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OR3LP26BM680I
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AGERE OR3LP26BA352C, OR3LP26BM680I, OR3LP26BM680C, OR3LP26BA352I Datasheet

Data Sheet March 2000
ORCA
®
OR3LP26B Field-Programmable System Chip (FPSC
)
Embedded Master/Target PCI Interface
Introduction
Lucent Technologies Microelectronics Group has developed a solution for designers who need the many advantages of an FPGA-based design imple­mentation, coupled with the high bandwidth of an industry-standard PCI interface. The
ORCA
OR3LP26B (a member of the Series 3+ FPSC family) provides a full-featured 33/50/66 MHz, 32-/64-bit PCI interface, fully designed and tested, in hardware, plus FPGA logic for user-programmable functions.
PCI Bus Core Highlights
Implemented in an
ORCA
Series 3 OR3L125B base array, displacing the bottom ten rows of 28 columns.
Core is a well-tested ASIC model.
Fully compliant to Revision 2.2 of PCI Local Bus specification.
Operates at PCI bus speeds up to 66 MHz on a 32-/64-bit wide bus.
Comprises two independent controllers for Master and Target.
Meets/exceeds all requirements for
PICMG
*
Hot
Swap friendly silicon, full Hot Swap model, per the
CompactPCI
*
Hot Swap specification,
PICMG
2.1
R1.0.
PCI SIG Hot Plug (R1.0) compliant.
Four internal FIFOs individually buffer both direc­tions of both the Master and Target interfaces: — Both Master FIFOs are 64 bits wide by 32 bits
deep.
— Both Target FIFOs are 64 bits wide by 16 bits
deep.
Capable of no-wait-state, full-burst PCI transfers in either direction, on either the Master or Target interface. The dual 64-bit data paths extend into the FPGA logic, permitting full-bandwidth, simulta­neous bidirectional data transfers of up to 528 Mbytes/s to be sustained indefinitely.
Can be configured to provide either two 64-bit buses (one in each direction) to be multiplexed between Master and Target, or four independent 32-bit buses.
Provides many hardware options in the PCI core that are set during FPGA logic configuration.
Operates within the requirements of the PCI 5 V and 3.3 V signaling environments and 3.3 V com­mercial environmental conditions, allowing the same device to be used in 5 V or 3.3 V PCI sys­tems.
FPGA is reconfigurable via the PCI interface's con­figuration space (as well as conventionally), allow­ing the FPGA to be field-updated to meet late­breaking requirements of emerging protocols.
*
PICMG
and
CompactPCI
are registered trademarks of the PCI
Industrial Computer Manufacturers Group.
Table 1.
ORCA
OR3LP26B PCI FPSC Solution—Available FPGA Logic
†The embedded core and interface comprise approximately 85K standard-cell ASIC gates in addition to these usable gates. The usable
gate counts range from a logic-only gate count to a gate count assuming 30% of the PFUs/SLICs being used as RAMs. The logic-only gate count includes each PFU/SLIC (counted as 108 gates per PFU/SLIC), including 12 gates per LUT/FF pair (eight per PFU), and 12 gates per SLIC/FF pair (one per PFU). Each of the four PIOs per PIC is counted as 16 gates (two FFs, fast-capture latch, output logic, CLK drivers, and I/O buffers). PFUs used as RAM are counted at four gates per bit, with each PFU capable of implementing a 32 x 4 RAM (or 512 gates) per PFU.
Device Usable Gates
Number of
LUTs
Number of
Registers
Max User
RAM
Max User
I/Os
Array
Size
Number of
PFUs
OR3LP26B 60K—120K 4032 5304 64K 259 18 x 28 504
Table of Contents
Contents Page Contents Page
ORCA
OR3LP26B FPSC Data Sheet
Embedded Master/Target PCI Interface March 2000
2 Lucent Technologies Inc.
Introduction ..........................................................................1
PCI Bus Core Highlights ......................................................1
Figures .................................................................................2
Tables ..................................................................................3
FPSC Highlights ...................................................................5
Software Support .................................................................6
Description ...........................................................................7
What Is an FPSC? ............................... ...... ...... ..... ...... ......7
FPSC Overview .......................................... ...... ..... ...... ......7
FPSC Gate Counting ........................................................7
FPGA/Embedded Core Interface ......................................7
ORCA
Foundry Development System ..............................7
FPSC Design Kit ...............................................................8
FPGA Logic Overview .......................................................8
PLC Logic ..........................................................................8
PIC Logic .............................................. .............................9
System Features ...............................................................9
Routing ..............................................................................9
Configuration .....................................................................9
Boundary Scan ..................................................................9
More Series 3 Information .................................................9
OR3LP26B Overview .........................................................10
Device Layout ............................................................. ....10
PCI Local Bus ................................. ..... ...........................10
OR3LP26B PCI Bus Core Overview ...............................12
PCI Bus Interface ............................................................12
Embedded Core Options/FPGA Configuration ...............13
PCI Bus Core Detailed Description ....................................14
PCI Bus Commands .............................................. ...... ....14
PCI Protocol Fundamentals ............................. ...............16
FIFO Memories and Control ............................................17
PCI Bus Pin Information ............................. .....................18
PCI Bus Core Detailed Description Dual Port ....................21
Embedded Core/FPGA Interface Signal Descriptions ....21
Embedded Core/FPGA Interface Signal Locations .........27
Embedded Core Bit Stream Configurable Options .........32
Understanding FIFO Packing/Unpacking ........................33
Embedded Core/FPGA Interface Operation ...................34
Embedded Core/FPGA Interface Operation Summary ...35
Master (FPGA Initiated) Write .........................................36
Master (FPGA Initiated) Read .........................................42
Target (PCI Bus Initiated) Write ......................................49
Target (PCI Bus Initiated) Read ......................................58
PCI Bus Core Detailed Description Quad Port ...................70
Embedded Core/FPGA Interface Signal Descriptions ....70
Embedded Core/FPGA Interface Signal Locations .........76
Embedded Core Bit Stream Configurable Options .........83
Understanding FIFO Packing/Unpacking ........................84
Embedded Core/FPGA Interface Operation ...................86
Embedded Core/FPGA Interface Operation Summary ...87
Master (FPGA Initiated) Write .........................................88
Master (FPGA Initiated) Read .........................................94
Target (PCI Bus Initiated) Write ....................................101
Target (PCI Bus Initiated) Read ....................................110
Configuration Space of the PCI Core ...............................123
PCI Bus Configuration Space Organization ..................123
FPSC Configuration ................................... ...... ..... ...... .....126
Configuration via PCI Bus .............................................126
Readback via PCI interface ..........................................127
Interaction Among Configurat io n Modes ......................127
Clocking Options at FPGA/Core Boundary ..................... 128
PCI Clock as System Clock ..........................................128
Local Clock as System Clock .......................................128
FPGA Configuration Data Format ...................................130
Using
ORCA
Foundry to Generate Configuration
RAM Data ...................................................................130
FPGA Configuration Data Frame ..................................130
Bit Stream Error Checking ...............................................132
FPGA Configuration Modes .............................................132
Powerup Sequencing for Series OR3LP26B Device .......133
Absolute Maximum Ratings .............................................133
Recommended Operating Conditi ons .............................134
Electrical Characteristics .................................................135
Timing Characteristics .....................................................136
Description ....................................................................136
Clock Timing .................................................................137
Input/Output Buffer Measurement Conditions ................. 148
Output Buffer Characteristics ..........................................149
Estimating Power Dissipation ..........................................150
Pin Information ................................................................151
Package Compatibility ..................................................154
Package Thermal Characteristics Summary ................... 178
Θ
JA ............................................................................... 178
ψ
JC ............................................................................... 178
Θ
JC ...............................................................................178
Θ
JB ............................................................................... 178
FPGA Maximum Junction Temperature .......................178
Package Coplanarity .......................................................179
Package Parasitics ..........................................................180
Package Outline Diagrams ..............................................181
Terms and Definitions ...................................................181
352-Pin PBGA ..............................................................182
680-Pin PBGA ..............................................................183
Ordering Information ........................................................184
Figures
Figure 1. ORCA OR3LP26B PCI FPSC
Block Diagram...............................................................13
Figure 2. Master Write Single (FPGA Bus, Dual-Port).....38
Figure 3. Master Write Single (PCI Bus, 64-Bit)..............39
Figure 4. Master Write 32-Byte Burst
(FPGA Bus, Dual-Port) .................................................40
Figure 5. Master Write 32-Byte Burst (PCI Bus, 64-Bit)..41 Figure 6. Master Read Single (FPGA Bus, Dual-Port,
Specified Burst Length, 64-Bit Address).......................44
Figure 7. Master Read Single (PCI Bus, 64-Bit)..............45
Figure 8. Master Read 32-Byte Burst (FPGA Bus,
Dual-Port, Burst Length, and 64-Bit Address)..............46
Figure 9. Master Read 32-Byte Burst
(PCI Bus, 64-Bit)...........................................................47
Lucent Technologies Inc. 3
Lucent Technologies Inc.
Table of
Contents
(continued)
Contents Page Contents Page
Data Sheet
ORCA
OR3LP26B FPSC
Marc h 2000 Embedded Master/Target PCI Inte rface
Figure 10. Target Configuration Write
(PCI Bus, 64-Bit)...........................................................52
Figure 11. Target I/O Write, Delayed (PCI Bus, 64-Bit) ...53 Figure 12. Target Write Memory Single
(PCI Bus, 64-Bit)...........................................................54
Figure 13. Target Write Single (FPGA Bus, Dual-Port)....55
Figure 14. Target Memory Write 32-Byte Burst
(PCI Bus, 64-Bit)...........................................................56
Figure 15. Target Write Memory 32-Byte Burst
(FPGA Bus, Dual-Port) ....................................... ...... ....57
Figure 16. Target Configuration Read
(PCI Bus, 64-Bit)...........................................................61
Figure 17. Target I/O Read, Delayed (PCI Bus, 64-Bit)...62 Figure 18. Target I/O Read, Not Delayed
(PCI Bus, 64-Bit)...........................................................63
Figure 19. Target Memory Single Read, Delayed
(PCI Bus, 64-Bit)...........................................................64
Figure 20. Target Read Single (FPGA Bus, Dual-Port)....65
Figure 21. Target Memory Read Single, Not Delayed
(PCI Bus, 64-Bit)...........................................................66
Figure 22. Target Memory Read 32-Byte Burst, Delayed
(PCI Bus, 64-Bit)...........................................................67
Figure 23. Target Read Memory 32-Byte Burst
(FPGA, Dual-Port) ........................................................68
Figure 24. Target Read Memory Burst, No Delayed
(PCI Bus, 32-Bit)...........................................................69
Figure 25. Master Write Single (PCI Bus, 64-Bit)............90
Figure 26. Master Write 32-Byte Burst
(PCI Bus, 64-Bit)...........................................................91
Figure 27. Master Write Single Quadword
(FPGA Bus, Quad-Port, 64-Bit Address)......................92
Figure 28. Master Write 32-Byte Burst
(FPGA Bus, Quad-Port, 64-Bit Address)......................93
Figure 29. Master Read Single (PCI Bus, 64-Bit)............96
Figure 30. Master Read Single Quadword (FPGA Bus,
Quad-Port, Specified Burst Length, 32-Bit Address) ....97
Figure 31. Master Read 32-Byte Burst
(PCI Bus, 64-Bit)...........................................................98
Figure 32. Master Read 32-Byte Burst (FPGA Bus,
Quad-Port, Specified Burst Length, 32-Bit Address) ....99
Figure 33. Target Configuration Write
(PCI Bus, 64-Bit)...........................................................104
Figure 34. Target I/O Write, Delayed (PCI Bus, 64-Bit) ...105 Figure 35. Target Write Memory Single
(PCI Bus, 64-Bit)...........................................................106
Figure 36. Target Write Single Quadword
(FPGA Bus, Quad-Port, 64-Bit Address)......................107
Figure 37. Target Memory Write 32-Byte Burst
(PCI Bus, 64-Bit)...........................................................108
Figure 38. Target Write Memory 32-Byte Burst
(FPGA Bus, Quad-Port, 32-Bit Address)......................109
Figure 39. Target Configuration Read
(PCI Bus, 64-Bit)...........................................................113
Figure 40. Target I/O Read, Delayed
(PCI Bus, 64-Bit)...........................................................114
Figure 41. Target I/O Read, Not Delayed
(PCI Bus, 64-Bit) ......................................................... .115
Figure 42. Target Memory Single Read, Delayed
(PCI Bus, 64-Bit) ......................................................... .116
Figure 43. Target Read Single (FPGA Bus, Quad-Port,
64-Bit Address).............................................................1 17
Figure 44. Target Memory Read Single, Not Delayed
(PCI Bus, 64-Bit) ......................................................... .118
Figure 45. Target Memory Read 32-Byte Burst, Delayed
(PCI Bus, 64-Bit) ......................................................... .119
Figure 46. Target Read Memory 32-Byte Burst
(FPGA Bus, Quad-Port, 32-Bit Address)......................120
Figure 47. Target Read Memory Burst, No Delayed
(PCI Bus, 32-Bit) ......................................................... .121
Figure 48. FPSC Block Diagram and Clock Network......129
Figure 49. Serial Configuration Data Format—
Autoincrement Mode....................................................131
Figure 50. Serial Configuration Data Format—
Explicit Mode................................................................131
Figure 51. ExpressCLK to Output Delay.........................138
Figure 52. Fast Clock to Output Delay ............................139
Figure 53. System Clock to Output Delay.......................140
Figure 54. Input to ExpressCLK Setup/Hold Time..........141
Figure 55. Input to Fast Clock Setup/Hold Time..............142
Figure 56. Input to System Clock Setup/Hold Time........143
Figure 57. ac Test Loads.................................................148
Figure 58. Output Buffer Delays......................................148
Figure 59. Input Buffer Delays.........................................148
Figure 60. Sinklim (TJ = 25 °C, VDD = 3.3 V).................149
Figure 61. Slewlim (TJ = 25 °C, VDD = 3.3 V)................149
Figure 62. Fast (TJ = 25 °C, VDD = 3.3 V)......................149
Figure 63. Sinklim (TJ = 125 °C, VDD = 3.0 V)...............149
Figure 64. Slewlim (TJ = 125 °C, VDD = 3.0 V)..............149
Figure 65. Fast (TJ = 125 °C, VDD = 3.0 V)....................149
Figure 66. Package Parasitics.........................................180
Tables
Table 1. ORCA OR3LP26B PCI FPSC Solution—
Available FPGA Logic...................................................1
Table 2. PCI Local Bus Data Rates................................10
Table 3. OR3LP26B Array..............................................11
Table 4. PCI Bus Command Descriptions......................14
Table 5. Timing Budgets.................................................17
Table 6. FIFO Flags Provided to FPGA Application.......18
Table 7. PCI Bus Pin Descriptions..................................18
Table 8. Embedded Core/FPGA Interface Signals.........21
Table 9. OR3LP26B FPGA/PCI Core Interface Signal
Locations......................................................................27
Table 10. Bit Definitions on FPGA/PCI Core Interface...30 Table 11. Address Cycle Sequences for Various
Operations ................................................................... 31
Table 12. PCI Core Options Settable via FPGA
Configuration RAM Bits................................................32
Table of
Contents
(continued)
