ETC PI7C8150

PI7C8150
2-Port PCI-to-PCI Bridge
REVISION 1.04
2380 Bering Drive, San Jose, CA 95131
Telephone: 1-877-PERICOM, (1-877-737-4266)
Fax: 408-435-1100
Email: [email protected]
Internet: http://www.pericom.com
PI7C8150
2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
LIFE SUPPORT POLICY
Pericom Semiconductor Corporation’s products are not authorized for use as critical components in life
support devices or systems unless a specific written agreement pertaining to such intended use is executed
between the manufacturer and an officer of PSC.
1) Life support devices or system 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.
2) A critical component is any component of a life support device or system whose failure to perform can
be reasonably expected to cause the failure of the life support device or system, or to affect its safety or
effectiveness. Pericom Semiconductor Corporation reserves the right to make changes to its products
or specifications at any time, without notice, in order to improve design or performance and to supply
the best possible product. Pericom Semiconductor does not assume any responsibility for use of any
circuitry described other than the circuitry embodied in a Pericom Semiconductor product. The
Company makes no representations that circuitry described herein is free from patent infringement or
other rights of third parties which may result from its use. No license is granted by implication or
otherwise under any patent, patent rights or other rights, of Pericom Semiconductor Corporation.
All other trademarks are of their respective companies.
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March 19, 2003 – Revision 1.04
PI7C8150
2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
REVISION HISTORY
Date
07/16/02
08/06/02
Revision Number
1.01
1.02
Description
First Release of Data Sheet
Removed “TBD” parameters for TDELAY in sections 17.4 and 17.5
Added 256-ball PBGA package information, Ordering Information
(18.1), and pin list.
Corrected pin type for pins 127 and 128 to “undefined” in the pin list
(section 2.3).
9/4/02
1.03
12/5/02
1.03
03/19/03
1.04
Added pin descriptions for pins MS0 and MS1 (section 2.2.4).
Corrected Secondary IDSEL S_AD[31:16] condition in Table 4-6
Corrected Maximum Voltage on Input pins in section 17.1
Revised PBGA pin list to reflect MS0 and MS1 for pins B14 and R16
respectively.
Corrected section reference on p17 from 5.3 to 4.3.
Corrected bits 24 and 25 descriptions for section 14.1.28 Bridge
Control Register – Offset 3Ch.
Corrected bit 4 description for section 14.1.29 Diagnostic / Chip
Control Register – Offset 40h.
Corrected bits 24 through 31 descriptions in section 14.1.39 GPIO Data
and Control Register – Offset 64h.
General corrections to reference numbers and page numbers.
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2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
TABLE OF CONTENTS
1
INTRODUCTION ................................................................................................................................ 1
2
SIGNAL DEFINITIONS ..................................................................................................................... 2
2.1
SIGNAL TYPES ................................................................................................................................. 2
2.2
SIGNALS .......................................................................................................................................... 2
2.2.1
PRIMARY BUS INTERFACE SIGNALS ............................................................................ 2
2.2.3
CLOCK SIGNALS ................................................................................................................. 5
2.2.4
MISCELLANEOUS SIGNALS............................................................................................. 5
2.2.5
GENERAL PURPOSE I/O INTERFACE SIGNALS .......................................................... 6
2.2.6
JTAG BOUNDARY SCAN SIGNALS .................................................................................. 6
2.2.7
POWER AND GROUND....................................................................................................... 7
2.3
PIN LIST – 208-PIN FQFP............................................................................................................. 7
2.4
PIN LIST – 256-BALL PBGA........................................................................................................ 9
3
PCI BUS OPERATION ..................................................................................................................... 10
3.1
TYPES OF TRANSACTIONS ..................................................................................................... 10
3.2
SINGLE ADDRESS PHASE........................................................................................................ 11
3.3
DEVICE SELECT (DEVSEL_L) GENERATION....................................................................... 11
3.4
DATA PHASE.............................................................................................................................. 12
3.5
WRITE TRANSACTIONS .......................................................................................................... 12
3.5.1
MEMORY WRITE TRANSACTIONS................................................................................ 12
3.5.2
MEMORY WRITE AND INVALIDATE ............................................................................ 13
3.5.3
DELAYED WRITE TRANSACTIONS............................................................................... 13
3.5.4
WRITE TRANSACTION ADDRESS BOUNDARIES....................................................... 14
3.5.5
BUFFERING MULTIPLE WRITE TRANSACTIONS..................................................... 15
3.5.6
FAST BACK-TO-BACK TRANSACTIONS ....................................................................... 15
3.6
READ TRANSACTIONS ............................................................................................................ 15
3.6.1
PREFETCHABLE READ TRANSACTIONS.................................................................... 15
3.6.2
NON-PREFETCHABLE READ TRANSACTIONS.......................................................... 16
3.6.3
READ PREFETCH ADDRESS BOUNDARIES ............................................................... 16
3.6.4
DELAYED READ REQUESTS .......................................................................................... 17
3.6.5
DELAYED READ COMPLETION WITH TARGET ........................................................ 17
3.6.6
DELAYED READ COMPLETION ON INITIATOR BUS................................................ 18
3.6.7
FAST BACK-TO-BACK READ TRANSACTION ............................................................. 19
3.7
CONFIGURATION TRANSACTIONS ...................................................................................... 19
3.7.1
TYPE 0 ACCESS TO PI7C8150 ......................................................................................... 19
3.7.2
TYPE 1 TO TYPE 0 CONVERSION .................................................................................. 20
3.7.3
TYPE 1 TO TYPE 1 FORWARDING................................................................................. 21
3.7.4
SPECIAL CYCLES ............................................................................................................. 22
3.8
TRANSACTION TERMINATION.............................................................................................. 23
3.8.1
MASTER TERMINATION INITIATED BY PI7C8150.................................................... 24
3.8.2
MASTER ABORT RECEIVED BY PI7C8150................................................................... 24
3.8.3
TARGET TERMINATION RECEIVED BY PI7C8150 .................................................... 25
3.8.4
TARGET TERMINATION INITIATED BY PI7C8150 .................................................... 27
4
ADDRESS DECODING..................................................................................................................... 29
4.1
ADDRESS RANGES ................................................................................................................... 29
4.2
I/O ADDRESS DECODING ........................................................................................................ 29
4.2.1
I/O BASE AND LIMIT ADDRESS REGISTER................................................................ 30
4.2.2
ISA MODE........................................................................................................................... 31
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2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
4.3
MEMORY ADDRESS DECODING............................................................................................ 31
4.3.1
MEMORY-MAPPED I/O BASE AND LIMIT ADDRESS REGISTERS ......................... 32
4.3.2
PREFETCHABLE MEMORY BASE AND LIMIT ADDRESS REGISTERS ................. 33
4.4
VGA SUPPORT ........................................................................................................................... 34
4.4.1
VGA MODE......................................................................................................................... 34
4.4.2
VGA SNOOP MODE........................................................................................................... 34
5
TRANSACTION ORDERING.......................................................................................................... 35
5.1
5.2
5.3
5.4
6
TRANSACTIONS GOVERNED BY ORDERING RULES ........................................................ 35
GENERAL ORDERING GUIDELINES...................................................................................... 36
ORDERING RULES .................................................................................................................... 36
DATA SYNCHRONIZATION .................................................................................................... 37
ERROR HANDLING......................................................................................................................... 38
6.1
ADDRESS PARITY ERRORS .................................................................................................... 38
6.2
DATA PARITY ERRORS............................................................................................................ 39
6.2.1
CONFIGURATION WRITE TRANSACTIONS TO CONFIGURATION SPACE.......... 39
6.2.2
READ TRANSACTIONS .................................................................................................... 39
6.2.3
DELAYED WRITE TRANSACTIONS............................................................................... 40
6.2.4
POSTED WRITE TRANSACTIONS.................................................................................. 43
6.3
DATA PARITY ERROR REPORTING SUMMARY ................................................................. 44
6.4
SYSTEM ERROR (SERR#) REPORTING.................................................................................. 48
7
EXCLUSIVE ACCESS ...................................................................................................................... 49
7.1
CONCURRENT LOCKS ............................................................................................................. 49
7.2
ACQUIRING EXCLUSIVE ACCESS ACROSS PI7C8150........................................................ 49
7.2.1
LOCKED TRANSACTIONS IN DOWNSTREAM DIRECTION ..................................... 49
7.2.2
LOCKED TRANSACTION IN UPSTREAM DIRECTION .............................................. 51
7.3
ENDING EXCLUSIVE ACCESS ................................................................................................ 51
8
PCI BUS ARBITRATION................................................................................................................. 51
8.1
PRIMARY PCI BUS ARBITRATION......................................................................................... 52
8.2
SECONDARY PCI BUS ARBITRATION .................................................................................. 52
8.2.1
SECONDARY BUS ARBITRATION USING THE INTERNAL ARBITER.................... 52
8.2.2
PREEMPTION .................................................................................................................... 54
8.2.3
SECONDARY BUS ARBITRATION USING AN EXTERNAL ARBITER...................... 54
8.2.4
BUS PARKING.................................................................................................................... 54
9
CLOCKS ............................................................................................................................................. 55
9.1
9.2
10
10.1
10.2
10.3
PRIMARY CLOCK INPUTS....................................................................................................... 55
SECONDARY CLOCK OUTPUTS............................................................................................. 55
GENERAL PURPOSE I/O INTERFACE.................................................................................... 55
GPIO CONTROL REGISTERS ................................................................................................... 55
SECONDARY CLOCK CONTROL............................................................................................ 56
LIVE INSERTION ....................................................................................................................... 58
11
PCI POWER MANAGEMENT .................................................................................................... 58
12
RESET............................................................................................................................................. 59
12.1
12.2
12.3
PRIMARY INTERFACE RESET ................................................................................................ 59
SECONDARY INTERFACE RESET .......................................................................................... 59
CHIP RESET ................................................................................................................................ 60
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PI7C8150
2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
13
13.1
13.2
14
SUPPORTED COMMANDS......................................................................................................... 60
PRIMARY INTERFACE ............................................................................................................. 60
SECONDARY INTERFACE ....................................................................................................... 61
CONFIGURATION REGISTERS................................................................................................ 62
14.1 CONFIGURATION REGISTER.................................................................................................. 62
14.1.1 VENDOR ID REGISTER – OFFSET 00h......................................................................... 63
14.1.2 DEVICE ID REGISTER – OFFSET 00h .......................................................................... 63
14.1.3 COMMAND REGISTER – OFFSET 04h.......................................................................... 63
14.1.4 STATUS REGISTER – OFFSET 04h ................................................................................ 64
14.1.5 REVISION ID REGISTER – OFFSET 08h ...................................................................... 65
14.1.6 CLASS CODE REGISTER – OFFSET 08h....................................................................... 65
14.1.7 CACHE LINE SIZE REGISTER – OFFSET 0Ch ............................................................ 65
14.1.8 PRIMARY LATENCY TIMER REGISTER – OFFSET 0Ch ........................................... 66
14.1.9 HEADER TYPE REGISTER – OFFSET 0Ch................................................................... 66
14.1.10
PRIMARY BUS NUMBER REGISTSER – OFFSET 18h............................................ 66
14.1.11
SECONDARY BUS NUMBER REGISTER – OFFSET 18h ........................................ 66
14.1.12
SUBORDINATE BUS NUMBER REGISTER – OFFSET 18h.................................... 66
14.1.13
SECONDARY LATENCY TIMER REGISTER – OFFSET 18h .................................. 66
14.1.14
I/O BASE REGISTER – OFFSET 1Ch.......................................................................... 67
14.1.15
I/O LIMIT REGISTER – OFFSET 1Ch ........................................................................ 67
14.1.16
SECONDARY STATUS REGISTER – OFFSET 1Ch................................................... 67
14.1.17
MEMORY BASE REGISTER – OFFSET 20h .............................................................. 68
14.1.18
MEMORY LIMIT REGISTER – OFFSET 20h............................................................. 68
14.1.19
PEFETCHABLE MEMORY BASE REGISTER – OFFSET 24h ................................ 68
14.1.20
PREFETCHABLE MEMORY LIMIT REGISTER – OFFSET 24h ............................ 69
14.1.21
PREFETCHABLE MEMORY BASE ADDRESS UPPER 32-BITS REGISTER –
OFFSET 28h ....................................................................................................................................... 69
14.1.22
PREFETCHABLE MEMORY LIMIT ADDRESS UPPER 32-BITS REGISTER –
OFFSET 2Ch....................................................................................................................................... 69
14.1.23
I/O BASE ADDRESS UPPER 16-BITS REGISTER – OFFSET 30h .......................... 69
14.1.24
I/O LIMIT ADDRESS UPPER 16-BITS REGISTER – OFFSET 30h......................... 70
14.1.25
ECP POINTER REGISTER – OFFSET 34h................................................................. 70
14.1.26
INTERRUPT LINE REGISTER – OFFSET 3Ch ......................................................... 70
14.1.27
INTERRUPT PIN REGISTER – OFFSET 3Ch............................................................ 70
14.1.28
BRIDGE CONTROL REGISTER – OFFSET 3Ch ....................................................... 70
14.1.29
DIAGNOSTIC / CHIP CONTROL REGISTER – OFFSET 40h.................................. 72
14.1.30
ARBITER CONTROL REGISTER – OFFSET 40h...................................................... 73
14.1.31
EXTENDED CHIP CONTROL REGISTER – OFFSET 48h....................................... 73
14.1.32
UPSTREAM MEMORY CONTROL REGISTER – OFFSET 48h ............................... 74
14.1.33
SECONDARY BUS ARBITER PREEMPTION CONTROL REGISTER – OFFSET
4Ch
.......................................................................................................................................... 74
14.1.34
UPSTREAM (S TO P) MEMORY BASE REGISTER – OFFSET 50h ........................ 74
14.1.35
UPSTREAM (S TO P) MEMORY LIMIT REGISTER – OFFSET 50h....................... 74
14.1.36
UPSTREAM (S TO P) MEMORY BASE UPPER 32-BITS REGISTER – OFFSET 54h
.......................................................................................................................................... 75
14.1.37
UPSTREAM (S TO P) MEMORY LIMIT UPPER 32-BITS REGISTER – OFFSET
58h
.......................................................................................................................................... 75
14.1.38
P_SERR_L EVENT DISABLE REGISTER – OFFSET 64h........................................ 75
14.1.39
GPIO DATA AND CONTROL REGISTER – OFFSET 64h ........................................ 76
14.1.40
SECONDARY CLOCK CONTROL REGISTER – OFFSET 68h ................................. 77
14.1.41
P_SERR_L STATUS REGISTER – OFFSET 68h ........................................................ 77
14.1.42
PORT OPTION REGISTER – OFFSET 74h ................................................................ 78
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2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
14.1.43
14.1.44
14.1.45
14.1.46
14.1.47
14.1.48
14.1.49
14.1.50
14.1.51
14.1.52
14.1.53
14.1.54
14.1.55
15
RETRY COUNTER REGISTER – OFFSET 78h .......................................................... 79
PRIMARY MASTER TIMEOUT COUNTER – OFFSET 80h ..................................... 79
SECONDARY MASTER TIMEOUT COUNTER – OFFSET 80h ............................... 79
CAPABILITY ID REGISTER – OFFSET B0h ............................................................. 79
NEXT POINTER REGISTER – OFFSET B0h ............................................................. 80
SLOT NUMBER REGISTER – OFFSET B0h .............................................................. 80
CHASSIS NUMBER REGISTER – OFFSET B0h ....................................................... 80
CAPABILITY ID REGISTER – OFFSET DCh............................................................. 80
NEXT ITEM POINTER REGISTER – OFFSET DCh ................................................. 80
POWER MANAGEMENT CAPABILITIES REGISTER – OFFSET DCh ................. 80
POWER MANAGEMENT DATA REGISTER – OFFSET E0h................................... 81
CAPABILITY ID REGISTER – OFFSET E4h ............................................................. 81
NEXT POINTER REGISTER – OFFSET E4h ............................................................. 81
BRIDGE BEHAVIOR.................................................................................................................... 82
15.1 BRIDGE ACTIONS FOR VARIOUS CYCLE TYPES................................................................ 82
15.2 ABNORMAL TERMINATION (INITIATED BY BRIDGE MASTER)..................................... 82
15.2.1 MASTER ABORT................................................................................................................ 82
15.2.2 PARITY AND ERROR REPORTING ................................................................................ 82
15.2.3 REPORTING PARITY ERRORS ....................................................................................... 83
15.2.4 SECONDARY IDSEL MAPPING ...................................................................................... 83
16
IEEE 1149.1 COMPATIBLE JTAG CONTROLLER................................................................ 83
16.1 BOUNDARY SCAN ARCHITECTURE ..................................................................................... 83
16.1.1 TAP PINS ............................................................................................................................ 84
16.1.2 INSTRUCTION REGISTER .............................................................................................. 84
16.2 BOUNDARY SCAN INSTRUCTION SET ................................................................................. 85
16.3 TAP TEST DATA REGISTERS .................................................................................................. 85
16.4 BYPASS REGISTER ................................................................................................................... 86
16.5 BOUNDARY-SCAN REGISTER................................................................................................ 86
16.6 TAP CONTROLLER ................................................................................................................... 86
17
17.1
17.2
17.3
17.4
17.5
17.6
18
18.1
18.2
18.3
ELECTRICAL AND TIMING SPECIFICATIONS................................................................... 90
MAXIMUM RATINGS ............................................................................................................... 90
DC SPECIFICATIONS ................................................................................................................ 90
AC SPECIFICATIONS ................................................................................................................ 91
66MHZ TIMING .......................................................................................................................... 91
33MHZ TIMING .......................................................................................................................... 92
POWER CONSUMPTION........................................................................................................... 92
PACKAGE INFORMATION........................................................................................................ 92
208-PIN FQFP PACKAGE DIAGRAM....................................................................................... 92
256-BALL PBGA PACKAGE DIAGRAM.................................................................................. 93
PART NUMBER ORDERING INFORMATION ........................................................................ 93
LIST OF TABLES
Table 3-1.
Table 3-2.
Table 4-1.
Table 4-2.
Table 4-3.
Table 4-4.
Pin list – 208-pin FQFP_______________________________________________________ 7
Pin list – 256-ball PBGA ______________________________________________________ 9
PCI Transactions ___________________________________________________________ 11
Write Transaction Forwarding ________________________________________________ 12
Write Transaction Disconnect Address Boundaries ________________________________ 15
Read Prefetch Address Boundaries _____________________________________________ 16
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2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
Table 4-5. Read Transaction Prefetching_________________________________________________ 17
Table 4-6. Device Number to IDSEL S_AD Pin Mapping____________________________________ 21
Table 4-7. Delayed Write Target Termination Response _____________________________________ 25
Table 4-8. Response to Posted Write Target Termination ____________________________________ 26
Table 4-9. Response to Delayed Read Target Termination ___________________________________ 27
Table 5-1. Summary of Transaction Ordering _____________________________________________ 36
Table 6-1. Setting the Primary Interface Detected Parity Error Bit ____________________________ 44
Table 6-2. Setting Secondary Interface Detected Parity Error Bit______________________________ 45
Table 6-3. Setting Primary Interface Master Data Parity Error Detected Bit_____________________ 45
Table 6-4. Setting Secondary Interface Master Data Parity Error Detected Bit ___________________ 46
Table 6-5. Assertion of P_PERR#_______________________________________________________ 46
Table 6-6. Assertion of S_PERR# _______________________________________________________ 47
Table 6-7. Assertion of P_SERR# for Data Parity Errors ____________________________________ 47
Table 10-1. GPIO Operation ___________________________________________________________ 56
Table 10-2. GPIO Serial Data Format ___________________________________________________ 57
Table 11-1. Power management transitions _______________________________________________ 58
Table 16-1. TAP Pins_________________________________________________________________ 85
Table 16-2. JTAG Boundary Register Order _______________________________________________ 87
LIST OF FIGURES
Figure 9-1. Secondary Arbiter Example...................................................................................................... 53
Figure 16-1. Test Access Port Block Diagram ............................................................................................ 84
Figure 17-1. PCI Signal Timing Measurement Conditions ......................................................................... 91
Figure 18-1. 208-pin FQFP Package Outline ............................................................................................... 92
Figure 18-2. 256-ball PBGA Package Outline ............................................................................................. 93
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2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
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2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
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2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
1
INTRODUCTION
Product Description
The PI7C8150 is Pericom Semiconductor’s third-generation PCI-PCI Bridge.
It is designed to be fully compliant with the 32-bit, 66MHz implementation of
the PCI Local Bus Specification, Revision 2.2. The PI7C8150 supports only synchronous
bus transactions between devices on the Primary Bus running at 33MHz to 66MHz and the
Secondary Buses operating at either 33MHz or 66MHz. The Primary and Secondary Bus
can also operate in concurrent mode, resulting in added increase in system performance.
Concurrent bus operation off-loads and isolates unnecessary traffic from the Primary Bus,
thereby enabling a master and a target device on the Secondary PCI Bus to communicate
even while the Primary Bus is busy.
Product Features
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
32-bit Primary and Secondary Ports run up to 66MHz
Compliant with the PCI Local Bus Specification, Revision 2.2
Compliant with PCI-to-PCI Bridge Architecture Specification, Revision 1.1.
- All I/O and memory commands
- Type 1 to Type 0 configuration conversion
- Type 1 to Type 1 configuration forwarding
- Type 1 configuration write to special cycle conversion
Compliant with the Advanced Configuration Power Interface (ACPI) Specification.
Compliant with the PCI Power Management Specification, Revision 1.0.
Concurrent Primary to Secondary Bus operation and independent intra-Secondary Port
channel to reduce traffic on the Primary Port
Provides internal arbitration for one set of nine secondary bus masters
- Programmable 2-level priority arbiter
- Disable control for use of external arbiter
Supports posted write buffers in all directions
Two 128 byte FIFO’s for delay transactions
Two 128 byte FIFO’s for posted memory transactions
Enhanced address decoding
- 32-bit I/O address range
- 32-bit memory-mapped I/O address range
- VGA addressing and VGA palette snooping
- ISA-aware mode for legacy support in the first 64KB of I/O address range
Interrupt handling
- PCI interrupts are routed through an external interrupt concentrator
Supports system transaction ordering rules
Extended commercial temperature range 0°C to 85°C
IEEE 1149.1 JTAG interface support
3.3V core; 3.3V and 5V signaling
208-pin FQFP package
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PI7C8150
2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
2
SIGNAL DEFINITIONS
2.1
Signal Types
Signal Type
I
O
P
TS
STS
Description
Input Only
Output Only
Power
Tri-State bi-directional
Sustained Tri-State. Active LOW signal must be pulled HIGH for 1 cycle when
deasserting.
Open Drain
OD
2.2
Signals
Note: Signal names that end with “_L” are active LOW.
2.2.1
PRIMARY BUS INTERFACE SIGNALS
Name
P_AD[31:0]
P_CBE[3:0]
Pin #
49, 50, 55, 57, 58,
60, 61, 63, 67, 68,
70, 71, 73, 74, 76,
77, 93, 95, 96, 98,
99, 101, 107, 109,
112, 113, 115,
116, 118, 119,
121, 122
64, 79, 92, 110
Type
TS
P_PAR
90
TS
P_FRAME_L
80
STS
TS
Description
Primary Address / Data: Multiplexed address and data
bus. Address is indicated by P_FRAME_L assertion.
Write data is stable and valid when P_IRDY_L is
asserted and read data is stable and valid when
P_TRDY_L is asserted. Data is transferred on rising
clock edges when both P_IRDY_L and P_TRDY_L are
asserted. During bus idle, PI7C8150 drives P_AD to a
valid logic level when P_GNT_L is asserted.
Primary Command/Byte Enables: Multiplexed
command field and byte enable field. During address
phase, the initiator drives the transaction type on these
pins. After that, the initiator drives the byte enables
during data phases. During bus idle, PI7C8150 drives
P_CBE[3:0] to a valid logic level when P_GNT_L is
asserted.
Primary Parity. Parity is even across P_AD[31:0],
P_CBE[3:0], and P_PAR (i.e. an even number of 1’s).
P_PAR is an input and is valid and stable one cycle after
the address phase (indicated by assertion of
P_FRAME_L) for address parity. For write data phases,
P_PAR is an input and is valid one clock after
P_IRDY_L is asserted. For read data phase, P_PAR is
an output and is valid one clock after P_TRDY_L is
asserted. Signal P_PAR is tri-stated one cycle after the
P_AD lines are tri-stated. During bus idle, PI7C8150
drives P_PAR to a valid logic level when P_GNT_L is
asserted.
Primary FRAME (Active LOW). Driven by the
initiator of a transaction to indicate the beginning and
duration of an access. The de-assertion of P_FRAME_L
indicates the final data phase requested by the initiator.
Before being tri-stated, it is driven to a de-asserted state
for one cycle.
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PI7C8150
2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
Name
P_IRDY_L
Pin #
82
Type
STS
P_TRDY_L
83
STS
P_DEVSEL_L
84
STS
P_STOP_L
85
STS
P_LOCK_L
87
STS
P_IDSEL
65
I
P_PERR_L
88
STS
P_SERR_L
89
OD
P_REQ_L
47
TS
P_GNT_L
46
I
P_RESET_L
43
I
P_M66EN
102
I
Description
Primary IRDY (Active LOW). Driven by the initiator
of a transaction to indicate its ability to complete current
data phase on the primary side. Once asserted in a data
phase, it is not de-asserted until the end of the data
phase. Before tri-stated, it is driven to a de-asserted state
for one cycle.
Primary TRDY (Active LOW). Driven by the target of
a transaction to indicate its ability to complete current
data phase on the primary side. Once asserted in a data
phase, it is not de-asserted until the end of the data
phase. Before tri-stated,
it is driven to a de-asserted state for one cycle.
Primary Device Select (Active LOW). Asserted by the
target indicating that the device is accepting the
transaction. As a master, PI7C8150 waits for the
assertion of this signal within 5 cycles of P_FRAME_L
assertion; otherwise, terminate with master abort. Before
tri-stated, it is driven to a
de-asserted state for one cycle.
Primary STOP (Active LOW). Asserted by the target
indicating that the target is requesting the initiator to stop
the current transaction. Before tri-stated, it is driven to a
de-asserted state for one cycle.
Primary LOCK (Active LOW). Asserted by the
master for multiple transactions to complete.
Primary ID Select. Used as a chip select line for Type
0 configuration access to PI7C8150 configuration space.
Primary Parity Error (Active LOW). Asserted when
a data parity error is detected for data received on the
primary interface. Before being tri-stated, it is driven to
a de-asserted state for one cycle.
Primary System Error (Active LOW). Can be driven
LOW by any device to indicate a system error condition.
PI7C8150 drives this pin on:
!
Address parity error
!
Posted write data parity error on target bus
!
Secondary S_SERR_L asserted
!
Master abort during posted write transaction
!
Target abort during posted write transaction
!
Posted write transaction discarded
!
Delayed write request discarded
!
Delayed read request discarded
!
Delayed transaction master timeout
This signal requires an external pull-up resistor for
proper operation.
Primary Request (Active LOW): This is asserted by
PI7C8150 to indicate that it wants to start a transaction
on the primary bus. PI7C8150 de-asserts this pin for at
least 2 PCI clock cycles before asserting it again.
Primary Grant (Active LOW): When asserted,
PI7C8150 can access the primary bus. During idle and
P_GNT_L asserted, PI7C8150 will drive P_AD, P_CBE,
and P_PAR to valid logic levels.
Primary RESET (Active LOW): When P_RESET_L is
active, all PCI signals should be asynchronously tristated.
Primary Interface 66MHz Operation.
This input is used to specify if PI7C8150 is capable of
running at 66MHz. For 66MHz operation on the Primary
bus, this signal should be pulled “HIGH”. For 33MHz
operation on the Primary bus, this signal should be
pulled “LOW”. In this condition, S_M66EN will need
to be “LOW”, forcing the secondary buse to run at
33MHz also.
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March 19, 2003 – Revision 1.04
PI7C8150
2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
2.2.2
SECONDARY BUS INTERFACE SIGNALS
Name
S_AD[31:0]
S_CBE[3:0]
Pin #
206, 204, 203,
201, 200, 198,
197, 195, 192,
191, 189, 188,
186, 185, 183,
182, 165, 164,
162, 161, 159,
154, 152, 150,
147, 146, 144,
143, 141, 140,
138, 137
194, 180, 167, 149
Type
TS
Description
Secondary Address/Data: Multiplexed address and data
bus. Address is indicated by S_FRAME_L assertion.
Write data is stable and valid when S_IRDY_L is
asserted and read data is stable and valid when
S_IRDY_L is asserted. Data is transferred on rising
clock edges when both S_IRDY_L and S_TRDY_L are
asserted. During bus idle, PI7C8150 drives S_AD to a
valid logic level when S_GNT_L is asserted
respectively.
TS
Secondary Command/Byte Enables: Multiplexed
command field and byte enable field. During address
phase, the initiator drives the transaction type on these
pins. The initiator then drives the byte enables during
data phases. During bus idle, PI7C8150 drives
S_CBE[3:0] to a valid logic level when the internal grant
is asserted.
