PMC PM7364-BI

PM7364 FREEDM-32
RELEASED
DATA SHEET
PMC-1960758
ISSUE 6
FRAME ENGINE AND DATA LINK MANAGER
PM7364
FREEDM™-32
FRAME ENGINE AND DATALINK
MANAGER
DATA SHEET
ISSUE 6: AUGUST 2001
PROPRIETARY AND CONFIDENTIAL TO PMC-SIERRA, INC., AND FOR ITS CUSTOMER’S INTERNAL USE
PM7364 FREEDM-32
RELEASED
DATA SHEET
PMC-1960758
ISSUE 6
FRAME ENGINE AND DATA LINK MANAGER
PUBLIC REVISION HISTORY
Issue No.
Issue Date
Details of Change
6
August
2001
Patent information added to legal footer.
5
May 1998
Document re-issue.
4
April 1998
Document re-issue.
3
October
1997
Document re-formatted.
2
April 23,
1997
Pin Diagram page replaced.
Two entries added to Pin table diagram.
Added AC, DC Timing section and 256 BGA
mechanical package information.
1
July 24,
1996
Creation of Data Sheet
PROPRIETARY AND CONFIDENTIAL TO PMC-SIERRA, INC., AND FOR ITS CUSTOMER’S INTERNAL USE
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PM7364 FREEDM-32
RELEASED
DATA SHEET
PMC-1960758
ISSUE 6
FRAME ENGINE AND DATA LINK MANAGER
CONTENTS
1
FEATURES...............................................................................................1
2
APPLICATIONS........................................................................................3
3
REFERENCES .........................................................................................4
4
APPLICATION EXAMPLES ......................................................................5
5
BLOCK DIAGRAM....................................................................................6
6
DESCRIPTION .........................................................................................7
7
PIN DIAGRAM ..........................................................................................9
8
PIN DESCRIPTION ................................................................................10
9
FUNCTIONAL DESCRIPTION ...............................................................31
9.1
HIGH-LEVEL DATA LINK CONTROL PROTOCOL......................31
9.2
RECEIVE CHANNEL ASSIGNER ................................................32
9.3
9.4
9.2.1
LINE INTERFACE..........................................................33
9.2.2
PRIORITY ENCODER ...................................................33
9.2.3
CHANNEL ASSIGNER ..................................................33
9.2.4
LOOPBACK CONTROLLER .........................................34
RECEIVE HDLC PROCESSOR / PARTIAL PACKET BUFFER...34
9.3.1
HDLC PROCESSOR .....................................................34
9.3.2
PARTIAL PACKET BUFFER PROCESSOR ..................35
RECEIVE DMA CONTROLLER ...................................................37
9.4.1
DATA STRUCTURES ....................................................37
9.4.2
DMA TRANSACTION CONTROLLER...........................47
9.4.3
WRITE DATA PIPELINE/MUX .......................................47
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RELEASED
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ISSUE 6
9.5
9.6
9.7
9.8
FRAME ENGINE AND DATA LINK MANAGER
9.4.4
DESCRIPTOR INFORMATION CACHE ........................47
9.4.5
FREE QUEUE CACHE ..................................................47
PCI CONTROLLER......................................................................48
9.5.1
MASTER MACHINE ......................................................49
9.5.2
MASTER LOCAL BUS INTERFACE..............................51
9.5.3
TARGET MACHINE .......................................................52
9.5.4
CBI BUS INTERFACE ...................................................54
9.5.5
ERROR / BUS CONTROL .............................................54
TRANSMIT DMA CONTROLLER.................................................54
9.6.1
DATA STRUCTURES ....................................................55
9.6.2
TASK PRIORITIES ........................................................67
9.6.3
DMA TRANSACTION CONTROLLER...........................67
9.6.4
READ DATA PIPELINE..................................................67
9.6.5
DESCRIPTOR INFORMATION CACHE ........................67
9.6.6
FREE QUEUE CACHE ..................................................67
TRANSMIT HDLC CONTROLLER / PARTIAL PACKET BUFFER68
9.7.1
TRANSMIT HDLC PROCESSOR..................................68
9.7.2
TRANSMIT PARTIAL PACKET BUFFER PROCESSOR69
TRANSMIT CHANNEL ASSIGNER .............................................71
9.8.1
LINE INTERFACE..........................................................72
9.8.2
PRIORITY ENCODER ...................................................72
9.8.3
CHANNEL ASSIGNER ..................................................73
9.9
PERFORMANCE MONITOR .......................................................73
9.10
JTAG TEST ACCESS PORT INTERFACE...................................73
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RELEASED
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ISSUE 6
9.11
10
13
14
PCI HOST ACCESSIBLE REGISTERS .......................................79
PCI CONFIGURATION REGISTER DESCRIPTION ............................251
11.1
12
PCI HOST INTERFACE ...............................................................73
NORMAL MODE REGISTER DESCRIPTION ........................................79
10.1
11
FRAME ENGINE AND DATA LINK MANAGER
PCI CONFIGURATION REGISTERS.........................................251
TEST FEATURES DESCRIPTION .......................................................262
12.1
TEST MODE REGISTERS ........................................................262
12.2
JTAG TEST PORT .....................................................................263
12.2.1
IDENTIFICATION REGISTER .....................................264
12.2.2
BOUNDARY SCAN REGISTER ..................................264
OPERATIONS ......................................................................................278
13.1
EQUAD CONNECTIONS...........................................................278
13.2
TOCTL CONNECTIONS ............................................................278
13.3
JTAG SUPPORT........................................................................279
FUNCTIONAL TIMING .........................................................................285
14.1
RECEIVE LINK INPUT TIMING .................................................285
14.2
TRANSMIT LINK OUTPUT TIMING...........................................286
14.3
PCI INTERFACE ........................................................................288
14.4
BERT INTERFACE ....................................................................297
15
ABSOLUTE MAXIMUM RATINGS........................................................299
16
D.C. CHARACTERISTICS....................................................................300
17
FREEDM-32 TIMING CHARACTERISTICS .........................................302
18
ORDERING AND THERMAL INFORMATION ......................................308
19
MECHANICAL INFORMATION.............................................................309
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RELEASED
DATA SHEET
PMC-1960758
ISSUE 6
FRAME ENGINE AND DATA LINK MANAGER
LIST OF REGISTERS
REGISTER 0X000 : FREEDM-32 MASTER RESET.........................................80
REGISTER 0X004 : FREEDM-32 MASTER INTERRUPT ENABLE .................82
REGISTER 0X008 : FREEDM-32 MASTER INTERRUPT STATUS .................87
REGISTER 0X00C : FREEDM-32 MASTER CLOCK / BERT ACTIVITY
MONITOR AND ACCUMULATION TRIGGER ........................................91
REGISTER 0X010 : FREEDM-32 MASTER LINK ACTIVITY MONITOR..........93
REGISTER 0X014 : FREEDM-32 MASTER LINE LOOPBACK #1...................97
REGISTER 0X018 : FREEDM-32 MASTER LINE LOOPBACK #2...................99
REGISTER 0X020 : FREEDM-32 MASTER BERT CONTROL.......................101
REGISTER 0X024 : FREEDM-32 MASTER PERFORMANCE MONITOR
CONTROL ............................................................................................103
REGISTER 0X040 : GPIC CONTROL ............................................................107
REGISTER 0X100 : RCAS INDIRECT LINK AND TIME-SLOT SELECT........ 110
REGISTER 0X104 : RCAS INDIRECT CHANNEL DATA ................................ 112
REGISTER 0X108 : RCAS FRAMING BIT THRESHOLD............................... 114
REGISTER 0X10C : RCAS CHANNEL DISABLE ........................................... 116
REGISTER 0X180 : RCAS LINK #0 CONFIGURATION ................................. 118
REGISTER 0X184 - 0X188 : RCAS LINK #1 TO #2 CONFIGURATION.........120
REGISTER 0X18C : RCAS LINK #3 CONFIGURATION ................................122
REGISTER 0X190-0X1FC : RCAS LINK #4 TO LINK #31 CONFIGURATION124
REGISTER 0X200 : RHDL INDIRECT CHANNEL SELECT ...........................126
REGISTER 0X204 : RHDL INDIRECT CHANNEL DATA REGISTER #1 ........128
REGISTER 0X208 : RHDL INDIRECT CHANNEL DATA REGISTER #2 ........131
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RELEASED
DATA SHEET
PMC-1960758
ISSUE 6
FRAME ENGINE AND DATA LINK MANAGER
REGISTER 0X210 : RHDL INDIRECT BLOCK SELECT ................................134
REGISTER 0X214 : RHDL INDIRECT BLOCK DATA .....................................136
REGISTER 0X220 : RHDL CONFIGURATION ...............................................138
REGISTER 0X224 : RHDL MAXIMUM PACKET LENGTH .............................140
REGISTER 0X280 : RMAC CONTROL...........................................................142
REGISTER 0X284 : RMAC INDIRECT CHANNEL PROVISIONING ..............145
REGISTER 0X288 : RMAC PACKET DESCRIPTOR TABLE BASE LSW ......147
REGISTER 0X28C : RMAC PACKET DESCRIPTOR TABLE BASE MSW.....148
REGISTER 0X290 : RMAC QUEUE BASE LSW ............................................150
REGISTER 0X294 : RMAC QUEUE BASE MSW ...........................................151
REGISTER 0X298 : RMAC PACKET DESCRIPTOR REFERENCE LARGE
BUFFER FREE QUEUE START...........................................................153
REGISTER 0X29C : RMAC PACKET DESCRIPTOR REFERENCE LARGE
BUFFER FREE QUEUE WRITE ..........................................................155
REGISTER 0X2A0 : RMAC PACKET DESCRIPTOR REFERENCE LARGE
BUFFER FREE QUEUE READ ............................................................157
REGISTER 0X2A4 : RMAC PACKET DESCRIPTOR REFERENCE LARGE
BUFFER FREE QUEUE END...............................................................159
REGISTER 0X2A8 : RMAC PACKET DESCRIPTOR REFERENCE SMALL
BUFFER FREE QUEUE START...........................................................161
REGISTER 0X2AC : RMAC PACKET DESCRIPTOR REFERENCE SMALL
BUFFER FREE QUEUE WRITE ..........................................................163
REGISTER 0X2B0 : RMAC PACKET DESCRIPTOR REFERENCE SMALL
BUFFER FREE QUEUE READ ............................................................165
REGISTER 0X2B4 : RMAC PACKET DESCRIPTOR REFERENCE SMALL
BUFFER FREE QUEUE END...............................................................167
REGISTER 0X2B8 : RMAC PACKET DESCRIPTOR REFERENCE READY
QUEUE START ....................................................................................169
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RELEASED
DATA SHEET
PMC-1960758
ISSUE 6
FRAME ENGINE AND DATA LINK MANAGER
REGISTER 0X2BC : RMAC PACKET DESCRIPTOR REFERENCE READY
QUEUE WRITE ....................................................................................171
REGISTER 0X2C0 : RMAC PACKET DESCRIPTOR REFERENCE READY
QUEUE READ ......................................................................................173
REGISTER 0X2C4 : RMAC PACKET DESCRIPTOR REFERENCE READY
QUEUE END ........................................................................................175
REGISTER 0X300 : TMAC CONTROL ...........................................................177
REGISTER 0X304 : TMAC INDIRECT CHANNEL PROVISIONING...............180
REGISTER 0X308 : TMAC DESCRIPTOR TABLE BASE LSW......................182
REGISTER 0X30C : TMAC DESCRIPTOR TABLE BASE MSW ....................183
REGISTER 0X310 : TMAC QUEUE BASE LSW ............................................185
REGISTER 0X314 : TMAC QUEUE BASE MSW ...........................................186
REGISTER 0X318 : TMAC DESCRIPTOR REFERENCE FREE QUEUE START
..............................................................................................................188
REGISTER 0X31C TMAC DESCRIPTOR REFERENCE FREE QUEUE WRITE
..............................................................................................................190
REGISTER 0X320 : TMAC DESCRIPTOR REFERENCE FREE QUEUE READ
..............................................................................................................192
REGISTER 0X324 : TMAC DESCRIPTOR REFERENCE FREE QUEUE END
..............................................................................................................194
REGISTER 0X328 :TMAC DESCRIPTOR REFERENCE READY QUEUE
START ..................................................................................................196
REGISTER 0X32C : TMAC DESCRIPTOR REFERENCE READY QUEUE
WRITE ..................................................................................................198
REGISTER 0X330 : TMAC DESCRIPTOR REFERENCE READY QUEUE READ200
REGISTER 0X334 : TMAC DESCRIPTOR REFERENCE READY QUEUE END
..............................................................................................................202
REGISTER 0X380 : THDL INDIRECT CHANNEL SELECT............................204
REGISTER 0X384 : THDL INDIRECT CHANNEL DATA #1 ............................206
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RELEASED
DATA SHEET
PMC-1960758
ISSUE 6
FRAME ENGINE AND DATA LINK MANAGER
REGISTER 0X388 : THDL INDIRECT CHANNEL DATA #2 ............................209
REGISTER 0X38C : THDL INDIRECT CHANNEL DATA #3 ...........................212
REGISTER 0X3A0 : THDL INDIRECT BLOCK SELECT ................................217
REGISTER 0X3A4 : THDL INDIRECT BLOCK DATA .....................................219
REGISTER 0X3B0 : THDL CONFIGURATION ...............................................221
REGISTER 0X400 : TCAS INDIRECT LINK AND TIME-SLOT SELECT ........223
REGISTER 0X404 : TCAS INDIRECT CHANNEL DATA ................................225
REGISTER 0X408 : TCAS FRAMING BIT THRESHOLD ...............................227
REGISTER 0X40C : TCAS IDLE TIME-SLOT FILL DATA...............................229
REGISTER 0X410 : TCAS CHANNEL DISABLE ............................................231
REGISTER 0X480 : TCAS LINK #0 CONFIGURATION .................................233
REGISTER 0X484-0X488 : TCAS LINK #1 TO LINK #2 CONFIGURATION ..235
REGISTER 0X48C : TCAS LINK #3 CONFIGURATION .................................237
REGISTER 0X490-0X4FC : TCAS LINK #4 TO LINK #31 CONFIGURATION239
REGISTER 0X500 : PMON STATUS ..............................................................241
REGISTER 0X504 : PMON RECEIVE FIFO OVERFLOW COUNT................243
REGISTER 0X508 : PMON RECEIVE FIFO UNDERFLOW COUNT .............245
REGISTER 0X50C : PMON CONFIGURABLE COUNT #1.............................247
REGISTER 0X510 : PMON CONFIGURABLE COUNT #2 .............................249
REGISTER 0X00 : VENDOR IDENTIFICATION/DEVICE IDENTIFICATION..252
REGISTER 0X04 : COMMAND/STATUS ........................................................253
REGISTER 0X08 : REVISION IDENTIFIER/CLASS CODE............................257
REGISTER 0X0C : CACHE LINE SIZE/LATENCY TIMER/HEADER TYPE ...258
REGISTER 0X10 : CBI MEMORY BASE ADDRESS REGISTER...................259
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ISSUE 6
FRAME ENGINE AND DATA LINK MANAGER
REGISTER 0X3C : INTERRUPT LINE / INTERRUPT PIN / MIN_GNT /
MAX_LAT..............................................................................................261
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ISSUE 6
FRAME ENGINE AND DATA LINK MANAGER
LIST OF FIGURES
FIGURE 1 – HDLC FRAME...............................................................................31
FIGURE 2 – CRC GENERATOR.......................................................................32
FIGURE 3 – PARTIAL PACKET BUFFER STRUCTURE ..................................36
FIGURE 4 – RECEIVE PACKET DESCRIPTOR...............................................38
FIGURE 5 – RECEIVE PACKET DESCRIPTOR TABLE...................................41
FIGURE 6 – RPDRF AND RPDRR QUEUES ...................................................43
FIGURE 7 – RPDRR QUEUE OPERATION......................................................45
FIGURE 8 – RECEIVE CHANNEL DESCRIPTOR REFERENCE TABLE.........46
FIGURE 9 – GPIC ADDRESS MAP ..................................................................53
FIGURE 10 – TRANSMIT DESCRIPTOR .........................................................55
FIGURE 11 – TRANSMIT DESCRIPTOR TABLE .............................................59
FIGURE 12 – TDRR AND TDRF QUEUES .......................................................61
FIGURE 13 – TRANSMIT CHANNEL DESCRIPTOR REFERENCE TABLE ....63
FIGURE 14 – TD LINKING................................................................................66
FIGURE 15 – PARTIAL PACKET BUFFER STRUCTURE ................................70
FIGURE 16 – INPUT OBSERVATION CELL (IN_CELL) .................................275
FIGURE 17 – OUTPUT CELL (OUT_CELL) ...................................................276
FIGURE 18 – BI-DIRECTIONAL CELL (IO_CELL) .........................................276
FIGURE 19 – LAYOUT OF OUTPUT ENABLE AND BI-DIRECTIONAL CELLS
..............................................................................................................277
FIGURE 20 – BOUNDARY SCAN ARCHITECTURE ......................................279
FIGURE 21 – TAP CONTROLLER FINITE STATE MACHINE ........................281
FIGURE 22 – UNCHANNELISED RECEIVE LINK TIMING ............................285
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FIGURE 23 – CHANNELISED T1 RECEIVE LINK TIMING ............................286
FIGURE 24 – CHANNELISED E1 RECEIVE LINK TIMING ............................286
FIGURE 25 – UNCHANNELISED TRANSMIT LINK TIMING..........................287
FIGURE 26 – CHANNELISED T1 TRANSMIT LINK TIMING..........................287
FIGURE 27 – CHANNELISED E1 TRANSMIT LINK TIMING .........................288
FIGURE 28 – PCI READ CYCLE ....................................................................289
FIGURE 29 – PCI WRITE CYCLE ..................................................................291
FIGURE 30 – PCI TARGET DISCONNECT ....................................................292
FIGURE 31 – PCI TARGET ABORT................................................................292
FIGURE 32 – PCI BUS REQUEST CYCLE ....................................................293
FIGURE 33 – PCI INITIATOR ABORT TERMINATION ...................................294
FIGURE 34 – PCI EXCLUSIVE LOCK CYCLE ...............................................295
FIGURE 35 – PCI FAST BACK TO BACK.......................................................297
FIGURE 36 – RECEIVE BERT PORT TIMING ...............................................297
FIGURE 37 – TRANSMIT BERT PORT TIMING .............................................298
FIGURE 38 – RECEIVE LINK INPUT TIMING ................................................303
FIGURE 39 – BERT INPUT TIMING ...............................................................303
FIGURE 40 – TRANSMIT LINK OUTPUT TIMING..........................................305
FIGURE 41 – BERT OUTPUT TIMING ...........................................................305
FIGURE 42 – PCI INTERFACE TIMING .........................................................306
FIGURE 43 – JTAG PORT INTERFACE TIMING............................................307
FIGURE 44 – 256 PIN ENHANCED BALL GRID ARRAY (SBGA) ..................309
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FRAME ENGINE AND DATA LINK MANAGER
LIST OF TABLES
TABLE 1 – LINE SIDE INTERFACE SIGNALS (132) ........................................10
TABLE 2 – PCI HOST INTERFACE SIGNALS (51) ..........................................15
TABLE 3 – MISCELLANEOUS INTERFACE SIGNALS (13).............................24
TABLE 4 – PRODUCTION TEST INTERFACE SIGNALS (0 - MULTIPLEXED)26
TABLE 5 – POWER AND GROUND SIGNALS (60) .........................................28
TABLE 6 – RECEIVE PACKET DESCRIPTOR FIELDS....................................38
TABLE 7 – RPDRR QUEUE ELEMENT ............................................................44
TABLE 8 – RECEIVE CHANNEL DESCRIPTOR REFERENCE TABLE FIELDS
................................................................................................................46
TABLE 9 – TRANSMIT DESCRIPTOR FIELDS ................................................56
TABLE 10 – TRANSMIT DESCRIPTOR REFERENCE.....................................62
TABLE 11 – TRANSMIT CHANNEL DESCRIPTOR REFERENCE TABLE
FIELDS ...................................................................................................64
TABLE 12 – NORMAL MODE PCI HOST ACCESSIBLE REGISTER MEMORY
MAP ........................................................................................................74
TABLE 13 – PCI CONFIGURATION REGISTER MEMORY MAP.....................78
TABLE 14 – BIG ENDIAN FORMAT................................................................108
TABLE 15 – LITTLE ENDIAN FORMAT ..........................................................108
TABLE 16 – CRC[1:0] SETTINGS...................................................................130
TABLE 17 – RPQ_RDYN[2:0] SETTINGS ......................................................143
TABLE 18 – RPQ_LFN[1:0] SETTINGS..........................................................144
TABLE 19 – RPQ_SFN[1:0] SETTINGS .........................................................144
TABLE 20 – TDQ_RDYN[2:0] SETTINGS.......................................................178
TABLE 21 – TDQ_FRN[1:0] SETTINGS .........................................................178
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TABLE 22 – CRC[1:0] SETTINGS...................................................................207
TABLE 23 – FLAG[2:0] SETTINGS .................................................................213
TABLE 24 – LEVEL[3:0]/TRANS SETTINGS ..................................................215
TABLE 25 – TEST MODE REGISTER MEMORY MAP ..................................263
TABLE 26 – INSTRUCTION REGISTER ........................................................264
TABLE 27 – BOUNDARY SCAN CHAIN .........................................................265
TABLE 28 – FREEDM–EQUAD CONNECTIONS ...........................................278
TABLE 29 – FREEDM–TOCTAL CONNECTIONS ..........................................278
TABLE 30 – FREEDM-32 ABSOLUTE MAXIMUM RATINGS .........................299
TABLE 31 – FREEDM-32 D.C. CHARACTERISTICS .....................................300
TABLE 32 – FREEDM-32 LINK INPUT (FIGURE 38, FIGURE 39) .................302
TABLE 33 – FREEDM-32 LINK OUTPUT (FIGURE 40, FIGURE 41) .............304
TABLE 34 – PCI INTERFACE (FIGURE 42) ...................................................305
TABLE 35 – JTAG PORT INTERFACE (FIGURE 43)......................................306
TABLE 36 – FREEDM-32 ORDERING INFORMATION ..................................308
TABLE 37 – FREEDM-32 THERMAL INFORMATION ....................................308
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FEATURES
·
Single-chip Peripheral Component Interconnect (PCI) Bus multi-channel
HDLC controller.