Contents Page Contents Page
ORCA
OR3LP26B FPSC Data Sheet
Embedded Master/Target PCI Interface March 2000
4 Lucent Technologies Inc.
Table 13. Dual-Port FIFO Packing/Unpacking, Case 1,
PCI Side ........................................................... ..... ......33
Table 14. Dual-Port FIFO Packing/Unpacking, Case 1,
FPGA Side ..................................................................33
Table 15. Dual-Port FIFO Packing/Unpacking, Case 2,
PCI Side...................................................... ...... ..... ......33
Table 16. Dual-Port FIFO Packing/Unpacking, Case 2,
FPGA Side ..................................................................34
Table 17. Index to State Sequence Tables.....................35
Table 18. Dual-Port Master Write ..................................41
Table 19. Dual-Port Master Read, 64-Bit Address
Supplied.......................................................................48
Table 20. Dual-Port Master Read, 32-Bit Address
Supplied ...................................................................... 48
Table 21. Dual-Port Target Write ...................................57
Table 22. Dual-Port Target Read ...................................69
Table 23. Embedded Core/FPGA Interface Signals....... 70
Table 24. OR3LP26B FPGA/PCI Core Interface Signal
Locations......................................................................76
Table 25. Bit Definitions on FPGA/PCI Core Interface...79 Table 26. Address Cycle S equences for Various
Operations ...................................................................82
Table 27. PCI Core Options Settable via FPGA
Configuration RAM Bits................................................83
Table 28. Quad-Port FIFO Packing/Unpacking, Case 1,
PCI Side...................................................... ...... ..... ......84
Table 29. Dual-Port FIFO Packing/Unpacking, Case 1,
FPGA Side ..................................................................84
Table 30. Quad-Port FIFO Packing/Unpacking, Case 1,
PCI Side ........................................................... ..... ......85
Table 31. Quad-Port FIFO Packing/Unpacking,
Case 1, FPGA Side......................................................85
Table 32. Quad-Port FIFO Packing/Unpacking, Case 2,
PCI Side...................................................... ...... ..... ......85
Table 33. Quad-Port FIFO Packing/Unpacking, Case 1,
FPGA Side...................................................................85
Table 34. Holding Registers, Examples of Typical
Operation .....................................................................86
Table 35. Index to State Sequence Tables.....................87
Table 36. Quad-Port Master Write .................................93
Table 37. Quad-Port Master Read, Duplicate Burst
Length and 16-Bit Address...........................................100
Table 38. Quad-Port Master Read, Specified Burst
Length and 64-Bit Address ..........................................100
Table 39. Quad-Port Target Write ..................................109
Table 40. Quad-Port Target Read...................................122
Table 41. Configuration Space Layout............................123
Table 42. Configuration Space Assignment ................... 124
Table 43. Configuration Frame Format and Contents .... 131
Table 44. Configuration Frame Size...............................132
Table 45. Configuration Modes.......................................132
Table 46. Absolute Maximum Ratings............................133
Table 47. Recommended Operating Conditions.............134
Table 48. Electrical Characteristics................................135
Table 49. Derating for Commercial Devices
(I/O Supply VDD) ............................. ..... ...... ...... ...........136
Table 50. .........................................................................Der-
ating for Commercial Devices (I/O Supply VDD2)........136
Table 51. ExpressCLK (ECLK) and Fast Clock (fclk)
TimingCharacteristics...................................................137
Table 52. General-Purpose Clock Timing
Characteristics (Internally Generated Clock)................138
Table 53. OR3LP26B ExpressCLK to Output
Delay (Pin-to-Pin)............................................... ...... ....138
Table 54. OR3LP26B Fast Clock (fclk) to Output
Delay (Pin-to-Pin)............................................... ...... ....139
Table 55. OR3LP26B General System Clock (SCLK)
to Output Delay (Pin-to-Pin)..........................................140
Table 56. OR3LP26B Input to ExpressCLK (ECLK)
Fast-Capture Setup/Hold Time (Pin-to-Pin)..................141
Table 57. OR3LP26B Input to Fast Clock
Setup/Hold Time (Pin-to-Pin)........................................142
Table 58. OR3LP26B Input to General System
Clock (SCLK) Setup/Hold Time (Pin-to-Pin).................143
Table 59. OR3LP26B PCI and FPGA Interface Clock
Operation Frequencies.................................................143
Table 60. OR3LP26B FPGA to PCI, and PCI to FPGA,
Combinatorial Path Delays...........................................144
Table 61. OR3LP26B FPGA Side Interface
Combinatorial Path Delay Signals ................................144
Table 62. OR3LP26B Interbuf Delays.............................145
Table 63. OR3LP26B FPGA Side Interface Clock to
Output Delays, pciclk Synchronous Signals.................145
Table 64. OR3LP26B FPGA Side Interface Clock to
Output Delays, fclk Synchronous Signals.....................146
Table 65. OR3LP26B FPGA Side Interface Input
Setup Delays, pciclk Synchronous Signals...................147
Table 66. OR3LP26B FPGA Side Interface Input
Setup Delays, fclk Synchronous Signals ......................147
Table 67. PCI Core Internal Power Dissapation .............150
Table 68. FPGA Common-Function Pin Descriptions.....151
Table 69. ORCA OR3LP26B I/Os Summary ..................154
Table 70. Pinout Information ..........................................155
Table 71. ORCA OR3LP26B Plastic Package Thermal
Guidelines.....................................................................178
Table 72. Package Coplanarity.......................................179
Table 73. Package Parasitics..........................................180
Table 74. Voltage Options...............................................184
Table 75. Package Options.............................................184
Table 76. ORCA Series 3+ Package Matrix....................184
Table 77. Embedded Core Type......................................184
Table 78. FPSC Base Array............................................184
Lucent Technologies Inc. 5
Data Sheet
ORCA
OR3LP26B FPSC
Marc h 2000 Embedded Master/Target PCI Inte rface
Lucent Technologies Inc.
PCI Bus Core Highlights
(continued)
Master: — Generates all defined command codes except
interrupt acknowledge and special cycle. — Capable of accessing its own local Target. — Capable of acting as the system's configuration
agent by booting up with the Master logic
enabled. — Supports multiple options for Master bus requests,
to increase PCI bus bandwidth. — Supports single-cycle I/O space accesses. — Provides option to delay PCI access until FIFO is
full on Master writes to increase PCI bandwidth. — Supports programmable latency timer control.
Target: — Responds legally to all command codes: interrupt
acknowledge, special cycle, and reserved com-
mands ignored; memory read multiple and line
handled as memory read; memory write and
invalidate handled as memory write. — Implements Target abort, disconnect, retry, and
wait cycles. — Handles delayed transactions. — Handles fast back-to-back transactions. — Method of handling retries is programmable at
FPGA configuration to allow tailoring to different
Target data access latencies. — Decodes at medium speed. — Provides option to delay PCI access until FIFO is
full on Target reads to increase PCI bandwidth.
Supports dual-address cycles (both as Master and Target).
Supports all six base address registers (BARs), as either memory (32-bit or 64-bit) or I/O. Any legal page size can be independently specified for each BAR during FPGA configuration.
Independent Master and Target clocks can be sup­plied to the PCI FIFO interface from the FPGA-based logic.
Provides vers atile clocking capabilities with FPGA clocks sourced from PCI bus clock or elsewhere. FIFO interface buffers asynchronous clock domains between the PCI interface and FPGA-based logic.
PCI interface timing: meets or exceeds 33 MHz, 50 MHz, and 66 MHz PCI requirements.
Configuration options: — Class code, revision ID. — Latency timer. — Cache line size. — Subsystem ID. — Subsystem vendor ID. — Maximum latency, minimum grant. — Interrupt line. — Hot Plug/Hot Swap capability.
Generates interrupts on
intan
as directed by the
FPGA.
PCI I/O output drivers can be programmed for fast or slew-limited operation.
Automatically detects 5 V or 3.3 V PCI bus signaling environment and provides appropriate I/O signaling, under 3.3 V commercial conditions.
Ideally suited for such applications as: — PCI-based graphics/video/multimedia. — Bridges to ISA/EISA/MCA, LAN, SCSI, Ethernet,
ATM, or other bus architectures.
— High-bandwidth data transfer in proprietary sys-
tems.
FPSC Highlights
Implemented as an embedded core into the advanced Series 3+
ORCA
FPSC architecture.
Allows the user to integrate the core with up to 120K gates of programmable logic, all in one device, and provides up to 259 user I/O pins in addition to the PCI interface pins.
FPGA portion retains all of the features of the
ORCA
3 FPGA architecture: — High-performance, cost-effective, 0.25 µm
5-level metal technology.
— Twin-quad programmable function unit (PFU)
architecture with eight 16-bit look-up tables (LUTs) per PFU, organized in two nibbles for use in nibble- or byte-wide functions. Allows for mixed arithmetic and logic functions in a single PFU.
Parameter 33 MHz 50 MHz 66 MHz
Device Clock = > Out 11.0 ns 7.5 ns 6.0 ns Device Setup Time 7.0 ns 4.5 ns 3.0 ns Board Prop. Delay 10.0 ns 6.5 ns 5.0 ns Board Clock Skew 2.0 ns 1.5 ns 1.0 ns Total Budget 30.0 ns 20.0 ns 15.0 ns Load Capacitance 50 pF 50 pF 10 pF
66 Lucent Technologies Inc.
ORCA
OR3LP26B FPSC Data Sheet
Embedded Master/Target PCI Interface March 2000
Lucent Technologies Inc.
FPSC Highlights
(continued)
— Softwired LUTs (SWL) allow fast cascading of up
to three levels of LUT logic in a single PFU.
— Supplemental logic and interconnect cell (SLIC)
provides 3-statable buffers, up to 10-bit decoder, and
PAL
*-like AND-OR-INVERT (AOI) in each
programmable logic cell (PLC).