Secondary Parity: Parity is even across S_AD[31:0],
S_CBE[3:0], and S_PAR (i.e. an even number of 1’s).
S_PAR is an input and is valid and stable one cycle after
the address phase (indicated by assertion of
S_FRAME_L) for address parity. For write data phases,
S_PAR is an input and is valid one clock after
S_IRDY_L is asserted. For read data phase, S_PAR is
an output and is valid one clock after S_TRDY_L is
asserted. Signal S_PAR is tri-stated one cycle after the
S_AD lines are tri-stated. During bus idle, PI7C8150
drives S_PAR to a valid logic level when the internal
grant is asserted.
Secondary FRAME (Active LOW): Driven by the
initiator of a transaction to indicate the beginning and
duration of an access. The de-assertion of S_FRAME_L
indicates the final data phase requested by the initiator.
Before being tri-stated, it is driven to a de-asserted state
for one cycle.
Secondary IRDY (Active LOW): Driven by the
initiator of a transaction to indicate its ability to
complete current data phase on the secondary side. Once
asserted in a data phase, it is not de-asserted until the end
of the data phase. Before tri-stated, it is driven to a deasserted state for one cycle.
Secondary TRDY (Active LOW): Driven by the target
of a transaction to indicate its ability to complete current
data phase on the secondary side. Once asserted in a
data phase, it is not de-asserted until the end of the data
phase. Before tri-stated, it is driven to a de-asserted state
for one cycle.
Secondary Device Select (Active LOW): Asserted by
the target indicating that the device is accepting the
transaction. As a master, PI7C8150 waits for the
assertion of this signal within 5 cycles of S_FRAME_L
assertion; otherwise, terminate with master abort. Before
tri-stated, it is driven to a de-asserted state for one cycle.
Secondary STOP (Active LOW): Asserted by the
target indicating that the target is requesting the initiator
to stop the current transaction. Before tri-stated, it is
driven to a de-asserted state for one cycle.
Secondary LOCK (Active LOW): Asserted by the
master for multiple transactions to complete.
S_PAR
168
TS
S_FRAME_L
179
STS
S_IRDY_L
177
STS
S_TRDY_L
176
STS
S_DEVSEL_L
175
STS
S_STOP_L
173
STS
S_LOCK_L
172
STS
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March 19, 2003 – Revision 1.04
PI7C8150
2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
2.2.3
Name
S_PERR_L
Pin #
171
Type
STS
S_SERR_L
169
I
S_REQ_L[8:0]
9, 8, 7, 6, 5, 4, 3,
2, 207
I
S_GNT_L[8:0]
19, 18, 17, 16, 15,
14, 13, 11, 10
TS
S_RESET_L
22
O
S_M66EN
153
I/OD
S_CFN_L
23
I
Description
Secondary Parity Error (Active LOW): Asserted
when a data parity error is detected for data received on
the secondary interface. Before being tri-stated, it is
driven to a de-asserted state for one cycle.
Secondary System Error (Active LOW): Can be
driven LOW by any device to indicate a system error
condition.
Secondary Request (Active LOW): This is asserted by
an external device to indicate that it wants to start a
transaction on the secondary bus. The input is externally
pulled up through a resistor to VDD.
Secondary Grant (Active LOW): PI7C8150 asserts this
pin to access the secondary bus. PI7C8150 de-asserts
this pin for at least 2 PCI clock cycles before asserting it
again. During idle and S_GNT_L asserted, PI7C8150
will drive S_AD, S_CBE, and S_PAR.
Secondary RESET (Active LOW): Asserted when any
of the following conditions are met:
1.
Signal P_RESET_L is asserted.
2.
Secondary reset bit in bridge control register in
configuration space is set.
When asserted, all control signals are tri-stated and
zeroes are driven on S_AD, S_CBE, and S_PAR.
Secondary Interface 66MHz Operation: This input is
used to specify if PI7C8150 is running at 66MHz on the
secondary side. When HIGH, the Secondary bus may
run at 66MHz. When LOW, the Secondary bus may
only run at 33MHz.
If P_M66EN is pulled LOW, the S_M66EN is driven
also driven LOW.
Secondary Bus Central Function Control Pin: When
tied LOW, it enables the internal arbiter. When tied
HIGH, an external arbiter must be used. S_REQ_L[0] is
reconfigured to be the secondary bus grant input, and
S_GNT_L[0] is reconfigured to be the secondary bus
request output.
CLOCK SIGNALS
Name
P_CLK
Pin #
45
Type
I
S_CLKIN
21
I
S_CLKOUT[9:0]
42, 41, 39, 38, 36,
35, 33, 32, 30, 29
O
Description
Primary Clock Input: Provides timing for all
transactions on the primary interface.
Secondary Clock Input: Provides timing for all
transactions on the secondary interface.
Secondary Clock Output: Provides secondary clocks
phase synchronous with the P_CLK.
When these clocks are used, one of the clock outputs
must be fed back to S_CLKIN. Unused outputs may be
disabled by:
1. Writing the secondary clock disable bits in the
configuration space
2. Using the serial disable mask using the GPIO pins and
MSK_IN
3. Terminating them electrically.
2.2.4
MISCELLANEOUS SIGNALS
Name
Pin #
Type
Description
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March 19, 2003 – Revision 1.04
PI7C8150
2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
MSK_IN
126
I
P_VIO
124
I
S_VIO
135
I
BPCCE
44
I
CFG66
125
I
SCAN_EN_H
125
I
MS0, MS1
155, 106
I
Secondary Clock Disable Serial Input: This pin is used
by PI7C8150 to disable secondary clock outputs. The
serial stream is received by MSK_IN, starting when
P_RESET is detected deasserted and S_RESET_L is
detected as being asserted. The serial data is used for
selectively disabling secondary clock outputs and is
shifted into the secondary clock control configuration
register. This pin can be tied LOW to enable all
secondary clock outputs or tied HIGH to drive all the
secondary clock outputs HIGH.
Primary I/O Voltage: This pin is used to determine
either 3.3V or 5V signaling on the primary bus. P_VIO
must be tied to 3.3V only when all devices on the
primary bus use 3.3V signaling. Otherwise, P_VIO is
tied to 5V.
Secondary I/O Voltage: This pin is used to determine
either 3.3V or 5V signaling on the secondary bus.
S_VIO must be tied to 3.3V only when all devices on the
secondary bus use 3.3V signaling. Otherwise, S_VIO is
tied to 5V.
Bus/Power Clock Control Management Pin: When
this pin is tied HIGH and the PI7C8150 is placed in the
D3HOT power state, it enables the PI7C8150 to place the
secondary bus in the B2 power state. The secondary
clocks are disabled and driven to 0. When this pin is tied
LOW, there is no effect on the secondary bus clocks
when the PI7C8150 enters the D3HOT power state.
66MHz Configuration: This pin is used to designate
66MHz operation. Tie HIGH to enable 66MHz operation
or tie LOW to designate 33MHz operation.
Full-Scan Enable Control: When SCAN_EN_H is
LOW, full-scan is in shift operation. When
SCAN_EN_H is HIGH, full-scan is in parallel operation.
Note: Valid only in test mode. Pin is CFG66 in normal
operation.
Mode Selection: Reserved for future features.
MS0: 0, MS1: 0 – RESERVED
MS0: 0, MS1: 1 – RESERVED
MS0: 1, MS1: x – Intel compatible (default)
2.2.5
GENERAL PURPOSE I/O INTERFACE SIGNALS
Name
GPIO[3:0]
2.2.6
Pin #
24, 25, 27, 28
Type
TS
Description
General Purpose I/O Data Pins: The 4 general-purpose
signals are programmable as either input-only or bidirectional signals by writing the GPIO output enable
control register in the configuration space.
JTAG BOUNDARY SCAN SIGNALS
Name
TCK
Pin #
133
Type
I
TMS
132
I
TDO
130
O
Description
Test Clock. Used to clock state information and data
into and out of the PI7C8150 during boundary scan.
Test Mode Select. Used to control the state of the Test
Access Port controller.
Test Data Output. When SCAN_EN_H is HIGH, it is
used (in conjunction with TCK) to shift data out of the
Test Access Port (TAP) in a serial bit stream.
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March 19, 2003 – Revision 1.04
PI7C8150
2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
2.2.7
TDI
129
I
TRST_L
134
I
POWER AND GROUND
Name
VDD
VSS
2.3
Test Data Input. When SCAN_EN_H is HIGH, it is
used (in conjunction with TCK) to shift data and
instructions into the Test Access Port (TAP) in a serial
bit stream.
Test Reset. Active LOW signal to reset the Test Access
Port (TAP) controller into an initialized state.
Pin #
1, 26, 34, 40, 51,
53, 56, 62, 69, 75,
81, 91, 97, 103,
105, 108, 114,
120, 131, 139,
145, 151, 155,
157, 163, 170,
178, 184, 190,
196, 202, 208
12, 20, 31, 37, 48,
52, 54, 59, 66, 72,
78, 86, 94, 100,
104, 106, 111,
117, 123, 136,
142, 148, 156,
158, 160, 166,
174, 181, 187,
193, 199, 205
Type
P
P
Description
Power: +3.3V Digital power.
Ground: Digital ground.
PIN LIST – 208-PIN FQFP
Table 3-1. Pin list – 208-pin FQFP
Pin Number
1
3
5
7
9
11
13
15
17
19
21
23
25
27
29
31
33
35
37
39
41
43
45
47
49
51
53
Name
VDD
S_REQ_L[2]
S_REQ_L[4]
S_REQ_L[6]
S_REQ_L[8]
S_GNT_L[1]
S_GNT_L[2]
S_GNT_L[4]
S_GNT_L[6]
S_GNT_L[8]
S_CLKIN
S_CFN_L
GPIO[2]
GPIO[1]
S_CLKOUT[0]
VSS
S_CLKOUT[3]
S_CLKOUT[4]
VSS
S_CLKOUT[7]
S_CLKOUT[8]
P_RESET_L
P_CLK
P_REQ_L
P_AD[31]
VDD
VDD
Type
P
I
I
I
I
TS
TS
TS
TS
TS
I
I
TS
TS
O
P
O
O
P
O
O
I
I
TS
TS
P
P
Pin Number
2
4
6
8
10
12
14
16
18
20
22
24
26
28
30
32
34
36
38
40
42
44
46
48
50
52
54
Name
S_REQ_L[1]
S_REQ_L[3]
S_REQ_L[5]
S_REQ_L[7]
S_GNT_L[0]
VSS
S_GNT_L[3]
S_GNT_L[5]
S_GNT_L[7]
VSS
S_RESET_L
GPIO[3]
VDD
GPIO[0]
S_CLKOUT[1]
S_CLKOUT[2]
VDD
S_CLKOUT[5]
S_CLKOUT[6]
VDD
S_CLKOUT[9]
BPCCE
P_GNT_L
VSS
P_AD[30]
VSS
VSS
Type
I
I
I
I
TS
P
TS
TS
TS
P
O
TS
P
TS
O
O
P
O
O
P
O
I
I
P
TS
P
P
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March 19, 2003 – Revision 1.04
PI7C8150
2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
Pin Number
55
57
59
61
63
65
67
69
71
73
75
77
79
81
83
85
87
89
91
93
95
97
99
101
103
105
107
109
111
113
115
117
119
121
123
125
127
129
131
133
135
137
139
141
143
145
147
149
151
153
155
157
159
161
163
165
167
169
171
173
175
177
179
Name
P_AD[29]
P_AD[28]
VSS
P_AD[25]
P_AD[24]
P_IDSEL
P_AD[23]
VDD
P_AD[20]
P_AD[19]
VDD
P_AD[16]
P_CBE[2]
VDD
P_TRDY_L
P_STOP_L
P_LOCK_L
P_SERR_L
VDD
P_AD[15]
P_AD[14]
VDD
P_AD[11]
P_AD[10]
VDD
VDD
P_AD[9]
P_AD[8]
VSS
P_AD[6]
P_AD[5]
VSS
P_AD[2]
P_AD[1]
VSS
CFG66 / SCAN_EN_H
RESERVED
TDI
VDD
TCK
S_VIO
S_AD[0]
VDD
S_AD[3]
S_ADD[4]
VDD
S_AD[7]
S_CBE[0]
VDD
S_M66EN
MS0
VDD
S_AD[11]
S_AD[12]
VDD
S_AD[15]
S_CBE[1]
S_SERR_L
S_PERR_L
S_STOP_L
S_DEVSEL_L
S_IRDY_L
S_FRAME_L
Type
TS
TS
P
TS
TS
I
TS
P
TS
TS
P
TS
TS
P
STS
STS
STS
STS
P
TS
TS
P
TS
TS
P
P
TS
TS
P
TS
TS
P
TS
TS
P
I
I
P
I
I
TS
P
TS
TS
P
TS
TS
P
I/OD
I
P
TS
TS
P
TS
TS
I
STS
STS
STS
STS
STS
Pin Number
56
58
60
62
64
66
68
70
72
74
76
78
80
82
84
86
88
90
92
94
96
98
100
102
104
106
108
110
112
114
116
118
120
122
124
126
128
130
132
134
136
138
140
142
144
146
148
150
152
154
156
158
160
162
164
166
168
170
172
174
176
178
180
Name
VDD
P_AD[27]
P_AD[26]
VDD
P_CBE[3]
VSS
P_AD[22]
P_AD[21]
VSS
P_AD[18]
P_AD[17]
VSS
P_FRAME_L
P_IRDY_L
P_DEVSEL_L
VSS
P_PERR_L
P_PAR
P_CBE[1]
VSS
P_AD[13]
P_AD[12]
VSS
P_M66EN
VSS
MS1
VDD
P_CBE[0]
P_AD[7]
VDD
P_AD[4]
P_AD[3]
VDD
P_AD[0]
P_VIO
MSK_IN
RESERVED
TDO
TMS
TRST_L
VSS
S_AD[1]
S_AD[2]
VSS
S_AD[5]
S_AD[6]
VSS
S_AD[8]
S_AD[9]
S_AD[10]
VSS
VSS
VSS
S_AD[13]
S_AD[14]
VSS
S_PAR
VDD
S_LOCK_L
VSS
S_TRDY_L
VDD
S_CBE[2]
Type
P
TS
TS
P
TS
P
TS
TS
P
TS
TS
P
STS
STS
STS
P
STS
STS
TS
P
TS
TS
P
I
P
I
P
TS
TS
P
TS
TS
P
TS
I
I
O
I
I
P
TS
TS
P
TS
TS
P
TS
TS
TS
P
P
P
TS
TS
P
TS
P
STS
P
STS
P
TS
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March 19, 2003 – Revision 1.04
PI7C8150
2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
Pin Number
181
183
185
187
189
191
193
195
197
199
201
203
205
207
2.4
Name
VSS
S_AD[17]
S_AD[18]
VSS
S_AD[21]
S_AD[22]
VSS
S_AD[24]
S_AD[25]
VSS
S_AD[28]
S_AD[29]
VSS
S_REQ_L[0]
Type
P
TS
TS
P
TS
TS
P
TS
TS
P
TS
TS
P
I
Pin Number
182
184
186
188
190
192
194
196
198
200
202
204
206
208
Name
S_AD[16]
VDD
S_AD[19]
S_AD[20]
VDD
S_AD[23]
S_CBE[3]
VDD
S_AD[26]
S_AD[27]
VDD
S_AD[30]
S_AD[31]
VDD
Type
TS
P
TS
TS
P
TS
TS
P
TS
TS
P
TS
TS
P
PIN LIST – 256-BALL PBGA
Table 3-2. Pin list – 256-ball PBGA
Pin
Number
A1
A4
A7
A10
A13
A16
B3
B6
B9
B12
B15
C2
C5
C8
C11
C14
D1
D4
D7
D10
D13
D16
E3
E6
E9
E12
E15
F2
F5
F8
F11
F14
G1
G4
G7
G10
G13
G16
H3
H6
Name
VSS
S_AD[31]
S_AD[22]
S_FRAME_L
S_PAR
VSS
S_REQ_L[1]
S_CBE_L[3]
S_CBE_L[2]
S_CBE_L[1]
VSS
S_REQ_L[4]
S_AD[29]
S_AD[20]
S_LOCK_L
VSS
S_GNT_L[0]
VSS
VDD
VDD
VSS
S_AD[6]
S_REQ_L[7]
VDD
VDD
VSS
S_CBE_L[0]
S_GNT_L[6]
VDD
VSS
VSS
S_AD[3]
S_GNT_L[8]
VDD
VSS
VSS
VDD
S_AD[0]
S_CLKIN
VSS
Type
P
TS
TS
STS
TS
P
I
TS
TS
TS
P
I
TS
TS
STS
P
TS
P
P
P
P
TS
I
P
P
P
TS
TS
P
P
P
TS
TS
P
P
P
P
TS
I
P
Pin
Number
A2
A5
A8
A11
A14
B1
B4
B7
B10
B13
B16
C3
C6
C9
C12
C15
D2
D5
D8
D11
D14
E1
E4
E7
E10
E13
E16
F3
F6
F9
F12
F15
G2
G5
G8
G11
G14
H1
H4
H7
Name
Type
S_REQ_L[2]
S_AD[28]
S_AD[19]
S_DEVSEL_L
S_AD[13]
VSS
S_REQ_L[0]
S_AD[21]
S_IRDY_L
S_AD[12]
S_AD[10]
VSS
S_AD[24]
S_AD[16]
S_AD[15]
VDD
S_REQ_L[6]
S_AD[30]
VDD
S_SERR_L
VSS
S_GNT_L[3]
S_REQ_L[8]
VDD
VDD
S_AD[9]
S_AD[4]
S_GNT_L[1]
VSS
VSS
VDD
S_AD[2]
VSS
VDD
VSS
VSS
S_VIO
S_RESET_L
VDD
VSS
I
TS
TS
STS
TS
P
I
TS
STS
TS
TS
P
TS
TS
TS
P
I
TS
P
I
P
TS
I
P
P
TS
TS
TS
P
P
P
TS
P
P
P
P
I
O
P
P
Pin
Number
A3
A6
A9
A12
A15
B2
B5
B8
B11
B14
C1
C4
C7
C10
C13
C16
D3
D6
D9
D12
D15
E2
E5
E8
E11
E14
F1
F4
F7
F10
F13
F16
G3
G6
G9
G12
G15
H2
H5
H8
Name
VDD
S_AD[25]
S_AD[17]
S_PERR_L
S_AD[11]
VSS
S_AD[27]
S_AD[18]
S_STOP_L
MS0
S_REQ_L[5]
VDD
S_AD[23]
S_TRDY_L
VSS
S_AD[8]
S_REQ_L[3]
S_AD[26]
VDD
S_AD[14]
S_M66EN
S_GNT_L[2]
VSS
VDD
VDD
S_AD[7]
S_GNT_L[7]
S_GNT_L[4]
VSS
VSS
S_AD[5]
S_AD[1]
S_GNT_L[5]
VSS
VSS
VDD
TRST_L
S_CFN_L
VDD
VSS
Type
P
TS
TS
STS
TS
P
TS
TS
STS
P
I
P
TS
STS
P
TS
I
TS
P
TS
I/OD
TS
P
P
P
TS
TS
TS
P
P
TS
TS
TS
P
P
P
I
I
P
P
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Pin
Number
H9
H12
H15
J2
J5
J8
J11
J14
K1
K4
K7
K10
K13
K16
L3
L6
L9
L10
L13
L16
M3
M6
M9
M12
M15
N2
N5
N8
N11
N14
P1
P4
P7
P10
P13
P16
R3
R6
R9
R12
R15
T2
T5
T8
T11
T14
3
Name
VSS
VDD
TCK
GPIO[2]
VDD
VSS
VSS
RESERVED
GPIO[0]
VDD
VSS
VSS
VDD
CFG66/SCAN_EN_H
S_CLKOUT[5]
VSS
VSS
VSS
P_AD[4]
P_AD[0]
S_CLKOUT[9]
VDD
VDD
VSS
P_AD[5]
BPCCE
P_AD[28]
VDD
P_PAR
VSS
P_RESET_L
VSS
P_AD[22]
P_DEVSEL_L
VDD
P_AD[9]
VDD
P_CBE_L[3]
P_CBE_L[2]
P_AD[15]
VSS
P_AD[30]
P_AD[26]
P_AD[19]
P_STOP_L
P_AD[13]
Type
P
P
I
TS
P
P
P
TS
P
P
P
P
I
O
P
P
P
TS
TS
O
P
P
P
TS
I
TS
P
TS
P
I
P
TS
STS
P
TS
P
TS
TS
TS
P
TS
TS
TS
STS
TS
Pin
Number
H10
H13
H16
J3
J6
J9
J12
J15
K2
K5
K8
K11
K14
L1
L4
L7
Name
Type
VSS
VDD
TDO
GPIO[3]
VSS
VSS
VDD
TDI
S_CLKOUT[0]
VDD
VSS
VSS
P_VIO
S_CLKOUT[2]
S_CLKOUT[6]
VSS
L11
L14
M1
M4
M7
M10
M13
M16
N3
N6
N9
N12
N15
P2
P5
P8
P11
P14
R1
R4
R7
R10
R13
R16
T3
T6
T9
T12
T15
VSS
P_AD[2]
S_CLKOUT[4]
P_CLK
VDD
VDD
P_AD[6]
P_AD[3]
P_AD[31]
P_AD[25]
VDD
P_AD[11]
P_AD[8]
P_REQ_L
P_AD[27]
P_AD[18]
P_SERR_L
VSS
P_GNT_L
VSS
P_AD[20]
P_TRDY_L
P_AD[12]
MS1
VDD
P_AD[23]
P_AD[16]
P_PERR_L
P_AD[10]
Name
Type
P
P
O
TS
P
P
P
I
O
P
P
P
I
O
O
P
Pin
Number
H11
H14
J1
J4
J7
J10
J13
J16
K3
K6
K9
K12
K15
L2
L5
L8
VSS
TMS
GPIO[1]
VDD
VSS
VSS
VDD
RESERVED
S_CLKOUT[1]
VSS
VSS
VDD
MSK_IN
S_CLKOUT[3]
VDD
VSS
P
I
TS
P
P
P
P
O
P
P
P
I
O
P
P
P
TS
O
I
P
P
TS
TS
TS
TS
P
TS
TS
TS
TS
TS
OD
P
I
P
TS
STS
TS
P
P
TS
TS
STS
TS
L12
L15
M2
M5
M8
M11
M14
N1
N4
N7
N10
N13
N16
P3
P6
P9
P12
P15
R2
R5
R8
R11
R14
T1
T4
T7
T10
T13
T16
VDD
P_AD[1]
S_CLKOUT[8]
VSS
VDD
VDD
P_AD[7]
S_CLKOUT[7]
VSS
VDD
VDD
VSS
P_CBE_L[0]
VSS
P_IDSEL
P_FRAME_L
P_AD[14]
VDD
VSS
P_AD[24]
P_AD[17]
P_LOCK_L
P_M66EN
VSS
P_AD[29]
P_AD[21]
P_IRDY_L
P_CBE_L[1]
VSS
P
TS
O
P
P
P
TS
O
P
P
P
P
TS
P
I
STS
TS
P
P
TS
TS
STS
I
P
TS
TS
STS
TS
P
PCI BUS OPERATION
This Chapter offers information about PCI transactions, transaction forwarding across
PI7C8150, and transaction termination. The PI7C8150 has two 128-byte buffers for
buffering of upstream and downstream transactions. These hold addresses, data,
commands, and byte enables and are used for both read and write transactions.
3.1
TYPES OF TRANSACTIONS
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This section provides a summary of PCI transactions performed by PI7C8150.
Table 4–1 lists the command code and name of each PCI transaction. The Master and
Target columns indicate support for each transaction when PI7C8150 initiates transactions
as a master, on the primary (P) and secondary (S) buses, and when PI7C8150 responds to
transactions as a target, on the primary (P) and secondary (S) buses.
Table 4-1. PCI Transactions
Types of Transactions
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
1011
1100
1101
1110
1111
Interrupt Acknowledge
Special Cycle
I/O Read
I/O Write
Reserved
Reserved
Memory Read
Memory Write
Reserved
Reserved
Configuration Read
Configuration Write
Memory Read Multiple
Dual Address Cycle
Memory Read Line
Memory Write and Invalidate
Initiates as Master
Primary
N
Y
Y
Y
N
N
Y
Y
N
N
N
Y (Type 1 only)
Y
Y
Y
Y
Secondary
N
Y
Y
Y
N
N
Y
Y
N
N
Y
Y
Y
Y
Y
Y
Responds as Target
Primary
Secondary
N
N
N
N
Y
Y
Y
Y
N
N
N
N
Y
Y
Y
Y
N
N
N
N
Y
N
Y
Y (Type 1 only)
Y
Y
Y
Y
Y
Y
Y
Y
As indicated in Table 4–1, the following PCI commands are not supported by PI7C8150:
3.2
!
PI7C8150 never initiates a PCI transaction with a reserved command code and, as a
target, PI7C8150 ignores reserved command codes.
!
PI7C8150 does not generate interrupt acknowledge transactions. PI7C8150 ignores
interrupt acknowledge transactions as a target.
!
PI7C8150 does not respond to special cycle transactions. PI7C8150 cannot guarantee
delivery of a special cycle transaction to downstream buses because of the broadcast
nature of the special cycle command and the inability to control the transaction as a
target. To generate special cycle transactions on other PCI buses, either upstream or
downstream, Type 1 configuration write must be used.
!
PI7C8150 neither generates Type 0 configuration transactions on the primary PCI
bus nor responds to Type 0 configuration transactions on the secondary PCI buses.
SINGLE ADDRESS PHASE
A 32-bit address uses a single address phase. This address is driven on P_AD[31:0], and
the bus command is driven on P_CBE[3:0]. PI7C8150 supports the linear increment
address mode only, which is indicated when the lowest two address bits are equal to zero.
If either of the lowest two address bits is nonzero, PI7C8150 automatically disconnects the
transaction after the first data transfer.
3.3
DEVICE SELECT (DEVSEL_L) GENERATION
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PI7C8150 always performs positive address decoding (medium decode) when accepting
transactions on either the primary or secondary buses. PI7C8150 never does subtractive
decode.
3.4
DATA PHASE
The address phase of a PCI transaction is followed by one or more data phases.
A data phase is completed when IRDY_L and either TRDY_L or STOP_L are asserted.
A transfer of data occurs only when both IRDY_L and TRDY_L are asserted during the
same PCI clock cycle. The last data phase of a transaction is indicated when FRAME_L is
de-asserted and both TRDY_L and IRDY_L are asserted, or when IRDY_L and STOP_L
are asserted. See Section 4.8 for further discussion of transaction termination.
Depending on the command type, PI7C8150 can support multiple data phase
PCI transactions. For detailed descriptions of how PI7C8150 imposes disconnect
boundaries, see Section 3.5.4 for write address boundaries and Section 3.6.3 read address
boundaries.
3.5
WRITE TRANSACTIONS
Write transactions are treated as either posted write or delayed write transactions.
Table 4–2 shows the method of forwarding used for each type of write operation.
Table 4-2. Write Transaction Forwarding
Type of Transaction
Memory Write
Memory Write and Invalidate
Memory Write to VGA memory
I/O Write
Type 1 Configuration Write
3.5.1
Type of Forwarding
Posted (except VGA memory)
Posted
Delayed
Delayed
Delayed
MEMORY WRITE TRANSACTIONS
Posted write forwarding is used for “Memory Write” and “Memory Write and Invalidate”
transactions.
When PI7C8150 determines that a memory write transaction is to be forwarded across the
bridge, PI7C8150 asserts DEVSEL_L with medium timing and TRDY_L
in the next cycle, provided that enough buffer space is available in the posted memory
write queue for the address and at least one DWORD of data. Under
this condition, PI7C8150 accepts write data without obtaining access to the target bus. The
PI7C8150 can accept one DWORD of write data every PCI clock cycle.
That is, no target wait state is inserted. The write data is stored in an internal
posted write buffers and is subsequently delivered to the target.
The PI7C8150 continues to accept write data until one of the following events occurs:
!
The initiator terminates the transaction by de-asserting FRAME# and IRDY#.
!
An internal write address boundary is reached, such as a cache line boundary or an
aligned 4KB boundary, depending on the transaction type.
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!
The posted write data buffer fills up.
When one of the last two events occurs, the PI7C8150 returns a target disconnect to the
requesting initiator on this data phase to terminate the transaction.
Once the posted write data moves to the head of the posted data queue, PI7C8150 asserts
its request on the target bus. This can occur while PI7C8150 is still receiving data on the
initiator bus. When the grant for the target bus is received and the target bus is detected in
the idle condition, PI7C8150 asserts FRAME_L and drives the stored write address out on
the target bus. On the following cycle, PI7C8150 drives the first DWORD of write data and
continues to transfer write data until all write data corresponding to that transaction is
delivered, or until a target termination is received.
