DtSheet

NSC PC87413

PC87413, PC87414, PC87416, PC87417
LPC ServerI/O for Servers and Workstations
General Description
®
The National Semiconductor PC8741x family of LPC ServerI/O devices (“PC8741x”) comprises highly integrated Advanced I/O products. The PC8741x is targeted for a wide
range of servers and workstations that use the Low Pin Count
(LPC) bus for the host interface and the serial ACCESS.bus
or SMBus® for the embedded controller interface.
The PC8741x features an X-Bus extension for read and write
operations over the X-Bus for both LPC and ACCESS.bus
cycles. Boot Flash and I/O devices can be accessed over this
X-Bus.
Embedded controllers can access the PC8741x and its X-Bus
via the ACCESS.bus or SMBus serial interface when VSB
exists, regardless of the LPC bus state. Some of the
PC8741x logical devices can be disabled, or their pins can be
floated, under control of the VSB-powered serial bus.
The PC8741x provides a VSB-powered high-frequency clock
for on-chip peripherals and for other VSB-powered platform
components.
The PC8741x’s extended wake-up support complements the
chipset’s ACPI controller and the platform embedded controllers. The PC8741x can monitor the Power and Sleep buttons
and control the power supply of simple platforms that lack an
embedded controller. The System Wake-Up Control (SWC)
module is powered by VSB and VBAT power supplies. It sup-
ports flexible wake-up and power-off request mechanisms in
any sleep state. It features Main and Standby power-on
elapsed-time counters.
The PC8741x also incorporates a Floppy Disk Controller
(FDC), two serial ports (UARTs), a Keyboard and Mouse
Controller (KBC), a Real-Time Clock (RTC), a fully compliant
IEEE 1284 Parallel Port, General-Purpose Input/Output
(GPIO) for a total of 51 ports and an Interrupt Serializer for
Parallel IRQs.
Outstanding Features
■
LPC Interface, based on Intel’s LPC Interface Specification, Revision 1.0, September 29th, 1997
■
VSB-powered access to modules through ACCESS.bus
or SMBus (PC87413 and PC87417)
■
X-Bus Extension for memory and I/O (PC87416 and
PC87417)
■
PC01 Revision 0.5 and ACPI Revision 1.0b compliant
■
ServerI/O modules: Parallel Port, FDC, two Serial Ports
(UARTs) and a Keyboard and Mouse Controller (KBC)
■
Y2K-compliant RTC with 242 bytes of RAM
■
51 GPIO ports with a variety of wake-up events
■
Extremely low current consumption in Battery Backup mode
■
128-pin PQFP package
Block Diagram
PC87417 (See page 5 for other PC8741x diagrams.)
Serial
Serial
Interface Interface
ServerI/O
Clock
VDD
Serial
Port 1
Serial
Port 2
Parallel Port
Interface
Floppy Drive
Interface
IEEE 1284
Parallel Port
Floppy Disk
Controller
LPC Serial
Keyboard Mouse
Interface Interface Interface IRQ
Keyboard &
Mouse Controller
LPC Bus
Interface
Device
Configuration
Internal Clocks
VBAT
VSB
Power
System
On
Wake-Up Control
Timers
Wake-Up Power SCI &
Events Control SMI
RTC
Clock
Generator
Low-F High-F
32.768 KHz Clock Clock
GPIO
Ports
X-Bus
Extension
X-Bus XIRQ
I/O
Ports Interface
ACCESS.bus
Interface
Clock Serial
Data
National Semiconductor and TRI-STATE are registered trademarks of National Semiconductor Corporation. All other
brand or product names are trademarks or registered trademarks of their respective holders.
© 2003 National Semiconductor Corporation
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PC87413, PC87414, PC87416, PC87417 LPC ServerI/O for Servers and Workstations
July 2003
Revision 1.2
PC8741x
Features
Bus Interfaces
■
■
■
LPC Bus Interface
— Based on Intel’s LPC Interface Specification Revision 1.0, September 29, 1997
— Synchronous cycles using up to 33 MHz bus clock
— 8-bit I/O and Memory read and write cycles
— Up to four 8-bit DMA channels
— Serial IRQ
— Supports bootable memory
— Reset input
— CLKRUN support
— FWH Transaction support
— Proprietary commands for read/write byte from/to:
❏ Internal register
X-Bus I/O device
❏
X-Bus memory device
Programmable through the LPC bus
❏
VBAT backed-up
■
IEEE 1284-compliant Parallel Port
— ECP, with Level 2 (14 mA sink and source output
buffers)
— Software or hardware control
— Enhanced Parallel Port (EPP) compatible with EPP
1.7 and EPP 1.9
— Supports EPP as mode 4 of the Extended Control
Register (ECR)
— Selection of internal pull-up or pull-down resistor for
Paper End (PE) pin
— Supports a demand DMA mode mechanism and a
DMA fairness mechanism for improved bus utilization
— Protection circuit that prevents damage to the
parallel port when a printer connected to it powers
up or is operated at high voltages, even if the device
is in power-down state
— Optional outputs TRI-STATE by external pin
■
Floppy Disk Controller (FDC)
— Programmable write protect
— Supports FM and MFM modes
— Supports Enhanced mode command for three-mode
Floppy Disk Drive (FDD)
— Perpendicular recording drive support for 2.88 MB
— Burst and Non-Burst modes
— Full support for IBM Tape Drive Register (TDR) implementation of AT and PS/2 drive types
— 16-byte FIFO
— Error-free handling of data overrun and underrun
conditions during DMA transactions (i.e., does not
lose data or status bytes and is free of the NEC765A
bug)
— Software compatible with the PC8477, which
contains a superset of the FDC functions in the
µDP8473, NEC µPD765A/B and N82077
— High-performance digital separator
— Supports standard 5.25" and 3.5" FDDs
— Supports up to four FDDs
— Optional internal pull-up on the ACBDAT and
ACBCLK pins
X-Bus Extension (PC87416 and PC87417)
— Supports I/O and Memory read/write operations
— 8-bit data bus, 28-bit address
— Multiplexed address-data lines:
❏ Four direct address lines
❏
Partial non-multiplexed option
— Boot configuration selected by straps
— Four chip-select outputs, each supporting multiple
zones:
❏ Up to 32 MByte BIOS memory zones
❏
Up to 32 MByte user-defined memory zones
❏
Four user-defined I/O zones
❏
Test port and other I/O ports
—
—
—
—
—
Optional indirect addressing of memory
XRD-XEN or XWR-XR/W mode support
Supports both slow and fast devices
Accessible from both LPC and ACB buses
Programmable protection control over access from
the LPC bus
— VSB powered
— External Interrupt support via XIRQ pin
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Up to four optional 8-bit DMA channels
Serial Ports 1 and 2
— Software compatible with the 16550A and the 16450
— Supports shadow register for write-only bit monitoring
— UART data rates up to 1.5 Mbaud
— Concurrent access with the LPC bus
— VSB powered
■
❏
■
— Slave address:
❏ Two values selected by strap
❏
15 IRQ routing options to serial IRQ
Legacy Modules
ACCESS.bus
❏
❏
— ACCESS.bus control over pin multiplexing, module
disable and output TRI-STATE for all Legacy modules (PC87413 and PC87417)
ACCESS.bus (ACB) Interface (PC87413 and PC87417)
— Enables a system controller to access the internal
functions and the X-Bus extension
— Supports slave operation compatible with:
❏ Intel SMBus
❏
Configuration Control (via LPC bus)
— Compliant with PC01 Specification Revision 0.5,
November 2, 1999
— Plug and Play (PnP) Configuration register structure
— Base Address strap to setup the address of the
Index-Data register pair
— Flexible resource allocation for all logical devices:
❏ Relocatable base address
2
Revision1.2
(Continued)
Power Management
— Supports fast tape drives (2 Mbps) and standard
tape drives (1 Mbps, 500 Kbps and 250 Kbps)
■
Keyboard and Mouse Controller (KBC)
— 8-bit microcontroller, software compatible with
8042AH and PC87911
— Standard interface (60h, 64h, IRQ1 and IRQ12)
— Supports two external swapable PS/2 interfaces for
keyboard and mouse
— Five programmable, dedicated, open-drain I/O lines
(Fast GA20/P21, KBRST/P20, P12, P16, P17)
■
Supports ACPI Specification Revision 1.0b, Feb. 2, 1999
■
System Wake-Up Control (SWC)
— Wake-up request on detection of:
❏ Preprogrammed Keyboard or Mouse sequence
❏
External modem ring from RI1 or RI2 on serial
ports
❏
Predetermined RTC date and time alarm
❏
General-Purpose Input Events from up to 16
GPIO pins
❏
IRQs of internal logical devices
General-Purpose Modules
■
General-Purpose I/O (GPIO) Ports
— 51 GPIO Ports:
❏ Individually assigned to either LPC or ACB control (PC87413 and PC87417)
❏
46 individually configured as input or output
❏
Five output-only
— Optional routing of power-up request to SERIRQ,
SIOSMI, SIOSCI, PWBTOUT and ONCTL
— Routing control per input/output event combination
— Outputs enable/disable per event and system state
combination (ACPI Sx states)
— Implements bank “b” of the ACPI registers
— Suspend modes via software emulation (control)
— Battery-backed event-logic configuration
— Power button support, featuring:
❏ On/Off control
— Programmable features for each output pin:
❏ Drive type (open-drain, push-pull or TRI-STATE)
❏
TRI-STATE on VDD-fall detection for pins driving
VDD-supplied devices
— Programmable option for internal pull-up resistor on
each input pin
— Lock option for the configuration and data of each
output pin
— 16 GPIO ports generate IRQ/SIOSMI/SIOSCI for
wake-up events, with individual:
❏ Enable control
❏
Polarity and edge/level selection
❏
Debounce mechanism
Real-Time Clock (RTC)
— DS1287, MC146818 and PC87911 compatible
— 242-byte battery backed-up CMOS RAM in two
banks (accessed through 70-71h and 72-73h)
— Selective lock mechanisms for the RTC RAM
— Y2K-compliant calendar, including century and
automatic leap-year adjustment
— Time of day in seconds, minutes and hours that allows a 12-hour or 24-hour format with optional
adjustment for daylight saving time
— BCD or binary format for timekeeping
— Four individually maskable interrupt event flags:
❏ Periodic rates from 122 µs to 500 ms
Day-of-month alarm
❏
Time-of-day alarm
❏
Once-per-second to once-per-day
Power-off, 4-second override
❏
Power button output
■
Power Supply On/Off control
— Supports Legacy- and ACPI-compatible Power
button
— Direct power supply control in response to wake-up
events
— Programmable Crowbar time-out for On request
— On/Off control via software emulation
— Power-fail recovery
■
Enhanced Power Management (PM), including:
— Special configuration registers for power down
— Reduced current leakage from pins
— Low-power CMOS technology
— Ability to disable all modules
■
Keyboard Events
— Wake-up on any key
— Supports programmable 8-byte sequence “password” for Power Management
— Simultaneous recognition of three programmable
keys (sequences): “Power”, “Sleep” and “Resume”
■
Power Active Timers
— Two power-on, elapsed-time counters for the main
(VDD) and standby (VSB) power supplies
— Low-cost external GPIO port expansion via X-Bus
(PC87416 and PC87417)
❏
❏
— Sleep Button support
— VSB powered
■
PC8741x
Features
— 32-bit counters with 1 second LSB
— VBAT backed-up counters
— Double-buffer time registers
Revision 1.2
3
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PC8741x
Features (Continued)
■
— On-chip low-frequency clock generator:
❏ 32.768 KHz for RTC, System Wake-Up Control
(SWC), Power Active timers and the high-frequency clock generator
Watchdog
— Watchdog counter reset by:
❏ Serial Ports Interrupts
❏
Keyboard and Mouse Interrupts
❏
Software control
— 8-bit counter with 1 minute LSB
— Generates a 250 ms pulse at WDO pin
— Programmable SIOSMI or SIOSCI events
❏
Very low power consumption
❏
VBAT powered
— On-chip high-frequency clock generator:
❏ Based on the 32.768 KHz clock
❏
Clocking, Supply and Package Information
■
■
VSB powered
— Clock outputs:
❏ LFCKOUT: 32.768 KHz or 1 Hz
Strap Input Controlled Operating Modes
— Base Address (BADDR) for the PnP Index-Data
register pair
— Input clock presence (CKIN48) select
— X-Bus configuration (XCNF2-0) select (PC87413
and PC87417)
— ACCESS.bus slave address (ACBSA) select
(PC87416 and PC87417)
— TRI-STATE device pins (TRIS)
❏
Clocks
— LPC clock input (up to 33 MHz)
— ServerI/O modules clock input: 48 MHz or no clock
— Single 32.768 KHz crystal
HFCKOUT: 48 MHz or 40 MHz (or divided)
■
Protection
— All pins are 5V tolerant and back-drive protected
(except the LPC bus pins)
— Separate battery pin that includes an internal UL
protection resistor
— GPIO multiplexing configuration lock
■
Power Supply
— 3.3V supply operation
— Separate pins for main (VDD) and standby (VSB)
power supplies
— Backup battery input for RTC, SWC and Power
Active timers
— Reduced standby power consumption
— Very low power consumption for RTC and timers
(0.9 µA typical) from backup battery
■
Package
— 128-pin PQFP
Device-Specific Information
The following table shows the main features for each device in the PC8741x family.
Function1,2
PC87413
LPC Bus Interface
X-Bus Extension
PC87414
YES
NO
PC87416
YES
NO
PC87417
YES
YES
YES
YES
ACCESS.bus Interface
YES
General-Purpose Input/Output Ports (GPIO)
YES
YES
YES
YES
Real Time Clock (RTC)
YES
YES
YES
YES
System Wake-Up Control (SWC)
YES
YES
YES
YES
Legacy Functional Blocks
YES
YES
YES
YES
NO
NO
YES
1. This Datasheet contains notes that are device specific.
2. The “not implemented” functions must not be accessed by the host/controller, because correct
operation is not guaranteed.
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4
Revision1.2
PC8741x
Features
(Continued)
Block Diagrams
These are the block diagrams for the remaining PC8741x devices (see page 1 for the PC87417):
PC87413
Serial
Serial
Interface Interface
ServerI/O
Clock
VDD
Serial
Port 1
Serial
Port 2
Parallel Port
Interface
Floppy Drive
Interface
IEEE 1284
Parallel Port
Floppy Disk
Controller
LPC Serial
Keyboard Mouse
Interface Interface Interface IRQ
Keyboard &
Mouse Controller
LPC Bus
Interface
Device
Configuration
Internal Clocks
VBAT
Power
System
On
Wake-Up Control
Timers
VSB
Wake-Up Power SCI &
Events Control SMI
RTC
Clock
Generator
Low-F High-F
32.768 KHz Clock Clock
GPIO
Ports
ACCESS.bus
Interface
I/O
Ports
Clock Serial
Data
PC87414
Serial
Serial
Interface Interface
ServerI/O
Clock
VDD
Serial
Port 1
Serial
Port 2
Parallel Port
Interface
Floppy Drive
Interface
IEEE 1284
Parallel Port
Floppy Disk
Controller
LPC Serial
Keyboard Mouse
Interface Interface Interface IRQ
Keyboard &
Mouse Controller
LPC Bus
Interface
Device
Configuration
Internal Clocks
VBAT
System
Wake-Up Control
VSB
Power
On
Timers
Wake-Up Power SCI &
Events Control SMI
RTC
GPIO
Ports
Clock
Generator
Low-F High-F
32.768 KHz Clock Clock
I/O
Ports
PC87416
Serial
Serial
Interface Interface
ServerI/O
Clock
VDD
Serial
Port 1
Serial
Port 2
Parallel Port
Interface
Floppy Drive
Interface
IEEE 1284
Parallel Port
Floppy Disk
Controller
LPC Serial
Keyboard Mouse
Interface Interface Interface IRQ
Keyboard &
Mouse Controller
LPC Bus
Interface
Device
Configuration
Internal Clocks
VBAT
VSB
Power
System
On
Wake-Up Control
Timers
Wake-Up Power SCI &
Events Control SMI
Revision 1.2
RTC
Clock
Generator
Low-F High-F
32.768 KHz Clock Clock
5
GPIO
Ports
X-Bus
Extension
X-Bus XIRQ
I/O
Ports Interface
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PC8741x
Datasheet Revision Record
Revision Date
July 2000
October 2000
March 2001
Status
Comments
Preliminary Datasheet First issue - Rev 0.12
Preliminary Datasheet Second issue - Rev 0.13
Preliminary Datasheet Third issue - Rev 1.0
November 2001 Preliminary Datasheet Fourth issue - Rev 1.1
July 2003
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Datasheet
Non-preliminary revision, Rev 1.2
6
Revision1.2
PC8741x
Table of Contents
1.0
2.0
3.0
Signal/Pin Connection and Description
1.1
CONNECTION DIAGRAMS ...................................................................................................... 16
1.2
BUFFER TYPES AND SIGNAL/PIN DIRECTORY .................................................................... 20
1.3
PIN MULTIPLEXING ................................................................................................................. 20
1.4
DETAILED SIGNAL/PIN DESCRIPTIONS ................................................................................ 22
1.4.1
LPC Interface .............................................................................................................. 23
1.4.2
ACCESS.bus (ACB) Interface (PC87413 and PC87417) ........................................... 23
1.4.3
X-Bus Extension (PC87416 and PC87417) ................................................................ 23
1.4.4
Serial Port 1 and Serial Port 2 (UART1 and UART2) ................................................. 24
1.4.5
Parallel Port ................................................................................................................ 25
1.4.6
Floppy Disk Controller (FDC) ..................................................................................... 26
1.4.7
Keyboard and Mouse Controller (KBC) ...................................................................... 27
1.4.8
General-Purpose I/O (GPIO) ...................................................................................... 27
1.4.9
System Wake-Up Control (SWC) ............................................................................... 28
1.4.10 Clocks .......................................................................................................................... 29
1.4.11 Configuration Straps ................................................................................................... 29
1.4.12 Power and Ground ...................................................................................................... 30
1.5
INTERNAL PULL-UP AND PULL-DOWN RESISTORS ............................................................ 30
Power, Reset and Clocks
2.1
POWER ..................................................................................................................................... 32
2.1.1
Power Planes .............................................................................................................. 32
2.1.2
Power States ............................................................................................................... 32
2.1.3
Power Connection and Layout Guidelines .................................................................. 33
2.2
RESET SOURCES AND TYPES ............................................................................................... 34
2.2.1
VPP Power-Up Reset ................................................................................................... 34
2.2.2
VSB Power-Up Reset .................................................................................................. 34
2.2.3
Controller Software Reset (PC87413 and PC87417) .................................................. 35
2.2.4
VDD Power-Up Reset .................................................................................................. 35
2.2.5
Hardware Reset ........................................................................................................... 35
2.2.6
Host Software Reset .................................................................................................... 35
2.3
CLOCK GENERATION .............................................................................................................. 36
2.3.1
Clock Domains ............................................................................................................ 36
2.3.2
Clock Generator .......................................................................................................... 36
2.3.3
Low Frequency Clock .................................................................................................. 37
Device Architecture and Configuration
3.1
OVERVIEW ............................................................................................................................... 38
3.2
CONFIGURATION STRUCTURE AND ACCESS ..................................................................... 38
3.2.1
The Index-Data Register Pair ...................................................................................... 38
3.2.2
Banked Logical Device Registers Structure ................................................................ 39
3.2.3
Standard Configuration Register Definitions ............................................................... 40
3.2.4
Standard Configuration Registers ............................................................................... 42
Revision 1.2
7
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PC8741x
Table of Contents
3.2.5
(Continued)
Default Configuration Setup ........................................................................................ 43
3.3
MODULE CONTROL ................................................................................................................. 43
3.3.1
Module Enable/Disable ................................................................................................ 43
3.3.2
Module Lock by ACCESS.bus (PC87413 and PC87417) ........................................... 44
3.4
INTERNAL ADDRESS DECODING .......................................................................................... 45
3.5
PROTECTION ........................................................................................................................... 46
3.5.1
Multiplexed Pins Configuration Lock ........................................................................... 46
3.5.2
GPIO Ports Configuration Lock ................................................................................... 46
3.5.3
Fast Disable Configuration Lock .................................................................................. 46
3.5.4
Clock Generator Configuration Lock ........................................................................... 46
3.5.5
GPIO Ports Lock .......................................................................................................... 46
3.5.6
X-Bus I/O Map Lock (PC87416 and PC87417) ........................................................... 47
3.5.7
X-Bus Memory Map Lock (PC87416 and PC87417) ................................................... 47
3.5.8
X-Bus Chip Select Configuration Lock (PC87416 and PC87417) ............................... 47
3.5.9
X-Bus Host Protection Lock (PC87416 and PC87417) ............................................... 47
3.5.10 SWC Timers Protection Lock ...................................................................................... 47
3.5.11 SWC Sleep State Configuration Lock .......................................................................... 47
3.5.12 CMOS RAM Access Lock ............................................................................................ 47
3.6
REGISTER TYPE ABBREVIATIONS ........................................................................................ 48
3.7
SERVERI/O CONFIGURATION REGISTERS .......................................................................... 48
3.7.1
ServerI/O ID Register (SID) ......................................................................................... 49
3.7.2
ServerI/O Configuration 1 Register (SIOCF1) ............................................................. 49
3.7.3
ServerI/O Configuration 2 Register (SIOCF2) ............................................................. 50
3.7.4
ServerI/O Configuration 3 Register (SIOCF3) ............................................................. 51
3.7.5
ServerI/O Configuration 4 Register (SIOCF4) ............................................................. 52
3.7.6
ServerI/O Configuration 5 Register (SIOCF5) ............................................................. 53
3.7.7
ServerI/O Configuration 6 Register (SIOCF6) ............................................................. 54
3.7.8
ServerI/O Revision ID Register (SRID) ....................................................................... 55
3.7.9
ServerI/O Configuration 8 Register (SIOCF8) ............................................................. 55
3.7.10 Clock Generator Configuration Register (CLOCKCF) ................................................. 56
3.7.11 ACCESS.bus Configuration (ACBCF) Register ........................................................... 57
3.8
FLOPPY DISK CONTROLLER (FDC) CONFIGURATION ........................................................ 58
3.8.1
General Description ..................................................................................................... 58
3.8.2
Logical Device 0 (FDC) Configuration ......................................................................... 58
3.8.3
FDC Configuration Register ........................................................................................ 59
3.8.4
Drive ID Register ......................................................................................................... 60
3.9
PARALLEL PORT (PP) CONFIGURATION ............................................................................. 61
3.9.1
General Description ..................................................................................................... 61
3.9.2
Logical Device 1 (PP) Configuration ............................................................................ 61
3.9.3
Parallel Port Configuration Register ............................................................................ 62
3.10
SERIAL PORT 2 CONFIGURATION ........................................................................................ 63
3.10.1 General Description ..................................................................................................... 63
3.10.2 Logical Device 2 (SP2) Configuration .......................................................................... 63
3.10.3 Serial Port 2 Configuration Register ............................................................................ 64
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8
Revision 1.2
(Continued)
3.11
SERIAL PORT 1 CONFIGURATION ........................................................................................ 65
3.11.1 General Description ..................................................................................................... 65
3.11.2 Logical Device 3 (SP1) Configuration .......................................................................... 65
3.11.3 Serial Port 1 Configuration Register ............................................................................ 66
3.12
SYSTEM WAKE-UP CONTROL (SWC) CONFIGURATION .................................................... 67
3.12.1 General Description ..................................................................................................... 67
3.12.2 Logical Device 4 (SWC) Configuration ........................................................................ 67
3.13
KEYBOARD AND MOUSE CONTROLLER (KBC) CONFIGURATION .................................... 68
3.13.1 General Description ..................................................................................................... 68
3.13.2 Logical Devices 5 and 6 (Mouse and Keyboard) Configuration .................................. 68
3.13.3 KBC Configuration Register ........................................................................................ 69
3.14
GENERAL-PURPOSE INPUT/OUTPUT (GPIO) PORTS CONFIGURATION ......................... 70
3.14.1 General Description ..................................................................................................... 70
3.14.2 Logical Device 7 (GPIO) Configuration ....................................................................... 71
3.14.3 GPIO Pin Select Register (GPSEL) ............................................................................. 72
3.14.4 GPIO Pin Configuration Register 1 (GPCFG1) ........................................................... 72
3.14.5 GPIO Event Routing Register (GPEVR) ...................................................................... 74
3.14.6 GPIO Pin Configuration Register 2 (GPCFG2) ........................................................... 74
3.15
X-BUS CONFIGURATION ........................................................................................................ 75
3.15.1 Logical Device F (X-Bus) Configuration ...................................................................... 75
3.15.2 X-Bus I/O Range Programming ................................................................................... 75
3.15.3 X-Bus Memory Range Programming ........................................................................... 76
3.15.4 X-Bus I/O Configuration Register (XIOCNF) ............................................................... 78
3.15.5 X-Bus I/O Base Address 1 High Byte Register (XIOBA1H) ......................................... 79
3.15.6 X-Bus I/O Base Address 1 Low Byte Register (XIOBA1L) .......................................... 80
3.15.7 X-Bus I/O Size 1 Configuration Register (XIOSIZE1) .................................................. 80
3.15.8 X-Bus I/O Base Address 2 High Byte Register (XIOBA2H) ......................................... 81
3.15.9 X-Bus I/O Base Address 2 Low Byte Register (XIOBA2L) .......................................... 81
3.15.10 X-Bus I/O Size 2 Configuration Register (XIOSIZE2) ................................................. 82
3.15.11 X-Bus Memory Configuration Register 1 (XMEMCNF1) ............................................ 83
3.15.12 X-Bus Memory Configuration Register 2 (XMEMCNF2) ............................................ 84
3.15.13 X-Bus Memory Base Address High Byte Register (XMEMBAH) ................................ 85
3.15.14 X-Bus Memory Base Address Low Byte Register (XMEMBAL) ................................. 85
3.15.15 X-Bus Memory Size Configuration Register (XMEMSIZE) ......................................... 86
3.15.16 X-Bus IRQ Mapping Register (XIRQMAP) ................................................................. 86
3.16
REAL TIME CLOCK (RTC) CONFIGURATION ....................................................................... 87
3.16.1 General Description ..................................................................................................... 87
3.16.2 Logical Device 10 (RTC) Configuration ....................................................................... 87
3.16.3 RAM Lock Register (RLR) ........................................................................................... 88
3.16.4 Date-of-Month Alarm Register Offset (DOMAO) ......................................................... 89
3.16.5 Month Alarm Register Offset (MONAO) ...................................................................... 89
3.16.6 Century Register Offset (CENO) ................................................................................. 89
Revision 1.2
9
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PC8741x
Table of Contents
PC8741x
Table of Contents
4.0
5.0
6.0
(Continued)
LPC Bus Interface
4.1
OVERVIEW ............................................................................................................................... 90
4.2
LPC TRANSACTIONS ............................................................................................................... 90
4.3
CLKRUN FUNCTIONALITY ...................................................................................................... 91
4.4
INTERRUPT SERIALIZER ........................................................................................................ 91
X-Bus Extension
5.1
OVERVIEW ............................................................................................................................... 92
5.2
X-BUS TRANSACTIONS ........................................................................................................... 92
5.2.1
Transaction Clock ........................................................................................................ 93
5.2.2
Programmable Range Chip Select .............................................................................. 93
5.2.3
LPC and FWH Address-to-X-Bus Address Translation ............................................... 93
5.2.4
Indirect Memory Read and Write Transactions ........................................................... 95
5.2.5
Mode 0, Normal Address X-Bus Transactions ............................................................ 95
5.2.6
Mode 0, Normal Address, Fast X-Bus Transactions ................................................... 97
5.2.7
Mode 0, Normal Address, Turbo X-Bus Transactions ................................................. 99
5.2.8
Mode 1, Normal Address Transactions ..................................................................... 100
5.2.9
Latched Address Mode X-Bus Transactions ............................................................. 101
5.3
X-BUS PROTECTION ............................................................................................................. 105
5.4
X-BUS REGISTERS ................................................................................................................ 107
5.4.1
X-Bus Register Map .................................................................................................. 107
5.4.2
X-Bus Configuration Register (XBCNF) .................................................................... 108
5.4.3
X-Bus Select Configuration Registers (XZCNF0 to XZCNF3) ................................... 108
5.4.4
X-Bus IRQ Configuration Register (XIRQC) .............................................................. 110
5.4.5
X-Bus Indirect Memory Address Register 0 (XIMA0) ................................................ 111
5.4.6
X-Bus Indirect Memory Address Register 1 (XIMA1) ................................................ 111
5.4.7
X-Bus Indirect Memory Address Register 2 (XIMA2) ................................................ 112
5.4.8
X-Bus Indirect Memory Address Register 3 (XIMA3) ................................................ 112
5.4.9
X-Bus Indirect Memory Data Register (XIMD) ........................................................... 112
5.4.10 X-Bus Select Mode Register (XZM0 to XZM3) .......................................................... 113
5.4.11 Host Access Protect Register (HAP0 to HAP1) ......................................................... 114
5.5
USAGE HINTS ........................................................................................................................ 115
5.6
X-BUS EXTENSION REGISTER BITMAP ............................................................................. 116
ACCESS.bus Interface
6.1
OVERVIEW ............................................................................................................................. 117
6.2
FUNCTIONAL DESCRIPTION ................................................................................................ 117
6.2.1
Bus Signals ................................................................................................................ 117
6.2.2
Data Transactions ..................................................................................................... 117
6.2.3
Start and Stop Conditions .......................................................................................... 118
6.2.4
Acknowledge (ACK) Cycle ........................................................................................ 118
6.2.5
Acknowledge after Every Byte Rule .......................................................................... 119
6.2.6
Addressing Transfer Formats .................................................................................... 119
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10
Revision 1.2
6.2.7
6.2.8
6.2.9
6.2.10
7.0
8.0
(Continued)
Arbitration on the Bus ................................................................................................ 120
Packet Error Check (PEC) ......................................................................................... 120
ACCESS.bus Protocol ............................................................................................... 121
Transaction Execution ............................................................................................... 125
6.3
ACB REGISTERS (ON ACCESS.BUS ONLY) ........................................................................ 126
6.3.1
ACB Register Map (on ACCESS.bus Only) .............................................................. 126
6.3.2
ACCESS.bus Control/Status Register (ACBCST) ..................................................... 127
6.3.3
ACCESS.bus Configuration Register (ACBCFG) ...................................................... 128
6.3.4
ACCESS.bus Lock Control Register (ACBLKCTL) ................................................... 128
6.3.5
ACCESS.bus Fast Disable Register (ACBFDIS) ....................................................... 130
6.3.6
ACCESS.bus TRI-STATE Register (ACBTRIS) ........................................................ 131
6.3.7
Access Lock Configuration 1 Register (ACCLCF1) ................................................... 132
6.3.8
Access Lock Configuration 2 Register (ACCLCF2) ................................................... 133
6.4
ACB REGISTER BITMAP ........................................................................................................ 134
General-Purpose Input/Output (GPIO) Ports
7.1
OVERVIEW ............................................................................................................................. 135
7.2
BASIC FUNCTIONALITY ........................................................................................................ 136
7.2.1
Configuration Options ................................................................................................ 136
7.2.2
Operation ................................................................................................................... 137
7.3
EVENT HANDLING AND SYSTEM NOTIFICATION .............................................................. 137
7.3.1
Event Configuration ................................................................................................... 137
7.3.2
System Notification .................................................................................................... 138
7.4
GPIO PORT REGISTERS ....................................................................................................... 139
7.4.1
GPIO Pin Configuration Registers Structure ............................................................. 139
7.4.2
GPIO Port Runtime Register Map ............................................................................. 140
7.4.3
GPIO Data Out Register (GPDO) .............................................................................. 140
7.4.4
GPIO Data In Register (GPDI) .................................................................................. 140
7.4.5
GPIO Event Enable Register (GPEVEN) .................................................................. 141
7.4.6
GPIO Event Status Register (GPEVST) .................................................................... 141
Real-Time Clock (RTC)
8.1
OVERVIEW ............................................................................................................................. 142
8.2
FUNCTIONAL DESCRIPTION ................................................................................................ 142
8.2.1
Bus Interface ............................................................................................................. 142
8.2.2
RTC Clock Generation .............................................................................................. 142
8.2.3
Internal Oscillator ....................................................................................................... 142
8.2.4
External Oscillator ..................................................................................................... 143
8.2.5
Timing Generation ..................................................................................................... 144
8.2.6
Timekeeping .............................................................................................................. 144
8.2.7
Updating .................................................................................................................... 145
8.2.8
Alarms ....................................................................................................................... 145
8.2.9
Power Supply ............................................................................................................ 146
8.2.10 System Bus Lockout .................................................................................................. 147
Revision 1.2
11
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PC8741x
Table of Contents
PC8741x
Table of Contents
8.2.11
8.2.12
8.2.13
8.2.14
9.0
(Continued)
Power-Up Detection .................................................................................................. 147
Oscillator Activity ....................................................................................................... 147
Interrupt Handling ...................................................................................................... 148
Battery-Backed RAMs and Registers ........................................................................ 148
8.3
RTC REGISTERS .................................................................................................................... 149
8.3.1
RTC Configuration Registers Structure ..................................................................... 149
8.3.2
RTC Runtime Register Map ...................................................................................... 150
8.3.3
Seconds Register (SEC) ........................................................................................... 150
8.3.4
Seconds Alarm Register (SECA) ............................................................................... 151
8.3.5
Minutes Register (MIN) .............................................................................................. 151
8.3.6
Minutes Alarm Register (MINA) ................................................................................. 151
8.3.7
Hours Register (HOR) ............................................................................................... 152
8.3.8
Hours Alarm Register (HORA) .................................................................................. 152
8.3.9
Day-of-Week Register (DOW) ................................................................................... 152
8.3.10 Date-of-Month Register (DOM) ................................................................................. 153
8.3.11 Month Register (MON) .............................................................................................. 153
8.3.12 Year Register (YER) .................................................................................................. 153
8.3.13 RTC Control Register A (CRA) .................................................................................. 154
8.3.14 RTC Control Register B (CRB) .................................................................................. 156
8.3.15 RTC Control Register C (CRC) ................................................................................. 157
8.3.16 RTC Control Register D (CRD) ................................................................................. 157
8.3.17 Date-of-Month Alarm Register (DOMA) ..................................................................... 158
8.3.18 Month Alarm Register (MONA) .................................................................................. 158
8.3.19 Century Register (CEN) ............................................................................................. 158
8.3.20 BCD and Binary Formats ........................................................................................... 159
8.4
USAGE HINTS ........................................................................................................................ 159
8.5
RTC REGISTER BITMAP ........................................................................................................ 160
8.6
RTC GENERAL-PURPOSE RAM MAP ................................................................................... 160
System Wake-Up Control (SWC)
9.1
OVERVIEW ............................................................................................................................. 161
9.2
FUNCTIONAL DESCRIPTION ................................................................................................ 162
9.2.1
External Events ......................................................................................................... 162
9.2.2
Internal Events ........................................................................................................... 166
9.2.3
Sleep States .............................................................................................................. 167
9.2.4
Interrupt Signals ........................................................................................................ 168
9.2.5
Power Management Signals ...................................................................................... 169
9.2.6
Special Power Management Functions ..................................................................... 172
9.2.7
LED Control ............................................................................................................... 173
9.2.8
Power Active Timers .................................................................................................. 174
9.2.9
Watchdog Function .................................................................................................... 174
9.2.10 Miscellaneous Functions ........................................................................................... 175
9.3
SWC REGISTERS ................................................................................................................... 176
9.3.1
SWC Register Map .................................................................................................... 176
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12
Revision 1.2
9.3.2
9.3.3
9.3.4
9.3.5
9.3.6
9.3.7
9.3.8
9.3.9
9.3.10
9.3.11
9.3.12
9.3.13
9.3.14
9.3.15
9.3.16
9.3.17
9.3.18
9.3.19
9.3.20
9.3.21
9.3.22
9.3.23
9.3.24
9.3.25
9.3.26
9.3.27
9.3.28
9.3.29
9.3.30
9.3.31
9.3.32
9.3.33
9.3.34
9.3.35
9.4
Revision 1.2
(Continued)
Wake-Up Event Select Register (WK_EVT_SEL) ..................................................... 178
Wake-Up State Enable Register (WK_ST_EN) ......................................................... 180
GPE1_STS Events to IRQ Enable Low Register (GPE1_2IRQ_LOW) ..................... 181
GPE1_STS Events to IRQ Enable High Register (GPE1_2IRQ_HIGH) ................... 182
GPE1_STS Events to SMI Enable Low Register (GPE1_2SMI_LOW) ..................... 183
GPE1_STS Events to SMI Enable High Register (GPE1_2SMI_HIGH) ................... 184
SWC Fast Disable Register (SWCFDIS) ................................................................... 185
SWC TRI-STATE Register (SWCTRIS) .................................................................... 186
SWC Miscellaneous Control Register (SWC_CTL) ................................................... 187
Power On Control Register (PWONCTL) .................................................................. 188
LED Control Register (LEDCTL) ............................................................................... 190
LED Blink Control Register (LEDBLNK) .................................................................... 191
BIOS General-Purpose Scratch Register (BIOSGPR) .............................................. 191
Bank Select Register (BANKSEL) ............................................................................. 192
Keyboard Wake-Up Control Register (KBDWKCTL) ................................................. 193
PS2 Protocol Control Register (PS2CTL) .................................................................. 194
Keyboard Data Shift Register (KDSR) ....................................................................... 195
Mouse Data Shift Register (MDSR) ........................................................................... 195
PS2 Keyboard Key Data 0 to 7 Registers (PS2KEY0 to PS2KEY7) ......................... 195
VDD Active Timer 0 Register (VDD_ON_TMR_0) .................................................... 196
VDD Active Timer 1 Register (VDD_ON_TMR_1) .................................................... 196
VDD Active Timer 2 Register (VDD_ON_TMR_2) .................................................... 196
VDD Active Timer 3 Register (VDD_ON_TMR_3) .................................................... 197
VSB Active Timer 0 Register (VSB_ON_TMR_0) ..................................................... 197
VSB Active Timer 1 Register (VSB_ON_TMR_1) ..................................................... 197
VSB Active Timer 2 Register (VSB_ON_TMR_2) ..................................................... 198
VSB Active Timer 3 Register (VSB_ON_TMR_3) ..................................................... 198
Power Active Timers Control Register (PWTMRCTL) ............................................... 199
S0 to S5 Sleep Type Encoding Registers (S0_SLP_TYP to S5_SLP_TYP) ............. 199
Sleep State Configuration Register (SLP_ST_CFG) ................................................. 200
ACPI Configuration Register (ACPI_CFG) ................................................................ 201
Watchdog Control Register (WDCTL) ....................................................................... 202
Watchdog Time-Out Register (WDTO) ...................................................................... 202
Watchdog Configuration Register (WDCFG) ............................................................. 203
ACPI REGISTERS ................................................................................................................... 204
9.4.1
ACPI Register Map .................................................................................................... 204
9.4.2
PM1 Status Low Register (PM1b_STS_LOW) .......................................................... 205
9.4.3
PM1 Status High Register (PM1b_STS_HIGH) ........................................................ 205
9.4.4
PM1 Enable Low Register (PM1b_EN_LOW) ........................................................... 206
9.4.5
PM1 Enable High Register (PM1b_EN_HIGH) ......................................................... 207
9.4.6
PM1 Control Low Register (PM1b_CNT_LOW) ........................................................ 208
9.4.7
PM1 Control High Register (PM1b_CNT_HIGH) ....................................................... 208
9.4.8
General-Purpose Status 1 Register 0 (GPE1_STS_0) .............................................. 209
9.4.9
General-Purpose Status 1 Register 1 (GPE1_STS_1) .............................................. 209
9.4.10 General-Purpose Status 1 Register 2 (GPE1_STS_2) .............................................. 210
9.4.11 General-Purpose Status 1 Register 3 (GPE1_STS_3) .............................................. 211
13
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PC8741x
Table of Contents
PC8741x
Table of Contents
9.4.12
9.4.13
9.4.14
9.4.15
9.5
(Continued)
General-Purpose Enable 1 Register 0 (GPE1_EN_0)
General-Purpose Enable 1 Register 1 (GPE1_EN_1)
General-Purpose Enable 1 Register 2 (GPE1_EN_2)
General-Purpose Enable 1 Register 3 (GPE1_EN_3)
............................................... 213
............................................... 213
............................................... 214
............................................... 215
SYSTEM WAKE-UP CONTROL REGISTERS BITMAP ......................................................... 216
10.0 Legacy Functional Blocks
10.1
FLOPPY DISK CONTROLLER (FDC) .................................................................................... 220
10.1.1 General Description ................................................................................................... 220
10.1.2 FDC Bitmap Summary ............................................................................................... 221
10.2
PARALLEL PORT ................................................................................................................... 222
10.2.1 General Description ................................................................................................... 222
10.2.2 Parallel Port Register Map ......................................................................................... 222
10.2.3 Parallel Port Bitmap Summary .................................................................................. 223
10.3
SERIAL PORTS (SP1 AND SP2) ............................................................................................ 225
10.3.1 General Description ................................................................................................... 225
10.3.2 Register Bank Overview ............................................................................................ 225
10.3.3 SP1/SP2 Register Maps ............................................................................................ 226
10.3.4 SP1 Bitmap Summary ............................................................................................... 227
10.4
KEYBOARD AND MOUSE CONTROLLER (KBC) ................................................................. 229
10.4.1 General Description ................................................................................................... 229
10.4.2 KBC Register Map ..................................................................................................... 230
10.4.3 KBC Bitmap Summary ............................................................................................... 230
11.0 Device Characteristics
11.1
GENERAL DC ELECTRICAL CHARACTERISTICS .............................................................. 231
11.1.1 Recommended Operating Conditions ....................................................................... 231
11.1.2 Absolute Maximum Ratings ....................................................................................... 231
11.1.3 Capacitance .............................................................................................................. 232
11.1.4 Power Consumption under Recommended Operating Conditions ............................ 232
11.1.5 Voltage Thresholds .................................................................................................... 232
11.2
DC CHARACTERISTICS OF PINS, BY I/O BUFFER TYPES ............................................... 233
11.2.1 Input, CMOS Compatible with Schmitt Trigger .......................................................... 233
11.2.2 Input, PCI 3.3V .......................................................................................................... 233
11.2.3 Input, SMBus Compatible .......................................................................................... 233
11.2.4 Input, TTL Compatible ............................................................................................... 234
11.2.5 Input, TTL Compatible with Schmitt Trigger .............................................................. 234
11.2.6 Output, TTL Compatible Push-Pull Buffer ................................................................. 234
11.2.7 Output, Open-Drain Buffer ......................................................................................... 235
11.2.8 Output, PCI 3.3V ....................................................................................................... 235
11.2.9 Exceptions ................................................................................................................. 235
11.2.10 Terminology ............................................................................................................... 235
11.3
INTERNAL RESISTORS ........................................................................................................ 236
11.3.1 Pull-Up Resistor ......................................................................................................... 237
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14
Revision 1.2
11.3.2
(Continued)
Pull-Down Resistor .................................................................................................... 237
11.4
PACKAGE THERMAL INFORMATION ................................................................................... 237
11.5
AC ELECTRICAL CHARACTERISTICS ................................................................................. 238
11.5.1 AC Test Conditions .................................................................................................... 238
11.5.2 Reset Timing ............................................................................................................. 239
11.5.3 Clock Timing .............................................................................................................. 241
11.5.4 LPC Interface Timing ................................................................................................ 243
11.5.5 X-Bus Extension Timing (PC87416 and PC87417) ................................................. 245
11.5.6 ACCESS.bus Timing (PC87413 and PC87417) ........................................................ 246
11.5.7 FDC Timing ............................................................................................................... 248
11.5.8 Parallel Port Timing ................................................................................................... 250
11.5.9 Serial Ports 1 and 2 Timing ...................................................................................... 252
11.5.10 SWC Timing ............................................................................................................. 253
Revision 1.2
15
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PC8741x
Table of Contents
CONNECTION DIAGRAMS
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
43
42
41
40
39
STEP
WDATA
WGATE
TRK0
WP
RDATA
HDSEL
DSKCHG
GPIO55/CLKIN
GPO64/WDO/CKIN48
GPIO54/VDDFELL
GPIOE47/SLPS5
GPIOE46/SLPS3
GPIOE45/LED2
GPIOE44/LED1
GPIOE43/PWBTOUT
GPO63/ACBSA
ACBCLK
ACBDAT
GPIO53/LFCKOUT/MSEN0
32KX2
VSS
32KX1_32KCLKIN
VBAT
VSB
ONCTL
1.1
Signal/Pin Connection and Description
MTR0
INDEX
DRATE0
DENSEL
SLCT
PE
BUSY_WAIT
ACK
PD7
PD6
PD5
PD4
PD3
SLIN_ASTRB
PD2
INIT
PD1
ERR
PD0
AFD_DSTRB
STB_WRITE
VDD
VSS
DCD1
DSR1
SIN1
RTS1/TRIS
SOUT1
CTS1
DTR1_BOUT1/BADDR
RI1
DCD2
65
66
67
38
37
36
35
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
34
33
32
PC87413-xxx/VLA
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
DIR
MTR1/P17
DR0
VSS
VDD
DR1/P16
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
GPIO52/SIOSCI
GPIO51/SIOSMI
GPIO50/PWBTIN
GPIOE42/SLBTIN
GPO62
GPO61
GPO60
GPIO37
GPIO36
GPIO35
GPIO34
GPIO33
GPIO32
GPIO31
GPIO30
GPIO27
GPIO26
GPIOE41
GPIOE40
GPIO25
GPIO24
GPIO23
GPIO22
GPIO21
GPIO20
GPIO07/HFCKOUT
VSB
VSS
GPIO06
GPIO05
GPIOE17
GPIOE16
GPIOE15
GPIOE14
GPIOE13
GPIOE12
GPIOE11
GPIOE10
DSR2
SIN2
RTS2
SOUT2
CTS2
DTR2_BOUT2
RI2
LAD3
LAD2
LAD1
LAD0
LCLK
VSS
VDD
LFRAME
LDRQ
SERIRQ
LRESET
P12/PPDIS
KBRST
GA20
GPIO00/CLKRUN
GPIO01/KBCLK
GPIO02/KBDAT
GPIO03/MCLK
GPIO04/MDAT
PC8741x
1.0
Plastic Quad Flatpack (PQFP), JEDEC
Order Number PC87413-xxx/VLA
See NS Package Number VLA128A
xxx = Three-character identifier for National data, keyboard ROM and/or customer identification code.
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16
Revision1.2
PC8741x
(Continued)
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
43
42
41
40
39
STEP
WDATA
WGATE
TRK0
WP
RDATA
HDSEL
DSKCHG
GPIO55/CLKIN
GPO64/WDO/CKIN48
GPIO54/VDDFELL
GPIOE47/SLPS5
GPIOE46/SLPS3
GPIOE45/LED2
GPIOE44/LED1
GPIOE43/PWBTOUT
GPO63
NC
NC
GPIO53/LFCKOUT/MSEN0
32KX2
VSS
32KX1_32KCLKIN
VBAT
VSB
ONCTL
1.0 Signal/Pin Connection and Description
MTR0
INDEX
DRATE0
DENSEL
SLCT
PE
BUSY_WAIT
ACK
PD7
PD6
PD5
PD4
PD3
SLIN_ASTRB
PD2
INIT
PD1
ERR
PD0
AFD_DSTRB
STB_WRITE
VDD
38
37
36
35
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
34
33
32
PC87414-xxx/VLA
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
GPIO52/SIOSCI
GPIO51/SIOSMI
GPIO50/PWBTIN
GPIOE42/SLBTIN
GPO62
GPO61
GPO60
GPIO37
GPIO36
GPIO35
GPIO34
GPIO33
GPIO32
GPIO31
GPIO30
GPIO27
GPIO26
GPIOE41
GPIOE40
GPIO25
GPIO24
GPIO23
GPIO22
GPIO21
GPIO20
GPIO07/HFCKOUT
VSB
VSS
GPIO06
GPIO05
GPIOE17
GPIOE16
GPIOE15
GPIOE14
GPIOE13
GPIOE12
GPIOE11
GPIOE10
DSR2
SIN2
RTS2
SOUT2
CTS2
DTR2_BOUT2
RI2
LAD3
LAD2
LAD1
LAD0
LCLK
VSS
VDD
LFRAME
LDRQ
SERIRQ
LRESET
P12/PPDIS
KBRST
GA20
GPIO00/CLKRUN
GPIO01/KBCLK
GPIO02/KBDAT
GPIO03/MCLK
GPIO04/MDAT
VSS
DCD1
DSR1
SIN1
RTS1/TRIS
SOUT1
CTS1
DTR1_BOUT1/BADDR
RI1
DCD2
65
66
67
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
DIR
MTR1/P17
DR0
VSS
VDD
DR1/P16
NC - Not Connected (these pins should be left unconnected)
Plastic Quad Flatpack (PQFP), JEDEC
Order Number PC87414-xxx/VLA
See NS Package Number VLA128A
xxx = Three-character identifier for National data, keyboard ROM and/or customer identification code.
Revision 1.2
17
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64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
43
42
41
40
39
STEP
WDATA
WGATE
TRK0
WP
RDATA
HDSEL
DSKCHG
GPIO55/CLKIN
GPO64/WDO/CKIN48
GPIO54/VDDFELL
GPIOE47/SLPS5
GPIOE46/SLPS3
GPIOE45/LED2
GPIOE44/LED1
GPIOE43/PWBTOUT
GPO63
NC
NC
GPIO53/LFCKOUT/MSEN0
32KX2
VSS
32KX1_32KCLKIN
VBAT
VSB
ONCTL
(Continued)
MTR0
INDEX
DRATE0
DENSEL
SLCT
PE
BUSY_WAIT
ACK
PD7
PD6
PD5
PD4
PD3
SLIN_ASTRB
PD2
INIT
PD1
ERR
PD0
AFD_DSTRB
STB_WRITE
VDD
VSS
DCD1
DSR1
SIN1
RTS1/TRIS
SOUT1
CTS1
DTR1_BOUT1/BADDR
RI1
DCD2
65
66
67
38
37
36
35
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
34
33
32
PC87416-xxx/VLA
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
DIR
MTR1/P17
DR0
VSS
VDD
DR1/P16
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
GPIO52/SIOSCI
GPIO51/SIOSMI
GPIO50/PWBTIN
GPIOE42/SLBTIN
GPO62/XSTB0/XCNF0
GPO61/XSTB1/XCNF1
GPO60/XSTB2/XCNF2
GPIO37/XD0
GPIO36/XD1
GPIO35/XD2
GPIO34/XD3
GPIO33/XD4
GPIO32/XD5
GPIO31/XD6
GPIO30/XD7
GPIO27/XCS0
GPIO26/XCS1
GPIOE41/XCS2
GPIOE40/XCS3
GPIO25/XA0
GPIO24/XA1
GPIO23/XA2
GPIO22/XA3
GPIO21/XWR_XRW
GPIO20/XRD_XEN
GPIO07/HFCKOUT
VSB
VSS
GPIO06/XIRQ
GPIO05/XRDY
GPIOE17/XA4
GPIOE16/XA5
GPIOE15/XA6
GPIOE14/XA7
GPIOE13/XA8
GPIOE12/XA9
GPIOE11/XA10
GPIOE10/XA11
DSR2
SIN2
RTS2
SOUT2
CTS2
DTR2_BOUT2
RI2
LAD3
LAD2
LAD1
LAD0
LCLK
VSS
VDD
LFRAME
LDRQ
SERIRQ
LRESET
P12/PPDIS
KBRST
GA20
GPIO00/CLKRUN
GPIO01/KBCLK
GPIO02/KBDAT
GPIO03/MCLK
GPIO04/MDAT
PC8741x
1.0 Signal/Pin Connection and Description
NC - Not Connected (these pins should be left unconnected)
Plastic Quad Flatpack (PQFP), JEDEC
Order Number PC87416-xxx/VLA
See NS Package Number VLA128A
xxx = Three-character identifier for National data, keyboard ROM and/or customer identification code.
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18
Revision1.2
PC8741x
(Continued)
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
43
42
41
40
39
STEP
WDATA
WGATE
TRK0
WP
RDATA
HDSEL
DSKCHG
GPIO55/CLKIN
GPO64/WDO/CKIN48
GPIO54/VDDFELL
GPIOE47/SLPS5
GPIOE46/SLPS3
GPIOE45/LED2
GPIOE44/LED1
GPIOE43/PWBTOUT
GPO63/ACBSA
ACBCLK
ACBDAT
GPIO53/LFCKOUT/MSEN0
32KX2
VSS
32KX1_32KCLKIN
VBAT
VSB
ONCTL
1.0 Signal/Pin Connection and Description
MTR0
INDEX
DRATE0
DENSEL
SLCT
PE
BUSY_WAIT
ACK
PD7
PD6
PD5
PD4
PD3
SLIN_ASTRB
PD2
INIT
PD1
ERR
PD0
AFD_DSTRB
STB_WRITE
VDD
38
37
36
35
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
34
33
32
PC87417-xxx/VLA
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
GPIO52/SIOSCI
GPIO51/SIOSMI
GPIO50/PWBTIN
GPIOE42/SLBTIN
GPO62/XSTB0/XCNF0
GPO61/XSTB1/XCNF1
GPO60/XSTB2/XCNF2
GPIO37/XD0
GPIO36/XD1
GPIO35/XD2
GPIO34/XD3
GPIO33/XD4
GPIO32/XD5
GPIO31/XD6
GPIO30/XD7
GPIO27/XCS0
GPIO26/XCS1
GPIOE41/XCS2
GPIOE40/XCS3
GPIO25/XA0
GPIO24/XA1
GPIO23/XA2
GPIO22/XA3
GPIO21/XWR_XRW
GPIO20/XRD_XEN
GPIO07/HFCKOUT
VSB
VSS
GPIO06/XIRQ
GPIO05/XRDY
GPIOE17/XA4
GPIOE16/XA5
GPIOE15/XA6
GPIOE14/XA7
GPIOE13/XA8
GPIOE12/XA9
GPIOE11/XA10
GPIOE10/XA11
DSR2
SIN2
RTS2
SOUT2
CTS2
DTR2_BOUT2
RI2
LAD3
LAD2
LAD1
LAD0
LCLK
VSS
VDD
LFRAME
LDRQ
SERIRQ
LRESET
P12/PPDIS
KBRST
GA20
GPIO00/CLKRUN
GPIO01/KBCLK
GPIO02/KBDAT
GPIO03/MCLK
GPIO04/MDAT
VSS
DCD1
DSR1
SIN1
RTS1/TRIS
SOUT1
CTS1
DTR1_BOUT1/BADDR
RI1
DCD2
65
66
67
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
DIR
MTR1/P17
DR0
VSS
VDD
DR1/P16
Plastic Quad Flatpack (PQFP), JEDEC
Order Number PC87417-xxx/VLA
See NS Package Number VLA128A
xxx = Three-character identifier for National data, keyboard ROM and/or customer identification code.
Revision 1.2
19
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PC8741x
1.0 Signal/Pin Connection and Description
1.2
(Continued)
BUFFER TYPES AND SIGNAL/PIN DIRECTORY
The signal DC characteristics of the pins described in Section 1.4 are denoted by buffer type symbols, which are defined in
Table 1 and described in further detail in Section 11.2. The pin multiplexing information refers to two different types of multiplexing:
●
Multiplexed, denoted by a slash (/) between pins in the diagrams in Section 1.1. Pins are shared between two different functions. Each function is associated with different board connectivity. Normally, the function selection is determined by the board design and cannot be changed dynamically. The multiplexing options must be configured by the
BIOS upon power-up in order to comply with the board implementation.
●
Multiple Mode, denoted by an underscore (_) between pins in the diagrams in Section 1.1. Pins have two or more
modes of operation within the same function. These modes are associated with the same external (board)
connectivity. Mode selection may be controlled by the device driver through the registers of the functional block and
do not require a special BIOS setup upon power-up. These pins are not considered multiplexed pins from the
ServerI/O configuration perspective. The mode selection method (registers and bits), as well as the signal specification in each mode, are described within the functional description of the relevant functional block.
Table 1. Buffer Types
Symbol
1.3
Description
INCS
Input, CMOS compatible, with Schmitt Trigger
INOSC
Input, from crystal oscillator (not characterized)
INPCI
Input, PCI 3.3V
INSM
Input, ACCESS.bus and SMBus compatible
INT
Input, TTL compatible
INTS
Input, TTL compatible, with Schmitt Trigger
INULR
Input, power, resistor protected (not characterized)
Op/n
Output, push-pull output buffer capable of sourcing p mA and sinking n mA
ODn
Output, open-drain output buffer capable of sinking n mA
OOSC
Output, to crystal oscillator (not characterized)
OPCI
Output, PCI 3.3V
PWR
Power pin
GND
Ground pin
PIN MULTIPLEXING
The table below shows only multiplexed pins, their associated functional blocks and the configuration bits for the selection
of the multiplexed options used in the PC8741x. Some PC8741x devices implement a subset of these signals. Refer to
Device-Specific Information on page 4 to identify the functions relevant to a specific device.
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20
Revision1.2
PC8741x
1.0 Signal/Pin Connection and Description
(Continued)
Table 2. Pin Multiplexing Configuration
Pin
Functional
Block
Signal
Functional
Block
Signal
Functional
Strap/Wake-up Configuration Select
Block
1
GPIOE10
XA11
GPIOE10
2
GPIOE11
XA10
GPIOE11
3
GPIOE12
XA9
GPIOE12
4
GPIOE13
XA8
GPIOE13
SWC
5
GPIOE14
6
SIOCF4.NOADDIR
XA7
GPIOE14
GPIOE15
XA6
GPIOE15
7
GPIOE16
XA5
GPIOE16
8
GPIOE17
XA4
GPIOE17
9
GPIO05
XRDY
SIOCF4.XRDYMUX
10
GPIO06
XIRQ
SIOCF5.XIRQMUX
13
GPIO07
HFCKOUT
SIOCF4.HFCKMUX
14
GPIO20
XRD_XEN
15
GPIO21
XWR_XRW
16
GPIO22
XA3
17
GPIO23
XA2
GPIO24
XA1
19
GPIO25
XA0
22
GPIO26
XCS1
SIOCF5.XCS1MUX
23
GPIO27
XCS0
SIOCF5.XCS0MUX
20
GPIOE40
XCS3
X-Bus
CLKGEN
SIOCF4.NOXBUS
18
GPIO
GPIOE40
SIOCF5.XCS3MUX
GPIOE41
SIOCF5.XCS2MUX
SWC
XCS2
21
GPIOE41
24
GPIO30
25
GPIO31
XD6
26
GPIO32
XD5
27
GPIO33
XD4
28
GPIO34
XD3
29
GPIO35
XD2
30
GPIO36
XD1
31
GPIO37
XD0
32
GPO60
XSTB2
33
GPO61
XSTB1
34
GPO62
XSTB0
X-Bus
XD7
SIOCF4.NOXBUS
Revision 1.2
Straps
21
XCNF2
SIOCF5.XSTB2MUX
XCNF1
SIOCF5.XSTB1MUX
XCNF0
SIOCF5.XSTB0MUX
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PC8741x
1.0 Signal/Pin Connection and Description
(Continued)
Table 2. Pin Multiplexing Configuration (Continued)
Pin
Functional
Block
Signal
35
GPIOE42
36
GPIO50
Functional
Block
Signal
SLBTIN
Functional
Strap/Wake-up Configuration Select
Block
SWC
GPIOE42
SIOCF3.SLBTIMUX
PWBTIN
SIOCF3.PWBTIMUX
SWC
37
GPIO51
SIOSMI
SIOCF3.SMIMUX
38
GPIO52
SIOSCI
SIOCF3.SCIMUX
45
GPIO53
48
CLKGEN
LFCKOUT
FDC
MSEN0
SIOCF4.LFCKMUX
GPO63
49
Straps
ACBSA
GPIOE43
PWBTOUT
GPIOE43
SIOCF3.PWBTOMUX
50
GPIOE44
LED1
GPIOE44
SIOCF3.LED1MUX
51
GPIOE45
LED2
GPIOE45
SIOCF3.LED2MUX
52
GPIOE46
SLPS3
GPIOE46
SIOCF3.EXTSTMUX
53
GPIOE47
SLPS5
GPIOE47
SIOCF3.EXTSTMUX
54
GPIO54
VDDFELL
55
GPO64
WDO
56
GPIO55
GPIO
SWC
CLKGEN
MTR1
66
SWC
SIOCF2.VDDFLMUX
Straps
CKIN48
SIOCF2.WDOMUX
CLKIN
CLOCKCF.CKIN48
P17
SIOCF2.P17MUX
P16
SIOCF2.P16MUX
KBC
FDC
70
DR1
97
RTS1
TRIS
Straps
100 Serial Port 1 DTR1_BOUT1
101
BADDR
RI1
RI1
SWC
109 Serial Port 2 RI2
RI2
121 Parallel Port PPDIS
KBC
P12
SIOCF2.P12MUX
124
GPIO00
LPC I/F
CLKRUN
SIOCF2.CLKRNMUX
125
GPIO01
126 GPIO
GPIO02
KBCLK
KBCLK
KBDAT
KBDAT
KBC
SWC
SIOCF2.NOKBC
127
GPIO03
MCLK
MCLK
128
GPIO04
MDAT
MDAT
1.4
DETAILED SIGNAL/PIN DESCRIPTIONS
This section describes all the signals of the PC8741x devices. Some PC8741x devices implement a subset of these signals. Refer to Device-Specific Information on page 4 to identify the functions relevant to a specific device. Device signals
are organized by functional group.
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22
Revision1.2
1.4.1
PC8741x
1.0 Signal/Pin Connection and Description
(Continued)
LPC Interface
Signal
Pin(s)
I/O Buffer Type Power Well
Description
LAD3-01
110-113 I/O
INPCI/OPCI
VDD
LPC Address-Data. Multiplexed command, address bidirectional
data and cycle status.
LCLK1
114
I
INPCI
VDD
LPC Clock. Derived from the PCI clock (up to 33 MHz).
LFRAME1
117
I
INPCI
VDD
LPC Frame. Low pulse indicates the beginning of a new LPC cycle or termination of a broken cycle.
LDRQ1
118
O
OPCI
VDD
LPC DMA Request. Encoded DMA request for LPC Interface.
LRESET1
120
I
INPCI
VDD
LPC Reset. Derived from the PCI system reset.
SERIRQ1
119
I/O
INPCI/OPCI
VDD
Serial IRQ. The interrupt requests are serialized over a single pin,
where each IRQ level is delivered during a designated time slot.
CLKRUN1
124
I/OD INPCI/OD6
VDD
Clock Run. Indicates that LCLK is going to be stopped and requests full-speed LCLK (same behavior as PCI CLKRUN).
1. This pin is neither 5-Volt tolerant, nor back-drive protected.
1.4.2
ACCESS.bus (ACB) Interface (PC87413 and PC87417)
Signal
Pin(s)
I/O Buffer Type Power Well
Description
ACBCLK
47
I/O
INSM/OD6
VSB
ACCESS.bus Clock. An internal pull-up for this pin is optional.
ACBDAT
46
I/O
INSM/OD6
VSB
ACCESS.bus Serial Data. An internal pull-up for this pin is
optional.
1.4.3
X-Bus Extension (PC87416 and PC87417)
Signal
XRD_XEN
Pin/s
I/O Buffer Type Power Well
Description
14
O
O3/6
VSB
Read. Active (low) level indicates read cycle on the X-Bus.
Enable. Active (high) level indicates valid data on the X-Bus.
XWR_XRW 15
O
O3/6
VSB
Write. Active (low) level indicates a write cycle on the X-Bus.
Read/Write. A high level indicates a read cycle on the X-Bus; a
low level indicates a write cycle on the X-Bus.
XD7-0
24-31
I/O
INTS/O3/6
VSB
Data Bus. 8-bit data multiplexed with the address lines XA27-4.
XA11-4,
XA3-0
1-8
16-19
O
O3/6
VSB
Address Bus. The XA27-12 address lines are always multiplexed
with the data lines.
XSTB2-0
32-34
O
O3/6
VSB
Address Strobes. Control the strobe of up to three external
latches for the multiplexed address lines.
XCS3-0
20-23
O
O3/6
VSB
Chip Selects. Control the selection of up to four devices residing
on the X-Bus.
XRDY
9
I
INTS
VSB
I/O Ready. Instructs the PC8741x to extend the access cycle.
XIRQ
10
I
INTS
VSB
X-Bus Interrupt. Converted into serial interrupt by the Interrupt
Serializer. The system configuration includes the interrupt number
associated with this signal.
Revision 1.2
23
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PC8741x
1.0 Signal/Pin Connection and Description
1.4.4
(Continued)
Serial Port 1 and Serial Port 2 (UART1 and UART2)
Signal
Pin/s
I/O Buffer Type Power Well
Description
CTS1
CTS2
99
107
I
INTS
VDD
Clear to Send. When low, indicates that the modem or other data
transfer device is ready to exchange data.
DCD1
DCD2
94
102
I
INTS
VDD
Data Carrier Detected. When low, indicates that the modem or
other data transfer device has detected the data carrier.
DSR1
DSR2
95
103
I
INTS
VDD
Data Set Ready. When low, indicates that the data transfer device,
e.g., modem, is ready to establish a communications link.
O
O3/6
VDD
Data Terminal Ready. When low, indicates to the modem or other
data transfer device that the UART is ready to establish a
communications link. After a system reset, these pins provide the
DTR function and set these signals to inactive high. Loopback
operation holds them inactive.
Baud Output. Provides the associated serial channel baud rate
generator output signal if Test mode is selected, i.e., bit 7 of the
EXCR1 register is set.
DTR1_
BOUT1
100
DTR2_
BOUT2
108
RI1
RI2
101
109
I
INTS
VDD
Ring Indicator. When low, indicates that a telephone ring signal
has been received by the modem. These pins are monitored
during VDD power-off for wake-up event detection.
RTS1
RTS2
97
105
O
O3/6
VDD
Request to Send. When low, indicates to the modem or other
data transfer device that the corresponding UART is ready to
exchange data. A system reset sets these signals to inactive high,
and loopback operation holds them inactive.
SIN1
SIN2
96
104
I
INTS
VDD
Serial Input. Receives composite serial data from the
communications link (peripheral device, modem or other data
transfer device).
SOUT1
SOUT2
98
106
O
O3/6
VDD
Serial Output. Sends composite serial data to the communications
link (peripheral device, modem or other data transfer device).
These signals are set active high after a system reset.
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24
Revision1.2
1.4.5
(Continued)
Parallel Port
Signal
ACK
PC8741x
1.0 Signal/Pin Connection and Description
Pin/s
I/O Buffer Type Power Well
Description
78
I
INT
VDD
Acknowledge. Pulsed low by the printer to indicate that it has
received data from the parallel port.
AFD_DSTRB 90
O
OD14, O14/14
VDD
AFD - Automatic Feed. When low, instructs the printer to
automatically feed a line after printing each line. This pin is in
TRI-STATE after a 0 is loaded into the corresponding control
register bit. An external 4.7 KΩ pull-up resistor must be
connected to this pin.
DSTRB - Data Strobe (EPP). Active low, used in EPP mode
to denote a data cycle. When the cycle is aborted, DSTRB
becomes inactive (high).
BUSY_WAIT 77
I
INT
VDD
Busy. Set high by the printer when it cannot accept another
character.
Wait. In EPP mode, the parallel port device uses this active
low signal to extend its access cycle.
ERR
88
I
INT
VDD
Error. Set active low by the printer when it detects an error.
INIT
86
O
OD14, O14/14
VDD
Initialize. When low, initializes the printer. This signal is in
TRI-STATE after a 1 is loaded into the corresponding control
register bit. An external 4.7 KΩ pull-up resistor must be
connected to this pin.
PD7-3
PD2
PD1
PD0
79-83
85
87
89
I/O
INT/O14/14
VDD
PE
76
I
INT
VDD
Paper End. Set high by the printer when it is out of paper. This
pin has an internal weak pull-up or pull-down resistor.
SLCT
75
I
INT
VDD
Select. Set active high by the printer when the printer is
selected.
SLIN_ASTRB 84
O
OD14, O14/14
VDD
SLIN - Select Input. When low, selects the printer. This signal
is in TRI-STATE after a 0 is loaded into the corresponding
control register bit. An external 4.7 KΩ pull-up resistor must be
connected to this pin.
ASTRB - Address Strobe (EPP). Active low, used in EPP
mode to denote an address or data cycle. When the cycle is
aborted, ASTRB becomes inactive (high).
STB_WRITE 91
O
OD14, O14/14
VDD
STB - Data Strobe. When low, Indicates to the printer that
valid data is available at the printer port. This signal is in
TRI-STATE after a 0 is loaded into the corresponding control
register bit. An external 4.7 KΩ pull-up resistor must be
connected to this pin.
WRITE - Write Strobe. Active low, used in EPP mode to
denote an address or data cycle. When the cycle is aborted,
WRITE becomes inactive (high).
I
INT
VDD
Parallel Port Disable. When high, this input disables (TRISTATEs) all the output signals of the parallel port.1
PPDIS
121
Parallel Port Data. Transfers data to and from the peripheral
data bus and the appropriate parallel port data register. These
signals have a high current drive capability.
1. If this feature is not used, either select the alternate function (P12 port) at the pin multiplexer (see Section 3.7.3
on page 50) or connect an external 3.3 KΩ pull-down resistor to this pin. If the function connected to the
pin is PPDIS and the pin is left unconnected, the output signals of the parallel port will float.
Revision 1.2
25
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PC8741x
1.0 Signal/Pin Connection and Description
1.4.6
(Continued)
Floppy Disk Controller (FDC)
Signal
Pin(s)
I/O Buffer Type Power Well
Description
DENSEL
74
O
O2/12
VDD
Density Select. Indicates that a high FDC density data rate (500
Kbps, 1 Mbps or 2 Mbps) or a low density data rate (250 or 300
Kbps) is selected.
DIR
65
O
OD12, O2/12
VDD
Direction. Determines the direction of the Floppy Disk Drive
(FDD) head movement (active = step in; inactive = step out)
during a seek operation.
DR1
70
OD12, O2/12
VDD
Drive Select. Decoded output signals in Two-Drive mode or
encoded signals in Four-Drive mode. Controlled by bits 1 and 0 of
the Digital Output Register (DOR).
O
DR0
67
DRATE0
73
O
O3/6
VDD
Data Rate. Reflects the value of bit 0 of the Configuration Control
Register (CCR) or the Data Rate Select Register (DSR), whichever
was written to last.
DSKCHG
57
I
INT
VDD
Disk Change. Indicates if the drive door has been opened.
HDSEL
58
O
OD12, O2/12
VDD
Head Select. Determines which side of the FDD is accessed.
Active low selects side 1; inactive selects side 0.
INDEX
72
I
INT
VDD
Index. Indicates the beginning of an FDD track.
MSEN0
45
I
INT
VDD
Automatic Media Sense. Identifies the media type of the floppy
disk in drives 1 and 0 (if the drives support this protocol).
MTR1
66
OD12, O2/12
VDD
Motor Select. Active low, motor enable lines for drives 1 and 0,
controlled by bits D7-4 of the Digital Output Register (DOR). MTR0 is
used to decode DR1 and DR0 in Four-Drive mode.
O
MTR0
71
RDATA
59
I
INT
VDD
Read Data. Raw serial input data stream read from the FDD.
STEP
64
O
OD12, O2/12
VDD
Step. Issues pulses to the disk drive at a software programmable
rate to move the head during a seek operation.
TRK0
61
I
INT
VDD
Track 0. Indicates to the controller that the head of the selected
floppy disk drive is at track 0.
WDATA
63
O
OD12, O2/12
VDD
Write Data. Carries out the pre-compensated serial data that is
written to the FDD. Pre-compensation is software selectable.
WGATE
62
O
OD12, O2/12
VDD
Write Gate. Enables the write circuitry of the selected FDD.
WGATE is designed to prevent glitches during power-up and
power-down. This prevents writing to the disk when power is
cycled.
WP
60
I
INT
VDD
Write Protected. Indicates that the disk in the selected drive is
write protected.
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26
Revision1.2
1.4.7
PC8741x
1.0 Signal/Pin Connection and Description
(Continued)
Keyboard and Mouse Controller (KBC)
Signal
Pin/s
I/O Buffer Type Power Well
Description
KBCLK
125
I/O
INTS/OD14
VDD
Keyboard Clock. Keyboard clock signal. External pull-up resistor
is required for PS/2 compliance. This pin is monitored during VDD
power-off for wake-up event detection.
KBDAT
126
I/O
INTS/OD14
VDD
Keyboard Data. Keyboard data signal. External pull-up resistor is
required for PS/2 compliance. This pin is monitored during VDD
power-off for wake-up event detection.
MCLK
127
I/O
INTS/OD14
VDD
Mouse Clock. Mouse clock signal. External pull-up resistor is
required for PS/2 compliance. This pin is monitored during VDD
power-off for wake-up event detection.
MDAT
128
I/O
INTS/OD14
VDD
Mouse Data. Mouse data signal. External pull-up resistor is
required for PS/2 compliance. This pin is monitored during VDD
power-off for wake-up event detection.
KBRST
122
I/O
INT/OD2
VDD
KBD Reset. Keyboard reset (P20) open-drain output.
GA20
123
I/O
INT/OD2
VDD
Gate A20. KBC gate A20 (P21) open-drain output.
P12,
P16, P17
121,
70, 66
I/O
INT/OD2,
O2/2
VDD
I/O Port. KBC quasi-bidirectional signal for general-purpose input
and output (controlled by KBC firmware).
