Memory Space Enable (MSE)—R/W. The ICH2 provides this bit as read/writable for software only.
However, the ICH2 ignores the programming of this bit, and runs hub interface memory cycles to
PCI.
0
I/O Space Enable (IOE)—R/W. The ICH2 provides this bit as read/writable for software only.
However, the ICH2 ignores the programming of this bit and runs hub interface I/O cycles to PCI that
are not intended for USB, IDE, or AC’97.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
8-3
Hub Interface to PCI Bridge Registers (D30:F0)
8.1.4
PD_STS—Primary Device Status Register
(HUB-PCI—D30:F0)
Offset Address:
Default Value:
06–07h
0080h
Attribute:
Size:
R/WC
16 bits
For the writable bits in this register, writing a 1 will clear the bit. Writing a 0 to the bit will have no
effect.
Bit
Description
15
Detected Parity Error (DPE)—R/WC.
1 = Indicates that the ICH2 detected a parity error on the hub interface. This bit gets set even if the
Parity Error Response bit (offset 04, bit 6) is not set.
0 = Software clears this bit by writing a 1 to the bit location.
14
Received System Error (SSE)—R/WC.
1 = An address, or command parity error, or special cycles data parity error has been detected on
the PCI bus, and the Parity Error Response bit (D30:F0, Offset 04h, bit 6) is set. If this bit is set
because of parity error and the D30:F0 SERR_EN bit (Offset 04h, bit 8) is also set, the ICH2
will generate an NMI (or SMI# if NMI routed to SMI#)
0 = Software clears this bit by writing a 1 to the bit location.
13
Received Master Abort (RMA)—R/WC.
1 = ICH2 received a master abort from the hub interface device.
0 = Software clears this bit by writing a 1 to the bit location.
12
Received Target Abort (RTA)—R/WC.
1 = ICH2 received a target abort from the hub interface device. The TCO logic can cause an SMI#,
NMI, or interrupt based on this bit getting set.
0 = Software clears this bit by writing a 1 to the bit location.
11
Signaled Target Abort (STA)—R/WC.
1 = ICH2 signals a target abort condition on the hub interface.
0 = Software clears this bit by writing a 1 to the bit location.
10:9
8
DEVSEL# Timing Status—RO.
00h = Fast timing. This register applies to the hub interface; therefore, this field does not matter.
Data Parity Error Detected (DPD)—R/WC. Since this register applies to the hub interface, the
ICH2 must interpret this bit differently than it is in the PCI specification.
1 = ICH2 detects a parity error on the hub interface and the Parity Error Response bit in the
Command Register (offset 04h, bit 6) is set.
0 = Software clears this bit by writing a 1 to the bit location.
7
Fast Back to Back—RO. Hardwired to 1.
6
User Definable Features (UDF)—RO. Hardwired to 0.
5
66 MHz Capable—RO. Hardwired to 0.
4:0
8.1.5
Reserved.
REVID—Revision ID Register (HUB-PCI—D30:F0)
Offset Address:
Default Value:
Bit
7:0
8-4
08h
See bit description
Attribute:
Size:
RO
8 bits
Description
Revision Identification Number—RO. 8-bit value that indicates the revision number for the ICH2
hub interface to PCI bridge. Refer to the Specification Update for the value of the Revision ID
Register.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Hub Interface to PCI Bridge Registers (D30:F0)
8.1.6
SCC—Sub-Class Code Register (HUB-PCI—D30:F0)
Offset Address:
Default Value:
8.1.7
Attribute:
Size:
RO
8 bits
Bit
Description
7:0
Sub-Class Code—RO. This 8-bit value indicates the category of bridge for the ICH2 hub interface to
PCI bridge. The code is 04h indicating a PCI-to-PCI bridge.
BCC—Base-Class Code Register (HUB-PCI—D30:F0)
Offset Address:
Default Value:
8.1.8
0Ah
04h
0Bh
06h
Attribute:
Size:
RO
8 bits
Bit
Description
7:0
Base Class Code—RO. This 8-bit value indicates the type of device for the ICH2 hub interface to PCI
bridge. The code is 06h indicating a bridge device.
PMLT—Primary Master Latency Timer Register
(HUB-PCI—D30:F0)
Offset Address:
Default Value:
0Dh
00h
Attribute:
Size:
RO
8 bits
This register does not apply to hub interface.
Bit
8.1.9
Description
7:3
Master Latency Count. Not implemented.
2:0
Reserved.
HEADTYP—Header Type Register (HUB-PCI—D30:F0)
Offset Address:
Default Value:
0Eh
01h
Bit
7
6:0
Attribute:
Size:
RO
8 bits
Description
Multi-function Device—RO. This bit is 0 to indicate a single function device.
Header Type—RO. 8-bit field identifies the header layout of the configuration space, which is a PCIto-PCI bridge in this case.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
8-5
Hub Interface to PCI Bridge Registers (D30:F0)
8.1.10
PBUS_NUM—Primary Bus Number Register
(HUB-PCI—D30:F0)
Offset Address:
Default Value:
8.1.11
RO
8 bits
Description
7:0
Primary Bus Number—RO. This field indicates the bus number of the hub interface and is hardwired
to 00h.
SBUS_NUM—Secondary Bus Number Register
(HUB-PCI—D30:F0)
19h
00h
Attribute:
Size:
R/W
8 bits
Bit
Description
7:0
Secondary Bus Number—R/W. This field indicates the bus number of PCI. Note that when this
number is equal to the primary bus number (i.e., bus #0), the ICH2 will run hub interface configuration
cycles to this bus number as Type 1 configuration cycles on PCI.
SUB_BUS_NUM—Subordinate Bus Number Register
(HUB-PCI—D30:F0)
Offset Address:
Default Value:
8.1.13
Attribute:
Size:
Bit
Offset Address:
Default Value:
8.1.12
18h
00h
1A
00h
Attribute:
Size:
R/W
8 bits
Bit
Description
7:0
Subordinate Bus Number—R/W. This field specifies the highest PCI bus number below the hub
interface to PCI bridge. If a Type 1 configuration cycle from the hub interface does not fall in the
Secondary-to-Subordinate Bus ranges of Device 30, the ICH2 indicates a master abort back to the
hub interface.
SMLT—Secondary Master Latency Timer Register
(HUB-PCI—D30:F0)
Offset Address:
Default Value:
1Bh
00h
Attribute:
Size:
R/W
8 bits
This Master Latency Timer (MLT) controls the amount of time that the ICH2 continues to burst
data as a master on the PCI bus. When the ICH2 starts the cycle after being granted the bus, the
counter is loaded and starts counting down from the assertion of FRAME#. If the internal grant to
this device is removed, then the expiration of the MLT counter results in the deassertion of
FRAME#. If the internal grant has not been removed, the ICH2 can continue to own the bus.
Bit
8-6
Description
7:3
Master Latency Count—R/W. This 5-bit value indicates the number of PCI clocks, in 8-clock
increments, that the ICH2 remains as master of the bus.
2:0
Reserved.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Hub Interface to PCI Bridge Registers (D30:F0)
8.1.14
IOBASE—I/O Base Register (HUB-PCI—D30:F0)
Offset Address:
Default Value:
8.1.15
1Ch
F0h
Attribute:
Size:
R/W
8 bits
Bit
Description
7:4
I/O Address Base bits [15:12]—R/W. I/O Base bits corresponding to address lines 15:12 for 4 KB
alignment. Bits 11:0 are assumed to be padded to 000h.
3:0
I/O Addressing Capability—RO. This is hardwired to 0h, indicating that the hub interface to PCI
bridge does not support 32-bit I/O addressing. This means that the I/O Base Register and I/O Limit
Upper Address registers must be read only.
IOLIM—I/O Limit Register (HUB-PCI—D30:F0)
Offset Address:
Default Value:
1Dh
00h
Attribute:
Size:
R/W
8 bits
Bit
Description
7:4
I/O Address Limit bits [15:12]—R/W. I/O Base bits corresponding to address lines 15:12 for 4 KB
alignment. Bits 11:0 are assumed to be padded to FFFh.
3:0
I/O Addressing Capability—RO. This is hardwired to 0h, indicating that the hub interface-to-PCI
bridge does not support 32-bit I/O addressing. This means that the I/O Base Register and I/O Limit
Upper Address registers must be read only.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
8-7
Hub Interface to PCI Bridge Registers (D30:F0)
8.1.16
SECSTS—Secondary Status Register (HUB-PCI—D30:F0)
Offset Address:
Default Value:
1E–1Fh
0280h
Attribute:
Size:
R/W
16 bits
For the writable bits in this register, writing a 1 will clear the bit. Writing a 0 to the bit will have no
effect.
Bit
15
Description
Detected Parity Error (DPE)—R/WC.
1 = ICH2 detected a parity error on the PCI bus.
0 = Software clears this bit by writing a 1 to the bit position.
14
Received System Error (SSE)—R/WC.
1 = SERR# assertion is received on PCI.
0 = Software clears this bit by writing a 1 to the bit position.
13
Received Master Abort (RMA)—R/WC.
1 = Hub interface to PCI cycle is master-aborted on PCI.
0 = Software clears this bit by writing a 1 to the bit position.
12
Received Target Abort (RTA)—R/WC.
1 = Hub interface to PCI cycle is target-aborted on PCI. For “completion required” cycles from the
hub interface, this event should also set the Signaled Target Abort in the Primary Status
Register in this device and the ICH2 must send the “target abort” status back to the hub
interface.
0 = Software clears this bit by writing a 1 to the bit position.
11
10:9
Signaled Target Abort (STA)—RO. The ICH2 does not generate target aborts.
DEVSEL# Timing Status—RO.
01h = Medium timing.
Data Parity Error Detected (DPD)—R/WC.
1 = The ICH2 sets this bit when all of the following three conditions are met:
- The Parity Error Response Enable bit in the Bridge Control Register (bit 0, offset 3Eh) is set
8
- USB, AC’97 or IDE is a Master
- PERR# asserts during a write cycle OR a parity error is detected internally during a read cycle
0 = Software clears this bit by writing a 1 to the bit position.
7
Fast Back to Back—RO. Hardwired to 1 to indicate that the PCI to hub interface target logic is
capable of receiving fast back-to-back cycles.
6
User Definable Features (UDF)—RO. Hardwired to 0.
5
4:0
8-8
66 MHz Capable—RO. Hardwired to 0.
Reserved.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Hub Interface to PCI Bridge Registers (D30:F0)
8.1.17
MEMBASE—Memory Base Register (HUB-PCI—D30:F0)
Offset Address:
Default Value:
20–21h
FFF0h
Attribute:
Size:
R/W
16 bits
This register defines the base of the hub interface to PCI non-prefetchable memory range. Since the
ICH2 forwards all hub interface memory accesses to PCI, the ICH2 only uses this information for
determining when not to accept cycles as a target.
This register must be initialized by the configuration software. For the purpose of address decode,
address bits A[19:0] are assumed to be 0. Thus, the bottom of the defined memory address range
will be aligned to a 1 MB boundary.
Bit
8.1.18
Description
15:4
Memory Address Base—R/W. Defines the base of the memory range for PCI. These 12 bits
correspond to address bits 31:20.
3:0
Reserved.
MEMLIM—Memory Limit Register (HUB-PCI—D30:F0)
Offset Address:
Default Value:
22–23h
0000h
Attribute:
Size:
R/W
16 bits
This register defines the upper limit of the hub interface to PCI non-prefetchable memory range.
Since the ICH2 will forward all hub interface memory accesses to PCI, the ICH2 will only use this
information for determining when not to accept cycles as a target.
This register must be initialized by the configuration software. For the purpose of address decode,
address bits A[19:0] are assumed to be FFFFFh. Thus, the top of the defined memory address range
will be aligned to a 1 MB boundary.
Bit
8.1.19
Description
15:4
Memory Address Limit—R/W. Defines the top of the memory range for PCI. These 12 bits
correspond to address bits 31:20.
3:0
Reserved.
PREF_MEM_BASE—Prefetchable Memory Base Register
(HUB-PCI—D30:F0)
Offset Address:
Default Value:
24h–25h
0000FFF0h
Attribute:
Size:
R/W
16-bit
Bit
Description
15:4
Prefetchable Memory Address Base—R/W. Defines the base address of the prefetchable memory
address range for PCI. These 12 bits correspond to address bits 31:20.
3:0
Reserved. RO.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
8-9
Hub Interface to PCI Bridge Registers (D30:F0)
8.1.20
PREF_MEM_MLT—Prefetchable Memory Limit Register
(HUB-PCI—D30:F0)
Offset Address:
Default Value:
8.1.21
26h–27h
00000000h
Description
15:4
Prefetchable Memory Address Limit—RW. Defines the limit address of the prefetchable memory
address range for PCI. These 12 bits correspond to address bits 31:20.
3:0
Reserved. RO
IOBASE_HI—I/O Base Upper 16 Bits Register
(HUB-PCI—D30:F0)
30–31h
0000h
Bit
15:0
RO
16 bits
I/O Address Base Upper 16 bits [31:16]—RO. Not supported; hardwired to 0.
IOLIM_HI—I/O Limit Upper 16 Bits Register
(HUB-PCI—D30:F0)
32–33h
0000h
Bit
15:0
Attribute:
Size:
RO
16 bits
Description
I/O Address Limit Upper 16 bits [31:16]—RO. Not supported; hardwired to 0.
INT_LINE—Interrupt Line Register (HUB-PCI—D30:F0)
Offset Address:
Default Value:
Bit
7:0
8-10
Attribute:
Size:
Description
Offset Address:
Default Value:
8.1.23
R/W
16-bit
Bit
Offset Address:
Default Value:
8.1.22
Attribute:
Size:
3Ch
00h
Attribute:
Size:
RO
8 bits
Description
Interrupt Line Routing—RO. Hardwired to 00h. The bridge does not generate interrupts, and
interrupts from downstream devices are routed around the bridge.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Hub Interface to PCI Bridge Registers (D30:F0)
8.1.24
BRIDGE_CNT—Bridge Control Register (HUB-PCI—D30:F0)
Offset Address:
Default Value:
3E–3Fh
0000h
Bit
15:8
Attribute:
Size:
R/W
16 bits
Description
Reserved.
7
Fast Back to Back Enable—RO. Hardwired to 0. The PCI logic will not generate fast back-to-back
cycles on the PCI bus.
6
Secondary Bus Reset—RO. hardwired to 0. The ICH2 does not follow the P2P bridge reset scheme;
Software-controlled resets are implemented in the PCI-LPC device.
5
Master Abort Mode—R/W. The ICH2 ignores this bit. However, this bit is read/write for software
compatibility. The ICH2 must handle master aborts as if this bit is reset to 0.
4
Reserved.
3
VGA Enable—R/W.
1 = Enable. Indicates that the VGA device is on PCI. Therefore, the PCI to hub interface decoder will
not accept memory cycles in the range A0000h–BFFFFh. Note that the ICH2 will never take I/O
cycles in the VGA range from PCI.
0 = No VGA device on PCI.
2
1
ISA Enable—R/W. The ICH2 ignores this bit. However, this bit is read/write for software compatibility.
Since the ICH2 forwards all I/O cycles that are not in the USB, AC’97, or IDE ranges to PCI, this bit
would have no effect.
SERR# Enable—R/W.
1 = Enable. If this bit is set AND bit 8 in CMD register (D30:F0 Offset 04h) is also set, the ICH2 sets
the SSE bit in PD_STS register (D30:F0, offset 06h, bit 14) AND also generate an NMI (or SMI#
if NMI routed to SMI) when the SERR# signal is asserted.
0 = Disable
Parity Error Response Enable—R/W.
0
1 = Enable the hub interface to PCI bridge for parity error detection and reporting on the PCI bus.
0 = Disable
8.1.25
BRIDGE_CNT2—Bridge Control Register 2
(HUB-PCI—D30:F0)
Offset Address:
Default Value:
40h
00h
Bit
7:1
Attribute:
Size
R/W
8 bits
Description
Reserved
PCI_DAC_EN—R/W. Allows ICH2 to recognize external PCI masters performing DAC on PCI.
0
0 = Disable.
1 = Enable.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
8-11
Hub Interface to PCI Bridge Registers (D30:F0)
8.1.26
CNF—ICH2 Configuration Register (HUB-PCI—D30:F0)
Offset Address:
Default Value:
50–51h
0000h
Bit
15:10
Attribute:
Size:
R/W
16 bits
Description
Reserved.
9
HP_PCI_EN—R/W. High Priority PCI Enable.
1 = Enables a mode where the REQ[0]#/GNT[0]# signal pair has a higher arbitration priority.
0 = All PCI REQ#/GNT pairs have the same arbitration priority.
8
Hole Enable (15 MB–16 MB)—R/W.
1 = Enables the 15 MB to 16 MB hole in the DRAM.
0 = Disable
7:3
2
Reserved.
Discard Timer Mode. This bit shortens all of the Delayed Transaction discard timers to 128 PCI
clocks. It controls how long the ICH2-M will wait before flushing previously requested prefetched
read data due to a Delayed Transaction, and then servicing a different request.
0 = 1024 PCI clocks (32 us) (Default).
1 = 128 PCI clocks (4 us).
8.1.27
1
32-Clock Retry Enable—R/W. System BIOS must set this bit for PCI compliance.
1 = When a PCI device is running a locked memory read cycle, while all other bus masters are
waiting to run locked cycles, concurrent with a LPC DMA transfer, this bit, when set allows the
ICH2 to retry the locked memory read cycle.
0 = If this bit is not set, under the same circumstance, the bus will not be released since all other
masters see the lock in use.
0
Reserved.
MTT—Multi-Transaction Timer Register (HUB-PCI—D30:F0)
Offset Address:
Default Value:
70h
20h
Attribute:
Size:
R/W
8 bits
MTT is an 8-bit register that controls the amount of time that the ICH2’s arbiter allows a PCI
initiator to perform multiple back-to-back transactions on the PCI bus. The ICH2’s MTT
mechanism is used to guarantee a fair share of the Primary PCI bandwidth to an initiator that
performs multiple back-to-back transactions to fragmented memory ranges (and as a consequence
it can not use long burst transfers).
The number of clocks programmed in the MTT represents the guaranteed time slice (measured in
PCI clocks) allotted to the current agent, after which the arbiter grants another agent that is
requesting the bus. The MTT value must be programmed with 8 clock granularity in the same
manner as MLT. For example, if the MTT is programmed to 18h, the selected value corresponds to
the time period of 24 PCI clocks.The default value of MTT is 20h (32 PCI clocks).
Note:
Programming the MTT to a value of 00h disables this function, which could cause starvation issues
for some PCI master devices. Programming of the MTT to anything less than 16 clocks will not
allow the Grant-to-FRAME# latency to be 16 clocks. The MTT timer will time-out before the
Grant-to-FRAME# trigger causing a re-arbitration.
Bit
8-12
Description
7:3
Multi-Transaction Timer Count Value—R/W. This field specifies the amount of time that grant
remains asserted to a master continuously asserting its request for multiple transfers. This field
specifies the count in an 8-clock (PCI clock) granularity.
2:0
Reserved.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Hub Interface to PCI Bridge Registers (D30:F0)
8.1.28
PCI_MAST_STS—PCI Master Status Register
(HUB-PCI—D30:F0)
Offset Address:
Default Value:
82h
00h
Bit
7
Attribute:
Size:
R/WC
8 bits
Description
Internal PCI Master Request Status (INT_MREQ_STS)—R/WC.
1 = The ICH2’s internal DMA controller or LPC has requested use of the PCI bus.
0 = Software clears this bit by writing a 1 to the bit position.
6
Internal LAN Master Request Status (LAN_MREQ_STS)—R/WC.
1 = The ICH2’s internal LAN controller has requested use of the PCI bus.
0 = Software clears this bit by writing a 1 to the bit position.
5:0
PCI Master Request Status (PCI_MREQ_STS)—R/WC. Allows software to see if a particular bus
master has requested use of the PCI bus. For example, bit 0 will be set if ICH2 has detected
REQ[0]# asserted and bit 5 will be set if ICH2 detected REQ[5]# asserted.
1 = The associated PCI master has requested use of the PCI bus.
0 = Software clears these bits by writing a 1 to the bit position.
8.1.29
ERR_CMD—Error Command Register (HUB-PCI—D30:F0)
Offset Address:
Default Value:
Lockable:
90h
00h
No
Attribute:
Size:
Power Well:
R/W
8-bit
Core
This register configures the ICH2’s Device 30 responses to various system errors. The actual
assertion of the internal SERR# (routed to cause NMI# or SMI#) is enabled via the PCI Command
register.
Bit
7:3
2
Description
Reserved.
SERR# enable on receiving target abort (SERR_RTA_EN)—R/W.
1 = Enable. When SERR_EN is set, the ICH2 will report SERR# when SERR_RTA is set.
0 = Disable
1
SERR# enable on Delayed Transaction Time-out (SERR_DTT_EN)—R/W.
1 = Enable. When SERR_EN is set, the ICH2 will report SERR# when SERR_DTT is set.
0 = Disable.
0
Reserved.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
8-13
Hub Interface to PCI Bridge Registers (D30:F0)
8.1.30
ERR_STS—Error Status Register (HUB-PCI—D30:F0)
Offset Address:
Default Value:
Lockable:
92h
00h
No
Attribute:
Size:
Power Well:
R/W
8-bit
Core
This register records the cause of system errors in Device 30. The actual assertion of SERR# is
enabled via the PCI Command register.
Bit
7:3
2
Description
Reserved.
SERR# Due to Received Target Abort (SERR_RTA)—R/W.
1 = The ICH2 sets this bit when the ICH2 receives a target abort. If SERR_EN, the ICH2 will also
generate an SERR# when SERR_RTA is set.
0 = This bit is cleared by writing a 1.
1
SERR# Due to Delayed Transaction Time-out (SERR_DTT)—R/W.
1 = When a PCI master does not return for the data within 1 ms of the cycle’s completion, the ICH2
clears the delayed transaction, and sets this bit. If both SERR_DTT_EN and SERR_EN are
set, then ICH2 will also generate an SERR# when SERR_DTT is set.
0 = This bit is cleared by writing a 1.
0
8-14
Reserved.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
LPC Interface Bridge Registers
(D31:F0)
9
The LPC Bridge function of the ICH2 resides in PCI Device 31:Function 0. This function contains
many other functional units (e.g., DMA and Interrupt Controllers, Timers, Power Management,
System Management., GPIO, RTC, and LPC Configuration Registers).
Registers and functions associated with other functional units (power management, GPIO, USB,
IDE, etc.) are described in their respective sections.
9.1
PCI Configuration Registers (D31:F0)
Note:
Registers that are not shown should be treated as Reserved (See Section 6.2 for details).
.
Table 9-1. PCI Configuration Map (LPC I/F—D31:F0)
Offset
Mnemonic
Register Name
00h–01h
VID
Vendor ID
02h–03h
DID
Device ID
04h–05h
PCICMD
PCI Command Register
000Fh
R/W
06h–07h
PCISTS
PCI Device Status Register
0280h
R/W
08h
RID
See Note
RO
09h
PI
Programming Interface
00h
RO
Revision ID
Default
Type
8086h
RO
2440h (ICH2)
244Ch (ICH2-M)
RO
0Ah
SCC
Sub Class Code
01h
RO
0Bh
BCC
Base Class Code
06h
RO
0Eh
HEADT
Header Type
80h
RO
40h–43h
PMBASE
00000001h
R/W
ACPI Base Address Register
44h
ACPI_CNTL
ACPI Control
4Eh–4Fh
BIOS_CNTL
BIOS Control Register
54h
TCO_CNTL
TCO Control
58h–5Bh
GPIO_BASE
GPIO Base Address Register
GPIO Control Register
00h
R/W
0000h
R/W
00h
R/W
00000001h
R/W
5Ch
GPIO_CNTL
00h
R/W
60h–63h
PIRQ[n]_ROUT
PIRQ[A–D] Routing Control
80808080h
R/W
64h
SIRQ_CNTL
Serial IRQ Control Register
10h
R/W
68h–6Bh
PIRQ[n]_ROUT
PIRQ[E–H] Routing Control
80808080h
R/W
88h
D31_ERR_CFG
Device 31 Error configuration Register
00h
R/W
8Ah
D31_ERR_STS
Device 31 Error Status Register
00h
R/W
90h–91h
PCI_DMA_C
0000h
R/W
A0h–CFh
PCI DMA Configuration Registers
Power Management Registers
See Section 9.8.1
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-1
LPC Interface Bridge Registers (D31:F0)
Table 9-1. PCI Configuration Map (LPC I/F—D31:F0) (Continued)
Offset
Mnemonic
Register Name
Default
Type
D0h–D3h
GEN_CNTL
General Control
00000000h
R/W
D4h–D7h
GEN_STS
General Status
00000F00h
R/W
D8h
RTC_CONF
Real Time Clock Configuration
00h
R/W
E0h
COM_DEC
LPC I/F COM Port Decode Ranges
00h
R/W
E1h
LPCFDD_DEC
E2h
SND_DEC
E3h
FWH_DEC_EN1
E4h–E5h
GEN1_DEC
LPC I/F FDD & LPT Decode Ranges
00h
R/W
LPC I/F Sound Decode Ranges
00h
R/W
FWH Decode Enable 1
FFh
R/W
0000h
R/W
LPC I/F General 1 Decode Range
E6h–E7h
LPC_EN
E8h–EBh
FWH_SEL1
LPC I/F Enables
FWH Select 1
00h
R/W
00112233h
R/W
ECh–EDh
GEN2_DEC
LPC I/F General 2 Decode Range
0000h
R/W
EEh–EFh
FWH_SEL2
FWH Select 2
5678h
R/W
F0h
FWH_DEC_EN2
F2h
FUNC_DIS
FWH Decode Enable 2
0Fh
R/W
Function Disable Register
00h
R/W
NOTE: Refer to the Specification Update for the value of the Revision ID Register.
9.1.1
VID—Vendor ID Register (LPC I/F—D31:F0)
Offset Address:
Default Value:
Lockable:
00–01h
8086h
No
Bit
15:0
9.1.2
RO
16-bit
Core
Description
Vendor ID Value. This is a 16 bit value assigned to Intel. Intel VID = 8086h
DID—Device ID Register (LPC I/F—D31:F0)
Offset Address:
Lockable:
02–03h
No
Default Value:
2440h (82801BA ICH2)
244Ch (82801BAM ICH2-M)
Bit
15:0
9-2
Attribute:
Size:
Power Well:
Attribute:
Size:
Power Well:
RO
16-bit
Core
Description
Device ID Value. This is a 16 bit value assigned to the ICH2 LPC Bridge.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.1.3
PCICMD—PCI COMMAND Register (LPC I/F—D31:F0)
Offset Address:
Default Value:
Lockable:
04–05h
000Fh
No
Bit
15:10
9
Attribute:
Size:
Power Well:
R/W
16-bit
Core
Description
Reserved.
Fast Back to Back Enable (FBE)—RO. Hardwired to 0.
SERR# Enable (SERR_EN)—R/W.
8
1 = Enable. Allow SERR# to be generated.
0 = Disable.
7
Wait Cycle Control (WCC)—RO. Hardwired to 0.
6
Parity Error Response (PER)—R/W.
1 = The ICH will take normal action when a parity error is detected.
0 = No action is taken when detecting a parity error.
5
VGA Palette Snoop (VPS)—RO. Hardwired to 0
4
Postable Memory Write Enable (PMWE)—RO. Hardwired to 0
3
Special Cycle Enable (SCE). Hardwired to 1.
2
Bus Master Enable (BME)—RO. Hardwired to 1 to indicate that bus mastering can not be disabled
for function 0 (DMA/ISA Master).
1
Memory Space Enable (MSE)—RO. Hardwired to 1 to indicate that memory space can not be
disabled for Function 0 (LPC I/F).
0
I/O Space Enable (IOE)—RO. Hardwired to 1 to indicate that the I/O space cannot be disabled for
function 0 (LPC I/F).
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-3
LPC Interface Bridge Registers (D31:F0)
9.1.4
PCISTS—PCI Device Status (LPC I/F—D31:F0)
Offset Address:
Default Value:
Lockable:
06–07h
0280h
No
Bit
15
Attribute:
Size:16-bit
Power Well:
R/WC
Core
Description
Detected Parity Error (DPE)—R/W.
1 = PERR# signal goes active. Set even if the PER bit is 0.
0 = This bit is cleared by software writing a 1 to the bit position.
14
Signaled System Error (SSE)—R/W.
1 = Set by the ICH2 if the SERR_EN bit is set and the ICH2 generates an SERR# on function 0. The
ERR_STS register can be read to determine the cause of the SERR#. The SERR# can be routed
to cause SMI#, NMI, or interrupt.
0 = This bit is cleared by software writing a 1 to the bit position.
13
Master Abort Status (RMA)—R/W.
1 = ICH2 generated a master abort on PCI due to LPC I/F master or DMA cycles.
0 = This bit is cleared by software writing a 1 to the bit position.
12
Received Target Abort (RTA)—R/W.
1 = ICH2 received a target abort during LPC I/F master or DMA cycles to PCI.
0 = This bit is cleared by software writing a 1 to the bit position.
11
Signaled Target Abort (STA)—R/W.
1 = ICH2 generated a target abort condition on PCI cycles claimed by the ICH2 for ICH2 internal
registers or for going to LPC I/F.
0 = This bit is cleared by software writing a 1 to the bit position.
10:9
8
DEVSEL# Timing Status (DEV_STS)—RO.
01 = Medium Timing.
Data Parity Error Detected (DPED)—R/WC.
1 = Set when all three of the following conditions are true:
- The ICH2 is the initiator of the cycle,
- The ICH2 asserted PERR# (for reads) or observed PERR# (for writes), and
- The PER bit is set.
0 = This bit is cleared by software writing a 1 to the bit position.
7
Fast Back to Back (FB2B)—RO. Always 1. Indicates ICH2 as a target can accept fast back-to-back
transactions.
6
User Definable Features (UDF). Hardwired to 0
5
66 MHz Capable (66MHZ_CAP)—RO. Hardwired to 0
4:0
9.1.5
Reserved.
REVID—Revision ID Register (LPC I/F—D31:F0)
Offset Address:
Default Value:
9-4
08h
See bit description
Attribute:
Size:
RO
8 bits
Bit
Description
7:0
Revision Identification Number. 8-bit value that indicates the revision number for the LPC bridge.
For the A-0 stepping, this value is 00h. Refer to the Specification Update for the value of the Revision
ID Register
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.1.6
PI—Programming Interface (LPC I/F—D31:F0)
Offset Address:
Default Value:
09h
00h
Bit
7:0
9.1.7
Programming Interface Value.
SCC—Sub-Class Code Register (LPC I/F—D31:F0)
0Ah
01h
Bit
7:0
Attribute:
Size:
RO
8 bits
Description
Sub-Class Code. This 8-bit value indicates the category of bridge for the LPC PCI bridge.
BCC—Base-Class Code Register (LPC I/F—D31:F0)
Offset Address:
Default Value:
0Bh
06h
Bit
7:0
9.1.9
RO
8 bits
Description
Offset Address:
Default Value:
9.1.8
Attribute:
Size:
Attribute:
Size:
RO
8 bits
Description
Base Class Code. This 8-bit value indicates the type of device for the LPC bridge. The code is 06h
indicating a bridge device.
HEADTYP—Header Type Register (LPC I/F—D31:F0)
Offset Address:
Default Value:
0Eh
80h
Bit
7
6:0
Attribute:
Size:
RO
8 bits
Description
Multi-function Device—RO. This bit is 1 to indicate a multi-function device.
Header Type—RO. This 8-bit field identifies the header layout of the configuration space.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-5
LPC Interface Bridge Registers (D31:F0)
9.1.10
PMBASE—ACPI Base Address (LPC I/F—D31:F0)
Offset Address:
Default Value:
Lockable:
40–43h
00000001h
No
Attribute:
Size:
Usage:
Power Well:
R/W
32-bit
ACPI, Legacy
Core
Sets base address for ACPI I/O registers, GPIO registers and TCO I/O registers. Can be mapped
anywhere in the 64 KB I/O space on 128-byte boundaries.
Bit
31:16
Reserved.
15:7
Base Address—R/W. Provides 128 bytes of I/O space for ACPI, GPIO, and TCO logic. This is
placed on a 128-byte boundary.
6:1
Reserved.
0
9.1.11
Description
Resource Indicator—RO. Tied to 1 to indicate I/O space.
ACPI_CNTL—ACPI Control (LPC I/F—D31:F0)
Offset Address:
Default Value:
Lockable:
44h
00h
No
Bit
7:5
4
Attribute:
Size:
Usage:
Power Well:
R/W
8-bit
ACPI, Legacy
Core
Description
Reserved.
ACPI Enable (ACPI_EN)—R/W.
1 = Decode of the I/O range pointed to by the ACPI base register is enabled, and the ACPI power
management function is enabled. Note that the APM power management ranges (B2/B3h) are
always enabled and are not affected by this bit.
0 = Disable.
3
Reserved.
SCI IRQ Select (SCI_IRQ_SEL)—R/W. Specifies on which IRQ the SCI will internally appear. If not
using the APIC, the SCI must be routed to IRQ[9:11], and that interrupt is not sharable with the
SERIRQ stream, but is shareable with other PCI interrupts. If using the APIC, the SCI can also be
mapped to IRQ[20:23], and can be shared with other interrupts.
000 = IRQ9
001 = IRQ10
2:0
010 = IRQ11
011 = Reserved
100 = IRQ20 (Only available if APIC enabled)
101 = IRQ21 (Only available if APIC enabled)
110 = RQ22 (Only available if APIC enabled)
111 = IRQ23 (Only available if APIC enabled)
9-6
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.1.12
BIOS_CNTL (LPC I/F—D31:F0)
Offset Address:
Default Value:
Lockable:
4E–4Fh
0000h
No
Bit
15:2
1
0
Attribute:
Size:
Power Well:
R/W
16-bit
Core
Description
Reserved.
BIOS Lock Enable (BLE)—R/W.
1 = Enables setting the BIOSWE bit to cause SMIs.
0 = Setting the BIOSWE will not cause SMIs. Once set, this bit can only be cleared by a
PCIRST#.
BIOS Write Enable (BIOSWE)—R/W.
1 = Access to the BIOS space is enabled for both read and write cycles. When this bit is written
from a 0 to a 1 and BIOS lock Enable (BLE) is also set, an SMI# is generated. This ensures
that only SMM code can update BIOS.
0 = Only read cycles result in FWH interface cycles.
9.1.13
TCO_CNTL—TCO Control (LPC I/F—D31:F0)
Offset Address:
Default Value:
Lockable:
54h
00h
No
Bit
7:4
3
Attribute:
Size:
Power Well:
R/W
8-bit
Core
Description
Reserved.
TCO Interrupt Enable (TCO_INT_EN)—R/W. This bit enables/disables the TCO interrupt.
1 = Enables TCO Interrupt, as selected by the TCO_INT_SEL field.
0 = Disables TCO interrupt.
TCO Interrupt Select (TCO_INT_SEL)—R/W. Specifies which IRQ the TCO internally appears. If
not using the APIC, the TCO interrupt must be routed to IRQ[9:11], and that interrupt is not
sharable with the SERIRQ stream, but is shareable with other PCI interrupts. If using the APIC, the
TCO interrupt can also be mapped to IRQ[20:23], and can be shared with other interrupt. Note that
if the TCOSCI_EN bit is set (bit 6 in the GPE0_EN register), then the TCO interrupt will be sent to
the same interrupt as the SCI, and the TCO_INT_SEL bits will have no meaning. When the TCO
interrupt is mapped to APIC interrupts 10 or 11, the signal is, in fact, active high. When the TCO
interrupt is mapped to IRQ[20, 21, or 22], the signal is active low and can be shared with PCI
interrupts that may be mapped to the same signals (IRQs).
2:0
000 = IRQ9
001 = IRQ10
010 = IRQ11
011 = Reserved
100 = IRQ20 (Only available if APIC enabled)
101 = IRQ21 (Only available if APIC enabled)
110 = IRQ22 (Only available if APIC enabled)
111 = IRQ23 (Only available if APIC enabled)
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-7
LPC Interface Bridge Registers (D31:F0)
9.1.14
GPIOBASE—GPIO Base Address (LPC I/F—D31:F0)
Offset Address:
Default Value:
Lockable:
58h–5Bh
00000001h
No
Attribute:
Size:
Power Well:
Bit
9.1.15
Description
31:16
Reserved.
15:6
Base Address—R/W. Provides the 64 bytes of I/O space for GPIO.
5:1
Reserved.
0
R/W
32-bit
Core
Resource Indicator—RO. Tied to 1 to indicate I/O space.
GPIO_CNTL—GPIO Control (LPC I/F—D31:F0)
Offset Address:
Default Value:
Lockable:
5Ch
00h
No
Attribute:
Size:
Power Well:
Bit
7:5
4
R/W
8-bit
Core
Description
Reserved.
GPIO Enable (GPIO_EN)—R/W. This bit enables/disables decode of the I/O range pointed to by
the GPIO base register and enables/disables the GPIO function.
1 = Enable
0 = Disable
3:0
9.1.16
Reserved.
PIRQ[n]_ROUT—PIRQ[A,B,C,D] Routing Control
(LPC I/F—D31:F0)
Offset Address:
Default Value:
Lockable:
PIRQA–60h, PIRQB–61h,
PIRQC–62h, PIRQD–63h
80h
No
Attribute:
R/W
Size:
Power Well:
8-bit
Core
Bit
Description
7
Interrupt Routing Enable (IRQEN)—R/W. Note that BIOS must program this bit to 0 during POST
for any of the PIRQs that are being used. The value of this bit may subsequently be changed by the
OS when setting up for I/O APIC interrupt delivery mode.
0 = The corresponding PIRQ is routed to one of the ISA-compatible interrupts specified in bits[3:0].
1 = The PIRQ is not routed to the 8259.
6:4
Reserved.
IRQ Routing—R/W. (ISA compatible)
3:0
9-8
0000 = Reserved
0001 = Reserved
0010 = Reserved
0011 = IRQ3
0100 = IRQ4
0101 = IRQ5
0110 = IRQ6
0111 = IRQ7
1000 = Reserved
1001 = IRQ9
1010 = IRQ10
1011 = IRQ11
1100 = IRQ12
1101 = Reserved
1110 = IRQ14
1111 = IRQ15
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.1.17
SERIRQ_CNTL—Serial IRQ Control (LPC I/F—D31:F0)
Offset Address:
Default Value:
Lockable:
64h
10h
No
Attribute:
Size:
Power Well:
Bit
7
R/W
8-bit
Core
Description
Serial IRQ Enable (SIRQEN)—R/W.
1 = Serial IRQs will be recognized. The SERIRQ pin will be configured as SERIRQ.
0 = The buffer is input only and internally SERIRQ will be a 1.
6
Serial IRQ Mode Select (SIRQMD)—R/W. For systems using Quiet Mode, this bit should be set to 1
(Continuous Mode) for at least one frame after coming out of reset before switching back to Quiet
Mode. Failure to do so will result in the ICH2 not recognizing SERIRQ interrupts.
1 = The serial IRQ machine will be in continuous mode.
0 = The serial IRQ machine will be in quiet mode.
5:2
Serial IRQ Frame Size (SIRQSZ)—R/W. Fixed field that indicates the size of the SERIRQ frame. In
the ICH2, this field needs to be programmed to 21 frames (0100). This is an offset from a base of 17
which is the smallest data frame size.
Start Frame Pulse Width (SFPW)—R/W. This is the number of PCI clocks that the SERIRQ pin will
be driven low by the serial IRQ machine to signal a start frame. In continuous mode, the ICH2 will
drive the start frame for the number of clocks specified. In quiet mode, the ICH2 will drive the start
frame for the number of clocks specified minus one, as the first clock was driven by the peripheral.
1:0
00 = 4 clocks
01 = 6 clocks
10 = 8 clocks
11 = Reserved
9.1.18
PIRQ[n]_ROUT—PIRQ[E,F,G,H] Routing Control
(LPC I/F—D31:F0)
Offset Address:
Default Value:
Lockable:
PIRQE–68h, PIRQF–69h,
PIRQG–6Ah, PIRQH–6Bh
80h
No
Attribute:
R/W
Size:
Power Well:
8-bit
Core
Bit
Description
7
Interrupt Routing Enable (IRQEN)—R/W. Note that BIOS must program this bit to 0 during POST
for any of the PIRQs that are being used. The value of this bit may subsequently be changed by the
OS when setting up for I/O APIC interrupt delivery mode.
0 = The corresponding PIRQ is routed to one of the ISA-compatible interrupts specified in bits[3:0].
1 = The PIRQ is not routed to the 8259.
6:4
Reserved.
IRQ Routing—R/W. (ISA compatible)
3:0
0000 = Reserved
1000 = Reserved
0001 = Reserved
1001 = IRQ9
0010 = Reserved
1010 = IRQ10
0011 = IRQ3
1011 = IRQ11
0100 = IRQ4
1100 = IRQ12
0101 = IRQ5
1101 = Reserved
0110 = IRQ6
1110 = IRQ14
0111 = IRQ7
1111 = IRQ15
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-9
LPC Interface Bridge Registers (D31:F0)
9.1.19
D31_ERR_CFG—Device 31 Error Configuration Register
(LPC I/F—D31:F0)
Offset Address:
Default Value:
Lockable:
.
88h
00h
No
Attribute:
Size:
Power Well:
R/W
8-bit
Core
This register configures the ICH2’s Device 31 responses to various system errors. The actual
assertion of SERR# is enabled via the PCI Command register
Bit
7:3
2
Description
Reserved.
SERR# on Received Target Abort Enable (SERR_RTA_EN)—R/W.
1 = The ICH2 will generate SERR# when SERR_RTA is set if SERR_EN is set.
0 = Disable. No SERR# assertion on Received Target Abort.
1
SERR# on Delayed Transaction Time-out Enable (SERR_DTT_EN)—R/W.
1 = The ICH2 will generate SERR# when SERR_DTT bit is set if SERR_EN is set.
0 = Disable. No SERR# assertion on Delayed Transaction Time-out.
0
9.1.20
Reserved
D31_ERR_STS—Device 31 Error Status Register
(LPC I/F—D31:F0)
Offset Address:
Default Value:
Lockable:
8Ah
00h
No
Attribute:
Size:
Power Well:
R/WC
8-bit
Core
This register configures the ICH2’s Device 31 responses to various system errors. The actual
assertion of SERR# is enabled via the PCI Command register.
Bit
7:3
2
Description
Reserved.
SERR# Due to Received Target Abort (SERR_RTA)—R/WC.
1 = The ICH2 sets this bit when it receives a target abort. If SERR_EN, the ICH2 will also generate
an SERR# when SERR_RTA is set.
0 = Software clears this bit by writing a 1 to the bit location.
1
SERR# Due to Delayed Transaction Time-out (SERR_DTT)—R/WC.
1 = When a PCI master does not return for the data within 1 ms of the cycle’s completion, the ICH2
clears the delayed transaction and sets this bit. If both SERR_DTT_EN and SERR_EN are set,
then ICH2 will also generate an SERR# when SERR_DTT is set.
0 = Software clears this bit by writing a 1 to the bit location.
0
9-10
Reserved.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.1.21
PCI_DMA_CFG—PCI DMA Configuration (LPC I/F—D31:F0)
Offset Address:
Default Value:
Lockable:
90h–91h
0000h
No
Bit
Attribute:
Size:
Power Well:
R/W
16-bit
Core
Description
Channel 7 Select—R/W.
00 = Reserved
15:14
01 = PC/PCI DMA
10 = Reserved
11 = LPC I/F DMA
13:12
11:10
9.1.22
Channel 6 Select—R/W. Same bit decode as for Channel 7
Channel 5 Select—R/W. Same bit decode as for Channel 7
9:8
Reserved.
7:6
Channel 3 Select—R/W. Same bit decode as for Channel 7
5:4
Channel 2 Select—R/W. Same bit decode as for Channel 7
3:2
Channel 1 Select—R/W. Same bit decode as for Channel 7
1:0
Channel 0 Select—R/W. Same bit decode as for Channel 7
GEN_CNTL—General Control Register (LPC I/F—D31:F0)
Offset Address:
Default Value:
Lockable:
D0h–D3h
00000000h
No
Bit
31:26
25
Attribute:
Size:
Power Well:
R/W
32-bit
Core
Description
Reserved.
REQ[5]#/GNT[5]# PC/PCI protocol select (PCPCIB_SEL)—R/W.
1 = When this bit is set to a 1, the PCI REQ[5]#/GNT[5]# signal pair will use the PC/PCI protocol as
REQ[B]#/GNT[B]. The corresponding bits in the GPIO_USE_SEL register must also be set to a
0. If the corresponding bits in the GPIO_USE_SEL register are set to a 1, the signals will be
used as a GPI and GPO.
0 = The REQ[5]#/GNT[5]# pins will function as a standard PCI REQ/GNT signal pair.
24
Hide ISA Bridge (HIDE_ISA)—R/W.
1 = Software sets this bit to 1 to disable configuration cycle from being claimed by a PCI-to-ISA
bridge. This prevents the operating system PCI PnP from getting confused by seeing two ISA
bridges. It is required for the ICH2 PCI address line AD22 to connect to the PCI-to-ISA bridge’s
IDSEL input. When this bit is 1, the ICH2 does not assert AD22 during configuration cycles to
the PCI-to-ISA bridge.
0 = The ICH2 does not prevent AD22 from asserting during configuration cycles to the PCI-to-ISA
bridge.
23:14
13
Reserved.
Coprocessor Error Enable (COPR_ERR_EN)—R/W.
1 = When FERR# is low, ICH2 generates IRQ13 internally and holds it until an I/O write to port F0h.
It will also drive IGNNE# active.
0 = FERR# will not generate IRQ13 nor IGNNE#.
12
Keyboard IRQ1 Latch Enable (IRQ1LEN)—R/W.
1 = The active edge of IRQ1 will be latched and held until a port 60h read.
0 = IRQ1 will bypass the latch.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-11
LPC Interface Bridge Registers (D31:F0)
Bit
11
Description
Mouse IRQ12 Latch Enable (IRQ12LEN)—R/W.
1 = The active edge of IRQ12 will be latched and held until a port 60h read.
0 = IRQ12 will bypass the latch.
10:9
81
Reserved
APIC Enable (APIC_EN)—R/W.
1 = Enables the internal I/O (x) APIC and its address decode.
0 = Disables internal I/O (x) APIC.
71
Enables I/O (x) Extension Enable (XAPIC_EN)—R/W. Note that this bit is only valid if the
AIPC_EN bit (bit 8) is also set to 1.
1 = Enables the extra features (beyond standard I/O APIC) associated with the I/O (x) APIC.
0 = The I/O (x) APIC extensions are not supported.
6
5:3
2
Alternate Access Mode Enable (ALTACC_EN)—R/W.
1 = Alternate Access Mode Enable
0 = Alternate Access Mode Disabled (default). Alternate Access Mode allows reads to otherwise
unreadable registers and writes otherwise unwriteable registers.
Reserved.
DMA Collection Buffer Enable (DCB_EN)—R/W.
1 = Enables DMA Collection Buffer (DCB) for LPC I/F and PC/PCI DMA.
0 = DCB disabled.
1
Delayed Transaction Enable (DTE)—R/W.
1 = ICH2 enables delayed transactions for internal register, FWH, and LPC interface accesses.
0 = Delayed transactions disabled.
Positive Decode Enable (POS_DEC_EN)—R/W.
1 = Enables ICH2 to only perform positive decode on the PCI bus.
0
0 = The ICH2 performs subtractive decode on the PCI bus and forward the cycles to LPC interface
if not to an internal register or other known target on the LPC interface. Accesses to internal
registers and to known LPC interface devices are still be positively decoded.
NOTES:
1. Rule 1: If bit 8 is 0, the ICH2 does not decode any of the registers associated with the I/O APIC or I/O (x)
APIC. The state of bit 7 is a “Don’t Care” in this case.
Rule 2: If bit 8 is 1 and bit 7 is 0, the ICH2 decodes the memory space associated with the I/O APIC, but not
the extra registers associated with the I/O (x) APIC.
Rule 3: If bit 8 is 1 and bit 7 is 1, the ICH2 decodes the memory space associated with both the I/O APIC and
the I/O (x) APIC. This also enables PCI masters to write directly to the register to cause interrupts (PCI
Message Interrupt).
Note that there is no separate way to disable PCI Message Interrupts if the I/O (x) APIC is enabled. This is
not considered necessary.
9-12
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.1.23
GEN_STS—General Status (LPC I/F—D31:F0)
Offset Address:
Default Value:
Lockable:
D4h–D7h
00000F0Xh
No
Bit
31:14
13
Attribute:
Size:
Power Well:
R/W
32-bit
Core(0:7), RTC (8:15)
Description
Reserved.
TOP_SWAP—R/W.
1 = ICH2 will invert A16 for cycles targeting FWH BIOS space (Does not affect accesses to FWH
feature space).
0 = ICH2 will not invert A16. This bit is cleared by RTCRST# assertion, but not by any other type of
reset.
12
CPU BIST Enable (CPU_BIST_EN)—R/W. This bit is in the Resume Well and is reset by
RSMRST# (not in the RTC Well and not reset by RTEST#).
1 = The INIT# signal is driven active when CPURST# is active. INIT# goes inactive with the same
timings as the other processor interface signals (Hold Time after CPURST# inactive). Note that
CPURST# is generated by the memory controller hub; however, the ICH2 has a hub interface
special cycle that allows the ICH2 to control the assertion/deassertion of CPURST#.
0 = Disable.
11:8
Processor Frequency Strap (FREQ_STRAP[3:0])—R/W. These bits determine the internal
frequency multiplier of the processor. These bits can be reset to 1111 based on an external pin strap
or via the RTCRST# input signal. Software must program this field based on the processor’s
specified frequency. These bits are in the RTC well.
This field is only writeable when SAFE_MODE (bit 2) is cleared to 0. SAFE_MODE is only cleared
by a PWROK rising edge.
7:3
2
Reserved
SAFE_MODE—RO.
1 = ICH2 sampled AC_SDOUT high on the rising edge of PWROK. ICH2 will force
FREQ_STRAP[3:0] bits to all 1s (safe mode multiplier).
0 = ICH2 sampled AC_SDOUT low on the rising edge of PWROK.
1
NO_REBOOT—R/W (special).
1 = ICH2 will disable the TCO Timer system reboot feature. This bit is set either by hardware when
SPKR is sampled low on the rising edge of PWROK or by software writing a 1 to the bit.
0 = Normal TCO Timer reboot functionality (reboot after 2nd TCO time-out).
Note that this bit cannot be cleared while an external jumper is in place on the SPKR signal.
0
Reserved.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-13
LPC Interface Bridge Registers (D31:F0)
9.1.24
RTC_CONF—RTC Configuration Register (LPC I/F—D31:F0)
Offset Address:
Default Value:
Lockable:
D8h
00h
Yes
Bit
7:5
4
Attribute:
Size:
Power Well:
R/W
8-bit
Core
Description
Reserved.
Upper 128-byte Lock (U128LOCK)—R/W (special).
1 = Lock reads and writes to bytes 38h–3Fh in the upper 128 byte bank of the RTC CMOS RAM.
Write cycles to this range will have no effect and read cycles will not return any particular
guaranteed value. This is a write once register that can only be reset by a hardware reset.
0 = Access to these bytes in the upper CMOS RAM range have not been locked.
3
Lower 128-byte Lock (L128LOCK)—R/W (special).
1 = Locks reads and writes to bytes 38h–3Fh in the lower 128 byte bank of the RTC CMOS RAM.
Write cycles to this range will have no effect and read cycles will not return any particular
guaranteed value. This is a write once register that can only be reset by a hardware reset.
0 = Access to these bytes in the lower CMOS RAM range have not been locked.
2
Upper 128-byte Enable (U128E)—R/W.
1 = Enables access to the upper 128 byte bank of RTC CMOS RAM.
0 = Disable.
1:0
9.1.25
Reserved.
COM_DEC—LPC I/F Communication Port Decode Ranges
(LPC I/F—D31:F0)
Offset Address:
Default Value:
Lockable:
E0h
00h
No
Bit
7
Attribute:
Size:
Power Well:
R/W
8-bit
Core
Description
Reserved
COMB Decode Range—R/W. This field determines which range to decode for the COMB Port.
6:4
3
000 = 3F8h–3FFh (COM1)
001 = 2F8h–2FFh (COM2)
010 = 220h–227h
011 = 228h–22Fh
100 = 238h–23Fh
101 = 2E8h–2EFh (COM4)
110 = 338h–33Fh
111 = 3E8h–3EFh (COM3)
Reserved
COMA Decode Range—R/W. This field determines which range to decode for the COMA Port.
2:0
9-14
000 = 3F8h–3FFh (COM1)
001 = 2F8h–2FFh (COM2)
010 = 220h–227h
011 = 228h–22Fh
100 = 238h–23Fh
101 = 2E8h–2EFh (COM4)
110 = 338h–33Fh
111 = 3E8h–3EFh (COM3)
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.1.26
FDD/LPT_DEC—LPC I/F FDD & LPT Decode Ranges
(LPC I/F—D31:F0)
Offset Address:
Default Value:
Lockable:
E1h
00h
No
Bit
7:5
Attribute:
Size:
Power Well:
R/W
8-bit
Core
Description
Reserved
FDD Decode Range—R/W. Determines which range to decode for the FDD Port
4
3:2
0 = 3F0h–3F5h, 3F7h (Primary)
1 = 370h–2FFh (Secondary)
Reserved
LPT Decode Range—R/W. This field determines which range to decode for the LPT Port.
00 = 378h–37Fh and 778h–77Fh
1:0
01 = 278h–27Fh (port 279h is read only) and 678h–67Fh
10 = 3BCh–3BEh and 7BCh–7BEh
11 = Reserved
9.1.27
SND_DEC—LPC I/F Sound Decode Ranges
(LPC I/F—D31:F0)
Offset Address:
Default Value:
Lockable:
E2h
00h
No
Bit
7:6
Attribute:
Size:
Power Well:
R/W
8-bit
Core
Description
Reserved
MSS Decode Range—R/W. This field determines which range to decode for the Microsoft* Sound
System (MSS).
00 = 530h–537h
5:4
01 = 604h–60Bh
10 = E80h–E87h
11 = F40h–F47h
MIDI Decode Range—R/W. This bit determines which range to decode for the Midi Port.
3
0 = 330h–331h
1 = 300h–301h
2
Reserved
SB16 Decode Range—R/W. This field determines which range to decode for the Sound Blaster 16
(SB16) Port.
00 = 220h–233h
1:0
01 = 240h–253h
10 = 260h–273h
11 = 280h–293h
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-15
LPC Interface Bridge Registers (D31:F0)
9.1.28
FWH_DEC_EN1—FWH Decode Enable 1 Register
(LPC I/F—D31:F0)
Offset Address:
Default Value:
E3h
FFh
Attribute:
Size:
R/W
8 bits
This register determines which memory ranges will be decoded on the PCI bus and forwarded to
the FWH. The ICH2 will subtractively decode cycles on PCI unless POS_DEC_EN is set to 1.
Bit
7
Description
FWH Address Range Enable (FWH_F8_EN)—RO. Enables decoding two 512 KB FWH memory
ranges and one 128 KB memory range.
1 = Enable the following ranges for the FWH
FFF80000h–FFFFFFFFh
FFB80000h–FFBFFFFFh
000E0000h–000FFFFFh
FWH Address Range Enable (FWH_F0_EN)—R/W. Enables decoding two 512 KB FWH memory
ranges.
6
0 = Disable.
1 = Enable the following ranges for the FWH:
FFF00000h–FFF7FFFFh
FFB00000h–FFB7FFFFh
FWH Address Range Enable (FWH_E8_EN)—R/W. Enables decoding two 512 KB FWH memory
ranges.
5
0 = Disable.
1 = Enable the following ranges for the FWH:
FFE80000h–FFEFFFFh
FFA80000h–FFAFFFFFh
FWH Address Range Enable (FWH_E0_EN)—R/W. Enables decoding two 512 KB FWH memory
ranges.
4
0 = Disable.
1 = Enable the following ranges for the FWH:
FFE00000h–FFE7FFFFh
FFA00000h–FFA7FFFFh
FWH Address Range Enable (FWH_D8_EN)—R/W. Enables decoding two 512 KB FWH memory
ranges.
3
0 = Disable.
1 = Enable the following ranges for the FWH
FFD80000h–FFDFFFFFh
FF980000h–FF9FFFFFh
FWH Address Range Enable (FWH_D0_EN)—R/W. Enables decoding two 512 KB FWH memory
ranges.
2
0 = Disable.
1 = Enable the following ranges for the FWH
FFD00000h–FFD7FFFFh
FF900000h–FF97FFFFh
FWH Address Range Enable (FWH_C8_EN)—R/W. Enables decoding two 512 KB FWH memory
ranges.
1
0 = Disable.
1 = Enable the following ranges for the FWH
FFC80000h–FFCFFFFFh
FF880000h–FF8FFFFFh
FWH Address Range Enable (FWH_C0_EN)—R/W. Enables decoding two 512 KB FWH memory
ranges.
0
9-16
0 = Disable.
1 = Enable the following ranges for the FWH
FFC00000h–FFC7FFFFh
FF800000h–FF87FFFFh
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.1.29
GEN1_DEC—LPC I/F Generic Decode Range 1
(LPC I/F—D31:F0)
Offset Address:
Default Value:
Lockable:
E4h–E5h
00h
Yes
Bit
15:7
6:1
Attribute:
Size:
Power Well:
R/W
16-bit
Core
Description
Generic I/O Decode Range 1 Base Address (GEN1_BASE)—R/W. This address is aligned on a
128-byte boundary, and must have address lines 31:16 as 0.
Note that this generic decode is for I/O addresses only, not memory addresses. The size of this
range is 128 bytes.
Reserved.
Generic Decode Range 1 Enable (GEN1_EN)—R/W.
0
9.1.30
0 = Disable.
1 = Enable the GEN1 I/O range to be forwarded to the LPC I/F
LPC_EN—LPC I/F Enables (LPC I/F—D31:F0)
Offset Address:
Default Value:
Lockable:
E6h–E7h
00h
Yes
Bit
15:14
Attribute:
Size:
Power Well:
R/W
16-bit
Core
Description
Reserved
Microcontroller Address Range Enable (CNF2_LPC_EN)—R/W.
13
0 = Disable.
1 = Enables the decoding of the I/O locations 4Eh and 4Fh to the LPC interface. This range is used
for a microcontroller.
Super I/O Address Range Enable (CNF1_LPC_EN)—R/W.
12
0 = Disable.
1 = Enables the decoding of the I/O locations 2Eh and 2Fh to the LPC interface. This range is used
for Super I/O devices.
Microcontroller Address Range Enable (MC_LPC_EN)—R/W.
11
0 = Disable.
1 = Enables the decoding of the I/O locations 62h and 66h to the LPC interface. This range is used
for a microcontroller.
Microcontroller Address Range Enable (KBC_LPC_EN)—R/W.
10
0 = Disable.
1 = Enables the decoding of the I/O locations 60h and 64h to the LPC interface. This range is used
for a microcontroller.
Game Port Address Range Enable (GAMEH_LPC_EN)—R/W.
9
0 = Disable.
1 = Enables the decoding of the I/O locations 208h to 20Fh to the LPC interface. This range is
used for a gameport.
Game Port Address Range Enable (GAMEL_LPC_EN)—R/W.
8
0 = Disable.
1 = Enables the decoding of the I/O locations 200h to 207h to the LPC interface. This range is
used for a gameport.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-17
LPC Interface Bridge Registers (D31:F0)
Bit
Description
ADLIB Address Range Enable (ADLIB_LPC_EN)—R/W.
7
0 = Disable.
1 = Enables the decoding of the I/O locations 388h–38Bh to the LPC interface.