As long as write data exists in the queue, PI7C8150 can drive one DWORD of write data
each PCI clock cycle; that is, no master wait states are inserted. If write data is flowing
through PI7C8150 and the initiator stalls, PI7C8150 will signal the last data phase for the
current transaction at the target bus if the queue empties. PI7C8150 will restart the followon transactions if the queue has new data.
PI7C8150 ends the transaction on the target bus when one of the following conditions is
met:
!
All posted write data has been delivered to the target.
!
The target returns a target disconnect or target retry (PI7C8150 starts another
transaction to deliver the rest of the write data).
!
The target returns a target abort (PI7C8150 discards remaining write data).
!
The master latency timer expires, and PI7C8150 no longer has the target bus grant
(PI7C8150 starts another transaction to deliver remaining write data).
Section 3.8.3.2 provides detailed information about how PI7C8150 responds to target
termination during posted write transactions.
3.5.2
MEMORY WRITE AND INVALIDATE
Posted write forwarding is used for Memory Write and Invalidate transactions.
The PI7C8150 disconnects Memory Write and Invalidate commands at aligned cache line
boundaries. The cache line size value in the cache line size register gives the number of
DWORD in a cache line.
If the value in the cache line size register does meet the memory write and invalidate
conditions, the PI7C8150 returns a target disconnect to the initiator on a cache line
boundary.
3.5.3
DELAYED WRITE TRANSACTIONS
Delayed write forwarding is used for I/O write transactions and Type 1 configuration write
transactions.
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A delayed write transaction guarantees that the actual target response is returned back to
the initiator without holding the initiating bus in wait states.
A delayed write transaction is limited to a single DWORD data transfer.
When a write transaction is first detected on the initiator bus, and PI7C8150 forwards it as
a delayed transaction, PI7C8150 claims the access by asserting DEVSEL_L and returns a
target retry to the initiator. During the address phase, PI7C8150 samples the bus command,
address, and address parity one cycle later. After IRDY_L is asserted, PI7C8150 also
samples the first data DWORD, byte enable bits, and data parity. This information is
placed into the delayed transaction queue. The transaction is queued only if no other
existing delayed transactions have the same address and command, and if the delayed
transaction queue is not full. When the delayed write transaction moves to the head of the
delayed transaction queue and all ordering constraints with posted data are satisfied. The
PI7C8150 initiates the transaction on the target bus. PI7C8150 transfers the write data to
the target. If PI7C8150 receives a target retry in response to the write transaction on the
target bus, it continues to repeat the write transaction until the data transfer is completed, or
until an error condition is encountered.
If PI7C8150 is unable to deliver write data after 224 (default) or 232 (maximum) attempts,
PI7C8150 will report a system error. PI7C8150 also asserts P_SERR_L if the primary
SERR_L enable bit is set in the command register. See Section 6.4 for information on the
assertion of P_SERR_L. When the initiator repeats the same write transaction (same
command, address, byte enable bits, and data), and the completed delayed transaction is at
the head of the queue, the PI7C8150 claims the access by asserting DEVSEL_L and returns
TRDY_L to the initiator, to indicate that the write data was transferred. If the initiator
requests multiple DWORD, PI7C8150 also asserts STOP_L in conjunction with TRDY_L
to signal a target disconnect. Note that only those bytes of write data with valid byte enable
bits are compared. If any of the byte enable bits are turned off (driven HIGH), the
corresponding byte of write data is not compared.
If the initiator repeats the write transaction before the data has been transferred to the
target, PI7C8150 returns a target retry to the initiator. PI7C8150 continues to return a target
retry to the initiator until write data is delivered to the target, or until an error condition is
encountered. When the write transaction is repeated, PI7C8150 does not make a new entry
into the delayed transaction queue. Section 3.8.3.1 provides detailed information about how
PI7C8150 responds to target termination during delayed write transactions.
PI7C8150 implements a discard timer that starts counting when the delayed write
completion is at the head of the delayed transaction completion queue.
The initial value of this timer can be set to the retry counter register offset 78h.
If the initiator does not repeat the delayed write transaction before the discard
timer expires, PI7C8150 discards the delayed write completion from the delayed
transaction completion queue. PI7C8150 also conditionally asserts P_SERR_L
(see Section 6.4).
3.5.4
WRITE TRANSACTION ADDRESS BOUNDARIES
PI7C8150 imposes internal address boundaries when accepting write data.
The aligned address boundaries are used to prevent PI7C8150 from continuing
a transaction over a device address boundary and to provide an upper limit on maximum
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latency. PI7C78150 returns a target disconnect to the initiator when it reaches the aligned
address boundaries under conditions shown in Table 4–3.
Table 4-3. Write Transaction Disconnect Address Boundaries
Type of Transaction
Delayed Write
Posted Memory Write
Posted Memory Write
Posted Memory Write and
Invalidate
Posted Memory Write and
Invalidate
Condition
All
Memory write disconnect control
bit = 0(1)
Memory write disconnect control
bit = 1(1)
Cache line size ≠ 1, 2, 4, 8, 16
Aligned Address Boundary
Disconnects after one data transfer
4KB aligned address boundary
Disconnects at cache line boundary
4KB aligned address boundary
Cache line boundary if posted memory
write data FIFO does not have enough
space for the cache line
Note 1. Memory write disconnect control bit is bit 1 of the chip control register at offset 40h in the
configuration space.
3.5.5
Cache line size = 1, 2, 4, 8, 16
BUFFERING MULTIPLE WRITE TRANSACTIONS
PI7C8150 continues to accept posted memory write transactions as long as space for at
least one DWORD of data in the posted write data buffer remains. If the posted write data
buffer fills before the initiator terminates the write transaction, PI7C8150 returns a target
disconnect to the initiator.
Delayed write transactions are posted as long as at least one open entry in
the delayed transaction queue exists. Therefore, several posted and delayed write
transactions can exist in data buffers at the same time. See Chapter 6 for information about
how multiple posted and delayed write transactions are ordered.
3.5.6
FAST BACK-TO-BACK TRANSACTIONS
PI7C8150 can recognize and post fast back-to-back write transactions.
When PI7C8150 cannot accept the second transaction because of buffer
space limitations, it returns a target retry to the initiator. The fast back-to-back enable bit
must be set in the command register for upstream write transactions, and in the bridge
control register for downstream write transactions.
3.6
READ TRANSACTIONS
Delayed read forwarding is used for all read transactions crossing PI7C8150.
Delayed read transactions are treated as either prefetchable or non-prefetchable. Table 4-5
shows the read behavior, prefetchable or non-prefetchable, for each
type of read operation.
3.6.1
PREFETCHABLE READ TRANSACTIONS
A prefetchable read transaction is a read transaction where PI7C8150 performs speculative
DWORD reads, transferring data from the target before it is requested from the initiator.
This behavior allows a prefetchable read transaction to consist of multiple data transfers.
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However, byte enable bits cannot be forwarded for all data phases as is done for the single
data phase of the non-prefetchable read transaction. For prefetchable read transactions,
PI7C8150 forces all byte enable bits to be turned on for all data phases.
Prefetchable behavior is used for memory read line and memory read multiple transactions,
as well as for memory read transactions that fall into prefetchable memory space.
The amount of data that is pre-fetched depends on the type of transaction.
The amount of pre-fetching may also be affected by the amount of free buffer
space available in PI7C8150, and by any read address boundaries encountered.
Pre-fetching should not be used for those read transactions that have side effects in the
target device, that is, control and status registers, FIFO’s, and so on.
The target device’s base address register or registers indicate if a memory address region is
prefetchable.
3.6.2
NON-PREFETCHABLE READ TRANSACTIONS
A non-prefetchable read transaction is a read transaction where PI7C8150 requests one and
only one DWORD from the target and disconnects the initiator after delivery of the first
DWORD of read data. Unlike prefetchable read transactions, PI7C8150 forwards the read
byte enable information for the data phase.
Non-prefetchable behavior is used for I/O and configuration read transactions,
as well as for memory read transactions that fall into non-prefetchable memory space.
If extra read transactions could have side effects, for example, when accessing a FIFO, use
non-prefetchable read transactions to those locations. Accordingly, if it is important to
retain the value of the byte enable bits during the data phase, use non-prefetchable read
transactions. If these locations are mapped in memory space, use the memory read
command and map the target into non-prefetchable (memory-mapped I/O) memory space
to use non-prefetching behavior.
3.6.3
READ PREFETCH ADDRESS BOUNDARIES
PI7C8150 imposes internal read address boundaries on read pre-fetched data. When a read
transaction reaches one of these aligned address boundaries, the PI7C8150 stops prefetched data, unless the target signals a target disconnect before the read pre-fetched
boundary is reached. When PI7C8150 finishes transferring this read data to the initiator, it
returns a target disconnect with the last data transfer, unless the initiator completes the
transaction before all pre-fetched read data is delivered. Any leftover pre-fetched data is
discarded.
Prefetchable read transactions in flow-through mode pre-fetch to the nearest aligned 4KB
address boundary, or until the initiator de-asserts FRAME_L. Section 3.6.6 describes flowthrough mode during read operations.
Table 4-4 shows the read pre-fetch address boundaries for read transactions during nonflow-through mode.
Table 4-4. Read Prefetch Address Boundaries
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Type of Transaction
Address Space
Configuration Read
I/O Read
Memory Read
Memory Read
Non-Prefetchable
Prefetchable
Cache Line
(CLS)
*
*
*
CLS = 0 or 16
Size
Memory Read
Memory Read Line
Prefetchable
-
CLS = 1, 2, 4, 8, 16
CLS = 0 or 16
Memory Read Line
Memory Read Multiple
-
CLS = 1, 2, 4, 8, 16
CLS = 0 or 16
Memory Read Multiple
CLS = 1, 2, 4, 8, 16
- does not matter if it is prefetchable or non-prefetchable
* don’t care
Prefetch Aligned Address
Boundary
One DWORD (no prefetch)
One DWORD (no prefetch)
One DWORD (no prefetch)
16-DWORD aligned address
boundary
Cache line address boundary
16-DWORD aligned address
boundary
Cache line boundary
32-DWORD aligned address
boundary
2X of cache line boundary
Table 4-5. Read Transaction Prefetching
Type of Transaction
I/O Read
Configuration Read
Read Behavior
Prefetching never allowed
Prefetching never allowed
Downstream: Prefetching used if address is prefetchable space
Memory Read
Upstream: Prefetching used or programmable
Memory Read Line
Prefetching always used
Memory Read Multiple
Prefetching always used
See Section 4.3 for detailed information about prefetchable and non-prefetchable address spaces.
3.6.4
DELAYED READ REQUESTS
PI7C8150 treats all read transactions as delayed read transactions, which means
that the read request from the initiator is posted into a delayed transaction queue.
Read data from the target is placed in the read data queue directed toward the initiator bus
interface and is transferred to the initiator when the initiator repeats
the read transaction.
When PI7C8150 accepts a delayed read request, it first samples the read address, read bus
command, and address parity. When IRDY_L is asserted, PI7C8150 then samples the byte
enable bits for the first data phase. This information is entered into the delayed transaction
queue. PI7C8150 terminates the transaction by signaling a target retry to the initiator. Upon
reception of the target retry, the initiator is required to continue to repeat the same read
transaction until at least one data transfer is completed, or until a target response (target
abort or master abort) other than a target retry is received.
3.6.5
DELAYED READ COMPLETION WITH TARGET
When delayed read request reaches the head of the delayed transaction queue, PI7C8150
arbitrates for the target bus and initiates the read transaction only if all previously queued
posted write transactions have been delivered. PI7C8150 uses the exact read address and
read command captured from the initiator during the initial delayed read request to initiate
the read transaction. If the read transaction is a non-prefetchable read, PI7C8150 drives the
captured byte enable bits during the next cycle. If the transaction is a prefetchable read
transaction, it drives all byte enable bits to zero for all data phases. If PI7C8150 receives a
target retry in response to the read transaction on the target bus, it continues to repeat the
read transaction until at least one data transfer is completed, or until an error condition is
encountered. If the transaction is terminated via normal master termination or target
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disconnect after at least one data transfer has been completed, PI7C8150 does not initiate
any further attempts to read more data.
If PI7C8150 is unable to obtain read data from the target after 224 (default) or 232
(maximum) attempts, PI7C8150 will report system error. The number of attempts is
programmable. PI7C8150 also asserts P_SERR_L if the primary SERR_L enable bit is set
in the command register. See Section 6.4 for information on the assertion of P_SERR_L.
Once PI7C8150 receives DEVSEL_L and TRDY_L from the target, it transfers the data
read to the opposite direction read data queue, pointing toward the opposite inter-face,
before terminating the transaction. For example, read data in response to a downstream
read transaction initiated on the primary bus is placed in the upstream read data queue. The
PI7C8150 can accept one DWORD of read data each PCI clock cycle; that is, no master
wait states are inserted. The number of DWORD’s transferred during a delayed read
transaction depends on the conditions given in Table 4-4 (assuming no disconnect is
received from the target).
3.6.6
DELAYED READ COMPLETION ON INITIATOR BUS
When the transaction has been completed on the target bus, and the delayed read data is at
the head of the read data queue, and all ordering constraints with posted write transactions
have been satisfied, the PI7C8150 transfers the data to the initiator when the initiator
repeats the transaction. For memory read transactions, PI7C8150 aliases the memory read,
memory read line, and memory read multiple bus commands when matching the bus
command of the transaction to the bus command in the delayed transaction queue.
PI7C8150 returns a target disconnect along with the transfer of the last DWORD of read
data to the initiator. If PI7C8150 initiator terminates the transaction before all read data has
been transferred, the remaining read data left in data buffers is discarded.
When the master repeats the transaction and starts transferring prefetchable read data from
data buffers while the read transaction on the target bus is still in progress and before a read
boundary is reached on the target bus, the read transaction starts operating in flow-through
mode. Because data is flowing through the data buffers from the target to the initiator, long
read bursts can then be sustained. In this case, the read transaction is allowed to continue
until the initiator terminates the transaction, or until an aligned 4KB address boundary is
reached, or until the buffer fills, whichever comes first. When the buffer empties,
PI7C8150 reflects the stalled condition to the initiator by disconnecting the initiator with
data. The initiator may retry the transaction later if data are needed. If the initiator does not
need any more data, the initiator will not continue the disconnected transaction. In this
case, PI7C8150 will start the master timeout timer. The remaining read data will be
discarded after the master timeout timer expires. To provide better latency, if there are any
other pending data for other transactions in the RDB (Read Data Buffer), the remaining
read data will be discarded even though the master timeout timer has not expired.
PI7C8150 implements a master timeout timer that starts counting when the delayed read
completion is at the head of the delayed transaction queue, and the read data is at the head
of the read data queue. The initial value of this timer is programmable through
configuration register. If the initiator does not repeat the read transaction and before the
master timeout timer expires (215 default), PI7C8150 discards the read transaction and read
data from its queues. PI7C8150 also conditionally asserts P_SERR_L (see Section 6.4).
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PI7C8150 has the capability to post multiple delayed read requests, up to a maximum of
four in each direction. If an initiator starts a read transaction that matches the address and
read command of a read transaction that is already queued, the current read command is not
posted as it is already contained in the delayed transaction queue.
See Section 5 for a discussion of how delayed read transactions are ordered when crossing
PI7C8150.
3.6.7
FAST BACK-TO-BACK READ TRANSACTION
PI7C8150 can recognize fast back-to-back read transaction
3.7
CONFIGURATION TRANSACTIONS
Configuration transactions are used to initialize a PCI system. Every PCI device
has a configuration space that is accessed by configuration commands. All registers are
accessible in configuration space only.
In addition to accepting configuration transactions for initialization of its own
configuration space, the PI7C8150 also forwards configuration transactions for device
initialization in hierarchical PCI systems, as well as for special cycle generation.
To support hierarchical PCI bus systems, two types of configuration transactions are
specified: Type 0 and Type 1.
Type 0 configuration transactions are issued when the intended target resides on the same
PCI bus as the initiator. A Type 0 configuration transaction is identified by the
configuration command and the lowest two bits of the address set to 00b.
Type 1 configuration transactions are issued when the intended target resides on another
PCI bus, or when a special cycle is to be generated on another PCI bus.
A Type 1 configuration command is identified by the configuration command and
the lowest two address bits set to 01b.
The register number is found in both Type 0 and Type 1 formats and gives the DWORD
address of the configuration register to be accessed. The function number is also included
in both Type 0 and Type 1 formats and indicates which function of a multifunction device
is to be accessed. For single-function devices, this value is not decoded. The addresses of
Type 1 configuration transaction include a 5-bit field designating the device number that
identifies the device on the target PCI bus that is to be accessed. In addition, the bus
number in Type 1 transactions specifies the PCI bus to which the transaction is targeted.
3.7.1
TYPE 0 ACCESS TO PI7C8150
The configuration space is accessed by a Type 0 configuration transaction on the primary
interface. The configuration space cannot be accessed from the secondary bus. The
PI7C8150 responds to a Type 0 configuration transaction by asserting P_DEVSEL_L when
the following conditions are met during the address phase:
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!
The bus command is a configuration read or configuration write transaction.
!
Lowest two address bits P_AD[1:0] must be 00b.
!
Signal P_IDSEL must be asserted.
PI7C8150 limits all configuration access to a single DWORD data transfer and returns
target-disconnect with the first data transfer if additional data phases are requested.
Because read transactions to configuration space do not have side effects, all bytes in the
requested DWORD are returned, regardless of the value of the byte enable bits.
Type 0 configuration write and read transactions do not use data buffers; that is, these
transactions are completed immediately, regardless of the state of the data buffers. The
PI7C8150 ignores all Type 0 transactions initiated on the secondary interface.
3.7.2
TYPE 1 TO TYPE 0 CONVERSION
Type 1 configuration transactions are used specifically for device configuration in a
hierarchical PCI bus system. A PCI-to-PCI bridge is the only type of device that should
respond to a Type 1 configuration command. Type 1 configuration commands are used
when the configuration access is intended for a PCI device that resides on a PCI bus other
than the one where the Type 1 transaction is generated.
PI7C8150 performs a Type 1 to Type 0 translation when the Type 1 transaction
is generated on the primary bus and is intended for a device attached directly to the
secondary bus. PI7C8150 must convert the configuration command to a Type 0 format so
that the secondary bus device can respond to it. Type 1 to Type 0 translations are
performed only in the downstream direction; that is, PI7C8150 generates a Type 0
transaction only on the secondary bus, and never on the primary bus.
PI7C8150 responds to a Type 1 configuration transaction and translates it into a Type 0
transaction on the secondary bus when the following conditions are met during the address
phase:
!
The lowest two address bits on P_AD[1:0] are 01b.
!
The bus number in address field P_AD[23:16] is equal to the value in the secondary
bus number register in configuration space.
!
The bus command on P_CBE[3:0] is a configuration read or configuration write
transaction.
When PI7C8150 translates the Type 1 transaction to a Type 0 transaction on
the secondary interface, it performs the following translations to the address:
!
Sets the lowest two address bits on S_AD[1:0].
!
Decodes the device number and drives the bit pattern specified in Table 4–6 on
S_AD[31:16] for the purpose of asserting the device’s IDSEL signal.
!
Sets S_AD[15:11] to 0.
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!
Leaves unchanged the function number and register number fields.
PI7C8150 asserts a unique address line based on the device number. These address lines
may be used as secondary bus IDSEL signals. The mapping of the address lines depends on
the device number in the Type 1 address bits P_AD[15:11]. Table 4–6 presents the
mapping that PI7C8150 uses.
Table 4-6. Device Number to IDSEL S_AD Pin Mapping
Device Number
0h
1h
2h
3h
4h
5h
6h
7h
8h
9h
Ah
Bh
Ch
Dh
Eh
Fh
10h – 1Eh
1Fh
P_AD[15:11]
00000
00001
00010
00011
00100
00101
00110
00111
01000
01001
01010
01011
01100
01101
01110
01111
10000 – 11110
11111
Secondary IDSEL S_AD[31:16]
0000 0000 0000 0001
0000 0000 0000 0010
0000 0000 0000 0100
0000 0000 0000 1000
0000 0000 0001 0000
0000 0000 0010 0000
0000 0000 0100 0000
0000 0000 1000 0000
0000 0001 0000 0000
0000 0010 0000 0000
0000 0100 0000 0000
0000 1000 0000 0000
0001 0000 0000 0000
0010 0000 0000 0000
0100 0000 0000 0000
1000 0000 0000 0000
0000 0000 0000 0000
Generate special cycle (P_AD[7:2] > 00h)
0000 0000 0000 0000 (P_AD[7:2] = 00h)
S_AD
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
-
PI7C8150 can assert up to 9 unique address lines to be used as IDSEL signals for
up to 9 devices on the secondary bus, for device numbers ranging from 0 through 8.
Because of electrical loading constraints of the PCI bus, more than 9 IDSEL signals should
not be necessary. However, if device numbers greater than 9 are desired, some external
method of generating IDSEL lines must be used, and no upper address bits are then
asserted. The configuration transaction is still translated and passed from the primary bus to
the secondary bus. If no IDSEL pin is asserted to a secondary device, the transaction ends
in a master abort.
PI7C8150 forwards Type 1 to Type 0 configuration read or write transactions as delayed
transactions. Type 1 to Type 0 configuration read or write transactions are limited to a
single 32-bit data transfer.
3.7.3
TYPE 1 TO TYPE 1 FORWARDING
Type 1 to Type 1 transaction forwarding provides a hierarchical configuration mechanism
when two or more levels of PCI-to-PCI bridges are used.
When PI7C8150 detects a Type 1 configuration transaction intended for a PCI bus
downstream from the secondary bus, PI7C8150 forwards the transaction unchanged to the
secondary bus. Ultimately, this transaction is translated to a Type 0 configuration command
or to a special cycle transaction by a downstream PCI-to-PCI bridge. Downstream Type 1
to Type 1 forwarding occurs when the following conditions are met during the address
phase:
!
The lowest two address bits are equal to 01b.
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!
The bus number falls in the range defined by the lower limit (exclusive)
in the secondary bus number register and the upper limit (inclusive) in
the subordinate bus number register.
!
The bus command is a configuration read or write transaction.
PI7C8150 also supports Type 1 to Type 1 forwarding of configuration write transactions
upstream to support upstream special cycle generation. A Type 1 configuration command
is forwarded upstream when the following conditions
are met:
!
The lowest two address bits are equal to 01b.
!
The bus number falls outside the range defined by the lower limit (inclusive)
in the secondary bus number register and the upper limit (inclusive) in the subordinate
bus number register.
!
The device number in address bits AD[15:11] is equal to 11111b.
!
The function number in address bits AD[10:8] is equal to 111b.
!
The bus command is a configuration write transaction.
The PI7C8150 forwards Type 1 to Type 1 configuration write transactions as delayed
transactions. Type 1 to Type 1 configuration write transactions are limited to a single data
transfer.
3.7.4
SPECIAL CYCLES
The Type 1 configuration mechanism is used to generate special cycle transactions in
hierarchical PCI systems. Special cycle transactions are ignored by acting as a target and
are not forwarded across the bridge. Special cycle transactions can be generated from Type
1 configuration write transactions in either the upstream or the down-stream direction.
PI7C8150 initiates a special cycle on the target bus when a Type 1 configuration write
transaction is being detected on the initiating bus and the following conditions are met
during the address phase:
!
The lowest two address bits on AD[1:0] are equal to 01b.
!
The device number in address bits AD[15:11] is equal to 11111b.
!
The function number in address bits AD[10:8] is equal to 111b.
!
The register number in address bits AD[7:2] is equal to 000000b.
!
The bus number is equal to the value in the secondary bus number register in
configuration space for downstream forwarding or equal to the value in the primary
bus number register in configuration space for upstream forwarding.
!
The bus command on CBE_L is a configuration write command.
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When PI7C8150 initiates the transaction on the target interface, the bus command is
changed from configuration write to special cycle. The address and data are for-warded
unchanged. Devices that use special cycles ignore the address and decode only the bus
command. The data phase contains the special cycle message. The transaction is
forwarded as a delayed transaction, but in this case the target response is not forwarded
back (because special cycles result in a master abort). Once the transaction is completed on
the target bus, through detection of the master abort condition, PI7C8150 responds with
TRDY_L to the next attempt of the con-figuration transaction from the initiator. If more
than one data transfer is requested, PI7C8150 responds with a target disconnect operation
during the first data phase.
3.8
TRANSACTION TERMINATION
This section describes how PI7C8150 returns transaction termination conditions back to the
initiator.
The initiator can terminate transactions with one of the following types of termination:
! Normal termination
Normal termination occurs when the initiator de-asserts FRAME# at the beginning of the
last data phase, and de-asserts IRDY# at the end of the last data phase in conjunction with
either TRDY_L or STOP_L assertion from the target.
! Master abort
A master abort occurs when no target response is detected. When the initiator does not
detect a DEVSEL_L from the target within five clock cycles after asserting FRAME_L, the
initiator terminates the transaction with a master abort. If FRAME_L is still asserted, the
initiator de-asserts FRAME_L on the next cycle, and then de-asserts IRDY_L on the
following cycle. IRDY_L must be asserted in the same cycle in which FRAME_L deasserts. If FRAME_L is already de-asserted, IRDY_L can be de-asserted on the next clock
cycle following detection of the master abort condition.
The target can terminate transactions with one of the following types of termination:
! Normal termination
TRDY_L and DEVSEL_L asserted in conjunction with FRAME_L de-asserted and
IRDY_L asserted.
! Target retry
STOP_L and DEVSEL_L asserted with TRDY_L de-asserted during the first data phase.
No data transfers occur during the transaction. This transaction must be repeated.
! Target disconnect with data transfer
STOP_L, DEVSEL_L and TRDY_L asserted. It signals that this is the last data transfer of
the transaction.
! Target disconnect without data transfer
STOP_L and DEVSEL_L asserted with TRDY_L de-asserted after previous data transfers
have been made. Indicates that no more data transfers will be made during this transaction.
!
Target abort
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STOP_L asserted with DEVSEL_L and TRDY_L de-asserted. Indicates that target will
never be able to complete this transaction. DEVSEL_L must be asserted for at least one
cycle during the transaction before the target abort is signaled.
3.8.1
MASTER TERMINATION INITIATED BY PI7C8150
PI7C8150, as an initiator, uses normal termination if DEVSEL_L is returned by target
within five clock cycles of PI7C8150’s assertion of FRAME_L on the target bus. As an
initiator, PI7C8150 terminates a transaction when the following conditions are met:
!
During a delayed write transaction, a single DWORD is delivered.
!
During a non-prefetchable read transaction, a single DWORD is transferred from the
target.
!
During a prefetchable read transaction, a pre-fetch boundary is reached.
!
For a posted write transaction, all write data for the transaction is transferred from data
buffers to the target.
!
For burst transfer, with the exception of “Memory Write and Invalidate” transactions,
the master latency timer expires and the PI7C8150’s bus grant is de-asserted.
!
The target terminates the transaction with a retry, disconnect, or target abort.
If PI7C8150 is delivering posted write data when it terminates the transaction because the
master latency timer expires, it initiates another transaction to deliver the remaining write
data. The address of the transaction is updated to reflect the address of the current DWORD
to be delivered.
If PI7C8150 is pre-fetching read data when it terminates the transaction because the master
latency timer expires, it does not repeat the transaction to obtain more data.
3.8.2
MASTER ABORT RECEIVED BY PI7C8150
If the initiator initiates a transaction on the target bus and does not detect DEVSEL_L
returned by the target within five clock cycles of the assertion of FRAME_L, PI7C8150
terminates the transaction with a master abort. This sets the received-master-abort bit in the
status register corresponding to the target bus.
For delayed read and write transactions, PI7C8150 is able to reflect the master abort
condition back to the initiator. When PI7C8150 detects a master abort in response to a
delayed transaction, and when the initiator repeats the transaction, PI7C8150 does not
respond to the transaction with DEVSEL_L, which induces the master abort condition back
to the initiator. The transaction is then removed from the delayed transaction queue. When
a master abort is received in response to a posted write transaction, PI7C8150 discards the
posted write data and makes no more attempt to deliver the data. PI7C8150 sets the
received-master-abort bit in the status register when the master abort is received on the
primary bus, or it sets the received master abort bit in the secondary status register when
the master abort is received on the secondary interface. When master abort is detected in
posted write transaction with both master-abort-mode bit (bit 5 of bridge control register)
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and the SERR_L enable bit (bit 8 of command register for secondary bus) are set,
PI7C8150 asserts P_SERR_L if the master-abort-on-posted-write is not set. The masterabort-on-posted-write bit is bit 4 of the P_SERR_L event disable register (offset 64h).
Note: When PI7C8150 performs a Type 1 to special cycle conversion, a master abort is the
expected termination for the special cycle on the target bus. In this case, the master abort
received bit is not set, and the Type 1 configuration transaction is disconnected after the
first data phase.
3.8.3
TARGET TERMINATION RECEIVED BY PI7C8150
When PI7C8150 initiates a transaction on the target bus and the target responds with
DEVSEL_L, the target can end the transaction with one of the following types
of termination:
!
Normal termination (upon de-assertion of FRAME_L)
!
Target retry
!
Target disconnect
!
Target abort
PI7C8150 handles these terminations in different ways, depending on the type of
transaction being performed.