1.4.8
General-Purpose I/O (GPIO)
Signal
GPIO01-04
Pin(s)
125-128
GPIOE44, 45 50, 51
I/O Buffer Type Power Well
I/O
INTS/
OD14, O3/14
VSB
I/O
INTS/
OD12, O12/12
VSB
I/O
INTS/
OD4, O2/4
VSB
I/O
INTS/
OD2, O1/2
VSB
GPIO07
13
GPIO53
45
GPIO00,
GPIO05-06,
GPIOE10-17,
GPIO20-25,
GPIO26-27,
GPIO30-37,
GPIOE40-41,
GPIOE42, 43,
GPIOE46, 47,
GPIO50-52,
GPIO54, 55
124
9-10
1-8
14-19
22-23
24-31
2-21
35, 49
52, 53
36-38
54, 56
I/O
INTS/
OD6, O3/6
VSB
GPO60-62,
63, 64
32-34,
48, 55
O
OD6, O3/6
VSB
Revision 1.2
Description
General-Purpose I/O Ports. Each pin is configured
independently as input or I/O with or without static pull-up and
with either open-drain or push-pull output type. The GPIOEnn
pins have event detection capability.
General-Purpose Output Ports. Each pin is configured
independently for either open-drain or push-pull output type.
27
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PC8741x
1.0 Signal/Pin Connection and Description
1.4.9
(Continued)
System Wake-Up Control (SWC)
Signal
Pin(s)
I/O Buffer Type
Power
Well
Description
INTS
VSB
I
INTS
VSB
Ring Indicator Wake-up. When low, generates a wake-up
event or an interrupt, indicating that a telephone ring signal was
received by the modem.
125
I/O
INTS/OD14
VSB
Keyboard Clock Wake-up. Generates a wake-up event or an
interrupt, indicating a change in the keyboard clock signal.
KBDAT
126
I/O
INTS/OD14
VSB
Keyboard Data Wake-up. Generates a wake-up event or an
interrupt, indicating a change in the keyboard data signal.
MCLK
127
I/O
INTS/OD14
VSB
Mouse Clock Wake-up. Generates a wake-up event or an
interrupt, indicating a change in the mouse clock signal.
MDAT
128
I/O
INTS/OD14
VSB
Mouse Data Wake-up. Generates a wake-up event or an
interrupt, indicating a change in the mouse data signal.
PWBTIN
36
I
INTS
VSB
Power Button In. Active (low) level indicates a user request to
turn the power on or off. This pin has debounce protection.
PWBTOUT
49
O
OD6
VSB
Power Button Out. Output for the chip-set Power button input.
SLBTIN
35
I
INTS
VSB
Sleep Button In. Active (low) level indicates a user request to
enter or exit Sleep mode. This pin has debounce protection.
SLPS3,
SLPS5
52, 53
I
INTS
VSB
Sleep State 3 to 5. Active (low) level indicates the system is in
one of the sleep states S3, S4 or S5. These signals are
generated by an external ACPI controller.
GPIOE10-17,
GPIOE40-41,
GPIOE42,
GPIOE43-47,
1-8
2-21
35
49-53
I
RI1
RI2
101
109
KBCLK
Wake-up Inputs. Generate a wake-up event or an interrupt.
These pins have programmable debounce protection.
Pins
SLPS3 SLPS5Functionality
1
0
0
1
1
1
0
0
Working state (S0) or sleep states S1 or S2
Sleep state S3
Sleep states S4 or S5
Illegal combination
SIOSCI
38
O
OD6
VSB
System Control Interrupt. Active (low) level indicates that a
wake-up event occurred, causing the system to exit its current
sleep state. External pull-up resistor to VSB is required.
SIOSMI
37
O
OD6
VSB
System Management Interrupt. Active (low) level indicates
that an SMI occurred. External pull-up resistor to VSB is
required.
ONCTL
39
O
OD6
VSB
Power Supply On/Off Control. Active level (low) indicates that
the power should be turned on. External pull-up resistor is
required
LED1, LED2
50, 51
O
O12/12
VSB
LED Drive. These outputs can be connected directly to LED
devices. They can be configured as one dual-colored LED or
two single-colored LEDs with programmable blink rate for all
LEDs.
VDDFELL
54
O
O3/6
VSB
VDD Power Fell. Active pulse (high) indicates that the VDD
power supply has been turned off. Optionally, this pin can be
used to drive an external circuit that pulses the VSB power to
the Keyboard and Mouse, thus resetting them.
WDO
55
O
O3/6
VSB
Watchdog Out. An active pulse (low) of a fixed width; it is
generated when a watchdog time-out occurs.
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28
Revision1.2
PC8741x
1.0 Signal/Pin Connection and Description
(Continued)
1.4.10 Clocks
Signal
Pin(s) I/O Buffer Type Power Well
Description
32KX1_32KCLKIN1 42
I
INOSC
VPP
32.768 KHz Crystal Input. Input from external crystal
oscillator circuitry.
32.768 KHz Clock Oscillator Input. Input from external
clock oscillator device.
32KX22
44
O
OOSC
VPP
32.768 KHz Crystal Oscillator Output. Output to external
crystal oscillator circuitry.
LFCKOUT
45
O
O1/2
VSB
Low Frequency Clock Output. The Real-Time Clock
frequency (32.768 KHz) or a 1 Hz clock output.
CLKIN
56
I
INTS
VSB3
Clock Input. 48 MHz for the Legacy functions or no input
clock.
HFCKOUT
13
O
O2/4
VSB
High Frequency Clock Output. Clock output for system
use.
1. This pin is not 5-volt tolerant.
2. This pin is neither 5-volt tolerant nor back-drive protected.
3. The CLKIN signal source can be VDD powered.
1.4.11 Configuration Straps
Signal
Pin(s)
I/O Buffer Type Power Well
Description
BADDR
100
I
INCS
VDD
Base Address. Sampled at VDD Power-Up reset to determine
the base address of the configuration Index-Data register pair,
as follows:
No pull-up resistor:
2Eh-2Fh
10 KΩ external pull-up resistor: 4Eh-4Fh
TRIS
97
I
INCS
VDD
TRI-STATE Device. Sampled at VDD Power-Up reset to force
the device to float all its output and I/O pins, as follows:
No pull-up resistor: pins active
4.7 KΩ external pull-up resistor:pins floating
CKIN48
55
I
INCS
VSB
CLKIN 48 MHz. Sampled at VSB Power-Up reset to determine
the presence of the 48 MHz input clock at the CLKIN pin, as
follows:
No pull-up resistor:
no clock
10 KΩ external pull-up resistor: 48 MHz clock
XCNF2-0
(PC87416,
PC87417)
32-34
I
INCS
VSB
X-Bus Default Configuration. Sampled at VSB Power-Up reset
to set the configuration of the X-Bus transactions.
Pins
2 1 0
Functionality
0
1
1
1
1
No BIOS
With BIOS, XA11-4 multiplexed, XRDY disabled
With BIOS, XA11-4 multiplexed, XRDY enabled
With BIOS, XA11-4 direct, XRDY disabled
With BIOS, XA11-4 direct, XRDY enabled
x
0
0
1
1
x
0
1
0
1
Pulled to 0 by internal resistor or set to 1 by external 10 KΩ pullup resistor.
ACBSA
(PC87413,
PC87417)
Revision 1.2
48
I
INCS
VSB
ACCESS.bus Slave Address. Sampled at VSB Power-Up reset
to determine the slave address of the device on the
ACCESS.bus, as follows
No pull-up resistor:
D8h, D9h
10 KΩ external pull-up resistor: 60h, 61h
29
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PC8741x
1.0 Signal/Pin Connection and Description
(Continued)
1.4.12 Power and Ground
Signal
Pin(s)
I/O Buffer Type
Power
Well
Description
VSS
11, 43, 68,
93, 115
I
GND
Ground. Serves for both on-chip logic, output drivers and backup battery circuit.
VDD
69, 92,
116
I
PWR
Digital 3.3V Power Supply. Serves as power supply for the
legacy peripherals and the LPC Interface.
VSB
12, 40
I
PWR
Standby Digital 3.3V Power Supply. Used for the ACB and
X-Bus Interfaces, the GPIO ports and the clock generator. When
active, it also powers the RTC and the SWC.
VBAT
41
I
INULR
Battery Power Supply. When VSB is off, this supply provides
battery back-up to the SWC registers, to the RTC and to the
32 KHz crystal oscillator. The pin is connected to the internal
logic through a series resistor for UL-compliant protection.
1.5
INTERNAL PULL-UP AND PULL-DOWN RESISTORS
The signals listed in Table 3 have internal pull-up (PU) and/or pull-down (PD) resistors. The internal resistors are optional
for those signals indicated as “Programmable”. See Section 11.3 on page 236 for the values of each resistor type.
Table 3. Internal Pull-Up and Pull-Down Resistors
Signal
Pin/s
Type
Comments
Parallel Port
ACK
78
PU220
AFD_DSTRB
90
PU440
BUSY_WAIT
77
PD120
ERR
88
PU220
INIT
86
PU440
PE
76
PU220/
PD110
SLCT
75
PD110
SLIN_ASTRB
84
PU440
STB_WRITE
91
PU440
PPDIS
121
PU25
Programmable
Keyboard and Mouse Controller (KBC)
P12, P16, P17
PU25
121, 70, 66
ACCESS.bus (ACB) Interface (PC87413 and PC87417)
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ACBCLK
47
PU25
Programmable1
ACBDAT
46
PU25
Programmable1
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Revision1.2
PC8741x
1.0 Signal/Pin Connection and Description
(Continued)
Table 3. Internal Pull-Up and Pull-Down Resistors (Continued)
Signal
Pin/s
Type
Comments
System Wake-Up Control (SWC)
PWBTIN
36
PU25
SLBTIN
35
PU25
PWBTOUT
49
PU25
Note 2
General-Purpose Input/Output (GPIO) Ports
GPIO00-04, 05-06, 07 124-128, 9-10, 13
PU25
Programmable3
GPIOE10-17
1-8
PU25
Programmable3
GPIO20-25, 26-27
14-19, 22-23
PU25
Programmable3
GPIO30-37
24-31
PU25
Programmable3
GPIOE40-41, 42, 43-47 20-21, 35, 49-53
PU25
Programmable3
GPIO50-52, 53, 54, 55 36-38, 45, 54, 56
PU25
Programmable3
GPO60-62, 63, 64
PU50
Programmable3,4
32-34, 48, 55
Strap Configuration
BADDR
100
PD110
Strap5
TRIS
97
PD60
Strap5
CKIN48
55
PD110
Strap6
XCNF2-0
(PC87416, PC87417)
32-34
PD110
Strap6
ACBSA
(PC87413, PC87417)
48
PD110
Strap6
1. Default at reset: disabled.
2. Disabled when VDD is off.
3. See Table 26 on page 73 for default value at reset (0 = PU disabled,
1 = PU enabled).
4. Disabled during VSB Power-Up reset.
5. Active only during VDD Power-Up reset.
6. Active only during VSB Power-Up reset.
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PC8741x
2.0
2.1
Power, Reset and Clocks
POWER
2.1.1
Power Planes
The PC8741x devices have three power planes (wells), as shown in the table below:
Table 4. Power Planes
Power Plane
Description
Power Pins Ground Pins
Powers the Legacy modules (Serial Ports, Parallel Port,
FDC, KBC), the LPC Interface, part of the Configuration
Control and some external signals1
VDD
VSS
Main
Powers the ACCESS.bus and X-Bus Interfaces, the GPIO
ports, the Clock Generator, part of the SWC, part of the
Configuration Control and some external related signals1
VSB
VSS
Standby
Powers the RTC, the 32.768 KHz clock/crystal oscillator,
part of the SWC and some functions that must be
preserved at all times1
VPP2
VSS
Backup
1. See the tables in Section 1.4 (pages 23-30), specifically the Power Well column.
2. VPP is an internal power signal derived from VSB or VBAT. VPP is taken from VSB if it is greater than
the minimum value defined in Section 11.1.5; otherwise it is taken from VBAT. For more
details on switching between them, refer to Section 8.2.9.
For correct operation, either VSB or VBAT must be applied whenever VDD is applied.
2.1.2
Power States
The PC8741x devices have four power states:
•
•
Battery Fail - the Main, Standby and Backup power planes are all powered off (VDD, VSB and VBAT are inactive).
•
Power Off - the Main power plane is powered off; the Standby power plane is on; the Backup power plane is on (VDD
is inactive; VSB is active; VBAT is irrelevant).
•
Power On - the Main and Standby power planes are powered on; the Backup power plane may is on (VDD and VSB
are active; VBAT is irrelevant).
Power Fail - the Main and Standby power planes are powered off; the Backup power plane is on (VDD and VSB are
inactive; VBAT is active).
The following power state is illegal:
•
The Main power plane is powered on, the Standby power plane is off and the Backup power plane is on or off (i.e., VDD
is active, VSB is inactive and VBAT is irrelevant).
The following table summarizes the power states described above.
Table 5. Power States and Related Power Planes
Power State
Main (VDD)
Standby (VSB)
Backup (VPP)
Off
Battery Fail
Off
Off
Power Fail
Off
Off
Power Off
Off
Off
On
On
Power On
On
Illegal1
On
On
Off
VBAT
On or Off
On
On
On or Off
On
On or Off
On or Off
1. Operation is not guaranteed and register data may be corrupted.
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32
Revision1.2
PC8741x
2.0 Power, Reset and Clocks
(Continued)
Figure 1 shows the power state transitions:
Battery Fail
VDD, VSB and VBAT Off
VBAT Off
VBAT On,
VPP Power-Up Reset
Cold Reset +
VPP Power-Up Reset
Power Fail
VDD and VSB Off, VBAT On
VSB Off
VSB On (VBAT Off),
VSB On,
VSB Power-Up Reset
VSB Off (VBAT Off)
Power Off
VDD Off, VSB On
VBAT On
VBAT Off
VDD Off
VDD On,
VDD Power-Up Reset
Power On
VDD and VSB On
VBAT On
VBAT Off
Figure 1. Power State Transitions
2.1.3
Power Connection and Layout Guidelines
The PC8741x requires a power supply voltage of 3.3V ± 10% for both the VDD and the VSB supplies. The device is designed
to operate with a Lithium backup battery supplying up to 3.6V. Therefore, it includes an internal current-limiting resistor on
the VBAT input to prevent the battery from shorting, as required by the UL regulations.
VDD, VSB and VBAT use a common ground return marked VSS.
To obtain the best performance, bear in mind the following recommendations.
Ground Connection. The following items must be connected to the ground layer (VSS) as close to the device as possible:
•
•
•
•
The five ground return (VSS) pins.
The decoupling capacitors of the Main power supply (VDD) pins.
The decoupling capacitors of the Standby power supply (VSB) pins.
The decoupling capacitor of the Backup battery (VBAT) pin.
Note that a low-impedance ground layer also improves noise isolation.
Decoupling Capacitors. The following decoupling capacitors must be used in order to reduce EMI and ground bounce:
•
Main power supply (VDD): Place one capacitor of 0.1 µF on each VDD-VSS pin pair as close to the pin as possible. In
addition, place one 10−47 µF tantalum capacitor on the common net as close to the chip as possible.
•
Standby power supply (VSB): Place one capacitor of 0.1 µF on each VSB-VSS pin pair as close to the pin as possible. In
addition, place one 10−47 µF tantalum capacitor on the common net as close to the chip as possible.
•
Backup battery (VBAT): Place one capacitor of 0.1 µF on the VBAT pin as close to the pin as possible. In addition, place
one 4.7−10 µF ceramic capacitor on the common net as close to the chip as possible.
Revision 1.2
33
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PC8741x
2.0 Power, Reset and Clocks
2.2
(Continued)
RESET SOURCES AND TYPES
The PC8741x devices have up to six reset sources:
•
•
•
•
•
VPP Power-Up Reset - activated when either VSB or VBAT is powered up after both have been off.
•
Controller Software Reset (PC87413 and PC87417) - triggered by the CSWRST bit of the ACBCFG register (see Section 6.3.3 on page 128); the CSWRST bit is set by the system controller through the ACCESS.bus Interface.
VSB Power-Up Reset - activated when VSB is powered up.
VDD Power-Up Reset - activated when VDD is powered up.
Hardware Reset - activated when the LRESET input is asserted (low).
Host Software Reset - triggered by the HSWRST bit of the SIOCF1 register (see Section 3.7.2 on page 49); the
HSWRST bit is set by the host through the LPC Interface.
Unless otherwise noted, reset references throughout the modules of the PC8741x devices default to the following resets:
●
For VPP-retained functions (RTC, part of SWC and some other functions): VPP Power-Up reset.
●
For VSB-powered functions (ACCESS.bus, X-Bus, GPIO ports, Clock Generator, part of SWC and part of Configuration Control): VSB Power-Up reset or Controller Software Reset (within the limitations described in Section 2.2.3).
●
For VDD-powered functions (Legacy modules, LPC and part of Configuration Control): VDD Power-Up reset,
Hardware Reset or Host Software Reset (within the limitations described in Section 2.2.6).
The following sections detail the sources and effects of the various resets on the PC8741x devices per reset source.
2.2.1
VPP Power-Up Reset
VPP is an internal power signal derived from VSB and VBAT. VPP Power-Up reset is generated by an internal circuit that detects the status of the VPP power. An active VPP Power-Up reset signal is generated following a rise in the VPP until the VPP
power within the accepted range is detected (see Section 11.1.5 on page 232). When VPP Power-Up reset is active, it resets
the modules and registers whose values are retained by VPP (RTC, part of SWC and some other functions). The VPP PowerUp reset also activates the 32 KHz internal crystal oscillator.
2.2.2
VSB Power-Up Reset
VSB Power-Up reset is generated by an internal circuit when VSB power is applied. This reset is completed after 8,192 cycles
of the 32 KHz clock (t32KOSC). However, if the 32 KHz on-chip crystal oscillator was disabled before VSB power-up, a delay
of t32KW (see Low Frequency Clock Timing on page 242) is added to tIRST (see VSB Power-Up Reset on page 239) to account for the time required by the 32 KHz oscillator to stabilize. In addition, if the Hardware reset (LRESET) is de-asserted
in an early stage, only 1,280 clock cycles are required to complete the VSB Power-Up reset.
External devices should wait at least tIRST before accessing the PC8741x device. However, if the system controller accesses
the PC8741x device (through the ACCESS.bus) before tIRST ends, both the ACBDAT and the ACBCLK signals will float until
the end of VSB Power-Up reset, which is when the ACCESS.bus Interface becomes operational. Since these signals are
pulled-up by external resistors, this situation is equivalent to generating a NACK condition in response to the system controller access (see Section 6.2.4 on page 118).
VSB Power-Up reset performs the following actions and all the actions performed by VDD Power-Up reset (if the VDD power
is already active):
•
•
•
•
•
•
•
•
•
•
Activates the Clock Generator and sets its output to the default frequency.
Puts pins with VSB strap options into TRI-STATE and enables their internal pull-down resistors.
Samples the logic levels of the VSB strap pins.
Sets up the PC8741x device slave address on the ACCESS.bus (PC87413 and PC87417).
Resets the VSB-powered lock bits in the Configuration Control and X-Bus (PC87416 and PC87417).
Loads default values to the GPIO Configuration bits: VDDLOAD and BUSCTL.
Loads default values to the VSB-powered bits in SWC.
Loads default values to the bits in ACCESS.bus Interface (PC87413 and PC87417).
Sets up the pull-up option and the default source for the VSB-powered multiplexed output pins.
Executes all the actions performed by the Controller Software reset (see Section 2.2.3 on page 35) in all PC8741x devices.
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Revision1.2
2.2.3
PC8741x
2.0 Power, Reset and Clocks
(Continued)
Controller Software Reset (PC87413 and PC87417)
The Controller Software reset is initiated by the system controller through the ACCESS.bus Interface. The system controller
can trigger this reset by setting the CSWRST bit of the ACBCFG register (see Section 6.3.3 on page 128).
The Controller Software reset performs the following actions:
•
•
•
Updates the VSB-powered strap configuration bits with the strap levels sampled during the VSB Power-Up reset.
•
Loads default values to the bits in the ACBCST, ACBDIS and ACBTRIS registers of the ACCESS.bus Interface
(PC87413 and PC87417).
•
Terminates any transaction involving the internal modules of the PC8741x device that were initiated by the ACCESS.bus
Interface.
Loads default values to the VSB-powered unlocked bits in the Configuration Control and X-Bus (PC87416 and PC87417).
Loads default values to the unlocked GPIO Configuration and Data bits for those GPIO ports with VDDLOAD = 0. The
VDDLOAD and BUSCTL bits are not affected.
2.2.4
VDD Power-Up Reset
VDD Power-Up reset is generated by an internal circuit when VDD power is turned on. This reset is completed after 8,192
cycles of the 32 KHz clock (t32KOSC; see Low Frequency Clock Timing on page 242). However, if the Hardware reset
(LRESET) is de-asserted in an early stage, tIRST (see VSB Power-Up Reset on page 239) is shortened to only 1,280 clock
cycles. In any condition, the VDD Power-Up reset ends after the VSB Power-Up reset.
External devices must wait at least tIRST before accessing the PC8741x device. If the host processor accesses the device
during this time, the PC8741x device ignores the transaction (that is, it does not return SYNC response).
VDD Power-Up reset performs the following actions:
•
•
•
Puts pins with VDD strap options into TRI-STATE and enables their internal pull-down resistors.
Samples the logic levels of the VDD strap pins.
Executes all the actions performed by the Hardware reset (see Section 2.2.5 on page 35).
2.2.5
Hardware Reset
Hardware reset is activated by the assertion (low) of the LRESET input while VDD is “good”. When the VDD power is Off, the
PC8741x device ignores the level of the LRESET input. Hardware reset performs the following actions:
•
Resets the VSB-powered lock bits in the Configuration Control and X-Bus (PC87416 and PC87417), if VSBLOCK = 0 in
the ACBLKCTL register (in PC87414 and PC87416, VSBLOCK is always ‘0’).
•
•
Sets up the pull-up option and the default source for the VDD-powered multiplexed output pins.
Executes all the actions performed by the Host Software reset (see Section 2.2.6 on page 35).
2.2.6
Host Software Reset
The Host Software reset is triggered by the host setting the HSWRST bit of the SIOCF1 register (see Section 3.7.2 on
page 49) through the LPC Interface. The Host Software reset performs the following actions:
•
•
•
•
•
•
Updates the VDD-powered strap configuration bits with the strap levels sampled during the VDD Power-Up reset.
Loads default values to the VDD-powered unlocked bits in the Configuration Control.
Loads default values to the VSB-powered unlocked GPIO Configuration and Data bits for those GPIO ports with
VDDLOAD = 1. The VDDLOAD and BUSCTL bits are not affected.
Resets all the VDD-powered Legacy logical devices.
Loads default values to all the VDD-powered Legacy module registers.
Terminates any transaction involving the internal modules of the PC8741x device that were initiated by the LPC bus Interface.
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PC8741x
2.0 Power, Reset and Clocks
2.3
(Continued)
CLOCK GENERATION
2.3.1
Clock Domains
The PC8741x devices have five clock domains, as shown in Table 6.
Table 6. Clock Domains of the PC8741x
Clock Domain
Frequency
Source
Usage
LPC
Up to 33 MHz
LPC clock input (LCLK)
LPC bus Interface
Legacy
48 MHz
Clock input (CLKIN) or Clock
Generator
Legacy functions (Serial Ports, Parallel
Port, FDC, KBC)
Output Clock
Up to 40 or 48 MHz
Clock Generator
External Devices
Standby
20 or 24 MHz
Clock Generator
VSB-powered functions (ACCESS.bus
and X-Bus Interfaces)
RTC
32.768 KHz
Clock input or on-chip oscillator
(32KX1, 32KX2)1
RTC, Clock Generator, SWC, GPIO
1. See Section 8.2 on page 142.
The LPC and Legacy clock domains, and the modules using them, are powered by the Main power plane. Therefore, these
two clock domains are only active when the VDD power supply is on; however, if the Legacy clock domain is sourced by the
Clock Generator, it is active also during the time VDD power supply is off.
The Standby and Output clock domains are sourced by the Clock Generator, which is supplied by the Standby power plane.
These two clock domains are active while the VSB power supply is on. Both clock domains require a certain amount of time
to stabilize after VSB becomes active. Moreover, if the 32 KHz on-chip crystal oscillator was disabled before VSB power-up,
the time required for the clocks to stabilize is t32KOSC (see Section 11.5.3 on page 241). The selection of 40 MHz (or its
divisions) or 48 MHz (or its divisions) is set by the CKIN48 strap.
The RTC clock domain is sourced either by a clock input or by the on-chip crystal oscillator, which are supplied by the Backup
power plane. This clock domain is active while either the VBAT or VSB power supply is on. At VBAT or VSB power-up, the clock
requires t32KOSC to stabilize.
2.3.2
Clock Generator
The Clock Generator is the source of the Standby and Output clock domains; it is also the source of the Legacy clock domain
if the 48 MHz clock input is not available. The Clock Generator is fed by the 32.768 KHz from the on-chip crystal oscillator
and supplied by the Standby power plane. It starts generating clock output either after the VSB power supply is turned on (if
the 32.768 KHz clock is already stable) or after the 32.768 KHz clock stabilizes (if VBAT was inactive previous to VSB poweron), whichever occurs last.
Operation
Figure 2 shows a simplified diagram of the Clock Generator.
CLKIN
48 MHz or no clock
1
48 MHz
0
CKIN48(strap)
Divide
by 2
20/24 MHz
Legacy
Modules
ACCESS.bus Interface
X-Bus Extension
Frequency
On-chip
Crystal
Oscillator
32.768 KHz
Multiplier
40/48 MHz
32.768 KHz
RTC
1 Hz
0
Programmable
Divider
32.768 KHz / 1 Hz
HFCKOUT
LFCKOUT
1
LFCKSEL
Figure 2. Clock Generator - Simplified Diagram
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The Frequency Multiplier generates either a 40 MHz or a 48 MHz clock out of the 32.768 KHz clock from the on-chip crystal
oscillator (which is a part of the RTC module; see Section 8.2.2 on page 142). The frequency is selected by the value read
at VSB Power-Up reset from the CKIN48 strap input pin (available for read in the CKIN48 bit of the CLOCKCF register; see
Section 3.7.10 on page 56):
•
A strap value of ‘0’ configures the PC8741x device to work without a clock signal that is connected to the CLKIN pin and
to generate a 48 MHz internal clock. This clock is used for the Standby and Output clock domains and is also selected
for the Legacy modules.
•
A strap value of ‘1’ configures the PC8741x device to work with a 48 MHz clock signal connected to the CLKIN pin and
to generate a 40 MHz internal clock. This clock is used only for the Standby and Output clock domains. The 48 MHz
input clock is selected for the Legacy modules.
The internal clock generated by the Frequency Multiplier is divided by two and used as the basic clock for the ACCESS.bus Interface and X-Bus Extension modules. In addition, it is scaled-down by a programmable divider and generates the HFCKOUT signal.
On power-up, when VSB is applied, the Frequency Multiplier waits for the 32.768 KHz clock to stabilize before it starts
generating the internal clock. The multiplier output clock is frozen to a low level until the multiplier provides a stable clock
signal that meets all requirements. Then the multiplier output clock starts toggling.
The status of the internal clock is indicated by the CKVALID bit of the CLOCKCF register. While either the on-chip crystal
oscillator or the Frequency Multiplier is stabilizing, this bit is 0, indicating an internal clock frozen at low level. When the internal clock starts toggling, this bit is set to 1. The software must activate (enable) the Legacy modules (Serial Ports, Parallel
Port, FDC, KBC) only after the CKVALID bit is set.
The programmable divider scales down the frequency of the internal clock according to the CKIN48 strap and the HFCKDV
field of the CLOCKCF register (see Section 3.7.10 on page 56), as shown in Table 7.
.
Table 7. HFCKOUT Frequency Selection
HFCKOUT Frequency
HFCKDIV Field
Divisor
Default
0
1
40 MHz at CKIN48=1
0
1
22
24 MHz at CKIN48=0
0
1
0
3
10 MHz
0
1
1
4
8 MHz
6.667 MHz
1
0
0
6
6 MHz
5 MHz
1
0
1
8
4 MHz
3.333 MHz
1
1
0
12
3 MHz
2.5 MHz
1
1
1
16
CKIN48 = 0
CKIN48 = 1
Bit 2
Bit 1
Bit 0
48 MHz
40 MHz1
0
0
24 MHz
20 MHz
0
16 MHz
13.333 MHz
12 MHz
1. The actual value is 40.004 MHz.
2. The output signal, generated using all the division ratios (divisors), has an accurate 50% duty cycle.
During frequency transitions caused by software changing the HFCKDIV field value, the output clock is guaranteed to be
glitch free. The high or low level of the clock signal is stable for at least half of the shortest cycle between the previous and
the new frequency.
When the alternate function (GPIO07) is selected for the device pin (see Section 3.7.3 on page 50) or if the HFCKDIS bit in
the CLOCKCF register is set, the programmable divider is disabled to save power. When the programmable divider is disabled by setting the HFCKDIS bit, HFCKOUT is stopped at low level.
Specifications
Frequency Multiplier wake-up time is 33 msec (maximum). This is measured from a valid VSB or a valid 32.768 KHz clock
until the internal clock is stable. Tolerance (long term deviation) of the multiplier output clock, relative to the 32.768 KHz clock,
is ±110 ppm. Total tolerance is therefore ± (input clock tolerance + 110 ppm). Cycle-by-cycle variance is 0.4 nsec (maximum).
2.3.3
Low Frequency Clock
This clock output is obtained by selecting to the LFCKOUT pin either the 32.768 KHz clock or a 1 Hz signal (generated by
the RTC). The LFCKSEL bit in the CLOCKCF register (see Section 3.7.10 on page 56) is responsible for the selection. The
transition from one clock source to the other is not guaranteed to be glitch free.
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PC8741x
2.0 Power, Reset and Clocks
PC8741x
3.0
Device Architecture and Configuration
The PC8741x devices comprise a collection of legacy and proprietary functional blocks. Each functional block is described
in a separate chapter in this document. However, some parameters in the implementation of each functional block may vary
per ServerI/O device. This chapter describes the structure of the PC8741x devices and provides all logical device specific
information, including special implementation of generic blocks, system interface and device configuration.
3.1
OVERVIEW
The PC8741x consists of the following: up to 10 logical devices, the host interface, the system controller interface and a
central set of configuration registers. All these components are built around a central, internal bus. The internal bus is similar
to an 8-bit ISA bus protocol. See the Block Diagram on page 1, which illustrates the blocks and the internal bus.
The host, via the LPC Interface, can access the modules connected to the Internal bus. This interface supports 8-bit I/O
Read/Write, 8-bit Memory Read/Write and 8-bit DMA transactions of the LPC bus (see Section 4.2 on page 90).
The system controller can access these modules via the ACB Interface (PC87413 and PC87417). This interface supports
slave operation for 8-bit I/O Read/Write and 8-bit Memory Read/Write transactions of the ACCESS.bus (see Section 6.2 on
page 117).
Both the host and system controller accesses occur concurrently via the Internal bus.
The central configuration register set is ACPI compliant and supports PnP configuration. The configuration registers are structured as a subset of the Plug and Play Standard registers, defined in Appendix A of the Plug and Play ISA Specification, Revision 1.0a by Intel and Microsoft®. All system resources assigned to the functional blocks (I/O address space, IRQ numbers
and DMA channels) are configured in and managed by the central configuration register set. In addition, some function-specific
parameters are configurable through the configuration registers and distributed to the functional blocks through special control
signals. Access through the ACB Interface (PC87413 and PC87417) ignores the PnP configuration registers and thus the
system resources assigned through them.
3.2
CONFIGURATION STRUCTURE AND ACCESS
The configuration structure is comprised of a set of banked registers that are accessed via a pair of specialized registers.
3.2.1
The Index-Data Register Pair
Access to the ServerI/O configuration registers is via an Index-Data register pair, using only two system I/O byte locations.
The base address of this register pair is determined during reset, according to the state of the hardware strapping option on
the BADDR pin. Table 8 shows the selected base addresses as a function of BADDR. The I/O location of the Index-Data
register pair is irrelevant when the configuration is accessed through the ACB Interface.
Table 8. BADDR Strapping Options
I/O Address
BADDR
Index Register
Data Register
0
2Eh
2Fh
1
4Eh
4Fh
The Index register is an 8-bit read/write register located at the selected base address (Base+0). It is used as a pointer to the
configuration register file and holds the index of the configuration register that is currently accessible via the Data register.
Reading the Index register returns the last value written to it (or the default of 00h after reset).
The Data register is an 8-bit register (Base+1) used as a data path to any configuration register. Accessing the Data register
actually accesses the configuration register that is currently pointed to by the Index register.
The Index, Data and Logical Device Number registers are duplicated to enable concurrent access to the configuration registers from the LPC bus and ACCESS.bus, without contention (PC87413 and PC87417). Each bus has its own set of registers (Index/Data/LDN) powered from the VSB well (ACCESS.bus set) or the VDD well (LPC bus set). This power scheme
allows access to the configuration registers of the VSB-powered modules while in Power Off state (VDD off). In this case,
access is possible only through the ACCESS.bus.
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3.0 Device Architecture and Configuration
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Banked Logical Device Registers Structure
Each functional block is associated with a Logical Device Number (LDN). The configuration registers are grouped into banks,
where each bank holds the standard configuration registers of the corresponding logical device. Table 9 shows the LDN values of the PC8741x functional blocks. Any value not listed is reserved.
Figure 3 shows the structure of the standard configuration register file. The LDN and ServerI/O Configuration registers are
not banked and are accessed by the Index-Data register pair only, as described above. However, the device control and
device configuration registers are duplicated over 10 banks for the 10 logical devices. Therefore, accessing a specific register in a specific bank is performed by two-dimensional indexing, where the LDN register selects the bank (or logical device)
and the Index register selects the register within the bank. Accessing the Data register while the Index register holds a value
of 30h or higher actually accesses the configuration registers of the logical device selected by the LDN register and pointed
to by the Index register.
07h
Logical Device Number Register
20h
2Fh
ServerI/O Configuration Registers
30h
Logical Device Control Register
60h
63h
70h
71h
74h
75h
F0h
FEh
Standard Logical Device
Configuration Registers
Special (Vendor-defined)
Logical Device
Configuration Registers
Bank Select
Banks
(One per Logical Device)
Figure 3. Structure of Standard Configuration Register File
Table 9. Logical Device Number (LDN) Assignments
LDN
Functional Block
00h
Floppy Disk Controller (FDC)
01h
Parallel Port (PP)
02h
Serial Port 2 (SP2)
03h
Serial Port 1 (SP1)
04h
System Wake-Up Control (SWC)
05h
Keyboard and Mouse Controller (KBC) - Mouse Interface
06h
Keyboard and Mouse Controller (KBC) - Keyboard Interface
07h
General-Purpose I/O (GPIO) Ports
0Fh
X-Bus Extension (PC87416 and PC87417)
10h
Real Time Clock (RTC)
Write accesses to unimplemented registers (i.e., accessing the Data register while the Index register points to a non-existing
register) are ignored. Read accesses return 00h on all addresses, except for 74h and 75h (DMA configuration registers),
which returns 04h (indicating no DMA channel). The configuration registers are accessible immediately after reset.
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3.0 Device Architecture and Configuration
3.2.3
(Continued)
Standard Configuration Register Definitions
In the registers below, any undefined bit is reserved. Unless otherwise noted, the following definitions also hold true:
•
•
All registers are read/write.
•
Write-only registers must not use read-modify-write during updates.
All reserved bits return 0 on reads, except where noted otherwise. To prevent unpredictable results, do not modify these
bits. Use read-modify-write to prevent the values of reserved bits from being changed during write.
Table 10. Standard General Configuration Registers
Index
Register Name
07h
Logical Device
Number
20h - 2Fh
ServerI/O
Configuration
Description
This register selects the current logical device. See Table 9 for valid numbers. All
other values are reserved.
ServerI/O configuration registers and ID registers.
Table 11. Logical Device Activate Register
Index
Register Name
30h
Activate
Description
Bit 0 - Logical device activation control (see Section 3.3 on page 43)
0: Disabled
1: Enabled
Bits 7-1 - Reserved
Table 12. I/O Space Configuration Registers
Index
Register Name
Description
60h
I/O Port Base
Address Bits (15-8) Indicates selected I/O lower limit address bits 15-8 for I/O Descriptor 0.
Descriptor 0
61h
I/O Port Base
Address Bits (7-0) Indicates selected I/O lower limit address bits 7-0 for I/O Descriptor 0.
Descriptor 0
62h
I/O Port Base
Address Bits (15-8) Indicates selected I/O lower limit address bits 15-8 for I/O Descriptor 1.
Descriptor 1
63h
I/O Port Base
Address Bits (7-0) Indicates selected I/O lower limit address bits 7-0 for I/O Descriptor 1.
Descriptor 1
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Table 13. Interrupt Configuration Registers
Index
Register Name
Description
70h
Interrupt Number Indicates selected interrupt number.
and Wake-Up on Bits 7-5 - Reserved.
IRQ Enable
Bit 4 - Enables a Power Management event (SCI or wake-up) from the IRQ of the
logical device. When enabled, IRQ assertion sets the respective XXX_IRQ_STS bit
(XXX is MOD, MS or KBD) in the GPE1_STS_3 register (see Section 9.4.11 on
page 211).
0: Disabled (default)
1: Enabled
Note: If the BIOS routine that sets IRQ does not use a Read-Modify-Write
sequence, it might reset bit 4. To ensure that the system wakes up, the BIOS must
set bit 4 before the system goes to sleep.
Bits 3-0 select the interrupt number. A value of 1 selects IRQ1. A value of 15
selects IRQ15. IRQ0 is not a valid interrupt selection and represents no interrupt
selection.
Note: Avoid selecting the same interrupt number (except 0) for different Logical
Devices, as it causes the PC8741x device to behave unpredictably.
71h
Interrupt Request Indicates the type and polarity of the interrupt request number selected in the
Type Select
previous register. If a logical device supports only one type of interrupt, the
corresponding bit is read-only.
Bits 7-2 - Reserved.
Bit 0 - Type of interrupt request selected in previous register
0: Edge
1: Level
Bit 1 - Polarity of interrupt request selected in previous register
0: Low polarity
1: High polarity
Table 14. DMA Configuration Registers
Index
Register Name
Description
74h
DMA Channel
Select 0
Indicates selected DMA channel for DMA 0 of the logical device (0 - The first DMA
channel in case of using more than one DMA channel).
Bits 7-3 - Reserved.
Bits 2-0 select the DMA channel for DMA 0. The valid choices are 0-3, where:
- A value of 0 selects DMA channel 0, 1 selects channel 1, etc.
- A value of 4 indicates that no DMA channel is active.
- The values 5-7 are reserved.
Note: Avoid selecting the same DMA channel (except 4) for different Logical
Devices, as it causes the PC8741x device to behave unpredictably.
75h
DMA Channel
Select 1
Indicates selected DMA channel for DMA 1 of the logical device (1 - The second
DMA channel in case of using more than one DMA channel).
Bits 7-3 - Reserved.
Bits 2-0 select the DMA channel for DMA 1. The valid choices are 0-3, where:
- A value of 0 selects DMA channel 0, 1 selects channel 1, etc.
- A value of 4 indicates that no DMA channel is active.
- The values 5-7 are reserved.
Note: Avoid selecting the same DMA channel (except 4) for different Logical
Devices, as it causes the PC8741x device to behave unpredictably.
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3.0 Device Architecture and Configuration
(Continued)
Table 15. Special Logical Device Configuration Registers
Index
Register Name
F0h-FEh
Logical Device
Configuration
3.2.4
Description
Special (vendor-defined) configuration options.
Standard Configuration Registers
Index
ServerI/O Control and
Configuration Registers
Logical Device Control and
Configuration Registers one per Logical Device
(some are optional)
Register Name
07h
Logical Device Number
20h
ServerI/O ID
21h
ServerI/O Configuration 1
22h
ServerI/O Configuration 2
23h
ServerI/O Configuration 3
24h
ServerI/O Configuration 4
25h
ServerI/O Configuration 5
26h
ServerI/O Configuration 6
27h
ServerI/O Revision ID
28h
ServerI/O Configuration 8
29h
Clock Generator Configuration
2Ah
ACCESS.bus Configuration
2Bh - 2Fh
Reserved for National use
30h
Logical Device Control (Activate)
60h
I/O Base Address Descriptor 0 Bits 15-8
61h
I/O Base Address Descriptor 0 Bits 7-0
62h
I/O Base Address Descriptor 1 Bits 15-8
63h
I/O Base Address Descriptor 1 Bits 7-0
70h
Interrupt Number and Wake-Up on IRQ Enable
71h
IRQ Type Select
74h
DMA Channel Select 0
75h
DMA Channel Select 1
F0h - FFh
Device Specific Logical Device Configuration
Figure 4. Configuration Register Map
ServerI/O Control and Configuration Registers
The ServerI/O configuration registers at indexes 20h (ServerI/O ID) and 27h (ServerI/O Revision ID) are used for part identification. The other configuration registers are used for global power management and selecting pin multiplexing options.
For details, see Section 3.7 on page 48.
Logical Device Control and Configuration Registers
A subset of these registers is implemented for each logical device. See functional block descriptions in the following sections.
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3.0 Device Architecture and Configuration
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Control
The only implemented control register for each logical device is the Activate register at index 30h. Bit 0 of the Activate
register controls the activation of the associated functional block. Activation enables access to the functional block’s runtime
registers and attaches its system resources, which are unassigned as long as it is not activated. Other effects may apply on
a function-specific basis (such as clock enable and active pinout signaling). Access to the configuration register of the logical
device is enabled even when the logical device is not activated.
Standard Configuration
The standard configuration registers manage the PnP resource allocation to the functional blocks. The I/O port base address
descriptor 0 is a pair of registers at Index 60-61h that hold the first 16-bit base address for the register set of the functional
block. An optional 16-bit second base-address (descriptor 1) at index 62-63h is used for logical devices with more than one
continuous register set. Interrupt Number and Wake-Up on IRQ Enable (index 70h) and IRQ Type Select (index 71h) allocate
an IRQ line to the block and control its type. DMA Channel Select 0 (index 74h) allocates a DMA channel to the block, where
applicable. DMA Channel Select 1 (index 75h) allocates a second DMA channel, where applicable.
Special Configuration
The vendor-defined registers, starting at index F0h, control function-specific parameters such as operation modes, power
saving modes, pin TRI-STATE, clock rate selection and non-standard extensions to generic functions.
3.2.5
Default Configuration Setup
The default configuration setup of the PC8741x device is determined by the six reset types described in Section 2.2 on
page 34. See the specific register descriptions for the bits affected by each reset source.
In the event of a VDD Power-Up (also induced by VSB Power-Up reset) or Hardware reset, the PC8741x device wakes up
with the following default configuration setup:
•
•
•
The configuration base address is 2Eh or 4Eh, according to the BADDR strap pin value, as shown in Table 8 on page 38.
If the VSBLOCK bit in the ACBLKCTL register is ‘0’ (see Section 6.3.4 on page 128; in PC87414 and PC87416,
VSBLOCK is always ‘0’), all lock bits in the Configuration Control registers are reset (the protected bits are unlocked).
All the actions performed by the Host Software reset are executed.
If a Host software reset occurs, the PC8741x device wakes up with the following default configuration setup:
•
All logical devices are disabled (the Activation bit is reset) and the VSB-powered logical devices (X-Bus, GPIO, RTC and
SWC) remain functional but their registers cannot be accessed by the Host.
•
•
Standard configuration registers of all logical devices are set to their default values.
•
All Legacy devices are reset. Default values are loaded into the Legacy module runtime registers.
National proprietary functions are not assigned with any default resources and the default values of their base addresses
are all 00h.
3.3
MODULE CONTROL
Module control is performed primarily through the Activation bit (bit 0 of index 30h) of each logical device. The operation of
each module can be controlled either by the host through the LPC bus or by the Embedded Controller through the
ACCESS.bus (PC87413 and PC87417). This dual control is supported by two interacting mechanisms: a dual enable/disable and an access lock (the access lock is available only through the ACCESS.bus).
3.3.1
Module Enable/Disable
LPC Control. Module enable/disable by the host through the LPC bus is controlled by the following bits (see Figure 5 on
page 45):
●
Activation bit (bit 0) in index 30h of the Standard configuration registers (see Section 3.2.3 on page 40).
●
Fast Disable bit in the SIOCF6 register (see Section 3.7.7 on page 54) - only for the FDC, Parallel Port and Serial
Port 1 and 2 modules.
●
Fast Disable bit in the SWCFDIS register (see Section 9.3.8 on page 185) - only for the KBC, FDC, Parallel Port and
Serial Port 1 and 2 modules.
● Global Enable bit (GLOBEN) in the SIOCF1 register (see Section 3.7.2 on page 49).
A module is enabled only if all these bits are set to their “enable” value and the module’s enable/disable is not controlled by
the Embedded Controller as described in the next paragraph. Although possible, changing the above bits by the Embedded
Controller through the ACCESS.bus (PC87413 and PC87417) is not recommended.
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3.0 Device Architecture and Configuration
(Continued)
ACCESS.bus Control. Module enable/disable by the Embedded Controller through the ACCESS.bus (PC87413 and
PC87417) is controlled by the following bits:
●
Access lock bit (xxxALOK) in the ACCLCF1 and ACCLCF2 registers (see Sections 6.3.7 and 6.3.8 on pages 132ff.)
- for the FDC, Parallel Port, Serial Port 1 and 2, KBC, X-Bus, RTC and SWC modules.
●
Fast Disable bit in the ACBFDIS register (see Section 6.3.5 on page 130) - only for the KBC, FDC, Parallel Port and
Serial Port 1 and 2 modules.
A module is enabled if both the Access lock bit is set to “lock” and the Fast Disable bit is set to “enable”. When the module
enable/disable is controlled by the Embedded Controller, the setting of the Activation, Fast Disable (in both SIOCF6 and
SWCFDIS) or Global Enable bits is ignored (see Figure 5 on page 45).
When a VDD-powered module (FDC, Parallel Port and Serial Port 1 and 2 and KBC) is disabled, the following takes place:
●
The host system resources of the logical device (IRQ, DMA and runtime address range) are unassigned.
●
Access to the standard- and device-specific Logical Device configuration registers, through LPC bus or ACCESS.bus,
remains enabled.
●
Access to the module’s runtime registers through the LPC bus is disabled (transactions are ignored; SYNC cycle is
not generated).
●
Access to the module’s runtime registers through the ACCESS.bus causes unpredictable results, and therefore is not
allowed.
•
The module’s internal clock is disabled (the module is not functional) to lower power consumption.
When a VSB-powered module (X-Bus, GPIO, RTC and SWC) is disabled, the following takes place:
●
The host system resources of the logical device (IRQ, DMA and runtime address range)) are unassigned, with the
exception of the XIRQ interrupt, which is not a resource of the X-Bus Extension and therefore remains operational.
●
Access to the standard and device specific Logical Device configuration registers, through the LPC bus or
ACCESS.bus, remains enabled.
●
Access to the module’s runtime registers through the LPC bus is disabled (transactions are ignored; SYNC cycle is
not generated).
●
Access to the module’s runtime registers through the ACCESS.bus causes unpredictable results, and therefore is not
allowed.
•
The module is functional.
3.3.2
Module Lock by ACCESS.bus (PC87413 and PC87417)
A module can be locked to allow only ACCESS.bus control over its registers. In this case, only the setting of the Fast Disable
bit in the ACBFDIS register controls the enable/disable of the module (see Figure 5 on page 45). The setting of the Activation,
Fast Disable (in both SIOCF6 and SWCFDIS) or Global Enable bits is ignored. Module locking is controlled by the bits of
the ACCLCF1 and ACCLCF2 registers (see Sections 6.3.7 and 6.3.8 on pages 132ff.).
When a module is locked for sole use by ACCESS.bus, the following takes place:
●
The system resources of the logical device (IRQ, DMA) are forced to their inactive level, with the exception of the
XIRQ interrupt, which is not a resource of the X-Bus Extension and therefore remains operational.
●
Host read access to the Logical Device Standard and Device Specific configuration registers (through the LPC bus)
remains enabled. Host write access to these registers is ignored.
●
Host access to the module’s runtime registers (through the LPC bus) is disabled and the transaction is performed according to the setting of the ACCLMD field, as described in the next paragraph.
•
The module is functional.
If, the host tries to access the runtime registers of a locked module, the LPC transaction is performed according to the value
of the ACCLMD field in the ACBCFG register (see Section 6.3.3 on page 128). In addition, the ACCLVIOL bit in the ACBCST
register (see Section 6.3.2 on page 127) is set, indicating a lock violation attempt.
Since a locked module and a disabled module behave similarly, the ACTSTAT bit in the ACBCFG register (see Section 6.3.3
on page 128) allows the software to control the behavior of the Activation bit when read through the LPC bus. When a module is locked or disabled by the Fast Disable bit in the ACBFDIS register, the ACTSTAT bit selects the value the host reads
from the Activation bit. This value is either the actual value of the Activation bit or ‘0’ (module disabled).
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ACCLCF1,
ACCLCF2 Registers
Device Configuration
Access
Lock
xxxALOK
PC8741x
3.0 Device Architecture and Configuration
(Continued)
ACBFDIS
Register
Fast
Disable
xxxDIS
ACCESS.bus
Interface
(PC87413, PC87417)
Index 30h Activation
Register
Bit
Module
SIOCF1
Register
Global
Enable
GLOBEN
SIOCF6
Register
Fast
Disable
xxxDIS
Module
Enable
Runtime
Registers
0
1
SWC Module
SWCFDIS
Register
Fast
Disable
xxxDIS
LPC Bus
ACCESS.bus
(PC87413, PC87417)
Figure 5. Module Enable and Access Control
3.4
INTERNAL ADDRESS DECODING
A full 16-bit address decoding is applied when accessing the configuration I/O space as well as the registers of the functional
blocks. However, the number of configurable bits in the base address registers varies for each logical device.
The lower 1, 2, 3, 4 or 5 address bits are decoded in the functional block to determine the offset of the accessed register
within the logical device’s I/O range of 2, 4, 8, 16 or 32 bytes, respectively. The rest of the bits are matched with the base
address register to decode the entire I/O range allocated to the logical device. Therefore, the lower bits of the base address
register are forced to 0 (read only), and the base address is forced to be 2, 4, 8, 16 or 32 byte-aligned, according to the size
of the I/O range.
The base address of the FDC, Serial Port 1, Serial Port 2, KBC and RTC are limited to the I/O address range of 00h to 7FXh
only (bits 11-15 are forced to 0). The Parallel Port base address is limited to the I/O address range of 00h to 3F8h. The
addresses of the non-legacy logical devices, including the SWC, GPIO and X-Bus, are configurable within the full 16-bit address range (up to FFFXh).
In some special cases, other address bits are used for internal decoding (such as bit 2 in the KBC and bit 10 in the Parallel
Port). The KBC has two I/O base addresses with some implied dependency between them. For more details, see the description of the base address register for each logical device.
The X-Bus extension (PC87416 and PC87417) serves as a bridge from the LPC to the X-Bus. For module control and security function registers, the 16-bit base address is applied through the configuration address space. The lower five address
bits are decoded in the X-Bus to access each register. The address ranges in the LPC I/O space and the LPC or FWH memory space that are bridged to the X-Bus are defined in the configuration section of the X-Bus bridge. The number of address
bits used for this bridge decoding varies according to the specified zones and their sizes. See Sections 3.15.2 and 3.15.3
on pages 75ff. for details of the address range specifications.
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PC8741x
3.0 Device Architecture and Configuration
3.5
(Continued)
PROTECTION
The PC8741x devices provide features to protect the hardware configuration from changes made by application software
running on the host.
The protection is activated by the software setting a “sticky” lock bit. Each lock bit protects a group of configuration bits located either in the same register or in different registers. When the lock bit is set, the lock bit and all the protected bits become read only and cannot be further modified by the host through the LPC bus. However, for each lock bit there is an unlock
bit in the ACCESS.bus Interface (ACBLKCTL register; see Section 6.3.4 on page 128). Setting an unlock bit through the
ACCESS.bus resets the corresponding lock bit, thus releasing the locked configuration bits, which again become read/write
bits (PC87413 and PC87417).
In addition, all the lock bits are reset by power-up reset, thus unlocking the protected configuration bits. The VSBLOCK bit
in the ACBLKCTL register (see Section 6.3.4 on page 128; in PC87414 and PC87416, VSBLOCK is always ‘0’) selects
which power-up reset clears the lock bits: VDD Power-Up reset (or Hardware reset) or VSB Power-Up reset. Note that the
locked configuration bits are not reset by the selected power-up reset, unless the selected power-up reset corresponds with
the default reset defined for the power well of the locked configuration bits (see Section 2.2 on page 34).
The bit locking protection mechanism can be used optionally.
The protected groups of configuration bits are described below.
3.5.1
Multiplexed Pins Configuration Lock
Protects the configuration of all the multiplexed device pins.
Lock bit: LOCKMCF in SIOCF1 register (Device Configuration).
Unlock bit: UNLOCKM in ACBLKCTL register (ACCESS.bus Interface - PC87413 and PC87417).
Protected bits: DMAWAIT, IOWAIT in SIOCF1 register and all bits of the SIOCF2, SIOCF3, SIOCF4 and SIOCF5 registers
(Device Configuration).
3.5.2
GPIO Ports Configuration Lock
Protects the configuration (but not the data) of all the GPIO Ports.
Lock bit: LOCKGCF in SIOCF1 register (Device Configuration).
Unlock bit: UNLOCKG in ACBLKCTL register (ACCESS.bus Interface - PC87413 and PC87417).
Protected bits for each GPIO Port: All bits of the GPCFG1, GPEVR and GPCFG2 registers except the LOCKCFP bit (Device
Configuration).
3.5.3
Fast Disable Configuration Lock
Protects the Fast Disable bits for all the Legacy modules.
Lock bit: LOCKFDS in SIOCF6 register (Device Configuration).
Unlock bit: UNLOCKF in ACBLKCTL register (ACCESS.bus Interface - PC87413 and PC87417).
Protected bits: All bits of the SIOCF6 register, except the General-Purpose Scratch bits (Device Configuration).
3.5.4
Clock Generator Configuration Lock
Protects the Clock Generator configuration bits.
Lock bit: LOCKCCF in CLOCKCF register (Device Configuration).
Unlock bit: UNLOCKC in ACBLKCTL register (ACCESS.bus Interface).
Protected bits: All bits of the CLOCKCF register (Device Configuration).
3.5.5
GPIO Ports Lock
Protects the configuration and data of all the GPIO Ports.
Lock bit: LOCKCFP in GPCFG1 register, for each GPIO Port (Device Configuration).
Unlock bit: UNLOCKG in ACBLKCTL register (ACCESS.bus Interface - PC87413 and PC87417).
Protected bits for each GPIO Port: PUPCTL, OUTTYPE and OUTENA in GPCFG1 register; all bits of the GPCFG2 register
(Device Configuration); the corresponding bit (to the port pin) in the GPDO register (GPIO Ports).
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3.0 Device Architecture and Configuration
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X-Bus I/O Map Lock (PC87416 and PC87417)
Protects the configuration of the X-Bus I/O address mapping.
Lock bit: LOCKIOMP in XIOCNF register (Device Configuration).
Unlock bit: UNLOCKX in ACBLKCTL register (ACCESS.bus Interface - PC87417).
Protected bits: All bits of the XIOCNF, XIOBA1H, XIOBA1L, XIOSIZE1, XIOBA2H, XIOBA2L and XIOSIZE2 registers (Device Configuration).
3.5.7
X-Bus Memory Map Lock (PC87416 and PC87417)
Protects the configuration of the X-Bus memory address mapping.
Lock bit: LOCKMMP in XMEMCNF2 register (Device Configuration).
Unlock bit: UNLOCKX in ACBLKCTL register (ACCESS.bus Interface - PC87417).
Protected bits: All bits of the XMEMCNF1, XMEMCNF2, XMEMBAH, XMEMBAL and XMEMSIZE registers (Device Configuration).
3.5.8
X-Bus Chip Select Configuration Lock (PC87416 and PC87417)
Protects the configuration of the four X-Bus chip selects.
Lock bit: LOCKXSCF in XZM0 to XZM3 register (X-Bus Extension).
Unlock bit: UNLOCKX in ACBLKCTL register (ACCESS.bus Interface - PC87417).
Protected bits: All bits of the XBCNF, XZCNF0 to XZCNF3 and XZM0 to XZM3 registers, except the WRSTAT bit of the
XZM0-XZM3 registers (X-Bus Extension).
3.5.9
X-Bus Host Protection Lock (PC87416 and PC87417)
Protects the Host Protection configuration bits for each memory block of XCS0 and XCS1 chip selects.
Lock bit: LOCKXHP in all 16 indexes of the HAP0 and HAP1 registers (X-Bus Extension).
Unlock bit: UNLOCKX in ACBLKCTL register (ACCESS.bus Interface - PC87417).
Protected bits: HWRP and HRDP bits of all 16 indexes of the HAP0 and HAP1 registers (X-Bus Extension).
3.5.10 SWC Timers Protection Lock
Protects the access to the reset of the Power Active timers in the SWC module.
Lock bit: LOCK_TMRRST in PWTMRCTL register (System Wake-Up Control).
Unlock bit: UNLOCKS in ACBLKCTL register (ACCESS.bus Interface - PC87413 and PC87417).
Protected bits: All bits of the PWTMRCTL register (System Wake-Up Control).
3.5.11 SWC Sleep State Configuration Lock
Protects the Sleep Type encoding configuration in the SWC module.
Lock bit: LOCK_SLP_ENC in SLP_ST_CFG register (System Wake-Up Control).
Unlock bit: UNLOCKS in ACBLKCTL register (ACCESS.bus Interface - PC87413 and PC87417).
Protected bits: All bits of the SLP_ST_CFG and S0_SLP_TYP to S5_SLP_TYP registers (System Wake-Up Control).
3.5.12 CMOS RAM Access Lock
Protects access lock configuration bits of the CMOS Standard and Extended RAM.
Lock bits: BLSTR, BLRWR, BLEXRWR, BLEXRRD and BLEXR in RLR register (Real-Time Clock).
Unlock bit: UNLOCKR in ACBLKCTL register (ACCESS.bus Interface - PC87413 and PC87417).
Protected bits: Standard and Extended CMOS RAM bits for read and/or write access by the host (Real-Time Clock; see Section 3.16.3 on page 88).
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3.0 Device Architecture and Configuration
3.6
(Continued)
REGISTER TYPE ABBREVIATIONS
The following abbreviations are used to indicate the Register Type:
●
R/W
= Read/Write.
●
R
= Read from a specific register (write to the same address is to a different register).
●
W
= Write (see above).
●
RO
= Read Only.
●
WO
= Write Only. Reading from the bit returns 0.
●
R/W1C = Read/Write 1 to Clear. Writing 1 to a bit clears it to 0. Writing 0 has no effect.
●
R/W1S = Read/Write 1 to Set. Writing 1 to a bit sets its value to 1. Writing 0 has no effect.
In the registers below, use one of the following methods to handle the Reserved bits:
●
Write 0 to reserved bits, unless another “required value” is specified. This method can be used for registers containing bits of all types.
●
Use read-modify-write to preserve the values of the reserved bits. This method can be used only for registers containing bits of R/W, RO, R/W1C and R/W1S types.
3.7
SERVERI/O CONFIGURATION REGISTERS
This section describes the ServerI/O configuration and ID registers (those registers with first level indexes in the range of
20h - 2Eh). See Table 16 for a summary and directory of these registers.
Table 16. ServerI/O Configuration Registers
Index
Mnemonic
Register Name
Power Well
Type
Section
20h
SID
ServerI/O ID
VSB
RO
3.7.1
21h
SIOCF1
ServerI/O Configuration 1
VSB
Varies per bit
3.7.2
22h
SIOCF2
ServerI/O Configuration 2
VSB
R/W or RO
3.7.3
23h
SIOCF3
ServerI/O Configuration 3
VSB
R/W or RO
3.7.4
24h
SIOCF4
ServerI/O Configuration 4
VSB
R/W or RO
3.7.5
25h
SIOCF5
ServerI/O Configuration 5
VSB
R/W or RO
3.7.6
26h
SIOCF6
ServerI/O Configuration 6
VSB
Varies per bit
3.7.7
27h
SRID
ServerI/O Revision ID
VSB
RO
3.7.8
28h
SIOCF8
ServerI/O Configuration 8
VSB
R/W
3.7.9
29h
CLOCKCF Clock Generator Configuration
VSB
Varies per bit
3.7.10
2Ah
ACBCF
VPP
R/W or RO
3.7.11
ACCESS.bus Configuration
2Bh - 2Fh Reserved for National use
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3.0 Device Architecture and Configuration
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ServerI/O ID Register (SID)
This register contains the identity number of the device family. The PC8741x family is identified by the value EEh.
Power Well:VSB
Location:Index 20h
Type:
RO
Bit
7
6
5
4
3
Name
Family ID
Reset
EEh
Bit
7-0
3.7.2
2
1
0
Description
Family ID. These bits identify a family of devices with similar functionality but with different implemented
options.
ServerI/O Configuration 1 Register (SIOCF1)
Power Well:VSB
Location:Index 21h
Type:
Varies per bit
Bit
7
6
Name
LOCKMCF
LOCKGCF
Reset
0
0
Bit
5
4
3
Reserved
0
2
IOWAIT
1
Type
0
0
1
0
HSWRST
GLOBEN
0
1
Description
7
R/W1S LOCKMCF (Lock Multiplexing Configuration). When set to 1, this bit locks the configuration of
registers SIOCF1, SIOCF2, SIOCF3, SIOCF4 and SIOCF5 by disabling writing to all bits in these
registers (including the LOCKMCF bit itself), except for the LOCKGCF, HSWRST and GLOBEN bits of
SIOCF1. Once set, this bit can be cleared either by VDD Power-Up reset (or Hardware reset) or by VSB
Power-Up reset, according to the VSBLOCK bit in the ACBLKCTL register (see Section 6.3.4 on
page 128). In addition, this bit is cleared by setting the UNLOCKM bit in the ACBLKCTL register
(PC87413 and PC787417).
0: R/W bits are enabled for write (default)
1: All bits are RO
6
R/W1S LOCKGCF (Lock GPIO Pins Configuration). When set to 1, this bit locks the configuration registers
of all the GPIO pins (see Section 3.14.2 on page 71) by disabling writing to all their bits (including the
LOCKGCF bit itself). Once set, this bit can be cleared either by VDD Power-Up reset (or Hardware
reset) or by VSB Power-Up reset, according to the VSBLOCK bit in the ACBLKCTL register (see
Section 6.3.4 on page 128). In addition, this bit is cleared by setting the UNLOCKG bit in the
ACBLKCTL register (PC87413 and PC787417).
0: R/W bits are enabled for write (default)
1: All bits are RO
5-4
3-2
Revision 1.2
Reserved (must be ‘01’).
R/W or IOWAIT (Number of I/O Wait States). These bits set the number of wait states for I/O transactions
RO through the LPC bus.
Bits
3 2
Number of wait states
0
0
1
1
0 (Zero - default)
2
6
12
0:
1:
0:
1:
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PC8741x
3.0 Device Architecture and Configuration
Bit
Type
1
R/W
0
(Continued)
Description
HSWRST (Host Software Reset). When set to 1, this bit triggers the Host Software reset sequence
(see Section 2.2.6 on page 35), after which it returns to 0. Read always returns 0. This bit is not
influenced by the value of LOCKMCF.
0: Inactive (default)
1: Trigger the Host Software reset sequence
R/W or GLOBEN (Global Device Enable). When set to 1, this bit allows the operation of all the logical devices
RO of the PC8741x device (see Table 9 on page 39). The behavior of the different devices is explained in
Section 3.3. When cleared, this bit forces all logical devices to be disabled simultaneously by writing to
a single bit.
0: All logical devices in the PC8741x device are forced to be disabled and their resources are released
1: Each logical device may be enabled; see Section 3.3.1 on page 43 (default)
3.7.3
ServerI/O Configuration 2 Register (SIOCF2)
Power Well:VSB
Location:Index 22h
Type:
R/W or RO
Bit
7
6
5
4
3
2
1
0
Name
WDOMUX
Reserved
NOKBC
VDDFLMUX
P17MUX
P16MUX
P12MUX
CLKRNMUX
Reset
0
0
1
0
0
0
0
0
Bit
Description
7
WDOMUX (Watchdog Out Multiplex Control). Selects the function connected to pin 55.
0: GPO64 port - GPIO (default)
1: WDO - SWC
6
Reserved.
5
NOKBC (Keyboard and Mouse Multiplex Control). Selects the function connected to pins 125-128.
0: GPIO01-GPIO04 ports - GPIO
1: KBCLK, KBDAT, MCLK, MDAT - KBC (default)
4
VDDFLMUX (VDDFELL Multiplex Control). Selects the function connected to pin 54.
0: GPIO54 - GPIO (default)
1: VDDFELL - SWC
3
P17MUX (P17 Multiplex Control). Selects the function connected to pin 66.
0: MTR1 - FDC (default)
1: P17 port - KBC
2
P16MUX (P16 Multiplex Control). Selects the function connected to pin 70.
0: DR1 - FDC (default)
1: P16 port - KBC
1
P12MUX (P12 Multiplex Control). Selects the function connected to pin 121.
0: PPDIS - Parallel Port (default)1
1: P12 port - KBC (internally, PPDIS is set to 0; Parallel Port enabled)
0
CLKRNMUX (CLKRUN Multiplex Control). Selects the function connected to pin 124.
0: GPIO00 port - GPIO (default)
1: CLKRUN - LPC Interface
1. If this feature is not used, either select the P12 port or connect an external 3.3 KΩ pull-down resistor to pin 121.
If the function connected to the pin is PPDIS and the pin is left unconnected, the output signals of the parallel port will float.
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3.0 Device Architecture and Configuration
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ServerI/O Configuration 3 Register (SIOCF3)
Power Well:VSB
Location:Index 23h
Type:
Bit
R/W or RO
7
6
5
Name
EXTSTMUX
SCIMUX
SMIMUX
Reset
EXT_ST
_SELECT1
0
0
4
3
2
PWBTOMUX PWBTIMUX SLBTIMUX
0
0
1
0
LED2MUX
LED1MUX
0
0
0
1. The reset value is the same as the value set to the EXT_ST_SELECT bit in the SLP_ST_CFG register (see
Section 9.3.31 on page 200).
Bit
Description
7
EXTSTMUX (External PM State Multiplex Control). Selects the function connected to pins 52 and 53.
0: GPIOE46, GPIOE47 ports - GPIO (internally, SLPS3 and SLPS5 are both set to 1; not in S3-S5 states)
1: SLPS3, SLPS5 - SWC
6
SCIMUX (SIOSCI Multiplex Control). Selects the function connected to pin 38.
0: GPIO52 port - GPIO (default)
1: SIOSCI - SWC
5
SMIMUX (SIOSMI Multiplex Control). Selects the function connected to pin 37.
0: GPIO51 port - GPIO (default)
1: SIOSMI - SWC
4
PWBTOMUX (PWBTOUT Multiplex Control). Selects the function connected to pin 49.
0: PWBTOUT - SWC (default)
1: GPIOE43 port - GPIO
3
PWBTIMUX (PWBTIN Multiplex Control). Selects the function connected to pin 36.
0: PWBTIN - SWC (default)
1: GPIO50 port - GPIO (internally, PWBTIN is set to 1; Power button not active)
2
SLBTIMUX (SLBTIN Multiplex Control). Selects the function connected to pin 35.
0: GPIOE42 port - GPIO (default; internally, SLBTIN is set to 1; Sleep button not active)
1: SLBTIN - SWC
1
LED2MUX (LED2 Multiplex Control). Selects the function connected to pin 51.
0: GPIOE45 port - GPIO (default)
1: LED2 - SWC
0
LED1MUX (LED1 Multiplex Control). Selects the function connected to pin 50.
0: GPIOE44 port - GPIO (default)
1: LED1 - SWC
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3.0 Device Architecture and Configuration
3.7.5
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ServerI/O Configuration 4 Register (SIOCF4)
Power Well:VSB
Location:Index 24h
Type:
R/W or RO
Bit
7
Name
HFCKMUX
Reset
0
Bit
6
5
LFCKMUX
0
0
4
3
2
1
0
Reserved
SMI2IRQ2
NOXBUS
NOADDIR
XRDYMUX
0
0
Strap
Strap
Strap
Description
7
HFCKMUX (HFCKOUT Multiplex Control). Selects the function connected to pin 13.
0: HFCKOUT - Clock Generator (default)
1: GPIO07 port - GPIO
6-5
LFCKMUX (LFCKOUT Multiplex Control). Selects the function connected to pin 45.
Bits
6 5
Function
0
0
1
1
GPIO53 port - GPIO (default; internally, MSEN0 is set to 1)
LFCKOUT - Clock Generator (internally, MSEN0 is set to 1)
MSEN0 - FDC
Reserved
0:
1:
0:
1:
4
Reserved.
3
SMI2IRQ2 (SMI to IRQ2 Enable). This bit enables the SMI interrupt to the IRQ2 slot of the SERIRQ.
0: Disabled (default)
1: Enabled (the SMI interrupt is shared with the interrupt source selected to IRQ2; see Table 13 on page 41)
2
NOXBUS (Basic X-Bus Multiplex Control). Selects the function connected to pins 14-19 and 24-31. The
default value is set according to the XCNF2 strap, sampled at VSB Power-Up reset.
0: GPIO20-GPIO25, GPIO30-GPIO37 ports - GPIO
1: XRD_XEN, XWR_XRW, XA3-XA0, XD7-XD0 - X-Bus (PC87416 and PC87417)
1
NOADDIR (XA11-4 Multiplex Control). Selects the function connected to pins 1-8. The default value is set by
the XCNF1 strap if XCNF2 = 1 or to 0 if XCNF2 = 0. The XCNF2 and XCNF1 straps are sampled at VSB
Power-Up reset.
0: GPIOE10-GPIOE17 ports - GPIO
1: XA11-XA4 - X-Bus (PC87416 and PC87417)
0
XRDYMUX (XRDY Multiplex Control). Selects the function connected to pin 9. The default value is set by the
XCNF0 strap if XCNF2 = 1 or to 0 if XCNF2 = 0. The XCNF2 and XCNF0 straps are sampled at VSB PowerUp reset.
0: GPIO05 port - GPIO (internally, XRDY is set to 1; device ready)
1: XRDY - X-Bus (PC87416 and PC87417)
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3.0 Device Architecture and Configuration
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ServerI/O Configuration 5 Register (SIOCF5)
Power Well:VSB
Location:Index 25h
Type:
Bit
R/W or RO
7
Name
Reset
6
5
4
3
XIRQMUX XSTB2MUX XSTB1MUX XSTB0MUX XCS3MUX
0
Strap
Strap
Bit
Strap
0
2
1
0
XCS2MUX
XCS1MUX
XCS0MUX
0
0
Strap
Description
7
XIRQMUX (XIRQ Multiplex Control). Selects the function connected to pin 10.
0: GPIO06 port - GPIO (default; internally, XIRQ is set to 0; Interrupt not active)
1: XIRQ - X-Bus (PC87416 and PC87417)
6
XSTB2MUX (XSTB2 Multiplex Control). Selects the function connected to pin 32. The default value is set to 0
if XCNF2 = 1 or to 1 if XCNF2 = 0. The XCNF2 strap is sampled at VSB Power-Up reset.
0: XSTB2 - X-Bus (PC87416 and PC87417)
1: GPO60 port - GPIO
5
XSTB1MUX (XSTB1 Multiplex Control). Selects the function connected to pin 33. The default value is set to 0
if XCNF2 = 1 or to 1 if XCNF2 = 0. The XCNF2 strap is sampled at VSB Power-Up reset.
0: XSTB1 - X-Bus (PC87416 and PC87417)
1: GPO61 port - GPIO
4
XSTB0MUX (XSTB0 Multiplex Control). Selects the function connected to pin 34. The default value is set to 0
if XCNF2 = 1 or to 1 if XCNF2 = 0. The XCNF2 strap is sampled at VSB Power-Up reset.
0: XSTB0 - X-Bus (PC87416 and PC87417)
1: GPO62 port - GPIO
3
XCS3MUX (XCS3 Multiplex Control). Selects the function connected to pin 20.
0: GPIOE40 port - GPIO (default)
1: XCS3 - X-Bus (PC87416 and PC87417)
2
XCS2MUX (XCS2 Multiplex Control). Selects the function connected to pin 21.
0: GPIOE41 port - GPIO (default)
1: XCS2 - X-Bus (PC87416 and PC87417)
1
XCS1MUX (XCS1 Multiplex Control). Selects the function connected to pin 22.
0: GPIO26 port - GPIO (default)
1: XCS1 - X-Bus (PC87416 and PC87417)
0
XCS0MUX (XCS0 Multiplex Control). Selects the function connected to pin 23. The default value is set to 0 if
XCNF2 = 1 or to 1 if XCNF2 = 0. The XCNF2 strap is sampled at VSB Power-Up reset.
0: XCS0 - X-Bus (PC87416 and PC87417)
1: GPIO27 port - GPIO
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3.0 Device Architecture and Configuration
3.7.7
(Continued)
ServerI/O Configuration 6 Register (SIOCF6)
This register provides a fast way to disable one or more modules, without having to access the Activate register of each (see
Section 3.3.1 on page 43).
Power Well:VSB
Location:Index 26h
Type:
Varies per bit
Bit
7
Name
LOCKFDS
Reset
0
Bit
7
6
5
General-Purpose
Scratch
0
0
4
3
2
1
0
Reserved
SER1DIS
SER2DIS
PARPDIS
FDCDIS
0
0
0
0
0
Type
Description
R/W1S LOCKFDS (Lock Fast Disable Configuration). When set to 1, this bit locks itself, the SER1DIS,
SER2DIS, PARPDIS and FDCDIS bits in this register and the GLOBEN bit in the SIOCF1 register by
disabling writing to all these bits. Once set, this bit can be cleared either by VDD Power-Up reset (or
Hardware reset) or by VSB Power-Up reset, according to the VSBLOCK bit in the ACBLKCTL register
(see Section 6.3.4 on page 128). In addition, this bit is cleared by setting the UNLOCKF bit in the
ACBLKCTL register (PC87413 and PC87417).