·
Supports up to 128 bi-directional HDLC channels assigned to a maximum of
32 channelised T1 or E1 links. The number of time-slots assigned to an
HDLC channel is programmable from 1 to 24 (for T1) and from 1 to 31 (for
E1).
·
Supports up to 32 bi-directional HDLC channels each assigned to an
unchannelised arbitrary rate link; subject to a maximum aggregate link clock
rate of 64 MHz in each direction. Channels assigned to links 0 to 2 can have
a clock rate of up to 45 MHz when SYSCLK is at or above 25 MHz and up to
52 MHz when SYSCLK is at 33 MHz. Channels assigned to links 3 to 31 can
have a clock rate of up to 10 MHz.
·
Supports up to two bi-directional HDLC channels each assigned to an
unchannelised arbitrary rate link of up to 45 MHz when SYSCLK is at or
above 25 MHz and up to 52 MHz when SYSCLK is at 33 MHz.
·
Supports a mix of up to 32 channelised and unchannelised links; subject to
the constraint of a maximum of 128 channels and a maximum aggregate link
clock rate of 64 MHz in each direction.
·
For each channel, the HDLC receiver performs flag sequence detection, bit
de-stuffing, and frame check sequence validation. The receiver supports the
validation of both CRC-CCITT and CRC-32 frame check sequences. The
receiver also checks for packet abort sequences, octet aligned packet length
and for minimum and maximum packet length.
·
Alternatively, for each channel, the receiver supports a transparent mode
where each octet is transferred transparently to host memory. For
channelised links, the octets are aligned with the receive time-slots.
·
For each channel, time-slots are selectable to be in 56 kbits/s format or 64
kbits/s clear channel format.
·
For each channel, the HDLC transmitter performs flag sequence generation,
bit stuffing, and, optionally, frame check sequence generation. The
transmitter supports the generation of both CRC-CCITT and CRC-32 frame
check sequences. The transmitter also aborts packets under the direction of
the host or automatically when the channel underflows.
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FRAME ENGINE AND DATA LINK MANAGER
·
Supports two levels of non-preemptive packet priority on each transmit
channel. Low priority packets will not begin transmission until all high priority
packets are transmitted.
·
Alternatively, for each channel, the transmitter supports a transparent mode
where each octet is inserted transparently from host memory. For
channelised links, the octets are aligned with the transmit time-slots.
·
Directly supports a 32-bit, 33 MHz PCI 2.1 interface for configuration,
monitoring and transfer of packet data, with an on-chip DMA controller with
scatter/gather capabilities.
·
Provides 8 kbytes of on-chip memory for partial packet buffering in each
direction. This memory can be configured to support a variety of different
channel configurations from a single channel with 8 kbytes of buffering to 128
channels, each with a minimum of 48 bytes of buffering.
·
Supports PCI burst sizes of up to 128 bytes for transfers of packet data.
·
Pin compatible with PM7366 (FREEDM-8) device.
·
Provides a standard 5 signal P1149.1 JTAG test port for boundary scan board
test purposes.
·
Supports 3.3 and 5 Volt PCI signaling environments.
·
Low power CMOS technology.
·
256 pin enhanced ball grid array (SBGA) package (27 mm X 27 mm).
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APPLICATIONS
·
IETF PPP interfaces for routers
·
Frame Relay interfaces for ATM or Frame Relay switches and multiplexors
·
FUNI or Frame Relay service inter-working interfaces for ATM switches and
multiplexors.
·
D-channel processing in ISDN terminals and switches.
·
Internet/Intranet access equipment.
·
Packet-based DSLAM equipment.
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REFERENCES
1. International Organization for Standardization, ISO Standard 3309-1993,
"Information Technology - Telecommunications and information exchange
between systems - High-level data link control (HDLC) procedures - Frame
structure", December 1993.
2. RFC-1662 - "PPP in HDLC-like Framing" Internet Engineering Task Force,
July 1994.
3. PCI Special Interest Group, PCI Local Bus Specification, June 1, 1995,
Version 2.1.
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APPLICATION EXAMPLES
HDLC BASED UPLINK SIDE
ACCESS SIDE
DS3
PM8313
D3MX
PM4388
TOCTL
M13 Access Module
T1
PM4314
QDSX
PM4388
TOCTL
T1 Access Modu le
E1
PM4314
QDSX
PM6344
EQUAD
PM7364
FREEDM
FREEDM-32
HSSI
Module
PCI Bus
DS3/E3
Framer
LIU
Packet
Memory
Microprocessor
HSSI
DS3/E3/J2
HDLC Based
Uplink Module
Processor Module
E1 Access Module
ATM CELL BASED UPLINK SIDE
ACCESS SIDE
PM7345
S/UNI-PDH
PM7364
FREEDM-32
DS-3/E3 ATM
SAR
PCI Bus
xDSL
XDSL
PHY
T3/E3
PM5346
PM5348
S/UNI-LITE S/UNI-DUAL
OC-3
STS-3c ATM UNI
Packet
Memory
Microprocessor
xDSL Access Module
PM7322
RCMP
PM5347
S/UNI-PLUS
OC-3
STS-3c ATM NNI
PM5355
S/UNI-622
Processor Module
OC-12
STS-12c ATM UNI/NNI
PROPRIETARY AND CONFIDENTIAL TO PMC-SIERRA, INC., AND FOR ITS CUSTOMER’S INTERNAL USE
5
TCLK[31:0]
RBD
TD[31:0]
Transmit
Channel
Assigner
(TCAS)
Transmit HDLC Processor /
Partial Packet Buffer
(THDL)
Transmit
DMA
Controller
(TMAC)
Receive
DMA
Controller
(RMAC)
JTAG Port
PCI
Controller
(GPIC)
RSTB
Performance Monitor
(PMON)
Receive HDLC Processor /
Partial Packet Buffer
(RHDL)
REQB
GNTB
PERRB
SERRB
PCIINTB
PCICLK
PCICLKO
SYSCLK
AD[31:0]
C/BEB[3:0]
PAR
FRAMEB
TRDYB
IRDYB
STOPB
DEVSELB
IDSEL
LOCKB
PMC-1960758
RCLK[31:0]
RBCLK
Receive
Channel
Assigner
(RCAS)
5
RD[31:0]
RELEASED
PM7364 FREEDM-32
DATA SHEET
ISSUE 6
FRAME ENGINE AND DATA LINK MANAGER
BLOCK DIAGRAM
.
PMCTEST
TDO
TDI
TCK
TMS
TRSTB
TBCLK
TBD
PROPRIETARY AND CONFIDENTIAL TO PMC-SIERRA, INC., AND FOR ITS CUSTOMER’S INTERNAL USE
6
PM7364 FREEDM-32
RELEASED
DATA SHEET
PMC-1960758
6
ISSUE 6
FRAME ENGINE AND DATA LINK MANAGER
DESCRIPTION
The PM7364 FREEDM-32 Frame Engine and Datalink Manager device is a
monolithic integrated circuit that implements HDLC processing, and PCI Bus
memory management functions for a maximum of 128 bi-directional channels.
For channelised links, the FREEDM-32 allows up to 128 bi-directional HDLC
channels to be assigned to individual time-slots within a maximum of 32
independently timed T1 or E1 links. The channel assignment supports the
concatenation of time-slots (N x DS0) up to a maximum of 24 concatenated timeslots for a T1 link and 31 concatenated time-slots for an E1 link. Time-slots
assigned to any particular channel need not be contiguous within the T1 or E1
link.
For unchannelised links, the FREEDM-32 processes up to 32 bi-directional
HDLC channels within 32 independently timed links. The links can be of
arbitrary frame format. When limited to two unchannelised links, each link can
be rated at up to 45 MHz when SYSCLK is at 25 MHz and at up to 52 MHz when
SYSCLK is at 33 MHz. For lower rate unchannelised links, the FREEDM-32
processes up to 32 links, where the aggregate clock rate of all the links is limited
to 64 MHz, links 0 to 2 can have a clock rate of up to 45 MHz when SYSCLK is
at or above 25 MHz and up to 52 MHz when SYSCLK is at 33 MHz and links 3 to
31 can have a clock rate of up to 10 MHz.
The FREEDM-32 supports mixing of up to 32 channelised and unchannelised
links. The total number of channels in each direction is limited to 128. The
aggregate clock rate over all 32 possible links is limited to 64 MHz.
In the receive direction, the FREEDM-32 performs channel assignment and
packet extraction and validation. For each provisioned HDLC channel, the
FREEDM-32 delineates the packet boundaries using flag sequence detection,
and performs bit de-stuffing. Sharing of opening and closing flags, as well as,
sharing of zeros between flags are supported. The resulting packet data is
placed into the internal 8 kbyte partial packet buffer RAM. The partial packet
buffer acts as a logical FIFO for each of the assigned channels. Partial packets
are DMA'd out of the RAM, across the PCI bus and into host packet memory.
The FREEDM-32 validates the frame check sequence for each packet, and
verifies that the packet is an integral number of octets in length and is within a
programmable minimum and maximum length. The receive packet status is
updated before linking the packet into a receive ready queue. The FREEDM-32
alerts the PCI Host that there are packets in a receive ready queue by, optionally,
asserting an interrupt on the PCI bus.
PROPRIETARY AND CONFIDENTIAL TO PMC-SIERRA, INC., AND FOR ITS CUSTOMER’S INTERNAL USE
7
PM7364 FREEDM-32
RELEASED
DATA SHEET
PMC-1960758
ISSUE 6
FRAME ENGINE AND DATA LINK MANAGER
Alternatively, in the receive direction, the FREEDM-32 supports a transparent
operating mode. For each provisioned transparent channel, the FREEDM-32
directly transfers the received octets into host memory verbatim. If the
transparent channel is assigned to a channelised link, then the octets are aligned
to the received time-slots.
In the transmit direction, the PCI Host provides packets to transmit using a
transmit ready queue. For each provisioned HDLC channel, the FREEDM-32
DMA's partial packets across the PCI bus and into the transmit partial packet
buffer. The partial packets are read out of the packet buffer by the FREEDM-32
and frame check sequence is optionally calculated and inserted at the end of
each packet. Bit stuffing is performed before being assigned to a particular link.
The flag sequence is automatically inserted when there is no packet data for a
particular channel. Sequential packets are optionally separated by two flags (an
opening flag and a closing flag) or a single flag (combined opening and closing
flag). Zeros between flags are not shared. PCI bus latency may cause one or
more channels to underflow, in which case, the packets are aborted, and the
host is notified. For normal traffic, an abort sequence is generated, followed by
inter-frame time fill characters (flags or all-ones bytes) until a new packet is
sourced from the PCI host. No attempt is made to automatically re-transmit an
aborted packet.
Alternatively, in the transmit direction, the FREEDM-32 supports a transparent
operating mode. For each provisioned transparent channel, the FREEDM-32
directly inserts the transmitted octets from host memory. If the transparent
channel is assigned to a channelised link, then the octets are aligned to the
transmitted time-slots. If a channel underflows due to excessive PCI bus latency,
an abort sequence is generated, followed by inter-frame time fill characters (flags
or all-ones bytes) to indicate idle channel. Data resumes immediately when the
FREEDM-32 receives new data from the host.
The FREEDM-32 is configured, controlled and monitored using the PCI bus
interface. The FREEDM-32 is implemented in low power CMOS technology. It
has TTL compatible inputs and outputs and is packaged in a 256 pin enhanced
ball grid array (SBGA) package.
PROPRIETARY AND CONFIDENTIAL TO PMC-SIERRA, INC., AND FOR ITS CUSTOMER’S INTERNAL USE
8
PM7364 FREEDM-32
RELEASED
DATA SHEET
PMC-1960758
7
ISSUE 6
FRAME ENGINE AND DATA LINK MANAGER
PIN DIAGRAM
The FREEDM-32 is manufactured in a 256 pin enhanced ball grid array package.
20
19
18
17
16
5
4
3
2
1
A
VSS
VSS
VSS
RD[27]
RD[29]
VSS
VSS
VSS
A
B
VSS
VDD
VDD
RD[8]
RD[10]
VDD
VDD
VSS
B
C
VSS
VDD
VDD
RD[7]
RD[9]
RD[11]
VDD
VDD
VSS
C
D
RD[5]
RCLK[5]
RCLK[6]
EN5V
RCLK[7]
RCLK[9]
GNTB
AD[31]
AD[30]
D
E
RD[3]
RCLK[3]
RCLK[4]
RD[6]
REQB
AD[29]
AD[27]
AD[26]
E
F
RCLK[1]
RD[2]
RCLK[2]
RD[4]
AD[28]
AD[25]
AD[24]
CBEB[3]
F
G
RBCLK
RD[0]
RD[1]
VDD
VDD
IDSEL
AD[22]
AD[21]
G
H
VBIAS[1]
SYSCLK
RBD
RCLK[0]
AD[23]
AD[20]
AD[18]
VSS
H
J
VSS
TCK
TMS
TRSTB
AD[19]
AD[17]
AD[16]
CBEB[2]
J
K
VSS
TDI
TDO
VDD
FRAMEB
IRDYB
TRDYB
DEVSELB
K
L
TD[0]
TCLK[0]
TD[1]
TCLK[1]
VDD
STOPB
LOCKB
VSS
L
M
TD[2]
TCLK[2]
TD[3]
TD[4]
CBEB[1]
SERRB
PERRB
VSS
M
N
VSS
TCLK[3]
TCLK[4]
TD[6]
AD[11]
AD[14]
AD[15]
PAR
N
P
TD[5]
TCLK[5]
TCLK[6]
VDD
VDD
AD[10]
AD[12]
AD[13]
P
R
TD[7]
TCLK[7]
TD[8]
TCLK[9]
AD[5]
CBEB[0]
AD[8]
AD[9]
R
T
TCLK[8]
TD[9]
TD[10]
TCLK[11]
AD[1]
AD[4]
AD[6]
AD[7]
T
U
TCLK[10]
TD[11]
TD[12]
NC
AD[0]
AD[2]
AD[3]
U
V
VSS
VDD
VDD
W
VSS
VDD
VDD
Y
VSS
VSS
VSS
TD[14]
TD[16]
20
19
18
17
16
RCLK[8] RCLK[10]
15
14
13
12
11
10
9
RD[12]
RD[14]
VSS
RD[17]
RD[19]
VSS
VSS
RCLK[11] RCLK[13] RCLK[15] RCLK[16] RCLK[18]
RCLK[12] RCLK[14]
VDD
RD[13]
RD[20]
8
7
6
RCLK[21] RCLK[23] RCLK[25]
RCLK[20] RCLK[22]
RD[24]
RD[16]
RD[18]
RCLK[19]
RD[21]
RD[23]
RD[25]
RD[15]
RCLK[17]
VDD
RD[22]
RCLK[24]
VDD
RD[26]
RCLK[27] RCLK[29]
RCLK[26] RCLK[28]
RD[28]
PCICLKO VBIAS[2]
BOTTOM VIEW
TD[13]
TD[15]
VDD
TCLK[18]
TD[21]
VDD
TCLK[25]
TD[28]
TCLK[12] TCLK[14] TCLK[16]
TD[18]
TD[20]
TD[22]
TCLK[23]
TD[25]
TD[27]
TCLK[13] TCLK[15]
TD[19]
TD[17]
TCLK[20] TCLK[22]
TCLK[17] TCLK[19] TCLK[21]
15
14
13
TD[23]
TD[30]
VDD
TCLK[28] TCLK[30]
PCICLK
PMCTEST RCLK[30] VBIAS[3]
TBD
TCLK[24] TCLK[26] TCLK[27] TCLK[29] TCLK[31]
PCIINTB
RD[30]
VDD
VDD
VSS
V
RSTB
RD[31]
VDD
VDD
VSS
W
Y
VSS
VSS
TD[24]
TD[26]
VSS
TD[29]
TD[31]
TBCLK
RCLK[31]
VSS
VSS
VSS
12
11
10
9
8
7
6
5
4
3
2
1
PROPRIETARY AND CONFIDENTIAL TO PMC-SIERRA, INC., AND FOR ITS CUSTOMER’S INTERNAL USE
9
PM7364 FREEDM-32
RELEASED
DATA SHEET
PMC-1960758
8
ISSUE 6
FRAME ENGINE AND DATA LINK MANAGER
PIN DESCRIPTION
Table 1 – Line Side Interface Signals (132)
Pin Name
Type
Pin
No.