3.8.3.1
DELAYED WRITE TARGET TERMINATION RESPONSE
When PI7C8150 initiates a delayed write transaction, the type of target termination
received from the target can be passed back to the initiator. Table 4–7 shows the response
to each type of target termination that occurs during a delayed write transaction.
PI7C8150 repeats a delayed write transaction until one of the following conditions is met:
!
PI7C8150 completes at least one data transfer.
!
PI7C8150 receives a master abort.
!
PI7C8150 receives a target abort.
PI7C8150 makes 224 (default) or 232 (maximum) write attempts resulting in a response of
target retry.
Table 4-7. Delayed Write Target Termination Response
Target Termination
Normal
Target Retry
Target Disconnect
Target Abort
Response
Returning disconnect to initiator with first data transfer only if multiple data
phases requested.
Returning target retry to initiator. Continue write attempts to target
Returning disconnect to initiator with first data transfer only if multiple data
phases requested.
Returning target abort to initiator. Set received target abort bit in target interface
status register. Set signaled target abort bit in initiator interface status register.
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After the PI7C8150 makes 224 (default) attempts of the same delayed write trans-action on
the target bus, PI7C8150 asserts P_SERR_L if the SERR_L enable bit (bit 8
of command register for the secondary bus) is set and the delayed-write-non-delivery bit is
not set. The delayed-write-non-delivery bit is bit 5 of P_SERR_L event disable register
(offset 64h). PI7C8150 will report system error. See Section 6.4 for a description of system
error conditions.
3.8.3.2
POSTED WRITE TARGET TERMINATION RESPONSE
When PI7C8150 initiates a posted write transaction, the target termination cannot
be passed back to the initiator. Table 4–8 shows the response to each type of target
termination that occurs during a posted write transaction.
Table 4-8. Response to Posted Write Target Termination
Target Termination
Normal
Target Retry
Target Disconnect
Target Abort
Repsonse
No additional action.
Repeating write transaction to target.
Initiate write transaction for delivering remaining posted write data.
Set received-target-abort bit in the target interface status register. Assert
P_SERR# if enabled, and set the signaled-system-error bit in primary status
register.
Note that when a target retry or target disconnect is returned and posted write data
associated with that transaction remains in the write buffers, PI7C8150 initiates another
write transaction to attempt to deliver the rest of the write data. If there is a target retry, the
exact same address will be driven as for the initial write trans-action attempt. If a target
disconnect is received, the address that is driven on a subsequent write transaction attempt
will be updated to reflect the address of the current DWORD. If the initial write transaction
is Memory-Write-and-Invalidate transaction, and a partial delivery of write data to the
target is performed before a target disconnect is received, PI7C8150 will use the memory
write command to deliver the rest of the write data. It is because an incomplete cache line
will be transferred in the subsequent write transaction attempt.
After the PI7C8150 makes 224 (default) write transaction attempts and fails to deliver all
posted write data associated with that transaction, PI7C8150 asserts P_SERR_L if the
primary SERR_L enable bit is set (bit 8 of command register for secondary bus) and
posted-write-non-delivery bit is not set. The posted-write-non-delivery bit is the bit 2 of
P_SERR_L event disable register (offset 64h). PI7C8150 will report system error. See
Section 6.4 for a discussion of system error conditions.
3.8.3.3
DELAYED READ TARGET TERMINATION RESPONSE
When PI7C8150 initiates a delayed read transaction, the abnormal target responses can be
passed back to the initiator. Other target responses depend on how much data the initiator
requests. Table 4–9 shows the response to each type of target termination that occurs
during a delayed read transaction.
PI7C8150 repeats a delayed read transaction until one of the following conditions is met:
!
PI7C8150 completes at least one data transfer.
!
PI7C8150 receives a master abort.
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!
PI7C8150 receives a target abort.
PI7C8150 makes 224 (default) read attempts resulting in a response of target retry.
Table 4-9. Response to Delayed Read Target Termination
Target Termination
Normal
Target Retry
Target Disconnect
Target Abort
Response
If prefetchable, target disconnect only if initiator requests more data than read
from target. If non-prefetchable, target disconnect on first data phase.
Re-initiate read transaction to target
If initiator requests more data than read from target, return target disconnect to
initiator.
Return target abort to initiator. Set received target abort bit in the target
interface status register. Set signaled target abort bit in the initiator interface
status register.
After PI7C8150 makes 224(default) attempts of the same delayed read transaction on the
target bus, PI7C8150 asserts P_SERR_L if the primary SERR_L enable bit is set (bit 8 of
command register for secondary bus) and the delayed-write-non-delivery bit is not set. The
delayed-write-non-delivery bit is bit 5 of P_SERR_L event disable register (offset 64h).
PI7C8150 will report system error. See Section 6.4 for a description of system error
conditions.
3.8.4
TARGET TERMINATION INITIATED BY PI7C8150
PI7C8150 can return a target retry, target disconnect, or target abort to an initiator for
reasons other than detection of that condition at the target interface.
3.8.4.1
TARGET RETRY
PI7C8150 returns a target retry to the initiator when it cannot accept write data or return
read data as a result of internal conditions. PI7C8150 returns a target retry to an initiator
when any of the following conditions is met:
For delayed write transactions:
!
The transaction is being entered into the delayed transaction queue.
!
Transaction has already been entered into delayed transaction queue, but target
response has not yet been received.
!
Target response has been received but has not progressed to the head of the return
queue.
!
The delayed transaction queue is full, and the transaction cannot be queued.
!
A transaction with the same address and command has been queued.
!
A locked sequence is being propagated across PI7C8150, and the write transaction is
not a locked transaction.
!
The target bus is locked and the write transaction is a locked transaction.
!
Use more than 16 clocks to accept this transaction.
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For delayed read transactions:
!
The transaction is being entered into the delayed transaction queue.
!
The read request has already been queued, but read data is not yet available.
!
Data has been read from target, but it is not yet at head of the read data queue or a
posted write transaction precedes it.
!
The delayed transaction queue is full, and the transaction cannot be queued.
!
A delayed read request with the same address and bus command has already been
queued.
!
A locked sequence is being propagated across PI7C8150, and the read transaction is
not a locked transaction.
!
PI7C78150 is currently discarding previously pre-fetched read data.
!
The target bus is locked and the write transaction is a locked transaction.
!
Use more than 16 clocks to accept this transaction.
For posted write transactions:
3.8.4.2
!
The posted write data buffer does not have enough space for address and at least one
DWORD of write data.
!
A locked sequence is being propagated across PI7C8150, and the write transaction is
not a locked transaction.
!
When a target retry is returned to the initiator of a delayed transaction, the initiator
must repeat the transaction with the same address and bus command as well as the data
if it is a write transaction, within the time frame specified by the master timeout value.
Otherwise, the transaction is discarded from the buffers.
TARGET DISCONNECT
PI7C8150 returns a target disconnect to an initiator when one of the following conditions is
met:
!
PI7C8150 hits an internal address boundary.
!
PI7C8150 cannot accept any more write data.
!
PI7C8150 has no more read data to deliver.
See Section 3.5.4 for a description of write address boundaries, and Section 3.6.3 for a
description of read address boundaries.
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3.8.4.3
TARGET ABORT
PI7C8150 returns a target abort to an initiator when one of the following conditions is met:
4
!
PI7C8150 is returning a target abort from the intended target.
!
When PI7C8150 returns a target abort to the initiator, it sets the signaled target abort
bit in the status register corresponding to the initiator interface.
ADDRESS DECODING
PI7C8150 uses three address ranges that control I/O and memory transaction forwarding.
These address ranges are defined by base and limit address registers in the configuration
space. This chapter describes these address ranges, as well as ISA-mode and VGAaddressing support.
4.1
ADDRESS RANGES
PI7C8150 uses the following address ranges that determine which I/O and memory
transactions are forwarded from the primary PCI bus to the secondary PCI bus, and from
the secondary bus to the primary bus:
!
Two 32-bit I/O address ranges
!
Two 32-bit memory-mapped I/O (non-prefetchable memory) ranges
!
Two 32-bit prefetchable memory address ranges
Transactions falling within these ranges are forwarded downstream from the primary PCI
bus to the secondary PCI bus. Transactions falling outside these ranges are forwarded
upstream from the secondary PCI bus to the primary PCI bus.
No address translation is required in PI7C8150. The addresses that are not marked for
downstream are always forwarded upstream.
4.2
I/O ADDRESS DECODING
PI7C8150 uses the following mechanisms that are defined in the configuration space to
specify the I/O address space for downstream and upstream forwarding:
!
I/O base and limit address registers
!
The ISA enable bit
!
The VGA mode bit
!
The VGA snoop bit
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This section provides information on the I/O address registers and ISA mode.
Section 5.4 provides information on the VGA modes.
To enable downstream forwarding of I/O transactions, the I/O enable bit must be set in the
command register in configuration space. All I/O transactions initiated on the primary bus
will be ignored if the I/O enable bit is not set. To enable upstream forwarding of I/O
transactions, the master enable bit must be set in the command register. If the masterenable bit is not set, PI7C8150 ignores all I/O and memory transactions initiated on the
secondary bus.
The master-enable bit also allows upstream forwarding of memory transactions
if it is set.
CAUTION
If any configuration state affecting I/O transaction forwarding is changed by a
configuration write operation on the primary bus at the same time that I/O transactions are
ongoing on the secondary bus, PI7C8150 response to the secondary bus I/O transactions is
not predictable. Configure the I/O base and limit address registers, ISA enable bit, VGA
mode bit, and VGA snoop bit before setting I/O enable and master enable bits, and change
them subsequently only when the primary and secondary PCI buses are idle.
4.2.1
I/O BASE AND LIMIT ADDRESS REGISTER
PI7C8150 implements one set of I/O base and limit address registers in configuration space
that define an I/O address range per port downstream forwarding. PI7C8150 supports 32bit I/O addressing, which allows I/O addresses downstream of PI7C8150 to be mapped
anywhere in a 4GB I/O address space.
I/O transactions with addresses that fall inside the range defined by the I/O base and limit
registers are forwarded downstream from the primary PCI bus to the secondary PCI bus.
I/O transactions with addresses that fall outside this range are forwarded upstream from the
secondary PCI bus to the primary PCI bus.
The I/O range can be turned off by setting the I/O base address to a value greater than that
of the I/O limit address. When the I/O range is turned off, all I/O trans-actions are
forwarded upstream, and no I/O transactions are forwarded downstream. The I/O range has
a minimum granularity of 4KB and is aligned on a 4KB boundary. The maximum I/O
range is 4GB in size. The I/O base register consists of an 8-bit field at configuration
address 1Ch, and a 16-bit field at address 30h. The top 4 bits of the 8-bit field define bits
[15:12] of the I/O base address. The bottom 4 bits read only as 1h to indicate that
PI7C8150 supports 32-bit I/O addressing. Bits [11:0] of the base address are assumed to be
0, which naturally aligns the base address to a 4KB boundary. The 16 bits contained in the
I/O base upper 16 bits register at configuration offset 30h define AD[31:16] of the I/O base
address. All 16 bits are read/write. After primary bus reset or chip reset, the value
of the I/O base address is initialized to 0000 0000h.
The I/O limit register consists of an 8-bit field at configuration offset 1Dh and a 16-bit field
at offset 32h. The top 4 bits of the 8-bit field define bits [15:12] of the I/O limit address.
The bottom 4 bits read only as 1h to indicate that 32-bit I/O addressing is supported. Bits
[11:0] of the limit address are assumed to be FFFh, which naturally aligns the limit address
to the top of a 4KB I/O address block. The 16 bits contained in the I/O limit upper 16 bits
register at configuration offset 32h define AD[31:16] of the I/O limit address. All 16 bits
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are read/write. After primary bus reset or chip reset, the value of the I/O limit address is
reset to 0000 0FFFh.
Note: The initial states of the I/O base and I/O limit address registers define
an I/O range of 0000 0000h to 0000 0FFFh, which is the bottom 4KB of I/O space. Write
these registers with their appropriate values before setting either the I/O enable bit or the
master enable bit in the command register in configuration space.
4.2.2
ISA MODE
PI7C8150 supports ISA mode by providing an ISA enable bit in the bridge control register
in configuration space. ISA mode modifies the response of PI7C8150 inside the I/O
address range in order to support mapping of I/O space in the presence of an ISA bus in the
system. This bit only affects the response of PI7C8150 when the transaction falls inside the
address range defined by the I/O base and limit address registers, and only when this
address also falls inside the first 64KB of I/O space (address bits [31:16] are 0000h).
When the ISA enable bit is set, PI7C8150 does not forward downstream any I/O
transactions addressing the top 768 bytes of each aligned 1KB block. Only those
transactions addressing the bottom 256 bytes of an aligned 1KB block inside the base and
limit I/O address range are forwarded downstream. Transactions above the 64KB I/O
address boundary are forwarded as defined by the address range defined by the I/O base
and limit registers.
Accordingly, if the ISA enable bit is set, PI7C8150 forwards upstream those I/O
transactions addressing the top 768 bytes of each aligned 1KB block within the first 64KB
of I/O space. The master enable bit in the command configuration register must also be set
to enable upstream forwarding. All other I/O transactions initiated on the secondary bus are
forwarded upstream only if they fall outside the I/O address range.
When the ISA enable bit is set, devices downstream of PI7C8150 can have I/O space
mapped into the first 256 bytes of each 1KB chunk below the 64KB boundary, or anywhere
in I/O space above the 64KB boundary.
4.3
MEMORY ADDRESS DECODING
PI7C8150 has three mechanisms for defining memory address ranges for forwarding of
memory transactions:
!
Memory-mapped I/O base and limit address registers
!
Prefetchable memory base and limit address registers
!
VGA mode
This section describes the first two mechanisms. Section 4.4.1 describes VGA mode. To
enable downstream forwarding of memory transactions, the memory enable bit must be set
in the command register in configuration space. To enable upstream forwarding of memory
transactions, the master-enable bit must be set in the command register. The master-enable
bit also allows upstream forwarding of I/O transactions if it is set.
CAUTION
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If any configuration state affecting memory transaction forwarding is changed by a
configuration write operation on the primary bus at the same time that memory
transactions are ongoing on the secondary bus, response to the secondary bus memory
transactions is not predictable. Configure the memory-mapped I/O base and limit address
registers, prefetchable memory base and limit address registers, and VGA mode bit before
setting the memory enable and master enable bits, and change them subsequently only
when the primary and secondary PCI buses are idle.
4.3.1
MEMORY-MAPPED I/O BASE AND LIMIT ADDRESS REGISTERS
Memory-mapped I/O is also referred to as non-prefetchable memory. Memory addresses
that cannot automatically be pre-fetched but that can be conditionally pre-fetched based on
command type should be mapped into this space. Read transactions to non-prefetchable
space may exhibit side effects; this space may have non-memory-like behavior. PI7C8150
prefetches in this space only if the memory read line or memory read multiple commands
are used; transactions using the memory read command are limited to a single data transfer.
The memory-mapped I/O base address and memory-mapped I/O limit address registers
define an address range that PI7C8150 uses to determine when to forward memory
commands. PI7C8150 forwards a memory transaction from the primary to the secondary
interface if the transaction address falls within the memory-mapped I/O address range.
PI7C8150 ignores memory transactions initiated on the secondary interface that fall into
this address range. Any transactions that fall outside this address range are ignored on the
primary interface and are forwarded upstream from the secondary interface (provided that
they do not fall into the prefetchable memory range or are not forwarded downstream by
the VGA mechanism).
The memory-mapped I/O range supports 32-bit addressing only. The PCI-to-PCI Bridge
Architecture Specification does not provide for 64-bit addressing in the memory-mapped
I/O space. The memory-mapped I/O address range has a granularity and alignment of
1MB. The maximum memory-mapped I/O address range is 4GB.
The memory-mapped I/O address range is defined by a 16-bit memory-mapped I/O base
address register at configuration offset 20h and by a 16-bit memory-mapped I/O limit
address register at offset 22h. The top 12 bits of each of these registers correspond to bits
[31:20] of the memory address. The low 4 bits are hardwired to 0. The lowest 20 bits of the
memory-mapped I/O base address are assumed to be 0 0000h, which results in a natural
alignment to a 1MB boundary. The lowest 20 bits of the memory-mapped I/O limit address
are assumed to be FFFFFh, which results in an alignment to the top of a 1MB block.
Note: The initial state of the memory-mapped I/O base address register is 0000 0000h. The
initial state of the memory-mapped I/O limit address register is 000F FFFFh. Note that the
initial states of these registers define a memory-mapped I/O range at the bottom 1MB block
of memory. Write these registers with their appropriate values before setting either the
memory enable bit or the master enable bit in the command register in configuration space.
To turn off the memory-mapped I/O address range, write the memory-mapped I/O base
address register with a value greater than that of the memory-mapped I/O limit address
register.
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4.3.2
PREFETCHABLE MEMORY BASE AND LIMIT ADDRESS
REGISTERS
Locations accessed in the prefetchable memory address range must have true memory-like
behavior and must not exhibit side effects when read. This means that extra reads to a
prefetchable memory location must have no side effects. PI7C8150 pre-fetches for all types
of memory read commands in this address space.
The prefetchable memory base address and prefetchable memory limit address registers
define an address range that PI7C8150 uses to determine when to forward memory
commands. PI7C8150 forwards a memory transaction from the primary to the secondary
interface if the transaction address falls within the prefetchable memory address range.
PI7C8150 ignores memory transactions initiated on the secondary interface that fall into
this address range. PI7C8150 does not respond to any transactions that fall outside this
address range on the primary interface and forwards those transactions upstream from the
secondary interface (provided that they do not fall into the memory-mapped I/O range or
are not forwarded by the VGA mechanism).
The prefetchable memory range supports 64-bit addressing and provides additional
registers to define the upper 32 bits of the memory address range, the prefetchable memory
base address upper 32 bits register, and the prefetchable memory limit address upper 32
bits register. For address comparison, a single address cycle (32-bit address) prefetchable
memory transaction is treated like a 64-bit address transaction where the upper 32 bits of
the address are equal to 0. This upper 32-bit value of 0 is compared to the prefetchable
memory base address upper 32 bits register and the prefetchable memory limit address
upper 32 bits register. The prefetchable memory base address upper 32 bits register must be
0 to pass any single address cycle transactions downstream.
Prefetchable memory address range has a granularity and alignment of 1MB. Maximum
memory address range is 4GB when 32-bit addressing is being used. Prefetchable memory
address range is defined by a 16-bit prefetchable memory base address register at
configuration offset 24h and by a 16-bit prefetchable memory limit address register at
offset 26h. The top 12 bits of each of these registers correspond to bits [31:20] of the
memory address. The lowest 4 bits are hardwired to 1h. The lowest 20 bits of the
prefetchable memory base address are assumed to be 0 0000h, which results in a natural
alignment to a 1MB boundary. The lowest 20 bits of the prefetchable memory limit address
are assumed to be FFFFFh, which results in an alignment to the top of a 1MB block.
Note: The initial state of the prefetchable memory base address register is 0000 0000h. The
initial state of the prefetchable memory limit address register is 000F FFFFh. Note that the
initial states of these registers define a prefetchable memory range at the bottom 1MB
block of memory. Write these registers with their appropriate values before setting either
the memory enable bit or the master enable bit in the command register in configuration
space.
To turn off the prefetchable memory address range, write the prefetchable memory base
address register with a value greater than that of the prefetchable memory limit address
register. The entire base value must be greater than the entire limit value, meaning that the
upper 32 bits must be considered. Therefore, to disable the address range, the upper 32 bits
registers can both be set to the same value, while the lower base register is set greater than
the lower limit register. Otherwise, the upper 32-bit base must be greater than the upper 32bit limit.
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4.4
VGA SUPPORT
PI7C8150 provides two modes for VGA support:
4.4.1
!
VGA mode, supporting VGA-compatible addressing
!
VGA snoop mode, supporting VGA palette forwarding
VGA MODE
When a VGA-compatible device exists downstream from PI7C8150, set the VGA mode bit
in the bridge control register in configuration space to enable VGA mode. When PI7C8150
is operating in VGA mode, it forwards downstream those transactions addressing the VGA
frame buffer memory and VGA I/O registers, regardless of the values of the base and limit
address registers. PI7C8150 ignores transactions initiated on the secondary interface
addressing these locations.
The VGA frame buffer consists of the following memory address range:
000A 0000h–000B FFFFh
Read transactions to frame buffer memory are treated as non-prefetchable. PI7C8150
requests only a single data transfer from the target, and read byte enable bits are forwarded
to the target bus.
The VGA I/O addresses are in the range of 3B0h–3BBh and 3C0h–3DFh I/O. These I/O
addresses are aliases every 1KB throughout the first 64KB of I/O space. This means that
address bits <15:10> are not decoded and can be any value, while address bits [31:16] must
be all 0’s. VGA BIOS addresses starting at C0000h are not decoded in VGA mode.
4.4.2
VGA SNOOP MODE
PI7C8150 provides VGA snoop mode, allowing for VGA palette write transactions to be
forwarded downstream. This mode is used when a graphics device downstream from
PI7C8150 needs to snoop or respond to VGA palette write transactions. To enable the
mode, set the VGA snoop bit in the command register in configuration space. Note that
PI7C8150 claims VGA palette write transactions by asserting DEVSEL_L in VGA snoop
mode.
When VGA snoop bit is set, PI7C8150 forwards downstream transactions within the 3C6h,
3C8h and 3C9h I/O addresses space. Note that these addresses are also forwarded as part of
the VGA compatibility mode previously described. Again, address bits <15:10> are not
decoded, while address bits <31:16> must be equal to 0, which means that these addresses
are aliases every 1KB throughout the first 64KB of I/O space.
Note: If both the VGA mode bit and the VGA snoop bit are set, PI7C8150 behaves in the
same way as if only the VGA mode bit were set.
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5
TRANSACTION ORDERING
To maintain data coherency and consistency, PI7C8150 complies with the ordering rules
set forth in the PCI Local Bus Specification, Revision 2.2, for transactions crossing the
bridge. This chapter describes the ordering rules that control transaction forwarding across
PI7C8150.
5.1
TRANSACTIONS GOVERNED BY ORDERING RULES
Ordering relationships are established for the following classes of transactions crossing
PI7C8150:
Posted write transactions, comprised of memory write and memory write and
invalidate transactions.
Posted write transactions complete at the source before they complete at the destination;
that is, data is written into intermediate data buffers before it reaches the target.
Delayed write request transactions, comprised of I/O write and configuration write
transactions.
Delayed write requests are terminated by target retry on the initiator bus and
are queued in the delayed transaction queue. A delayed write transaction must complete on
the target bus before it completes on the initiator bus.
Delayed write completion transactions, comprised of I/O write and configuration
write transactions.
Delayed write completion transactions complete on the target bus, and the target response
is queued in the buffers. A delayed write completion transaction proceeds
in the direction opposite that of the original delayed write request; that is, a delayed write
completion transaction proceeds from the target bus to the initiator bus.
Delayed read request transactions, comprised of all memory read, I/O read, and
configuration read transactions.
Delayed read requests are terminated by target retry on the initiator bus and are queued in
the delayed transaction queue.
Delayed read completion transactions, comprised of all memory read, I/O read, &
configuration read transactions.
Delayed read completion transactions complete on the target bus, and the read data is
queued in the read data buffers. A delayed read completion transaction proceeds in the
direction opposite that of the original delayed read request; that is, a delayed read
completion transaction proceeds from the target bus to the initiator bus.
PI7C8150 does not combine or merge write transactions:
!
PI7C8150 does not combine separate write transactions into a single write
transaction—this optimization is best implemented in the originating master.
!
PI7C8150 does not merge bytes on separate masked write transactions to the same
DWORD address—this optimization is also best implemented in the originating
master.
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!
5.2
PI7C8150 does not collapse sequential write transactions to the same address into a
single write transaction—the PCI Local Bus Specification does not permit this
combining of transactions.
GENERAL ORDERING GUIDELINES
Independent transactions on primary and secondary buses have a relationship only when
those transactions cross PI7C8150.
The following general ordering guidelines govern transactions crossing PI7C8150:
5.3
!
The ordering relationship of a transaction with respect to other transactions is
determined when the transaction completes, that is, when a transaction ends with a
termination other than target retry.
!
Requests terminated with target retry can be accepted and completed in any order with
respect to other transactions that have been terminated with target retry. If the order of
completion of delayed requests is important, the initiator should not start a second
delayed transaction until the first one has been completed. If more than one delayed
transaction is initiated, the initiator should repeat all delayed transaction requests,
using some fairness algorithm. Repeating a delayed transaction cannot be contingent
on completion of another delayed transaction. Otherwise, a deadlock can occur.
!
Write transactions flowing in one direction have no ordering requirements with respect
to write transactions flowing in the other direction. PI7C8150 can accept posted write
transactions on both interfaces at the same time, as well as initiate posted write
transactions on both interfaces at the same time.
!
The acceptance of a posted memory write transaction as a target can never be
contingent on the completion of a non-locked, non-posted transaction as a master. This
is true for PI7C81500 and must also be true for other bus agents. Otherwise, a
deadlock can occur.
!
PI7C8150 accepts posted write transactions, regardless of the state of completion of
any delayed transactions being forwarded across PI7C8150.
ORDERING RULES
Table 5–1 shows the ordering relationships of all the transactions and refers by number to
the ordering rules that follow.
Table 5-1. Summary of Transaction Ordering
Pass
Posted
Write
Delayed
Write
Request
Yes5
No
No
Yes
Delayed Read
Completion
Delayed Write
Completion
No1
No2
No4
No3
Delayed
Read
Request
Yes5
No
No
Yes
Posted Write
Delayed Read Request
Delayed Write Request
Delayed Read
Completion
Delayed Write
Completion
Yes5
Yes
Yes
No
Yes5
Yes
Yes
No
Yes
Yes
Yes
No
No
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Note: The superscript accompanying some of the table entries refers to any applicable
ordering rule listed in this section. Many entries are not governed by these ordering rules;
therefore, the implementation can choose whether or not the transactions pass each other.
The entries without superscripts reflect the PI7C8150’s implementation choices.
The following ordering rules describe the transaction relationships. Each ordering rule is
followed by an explanation, and the ordering rules are referred to by number in Table 6–1.
These ordering rules apply to posted write transactions, delayed write and read requests,
and delayed write and read completion transactions crossing PI7C8150 in the same
direction. Note that delayed completion transactions cross PI7C8150 in the direction
opposite that of the corresponding delayed requests.
1. Posted write transactions must complete on the target bus in the order in which they
were received on the initiator bus. The subsequent posted write transaction can be setting a
flag that covers the data in the first posted write transaction; if the second transaction were
to complete before the first transaction, a device checking the flag could subsequently
consume stale data.
2. A delayed read request traveling in the same direction as a previously queued posted
write transaction must push the posted write data ahead of it. The posted write transaction
must complete on the target bus before the delayed read request can be attempted on the
target bus. The read transaction can be to the same location as the write data, so if the read
transaction were to pass the write transaction, it would return stale data.
3. A delayed read completion must ‘‘pull’’ ahead of previously queued posted write data
traveling in the same direction. In this case, the read data is traveling in the same direction
as the write data, and the initiator of the read transaction is on the same side of PI7C8150
as the target of the write transaction. The posted write transaction must complete to the
target before the read data is returned
to the initiator. The read transaction can be a reading to a status register of the initiator of
the posted write data and therefore should not complete until the write transaction is
complete.
4. Delayed write requests cannot pass previously queued posted write data. For posted
memory write transactions, the delayed write transaction can set a flag that covers the data
in the posted write transaction. If the delayed write request were to complete before the
earlier posted write transaction, a device checking the flag could subsequently consume
stale data.
5. Posted write transactions must be given opportunities to pass delayed read and write
requests and completions. Otherwise, deadlocks may occur when some bridges which
support delayed transactions and other bridges which do not support delayed transactions
are being used in the same system. A fairness algorithm is used to arbitrate between the
posted write queue and the delayed transaction queue.
5.4
DATA SYNCHRONIZATION
Data synchronization refers to the relationship between interrupt signaling and data
delivery. The PCI Local Bus Specification, Revision 2.2, provides the following alternative
methods for synchronizing data and interrupts:
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!
The device signaling the interrupt performs a read of the data just written (software).
!
The device driver performs a read operation to any register in the interrupting device
before accessing data written by the device (software).
!
System hardware guarantees that write buffers are flushed before interrupts are
forwarded.
PI7C8150 does not have a hardware mechanism to guarantee data synchronization for
posted write transactions. Therefore, all posted write transactions must be followed by a
read operation, either from the device to the location just written (or some other location
along the same path), or from the device driver to one of the device registers.
6
ERROR HANDLING
PI7C8150 checks, forwards, and generates parity on both the primary and secondary
interfaces. To maintain transparency, PI7C8150 always tries to forward the existing parity
condition on one bus to the other bus, along with address and data. PI7C8150 always
attempts to be transparent when reporting errors, but this is not always possible, given the
presence of posted data and delayed transactions.
To support error reporting on the PCI bus, PI7C8150 implements the following:
!