MSS Address Range Enable (MSS_LPC_EN)—R/W.
6
0 = Disable.
1 = Enables the decoding of the MSS range to the LPC interface. This range is selected in the
LPC_Sound Decode Range Register.
MIDI Address Range Enable (MIDI_LPC_EN)—R/W.
5
0 = Disable.
1 = Enables the decoding of the MIDI range to the LPC interface. This range is selected in the
LPC_Sound Decode Range Register.
Sound Blaster Address Range Enable (SB16_LPC_EN)—R/W.
4
0 = Disable.
1 = Enables the decoding of the SB16 range to the LPC interface. This range is selected in the
LPC_Sound Decode Range Register.
FDD Address Range Enable (FDD_LPC_EN)—R/W.
3
0 = Disable.
1 = Enables the decoding of the FDD range to the LPC interface. This range is selected in the
LPC_FDD/LPT Decode Range Register.
LPT Address Range Enable (LPT_LPC_EN)—R/W.
2
0 = Disable.
1 = Enables the decoding of the LPT range to the LPC interface. This range is selected in the
LPC_FDD/LPT Decode Range Register.
COM B Address Range Enable (COMB_LPC_EN)—R/W.
1
0 = Disable.
1 = Enables the decoding of the COMB range to the LPC interface. This range is selected in the
LPC_COM Decode Range Register.
Com A Address Range Enable (COMA_LPC_EN)—R/W.
0
9-18
0 = Disable.
1 = Enables the decoding of the COMA range to the LPC interface. This range is selected in the
LPC_COM Decode Range Register.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.1.31
FWH_SEL1—FWH Select 1 Register (LPC I/F—D31:F0)
Offset Address:
Default Value:
E8h
00112233h
Attribute:
Size:
R/W
32 bits
Bit
Description
31:28
FWH Address Range Select (FWH_F8_IDSEL)—RO. IDSEL for two 512 KB FWH memory ranges
and one 128KB memory range. This field is fixed at 0000. The IDSEL in this field addresses the
following memory ranges:
FFF8 0000h–FFFF FFFFh
FFB8 0000h–FFBF FFFFh
000E 0000h–000F FFFFh
27:24
FWH Address Range Select (FWH_F0_IDSEL)—R/W. IDSEL for two 512 KB FWH memory
ranges. The IDSEL programmed in this field addresses the following memory ranges:
FFF0 0000h–FFF7 FFFFh
FFB0 0000h–FFB7 FFFFh
23:20
FWH Address Range Select (FWH_E8_IDSEL)—R/W. IDSEL for two 512 KB FWH memory
ranges. The IDSEL programmed in this field addresses the following memory ranges:
FFE8 0000h–FFEF FFFFh
FFA8 0000h–FFAF FFFFh
19:16
FWH Address Range Select (FWH_E0_IDSEL)—R/W. IDSEL for two 512 KB FWH memory
ranges. The IDSEL programmed in this field addresses the following memory ranges:
FFE0 0000h–FFE7 FFFFh
FFA0 0000h–FFA7 FFFFh
15:12
FWH Address Range Select (FWH_D8_IDSEL)—R/W. IDSEL for two 512 KB FWH memory
ranges. The IDSEL programmed in this field addresses the following memory ranges:
FFD8 0000h–FFDF FFFFh
FF98 0000h–FF9F FFFFh
11:8
FWH Address Range Select (FWH_D0_IDSEL)—R/W. IDSEL for two 512 KB FWH memory
ranges. The IDSEL programmed in this field addresses the following memory ranges:
FFD0 0000h–FFD7 FFFFh
FF90 0000h–FF97 FFFFh
7:4
FWH Address Range Select (FWH_C8_IDSEL)—R/W. IDSEL for two 512 KB FWH memory
ranges. The IDSEL programmed in this field addresses the following memory ranges:
FFC8 0000h–FFCF FFFFh
FF88 0000h–FF8F FFFFh
3:0
FWH Address Range Select (FWH_C0_IDSEL)—R/W. IDSEL for two 512 KB FWH memory
ranges. The IDSEL programmed in this field addresses the following memory ranges:
FFC0 0000h–FFC7 FFFFh
FF80 0000h–FF87 FFFFh
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-19
LPC Interface Bridge Registers (D31:F0)
9.1.32
GEN2_DEC—LPC I/F Generic Decode Range 2
(LPC I/F—D31:F0)
Offset Address:
Default Value:
Lockable:
ECh–EDh
00h
Yes
Bit
15:4
3:1
Attribute:
Size:
Power Well:
R/W
16-bit
Core
Description
Generic I/O Decode Range 2 Base Address (GEN2_BASE)—R/W. This address is aligned on a
64-byte boundary and must have address lines 31:16 as 0.
Note that this generic decode is for I/O addresses only; not memory addresses. The size of this
range is 16 bytes.
Reserved. Read as 0
Generic I/O Decode Range 2 Enable (GEN2_EN)—R/W.
0
9.1.33
0 = Disable.
1 = Accesses to the GEN2 I/O range will be forwarded to the LPC interface.
FWH_SEL2—FWH Select 2 Register (LPC I/F—D31:F0)
Offset Address:
Default Value:
9-20
EEh–EFh
4567h
Attribute:
Size:
R/W
32 bits
Bit
Description
15:12
FWH Address Range Select (FWH_70_IDSEL)—R/W. IDSEL for two 1 MB FWH memory ranges.
The IDSEL programmed in this field addresses the following memory ranges:
FF70 0000h–FF7F FFFFh
FF30 0000h–FF3F FFFFh
11:8
FWH Address Range Select (FWH_60_IDSEL)—R/W. IDSEL for two 1 MB FWH memory ranges.
The IDSEL programmed in this field addresses the following memory ranges:
FF60 0000h–FF6F FFFFh
FF20 0000h–FF2F FFFFh
7:4
FWH Address Range Select (FWH_50_IDSEL)—R/W. IDSEL for two 1 MB FWH memory ranges.
The IDSEL programmed in this field addresses the following memory ranges:
FF50 0000h–FF5F FFFFh
FF10 0000h–FF1F FFFFh
3:0
FWH Address Range Select (FWH_40_IDSEL)—R/W. IDSEL for two 1 MB FWH memory ranges.
The IDSEL programmed in this field addresses the following memory ranges:
FF40 0000h–FF4F FFFFh
FF00 0000h–FF0F FFFFh
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.1.34
FWH_DEC_EN2—FWH Decode Enable 2 Register
(LPC I/F—D31:F0)
Offset Address:
Default Value:
F0h
0Fh
Attribute:
Size:
R/W
8 bits
This register determines which memory ranges are decoded on the PCI bus and forwarded to the
FWH. The ICH2 subtractively decodes cycles on PCI unless POS_DEC_EN is set to 1.
Bit
7:4
Description
Reserved.
FWH Address Range Enable (FWH_70_EN)—R/W. Enables decoding two 1 MB FWH memory
ranges.
3
0 = Disable.
1 = Enable the following ranges for the FWH
FF70 0000h–FF7F FFFFh
FF30 0000h–FF3F FFFFh
FWH Address Range Enable (FWH_60_EN)—R/W. Enables decoding two 1 MB FWH memory
ranges.
2
0 = Disable.
1 = Enable the following ranges for the FWH
FF60 0000h–FF6F FFFFh
FF20 0000h–FF2F FFFFh
FWH Address Range Enable (FWH_50_EN)—R/W. Enables decoding two 1 MB FWH memory
ranges.
1
0 = Disable.
1 = Enable the following ranges for the FWH
FF50 0000h–FF5F FFFFh
FF10 0000h–FF1F FFFFh
FWH Address Range Enable (FWH_40_EN)—R/W. Enables decoding two 1 MB FWH memory
ranges.
0
0 = Disable.
1 = Enable the following ranges for the FWH
FF40 0000h–FF4F FFFFh
FF00 0000h–FF0F FFFFh
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-21
LPC Interface Bridge Registers (D31:F0)
9.1.35
FUNC_DIS—Function Disable Register (LPC I/F—D31:F0)
Offset Address:
Default Value:
Lockable:
F2h
00h
No
Bit
15:9
Attribute:
Size:
Power Well:
R/W
16-bit
Core
Description
Reserved
SMBus For BIOS (SMB_FOR_BIOS)—R/W. This bit is used in conjunction with bit 3 in this
register.
8
0 = No effect.
1 = Allows the SMBus I/O space to be accessible by software when bit 3 in this register is set. The
PCI configuration space is hidden in this case. Note that if bit 3 is set alone, the decode of both
SMBus PCI configuration and I/O space will be disabled.
7
Reserved
6
AC’97 Modem Disable (F6_Disable)—R/W. Software sets this bit to disable the AC’97 modem
controller function. BIOS must not enable I/O or memory address space decode, interrupt
generation or any other functionality for functions that are to be disabled.
0 = AC’97 Modem is enabled
1 = AC’97 Modem is disabled
5
AC’97 Audio Controller Disable (F5_Disable)—R/W. Software sets this bit to disable the AC’97
audio controller function. BIOS must not enable I/O or memory address space decode, interrupt
generation or any other functionality for functions that are to be disabled.
0 = AC’97 audio controller is enabled
1 = AC’97 audio controller is disabled
4
USB Controller 2 Disable (F4_Disable)—R/W. Software sets this bit to disable the USB Controller
#2 function. BIOS must not enable I/O or memory address space decode, interrupt generation or
any other functionality for functions that are to be disabled.
0 = USB Controller #2 is enabled
1 = USB Controller #2 is disabled
3
SMBus Controller Disable (F3_Disable)—R/W. Software sets this bit to disable the SMBus Host
Controller function. BIOS must not enable I/O or memory address space decode, interrupt
generation or any other functionality for functions that are to be disabled.
0 = SMBus controller is enabled
1 = SMBus controller is disabled
2
USB Controller 1 Disable (F2_Disable)—R/W. Software sets this bit to disable the USB Controller
#1 function. BIOS must not enable I/O or memory address space decode, interrupt generation or
any other functionality for functions that are to be disabled.
0 = USB Controller #1 is enabled
1 = USB Controller #1 is disabled
1
IDE Controller Disable (F1_Disable)—R/W. Software sets this bit to disable the IDE controller
function. BIOS must not enable I/O or memory address space decode, interrupt generation or any
other functionality for functions that are to be disabled.
0 = IDE controller is enabled
1 = IDE controller is disabled
0
9-22
Reserved.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.2
DMA I/O Registers
Table 9-2. DMA Registers
Port
Alias
00h
10h
Register Name/Function
Default
Type
Channel 0 DMA Base & Current Address Register
Undefined
R/W
01h
11h
Channel 0 DMA Base & Current Count Register
Undefined
R/W
02h
12h
Channel 1 DMA Base & Current Address Register
Undefined
R/W
03h
13h
Channel 1 DMA Base & Current Count Register
Undefined
R/W
04h
14h
Channel 2 DMA Base & Current Address Register
Undefined
R/W
05h
15h
Channel 2 DMA Base & Current Count Register
Undefined
R/W
06h
16h
Channel 3 DMA Base & Current Address Register
Undefined
R/W
07h
17h
Channel 3 DMA Base & Current Count Register
Undefined
R/W
Channel 0–3 DMA Command Register
Undefined
WO
08h
18h
Undefined
RO
0Ah
1Ah
Channel 0–3 DMA Write Single Mask Register
000001XXb
WO
0Bh
1Bh
Channel 0–3 DMA Channel Mode Register
000000XXb
WO
0Ch
1Ch
Channel 0–3 DMA Clear Byte Pointer Register
Undefined
WO
0Dh
1Dh
Channel 0–3 DMA Master Clear Register
Undefined
WO
0Eh
1Eh
Channel 0–3 DMA Clear Mask Register
Undefined
WO
0Fh
1Fh
Channel 0–3 DMA Write All Mask Register
0Fh
R/W
80h
90h
Reserved Page Register
Undefined
R/W
81h
91h
Channel 2 DMA Memory Low Page Register
Undefined
R/W
82h
–
Channel 3 DMA Memory Low Page Register
Undefined
R/W
83h
93h
Channel 1 DMA Memory Low Page Register
Undefined
R/W
84h–86h
94h–96h
Reserved Page Registers
Undefined
R/W
87h
97h
Channel 0 DMA Memory Low Page Register
Undefined
R/W
88h
98h
Reserved Page Register
Undefined
R/W
89h
99h
Channel 6 DMA Memory Low Page Register
Undefined
R/W
8Ah
9Ah
Channel 7 DMA Memory Low Page Register
Undefined
R/W
Channel 0–3 DMA Status Register
8Bh
9Bh
8Ch–8Eh
9Ch–9Eh
Channel 5 DMA Memory Low Page Register
Undefined
R/W
Reserved Page Registers
Undefined
R/W
8Fh
9Fh
Refresh Low Page Register
Undefined
R/W
C0h
C1h
Channel 4 DMA Base & Current Address Register
Undefined
R/W
C2h
C3h
Channel 4 DMA Base & Current Count Register
Undefined
R/W
C4h
C5h
Channel 5 DMA Base & Current Address Register
Undefined
R/W
C6h
C7h
Channel 5 DMA Base & Current Count Register
Undefined
R/W
C8h
C9h
Channel 6 DMA Base & Current Address Register
Undefined
R/W
CAh
CBh
Channel 6 DMA Base & Current Count Register
Undefined
R/W
CCh
CDh
Channel 7 DMA Base & Current Address Register
Undefined
R/W
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-23
LPC Interface Bridge Registers (D31:F0)
Table 9-2. DMA Registers (Continued)
Port
Alias
Register Name/Function
Default
Type
CEh
CFh
Channel 7 DMA Base & Current Count Register
Undefined
R/W
D0h
D1h
Channel 4–7 DMA Command Register
Undefined
WO
Undefined
RO
D4h
D5h
Channel 4–7 DMA Write Single Mask Register
000001XXb
WO
D6h
D7h
Channel 4–7 DMA Channel Mode Register
000000XXb
WO
D8h
D9h
Channel 4–7 DMA Clear Byte Pointer Register
Undefined
WO
Channel 4–7 DMA Status Register
9.2.1
DAh
DBh
Channel 4–7 DMA Master Clear Register
Undefined
WO
DCh
DDh
Channel 4–7 DMA Clear Mask Register
Undefined
WO
DEh
DFh
Channel 4–7 DMA Write All Mask Register
0Fh
R/W
DMABASE_CA—DMA Base and Current Address Registers
I/O Address:
Default Value:
Lockable:
Bit
Ch. #0 = 00h; Ch. #1 = 02h
Ch. #2 = 04h; Ch. #3 = 06h
Ch. #5 = C4h Ch. #6 = C8h
Ch. #7 = CCh;
Undef
No
Attribute:
Size:
RO
16-bit (per channel),
but accessed in two 8-bit
quantities
Power Well:
Core
Description
Base and Current Address—R/W. This register determines the address for the transfers to be
performed. The address specified points to two separate registers. On writes, the value is stored in
the Base Address register and copied to the Current Address register. On reads, the value is returned
from the Current Address register.
15:0
The address increments/decrements in the Current Address register after each transfer, depending
on the mode of the transfer. If the channel is in auto-initialize mode, the Current Address register will
be reloaded from the Base Address register after a terminal count is generated.
For transfers to/from a 16-bit slave (channels 5–7), the address is shifted left one bit location. Bit 15
will be shifted out. Therefore, if bit 15 was a 1, it will be lost.
The register is accessed in 8 bit quantities. The byte is pointed to by the current byte pointer flip/flop.
Before accessing an address register, the byte pointer flip/flop should be cleared to ensure that the
low byte is accessed first.
9-24
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.2.2
DMABASE_CC—DMA Base and Current Count Registers
I/O Address:
Default Value:
Lockable:
Ch. #0 = 01h; Ch. #1 = 03h
Ch. #2 = 05h; Ch. #3 = 07h
Ch. #5 = C6h; Ch. #6 = CAh
Ch. #7 = CEh;
Undefined
No
Bit
Attribute:
Size:
R/W
16-bit (per channel),
but accessed in two 8-bit
quantities
Power Well:
Core
Description
Base and Current Count—R/W. This register determines the number of transfers to be performed.
The address specified points to two separate registers. On writes the value is stored in the Base
Count register and copied to the Current Count register. On reads the value is returned from the
Current Count register.
15:0
The actual number of transfers is one more than the number programmed in the Base Count Register
(i.e., programming a count of 4h results in 5 transfers). The count is decrements in the Current Count
register after each transfer. When the value in the register rolls from zero to FFFFh, a terminal count
is generated. If the channel is in auto-initialize mode, the Current Count register will be reloaded from
the Base Count register after a terminal count is generated.
For transfers to/from an 8-bit slave (channels 0–3), the count register indicates the number of bytes to
be transferred. For transfers to/from a 16-bit slave (channels 5–7), the count register indicates the
number of words to be transferred.
The register is accessed in 8 bit quantities. The byte is pointed to by the current byte pointer flip/flop.
Before accessing a count register, the byte pointer flip/flop should be cleared to ensure that the low
byte is accessed first.
9.2.3
DMAMEM_LP—DMA Memory Low Page Registers
I/O Address:
Default Value:
Lockable:
Ch. #0 = 87h; Ch. #1 = 83h
Ch. #2 = 81h; Ch. #3 = 82h
Ch. #5 = 8Bh; Ch. #6 = 89h
Ch. #7 = 8Ah;
Undefined
No
Attribute:
Size:
Power Well:
R/W
8-bit
Core
Bit
Description
7:0
DMA Low Page (ISA Address bits [23:16])—R/W. This register works in conjunction with the DMA
controller's Current Address Register to define the complete 24-bit address for the DMA channel.
This register remains static throughout the DMA transfer.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-25
LPC Interface Bridge Registers (D31:F0)
9.2.4
DMACMD—DMA Command Register
I/O Address:
Default Value:
Lockable:
Ch. #0–3 = 08h;
Ch. #4–7 = D0h
Undefined
No
Bit
7:5
4
3
Attribute:
Size:
Power Well:
WO
8-bit
Core
Description
Reserved. Must be 0.
DMA Group Arbitration Priority—WO. Each channel group is individually assigned either fixed or
rotating arbitration priority. At part reset, each group is initialized in fixed priority.
0 = Fixed priority to the channel group
1 = Rotating priority to the group.
Reserved. Must be 0
DMA Channel Group Enable—WO. Both channel groups are enabled following part reset.
2
1:0
9.2.5
0 = Enable the DMA channel group.
1 = Disable. Disabling channel group 4–7 also disables channel group 0–3, which is cascaded
through channel 4.
Reserved. Must be 0.
DMASTS—DMA Status Register
I/O Address:
Default Value:
Lockable:
Ch. #0–3 = 08h;
Ch. #4–7 = D0h
Undefined
No
Bit
7:4
Attribute:
Size:
Power Well:
RO
8-bit
Core
Description
Channel Request Status—RO. When a valid DMA request is pending for a channel, the
corresponding bit is set to 1. When a DMA request is not pending for a particular channel, the
corresponding bit is set to 0. The source of the DREQ may be hardware or a software request. Note
that channel 4 is the cascade channel, so the request status of channel 4 is a logical OR of the
request status for channels 0 through 3.
4 = Channel 0
5 = Channel 1 (5)
6 = Channel 2 (6)
7 = Channel 3 (7)
Channel Terminal Count Status—RO. When a channel reaches terminal count (TC), its status bit is
set to 1. If TC has not been reached, the status bit is set to 0. Channel 4 is programmed for cascade,
so the TC bit response for channel 4 is irrelevant.
3:0
0 = Channel 0
1 = Channel 1 (5)
2 = Channel 2 (6)
3 = Channel 3 (7)
9-26
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.2.6
DMA_WRSMSK—DMA Write Single Mask Register
I/O Address:
Default Value:
Lockable:
Ch. #0–3 = 0Ah;
Ch. #4–7 = D4h
0000 01xx
No
Bit
7:3
Attribute:
Size:
Power Well:
WO
8-bit
Core
Description
Reserved. Must be 0.
Channel Mask Select—WO.
2
0 = Enable DREQ for the selected channel. The channel is selected through bits [1:0]. Therefore,
only one channel can be masked / unmasked at a time.
1 = Disable DREQ for the selected channel.
DMA Channel Select—WO. These bits select the DMA Channel Mode Register to program.
00 = Channel 0 (4)
1:0
01 = Channel 1 (5)
10 = Channel 2 (6)
11 = Channel 3 (7)
9.2.7
DMACH_MODE—DMA Channel Mode Register
I/O Address:
Default Value:
Lockable:
Ch. #0–3 = 0Bh;
Ch. #4–7 = D6h
0000 00xx
No
Attribute:
Size:
Power Well:
WO
8-bit
Core
Bit
Description
7:6
DMA Transfer Mode—WO. Each DMA channel can be programmed in one of four different modes:
00 = Demand mode
01 = Single mode
10 = Reserved
11 = Cascade mode
5
Address Increment/Decrement Select—WO. This bit controls address increment/decrement during
DMA transfers.
0 = Address increment. (default after part reset or Master Clear)
1 = Address decrement.
Autoinitialize Enable—WO.
4
0 = Autoinitialize feature is disabled and DMA transfers terminate on a terminal count. A part reset or
Master Clear disables autoinitialization.
1 = DMA restores the Base Address and Count registers to the current registers following a terminal
count (TC).
DMA Transfer Type—WO. These bits represent the direction of the DMA transfer. When the channel
is programmed for cascade mode, (bits[7:6] = “11”) the transfer type is irrelevant.
3:2
00 = Verify - No I/O or memory strobes generated
01 = Write - Data transferred from the I/O devices to memory
10 = Read - Data transferred from memory to the I/O device
11 = Illegal
DMA Channel Select—WO. These bits select the DMA Channel Mode Register that will be written
by bits [7:2].
1:0
00 = Channel 0 (4)
01 = Channel 1 (5)
10 = Channel 2 (6)
11 = Channel 3 (7)
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-27
LPC Interface Bridge Registers (D31:F0)
9.2.8
DMA Clear Byte Pointer Register
I/O Address:
Default Value:
Lockable:
9.2.9
WO
8-bit
Core
Description
7:0
Clear Byte Pointer—WO. No specific pattern. Command enabled with a write to the I/O port address.
Writing to this register initializes the byte pointer flip/flop to a known state. It clears the internal latch
used to address the upper or lower byte of the 16-bit Address and Word Count Registers. The latch is
also cleared by part reset and by the Master Clear command. This command precedes the first
access to a 16-bit DMA controller register. The first access to a 16 bit register will then access the
significant byte, and the second access automatically accesses the most significant byte.
DMA Master Clear Register
Default Value:
Ch. #0–3 = 0Dh;
Ch. #4–7 = DAh
xxxx xxxx
Attribute:
Size:
WO
8-bit
Bit
Description
7:0
Master Clear—WO. No specific pattern. Enabled with a write to the port. This has the same effect as
the hardware Reset. The Command, Status, Request, and Byte Pointer flip/flop registers are cleared
and the Mask Register is set.
DMA_CLMSK—DMA Clear Mask Register
I/O Address:
Default Value:
Lockable:
Bit
7:0
9-28
Attribute:
Size:
Power Well:
Bit
I/O Address:
9.2.10
Ch. #0–3 = 0Ch;
Ch. #4–7 = D8h
xxxx xxxx
No
Ch. #0–3 = 0Eh;
Ch. #4–7 = DCh
xxxx xxxx
No
Attribute:
Size:
Power Well:
WO
8-bit
Core
Description
Clear Mask Register—WO. No specific pattern. Command enabled with a write to the port.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.2.11
DMA_WRMSK—DMA Write All Mask Register
I/O Address:
Default Value:
Lockable:
Ch. #0–3 = 0Fh;
Ch. #4–7 = DEh
0000 1111
No
Bit
7:4
Attribute:
Size:
Power Well:
R/W
8-bit
Core
Description
Reserved. Must be 0.
Channel Mask Bits—R/W. This register permits all four channels to be simultaneously enabled/
disabled instead of enabling/disabling each channel individually, as is the case with the Mask
Register - Write Single Mask Bit. In addition, this register has a read path to allow the status of the
channel mask bits to be read. A channel's mask bit is automatically set to 1 when the Current Byte/
Word Count Register reaches terminal count (unless the channel is in auto-initialization mode).
3:0
Setting the bit(s) to a 1 disables the corresponding DREQ(s). Setting the bit(s) to a 0 enables the
corresponding DREQ(s). Bits [3:0] are set to 1 upon part reset or Master Clear. When read, bits [3:0]
indicate the DMA channel [3:0] ([7:4]) mask status.
Bit 0 = Channel 0 (4)
1 = Masked, 0 = Not Masked
Bit 1 = Channel 1 (5)
1 = Masked, 0 = Not Masked
Bit 2 = Channel 2 (6)
1 = Masked, 0 = Not Masked
Bit 3 = Channel 3 (7)
1 = Masked, 0 = Not Masked
Note: Disabling channel 4 also disables channels 0–3 due to the cascade of channels 0–3 through
channel 4.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-29
LPC Interface Bridge Registers (D31:F0)
9.3
Timer I/O Registers
Port
Aliases
40h
50h
Register Name/Function
Counter 0 Interval Time Status Byte Format
Counter 0 Counter Access Port Register
RO
Undefined
R/W
0XXXXXXXb
RO
Counter 2 Counter Access Port Register
Undefined
R/W
Timer Control Word Register
Undefined
WO
XXXXXXX0b
WO
X0h
WO
51h
52h
53h
Timer Control Word Register Read Back
Counter Latch Command
9.3.1
RO
R/W
Counter 2 Interval Time Status Byte Format
43h
0XXXXXXXb
Undefined
Counter 1 Counter Access Port Register
42h
Type
0XXXXXXXb
Counter 1 Interval Time Status Byte Format
41h
Default Value
TCW—Timer Control Word Register
I/O Address:
Default Value:
43h
All bits undefined
Attribute:
Size:
WO
8 bits
This register is programmed prior to any counter being accessed to specify counter modes.
Following part reset, the control words for each register are undefined and each counter output is 0.
Each timer must be programmed to bring it into a known state.
Bit
Description
Counter Select—WO. The Counter Selection bits select the counter the control word acts upon as
shown below. The Read Back Command is selected when bits[7:6] are both 1.
00 = Counter 0 select
7:6
01 = Counter 1 select
10 = Counter 2 select
11 = Read Back Command
Read/Write Select—WO. These bits are the read/write control bits. The actual counter programming
is done through the counter port (40h for counter 0, 41h for counter 1, and 42h for counter 2).
00 = Counter Latch Command
5:4
01 = Read/Write Least Significant Byte (LSB)
10 = Read/Write Most Significant Byte (MSB)
11 = Read/Write LSB then MSB
Counter Mode Selection—WO. These bits select one of six possible modes of operation for the
selected counter.
3:1
000 = Mode 0
Out signal on end of count (=0)
001 = Mode 1
Hardware retriggerable one-shot
x10 = Mode 2
Rate generator (divide by n counter)
x11 = Mode 3
Square wave output
100 = Mode 4
Software triggered strobe
101 = Mode 5
Hardware triggered strobe
Binary/BCD Countdown Select—WO.
0
0 = Binary countdown is used. The largest possible binary count is 216
1 = Binary coded decimal (BCD) count is used. The largest possible BCD count is 104
9-30
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
There are two special commands that can be issued to the counters through this register, the Read
Back Command and the Counter Latch Command. When these commands are chosen, several bits
within this register are redefined. These register formats are described below.
9.3.1.1
RDBK_CMD—Read Back Command
The Read Back Command is used to determine the count value, programmed mode, and current
states of the OUT pin and Null count flag of the selected counter or counters. Status and/or count
may be latched in any or all of the counters by selecting the counter during the register write. The
count and status remain latched until read, and further latch commands are ignored until the count
is read. Both count and status of the selected counters may be latched simultaneously by setting
both bit 5 and bit 4 to 0. If both are latched, the first read operation from that counter returns the
latched status. The next one or two reads, depending on whether the counter is programmed for one
or two byte counts, returns the latched count. Subsequent reads return an unlatched count.
Bit
7:6
Description
Read Back Command. This field must be “11” to select the Read Back Command.
Latch Count of Selected Counters.
5
0 = Current count value of the selected counters will be latched
1 = Current count will not be latched
Latch Status of Selected Counters.
4
9.3.1.2
0 = Status of the selected counters will be latched
1 = Status will not be latched
3
Counter 2 Select.
1 = Counter 2 count and/or status will be latched
2
Counter 1 Select.
1 = Counter 1 count and/or status will be latched
1
Counter 0 Select.
1 = Counter 0 count and/or status will be latched.
0
Reserved. Must be 0.
LTCH_CMD—Counter Latch Command
The Counter Latch Command latches the current count value. This command is used to insure that
the count read from the counter is accurate. The count value is then read from each counter's count
register through the Counter Ports Access Ports Register (40h for counter 0, 41h for counter 1, and
42h for counter 2). The count must be read according to the programmed format (i.e., if the counter
is programmed for two byte counts, two bytes must be read). The two bytes do not have to be read
one right after the other (read, write, or programming operations for other counters may be inserted
between the reads). If a counter is latched once and then latched again before the count is read, the
second Counter Latch Command is ignored.
Bit
7:6
5:4
3:0
Description
Counter Selection. These bits select the counter for latching. If “11” is written, then the write is
interpreted as a read back command.
00 = Counter 0
01 = Counter 1
10 = Counter 2
Counter Latch Command.
00 = Selects the Counter Latch Command.
Reserved. Must be 0.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-31
LPC Interface Bridge Registers (D31:F0)
9.3.2
SBYTE_FMT—Interval Timer Status Byte Format Register
I/O Address:
Default Value:
Counter 0 = 40h,
Counter 1 = 41h,
Counter 2 = 42h
Bits[6:0] undefined, Bit 7=0
Attribute:
Size:
RO
8 bits per counter
Each counter's status byte can be read following a Read Back Command. If latch status is chosen
(bit 4=0, Read Back Command) as a read back option for a given counter, the next read from the
counter's Counter Access Ports Register (40h for counter 0, 41h for counter 1, and 42h for counter
2) returns the status byte. The status byte returns the following:
Bit
Description
Counter OUT Pin State—RO.
7
6
0 = OUT pin of the counter is also a 0.
1 = OUT pin of the counter is also a 1.
Count Register Status—RO. This bit indicates when the last count written to the Count Register
(CR) has been loaded into the counting element (CE). The exact time this happens depends on the
counter mode, but until the count is loaded into the counting element (CE), the count value will be
incorrect.
0 = Count has been transferred from CR to CE and is available for reading.
1 = Null Count. Count has not been transferred from CR to CE and is not yet available for reading.
Read/Write Selection Status—RO. These reflect the read/write selection made through bits[5:4] of
the control register. The binary codes returned during the status read match the codes used to
program the counter read/write selection.
5:4
00 = Counter Latch Command
01 = Read/Write Least Significant Byte (LSB)
10 = Read/Write Most Significant Byte (MSB)
11 = Read/Write LSB then MSB
Mode Selection Status—RO. These bits return the counter mode programming. The binary code
returned matches the code used to program the counter mode, as listed under the bit function above.
3:1
000 = Mode 0
Out signal on end of count (=0)
001 = Mode 1
Hardware retriggerable one-shot
x10 = Mode 2
Rate generator (divide by n counter)
x11 = Mode 3
Square wave output
100 = Mode 4
Software triggered strobe
101 = Mode 5
Hardware triggered strobe
Countdown Type Status—RO. This bit reflects the current countdown type.
0
9.3.3
0 = Binary countdown
1 = Binary Coded Decimal (BCD) countdown.
Counter Access Ports Register
I/O Address:
Default Value:
9-32
Counter 0 –40h,
Counter 1 –41h,
Counter 2–42h
All bits undefined
Attribute:
R/W
Size:
8 bit
Bit
Description
7:0
Counter Port—R/W. Each counter port address is used to program the 16-bit Count Register. The
order of programming (either LSB only, MSB only, or LSB then MSB) is defined with the Interval
Counter Control Register at port 43h. The counter port is also used to read the current count from the
Count Register, and return the status of the counter programming following a Read Back Command.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.4
8259 Interrupt Controller (PIC) Registers
9.4.1
Interrupt Controller I/O MAP
The interrupt controller registers are located at 20h and 21h for the master controller (IRQ[0:7]),
and at A0h and A1h for the slave controller (IRQ[8:13]). These registers have multiple functions
depending on the data written to them. Table 9-3 lists the different register possibilities for each
address.
Table 9-3. PIC Registers
Port
20h
Aliases
Register Name/Function
Default Value
Type
24h, 28h,
Master PIC ICW1 Init. Cmd Word 1 Register
Undefined
WO
2Ch, 30h,
Master PIC OCW2 Op Ctrl Word 2 Register
001XXXXXb
WO
34h, 38h, 3Ch
Master PIC OCW3 Op Ctrl Word 3 Register
X01XXX10b
R/W
Master PIC ICW2 Init. Cmd Word 2 Register
Undefined
WO
Master PIC ICW3 Init. Cmd Word 3 Register
Undefined
WO
25h, 29h,
21h
2Dh, 31h,
Master PIC ICW4 Init. Cmd Word 4 Register
01h
WO
Master PIC OCW1 Op Ctrl Word 1 Register
00h
R/W
A4h, A8h,
Slave PIC ICW1 Init. Cmd Word 1 Register
Undefined
WO
ACh, B0h,
Slave PIC OCW2 Op Ctrl Word 2 Register
001XXXXXb
WO
35h, 39h, 3Dh
A0h
B4h, B8h, BCh
A5h, A9h,
A1h
Slave PIC OCW3 Op Ctrl Word 3 Register
X01XXX10b
R/W
Slave PIC ICW2 Init. Cmd Word 2 Register
Undefined
WO
Slave PIC ICW3 Init. Cmd Word 3 Register
Undefined
WO
Slave PIC ICW4 Init. Cmd Word 4 Register
01h
WO
ADh, B1h,
B5h, B9h, BDh
Slave PIC OCW1 Op Ctrl Word 1 Register
00h
R/W
4D0h
–
Master PIC Edge/Level Triggered Register
00h
R/W
4D1h
–
Slave PIC Edge/Level Triggered Register
00h
R/W
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-33
LPC Interface Bridge Registers (D31:F0)
9.4.2
ICW1—Initialization Command Word 1 Register
Offset Address:
Default Value:
Master Controller–020h
Slave Controller–0A0h
All bits undefined
Attribute:
Size:
WO
8 bit /controller
A write to Initialization Command Word 1 starts the interrupt controller initialization sequence,
during which the following occurs:
1. The Interrupt Mask register is cleared.
2. IRQ7 input is assigned priority 7.
3. The slave mode address is set to 7.
4. Special Mask Mode is cleared and Status Read is set to IRR.
Once this write occurs, the controller expects writes to ICW2, ICW3, and ICW4 to complete the
initialization sequence.
Bit
7:5
4
3
2
1
0
9-34
Description
ICW/OCW select—WO. These bits are MCS-85 specific, and not needed.
000 = Should be programmed to “000”
ICW/OCW select—WO.
1 = This bit must be a 1 to select ICW1 and enable the ICW2, ICW3, and ICW4 sequence.
Edge/Level Bank Select (LTIM)—WO. Disabled. Replaced by the edge/level triggered control
registers (ELCR).
ADI—WO.
0 = Ignored for the ICH2. Should be programmed to 0.
Single or Cascade (SNGL)—WO.
0 = Must be programmed to a 0 to indicate two controllers operating in cascade mode.
ICW4 Write Required (IC4)—WO.
1 = This bit must be programmed to a 1 to indicate that ICW4 needs to be programmed.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.4.3
ICW2—Initialization Command Word 2 Register
Offset Address:
Default Value:
Master Controller–021h
Slave Controller–0A1h
All bits undefined
Attribute:
Size:
WO
8 bit /controller
ICW2 is used to initialize the interrupt controller with the five most significant bits of the interrupt
vector address. The value programmed for bits[7:3] is used by the processor to define the base
address in the interrupt vector table for the interrupt routines associated with each IRQ on the
controller. Typical ISA ICW2 values are 08h for the master controller and 70h for the slave
controller.
Bit
7:3
Description
Interrupt Vector Base Address—WO. Bits [7:3] define the base address in the interrupt vector
table for the interrupt routines associated with each interrupt request level input.
Interrupt Request Level—WO. When writing ICW2, these bits should all be 0. During an interrupt
acknowledge cycle, these bits are programmed by the interrupt controller with the interrupt to be
serviced. This is combined with bits [7:3] to form the interrupt vector driven onto the data bus
during the second INTA# cycle. The code is a three bit binary code:
2:0
9.4.4
Code
Master Interrupt
Slave Interrupt
000
IRQ0
IRQ8
001
IRQ1
IRQ9
010
IRQ2
IRQ10
011
IRQ3
IRQ11
100
IRQ4
IRQ12
101
IRQ5
IRQ13
110
IRQ6
IRQ14
111
IRQ7
IRQ15
ICW3—Master Controller Initialization Command Word 3
Register
Offset Address:
Default Value:
21h
All bits undefined
Bit
7:3
2
1:0
Attribute:
Size:
WO
8 bits
Description
0 = These bits must be programmed to zero.
Cascaded Interrupt Controller IRQ Connection—WO. This bit indicates that the slave controller is
cascaded on IRQ2. When IRQ8#–IRQ15 is asserted, it goes through the slave controller’s priority
resolver. The slave controller’s INTR output onto IRQ2. IRQ2 then goes through the master
controller’s priority solver. If it wins, the INTR signal is asserted to the processor, and the returning
interrupt acknowledge returns the interrupt vector for the slave controller.
1 = This bit must always be programmed to a 1.
0 = These bits must be programmed to zero.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-35
LPC Interface Bridge Registers (D31:F0)
9.4.5
ICW3—Slave Controller Initialization Command Word 3
Register
Offset Address:
Default Value:
A1h
All bits undefined
Bit
9.4.6
Attribute:
Size:
WO
8 bits
Description
7:3
0 = These bits must be programmed to zero.
2:0
Slave Identification Code—WO. These bits are compared against the slave identification code
broadcast by the master controller from the trailing edge of the first internal INTA# pulse to the trailing
edge of the second internal INTA# pulse. These bits must be programmed to 02h to match the code
broadcast by the master controller. When 02h is broadcast by the master controller during the INTA#
sequence, the slave controller assumes responsibility for broadcasting the interrupt vector.
ICW4—Initialization Command Word 4 Register
Offset Address:
Master Controller–021h
Slave Controller–0A1h
Bit
7:5
Attribute:
Size:
WO
8 bits
Description
0 = These bits must be programmed to zero.
Special Fully Nested Mode (SFNM)—WO.
4
3
2
0 = Should normally be disabled by writing a 0 to this bit.
1 = Special fully nested mode is programmed.
Buffered Mode (BUF)—WO.
0 = Must be programmed to 0 for the ICH2. This is non-buffered mode.
Master/Slave in Buffered Mode—WO. Not used.
0 = Should always be programmed to 0.
Automatic End of Interrupt (AEOI)—WO.
1
0
9.4.7
0 = This bit should normally be programmed to 0. This is the normal end of interrupt.
1 = Automatic End of Interrupt (AEOI) mode is programmed. AEOI is discussed in Section 5.7.4.
Microprocessor Mode—WO.
1 = Must be programmed to 1 to indicate that the controller is operating in an Intel Architecturebased system.
OCW1—Operational Control Word 1 (Interrupt Mask)
Register
Offset Address:
Default Value:
9-36
Master Controller–021h
Slave Controller–0A1h
00h
Attribute:
Size:
R/W
8 bits
Bit
Description
7:0
Interrupt Request Mask—R/W. When a 1 is written to any bit in this register, the corresponding IRQ
line is masked. When a 0 is written to any bit in this register, the corresponding IRQ mask bit is
cleared and interrupt requests will again be accepted by the controller. Masking IRQ2 on the master
controller will also mask the interrupt requests from the slave controller.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.4.8
OCW2—Operational Control Word 2 Register
Offset Address:
Default Value:
Master Controller–020h
Attribute:
Slave Controller–0A0h
Size:
Bit[4:0]=undefined, Bit[7:5]=001
WO
8 bits
Following a part reset or ICW initialization, the controller enters the fully nested mode of
operation. Non-specific EOI without rotation is the default. Both rotation mode and specific EOI
mode are disabled following initialization.
Bit
Description
Rotate and EOI Codes (R, SL, EOI)—WO. These three bits control the Rotate and End of Interrupt
modes and combinations of the two.
000 = Rotate in Auto EOI Mode (Clear)
001 = Non-specific EOI command
010 = No Operation
7:5
011 = Specific EOI Command
100 = Rotate in Auto EOI Mode (Set)
101 = Rotate on Non-Specific EOI Command
110 = *Set Priority Command
111 = *Rotate on Specific EOI Command
*L0–L2 Are Used
4:3
OCW2 Select—WO. When selecting OCW2, bits 4:3 = “00”
Interrupt Level Select (L2, L1, L0)—WO. L2, L1, and L0 determine the interrupt level acted upon
when the SL bit is active. A simple binary code, outlined below, selects the channel for the command
to act upon. When the SL bit is inactive, these bits do not have a defined function; programming L2,
L1 and L0 to 0 is sufficient in this case.
2:0
Bits
Interrupt Level
Bits
Interrupt Level
000
IRQ0/8
100
IRQ4/12
001
IRQ1/9
101
IRQ5/13
010
IRQ2/10
110
IRQ6/14
011
IRQ3/11
111
IRQ7/15
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-37
LPC Interface Bridge Registers (D31:F0)
9.4.9
OCW3—Operational Control Word 3 Register
Offset Address:
Default Value:
Master Controller–020h
Attribute:
Slave Controller–0A0h
Size:
Bit[6,0]=0, Bit[7,4:2]=undefined,
Bit[5,1]=1
Bit
WO
8 bits
Description
7
Reserved. Must be 0.
6
Special Mask Mode (SMM)—WO.
1 = The Special Mask Mode can be used by an interrupt service routine to dynamically alter the
system priority structure while the routine is executing, through selective enabling/disabling of
the other channel's mask bits. Bit 5, the ESMM bit, must be set for this bit to have any meaning.
Enable Special Mask Mode (ESMM)—WO.
5
4:3
0 = Disable. The SMM bit becomes a "don't care".
1 = Enable the SMM bit to set or reset the Special Mask Mode.
OCW3 Select—WO. When selecting OCW3, bits 4:3 = “01”
Poll Mode Command—WO.
2
1:0
0 = Disable. Poll Command is not issued.
1 = Enable. The next I/O read to the interrupt controller is treated as an interrupt acknowledge cycle.
An encoded byte is driven onto the data bus, representing the highest priority level requesting
service.
Register Read Command—WO. These bits provide control for reading the In-Service Register (ISR)
and the Interrupt Request Register (IRR). When bit 1=0, bit 0 will not affect the register read selection.
When bit 1=1, bit 0 selects the register status returned following an OCW3 read. If bit 0=0, the IRR
will be read. If bit 0=1, the ISR will be read. Following ICW initialization, the default OCW3 port
address read will be "read IRR". To retain the current selection (read ISR or read IRR), always write a
0 to bit 1 when programming this register. The selected register can be read repeatedly without
reprogramming OCW3. To select a new status register, OCW3 must be reprogrammed prior to
attempting the read.
00 = No Action
01 = No Action
10 = Read IRQ Register
11 = Read IS Register
9-38
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.4.10
ELCR1—Master Controller Edge/Level Triggered Register
Offset Address:
Default Value:
4D0h
00h
Attribute:
Size:
R/W
8 bits
In edge mode, (bit[x] = 0), the interrupt is recognized by a low to high transition. In level mode
(bit[x] = 1), the interrupt is recognized by a high level. The cascade channel, IRQ2, the heart beat
timer (IRQ0), and the keyboard controller (IRQ1), cannot be put into level mode.
Bit
Description
IRQ7 ECL—R/W.
7
0 = Edge.
1 = Level.
IRQ6 ECL—R/W.
6
0 = Edge.
1 = Level.
IRQ5 ECL—R/W.
5
0 = Edge.
1 = Level.
IRQ4 ECL—R/W.
4
0 = Edge.
1 = Level.
IRQ3 ECL—R/W.
3
2:0
0 = Edge.
1 = Level.
Reserved. Must be 0.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-39
LPC Interface Bridge Registers (D31:F0)
9.4.11
ELCR2—Slave Controller Edge/Level Triggered Register
Offset Address:
Default Value:
4D1h
00h
Attribute:
Size:
R/W
8 bits
In edge mode (bit[x] = 0) the interrupt is recognized by a low-to-high transition. In level mode
(bit[x] = 1) the interrupt is recognized by a high level. The real time clock interrupt (IRQ8#) and
the floating point error interrupt (IRQ13) cannot be programmed for level mode.
Bit
Description
IRQ15 ECL—R/W.
7
0 = Edge.
1 = Level.
IRQ14 ECL—R/W.
6
0 = Edge.
1 = Level.
5
Reserved. Must be 0.
IRQ12 ECL—R/W.
4
0 = Edge.
1 = Level.
IRQ11 ECL—R/W.
3
0 = Edge.
1 = Level.
IRQ10 ECL—R/W.
2
0 = Edge.
1 = Level.
IRQ9 ECL—R/W.
9-40
1
0 = Edge.
1 = Level.
0
Reserved. Must be 0.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.5
Advanced Interrupt Controller (APIC)
9.5.1
APIC Register Map
The APIC is accessed via an indirect addressing scheme. Two registers are visible by software for
manipulation of most of the APIC registers. These registers are mapped into memory space. The
registers are shown in Table 9-4.
Table 9-4. APIC Direct Registers
Address
Register
Size
Type
FEC0_0000h
Index Register
8 bits
R/W
FEC0_0010h
Data Register
32 bits
R/W
FECO_0020h
IRQ Pin Assertion Register
8 bits
WO
FECO_0040h
EOI Register
8 bits
WO
Table 9-5 lists the registers which can be accessed within the APIC via the Index Register. When
accessing these registers, accesses must be done a DWord at a time. For example, software should
never access byte 2 from the Data register before accessing bytes 0 and 1. The hardware will not
attempt to recover from a bad programming model in this case.
Table 9-5. APIC Indirect Registers
Index
Register
Type
00h
ID
32 bits
R/W
01h
Version
32 bits
RO
02h
Arbitration ID
32 bits
RO
03h
Boot Configuration
32 bits
R/W
03h–0Fh
Reserved
10h –11h
Redirection Table 0
64 bits
R/W
12h–13h
Redirection Table 1
64 bits
R/W
...
...
64 bits
R/W
...
9.5.2
Size
RO
...
3Eh–3Fh
Redirection Table 23
40h–FFh
Reserved
RO
IND—Index Register
Memory Address
Default Value:
FEC0_0000h
00h
Attribute:
Size:
R/W
8 bits
The Index Register will select which APIC indirect register to be manipulated by software. The
selector values for the indirect registers are listed in Table 9-5. Software programs this register to
select the desired APIC internal register
.
Bit
7:0
Description
APIC Index—R/W. This is an 8 bit pointer into the I/O APIC register table.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-41
LPC Interface Bridge Registers (D31:F0)
9.5.3
DAT—Data Register
Memory Address
Default Value:
FEC0_0010h
00000000h
Attribute:
Size:
R/W
32 bits
This is a 32 bit register specifying the data to be read or written to the register pointed to by the
Index register. This register can only be accessed in DWord quantities.
Bit
7:0
9.5.4
Description
APIC Data—R/W. This is a 32 bit register for the data to be read or written to the APIC indirect
register pointed to by the Index register.
IRQPA—IRQ Pin Assertion Register
Memory Address
Default Value:
FEC0_0020h
N/A
Attribute:
Size:
WO
32 bits
The IRQ Pin Assertion Register is present to provide a mechanism to scale the number of interrupt
inputs into the I/O APIC without increasing the number of dedicated input pins. When a device that
supports this interrupt assertion protocol requires interrupt service, that device will issue a write to
this register. Bits 4:0 written to this register contain the IRQ number for this interrupt. The only
valid values are 0–23. Bits 31:5 are ignored. To provide for future expansion, peripherals should
always write a value of 0 for Bits 31:5.
See Section 5.8.4 for more details on how PCI devices will use this field.
Note:
Writes to this register are only allowed by the processor and by masters on the ICH2’s PCI bus.
Writes by devices on PCI buses above the ICH2 (e.g., a PCI segment on a P64H) are not supported.
Bit
9-42
Description
31:5
Reserved. Bits 31:5 are ignored.
4:0
IRQ Number—WO. Bits 4:0 written to this register contain the IRQ number for this interrupt. The
only valid values are 0–23.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.5.5
EOIR—EOI Register
Memory Address
Default Value:
FEC0_0040h
N/A
Attribute:
Size:
WO
32 bits
The EOI register is present to provide a mechanism to maintain the level triggered semantics for
level-triggered interrupts issued on the parallel bus.
When a write is issued to this register, the I/O APIC will check the lower 8 bits written to this
register, and compare it with the vector field for each entry in the I/O Redirection Table. When a
match is found, the Remote_IRR bit for that I/O Redirection Entry will be cleared.
9.5.6
Note:
This is similar to what already occurs when the APIC sees the EIO message on the serial bus. Note
that if multiple I/O Redirection entries, for any reason, assign the same vector for more than one
interrupt input, each of those entries will have the Remote_IRR bit reset to 0. The interrupt which
was prematurely reset will not be lost because if its input remained active when the Remote_IRR
bit is cleared, the interrupt will be reissued and serviced at a later time. Note: Only bits 7:0 are
actually used. Bits 31:8 are ignored by the ICH2.
Note:
To provide for future expansion, the processor should always write a value of 0 to Bits 31:8.
Bit
Description
31:8
Reserved. To provide for future expansion, the processor should always write a value of 0 to Bits
31:8.
7:0
Redirection Entry Clear—WO. When a write is issued to this register, the I/O APIC will check
this field, and compare it with the vector field for each entry in the I/O Redirection Table. When a
match is found, the Remote_IRR bit for that I/O Redirection Entry will be cleared.
ID—Identification Register
Index Offset:
Default Value:
00h
00000000h
Attribute:
Size:
R/W
32 bits
The APIC ID serves as a physical name of the APIC. The APIC bus arbitration ID for the APIC is
derived from its I/O APIC ID. This register is reset to zero on power up reset.
Bit
Description
31:28
Reserved.
27:24
APIC ID—R/W. Software must program this value before using the APIC.
23:0
Reserved.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-43
LPC Interface Bridge Registers (D31:F0)
9.5.7
VER—Version Register
Index Offset:
Default Value:
01h
00170002h
Attribute:
Size:
RO
32 bits
Each I/O APIC contains a hardwired Version Register that identifies different implementation of
APIC and their versions. The maximum redirection entry information also is in this register, to let
software know how many interrupt are supported by this APIC.
Bit
31:24
Reserved.
23:16
Maximum Redirection Entries—RO. This is the entry number (0 being the lowest entry) of the
highest entry in the redirection table. It is equal to the number of interrupt input pins minus one and
is in the range 0 through 239. In the ICH2 this field is hardwired to 17h to indicate 24 interrupts.
15
14 :8
7:0
9.5.8
Description
PRQ—RO. This bit is set to 1 to indicate that this version of the I/O APIC implements the IRQ
Assertion register and allows PCI devices to write to it to cause interrupts.
Reserved.
Version—RO. This is a version number that identifies the implementation version.
ARBID—Arbitration ID Register
Index Offset:
Default Value:
02h
00000000h
Attribute:
Size:
RO
32 bits
This register contains the bus arbitration priority for the APIC. This register is loaded whenever the
APIC ID register is loaded. A rotating priority scheme is used for APIC bus arbitration. The winner
of the arbitration becomes the lowest priority agent and assumes an arbitration ID of 0.
a
Bit
31:28
9.5.9
Description
Reserved.
27:24
I/O APIC Identification—RO. This 4 bit field contains the I/O APIC Arbitration ID.
23:0
Reserved.
BOOT_CONFIG—Boot Configuration Register
Index Offset:
Default Value:
03h
00000000h
Attribute:
Size:
R/W
32 bits
This register is used to control the interrupt delivery mechanism for the APIC.
a
Bit
31:1
Description
Reserved.
Delivery Type (DT)—R/W.
0
9-44
0 = Interrupt delivery mechanism is via the APIC serial bus (default).
1 = Interrupt delivery mechanism is a front-side bus message.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.5.10
Redirection Table
Index Offset:
Default Value:
10h–11h (vector 0) through
3E–3Fh (vector 23)
Bit 16–1, Bits[15:12]=0.
All other bits undefined
Attribute:
R/W
Size:
64 bits each, (accessed as
two 32 bit quantities)
The Redirection Table has a dedicated entry for each interrupt input pin. The information in the
Redirection Table is used to translate the interrupt manifestation on the corresponding interrupt pin
into an APIC message.
The APIC will respond to an edge-triggered interrupt as long as the interrupt is held until after the
acknowledge cycle has begun. Once the interrupt is detected, a delivery status bit internally to the
I/O APIC is set. The state machine will step ahead and wait for an acknowledgment from the APIC
bus unit that the interrupt message was sent over the APIC bus. Only then will the I/O APIC be
able to recognize a new edge on that interrupt pin. That new edge will only result in a new
invocation of the handler if its acceptance by the destination APIC causes the Interrupt Request
Register bit to go from 0 to 1. (In other words, if the interrupt was not already pending at the
destination.)
Bit
Description
63:56
Destination—R/W. If bit 11 of this entry is 0 [Physical], then bits [59:56] specifies an APIC ID. If
bit 11 of this entry is 1 [Logical], then bits [63:56] specify the logical destination address of a set of
processors.
55:17
Reserved.
Mask—R/W.
16
15
14
13
0 = Not masked: An edge or level on this interrupt pin results in the delivery of the interrupt to the
destination.
1 = Masked: Interrupts are not delivered nor held pending. Setting this bit after the interrupt is
accepted by a local APIC has no effect on that interrupt. This behavior is identical to the
device withdrawing the interrupt before it is posted to the processor. It is software's
responsibility to deal with the case where the mask bit is set after the interrupt message has
been accepted by a local APIC unit but before the interrupt is dispensed to the processor.
Trigger Mode—R/W. This field indicates the type of signal on the interrupt pin that triggers an
interrupt.
0 = Edge triggered.
1 = Level triggered.
Remote IRR—R/W. This bit is used for level triggered interrupts; its meaning is undefined for
edge triggered interrupts.
0 = Reset when an EOI message is received from a local APIC.
1 = Set when Local APIC/s accept the level interrupt sent by the I/O APIC.
Interrupt Input Pin Polarity—R/W. This bit specifies the polarity of each interrupt signal
connected to the interrupt pins.
0 = Active high.
1 = Active low.
Delivery Status—RO. This field contains the current status of the delivery of this interrupt. Writes
to this bit have no effect.
12
0 = Idle. No activity for this interrupt.
1 = Pending. Interrupt has been injected, but delivery is held up due to the APIC bus being busy
or the inability of the receiving APIC unit to accept the interrupt at this time.
Destination Mode—R/W. This field determines the interpretation of the Destination field.
11
0 = Physical. Destination APIC ID is identified by bits [59:56].
1 = Logical. Destinations are identified by matching bit [63:56] with the Logical Destination in the
Destination Format Register and Logical Destination Register in each Local APIC.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-45
LPC Interface Bridge Registers (D31:F0)
Bit
Description
Delivery Mode—R/W. This field specifies how the APICs listed in the destination field should act
upon reception of this signal. Certain Delivery Modes will only operate as intended when used in
conjunction with a specific trigger mode. These encodings are:
000 = Fixed. Deliver the signal on the INTR signal of all processor cores listed in the destination.
Trigger Mode can be edge or level.
001 = Lowest Priority. Deliver the signal on the INTR signal of the processor core that is executing
at the lowest priority among all the processors listed in the specified destination. Trigger
Mode can be edge or level.
010 = SMI (System Management Interrupt). Requires the interrupt to be programmed as edge
triggered. The vector information is ignored but must be programmed to all zeroes for future
compatibility.
011 = Reserved
10:8
100 = NMI. Deliver the signal on the NMI signal of all processor cores listed in the destination.
Vector information is ignored. NMI is treated as an edge triggered interrupt even if it is
programmed as level triggered. For proper operation this redirection table entry must be
programmed to edge triggered. The NMI delivery mode does not set the RIRR bit. Once the
interrupt is detected, it will be sent over the APIC bus.
If the redirection table is incorrectly set to level, the loop count will continue counting
through the redirection table addresses. Once the count for the NMI pin is reached again,
the interrupt will be sent over the APIC bus again.
101 = INIT. Deliver the signal to all processor cores listed in the destination by asserting the INIT
signal. All addressed local APICs will assume their INIT state. INIT is always treated as an
edge triggered interrupt even if programmed as level triggered. For proper operation this
redirection table entry must be programmed to edge triggered. The INIT delivery mode
does not set the RIRR bit. Once the interrupt is detected, it will be sent over the APIC bus.
If the redirection table is incorrectly set to level, the loop count will continue counting
through the redirection table addresses. Once the count for the INIT pin is reached again,
the interrupt will be sent over the APIC bus again
110 = Reserved
111 = ExtINT. Deliver the signal to the INTR signal of all processor cores listed in the destination
as an interrupt that originated in an externally connected 8259A compatible interrupt
controller. The INTA cycle that corresponds to this ExtINT delivery will be routed to the
external controller that is expected to supply the vector. Requires the interrupt to be
programmed as edge triggered.
7:0
9-46
Vector—R/W. This field contains the interrupt vector for this interrupt. Values range between 10h
and FEh.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.6
Real Time Clock Registers
9.6.1
I/O Register Address Map
The RTC internal registers and RAM are organized as two banks of 128 bytes each, called the
standard and extended banks. The first 14 bytes of the standard bank contain the RTC time and date
information along with four registers, A–D, that are used for configuration of the RTC. The
extended bank contains a full 128 bytes of battery backed SRAM and will be accessible even when
the RTC module is disabled (via the RTC configuration register). Registers A–D do not physically
exist in the RAM.
All data movement between the host processor and the real-time clock is done through registers
mapped to the standard I/O space. The register map appears in Table 9-6.
Table 9-6. RTC I/O Registers
I/O Locations
If U128E bit = 0
Function
70h and 74h
Also alias to 72h and 76h
Real-Time Clock (Standard RAM) Index Register
71h and 75h
Also alias to 73h and 77h
Real-Time Clock (Standard RAM) Target Register
72h and 76h
Extended RAM Index Register (if enabled)
73h and 77h
Extended RAM Target Register (if enabled)
NOTES:
1. I/O locations 70h and 71h are the standard ISA location for the real-time clock. The map for this bank is
shown in Table 9-7. Locations 72h and 73h are for accessing the extended RAM. The extended RAM bank
is also accessed using an indexed scheme. I/O address 72h is used as the address pointer and I/O address
73h is used as the data register. Index addresses above 127h are not valid. If the extended RAM is not
needed, it may be disabled.
2. Software must preserve the value of bit 7 at I/O addresses 70h and 74h. When writing to these addresses,
software must first read the value, and then write the same value for bit 7 during the sequential address
write.
9.6.2
Indexed Registers
The RTC contains two sets of indexed registers that are accessed using the two separate Index and
Target registers (70h/71h or 72h/73h), as shown in Table 9-7.
Table 9-7. RTC (Standard) RAM Bank
Index
Name
Index
Name
00h
Seconds
08h
Month
01h
Seconds Alarm.
09h
Year
02h
Minutes
0Ah
Register A
03h
Minutes Alarm
0Bh
Register B
04h
Hours
0Ch
Register C
05h
Hours Alarm
0Dh
Register D
06h
Day of Week
0Eh–7Fh
07h
Day of Month
82801BA ICH2 and 82801BAM ICH2-M Datasheet
114 Bytes of User RAM
9-47
LPC Interface Bridge Registers (D31:F0)
9.6.2.1
RTC_REGA—Register A
RTC Index:
Default Value:
Lockable:
0A
Undefined
No
Attribute:
Size:
Power Well:
R/W
8-bit
RTC
This register is used for general configuration of the RTC functions. None of the bits are affected
by RSMRST# or any other ICH2 reset signal.