Function
RCLK[0]
RCLK[1]
RCLK[2]
RCLK[3]
RCLK[4]
RCLK[5]
RCLK[6]
RCLK[7]
RCLK[8]
RCLK[9]
RCLK[10]
RCLK[11]
RCLK[12]
RCLK[13]
RCLK[14]
RCLK[15]
RCLK[16]
RCLK[17]
RCLK[18]
RCLK[19]
RCLK[20]
RCLK[21]
RCLK[22]
RCLK[23]
RCLK[24]
RCLK[25]
RCLK[26]
RCLK[27]
RCLK[28]
RCLK[29]
RCLK[30]
RCLK[31]
Input
H17
F20
F18
E19
E18
D19
D18
D16
A17
D15
A16
B15
C14
B14
C13
B13
B12
D11
B11
C10
B9
A8
B8
A7
D8
A6
C6
B5
C5
B4
U5
Y4
The receive line clock signals (RCLK[31:0])
contain the recovered line clock for the 32
independently timed links. Processing of
the receive links is on a priority basis, in
descending order from RCLK[0] to
RCLK[31]. Therefore, the highest rate link
should be connected to RCLK[0] and the
lowest to RCLK[31]. RD[31:0] is sampled
on the rising edge of the corresponding
RCLK[31:0] clock.
For channelised T1 or E1 links, RCLK[n]
must be gapped during the framing bit (for
T1 interfaces) or during time-slot 0 (for E1
interfaces) of the RD[n] stream. The
FREEDM-32 uses the gapping information
to determine the time-slot alignment in the
receive stream. RCLK[31:0] is nominally a
50% duty cycle clock of 1.544 MHz for T1
links and 2.048 MHz for E1 links.
For unchannelised links, RCLK[n] must be
externally gapped during the bits or timeslots that are not part of the transmission
format payload (i.e. not part of the HDLC
packet). RCLK[2:0] is nominally a 50% duty
cycle clock between 0 and 52 MHz.
RCLK[31:3] is nominally a 50% duty cycle
clock between 0 and 10 MHz.
PROPRIETARY AND CONFIDENTIAL TO PMC-SIERRA, INC., AND FOR ITS CUSTOMER’S INTERNAL USE
10
PM7364 FREEDM-32
RELEASED
DATA SHEET
PMC-1960758
ISSUE 6
FRAME ENGINE AND DATA LINK MANAGER
Pin Name
Type
Pin
No.
Function
RD[0]
RD[1]
RD[2]
RD[3]
RD[4]
RD[5]
RD[6]
RD[7]
RD[8]
RD[9]
RD[10]
RD[11]
RD[12]
RD[13]
RD[14]
RD[15]
RD[16]
RD[17]
RD[18]
RD[19]
RD[20]
RD[21]
RD[22]
RD[23]
RD[24]
RD[25]
RD[26]
RD[27]
RD[28]
RD[29]
RD[30]
RD[31]
Input
G19
G18
F19
E20
F17
D20
E17
C17
B17
C16
B16
C15
A15
D13
A14
D12
C12
A12
C11
A11
B10
C9
D9
C8
B7
C7
B6
A5
D6
A4
V4
W4
The receive data signals (RD[31:0]) contain
the recovered line data for the 32
independently timed links in normal mode
(PMCTEST set low). Processing of the
receive links is on a priority basis, in
descending order form RD[0] to RD[31].
Therefore, the highest rate link should be
connected to RD[0] and the lowest to
RD[31].
RBD
Tristate
Output
H18
The receive BERT data signal (RBD)
contains the receive bit error rate test data.
RBD reports the data on the selected one of
the receive data signals (RD[31:0]) and is
updated on the falling edge of RBCLK.
RBD may be tri-stated by setting the RBEN
bit in the FREEDM-32 Master BERT Control
register low.
For channelised links, RD[n] contains the 24
(T1) or 31 (E1) time-slots that comprise the
channelised link. RCLK[n] must be gapped
during the T1 framing bit position or the E1
frame alignment signal (time-slot 0). The
FREEDM-32 uses the location of the gap to
determine the channel alignment on RD[n].
For unchannelised links, RD[n] contains the
HDLC packet data. For certain transmission
formats, RD[n] may contain place holder bits
or time-slots. RCLK[n] must be externally
gapped during the place holder positions in
the RD[n] stream. The FREEDM-32
supports a maximum data rate of 10 Mbit/s
on an individual RD[31:3] link and a
maximum data rate of 52 Mbit/s on RD[2:0].
RD[31:0] is sampled on the rising edge of
the corresponding RCLK[31:0] clock.
PROPRIETARY AND CONFIDENTIAL TO PMC-SIERRA, INC., AND FOR ITS CUSTOMER’S INTERNAL USE
11
PM7364 FREEDM-32
RELEASED
DATA SHEET
PMC-1960758
ISSUE 6
FRAME ENGINE AND DATA LINK MANAGER
Pin Name
Type
Pin
No.
Function
RBCLK
Tristate
Output
G20
The receive BERT clock signal (RBCLK)
contains the receive bit error rate test clock.
RBCLK is a buffered version of the selected
one of the receive clock signals
(RCLK[31:0]). RBCLK may be tri-stated by
setting the RBEN bit in the FREEDM-32
Master BERT Control register low.
TCLK[0]
TCLK[1]
TCLK[2]
TCLK[3]
TCLK[4]
TCLK[5]
TCLK[6]
TCLK[7]
TCLK[8]
TCLK[9]
TCLK[10]
TCLK[11]
TCLK[12]
TCLK[13]
TCLK[14]
TCLK[15]
TCLK[16]
TCLK[17]
TCLK[18]
TCLK[19]
TCLK[20]
TCLK[21]
TCLK[22]
TCLK[23]
TCLK[24]
TCLK[25]
TCLK[26]
TCLK[27]
TCLK[28]
TCLK[29]
TCLK[30]
TCLK[31]
Input
L19
L17
M19
N19
N18
P19
P18
R19
T20
R17
U20
T17
V17
W17
V16
W16
V15
Y15
U13
Y14
W13
Y13
W12
V11
W10
U10
W9
W8
V8
W7
V7
W6
The transmit line clock signals (TCLK[31:0])
contain the transmit clocks for the 32
independently timed links. Processing of
the transmit links is on a priority basis, in
descending order from TCLK[0] to
TCLK[31]. Therefore, the highest rate link
should be connected to TCLK[0] and the
lowest to TCLK[31]. TD[31:0] is updated on
the falling edge of the corresponding
TCLK[31:0] clock.
For channelised T1 or E1 links, TCLK[n]
must be gapped during the framing bit (for
T1 interfaces) or during time-slot 0 (for E1
interfaces) of the TD[n] stream. The
FREEDM-32 uses the gapping information
to determine the time-slot alignment in the
transmit stream.
For unchannelised links, TCLK[n] must be
externally gapped during the bits or timeslots that are not part of the transmission
format payload (i.e. not part of the HDLC
packet).
TCLK[31:3] is nominally a 50% duty cycle
clock between 0 and 10 MHz. TCLK[2:0] is
nominally a 50% duty cycle clock between 0
and 52 MHz. Typical values for TCLK[31:0]
include 1.544 MHz (for T1 links) and 2.048
MHz (for E1 links).
PROPRIETARY AND CONFIDENTIAL TO PMC-SIERRA, INC., AND FOR ITS CUSTOMER’S INTERNAL USE
12
PM7364 FREEDM-32
RELEASED
DATA SHEET
PMC-1960758
ISSUE 6
FRAME ENGINE AND DATA LINK MANAGER
Pin Name
Type
Pin
No.
Function
TD[0]
TD[1]
TD[2]
TD[3]
TD[4]
TD[5]
TD[6]
TD[7]
TD[8]
TD[9]
TD[10]
TD[11]
TD[12]
TD[13]
TD[14]
TD[15]
TD[16]
TD[17]
TD[18]
TD[19]
TD[20]
TD[21]
TD[22]
TD[23]
TD[24]
TD[25]
TD[26]
TD[27]
TD[28]
TD[29]
TD[30]
TD[31]
Output
L20
L18
M20
M18
M17
P20
N17
R20
R18
T19
T18
U19
U18
U16
Y17
U15
Y16
W15
V14
W14
V13
U12
V12
W11
Y10
V10
Y9
V9
U9
Y7
U8
Y6
The transmit data signals (TD[31:0])
contains the transmit data for the 32
independently timed links in normal mode
(PMCTEST set low). Processing of the
transmit links is on a priority basis, in
descending order from TD[0] to TD[31].
Therefore, the highest rate link should be
connected to TD[0] and the lowest to
TD[31].
TBD
Input
V6
The transmit BERT data signal (TBD)
contains the transmit bit error rate test data.
When the TBERTEN bit in the BERT
Control register is set high, the data on TBD
is transmitted on the selected one of the
transmit data signals (TD[31:0]). TBD is
sampled on the rising edge of TBCLK.
For channelised links, TD[n] contains the 24
(T1) or 31 (E1) time-slots that comprise the
channelised link. TCLK[n] must be gapped
during the T1 framing bit position or the E1
frame alignment signal (time-slot 0). The
FREEDM-32 uses the location of the gap to
determine the channel alignment on TD[n].
For unchannelised links, TD[n] contains the
HDLC packet data. For certain transmission
formats, TD[n] may contain place holder bits
or time-slots. TCLK[n] must be externally
gapped during the place holder positions in
the TD[n] stream. The FREEDM-32
supports a maximum data rate of 10 Mbit/s
on an individual TD[31:3] link and a
maximum data rate of 52 Mbit/s on TD[2:0]
TD[31:0] is updated on the falling edge of
the corresponding TCLK[31:0] clock.
PROPRIETARY AND CONFIDENTIAL TO PMC-SIERRA, INC., AND FOR ITS CUSTOMER’S INTERNAL USE
13
PM7364 FREEDM-32
RELEASED
DATA SHEET
PMC-1960758
ISSUE 6
FRAME ENGINE AND DATA LINK MANAGER
Pin Name
Type
Pin
No.
Function
TBCLK
Tristate
Output
Y5
The transmit BERT clock signal (TBCLK)
contains the transmit bit error rate test
clock. TBCLK is a buffered version of the
selected one of the transmit clock signals
(TCLK[31:0]). TBCLK may be tri-stated by
setting the TBEN bit in the FREEDM-32
Master BERT Control register low.
PROPRIETARY AND CONFIDENTIAL TO PMC-SIERRA, INC., AND FOR ITS CUSTOMER’S INTERNAL USE
14
PM7364 FREEDM-32
RELEASED
DATA SHEET
PMC-1960758
ISSUE 6
FRAME ENGINE AND DATA LINK MANAGER
Table 2 – PCI Host Interface Signals (51)
Pin Name
Type
Pin
No.
Function
PCICLK
Input
C4
The PCI clock signal (PCICLK) provides timing
for PCI bus accesses. PCICLK is a nominally
50% duty cycle, 0 to 33 MHz clock.
PCICLKO
Output
D5
The PCI clock output signal (PCICLKO) is a
buffered version of the PCICLK. PCICLKO may
be used to drive the SYSCLK input.
AD[0]
AD[1]
AD[2]
AD[3]
AD[4]
AD[5]
AD[6]
AD[7]
AD[8]
AD[9]
AD[10]
AD[11]
AD[12]
AD[13]
AD[14]
AD[15]
AD[16]
AD[17]
AD[18]
AD[19]
AD[20]
AD[21]
AD[22]
AD[23]
AD[24]
AD[25]
AD[26]
AD[27]
AD[28]
AD[29]
AD[30]
I/O
U3
T4
U2
U1
T3
R4
T2
T1
R2
R1
P3
N4
P2
P1
N3
N2
J2
J3
H2
J4
H3
G1
G2
H4
F2
F3
E1
E2
F4
E3
D1
The PCI address and data bus (AD[31:0])
carries the PCI bus multiplexed address and
data. During the first clock cycle of a
transaction, AD[31:0] contains a physical byte
address. During subsequent clock cycles of a
transaction, AD[31:0] contains data.
A transaction is defined as an address phase
followed by one or more data phases. When
Little-Endian byte formatting is selected,
AD[31:24] contain the most significant byte of a
DWORD while AD[7:0] contain the least
significant byte. When Big-Endian byte
formatting is selected. AD[7:0] contain the most
significant byte of a DWORD while AD[31:24]
contain the least significant byte. When the
FREEDM-32 is the initiator, AD[31:0] is an
output bus during the first (address) phase of a
transaction. For write transactions, AD[31:0]
remains an output bus for the data phases of
the transaction. For read transactions, AD[31:0]
is an input bus during the data phases.
When the FREEDM-32 is the target, AD[31:0] is
an input bus during the first (address) phase of
a transaction. For write transactions, AD[31:0]
remains an input bus during the data phases of
the transaction. For read transactions, AD[31:0]
is an output bus during the data phases.
When the FREEDM-32 is not involved in the
current transaction, AD[31:0] is tri-stated.
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Pin Name
Type
Pin
No.
Function
AD[31]
I/O
D2
As an output bus, AD[31:0] is updated on the
rising edge of PCICLK. As an input bus,
AD[31:0] is sampled on the rising edge of
PCICLK.
C/BEB[0]
C/BEB[1]
C/BEB[2]
C/BEB[3]
I/O
R3
M4
J1
F1
The PCI bus command and byte enable bus
(C/BEB[3:0]) contains the bus command or the
byte valid indications. During the first clock
cycle of a transaction, C/BEB[3:0] contains the
bus command code. For subsequent clock
cycles, C/BEB[3:0] identifies which bytes on the
AD[31:0] bus carry valid data. C/BEB[3] is
associated with byte 3 (AD[31:24]) while
C/BEB[0] is associated with byte 0 (AD[7:0]).
When C/BEB[n] is set high, the associated byte
is invalid. When C/BEB[n] is set low, the
associated byte is valid.
When the FREEDM-32 is the initiator,
C/BEB[3:0] is an output bus.
When the FREEDM-32 is the target, C/BEB[3:0]
is an input bus.
When the FREEDM-32 is not involved in the
current transaction, C/BEB[3:0] is tri-stated.
As an output bus, C/BEB[3:0] is updated on the
rising edge of PCICLK. As an input bus,
C/BEB[3:0] is sampled on the rising edge of
PCICLK.
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Pin Name
Type
Pin
No.
Function
PAR
I/O
N1
The parity signal (PAR) indicates the parity of
the AD[31:0] and C/BEB[3:0] buses. Even
parity is calculated over all 36 signals in the
buses regardless of whether any or all the bytes
on the AD[31:0] are valid. PAR always reports
the parity of the previous PCICLK cycle. Parity
errors detected by the FREEDM-32 are
indicated on output PERRB and in the
FREEDM-32 Interrupt Status register.
When the FREEDM-32 is the initiator, PAR is an
output for writes and an input for reads.
When the FREEDM-32 is the target, PAR is an
input for writes and an output for reads.
When the FREEDM-32 is not involved in the
current transaction, PAR is tri-stated.
As an output signal, PAR is updated on the
rising edge of PCICLK. As an input signal, PAR
is sampled on the rising edge of PCICLK.
FRAMEB
I/O
K4
The active low cycle frame signal (FRAMEB)
identifies a transaction cycle. When FRAMEB
transitions low, the start of a bus transaction is
indicated. FRAMEB remains low to define the
duration of the cycle. When FRAMEB
transitions high, the last data phase of the
current transaction is indicated.
When the FREEDM-32 is the initiator, FRAMEB
is an output.
When the FREEDM-32 is the target, FRAMEB
is an input.
When the FREEDM-32 is not involved in the
current transaction, FRAMEB is tri-stated.
As an output signal, FRAMEB is updated on the
rising edge of PCICLK. As an input signal,
FRAMEB is sampled on the rising edge of
PCICLK.
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Pin Name
Type
Pin
No.
Function
TRDYB
I/O
K2
The active low target ready signal (TRDYB)
indicates when the target is ready to start or
continue with a transaction. TRDYB works in
conjunction with IRDYB to complete transaction
data phases. During a transaction in progress,
TRDYB is set high to indicate that the target
cannot complete the current data phase and to
force a wait state. TRDYB is set low to indicate
that the target can complete the current data
phase. The data phase is completed when
TRDYB is set low and the initiator ready signal
(IRDYB) is also set low.
When the FREEDM-32 is the initiator, TRDYB is
an input.
When the FREEDM-32 is the target, TRDYB is
an output. During accesses to FREEDM-32
registers, TRDYB is set high to extend data
phases over multiple PCICLK cycles.
When the FREEDM-32 is not involved in the
current transaction, TRDYB is tri-stated.
As an output signal, TRDYB is updated on the
rising edge of PCICLK. As an input signal,
TRDYB is sampled on the rising edge of
PCICLK.
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Pin Name
Type
Pin
No.
Function
IRDYB
I/O
K3
The active low initiator ready (IRDYB) signal is
used to indicate whether the initiator is ready to
start or continue with a transaction. IRDYB
works in conjunction with TRDYB to complete
transaction data phases. When IRDYB is set
high and a transaction is in progress, the
initiator is indicating it cannot complete the
current data phase and is forcing a wait state.
When IRDYB is set low and a transaction is in
progress, the initiator is indicating it has
completed the current data phase. The data
phase is completed when IRDYB is set low and
the target ready signal (IRDYB) is also set low.
When the FREEDM-32 is the initiator, IRDYB is
an output.
When the FREEDM-32 is the target, IRDYB is
an input.
When the FREEDM-32 is not involved in the
current transaction, IRDYB is tri-stated.
IRDYB is updated on the rising edge of PCICLK
or sampled on the rising edge of PCICLK
depending on whether it is an output or an
input.
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Pin Name
Type
Pin
No.
Function
STOPB
I/O
L3
The active low stop signal (STOPB) requests
the initiator to stop the current bus transaction.
When STOPB is set high by a target, the
initiator continues with the transaction. When
STOPB is set low, the initiator will stop the
current transaction.
When the FREEDM-32 is the initiator, STOPB is
an input. When STOPB is sampled low, the
FREEDM-32 will terminate the current
transaction in the next PCICLK cycle.
When the FREEDM-32 is the target, STOPB is
an output. The FREEDM-32 only issues
transaction stop requests when responding to
reads and writes to configuration space
(disconnecting after 1 DWORD transferred) or if
an initiator introduces wait states during a
transaction.
When the FREEDM-32 is not involved in the
current transaction, STOPB is tri-stated.
STOPB is updated on the rising edge of
PCICLK or sampled on the rising edge of
PCICLK depending on whether it is an output or
an input.