0: R/W bits are enabled for write (default)
1: All bits are RO
6-5
R/W
4
-
General-Purpose Scratch.
Reserved.
3
R/W or SER1DIS (Serial Port 1 Disable). When set to 1, this bit forces the Serial Port 1 module to be disabled
RO (and its resources released) regardless of the actual setting of its Activation bit (index 30).
0: Enabled or Disabled, according to Activation bit (default)
1: Disabled
2
R/W or SER2DIS (Serial Port 2 Disable). When set to 1, this bit forces the Serial Port 2 module to be disabled
RO (and its resources released) regardless of the actual setting of its Activation bit (index 30).
0: Enabled or Disabled, according to Activation bit (default)
1: Disabled
1
R/W or PARPDIS (Parallel Port Disable). When set to 1, this bit forces the Parallel Port module to be disabled
RO (and its resources released) regardless of the actual setting of its Activation bit (index 30).
0: Enabled or Disabled, according to Activation bit (default)
1: Disabled
0
R/W or FDCDIS (Floppy Disk Controller Disable). When set to 1, this bit forces the Floppy Disk Controller
RO module to be disabled (and its resources released) regardless of the actual setting of its Activation bit
(index 30).
0: Enabled or Disabled, according to Activation bit (default)
1: Disabled
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3.0 Device Architecture and Configuration
(Continued)
ServerI/O Revision ID Register (SRID)
This register contains the ID number of the specific family member (Chip ID) and the chip revision number (Chip Rev).
Power Well:VSB
Location:Index 27h
Type:
RO
Bit
7
Name
6
5
4
3
Chip ID (N/A)
Reset
X
X
2
1
0
X
X
Chip Rev
X
X
Bit
X
X
Description
7-5
Chip ID (N/A). These bits identify a specific device of a family. Note: Not applicable for the PC8741x family
4-0
Chip Rev. These bits identify the device revision. The value is incremented on each revision.
3.7.9
ServerI/O Configuration 8 Register (SIOCF8)
Power Well:VSB
Location:Index 28h
Type:
R/W
Bit
7
Name
5
Reserved
Reset
0
Bit
7-5
6
0
4
MIRQ2SMI
0
3
2
1
KIRQ2SMI KBCP12SMI GPIO2SMI
0
0
0
0
0
Reserved
0
Description
Reserved.
4
MIRQ2SMI (Mouse IRQ to SMI Enable). Controls the routing of the Mouse interrupt to the SIOSMI pin.
0: Disabled (default)
1: Enabled
3
KIRQ2SMI (Keyboard IRQ to SMI Enable). Controls the routing of the Keyboard interrupt to the SIOSMI pin.
0: Disabled (default)
1: Enabled
2
KBCP12SMI (KBC P12 to SMI Enable). Controls the routing of the P12 port of the KBC to the SIOSMI pin.
0: Disabled (default)
1: Enabled
1
GPIO2SMI (GPIO IRQ to SMI Enable). Controls the routing of the GPIO event (see Section 7.3.2 on page 138)
to the SIOSMI pin.
0: Disabled (default)
1: Enabled
0
Reserved.
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3.0 Device Architecture and Configuration
(Continued)
3.7.10 Clock Generator Configuration Register (CLOCKCF)
Power Well:VSB
Location:Index 29h
Type:
Varies per bit
Bit
7
6
5
4
3
Name
LOCKCCF
LFCKSEL
HFCKDIS
CKVALID
CKIN48
Reset
0
0
0
0
Strap
Bit
Type
2
1
0
HFCKDIV
0
0
See Table
Description
7
R/W1S LOCKCCF (Lock Clock Configuration). When set to 1, this bit locks the configuration register
CLOCKCF by disabling writing to all its bits (including to the LOCKCCF bit itself). Once set, this bit can
be cleared either by VDD Power-Up reset (or Hardware reset) or by VSB Power-Up reset, according to
the VSBLOCK bit in the ACBLKCTL register (see Section 6.3.4 on page 128). In addition, this bit is
cleared by setting the UNLOCKC bit in the ACBLKCTL register (PC87413 and PC87417).
0: R/W bits are enabled for write (default)
1: All bits are RO
6
R/W or LFCKSEL (Low Frequency Clock Select). Selects the frequency generated at the LFCKOUT pin.
RO 0: 32.768 KHz (default)
1: 1 Hz
5
R/W or HFCKDIS (High Frequency Clock Disable). Disables both the HFCKOUT output and the
RO programmable divider to save power.
0: Enabled (default)
1: Disabled (set low)
4
RO
CKVALID (Valid Multiplier Clock Status). This bit indicates the status of output from the Frequency
Multiplier (the internal clock signal).
0: Internal clock frozen (default)
1: Internal clock active (stable and toggling)
3
RO
CKIN48 (Clock Input Available). This bit indicates the value of the CKIN48 strap input, sampled at VSB
Power-Up reset.
0: No clock is available at the CLKIN pin (pin 56 connected to GPIO55)
1: A 48 MHz clock is available at the CLKIN pin (pin 56 connected to CLKIN)
2-0
R/W or HFCKDIV (High Frequency Clock Divisor). These bits define the value by which the 48 MHz or 40
RO MHz internal clock frequency is divided to generate the HFCKOUT signal. The resulting frequency
depends on the value of the CKIN48 bit (see Table 7 on page 37).
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Bits
2 1 0
Function
0
0
0
0
1
1
1
1
Divide by 1 (default for CKIN48 = 1)
Divide by 2 (default for CKIN48 = 0)
Divide by 3
Divide by 4
Divide by 6
Divide by 8
Divide by 12
Divide by 16
0
0
1
1
0
0
1
1
0:
1:
0:
1:
0:
1:
0:
1:
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3.0 Device Architecture and Configuration
(Continued)
3.7.11 ACCESS.bus Configuration (ACBCF) Register
This register is relevant only for the PC87413 and PC87417. In the PC87414 and PC87416, all bits are held at their
default value.
This register may be written only once. All eight bits must be updated in a single write operation, after which the data in the
register becomes read only. The register is cleared and the write-lock released only by VPP Power-Up reset.
Power Well:VPP
Location:Index 2Ah
Type:
Bit
R/W or RO
7
Name
ACBPUEN
Reset
0
6
5
4
3
2
1
0
0
0
0
ACBSADD
0
0
0
0
Bit
Description
7
ACBPUEN (ACCESS.bus Signals Pull-Up Enable). This bit controls the internal pull-up resistors connected to
the ACBCLK and ACBDAT signals (see Section 1.5 on page 30).
0: Disconnected (default)
1: Connected
6-0
ACBSADD (ACCESS.bus Slave Address). This field defines the slave address on the ACCESS.bus for the
PC8741x devices. This address, once programmed by the host, is preserved as long as the VPP power is active
(VSB or VBAT). The 7-bit slave address is used to access the PC8741x devices (see Section 6.2.6 on page 119).
A non-zero value read from this field indicates that ACBSADD contains a valid slave address.
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PC8741x
3.0 Device Architecture and Configuration
3.8
(Continued)
FLOPPY DISK CONTROLLER (FDC) CONFIGURATION
3.8.1
General Description
The generic FDC is a standard FDC with a digital data separator and is DP8473 and N82077 software compatible. The
PC8741x FDC supports 14 of the 17 standard FDC signals described in the generic Floppy Disk Controller (FDC) chapter,
including (see Section 10.1 on page 220):
•
FM and MFM modes are supported. To select either mode, set bit 6 of the first command byte when writing to/reading
from a diskette, where:
0 = FM mode
1 = MFM mode
•
A logic 1 is returned during LPC I/O read cycles by all register bits reflecting the state of floating (TRI-STATE) FDC pins.
Exceptions to standard FDC are:
•
•
Automatic media sense using the MSEN1 signal is not supported
DRATE1 is not supported.
The FDC functional block registers are shown in Section 10.1 on page 220. All these registers are VDD powered.
3.8.2
Logical Device 0 (FDC) Configuration
Table 17 lists the configuration registers that affect the FDC. Only the last two registers (F0h and F1h) are described here.
See Section 3.2.3 on page 40 for descriptions of the other configuration registers. All these registers are VDD powered.
Table 17. FDC Configuration Registers
Index
Configuration Register or Action
Type
Power Well Reset
30h
Activate (see Section 3.3.1 on page 43).
R/W
VDD
00h
60h
Base Address MSB register. Bits 7-3 (for A15-11) are read only, 00000b.
R/W
VDD
03h
61h
Base Address LSB register. Bits 2 and 0 (for A2 and A0) are read only, 00b.
R/W
VDD
F2h
70h
Interrupt Number and Wake-Up on IRQ Enable register.
R/W
VDD
06h
71h
Interrupt Type. Bit 1 is read/write; other bits are read only.
R/W
VDD
03h
74h
DMA Channel Select.
R/W
VDD
02h
75h
Report no second DMA assignment.
RO
VDD
04h
F0h
FDC Configuration register.
R/W
VDD
24h
F1h
Drive ID register.
R/W
VDD
00h
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3.8.3
PC8741x
3.0 Device Architecture and Configuration
(Continued)
FDC Configuration Register
This register is reset by hardware to 24h.
Power Well:VDD
Location:Index F0h
Type:
R/W
Bit
7
6
5
4
3
Name
Four-Drive
Encode
Enable
TDR
Register
Mode
DENSEL
Polarity
Control
FDC 2Mbps
Enable
Write
Protect
Reset
0
0
1
0
0
Bit
2
1
PC-AT or
PS/2 Drive Reserved
Mode Select
1
0
0
TRI-STATE
Control
0
Description
7
Four-Drive Encode Enable.
0: Two floppy drives are directly controlled by DR1-0, MTR1-0 (default)
1: Four floppy drives are controlled with the aid of an external decoder
6
TDR Register Mode.
0: PC-AT-Compatible Drive mode; i.e., bits 7-2 of the TDR are 111111b (default)
1: Enhanced Drive mode
5
DENSEL Polarity Control.
0: Active low for 500 Kbps or 1 or 2 Mbps data rates
1: Active high for 500 Kbps or 1 or 2 Mbps data rates (default)
4
FDC 2Mbps Enable. This bit is set only when a 2 Mbps drive is used.
0: 2 Mbps disabled and the FDC clock is 24 MHz (default)
1: 2 Mbps enabled and the FDC clock is 48 MHz
3
Write Protect. This bit enables forcing of write protect functionality by software. When set, writes to the floppy
disk drive are disabled. This effect is identical to an active WP signal.
0: Write protected according to WP signal (default)
1: Write protected regardless of value of WP signal
2
PC-AT or PS/2 Drive Mode Select.
0: PS/2 Drive mode
1: PC-AT Drive mode (default)
1
Reserved.
0
TRI-STATE Control. When enabled and the device is inactive (see Section 3.3.1 on page 43), the logical device
output pins are in TRI-STATE.
0: Disabled (default)
1: Enabled
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PC8741x
3.0 Device Architecture and Configuration
3.8.4
(Continued)
Drive ID Register
This register is reset by hardware to 00h. This register controls bits 5 and 4 of the TDR register in Enhanced mode.
Power Well:VDD
Location:Index F1h
Type: R/W
Bit
7
6
Name
5
4
3
Reserved
Reset
0
Bit
0
2
1
Drive 1 ID
0
0
0
0
Drive 0 ID
0
0
0
Description
7-4
Reserved.
3-2
Drive 1 ID. When drive 1 is accessed, these bits are reflected on bits 5-4 of the TDR register, respectively.
1-0
Drive 0 ID. When drive 0 is accessed, these bits are reflected on bits 5-4 of the TDR register, respectively.
Usage Hints: Some BIOS implementations support automatic media sense FDDs, in which case bit 5 of the TDR register
in the Enhanced mode is interpreted as valid media sense when it is cleared to 0. If drive 0 and/or drive 1 do not support
automatic media sense, bits 1 and/or 3 of the Drive ID register must be set to 1 (to indicate non-valid media sense). When
Drive 0 or Drive 1 is selected, the Drive ID bit is reflected on bit 5 of the TDR register in Enhanced mode.
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3.9
PC8741x
3.0 Device Architecture and Configuration
(Continued)
PARALLEL PORT (PP) CONFIGURATION
3.9.1
General Description
The PC8741x Parallel Port supports all IEEE1284 standard communication modes: Compatibility (also known as Standard
or SPP), Bidirectional (known also as PS/2), FIFO, EPP (also known as mode 4) and ECP (with an optional Extended ECP
mode).
The Parallel Port includes two groups of runtime registers, as follows (see Section 10.2 on page 222):
•
A group of 21 registers at first level offset, sharing 14 entries. Three of this registers (at offsets 403h, 404h and 405h)
are used only in the Extended ECP mode.
•
A group of four registers, used only in the Extended ECP mode, accessed by a second level offset.
The desired mode is selected by the ECR runtime register (offset 402h). The selected mode determines which runtime registers are used and which address bits are used for the base address. The FDC functional block registers are shown in
Section 10.2 on page 222. All these registers are VDD powered.
3.9.2
Logical Device 1 (PP) Configuration
Table 18 lists the configuration registers that affect the Parallel Port. Only the last register (F0h) is described here. See Section 3.2.3 on page 40 for descriptions of the other configuration registers. All these registers are VDD powered.
Table 18. Parallel Port Configuration Registers
Index
Configuration Register or Action
Type
Power Well Reset
30h Activate (see Section 3.3.1 on page 43).
R/W
VDD
00h
60h Base Address MSB register. Bits 7-3 (for A15-11) are read only, 00000b. Bit 2
(for A10) must be 0b.
R/W
VDD
02h
61h Base Address LSB register. Bits 1 and 0 (A1 and A0) are read only, 00b. For ECP
mode 4 (EPP) or when using the Extended registers, bit 2 (A2) must also be 0b.
R/W
VDD
78h
70h Interrupt Number and Wake-Up on IRQ Enable register.
R/W
VDD
07h
71h Interrupt Type:
Bits 7-2 are read only.
Bit 1 is a read/write bit.
Bit 0 is read only. It reflects the interrupt type dictated by the Parallel Port
operation mode. This bit is set to 1 (level interrupt) in Extended mode and
cleared (edge interrupt) in all other modes.
R/W
VDD
02h
74h DMA Channel Select.
R/W
VDD
04h
75h Report no second DMA assignment.
RO
VDD
04h
F0h Parallel Port Configuration register.
R/W
VDD
F2h
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3.0 Device Architecture and Configuration
3.9.3
(Continued)
Parallel Port Configuration Register
This register is reset by hardware to F2h.
Power Well:VDD
Location:Index F0h
Type:
R/W
Bit
7
Name
1
Bit
4
3-2
5
Parallel Port Mode Select
Reset
7-5
6
1
1
4
3
Extended
Register
Access
1
2
Reserved
0
0
1
0
Power
Mode
Control
TRI-STATE
Control
1
0
Description
Parallel Port Mode Select.
000: SPP-Compatible mode. PD7-0 are always output signals
001: SPP Extended mode. PD7-0 direction is controlled by software
010: EPP 1.7 mode
011: EPP 1.9 mode
100: ECP mode (IEEE1284 register set), with no support for EPP mode
101: Reserved
110: Reserved
111: ECP mode (IEEE1284 register set), with EPP mode selectable as mode 4 (default)
Selection of EPP 1.7 or 1.9 in ECP mode 4 is controlled by bit 4 of the Control2 configuration register of the
parallel port at offset 02h.
Note: Before setting bits 7-5, enable the parallel port and set CTR/DCR (at base address + 2) to C4h.
Extended Register Access.
0: Registers at base (address) + 403h, base + 404h and base + 405h are not accessible (reads and writes are
ignored)
1: Registers at base (address) + 403h, base + 404h and base + 405h are accessible. This option supports runtime configuration within the Parallel Port address space (default).
Reserved.
1
Power Mode Control. When the logical device is active:
0: Parallel port clock disabled. ECP modes and EPP time-out are not functional when the logical device is active.
Registers are maintained.
1: Parallel port clock enabled. All operation modes are functional when the logical device is active (default).
0
TRI-STATE Control. When enabled and the device is inactive (see Section 3.3.1 on page 43), the logical device
output pins are in TRI-STATE.
0: Disabled (default)
1: Enabled
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PC8741x
3.0 Device Architecture and Configuration
(Continued)
3.10 SERIAL PORT 2 CONFIGURATION
3.10.1 General Description
Serial Port 2 provides UART functionality by supporting serial data communication with remote peripheral device or modem.
The functional blocks can function as a standard 16450 or 16550 or as an Extended UART.
Serial Port 2 includes four register banks, each containing eight runtime registers, as shown in Section 10.3 on page 225.
All these registers are VDD powered.
3.10.2 Logical Device 2 (SP2) Configuration
Table 19 lists the configuration registers that affect Serial Port 2. Only the last register (F0h) is described here. See Section
3.2.3 on page 40 for descriptions of the other configuration registers. All these registers are VDD powered.
Table 19. Serial Port 2 Configuration Registers
Index
Configuration Register or Action
Type
Power Well Reset
30h Activate (see Section 3.3.1 on page 43).
R/W
VDD
00h
60h Base Address MSB register. Bits 7-3 (for A15-11) are read only, 00000b.
R/W
VDD
02h
61h Base Address LSB register. Bit 2-0 (for A2-0) are read only, 000b.
R/W
VDD
F8h
70h Interrupt Number and Wake-Up on IRQ Enable register.
R/W
VDD
03h
71h Interrupt Type. Bit 1 is R/W; other bits are read only.
R/W
VDD
03h
74h Report no DMA Assignment.
RO
VDD
04h
75h Report no DMA Assignment.
RO
VDD
04h
F0h Serial Port 2 Configuration register.
R/W
VDD
02h
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PC8741x
3.0 Device Architecture and Configuration
(Continued)
3.10.3 Serial Port 2 Configuration Register
This register is reset by hardware to 02h.
Power Well:VDD
Location:Index F0h
Type:
R/W
Bit
7
6
Name
Bank
Select
Enable
Fast
TRI-STATE
Reset
0
0
Bit
5
4
3
Reserved
0
0
0
2
1
0
Busy
Indicator
Power
Mode
Control
TRI-STATE
Control
0
1
0
Description
7
Bank Select Enable. Enables bank switching for Serial Port 2.
0: All attempts to access the extended registers in Serial Port 2 are ignored (default)
1: Enables bank switching for Serial Port 2
6
Fast TRI-STATE. When set, the logical device output pins are in TRI-STATE and the input pins are internally
held at inactive level (high), regardless of the device activation (Activation bit - Section 3.3.1 on page 43;
SER2DIS - Section 3.7.7 on page 54; GLOBEN - Section 3.7.2 on page 49; SER2DIS - Section 9.3.8 on
page 185; SER2ALOK - Section 6.3.7 on page 132; SER2DIS - Section 6.3.5 on page 130).
0: Device pins active (default)
1: Device pins disabled
5-3
Reserved.
2
Busy Indicator. This read only bit can be used by power management software to decide when to power-down
the Serial Port 2 logical device.
0: No transfer in progress (default)
1: Transfer in progress
1
Power Mode Control. When the logical device is active in:
0: Low-Power mode
Serial Port 2 clock disabled. The output signals are set to their default states. The RI input signal can be programmed to generate an interrupt. Registers are maintained (unlike Active bit in index 30 that also prevents
access to Serial Port 2 registers).
1: Normal Power mode
Serial Port 2 clock enabled. Serial Port 2 is functional when the logical device is active (default).
0
TRI-STATE Control. When enabled and the device is inactive (see Section 3.3.1 on page 43), the logical device
output pins are in TRI-STATE.
0: Disabled (default)
1: Enabled
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3.0 Device Architecture and Configuration
(Continued)
3.11 SERIAL PORT 1 CONFIGURATION
3.11.1 General Description
Serial Port 1 provides UART functionality by supporting serial data communication with remote peripheral device or modem.
The functional blocks can function as a standard 16450 or 16550 or as an Extended UART.
Serial Port 1 includes the same register banks and runtime registers as Serial Port 2 (see Section 10.3 on page 225). All the
registers are VDD powered.
3.11.2 Logical Device 3 (SP1) Configuration
Table 20 lists the configuration registers that affect Serial Port 1. Only the last register (F0h) is described here. See Section
3.2.3 on page 40 for descriptions of the other configuration registers. All these registers are VDD powered.
Table 20. Serial Port 1 Configuration Registers
Index
Configuration Register or Action
Type
Power Well Reset
30h Activate (see Section 3.3.1 on page 43).
R/W
VDD
00h
60h Base Address MSB register. Bits 7-3 (for A15-11) are read only, 00000b.
R/W
VDD
03h
61h Base Address LSB register. Bit 2-0 (for A2-0) are read only, 000b.
R/W
VDD
F8h
70h Interrupt Number and Wake-Up on IRQ Enable register.
R/W
VDD
04h
71h Interrupt Type. Bit 1 is R/W; other bits are read only.
R/W
VDD
03h
74h Report no DMA Assignment.
RO
VDD
04h
75h Report no DMA Assignment.
RO
VDD
04h
F0h Serial Port 1 Configuration register.
R/W
VDD
02h
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PC8741x
3.0 Device Architecture and Configuration
(Continued)
3.11.3 Serial Port 1 Configuration Register
This register is reset by hardware to 02h.
Power Well:VDD
Location:Index F0h
Type:
R/W
Bit
7
Bank
Select
Enable
Name
Reset
0
Bit
6
5
Fast
TRI-STATE
0
4
3
Reserved
0
0
0
2
1
0
Busy
Indicator
Power
Mode
Control
TRI-STATE
Control
0
1
0
Description
7
Bank Select Enable. Enables bank switching for Serial Port 1.
0: All attempts to access the extended registers in Serial Port 1 are ignored (default)
1: Enables bank switching for Serial Port 1
6
Fast TRI-STATE. When set, the logical device output pins are in TRI-STATE and the input pins are internally
held at inactive level (high), regardless of the device activation (Activation bit - Section 3.3.1 on page 43;
SER1DIS - Section 3.7.7 on page 54; GLOBEN - Section 3.7.2 on page 49; SER1DIS - Section 9.3.8 on
page 185; SER1ALOK - Section 6.3.7 on page 132; SER1DIS - Section 6.3.5 on page 130).
0: Device pins active (default)
1: Device pins disabled
5-3
Reserved.
2
Busy Indicator. This read only bit can be used by power management software to decide when to power-down
the Serial Port 1 logical device.
0: No transfer in progress (default)
1: Transfer in progress
1
Power Mode Control. When the logical device is active in:
0: Low-Power mode
Serial Port 1 clock disabled. The output signals are set to their default states. The RI input signal can be programmed to generate an interrupt. Registers are maintained (unlike Active bit in Index 30;s which also prevents
access to Serial Port 1 registers).
1: Normal Power mode
Serial Port 1 clock enabled. Serial Port 1 is functional when the logical device is active (default).
0
TRI-STATE Control. When enabled and the device is inactive (see Section 3.3.1 on page 43), the logical device
output pins are in TRI-STATE.
0: Disabled (default)
1: Enabled
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3.0 Device Architecture and Configuration
(Continued)
3.12 SYSTEM WAKE-UP CONTROL (SWC) CONFIGURATION
3.12.1 General Description
System Wake-up Control provides wake-up and power management functionality according to ACPI specification (see Section 9.1 on page 161). Its registers are VPP or VSB powered.
3.12.2 Logical Device 4 (SWC) Configuration
Table 21 lists the configuration registers that affect the SWC. See Section 3.2.3 on page 40 for a detailed description of
these registers. All these registers are VDD powered.
Table 21. System Wake-Up Control (SWC) Configuration Registers
Index
Configuration Register or Action
Type
Power Well Reset
30h
Activate. When bit 0 is cleared, the runtime registers of this logical device are
not accessible (see Section 3.3.1 on page 43).1
R/W
VDD
00h
60h
SWC Base Address MSB register.
R/W
VDD
00h
61h
SWC Base Address LSB register. Bits 4-0 (for A4-0) are read only, 00000b.
R/W
VDD
00h
62h
PM1b_EVT_BLK Base Address MSB register.
R/W
VDD
00h
63h
PM1b_EVT_BLK Base Address LSB register. Bits 1-0 (for A1-0) are read only,
00b.
R/W
VDD
00h
64h
PM1b_CNT_BLK Base Address MSB register.
R/W
VDD
00h
65h
PM1b_CNT_BLK Base Address LSB register. Bits 1-0 (for A1-0) are read only,
00b.
R/W
VDD
00h
66h
GPE1_BLK Base Address MSB register.
R/W
VDD
00h
67h
GPE1_BLK Base Address LSB register. Bits 2-0 (for A2-0) are read only, 000b.
R/W
VDD
00h
70h
Interrupt Number.
R/W
VDD
00h
71h
Interrupt Type. Bit 1 is read/write. Other bits are read only.
R/W
VDD
03h
74h
Report no DMA assignment.
RO
VDD
04h
75h
Report no DMA assignment.
RO
VDD
04h
1. The logical device runtime registers are maintained and all wake-up detection mechanisms are functional.
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PC8741x
3.0 Device Architecture and Configuration
(Continued)
3.13 KEYBOARD AND MOUSE CONTROLLER (KBC) CONFIGURATION
3.13.1 General Description
The KBC is implemented physically as a single hardware module and houses two separate logical devices: a Mouse controller (Logical Device 5) and a Keyboard controller (Logical Device 6). The KBC is functionally equivalent to the industry
standard 8042A Keyboard controller. Technical references for the standard 8042A Keyboard Controller may serve as detailed technical references for the KBC.
The Keyboard and Mouse Controller runtime registers are described in Section 10.4 on page 229. All the registers are VDD
powered.
3.13.2 Logical Devices 5 and 6 (Mouse and Keyboard) Configuration
Tables 22 and 23 list the configuration registers that affect the Mouse and the Keyboard logical devices, respectively. Only
the last register (F0h) is described here. See Section 3.2.3 on page 40 for descriptions of the other configuration registers.
All these registers are VDD powered.
Table 22. Mouse Configuration Registers
Index
Mouse Configuration Register or Action
Type
Power Well Reset
30h
Activate (see Section 3.2.3 on page 40). When the Mouse of the KBC is
inactive, the IRQ selected by the Mouse Interrupt Number and Wake-Up on IRQ
Enable register (index 70h) are not asserted. This register has no effect on host
KBC commands handling the PS/2 Mouse.
R/W
VDD
00h
70h
Mouse Interrupt Number and Wake-Up on IRQ Enable register.
R/W
VDD
0Ch
71h
Mouse Interrupt Type. Bits 1,0 are read/write; other bits are read only.
R/W
VDD
02h
74h
Report no DMA assignment.
RO
VDD
04h
75h
Report no DMA assignment.
RO
VDD
04h
Table 23. Keyboard Configuration Registers
Index
Keyboard Configuration Register or Action
Type
30h
Activate (see Section 3.2.3 on page 40). When the Keyboard of the KBC is
inactive, the IRQ selected by the Keyboard Interrupt Number and Wake-Up on
IRQ Enable register (index 70h) are not asserted.
R/W
VDD
00h
60h
Base Address MSB register. Bits 7-3 (for A15-11) are read only, 00000b.
R/W
VDD
00h
61h
Base Address LSB register. Bits 2-0 (for A2-0) are read-only 000b.
R/W
VDD
60h
62h
Command Base Address MSB register. Bits 7-3 (for A15-11) are read only,
00000b.
R/W
VDD
00h
63h
Command Base Address LSB. Bits 2-0 (for A2-0) are read-only 100b.
R/W
VDD
64h
70h
KBD Interrupt Number and Wake-Up on IRQ Enable register.
R/W
VDD
01h
71h
KBD Interrupt Type. Bits 1,0 are read/write; others are read only.
R/W
VDD
02h
74h
Report no DMA assignment.
RO
VDD
04h
75h
Report no DMA assignment.
RO
VDD
04h
F0h
KBC Configuration register.
R/W
VDD
40h
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Power Well Reset
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3.0 Device Architecture and Configuration
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3.13.3 KBC Configuration Register
This register is reset by hardware to 40h.
Power Well:VDD
Location:Index F0h
Type:
R/W
Bit
7
Name
6
KBC Clock Source
Reset
Required
0
1
Bit
7-6
5-4
3
2-1
0
5
4
Reserved
0
3
2
Swap
0
0
1
Reserved
0
0
0
0
TRI-STATE
Control
0
Description
KBC Clock Source. The clock source can be changed only when the KBC is inactive (disabled).
Bits
7 6
Source
0
0
1
1
8 MHz
12 MHz (default)
16 MHz
Reserved
0:
1:
0:
1:
Reserved.
Swap. This bit swaps between the Keyboard and Mouse Interface pins.
0: KBCLK and KBDAT are Keyboard Interface; MCLK and MDAT are Mouse Interface (default)
1: KBCLK and KBDAT are Mouse Interface; MCLK and MDAT are Keyboard Interface
Reserved.
TRI-STATE Control. If the keyboard is inactive (see Section 3.3.1 on page 43) when this bit is set, the KBD pins
(KBCLK and KBDAT) are in TRI-STATE. If the mouse is inactive (see Section 3.3.1 on page 43) when this bit is set,
the mouse pins (MCLK and MDAT) are in TRI-STATE.
0: Disabled (default)
1: Enabled
Usage Hints:
1. To change the clock frequency of the KBC:
a. Disable the KBC logical devices.
b. Change the frequency setting.
c. Enable the KBC logical devices.
2. Before swapping between the Keyboard and Mouse Interface pins, disable the KBC logical devices and both pin sets.
After swapping, the software must issue a synchronization command to the Keyboard and Mouse through the KBC to
regain synchronization with these devices.
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3.0 Device Architecture and Configuration
(Continued)
3.14 GENERAL-PURPOSE INPUT/OUTPUT (GPIO) PORTS CONFIGURATION
3.14.1 General Description
The GPIO functional block includes 51 pins arranged in seven ports:
●
Ports 1 and 4 contain eight GPIOE pins each.
●
Ports 0, 2 and 3 contain eight GPIO pins each.
●
Port 5 contains six GPIO pins.
●
Port 6 contains five GPO pins (see Section 1.4.8 on page 27).
All the pins of Ports 1 and 4 and have full event detection capability (see Section 1.3 on page 20), enabling them to trigger
the assertion of IRQ or SIOSMI signals. In addition, through the SWC functional block, the pins of Ports 1 and 4 can trigger
the SIOSCI, control the ONCTL signal or enable the generation of a pulse in the PWBTOUT signal. The pins of Ports 0-5
are I/O, however the five pins of Port 6 are output only.
All 51 GPIO pins are powered from the VSB well. The 17 runtime registers associated with the seven ports are arranged in
the GPIO address space as shown in Table 24. The GPIO ports with wake-up event detection capability (such as Ports 1
and 4) have four runtime registers; the other ports have only 2. Port 6 contains only GPO pins and therefore has only one
runtime register. The GPIO base address is 32-byte aligned. Address bits 4-0 are used to indicate the register offset.
The specific runtime registers implemented in the PC8741x devices are shown in Table 24. All these registers are VSB powered.
Table 24. Runtime Registers in GPIO Address Space
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Offset
Mnemonic
Register Name
00h
GPDO0
GPIO Data Out 0
01h
GPDI0
GPIO Data In 0
02h
GPDO1
GPIO Data Out 1
03h
GPDI1
GPIO Data In 1
Port Power Well
0
1
Type
VSB
R/W
VSB
RO
VSB
R/W
VSB
RO
04h
GPEVEN1 GPIO Event Enable 1
VSB
R/W
05h
GPEVST1 GPIO Event Status 1
VSB
R/W1C
VSB
R/W
VSB
RO
VSB
R/W
VSB
RO
VSB
R/W
VSB
RO
06h
GPDO2
GPIO Data Out 2
07h
GPDI2
GPIO Data In 2
08h
GPDO3
GPIO Data Out 3
09h
GPDI3
GPIO Data In 3
0Ah
GPDO4
GPIO Data Out 4
0Bh
GPDI4
GPIO Data In 4
2
3
4
0Ch
GPEVEN4 GPIO Event Enable 4
VSB
R/W
0Dh
GPEVST4 GPIO Event Status 4
VSB
R/W1C
VSB
R/W
VSB
RO
VSB
R/W
0Eh
GPDO5
GPIO Data Out 5
0Fh
GPDI5
GPIO Data In 5
10h
GPDO6
GPIO Data Out 6
5
6
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3.0 Device Architecture and Configuration
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3.14.2 Logical Device 7 (GPIO) Configuration
Table 25 lists the configuration registers that affect the GPIO. Only the last three registers (F0h - F2h) are described here.
See Section 3.2.3 on page 40 for a detailed description of the other configuration registers. The standard configuration registers are powered by VDD, however the specific configuration registers are powered by VSB.
Table 25. GPIO Configuration Register
Index
Configuration Register or Action
Type
Power Well Reset
30h
Activate (see Section 3.2.3 on page 40).
R/W
VDD
00h
60h
Base Address MSB register.
R/W
VDD
00h
61h
Base Address LSB register. Bits 4-0 (for A4-0) are read-only 00000b.
R/W
VDD
00h
70h
Interrupt Number and Wake-Up on IRQ Enable register.
R/W
VDD
00h
71h
Interrupt Type. Bit 1 is read/write. Other bits are read only.
R/W
VDD
03h
74h
Report no DMA assignment.
RO
VDD
04h
75h
Report no DMA assignment.
RO
VDD
04h
F0h
GPIO Pin Select register (GPSEL).
R/W
VSB
00h
F1h
GPIO Pin Configuration register 1 (GPCFG1).
R/W
VSB
See text
F2h
GPIO Pin Event Routing register (GPEVR).
R/W
VSB
01h
F3h
GPIO Pin Configuration register 2 (GPCFG2).
R/W
VSB
00h
Figure 6 shows the organization of these registers:
GPIO Pin Select Register
(Index F0h)
Port Select
Pin Select
Pin 0
Port 0
Port 6, Pin 0
Port 5, Pin 0
Port 4, Pin 0
Port 3, Pin 0
Port 2, Pin 0
Port 1, Pin 0
Port 0, Pin 0
GPIO Pin
Configuration Registers
(Index F1h)
(Index F3h)
Port 0, Pin 7
Port 6
Pin 7
Pin 0
Port 4, Pin 0
Port 1, Pin 0
Port 1
GPIO Pin Event
Routing Register
(Index F2h)
Port 4
Pin 7
Port 1, Pin 7
Figure 6. Organization of GPIO Pin Registers
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3.0 Device Architecture and Configuration
(Continued)
3.14.3 GPIO Pin Select Register (GPSEL)
This register selects the GPIO pin (port number and bit number) to be configured (i.e., which register is accessed via the
GPIO configuration registers). Since access to the pin configuration requires two transactions (first to GPSEL, then to the
configuration register) and since the LPC bus and ACCESS.bus concurrently access the module (PC87413 and PC87417),
the GPSEL register is duplicated (one GPSEL register is accessed by the host and one by the ACCESS.bus). This register
is reset by hardware to 00h.
Power Well:VSB
Location:Index F0h
Type:
R/W
Bit
7
Name
Reserved
Reset
0
6
5
0
5-4
3
2-0
3
2
Reserved
0
Bit
7
4
PORTSEL
0
0
1
0
PINSEL
0
0
0
Description
Reserved.
PORTSEL (Port Select). These bits select the GPIO port to be configured:
000: Port 0 (default)
001 to 110: Binary value of port numbers 1-6, respectively (all other values are reserved)
Reserved.
PINSEL (Pin Select). These bits select the GPIO pin of the selected port, to be configured:
000:
Pin 0 (default)
001 to 111: Binary value of pin number 1-7, respectively
3.14.4 GPIO Pin Configuration Register 1 (GPCFG1)
This register reflects, for both read and write, the register currently selected by the GPIO Pin Select register. All the GPIO
Pin Configuration registers have a common bit structure, as shown below. Ports 1 and 4 are reset by hardware to
01000X00b. Ports 0, 2, 3, 5 and 6 are reset to 00000X00b (see Table 26 on page 73 for the value of ‘X’).
Power Well:VSB
Location:Index F1h
Type: Varies per bit
Ports 1 and 4 (With Wake-Up Event Detection Capability)
Bit
7
6
5
4
3
2
1
0
Name
Reserved
EVDBNC
EVPOL
EVTYPE
Reset
0
1
0
0
LOCKCFP
PUPCTL
OUTTYPE
OUTENA
0
see Table 26
0
0
3
2
1
0
LOCKCFP
PUPCTL
OUTTYPE
OUTENA
0
see Table 26
0
0
Ports 0, 2, 3, 5 and 6 (Without Wake-Up Event Detection Capability)
Bit
7
6
0
0
Name
Reset
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5
4
0
0
Reserved
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Bit
Type
Description
7
-
6
R/W
Reserved for Ports 0, 2, 3, 5, and 6.
For Ports 1 and 4: EVDBNC (Event Debounce Enable). This bit enables the debounce circuit in the
event input path of the selected GPIO pin. The event is detected after a predetermined debouncing
period of time (see Section 7.3 on page 137).
0: Disabled
1: Enabled (default)
5
R/W
Reserved for Ports 0, 2, 3, 5, and 6.
For Ports 1 and 4: EVPOL (Event Polarity). This bit defines the polarity of the wake-up signal that
issues an event from the selected GPIO pin (see Section 7.3 on page 137).
0: Falling edge or low level input (default)
1: Rising edge or high level input
4
R/W
Reserved for Ports 0, 2, 3, 5, and 6.
For Ports 1 and 4: EVTYPE (Event Type). This bit defines the type of the wake-up signal that issues
an event from the selected GPIO pin (see Section 7.3 on page 137).
0: Edge input (default)
1: Level input
Reserved (note that for Ports 0, 2, 3, 5, and 6, bits 7-4 are reserved).
3
R/W1S LOCKCFP (Lock Configuration of Pin). When set to 1, this bit locks the GPIO pin configuration and
data (see also Section 7.4 on page 139) by disabling writing to itself, to GPCFG1 register bits PUPCTL,
OUTTYPE and OUTENA, to all the bits of the GPCFG2 register and to the corresponding bit in the
GPDO register. Once set, this bit can be cleared by VDD Power-Up reset (or Hardware reset) or by VSB
Power-Up reset, according to the VSBLOCK bit in the ACBLKCTL register (see Section 6.3.4 on
page 128). In addition, this bit is cleared by setting the UNLOCKG bit in the ACBLKCTL register
(PC87413 and PC87417).
0: R/W bits are enabled for write (default)
1: All bits are RO
2
R/W or PUPCTL (Pull-Up Control). This bit controls the internal pull-up resistor of the selected GPIO pin (see
RO Section 7.2 on page 136).
0: Disabled (for default value, see Table 26)
1: Enabled (for default value, see Table 26)
1
R/W or OUTTYPE (Output Type). This bit controls the output buffer type of the selected GPIO pin (see Section
RO 7.2 on page 136).
0: Open-drain (default)
1: Push-pull
0
R/W or OUTENA (Output Enable). This bit controls the output buffer of the selected GPIO pin (see Section 7.2
RO on page 136).
0: TRI-STATE (default)
1: Output buffer enabled
Table 26. Reset Values for PUPCTL Bit
GP(I)O(E)nn
PUPCTL
00-07,10-17 20,21
0
1
22-25
26,27,30-37,40-42
43-47,50
51-53
54,55,60-63
641
0
1
0
1
0
1
1. The pull-up resistor is disabled during VSB Power-Up reset.
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3.0 Device Architecture and Configuration
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3.14.5 GPIO Event Routing Register (GPEVR)
This register enables the routing of the GPIO event (see Section 7.3.2 on page 138) to IRQ and/or SIOSMI signals. It is
implemented only for Ports 1 and 4, which have wake-up event detection capability. This register is reset by hardware to 01h.
Power Well:VSB
Location:Index F2h
Type:
R/W
Bit
7
6
5
Name
4
Reset
0
0
0
0
Bit
7-2
3
2
Reserved
0
1
0
EV2SMI
EV2IRQ
0
1
0
Description
Reserved.
1
EV2SMI (Event to SMI Routing). Controls the routing of the event from the selected GPIO pin to SIOSMI (see
Section 7.3 on page 137).
0: Disabled (default)
1: Enabled
0
EV2IRQ (Event to IRQ Routing). Controls the routing of the event from the selected GPIO pin to IRQ (see
Section 7.3 on page 137).
0: Disabled
1: Enabled (default)
3.14.6 GPIO Pin Configuration Register 2 (GPCFG2)
This register controls the access to the GPIO pin from one of the two buses. This register is reset by hardware to 00h.
Power Well:VSB
Location:Index F3h
Type: R/W or RO
Bit
7
Name
Reserved
Reset
0
Bit
7
6-5
4
6
5
BUSCTL
0
4
3
2
VDDLOAD
0
0
1
0
0
0
Reserved
0
0
Description
Reserved.
BUSCTL (Bus Control). These bits select the bus (ACCESS.bus or LPC bus) that controls the configuration and
data of the selected GPIO pin. The bus not selected has read-only access to the GPCFG1, GPCFG2 and GPEVR
registers and to the corresponding bit in the GPDO, GPEVEN and GPEVST registers (see Section 7.4.2 on
page 140). In the PC87414 and PC87416, these bits are irrelevant because only the LPC bus is available.
Bits
6 5
Function
0
0
1
1
Access from ACCESS.bus and LPC bus (default)
Access from ACCESS.bus only
Access from LPC bus only
Reserved
0:
1:
0:
1:
VDDLOAD (VDD-Powered Load). This bit indicates that the selected GPIO pin is connected to a device
powered by VDD. The input and output (including the internal pull-up) of such a GPIO pin are disabled whenever
VDD power to the PC8741x device falls below a certain value (see Section 11.1.5 on page 232).
0: GPIO pin connected to a VSB-powered load (default)
1: GPIO pin connected to a VDD-powered load
3-0
Reserved.
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3.15 X-BUS CONFIGURATION
This section is relevant only for the PC87416 and PC87417.
3.15.1 Logical Device F (X-Bus) Configuration
Table 27 lists the configuration registers that affect the X-Bus functional block. The X-Bus base address registers point to
the X-Bus runtime registers described in Section 5.4 on page 107. The memory space to which the X-Bus responds is defined by the configuration registers described in the sections below. See Section 3.2.3 on page 40 for a detailed description
of the other configuration registers. The standard configuration registers are powered by VDD, however the specific configuration registers are powered by VSB.
Table 27. X-Bus Configuration Registers
Index
Configuration Register or Action
Type
Power Well Reset
30h
Activate (see Section 3.3.1 on page 43). When bit 0 is cleared, the
registers of this logical device are not accessible.
R/W
VDD
00h
60h
Base Address MSB register.
R/W
VDD
00h
61h
Base Address LSB register. Bits 4-0 (for A4-A0) are read only, 00000b. Varies per bit
VDD
00h
70h
Interrupt Number and wake-up on IRQ enable.
RO
VDD
00h
71h
Interrupt Type.
RO
VDD
00h
74h
Report no DMA assignment.
RO
VDD
04h
75h
Report no DMA assignment.
RO
VDD
04h
F0h
X-Bus I/O Configuration register (XIOCNF).
Varies per bit
VSB
00h
F1h
X-Bus I/O Base Address 1 High Byte register (XIOBA1H).
R/W or RO
VSB
00h
F2h
X-Bus I/O Base Address 1 Low Byte register (XIOBA1L).
R/W or RO
VSB
00h
F3h
X-Bus I/O Size 1 Configuration register (XIOSIZE1).
R/W or RO
VSB
00h
F4h
X-Bus I/O Base Address 2 High Byte register (XIOBA2H).
R/W or RO
VSB
00h
F5h
X-Bus I/O Base Address 2 Low Byte register (XIOBA2L).
R/W or RO
VSB
00h
F6h
X-Bus I/O Size 2 Configuration register (XIOSIZE2).
R/W or RO
VSB
00h
F7h
X-Bus Memory Configuration register 1 (XMEMCNF1).
R/W or RO
VSB
00h
F8h
X-Bus Memory Configuration register 2 (XMEMCNF2).
Varies per bit
VSB
00h
F9h
X-Bus Memory Base Address High Byte register (XMEMBAH).
R/W or RO
VSB
00h
FAh
X-Bus Memory Base Address Low Byte register (XMEMBAL).
R/W or RO
VSB
00h
FBh
X-Bus Memory Size Configuration register (XMEMSIZE).
R/W or RO
VSB
00h
FCh
X-Bus IRQ Mapping register (XIRQMAP).
R/W
VSB
00h
3.15.2 X-Bus I/O Range Programming
LPC I/O transactions can be forwarded to the X-Bus of the PC8741x device. The X-Bus I/O configuration registers define
the map of I/O addresses to be forwarded. The PC8741x provides five individually enabled I/O zones. Each zone generates
an internal select signal that is sent to the X-Bus functional block. The mapping of the internal select signals to the XCS0-3
signals of the PC8741x device is controlled by the X-Bus functional block. See Section 5.2 on page 92 for further details.
The supported I/O zones are:
●
User-Defined I/O Zone 0 through 3 (UDIZ0-3) - specified using the zone size (2n where n is 0 through 8) and start
address (must be aligned with the zone size).
●
Debug Port Address (TST) - This zone is for debug use only.
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3.0 Device Architecture and Configuration
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These decoded I/O zones are determined by the following seven registers: X-Bus I/O Configuration, X-Bus I/O Zone Base
Address 1/2 High and Low Byte and X-Bus I/O Size 1/2 Configuration. When a zone is enabled but is not associated with
any XCS0-3 select signal in the X-Bus Interface, the X-Bus does not respond to LPC transactions accessing that zone.
The I/O Address Map Lock bit (LOCKIOMP) in XIOCNF register enables protecting the contents of the I/O mapping by preventing modifications to them that would cause access rights violation through aliasing.
Figure 7 illustrates the mapping of the User-Defined I/O zones to the host I/O space. The order between Base Address 1
and 2 is an example only and may be reversed.
Host I/O Space
FFFFh
Zone Size 2
User-Defined I/O Zone 3 (UDIZ3)
Zone Size 2
Base Address 2 (High, Low)
User-Defined I/O Zone 2 (UDIZ2)
Zone Size 1
User-Defined I/O Zone 1 (UDIZ1)
Zone Size 1
Base Address 1 (High, Low)
User-Defined I/O Zone 0 (UDIZ0)
0000h
Figure 7. User-Defined I/O Block Mapping
3.15.3 X-Bus Memory Range Programming
LPC memory transactions or LPC-FWH transactions can be forwarded to the X-Bus Extension of the PC8741x device.
X-Bus Memory Configuration Register 1 defines the address space to which the device responds. The XCNF2 strap input
controls the default setting of the XMEMCNF1 register to enable booting from memories connected on the X-Bus. Two memory areas may be individually enabled: a user-defined zone and a BIOS memory zone (either BIOS-LPC, or BIOS-FWH
spaces).
To enable BIOS support, set the XCNF2 strap input to select the BIOS mode (see Section 1.4.11 on page 29 for details).
The PC8741x devices respond to LPC memory read and write transactions to/from the BIOS address spaces (see Table 28)
as long as the BIOLPCEN bit of XMEMCNF1 register is set (see Section 3.15.11 on page 83).
Table 28. BIOS-LPC Memory Space Definition
Memory Address Range
000E 0000h - 000E FFFFh
000F 0000h - 000F FFFFh
FFFC 0000h - FFFF FFFFh
FFF8 0000h - FFFF FFFFh
FFF0 0000h - FFFF FFFFh
FFE0 0000h - FFFF FFFFh
FFC0 0000h - FFFF FFFFh
FF80 0000h - FFFF FFFFh
FF00 0000h - FFFF FFFFh
FE00 0000h - FFFF FFFFh
Description
Extended BIOS Range (Legacy)
Only when BIOEXTEN = 1 in XMEMCNF1 register
BIOS Range (Legacy)
386 mode BIOS Range.
This is the upper 256 Kbytes to 32 Mbytes of the memory
space, depending on the setting of BIOSIZE and SEL2BIOS
in XMEMCNF2 (see Section 3.15.12 on page 84).
The PC8741x devices respond to LPC-FWH read transactions from the high memory address range (’386’ mode BIOS
range), shown in Table 28, as long as BIOFWHEN = 1 in the XMEMCNF1 register.
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3.0 Device Architecture and Configuration
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Table 29. BIOS-FWH Memory Space Definition
Memory Address Range
FFFC 0000h - FFFF FFFFh
FFF8 0000h - FFFF FFFFh
FFF0 0000h - FFFF FFFFh
FFE0 0000h - FFFF FFFFh
FFC0 0000h - FFFF FFFFh
FF80 0000h - FFFF FFFFh
FF00 0000h - FFFF FFFFh
FE00 0000h - FFFF FFFFh
Description
386 mode BIOS Range.
This is the upper 256 Kbytes to 32 Mbytes of the memory
space, depending on the setting of BIOSIZE and SEL2BIOS
in XMEMCNF2 (see Section 3.15.12 on page 84). The
PC8741x devices use the ID field and address bits A18-A27
to A25-A27, respectively, to identify FWH access to the BIOS
memory.
Upon reset in BIOS mode, both the BIOLPCEN and the BIOFWHEN bits in the XMEMCNF1 register are set. The PC8741x
device automatically detects the type of host boot protocol in use via the first completed BIOS read transaction after reset.
If the first read is an LPC memory read, the BIOFWHEN bit is cleared. If the first read is an LPC-FWH read, the BIOLPCEN
bit is cleared. The succeeding LPC or LPC-FWH transactions do not influence the BIOLPCEN and BIOFWHEN bits. The
software can later enable the response to both address spaces by setting the cleared bit. Figure 8 illustrates this behavior.
VSB Power-Up Reset
XCNF2 = Disable BIOS
XC
NF
2=
Ena
ble
BIO
S
BIOFWHEN = 0
BIOLPCEN = 0
BIOFWHEN = 1
BIOLPCEN = 1
First Memory Read
is LPC
Note:
Only hardware controlled transitions are shown.
Other transitions are possible via software
writing to the bits.
BIOFWHEN = 0
BIOLPCEN = 1
First Memory Read
is FWH
BIOFWHEN = 1
BIOLPCEN = 0
Figure 8. BIOS Mapping Enable Scheme
The two User-Defined Memory Zones (MEM0 and MEM1) are specified via a 32-bit base address. This address is formed
by eight bits of the XMEMBAL register, eight bits of the XMEMBAH register and 16 least significant bits of 0. The size of
each zone is specified through the XMEMSIZE register. The base address must be aligned to the block size. Figure 9 and
Figure 10 illustrate the mapping of the LPC and FWH spaces to the different memory zones.
The Memory Address Map Lock bit in X-Bus Memory Configuration Register 2 enables protection of the contents of the
memory mapping, thus preventing modifications to them that may cause access rights violation through aliasing.
The address used for the X-Bus transaction is the 28 least significant bits of the address bus. In read transactions, the data
read from the X-Bus is passed to the LPC bus. In write transactions, the data from the LPC is passed to the X-Bus.
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3.0 Device Architecture and Configuration
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Host Memory Space
FFFF FFFFh
BIOS Size
BIOS Zone 0 (BIOS 0)
BIOS Size
BIOS Zone 1 (BIOS 1)
Memory Zone Size
User-Defined Memory Zone 1 (MEM 1)
Memory Zone Size
User-Defined Memory Zone 0 (MEM 0)
Memory Base Address (High, Low)
Legacy BIOS Address space
0000 0000h
Figure 9. Memory Block Mapping
FFFF FFFFh
FWH Space
BIOS Size
FWH ID Match
BIOS Zone 0 (BIOS 0)
BIOS Size
BIOS Zone 1 (BIOS 1)
0000 0000h
Figure 10. FWH Memory Mapping
3.15.4 X-Bus I/O Configuration Register (XIOCNF)
This register is reset by hardware to 00h.
Power Well:VSB
Location:Index F0h
Type:
Varies per bit
Bit
7
Name
LOCKIOMP
Reset
0
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6
5
Reserved
0
4
TSTADEN
0
0
78
3
2
1
0
UDIOZEN3 UDIOZEN2 UDIOZEN1 UDIOZEN0
0
0
0
0
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7
6-5
PC8741x
3.0 Device Architecture and Configuration
(Continued)
Type
Description
RW1L LOCKIOMP (Lock I/O Address Map). When set to 1, this bit locks the configuration of registers
XIOCNF, XIOBA1H, XIOBA1L, XIOSIZE1, XIOBA2H, XIOBA2L and XIOSIZE2 by disabling writing to all
their bits (including to the LOCKIOMP bit itself). Once set, this bit can be cleared either by VDD PowerUp reset (or Hardware reset) or by VSB Power-Up reset, according to the VSBLOCK bit in the
ACBLKCTL register (see Section 6.3.4 on page 128). In addition, this bit is cleared by setting the
UNLOCKX bit in the ACBLKCTL register (PC87417).
0: R/W bits are enabled for write (default)
1: All bits are RO
-
Reserved.
4
R/W or TSTADEN (TST Debug Port Address Enable). When set, enables the mapping of I/O address 80h to
RO the X-Bus space.
0: Disabled (default)
1: Enabled
3
R/W or UDIOZEN3 (User-Defined I/O Zone Enable 3). This bit enables the mapping of the User-Defined I/O
RO zone 3 to the X-Bus space. The zone base address and size are defined by the XIOBA2H/XIOBA2L
and XIOSIZE2 registers, respectively.
The base address for this Zone is: (Base Address 2) + (Size 2)
0: Disabled (default)
1: Enabled
2
R/W or UDIOZEN2 (User-Defined I/O Zone Enable 2). This bit enables the mapping of the User-Defined I/O
RO zone 2 to the X-Bus space. The zone base address and size are defined by the XIOBA2H/XIOBA2L
and XIOSIZE2 registers, respectively.
The base address for this Zone is: (Base Address 2)
0: Disabled (default)
1: Enabled
1
R/W or UDIOZEN1 (User-Defined I/O Zone Enable 1). This bit enables the mapping of the User-Defined I/O
RO zone 1 to the X-Bus space. The zone base address and size are defined by the XIOBA1H/XIOBA1L
and XIOSIZE1 registers, respectively.
The base address for this Zone is: (Base Address 1) + (Size 1)
0: Disabled (default)
1: Enabled
0
R/W or UDIOZEN0 (User-Defined I/O Zone Enable 0). This bit enables the mapping of the User-Defined I/O
RO zone 0 to the X-Bus space. The zone base address and size are defined by the XIOBA1H/XIOBA1L
and XIOSIZE1 registers, respectively.
The base address for this Zone is: (Base Address 1)
0: Disabled (default)
1: Enabled
3.15.5 X-Bus I/O Base Address 1 High Byte Register (XIOBA1H)
This register describes the high byte of the Base Address for user-defined I/O zone blocks 0 and 1, which are mapped to
the X-Bus. This register is reset by hardware to 00h.
Power Well:VSB
Location:Index F1
Type:
Bit
R/W or RO
7
6
5
4
0
0
0
0
Name
Reset
Revision 1.2
3
2
1
0
0
0
0
0
IOBA1H
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3.0 Device Architecture and Configuration
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Bit
Description
7-0
IOBA1H (I/O User-Defined Zone Base Address 1 High). Defines the upper eight bits of the user-defined I/O
blocks 0 and 1 base address. The base address must be aligned on the selected block size.
3.15.6 X-Bus I/O Base Address 1 Low Byte Register (XIOBA1L)
This register describes the low byte of the Base Address for User-Defined I/O zone blocks 0 and 1, which are mapped to
the X-Bus. This register is reset by hardware to 00h.
Power Well:VSB
Location:Index F2h
Type:
R/W or RO
Bit
7
6
5
4
Name
2
1
0
0
0
0
0
IOBA1L
Reset
0
0
0
Bit
7-0
3
0
Description
IOBA1L (I/O User-Defined Zone Base Address 1 Low). Defines the lower eight bits of the user-defined I/O
blocks 0 and 1 base address. The base address must be aligned on the selected block size.
3.15.7 X-Bus I/O Size 1 Configuration Register (XIOSIZE1)
This register defines the size of User-Defined I/O zone blocks 0 and 1, which are mapped to the X-Bus. The two blocks are
contiguous and both have the same size. The User-Defined I/O Zone 1 address does not depend on Zone 0 being enabled.
This register is reset by hardware to 00h.
Power Well:VSB
Location:Index F3h
Type:
R/W or RO
Bit
7
6
0
0
Name
5
4
3
2
0
0
0
0
Reserved
Reset
Bit
1
0
0
0
IOSIZE1
Description
7-4
Reserved.
3-0
IOSIZE1 (User-Defined I/O Zone Size 1). Defines the size in bytes of the zone window. The size is defined as
a power of two using the equation: NumOfBytes = 2n (where n = the value of the IOSIZE1 field). The zone must
always be aligned to the window size (i.e., for a 128-byte window, the seven LSBs of the base address are zero).
Bits
3210
Size (Bytes)
0 0 0 0:
1 (20 - default)
...
1 0 0 0:
Other:
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256 (28)
Reserved
80
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3.0 Device Architecture and Configuration
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3.15.8 X-Bus I/O Base Address 2 High Byte Register (XIOBA2H)
This register describes the high byte of the Base Address for User-Defined I/O zone blocks 2 and 3, which are mapped to
the X-Bus. This register is reset by hardware to 00h.
Power Well:VSB
Location:Index F4
Type:
R/W or RO
Bit
7
6
5
4
Name
3
2
1
0
0
0
0
0
IOBA2H
Reset
0
0
0
0
Bit
Description
7-0
IOBA2H (I/O User-Defined Zone Base Address 2 High). Defines the upper eight bits of the User-Defined I/O
blocks 2 and 3 base address. The base address must be aligned on the selected block size.
3.15.9 X-Bus I/O Base Address 2 Low Byte Register (XIOBA2L)
This register describes the low byte of the Base Address for User-Defined I/O zone blocks 2 and 3, which are mapped to
the X-Bus. This register is reset by hardware to 00h.
Power Well:VSB
Location:Index F5h
Type:
Bit
R/W or RO
7
6
5
4
Name
Reset
Bit
7-0
Revision 1.2
3
2
1
0
0
0
0
0
IOBA2L
0
0
0
0
Description
IOBA2L (I/O User-Defined Zone Base Address 2 Low). Defines the lower eight bits of the user-defined I/O
blocks 2 and 3 base address. The base address must be aligned on the selected block size.
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PC8741x
3.0 Device Architecture and Configuration
(Continued)
3.15.10 X-Bus I/O Size 2 Configuration Register (XIOSIZE2)
This register defines the size of User-Defined I/O zone blocks 2 and 3, which are mapped to the X-Bus. The two blocks are
contiguous and have the same size. The User-Defined I/O Zone 3 address does not depend on Zone 2 being enabled. This
register is reset by hardware to 00h.
Power Well:VSB
Location:Index F6h
Type:
R/W or RO
Bit
7
6
0
0
Name
5
4
3
2
0
0
0
0
Reserved
Reset
Bit
1
0
0
0
IOSIZE2
Description
7-4
Reserved.
3-0
IOSIZE2 (User-Defined I/O Zone Size 2). Defines the size in bytes of the zone window. The size is defined as
a power of two using the equation: NumOfBytes = 2n (where n = the value of bits 3-0). The zone must always
be aligned to the window size (i.e., for a 128-byte window, the seven LSBs of the base address are zero).
Bits
3210
Size (Bytes)
0 0 0 0:
1 (20 - default)
...
1 0 0 0:
Other:
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256 (28)
Reserved
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3.0 Device Architecture and Configuration
(Continued)
3.15.11 X-Bus Memory Configuration Register 1 (XMEMCNF1)
This register is reset by hardware to 00h.
Power Well:VSB
Location:Index F7h
Type:
Bit
R/W or RO
7
6
0
0
Name
Reset
5
4
0
0
FWHID
3
2
1
0
BIOFWHEN UDMEMEN BIOEXTEN BIOLPCEN
Strap
0
0
Strap
Bit
Description
7-4
FWHID (BIOS FWH ID). These four bits correspond to the Device Select nibble that is part of a FWH transaction
(see Section 4.2 on page 90 for details).
3
BIOFWHEN (BIOS FWH Enable). When set, this bit enables the PC8741x device to respond to LPC-FWH
transactions to the BIOS-FWH space. The default value is set according to the XCNF2 strap, sampled at VSB
Power-Up reset. The value of this bit is later updated based on the detected host BIOS scheme (see Section
3.15.3 on page 76 for details).
0: Disabled (default when XCNF2 = 0 - disables BIOS configuration)
1: Enabled (default when XCNF2 = 1 - enables BIOS configuration)
2
UDMEMEN (User-Defined Memory Space Enable). When set, this bit enables the PC8741x device to respond
to LPC memory read and write transactions in the user-defined memory range. The base address and size of
the user-defined range is specified by the XMEMBAH/XMEMBAL and XMEMSIZE registers, respectively.
0: Disabled (default)
1: Enabled
1
BIOEXTEN (BIOS Extended Space Enable). Expands the BIOS address space to which the PC8741x device
responds, to include the Extended BIOS address range.
0: Disabled (default)
1: Enabled
0
BIOLPCEN (BIOS LPC Enable). Enables the PC8741x device to respond to LPC memory transactions to the
BIOS-LPC space. The default value is set according to the XCNF2 strap, sampled at VSB Power-Up reset. The
value of this bit is later updated, based on the detected host BIOS scheme (see Section 3.15.3 on page 76 for
details).
0: Disabled (default when XCNF2 = 0 - disables BIOS configuration)
1: Enabled (default when XCNF2 = 1 - enables BIOS configuration)
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PC8741x
3.0 Device Architecture and Configuration
(Continued)
3.15.12 X-Bus Memory Configuration Register 2 (XMEMCNF2)
This register is reset by hardware to 00h.
Power Well:VSB
Location:Index F8h
Type:
Varies per bit
Bit
7
Name
LOCKMMP
Reset
0
6
5
Reserved
0
0
4
3
SEL2UDM
SEL2BIOS
0
0
2
1
0
BIOSIZE
0
0
0
Bit
Description
7
LOCKMMP (Lock Memory Address Map). When set to 1, this bit locks the configuration of registers
XMEMCNF1, XMEMCNF2, XMEMBAH, XMEMBAL and XMEMSIZE by disabling writing to all their bits
(including to the LOCKMAP bit itself). Once set, this bit can be cleared either by VDD Power-Up reset (or
Hardware reset) or by VSB Power-Up reset, according to the VSBLOCK bit in the ACBLKCTL register (see
Section 6.3.4 on page 128). In addition, this bit is cleared by setting the UNLOCKX bit in the ACBLKCTL register
(PC87417).
0: R/W bits are enabled for write (default)
1: All bits are RO
6-5
Reserved.
4
SEL2UDM (Dual User-Defined Memory Select Enable). Enables the PC8741x device to control two memory
devices for data storage. The second zone (MEM Zone 1) is mapped on top of the first zone (MEM Zone 0).
Both zones are the same size. The base address of MEM Zone 0 is specified by the XMEMBAH and XMEMBAL
registers. The size of both memory zones is specified by the XMEMSIZE register. The base address of MEM
Zone 1 is: (Base Address Memory Zone) + (Size Memory Zone).
0: Disabled - Use only MEM Zone 0, if enabled (default)
1: Enabled - If the user-defined memory is enabled, use both MEM Zone 0 and MEM Zone 1
3
SEL2BIOS (Dual BIOS Select Enable). Enables the PC8741x device to control two flash devices for BIOS
storage. The first device (BIOS Zone 0) is used for legacy and the upper 386 zone. BIOS zone 1 is on the next
“BIOS Size” block in the 386 address range (addresses lower than these of Block 1). When FWH is enabled,
BIOS Zone 0 responds to the upper addresses and BIOS Zone 1, if enabled, responds to the group below Zone
0, as defined by BIOS Size. Both zones use the same FWHID value.
0: Disabled - Use BIOS Zone 0 only, if enabled (default)
1: Enabled - If either the LPC BIOS or the FWH BIOS is enabled, use both BIOS Zone 0 and BIOS Zone 1
2-0
BIOSIZE (BIOS Size). Define the Size of one BIOS Zone in the 386 range. Note that by setting the Dual BIOS
Select Enable, two equal-sized BIOS Zones are available.
Bits
2 1
0 0
0 0
0 1
0 1
1 0
1 0
1 1
1 1
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0
0:
1:
0:
1:
0:
1:
0:
1:
Size (Bytes)
256 Kbytes (default)
512 Kbytes
1 Mbyte
2 Mbytes
4 Mbytes
8 Mbytes
16 Mbytes
Reserved
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3.0 Device Architecture and Configuration
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3.15.13 X-Bus Memory Base Address High Byte Register (XMEMBAH)
This register describes the high byte for the user-defined memory zones mapped to the X-Bus (decoded as bits 31 to 24 of
the 32-bit address range; bits 15-0 are 0). This register is reset by hardware to 00h.
Power Well:VSB
Location:Index F9h
Type:
R/W or RO
Bit
7
6
5
4
Name
2
1
0
0
0
0
0
MEMBAH
Reset
0
0
0
Bit
7-0
3
0
Description
MEMBAH (User-Defined Memory Zone Address High). Defines the upper eight bits of the user-defined
memory block base address. The base address must be aligned on the selected block size.
3.15.14 X-Bus Memory Base Address Low Byte Register (XMEMBAL)
This register describes the low byte for the user-defined memory zones mapped to the X-Bus (decoded as bits 23 to 16 of
the 32-bit address range; bits 15 to 0 are 0). This register is reset by hardware to 00h.
Power Well:VSB
Location:Index FAh
Type:
Bit
R/W or RO
7
6
5
4
Name
Reset
Bit
7-0
Revision 1.2
3
2
1
0
0
0
0
0
MEMBAL
0
0
0
0
Description
MEMBAL (User-Defined Memory Zone Address Low). Defines the lower eight bits of the user-defined
memory block base address. The base address must be aligned on the selected block size.
85
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PC8741x
3.0 Device Architecture and Configuration
(Continued)
3.15.15 X-Bus Memory Size Configuration Register (XMEMSIZE)
This register defines the size of each user-defined memory zone mapped to the X-Bus. This register is reset by hardware
to 00h.
Power Well:VSB
Location:Index FBh
Type:
R/W or RO
Bit
7
6
Name
5
4
3
2
Reserved
Reset
0
0
1
0
0
0
MEMSIZE
0
Bit
0
0
0
Description
7-4
Reserved.
3-0
MEMSIZE (User-Defined Memory Zone Size). Defines the size of one zone window (in bytes). The size is
defined as a power of two using the equation: NumOfBytes = 2n (where n = the value of the MEMSIZE field
+16). The zone must always be aligned to the window size (i.e., for a 128 Kbyte window, the 17 LSBs of the
address must be zero).
Bits
3 210
Size (Bytes)
0 0 0 0:
64K (216 - default)
...
1 0 0 0:
Other:
16M (224)
Reserved
3.15.16 X-Bus IRQ Mapping Register (XIRQMAP)
This register defines the mapping of the XIRQ signal.
Power Well:VSB
Location:Index FCh
Type:
R/W
Bit
7
6
Name
5
4
3
2
Reserved
Reset
0
0
Bit
1
0
0
0
IRQMAP
0
0
0
0
Description
7-4
Reserved.
3-0
IRQMAP (XIRQ Mapping). Defines to which host IRQ the XIRQ input is routed.
Bits
3 2 1 0
Function
0 0 0 0:
0 0 0 1:
...
IRQ Disabled (default)
IRQ1
1 1 1 1:
IRQ 15
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3.0 Device Architecture and Configuration
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3.16 REAL TIME CLOCK (RTC) CONFIGURATION
3.16.1 General Description
The RTC provides timekeeping and calendar management capabilities. It uses a 32.768 KHz signal as the basic clock for
timekeeping. The RTC also includes 242 bytes of battery-backed RAM for general-purpose use.
The RTC runtime registers are shown in Section 8.3.2 on page 150. These registers are VPP powered.
3.16.2 Logical Device 10 (RTC) Configuration
Table 30 lists the configuration registers that affect the Real Time Clock. The standard configuration registers (see Section
3.2.3 on page 40) are powered by VDD. The specific configuration registers are powered by VSB.
Table 30. RTC Configuration Registers
Index
RTC Configuration Register or Action
Type
Power Well Reset
30h
Activate (see Section 3.3.1 on page 43). When bit 0 is cleared, the runtime
registers of this logical device are not accessible.
R/W
VDD
00h
60h
Standard Base Address MSB register.
R/W
VDD
00h
61h
Standard Base Address LSB register. Bit 0 (for A0) is read only 0b.
R/W
VDD
70h
62h
Extended RAM Base Address MSB register.
R/W
VDD
00h
63h
Extended RAM Base Address LSB register. Bit 0 (for A0) is read only 0b.
R/W
VDD
72h
70h
RTC Interrupt Number and Wake-Up on IRQ Enable register.
R/W
VDD
08h
71h
RTC Interrupt Type. Bit 1 is read/write; other bits are read only.
R/W
VDD
00h
74h
Report no DMA assignment.
RO
VDD
04h
75h
Report no DMA assignment.
RO
VDD
04h
F0h
RAM Lock Register (RLR).
R/W1S
VSB
00h
F1h
Date-of-Month Alarm Register Offset (DOMAO).
R/W
VSB
00h
F2h
Month Alarm Register Offset (MONAO).
R/W
VSB
00h
F3h
Century Register Offset (CENO).
R/W
VSB
00h
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PC8741x
3.0 Device Architecture and Configuration
(Continued)
3.16.3 RAM Lock Register (RLR)
Once a non-reserved bit is set to 1, it can be cleared either by VDD Power-Up reset (or Hardware reset) or by VSB Power-Up
reset, according to the VSBLOCK bit in the ACBLKCTL register (see Section 6.3.4 on page 128). In addition, all the bits are
cleared by setting the UNLOCKR bit in the ACBLKCTL register (see Section 6.3.4 on page 128 - PC87413 and PC87417).
Power Well:VSB
Location:Index F0h
Type:
R/W1S
Bit
7
6
5
4
3
Name
BLSTR
BLRWR
BLEXRWR
BLEXRRD
BLEXR
Reset
0
0
0
0
0
2
1
0
Reserved
0
0
0
Bit
Description
7
BLSTR (Block Standard RAM). Disables both read and write access to locations 38h-3Fh of the Standard RAM
(writes are ignored; reads return FFh).
0: Normal access (default)
1: Read and write to locations 38h-3Fh of the Standard RAM are blocked
6
BLRWR (Block RAM Write). Disables write access to both the Standard and Extended RAM (writes are
ignored).
0: Normal access (default)
1: Writes to RAM (Standard and Extended) are blocked
5
BLEXRWR (Block Extended RAM Write). Disables write access to bytes 00h-1Fh of the Extended RAM (writes
are ignored).
0: Normal access (default)
1: Writes to bytes 00h-1Fh of the Extended RAM are blocked
4
BLEXRRD (Block Extended RAM Read). Disables read access from bytes 00h-1Fh of the Extended RAM
(reads return FFh).
0: Normal access (default)
1: Reads from bytes 00h-1Fh of the Extended RAM are blocked
3
BLEXR (Block Extended RAM). Disables both read and write access to the Extended RAM (writes are ignored;
reads return FFh).
0: Normal access (default)
1: Read and write to the Extended RAM are blocked
2-0
Reserved.
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3.0 Device Architecture and Configuration
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3.16.4 Date-of-Month Alarm Register Offset (DOMAO)
Power Well:VSB
Location:Index F1h
Type:
R/W
Bit
7
Name
Reserved
Reset
0
6
5
6-0
3
2
1
0
0
0
0
DOMAO
0
0
Bit
7
4
0
0
Description
Reserved.
DOMAO (Date of Month Alarm Register Offset Value). Sets the offset value of the Date-of-Month Alarm
(DOMA) runtime register.
3.16.5 Month Alarm Register Offset (MONAO)
Power Well: VSB
Location:
Index F2h
Type: R/W
Bit
7
Name
Reserved
Reset
0
6
5
6-0
3
2
1
0
0
0
0
MONAO
0
0
Bit
7
4
0
0
Description
Reserved.
MONAO (Month Alarm Register Offset Value). Sets the offset value of the Month Alarm (MONA) runtime
register.
3.16.6 Century Register Offset (CENO)
Power Well:VSB
Location:Index F3h
Type:
R/W
Bit
7
Name
Reserved
Reset
0
Bit
7
6-0
Revision 1.2
6
5
4
3
2
1
0
0
0
0
CENO
0
0
0
0
Description
Reserved.
CENO (Century Register Offset Value). Sets the offset value of the Century (CEN) runtime register.
89
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PC8741x
4.0
LPC Bus Interface
With the exception of the ACCESS.bus Interface, the host can access all the functional blocks of the PC8741x device
through the LPC bus.
4.1
OVERVIEW
The LPC host Interface supports 8-bit I/O Read, 8-bit I/O Write and 8-bit DMA transactions, as defined in Intel’s LPC Interface Specification, Revision 1.0.
4.2
LPC TRANSACTIONS
The LPC Interface of the PC8741x devices can respond to the following LPC transactions as part of the standard ServerI/O
implementation:
•
•
•
8-bit I/O read and write cycles.
8-bit DMA read and write cycles.
DMA request cycles.
In addition, the X-Bus bridge uses the following transactions (PC87416 and PC87417):
•
•
•
8-bit I/O read and write cycles.
8-bit memory read and write.
8-bit FWH read
LPC-FWH Cycles: The LPC bus and the ACCESS.bus (PC87413 and PC87417) use the internal bus of the PC8741x device to access the internal modules or to bridge transactions to the X-Bus (see the Block Diagrams on pages 1 and 5). In
case both the LPC and the ACCESS.bus try to access targets (same or different) through the internal bus simultaneously,
the LPC transaction is deferred until the end of the ACCESS.bus transaction. This is achieved by generating Long Wait
SYNC cycles on the LPC bus. The amount of time the LPC bus waits depends on the duration of the ACCESS.bus transaction (see Section 6.2.10 on page 125). An LPC transaction that starts before an ACCESS.bus transaction is performed normally (i.e., without interference).