Bit
Description
Update In Progress (UIP)—R/W. This bit may be monitored as a status flag.
7
0 = The update cycle will not start for at least 492us. The time, calendar, and alarm information in
RAM is always available when the UIP bit is 0.
1 = The update is soon to occur or is in progress.
Division Chain Select (DV[2:0])—R/W. These three bits control the divider chain for the oscillator,
and are not affected by RSMRST# or any other reset signal. DV[2] corresponds to bit 6.
010 = Normal Operation
11X = Divider Reset
6:4
101 = Bypass 15 stages (test mode only)
100 = Bypass 10 stages (test mode only)
011 = Bypass 5 stages (test mode only)
001 = Invalid
000 = Invalid
RS[3:0] Rate Select—R/W. Selects one of 13 taps of the 15 stage divider chain. The selected tap
can generate a periodic interrupt if the PIE bit is set in Register B. Otherwise this tap will set the PF
flag of Register C. If the periodic interrupt is not to be used, these bits should all be set to zero. RS3
corresponds to bit 3.
3:0
9-48
0000 = Interrupt never toggles
1000 = 3.90625 ms
0001 = 3.90625 ms
1001 = 7.8125 ms
0010 = 7.8125 ms
1010 = 15.625 ms
0011 = 122.070 us
1011 = 31.25 ms
0100 = 244.141 us
1100 = 62.5 ms
0101 = 488.281 us
1101 = 125 ms
0110 = 976.5625 us
1110 = 250 ms
0111 = 1.953125 ms
1111= 500 ms
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.6.2.2
RTC_REGB—Register B (General Configuration)
RTC Index:
Default Value:
Lockable:
0Bh
U0U00UUU (U: Undefined)
No
Bit
Attribute:
Size:
Power Well:
R/W
8-bit
RTC
Description
Update Cycle Inhibit (SET)—R/W. Enables/Inhibits the update cycles. This bit is not affected by
RSMRST# nor any other reset signal.
7
0 = Update cycle occurs normally once each second.
1 = A current update cycle will abort and subsequent update cycles will not occur until SET is
returned to zero. When set is one, the BIOS may initialize time and calendar bytes safely.
Periodic Interrupt Enable (PIE)—R/W. This bit is cleared by RSMRST#, but not on any other reset.
6
0 = Disable.
1 = Allows an interrupt to occur with a time base set with the RS bits of register A.
5
0 = Disable.
1 = Allows an interrupt to occur when the AF is set by an alarm match from the update cycle. An
alarm can occur once a second, one an hour, once a day, or one a month.
Alarm Interrupt Enable (AIE)—R/W. This bit is cleared by RSMRST#, but not on any other reset.
4
3
2
1
Update-ended Interrupt Enable (UIE)—R/W. This bit is cleared by RSMRST#, but not on any other
reset.
0 = Disable.
1 = Allows an interrupt to occur when the update cycle ends.
Square Wave Enable (SQWE)—R/W. This bit serves no function in the ICH2. It is left in this register
bank to provide compatibility with the Motorola* 146818B. The ICH2 has no SQW pin. This bit is
cleared by RSMRST#, but not on any other reset.
Data Mode (DM)—R/W. Specifies either binary or BCD data representation. This bit is not affected by
RSMRST# nor any other reset signal.
0 = BCD
1 = Binary
Hour Format (HOURFORM)—R/W. Indicates the hour byte format. This bit is not affected by
RSMRST# nor any other reset signal.
0 = Twelve-hour mode. In twelve hour mode, the seventh bit represents AM as zero and PM as one.
1 = Twenty-four hour mode.
Daylight Savings Enable (DSE)—R/W. Triggers two special hour updates per year. The days for the
hour adjustment are those specified in United States federal law as of 1987, which is different than
previous years. This bit is not affected by RSMRST# nor any other reset signal.
0
0 = Daylight Savings Time updates do not occur.
1 = a) Update on the first Sunday in April, where time increments from 1:59:59 AM to 3:00:00 AM.
b) Update on the last Sunday in October when the time first reaches 1:59:59 AM, it is changed to
1:00:00 AM. The time must increment normally for at least two update cycles (seconds) previous
to these conditions for the time change to occur properly.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-49
LPC Interface Bridge Registers (D31:F0)
9.6.2.3
RTC_REGC—Register C (Flag Register)
RTC Index:
Default Value:
Lockable:
0Ch
00U00000 (U: Undefined)
No
Attribute:
Size:
Power Well:
RO
8-bit
RTC
Writes to Register C have no effect.
Bit
Description
7
Interrupt Request Flag (IRQF)—RO. IRQF = (PF * PIE) + (AF * AIE) + (UF *UFE). This also causes
the CH_IRQ_B signal to be asserted. This bit is cleared upon RSMRST# or a read of Register C.
Periodic Interrupt Flag (PF)—RO. This bit is cleared upon RSMRST# or a read of Register C.
6
0 = If no taps are specified via the RS bits in Register A, this flag will not be set.
1 = Periodic interrupt Flag will be 1 when the tap specified by the RS bits of register A is 1.
Alarm Flag (AF)—RO.
5
0 = This bit is cleared upon RTCRST# or a read of Register C.
1 = Alarm Flag will be set after all Alarm values match the current time.
4
0 = The bit is cleared upon RSMRST# or a read of Register C.
1 = Set immediately following an update cycle for each second.
Update-ended Flag (UF)—RO.
3:0
9.6.2.4
Reserved. Will always report 0.
RTC_REGD—Register D (Flag Register)
RTC Index:
Default Value:
Lockable:
0Dh
10UUUUUU (U: Undefined)
No
Bit
Attribute:
Size:
Power Well:
R/W
8-bit
RTC
Description
Valid RAM and Time Bit (VRT)—R/W.
7
0 = This bit should always be written as a 0 for write cycle; however, it will return a 1 for read cycles.
1 = The Valid Ram and Time bit is set to 1 when the PWRGD (power good) signal provided is high.
This feature is not typically used.
6
Reserved. This bit always returns a 0 and should be set to 0 for write cycles.
5:0
9-50
Date Alarm—R/W. These bits store the date of month alarm value. If set to 000000b, then a don’t
care state is assumed. The host must configure the date alarm for these bits to do anything, yet they
can be written at any time. If the date alarm is not enabled, these bits will return zeros to mimic the
functionality of the Motorola* 146818B. These bits are not affected by RESET.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.7
Processor Interface Registers
9.7.1
NMI_SC—NMI Status and Control Register
I/O Address:
Default Value:
Lockable:
61h
00h
No
Attribute:
Size:
Power Well:
R/W (some bits RO)
8-bit
Core
Bit
Description
7
SERR# NMI Source Status (SERR#_NMI_STS)—RO.
1 = PCI agent detected a system error and pulses the PCI SERR# line. This interrupt source is
enabled by setting bit 2 to 0. To reset the interrupt, set bit 2 to 1 and then set it to 0. When writing
to port 61h, this bit must be 0.
6
IOCHK# NMI Source Status (IOCHK_NMI_STS)—RO.
1 = An ISA agent (via SERIRQ) asserted IOCHK# on the ISA bus. This interrupt source is enabled
by setting bit 3 to 0. To reset the interrupt, set bit 3 to 0 and then set it to 1. When writing to port
61h, this bit must be a 0.
5
Timer Counter 2 OUT Status (TMR2_OUT_STS)—RO. This bit reflects the current state of the 8254
counter 2 output. Counter 2 must be programmed following any PCI reset for this bit to have a
determinate value. When writing to port 61h, this bit must be a 0.
4
Refresh Cycle Toggle (REF_TOGGLE)—RO. This signal toggles from either 0 to 1 or 1 to 0 at a rate
that is equivalent to when refresh cycles would occur. When writing to port 61h, this bit must be a 0.
IOCHK# NMI Enable (IOCHK_NMI_EN)—R/W.
3
0 = Enabled.
1 = Disabled and cleared.
PCI SERR# Enable (PCI_SERR_EN)—R/W.
2
0 = SERR# NMIs are enabled.
1 = SERR# NMIs are disabled and cleared.
Speaker Data Enable (SPKR_DAT_EN)—R/W.
1
0 = SPKR output is a 0.
1 = SPKR output is equivalent to the Counter 2 OUT signal value.
Timer Counter 2 Enable (TIM_CNT2_EN)—R/W.
0
0 = Disable.
1 = Enable
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-51
LPC Interface Bridge Registers (D31:F0)
9.7.2
NMI_EN—NMI Enable (and Real Time Clock Index)
I/O Address:
Default Value:
Lockable:
Note:
70h
80h
No
Attribute:
Size:
Power Well:
R/W (Special)
8-bit
Core
The RTC Index field is write-only for normal operation. This field can only be read in Alt-Access
Mode. Note, however, that this register is aliased to Port 74h (documented in Table 19-2), and all
bits are readable at that address.
Bits
Description
NMI Enable (NMI_EN)—R/W.
7
6:0
9.7.3
0 = Enable NMI sources.
1 = Disable All NMI sources.
Real Time Clock Index Address (RTC_INDX)—R/W. This data goes to the RTC to select which
register or CMOS RAM address is being accessed.
PORT92—Fast A20 and Init Register
I/O Address:
Default Value:
Lockable:
92h
00h
No
Bit
7:2
1
0
9.7.4
R/W
8-bit
Core
Description
Reserved.
Alternate A20 Gate (ALT_A20_GATE)—R/W. This bit is ORed with the A20GATE input signal to
generate A20M# to the processor.
0 = A20M# signal can potentially go active.
1 = This bit is set when INIT# goes active.
Interrupt Now (INIT_NOW)—R/W. When this bit transitions from a 0 to a 1, the ICH2 will force
INIT# active for 16 PCI clocks.
COPROC_ERR—Coprocessor Error Register
I/O Address:
Default Value:
Lockable:
9-52
Attribute:
Size:
Power Well:
F0h
00h
No
Attribute:
Size:
Power Well:
WO
8-bits
Core
Bits
Description
7:0
Coprocessor Error (COPROC_ERR)—WO. Any value written to this register will cause IGNNE# to
go active, if FERR# had generated an internal IRQ13. For FERR# to generate an internal IRQ13,
the COPROC_ERR_EN bit (Device 31:Function 0, Offset D0, Bit 13) must be 1.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.7.5
RST_CNT—Reset Control Register
I/O Address:
Default Value:
Lockable:
CF9h
00h
No
Bit
7:4
3
Attribute:
Size:
Power Well:
R/W
8-bit
Core
Description
Reserved.
Full Reset (FULL_RST)—R/W. This bit is used to determine the states of SLP_S3# and SLP_S5#
after a CF9 hard reset (SYS_RST =1 and RST_CPU is set to 1), after PWROK going low (with
RSMRST# high), or after two TCO time-outs.
1 = ICH2 will drive SLP_S3# and SLP_S5# low for 3–5 seconds.
0 = ICH2 will keep SLP_S3# and SLP_S5# high.
2
Reset Processor (RST_CPU)—R/W. When this bit transitions from a 0 to a 1, it initiates a hard or
soft reset, as determined by the SYS_RST bit (bit 1 of this register).
System Reset (SYS_RST)—R/W. This bit is used to determine a hard or soft reset to the
processor.
1
1 = When RST_CPU bit goes from 0 to 1, the ICH2 performs a hard reset by activating PCIRST# for
1 millisecond. It also resets the resume well bits (except for those noted throughout the
datasheet).
0 = When RST_CPU bit goes from 0 to 1, the ICH2 performs a soft reset by activating INIT# for 16
PCI clocks.
0
Reserved.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-53
LPC Interface Bridge Registers (D31:F0)
9.8
Power Management Registers (D31:F0)
The power management registers are distributed within the PCI Device 31: Function 0 space, as
well as a separate I/O range. Each register is described below. Unless otherwise indicate, bits are in
the main (core) power well.
Bits not explicitly defined in each register are assumed to be reserved. When writing to a reserved
bit, the value should always be 0. Software should not attempt to use the value read from a reserved
bit, as it may not be consistently 1 or 0.
9.8.1
Power Management PCI Configuration Registers (D31:F0)
Table 9-8 shows a small part of the configuration space for PCI Device 31: Function 0. It includes
only those registers dedicated for power management. Some of the registers are only used for
Legacy Power management schemes.
Table 9-8. PCI Configuration Map (PM—D31:F0)
9.8.1.1
Offset
Mnemonic
Register Name/Function
40h–43h
ACPI_BASE
ACPI Base Address
44h
ACPI_CNTL
ACPI Control
A0h
GEN_PMCON_1
Default
Type
00000001h
R/W
00h
R/W
General Power Management Configuration 1
0000h
R/W
A2h
GEN_PMCON_2
General Power Management Configuration 2
0000h
R/W
A4h
GEN_PMCON_3
General Power Management Configuration 3
00h
R/W
00000000h
R/W
B8–BBh
GPI_ROUT
C0
TRP_FWD_EN
C4–CAh
MON[n]_TRP_RNG
CCh
MON_TRP_MSK
GPI Route Control
I/O Monitor Trap Forwarding Enable
I/O Monitor[4:7] Trap Range
0000h
R/W
I/O Monitor Trap Range Mask
0000h
R/W
GEN_PMCON_1—General PM Configuration 1 Register (PM—D31:F0)
Offset Address:
Default Value:
Lockable:
A0h
00h
No
Bit
Attribute:
Size:
Usage:
Power Well:
R/W
16-bit
ACPI, Legacy
Core
Description
ICH2 (82801BA):
Reserved
ICH2-M (82801BAM):
15:12
Global Standby Timer Timeout Count (GST_TIMEOUT) — R/W. For the ICH2-M, this field sets
the number of clock ticks that the Global Standby Timer counts before generating a wake event.
The GST starts counting when the ICH2-M enters the S1 state. If a value of 0h is entered in this
field, the GST does not count and no wake event is generated. The GST_TICK bit sets the tick rate.
ICH2 (82801BA):
Reserved
11
ICH2-M (82801BAM):
Global Standby Timer Tick Rate (GST_TICK) — R/W.
0 = 1 minute resolution. This yields a GST timeout range of 1 to 15 minutes.
1 = 32 minute resolution, This yields a GST timeout range of 32 minutes to 8 hours.
9-54
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
Bit
Description
Software SMI Rate Select (SWSMI_RATE_SEL)—R/W.
10
9
8:7
6
0 = SWSMI Timer will time out in 64 ms ± 4 ms (default).
1 = SWSMI Timer will time out in 1.5 ms ± 0.5 ms.
PWRBTN# Level (PWRBTN_LVL)—RO. This read-only bit indicates the current state of the
PWRBTN# signal.
0 = Low.
1 = High.
Reserved.
iiA64 Processor Mode Enable (A64_EN)—R/W. Set by software to indicate the presence of an
iA64 processor.
0 = iA32 processor mode.
1 = iA64 processor mode.
CPU SLP# Enable (CPUSLP_EN)—R/W.
0 = Disable..
ICH2 (82801BA):
1 = Enables the CPUSLP# signal to go active in the S1 state. This reduces the processor power.
5
Note that CPUSLP# will go active on entry to S3, S4 and S5 even if this bit is not set.
ICH2-M (82801BAM):
1 = Enables the CPUSLP# signal to go active in the C3 state. This reduces the processor power.
Note that CPUSLP# goes active during SpeedStep™ transitions and on entry to S1, S3, S4 and
S5 even if this bit is not set.
4
Reserved.
ICH2 (82801BA):
Reserved
ICH2-M (82801BAM):
3
Intel® SpeedStep™ Enable (SS_EN)— R/W.
0 = Intel® SpeedStep™ logic is disabled and the SS_CNT register will not be visible (reads to
SS_CNT return 00h and writes have no effect).
1 = Intel® SpeedStep™ logic is enabled.
ICH2 (82801BA):
Reserved
ICH2-M (82801BAM):
PCI CLKRUN# Enable (CLKRUN_EN)— R/W.
2
0 = Disable. ICH2-M drives the CLKRUN# signal low.
1 = Enable CLKRUN# logic to control the system PCI clock via the CLKRUN# and STP_PCI#
signals.
Note that when the SLP_EN# bit is set, the ICH2-M drives the CLKRUN# signal low, regardless of
the state of the CLKRUN_EN bit. This ensures that the PCI and LPC clocks continue running during
a transition to a sleep state.
Periodic SMI# rate Select (PER_SMI_SEL)—R/W. Set by software to control the rate at which
periodic SMI# is generated.
00 = 1 minute
1:0
01 = 32 seconds
10 = 16 seconds
11 = 8 seconds
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-55
LPC Interface Bridge Registers (D31:F0)
9.8.1.2
GEN_PMCON_2—General PM Configuration 2 Register (PM—D31:F0)
Offset Address:
Default Value:
Lockable:
A2h
00h
No
Bit
7:2
Attribute:
Size:
Usage:
Power Well:
R/WC
16-bit
ACPI, Legacy
Resume
Description
Reserved.
CPU Power Failure (CPUPWR_FLR)—R/WC.
1
0 = Software clears this bit by writing a 1 to the bit position..
ICH2 (82801BA):
1 = Indicates that the VRMPWRGD signal from the processor’s VRM went low.
ICH2-M (82801BAM):
1 = Indicates that the VGATE signal from the processor’s VRM went low. This bit will not be set if
VGATE went low due to a Intel® SpeedStep™ transition.
PWROK Failure (PWROK_FLR)—R/WC.
0 = Software clears this bit by writing a 1 to the bit position, or when the system goes into a G3
state.
1 = This bit will be set any time PWROK goes low, when the system was in S0 or S1 state. The bit
will be cleared only by software by writing a 1 to this bit or when the system goes to a G3 state.
0
9-56
Note: Traditional designs have a reset button logically ANDed with the PWROK signal from the
power supply and the processor’s voltage regulator module. If this is done with the ICH2, the
PWROK_FLR bit will be set. The ICH2 treats this internally as if the RSMRST# signal had
gone active. However, it is not treated as a full power failure. If PWROK goes inactive and
then active (but RSMRST# stays high), then the ICH2 will reboot (regardless of the state of
the AFTERG3 bit). If the RSMRST# signal also goes low before PWROK goes high, then this
is a full power failure and the reboot policy is controlled by the AFTERG3 bit.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.8.1.3
GEN_PMCON_3—General PM Configuration 3 Register (PM—D31:F0)
Offset Address:
Default Value:
Lockable:
A4h
00h
No
Attribute:
Size:
Usage:
Power Well:
Bit
7:3
R/W
8-bit
ACPI, Legacy
RTC
Description
Reserved.
RTC Power Status (RTC_PWR_STS)—R/WC.
2
0 = Software clears this bit by writing a 1 to the bit position.
1 = Indicates that the RTC battery was removed or failed. This bit is set when RTCRST# signal is
low.
Note: Clearing CMOS in an ICH-based platform can be done by using a jumper on RTCRST# or
GPI, or using SAFEMODE strap. Implementations should not attempt to clear CMOS by using
a jumper to pull VccRTC low.
Power Failure (PWR_FLR)—R/WC. This bit is in the RTC well and is not cleared by any type of
reset except RTCRST#.
1
0 = Indicates that the trickle current has not failed since the last time the bit was cleared. Software
clears this bit by writing a 1 to the bit position.
1 = Indicates that the trickle current (from the main battery or trickle supply) was removed or failed.
Note: Clearing CMOS in an ICH-based platform can be done by using a jumper on RTCRST# or
GPI, or using SAFEMODE strap. Implementations should not attempt to clear CMOS by using
a jumper to pull VccRTC low.
After G3 State Select (AFTERG3_EN)—R/W. Determines what state to go to when power is reapplied after a power failure (G3 state). This bit is in the RTC well and is not cleared by any type of
reset except writes to CF9h or RTCRST#.
0
9.8.1.4
0 = System will return to S0 state (boot) after power is re-applied.
1 = System will return to the S5 state (except if it was in S4, in which case it will return to S4). In the
S5 state, the only enabled wake event is the Power Button or any enabled wake event that was
preserved through the power failure.
GPI_ROUT—GPI Routing Control Register (PM—D31:F0)
Offset Address:
Default Value:
Lockable:
B8h–BBh
0000h
No
Attribute:
Size:
Power Well:
Bit
31:30
R/W
32-bit
Resume
Description
GPI[15] Route—R/W. See bits 1:0 for description.
Same pattern for GPI[14] through GPI[3]
5:4
GPI[2] Route—R/W. See bits 1:0 for description.
3:2
GPI[1] Route—R/W. See bits 1:0 for description.
GPI[0] Route—R/W. GPIO[13:11,8:6,4:3,1:0] can be routed to cause an SMI or SCI when the
GPI[n]_STS bit is set. If the GPIO is not set to an input, this field has no effect.
If the system is in an S1–S5 state and if the GPE1_EN bit is also set, then the GPI can cause a
Wake event, even if the GPI is NOT routed to cause an SMI# or SCI.
1:0
00 = No effect.
01 = SMI# (if corresponding GPE1_EN bit is also set)
10 = SCI (if corresponding GPE1_EN bit is also set)
11 = Reserved
Note:
GPIOs that are not implemented will not have the corresponding bits implemented in this register.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-57
LPC Interface Bridge Registers (D31:F0)
9.8.1.5
TRP_FWD_EN—IO Monitor Trap Forwarding Enable Register
(PM—D31:F0)
Offset Address:
Default Value:
Lockable:
Power Well:
C0h
00h
No
Core
Attribute:
Size:
Usage:
R/W (Special)
8 bits
Legacy Only
The ICH2 uses this register to enable the monitors to forward cycles to LPC, independent of the
POS_DEC_EN bit and the bits that enable the monitor to generate an SMI#. The only criteria is
that the address passes the decoding logic as determined by the MON[n]_TRP_RNG and
MON_TRP_MSK register settings.
Bit
Description
Monitor 7 Forward Enable (MON7_FWD_EN)—R/W.
7
0 = Disable. Cycles trapped by I/O Monitor 7 will not be forwarded to LPC.
1 = Enable. Cycles trapped by I/O Monitor 7 will be forwarded to LPC.
Monitor 6 Forward Enable (MON6_FWD_EN)—R/W.
6
0 = Disable. Cycles trapped by I/O Monitor 6 will not be forwarded to LPC.
1 = Enable. Cycles trapped by I/O Monitor 6 will be forwarded to LPC.
Monitor 5 Forward Enable (MON5_FWD_EN)—R/W.
5
0 = Disable. Cycles trapped by I/O Monitor 5 will not be forwarded to LPC.
1 = Enable. Cycles trapped by I/O Monitor 5 will be forwarded to LPC.
Monitor 4 Forward Enable (MON4_FWD_EN)—R/W.
4
3:0
9-58
0 = Disable. Cycles trapped by I/O Monitor 4 will not be forwarded to LPC.
1 = Enable. Cycles trapped by I/O Monitor 4 will be forwarded to LPC.
Reserved.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.8.1.6
MON[n]_TRP_RNG—I/O Monitor [4:7] Trap Range Register for
Devices 4–7 (PM—D31:F0)
Offset Address:
Default Value:
Lockable:
Power Well:
C4h, C6h, C8h, CAh
00h
No
Core
Attribute:
Size:
Usage:
R/W
16 bits
Legacy Only
These registers set the ranges that Device Monitors 4–7 should trap. Offset 4Ch corresponds to
Monitor 4. Offset C6h corresponds to Monitor 5, etc.
If the trap is enabled in the MON_SMI register and the address is in the trap range (and passes the
mask set in the MON_TRP_MSK register) the ICH2 generates an SMI#. This SMI# occurs if the
address is positively decoded by another device on PCI or by the ICH2 (because it would be
forwarded to LPC or some other ICH2 internal registers). The trap ranges should not point to
registers in the ICH2’s internal IDE, USB, AC’97 or LAN I/O space. If the cycle is to be claimed
by the ICH2 and targets one of the permitted ICH2 internal registers (interrupt controller, RTC,
etc.), the cycle will complete to the intended target and an SMI# will be generated (this is the same
functionality as the ICH component). If the cycle is to be claimed by the ICH2 and the intended
target is on LPC, an SMI# will be generated but the cycle will only be forwarded to the intended
target if forwarding to LPC is enabled via the TRP_FWD_EN register settings.
Bit
Description
15:0
Monitor Trap Base Address (MON[n]_TRAP_BASE)—R/W. Base I/O locations that MON[n] traps
(where n = 4, 5, 6 or 7). The range can be mapped anywhere in the processor I/O space
(0–64 KB).
Any access to the range will generate an SMI# if enabled by the associated DEV[n]_TRAP_EN bit in
the MON_SMI register (PMBASE +40h).
9.8.1.7
MON_TRP_MSK—I/O Monitor Trap Range Mask Register for
Devices 4–7 (PM—D31:F0)
Offset Address:
Default Value:
Lockable:
Power Well:
CCh
00h
No
Core
Bit
Attribute:
Size:
Usage:
R/W
16 bits
Legacy Only
Description
15:12
Monitor 7 Forward Mask (MON7_MASK)—R/W. Selects low 4-bit mask for the I/O locations that
MON7 will trap. Similar to MON4_MASK.
11:8
Monitor 6 Forward Mask (MON6_MASK)—R/W. Selects low 4-bit mask for the I/O locations that
MON6 will trap. Similar to MON4_MASK.
7:4
Monitor 5 Forward Mask (MON5_MASK)—R/W. Selects low 4-bit mask for the I/O locations that
MON5 will trap. Similar to MON4_MASK.
3:0
Monitor 4 Forward Mask (MON4_MASK)—R/W. Selects low 4-bit mask for the I/O locations that
MON7 will trap. When a mask bit is set to a 1, the corresponding bit in the base I/O selection will not
be decoded.
For example, if MON4_TRAP_BASE = 1230h, and MON4_MSK = 0011b, the ICH2 will decode
1230h, 1231h, 1232h, and 1233h for Monitor 4.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-59
LPC Interface Bridge Registers (D31:F0)
9.8.2
APM I/O Decode
Table 9-9 shows the I/O registers associated with APM support. This register space is enabled in
the PCI Device 31: Function 0 space (APMDEC_EN), and cannot be moved (fixed I/O location).
Table 9-9. APM Register Map
9.8.2.1
Address
Mnemonic
B2h
APM_CNT
B3h
APM_STS
B2h
00h
No
Core
Bit
7:0
Type
Advanced Power Management Control Port
00h
R/W
Advanced Power Management Status Port
00h
R/W
Attribute:
Size:
Usage:
R/W
8-bit
Legacy Only
Description
Used to pass an APM command between the OS and the SMI handler. Writes to this port not only
store data in the APMC register but also generate an SMI# when the APMC_EN bit is set.
APM_STS—Advanced Power Management Status Port Register
I/O Address:
Default Value:
Lockable:
Power Well:
9-60
Default
APM_CNT—Advanced Power Management Control Port Register
I/O Address:
Default Value:
Lockable:
Power Well:
9.8.2.2
Register Name/Function
B3h
00h
No
Core
Attribute:
Size:
Usage:
R/W
8-bit
Legacy Only
Bit
Description
7:0
Used to pass data between the OS and the SMI handler. Basically, this is a scratchpad register and
is not effected by any other register or function (other than a PCI reset).
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.8.3
Power Management I/O Registers
Table 9-10 shows the registers associated with ACPI and Legacy power management support.
These registers are enabled in the PCI Device 31: Function 0 space (PM_IO_EN), and can be
moved to any I/O location (128-byte aligned). The registers are defined to be compliant with the
ACPI 1.0 specification, and use the same bit names.
Note:
All reserved bits and registers will always return 0 when read, and will have no effect when written.
Table 9-10. ACPI and Legacy I/O Register Map
PMBASE+
Offset
Register Name
ACPI Pointer
Default
Attributes
00–01h
PM1 Status
PM1a_EVT_BLK
0000h
R/W
02–03h
PM1 Enable
PM1a_EVT_BLK+2
0000h
R/W
04–07h
PM1 Control
PM1a_CNT_BLK
00000000h
R/W
08–0Bh
PM1 Timer
PMTMR_BLK
00000000h
RO
0Ch
10h–13h
14h
Reserved
Processor Control
Level 2
—
—
—
P_BLK
00000000h
R/W
P_BLK+4
00h
RO
—
—
—
P_BLK+5
0000h
RO
—
—
—
—
—
—
PM2a_CNT_BLK
0000h
R/W
ICH2 (82801BA):
15h
Reserved
ICH2-M (82801BAM):
Level 3
16–19h
Reserved
ICH2 (82801BA):
20h
Reserved
ICH2-M (82801BAM):
PM2 Control
28–29h
General Purpose Event 0 Status
2A–2Bh
General Purpose Event 0 Enables
2C–2D
General Purpose Event 1 Status
2E–2F
General Purpose Event 1 Enables
GPE0_BLK
0000h
R/W
GPE0_BLK+2
0000h
R/W
GPE1_BLK
0000h
R/W
GPE1_BLK+2
0000h
R/W
30–31h
SMI# Control and Enable
—
0000h
R/W
34–35h
SMI Status Register
—
0000h
R/W
36–3Fh
Reserved
—
0000h
RO
40h
Monitor SMI Status
—
0000h
R/W
42h
Reserved
—
—
—
44h
Device Trap Status
—
0000h
R/W
48h
Trap Enable register
—
0000h
R/W
4Ch–4Dh
Bus Address Tracker
—
Last Cycle
RO
Bus Cycle Tracker
—
Last Cycle
RO
—
—
—
SpeedStep™ Control
—
00h
WO
51–5Fh
Reserved
—
—
—
60h–7Fh
Reserved for TCO Registers
—
—
—
4Eh
ICH2 (82801BA):
50h
Reserved
ICH2-M (82801BAM):
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-61
LPC Interface Bridge Registers (D31:F0)
9.8.3.1
PM1_STS—Power Management 1 Status Register
I/O Address:
Default Value:
Lockable:
Power Well:
PMBASE + 00h
(ACPI PM1a_EVT_BLK)
0000h
No
Bits 0–7: Core,
Bits 8–15: Resume,
except Bit 11 in RTC
Attribute:
Size:
Usage:
R/WC
16-bit
ACPI or Legacy
If bit 10 or 8 in this register is 1 and the corresponding _EN bit is set in the PM1_EN register, ICH2
generates a Wake Event. Once back in an S0 state (or if already in S0 state when the event occurs),
ICH2 also generates an SCI if the SCI_EN bit is set or an SMI# if the SCI_EN bit is not set.
Note:
Bit 5 does not cause an SMI# or a wake event. Bit 0 does not cause a wake event but can cause an
SMI# or SCI.
Bit
Description
Wake Status (WAK_STS)—R/WC. This bit is not affected by hard resets caused by a CF9 write but
is reset by RSMRST#.
0 = Software clears this bit by writing a 1 to the bit position.
1 = Set by hardware when the system is in one of the sleep states (via the SLP_EN bit) and an
enabled wake event occurs. Upon setting this bit, the ICH2 will transition the system to the ON
state.
15
If the AFTERG3_EN bit is not set and a power failure occurs without the SLP_EN bit set, the system
will return to an S0 state when power returns, and the WAK_STS bit will not be set. For the
82801BAM ICH2-M, power failure could result from removing the batteries.
If the AFTERG3_EN bit is set and a power failure occurs without the SLP_EN bit having been set,
the system will go into an S5 state when power returns and a subsequent wake event will cause the
WAK_STS bit to be set. Note that any subsequent wake event would have to be caused by either a
Power Button press or an enabled wake event that was preserved through the power failure (enable
bit in the RTC well).
14:12
Reserved
Power Button Override Status (PRBTNOR_STS)—R/WC. This bit is not affected by hard resets
caused by a CF9 write and is not reset by RSMRST#. Thus, this bit will be preserved through a
power failure.
11
0 = The BIOS or SCI handler can clear this bit by writing a 1 to it.
1 = Set by hardware anytime a Power Button Override Event occurs which occurs when the power
button is pressed for at least 4 consecutive seconds. The power button override causes an
unconditional transition to the S5 state and sets the AFTERG3 bit. This bit can also be set by
the SMBus Slave logic.
RTC Status (RTC_STS)—R/WC. This bit is not affected by hard resets caused by a CF9 write but is
reset by RSMRST#.
10
0 = Software clears this bit by writing a 1 to the bit position.
1 = Set by hardware when the RTC generates an alarm (assertion of the IRQ8# signal).
Additionally if the RTC_EN bit is set, the setting of the RTC_STS bit will generate a wake event.
9
Reserved
8
Power Button Status (PWRBTN_STS)—R/WC. This bit is not affected by hard resets caused by a
CF9 write.
1 = This bit is set by hardware when the PWRBTN# signal is asserted Low, independent of any
other enable bit.
In the S0 state, while PWRBTN_EN and PWRBTN_STS are both set, an SCI (or SMI# if
SCI_EN is not set) will be generated.
In any sleeping state S1–S5, while PWRBTN_EN and PWRBTN_STS are both set, a wake
event is generated.
0 = If the PWRBTN# signal is held low for more than 4 seconds, the hardware clears the
PWRBTN_STS bit, sets the PWRBTNOR_STS bit, and the system transitions to the S5 state
with only PWRBTN# enabled as a wake event.
This bit can be cleared by software by writing a one to the bit position.
9-62
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
Bit
7:6
5
Description
Reserved
Global Status (GBL _STS)—R/WC.
1 = Set when an SCI is generated due to BIOS wanting the attention of the SCI handler. BIOS has
a corresponding bit, BIOS_RLS, which will cause an SCI and set this bit.
0 = The SCI handler should then clear this bit by writing a 1 to the bit location.
ICH2 (82801BA):
Reserved
ICH2-M (82801BAM):
4
Bus Master Status (BM_STS)— R/WC.
1 = Set by the ICH2-M when a bus master requests a break from the C3 state (the bus master
break events are generated by PIRQ[x]# assertion or bus master activity by any of ICH2-M’s
internal bus masters). Bus master activity is detected by any of the PCI requests being active,
any internal bus master request being active, the AGPBUSY# signal being active, or activity on
either of the ICH2-M’s USB Controllers. A USB Controller is considered active if all three of the
following conditions are true
1. The controller is not in Global Suspend
2. At least one of the controller’s ports is not suspended
3. The USB RUN bit is set
Bus Master IDE Controller activity also causes BM_STS to be set. The ICH2-M’s BMIDE
Controller is considered active when the Controller’s Start bit is set.
0 = Software clears this bit by writing a 1 to the bit position.
3:1
0
Reserved
Timer Overflow Status (TMROF_STS)—R/WC.
1 = This bit gets set any time bit 22 of the 24-bit timer goes high (bits are numbered from 0 to 23).
This will occur every 2.3435 seconds. When the TMROF_EN bit is set, then the setting of the
TMROF_STS bit will additionally generate an SCI or SMI# (depending on the SCI_EN).
0 = The SCI or SMI# handler clears this bit by writing a 1 to the bit location.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-63
LPC Interface Bridge Registers (D31:F0)
9.8.3.2
PM1_EN—Power Management 1 Enable Register
I/O Address:
PMBASE + 02h
(ACPI PM1a_EVT_BLK + 2)
0000h
No
Bits 0–7: Core,
Bits 8–15: Resume
Default Value:
Lockable:
Power Well:
Bit
15:11
10
Attribute:
Size:
Usage:
R/W
16-bit
ACPI or Legacy
Description
Reserved.
RTC Event Enable (RTC_EN)—R/W. This bit is in the RTC well to allow an RTC event to wake after
a power failure. This bit is not cleared by any reset other than RTCRST# or a Power Button Override
event.
1 = An SCI (or SMI#) or wake event will occur when this bit is set and the RTC_STS bit goes
active.
0 = No SCI (or SMI#) or wake event is generated then RTC_STS goes active.
8
Power Button Enable (PWRBTN_EN)—R/W. This bit is used to enable the setting of the
PWRBTN_STS bit to generate a power management event (SMI#, SCI). PWRBTN_EN has no
effect on the PWRBTN_STS bit being set by the assertion of the power button. The Power Button is
always enabled as a Wake event.
0 = Disable.
1 = Enable.
5
Global Enable (GBL_EN)—R/W. When both the GBL_EN and the GBL_STS are set, an SCI is
raised.
0 = Disable.
1 = Enable SCI on GBL_STS going active.
Timer Overflow Interrupt Enable (TMROF_EN)—R/W. Works in conjunction with the SCI_EN bit
as described below:
0
9-64
TMROF_EN
SCI_EN
0
1
1
x
0
1
Effect when TMROF_STS is set
No SMI# or SCI
SMI#
SCI
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.8.3.3
PM1_CNT—Power Management 1 Control Register
I/O Address:
Default Value:
Lockable:
Power Well:
PMBASE + 04h
(ACPI PM1a_CNT_BLK)
0000h
No
Bits 0–7: Core,
Bits 8–15: Resume
Attribute:
Size:
Usage:
R/W
32-bit
ACPI or Legacy
Bit
Description
13
Sleep Enable (SLP_EN)—WO. Setting this bit causes the system to sequence into the Sleep state
defined by the SLP_TYP field.
Sleep Type (SLP_TYP)—R/W. This 3-bit field defines the type of Sleep the system should enter
when the SLP_EN bit is set to 1.
000 = ON: Typically maps to S0 state..
001 = ICH2 (82801BA): Assert STPCLK#. Puts processor in Stop-Grant state. Optional to assert
CPUSLP# to put processor in sleep state: Typically, maps to S1 state.
ICH2-M (82801BAM): Reserved.
12:10
010 = ICH2 (82801BA): Reserved
ICH2-M (82801BAM): Assert SLP_S1#: Typically, maps to S1 state.
011 = Reserved
100 = Reserved
101 = Suspend-To-RAM. Assert SLP_S1# and SLP_S3#; typically, maps to S3 state.
110 = Suspend-To-Disk. Assert SLP_S1#, SLP_S3#, and SLP_S5# SLP_S3# and, SLP_S5#;
typically, maps to S4 state.
111 = Soft Off. Assert SLP_S1#, SLP_S3#, and SLP_S5# SLP_S3#, and SLP_S5#; typically, maps
to S5 state.
2
Global Release (GBL_RLS)—WO.
1 = ACPI software writes a 1 to this bit to raise an event to the BIOS. BIOS software has
corresponding enable and status bits to control its ability to receive ACPI events.
0 = This bit always reads as 0.
ICH2 (82801BA):
Reserved
ICH2-M (82801BAM):
1
Bus Master Reload (BM_RLD)— R/W. This bit is reset to 0 by PCIRST#
0 = Bus master requests do not cause a break from the C3 state.
1 = Enable Bus Master requests (internal, external or AGPBUSY#) to cause a break from the C3
state.
0
SCI Enable (SCI_EN)—R/W. Selects the SCI interrupt or the SMI# interrupt for various events
including the bits in the PM1_STS register (bit 10, 8, 0), and bits in GPE0_STS.
0 = These events will generate an SMI#.
1 = These events will generate an SCI.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-65
LPC Interface Bridge Registers (D31:F0)
9.8.3.4
PM1_TMR—Power Management 1 Timer Register
I/O Address:
PMBASE + 08h
(ACPI PMTMR_BLK)
Default Value:
Lockable:
Power Well:
xx000000h
No
Core
Bit
31:24
23:0
9.8.3.5
Attribute:
Size:
Usage:
RO
32-bit
ACPI
Description
Reserved
Timer Value (TMR_VAL)—RO. Returns the running count of the PM timer. This counter runs off a
3.579545 MHz clock (14.31818 MHz divided by 4). It is reset to zero during a PCI reset and then
continues counting as long as the system is in the S0 state.
Anytime bit 22 of the timer goes HIGH to LOW (bits referenced from 0 to 23), the TMROF_STS bit is
set. The High-to-Low transition will occur every 2.3435 seconds. If the TMROF_EN bit is set, an SCI
interrupt is also generated.
PROC_CNT—Processor Control Register
I/O Address:
Default Value:
Lockable:
Power Well:
PMBASE + 10h
(ACPI P_BLK)
00000000h
No (bits 7:5 are write once)
Core
Bit
31:18
Attribute:
Size:
Usage:
R/W
32-bit
ACPI or Legacy
Description
Reserved.
Throttle Status (THTL_STS)—RO.
17
16:9
0 = No clock throttling is occurring (maximum processor performance).
1 = Indicates that the clock state machine is in some type of low power state (where the processor
is not running at its maximum performance): thermal throttling or hardware throttling.
Reserved
Force Thermal Throttling (FORCE_THTL)—R/W. Software can set this bit to force the thermal
throttling function. This has the same effect as the THRM# signal being active for 2 seconds.
8
0 = No forced throttling.
1 = Throttling at the duty cycle specified in THRM_DTY starts immediately (no 2 second delay), and
no SMI# is generated.
Thermal Duty Cycle (THRM_DTY). This write-once 3-bit field determines the duty cycle of the
throttling when the thermal override condition occurs. The duty cycle indicates the approximate
percentage of time the STPCLK# signal is asserted while in the throttle mode. The STPCLK# throttle
period is 1024 PCICLKs. Note that the throttling only occurs if the system is in the C0 state. If in the
C2 state, no throttling occurs.
There is no enable bit for thermal throttling, because it should not be disabled. Once the
THRM_DTY field is written, any subsequent writes will have no effect until PCIRST# goes active.
7:5
THRM_DTY
000
001
010
011
100
101
110
111
9-66
Throttle Mode
RESERVED (Default)
(Will be 50%)
87.5%
75.0%
62.5%
50%
37.5%
25%
12.5%
PCI Clocks
512
896
768
640
512
384
256
128
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
Bit
4
Description
Throttling Enable (THTL_EN). When this bit is set and the system is in a C0 state, processorcontrolled STPCLK# throttling is enabled. The duty cycle is selected in the THTL_DTY field.
0 = Disable
1 = Enable
Throttling Duty Cycle (THTL_DTY). This 3-bit field determines the duty cycle of the throttling when
the THTL_EN bit is set. The duty cycle indicates the approximate percentage of time the STPCLK#
signal is asserted (low) while in the throttle mode. The STPCLK# throttle period is 1024 PCICLKs.
3:1
0
9.8.3.6
THTL_DTY
Throttle Mode
PCI Clocks
000
RESERVED (Default)
(Will be 50%)
87.5%
75.0%
62.5%
50%
37.5%
25%
12.5%
512
001
010
011
100
101
110
111
Reserved
LV2—Level 2 Register
I/O Address:
Default Value:
Lockable:
Power Well:
9.8.3.7
896
768
640
512
384
256
128
PMBASE + 14h
(ACPI P_BLK+4)
00h
No
Core
Attribute:
Size:
Usage:
RO
8-bit
ACPI or Legacy
Bit
Description
7:0
Reads to this register return all zeros; writes have no effect. Reads to this register generate a “enter
a level 2 power state” (C2) to the clock control logic. This causes the STPCLK# signal to go active,
and stay active until a break event occurs. Throttling (due either to THTL_EN or THRM# override)
will be ignored.
LV3—Level 3 Register (82801BAM ICH2-M)
I/O Address:
Default Value:
Lockable:
PMBASE + 15h (ACPI P_BLK + 5)
Attribute:
00h
Size:
No
Usage:
Power Well:
Bit
7:0
RO
8-bit
ACPI or Legacy
Core
Description
Reads to this register return all zeros, writes to this register have no effect. Reads to this register
generate an “enter a C3 power state” to the clock control logic. The C3 state persists until a break
event occurs.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-67
LPC Interface Bridge Registers (D31:F0)
9.8.3.8
PM2_CNT—Power Management 2 Control (82801BAM ICH2-M)
I/O Address:
Default Value:
Lockable:
Power Well:
PMBASE + 20h
(ACPI PM2_BLK)
00h
No
Core
Bit
7:1
Attribute:
Size:
Usage:
R/W
8-bit
ACPI
Description
Reserved.
Arbiter Disable (ARB_DIS)— R/W.
0 = Enable system arbiter. The arbiter can grant the bus to bus masters (internal devices or external
PCI devices), other than the processor.
0
9.8.3.9
1 = Disable system arbiter (default). Processor has ownership of the system bus and memory. No
bus masters (internal or external) are granted the bus. Note that after the arbiter is disabled, the
processor must not initiate any down-bound reads to PCI devices that may have up-bound
posted data, as this will result in system deadlock.
GPE0_STS—General Purpose Event 0 Status Register
I/O Address:
Default Value:
Lockable:
Power Well:
Note:
PMBASE + 28h
(ACPI GPE0_BLK)
0000h
No
Resume
Attribute:
Size:
Usage:
R/WC
16-bit
ACPI
This register is symmetrical to the General Purpose Event 0 Enable Register. If the corresponding
seen bit is set, then when the _STS bit get set, ICH2 generates a Wake Event. Once back in an S0
state (or if already in an S0 state when the event occurs), ICH2 also generates an SCI if the SCI_EN
bit is set, or an SMI# if the SCI_EN bit is not set. There will be no SCI/SMI# or wake event on
THRMOR_STS since there is no corresponding x_EN bit. None of these bits are reset by CF9h
write. All are reset by RSMRST#.
Bit
15:12
Description
Reserved.
PME Status (PME_STS)—R/WC.
11
0 = Software clears this bit by writing a 1 to the bit position.
1 = Set by hardware when the PME# signal goes active. Additionally, if the PME_EN bit is set, and
the system is in an S0 state, then the setting of the PME_STS bit will generate an SCI or SMI#
(if SCI_EN is not set). If the PME_EN bit is set, and the system is in an S1–S4 state (or S5 state
due to setting SLP_TYP and SLP_EN), then the setting of the PME_STS bit will generate a
wake event, and an SCI will be generated. If the system is in an S5 state due to power button
override or a power failure, then PME_STS will not cause a wake event or SCI.
ICH2 (82801BA):
Reserved
10
ICH2-M (82801BAM):
BATLOW_STS — R/WC.
0 = Software clears this bit by writing a 1 to the bit position.
1 = Set by hardware when the BATLOW# signal is asserted.
9-68
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
Bit
Description
ICH2 (82801BA):
Reserved
ICH2-M (82801BAM):
9
Global Standby Timer Status (GST_STS)— R/WC.
0 = Software clears this bit by writing a 1 to the bit position.
1 = Set by hardware to indicate that the wake event was due to GST timeout. This bit will only be
set when the system was in the S1 state.
RI_STS—R/WC.
8
0 = Software clears this bit by writing a 1 to the bit position.
1 = Set by hardware when the RI# input signal goes active.
SMBus Wake Status (SMB_WAK_STS)—R/WC. SMBus Wake Status—R/WC. The SMBus
controller can independently cause an SMI# or SCI; thus, this bit does not need to do so (unlike the
other bits in this register).
7
0 = Software clears this bit by writing a 1 to the bit position.
1 = Set by hardware to indicate that the wake event was caused by the ICH2’s SMBus logic. This
bit is set by the WAKE/SMI# command type, even if the system is already awake. The SMI
handler should then clear this bit.
TCO SCI Status (TCOSCI_STS)—R/WC.
6
0 = Software clears this bit by writing a 1 to the bit position.
1 = Set by hardware when the TCO logic causes an SCI.
AC97 Status (AC97_STS)—R/WC.
5
0 = Software clears this bit by writing a 1 to the bit position.
1 = Set by hardware when the codecs are attempting to wake the system. The AC97_STS bit gets
set only from the following two cases:
1. ACSDIN[1] or ACSDIN[0] is high and BITCLK is not oscillating, or
2. The GSCI bit is set (section 13.2.9, NAMBAR +30h, bit 0)
USB Controller 2 Status (USB2_STS)—R/WC.
4
0 = Software clears this bit by writing a 1 to the bit position.
1 = Set by hardware when USB Controller 2 needs to cause a wake. Wake event will be generated
if the corresponding USB2_EN bit is set.
USB Controller 1 Status (USB1_STS)—R/WC.
3
0 = Software clears this bit by writing a 1 to the bit position.
1 = Set by hardware when USB Controller 1 needs to cause a wake. Wake event will be generated
if the corresponding USB1_EN bit is set.
2
Reserved.
Thermal Interrupt Override Status (THRMOR_STS)—R/WC.
1
0 = Software clears this bit by writing a 1 to the bit position.
1 = This bit is set by hardware anytime a thermal over-ride condition occurs and starts throttling the
processor’s clock at the THRM_DTY ratio. This will not cause an SMI#, SCI, or wake event.
Thermal Interrupt Status (THRM_STS)—R/WC.
0
0 = Software clears this bit by writing a 1 to the bit position.
1 = Set by hardware anytime the THRM# signal is driven active as defined by the THRM_POL bit.
Additionally, if the THRM_EN bit is set, then the setting of the THRM_STS bit will also generate
a power management event (SCI or SMI#).
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-69
LPC Interface Bridge Registers (D31:F0)
9.8.3.10
GPE0_EN—General Purpose Event 0 Enables Register
I/O Address:
Default Value:
Lockable:
Power Well:
Note:
PMBASE + 2Ah
(ACPI GPE0_BLK + 2)
0000h
No
Bits 0–7 Resume,
Bits 8–15 RTC
Attribute:
Size:
Usage:
R/W
16-bit
ACPI
This register is symmetrical to the General Purpose Event 0 Status Register. All the bits in this
register should be cleared to 0 based on a Power Button Override. The resume well bits are all
cleared by RSMRST#. The RTC sell bits are cleared by RTCRST#.
Bit
15:12
Description
Reserved.
PME# Enable (PME_EN)—R/W.
11
0 = Disable.
1 = Enables the setting of the PME_STS to generate a wake event and/or an SCI. PME# can be
a wake event from the S1–S4 state or from S5 (if entered via SLP_EN, but not power button
override).
ICH2 (82801BA):
Reserved
ICH2-M (82801BAM):
10
BATLOW_EN — R/W.
0 = Disable.
1 = Enables the BATLOW# signal to cause an SMI# or SCI (depending on the SCI_EN bit) when
it goes low. This bit does not prevent the BATLOW# signal from inhibiting the wake event.
9
8
7
Reserved
RI_EN—R/W. The value of this bit will be maintained through a G3 state and is not affected by a
hard reset caused by RSMRST# or a CF9h write. Assertion of RTCRST# resets this bit.
0 = Disable.
1 = Enables the setting of the RI_STS to generate a wake event.
Reserved
TCO SCI Enable (TCOSCI_EN)—R/W.
6
0 = Disable.
1 = Enables the setting of the TCOSCI_STS to generate an SCI.
AC97 Enable (AC97_EN)—R/W.
5
0 = Disable.
1 = Enables the setting of the AC97_STS to generate a wake event.
USB Controller 2 Enable (USB2_EN)—R/W.
4
0 = Disable.
1 = Enables the setting of the USB2_STS to generate a wake event.
USB Controller 1 Enable (USB1_EN)—R/W.
3
2
1
0 = Disable.
1 = Enables the setting of the USB1_STS to generate a wake event.
Thermal Pin Polarity (THRM#_POL)—R/W. This bit controls the polarity of the THRM# pin
needed to set the THRM_STS bit.
0 = Low value on the THRM# signal will set the THRM_STS bit.
1 = HIGH value on the THRM# signal will set the THRM_STS bit.
Reserved.
Thermal Signal Reporting Enable (THRM_EN)—R/W.
0
9-70
0 = Disable.
1 = Active assertion of the THRM# signal (as defined by the THRM_POL bit) will set the
THRM_STS bit and generate a power management event (SCI or SMI).
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.8.3.11
GPE1_STS—General Purpose Event 1 Status Register
I/O Address:
Default Value:
Lockable:
Power Well:
PMBASE + 2Ch
(ACPI GPE1_BLK)
0000h
No
Resume
Attribute:
Size:
Usage:
R/WC
16-bit
ACPI
Note:
This register is symmetrical to the General Purpose Event 1 Enable Register. GPIOs that are not
implemented will not have the corresponding bits implemented in this register.
Note:
Bits 5 and 2 are not implemented since GPIO5 and GPIO2 are not implemented.
Bit
Description
GPI[15:6] Status (GPI[15:6]_STS)—R/WC.
0 = Software clears each bit by writing a 1 to the bit position when the corresponding GPIO signal
is not active. (The status bit cannot be cleared while the corresponding signal is still active).
1 = These bits are set any time the corresponding GPIO is set up as an input and the
corresponding GPIO signal is low (or high if the corresponding GP_INV bit is set).
15:6
If the corresponding GPI[n]_EN bit is set in the GPE1_EN register, and the GPI[n]_STS bit is
set, then:
- If the system is in an S1_S5 state, the event will also wake the system.
- If the system is in an S0 state (or upon waking back to an S0 state), an SMI# or SCI will
be generated, depending on the GPI_ROUT bits for the corresponding GPI.
5
Reserved
GPI[4:3] Status (GPI[4:3]_STS)—R/WC.
0 = Software clears each bit by writing a 1 to the bit position when the corresponding GPIO signal
is not active. (The status bit cannot be cleared while the corresponding signal is still active).
1 = These bits are set any time the corresponding GPIO is set up as an input and the
corresponding GPIO signal is low (or high if the corresponding GP_INV bit is set).
4:3
If the corresponding GPI[n]_EN bit is set in the GPE1_EN register, and the GPI[n]_STS bit is
set, then:
- If the system is in an S1_S5 state, the event will also wake the system.
- If the system is in an S0 state (or upon waking back to an S0 state), an SMI# or SCI will
be generated, depending on the GPI_ROUT bits for the corresponding GPI.
2
Reserved
GPI[1:0] Status (GPI[1:0]_STS)—R/WC.
0 = Software clears each bit by writing a 1 to the bit position when the corresponding GPIO signal
is not active. (The status bit cannot be cleared while the corresponding signal is still active).
1 = These bits are set any time the corresponding GPIO is set up as an input and the
corresponding GPIO signal is low (or high if the corresponding GP_INV bit is set).
1:0
If the corresponding GPI[n]_EN bit is set in the GPE1_EN register, and the GPI[n]_STS bit is
set, then:
- If the system is in an S1_S5 state, the event will also wake the system.
- If the system is in an S0 state (or upon waking back to an S0 state), an SMI# or SCI will be
generated, depending on the GPI_ROUT bits for the corresponding GPI.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-71
LPC Interface Bridge Registers (D31:F0)
9.8.3.12
GPE1_EN—General Purpose Event 1 Enable Register
I/O Address:
Default Value:
Lockable:
Power Well:
PMBASE + 2Eh
(ACPI GPE1_BLK + 2)
0000h
No
Resume
Attribute:
Size:
Usage:
R/W
16-bit
ACPI
Note:
This register is symmetrical to the General Purpose Event 1 Status Register. GPIOs that are not
implemented will not have the corresponding bits implemented in this register. All of the bits in
this register will be cleared by RSMRST#.
Note:
Bits 5 and 2 are not implemented since GPIO5 and GPIO2 are not implemented.
Bit
Description
15:6
GPI[15:6] Enable (GPI[15:6]_EN)—R/W.
1 = Enable the corresponding GPI[n]_STS bit being set to cause an SMI#, SCI, and/or wake event.
0 = Disable.
5
4:3
Reserved
GPI[4:3] Enable (GPI[4:3]_EN)—R/W.
1 = Enable the corresponding GPI[n]_STS bit being set to cause an SMI#, SCI, and/or wake event.
0 = Disable.
2
1:0
Reserved
GPI[1:0] Enable (GPI[1:0]_EN)—R/W.
1 = Enable the corresponding GPI[n]_STS bit being set to cause an SMI#, SCI, and/or wake event.
0 = Disable.
9.8.3.13
SMI_EN—SMI Control and Enable Register
I/O Address:
Default Value:
Lockable:
Power Well:
PMBASE + 30h
0000h
No
Core
Bit
31:15
Attribute:
Size:
Usage:
R/W
32 bit
ACPI or Legacy
Description
Reserved
Periodic SMI# Enable (PERIODIC_EN)—R/W.
14
0 = Disable.
1 = Enables the ICH2 to generate an SMI# when the PERIODIC_STS bit is set in the SMI_STS
register.
TCO Enable (TCO_EN)—R/W.
13
12
0 = Disables TCO logic generating an SMI#. Note that if the NMI2SMI_EN bit is set, SMIs that are
caused by re-routed NMIs will not be gated by the TCO_EN bit. Even if the TCO_EN bit is 0,
NMIs will still be routed to cause SMIs.
1 = Enables the TCO logic to generate SMI#.
Reserved
Microcontroller SMI# Enable (MCSMI_EN)—R/W.
11
10:8
9-72
0 = Disable.
1 = Enables ICH2 to trap accesses to the microcontroller range (62h or 66h) and generate an
SMI#. Note that ’trapped’ cycles will be claimed by the ICH2 on PCI, but not forwarded to LPC.
Reserved
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
Bit
Description
BIOS Release (BIOS_RLS)—WO.
7
0 = This bit will always return 0 on reads. Writes of 0 to this bit have no effect.
1 = Enables the generation of an SCI interrupt for ACPI software when a one is written to this bit
position by BIOS software.
Software SMI# Timer Enable (SWSMI_TMR_EN)—R/W.
6
0 = Disable. Clearing the SWSMI_TMR_EN bit before the timer expires will reset the timer and the
SMI# will not be generated.
1 = Starts Software SMI# Timer. When the SWSMI timer expires (the time-out period depends
upon the SWSMI_RATE_SEL bit setting), SWSMI_TMR_STS is set and an SMI# is generated.
SWSMI_TMR_EN stays set until cleared by software.
APMC Enable (APMC_EN)—R/W.
5
0 = Disable. Writes to the APM_CNT register will not cause an SMI#.
1 = Enables writes to the APM_CNT register to cause an SMI#.
SLP SMI Enable (SLP_SMI_EN)—R/W.
4
0 = Disables the generation of SMI# on SLP_EN. Note that this bit must be 0 before the software
attempts to transition the system into a sleep state by writing a 1 to the SLP_EN bit.
1 = A write of 1 to the SLP_EN bit (bit 13 in PM1_CNT register) will generate an SMI#, and the
system will not transition to the sleep state based on that write to the SLP_EN bit.
Legacy USB Enable (LEGACY_USB_EN)—R/W.
3
0 = Disable.
1 = Enables legacy USB circuit to cause SMI#.
BIOS Enable (BIOS_EN)—R/W.
2
1
0 = Disable.
1 = Enables the generation of SMI# when ACPI software writes a 1 to the GBL_RLS bit.
End of SMI (EOS)—R/W (special). This bit controls the arbitration of the SMI signal to the
processor. This bit must be set for the ICH2 to assert SMI# low to the processor.
1 = When this bit is set, SMI# signal will be deasserted for 4 PCI clocks before its assertion. In the
SMI handler, the processor should clear all pending SMIs (by servicing them and then clearing
their respective status bits), set the EOS bit, and exit SMM. This will allow the SMI arbiter to reassert SMI upon detection of an SMI event and the setting of a SMI status bit.
0 = Once the ICH2 asserts SMI# low, the EOS bit is automatically cleared.
Global SMI Enable (GBL_SMI_EN)—R/W.
0
0 = No SMI# will be generated by ICH2. This bit is reset by a PCI reset event.
1 = Enables the generation of SMI# in the system upon any enabled SMI event.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-73
LPC Interface Bridge Registers (D31:F0)
9.8.3.14
SMI_STS—SMI Status Register
I/O Address:
Default Value:
Lockable:
Power Well:
Note:
PMBASE + 34h
0000h
No
Core
Attribute:
Size:
Usage:
R/W
32-bit
ACPI or Legacy
If the corresponding _EN bit is set when the _STS bit is set, the ICH2 will cause an SMI# (except
bits 8:10 and 12, which do not need enable bits since they are logic ORs of other registers that have
enable bits).
Bit
31:17
16
Description
Reserved
SMBus SMI Status (SMBUS_SMI_STS)—R/WC.