IDSEL
Input
G3
The initialization device select signal (IDSEL)
enables read and write access to the PCI
configuration registers. When IDSEL is set high
during the address phase of a transaction and
the C/BEB[3:0] code indicates a register read or
write, the FREEDM-32 performs a PCI
configuration register transaction and asserts
the DEVSELB signal in the next PCICLK period.
IDSEL is sampled on the rising edge of
PCICLK.
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Pin Name
Type
Pin
No.
Function
DEVSELB
I/O
K1
The active low device select signal (DEVSELB)
indicates that a target claims the current bus
transaction. During the address phase of a
transaction, all targets decode the address on
the AD[31:0] bus. When a target, recognizes
the address as its own, it sets DEVSELB low to
indicate to the initiator that the address is valid.
If no target claims the address in six bus clock
cycles, the initiator assumes that the target
does not exist or cannot respond and aborts the
transaction.
When the FREEDM-32 is the initiator,
DEVSELB is an input. If no target responds to
an address in six PCICLK cycles, the FREEDM32 will abort the current transaction and alerts
the PCI Host via an interrupt.
When the FREEDM-32 is the target, DEVSELB
is an output. DELSELB is set low when the
address on AD[31:0] is recognised.
When the FREEDM-32 is not involved in the
current transaction, DEVSELB is tri-stated.
FREEDM-32 is updated on the rising edge of
PCICLK or sampled on the rising edge of
PCICLK depending on whether it is an output or
an input.
LOCKB
Input
L2
The active low bus lock signal (LOCKB) locks a
target device. When LOCKB and FRAME are
set low, and the FREEDM-32 is the target, an
initiator is locking the FREEDM-32 as an
"owned" target. Under these circumstances,
the FREEDM-32 will reject all transaction with
other initiators. The FREEDM-32 will continue
to reject other initiators until its owner releases
the lock by forcing both FRAMEB and LOCKB
high. As a initiator, the FREEDM-32 will never
lock a target.
LOCKB is sampled using the rising edge of
PCICLK.
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Pin Name
Type
Pin
No.
Function
REQB
Output
E4
The active low PCI bus request signal (REQB)
requests an external arbiter for control of the
PCI bus. REQB is set low when the FREEDM32 desires access to the host memory. REQB
is set high when access is not desired.
REQB is updated on the rising edge of PCICLK.
GNTB
Input
D3
The active low PCI bus grant signal (GNTB)
indicates the granting of control over the PCI in
response to a bus request via the REQB output.
When GNTB is set high, the FREEDM-32 does
not have control over the PCI bus. When
GNTB is set low, the external arbiter has
granted the FREEDM-32 control over the PCI
bus. However, the FREEDM-32 will not
proceed until the FRAMEB signal is sampled
high, indicating no current transactions are in
progress.
GNTB is sampled on the rising edge of PCICLK.
PCIINTB
OD
Output
V5
The active low PCI interrupt signal (PCIINTB) is
set low when a FREEDM-32 interrupt source is
active, and that source is unmasked. The
FREEDM-32 may be enabled to report many
alarms or events via interrupts. PCIINTB
returns high when the interrupt is acknowledged
via an appropriate register access.
PCIINTB is an open drain output and is updated
on the rising edge of PCICLK.
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Pin Name
Type
Pin
No.
Function
PERRB
I/O
M2
The active low parity error signal (PERRB)
indicates a parity error over the AD[31:0] and
C/BEB[3:0] buses. Parity error is signalled
when even parity calculations do not match the
PAR signal. PERRB is set low at the cycle
immediately following an offending PAR cycle.
PERRB is set high when no parity error is
detected.
PERRB is enabled by setting the PERREN bit in
the Control/Status register in the PCI
Configuration registers space. Regardless of
the setting of PERREN, parity errors are always
reported by the PERR bit in the Control/Status
register in the PCI Configuration registers
space.
PERRB is updated on the rising edge of
PCICLK.
SERRB
OD
Output
M3
The active low system error signal (SERRB)
indicates an address parity error. Address parity
errors are detected when the even parity
calculations during the address phase do not
match the PAR signal. When the FREEDM-32
detects a system error, SERRB is set low for
one PCICLK period.
SERRB is enabled by setting the SERREN bit in
the Control/Status register in the PCI
Configuration registers space. Regardless of
the setting of SERREN, parity errors are always
reported by the SERR bit in the Control/Status
register in the PCI Configuration registers
space.
SERRB is an open drain output and is updated
on the rising edge of PCICLK.
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Table 3 – Miscellaneous Interface Signals (13)
Pin Name
Type
Pin
No.
Function
SYSCLK
Input
H19
The system clock (SYSCLK) provides timing for
the core logic. SYSCLK is nominally a 50% duty
cycle 25 MHz to 33 MHz clock.
RSTB
Input
W5
The active low reset signal (RSTB) signal
provides an asynchronous FREEDM-32 reset.
RSTB is an asynchronous input. When RSTB is
set low, all FREEDM-32 registers are forced to
their default states. In addition, TD[31:0] are
forced high and all PCI output pins are forced
tri-state and will remain high or tri-stated,
respectively, until RSTB is set high.
PMCTEST
Input
U6
The PMC production test enable signal
(PMCTEST) places the FREEDM-32 is test
mode. When PMCTEST is set high, production
test vectors can be executed to verify
manufacturing via the test mode interface signals
TA[10:0], TA[11]/TRS, TRDB, TWRB and
TDAT[15:0]. PMCTEST must be tied low in
normal operation.
TCK
Input
J19
The test clock signal (TCK) provides timing for
test operations that can be carried out using the
IEEE P1149.1 test access port. TMS and TDI are
sampled on the rising edge of TCK. TDO is
updated on the falling edge of TCK.
TMS
Input
J18
The test mode select signal (TMS) controls the
test operations that can be carried out using the
IEEE P1149.1 test access port. TMS is sampled
on the rising edge of TCK. TMS has an integral
pull up resistor.
TDI
Input
K19
The test data input signal (TDI) carries test data
into the FREEDM-32 via the IEEE P1149.1 test
access port. TDI is sampled on the rising edge of
TCK.
TDI has an integral pull up resistor.
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FRAME ENGINE AND DATA LINK MANAGER
Pin Name
Type
TDO
Tristate K18
Output
The test data output signal (TDO) carries test
data out of the FREEDM-32 via the IEEE P1149.1
test access port. TDO is updated on the falling
edge of TCK. TDO is a tri-state output which is
inactive except when scanning of data is in
progress.
TRSTB
Input
The active low test reset signal (TRSTB) provides
an asynchronous FREEDM-32 test access port
reset via the IEEE P1149.1 test access port.
TRSTB is an asynchronous input with an integral
pull up resistor.
J17
Function
Note that when TRSTB is not being used, it must
be connected to the RSTB input.
VBIAS[3:1]
Input
U4
D4
H20
The bias signals (VBIAS[3:1]) provide 5 Volt bias
to input and I/O pads to allow the FREEDM-32 to
tolerate connections to 5 Volt devices. To avoid
damage to the device, the VBIAS[3:1] signals
must be connected together externally and must
at all times be kept at a voltage that is equal to or
higher than the VDD[28:1] power supplies. In a
3.3V operating environment, VBIAS[3:1] and
VDD[28:1] may be connected together. In a 5V
operating environment, VBIAS[3:1] should be
powered up to 5V before VDD[28:1] are powered
up to 3.3V.
EN5V
Input
D17
The 5 Volt PCI signalling enable signal (EN5V)
causes the PCI Host Interface Signals to operate
in the 5V PCI signalling environment when set
high and the 3.3V PCI signalling environment
when set low. EN5V is an asynchronous input
with an integral pull up resistor.
NC
Open
U17
This pin must be left unconnected.
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Table 4 – Production Test Interface Signals (0 - Multiplexed)
Pin Name
Type
Pin
No.
Function
TA[0]
TA[1]
TA[2]
TA[3]
TA[4]
TA[5]
TA[6]
TA[7]
TA[8]
TA[9]
TA[10]
Input
The test mode address bus (TA[10:0]) selects
specific registers during production test
(PMCTEST set high) read and write accesses.
TA[10:0] replace RD[20:10] when PMCTEST is
set high.
TA[11]/TR
S
Input
The test register select signal (TA[11]/TRS)
selects between normal and test mode register
accesses during production test (PMCTEST set
high). TRS is set high to select test registers and
is set low to select normal registers. TA[11]/TRS
replaces RD[21] when PMCTEST is set high.
TRDB
Input
The test mode read enable signal (TRDB) is set
low during FREEDM-32 register read accesses
during production test (PMCTEST set high). The
FREEDM-32 drives the test data bus
(TDAT[15:0]) with the contents of the addressed
register while TRDB is low. TRDB replaces
RD[22] when PMCTEST is set high.
TWRB
Input
The test mode write enable signal (TWRB) is set
low during FREEDM-32 register write accesses
during production test (PMCTEST set high). The
contents of the test data bus (TDAT[15:0]) are
clocked into the addressed register on the rising
edge of TWRB. TWRB replaces RD[23] when
PMCTEST is set high.
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Pin Name
Type
TDAT[0]
TDAT[1]
TDAT[2]
TDAT[3]
TDAT[4]
TDAT[5]
TDAT[6]
TDAT[7]
TDAT[8]
TDAT[9]
TDAT[10]
TDAT[11]
TDAT[12]
TDAT[13]
TDAT[14]
TDAT[15]
I/O
Pin
No.
FRAME ENGINE AND DATA LINK MANAGER
Function
The bi-directional test mode data bus
(TDAT[15:0]) carries data read from or written to
FREEDM-32 registers during production test.
TDAT[15:0] replace TD[31:16] when PMCTEST is
set high.
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Table 5 – Power and Ground Signals (60)
Pin Name
Type
Pin
No.
Function
VDD1
VDD2
VDD3
VDD4
VDD5
VDD6
VDD7
VDD8
VDD9
VDD10
VDD11
VDD12
VDD13
VDD14
VDD15
VDD16
VDD17
VDD18
VDD19
VDD20
VDD21
VDD22
VDD23
VDD24
VDD25
VDD26
VDD27
VDD28
Power
B2
B3
B18
B19
C2
C3
C18
C19
D7
D10
D14
G4
G17
K17
L4
P4
P17
U7
U11
U14
V2
V3
V18
V19
W2
W3
W1
8
W1
9
The DC power pins should be connected to a
well decoupled +3.3 V DC supply.
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Pin Name
Type
Pin
No.
Function
VSS1
VSS2
VSS3
VSS4
VSS5
VSS6
VSS7
VSS8
VSS9
VSS10
VSS11
VSS12
VSS13
VSS14
VSS15
VSS16
VSS17
VSS18
VSS19
VSS20
VSS21
VSS22
VSS23
VSS24
VSS25
VSS26
VSS27
VSS28
VSS29
VSS30
VSS31
VSS32
Ground
A1
A2
A3
A9
A10
A13
A18
A19
A20
B1
B20
C1
C20
H1
J20
K20
L1
M1
N20
V1
V20
W1
W2
0
Y1
Y2
Y3
Y8
Y11
Y12
Y18
Y19
Y20
The DC ground pins should be connected to
ground.
Notes on Pin Description:
1. All FREEDM-32 inputs and bi-directionals present minimum capacitive
loading and operate at TTL compatible logic levels. PCI signals conform to
the 3.3 or 5 Volt signaling environment depending on the setting of the EN5V
input.
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2. Most FREEDM-32 non-PCI digital outputs and bi-directionals have 4 mA drive
capability, except the PCICLKO, RBCLK, TBCLK, RBD and PCIINTB outputs
which have 6 mA drive capability and the TD[0], TD[1], and TD[2] outputs
which have 8 mA drive capability.
3. All FREEDM-32 non-PCI digital outputs and bi-directionals are 5 V tolerant
when tristated except those with 8 mA drive capability, i.e. TD[2:0]. (TD[2:0]
are never tristated in normal operation – only under JTAG boundary scan
control.)
4. Inputs TMS, TDI, TRSTB and EN5V are Schmitt triggered and have internal
pull-up resistors.
5. Inputs RD[31:0], RCLK[31:0], TCLK[31:0], SYSCLK, PCICLK, TBD, RSTB,
GNTB, IDSEL, LOCKB, TCK and PMCTEST are Schmitt triggered.
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9.1
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FRAME ENGINE AND DATA LINK MANAGER
FUNCTIONAL DESCRIPTION
High-Level Data Link Control Protocol
Figure 1 shows a diagram of the synchronous HDLC protocol supported by the
FREEDM-32. The incoming stream is examined for flag bytes (01111110 bit
pattern) which delineate the opening and closing of the HDLC packet. The
packet is bit de-stuffed which discards a "0" bit which directly follows five
contiguous "1" bits. The resulting HDLC packet size must be a multiple of an
octet (8 bits) and within the expected minimum and maximum packet length
limits. The minimum packet length is that of a packet containing two information
bytes (address and control) and FCS bytes. For packets with CRC-CCITT as
FCS, the minimum packet length is four bytes while those with CRC-32 as FCS,
the minimum length is six bytes. An HDLC packet is aborted when seven
contiguous "1" bits (with no inserted "0" bits) are received. At least one flag byte
must exist between HDLC packets for delineation. Contiguous flag bytes, or all
ones bytes between packets are used as an "inter-frame time fill". Adjacent flag
bytes may share zeros.
Figure 1 – HDLC Frame
Flag
Information
FCS
Flag
Flag
HDLC Packet
The CRC algorithm for the frame checking sequence (FCS) field is either a
CRC-CCITT or CRC-32 function. Figure 2 shows a CRC encoder block diagram
using the generating polynomial g(X) = 1 + g1X + g2X2 +…+ gn-1Xn-1 + Xn. The
CRC-CCITT FCS is two bytes in size and has a generating polynomial g(X) = 1 +
X5 + X12 + X16. The CRC-32 FCS is four bytes in size and has a generating
polynomial g(X) = 1 + X + X2 + X4 + X5 + X7 + X8 + X10 + X11 + X12 + X16 + X22
+ X23 + X26 + X32. The first FCS bit received is the residue of the highest term.
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Figure 2 – CRC Generator
g1
D0
g2
D1
LSB
9.2
gn-1
D2
Parity Check Digits
Message
Dn-1
MSB
Receive Channel Assigner
The Receive Channel Assigner block (RCAS) processes up to 32 serial links.
Each link is independent and has its own associated clock. For each link, the
RCAS performs a serial to parallel conversion to form data bytes. The data
bytes are multiplexed, in byte serial format, for delivery to the Receive HDLC
Processor / Partial Packet Buffer block (RHDL) at SYSCLK rate. In the event
where multiple streams have accumulated a byte of data, multiplexing is
performed on a fixed priority basis with link #0 having the highest priority and link
#31 the lowest.
Links containing a T1 or an E1 stream may be channelised. Data at each timeslot may be independently assigned to a different channel. The RCAS performs
a table lookup to associate the link and time-slot identity with a channel. T1 and
E1 framing bits/bytes are identified by observing the gap in the link clock which is
squelched during the framing bits/bytes. For unchannelised links, clock rates are
limited to 52 MHz on link #0 to #2 and limited to 10 MHz for the remaining links.
All data on each link belongs to one channel. For the case of two unchannelised
links, the maximum link rate is 45 MHz for SYSCLK at 25 MHz and 52 MHz for
SYSCLK at 33 MHz. For the case of more numerous unchannelised links or a
mixture of channelise with unchannelised links, the total instantaneous link rate
over all the links is limited to 64 MHz. The RCAS performs a table lookup using
only the link number to determine the associated channel, as time-slots are
non-existent in unchannelised links.
The RCAS provides diagnostic loopback that is selectable on a per channel
basis. When a channel is in diagnostic loopback, stream data on the received
links originally destined for that channel is ignored. Transmit data of that channel
is substituted in its place.
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9.2.1 Line Interface
There are 32 identical line interface blocks in the RCAS. Each line interface
contains a bit counter, an 8-bit shift register and a holding register, that, together,
perform serial to parallel conversion. Whenever the holding register is updated,
a request for service is sent to the priority encoder block. When acknowledged
by the priority encoder, the line interface would respond with the data residing in
the holding register.
To support channelised links, each line interface block contains a time-slot
counter and a clock activity monitor. The time-slot counter is incremented each
time the holding register is updated. The clock activity monitor is a counter that
increments at the system clock (SYSCLK) rate and is cleared by a rising edge of
the receive clock (RCLK[n]). A framing bit (T1) or framing byte (E1) is detected
when the counter reaches a programmable threshold. In which case, the bit and
time-slot counters are initialised to indicate that the next bit is the most significant
bit of the first time-slot. For unchannelised links, the time-slot counter and the
clock activity monitor are held reset.
9.2.2 Priority Encoder
The priority encoder monitors the line interfaces for requests and synchronises
them to the SYSCLK timing domain. Requests are serviced on a fixed priority
scheme where highest to lowest priority is assigned from the line interface
attached to RD[0] to that attached to RD[31]. Thus, simultaneous requests from
RD[m] will be serviced ahead of RD[n], if m < n. When there are no pending
requests, the priority encoder generates an idle cycle. In addition, once every
fourth SYSCLK cycle, the priority encoder inserts a null cycle where no requests
are serviced. This cycle is used by the channel assigner downstream for host
microprocessor accesses to the provisioning RAMs.
9.2.3 Channel Assigner
The channel assigner block determines the channel number of the data byte
currently being processed. The block contains a 1024 word channel provision
RAM. The address of the RAM is constructed from concatenating the link
number and the time-slot number of the current data byte. The fields of each
RAM word include the channel number and a time-slot enable flag. The time-slot
enable flag labels the current time-slot as belonging to the channel indicted by
the channel number field.
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9.2.4 Loopback Controller
The loopback controller block implements the channel based diagnostic
loopback function. Every valid data byte belonging to a channel with diagnostic
loopback enabled from the Transmit HDLC Processor / Partial Packet Buffer
block (THDL) is written into a 64 word FIFO. The loopback controller monitors
for an idle time-slot or a time-slot carrying a channel with diagnostic loopback
enabled. If either conditions hold, the current data byte is replaced by data
retrieved from the loopback data FIFO.
9.3
Receive HDLC Processor / Partial Packet Buffer
The Receive HDLC Processor / Partial Packet Buffer block (RHDL) processes up
to 128 synchronous transmission HDLC data streams. Each channel can be
individually configured to perform flag sequence detection, bit de-stuffing and
CRC-CCITT or CRC-32 verification. The packet data is written into the partial
packet buffer. At the end of a frame, packet status including CRC error, octet
alignment error and maximum length violation are also loaded into the partial
packet buffer. Alternatively, a channel can be provisioned as transparent, in
which case, the HDLC data stream is passed to the partial packet buffer
processor verbatim.
There is a natural precedence in the alarms detectable on a receive packet.
Once a packet exceeds the programmable maximum packet length, no further
processing is performed on it. Thus, octet alignment detection, FCS verification
and abort recognition are squelched on packets with a maximum length violation.
An abort indication squelches octet alignment detection, minimum packet length
violations, and FCS verification. In addition, FCS verification is only performed
on packets that do not have octet alignment errors, in order to allow the RHDL to
perform CRC calculations on a byte-basis.