— Up to three ExpressCLK inputs allow extremely
fast clocking of signals on- and off-chip plus access to internal general clock routing.
— Dual-use microprocessor interface (MPI) can be
used for configuration, readback, device control, and device status, as well as for a general-pur­pose interface to the FPGA. Glueless interface to
i960
and
PowerPC
‡ processors w ith use r-co nf ig-
urable address space provided.
— Programmable clock manager (PCM) adjusts
clock phase and duty cycle for input clock rates from 5 MHz to 120 MHz. The PCM may be com­bined with FPGA logic to create complex func­tions, such as digital phase-locked loops (DPLL), frequency counters, and frequency synthesizers or clock doublers. Two PCMs are provided per device.
— True internal 3-state, bidirectional buses with sim-
ple control provided by the SLIC.
— 32 x 4 RAM per PFU, configurable as single or
dual port. Create large, fast RAM/ROM blocks (128 x 8 in only eight PFUs) using the SLIC decoders as bank drivers.
— Built-in boundary scan (
IEEE
§
1149.1 JTAG) and
TS_ALL testability function to 3-state all I/O pins.
High-speed on-chip interface provided between FPGA logic and embedded core to reduce bottle­necks typically found when interfacing off-chip.
Supported in two packages: 352-pin PBGA and 680-pin PBGAM.
*
PAL
is a trademark of Advanced Micro Devices, Inc.
i960
is a registered trademark of Intel Corporation.
PowerPC
is a registered trademark of International Business
Machines Corporation.
§
IEEE
is a registered trademark of The Institute of Electrical and
Electronics Engineers, Inc.
Note
: This document will conform to the nomenclature
of the PCI Local Bus Specification, as follows:
Software Support
Supported by
ORCA
Foundry software and third-
part
y
CAE tools for implementing
ORCA
Series 3+
devices and simulation/timin
g
analysis with embed-
ded PCI bus core.
PCI core configuration options and simulati on netlists
g
enerated by FPSC Configuration Manager
utility in
ORCA
Foundry software.
Preference files provided for timing interface between PCI bus core and FPGA logic.
Term Meaning
byte 8 bits
word 16 bits
DWORD 32 bits
Quadword 64 bits
Lucent Technologies Inc. 7
Data Sheet
ORCA
OR3LP26B FPSC
Marc h 2000 Embedded Master/Target PCI Inte rface
Lucent Technologies Inc.
Description
What Is an FPSC?
FPSCs, or field-programmable system chips, are devices that combine field-programmable logic with ASIC or mask-programmed logic on a single device. FPSCs provide the time to market and flexibility of FPGAs, the design effort savings of using soft intellec­tual property (IP) cores, and the speed, design density, and economy of ASICs.
FPSC Overview
Lucent’s Series 3+ FPSCs are created from Series 3
ORCA
FPGAs. To create a Series 3+ FPSC, several rows of programmable logic cells (see FPGA Logic Overview section for FPGA logic details) are removed from a Series 3
ORCA
FPGA, and the area is replaced with an embedded logic core. Other than replacing some FPGA gates with ASIC gates, at greater than 10:1 efficiency, none of the FPGA functionality is changed—all of the Ser ies 3 FPGA ca pabi li ty is retained: MPI, PCMs, boundary scan, etc. The rows of programmable logic are replaced at the bottom of the device, allowing pins on the bottom and sides of the replaced rows to be used as I/O pins for the embedded core. The remainder of the device pins retain their FPGA functionality as do special function FPGA pins within the embedded core area.
The embedded cores can take many forms and gener­ally come from Lucent Technologies ASIC libraries. Future offerings will allow customers to supply their own core functions for the creation of custom FPSCs.
FPSC Gate Counting
The total gate count for an FPSC is the sum of its embedded core (standard-cell/ASIC gates) and its FPGA gates. Because FPGA gates are generally expressed as a usable range with a nominal value, the total FPSC gate count is sometimes expressed in the same manner. Standard-cell/ASIC gates are, however, 10 to 25 times more silicon area efficient than FPGA gates. Therefore, an FPSC with an embedded function is gate equivalent to an FPGA with a much larger gate count.
FPGA/Embedded Core Interface
The interface between the FPGA logic and the embed­ded core is designed to look like FPGA I/Os from the FPGA side, simplifying interface signal routing and pro­viding a unified approach with general FPGA design. Effectively, the FPGA is designed as if signals were going off of the device to the embedded core, but the on-chip interface is much faster than going off-chip and requires less power. All of the delays for the interface are precharacterized and accounted for in the
ORCA
Foundry Development System. Clock spines also can pass across the FPGA/embed-
ded core boundary. This allows for fast, low-ske w clock­ing between the FPGA and the embedded core. Many of the special signals from the FPGA, such as DONE and global set/reset, are also available to the embed­ded core, making it possible to fully integrate the embedded core with the FPGA as a system.
For even greater system flexibility, FPGA configuration RAMs are available for use by the embedded core. This allows for user-programmable options in the embedded core, in turn allowing for greater flexibility. Multiple embedded core configurations may be designed into a single device with user-programmable control over which configurations are implemented, as well as the capability to change core functionality simply by recon­figuring the device.
ORCA
Foundry Development System
The
ORCA
Foundry Development System is used to process a design from a netlist to a configured FPSC. This system is used to map a design onto the
ORCA
architecture and then place and route it using
ORCA
Foundry’s timing-driven tools. The development system also includes interfaces to, and libraries for, other popu­lar CAE tools for design entry, synthesis, simulation, and timing analysis.
The
ORCA
Foundry Development System interfaces to front-end design entry tools and provides the tools to produce a configured FPSC. In the design flow, the user defines the functionality of the FPGA portion of the FPSC and embedded core settings at two points in the design flow: at design entry and at the bit stream generation stage.
88 Lucent Technologies Inc.
ORCA
OR3LP26B FPSC Data Sheet
Embedded Master/Target PCI Interface March 2000
Lucent Technologies Inc.
Description
(continued)
Following design entry, the dev elopment system’s map , place, and route tools translate the netlist into a routed FPSC. A static timing analysis tool is provided to deter­mine device speed and a back-annotated netlist can be created to allow simulation. Timing and simulation out­put files from
ORCA
Foundry are also compatible with many third-party analysis tools. Its bit stream generator is then used to generate the configuration data which is loaded into the FPSC’s internal configuration RAM. When using the bit stream generator, the user selects options that affect the functionality of the FPSC. Com­bined with the front-end tools,
ORCA
Foundry pro­duces configuration data that implements the various logic and routing options discussed in this data sheet.
FPSC Design Kit
Development is facilitated by an FPSC Design Kit which, together with
ORCA
Foundry and third-party synthesis and simulation engines, provides all software and documentation required to design and verify an FPSC implementation. Included in the kit are the FPSC Configuration Manager,
Verilog
* and
VHDL
* gate-level structural netlists, all necessary synthesis libraries, and complete online documentation. The kit's software cou­ples with
ORCA
Foundry under the control of the
ORCA
Foundry Control Center (OFCC), providing a seamless FPSC design environment. More information can be obtained by visiting the
ORCA
website or con­tacting a local sales office, both listed on the last page of this document.
FPGA Logic Overview
ORCA
Series 3 FPGA logic is a new generation of SRAM-based FPGA logic built on the successful Series 2 FPGA line from Lucent Technologies Microelectron­ics Group, with enhancements and innovations geared toward today’s high-speed designs and tomorrow’s sys­tems on a single chip. Designed from the start to be synthesis friendly and to reduce place and route times while maintaining the complete routability of the
ORCA
Series 2 devices, the Series 3 more than doubles the logic available in each logic block and incorporates sys­tem-level features that can further reduce logic require­ments and increase system speed.
ORCA
Series 3 devices contain many new patented enhancements and are offered in a variety of packages, speed grades, and temperature ranges.
ORCA
Series 3 FPGA logic consists of three basic ele­ments: programmable logic cells (PLCs), programma­ble input/output cells (PICs), and system-level features. An array of PLCs is surrounded by PICs. Each PLC contains a programmable function unit (PFU), a sup­plemental logic and interconnect cell (SLIC), local rout­ing resources, and configuration RAM. Most of the FPGA logic is performed in the PFU, but decoders,
PAL
-like functions, and 3-state buffering can be per­formed in the SLIC. The PICs provide device inputs and outputs and can be used to register signals and to perform input demultiplexing, output multiplexing, and other functions on two output signals. Some of the system-level functions include the new microprocessor interface (
MPI
) and the programmable clock manager
(
PCM
).
PLC Logic
Each PFU within a PLC contains eight 4-input (16-bit) look-up tables (LUTs), eight latches/flip-flops (FFs), and one additional flip-flop that may be used indepen­dently or with arithmetic functions.
The PFU is organized in a twin-quad fashion: two sets of four LUTs and FFs that can be controlled indepen­dently. LUTs may also be combined for use in arith­metic functions using fast-carry chain logic in either 4-bit or 8-bit modes. The carry-out of either mode may be registered in the ninth FF for pipelining. Each PFU may also be configured as a synchronous 32 x 4 single- or dual-port RAM or ROM. The FFs (or latches) may obtain input from LUT outputs or directly from invertible PFU inputs, or they can be tied high or tied low. The FFs also have programmable clock polarity, clock enables, and local set/reset.
The SLIC is connected to PLC routing resources and to the outputs of the PFU. It contains 3-state, bidirectional buffers and logic to perform up to a 10-bit AND function for decoding, or an AND-OR with optional INVERT (AOI) to perform
PAL
-like functions. The 3-state drivers in the SLIC and their direct connections to the PFU out­puts make fast, true 3-state buses possible within the FPGA logic, reducing required routing and allowing for real-world system performance.
*
Verilog
and
VHDL
are registered trademarks of Cadance Design
Systems, Inc.
Lucent Technologies Inc. 9
Data Sheet
ORCA
OR3LP26B FPSC
Marc h 2000 Embedded Master/Target PCI Inte rface
Lucent Technologies Inc.
Description
(continued)
PIC Logic
The Series 3 PIC addresses the demand for ever­increasing system clock speeds. Each PIC contains four programmable inputs/outputs (PIOs) and routing resources. On the input side, each PIO contains a fast­capture latch that is clocked by an
ExpressCLK
. This latch is followed by a latch/FF that is clocked by a sys­tem clock from the internal general clock routing. The combination provides for very low setup requirements and zero hold times for signals coming on-chip. It may also be used to demultiplex an input signal, such as a multiplexed address/data signal, and register the sig­nals without explicitly building a demultiplexer. Two input signals are available to the PLC array from each PIO, and the
ORCA
Series 2 capability to use any input
pin as a clock or other global input is maintained. On the output side of each PIO, two outputs from the
PLC array can be routed to each output flip-flop, and logic can be associated with each I/O pad. The output logic associated with each pad allows for multiplexing of output signals and other functions of two output sig­nals.
The output FF, in combination with output signal multi­plexing, is particularly useful for registering address signals to be multiplexed with data, allowing a full clock cycle for the data to propagate to the output. The I/O buffer associated with each pad is the same as the
ORCA
Series 3 buffer.
System Features
The Series 3 also provides system-level functionality by means of its dual-use microprocessor interface (MPI) and its innovative programmable clock manager (PCM). These functional blocks allow for easy glueless system interfacing and the capability to adjust to vary­ing conditions in today’s high-speed systems. Since these and all other Series 3 features are available in every Series 3+ FPSC, they can also interface to the embedded core providing for easier system integration.
Routing
The abundant routing resources of
ORCA
Series 3 FPGA logic are organized to route signals individually or as buses with related control signals. Clocks are routed on a low-skew, high-speed distribution network and may be sourced from PLC logic, externally from any I/O pad, or from the very fast
ExpressCLK
pins.
ExpressCLKs may be glitchlessly and independently enabled and disabled with a programmable control sig­nal using the new
StopCLK
feature. The improved PIC routing resources are now similar to the patented intra­PLC routing resources and provide great flexibility in moving signals to and from the PIOs. This flexibility translates into an improved capability to route designs at the required speeds when the I/O signals have been locked to specific pins.
Configuration
The FPGA logic’s functionality is determined by internal configuration RAM. The FPGA logic’s internal initializa­tion/configuration circuitry loads the configuration data at powerup or under system control. The RAM is loaded by using one of several configuration modes, including serial EEPROM, the microprocessor inter­face, or the embedded function core.
Boundary Scan
Boundary scan is implemented in the OR3LP26B device as with any of the OR3LXXB family of parts. The PCI core side of the device contains the same bound­ary-scan registers. After performing a boundary-scan test, it is highly recommended that the device be reset through the PCI
rstn
pin. This reset will clear out any PCI core internal registers that may have been set dur­ing the boundary-scan tests.