PERR_L and SERR_L signals on both the primary and secondary interfaces
!
Primary status and secondary status registers
!
The device-specific P_SERR_L event disable register
This chapter provides detailed information about how PI7C8150 handles errors.
It also describes error status reporting and error operation disabling.
6.1
ADDRESS PARITY ERRORS
PI7C8150 checks address parity for all transactions on both buses, for all address and all
bus commands. When PI7C8150 detects an address parity error on the primary interface,
the following events occur:
!
If the parity error response bit is set in the command register, PI7C8150 does not claim
the transaction with P_DEVSEL_L; this may allow the transaction to terminate in a
master abort. If parity error response bit is not set, PI7C8150 proceeds normally and
accepts the transaction if it is directed to or across PI7C8150.
!
PI7C8150 sets the detected parity error bit in the status register.
!
PI7C8150 asserts P_SERR_L and sets signaled system error bit in the status register, if
both the following conditions are met:
!
The SERR_L enable bit is set in the command register.
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!
The parity error response bit is set in the command register.
When PI7C8150 detects an address parity error on the secondary interface, the following
events occur:
6.2
!
If the parity error response bit is set in the bridge control register, PI7C8150 does not
claim the transaction with S_DEVSEL_L; this may allow the transaction to terminate
in a master abort. If parity error response bit is not set, PI7C8150 proceeds normally
and accepts transaction if it is directed to or across PI7C8150.
!
PI7C8150 sets the detected parity error bit in the secondary status register.
!
PI7C8150 asserts P_SERR_L and sets signaled system error bit in status register, if
both of the following conditions are met:
!
The SERR_L enable bit is set in the command register.
!
The parity error response bit is set in the bridge control register.
DATA PARITY ERRORS
When forwarding transactions, PI7C8150 attempts to pass the data parity condition from
one interface to the other unchanged, whenever possible, to allow the master and target
devices to handle the error condition.
The following sections describe, for each type of transaction, the sequence of events that
occurs when a parity error is detected and the way in which the parity condition is
forwarded across PI7C8150.
6.2.1
CONFIGURATION WRITE TRANSACTIONS TO
CONFIGURATION SPACE
When PI7C8150 detects a data parity error during a Type 0 configuration write transaction
to PI7C8150 configuration space, the following events occur:
If the parity error response bit is set in the command register, PI7C8150 asserts
P_TRDY_L and writes the data to the configuration register. PI7C8150 also asserts
P_PERR_L. If the parity error response bit is not set, PI7C8150 does not assert
P_PERR_L.
PI7C8150 sets the detected parity error bit in the status register, regardless of the state of
the parity error response bit.
6.2.2
READ TRANSACTIONS
When PI7C8150 detects a parity error during a read transaction, the target drives data and
data parity, and the initiator checks parity and conditionally asserts PERR_L.
For downstream transactions, when PI7C8150 detects a read data parity error on the
secondary bus, the following events occur:
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!
PI7C8150 asserts S_PERR_L two cycles following the data transfer, if the secondary
interface parity error response bit is set in the bridge control register.
!
PI7C8150 sets the detected parity error bit in the secondary status register.
!
PI7C8150 sets the data parity detected bit in the secondary status register, if the
secondary interface parity error response bit is set in the bridge control register.
!
PI7C8150 forwards the bad parity with the data back to the initiator on the primary
bus. If the data with the bad parity is pre-fetched and is not read by the initiator on the
primary bus, the data is discarded and the data with bad parity is not returned to the
initiator.
!
PI7C8150 completes the transaction normally.
For upstream transactions, when PI7C8150 detects a read data parity error on the primary
bus, the following events occur:
!
PI7C8150 asserts P_PERR_L two cycles following the data transfer, if the primary
interface parity error response bit is set in the command register.
!
PI7C8150 sets the detected parity error bit in the primary status register.
!
PI7C8150 sets the data parity detected bit in the primary status register, if the primary
interface parity-error-response bit is set in the command register.
!
PI7C8150 forwards the bad parity with the data back to the initiator on the secondary
bus. If the data with the bad parity is pre-fetched and is not read by the initiator on the
secondary bus, the data is discarded and the data with bad parity is not returned to the
initiator.
!
PI7C8150 completes the transaction normally.
PI7C8150 returns to the initiator the data and parity that was received from the target.
When the initiator detects a parity error on this read data and is enabled to report it, the
initiator asserts PERR_L two cycles after the data transfer occurs. It is assumed that the
initiator takes responsibility for handling a parity error condition; therefore, when
PI7C8150 detects PERR_L asserted while returning read data to the initiator, PI7C8150
does not take any further action and completes the transaction normally.
6.2.3
DELAYED WRITE TRANSACTIONS
When PI7C8150 detects a data parity error during a delayed write transaction, the initiator
drives data and data parity, and the target checks parity and conditionally asserts PERR_L.
For delayed write transactions, a parity error can occur at the following times:
!
During the original delayed write request transaction
!
When the initiator repeats the delayed write request transaction
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!
When PI7C8150 completes the delayed write transaction to the target
When a delayed write transaction is normally queued, the address, command, address
parity, data, byte enable bits, and data parity are all captured and a target retry is returned to
the initiator. When PI7C8150 detects a parity error on the write data for the initial delayed
write request transaction, the following events occur:
!
If the parity-error-response bit corresponding to the initiator bus is set, PI7C8150
asserts TRDY_L to the initiator and the transaction is not queued. If multiple data
phases are requested, STOP_L is also asserted to cause a target disconnect. Two cycles
after the data transfer, PI7C8150 also asserts PERR_L.
!
If the parity-error-response bit is not set, PI7C8150 returns a target retry.
It queues the transaction as usual. PI7C8150 does not assert PERR_L.
In this case, the initiator repeats the transaction.
!
PI7C8150 sets the detected-parity-error bit in the status register corresponding to the
initiator bus, regardless of the state of the parity-error-response bit.
Note: If parity checking is turned off and data parity errors have occurred for queued or
subsequent delayed write transactions on the initiator bus, it is possible that the initiator’s
re-attempts of the write transaction may not match the original queued delayed write
information contained in the delayed transaction queue. In this case, a master timeout
condition may occur, possibly resulting in a system error (P_SERR_L assertion).
For downstream transactions, when PI7C8150 is delivering data to the target on the
secondary bus and S_PERR_L is asserted by the target, the following events occur:
!
PI7C8150 sets the secondary interface data parity detected bit in the secondary status
register, if the secondary parity error response bit is set in the bridge control register.
!
PI7C8150 captures the parity error condition to forward it back to the initiator on the
primary bus.
Similarly, for upstream transactions, when PI7C8150 is delivering data to the target on the
primary bus and P_PERR_L is asserted by the target, the following events occur:
!
PI7C8150 sets the primary interface data-parity-detected bit in the status register, if the
primary parity-error-response bit is set in the command register.
!
PI7C8150 captures the parity error condition to forward it back to the initiator on the
secondary bus.
A delayed write transaction is completed on the initiator bus when the initiator repeats the
write transaction with the same address, command, data, and byte enable bits as the
delayed write command that is at the head of the posted data queue. Note that the parity bit
is not compared when determining whether the transaction matches those in the delayed
transaction queues.
Two cases must be considered:
!
When parity error is detected on the initiator bus on a subsequent re-attempt of the
transaction and was not detected on the target bus
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!
When parity error is forwarded back from the target bus
For downstream delayed write transactions, when the parity error is detected on the
initiator bus and PI7C8150 has write status to return, the following events occur:
!
PI7C8150 first asserts P_TRDY_L and then asserts P_PERR_L two cycles later, if the
primary interface parity-error-response bit is set in the command register.
!
PI7C8150 sets the primary interface parity-error-detected bit in the status register.
!
Because there was not an exact data and parity match, the write status is not returned
and the transaction remains in the queue.
Similarly, for upstream delayed write transactions, when the parity error is detected on the
initiator bus and PI7C8150 has write status to return, the following events occur:
!
PI7C8150 first asserts S_TRDY_L and then asserts S_PERR_L two cycles later, if the
secondary interface parity-error-response bit is set in the bridge control register (offset
3Ch).
!
PI7C8150 sets the secondary interface parity-error-detected bit in the secondary status
register.
!
Because there was not an exact data and parity match, the write status is not returned
and the transaction remains in the queue.
For downstream transactions, where the parity error is being passed back from the target
bus and the parity error condition was not originally detected on the initiator bus, the
following events occur:
!
!
PI7C8150 asserts P_PERR_L two cycles after the data transfer, if the following are
both true:
!
The parity-error-response bit is set in the command register of the primary
interface.
!
The parity-error-response bit is set in the bridge control register of the
secondary interface.
PI7C8150 completes the transaction normally.
For upstream transactions, when the parity error is being passed back from the target bus
and the parity error condition was not originally detected on the initiator bus, the following
events occur:
!
PI7C8150 asserts S_PERR_L two cycles after the data transfer, if the following are
both true:
!
The parity error response bit is set in the command register of the primary
interface.
!
The parity error response bit is set in the bridge control register of the
secondary interface.
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!
6.2.4
PI7C8150 completes the transaction normally.
POSTED WRITE TRANSACTIONS
During downstream posted write transactions, when PI7C8150 responds as a target, it
detects a data parity error on the initiator (primary) bus and the following events occur:
!
PI7C8150 asserts P_PERR_L two cycles after the data transfer, if the parity error
response bit is set in the command register of primary interface.
!
PI7C8150 sets the parity error detected bit in the status register of the primary
interface.
!
PI7C8150 captures and forwards the bad parity condition to the secondary bus.
!
PI7C8150 completes the transaction normally.
Similarly, during upstream posted write transactions, when PI7C8150 responds as a target,
it detects a data parity error on the initiator (secondary) bus, the following events occur:
!
PI7C8150 asserts S_PERR_L two cycles after the data transfer, if the parity error
response bit is set in the bridge control register of the secondary interface.
!
PI7C8150 sets the parity error detected bit in the status register of the secondary
interface.
!
PI7C8150 captures and forwards the bad parity condition to the primary bus.
!
PI7C8150 completes the transaction normally.
During downstream write transactions, when a data parity error is reported on the target
(secondary) bus by the target’s assertion of S_PERR_L, the following events occur:
!
PI7C8150 sets the data parity detected bit in the status register of secondary interface,
if the parity error response bit is set in the bridge control register of the secondary
interface.
!
PI7C8150 asserts P_SERR_L and sets the signaled system error bit in the status
register, if all the following conditions are met:
!
The SERR_L enable bit is set in the command register.
!
The posted write parity error bit of P_SERR_L event disable register is not
set.
!
The parity error response bit is set in the bridge control register of the
secondary interface.
!
The parity error response bit is set in the command register of the primary
interface.
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!
PI7C8150 has not detected the parity error on the primary (initiator) bus
which the parity error is not forwarded from the primary bus to the
secondary bus.
During upstream write transactions, when a data parity error is reported on the target
(primary) bus by the target’s assertion of P_PERR_L, the following events occur:
!
PI7C8150 sets the data parity detected bit in the status register, if the parity error
response bit is set in the command register of the primary interface.
!
PI7C8150 asserts P_SERR_L and sets the signaled system error bit in the status
register, if all the following conditions are met:
!
The SERR_L enable bit is set in the command register.
!
The parity error response bit is set in the bridge control register of the
secondary interface.
!
The parity error response bit is set in the command register of the primary
interface.
!
PI7C8150 has not detected the parity error on the secondary (initiator) bus,
which the parity error is not forwarded from the secondary bus to the
primary bus.
Assertion of P_SERR_L is used to signal the parity error condition when the initiator does
not know that the error occurred. Because the data has already been delivered with no
errors, there is no other way to signal this information back to the initiator.
If the parity error has forwarded from the initiating bus to the target bus, P_SERR_L will
not be asserted.
6.3
DATA PARITY ERROR REPORTING SUMMARY
In the previous sections, the responses of PI7C8150 to data parity errors are presented
according to the type of transaction in progress. This section organizes the responses of
PI7C8150 to data parity errors according to the status bits that PI7C8150 sets and the
signals that it asserts.
Table 6–1 shows setting the detected parity error bit in the status register, corresponding to
the primary interface. This bit is set when PI7C8150 detects a parity error on the primary
interface.
Table 6-1. Setting the Primary Interface Detected Parity Error Bit
Primary Detected
Parity Error Bit
Transaction Type
Direction
Bus Where Error
Was Detected
0
0
1
0
1
0
0
Read
Read
Read
Read
Posted Write
Posted Write
Posted Write
Downstream
Downstream
Upstream
Upstream
Downstream
Downstream
Upstream
Primary
Secondary
Primary
Secondary
Primary
Secondary
Primary
Primary/
Secondary Parity
Error Response
Bits
x/x
x/x
x/x
x/x
x/x
x/x
x/x
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0
1
0
0
0
X = don’t care
Posted Write
Delayed Write
Delayed Write
Delayed Write
Delayed Write
Upstream
Downstream
Downstream
Upstream
Upstream
Secondary
Primary
Secondary
Primary
Secondary
x/x
x/x
x/x
x/x
x/x
Table 6–2 shows setting the detected parity error bit in the secondary status register,
corresponding to the secondary interface. This bit is set when PI7C8150 detects a parity
error on the secondary interface.
Table 6-2. Setting Secondary Interface Detected Parity Error Bit
Secondary
Detected Parity
Error Bit
Transaction Type
Direction
Bus Where Error
Was Detected
0
1
0
0
0
0
0
1
0
0
0
1
X = don’t care
Read
Read
Read
Read
Posted Write
Posted Write
Posted Write
Posted Write
Delayed Write
Delayed Write
Delayed Write
Delayed Write
Downstream
Downstream
Upstream
Upstream
Downstream
Downstream
Upstream
Upstream
Downstream
Downstream
Upstream
Upstream
Primary
Secondary
Primary
Secondary
Primary
Secondary
Primary
Secondary
Primary
Secondary
Primary
Secondary
Primary/
Secondary Parity
Error Response
Bits
x/x
x/x
x/x
x/x
x/x
x/x
x/x
x/x
x/x
x/x
x/x
x/x
Table 6–3 shows setting data parity detected bit in the primary interface’s status register.
This bit is set under the following conditions:
!
PI7C8150 must be a master on the primary bus.
!
The parity error response bit in the command register, corresponding to the primary
interface, must be set.
!
The P_PERR_L signal is detected asserted or a parity error is detected on the primary
bus.
Table 6-3. Setting Primary Interface Master Data Parity Error Detected Bit
Primary
Parity Bit
Data
0
0
1
0
0
0
1
0
0
0
1
0
X = don’t care
Transaction Type
Direction
Bus Where Error
Was Detected
Read
Read
Read
Read
Posted Write
Posted Write
Posted Write
Posted Write
Delayed Write
Delayed Write
Delayed Write
Delayed Write
Downstream
Downstream
Upstream
Upstream
Downstream
Downstream
Upstream
Upstream
Downstream
Downstream
Upstream
Upstream
Primary
Secondary
Primary
Secondary
Primary
Secondary
Primary
Secondary
Primary
Secondary
Primary
Secondary
Primary /
Secondary Parity
Error Response
Bits
x/x
x/x
1/x
x/x
x/x
x/x
1/x
x/x
x/x
x/x
1/x
x/x
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Table 6–4 shows setting the data parity detected bit in the status register of secondary
interface. This bit is set under the following conditions:
!
The PI7C8150 must be a master on the secondary bus.
!
The parity error response bit must be set in the bridge control register of secondary
interface.
!
The S_PERR_L signal is detected asserted or a parity error is detected on the
secondary bus.
Table 6-4. Setting Secondary Interface Master Data Parity Error Detected Bit
Secondary
Detected Parity
Detected Bit
Transaction Type
Direction
Bus Where Error
Was Detected
0
1
0
0
0
1
0
0
0
1
0
0
X= don’t care
Read
Read
Read
Read
Posted Write
Posted Write
Posted Write
Posted Write
Delayed Write
Delayed Write
Delayed Write
Delayed Write
Downstream
Downstream
Upstream
Upstream
Downstream
Downstream
Upstream
Upstream
Downstream
Downstream
Upstream
Upstream
Primary
Secondary
Primary
Secondary
Primary
Secondary
Primary
Secondary
Primary
Secondary
Primary
Secondary
Primary /
Secondary Parity
Error Response
Bits
x/x
x/1
x/x
x/x
x/x
x/1
x/x
x/x
x/x
x/1
x/x
x/x
Table 6–5 shows assertion of P_PERR_L. This signal is set under the following conditions:
!
PI7C8150 is either the target of a write transaction or the initiator of a read transaction
on the primary bus.
!
The parity-error-response bit must be set in the command register of primary interface.
!
PI7C8150 detects a data parity error on the primary bus or detects S_PERR_L asserted
during the completion phase of a downstream delayed write transaction on the target
(secondary) bus.
Table 6-5. Assertion of P_PERR#
P_PERR#
Transaction Type
Direction
Bus Where Error
Was Detected
Primary/
Secondary Parity
Error Response
Bits
x/x
x/x
1/x
x/x
1/x
x/x
x/x
x/x
1/x
1/1
x/x
x/x
1 (de-asserted)
Read
Downstream
Primary
1
Read
Downstream
Secondary
0 (asserted)
Read
Upstream
Primary
1
Read
Upstream
Secondary
0
Posted Write
Downstream
Primary
1
Posted Write
Downstream
Secondary
1
Posted Write
Upstream
Primary
1
Posted Write
Upstream
Secondary
0
Delayed Write
Downstream
Primary
02
Delayed Write
Downstream
Secondary
1
Delayed Write
Upstream
Primary
1
Delayed Write
Upstream
Secondary
X = don’t care
2
The parity error was detected on the target (secondary) bus but not on the initiator (primary) bus.
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Table 6–6 shows assertion of S_PERR_L that is set under the following conditions:
!
PI7C8150 is either the target of a write transaction or the initiator of a read transaction
on the secondary bus.
!
The parity error response bit must be set in the bridge control register of secondary
interface.
!
PI7C8150 detects a data parity error on the secondary bus or detects P_PERR_L
asserted during the completion phase of an upstream delayed write transaction on the
target (primary) bus.
Table 6-6. Assertion of S_PERR#
S_PERR#
Transaction Type
Direction
Bus Where Error
Was Detected
Primary/
Secondary Parity
Error Response
Bits
x/x
x/1
x/x
x/x
x/x
x/x
x/x
x/1
x/x
x/x
1/1
x/1
1 (de-asserted)
Read
Downstream
Primary
0 (asserted)
Read
Downstream
Secondary
1
Read
Upstream
Primary
1
Read
Upstream
Secondary
1
Posted Write
Downstream
Primary
1
Posted Write
Downstream
Secondary
1
Posted Write
Upstream
Primary
0
Posted Write
Upstream
Secondary
1
Delayed Write
Downstream
Primary
1
Delayed Write
Downstream
Secondary
02
Delayed Write
Upstream
Primary
0
Delayed Write
Upstream
Secondary
X = don’t care
2
The parity error was detected on the target (secondary) bus but not on the initiator (primary) bus.
Table 6–7 shows assertion of P_SERR_L. This signal is set under the following
conditions:
!
PI7C8150 has detected P_PERR_L asserted on an upstream posted write transaction
or S_PERR_L asserted on a downstream posted write transaction.
!
PI7C8150 did not detect the parity error as a target of the posted write transaction.
!
The parity error response bit on the command register and the parity error response bit
on the bridge control register must both be set.
!
The SERR_L enable bit must be set in the command register.
Table 6-7. Assertion of P_SERR# for Data Parity Errors
P_SERR#
Transaction Type
Direction
Bus Where Error
Was Detected
1 (de-asserted)
1
1
1
1
02 (asserted)
03
1
Read
Read
Read
Read
Posted Write
Posted Write
Posted Write
Posted Write
Downstream
Downstream
Upstream
Upstream
Downstream
Downstream
Upstream
Upstream
Primary
Secondary
Primary
Secondary
Primary
Secondary
Primary
Secondary
Primary /
Secondary Parity
Error Response
Bits
x/x
x/x
x/x
x/x
x/x
1/1
1/1
x/x
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P_SERR#
Transaction Type
Direction
Bus Where Error
Was Detected
Primary /
Secondary Parity
Error Response
Bits
x/x
x/x
x/x
x/x
1
Delayed Write
Downstream
Primary
1
Delayed Write
Downstream
Secondary
1
Delayed Write
Upstream
Primary
1
Delayed Write
Upstream
Secondary
X = don’t care
2
The parity error was detected on the target (secondary) bus but not on the initiator (primary) bus.
3
The parity error was detected on the target (primary) bus but not on the initiator (secondary) bus.
6.4
SYSTEM ERROR (SERR#) REPORTING
PI7C8150 uses the P_SERR_L signal to report conditionally a number of system error
conditions in addition to the special case parity error conditions described in Section 7.2.3.
Whenever assertion of P_SERR_L is discussed in this document, it is assumed that the
following conditions apply:
!
For PI7C8150 to assert P_SERR_L for any reason, the SERR_L enable bit must be set
in the command register.
!
Whenever PI7C8150 asserts P_SERR_L, PI7C8150 must also set the signaled system
error bit in the status register.
In compliance with the PCI-to-PCI Bridge Architecture Specification, PI7C8150 asserts
P_SERR_L when it detects the secondary SERR_L input, S_SERR_L, asserted and the
SERR_L forward enable bit is set in the bridge control register. In addition, PI7C8150 also
sets the received system error bit in the secondary status register.
PI7C8150 also conditionally asserts P_SERR_L for any of the following reasons:
!
Target abort detected during posted write transaction
!
Master abort detected during posted write transaction
!
Posted write data discarded after 224 (default) attempts to deliver (224 target retries
received)
!
Parity error reported on target bus during posted write transaction (see previous
section)
!
Delayed write data discarded after 224 (default) attempts to deliver (224 target retries
received)
!
Delayed read data cannot be transferred from target after 224 (default) attempts (224
target retries received)
!
Master timeout on delayed transaction
The device-specific P_SERR_L status register reports the reason for the assertion of
P_SERR_L. Most of these events have additional device-specific disable bits in the
P_SERR_L event disable register that make it possible to mask out P_SERR_L assertion
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for specific events. The master timeout condition has a SERR_L enable bit for that event in
the bridge control register and therefore does not have a device-specific disable bit.
7
EXCLUSIVE ACCESS
This chapter describes the use of the LOCK_L signal to implement exclusive access to a
target for transactions that cross PI7C8150.
7.1
CONCURRENT LOCKS
The primary and secondary bus lock mechanisms operate concurrently except when
a locked transaction crosses PI7C8150. A primary master can lock a primary target without
affecting the status of the lock on the secondary bus, and vice versa. This means that a
primary master can lock a primary target at the same time that a secondary master locks a
secondary target.
7.2
ACQUIRING EXCLUSIVE ACCESS ACROSS PI7C8150
For any PCI bus, before acquiring access to the LOCK_L signal and starting a series of
locked transactions, the initiator must first check that both of the following conditions are
met:
!
The PCI bus must be idle.
!
The LOCK_L signal must be de-asserted.
The initiator leaves the LOCK_L signal de-asserted during the address phase and asserts
LOCK_L one clock cycle later. Once a data transfer is completed from the target, the target
lock has been achieved.
7.2.1
LOCKED TRANSACTIONS IN DOWNSTREAM DIRECTION
Locked transactions can cross PI7C8150 only in the downstream direction, from the
primary bus to the secondary bus.
When the target resides on another PCI bus, the master must acquire not only the lock on
its own PCI bus but also the lock on every bus between its bus and the target’s bus. When
PI7C8150 detects on the primary bus, an initial locked transaction intended for a target on
the secondary bus, PI7C8150 samples the address, transaction type, byte enable bits, and
parity, as described in Section 3.5.4. It also samples the lock signal. If there is a lock
established between 2 ports or the target bus is already locked by another master, then the
current lock cycle is retried without forward. Because a target retry is signaled to the
initiator, the initiator must relinquish the lock on the primary bus, and therefore the lock is
not yet established.
The first locked transaction must be a memory read transaction. Subsequent locked
transactions can be memory read or memory write transactions. Posted memory write
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transactions that are a part of the locked transaction sequence are still posted. Memory read
transactions that are a part of the locked transaction sequence are not pre-fetched.
When the locked delayed memory read request is queued, PI7C8150 does not queue any
more transactions until the locked sequence is finished. PI7C8150 signals a target retry to
all transactions initiated subsequent to the locked read transaction that are intended for
targets on the other side of PI7C8150. PI7C8150 allows any transactions queued before the
locked transaction to complete before initiating the locked transaction.
When the locked delayed memory read request transaction moves to the head of the
delayed transaction queue, PI7C8150 initiates the transaction as a locked read transaction
by de-asserting LOCK_L on the target bus during the first address phase, and by asserting
LOCK_L one cycle later. If LOCK_L is already asserted (used by another initiator),
PI7C8150 waits to request access to the secondary bus until LOCK_L is de-asserted when
the target bus is idle. Note that the existing lock on the target bus could not have crossed
PI7C8150. Otherwise, the pending queued locked transaction would not have been queued.
When PI7C8150 is able to complete a data transfer with the locked read transaction, the
lock is established on the secondary bus.
When the initiator repeats the locked read transaction on the primary bus with the same
address, transaction type, and byte enable bits, PI7C8150 transfers the read data back to the
initiator, and the lock is then also established on the primary bus.
For PI7C8150 to recognize and respond to the initiator, the initiator’s subsequent attempts
of the read transaction must use the locked transaction sequence (de-assert LOCK_L during
address phase, and assert LOCK_L one cycle later). If the LOCK_L sequence is not used in
subsequent attempts, a master timeout condition may result. When a master timeout
condition occurs, SERR_L is conditionally asserted (see Section 6.4), the read data and
queued read transaction are discarded, and the LOCK_L signal is de-asserted on the target
bus.
Once the intended target has been locked, any subsequent locked transactions initiated on
the initiator bus that are forwarded by PI7C8150 are driven as locked transactions on the
target bus.
The first transaction to establish LOCK_L must be Memory Read. If the first transaction is
not Memory read, the following transactions behave accordingly:
!
Type 0 Configuration Read/Write induces master abort
!
Type 1 Configuration Read/Write induces master abort
!
I/O Read induces master abort
!
I/O Write induces master abort
!
Memory Write induces master abort
When PI7C8150 receives a target abort or a master abort in response to the delayed locked
read transaction, this status is passed back to the initiator, and no locks are established on
either the target or the initiator bus. PI7C8150 resumes forwarding unlocked transactions in
both directions.
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7.2.2
LOCKED TRANSACTION IN UPSTREAM DIRECTION
PI7C8150 ignores upstream lock and transactions. PI7C8150 will pass these transactions as
normal transactions without lock established.
7.3
ENDING EXCLUSIVE ACCESS
After the lock has been acquired on both initiator and target buses, PI7C8150 must
maintain the lock on the target bus for any subsequent locked transactions until the initiator
relinquishes the lock.
The only time a target-retry causes the lock to be relinquished is on the first transaction of a
locked sequence. On subsequent transactions in the sequence,
the target retry has no effect on the status of the lock signal.
An established target lock is maintained until the initiator relinquishes the lock. PI7C8150
does not know whether the current transaction is the last one in a sequence of locked
transactions until the initiator de-asserts the LOCK_L signal at
end of the transaction.
When the last locked transaction is a delayed transaction, PI7C8150 has already completed
the transaction on the target bus. In this example, as soon as PI7C8150 detects that the
initiator has relinquished the LOCK_L signal by sampling it in the de-asserted state while
FRAME_L is de-asserted, PI7C8150 de-asserts the LOCK_L signal on the target bus as
soon as possible. Because of this behavior, LOCK_L may not be de-asserted until several
cycles after the last locked transaction has been completed on the target bus. As soon as
PI7C8150 has de-asserted LOCK_L to indicate the end of a sequence of locked
transactions, it resumes forwarding unlocked transactions.
When the last locked transaction is a posted write transaction, PI7C8150 de-asserts
LOCK_L on the target bus at the end of the transaction because the lock was relinquished
at the end of the write transaction on the initiator bus.
When PI7C8150 receives a target abort or a master abort in response to a locked delayed
transaction, PI7C8150 returns a target abort or a master abort when the initiator repeats the
locked transaction. The initiator must then de-assert LOCK_L at the end of the transaction.
PI7C8150 sets the appropriate status bits, flagging the abnormal target termination
condition (see Section 3.8). Normal forwarding of unlocked posted and delayed
transactions is resumed.
When PI7C8150 receives a target abort or a master abort in response to a locked posted
write transaction, PI7C8150 cannot pass back that status to the initiator. PI7C8150 asserts
SERR_L on the initiator bus when a target abort or a master abort is received during a
locked posted write transaction, if the SERR_L enable bit is set in the command register.
Signal SERR_L is asserted for the master abort condition if the master abort mode bit is set
in the bridge control register (see Section 6.4).