The LPC-FWH read cycle is similar to the LPC memory read cycle, as shown below. The DATA, TAR and SYNC fields are
as specified for LPC memory read cycle. The START field is similar to the equivalent field in the LPC memory read cycle
but differs in the data placed on the LAD signals (see details in the cycle description). The Address field contains only seven
nibbles (A27-A0), starting with the most significant. The IDSEL and MSIZE fields are specific to LPC-FWH transactions.
FWH Read Cycle
1. START
FWH Memory Read cycle type = 1101 (0Dh).
2. IDSEL
FWH Device Select ID nibble (compared with the FWHID field in the XMEMCNF1 register,
Section 3.15.11 on page 83).
3. MADDR
Memory Address: seven address nibbles, MS nibble first (see LPC-FWH Address Translation:, below).
4. MSIZE
Memory Size, single byte = 0000 (00h).
5. TAR (two cycles).
6. SYNC.
7. DATA
Data: two nibbles, LS nibble first (D3-D0, D7-D4).
8. TAR (two cycles).
The IDSEL field is compared with the FWHID field in the XMEMCNF1 register, as described in Section 3.15.11 on page 83.
If the two match, the PC8741x device continues handling the transaction; if not, the current LPC-FWH transaction is ignored.
The MSIZE field is ignored by the PC8741x devices.
LPC-FWH Address Translation: The address field in the LPC-FWH transaction is constructed of seven nibbles, containing
the 28 LS address bits (A27-A0), as follows: the first incoming nibble corresponds to addresses A27-A24, the second to A23A20, and so forth, until the seventh nibble, which corresponds to A3-A0. The MS bits of the 32-bit addresses (A31-A28) are
assumed to be ‘1111’.
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4.3
PC8741x
4.0 LPC Bus Interface
(Continued)
CLKRUN FUNCTIONALITY
The PC8741x devices support the CLKRUN I/O signal, which is implemented according to the specification in PCI Mobile
Design Guide, Revision 1.1, December 18, 1998. The PC8741x devices support operation with both a slow and stopped
clock in ACPI state S0 (the system is active but is not being accessed). In the following cases, the PC8741x device drives
the CLKRUN signal low to force the LPC bus clock into full speed operation:
●
An IRQ is pending internally, waiting to be sent through the serial IRQ.
●
A DMA request is pending internally, waiting to be sent through the serial DMA.
Note: When the CLKRUN signal is not in use, the PC8741x devices assume a valid clock on the LCLK pin.
4.4
INTERRUPT SERIALIZER
The Interrupt Serializer translates parallel interrupt request (PIRQ) signals received from external devices, via the XIRQ pin
(PC87416 and PC87417) and from internal IRQ sources, into serial interrupt request data transmitted over the SERIRQ bus.
This enables devices that support only parallel IRQs to be integrated into a system that supports only serial IRQs.
The external XIRQ signal and the internal IRQs are fed into a Mapping, Enable and Polarity Control block, which maps them
to their associated IRQ slots. The IRQs are then fed into the Interrupt Serializer, where they are translated into serial data
and transmitted over the SERIRQ bus.
The XIRQ input value is routed to the Interrupt Serializer as the IRQn value to be driven onto IRQ slot n.
The same slot cannot be shared among different interrupt sources in the device.
When a transition is sensed on an IRQ source, the new value of the IRQ source is transmitted over the SERIRQ bus during
the corresponding IRQ slot. For example, when a transition on XIRQ is sensed, the new value of XIRQ is transmitted during
slot n of the SERIRQ bus.
Figure 11 shows the mechanism for both interrupt serialization and wake-up.
Bus Interface
Internal
IRQ
Sources
IRQ1
IRQ Mapping
and Polarity
Control
XIRQ
Interrupt
Serializer
SERIRQ
IRQ15
(PC87416 and PC87417)
Control
Signals
Wake-Up
Enable
Control
SWC
Figure 11. Interrupt Serialization and Wake-Up Mechanism
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X-Bus Extension
This section is relevant only for the PC87416 and PC87417. In the PC87413 and PC87414, all X-Bus Extension bits
and signals that influence other modules are at their default value.
5.1
OVERVIEW
The PC8741x provides an X-Bus extension to the LPC bus or ACCESS.bus to enable the connection of external 8-bit
memories or peripherals through the X-Bus’s ISA-like interface. A single read/write line and an enable pin replace the ISAlike protocol. The decode logic, described in Section 3.15 on page 75, defines the addresses for which the X-Bus generates
transactions that occur in the I/O address space and memory address space or in the FWH memory address space. Using
the X-Bus Interface, the PC8741x serves as a bridge for such transactions over the X-Bus. Figure 12 is a block diagram of
the X-Bus bridging function. For details on the decoder functions, see Section 3.15 on page 75. All other functions are described in detail in this section.
IRQ
Serializer
XA11-0
X-Bus
Configuration
XD7-0
ACCESS.bus
Device Architecture Module
X-Bus Interface
MUX
I/O
Address
Decoder
XCS0
MUX
Memory
Address
Decoder
XRD_XEN
XWR_XRW
XSTB2-0
XRDY
XCS1
MUX
Bus
Cycle
Generator
XCS2
MUX
LPC Interface
LPC
Bus
XIRQ
IRQ Router
Internal Bus
SERIRQ
ACCESS.bus Interface
PC8741x
5.0
XCS3
XCNF2-0
Figure 12. X-Bus Extension Block Diagram
The PC8741x supports one IRQ input: XIRQ. This pin may be used to support external legacy devices that are connected
on the X-Bus. The interrupt from this pin can be routed to any one of 15 host IRQs. The IRQ input is mapped by the X-Bus
XIRQ Mapping register at FCh. The XIRQC register enables the user to define the interrupt as active high or low and to route
it to a wake-up event.
5.2
X-BUS TRANSACTIONS
The X-Bus extension supports 8-bit I/O or Memory read/write cycles.
The zone mapping of the chip-select signals determines how X-Bus read and write cycles correspond to memory and I/O
LPC bus cycles. The zone mapping to a select signal (XCS3-0) must be enabled in order for the zone to respond to LPC
transactions. However, when the chip-select signal is not required by an off-chip device, multiplexing the chip select to a pin
is not necessary.
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There are two X-Bus address modes:
●
Normal Address mode - A signal is assigned for each address line (only XA11-XA0 are available at the device pins)
and a non-multiplexed address data bus is used. In this mode, only address signals 0 through 11 are generated.
●
Latched Address mode - The number of pins used for outputting the address is reduced. The address lines are multiplexed with the data bus. External latches may be used to generate address signals from the multiplexed bus. These
address signals are required to access memory and I/O devices. In this mode address, signals 0 through 27 are generated, allowing access to memory in excess of 1 Mbyte.
There are two X-Bus transaction modes:
●
Mode 0 - The X-Bus transactions are ISA-like, using separate read and write signals. XWR_XRW functions as the
write signal (XWR); XRD_XEN functions as the read signal (XRD). The following speed levels are available for
Mode 0, X-Bus transactions:
— Normal
— Fast
— Turbo
●
Mode 1 - The X-Bus transactions are read/write and enable controlled transactions, using XWR_XRW as the read
and write signal (XRW) and XRD_XEN as the enable signal (XEN). When XWR_XRW is high, it identifies a read
transaction; when low, it identifies a write transaction.
5.2.1
Transaction Clock
X-Bus access timing is referenced to an internal clock referred to as CLK or “the clock”. Transactions are described in terms
of this clock and the AC specifications are also defined relative to it. This provides an easy way for calculating the timing
during system design. Note that the system interface is optimized for an asynchronous interface. For hints on how to use the
asynchronous interface, refer to the usage hints in Section 5.5 on page 115.
X-Bus Clock:
●
For transactions triggered by the LPC bus, the clock is an internal version of the LPC clock (i.e., it has the same frequency but may have some phase delay).
●
For transactions driven by the ACCESS.bus (PC87417), the clock is the Standby clock as defined in Section 2.3.1 on
page 36.
5.2.2
Programmable Range Chip Select
The PC8741x has four chip-select signals (XCS3-0) to control the X-Bus accesses to off-chip devices. The PC8741x X-Bus
functional block enables flexible association of these chip selects with I/O and memory address ranges in the LPC address
space. The Zone Mapping field of the X-Bus Select Configuration registers defines the decoded address range(s) to which
the specific XCSn signal responds. In addition, the X-Bus Configuration register enables specifying the access time for each
select signal via bits that control the fixed wait and variable wait cycles (using the XRDY input).
If the chip-select signal setting results in a conflict in which one or more selects are configured for the same zone, XCS0 has
the highest priority and XCS3 has the lowest. The XCSn signal with the lower priority remain inactive and their Select Configuration register setting is ignored. For zones that are not associated with one of the chip-select signals, the X-Bus does
not respond to LPC transactions.
In addition, X-Bus transactions may be generated in response to a request from the ACCESS.bus (PC87417). In such a
case, the target select signal (XCS3) and the offset address are specified in the ACCESS.bus protocol. See Section 6.2.9
on page 121 for the specification of ACCESS.bus operation.
5.2.3
LPC and FWH Address-to-X-Bus Address Translation
The BIOS memory on the LPC bus can occupy one of three regions in the memory space (see Table 28 on page 76). Address translation between the LPC bus address and the X-Bus is performed as follows:
I/O Transactions. The 16-bit address received from the LPC bus is used to decode the different I/O zones described in
Section 3.15.2 on page 75. The address is then left-padded with zeroes (address lines 16 through 27) to create the 28-line
input address to the X-Bus Extension functional block.
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Memory Transactions. The 32-bit address received from the LPC bus is used to decode the different memory zones described in Section 3.15.3 on page 76. The address is then translated to the X-Bus address, using the following rules:
●
User-Defined Memory Zones (MEM 0 and MEM 1) and 386 Mode-Compatible BIOS Range: The 28 least significant
address lines of the LPC address are used as the X-Bus input address. Figure 13 illustrates the mapping for this
zone.
●
Legacy and Extended Legacy BIOS Range: The 17 least significant address lines (A16-0) of the LPC address are
routed as the 17 least significant address signals of the X-Bus (XA16-0). The upper 11 X-Bus address lines are driven to ‘1’. This shifts the addresses to the top of the X-Bus memory space (see Figure 14).
X-Bus Address
LPC Bus Address
xFFF FFFFh
FFFC 0000h
xFFC 0000h
*******
FFFF FFFFh
0000 0000h
Figure 13. LPC-to-X-Bus Address Translation: 386 Mode-Compatible BIOS Range
X-Bus Address
LPC Bus Address
FFFF FFFFh
xFFF FFFFh
000F FFFFh
Legacy BIOS
xFFE 0000h
000F 0000h
000E FFFFh
Extended
Legacy BIOS
000E 0000h
*******
PC8741x
5.0 X-Bus Extension
0000 0000h
Figure 14. LPC-to-X-Bus Address Translation: Legacy and Extended Legacy BIOS Ranges
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Indirect Memory Read and Write Transactions
I/O mapped registers accessed through an LPC I/O transaction may be used to perform an X-Bus memory transaction. This
mechanism uses the following X-Bus Extension module registers:
●
Four Indirect Memory Address registers (XIMA3-0), representing address bits 31 to 0.
●
One Indirect Memory Data register (XIMD), representing data bits 7 to 0.
●
Four enable bits, one for each Select Configuration register, XZCNF0, XZCNF1, XZCNF2 and XZCNF3.
Following an LPC I/O write to the XIMD register, a Memory write cycle is initiated on the X-Bus using the addresses from
the previously written XIMA3-0 registers and data from the XIMD register. Following an LPC I/O read from the XIMD register,
a Memory read cycle is initiated on the X-Bus using the address from the XIMA3-0 registers. The returned data from the XBus cycle is used to finish the read cycle from the XIMD register.
Indirect memory transactions may be enabled for one chip-select signal only. If more than one enable bit in the Select Configuration registers is set, the indirect memory access will be available only for the XCSn with the highest priority. The setting
of the enable bit for the chip selects with lower priority will be ignored. XCS0 has the highest priority and XCS3 has the lowest
priority.
5.2.5
Mode 0, Normal Address X-Bus Transactions
The read and write transactions in Normal Address mode are similar to those used in the X-Bus or ISA bus. At least two idle
cycles are inserted at the end of each X-Bus transaction cycle before the next transaction starts (there may be more idle
cycles due to the LPC transactions). This mode is selected for transactions accessing XCSn by setting TRANSMD = 0 in the
corresponding XZMn register.
Read Transactions. When a read cycle on the LPC falls within an enabled decoded address range of the X-Bus functional
block (or an indirect read is started or an X-Bus read through the ACCESS.bus is started) and the relevant XCSn is set to
mode 0, a Mode 0 read cycle begins. A read cycle (see Figure 15) starts by outputting the address on address signals XA110 on the rising edge of the clock. During this time, the PC8741x device does not drive the data bus signals XD7-0. One CLK
cycle later, a chip-select signal XCSn is asserted, where n is a chip-select number from 0 to 3, based on the address accessed and the select signal mapping. Three CLK cycles later, on the rising edge of the clock, the XRD signal is asserted
(set low), indicating a read cycle and enabling the accessed device to drive the data bus. After 16 CLK cycles plus the internally programmed wait state period, if XRDY use is enabled for this zone, its value is then sampled on the rising edge of the
clock. The transaction is extended until XRDY is detected to be high. Four CLK cycles later, the input data XD7-0 is sampled
on the rising edge of the clock. One CLK cycle later, XRD is de-asserted (set high) and one CLK cycle after that, the transaction is completed by de-asserting XCSn. The address is retained for two more CLK cycles after which the address lines
are driven to 0.
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5.0 X-Bus Extension
(Continued)
CLK
(Internal; for
Reference Only)
XD7-0
XD7-0 (Data In)
(Data Read)
XA11-0
XCSn
XWR_XRW
XRD_XEN
XRDY
Insert: 12 + “Programmed Wait States” CLK cycles here.
During this time, non-clock signals do not change.
Figure 15. Mode 0, Normal Address X-Bus Transaction - Read Access Cycle
Write Transactions. When a write cycle on the LPC falls within any of the enabled decoded address ranges of the X-Bus
functional block (or an indirect write is started or an X-Bus write through the ACCESS.bus is started) and the relevant XCSn
is set to mode 0, a Mode 0 write cycle begins. A write cycle (see Figure 16) starts by outputting the address on address
signals XA11-0 and the data signals on data pins XD7-0 on the rising edge of the clock. One CLK cycle later, a chip-select
signal XCSn is asserted, where n is a chip-select number from 0 to 3, based on the address accessed and the select signal
mapping. Three CLK cycles later, on the rising edge of the clock, the XWR signal is asserted (set low), indicating a write
cycle and enabling the accessed device to be written. After 16 CLK cycles plus the internally programmed wait state period,
if XRDY use is enabled for this zone, its value is then sampled on the rising edge of the clock. The transaction is extended
until XRDY is detected to be high. Five CLK cycles later, XWR is de-asserted (set high) and one CLK cycle later, the transaction is completed by de-asserting XCSn and floating the data bus signals XD7-0. Two CLK cycles later, the address lines
are driven to 0.
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CLK
(Internal;
for Reference Only)
XD7-0
XA11-0
XCSn
XWR_XRW
XRD_XEN
XRDY
Insert: 12 + “Programmed Wait States” CLK cycles here.
During this time, non-clock signals do not change.
Figure 16. Mode 0, Normal Address X-Bus Transaction - Write Access Cycle
5.2.6
Mode 0, Normal Address, Fast X-Bus Transactions
The read and write transactions in Normal Address, Fast X-Bus transactions are similar to those in Mode 0, Normal Address
X-Bus Transactions on page 95, differing only in the delay for valid data. Because Normal Address, Fast X-Bus transactions
have 14 to 20 fewer cycles than Normal Address transactions, they can be used to speed up access to fast devices. The
gray areas in Figures Figure 15 and Figure 16 (+ 2 CLK cycles) represent the additional cycles that Fast transactions (Figures Figure 17 and Figure 18) do not perform. This mode is selected for transactions accessing XCSn by setting TRANSMD
= 0 and TRANSPD = 1 in the corresponding XZMn register.
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(Continued)
CLK
(Internal; for
Reference Only)
XD7-0
XD7-0 (Data In)
(Data Read)
XA11-0
XCSn
XWR_XRW
XRD_XEN
XRDY
Figure 17. Mode 0, Normal Address, Fast X-Bus Transaction - Read Access Cycle
CLK
(Internal; for
Reference Only)
XD7-0
XA11-0
XCSn
XWR_XRW
XRD_XEN
XRDY
Figure 18. Mode 0, Normal Address, Fast X-Bus Transaction - Write Access Cycle
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Mode 0, Normal Address, Turbo X-Bus Transactions
The read and write transactions in Normal Address, Turbo X-Bus transactions provide a lower access time than those in
Mode 0, Normal Address, Fast X-Bus transactions. Because Normal Address, Turbo X-Bus transactions have seven fewer
cycles than Normal Address, Fast X-Bus transactions, they efficiently access very fast devices. This mode is selected for transactions accessing XCSn by setting TRANSMD = 0 in the corresponding XZMn register and TBXCSn = 1 in the XBCNF register.
Read Transactions. When a read cycle on the LPC starts and the relevant XCSn is set to Turbo mode, a Mode 0, Normal
Address, Turbo X-Bus Transaction read cycle begins. A read cycle (Figure 21, below) starts by outputting the address on
address signals XA11-0 on the rising edge of the clock. During this time, the PC8741x device does not drive the data bus
signals XD7-0. One CLK cycle later, a chip-select signal XCSn is asserted. One CLK cycle after that, the XRD signal is asserted (set low), indicating a read cycle and enabling the accessed device to drive the data bus. In Turbo X-Bus transactions,
XRDY is ignored. Two CLK cycles later, the input data XD7-0 is sampled on the rising edge of the clock. One CLK cycle after
that, XRD is de-asserted (set high) and one CLK cycle later, the transaction is completed by de-asserting XCSn. The address is retained for one more CLK cycle, after which the address lines are driven to 0.
CLK
(Internal; for
Reference Only)
XD7-0
XD7-0
(Data Read)
XA11-0
XCSn
XWR_XRW
XRD_XEN
Figure 19. Mode 0, Normal Address, Turbo X-Bus Transaction - Read Access Cycle
Write Transactions. When a write cycle on the LPC starts and the relevant XCSn is set to Turbo mode, a Mode 0, Normal
Address, Turbo X-Bus Transaction write cycle begins. A write cycle (Figure 22, below) starts by outputting the address on
address signals XA11-0 and the data signals on data pins XD7-0 on the rising edge of the clock. One CLK cycle later, a chipselect signal XCSn is asserted. One CLK cycle after that, the XWR signal is asserted (set low), indicating a write cycle and
enabling the accessed device to be written. In Turbo X-Bus transactions, XRDY is ignored. Three CLK cycles later, XWR is
de-asserted (set high) and one CLK cycle after that, the transaction is completed by de-asserting XCSn and floating the data
bus signals XD7-0. One CLK cycle later, the address lines are driven to 0.
CLK
(Internal; for
Reference Only)
XD7-0
XA11-0
XCSn
XWR_XRW
XRD_XEN
Figure 20. Mode 0, Normal Address, Turbo X-Bus Transaction - Write Access Cycle
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5.2.8
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Mode 1, Normal Address Transactions
Read and write transactions in mode 1 use an Enable signal and a R/W signal controlled protocol. At least two idle cycles
are inserted at the end of each X-Bus transaction cycle (though there may be more idle cycles due to the LPC transactions).
This mode is selected for transactions accessing XCSn by setting TRANSMD = 1 in the corresponding XZMn register.
Read Transactions. When a read cycle on the LPC falls within any of the enabled decoded address ranges of the X-Bus
functional block (or an indirect read is started or an X-Bus read through the ACCESS.bus is started) and the relevant XCSn
is set to mode 1, a Mode 1 read cycle begins. A Mode 1 read cycle (see Figure 21) begins with the de-assertion of XRD_XEN
(set low). At the same time, the address is driven on the XA11-0. Ten CLK cycles later, XCSn is asserted (set low). After five
CLK cycles, XRD_XEN is asserted (set high) and remains asserted for 18 cycles plus the internally programmed wait state
period. During the period that XRD_XEN is asserted, the data must be driven on XD7-0 by the target device. XRD_XEN is
then de-asserted for two CLK cycles. The data from XD7-0 is sampled at the rising edge of the clock one CLK cycle before
XRD_XEN is de-asserted. At the end of these two CLK cycles, XCSn is set high, and after one CLK cycle, XRD_XEN is also
set high. One CLK cycle later, the address lines XA11-0 are driven low.
CLK
(Internal; for Reference Only)
XD7-0
Data In
XA11-0
XCSn
XWR_XRW
XRD_XEN
Insert: 8 CLK cycles.
Insert: 16 + “Programmed Wait States” CLK cycles.
During this time, non-clock signals do not change.
Figure 21. Mode 1, Normal Address X-Bus Transaction - Read Access Cycle
Write Transactions. When a write cycle on the LPC falls within any of the enabled decoded address ranges of the X-Bus
functional block (or an indirect write is started or an X-Bus write through the ACCESS.bus is started) and the relevant XCSn
is set to mode 1, a Mode 1 write cycle begins. A mode 1 write cycle (see Figure 22) begins with a de-assertion of XRD_XEN
(set low). At the same time, the address is driven on the XA11-0 and the data is driven on XD7-0. After ten CLK cycles, XCSn
and XWR_XRW are asserted (set low). After five CLK cycles, XRD_XEN is asserted (set high) and remains asserted for 18
cycles plus the internally programmed wait state period. XRD_XEN is then de-asserted for two CLK cycles. At the end of
these two CLK cycles, XCSn is set high. After another CLK cycle, XWR_XRW and XRD_XEN are set high. Address lines
XA11-0 are driven low one CLK cycle later (at the end of the transaction).
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CLK
(Internal; for Reference Only)
XD7-0
XA11-0
XCSn
XWR_XRW
XRD_XEN
Insert: 16 + “Programmed Wait States” CLK cycles.
During this time, non-clock signals do not change.
Insert: 8 CLK cycles.
Figure 22. Mode 1, Normal Address X-Bus Transaction - Write Access Cycle
5.2.9
Latched Address Mode X-Bus Transactions
The read and write transactions in Latched Address mode are similar to those used in Normal Address mode except for the
way the addresses are placed on the X-Bus. In Latched Address mode, address signals 27-0 are output using the XA signals
via multiplexing over the data bus (XD7-0). The purpose of Latch control signals XSTB2-0 is to separate the XA signals from
the XD7-0 data bus. The XSTB2-0 signals are active from the time the address signals are valid (and until the end of a transaction).
Latched address X-Bus transactions are available at two levels:
●
Standard - standard access time transactions available in mode 0, mode 0 fast, and mode 1.
●
Turbo - low access time transactions available in mode 0 turbo.
Standard Read Transactions. When a read cycle on the LPC falls within any of the enabled X-Bus decoded address ranges (or an indirect read is started or an X-Bus read through the ACCESS.bus is started), a read cycle begins. A read cycle
starts by outputting the lower 12 address signals on address signals XA11-0 and by outputting address lines 27-20 on data
signals XD7-0 on the rising edge of the clock. Two CLK cycles later, a strobe signal (XSTB2) is asserted to latch the address
in an external latch. Two CLK cycles later, a second set of address lines (19-12) is placed on data pins XD7-0. These can
be latched by the strobe signal XSTB1 asserted two cycles later on the rising edge of the clock. Two CLK cycles later, the
last group of address lines (11-4) is placed on data signals XD7-0. The XSTB0, asserted two cycles later on the rising edge
of the clock, can be used to latch this part of the address. Two CLK cycles later on the rising edge of the clock, the PC8741x
stops driving the data bus. At this point, all addresses are available either at the address outputs of the PC8741x (XA11-0)
or in the three latches. The system may require only part of these addresses, depending on the size of the memory or peripheral address space. One CLK cycle later, either a chip-select signal XCSn or the enable signal XRD_XEN is asserted,
based on the XCSn mode setting (where n is a chip-select number from 0 to 3, based on the address accessed and the
select signal mapping). From this point, the read continues as described for the Normal Address mode. XSTB2-0 are deasserted one CLK cycle after the de-assertion of XCSn. At this time, the latched address becomes invalid.
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CLK
(Internal; for
Reference Only)
A
[27-20]
XD7-0
A
[19-12]
A
[11-4]
XSTB2
XSTB1
XSTB0
XA11-0
(Availability on Device Pins
Depends on Multiplexing)
XA27-0
(After Latching)
XCSn
Starting point
for mode 0
XRD_XEN
Starting point
for mode 1
XWR_XRW
XRDY
Transaction Continues as for Non-Latched Address Mode 0 and Mode 1 Read
Figure 23. Standard Latched Address Mode - X-Bus Read Access Cycle
Standard Write Transactions. When a write cycle on the LPC falls within any of the enabled decoded address ranges of
the X-Bus functional block (or an indirect write is started or an X-Bus write through the ACCESS.bus is started), a write cycle
begins. A write cycle starts by outputting the lower 12 address signals on address signals XA11-0 and address lines 27-20
on data signals XD7-0 on the rising edge of the clock. Two CLK cycles later, a strobe signal (XSTB2) is asserted to latch the
address in an external latch. Two CLK cycles after that, a second set of address lines (19-12) is placed on data pins XD7-0.
These can be latched by the strobe signal XSTB1 asserted two cycles later on the rising edge of the clock. Two CLK cycles
later, the last group of address lines (11-4) is output on the data signals XD7-0. The XSTB0, asserted two CLK cycles later
on the rising edge of the clock, can be used to latch this part of the address. Two CLK cycles later on the rising edge of the
clock, the PC8741x outputs the data signals on data pins XD7-0. At this point, all the addresses are available either at the
address outputs of the PC8741x (XA11-0) or at the outputs of the three latches. The system may require only part of these
addresses, depending on the size of the memory or peripheral address space. One CLK cycle later, either a chip-select signal XCSn or the enable signal XRD_XEN is asserted, based on the XCSn mode setting (where n is a chip-select number
from 0 to 3, based on the address accessed and the select signal mapping). From this point, the write continues as described
for the Normal Address mode. XSTB2-0 are de-asserted one CLK cycle after the de-assertion of XCSn. At this time, the
latched address becomes invalid.
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CLK
(Internal; for
Reference Only)
A
[27-20]
XD7-0
A
[19-12]
A
[11-4]
D
[7-0]
XSTB2
XSTB1
XSTB0
XA11-0
(Availability on Device Pins
Depends on Multiplexing)
XA27-0
(After Latching)
XCSn
Starting point
for mode 0
XRD_XEN
Starting point
for mode 1
XWR_XRW
XRDY
Transaction Continues as for Non-Latched Address Mode 0 and Mode 1 Write
Figure 24. Standard Latched Address Mode - X-Bus Write Access Cycle
Turbo Read Transactions. A Turbo read cycle starts by outputting the lower 12 address signals on address signals XA11-0
and by outputting address lines 27-20 on data signals XD7-0 on the rising edge of the clock. One CLK cycle later, a strobe
signal (XSTB2) is asserted to latch the address in an external latch. One CLK cycle after that, a second set of address lines
(19-12) is placed on data pins XD7-0. These can be latched by the strobe signal XSTB1, asserted one cycle later on the
rising edge of the clock. One CLK cycle later, the last group of address lines (11-4) is placed on data signals XD7-0. The
XSTB0, asserted one cycle later on the rising edge of the clock, can be used to latch this part of the address. One CLK cycle
later on the rising edge of the clock, the PC8741x stops driving the data bus. At this point, all addresses are available either
at the address outputs of the PC8741x (XA11-0) or in the three latches. The system may require only part of these addresses, depending on the size of the memory or peripheral address space. One CLK cycle later, the chip-select signal XCSn is
asserted, based on the XCSn Turbo mode setting. From this point, the read continues as described for the Normal Address
Turbo transaction, Mode 0. XSTB2-0 are de-asserted one CLK cycle after the de-assertion of XCSn. At this time, the latched
address becomes invalid. At the same time, the address signals XA11-0 are driven to low level.
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CLK
(Internal; for
Reference Only)
A
A
[27-20] [19-12]
XD7-0
A
[11-4]
XSTB2
XSTB1
XSTB0
XA11-0
(Availability on Device Pins
Depends on Multiplexing)
XA27-0
(After Latching)
Starting point
XCSn
XRD_XEN
XWR_XRW
Transaction Continues as for Non-Latched, Turbo X-Bus Address Mode 0 Read
Figure 25. Turbo Latched Address Mode - X-Bus Read Access Cycle
Turbo Write Transactions. A Turbo write cycle starts by outputting the lower 12 address signals on address signals
XA11-0 and by outputting address lines 27-20 on data signals XD7-0 on the rising edge of the clock. One CLK cycle later,
a strobe signal (XSTB2) is asserted to latch the address in an external latch. One CLK cycle after that, a second set of address lines (19-12) is placed on data pins XD7-0. These can be latched by the strobe signal XSTB1, asserted one cycle later
on the rising edge of the clock. One CLK cycle later, the last group of address lines (11-4) is output on the data signals XD70. The XSTB0, asserted one CLK cycle later on the rising edge of the clock, can be used to latch this part of the address.
One CLK cycle later on the rising edge of the clock, the PC8741x outputs the data signals on data pins XD7-0. At this point,
all the addresses are available either at the address outputs of the PC8741x (XA11-0) or at the outputs of the three latches.
The system may require only part of these addresses, depending on the size of the memory or peripheral address space.
One CLK cycle later, the chip-select signal XCSn is asserted, based on the XCSn Turbo mode setting. From this point, the
write continues as described for the Normal Address Turbo transaction, Mode 0. XSTB2-0 are de-asserted one CLK cycle
after the de-assertion of XCSn. At this time, the latched address becomes invalid. At the same time, the address signals
XA11-0 are driven to low level.
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104
Revision1.2
PC8741x
5.0 X-Bus Extension
(Continued)
CLK
(Internal; for
Reference Only)
A
A
[27-20] [19-12]
XD7-0
A
[11-4]
D
[7-0]
XSTB2
XSTB1
XSTB0
XA11-0
(Availability on Device Pins
Depends on Multiplexing)
XA27-0
(After Latching)
Starting point
XCSn
XRD_XEN
XWR_XRW
Transaction Continues as for Non-Latched, Turbo X-Bus Address Mode 0 Write
Figure 26. Turbo Latched Address Mode - X-Bus Write Access Cycle
5.3
X-BUS PROTECTION
The PC8741x devices include a mechanism to protect the settings of the X-Bus mapping functions and the contents of the
memories mapped to it. This mechanism consists of three separate lock mechanisms, which must all be in use to obtain the
most comprehensive protection:
●
Lock the memory mapping by the host, using the lock bit in the X-Bus Memory Configuration register and X-Bus I/O
Configuration register.
●
Lock the bits of the X-Bus Select n Configuration register and X-Bus Mode n register, using the lock bit in the respective X-Bus Mode register.
●
A Memory protection mechanism is available for XCS0 and XCS1. This protects the contents of up to two memory
devices (one for each chip-select) for read and/or write with a granularity of 16 blocks each. This is done using the
Host Access Protect registers 0 and 1 for XCS0 and XCS1, respectively.
Note that access protection is provided only for XCS0 and XCS1. Absolute access protection is only enabled by using all
three lock levels.
The Memory protection mechanism pertains to the X-Bus address and the chip-select (XCS0 or XCS1) involved in the transaction. The size of a protected block is determined by dividing the size of each BIOS Zone by 16 (see Section 3.15.12 on
page 84). Table 31 on page 106 shows the protected block size for different BIOS Zone sizes.
Revision 1.2
105
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PC8741x
5.0 X-Bus Extension
(Continued)
Table 31. Protected Block Size
BIOS Zone Size BIOSIZE2-BIOSIZE0 Protected Block Size
Address Lines Used for
Block Selection1,2
256 Kbyte
000
16 Kbyte
XA17-XA14
512 Kbyte
001
32 Kbyte
XA18-XA15
1 Mbyte
010
64 Kbyte
XA19-XA16
2 Mbyte
011
128 Kbyte
XA20-XA17
4 Mbyte
100
256 Kbyte
XA21-XA18
8 Mbyte
101
512 Kbyte
XA22-XA19
16 Mbyte
110
1 Mbyte
XA23-XA20
1. Selects the block according to the HAPINDX3-HAPINDX0 setting in the HAP0-HAP1 registers.
2. All the other address lines are ignored.
A read/write transaction to/from a protected block is not allowed to take place if, for the respective block number, the
HWRP/HRDP bit is set in the HAP0 or HAP1 register (see Section 5.4.11 on page 114). This includes both memory and I/O
transactions.
To prevent bypassing the protection by selecting additional non-BIOS zones to XCS0 or XCS1, the upper lines of the
address are not used for block selection. This results in the aliasing of a protected block in each area of X-Bus memory space
that has the same size as the BIOS Zone (see Figure 27).
X-Bus Memory Space
FFF FFFFh
BIOS Zone Size
Protected Block n
BIOS Zone Size
Protected Block n
....
BIOS Zone Size
Protected Block n
BIOS Zone Size
Protected Block n
000 0000h
Figure 27. Protected Block Aliasing
The SMI interrupt generated on access to XCS0 and XCS1 may be used to allow flash updates under System Management
protection.
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106
Revision1.2
5.4
PC8741x
5.0 X-Bus Extension
(Continued)
X-BUS REGISTERS
The following abbreviations are used to indicate the Register Type:
●
R/W
= Read/Write.
●
R
= Read from a specific register (write to the same address is to a different register).
●
W
= Write (see above).
●
RO
= Read Only.
●
WO
= Write Only. Reading from the bit returns 0.
●
R/W1C = Read/Write 1 to Clear. Writing 1 to a bit clears it to 0. Writing 0 has no effect.
●
R/W1S = Read/Write 1 to Set. Writing 1 to a bit sets its value to 1. Writing 0 has no effect.
5.4.1
X-Bus Register Map
The following table lists the X-Bus registers. All these registers are VSB powered.
Offset
Mnemonic
00h
XBCNF
01h
Type
Power Well
Section
X-Bus Configuration Register.
R/W or RO
VSB
5.4.2
XZCNF0
X-Bus Select 0 Configuration Register.
R/W or RO
VSB
5.4.3
02h
XZCNF1
X-Bus Select 1 Configuration Register.
R/W or RO
VSB
5.4.3
04h
XIRQC
X-Bus IRQ Configuration Register.
R/W
VSB
5.4.4
08h
XIMA0
X-Bus Indirect Memory Address Register 0.
R/W
VSB
5.4.5
09h
XIMA1
X-Bus Indirect Memory Address Register 1.
R/W
VSB
5.4.6
0Ah
XIMA2
X-Bus Indirect Memory Address Register 2.
R/W
VSB
5.4.7
0Bh
XIMA3
X-Bus Indirect Memory Address Register 3.
R/W
VSB
5.4.8
0Ch
XIMD
X-Bus Indirect Memory Data Register.
R/W
VSB
5.4.9
0Dh
XZCNF2
X-Bus Select 2 Configuration Register.
R/W or RO
VSB
5.4.3
0Eh
XZCNF3
X-Bus Select 3 Configuration Register.
R/W or RO
VSB
5.4.3
0Fh
XZM0
X-Bus Select 0 Mode Register.
Varies per bit
VSB
5.4.10
10h
XZM1
X-Bus Select 1 Mode Register.
Varies per bit
VSB
5.4.10
11h
XZM2
X-Bus Select 2 Mode Register.
Varies per bit
VSB
5.4.10
12h
XZM3
X-Bus Select 3 Mode Register.
Varies per bit
VSB
5.4.10
13h
HAP0
Host Access Protect Register 0.
Varies per bit
VSB
5.4.11
14h
HAP1
Host Access Protect Register 1.
Varies per bit
VSB
5.4.11
Other
Revision 1.2
Register Name
Reserved for National use.
107
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PC8741x
5.0 X-Bus Extension
5.4.2
(Continued)
X-Bus Configuration Register (XBCNF)
This register affects the functionality mode of the X-Bus.
Power Well:VSB
Location:Offset 00h
Type:
R/W or RO
Bit
7
6
5
4
Name
TBXCS3
TBXCS2
TBXCS1
TBXCS0
Reset
0
0
0
0
3
2
1
Reserved
0
0
0
LADEN
0
Strap
Bit
Description
7
TBXCS3 (Turbo Transactions on XCS3). When set to 1 and mode 0 is selected (TRANSMD = 0 in the XZM3
register), enables Turbo X-Bus transactions (see Section 5.2.7 on page 99) when XCS3 is accessed. The Turbo
transactions are Normal Address or Latched Address (see Section 5.2.9 on page 101), according to the setting
of the LADEN bit. This bit is locked by setting at least one of the LOCKXSCF bits in the XZM0-XZM3 registers.
0: Disabled (default)
1: Enabled
6
TBXCS2 (Turbo Transactions on XCS2). When set to 1 and mode 0 is selected (TRANSMD = 0 in the XZM2
register), enables Turbo X-Bus transactions (see Section 5.2.7 on page 99) when XCS2 is accessed. The Turbo
transactions are Normal Address or Latched Address (see Section 5.2.9 on page 101), according to the setting
of the LADEN bit. This bit is locked by setting at least one of the LOCKXSCF bits in the XZM0-XZM3 registers.
0: Disabled (default)
1: Enabled
5
TBXCS1 (Turbo Transactions on XCS1). When set to 1 and mode 0 is selected (TRANSMD = 0 in the XZM1
register), enables Turbo X-Bus transactions (see Section 5.2.7 on page 99) when XCS1 is accessed. The Turbo
transactions are Normal Address or Latched Address (see Section 5.2.9 on page 101), according to the setting
of the LADEN bit. This bit is locked by setting at least one of the LOCKXSCF bits in the XZM0-XZM3 registers.
0: Disabled (default)
1: Enabled
4
TBXCS0 (Turbo Transactions on XCS0). When set to 1 and mode 0 is selected (TRANSMD = 0 in the XZM0
register), enables Turbo X-Bus transactions (see Section 5.2.7 on page 99) when XCS0 is accessed. The Turbo
transactions are Normal Address or Latched Address (see Section 5.2.9 on page 101), according to the setting
of the LADEN bit. This bit is locked by setting at least one of the LOCKXSCF bits in the XZM0-XZM3 registers.
0: Disabled (default)
1: Enabled
3-1
0
5.4.3
Reserved.
LADEN (Latch Address Mode Enabled). When set to 1, enables addresses XA27-XA4 to be multiplexed with
the data pins in three phases. Reset value of this bit is set according to the XCNF2 strap, sampled at VSB
Power-Up reset. See Section 1.4.11 on page 29 for the definition of strap setting. This bit is locked by setting at
least one of the LOCKXSCF bits in the XZM0-XZM3 registers.
0: Disabled (default if XCNF2 = 0 - No BIOS)
1: Enabled (default if XCNF2 = 1 - With BIOS)
X-Bus Select Configuration Registers (XZCNF0 to XZCNF3)
These registers control the mapping of I/O and Memory Zones to XCSn, where n is from 0 to 3.
Power Well:VSB
Location:Offset 01h (XZCNF0)
Location:Offset 02h (XZCNF1)
Location:Offset 0Dh (XZCNF2)
Location:Offset 0Eh (XZCNF3)
Type:
R/W or RO
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108
Revision1.2
Bit
PC8741x
5.0 X-Bus Extension
(Continued)
7
6
5
4
Name
XRDYEN
WAITSEN
INDIRMEN
ZSELMAP
Reset
Strap
1
0
Strap
Bit
7
3
2
1
0
Description
XRDYEN (XRDY Enable). Enables the use of XRDY input for the zones mapped to XCSn. The reset value of
this bit depends on the setting of XCNF2 and XCNF0 straps, sampled at VSB Power-Up reset.
0: Disabled (default for XZCNF1-3; default for XZCNF0 if XCNF0 = 0 or XCNF2 = 0)
1: Enabled (default for XZCNF0 if XCNF0 = 1 and XCNF2 = 1)
6
WAITSEN (Wait States Enable). This bit controls the number of wait states added to an X-Bus transaction. If the
TRANSPD bit in the XZM0 to XZM3 registers is set, the setting of WAITSEN is ignored (wait states are disabled).
0: Wait states disabled
1: Eight wait states (CLK cycles) enabled (default)
5
INDIRMEN (Indirect Memory Access Enable). Enables indirect memory access mechanism to generate
memory transactions through XCSn.
0: Disabled (default)
1: Enabled
4-0
ZSELMAP (Zone Select Mapping).
UDIZ = User-Defined I/O Zone.
MEM = User-Defined Memory Zone.
= XCSn does not respond to this zone decode.
+ = XCSn responds to this zone decode and is influenced by its setting.
Bits
Function
4 3 2 1 0 UDIZ0 UDIZ1 UDIZ2 UDIZ3 TST BIOS0 BIOS1 MEM0 MEM1
Revision 1.2
0 0 0 0 0:
-
-
-
-
-
-
-
-
0 0 0 0 1:
0 0 0 1 0:
0 0 0 1 1:
0 0 1 0 0:
0 0 1 0 1:
0 0 1 1 0:
0 0 1 1 1:
0 1 0 0 0:
0 1 0 0 1:
0 1 0 1 0:
0 1 0 1 1:
0 1 1 0 0:
0 1 1 0 1:
0 1 1 1 0:
0 1 1 1 1:
1 0 0 0 0:
1 0 0 0 1:
1 0 0 1 0:
1 0 0 1 1:
1 0 1 0 0:
1 0 1 0 1:
1 0 1 1 0:
1 0 1 1 1:
1 1 0 0 0:
Others:
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
-
+
+
+
+
+
+
+
+
+
+
+
+
+
+
Reserved
+
+
+
+
+
+
+
+
+
+
+
-
+
+
+
+
+
+
+
-
+
+
+
+
+
+
+
+
+
-
+
+
+
+
+
+
+
+
+
-
+
+
+
-
+
+
+
+
+
+
+
+
+
109
- (default for XZCNF1-3;
default for XZCNF0 if XCNF2 = 0)
- (default for XZCNF0 if XCNF2 = 1)
+
+
+
+
+
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PC8741x
5.0 X-Bus Extension
5.4.4
(Continued)
X-Bus IRQ Configuration Register (XIRQC)
This register defines the functionality of the XIRQ signal.
Power Well:VSB
Location:Offset 04h
Type:
R/W
Bit
7
6
Name
5
4
Reserved
Reset
0
0
0
2
1
0
IRQPOLINV
IRQEN
IRQPOL
PWUREN
0
0
0
0
0
Bit
7-4
3
Description
Reserved.
3
IRQPOLINV (IRQ Polarity Inversion). This bit controls the polarity of the IRQ signal sent through the IRQ
Serializer (see Table 32). This bit is reset to ‘0’.
2
IRQEN (IRQ Enable). When this bit is set, it enables the interrupt. The bit is ignored when the IRQ is mapped
to zero (see Section 3.2.3 on page 40).
0: Disabled (default)
1: Enabled
1
IRQPOL (IRQ Polarity). This bit specifies the active level of the incoming IRQ signal.
0: Active low (default)
1: Active high
0
PWUREN (Power-Up Request Enable). When this bit is set, an XIRQ event is routed to the Modules IRQ
Wake-Up Event (bit MOD_IRQ_STS in the GPE1_STS_3 register; see Section 9.4.11 on page 211).
0: Disabled (default)
1: Enabled
Table 32. Serial IRQ vs. XIRQ Polarity
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IRQPOLINV
IRQPOL
0
0
XIRQ
0
1
XIRQ
1
0
XIRQ
1
1
XIRQ
110
Serial IRQ
Revision1.2
PC8741x
5.0 X-Bus Extension
(Continued)
Bit
Name
0
1
Power-Up
IRQ
Request Polarity
Enable
2
IRQ
Enable
3
IRQ
Polarity
Inversion
0
0
IRQ
Serializer
1
1
XIRQ
Modules IRQ
Wake-Up Event
IRQ from
Legacy Modules
Figure 28. Functional Illustration of X-Bus IRQ Configuration Register
5.4.5
X-Bus Indirect Memory Address Register 0 (XIMA0)
This register holds addresses 7-0 for indirect read or write transactions to memory or I/O.
Power Well:VSB
Location:Offset 08h
Type:
R/W
Bit
7
6
Name
5
0
0
0
Bit
5.4.6
3
2
1
0
0
0
1
0
0
0
X-Bus Indirect Memory or I/O Address 7-0
Reset
7-0
4
0
0
0
Description
X-Bus Indirect Memory or I/O Address 7-0.
X-Bus Indirect Memory Address Register 1 (XIMA1)
This register holds addresses 15-8 for indirect read or write transactions to memory or I/O.
Power Well:VSB
Location:Offset 09h
Type:
Bit
R/W
7
6
Name
Reset
5
Revision 1.2
3
2
X-Bus Indirect Memory or I/O Address 15-8
0
0
0
Bit
7-0
4
0
0
0
Description
X-Bus Indirect Memory or I/O Address 15-8.
111
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PC8741x
5.0 X-Bus Extension
5.4.7
(Continued)
X-Bus Indirect Memory Address Register 2 (XIMA2)
This register holds addresses 23-16 for indirect read or write transactions to the memory.
Power Well:VSB
Location:Offset 0Ah
Type:
R/W
Bit
7
6
Name
5
0
0
0
Bit
5.4.8
3
2
1
0
0
0
1
0
0
0
0
2
1
0
0
0
X-Bus Indirect Memory Address 23-16
Reset
7-0
4
0
0
0
Description
X-Bus Indirect Memory Address 23-16.
X-Bus Indirect Memory Address Register 3 (XIMA3)
This register holds addresses 31-24 for indirect read or write transactions to the memory.
Power Well:VSB
Location:Offset 0Bh
Type:
R/W
Bit
7
6
Name
5
0
0
0
Bit
5.4.9
3
2
X-Bus Indirect Memory Address 31-24
Reset
7-0
4
0
0
Description
X-Bus Indirect Memory Address 31-24.
X-Bus Indirect Memory Data Register (XIMD)
This register holds data bits 7-0 for indirect read or write transactions to memory or I/O.
Power Well:VSB
Location:Offset 0Ch
Type:
R/W
Bit
7
6
Name
5
3
X-Bus Indirect Memory or I/O Data 7-0
Reset
0
0
0
Bit
7-0
4
0
0
0
Description
X-Bus Indirect Memory or I/O Data 7-0.
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Revision1.2
PC8741x
5.0 X-Bus Extension
(Continued)
5.4.10 X-Bus Select Mode Register (XZM0 to XZM3)
These registers control the operation mode of chip select XCSn, where n is from 0 to 3.
Power Well:VSB
Location:Offset 0Fh (XZM0)
Location:Offset 10h (XZM1)
Location:Offset 11h (XZM2)
Location:Offset 12h (XZM3)
Type:
Varies per bit
Bit
7
6
5
4
Name
LOCKXSCF
WRSTAT
SMIWREN
XCSPOL
Reset
0
0
0
0
Bit
Type
3
2
XCSTIM
0
0
1
0
TRANSMD
TRANSPD
0
0
Description
7
LOCKXSCF (X-Bus Select Configuration Lock). Locks the configuration registers of the respective
XCSn signal (both XZCNFn register and XZMn register) by disabling writing to all their bits (including to
itself). An exception to this is the WRSTAT bit of the XZMn register. In addition, it locks the bits in the
XBCNF register. Once set, this bit can be cleared either by the VDD Power-Up reset (or Hardware
R/W1S reset) or by the VSB Power-Up reset, according to the VSBLOCK bit in the ACBLKCTL register (see
Section 6.3.4 on page 128). In addition, this bit is cleared by setting the UNLOCKX bit in the
ACBLKCTL register (PC87417).
0: Lock Disabled (default)
1: Lock Enabled, protecting the configuration for this chip select
6
WRSTAT (Write Status). This bit is set if a write to the chip select occurred. Writing 1 to this bit clears
it to 0. WRSTAT is not locked by the LOCKXSCK bit.
R/W1C
0: No write detected (default)
1: Write to the chip select detected
5
SMIWREN (SMI-on-Write Enable). Enables the generation of an SMI, if the WRSTAT bit is set by the
R/W or occurrence of a write to the chip select.
RO
0: SMI Disabled (default)
1: SMI Enabled
4
XCSPOL (XCS Polarity Control). Selects the polarity of the XCSn signal.
R/W or
0: Active low - idle = 1, select = 0 (default)
RO
1: Active high - idle = 0, select = 1
3-2
XCSTIM (XCS Timing Control). Selects the timing of the XCSn signal during read and write
transactions in mode 0. If TRANSMD bit is set to mode 1, the value of these bits is ignored and they
are treated as ‘00’.
R/W or Bits
3 2
RO
0 0:
0 1:
1 0:
1 1:
1
Revision 1.2
Function
Normal XCSn timing
Normal XCSn timing
Normal XCSn timing
XRD_XEN timing for
for both read and write cycles (default)
during write cycles; XRD_XEN timing for XCSn during read cycles
during read cycles; XWR_XRW timing for XCSn during write cycles
XCSn during read cycles; XWR_XRW timing for XCSn during write cycles
TRANSMD (X-Bus Transaction Mode). Selects the X-Bus transaction mode pertaining to the behavior
of the XWR_XRW and XRD_XEN signals during a transaction.
0: Mode 0 - This is an ISA-like mode. When accessing the XCSn, XWR_XRW functions as an active low
R/W or
write signal and XRD_XEN functions as an active low read signal (default)
RO
1: Mode 1 - In this mode, when accessing the XCSn, XWR_XRW functions as a read/write signal (high
for a read transaction and low for a write transaction) and XRD_XEN functions as an active high enable
signal
113
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PC8741x
5.0 X-Bus Extension
Bit
0
(Continued)
Type
Description
TRANSPD (X-Bus Transaction Speed). When set to 1, removes the additional cycles from mode 0
read and write transactions. In this situation, the setting of WAITSEN bit in the XZCNF0 to XZCNF3
R/W or registers is ignored (wait states are disabled).
0: Sixteen additional CLK cycles (apart from the programmed number of wait states) are inserted into
RO
mode 0 read and write transactions when accessing the XCSn (default)
1: No CLK cycles are inserted
5.4.11 Host Access Protect Register (HAP0 to HAP1)
HAP0 and HAP1 registers hold the read/write protection and lock control bits for access control to XCS0 and XCS1, respectively. Each register defines the access rights for a group of 16 blocks of the related chip select (see Section 5.3 on page 105
for more information on how to define these blocks). Each block is protected by three bits, which are accessed through the
block number written into the Host Access Protection Index field.
The lock bit for each block is cleared either by reset or by writing a ‘0’ through the ACCESS.bus (PC87417). When a lock
bit is cleared, the related write-protect flag is set and the read-protect flag is cleared.
Power Well:VSB
Location:Offset 13h and 14h
Type:
Varies per bit
Bit
7
6
Name
5
4
HAPINDX
Reset
0
0
0
0
3
2
1
0
INDXWR
LOCKXHP
HWRP
HRDP
0
0
1
0
Bit
Type
Description
7-4
R/W
HAPINDX (Host Access Protection Index). Holds the index for the block number to be accessed by
the other fields in this register. All blocks are 16 KByte up to 1 MByte in size (see Section 5.3 on
page 105).
0000b - 1111b - index for block numbers of 0-15, respectively (0000b = default).
3
WO
INDXWR (Index Write). Indicates an index write transaction for which the value of bits 2-0 are ignored
(not written). This bit always returns ‘0’ when read.
0: Index and Data write transaction (writes bits 2-0 according to the newly written index); (default)
1: Index update write transaction (bits 2-0 are not updated by this write)
2
R/W1S LOCKXHP (Lock Host Protection). When set to ‘1’ through the LPC bus, this bit locks itself and the
two HWRP and HRDP protection bits by disabling writing to them. The block number these three bits
relate to is pointed to by the Index field. Once set, this bit can be cleared either by the VDD Power-Up
reset (or Hardware reset) or by the VSB Power-Up reset, according to the VSBLOCK bit in the
ACBLKCTL register (see Section 6.3.4 on page 128). In addition, this bit is cleared by setting the
UNLOCKX bit in the ACBLKCTL register (PC87417).
This bit may be set or reset through the ACCESS.bus (PC87417), regardless of its value (it is not selflocking).
0: Changes to protection bits (2-0) for this block are enabled (default)
1: Protection bits (2-0) for this block are locked and their values cannot be changed
1
R/W or HWRP (Host Write Protection). This bit prevents writes to a block, thus preventing programming or
RO erasing of the flash memory connected to the XCSn. The block number affected by this field is the one
pointed to by the Index field.
0: Host writes to this block are allowed
1: Host writes to this block are inhibited (default)
0
R/W or HRDP (Host Read Protection). This bit prevents reads from a block, thus protecting the contents of the
RO flash memory connected to the XCSn. The block number affected by this field is the one pointed to by
the Index field.
0: Host reads from this block are allowed (default)
1: Host reads from this block are inhibited
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Revision1.2
5.5
PC8741x
5.0 X-Bus Extension
(Continued)
USAGE HINTS
1. Bear in mind the following system design hints for asynchronous X-Bus use:
— The chip-select signal must be used as a qualifier with the address when partial address decoding is in use for multiple device access control.
— In read cycles, the system may drive the data until the read signal XRD_XEN is de-asserted to guarantee the proper
PC8741x sampling.
— In write cycles, use either the falling or rising edge of the write control signal (XWR_XRW) to latch the data in the
device.
2. Address multiplexing on XD7-0 and strobe signals XSTB2-0 are designed for glueless interface with off-chip latch components (see the example in Figure 29).
XD7-0
D7-0
XSTB2
PC8741x
XSTB1
XSTB0
Latch
(74HC373*)
A27-20
Latch
(74HC373*)
A19-12
Latch
(74HC373*)
A11-4
XA3-0
A3-0
* - For mode 0, mode 0 fast, and mode 1, use 74HC373
- For mode 0 turbo, use 74VHC373
- For 5V-powered X-Bus devices, use 74HCT/VHCT373, which is also powered by the 5V supply.
Figure 29. Latched Mode X-Bus Transaction External Logic
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PC8741x
5.0 X-Bus Extension
5.6
(Continued)
X-BUS EXTENSION REGISTER BITMAP
Register
Bits
Offset
Mnemonic
7
6
5
4
00h
XBCNF
TBXCS3
TBXCS2
TBXCS1
TBXCS0
01h
XZCNF0
XRDYEN
WAITSEN INDIRMEN
ZSELMAP
02h
XZCNF1
XRDYEN
WAITSEN INDIRMEN
ZSELMAP
04h
XIRQC
08h
XIMA0
X-Bus Indirect Memory Address 7-0
09h
XIMA1
X-Bus Indirect Memory Address 15-8
0Ah
XIMA2
X-Bus Indirect Memory Address 23-16
0Bh
XIMA3
X-Bus Indirect Memory Address 31-24
0Ch
XIMD
X-Bus Indirect Memory or I/O Data 7-0
0Dh
XZCNF2
XRDYEN
WAITSEN INDIRMEN
ZSELMAP
0Eh
XZCNF3
XRDYEN
WAITSEN INDIRMEN
ZSELMAP
0Fh
XZM0
LOCKXSCF WRSTAT
SMIWREN
XCSPOL
XCSTIM
TRANSMD TRANSPD
10h
XZM1
LOCKXSCF WRSTAT
SMIWREN
XCSPOL
XCSTIM
TRANSMD TRANSPD
11h
XZM2
LOCKXSCF WRSTAT
SMIWREN
XCSPOL
XCSTIM
TRANSMD TRANSPD
12h
XZM3
LOCKXSCF WRSTAT
SMIWREN
XCSPOL
XCSTIM
TRANSMD TRANSPD
13h
HAP0
HAPINDX
INDXWR
LOCKXHP
HWRP
HRDP
14h
HAP1
HAPINDX
INDXWR
LOCKXHP
HWRP
HRDP
Other
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Reserved
3
2
1
Reserved
IRQPOLINV
IRQEN
0
LADEN
IRQPOL
PWUREN
Reserved for National use
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ACCESS.bus Interface
This section is relevant only for the PC87413 and PC87417. In the PC87414 and PC87416, all ACCESS.bus Interface
bits and signals that influence other modules are at their default value.
The ACCESS.bus Interface is a two-wire synchronous serial interface compatible with the ACCESS.bus (Specification Rev.
3.0 Sep. 1995) and with Intel's SMBus (Specification Rev 1.1 Dec. 11, 1998). The ACCESS.bus Interface acts as a slave
device controlled by a bus master. The ACCESS.bus Interface uses proprietary commands for AdvancedI/O access, compatible with the Physical, Data Link and Transport layers defined by the above specifications.
This chapter describes the ACCESS.bus Interface functional block.
6.1
OVERVIEW
The ACCESS.bus protocol uses a two-wire interface for bidirectional communication between the devices connected to the
bus. The two interface lines are the Serial Data Line (ACBDAT) and the Serial Clock Line (ACBCLK). These open-drain lines
must be connected to a positive supply via an internal or an external pull-up resistor and remain high when the bus is idle.
Each device connected to the bus has a unique address and can operate as a transmitter or a receiver (though some peripherals are only receivers).
During data transactions, the master device initiates the transaction with an attached peripheral, generates the clock signal
and terminates the transaction. When the master sends a slave address or data, the peripheral behaves as a receiver. When
the slave responds and sends data to the master, the peripheral behaves as a transmitter.
6.2
FUNCTIONAL DESCRIPTION
6.2.1
Bus Signals
ACBDAT and ACBCLK Signals
The ACBDAT and ACBCLK are open-drain signals. The device permits the user to define whether to enable or disable the
internal pull-up of these two signals (at reset, the internal pull-up is disabled).
Clock Frequency
The PC8741x device is a slave device that synchronizes to the clock frequency of the ACCESS.bus clock. The maximum
clock frequency is 100 kHz and the minimum is 10 kHz (limited by the 50 µsec maximum high time required by the standards
to detect a Bus Idle condition). However, since the PC8741x device is a slave device, the minimum clock frequency limitation
is ignored. The clock low period may be extended by stall periods initiated by the ACCESS.bus Interface (see Section 11.5.6
on page 246).
6.2.2
Data Transactions
One data bit is transferred during each clock pulse. Data is sampled during the high state of the serial clock (ACBCLK). Consequently, throughout the high period of the clock, the data must remain stable (see Figure 30). Any change in midtransaction on the ACBDAT line during the high period of the ACBCLK aborts the transaction and releases the ACBDAT
signal (to high level), thus generating Negative Acknowledge (NACK) cycles (see Section 6.2.4 on page 118). In addition,
the PC8741x device sets the BUSERR bit in the ACBCST register (see Section 6.3.2 on page 127). Data must be driven
onto the bus only during the low ACBCLK period. This protocol permits a single data line to transfer both command/control
information and data, using the synchronous serial clock.
During each clock cycle, while the slave handles the received data or prepares the data to be sent, it can stall the master.
The slave can do this for each bit transferred or on a byte boundary by holding ACBCLK low to extend the clock-low period.
Typically, slaves extend the first clock cycle of a transfer if a byte written has not yet been stored or if the byte to be read is
not yet ready. Some microcontroller-based masters with limited hardware support for ACCESS.bus extend the access after
each bit, thus allowing the software to handle the bit.
Each data transaction is composed of a Start Condition, a number of byte transfers (defined by the protocol) and a Stop
Condition to terminate the transaction. Each byte (eight bits) is transferred with the most significant bit first. After each byte,
an Acknowledge signal must follow. The following sections provide further details of this process.
ACBDAT
ACBCLK
Data Line Stable:
Data Valid
Change of Data
Allowed
Figure 30. Data Bit Transfer
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6.0
PC8741x
6.0 ACCESS.bus Interface
6.2.3
(Continued)
Start and Stop Conditions
The ACCESS.bus master generates Start and Stop Conditions (control codes). After a Start Condition is generated, the bus
remains busy until after a Stop Condition is generated. A high-to-low transition of the data line (ACBDAT) while the clock
(ACBCLK) is high indicates a Start Condition. A low-to-high transition of the ACBDAT line while the ACBCLK is high indicates a Stop Condition (Figure 31).
A transaction begins with a Start Condition and ends with a Stop Condition. However, a Restart Condition can be generated
in the middle of a transaction (without the need for a Stop Condition) in order to change the direction of data transfer (from
address/data write to data read).
Before a Start condition, any changes of the ACBDAT line outside the high period of the ACBCLK are ignored. A Stop condition encountered in mid-transaction on the ACBDAT line aborts the transaction. The PC8741x device releases the ACBDAT signal (to high level), thus generating Negative Acknowledge (NACK) cycles (see Section 6.2.4). In addition, the
PC8741x device sets the BUSERR bit in the ACBCST register (see Section 6.3.2 on page 127).
ACBDAT
ACBCLK
S or R
P
Start or Restart
Condition
Stop
Condition
Figure 31. Start, Restart and Stop Conditions
6.2.4
Acknowledge (ACK) Cycle
The ACK cycle involves two signals: the ACK clock pulse, sent by the master after each byte transferred, and the ACK data
signal, sent by the receiving device (see Figure 32).
The master generates the ACK clock pulse on the ninth clock pulse of the byte transfer. The transmitter (master or slave)
releases the ACBDAT line (allows it to go high) to allow the receiver to send the ACK signal. The receiver must pull down
the ACBDAT line during the ACK clock pulse, signalling that it correctly received the previous data byte and is ready to receive the next byte. If the receiver does not pull the ACBDAT line (leaves it high), the transmitter identifies it as a NACK
condition (see Section 6.2.5). Figure 33 illustrates the ACK cycle.
Acknowledge Signal
From Receiver
ACBDAT
MSB
ACBCLK
S
1
LSB
2 3-6
7
8
9
ACK
Start
Condition
1
2
3-8
9
ACK
P
Stop
Condition
Byte Complete
Interrupt Within
Receiver
Clock Line Held
Low by Receiver
While Interrupt is Serviced
Figure 32. ACCESS.bus Data Transaction with Acknowledge
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6.0 ACCESS.bus Interface
(Continued)
Data Output
by Transmitter
Transmitter Stays Off Bus
During Acknowledge Clock
Data Output
by Receiver
Acknowledge
Signal From Receiver
ACBCLK
1
S
2 3-6
7
8
9
Start Condition
Figure 33. ACCESS.bus Acknowledge Cycle
6.2.5
Acknowledge after Every Byte Rule
According to this rule, the master generates an acknowledge clock pulse after each byte transfer and the receiver (master
or slave) sends an acknowledge signal after every byte received. There are two exceptions to this rule:
•
When the master is the receiver, it must indicate to the slave transmitter the end of the expected data by not acknowledging (NACK) the last byte clocked out of the slave. This negative acknowledge still includes the acknowledge clock
pulse (generated by the master), but the ACBDAT line is not pulled down.
•
When a problem has occurred in the slave receiver, it sends a NACK to indicate that it did not accept the previous data
byte or cannot accept additional data bytes.
The NACK indicates an error in data reception (by slave or master) and a request to repeat the ACCESS.bus transaction.
6.2.6
Addressing Transfer Formats
Each device on the bus has a unique address. The PC8741x device starts a slave address set-up process if one of the following occurs:
•
A VSB Power-Up reset is activated by VSB going up: in this case, the ACBSA strap value is also sampled (see Section
2.2.2 on page 34).
•
A broadcast transaction to the General Call address with a “Reset and write programmable part of slave address by hardware” command is received over the ACCESS.bus (see below).
During the slave address set-up process, the PC8741x device performs the following actions in the order listed:
1. Checks the value of the ACBSADD field in the ACBCF register (see Section 3.7.11 on page 57); if the value of the bits
is valid (not zero), the value is adopted and the other two actions are ignored.
2. Checks the value of the ACBSA strap sampled at the VSB Power-Up reset.
3. Adopts one of the two fixed values (see Section 1.4.11 on page 29) for its slave address, according to the ACBSA value.
Before any data is transmitted, the master transmits the address of the target slave. The slave must send an acknowledge
signal on the ACBDAT line once it recognizes its address.
The address consists of the first seven bits after a Start Condition. The direction of the data transfer (R/W) depends on the
eighth bit (which is sent after the address).
When the address is sent, each device in the system compares this address with its own. If there is a match, the device
considers itself addressed and sends an acknowledge signal. Depending on the state of the R/W bit (1=read, 0=write), the
device acts either as a transmitter or a receiver. The combination of the 7-bit address and the R/W bit is used in this document to define the slave address as a write address (even) and a read address (odd) pair.
A low-to-high transition during a ACBCLK high period indicates the Stop Condition and ends the transaction of ACBDAT
(see Figure 34).
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PC8741x
6.0 ACCESS.bus Interface
(Continued)
The ACCESS.bus protocol allows a General Call address to be sent to all slaves connected to the bus. The first byte sent
specifies the General Call address (00h) and the second byte specifies the meaning of the general call (“Reset and write
programmable part of slave address by hardware”—06h). When a 00h-followed-by-a-06h transaction is detected, the
PC8741x device resets the ACCESS.bus Interface logic and the data registers (except for the configuration registers) and
reloads the default slave address.
ACBDAT
ACBCLK
1-7
S
8
9
Start
Slave
Condition Address R/W ACK
1-7
Data
8
9
1-7
ACK
Data
9
8
ACK
P
Stop
Condition
Figure 34. A Complete ACCESS.bus Data Transaction
6.2.7
Arbitration on the Bus
Multiple master devices on the bus require arbitration between their conflicting bus access demands. Control of the bus is
initially determined according to address bits and clock cycle. If more than one master try to address the same slave, data
comparisons determine the outcome of this arbitration. A master device immediately aborts a transaction if the value sampled on the ACBDAT line differs from the value internally driven by the device. (An exception to this rule is ACBDAT while
the master is receiving data. The lines may be held low by the slave without causing an abort.)
The ACBCLK signal is monitored by the master for clock synchronization and to allow the slave to stall the bus. The actual
clock period is set either by the master with the longest clock period or by the slave stall period. The maximum allowed “cumulative clock low extend time” of a slave device (per transaction) is defined in Section 11.5.6 on page 246. The clock high
period is determined by the master with the shortest clock high period; however, it must not be longer than the value defined
in Section 11.5.6.
When an abort occurs during the address transmission, the master that identifies the conflict must release the bus, switch
to Slave mode and continue to sample ACBDAT to check if it is being addressed by the winning master on the bus.
If the PC8741x device detects that ACBCLK is held low longer than the maximum allowed time, it aborts the current transaction and sets the LOWCKTO bit in the ACBCST register (see Section 6.3.2 on page 127).
6.2.8
Packet Error Check (PEC)
The Packet Error Checking mechanism complies with Revision 1.1 of the SMBus Specification. It consists of appending an
error check byte to the end of each transaction (before the Stop condition).
The PC8741x devices are capable of communicating with all masters, whether or not they implement the PEC.
Master PEC Assessment
After reset, a master supporting the PEC feature performs the following sequence:
1. Read (without PEC) the ACBCST register of the PC8741x slave device.
2. Check the PECAVAIL bit (bit 0 of the register), which indicates the PEC slave support (for the PC8741x devices, this bit
is always ‘1’).
3. Read (with PEC) the ACBCST register and check for its correctness.
4. Register the PC8741x slave device as PEC compliant.
All subsequent transactions between the master and the PEC-compliant slave include the PEC byte. During write transactions, the master provides the PEC of the transmitted data. During read transactions, the master checks the received data
using the PEC supplied by the slave. In both cases, the master supplies the number of ACBCLK cycles required for PEC
support. If the master does not supply these clock cycles, the PC8741x device considers that PEC is not supported during
the current transaction (i.e., there is no error condition).
Slave PEC Support
The PC8741x device provides PEC support when the master also requires it. However, the PC8741x device always calculates the PEC value of the incoming or outgoing data.
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(Continued)
After the last bytes of a write transaction, if the master supplies additional ACBCLK cycles, the PC8741x device receives the
PEC byte and compare it with the calculated PEC value. Otherwise, it just ignores the calculated PEC. If the comparison
fails, the PC8741x device generates a NACK bit at the end of the PEC byte and sets the PECERR bit in the ACBCST register
(see Section 6.3.2 on page 127) but does not execute the write transaction.
At the end of the last byte of a read transaction, if the master generates an ACK for the last byte (instead of a NACK), the
PC8741x device sends the calculated PEC value during the following byte. Otherwise, it discards the calculated PEC.
PEC Implementation
The PEC is an 8-bit cyclic redundancy check (CRC-8) value attached at the end of an ACCESS.bus transaction as the last
byte transmitted before the Stop condition.
The PC8741x device calculates the PEC value by hardware (bit-by-bit), using all the bytes in the transaction (except the PEC
byte itself). PEC calculation does not include Start, Restart, Stop, ACK or NACK, which are bus control bits and not data
bits. The PEC value is generated using the polynomial C(x) = x8 + x2 + x1 + 1, which is specified in Intel's SMBus Specification (Rev 1.1 Dec. 11, 1998). During a read transaction, the PEC value is generated by the PC8741x device and checked
by the master; during a write transaction, it is generated by the master and checked by the slave.
6.2.9
ACCESS.bus Protocol
The protocol is based on five basic byte types: Save Address, Command, Offset Address, Data and PEC; these are described below. An error is flagged in the following cases:
●
If the number of bytes in the transaction differs from the number of bytes required by the Command byte.
●
For Command byte type, if the reserved bit is not zero.
When an error is flagged, a NACK is generated at the end of the current byte (the current transaction is aborted) and the
ILGCOM bit in the ACBCST register is set (see Section 6.3.2 on page 127).
Slave Address Byte Type
Bit
7
Name
6
5
4
3
2
1
0
SLAVEAD
ACBRW
Bit
Description
7-1
SLAVEAD (Slave Address). This seven-bit field indicates the slave address of the accessed device. If its value
is the same as the one selected during the set-up process (see Section 6.2.6), the PC8741x device responds
to the present transaction.
0
Revision 1.2
ACBRW (ACCESS.bus Read/Write Mode). Selects the transfer direction for the current transaction.
0: Write ACCESS.bus transaction (from master to slave) - equivalent to an even 8-bit slave address
1: Read ACCESS.bus transaction (from slave to master) - equivalent to an odd 8-bit slave address
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PC8741x
6.0 ACCESS.bus Interface
PC8741x
6.0 ACCESS.bus Interface
(Continued)
Command Byte Type
This type has two variations, according to the value of the INEX bit.
Bit
Name
7
6
INEX=0
RDWR
7
6
5
INEX=1
RDWR
Reserved
Bit
Name
Bit
5
4
3
2
1
0
2
1
0
LOGDEV
4
3
XBCSN
XA26-XA24
Description
7
INEX (Internal/External Access). Selects the access type for the current transaction.
0: Internal access - to modules within the PC8741x device
1: External access - to devices connected to the X-Bus (PC87417)
6
RDWR (Read/Write Access). Selects the access direction for the current transaction.
0: Write access - data sent by the master is written into the selected address
1: Read access - data read from the selected address is stored in the Read Buffer
5-0
5
4-3
LOGDEV (Logical Device Number). This field indicates the Logical Device Number (LDN) of the accessed
internal functional block. Table 33 defines the LDN assignment for each functional block of the PC8741x device;
other table values are not allowed. These LDNs are equivalent but not identical to those assigned by the plugand-play configuration. Only those Logical Devices that can be accessed both through the ACCESS.bus and the
LPC bus are assigned the same LDN.
Reserved.
XBCSN (X-Bus Chip-Select Number). These two bits select one of the four X-Bus chip-selects to be accessed
during the current transaction (PC87417).
Bits
4 3
0 0:
0 1:
1 0:
1 1:
2-0
Chip-Select
XCS0
XCS1
XCS2
XCS3
XA26-XA24 (X-Bus Offset Address). These bits set the value of the X-Bus address lines XA26-XA24, which
are used as offset for the X-Bus access during the current transaction (PC87417). The XA27 address line is set
to ‘0’.
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PC8741x
6.0 ACCESS.bus Interface
(Continued)
Table 33. Logical Device Number (LDN) Assignment for ACCESS.bus
LDN
Functional Block
00h
Floppy Disk Controller (FDC)
01h
Parallel Port (PP)
02h
Serial Port 2 (SP2)
03h
Serial Port 1 (SP1)
04h
System Wake-Up Control (SWC)
06h
Keyboard and Mouse Controller (KBC)1
07h
General-Purpose I/O (GPIO) Ports
0Fh
X-Bus Extension (PC87417)
10h
Real Time Clock (RTC)2
30h
PM1b_EVT_BLK (SWC-ACPI)
31h
PM1b_CNT_BLK (SWC-ACPI)
32h
GPE1_BLK (SWC-ACPI)
3Eh
Device Configuration (CONFIG)3,4
3Fh
ACCESS.bus Interface (ACB)3
1. This Logical Device has two chip selects for the Index/Data registers, each
pointed to by a different Base Address in the configuration. The A2 bit of the Offset Address Byte differentiates between the two chip selects:
A2 = 0: the Index/Data registers pointed to by the Base Address at 60h and 61h
A2 = 1: the Index/Data registers pointed to by the Base Address at 62h and 63h.
2. This Logical Device has two chip selects for the Index/Data registers, each
pointed to by a different Base Address in the configuration. The A1 bit of the Offset Address Byte differentiates between the two chip selects (see Note 1
above).
3. This Logical Device is accessible only through the ACCESS.bus.
4. Access to this Logical Device is through the Index register located at offset 00h
and data register located at offset 01h.
Offset Address Byte Type
This is an 8-bit value representing either of the following:
•
•
Internal access - the offset address from the base of the functional block.
External access - eight bits of the offset address from the base of the X-Bus chip-select (PC87417).
The offset address value must be within the defined range for the selected Logical Device or X-Bus chip-select. Offset values
outside this range are reserved.
Data Byte Type
This is an 8-bit value representing either the written or read data.