More Series 3 Information
For more information on Series 3 FPGAs, please refer to the Series 3 FPGA data sheet, available on the
ORCA
worldwide website or by contacting Lucent Technologies as directed on the back of this data sheet.
1010 Lucent Technologies Inc.
ORCA
OR3LP26B FPSC Data Sheet
Embedded Master/Target PCI Interface March 2000
Lucent Technologies Inc.
OR3LP26B Overview
Device Layout
The OR3LP26B FPSC provides a PCI local bus core (with FIFOs) combined with FPGA logic. The device is based on a 2.5 V OR3L125B FPGA. The OR3L125B has a 28 x 28 array of programmable logic cells (PLCs). For the OR3LP26B, the bottom ten rows of PLCs in the array were replaced with the embedded PCI bus core. Table 3 shows a schematic view of the OR3LP26B. The upper portion of the device is an 18 x 28 array of PLCs surrounded on the left, top, and right by programmable input/output cells (PICs). At the bottom of the PLC array are the core interface cells (CICs) connecting to the embedded core region. The embedded core region contains the PCI bus functionality of the device. It is surrounded on the left, bottom, and right by PCI bus dedicated I/Os as well as power and special function FPGA pins. Also shown are the interquad routing blocks (hIQ, vIQ) present in the Series 3 FPGA devices. System-level functions (located in the corners of the PLC array), routing resources, and configuration RAM are not shown in Figure 1.
PCI Local Bus
PCI local bus, or simply, PCI bus, has become an industry-standard interface protocol for use in applica­tions ranging from desktop PC busing to high-band­width backplanes in networking and communications equipment. The PCI bus specification* provides for both 5 V and 3.3 V signaling environments. The inter­face clock speed is specified in the range from dc to 66 MHz with detailed specifications at 33 MHz and 66 MHz as well as recommendations for 50 MHz oper­ation. Data paths are defined as either 32-bit or 64-bit. These data path and frequency combinations allow for the peak data transfer rates described in Table 2.
* PCI Local Bus Specification Rev. 2.2, PCI SIG, December 18,
1998.
The PCI bus is electrically specified so that no glue logic is required to interface to the bus—PCI devices interface directly to the PCI bus. Other features include registers for device and subsystem identification and autoconfiguration, support for 64-bit addressing, and multi-Master capabilit y that allows any PCI bus Master access to any PCI bus Target.
Table 2. PCI Local Bus Data Rates
Clock
Frequency
(MHz)
Data Path
Width (bits)
Peak Data Rate
(Mbytes)
33 32 132 33 64 264 66 32 264 66 64 528
Lucent Technologies Inc. 11
Data Sheet
ORCA
OR3LP26B FPSC
Marc h 2000 Embedded Master/Target PCI Inte rface
Lucent Technologies Inc.
OR3LP26B Overview
(continued)
Table 3. OR3LP26B Arra y
IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII
PT1 PT2 PT3 PT4 PT5 PT6 PT7 PT8 PT9 PT10 PT11 PT12 PT13 PT14 PT15 PT16 PT17 PT18 PT19 PT20 PT21 PT22 PT23 PT24 P T25 PT2 6 PT2 7 PT28
IIII
PL1
R1C1R1C2R1C3R1C4R1C5R1C6R1C7R1C8R1C9R1
C10R1C11R1C12R1C13R1C14R1C15R1C16R1C17R1C18R1C19R1C20R1C21R1C22R1C23R1C24R1C25R1C26R1C27R1C28
PR1
IIII
IIII
PL2
R2C1R2C2R2C3R2C4R2C5R2C6R2C7R2C8R2C9R2
C10R2C11R2C12R2C13R2C14R2C15R2C16R2C17R2C18R2C19R2C20R2C21R2C22R2C23R2C24R2C25R2C26R2C27R2C28
PR2
IIII
IIII
PL3
R3C1R3C2R3C3R3C4R3C5R3C6R3C7R3C8R3C9R3
C10R3C11R3C12R3C13R3C14R3C15R3C16R3C17R3C18R3C19R3C20R3C21R3C22R3C23R3C24R3C25R3C26R3C27R3C28
PR3
IIII
IIII
PL4
R4C1R4C2R4C3R4C4R4C5R4C6R4C7R4C8R4C9R4
C10R4C11R4C12R4C13R4C14R4C15R4C16R4C17R4C18R4C19R4C20R4C21R4C22R4C23R4C24R4C25R4C26R4C27R4C28
PR4
IIII
IIII
PL5
R5C1R5C2R5C3R5C4R5C5R5C6R5C7R5C8R5C9R5
C10R5C11R5C12R5C13R5C14R5C15R5C16R5C17R5C18R5C19R5C20R5C21R5C22R5C23R5C24R5C25R5C26R5C27R5C28
PR5
IIII
IIII
PL6
R6C1R6C2R6C3R6C4R6C5R6C6R6C7R6C8R6C9R6
C10R6C11R6C12R6C13R6C14R6C15R6C16R6C17R6C18R6C19R6C20R6C21R6C22R6C23R6C24R6C25R6C26R6C27R6C28
PR6
IIII
IIII
PL7
R7C1R7C2R7C3R7C4R7C5R7C6R7C7R7C8R7C9R7
C10R7C11R7C12R7C13R7C14R7C15R7C16R7C17R7C18R7C19R7C20R7C21R7C22R7C23R7C24R7C25R7C26R7C27R7C28
PR7
IIII
IIII
PL8
R8C1R8C2R8C3R8C4R8C5R8C6R8C7R8C8R8C9R8
C10R8C11R8C12R8C13R8C14R8C15R8C16R8C17R8C18R8C19R8C20R8C21R8C22R8C23R8C24R8C25R8C26R8C27R8C28
PR8
IIII
IIII
PL9
R9C1R9C2R9C3R9C4R9C5R9C6R9C7R9C8R9C9R9
C10R9C11R9C12R9C13R9C14R9C15R9C16R9C17R9C18R9C19R9C20R9C21R9C22R9C23R9C24R9C25R9C26R9C27R9C28
PR9
IIII
IIII
PL10
R10C1R10C2R10C3R10C4R10C5R10C6R10C7R10C8R10C9R10
C10
R10 C11
R10 C12
R10 C13
R10 C14
R10 C15
R10 C16
R10 C17
R10 C18
R10 C19
R10 C20
R10 C21
R10 C22
R10 C23
R10 C24
R10 C25
R10 C26
R10 C27
R10 C28
PR10
IIII
IIII
PL11
R11C1R11C2R11C3R11C4R11C5R11C6R11C7R11C8R11C9R11
C10
R11 C11
R11 C12
R11 C13
R11 C14
R11 C15
R11 C16
R11 C17
R11 C18
R11 C19
R11 C20
R11 C21
R11 C22
R11 C23
R11 C24
R11 C25
R11 C26
R11 C27
R11 C28
PR11
IIII
IIII
PL12
R12C1R12C2R12C3R12C4R12C5R12C6R12C7R12C8R12C9R12
C10
R12 C11
R12 C12
R12 C13
R12 C14
R12 C15
R12 C16
R12 C17
R12 C18
R12 C19
R12 C20
R12 C21
R12 C22
R12 C23
R12 C24
R12 C25
R12 C26
R12 C27
R12 C28
PR12
IIII
IIII
PL13
R13C1R13C2R13C3R13C4R13C5R13C6R13C7R13C8R13C9R13
C10
R13 C11
R13 C12
R13 C13
R13 C14
R13 C15
R13 C16
R13 C17
R13 C18
R13 C19
R13 C20
R13 C21
R13 C22
R13 C23
R13 C24
R13 C25
R13 C26
R13 C27
R13 C28
PR13
IIII
IIII
PL14
R14C1R14C2R14C3R14C4R14C5R14C6R14C7R14C8R14C9R14
C10
R14 C11
R14 C12
R14 C13
R14 C14
R14 C15
R14 C16
R14 C17
R14 C18
R14 C19
R14 C20
R14 C21
R14 C22
R14 C23
R14 C24
R14 C25
R14 C26
R14 C27
R14 C28
PR14
IIII
IIII
PL15
R15C1R15C2R15C3R15C4R15C5R15C6R15C7R15C8R15C9R15
C10
R15 C11
R15 C12
R15 C13
R15 C14
R15 C15
R15 C16
R15 C17
R15 C18
R15 C19
R15 C20
R15 C21
R15 C22
R15 C23
R15 C24
R15 C25
R15 C26
R15 C27
R15 C28
PR15
IIII
IIII
PL16
R16C1R16C2R16C3R16C4R16C5R16C6R16C7R16C8R16C9R16
C10
R16 C11
R16 C12
R16 C13
R16 C14
R16 C15
R16 C16
R16 C17
R16 C18
R16 C19
R16 C20
R16 C21
R16 C22
R16 C23
R16 C24
R16 C25
R16 C26
R16 C27
R16 C28
PR16
IIII
IIII
PL17
R17C1R17C2R17C3R17C4R17C5R17C6R17C7R17C8R17C9R17
C10
R17 C11
R17 C12
R17 C13
R17 C14
R17 C15
R17 C16
R17 C17
R17 C18
R17 C19
R17 C20
R17 C21
R17 C22
R17 C23
R17 C24
R17 C25
R17 C26
R17 C27
R17 C28
PR17
IIII
IIII
PL18
R18C1R18C2R18C3R18C4R18C5R18C6R18C7R18C8R18C9R18
C10
R18 C11
R18 C12
R18 C13
R18 C14
R18 C15
R18 C16
R18 C17
R18 C18
R18 C19
R18 C20
R18 C21
R18 C22
R18 C23
R18 C24
R18 C25
R18 C26
R18 C27
R18 C28
PR18
IIII
IIII
ASB1 ASB2 ASB3 ASB4 ASB5 ASB6 ASB7 ASB8 ASB9 ASB10 ASB11 ASB12 ASB13 ASB14 ASB15 ASB16 ASB17 ASB18 ASB19 ASB20 ASB21 ASB22 ASB23 ASB24 ASB25 ASB26 ASB27 ASB28
IIII
EMBEDDED CORE AREA
IIII
IIII
IIII
IIII
IIII
IIII
IIII
IIII
IIII
IIII
IIII
IIII
IIII
IIII
IIII
IIII
IIII
IIII
IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII IIII III IIII IIII IIII IIII
1212 Lucent Technologies Inc.
ORCA
OR3LP26B FPSC Data Sheet
Embedded Master/Target PCI Interface March 2000
Lucent Technologies Inc.
OR3LP26B Overview
(continued)
OR3LP26B PCI Bus Core Overview
The OR3LP26B embedded core comprises a PCI bus interface with independent Master and Target control­lers, FIFO memories and control logic for data buffer­ing, a dual-/quad-port interface to the FPGA logic which performs data packing and multiplexing, and logic to support embedded core and FPGA configura­tion. Each of these areas is briefly described in the fol­lowing paragraphs. A detailed description of all of the features and functionality of the OR3LP26B embedded core is provided in the next section.
PCI Bus Interface
The OR3LP26B PCI bus interface is compliant to Revi­sion 2.2 of the PCI Local Bus specification. It is capable of no-wait-state, full-burst operation at all of the rate/data width combinations described in Table 2 as well as at a 50 MHz specification that provides a speed increase over the 33 MHz specification and a larger bus loading capability than the 66 MHz specification. The OR3LP26B operates in either the 3.3 V or 5 V PCI signaling environment and is automatically configured for the appropriate environment by a PCI bus
vio
pin.
Independent Master and Target controllers are pro­vided for use in systems requiring Master/Target or Tar­get only operation. Six 32-bit base address registers (BARs) are provided for choosing the address space of the PCI device, and these six registers can be com­bined in pairs to produce 64-bit BARs. Dual address cycles are supported in both 32-bit and 64-bit address­ing modes. The BARs work in either the I/O or the memory space of the device, and can be configured as prefetchable or nonprefetchable.
Lucent Technologies Inc. 13
Data Sheet
ORCA
OR3LP26B FPSC
Marc h 2000 Embedded Master/Target PCI Inte rface
Lucent Technologies Inc.
OR3LP26B Overview
(continued)
Independent data paths exist for the Master and Target controllers. This allows for separate operation of Master and Target functions, and the capability for a Master to talk to a Target on the same device.
In dual-port mode, the Master and T arget controllers share two 64-bit data paths, one in each direction, between the FIFOs and the FPGA logic. This provides for full-rate transfers in both 32- and 64-bit PCI bus operation.