8
PCI BUS ARBITRATION
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PI7C8150 must arbitrate for use of the primary bus when forwarding upstream
transactions. Also, it must arbitrate for use of the secondary bus when forwarding
downstream transactions. The arbiter for the primary bus resides external to PI7C8150,
typically on the motherboard. For the secondary PCI bus, PI7C8150 implements an internal
arbiter. This arbiter can be disabled, and an external arbiter can be used instead. This
chapter describes primary and secondary bus arbitration.
8.1
PRIMARY PCI BUS ARBITRATION
PI7C8150 implements a request output pin, P_REQ_L, and a grant input pin, P_GNT_L,
for primary PCI bus arbitration. PI7C8150 asserts P_REQ_L when forwarding transactions
upstream; that is, it acts as initiator on the primary PCI bus. As long as at least one pending
transaction resides in the queues in the upstream direction, either posted write data or
delayed transaction requests, PI7C8150 keeps P_REQ_L asserted. However, if a target
retry, target disconnect, or a target abort is received in response to a transaction initiated by
PI7C8150 on the primary PCI bus, PI7C8150 de-asserts P_REQ_L for two PCI clock
cycles.
For all cycles through the bridge, P_REQ_L is not asserted until the transaction request has
been completely queued. When P_GNT_L is asserted LOW by the primary bus arbiter
after PI7C8150 has asserted P_REQ_L, PI7C8150 initiates a transaction on the primary bus
during the next PCI clock cycle. When P_GNT_L is asserted to PI7C8150 when P_REQ_L
is not asserted, PI7C8150 parks P_AD, P_CBE, and P_PAR by driving them to valid logic
levels. When the primary bus is parked at PI7C8150 and PI7C8150 has a transaction to
initiate on the primary bus, PI7C8150 starts the transaction if P_GNT_L was asserted
during the previous cycle.
8.2
SECONDARY PCI BUS ARBITRATION
PI7C8150 implements an internal secondary PCI bus arbiter. This arbiter supports eight
external masters on the secondary bus in addition to PI7C8150. The internal arbiter can be
disabled, and an external arbiter can be used instead for secondary bus arbitration.
8.2.1
SECONDARY BUS ARBITRATION USING THE INTERNAL
ARBITER
To use the internal arbiter, the secondary bus arbiter enable pin, S_CFN_L, must be tied
LOW. PI7C8150 has nine secondary bus request input pins, S_REQ_L[8:0], and has nine
secondary bus output grant pins, S_GNT_L[8:0], to support external secondary bus
masters.
The secondary bus request and grant signals are connected internally to the arbiter and are
not brought out to external pins when S_CFN_L is HIGH.
The secondary arbiter supports a 2-sets programmable 2-level rotating algorithm with each
set taking care of 9 requests / grants. Each set of masters can be assigned to a high priority
group and a low priority group. The low priority group as a whole represents one entry in
the high priority group; that is, if the high priority group consists of n masters, then in at
least every n+1 transactions the highest priority is assigned to the low priority group.
Priority rotates evenly among the low priority group. Therefore, members of the high
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priority group can be serviced n transactions out of n+1, while one member of the low
priority group is serviced once every n+1 transactions. Figure 9–1 shows an example of an
internal arbiter where four masters, including PI7C8150, are in the high priority group, and
five masters are in the low priority group. Using this example, if all requests are always
asserted, the highest priority rotates among the masters in the following fashion (high
priority members are given in italics, low priority members, in boldface type): B, m0, m1,
m2, m3, B, m0, m1, m2, m4, B, m0, m1, m2, m5, B, m0, m1, m2, m6, B, m0, m1, m2, m7
and so on.
Figure 9-1. Secondary Arbiter Example
Each bus master, including PI7C8150, can be configured to be in either the low priority
group or the high priority group by setting the corresponding priority bit in the arbitercontrol register. The arbiter-control register is located at offset 40h. Each master has a
corresponding bit. If the bit is set to 1, the master is assigned to the high priority group. If
the bit is set to 0, the master is assigned to the low priority group. If all the masters are
assigned to one group, the algorithm defaults to a straight rotating priority among all the
masters. After reset, all external masters are assigned to the low priority group, and
PI7C8150 is assigned to the high priority group. PI7C8150 receives highest priority on the
target bus every other transaction, and priority rotates evenly among the other masters.
Priorities are re-evaluated every time S_FRAME_L is asserted at the start of each new
transaction on the secondary PCI bus. From this point until the time that the next
transaction starts, the arbiter asserts the grant signal corresponding to the highest priority
request that is asserted. If a grant for a particular request is asserted, and a higher priority
request subsequently asserts, the arbiter de-asserts the asserted grant signal and asserts the
grant corresponding to the new higher priority request on the next PCI clock cycle. When
priorities are re-evaluated, the highest priority is assigned to the next highest priority
master relative to the master that initiated the previous transaction. The master that initiated
the last transaction now has the lowest priority in its group.
If PI7C8150 detects that an initiator has failed to assert S_FRAME_L after 16 cycles of
both grant assertion and a secondary idle bus condition, the arbiter de-asserts the grant.
To prevent bus contention, if the secondary PCI bus is idle, the arbiter never asserts one
grant signal in the same PCI cycle in which it de-asserts another. It de-asserts one grant and
asserts the next grant, no earlier than one PCI clock cycle later. If the secondary PCI bus is
busy, that is, S_FRAME_L or S_IRDY_L is asserted, the arbiter can be de-asserted one
grant and asserted another grant during the same PCI clock cycle.
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8.2.2
PREEMPTION
Preemption can be programmed to be either on or off, with the default to on (offset 4Ch, bit
31=0). Time-to-preempt can be programmed to 0, 1, 2, 4, 8, 16, 32, or 64 (default is 0)
clocks.
If the current master occupies the bus and other masters are waiting, the current master will
be preempted by removing its grant (GNT#) after the next master waits for the time-topreempt.
8.2.3
SECONDARY BUS ARBITRATION USING AN EXTERNAL
ARBITER
The internal arbiter is disabled when the secondary bus central function control pin,
S_CFN_L, is tied HIGH. An external arbiter must then be used.
When S_CFN_L is tied HIGH, PI7C8150, reconfigures two pins to be external request and
grant pins. The S_GNT_L[0] pin is reconfigured to be the external request pin because it’s
an output. The S_REQ_L[0] pin is reconfigured to be the external grant pin because it’s an
input. When an external arbiter is used, PI7C8150 uses the S_GNT_L[0] pin to request the
secondary bus. When the reconfigured S_REQ_L[0] pin is asserted LOW after PI7C8150
has asserted S_GNT_L[0], PI7C8150 initiates a transaction on the secondary bus one cycle
later. If grant is asserted and PI7C8150 has not asserted the request, PI7C8150 parks AD,
CBE and PAR pins by driving them to valid logic levels.
The unused secondary bus grant outputs, S_GNT_L[8:1] are driven HIGH. The unused
secondary bus request inputs, S_REQ_L[8:1], should be pulled HIGH.
8.2.4
BUS PARKING
Bus parking refers to driving the AD[31:0], CBE[3:0]#, and PAR lines to a known value
while the bus is idle. In general, the device implementing the bus arbiter is responsible for
parking the bus or assigning another device to park the bus. A device parks the bus when
the bus is idle, its bus grant is asserted, and the device’s request is not asserted. The AD
and CBE signals should be driven first, with the PAR signal driven one cycle later.
PI7C8150 parks the primary bus only when P_GNT_L is asserted, P_REQ_L is deasserted, and the primary PCI bus is idle. When P_GNT_L is de-asserted, PI7C8150 3states the P_AD, P_CBE, and P_PAR signals on the next PCI clock cycle. If PI7C8150 is
parking the primary PCI bus and wants to initiate a transaction on that bus, then PI7C8150
can start the transaction on the next PCI clock cycle by asserting P_FRAME_L if
P_GNT_L is still asserted.
If the internal secondary bus arbiter is enabled, the secondary bus is always parked at the
last master that used the PCI bus. That is, PI7C8150 keeps the secondary bus grant asserted
to a particular master until a new secondary bus request comes along. After reset,
PI7C8150 parks the secondary bus at itself until transactions start occurring on the
secondary bus. Offset 48h, bit 1, can be set to 1 to park the secondary bus at PI7C8150. By
default, offset 48h, bit 1, is set to 0. If the internal arbiter is disabled, PI7C8150 parks the
secondary bus only when the reconfigured grant signal, S_REQ_L[0], is asserted and the
secondary bus is idle.
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9
CLOCKS
This chapter provides information about the clocks.
9.1
PRIMARY CLOCK INPUTS
PI7C8150 implements a primary clock input for the PCI interface. The primary interface is
synchronized to the primary clock input, P_CLK, and the secondary interface is
synchronized to the secondary clock. The secondary clock is derived internally from the
primary clock, P_CLK. PI7C8150 operates at a maximum frequency of 66 MHz.
9.2
SECONDARY CLOCK OUTPUTS
PI7C8150 has 10 secondary clock outputs, S_CLKOUT[9:0] that can be used as clock
inputs for up to nine external secondary bus devices. The S_CLKOUT[9:0] outputs are
derived from P_CLK. The secondary clock edges are delayed from P_CLK edges by a
minimum of 0ns. This is the rule for using secondary clocks:
Each secondary clock output is limited to no more than one load.
10
GENERAL PURPOSE I/O INTERFACE
The PI7C8150 implements a 4-pin general purpose I/O interface. During normal operation,
device specific configuration registers control the GPIO interface. The GPIO interface can
be used for the following functions:
10.1
!
During secondary interface reset, the GPIO interface can be used to shift in a 16-bit
serial stream that serves as a secondary bus clock disable mask.
!
Along with the GPIO[3] pin, a live insertion bit can be used to bring the PI7C8150 to a
halt through hardware, permitting live insertion of option cards behind the PI7C8150.
GPIO CONTROL REGISTERS
During normal operation, the following device specific configuration registers control the
GPIO interface:
!
The GPIO output data register
!
The GPIO output enable control register
!
The GPIO input data register
These registers consist of five 8-bit fields:
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!
Write-1-to-set output data field
!
Write-1-to-clear output data field
!
Write-1-to-set signal output enable control field
!
Write-1-to-clear signal output enable control field
!
Input data field
The bottom four bits of the output enable fields control whether each GPIO signal is input
only or bi-directional. Each signal is controlled independently by a bit in each output
enable control field. If a 1 is written to the write-1-to-set field, the corresponding pin is
activated as an output. If a 1 is written to the write-1-to-clear field, the output driver is tristated, and the pin is then input only. Writing zeroes to these registers has no effect. The
reset for these signals is input only.
The input data field is read only and reflects the current value of the GPIO pins. A type 0
configuration read operation to this address is used to obtain the values of these pins. All
pins can be read at any time, whether configured as input only or as bi-directional.
The output data fields also use the write-1-to-set and write-1-to-clear mode. If a 1 is
written to the write-1-to-set field and the pin is enabled as an output, the corresponding
GPIO output is driven HIGH. If a 1 is written to the write-1-to-clear field and the pin is
enabled as an output, the corresponding GPIO output is driven LOW. Writing zeros to
these registers has no effect. The value written to the output register will be driven only
when the GPIO signal is configured as bi-directional. A type 0 configuration write
operation is used to program these fields. The rest value for the output is 0.
10.2
SECONDARY CLOCK CONTROL
The PI7C8150 uses the GPIO pins and the MSK_IN signal to input a 16-bit serial data
stream. This data stream is shifted into the secondary clock control register and is used for
selectively disabling secondary clock outputs.
The serial data stream is shifted in as soon as P_RST_L is detected deasserted and the
secondary reset signal, S_RST_L, is detected asserted. The deassertion of S_RST_L is
delayed until the PI7C8150 completes shifting in the clock mask data, which takes 23 clock
cycles. After that, the GPIO pins can be used as general-purpose I/O pins.
An external shift register should be used to load and shift the data. The GPIO pins are used
for shift register control and serial data input. Table 10-1 shows the operation of the GPIO
pins.
Table 10-1. GPIO Operation
GPIO Pin
Operation
Shift register clock output at 33MHz max frequency
Not used
Shift register control
0: Load
1: Shift
Not used
GPIO[0]
GPIO[1]
GPIO[2]
GPIO[3]
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The data is input through the dedicated input signal, MSK_IN.
The shift register circuitry is not necessary for correct operation of PI7C8150. The shift
register can be eliminated, and MSK_IN can be tied LOW to enable all secondary clock
outputs or tied HIGH to force all secondary clock outputs HIGH. Table 10-2 shows the
format of the serial stream.
Table 10-2. GPIO Serial Data Format
Bit
[1:0]
[3:2]
[5:4]
[7:6]
[8]
[9]
[10]
[11]
[12]
[13]
[14]
[15]
Description
Slot 0 PRSNT#[1:0] or device 0
Slot 1 PRSNT#[1:0] or device 1
Slot 2 PRSNT#[1:0] or device 2
Slot 3 PRSNT#[1:0] or device 3
Device 4
Device 5
Device 6
Device 7
Device 8
PI7C8150 S_CLKIN
Reserved
Reserved
S_CLKOUT
0
1
2
3
4
5
6
7
8
9
NA
NA
The first 8 bits contain the PRSNT#[1:0] signal values for four slots, and these bits control
the S_CLKOUT[3:0] outputs. If one or both of the PRSNT#[1:0] signals are 0, that
indicates that a card is present in the slot and therefore the secondary clock for that slot is
not masked. If these clocks are connected to devices and not to slots, one or both of the bits
should be tied low to enable the clock.
The next 5 bits are the clock mask for devices; each bit enables or disables the clock for
one device. These bits control the S_CLKOUT[8:4] outputs: 0 enables the clock, and 1
disables the clock.
Bit 13 is the clock enable bit for S_CLKOUT[9], which is connected to PI7C8150’s
S_CLKIN input.
If desired, the assignment of S_CLKOUT outputs to slots, devices, and PI7C8150’s
S_CLKIN input can be rearranged from the assignment shown here. However, it is
important that the serial data stream format match the assignment of S_CLKOUT.
The 8 least significant bits are connected to the PRSNT# pins for the slots. The next 5 bits
are tied high to disable their respective secondary clocks because those clocks are not
connected to anything. The next bit is tied LOW because that secondary clock output is
connected to the PI7C8150 S_CLKIN input. When the secondary reset signal, S_RST_L, is
detected asserted and the primary reset signal, P_RST_L, is detected deasserted, PI7C8150
drives GPIO[2] LOW for one cycle to load the clock mask inputs into the shift register. On
the next cycle, PI7C8150 drives GPIO[2] HIGH to perform a shift operation. This shifts the
clock mask into MSK_IN; the most significant bit is shifted in first, and the least
significant bit is shifted in last.
After the shift operation is complete, PI7C8150 tri-states the GPIO signals and can deassert
S_RST_L if the secondary reset bit is clear. PI7C8150 then ignores MSK_IN. Control of
the GPIO signal now reverts to PI7C8150 GPIO control registers. The clock disable mask
can be modified subsequently through a configuration write command to the secondary
clock control register in device-specific configuration space.
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10.3
LIVE INSERTION
The GPIO[3] pin can be used, along with a live insertion mode bit, to disable transaction
forwarding.
To enable live insertion mode, the live insertion mode bit in the chip control register must
be set to 1, and the output enable control for GPIO[3] must be set to input only in the GPIO
output enable control register. When live insertion mode is enabled, whenever GPIO[3] is
driven to a value of 1, the I/O enable, the memory enable, and the master enable bits are
internally masked to 0. This means that, as a target, PI7C8150 no longer accepts any I/O or
memory transactions, on either interface. When read, the register bits still reflect the value
originally written by a configuration write command; when GPIO[3] is deasserted, the
internal enable bits return to their original value (as they appear when read from the
command register). When this mode is enabled, as a master, PI7C8150 completes any
posted write or delayed request transactions that have already been queued.
Delayed completion transactions are not returned to the master in this mode because
PI7C8150 is not responding to any I/O or memory transactions during this time. PI7C8150
continues to accept configuration transactions in live insertion mode. Once live insertion
mode brings PI7C8150 to a halt and queued transactions are completed, the secondary reset
bit in the bridge control register can be used to assert S_RST_L, if desired, to reset and tristate secondary bus devices, and to enable any live insertion hardware.
11
PCI POWER MANAGEMENT
PI7C8150 incorporates functionality that meets the requirements of the PCI Power
Management Specification, Revision 1.0. These features include:
!
PCI Power Management registers using the Enhanced Capabilities Port (ECP) address
mechanism
!
Support for D0, D3 hot and D3 cold power management states
!
Support for D0, D1, D2, D3 hot , and D3 cold power management states for devices
behind the bridge
!
Support of the B2 secondary bus power state when in the D3 hot power management
state
Table 11-1 shows the states and related actions that PI7C8150 performs during power
management transitions. (No other transactions are permitted.)
Table 11-1. Power management transitions
Current Status
D0
Next State
D3cold
D0
D3hot
D0
D2
D0
D1
D3hot
D0
Action
Power has been removed from PI7C8150. A power-up reset must be
performed to bring PI7C8150 to D0.
If enabled to do so by the BPCCE pin, PI7C8150 will disable the
secondary clocks and drive them LOW.
Unimplemented power state. PI7C8150 will ignore the write to the
power state bits (power state remains at D0).
Unimplemented power state. PI7C8150 will ignore the write to the
power state bits (power state remains at D0).
PI7C8150 enables secondary clock outputs and performs an internal
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D3hot
D3cold
D3cold
D0
chip reset. Signal S_RST_L will not be asserted. All registers will
be returned to the reset values and buffers will be cleared.
Power has been removed from PI7C8150. A power-up reset must be
performed to bring PI7C8150 to D0.
Power-up reset. PI7C8150 performs the standard power-up reset
functions as described in Section 12.
PME# signals are routed from downstream devices around PCI-to-PCI bridges. PME#
signals do not pass through PCI-to-PCI bridges.
12
RESET
This chapter describes the primary interface, secondary interface, and chip reset
mechanisms.
12.1
PRIMARY INTERFACE RESET
PI7C8150 has a reset input, P_RESET_L. When P_RESET_L is asserted, the following
events occur:
!
PI7C8150 immediately tri-states all primary and secondary PCI interface signals.
!
PI7C8150 performs a chip reset.
!
Registers that have default values are reset.
P_RESET_L asserting and de-asserting edges can be asynchronous to P_CLK and
S_CLKOUT. PI7C8150 is not accessible during P_RESET_L. After P_RESET_L is deasserted, PI7C8150 remains inaccessible for 16 PCI clocks before the first configuration
transaction can be accepted.
12.2
SECONDARY INTERFACE RESET
PI7C8150 is responsible for driving the secondary bus reset signals, S_RESET_L.
PI7C8150 asserts S_RESET_L when any of the following conditions are met:
Signal P_RESET_L is asserted. Signal S_RESET_L remains asserted as long as
P_RESET_L is asserted and does not de-assert until P_RESET_L is de-asserted.
The secondary reset bit in the bridge control register is set. Signal S_RESET_L
remains asserted until a configuration write operation clears the secondary reset bit.
S_RESET_L pin is asserted. When S_RESET_L is asserted, PI7C8150 immediately 3states all the secondary PCI interface signals associated with the secondary port. The
S_RESET_L in asserting and de-asserting edges can be asynchronous to P_CLK.
When S_RESET_L is asserted, all secondary PCI interface control signals, including the
secondary grant outputs, are immediately 3-stated. Signals S1_AD, S1_CBE[3:0]#, S_PAR
are driven low for the duration of S_RESET_L assertion. All posted write and delayed
transaction data buffers are reset. Therefore, any transactions residing inside the buffers at
the time of secondary reset are discarded.
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When S_RESET_L is asserted by means of the secondary reset bit, PI7C8150 remains
accessible during secondary interface reset and continues to respond to accesses to its
configuration space from the primary interface.
12.3
CHIP RESET
The chip reset bit in the diagnostic control register can be used to reset the PI7C8150 and
the secondary bus.
When the chip reset bit is set, all registers and chip state are reset and all signals are
tristated. S_RESET_L is asserted and the secondary reset bit is automatically set.
S_RESET_L remains asserted until a configuration write operation clears the secondary
reset bit and the serial clock mask has been shifted in. Within 20 PCI clock cycles after
completion of the configuration write operation, PI7C8150’s reset bit automatically clears
and PI7C8150 is ready for configuration.
During reset, PI7C8150 is inaccessible.
13
SUPPORTED COMMANDS
The PCI command set is given below for the primary and secondary interfaces.
13.1
PRIMARY INTERFACE
P_CBE [3:0]
0000
0001
0010
0011
0100
0101
0110
Command
Interrupt
Acknowledge
Special Cycle
I/O Read
Action
Ignore
Do not claim. Ignore.
1. If address is within pass through I/O range, claim and pass
through.
2. Otherwise, do not pass through and do not claim for
internal access.
Same as I/O Read.
--------1. If address is within pass through memory range, claim and
pass through.
I/O Write
Reserved
Reserved
Memory Read
2. If address is within pass through memory mapped I/O
range, claim and pass through.
0111
1000
1001
1010
Memory Write
Reserved
Reserved
Configuration Read
3. Otherwise, do not pass through and do not claim for
internal access.
Same as Memory Read.
--------Type 0 Configuration Read:
If the bridge’s IDSEL line is asserted, perform function
decode and claim if target function is implemented.
Otherwise, ignore. If claimed, permit access to target
function’s configuration registers. Do not pass through
under any circumstances.
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Type 1 Configuration Read:
1. If the target bus is the bridge’s secondary bus: claim and
pass through as a Type 0 Configuration Read.
2. If the target bus is a subordinate bus that exists behind the
bridge (but not equal to the secondary bus): claim and pass
through as a Type 1 Configuration Read.
1011
Configuration Write
3. Otherwise, ignore.
Type 0 Configuration Write: same as Configuration
Read.
Type 1 Configuration Write (not special cycle request):
1. If the target bus is the bridge’s secondary bus: claim and
pass through as a Type 0 Configuration Write
2. If the target bus is a subordinate bus that exists behind the
bridge (but not equal to the secondary bus): claim and pass
through unchanged as a Type 1 Configuration Write.
3. Otherwise, ignore.
Configuration Write as Special Cycle Request
(device = 1Fh, function = 7h)
1. If the target bus is the bridges secondary bus:
claim and pass through as a special cycle.
2. If the target bus is a subordinate bus that exists
behind the bridge (but not equal to the secondary
bus): claim and pass through unchanged as a type
1 Configuration Write.
1100
1101
1110
1111
13.2
Memory Read
Multiple
Dual Address Cycle
Memory Read Line
Memory Write and
Invalidate
3. Otherwise ignore
Same as Memory Read
Supported
Same as Memory Read
Same as Memory Read
SECONDARY INTERFACE
S_CBE[3:0]
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
Command
Interrupt
Acknowledge
Special Cycle
I/O Read
I/O Write
Reserved
Reserved
Memory Read
Memory Write
Reserved
Reserved
Configuration Read
Action
Ignore
Do not claim. Ignore.
Same as Primary Interface
Same as I/O Read.
--------Same as Primary Interface
Same as Memory Read.
--------Ignore
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1011
Configuration Write
I. Type 0 Configuration Write: Ignore
II. Type 1 Configuration Write (not special cycle
request):Ignore
III. Configuration Write as Special Cycle Request (device
= 1Fh, function = 7h):
1. If the target bus is the bridge’s primary bus: claim and
pass through as a Special Cycle
2. If the target bus is neither the primary bus nor is it in range
of buses defined by the bridge’s secondary and subordinate
bus registers: claim and pass through unchanged as a Type 1
Configuration Write.
1100
Memory Read
Multiple
Dual Address Cycle
Memory Read Line
Memory Write and
Invalidate
1101
1110
1111
14
3. If the target bus is not the bridge’s primary bus, but is in
range of buses defined by the bridge’s secondary and
subordinate bus registers: ignore.
Same as Memory Read
Supported
Same as Memory Read
Same as Memory Read
CONFIGURATION REGISTERS
PCI configuration defines a 64-byte space (configuration header) to define various
attributes of PI7C8150 as shown below.
14.1
CONFIGURATION REGISTER
31-24
23-16
15-8
Device ID
Primary Status
7-0
Vendor ID
Command
Revision ID
Primary Latency Timer
Cache Line Size
Reserved
Reserved
Secondary Latency
Subordinate Bus
Secondary Bus
Primary Bus Number
Timer
Number
Number
Secondary Status
I/O Limit
I/O Base
Memory Limit
Memory Base
Prefetchable Memory Limit
Prefetchable Memory Base
Prefetchable Base Upper 32-bit
Prefetchable Limit Upper 32-bit
I/O Limit Upper 16-bit
I/O Base Upper 16-bit
Reserved
Capability Pointer to
DCh
Reserved
Bridge Control
Reserved
Interrupt Line
Arbiter Control
Diagnostic / Chip Control
Reserved
Upstream Memory Control
Extended Chip Control
Secondary
Hot Swap Switch Time Slot
Reserved
Class Code
Header Type
Address
00h
04h
08h
0Ch
10h
14h
18h
Bus Arbiter
Preemption
Control
Upstream (S to P) Memory Limit
Upstream (S to P) Memory Base
Upstream (S to P) Memory Base Upper 32-bit
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1Ch
20h
24h
28h
2Ch
30h
34h
38h
3Ch
40h
44h
48h
4Ch
50h
54h
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Upstream (S to P) Memory Limit Upper 32-bit
Reserved
Reserved
GPIO Data and Control
58h
5Ch
60h
64h
P_SERR_L Status
Reserved
Reserved
Reserved
Port Option
Retry Counter
Reserved
Secondary Master Timeout Counter
Primary Master Timeout Counter
Reserved
Chassis Number
Slot Number
Next Pointer
Capability ID
Reserved
Power Management Capabilities
Next Item Pointer
Capability ID
Reserved
PPB Support Extensions
Power Management Data
Reserved
Next Pointer
Capability ID
Reserved
68h
6Ch
70h
74h
78h
7Ch
80h
84h-AFh
B0h
B4h-D8h
DCh
E0h
E4h
E8h-FFh
P_SERR# Event
Disable
Secondary Clock Control
Reserved
14.1.1
VENDOR ID REGISTER – OFFSET 00h
Bit
15:0
14.1.2
Type
R/O
Description
Identifies Pericom as vendor of this device. Hardwired as 12D8h.
DEVICE ID REGISTER – OFFSET 00h
Bit
31:16
14.1.3
Function
Vendor ID
Function
Device ID
Type
R/O
Description
Identifies this device as the PI7C8150. Hardwired as 8150h.
COMMAND REGISTER – OFFSET 04h
Bit
Function
Type
0
I/O Space Enable
R/W
Description
Controls response to I/O access on the primary interface
0: ignore I/O transactions on the primary interface
1: enable response to I/O transactions on the primary interface
Reset to 0
Controls response to memory accesses on the primary interface
1
Memory Space
Enable
0: ignore memory transactions on the primary interface
R/W
1: enable response to memory transactions on the primary interface
Reset to 0
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PI7C8150
2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
Controls ability to operate as a bus master on the primary interface
2
3
4
Bus Master
Enable
Special Cycle
Enable
Memory Write
And Invalidate
Enable
0: do not initiate memory or I/O transactions on the primary
interface and disable response to memory and I/O transactions on
the secondary interface
R/W
1: enables 7C8150 to operate as a master on the primary interfaces
for memory and I/O transactions forwarded from the secondary
interface
R/O
R/O
Reset to 0
No special cycles defined.
Bit is defined as read only and returns 0 when read
Memory write and invalidate not supported.
Bit is implemented as read only and returns 0 when read (unless
forwarding a transaction for another master)
Controls response to VGA compatible palette accesses
0: ignore VGA palette accesses on the primary
5
6
VGA Palette
Snoop Enable
Parity Error
Response
R/W
1: enable positive decoding response to VGA palette writes on the
primary interface with I/O address bits AD[9:0] equal to 3C6h,
3C8h, and 3C9h (inclusive of ISA alias; AD[15:10] are not decoded
and may be any value)
Controls response to parity errors
0: 7C8150 may ignore any parity errors that it detects and continue
normal operation
R/W
1: 7C8150 must take its normal action when a parity error is
detected
Reset to 0
Controls the ability to perform address / data stepping
7
Wait Cycle
Control
0: disable address/data stepping (affects primary and secondary)
R/O
1: enable address/data stepping (affects primary and secondary)
Reset to 0
Controls the enable for the P_SERR_L pin
8
P_SERR_L
enable
0: disable the P_SERR_L driver
R/W
1: enable the P_SERR_L driver
Reset to 0
Controls 7C8150’s ability to generate fast back-to-back transactions
to different devices on the primary interface.