1 = Indicates that the SMI# was caused by either the SMBus Slave receiving a message, or the
SMBALERT# signal going active. This bit will be set on SMBALERT# assertion only if the
SMBus Host Controller is programmed to generate SMIs (not interrupts).
0 = This bit is cleared by writing a 1 to its bit position.
15
SERR IRQ SMI Status (SERIRQ_SMI_STS)—RO.
1 = Indicates that the SMI# was caused by the SERIRQ decoder.
0 = SMI# was not caused by SERIRQ decoder. This is not a sticky bit.
14
Periodic Status (PERIODIC_STS)—R/WC.
1 = This bit will be set at the rate determined by the PER_SMI_SEL bits. If the PERIODIC_EN bit is
also set, the ICH2 will generate an SMI#.
0 = This bit is cleared by writing a 1 to its bit position.
TCO Status (TCO_STS)—RO.
13
12
0 = SMI# not caused by TCO logic.
1 = Indicates the SMI# was caused by the TCO logic. Note that this is not a wake event.
Device Monitor Status (DEVMON_STS)—RO.
1 = Set under any of the following conditions:
- Any of the DEV[7:4]_TRAP_STS bits are set and the corresponding DEV[7:4]_TRAP_EN bits
are also set.
- Any of the DEVTRAP_STS bits are set and the corresponding DEVTRAP_EN bits are also set.
0 = SMI# not caused by Device Monitor.
Microcontroller SMI# Status (MCSMI_STS)—R/WC.
11
10
0 = Indicates that there has been no access to the power management microcontroller range (62h or
66h). This bit is cleared by software writing a 1 to the bit position.
1 = Set if there has been an access to the power management microcontroller range (62h or 66h). If
this bit is set, and the MCSMI_EN bit is also set, the ICH2 will generate an SMI#.
GPE1 Status (GPE1_STS)—RO. This bit is a logical OR of the bits in the GPE1_STS register that
are also set up to cause an SMI# (as indicated by the GPI_ROUT registers) and have the
corresponding bit set in the GPE1_EN register. Bits that are not routed to cause an SMI# will have no
effect on the GPE1_STS bit.
0 = SMI# was not generated by a GPI assertion.
1 = SMI# was generated by a GPI assertion.
9
8
7
9-74
GPE0 Status (GPE0_STS)—RO. This bit is a logical OR of the bits in the GPE0_STS register that
also have the corresponding bit set in the GPE0_EN register.
0 = SMI# was not generated by a GPE0 event.
1 = SMI# was generated by a GPE0 event.
PM1 Status Register (PM1_STS_REG)—RO. This is an OR of the bits in the ACPI PM1 Status
Register (offset PMBASE+00h) that can cause an SMI#.
0 = SMI# was not generated by a PM1_STS event.
1 = SMI# was generated by a PM1_STS event.
Reserved.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
Bit
6
Description
Software SMI Timer Status (SWSMI_TMR_STS)—R/WC.
1 = Set by the hardware when the Software SMI# Timer expires.
0 = Software clears this bit by writing a 1 to the bit location.
5
APM Status (APM_STS)—R/WC.
1 = SMI# was generated by a write access to the APM control register with the APMC_EN bit set.
0 = Software clears this bit by writing a 1 to the bit location.
4
SLP SMI Status (SLP_SMI_STS)—R/WC.
1 = Indicates an SMI# was caused by a write of 1 to SLP_EN bit when SLP_SMI_EN bit is also set.
0 = Software clears this bit by writing a 1 to the bit location.
3
Legacy USB Status (LEGACY_USB_STS)—RO. This bit is a logical OR of each of the SMI status
bits in the USB Legacy Keyboard/Mouse Control Registers ANDed with the corresponding enable
bits. This bit will not be active if the enable bits are not set.
0 = SMI# was not generated by USB Legacy event.
1 = SMI# was generated by USB Legacy event.
2
BIOS Status (BIOS_STS)—R/WC.
1 = SMI# was generated due to ACPI software requesting attention (writing a 1 to the GBL_RLS bit
with the BIOS_EN bit set).
0 = This bit cleared by software writing a 1 to its bit position.
1:0
9.8.3.15
Reserved.
MON_SMI—Device Monitor SMI Status and Enable Register
I/O Address:
Default Value:
Lockable:
Power Well:
PMBASE +40h
0000h
No
Core
Bit
15:12
Attribute:
Size:
Usage:
R/W, R/WC
16-bit
Legacy Only
Description
Device 7:4 Trap Status (DEV[7:4]_TRAP_STS)—R/WC. Bit 12 corresponds to Monitor 4, bit 13
corresponds to Monitor 5 etc.
1 = SMI# was caused by an access to the corresponding device monitor’s I/O range.
0 = SMI# was not caused by the associated device monitor.
11:8
Device 7:4 Trap Enable (DEV[7:4]_TRAP_EN)—R/W. Bit 8 corresponds to Monitor 4, bit 9
corresponds to Monitor 5 etc.
1 = Enables SMI# due to an access to the corresponding device monitor’s I/O range.
7:0
Reserved
0 = Disable.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-75
LPC Interface Bridge Registers (D31:F0)
9.8.3.16
DEVACT_STS—Device Activity Status Register
I/O Address:
Default Value:
Lockable:
Power Well:
PMBASE +44h
0000h
No
Core
Attribute:
Size:
Usage:
R/WC
16-bit
Legacy Only
This register is used in conjunction with the Periodic SMI# timer to detect any system activity for
legacy power management.
Bit
15:14
Description
Reserved
ADLIB Activity Status (ADLIB_ACT_STS)—R/WC.
13
0 = Indicates that there has been no access to this device’s I/O range.
1 = This device’s I/O range has been accessed. Clear this bit by writing a 1 to the bit location.
Keyboard Controller Activity Status (KBC_ACT_STS)—R/WC. KBC (60/64h).
12
0 = Indicates that there has been no access to this device’s I/O range.
1 = This device’s I/O range has been accessed. Clear this bit by writing a 1 to the bit location.
MIDI Activity Status (MIDI_ACT_STS)—R/WC.
11
0 = Indicates that there has been no access to this device’s I/O range.
1 = This device’s I/O range has been accessed. Clear this bit by writing a 1 to the bit location.
Audio Activity Status (AUDIO_ACT_STS)—R/WC. Audio (Sound Blaster “ORed” with MSS).
10
0 = Indicates that there has been no access to this device’s I/O range.
1 = This device’s I/O range has been accessed. Clear this bit by writing a 1 to the bit location.
PIRQ[D or H] Activity Status (PIRQDH_ACT_STS)—R/WC.
9
0 = The corresponding PCI interrupts have not been active.
1 = At least one of the corresponding PCI interrupts has been active. Clear this bit by writing a 1 to
the bit location.
PIRQ[C or G] Activity Status (PIRQCG_ACT_STS)—R/WC.
8
0 = The corresponding PCI interrupts have not been active.
1 = At least one of the corresponding PCI interrupts has been active. Clear this bit by writing a 1 to
the bit location.
PIRQ[B or F] Activity Status (PIRQBF_ACT_STS)—R/WC.
7
0 = The corresponding PCI interrupts have not been active.
1 = At least one of the corresponding PCI interrupts has been active. Clear this bit by writing a 1 to
the bit location.
PIRQ[A or E] Activity Status (PIRQAE_ACT_STS)—R/WC.
6
5
0 = The corresponding PCI interrupts have not been active.
1 = At least one of the corresponding PCI interrupts has been active. Clear this bit by writing a 1 to
the bit location.
Legacy Activity Status (LEG_ACT_STS)—R/WC. Parallel Port, Serial Port 1, Serial Port 2, Floppy
Disk Controller.
0 = Indicates that there has been no access to this device’s I/O range.
1 = This device’s I/O range has been accessed. Clear this bit by writing a 1 to the bit location.
4
Reserved.
3
0 = Indicates that there has been no access to this device’s I/O range.
1 = This device’s I/O range has been accessed. Clear this bit by writing a 1 to the bit location.
IDE Secondary Drive 1 Activity Status (IDES1_ACT_STS)—R/WC.
IDE Secondary Drive 0 Activity Status (IDES0_ACT_STS)—R/WC.
2
9-76
0 = Indicates that there has been no access to this device’s I/O range.
1 = This device’s I/O range has been accessed. Clear this bit by writing a 1 to the bit location.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
Bit
Description
IDE Primary Drive 1 Activity Status (IDEP1_ACT_STS)—R/WC.
1
0 = Indicates that there has been no access to this device’s I/O range.
1 = This device’s I/O range has been accessed. Clear this bit by writing a 1 to the bit location.
IDE Primary Drive 0 Activity Status (IDEP0_ACT_STS)—R/WC.
0
9.8.3.17
0 = Indicates that there has been no access to this device’s I/O range.
1 = This device’s I/O range has been accessed. Clear this bit by writing a 1 to the bit location.
DEVTRAP_EN—Device Trap Enable Register
I/O Address:
Default Value
Lockable:
Power Well:
PMBASE +48h
0000h
No
Core
Attribute:
Size:
Usage:
R/W
16-bit
Legacy Only
This register enables the individual trap ranges to generate an SMI# when the corresponding status
bit in the DEVACT_STS register is set. When a range is enabled, I/O cycles associated with that
range will not be forwarded to LPC or IDE.
Bit
15:14
Description
Reserved
ADLIB Trap Enable (ADLIB_TRP_EN)—R/W.
13
0 = Disable.
1 = Enable.
KBC Trap Enable (KBC_TRP_EN)—R/W. KBC (60/64h).
12
0 = Disable.
1 = Enable.
MIDI Trap Enable (MIDI_TRP_EN)—R/W.
11
0 = Disable.
1 = Enable.
Audio Trap Enable (AUDIO_TRP_EN)—R/W. Audio (Sound Blaster “ORed” with MSS).
10
0 = Disable.
1 = Enable.
9:6
Reserved
LEG_IO_TRP_EN—R/W. Parallel Port, Serial Port 1, Serial Port 2, Floppy Disk Controller.
5
0 = Disable.
1 = Enable.
4
Reserved.
IDE Secondary Drive 1 Trap Enable (IDES1_TRP_EN)—R/W.
3
0 = Disable.
1 = Enable.
2
0 = Disable.
1 = Enable.
IDE Secondary Drive 0 Trap Enable (IDES0_TRP_EN)—R/W.
IDE Primary Drive 1 Trap Enable (IDEP1_TRP_EN)—R/W.
1
0 = Disable.
1 = Enable.
IDE Primary Drive 0 Trap Enable (IDEP0_TRP_EN)—R/W.
0
0 = Disable.
1 = Enable.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-77
LPC Interface Bridge Registers (D31:F0)
9.8.3.18
BUS_ADDR_TRACK—Bus Address Tracker Register
I/O Address:
Lockable:
Power Well:
PMBASE +4Ch
No
Core
Attribute:
Size:
Usage:
RO
16-bit
Legacy Only
This register could be used by the SMI# handler to assist in determining what was the last cycle
from the processor.
9.8.3.19
Bit
Description
15:0
Corresponds to the low 16 bits of the last I/O cycle, as would be defined by the PCI AD[15:0] signals
on the PCI bus (even though it may not be a real PCI cycle). The value is latched based on SMI#
active. This functionality is useful for figuring out which I/O was last being accessed.
BUS_CYC_TRACK—Bus Cycle Tracker Register
I/O Address:
Lockable:
Power Well:
PMBASE +4Eh
No
Core
Attribute:
Size:
Usage:
RO
8-bit
Legacy Only
This register could be used by the SMM handler to assist in determining what was the last cycle
from the processor.
Bit
9.8.3.20
Description
7:4
Corresponds to the byte enables, as would be defined by the PCI C/BE# signals on the PCI bus
(even though it may not be a real PCI cycle). The value is latched based on SMI# going active.
3:0
Corresponds to the cycle type, as would be defined by the PCI C/BE# signals on the PCI bus (even
though it may not be a real PCI cycle). The value is latched based on SMI# going active.
SS_CNT— SpeedStep™ Control Register (82801BAM ICH2-M)
I/O Address:
Default Value
Lockable:
Power Well:
PMBASE +50h
01h
No
Core
Attribute:
Size:
Usage:
R/W (special)
8-bit
ACPI/Legacy
Writes to this register initiates an Intel® SpeedStep™ transition, which involves a temporary
transition to a C3-like state in which the STPCLK# signal will go active. An Intel® SpeedStep™
transition always occur on writes to the SS_CNT register, even if the value written to SS_STATE
is the same as the previous value (after this “transition” the system would still be in the same
Intel® SpeedStep™ state).
Bit
7:1
0
Description
Reserved
SpeedStepTM State (SS_STATE)— R/W (Special). When this bit is read, it will return the current
SpeedStep™ state. Writes to this register will cause a change to the SpeedStepTM state indicated
by the value written to this bit.
0 = High-power state.
1 = Low-power state.
9-78
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.9
System Management TCO Registers (D31:F0)
The TCO logic is accessed via registers mapped to the PCI configuration space
(Device 31:Function 0) and the system I/O space. For TCO PCI Configuration registers, see LPC
Device 31:Function 0 PCI Configuration registers.
9.9.1
TCO Register I/O Map
The TCO I/O registers reside in a 32-byte range pointed to by a TCOBASE value, which is,
ACPIBASE + 60h in the PCI configuration space. The following table shows the mapping of the
registers within that 32-byte range. Each register is described in the sections below.
Table 9-11. TCO I/O Register Map
Offset
Mnemonic
Type
00h
TCO_RLD
TCO Timer Reload and Current Value
R/W
01h
TCO_TMR
TCO Timer Initial Value
R/W
02h
TCO_DAT_IN
TCO Data In
R/W
03h
TCO_DAT_OUT
TCO Data Out
R/W
04h–05h
TCO1_STS
TCO Status
R/W
06h–07h
TCO2_STS
TCO Status
R/W
08h–09h
TCO1_CNT
TCO Control
R/W
0Ah–0Bh
TCO2_CNT
TCO Control
R/W
0Ch–0Dh
TCO_MESSAGE1,
TCO_MESSAGE2
Used by BIOS to indicate POST/Boot progress
R/W
0Eh
TCO_WDSTATUS
Watchdog Status Register
R/W
0Fh
10h
SW_IRQ_GEN
11h–1Fh
9.9.2
Register Name: Function
Reserved
RO
Software IRQ Generation Register
R/W
Reserved
RO
TCO1_RLD—TCO Timer Reload and Current Value Register
I/O Address:
Default Value:
Lockable:
TCOBASE +00h
0000h
No
Attribute:
Size:
Power Well:
R/W
8-bit
Core
Bit
Description
7:0
TCO Timer Value. Reading this register will return the current count of the TCO timer. Writing any
value to this register will reload the timer to prevent the time-out. Bits 7:6 will always be 0.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-79
LPC Interface Bridge Registers (D31:F0)
9.9.3
TCO1_TMR—TCO Timer Initial Value Register
I/O Address:
Default Value:
Lockable:
TCOBASE +01h
0004h
No
Bit
9.9.4
7:6
Reserved
5:0
TCO Timer Initial Value. Value that is loaded into the timer each time the TCO_RLD register is
written. Values of 0h–3h will be ignored and should not be attempted. The timer is clocked at
approximately 0.6 seconds, and this allows time-outs ranging from 2.4 seconds to 38 seconds.
TCO1_DAT_IN—TCO Data In Register
TCOBASE +02h
0000h
No
Attribute:
Size:
Power Well:
R/W
8-bit
Core
Bit
Description
7:0
TCO Data In Value. Data Register for passing commands from the OS to the SMI handler. Writes
to this register will cause an SMI and set the OS_TCO_SMI bit in the TCO_STS register.
TCO1_DAT_OUT—TCO Data Out Register
I/O Address:
Default Value:
Lockable:
9.9.6
R/W
8-bit
Core
Description
I/O Address:
Default Value:
Lockable:
9.9.5
Attribute:
Size:
Power Well:
TCOBASE +03h
0000h
No
Attribute:
Size:
Power Well:
R/W
8-bit
Core
Bit
Description
7:0
TCO Data Out Value. Data Register for passing commands from the SMI handler to the OS.
Writes to this register will set the TCO_INT_STS bit in the TCO_STS register. It will also cause an
interrupt, as selected by the TCO_INT_SEL bits.
TCO1_STS—TCO1 Status Register
I/O Address:
Default Value:
Lockable:
Bit
15:13
12
TCOBASE +04h
0000h
No
Attribute:
Size:
Power Well:
R/WC RO
16-bit
Core
(Except bit 7, in RTC)
Description
Reserved
Hub Interface SERR Status (HUBSERR_STS)—R/WC.
1 = ICH2 received an SERR# message via the hub interface. The software must read the memory
controller hub (or its equivalent) to determine the reason for the SERR#.
0 = Software clears this bit by writing a 1 to the bit position.
11
Hub Interface NMI Status (HUBNMI_STS)—R/WC.
1 = ICH2 received an NMI message via the hub interface. The software must read the memory
controller hub (or its equivalent) to determine the reason for the NMI.
0 = Software clears this bit by writing a 1 to the bit position.
9-80
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
Bit
10
Description
Hub Interface SMI Status (HUBSMI_STS)—R/WC.
1 = ICH2 received an SMI message via the hub interface. The software must read the memory
controller hub (or its equivalent) to determine the reason for the SMI#.
0 = Software clears this bit by writing a 1 to the bit position.
9
Hub Interface SCI Status (HUBSCI_STS)—R/WC.
1 = ICH2 received an SCI message via the hub interface. The software must read the memory
controller hub (or its equivalent) to determine the reason for the SCI.
0 = Software clears this bit by writing a 1 to the bit position.
8
BIOS Write Status (BIOSWR_STS)—R/WC.
1 = ICH2 sets this bit and generates and SMI# to indicate an illegal attempt to write to the BIOS.
This occurs when either:
a) The BIOSWP bit is changed from 0 to 1 and the BLD bit is also set, or
b) any write is attempted to the BIOS and the BIOSWP bit is also set.
0 = Software clears this bit by writing a 1 to the bit position.
Note:On write cycles attempted to the 4 MB lower alias to the BIOS space, the BIOSWR_STS will
not be set.
New Century Status (NEWCENTURY_STS)—R/WC. This bit is in the RTC well.
1 = This bit is set when the Year byte (RTC I/O space, index offset 09h) rolls over from 99 to 00.
Setting this bit will cause an SMI# (but not a wake event).
0 = Cleared by writing a 1 to the bit position or by RTCRST# going active.
7
Note that the NEWCENTURY_STS bit is not valid when the RTC battery is first installed (or when
RTC power has not been maintained). Software can determine if RTC power has not been
maintained by checking the RTC_PWR_STS bit or by other means (e.g., a checksum on RTC
RAM). If RTC power is determined to have not been maintained, BIOS should set the time to a
legal value and then clear the NEWCENTURY_STS bit.
The NEWCENTURY_STS bit may take up to 3 RTC clocks for the bit to be cleared after a “1” is
written to the bit to clear it. After writing a “1” to this bit, software should not exit the SMI handler
until verifying that the bit has actually been cleared. This will ensure that the SMI is not re-entered.
6:4
3
Reserved
Time Out Status (TIMEOUT)—R/WC.
1 = Set by ICH2 to indicate that the SMI was caused by the TCO timer reaching 0.
0 = Software clears this bit by writing a 1 to the bit position.
2
TCO Interrupt Status (TCO_INT_STS)—R/WC.
1 = SMI handler caused the interrupt by writing to the TCO_DAT_OUT register.
0 = Software clears this bit by writing a 1 to the bit position.
1
Software TCO SMI Status (SW_TCO_SMI)—R/WC.
1 = Software caused an SMI# by writing to the TCO_DAT_IN register.
0 = Software clears this bit by writing a 1 to the bit position.
0
NMI to SMI Status (NMI2SMI_STS)—RO.
1 = Set by the ICH2 when an SMI# occurs because an event occurred that would otherwise have
caused an NMI (because NMI2SMI_EN is set).
0 = Cleared by clearing the associated NMI status bit.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-81
LPC Interface Bridge Registers (D31:F0)
9.9.7
TCO2_STS—TCO2 Status Register
I/O Address:
Default Value:
Lockable:
Bit
15:3
TCOBASE +06h
0000h
No
Attribute:
Size:
Power Well:
R/WC, RO
16-bit
Resume
(Except Bit 0, in RTC)
Description
Reserved
Boot Status (BOOT_STS):
1 = Set to 1 when the SECOND_TO_STS bit goes from 0 to 1 and the processor has not fetched the
first instruction.
2
0 = Cleared by ICH2 based on RSMRST# or by software writing a 1 to this bit. Note that software
should first clear the SECOND_TO_STS bit before writing a 1 to clear the BOOT_STS bit.
If rebooting due to a second TCO timer time-out and if the BOOT_STS bit is set, the ICH2 will reboot
using the ‘safe’ multiplier (1111). This allows the system to recover from a processor frequency
multiplier that is too high, and allows the BIOS to check the BOOT_STS bit at boot. If the bit is set and
the frequency multiplier is 1111, then the BIOS knows that the processor has been programmed to an
illegal multiplier.
1
Second TCO Time-out Status (SECOND_TO_STS)—R/WC.
1 = The ICH2 sets this bit to a 1 to indicate that the TCO timer timed out a second time (probably due
to system lock). If this bit is set the ICH2 will reboot the system after the second time-out. The
reboot is done by asserting PCIRST#.
0 = This bit is cleared by writing a 1 to the bit position or by a RSMRST#.
0
Intruder Detect (INTRD_DET)—R/WC.
1 = Set by ICH2 to indicate that an intrusion was detected. This bit is set even if the system is in G3
state.
0 = This bit is only cleared by writing a 1 to the bit position, or by RTCRST# assertion.
9-82
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.9.8
TCO1_CNT—TCO1 Control Register
I/O Address:
Default Value:
Lockable:
TCOBASE +08h
0000h
No
Attribute:
Size:
Power Well:
Bit
15:12
R/W, R/WC
16-bit
Core
Description
Reserved
TCO Timer Halt (TCO_TMR_HLT)—R/W.
11
0 = The TCO Timer is enabled to count.
1 = The TCO Timer will halt. It will not count and, thus, cannot reach a value that will cause an
SMI# or set the SECOND_TO_STS bit. When set, this bit prevents rebooting and prevents
Alert On LAN event messages from being transmitted on the SMLINK (but not Alert On LAN
heartbeat messages).
Send Now (SENDNOW)—R/W (special).
1 = Writing a 1 to this bit will cause the ICH to send an Alert On LAN Event message over the
SMLINK interface, with the Software Event bit set.
10
0 = The ICH will clear this bit when it has completed sending the message. Software must not set
this bit to 1 again until the ICH has set it back to 0.
Setting the SENDNOW bit causes the ICH2 integrated LAN Controller to reset, which can have
unpredictable side-effects. Unless software protects against these side effects, software should not
attempt to set this bit.
NMI to SMI Enable (NMI2SMI_EN)—R/W.
0 = Normal NMI functionality.
1 = Forces all NMIs to instead cause SMIs. The functionality of this bit is dependent upon the
settings of the NMI_EN bit and the GBL_SMI_EN bit as detailed in the following table:
9
8
NMI_EN
GBL_SMI_EN
Description
0
0
No SMI# at all because GBL_SMI_EN = 0
0
1
SMI# will be caused due to NMI events
1
0
No SMI# at all because GBL_SMI_EN = 0
1
1
No SMI# due to NMI because NMI_EN = 1
NMI Now (NMI_NOW)—R/WC.
1 = Writing a 1 to this bit causes an NMI. This allows the BIOS or SMI handler to force an entry to
the NMI handler.
0 = This bit is cleared by writing a 1 to the bit position. The NMI handler is expected to clear this bit.
Another NMI will not be generated until the bit is cleared.
7:0
9.9.9
Reserved
TCO2_CNT—TCO2 Control Register
I/O Address:
Default Value:
Lockable:
TCOBASE +0Ah
0000h
No
Bit
15:3
Attribute:
Size:
Power Well:
R/W
16-bit
Resume
Description
Reserved.
INTRUDER# Signal Select (INTRD_SEL)—R/W. Selects the action to take if the INTRUDER# signal
goes active.
00 = No interrupt or SMI#
2:1
01 = Interrupt (as selected by TCO_INT_SEL).
10 = SMI
11 = Reserved
0
Reserved.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-83
LPC Interface Bridge Registers (D31:F0)
9.9.10
TCO_MESSAGE1 and TCO_MESSAGE2 Registers
I/O Address:
Default Value:
Lockable:
9.9.11
8-bit
Resume
Description
7:0
TCO Message (TCO_MESSAGE[n])—R/W.The value written into this register will be sent out via
the SMLINK interface in the MESSAGE field of the Alert On LAN message. BIOS can write to this
register to indicate its boot progress which can be monitored externally.
TCO_WDSTATUS—TCO2 Control Register
TCOBASE + 0Eh
00h
Resume
Attribute:
Size:
R/W
8 bits
Bit
Description
7:0
Watchdog Status (WDSTATUS)—R/W. The value written to this register will be sent in the Alert On
LAN message on the SMLINK interface. It can be used by the BIOS or system management
software to indicate more details on the boot progress. This register will be reset to the default of
00h based on RSMRST# (but not PCI reset).
SW_IRQ_GEN—Software IRQ Generation Register
Offset Address:
Default Value:
Power Well:
Bit
7:2
9-84
R/W
Bit
Offset Address:
Default Value:
Power Well:
9.9.12
TCOBASE +0Ch (Message 1) Attribute:
TCOBASE +0Dh (Message 2)
00h
Size:
No
Power Well:
TCOBASE + 10h
03h
Resume
Attribute:
Size:
R/W
8 bits
Description
Reserved.
1
IRQ12 Cause (IRQ12_CAUSE)—R/W. The state of this bit is logically ANDed with the IRQ12 signal
as received by the ICH2’s SERIRQ logic. This bit must be a “1” (default) if the ICH2 is expected to
receive IRQ12 assertions from a SERIRQ device.
0
IRQ1 Cause (IRQ1_CAUSE)—R/W. The state of this bit is logically ANDed with the IRQ1 signal as
received by the ICH2’s SERIRQ logic. This bit must be a “1” (default) if the ICH2 is expected to
receive IRQ1 assertions from a SERIRQ device.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.10
General Purpose I/O Registers (D31:F0)
The control for the general purpose I/O signals is handled through a separate 64-byte I/O space.
The base offset for this space is selected by the GPIO_BAR register. Table 9-12 summarizes the
ICH2 GPIO implementation.
Table 9-12. Summary of GPIO Implementation
GPIO
Type
Alternate
Function
(Note 1)
Power
Well
GPIO[0]
Input
Only
REQ[A]#
Core
GPIO_USE_SEL bit 0 enables REQ/GNT[A]# pair.
Input active status read from GPE1_STS register bit 0.
Input active high/low set through GPI_INV register bit 0.
GPIO[1]
Input
Only
REQ[B]# or
REQ[5]#
Core
GPIO_USE_SEL bit 1 enables REQ/GNT[B]# pair
(See note 4).
Input active status read from GPE1_STS register bit 1.
Input active high/low set through GPI_INV register bit 1.
GPIO[2]
N/A
N/A
N/A
Not implemented
GPIO[3:4]
Input
Only
PIRQ[E:H]#
Core
GPIO_USE_SEL bits [3:4] enable PIRQ[F:G]#.
Input active status read from GPE1_STS reg. bits [3:4].
Input active high/low set through GPI_INV reg. bit [3:4].
GPIO[5]
N/A
N/A
N/A
Not implemented
Notes
ICH2 (82801BA):
GPIO[6]
Input
Only
Unmuxed
Core
Input active status read from GPE1_STS register bit 6.
Input active high/low set through GPI_INV register bit 6.
ICH2-M (82801BAM):
Not implemented.
GPIO[7]
Input
Only
Unmuxed
Core
Input active status read from GPE1_STS register bit 7.
Input active high/low set through GPI_INV register bit 7
GPIO[8]
Input
Only
Unmuxed
Resume
Input active status read from GPE1_STS register bit 8.
Input active high/low set through GPI_INV register bit 8.
GPIO[9:10]
N/A
N/A
N/A
GPIO[11]
Input
Only
SMBALERT#
Resume
GPIO_USE_SEL bit 11 enables SMBALERT#
Input active status read from GPE1_STS register bit 11.
Input active high/low set through GPI_INV register bit 11.
GPIO[12]
Input
Only
Unmuxed
Resume
Input active status read from GPE1_STS register bit 12.
Input active high/low set through GPI_INV register bit 12.
GPIO[13]
Input
Only
Unmuxed
Resume
Input active status read from GPE1_STS register bit 13.
Input active high/low set through GPI_INV register bit 13.
GPIO[14:15]
N/A
N/A
N/A
Not Implemented
GPIO[16]
Output
Only
GNT[A]#
Core
Output controlled via GP_LVL register bit 16.
TTL driver output
GPIO[17]
Output
Only
GNT[B]# or
GNT[5]#
Core
Output controlled via GP_LVL register bit 17.
TTL driver output
Not implemented
ICH2 (82801BA):
GPIO[18:19]
Output
Only
Unmuxed
Core
Output controlled via GP_LVL register bits [18:19].
TTL driver output
ICH2-M (82801BAM):
Not implemented.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-85
LPC Interface Bridge Registers (D31:F0)
Table 9-12. Summary of GPIO Implementation (Continued)
GPIO
Type
Alternate
Function
(Note 1)
Power
Well
Notes
ICH2 (82801BA):
GPIO[20]
Output
Only
Unmuxed
Core
Output controlled via GP_LVL register bit 20.
TTL driver output
ICH2-M (82801BAM):
Not implemented.
ICH2 (82801BA):
GPIO[21]
Output
Only
Unmuxed for
ICH2
82801BA
CS_STAT#
for ICH2-M
82801BAM
Core
This GPO defaults high.
Output controlled via GP_LVL register bit 21.
TTL driver output
ICH2-M (82801BAM):
Output controlled via GP_LVL register bit 21.
TTL driver output
ICH2 (82801BA):
GPIO[22]
Output
Only
Unmuxed
Core
Output controlled via GP_LVL register bit [22].
Open-drain output
ICH2-M (82801BAM):
Not implemented.
ICH2 (82801BA):
GPIO[23]
Output
Only
Unmuxed
Core
Output controlled via GP_LVL register bit [23].
TTL driver output
ICH2-M (82801BAM):
Not implemented.
ICH2 (82801BA):
GPIO[24]
Input /
Output
Unmuxed
Resume
Input active status read from GP_LVL register bit 24.
Output controlled via GP_LVL register bit 24.
TTL driver output
ICH2-M (82801BAM):
Not implemented.
GPIO[25]
Input /
Output
Unmuxed
Resume
GPIO[26]
N/A
N/A
N/A
GPIO[27:28]
Input /
Output
Unmuxed
Resume
GPIO[29:31]
N/A
N/A
N/A
Blink enabled via GPO_BLINK register bit 25.
Input active status read from GP_LVL register bit 25
Output controlled via GP_LVL register bit 25.
TTL driver output
Not implemented
Input active status read from GP_LVL register bits [27:28]
Output controlled via GP_LVL register bits [27:28]
TTL driver output
Not implemented
NOTES:
1. All GPIOs default to their alternate function
2. All inputs are sticky. The status bit will remain set as long as the input was asserted for 2 clocks. GPIs are
sampled on PCI clocks in S0/S1...
3. GPIs are sampled on RTC clocks in S3/S4/S5 for the 82801BA ICH2 and in S1/S3/S4/S5 for the 82801BAM
ICH2-M.
4. GPIO[7:6,4:3,1:0] (GPIO[7,4:3,1:0] for the ICH2-M) are 5V tolerant, and all GPIs can be routed to cause an
SCI or SMI#
5. If GPIO_USE_SEL bit 1 is set to 1 and GEN_CNT bit 25 is also set to 1 then REQ/GNT[5]# is enabled. See
Section 9.1.22.
9-86
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.10.1
GPIO Register I/O Address Map
Table 9-13. Registers to Control GPIO
Offset
Mnemonic
Register Name
Default
Access
GPIO Use Select
1A00 3180h
R/W
GPIO Input/Output Select
0000 FFFFh
R/W
00h
RO
1F1F 0000h
R/W
00h
RO
GPIO TTL Select
06630000h
RO
GPIO Blink Enable
00000000h
R/W
0
RO
Reserved
00000000h
RO
GPIO Signal Invert
00000000h
R/W
General Registers
00–03h
GPIO_USE_SEL
04–07h
GP_IO_SEL
08–0Bh
—
0C–0Fh
GP_LVL
10–13h
—
Reserved
GPIO Level for Input or Output
Reserved
Output Control Registers
14–17h
GPO_TTL
18–1Bh
GPO_BLINK
1C–1Fh
—
Reserved
Input Control Registers
9.10.2
20–2Bh
—
2C–2Fh
GPI_INV
GPIO_USE_SEL—GPIO Use Select Register
Offset Address:
Default Value:
Lockable:
GPIOBASE + 00h
1A003180h
Yes
Bit
Attribute:
Size:
Power Well:
R/W
32-bit
Resume
Description
GPIO Use Select (GPIO_USE_SEL)—R/W. Each bit in this register enables the corresponding
GPIO (if it exists) to be used as a GPIO, rather than for the native function.
0 = Signal used as native function.
1 = Signal used as a GPIO.
21,11,
5:0
Note: ICH2 82801BA: Bits 31:29, 26, 15:14, 10:9 and 7 are not implemented because there is no
corresponding GPIO.
ICH2-M 82801BAM: Bits 31:29, 26, 24:22, 20:18, 15:14, 10:9, and 7:6 are not implemented
because there is no corresponding GPIO.
Note: ICH2 82801BA: Bits 28:27, 25:22, 20:18,13:12, 8 and 6 are not implemented because the
corresponding GPIOs are not multiplexed.
ICH2-M 82801BAM: Bits 28:27, 25, 13:12 and 8 are not implemented because the
corresponding GPIOs are not mutiplexed.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-87
LPC Interface Bridge Registers (D31:F0)
9.10.3
GP_IO_SEL—GPIO Input/Output Select Register
Offset Address:
Default Value:
Lockable:
GPIOBASE +04h
0000FFFFh
No
Bit
31:29, 26 15:14,
10:9, 5, 2
28:27,25:24 (ICH2)
28:27,25 (ICH2-M)
24:22, 20:18, 6
(ICH2-M)
23:16 (ICH2)
21:16 (ICH2-M)
13:11, 8:6, 4:3, 1:0
(ICH2)
13:11, 8:7, 4:3, 1:0
(ICH2-M)
Attribute:
Size:
Power Well:
R/W
32-bit
Resume
Description
Reserved.
GPIO[n] Select (GPIO[n]_SEL)—R/W.
0 = Output. The corresponding GPIO signal is an output.
1 = Input. The corresponding GPIO signal is an input.
Reserved
Always 0. The GPIOs are fixed as outputs.
Always 1. These GPIOs are fixed as inputs.
NOTES:
1. There will be some delay on GPIO[24:28] going to their default state based on the rising edge of
RSMRST#. This is the case since these signals are in the resume well and resume well outputs
are not valid until after RSMRST# goes high. ICH2 only guarantees that these GPIOs will be
stable prior to SLP_S3# going active.
9-88
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.10.4
GP_LVL—GPIO Level for Input or Output Register
Offset Address:
Default Value:
Lockable:
GPIOBASE +0Ch
1B3F 0000h
No
Bit
Attribute:
Size:
Power Well:
R/W, RO
32-bit
See bit descriptions
Description
31:29, 26, 15:14,
10:9, 5, 2
(ICH2)
31:29, 26, 24:22,
20:18, 15:14, 10:9 6,
5, 2
(ICH2-M)
28:27, 25:24
(ICH2)
28:27, 25
(ICH2-M)
Reserved.
GPIO Level (GP_LVL[n])—R/W. If GPIO[n] is programmed to be an output (via the
corresponding bit in the GP_IO_SEL register), then the bit can be updated by software
to drive a high or low value on the output pin. If GPIO[n] is programmed as an input,
then software can read the bit to determine the level on the corresponding input pin.
These bits correspond to GPIO that are in the Resume well, and will be reset to their
default values by RSMRST# but not by PCIRST#.
0 = Low
1 = High
23:16
(ICH2)
21, 17:16
(ICH2-M)
13:11, 8:6, 4:3, 1:0
(ICH2)
13:11, 8:7, 4:3, 1:0
(ICH2-M)
GPIO Level (GP_LVL[n])—R/W. These bits can be updated by software to drive a
high or low value on the output pin. These bits correspond to GPIO that are in the
Core well, and will be reset to their default values by PCIRST#.
0 = Low
1 = High
ICH2 82801BA:
For GPI[13:11] and [8:6,4:3,1:0], the active status of a GPI is read from the
corresponding bit in GPE1_STS register.
ICH2-M 82801BAM:
For GPI[13:11] and [8:7,4:3,1:0], the active status of a GPI is read from the
corresponding bit in GPE1_STS register.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-89
LPC Interface Bridge Registers (D31:F0)
9.10.5
GPO_BLINK—GPO Blink Enable Register
Offset Address:
Default Value:
Lockable:
GPIOBASE +18h
0004 0000h
No
Bit
31:29, 26, 24:20,
17:0
(ICH2)
31:29, 26, 24:20,
18:0
(ICH2-M)
28:27, 25
19:18 (ICH2)
19 (ICH2-M)
Attribute:
Size:
Power Well:
R/W
32-bit
See bit description
Description
Reserved
GPIO Blink (GP_BLINK[n])—R/W. The setting of these bits will have no effect if the
corresponding GPIO is programmed as an input. These bits correspond to GPIO that
are in the Resume well and will be reset to their default values by RSMRST# but not by
PCIRST#.
0 = The corresponding GPIO will function normally.
1 = If the corresponding GPIO is programmed as an output, the output signal will blink
at a rate of approximately once per second. The high and low times have
approximately 50% duty cycle. The GP_LVL bit is not altered when this bit is set.
GPIO Blink (GP_BLINK[n])—R/W. The setting of these bits will have no effect if the
corresponding GPIO is programmed as an input. These bits correspond to GPIO that
are in the Core well, and will be reset to their default values by PCIRST#.
0 = The corresponding GPIO will function normally.
1 = If the corresponding GPIO is programmed as an output, the output signal will blink
at a rate of approximately once per second. The high and low times have
approximately 50% duty cycle. The GP_LVL bit is not altered when this bit is set.
NOTES:.
1. ICH2 82801BA: GPIO[18]
blinks, by default, immediately after reset. This signal could be
connected to an LED to indicate a failed boot (by programming BIOS to clear GP_BLINK[18]
after successful POST).
9-90
82801BA ICH2 and 82801BAM ICH2-M Datasheet
LPC Interface Bridge Registers (D31:F0)
9.10.6
GPI_INV—GPIO Signal Invert Register
Offset Address:
Default Value:
Lockable:
GPIOBASE +2Ch
00000000h
No
Bit
31:14, 10:9,
5, 2
(ICH2)
31:14, 10:9, 6,
5, 2
(ICH2-M)
13:11, 8
Attribute:
Size:
Power Well:
R/W
32-bit
See bit description
Description
Reserved
GPIO Signal High/Low Select (GP_INV[n])—R/W. These bits are used to allow both activelow and active-high inputs to cause SMI# or SCI. Note that in the S0 or S1 state, the input
signal must be active for at least 2 PCI clocks to ensure detection by the ICH2. In the S3, S4
or S5 states the input signal must be active for at least 2 RTC clocks to ensure detection. The
setting of these bits will have no effect if the corresponding GPIO is programmed as an
output. These bits correspond to GPIO that are in the Resume well, and will be reset to their
default values by RSMRST# but not by PCIRST#.
0 = The corresponding GPI_STS bit will be set when the ICH2 detects the state of the input
pin to be high.
1 = The corresponding GPI_STS bit will be set when the ICH2 detects the state of the input
pin to be low.
7:6, 4:3, 1:0
(ICH2)
7, 4:3, 1:0
(ICH2-M)
GPIO Signal High/Low Select (GP_INV[n])—R/W. These bits are used to allow both activelow and active-high inputs to cause SMI# or SCI. Note that in the S0 or S1 state, the input
signal must be active for at least 2 PCI clocks to ensure detection by the ICH2. The setting of
these bits will have no effect if the corresponding GPIO is programmed as an output. These
bits correspond to GPIO that are in the Core well, and will be reset to their default values by
PCIRST#.
0 = The corresponding GPI_STS bit will be set when the ICH2 detects the state of the input
pin to be high.
1 = The corresponding GPI_STS bit will be set when the ICH2 detects the state of the input
pin to be low.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
9-91
LPC Interface Bridge Registers (D31:F0)
This page is intentionally left blank
9-92
82801BA ICH2 and 82801BAM ICH2-M Datasheet
IDE Controller Registers (D31:F1)
IDE Controller Registers (D31:F1)
10.1
10
PCI Configuration Registers (IDE—D31:F1)
Note:
Registers that are not shown should be treated as Reserved (See Section 6.2 for details).
All of the IDE registers are in the Core well. None can be locked.
Table 10-1. PCI Configuration Map (IDE—D31:F1)
Offset
Mnemonic
Register Name/Function
00h–01h
VID
Vendor ID
02h–03h
DID
Device ID
04h–05h
CMD
Command Register
06h–07h
STS
Device Status
08h
RID
Revision ID
Default
Type
8086h
RO
244Bh (ICH2)
244Ah (ICH2-M)
RO
00h
R/W
0280h
R/W
See Note 1
RO
09h
PI
Programming Interface
80h
RO
0Ah
SCC
Sub Class Code
01h
RO
0Bh
BCC
Base Class Code
01h
RO
0Dh
MLT
Master Latency Timer
00
RO
0Eh
HTYPE
00h
RO
20h–23h
BAR
Base Address Register
Header Type
00000001h
R/W
2C–2Dh
SVID
Subsystem Vendor ID
00
R/WriteOnce
2E–2Fh
SID
Subsystem ID
00
R/WriteOnce
40h–41h
IDE_TIMP
Primary IDE Timing
0000h
R/W
42–43h
ID_TIMS
Secondary IDE Timing
0000h
R/W
44h
SIDETIM
Slave IDE Timing
00h
R/W
48h
SDMAC
Synchronous DMA Control Register
00h
R/W
4Ah–4Bh
SDMATIM
Synchronous DMA Timing Register
0000h
R/W
54h
IDE_CONFIG
00h
R/W
IDE I/O Configuration Register
NOTES:
1. Refer to the Specification Update for the value of the Revision ID Register
2. The ICH2 IDE controller is not arbitrated as a PCI device; therefore, it doe s not need a master latency timer.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
10-1
IDE Controller Registers (D31:F1)
10.1.1
VID—Vendor ID Register (IDE—D31:F1)
Offset Address:
Default Value:
Lockable:
00–01h
8086h
No
Bit
15:0
10.1.2
RO
16-bit
Core
Description
Vendor ID Value. This is a 16 bit value assigned to Intel. Intel VID = 8086h
DID—Device ID Register (IDE—D31:F1)
Offset Address:
Lockable:
02–03h
No
Default Value:
244Bh (82801BA ICH2)
244Ah (82801BAM ICH2-M)
Bit
15:0
10.1.3
Attribute:
Size:
Power Well:
Attribute:
Size:
Power Well:
RO
16-bit
Core
Description
Device ID Value. This is a 16 bit value assigned to the ICH2 IDE controller.
CMD—Command Register (IDE—D31:F1)
Address Offset:
Default Value:
04h–05h
00h
Bit
15:10
Attribute:
Size:
RO, R/W
16 bits
Description
Reserved.
9
Fast Back to Back Enable (FBE)—RO. Reserved as 0.
8
SERR# Enable—RO. Reserved as 0.
7
Wait Cycle Control—RO. Reserved as 0.
6
Parity Error Response—RO. Reserved as 0.
5
VGA Palette Snoop—RO. Reserved as 0.
4
Postable Memory Write Enable (PMWE)—RO. Reserved as 0.
3
Special Cycle Enable (SCE)—RO. Reserved as 0.
2
Bus Master Enable (BME)—R/W. Controls the ICH2’s ability to act as a PCI master for IDE Bus
Master transfers.
1
Memory Space Enable (MSE)—RO. Reserved as 0.
I/O Space Enable (IOSE)—R/W. This bit controls access to the I/O space registers.
0
0 = Disables access to the Legacy IDE ports (both Primary and Secondary) as well as the Bus
Master IO registers.
1 = Enable. Note that the Base Address register for the Bus Master registers should be
programmed before this bit is set.
Note: Separate bits are provided (IDE Decode Enable, in the IDE Timing register) to independently
disable the Primary or Secondary I/O spaces.
10-2
82801BA ICH2 and 82801BAM ICH2-M Datasheet
IDE Controller Registers (D31:F1)
10.1.4
STS—Device Status Register (IDE—D31:F1)
Address Offset:
Default Value:
06–07h
0280h
Bit
Attribute:
Size:
R/WC, RO
16 bits
Description
15
Detected Parity Error (DPE)—RO. Reserved as 0.
14
Signaled System Error (SSE)—RO. Reserved as 0.
Received Master-Abort Status (RMA)—R/WC.
13
1 = Bus Master IDE interface function, as a master, generated a master abort.
0 = Cleared by writing a 1 to it.
12
Reserved as 0—RO.
Signaled Target-Abort Status (STA)—R/WC.
11
1 = ICH2 IDE interface function is targeted with a transaction that the ICH2 terminates with a target
abort.
0 = Cleared by writing a 1 to it.
DEVSEL# Timing Status (DEVT)—RO.
10:9
8
Data Parity Error Detected—RO. Reserved as 0.
7
Fast Back-to-Back Capable—RO. Reserved as 1.
6
User Definable Features (UDF)—RO. Reserved as 0.
5
66 MHz Capable—RO. Reserved as 0.
4:0
10.1.5
01 = Hardwired; however, the ICH2 does not have a real DEVSEL# signal associated with the IDE
unit, so these bits have no effect.
Reserved
RID—Revision ID Register (HUB-PCI—D30:F0)
Offset Address:
Default Value:
08h
See bit description
Bit
7:0
10.1.6
Attribute:
Size:
RO
8 bits
Description
Revision Identification Number—RO. This 8-bit value indicates the revision number for the ICH2
IDE controller. Refer to the Specification Update for the value of the Revision ID Register.
PI—Programming Interface (IDE—D31:F1)
Address Offset:
Default Value:
09h
80h
Bit
7:0
Attribute:
Size:
RO
8 bits
Description
Programming Interface Value—RO.
80h = The 1b in bit 7 indicates that this IDE controller is capable of bus master operation.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
10-3
IDE Controller Registers (D31:F1)
10.1.7
SCC—Sub Class Code (IDE—D31:F1)
Address Offset:
Default Value:
0Ah
01h
Bit
7:0
10.1.8
RO
8 bits
Description
Sub Class Code—RO.
01h = IDE device, in the context of a mass storage device.
BCC—Base Class Code (IDE—D31:F1)
Address Offset:
Default Value:
0Bh
01h
Bit
7:0
10.1.9
Attribute:
Size:
Attribute:
Size:
RO
8 bits
Description
Base Class Code—RO.
01 = Mass storage device
MLT—Master Latency Timer (IDE—D31:F1)
Address Offset:
Default Value:
0Dh
00h
Bit
7:0
Attribute:
Size:
RO
8 bits
Description
Bus Master Latency—RO. The IDE controller is implemented internally, and is not arbitrated as a
PCI device, so it does not need a Master Latency Timer.
Hardwired to 00h.
10.1.10
BM_BASE—Bus Master Base Address Register
(IDE—D31:F1)
Address Offset:
Default Value:
20h–23h
00000001h
Attribute:
Size:
R/W
32 bits
The Bus Master IDE interface function uses Base Address register 5 to request a 16 byte IO space
to provide a software interface to the Bus Master functions. Only 12 bytes are actually used
(6 bytes for primary, 6 bytes for secondary). Only bits [15:4] are used to decode the address.
Bit
31:16
Reserved.
15:4
Base Address—R/W. Base address of the I/O space (16 consecutive I/O locations).
3:1
Reserved.
0
10-4
Description
Resource Type Indicator (RTE)—RO. Hardwired to 1, indicating a request for IO space.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
IDE Controller Registers (D31:F1)
10.1.11
IDE_SVID—Subsystem Vendor ID (IDE—D31:F1)
Address Offset:
Default Value:
Lockable:
2Ch–2Dh
00h
No
Bit
15:0
10.1.12
R/Write-Once
16 bits
Core
Description
Subsystem Vendor ID (SVID)—R/Write-Once. The SVID register, in combination with the
Subsystem ID (SID) register, enables the operating system (OS) to distinguish subsystems from
each other. Software (BIOS) sets the value in this register. After that, the value can be read, but
subsequent writes to this register have no effect. The value written to this register will also be
readable via the corresponding SVID registers for the USB#1, USB#2 and SMBus functions.
IDE_SID—Subsystem ID (IDE—D31:F1)
Address Offset:
Default Value:
Lockable:
10.1.13
Attribute:
Size:
Power Well:
2Eh–2Fh
00h
No
Attribute:
Size:
Power Well:
R/Write-Once
16 bits
Core
Bit
Description
15:0
Subsystem ID (SID)—R/Write-Once. The SID register, in combination with the SVID register,
enables the operating system (OS) to distinguish subsystems from each other. Software (BIOS)
sets the value in this register. After that, the value can be read, but subsequent writes to this register
have no effect. The value written to this register will also be readable via the corresponding SID
registers for the USB#1, USB#2 and SMBus functions.
IDE_TIM—IDE Timing Register (IDE—D31:F1)
Address Offset:
Default Value:
Primary:
40–41h
Secondary: 42–43h
0000h
Attribute:
R/W
Size:
16 bits
This register controls the timings driven on the IDE cable for PIO and 8237 style DMA transfers. It
also controls operation of the buffer for PIO transfers.
Bit
Description
15
IDE Decode Enable (IDE)—R/W. Individually enable/disable the Primary or Secondary decode.
The IDE I/O Space Enable bit in the Command register must be set in order for this bit to have any
effect. Additionally, separate configuration bits are provided (in the IDE I/O Configuration register)
to individually disable the primary or secondary IDE interface signals, even if the IDE Decode
Enable bit is set.
0 = Disable.
1 = Enables the ICH2 to decode the associated Command Blocks (1F0h–1F7h for primary,
170h–177h for secondary) and Control Block (3F6h for primary and 376h for secondary).
Drive 1 Timing Register Enable (SITRE)—R/W.
14
0 = Use bits 13:12, 9:8 for both drive 0 and drive 1.
1 = Use bits 13:12, 9:8 for drive 0, and use the Slave IDE Timing register for drive 1
IORDY Sample Point (ISP). The setting of these bits determine the number of PCI clocks between
IDE IOR#/IOW# assertion and the first IORDY sample point.
00 = 5 clocks
13:12
01 = 4 clocks
10 = 3 clocks
11 = Reserved
82801BA ICH2 and 82801BAM ICH2-M Datasheet
10-5
IDE Controller Registers (D31:F1)
Bit
11:10
Description
Reserved.
Recovery Time (RCT)—R/W. The setting of these bits determines the minimum number of PCI
clocks between the last IORDY sample point and the IOR#/IOW# strobe of the next cycle.
00 = 4 clocks
9:8
01 = 3 clocks
10 = 2 clocks
11 = 1 clock
Drive 1 DMA Timing Enable (DTE1)—R/W.
7
0 = Disable.
1 = Enable the fast timing mode for DMA transfers only for this drive. PIO transfers to the IDE data
port will run in compatible timing.
Drive 1 Prefetch/Posting Enable (PPE1)—R/W.
6
0 = Disable.
1 = Enable Prefetch and posting to the IDE data port for this drive.
Drive 1 IORDY Sample Point Enable (IE1)—R/W.
5
0 = Disable IORDY sampling for this drive.
1 = Enable IORDY sampling for this drive.
Drive 1 Fast Timing Bank (TIME1)—R/W.
4
0 = Accesses to the data port will use compatible timings for this drive.
1 = When this bit = 1 and bit 14 = 0, accesses to the data port will use bits 13:12 for the IORDY
sample point, and bits 9:8 for the recovery time. When this bit = 1 and bit 14 = 1, accesses to
the data port will use the IORDY sample point and recover time specified in the slave IDE
timing register.
Drive 0 DMA Timing Enable (DTE0)—R/W.
3
0 = Disable.
1 = Enable fast timing mode for DMA transfers only for this drive. PIO transfers to the IDE data
port will run in compatible timing.
Drive 0 Prefetch/Posting Enable (PPE0)—R/W.
2
0 = Disable prefetch and posting to the IDE data port for this drive.
1 = Enable prefetch and posting to the IDE data port for this drive.
Drive 0 IORDY Sample Point Enable (IE0)—R/W.
1
0 = Disable IORDY sampling is disabled for this drive.
1 = Enable IORDY sampling for this drive.
Drive 0 Fast Timing Bank (TIME0)—R/W.
0
10-6
0 = Accesses to the data port will use compatible timings for this drive.
1 = Accesses to the data port will use bits 13:12 for the IORDY sample point, and bits 9:8 for the
recovery time
82801BA ICH2 and 82801BAM ICH2-M Datasheet
IDE Controller Registers (D31:F1)
10.1.14
SLV_IDETIM—Slave (Drive 1) IDE Timing Register
(IDE—D31:F1)
Address Offset:
Default Value:
44h
00h
Bit
Attribute:
Size:
R/W
8 bits
Description
Secondary Drive 1 IORDY Sample Point (SISP1)—R/W. Determines the number of PCI clocks
between IDE IOR#/IOW# assertion and the first IORDY sample point, if the access is to drive 1 data
port and bit 14 of the IDE timing register for secondary is set.
7:6
00 = 5 clocks
01 = 4 clocks
10 = 3 clocks
11 = Reserved
Secondary Drive 1 Recovery Time (SRCT1)—R/W. Determines the minimum number of PCI clocks
between the last IORDY sample point and the IOR#/IOW# strobe of the next cycle, if the access is to
drive 1 data port and bit 14 of the IDE timing register for secondary is set.
5:4
00 = 4 clocks
01 = 3 clocks
10 = 2 clocks
11 = 1 clocks
Primary Drive 1 IORDY Sample Point (PISP1)—R/W. Determines the number of PCI clocks
between IOR#/IOW# assertion and the first IORDY sample point, if the access is to drive 1 data port
and bit 14 of the IDE timing register for primary is set.
3:2
00 = 5 clocks
01 = 4 clocks
10 = 3 clocks
11 = Reserved
Primary Drive 1 Recovery Time (PRCT1)—R/W. Determines the minimum number of PCI clocks
between the last IORDY sample point and the IOR#/IOW# strobe of the next cycle, if the access is to
drive 1 data port and bit 14 of the IDE timing register for primary is set.
1:0
00 = 4 clocks
01 = 3 clocks
10 = 2 clocks
11 = 1 clocks
82801BA ICH2 and 82801BAM ICH2-M Datasheet
10-7
IDE Controller Registers (D31:F1)
10.1.15
SDMA_CNT—Synchronous DMA Control Register
(IDE—D31:F1)
Address Offset:
Default Value:
48h
00h
Bit
7:4
Attribute:
Size:
R/W
8 bits
Description
Reserved.
Secondary Drive 1 Synchronous DMA Mode Enable (SSDE1)—R/W.
3
0 = Disable (default).
1 = Enable Synchronous DMA mode for secondary channel drive 1
Secondary Drive 0 Synchronous DMA Mode Enable (SSDE0)—R/W.
2
0 = Disable (default).
1 = Enable Synchronous DMA mode for secondary drive 0.
Primary Drive 1 Synchronous DMA Mode Enable (PSDE1)—R/W.
1
0 = Disable (default).
1 = Enable Synchronous DMA mode for primary channel drive 1
Primary Drive 0 Synchronous DMA Mode Enable (PSDE0)—R/W.
0
10.1.16
0 = Disable (default).
1 = Enable Synchronous DMA mode for primary channel drive 0
SDMA_TIM—Synchronous DMA Timing Register
(IDE—D31:F1)
Address Offset:
Default Value:
4A–4Bh
0000h
Bit
15:14
Attribute:
Size:
R/W
16 bits
Description
Reserved.
Secondary Drive 1 Cycle Time (SCT1)—R/W. For Ultra ATA mode, the setting of these bits
determines the minimum write strobe cycle time (CT). The DMARDY#-to-STOP (RP) time is also
determined by the setting of these bits.
13:12
11:10
SCB1 = 0 (33 MHz clk)
SCB1 = 1 (66 MHz clk)
FAST_SCB1 = 1 (133 MHz clk)
00 = CT 4 clocks, RP 6 clocks
00 = Reserved
00 = Reserved
01 = CT 3 clocks, RP 5 clocks
01 = CT 3 clocks, RP 8 clocks
01 = CT 3 clks, RP 16 clks
10 = CT 2 clocks, RP 4 clocks
10 = CT 2 clocks, RP 8 clocks
10 = Reserved
11 = Reserved
11 = Reserved
11 = Reserved
Reserved.
Secondary Drive 0 Cycle Time (SCT0)—R/W. For Ultra ATA mode, the setting of these bits
determines the minimum write strobe cycle time (CT). The DMARDY#-to-STOP (RP) time is also
determined by the setting of these bits.
9:8
7:6
10-8
SCB1 = 0 (33 MHz clk)
SCB1 = 1 (66 MHz clk)
FAST_SCB1 = 1 (133 MHz clk)
00 = CT 4 clocks, RP 6 clocks
00 = Reserved
00 = Reserved
01 = CT 3 clocks, RP 5 clocks
01 = CT 3 clocks, RP 8 clocks
01 = CT 3 clks, RP 16 clks
10 = CT 2 clocks, RP 4 clocks
10 = CT 2 clocks, RP 8 clocks
10 = Reserved
11 = Reserved
11 = Reserved
11 = Reserved
Reserved.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
IDE Controller Registers (D31:F1)
Bit
Description
Primary Drive 1 Cycle Time (PCT1)—R/W. For Ultra ATA mode, the setting of these bits
determines the minimum write strobe cycle time (CT). The DMARDY#-to-STOP (RP) time is also
determined by the setting of these bits.
PCB1 = 0 (33 MHz clk)
5:4
3:2
PCB1 = 1 (66 MHz clk)
FAST_PCB1 = 1 (133 MHz clk)
00 = CT 4 clocks, RP 6 clocks 00 = Reserved
00 = Reserved
01 = CT 3 clocks, RP 5 clocks 01 = CT 3 clocks, RP 8 clocks
01 = CT 3 clks, RP 16 clks
10 = CT 2 clocks, RP 4 clocks 10 = CT 2 clocks, RP 8 clocks
10 = Reserved
11 = Reserved
11 = Reserved
11 = Reserved
Reserved.
Primary Drive 0 Cycle Time (PCT0)—R/W. For Ultra ATA mode, the setting of these bits
determines the minimum write strobe cycle time (CT). The DMARDY#-to-STOP (RP) time is also
determined by the setting of these bits.
PCB1 = 0 (33 MHz clk)
1:0
10.1.17
PCB1 = 1 (66 MHz clk)
FAST_PCB1 = 1 (133 MHz clk)
00 = CT 4 clocks, RP 6 clocks 00 = Reserved
00 = Reserved
01 = CT 3 clocks, RP 5 clocks 01 = CT 3 clocks, RP 8 clocks
01 = CT 3 clks, RP 16 clks
10 = CT 2 clocks, RP 4 clocks 10 = CT 2 clocks, RP 8 clocks
10 = Reserved
11 = Reserved
11 = Reserved
11 = Reserved
IDE_CONFIG—IDE I/O Configuration Register
Address Offset:
Default Value:
54h
00h
Bit
31:20
Attribute:
Size:
R/W
32 bits
Description
Reserved.
Secondary IDE Signal Mode (SEC_SIG_MODE)—R/W.
00 = Normal (Enabled).
01 = Tri-state (Disabled).