Quad-port mode provides two 32-bit data paths for each controller: one in each direction. This mode allows for simultaneous reads and writes on either the Master or Target controller.
Diagrams for dual-port and quad-port operation are shown in Figure 1.
5-6368(F).e
Note: User I/O pin count includes three ExpressCLK pins.
Figure 1.
ORCA
OR3LP26B PCI FPSC Block Diagram
Embedded Core Options/FPGA Configuration
In addition to the Series 3 FPGA configuration modes (less Master parallel), the OR3LP26B can also be configured via the PCI bus. Configuration as discussed here has two meanings. There is configuration of the FPGA logic, and there is configuration of the options available in the embedded core. Both are accomplished through the FPGA configuration process (some PCI configuration options may also be set via registers within the PCI bus core). Readback of FPGA and PCI core options is also possible using the PCI bus or Series 3 FPGA readback modes. The PCI bus core will be functional in the default PCI bus configuration space, as defined in the PCI bus 2.2 speci­fication, prior to an initial configuration of the FPGA logic or the embedded core options.
113 USER I/O PADS
OR3T SERIES FPGA
18 ROWS x 28 COLUMNS
73
USER
I/O PADS
73
USER
I/O PADS
PCI
MASTER/TARGET
INTERFACE
PCI BUS
DATA CONTROL
AND
MULTIPLEXING
32 32
32 32
64-bit x
16 DEEP
FIFO
TARGET
64-bit x
16 DEEP
FIFO
TARGET
64-bit x
32 DEEP
FIFO
MASTER
64-bit x
32 DEEP
FIFO
MASTER
113 USER I/O PADS
OR3T SERIES FPGA
18 ROWS x 28 COLUMNS
73
USER
I/O PADS
73
USER
I/O PADS
64-bit x
32 DEEP
FIFO
PCI
MASTER/TARGET
INTERFACE
PCI
BUS
DATA CONTROL
AND
MULTIPLEXING
64
64
MASTER
64-bit x
32 DEEP
FIFO
MASTER
64-bit x
16 DEEP
FIFO
TARGET
64-bit x
16 DEEP
FIFO
TARGET
ORCA
OR3LP26B FPSC Data Sheet
Embedded Master/Target PCI Interface
March 2000
14 Lucent Technologies Inc.
Lucent Technologies Inc.
PCI Bus Core Detailed Description
The following sections describe the operation of the embedded core PCI bus interface.
PCI Bus Commands
The PCI core supports all commands required by the PCI specification. The following table describes each com­mand. Subsequent sections will describe the protocols in which the commands are used.
Table 4. PCI Bus Command Descriptions
Command
Code
(Binary
)
Command
Master
Generates
Target
Accepts
Description
0000 Interrupt
Acknowl-
edge
Only implemented as Master by agents that interface to the sys-
tem CPU and as Target by agents that incorporate the system interrupt controller.
0001 Special
Cycle
Target ignores, per PCI Specification section 3.6.2.
0010 I/O Read
√√
Fully implemented.
Target:
Bursting is prevented by disconnecting with data on the
first data phase. If signal
deltrn
is asserted low, I/O (and memory) reads are handled as delayed transactions; no wait-states are generated. If signal
deltrn
is deasserted high, the unit waits for the data from the FPGA application, inserting wait-states (up to the maximum allowed, after which a retry is issued).
Master:
Bursting is allowed, and no wait-states are generated.
0011 I/O Write
√√
Fully implemented.
Target:
Bursting is prevented by disconnecting with data on the
first data phase. If signal
deltrn
is asserted low, I/O writes are
handled as delayed transactions; no wait-states are generated.
Master:
Bursting is allowed, and no wait-states are generated. 0100 (reserved) Target ignores, per PCI Specification section 3.1.1. 0101 (reserved) Target ignores, per PCI Specification section 3.1.1. 0110 Memory
Read
√√
Fully implemented.
Target:
Bursting is allowed. If signal
deltrn
is asserted low, mem-
ory (and I/O) reads are handled as delayed transactions. If signal
deltrn
is deasserted high, the unit waits for the data from the FPGA application, inserting wait-states (up to the maximum allowed, after which a retry is issued). If signal
trburstpendn
is asserted low and the Target Read FIFO is empty, wait-states are inserted (up to the maximum allowed, after which a retry is issued).
Master:
Bursting is allowed, and no wait-states are generated.
Lucent Technologies Inc. 15
Data Sheet
ORCA
OR3LP26B FPSC
Marc h 2000 Embedded Master/Target PCI Inte rface
Lucent Technologies Inc.
PCI Bus Core Detailed Description
(continued)
Table 4. PCI Bus Command Descriptions
(continued)
Command
Code
(Binary
)
Command
Master
Generates
Target
Accepts
Description
0111 Memory
Write
√√
Fully implemented.
Target:
Writes are posted, bursting is allowed, and no wait-states
are generated.
Master:
Bursting is allowed, and no wait-states are generated. 1000 (reserved) Target ignores, per PCI Specification section 3.1.1. 1001 (reserved) Target ignores, per PCI Specification section 3.1.1. 1010 Configura-
tion Read
√√
Fully implemented.
Target:
Bursting is disallowed, and no wait-states are generated. Target disconnects with data on first data word. The FPGA portion of the device is not involved in Target configuration transactions.
Master:
Bursting is allowed, and no wait-states are generated.
1011 Configura-
tion Write
√√
Fully implemented.
Target:
Bursting is disallowed, and no wait-states are generated. Target disconnects with data on first data word. The FPGA portion of the device is not involved in Target configuration transactions.
Master:
Bursting is allowed, and no wait-states are generated.
1100 Memory
Read
Multiple
√√
Fully implemented. Both the Master and the Target treat this instruction the same as a memory read (0110); the user’s FPGA logic is responsible for ensuring that the Master operation meets the special requirement that the read request ends on a cacheline boundary.
1101 Dual
Access
Cycle
√√
Fully implemented. Per PCI Specification section 3.9, the PCI core will automatically convert a 64-bit address to a 32-bit address if the upper 32 bits are all zeros.
1110 Memory
Read Line
√√
Fully implemented. Both the Master and the Target treat this instruction the same as a memory read (0110); the user’s FPGA logic is responsible for ensuring that the Master operation meets the special requirement that the read request continues to the next cacheline boundary.
1111 Memory
Write and Invalidate
√√
Fully implemented. Both the Master and the Target treat this instruction the same as a memory write (0111); the user’s FPGA logic is responsible for ensuring that the Master operation meets the special requirement that writes of complete cachelines, with all byte enables, are performed.
1616 Lucent Technologies Inc.
ORCA
OR3LP26B FPSC Data Sheet
Embedded Master/Target PCI Interface March 2000
Lucent Technologies Inc.
PCI Bus Core Detailed Description
(continued)
PCI Protocol Fundamentals
Basic Transfer Control
The following paragraphs describe various aspects of the PCI protocol and the way they are handled by the PCI core.
Addressing.
The PCI Specification defines three types of address spaces. The first, configuration address space, is a physical address of space and is intended as a means for powerup software to identify agents and configure them before other address spaces have allo­cated. The second, I/O address space, is intended for mapping control functions. Control function page sizes in configuration space should be no more than 256 bytes. The third, memory address space, is intended for bulk data transfer. It has features to facili­tate this, such as special commands for cache imple­mentation, large page sizes, and mechanisms for prefetching. The PCI core handles all three address space types as both a Master and a Target.
Byte Alignment.
On all write operations (configuration, I/O, and memory space, and including the memory write and invalidate instruction), for both the PCI core’s Master and Target functions, byte enables are fully implemented from/to the FPGA interface. Note, how­ever, that even though the PCI core implements the ability to control byte enables for the memory write and invalidate instruction, the PCI Specification requires that this instruction assert all byte enables, and this is the FPGA application’s responsibility. On read opera­tions, the utility of byte enables is more dubious since the data must be enroute from the PCI bus from Target to Master, at the time that the corresponding byte enables are enroute on the PCI bus Master to Target (unless wait-states are inserted). The PCI core, there­fore, does not implement byte enable control for Master or Target reads. Byte enables on master read opera­tions are always asserted, and target ignores the byte enables that are sent, in accordance with PCI Specifi­cation requirements.
Device Selectio n (devseln)
The target is responsible for responding to a master’s request by asserting the PCI bus signal
devseln
.
devseln
may be asserted one, two, or three clocks after the address phrase of a transaction, correspond­ing to fast, medium, or slow decode, respectively. The PCI core’s target is capable of preforming a medium­speed decode response. The decode response speed has a significant impact on the overall latency and bandwidth of nonburst PCI transactions, but its impact decreases greatly for burst transactions, particularly for burst lengths of the size of the PCI core’s FIFOs.
Address/Data Stepping
Stepping is an optional feature added to the PCI Speci­fication to accommodate agents whose bus drive capa­bility is insufficient to handle large groups of signals changing state in one clock cycle. Continuous stepping allows weak drivers multiple cycles for signal transition. Discrete stepping partitions the bus into two or more groups of bits that transition on successive clock cycles. However, stepping exacts a heavy toll on perfor­mance, cutting maximum bandwidth by at least 50% and increasing latency. The PCI core is designed for maximum throughput with high-performance buffers, so stepping is unnecessary and not implemented. The wait cycle control, bit 7 of the command register, is therefore hardwired to a zero.
Reset Operation
The PCI bus contains a signal,
rstn
, that performs a PCI reset function. When the reset occurs, all state machines in the ASIC are placed in their idle state, the configuration space BARs are reset to their mask val­ues, and the command registers are reset. The reset does not reset the FPGA logic. The PCI reset signal is fed from the ASIC to the FPGA logic to be used by the designer.
Interrupt Acknowledge
The interrupt acknowledge command is a read by the system CPU implicitly addressed to the system inter­rupt controller. Other agents, including the PCI core, are not required to implement this instruction; the PCI core’s Master does not generate it and its Target ignores it.
Lucent Technologies Inc. 17
Data Sheet
ORCA
OR3LP26B FPSC
Marc h 2000 Embedded Master/Target PCI Inte rface
Lucent Technologies Inc.
PCI Bus Core Detailed Description
(continued)
Arbitration Parking
The PCI Specification requires that all master agents properly handle bus parking, which means that when that agent receives an asserted
gntn
without the agent
having asserted
reqn
, the agent still must drive signal
par
and buses AD and c_ben. The PCI core meets this
requirement.
Parity
The PCI core implements all required and optional fea­tures, including the following:
Master generates parity on all addresses placed on the bus.
Sending agent generates parity on all data placed on the bus.
Target calculates parity on all addresses received from the bus.
Receiving agent calculates parity on all data received from the bus.
The detected parity error bit in the status register is set whenever an agent calculates corrupted parity.
The signal
perrn
is generated whenever an agent calculates corrupted parity and the parity error response bit is set in the command register.
66 MHz Operation
The PCI core is fully compliant to PCI Specification requirements at all clock rates up to 66 MHz. All 33 MHz requirements are also met.
Timing Budget
The PCI core’s timing budget is summarized in Table 5. Note that the 66 MHz timing requirements only allow 5 ns for signal propagation (T
PROP
), as compared to 10 ns at 33 MHz. The effect of the reduction is to also reduce the number of agents that the bus can support, although the actual number is not specified in the PCI Specification and is dependent on the design of the hardware components. The four components of the timing budget are T
VAL
(valid output delay), T
PROP
(propagation time), T
SU
(input setup time), and T
SKEW
(clock sk ew); o f these, only T
VAL
and T
SU
are controlled
by the PCI component, and T
PROP
and T
SKEW
are sys­tem parameters. Table 5 includes a third column (also shown in the PCI Specification). This column indicates the performance attainable if all 66 MHz requirements are met except T
PROP
= 10 ns, which is the 33 MHz
value. In this case, the total budget increases from 15 ns (66 MHz) to 20 ns (50 MHz).
Table 5. Timing Budgets
64-Bit Addressing
The PCI core fully supports 64-bit addressing, whether or not the PCI core is configured to utilize the 64-bit data extension. When the PCI core is a 64-bit target being addressed by 64-bit master, the PCI core will decode the address one cycle faster so that dual­address operation will have no performance impact; see PCI Specification section 3.9 for details.
Section 3.9 of the PCI Specification also states that a Master that supports 64-bit addressin g must neverthe­less generate requests utilizing a single address instead of a dual address when the upper 32 bits are all zeros. This shortens the request time by one cycle when comm unicati ng wit h 32-bit Targets. It is the FPGA application’s responsibility to ensure that this require­ment is met.