The partial packet buffer is an 8 Kbyte RAM that is divided into 16-byte blocks.
Each block has an associated pointer which points to another block. A logical
FIFO is created for each provisioned channel by programming the block pointers
to form a circular linked list. A channel FIFO can be assigned a minimum of 3
blocks (48 bytes) and a maximum of 512 blocks (8 Kbytes). The depth of the
channel FIFOs are monitored in a round-robin fashion. Requests are made to
the Receive DMA Controller block (RMAC) to transfer, to the PCI host memory,
data in channel FIFOs with depths exceeding their associated threshold.
9.3.1 HDLC Processor
The HDLC processor is a time-slice state machine which can process up to 128
independent channels. The state vector and provisioning information for each
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channel is stored in a RAM. Whenever new channel data arrives, the
appropriate state vector is read from the RAM, processed and written back to the
RAM. The HDLC state-machine can be configured to perform flag delineation,
bit de-stuffing, CRC verification and length monitoring. The resulting HDLC data
and status information is passed to the partial packet buffer processor to be
stored in the appropriate channel FIFO buffer.
The configuration of the HDLC processor is accessed using indirect channel
read and write operations. When an indirect operation is performed, the
information is accessed from RAM during a null clock cycle generated by the
upstream Receive Channel Assigner block (RCAS). Writing new provisioning
data to a channel resets the channel's entire state vector.
9.3.2 Partial Packet Buffer Processor
The partial packet buffer processor controls the 8 Kbyte partial packet RAM
which is divided into 16 byte blocks. A block pointer RAM is used to chain the
partial packet blocks into circular channel FIFO buffers. Thus, non-contiguous
sections of the RAM can be allocated in the partial packet buffer RAM to create a
channel FIFO. System software is responsible for the assignment of blocks to
individual channel FIFOs. Figure 3 shows an example of three blocks (blocks 1,
3, and 200) linked together to form a 48 byte channel FIFO.
The partial packet buffer processor is divided into three sections: writer, reader
and roamer. The writer is a time-sliced state machine which writes the HDLC
data and status information from the HDLC processor into a channel FIFO in the
packet buffer RAM. The reader transfers channel FIFO data from the packet
buffer RAM to the downstream Receive DMA Controller block (RMAC). The
roamer is a time-sliced state machine which tracks channel FIFO buffer depths
and signals the reader to service a particular channel. If a buffer over-run
occurs, the writer ends the current packet from the HDLC processor in the
channel FIFO with an over-run flag and ignores the rest of the packet.
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Figure 3 – Partial Packet Buffer Structure
Partial Packet
Buffer RAM
Block
Pointer RAM
Block 0
16 bytes
Block 0
XX
Block 1
16 bytes
Block 1
0x03
Block 2
16 bytes
Block 2
XX
Block 3
16 bytes
Block 3
0xC8
Block 200
16 bytes
Block 200
0x01
Block 511
16 bytes
Block 511
XX
The FIFO algorithm of the partial packet buffer processor is based on a
programmable per-channel transfer size. Instead of tracking the number of full
blocks in a channel FIFO, the processor tracks the number of transactions.
Whenever the partial packet writer fills a transfer-sized number of blocks or
writes an end-of-packet flag to the channel FIFO, a transaction is created.
Whenever the partial packet reader transmits a transfer-size number of blocks or
an end-of-packet flag to the RMAC block, a transaction is deleted. Thus, small
packets less than the transfer size will be naturally transferred to the RMAC
block without having to precisely track the number of full blocks in the channel
FIFO.
The partial packet roamer performs the transaction accounting for all channel
FIFOs. The roamer increments the transaction count when the writer signals a
new transaction and sets a per-channel flag to indicate a non-zero transaction
count. The roamer searches the flags in a round-robin fashion to decide for
which channel FIFO to request transfer by the RMAC block. The roamer informs
the partial packet reader of the channel to process. The reader transfers the
data to the RMAC until the channel transfer size is reached or an end of packet
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is detected. The reader then informs the roamer that a transaction is consumed.
The roamer updates its transaction count and clears the non-zero transaction
count flag if required. The roamer then services the next channel with its
transaction flag set high.
The writer and reader determine empty and full FIFO conditions using flags.
Each block in the partial packet buffer has an associated flag. The writer sets
the flag after the block is written and the reader clears the flag after the block is
read. The flags are initialized (cleared) when the block pointers are written using
indirect block writes. The writer declares a channel FIFO overrun whenever the
writer tries to store data to a block with a set flag. In order to support optional
removal of the FCS from the packet data, the writer does not declare a block as
filled (set the block flag nor increment the transaction count) until the first double
word of the next block in channel FIFO is filled. If the end of a packet resides in
the first double word, the writer declares both blocks as full at the same time.
When the reader finishes processing a transaction, it examines the first double
word of the next block for the end-of-packet flag. If the first double word of the
next block contains only FCS bytes, the reader would, optionally, process next
transaction (end-of-packet) and consume the block, as it contains information not
transferred to the RMAC block.
9.4
Receive DMA Controller
The Receive DMA Controller block (RMAC) is a DMA controller which stores
received packet data in host computer memory. The RMAC is not directly
connected to the host memory PCI bus. Memory accesses are serviced by a
downstream PCI controller block (GPIC). The RMAC and the host exchange
information using receive packet descriptors (RPDs). The descriptor contains
the size and location of buffers in host memory and the packet status information
associated with the data in each buffer. RPDs are transferred from the RMAC to
the host and vice versa using descriptor reference queues. The RMAC
maintains all the pointers for the operation of the queues. The RMAC provides
two receive packet descriptor reference (RPDR) free queues to support small
and large buffers. The RMAC acquires free buffers by reading RPDRs from the
free queues. After a packet is received, the RMAC places the associated RPDR
onto a RPDR ready queue. To minimise host bus accesses, the RMAC
maintains a descriptor reference table to store current DMA information. This
table contains separate DMA information entries for up to 128 receive channels.
9.4.1 Data Structures
For packet data, the RMAC communicates with the host using Receive Packet
Descriptors (RPD), Receive Packet Descriptor References (RPDR), the Receive
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Packet Descriptor Reference Ready (RPDRR) queue and the Receive Packet
Descriptor Reference Small and Large Buffer Free (RPDRF) queues.
The RMAC copies packet data to data buffers in host memory. The RPD, RPDR,
RPDRR queue, and Small and Large RPDRF queues are data structures which
are used to transfer host memory data buffer information. All five data structures
are manipulated by both the RMAC and the host computer. The RPD holds the
data buffer size, data buffer address, and packet status information. The RPDR
is a pointer which is used to index into a table of RPDs. The RPDRR queue and
RPDRF queues allow the RMAC and the host to pass RPDRs back and forth.
These data structures are described in more detail in the following sections.
Receive Packet Descriptor
The Receive Packet Descriptors (RPDs) pass buffer and packet information
between the RMAC and the host. Both the RMAC and the host read and write
information in the RPDs. The host writes RPD fields which describe the size and
address of data buffers in host memory. The RMAC writes RPD fields which
provide number of bytes used in each data buffer, RPD link information, and the
status of the received packet. RPDs are stored in host memory in a Receive
Packet Descriptor Table which is described in a later section. The Receive
Packet Descriptor structure is shown in Figure 4.
Figure 4 – Receive Packet Descriptor
Bit 31
0
Data Buffer Start Address [31:0]
Bytes In Buffer [15:0]
Status [5:0]
Reserved (18)
Reserved (16)
Offset[1:0]
CE
RCC [6:0]
Next RPD Pointer [13:0]
Receive Buffer Size [15:0]
Table 6 – Receive Packet Descriptor Fields
Field
Data Buffer Start
Address[31:0]
Description
The Data Buffer Start Address[31:0] bits point to the data
buffer in host memory. This field is expected to be
configured by the Host during initialisation.
The Data Buffer Start Address field is valid in all RPDs.
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Field
RCC[6:0]
FRAME ENGINE AND DATA LINK MANAGER
Description
The Receive Channel Code (RCC[6:0]) bits are used by
the RMAC to indicate which channel an RPD is
associated with.
For a linked list of RPDs, all the RPDs’ RCC fields are
valid, i.e. all contain the same channel value.
CE
The Chain End (CE) bit indicates the end of a linked list of
RPDs. When CE is set to logic one, the current RPD is
the last RPD of a linked list of RPDs. When CE is set to
logic zero, the current RPD is not the last RPD of a linked
list.
The CE bit is valid for all RPDs written by the RMAC to
the Receive Ready Queue. When a packet requires only
one RPD, the CE bit is set to logic one. The CE bit is
ignored for all RPDs read by the RMAC from the Receive
Free Queues, each of which is assumed to point to only
one buffer, i.e. not a chain.
Offset[1:0]
The Offset[1:0] bits indicate the byte offset of the data
packet from the start of the buffer. If this value is nonzero, there will be ‘dummy’ (i.e. undefined) bytes at the
start of the data buffer prior to the packet data proper.
For a linked list of RPDs, only the first RPD's Offset field
is valid. All other RPD Offset fields of the linked list are
set to 0.
Status [5:0]
The Status[5:0] bits indicate the status of the received
packet.
Status[0]
Status[1]
Status[2]
Status[3]
Status[4]
Status[5]
Rx buffer overrun
Packet exceeds max. allowed size
CRC error
Packet Length not an exact no. of bytes
HDLC abort detected
Unused (set to 0)
For a linked list of RPDs, only the last RPD's Status field
is valid. All other RPD Status fields of the linked list are
invalid and should be ignored. When a packet requires
only one RPD, the Status field is valid.
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Field
Bytes in Buffer
[15:0]
FRAME ENGINE AND DATA LINK MANAGER
Description
The Bytes in Buffer[15:0] bits indicate the number of bytes
actually used in the current RPD's data buffer to store
packet data. The count excludes the 'dummy' bytes
inserted as a result of a non-zero Offset field. A count
greater than 32767 bytes indicates a packet that is
shorter than the expected length of the FCS field.
The Bytes in Buffer field is invalid when Status[0] or
Status[4] is asserted .
Next RPD Pointer
[13:0]
The Next RPD Pointer[13:0] bits store a RPDR which
enables the RMAC to support linked lists of RPDs. This
field, which is only valid when CE is equal to logic zero,
contains the RPDR to the next RPD in a linked list. The
RMAC links RPDs when more than one buffer is needed
to store a packet.
The Next RPD Pointer is not valid for the last RPD in a
linked list (when CE=1). When a packet requires only one
RPD, the Next RPD Pointer field is not valid.
Receive Buffer Size The Receive Buffer Size[15:0] bits indicate the size in
[15:0]
bytes of the current RPD's data buffer. This field is
expected to be configured by the Host during initialisation.
The Receive Buffer Size must be a non-zero integer
multiple of four and less than or equal to 32764.
The Receive Buffer Size field is valid in all RPDs.
The Receive Buffer Size and Data Buffer Start Address fields are written only by
the host. The RMAC reads these fields to determine where to store packet data.
All other fields are written only by the RMAC.
Receive Packet Descriptor Table
The Receive Packet Descriptor Table resides in host memory and stores all the
RPDs. The RPD Table can contain a maximum of 16384 RPDs. The base of
the RPD table is user programmable using the Rx Packet Descriptor Table Base
(RPDTB) register. The table is indexed by a Receive Packet Descriptor
Reference (RPDR) which is a 14-bit pointer defining the offset of a RPD from the
table base. Thus, as shown in the following diagram, a RPD can be located by
adding the RPDR to the Rx Packet Descriptor Table Base register.
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Figure 5 – Receive Packet Descriptor Table
RPDTB[31:4] = Rx Packet Descriptor Table Base register
RPDR[13:0] = Receive Packet Desriptor Reference
RPD_ADDR[31:0] = Receive Packet Descriptor Address
Bit 31
Bit 0
RPDTB[31:4]
0000
+
RPDR[13:0]
0000
=
RPD_ADDR[31:0]
Bit 31
RPDTB
RPD 1
RPD_ADDR
Bit 0
Dword 0
Dword 1
Dword 2
Dword 3
Dword 0
RPD 2
Dword 3
Dword 0
RPD 16384
Dword 3
The Receive Packet Descriptor Table resides in host memory. The Rx Packet
Descriptor Table Base register resides in the RMAC; this register is initialised by
the host. The RPDRs reside in host memory and are accessed using receive
packet queues which are described in the next section.
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Receive Packet Queues
Receive Packet Queues are used to transfer RPDRs between the host and the
RMAC. There are three queues: a RPDR Large Buffer Free Queue (RPDRLFQ),
a RPDR Small Buffer Free Queue (RPDRSFQ) and a RPDR Ready Queue
(RPDRRQ). The free queues contain RPDRs referencing RPDs that define free
buffers. The ready queue contains RPDRs referencing RPDs that define buffers
ready for host processing. The RMAC pulls RPDRs from the free queues when
it needs free data buffers. The RMAC places an RPDR onto the ready queue
after it has filled the buffers with data from each complete packet. The host
removes RPDRs from the ready queue to process the data buffers. The host
places the RPDRs back onto the free queues after it finishes reading the data
from the buffers.
When starting to process a packet, the RMAC uses a small buffer RPD to store
the packet data. If the packet requires more than one buffer, the RMAC uses
large buffer RPDs to store the remainder of the packet. The RMAC links
together all the RPDs required to store the packet and returns the RPDR
associated with the first RPD onto the ready queue.
All receive packet queues reside in host memory and are defined by the Rx
Queue Base (RQB) register and index registers which reside in the RMAC. The
Rx Queue Base is the base address for the receive packet queues. Each packet
queue has four index registers which define the start and end of the queue and
the read and write locations of the queue. Each index register is 16 bits in length
and defines an offset from the Rx Queue Base. Thus, as shown in the Figure 6,
the host address of a RPDR is calculated by adding the index register to the Rx
Queue Base register. The host initialises the Rx Queue Base and all the index
registers. When an entity (either the RMAC or the host) removes elements from
a queue, the entity updates the read pointer for that queue. When an entity
(either the RMAC or the host) places elements onto a queue, the entity updates
the write pointer for that queue.
The read index for each queue points to the last valid RPDR read while the write
index points to where the next RPDR can be written. The start index points to the
first valid location within the queue; an RPDR can be written to this location.
However, the end index points to a location that is beyond a queue; an RPDR
can not be written to this location. Note however, the start index of one queue
can be set to the end index of another queue. A queue is empty when the read
index is one less than the write index; a queue is also empty if the read index is
one less than the end index and the write index equals the start index. A queue is
full when the read index is equal to the write index. Figure 6 shows the RPDR
reference queues.
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Figure 6 – RPDRF and RPDRR Queues
Receive Packet Descriptor (RPD) Reference Queues
Base Address:
RQB[31:2] = Rx Queue Base register
Index Registers:
Large Buffer Free Queue:
Small Buffer Free Queue:
RPDRLFQS[15:0] =
RPDRLFQW[15:0] =
RPDRLFQR[15:0] =
RPDRLFQE[15:0] =
RPDRSFQS[15:0]
RPDRSFQW[15:0]
RPDRSFQR[15:0]
RPDRSFQE[15:0]
RPDR Large Free Queue Start register
RPDR Large Free Queue Write register
RPDR Large Free Queue Read register
RPDR Large Free Queue End register
=
=
=
=
RPDR Small Free Queue Start register
RPDR Small Free Queue Write register
RPDR Small Free Queue Read register
RPDR Small Free Queue End register
Ready Queue:
RPDRRQS[15:0]
RPDRRQW[15:0]
RPDRRQR[15:0]
RPDRRQE[15:0]
=
=
=
=
RPDR Ready Queue Start register
RPDR Ready Queue Write register
RPDR Ready Queue Read register
RPDR Ready Queue End register
Base Address
+ Index Register
------------------------Host Address
RQB[31:2]
+
Index[15:0]
00
00
AD[31:0]
Rx Packet Descriptor Reference Queue Memory
M
Bit 31
RPDRRQS
RPDRRQR
Bit 0
Status + RPDR
Status + RPDR
Status + RPDR
Host Memory
Status + RPDR
RPDRRQW
Status + RPDR
Status + RPDR
RPDRRQE
RPDRLFQS
RPDRLFQR
RQB
RPDR
RPD Reference Queues
RPDR
RPDR
RPDRLFQW
RPDRLFQE
RPDRSFQS
RPDRSFQR
RPDR
RPDR
RPDR
RPDR
RPDR
RPDR
Valid RPDR
RPDRSFQW
RPDRSFQE
RPDR
RPDR
RPDR
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Note that the maximum value to which an end pointer may be set is FFFF hex,
resulting in a maximum offset from the queue base address of (4*(FFFF-1)) =
3FFF8 hex. An end pointer must not be set to 0 hex in an attempt to include
offset 3FFFC hex in a queue.
As shown in Figure 6, the ready queue elements have a status field as well as an
RPDR field. The RMAC fills in the status field to mark whether a packet was
successfully received or not. The host reads the status field. The ready queue
element is shown in Table 7 below along with the definition of the status bits.
If the RMAC requires a buffer of a particular size (i.e. small or large) and no
RPDR is available in the corresponding free queue, a RPDR from the other free
queue is substituted. The host may, therefore, force the RMAC to store
received data in buffers of only one size by setting one of the free queues to zero
length, i.e. by setting the start and end index registers of one of the queues to
equal values. If the RMAC requires a buffer and neither free queue contains
RPDRs, an RPQ_ERRI interrupt is generated.
Table 7 – RPDRR Queue Element
Bit 15
Bit 0
STATUS[1:0]
RPDR[13:0]
Field
Description
STATUS[1:0]
The encoding for the status field is as follows:
00 - Successful reception of packet.
01 - Unsuccessful reception of packet.
10 - Unprovisioned partial packet.
11 - Reserved.
RPDR[13:0]
The RPDR[13:0] field defines the offset of the first
RPD in a linked chain of RPDs, each pointing to a
buffer containing the received data.
As described previously, the RMAC links a large buffer RPD to a small buffer
RPD if more than one buffer is needed for a packet. The RMAC links additional
large buffer RPDs to the end of the chain as required until the entire packet is
copied to host memory (provided that the host has not disabled use of both free
queues by setting one of them to length zero). After storing the packet data, the
RMAC places the STATUS+RPDR for the first RPD onto the ready queue. Only
the RPDR associated with the first RPD is placed onto the ready queue. All
other required RPDs are linked to the first RPD as shown in Figure 7.
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Although a STATUS+RPDR only totals to 16 bits, each queue entry is a dword,
i.e. 32 bits. When the RMAC block writes a STATUS+RPDR to the ready queue,
it sets the third byte to 0 and the fourth (most significant) byte is unmodified.
Figure 7 – RPDRR Queue Operation
Rx Packet Descriptor Reference Ready Queue
RPDRRQ_START_ADDR
Bit 31
Bit 0
RPDRRQ_READ_ADDR
buffer
-packet M
RPD - 16 bytes
STATUS + RPDR
STATUS + RPDR
RPDRRQ_WRITE_ADDR
STATUS + RPDR
RPD - 16 bytes
buffer
-packet N
RPD - 16 bytes
buffer
-start of
packet O
RPD - 16 bytes
buffer
-middle of
packet O
RPD - 16 bytes
buffer
-end of
packet O
RPDRRQ_END_ADDR
Receive Channel Descriptor Reference Table
On a per-channel basis, the RMAC caches information such as the current DMA
information in a Receive Channel Descriptor Reference (RCDR) Table. The
RMAC can process 128 channels and stores three dwords of information per
channel. This information is cached internally in order to decrease the number
of host bus accesses required to process each data packet. The structure of the
RCDR table is shown in Figure 8.