PEC Byte Type
This is an 8-bit value representing the 8-bit cyclic redundancy check of all the transferred bytes (see Section 6.2.8 on
page 120).
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6.0 ACCESS.bus Interface
(Continued)
Reset Slave Transaction
This is a broadcast transaction to the General Call address (00h) that resets the ACCESS.bus Interface logic and the data
registers (the configuration registers are not affected) and reloads the current slave address by starting a slave address setup process (see Section 6.2.6 on page 119). PEC is not supported for this transaction. Since this is a broadcast transaction,
all slave devices connected to the ACCESS.bus respond to it.
S General Call Address A Reset & Reload Slave Address A P
(00h)
(06h)
S
= Start condition
P
= Stop condition
A
= ACK by slave
Write Internal Transaction
This transaction writes a byte of data to a register of a functional block of the PC8741x device. The functional block is selected by the Logical Device Number for the ACCESS.bus (see Table 33 on page 123). The specific register is accessed
using the 8-bit offset address (from the base of the functional block). If PEC is supported, the master sends a PEC byte at
the end of the transaction.
If the selected Logical Device is not powered (the VDD supply is off), the PC8741x device generates a NACK bit at the end
of the Command byte, sets the OFFLDN bit in the ACBCST register (see Section 6.3.2 on page 127) and aborts the transaction.
S Slave Address A
Command
A Offset Address A
(S.A, Write)
(Int, Write, LDN)
(OA7-OA0)
S
= Start condition
P
= Stop condition
Data
A
A
PEC
A P
= ACK by slave
Read Internal Transaction
This transaction reads a byte of data from a register of a functional block of the PC8741x device. The functional block is
selected by the Logical Device Number for the ACCESS.bus (see Table 33 on page 123). The specific register is accessed
using the 8-bit offset address (from the base of the functional block). This transaction is executed in two phases:
●
The master executes an ACCESS.bus write transaction, which conveys the Command (Read) and Offset Address
information to the PC8741x device. During this phase, the data is read from the specific register into the Read Buffer.
This phase has no Stop Condition.
●
Following a Restart condition, the master executes an ACCESS.bus read transaction. During this phase the data is
transferred from the Read Buffer to the master. At the end of this phase, the PC8741x device returns a PEC byte if
required by the master. The calculated PEC value is based on the bytes transferred during both phases.
If the selected Logical Device is not powered (the VDD supply is off), the PC8741x device generates a NACK bit at the end
of the Command byte, sets the OFFLDN bit in the ACBCST register (see Section 6.3.2 on page 127) and aborts the transaction.
S Slave Address A
Command
A Offset Address A
(S.A, Write)
(Int, Read, LDN)
(OA7-OA0)
R Slave Address A
Data
A
PEC
N P
(S.A, Read)
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S
= Start condition
R
= Restart condition
N
= NACK by master
P
= Stop condition
A
= ACK by master
A
= ACK by slave
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6.0 ACCESS.bus Interface
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Write External Transaction (PC87417)
This transaction writes a byte of data to a memory device or to an I/O port connected to the X-Bus. The chip-select for the
device is selected by the XBCSN field in the command byte. The specific memory location or I/O port register is accessed
using a 27-bit offset address (from the base of the chip-select). The 27-bit offset address is broken into four bytes: XA26XA24 in the Command byte and XA23-XA16, XA15-XA8 and XA7-XA0 in three successive Offset Address bytes. If PEC is
supported, the master sends a PEC byte at the end of the transaction.
S Slave Address A
(S.A, Write)
Command
A Offset Address A Offset Address A Offset Address A
(Ext, Write, XA26-24)
(XA23-XA16)
(XA15-XA8)
(XA7-XA0)
Data
S
= Start condition
P
= Stop condition
A
A
PEC
A P
= ACK by slave
Read External Transaction (PC87417)
This transaction reads a byte of data from a memory device or from an I/O port connected to the X-Bus. The chip-select for
the device is selected by the XBCSN field in the command byte. The specific memory location or I/O port register is accessed
using a 27-bit offset address (from the base of the chip-select). The 27-bit offset address is broken in four bytes: XA26-XA24
in the Command byte and XA23-XA16, XA15-XA8 and XA7-XA0 in three successive Offset Address bytes. This transaction
is executed in two phases:
●
The master executes an ACCESS.bus write transaction, which conveys the Command (Read), chip-select and Offset
Address information to the PC8741x device. During this phase, the data is read from the specific memory location or
I/O port register into the Read Buffer. This phase has no Stop Condition.
●
Following a Restart condition, the master executes an ACCESS.bus read transaction. During this phase the data is
transferred from the Read Buffer to the master. At the end of this phase, the PC8741x device returns a PEC byte if
required by the master. The calculated PEC value is based on the bytes transferred during both phases.
S Slave Address A
(S.A, Write)
Command
A Offset Address A Offset Address A Offset Address A
(Ext, Read, XA26-24)
(XA23-XA16)
(XA15-XA8)
R Slave Address A
Data
(XA7-XA0)
A
PEC
N P
(S.A, Read)
S
= Start condition
R
= Restart condition
N
= NACK by master
P
= Stop condition
A
= ACK by master
A
= ACK by slave
6.2.10 Transaction Execution
The ACCESS.bus uses the internal bus of the PC8741x device to access the internal modules (except its own registers) or
to bridge transactions to the X-Bus (see “Block Diagram” on page 1). Since the same internal bus is also used independently
by the LPC bus, the duration of the ACCESS.bus use of the internal bus is held to a minimum.
At the highest ACBCLK frequency (100 KHz), the longest ACCESS.bus transaction (Read External) takes at least 750 µs
to complete. In order not to stall the internal bus for such a long time, the ACCESS.bus transactions are executed as follows:
●
Write - data is written through the internal bus at the end of the transaction after the Stop condition is detected; the
next ACCESS.bus transaction can start immediately while the present data is written through the internal bus.
●
Read - data is read through the internal bus during the second part of the transaction (beginning with Restart), after
the Slave Address is received and before it is acknowledged (ACK); while the data is read through the internal bus,
the ACBCLK signal is held low, indicating to the ACCESS.bus master that PC8741x device is not ready (see Section
6.2.7 on page 120).
The duration of the ACCESS.bus transaction through the internal bus is longer for external access (X-Bus devices PC87417) than for internal access (internal modules of the PC8741x device). If wait states are configured for the module or
X-Bus access, their duration must be added to the internal bus transaction time. When the XRDY signal is in use, its delay
must also be accounted for.
If an LPC transaction started before an ACCESS.bus transaction, the execution of the ACCESS.bus transaction through the
internal bus is withheld until the end of the LPC transaction.
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PC8741x
6.0 ACCESS.bus Interface
6.3
(Continued)
ACB REGISTERS (ON ACCESS.BUS ONLY)
All these registers are accessible only through the ACCESS.bus.
The following abbreviations are used to indicate the Register Type:
●
R/W
= Read/Write.
●
R
= Read from a specific register (write to the same address is to a different register).
●
W
= Write (see above).
●
RO
= Read Only.
●
WO
= Write Only. Reading from the bit returns 0.
●
R/W1C = Read/Write 1 to Clear. Writing 1 to a bit clears it to 0. Writing 0 has no effect.
●
R/W1S = Read/Write 1 to Set. Writing 1 to a bit sets its value to 1. Writing 0 has no effect.
6.3.1
ACB Register Map (on ACCESS.bus Only)
Offset
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Mnemonic
Register Name
Type
Power Well
Section
00h
ACBCST
ACCESS.bus Control/Status
Varies per bit
VSB
6.3.2
01h
ACBCFG
ACCESS.bus Configuration
Varies per bit
VSB
6.3.3
02h
ACBLKCTL
ACCESS.bus Lock Control
Varies per bit
VSB
6.3.4
03h
ACBFDIS
ACCESS.bus Fast Disable
R/W
VSB
6.3.5
04h
ACBTRIS
ACCESS.bus TRI-State
R/W
VSB
6.3.6
05h
ACCLCF1
Access Lock Configuration 1
R/W
VSB
6.3.7
06h
ACCLCF2
Access Lock Configuration 2
R/W
VSB
6.3.8
126
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6.3.2
PC8741x
6.0 ACCESS.bus Interface
(Continued)
ACCESS.bus Control/Status Register (ACBCST)
This register controls the ACCESS.bus interface and holds the status of the last transactions. On reset, it is cleared (01h).
Power Well:VSB
Location:
Offset 00h
Type:
Varies per bit
Bit
7
6
5
4
Name
OFFLDN
ILGCOM
PECERR
BUSERR
Reset
0
0
0
0
Bit
7
Type
3
2
LOWCKTO ACCLVIOL
0
0
1
0
VDDSTAT
PECAVAIL
0
1
Description
R/W1C OFFLDN (Accessed LDN Powered-off Flag). Indicates that the Logical Device accessed through the
command byte (only for Internal Access mode, i.e., when INEX = 0) is powered-off (relevant for the
Legacy functional blocks powered from the VDD plane). Writing ‘1’ clears this bit; writing ‘0’ is ignored.
0: Powered Logical Device accessed (default)
1: Unpowered Logical Device accessed
6
R/W1C ILGCOM (Illegal Command Flag). Indicates that an illegal command code or an incorrect number of
address/data bytes was received or requested for transmission (by last byte NACK or Stop control).
Writing ‘1’ clears this bit; writing ‘0’ is ignored.
0: Correct protocol (default)
1: Illegal command or number of bytes
5
R/W1C PECERR (PEC Error Flag). Indicates that a PEC error was detected in the write transaction bytes that
were received from the master. This bit is not updated if the master does not send a PEC byte. Writing
‘1’ clears this bit; writing ‘0’ is ignored.
0: Correct PEC (default)
1: CRC of the received bytes differs from the received PEC
4
R/W1C BUSERR (Bus Error Flag). Indicates that an unexpected Start, Restart or Stop Condition was detected
during a read or write transaction. Writing ‘1’ clears this bit; writing ‘0’ is ignored.
0: Correct transaction (default)
1: Illegal Start, Restart or Stop Condition
3
R/W1C LOWCKTO (Low Clock Timeout Flag). Indicates that the ACBCLK signal was detected low for longer
than the maximum allowed “cumulative clock low extend time” during a transaction, as defined in
Section 11.5.6 on page 246. Writing ‘1’ clears this bit; writing ‘0’ is ignored.
0: Correct clock low timing (default)
1: Clock low timeout
2
R/W1C ACCLVIOL (Access Lock Violation Flag). Indicates that an LPC access to a functional module locked
for sole use by ACCESS.bus was detected. Writing ‘1’ clears this bit; writing ‘0’ is ignored.
0: Correct LPC access (default)
1: LPC access to a locked functional module
1
RO
VDDSTAT (VDD Power Status). Indicates the actual status of the VDD power supply to the PC8741x
device.
0: VDD power Off
1: VDD power On
0
RO
PECAVAIL (PEC Feature Available). Enables the master to detect the availability of the PEC
implementation in the slave.
0: Peripheral does not support PEC
1: Peripheral supports PEC (default and fixed value for PC8741x devices)
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PC8741x
6.0 ACCESS.bus Interface
6.3.3
(Continued)
ACCESS.bus Configuration Register (ACBCFG)
This register controls the configuration of the ACCESS.bus Interface. On reset, it is cleared (00h).
Power Well:
VSB
Location:
Offset 01h
Type:
Varies per bit
Bit
7
6
Name
CSWRST
Reserved
Reset
0
0
Bit
Type
7
R/W
6
4
3
ACCLMD
0
2
1
Reserved
0
0
0
0
ACTSTAT
0
0
Description
CSWRST (Controller Software Reset). When set to ‘1’, this bit triggers a Controller Software reset
sequence (see Section 2.2.3 on page 35) and then returns to ‘0’. It always returns ‘0’ when read.
0: Normal operation (default)
1: Enable the Controller Software Reset
Reserved.
5-4
R/W
ACCLMD (Locked Module Access Mode). These bits control the behavior of the LPC Interface
whenever a locked module is accessed.
Bits
5 4
0 0:
0 1:
1 0:
1 1:
3-1
Function
Complete cycle and generate Error SYNC; read 00h; ignore write (default).
Complete cycle; read 00h; ignore write.
Ignore cycle (do not generate SYNC).
− Locked X-Bus chip-select (XCS3-XCS0): Generate Long Wait SYNC for read and write until
access lock is removed; then complete transaction normally.
− Any other locked module: Complete cycle; read 00h; ignore write.
Reserved.
0
6.3.4
5
R/W
ACTSTAT (Module Activation Status Configuration). This bit configures the behavior of the
Activation bit (for the Legacy modules) when read through the LPC bus (index 30; see Section 3.2.3 on
page 40). When this bit is set to ‘1’ and a specific module is disabled by the bits in the ACBFDIS
register (see Section 6.3.5 on page 130), or when the module is locked by the bits in the ACCLCF1
register (see Section 6.3.7 on page 132), the module Activation status that is read through the LPC
returns a ‘0’ value, ignoring the actual setting of the Activation bit.
0: Activation status reflects the value of the Activation bit (default)
1: Activation status reflects the value of the Activation bit, or returns ‘0’ if either the module is locked, or
disabled by the bits in the ACBFDIS register
ACCESS.bus Lock Control Register (ACBLKCTL)
This register controls the configuration lock of the PC8741x device. On reset, it is cleared (00h).
Power Well: VSB
Location:
Offset 02h
Type:
Varies per bit
Bit
7
Name
VSBLOCK
Reset
0
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6
5
UNLOCKM UNLOCKG
0
0
4
3
2
1
0
UNLOCKF
UNLOCKC
UNLOCKX
UNLOCKR
UNLOCKS
0
0
0
0
0
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Bit
7
PC8741x
6.0 ACCESS.bus Interface
(Continued)
Type
Description
R/W1S VSBLOCK (Configuration Lock Until VSB Reset). Controls the reset source of the following lock bits:
LOCKMCF and LOCKGCF in the SIOCF1 register, LOCKFDS in the SIOCF6 register, LOCKCCF in the
CLOCKCF register, LOCKCFP in all GPCFG1 registers (for each GPIO pin), LOCKIOMP in the XIOCNF
register (PC87417), LOCKMMP in the XMEMCNF2 register (PC87417), all bits of the RLR register,
LOCKXSCF in the XZM0-XZM3 registers (PC87417), LOCKXHP in the HAP0 and HAP1 registers
(PC87417), LOCK_TMRRST in the PWTMRCTL register and LOCK_SLP_ENC in the SLP_ST_CFG
register. When set to ‘1’, this bit is cleared only by the VSB Power-Up reset.
0: Lock bits cleared by VDD Power-Up reset, by Hardware reset or by VSB Power-Up reset (default)
1: Lock bits cleared only by VSB Power-Up reset
6
R/W
UNLOCKM (Unlock Multiplexing Configuration). When set to ‘1’, this bit resets the LOCKMCF bit in
the SIOCF1 register, ignoring the setting of the VSBLOCK bit. It always returns ‘0’ when read.
0: Normal operation (default)
1: Reset the LOCKMCF bit
5
R/W
UNLOCKG (Unlock GPIO Configuration). When set to ‘1’, this bit resets the LOCKGCF bit in the
SIOCF1 register and the LOCKCFP bit in all the GPCFG1 registers (for each GPIO pin), ignoring the
setting of the VSBLOCK bit. It always returns ‘0’ when read.
0: Normal operation (default)
1: Reset the LOCKGCF and all the LOCKCFP bits
4
R/W
UNLOCKF (Unlock Fast Disable Configuration). When set to ‘1’, this bit resets the LOCKFDS bit in
the SIOCF6 register, ignoring the setting of the VSBLOCK bit. It always returns ‘0’ when read.
0: Normal operation (default)
1: Reset the LOCKFDS bit
3
R/W
UNLOCKC (Unlock Clock Configuration). When set to ‘1’, this bit resets the LOCKCCF bit in the
CLOCKCF register, ignoring the setting of the VSBLOCK bit. It always returns ‘0’ when read.
0: Normal operation (default)
1: Reset the LOCKCCF bit
2
R/W
UNLOCKX (Unlock X-Bus Configuration). When set to ‘1’, this bit resets the LOCKIOMP bit in the
XIOCNF register, the LOCKMMP bit in the XMEMCNF2 register, the LOCKXSCF bit in the XZM0-XZM3
registers and the LOCKXHP bit in the HAP0 and HAP1 registers, ignoring the setting of the VSBLOCK
bit (PC87417). It always returns ‘0’ when read.
0: Normal operation (default)
1: Reset the LOCKIOMP, LOCKMMP, LOCKXSCF and LOCKXHP bits
1
R/W
UNLOCKR (Unlock RAM Lock Configuration). When set to ‘1’, this bit resets all the bits of the RLR
register (see Section 3.16.3 on page 88), ignoring the setting of the VSBLOCK bit. It always returns ‘0’
when read.
0: Normal operation (default)
1: Reset all the bits of the RLR register
0
R/W
UNLOCKS (Unlock SWC Configuration). When set to ‘1’, this bit resets the LOCK_TMRRST bit in the
PWTMRCTL register and the LOCK_SLP_ENC bit in the SLP_ST_CFG register, ignoring the setting of
the VSBLOCK bit. It always returns ‘0’ when read.
0: Normal operation (default)
1: Reset the LOCK_TMRRST and LOCK_SLP_ENC bits
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PC8741x
6.0 ACCESS.bus Interface
6.3.5
(Continued)
ACCESS.bus Fast Disable Register (ACBFDIS)
This register provides a fast way to disable one or more modules through the ACCESS.bus without having to access the
Activate register of each module (see Section 3.2.3 on page 40). It is reset by hardware to 00h.
Power Well: VSB
Location:
Type:
Offset 03h
R/W
Bit
7
Name
Reserved
Reset
0
Bit
7-6
6
0
5
4
3
2
1
0
KBDDIS
MSDIS
SER1DIS
SER2DIS
PARPDIS
FDCDIS
0
0
0
0
0
0
Description
Reserved.
5
KBDDIS (Keyboard Controller Disable). When set to 1, this bit forces the Keyboard Controller module (Logical
Device 6) to be disabled (and its resources released) regardless of the actual setting of its Activation bit (index
30).
0: Enabled or Disabled, according to Activation bit (default)
1: Disabled
4
MSDIS (Mouse Controller Disable). When set to 1, this bit forces the Mouse Controller module (Logical Device
5) to be disabled (and its resources released) regardless of the actual setting of its Activation bit (index 30).
0: Enabled or Disabled, according to Activation bit (default)
1: Disabled
3
SER1DIS (Serial Port 1 Disable). When set to 1, this bit forces the Serial Port 1 module to be disabled (and its
resources released) regardless of the actual setting of its Activation bit (index 30).
0: Enabled or Disabled, according to Activation bit (default)
1: Disabled
2
SER2DIS (Serial Port 2 Disable). When set to 1, this bit forces the Serial Port 2 module to be disabled (and its
resources released) regardless of the actual setting of its Activation bit (index 30).
0: Enabled or Disabled, according to Activation bit (default)
1: Disabled
1
PARPDIS (Parallel Port Disable). When set to 1, this bit forces the Parallel Port module to be disabled (and its
resources released) regardless of the actual setting of its Activation bit (index 30).
0: Enabled or Disabled, according to Activation bit (default)
1: Disabled
0
FDCDIS (Floppy Disk Controller Disable). When set to 1, this bit forces the Floppy Disk Controller module to
be disabled (and its resources released) regardless of the actual setting of its Activation bit (index 30).
0: Enabled or Disabled, according to Activation bit (default)
1: Disabled
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PC8741x
6.0 ACCESS.bus Interface
(Continued)
ACCESS.bus TRI-STATE Register (ACBTRIS)
This register provides a fast way to float the outputs of one or more modules through the ACCESS.bus without having to
access their TRI-STATE Control bit in the Special Configuration register at index F0h. The module outputs enter TRI-STATE
only when the module is disabled (see Section 6.3.5 on page 130). The register is reset by hardware to 00h.
Power Well: VSB
Location:
Type:
Offset 04h
R/W
Bit
7
Name
5
Reserved
Reset
0
Bit
7-5
6
0
4
3
KBMSTRIS SER1TRIS
0
0
0
2
1
0
SER2TRIS
PARPTRIS
FDCTRIS
0
0
0
Description
Reserved.
4
KBMSTRIS (Keyboard and Mouse Outputs TRI-STATE). When set to 1 and the module is disabled, this bit
forces the outputs of the Keyboard and Mouse Controller to be in TRI-STATE regardless of bit 0 in the Keyboard
Configuration register (see Section 3.13.3 on page 69).
0: Enabled or Disabled, according to bit 0 in the Keyboard Configuration register (default)
1: Outputs in TRI-STATE
3
SER1TRIS (Serial Port 1 Outputs TRI-STATE). When set to 1 and the module is disabled, this bit forces the
outputs of the Serial Port 1 module to be in TRI-STATE regardless of bits 6 and 0 in the Serial Port 1
Configuration register (see Section 3.11.3 on page 66).
0: Enabled or Disabled, according to bits 6 and 0 in the Serial Port 1 Configuration register (default)
1: Outputs in TRI-STATE
2
SER2TRIS (Serial Port 2 Outputs TRI-STATE). When set to 1 and the module is disabled, this bit forces the
outputs of the Serial Port 2 module to be in TRI-STATE regardless of bits 6 and 0 in the Serial Port 2
Configuration register (see Section 3.10.3 on page 64).
0: Enabled or Disabled, according to bits 6 and 0 in the Serial Port 2 Configuration register (default)
1: Outputs in TRI-STATE
1
PARPTRIS (Parallel Port Outputs TRI-STATE). When set to 1 and the module is disabled, this bit forces the
outputs of the Parallel Port module to be in TRI-STATE regardless of bit 0 in the Parallel Port Configuration
register (see Section 3.9.3 on page 62).
0: Enabled or Disabled, according to bit 0 in the Parallel Port Configuration register (default)
1: Outputs in TRI-STATE
0
FDCTRIS (Floppy Disk Controller Outputs TRI-STATE). When set to 1 and the module is disabled, this bit
forces the outputs of the Floppy Disk Controller module to be in TRI-STATE regardless of bit 0 in the FDC
Configuration register (see Section 3.8.3 on page 59).
0: Enabled or Disabled, according to bit 0 in the FDC Configuration register (default)
1: Outputs in TRI-STATE
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PC8741x
6.0 ACCESS.bus Interface
6.3.7
(Continued)
Access Lock Configuration 1 Register (ACCLCF1)
This register controls the locking of the device functional blocks to LPC bus access. On reset, it is cleared (00h).
Power Well: VSB
Location:
Offset 05h
Type:
R/W
Bit
7
Name
CONFALOK
Reset
0
Bit
7
6-5
6
5
Reserved
0
4
3
2
1
0
KBCALOK SER1ALOK SER2ALOK PARPALOK FDCALOK
0
0
0
0
0
0
Description
CONFALOK (Configuration Access Lock). When set to 1, this bit disables LPC bus access to the Device
Configuration module and locks the module for use by ACCESS.bus only. If the module is accessed through
the LPC bus, it responds according to the setting of the ACCLMD field in the ACBCFG register (see Section
6.3.3 on page 128); in addition, the ACCLVIOL bit in ACBCST is set (see Section 6.3.2 on page 127).
0: Module opened for LPC access (default)
1: Module locked for LPC access and opened for use by ACCESS.bus only
Reserved.
4
KBCALOK (Keyboard/Mouse Controller Access Lock). When set to 1, this bit disables LPC bus access to
the Keyboard/Mouse Controller module and locks the module for use by ACCESS.bus only. If the module is
accessed through the LPC bus, it responds according to the setting of the ACCLMD field and the ACCLVIOL
bit (see CONFALOK bit). The setting of this bit also forces module activation regardless of the actual setting of
its Activation bit (index 30; see Section 3.2.3 on page 40) and of the setting of the global enable bit (GLOBEN
bit in the SIOCF1 register).
0: Module opened for LPC access (default)
1: Module locked for LPC access and opened for use by ACCESS.bus only (see Section 3.3.2 on page 44)
3
SER1ALOK (Serial Port 1 Access Lock). When set to 1, this bit disables LPC bus access to the Serial Port
1 module and locks the module for use by ACCESS.bus only. If the module is accessed through the LPC bus,
it responds according to the setting of the ACCLMD field and the ACCLVIOL bit (see CONFALOK bit). The
setting of this bit also forces module activation regardless of the actual setting of its Activation bit (index 30; see
Section 3.2.3 on page 40), of its fast-enable bit (SER1DIS bit in the SIOCF6 register) and of the setting of the
global enable bit (GLOBEN bit in the SIOCF1 register).
0: Module opened for LPC access (default)
1: Module locked for LPC access and opened for use by ACCESS.bus only (see Section 3.3.2 on page 44)
2
SER2ALOK (Serial Port 2 Access Lock). When set to 1, this bit disables LPC bus access to the Serial Port
2 module and locks the module for use by ACCESS.bus only. This bit behaves like the SER1ALOK bit.
0: Module opened for LPC access (default)
1: Module locked for LPC access and opened for use by ACCESS.bus only (see Section 3.3.2 on page 44)
1
PARPALOK (Parallel Port Access Lock). When set to 1, this bit disables LPC bus access to the Parallel Port
module and locks the module for use by ACCESS.bus only. This bit behaves like the SER1ALOK bit.
0: Module opened for LPC access (default)
1: Module locked for LPC access and opened for use by ACCESS.bus only (see Section 3.3.2 on page 44)
0
FDCALOK (Floppy Disk Controller Access Lock). When set to 1, this bit disables LPC bus access to the
Floppy Disk Controller module and locks the module for use by ACCESS.bus only. This bit behaves like the
SER1ALOK bit.
0: Module opened for LPC access (default)
1: Module locked for LPC access and opened for use by ACCESS.bus only (see Section 3.3.2 on page 44)
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6.3.8
PC8741x
6.0 ACCESS.bus Interface
(Continued)
Access Lock Configuration 2 Register (ACCLCF2)
This register controls the locking to LPC bus access of the device functional blocks. On reset, it is cleared (00h).
Power Well: VSB
Location:
Offset 06h
Type:
Bit
R/W
7
Name
Reset
6
SWCALOK RTCALOK
0
0
5
4
XBSALOK
Reserved
0
0
3
2
1
0
XCS3ALOK XCS2ALOK XCS1ALOK XCS0ALOK
0
0
0
0
Bit
Description
7
SWCALOK (System Wake-up Controller Access Lock). When set to 1, this bit disables the LPC bus access
to the System Wake-up Controller module and locks the module for use by ACCESS.bus only. If the module is
accessed through the LPC bus (the SWC registers), it responds according to the setting of the ACCLMD field
in the ACBCFG register (see Section 6.3.3 on page 128), and the ACCLVIOL bit in ACBCST is set (see Section
6.3.2 on page 127). This bit does not affect LPC access to the ACPI registers. The setting of this bit also forces
module activation regardless of the actual setting of its Activation bit (index 30; see Section 3.2.3 on page 40)
and of the setting of the global enable bit (GLOBEN bit in the SIOCF1 register).
0: Module opened for LPC access (default)
1: Module locked for LPC access and opened for use by ACCESS.bus only (see Section 3.3.2 on page 44)
6
RTCALOK (Real-Time Clock Access Lock). When set to 1, this bit disables the LPC bus access to the RealTime Clock module and locks the module for use by ACCESS.bus only. This bit behaves like the SWCALOK bit.
0: Module opened for LPC access (default)
1: Module locked for LPC access and opened for use by ACCESS.bus only (see Section 3.3.2 on page 44)
5
XBSALOK (X-Bus Module Access Lock). When set to 1, this bit disables the LPC bus access to the X-Bus
module and locks the module for use by ACCESS.bus only (PC87417). This bit behaves like the SWCALOK bit.
0: Module opened for LPC access (default)
1: Module locked for LPC access and opened for use by ACCESS.bus only (see Section 3.3.2 on page 44)
4
Reserved.
3
XCS3ALOK (X-Bus XCS3 Access Lock). When set to 1, this bit disables the LPC bus access to the X-Bus
devices connected to XCS3 and locks them for use by ACCESS.bus only (PC87417). This bit behaves like the
SWCALOK bit.
0: XCS3-connected devices opened for LPC access (default)
1: XCS3-connected devices locked for LPC access and opened for use by ACCESS.bus only (see Section 3.3.2 on
page 44)
2
XCS2ALOK (X-Bus XCS2 Access Lock). Same as XCS3ALOK bit for X-Bus devices connected to XCS2
(PC87417)
1
XCS1ALOK (X-Bus XCS1 Access Lock). Same as XCS3ALOK bit for X-Bus devices connected to XCS1
(PC87417)
0
XCS0ALOK (X-Bus XCS0 Access Lock). Same as XCS3ALOK bit for X-Bus devices connected to XCS0
(PC87417)
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PC8741x
6.0 ACCESS.bus Interface
6.4
(Continued)
ACB REGISTER BITMAP
Register
Offset Mnemonic
Bits
7
6
5
4
PECERR
BUSERR
00h
ACBCST
OFFLDN
ILGCOM
01h
ACBCFG
CSWRST
Reserved
02h
3
2
1
0
LOWCKTO ACCLVIOL VDDSTAT
PECAVAIL
Reserved
ACTSTAT
ACCLMD
ACBLKCTL VSBLOCK UNLOCKM UNLOCKG UNLOCKF UNLOCKC UNLOCKX UNLOCKR UNLOCKS
03h
ACBFDIS
04h
ACBTRIS
05h
ACCLCF1
CONFALOK
06h
ACCLCF2
SWCALOK RTCALOK
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Reserved
KBDDIS
Reserved
Reserved
MSDIS
SER1DIS
SER2DIS
PARPDIS
FDCDIS
KBMSTRIS SER1TRIS SER2TRIS PARPTRIS FDCTRIS
KBCALOK SER1ALOK SER2ALOK PARPALOK FDCALOK
Reserved
134
XCS3ALOK XCS2ALOK XCS1ALOK XCS0ALOK
Revision1.2
General-Purpose Input/Output (GPIO) Ports
This chapter describes one 8-bit port. A device may include a combination of several ports with different implementations.
For device specific implementation, see Section 3.14 on page 70.
7.1
OVERVIEW
The GPIO port is an 8-bit port, connected to eight pins. It features:
•
•
•
•
Software capability to control and read pin levels.
Flexible system notification by several means, based on the pin level or level transition.
Ability to capture and route events and their associated status.
Back-drive protected pins.
GPIO port operation is associated with two sets of registers:
•
Pin Configuration registers mapped in the Device Configuration space. These registers are used to set up the logical
behavior of each pin. There are three registers for each GPIO pin: GPIO Pin Configuration registers 1 and 2 (GPCFG1,
GPCFG2) and the GPIO Pin Event Routing register (GPEVR).
•
Four 8-bit runtime registers: GPIO Data Out (GPDO), GPIO Data In (GPDI), GPIO Event Enable (GPEVEN) and GPIO
Event Status (GPEVST). These registers are mapped in the GPIO device IO space (which is determined by the base
address registers in the GPIO Device Configuration). They are used to control and/or read the pin values and to handle
system notification. Each runtime register corresponds to the 8-pin port, such that bit ‘n’ in each one of the four registers
is associated with GPIOXn pin, where ‘X’ is the port number.
Each GPIO pin is associated with configuration bits and the corresponding bit slice of the four runtime registers, as shown
in Figure 35.
The functionality of the GPIO port is divided into basic functionality, which includes the control and reading of the GPIO pins
and enhanced functionality, which includes wake-up event detection and system notification. Basic functionality is described
in Section 7.2; enhanced functionality is described in Section 7.3.
Bit n
GPDOX
GPIOX Base Address
GPDIX
8 GPCFG
Registers
X = port number
n = pin number (0 to 7)
GPIO Pin
Configuration 1 and 2
(GPCFG1 and GPCFG2)
Registers
GPEVENX
Runtime
Registers
GPEVSTX
GPIOXn
Pin
GPIOXn CNFG
GPIOXn
Port Logic
GPIO Pin
Select (GPSEL)
Register
GPIO Pin Event
Routing (GPEVR)
Register
Port and Pin
Select
x8
8 GPEVR
Registers
x8
GPIO
Event
x8
Pending
Indication
Event
Routing
Control
GPIOXn ROUTE
Interrupt Request
SIOSMI
Power Button
Pulse Enable
SWC
SIOSCI
ONCTL
Figure 35. GPIO Port Architecture
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7.2
(Continued)
BASIC FUNCTIONALITY
The basic functionality of each GPIO pin is based on four configuration bits and a bit slice of runtime registers GPDO and
GPDI. The configuration and operation of a single pin GPIOXn (pin ‘n’ in port ‘X’) is shown in Figure 36.
ACCESS.bus
LPC Bus
(GPDI)
Read Only
Data In
Static
Pull-Up
Push-Pull =1
(GPDO)
Pin
Read/Write
Data Out
Pull-Up
Enable
Lock
(GPCFG1)
Lock
Bus
Control
(Bits 6,5)
Pin
Lock
(Bit 3)
Lock
Output
Type
(Bit 1)
Pull-Up
Control
(Bit 2)
Lock
Output
Enable
(Bit 0)
No_Vdd
Lock
V DD-powered
(GPCFG2)
Load
(Bit 4)
GPIO Pin Configuration Registers 1 and 2
Figure 36. GPIO Basic Functionality
7.2.1
Configuration Options
The GPCFG1 register controls the following basic configuration options:
•
•
Port Direction - Controlled by the Output Enable bit (bit 0).
•
•
Static Pull-Up - May be added to any type of port (input, open-drain or push-pull). It is controlled by Pull-Up Control (bit 2).
Output Type - Push-pull vs. open-drain. It is controlled by Output Buffer Type (bit 1) by enabling/disabling the upper transistor of the output buffer.
Pin Lock - GPIO pin may be locked to prevent any changes in the output value and/or the output configuration. The lock
is controlled by bit 3. It disables writes to the GPDO register bits, to bits 0-3 of the GPCFG1 register (including the Lock
bit itself) and to bits 4-6 of the GPCFG2 register. Once locked, it can be released by reset or by the UNLOCKG bit in the
ACBLKCTL register (see Section 6.3.4 on page 128 - PC87413 and PC87417).
The GPCFG2 register controls the following basic configuration options:
•
Load Protection - Disables the Output Buffer (if enabled), the Static Pull-Up (if enabled) and the Input Buffer (if the Port
is not a GPO type) if the specific GPIO pin is connected to a VDD-powered device and the VDD power is not present
(No_Vdd). This function is controlled by the VDD-powered Load bit (bit 4).
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•
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Access Control - Limits access to the specific pin from only one of the buses (ACCESS.bus or LPC bus). When access
from a bus is disabled, attempted writes to the Basic Functionality configuration registers (GPCFG1 bits 3-0 and
GPCFG2 bits 6-4, none of which are shown in Figure 36) and to the corresponding bit in the GPDO register are ignored.
Reads from the bits above and from the corresponding bit in the GPDI register are allowed and return the actual bit value.
Bus access is controlled by Bus Control bits (bits 6 and 5). After reset, both bits are ‘0’ and access is allowed from both
ACCESS.bus and LPC bus. In the PC87414 and PC87416, this feature is irrelevant because only the LPC bus is
available.
7.2.2
Operation
If the output is enabled, the value that is written to the GPDO register is driven to the pin. Reading from the GPDO register
returns its contents regardless of the actual pin value or the port configuration.
The GPDI register is a read-only register. Reading from the GPDI register returns the actual pin value regardless of its
source (the port itself or an external device). Writing to this register is ignored.
Activation of the GPIO module is controlled by device-specific configuration bits. When this module is inactive, access
through the LPC bus to the runtime registers (GPDI and GPDO) is disabled; however, there is no change in the GPDO value
and therefore there is no effect on the outputs of the pins.
7.3
EVENT HANDLING AND SYSTEM NOTIFICATION
The enhanced GPIO port (GPIOE) supports system notification based on event detection. This functionality is based on
configuration bits and a bit slice of runtime registers GPEVEN and GPEVST. The configuration and operation of the event
detection capability is shown in Figure 37. System notification is described in Section 7.3.2.
GPIO Event Indication to SWC
1
Set
0
GPIO
Event
Pending
Indication
GPIO
Status
Read
Reset
R/W
Write 1 to Clear
Event
Enable
0
Input
Debouncer
Rising
Edge
Detector
1
Pin
Rising Edge or
High Level =1
Level =1
Event
Debounce
Enable
Event Polarity
Event Type
Bit 6
Bit 5
Bit 4
Internal
Bus
GPIO Pin Configuration Register 1
(GPCFG1)
Figure 37. Event Detection
7.3.1
Event Configuration
Each pin in the GPIO port is a potential input event source. The event detection can trigger a system notification upon predetermined behavior of the source pin. The GPCFG1 register determines the event detection trigger type for the system
notification.
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(Continued)
Event Debounce Enable
The input signal can be debounced for about 15 msec before entering the detector. To ensure that the signal is stable, the
signal state is transferred to the event detector only after a debouncing period during which the signal has no transitions.
The debouncer adds a 16 msec delay to both assertion and de-assertion of the event pending indicator (IRQ, SMI, SCI).
The debounce is controlled by Event Debounce Enable (bit 6 of the GPCFG1 register).
Event Type and Polarity
Two trigger types of event detection are supported: edge and level. An edge event may be detected upon a source pin transition either from high to low or low to high. A level event may be detected when the source pin is either at high or low level.
The trigger type is determined by Event Type (bit 4 of the GPCFG1 register). The direction of the transition (for edge) or the
polarity of the active level (for level) is determined by Event Polarity (bit 5 of the GPCFG1 register).
The term active edge refers to a change in a GPIO pin level that matches the Event Polarity bit (1 for rising edge and 0 for
falling edge). Active level refers to the GPIO pin level that matches the Event Polarity bit (1 for high level and 0 for low level).
The corresponding bit of the GPEVST register is set by hardware whenever an active edge or an active level is detected
regardless of the GPEVEN register setting. Writing 1 to the Status bit clears it to 0. Writing 0 is ignored.
A GPIO pin is in event pending state if an active event occurred (the corresponding bit of the GPEVST register is set) and
the corresponding bit of the GPEVEN register is set.
7.3.2
System Notification
System notification on GPIO-triggered events is achieved by asserting at least one of the following output pins:
•
•
Interrupt Request (via the Interrupt Serializer in the LPC Bus Interface).
System Management Interrupt (SIOSMI, via the System Wake-Up Control).
The system notification for each GPIO pin is controlled by the corresponding bit in the GPEVEN register and the bits of the
GPEVR register. System notification by a GPIO pin is enabled if the corresponding bit of the GPEVEN register is set to 1.
The bits of the GPEVR register select the means of system notification (IRQ or SMI) that the detected GPIO event is routed
to. The event routing mechanism is described in Figure 38.
GPIO Event Pending Indication
GPIO Event to
SIOSMI
GPIO Event to
IRQ
Event
Routing
Logic
Enable
SMI
Routing
Enable
IRQ
Routing
Bit 1
Bit 0
GPIO Pin
Event Routing Register
(GPEVR)
Routed Events
from other GPIO Pins
Figure 38. GPIO Event Routing Mechanism for System Notification
The system notification to the target is asserted if at least one GPIO pin is in event pending state.
The selection of the target (the means of system notification) is determined by the GPEVR register. If IRQ is selected as one
of the means for the system notification, the specific IRQ number is determined by the IRQ selection procedure of the device
configuration. The assertion of IRQ (as a means of system notification) is disabled either when the GPIO functional block is
deactivated or when the VDD power is Off.
The assertion of SMI is independent of the activation of the GPIO functional block. SMI from GPIO pins connected to a device
powered by VDD (VDDLOAD = 1 in the GPCFG2 register) is disabled when the VDD power is Off. However, SMI from GPIO
pins connected to a device powered by VSB (VDDLOAD = 0) is not affected by the status of the VDD power.
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System notification through IRQ, SMI or SCI (see Section 9.2.1 on page 162) can be initiated by software by writing to the
Data Out bit (in the GPDO register) of a GPIO pin. This is possible only if the output of the corresponding GPIO pin is enabled, pin multiplexing is selected for the GPIO function (see Section 1.3 on page 20) and the GPIO event is routed to IRQ,
SMI or SCI. System notification is asserted according to the actual level at the GPIO pin driven by the GPIO output and/or
by external circuitry. The level driven by the GPIO output should not cause a contention with the level driven by the external
circuitry.
A pending edge event may be cleared by clearing the corresponding GPEVST bit. However, a level event source may not
be released by software (except for disabling the source) as long as the pin is at active level. When level event is used, it is
also recommended to disable the input debouncer.
Upon deactivation of the GPIO functional block and while the VDD power is Off, access through the LPC bus to the runtime
registers (GPEVST and GPEVEN) is disabled. All means of system notification that include the target IRQ number are detached from the GPIO and de-asserted.
When the VDD power is Off, the status bits of the GPIO pins connected to a VDD-powered device (VDDLOAD = 1) are cleared,
however the status bits of the GPIO pins connected to a VSB-powered device (VDDLOAD = 0) is not affected.
Before enabling any system notification, it is recommended to set the desired event configuration and then verify that the
status registers are cleared.
7.4
GPIO PORT REGISTERS
The following abbreviations are used to indicate the Register Type:
●
R/W
= Read/Write.
●
R
= Read from a specific register (write to the same address is to a different register).
●
W
= Write (see above).
●
RO
= Read Only.
●
WO
= Write Only. Reading from the bit returns 0.
●
R/W1C = Read/Write 1 to Clear. Writing 1 to a bit clears it to 0. Writing 0 has no effect.
●
R/W1S = Read/Write 1 to Set. Writing 1 to a bit sets its value to 1. Writing 0 has no effect.
7.4.1
GPIO Pin Configuration Registers Structure
For each Port, there is a group of eight identical sets of configuration registers. Each set is associated with one GPIO pin.
The entire group is mapped to the PnP configuration space. The mapping scheme is based on the GPSEL register (see
Section 3.14.3 on page 72), which functions as an index register, and the specific GPCFG1, GPEVR and GPCFG2 registers
that reflect the configuration of the currently selected pin (see Table 34). All these registers are VSB powered.
Table 34. GPIO Configuration Registers
Index
Configuration Register or Action
Type
Power Well Reset
F0h
GPIO Pin Select register (GPSEL).
R/W
VSB
00h
F1h
GPIO Pin Configuration register 1 (GPCFG1).
R/W
VSB
Note1
F2h
GPIO Pin Event Routing register (GPEVR).
R/W
VSB
01h
F3h
GPIO Pin Configuration register 2 (GPCFG2).
R/W
VSB
00h
1. See Section 3.14.3 on page 72.
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7.4.2
(Continued)
GPIO Port Runtime Register Map
All these registers are VSB powered.
Offset
Mnemonic
Register Name
Type
Power Well
Reset
Section
Device specific1
GPDO
GPIO Data Out
R/W
VSB
FFh
7.4.3
Device specific1
GPDI
GPIO Data In
RO
VSB
-
7.4.4
Device specific1
GPEVEN
GPIO Event Enable
R/W
VSB
00h
7.4.5
Device specific1
GPEVST
GPIO Event Status
R/W1C
VSB
00h
7.4.6
1. The location of this register is defined in Section 3.14.1 on page 70.
7.4.3
GPIO Data Out Register (GPDO)
Power Well:VSB
Location:Device specific
Type:
R/W
Bit
7
6
5
4
Name
3
2
1
0
1
1
1
1
DATAOUT
Reset
1
1
1
1
Bit
Description
7-0
DATAOUT (Data Out). Bits 7-0 correspond to pins 7-0 of the specific Port. The value of each bit determines the
value driven on the corresponding GPIO pin when its output buffer is enabled. Writing to the bit latches the
written data unless the bit is locked by the GPCFG register Lock bit. Reading the bit returns its value regardless
of the pin value and configuration.
0: Corresponding pin driven to low
1: Corresponding pin driven or released (according to buffer type selection) to high (default)
7.4.4
GPIO Data In Register (GPDI)
Power Well:VSB
Location:Device specific
Type:
RO
Bit
7
6
5
4
Name
3
2
1
0
X
X
X
X
DATAIN
Reset
X
X
X
X
Bit
Description
7-0
DATAIN (Data In). Bits 7-0 correspond to pins 7-0 of the specific Port. Reading each bit returns the value of the
corresponding GPIO pin. Pin configuration and the GPDO register value may influence the pin value. Write is
ignored.
0: Corresponding pin level low
1: Corresponding pin level high
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(Continued)
GPIO Event Enable Register (GPEVEN)
Power Well:VSB
Location:Device specific
Type:
R/W
Bit
7
6
5
4
Name
3
2
1
0
0
0
0
0
EVTENA
Reset
0
0
0
0
Bit
Description
7-0
EVTENA (Event Enable). Bits 7-0 correspond to pins 7-0 of the specific Port. Each bit enables system
notification by the corresponding GPIO pin. The bit has no effect on the corresponding Status bit in the GPEVST
register.
0: Event Pending by corresponding GPIO pin masked
1: Event Pending by corresponding GPIO pin enabled
7.4.6
GPIO Event Status Register (GPEVST)
Power Well:VSB
Location:Device specific
Type:
Bit
R/W1C
7
6
5
4
Name
Reset
3
2
1
0
0
0
0
0
EVTSTAT
0
0
0
0
Bit
Description
7-0
EVTSTAT (Event Status). Bits 7-0 correspond to pins 7-0 of the specific Port. The setting of each bit is
independent of the Event Enable bit in the GPEVEN register. An active event sets the Status bit, which may be
cleared only by software writing 1 to the bit.
0: No active edge or level detected since last cleared
1: Active edge or level detected
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8.1
Real-Time Clock (RTC)
OVERVIEW
The RTC provides timekeeping and calendar management capabilities. It uses a 32.768 KHz signal as the basic clock for
timekeeping. The RTC also includes 242 bytes of battery-backed RAM for general-purpose use.
The RTC provides the following functions:
●
Accurate timekeeping and calendar management.
●
Alarm at a predetermined time and/or date.
●
Three programmable interrupt sources.
●
Valid timekeeping during power-down by utilizing external battery backup.
●
242 bytes of battery-backed RAM.
●
RAM lock schemes to protect its content.
●
Internal oscillator circuit (the crystal itself is off-chip) or external clock supply for the 32.768 KHz clock.
●
A century counter.
●
PnP support:
— Relocatable index and data registers
— Module access enable/disable option
— Host interrupt enable/disable option
●
Additional low-power features such as:
— Automatic switching from VBAT to VSB
— Internal power monitoring on the VRT bit
— Oscillator disabling to conserve battery power during storage
●
Software compatible with the DS1287 and MC146818.
8.2
8.2.1
FUNCTIONAL DESCRIPTION
Bus Interface
The RTC function is initially mapped to the default ServerI/O locations at indexes 70h to 73h (two Index/Data pairs). These
locations may be reassigned in compliance with Plug and Play requirements.
8.2.2
RTC Clock Generation
The RTC uses a 32.768 KHz clock signal as the basic clock for timekeeping. The 32.768 KHz clock is supplied by either the
internal oscillator circuit or by an external oscillator (see Sections 8.2.3 and 8.2.4).
8.2.3
Internal Oscillator
The internal oscillator employs an external crystal connected to the on-chip amplifier. The on-chip amplifier is accessible on
the 32KX1 input pin and 32KX2 output pin. See Figure 39 for the recommended external circuit; see Table 35 on page 143
for a listing of the circuit components. The oscillator may be disabled in certain conditions. See Section 8.2.12 on page 147
for more details.
To other
modules
VBAT
CF
32KX1 /
32KCLKIN
B1
32KX2
R1
C1
Y
Battery
Internal
External
R2
C2
CF = 0.1µF
Figure 39. Recommended Oscillator External Circuitry
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Table 35. Crystal Oscillator Circuit Components
Component
Parameters
Resonance Frequency
Values
Tolerance
32.768 KHz Parallel mode
User defined
Type
Crystal
N-Cut or XY-bar
Serial Resistance
40 KΩ
Max
Quality Factor, Q
35000
Min
2 pF
Max
Shunt Capacitance
9-13 pF
Load Capacitance, CL
Temperature Coefficient
User-defined
Resistor R1
Resistance
20 MΩ
5%
Resistor R2
Resistance
510 KΩ
5%
Capacitor C1
Capacitance
10 pF
5%
Capacitor C2
Capacitance
10 pF
5%
External Elements
Choose C1 and C2 capacitors (see Figure 39) to match the crystal’s load capacitance. The load capacitance CL “seen” by
crystal Y is comprised of C1 in series with C2 and in parallel with the parasitic capacitance of the circuit. The parasitic capacitance is caused by the chip package, board layout and socket (if any) and can vary from 0 to 8 pF. The rule of thumb in
choosing these capacitors is:
CL = (C1 * C2) / (C1 + C2) + CPARASITIC
Oscillator Start-Up
The oscillator starts to generate 32.768 KHz pulses to the RTC after about t32KW from when VBAT is higher than VBATMIN
(2.4V) or VSB is higher than VSBON (2.5V). The oscillation amplitude on the X2C pin stabilizes to its final value (approximately
0.4V peak-to-peak around 0.7V DC) in about 1 sec.
C1 can be trimmed to achieve precisely 32.768 KHz. For highly accurate timekeeping, use crystal and capacitors with low
tolerance and temperature coefficients.
8.2.4
External Oscillator
32.768 KHz can be applied from an external clock source, as shown in Figure 40.
VBAT
To other
modules
Internal
CF
32KCLKIN /
32KX1
32KX2 External
NC
OUT
PWR
32.768 KHz
Clock Generator
CF
B1
Battery
CF = 0.1µF
Figure 40. External Oscillator Connections
Connections
Connect the clock to the 32KCLKIN pin, leaving the oscillator output, 32KX2, unconnected.
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Signal Parameters
The signal levels must conform to the voltage level requirements for 32KCLKIN/32KX1 stated in Section 11.2 on page 233.
The signal must have a duty cycle of approximately 50%. To oscillate during power-down, the signal must be sourced from
a battery-backed source. This assures that the RTC delivers updated time/calendar information.
8.2.5
Timing Generation
The timing generation function divides the 32.768 KHz clock by 215 to derive a 1 Hz signal, which serves as the input for the
seconds counter. This is performed by a divider chain composed of 15 divide-by-two latches, as shown in Figure 41.
Divider Chain
1
2
2
2
3
2
13 14 15
2 2 2
1 Hz
Reset
DV2 DV1 DV0
6
4
5
CRA Register
32.768 KHz
To other
modules
32KX1 /
32KCLKIN
Oscillator
Enable
32KX2
Figure 41. Divider Chain Control
Bits 6-4 (DV2-0) of the CRA register control the following functions:
●
Normal operation of the divider chain (counting).
●
Divider chain reset to 0.
●
Oscillator activity when only VBAT power is present (backup state).
The divider chain can be activated by setting Normal Operation mode (bits 6-4 of CRA = 010b). The first update occurs
500 ms after divider chain activation.
Bits 3-0 of the CRA register select one the of 15 taps from the divider chain to be used as a periodic interrupt. The periodic
flag becomes active after half of the programmed period has elapsed, following divider chain activation.
See Section 8.3.13 on page 154 for more details.
8.2.6
Timekeeping
Data Format
Time is kept in BCD or binary format, as determined by bit 2 (DM) of Control Register B (CRB), and in either 12 or 24-hour
format, as determined by bit 1 of this register.
Note: When changing the above formats, re-initialize all the time registers.
Daylight Saving
Daylight saving time exceptions are handled automatically, as described in the RTC Control Register B (CRB) in Section
8.3.2 on page 150.
Leap Years
Leap year exceptions are handled automatically by the internal calendar function (every four years, February is extended to
29 days).
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Updating
The time and calendar registers are updated once per second regardless of bit 7 (SET) of the CRB register. Since the time
and calendar registers are updated serially, unpredictable results may occur if they are accessed during the update. Therefore, it is essential to ensure that reading or writing to the time storage locations does not coincide with a system update of
these locations. There are four methods to avoid this contention.
Method 1
1. Set bit 7 of the CRB register to 1. This takes a “snapshot” of the internal time registers and loads them into the user copy
registers. The user copy registers are seen when accessing the RTC from outside and are part of the double buffering
mechanism. This bit may be kept set for up to 1 second, since the time/calendar chain continues to be updated once per
second.
2. Read or write the required registers (since bit 7 is set, the access is to the user copy registers). If a read operation is
performed, the information read is correct from the time bit 7 was set. If a write operation is performed, the write is only
to the user copy registers.
3. Reset bit 7 to 0. During the transition, the user copy registers update the internal registers, using the double buffering
mechanism to ensure that the update is performed between two time updates. This mechanism enables new time parameters to be loaded in the RTC.
Method 2
1. Access the RTC registers after detection of an Update Ended interrupt. The detection interrupt implies that an update
has just been completed and 999 ms remain until the next update.
2. To detect an Update Ended interrupt, either:
— Poll bit 4 of the CRC register.
— Use the following interrupt routine:
a) Set bit 4 of the CRB register.
b) Wait for an interrupt from interrupt pin.
c) Clear the IRQF flag of the CRC register before exiting the interrupt routine.
Method 3
Poll bit 7 of the CRA register. The update occurs 244 µs after this bit goes high. Therefore, if a 0 is read, the time registers
remain stable for at least 244 µs.
Method 4
Use a periodic interrupt routine to determine if an update cycle is in progress, as follows:
1. Set the periodic interrupt to the desired period.
2. Set bit 6 of the CRB register to enable the interrupt from periodic interrupt.
3. Wait for the appearance of a periodic interrupt, which indicates that the period represented by the following expression
remains until another update occurs:
[(Period of periodic interrupt / 2) + 244 µs]
8.2.8
Alarms
The timekeeping function can be set to generate an alarm when the current time reaches a stored alarm time. After each
RTC time update (every 1 second), the seconds, minutes, hours, date-of-month and month counters are compared with their
corresponding registers in the alarm settings. If they are equal, bit 5 of the CRC register is set to 1 and sent to the SWC as
an alarm signal. If the Alarm Interrupt Enable bit was previously set (bit 5 of the CRB register), the interrupt request pin is
also active.
Any alarm register may be set to Unconditional Match by setting bits 7 and 6 to binary ‘11’. This combination, not used by
any BCD or binary time codes, results in a periodic alarm. The rate of this periodic alarm is determined by the registers that
were set to Unconditional Match.
For example, if all but the seconds and minutes alarm registers are set to Unconditional Match, an interrupt is generated
every hour at the specified minute and second. If all but the seconds, minutes and hours alarm registers are set to Unconditional Match, an interrupt is generated every day at the specified hour, minute and second.
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8.2.9
(Continued)
Power Supply
The device is supplied from three supply voltages, as shown in Figure 42:
●
System power supply voltage, VDD.
●
System standby power supply voltage, VSB.
●
Backup voltage, from low-capacity Lithium battery VBAT.
A standby voltage (VSB) from the external AC/DC power supply powers the RTC under normal conditions.
External AC Power
Power Management
VDD Sense
Power
Supply
VDD
VDD
ONCTL
ONCTL
RTC
VDD
VSB
VSB
VBAT
VBAT
VSB
On/Off
Control
VSB
VBAT
VBAT
Backup
Battery
Figure 42. Power Supply Connections
Figure 43 shows a typical battery configuration. No external diode is required to meet the UL standard due to the internal
switch and internal serial resistor RUL(see the MCRS parameter in Section 11.1.2 on page 231).
RTC
VPP
VSB
CF
0.1 µF
VREF
VBAT
RUL
CE
22 µF
VSB
BT1
CF
0.1 µF
1. Place a 0.1 µF capacitor on each VSB power supply
pin and on VBAT as close to the pin as possible.
2. Place a 10-47 µF capacitor on the common VSB power
supply net as close to the device as possible.
Figure 43. Typical Battery Configuration
The RTC is supplied from one of two power supplies, VSB or VBAT, depending on their voltage levels. An internal voltage
comparator delivers the control signals to a pair of switches. Battery backup voltage VBAT maintains the correct time and
saves the CMOS memory when the VSB voltage is absent due to power failure or disconnection of the external AC/DC input
power supply or VSB main battery.
To ensure that the module uses power from VSB and not from VBAT, the VSB voltage must be maintained above its minimum,
as detailed in Section 11.1.5 on page 232.
The actual voltage point where the module switches from VBAT to VSB is lower than the minimum workable battery voltage
but high enough to guarantee the correct functionality of the oscillator and the CMOS RAM.
Figure 44 shows typical battery current consumption during battery-backed operation; Figure 45 shows the same during normal operation.
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IBAT (µA)
1.0
0.9
0.8
0.7
2.4 3.0 3.6
VBAT (V)
Figure 44. Typical Battery Current During Battery-Backed Power Mode
IBAT (µA)
0.20
0.15
0.10
0.05
VSB
(V)
3.0 3.3 3.6
Note: Battery voltage in this test is 3.0V.
Figure 45. Typical Battery Current During Normal Operation Mode
8.2.10 System Bus Lockout
During power On or power Off, spurious bus transactions from the host may occur. To protect the data in the RTC internal
registers from being corrupted, all inputs are automatically locked out. The lockout condition is asserted when VSB is lower
than VSBON at VSB power-on or VSBOFF at VSB power-off.
8.2.11 Power-Up Detection
When system power is restored after a power failure or power off state (VSB=0), the lockout condition continues for a delay
of 62 ms (minimum) to 125 ms (maximum) after the RTC switches from battery to system power.
The lockout condition is switched off immediately in the following situations:
•
If the Divider Chain Control bits, DV0-2 (bits 6-4 in the CRA register), specify a normal operation mode (010), all input
signals are enabled immediately on detection of system voltage above VSBON.
•
When battery voltage is below VBATDCT and LRESET is 0, all input signals are enabled immediately on detection of system voltage above VSBON. This also initializes registers at offsets 00h through 0Dh.
•
If bit 7 (VRT) of the CRD register is 0, all input signals are enabled immediately on detection of system voltage above
VSBON.
8.2.12 Oscillator Activity
The RTC oscillator is active if:
●
VSB power supply is higher than VSBON regardless of the battery voltage, VBAT.
●
VBAT power supply is higher than VBATMIN whether or not VSB is present.
The RTC oscillator is disabled if:
●
During power-down (VBAT only), if the battery voltage drops below VBATMIN, Battery Fail state may be entered. In this
case, the oscillator may stop oscillating and memory contents may be corrupted or lost.
●
Software writes 00h to DV2-0 bits of the CRA register and VSB is removed. This disables the oscillator and decreases
the power consumption from the battery connected to the VBAT pin. When disabling the oscillator, the CMOS RAM is
not affected as long as the battery is present at a correct voltage level.
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If the RTC oscillator becomes inactive, the following features are dysfunctional/disabled:
●
Timekeeping.
●
Periodic interrupt.
●
Alarm.
8.2.13 Interrupt Handling
The RTC has a single Interrupt Request line which handles the following three interrupt conditions:
●
Periodic interrupt.
●
Alarm interrupt.
●
Update end interrupt.
The interrupts are generated if the respective enable bits in the CRB register are set prior to an interrupt event occurrence.
Reading the CRC register clears all interrupt flags. Thus, when multiple interrupts are enabled, the interrupt service routine
must first read and store the CRC register and then deal with all pending interrupts by referring to this stored status.
If an interrupt is not serviced before a second occurrence of the same interrupt condition, the second interrupt event is lost.
Figure 46 illustrates the interrupt and status timing in the RTC.
Bit 7 of CRA
A
(244 µs)
Bit 4 of CRC
P
P/2
Bit 6 of CRC
P/2
B
C (30.5 µs)
Bit 5 of CRC
Flags (and IRQ) are reset at the conclusion
of CRC read or by reset.
A:
B:
C:
P:
Update In Progress bit high before update occurs = 244 µs
Periodic interrupt to update = (P/2 + A)
Update to Alarm Interrupt = 30.5 µs
Periodic interrupt cycle (programmed by RS3-0 of CRA)
Figure 46. Interrupt/Status Timing
8.2.14 Battery-Backed RAMs and Registers
The RTC has two battery-backed RAMs and 17 registers used by the logical units themselves. Battery-backup power enables information retention during system power down.
The RAMs are:
●
Standard RAM.
●
Extended RAM.
The memory maps and register content of the RAMs are illustrated in Section 8.6 on page 160.
The first 14 bytes and three programmable bytes of the Standard RAM are overlaid by time, alarm data and control registers.
The remaining 111 bytes are general-purpose memory.
Registers with reserved bits must be written using the “Read-Modify-Write” method.
All register locations within the device are accessed by the RTC Index and Data registers (at base address and base address+1). The Index register points to the register location being accessed. The Data register contains the data to be transferred to or from the location. An additional 128 bytes of battery-backed RAM (also called Extended RAM) may be accessed
via a second pair of Index and Data registers pointed at by the secondary base address and base address+1.
Access to the two RAMs may be locked. For details see the RAM Lock Register (RLR) in Section 3.16.3 on page 88.
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RTC REGISTERS
The RTC configuration registers can be accessed at any time during normal or standby operation; i.e., when VSB and/or VDD
are within the recommended operation range. Access to the RTC configuration registers is disabled during battery-backed
operation.
The register maps in this chapter use the following abbreviations for Type:
●
R/W
= Read/Write.
●
R
= Read from a specific register (write to the same address is to a different register).
●
W
= Write (see above).
●
RO
= Read Only.
●
WO
= Write Only. Reading from the bit returns 0.
●
R/W1C = Read/Write 1 to Clear. Writing 1 to a bit clears it to 0. Writing 0 has no effect.
●
R/W1S = Read/Write 1 to Set. Writing 1 to a bit sets its value to 1. Writing 0 has no effect.
8.3.1
RTC Configuration Registers Structure
The RTC configuration registers can be accessed at any time during normal or standby operation; i.e., when VSB and/or VDD
are within the recommended operation range. Access to the RTC configuration registers is disabled during battery-backed
operation. See Section 3.16 on page 87 for a description of the Configuration registers.
Table 36. RTC Configuration Register Map
Index
RTC Configuration Register or Action
Type
Power Well Reset
R/W1S
VSB
00h
Date-of-Month Alarm Register Offset (DOMAO).
R/W
VSB
00h
F2h
Month Alarm Register Offset (MONAO).
R/W
VSB
00h
F3h
Century Register Offset (CENO).
R/W
VSB
00h
F0h
RAM Lock Register (RLR).
F1h
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RTC Runtime Register Map
The RTC runtime registers can be accessed at any time during normal or standby operation; i.e., when VSB and/or VDD are
within the recommended operation range. The access is disabled during battery-backed operation. Write operation to these
registers is also disabled if bit 7 of the CRD register is 0 (see Section 8.3.16 on page 157).
Note: Before attempting to perform any start-up procedures, read the explanation of bit 7 (VRT) of the CRD register (see
Section 8.3.16 on page 157).
See Section 8.6 on page 160 for a detailed description of the memory map for the RTC registers.
This section describes the RTC Timing and Control registers that control basic RTC functionality. All registers are VPP powered.
Index
Mnemonic
Name
Type
Power
Well
Reset
Section
00h
SEC
Seconds Register
R/W
VPP
VPP PUR
8.3.3
01h
SECA
Seconds Alarm Register
R/W
VPP
VPP PUR
8.3.4
02h
MIN
Minutes Register
R/W
VPP
VPP PUR
8.3.5
03h
MINA
Minutes Alarm Register
R/W
VPP
VPP PUR
8.3.6
04h
HOR
Hours Register
R/W
VPP
VPP PUR
8.3.7
05h
HORA
Hours Alarm Register
R/W
VPP
VPP PUR
8.3.8
06h
DOW
Day-of-Week Register
R/W
VPP
VPP PUR
8.3.9
07h
DOM
Date-of-Month Register
R/W
VPP
VPP PUR
8.3.10
08h
MON
Month Register
R/W
VPP
VPP PUR
8.3.11
09h
YER
Year Register
R/W
VPP
VPP PUR
8.3.12
0Ah
CRA
RTC Control Register A
Varies per bit
VPP
Bit specific
8.3.13
0Bh
CRB
RTC Control Register B
R/W
VPP
Bit specific
8.3.14
0Ch
CRC
RTC Control Register C
R/O
VPP
Bit specific
8.3.15
0Dh
CRD
RTC Control Register D
R/O
VPP
VPP PUR
8.3.16
Programmable1 by DOMAO DOMA
Date-of-Month Alarm Register
R/W
VPP
VPP PUR
8.3.17
Programmable1 by MONAO MONA
Month Alarm Register
R/W
VPP
VPP PUR
8.3.18
Programmable1 by CENO
Century Register
R/W
VPP
VPP PUR
8.3.19
CEN
1. Overlaid on RAM bytes in range 0Eh-7Fh.
8.3.3
Seconds Register (SEC)
Power Well:VPP
Location: Index 00h
Type:
R/W
Bit
7
6
5
Name
3
2
1
0
0
0
0
Seconds Data
Reset
0
Bit
7-0
4
0
0
0
0
Description
Seconds Data. Values may be 00 to 59 in BCD format or 00 to 3B in Binary format.
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Seconds Alarm Register (SECA)
Power Well: VPP
Location: Index 01h
Type:
R/W
Bit
7
6
5
Name
0
0
0
Bit
8.3.5
3
2
1
0
0
0
0
Seconds Alarm Data
Reset
7-0
4
0
0
Description
Seconds Alarm Data. Values may be 00 to 59 in BCD format or 00 to 3B in Binary format.
When bits 7 and 6 are both set to one (‘11’), unconditional match is selected.
Minutes Register (MIN)
Power Well:VPP
Location: Index 02h
Type:
R/W
Bit
7
6
5
Name
0
0
0
Bit
8.3.6
3
2
1
0
0
0
0
2
1
0
0
0
0
Minutes Data
Reset
7-0
4
0
0
Description
Minutes Data. Values may be 00 to 59 in BCD format or 00 to 3B in Binary format.
Minutes Alarm Register (MINA)
Power Well:VPP
Location: Index 03h
Type:
Bit
R/W
7
6
5
Name
Reset
Bit
7-0
Revision 1.2
4
3
Minutes Alarm Data
0
0
0
0
0
Description
Minutes Alarm Data. Values may be 00 to 59 in BCD format or 00 to 3B in Binary format.
When bits 7 and 6 are both set to one (‘11’), unconditional match is selected.
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Hours Register (HOR)
Power Well:VPP
Location: Index 04h
Type:
R/W
Bit
7
6
5
4
Name
3
2
1
0
0
0
0
0
Hours Data
Reset
0
0
0
0
Bit
Description
7-0
Hours Data. For 12-Hour mode, values may be 01 to 12 (AM) and 81 to 92 (PM) in BCD format or 01 to 0C
(AM) and 81 to 8C (PM) in Binary format. For 24-Hour mode, values may be 0 to 23 in BCD format or 00 to 17
in Binary format.
8.3.8
Hours Alarm Register (HORA)
Power Well:VPP
Location: 05h
Type:
R/W
Bit
7
6
5
Name
4
3
2
1
0
0
0
0
Hours Alarm Data
Reset
0
0
0
0
0
Bit
Description
7-0
Hours Alarm Data. For 12-Hour mode, values may be 01 to 12 (AM) and 81 to 92 (PM) in BCD format or 01
to 0C (AM) and 81 to 8C (PM) in Binary format. For 24-Hour mode, values may be 0 to 23 in BCD format or 00
to 17 in Binary format.
When bits 7 and 6 are both set to one (‘11’), unconditional match is selected.
8.3.9
Day-of-Week Register (DOW)
Power Well:VPP
Location: Index 06h
Type:
R/W
Bit
7
6
5
Name
3
2
1
0
0
0
0
Day-of-Week Data
Reset
0
Bit
7-0
4
0
0
0
0
Description
Day-of-Week Data. Values may be 01 to 07 in BCD format or 01 to 07 in Binary format.
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8.3.10 Date-of-Month Register (DOM)
Power Well:VPP
Location: Index 07h
Type:
R/W
Bit
7
6
5
Name
3
2
1
0
0
0
0
2
1
0
0
0
0
Date-of-Month Data
Reset
0
0
0
Bit
7-0
4
0
0
Description
Date-of-Month Data. Values may be 01 to 31 in BCD format or 01 to 1F in Binary format.
8.3.11 Month Register (MON)
Power Well:VPP
Location: Index 08h
Type:
R/W
Bit
7
6
5
Name
3
Month Data
Reset
0
0
0
Bit
7-0
4
0
0
Description
Month Data. Values may be 01 to 12 in BCD format or 01 to 0C in Binary format.
8.3.12 Year Register (YER)
Power Well:VPP
Location: Index 09h
Type:
Bit
R/W
7
6
5
4
Name
Reset
Bit
7-0
Revision 1.2
3
2
1
0
0
0
0
0
Year Data
0
0
0
0
Description
Year Data. Values may be 00 to 99 in BCD format or 00 to 63 in Binary format.
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8.3.13 RTC Control Register A (CRA)
This register controls test selection in addition to other functions. This register cannot be written before reading bit 7 of the
CRD register.
Power Well:VPP
Location: Index 0Ah
Type:
Varies per bit
Bit
7
6
Name
Update in
Progress
Reset
0
5
4
3
Divider Chain Control
0
1
2
1
0
Periodic Interrupt Rate Select
0
0
0
0
0
Bit
Type
Description
7
RO
Update in Progress. This bit is not affected by reset. It reads 0 when bit 7 of the CRB register is 1.
0: Timing registers not updated within 244 µs
1: Timing registers updated within 244 µs
6-4
R/W
Divider Chain Control. These bits control the configuration of the divider chain for timing generation
(see Table 37). They are cleared to 000 as long as bit 7 of the CRD register reads 0.
3-0
R/W
Periodic Interrupt Rate Select. These bits select one of 15 output taps from the clock divider chain to
control the rate of the periodic interrupt (see Table 38 and Figure 41 on page 144). They are cleared to
000 as long as bit 7 of the CRD register reads 0.
Table 37. Divider Chain Control and Test Selection
DV2
(CRA6)
DV1
(CRA5)
DV0
(CRA4)
0
0
X
Oscillator Disabled
0
1
0
Normal Operation
0
1
1
1
0
X
1
1
X
Configuration
Reserved
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Divider Chain Reset
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Table 38. Periodic Interrupt Rate Encoding
Revision 1.2
Rate Select
3210
Periodic Interrupt
Rate (ms)
0000
No interrupts
0001
3.906250
7
0010
7.812500
8
0011
0.122070
2
0100
0.244141
3
0101
0.488281
4
0110
0.976562
5
0111
1.953125
6
1000
3.906250
7
1001
7.812500
8
1010
15.625000
9
1011
31.250000
10
1100
62.500000
11
1101
125.000000
12
1110
250.000000
13
1111
500.000000
14
155
Divider Chain
Output
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8.3.14 RTC Control Register B (CRB)
Power Well:VPP
Location: Index 0Bh
Type:
R/W
Bit
7
6
5
4
3
2
1
0
Name
SETMODE
PIE
AIE
UIE
Reserved
DATMODE
HRMODE
DSVMODE
Reset
0
0
0
0
0
0
0
0
.
Bit
7
Description
SETMODE (Set Mode). This bit is reset at VPP power-up reset only.
0: Timing updates occur normally
1: User copy of time is frozen, allowing the time registers to be accessed whether or not an update occurs
6
PIE (Periodic Interrupt Enable). Bits 3-0 of the CRA register determine the rate at which this interrupt is
generated. It is cleared to 0 on RTC reset (i.e., VSB Power-Up reset) or when RTC is disabled.
0: Disabled
1: Enabled
5
AIE (Alarm Interrupt Enable). This interrupt is generated immediately after a time update in which the seconds,
minutes, hours, date and month time equal their respective alarm counterparts. It is cleared to 0 as long as bit
7 of the CRD register reads 0.
0: Disabled
1: Enabled
4
UIE (Update Ended Interrupt Enable). This interrupt is generated when an update occurs. It is cleared to 0 on
RTC reset (i.e., VSB Power-Up reset) or when the RTC is disabled.
0: Disabled
1: Enabled
3
Reserved. This bit is defined as “Square Wave Enable” by MC146818 and is not supported by the RTC. It is
always read as 0.
2
DATMODE (Data Mode). This bit is reset at VPP power-up reset only.
0: BCD format enabled
1: Binary format enabled
1
HRMODE (Hour Mode). This bit is reset at VPP power-up reset only.
0: 12-hour format enabled
1: 24-hour format enabled
0
DSVMODE (Daylight Saving). This bit is reset at VPP power-up reset only.
0: Disabled
1: Enabled:
In the spring, time advances from 1:59:59 AM to 3:00:00 AM on the first Sunday in April.
In the fall, time returns from 1:59:59 AM to 1:00:00 AM on the last Sunday in October.
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8.3.15 RTC Control Register C (CRC)
Power Well:VPP
Location: Index 0Ch
Type:
RO
Bit
7
6
5
4
Name
IRQF
PIF
AF
UF
Reset
0
0
0
0
3
2
1
0
0
0
Reserved
0
0
Bit
Description
7
IRQF (IRQ Flag). This bit mirrors the value on the interrupt output signal. When interrupt is active, this bit is 1.
To clear this bit (and deactivate the interrupt pin), perform a read on the CRC register. This read also clears flag
bits UF, AF and PF.
0: IRQ inactive
1: IRQ active, according to the equation: ((UIE and UF) or (AIE and AF) or (PIE and PF)); see Section 8.3.14 on
page 156
6
PIF (Periodic Interrupt Flag). This bit is cleared to 0 on RTC reset (i.e., hardware or software reset) or when
the RTC is disabled. In addition, this bit is cleared to 0 when this register is read.
0: No transition occurred on the selected tap since the last read
1: Transition occurred on the selected tap of the divider chain
5
AIF (Alarm Interrupt Flag). This bit is cleared to 0 as long as bit 7 of the CRD register is reads 0. In addition,
this bit is cleared to 0 when this register is read.
0: No alarm detected since the last read
1: Alarm condition detected
4
UIF (Update Ended Interrupt Flag). This bit is cleared to 0 on RTC reset (i.e., hardware or software reset) or
the RTC disabled. In addition, this bit is cleared to 0 when this register is read.