FIFO Memories and Control
The OR3LP26B embedded core contains four FIFO memories and supporting control logic. Two FIFOs are for the master interface data and two for the target interface data. These FIFOs are always configured to operate in 64-bit mode and also carry byte enable bits on a per-byte basis (e.g., the 64-bit FIFO actually car­ries 64 bits of data and 8 byte enable bits for a total of 72 bits). During 32-bit transactions, the FPSC will pack the data to fully utilize the memories. All FIFOs have four flags: Full, Almost Full (Full-4), Empty, and Almost Empty (Empty+4). (See Table 6.) The FPGA applica­tion is provided with the Full/Empty signal and Almost Full/Empty signal associated with the FPGA side of the FIFO. In addition, the FPGA application is provided with the PCI side's Full/Empty signal (but not the Almost Full/Empty signal), to enable checking for oper­ation completion. Clocking for the FPGA side of all FIFOs is flexible, with options for different clocks f or the Master and Target FIFOs, sourced by the FPGA logic, or by the PCI bus clock.
Timing Element 33 MHz 50 MHz 66 MHz Unit
Cycle Time 30.0 20.0 1 5.0 ns Valid Output
Delay
11.0 7.5 6.0 ns
Propagation Time
10.0 6.5 5.0 ns
Input Setup Time 7.0 4.5 3.0 ns Clock Skew 2.0 1.5 1.0 ns
ORCA
OR3LP26B FPSC Data Sheet
Embedded Master/Target PCI Interface
March 2000
18 Lucent Technologies Inc.
Lucent Technologies Inc.
PCI Bus Core Detailed Description
(continued)
Table 6. FIFO Flags Provided to FPGA Application
PCI Bus Pin Information
This section describes signals on the PCI bus interface and at the embedded core/FPGA interface. Some signal definitions change name and location based on the mode of operation. Modes of operation are described following the signal descriptions. PCI bus signal package pin locations can be found in Table 70.
Table 7. PCI Bus Pin Descriptions
Write Operation Read Operation
FPGA Side PCI Side FPGA Side PCI Side
Master Operation
mw_fulln mw_emptyn mr_emptyn mr_fulln
mw_afulln mr_aemptyn
Target Operation
tw_emptyn tw_fulln tr_fulln tr_emptyn
tw_aemptyn tr_afulln
S
y
mbol
I/O
Description
System Pins
clk
I
Clock.
Provides timing for all transactions on the PCI bus and is an input to the
OR3LP26B device. All PCI signals, except
rstn
and
intan
, are sampled on the ris-
ing edge of
clk
, and all other PCI bus timing parameters are defined with respect to
this edge. The signal
clk
operates up to 66 MHz, and the minimum frequency is dc.
rstn I
Reset.
An active-low signal used to reset the entire PCI bus.
rstn
is asynchronous
to
clk
. During
rstn
, all PCI output signals are 3-stated.
Address and Data Pins
ad[31:0] I/O
Address and Data.
Multiplexed on the same PCI pins. A PCI bus transaction con-
sists of an address phase followed by one or more data phases. During data phases,
ad[7:0]
contain the least significant byte and
ad[31:24]
con-
tain the most significant byte. During memory commands, the
ad[31:2]
lines spec-
ify the address and
ad[1:0]
specify the type of bursting sequence to use. The table
below outlines the bursting sequence based on the values of
ad[1:0]
.
ad[1:0]
Bursting sequence.
00 Linear incrementing.
01 Disconnect after first transfer. 10 Disconnect after first transfer. 11 Disconnect after first transfer.
c_ben[3:0] I/O
Bus Command and Byte Enables.
Active-low signals multiplexed on the same
PCI pins. During the address phase of a transaction,
c_ben[3:0]
define the bus
command. During the data phase,
c_ben[3:0]
are used as byte enables. The byte enables are valid for the entire data phase and determine which byte lanes carry meaningful data.
par I/O
Parity.
Specifies even parity across
ad[31:0]
and
c_ben[3:0]. par
is stable and
valid one clock after the address phase. For data phases,
par
is stable and valid
one clock after
irdyn
is asserted on a write transaction or
trdyn
is asserted on a
read tran sa cti o n. Once
par
is valid, it remains valid until one clock after the comple-
tion of the current data phase. The Master drives
par
for address and write data
phases; the Target drives
par
for read data phases.
Lucent Technologies Inc. 19
Data Sheet
ORCA
OR3LP26B FPSC
Marc h 2000 Embedded Master/Target PCI Inte rface
Lucent Technologies Inc.
PCI Bus Core Detailed Description
(continued)
Table 7. PCI Bus Pin Descriptions
(continued)
S
y
mbol
I/O
Description
Interface Control Pins
framen I/O
Cycle Frame.
An active-low signal driven by the current Master to indicate the beginning and duration of an access. The signal framen is asserted to indicate a bus transaction is beginning. While
framen
is asserted, data transfers continue.
When
framen
is deasserted, the transaction is in the final phase or has completed.
irdyn I/O
Initiator Ready.
An active-low signal indicating the bus Master’s ability to complete
the current data phase of the transaction. The signal
irdyn
is used in conjunction
with
trd
y
n
. A data phase is completed on any clock cycle during which both
irdyn
and
trd
y
n
are asserted. Duri ng a write ,
irdyn
indicates that valid data is present on
ad[31:0]
. During a read, it indicates the Master is prepared to accept data. Wait
cycles are inserted until both
irdyn
and
trd
y
n
are asserted together.
trd
y
n
I/O
Target Ready.
An active-low signal asserted to indicate the readiness of the Tar-
get’s agent to complete the current data phase of the transaction. The signal
trd
y
n
is used in conjunction with
irdyn
. A data phase is completed on any clock where
both
trd
y
n
and
irdyn
are sampled active. During reads,
trdyn
indicates that valid
data is present on
ad[31:0]
lines. During write cycles,
trd
y
n
indicates that the Tar-
get is prepared to accept data.
stopn
I/O
STOPn.
Indicates that the current Target is requesting the Master to stop the cur-
rent transaction.
idsel I
Initialization Device Select.
Used as a chip select during PCI configuration read
and write transactions. Generally, the user ties
idsel
to one of the upper 24 address
lines,
ad[31:8]
.
devseln I/O
Device Select.
An active-low input indicating that a device on the bus has been selected. As an output, it indicates that the driving device has decoded its address as the Target of the current access.
Arbitration Pins (for Bus Master Only)
reqn O
Request.
An active-low signal that indicates to the arbiter that the asserting agent desires use of the bus. In the OR3LP26B, this signal is asserted when the OR3LP26B Master controller needs access to the PCI bus.
gntn I
Grant.
An active-low signal that indicates to the OR3LP26B that access to the PCI
bus has been granted.
Error Reporting Pins
perrn I/O
Parity Error.
An active-low signal for the reporting of data parity errors during all
PCI transact i ons except a sp e ci al cy cl e. The
perrn
pin is a sustained 3-state signal and must be driven active by the agent receiving data two clocks following the data when a data parity error is detected. The minimum duration of
perrn
is one clock for each data phase that a data parity error is detected. If sequential data phases each have a data parity error, the
perrn
signal will be asserted for more than a single
clock.
perrn
is driven high for one clock before being 3-stated. The signal
perrn
is
not asserted until it has claimed the access by asserting
devseln
and completed a
data phase.
ORCA
OR3LP26B FPSC Data Sheet
Embedded Master/Target PCI Interface
March 2000
20 Lucent Technologies Inc.
Lucent Technologies Inc.
PCI Bus Core Detailed Description
(continued)
Table 7. PCI Bus Pin Descriptions
(continued)
S
y
mbol
I/O
Description
serrn
O
System Error.
An active-low open drain signal pulsed by agents to report errors
other than parity.
serrn
is sampled every
clk
edge, so any agent asserting
serrn
must ensure it is valid for at least one clock period. The OR3LP26B asserts
serrn
if a Master abort sequence is asserted when the Master controller is accessing the PCI bus.
Interrupt Pins
intan O
PCI Interrupt.
The OR3LP26B asserts this active-low open drain signal when it
requests an interrupt from the PCI compliant interrupt controller.
64-Bit Bus Extension Pins
ad[63:32] I/O
64-Bit Address and Data.
These signals provide the upper 32 bits of address and data when in PCI 64-bit operation. During an address phase (when using the DAC command and when
req64n
is asserted), these address bits are transferred. Dur-
ing a data phase, the data is valid when
req64n
and
ack64n
are both asserted.
Otherwise, these bits are 3-stated.
c_ben[7:4] I/O
Byte Enables.
These are the upper four, active-low, bus command and byte enables when in PCI 64-bit operation. During an address phase (when using the DAC command and when
req64n
is asserted), the bus command is transferred. During a data phase, these bits are the active-low byte enables for data bits 64:32. Otherwise, these bits are 3-stated.
req64n I/O
Request 64-Bit Transfer.
This active-low signal is asserted by the current bus
Master to indicate that it desires to transfer data using 64 bits. The signal
req64n
has the same meaning as
framen
for 32-bit transfers.
ack64n I/O
Acknowledge 64-Bit Transfer.
The Target drives this signal low to indicate that it has decoded its own address as the Target of the current access and that it can do 64-bit transfers. The signal
ack64n
has the same timing as
devseln
in 32-bit trans-
fers.
par64 I/O
Upper Double-Word Parity.
The even parity bit that covers
ad[63:32]
and
c_ben[7:4]
. PAR64 is valid one clock after the initial address phase when
req64n
is
asserted and the DAC command is indicated on
c_ben[7:4]
. It is also valid the
clock cycle after the second address phase of a DAC command when
req64n
is
asserted.
Hot Swap Function Pins
enumn O Active-low open drain signal that notifies the system host that the card has been
freshly inserted or is about to be extracted. The system host can then either install (for insertion) or quiesce (for extraction) the card’s driver to adjust for the change in system configuration.
ledn O Active-low open-drain signal that drives a blue LED, indicating that removal of the
card is permitted. This signal is asserted low whenever the LED ON/OFF (LOO) bit in the hot swap control and status register (HSSCR) is asserted high.
ejectsw I Active-high signal that indicates that the card’s ejector handle is unseated. This sig-
nals that the operator has freshly inserted the card, or will extract the card when the blue LED illuminates. If not used, tie high or low.
vio I
PCI Bus Signaling Environment Voltage.
This input indicates to the PCI core the signaling environment being employed on the PCI bus. The input is tied to the appropriate voltage supply (either 5.0 V or 3.3 V).
Lucent Technologies Inc. 21
Data Sheet
ORCA
OR3LP26B FPSC
Marc h 2000 Embedded Master/Target PCI Inte rface
Lucent Technologies Inc.
PCI Bus Core Detailed Description Dual Port
Pages 21—69 will refer to the dual-port mode of the OR3LP26B device. For quad-port mode, please refer to pages 70—122.
Embedded Core/FPGA Interface Signal Descriptions
In Table 8, an input refers to a signal flowing into the FPGA logic (out of the embedded core) and an output refers to a signal flowing out of the FPGA logic (into the embedded core).
Table 8
. Embedded Core/FPGA Interface Si
g
nals
Symbol I/O Description
Data FIFO Signals
datafmfpga[63:0] datafmfpgax[7:0]
O
Main data bus into the master write FIFO and target read FIFO. Refer to Table 10 on page 30 for bus usage and bit descriptions. These signals must be synchronous to
fclk
.
datatofpga[63:0] datatofpgax[7:0]
I
Main data bus out of the master read FIFO and target write FIFO. Refer to Table 10 on page 30 for bus usage and bit descriptions. These signals are synchronous to
fclk
.
Master General Signals
fpga_mbusyn
O
FPGA Master Is Busy .
This signal is used in modes currently not implemented in the
core. Tie off this signal to a 1.
fpga_msyserror
I
FPGA Master Cycle Aborted by PCI Target.
The PCI Master controller in the PCI core asserts this active-high as an indication that the current cycle to the PCI bus has been aborted. This signal is synchronous to
fclk
.
mcfgshiftenn
pci_mcfg_stat
OImcfgshiftenn is an active-low si gnal that determines the data that is output by the PCI
core onto signal
pci_mcfg_stat
:
mcfgshiftenn
= 1:
pci_mcfg_stat
= wired-OR of all bits below, after being
masked by FPGA configuration RAM bits;
mcfgshiftenn
= 0:
pci_mcfg_stat
= each bit below, one at a time on succes-
sive
pciclk
rising edges (unmasked), reset when
mcfgshiftenn
= 1;
Status bits: Data parity error detected, Target abort received, and
Master abort received.
Both signals are synchronous to
fclk
.
Master FIFO Address and Command Register Control Signals
S
y
mbol I/O Description
maenn O
Master Command/Address/Burst Length Enable.