10 = Drive low (Disabled).
11 = Reserved.
19:18
ICH2 (82801BA):
These bits are used to control mode of the Secondary IDE signal pins. These bits should always be
set to 00b for desktop implementations.
ICH2-M (82801BAM):
These bits are used to control mode of the Secondary IDE signal pins for mobile swap bay support.
Primary IDE Signal Mode (PRIM_SIG_MODE)—R/W.
00 = Normal (Enabled).
01 = Tri-state (Disabled).
10 = Drive low (Disabled).
11 = Reserved.
17:16
ICH2 (82801BA):
These bits are used to control mode of the Primary IDE signal pins. These bits should always be
set to 00b for desktop implementations.
ICH2-M (82801BAM):
These bits are used to control mode of the Secondary IDE signal pins for mobile swap bay support.
15
Fast Secondary Drive 1 Base Clock (FAST_SCB1)—R/W. This bit is used in conjuction with the
SCT1 bits to enable/disable Ultra ATA/100 timings for the Secondary Slave drive.
0 = Disable Ultra ATA/100 timing for the Secondary Slave drive.
1 = Enable Ultra ATA/100 timing for the Secondary Slave drive (overrides bit 3 in this register).
82801BA ICH2 and 82801BAM ICH2-M Datasheet
10-9
IDE Controller Registers (D31:F1)
Bit
14
13
12
11
Description
Fast Secondary Drive 0 Base Clock (FAST_SCB0)—R/W. This bit is used in conjuction with the
SCT0 bits to enable/disable Ultra ATA/100 timings for the Secondary Master drive.
0 = Disable Ultra ATA/100 timing for the Secondary Master drive.
1 = Enable Ultra ATA/100 timing for the Secondary Master drive (overrides bit 2 in this register).
Fast Primary Drive 1 Base Clock (FAST_PCB1)—R/W. This bit is used in conjuction with the
PCT1 bits to enable/disable Ultra ATA/100 timings for the Primary Slave drive.
0 = Disable Ultra ATA/100 timing for the Primary Slave drive.
1 = Enable Ultra ATA/100 timing for the Primary Slave drive (overrides bit 1 in this register).
Fast Primary Drive 0 Base Clock (FAST_PCB0)—R/W. This bit is used in conjuction with the
PCT0 bits to enable/disable Ultra ATA/100 timings for the Primary Master drive.
0 = Disable Ultra ATA/100 timing for the Primary Master drive.
1 = Enable Ultra ATA/100 timing for the Primary Master drive (overrides bit 0 in this register).
Reserved.
Write Buffer PingPong Enable (WR_PingPong_EN)—R/W.
10
0 = Disabled. The buffer will behave similar to PIIX4.
1 = Enables the write buffer to be used in a split (ping/pong) manner.
9:8
Reserved.
7
Secondary Slave Channel Cable Reporting—R/W. BIOS should program this bit to tell the IDE
driver which cable is plugged into the channel.
0 = 40 conductor cable is present.
1 = 80 conductor cable is present.
6
Secondary Master Channel Cable Reporting—R/W. Same description as bit 7
5
Primary Slave Channel Cable Reporting—R/W. Same description as bit 7
4
Primary Master Channel Cable Reporting—R/W. Same description as bit 7
Secondary Drive 1 Base Clock (SCB1)—R/W.
3
0 = 33 MHz base clock for Ultra ATA timings.
1 = 66 MHz base clock for Ultra ATA timings
Secondary Drive 0 Base Clock (SCBO)—R/W.
2
0 = 33 MHz base clock for Ultra ATA timings.
1 = 66 MHz base clock for Ultra ATA timings
Primary Drive 1 Base Clock (PCB1)—R/W.
1
0 = 33 MHz base clock for Ultra ATA timings.
1 = 66 MHz base clock for Ultra ATA timings
Primary Drive 0 Base Clock (PCB0)—R/W.
0
10-10
0 = 33 MHz base clock for Ultra ATA timings.
1 = 66 MHz base clock for Ultra ATA timings
82801BA ICH2 and 82801BAM ICH2-M Datasheet
IDE Controller Registers (D31:F1)
10.2
Bus Master IDE I/O Registers (D31:F1)
The bus master IDE function uses 16 bytes of I/O space, allocated via the BMIBA register, located
in Device 31:Function 1 Configuration space (offset 20h). All bus master IDE I/O space registers
can be accessed as byte, word, or DWord quantities. Reading reserved bits returns an
indeterminate, inconsistent value; writes to reserved bits have no affect (but should not be
attempted). The description of the I/O registers is shown in Table 10-2.
Table 10-2. Bus Master IDE I/O Registers
Offset
Mnemonic
00h
BMICP
01h
02h
BMISP
03h
Default
Type
Command Register Primary
00h
R/W
Reserved
00h
RO
Status Register Primary
00h
R/WC
Reserved
00h
RO
xxxxxxxxh
R/W
R/W
04h–07h
BMIDP
Descriptor Table Pointer Primary
08h
BMICS
Command Register Secondary
00h
Reserved
00h
RO
Status Register Secondary
00h
R/WC
Reserved
00h
RO
xxxxxxxxh
R/W
09h
0Ah
BMISS
0Bh
0Ch–0Fh
10.2.1
Register
BMIDS
Descriptor Table Pointer Secondary
BMIC[P,S]—Bus Master IDE Command Register
Address Offset:
Default Value:
Primary: 00h
Secondary: 08h
00h
Bit
7:4
3
2:1
Attribute:
R/W
Size:
8 bits
Description
Reserved. Returns 0s.
Read / Write Control (RWC)—R/W. This bit sets the direction of the bus master transfer: This bit
must NOT be changed when the bus master function is active.
0 = Memory reads.
1 = Memory writes
Reserved. Returns 0s.
Start/Stop Bus Master (START)—R/W.
1 = Enables bus master operation of the controller. Bus master operation begins when this bit is
detected changing from a zero to a one. The controller will transfer data between the IDE device
and memory only when this bit is set. Master operation can be halted by writing a '0' to this bit.
0
0 = All state information is lost when this bit is cleared. Master mode operation cannot be stopped
and then resumed. If this bit is reset while bus master operation is still active (i.e., the Bus Master
IDE Active bit of the Bus Master IDE Status register for that IDE channel is set) and the drive has
not yet finished its data transfer (the Interrupt bit in the Bus Master IDE Status register for that
IDE channel is not set), the bus master command is said to be aborted and data transferred from
the drive may be discarded instead of being written to system memory.
This bit is intended to be reset after the data transfer is completed, as indicated by either the Bus
Master IDE Active bit or the Interrupt bit of the Bus Master IDE Status register for that IDE
channel being set, or both.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
10-11
IDE Controller Registers (D31:F1)
10.2.2
BMIS[P,S]—Bus Master IDE Status Register
Address Offset:
Default Value:
Primary: 02h
Secondary: 0Ah
00h
Bit
7
Attribute:
R/WC
Size:
8 bits
Description
Reserved. Returns 0.
Drive 1 DMA Capable—R/W.
6
0 = Not Capable.
1 = Capable. Set by device dependent code (BIOS or device driver) to indicate that drive 1 for this
channel is capable of DMA transfers, and that the controller has been initialized for optimum
performance. The ICH2 does not use this bit. It is intended for systems that do not attach BMIDE
to the PCI bus.
Drive 0 DMA Capable—R/W.
5
4:3
2
0 = Not Capable.
1 = Capable. Set by device dependent code (BIOS or device driver) to indicate that drive 0 for this
channel is capable of DMA transfers and that the controller has been initialized for optimum
performance. The ICH2 does not use this bit. It is intended for systems that do not attach BMIDE
to the PCI bus.
Reserved. Returns 0s.
Interrupt—R/WC. Software can use this bit to determine if an IDE device has asserted its interrupt
line (IRQ14 for the Primary channel and IRQ15 for Secondary).
1 = Set by the rising edge of the IDE interrupt line, regardless of whether or not the interrupt is
masked in the 8259 or the internal I/O APIC. When this bit is read as a one, all data transferred
from the drive is visible in system memory.
0 = This bit is cleared by software writing a '1' to the bit position. If this bit is cleared while the
interrupt is still active, this bit will remain clear until another assertion edge is detected on the
interrupt line.
1
Error—R/WC.
1 = This bit is set when the controller encounters a target abort or master abort when transferring
data on PCI.
0 = This bit is cleared by software writing a '1' to the bit position.
Bus Master IDE Active (ACT)—RO.
1 = Set by the ICH2 when the Start bit is written to the Command register.
0
10.2.3
0 = This bit is cleared by the ICH2 when the last transfer for a region is performed, where EOT for
that region is set in the region descriptor. It is also cleared by the ICH2 when the Start bit is
cleared in the Command register. When this bit is read as a zero, all data transferred from the
drive during the previous bus master command is visible in system memory, unless the bus
master command was aborted.
BMID[P,S]—Bus Master IDE Descriptor Table Pointer
Register
Address Offset:
Default Value:
Bit
10-12
Primary: 04h
Secondary: 0Ch
All bits undefined
Attribute:
R/W
Size:
32 bits
Description
31:2
Base address of Descriptor table (BADDR)—R/W. Corresponds to A[31:2]. The Descriptor Table
must be DWord aligned. The Descriptor Table must not cross a 64 KB boundary in memory.
1:0
Reserved.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
USB Controller Registers
11
USB Controller Registers
11.1
PCI Configuration Registers (D31:F2/F4)
Note:
Registers that are not shown should be treated as Reserved (See Section 6.2 for details).
Table 11-1. PCI Configuration Map (USB—D31:F2/F4)
Register Name/Function
Function 2
Default
Function 4
Default
Type
8086h
8086h
RO
Offset
Mnemonic
00–01h
VID
Vendor ID
02–03h
DID
Device ID
2442h
2444h
RO
04–05h
CMD
Command Register
0000h
0000h
R/W
06–07h
STA
Device Status
0280h
0280h
R/W
08h
RID
Revision ID
See Note
See Note
RO
09h
PI
Programming Interface
00h
00h
RO
0Ah
SCC
Sub Class Code
03h
03h
RO
0Bh
BCC
Base Class Code
0Ch
0Ch
RO
0Eh
HTYPE
Header Type
00h
00h
RO
20–23h
Base
Base Address Register
00000001h
00000001h
R/W
2C–2Dh
SVID
Subsystem Vendor ID
00
00
RO
2E–2Fh
SID
Subsystem ID
00
00
RO
3Ch
INTR_LN
Interrupt Line
00h
00h
R/W
3Dh
INTR_PN
Interrupt Pin
03h
03h
RO
60h
SB_RELNUM
Serial Bus Release Number
10h
10h
RO
C0–C1h
USB_LEGKEY
USB Legacy Keyboard/
Mouse Control
2000h
2000h
R/W
C4h
USB_RES
00h
00h
R/W
USB Resume Enable
NOTE: Refer to the Specification Update for the value of the Revision ID Register.
11.1.1
VID—Vendor Identification Register (USB—D31:F2/F4)
Address Offset:
Default Value:
00–01h
8086h
Bit
15:0
Attribute:
Size:
RO
16 bits
Description
Vendor ID Value—RO. This is a 16-bit value assigned to Intel.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
11-1
USB Controller Registers
11.1.2
DID—Device Identification Register (USB—D31:F2/F4)
Address Offset:
Default Value:
02–03h
Function 2: 2442h
Function 4: 2444h
Bit
15:0
11.1.3
Attribute:
Size:
RO
16 bits
Description
Device ID Value—RO. This is a 16-bit value assigned to the ICH2 USB Host Controllers
CMD—Command Register (USB—D31:F2/F4)
Address Offset:
Default Value:
04–05h
0000h
Bit
15:10
Attribute:
Size:
R/W
16 bits
Description
Reserved.
9
Fast Back to Back Enable (FBE)—RO. Reserved as 0.
8
SERR# Enable—RO. Reserved as 0.
7
Wait Cycle Control—RO. Reserved as 0.
6
Parity Error Response—RO. Reserved as 0.
5
VGA Palette Snoop—RO. Reserved as 0.
4
Postable Memory Write Enable (PMWE)—RO. Reserved as 0.
3
Special Cycle Enable (SCE)—RO. Reserved as 0.
2
Bus Master Enable (BME)—R/W. When set, the ICH2 can act as a master on the PCI bus for USB
transfers.
1
Memory Space Enable (MSE)—RO. Reserved as 0.
0
I/O Space Enable (IOSE)—R/W. This bit controls access to the I/O space registers.
1 = Enable accesses to the USB I/O registers. The Base Address register for USB should be
programmed before this bit is set.
0 = Disable
11-2
82801BA ICH2 and 82801BAM ICH2-M Datasheet
USB Controller Registers
11.1.4
STA—Device Status Register (USB—D31:F2/F4)
Address Offset:
Default Value:
06–07h
0280h
Bit
15:14
Attribute:
Size:
R/WC
16 bits
Description
Reserved as ‘00b’. Read Only.
13
Received Master-Abort Status (RMA)—R/WC.
1 = USB, as a master, generated a master-abort.
12
Reserved. Always read as 0.
0 = Software clears this bit by writing a 1 to the bit location.
Signaled Target-Abort Status (STA)—R/WC.
11
1 = USB function is targeted with a transaction that the ICH2 terminates with a target abort.
0 = Software clears this bit by writing a 1 to the bit location.
10:9
8
Data Parity Error Detected: Reserved as 0. Read Only.
7
Fast Back-to-Back Capable: Reserved as 1. Read Only.
6
User Definable Features (UDF): Reserved as 0. Read Only.
5
66 MHz Capable: Reserved as 0. Read Only.
4:0
11.1.5
DEVSEL# Timing Status (DEVT)—RO. This 2-bit field defines the timing for DEVSEL# assertion.
These read only bits indicate the ICH2's DEVSEL# timing when performing a positive decode. ICH2
generates DEVSEL# with medium timing for USB.
Reserved.
RID—Revision Identification Register (USB—D31:F2/F4)
Address Offset:
Default Value:
08h
See bit description
Bit
7:0
11.1.6
Attribute:
Size:
RO
8 bits
Description
Revision Identification. These bits contain device stepping information and are hardwired to the
default value. Refer to the Specification Update for the value of the Revision ID Register.
PI—Programming Interface (USB—D31:F2/F4)
Address Offset:
Default Value:
09h
00h
Bit
7:0
Attribute:
Size:
RO
8 bits
Description
Programming Interface—RO.
00h = No specific register level programming interface defined.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
11-3
USB Controller Registers
11.1.7
SCC—Sub Class Code Register (USB—D31:F2/F4)
Address Offset:
Default Value:
0Ah
03h
Bit
7:0
11.1.8
Sub Class Code—RO.
03h = Universal Serial Bus Host Controller.
BCC—Base Class Code Register (USB—D31:F2/F4)
0Bh
0Ch
Bit
7:0
RO
8 bits
Base Class Code—RO.
0Ch = Serial Bus controller.
BASE—Base Address Register (USB—D31:F2/F4)
20–23h
00000001h
Bit
Attribute:
Size:
R/W
32 bits
Description
31:16
Reserved.
15:5
Base Address—R/W. Bits [15:5] correspond to I/O address signals AD [15:5], respectively. This
gives 32 bytes of relocatable I/O space.
4:1
Reserved.
0
Resource Type Indicator (RTE)—RO. This bit is hardwired to 1 indicating that the base address
field in this register maps to I/O space
SVID—Subsystem Vendor ID (USB—D31:F2/F4)
Address Offset:
Default Value:
Lockable:
Bit
15:0
11-4
Attribute:
Size:
Description
Address Offset:
Default Value:
11.1.10
RO
8 bits
Description
Address Offset:
Default Value:
11.1.9
Attribute:
Size:
2Ch–2Dh
00h
No
Attribute:
Size:
Power Well:
RO
16 bits
Core
Description
Subsystem Vendor ID (SVID)—RO. The SVID register, in combination with the Subsystem ID
(SID) register, enables the operating system (OS) to distinguish subsystems from each other. The
value returned by reads to this register is the same as that which was written by BIOS into the
IDE_SVID register.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
USB Controller Registers
11.1.11
SID—Subsystem ID (USB—D31:F2/F4)
Address Offset:
Default Value:
Lockable:
11.1.12
Attribute:
Size:
Power Well:
RO
16 bits
Core
Bit
Description
15:0
Subsystem ID (SID)—R/Write-Once. The SID register, in combination with the SVID register,
enables the operating system (OS) to distinguish subsystems from each other. The value returned
by reads to this register is the same as that which was written by BIOS into the IDE_SID register.
INTR_LN—Interrupt Line Register (USB—D31:F2/F4)
Address Offset:
Default Value:
11.1.13
2Eh–2Fh
00h
No
3Ch
00h
Attribute:
Size:
R/W
8 bits
Bit
Description
7:0
Interrupt Line—R/W. This data is not used by the ICH2. It is to communicate to software the interrupt
line that the interrupt pin is connected to.
INTR_PN—Interrupt Pin Register (USB—D31:F2/F4)
Address Offset:
Default Value:
Default Value:
3Dh
Attribute:
Size:
Function 2: 03h(82801BA ICH2)
04h (82801B AM ICH2-M)
Function 4: 03h (both ICH2 and ICH2-M)
Bit
7:3
RO
8 bits
Description
Reserved.
Interrupt Pin—RO. The value of 03h in Function 2 indicates that the ICH2 will drive PIRQD# as its
interrupt line for USB Controller 0 (ports 0 and 1).
2:0
11.1.14
The value of 03h in Function 4 indicates that the ICH2 will drive PIRQC# as its interrupt line for USB
Controller 1 (ports 2 and 3). However, in the ICH2 implementation, when the USB Controller 1
interrupt is generated PIRQ[H]# will go active, not PIRQ[C]#.
SB_RELNUM—Serial Bus Release Number Register
(USB—D31:F2/F4)
Address Offset:
Default Value:
60h
10h
Bit
7:0
Attribute:
Size:
RO
8 bits
Description
Serial Bus Release Number—RO.
10h = Indicates that the USB controller is compliant with the USB specification release 1.0.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
11-5
USB Controller Registers
11.1.15
USB_LEGKEY—USB Legacy Keyboard/Mouse Control
Register (USB—D31:F2/F4)
Address Offset:
Default Value:
Bit
15
C0–C1
2000h
Attribute:
Size:
R/W, R/WC, RO
16 bits
Description
SMI Caused by End of Pass-through (SMIBYENDPS)—R/WC. Indicates if the event occurred.
Note that even if the corresponding enable bit is not set in bit 0, this bit will still be active. It is up to the
SMM code to use the enable bit to determine the exact cause of the SMI#.
1 = Event Occurred
0 = Software clears this bit by writing a 1 to the bit location.
14
13
Reserved.
PCI Interrupt Enable (USBPIRQEN)—R/W. Used to prevent the USB controller from generating an
interrupt due to transactions on its ports. Note that it will probably be configured to generate an SMI
using bit 4 of this register. Default to 1 for compatibility with older USB software.
1 = Enable
0 = Disable
12
SMI Caused by USB Interrupt (SMIBYUSB)—RO. Indicates if the event occurred. Note that even if
the corresponding enable bit is not set in the bit 4, this bit will still be active. It is up to the SMM code
to use the enable bit to determine the exact cause of the SMI#.
1 = Event Occurred
0 = Software should clear the IRQ via the USB controller. Writing a 1 to this bit will have no effect.
11
SMI Caused by Port 64 Write (TRAPBY64W)—R/WC. Indicates if the event occurred. Note that
even if the corresponding enable bit is not set in bit 3, this bit will still be active. It is up to the SMM
code to use the enable bit to determine the exact cause of the SMI#.
1 = Event Occurred
0 = Software clears this bit by writing a 1 to the bit location.
10
SMI Caused by Port 64 Read (TRAPBY64R)—R/WC. Indicates if the event occurred. Note that
even if the corresponding enable bit is not set in bit 2, this bit will still be active. It is up to the SMM
code to use the enable bit to determine the exact cause of the SMI#.
1 = Event Occurred
0 = Software clears this bit by writing a 1 to the bit location.
9
SMI Caused by Port 60 Write (TRAPBY60W)—R/WC. Indicates if the event occurred. Note that
even if the corresponding enable bit is not set in bit 1, this bit will still be active. It is up to the SMM
code to use the enable bit to determine the exact cause of the SMI#.
1 = Event Occurred
0 = Software clears this bit by writing a 1 to the bit location.
8
SMI Caused by Port 60 Read (TRAPBY60R)—R/WC. Indicates if the event occurred. Note that
even if the corresponding enable bit is not set in bit 0, this bit will still be active. It is up to the SMM
code to use the enable bit to determine the exact cause of the SMI#.
1 = Event Occurred
0 = Software clears this bit by writing a 1 to the bit location.
7
SMI at End of Pass-through Enable (SMIATENDPS)—R/W. May need to cause SMI at the end of a
pass-through. Can occur if an SMI is generated in the middle of a pass through, and needs to be
serviced later.
1 = Enable
0 = Disable
6
Pass Through State (PSTATE)—RO.
1 = Indicates that the state machine is in the middle of an A20GATE pass-through sequence.
0 = If software needs to reset this bit, it should set bit 5 to 0.
5
A20Gate Pass-Through Enable (A20PASSEN)—R/W.
1 = Allows A20GATE sequence Pass-Through function. SMI# will not be generated, even if the
various enable bits are set.
0 = Disable
11-6
82801BA ICH2 and 82801BAM ICH2-M Datasheet
USB Controller Registers
Bit
4
Description
SMI on USB IRQ Enable (USBSMIEN)—R/W.
1 = USB interrupt will cause an SMI event.
0 = Disable
3
SMI on Port 64 Writes Enable (64WEN)—R/W.
1 = A write to port 64h will cause an SMI event.
0 = Disable
2
SMI on Port 64 Reads Enable (64REN)—R/W.
1 = A read to port 64h will cause an SMI event.
0 = Disable
1
SMI on Port 60 Writes Enable (60WEN)—R/W.
1 = A write to port 60h will cause an SMI event.
0 = Disable
0
SMI on Port 60 Reads Enable (60REN)—R/W.
1 = A read to port 60h will cause an SMI event.
0 = Disable
11.1.16
USB_RES—USB Resume Enable Register
(USB—D31:F2/F4)
Address Offset:
Default Value:
C4h
00h
Bit
7:2
1
Attribute:
Size:
R/W
8 bits
Description
Reserved.
PORT1EN—R/W. Enable the USB controller to respond to wakeup events on this port. For Function
2 this applies to port 1; for Function 4, this applies to port 3.
1 = The USB controller will monitor this port for remote wakeup and connect/disconnect events.
0 = The USB controller will not look at this port for a wakeup event.
0
PORT0EN—R/W. Enable the USB controller to respond to wakeup events on this port. For Function
2 this applies to port 0; for Function 4, this applies to port 2.
1 = The USB controller will monitor this port for remote wakeup and connect/disconnect events.
0 = The USB controller will not look at this port for a wakeup event.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
11-7
USB Controller Registers
11.2
USB I/O Registers
Some of the read/write register bits that deal with changing the state of the USB hub ports function
such that on read back they reflect the current state of the port, and not necessarily the state of the
last write to the register. This allows the software to poll the state of the port and wait until it is in
the proper state before proceeding. A Host Controller Reset, Global Reset, or Port Reset will
immediately terminate a transfer on the affected ports and disable the port. This affects the
USBCMD register, bit [4] and the PORTSC registers, bits [12,6,2]. See individual bit descriptions
for more detail.
Table 11-2. USB I/O Registers
Offset
Mnemonic
00–01h
USBCMD
Register
USB Command Register
Default
Type
0000h
R/W*
02–03h
USBSTS
USB Status Register
0020h
R/WC
04–05h
USBINTR
USB Interrupt Enable
0000h
R/W
USB Frame Number
06–07h
FRNUM
08–0Bh
FRBASEADD
0Ch
SOFMOD
0D–0Fh
—
USB Frame List Base Address
USB Start of Frame Modify
Reserved
0000h
R/W (see Note 1)
Undefined
R/W
40h
R/W
0
RO
10–11h
PORTSC0
Port 0 Status/Control
0080h
R/WC (see Note 1)
12–13h
PORTSC1
Port 1 Status/Control
0080h
R/WC (see Note 1)
14–17h
—
18h
LOOPDATA
Reserved
Loop Back Test Data
0
RO
00h
RO
NOTES:
1. These registers are Word writable only. Byte writes to these registers have unpredictable effects.
11.2.1
USBCMD—USB Command Register
I/O Offset:
Default Value:
Base + (00–01h)
0000h
Attribute:
Size:
R/W
16 bits
The Command Register indicates the command to be executed by the serial bus host controller.
Writing to the register causes a command to be executed. The table following the bit description
provides additional information on the operation of the Run/Stop and Debug bits.
Bit
15:7
8
Description
Reserved.
Loop Back Test Mode—R/W.
1 = ICH2 is in loop back test mode. When both ports are connected together, a write to one port will
be seen on the other port and the data will be stored in I/O offset 18h.
0 = Disable loop back test mode.
7
Max Packet (MAXP)—R/W. This bit selects the maximum packet size that can be used for full
speed bandwidth reclamation at the end of a frame. This value is used by the Host Controller to
determine whether it should initiate another transaction based on the time remaining in the SOF
counter. Use of reclamation packets larger than the programmed size will cause a Babble error if
executed during the critical window at frame end. The Babble error results in the offending endpoint
being stalled. Software is responsible for ensuring that any packet which could be executed under
bandwidth reclamation be within this size limit.
1 = 64 bytes
0 = 32 bytes
11-8
82801BA ICH2 and 82801BAM ICH2-M Datasheet
USB Controller Registers
Bit
6
Description
Configure Flag (CF)—R/W. This bit has no effect on the hardware. It is provided only as a
semaphore service for software.
1 = HCD software sets this bit as the last action in its process of configuring the Host Controller.
0 = Indicates that software has not completed host controller configuration.
5
Software Debug (SWDBG)—R/W. The SWDBG bit must only be manipulated when the controller is
in the stopped state. This can be determined by checking the HCHalted bit in the USBSTS register.
1 = Debug mode. In SW Debug mode, the Host Controller clears the Run/Stop bit after the
completion of each USB transaction. The next transaction is executed when software sets the
Run/Stop bit back to 1.
0 = Normal Mode.
4
3
Force Global Resume (FGR)—R/W.
1 = Host Controller sends the Global Resume signal on the USB, and sets this bit to 1 when a
resume event (connect, disconnect, or K-state) is detected while in global suspend mode.
0 = Software resets this bit to 0 after 20 ms has elapsed to stop sending the Global Resume signal.
At that time all USB devices should be ready for bus activity. The 1 to 0 transition causes the
port to send a low speed EOP signal. This bit will remain a 1 until the EOP has completed.
Enter Global Suspend Mode (EGSM)—R/W.
1 = Host Controller enters the Global Suspend mode. No USB transactions occur during this time.
The Host Controller is able to receive resume signals from USB and interrupt the system.
Software must ensure that the Run/Stop bit (bit 0) is cleared prior to setting this bit.
0 = Software resets this bit to 0 to come out of Global Suspend mode. Software writes this bit to 0 at
the same time that Force Global Resume (bit 4) is written to 0 or after writing bit 4 to 0.
2
Global Reset (GRESET)—R/W.
1 = Global Reset. The Host Controller sends the global reset signal on the USB and then resets all
its logic, including the internal hub registers. The hub registers are reset to their power on state.
Chip Hardware Reset has the same effect as Global Reset (bit 2), except that the Host
Controller does not send the Global Reset on USB.
0 = This bit is reset by the software after a minimum of 10 ms has elapsed as specified in Chapter 7
of the USB Specification.
1
Host Controller Reset (HCRESET)—R/W. The effects of HCRESET on Hub registers are slightly
different from Chip Hardware Reset and Global USB Reset. The HCRESET affects bits [8,3:0] of the
Port Status and Control Register (PORTSC) of each port. HCRESET resets the state machines of
the Host Controller including the Connect/Disconnect state machine (one for each port). When the
Connect/Disconnect state machine is reset, the output that signals connect/disconnect are negated
to 0, effectively signaling a disconnect, even if a device is attached to the port. This virtual
disconnect causes the port to be disabled. This disconnect and disabling of the port causes bit 1
(connect status change) and bit 3 (port enable/disable change) of the PORTSC to get set. The
disconnect also causes bit 8 of PORTSC to reset. About 64 bit times after HCRESET goes to 0, the
connect and low-speed detect will take place, and bits 0 and 8 of the PORTSC will change
accordingly.
1 = Reset. When this bit is set, the Host Controller module resets its internal timers, counters, state
machines, etc. to their initial value. Any transaction currently in progress on USB is immediately
terminated.
0 = Reset by the Host Controller when the reset process is complete.
0
Run/Stop (RS)—R/W. When set to 1, the ICH2 proceeds with execution of the schedule. The ICH2
continues execution as long as this bit is set. When this bit is cleared, the ICH2 completes the
current transaction on the USB and then halts. The HC Halted bit in the status register indicates
when the Host Controller has finished the transaction and has entered the stopped state. The Host
Controller clears this bit when the following fatal errors occur: consistency check failure, PCI Bus
errors.
1 = Run
0 = Stop
82801BA ICH2 and 82801BAM ICH2-M Datasheet
11-9
USB Controller Registers
Table 11-3. Run/Stop, Debug Bit Interaction SWDBG (Bit 5), Run/Stop (Bit 0) Operation
SWDBG
(Bit 5)
Run/Stop
(Bit 0)
Description
0
0
If executing a command, the Host Controller completes the command and then
stops. The 1.0 ms frame counter is reset and command list execution resumes from
start of frame using the frame list pointer selected by the current value in the FRNUM
register. (While Run/Stop=0, the FRNUM register can be reprogrammed).
0
1
Execution of the command list resumes from Start Of Frame using the frame list
pointer selected by the current value in the FRNUM register. The Host Controller
remains running until the Run/Stop bit is cleared (by software or hardware).
1
0
If executing a command, the Host Controller completes the command and then stops
and the 1.0 ms frame counter is frozen at its current value. All status are preserved.
The Host Controller begins execution of the command list from where it left off when
the Run/Stop bit is set.
1
Execution of the command list resumes from where the previous execution stopped.
The Run/Stop bit is set to 0 by the Host Controller when a TD is being fetched. This
causes the Host Controller to stop again after the execution of the TD (single step).
When the Host Controller has completed execution, the HC Halted bit in the Status
Register is set.
1
When the USB Host Controller is in Software Debug Mode (USBCMD Register bit 5=1), the
single stepping software debug operation is as follows:
To Enter Software Debug Mode:
1. HCD puts Host Controller in Stop state by setting the Run/Stop bit to 0.
2. HCD puts Host Controller in Debug Mode by setting the SWDBG bit to 1.
3. HCD sets up the correct command list and Start Of Frame value for starting point in the Frame
List Single Step Loop.
4. HCD sets Run/Stop bit to 1.
5. Host Controller executes next active TD, sets Run/Stop bit to 0, and stops.
6. HCD reads the USBCMD register to check if the single step execution is completed
(HCHalted=1).
7. HCD checks results of TD execution. Go to step 4 to execute next TD or step 8 to end
Software Debug mode.
8. HCD ends Software Debug mode by setting SWDBG bit to 0.
9. HCD sets up normal command list and Frame List table.
10. HCD sets Run/Stop bit to 1 to resume normal schedule execution.
In Software Debug mode, when the Run/Stop bit is set, the Host Controller starts. When a valid TD
is found, the Run/Stop bit is reset. When the TD is finished, the HCHalted bit in the USBSTS
register (bit 5) is set.
The SW Debug mode skips over inactive TDs and only halts after an active TD has been executed.
When the last active TD in a frame has been executed, the Host Controller waits until the next SOF
is sent and then fetches the first TD of the next frame before halting.
This HCHalted bit can also be used outside of Software Debug mode to indicate when the Host
Controller has detected the Run/Stop bit and has completed the current transaction. Outside of the
Software Debug mode, setting the Run/Stop bit to 0 always resets the SOF counter so that when the
Run/Stop bit is set the Host Controller starts over again from the frame list location pointed to by
the Frame List Index (see FRNUM Register description) rather than continuing where it stopped.
11-10
82801BA ICH2 and 82801BAM ICH2-M Datasheet
USB Controller Registers
11.2.2
USBSTA—USB Status Register
I/O Offset:
Default Value:
Base + (02–03h)
0020h
Attribute:
Size:
R/WC
16 bits
This register indicates pending interrupts and various states of the Host Controller. The status
resulting from a transaction on the serial bus is not indicated in this register. Software sets a bit to 0
in this register by writing a 1 to it.
Bit
15:6
5
Description
Reserved.
HCHalted—R/WC.
1 = The Host Controller has stopped executing as a result of the Run/Stop bit being set to 0, either
by software or by the Host Controller hardware (debug mode or an internal error). Default.
0 = Software resets this bit to 0 by writing a 1 to the bit position.
4
Host Controller Process Error—R/WC.
1 = The Host Controller has detected a fatal error. This indicates that the Host Controller suffered
a consistency check failure while processing a Transfer Descriptor. An example of a
consistency check failure would be finding an illegal PID field while processing the packet
header portion of the TD. When this error occurs, the Host Controller clears the Run/Stop bit
in the Command register to prevent further schedule execution. A hardware interrupt is
generated to the system.
0 = Software resets this bit to 0 by writing a 1 to the bit position.
3
Host System Error—R/WC.
1 = A serious error occurred during a host system access involving the Host Controller module. In
a PCI system, conditions that set this bit to 1 include PCI Parity error, PCI Master Abort, and
PCI Target Abort. When this error occurs, the Host Controller clears the Run/Stop bit in the
Command register to prevent further execution of the scheduled TDs. A hardware interrupt is
generated to the system.
0 = Software resets this bit to 0 by writing a 1 to the bit position.
2
Resume Detect (RSM_DET)—R/WC.
1 = The Host Controller received a “RESUME” signal from a USB device. This is only valid if the
Host Controller is in a global suspend state (bit 3 of Command register = 1).
0 = Software resets this bit to 0 by writing a 1 to the bit position.
1
USB Error Interrupt—R/WC.
1 = Completion of a USB transaction resulted in an error condition (e.g., error counter underflow).
If the TD on which the error interrupt occurred also had its IOC bit set, both this bit and Bit 0
are set.
0 = Software resets this bit to 0 by writing a 1 to the bit position.
0
USB Interrupt (USBINT)—R/WC.
1 = The Host Controller sets this bit when the cause of an interrupt is a completion of a USB
transaction whose Transfer Descriptor had its IOC bit set. Also set when a short packet is
detected (actual length field in TD is less than maximum length field in TD), and short packet
detection is enabled in that TD.
0 = Software resets this bit to 0 by writing a 1 to the bit position.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
11-11
USB Controller Registers
11.2.3
USBINTR—Interrupt Enable Register
I/O Offset:
Default Value:
Base + (04–05h)
0000h
Attribute:
Size:
R/W
16 bits
This register enables and disables reporting of the corresponding interrupt to the software. When a
bit is set and the corresponding interrupt is active, an interrupt is generated to the host. Fatal errors
(Host Controller Processor Error-bit 4, USBSTS Register) cannot be disabled by the host
controller. Interrupt sources that are disabled in this register still appear in the Status Register to
allow the software to poll for events.
Bit
15:4
3
Description
Reserved.
Short Packet Interrupt Enable—R/W.
1 = Enabled.
0 = Disabled.
2
Interrupt On Complete (IOC) Enable—R/W.
1 = Enabled.
0 = Disabled.
1
Resume Interrupt Enable—R/W.
1 = Enabled.
0 = Disabled.
0
Time-out/CRC Interrupt Enable—R/W.
1 = Enabled.
0 = Disabled.
11.2.4
FRNUM—Frame Number Register
I/O Offset:
Default Value:
Base + (06–07h)
0000h
Attribute:
Size:
R/W (Writes must be Word Writes)
16 bits
Bits [10:0] of this register contain the current frame number which is included in the frame SOF
packet. This register reflects the count value of the internal frame number counter. Bits [9:0] are
used to select a particular entry in the Frame List during scheduled execution. This register is
updated at the end of each frame time.
This register must be written as a word. Byte writes are not supported. This register cannot be
written unless the Host Controller is in the STOPPED state as indicated by the HCHalted bit
(USBSTS register). A write to this register while the Run/Stop bit is set (USBCMD register) is
ignored.
Bit
11-12
Description
15:11
Reserved.
10:0
Frame List Current Index/Frame Number—R/W. Provides the frame number in the SOF Frame.
The value in this register increments at the end of each time frame (approximately every 1 ms). In
addition, bits [9:0] are used for the Frame List current index and correspond to memory address
signals [11:2].
82801BA ICH2 and 82801BAM ICH2-M Datasheet
USB Controller Registers
11.2.5
FRBASEADD—Frame List Base Address
I/O Offset:
Default Value:
Base + (08–0Bh)
Undefined
Attribute:
Size:
R/W
32 bits
This 32-bit register contains the beginning address of the Frame List in the system memory. HCD
loads this register prior to starting the schedule execution by the Host Controller. When written,
only the upper 20 bits are used. The lower 12 bits are written as zero (4-KB alignment). The
contents of this register are combined with the frame number counter to enable the Host Controller
to step through the Frame List in sequence. The two least significant bits are always 00. This
requires DWord alignment for all list entries. This configuration supports 1024 Frame List entries.
Bit
31:12
11:0
11.2.6
Description
Base Address—R/W. These bits correspond to memory address signals [31:12], respectively.
Reserved.
SOFMOD—Start of Frame Modify Register
I/O Offset:
Default Value:
Base + (0Ch)
40h
Attribute:
Size:
R/W
8 bits
This 1-byte register is used to modify the value used in the generation of SOF timing on the USB.
Only the 7 least significant bits are used. When a new value is written into these 7 bits, the SOF
timing of the next frame will be adjusted. This feature can be used to adjust out any offset from the
clock source that generates the clock that drives the SOF counter. This register can also be used to
maintain real time synchronization with the rest of the system so that all devices have the same
sense of real time. Using this register, the frame length can be adjusted across the full range
required by the USB specification. Its initial programmed value is system dependent based on the
accuracy of hardware USB clock and is initialized by system BIOS. It may be reprogrammed by
USB system software at any time. Its value will take effect from the beginning of the next frame.
This register is reset upon a Host Controller Reset or Global Reset. Software must maintain a copy
of its value for reprogramming if necessary.
Bit
7
Description
Reserved.
SOF Timing Value—R/W. Guidelines for the modification of frame time are contained in Chapter 7 of
the USB Specification. The SOF cycle time (number of SOF counter clock periods to generate a SOF
frame length) is equal to 11936 + value in this field. The default value is decimal 64 which gives a SOF
cycle time of 12000. For a 12 MHz SOF counter clock input, this produces a 1 ms Frame period. The
following table indicates what SOF Timing Value to program into this field for a certain frame period.
6:0
Frame Length
(# 12 MHz Clocks)
(decimal)
SOF Reg. Value
(decimal)
11936
11937
.
.
11999
12000
12001
.
.
12062
12063
0
1
.
.
63
64
65
.
.
126
127
82801BA ICH2 and 82801BAM ICH2-M Datasheet
11-13
USB Controller Registers
11.2.7
PORTSC[0,1]—Port Status and Control Register
I/O Offset:
Default Value:
Note:
Port 0/2: Base + (10–11h)
Port 1/3: Base + (12–13h)
0080h
Attribute:
R/W (Word writes only)
Size:
16 bits
For Function 2, this applies to ICH2 USB ports 0 and 1. For Function 4, this applies to ICH2 USB
ports 2 and 3.
After a Power-up reset, Global reset, or Host Controller reset, the initial conditions of a port are: no
device connected, Port disabled, and the bus line status is 00 (single-ended zero).
Bit
15:13
Description
Reserved—RO.
Suspend—R/W. This bit should not be written to a 1 if global suspend is active (bit 3=1 in the
USBCMD register). Bit 2 and bit 12 of this register define the hub states as follows:
Bits [12,2]
X0
01
11
12
Hub State
Disable
Enable
Suspend
When in suspend state, downstream propagation of data is blocked on this port, except for singleended 0 resets (global reset and port reset). The blocking occurs at the end of the current
transaction, if a transaction was in progress when this bit was written to 1. In the suspend state, the
port is sensitive to resume detection. Note that the bit status does not change until the port is
suspended and that there may be a delay in suspending a port if there is a transaction currently in
progress on the USB.
1 = Port in suspend state.
0 = Port not in suspend state.
Note: Normally, if a transaction is in progress when this bit is set, the port will be suspended when
the current transaction completes. However, in the case of a specific error condition (out transaction
with babble), the ICH2 may issue a start-of-frame, and then suspend the port.
11
Overcurrent Indicator—R/WC. Set by hardware
1 = Overcurrent pin has gone from inactive to active on this port.
0 = Software clears this bit by writing a 1 to the bit position.
10
Overcurrent Active—RO. This bit is set and cleared by hardware.
1 = Indicates that the overcurrent pin is active (low).
0 = Indicates that the overcurrent pin is inactive (high).
9
Port Reset—RO.
1 = Port is in Reset. When set, the port is disabled and sends the USB Reset signaling.
0 = Port is not in Reset.
8
Low Speed Device Attached (LS)—RO. Writes have no effect.
1 = Low speed device is attached to this port.
7
Reserved—RO. Always read as 1.
0 = Full speed device is attached.
6
Resume Detect (RSM_DET)—R/W. Software sets this bit to a 1 to drive resume signaling. The
Host Controller sets this bit to a 1 if a J-to-K transition is detected for at least 32 microseconds while
the port is in the Suspend state. The ICH2 then reflects the K-state back onto the bus as long as the
bit remains a 1 and the port is still in the suspend state (bit 12,2 are 11). Writing a 0 (from 1) causes
the port to send a low speed EOP. This bit will remain a 1 until the EOP has completed.
1 = Resume detected/driven on port.
0 = No resume (K-state) detected/driven on port.
5:4
11-14
Line Status—RO. These bits reflect the D+ (bit 4) and D- (bit 5) signals lines’ logical levels. These
bits are used for fault detect and recovery as well as for USB diagnostics. This field is updated at
EOF2 time (See Chapter 11 of the USB Specification).
82801BA ICH2 and 82801BAM ICH2-M Datasheet
USB Controller Registers
Bit
3
Description
Port Enable/Disable Change—R/WC. For the root hub, this bit gets set only when a port is
disabled due to disconnect on that port or due to the appropriate conditions existing at the EOF2
point (See Chapter 11 of the USB Specification).
1 = Port enabled/disabled status has changed.
0 = No change. Software clears this bit by writing a 1 to the bit location.
2
Port Enabled/Disabled (PORT_EN)—R/W. Ports can be enabled by host software only. Ports can
be disabled by either a fault condition (disconnect event or other fault condition) or by host software.
Note that the bit status does not change until the port state actually changes and that there may be
a delay in disabling or enabling a port if there is a transaction currently in progress on the USB.
1 = Enable.
0 = Disable.
1
Connect Status Change—R/WC. Indicates that a change has occurred in the port’s Current
Connect Status (see bit 0). The hub device sets this bit for any changes to the port device connect
status, even if system software has not cleared a connect status change. If, for example, the
insertion status changes twice before system software has cleared the changed condition, hub
hardware will be setting” an already-set bit (i.e., the bit will remain set). However, the hub transfers
the change bit only once when the Host Controller requests a data transfer to the Status Change
endpoint. System software is responsible for determining state change history in such a case.
1 = Change in Current Connect Status.
0 = No change. Software clears this bit by writing a 1 to the bit location.
0
Current Connect Status—RO. This value reflects the current state of the port, and may not
correspond directly to the event that caused the Connect Status Change bit (Bit 1) to be set.
1 = Device is present on port.
0 = No device is present.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
11-15
USB Controller Registers
This page is intentionally left blank.
11-16
82801BA ICH2 and 82801BAM ICH2-M Datasheet
SMBus Controller Registers (D31:F3)
SMBus Controller Registers (D31:F3) 12
12.1
PCI Configuration Registers (SMBUS—D31:F3)
Table 12-1. PCI Configuration Registers (SMBUS—D31:F3)
Note:
12.1.1
Offset
Mnemonic
00–01h
VID
Register Name/Function
Vendor ID
RO
02–03h
DID
Device ID
04–05h
CMD
Command Register
06–07h
STA
Device Status
08h
RID
Revision ID
RO
RO
RO, R/W
RO, R/WC
09h
PI
Programming Interface
RO
0Ah
SCC
Sub Class Code
RO
0Bh
BCC
Base Class Code
RO
20–23h
SMB_BASE
SMBus Base Address Register
R/W
2C–2Dh
SVID
Subsystem Vendor ID
RO
2E–2Fh
SID
Subsystem ID
RO
3Ch
INTR_LN
Interrupt Line
R/W
3Dh
INTR_PN
Interrupt Pin
RO
40h
HOSTC
Host Configuration
R/W
Registers that are not shown should be treated as Reserved (See Section 6.2 for details).
VID—Vendor Identification Register (SMBUS—D31:F3)
Address:
Default Value:
00–01h
8086h
Bit
15:0
12.1.2
Attribute
Attributes:
Size:
RO
16 bits
Description
Vendor ID Value—RO. This is a 16 bit value assigned to Intel
DID—Device Identification Register (SMBUS—D31:F3)
Address:
Default Value:
02–03h
2443h
Bit
15:0
Attributes:
Size:
RO
16 bits
Description
Device ID value—RO.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
12-1
SMBus Controller Registers (D31:F3)
12.1.3
CMD—Command Register (SMBUS—D31:F3)
Address:
Default Value:
04–05h
0000h
Bit
15:10
Attributes:
Size:
RO, R/W
16 bits
Description
Reserved.
9
Fast Back to Back Enable (FBE)—RO. Reserved as 0.
8
SERR# Enable (SERREN)—RO. Reserved as 0.
7
Wait Cycle Control (WCC)—RO. Reserved as 0.
6
Parity Error Response (PER)—RO. Reserved as 0.
5
VGA Palette Snoop (VPS)—RO. Reserved as 0.
4
Postable Memory Write Enable (PMWE)—RO. Reserved as 0.
3
Special Cycle Enable (SCE)—RO. Reserved as 0.
2
Bus Master Enable (BME)—RO. Reserved as 0.
1
Memory Space Enable (MSE)—RO. Reserved as 0.
I/O Space Enable (IOSE)—R/W.
0
12.1.4
0 = Disable.
1 = Enables access to the SM Bus I/O space registers as defined by the Base Address Register.
STA—Device Status Register (SMBUS—D31:F3)
Address:
Default Value:
06–07h
0280h
Bit
Attributes:
Size:
RO, R/WC
16 bits
Description
15
Detected Parity Error (DPE)—RO. Reserved as 0.
14
Signaled System Error (SSE)—RO. Reserved as 0.
13
Received Master Abort (RMA)—RO. Reserved as 0.
12
Received Target Abort (RTA)—RO. Reserved as 0.
Signaled Target-Abort Status (STA)—R/WC.
11
1 = Function is targeted with a transaction that the ICH2 terminates with a target abort.
0 = Software resets STA to 0 by writing a 1 to this bit location.
10:9
DEVSEL# Timing Status (DEVT)—RO. This 2-bit field defines the timing for DEVSEL# assertion
for positive decode.
01 = Medium timing.
8
Data Parity Error Detected—RO. Reserved as 0.
7
Fast Back-to-Back Capable—RO. Reserved as 1.
6
User Definable Features (UDF)—RO. Reserved as 0.
5
66 MHz Capable—RO. Reserved as 0.
4:0
12-2
Reserved.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
SMBus Controller Registers (D31:F3)
12.1.5
RID—Revision ID Register (SMBUS—D31:F3)
Offset Address:
Default Value:
08h
See bit description
Bit
7:0
12.1.6
Revision Identification Number. 8-bit value that indicates the revision number for the SMBus
Controller. Refer to the Specification Update for the value of the Revision ID Register
PI—Programming Interface (SMBUS—D31:F3)
09h
80h
Bit
7:0
Attribute:
Size:
RO
8 bits
Description
Programming Interface Value—RO.
80h = The 1b in bit 7 indicates that this IDE controller is capable of bus master operation.
SCC—Sub Class Code Register (SMBUS—D31:F3)
Address Offset:
Default Value:
0Ah
05h
Bit
7:0
12.1.8
RO
8 bits
Description
Address Offset:
Default Value:
12.1.7
Attribute:
Size:
Attributes:
Size:
RO
8 bits
Description
Sub Class Code—RO.
05h = SM Bus serial controller
BCC—Base Class Code Register (SMBUS—D31:F3)
Address Offset:
Default Value:
0Bh
0Ch
Bit
7:0
Attributes:
Size:
RO
8 bits
Description
Base Class Code—RO.
0Ch = Serial controller.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
12-3
SMBus Controller Registers (D31:F3)
12.1.9
SMB_BASE—SMBus Base Address Register
(SMBUS—D31:F3)
Address Offset:
Default Value:
20–23h
00000001h
Bit
Description
Reserved.
15:4
Base Address—R/W. Provides the 16-bit system I/O base address for the ICH2 SMB logic.
3:1
Reserved.
IO Space Indicator—RO. This read-only bit is always 1, indicating that the SMB logic is I/O
mapped.
SVID—Subsystem Vendor ID (SMBUS—D31:F2/F4)
Address Offset:
Default Value:
Lockable:
2Ch–2Dh
00h
No
Bit
15:0
12.1.11
RO
16 bits
Core
Subsystem Vendor ID (SVID)—RO. The SVID register, in combination with the Subsystem ID
(SID) register, enables the operating system (OS) to distinguish subsystems from each other. The
value returned by reads to this register is the same as that which was written by BIOS into the
IDE_SVID register.
SID—Subsystem ID (SMBUS—D31:F2/F4)
2Eh–2Fh
00h
No
Attribute:
Size:
Power Well:
RO
16 bits
Core
Bit
Description
15:0
Subsystem ID (SID)—R/Write-Once. The SID register, in combination with the SVID register,
enables the operating system (OS) to distinguish subsystems from each other. The value returned
by reads to this register is the same as that which was written by BIOS into the IDE_SID register.
INTR_LN—Interrupt Line Register (SMBUS—D31:F3)
Address Offset:
Default Value:
12-4
Attribute:
Size:
Power Well:
Description
Address Offset:
Default Value:
Lockable:
12.1.12
R/W
32-bits
31:16
0
12.1.10
Attribute:
Size:
3Ch
00h
Attributes:
Size:
R/W
8 bits
Bit
Description
7:0
Interrupt line—R/W. This data is not used by the ICH2. It is to communicate to software the interrupt
line that the interrupt pin is connected to PIRQB#.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
SMBus Controller Registers (D31:F3)
12.1.13
INTR_PN—Interrupt Pin Register (SMBUS—D31:F3)
Address Offset:
Default Value:
3Dh
02h
Bit
7:0
12.1.14
Attributes:
Size:
RO
8 bits
Description
Interrupt PIN—RO.
02h = Indicates that the ICH2 SMBus Controller will drive PIRQB# as its interrupt line.
HOSTC—Host Configuration Register (SMBUS—D31:F3)
Address Offset:
Default Value:
40h
00h
Bit
7:3
Attribute:
Size:
R/W
8 bits
Description
Reserved.
I2C Enable (I2C_EN)—R/W.
2
0 = SMBus behavior.
1 = The ICH2 is enabled to communicate with I2C devices. This will change the formatting of some
commands.
SMBus to SMI Enable (SMB_SMI_EN)—R/W.
1
0 = SMBus interrupts will not generate an SMI#.
1 = Any source of an SMB interrupt will instead be routed to generate an SMI#. This bit will only
take effect if the INTREN bit is set in I/O space.This bit needs to be set for SMBALERT# to be
enabled.
SMBus Host Enable (HST_EN)—R/W.
0
0 = Disable the SMBus Host Controller.
1 = Enable. The SMB Host Controller interface is enabled to execute commands. The INTREN bit
needs to be enabled for the SMB Host Controller to interrupt or SMI#. Note that the SMB Host
Controller will not respond to any new requests until all interrupt requests have been serviced.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
12-5
SMBus Controller Registers (D31:F3)
12.2
SMBus I/O Registers
Table 12-2. SMB I/O Registers
12-6
Offset
Mnemonic
00h
HST_STS
02h
Register Name/Function
Default
Access
Host Status
00h
R/W
HST_CNT
Host Control
00h
R/W
03h
HST_CMD
Host Command
00h
R/W
04h
XMIT_SLVA
Transmit Slave Address
00h
R/W
05h
HST_D0
Host Data 0
00h
R/W
06h
HST_D1
Host Data 1
00h
R/W
07h
BLOCK_DB
Block Data Byte
00h
R/W
08h
—
Reserved
00h
RO
09h
RCV_SLVA
Receive Slave Address
44h
R/W
0Ah
SLV_DATA
Slave Data
0000h
R/W
0Bh–0Dh
—
00h
RO
0Eh
SMLINK_PIN_CTL
SMLINK Pin Control
See
Register
Description
R/W
0Fh
SMBUS_PIN_CTL
SMbus Pin Control
See
Register
Description
R/W
Reserved
82801BA ICH2 and 82801BAM ICH2-M Datasheet
SMBus Controller Registers (D31:F3)
12.2.1
HST_STS—Host Status Register
Register Offset:
Default Value:
00h
00h
Attribute:
Size:
R/WC
8-bits
All status bits are set by hardware and cleared by the software writing a one to the particular bit
position. Writing a zero to any bit position has no effect.
Bit
7
Description
Byte Done Status (BYTE_DONE_STA)—R/WC.
1 = The ICH2 has received a byte (for Block Read commands) or if it has completed transmission
of a byte (for Block Write commands). This bit will be set even on the last byte of the transfer. It
will not be set when transmission is due to the Alert On LAN* heartbeat.
0 = Cleared by writing a 1 to the bit position.
In Use Status (INUSE_STA)—R/WC (special). This bit is used as semaphore among various
independent software threads that may need to use the ICH2’s SMBus logic and has no other effect
on Hardware.
6
0 = After a full PCI reset, a read to this bit returns a 0.
1 = After the first read, subsequent reads will return a 1. A write of a 1 to this bit will reset the next
read value to 0. Writing a 0 to this bit has no effect. Software can poll this bit until it reads a 0,
and will then own the usage of the host controller.
SMBus Alert Status (SMBALERT_STA)—R/WC.
5
0 = Interrupt or SMI# was not generated by SMBALERT#.
1 = The source of the interrupt or SMI# was the SMBALERT# signal. This bit is only cleared by
software writing a 1 to the bit position or by RSMRST# going low.
If the signal is programmed as a GPIO, then this bit will never be set.
4
Interrupt/SMI# was Failed Bus Transaction (FAILED)—R/WC.
1 = The source of the interrupt or SMI# was a failed bus transaction. This bit is set in response to
the KILL bit being set to terminate the host transaction.
0 = Cleared by writing a 1 to the bit position.
3
Bus Error (BUS_ERR)—R/WC.
1 = The source of the interrupt of SMI# was a transaction collision.
0 = Cleared by writing a 1 to the bit position.
Device Error (DEV_ERR)—R/WC.
1 = The source of the interrupt or SMI# was due to one of the following:
• Illegal Command Field,
2
• Unclaimed Cycle (host initiated),
• Host Device Time-out Error.]
0 = Software resets this bit by writing a 1 to this location. The ICH2 will then deassert the interrupt
or SMI#.
1
Interrupt/SMI# was Successful Completion (INTR)—R/WC (special). This bit can only be set by
termination of a command. INTR is not dependent on the INTREN bit of the Host Controller Register
(offset 02h); it is only dependent on the termination of the command. If the INTREN bit is not set, the
INTR bit will be set, although the interrupt will not be generated. Software can poll the INTR bit in
this non-interrupt case.
1 = The source of the interrupt or SMI# was the successful completion of its last command.
0 = Software resets this bit by writing 1 to this location. The ICH2 then deasserts the interrupt or
SMI#.
0
Host Busy (HOST_BUSY)—RO.
1 = Indicates that the ICH2 is running a command from the host interface. No SMB registers should
be accessed while this bit is set, except the Block Data Byte Register. The Block Data Byte
register can be accessed when this bit is set only when the SMB_CMD bits in the Host Control
register are programmed for Block command or I2C Read command. This is necessary in order
to check the BYTE_DONE_STS bit.
0 = Cleared by the ICH2 when the current transaction is completed.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
12-7
SMBus Controller Registers (D31:F3)
12.2.2
HST_CNT—Host Control Register
Register Offset:
Default Value:
02h
00h
Bit
Attribute:
Size:
R/W
8-bits
Description
7
Reserved.
6
START—WO.
1 = Writing a 1 to this bit initiates the command described in the SMB_CMD field. All registers
should be setup prior to writing a 1 to this bit position.
0 = This bit will always return 0 on reads. The HOST_BUSY bit in the Host Status register (offset
00h) can be used to identify when the ICH2 has finished the command.
5
LAST BYTE—WO. This bit is used for Block Read commands.
1 = Software sets this bit to indicate that the next byte will be the last byte to be received for the
block. This causes the ICH2 to send a NACK (instead of an ACK) after receiving the last byte.
SMBus Command (SMB_CMD)—R/W. The bit encoding below indicates which command the ICH2
is to perform. If enabled, the ICH2 generates an interrupt or SMI# when the command has
completed. If the value is for a non-supported or reserved command, the ICH2 sets the device error
(DEV_ERR) status bit and generates an interrupt when the START bit is set. The ICH2 performs no
command and does not operate until DEV_ERR is cleared.
000 = Quick: The slave address and read/write value (bit 0) are stored in the transmit slave address
register.
001 = Byte: This command uses the transmit slave address and command registers. Bit 0 of the
slave address register determines if this is a read or write command.
010 = Byte Data: This command uses the transmit slave address, command, and DATA0 registers.
Bit 0 of the slave address register determines if this is a read or write command. If it is a read,
the DATA0 register will contain the read data.
4:2
011 = Word Data: This command uses the transmit slave address, command, DATA0 and DATA1
registers. Bit 0 of the slave address register determines if this is a read or write command. If it
is a read, after the command completes, the DATA0 and DATA1 registers will contain the read
data.
100 = Process Call: This command uses the transmit slave address, command, DATA0 and DATA1
registers. Bit 0 of the slave address register determines if this is a read or write command.
After the command completes, the DATA0 and DATA1 registers will contain the read data.
101 = Block: This command uses the transmit slave address, command, DATA0 registers, and the
Block Data Byte register. For block write, the count is stored in the DATA0 register and
indicates how many bytes of data will be transferred. For block reads, the count is received
and stored in the DATA0 register. Bit 0 of the slave address register selects if this is a read or
write command. For writes, data is retrieved from the first n (where n is equal to the specified
count) addresses of the SRAM array. For reads, the data is stored in the Block Data Byte
register.
110 = I2C Read: This command uses the transmit slave address, command, DATA0, DATA1
registers, and the Block Data Byte register. The read data is stored in the Block Data Byte
register. The ICH2 will continue reading data until the NAK is received.
111 = Reserved
1
KILL—R/W.
1 = When set, kills the current host transaction taking place, sets the FAILED status bit, and
asserts the interrupt (or SMI#). This bit, once set, must be cleared by software to allow the
SMBus Host Controller to function normally.
0 = Normal SMBus Host Controller functionality.
0
INTREN—R/W.
1 = Enable the generation of an interrupt or SMI# upon the completion of the command.
0 = Disable.
12-8
82801BA ICH2 and 82801BAM ICH2-M Datasheet
SMBus Controller Registers (D31:F3)
12.2.3
HST_CMD—Host Command Register
Register Offset:
Default Value:
03h
00h
Bit
7:0
12.2.4
Attribute:
Size:
R/W
8 bits
Description
Host Command—R/W. This eight bit field is transmitted by the host controller in the command field
of the SMBus protocol during the execution of any command.