0: No update occurred since the last read
1: Time registers updated
3-0
Reserved.
8.3.16 RTC Control Register D (CRD)
Power Well: VPP
Location: Index 0Dh
Type:
RO
Bit
7
Name
Valid RAM
and Time
Reset
0
6
5
4
3
2
1
0
0
0
0
Reserved
0
0
0
0
Bit
Description
7
Valid RAM and Time. This bit senses the voltage that feeds the RTC (VSB or VBAT) and indicates if the voltage
dropped below the specified minimum value VBATMIN. If the voltage is too low, the RTC contents (time/calendar
registers and CMOS RAM) are not valid. Reading this bit enables its updating by the status of the RTC supply
voltage.
0: RTC contents not valid
1: RTC contents (time/calendar registers and CMOS RAM) are valid
6-0
Revision 1.2
Reserved.
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8.3.17 Date-of-Month Alarm Register (DOMA)
Power Well:VPP
Location: Programmable Index through DOMAO register
Type:
R/W
Bit
7
6
5
Name
4
2
1
0
0
0
0
Date-of-Month Alarm Data
Reset
1
1
0
Bit
7-0
3
0
0
Description
Date-of-Month Alarm Data. Values may be 01 to 31 in BCD format or 01 to 1F in Binary format.
When bits 7 and 6 are both set to one (‘11’), unconditional match is selected (default).
8.3.18 Month Alarm Register (MONA)
Power Well: VPP
Location: Programmable Index through MONAO register
Type:
R/W
Bit
7
6
5
Name
3
2
1
0
0
0
0
2
1
0
0
0
0
Month Alarm Data
Reset
1
1
0
Bit
7-0
4
0
0
Description
Month Alarm Data. Values may be 01 to 12 in BCD format or 01 to 0C in Binary format.
When bits 7 and 6 are both set to one (‘11’), unconditional match is selected (default).
8.3.19 Century Register (CEN)
Power Well:VPP
Location: Programmable Index through CENO register
Type:
R/W
Bit
7
6
5
Name
3
Century Data
Reset
0
Bit
7-0
4
0
0
0
0
Description
Century Data. Values may be 00 to 99 in BCD format or 00 to 63 in Binary format.
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8.3.20 BCD and Binary Formats
Parameter
8.4
BCD Format
Binary Format
Seconds
00 to 59
00 to 3B
Minutes
00 to 59
00 to 3B
Hours
12-Hour mode: 01 to 12 (AM)
81 to 92 (PM)
24-Hour mode: 00 to 23
12-Hour mode: 01 to 0C (AM)
81 to 8C (PM)
24-Hour mode: 00 to 17
Day
01 to 07 (Sunday = 01)
01 to 07
Date
01 to 31
01 to 1F
Month
01 to 12 (January = 01)
01 to 0C
Year
00 to 99
00 to 63
Century
00 to 99
00 to 63
USAGE HINTS
1. Read bit 7 of the CRD register at each system power-up to validate the contents of the RTC registers and the CMOS
RAM. When this bit is 0, the contents of these registers and the CMOS RAM are questionable. This bit is reset when the
backup battery voltage is below the minimum specified battery voltage, VBATMIN. Although the RTC oscillator may function properly and the register contents may be correct at lower voltages than VBATMIN, this bit is reset because correct
functionality cannot be guaranteed. System BIOS may use a checksum method to revalidate the contents of the CMOSRAM. The checksum byte must be stored in the CMOS RAM.
2. To maintain valid time and register information, change the backup battery while normal operating power is on and not
while in Backup mode; however, if a low leakage capacitor is connected to VBAT, the battery can also be changed in
Backup mode.
3. A rechargeable NiCd battery may be used instead of a non-rechargeable Lithium battery. This is the preferred solution
for portable systems, where small size components is essential.
4. A supercap capacitor may be used instead of the normal Lithium battery. In a portable system, the VSB voltage is usually
present because the power management stops the system before its voltage falls. The supercap capacitor in the range
of 0.047-0.47F will supply the power during the battery replacement.
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8.5
(Continued)
RTC REGISTER BITMAP
Register
Bits
Offset Mnemonic
7
6
5
4
3
2
00h
SEC
Seconds Data
01h
SECA
Seconds Alarm Data
02h
MIN
Minutes Data
03h
MINA
Minutes Alarm Data
04h
HOR
Hours Data
05h
HORA
Hours Alarm Data
06h
DOW
Day-of-Week Data
07h
DOM
Date-of-Month Data
08h
MON
Month Data
09h
YER
Year Data
0Ah
CRA
Update in
Progress
0Bh
CRB
SETMODE
PIE
AIE
UIE
0Ch
CRC
IRQF
PIF
AIF
UIF
0Dh
CRD
Valid RAM
and Time
Prog.
DOMA
Date-of-Month Alarm Data
Prog.
MONA
Month Alarm Data
Prog.
CEN
Century Data
8.6
Divider Chain Control
1
0
Periodic Interrupt Rate Select
Reserved
DATMODE HRMODE DSVMODE
Reserved
Reserved
RTC GENERAL-PURPOSE RAM MAP
Table 39. Standard RAM Map
Index
0Eh - 7Fh1
Description
Battery-backed General-purpose 111-byte RAM.
1. Battery-backed 111-byte RAM (114−3 overlaid registers).
Table 40. Extended RAM Map
Index
00h - 7Fh
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Description
Battery-backed General-purpose 128-byte RAM.
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PC8741x
9.0
System Wake-Up Control (SWC)
OVERVIEW
The System Wake-Up Control supports the ACPI Specification, Revision 1.0b, Feb. 2, 1999.
The SWC functional block receives external events from the system and internal events from the functional blocks of the
PC8741x device. Using these events together with the ACPI sleep state information supplied by the software or by external
signals, the SWC generates system interrupts (IRQ, SIOSMI) and Power Management signals (SIOSCI, ONCTL,
PWBTOUT). In addition, it controls two LED indicators and contains two Power Active timers and a watchdog timer.
The SWC receives the following external events:
•
•
•
•
•
Sixteen VSB-powered General-Purpose Input/Output events (GPIOE10-17 and GPIOE40-47).
Two Modem Ring events (RI1 and RI2).
Mouse movement and button pressing events (via MCLK and MDAT).
Advanced key pressing events from the Keyboard (via KBCLK and KBDAT).
Power and Sleep buttons pressing events (PWBTIN and SLBTIN).
The SWC receives the following internal events:
•
•
•
RTC alarm event.
•
•
Watchdog time-out event.
Keyboard and Mouse interrupt event (IRQ).
Module interrupt (IRQ) event from the Legacy functional blocks (FDC, Parallel Port and Serial Ports 1 and 2) and from
the XIRQ pin (mapped to IRQ).
Software VDD On and VDD Off requests.
The SWC receives sleep state information either by software (writing the ACPI, SLP_TYPx and SLP_EN bits) or via the
SLPS3 and SLPS5 pins from an external ACPI controller. In Legacy Power Button mode, the Power button can generate an
S5 sleep state.
The SWC implements three ACPI fixed register groups: PM1 Event Group (block b), PM1 Control Group (block b) and General-Purpose Event 1 Group. The unimplemented functions in the first two groups (block b) are supported by returning zero.
The SWC generates the system interrupts, IRQ (via SERIRQ) and SMI (via SIOSMI), based on the external and internal
events (except GPIOE events) and on the routing information written into its registers. GPIOE events, the exception, are
routed to the IRQ and SMI by the GPIO functional block. The IRQ and SMI interrupts are independent of the sleep state.
The SWC generates the Power Management signals (the ACPI interrupt—SIOSCI, the ONCTL signal for the VDD power
supply control and the PWBTOUT signal, which is used by an external ACPI controller) based on the same external and
internal events, on routing information and on the current sleep state. The ONCTL and PWBTOUT signals are enabled according to the current sleep state, based on information written into the SWC registers. In Legacy Power Button mode,
ONCTL is controlled by the Power button external event. The ACPI-compatible SCI interrupt is independent of the current
sleep state.
Two functions bypass event routing by the sleep state mechanism and directly affect the ONCTL and PWBTOUT signals.
These are:
●
Power Button Override, which forces the VDD power supply off if the Power button is continuously pressed for more
than four seconds.
●
Crowbar, which releases the VDD Power On request if the VDD power supply refuses to turn on.
In addition, the SWC controls two LED indicators. Control is based on the current sleep state information or on the status of
the VSB and VDD power. The SWC also includes two Power Active timers that measure the time the VSB and VDD power
supplies are active (On).
Another function included in the SWC is the watchdog timer. If the watchdog is not retriggered by one of its event sources
and reaches time-out, it generates an SMI (via SIOSMI) or an SCI (via SIOSCI) interrupt. In addition, the watchdog generates a pulse at the WDO pin.
The SWC contains two Power Management registers that allow the software to disable each Legacy module and to TRISTATE its outputs in a centralized manner.
The SWC module is powered by the VPP plane (see Section 2.1 on page 32). However, during Power Fail state (i.e., when
only VBAT is present), the module functions (event detection, output generation and time counting) are disabled and only the
VPP-powered registers retain their data.
Figure 47 shows the simplified block diagram of the SWC functional block.
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9.0 System Wake-Up Control (SWC)
1 Min. Clock
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Watchdog
WDO
Interrupt
Routing
Control
31
Internal
Events
7
External
Events
24
SWC
Event
Status
Debounce
and
Detection
SCI
Interrupt
Enable
Legacy
Power
Button
SLP_TYPx
SLP_EN
4
SPLS3
SLPS5
2
Power Button
VDD, VSB Status
SIOSMI
SIOSCI
Power Button
S5
Sleep
State
Converter
IRQ
Current Sleep State
Power
Management
Signals
Enable
4 Sec.
Override
and
Crowbar
LED
Control
2
ONCTL
PWBTOUT
LED1
LED2
Power Active Timers
1 Hz Clock
Figure 47. SWC Block Diagram
9.2
9.2.1
FUNCTIONAL DESCRIPTION
External Events
General-Purpose Input/Output Events
The PC8741x devices support 16 VSB-powered General-Purpose Input/Output events through ports GPIOE10-17 and
GPIOE40-47. VDD- and VSB-powered signals can be connected to the GPIO pins to become sources of external events. A
VDD-powered signal used to generate an event is internally disabled (for event generation) while VDD power is off and also
for 1 second after VDD power is restored. This prevents the detection of false events during power transitions and while the
signal driver is unpowered. For the same reasons, a VSB-powered signal used to generate an event is enabled only 1 second
after the VSB power is on. (When VSB is off, the whole SWC module is disabled.)
Each GPIOE pin has programmable polarity and an optional 16 ms debouncer (see Figure 48). The debouncer is enabled
after the reset but can be disabled by software.
A GPIO event can generate the system interrupts (IRQ and SMI) if the event is enabled and routed to the specific interrupt.
The status, event enable and pending event routing bits to IRQ and SMI are implemented in the GPIO Ports module (see
Section 7.3 on page 137). The status bit is set when an event of the programmed type (edge or level) is detected.
A GPIO event can also generate the Power Management signals (the SCI interrupt, the ONCTL power supply control and
the PWBTOUT signal). The status, event enable and wake-up state enable bits are implemented in the SWC module (see
Figures 48 and 50).
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An active level-type event sets the status bit in registers GPE1_STS_0 for ports GPIOE10-17 and GPE1_STS_1 for ports
GPIOE40-47 (see Sections 9.4.8 and 9.4.9 on pages 209ff.). The status bit remains set even when the event becomes inactive. The status bit is cleared only when the software writes ‘1’ to the bit. If the event is still active when software writes
‘1’, the status bit remains set.
After changing the GPIOExx pin multiplexing, clear the relevant bits in the GPE1_STS_0 and GPE1_STS_1 registers, to
prevent false events (caused by the pin multiplexing switch) from generating a wake-up event.
GPIO
Status
Routing
Control
IRQ
SIOSMI
Event
Enable
GPIO Ports Module
GPIO Ports Module
0
Input
Debouncer
Set
1
SWC
GPIO
Status
SWC
GPIO
Event
Status
Read
Reset
Pin
Write 1 to Clear
Bit 6
Event
Debounce
Enable
Bit 5
Event Polarity
Internal
Bus
GPIO Pin Configuration Register 1
(GPCFG1)
Figure 48. GPIO Events
Modem Ring Events
High-to-low transitions on RI1 or RI2 indicate the detection of a ring signal by an external modem connected to Serial Port
1 or Serial Port 2, respectively. The transitions on RI1 and RI2 are detected by the RI Wake-up Detector powered by VSB,
which works independently of the Serial Port 1 or Serial Port 2 modules (powered by VDD).
A detected RI1 or RI2 transition sets the RI1_EVT_STS or RI2_EVT_STS status bits in the GPE1_STS_2 register (see Section 9.4.10 on page 210). A status bit is cleared only when the software writes ‘1’ to it.
The transition detection from RI1 and RI2 is enabled (for event generation) 1 second after the VSB power is on. This prevents
the detection of false events during VSB power-On transitions.
Mouse Wake-Up Event
The mouse wake-up event is detected by the Keyboard/Mouse Wake-up Detector, which monitors the MCLK and MDAT signals. Since the detection mechanisms for keyboard and mouse events are independent, they can be operated simultaneously. Moreover, the Keyboard signals may be swapped with the Mouse signals by setting the SWAP_KBMS bit in the
SWC_CTL register (see Section 9.3.10 on page 187). This bit must be set to the same value as the Swap bit in the KBC
Configuration register (see Section 3.13.3 on page 69). The Keyboard/Mouse Wake-up Detector is powered by VSB and
works independently of the Keyboard Controller module (powered by VDD).
The mouse event detection mechanism can be programmed to detect either a mouse click or movement, a specific mouse
click (left or right) or a double-click. To program which mouse action causes an event detection, set the MSEVCFG field in
the PS2CTL register (see Section 9.3.17 on page 194) to the required value.
A detected mouse event sets the MS_EVT_STS status bit in the GPE1_STS_2 register (see Section 9.4.10 on page 210).
The status bit is cleared only when the software writes ‘1’ to it.
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9.0 System Wake-Up Control (SWC)
(Continued)
The mouse event detection from MCLK and MDAT is enabled (for event generation) 1 second after the VSB power is on.
This prevents the detection of false events during Mouse VSB power-On transitions. In addition, if the Keyboard/Mouse Power Control feature (see Section 9.2.10 on page 175) is enabled by setting the VDDFLMUX bit to ‘1’ (in the SIOCF2 register;
see Section 3.7.3 on page 50), mouse event detection is disabled for 2 seconds from the moment the VDD power is turned
off. If this feature is disabled (VDDFLMUX = ‘0’ in SIOCF2) mouse event detection is enabled regardless of the VDD power
status; however, the wake-up becomes effective (VDD power is turned on) only 1 second after the VDD power was turned off.
Keyboard Wake-Up Events
Keyboard wake-up events are also detected by the Keyboard/Mouse Wake-up Detector, which monitors the KBCLK and
KBDAT signals. Since the detection mechanisms for keyboard and mouse events are independent, they can be operated
simultaneously. Moreover, the Keyboard signals may be swapped with the Mouse signals, as explained in the Mouse WakeUp Event section (page 163). The Keyboard/Mouse Wake-up Detector is powered by VSB and works independently of the
Keyboard Controller module (powered by VDD).
The keyboard event detection mechanism can be programmed to detect:
●
Any keystroke (Special Key Sequence mode).
●
A specific programmable sequence of up to eight alphanumeric keystrokes (Password mode).
●
Any programmable sequence of up to eight bytes of data received from the keyboard (Special Key Sequence mode).
●
Up to three programmable, Power Management keys concurrently available, each including a sequence of up to three
bytes of data received from the keyboard (Power Management Key mode).
The Keyboard/Mouse Wake-up Detector has three operation modes:
●
Password mode.
●
Special Key Sequence mode.
●
Power Management Key mode.
Up to eight Keyboard Data registers (PS2KEY0 to PS2KEY7) are used to define which keyboard data string generates an
event. Since the same set of registers is used by each operation mode, only one mode can be selected at a time.
In the modes involving more than one keystroke, the maximum delay allowed between pressing two consecutive keys is 4
seconds. A longer delay is interpreted by the Wake-up Detector as the beginning of a new sequence of keystrokes, which
causes the present sequence to be discarded. In all operation modes, pressing a wrong key requires a recovery time of 4
seconds, before a new (correct) sequence may be recognized.
Password Mode. In Password mode, the Make and Break bytes transmitted by the keyboard are discarded, and only the
keystroke data bytes are compared with those programmed in the PS2KEY0 to PS2KEY7 registers. If the two sets are equal,
a keyboard event that sets the KBD_EVT1_STS bit in the GPE1_STS_2 register is detected (see Section 9.4.10 on
page 210). The status bit is cleared only when the software writes ‘1’ to it. To simplify the detection mechanism, only keys
with a keystroke data of one byte can be included in the sequence to be detected. To program the Keyboard/Mouse Wakeup Detector to operate in Password mode, proceed as follows:
1. Set KBDMODE bit in the KBDWKCTL register to ‘0’ (see Section 9.3.16 on page 193).
2. Set KBEVCFG field in the PS2CTL register to a value that indicates the desired number of alphanumeric keystrokes in
the sequence. The programmed value = the number of keystrokes + 7. For example, to detect a sequence of two keys,
set KBEVCFG to 9h.
3. Program the appropriate subset of the PS2KEY0-PS2KEY7 registers in sequential order with the data bytes of the keys
in the sequence. For example, if there are three keys in the sequence and the keystroke data of these keys are 05h (first),
50h (second) and 44h (third), program PS2KEY0 to 05h, PS2KEY1 to 50h and PS2KEY2 to 44h (the scan codes are
only examples).
Special Key Sequence Mode. In Special Key Sequence mode, all the bytes transmitted by the keyboard are compared
with those programmed in the PS2KEY0 to PS2KEY7 registers. These include also the Make and Break bytes. If the two
sets are equal, a keyboard event is detected, as explained in Password Mode, above. This mode enables the detection of
any sequence of keystrokes, including keys as “Shift” and “Alt”. To program the Keyboard/Mouse Wake-up Detector to operate in Special Key Sequence mode, proceed as follows:
1. Set KBDMODE bit in the KBDWKCTL register to ‘0’ (see Section 9.3.16 on page 193).
2. Set KBEVCFG field in the PS2CTL register to a value that indicates the desired number of keystrokes in the sequence.
The programmed value = the number of keystrokes + 1. For example, to detect a sequence of three received bytes (i.e.,
one keystroke), set KBEVCFG to 2h.
3. Program the appropriate subset of the PS2KEY0-PS2KEY7 registers in sequential order with the data bytes that comprise the sequence. For example, if the number of bytes in the sequence is four, and the values of these bytes are E0h
(first), 5Bh (second), E0h (third) and DBh (fourth), program PS2KEY0 to E0h, PS2KEY1 to 5Bh, PS2KEY2 to E0h and
PS2KEY3 to DBh (the byte values are only examples).
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Special Key Sequence mode also enables detection of a specific single keystroke. To program the Keyboard/Mouse Wakeup Detector to wake-up on a single keystroke, perform the following sequence:
1. Set KBDMODE bit in the KBDWKCTL register to ‘0’ (see Section 9.3.16 on page 193).
2. Set KBEVCFG field in the PS2CTL register to 0001b.
3. Program the PS2KEY0 and PS2KEY1 registers to 00h. This forces the detector to ignore the values of incoming data,
thus causing it to detect a keyboard event on the single keystroke.
Power Management Mode. In Power Management Key mode, the PS2KEY0 to PS2KEY7 register bank is divided into three
groups of registers: PS2KEY0 to PS2KEY2, PS2KEY3 to PS2KEY5 and PS2KEY6 to PS2KEY7. Each group can be programmed with different data bytes, allowing the bytes transmitted by the keyboard to be compared simultaneously with three
keystroke sequences. If the bytes transmitted by the keyboard (including Make and Break) are equal to the data bytes in
one register group, the related keyboard event is detected. The detection of Keyboard Event 1 (data in PS2KEY0PS2KEY2) sets the KBD_EVT1_STS bit, the detection of Keyboard Event 2 (data in PS2KEY3-PS2KEY5) sets the
KBD_EVT2_STS bit and the detection of Keyboard Event 3 (data in PS2KEY6-PS2KEY7) sets the KBD_EVT3_STS bit. All
three status bits are in the GPE1_STS_2 register (see Section 9.4.10 on page 210). Each status bit is cleared only when
the software writes ‘1’ to the bit. This mode enables the detection of any sequence of keys.
Note: Do not use a byte sequence that is a “subset” of the byte sequence of another (“superset”) Power Management key
event. The subset sequence has fewer bytes (set by the EVTxCFG fields in the KBDWKCTL register) than the superset sequence; the bytes contained in the subset sequence (as programed in the PS2KEY0 to PS2KEY7 registers) are identical to
the respective bytes of the superset sequence.
To program the Keyboard/Mouse Wake-up Detector to operate in Power Management Key mode, proceed as follows:
1. Set KBDMODE bit in the KBDWKCTL register to ‘1’ (see Section 9.3.16 on page 193).
2. Set each event configuration field (EVT1CFG, EVT2CFG and EVT3CFG) in the KBDWKCTL register to a value that indicates the desired number of keystroke data bytes in the sequence, for each event. For example, to detect a sequence
of two received bytes, set EVTxCFG to 2h.
3. Program each group of the PS2KEY0-PS2KEY7 registers in sequential order with the data bytes of the keys in the sequence for each event.
Event Generation. Keyboard event detection from KBCLK and KBDAT is enabled (for event generation) 1 second after the
VSB power is on. This prevents the detection of false events during Keyboard VSB power-On transitions. In addition, if the
Keyboard/Mouse Power Control feature (see Section 9.2.10 on page 175) is enabled by setting the VDDFLMUX bit to ‘1’ (in
the SIOCF2 register; see Section 3.7.3 on page 50), keyboard event detection is disabled for 2 seconds from the moment
the VDD power is turned off. If this feature is disabled (VDDFLMUX = ‘0’ in SIOCF2) keyboard event detection is enabled
regardless of the VDD power status; however, the wake-up becomes effective (VDD power is turned on) only 1 second after
the VDD power was turned off.
Power Button Event
A low level signal at PWBTIN indicates that the Power button was pressed. This input, filtered by a 16 ms debouncer, is
bridged to the PWBTOUT output to synchronize an external ACPI controller (which is optional).
A detected low level signal sets the PWRBTN_STS status bit in the PM1b_STS_HIGH register (see Section 9.4.3 on
page 205) and the PWBT_EVT_STS status bit in the GPE1_STS_2 register (see Section 9.4.10 on page 210). Note, however, that the PWRBTN_STS status bit is not set if the PWRBTN_EV_DIS bit in the ACPI_CFG register is reset (see Section
9.3.32 on page 201). This functionality is required for ACPI compatibility in case the Power button event is implemented in
an (optional) external ACPI controller. Both status bits are cleared when the software writes ‘1’ to any of them. If a low level
is present at the input when software writes ‘1’ to the status bit, the status bit remains set. The low level detection from PWBTIN is enabled (for event generation) 1 second after the VSB power is on. This prevents the detection of false events during
VSB power-On transitions.
The Power button event is always enabled for wake-up in any sleep state. In addition, the Power button event is the only
wake-up event available after a Power Button Override or a Crowbar condition (see Section 9.2.6 on page 172).
In Legacy Power Button mode (LEGACY_PWBT = 1 in the PWONCTL register; see Section 9.3.11 on page 188), a lowlevel signal at PWBTIN, when the VDD power is on, generates an S45 current sleep state (see Section 9.2.3 on page 167),
which sets ONCTL to Off. In addition, the PWRBTN_STS and the PWBT_EVT_STS status bits are reset in this situation. In
this mode, the Power button event is the only wake-up event available after ONCTL is turned off.
Sleep Button Event
A low level on SLBTIN indicates the Sleep button was pressed. This input is also filtered by a 16 ms debouncer.
A detected low level sets the SLPBTN_STS status bit in the PM1b_STS_HIGH register (see Section 9.4.3 on page 205) and
the SLBT_EVT_STS status bit in the GPE1_STS_2 register (see Section 9.4.10 on page 210). Note, however, that the
SLPBTN_STS status bit is not set if the SLPBTN_EV_DIS bit in the ACPI_CFG register is reset (see Section 9.3.32 on
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9.0 System Wake-Up Control (SWC)
(Continued)
page 201). This functionality is required for ACPI compatibility in case the Sleep Button event is implemented in an (optional)
external ACPI controller. Both status bits are cleared when the software writes ‘1’ to either of them. If a low level is present
at the input when software writes ‘1’ to the status bit, the status bit remains set.
The low level detection from SLBTIN is enabled (for event generation) 1 second after the VSB power is on. This prevents the
detection of false events during VSB power-On transitions.
9.2.2
Internal Events
RTC Alarm Event
An RTC Alarm event is generated by the RTC functional block. An asserted RTC Alarm sets the RTC_STS status bit in the
PM1b_STS_HIGH register (see Section 9.4.3 on page 205) and the RTC_EVT_STS status bit in the GPE1_STS_3 register
(see Section 9.4.11 on page 211). Note, however, that the RTC_STS status bit is not set if the RTC_EV_DIS bit in the
ACPI_CFG register (see Section 9.3.32 on page 201) is reset. This functionality is required for ACPI compatibility in case
the RTC Alarm event is implemented in an (optional) external ACPI controller. Both status bits are cleared when the software
writes ‘1’ to any of them. If the RTC Alarm is asserted when software writes ‘1’ to the status bit, the status bit remains set.
KBC P12 Event
A KBC P12 event is detected when the P12 port of the Keyboard Controller (KBC) functional block is set to ‘1’. For this to
happen, the KBC module must be enabled (see Section 3.3.1 on page 43). Since the Keyboard Controller functional block
is powered by VDD, a P12 event can occur only when VDD is present.
A high level at the P12 port of the KBC sets the P12_EVT_STS status bit in the GPE1_STS_3 register (see Section 9.4.11
on page 211). The status bit is cleared only when the software writes ‘1’ to it. If the P12 port is at high level when software
writes ‘1’ to the status bit, the status bit remains set.
Keyboard and Mouse IRQ Events
Keyboard and Mouse IRQ events are detected when either the Keyboard IRQ or Mouse IRQ is asserted.
To enable the IRQ of a logical device to generate an IRQ event, the associated Enable bit (bit 4 of the configuration register
at index 70h; see Section 3.2.3 on page 40) must be set to ‘1’. Since the Keyboard Controller (KBC) functional block is powered by VDD, a Keyboard or Mouse IRQ event can occur only when VDD is present.
An active (level-type) Keyboard IRQ event sets the KBD_IRQ_STS status bit and an active Mouse IRQ event sets the
MS_IRQ_STS status bit. Both status bits are in the GPE1_STS_3 register (see Section 9.4.11 on page 211). A status bit is
cleared only when the software writes ‘1’ to it. If the IRQ event is active when software writes ‘1’ to the status bit, the status
bit remains set.
The ROM code used for the Keyboard Controller generates active high Keyboard and Mouse interrupts, used by the SWC
module.
Module IRQ Event
A Module IRQ event is detected when one of the Legacy modules (FDC, Parallel Port, Serial Port 1 or 2) asserts its IRQ or
when an active level is detected at the XIRQ pin (PC87416 and PC87417).
To enable the IRQ of a logical device to generate an IRQ event, the associated Enable bit (bit 4 of the configuration register
at index 70h; see Section 3.2.3 on page 40) must be set to ‘1’. Since the Legacy modules are powered by VDD, they can
assert IRQ only when VDD is present.
To enable an active level at the XIRQ pin (PC87416 and PC87417) to generate an event, both the IRQEN and the PWUREN
bits in the XIRQC register (see Section 5.4.4 on page 110) must be set to ‘1’. Since the XIRQ interrupt belongs to the X-Bus
Extension functional block powered by VSB, an active level at the XIRQ pin can also generate a Module IRQ event when
VDD is off. The XIRQ detection enabled (for event generation) 1 second after the VSB power is on. This prevents the detection of false events during VSB power-On transitions.
The MOD_IRQ_STS status bit in the GPE1_STS_3 register is set by an IRQ that is asserted by one of the Legacy modules
or by an active level at the XIRQ pin (see Section 9.4.11 on page 211). The status bit is cleared only when the software
writes ‘1’ to it. If the Module IRQ event is active when software writes ‘1’ to the status bit, the status bit remains set.
Watchdog Time-Out Event
A watchdog time-out event is generated by the watchdog function in the SWC module (see Section 9.2.9 on page 174). An
asserted watchdog event sets the WDO_EVT_STS status bit in the GPE1_STS_3 register (see Section 9.4.11 on
page 211). A status bit is cleared only when the software writes ‘1’ to it. If the watchdog event is asserted when software
writes ‘1’ to the status bit, the status bit remains set.
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Software Power On/Off Events
A Software Power event is triggered when software writes ‘1’ to the SW_ON_CTL bit (for Power On) or to the SW_OFF_CTL
bit (for Power Off). After being written ‘1’, these bits automatically return to their default value of ‘0’. Both bits are located in
the SWC_CTL register (see Section 9.3.10 on page 187). If the VDD power is not preset, these two bits can be written ‘1’
through the ACCESS.bus (PC87413 and PC87417), which is powered by VSB.
A Software Power On event sets the SW_ON_STS status bit and a Software Power Off event sets the SW_OFF_STS status
bit. Both bits are in the GPE1_STS_3 register (see Section 9.4.11 on page 211). A status bit is cleared only when the software writes ‘1’ to it.
9.2.3
Sleep States
Compliance with ACPI Specification, Revision 1.0b, Feb. 2, 1999 requires the PC8741x devices to recognize the six system
states: Working (G0/S0), Sleeping (G1-S1 to G1-S4) and Soft-off (G2/S5). The system state is written by the host into the
SLP_TYPx field of the PM1b_CNT_HIGH register (see Section 9.4.7 on page 208) and updated by writing a ‘1’ to the
SLP_EN bit in the same register.
The value written in the SLP_TYPx field is translated to one of the internal states (S0 to S5), using the data programmed in
the Sleep Type Encoding registers. This translation mechanism allows the software to use any SLP_TYPx encoding scheme.
Each of the six Sleep Type Encoding registers (S0_SLP_TYP to S5_SLP_TYP; see Section 9.3.30 on page 199) contains
a 3-bit SLP_ENC_TYP field. The software must program this field with the SLP_TYPx code used for the internal state represented by the register. The software must program all six registers even if not all the system states are supported.
The SWC uses three current sleep states to control its operation. The six decoded internal states are converted to the current
sleep states as follows (see Section 9.2.5 for the usage of the current sleep states):
●
S0, S1 and S2 are converted to the S12 current state; this is the active state for the PC8741x device, with VDD and
VSB power supplies being On.
●
S3 is converted to the S3I current state; in this sleep state, the VSB power is On but the VDD power supply can be
On or Off, according to the setting of the S3I_VDD_ON bit in the SLP_ST_CFG register (see Section 9.3.31 on
page 200).
●
S4 is converted to either S3I or S45 current states, according to the setting of the S4_SELECT bit in the
SLP_ST_CFG register (see Section 9.3.31 on page 200).
●
S5 is converted to the S45 current state; in this sleep state, the VSB power is On but the VDD power supply is Off.
If an active (optional) ACPI controller is located in an external device, the SLPS3 and SLPS5 signals are used to determine
the system sleep state. This option is selected by setting both the EXTSTMUX bit in the SIOCF3 register (see Section 3.7.4
on page 51) and the EXT_ST_SELECT bit in the SLP_ST_CFG register (see Section 9.3.31 on page 200) to ‘1’. Table 41
shows how the levels of the SLPS3 and SLPS5 signals are converted to current sleep states.
Table 41. SLPS3, SLPS5 Conversion to Current Sleep States
SLPS3
SLPS5
Current Sleep State
1
1
S12
0
1
S3I
0
0
S45
1
0
Reserved
Note: The internal and external sleep state modes are mutually exclusive. The internal sleep state register
(PM1b_CNT_HIGH) should not be used when External Sleep State mode is selected. Similarly, pins SLPS3 and SLPS5
should not be used when Internal Sleep State mode is selected.
The use of the external SLPS3 and SLPS5 signals to determine the current sleep state is enabled 1 second after the VSB
power is on. This prevents the selection of an erroneous current sleep state during VSB power-On transitions.
In Legacy Power Button mode, when the VDD power is on, an S45 current state is generated by a low-level signal at
PWBTIN.
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9.2.4
(Continued)
Interrupt Signals
The SWC generates three system interrupts: IRQ (via SERIRQ), SMI (via SIOSMI) and SCI (via SIOSCI). The IRQ and SMI
interrupts are not related to the ACPI-compatible system control but are based on the external and internal events, each with
its status and enable bit in the SWC module. However, the status and enable bits for the GPIOE events (GPIOE10-17 and
GPIOE40-47) related to IRQ and SMI generation are located in the GPIO functional block (see Section 7.3 on page 137).
SCI is the Power Management interrupt defined by ACPI. Its status and enable bits are all located in the SWC module.
IRQ Interrupt
The external and internal events processed by the SWC for IRQ generation set a status bit in the GPE1_STS_2 and
GPE1_STS_3 registers. Only those events that are allowed to be routed to the IRQ interrupt by the SWC have an associated
enable bit in the GPE1_2IRQ_LOW and GPE1_2IRQ_HIGH registers (see Sections 9.3.4 and 9.3.5 on pages181ff.). When
an enable bit is set, and if the corresponding status bit is set, an active IRQ is generated. The IRQ interrupt is independent
of the system sleep state.
SMI Interrupt
The external and internal events processed by the SWC for SMI generation set a status bit in the GPE1_STS_2 and
GPE1_STS_3 registers. Only those events that are allowed to be routed to the SMI interrupt by the SWC have an associated
enable bit in the GPE1_2SMI_LOW and GPE1_2SMI_HIGH registers (see Sections 9.3.6 and 9.3.7 on pages 183ff.). When
an enable bit is set, and if the corresponding status bit is set, an active SMI is generated. The SMI interrupt is independent
of the system sleep state.
SCI Interrupt
All external and internal events (including GPIOE) are exclusively processed by the SWC to generate the Power Management interrupt, SCI. Each active event sets a status bit in the GPE1_STS_0 to GPE1_STS_3 registers. Three events, the
Power button event, the Sleep button event and the RTC event each have an additional status bit in the PM1b_STS_HIGH
register (PWRBTN_STS, SLPBTN_STS and RTC_STS bits, respectively). Each of the additional status bits is set only if the
PC8741x device is assigned the specific function by the ACPI software (see Sections 9.2.1 and 9.2.2 on pages 162ff.).
For each status bit, the SWC holds an enable bit in the GPE1_EN_0 to GPE1_EN_3 registers (see Sections 9.4.12 to 9.4.15
on pages 213ff.). A set status bit can cause the assertion of the SCI interrupt only when an enable bit is set. Each of the
three events mentioned in the previous paragraph also has additional enable bits in the PM1b_EN_HIGH register (see Section 9.4.5 on page 207). Each additional enable and status bit is reset if the respective bit (PWRBTN_EV_DIS,
SLPBTN_EV_DIS or RTC_EV_DIS) in the ACPI_CFG register is reset (see Section 9.3.32 on page 201). This “dual control”
behavior is required for ACPI compatibility in case one of these events is implemented in an (optional) external ACPI controller. An SCI from one of these dual control functions is generated if at least one enabled status bit (of the pair) is set.
The SCI interrupt is independent of the system sleep state with one exception, the Power button event. When the system is
in a sleep state (S1-S5), a set PWRBTN_STS bit generates an active SCI regardless of the value of the PWRBTN_EN bit.
S0 can be separated from the sleep states (S1-S5) only when the PC8741x device serves as an ACPI controller and the
software writes the system state (SLP_TYPx) in the PM1b_CNT_HIGH register. The bypass of the PWRBTN_EN bit during
sleep states (i.e., a set PWRBTN_STS bit generates SCI regardless of the PWRBTN_EN bit) is therefore available only if
the EXT_ST_SELECT bit in the SLP_ST_CFG register is reset (see Section 9.3.31 on page 200).
When the SCI interrupt is asserted and the system is in a sleep state (S1-S5), the WAK_STS bit of the PM1b_STS_HIGH
register is set. This feature, too, is available only if the EXT_ST_SELECT bit in the SLP_ST_CFG register is reset (the ACPI
controller is implemented by the PC8741x device).
Figure 49 shows the SCI generation by the dual control functions and the behavior of the Power button event as a function
of the sleep state.
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GPE1_STS_2/3
Status
Set
Detected Event
Enable
SCI
Interrupt
GPE1_STS_2/3
Only for
Power Button Event
State S0
PM1b_STS_HIGH
0
Status
1
Set
Reset
From Other
Enabled Events
Enable
ACPI_CFG
Reset
PM1b_EN_HIGH
Disable
Figure 49. Dual Control Functions
9.2.5
Power Management Signals
The SWC generates two Power Management signals: ONCTL, for the VDD power supply control, and PWBTOUT, which is
used by an external ACPI controller. These signals are based on the external and internal events, each with its status and
enable bits in the SWC module (including GPIOE). ONCTL and the PWBTOUT are generated according to the current sleep
state.
Special Power Management functions, either required by the ACPI Specification or inherited from the Legacy Power Management, also affect the ONCTL and PWBTOUT outputs. These functions are described in Section 9.2.6.
Power Supply Control (ONCTL)
Each active external or internal event (including GPIOE) sets a status bit in the GPE1_STS_0 to GPE1_STS_3 registers.
Three events (Power button, Sleep button and RTC alarm) each have an additional status bit in the PM1b_STS_HIGH register. Their behavior is described in the SCI Interrupt section (page 168).
ONCTL generation is independent of the enable bits in the GPE1_EN_0 to GPE1_EN_3 registers. It is also independent of
the three additional enable bits in the PM1b_EN_HIGH register (for Power button, Sleep button and RTC alarm events).
ONCTL is not affected by the Watchdog Status bit (WDO_EVT_STS).
ONCTL is turned off (inactive: ONCTL = high level) according to the current sleep states, S3I and S45 (S12 is the active
state for the PC8741x device and does not influence ONCTL; see Section 9.2.3 on page 167). These current sleep states
are decoded from the value of the SLP_TYPx field of the PM1b_CNT_HIGH register (for EXT_ST_SELECT = 0 in the
SLP_ST_CFG register) or from the levels of the SLPS3 and SLPS5 signals (for EXT_ST_SELECT = 1 in the SLP_ST_CFG
register and EXTSTMUX = 1 in the SIOCF3 register). In Legacy Power button mode, when the VDD power is on, an S45
current state is generated by a low-level signal at PWBTIN, overriding the decoded sleep states.
When the PC8741x device enters the S45 state, it turns the VDD power supply Off by setting ONCTL = 1. The state of the
VDD power supply (On or Off) in S3I state depends on the setting of the S3I_VDD_ON bit in the SLP_ST_CFG register (see
Section 9.3.31 on page 200).
If the PC8741x device is the ACPI controller of the system (EXT_ST_SELECT = 0 in the SLP_ST_CFG register), ONCTL is
turned On by an active wake-up event. This is possible only if the event is enabled for wake-up (in the WK_ST_EN register)
in the current sleep state.
Each external or internal event has its own Wake-Up State Enable register (WK_ST_EN), which is accessed by the software
writing its index value (see Table 48 on page 179) into the WKUPSEL field of the Wake-Up Event Select register
(WK_EVT_SEL; see Section 9.3.2). The currently accessed WK_ST_EN register selects the current sleep states for which
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the related event generates a wake-up (i.e., it turns the VDD power supply On by setting ONCTL = 0). The ONCTL_EN_S3I
and ONCTL_EN_S45 bits enable or disable wake-up by the event when the PC8741x device is in S3I or in S45 current state,
respectively. Only two events lack a Wake-Up State Enable register (WK_ST_EN). These are:
— The watchdog event (flagged by the WDO_EVT_STS bit): this event does not affect ONCTL generation.
— The Power button event (flagged by either the PWBT_EVT_STS bit or the PWRBTN_STS bit): this event unconditionally generates a wake-up (sets ONCTL = 0) when the PC8741x device is in S3I or S45 current states.
In addition, in Legacy Power Button mode (LEGACY_PWBT = 1 in the PWONCTL register), all wake-up events are ignored
(regardless of the bit value in their WK_ST_EN register) after the power supply has been turned off (by setting ONCTL = 1)
in response to a Power button event. In this case, the next Power button event unconditionally generates a wake-up (sets
ONCTL = 0).
Optionally, the system ACPI controller can be located in an external device. To select this option, both the EXT_ST_SELECT
bit in the SLP_ST_CFG register (see Section 9.3.31 on page 200) and the EXTSTMUX bit in the SIOCF3 register (see Section 3.7.4 on page 51) must be set to ‘1’. In this case, ONCTL is turned On when the SLPS3 signal goes high (the system
is in S0 - S2 states). In this mode, ONCTL is independent of any wake-up event, including the Power button event (flagged
by either the PWBT_EVT_STS bit or the PWRBTN_STS bit).
Any valid wake-up event is disabled from reactivating the VDD power supply (by setting ONCTL = 0) for 1 second after the
power supply has been turned off (by setting ONCTL = 1). This feature protects the power supply from repeated on/off
switching if an event (such as Power button) is active for an extended period of time. If the Keyboard/Mouse Power Control
feature (VDDFELL; see Section 9.2.10 on page 175) is enabled by setting the VDDFLMUX bit to ‘1’ (in the SIOCF2 register;
see Section 3.7.3 on page 50), the Keyboard and Mouse wake-up events are disabled from reactivating the VDD for 2 seconds after the power supply has been turned off (by setting ONCTL = 1).
S3I_
VDD_ON
Power Button Override
Crowbar
State S3I
State S45
EXT_ST_
SELECT
SLPS5
Off
Reset
SLPS3
GPE1_STS_0-3
Detected
Status
Event
Set
(one of 31
events)
1 Second
Pulse
ONCTL
Set
State S45
1
ONCTL_
EN_S45
0
State S3I
ONCTL_
EN_S3I
On
Resume
from
Power Fail
From Other
Enabled Events
Figure 50. ONCTL Control
Power Button Output (PWBTOUT)
The PWBTOUT function of the PC8741x device enables the (optional) external ACPI controller to synchronize its operation
to the wake-up events detected by the PC8741x device and to control the VDD power supply.
The Power button input (PWBTIN) is bridged to PWBTOUT regardless of any PC8741x device configuration bits, internal
state or wake-up event. This bridging is also independent of the status of the VDD power supply.
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In addition, a wake-up mechanism can be enabled to trigger a 100 ms pulse at the PWBTOUT output on each valid wakeup event. This wake-up mechanism is routed to the PWBTOUT pulse generator only if the PWBTOUT_MODE bit in the
ACPI_CFG register (see Section 9.3.32 on page 201) is reset.
The PWBTOUT wake-up mechanism is similar to the one described for the ONCTL signal, as follows:
●
It is based on status bits in the GPE1_STS_0 to GPE1_STS_3 registers and in the PM1b_STS_HIGH register (except the PWBT_EVT_STS and the PWRBTN_STS bits).
●
It is not affected by the Watchdog Status bit (WDO_EVT_STS).
●
It is independent of the enable bits in the GPE1_EN_0 to GPE1_EN_3 registers and in the PM1b_EN_HIGH register.
●
It is dependent only on the S3I and S45 current sleep states.
●
Its configuration bits are also located in the WK_ST_EN register, which is accessed by writing the event index value
into the WKUPSEL field of the WK_EVT_SEL register.
The PWBT_EN_S3I and PWBT_EN_S45 bits control the generation of a wake-up pulse on PWBTOUT by an active event
(currently accessed through the WK_EVT_SEL register) when the PC8741x device is in S3I or in S45 current state, respectively.
Any valid wake-up event is disabled from generating a wake-up pulse on PWBTOUT for 1 second after the power supply
has been turned off (by setting ONCTL = 1). If the Keyboard/Mouse Power Control feature (VDDFELL) is enabled by setting
the VDDFLMUX bit to ‘1’ (in the SIOCF2 register; see Section 3.7.3 on page 50), the Keyboard and Mouse wake-up events
are disabled from generating a wake-up pulse for 2 seconds after the power supply has been turned off (by setting ONCTL
= 1).
A PWBTOUT pulse is generated only when the VDD power is not present or when a PWBTIN pulse occurred.
PWBTIN
PWBTIN
Status
Set
Off
State S45
GPE1_STS_0-3
Detected
Event
(one of 30
events;
PWBTN is
separate)
Resume
from
Power Fail
1 Second
Pulse
No_Vdd
Status
Set
PWBT_
EN_S45
State S3I
PWBT_
EN_S3I
PWBTOUT
100 ms
Pulse
PWBTOUT
_MODE
From Other
Enabled Events
4s
Pulse
Crowbar
Figure 51. PWBTOUT Control
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9.2.6
(Continued)
Special Power Management Functions
Three special Power Management functions are provided by the PC8741x device to respond to abnormal system behavior.
These are:
●
Power Button Override, which forces the VDD power supply to be turned off when the software does not respond to
the SCI interrupt.
●
Crowbar, which forces the ONCTL to release the On request, thus protecting an overloaded VDD power supply that
refuses to turn on.
●
Resume from Power Fail, which enables a system to return to a predetermined state when returning from Power Fail
(caused by the mechanical switch or by AC power failure).
These functions bypass the mechanisms described in Section 9.2.5 and thus directly control the ONCTL and PWBTOUT
outputs.
Power Button Override
Whenever the Power button (PWBTIN) is pressed continuously for more than 3.9 seconds, the PC8741x device detects a
Power Button Override condition. The Power button pressing at PWBTIN is replicated at PWBTOUT during these 3.9 seconds. PWBTOUT is then forced active for 0.2 seconds regardless of the actual level at PWBTIN. Thus, the pulse generated
at PWBTOUT has a width of minimum 4.1 seconds, allowing an (optional) external ACPI controller to detect this Power Button Override condition. In addition, at the end of the 4.1 seconds, ONCTL is forced to inactive level (VDD power supply Off).
A Power Button Override condition also resets the PWRBTN_STS bit in the PM1b_STS_HIGH register (set by the Power
button event) and updates the current sleep state of the PC8741x device to S45 (since the software is not capable of doing
it). In addition, it sets the PWR_OVR_STS bit in the SWC_CTL register.
This function bypasses the regular control on the ONCTL and PWBTOUT signals (see Figures 50 and 51).
After a Power Button Override condition, only an active Power button event is allowed to wake-up the system (by setting
ONCTL = 0 and generating a PWBTOUT pulse). However, in order to protect the power supply, ONCTL can go active
(ONCTL = 0) only 1 second after the power supply has been turned off (by setting ONCTL = 1).
In Legacy Power Button mode, when the VDD power is on, pressing the Power button (PWBTIN) forces ONCTL to inactive
level (VDD power supply Off) before a Power Button Override condition is detected. In this case, the PWR_OVR_STS bit is
not set.
Crowbar
When a valid wake-up event or a high SLPS3 signal activates the VDD power supply (by setting ONCTL = 0), the PC8741x
device starts checking the presence of the VDD power. If the VDD power fails to resume for a time period longer than the
Crowbar timeout, the power-on request is aborted (by setting ONCTL = 1). Crowbar timeout is also started if the VDD power
falls while the VDD power supply is On (ONCTL = 0). If the VDD power fails to resume before the timeout period expired, the
VDD power supply is turned off (by setting ONCTL = 1).
After turning the VDD power supply Off (by setting ONCTL = 1), a 4 sec pulse is generated at the PWBTOUT output. This
pulse informs an (optional) external ACPI controller of the occurrence of the Crowbar timeout by simulating a Power Button
Override condition.
This function bypasses the regular control of the ONCTL and PWBTOUT signals (see Figures 50 and 51).
The Crowbar timeout value is selected by the CRBAR_TOUT field in the PWONCTL register (see Section 9.3.11 on
page 188). The equivalent timeout is in the range of 0.5 to 20 seconds (the default value is 20 seconds).
When a Crowbar event is detected, the CROWBAR_STS bit in the SWC_CTL register (see Section 9.3.10 on page 187) is
set.
Only an active Power button event is allowed to retry the activation of the VDD power supply (by setting ONCTL = 0). However,
no retry can take place for 5 seconds after the VDD power supply was turned off (by setting ONCTL = 1) because all wakeup events (including Power button) are disabled for 1 second after the end of the PWBTOUT pulse.
Resume from Power Fail
Whenever a Power Fail condition is detected (i.e., when VDD and VSB power supplies are off), the value of the ONCTL signal
is saved in the LAST_ONCTL bit of the PWONCTL register (see Section 9.3.11 on page 188). When the system exits Power
Fail (i.e., when VSB power is back on), this read-only bit serves as a snapshot of the VDD power supply status before the
power was turned off (by an external agent, such as a mechanical switch).
The WAS_PFAIL bit in the PWONCTL register is set by VSB Power-Up reset (the system exits Power Fail), thus indicating
that a Resume from Power Fail condition occurred. This indication is used by the software to decide if the system woke up
from Power Fail or from a sleep state.
The Resume from Power Fail process starts 1 second after the VSB power is on. This prevents the selection of an erroneous
current sleep state during VSB power-On transitions.
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The RESUME_MD field in the PWONCTL register controls the behavior of the ONCTL and PWBTOUT signals during a Resume from Power Fail condition (see Table 49 on page 189):
•
00b − The state of the ONCTL and PWBTOUT signals is controlled solely by the SLPS3 input generated by an (optional)
external ACPI controller.
If the sleep state control by SLPS3, SLPS5 option is selected by setting both the EXT_ST_SELECT bit in the
SLP_ST_CFG register and the EXTSTMUX bit in the SIOCF3 register to ‘1’, and if SLPS3 = 1 (no sleep), the VDD power
supply is turned on (ONCTL = 0). Otherwise, the VDD power supply remains off. Whenever ONCTL is asserted, a 100
ms pulse is also generated at the PWBTOUT output to inform an (optional) external ACPI controller of the new status of
the VDD power supply.
If the SLPS3, SLPS5 option is not selected (EXT_ST_SELECT bit in the SLP_ST_CFG register and EXTSTMUX bit in
the SIOCF3 register are both ‘0’), the VDD power supply remains off (“Silent mode”).
•
01b − The PC8741x device behaves the same as in the 00b combination.
In addition, if an RTC Alarm event was active during the Power Fail, the VDD power supply is turned on (ONCTL = 0) and
a 100 ms pulse is generated at the PWBTOUT output. This happens regardless of the setting of the EXT_ST_SELECT
and EXTSTMUX bits or of the value of the SLPS3 input.
•
10b − The state of the ONCTL and PWBTOUT signals is controlled solely by the LAST_ONCTL bit of the PWONCTL
register regardless of the setting of the EXT_ST_SELECT and EXTSTMUX bits.
If LAST_ONCTL = 1 (VDD power was on before Power Fail), the VDD power supply is turned on (ONCTL = 0) and a 100
ms pulse is generated at the PWBTOUT output. Otherwise, the VDD power supply remains off.
•
11b − The PC8741x device behaves the same as in the 10b combination.
In addition, if an RTC Alarm event was active during the Power Fail, the VDD power supply is turned on (ONCTL = 0) and
a 100 ms pulse is generated at the PWBTOUT output. This happens regardless of the value of the LAST_ONCTL bit of
the PWONCTL register.
The Resume from Power Fail function bypasses the regular control on the ONCTL and PWBTOUT signals.
After the Resume from Power Fail process ends, the ONCTL and PWBTOUT signals behave as described in Section 9.2.5
and in the Power Button Override and Crowbar sections (page 172).
9.2.7
LED Control
The PC8741x devices support LED indicators for two purposes:
●
Visual indication of the system power state or sleep state.
●
General-purpose visual indication of the software status.
The LEDCFG bit selects the configuration of the LED connection. There are two possible configurations: two regular LEDs
are connected between each pin and ground or VSB (one at LED1 and the other at LED2 pins) or one dual-color LED is
connected between the LED1 and LED2 pins. The LEDPOL bit selects the polarity of the On state at both pins (LED1 and
LED2). The LEDCFG and LEDPOL bits are located in the LEDCTL register (see Section 9.3.12 on page 190). The polarity
of the On state at LED1 and LED2 pins depends on the setting of the LEDCFG and LEDPOL bits (see Table ).
Table 42. LED On Polarity as a Function of LEDCFG and LEDPOL
LEDCFG
LEDPOL
LED1
LED2
Connection
0
0
High
Low
LED1 to LED2
0
1
Low
High
LED2 to LED1
1
0
High
High
LED1 and LED2 to GND
1
1
Low
Low
LED1 and LED2 to VSB
The LED1BLNK and LED2BLNK fields in the LEDBLNK register control the On/Off state or the blinking rate of the LED1 and
LED2 pins, respectively. For each LED pin, a different blink rate can be selected. Different blink rates can also be selected
for the dual-color LED mode (LEDCFG = 0).
The LEDMOD field in the LEDCTL register controls the behavior of the LED1 and LED2 pins in each power state or sleep
state (see Table 50 on page 190):
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•
00b − The behavior of the LED1 and LED2 pins is controlled by software only (through the setting of the LED1BLNK and
LED2BLNK fields), except for the Power Fail state (VSB and VDD off) when both LEDs are Off.
•
01b − The behavior of the LED1 and LED2 pins is controlled by the power states and by software.
In the Power Fail state (VSB and VDD off), both LEDs are Off;
In the Power Off state (VSB on and VDD off), both LEDs blink at a 1 Hz rate, with a 50% duty cycle;
In the Power On state (VSB and VDD on), each LED behaves according to the setting of its LEDxBLNK field.
•
10b − The behavior of the LED1 and LED2 pins is controlled by the S3I sleep state and by software.
In the Power Fail state (VSB and VDD off) and in the S45 sleep state, both LEDs are Off;
In the Power On state (VSB and VDD on) and in the S3I sleep state, each LED behaves according to the setting of its
LEDxBLNK field.
•
11b − The behavior of the LED1 and LED2 pins is controlled by the sleep states and by software.
In the Power Fail state (VSB and VDD off), both LEDs are Off;
In the Power On state (VSB and VDD on) and in the S45 and S3I sleep states, each LED behaves according to the setting
of its LEDxBLNK field.
9.2.8
Power Active Timers
The SWC includes two 32-bit Power Active timers: a VDD Active Timer, and a VSB Active Timer. Each timer is clocked by a
1 Hz internal clock derived from the battery-backed 32.768 kHz crystal clock generator.
These timers measure the cumulative amount of time (in seconds) that the VSB and the VDD power supplies are active (On).
Each of them is enabled for counting when its related power supply is turned on and stops counting when the power supply
goes off.
Due to their 32-bit length, the timers do not need to be reset; however, a reset bit is available for each timer (VSB_TMR_RST
and VDD_TMR_RST) in the PWTMRCTL register (see Section 9.3.29 on page 199).
The timer count data of the VDD Active Timer is available to the software in the VDD_ON_TMR_0 to VDD_ON_TMR_3 readonly registers (see Sections 9.3.21 to 9.3.24 on pages 196ff.), which are updated each second with the actual count value
of the timer. When VDD_ON_TMR_0 (the LSByte of the count data) is read, the updating of all four registers
(VDD_ON_TMR_0 to VDD_ON_TMR_3) is stopped, freezing the count value. The VDD_ON_TMR_1 and
VDD_ON_TMR_2 registers can then be read in any order. Finally, reading from the VDD_ON_TMR_3 register resumes the
registers updating with the actual count value of the timer. Therefore, the VDD_ON_TMR_0 register must be read first and
the VDD_ON_TMR_3 register last.
The same applies for the VSB Active Timer, whose timer count data is available to the software in the VSB_ON_TMR_0 to
VSB_ON_TMR_3 read-only registers (see Sections 9.3.25 to 9.3.28 on pages 197ff.).
9.2.9
Watchdog Function
The watchdog includes an 8-bit timer clocked by a 1-minute internal clock that is derived from the battery-backed 32.768
KHz crystal clock generator. The timer is loaded with the Watchdog Time-Out Data value written in the WDTO register (see
Section 9.3.34 on page 202) and counts down to zero. This 8-bit data enables time-out values between 1 to 255 minutes to
be programmed (00h is an invalid data value).
Five events can trigger the watchdog by reloading the timer:
●
Keyboard interrupt.
●
Mouse interrupt.
●
Serial Port 1 interrupt.
●
Serial Port 2 interrupt.
●
Software writing a ‘1’ to the SW_WD_TRG bit of the WDCTL register (see Section 9.3.33 on page 202).
Each event can be masked by an enable bit in the WDCFG register (see Section 9.3.35 on page 203). Whenever an active
edge of any enabled event is detected, the timer is restarted from the Watchdog Time-Out Data value. If no event occurs
before the timer reaches 00h, the WDO_EVT_STS status bit in the GPE1_STS_3 register (see Section 9.4.11 on page 211)
is set to ‘1’ and a 250 ms active low pulse is generated at the WDO pin. After a watchdog time-out or when the Hardware
reset is active (LRESET), the timer is reloaded.
The WDO_EVT_STS status bit can be routed either to the SIOSMI pin by the WDO_EVT_2SMI bit in the GPE1_2SMI_HIGH
register (see Section 9.3.7 on page 184) or to the SIOSCI pin by the WDO_EVT_EN bit in the GPE1_EN_3 register (see
Section 9.4.15 on page 215).
After either VSB Power-up reset or VDD Power-up reset, the watchdog is disabled. Its operation is enabled by setting the
WDEN bit in the WDCTL register (see Section 9.3.33 on page 202) to ‘1’. Once set, this bit cannot be cleared by software.
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The VSB Power-up and VDD Power-up resets both de-assert the WDO signal before the 250 ms have passed. The
WDO_EVT_STS status bit is cleared by the VSB Power-up reset.
Usage Hints Before changing the Watchdog Time-Out Data value in the WDTO register, set all the enable bits of the watchdog trigger events to ‘0’ - disable (in the WDCFG register; see Section 9.3.35 on page 203). Re-enable the watchdog trigger
events (set to ‘1’) after writing the new Watchdog Time-Out Data.
9.2.10 Miscellaneous Functions
Power Management Control
The SWC contains two Power Management registers, which allows the software to disable each Legacy module and to
TRI-STATE its outputs in a centralized manner.
The SWC Fast Disable register (SWCFDIS) provides a fast way for the Power Management software to disable one or
more Legacy modules without having to access the Activate register of each module (at index 30h) through the Index/Data
registers. The FDC, Parallel Port, Serial Port 1, Serial Port 2, Mouse Control and Keyboard Control logical devices can be
disabled through the SWCFDIS register (see Section 9.3.8 on page 185).
The SWC TRI-STATE register (SWCTRIS) also provides a fast way for the Power Management software to float the outputs of one or more Legacy modules without having to access their TRI-STATE Control bit in the Special Configuration register at index F0h. The module outputs enter TRI-STATE only when the module is disabled. The FDC, Parallel Port, Serial
Port 1, Serial Port 2, Mouse and Keyboard Control module outputs can be TRI-STATED through the SWCTRIS register (see
Section 9.3.9 on page 186).
Keyboard/Mouse Power Control (VDDFELL)
If the VDDFLMUX bit in the SIOCF2 register (see Section 3.7.3 on page 50) is set to ‘1’, the SWC generates a 1 second,
active high pulse at the VDDFELL pin each time the VDD power supply is turned off (by setting the ONCTL signal to high
level). This signal can be used by the system to turn off VSB power to the Keyboard and Mouse devices, thus causing them
to reset their internal circuits.
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9.0 System Wake-Up Control (SWC)
PC8741x
9.0 System Wake-Up Control (SWC)
9.3
(Continued)
SWC REGISTERS
The SWC registers are organized in four banks. The offsets are related to the base address determined by the SWC Base
Address register at indexes 60h - 61h in the SWC device configuration. The lower 16 offsets (00h-0Fh) are common to the
four banks; the upper offsets (10h-1Fh) are divided as follows:
•
•
•
•
Bank 0 holds registers related to the Keyboard/Mouse Wake-up Detector.
Bank 1 holds registers related to the Power Active timers.
Bank 2 holds registers related to sleep states and ACPI configuration.
Bank 3 holds registers related to the watchdog.
The active bank is selected through the BNK_SEL1-BNK_SEL0 bits in the Bank Select register (BANKSEL). For details, see
Section 9.3.15 on page 192.
The following abbreviations are used to indicate the Register Type:
●
R/W
= Read/Write.
●
R
= Read from a specific register (write to the same address is to a different register).
●
W
= Write (see above).
●
RO
= Read Only.
●
WO
= Write Only. Reading from the bit returns 0.
●
R/W1C = Read/Write 1 to Clear. Writing 1 to a bit clears it to 0. Writing 0 has no effect.
●
R/W1S = Read/Write 1 to Set. Writing 1 to a bit sets its value to 1. Writing 0 has no effect.
9.3.1
SWC Register Map
The following tables list the SWC registers. For the SWC register bitmap, see Section 9.5 on page 216. Most of the registers
are battery backed, however some are VSB powered.
Table 43. Banks 0, 1, 2 and 3 - Common Register Map
Offset
Mnemonic
Register Name
Type
Power Well Section
00h
WK_EVT_SEL
Wake-Up Event Select
R/W
VPP
9.3.2
01h
WK_ST_EN
Wake-Up State Enable
R/W
VPP
9.3.3
02h
GPE1_2IRQ_LOW
GPE1_STS Events to IRQ Enable Low
R/W
VPP
9.3.4
03h
GPE1_2IRQ_HIGH
GPE1_STS Events to IRQ Enable High
R/W
VPP
9.3.5
04h
GPE1_2SMI_LOW
GPE1_STS Events to SMI Enable Low
R/W
VPP
9.3.6
05h
GPE1_2SMI_HIGH
GPE1_STS Events to SMI Enable High
R/W
VPP
9.3.7
06h
SWCFDIS
SWC Fast Disable
R/W
VSB
9.3.8
07h
SWCTRIS
SWC TRI-STATE
R/W
VSB
9.3.9
08h
SWC_CTL
SWC Miscellaneous Control
Varies per bit
VPP
9.3.10
09h
PWONCTL
Power On Control
Varies per bit
VPP
9.3.11
0Ah
LEDCTL
LED Control
R/W
VPP
9.3.12
0Bh
LEDBLNK
LED Blinking Control
R/W
VPP
9.3.13
0Ch-0Dh Reserved
0Eh
BIOSGPR
BIOS General-Purpose Scratch
R/W
VPP
9.3.14
0Fh
BANKSEL
Bank Select
R/W
VPP
9.3.15
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Table 44. Bank 0 - Keyboard/Mouse Wake-Up Detector Register Map
Offset
Mnemonic
Register Name
Type
Power Well Section
10h-11h Reserved
12h
KBDWKCTL
Keyboard Wake-Up Control
R/W
VPP
9.3.16
13h
PS2CTL
PS2 Protocol Control
R/W
VPP
9.3.17
14h-15h Reserved
16h
KDSR
Keyboard Data Shift-Register
RO
VPP
9.3.18
17h
MDSR
Mouse Data Shift-Register
RO
VPP
9.3.19
18h
PS2KEY0
PS2 Keyboard Key Data 0
R/W
VPP
9.3.20
19h
PS2KEY1
PS2 Keyboard Key Data 1
R/W
VPP
9.3.20
1Ah
PS2KEY2
PS2 Keyboard Key Data 2
R/W
VPP
9.3.20
1Bh
PS2KEY3
PS2 Keyboard Key Data 3
R/W
VPP
9.3.20
1Ch
PS2KEY4
PS2 Keyboard Key Data 4
R/W
VPP
9.3.20
1Dh
PS2KEY5
PS2 Keyboard Key Data 5
R/W
VPP
9.3.20
1Eh
PS2KEY6
PS2 Keyboard Key Data 6
R/W
VPP
9.3.20
1Fh
PS2KEY7
PS2 Keyboard Key Data 7
R/W
VPP
9.3.20
Table 45. Bank 1 - Power Active Timers Register Map
Offset
Mnemonic
Register Name
Type
Power Well Section
10h
VDD_ON_TMR_0
VDD Active Timer 0
RO
VPP
9.3.21
11h
VDD_ON_TMR_1
VDD Active Timer 1
RO
VPP
9.3.22
12h
VDD_ON_TMR_2
VDD Active Timer 2
RO
VPP
9.3.23
13h
VDD_ON_TMR_3
VDD Active Timer 3
RO
VPP
9.3.24
14h
VSB_ON_TMR_0
VSB Active Timer 0
RO
VPP
9.3.25
15h
VSB_ON_TMR_1
VSB Active Timer 1
RO
VPP
9.3.26
16h
VSB_ON_TMR_2
VSB Active Timer 2
RO
VPP
9.3.27
17h
VSB_ON_TMR_3
VSB Active Timer 3
RO
VPP
9.3.28
18h
PWTMRCTL
Power Active Timers Control
Varies per bit
VPP
9.3.29
19h-1Fh Reserved
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9.0 System Wake-Up Control (SWC)
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Table 46. Bank 2 - Sleep States and ACPI Configuration Register Map
Offset
Mnemonic
Register Name
Type
Power Well Section
10h
S0_SLP_TYP
S0 Sleep Type Encoding
R/W or RO
VPP
9.3.30
11h
S1_SLP_TYP
S1 Sleep Type Encoding
R/W or RO
VPP
9.3.30
12h
S2_SLP_TYP
S2 Sleep Type Encoding
R/W or RO
VPP
9.3.30
13h
S3_SLP_TYP
S3 Sleep Type Encoding
R/W or RO
VPP
9.3.30
14h
S4_SLP_TYP
S4 Sleep Type Encoding
R/W or RO
VPP
9.3.30
15h
S5_SLP_TYP
S5 Sleep Type Encoding
R/W or RO
VPP
9.3.30
16h
SLP_ST_CFG
Sleep State Configuration
Varies per bit
VPP
9.3.31
17h
ACPI_CFG
ACPI Configuration
R/W
VPP
9.3.32
18h-1Fh Reserved
Table 47. Bank 3 - Watchdog Register Map
Offset
Mnemonic
Register Name
10h
WDCTL
Watchdog Control
11h
WDTO
12h
WDCFG
Type
Power Well Section
Varies per bit
VSB
9.3.33
Watchdog Time-Out
R/W
VSB
9.3.34
Watchdog Configuration
R/W
VSB
9.3.17
13h-1Fh Reserved
9.3.2
Wake-Up Event Select Register (WK_EVT_SEL)
This register selects the wake-up event to be configured (i.e., which register is accessed via the Wake-Up State Enable register). Since access to the Wake-Up State Enable register requires two transactions (first to WK_EVT_SEL and then to
WK_ST_EN) and since the LPC bus and ACCESS.bus access the module concurrently (PC87413 and PC87417), the
WK_EVT_SEL register is duplicated (one accessed by the host and one by the ACCESS.bus).This register is reset by hardware to 00h.
The wake-up events selected through this register are active when either the bits of the GPE1_STS_0 to GPE1_STS_3 registers or the PM1b_STS_HIGH register are set. Table 48 shows the mapping of the WKUPSEL field value to each wake-up
event and the related status bit.
Power Well:VPP
Location: All Banks, Offset 00h
Type:
R/W
Bit
7
Name
6
5
4
3
Reserved
Reset
0
Bit
0
2
1
0
0
0
WKUPSEL
0
0
0
0
Description
7-5
Reserved.
4-0
WKUPSEL (Wake-Up Event Select). These bits select a wake-up event to be configured through the
WK_ST_EN register (see Table 48).
00000: GPIOE10 Event Status (default)
00001 to 11111: Wake-up events (see Table 48)
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Table 48. Wake-Up Event Select Field Map
WKUPSEL
Wake-Up Event Name
WK_ST_EN Class GPE1_STS_n Bit PM1b_STS_HIGH Bit
Notes
00h
GPIOE10 Event Status
A
GPIOE10_STS
01h
GPIOE11 Event Status
A
GPIOE11_STS
02h
GPIOE12 Event Status
A
GPIOE12_STS
03h
GPIOE13 Event Status
A
GPIOE13_STS
04h
GPIOE14 Event Status
A
GPIOE14_STS
05h
GPIOE15 Event Status
A
GPIOE15_STS
06h
GPIOE16 Event Status
A
GPIOE16_STS
07h
GPIOE17 Event Status
A
GPIOE17_STS
08h
GPIOE40 Event Status
A
GPIOE40_STS
09h
GPIOE41 Event Status
A
GPIOE41_STS
0Ah
GPIOE42 Event Status
A
GPIOE42_STS
0Bh
GPIOE43 Event Status
A
GPIOE43_STS
0Ch
GPIOE44 Event Status
A
GPIOE44_STS
0Dh
GPIOE45 Event Status
A
GPIOE45_STS
0Eh
GPIOE46 Event Status
A
GPIOE46_STS
0Fh
GPIOE47 Event Status
A
GPIOE47_STS
10h
RI1 Event Status
A
RI1_EVT_STS
11h
RI2 Event Status
A
RI2_EVT_STS
12h
Mouse Event Status
A
MS_EVT_STS
13h
Keyboard Event 1 Status
A
KBD_EVT1_STS
14h
Keyboard Event 2 Status
A
KBD_EVT2_STS
15h
Keyboard Event 3 Status
A
KBD_EVT3_STS
16h
Sleep Button Event Status
A
SLBT_EVT_STS
SLPBTN_STS
ORed bits
17h
Reserved
18h
RTC Alarm Event Status
A
RTC_EVT_STS
RTC_STS
ORed bits
19h
Port P12 Event Status
B
P12_EVT_STS
1Ah
Keyboard IRQ Event Status
B
KBD_IRQ_STS
1Bh
Mouse IRQ Event Status
B
MS_IRQ_STS
1Ch
Modules IRQ Event Status
A
MOD_IRQ_STS
1Dh
Reserved
1Eh
Software On Event Status
A
SW_ON_STS
1Fh
Software Off Event Status
A
SW_OFF_STS
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9.3.3
(Continued)
Wake-Up State Enable Register (WK_ST_EN)
This register configures the wake-up event selected by the Wake-Up Event Select register. Two different classes (A and B)
are defined for this register (see Table 48 on page 179). Both classes are reset by hardware to 00h.
The sleep states for which the outputs are enabled when the event is active are PC8741x device current states (see Section
9.2.3 on page 167).
Power Well:VPP
Location: All Banks, Offset 01h
Type:
R/W
Class:
A
Bit
7
6
Reset
3
PWBT_EN
_S3I
0
0
0
7
6
5
2
1
0
PWBT_EN ONCTL_EN ONCTL_EN
_S45
_S3I
_S45
0
0
0
4
3
2
0
0
1
0
B
Bit
ONCTL_EN ONCTL_EN
_S3I
_S45
Reserved
Name
Reset
0
Bit
7-4
4
Reserved
Name
Class:
5
0
0
0
0
0
0
0
Description
Reserved.
3
PWBT_EN_S3I (PWBTOUT Pulse Enable in S3I). Enables generating a PWBTOUT pulse when the selected
Class A event becomes active and the device is in S3I sleep state. The selected event affects the output regardless of
the setting of the related enable bit in the GPE1_EN_n register. However, for a PWBTOUT pulse to be
generated, the PWBTOUT_MODE bit in the ACPI_CFG register (see Section 9.3.32 on page 201) must be ‘0’.
0: Disable pulse (default)
1: Enable pulse in S3I state
2
PWBT_EN_S45 (PWBTOUT Pulse Enable in S45). Enables generating a PWBTOUT pulse when the selected
Class A event becomes active and the device is in S45 sleep state. The selected event affects the output regardless of
the setting of the related enable bit in the GPE1_EN_n register. However, for a PWBTOUT pulse to be
generated, the PWBTOUT_MODE bit in the ACPI_CFG register (see Section 9.3.32 on page 201) must be ‘0’.
0: Disable pulse (default)
1: Enable pulse in S45 state
3-2
Reserved.
Class B
1
ONCTL_EN_S3I (ONCTL Active Enable in S3I). Enables activation (turning the VDD power On) Of the ONCTL
output when the selected event becomes active and the device is in the S3I sleep state. The selected event
affects the output regardless of the setting of the related enable bit in the GPE1_EN_n register. This bit is
relevant only if the PC8741x device is the ACPI controller of the system (EXT_ST_SELECT = 0 in the
SLP_ST_CFG register).
0: Disable activation (default)
1: Enable activation in S3I state
0
ONCTL_EN_S45 (ONCTL Active Enable in S45). Enables activation (turning the VDD power On) of the ONCTL
output when the selected event becomes active and the device is in the S45 sleep state. The selected event
affects the output regardless of the setting of the related enable bit in the GPE1_EN_n register. This bit is
relevant only if the PC8741x device is the ACPI controller of the system (EXT_ST_SELECT = 0 in the
SLP_ST_CFG register).
0: Disable activation (default)
1: Enable activation in S45 state
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9.0 System Wake-Up Control (SWC)
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GPE1_STS Events to IRQ Enable Low Register (GPE1_2IRQ_LOW)
This register enables the wake-up events contained in bits 16-23 of the GPE1_STS register to generate an IRQ. It is reset
by hardware to 00h.
Power Well:VPP
Location: All Banks, Offset 02h
Type:
Bit
R/W
7
Name
Reset
6
5
4
3
PWBT_EVT SLBT_EVT KBD_EVT3 KBD_EVT2 KBD_EVT1
_2IRQ
_2IRQ
_2IRQ
_2IRQ
_2IRQ
0
0
0
0
0
2
1
0
MS_EVT
_2IRQ
RI2_EVT
_2IRQ
RI1_EVT
_2IRQ
0
0
0
Bit
Description
7
PWBT_EVT_2IRQ (Power Button Event to IRQ Enable). Enables the Power button pressing event to generate
an IRQ.
0: Disable IRQ (default)
1: Enable IRQ from Power button pressing event
6
SLBT_EVT_2IRQ (Sleep Button Event to IRQ Enable). Enables the Sleep button pressing event to generate
an IRQ.