9
Fast Back-toBack Enable
R/W
0: no fast back-to-back transactions
1: enable fast back-to-back transactions
15:10
14.1.4
Reserved
R/O
Reset to 0
Returns 000000 when read
STATUS REGISTER – OFFSET 04h
Bit
19:16
Function
Reserved
Type
R/O
Description
Reset to 0
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PI7C8150
2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
20
Capabilities List
R/O
Set to 1 to enable support for the capability list (offset 34h is the
pointer to the data structure)
21
66MHz Capable
R/O
22
23
Reserved
Fast Back-toBack Capable
R/O
R/O
Reset to 1
Reset to 0
Set to 1 to enable decoding of fast back-to-back transactions on the
primary interface to different targets
24
Data Parity Error
Detected
R/WC
Reset to 1
Set to 1 when P_PERR_L is asserted and bit 6 of command register
is set
26:25
DEVSEL_L
timing
R/O
Reset to 1
Set to 1 to enable 66MHz operation on the primary interface
Reset to 0
DEVSEL_L timing (medium decoding)
00: fast DEVSEL_L decoding
01: medium DEVSEL_L decoding
10: slow DEVSEL_L decoding
11: reserved
Reset to 01
Set to 1 (by a target device) whenever a target abort cycle occurs
27
Signaled Target
Abort
R/WC
28
Received Target
Abort
R/WC
Reset to 0
Set to 1 (by a master device) whenever transactions are terminated
with target aborts
29
Received Master
Abort
R/WC
Reset to 0
Set to 1 (by a master) when transactions are terminated with Master
Abort
30
Signaled System
Error
R/WC
31
Detected Parity
Error
R/WC
Reset to 0
Set to 1 when P_SERR_L is asserted
Reset to 0
Set to 1 when address or data parity error is detected on the primary
interface
Reset to 0
14.1.5
REVISION ID REGISTER – OFFSET 08h
Bit
7:0
14.1.6
Type
R/O
Description
Indicates revision number of device. Hardwired to 01h
CLASS CODE REGISTER – OFFSET 08h
Bit
15:8
23:16
31:24
14.1.7
Function
Revision
Function
Programming
Interface
Sub-Class Code
Base Class Code
Type
R/O
R/O
R/O
Description
Read as 0 to indicate no programming interfaces have been defined
for PCI-to-PCI bridges
Read as 04h to indicate device is PCI-to-PCI bridge
Read as 06h to indicate device is a bridge device
CACHE LINE SIZE REGISTER – OFFSET 0Ch
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PI7C8150
2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
Bit
7:0
Function
Cache Line Size
Type
R/W
Description
Designates the cache line size for the system and is used when
terminating memory write and invalidate transactions and when
prefetching memory read transactions.
Only cache line sizes (in units of 4-byte) which are a power of two
are valid (only one bit can be set in this register; only 00h, 01h, 02h,
04h, 08h, and 10h are valid values).
Reset to 0
14.1.8
PRIMARY LATENCY TIMER REGISTER – OFFSET 0Ch
Bit
15:8
Function
Primary Latency
timer
Type
R/W
Description
This register sets the value for the Master Latency Timer, which
starts counting when the master asserts FRAME_L.
Reset to 0
14.1.9
HEADER TYPE REGISTER – OFFSET 0Ch
Bit
23:16
14.1.10
Function
Header Type
Type
R/O
Description
Read as 01h to indicate that the register layout conforms to the
standard PCI-to-PCI bridge layout.
PRIMARY BUS NUMBER REGISTSER – OFFSET 18h
Bit
7:0
Function
Primary Bus
Number
Type
R/W
Description
Indicates the number of the PCI bus to which the primary interface
is connected. The value is set in software during configuration.
Reset to 0
14.1.11
SECONDARY BUS NUMBER REGISTER – OFFSET 18h
Bit
15:8
Function
Secondary Bus
Number
Type
R/W
Description
Indicates the number of the PCI bus to which the secondary
interface is connected. The value is set in software during
configuration.
Reset to 0
14.1.12
SUBORDINATE BUS NUMBER REGISTER – OFFSET 18h
Bit
23:16
Function
Subordinate Bus
Number
Type
R/W
Description
Indicates the number of the PCI bus with the highest number that is
subordinate to the bridge. The value is set in software during
configuration.
Reset to 0
14.1.13
SECONDARY LATENCY TIMER REGISTER – OFFSET 18h
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PI7C8150
2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
Bit
31:24
Function
Secondary
Latency Timer
Type
R/W
Description
Designated in units of PCI bus clocks. Latency timer checks for
master accesses on the secondary bus interfaces that remain
unclaimed by any target.
Reset to 0
14.1.14
I/O BASE REGISTER – OFFSET 1Ch
Bit
3:0
7:4
Function
32-bit Indicator
I/O Base Address
[15:12]
Type
R/O
R/W
Description
Read as 01h to indicate 32-bit I/O addressing
Defines the bottom address of the I/O address range for the bridge
to determine when to forward I/O transactions from one interface to
the other. The upper 4 bits correspond to address bits [15:12] and
are writable. The lower 12 bits corresponding to address bits [11:0]
are assumed to be 0. The upper 16 bits corresponding to address
bits [31:16] are defined in the I/O base address upper 16 bits address
register
Reset to 0
14.1.15
I/O LIMIT REGISTER – OFFSET 1Ch
Bit
11:8
15:12
Function
32-bit Indicator
I/O Base Address
[15:12]
Type
R/O
R/W
Description
Read as 01h to indicate 32-bit I/O addressing
Defines the top address of the I/O address range for the bridge to
determine when to forward I/O transactions from one interface to
the other. The upper 4 bits correspond to address bits [15:12] and
are writable. The lower 12 bits corresponding to address bits [11:0]
are assumed to be FFFh. The upper 16 bits corresponding to
address bits [31:16] are defined in the I/O base address upper 16 bits
address register
Reset to 0
14.1.16
SECONDARY STATUS REGISTER – OFFSET 1Ch
Bit
20:16
21
Function
Reserved
66MHz Capable
Type
R/O
R/O
22
Reserved
R/O
23
Fast Back-toBack Capable
R/O
24
Master Data
Parity Error
Detected
R/WC
Description
Reset to 0
Set to 1 to enable 66MHz operation on the secondary interface
Reset to 1
Reset to 0
Set to 1 to enable decoding of fast back-to-back transactions on the
secondary interface to different targets
Reset to 0
Set to 1 when S_PERR_L is asserted and bit 6 of command register
is set
Reset to 0
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PI7C8150
2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
DEVSEL# timing (medium decoding)
26:25
27
28
29
30
31
DEVSEL_L
timing
Signaled Target
Abort
Received Target
Abort
Received Master
Abort
R/O
R/WC
R/WC
R/WC
00: fast DEVSEL_L decoding
01: medium DEVSEL_L decoding
10: slow DEVSEL_L decoding
11: reserved
Reset to 01
Set to 1 (by a target device) whenever a target abort cycle occurs on
its secondary interface
Reset to 0
Set to 1 (by a master device) whenever transactions on its secondary
interface are terminated with target abort
Reset to 0
Set to 1 (by a master) when transactions on its secondary interface
are terminated with Master Abort
Reset to 0
Set to 1 when S_SERR_L is asserted
Received System
Error
R/WC
Detected Parity
Error
R/WC
Reset to 0
Set to 1 when address or data parity error is detected on the
secondary interface
Reset to 0
14.1.17
MEMORY BASE REGISTER – OFFSET 20h
Bit
3:0
Function
Type
R/O
15:4
Memory Base
Address [15:4]
R/W
Description
Lower four bits of register are read only and return 0.
Reset to 0
Defines the bottom address of an address range for the bridge to
determine when to forward memory transactions from one interface
to the other. The upper 12 bits correspond to address bits [31:20]
and are writable. The lower 20 bits corresponding to address bits
[19:0] are assumed to be 0.
Reset to 0
14.1.18
14.1.19
MEMORY LIMIT REGISTER – OFFSET 20h
Bit
19:16
Function
Type
R/O
31:20
Memory Limit
Address [31:20]
R/W
Description
Lower four bits of register are read only and return 0.
Reset to 0
Defines the top address of an address range for the bridge to
determine when to forward memory transactions from one interface
to the other. The upper 12 bits correspond to address bits [31:20]
and are writable. The lower 20 bits corresponding to address bits
[19:0] are assumed to be FFFFFh.
PEFETCHABLE MEMORY BASE REGISTER – OFFSET 24h
Bit
Function
Type
Description
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PI7C8150
2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
3:0
64-bit addressing
R/O
Indicates 64-bit addressing
0000: 32-bit addressing
0001: 64-bit addressing
15:4
14.1.20
Prefetchable
Memory Base
Address [31:20]
R/W
Reset to 1
Defines the bottom address of an address range for the bridge to
determine when to forward memory read and write transactions from
one interface to the other. The upper 12 bits correspond to address
bits [31:20] and are writable. The lower 20 bits are assumed to be 0.
PREFETCHABLE MEMORY LIMIT REGISTER – OFFSET 24h
Bit
19:16
Function
64-bit addressing
Type
R/O
Description
Indicates 64-bit addressing
0000: 32-bit addressing
0001: 64-bit addressing
31:20
14.1.21
Prefetchable
Memory Limit
Address [31:20]
R/W
Reset to 1
Defines the top address of an address range for the bridge to
determine when to forward memory read and write transactions from
one interface to the other. The upper 12 bits correspond to address
bits [31:20] and are writable. The lower 20 bits are assumed to be
FFFFFh.
PREFETCHABLE MEMORY BASE ADDRESS UPPER 32-BITS
REGISTER – OFFSET 28h
Bit
31:0
Function
Prefetchable
Memory Base
Address, Upper
32-bits [63:32]
Type
R/W
Description
Defines the upper 32-bits of a 64-bit bottom address of an address
range for the bridge to determine when to forward memory read and
write transactions from one interface to the other.
Reset to 0
14.1.22
PREFETCHABLE MEMORY LIMIT ADDRESS UPPER 32-BITS
REGISTER – OFFSET 2Ch
Bit
31:0
Function
Prefetchable
Memory Limit
Address, Upper
32-bits [63:32]
Type
R/W
Description
Defines the upper 32-bits of a 64-bit top address of an address range
for the bridge to determine when to forward memory read and write
transactions from one interface to the other.
Reset to 0
14.1.23
I/O BASE ADDRESS UPPER 16-BITS REGISTER – OFFSET 30h
Bit
Function
Type
Description
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PI7C8150
2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
15:0
I/O Base
Address, Upper
16-bits [31:16]
R/W
Defines the upper 16-bits of a 32-bit bottom address of an address
range for the bridge to determine when to forward I/O transactions
from one interface to the other.
Reset to 0
14.1.24
I/O LIMIT ADDRESS UPPER 16-BITS REGISTER – OFFSET 30h
Bit
31:0
Function
I/O Limit
Address, Upper
16-bits [31:16]
Type
R/W
Description
Defines the upper 16-bits of a 32-bit top address of an address range
for the bridge to determine when to forward I/O transactions from
one interface to the other.
Reset to 0
14.1.25
ECP POINTER REGISTER – OFFSET 34h
Bit
7:0
14.1.26
Description
Enhanced capabilities port offset pointer. Read as DCh to indicate
that the first item resides at that configuration offset.
Function
Interrupt Line
Type
R/W
Description
For POST to program to FFh, indicating that the PI7C8150 does not
implement an interrupt pin.
INTERRUPT PIN REGISTER – OFFSET 3Ch
Bit
15:8
14.1.28
Type
R/O
INTERRUPT LINE REGISTER – OFFSET 3Ch
Bit
7:0
14.1.27
Function
Enhanced
Capabilities Port
Pointer
Function
Interrupt Pin
Type
R/O
Description
Interrupt pin not supported on the PI7C8150
BRIDGE CONTROL REGISTER – OFFSET 3Ch
Bit
16
Function
Parity Error
Response
Type
R/W
Description
Controls the bridge’s response to parity errors on the secondary
interface.
0: ignore address and data parity errors on the secondary interface
1: enable parity error reporting and detection on the secondary
interface
17
S_SERR_L
enable
R/W
Reset to 0
Controls the forwarding of S_SERR_L to the primary interface.
0: disable the forwarding of S_SERR_L to primary interface
1: enable the forwarding of S_SERR_L to primary interface
Reset to 0
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PI7C8150
2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
18
ISA enable
R/W
Modifies the bridge’s response to ISA I/O addresses, applying only
to those addresses falling within the I/O base and limit address
registers and within the first 64KB or PCI I/O space.
0: forward all I/O addresses in the range defined by the I/O base and
I/O limit registers
1: blocks forwarding of ISA I/O addresses in the range defined by the
I/O base and I/O limit registers that are in the first 64KB of I/O space
that address the last 768 bytes in each 1KB block. Secondary I/O
transactions are forwarded upstream if the address falls within the
last 768 bytes in each 1KB block
19
VGA enable
R/W
Reset to 0
Controls the bridge’s response to VGA compatible addresses.
0: does not forward VGA compatible memory and I/O
addresses from primary to secondary
1: forward VGA compatible memory and I/O addresses from
primary to secondary regardless of other settings
20
21
Reserved
Master Abort
Mode
R/O
R/W
Reset to 0
Reserved. Returns 0 when read. Reset to 0
Control’s bridge’s behavior responding to master aborts on
secondary interface.
0: does not report master aborts (returns FFFF_FFFFh on reads and
discards data on writes)
1: reports master aborts by signaling target abort if possible by the
assertion of P_SERR_L if enabled
22
Secondary
Interface Reset
R/W
Reset to 0
Controls the assertion of S_RESET_L signal pin on the secondary
interface
0: does not force the assertion of S_RESET_L pin
1: forces the assertion of S_RESET_L
23
Fast Back-toBack Enable
R/W
Reset to 0
Controls bridge’s ability to generate fast back-to-back transactions to
different devices on the secondary interface.
0: does not allow fast back-to-back transactions
1: enables fast back-to-back transactions
24
Primary Master
Timeout
R/W
Reset to 0
Set’s the maximum number of PCI clocks the bridge will wait for an
initiator on the primary to repeat a delayed transaction request. The
counter starts right after the delayed transaction is at the front of the
queue. If the master has not repeated at least once before the counter
expires, the bridge discards the transaction from the queue.
0: 2
15
PCI clocks
1: 2
10
PCI clocks
Reset to 0
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PI7C8150
2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
25
14.1.29
Secondary
Master Timeout
R/W
Set’s the maximum number of PCI clocks the bridge will wait for an
initiator on the secondary to repeat a delayed transaction request. The
counter starts right after the delayed transaction is at the front of the
queue. If the master has not repeated at least once before the counter
expires, the bridge discards the transaction from the queue.
0: 2
15
PCI clocks
1: 2
10
PCI clocks
26
Master Timeout
Status
R/WC
Reset to 0
This bit is set to 1 when either the primary master timeout counter or
secondary master timeout counter expires.
27
Discard Timer
P_SERR_L
enable
R/W
Reset to 0
This bit is set to 1 and P_SERR_L is asserted when either the
primary discard timer or the secondary discard timer expire.
31-28
Reserved
R/O
Reset to 0
Reserved. Returns 0 when read. Reset to 0.
DIAGNOSTIC / CHIP CONTROL REGISTER – OFFSET 40h
Bit
0
1
Function
Reserved
Memory Write
Disconnect
Control
Type
R/O
R/W
Description
Reserved. Returns 0 when read. Reset to 0
Controls when the bridge (as a target) disconnects memory write
transactions.
0: memory write disconnects at 4KB aligned address boundary
1: memory write disconnects at cache line aligned address boundary
3:2
4
Reserved
Secondary Bus
Prefetch Disable
R/O
R/W
Reset to 0
Reserved. Returns 0 when read. Reset to 0.
Controls the bridge’s ability to prefetch during upstream memory
read transactions.
0: The bridge prefetches and does not forward byte enable bits during
upstream memory reads.
1: The bridge requests only 1 DWORD from the target and forwards
read byte enable bits during upstream memory reads.
5
Live Insertion
Mode
R/W
Reset to 0
Enables hardware control of transaction forwarding.
0: GPIO[3] has no effect on the I/O, memory, and master enable bits
1: If GPIO[3] is set to input mode, this bit enables GPIO[3] to mask
I/O enable, memory enable and master enable bits to 0. PI7C8150
will stop accepting I/O and memory transactions as a result.
7:6
8
Reserved
Chip Reset
R/O
R/WR
Reset to 0
Reserved. Returns 0 when read. Reset to 0
Controls the chip and secondary bus reset.
0: PI7C8150 is ready for operation
1: Causes PI7C8150 to perform a chip reset
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PI7C8150
2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
10:9
Test Mode For
All Counters at P
and S1
R/O
Controls the testability of the bridge’s internal counters.
The bits are used for chip test only.
00: all bits are exercised
01: byte 1 is exercised
10: byte 2 is exercised
11: byte 3 is exercised
15:11
14.1.30
Reserved
R/O
Reset to 0
Reserved. Returns 0 when read. Reset to 0.
ARBITER CONTROL REGISTER – OFFSET 40h
Bit
24:16
Function
Arbiter Control
Type
R/W
Description
Each bit controls whether a secondary bus master is assigned to the
high priority group or the low priority group.
Bits [24:16] correspond to request inputs S_REQ_L[8:0]
respectively.
Bit 24 corresponds to S_REQ_L[8]
Bit 16 corresponds to S_REQ_L[0]
0: low priority
1: high priority
25
Priority of
Secondary
Interface
R/W
Reset to 0
Controls whether the secondary interface of the bridge is in the high
priority group or the low priority group.
0: low priority
1: high priority
31:26
14.1.31
Reserved
R/O
Reset to 1
Reserved. Returns 0 when read. Reset to 0.
EXTENDED CHIP CONTROL REGISTER – OFFSET 48h
Bit
Function
Type
0
Memory Read
Flow Through
Disable
R/W
Description
Controls ability to do memory read flow through
0: Enable flow through during a memory read transaction
1: Disables flow through during a memory read transaction
Reset to 0
Controls bus arbiter’s park function
0: Park to last master
1
Park
R/W
1: Park to bridge
15:2
Reserved
R/O
Reset to 0
Reserved. Returns 0 when read. Reset to 0
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PI7C8150
2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
14.1.32
14.1.33
UPSTREAM MEMORY CONTROL REGISTER – OFFSET 48h
Bit
Function
Type
Description
0: Upstream memory is the entire range except the down stream
memory channel
16
Upstream (S to
P) Memory Base
and Limit Enable
R/W
1: Upstream memory is confined to upstream Memory Base and
Limit (See offset 50th and 54th for upstream memory range)
31:17
Reserved
R/O
Reset to 0
Reserved. Returns 0 when read. Reset to 0
SECONDARY BUS ARBITER PREEMPTION CONTROL
REGISTER – OFFSET 4Ch
Bit
Function
Type
Description
Controls the number of clock cycles after frame is asserted before
preemption is enabled.
1xxx: Preemption off
0000: Preemption enabled after 0 clock cycles after FRAME asserted
0001: Preemption enabled after 1 clock cycle after FRAME asserted
31:28
Secondary bus
arbiter
preemption
contorl
0010: Preemption enabled after 2 clock cycles after FRAME asserted
R/W
0011: Preemption enabled after 4 clock cycles after FRAME asserted
0100: Preemption enabled after 8 clock cycles after FRAME asserted
0101: Preemption enabled after 16 clock cycles after FRAME
asserted
0110: Preemption enabled after 32 clock cycles after FRAME
asserted
0111: Preemption enabled after 64 clock cycles after FRAME
asserted
14.1.34
14.1.35
UPSTREAM (S TO P) MEMORY BASE REGISTER – OFFSET 50h
Bit
Function
Type
Description
0: 32 bit addressing
3:0
64 bit addressing
R/O
1: 64 bit addressing
15:4
Upstream
Memory Base
Address
Reset to 1
Controls upstream memory base address.
R/W
Reset to 00000000h
UPSTREAM (S TO P) MEMORY LIMIT REGISTER – OFFSET 50h
Bit
Function
Type
Description
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PI7C8150
2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
0: 32 bit addressing
14.1.36
19:16
64 bit addressing
31:20
Upstream
Memory Limit
Address
31:0
Reset to 1
Controls upstream memory limit address.
R/W
Reset to 000FFFFFh
Function
Upstream
Memory Base
Address
Type
Description
Defines bits [63:32] of the upstream memory base
R/W
Reset to 0
UPSTREAM (S TO P) MEMORY LIMIT UPPER 32-BITS
REGISTER – OFFSET 58h
Bit
31:0
14.1.38
1: 64 bit addressing
UPSTREAM (S TO P) MEMORY BASE UPPER 32-BITS REGISTER
– OFFSET 54h
Bit
14.1.37
R/O
Function
Upstream
Memory Limit
Address
Type
Description
Defines bits [63:32] of the upstream memory limit
R/W
Reset to 0
P_SERR_L EVENT DISABLE REGISTER – OFFSET 64h
Bit
0
Function
Reserved
Type
R/O
1
Posted Write
Parity Error
R/W
Description
Reserved. Returns 0 when read. Reset to 0
Controls PI7C8150’s ability to assert P_SERR_L when it is unable to
transfer any read data from the target after 224 attempts.
0: P_SERR_L is asserted if this event occurs and the SERR_L enable
bit in the command register is set.
1: P_SERR_L is not assert if this event occurs.
Reset to 0
Controls PI7C8150’s ability to assert P_SERR_L when it is unable to
transfer delayed write data after 224 attempts.
2
Posted Write
Non-Delivery
R/W
0: P_SERR_L is asserted if this event occurs and the SERR_L enable
bit in the command register is set
1: P_SERR_L is not asserted if this event occurs
Reset to 0
Controls PI7C8150’s ability to assert P_SERR_L when it receives a
target abort when attempting to deliver posted write data.
3
Target Abort
During Posted
Write
R/W
0: P_SERR_L is asserted if this event occurs and the SERR_L enable
bit in the command register is set
1: P_SERR_L is not asserted if this event occurs
Reset to 0
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Controls PI7C8150’s ability to assert P_SERR_L when it receives a
master abort when attempting to deliver posted write data.
4
Master Abort On
Posted Write
R/W
0: P_SERR# is asserted if this event occurs and the SERR# enable bit
in the command register is set
1: P_SERR# is not asserted if this event occurs
Reset to 0
Controls PI7C8150’s ability to assert P_SERR# when it is unable to
transfer delayed write data after 224 attempts.
5
Delayed Write
Non-Delivery
R/W
0: P_SERR_L is asserted if this event occurs and the SERR_L enable
bit in the command register is set
1: P_SERR_L is not asserted if this event occurs
Reset to 0
Controls PI7C8150’s ability to assert P_SERR_L when it is unable to
transfer any read data from the target after 224 attempts.
6
Delayed Read –
No Data From
Target
R/W
0: P_SERR_L is asserted if this event occurs and the SERR_L enable
bit in the command register is set
1: P_SERR_L is not asserted if this event occurs
7
14.1.39
Reserved
R/O
Reset to 0
Reserved. Returns 0 when read. Reset to 0
GPIO DATA AND CONTROL REGISTER – OFFSET 64h
Bit
Function
Type
11:8
GPIO Output
Write-1-to-Clear
R/WC
15:12
19:16
23:20
27:24
31:28
GPIO Output
Write-1-to-Set
GPIO Output
Enable Write-1to-Clear
GPIO Output
Enable Write-1to-Set
Reserved
GPIO Input Data
Register
R/WS
R/WC
R/WS
R
R/O
Description
Writing 1 to any of these bits drives the corresponding bit LOW on
the GPIO[3:0] bus if it is programmed as bidirectional. Data is
driven on the PCI clock cycle following completion of the
configuration write to this register. Bit positions corresponding to
GPIO pins that are programmed as input only are not driven. Writing
0 has no effect and will show last the last value written when read.
Reset to 0.
Writing 1 to any of these bits drives the corresponding bit HIGH on
the GPIO[3:0] bus if it is programmed as bidirectional. Data is
driven on the PCI clock cycle following completion of the
configuration write to this register. Bit positions corresponding to
GPIO pins that are programmed as input only are not driven. Writing
0 has no effect and will show last the last value written when read.
Reset to 0.
Writing 1 to and of these bits configures the corresponding
GPIO[3:0] pin as an input only. The output driver is tristated.
Writing 0 to this register has no effect and will reflect the last value
written when read.
Reset to 0.
Writing 1 to and of these bits configures the corresponding
GPIO[3:0] pin as bidirectional. The output driver is enabled and
drives the value set in the output data register (65h). Writing 0 to this
register has no effect and will reflect the last value written when read.
Reset to 0.
Reserved. Returns 0 when read. Reset to 0.
Reads the state of the GPIO[3:0] pins. The state is updated on the PCI
clock following a change in the GPIO[3:0] pins.
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14.1.40
14.1.41
SECONDARY CLOCK CONTROL REGISTER – OFFSET 68h
Bit
Function
Type
1:0
Clock 0 disable
R/W
3:2
Clock 1 disable
R/W
5:4
Clock 2 disable
R/W
7:6
Clock 3 disable
R/W
8
Clock 4 disable
R/W
9
Clock 5 disable
R/W
10
Clock 6 disable
R/W
11
Clock 7 disable
R/W
12
Clock 8 disable
R/W
13
Clock 9 disable
R/W
15:14
Reserved
RO
Description
If either bit is 0, then S_CLKOUT [0] is enabled.
If both bits are 1, then S_CLKOUT [0] is disabled.
If either bit is 0, then S_CLKOUT [1] is enabled.
If both bits are 1, then S_CLKOUT [1] is disabled.
If either bit is 0, then S_CLKOUT [2] is enabled.
If both bits are 1, then S_CLKOUT [2] is disabled.
If either bit is 0, then S_CLKOUT [3] is enabled.
If both bits are 1, then S_CLKOUT [3] is disabled.
If bit is 0, then S_CLKOUT [4] is enabled.
If bit is 1, then S_CLKOUT [4] is disabled and driven low.
If bit is 0, then S_CLKOUT [5] is enabled.
If bit is 1, then S_CLKOUT [5] is disabled and driven low.
If bit is 0, then S_CLKOUT [6] is enabled.
If bit is 1, then S_CLKOUT [6] is disabled and driven low.
If bit is 0, then S_CLKOUT [7] is enabled.
If bit is 1, then S_CLKOUT [7] is disabled and driven low.
If bit is 0, then S_CLKOUT [8] is enabled.
If bit is 1, then S_CLKOUT [8] is disabled and driven low.
If bit is 0, then S_CLKOUT [9] is enabled.
If bit is 1, then S_CLKOUT [9] is disabled and driven low.
Reserved. Returns 00 when read.
P_SERR_L STATUS REGISTER – OFFSET 68h
Bit
Function
Type
16
Address Parity
Error
R/WC
17
18
19
20
21
Posted Write
Data Parity Error
Posted Write
Non-delivery
R/WC
R/WC
Target Abort
during Posted
Write
R/WC
Master Abort
during Posted
Write
R/WC
Delayed Write
Non-delivery
R/WC
22
Delayed Read –
No Data from
Target
R/WC
23
Delayed
Transaction
Master Timeout
R/WC
Description
1: Signal P_SERR_L was asserted because an address parity error
was detected on P or S bus.
Reset to 0
1: Signal P_SERR_L was asserted because a posted write data parity
error was detected on the target bus.
Reset to 0
1: Signal P_SERR_L was asserted because the bridge was unable to
deliver post memory write data to the target after 224 attempts.
Reset to 0
1: Signal P_SERR_L was asserted because the bridge received a
target abort when delivering post memory write data.
Reset to 0.
1: Signal P_SERR_L was asserted because the bridge received a
master abort when attempting to deliver post memory write data
Reset to 0.
1: Signal P_SERR_L was asserted because the bridge was unable to
deliver delayed write data after 224 attempts.
Reset to 0
1: Signal P_SERR_L was asserted because the bridge was unable to
read any data from the target after 224 attempts.
Reset to 0.
1: Signal P_SERR_L was asserted because a master did not repeat a
read or write transaction before master timeout.
Reset to 0.
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ADVANCE INFORMATION
14.1.42
PORT OPTION REGISTER – OFFSET 74h
Bit
0
Function
Reserved
Type
R/O
1
Primary MEMR
Command Alias
Enable
R/W
Description
Reserved. Returns 0 when read. Reset to 0.
Controls PI7C8150’s detection mechanism for matching memory
read retry cycles from the initiator on the primary interface
0: exact matching for non-posted memory write retry cycles from
initiator on the primary interface
1: alias MEMRL or MEMRM to MEMR for memory read retry
cycles from the initiator on the primary interface
Reset to 0
Controls PI7C8150’s detection mechanism for matching non-posted
memory write retry cycles from the initiator on the primary interface
2
Primary MEMW
Command Alias
Enable
R/W
0: exact matching for non-posted memory write retry cycles from
initiator on the primary interface
1: alias MEMWI to MEMW for non-posted memory write retry
cycles from initiator on the primary interface
Reset to 0
Controls PI7C8150’s detection mechanism for matching memory
read retry cycles from the initiator on the secondary
3
Secondary
MEMR
Command Alias
Enable
R/W
0: exact matching for memory read retry cycles from initiator on the
secondary interface
1: alias MEMRL or MEMRM to MEMR for memory read retry
cycles from initiator on the secondary interface
Reset to 0
Controls PI7C8150’s detection mechanism for matching non-posted
memory write retry cycles from the initiator on the primary interface
Secondary
MEMW
Command Alias
Enable
R/W
8:5
Reserved
R/O
9
Enable Long
Request
R/W
4
0: exact matching for non-posted memory write retry cycles from
initiator on the secondary interface
1: alias MEMWI to MEMW for non-posted memory write retry
cycles from initiator on the secondary interface
Reset to 0
Reserved. Returns 0 when read. Reset to 0.