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Figure 8 – Receive Channel Descriptor Reference Table
Bit 31
RCC 0
Bit 0
Bytes Available in Buffer[15:0] RBC[1:0]
Buffer Size[15:0]
Res
V
RPD Pointer[13:0]
Start RPD Pointer[13:0]
DMA Current Address[31:0]
RCC 1
Bytes Available in Buffer[15:0] RBC[1:0]
Buffer Size[15:0]
Res
V
RPD Pointer[13:0]
Start RPD Pointer[13:0]
DMA Current Address[31:0]
RCC 127
Bytes Available in Buffer[15:0] RBC[1:0]
Buffer Size[15:0]
Res
V
RPD Pointer[13:0]
Start RPD Pointer[13:0]
DMA Current Address[31:0]
Table 8 – Receive Channel Descriptor Reference Table Fields
Field
Description
Bytes Available in
Buffer[15:0]
This field is used to keep track of the number of bytes
available in the current data buffer. The RMAC initialises
the Bytes Available in Buffer to the Receive Buffer Size
minus the offset at the head of the buffer. The field is
decremented each time a byte is written into the buffer.
RBC[1:0]
This field is used to keep track of the number of buffers
used when storing ‘raw’ (i.e. non packet delimited) data.
The RMAC initialises the RBC field to the value of the
RAWMAX[1:0] field in the RMAC Control Register. The
field is decremented each time a buffer is filled with
data. If the field reaches zero, the chain of RPDs is
placed on the ready queue and a new chain started.
RPD Pointer[13:0]
This field contains the pointer to the current RPD.
Buffer Size[15:0]
This field contains the size in bytes of the buffer
currently being written to.
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Field
Description
V
This bit (Valid) indicates whether a packet is currently
being received on the DMA channel. When the V bit is
set to 1, the other fields in the RCDR table entry for the
DMA channel contain valid information.
Start RPD
Pointer[13:0]
This field contains the pointer to the first RPD for the
packet being received.
DMA Current
Address[31:0]
The DMA Current Address [31:0] bits holds the host
address of the next dword in the current buffer. The
RMAC increments this field on each access to the
buffer.
9.4.2 DMA Transaction Controller
The DMA Transaction Controller coordinates the reception of data packets from
the Receive Packet Interface and their subsequent storage in host memory. A
packet may be received over a number of separate transactions, interleaved with
transactions belonging to other DMA channels. As well as sending the received
data to host memory, the DMA Transaction Controller initiates data transactions
of its own for the purposes of maintaining the data structures (queues,
descriptors, etc.) in host memory.
9.4.3 Write Data Pipeline/Mux
The Write Data Pipeline/Mux performs two functions. First, it pipelines receive
data between the RHDL block and the GPIC block, inserting enough delay to
enable the DMA Transaction Controller to generate appropriate control signals at
the GPIC interface. Second, it provides a multiplexor to the data out lines on the
GPIC interface, allowing the DMA Transaction Controller to output data relating
to the transactions the controller itself initiates.
9.4.4 Descriptor Information Cache
The Descriptor Information Cache provides the storage for the Receive Channel
Descriptor Reference (RCDR) Table described above (Figure 8).
9.4.5 Free Queue Cache
The Free Queue Cache block implements the 6 element RPDR Small Buffer
Free Queue cache and the 6 element RPDR Large Buffer Free Queue cache.
These caches are used to store free small buffer and large buffer RPDRs.
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Caching RPDRs reduces the number of host bus accesses that the RMAC
makes.
Each cache is managed independently. The elements of the cache are
consumed one at a time as they are needed by the RMAC. The RPDR small
buffer cache is reloaded when it is empty and the RMAC requires a new small
buffer RPDR. The large buffer RPDR cache is reloaded when it is empty and the
RMAC requires a new large buffer RPDR. When reloading either of the caches,
the appropriate cache controller will read up to six new elements. The cache
controller may read fewer than six elements if there are fewer than six new
elements available, or the read pointer index is within six elements of the end of
the free queue. If the read pointer is near the end of the free queue, the cache
controller reads only to the end of the queue and does not start reading from the
top of the queue until the next time a reload is required. To do so would require
two host memory transactions and would be of no benefit.
9.5
PCI Controller
The General-Purpose Peripheral Component Interconnect Controller block
(GPIC) provides a 32-bit Master and Target interface core which contains all the
required control functions for Peripheral Component Interconnect (PCI) Bus
Revision 2.1 interfacing. Communications between the PCI bus and other
FREEDM-32 blocks can be made through either an internal asynchronous16-bit
bus or through one of two synchronous FIFO interfaces. One of the FIFO
interfaces is dedicated to servicing the Receive DMA Controller block (RMAC)
and the other to the Transmit DMA Controller block (TMAC).
The GPIC supports a 32-bit PCI bus operating at up to 33 MHz and bridges
between the timing domain of the DMA controllers (SYSCLK) and the timing
domain of the PCI bus (PCICLK). By itself, the GPIC does not generate any PCI
bus accesses. All transactions on the bus are initiated by another PCI bus
master or by the core device. The GPIC transforms each access to and from the
PCI bus to the intended target or initiator in the core device. Except for the
configuration space registers and parity generating/checking, the GPIC performs
no operations on the data.
The GPIC is made up of four sections: master state machine, a target state
machine, internal microprocessor bus interface and error/bus controller. The
target and master blocks operate independent of each other. The error/bus
control block monitors the control signals from the target and master blocks to
determine the state of the PCI I/O pads. This block also generates and/or
checks parity for all data going to or coming from the PCI bus. The internal
microprocessor bus interface block contains configuration and status registers
together with the production test logic for the GPIC block.
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9.5.1 Master Machine
The GPIC master machine translates requests from the RMAC and TMAC block
interfaces into PCI bus transactions. The GPIC initiates four types of PCI cycles:
memory read (burst or single), memory read multiple, memory read line and
memory write (burst or single). The number of data transfers in any cycle is
controlled by the DMA controllers. The maximum burst size is determined by the
particular data path. A read cycle to the RMAC is restricted to a maximum burst
size of 8 dwords and a write cycle is limited to a maximum of 32. The TMAC
interface has a limit of 32 dwords on a read cycle and 8 on a write cycle.
In response to a DMA controller requesting a cycle, the GPIC must arbitrate for
control of the PCI bus. Before asserting the PCI Request line, the GPIC first
does an internal arbitration to determine the priority of service in the event that
both the RMAC and TMAC are requesting service. The GPIC arbitrates between
the four FIFOs based on either a RMAC priority or a round-robin scheme that is
software selectable. It is possible for all four FIFOs (RMAC read, TMAC read,
RMAC write, TMAC write) to request service simultaneously.
When an external PCI bus arbitrator issues a Grant in response to the Request
from the GPIC, the master state machine monitors the PCI bus to insure that the
previous master has completed its transaction and has released the bus before
beginning the cycle. Once the GPIC has control of the bus, it will assert the
FRAME signal and drive the bus with the address and command. The value for
the address is provided by the selected DMA controller. After the initial data
transfer, the GPIC tracks the address for all remaining transfers in the burst
internally in case the GPIC is disconnected by the target and must retry the
transaction.
The target of the GPIC master burst cycle has the option of stopping or
disconnecting the burst at any point. In the event of a target disconnect the
GPIC will terminate the present cycle and release the PCI bus. If the GPIC is
asserting the REQUEST line at the time of the disconnect, it will remove the
REQUEST for two PCI clock cycles then reassert it. When the PCI bus arbitrator
returns the GRANT, the GPIC will restart the burst access at the next address
and continue until the burst is completed or repeat the sequence if the target
disconnects again.
During burst reads, the GPIC accepts the data without inserting any wait states.
Data is written directly into the read FIFO where the RMAC or TMAC can remove
it at its own rate. During burst writes, the GPIC will output the data without
inserting any wait states, but may terminate the transaction early if the local
master fails to fill the write FIFO with data before the GPIC requires it. (If a write
transaction is terminated early due to data starvation, the GPIC will automatically
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initiate a further transaction to write the remaining data when it becomes
available.)
Normally, the GPIC will begin requesting the PCI bus for a write transaction
shortly after data starts to be loaded into the write FIFO by the RMAC or TMAC.
The RMAC, however, is not required to supply a transaction length when writing
packet data and in addition, may insert pauses during the transfer. In the case of
packet data writes by the RMAC, the GPIC will hold off requesting the PCI bus
until the write FIFO has filled up with a number of dwords equal to a
programmable threshold. If the FIFO empties without reaching the end of the
transition, the GPIC will terminate the current transaction and restart a new
transaction to transfer any remaining data when the RMAC signals an end of
transaction. Beginning the PCI transaction before all the data is in the write
FIFO allows the GPIC to reduce the impact of the bus latency on the core
device.
Each master PCI cycle generated by the GPIC can be terminated in three ways:
Completion, Timeout or Master Abort. The normal mode of operation of the GPIC
is to terminate after transferring all the data from the master FIFO selected. As
noted above this may involve multiple PCI accesses because of the inability of
the target to accept the full burst or data starvation during writes. After the
completion of the burst transfer the GPIC will release the bus unless another
FIFO is requesting service, in which case if the GRANT is asserted the GPIC will
insert one idle cycle on the bus and then start a new transfer.
The maximum duration of the a master burst cycle is controlled by the value set
in the LATENCY TIMER register in the GPIC Configuration Register block. This
value is set by the host on boot and is loaded into a counter in the GPIC master
state at the start of each access. If the counter reaches zero and the GRANT
signal has been removed the GPIC will release the bus regardless of whether it
has completed the present burst cycle. This type of termination is referred to as
a Master Time-out. In the case of a Master Time-out the GPIC will remove the
REQUEST signal for two PCI clocks and then reassert it to complete the burst
cycle.
If no target responds to the address placed on the bus by the GPIC after 4 PCI
clocks the GPIC will terminate the cycle and flag the cycle in the PCI Command/
Status Configuration Register as a Master Abort. If the Stop on Error enable
(SOE_E) bit is set in the GPIC Command Register, the GPIC will not process any
more requests until the error condition is cleared. If the SOE_E is not set, the
GPIC will discard the REQUEST and indicate to the local master that the cycle is
complete. This action will result in any write data being lost and any read data
being erroneous.
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9.5.2 Master Local Bus Interface
The master local bus is a 32 bit data bus which connects the local master device
to the GPIC. The GPIC contains two local master interface blocks, with one
supporting the RMAC and the other the TMAC. Each local master interface has
been optimised to support the traffic pattern generated by the RMAC or the
TMAC and are not interchangeable.
The data path between the GPIC and local master device provides a mechanism
to segregate the system timing domain of the core from the PCI bus. Transfers
on each of the RMAC and TMAC interfaces are timed to its own system clock.
The DMA controllers isolated from all aspects of the PCI bus protocol, and
instead “sees” a simple synchronous protocol. Read or write cycles on the local
master bus will initiate a request for service to the GPIC which will then transfer
the data via the PCI bus.
The GPIC maximises data throughput between the PCI bus and the local device
by paralleling local bus data transfers with PCI access latency. The GPIC allows
either DMA controller to write data independent of each other and independent of
PCI bus control. The GPIC temporarily buffers the data from each DMA
controller while it is arbitrating for control of the PCI bus. After completion of a
write transfer, the DMA controller is then released to perform other tasks. The
GPIC can buffer only a single transaction from each DMA controller.
Read accesses on the local bus are optimised by allowing the DMA controllers
access to the data from the PCI bus as soon as the first data becomes available.
After the initial synchronisation and PCI bus latency data is transferred at the
slower of PCI bus rate or the core logic SYSCLK rate. Once a read transaction
is started, the DMA controller is held waiting for the ready signal while the GPIC
is arbitrating for the PCI bus.
All data is passed between the GPIC and the DMA controllers in little Endian
format and, in the default mode of operation, the GPIC expects all data on the
PCI bus to also be in little Endian format. The GPIC provides a selection bit in
the internal Control register which allows the Endian format of the PCI bus data
to be changed. If enabled, the GPIC will swizzle all packet data on the PCI bus
(but not descriptor references and the contents of descriptors). The swizzling is
performed according to the “byte address invariance” rule, i.e. the only change
to the data is the mirror-imaging of byte lanes.
The interface for the RMAC provides for byte addressability of write transactions
whereas the interface for the TMAC provides for byte addressability of read
transactions. Other transactions must be dword aligned. For byte-addressable
transactions, the data transferred between the local device and the GPIC need
not be dword aligned with the data as it is presented on the PCI bus. The GPIC
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will perform any byte-realignment required. In order to complete a transfer
involving byte re-alignment, the GPIC may need to add an extra burst cycle to
the PCI transaction.
9.5.3 Target Machine
The GPIC target machine performs all the required functions of a stand alone
PCI target device. The target block performs three main functions. The first is
the target state machine which controls the protocol of PCI target accesses to
the GPIC. The second function is to provide all PCI Configuration registers.
Last, the target block provides a Target Interface to the CBI registers in the other
FREEDM-32 blocks.
The GPIC tracks the PCI bus and decodes all addresses and commands placed
on the bus to determine whether to respond to the access. The GPIC responds
to the following types of PCI bus commands only: Configuration read and write,
memory read and write, memory-read-multiple and memory-read-line which are
aliased to memory read and memory-write-and-invalidate which is aliased to
memory write. The GPIC will ignore any access that falls within the address
range but has any other command type.
After accepting a target access as a medium speed device, the FREEDM inserts
one wait state for a configuration read/write and five wait states for other
command types before completing the transaction by asserting TRDYB.
Burst accesses to the GPIC are accepted provided they are of linear type. If a
master makes a memory access to the GPIC with the lower two address bits set
to any value but "00" (linear burst type) the GPIC ignores the cycle. Burst
accesses of any length are accepted, but the FREEDM will disconnect if the
master inserts any wait states during the transaction. The FREEDM will also
disconnect on every read and write access to configuration space after
transferring one Dword of data.
Figure 9 illustrates the GPIC address space.
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Figure 9 – GPIC Address Map
PCI ADDRESS MAP
0B
CBI Registers
Base Address
CBI Registers
4KB
4GB
The GPIC responds with medium timing to master accesses. (I.e. DEVSELB is
asserted 2 PCICLK cycles after FRAMEB asserted) It inserts three wait states
on reads to the internal CBI register space (four wait states for the 2nd and
subsequent dwords of a burst read). The target machine will only terminate an
access with a Retry if the target is locked and another master tries to access the
GPIC. The GPIC will terminate any access to a non-burst area with a
Disconnect and always with data transferred. The target does not support
delayed transactions. The GPIC will perform a Target-Abort termination only in
the case of an address parity error in an address that the GPIC claims.
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9.5.4 CBI Bus Interface
The CBI bus interface provides access to the CBI address space of the
FREEDM-32 blocks. The CBI address space is set by the associated BAR in the
PCI Configuration registers.
Write transfers to the CBI space always write all 32 bits provided that at least
one byte enable is asserted. A write command with all byte enables negated will
be ignored. Read transfers always return the 32 bits regardless of the status of
the byte enables, as long as at least one byte enable is asserted. A read
command with all byte enables negated will be ignored.
9.5.5 Error / Bus Control
The Error/Bus Control block monitors signals from both the Target block and
Master Block to determine the direction of the PCI bus pads and to generate or
check parity. After reset, the GPIC sets all bi-directional PCI bus pads to inputs
and monitors the bus for accesses. The Error/Bus control unit remains in this
state unless either the Master requests the PCI bus or the Target responds to a
PCI Master Access. The Error/Bus control unit decodes the state of each state
machine to determine the direction of each PCI bus signal.
All PCI bus devices are required to check and generate even parity across
AD[31:0] and C/BEB[3:0] signals. The GPIC generates parity on Master address
and write data phases; the target generates parity on read data phases. The
GPIC is required to check parity on all PCI bus phases even if it is not
participating in the cycle. But, the GPIC will report parity errors only if the GPIC
is involved in the PCI cycle or if the GPIC detects an address parity error or data
parity is detected in a PCI special cycle. The GPIC updates the PCI
Configuration Status register for all detected error conditions.
9.6
Transmit DMA Controller
The Transmit DMA Controller block (TMAC) is a DMA controller which retrieves
packet data from host computer memory for transmission. The minimum packet
data length is two bytes. The TMAC communicates with the host computer bus
through the master interface connected to PCI Controller block (GPIC) which
translates host bus specific signals from the host to the master interface format.
The TMAC uses the master interface whenever it wishes to initiate a host bus
read or write; in this case, the TMAC is the initiator and the host memory is the
target.
The TMAC and the host exchange information using transmit descriptors (TDs).
The descriptor contains the size and location of buffers in host memory and the
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packet status information associated with the data in each buffer. TDs are
transferred from the TMAC to the host and vice versa using descriptor reference
queues. The TMAC maintains all the pointers for the operation of the queues.
The TMAC acquires buffers with data ready for transmission by reading TDRs
from a TDR ready queue. After a packet has been transmitted, the TMAC places
the associated TDR onto a TDR free queue.
To minimise host bus accesses, the TMAC maintains a descriptor reference table
to store current DMA information. This table contains separate DMA information
entries for up to 128 transmit channels. The TMAC also performs per-channel
sorting of packets received in the TDR ready queue to eliminate head-of-line
blocking.
9.6.1 Data Structures
The TMAC communicates with the host using Transmit Descriptors (TD),
Transmit Descriptor References (TDR), the Transmit Data Reference Ready
(TDRR) queue and the Transmit Data Reference Free (TDRF) queue.
The TMAC reads packet data from data buffers in host memory. The TD, TDR,
TDRR queue, and TDRF queue are data structures which are used to transfer
host memory data buffer information. All four data structures are manipulated by
both the TMAC and the host computer. The TD holds the data buffer size, data
buffer address, and other packet information. The TDR is a pointer which is
used to index into a table of TDs. The TDRR queue and TDRF queue allow the
TMAC and the host to pass TDRs back and forth. These data structures are
described in more detail in the following sections.
Transmit Descriptor
The Transmit Descriptors (TDs) pass buffer and packet information between the
TMAC and the host. Both the TMAC and the host read and write information in
the TDs. TDs are stored in host memory in a Transmit Descriptor Table. The
Transmit Descriptor structure is shown in Figure 10.
Figure 10 – Transmit Descriptor
Bit 31
Bit 0
Data Buffer Start Address [31:0]
Bytes In Buffer [15:0]
Res(2)
TMAC Next TD Pointer [13:0]
Reserved (16)
Reserved (5)
ABT IOC
P
V
M
CE
TCC[6:0]
Host Next TD Pointer [13:0]
Transmit Buffer Size [15:0]
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Table 9 – Transmit Descriptor Fields
Field
Description
Data Buffer Start
Address [31:0]
The Data Buffer Start Address[31:0] bits point to the
data buffer in host memory.