0: Disable IRQ (default)
1: Enable IRQ from Sleep button pressing event
5
KBD_EVT3_2IRQ (Keyboard Event 3 to IRQ Enable). Enables the “PM Key 3” (keyboard) pressing event to
generate an IRQ.
0: Disable IRQ (default)
1: Enable IRQ from pressing “PM Key 3” on the keyboard
4
KBD_EVT2_2IRQ (Keyboard Event 2 to IRQ Enable). Enables the “PM Key 2” (keyboard) pressing event to
generate an IRQ.
0: Disable IRQ (default)
1: Enable IRQ from pressing “PM Key 2” on the keyboard
3
KBD_EVT1_2IRQ (Keyboard Event 1 to IRQ Enable). Enables the event of pressing any keyboard key, key
sequence or “PM Key 1” to generate an IRQ.
0: Disable IRQ (default)
1: Enable IRQ from pressing any key, key sequence or “PM Key 1” on the keyboard
2
MS_EVT_2IRQ (Mouse Event to IRQ Enable). Enables a mouse event identified by the Keyboard/Mouse
Wake-up Detector to generate an IRQ.
0: Disable IRQ (default)
1: Enable IRQ from a mouse event identified by the Keyboard/Mouse Wake-up Detector
1
RI2_EVT_2IRQ (RI2 Event to IRQ Enable). Enables a telephone ring event received at the Serial Port 2,
identified by the RI Wake-up Detector, to generate an IRQ.
0: Disable IRQ (default)
1: Enable IRQ from the telephone ring event received at the Serial Port 2
0
RI1_EVT_2IRQ (RI1 Event to IRQ Enable). Enables a telephone ring event received at the Serial Port 1,
identified by the RI Wake-up Detector, to generate an IRQ.
0: Disable IRQ (default)
1: Enable IRQ from the telephone ring event received at the Serial Port 1
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9.0 System Wake-Up Control (SWC)
9.3.5
(Continued)
GPE1_STS Events to IRQ Enable High Register (GPE1_2IRQ_HIGH)
This register enables the wake-up events contained in 24-31 of the GPE1_STS register to generate an IRQ. It is reset by
hardware to 00h.
Power Well:VPP
Location: All Banks, Offset 03h
Type:
R/W
Bit
7
6
Name
SW_OFF
_2IRQ
SW_ON
_2IRQ
Reset
0
0
Bit
5
4
3
2
Reserved
0
0
0
0
1
0
P12_EVT
_2IRQ
Reserved
0
0
Description
7
SW_OFF_2IRQ (Software Off Event to IRQ Enable). Enables the event of the software writing a ‘1’ to the
SW_OFF_CTL bit in the SWC_CTL register to generate an IRQ.
0: Disable IRQ (default)
1: Enable IRQ from the software writing a ‘1’ to the SW_OFF_CTL bit in the SWC_CTL register
6
SW_ON_2IRQ (Software On Event to IRQ Enable). Enables the event of the software writing a ‘1’ to the
SW_ON_CTL bit in the SWC_CTL register to generate an IRQ.
0: Disable IRQ (default)
1: Enable IRQ from the software writing a ‘1’ to the SW_ON_CTL bit in the SWC_CTL register
5-2
Reserved.
1
P12_EVT_2IRQ (Port P12 Event to IRQ Enable). Enables an active high signal generated at the P12 pin to
generate an IRQ.
0: Disable IRQ (default)
1: Enable IRQ from an active high signal generated at the P12 pin
0
Reserved.
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GPE1_STS Events to SMI Enable Low Register (GPE1_2SMI_LOW)
This register enables the wake-up events contained in bits 16-23 of the GPE1_STS register to generate an SMI interrupt. It
is reset by hardware to 00h.
Power Well:VPP
Location: All Banks, Offset 04h
Type:
Bit
R/W
7
Name
Reset
6
5
4
3
PWBT_EVT SLBT_EVT KBD_EVT3 KBD_EVT2 KBD_EVT1
_2SMI
_2SMI
_2SMI
_2SMI
_2SMI
0
0
0
0
0
2
1
0
MS_EVT
_2SMI
RI2_EVT
_2SMI
RI1_EVT
_2SMI
0
0
0
Bit
Description
7
PWBT_EVT_2SMI (Power Button Event to SMI Enable). Enables the Power button pressing event to generate
an SMI interrupt.
0: Disable SMI (default)
1: Enable SMI from Power button pressing event
6
SLBT_EVT_2SMI (Sleep Button Event to SMI Enable). Enables the Sleep button pressing event to generate
an SMI interrupt.
0: Disable SMI (default)
1: Enable SMI from Sleep button pressing event
5
KBD_EVT3_2SMI (Keyboard Event 3 to SMI Enable). Enables the “PM Key 3” (keyboard) key pressing event
to generate an SMI interrupt.
0: Disable SMI (default)
1: Enable SMI from pressing “PM Key 3” on the keyboard
4
KBD_EVT2_2SMI (Keyboard Event 2 to SMI Enable). Enables the “PM Key 2” (keyboard) key pressing event
to generate an SMI interrupt.
0: Disable SMI (default)
1: Enable SMI from pressing “PM Key 2” on the keyboard
3
KBD_EVT1_2SMI (Keyboard Event 1 to SMI Enable). Enables the event of pressing any keyboard key, key
sequence or “PM Key 1” to generate an SMI interrupt.
0: Disable SMI (default)
1: Enable SMI from pressing any key, key sequence or “PM Key 1” on the keyboard
2
MS_EVT_2SMI (Mouse Event to SMI Enable). Enables a mouse event, identified by the Keyboard/Mouse
Wake-up Detector, to generate an SMI interrupt.
0: Disable SMI (default)
1: Enable SMI from the mouse event identified by the Keyboard/Mouse Wake-up Detector
1
RI2_EVT_2SMI (RI2 Event to SMI Enable). Enables a telephone ring event received at the Serial Port 2,
identified by the RI Wake-up Detector, to generate an SMI interrupt.
0: Disable SMI (default)
1: Enable SMI from the telephone ring event received at the Serial Port 2
0
RI1_EVT_2SMI (RI1 Event to SMI Enable). Enables a telephone ring event received at the Serial Port 1,
identified by the RI Wake-up Detector, to generate an SMI interrupt.
0: Disable SMI (default)
1: Enable SMI from the telephone ring event received at the Serial Port 1
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9.0 System Wake-Up Control (SWC)
9.3.7
(Continued)
GPE1_STS Events to SMI Enable High Register (GPE1_2SMI_HIGH)
This register enables the wake-up events contained in bits 24-31 of the GPE1_STS register to generate an SMI interrupt. It
is reset by hardware to 00h.
Power Well:VPP
Location: All Banks, Offset 05h
Type:
R/W
Bit
7
6
5
Name
SW_OFF
_2SMI
SW_ON
_2SMI
WDO_EVT
_2SMI
Reset
0
0
0
Bit
4
3
2
1
RTC_EVT
_2SMI
Reserved
0
0
0
0
0
0
Description
7
SW_OFF_2SMI (Software Off Event to SMI Enable). Enables the event of the software writing a ‘1’ to the
SW_OFF_CTL bit in the SWC_CTL register to generate an SMI interrupt.
0: Disable SMI (default)
1: Enable SMI from the software writing a ‘1’ to the SW_OFF_CTL bit in the SWC_CTL register
6
SW_ON_2SMI (Software On Event to SMI Enable). Enables the event of the software writing a ‘1’ to the
SW_ON_CTL bit in the SWC_CTL register to generate an SMI interrupt.
0: Disable SMI (default)
1: Enable SMI from the software writing a ‘1’ to the SW_ON_CTL bit in the SWC_CTL register
5
WDO_EVT_2SMI (Watchdog Event to SMI Enable). Enables a watchdog time-out to generate an SMI
interrupt.
0: Disable SMI (default)
1: Enable SMI from watchdog time-out
4-1
0
Reserved.
RTC_EVT_2SMI (RTC Alarm Event to SMI Enable). Enables an RTC alarm to generate an SMI interrupt.
0: Disable SMI (default)
1: Enable SMI from RTC alarm
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9.0 System Wake-Up Control (SWC)
(Continued)
SWC Fast Disable Register (SWCFDIS)
This register provides a fast way for the Power Management software to disable one or more modules without having to
access the Activate register of each module (see Section 3.3.1 on page 43). It is reset by hardware to 00h.
Power Well:VSB
Location: All Banks, Offset 06h
Type:
R/W
Bit
7
Name
Reserved
Reset
0
Bit
7-6
6
0
5
4
3
2
1
0
KBDDIS
MSDIS
SER1DIS
SER2DIS
PARPDIS
FDCDIS
0
0
0
0
0
0
Description
Reserved.
5
KBDDIS (Keyboard Controller Disable). When set to 1, this bit forces the Keyboard Controller module (Logical
Device 6) to be disabled (and its resources released) regardless of the actual setting of its Activation bit (index
30).
0: Enabled or Disabled, according to Activation bit (default)
1: Disabled
4
MSDIS (Mouse Controller Disable). When set to 1, this bit forces the Mouse Controller module (Logical Device
5) to be disabled (and its resources released) regardless of the actual setting of its Activation bit (index 30).
0: Enabled or Disabled, according to Activation bit (default)
1: Disabled
3
SER1DIS (Serial Port 1 Disable). When set to 1, this bit forces the Serial Port 1 module to be disabled (and its
resources released) regardless of the actual setting of its Activation bit (index 30).
0: Enabled or Disabled, according to Activation bit (default)
1: Disabled
2
SER2DIS (Serial Port 2 Disable). When set to 1, this bit forces the Serial Port 2 module to be disabled (and its
resources released) regardless of the actual setting of its Activation bit (index 30).
0: Enabled or Disabled, according to Activation bit (default)
1: Disabled
1
PARPDIS (Parallel Port Disable). When set to 1, this bit forces the Parallel Port module to be disabled (and its
resources released) regardless of the actual setting of its Activation bit (index 30).
0: Enabled or Disabled, according to Activation bit (default)
1: Disabled
0
FDCDIS (Floppy Disk Controller Disable). When set to 1, this bit forces the Floppy Disk Controller module to
be disabled (and its resources released) regardless of the actual setting of its Activation bit (index 30).
0: Enabled or Disabled, according to Activation bit (default)
1: Disabled
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PC8741x
9.0 System Wake-Up Control (SWC)
9.3.9
(Continued)
SWC TRI-STATE Register (SWCTRIS)
This register provides a fast way for the Power Management software to float the outputs of one or more modules without
having to access their TRI-STATE Control bit in the Special Configuration register at index F0h. The module outputs enter
TRI-STATE only when the module is disabled (see Section 9.3.8). The register is reset by hardware to 00h.
Power Well:VSB
Location: All Banks, Offset 07h
Type:
R/W
Bit
7
Name
5
Reserved
Reset
0
Bit
7-5
6
0
4
3
KBMSTRIS SER1TRIS
0
0
0
2
1
0
SER2TRIS
PARPTRIS
FDCTRIS
0
0
0
Description
Reserved.
4
KBMSTRIS (Keyboard and Mouse Outputs TRI-STATE). When set to 1 and the module is disabled, this bit
forces the outputs of the Keyboard and Mouse Controller to be in TRI-STATE regardless of bit 0 in the Keyboard
Configuration register (see Section 3.13.3 on page 69).
0: Enabled or Disabled, according to bit 0 in the Keyboard Configuration register (default)
1: Outputs in TRI-STATE
3
SER1TRIS (Serial Port 1 Outputs TRI-STATE). When set to 1 and the module is disabled, this bit forces the
outputs of the Serial Port 1 module to be in TRI-STATE regardless of bit 0 in the Serial Port 1 Configuration
register (see Section 3.11.3 on page 66).
0: Enabled or Disabled, according to bit 0 in the Serial Port 1 Configuration register (default)
1: Outputs in TRI-STATE
2
SER2TRIS (Serial Port 2 Outputs TRI-STATE). When set to 1 and the module is disabled, this bit forces the
outputs of the Serial Port 2 module to be in TRI-STATE regardless of bit 0 in the Serial Port 2 Configuration
register (see Section 3.10.3 on page 64).
0: Enabled or Disabled, according to bit 0 in the Serial Port 2 Configuration register (default)
1: Outputs in TRI-STATE
1
PARPTRIS (Parallel Port Outputs TRI-STATE). When set to 1 and the module is disabled, this bit forces the
outputs of the Parallel Port module to be in TRI-STATE regardless of bit 0 in the Parallel Port Configuration
register (see Section 3.9.3 on page 62).
0: Enabled or Disabled, according to bit 0 in the Parallel Port Configuration register (default)
1: Outputs in TRI-STATE
0
FDCTRIS (Floppy Disk Controller Outputs TRI-STATE). When set to 1 and the module is disabled, this bit
forces the outputs of the Floppy Disk Controller module to be in TRI-STATE regardless of bit 0 in the FDC
Configuration register (see Section 3.8.3 on page 59).
0: Enabled or Disabled, according to bit 0 in the FDC Configuration register (default)
1: Outputs in TRI-STATE
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9.0 System Wake-Up Control (SWC)
(Continued)
9.3.10 SWC Miscellaneous Control Register (SWC_CTL)
This register contains control and status bits for the SWC module. It is reset by hardware to 00h.
Power Well:VPP
Location: All Banks, Offset 08h
Type:
Varies per bit
Bit
7
6
Name
SW_OFF
_CTL
SW_ON
_CTL
Reset
0
0
5
4
3
PWB_OVR CROWBAR
_STS
_STS
0
0
2
1
Reserved
0
0
0
SWAP
_KBMS
0
0
Bit
Type
Description
7
R/W
SW_OFF_CTL (Software Off Control). Writing ‘1’ to this bit sets the SW_OFF_STS bit in the
GPE1_STS_3 register (see Section 9.4.11 on page 211), which requests a VDD power off sequence.
This bit then returns to ‘0’ (read always returns ‘0’).
0: Inactive (default)
1: Requests a VDD power off sequence
6
R/W
SW_ON_CTL (Software On Control). Writing ‘1’ to this bit sets the SW_ON_STS bit in the
GPE1_STS_3 register (see Section 9.4.11 on page 211), which requests a VDD Power On sequence.
This bit then returns to ‘0’ (read always returns ‘0’). When the VDD power is off, this bit can be written
only through the ACCESS.bus (PC87413 and PC87417).
0: Inactive (default)
1: Requests a VDD Power On sequence
5
R/W1C PWB_OVR_STS (Power Button Override Status). Indicates that the Power Button Override event has
occurred (Power button pressed for more than 4 seconds). In this condition the VDD power is
unconditionally turned off. Writing ‘1’ clears this bit; writing ‘0’ is ignored.
0: Inactive (default)
1: Power Button Override event has occurred
4
R/W1C CROWBAR_STS (Crowbar Status). Indicates that the Crowbar event has been detected (VDD
remained Off for longer than the Crowbar Timeout). In this condition the VDD power is turned off. Writing
‘1’ clears this bit; writing ‘0’ is ignored.
0: Inactive (default)
1: Crowbar event has been detected
3-1
0
Revision 1.2
Reserved.
R/W
SWAP_KBMS (Swap Keyboard and Mouse Inputs). When this bit is set, the keyboard signals
(KBCLK and KBDAT) are swapped with the mouse signals (MCLK and MDAT). This bit must be set to
the same value as the Swap bit in the KBC Configuration register (see Section 3.13.3 on page 69).
0: No swapping (default)
1: Swaps the keyboard and mouse signals
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PC8741x
9.0 System Wake-Up Control (SWC)
(Continued)
9.3.11 Power On Control Register (PWONCTL)
This register controls the power-On process and the way the PC8741x device resumes operation after Power Fail. It is reset
by hardware to 87h.
Power Well:VPP
Location: All Banks, Offset 09h
Type:
Varies per bit
Bit
7
6
Name
WAS
_PFAIL
LAST
_ONCTL
Reset
1
0
5
4
RESUME_MD
0
0
3
2
LEGACY
_PWBT1
0
1
0
CRBAR_TOUT
1
1
1
1. This bit is powered from the VDD well and is reset either by VDD power-up reset or by hardware reset.
Bit
7
6
Type
Description
R/W1C WAS_PFAIL (Was Power Fail Status). Indicates that the device has woken up from a Power Fail
condition (VDD and VSB off). This bit is set by VSB Power-Up reset. Writing ‘1’ clears this bit; writing ‘0’
is ignored.
0: Inactive
1: Wake-up from Power Fail (default)
RO
LAST_ONCTL (Last Value of ONCTL). This bit reflects the last value of the ONCTL signal when the
previous Power Fail condition (VDD and VSB off) occurred. Writing to this bit is ignored.
0: ONCTL inactive - VDD power Off (default)
1: ONCTL active - VDD power On
5-4
R/W
RESUME_MD (Resume Mode Control). These bits control the power state to which the PC8741x
device resumes after waking-up from a Power Fail condition (i.e., when VDD and VSB are off). Table 49
shows the behavior of the ONCTL and PWBTOUT signals in all four Resume modes.
3
R/W
LEGACY_PWBT (Legacy Power Button). This bit allows the Power button to set ONCTL to inactive
level (VDD power supply Off).
0: ACPI-compliant Power button - VDD power turned off by sleep state (written into SLP_TYPx field or
decoded from SLPS3 and SLPS5) or by a Power Button Override condition (default)
1: Legacy Power button - VDD power turned off by pressing the Power button (PWBTIN) when the VDD
power is on
2-0
R/W
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CRBAR_TOUT (Crowbar Timeout Configuration). This field controls the timeout value for the
Crowbar function (the time between the activation of ONCTL and its deactivation as a result of VDD
remaining off). After the Crowbar timeout, the PC8741x device waits another second before it accepts
a new Power button event.
Bits
2 1 0
Timeout (Seconds)
0
0
0
0
1
1
1
1
0.5
1
2
3
6
10
15
20 (default)
0
0
1
1
0
0
1
1
0:
1:
0:
1:
0:
1:
0:
1:
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9.0 System Wake-Up Control (SWC)
(Continued)
Table 49. ONCTL and PWBTOUT as a Function of the Power Fail Resume Mode
RESUME_MD
EXT_ST_SELECT1
0
00
(Default)
RTC Alarm in
Power Fail2
ONCTL Pin
PWBTOUT Pin
X
X
X
1
-
0
X
X
1
-
1
X
X
0 (On)
Pulse3
X
X
0
1
-
0
X
0
1
-
1
X
X
0 (On)
Pulse3
X
X
X
1
0 (On)
Pulse3
X
X
0
X
1
-
X
X
1
X
0 (On)
Pulse3
X
X
0
0
1
-
X
X
1
X
0 (On)
Pulse3
X
X
X
1
0 (On)
Pulse3
1
0
01
SLPS3 Pin LAST_ONCTL
1
10
11
1. EXT_ST_SELECT bit in the SLP_ST_CFG register (see Section 9.3.31 on page 200). The EXTSTMUX bit in
the SIOCF3 register (see Section 3.7.4 on page 51) has to be set to the same value as
EXT_ST_SELECT.
2. RTC Alarm event active during Power Fail.
3. A pulse is generated only if the PWBTOUT_MODE bit in the ACPI_CFG register is ‘0’ (see Section 9.3.32 on
page 201).
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PC8741x
9.0 System Wake-Up Control (SWC)
(Continued)
9.3.12 LED Control Register (LEDCTL)
This register controls the operation mode of the two LEDs driven by the PC8741x device. It is reset by hardware to 00h.
Power Well:VPP
Location: All Banks, Offset 0Ah
Type:
R/W
Bit
7
Name
6
Reserved
Reset
0
5
4
LEDCFG
LEDPOL
0
0
0
Bit
7-6
5
3
2
1
0
0
Reserved
0
0
LEDMOD
0
Description
Reserved.
LEDCFG (LED Configuration). This bit enables the use of either two regular LEDs, connected between each
pin (LED1, LED2) and ground or VSB, or one dual-colored LED, connected between the LED1 and LED2 pins.
0: One dual-colored LED (default)
1: Two regular LEDs
4
LEDPOL (LED Polarity). This bit determines the polarity of LED1 and LED2 outputs. An active output,
according to this bit setting, turns the LED On. For the dual-colored LED configuration, changing the polarity
reverses the LED colors.
0: Active high - LED cathode connected to ground (default)
1: Active low - LED anode connected to VSB
3-2
Reserved.
1-0
LEDMOD (LED Operation Mode). These bits control the operation mode of LED1 and LED2 in each power
state. Table 50 shows the behavior of the LED1 and LED2 outputs as a function of the system power state.
Table 50. LED1 and LED2 as a Function of the Power State
LEDMOD
00
(default)
Power Fail1
Power Off1
State S452
State S3I2
Power On1
Yes
No
X
X
X
X
Yes
01
Yes
X
X
Yes
Yes
X
Yes
LED1
LED2
Off
Off
S/W13
S/W24
Off
Off
Blink5
Blink5
S/W1
S/W2
Off
Off
Off
Off
S/W1
S/W2
S/W1
S/W2
Off
Off
S/W1
S/W2
S/W1
S/W2
S/W1
S/W2
10
X
Yes
Yes
Yes
X
Yes
11
X
Yes
Yes
1. Power Fail: VSB and VDD Off. Power Off: VSB On, VDD Off. Power On: VSB and VDD On;
2. Sleep states S3I and S45 are PC8741x device current states (see Section 9.3.31 on page 200).
3. Controlled by the value of LED1BLNK in the LEDBLNK register.
4. Controlled by the value of LED2BLNK in the LEDBLNK register.
5. 1 Hz blink with 50% duty cycle.
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9.0 System Wake-Up Control (SWC)
(Continued)
9.3.13 LED Blink Control Register (LEDBLNK)
This register controls the blinking rate of the two LEDs driven by the PC8741x device. It is reset by hardware to 70h.
Power Well:VPP
Location: All Banks, Offset 0Bh
Type:
R/W
Bit
7
Name
Reserved
Reset
0
6
5
4
LED2BLNK
1
6-4
3
2-0
2
Reserved
1
1
Bit
7
3
0
1
0
LED1BLNK
0
0
0
Description
Reserved.
LED2BLNK (LED2 Blink Rate). These bits control the blinking rate of LED2 output.
Bits
6 5 4
Rate (Hz)
Duty Cycle
0
0
0
0
1
1
1
1
Off
0.25
0.5
1
2
3
4
On
Always inactive
12.5%
25%
50%
50%
50%
50%
Always active (default)
0
0
1
1
0
0
1
1
0:
1:
0:
1:
0:
1:
0:
1:
Reserved.
LED1BLNK (LED1 Blink Rate). These bits control the blinking rate of LED1 output.
Bits
2 1 0
Rate (Hz)
Duty Cycle
0
0
0
0
1
1
1
1
Off
0.25
0.5
1
2
3
4
On
Always inactive (default)
12.5%
25%
50%
50%
50%
50%
Always active
0
0
1
1
0
0
1
1
0:
1:
0:
1:
0:
1:
0:
1:
9.3.14 BIOS General-Purpose Scratch Register (BIOSGPR)
This register may be used by the BIOS for general-purpose battery-backed data storage. It is reset by hardware to 00h.
Power Well:VPP
Location: All Banks, Offset 0Eh
Type:
Bit
R/W
7
6
5
Name
Reset
0
0
Bit
7-0
Revision 1.2
4
3
2
1
0
0
0
0
General-Purpose Scratch
0
0
0
Description
General-Purpose Scratch
191
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PC8741x
9.0 System Wake-Up Control (SWC)
(Continued)
9.3.15 Bank Select Register (BANKSEL)
This register selects the active bank for the upper offsets (10h-1Fh). Since the access to registers at offsets 10h-1Fh requires
two transactions (first to BANKSEL and then to the specific register) and since the LPC bus and ACCESS.bus access the
module concurrently (PC87413 and PC87417), the BANKSEL register is duplicated (one is accessed by the host and one
by the ACCESS.bus).This register is reset by hardware to 00h.
Power Well:VPP
Location:All Banks, Offset 0Fh
Type:
R/W
Bit
7
6
5
Name
4
3
2
1
Reserved
Reset
0
0
Bit
0
0
BNK_SEL
0
0
0
0
0
Description
7-2
Reserved.
1-0
BNK_SEL (Bank Select). This field selects the active bank for the upper offsets (10h-1Fh).
Bits
1 0
Active Bank
0
0
1
1
Bank 0: holds registers related to the Keyboard/Mouse Wake-up Detector (default)
Bank 1: holds registers related to the Power Active timers
Bank 2: holds registers related to sleep states and ACPI configuration
Bank 3: holds registers related to watchdog configuration and control
0:
1:
0:
1:
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9.0 System Wake-Up Control (SWC)
(Continued)
9.3.16 Keyboard Wake-Up Control Register (KBDWKCTL)
This register configures the keyboard events detected by the Keyboard/Mouse Wake-up Detector. It is reset by hardware
to 00h.
Power Well:VPP
Location:Bank 0, Offset 12h
Type:
R/W
Bit
7
6
Name
KBDMODE
Reserved
Reset
0
0
Bit
5
4
3
EVT3CFG
0
2
1
EVT2CFG
0
0
0
EVT1CFG
0
0
0
Description
7
KBDMODE (Keyboard Mode Select). This bit selects one of the keyboard wake-up modes for the
Keyboard/Mouse Wake-up Detector.
0: Special Key Sequence or Password modes - configured by bits 3-0 of the PS2CTL register (default)
1: Power Management Key mode - configured by bits 5-0 of the KBDWKCTL register
6
Reserved.
5-4
3-2
1-0
Revision 1.2
EVT3CFG (Keyboard Event 3 Configuration). These bits configure the keyboard data sequence for Keyboard
Event 3, which indicates that “PM Key 3” was pressed on the keyboard. The setting of the EVT3CFG field is
relevant only if the Keyboard/Mouse Wake-up Detector is in Power Management Key mode (KBDMODE = 1).
The keyboard data sequence used to detect Keyboard Event 3 is stored in registers PS2KEY6 and PS2KEY7,
starting with PS2KEY6.
Bits
5 4
Sequence Length
0
0
1
1
0 bytes - Keyboard Event 3 disabled (default)
1 byte (PS2KEY6)
2 bytes (PS2KEY6, PS2KEY7)
Reserved
0:
1:
0:
1:
EVT2CFG (Keyboard Event 2 Configuration). These bits configure the keyboard data sequence for Keyboard
Event 2, which indicates that “PM Key 2” was pressed on the keyboard. The setting of the EVT2CFG field is
relevant only if the Keyboard/Mouse Wake-up Detector is in Power Management Key mode (KBDMODE = 1).
The keyboard data sequence used to detect Keyboard Event 2 is stored in registers PS2KEY3 to PS2KEY5,
starting with PS2KEY3.
Bits
3 2
Sequence Length
0
0
1
1
0 bytes - Keyboard Event 2 disabled (default)
1 byte (PS2KEY3)
2 bytes (PS2KEY3, PS2KEY4)
3 bytes (PS2KEY3, PS2KEY4, PS2KEY5)
0:
1:
0:
1:
EVT1CFG (Keyboard Event 1 Configuration). These bits configure the keyboard data sequence for Keyboard
Event 1, which indicates that “PM Key 1” was pressed on the keyboard. The setting of the EVT1CFG field is
relevant only if the Keyboard/Mouse Wake-up Detector is in Power Management Key mode (KBDMODE = 1).
The keyboard data sequence used to detect Keyboard Event 1 is stored in registers PS2KEY0 to PS2KEY2,
starting with PS2KEY0.
Bits
1 0
Sequence Length
0
0
1
1
0 bytes - Keyboard Event 1 disabled (default)
1 byte (PS2KEY0)
2 bytes (PS2KEY0, PS2KEY1)
3 bytes (PS2KEY0, PS2KEY1, PS2KEY2)
0:
1:
0:
1:
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PC8741x
9.0 System Wake-Up Control (SWC)
(Continued)
9.3.17 PS2 Protocol Control Register (PS2CTL)
This register configures the keyboard and mouse events detected by the Keyboard/Mouse Wake-up Detector. It is reset
by hardware to 00h.
Power Well:VPP
Location: Bank 0, Offset 13h
Type:
R/W
Bit
7
6
Name
DISPAR
Reset
0
5
6-4
3-0
3
2
MSEVCFG
0
Bit
7
4
0
1
0
0
0
KBEVCFG
0
0
0
Description
DISPAR (Disable Parity Check). This controls the parity checking of the keyboard and mouse data by the
Keyboard/Mouse Wake-up Detector.
0: Enable parity check (default)
1: Disable parity check
MSEVCFG (Mouse Event Configuration). These bits configure the mouse data sequence for the Mouse event.
Before setting them to a new value, these bits must be cleared by writing a value of 000b.
Bits
6 5 4
Event Configuration
0
0
0
0
1
1
1
1
Disable mouse wake-up detection (default)
Wake-up on any mouse movement or button click
Wake-up on left button click
Wake-up on left button double-click
Wake-up on right button click
Wake-up on right button double-click
Wake-up on any button single-click (left, right or middle)
Wake-up on any button double-click (left, right or middle)
0
0
1
1
0
0
1
1
0:
1:
0:
1:
0:
1:
0:
1:
KBEVCFG (Keyboard Event Configuration). These bits configure the keyboard data sequence for the
Keyboard event, which indicates that any key or key sequence was pressed on the keyboard. The setting of the
KBEVCFG field is relevant only if the Keyboard/Mouse Wake-up Detector is in either Special Key Sequence or
Password mode (KBDMODE = 0). The keyboard data sequence used to detect a Keyboard Event is stored in
registers PS2KEY0 to PS2KEY7, starting with PS2KEY0. Before setting them to a new value, the KBEVCFG
field must be cleared by writing a value of 0000b.
Bits
3 2 1 0
Event Configuration
0 0 0 0:
Disable keyboard wake-up detection (default)
0 0 0 1
to
0 1 1 1
1 0 0 0
to
1 1 1 1
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}
}
Special Key Sequence mode 2-8 PS/2 data bytes, “Make” and “Break” (including Shift and Alt keys)
Password Enabled mode with 1-8 keys “Make” code (excluding Shift and Alt keys)
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9.0 System Wake-Up Control (SWC)
(Continued)
9.3.18 Keyboard Data Shift Register (KDSR)
When keyboard wake-up detection is enabled, this register stores the keyboard data shifted in from the keyboard during
transmission. It is reset by hardware to 00h.
Power Well:VPP
Location: Bank 0, Offset 16h
Type:
RO
Bit
7
6
5
Name
3
2
1
0
0
0
0
Keyboard Data
Reset
0
0
0
Bit
7-0
4
0
0
Description
Keyboard Data.
9.3.19 Mouse Data Shift Register (MDSR)
When mouse wake-up detection is enabled, this register stores the mouse data shifted in from the mouse during
transmission. It is reset by hardware to 00h.
Power Well:VPP
Location: Bank 0, Offset 17h
Type:
RO
Bit
7
6
0
0
Name
5
4
3
2
0
0
0
Reserved
Reset
0
Bit
1
0
Mouse Data
0
0
Description
7-3
Reserved.
2-0
Mouse Data.
9.3.20 PS2 Keyboard Key Data 0 to 7 Registers (PS2KEY0 to PS2KEY7)
These eight registers (PS2KEY0-PS2KEY7) store the data bytes for Special Key Sequence or Password mode
(KBDMODE = 0) or for Power Management Key mode (KBDMODE = 1) of the Keyboard/Mouse Wake-up Detector.
In Special Key Sequence or in Password modes, the keyboard data is stored as follows:
●
PS2KEY0 register stores the data byte for the first key in the sequence.
●
PS2KEY1 register stores the data byte for the second key in the sequence.
●
PS2KEY2 - PS2KEY7 registers store data bytes for the third to eighth key in the sequence.
For keyboard data storage in Power Management Key mode, see Section 9.3.16 on page 193.
When one of these registers is set to 00h, it indicates that the value of the corresponding data byte is ignored (not compared).
These registers are reset by hardware to 00h.
Power Well: VPP
Location: Bank 0, Offset 18h to 1Fh
Type:
Bit
R/W
7
6
5
Name
Reset
Revision 1.2
3
2
1
0
0
0
0
Data Byte of Key
0
Bit
7-0
4
0
0
0
0
Description
Data Byte of Key.
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PC8741x
9.0 System Wake-Up Control (SWC)
(Continued)
9.3.21 VDD Active Timer 0 Register (VDD_ON_TMR_0)
This register holds a copy of bits 0-7 of the VDD Active Timer. Whenever the VDD_ON_TMR_0 register is read, the
updating of all four VDD_ON_TMR_0 to VDD_ON_TMR_3 registers is stopped, freezing the count value. Therefore, this
register must be read first. It is reset by hardware to 00h.
Power Well:VPP
Location: Bank 1, Offset 10h
Type:
RO
Bit
7
6
5
4
2
1
0
0
0
0
VDD Timer Data Bits 0-7
Name
Reset
0
0
0
0
Bit
7-0
3
0
Description
VDD Timer Data, bits 0-7. An LSBit is equivalent to 1 second of the VDD power being active (On).
9.3.22 VDD Active Timer 1 Register (VDD_ON_TMR_1)
This register holds a copy of bits 8-15 of the VDD Active Timer. It is reset by hardware to 00h.
Power Well:VPP
Location: Bank 1, Offset 11h
Type:
RO
Bit
7
6
5
4
Reset
0
0
0
0
Bit
7-0
3
2
1
0
0
0
0
2
1
0
0
0
0
VDD Timer Data Bits 8-15
Name
0
Description
VDD Timer Data, bits 8-15.
9.3.23 VDD Active Timer 2 Register (VDD_ON_TMR_2)
This register holds a copy of bits 16-23 of the VDD Active Timer. It is reset by hardware to 00h.
Power Well:VPP
Location:Bank 1, Offset 12h
Type:
RO
Bit
7
6
5
3
VDD Timer Data Bits 16-23
Name
Reset
0
0
Bit
7-0
4
0
0
0
Description
VDD Timer Data, bits 16-23.
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9.3.24 VDD Active Timer 3 Register (VDD_ON_TMR_3)
This register holds a copy of bits 24-31 of the VDD Active Timer. Whenever the VDD_ON_TMR_3 register is read, the
updating of all four VDD_ON_TMR_0 to VDD_ON_TMR_3 registers is resumed. Therefore, this register must be read
last. It is reset by hardware to 00h.
Power Well:VPP
Location: Bank 1, Offset 13h
Type:
RO
Bit
7
6
5
4
2
1
0
0
0
0
VDD Timer Data Bits 24-31
Name
Reset
0
0
0
0
Bit
7-0
3
0
Description
VDD Timer Data, bits 24-31.
9.3.25 VSB Active Timer 0 Register (VSB_ON_TMR_0)
This register holds a copy of bits 0-7 of the VSB Active Timer. Whenever the VSB_ON_TMR_0 register is read, the
updating of all four VSB_ON_TMR_0 to VSB_ON_TMR_3 registers is stopped, freezing the count value. Therefore, this
register must be read first. It is reset by hardware to 00h.
Power Well:VPP
Location: Bank 1, Offset 14h
Type:
RO
Bit
7
6
5
4
Name
Reset
0
0
0
0
Bit
7-0
3
2
1
0
0
0
0
VSB Timer Data Bits 0-7
0
Description
VSB Timer Data, bits 0-7. An LSBit is equivalent to 1 second of the VDD power being active (On).
9.3.26 VSB Active Timer 1 Register (VSB_ON_TMR_1)
This register holds a copy of bits 8-15 of the VSB Active Timer. It is reset by hardware to 00h.
Power Well:VPP
Location: Bank 1, Offset 15h
Type:
Bit
RO
7
6
5
Name
Reset
0
0
Bit
7-0
Revision 1.2
4
3
2
1
0
0
0
0
VSB Timer Data Bits 8-15
0
0
0
Description
VSB Timer Data, bits 8-15.
197
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9.3.27 VSB Active Timer 2 Register (VSB_ON_TMR_2)
This register holds a copy of bits 16-23 of the VSB Active Timer. It is reset by hardware to 00h.
Power Well:VPP
Location:Bank 1, Offset 16h
Type:
RO
Bit
7
6
5
4
2
1
0
0
0
0
VSB Timer Data Bits 16-23
Name
Reset
0
0
0
0
Bit
7-0
3
0
Description
VSB Timer Data, bits 16-23.
9.3.28 VSB Active Timer 3 Register (VSB_ON_TMR_3)
This register holds a copy of bits 24-31 of the VSB Active Timer. Whenever the VSB_ON_TMR_3 register is read, the
updating of all four VSB_ON_TMR_0 to VSB_ON_TMR_3 registers is resumed. Therefore, this register must be read
last. It is reset by hardware to 00h.
Power Well: VPP
Location: Bank 1, Offset 17h
Type:
RO
Bit
7
6
5
3
2
1
0
0
0
0
VSB Timer Data Bits 24-31
Name
Reset
0
0
Bit
7-0
4
0
0
0
Description
VSB Timer Data, bits 24-31.
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9.3.29 Power Active Timers Control Register (PWTMRCTL)
This register controls the reset by software of the VDD and VSB Active Timers. It is reset by hardware to 00h.
Power Well:VPP
Location: Bank 1, Offset 18h
Type:
Varies per bit
Bit
7
Name
LOCK
_TMRRST
Reset
0
Bit
7
4
3
Reserved
0
0
0
1
0
VSB_TMR
_RST
2
Reserved
VDD_TMR
_RST
0
0
0
0
Description
R/W1S LOCK_TMRRST (Lock Timers Reset). When set to 1, this bit locks the VSB_TMR_RST and
VDD_TMR_RST bits by disabling the writing to them (including to the LOCK_TMRRST bit itself). Once
set, this bit can be cleared either by VDD Power-Up reset (or Hardware reset) or by VSB Power-Up
reset, according to the VSBLOCK bit in the ACBLKCTL register (see Section 6.3.4 on page 128). In
addition, this bit is cleared by setting the UNLOCKS bit in the ACBLKCTL register (PC87413 and
PC87417).
0: R/W bits are enabled for write (default)
1: All bits are RO
Reserved.
R/W or VSB_TMR_RST (VSB Active Timer Reset). Writing ‘1’ to this bit resets the VSB Active Timer (the timer
RO is reset within 1 second following the write). This bit then returns to ‘0’ (read always returns ‘0’).
0: Inactive (default)
1: Reset the VSB Active Timer
1
0
5
Type
6-3
2
6
Reserved.
R/W or VDD_TMR_RST (VDD Active Timer Reset). Writing ‘1’ to this bit resets the VDD Active Timer (the timer
RO is reset within 1 second following the write). This bit then returns to ‘0’ (read always returns ‘0’).
0: Inactive (default)
1: Reset the VDD Active Timer
9.3.30 S0 to S5 Sleep Type Encoding Registers (S0_SLP_TYP to S5_SLP_TYP)
These registers hold the system Sleep Type encoding for each sleep state: Working (G0/S0), Sleeping (G1/S1-S4) and
Soft-off (G2/S5). The Sleep Type is defined by the SLP_TYPx field of the PM1b_CNT_HIGH register (see Section 9.4.7
on page 208). These registers are reset by hardware to 00h.
Power Well:VPP
Location: Bank 2, Offset 10h to 15h
Type:
R/W or RO
Bit
7
6
Name
5
4
3
2
Reserved
Reset
0
Bit
0
0
1
0
SLP_TYP_ENC
0
0
0
0
0
Description
7-3
Reserved.
2-0
SLP_TYP_ENC (Sleep Type Encoding). The value used by the system for the sleep state defined by the
specific register. This value must always be set after VPP reset (default = 000b). For sleep states not supported
by the system, select an unused value.
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9.3.31 Sleep State Configuration Register (SLP_ST_CFG)
This register controls the operation of the Sleep Type encoding. It is reset by hardware to 00h.
Power Well:VPP
Location:Bank 2, Offset 16h
Type:
Varies per bit
Bit
7
Name
LOCK
_SLP_ENC
Reset
0
Bit
7
6
5
4
3
Reserved
0
0
0
Type
0
2
1
0
EXT_ST
_SELECT
S3I
_VDD_ON
S4
_SELECT
0
0
0
Description
R/W1S LOCK_SLP_ENC (Lock Sleep Type Encoding). When set to 1, this bit locks the S0_SLP_TYP to
S5_SLP_TYP and the SLP_ST_CFG registers by disabling the writing to them (including to the
LOCK_SLP_ENC bit itself). Once set, this bit can be cleared either by VDD Power-Up reset (or
Hardware reset) or by VSB Power-Up reset, according to the VSBLOCK bit in the ACBLKCTL register
(see Section 6.3.4 on page 128). In addition, this bit is cleared by setting the UNLOCKS bit in the
ACBLKCTL register (PC87413 and PC87417).
0: R/W bits are enabled for write (default)
1: All bits are RO
6-3
Reserved.
2
R/W or EXT_ST_SELECT (External Sleep State Select). Selects the source of the current sleep states.
RO 0: SLP_TYPx field in the PM1b_CNT_HIGH register (see Section 9.4.7 on page 208); (default)
1: SLPS3 and SLPS5 signals from an external ACPI controller (see also the EXTSTMUX bit in the
SIOCF3 register, Section 3.7.4 on page 51)
1
R/W or S3I_VDD_ON (VDD-On in S3I Select). Selects the state of the VDD power supply in the S3I current
RO sleep state.
0: VDD power supply Off (default)
1: VDD power supply On
0
R/W or S4_SELECT (S4 Select). Selects whether the sleep state S4 (if supported) is included in either S3I or
RO S45 current sleep states.
0: S45 = S5 or S4 (default)
1: S3I = S3 or S4
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9.3.32 ACPI Configuration Register (ACPI_CFG)
This register configures some of the ACPI wake-up events and the PWBTOUT operation mode. It is reset by hardware to
00h.
Power Well:VPP
Location: Bank 2, Offset 17h
Type:
R/W
Bit
7
Name
PWBTOUT
_MODE
Reset
0
6
5
4
3
Reserved
0
0
0
0
2
1
0
RTC_EV
_DIS
SLPBTN
_EV_DIS
PWRBTN
_EV_DIS
0
0
0
Bit
Description
7
PWBTOUT_MODE (PWBTOUT Mode). When reset, this bit enables the pulsing of the PWBTOUT pin whenever
an enabled wake-up event occurs.
0: PWBTOUT pulsed by (default):
— PWBTIN activation
— Crowbar condition
— Wake-Up events
1: PWBTOUT pulsed by:
— PWBTIN activation
— Crowbar condition
6-3
Reserved.
2
RTC_EV_DIS (RTC Event Disable). Disables the RTC alarm event to the PM1b_STS_HIGH and
PM1b_EN_HIGH, ACPI registers (RTC_STS = 0, RTC_EN = 0). However, the RTC_EVT_STS bit in the
GPE1_STS_3 register and the RTC_EVT_EN bit in the GPE1_EN_3 register are not affected.
0: Disable event (default)
1: Enable the RTC alarm event
1
SLPBTN_EV_DIS (Sleep Button Event Disable). Enables the Sleep button pressing event to the
PM1b_STS_HIGH and PM1b_EN_HIGH ACPI registers (SLPBTN_STS = 0, SLPBTN_EN = 0). The
SLBT_EVT_STS bit in the GPE1_STS_2 register and the SLBT_EVT_EN bit in the GPE1_EN_2 register are not
affected.
0: Disable event (default)
1: Enable Sleep button pressing event
0
PWRBTN_EV_DIS (Power Button Event Disable). Enables the Power button pressing event to the
PM1b_STS_HIGH and PM1b_EN_HIGH ACPI registers (PWRBTN_STS = 0, PWRBTN_EN = 0). The
PWBT_EVT_STS bit in the GPE1_STS_2 register and the PWBT_EVT_EN bit in the GPE1_EN_2 register are
not affected.
0: Disable event (default)
1: Enable Power button pressing event
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9.3.33 Watchdog Control Register (WDCTL)
This register contains the control bits for the watchdog. It is reset by hardware to 00h.
Power Well:VSB
Location: Bank 3, Offset 10h
Type:
Varies per bit
Bit
7
Name
SW_WD
_TRG
Reset
0
6
5
4
3
2
1
Reserved
0
0
0
0
WDEN
0
0
0
0
Bit
Type
Description
7
R/W
SW_WD_TRG (Software Watchdog Trigger). Writing ‘1’ to this bit triggers the watchdog to start a new
count. This bit then returns to ‘0’ (read always returns ‘0’).
0: Inactive (default)
1: Triggers a new watchdog count
6-1
0
Reserved.
R/W1S WDEN (Watchdog Enable). When set to 1, this bit enables the watchdog function. Once set, this bit
can be cleared either by VDD Power-Up reset, or by VSB Power-Up reset.
0: Watchdog disabled (default)
1: Watchdog enabled
9.3.34 Watchdog Time-Out Register (WDTO)
This register contains the watchdog time-out period. It is reset by hardware to 01h.
Power Well:VSB
Location: Bank 3, Offset 11h
Type:
R/W
Bit
7
6
5
Name
3
2
1
0
0
0
1
Watchdog Time-Out Data
Reset
0
Bit
7-0
4
0
0
0
0
Description
Watchdog Time-Out Data. The load value for the watchdog down counter. The value defines the time-out in
minutes for a span of: 1 to 255 minutes. The 00h value is reserved.
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9.3.35 Watchdog Configuration Register (WDCFG)
This register contains the enable bits for the watchdog trigger sources. Reset all the bits before writing a new value to the
WDTO register. It is reset by hardware to 00h.
Power Well:VSB
Location:Bank 3, Offset 12h
Type:
R/W
Bit
7
Name
SW_WD
_TREN
Reset
0
Bit
7
6-4
6
5
4
Reserved
0
0
3
2
1
0
SER2_IRQ
_TREN
SER1_IRQ
_TREN
MS_IRQ
_TREN
KBD_IRQ
_TREN
0
0
0
0
0
Description
SW_WD_TREN (Software Watchdog Trigger Enable). Enables the event of the software writing a ‘1’ to the
SW_WD_TRG bit in the WDCTL register (see Section 9.3.33) to trigger the watchdog to start a new count.
0: Disable trigger (default)
1: Enable trigger by the SW_WD_TRG bit in the WDCTL register
Reserved.
3
SER2_IRQ_TREN (Serial Port 2 IRQ, Watchdog Trigger Enable). Enables an active IRQ from the Serial Port
2 to trigger the watchdog to start a new count.
0: Disable trigger (default)
1: Enable trigger by an active IRQ from the Serial Port 2
2
SER1_IRQ_TREN (Serial Port 1 IRQ, Watchdog Trigger Enable). Enables an active IRQ from the Serial Port
1 to trigger the watchdog to start a new count.
0: Disable trigger (default)
1: Enable trigger by an active IRQ from the Serial Port 1
1
MS_IRQ_TREN (Mouse IRQ, Watchdog Trigger Enable). Enables an active IRQ from the mouse interface
section of the KBC module to trigger the watchdog to start a new count.
0: Disable trigger (default)
1: Enable trigger by an active IRQ from the mouse interface section of the KBC module
0
KBD_IRQ_TREN (Keyboard IRQ, Watchdog Trigger Enable). Enables an active IRQ from the keyboard
interface section of the KBC module to trigger the watchdog to start a new count.
0: Disable trigger (default)
1: Enable trigger by an active IRQ from the keyboard interface section of the KBC module
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9.4
(Continued)
ACPI REGISTERS
The ACPI registers are organized in three groups, all of which are VSB powered. The offsets are related to the base address
determined by the Base Address registers at indexes 62h - 67h in the SWC device configuration.
The PC8741x devices support the following ACPI fixed register groups:
•
•
•
PM1 Event Group (block b), containing the PM1b_STS and PM1b_EN registers, each with a length of two bytes.
PM1 Control Group (block b), containing the PM1b_CNT register with a length of 2 bytes.
General-Purpose Event 1 Group, containing the GPE1_STS and GPE1_EN registers, each with a length of four bytes.
The following abbreviations are used to indicate the Register Type:
●
R/W
= Read/Write.
●
R
= Read from a specific register (write to the same address is to a different register).
●
W
= Write (see above).
●
RO
= Read Only.
●
WO
= Write Only. Reading from the bit returns 0.
●
R/W1C = Read/Write 1 to Clear. Writing 1 to a bit clears it to 0. Writing 0 has no effect.
●
R/W1S = Read/Write 1 to Set. Writing 1 to a bit sets its value to 1. Writing 0 has no effect.
9.4.1
ACPI Register Map
The following table lists the ACPI registers. All these registers are VSB powered.
Base
Registers
At index
62h, 63h
At index
64h, 65h
At index
66h, 67h
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Offset
Mnemonic
Register Name
Type
Power Well Section
00h
PM1b_STS_LOW PM1 Status Low Register
RO
VSB
9.4.2
01h
PM1b_STS_HIGH PM1 Status High Register
R/W1C
VSB
9.4.3
02h
PM1b_EN_LOW PM1 Enable Low Register
RO
VSB
9.4.4
03h
PM1b_EN_HIGH PM1 Enable High Register
R/W
VSB
9.4.5
00h
PM1b_CNT_LOW PM1 Control Low Register
RO
VSB
9.4.6
01h
PM1b_CNT_HIGH PM1 Control High Register
Varies per bit
VSB
9.4.7
00h
GPE1_STS_0
General-Purpose Status 1 Register 0
R/W1C
VSB
9.4.8
01h
GPE1_STS_1
General-Purpose Status 1 Register 1
R/W1C
VSB
9.4.9
02h
GPE1_STS_2
General-Purpose Status 1 Register 2
R/W1C
VSB
9.4.10
03h
GPE1_STS_3
General-Purpose Status 1 Register 3
R/W1C
VSB
9.4.11
04h
GPE1_EN_0
General-Purpose Enable 1 Register 0
R/W
VSB
9.4.12
05h
GPE1_EN_1
General-Purpose Enable 1 Register 1
R/W
VSB
9.4.13
06h
GPE1_EN_2
General-Purpose Enable 1 Register 2
R/W
VSB
9.4.14
07h
GPE1_EN_3
General-Purpose Enable 1 Register 3
R/W
VSB
9.4.15
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PM1 Status Low Register (PM1b_STS_LOW)
This register contains the eight low bits of the PM1_STS register. The PC8741x devices contain the block ‘b’ instance of the
PM1_STS register. This register belongs to the PM1 Event Group of the ACPI fixed-feature space registers.
PM1_STS register bits that are specified by the ACPI but not implemented in the PC8741x devices have a ‘0’ value.
Power Well:VSB
Location: Offset 00h
Type:
RO
Bit
7
Name
6
Reserved
Reset
0
0
5
4
GBL_STS
BM_STS
0
0
Bit
7-6
3
0
TMR_STS
0
0
Reserved.
4
BM_STS (Bus Master Status). Not implemented. Always at ‘0’.
9.4.3
0
0
Description
GBL_STS (Global Lock Status). Not implemented. Always at ‘0’.
0
1
Reserved
5
3-1
2
Reserved.
TMR_STS (PM Timer Status). Not implemented. Always at ‘0’.
PM1 Status High Register (PM1b_STS_HIGH)
This register contains the eight high bits of the PM1_STS register. The PC8741x devices contain the block ‘b’ instance of
the PM1_STS register. This register belongs to the PM1 Event Group of the ACPI fixed-feature space registers.
PM1_STS register bits that are specified by the ACPI but not implemented in the PC8741x devices have a ‘0’ value. All the
implemented status bits behave according to the Sticky Status Bit definition (the bit is set by the HIGH level of the hardware
signal and is only cleared by the software writing ‘1’ to it) in the ACPI Specification.
Power Well:VSB
Location: Offset 01h
Type:
R/W1C
Bit
7
Name
WAK_STS
Reset
0
6
5
4
Reserved
0
0
3
2
1
0
Ignored
RTC_STS
SLPBTN
_STS
PWRBTN
_STS
0
0
0
0
0
Bit
Description
7
WAK_STS (Wake-up Event Status). Indicates that a power management event, enabled to generate SCI, has
occurred. This bit is set only if the system is in a sleep state (S1-S5). Writing ‘1’ while the system is in the
working state (S0), clears this bit; writing ‘0’ is ignored. When the system is in a sleep state (S1-S5) and an
enabled event is active, writing ‘1’ does not clear the WAK_STS bit.
0: Inactive (default)
1: At least one event enabled to SCI was active while the system was in a sleep state (S1-S5), since this bit was
last cleared
6-4
3
Revision 1.2
Reserved.
Ignored. The data written is ignored; the data read is undefined.
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Bit
Description
2
RTC_STS (RTC Event Status). Indicates that an enabled RTC alarm has occurred. This bit is set by the RTC
alarm becoming active. Writing ‘1’ clears this bit and the RTC_EVT_STS bit in the GPE1_STS_3 register; writing
‘0’ is ignored. This bit is forced to ‘0’ when the RTC_EV_DIS bit in the ACPI_CFG register is reset to ‘0’, ignoring
any RTC alarm.
0: Inactive (default)
1: An RTC alarm has occurred
1
SLPBTN_STS (Sleep Button Event Status). Indicates that the Sleep button was pressed. This feature is
compatible with the ACPI model for a two-button system. The SLBTIN signal is internally debounced. Writing ‘1’
clears this bit and the SLBT_EVT_STS bit in the GPE1_STS_2 register; writing ‘0’ is ignored. This bit is forced
to ‘0’ when the SLPBTN_EV_DIS bit in the ACPI_CFG register is reset to ‘0’, ignoring any Sleep button event.
0: Inactive (default)
1: The Sleep button was pressed
0
PWRBTN_STS (Power Button Event Status). Indicates that the Power button was pressed. This feature is
compatible with the ACPI model for both a single-button and a two-button system. The PWBTIN signal is
internally debounced. Writing ‘1’ clears this bit and the PWBT_EVT_STS bit in the GPE1_STS_2 register; writing
‘0’ is ignored. This bit is forced to ‘0’ when the PWRBTN_EV_DIS bit in the ACPI_CFG register is reset to ‘0’,
ignoring any Power button event. This bit is also cleared in Legacy Power Button mode (LEGACY_PWBT = 1
in PWONCTL) when VDD is turned off by pressing the Power button.
0: Inactive (default)
1: The Power button was pressed
9.4.4
PM1 Enable Low Register (PM1b_EN_LOW)
This register contains the eight low bits of the PM1_EN register. The PC8741x devices contain the block ‘b’ instance of the
PM1_EN register. This register belongs to the PM1 Event Group of the ACPI fixed-feature space registers.
PM1_EN register bits that are specified by the ACPI but not implemented in the PC8741x devices have a ‘0’ value.
Power Well:VSB
Location: Offset 02h
Type:
RO
Bit
7
Name
Reserved
Reset
0
Bit
7-6
5
4-1
0
6
5
4
3
GBL_EN
0
0
2
1
Reserved
0
0
0
TMR_EN
0
0
0
Description
Reserved.
GBL_EN (Global Lock Enable). Not implemented. Always at ‘0’.
Reserved.
TMR_EN (PM Timer Enable). Not implemented. Always at ‘0’.
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PM1 Enable High Register (PM1b_EN_HIGH)
This register contains the eight high bits of the PM1_EN register. The PC8741x devices contain the block ‘b’ instance of the
PM1_EN register. This register belongs to the PM1 Event Group of the ACPI fixed-feature space registers.
PM1_EN register bits that are specified by the ACPI but not implemented in the PC8741x devices have a ‘0’ value. All the implemented enable bits behave according to the Enable Bit definition (the bit is read/write by software) in the ACPI Specification.
Power Well:VSB
Location: Offset 03h
Type:
R/W
Bit
7
6
Name
4
3
Reserved
Reset
0
Bit
7-3
5
0
0
0
0
2
1
0
RTC_EN
SLPBTN
_EN
PWRBTN
_EN
0
0
0
Description
Reserved.
2
RTC_EN (RTC Event Enable). Enables the RTC alarm to generate a power management interrupt (SIOSCI).
This bit is forced to ‘0’ when the RTC_EV_DIS bit in the ACPI_CFG register is reset to ‘0’, disabling any RTC
alarm event.
0: Disable SCI (default)
1: Enable SCI from RTC alarm
1
SLPBTN_EN (Sleep Button Event Enable). Enables Sleep button pressing to generate a power management
interrupt (SIOSCI). This bit is forced to ‘0’ when the SLPBTN_EV_DIS bit in the ACPI_CFG register is reset to
‘0’, disabling any Sleep button event.
0: Disable SCI (default)
1: Enable SCI from Sleep button pressing
0
PWRBTN_EN (Power Button Event Enable). Enables Power button pressing to generate a power management
interrupt (SIOSCI) when the system is in the active state (S0). This bit does not influence SCI generation when
the system is in a sleep state (S1-S5). This bit is forced to ‘0’ when the PWRBTN_EV_DIS bit in the ACPI_CFG
register is reset to ‘0’, disabling any Power button event.
0: Disable SCI (default)
1: Enable SCI from Power button pressing
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PC8741x
9.0 System Wake-Up Control (SWC)
9.4.6
(Continued)
PM1 Control Low Register (PM1b_CNT_LOW)
This register contains the eight low bits of the PM1_CNT register. The PC8741x devices contain the block ‘b’ instance of the
PM1_CNT register. This register belongs to the PM1 Control Group of the ACPI fixed-feature space registers.
PM1_CNT register bits that are specified by the ACPI but not implemented in the PC8741x devices have a ‘0’ value.
Power Well:VSB
Location:Offset 00h
Type:
RO
Bit
7
6
Name
5
3
Reserved
Reset
0
0
0
Bit
7-3
4
0
2
1
0
GBL_RLS
BM_RLD
SCI_EN
0
0
0
0
Description
Reserved.
2
GBL_RLS (Global Lock Release). Not implemented. Always at ‘0’.
1
BM_RLD (Bus Master Request Control). Not implemented. Always at ‘0’.
0
SCI_EN (SCI Enable). Not implemented. Always at ‘0’.
9.4.7
PM1 Control High Register (PM1b_CNT_HIGH)
This register contains the eight high bits of the PM1_CNT register. The PC8741x devices contain the block ‘b’ instance of
the PM1_CNT register. This register belongs to the PM1 Control Group of the ACPI fixed-feature space registers.
PM1_CNT register bits that are specified by the ACPI but not implemented in the PC8741x devices have a ‘0’ value. All the
implemented control bits behave according to the Control bit definition (the bit is read/write by software) and Write-Only Control Bit definition (the bit is written by software; when read, it returns 0) in the ACPI Specification.
Power Well:VSB
Location: Offset 01h
Type:
Varies per bit
Bit
7
Name
6
Reserved
Reset
0
Bit
Type
7-6
-
5
WO
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5
4
SLP_EN
0
0
3
2
SLP_TYPx
0
0
0
1
0
Ignored
Reserved
0
0
Description
Reserved.
SLP_EN (Sleep Enable). Setting this bit causes the PC8741x device to accept the value of SLP_TYPx
as the system state code. This bit may be set in the same write cycle with a new SLP_TYPx value.
0: Inactive (default)
1: Update the system state code from the SLP_TYPx value
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Bit
Type
4-2
R/W
PC8741x
9.0 System Wake-Up Control (SWC)
(Continued)
Description
SLP_TYPx (Sleep Type). This field defines the system sleep state type (encoded). The states
supported by the PC8741x devices are: Working (G0/S0), Sleeping (G1/S1-S4) and Soft-off (G2/S5).
The encoding of the sleep state is programmed through the VPP-powered registers S0_SLP_TYP to
S5_SLP_TYP.
Bits
2 1 0 Function
0 0 0: Encoded 3-bit value for state Sn (n = 0-5); (default)
x x x: Encoded 3-bit value (except 000b) for the remaining 5 sleep states: Sn (n = 0-5)
1
-
Ignored. The data written is ignored; the data read is undefined.
0
-
Reserved.
9.4.8
General-Purpose Status 1 Register 0 (GPE1_STS_0)
This register contains bits 0-7 of the GPE1_STS register. This register belongs to the General-Purpose Event 1 Group of
the ACPI fixed-feature space registers.
The status bits behave according to the Sticky Status Bit definition (the bit is set by the HIGH level of the hardware signal
and is only cleared by the software writing ‘1’ to it) in the ACPI Specification.
Power Well:VSB
Location: Offset 00h
Type:
R/W1C
Bit
7
6
5
4
3
2
1
0
Name
GPIOE17
_STS
GPIOE16
_STS
GPIOE15
_STS
GPIOE14
_STS
GPIOE13
_STS
GPIOE12
_STS
GPIOE11
_STS
GPIOE10
_STS
Reset
0
0
0
0
0
0
0
0
Bit
Description
7
GPIOE17_STS (GPIOE17 Event Status). Indicates that an active event has been detected at pin 7 of the
GPIOE Port 1. The event has programmable polarity and the debounce option (see Section 7.3.1 on page 137).
The bit is set by an active level at the GPIOE17 pin. Writing ‘1’ clears this bit; writing ‘0’ is ignored.
0: Inactive since last cleared (default)
1: An active event has occurred
6-0
9.4.9
GPIOE16_STS to GPIOE10_STS (GPIOE16 to GPIOE10 Event Status). Same as above for pins 6-0 of the
GPIOE Port 1.
General-Purpose Status 1 Register 1 (GPE1_STS_1)
This register contains bits 8-15 of the GPE1_STS register. This register belongs to the General-Purpose Event 1 Group of
the ACPI fixed-feature space registers.
The status bits behave according to the Sticky Status Bit definition (the bit is set by the HIGH level of the hardware signal
and is only cleared by the software writing ‘1’ to it) in the ACPI Specification.
Power Well:VSB
Location: Offset 01h
Type:
Bit
R/W1C
7
6
5
4
3
2
1
0
Name
GPIOE47
_STS
GPIOE46
_STS
GPIOE45
_STS
GPIOE44
_STS
GPIOE43
_STS
GPIOE42
_STS
GPIOE41
_STS
GPIOE40
_STS
Reset
0
0
0
0
0
0
0
0
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9.0 System Wake-Up Control (SWC)
(Continued)
Bit
Description
7
GPIOE47_STS (GPIOE47 Event Status). Indicates that an active event has been detected at pin 7 of the
GPIOE Port 4. The event has programmable polarity and the debounce option (see Section 7.3.1 on page 137).
The bit is set by an active level at the GPIOE47 pin. Writing ‘1’ clears this bit; writing ‘0’ is ignored.
0: Inactive since last cleared (default)
1: An active event has occurred
6-0
GPIOE46_STS to GPIOE40_STS (GPIOE46 to GPIOE40 Event Status). Same as above for pins 6-0 of the
GPIOE Port 4.
9.4.10 General-Purpose Status 1 Register 2 (GPE1_STS_2)
This register contains bits 16-23 of the GPE1_STS register. This register belongs to the General-Purpose Event 1 Group of
the ACPI fixed-feature space registers.
The status bits behave according to the Sticky status bit definition (the bit is set by the HIGH level of the hardware signal
and is only cleared by the software writing ‘1’ to it) in the ACPI Specification.
Power Well:VSB
Location: Offset 02h
Type:
R/W1C
Bit
7
6
5
4
3
PWBT_EVT SLBT_EVT KBD_EVT3 KBD_EVT2 KBD_EVT1
_STS
_STS
_STS
_STS
_STS
Name
Reset
0
0
0
0
0
2
1
0
MS_EVT
_STS
RI2_EVT
_STS
RI1_EVT
_STS
0
0
0
Bit
Description
7
PWBT_EVT_STS (Power Button Event Status). Indicates that the Power button was pressed. This bit is similar
to the PWRBTN_STS bit in the PM1b_STS_HIGH register. The PWBTIN signal is internally debounced. Writing
‘1’ clears this bit and the PWRBTN_STS bit in the PM1b_STS_HIGH register; writing ‘0’ is ignored. This bit is
also cleared in Legacy Power Button mode (LEGACY_PWBT = 1 in PWONCTL) when VDD is turned off by
pressing the Power button.
0: Inactive (default)
1: The Power button was pressed
6
SLBT_EVT_STS (Sleep Button Event Status). Indicates that the Sleep button was pressed. This bit is similar
to the SLPBTN_STS bit in the PM1b_STS_HIGH register. The SLBTIN signal is internally debounced. Writing
‘1’ clears this bit and the SLPBTN_STS bit in the PM1b_STS_HIGH register; writing ‘0’ is ignored.
0: Inactive (default)
1: The Sleep button was pressed
5
KBD_EVT3_STS (Keyboard Event 3 Status). Indicates that “PM Key 3” was pressed and that the event was
identified by the Keyboard/Mouse Wake-up Detector. This bit is set only if the Keyboard/Mouse Wake-up
Detector is in the Power Management Key mode (see Section 9.3.16 on page 193). Writing ‘1’ clears this bit;
writing ‘0’ is ignored.
0: Inactive since last cleared (default)
1: The “PM Key 3” key was pressed on the keyboard
4
KBD_EVT2_STS (Keyboard Event 2 Status). Indicates that “PM Key 2” was pressed and that the event was
identified by the Keyboard/Mouse Wake-up Detector. This bit is set only if the Keyboard/Mouse Wake-up
Detector is in the Power Management Key mode (see Section 9.3.16 on page 193). Writing ‘1’ clears this bit;
writing ‘0’ is ignored.
0: Inactive since last cleared (default)
1: The “PM Key 2” key was pressed on the keyboard
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9.0 System Wake-Up Control (SWC)
(Continued)
Bit
Description
3
KBD_EVT1_STS (Keyboard Event 1 Status). This bit indicates that a keyboard event occurred and was
identified by the Keyboard/Mouse Wake-up Detector. The event type depends on the selected operation mode
for the Keyboard/Mouse Wake-up Detector (see Sections 9.3.16 and 9.3.17 on pages 193ff.):
●
Pressing any key or a sequence of special keys in Special Key Sequence mode.
●
Pressing a sequence of keys in Password mode.
●
Pressing the “PM Key 1” in Power Management Key mode.
Writing ‘1’ clears this bit; writing ‘0’ is ignored.
0: Inactive since last cleared (default)
1: A keyboard event occurred
2
MS_EVT_STS (Mouse Event Status). Indicates that a mouse event occurred and was identified by the
Keyboard/Mouse Wake-up Detector (see Section 9.3.17 on page 194). Writing ‘1’ clears this bit; writing ‘0’ is
ignored.
0: Inactive since last cleared (default)
1: A mouse event occurred
1
RI2_EVT_STS (RI2 Event Status). Indicates that a telephone ring signal was received at Serial Port 2 and the
event was identified by the RI Wake-up Detector. This bit is set by a high-to-low transition at the RI2 pin (see
Section 9.2.1 on page 162). Writing ‘1’ clears this bit; writing ‘0’ is ignored.
0: Inactive since last cleared (default)
1: A telephone ring signal was received at the Serial Port 2
0
RI1_EVT_STS (RI1 Event Status). Indicates that a telephone ring signal was received at Serial Port 1 and the
event was identified by the RI Wake-up Detector. This bit is set by a high-to low transition at the RI1 pin (see
Section 9.2.1 on page 162). Writing ‘1’ clears this bit; writing ‘0’ is ignored.
0: Inactive since last cleared (default)
1: A telephone ring signal was received at the Serial Port 1
9.4.11 General-Purpose Status 1 Register 3 (GPE1_STS_3)
This register contains bits 24-31 of the GPE1_STS register. This register belongs to the General-Purpose Event 1 Group of
the ACPI fixed-feature space registers.
The status bits behave according to the Sticky Status Bit definition (the bit is set by the HIGH level of the hardware signal
and is only cleared by the software writing ‘1’ to it) in the ACPI Specification.
Power Well:VSB
Location: Offset 03h
Type:
Bit
R/W1C
7
6
5
4
3
2
1
0
Name
SW_OFF
_STS
SW_ON
_STS
WDO_EVT
_STS
MOD_IRQ
_STS
MS_IRQ
_STS
KBD_IRQ
_STS
P12_EVT
_STS
RTC_EVT
_STS
Reset
0
0
0
0
0
0
0
0
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PC8741x
9.0 System Wake-Up Control (SWC)
(Continued)
Bit
Description
7
SW_OFF_STS (Software Off Event Status). Indicates that the software wrote a ‘1’ to the SW_OFF_CTL bit in
the SWC_CTL register to request a VDD power off sequence. Writing ‘1’ clears this bit; writing ‘0’ is ignored.
0: Inactive since last cleared (default)
1: ‘1’ was written to the SW_OFF_CTL bit in the SWC_CTL register
6
SW_ON_STS (Software On Event Status). Indicates that the software wrote a ‘1’ to the SW_ON_CTL bit in the
SWC_CTL register to request a VDD Power On sequence. When the VDD power is off, the SW_ON_CTL bit can
be written only through the ACCESS.bus (PC87413 and PC87417). Writing ‘1’ clears this bit; writing ‘0’ is
ignored.
0: Inactive since last cleared (default)
1: ‘1’ was written to the SW_ON_CTL bit in the SWC_CTL register
5
WDO_EVT_STS (Watchdog Event Status). Indicates that watchdog time-out has occurred. Writing ‘1’ clears
this bit; writing ‘0’ is ignored.
0: Inactive (default)
1: A watchdog time-out has occurred
4
MOD_IRQ_STS (Modules IRQ Event Status). Indicates that an IRQ was generated by one of the Legacy
modules (FDC, Parallel Port, Serial Port 1 and 2) or by the XIRQ pin (PC87416 and PC87417). For Legacy
modules IRQ, this bit is set only if the IRQ is enabled for wake-up (bit 4 of the Standard configuration register
at index 70h) and the related module is active (see Section 3.2.3 on page 40). For the XIRQ pin, this bit is set
only if XIRQ is enabled for wake-up by setting both the IRQEN and the PWUREN bits in the XIRQC register
(see Section 5.4.4 on page 110) to ‘1’. Writing ‘1’ clears this bit; writing ‘0’ is ignored.
0: Inactive since last cleared (default)
1: An enabled IRQ, from one of the Legacy modules or from the XIRQ pin, is active
3
MS_IRQ_STS (Mouse IRQ Event Status). Indicates that an IRQ was generated by the mouse interface section
of the KBC module. This bit is set only if the IRQ is enabled for wake-up (bit 4 of the Mouse Logical Device
configuration register at index 70h) and the KBC module is active (see Section 3.2.3 on page 40). Writing ‘1’
clears this bit; writing ‘0’ is ignored.
0: Inactive since last cleared (default)
1: An enabled IRQ, from the mouse interface section of the KBC module, is active
2
KBD_IRQ_STS (Keyboard IRQ Event Status). Indicates that an IRQ was generated by the keyboard interface
section of the KBC module. This bit is set only if the IRQ is enabled for wake-up (bit 4 of the Keyboard Logical
Device configuration register at index 70h) and the KBC module is active (see Section 3.2.3 on page 40). Writing
‘1’ clears this bit; writing ‘0’ is ignored.
0: Inactive since last cleared (default)
1: An enabled IRQ, from the keyboard interface section of the KBC module, is active
1
P12_EVT_STS (Port P12 Event Status). Indicates that an active high signal was generated by the KBC
module, at the P12 pin. This bit is set only if the KBC module is active (see Section 3.2.3 on page 40). Writing
‘1’ clears this bit; writing ‘0’ is ignored.
0: Inactive since last cleared (default)
1: An active high signal at the P12 pin was generated by the KBC module
0
RTC_EVT_STS (RTC Alarm Event Status). Indicates that an enabled RTC alarm has occurred. This bit is
similar to the RTC_STS bit in the PM1b_STS_HIGH register. Writing ‘1’ clears this bit and the RTC_STS bit in
the PM1b_STS_HIGH register; writing ‘0’ is ignored.
0: Inactive (default)
1: An RTC alarm has occurred
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9.0 System Wake-Up Control (SWC)
(Continued)
9.4.12 General-Purpose Enable 1 Register 0 (GPE1_EN_0)
This register contains bits 0-7 of the GPE1_EN register. This register belongs to the General-Purpose Event 1 Group of the
ACPI fixed-feature space registers.
The enable bits behave according to the Enable Bit definition (the bit is read/write by software) in the ACPI Specification.
Power Well:VSB
Location: Offset 04h
Type:
R/W
Bit
7
6
5
4
3
2
1
0
Name
GPIOE17
_EN
GPIOE16
_EN
GPIOE15
_EN
GPIOE14
_EN
GPIOE13
_EN
GPIOE12
_EN
GPIOE11
_EN
GPIOE10
_EN
Reset
0
0
0
0
0
0
0
0
Bit
Description
7
GPIOE17_EN (GPIOE17 Event Enable). Enables an active event at pin 7 of the GPIOE Port 1 to generate a
power management interrupt (SIOSCI).
0: Disable SCI (default)
1: Enable SCI
6-0
GPIOE16_EN to GPIOE10_EN (GPIOE16 to GPIOE10 Event Enable). Same as above for pins 6-0 of GPIOE
Port 1.
9.4.13 General-Purpose Enable 1 Register 1 (GPE1_EN_1)
This register contains bits 8-15 of the GPE1_EN register. This register belongs to the General-Purpose Event 1 Group of
the ACPI fixed-feature space registers.
The enable bits behave according to the Enable Bit definition (the bit is read/write by software) in the ACPI Specification.
Power Well:VSB
Location: Offset 05h
Type:
Bit
R/W
7
6
5
4
3
2
1
0
Name
GPIOE47
_EN
GPIOE46
_EN
GPIOE45
_EN
GPIOE44
_EN
GPIOE43
_EN
GPIOE42
_EN
GPIOE41
_EN
GPIOE40
_EN
Reset
0
0
0
0
0
0
0
0
Bit
7
6-0
Revision 1.2
Description
GPIOE47_EN (GPIOE47 Event Enable). Enables an active event at pin 7 of the GPIOE Port 4 to generate a
power management interrupt (SIOSCI).
0: Disable SCI (default)
1: Enable SCI
GPIOE46_EN to GPIOE40_EN (GPIOE46 to GPIOE40 Event Enable). Same as above for pins 6-0 of the
GPIOE Port 4.