XMIT_SLVA—Transmit Slave Address Register
Register Offset:
Default Value:
04h
00h
Attribute:
Size:
R/W
8 bits
This register is transmitted by the host controller in the slave address field of the SMBus protocol.
Bit
7:1
Description
ADDRESS—R/W. 7-bit address of the targeted slave.
Read/Write Select—R/W. Direction of the host transfer.
0
12.2.5
0 = Write
1 = Read
HST_D0—Data 0 Register
Register Offset:
Default Value:
12.2.6
05h
00h
Attribute:
Size:
R/W
8 bits
Bit
Description
7:0
DATA0/COUNT—R/W. This field contains the eight bit data sent in the DATA0 field of the SMBus
protocol. For block write commands, this register reflects the number of bytes to transfer. This register
should be programmed to a value between 1 and 32 for block counts. A count of 0 or a count above 32
will result in unpredictable behavior. The host controller does not check or log illegal block counts.
HST_D1—Data 1 Register
Register Offset:
Default Value:
06h
00h
Bit
7:0
Attribute:
Size:
R/W
8 bits
Description
DATA1—R/W. This eight bit register is transmitted in the DATA1 field of the SMBus protocol during
the execution of any command.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
12-9
SMBus Controller Registers (D31:F3)
12.2.7
BLOCK_DB—Block Data Byte Register
Register Offset:
Default Value:
07h
00h
Attribute:
Size:
R/W
8 bits
Bit
Description
7:0
Block Data Byte—R/W. For Block Writes, software writes the first byte to this register as part of the
setup for this command. After the ICH2 has sent the Address, Command, and Byte Count fields, it will
send the byte in the Block Data Byte register. After the byte has been sent, the ICH2 sets the
BYTE_DONE_STS bit in the Host Status register. If there are more bytes to send, the software then
writes in the next byte to the Block Data Byte register and software also clears the BYTE_DONE_STS
bit. The ICH2 then sends the next byte. During the time from when a byte has been transmitted to
when the next byte has been loaded, the ICH2 inserts wait-states on the SMBus/I2C.
A similar process will be used for Block Reads. After receiving the byte count (which goes in the DATA
0 register), the first “data byte” goes in the Block Data Byte register and the ICH2 generates an SMI#
or interrupt (depending on configuration). The interrupt or SMI# handler then reads the byte and
clears the BYTE_DONE_STS bit. This frees room for the next byte. During the time from when a byte
is read to when the BYTE_DONE_STS bit is cleared, the ICH2 inserts wait-states on the SMBus/I2C.
12.2.8
RCV_SLVA—Receive Slave Address Register
Register Offset:
Default Value:
Lockable:
09h
44h
No
Bit
12.2.9
Attribute:
Size:
Power Well:
R/W
8 bits
Resume
Description
7
Reserved
6:0
SLAVE_ADDR—R/W. This field is the slave address that the ICH2 decodes for read and write cycles.
The default is not 0 so the SMBus Slave Interface can respond even before the processor comes up
(or if the processor is dead). This register is cleared by RSMRST#, but not by PCIRST#.
SLV_DATA—Receive Slave Data Register
Register Offset:
Default Value:
Lockable:
0Ah
00h
No
Attribute:
Size:
Power Well:
RO
16 bits
Resume
This register contains the 16-bit data value written by the external SMBus master. The CPU can
then read the value from this register. This register is reset by RSMRST#, but not PCIRST#.
Bit
12-10
Description
15:8
DATA_MSG1: Data Message Byte 1—RO. See Section 5.17.5 for a discussion of this field.
7:0
DATA_MSG0: Data Message Byte 0—RO. See Section 5.17.5 for a discussion of this field.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
SMBus Controller Registers (D31:F3)
12.2.10
SMLINK_PIN_CTL—SMLINK Pin Control Register
Register Offset:
Default Value:
Note:
0Eh
See Below
Attribute:
Size:
Read/Write
8 bits
This register is in the resume well and is reset by RSMRST#.
Bit
7:3
Description
Reserved
SMLINK Clock Pin Control (SMLINK_CLK_CTL)—R/W.
2
1 = No functional impact on the SMLINK[0] pin. (default)
0 = ICH2 will drive the SMLINK[0] pin low, independent of the what the other SMLINK logic would
otherwise indicate for the SMLINK[0] pin.
1
SMLINK[1] Pin Current Status (SMLINK[1]_CUR_STA)—RO. This read-only bit has a default
value that is dependent on an external signal level. This pin returns the value on the SMLINK[1]
pin. This allows software to read the current state of the pin.
1 = SMLINK[1] pin is high
0 = SMLINK[1] pin is low
0
SMLINK[0] Pin Current Status (SMLINK[0]_CUR_STA)—RO. This read-only bit has a default
value that is dependent on an external signal level. This pin returns the value on the SMLINK[0]
pin. This allows software to read the current state of the pin.
1 = SMLINK[0] pin is high
0 = SMLINK[0] pin is low
12.2.11
SMBUS_PIN_CTL—SMBus Pin Control Register
Register Offset:
Default Value:
Note:
0Fh
See Below
Attribute:
Size:
Read/Write
8 bits
This register is in the resume well and is reset by RSMRST#.
Bit
7:3
Description
Reserved
SMBCLK Pin Control (SMBCLK_CTL)—R/W.
2
1 = No functional impact on the SMBCLK pin. (default)
0 = ICH2 drives the SMBCLK pin low, independent of the what the other SMB logic would
otherwise indicate for the SMBCLK pin.
1
SMBDATA Pin Current Status (SMBDATA_CUR_STA)—RO. This read-only bit has a
default value that is dependent on an external signal level. This pin returns the value on
the SMBDATA pin. This allows software to read the current state of the pin.
1 = SMBDATA pin is high
0 = SMBDATA pin is low
0
SMBCLK Pin Current Status (SMBCLK_CUR_STA)—RO. This read-only bit has a
default value that is dependent on an external signal level. This pin returns the value on
the SMBCLK pin. This allows software to read the current state of the pin.
1 = SMBCLK pin is high
0 = SMBCLK pin is low
82801BA ICH2 and 82801BAM ICH2-M Datasheet
12-11
SMBus Controller Registers (D31:F3)
This page is intentionally left blank.
12-12
82801BA ICH2 and 82801BAM ICH2-M Datasheet
AC’97 Audio Controller Registers (D31:F5)
AC’97 Audio Controller Registers
(D31:F5)
13.1
13
AC’97 Audio PCI Configuration Space (D31:F5)
Note:
Registers that are not shown should be treated as Reserved (See Section 6.2 for details).
Table 13-1. PCI Configuration Map (Audio—D31:F5)
Offset
Mnemonic
00h–01h
VID
Register
Default
Access
Vendor Identification
8086h
RO
02h–03h
DID
Device Identification
2445h
RO
04h–05h
PCICMD
PCI Command
0000
R/W
06h–07h
PCISTS
PCI Device Status
0280h
R/WC
08h
RID
Revision Identification
See Note
RO
09h
PI
Programming Interface
00
RO
0Ah
SCC
Sub Class Code
01h
RO
0Bh
BCC
Base Class Code
04h
RO
0Eh
HEDT
Header Type
00
RO
Native Audio Mixer Base Address
00000001h
R/W
Native Audio Bus Mastering Base Address
00000001h
R/W
00h
RO
Subsystem Vendor ID
0000h
Write-Once
Subsystem ID
0000h
Write-Once
—
—
10h–13h
NAMBAR
14h–17h
NABMBAR
18h–2Bh
—
2Ch–2Dh
SVID
2Eh–2Fh
SID
30h–3Bh
—
3Ch
INTR_LN
Interrupt Line
00h
R/W
3Dh
INTR_PN
Interrupt Pin
02h
RO
3Eh–FFh
—
—
—
Reserved
Reserved
Reserved
NOTE: Refer to the Specification Update for the value of the Revision ID Register
13.1.1
VID—Vendor Identification Register (Audio—D31:F5)
Offset:
Default Value:
Lockable:
01h-00h
8086h
No
Attribute:
Size:
Power Well:
Bit
Description
15:0
Vendor ID Value. This is a 16 bit value assigned to Intel
82801BA ICH2 and 82801BAM ICH2-M Datasheet
RO
16 Bits
Core
13-1
AC’97 Audio Controller Registers (D31:F5)
13.1.2
DID—Device Identification Register (Audio—D31:F5)
Offset:
Default Value:
Lockable:
03h–02h
2445h
No
Bit
15:0
13.1.3
Attribute:
Size:
Power Well:
RO
16 Bits
Core
Description
Device ID Value.
PCICMD—PCI Command Register (Audio—D31:F5)
Address Offset:
Default Value:
Lockable:
05h–04h
0000h
No
Attribute:
Size:
Power Well:
R/W
16 bits
Core
PCICMD is a 16-bit control register. Refer to the PCI 2.1 specification for complete details on each
bit.
Bit
15:10
Description
Reserved. Read as 0s.
9
Fast Back to Back Enable (FBE). Not implemented. Hardwired to 0.
8
SERR# Enable (SEN). Not implemented. Hardwired to 0.
7
Wait Cycle Control (WCC). Not implemented. Hardwired to 0.
6
Parity Error Response (PER). Not implemented. Hardwired to 0.
5
VGA Palette Snoop (VPS). Not implemented. Hardwired to 0.
4
Memory Write and Invalidate Enable (MWI). Not implemented. Hardwired to 0.
3
Special Cycle Enable (SCE). Not implemented. Hardwired to 0.
Bus Master Enable (BME)—R/W. Controls standard PCI bus mastering capabilities.
2
0 = Disable.
1 = Enable
1
Memory Space (MS). Hardwired to 0, AC '97 does not respond to memory accesses
IOS (I/O Space)—R/W. This bit controls access to the AC’97 Audio Controller I/O space registers.
0
13-2
0 = Disable (Default).
1 = Enable access to I/O space. The Native PCI Mode Base Address register should be
programmed prior to setting this bit.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
AC’97 Audio Controller Registers (D31:F5)
13.1.4
PCISTS—PCI Device Status Register (Audio—D31:F5)
Offset:
Default Value
Lockable:
07h–06h
0280h
No
Attribute:
Size:
Power Well:
R/WC
16 bits
Core
PCISTA is a 16-bit status register. Refer to the PCI 2.1 specification for complete details on each
bit.
Bit
Description
15
Detected Parity Error (DPE). Not implemented. Hardwired to 0.
14
SERR# Status (SERRS). Not implemented. Hardwired to 0.
13
Master-Abort Status (MAS)—R/WC.
1 = Bus Master AC '97 2.1 interface function, as a master, generates a master abort.
0 = Software clears this bit by writing a 1 to the bit position.
12
Reserved. Will always read as 0.
11
Signaled Target-Abort Status (STA). Not implemented. Hardwired to 0.
10:9
DEVSEL# Timing Status (DEVT)—RO. This 2-bit field reflects the ICH2's DEVSEL# timing when
performing a positive decode.
01b = Medium timing.
8
Data Parity Detected (DPD). Not implemented. Hardwired to 0.
7
Fast Back to back Capable (FBC). Hardwired to 1. This bit indicates that the ICH2 as a target is
capable of fast back-to-back transactions.
6
UDF Supported. Not implemented. Hardwired to 0.
5
4:0
13.1.5
66 MHz Capable. Hardwired to 0.
Reserved. Read as 0's.
RID—Revision Identification Register (Audio—D31:F5)
Offset:
Default Value:
Lockable:
08h
See bit description
No
Bit
7:0
13.1.6
Attribute:
Size:
Power Well:
RO
8 Bits
Core
Description
Revision ID Value—RO. Refer to the ICH2 / ICH2-M Specification Update for the value of the
Revision ID Register
PI—Programming Interface Register (Audio—D31:F5)
Offset:
Default Value:
Lockable:
09h
00h
No
Bit
7:0
Attribute:
Size:
Power Well:
RO
8 bits
Core
Description
Programming Interface—RO.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
13-3
AC’97 Audio Controller Registers (D31:F5)
13.1.7
SCC—Sub Class Code Register (Audio—D31:F5)
Address Offset:
Default Value:
Lockable:
0Ah
01h
No
Bit
7:0
13.1.8
Sub Class Code—RO.
01h = Audio Device
BCC—Base Class Code Register (Audio—D31:F5)
0Bh
04h
No
Bit
7:0
Attribute:
Size:
Power Well:
RO
8 bits
Core
Description
Base Class Code—RO.
04h = Multimedia device
HEDT—Header Type Register (Audio—D31:F5)
Address Offset:
Default Value:
Lockable:
0Eh
00h
No
Bit
7:0
13-4
RO
8 bits
Core
Description
Address Offset:
Default Value:
Lockable:
13.1.9
Attribute:
Size:
Power Well:
Attribute:
Size:
Power Well:
RO
8 bits
Core
Description
Header Type Value. Hardwired to 00h.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
AC’97 Audio Controller Registers (D31:F5)
13.1.10
NAMBAR—Native Audio Mixer Base Address Register
(Audio—D31:F5)
Address Offset:
Default Value:
Lockable:
10h–13h
00000001h
No
Attribute:
Size:
Power Well:
R/W
32 bits
Core
The Native PCI Mode Audio function uses PCI Base Address register #1 to request a contiguous
block of I/O space that is to be used for the Native Audio Mixer software interface. The mixer
requires 256 bytes of I/O space. Native Audio Mixer and Modem codec I/O registers are located
from 00h to 7Fh and reside in the codec. Access to these registers will be decoded by the AC '97
controller and forwarded over the AC-link to the codec. The codec will then respond with the
register value.
In the case of the split codec implementation, accesses to the different codecs are differentiated by
the controller by using address offsets 00h–7Fh for the primary codec and address offsets 80h–FEh
for the secondary codec.
For a description of these I/O registers, refer to the AC‘97 specification.
Bit
31:16
15:8
Description
Hardwired to 0s
Base Address—R/W. These bits are used in the I/O space decode of the Native Audio Mixer
interface registers. The number of upper bits that a device actually implements depends on how
much of the address space the device will respond to. For the AC ‘97 mixer, the upper 16 bits are
hardwired to 0, while bits 15:8 are programmable. This configuration yields a maximum I/O block
size of 256 bytes for this base address.
Note: This address must align to a 256-byte boundary.
7:1
0
13.1.11
Reserved. Read as 0s.
Resource Type Indicator (RTE)—RO. Hardwired to 1 indicating a request for I/O space.
NABMBAR—Native Audio Bus Mastering Base Address
Register (Audio—D31:F5)
Address Offset:
Default Value:
Lockable:
14h–17h
00000001h
No
Attribute:
Size:
Power Well:
R/W
32 bits
Core
The Native PCI Mode Audio function uses PCI Base Address register #1 to request a contiguous
block of I/O space that is to be used for the Native Mode Audio software interface.
Bit
31:16
15:6
Description
Hardwired to 0s
Base Address—R/W. These bits are used in the I/O space decode of the Native Audio Bus
Mastering interface registers. The number of upper bits that a device actually implements depends
on how much of the address space the device will respond to. For AC '97 bus mastering, the upper
16 bits are hardwired to 0, while bits 15:6 are programmable. This configuration yields a maximum
I/O block size of 64 bytes for this base address.
Note: This address must align to a 64-byte boundary.
5:1
0
Reserved. Read as 0s.
Resource Type Indicator (RTE)—RO. This bit is set to 1 indicating a request for I/O space.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
13-5
AC’97 Audio Controller Registers (D31:F5)
13.1.12
SVID—Subsystem Vendor ID Register (Audio—D31:F5)
Address Offset:
Default Value:
Lockable:
2Dh–2Ch
0000h
No
Attribute:
Size:
Power Well:
Read/Write-Once
16 bits
Core
The SVID register, in combination with the Subsystem ID register, enable the operating
environment to distinguish one audio subsystem from the other(s). This register is implemented as
write-once register. Once a value is written to it, the value can be read back. Any subsequent writes
will have no effect.
Bit
15:0
13.1.13
Description
Subsystem Vendor ID Value—R/Write-Once.
SID—Subsystem ID Register (Audio—D31:F5)
Address Offset:
Default Value:
Lockable:
2Fh–2Eh
0000h
No
Attribute:
Size:
Power Well:
Read/Write-Once
16 bits
Core
The SID register, in combination with the Subsystem Vendor ID register make it possible for the
operating environment to distinguish one audio subsystem from the other(s). This register is
implemented as write-once register. Once a value is written to it, the value can be read back. Any
subsequent writes will have no effect.
Bit
15:0
13.1.14
Description
Subsystem ID Value—R/Write-Once.
INTR_LN—Interrupt Line Register (Audio—D31:F5)
Address Offset:
Default Value:
Lockable:
3Ch
00h
No
Attribute:
Size:
Power Well:
R/W
8 bits
Core
This register indicates which PCI interrupt line is used for the AC’97 module interrupt.
Bit
7:0
13-6
Description
Interrupt Line—R/W. This data is not used by the ICH2. It is used to communicate to software the
interrupt line that the interrupt pin is connected to.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
AC’97 Audio Controller Registers (D31:F5)
13.1.15
INTR_PN—Interrupt Pin Register (Audio—D31:F5)
Address Offset:
Default Value:
Lockable:
3Dh
02h
No
Attribute:
Size:
Power Well:
RO
8 bits
Core
This register indicates which PCI interrupt pin is used for the AC '97 module interrupt. The AC '97
interrupt is internally OR’ed to the interrupt controller with the PIRQB# signal.
Bit
13.2
Description
7:3
Reserved.
2:0
AC '97 Interrupt Routing—RO. Hardwired to 010b to select PIRQB#.
AC’97 Audio I/O Space (D31:F5)
The AC’97 I/O space includes Native Audio Bus Master Registers and Native Mixer Registers.
Table 13-2 shows the register addresses for the audio mixer registers.
Table 13-2. ICH2 Audio Mixer Register Configuration
Primary
offset
Secondary
Offset
00h
80h
Reset
02h
82h
Master Volume Mute
04h
84h
Headphone Volume Mute
06h
86h
Master Volume Mono Mute
08h
88h
Master Tone (R & L)
NAMBAR Exposed Registers (D31:F5)
0Ah
8Ah
PC_BEEP Volume Mute
0Ch
8Ch
Phone Volume Mute
0Eh
8Eh
Mic Volume Mute
10h
90h
Line In Volume Mute
12h
92h
CD Volume Mute
14h
94h
Video Volume Mute
16h
96h
Aux Volume Mute
18h
98h
PCM Out Volume Mute
1Ah
9Ah
Record Select
1Ch
9Ch
Record Gain Mute
1Eh
9Eh
Record Gain Mic Mute
20h
A0h
General Purpose
22h
A2h
3D Control
24h
A4h
AC’97 RESERVED
26h
A6h
Powerdown Ctrl/Stat
28h
A8h
Extended Audio
2Ah
AAh
Extended Audio Ctrl/Stat
82801BA ICH2 and 82801BAM ICH2-M Datasheet
13-7
AC’97 Audio Controller Registers (D31:F5)
Table 13-2. ICH2 Audio Mixer Register Configuration (Continued)
Primary
offset
Secondary
Offset
2Ch
ACh
2Eh
AEh
PCM Surround DAC Rate
30h
B0h
PCM LFE DAC Rate
32h
B2h
PCM LR ADC Rate
34h
B4h
MIC ADC Rate
NAMBAR Exposed Registers (D31:F5)
PCM Front DAC Rate
36h
B6h
6Ch Vol: C, LFE Mute
38h
B8h
6Ch Vol: L, R Surround Mute
3Ah:56h
BAh–F6h
Intel RESERVED
58h1
Vendor Reserved
7Ah1
Vendor Reserved
7Ch1
Vendor ID1
7Eh1
Vendor ID2
NOTE:
1. Registers in bold are multiplexed between audio and modem functions
2. Software should not try to access reserved registers
The Bus Master registers are located from offset + 00h to offset + 51h and reside in the AC ‘97
controller. Accesses to these registers do NOT cause the cycle to be forwarded over the AC-link to
the codec.
In the case of the split codec implementation accesses to the different codecs are differentiated by
the controller by using address offsets 00h–7Fh for the primary codec and address offsets 80h–FEh
for the secondary codec.
The Global Control (GLOB_CNT) and Global Status (GLOB_STA) registers are aliased to the
same global registers in the audio and modem I/O space. Therefore a read/write to these registers in
either audio or modem I/O space affects the same physical register.
Bus Mastering registers exist in I/O space and reside in the AC ‘97 controller. The three channels
(PCM in, PCM out, and Mic in) each have their own set of Bus Mastering registers. The following
register descriptions apply to all three channels. The register definition section titles use a generic
“x_” in front of the register to indicate that the register applies to all three channels. The naming
prefix convention used in Table 13-3 and in the register description I/O address is as follows:
• PI = PCM in channel
• PO = PCM out channel
• MC = Mic in channel.
13-8
82801BA ICH2 and 82801BAM ICH2-M Datasheet
AC’97 Audio Controller Registers (D31:F5)
Table 13-3. Native Audio Bus Master Control Registers
13.2.1
Offset
Mnemonic
Name
Default
Access
00h
PI_BDBAR
04h
PI_CIV
PCM In Current Index Value
00000000h
R/W
00h
RO
05h
PI_LVI
PCM In Last Valid Index
00h
R/W
06h
PI_SR
PCM In Status Register
0001h
R/W
PCM In Position In Current Buffer
PCM In Buffer Descriptor list Base Address Register
08h
PI_PICB
0000h
RO
0Ah
PI_PIV
PCM In Prefetched Index Value
00h
RO
0Bh
PI_CR
PCM In Control Register
00h
R/W
10h
PO_BDBAR
00000000h
R/W
14h
PO_CIV
PCM Out Current Index Value
00h
RO
15h
PO_LVI
PCM Out Last Valid Index
00h
R/W
16h
PO_SR
PCM Out Status Register
0001h
R/W
18h
PO_PICB
PCM Out Position In Current Buffer
0000h
RO
1Ah
PO_PIV
PCM Out Prefetched Index Value
00h
RO
1Bh
PO_CR
PCM Out Control Register
00h
R/W
20h
MC_BDBAR
00000000h
R/W
24h
PM_CIV
Mic. In Current Index Value
00h
RO
25h
MC_LVI
Mic. In Last Valid Index
00h
R/W
26h
MC_SR
Mic. In Status Register
0001h
R/W
28h
MC_PICB
Mic In Position In Current Buffer
0000h
RO
2Ah
MC_PIV
00h
RO
PCM Out Buffer Descriptor list Base Address Register
Mic. In Buffer Descriptor list Base Address Register
Mic. In Prefetched Index Value
2Bh
MC_CR
00h
R/W
2Ch
GLOB_CNT
Global Control
Mic. In Control Register
00000000h
R/W
30h
GLOB_STA
Global Status
00000000h
RO
34h
ACC_SEMA
Codec Write Semaphore Register
00h
R/W
x_BDBAR—Buffer Descriptor Base Address Register
I/O Address:
Default Value:
Lockable:
NABMBAR + 00h (PIBDBAR), Attribute:
NABMBAR + 10h (POBDBAR),
NABMBAR + 20h (MCBDBAR)
00000000h
Size:
No
Power Well:
R/W (DWord access only)
32 bits
Core
This register can be accessed only as a DWord (32 bits).
Bit
Description
31:3
Buffer Descriptor Base Address[31:3]—R/W. These bits represent address bits 31:3. The data
should be aligned on 8 byte boundaries. Each buffer descriptor is 8 bytes long and the list can
contain a maximum of 32 entries.
2:0
Hardwired to 0.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
13-9
AC’97 Audio Controller Registers (D31:F5)
13.2.2
x_CIV—Current Index Value Register
I/O Address:
Default Value:
Lockable:
NABMBAR + 04h (PICIV),
NABMBAR + 14h (POCIV),
NABMBAR + 24h (MCCIV)
00h
No
Attribute:
RO
Size:
Power Well:
8 bits
Core
Software can read the registers at offsets 04h, 05h and 06h simultaneously by performing a single
32 bit read from address offset 04h. Software can also read this register individually by doing a
single 8 bit read to offset 04h.
Bit
13.2.3
Description
7:5
Hardwired to 0
4:0
Current Index Value[4:0]—RO. These bits represent which buffer descriptor within the list of 32
descriptors is currently being processed. As each descriptor is processed, this value is
incremented. The value rolls over after it reaches 31.
x_LVI—Last Valid Index Register
I/O Address:
Default Value:
Lockable:
NABMBAR + 05h (PILVI),
NABMBAR + 15h (POLVI),
NABMBAR + 25h (MCLVI)
00h
No
Attribute:
R/W
Size:
Power Well:
8 bits
Core
Software can read the registers at offsets 04h, 05h and 06h simultaneously by performing a single
32 bit read from address offset 04h. Software can also read this register individually by doing a
single 8 bit read to offset 05h.
Bit
13-10
Description
7:5
Hardwired to 0.
4:0
Last Valid Index[4:0]—R/W. This value represents the last valid descriptor in the list. This value is
updated by the software each time it prepares a new buffer and adds it to the list.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
AC’97 Audio Controller Registers (D31:F5)
13.2.4
x_SR—Status Register
I/O Address:
NABMBAR + 06h (PISR),
NABMBAR + 16h (POSR),
NABMBAR + 26h (MCSR)
0001h
No
Default Value:
Lockable:
Attribute:
R/WC, RO (Word Access only)
Size:
Power Well:
16 bits
Core
This register can be accessed only as a Word (16 bits).
Bit
15:5
Description
Reserved.
FIFO error (FIFOE)—R/WC.
1 = FIFO error occurs.
0 = Cleared by writing a 1 to this bit position.
4
PISR Register: FIFO error indicates a FIFO overrun. The FIFO pointers do not increment, the
incoming data is not written into the FIFO, thus is lost.
POSR Register: FIFO error indicates a FIFO underrun. The sample transmitted in this case should
be the last valid sample.
The ICH2 will set the FIFOE bit if the under-run or overrun occurs when there are more valid buffers
to process.
3
Buffer Completion Interrupt Status (BCIS)—R/WC.
1 = Set by the hardware after the last sample of a buffer has been processed, AND if the Interrupt
on Completion (IOC) bit is set in the command byte of the buffer descriptor. It remains active
until cleared by software.
0 = Cleared by writing a 1 to this bit position.
2
Last Valid Buffer Completion Interrupt (LVBCI)—R/WC.
1 = Last valid buffer has been processed. It remains active until cleared by software. This bit
indicates the occurrence of the event signified by the last valid buffer being processed. Thus,
this is an event status bit that can be cleared by software once this event has been
recognized. This event will cause an interrupt if the enable bit in the Control Register is set.
The interrupt is cleared when the software clears this bit.
In the case of Transmits (PCM out, Modem out) this bit is set, after the last valid buffer has
been fetched (not after transmitting it). While in the case of Receives, this bit is set after the
data for the last buffer has been written to memory.
0 = Cleared by writing a 1 to this bit position.
1
Current Equals Last Valid (CELV)—RO.
1 = Current Index is equal to the value in the Last Valid Index Register, and the buffer pointed to by
the CIV has been processed (i.e., after the last valid buffer has been processed). This bit is
very similar to bit 2, except this bit reflects the state rather than the event. This bit reflects the
state of the controller, and remains set until the controller exits this state.
0 = Cleared by hardware when controller exists state (i.e., until a new value is written to the LVI
register.)
0
DMA Controller Halted (DCH)—RO.
1 = Halted. This could happen because of the Start/Stop bit being cleared, or it could happen once
the controller has processed the last valid buffer (in which case it will set bit 1 and halt).
Software can read the above 3 registers simultaneously by scheduling a single 32 bit read from
address offset 04h. Software can also read this individual register by performing a 16 bit read from
06h.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
13-11
AC’97 Audio Controller Registers (D31:F5)
13.2.5
x_PICB—Position In Current Buffer Register
I/O Address:
Default Value:
Lockable:
NABMBAR + 08h (PIPICB),
NABMBAR + 18h (POPICB),
NABMBAR + 28h (MCPICB)
0000h
No
Attribute:
RO (Word access only)
Size:
Power Well:
16 bits
Core
This register can be accessed only as a Word (16 bits).
13.2.6
Bit
Description
15:0
Position In Current Buffer[15:0]—RO. These bits represent the number of DWords remaining to
be processed in the current buffer; the number of samples not yet read from memory (in the case of
reads from memory) or not yet written to memory (in the case of writes to memory), irrespective of
the number of samples that have been transmitted/received across AC-link.
x_PIV—Prefetched Index Value Register
I/O Address:
Default Value:
Lockable:
NABMBAR + 0Ah (PIPIV),
NABMBAR + 1Ah (POPIV),
NABMBAR + 2Ah (MCPIV)
00h
No
Bit
13-12
Attribute:
RO
Size:
Power Well:
8 bits
Core
Description
7:5
Hardwired to 0.
4:0
Prefetched Index Value[4:0]—RO. These bits represent which buffer descriptor in the list has
been prefetched. The bits in this register are also modulo 32 and roll over after they reach 31.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
AC’97 Audio Controller Registers (D31:F5)
13.2.7
x_CR—Control Register
I/O Address:
Default Value:
Lockable:
NABMBAR + 0Bh (PICR),
NABMBAR + 1Bh (POCR),
NABMBAR + 2Bh (MCCR)
00h
No
Bit
7:5
4
3
2
1
Attribute:
R/W
Size:
Power Well:
8 bits
Core
Description
Reserved.
Interrupt On Completion Enable (IOCE)—R/W. This bit controls whether or not an interrupt
occurs when a buffer completes with the IOC bit set in its descriptor.
0 = Disable. Interrupt will not occur.
1 = Enable.
FIFO Error Interrupt Enable (FEIE)—R/W. This bit controls whether the occurrence of a FIFO
error will cause an interrupt or not.
0 = Disable. Bit 4 in the Status Register will be set; however, the interrupt will not occur.
1 = Enable. Interrupt will occur.
Last Valid Buffer Interrupt Enable (LVBIE)—R/W. This bit controls whether the completion of the
last valid buffer will cause an interrupt or not.
0 = Disable. Bit 2 in the Status register will still be set; however, the interrupt will not occur.
1 = Enable.
Reset Registers (RR)—R/W (special).
1 = Contents of all Bus master related registers to be reset, except the interrupt enable bits (bit
4,3,2 of this register). Software needs to set this bit but need not clear it since the bit is self
clearing. This bit must be set only when the Run/Pause bit is cleared. Setting it when the Run
bit is set will cause undefined consequences.
0 = Removes reset condition.
Run/Pause Bus master (RPBM)—R/W.
0
0 = Pause bus master operation. This results in all state information being retained (i.e., master
mode operation can be stopped and then resumed).
1 = Run. Bus master operation starts.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
13-13
AC’97 Audio Controller Registers (D31:F5)
13.2.8
GLOB_CNT—Global Control Register
I/O Address:
Default Value:
Lockable:
NABMBAR + 2Ch
00000000h
No
Attribute:
Size:
Power Well:
R/W (DWord access only)
32 bits
Core
This register can be accessed only as a DWord (32 bits).
Bit
31:22
Description
Reserved.
PCM 4/6 Enable—R/W. Configures PCM Output for 2, 4 or 6 channel mode.
21:20
19:6
00 = 2-channel mode (default)
01 = 4-channel mode
10 = 6-channel mode
11 = Reserved
Reserved.
Secondary Resume Interrupt Enable—R/W.
5
0 = Disable.
1 = Enable an interrupt to occur when the secondary codec causes a resume event on the
AC-link.
Primary Resume Interrupt Enable—R/W.
4
0 = Disable.
1 = Enable an interrupt to occur when the primary codec causes a resume event on the AC-link.
ACLINK Shut Off—R/W.
3
0 = Normal operation.
1 = Drive all AC’97 outputs low and turn off all AC’97 input buffer enables
AC’97 Warm Reset—R/W (special).
2
0 = Normal operation.
1 = Writing a 1 to this bit causes a warm reset to occur on the AC-link. The warm reset will awaken
a suspended codec without clearing its internal registers. If software attempts to perform a
warm reset while bit_clk is running, the write will be ignored and the bit will not change. This bit
is self-clearing (it remains set until the reset completes and bit_clk is seen on the ACLink, after
which it clears itself).
AC ‘97 Cold Reset#—R/W.
1
0 = Writing a 0 to this bit causes a cold reset to occur throughout the AC ‘97 circuitry. All data in
the controller and the codec will be lost. Software needs to clear this bit no sooner than the
minimum number of ms have elapsed.
1 = This bit defaults to 0; thus, after reset, the driver needs to set this bit to a 1. The value of this
bit is retained after suspends; thus, if this bit is set to a 1 prior to suspending, a cold reset is not
generated automatically upon resuming.
Note: This bit is in the Resume well, not in the Core well.
0
13-14
GPI Interrupt Enable (GIE)—R/W. This bit controls whether the change in status of any GPI
causes an interrupt.
0 = Bit 0 of the Global Status Register is set, but no interrupt is generated.
1 = The change on value of a GPI causes an interrupt and sets bit 0 of the Global Status Register.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
AC’97 Audio Controller Registers (D31:F5)
13.2.9
GLOB_STA—Global Status Register
I/O Address:
Default Value:
Lockable:
NABMBAR + 30h
00300000h
No
Attribute:
RO, R/W, R/WC (DWord access only)
Size:
32 bits
Power Well: Core
This register can be accessed only as a DWord (32 bits).
Bit
31:22
Description
Reserved.
6 Channel Capability (6CH_CAP)—RO. Hardwired to 1.
21
0 = The AC ‘97 Controller does not support 6-channel PCM Audio output.
1 = The AC ‘97 Controller supports 6-channel PCM Audio output.
4 Channel Capability (4CH_CAP)—RO. Hardwired to 1.
20
19:18
0 = The AC ‘97 Controller does not support 4-channel PCM Audio output.
1 = The AC ‘97 Controller supports 4-channel PCM Audio output.
Reserved.
17
MD3—R/W. Power down semaphore for Modem. This bit exists in the suspend well and maintains
context across power states (except G3). The bit has no hardware function. It is used by software in
conjunction with the AD3 bit to coordinate the entry of the two codecs into D3 state.
16
AD3—R/W. Power down semaphore for Audio. This bit exists in the suspend well and maintains
context across power states (except G3). The bit has no hardware function. It is used by software in
conjunction with the MD3 bit to coordinate the entry of the two codecs into D3 state.
Read Completion Status (RCS)—R/WC. This bit indicates the status of codec read completions.
15
0 = A codec read completes normally.
1 = A codec read results in a time-out. The bit remains set until being cleared by software writing a
1 to the bit location.
14
Bit 3 of slot 12—RO. Display bit 3 of the most recent slot 12.
13
Bit 2 of slot 12—RO. Display bit 2 of the most recent slot 12.
12
Bit 1 of slot 12—RO. Display bit 1 of the most recent slot 12.
11
Secondary Resume Interrupt (SRI)—R/WC. This bit indicates that a resume event occurred on
AC_SDIN[1].
1 = Resume event occurred
0 = Cleared by writing a 1 to this bit position.
10
Primary Resume Interrupt (PRI)—R/WC. This bit indicates that a resume event occurred on
AC_SDIN[0].
1 = Resume event occurred
0 = Cleared by writing a 1 to this bit position.
9
Secondary Codec Ready (SCR)—RO. Reflects the state of the codec ready bit in AC_SDIN[1].
Bus masters ignore the condition of the codec ready bits, so software must check this bit before
starting the bus masters. Once the codec is “ready”, it must never go “not ready” spontaneously.
0 = Not Ready.
1 = Ready.
8
Primary Codec Ready (PCR)—RO. Reflects the state of the codec ready bit in AC_SDIN [0]. Bus
masters ignore the condition of the codec ready bits, so software must check this bit before starting
the bus masters. Once the codec is “ready”, it must never go “not ready” spontaneously.
0 = Not Ready.
1 = Ready.
7
Mic In Interrupt (MINT)—RO. This bit indicates that one of the Mic in channel interrupts occurred.
1 = Interrupt occurred.
0 = When the specific interrupt is cleared, this bit will be cleared.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
13-15
AC’97 Audio Controller Registers (D31:F5)
Bit
6
Description
PCM Out Interrupt (POINT)—RO. This bit indicates that one of the PCM out channel interrupts
occurred.
1 = Interrupt occurred.
0 = When the specific interrupt is cleared, this bit will be cleared.
5
PCM In Interrupt (PIINT)—RO. This bit indicates that one of the PCM in channel interrupts
occurred.
1 = Interrupt occurred.
0 = 0 = When the specific interrupt is cleared, this bit will be cleared.
4:3
2
Reserved
Modem Out Interrupt (MOINT)—RO. This bit indicates that one of the modem out channel
interrupts occurred.
1 = Interrupt occurred.
0 = When the specific interrupt is cleared, this bit will be cleared.
1
Modem In Interrupt (MIINT)—RO. This bit indicates that one of the modem in channel interrupts
occurred.
1 = Interrupt occurred.
0 = When the specific interrupt is cleared, this bit will be cleared.
0
GPI Status Change Interrupt (GSCI)—RWC. This bit reflects the state of bit 0 in slot 12, and is set
whenever bit 0 of slot 12 is set. This happens when the value of any of the GPIOs currently defined
as inputs changes.
1 = Input changed.
0 = Cleared by writing a 1 to this bit position.
13.2.10
CAS—Codec Access Semaphore Register
I/O Address:
Default Value:
Lockable:
Bit
7:1
NABMBAR + 34h
00h
No
Attribute:
Size:
Power Well:
R/W
8 bits
Core
Description
Reserved.
Codec Access Semaphore (CAS)—R/W (special). This bit is read by software to check whether a
codec access is currently in progress.
0
13-16
0 = No access in progress.
1 = The act of reading this register sets this bit to 1. The driver that read this bit can then perform
an I/O access. Once the access is completed, hardware automatically clears this bit.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
AC’97 Modem Controller Registers (D31:F6)
AC’97 Modem Controller Registers
(D31:F6)
14.1
14
AC’97 Modem PCI Configuration Space (D31:F6)
Note:
Registers that are not shown should be treated as Reserved (See Section 6.2 for details).
Table 14-1. PCI Configuration Map (Modem—D31:F6)
Offset
Mnemonic
00h–01h
VID
02h–03h
DID
04h–05h
PCICMD
06h–07h
PCISTA
08h
RID
Register
Default
Access
Vendor Identification
8086
RO
Device Identification
2446h
RO
PCI Command
0000
R/W
PCI Device Status
0280h
R/WC
See Note
RO
Revision Identification
09h
PI
Programming Interface
00
RO
0Ah
SCC
Sub Class Code
03h
RO
0Bh
BCC
Base Class Code
07h
RO
0Eh
HEDT
Header Type
00
RO
0Fh
—
10h–13h
MMBAR
14h–17h
MBAR
18h–1Bh
—
1Ch–2Bh
—
2Ch–2Dh
SVID
2Eh–2Fh
SID
30h–3Bh
—
3Ch
INTR_LN
3Dh
INT_PN
3Eh–FFh
—
—
—
Modem Mixer Base Address
Reserved
00000001h
R/W
Modem Base Address
00000001h
R/W
Reserved
00000001h
—
—
—
Subsystem Vendor ID
Reserved
0000h
Write-Once
Subsystem ID
0000h
Write-Once
—
—
Interrupt Line
00h
RO
Interrupt Pin
02h
RO
—
—
Reserved
Reserved
NOTE: Refer to the Specification Update for the value of the Revision ID Register
14.1.1
VID—Vendor Identification Register (Modem—D31:F6)
Address Offset:
Default Value:
Lockable:
01h–00h
8086
No
Bit
15:0
Attribute:
Size:
Power Well:
RO
16 Bits
Core
Description
Vendor ID Value.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
14-1
AC’97 Modem Controller Registers (D31:F6)
14.1.2
DID—Device Identification Register (Modem—D31:F6)
Address Offset:
Default Value:
Lockable:
03h–02h
2446h
No
Bit
15:0
14.1.3
Attribute:
Size:
Power Well:
RO
16 Bits
Core
Description
Device ID Value.
PCICMD—PCI Command Register (Modem—D31:F6)
Address Offset:
Default Value:
Lockable:
05h–04h
0000h
No
Attribute:
Size:
Power Well:
R/W
16 bits
Core
PCICMD is a 16-bit control register. Refer to the PCI 2.1 specification for complete details on each
bit.
Bit
15:10
Description
Reserved. Read 0.
9
Fast Back to Back Enable (FBE). Not implemented. Hardwired to 0.
8
SERR# Enable (SEN). Not implemented. Hardwired to 0.
7
Wait Cycle Control (WCC). Not implemented. Hardwired to 0.
6
Parity Error Response (PER). Not implemented. Hardwired to 0.
5
VGA Palette Snoop (VPS). Not implemented. Hardwired to 0.
4
Memory Write and Invalidate Enable (MWI). Not implemented. Hardwired to 0.
3
Special Cycle Enable (SCE). Not implemented. Hardwired to 0.
2
0 = Disable.
1 = Enable
1
Memory Space (MS). Hardwired to 0, AC ‘97 does not respond to memory accesses.
Bus Master Enable (BME)—R/W. Controls standard PCI bus mastering capabilities.
I/O Space (IOS)—R/W. This bit controls access to the I/O space registers.
0
14-2
0 = Disable access. (default = 0).
1 = Enable access to I/O space. The Native PCI Mode Base Address register should be
programmed prior to setting this bit.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
AC’97 Modem Controller Registers (D31:F6)
14.1.4
PCISTA—Device Status Register (Modem—D31:F6)
Address Offset:
Default Value:
Lockable:
07h–06h
0280h
No
Attribute:
Size:
Power Well:
R/WC
16 bits
Core
PCISTA is a 16-bit status register. Refer to the PCI 2.1 specification for complete details on each
bit.
Bit
Description
15
Detected Parity Error (DPE)—RO. Not implemented. Hardwired to 0.
14
SERR# Status (SERRS)—RO. Not implemented. Hardwired to 0.
13
Master-Abort Status (MAS)—R/WC.
1 = Bus Master AC ‘97 interface function, as a master, generates a master abort.
0 = Software clears this bit by writing a 1 to the bit position.
12
Reserved. Read as “0”.
11
Signaled Target-Abort Status (STA)—RO. Not implemented. Hardwired to 0.
10:9
8
Data Parity Detected (DPD)—RO. Not implemented. Hardwired to 0.
7
Fast Back to back Capable (FBC)—RO. Hardwired to 1. This bit indicates that the ICH2 as a target is
capable of fast back-to-back transactions.
6
UDF Supported—RO. Not implemented. Hardwired to 0.
5
66 MHz Capable—RO. Hardwired to 0.
4:0
14.1.5
DEVSEL# Timing Status (DEVT)—RO. This 2-bit field reflects the ICH2's DEVSEL# timing
parameter. These read only bits indicate the ICH2's DEVSEL# timing when performing a positive
decode.
Reserved. Read as 0s.
RID—Revision Identification Register (Modem—D31:F6)
Address Offset:
Default Value:
Lockable:
08h
See bit description
No
Bit
7:0
14.1.6
Attribute:
Size:
Power Well:
RO
8 Bits
Core
Description
Revision ID Value—RO. Refer to the Specification Update for the value of the Revision ID
Register
PI—Programming Interface Register (Modem—D31:F6)
Address Offset:
Default Value:
Lockable:
09h
00h
No
Bit
7:0
Attribute:
Size:
Power Well:
RO
8 bits
Core
Description
Programming Interface Value—RO.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
14-3
AC’97 Modem Controller Registers (D31:F6)
14.1.7
SCC—Sub Class Code Register (Modem—D31:F6)
Address Offset:
Default Value:
Lockable:
0Ah
03h
No
Attribute:
Size:
Power Well:
Bit
7:0
14.1.8
Description
Sub Class Code Value—RO.
03h = Generic Modem.
BCC—Base Class Code Register (Modem—D31:F6)
Address Offset:
Default Value:
Lockable:
0Bh
07h
No
Attribute:
Size:
Power Well:
Bit
7:0
14.1.9
RO
8 bits
Core
Description
Base Class Code Value—RO.
07h = Simple Communications Controller.
HEDT—Header Type Register (Modem—D31:F6)
Address Offset:
Default Value:
Lockable:
0Eh
00h
No
Bit
7:0
14.1.10
RO
8 bits
Core
Attribute:
Size:
Power Well:
RO
8 bits
Core
Description
Header Value—RO.
MMBAR—Modem Mixer Base Address Register
(Modem—D31:F6)
Address Offset:
Default Value:
10h–13h
00000001h
Attribute:
Size:
R/W
32 bits
The Native PCI Mode Modem uses PCI Base Address register #1 to request a contiguous block of
I/O space that is to be used for the Modem Mixer software interface. The mixer requires 256 bytes
of I/O space. All accesses to the mixer registers are forwarded over the AC-link to the codec where
the registers reside.
In the case of the split codec implementation accesses to the different codecs are differentiated by
the controller by using address offsets 00h–7Fh for the primary codec and address offsets 80h–FEh
for the secondary codec.
14-4
82801BA ICH2 and 82801BAM ICH2-M Datasheet
AC’97 Modem Controller Registers (D31:F6)
Bit
31:16
15:8
Description
Hardwired to 0s
Base Address—R/W. These bits are used in the I/O space decode of the Modem interface
registers. The number of upper bits that a device actually implements depends on how much of the
address space the device will respond to. For the AC ‘97 Modem, the upper 16 bits are hardwired to
0, while bits 15:8 are programmable. This configuration yields a maximum I/O block size of
256 bytes for this base address.
Note: This address must align to a 256-byte boundary.
7:1
0
14.1.11
Reserved. Read as 0
Resource Type Indicator (RTE)—RO. This bit is set to one, indicating a request for I/O space.
MBAR—Modem Base Address Register (Modem—D31:F6)
Address Offset:
Default Value:
14h–17h
00000001h
Attribute:
Size:
R/W
32 bits
The Modem function uses PCI Base Address register #1 to request a contiguous block of I/O space
that is to be used for the Modem software interface. The Modem Bus Mastering register space
requires 128 bytes of I/O space. All Modem registers reside in the controller, therefore cycles are
NOT forwarded over the AC-link to the codec.
Bit
31:16
15:7
Description
Hardwired to 0s
Base Address—R/W. These bits are used in the I/O space decode of the Modem interface
registers. The number of upper bits that a device actually implements depends on how much of the
address space the device will respond to. For the AC ‘97 Modem, the upper 16 bits are hardwired to
0, while bits 15:7 are programmable. This configuration yields a maximum I/O block size of
128 bytes for this base address.
Note: This address must align to a 128-byte boundary.
6:1
0
14.1.12
Reserved. Read as 0
Resource Type Indicator (RTE)—RO. This bit is set to one, indicating a request for I/O space.
SVID—Subsystem Vendor ID (Modem—D31:F6)
Address Offset:
Default Value:
Lockable:
2Dh–2Ch
0000h
No
Attribute:
Size:
Power Well:
Write-Once
16 bits
Core
The SVID register, in combination with the Subsystem ID register, enable the operating
environment to distinguish one audio subsystem from the other(s). This register is implemented as
write-once register. Once a value is written to the register, the value can be read back. Any
subsequent writes will have no effect.
Bit
15:0
Description
Subsystem Vendor ID Value—Read/Write-Once.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
14-5
AC’97 Modem Controller Registers (D31:F6)
14.1.13
SID—Subsystem ID (Modem—D31:F6)
Address Offset:
Default Value:
Lockable:
2Fh–2Eh
0000h
No
Attribute:
Size:
Power Well:
Write-Once
16 bits
Core
The SID register, in combination with the Subsystem Vendor ID register, makes it possible for the
operating environment to distinguish one audio subsystem from another. This register is
implemented as a write-once register. Once a value is written to the register, the value can be read
back. Any subsequent writes will have no effect.
Bit
15:0
14.1.14
Description
Subsystem ID Value—Read/Write-Once.
INTR_LN—Interrupt Line Register (Modem—D31:F6)
Address Offset:
Default Value:
Lockable:
3Ch
00h
No
Attribute:
Size:
Power Well:
R/W
8 bits
Core
This register indicates which PCI interrupt line is used for the AC’97 module interrupt.
Bit
7:0
14.1.15
Description
Interrupt Line—R/W. This data is not used by the ICH2. It is used to communicate to software the
interrupt line that the interrupt pin is connected to.
INT_PIN—Interrupt Pin (Modem—D31:F6)
Address Offset:
Default Value:
Lockable:
3Dh
02h
No
Attribute:
Size:
Power Well:
RO
8 bits
Core
This register indicates which PCI interrupt pin is used for the AC ‘97 modem interrupt. The AC ‘97
interrupt is internally ORed to the interrupt controller with the PIRQB# signal.
Bit
14-6
Description
7:3
Reserved.
2:0
AC ‘97 Interrupt Routing—RO. Hardwired to 010b to select PIRQB#.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
AC’97 Modem Controller Registers (D31:F6)
14.2
AC’97 Modem I/O Space (D31:F6)
In the case of the split codec implementation accesses to the modem mixer registers in different
codecs are differentiated by the controller by using address offsets 00h–7Fh for the primary codec
and address offsets 80h–FEh for the secondary codec. Table 14-2 shows the register addresses for
the modem mixer registers.
Table 14-2. ICH2 Modem Mixer Register Configuration
Register
MMBAR Exposed Registers (D31:F6)
Primary
Secondary
Name
00h:38h
80h:B8h
3Ch
BCh
Extended Modem ID
3Eh
BEh
Extended Modem Status/Control
40h
C0h
Line 1 DAC/ADC Rate
42h
C2h
Line 2 DAC/ADC Rate2
44h
C4h
Handset DAC/ADC Rate2
46h
C6h
Line 1 DAC/ADC Level Mute
48h
C8h
Line 2 DAC/ADC Level Mute2
4Ah
CAh
Handset DAC/ADC Level Mute2
4Ch
CCh
GPIO Pin Configuration
4Eh
CEh
GPIO Polarity/Type
50h
D0h
GPIO Pin Sticky
52h
D2h
GPIO Pin Wake Up
54h
D4h
GPIO Pin Status
Intel RESERVED
56h
D6h
Misc. Modem AFE Stat/Ctrl
58h1
D8h
Vendor Reserved
1
FAh
Vendor Reserved
1
FCh
Vendor ID1
1
FEh
Vendor ID2
7Ah
7Ch
7Eh
NOTE:
1. Registers in bold are multiplexed between audio and modem functions
2. Registers in italics are for functions not supported by the ICH2
3. Software should not try to access reserved registers
4. The ICH2 supports a modem codec as either primary or secondary, but does not support two modem codecs.
The Global Control (GLOB_CNT) and Global Status (GLOB_STA) registers are aliased to the
same global registers in the audio and modem I/O space. Therefore a read/write to these registers in
either audio or modem I/O space affects the same physical register.
These registers exist in I/O space and reside in the AC ‘97 controller. The two channels, Modem in
and Modem out, each have their own set of Bus Mastering registers. The following register
descriptions apply to both channels. The naming prefix convention used is as follows:
• MI = Modem in channel
• MO = Modem out channel
82801BA ICH2 and 82801BAM ICH2-M Datasheet
14-7
AC’97 Modem Controller Registers (D31:F6)
Table 14-3. Modem Registers
Offset
Mnemonic
Name
00h
MI_BDBAR
04h
MI_CIV
Modem In Current Index Value Register
00h
R
05h
MI_LVI
Modem In Last Valid Index Register
00h
R/W
06h
MI_SR
Modem In Status Register
0001h
R/W
08h
MI_PICB
00h
R
0Ah
MI_PIV
Modem In Prefetch Index Value Register
00h
RO
0Bh
MI_CR
Modem In Control Register
00h
R/W
10h
MO_BDBAR
00000000h
R/W
14h
MO_CIV
Modem Out Current Index Value Register
00h
RO
15h
MO_LVI
Modem Out Last Valid Register
00h
R/W
Modem In Buffer Descriptor List Base Address
Register
Default
Access
00000000h
R/W
Modem In Position In Current Buffer Register
Modem Out Buffer Descriptor List Base Address
Register
16h
MO_SR
Modem Out Status Register
0001h
R/W
18h
MI_PICB
Modem In Position In Current Buffer Register
00h
RO
1Ah
MO_PIV
Modem Out Prefetched Index Register
00h
RO
1Bh
MO_CR
Modem Out Control Register
00h
R/W
3Ch
GLOB_CNT
Global Control
00000000h
R/W
40h
GLOB_STA
Global Status
00000000h
RO
44h
ACC_SEMA
Codec Write Semaphore Register
00h
R/W
NOTE:
1. MI = Modem in channel; MO = Modem out channel
14.2.1
x_BDBAR—Buffer Descriptor List Base Address Register
I/O Address:
Default Value:
Lockable:
MBAR + 00h (MIBDBAR),
MBAR + 10h (MOBDBAR)
00000000h
No
Attribute:
R/W (DWord access only)
Size:
Power Well:
32bits
Core
This register can be accessed only as a DWord (32 bits).
Bit
14-8
Description
31:3
Buffer Descriptor List Base Address[31:3]—R/W. These bits represent address bits 31:3. The
entries should be aligned on 8 byte boundaries.
2:0
Hardwired to 0.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
AC’97 Modem Controller Registers (D31:F6)
14.2.2
x_CIV—Current Index Value Register
I/O Address:
Default Value:
Lockable:
MBAR + 04h (MICIV),
MBAR + 14h (MOCIV),
00h
No
Bit
14.2.3
Attribute:
RO
Size:
Power Well:
8bits
Core
Description
7:5
Hardwired to 0.
4:0
Current Index Value [4:0]—RO. These bits represent which buffer descriptor within the list of 16
descriptors is being processed currently. As each descriptor is processed, this value is
incremented.
x_LVI—Last Valid Index Register
I/O Address:
Default Value:
MBAR + 05h (MILVI),
MBAR + 15h (MOLVI)
00h
Bit
Attribute:
R/W
Power Well:
Core
Description
7:5
Hardwired to 0
4:0
Last Valid Index [4:0]—R/W. These bits indicate the last valid descriptor in the list. This value is
updated by software as it prepares new buffers and adds to the list.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
14-9
AC’97 Modem Controller Registers (D31:F6)
14.2.4
x_SR—Status Register
I/O Address:
MBAR + 06h (MISR),
MBAR + 16h (MOSR)
0001h
No
Default Value:
Lockable:
Attribute:
R/WC (Word access only)
Size:
Power Well:
16 bits
Core
This register can be accessed only as a Word (16 bits).
Bit
15:5
Description
Reserved.
FIFO error (FIFOE)—R/WC.
1 = FIFO error occurs.
0 = Cleared by writing a 1 to this bit position.
4
Modem in: FIFO error indicates a FIFO overrun. The FIFO pointers do not increment, the incoming
data is not written into the FIFO, thereby being lost.
Modem out: FIFO error indicates a FIFO underrun. The sample transmitted in this case should be
the last valid sample.
The ICH2 sets the FIFOE bit if the under-run or overrun occurs when there are more valid buffers to
process.
3
Buffer Completion Interrupt Status (BCIS)—R/WC.
1 = Set by the hardware after the last sample of a buffer has been processed, AND if the Interrupt
on Completion (IOC) bit is set in the command byte of the buffer descriptor. Remains active
until software clears bit.
0 = Cleared by writing a 1 to this bit position.
2
Last Valid Buffer Completion Interrupt (LVBCI)—R/WC.
1 = Set by hardware when last valid buffer has been processed. It remains active until cleared by
software. This bit indicates the occurrence of the event signified by the last valid buffer being
processed. Thus, this is an event status bit that can be cleared by software once this event
has been recognized. This event will cause an interrupt if the enable bit in the Control Register
is set. The interrupt is cleared when the software clears this bit.
In the case of transmits (PCM out, Modem out) this bit is set, after the last valid buffer has
been fetched (not after transmitting it) While in the case of Receives, this bit is set after the
data for the last buffer has been written to memory.
0 = Cleared by writing a 1 to this bit position
1
Current Equals Last Valid (CELV)—RO.
1 = Current Index is equal to the value in the Last Valid Index Register, AND the buffer pointed to
by the CIV has been processed (i.e., after the last valid buffer has been processed). This bit is
very similar to bit 2, except, this bit reflects the state rather than the event. This bit reflects the
state of the controller, and remains set until the controller exits this state.
0 = Hardware clears when controller exists state (i.e., until a new value is written to the LVI
register).
0
14-10
DMA Controller Halted (DCH)—RO.
1 = DMA controller is halted. This could happen because of the Start/Stop bit being cleared, or it
could happen once the controller has processed the last valid buffer (in which case it will set
bit 1 and halt).
82801BA ICH2 and 82801BAM ICH2-M Datasheet
AC’97 Modem Controller Registers (D31:F6)
14.2.5
x_PICB—Position In Current Buffer Register
I/O Address:
Default Value:
Lockable:
MBAR + 08h (MIPICB),
MBAR + 18h (MOPICB),
0000h
No
Attribute:
RO (Word access only)
Size:
Power Well:
16 bits
Core
This register can be accessed only as a Word (16 bits).
Bit
15:0
14.2.6
Description
Position In Current Buffer[15:0]—RO. These bits represent the number of DWords left to be
processed in the current buffer.
x_PIV—Prefetch Index Value Register
I/O Address:
Default Value:
Lockable:
MBAR + 0Ah (MIPIV),
MBAR + 1Ah (MOPIV)
00h
No
Bit
14.2.7
Attribute:
RO
Size:
Power Well:
8 bits
Core
Description
7:5
Hardwired to 0
4:0
Prefetched Index value [4:0]—RO. These bits represent which buffer descriptor in the list has
been prefetched.
x_CR—Control Register
I/O Address:
Default Value:
Lockable:
MBAR + 0Bh (MICR),
MBAR + 1Bh (MOCR)
00h
No
Bit
7:5
4
3
2
1
Attribute:
R/W
Size:
Power Well:
8 bits
Core
Description
Reserved.
Interrupt On Completion Enable (IOCE)—R/W. This bit controls whether or not an interrupt
occurs when a buffer completes with the IOC bit set in its descriptor.
0 = Disable.
1 = Enable.
FIFO Error Interrupt Enable (FEIE)—R/W. This bit controls whether the occurrence of a FIFO
error will cause an interrupt or not.
0 = Disable. Bit 4 in the Status Register will be set, but the interrupt will not occur.
1 = Enable. Interrupt will occur
Last Valid Buffer Interrupt Enable (LVBIE)—R/W. This bit controls whether the completion of the
last valid buffer will cause an interrupt or not.
0 = Disable. Bit 2 in the Status register will still be set, but the interrupt will not occur.
1 = Enable.
Reset Registers (RR)—R/W (special).
1 = Contents of all registers to be reset, except the interrupt enable bits (bit 4,3,2 of this register).
Software needs to set this bit. It must be set only when the Run/Pause bit is cleared. Setting it
when the Run bit is set will cause undefined consequences. This bit is self-clearing (software
does not need to clear it).
0 = Removes reset condition.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
14-11
AC’97 Modem Controller Registers (D31:F6)
Bit
Description
Run/Pause Bus master (RPBM)—R/W.
0
14.2.8
0 = Pause bus master operation. This results in all state information being retained (i.e., master
mode operation can be stopped and then resumed).
1 = Run. Bus master operation starts.
GLOB_CNT—Global Control Register
I/O Address:
Default Value:
Lockable:
MBAR + 3Ch
00000000h
No
Attribute:
Size:
Power Well:
R/W (DWord access only)
32 bits
Core
This register can be accessed only as a DWord (32 bits).
Bit
31:6
Description
Reserved.
Secondary Resume Interrupt Enable—R/W.
5
0 = Disable.
1 = Enable an interrupt to occur when the secondary codec causes a resume event on the
AC-link.
Primary Resume Interrupt Enable—R/W.
4
0 = Disable.
1 = Enable an interrupt to occur when the primary codec causes a resume event on the AC-link.
ACLINK Shut Off—R/W.
3
2
0 = Normal operation.