The Data Buffer Start Address field is valid in all TDs
Bytes In Buffer [15:0]
The Bytes In Buffer[15:0] field is used by the host to
indicate the total number of bytes to be transmitted in
the current TD. Zero length buffers are illegal.
P
The Priority bit is set by the host to indicate the
priority of the associated packet in a two level quality
of service scheme. Packets with its P bit set high are
queued in the high priority queue in the TMAC.
Packets with the P bit set low are queued in the low
priority queue. Packets in the low priority queue will
not begin transmission until the high priority queue is
empty.
V
The V bit is used to indicate that the TMAC Next TD
Pointer field is valid. When set to logic 1, the TMAC
Next TD Pointer[13:0] field is valid. When V is set to
logic 0, the TMAC Next TD Pointer[13:0] field is
invalid. The V bit is used by the host to reclaim data
buffers in the event that data presented to the TMAC
is returned to the host due to a channel becoming
unprovisioned. The V bit is expected to be initialised
to logic 0 by the host.
M
The More (M) bit is used by the host to support
packets that require multiple TDs. If M is set to
logic 1, the current TD is just one of several TDs for
the current packet. If M is set to logic 0, this TD
either describes the entire packet (in the single TD
packet case) or describes the end of a packet (in the
multiple TD packet case).
Note: When M is set to logic 1, the only valid value
for CE is logic 0.
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Field
Description
CE
The Chain End (CE) bit is used by the host to indicate
the end of a linked list of TDs presented to the TMAC.
The linked list can contain one or more packets as
delineated by the M bit (see above). When CE is set
to logic 1, the current TD is the last TD of a linked list
of TDs. When CE is set to logic 0, the current TD is
not the last TD of a linked list. When the current TD
is not the last of the linked list, the Host Next TD
Pointer[13:0] field is valid, otherwise the field is not
valid.
Note: When CE is set to logic 1, the only valid value
for M is logic 0.
Note: When presenting raw (i.e. unpacketised) data
for transmission, the host should code the M and CE
bits as for a single packet chain, i.e. M=1, CE=0 for
all TDs except the last in the chain and M=0, CE=1
for the last TD in the chain.
TCC[6:0]
The Transmit Channel Code (TCC[6:0]) field is used
by the host to indicate with which channel a TD is
associated. All TD in a chain must be associated with
the same channel, i.e. have this field set to the same
value.
TMAC Next TD Pointer
[13:0]
The TMAC Next TD Pointer[13:0] bits are used to
store TDRs which permits the TMAC to create linked
lists of TDs passed to it via the TDRR queue. The
TDs are linked with other TDs belonging to the same
channel and same priority level. In the case that data
presented to the TMAC is returned to the host due to
a channel becoming unprovisioned, a TDR pointing to
the start of the per-channel linked list of TDs is placed
on the TDRF queue. It is the responsibility of the
host to follow the TMAC and host links in order to
recover all the buffers.
ABT
The Abort (ABT) bit is used by the host to abort the
transmission of a packet. When ABT is set to logic 1,
the packet will be aborted after all the data in the
buffer has been transmitted. If ABT is set to logic 1 in
the current TD, the M bit must be set low and the CE
bit must be set to high..
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Field
Description
IOC
The Interrupt On Complete (IOC) bit is used by the
host to instruct the TMAC to interrupt the host when
the current TD's data buffer has been read. When
IOC is logic 1, the TMAC asserts the IOCI interrupt
when the data buffer has been read. Additionally, the
Free Queue FIFO will be flushed. If IOC is logic zero,
the TMAC will not generate an interrupt and the Free
Queue FIFO will operate normally.
Host Next TD Pointer
[13:0]
The Host Next TD Pointer[13:0] bits are used to store
TDRs which permits the host to support linked lists of
TDs. As described above, linked lists of TDs are
terminated by setting the CE bit to logic 1. Linked
lists of TDs are used by the host to pass multiple TD
packets or multiple packets associated with the same
channel and priority level to the TMAC.
Transmit Buffer Size
[15:0]
The Transmit Buffer Size[15:0] field is used to
indicate the size in bytes of the current TD's data
buffer. (N.B. The TMAC does not make use of this
field.)
Transmit Descriptor Table
The Transmit Descriptor Table, which resides in host memory, contains all of the
Transmit Descriptors referenced by the TMAC. To access a TD, the TMAC takes
a TDR from a TDRR queue or from the TCDR table and adds 16 times its value
(because each TD is 16 bytes in size) to the Transmit Descriptor Table Base
(TDTB) pointer to form the actual address of the TD in host memory. Each TD
must reside in the Transmit Descriptor Table. The Transmit Descriptor Table can
contain a maximum of 16384 TDs. The base of the Transmit Descriptor Table is
user programmable using the TMAC Tx Descriptor Table Base register. Thus, as
shown below, each TD can be located using a Transmit Descriptor Reference
(TDR) combined with the TMAC Tx Descriptor Table Base register.
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Figure 11 – Transmit Descriptor Table
TDTB[31:4] = Tx Descriptor Table Base register
TDR[13:0] = Transmit Descriptor Reference
TD_ADDR[31:0] = Transmit Descriptor Address
Bit 31
Bit 0
TDTB[31:4]
0000
+
TDR[13:0]
0000
=
TD_ADDR[31:0]
Bit 31
TDTB
TD1
TD_ADDR
Bit 0
Dword 0
Dword 1
Dword 2
Dword 3
Dword 0
TD2
Dword 3
Dword 0
TD 16384
Dword 3
Transmit Queues
Pointers to the transmit descriptors (TDs) containing packet(s) ready for
transmission are passed from the host to the TMAC using the Transmit
Descriptor Reference Ready (TDRR) queue, which resides in host memory.
Pointers to transmit descriptor structures whose buffers have been read by the
TMAC are passed from the TMAC to the host using the Transmit Descriptor
Reference Free (TDRF) queue, which also resides in host memory. The TMAC
contains a Free Queue cache which can store up to six TDRs. If caching is
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enabled, free TDRs are written into the TDRF queue six at a time, to reduce the
number of host memory accesses. The Free Queue cache is also flushed to the
TDRF queue if the Interrupt On Completion (IOC) bit is set in the TD, which
sends the corresponding TDR directly to the TDRF queue.
The queues, shown in Figure 12 are defined by a common base pointer residing
in the Transmit Queue Base register and eight offset pointers, four per queue.
For each queue, two pointers define the start and the end of the queue, and two
pointers keep track of the current read and write locations within the queue. The
read pointer for each queue points to the offset of the last valid TDR read, and
the write pointer points to the offset where next TDR can be written. The end of
a queue is not a valid location for a TDR to be read or written. A queue is empty
when the read pointer is one less than the write pointer or if the read pointer is
one less than the end pointer and the write pointer equals the start pointer. A
queue is full when the read pointer is equal to the write pointer. Each queue
element is 32 bits in size, but only the 17 least significant bits are valid. The 17
least significant bits consist of a 14-bit TDR and three status bits. The status bits
are used by the TMAC to inform the host of the success or failure of
transmission (see Table 10). When the TMAC writes TDRs to the TDRF queue,
it sets bits [23:17] of the queue element to 0. Once a TDR is placed on the
TDRF queue, the FREEDM-32 will make no further accesses to the TD nor the
associated buffer.
Note that the maximum value to which an end pointer may be set is FFFF hex,
resulting in a maximum offset from the queue base address of (4*(FFFF-1)) =
3FFF8 hex. An end pointer must not be set to 0 hex in an attempt to include
offset 3FFFC hex in a queue.
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Figure 12 – TDRR and TDRF Queues
Transmit Descriptor Referance Queues
Base Address:
TQB[31:2] = Tx Queue Base register
Index Registers:
Ready:
TDRRQS[15:0] =
TDRRQW[15:0] =
TDRRQR[15:0] =
TDRRQE[15:0] =
TDR Ready Queue Start register
TDR Ready Queue Write register
TDR Ready Queue Read register
TDR Ready Queue End register
Base Address
+ Index Register
------------------------PCI Address
Free:
TDRFQS[15:0] =
TDRFQW[15:0] =
TDRFQR[15:0] =
TDRFQE[15:0] =
TDR Free Queue Start register
TDR Free Queue Write register
TDR Free Queue Read register
TDR Free Queue End register
TQB[31:2]
+
00
Index[15:0] 00
AD[31:0]
Tx Descriptor Reference Queue Memory Map
TDRFQS
TDRFQR
Bit 31
Bit 0
Status + TDR
PCI Host Memory
Status + TDR
Status + TDR
Status + TDR
TDRFQW
Status + TDR
Status + TDR
TQB
256KB
TDR Reference Queues
TDRFQE
TDRRQS
TDRRQR
TDR
TDR
TDR
TDRRQW
TDRRQE
TDR
TDR
TDR
Valid TDR. Only least
significant 17
bits are valid.
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Table 10 – Transmit Descriptor Reference
Bit 16
Bit 0
STATUS[2:0]
TDR[13:0]
Field
Description
Status[2:0]
The TMAC fills in the Status field to indicate to the host
the results of processing the TD. The encoding is:
TDR[13:0]
Status[1:0]
Description
00
Last or only buffer of packet, buffer read.
01
Buffer of partial packet, buffer read.
10
Unprovisioned channel, buffer not read.
11
Malformed packet (e.g. Bytes In Buffer field
set to 0), buffer not read.
Status[2]
Description
0
No underflow detected.
1
Underflow detected.
The TDR[13:0] field contains the offset of the TD
returned.
If a TDR is returned to the host with the status field set to “10” (unprovisioned
channel), the TDR may point to a binary tree of TDs and buffers (as indicated by
the CE and V bits in the TDs). It is the responsibility of the host to traverse the
tree to reclaim all the buffers. If a TDR is returned to the host with the status
field set to any other value, the TDR will only point to one TD and buffer
regardless of the values of V and CE in that TD.
The underflow status bit (Status[2]) is normally attached to the TDR belonging to
a packet experiencing underflow. For long packets spanning multiple buffers,
underflow is reported only once at the first available TDR of that channel. All
subsequent TDRs of that packet will be returned normally without the underflow
status. In rare cases, due to internal buffering by the FREEDM-32, a packet may
experience underflow at the very end of a packet, just as the TDR is being
returned to the TDR free queue. The underflow status will then be reported in
the first TDR of the immediate next packet of that channel. Because of the
uncertainty with the reporting of underflows between the current verse the
subsequent packet, the underflow status should only be used to gather
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performance statistics on channels and not for initiating packet specific
responses such as retransmission.
Transmit Channel Descriptor Reference Table
The TMAC maintains a Transmit Channel Descriptor Reference (TCDR) table in
which is stored certain information relating to DMA activity on each channel
together with TD pointers which are used by the TMAC to sort packet chains
supplied by the host into per-channel linked lists (see below). The caching of
DMA-related information reduces the number of host bus accesses required to
process each data packet, while the sorting into per-channel linked lists
eliminates head of line blocking. Each channel is provided with two entries in the
TCDR table, one for high priority packets (Pri 1) and one for low priority packets
(Pri 0). The structure of the TCDR table is shown in Figure 13 below.
Figure 13 – Transmit Channel Descriptor Reference Table
Bit 31
TCC 0, Pri 0
M CE
Bit 0
Last TD Pointer [13:0]
Bytes to Tx [15:0]
A
D
Current TD Pointer [13:0]
Abrt IOC
Host TD Pointer [13:0]
DMA Current Address [31:0]
Reserved
TCC 1, Pri 0
M CE
PiP NA U
Last TD Pointer [13:0]
Bytes to Tx [15:0]
Last
M
V
Next TD Pointer [13:0]
A
D
Current TD Pointer [13:0]
Abrt IOC
Host TD Pointer [13:0]
DMA Current Address [31:0]
Reserved
PiP NA U
Last
M
V
Next TD Pointer [13:0]
A
D
Current TD Pointer [13:0]
:
:
:
TCC 127, Pri 1
M CE
Last TD Pointer [13:0]
Bytes to Tx [15:0]
Abrt IOC
Host TD Pointer [13:0]
DMA Current Address [31:0]
Reserved
PiP NA U
Last
M
V
Next TD Pointer [13:0]
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Table 11 – Transmit Channel Descriptor Reference Table Fields
Field
Description
M
A copy of the M bit in the TD currently being read.
CE
A copy of the CE bit in the TD currently being read.
Last TD Pointer [13:0]
Offset to the head of the last host-linked chain of TDs
to be read. (See Figure 14)
A
Indicates if this channel is active (i.e. provisioned). If
the channel is active, the A bit is set to logic 1. If the
channel is inactive, the A bit is set to logic 0.
D
Indicates whether the linked list of packets for this
channel is empty or not. If the D bit is set to logic 1,
the list is not empty and the current TD pointer field is
valid (i.e., it points to a valid TD). If the D bit is set to
logic 0, the list is empty and the current TD pointer field
is invalid.
Current TD Pointer
[13:0]
Offset to the TD currently being read.
Bytes To Tx[15:0]
The Bytes to Tx[15:0] bits are used to indicate the total
number of bytes that remain to be read in the current
buffer. Each access to the data buffer decrements this
value. A value of zero in this field indicates the buffer
has been completely read.
ABRT
A copy of the ABRT bit in the TD currently being read.
IOC
A copy of the IOC bit in the TD currently being read.
PiP
The Packet Transfer in Progress bit indicates that a
packet is currently being transmitted on this channel at
this priority level.
NA
Indicates that a ‘null abort’ is to be sent to the
downstream block when it next requests data on this
channel. The NA bit is set if a mal-formed TD is
encountered while searching down a host chain.
U
Indicates that a underflow has occurred on this
channel. This bit is set in response to an underflow
indication for the downstream THDL block and is
cleared when a TDR is written to the TDR Free Queue
(or to the free queue cache).
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Field
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Description
Host TD Pointer [13:0] A copy of the Host Next TD Pointer field of the TD
currently being read, i.e. a pointer to the next TD in the
chain currently being read. (See Figure 14)
DMA Current
Address[31:0]
The DMA Current Address [31:0] bits hold the address
of the next dword in the current buffer. This field is
incremented on each access to the buffer.
V
Indicates if the linked list of packets for this channel
contains more than one host-linked chain (See Figure
14). If the V bit is set to logic 1, the list contains more
than one chain and the next and last TD pointer fields
are valid. If the V bit is set to logic 0, the list is either
empty or contains only one host-linked chain and the
next and last TD pointer fields are invalid.
Next TD Pointer [13:0] Offset to the head of the next host-linked chain of TDs
to be read. (See Figure 14)
Transmit Descriptor Linking
As described above, the TCDR table contains pointers which the TMAC uses to
construct linked lists of data packets to be transmitted. After the host places a
new TDR in the TDR Ready queue, the TMAC retrieves the TDR and links it to
the TD pointed at by the Last TD Pointer field. The TMAC may create up to 256
linked lists, viz. a high-priority list and a low-priority list for each DMA channel.
Whenever a new data packet is requested by the downstream block, the TMAC
picks a packet from the high-priority linked list unless it is empty, in which case, a
packet from the low-priority linked list is used.
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Figure 14 – TD Linking
TD
TD
Curr. Next Last Host
TDR TDR TDR TDR
V=1
M=1
CE=0
TCDR Table
TD
P3
P1
V=1
M=1
CE=0
TMAC Link
Data
Host Link
P4
TMAC Link
V=0
M=0
CE=1
Data
Host Link
TD
TD
P3
P1
M=1
CE=0
M=0
CE=1
Data
Data
Host Link
TD
P1
M=0
CE=0
Data
Host Link
TD
P2
M=0
CE=1
Data
The host links the TDs vertically while the TMAC links TDs horizontally. Figure
14 shows the TDs for packets P1 and P2 linked by the host before the TDR is
placed on the TDRR queue, as are the TDs for packet P3. Packet P3 is linked to
packet P1 by the TMAC, as is packet P4 linked to packet P3. The TMAC
indicates valid horizontal links by setting the V bit to logic 1.
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9.6.2 Task Priorities
The TMAC must perform a number of tasks concurrently in order to maintain a
steady flow of data through the system. The main tasks of the TMAC are
managing the Ready Queue (i.e. removing chains of data packets from the
queue and attaching them to the appropriate per-channel linked list) and
servicing requests for data from the Transmit Packet Interface. The priority of
service for each of the tasks is fixed by the TMAC as follows:·
Top priority is given to servicing ‘expedited’ read requests from the Transmit
HDLC Processor / Partial Packet Buffer block (THDL).
·
Second priority is given to removing chains of data packets from the TDRR
queue and attaching them to the appropriate per-channel linked list.
·
Third priority is given to servicing non-expedited read requests from the
THDL.
9.6.3 DMA Transaction Controller
The DMA Transaction Controller coordinates the processing of requests from the
THDL with the reading of data stored in host memory. The reading of a data
packet may require a number of separate host memory transactions, interleaved
with transactions of other DMA channels. As well as reading data from the Host
Master Interface, the DMA Transaction Controller initiates read and write
transactions to the PCI Controller block (GPIC) for the purposes of maintaining
the data structures (queues, descriptors, etc.) in host memory.
9.6.4 Read Data Pipeline
The Read Data Pipeline inserts delay in the data stream between the GPIC
interface and the THDL interface to enable the DMA Transaction Controller to
generate appropriate control signals at the Transmit Packet Interface.
9.6.5 Descriptor Information Cache
The Descriptor Information Cache provides the storage for the Transmit Channel
Descriptor Reference (TCDR) Table.
9.6.6 Free Queue Cache
The Free Queue Cache block implements the 6 element TDR Free Queue
cache. Caching TDRs reduces the number of host bus accesses that the TMAC
makes.
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TDRs are written to the cache one at a time as they are released by the TMAC.
The cache is then flushed to host memory when it becomes full, when a TD with
the IOC bit set high is released or when a TD is released as the result of
unprovisioning a channel. The cache controller may also flush the cache when it
contains fewer than six elements or if the pointer index is within six elements of
the end of the free queue. If the write pointer is near the end of the free queue,
the cache controller writes only to the end of the queue and does not start writing
from the top of the queue until the next time a flush is required. To do so would
require two host memory transactions and would be of no benefit.
9.7
Transmit HDLC Controller / Partial Packet Buffer
The Transmit HDLC Controller / Partial Packet Buffer block (THDL) contains a
partial packet buffer for PCI latency control and a transmit HDLC controller.
Packet data retrieved from the PCI host memory by the Transmit DMA Controller
block (TMAC) is stored in channel specific FIFOs residing in the partial packet
buffer. When the amount of data in a FIFO reaches a programmable threshold,
the HDLC controller is enabled to initiate transmission. The HDLC controller
performs flag generation, bit stuffing and, optionally, frame check sequence
(FCS) insertion. The FCS is software selectable to be CRC-CCITT or CRC-32.
The minimum packet size, excluding FCS, is two bytes. A single byte payload is
illegal. The HDLC controller delivers data to the Transmit Channel Assigner
block (TCAS) on demand. A packet in progress is aborted if an under-run
occurs. The THDL is programmable to operate in transparent mode where
packet data retrieved from the PCI host is transmitted verbatim.