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9.0 System Wake-Up Control (SWC)
(Continued)
9.4.14 General-Purpose Enable 1 Register 2 (GPE1_EN_2)
This register contains bits 16-23 of the GPE1_EN register. This register belongs to the General-Purpose Event 1 Group of
the ACPI fixed-feature space registers.
The enable bits behave according to the Enable Bit definition (the bit is read/write by software) in the ACPI Specification.
Power Well:VSB
Location: Offset 06h
Type:
R/W
Bit
7
6
5
4
3
PWBT_EVT SLBT_EVT KBD_EVT3 KBD_EVT2 KBD_EVT1
_EN
_EN
_EN
_EN
_EN
Name
Reset
0
Bit
0
0
0
0
2
1
0
MS_EVT
_EN
RI2_EVT
_EN
RI1_EVT
_EN
0
0
0
Description
7
PWBT_EVT_EN (Power Button Event Enable). Enables Power button pressing to generate a power
management interrupt (SIOSCI). This bit is similar to the PWRBTN_EN bit in the PM1b_EN_HIGH register. It
should be enabled only if the system does not support the PM1b_EVT register block.
0: Disable SCI (default)
1: Enable SCI from Power button pressing
6
SLBT_EVT_EN (Sleep Button Event Enable). Enables Sleep button pressing to generate a power
management interrupt (SIOSCI). This bit is similar to the SLPBTN_EN bit in the PM1b_EN_HIGH register. It
should be enabled only if the system does not support the PM1b_EVT register block.
0: Disable SCI (default)
1: Enable SCI from Sleep button pressing
5
KBD_EVT3_EN (Keyboard Event 3 Enable). Enables the event of pressing “PM Key 3” (on the keyboard) to
generate a power management interrupt (SIOSCI).
0: Disable SCI (default)
1: Enable SCI from pressing the “PM Key 3” on the keyboard
4
KBD_EVT2_EN (Keyboard Event 2 Enable). Enables the event of pressing “PM Key 2” (on the keyboard) to
generate a power management interrupt (SIOSCI).
0: Disable SCI (default)
1: Enable SCI from pressing the “PM Key 2” on the keyboard
3
KBD_EVT1_EN (Keyboard Event 1 Enable). Enables the event of pressing any key, key sequence or “PM Key
1” (on the keyboard) to generate a power management interrupt (SIOSCI).
0: Disable SCI (default)
1: Enable SCI from pressing a sequence of keys or the “PM Key 1” on the keyboard
2
MS_EVT_EN (Mouse Event Enable). Enables a mouse event identified by the Keyboard/Mouse Wake-up
Detector to generate a power management interrupt (SIOSCI).
0: Disable SCI (default)
1: Enable SCI from mouse event identified by the Keyboard/Mouse Wake-up Detector
1
RI2_EVT_EN (RI2 Event Enable). Enables a telephone ring received at the Serial Port 2 event, and identified
by the RI Wake-up Detector, to generate a power management interrupt (SIOSCI).
0: Disable SCI (default)
1: Enable SCI from telephone ring event received at the Serial Port 2
0
RI1_EVT_EN (RI1 Event Enable). Enables a telephone ring received at the Serial Port 1 event, and identified
by the RI Wake-up Detector, to generate a power management interrupt (SIOSCI).
0: Disable event (default)
1: Enable SCI from telephone ring event received at the Serial Port 1
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9.0 System Wake-Up Control (SWC)
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9.4.15 General-Purpose Enable 1 Register 3 (GPE1_EN_3)
This register contains bits 24-31 of the GPE1_EN register. This register belongs to the General-Purpose Event 1 Group of
the ACPI fixed-feature space registers.
The enable bits behave according to the Enable Bit definition (the bit is read/write by software) in the ACPI Specification.
Power Well:VSB
Location:Offset 07h
Type:
Bit
R/W
7
6
5
4
3
2
1
0
Name
SW_OFF
_EN
SW_ON
_EN
WDO_EVT
_EN
MOD_IRQ
_EN
MS_IRQ
_EN
KBD_IRQ
_EN
P12_EVT
_EN
RTC_EVT
_EN
Reset
0
0
0
0
0
0
0
0
Bit
Description
7
SW_OFF_EN (Software Off Event Enable). Enables the event of the software writing a ‘1’ to the
SW_OFF_CTL bit in the SWC_CTL register to generate a power management interrupt (SIOSCI).
0: Disable SCI (default)
1: Enable SCI from the software writing a ‘1’ to the SW_OFF_CTL bit in the SWC_CTL register
6
SW_ON_EN (Software On Event Enable). Enables the event of the software writing a ‘1’ to the SW_ON_CTL
bit in the SWC_CTL register to generate a power management interrupt (SIOSCI).
0: Disable SCI (default)
1: Enable SCI from the software writing a ‘1’ to the SW_ON_CTL bit in the SWC_CTL register
5
WDO_EVT_EN (Watchdog Event Enable). Enables an watchdog time-out event to generate a power
management interrupt (SIOSCI).
0: Disable SCI (default)
1: Enable SCI from watchdog time-out
4
MOD_IRQ_EN (Modules IRQ Event Enable). Enables an active IRQ from one of the Legacy modules or from
the XIRQ pin (PC87413 and PC87417) to generate a power management interrupt (SIOSCI).
0: Disable SCI (default)
1: Enable SCI by an active IRQ from one of the Legacy modules or from the XIRQ pin
3
MS_IRQ_EN (Mouse IRQ Event Enable). Enables an IRQ generated by the mouse interface section of the
KBC module to generate a power management interrupt (SIOSCI).
0: Disable SCI (default)
1: Enable SCI from an IRQ generated by the mouse interface section of the KBC module
2
KBD_IRQ_EN (Keyboard IRQ Event Enable). Enables an IRQ generated by the keyboard interface section of
the KBC module to generate a power management interrupt (SIOSCI).
0: Disable SCI (default)
1: Enable SCI from an IRQ generated by the keyboard interface section of the KBC module
1
P12_EVT_EN (Port P12 Event Enable). Enables an IRQ by an active high signal generated at the P12 pin to
generate a power management interrupt (SIOSCI).
0: Disable SCI (default)
1: Enable SCI from an active high signal generated at the P12 pin
0
RTC_EVT_EN (RTC Alarm Event Enable). Enables an RTC alarm to generate a power management interrupt
(SIOSCI). This bit is similar to the RTC_EN bit in the PM1b_EN_HIGH register. It should be enabled only if the
system does not support the PM1b_EVT register block.
0: Disable SCI (default)
1: Enable SCI from RTC alarm
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9.0 System Wake-Up Control (SWC)
9.5
(Continued)
SYSTEM WAKE-UP CONTROL REGISTERS BITMAP
Table 51. Banks 0, 1, 2 and 3 - Common Register Map
Register
Bits
Offset
Mnemonic
00h
WK_EVT_SEL
01h
WK_ST_EN
02h
GPE1_2IRQ
PWBT_
SLBT_
KBD_EVT3 KBD_EVT2 KBD_EVT1
_LOW
EVT_2IRQ EVT_2IRQ
_2IRQ
_2IRQ
_2IRQ
03h
GPE1_2IRQ
_HIGH
04h
GPE1_2SMI
PWBT_
SLBT_
KBD_EVT3 KBD_EVT2 KBD_EVT1
_LOW
EVT_2SMI EVT_2SMI
_2SMI
_2SMI
_2SMI
05h
GPE1_2SMI
_HIGH
06h
SWCFDIS
07h
SWCTRIS
08h
SWC_CTL
SW_OFF
_CTL
SW_ON
_CTL
PWB_OVR CROWBAR
_STS
_STS
09h
PWONCTL
WAS
_PFAIL
LAST
_ONCTL
RESUME_MD
0Ah
LEDCTL
0Bh
LEDBLNK
0Ch0Dh
7
6
5
4
3
2
Reserved
SW_OFF
_2SMI
PWBT_EN PWBT_EN
_S3I
_S45
SW_ON
_2IRQ
SW_ON
_2SMI
Reserved
Reserved
MS_EVT
_2IRQ
Reserved
WDO_EVT
_2SMI
ONCTL
_EN_S3I
ONCTL
_EN_S45
RI2_EVT
_2IRQ
RI1_EVT
_2IRQ
P12_EVT
_2IRQ
Reserved
MS_EVT
_2SMI
RI2_EVT
_2SMI
RI1_EVT
_2SMI
RTC_EVT
_2SMI
Reserved
KBDDIS
MSDIS
Reserved
Reserved
0
WKUPSEL
Reserved
SW_OFF
_2IRQ
1
SER1DIS
SER2DIS
PARPDIS
FDCDIS
KBMSTRIS SER1TRIS SER2TRIS PARPTRIS FDCTRIS
LEDCFG
LEDPOL
LED2BLNK
SWAP
_KBMS
Reserved
LEGACY
_PWBT
Reserved
Reserved
CRBAR_TOUT
LEDMOD
LED1BLNK
Reserved
0Eh
BIOSGPR
0Fh
BANKSEL
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General-Purpose Scratch
Reserved
216
BNK_SEL
Revision1.2
PC8741x
9.0 System Wake-Up Control (SWC)
(Continued)
Table 52. Bank 0 - Keyboard/Mouse Wake-Up Detector Register Map
Register
Offset
Mnemonic
Bits
7
6
5
4
10h11h
3
2
1
0
Reserved
12h
KBDWKCTL KBDMODE Reserved
13h
PS2CTL
DISPAR
EVT3CFG
EVT2CFG
EVT1CFG
MSEVCFG
14h15h
KBEVCFG
Reserved
16h
KDSR
Keyboard Data
17h
MDSR
18h
PS2KEY0
Data Byte of Key
19h
PS2KEY1
Data Byte of Key
1Ah
PS2KEY2
Data Byte of Key
1Bh
PS2KEY3
Data Byte of Key
1Ch
PS2KEY4
Data Byte of Key
1Dh
PS2KEY5
Data Byte of Key
1Eh
PS2KEY6
Data Byte of Key
1Fh
PS2KEY7
Data Byte of Key
Reserved
Mouse Data
Table 53. Bank 1 - Power Active Timers Register Map
Register
Offset
Mnemonic
Bits
7
6
5
4
3
2
1
0
VSB_TMR
_RST
Reserved
VDD_TMR
_RST
10h
VDD_ON_
TMR_0
VDD Timer Data Bits 0-7
11h
VDD_ON_
TMR_1
VDD Timer Data Bits 8-15
12h
VDD_ON_
TMR_2
VDD Timer Data Bits 16-23
13h
VDD_ON_
TMR_3
VDD Timer Data Bits 24-31
14h
VSB_ON_
TMR_0
VSB Timer Data Bits 0-7
15h
VSB_ON_
TMR_1
VSB Timer Data Bits 8-15
16h
VSB_ON_
TMR_2
VSB Timer Data Bits 16-23
17h
VSB_ON_
TMR_3
VSB Timer Data Bits 24-31
18h
PWTMRCTL
19h1Fh
Revision 1.2
LOCK
_TMRRST
Reserved
Reserved
217
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PC8741x
9.0 System Wake-Up Control (SWC)
(Continued)
Table 54. Bank 2 - Sleep States and ACPI Configuration Register Map
Register
Bits
Offset
Mnemonic
7
6
5
4
10h
S0_SLP_TYP
Reserved
SLP_TYP_ENC
11h
S1_SLP_TYP
Reserved
SLP_TYP_ENC
12h
S2_SLP_TYP
Reserved
SLP_TYP_ENC
13h
S3_SLP_TYP
Reserved
SLP_TYP_ENC
14h
S4_SLP_TYP
Reserved
SLP_TYP_ENC
15h
S5_SLP_TYP
Reserved
SLP_TYP_ENC
16h
SLP_ST_CFG
LOCK_
SLP_ENC
Reserved
EXT_ST
S3I
S4
_SELECT _VDD_ON _SELECT
17h
ACPI_CFG
PWBTOUT
_MODE
Reserved
RTC_EV
_DIS
SLPBTN
_EV_DIS
PWRBTN
_EV_DIS
2
1
0
18h1Fh
3
2
1
0
Reserved
Table 55. Bank 3 - Watchdog Register Map
Register
Offset Mnemonic
10h
WDCTL
11h
WDTO
12h
WDCFG
Bits
7
6
5
4
SW_WD
_TRG
3
Reserved
WDEN
Watchdog Time-Out Data
SW_WD
_TREN
SER2_IRQ SER1_IRQ
_TREN
_TREN
Reserved
13h1Fh
MS_IRQ
_TREN
KBD_IRQ
_TREN
1
0
Reserved
Table 56. ACPI Register Map with Base Address at Index 62h, 63h
Register
Offset Mnemonic
Bits
7
6
5
4
GBL_STS
BM_STS
00h
PM1b_STS
_LOW
01h
PM1b_STS
WAK_STS
_HIGH
Reserved
02h
PM1b_EN_
LOW
GBL_EN
03h
PM1b_EN_
HIGH
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Reserved
Reserved
3
2
Reserved
Ignored
RTC_STS
TMR_STS
SLPBTN
_STS
Reserved
Reserved
RTC_EN
218
PWRBTN
_STS
TMR_EN
SLPBTN
_EN
PWRBTN
_EN
Revision1.2
PC8741x
9.0 System Wake-Up Control (SWC)
(Continued)
Table 57. ACPI Register Map with Base Address at Index 64h, 65h
Register
Offset Mnemonic
00h
PM1b_CNT
_LOW
01h
PM1b_CNT
_HIGH
Bits
7
6
5
4
3
Reserved
Reserved
SLP_EN
2
1
0
GBL_RLS
BM_RLD
SCI_EN
Ignored
Reserved
SLP_TYPx
Table 58. ACPI Register Map with Base Address at Index 66h, 67h
Register
Offset Mnemonic
Bits
7
6
5
4
3
2
1
0
00h
GPE1_STS
_0
GPIOE17
_STS
GPIOE16
_STS
GPIOE15
_STS
GPIOE14
_STS
GPIOE13
_STS
GPIOE12
_STS
GPIOE11
_STS
GPIOE10
_STS
01h
GPE1
_STS_1
GPIOE47
_STS
GPIOE46
_STS
GPIOE45
_STS
GPIOE44
_STS
GPIOE43
_STS
GPIOE42
_STS
GPIOE41
_STS
GPIOE40
_STS
02h
GPE1
_STS_2
PWBT_
EVT_STS
SLBT_
KBD_
KBD_
KBD_
EVT_STS EVT3_STS EVT2_STS EVT1_STS
MS_EVT
_STS
RI2_EVT
_STS
RI1_EVT
_STS
03h
GPE1
_STS_3
SW_OFF
_STS
SW_ON
_STS
04h
GPE1
_EN_0
GPIOE17
_EN
05h
GPE1
_EN_1
06h
07h
Revision 1.2
WDO_
MOD_IRQ
EVT_STS
_STS
MS_IRQ
_STS
KBD_IRQ
_STS
P12_EVT
_STS
RTC_EVT
_STS
GPIOE16
_EN
GPIOE15
_EN
GPIOE14
_EN
GPIOE13
_EN
GPIOE12
_EN
GPIOE11
_EN
GPIOE10
_EN
GPIOE47
_EN
GPIOE46
_EN
GPIOE45
_EN
GPIOE44
_EN
GPIOE43
_EN
GPIOE42
_EN
GPIOE41
_EN
GPIOE40
_EN
GPE1
_EN_2
PWBT_EV
T_EN
SLBT_
EVT_EN
KBD_EVT KBD_EVT KBD_EVT
3_EN
2_EN
1_EN
MS_EVT
_EN
RI2_EVT
_EN
RI1_EVT
_EN
GPE1
_EN_3
SW_OFF
_EN
SW_ON
_EN
KBD_IRQ
_EN
P12_EVT
_EN
RTC_EVT
_EN
WDO_
EVT_EN
MOD_IRQ
_EN
219
MS_IRQ
_EN
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PC8741x
10.0 Legacy Functional Blocks
This chapter briefly describes the following blocks, which provide legacy device functions:
●
Floppy Disk Controller (FDC).
●
Parallel Port (PP).
●
Serial Ports 1 and 2 (SP1 and SP2).
●
Keyboard and Mouse Controller (KBC).
The description of each Legacy block includes the sections listed below. For details on the general implementation of each
legacy block, see the SuperI/O Legacy Functional Blocks datasheet.
●
General Description.
●
Register Map table(s).
●
Bitmap table(s).
The register maps in this chapter use the following abbreviations for Type:
●
R/W
= Read/Write.
●
R
= Read from a specific register (write to the same address is to a different register).
●
W
= Write (see above).
●
RO
= Read Only.
●
WO
= Write Only. Reading from the bit returns 0.
●
R/W1C = Read/Write 1 to Clear. Writing 1 to a bit clears it to 0. Writing 0 has no effect.
●
R/W1S = Read/Write 1 to Set. Writing 1 to a bit sets its value to 1. Writing 0 has no effect.
10.1 FLOPPY DISK CONTROLLER (FDC)
10.1.1 General Description
The generic FDC is a standard FDC with a digital data separator and is DP8473 and N82077 software compatible. The PC8741x
FDC supports 14 of the 17 standard FDC signals described in the generic Floppy Disk Controller (FDC) chapter, including:
•
FM and MFM modes are supported. To select either mode, set bit 6 of the first command byte when writing to/reading
from a diskette, where:
— 0 = FM mode
— 1 = MFM mode
•
A logic 1 is returned during LPC I/O read cycles by all register bits, reflecting the state of floating (TRI-STATE) FDC pins.
Exceptions to standard FDC are:
•
•
Automatic media sense using the MSEN1 signal is not supported.
DRATE1 is not supported.
Table 59 lists the FDC functional block registers. All registers are VDD powered.
Table 59. FDC Registers
Offset1
Mnemonic
00h
SRA
Status A
RO
01h
SRB
Status B
RO
02h
DOR
Digital Output
R/W
03h
TDR
Tape Drive
R/W
04h
MSR
Main Status
R
DSR
Data Rate Select
W
FIFO
Data (FIFO)
05h
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Register Name
220
Type
R/W
Revision1.2
PC8741x
10.0 Legacy Functional Blocks
(Continued)
Table 59. FDC Registers (Continued)
Offset1
Mnemonic
06h
Register Name
Type
N/A
X
DIR
Digital Input
R
CCR
Configuration Control
W
07h
1. From the 8-byte aligned FDC base address.
10.1.2 FDC Bitmap Summary
The FDC supports two system operation modes: PC-AT mode and PS/2 mode. Unless specifically indicated otherwise, all
fields in all registers are valid in both drive modes.
Register
Offset Mnemonic
00h
SRA1
01h
SRB1
02h
DOR
Bits
7
6
5
4
3
2
1
0
IRQ
Pending
Reserved
Step
TRK0
Head
Select
INDEX
WP
Head
Direction
Drive
Select 0
Status
WDATA
RDATA
WGATE
MTR1
MTR0
Motor
Enable 1
Motor
Enable 0
DMAEN
Reset Controller
Reserved
Motor
Enable 3
Motor
Enable 2
TDR
03h
Reserved
Tape Drive Select 1,0
TDR2
Reserved
(must be 1)
MSEN0
Drive ID Information
MSR
RQM
Data I/O
Direction
Non-DMA Command
Execution in Progress
DSR
Software
Reset
Logical Drive
Exchange
Drive 3
Busy
Drive 2
Busy
04h
05h
Low Power Reserved
Precompensation Delay Select
FIFO
Drive Select
Tape Drive Select 1,0
Drive 1
Busy
Data Transfer Rate
Select
Data Bits
DIR3
DSKCHG
DIR1
DSKCHG
Reserved
07h
07h
Drive 0
Busy
CCR
Reserved
Reserved
DRATE 1,0 Status
High
Density
DRATE1,0
1. Applicable only in PS/2 Mode.
2. Applicable only in Enhanced TDR Mode.
3. Applicable only in PC-AT Compatible Mode.
Revision 1.2
221
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PC8741x
10.0 Legacy Functional Blocks
(Continued)
10.2 PARALLEL PORT
10.2.1 General Description
The Parallel Port supports all IEEE1284 standard communication modes:
●
Compatibility (known also as Standard or SPP).
●
Bidirectional (known also as PS/2).
●
FIFO.
●
EPP (known also as Mode 4).
●
ECP (with an optional Extended ECP mode).
10.2.2 Parallel Port Register Map
The Parallel Port includes two groups of runtime registers, as follows:
•
A group of 21 registers at first level offset, sharing 14 entries. Three of these registers (at offsets 403h, 404h and 405h)
are used only in the Extended ECP mode.
•
A group of four registers, used only in the Extended ECP mode, accessed by a second level offset.
EPP and second level offset registers are available only when the base address is 8-byte aligned.
The desired mode is selected by the ECR runtime register (offset 402h). The selected mode determines which runtime registers are used and which address bits are used for the base address. See Tables 60 and 61 for a listing of all registers, their
offset addresses and the associated modes. All registers are VDD powered.
Table 60. Parallel Port Registers at First Level Offset
Offset
Mnemonic
00h
DATAR
0,1
Data
AFIFO
3
ECP FIFO (Address)
DTR
4
Data (for EPP)
R/W
DSR
0,1,2,3
Status
RO
STR
4
Status (for EPP)
RO
DCR
0,1,2,3
Control
R/W
CTR
4
Control (for EPP)
R/W
03h
ADDR
4
EPP Address
R/W
04h
DATA0
4
EPP Data Port 0
R/W
05h
DATA1
4
EPP Data Port 1
R/W
06h
DATA2
4
EPP Data Port 2
R/W
07h
DATA3
4
EPP Data Port 3
R/W
400h
CFIFO
DFIFO
TFIFO
CNFGA
2
3
6
7
PP Data FIFO
ECP Data FIFO
Test FIFO
Configuration A
W
R/W
R/W
RO
401h
CNFGB
7
Configuration B
RO
402h
ECR
0,1,2,3
Extended Control
R/W
403h
EIR1
0,1,2,3
Extended Index
R/W
404h
EDR1
0,1,2,3
Extended Data
R/W
405h
EAR1
0,1,2,3
Extended Auxiliary Status
R/W
01h
02h
Mode(s)
Register Name
Type
R/W
W
1. These registers are extended to the standard IEEE1284 registers. They
are only accessible when enabled by bit 4 of the Parallel Port Configuration
register (see Section 3.9.3 on page 62).
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Revision1.2
PC8741x
10.0 Legacy Functional Blocks
(Continued)
Table 61. Parallel Port Registers at Second Level Offset
Offset
Mnemonic
Register Name
Type
00h
Control0
Extended Control 0
R/W
02h
Control2
Extended Control 1
R/W
04h
Control4
Extended Control 4
R/W
05h
PP Confg0
Configuration 0
R/W
10.2.3 Parallel Port Bitmap Summary
The Parallel Port functional block bitmaps are grouped according to first and second level offsets.
Table 62. Parallel Port Bitmap Summary for First Level Offset
Register
Offset Mnemonic
Bits
7
6
5
4
3
DATAR
Data Bits
AFIFO
Address Bits
2
1
0
000h
Printer
Status
ACK
Status
PE Status
SLCT
Status
ERR
Status
Reserved
EPP Timeout Status
Direction
Control
Interrupt
Enable
PP Input
Control
Printer
Automatic
Initialization Line Feed
Control
Control
Data
Strobe
Control
001h
DSR
002h
DCR
003h
ADDR
EPP Device or Register Selection Address Bits
004h
DATA0
EPP Device or R/W Data
005h
DATA1
EPP Device or R/W Data
006h
DATA2
EPP Device or R/W Data
007h
DATA3
EPP Device or R/W Data
400h
CFIFO
Data Bits
400h
DFIFO
Data Bits
400h
TFIFO
Data Bits
400h
CNFGA
401h
CNFGB
402h
ECR
403h
EIR
404h
EDR
405h
EAR
Revision 1.2
Reserved
Bit 7 of PP
Confg0
Reserved
Reserved
Interrupt
Request
Value
Interrupt Select
Reserved
DMA Channel Select
ECP Mode Control
ECP
Interrupt
Mask
ECP
Interrupt
Service
FIFO Full
Reserved
ECP DMA
Enable
Reserved
FIFO
Empty
Second Level Offset
Data Bits
FIFO Tag
Reserved
223
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PC8741x
10.0 Legacy Functional Blocks
(Continued)
Table 63. Parallel Port Bitmap Summary for Second Level Offset
Register
Second
Level
Offset
Mnemonic
Bits
7
6
4
DCR
Register
Live
Freeze Bit
Reserved
Revision
1.7 or 1.9
Select
00h
Control0
02h
Control2
SPP Compatibility
Channel
Address
Enable
04h
Control4
Reserved
PP DMA Request Inactive Time
PP Confg0
Bit 3 of
CNFGA
05h
www.national.com
Reserved
5
Demand
DMA
Enable
3
1
0
EPP Timeout
Interrupt
Mask
Reserved
Reserved
Reserved
ECP IRQ Channel Number
224
2
PP DMA Request Active Time
PE
Internal
Pull-up or
Pull-down
ECP DMA Channel
Number
Revision1.2
PC8741x
10.0 Legacy Functional Blocks
(Continued)
10.3 SERIAL PORTS (SP1 AND SP2)
10.3.1 General Description
The identical Serial Port functional blocks SP1 and SP2 both support serial data communication with a remote peripheral
device or modem using a wired interface. The Serial Ports can function in one of three modes:
●
16450-Compatible mode (Standard 16450)
●
16550-Compatible mode (Standard 16550)
●
Extended mode
Extended mode provides advanced functionality for the UART.
The Serial Ports provide receive and transmit channels that can operate concurrently in full-duplex mode. They perform all
functions required to conduct parallel data interchange with the system and composite serial data exchange with the external
data channel, including:
●
Format conversion between the internal parallel data format and the external programmable composite serial format
●
Serial data timing generation and recognition
●
Parallel data interchange with the system using a choice of bidirectional data transfer mechanisms
●
Status monitoring for all phases of communication activity
●
Complete MODEM-control capability.
Existing 16550-based legacy software is completely and transparently supported. Module organization and specific fallback
mechanisms switch the module to 16550-Compatible mode on reset or when initialized by 16550 software.
10.3.2 Register Bank Overview
Four register banks, each containing eight registers, control Serial Port operation. All registers use the same 8-byte address
space to indicate offsets 00h through 07h. The active bank must be selected by the software.
The register bank organization enables access to the banks as required for activation of all module modes, while maintaining
transparent compatibility with 16450 or 16550 software.
The Bank Selection register (BSR) selects the active bank and is common to all banks as shown in Figure 52. Therefore,
each bank defines seven new registers.
The default bank selection after system reset is 0.
BANK 3
BANK 2
BANK 1
BANK 0
Offset 07h
Offset 06h
Offset 05h
Offset 04h
Common
Register
Throughout
All Banks
LCR/BSR
Offset 02h
Offset 01h
Offset 00h
16550 Banks
Figure 52. Register Bank Architecture
Revision 1.2
225
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PC8741x
10.0 Legacy Functional Blocks
(Continued)
10.3.3 SP1/SP2 Register Maps
Table 64. Bank 0 Register Map
Offset
Mnemonic
00h
RXD
Receiver Data
RO
TXD
Transmitter Data
W
01h
IER
Interrupt Enable
R/W
02h
EIR
Event Identification
R
FCR
FIFO Control
W
LCR
Link Control
W
BSR
Bank Select
R/W
04h
MCR
Modem/Mode Control
R/W
05h
LSR
Link Status
R/W
06h
MSR
Modem Status
07h
SPR
Scratch Pad
R/W
Auxiliary Status and Control
RO
03h
ASCR
Register Name
Type
R
Table 65. Bank 1 Register Map
Offset
Mnemonic
Register Name
00h
LBGD(L)
Legacy Baud Generator Divisor (Low Byte)
R/W
01h
LBGD(H)
Legacy Baud Generator Divisor (High Byte)
R/W
02h
03h
Type
Reserved
LCR/BSR
Link Control/ Bank Select
04h-07h
R/W
Reserved
Table 66. Bank 2 Register Map
Offset
Mnemonic
Register Name
00h
BGD(L)
Baud Generator Divisor (Low Byte)
R/W
01h
BGD(H)
Baud Generator Divisor (High Byte)
R/W
02h
EXCR1
Extended Control 1
R/W
03h
BSR
Bank Select
R/W
04h
EXCR2
Extended Control 2
R/W
05h
www.national.com
Type
Reserved
06h
TXFLV
TX_FIFO Level
RO
07h
RXFLV
RX_FIFO Level
RO
226
Revision1.2
PC8741x
10.0 Legacy Functional Blocks
(Continued)
Table 67. Bank 3 Register Map
Offset
Mnemonic
00h
MRID
01h
Register Name
Type
Module Identification and Revision ID
RO
SH_LCR
Shadow of LCR
RO
02h
SH_FCR
Shadow of FIFO Control
RO
03h
BSR
Bank Select
R/W
04h-07h
Reserved
10.3.4 SP1 Bitmap Summary
Table 68. Bank 0 Bitmap
Register
Offset Mnemonic
Bits
7
6
5
4
3
2
MS_IE
LS_IE
TXLDL_IE RXHDL_IE
MS_IE
LS_IE
TXLDL_IE RXHDL_IE
00h
RXD
RXD7-0
00h
TXD
TXD7-0
IER1
Reserved
1
0
01h
IER2
Reserved
EIR1
FEN1-0
Reserved
RXFT
EIR2
Reserved
TXEMP_EV Reserved
MS_EV
FCR1
RXFTH1-0
Reserved
FCR2
RXFTH1-0
TXEMP_IE
Reserved
IPR1-0
LS_EV
IPF
TXLDL_EV RXHDL_EV
02h
LCR
BKSE
BSR
BKSE
TXFTH1-0
SBRK
STKP
EPS
TXSR
RXSR
FIFO_EN
Reserved
TXSR
RXSR
FIFO_EN
PEN
STB
WLS1-0
03h
MCR1
BSR6-0
Reserved
LOOP
04h
MCR2
Reserved
ISEN/
DCDLP
RILP
RTS
DTR
TX_DFR
Reserved
RTS
DTR
05h
LSR
ER_INF
TXEMP
TXRDY
BRK
FE
PE
OE
RXDA
06h
MSR
DCD
RI
DSR
CTS
DDCD
TERI
DDSR
DCTS
SPR1
Scratch Data
07h
ASCR2
Reserved
RXF_TOUT
1. Non-Extended mode
2. Extended mode
Revision 1.2
227
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PC8741x
10.0 Legacy Functional Blocks
(Continued)
Table 69. Bank 1 Bitmap
Register
Bits
Offset
Mnemonic
7
6
5
4
00h
LBGD(L)
LBGD7-0
01h
LBGD(H)
LBGD15-8
02h
3
2
1
PEN
STB
0
Reserved
LCR
BKSE
BSR
BKSE
SBRK
STKP
EPS
WLS1-0
03h
BSR6-0
04h-07h
Reserved
Table 70. Bank 2 Bitmap
Register
Bits
Offset
Mnemonic
7
6
5
00h
BGD(L)
BGD7-0
01h
BGD(H)
BGD15-8
02h
EXCR1
BTEST
03h
BSR
BKSE
04h
EXCR2
LOCK
Reserved
4
ETDLBK
3
LOOP
2
1
0
Reserved
EXT_SL
BSR6-0
Reserved
PRESL1-0
Reserved
05h
Reserved
06h
TXFLV
Reserved
TFL4-0
07h
RXFLV
Reserved
RFL4-0
Table 71. Bank 3 Bitmap
Register
Offset
Mnemonic
00h
MRID
01h
SH_LCR
02h
SH_FCR
03h
BSR
Bits
7
6
5
4
2
MID3-0
BKSE
SBRK
RXFTH1-0
1
0
RID3-0
STKP
EPS
TXFTH1-0
BKSE
PEN
STB
Reserved
TXSR
WLS1-0
RXSR
FIFO_EN
BSR6-0
04-07h
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3
Reserved
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10.0 Legacy Functional Blocks
(Continued)
10.4 KEYBOARD AND MOUSE CONTROLLER (KBC)
10.4.1 General Description
The KBC is implemented physically as a single hardware module and houses two separate logical devices: a mouse controller (Logical Device 5) and a keyboard controller (Logical Device 6). The KBC is functionally equivalent to the industry
standard 8042A keyboard controller. The 8042A datasheet can be used as a detailed technical reference for the KBC.
The hardware KBC module is integrated to provide the following pin functions: P12, P16, P17, KBRST (P20), GA20 (P21),
KBDAT, KBCLK, MDAT and MCLK. KBRST and GA20 are implemented as bidirectional open-drain pins. The keyboard and
mouse interfaces are implemented as bidirectional open-drain pins. P12, P16 and P17 are implemented as quasi-bidirectional pins. Their internal connections are shown in Figure 53.
P10, P11, P13-P15 and P22-P27 of the KBC core are not available on dedicated pins; neither are T0 and T1. P10, P11,
P22, P23, P26, P27, T0 and T1 are used to implement the keyboard and mouse interface.
Internal pull-ups are implemented only on P12, P16 and P17.
The KBC executes a program fetched from an on-chip 2Kbyte ROM. The code programmed in this ROM is user-customizable. The KBC has two interrupt request signals: one for the keyboard and one for the mouse. The interrupt requests are
implemented using ports P24 and P25 of the KBC core. The interrupt requests are controlled exclusively by the KBC firmware, except for the type and number, which are affected by configuration registers (see Section 3.2.3 on page 40).
The interrupt requests are implemented as bidirectional signals. When an I/O port is read, all unused bits return the value
latched in the output registers of the ports.
For KBC firmware that implements interrupt-on-OBF schemes, the following is the recommended implementation:
1. Put the data in DBBOUT.
2. Set the appropriate port bit to issue an interrupt request.
KBC
Internal Interface Bus
STATUS
DBBIN
DBBOUT
P12
P12
P16
P16
P17
P17
P20
KBRST
P21
GA20
P26
KBCLK
T0
P27
KBDAT
P10
P23
KBD IRQ
T1
P24
Matrix
Mouse IRQ
MCLK
P22
P25
MDAT
P11
Figure 53. Keyboard and Mouse Interfaces
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10.0 Legacy Functional Blocks
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10.4.2 KBC Register Map
All registers are VDD powered.
Offset
Mnemonic
Register Name
Type
DBBOUT Read KBC Data
00h
DBBIN
R
Write KBC Data
W
STATUS Read Status
04h
DBBIN
R
Write KBC Command
W
10.4.3 KBC Bitmap Summary
Register
Offset Mnemonic
Bits
7
6
5
4
3
DBBOUT
KBC Data Bits (For Read cycles)
DBBIN
KBC Data Bits (For Write cycles)
2
1
0
F0
IBF
OBF
00h
STATUS
General-Purpose Flags
F1
04h
DBBIN
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KBC Command Bits (For Write cycles)
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11.0 Device Characteristics
11.1 GENERAL DC ELECTRICAL CHARACTERISTICS
11.1.1 Recommended Operating Conditions
Symbol
Parameter
Min
Typ
Max
Unit
VDD
Supply Voltage
3.0
3.3
3.6
V
VSB
Standby Voltage
3.0
3.3
3.6
V
VBAT
Battery Backup Supply Voltage
2.4
3.0
3.6
V
+70
°C
TA
0
Operating Temperature
11.1.2 Absolute Maximum Ratings
Absolute maximum ratings are values beyond which damage to the device may occur. Unless otherwise specified, all voltages are relative to ground.
Symbol
VSUP
VI
VO
TSTG
Parameter
Min
Max
Unit
−0.5
+6.5
V
All other pins
−0.5
5.5
V
LCLK, LAD3-0, LFRAME, LRESET,
SERIRQ, CLKRUN, 32KX1_32KCLKIN
−0.5
VDD + 0.5
V
All other pins
−0.5
5.5
V
LAD3-0, LDRQ, SERIRQ, CLKRUN,
32KX2
−0.5
VDD + 0.5
V
−65
+165
°C
1
W
+260
°C
Supply Voltage1
Input Voltage
Output Voltage
Storage Temperature
PD
Power Dissipation
TL
Lead Temperature Soldering (10 s)
ESD Tolerance
MCRS
Conditions
CZAP = 100 pF
RZAP = 1.5 KΩ2
2000
V
VSB = 3.63V
4.53
mA
Battery Maximum Safe Reverse
Current
RUL3=0.8KΩ
1. VSUP is VDD, VSB or VBAT.
2. Value based on test complying with RAI-5-048-RA human body model ESD testing.
3. Minimum value of internal protection resistor (see Figure 45 on page 147).
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11.0 Device Characteristics
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11.1.3 Capacitance
Symbol
Min2
Parameter
Typ1
Max2
Unit
4
5
pF
8
12
pF
CIN
Input Pin Capacitance
CIN1
Clock Input Capacitance3
CIO
I/O Pin Capacitance
8
10
pF
CO
Output Pin Capacitance
6
8
pF
5
1. TA = 25°C, f = 1 MHz.
2. Not tested. Guaranteed by characterization.
3. LCLK, CLKIN.
11.1.4 Power Consumption under Recommended Operating Conditions
Symbol
IDD
VDD Average Main Supply Current
IDDLP
ISBLP
IBAT
VDD Quiescent Main Supply Current in
Low Power Mode2
VSB Average Main Supply Current
ISB
Conditions1
Typ
Max
Unit
VIL = 0.5V, VIH = 2.4V
No Load
21
30
mA
VIL = VSS, VIH = VDD
No Load
0.5
0.8
mA
VIL = 0.5V, VIH = 2.4V
No Load
14
20
mA
VIL = VSS, VIH = VSB
No Load
5
8
mA
VDD, VSB = 0V,
VBAT = 3V
0.9
1.5
µA
Parameter
VSB Quiescent Main Supply Current in
Low Power Mode2
VBAT Battery Supply Current
1. All parameters specified for 0° C ≤ TA ≤ 70° C; VDD and VSB = 3.3V ±10%, unless otherwise specified.
2. All the modules disabled; clock outputs disabled; no LPC or ACCESS.bus activity.
11.1.5 Voltage Thresholds
Symbol
Parameter1
Min2
Typ
Max2
Unit
VDDON
VDD Detected as Power-on
2.3
2.6
2.9
V
VDDOFF
VDD Detected as Power-off
2.2
2.5
2.8
V
VDDHY
VDD Hysteresis (VDDON − VDDOFF)
0.1
VSBON
VSB Detected as Power-on
2.3
2.6
2.9
V
VSBOFF
VSB Detected as Power-off
2.2
2.5
2.8
V
VSBHY
VSB Hysteresis (VSBON − VSBOFF)
0.1
VBATDTC
Battery Detected
1.0
1.2
V
VLOWBAT
Low Battery Voltage
1.3
1.9
V
V
V
1. All parameters specified for 0° C ≤ TA ≤ 70° C.
2. Not tested. Guaranteed by characterization.
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11.0 Device Characteristics
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11.2 DC CHARACTERISTICS OF PINS, BY I/O BUFFER TYPES
The following tables summarize the DC characteristics of all device pins described in Section 1.2 on page 20. The characteristics describe the general I/O buffer types defined in Table 1 on page 20. For exceptions, refer to Section 11.2.9 on
page 235. The DC characteristics of the LPC Interface meet the PCI Local Bus Specification (Rev 2.2 December 18, 1998)
for 3.3V DC signaling. The DC characteristics of the ACCESS.bus Interface meet the SMBus (Rev 1.1 Dec. 11, 1998) and
ACCESS.bus (Rev. 3.0 Sep. 1995) specifications for on-board devices.
11.2.1 Input, CMOS Compatible with Schmitt Trigger
Symbol: INCS
Symbol
Parameter
Conditions
Min
Max
Unit
VIH
Input High Voltage
0.75 VSUP1
5.52
V
VIL
Input Low Voltage
−0.51
1.1
V
VHY
Input Hysteresis
2003
IIL
µA
±14
0 < VIN < VSUP
Input Leakage Current
mV
1. VSUP is VDD, VSB or VPP according to the input power well.
2. Not tested. Guaranteed by design.
3. Not tested. Guaranteed by characterization.
4. Maximum 10 µA for all pins together. Not tested. Guaranteed by characterization.
11.2.2 Input, PCI 3.3V
Symbol: INPCI
Symbol
Parameter
Conditions
Min
Max
Unit
VIH
Input High Voltage
0.5 VDD
VDD + 0.51
V
VIL
Input Low Voltage
−0.51
0.3 VDD
V
lIL2
Input Leakage Current
±13
µA
0 < VIN < VDD
1. Not tested. Guaranteed by design.
2. Input leakage current includes the output leakage of the bidirectional buffers with TRI-STATE outputs.
3. Maximum 10 µA for all pins together. Not tested. Guaranteed by characterization.
11.2.3 Input, SMBus Compatible
Symbol: INSM
Symbol
Parameter
Conditions
Min
Max
Unit
VIH
Input High Voltage
1.4
5.51
V
VIL
Input Low Voltage
−0.51
0.8
V
IIL2
Input Leakage Current
±13
µA
0 < VIN < VSB
1. Not tested. Guaranteed by design.
2. Input leakage current includes the output leakage of the bidirectional buffers with TRI-STATE outputs.
3. Maximum 10 µA for all pins together. Not tested. Guaranteed by characterization.
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11.0 Device Characteristics
(Continued)
11.2.4 Input, TTL Compatible
Symbol: INT
Symbol
Parameter
Conditions
Min
Max
Unit
VIH
Input High Voltage
2.0
5.51
V
VIL
Input Low Voltage
−0.51
0.8
V
IIL2
Input Leakage Current
±14
µA
0 < VIN < VSUP3
1. Not tested. Guaranteed by design.
2. Input leakage current includes the output leakage of the bidirectional buffers with TRI-STATE outputs.
3. VSUP is VDD, VSB or VPP according to the input power well.
4. Maximum 10 µA for all pins together. Not tested. Guaranteed by characterization.
11.2.5 Input, TTL Compatible with Schmitt Trigger
Symbol: INTS
Symbol
Parameter
Conditions
Min
Max
Unit
VIH
Input High Voltage
2.0
5.51
V
VIL
Input Low Voltage
−0.51
0.8
V
VHY
Input Hysteresis
2002
IIL3
Input Leakage Current
mV
±15
0 < VIN < VSUP4
µA
1. Not tested. Guaranteed by design.
2. Not tested. Guaranteed by characterization.
3. Input leakage current includes the output leakage of the bidirectional buffers with TRI-STATE outputs.
4. VSUP is VDD, VSB or VPP according to the input power well.
5. Maximum 10 µA for all pins together. Not tested. Guaranteed by characterization.
11.2.6 Output, TTL Compatible Push-Pull Buffer
Symbol: Op/n
Output, TTL Compatible, rail-to-rail Push-Pull buffer that is capable of sourcing p mA and sinking n mA
Symbol
Parameter
VOH
Output High Voltage
VOL
Output Low Voltage
Conditions
Min
Max
Unit
IOH = −p mA
2.4
V
IOH = −50 µA
VSUP − 0.21
V
IOL = n mA
0.4
V
IOL = 50 µA
0.2
V
1. VSUP is VDD, VSB or VPP according to the output power well.
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11.0 Device Characteristics
(Continued)
11.2.7 Output, Open-Drain Buffer
Symbol: ODn
Output, TTL Compatible Open-Drain output buffer capable of sinking n mA. Output from these signals is open-drain and
is never forced high.
Symbol
VOL
Parameter
Conditions
Output Low Voltage
Min
Max
Unit
IOL = n mA
0.4
V
IOL = 50 µA
0.2
V
Max
Unit
11.2.8 Output, PCI 3.3V
Symbol: OPCI
Symbol
Parameter
Conditions
Min
0.9 VDD
VOH
Output High Voltage
lout = −500 µA
VOL
Output Low Voltage
lout =1500 µA
V
0.1 VDD
V
11.2.9 Exceptions
1. All pins are 5V tolerant except for the pins with PCI (INPCI, OPCI) buffer types.
2. All pins are back-drive protected except for the pins with PCI (INPCI, OPCI) and oscillator (OOSC) buffer types.
3. The following pins have an internal static pull-up resistor (when enabled) and therefore may have leakage current to
VSUP (when VIN = 0): ACK, AFD_DSTRB, ERR, INIT, PE, SLIN_ASTRB, STB_WRITE, PPDIS, P12, P16, P17, ACBCLK,
ACBDAT, PWBTIN, SLBTIN, PWBTOUT, GPIO00-07, GPIOE10-17, GPIO20-27, GPIO30-37, GPIOE40-47, GPIO50-55
and GPIO60-64.
4. The following pins have an internal static pull-down resistor (when enabled) and therefore may have leakage current to
VSS (when VIN = VSUP): BUSY_WAIT, PE and SLCT.
5. The following strap pins have an internal static pull-down resistor enabled during power-up reset and therefore may have
leakage current to VSS (when VIN = VSUP): BADDR, TRIS, CKIN48, XCNF2-0 and ACBSA.
6. When VDD = 0V, the following pins present a DC load to VSS of 30 KΩ minimum (not tested, guaranteed by design) for
a pin voltage of 0V to 3.6V: CTS1, CTS2, DCD1, DCD2, DSR1, DSR2, DTR1_BOUT1, DTR2_BOUT2, RI1, RI2, RTS1,
RTS2, SIN1, SIN2, SOUT1, SOUT2.
7. Output from SLCT, BUSY_WAIT (and PE if bit 2 of PP Confg0 register is 0) is open-drain in all SPP modes except in
SPP-Compatible mode when the setup mode is ECP-based FIFO and bit 4 of the Control2 parallel port register is 1.
Otherwise, output from these signals is level 2. External 4.7 KΩ pull-up resistors should be used.
8. Output from ACK, ERR (and PE if bit 2 of PP Confg0 register is set to 1) is open-drain in all SPP modes except in SPPCompatible mode when the setup mode is ECP-based FIFO and bit 4 of the Control2 parallel port register is set to 1.
Otherwise, output from these signals is level 2. External 4.7 KΩ pull-up resistors should be used.
9. Output from STB, AFD, INIT and SLIN is open-drain in all SPP modes, except in SPP-Compatible mode when the setup
mode is ECP-based (FIFO). Otherwise, output from these signals is level 2. External 4.7 KΩ pull-up resistors should be
used.
10. IOH is valid for a GPIO pin only when it is not configured as open-drain.
11.2.10 Terminology
Back-Drive Protection. A pin that is back-drive protected does not sink current into the supply when an input voltage higher
than the supply, but below the pin’s maximum input voltage, is applied to the pin. This is true even when the supply is inactive. Note that active pull-up resistors and active output buffers are typically not back-drive protected.
5-Volt Tolerance. An input signal that is 5V tolerant can operate with input voltage of up to 5V even though the supply to
the device is only 3.3V. The actual maximum input voltage allowed to be supplied to the pin is indicated by the maximum
high voltage allowed for the input buffer. Note that some pins have multiple buffers, not all of which are 5V tolerant. In such
cases, there is a note that indicates at what conditions a 5V input may be applied to the pin; if there is no note, the low maximum voltage among the buffers is the maximum voltage allowed for the pin.
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11.0 Device Characteristics
(Continued)
11.3 INTERNAL RESISTORS
DC Test Conditions
Pull-Up Resistor Test Circuit
Pull-Down Resistor Test Circuit
VSUP
VSUP
VSUP
Device
Under
Test
RPU
Device
Under
Test
IPU
Pin
IPD
Pin
A
A
VPIN
RPD
V
V
VPIN
Figure 54. Internal Resistor Test Conditions, TA = 0 °C to 70 °C, VSUP = 3.3V
Pull-Down Resistor for Straps
VSUP
VSUP
VPIN > VIH
Device
Under
Test
VPIN < VIL
VSUP
IPD
Device
Under
Test
10KΩ
(Note 3)
Pin
10µA
IPD
Pin
A
RPD
VPIN
V
VSUP
A
RPD
10µA
VPIN
V
Figure 55. Internal Pull-Down Resistor for Straps, TA = 0 °C to 70 °C, VSUP = 3.3V
Notes for Figures 54 and 55:
1. VSUP is VDD or VSB according to the pin power well.
1. The equivalent resistance of the pull-up resistor is calculated by RPU = (VSUP − VPIN) / IPU.
2. The equivalent resistance of the pull-down resistor is calculated by RPD = VPIN / IPD.
3. The external pull-up resistor is 4.7KΩ for the TRIS strap.
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11.0 Device Characteristics
(Continued)
11.3.1 Pull-Up Resistor
Symbol: PUnn
Symbol
RPU
Parameter
Pull-up equivalent resistance
Conditions1
Min2
Typical
Max2
Unit
VPIN = 0V
nn−30%
nn
nn+30%
KΩ
Conditions1
Min2
Typical
Max2
Unit
VPIN = VSUP
nn−30%
nn
nn+30%
KΩ
nn−50%
KΩ
1. TA = 0 °C to 70 °C, VSUP = 3.3V.
2. Not tested. Guaranteed by characterization.
11.3.2 Pull-Down Resistor
Symbol: PDnn
Symbol
RPD
Parameter
VPIN = 0.17 VSUP3
Pull-down equivalent resistance
VPIN = 0.8 VSUP3
nn−48%
KΩ
1. TA = 0 °C to 70 °C, VSUP = 3.3V.
2. Not tested. Guaranteed by characterization.
3. For strap pins only.
11.4 PACKAGE THERMAL INFORMATION
Thermal resistance (degrees C/W) ThetaJC and ThetaJA values for the PC8741x package are as follows:
Table 3. Theta (Θ) J Values
Package Type
128 PQFP
ThetaJA@0 lfpm ThetaJA@225 lfpm ThetaJA@500 lfpm
47
35.8
31.1
ThetaJC
14.9
Note: Airflow for ThetaJA values is measured in linear feet per minute (lfpm).
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11.0 Device Characteristics
(Continued)
11.5 AC ELECTRICAL CHARACTERISTICS
11.5.1 AC Test Conditions
Load Circuit
AC Testing Input, Output Waveform
VSUP
S1
2.4
0.1 µf
0.4
2.0
0.8
Test Points
2.0
0.8
RL
Input
Device
Under
Test
Output
CL
Figure 56. AC Test Conditions, TA = 0 °C to 70 °C, VSUP = 3.3V ±10%
Notes:
1. VSUP is VDD, VSB or VPP according to the pin power well.
2. CL = 50 pF for all output pins except the following pin groups:
CL = 100 pF for Serial Port 1 and 2 (see Section 1.4.4 on page 24), Parallel Port (see Section 1.4.5) and
Floppy Disk Controller (see Section 1.4.6) pins;
CL = 40 pF for HFCKOUT pin;
CL = 400 pF for ACCESS.bus pins (see Section 1.4.2 on page 23);
These values include both jig and oscilloscope capacitance.
3. S1 = Open for push-pull output pins.
S1 = VSUP for high impedance to active low and active low to high impedance transition measurements.
S1 = GND for high impedance to active high and active high to high impedance transition measurements.
RL = 1.0 KΩ for all the pins.
4. For the FDC open-drain interface pins, S1 = VDD and RL = 150 Ω.
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11.0 Device Characteristics
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11.5.2 Reset Timing
VSB Power-Up Reset
Description
Min1
Reference Conditions
Max1
Symbol
Figure
tLRST
57
Minimum LRESET active
time
Power stable to end of
LRESET
2048 * t32KOSC
tIRST
57
Internal power-on reset time
Power stable to end of
internal reset
8192 * t32KOSC2
t32KW3 +
8192 * t32KOSC
tIPLV
57
Internal strap pull-down
resistors, valid time4
Before end of internal reset
512 * t32KOSC
tIRST
tEPLV
57
External strap pull-up
resistors, valid time
Before end of internal reset
512 * t32KOSC
tIRST
1. Not tested. Guaranteed by design.
2. Valid VBAT; the 32 KHz internal clock is running while VSB is Off (see Low Frequency Clock Timing on
page 242).
3. No VBAT; the 32 KHz internal clock is stopped while VSB is Off (see Low Frequency Clock Timing on
page 242).
4. Active on VSB Power-Up reset only.
VSB (Power)
VSBONmin
t32KOSC
t32KW
32 KHz Clock
(Internal)
VSB Power-Up Reset
(Internal)
tIRST
tLRST
LRESET
tIPLV
Internal Straps
(Pull-Down)
tEPLV
External Straps
(Pull-Up)
Figure 57. Internal VSB Power-Up Reset (No VBAT)
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11.0 Device Characteristics
(Continued)
VDD Power-Up Reset
Description
Reference Conditions
Min1
Max1
Symbol
Figure
tLRST
58
Minimum LRESET active
time
Power stable to end of
LRESET
2048 * t32KOSC
tIRST
58
Internal Power-Up reset time
Power stable to end of
internal reset
8192 * t32KOSC
8704 * t32KOSC
tIPLV
58
Internal strap pull-down
resistors, valid time2
Before end of internal reset
512 * t32KOSC
tIRST
tEPLV
58
External strap pull-up
resistors, valid time
Before end of internal reset
512 * t32KOSC
tIRST
1. Not tested. Guaranteed by design.
2. Active on VDD Power-Up reset only.
VDDONmin
VDD (Power)
t32KOSC
32 KHz Clock
(Internal)
tIRST
VDD Power-Up Reset
(Internal)
tLRST
LRESET
tIPLV
Internal Straps
(Pull-Down)
tEPLV
External Straps
(Pull-Up)
Figure 58. Internal VDD Power-Up Reset
Hardware Reset
Symbol
Figure
tWRST
59
Description
Reference Conditions
LRESET pulse width
Min
Max
100 ns
Internal Clock
tWRST
LRESET
Figure 59. Hardware Reset
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11.0 Device Characteristics
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11.5.3 Clock Timing
High Frequency Clock Timing
CLKIN (48 MHz)
Symbol
Clock Input Parameter
Min
Typ
Unit
tCH
Clock High Pulse Width2
8.2
ns
tCL
Width2
8.2
ns
tCP
tCR
tCF
Clock Low Pulse
2
20
Clock Period (50%-50%)
20.83
21.5
ns
2.5
ns
2.5
ns
2
Clock Rise Time (20%-80%)
2
Clock Fall Time (80%-20%)
HFCKOUT (48 MHz)
Symbol
Max
HFCKOUT (40 MHz)
Clock Output Parameter
Min
Typ
Max
Min
Typ
Max
Unit
tCH
Clock High Pulse Width1,4
8.2
10.3
ns
tCL
Clock Low Pulse Width1,4
8.2
10.3
ns
tCP
Clock Period2
(50%-50%)
tCR
Clock Rise Time4
(20%-80%)
tCF
Clock Fall Time4
(80%-20%)
t48TYP −
20.83
32KTOL −
50ppm
t48TYP +
t40TYP −
25
32KTOL + 32KTOL −
50ppm
150ppm
3
3
3
t40TYP +
32KTOL3 +
150ppm
ns
CL = 15 pF
2.5
2.5
ns
CL = 40 pF
5
5
ns
CL = 15 pF
2.5
2.5
ns
CL = 40 pF
5
5
ns
1. CL = 15 pF.
2. Not tested. Guaranteed by design.
3. t32KCLKIN tolerance.
4. Not tested. Guaranteed by characterization.
.
tCP
tCH
CLKIN
HFCKOUT
VIH
VIH
VIL
VIL
tCL
Figure 60. External High Frequency Clock Timing
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11.0 Device Characteristics
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Low Frequency Clock Timing
Symbol
Figure
Description
Reference Conditions
Min
Typ
Max
Units
30.5145
(t32TYP −
100ppm)
30.517578
(t32TYP)
30.5206
(t32TYP +
100ppm)
µs
Clock Input Timing
t32KCLKIN
–
Required clock period for
32KCLKIN1
From RE to RE of
32KCLKIN.
Clock Output Timing
µs
t32KOSC
61
Clock period of the internal From RE to RE of
LFCKOUT.
oscillator2
t32KW
61
32K oscillator wake-up time3 After VSB > VSBON
1
sec
t32KD
62
Internally generated
After VSB > VSBON
40/48 MHz clock delay time3
33
ms
30.517578
(t32TYP)
1. Recommended for RTC timekeeping accuracy and for HFCKOUT, LFCKOUT frequency accuracy.
2. Determined by the values of the external crystal circuit components.
3. Not tested. Guaranteed by characterization.
VBAT
VSB
t32KW
t32KOSC
32KX1/32KCLKIN
0V
32KX2
0V
Figure 61. Low Frequency Clock Waveforms
VBAT
0V
VSB
t32KD
Internally Generated
40/48 MHz Clock
Figure 62. Internal Clock Waveforms
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242
Revision1.2
11.5.4
PC8741x
11.0 Device Characteristics
(Continued)
LPC Interface Timing
The AC characteristics of the LPC Interface meet the PCI Local Bus Specification (Rev 2.2 December 18, 1998) for 3.3V
DC signaling.
LCLK and LRESET
Symbol
Parameter
Min
Max
Units
tCYC1
LCLK Cycle Time
30
ns
tHIGH
LCLK High Time2
11
ns
tLOW
LCLK Low Time2
11
ns
-
LCLK Slew Rate2,3
1
-
LRESET Slew Rate2,4
50
4
V/ns
mV/ns
1. The PCI may have any clock frequency between nominal DC and 33 MHz. Device operational
parameters at frequencies under 16 MHz are guaranteed by design rather than by testing. The
clock frequency may be changed at any time during the operation of the system as long as the
clock edges remain “clean” (monotonic) and the minimum cycle high and low times are not violated. The clock may only be stopped in a low state.
2. Not tested. Guaranteed by characterization.
3. Rise and fall times are specified in terms of the edge rate measured in V/ns. This slew rate
must be met across the minimum peak-to-peak portion of the clock wavering (0.2 VDD to 0.6
VDD) as shown below.
4. The minimum LRESET slew rate applies only to the rising (de-assertion) edge of the reset signal and ensures that system noise cannot make an otherwise monotonic signal appear to
bounce in the switching range.
VDD = 3.3V ±10%
tHIGH
tLOW
0.6 VDD
0.5 VDD
0.4 VDD p-to-p
(minimum)
0.4 VDD
0.3 VDD
0.2 VDD
tCYC
Revision 1.2
243
www.national.com
PC8741x
11.0 Device Characteristics
(Continued)
SERIRQ and LPC Signals
Symbol
Figure
Description
Reference Conditions
Min
Max
Unit
tVAL
Output
Output Valid Delay
After RE CLK
11
ns
tON
Output
Float to Active Delay
After RE CLK
tOFF
Output
Active to Float Delay
After RE CLK
tSU
Input
Input Setup Time
Before RE CLK
7
ns
tHL
Input
Input Hold Time
After RE CLK
0
ns
21
ns
281
ns
1. Not tested. Guaranteed by characterization.
Outputs
VDD = 3.3V ±10%
LCLK
0.4 VDD
0.4 VDD
tVAL
tVAL
0.615 VDD
LAD3-LAD0,
LDRQ, SERIRQ
0.285 VDD
tON
LAD3-LAD0, Leakage Only
SERIRQ
VDD = 3.3V ±10%
LCLK
tOFF
Output Enabled
Inputs
0.4 VDD
tSU
LAD3-LAD0, LFRAME
LRESET, SERIRQ
www.national.com
Leakage Only
tHL
0.4 VDD
244
Revision1.2
PC8741x
11.0 Device Characteristics
(Continued)
11.5.5 X-Bus Extension Timing (PC87416 and PC87417)
Symbol
Figure
tVAL
Outputs
Output Valid Delay
After RE Internal Clock
tON
Outputs
Float to Active Delay
After RE Internal Clock
02
ns
tOH
Outputs
Output Hold time
After RE Internal Clock
02
ns
tOFF
Outputs
Active to Float Delay
After RE Internal Clock
tSU
Inputs
Input Setup Time
Before RE Internal Clock
151
ns
tHL
Inputs
Input Hold Time
After RE Internal Clock
01
ns
tCSDV
Description
Reference Conditions
Min
Max
Unit
201
ns
301
Mode 0 Turbo
Chip Select active to Data Valid Read from External Device
Read Transaction
75
ns
ns
1. Not tested. Guaranteed by characterization.
2. Not tested. Guaranteed by design.
Outputs
Internal Clock
(for reference only;
not available off chip)
tVAL
tOH
tON
XA11-0, XD7-0,
XRD_XEN, XWR_XRW,
XSTB2-0, XCS3-0
tOFF
Inputs
Internal Clock
(for reference only:
not available off chip)
tSU
XD7-0
XRDY, XIRQ
tHL
Input
Valid
Mode 0 Turbo Read Transaction
XCS3-0
tCSDV
Data
Valid
XD7-0
Revision 1.2
245
www.national.com
PC8741x
11.0 Device Characteristics
(Continued)
11.5.6 ACCESS.bus Timing (PC87413 and PC87417)
Type of
Requirement1
Description
Min
Max
Unit
Input2
10003
ns
Input
3003
ns
Output2
2504
ns
Symbol
Figure
tACBR
63
Rise time (ACBCLK and ACBDAT)
tACBF
63
Fall time (ACBCLK and ACBDAT)
tACBCKL
63
Clock low period (ACBCLK)
Input
4.7
µs
tACBCKH
63
Clock high period (ACBCLK)
Input
4
µs
tACBCY
64
Clock cycle (ACBCLK)
Input
10
µs
250
ns
tACBDS
64
Data setup time (before clock rising edge)
250
ns
Input
0
ns
Output2
300
ns
Input
Output
2
tACBDH
64
Data hold time (after clock falling edge)
tACBPS
65
Stop condition setup time (clock before data)
Input
4
µs
tACBSH
65
Start condition hold time (clock after data)
Input
4
µs
tACBBUF
65
Bus free time between Stop and Start
conditions (ACBDAT)
Input
4.7
µs
tACBRS
66
Restart condition setup time (clock before
data)
Input
4.7
µs
tACBRH
66
Restart condition hold time (clock after data)
Input
4
µs
tACBLEX
-
Cumulative clock low extend time from Start
to Stop (ACBCLK)
Output
tACBTO
-
Clock low time-out (ACBCLK)
Input
ms
253
ms
253,5
Output
ms
353,6
1. An “Input” type is a value the PC8741x device expects from the system; an “Output” type is a value the
PC8741x device provides to the system.
2. Test conditions: RL = 1 KΩ to VSB = 3.3V, CL = 400 pF to GND.
3. Not tested. Guaranteed by design.
4. Not tested. Guaranteed by characterization.
5. The PC8741x device detects a time-out condition if ACBCLK is held low for more than tACBTO.
6. On detection of a time-out condition, the PC8741x device resets the ACCESS.bus Interface no later than
tACBTO.
tACBCKH
3.0V
2.5V
2.5V
0.4V
0.4V
tACBR
0.4V
tACBCKL
0.4V
tACBF
Figure 63. ACCESS.bus Signals (ACBCLK and ACBDAT) Rising Time and Falling Time
www.national.com
246
Revision1.2
PC8741x
11.0 Device Characteristics
(Continued)
ACBDAT
tACBDH
tACBDS
ACBCLK
tACBCY
Figure 64. ACCESS.bus Data Bit Timing
Start Condition
Stop Condition
ACBDAT
tACBDS
ACBCLK
tACBPS
tBUF
tACBSH
Figure 65. ACB Start and Stop Condition Timing
Restart Condition
ACBDAT
ACBCLK
tACBDS
tACBRS
tACBRH
Figure 66. ACB Restart Condition TIming
Revision 1.2
247
www.national.com
PC8741x
11.0 Device Characteristics
(Continued)
11.5.7 FDC Timing
FDC Write Data Timing
Symbol
Parameter
Min
Max
Unit
tHDH
HDSEL Hold from WGATE Inactive1
100
µs
tHDS
HDSEL Setup to WGATE Active1
100
µs
tWDW
Write Data Pulse Width1
See tDRP, tICP and tWDW values in table below
1. Not tested. Guaranteed by design.
HDSEL
WGATE
tHDS
tHDH
tWDW
WDATA
tDRP tICP tWDW Values
Data Rate
tDRP
tICP
tICP Nominal
tWDW
tWDW Minimum
Unit
1 Mbps
1000
6 x tCP1
125
2 x tICP
250
ns
500 Kbps
2000
6 x tCP1
125
2 x tICP
250
ns
300 Kbps
3333
10 x tCP1
208
2 x tICP
375
ns
250 Kbps
4000
12 x tCP1
250
2 x tICP
500
ns
1. tCP is the clock period defined for CLKIN in Clock Timing on page 241.
www.national.com
248
Revision1.2
PC8741x
11.0 Device Characteristics
(Continued)
FDC Drive Control Timing
Symbol
Parameter
Min
Max
Unit
6
µs
Index Pulse Width
100
ns
tSTD
DIR Hold from STEP Inactive
tSTR
ms
tSTP
STEP Active High Pulse Width1
8
µs
tSTR
STEP Rate Time1
0.5
ms
tDST
DIR Setup to STEP Active1
tIW
1. Not tested. Guaranteed by design.
DIR
tSTD
tDST
STEP
tSTP
tSTR
INDEX
tIW
FDC Read Data Timing
Symbol
tRDW
Parameter
Min
50
Read Data Pulse Width
Max
Unit
ns
tRDW
RDATA
Revision 1.2
249
www.national.com
PC8741x
11.0 Device Characteristics
(Continued)
11.5.8 Parallel Port Timing
Standard Parallel Port Timing
Symbol
Parameter
Conditions
Typ
Max
Unit
tPDH
Port Data Hold
These times are system dependent
and therefore are not tested.
500
ns
tPDS
Port Data Setup
These times are system dependent
and therefore are not tested.
500
ns
tSW
Strobe Width
These times are system dependent
and therefore are not tested.
500
ns
Typical Data Exchange
BUSY
ACK
tPDH
tPDS
PD7-0
tSW
STB
Enhanced Parallel Port Timing
Symbol
Parameter
Min
Max
EPP 1.7 EPP 1.9
Unit
tWW19a
WRITE Active from WAIT Low
45
✔
ns
tWW19ia
WRITE Inactive from WAIT Low
45
✔
ns
tWST19a
DSTRB or ASTRB Active from WAIT Low
65
✔
ns
tWEST
DSTRB or ASTRB Active after WRITE Active
10
✔
✔
ns
tWPDH
PD7-0 Hold after WRITE Inactive
0
✔
✔
ns
tWPDS
PD7-0 Valid after WRITE Active
✔
✔
ns
tEPDW
PD7-0 Valid Width
80
✔
✔
ns
tEPDH
PD7-0 Hold after DSTRB or ASTRB Inactive
0
✔
✔
ns
15
tWW19a
WRITE
DSTRB
or
ASTRB
tWST19a
tWEST
tWPDH
PD7-0
tWPDS
tWW19ia
tWST19a
tEPDH
Valid
tEPDW
WAIT
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250
Revision1.2
PC8741x
11.0 Device Characteristics
(Continued)
Extended Capabilities Port (ECP) Timing
Forward Mode
Symbol
Parameter
Min
Max
Unit
tECDSF
Data Setup before STB Active
0
ns
tECDHF
Data Hold after BUSY Inactive
0
ns
tECLHF
BUSY Active after STB Active
75
ns
tECHHF
STB Inactive after BUSY Active1
0
1
s
tECHLF
BUSY Inactive after STB Active1
0
35
ms
tECLLF
STB Active after BUSY Inactive
0
ns
1. Not tested. Guaranteed by design.
tECDHF
PD7-0
AFD
tECDSF
tECLLF
STB
tECHLF
tECLHF
BUSY
tECHHF
Reverse Mode
Symbol
Parameter
Min
Max
Unit
tECDSR
Data Setup before ACK Active
0
ns
tECDHR
Data Hold after AFD Active
0
ns
tECLHR
AFD Inactive after ACK Active
75
ns
tECHHR
ACK Inactive after AFD Inactive1
0
35
ms
tECHLR
AFD Active after ACK Inactive1
0
1
s
tECLLR
ACK Active after AFD Active
0
ns
1. Not tested. Guaranteed by design.
tECDHR
PD7-0
BUSY
tECDSR
ACK
tECLLR
tECLHR
AFD
Revision 1.2
tECHLR
tECHHR
251
www.national.com
PC8741x
11.0 Device Characteristics
11.5.9
(Continued)
Serial Ports 1 and 2 Timing
Serial Port Data Timing
Symbol
tBT
Parameter
Single Bit Time in Serial
Conditions
Min
Max
Unit
Transmitter
tBTN − 252
tBTN + 252
ns
Receiver
tBTN − 2%2
tBTN + 2%2
ns
Port1
1. Not tested. Guaranteed by design.
2. tBTN is the nominal bit time in the Serial Port; it is determined by the setting of the Baud Generator Divisor
registers.
tBT
SIN1, SIN2
SOUT1, SOUT2
Modem Control Timing
Symbol
Parameter
Min
Max
Unit
tL
RI2,1 Low Time1,2
10
ns
tH
RI2,1 High Time1,2
10
ns
tSIM
Delay to Set IRQ from Modem Input
40
ns
1. Not tested. Guaranteed by characterization
2. This value also applies to RI2,1 wake-up detection in the SWC module.
CTS, DSR, DCD
tSIM
tSIM
INTERRUPT
(Read MSR)
(Read MSR)
tSIM
tL
tH
RI
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252
Revision1.2
PC8741x
11.0 Device Characteristics
(Continued)
11.5.10 SWC Timing
Inputs at VSB Power Switching
Symbol
Figure
tEWIV
67
tPBOP
68
Description
Reference Conditions
Min
Max
External Wake-up inputs
valid1
At VSB power On, after the
32 KHz clock is stable2
1s
1.25 s
PWBTOUT pulse time1
Resume by SLPS3, SLPS5
after Power Fail
100 ms3,
100.03 ms
1. Not tested. Guaranteed by design.
2. No VBAT; the 32 KHz internal clock is stopped while VSB is Off (see Low Frequency Clock Timing on
page 242).
3. Except when generated by PWBTIN pulse.
VSB (Power)
VSBOFF
VSBON
tIRST
VSB Power-Up Reset
(Internal)
t32KW
32 KHz Clock
(internal)
tEWIV
GPIOE10-17,
GPIOE40-47
RI1, RI2
PWBTIN, SLBTIN
XIRQ
KBCLK, MCLK
KBDAT, MDAT
SLPS3, SLPS5
Figure 67. Inputs at VSB Power Switching (No VBAT)
Revision 1.2
253
www.national.com
PC8741x
11.0 Device Characteristics
(Continued)
VSBOFF
VSBON
VSB (Power)
tIRST
VSB Power-Up Reset
(Internal)
t32KW
32 KHz Clock
(internal)
tEWIV
SLPS3, SLPS5
TRI-STATE
ONCTL
tPBOP
TRI-STATE
PWBTOUT
Figure 68. Resume by SLPS3, SLPS5, After Power Fail (No VBAT)
Wake-Up Inputs at VDD Power Switching
Symbol
Figure
Description
Reference Conditions
Min
Max
tEWIV
69
External Wake-up inputs
valid1
After VDD power On
1s
1.25 s
tVDFH
69
VDDFELL high time1
After VDD power Off
1s
1.25 s
tKBMID
69
Keyboard and Mouse Wake- After VDD power Off, if
VDDFELL is enabled
up inputs disable1
2s
2.25 s
1. Not tested. Guaranteed by design.
VDD (Power)
GPIOE10-17,
GPIOE40-47
(VDDLOAD = 1)
VDDON
VDDOFF
tEWIV
tVDFH
VDDFELL
tKBMID
KBCLK, MCLK
KBDAT, MDAT
Figure 69. Wake-Up Inputs at VDD Power Switching (VDDFELL Enabled)
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254
Revision1.2
PC8741x
11.0 Device Characteristics
(Continued)
Power Button Override
Symbol
Figure
Description
tPBOV
70
Power Button Override1
tOVEX
70
tPBID
70
Reference Conditions
Min
Max
After PWBTIN active
3.89 s
3.92 s
Power Button Override
Extension1
After the end of tPBOV
0.2 s
0.24 s
PWBTIN disable time1
After a Power-Off event
1s
1.25 s
1. Not tested. Guaranteed by design.
tPBOV
tOVEX
tPBID
PWBTIN
PWBTOUT
ONCTL
Figure 70. Power Button Override Timing
Revision 1.2
255
www.national.com
PC8741x
11.0 Device Characteristics
(Continued)
Crowbar
Symbol
Figure
tCBTO
71, 72
tCBPBO
tPBID
Description
Reference Conditions
Min
Max
Crowbar Timeout1
After ONCTL active, or VDD
power fall
0.5 s2
20 s2
71, 72
Crowbar generated,
PWBTOUT pulse time1
After completion of Crowbar
Timeout
4s
4.25 s
71, 72
PWBTIN disable time1
After a Power-Off event
1s
1.25 s
1. Not tested. Guaranteed by design.
2. Set by CRBAR_TOUT (see Section 9.3.11 on page 188).
tPBID
PWBTIN
tCBPBO
PWBTOUT
ONCTL
tCBTO
VDD (Power)
Figure 71. Power-On Crowbar Timing
tPBID
PWBTIN
tCBPBO
PWBTOUT
ONCTL
tCBTO
VDD (Power)
Figure 72. Power-Fall Crowbar Timing
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256
Revision1.2
PC87413, PC87414, PC87416, PC87417 LPC ServerI/O for Servers and Workstations
Physical Dimensions
All dimensions are in millimeters
Plastic Quad Flatpack (PQFP), JEDEC
Order Number PC8741x-xxx/VLA
NS Package Number VLA128A
LIFE SUPPORT POLICY
NATIONAL’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT
DEVICES OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT AND GENERAL
COUNSEL OF NATIONAL SEMICONDUCTOR CORPORATION. As used herein:
1. Life support devices or systems are devices or
systems which, (a) are intended for surgical implant
into the body, or (b) support or sustain life, and whose
failure to perform, when properly used in accordance
with instructions for use provided in the labeling, can
be reasonably expected to result in a significant injury
to the user.
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Corporation
Americas
Email: [email protected]
2. A critical component is any component of a life
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be reasonably expected to cause the failure of the life
support device or system, or to affect its safety or
effectiveness.
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Fax: +49 (0) 180-530 85 86
Email: [email protected]
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