This is an active-low signal and is used to enable registering commands , burst length, and start address into the Mas­ter address register of the PCI core. On each rising edge of the clock that this signal is sampled low, command, burst length, and address will be registered. This signal must be synchronous to
fclk
.
ma_fulln
I
Master Address Register Full Flag.
This active-low signal indicates that the Master address register is full and no more addresses can be registered. This signal is synchronous to
fclk
.
mstatecntr[2:0]
I
Internal State Counter.
Used for Master reads and writes. Details of the Master state machine operation can be found in tables at the end of each operation section. This signal is synchronous to
fclk
.
mfifoclrn
O
Master FIFO Clear.
This active-low signal i s asserted by the FPGA Master to clear all Master FIFOs. This signal must be synchronous to
fclk
.
ORCA
OR3LP26B FPSC Data Sheet
Embedded Master/Target PCI Interface
March 2000
22 Lucent Technologies Inc.
Lucent Technologies Inc.
PCI Bus Core Detailed Description Dual Port
(continued)
Table 8. Embedded Core/FPGA Interface Si
g
nals
(continued)
S
y
mbol
I/O
Description
m_ready
I
Master Logic Ready.
This active-high signal indicates that the Master logic interfacing to the FPGA logic is ready. This signal will be inactive during PCI bus reset or Master FIFO clears. This signal is synchronous to
fclk
.
mcmd[3:0]
O
Master Command Code.
Command code for the current Master read/write operation. Refer to Table 10 on page 30. This signal must be synchronous to
fclk
.
Master Write Data FIFO Signals
mwdataenn
O
Master Write FIFO Data Enable.
This active-low signal enables the registering
of bus
datafmfpga
during Master write operations into the PCI core Master
write data FIFOs on the rising edge of the Master FIFO clock signal. The signal
mwdataenn
should not be asserted when the Master write data FIFOs are full, or data may be lost. This signal must be synchronous to
fclk
.
mwpcihold
O
Master Write PCI Bus Hold.
During burst transfers on the PCI bus, this signal delays the start of the transfer on the PCI bus, allowing the FPGA application to fill the FIFO. The transaction will begin when
mwpcihold
is deasserted or the
FIFO becomes full. When asserted,
mwpcihold
must be held low for a mini-
mum of two
pciclk
periods.
This signal must be synchronous to
pcilk
.
mw_fulln
I
Master Write Data FIFO Full Flag.
This active-low signal indicates that the Master write data FIFOs are full. This signal is synchronous to
fclk
.
mw_afulln
I
Master Write Data FIFO Almost Full Flag.
This active-low signal indicates that only four more empty locations remain in the Master write data FIFOs. This signal is synchronous to
fclk
.
mw_emptyn
I
Master Write Data FIFO Empty Flag.
This active-low signal indicates that the Master write data FIFO is empty. Refer to Master write description on signal usage. This signal is synchronous to
pciclk
.
mwlastcycn O
Master Write Last Data Cycle.
This active-low signal has two functions:
a. It is asserted low to indicate that the accompanying 32/64 bits of Master read
or write address information is the final portion being sent. It can also be asserted prior to any address portion being sent, indicating that the previous address is to be used.
b. It is asserted low to indicate that the accompanying master write data is the
final data for this operation. When more than one cycle is required to transfer a complete data word, this signal is only valid on the last cycle. This signal must be synchronous to
fclk
.
Master Read Data FIFO Signals
mrdataenn O
Master Read FIFO Data Output Enable.
This active-low signal enables the
data from the PCI core Master read data FIFOs onto bus
datatofpga
during Master read operations on the rising edge of the Master FIFO clock signal. Valid data will be read from the FIFO whenever it is not empty. This signal must be synchronous to
fclk
.
mr_emptyn I
Master Read Data FIFO Empty.
This active-low signal indicates that the Mas­ter read data FIFOs of the PCI core are empty. This signal is synchronous to
fclk
.
Lucent Technologies Inc. 23
Data Sheet
ORCA
OR3LP26B FPSC
Marc h 2000 Embedded Master/Target PCI Inte rface
Lucent Technologies Inc.
PCI Bus Core Detailed Description Dual Port
(continued)
Table 8. Embedded Core/FPGA Interface Si
g
nals
(continued)
S
y
mbol
I/O
Description
mr_aemptyn I
Master Read Data FIFO Almost Empty.
This active-low signal indicates that only four more data locations are available to be read from the Master read data FIFOs of the PCI core. This signal is synchronous to
fclk
.
mr_fulln I
Master Read Data FIFO Full Flag.
This active-low signal indicates that the Master read data FIFO is full. Refer to Master read description on signal usage. This signal is synchronous to
pciclk
.
fpga_mstopburstn O
Stop Burst Reads.
This active-low signal is used by the FPGA Master to termi­nate burst reads before completion. When asserted, it must stay asserted for a minimum of two
pciclk
periods. When asserted,
fpga_mstopburstn
must stay
asserted until
ma_fulln
goes inactive (high).
This signal must be synchronous to
pciclk
.
mrlastcycn I
Master Read Last Data Cycle.
This active-low signal is asserted to indicate that the accompanying Master read data is the final data for this operation. When more than one cycle is required to transfer a complete data word, this signal is only valid on the last cycle (1
fclk
period).
This signal is synchronous to
fclk
.
Target General Signals
disctimerexpn I
Discard Timer Expired.
This active-low signal, when asserted, indicates that the discard timer has expired and the core will now treat the retried delayed transaction as a new transaction. The discard timer is a 15-bit counter which starts its count when a delayed transaction is started. This signal is synchronous to
fclk
.
fpga_tabort O
Target Abort.
This active-high signal is asserted by the FPGA Target applica­tion to abort all future PCI cycles. Once asserted, this signal needs to remain asserted for a minimum of two
pciclk
cycles.
This signal must be synchronous to
pciclk
.
fpga_tretryn O
Assert Retry.
This active-low signal is asserted by an FPGA Target to the PCI core to send a retry to the PCI bus. Once asserted, this signal needs to remain asserted for a minimum of two
pciclk
cycles.
This signal must be synchronous to
pciclk
.
deltrn O
Target Delayed Transaction.
Used for Target I/O write (page 50) and Target read operations (page 59). Target memory writes are always posted. Once asserted, this signal needs to remain asserted for a minimum of two
pciclk
cycles. This signal must be synchronous to
pciclk
.
tcfgshiftenn
pci_tcfg_stat
O
I
tcfgshiftenn
is an active-low signal that determines the data that is output by
the PCI core onto signal
pci_tcfg_stat
:
tcfgshiftenn
= 1:
pci_tcfg_stat
= wired-OR of all bits below, after being
masked by FPGA configuration RAM bits;
tcfgshiftenn
= 0:
pci_tcfg_stat
= each bit below, one at a time on suc-
cessive pciclk rising edges (unmasked), reset when
tcfgshiftenn
= 1;
Status bits: Target abort signaled, system error signaled,
and parity error detected.
Both signals are synchronous to
fclk
.
ORCA
OR3LP26B FPSC Data Sheet
Embedded Master/Target PCI Interface
March 2000
24 Lucent Technologies Inc.
Lucent Technologies Inc.
PCI Bus Core Detailed Description Dual Port
(continued)
Table 8. Embedded Core/FPGA Interface Si
g
nals
(continued)
S
y
mbol
I/O
Description
Target FIFO Address and Command Register Control Signals
tfifoclrn O
Target FIFO Clear.
This active-low signal is asserted by the FPGA Target to clear all Target FIFOs. This signal must be synchronous to
fclk
.
treqn I
Target Request from PCI.
This active-low signal is synchronous to the Target
FIFO clock signal. The PCI core asserts
treqn
as an indication to the Target that a transfer request (either read or write) is pending to the target. As long as there are valid target addresses present in the address FIFO, the treqn signal will continue to be active. This signal is synchronous to
fclk
.
t_ready I
T a rget Logic Ready.
This active-high signal indicates that the T arget logic inter­facing to the FPGA logic is ready. This signal will be inactive during PCI bus reset or Target FIFO clears. This signal is synchronous to
fclk
.
taenn O
Target Address and Command Register Output Enable.
This active-low sig­nal enables PCI addresses to be read from the Target address register of the PCI core, and PCI commands to be read from the Target command register. The PCI core will only execute enough address cycles to transfer the address within the matched page (higher-order bits are not stripped). This signal must be synchronous to
fclk
.
tcmd[3:0] I
Target Command Code.
This bus provides the command code for a new Tar-
get operation, and is valid when the FPGA senses
treqn
active-low.
Because it is synchron ous to
pciclk
, it must be qualified with
treqn
.
bar[2:0] I
Base Address Register Number.
This bus indicates which of the six BARs matched the address for the current Target operation, and is valid when the FPGA senses
treqn
active-low. The three 64-bit BARs are designated as num­bers 0, 2, and 4. Because it is synchron ous to
pciclk
, it must be qualified with
treqn
.
tstatecntr[2:0] I
Internal State Counter.
Used for target reads and writes. Details of the target state machine operation can be found in tables at the end of each operation section. This signal is synchronous to
fclk
.
Target Write Data FIFO Signals
twdataenn O
Target Write FIFO Data Enable.
This active-low signal enables data from the
PCI core Target write da t a F I FOs on t o bus
datatofpga
during Target write oper­ations on the rising edge of the Target FIFO clock signal. Valid data will be read from the FIFO whenever it is not empty. This signal must be synchronous to
fclk
.
tw_emptyn I
Target Write FIFO Empty.
This signal active indicates that the Target write FIFO is empty. This signal is synchronous to
fclk
.
tw_aemptyn I
Target Write FIFO Almost Empty.
This active-low signal indicates that only four more empty locations are available in the Target write FIFOs. This signal is synchronous to
fclk
.
tw_fulln I
Target Write Data FIFO Full Flag
. This active-low signal indicates that the tar­get write data FIFO is full. Refer to target write description on signal usage. This signal is synchronous to
pciclk
.
Lucent Technologies Inc. 25
Data Sheet
ORCA
OR3LP26B FPSC
Marc h 2000 Embedded Master/Target PCI Inte rface
Lucent Technologies Inc.
PCI Bus Core Detailed Description Dual Port
(continued)
Table 8. Embedded Core/FPGA Interface Signals
(continued)
S
y
mbol
I/O
Description
twlastcycn I
Target Write Last Data Cycle.
This active-low signal has two functions:
a. It is asserted low to indicate that the accompanying 32/64 bits of Target read or
write address information is the final portion being sent. It can also be asserted prior to any address portion being sent, indicating that the previous address is to be used.
b. It is asserted low to indicate that the accompanying T arget write data is the final
data for this operation. When more than one cycle is required to transfer a com­plete data word, this signal is only valid on the last cycle. This signal is synchronous to
fclk
.
Target Read Data FIFO Signals
twburstpendn O
Target Write Burst Data Availability Pending Flag.
This active-low signal directs the PCI core not to immediately disconnect when the Target write FIFO becomes full, but rather to insert PCI bus wait-states (up to the maximum allowed, and then disconnect). Once asserted, this signal needs to remain asserted for a minimum of two
pciclk
periods.
This signal must be synchronous to
pciclk
.
trdataenn O
Target Read FIFO Data Enable.
This active-low signal enables the registering of
bus
datafmfpga
during Target read operations into the PCI core Target read data
FIFOs on the rising edge of the Target FIFO clock signal. The signal
trdataenn
should not be asserted when the Target read data FIFOs are full, or data may be lost. This signal must be synchronous to
fclk
.
tr_fulln I
Target Read FIFO Full.
This signal is active-low and synchronous to the rising edge of the Target FIFO clock signal. The PCI core asserts this signal to indicate that the Target read FIFOs are full and that no more data can be clocked in. This signal is synchronous to
fclk
.
tr_afulln I
Target Read FIFO Almost Full.
This active-low signal indicates that the Target read FIFO has only four more empty locations available in the FIFOs. This signal is synchronous to
fclk
.
tr_emptyn I
Target Read Data FIFO Empty Flag.
This active-low signal indicates that the tar­get read data FIFO is empty. Refer to target read description on signal usage. This signal is synchronous to
pciclk
.
trpcihold O
Target Read PCI Bus Hold
. During burst transfers on the PCI bus, this signal delays the start of the transfer on the PCI bus, allowing the FPGA application to fill the FIFO. The transaction will begin when
trpcihold
is deasserted or the FIFO becomes full. Once asserted, this signal needs to remain asserted for a minimum of two
pciclk
periods.
This signal must be synchronous to
pciclk
.
trlastcycn I
Target Read Last Data Cycle.