Controls PI7C8150’s ability to enable long requests for lock cycles
0: normal lock operation
1: enable long request for lock cycle
Reset to 0
Control’s PI7C8150’s ability to enable the secondary bus to hold
requests longer.
10
Enable
Secondary To
Hold Request
Longer
R/W
0: internal secondary master will release REQ_L after FRAME_L
assertion
1: internal secondary master will hold REQ_L until there is no
transactions pending in FIFO or until terminated by target
Reset to 1
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Control’s PI7C8150’s ability to hold requests longer at the Primary
Port.
11
15:12
14.1.43
14.1.44
Enable Primary
To Hold Request
Longer
R/W
Reserved
R/O
0: internal Primary master will release REQ_L after FRAME_L
assertion
1: internal Primary master will hold REQ_L until there is no
transactions pending in FIFO or until terminated by target
Reset to 1
Reserved. Returns 0 when read. Reset to 0.
RETRY COUNTER REGISTER – OFFSET 78h
Bit
Function
Type
31:0
Retry Counter
R/W
Description
Holds the maximum number of attempts that PI7C8150 will try
before reporting retry timeout. Retry count set at 224 PCI clocks.
Default is 0100 0000h.
PRIMARY MASTER TIMEOUT COUNTER – OFFSET 80h
Bit
Function
Type
15:0
Primary Timeout
R/W
Description
Primary timeout occurs after 215 PCI clocks.
Reset to 8000h.
14.1.45
14.1.46
SECONDARY MASTER TIMEOUT COUNTER – OFFSET 80h
Bit
Function
Type
31:16
Secondary
Timeout
R/W
Description
Secondary timeout occurs after 215 PCI clocks.
Reset to 8000h.
CAPABILITY ID REGISTER – OFFSET B0h
Bit
Function
Type
Description
Capability ID for slot identification
00h: Reserved
01h: PCI Power Management (PCIPM)
02h: Accelerated Graphics Port (AGP)
03h: Vital Product Data (VPD)
7:0
Capability ID
R/O
04h: Slot Identification (SI)
05h: Message Signaled Interrupts (MSI)
06h: Compact PCI Hot Swap (CHS)
07h – 255h: Reserved
Reset to 04h
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14.1.47
NEXT POINTER REGISTER – OFFSET B0h
Bit
Function
Type
15:8
Next Pointer
R/O
Description
Reset to 1100 0000: next pointer (C0h if HS_EN is 1)
0000 0000: next pointer (00h if HS_EN is 0)
14.1.48
14.1.49
14.1.50
SLOT NUMBER REGISTER – OFFSET B0h
Bit
Function
Type
20:16
Expansion Slot
Number
R/W
21
First in Chassis
R/W
23:22
Reserved
R/O
Bit
Function
Type
31:24
Chassis Number
Register
R/W
Reset to 0
Reserved. Returns 0 when read. Reset to 0.
Description
Chassis number register.
Reset to 0
CAPABILITY ID REGISTER – OFFSET DCh
7:0
Function
Enhanced
Capabilities ID
Type
R/O
Description
Read as 01h to indicate that these are power management enhanced
capability registers.
NEXT ITEM POINTER REGISTER – OFFSET DCh
Bit
15:8
14.1.52
Reset to 0
First in chassis
CHASSIS NUMBER REGISTER – OFFSET B0h
Bit
14.1.51
Description
Determines expansion slot number
Function
Next Item
Pointer
Type
R/O
Description
Points to slot number register (0Bh).
POWER MANAGEMENT CAPABILITIES REGISTER – OFFSET
DCh
Bit
19
Function
Power
Management
Revision
PME# Clock
R/O
20
Auxiliary Power
R/O
18:16
21
24:22
Device Specific
Initialization
Reserved
Type
R/O
R/O
R/O
Description
Read as 001 to indicate the device is compliant to Revision 1.0 of
PCI Power Management Interface Specifications.
Read as 0 to indicate PI7C8150 does not support the PME# pin.
Read as 0 to indicate PI7C8150 does not support the PME# pin or an
auxiliary power source.
Read as 0 to indicate PI7C8150 does not have device specific
initialization requirements.
Read as 0
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25
26
31:27
14.1.53
D1 Power State
Support
D2 Power State
Support
PME# Support
R/O
R/O
R/O
Read as 0 to indicate PI7C8150 does not support the D1 power
management state.
Read as 0 to indicate PI7C8150 does not support the D2 power
management state.
Read as 0 to indicate PI7C8150 does not support the PME# pin.
POWER MANAGEMENT DATA REGISTER – OFFSET E0h
Bit
Function
Type
1:0
Power State
R/W
Description
Indicates the current power state of PI7C8150. If an unimplemented
power state is written to this register, PI7C8150 completes the write
transaction, ignores the write data, and does not change the value of
the field. Writing a value of D0 when the previous state was D3
cause a chip reset without asserting S_RESET_L
00: D0 state
01: not implemented
10: not implemented
11: D3 state
7:2
8
12:9
14:13
15
14.1.54
Reserved
PME# Enable
Data Select
Data Scale
PME status
R/O
R/O
R/O
R/O
R/O
Reset to 0
Read as 0
Read as 0 as PI7C8150 does not support the PME# pin.
Read as 0 as the data register is not implemented.
Read as 0 as the data register is not implemented.
Read as 0 as the PME# pin is not implemented.
CAPABILITY ID REGISTER – OFFSET E4h
Bit
Function
Type
Description
00h: Reserved.
01h: PCI Power Management (PCIPM)
02h: Accelerated Graphics Port (AGP)
03h: Vital Product Data (VPD)
7:0
Capability ID
R/O
04h: Slot Identification (SI)
05h: Message Signaled Interrupts (MSI)
06h: Compact PCI Hot Swap
07h-255h: Reserved
14.1.55
NEXT POINTER REGISTER – OFFSET E4h
Bit
15:8
Function
Next Pointer
Type
R/O
Description
End of pointer (00h)
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2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
15
BRIDGE BEHAVIOR
A PCI cycle is initiated by asserting the FRAME_L signal. In a bridge, there are a number
of possibilities. Those possibilities are summarized in the table below:
15.1
BRIDGE ACTIONS FOR VARIOUS CYCLE TYPES
Initiator
Master on Primary
Target
Target on Primary
Master on Primary
Target on Secondary
Master on Primary
Target not on Primary nor
Secondary Port
Target on the same
Secondary Port
Target on Primary or the
other Secondary Port
Master on Secondary
Master on Secondary
Master on Secondary
Target not on Primary nor
the other Secondary Port
Response
PI7C8150 does not respond. It detects
this situation by decoding the address as
well as monitoring the P_DEVSEL_L for
other fast and medium devices on the
Primary Port.
PI7C8150 asserts P_DEVSEL_L,
terminates the cycle normally if it is able
to be posted, otherwise return with a retry.
It then passes the cycle to the appropriate
port. When the cycle is complete on the
target port, it will wait for the initiator to
repeat the same cycle and end with normal
termination.
PI7C8150 does not respond and the cycle
will terminate as master abort.
PI7C8150 does not respond.
PI7C8150 asserts S_DEVSEL_L,
terminates the cycle normally if it is able
to be posted, otherwise returns with a
retry. It then passes the cycle to the
appropriate port. When cycle is complete
on the target port, it will wait for the
initiator to repeat the same cycle and end
with normal termination.
PI7C8150 does not respond.
15.2
ABNORMAL TERMINATION (INITIATED BY BRIDGE
MASTER)
15.2.1
MASTER ABORT
Master abort indicates that when PI7C8150 acts as a master and receives no response (i.e.,
no target asserts DEVSEL_L or S_DEVSEL_L) from
a target, the bridge de-asserts FRAME_L and then de-asserts IRDY_L.
15.2.2
PARITY AND ERROR REPORTING
Parity must be checked for all addresses and write data. Parity is defined on the P_PAR,
and S_PAR signals. Parity should be even (i. e. an even number of‘1’s) across AD, CBE,
and PAR. Parity information on PAR is valid the cycle after AD and CBE are valid. For
reads, even parity must be generated using the initiators CBE signals combined with the
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2-PORT PCI-TO-PCI BRIDGE
ADVANCE INFORMATION
read data. Again, the PAR signal corresponds to read data from the previous data phase
cycle.
15.2.3
REPORTING PARITY ERRORS
For all address phases, if a parity error is detected, the error should be reported on the
P_SERR_L signal by asserting P_SERR_L for one cycle and then 3-stating two cycles
after the bad address. P_SERR_L can only be asserted if bit 6 and 8 in the Command
Register are both set to 1. For write data phases, a parity error should be reported by
asserting the P_PERR_L signal two cycles after the data phase and should remain asserted
for one cycle when bit 6 in the Command register is set to a 1.
The target reports any type of data parity errors during write cycles, while the master
reports data parity errors during read cycles.
Detection of an address parity error will cause the PCI-to-PCI Bridge target to not claim
the bus (P_DEVSEL_L remains inactive) and the cycle will then terminate with a Master
Abort. When the bridge is acting as master, a data parity error during a read cycle results in
the bridge master initiating a Master Abort.
15.2.4
SECONDARY IDSEL MAPPING
When PI7C8150 detects a Type 1 configuration transaction for a device connected to
the secondary, it translates the Type 1 transaction to Type 0 transaction on the downstream
interface. Type 1 configuration format uses a 5-bit field at P_AD[15:11] as a device
number. This is translated to S_AD[31:16] by PI7C8150.
16
IEEE 1149.1 COMPATIBLE JTAG CONTROLLER
An IEEE 1149.1 compatible Test Access Port (TAP) controller and associated TAP pins
are provided to support boundary scan in PI7C8150 for board-level continuity test and
diagnostics. The TAP pins assigned are TCK, TDI, TDO, TMS and TRST_L. All digital
input, output, input/output pins are tested except TAP pins.
The IEEE 1149.1 Test Logic consists of a TAP controller, an instruction register, and
a group of test data registers including Bypass and Boundary Scan registers. The TAP
controller is a synchronous 16-state machine driven by the Test Clock (TCK) and the Test
Mode Select (TMS) pins. An independent power on reset circuit is provided to ensure the
machine is in TEST_LOGIC_RESET state at power-up. The JTAG signal lines are not
active when the PCI resource is operating PCI bus cycles.
PI7C8150 implements 3 basic instructions: BYPASS, SAMPLE/PRELOAD, and
EXTEST.
16.1
BOUNDARY SCAN ARCHITECTURE
Boundary-scan test logic consists of a boundary-scan register and support logic. These are
accessed through a Test Access Port (TAP). The TAP provides a simple serial interface
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ADVANCE INFORMATION
that allows all processor signal pins to be driven and/or sampled, thereby providing direct
control and monitoring of processor pins at the system level.
This mode of operation is valuable for design debugging and fault diagnosis since it
permits examination of connections not normally accessible to the test system. The
following subsections describe the boundary-scan test logic elements: TAP pins,
instruction register, test data registers and TAP controller. Figure 16-1 illustrates how these
pieces fit together to form the JTAG unit.
Figure 16-1. Test Access Port Block Diagram
16.1.1
TAP PINS
The PI7C8150’s TAP pins form a serial port composed of four input connections (TMS,
TCK, TRST_L and TDI) and one output connection (TDO). These pins are described in
Table 16-1. The TAP pins provide access to the instruction register and the test data
registers.
16.1.2
INSTRUCTION REGISTER
The Instruction Register (IR) holds instruction codes. These codes are shifted in through
the Test Data Input (TDI) pin. The instruction codes are used to select the specific test
operation to be performed and the test data register to be accessed.
The instruction register is a parallel-loadable, master/slave-configured 5-bit wide, serialshift register with latched outputs. Data is shifted into and out of the IR serially through the
TDI pin clocked by the rising edge of TCK. The shifted-in instruction becomes active upon
latching from the master stage to the slave stage. At that time the IR outputs along with the
TAP finite state machine outputs are decoded to select and control the test data register
selected by that instruction. Upon latching, all actions caused by any previous instructions
terminate.
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The instruction determines the test to be performed, the test data register to be accessed, or
both. The IR is two bits wide. When the IR is selected, the most significant bit is connected
to TDI, and the least significant bit is connected to TDO. The value presented on the TDI
pin is shifted into the IR on each rising edge of TCK. The TAP controller captures fixed
parallel data (1101 binary). When a new instruction is shifted in through TDI, the value
1101(binary) is always shifted out through TDO, least significant bit first. This helps
identify instructions in a long chain of serial data from several devices.
Upon activation of the TRST_L reset pin, the latched instruction asynchronously changes
to the id code instruction. When the TAP controller moves into the test state other than by
reset activation, the opcode changes as TDI shifts, and becomes active on the falling edge
of TCK.
16.2
BOUNDARY SCAN INSTRUCTION SET
The PI7C8150 supports three mandatory boundary-scan instructions (BYPASS, SAMPLE
and EXTEST). The table shown below lists the PI7C8150’s boundary-scan instruction
codes.
Table 16-1. TAP Pins
Instruction
Requisite
EXTEST
IEEE 1149.1
Required
16.3
/
Opcode (binary)
00000
SAMPLE
IEEE 1149.1
Required
0001
INTSCAN
CLAMP
00010
00100
BYPASS
11111
Description
EXTEST initiates testing of external circuitry, typically boardlevel interconnects and off chip circuitry. EXTEST connects the
boundary-scan register between TDI and TDO. When EXTEST
is selected, all output signal pin values are driven by values
shifted into the boundary-scan register and may change only of
the falling edge of TCK. Also, when EXTEST is selected, all
system input pin states must be loaded into the boundary-scan
register on the rising-edge of TCK.
SAMPLE performs two functions:
!
A snapshot of the sample instruction is captured on the
rising edge of TCK without interfering with normal
operation. The instruction causes boundary-scan register
cells associated with outputs to sample the value being
driven.
!
On the falling edge of TCK, the data held in the boundaryscan cells is transferred to the slave register cells.
Typically, the slave latched data is applied to the system
outputs via the EXTEST instruction.
Enable internal SCAN test
CLAMP instruction allows the state of the signals driven from
component pins to be determined from the boundary-scan
register while the bypass register is selected as the serial path
between TDI and TDO. The signal driven from the component
pins will not change while the CLAMP instruction is selected.
BYPASS instruction selects the one-bit bypass register between
TDI and TDO pins. 0 (binary) is the only instruction that
accesses the bypass register. While this instruction is in effect,
all other test data registers have no effect on system operation.
Test data registers with both test and system functionality
performs their system functions when this instruction is selected.
TAP TEST DATA REGISTERS
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ADVANCE INFORMATION
The PI7C8150 contains two test data registers (bypass and boundary-scan). Each test data
register selected by the TAP controller is connected serially between TDI and TDO. TDI is
connected to the test data register’s most significant bit. TDO is connected to the least
significant bit. Data is shifted one bit position within the register towards TDO on each
rising edge of TCK. While any register is selected, data is transferred from TDI to TDO
without inversion. The following sections describe each of the test data registers.
16.4
BYPASS REGISTER
The required bypass register, a one-bit shift register, provides the shortest path between
TDI and TDO when a bypass instruction is in effect. This allows rapid movement of test
data to and from other components on the board. This path can be selected when no test
operation is being performed on the PI7C8150.
16.5
BOUNDARY-SCAN REGISTER
The boundary-scan register contains a cell for each pin as well as control cells for I/O and
the high-impedance pin.
Table 16-2 shows the bit order of the PI7C8150 boundary-scan register. All table cells that
contain “Control” select the direction of bi-directional pins or high-impedance output pins.
When a “1” is loaded into the control cell, the associated pin(s) are high-impedance or
selected as output.
The boundary-scan register is a required set of serial-shiftable register cells, configured in
master/slave stages and connected between each of the PI7C8150’s pins and on-chip
system logic. The VDD, GND, and JTAG pins are NOT in the boundary-scan chain.
The boundary-scan register cells are dedicated logic and do not have any system function.
Data may be loaded into the boundary-scan register master cells from
the device input pins and output pin-drivers in parallel by the mandatory SAMPLE and
EXTEST instructions. Parallel loading takes place on the rising edge of TCK.
Data may be scanned into the boundary-scan register serially via the TDI serial input pin,
clocked by the rising edge of TCK. When the required data has been loaded into the
master-cell stages, it can be driven into the system logic at input pins or onto the output
pins on the falling edge of TCK state. Data may also be shifted out of the boundary-scan
register by means of the TDO serial output pin at the falling edge of TCK.
16.6
TAP CONTROLLER
The TAP (Test Access Port) controller is a 4-state synchronous finite state machine that
controls the sequence of test logic operations. The TAP can be controlled via a bus master.
The bus master can be either automatic test equipment or a component (i.e., PLD) that
interfaces to the TAP. The TAP controller changes state only in response to a rising edge of
TCK. The value of the test mode state (TMS) input signal at a rising edge of TCK controls
the sequence of state changes. The TAP controller is initialized after power-up by applying
a low to the TRST_L pin. In addition, the TAP controller can be initialized by applying a
high signal level on the TMS input for a minimum of five TCK periods.
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For greater detail on the behavior of the TAP controller, test logic in each controller state
and the state machine and public instructions, refer to the IEEE 1149.1 Standard Test
Access Port and Boundary-Scan Architecture document (available from the IEEE).
Table 16-2. JTAG Boundary Register Order
Boundary-Scan
Register Number
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
Pin Name
Pin Number
Type
S_AD[0]
S_AD[1]
S_AD[2]
S_AD[3]
S_AD[4]
S_AD[5]
S_AD[6]
S_AD[7]
S_CBE[0]
S_AD[8]
S_AD[9]
S_M66EN
S_AD[10]
S_AD[11]
S_AD[12]
S_AD[13]
S_AD[14]
S_AD[15]
137
138
140
141
143
144
146
147
149
150
152
153
154
159
161
162
164
165
S_CBE[1]
S_PAR
S_SERR_L
S_PERR_L
S_LOCK_L
S_STOP_L
167
168
169
171
172
173
S_DEVSEL_L
S_TRDY_L
S_IRDY_L
S_FRAME_L
S_CBE[2]
S_AD[16]
S_AD[17]
S_AD[18]
S_AD[19]
S_AD[20]
S_AD[21]
S_AD[22]
S_AD[23]
S_CBE[3]
S_AD[24]
S_AD[25]
S_AD[26]
S_AD[27]
S_AD[28]
S_AD[29]
S_AD[30]
175
176
177
179
180
182
183
185
186
188
189
191
192
194
195
197
198
200
201
203
204
S_AD[31]
S_REQ_L[0]
S_REQ_L[1]
S_REQ_L[2]
S_REQ_L[3]
S_REQ_L[4]
S_REQ_L[5]
206
207
2
3
4
5
6
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
OUTPUT
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
CONTROL
BIDIR
BIDIR
INPUT
BIDIR
BIDIR
BIDIR
CONTROL
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
CONTROL
BIDIR
INPUT
INPUT
INPUT
INPUT
INPUT
INPUT
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Boundary-Scan
Register Number
55
56
57
58
59
60
61
62
63
64
65
66
67
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
103
104
105
106
107
108
109
110
111
112
113
114
115
116
Pin Name
Pin Number
Type
S_REQ_L[6]
S_REQ_L[7]
S_REQ_L[8]
S_GNT_L[0]
S_GNT_L[1]
7
8
9
10
11
S_GNT_L[2]
S_GNT_L[3]
S_GNT_L[4]
S_GNT_L[5]
S_GNT_L[6]
S_GNT_L[7]
S_GNT_L[8]
S_CLKIN
S_RESET_L
S_CFN_L
GPIO[3]
GPIO[2]
GPIO[1]
GPIO[0]
S_CLKOUT[0]
S_CLKOUT[1]
13
14
15
16
17
18
19
21
22
23
24
25
27
28
29
30
S_CLKOUT[2]
S_CLKOUT[3]
S_CLKOUT[4]
S_CLKOUT[5]
S_CLKOUT[6]
S_CLKOUT[7]
S_CLKOUT[8]
S_CLKOUT[9]
P_RESET_L
BPCCE
P_CLK
P_GNT_L
P_REQ_L
32
33
35
36
38
39
41
42
43
44
45
46
47
P_AD[31]
P_AD[30]
P_AD[29]
P_AD[28]
P_AD[27]
P_AD[26]
P_AD[25]
P_AD[24]
P_CBE[3]
P_IDSEL
P_AD[23]
P_AD[22]
P_AD[21]
P_AD[20]
P_AD[19]
P_AD[18]
P_AD[17]
P_AD[16]
49
50
55
57
58
60
61
63
64
65
67
68
70
71
73
74
76
77
P_CBE[2]
P_FRAME_L
P_IRDY_L
P_TRDY_L
P_DEVSEL_L
P_STOP_L
79
80
82
83
84
85
INPUT
INPUT
INPUT
OUTPUT
OUTPUT
CONTROL
OUTPUT
OUTPUT
OUTPUT
OUTPUT
OUTPUT
OUTPUT
OUTPUT
INPUT
OUTPUT
INPUT
BIDIR
BIDIR
BIDIR
BIDIR
OUTPUT
OUTPUT
CONTROL
OUTPUT
OUTPUT
OUTPUT
OUTPUT
OUTPUT
OUTPUT
OUTPUT
OUTPUT
INPUT
INPUT
INPUT
INPUT
OUTPUT
CONTROL
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
INPUT
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
CONTROL
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
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Boundary-Scan
Register Number
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
Pin Name
Pin Number
P_LOCK_L
P_PERR_L
P_SERR_L
P_PAR
P_CBE[1]
P_AD[15]
P_AD[14]
P_AD[13]
P_AD[12]
P_AD[11]
P_AD[10]
P_M66EN
P_AD[9]
P_AD[8]
P_CBE[0]
P_AD[7]
P_AD[6]
P_AD[5]
P_AD[4]
P_AD[3]
P_AD[2]
P_AD[1]
P_AD[0]
87
88
89
90
92
93
95
96
98
99
101
102
107
109
110
112
113
115
116
118
119
121
122
CFG66
MSK_IN
125
126
Type
CONTROL
INPUT
BIDIR
OUTPUT
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
INPUT
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
BIDIR
CONTROL
INPUT
INPUT
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17
ELECTRICAL AND TIMING SPECIFICATIONS
17.1
MAXIMUM RATINGS
(Above which the useful life may be impaired. For user guidelines, not tested).
Storage Temperature
Ambient Temperature with Power Applied
Supply Voltage to Ground Potentials (AVCC and VDD only]
Voltage at Input Pins
-65°C to 150°C
0°C to 85°C
-0.3V to 3.6V
-0.5V to 5.5V
Note:
Stresses greater than those listed under MAXIMUM RATINGS may cause permanent
damage to the device. This is a stress rating only and functional operation of the device at
these or any conditions above those indicated in the operational sections of this
specification is not implied. Exposure to absolute maximum rating conditions for extended
periods of time may affect reliability.
17.2
DC SPECIFICATIONS
Symbol
VDD,
AVCC
Vih
Vil
Vih
Vil
Vipu
Iil
Voh
Vol
Voh
Vol
Cin
CCLK
CIDSEL
Lpin
Parameter
Supply Voltage
Condition
Input HIGH Voltage
Input LOW Voltage
CMOS Input HIGH Voltage
CMOS Input LOW Voltage
Input Pull-up Voltage
Input Leakage Current
Output HIGH Voltage
Output LOW Voltage
CMOS Output HIGH Voltage
CMOS Output LOW Voltage
Input Pin Capacitance
CLK Pin Capacitance
IDSEL Pin Capacitance
Pin Inductance
0 < Vin < VDD
Iout = -500µA
Iout = 1500µA
Iout = -500µA
Iout = 1500µA
Min.
3
Max.
3.6
Units
V
Notes
0.5 VDD
-0.5
0.7 VDD
-0.5
0.7 VDD
VDD + 0.5
0.3 VDD
VDD + 0.5
0.3 VDD
V
V
V
V
V
µA
V
V
V
V
pF
pF
pF
nH
3, 4
3, 4
1, 4
1, 4
3
3
3
3
2
2
3
3
3
3
±10
0.9VDD
0.1 VDD
VDD – 0.5
5
0.5
10
12
8
20
Notes:
1. CMOS Input pins: S_CFN_L, TCK, TMS, TDI, TRST_L, SCAN_EN, SCAN_TM_L
2. CMOS Output pin: TDO
3. PCI pins: P_AD[31:0], P_CBE[3:0], P_PAR, P_FRAME_L, P_IRDY_L, P_TRDY_L,
P_DEVSEL_L, P_STOP_L, P_LOCK_L, PIDSEL_L, P_PERR_L, P_SERR_L,
P_REQ_L, P_GNT_L, P_RESET_L, S_AD[31:0], S_CBE[3:0], S_PAR, S_FRAME_L,
S_IRDY_L, S_TRDY_L, S_DEVSEL_L, S_STOP_L, S_LOCK_L, S_PERR_L,
S_SERR_L, S_REQ[7:0]_L, S_GNT[7:0]_L, S_RESET_L, S_EN, HSLED, HS_SW_L,
HS_EN, ENUM_L.
4. VDD is in reference to the VDD of the input device.
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17.3
AC SPECIFICATIONS
Figure 17-1. PCI Signal Timing Measurement Conditions
Symbol
Tsu
Tsu(ptp)
Th
Tval
Tval(ptp)
Ton
Toff
Parameter
Input setup time to CLK – bused signals 1,2,3
Input setup time to CLK – point-to-point 1,2,3
Input signal hold time from CLK 1,2
CLK to signal valid delay – bused signals 1,2,3
CLK to signal valid delay – point-to-point 1,2,3
Float to active delay 1,2
Active to float delay 1,2
66 MHz
Min.
Max.
3
5
0
2
6
2
6
2
14
33 MHz
Min.
Max.
7
10, 124
0
2
11
2
12
2
28
Units
ns
1. See Figure 17-1 PCI Signal Timing Measurement Conditions.
2. All primary interface signals are synchronized to P_CLK. All secondary interface
signals are synchronized to S_CLKOUT.
3. Point-to-point signals are P_REQ_L, S_REQ_L[7:0], P_GNT_L, S_GNT_L[7:0],
HSLED, HS_SW_L, HS_EN, and ENUM_L. Bused signals are P_AD, P_BDE_L, P_PAR,
P_PERR_L, P_SERR_L, P_FRAME_L, P_IRDY_L, P_TRDY_L, P_LOCK_L,
P_DEVSEL_L, P_STOP_L, P_IDSEL, S_AD, S_CBE_L, S_PAR, S_PERR_L,
S_SERR_L, S_FRAME_L, S_IRDY_L, S_TRDY_L, S_LOCK_L, S_DEVSEL_L, and
S_STOP_L.
4. REQ_L signals have a setup of 10 and GNT_L signals have a setup of 12.
17.4
66MHZ TIMING
Symbol
TSKEW
TDELAY
TCYCLE
THIGH
TLOW
Parameter
SKEW among S_CLKOUT[9:0]
DELAY between PCLK and S_CLKOUT[9:0]
P_CLK, S_CLKOUT[9:0] cycle time
P_CLK, S_CLKOUT[9:0] HIGH time
P_CLK, S_CLKOUT[9:0] LOW time
Condition
20pF load
Min.
0
4.6
15
6
6
Max.
0.250
5.5
30
Units
ns
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2-PORT PCI-TO-PCI BRIDGE
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17.5
33MHZ TIMING
Symbol
TSKEW
TDELAY
TCYCLE
THIGH
TLOW
17.6
Parameter
SKEW among S_CLKOUT[9:0]
DELAY between PCLK and S_CLKOUT[9:0]
P_CLK, S_CLKOUT[9:0] cycle time
P_CLK, S_CLKOUT[9:0] HIGH time
P_CLK, S_CLKOUT[9:0] LOW time
Condition
20pF load
Min.
0
4.6
30
11
11
Max.
0.250
5.5
Units
ns
POWER CONSUMPTION
Parameter
Power Consumption at 66MHz
Supply Current, ICC
Typical
1.39
420
Units
W
mA
18
PACKAGE INFORMATION
18.1
208-PIN FQFP PACKAGE DIAGRAM
Figure 18-1. 208-pin FQFP Package Outline
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18.2
256-BALL PBGA PACKAGE DIAGRAM
Figure 18-2. 256-ball PBGA Package Outline
Thermal characteristics can be found on the web: http://www.pericom.com/packaging/mechanicals.php
18.3
PART NUMBER ORDERING INFORMATION
Part Number
PI7C8150MA
PI7C8150MA-33
PI7C8150ND
PI7C8150ND-33
Speed
66MHz
33MHz
66MHz
33MHz
Pin – Package
208 – FQFP
208 – FQFP
256 – PBGA
256 – PBGA
Temperature
0°C to 85°C
0°C to 85°C
0°C to 85°C
0°C to 85°C
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NOTES:
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ADVANCE INFORMATION
NOTES:
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ADVANCE INFORMATION
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