1 = Disable the AC-link signals (drive all AC’97 outputs low and turn off all AC’97 input buffer
enables)
AC’97 Warm Reset—R/W (special).
1 = Writing a 1 to this bit causes a warm reset to occur on the AC-link. The warm reset will awaken
a suspended codec without clearing its internal registers. If software attempts to perform a
warm reset while BIT_CLK is running, the write will be ignored and the bit will not be changed.
A warm reset can only occur in the absence of BIT_CLK.
0 = This bit is self-clearing (it clears itself after the reset has occurred and BIT_CLK has started).
AC‘97 Cold Reset#—R/W (special).
1
0
14-12
0 = Writing a 0 to this bit causes a cold reset to occur throughout the AC‘97 circuitry. All data in the
codec will be lost. Software needs to clear this bit no sooner than after 1usec has elapsed.
This bit reflects the state of the AC_RST# pin. The ICH2 clears this bit to “0” upon entering
S3/S4/S5 sleep states and PCIRST#.
GPI Interrupt Enable (GIE)—R/W. This bit controls whether the change in status of any GPI
causes an interrupt.
0 = Bit 0 of the Global Status Register is set, but an interrupt is not generated.
1 = The change on value of a GPI causes an interrupt and sets bit 0 of the Global Status Register.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
AC’97 Modem Controller Registers (D31:F6)
14.2.9
GLOB_STA—Global Status Register
I/O Address:
Default Value:
Lockable:
MBAR + 40h
00300000h
No
Attribute:
Size:
Power Well:
RO, R/W, R/WC (DWord access only)
32 bits
Core
This register can be accessed only as a DWord (32 bits).
Bit
31:22
Description
Reserved.
6 Channel Capability (6CH_CAP)—RO. Hardwired to 1.
21
0 = The AC ‘97 Controller does not support 6-channel PCM Audio output.
1 = The AC ‘97 Controller supports 6-channel PCM Audio output.
4 Channel Capability (4CH_CAP)—RO. Hardwired to 1.
20
19:18
0 = The AC ‘97 Controller does not support 4-channel PCM Audio output.
1 = The AC ‘97 Controller supports 4-channel PCM Audio output.
Reserved.
17
MD3—R/W. Power down semaphore for modem. This bit exists in the suspend well and maintains
context across power states (except G3). The bit has no hardware function. It is used by software in
conjunction with the AD3 bit to coordinate the entry of the two codecs into D3 state.
16
AD3—R/W. Power down semaphore for Audio. This bit exists in the suspend well and maintains
context across power states (except G3). The bit has no hardware function. It is used by software in
conjunction with the MD3 bit to coordinate the entry of the two codecs into D3 state.
Read Completion Status (RCS)—R/W. This bit indicates the status of codec read completions.
15
0 = A codec read completes normally.
1 = A codec read results in a time-out. The bit remains set until being cleared by software.
14
Bit 3 of slot 12—RO. Display bit 3 of the most recent slot 12
13
Bit 2 of slot 12—RO. Display bit 2 of the most recent slot 12
12
Bit 1 of slot 12—RO. Display bit 1 of the most recent slot 12
11
Secondary Resume Interrupt (SRI)—R/WC. This bit indicates that a resume event occurred on
AC_SDIN[1].
1 = Resume event occurred
0 = Cleared by writing a 1 to this bit position.
10
Primary Resume Interrupt (PRI)—R/WC. This bit indicates that a resume event occurred on
AC_SDIN[0].
1 = Resume event occurred
0 = Cleared by writing a 1 to this bit position.
9
Secondary Codec Ready (SCR)—RO. Reflects the state of the codec ready bit in AC_SDIN[1].
Bus masters ignore the condition of the codec ready bits, so software must check this bit before
starting the bus masters. Once the codec is “ready”, it must never go “not ready” spontaneously.
0 = Not Ready.
1 = Ready.
8
Primary Codec Ready (PCR)—RO. Reflects the state of the codec ready bit in AC_SDIN [0]. Bus
masters ignore the condition of the codec ready bits, so software must check this bit before starting
the bus masters. Once the codec is “ready”, it must never go “not ready” spontaneously.
0 = Not Ready.
1 = Ready.
7
Mic In Interrupt (MINT)—RO. This bit indicates that one of the Mic in channel interrupts occurred.
1 = Interrupt occurred.
0 = When the specific interrupt is cleared, this bit will be cleared.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
14-13
AC’97 Modem Controller Registers (D31:F6)
Bit
6
Description
PCM Out Interrupt (POINT)—RO. This bit indicates that one of the PCM out channel interrupts
occurred.
1 = Interrupt occurred.
0 = When the specific interrupt is cleared, this bit will be cleared.
5
PCM In Interrupt (PIINT)—RO. This bit indicates that one of the PCM in channel interrupts
occurred.
1 = Interrupt occurred.
0 = 0 = When the specific interrupt is cleared, this bit will be cleared.
4:3
2
Reserved
Modem Out Interrupt (MOINT)—RO. This bit indicates that one of the modem out channel
interrupts occurred.
1 = Interrupt occurred.
0 = When the specific interrupt is cleared, this bit will be cleared.
1
Modem In Interrupt (MIINT)—RO. This bit indicates that one of the modem in channel interrupts
occurred.
1 = Interrupt occurred.
0 = When the specific interrupt is cleared, this bit will be cleared.
0
GPI Status Change Interrupt (GSCI)—RWC. This bit reflects the state of bit 0 in slot 12, and is set
when bit 0 of slot 12 is set. This happens when the value of any of the GPIOs currently defined as
inputs changes.
1 = Input changed.
0 = Cleared by writing a 1 to this bit position.
Note:
14.2.10
On reads from a codec, the controller will give the codec a maximum of 4 frames to respond, after
which if no response is received, it will return a dummy read completion to the processor (with all
pHs on the data) and also set the Read Completion Status bit in the Global Status Register.
CAS—Codec Access Semaphore Register
I/O Address:
Default Value:
Lockable:
Bit
7:1
NABMBAR + 44h
00h
No
Attribute:
Size:
Power Well:
R/W
8 bits
Core
Description
Reserved.
Codec Access Semaphore (CAS)—R/W (special). This bit is read by software to check whether a
codec access is currently in progress.
0
14-14
0 = No access in progress.
1 = The act of reading this register sets this bit to 1. The driver that read this bit can then perform
an I/O access. Once the access is completed, hardware automatically clears this bit.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Pinout and Package Information
Pinout and Package Information
15.1
15
Pinout
This section contains the ICH2 82801BA and ICH2-M 82801BAM ballout information.
Figure 15-1 and Figure 15-2 provide a graphical illustration of how the ballout maps to the 360
EBGA package for both the ICH2 82801BA and 82801BAM ICH2-M. Table 15-1 provides the
ballout for the ICH2 82801BA, listed alphabetically by signal name. Table 15-2 provides the
ballout for the ICH2-M 82801BAM, listed alphabetically by signal name.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
15-1
Pinout and Package Information
Figure 15-1. ICH2 82801BA and ICH2-M 82801BAM Ballout (Top view — Left side)
1
2
3
4
5
6
7
8
9
10
11
A
VSS
VSS
HLCOMP
HL0
HL2
HL_STB
HL_STB#
HL5
HL7
VSS
IGNNE#
B
VSS
VSS
VSS
HUBREF
HL1
HL3
HL4
HL6
VSS
VSS
NMI
C
#N/A
VSS
VSS
VSS
HL11
HL9
HL10
HL8
VSS
STPCLK#
INTR
D
#N/A
VCC1_8
VSS
CLK66
VSS
VSS
VSS
VSS
VSS
VCC1_8
A20M#
E
#N/A
#N/A
#N/A
#N/A
VCC1_8
VSS
VSS
VSS
VSS
F
LAN_TXD2
LAN_TXD1
LAN_TXD0
#N/A
VSS
VSS
VSS
VCCSUS3_3
(ICH2)
VCCLAN3_3
(ICH2-M)
VCCSUS3_3
(ICH2)
G
LAN_RXD1
LAN_RXD0
LAN_CLK
#N/A
VCCLAN3_3
(ICH2-M)
VCCSUS1_8
(ICH2)
H
LAN_RXD2
LAN_RSTSYNC
#N/A
#N/A
VCCLAN1_8
(ICH2-M)
VCCSUS1_8
(ICH2)
J
#N/A
#N/A
EE_SHCLK
EE_DOUT
VCCLAN1_8
(ICH2-M)
K
VSS
V5REF1
EE_DIN
EE_CS
VSS
VSS
VSS
GPIO21 (ICH2)
L
C3_STAT# /
GPIO21
(ICH2-M)
GNTA# /GPIO16
REQB# /
REQ5# /
GPIO1
GNTB# /
GNT5# /
GPIO17
VSS
VSS
VSS
M
GNT1#
GNT0#
REQA# /
GPIO0
PIRQH#
VSS
VSS
VSS
N
PIRQG# /
GPIO4
PIRQF#/ GPIO3
PIRQE#
PIRQD#
VSS
VSS
VSS
P
PIRQA#
PIRQB#
PIRQC#
REQ4#
VCC1_8
VSS
VSS
VSS
R
GNT4#
REQ0#
REQ1#
GNT2#
VCC3_3
T
REQ2#
GNT3#
AD30
AD28
VCC3_3
U
AD26
AD24
AD22
AD20
VCC3_3
V
AD18
AD16
FRAME#
TRDY#
VCC3_3
VCC3_3
VCC3_3
VCC3_3
VCC1_8
W
STOP#
PAR
AD11
AD4
AD3
AD10
SERR#
IRDY#
AD21
AD27
PCICLK
Y
AD15
AD13
AD9
AD2
AD5
AD12
PERR#
C/BE2#
AD23
AD29
AGPBUSY#
(ICH2-M)
AA
VSS
VSS
C/BE0#
AD0
AD7
AD14
PLOCK#
AD17
C/BE3#
AD31
GPIO7
AB
VSS
VSS
AD6
AD1
AD8
C/BE1#
DEVSEL#
AD19
AD25
REQ3#
LFRAME# /
FWH4
1
2
3
4
5
6
7
8
9
10
11
GPIO6 (ICH2)
15-2
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Pinout and Package Information
Figure 15-2. ICH2 82801BA and ICH2-M 82801BAM Ballout (Top view — Right side)
12
13
14
15
16
17
18
19
20
21
22
CPUSLP#
CPUPWRGD
GPIO23 (ICH2)
GPIO18 (ICH2)
SDA0
SIORDY
SDD15
SDD13
SDD3
VSS
VSS
A
GMUXSEL#
(ICH2-M)
STP_PCI#
(ICH2-M)
VRMPWRGD
(ICH2)
SDA2
SDDACK#
SDDREQ
SDD1
SDD11
VSS
VSS
B
GPIO22 (ICH2)
SMI#
INIT#
RCIN#
A20GATE
CPUPERF#
(ICH2-M)
VGATE /
VRMPWRGD
(ICH2-M)
GPIO20 (ICH2)
SDCS1#
IRQ15
SDIOW#
SDD14
SDD12
SDD4
SDD5
SDD9
C
SDCS3#
SDA1
SDIOR#
SDD0
SDD2
SDD10
SDD8
SDD6
D
VCC3_3
VCC3_3
VCC3_3
VCC3_3
PDCS3#
SDD7
PDCS1#
PDA2
E
VCC3_3
PDA1
PDA0
IRQ14
PDDACK#
F
VCC3_3
PDIOR#
PIORDY
PDIOW#
PDDREQ
G
VCC3_3
PDD0
PDD15
PDD14
PDD1
H
VCC3_3
PDD2
PDD13
PDD12
PDD3
J
STP_CPU#
(ICH2-M)
V_CPU_IO
V_CPU_IO
GPIO19 (ICH2)
SLP_S1#
(ICH2-M)
VCC3_3
VSS
VSS
VSS
VSS
VSS
VSS
VCC1_8
PDD11
PDD4
PDD10
K
VSS
VSS
VSS
VCC1_8
PDD5
PDD9
PDD8
L
VSS
VSS
VSS
CLK14
V5REF2
PDD6
PDD7
M
VSS
VSS
VSS
APICD1
APICCLK
SERIRQ
SPKR
N
VSS
VSS
VSS
VCC3_3
AC_SYNC
CLK48
AC_SDOUT
APICD0
P
VCC3_3
AC_BITCLK
PWROK
RSMRST#
FERR#
R
VCCSUS3_3
INTRUDER#
RTCRST#
VBIAS
RTCX2
T
VCCSUS3_3
SMLINK0
TP0(ICH2)
VCCRTC
RTCX1
U
GPIO24 (ICH2)
AC_RST#
V
BATLOW#
(ICH2-M)
VCCSUS1_8
VCCSUS1_8
VCCSUS1_8
VCCSUS3_3
VCCSUS3_3
V5REF_SUS
SMLINK1
CLKRUN#
(ICH2-M)
LAD1 / FWH1
LDRQ1#
GPIO12
GPIO25
SLP_S3#
USBP0P
USBP2P
OC0#
OC3#
PWRBTN#
AC_SDIN1
W
LAD0 / FWH0
LDRQ0#
GPIO8
PME#
RSM_PWROK
(ICH2)
SUSSTAT#
USBP0N
USBP2N
OC1#
OC2#
AC_SDIN0
Y
LAN_PWROK#
(ICH2-M)
FS0
THRM#
GPIO28
PCIRST#
SMBDATA
RI#
SUSCLK
USBP1N
USBP3N
VSS
VSS
AA
LAD3 / FWH3
LAD2 / FWH2
GPIO27
GPIO13
SMBCLK
SMBALERT# /
GPIO11
SLP_S5#
USBP1P
USBP3P
VSS
VSS
AB
12
13
14
15
16
17
18
19
20
21
22
82801BA ICH2 and 82801BAM ICH2-M Datasheet
15-3
Pinout and Package Information
Table 15-1. ICH2 82801BA Alphabetical
Ball List by Signal Name
15-4
Signal Name
Ball Number
SDD03
A20
A20GATE
C13
A20M#
D11
AC_BITCLK
R19
AC_RST#
V22
AC_SDIN0
Y22
AC_SDIN1
W22
AC_SDOUT
P21
AC_SYNC
P19
AD0
AA4
AD1
AB4
AD2
Y4
AD3
W5
AD4
W4
AD5
Y5
AD6
AB3
AD7
AA5
AD8
AB5
AD9
Y3
AD10
W6
AD11
W3
AD12
Y6
AD13
Y2
AD14
AA6
AD15
Y1
AD16
V2
AD17
AA8
AD18
V1
AD19
AB8
AD20
U4
AD21
W9
AD22
U3
AD23
Y9
AD24
U2
AD25
AB9
AD26
U1
AD27
W10
Table 15-1. ICH2 82801BA Alphabetical
Ball List by Signal Name
Signal Name
Ball Number
AD28
T4
AD29
Y10
AD30
T3
AD31
AA10
APICCLK
N20
APICD0
P22
APICD1
N19
C/BE0#
AA3
C/BE1#
AB6
C/BE2#
Y8
C/BE3#
AA9
CLK14
M19
CLK48
P20
CLK66
D4
CPUPWRGD
A13
CPUSLP#
A12
DEVSEL#
AB7
EE_CS
K4
EE_DIN
K3
EE_DOUT
J4
EE_SHCLK
J3
FERR#
R22
FRAME#
V3
FS0
AA12
GNT0#
M2
GNT1#
M1
GNT2#
R4
GNT3#
T2
GNT4#
R1
GNTA# / GPIO16
L2
GNTB# / GNT5# / GPIO17
L4
GPIO6
Y11
GPIO7
AA11
GPIO8
Y14
GPIO12
W14
GPIO13
AB15
GPIO18
A15
GPIO19
D14
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Pinout and Package Information
Table 15-1. ICH2 82801BA Alphabetical
Ball List by Signal Name
Table 15-1. ICH2 82801BA Alphabetical
Ball List by Signal Name
Signal Name
Ball Number
Signal Name
Ball Number
GPIO20
C14
LAN_RXD1
G1
GPIO21
L1
LAN_RXD2
H1
GPIO22
B14
LAN_TXD0
F3
GPIO23
A14
LAN_TXD1
F2
GPIO24
V21
LAN_TXD2
F1
GPIO25
W15
LDRQ0#
Y13
GPIO27
AB14
LDRQ1#
W13
GPIO28
AA14
LFRAME# / FWH4
AB11
HL_STB
A6
NMI
B11
HL_STB#
A7
OC0#
W19
HL0
A4
OC1#
Y20
HL1
B5
OC2#
Y21
HL2
A5
OC3#
W20
HL3
B6
PAR
W2
HL4
B7
PCICLK
W11
HL5
A8
PCIRST#
AA15
HL6
B8
PDA0
F20
HL7
A9
PDA1
F19
HL8
C8
PDA2
E22
HL9
C6
PDCS1#
E21
HL10
C7
PDCS3#
E19
HL11
C5
PDD0
H19
HLCOMP
A3
PDD1
H22
HUBREF
B4
PDD2
J19
IGNNE#
A11
PDD3
J22
INIT#
C12
PDD4
K21
INTR
C11
PDD5
L20
INTRUDER#
T19
PDD6
M21
IRDY#
W8
PDD7
M22
IRQ14
F21
PDD8
L22
IRQ15
C16
PDD9
L21
LAD0 / FWH0
Y12
PDD10
K22
LAD1 / FWH1
W12
PDD11
K20
LAD2 / FWH2
AB13
PDD12
J21
LAD3 / FWH3
AB12
PDD13
J20
LAN_CLK
G3
PDD14
H21
LAN_RSTSYNC
H2
PDD15
H20
LAN_RXD0
G2
PDDACK#
F22
82801BA ICH2 and 82801BAM ICH2-M Datasheet
15-5
Pinout and Package Information
Table 15-1. ICH2 82801BA Alphabetical
Ball List by Signal Name
15-6
Table 15-1. ICH2 82801BA Alphabetical
Ball List by Signal Name
Signal Name
Ball Number
Signal Name
Ball Number
PDDREQ
G22
SDD2
D19
PDIOR#
G19
SDD4
C20
PDIOW#
G21
SDD5
C21
PERR#
Y7
SDD6
D22
PIORDY
G20
SDD7
E20
PIRQA#
P1
SDD8
D21
PIRQB#
P2
SDD9
C22
PIRQC#
P3
SDD10
D20
PIRQD#
N4
SDD11
B20
PIRQE#
N3
SDD12
C19
PIRQF# / GPIO3
N2
SDD13
A19
PIRQG# / GPIO4
N1
SDD14
C18
PIRQH#
M4
SDD15
A18
PLOCK#
AA7
SDDACK#
B17
PME#
Y15
SDDREQ
B18
PWRBTN#
W21
SDIOR#
D17
PWROK
R20
SDIOW#
C17
RCIN#
B13
SERIRQ
N21
REQ0#
R2
SERR#
W7
REQ1#
R3
SIORDY
A17
REQ2#
T1
SLP_S3#
W16
REQ3#
AB10
SLP_S5#
AB18
REQ4#
P4
SMBALERT# / GPIO11
AB17
REQA# / GPIO0
M3
SMBCLK
AB16
REQB# / REQ5#/ GPIO1
L3
SMBDATA
AA16
RI#
AA17
SMI#
B12
RSM_PWROK
Y16
SMLINK0
U19
RSMRST#
R21
SMLINK1
V20
RTCRST#
T20
SPKR
N22
RTCX1
U22
STOP#
W1
RTCX2
T22
STPCLK#
C10
SDA0
A16
SUSCLK
AA18
SDA1
D16
SUSSTAT#
Y17
SDA2
B16
THRM#
AA13
SDCS1#
C15
TP0
U20
SDCS3#
D15
TRDY#
V4
SDD0
D18
USBP0N
Y18
SDD1
B19
USBP0P
W17
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Pinout and Package Information
Table 15-1. ICH2 82801BA Alphabetical
Ball List by Signal Name
Table 15-1. ICH2 82801BA Alphabetical
Ball List by Signal Name
Signal Name
Ball Number
Signal Name
Ball Number
USBP1N
AA19
VCCSUS1_8
H5
USBP1P
AB19
VCCSUS1_8
J5
USBP2N
Y19
VCCSUS1_8
V14
USBP2P
W18
VCCSUS1_8
V15
USBP3N
AA20
VCCSUS1_8
V16
USBP3P
AB20
VCCSUS3_3
F5
V_CPU_IO
D12
VCCSUS3_3
G5
V_CPU_IO
D13
VCCSUS3_3
T18
V5REF_SUS
V19
VCCSUS3_3
U18
V5REF1
K2
VCCSUS3_3
V17
V5REF2
M20
VCCSUS3_3
V18
VBIAS
T21
VRMPWRGD
B15
VCC1_8
D10
VSS
D7
VCC1_8
D2
VSS
D8
VCC1_8
K19
VSS
D9
VCC1_8
L19
VSS
E6
VCC1_8
P5
VSS
E7
VCC1_8
V9
VSS
E8
VCC1_8
E5
VSS
E9
VCC3_3
E14
VSS
J10
VCC3_3
E15
VSS
J11
VCC3_3
E16
VSS
J12
VCC3_3
E17
VSS
J13
VCC3_3
E18
VSS
J14
VCC3_3
F18
VSS
J9
VCC3_3
G18
VSS
K1
VCC3_3
H18
VSS
K10
VCC3_3
J18
VSS
K11
VCC3_3
P18
VSS
K12
VCC3_3
R18
VSS
K13
VCC3_3
R5
VSS
K14
VCC3_3
T5
VSS
K9
VCC3_3
U5
VSS
L10
VCC3_3
V5
VSS
L11
VCC3_3
V6
VSS
A1
VCC3_3
V7
VSS
A10
VCC3_3
V8
VSS
A2
VCCRTC
U21
VSS
A21
82801BA ICH2 and 82801BAM ICH2-M Datasheet
15-7
Pinout and Package Information
Table 15-1. ICH2 82801BA Alphabetical
Ball List by Signal Name
15-8
Table 15-1. ICH2 82801BA Alphabetical
Ball List by Signal Name
Signal Name
Ball Number
Signal Name
Ball Number
VSS
A22
VSS
L12
VSS
AA1
VSS
L13
VSS
AA2
VSS
L14
VSS
AA21
VSS
L9
VSS
AA22
VSS
M10
VSS
AB1
VSS
M11
VSS
AB2
VSS
M12
VSS
AB21
VSS
M13
VSS
AB22
VSS
M14
VSS
B1
VSS
M9
VSS
B10
VSS
N10
VSS
B2
VSS
N11
VSS
B21
VSS
N12
VSS
B22
VSS
N13
VSS
B3
VSS
N14
VSS
B9
VSS
N9
VSS
C2
VSS
P10
VSS
C3
VSS
P11
VSS
C4
VSS
P12
VSS
C9
VSS
P13
VSS
D3
VSS
P14
VSS
D5
VSS
P9
VSS
D6
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Pinout and Package Information
Table 15-2. ICH2-M 82801BAM
Alphabetical Ball List by
Signal Name
Signal Name
Ball Number
A20GATE
C13
A20M#
D11
AC_BITCLK
R19
AC_RST#
V22
AC_SDIN0
Y22
AC_SDIN1
W22
AC_SDOUT
P21
AC_SYNC
P19
AD0
AA4
AD1
AB4
AD2
Y4
AD3
W5
AD4
W4
AD5
Y5
AD6
AB3
AD7
AA5
AD8
AB5
AD9
Y3
AD10
W6
AD11
W3
AD12
Y6
AD13
Y2
AD14
AA6
AD15
Y1
AD16
V2
AD17
AA8
AD18
V1
AD19
AB8
AD20
U4
AD21
W9
AD22
U3
AD23
Y9
AD24
U2
AD25
AB9
AD26
U1
AD27
W10
AD28
T4
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Table 15-2. ICH2-M 82801BAM
Alphabetical Ball List by
Signal Name
Signal Name
Ball Number
AD29
Y10
AD30
T3
AD31
AA10
AGPBUSY#
Y11
APICCLK
N20
APICD0
P22
APICD1
N19
BATLOW#
U20
C/BE0#
AA3
C/BE1#
AB6
C/BE2#
Y8
C/BE3#
AA9
C3_STAT# / GPIO21
L1
CLK14
M19
CLK48
P20
CLK66
D4
CLKRUN#
V21
CPUPERF#
B14
CPUPWRGD
A13
CPUSLP#
A12
DEVSEL#
AB7
EE_CS
K4
EE_DIN
K3
EE_DOUT
J4
EE_SHCLK
J3
FERR#
R22
FRAME#
V3
FS0
AA12
GMUXSEL#
A14
GNT0#
M2
GNT1#
M1
GNT2#
R4
GNT3#
T2
GNT4#
R1
GNTA# / GPIO16
L2
GNTB# / GNT5# / GPIO17
L4
GPIO7
AA11
15-9
Pinout and Package Information
Table 15-2. ICH2-M 82801BAM
Alphabetical Ball List by
Signal Name
15-10
Table 15-2. ICH2-M 82801BAM
Alphabetical Ball List by
Signal Name
Signal Name
Ball Number
Signal Name
Ball Number
GPIO8
Y14
LAN_RXD1
G1
GPIO12
W14
LAN_RXD2
H1
GPIO13
AB15
LAN_TXD0
F3
GPIO25
W15
LAN_TXD1
F2
GPIO27
AB14
LAN_TXD2
F1
GPIO28
AA14
LDRQ0#
Y13
HL_STB
A6
LDRQ1#
W13
HL_STB#
A7
LFRAME# / FWH4
AB11
HL0
A4
NMI
B11
HL1
B5
OC0#
W19
HL2
A5
OC1#
Y20
HL3
B6
OC2#
Y21
HL4
B7
OC3#
W20
HL5
A8
PAR
W2
HL6
B8
PCICLK
W11
HL7
A9
PCIRST#
AA15
HL8
C8
PDA0
F20
HL9
C6
PDA1
F19
HL10
C7
PDA2
E22
HL11
C5
PDCS1#
E21
HLCOMP
A3
PDCS3#
E19
HUBREF
B4
PDD0
H19
IGNNE#
A11
PDD1
H22
INIT#
C12
PDD2
J19
INTR
C11
PDD3
J22
INTRUDER#
T19
PDD4
K21
IRDY#
W8
PDD5
L20
IRQ14
F21
PDD6
M21
IRQ15
C16
PDD7
M22
LAD0 / FWH0
Y12
PDD8
L22
LAD1 / FWH1
W12
PDD9
L21
LAD2 / FWH2
AB13
PDD10
K22
LAD3 / FWH3
AB12
PDD11
K20
LAN_CLK
G3
PDD12
J21
LAN_PWROK
Y16
PDD13
J20
LAN_RSTSYNC
H2
PDD14
H21
LAN_RXD0
G2
PDD15
H20
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Pinout and Package Information
Table 15-2. ICH2-M 82801BAM
Alphabetical Ball List by
Signal Name
Table 15-2. ICH2-M 82801BAM
Alphabetical Ball List by
Signal Name
Signal Name
Ball Number
Signal Name
Ball Number
PDDACK#
F22
SDD1
B19
PDDREQ
G22
SDD2
D19
PDIOR#
G19
SDD3
A20
PDIOW#
G21
SDD4
C20
PERR#
Y7
SDD5
C21
PIORDY
G20
SDD6
D22
PIRQA#
P1
SDD7
E20
PIRQB#
P2
SDD8
D21
PIRQC#
P3
SDD9
C22
PIRQD#
N4
SDD10
D20
PIRQE#
N3
SDD11
B20
PIRQF# / GPIO3
N2
SDD12
C19
PIRQG# / GPIO4
N1
SDD13
A19
PIRQH#
M4
SDD14
C18
PLOCK#
AA7
SDD15
A18
PME#
Y15
SDDACK#
B17
PWRBTN#
W21
SDDREQ
B18
PWROK
R20
SDIOR#
D17
RCIN#
B13
SDIOW#
C17
REQ0#
R2
SERIRQ
N21
REQ1#
R3
SERR#
W7
REQ2#
T1
SIORDY
A17
REQ3#
AB10
SLP_S1#
D14
REQ4#
P4
SLP_S3#
W16
REQA# / GPIO0
M3
SLP_S5#
AB18
REQB# / REQ5#/ GPIO1
L3
SMBALERT# / GPIO11
AB17
RI#
AA17
SMBCLK
AB16
RSMRST#
R21
SMBDATA
AA16
RTCRST#
T20
SMI#
B12
RTCX1
U22
SMLINK0
U19
RTCX2
T22
SMLINK1
V20
SDA0
A16
SPKR
N22
SDA1
D16
STOP#
W1
SDA2
B16
STP_CPU#
C14
SDCS1#
C15
STP_PCI#
A15
SDCS3#
D15
STPCLK#
C10
SDD0
D18
SUSCLK
AA18
82801BA ICH2 and 82801BAM ICH2-M Datasheet
15-11
Pinout and Package Information
Table 15-2. ICH2-M 82801BAM
Alphabetical Ball List by
Signal Name
15-12
Table 15-2. ICH2-M 82801BAM
Alphabetical Ball List by
Signal Name
Signal Name
Ball Number
Signal Name
Ball Number
SUSSTAT#
Y17
VCC3_3
U5
THRM#
AA13
VCC3_3
V5
TRDY#
V4
VCC3_3
V6
USBP0N
Y18
VCC3_3
V7
USBP0P
W17
VCC3_3
V8
USBP1N
AA19
VCCLAN1_8
H5
USBP1P
AB19
VCCLAN1_8
J5
USBP2N
Y19
VCCLAN3_3
F5
USBP2P
W18
VCCLAN3_3
G5
USBP3N
AA20
VCCRTC
U21
USBP3P
AB20
VCCSUS1_8
V14
V_CPU_IO
D12
VCCSUS1_8
V15
V_CPU_IO
D13
VCCSUS1_8
V16
V5REF_SUS
V19
VCCSUS3_3
T18
V5REF1
K2
VCCSUS3_3
U18
V5REF2
M20
VCCSUS3_3
V17
VBIAS
T21
VCCSUS3_3
V18
VCC1_8
D10
VGATE / VRMPWRGD
B15
VCC1_8
D2
VSS
D7
VCC1_8
K19
VSS
D8
VCC1_8
L19
VSS
D9
VCC1_8
P5
VSS
E6
VCC1_8
V9
VSS
E7
VCC1_8
E5
VSS
E8
VCC3_3
E14
VSS
E9
VCC3_3
E15
VSS
J10
VCC3_3
E16
VSS
J11
VCC3_3
E17
VSS
J12
VCC3_3
E18
VSS
J13
VCC3_3
F18
VSS
J14
VCC3_3
G18
VSS
J9
VCC3_3
H18
VSS
K1
VCC3_3
J18
VSS
K10
VCC3_3
P18
VSS
K11
VCC3_3
R18
VSS
K12
VCC3_3
R5
VSS
K13
VCC3_3
T5
VSS
K14
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Pinout and Package Information
Table 15-2. ICH2-M 82801BAM
Alphabetical Ball List by
Signal Name
Table 15-2. ICH2-M 82801BAM
Alphabetical Ball List by
Signal Name
Signal Name
Ball Number
Signal Name
Ball Number
VSS
K9
VSS
C9
VSS
L10
VSS
D3
VSS
L11
VSS
D5
VSS
A1
VSS
D6
VSS
A10
VSS
L12
VSS
A2
VSS
L13
VSS
A21
VSS
L14
VSS
A22
VSS
L9
VSS
AA1
VSS
M10
VSS
AA2
VSS
M11
VSS
AA21
VSS
M12
VSS
AA22
VSS
M13
VSS
AB1
VSS
M14
VSS
AB2
VSS
M9
VSS
AB21
VSS
N10
VSS
AB22
VSS
N11
VSS
B1
VSS
N12
VSS
B10
VSS
N13
VSS
B2
VSS
N14
VSS
B21
VSS
N9
VSS
B22
VSS
P10
VSS
B3
VSS
P11
VSS
B9
VSS
P12
VSS
C2
VSS
P13
VSS
C3
VSS
P14
VSS
C4
VSS
P9
82801BA ICH2 and 82801BAM ICH2-M Datasheet
15-13
Pinout and Package Information
15.2
Package Information
Figure 15-3 and Figure 15-4 illustrate the ICH2 and ICH2-M 360 EBGA package.
Figure 15-3. ICH2 / ICH2-M Package (Top and Side Views)
Top View
0.127
A
-A23.00 ±0.10
19.50 ±0.20
Pin 1 corner
-BPin 1 I.D.
Detail A
23.00 ±0.10
14.70 REF
19.50 ±0.20
45° Chamfer
(4 places)
0.127
A
14.70 REF
Detail A (Not to scale)
Pin #1 Corner
No Radius
Au Gate
90°
Pin #1 SHINY
1.0 Dia x 0.15 Depth
6.75 ±0.50 x 6.75 ±0.50 From Center Line
Side View
2.23 ±0.19
1.17 ±0.05
30°
0.15 C
0.15
0.56 ±0.04
-C-
0.50 ±0.10
Seating Plane (see Note 3)
Notes:
1. All dimensions are in millimeters.
2. All dimensions and tolerances conform to ANSI Y14.5M - 1982.
3. Primary Datum (-C-) and seating plane are defined by the sperical crowns of the solder balls.
15-14
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Pinout and Package Information
Figure 15-4. ICH2 / ICH2-M Package (Bottom View)
B o tto m V iew
22
N ote 3
ϕ 0.30 S
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0.70
ϕ
C
21
P in A 1 corner
0.50
A S
A
B
B S
C
D
E
F
G
H
J
1.00
K
L
M
N
P
R
T
U
V
W
Y
AA
AB
1.00 R E F
1.00 R E F
1.00
ϕ 1.0
3 places
N otes :
1. A ll dim ensions are in m illim eters.
2. A ll dim ensions and toleranc es conform to A N S I Y 14.5M - 1982.
3. D im ension is m easured at the m axim um s older ball diam eter. P arallel to D atum (-C -) on S ide V iew illustration.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
15-15
Pinout and Package Information
This page is intentionally left blank.
15-16
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Electrical Characteristics
Electrical Characteristics
Note:
16.1
16
The data provided in this chapter regarding the Electrical Characteristics of the ICH2 component
are preliminary and subject to change.
Absolute Maximum Ratings
Case Temperature under Bias ..................................................................................... 0°C to +109°C
Storage Temperature ............................................................................................... -55°C to +150°C
Voltage on Any 3.3V Pin with Respect to Ground ...............................................-0.5 to Vcc + 0.3 V
Voltage on Any 5V Tolerant Pin with Respect to Ground (VREF=5V)...............-0.5 to VREF + 0.3 V
1.8V Supply Voltage with Respect to Vss ..................................................................... -0.5 to +2.7V
3.3V Supply Voltage with Respect to Vss .................................................................... -0.5 to +4.6 V
5.0V Supply Voltage (Vref) with Respect to Vss ......................................................... -0.5 to +5.5 V
Maximum Power Dissipation ....................................................................................................2.0 W
Warning:
16.2
Stressing the device beyond the "Absolute Maximum Ratings" may cause permanent damage.
These are stress ratings only. See Section 16.2 for the Functional Operating Range of the ICH2.
Functional Operating Range
All of the AC and DC Characteristics specified in this document assume that the ICH2 component
is operating within the Functional Operating Range given in this section. Operation outside of the
Functional Operating Range is not recommended, and extended exposure outside of the Functional
Operating Range may affect component reliability.
Case Temperature under Bias .................................................................................... 0°C to +109°C
1.8V Supply Voltage (VCC1_8) with respect to Vss......................................................1.7V to 1.9V
1.8V Supply Voltage (VccSus1_8) with respect to Vss..................................................1.6V to 1.9V
ICH2-M: 1.8V Supply Voltage (VCCLAN1_8) with respect to Vss...........................1.6V to 1.9V
3.3V Supply Voltage (VCC3_3, VccSus3_3) with respect to Vss .........................3.102V to 3.498V
ICH2-M: 3.3V Supply Voltage (VCCLAN3_3) with respect to Vss...................3.102V to 3.498V
5V Supply Voltage (V5REF, V5REF_Sus) with respect to Vss ................................ 4.75V to 5.25V
V_CPU_IO Voltage with respect to Vss......................................................................................TBD
82801BA ICH2 and 82801BAM ICH2-M Datasheet
16-1
Electrical Characteristics
16.3
D.C. Characteristics
Table 16-1. ICH2-M Power Consumption Measurements
Power Plane
Maximum Sustain Supply Current Icc(max)
S0
S1
S3
S4
S5
1.8V Core
300 mA
100 mA
0
0
0
3.3V I/O
410 mA
5 mA
0
0
0
1.8V LAN
30 mA
23 mA
6 mA
6 mA
6 mA
186 mA
180 mA
3.3V LAN
(LAN + LAN Connect
Component)
1.8V Sus
5 mA
3.3V Sus
15 mA
G3
(ICH2-M)
180 mA; 50 mA when LAN Connect Componenplaced
in reduced power mode (50 MHz clk!5 MHz)
2 mA
(ICH2)
1.8 mA
(ICH2-M)
1.4 mA
1.8 mA
1.8 mA
1.8 mA
1.4 mA
1.4 mA
1.4 mA
VccRTC
4 uA
NOTES:
1. 1.8V and 3.3V LAN Icc(max) in S0 was measured running Full Duplex LAN test.
2. 1.8V SUS Icc(max) in S0 state was measured while running a test that continuously accessed PM registers.
3. 3.3V SUS Icc(max) in S0 state was measured running a concurrency test, in which all 4 USB ports were
exercised.
4. 1.8V Core and 3.3V I/O Icc(max) in S0 state was measured running a test that generated a constant stream
of CPU->PCI writes, with an inverting pattern, causing data lines to switch on every clock.
Table 16-2. DC Characteristic Input Signal Association
Symbol
Associated Signals
PCI Signals: AD[31:0], C/BE[3:0]#, DEVSEL#, FRAME#, IRDY#, TRDY#, STOP#,
PAR, PERR#, PLOCK#, SERR#, REQ[4:0]#
PC/PCI Signals: REQ[A]#/GPIO[0], REQB[#]/REQ[5]#/GPIO[1]
IDE Signals: PDD[15:0], SDD[15:0], PDDREQ, PIORDY, SDDREQ, SIORDY
Interrupt Signals: IRQ[15:14], SERIRQ, PIRQ[D:A]#, PIRQ[H]#,
PIRQ[G:F]#/GPIO[4:3], PIRQ[E]#
VIH1/VIL1
(5V Tolerant)
Legacy Signals: RCIN#, A20GATE
USB Signals: OC[3:0]#.
ICH2 (82801BA):
GPIO Signals: GPIO[7,6,4,3,1,0]
ICH2-M (82801BAM):
GPIO Signals: GPIO[7,4,3,1,0]
Power Management Signals: AGPBUSY#
VIH2/VIL2
16-2
Clock Signals: CLK66, CLK48, CLK14, LAN_CLK, PCICLK
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Electrical Characteristics
Table 16-2. DC Characteristic Input Signal Association (Continued)
Symbol
Associated Signals
LPC/FWH Signals: LDRQ[1:0]#, LAD[3:0]/FWH[3:0].
System Management Signals: SMBALERT#/GPIO[11]
EEPROM Signals: EE_DIN
AC’97 Signals: AC_BITCLK, AC_SDIN[1:0], AC_SYNC
ICH2 (82801BA):
Power Management Signals: PME#, PWRBTN#, RI#, RSM_PWROK, RTCRST#,
THRM#, VRMPWRGD
VIH3/VIL3
GPIO Signals: GPIO[25:24, 13:12, 8]
ICH2-M (82801BAM):
Power Management Signals: BATLOW#, CLKRUN#, PME#, PWRBTN#, RI#,
LAN_PWROK, RTCRST#, THRM#, VRMPWRGD/VGATE
GPIO Signals: GPIO[25, 13:12, 8]
Clock Signals: APICCLK
VIH4/VIL4
SMBus Signals: SMBCLK, SMBDATA
System Management Signals: INTRUDER#, SMLINK[1:0]
VIH5/VIL5
Power Management Signals: RSMRST#, PWROK,
GPIO Signals: GPIO[28:27]
VIL6/VIH6
LAN Signals: LAN_RXD[2:0]
VIL7/VIH7
Processor Signals: FERR#, APICD[1:0]
VIL8/VIH8
Hub Interface Signals: HL[11:0], HL_STB#, HL_STB
VDI / VCM / VSE
VIL9/VIH9
USB Signals: USBP[1:0][P,N]
RTCX1
Table 16-3. DC Input Characteristics
Symbol
Parameter
Min.
Max
Unit
VIL1
Input Low Voltage
-0.5
0.8
V
VIH1
Input High Voltage
2.0
V5REF + 0.5
V
VIL2
Input Low Voltage
-0.5
0.8
V
VIH2
Input High Voltage
2.0
Vcc3_3 + 0.5
V
VIL3
Input Low Voltage
-0.5
0.3Vcc3_3
V
VIH3
Input High Voltage
0.5Vcc3_3
Vcc3_3 + 0.5
V
VIL4
Input Low Voltage
-0.5
0.7
V
VIH4
Input High Voltage
1.7
2.625
V
VIL5
Input Low Voltage
-0.5
0.6
V
VIH5
Input High Voltage
2.1
VccSus3_3 + 0.5
V
VIL6
Input Low Voltage
-0.5
0.3Vcc3_3
V
VIH6
Input High Voltage
0.6Vcc3_3
Vcc3_3 + 0.5
V
VIL7
Input Low Voltage
-0.5
0.6
V
VIH7
Input High Voltage
1.2
Vcc3_3 + 0.5
V
VIL8
Input Low Voltage
-0.5
HUBREF - 0.15
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Notes
Normal Mode
V
HUBREF - 0.20
Enhanced Mode
16-3
Electrical Characteristics
Table 16-3. DC Input Characteristics
Symbol
Parameter
Min.
Max
Unit
Vcc1_8 + 0.5
V
HUBREF + 0.15
VIH8
Input High Voltage
VDI
Differential Input
Sensitivity
0.2
VCM
Differential Common
Mode Range
0.8
VSE
Single-Ended
Receiver Threshold
VIL9
VIH10
Notes
Normal Mode
HUBREF + 0.20
Enhanced Mode
V
Note 1
2.5
V
Note 2
0.8
2.0
V
Input Low Voltage
-0.5
0.10
V
Input High Voltage
0.40
2.0
V
NOTES:
1. VDI = | USBPx[P] - USBPx[N] |
2. Includes VDI range.
Table 16-4. DC Characteristic Output Signal Association
Symbol
Associated Signals
VOH1/VOL1
IDE Signals: PDD[15:0], SDD[15:0], PDIOW#/PDSTOP, SDIOW#/SDSTOP, PDIOR#/
PDWSTB/PRDMARDY, SDIOR#/STWSTB/SRDMARDY, PDDACK#, SDDACK#,
PDA[2:0], SDA[2:0], PDCS[3,1]#, SDCS[3,1]#
VOH2/VOL2
Processor Signals: A20M#, CPUPWRGD, CPUSLP#, IGNNE#, INIT#, INTR, NMI,
SMI#, STPCLK#
VOH3/VOL3
PCI Signals: AD[31:0], C/BE[3:0]#, PCIRST#, GNT[4:0]#, PAR, DEVSEL#, PERR#,
PLOCK#, STOP#, TRDY#, IRDY#, FRAME#, SERR#
Interrupt Signals: SERIRQ, PIRQ[D:A]#, PIRQ[H]#, PIRQ[G:F]#/GPIO[4:3], PIRQ[E]#
PCI Signals: GNT5#/GNTB#/GPIO17, GNTA#/GPIO16
LPC/FWH Signals: LAD[3:0]/FWH[3:0], LFRAME#/FWH[4]
AC’97 Signals: AC_RST#, AC_SDOUT, AC_SYNC
VOH4/VOL4
LAN Signals: LAN_RSTSYNC, LAN_TXD[2:0]
ICH2 (82801BA):
Power Management Signals: PME#
GPIO Signals: GPIO[21]
ICH2-M (82801BAM):
Power Management Signals: PME#, C3_STAT#
SMBus Signals: SMBCLK, SMBDATA
VOL5/VOH5
System Management Signals: SMLINK[1:0]
Interrupt Signals: APICD[1:0]
EEPROM Signals: EE_CS, EE_DOUT, EE_SHCLK
Other Signals: SPKR]
ICH2 (82801BA):
VOL6/VOH6
Power Management Signals: SLP_S3#, SLP_S5#, SUS_STAT#, SUSCLK
GPIO Signals: GPIO[25:22, 20:18]
ICH2-M (82801BAM):
GPIO Signals: GPIO[25]
16-4
VOL7/VOH7
USB Signals: USBPO[P:N], USBP1[P:N]
VOL8/VOH8
Hub Signals: HL[11:0], HL_STB#, HL_STB
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Electrical Characteristics
Table 16-5. DC Output Characteristics
Symbol
Parameter
VOL1
Output Low Voltage
VOH1
Output High Voltage
VOL2
Output Low Voltage
VOH2
Output High Voltage
VOL3
Output Low Voltage
VOH3
Output High Voltage
VOL4
Output Low Voltage
VOH4
Output High Voltage
VOL5
Output Low Voltage
VOH5
Output High Voltage
VOL6
Output Low Voltage
VOH6
Output High Voltage
VOL7
Output Low Voltage
VOH7
Output High Voltage
VOL8
Output Low Voltage
VOH8
Output High Voltage
Min.
Max
Unit
IOL / IOH
0.5
V
4 mA
V
-0.4 mA
V
4.0 mA
V
-0.5 mA
V
6 mA
V
-2 mA
V
1.5 mA
V
-0.5 mA
V
3.0 mA
2.4
0.4
V_CPU_IO - 0.13V
0.55
2.4
0.1Vcc
0.9Vcc
0.4
N/A
V
0.4
Notes
Note 1
Note 1
Note 1
Note 1
V
4.0 mA
V
-2.0 mA
V
5 mA
V
-2 mA
0.1(Vcc1_8)
V
1 mA
Normal Mode
0.8
V
20 mA
Enhanced Mode
0.9(Vcc1_8)
V
-1 mA
Normal Mode
1.6
V
-1.5 mA
Vcc3_3 - 0.5
0.4
Vcc - 0.5
Note 1
Enhanced Mode
NOTES:
1. The CPUPWRGD, SERR#, PIRQ[A:H], PME#, GPIO22/CPUPERF, APIC[1:0], SMBDATA, SMBCLK and
SMLINK[1:0] signals have an open drain driver, and the VOH specification does not apply. These signals
must have external pull-up resistors.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
16-5
Electrical Characteristics
Table 16-6. Other DC Characteristics
Symbol
Parameter
Min.
Max
Unit
Notes
VBIAS
Voltage BIAS
0.32
0.44
V
V5REF
ICH2 Core Well Reference Voltage
4.75
5.25
V
VCC3_3
I/O Buffer Voltage
3.102
3.498
V
VCC1_8
Internal Logic Voltage
1.7
1.9
V
0.48(Vcc1.8)
0.52(Vcc1.8)
V
Normal Mode
HUBREF
Hub Interface Reference Voltage
0.64(Vcc1.8)
0.70(Vcc1.8)
V
Enhanced Mode
V5REF_Sus
Suspend Well Reference Voltage
4.75
5.25
V
VccSus3_3
Suspend Well I/O Buffer Voltage
3.102
3.498
V
VccSus1_8
Suspend Well Logic Voltage
1.6
1.9
V
VccLAN3_3
(ICH2-M)
LAN Controller I/O Buffer Voltage
3.102
3.498
V
VccLAN1_8
(ICH2-M)
LAN Controller Logic Voltage
1.7
1.9
V
Battery Voltage
2.0
3.6
V
VIT+
Hysteresis Input Rising Threshold
1.9
VIT-
Hysteresis Input Falling Threshold
Vcc(RTC)
1.3
V
Applied to
USBP[3:0][P:N]
V
Applied to
USBP[3:0]P:N]
VDI
Differential Input Sensitivity
0.2
V
|(USBPx+,USBPx-)|
VCM
Differential Common Mode Range
0.8
2.5
V
Includes VDI
VCRS
Output Signal Crossover Voltage
1.3
2.0
V
VSE
Single Ended Rcvr Threshold
0.8
2.0
V
ILI1
Input Leakage Current
-1.0
+1.0
uA
ILI2
Hi-Z State Data Line Leakage
-10
+10
uA
(0 V< VIN< 3.3V)
ILI3
Input Leakage Current - Clock
signals
-100
+100
uA
See Note
pF
FC = 1 MHz
CIN
COUT
CI/O
CL
Input Capacitance - Hub interface
8
Input Capacitance - All Other
12
Output Capacitance
12
pF
FC = 1 MHz
12
pF
FC = 1 MHz
15
pF
I/O Capacitance
Crystal Load Capacitance
7.5
NOTE: Includes APICCLK, CLK14, CLK48, CLK66, LAN_CLK and PCICLK
16-6
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Electrical Characteristics
16.4
A.C. Characteristics
Table 16-7. Clock Timings
Sym
Parameter
Min
Max
Unit
Notes
Figure
33.3
ns
16-2
ns
16-2
PCI Clock (PCICLK)
t1
Period
30
t2
High Time
12
t3
Low Time
12
ns
16-2
t4
Rise Time
3
ns
16-2
t5
Fall Time
3
ns
16-2
70
ns
16-2
Oscillator Clock (OSC)
t6
Period
67
t7
High Time
20
t8
Low time
20
16-2
ns
16-2
USB Clock (USBCLK)
fclk48
Operating Frequency
t9
Frequency Tolerance
48
MHz
t10
High Time
7
ns
16-2
t11
Low time
7
ns
16-2
t12
Rise Time
1.2
ns
16-2
t13
Fall Time
1.2
ns
16-2
2500
ppm
1
Suspend Clock (SUSCLK)
fsusclk
Operating Frequency
32
KHz
5
t14
High time
10
us
5
16-2
t15
Low Time
10
us
5
16-2
2
16-17
SMBus Clock (SMBCLK)
fsmb
Operating Frequency
10
16
KHz
t18
High time
4.0
50
us
t19
Low time
4.7
t20
Rise time
t21
Fall time
us
16-17
1000
ns
16-17
300
ns
16-17
14.32
33.33
MHz
I/O APIC Clock (APICCLK)
fioap
Operating Frequency
t22
High time
12
36
ns
16-2
t23
Low time
12
36
ns
16-2
t24
Rise time
1.0
5.0
ns
16-2
t25
Fall time
1.0
5.0
ns
16-2
82801BA ICH2 and 82801BAM ICH2-M Datasheet
16-7
Electrical Characteristics
Table 16-7. Clock Timings (Continued)
Sym
Parameter
Min
Max
Unit
Notes
Figure
AC’97 Clock (BITCLK)
fac97
Operating Frequency
12.288
t26
Output Jitter
750
t27
High time
32.56
48.84
ns
t28
Low time
32.56
48.84
ns
t29
Rise time
2.0
6.0
ns
4
16-2
t30
Fall time
2.0
6.0
ns
4
16-2
16-2
16-2
Hub Interface Clock
fhl
Operating Frequency
t31
High time
6.0
66
ns
16-2
t32
Low time
6.0
ns
16-2
t33
Rise time
0.25
1.2
ns
16-2
t34
Fall time
0.25
1.2
ns
t35
CLK66 leads PCICLK
1.0
4.5
16-2
3
NOTES:
1. The USBCLK is a 48 MHz that expects a 40/60% duty cycle.
2. The maximum high time (t18 Max) provide a simple guaranteed method for devices to detect bus idle
conditions.
3. This specification includes pin-to-pin skew from the clock generator as well as board skew.
4. BITCLK Rise and Fall times are measured from 10%VDD and 90%VDD.
5. SUSCLK duty cycle can range from 30% minimum to 70% maximum.
16-8
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Electrical Characteristics
Table 16-8. PCI Interface Timing
Sym
t40
Parameter
AD[31:0] Valid Delay
Min
Max
Units
Notes
2
11
ns
Min: 0pF
Max: 50pF
Figure
16-3
t41
AD[31:0] Setup Time to PCICLK Rising
7
ns
16-4
t42
AD[31:0] Hold Time from PCICLK Rising
0
ns
16-4
t43
C/BE[3:0]#, FRAME#, TRDY#, IRDY#, STOP#,
PAR, PERR#, PLOCK#, DEVSEL# Valid Delay
from PCICLK Rising
2
t44
C/BE[3:0]#, FRAME#, TRDY#, IRDY#, STOP#,
PAR, PERR#, PLOCK#, IDSEL, DEVSEL# Output
Enable Delay from PCICLK Rising
2
t45
C/BE[3:0]#, FRAME#, TRDY#, IRDY#, STOP#,
PERR#, PLOCK#, DEVSEL#, GNT[A:B]# Float
Delay from PCICLK Rising
2
t46
C/BE[3:0]#, FRAME#, TRDY#, IRDY#, STOP#,
SERR#, PERR#, DEVSEL#, Setup Time to
PCICLK Rising
t47
11
ns
Min: 0pF
Max: 50pF
16-3
ns
16-7
ns
16-5
7
ns
16-4
C/BE[3:0]#, FRAME#, TRDY#, IRDY#, STOP#,
SERR#, PERR#, DEVSEL#, REQ[A:B]# Hold
Time from PCLKIN Rising
0
ns
16-4
t48
PCIRST# Low Pulse Width
1
ms
16-6
t49
GNT[A:B}#, GNT[5:0]# Valid Delay from PCICLK
Rising
2
t50
REQ[A:B]#, REQ[5:0]# Setup Timer to PCICLK
Rising
12
82801BA ICH2 and 82801BAM ICH2-M Datasheet
28
12
ns
ns
16-9
Electrical Characteristics
Table 16-9. IDE PIO & Multiword DMA Mode Timing
Sym
Parameter
Min
Max
Units
Notes
Figure
t60
PDIOR#/PDIOW#/SDIOR#/SDIOW# Active From
CLK66 Rising
2
20
ns
16-8, 16-9
t61
PDIOR#/PDIOW#/SDIOR#/SDIOW# Inactive From
CLK66 Rising
2
20
ns
16-8, 16-9
t62
PDA[2:0]/SDA[2:0] Valid Delay From CLK66 Rising
2
30
ns
16-8
t63
PDCS1#/SDCS1#, PDCS3#/SDCS3# Active From
CLK66 Rising
2
30
ns
16-8
t64
PDCS1#/SDCS1#, PDCS3#/SDCS3# Inactive From
CLK66 Rising
2
30
ns
16-8
t65
PDDACK#/SDDACK# Active From CLK66 Rising
2
20
ns
16-9
t66
PDDACK#/SDDACK# Inactive From CLK66 Rising
2
20
ns
t67
PDDREQ/SDDREQ Setup Time to CLK66 Rising
7
ns
16-9
t68
PDDREQ/SDDREQ Hold From CLK66 Rising
7
ns
16-9
t69
PDD[15:0]/SDD[15:0] Valid Delay From CLK66
Rising
2
ns
16-8, 16-9
t70
PDD[15:0]/SDD[15:0] Setup Time to CLK66 Rising
10
ns
16-8, 16-9
t71
PDD[15:0]/SDD[15:0] Hold From CLK66 Rising
7
ns
16-8, 16-9
t72
PIORDY/SIORDY Setup Time to CLK66 Rising
7
ns
1
16-8
t73
PIORDY/SIORDY Hold From CLK66 Rising
7
ns
1
16-8
t74
PIORDY/SIORDY Inactive Pulse Width
48
ns
t75
PDIOR#/PDIOW#/SDIOR#/SDIOW# Pulse Width
Low
2,3
16-8, 16-9
t76
PDIOR#/PDIOW#/SDIOR#/SDIOW# Pulse Width
High
3,4
16-8, 16-9
30
16-8
NOTES:
1. IORDY is internally synchronized. This timing is to guarantee recognition on the next clock.
2. PIORDY sample point from DIOx# assertion and PDIOx# active pulse width is programmable from 2-5 PCI
clocks when the drive mode is Mode 2 or greater. Refer to the ISP field in the IDE Timing Register
3. PIORDY sample point from DIOx# assertion, PDIOx# active pulse width and PDIOx# inactive pulse width
cycle time is the compatible timing when the drive mode is Mode 0/1. Refer to the TIM0/1 field in the IDE
timing register.
4. PDIOx# inactive pulse width is programmable from 1-4 PCI clocks when the drive mode is Mode 2 or greater.
Refer to the RCT field in the IDE Timing Register.
16-10
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Electrical Characteristics
Table 16-10. Ultra ATA Timing (Mode 0, Mode 1, Mode 2)
Sym
Parameter (1)
Mode 0 (ns)
Mode 1 (ns)
Mode 2 (ns)
Min
Min
Min
Figure
Max
240
Max
160
Max
t80
Sustained Cycle Time (T2cyctyp)
t81
Cycle Time (Tcyc)
112
73
54
16-11
t82
Two Cycle Time (T2cyc)
230
154
115
16-11
t83
Data Setup Time (Tds)
15
10
7
16-11
t84
Data Hold Time (Tdh)
5
5
5
16-11
t85
Data Valid Setup Time (Tdvs)
70
48
30
16-11
t86
Data Valid Hold Time (Tdvh)
6
6
6
16-11
150
0
120
t87
Limited Interlock Time (Tli)
0
t88
Interlock Time w/ Minimum (Tmli)
20
150
t89
Envelope Time (Tenv)
20
t90
Ready to Pause Time (Trp)
160
125
100
16-12
t91
DMACK setup/hold Time (Tack)
20
20
20
16-10,
16-13
20
70
0
150
20
20
70
16-13
16-13
20
70
16-10
NOTE:
1. The specification symbols in parentheses correspond to the Ultra ATA specification name.
Table 16-11. Ultra ATA Timing (Mode 3, Mode 4, Mode 5)
Sym
Parameter (1)
Mode 3 (ns)
Mode 4 (ns)
Mode 5 (ns)
Min
Min
Min
Figure
Max
90
Max
60
Max
t80
Sustained Cycle Time (T2cyctyp)
t81
Cycle Time (Tcyc) (2)
39
25
16.8
16-11
t82
Two Cycle Time (T2cyc)
86
57
38
16-11
t83
Data Setup Time (Tds)
7
5
4.0
16-11
t84
Data Hold Time (Tdh)
5
5
4.6
16-11
t85
Data Valid Setup Time (Tdvs)
20
6
3.3
16-11
t86
Data Valid Hold Time (Tdvh)
6
6
3.3
16-11
t87
Limited Interlock Time (Tli)
0
100
0
55
20
40
100
0
75
16-13
20
16-13
55
20
50
16-10
t88
Interlock Time w/ Minimum (Tmli)
20
t89
Envelope Time (Tenv)
20
t90
Ready to Pause Time (Trp)
100
100
85
16-12
t91
DMACK setup/hold Time (Tack)
20
20
20
16-10,
16-13
82801BA ICH2 and 82801BAM ICH2-M Datasheet
20
16-11
Electrical Characteristics
Table 16-12. Universal Serial Bus Timing
Sym
Parameter
Min
Max
Units
Notes
Fig
Full Speed Source (Note 7)
t100
USBPx+, USBPx- Driver Rise Time
4
20
ns
1, CL = 50 pF
16-14
t101
USBPx+, USBPx- Driver Fall Time
4
20
ns
1, CL = 50 pF
16-14
-2
-1
2
1
ns
ns
2, 3
16-15
160
175
ns
4
16-16
-2
5
ns
5
-20
-10
20
10
ns
ns
3
16-15
ns
ns
4
16-16
ns
5
300
ns
ns
1, 6
CL = 50 pF
CL = 350 pF
16-14
300
ns
ns
1,6
CL = 50 pF
CL = 350 pF
16-14
-2
-1
2
1
ns
ns
2, 3
16-15
160
175
ns
4
16-16
Source Differential Driver Jitter
t102
To Next Transition
For Paired Transitions
t103
Source EOP Width
t104
Differential to SE0 Transition Skew
Receiver Data Jitter Tolerance
t105
To Next Transition
For Paired Transitions
t106
t107
EOP Width: Must reject as EOP
EOP Width: Must accept as EOP
40
85
Differential to SE0 Transition Skew
-2
5
Low Speed Source (Note 8)
t108
USBPx+, USBPx- Driver Rise Time
t109
USBPx+, USBPx- Driver Fall Time
75
75
Source Differential Driver Jitter
t110
To Next Transition
For Paired Transitions
t111
Source EOP Width
t112
Differential to SE0 Transition Skew
-2
5
ns
5
t113
Receiver Data Jitter Tolerance
To Next Transition
For Paired Transitions
-20
-10
20
10
ns
ns
3
16-15
t114
EOP Width: Must reject as EOP
EOP Width: Must accept as EOP
40
85
ns
ns
4
16-16
t115
Differential to SE0 Transition Skew
-2
ns
5
5
NOTES:
1. Driver output resistance under steady state drive is specified at 28 ohms at minimum and 43 ohms at
maximum
2. Timing difference between the differential data signals
3. Measured at crossover point of differential data signals
4. Measured at 50% swing point of data signals
5. Measured from last crossover point to 50% swing point of data line at leading edge of EOP
6. Measured from 10% to 90% of the data signal
7. Full Speed Data Rate has minimum of 11.97 Mbps and maximum of 12.03 Mbps
8. Low Speed Data Rate has a minimum of 1.48 Mbps and a maximum of 1.52 Mbps
16-12
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Electrical Characteristics
Table 16-13. IOAPIC Bus Timing
Sym
Parameter
Min
Max
12.0
Units
Notes
Fig
t120
APICCD[1:0]# Valid Delay from APICCLK Rising
3.0
ns
16-3
t121
APICCD[1:0]# Setup Time to APICCLK Rising
8.5
ns
16-4
t122
APICCD[1:0]# Hold Time from APICCLK Rising
3.0
ns
16-4
Table 16-14. SMBus Timing
Sym
Parameter
Min
Max
Units
Notes
Fig
t130
Bus Tree Time Between Stop and Start Condition
4.7
us
16-17
t131
Hold Time after (repeated) Start Condition. After this
period, the first clock is generated.