This active-low signal is asserted to indicate that the accompanying Target read data is the final data for this operation. When more than one cycle is required to transfer a complete data word, this signal is only valid on the last cycle. During a read burst,
trlastcycn
may remain inactive for longer than it is required to complete the data transfer. If this occurs, the FPGA Target should continue to write data into the Target read FIFOs unless the incre­mented address crosses the address decode space of the FPGA Target. The address should be incremented by a double word as long as
trlastcycn
is inac­tive. This signal is synchronous to
fclk
.
ORCA
OR3LP26B FPSC Data Sheet
Embedded Master/Target PCI Interface
March 2000
26 Lucent Technologies Inc.
Lucent Technologies Inc.
PCI Bus Core Detailed Description Dual Port
(continued)
Table 8. Embedded Core/FPGA Interface Signals
(continued)
S
y
mbol
I/O
Description
trburstpendn O
Target Read Burst Data Availability Pending Flag.
This active-low signal directs the PCI core not to immediately disconnect when the Target read FIFO becomes empty, but rather to insert PCI bus wait-states (up to the maximum allowed, and then disconnect). Once asserted, this signal needs to remain asserted for a minimum of two
pciclk
periods.
This signal must be synchronous to
pciclk
.
Miscellaneous Signals
pci_intan O
PCI Interrupt Request
. This active-low signal is used to generate a PCI bus
interrupt and is forwarded by the PCI core as
intan
onto the PCI bus. Once
asserted, this signal needs to remain asserted for a minimum of two
pciclk
cycles. This signal must be synchronous to
pciclk
.
fclk1 fclk2
O O
FPGA Clock 1 and 2
. Clocks for use by the PCI core for Master and Target FIFOs. When the PCI clock domain extends into the FPGA, the FPGA may reroute the PCI clock back into
fclk1
or
fclk2
. External or user-defined clocks may
also be used. The signals
fclk1
and
fclk2
must be the same clock in dual-port
mode.
pciclk I
PCI Clock
. The signal
pciclk
is synchronous to
clk
and may be used by the
FPGA logic.
pci_rstn I
PCI Reset for Use by the FPGA Logic
. This active-low signal indicates that a
PCI bus reset was received from the PCI bus (
rstn
).
fpga_syserror O
System Error
. This active-high signal is used by the FPGA to generate a system
error on the PCI bus. This is passed to the PCI bus as
serrn
.
This signal must be synchronous to
pciclk
.
pci_64bit I
PCI Bus in 64-Bit Mode
. This active-high signal indicates that the PCI core detected that it is connected as a 64-bit agent to the PCI bus. This is the result of detecting PCI signal
req64n
as active (low) on the inactive-going (rising) edge of
PCI signal
rstn
. Note that this does not imply that any particular transaction is
64-bit, since each transaction is individually negotiated using PCI signals
req64n
and
ack64n
.
This signal is synchronous to
pciclk
.
fifo_sel O
FIFO Select.
An active-high signal that is valid in the dual-port modes to select
either Master read data (
fifo_sel
= 0) or Target write data (
fifo_sel
= 1).
This signal must be synchronous to
fclk
.
Lucent Technologies Inc. 27
Data Sheet
ORCA
OR3LP26B FPSC
Marc h 2000 Embedded Master/Target PCI Inte rface
Lucent Technologies Inc.
PCI Bus Core Detailed Description Dual Port
(continued)
Embedded Core/FPGA Interface Signal Locations
Table 9 lists the physical locations of all signals on the PCI core/FPGA interface. Separate names are provided for dual-port and quad-port bus signals, since their functionality is port mode dependent.
Table 9. OR3LP26B FPGA/PCI Core Interface Signal Locations
PCI Core/FPGA Interface Site FPGA Input Signal Name FPGA Output Signal Name
ASB1A pci_rstn pci_intan ASB1B pci_64bit (unused) ASB1C (unused) fpga_syserror ASB1D (unused) fpga_mbusyn ASB2A datatofpga31 datafmfpga31 ASB2B datatofpga30 datafmfpga30 ASB2C datatofpga29 datafmfpga29 ASB2D datatofpga28 datafmfpga28 ASB3A datatofpga27 datafmfpga27 ASB3B datatofpga26 datafmfpga26 ASB3C datatofpga25 datafmfpga25 ASB3D datatofpga24 datafmfpga24 ASB4A datatofpga23 datafmfpga23 ASB4B datatofpga22 datafmfpga22 ASB4C datatofpga21 datafmfpga21 ASB4D datatofpga20 datafmfpga20 ASB5A datatofpga19 datafmfpga19 ASB5B datatofpga18 datafmfpga18 ASB5C datatofpga17 datafmfpga17 ASB5D datatofpga16 datafmfpga16 ASB6A datatofpgax3 datafmfpgax3 ASB6B datatofpgax2 datafmfpgax2 ASB6C datatofpgax1 datafmfpgax1 ASB6D datatofpgax0 datafmfpgax0 ASB7A datatofpga15 datafmfpga15 ASB7B datatofpga14 datafmfpga14 ASB7C datatofpga13 datafmfpga13 ASB7D datatofpga12 datafmfpga12 ASB8A datatofpga11 datafmfpga11 ASB8B datatofpga10 datafmfpga10 ASB8C datatofpga9 datafmfpga9 ASB8D datatofpga8 datafmfpga8 ASB9A datatofpga7 datafmfpga7 ASB9B datatofpga6 datafmfpga6 ASB9C datatofpga5 datafmfpga5 ASB9D datatofpga4 datafmfpga4
CKTOASB9 (unused) fclk1
ORCA
OR3LP26B FPSC Data Sheet
Embedded Master/Target PCI Interface
March 2000
28 Lucent Technologies Inc.
Lucent Technologies Inc.
PCI Bus Core Detailed Description Dual Port
(continued)
Table 9. OR3LP26B FPGA/PCI Core Interface Signal Locations
(continued)
PCI Core/FPGA Interface Site FPGA Input Signal Name FPGA Output Signal Name
ASB10A datatofpga3 datafmfpga3
ASB10B datatofpga2 datafmfpga2 ASB10C datatofpga1 datafmfpga1 ASB10D datatofpga0 datafmfpga0
ASB11A tstatecntr0 (unused)
ASB11B tstatecntr1 (unused) ASB11C tstatecntr2 (unused) ASB11D pci_tcfg_stat tcfgshiftenn
ASB12A tcmd0 (unused)
ASB12B tcmd1 (unused) ASB12C tcmd2 (unused) ASB12D tcmd3 twburstpendn
ASB13A bar0 trburstpendn
ASB13B bar1 fpga_tabort ASB13C bar2 fpga_tretryn ASB13D disctimerexpn deltrn
ASB14A treqn taenn
ASB14B twlastcycn twdataenn ASB14C tw_emptyn fifo_sel ASB14D tw_aemptyn (unused)
CKFMASB14 pciclk (unused)
ASB15A t_ready tfifoclrN
ASB15B trlastcycn trdataenn ASB15C tr_fulln (unused) ASB15D tr_afulln (unused)
ASB16A tw_fulln trpcihold
ASB16B tr_emptyn mwpcihold ASB16C mw_emptyn fpga_mstopburstn ASB16D mr_fulln (unused)
ASB17A ma_fulln maenn
ASB17B mw_fulln mwdataenn ASB17C mw_afulln mwlastcycn ASB17D m_ready mrdataenn
ASB18A mrlastcycn mcmd0
ASB18B mr_emptyn mcmd1 ASB18C mr_aemptyn mcmd2 ASB18D fpga_msyserror mcmd3
ASB19A datatofpga32 datafmfpga32
ASB19B datatofpga33 datafmfpga33 ASB19C datatofpga34 datafmfpga34 ASB19D datatofpga35 datafmfpga35
CKTOASB19 (unused) fclk2
ASB20A datatofpga36 datafmfpga36
Lucent Technologies Inc. 29
Data Sheet
ORCA
OR3LP26B FPSC
Marc h 2000 Embedded Master/Target PCI Inte rface
Lucent Technologies Inc.
PCI Bus Core Detailed Description Dual Port
(continued)
Table 9. OR3LP26B FPGA/PCI Core Interface Signal Locations
(continued)
PCI Core/FPGA Interface Site FPGA Input Signal Name FPGA Output Signal Name
ASB20B datatofpga37 datafmfpga37 ASB20C datatofpga38 datafmfpga38 ASB20D datatofpga39 datafmfpga39 ASB21A datatofpga40 datafmfpga40 ASB21B datatofpga41 datafmfpga41 ASB21C datatofpga42 datafmfpga42 ASB21D datatofpga43 datafmfpga43 ASB22A datatofpga44 datafmfpga44 ASB22B datatofpga45 datafmfpga45 ASB22C datatofpga46 datafmfpga46 ASB22D datatofpga47 datafmfpga47 ASB23A datatofpgax4 datafmfpgax4 ASB23B datatofpgax5 datafmfpgax5 ASB23C datatofpgax6 datafmfpgax6 ASB23D datatofpgax7 datafmfpgax7 ASB24A datatofpga48 datafmfpga48 ASB24B datatofpga49 datafmfpga49 ASB24C datatofpga50 datafmfpga50 ASB24D datatofpga51 datafmfpga51 ASB25A datatofpga52 datafmfpga52 ASB25B datatofpga53 datafmfpga53 ASB25C datatofpga54 datafmfpga54 ASB25D datatofpga55 datafmfpga55 ASB26A datatofpga56 datafmfpga56 ASB26B datatofpga57 datafmfpga57 ASB26C datatofpga58 datafmfpga58 ASB26D datatofpga59 datafmfpga59 ASB27A datatofpga60 datafmfpga60 ASB27B datatofpga61 datafmfpga61 ASB27C datatofpga62 datafmfpga62 ASB27D datatofpga63 datafmfpga63 ASB28A mstatecntr0 mfifoclrn ASB28B mstatecntr1 (unused) ASB28C mstatecntr2 (unused) ASB28D pci_mcfg_stat mcfgshiftenn
ORCA
OR3LP26B FPSC Data Sheet
Embedded Master/Target PCI Interface
March 2000
30 Lucent Technologies Inc.
Lucent Technologies Inc.
PCI Bus Core Detailed Description Dual Port
(continued)
Table 10. Bit Definitions on FPGA/PCI Core Interface
* Command Codes (codes correspond to PCI bus command codes): 0000 Not Used (interrupt acknowledge not implemented) 0001 Not Used (special cycle not implemented) 0010 I/O Read 0011 I/O Write 0100 Reserved (per PCI specification) 0101 Reserved (per PCI specification) 0110 Memory Read 0111 Memory Write 1000 Reserved (per PCI specification) 1001 Reserved (per PCI specification) 1010 Configuration Read 1011 Configuration Write 1100 Memory Read Multiple 1101 Not Used (dual address operation is indicated via separate signal) 1110 Memory Read Line 1111 Memory Write and Invalidate
Bits Name Description
A.
Dual-Port Master Write, Command and Address mstatecntr = 0
datafmfpgax[7:3] Unused
datafmfpgax[2] DA Dual address indicator (active-high)
datafmfpgax[1:0] Unused
datafmfpga[63:32] A3 & A2 Address words 3 and 2 (if DA = 1; else must set
all bits to 0s)
datafmfpga[31:0] A1 & A0 Address words 1 and 0
mcmd[3:0] mcmd Master command opcode*
B. Dual-Port Master Write, Data mstatecntr = 4
datafmfpgax[7:0] BE7—BE0 Byte enables (active-low)
datafmfpga[63:0] D7—D0 Data bytes 7 to 0
C. Dual-Port Master Read (Burst Length Cycle) mstatecntr = 0
datafmfpgax[7:3] Unused
datafmfpgax[2] DA Dual address indicator (active-high)
datafmfpgax[1:0] Unused datafmfpga[63:56] mrd_benn Byte enables (active-low) datafmfpga[55:50] Unused datafmfpg a[49:32] BL Burst length (in Quadwords)
datafmfpga[31:0] A1 & A0 Address words 1 and 0 (set to all 0s if 64-bit
address required—A1 & A0 supplied in next
cycle)
mcmd[3:0] mcmd Master command opcode*
D. Dual-Port Master Read (64-Bit Address Cycle) mstatecntr = 1
datafmfpgax[7:0] Unused datafmfpga[63:32] A3 & A2 Address words 3 and 2
datafmfpga[31:0] A1 & A0 Address words 1 and 0
mcmd[3:0] Unused
E. Dual-Port Master Read, Data mstatecntr = 4
datatofpgax[7:0] Unused datatofpga[63:0] D7—D0 Data bytes 7 to 0
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