4.0
us
16-17
t132
Repeated Start Condition Setup Time
4.7
us
16-17
t133
Stop Condition Setup Time
4.0
us
16-17
t134
Data Hold Time
300
ns
16-17
t135
Data Setup Time
250
ns
16-17
t136
Device Time Out
25
35
ms
1
t137
Cumulative Clock Low Extend Time (slave device)
25
ms
2
16-18
t138
Cumulative Clock Low Extend Time (master device)
10
ms
3
16-18
NOTES:
1. A device will time out when any clock low exceeds this value.
2. t137 is the cumulative time a slave device is allowed to extend the clock cycles in one message from the
initial start to stop. If a slave device exceeds this time, it is expected to release both its clock and data lines
and reset itself.
3. t138 is the cumulative time a master device is allowed to extend its clock cycles within each byte of a
message as defined from start-to-ack, ack-to-ack or ack-to-stop.
Table 16-15. AC’97 Timing
Sym
Parameter
Min
Max
Units
t140
ACSDIN[0:1] Setup to Falling Edge of BITCLK
15
ns
t141
ACSDIN[0:1] Hold from Falling Edge of BITCLK
5
ns
t142
ACSYNC, ACSDOUT valid delay from rising edge of
BITCLK
82801BA ICH2 and 82801BAM ICH2-M Datasheet
15
ns
Notes
Fig
16-3
16-13
Electrical Characteristics
Table 16-16. LPC Timing
Sym
Parameter
Min
Max
Units
Notes
Fig
11
ns
16-3
ns
16-7
ns
16-5
7
ns
16-4
t150
LAD[3:0] Valid Delay from PCICLK Rising
2
t151
LAD[3:0] Output Enable Delay from PCICLK Rising
2
t152
LAD[3:0] Float Delay from PCICLK Rising
t153
LAD[3:0] Setup Time to PCICLK Rising
t154
LAD[3:0] Hold Time from PCICLK Rising
0
ns
16-4
t155
LDRQ[1:0]# Setup Time to PCICLK Rising
12
ns
16-4
t156
LDRQ[1:0]# Hold Time from PCICLK Rising
0
ns
16-4
t157
LFRAME# Valid Delay from PCICLK Rising
2
ns
16-3
28
12
Table 16-17. Miscellaneous Timings
Sym
Parameter
Min
Max
Units
Notes
Fig
t160
SERIRQ Setup Time to PCICLK Rising
7
ns
16-4
t161
SERIRQ Hold Time from PCICLK Rising
0
ns
16-4
t162
RI#, EXTSMI#, GPI, USB Resume Pulse Width
2
RTCCLK
16-6
t163
SPKR Valid Delay from OSC Rising
200
ns
16-3
t164
SERR# Active to NMI Active
200
ns
t165
IGNNE# Inactive from FERR# Inactive
230
ns
Table 16-18. Power Sequencing and Reset Signal Timings
Sym
Min
Max
Units
Notes
Fig
16-18,
16-19
t170
VccRTC active to RTCRST# inactive
5
-
ms
t171
V5RefSus active to VccSus3_3, VccSus1_8
active
0
-
ms
1, 2
16-18,
16-19
t172
VccRTC supply active to VccSus supplies
active
0
-
ms
3
16-18,
16-19
t173
(ICH2)
VccSus supplies active to RSM_PWROK
active, RSMRST# inactive
10
-
ms
16-18,
16-21
VccSus supplies active to RSMRST# inactive
5
-
ms
16-19
16-22
V5Ref active to Vcc3_3, Vcc1_8 active
0
-
ms
1, 2
16-18,
16-19
VccSus supplies active to Vcc supplies active
0
-
ms
3
16-18
t175a
(ICH2-M)
VccSus supplies active to VccLAN supplies
active
0
-
ms
t175b
(ICH2-M)
VccLAN supplies active to LAN_PWROK
active
10
-
ms
16-19
16-20
t175c
(ICH2-M)
VccLAN supplies active to Vcc supplies active
0
-
ms
16-19
t173
(ICH2-M)
t174
t175
(ICH2)
16-14
Parameter
3
16-19
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Electrical Characteristics
Table 16-18. Power Sequencing and Reset Signal Timings (Continued)
Sym
Parameter
Min
Max
Units
t176
(ICH2)
Vcc supplies active to PWROK, VRMPWRGD
active
10
-
ms
16-18,
16-21,
16-25
t176
(ICH2-M)
Vcc supplies active to PWROK, VGATE active
10
-
ms
16-19
16-20
16-22
t177
PWROK, VRMPWRGD active to SUS_STAT#
inactive
32
34
RTCCLK
16-18,
16-21
16-25
t177
PWROK, VGATE active to SUS_STAT#
inactive
32
34
RTCCLK
16-18
16-20
16-22
RTCCLK
16-18,
16-19
16-21,
16-22
16-25,
16-26
t178
SUS_STAT# inactive to PCIRST# inactive
1
3
t179
AC_RST# active low pulse width
1
us
t180
AC_RST# inactive to BIT_CLK startup delay
162.8
ns
Notes
Fig
NOTES:
1. The V5Ref supply must power up before or simultaneous with its associated 3.3V supply, and must power
down simultaneous with or after the 3.3V supply. See Section 2.20.4 for details.
2. The associated 3.3V and 1.8V supplies are assumed to power up or down together. The difference between
the levels of the 3.3V and 1.8V supplies must never be greater than 2.0V.
3. 82801BA ICH2: The VccSus supplies must never be active while the VccRTC supply is inactive. Likewise,
the Vcc supplies must never be active while the VccSus supplies are inactive.
4. 82801BAM ICH2-M: The VccSus supplies must never be active while the VccRTC supply is inactive.
Likewise, the Vcc or VccLAN supplies must never be active while the VccSus supplies are inactive, and the
Vcc supplies must never be active while the VccLAN supplies are inactive.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
16-15
Electrical Characteristics
Table 16-19. Power Management Timings
Sym
Min
Max
Units
Notes
Fig
t181
VccSus active to SLP_S3#, SLP_S5#,
SUS_STAT# and PCIRST# active
50
ns
t182
t183
RSMRST# inactive to SUSCLK running,
SLP_S3#, SLP_S5# inactive
110
ms
Vcc active to STPCLK#, CPUSLP#, inactive,
and processor Frequency Strap signals high
50
ns
16-21,
16-25
t184
(ICH2-M)
Vcc active to STPCLK#, CPUSLP#,
STP_CPU#, STP_PCI#, SLP_S1, C3_STAT#
inactive, and CPU Frequency Strap signals high
50
ns
16-20
16-22
t185
PWROK and VRMPWRGD active to
SUS_STAT# inactive and processor Frequency
Straps latched to Strap Values
32
34
RTCCLK
1
16-21,
16-22
t186
Processor Reset Complete to Frequency Strap
signals unlatched from Strap Values
7
9
CLK66
2
16-21,
16-22
t187
STPCLK# active to Stop Grant cycle
N/A
N/A
3
16-23,
16-24
16-25,
16-26
t188
(ICH2)
Stop Grant cycle to CPUSLP# active
60
63
PCICLK
4
16-25,
16-25
t188a
(ICH2-M)
Stop Grant cycle to C3_STAT# active
0
6
PCICLK
t188b
(ICH2-M)
C3_STAT# active to CPUSLP# active
2.8
t189
(ICH2)
S1 Wake Event to CPUSLP# inactive
1
25
PCICLK
t184
(ICH2)
16-21,
16-22
16-21,
16-22
7
4
CPUSLP# inactive to STPCLK# inactive
204
237
us
t192
(ICH2)
CPUSLP# active to SUS_STAT# active
2
4
RTCCLK
t192a
(ICH2-M)
CPUSLP# active to STP_CPU# active
16
t192b
(ICH2-M)
STP_CPU# active to SUS_STAT# active
2
t193
(ICH2)
SUS_STAT# active to PCIRST# active
t193a
(ICH2-M)
16-23,
16-26,
16-28
16-23,
16-26,
16-28
us
t190
4
16-23
16-23,
16-25
1
16-25
PCICLK
4
16-23,
16-26,
16-28
4
RTCCLK
1
16-23,
16-26,
9
15
RTCCLK
SUS_STAT# active to STP_PCI# active
2
4
RTCCLK
1
16-23,
16-26,
t193b
(ICH2-M)
STP_PCI# active to SLP_S1# active
2
4
RTCCLK
1
16-23,
16-26,
t193c
(ICH2-M)
SLP_S1# active to PCIRST# active, STP_PCI#
inactive, SLP_S1# inactive, and STP_CPU#
inactive
5
7
RTCCLK
1
16-23,
16-26,
PCIRST# active to SLP_S3# active
1
2
RTCCLK
t194
16-16
Parameter
1
1
16-25
16-25,
16-26
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Electrical Characteristics
Table 16-19. Power Management Timings
Sym
Parameter
Min
Max
Units
2
RTCCLK
Notes
Fig
1, 6
16-25,
16-26
5
16-25,
16-26
t195
SLP_S3# active to SLP_S5# active
1
t196
SLP_S3# active to VRMPWRGD (VRMPWRGD
/ VGATE for ICh2-M) inactive
0
ms
t196a
SLP_S3# active to PWROK
100
us
16-25,
16-26
t197
PWROK, VRMPWRGD inactive to Vcc supplies
inactive
20
ns
16-25,
16-26
t198
Wake Event to SLP_S3#, SLP_S5# inactive
1
20
RTCCLK
t198a
(ICH2-M)
Wake Event to SLP_S1# inactive
1
20
RTCCLK
t199
(ICH2-M)
SLP_S1# inactive to STP_CPU#, STP_PCI#
inactive
3
6
ms
16-23,
t200
(ICH2-M)
STP_CPU#, STP_PCI# inactive to SUS_STAT#
inactive
7
10
ms
16-23,
t201
(ICH2-M)
SUS_STAT# inactive to CPU_SLP# inactive
2
4
PCICLK
t203
(ICH2-M)
STPCLK# inactive to C3_STAT# inactive
0
15
ns
t204
Processor I/F signals latched prior to STPCLK#
active
0
4
CLK66
t205
Break Event to STPCLK# inactive
30
3120
ns
16-27
t206
STPCLK# inactive to processor I/F signals
unlatched
240
1880
ns
16-27
t207
(ICH2-M)
Break Event to STP_CPU# inactive
0
8
PCICLK
t208
(ICH2-M)
STP_CPU# inactive to CPU_SLP# inactive
30
45
us
16-25,
16-26
1
1
4
16-23,
16-23,
16-23,
16-28
2
16-27
4
16-28
16-28
NOTES:
1. These transitions are clocked off the internal RTC. One RTC clock is approximately 32 us.
2. This transition is clocked off the 66 MHz CLK66. One CLK66 is approximately 15 ns.
3. The ICH2 STPCLK# assertion will trigger the processor to send a stop grant acknowledge cycle. The timing
for this cycle getting to the ICH2 is dependant on the processor and the memory controller.
4. These transitions are clocked off the 33 MHz PCICLK. 1 PCICLK is approximately 30 ns.
5. The ICH2 has no maximum timing requirement for this transition. It is up to the system designer to determine
if the SLP_S3# and SLP_S5# signals are used to control the power planes.
6. If the transition to S5 is due to Power Button Override, SLP_S3# and SLP_S5# are asserted together
following timing t194 (PCIRST# active to SLP_S3# and SLP_S5# active).
7. If there is no RTC battery in the system, so VccRTC and the VccSus supplies come up together, the delay
from RTCRST# and RSMRST# inactive to SUSCLK toggling may be as much as 1000 ms.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
16-17
Electrical Characteristics
16.5
Timing Diagrams
Figure 16-1. Clock Timing
Period
High Time
2.0V
0.8V
Low Time
Fall Time
Rise Time
Figure 16-2. Valid Delay From Rising Clock Edge
Clock
1.5V
Valid Delay
Output
VT
Figure 16-3. Setup And Hold Times
Clock
1.5V
Setup Time
Input
Hold Time
VT
VT
Figure 16-4. Float Delay
Input
VT
Float
Delay
Output
16-18
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Electrical Characteristics
Figure 16-5. Pulse Width
Pulse Width
VT
VT
Figure 16-6. Output Enable Delay
Clock
1.5V
Output
Enable
Delay
Output
VT
Figure 16-7. IDE PIO Mode
CLK66
t61
t60
t76
t75
DIOx#
t69
t69
write data
DD[15:0] Write
t71
t70
read data
DD[15:0] Read
t73
t72
IORDY
sample point
t74
t62,t63
t64
DA[2:0], CS1#, CS3#
82801BA ICH2 and 82801BAM ICH2-M Datasheet
16-19
Electrical Characteristics
Figure 16-8. IDE Multiword DMA
CLK66
t68
t67
DDREQ[1:0]
t65
DDACK[1:0]
t60
t61
t75
t76
DIOx#
t70
DD[15:0] Read
t71
Read Data
t69
t69
Write Data
DD[15:0] Write
Read Data
Write Data
id d
d
Figure 16-9. Ultra ATA Mode (Drive Initiating a Burst Read)
DMARQ (drive)
t91
DMACK# (host)
t89
STOP (host)
t89
DMARDY# (host)
STROBE (drive)
DD[15:0]
DA[2:0], CS[1:0]
16-20
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Electrical Characteristics
Figure 16-10. Ultra ATA Mode (Sustained Burst)
t82
t81
t81
t85
t85
STROBE @ sender
t86
t86
t86
Data @ sender
t83
t83
STROBE @ receiver
t84
t84
t84
Data @ receiver
Figure 16-11. Ultra ATA Mode (Pausing a DMA Burst)
t90
STOP (host)
DMARDY#
STROBE
DATA
82801BA ICH2 and 82801BAM ICH2-M Datasheet
16-21
Electrical Characteristics
Figure 16-12. Ultra ATA Mode (Terminating a DMA Burst)
DMARQ (drive)
t88
t91
DMACK# (host)
STOP (host)
DMARDY# (drive)
t87
Strobe (host)
DATA (host)
CRC
Figure 16-13. USB Rise and Fall Times
Rise Time
90%
CL
Fall Time
90%
Differential
Data Lines
10%
10%
CL
tR
Full Speed: 4 to 20 ns at
=C50 pF
L
tF
= 50 pF, 300 ns at
=
C350 pF
Low Speed: 75 ns at
L C
L
Figure 16-14. USB Jitter
Tperiod
Crossover
Points
Differential
Data Lines
Consecutive
Transitions
Paired
Transitions
16-22
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Electrical Characteristics
Figure 16-15. USB EOP Width
Tperiod
Data
Crossover
Level
Differential
Data Lines
EOP
Width
Figure 16-16. SMBus Transaction
t19
t20
t21
SMBCLK
t135
t131
t134
t133
t18
t132
SMBDATA
t130
Figure 16-17. SMBus Time-out
Start
Stop
t137
CLKack
t138
CLKack
t138
SMBCLK
SMBDATA
82801BA ICH2 and 82801BAM ICH2-M Datasheet
16-23
Electrical Characteristics
Figure 16-18. Power Sequencing and Reset Signal Timings (82801BA ICH2 only)
PWROK,
VRMPWRGD
T176
Vcc3_3, Vcc1_8,
V_CPU_IO
T175
T174
V5Ref
RSMRST#,
RSM_PWROK
VccSus3_3,
VccSus1_8
T173
T172
T171
V5RefSus
RTCRST#
T170
VccRTC
ich2_powerup_reset_DT.vsd
Figure 16-19. Power Sequencing and Reset Signal Timings (82801BAM ICH2-M only)
PWROK,
VGATE
Vcc3_3, Vcc1_8,
V_CPU_IO
T175c
T176
T174
V5Ref
T175b
LAN_PWROK
VccLAN3_3,
VccLAN1_8
T175a
RSMRST#
VccSus3_3,
VccSus1_8
T173
T172
T171
V5RefSus
RTCRST#
T170
VccRTC
ICH2_Powerup_Reset_MO.vst
16-24
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Electrical Characteristics
Figure 16-20. 1.8V/3.3V Power Sequencing
V
3.3
1.8
Voltage
V
V < 2.0V
t
Time
S
2
Figure 16-21. G3 (Mechanical Off) to S0 Timings (82801BA ICH2 only)
System
State
G3
G3
S5
S5
S0
S0 state
Hub interface "CPU
Reset Complete"
message
STPCLK#,
CPUSLP#
T186
T184
Frequency
Straps
Strap Values
Normal Operation
T185
PCIRST#
T178
T181
SUS_STAT#
T177
PWROK,
VRMPWRGD
T176
Vcc
SLP_S3#
SLP_S5#
T181
T183
Running
SUSCLK
T182
RSMRST#,
RSM_PWROK
T173
VccSus
ICH2_G3_S0_timing_DT1.vst
82801BA ICH2 and 82801BAM ICH2-M Datasheet
16-25
Electrical Characteristics
Figure 16-22. G3 (Mechanical Off) to S0 Timings (82801BAM ICH2-M only)
System
State
Main Battery
Removed (G3)
G3
S5
S5
S0
S0 state
Hub interface "CPU
Reset Complete"
message
STPCLK#, CPUSLP#,
STP_CPU#, STP_PCI#,
SLP_S1#, C3_STAT#
T186
T184
Frequency
Straps
Strap Values
Normal Operation
T185
PCIRST#
T178
T181
SUS_STAT#
T177
PWROK, VGATE,
LAN_PWROK
T175b / T176
Vcc,
VccLAN
SLP_S3#
SLP_S5#
T181
T183
Running
SUSCLK
T182
RSMRST#
T173
VccSus
ICH2 G3 S0 timing MO vsd
Figure 16-23. S0 to S1 to S0 Timings (82801BA ICH2 only)
STATE
S0
S0
S1
S1
S1
S0
S0
STPCLK#
T190
PCI Stop Grant
Cycle
T187
CPUSLP#
T188
T189
Wake Event
ich2_S0_S1D_timing.vsd
16-26
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Electrical Characteristics
Figure 16-24. S0 to S1 to S0 Timings (82801BAM ICH2-M only)
STATE
S0
S0
S1
S1
S1
S0
S0
STPCLK#
T190
PCI Stop Grant
Cycle
T187
T203
C3_STAT#
T188a
CPUSLP#
T188b
T201
STP_CPU#
T192a
T199
SUS_STAT#
T192b
T200
STP_PCI#
T193a
SLP_S1#
T198a
T193b
Wake Event
Figure 16-25. S0 to S5 to S0 Timings (82801BA ICH2 only)
S0
S0
S3
S3
S4/S5
S3/S4/S5
S0
S0
STPCLK#
Stop Grant
C ycle
T 184
T 187
C PU SLP#
T 188
SUS_ST AT #
T 192
T 177
PCIR ST #
T 193
T 178
SLP_S3#
T194
T 198
SLP_S5#
T 195
W ake Event
VRM PW R G D
T 196
T 176
PW R OK
T 196a
T 176
Vcc
T 197
82801BA ICH2 and 82801BAM ICH2-M Datasheet
16-27
Electrical Characteristics
Figure 16-26. S0 to S5 to S0 Timings (82801BAM ICH2-M only)
S0
S0
S3
S3
S4/S5
S3/S4/S5
S0
S0
STPC LK#
Stop G rant
C ycle
T 184
T 187
C 3_ST AT#
T1 88 a
C PU SLP#
T1 88 b
STP_C PU #
T1 92 a
T 177
SUS_STAT #
T1 92 b
SLP_S1#
T1 93 a
STP_PCI#
T1 93 b
T 178
PCIR ST #
T1 93 c
SLP_S3#
T1 94
T 198
SLP_S5#
T 195
W ake Event
VG AT E
T 196
T 176
PW R O K
T 196a
T 176
Vcc
T 197
Figure 16-27. C0 to C2 to C0 Timings
CPU I/F
Signals
Unlatched
Latched
Unlatched
STPCLK#
Break
Event
T204
T205
T206
ICH2 C0 C2 Ti i
16-28
d
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Electrical Characteristics
Figure 16-28. C0 to C3 to C0 Timings (82801BAM ICH2-M only)
CPU I/F Unlatched
Signals
Latched
Unlatched
STPCLK#
PCI Stop
Grant Cycle
T190
T204
T206
C3_STAT#
T203
T188a
CPU_SLP#
T208
T188b
STP_CPU#
Break
Event
T192a
T207
82801BA ICH2 and 82801BAM ICH2-M Datasheet
ICH2_C0_C3_Timing.vsd
16-29
Electrical Characteristics
This page is intentionally left blank.
16-30
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Testability
17
Testability
17.1
Test Mode Description
The ICH2 supports two types of test modes, a tri-state test mode and a XOR Chain test mode.
Driving RTCRST# low for a specific number of PCI clocks while PWROK is high activates a
particular test mode as described in Table 17-1.
Note:
RTCRST# can be driven low any time after PCIRST# is inactive.
.
Table 17-1. Test Mode Selection
Number of PCI Clocks RTCRST# driven low after
PWROK active
Test Mode
<4
No Test Mode Selected
4
XOR Chain 1
5
XOR Chain 2
6
XOR Chain 3
7
XOR Chain 4
8
All “Z”
9 - 24
Reserved. DO NOT ATTEMPT
>24
No Test Mode Selected
Figure 17-1 illustrates the entry into a test mode. A particular test mode is entered upon the rising
edge of the RTCRST# after being asserted for a specific number of PCI clocks while PWROK is
active. To change test modes, the same sequence should be followed again. To restore the ICH2 to
normal operation, execute the sequence with RTCRST# being asserted so that no test mode is
selected as specified in Table 17-1.
Figure 17-1. Test Mode Entry (XOR Chain Example)
RSMRST#
PWROK
RTCRST#
Other Signal
Outputs
82801BA ICH2 and 82801BAM ICH2-M Datasheet
N Number of PCI Clocks
All Output Signals Tri-Stated
Test Mode Entered
XOR Chain Output Enabled
17-1
Testability
17.2
Tri-state Mode
When in the tri-state mode, all outputs and bi-directional pin are tri-stated, including the XOR
Chain outputs.
17.3
XOR Chain Mode
In the ICH2, provisions for Automated Test Equipment (ATE) board level testing are implemented
with XOR Chains. The ICH2 signals are grouped into four independent XOR chains which are
enabled individually. When an XOR chain is enabled, all output and bi-directional buffers within
that chain are tri-stated, except for the XOR chain output. Every signal in the enabled XOR chain
(except for the XOR chain’s output) functions as an input. All output and bi-directional buffers for
pins not in the selected XOR chain are tri-stated. Figure 17-2 is a schematic example of XOR chain
circuitry.
Table 17-3 - Table 17-6 list each XOR chain pin ordering, with the first value being the first input
and the last value being the XOR chain output. Table 17-7 lists the signal pins not included in any
XOR chain.
Figure 17-2. Example XOR Chain Circuitry
Vcc
XOR
Chain
Output
Input
Pin 1
17.3.1
Input
Pin 3
Input
Pin 2
Input
Pin 4
Input
Pin 5
Input
Pin 6
XOR Chain Testability Algorithm Example
XOR chain testing allows motherboard manufacturers to check component connectivity (e.g.,
opens and shorts to VCC or GND). An example algorithm to do this is shown in Table 17-2.
Table 17-2. XOR Test Pattern Example
17-2
Vector
Input
Pin 1
Input
Pin 2
Input
Pin 3
Input
Pin 4
Input
Pin 5
Input
Pin 6
XOR
Output
1
0
0
0
0
0
0
1
2
1
0
0
0
0
0
0
3
1
1
0
0
0
0
1
4
1
1
1
0
0
0
0
5
1
1
1
1
0
0
1
6
1
1
1
1
1
0
0
7
1
1
1
1
1
1
1
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Testability
In this example, Vector 1 applies all "0s" to the chain inputs. The outputs being non-inverting, will
consistently produce a "1" at the XOR output on a good board. One short to Vcc (or open floating
to Vcc) will result in a "0" at the chain output, signaling a defect.
Likewise, applying Vector 7 (all "1s") to the chain inputs (given that there are an even number of
input signals in the chain), will consistently produce a "1" at the XOR chain output on a good
board. One short to Vss (or open floating to Vss) will result in a "0" at the chain output, signaling a
defect. It is important to note that the number of inputs pulled to "1" will affect the expected chain
output value. If the number of chain inputs pulled to "1" is even, then expect "1" at the output. If
the number of chain inputs pulled to "1" is odd, expect "0" at the output.
Continuing with the example in Table 17-2, as the input pins are driven to "1" across the chain in
sequence, the XOR Output will toggle between "0" and "1." Any break in the toggling sequence
(e.g., "1011") will identify the location of the short or open.
17.3.1.1
Test Pattern Consideration for XOR Chain 4
When the ICH2 is operated with the Hub Interface in "Normal" mode (See Section 2.20.1), the
HL_STB and HL_STB# signals must always be driven to complementary logic levels. For
example, if a "1" is driven on HL_STB, then a "0" must be driven on HL_STB# and vice versa.
This will need to be considered in applying test patterns to this chain.
When the ICH2 is operated with the Hub Interface in "Enhanced" mode there are no restrictions on
the values that may be driven onto the HL_STB and HL_STB# signals.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
17-3
Testability
Table 17-3. XOR Chain #1 (RTCRST# Asserted for 4 PCI Clocks while PWROK Active)
Pin Name
Ball #
Notes
Pin Name
Ball #
LAN_TXD0
F3
Top of XOR Chain
REQ2#
T1
LAN_TXD1
F2
2nd signal in XOR
GNT2#
R4
LAN_TXD2
F1
GNT3#
T2
LAN_RXD0
G2
AD26
U1
LAN_RXD1
G1
AD30
T3
LAN_RXD2
H1
AD28
T4
EE_DOUT
J4
AD18
V1
EE_SHCLK
J3
AD22
U3
EE_CS
K4
AD16
V2
EE_DIN
K3
STOP#
W1
C3_STAT#/
GPIO21
(ICH2-M)
L1
PAR
W2
GPIO16 / GNTA#
L2
FRAME#
V3
GPIO1 / REQB# /
REQ5#
L3
AD20
U4
GPIO17 / GNTB# /
GNT5#
L4
AD15
Y1
GNT1#
M1
TRDY#
V4
GNT0#
M2
AD11
W3
GPIO0 / REQA#
M3
AD13
Y2
PIRQH#
M4
AD4
W4
GPIO4 / PIRQG#
N1
AD9
Y3
GPIO3 / PIRQF#
N2
C/BE0#
Notes
GPIO21 (ICH2)
17-4
AA3
PIRQE#
N3
AD2
Y4
PIRQD#
N4
AD6
AB3
PIRQA#
P1
AD3
W5
PIRQB#
P2
AD0
AA4
PIRQC#
P3
AD5
Y5
REQ4#
P4
AD10
W6
GNT4#
R1
AD7
AA5
REQ0#
R2
REQ1#
R3
Last in XOR Chain
XOR Chain #1
AC_SDIN1
W22
OUTPUT
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Testability
Table 17-4. XOR Chain #2 (RTCRST# Asserted for 5 PCI clocks while PWROK Active)
Pin Name
Ball #
Notes
Pin Name
Ball #
AD1
AB4
Top of XOR Chain
LDRQ1#
W13
AD12
Y6
2nd signal in XOR
GPIO27
AB14
AD8
AB5
GPIO28
AA14
SERR#
W7
GPIO8
Y14
AD14
AA6
GPIO12
W14
PERR#
Y7
GPIO13
AB15
C/BE1#
AB6
PCIRST#
AA15
DEVSEL#
AB7
PME#
PLOCK#
AA7
GPIO25
W15
C/BE2#
Y8
SMBCLK
AB16
IRDY#
W8
SMBDATA
AA16
AD17
AA8
SMBALERT# /
GPIO11
AB17
AD19
AB8
RI#
AA17
AB18
Notes
Y15
AD23
Y9
SLP_S5#
AD21
W9
SUSSTAT#
Y17
C/BE3#
AA9
SLP_S3#
W16
AD25
AB9
SUSCLK
AA18
AD27
W10
USBP0P
W17
AD29
Y10
USBP0N
Y18
AD31
AA10
USBP1P
AB19
REQ3#
AB10
USBP1N
AA19
Y11
USBP2P
W18
GPIO6 (ICH2)
AGPBUSY#
(ICH2-M)
GPIO7
AA11
USBP2N
Y19
LFRAME# / FWH4
AB11
USBP3P
AB20
LAD3 / FWH3
AB12
USBP3N
AA20
FS0
AA12
OC0#
W19
LAD0 / FWH0
Y12
OC1#
Y20
LAD1 / FWH1
W12
OC2#
Y21
LAD2 / FWH2
AB13
OC3#
W20
THRM#
AA13
XOR Chain #2
TP0 (ICH2)
LDRQ0#
Y13
82801BA ICH2 and 82801BAM ICH2-M Datasheet
BATLOW#
(ICH2-M)
U20
OUTPUT
17-5
Testability
Table 17-5. XOR Chain #3 (RTCRST# Asserted for 6 PCI Clocks while PWROK Active)
Pin Name
Ball #
Notes
Pin name
Ball #
AC_SDIN0
Y22
Top of XOR Chain
PDD14
H21
PWRBTN#
W21
2nd signal in XOR
PDD0
H19
SMLINK0
U19
PDDREQ
G22
SMLINK1
V20
PDIOW#
G21
AC_SDIN1
W22
PDD15
H20
BATLOW#
(ICH2-M)
U20
PDDACK#
F22
AC_RST#
V22
PDA2
E22
CLKRUN#
(ICH2-M)
V21
IRQ14
F21
AC_SDOUT
P21
SDD6
D22
AC_SYNC
P19
PIORDY
G20
FERR#
R22
PDCS1#
E21
APICD0
P22
PDIOR#
G19
APICD1
N19
PDA0
F20
SERIRQ
N21
SDD8
D21
SPKR
N22
SDD9
C22
PDD6
M21
PDA1
F19
PDD7
M22
SDD7
E20
PDD8
L22
SDD5
C21
Notes
TP0 (ICH2)
GPIO24 (ICH2)
17-6
PDD9
L21
SDD10
D20
PDD5
L20
SDD4
C20
PDD10
K22
PDCS3#
E19
PDD4
K21
SDD11
B20
PDD11
K20
SDD2
D19
PDD13
J20
SDD12
C19
PDD3
J22
SDD3
A20
PDD12
J21
PDD1
H22
PDD2
J19
Last in XOR Chain
XOR Chain #3
RI#
AA17
OUTPUT
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Testability
Table 17-6. XOR Chain #4 (RTCRST# Asserted for 7 PCI Clocks while PWROK Active)
Pin Name
Ball #
Notes
Pin Name
Ball #
Notes
SDD13
A19
Top of XOR Chain
INIT#
C12
SDD1
B19
2nd signal in XOR
SMI#
B12
SDD14
C18
CPUSLP#
A12
SDD0
D18
IGNNE#
A11
SDIOR#
D17
NMI
B11
SDDREQ
B18
INTR
C11
SDIOW#
C17
A20M#
D11
SDD15
A18
STPCLK#
C10
SDA1
D16
HL7
A9
SDDACK#
B17
HL5
A8
IRQ15
C16
HL6
B8
SIORDY
A17
HL4
B7
SDA2
B16
HL8
C8
SDCS3#
D15
HL10
C7
See
Section 17.3.1.1
SDA0
A16
HL_STB#
A7
See
Section 17.3.1.1
SDCS1#
C15
HL_STB
A6
B15
HL9
C6
A15
HL2
A5
D14
HL1
B5
C14
HL0
A4
B14
HL11
C5
SSMUXSEL#
(ICH2-M)
A14
HLCOMP
A3
A20GATE
C13
RCIN#
B13
VRMPWRGD
(ICH2)
VRMPWRGD /
VGATE (ICH2-M)
GPIO18 (ICH2)
STP_PCI#
(ICH2-M)
GPIO19 (ICH2)
SLP_S1#
(ICH2-M)
GPIO20 (ICH2)
STP_CPU#
(ICH2-M)
GPIO22 (ICH2)
CPUPERF#
(ICH2-M)
GPIO23 (ICH2)
CPUPWRGD
Last in XOR Chain
XOR Chain #4
OC0#
W19
OUTPUT
A13
82801BA ICH2 and 82801BAM ICH2-M Datasheet
17-7
Testability
Table 17-7. Signals Not in XOR Chain
Pin Name
17-8
Ball #
Notes
Pin Name
Ball #
RSMRST#
R21
CLK14
M19
PWROK
R20
CLK48
P20
RTCX1
U22
CLK66
D4
RTCX2
T22
APICCLK
N20
VBIAS
T21
PCICLK
W11
RTCRST#
T20
INTRUDER#
T19
LAN_CLK
G3
AC_BITCLK
R19
RSM_PWROK
(ICH2)
LAN_PWROK
(ICH2-M)
Notes
Y16
82801BA ICH2 and 82801BAM ICH2-M Datasheet
I/O Register Index
I/O Register Index
A
Table A-1. ICH2 Fixed I/O Registers
Register Name
Port
EDS Section and Location
Channel 0 DMA Base & Current
Address Register
00h
Section 9.2.1, “DMABASE_CA—DMA Base and Current
Address Registers” on page 9-24
Channel 0 DMA Base & Current
Count Register
01h
Section 9.2.2, “DMABASE_CC—DMA Base and Current
Count Registers” on page 9-25
Channel 1 DMA Base & Current
Address Register
02h
Section 9.2.1, “DMABASE_CA—DMA Base and Current
Address Registers” on page 9-24
Channel 1 DMA Base & Current
Count Register
03h
Section 9.2.2, “DMABASE_CC—DMA Base and Current
Count Registers” on page 9-25
Channel 2 DMA Base & Current
Address Register
04h
Section 9.2.1, “DMABASE_CA—DMA Base and Current
Address Registers” on page 9-24
Channel 2 DMA Base & Current
Count Register
05h
Section 9.2.2, “DMABASE_CC—DMA Base and Current
Count Registers” on page 9-25
Channel 3 DMA Base & Current
Address Register
06h
Section 9.2.1, “DMABASE_CA—DMA Base and Current
Address Registers” on page 9-24
Channel 3 DMA Base & Current
Count Register
07h
Section 9.2.2, “DMABASE_CC—DMA Base and Current
Count Registers” on page 9-25
Channel 0–3 DMA Command
Register
08h
Channel 0–3 DMA Status Register
Section 9.2.4, “DMACMD—DMA Command Register”
on page 9-26
Section 9.2.5, “DMASTS—DMA Status Register” on
page 9-26
Channel 0–3 DMA Write Single
Mask Register
0Ah
Section 9.2.6, “DMA_WRSMSK—DMA Write Single
Mask Register” on page 9-27
Channel 0–3 DMA Channel Mode
Register
0Bh
Section 9.2.7, “DMACH_MODE—DMA Channel Mode
Register” on page 9-27
Channel 0–3 DMA Clear Byte
Pointer Register
0Ch
Section 9.2.8, “DMA Clear Byte Pointer Register” on
page 9-28
Channel 0–3 DMA Master Clear
Register
0Dh
Section 9.2.9, “DMA Master Clear Register” on
page 9-28
Channel 0–3 DMA Clear Mask
Register
0Eh
Section 9.2.10, “DMA_CLMSK—DMA Clear Mask
Register” on page 9-28
Channel 0–3 DMA Write All Mask
Register
0Fh
Section 9.2.11, “DMA_WRMSK—DMA Write All Mask
Register” on page 9-29
Aliased at 00h–0Fh
10h–1Fh
Master PIC ICW1 Init. Cmd Word 1
Register
Master PIC OCW2 Op Ctrl Word 2
Register
Master PIC OCW3 Op Ctrl Word 3
Register
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Section 9.4.2, “ICW1—Initialization Command Word 1
Register” on page 9-34
20h
Section 9.4.8, “OCW2—Operational Control Word 2
Register” on page 9-37
Section 9.4.9, “OCW3—Operational Control Word 3
Register” on page 9-38
A-1
I/O Register Index
Table A-1. ICH2 Fixed I/O Registers (Continued)
Register Name
Port
Master PIC ICW2 Init. Cmd Word 2
Register
Section 9.4.3, “ICW2—Initialization Command Word 2
Register” on page 9-35
Master PIC ICW3 Init. Cmd Word 3
Register
Section 9.4.4, “ICW3—Master Controller Initialization
Command Word 3 Register” on page 9-35
Master PIC ICW4 Init. Cmd Word 4
Register
21h
Master PIC OCW1 Op Ctrl Word 1
Register
24h–25h
Aliased at 20h–21h
28h–29h
Aliased at 20h–21h
24h–25h
Aliased at 20h–21h
2Ch–2Dh
Aliased at 20h–21h
30h–31h
Aliased at 20h–21h
34h–35h
Aliased at 20h–21h
38h–39h
Aliased at 20h–21h
3Ch–3Dh
Counter 0 Counter Access Port
Register
Counter 1 Interval Time Status Byte
Format
Counter 1 Counter Access Port
Register
Counter 2 Interval Time Status Byte
Format
Counter 2 Counter Access Port
Register
40h
41h
42h
43h
Section 9.3.3, “Counter Access Ports Register” on
page 9-32
Section 9.3.2, “SBYTE_FMT—Interval Timer Status
Byte Format Register” on page 9-32
Section 9.3.3, “Counter Access Ports Register” on
page 9-32
Section 9.3.2, “SBYTE_FMT—Interval Timer Status
Byte Format Register” on page 9-32
Section 9.3.3, “Counter Access Ports Register” on
page 9-32
Section 9.3.1.1, “RDBK_CMD—Read Back Command”
on page 9-31
Section 9.3.1.2, “LTCH_CMD—Counter Latch
Command” on page 9-31
Counter Latch Command
Aliased at 40h–43h
Section 9.3.2, “SBYTE_FMT—Interval Timer Status
Byte Format Register” on page 9-32
Section 9.3.1, “TCW—Timer Control Word Register” on
page 9-30
Timer Control Word Register
Timer Control Word Register Read
Back
Section 9.4.6, “ICW4—Initialization Command Word 4
Register” on page 9-36
Section 9.4.7, “OCW1—Operational Control Word 1
(Interrupt Mask) Register” on page 9-36
Aliased at 20h–21h
Counter 0 Interval Time Status Byte
Format
A-2
EDS Section and Location
50h–53h
NMI Status and Control Register
61h
Section 9.7.1, “NMI_SC—NMI Status and Control
Register” on page 9-51
NMI Enable Register
70h
Section 9.7.2, “NMI_EN—NMI Enable (and Real Time
Clock Index)” on page 9-52
Real-Time Clock (Standard RAM)
Index Register
70h
Section 9.7.2, “NMI_EN—NMI Enable (and Real Time
Clock Index)” on page 9-52
Real-Time Clock (Standard RAM)
Target Register
71h
Table 9-7 “RTC (Standard) RAM Bank” on page 9-47
Extended RAM Index Register
72h
Extended RAM Target Register
73h
Table 9-7 “RTC (Standard) RAM Bank” on page 9-47
82801BA ICH2 and 82801BAM ICH2-M Datasheet
I/O Register Index
Table A-1. ICH2 Fixed I/O Registers (Continued)
Register Name
Aliased at 70h–71h
Aliased at 72h–73h or 70h–71h
Port
74h–75h
76h–77h
EDS Section and Location
Aliased if U128E bit in RTC Configuration Register is
enabled
Section 9.1.24, “RTC_CONF—RTC Configuration
Register (LPC I/F—D31:F0)” on page 9-14
Aliased to 70h–71h if U128E bit in RTC Configuration
Register is enabled
Section 9.1.24, “RTC_CONF—RTC Configuration
Register (LPC I/F—D31:F0)” on page 9-14
Channel 2 DMA Memory Low Page
Register
81h
Section 9.2.3, “DMAMEM_LP—DMA Memory Low Page
Registers” on page 9-25
Channel 3 DMA Memory Low Page
Register
82h
Section 9.2.3, “DMAMEM_LP—DMA Memory Low Page
Registers” on page 9-25
Channel 1 DMA Memory Low Page
Register
83h
Section 9.2.3, “DMAMEM_LP—DMA Memory Low Page
Registers” on page 9-25
Reserved Page Registers
84h–86h
Channel 0 DMA Memory Low Page
Register
87h
Reserved Page Register
88h
Channel 6 DMA Memory Low Page
Register
89h
Section 9.2.3, “DMAMEM_LP—DMA Memory Low Page
Registers” on page 9-25
Channel 7 DMA Memory Low Page
Register
8Ah
Section 9.2.3, “DMAMEM_LP—DMA Memory Low Page
Registers” on page 9-25
Channel 5 DMA Memory Low Page
Register
8Bh
Section 9.2.3, “DMAMEM_LP—DMA Memory Low Page
Registers” on page 9-25
Reserved Page Registers
Refresh Low Page Register
Aliased at 81h–8Fh
Fast A20 and INIT Register
8Ch–8Eh
8Fh
91h–9Fh
(except 92h)
92h
Slave PIC ICW1 Init. Cmd Word 1
Register
Slave PIC OCW2 Op Ctrl Word 2
Register
Section 9.2.3, “DMAMEM_LP—DMA Memory Low Page
Registers” on page 9-25
Section 9.7.3, “PORT92—Fast A20 and Init Register” on
page 9-52
Section 9.4.2, “ICW1—Initialization Command Word 1
Register” on page 9-34
A0h
Section 9.4.8, “OCW2—Operational Control Word 2
Register” on page 9-37
Slave PIC OCW3 Op Ctrl Word 3
Register
Section 9.4.9, “OCW3—Operational Control Word 3
Register” on page 9-38
Slave PIC ICW2 Init. Cmd Word 2
Register
Section 9.4.3, “ICW2—Initialization Command Word 2
Register” on page 9-35
Slave PIC ICW3 Init. Cmd Word 3
Register
Section 9.4.4, “ICW3—Master Controller Initialization
Command Word 3 Register” on page 9-35
Slave PIC ICW4 Init. Cmd Word 4
Register
A1
Slave PIC OCW1 Op Ctrl Word 1
Register
Section 9.4.7, “OCW1—Operational Control Word 1
(Interrupt Mask) Register” on page 9-36
Aliased at A0h–A1h
A4h–A5h
Aliased at A0h–A1h
A8h–A9h
Aliased at A0h–A1h
ACh–ADh
Aliased at A0h–A1h
B0h–B1h
82801BA ICH2 and 82801BAM ICH2-M Datasheet
Section 9.4.6, “ICW4—Initialization Command Word 4
Register” on page 9-36
A-3
I/O Register Index
Table A-1. ICH2 Fixed I/O Registers (Continued)
Register Name
Port
Advanced Power Management
Control Port Register
B2h
Section 9.8.2.1, “APM_CNT—Advanced Power
Management Control Port Register” on page 9-60
Advanced Power Management
Status Port Register
B3h
Section 9.8.2.2, “APM_STS—Advanced Power
Management Status Port Register” on page 9-60
Aliased at A0h–A1h
B4h–B5h
Aliased at A0h–A1h
B8h–B9h
Aliased at A0h–A1h
BCh–BDh
Channel 4 DMA Base & Current
Address Register
C0h
Aliased at C0h
C1h
Channel 4 DMA Base & Current
Count Register
C2h
Aliased at C2h
C3h
Channel 5 DMA Base & Current
Address Register
C4h
Aliased at C4h
C5h
Channel 5 DMA Base & Current
Count Register
C6h
Aliased at C6h
C7h
Channel 6 DMA Base & Current
Address Register
C8h
Aliased at C8h
C9h
Channel 6 DMA Base & Current
Count Register
CAh
Aliased at CAh
CBh
Channel 7 DMA Base & Current
Address Register
CCh
Aliased at CCh
CDh
Channel 7 DMA Base & Current
Count Register
CEh
Aliased at CEh
CFh
Channel 4–7 DMA Command
Register
D0h
Channel 4–7 DMA Status Register
A-4
EDS Section and Location
Aliased at D0h
D1h
Channel 4–7 DMA Write Single
Mask Register
D4h
Aliased at D4h
D5h
Channel 4–7 DMA Channel Mode
Register
D6h
Aliased at D6h
D7h
Channel 4–7 DMA Clear Byte
Pointer Register
D8h
Aliased at D8h
D9h
Section 9.2.1, “DMABASE_CA—DMA Base and Current
Address Registers” on page 9-24
Section 9.2.2, “DMABASE_CC—DMA Base and Current
Count Registers” on page 9-25
Section 9.2.1, “DMABASE_CA—DMA Base and Current
Address Registers” on page 9-24
Section 9.2.2, “DMABASE_CC—DMA Base and Current
Count Registers” on page 9-25
Section 9.2.1, “DMABASE_CA—DMA Base and Current
Address Registers” on page 9-24
Section 9.2.2, “DMABASE_CC—DMA Base and Current
Count Registers” on page 9-25
Section 9.2.1, “DMABASE_CA—DMA Base and Current
Address Registers” on page 9-24
Section 9.2.2, “DMABASE_CC—DMA Base and Current
Count Registers” on page 9-25
Section 9.2.4, “DMACMD—DMA Command Register”
on page 9-26
Section 9.2.5, “DMASTS—DMA Status Register” on
page 9-26
Section 9.2.6, “DMA_WRSMSK—DMA Write Single
Mask Register” on page 9-27
Section 9.2.7, “DMACH_MODE—DMA Channel Mode
Register” on page 9-27
Section 9.2.8, “DMA Clear Byte Pointer Register” on
page 9-28
82801BA ICH2 and 82801BAM ICH2-M Datasheet
I/O Register Index
Table A-1. ICH2 Fixed I/O Registers (Continued)
Register Name
Port
Channel 4–7 DMA Master Clear
Register
DAh
Aliased at DAh
DBh
Channel 4–7 DMA Clear Mask
Register
DCh
Aliased at DCh
DEh
Channel 4–7 DMA Write All Mask
Register
DEh
Aliased at DEh
DFh
Coprocessor Error Reigster
F0h
EDS Section and Location
Section 9.2.9, “DMA Master Clear Register” on
page 9-28
Section 9.2.10, “DMA_CLMSK—DMA Clear Mask
Register” on page 9-28
Section 9.2.11, “DMA_WRMSK—DMA Write All Mask
Register” on page 9-29
Section 9.7.4, “COPROC_ERR—Coprocessor Error
Register” on page 9-52
PIO Mode Command Block Offset
for Secondary Drive
170h–177h
See ATA Specification for detailed register description
PIO Mode Command Block Offset
for Primary Drive
1F0h–1F7h
See ATA Specification for detailed register description
PIO Mode Control Block Offset for
Secondary Drive
376h
See ATA Specification for detailed register description
PIO Mode Control Block Offset for
Primary Drive
3F6h
See ATA Specification for detailed register description
Master PIC Edge/Level Triggered
Register
4D0h
Section 9.4.10, “ELCR1—Master Controller Edge/Level
Triggered Register” on page 9-39
Slave PIC Edge/Level Triggered
Register
4D1h
Section 9.4.11, “ELCR2—Slave Controller Edge/Level
Triggered Register” on page 9-40
Reset Control Register
CF9h
Section 9.7.5, “RST_CNT—Reset Control Register” on
page 9-53
NOTE: When the POS_DEC_EN bit is set, additional I/O ports get positively decoded by the ICH2. Refer to
through for a listing of these ranges.
82801BA ICH2 and 82801BAM ICH2-M Datasheet
A-5
I/O Register Index
Table A-2. ICH2 Variable I/O Registers
Register Name
Offset
EDS Section and Location
LAN Control/Status Registers (CSR) may be mapped to either I/O space or memory space.
LAN CSR at CSR_IO_BASE + Offset or CSR_MEM_BASE + Offset. CSR_MEM_BASE set in
Section 7.1.11, “CSR_MEM_BASE CSR—Memory-Mapped Base Address Register (LAN Controller—
B1:D8:F0)” on page 7-5 CSR_IO_BASE set in Section 7.1.12, “CSR_IO_BASE—CSR I/O-Mapped Base
Address Register (LAN Controller—B1:D8:F0)” on page 7-5
SCB Status Word
01h–00h
Section 7.2.1, “System Control Block Status Word
Register” on page 7-11
SCB Command Word
03h–02h
Section 7.2.2, “System Control Block Command Word
Register” on page 7-12
SCB General Pointer
07h–04h
Section 7.2.3, “System Control Block General Pointer
Register” on page 7-14
PORT
OBh–08h
Section 7.2.4, “PORT Register” on page 7-14
EEPROM Control Register
0Fh–0Eh
Section 7.2.5, “EEPROM Control Register” on
page 7-15
MDI Control Register
13h–10h
Section 7.2.6, “Management Data Interface (MDI)
Control Register” on page 7-16
Receive DMA Byte Count
17h–14h
Section 7.2.7, “Receive DMA Byte Count Register” on
page 7-16
Early Receive Interrupt
18h
Section 7.2.8, “Early Receive Interrupt Register” on
page 7-17
Flow Control Register
1Ah–19h
Section 7.2.9, “Flow Control Register” on page 7-18
PMDR
1Bh
Section 7.2.10, “Power Management Driver (PMDR)
Register” on page 7-19
General Control
1Ch
Section 7.2.11, “General Control Register” on
page 7-19
General Status
1Dh
Section 7.2.12, “General Status Register” on
page 7-20
Power Management I/O Registers at PMBASE+Offset
PMBASE set in Section 9.1.10, “PMBASE—ACPI Base Address (LPC I/F—D31:F0)” on page 9-6
PM1 Status
00–01h
Section 9.8.3.1, “PM1_STS—Power Management 1
Status Register” on page 9-62
PM1 Enable
02–03h
Section 9.8.3.2, “PM1_EN—Power Management 1
Enable Register” on page 9-64
PM1 Control
04–07h
Section 9.8.3.3, “PM1_CNT—Power Management 1
Control Register” on page 9-65
PM1 Timer
08–0Bh
Section 9.8.3.4, “PM1_TMR—Power Management 1
Timer Register” on page 9-66
Processor Control
10h–13h
Section 9.8.3.5, “PROC_CNT—Processor Control
Register” on page 9-66
Level 2 Register
A-6
14h
Section 9.8.3.6, “LV2—Level 2 Register” on
page 9-67
General Purpose Event 0 Status
28–29h
Section 9.8.3.9, “GPE0_STS—General Purpose
Event 0 Status Register” on page 9-68
General Purpose Event 0 Enables
2A–2Bh
Section 9.8.3.10, “GPE0_EN—General Purpose
Event 0 Enables Register” on page 9-70
General Purpose Event 1 Status
2C–2D
Section 9.8.3.11, “GPE1_STS—General Purpose
Event 1 Status Register” on page 9-71
General Purpose Event 1 Enables
2E–2F
Section 9.8.3.12, “GPE1_EN—General Purpose
Event 1 Enable Register” on page 9-72
82801BA ICH2 and 82801BAM ICH2-M Datasheet
I/O Register Index
Table A-2. ICH2 Variable I/O Registers (Continued)
Register Name
Offset
EDS Section and Location
SMI# Control and Enable
30–31h
Section 9.8.3.13, “SMI_EN—SMI Control and Enable
Register” on page 9-72
SMI Status Register
34–35h
Section 9.8.3.14, “SMI_STS—SMI Status Register”
on page 9-74
Monitor SMI Status
40h
Section 9.8.3.15, “MON_SMI—Device Monitor SMI
Status and Enable Register” on page 9-75
Device Activity Status
44h
Section 9.8.3.16, “DEVACT_STS—Device Activity
Status Register” on page 9-76
Device Trap Enable
48h
Section 9.8.3.17, “DEVTRAP_EN—Device Trap
Enable Register” on page 9-77
Bus Address Tracker
4Ch
Section 9.8.3.18, “BUS_ADDR_TRACK—Bus
Address Tracker Register” on page 9-78
Bus Cycle Tracker
4Eh
Section 9.8.3.19, “BUS_CYC_TRACK—Bus Cycle
Tracker Register” on page 9-78
TCO I/O Registers at TCOBASE + Offset
TCOBASE = PMBASE + 40h
PMBASE is set in Section 9.1.10, “PMBASE—ACPI Base Address (LPC I/F—D31:F0)” on page 9-6
TCO_RLD: TCO Timer Reload and
Current Value
00h
Section 9.9.2, “TCO1_RLD—TCO Timer Reload and
Current Value Register” on page 9-79
TCO_TMR: TCO Timer Initial Value
01h
Section 9.9.3, “TCO1_TMR—TCO Timer Initial Value
Register” on page 9-80
TCO_DAT_IN: TCO Data In
02h
Section 9.9.4, “TCO1_DAT_IN—TCO Data In
Register” on page 9-80
TCO_DAT_OUT: TCO Data Out
03h
Section 9.9.5, “TCO1_DAT_OUT—TCO Data Out
Register” on page 9-80
TCO1_STS: TCO Status
04h–05h
Section 9.9.6, “TCO1_STS—TCO1 Status Register”
on page 9-80
TCO2_STS: TCO Status
06h–07h
Section 9.9.7, “TCO2_STS—TCO2 Status Register”
on page 9-82
TCO1_CNT: TCO Control
08h–09h
Section 9.9.8, “TCO1_CNT—TCO1 Control Register”
on page 9-83
TCO2_CNT: TCO Control
0Ah–0Bh
Section 9.9.9, “TCO2_CNT—TCO2 Control Register”
on page 9-83
GPIO I/O Registers at GPIOBASE + Offset
GPIOBASE is set in Section 9.1.14, “GPIOBASE—GPIO Base Address (LPC I/F—D31:F0)” on page 9-8
GPIO Use Select
00–03h
Section 9.10.2, “GPIO_USE_SEL—GPIO Use Select
Register” on page 9-87
GPIO Input/Output Select
04–07h
Section 9.10.3, “GP_IO_SEL—GPIO Input/Output
Select Register” on page 9-88
GPIO Level for Input or Output
0C–0Fh
Section 9.10.4, “GP_LVL—GPIO Level for Input or
Output Register” on page 9-89
GPIO Blink Enable
18–1Bh
Section 9.10.5, “GPO_BLINK—GPO Blink Enable
Register” on page 9-90
GPIO Signal Invert
2C–2Fh
Section 9.10.6, “GPI_INV—GPIO Signal Invert
Register” on page 9-91
82801BA ICH2 and 82801BAM ICH2-M Datasheet
A-7
I/O Register Index
Table A-2. ICH2 Variable I/O Registers (Continued)
Register Name
Offset
EDS Section and Location
BMIDE I/O Registers at BM_BASE + Offset
BM_BASE is set at Section 10.1.10, “BM_BASE—Bus Master Base Address Register (IDE—D31:F1)” on
page 10-4
Command Register Primary
00h
Section 10.2.1, “BMIC[P,S]—Bus Master IDE
Command Register” on page 10-11
Status Register Primary
02h
Section 10.2.2, “BMIS[P,S]—Bus Master IDE Status
Register” on page 10-12
Descriptor Table Pointer Primary
04h–07h
Section 10.2.3, “BMID[P,S]—Bus Master IDE
Descriptor Table Pointer Register” on page 10-12
Command Register Secondary
08h
Section 10.2.1, “BMIC[P,S]—Bus Master IDE
Command Register” on page 10-11
Status Register Secondary
0Ah
Section 10.2.2, “BMIS[P,S]—Bus Master IDE Status
Register” on page 10-12
Descriptor Table Pointer Secondary
0Ch–0Fh
Section 10.2.3, “BMID[P,S]—Bus Master IDE
Descriptor Table Pointer Register” on page 10-12
USB I/O Registers at Base Address + Offset
USB Base Address is set at Section 11.1.9, “BASE—Base Address Register (USB—D31:F2/F4)” on
page 11-4
USB Command Register
00h–01h
Section 11.2.1, “USBCMD—USB Command Register”
on page 11-8
USB Status Register
02h–03h
Section 11.2.2, “USBSTA—USB Status Register” on
page 11-11
USB Interrupt Enable
04h–05h
Section 11.2.3, “USBINTR—Interrupt Enable
Register” on page 11-12
USB Frame Number
06h–07h
Section 11.2.4, “FRNUM—Frame Number Register”
on page 11-12
USB Frame List Base Address
08h–0Bh
Section 11.2.5, “FRBASEADD—Frame List Base
Address” on page 11-13
USB Start of Frame Modify
0Ch
Section 11.2.6, “SOFMOD—Start of Frame Modify
Register” on page 11-13
Port 0, 2 Status/Control
10h–11h
Section 11.2.7, “PORTSC[0,1]—Port Status and
Control Register” on page 11-14
Port 1, 3 Status/Control
12h–13h
Section 11.2.7, “PORTSC[0,1]—Port Status and
Control Register” on page 11-14
Loop Back Test Data
18h
SMBus I/O Registers at SMB_BASE + Offset
SMB_BASE is set at Section 12.1.9, “SMB_BASE—SMBus Base Address Register (SMBUS—D31:F3)” on
page 12-4
A-8
Host Status
00h
Section 12.2.1, “HST_STS—Host Status Register” on
page 12-7
Host Control
02h
Section 12.2.2, “HST_CNT—Host Control Register”
on page 12-8
Host Command
03h
Section 12.2.3, “HST_CMD—Host Command
Register” on page 12-9
Transmit Slave Address
04h
Section 12.2.4, “XMIT_SLVA—Transmit Slave
Address Register” on page 12-9
Host Data 0
05h
Section 12.2.5, “HST_D0—Data 0 Register” on
page 12-9
Host Data 1
06h
Section 12.2.6, “HST_D1—Data 1 Register” on
page 12-9
82801BA ICH2 and 82801BAM ICH2-M Datasheet
I/O Register Index
Table A-2. ICH2 Variable I/O Registers (Continued)
Register Name
Offset
EDS Section and Location
Block Data Byte
07h
Section 12.2.7, “BLOCK_DB—Block Data Byte
Register” on page 12-10
Receive Slave Address
09h
Section 12.2.8, “RCV_SLVA—Receive Slave Address
Register” on page 12-10