9.7.1 Transmit HDLC Processor
The HDLC processor is a time-slice state machine which can process up to 128
independent channels. The state vector and provisioning information for each
channel is stored in a RAM. Whenever the TCAS requests data, the appropriate
state vector is read from the RAM, processed and finally written back to the
RAM. The HDLC state-machine can be configured to perform flag insertion, bit
stuffing and CRC generation. The HDLC processor requests data from the
partial packet processor whenever a request for channel data arrives. However,
the HDLC processor does not start transmitting a packet until the entire packet is
stored in the channel FIFO or until the FIFO free space is less than the software
programmable limit. If a channel FIFO under-runs, the HDLC processor aborts
the packet.
The configuration of the HDLC processor is accessed using indirect channel
read and write operations. When an indirect operation is performed, the
information is accessed from RAM during a null clock cycle inserted by the TCAS
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block. Writing new provisioning data to a channel resets the channel's entire
state vector.
9.7.2 Transmit Partial Packet Buffer Processor
The partial packet buffer processor controls the 8 Kbyte partial packet RAM
which is divided into 16 byte blocks. A block pointer RAM is used to chain the
partial packet blocks into circular channel FIFO buffers. Thus, non-contiguous
sections of RAM can be allocated in the partial packet buffer RAM to create a
channel FIFOFigure 15 shows an example of three blocks (blocks 1, 3, and 200)
linked together to form a 48 byte channel FIFO. The three pointer values would
be written sequentially using indirect block write accesses. When a channel is
provisioned with this FIFO, the state machine can be initialised to point to any
one of the three blocks.
The partial packet buffer processor is divided into three sections: reader, writer
and roamer. The roamer is a time-sliced state machine which tracks each
channel's FIFO buffer free space and signals the writer to service a particular
channel. The writer requests data from the TMAC block and transfers packet
data from the TMAC to the associated channel FIFO. The reader is a time-sliced
state machine which transfers the HDLC information from a channel FIFO to the
HDLC processor when the HDLC processor requests it. If a buffer under-run
occurs for a channel, the reader informs the HDLC processor and purges the
rest of the packet.
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Figure 15 – Partial Packet Buffer Structure
Partial Packet
Buffer RAM
Block
Pointer RAM
Block 0
16 bytes
Block 0
XX
Block 1
16 bytes
Block 1
0x03
Block 2
16 bytes
Block 2
XX
Block 3
16 bytes
Block 3
0xC8
Block 200
16 bytes
Block 200
0x01
Block 511
16 bytes
Block 511
XX
The writer and reader determine empty and full FIFO conditions using flags.
Each block in the partial packet buffer has an associated flag. The writer sets
the flag after the block is written and the reader clears the flag after the block is
read. The flags are initialized (cleared) when the block pointers are written using
indirect block writes. The reader declares a channel FIFO under-run whenever it
tries to read data from a block without a set flag.
The FIFO algorithm of the partial packet buffer processor is based on perchannel software programmable transfer size and free space trigger level.
Instead of tracking the number of full blocks in a channel FIFO, the processor
tracks the number of empty blocks, called free space, as well as the number of
end of packets stored in the FIFO. Recording the number of empty blocks
instead of the number of full blocks reduces the amount of information the
roamer must store in its state RAM.
The partial packet roamer records the FIFO free space and end-of-packet count
for all channel FIFOs. When the reader signals that a block has been read, the
roamer increments the FIFO free space and sets a per-channel request flag if
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the free space is greater than the limit set by XFER[2:0]. The roamer also
decrements the end-of-packet count when the reader signals that it has passed
an end of a packet to the HDLC processor. If the HDLC is transmitting a packet
and the FIFO free space is greater than the free space trigger level and there are
no complete packets within the FIFO (end-of-packet count equal to zero), a perchannel expedite flag is set. The roamer searches the expedite flags in a roundrobin fashion to decide which channel FIFO should make expedited data
requests to the TMAC block. If no expedite flags are set, the roamer searches
the request flags in a round-robin fashion to decide which channel FIFO should
make regular data requests to the TMAC block. The roamer informs the partial
packet writer of the channel FIFO to process, the FIFO free space and the type
of request it should make. The writer sends a request for data to the TMAC
block and writes the response data to the channel FIFO setting block full flags.
The writer reports back to the roamer the number of blocks and end-of-packets
transferred. The maximum amount of data transferred during one request is
limited by a software programmable limit.
The configuration of the HDLC processor is accessed using indirect channel
read and write operations as well as indirect block read and write operations.
When an indirect operation is performed, the information is accessed from RAM
during a null clock cycle identified by the TCAS block. Writing new provisioning
data to a channel resets the entire state vector.
9.8
Transmit Channel Assigner
The Transmit Channel Assigner block (TCAS) processes up to 128 channels.
Data for all channels is sourced from a single byte-serial stream from the
Transmit HDLC Controller / Partial Packet Buffer block (THDL). The TCAS
demultiplexes the data and assigns each byte to any one of 32 links. Each link is
independent and has its own associated clock. For each high-speed link
(TD[2:0]), the TCAS provides a six byte FIFO. For the remaining links
(TD[31:3]), the TCAS provides a holding register. The TCAS also performs
parallel to serial conversion to form a bit-serial stream. In the event where
multiple links are in need of data, TCAS requests data from upstream blocks on
a fixed priority basis with link TD[0] having the highest priority and link TD[31] the
lowest.
Links containing a T1 or an E1 stream may be channelised. Data at each timeslot may be independently assigned to be sourced from a different channel. The
link clock is only active during time-slots 1 to 24 of a T1 stream and is inactive
during the frame bit. Similarly, the clock is only active during time-slots 1 to 31 of
an E1 stream and is inactive during the FAS and NFAS framing bytes. The most
significant bit of time-slot 1 of a channelised link is identified by noting the
absence of the clock and its re-activation. With knowledge of the transmit link
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and time-slot identity, the TCAS performs a table look-up to identify the channel
from which a data byte is to be sourced.
Links may also be unchannelised. Then, all data bytes on that link belong to one
channel. The TCAS performs a table look-up to identify the channel to which a
data byte belongs using only the outgoing link identity, as no time-slots are
associated with unchannelised links. Link clocks are no longer limited to T1 or
E1 rates and may range up to 52 MHz for TCLK[2:0]. For TCLK[31:3] the
maximum clock rate is 10 MHz. The link clock is only active during bit times
containing data to be transmitted and inactive during bits that are to be ignored
by the downstream devices, such as framing and overhead bits. For the case of
two unchannelised links, the maximum link rate is 45 MHz for SYSCLK at
25 MHz and 52 MHz for SYSCLK at 33 MHz. For the case of more numerous
unchannelised links or a mixture of channelised and unchannelised links, the
total instantaneous link rate over all the links is limited to 64 MHz.
9.8.1 Line Interface
There are two types of line interfaces in the TCAS; high-speed and low-speed
interfaces. Three identical high-speed interfaces are attached to the first three
links, while 29 identical low-speed interfaces are attached to the remaining links.
Each line interface contains a bit counter, an 8-bit shift register and a byte FIFO,
that, together, perform parallel to serial conversion. For the high-speed
interfaces the FIFO is six bytes deep. For the low-speed interfaces, the FIFO is
a single byte holding register. Whenever the shift register is updated, a request
for service is sent to the priority encoder block. The request will eventually be
serviced by the THDL block and the data is written into the FIFO.
To support channelised links, each line interface block contains a time-slot
counter and a clock activity monitor. The time-slot counter is incremented each
time the shift register is updated. The clock activity monitor is a counter that
increments at the system clock (SYSCLK) rate and is cleared by a rising edge of
the transmit clock (TCLK[n]). A framing bit (T1) or framing byte (E1) is detected
when the counter reaches a programmable threshold. At which point, the bit and
time-slot counters are initialised to indicate the next bit sampled is the most
significant bit of the first time-slot. For unchannelised links, the time-slot counter
and the clock activity monitor are held reset.
9.8.2 Priority Encoder
The priority encoder monitors the line interfaces for requests and synchronises
them to the SYSCLK timing domain. Requests are serviced on a fixed priority
scheme where highest to lowest priority is assigned from line interface TD[0] to
line interface TD[31]. Thus, simultaneous requests from line interface TD[m] will
be serviced ahead of line interface TD[n], if m < n. The priority encoder selects
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the request from the link with the highest priority for service. When there are no
pending requests, the priority encoder generates an idle cycle. In addition, once
every fourth SYSCLK cycle, the priority encoder inserts a null cycle where no
requests are serviced. This cycle is used by the channel assigner downstream
for CBI accesses to the channel provision RAM.
9.8.3 Channel Assigner
The channel assigner block determines the channel number of the request
currently being processed. The block contains a 1024 word channel provision
RAM. The address of the RAM is constructed from concatenating the link
number and the time-slot number of the highest priority requester. The fields of
each RAM word include the channel number and a time-slot enable flag. The
time-slot enable flag labels the current time-slot as belonging to the channel
indicted by the channel number field. For time-slots that are enabled, the
channel assigner issues a request to the THDL block which responds with packet
data within one byte period of the transmit stream.
9.9
Performance Monitor
The Performance Monitor block (PMON) contains four counters. The first two
accumulate receive partial packet buffer FIFO overrun events and transmit partial
packet buffer FIFO underflow events, respectively. The remaining two counters
are software programmable to accumulate a variety of events, such as receive
packet count, FCS error counts, etc. All counters saturate upon reaching
maximum value. The accumulation logic consists of a counter and holding
register pair. The counter is incremented when the associated event is detected.
Writing to the FREEDM-32 Master Clock / BERT Activity Monitor and
Accumulation Trigger register transfer the count to the corresponding holding
register and clear the counter. The contents of the holding register is accessible
via the PCI interface.
9.10 JTAG Test Access Port Interface
The JTAG Test Access Port block provides JTAG support for boundary scan.
The standard JTAG EXTEST, SAMPLE, BYPASS, IDCODE and STCTEST
instructions are supported. The FREEDM-32 identification code is 173640CD
hexadecimal.
9.11 PCI Host Interface
The FREEDM-32 supports two different normal mode register types as defined
below:
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1. PCI Host Accessible registers (PA) - these registers can be accessed through
the PCI Host interface.
2. PCI Configuration registers (PC) - these register can only be accessed
through the PCI Host interface during a PCI configuration cycle.
The PCI registers are addressable on dword boundaries only. The PCI offset
shown in the table below must be combined with a base address to form the PCI
Interface address. The base address can be found in the FREEDM-32 Memory
Base Address register in the PCI Configuration memory space.
Table 12 – Normal Mode PCI Host Accessible Register Memory Map
PCI Offset
Register
0x000
FREEDM-32 Master Reset
0x004
FREEDM-32 Master Interrupt Enable
0x008
FREEDM-32 Master Interrupt Status
0x00C
FREEDM-32 Master Clock / BERT Activity Monitor and
Accumulation Trigger
0x010
FREEDM-32 Master Link Activity Monitor
0x014
FREEDM-32 Master Line Loopback #1
0x018
FREEDM-32 Master Line Loopback #2
0x01C
Reserved
0x020
FREEDM-32 Master BERT Control
0x024
FREEDM-32 Master Performance Monitor Control
0x028 - 0x03C
Reserved
0x040
GPIC Control
0x044 - 0x07C
GPIC Reserved
0x080 - 0x0FC
Reserved
0x100
RCAS Indirect Channel and Time-slot Select
0x104
RCAS Indirect Channel Data
0x108
RCAS Framing Bit Threshold
0x10C
RCAS Channel Disable
0x110 - 0x17C
RCAS Reserved
0x180
RCAS Link #0 Configuration
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PCI Offset
Register
0x184 - 0x1FC
RCAS Link #1 to Link #31 Configuration
0x200
RHDL Indirect Channel Select
0x204
RHDL Indirect Channel Data Register #1
0x208
RHDL Indirect Channel Data Register #2
0x20C
RHDL Reserved
0x210
RHDL Indirect Block Select
0x214
RHDL Indirect Block Data Register
0x218
RHDL Reserved
0x21C
RHDL Reserved
0x220
RHDL Configuration
0x224
RHDL Maximum Packet Length
0x228 - 0x23C
RHDL Reserved
0x240 - 0x27C
Reserved
0x280
RMAC Control
0x284
RMAC Indirect Channel Provisioning
0x288
RMAC Packet Descriptor Table Base LSW
0x28C
RMAC Packet Descriptor Table Base MSW
0x290
RMAC Queue Base LSW
0x294
RMAC Queue Base MSW
0x298
RMAC Packet Descriptor Reference Large Buffer Free Queue
Start
0x29C
RMAC Packet Descriptor Reference Large Buffer Free Queue
Write
0x2A0
RMAC Packet Descriptor Reference Large Buffer Free Queue
Read
0x2A4
RMAC Packet Descriptor Reference Large Buffer Free Queue
End
0x2A8
RMAC Packet Descriptor Reference Small Buffer Free Queue
Start
0x2AC
RMAC Packet Descriptor Reference Small Buffer Free Queue
Write
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PCI Offset
Register
0x2B0
RMAC Packet Descriptor Reference Small Buffer Free Queue
Read
0x2B4
RMAC Packet Descriptor Reference Small Buffer Free Queue
End
0x2B8
RMAC Packet Descriptor Reference Ready Queue Start
0x2BC
RMAC Packet Descriptor Reference Ready Queue Write
0x2C0
RMAC Packet Descriptor Reference Ready Queue Read
0x2C4
RMAC Packet Descriptor Reference Ready Queue End
0x2C8 - 0x2FC
RMAC Reserved
0x300
TMAC Control
0x304
TMAC Indirect Channel Provisioning
0x308
TMAC Descriptor Table Base LSW
0x30C
TMAC Descriptor Table Base MSW
0x310
TMAC Queue Base LSW
0x314
TMAC Queue Base MSW
0x318
TMAC Descriptor Reference Free Queue Start
0x31C
TMAC Descriptor Reference Free Queue Write
0x320
TMAC Descriptor Reference Free Queue Read
0x324
TMAC Descriptor Reference Free Queue End
0x328
TMAC Descriptor Reference Ready Queue Start
0x32C
TMAC Descriptor Reference Ready Queue Write
0x330
TMAC Descriptor Reference Ready Queue Read
0x334
TMAC Descriptor Reference Ready Queue End
0x338 - 0x37C
TMAC Reserved
0x380
THDL Indirect Channel Select
0x384
THDL Indirect Channel Data #1
0x388
THDL Indirect Channel Data #2
0x38C
THDL Indirect Channel Data #3
0x390
THDL Reserved
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PCI Offset
Register
0x394
THDL Reserved
0x398
THDL Reserved
0x39C
THDL Reserved
0x3A0
THDL Indirect Block Select
0x3A4
THDL Indirect Block Data
0x3A8
THDL Reserved
0x3AC
THDL Reserved
0x3B0
THDL Configuration
0x3B4 - 0x3BC
THDL Reserved
0x3C0 - 0x3FF
Reserved
0x400
TCAS Indirect Channel and Time-slot Select
0x404
TCAS Indirect Channel Data
0x408
TCAS Framing Bit Threshold
0x40C
TCAS Idle Time-slot Fill Data and Config.
0x410
TCAS Channel Disable
0x414 - 0x47C
TCAS Reserved
0x480
TCAS Link #0 Configuration
0x484 - 0x4FC
TCAS Link #1 to Link #31 Configuration
0x500
PMON Status
0x504
PMON Receive FIFO Overflow Count
0x508
PMON Transmit FIFO Underflow Count
0x50C
PMON Configurable Count #1
0x510
PMON Configurable Count #2
0x514 - 0x51C
PMON Reserved
0x520 - 0x7FC
Reserved
The following PCI configuration registers are implemented by the PCI Interface.
These registers can only be accessed when the PCI Interface is a target and a
configuration cycle is in progress as indicated using the IDSEL input.
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Table 13 – PCI Configuration Register Memory Map
PCI Offset
Register
0x00
Vendor Identification/Device Identification
0x04
Command/Status
0x08
Revision Identifier/Class Code
0x0C
Cache Line Size/Latency Timer/Header Type/BIST
0x10
CBI Memory Base Address Register
0x14 - 0x24
Unused Base Address Register
0x28
Reserved
0x2C
Reserved
0x30
Reserved
0x34
Reserved
0x38
Reserved
0x3C
Interrupt Line/Interrupt Pin/MIN_GNT/MAX_LAT
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NORMAL MODE REGISTER DESCRIPTION
Normal mode registers are used to configure and monitor the operation of the
FREEDM.
Notes on Normal Mode Register Bits:
1. Writing values into unused register bits has no effect. However, to ensure
software compatibility with future, feature-enhanced versions of the product,
unused register bits must be written with logic zero. Reading back unused
bits can produce either a logic one or a logic zero; hence, unused register bits
should be masked off by software when read.
2. Except where noted, all configuration bits that can be written into can also be
read back. This allows the processor controlling the FREEDM-32 to
determine the programming state of the block.
3. Writable normal mode register bits are cleared to logic zero upon reset unless
otherwise noted.
4. Writing into read-only normal mode register bit locations does not affect
FREEDM-32 operation unless otherwise noted.
5. Certain register bits are reserved. These bits are associated with megacell
functions that are unused in this application. To ensure that the FREEDM-32
operates as intended, reserved register bits must only be written with their
default values. Similarly, writing to reserved registers should be avoided.
10.1 PCI Host Accessible Registers
PCI host accessible registers can be accessed by the PCI host. For each
register description below, the hexadecimal register number indicates the PCI
offset from the base address in the FREEDM-32 CBI Register Base Address
Register when accesses are made using the PCI Host Port.
Note
These registers are not byte addressable. Writing to any one of these registers
modifies all the bits in the register. Byte selection using byte enable signals
(CBEB[3:0]) are not implemented. However, when all four byte enables are
negated, no access is made to the register.
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Register 0x000 : FREEDM-32 Master Reset
Bit
Type
Function
Default
Unused
XXXXH
Reset
0
Bit 14
Unused
X
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
Bit 8
Unused
X
Bit 7
Unused
X
Bit 6
Unused
X
Bit 5
Unused
X
Bit 4
Unused
X
Bit 3
Unused
X
Bit 2
Unused
X
Bit 1
Unused
X
Bit 0
Unused
X
Bit 31
to
Bit 16
Bit 15
R/W
This register provides software reset capability.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
RESET:
The RESET bit allows the FREEDM-32 to be reset under software control. If
the RESET bit is a logic one, the entire FREEDM-32 except the PCI Interface
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is held in reset. This bit is not self-clearing. Therefore, a logic zero must be
written to bring the FREEDM-32 out of reset. Holding the FREEDM-32 in a
reset state places it into a low power, stand-by mode. A hardware reset
clears the RESET bit, thus negating the software reset.
Note
Unlike the hardware reset input (RSTB), RESET does not force the FREEDM32's PCI pins tri-state. Transmit link data pins (TD[31:0]) are forced high. In
addition, all registers except the GPIC PCI Configuration registers, are reset to
their default values.
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Register 0x004 : FREEDM-32 Master Interrupt Enable
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
TFUDRE
0
Bit 14
R/W
IOCE
0
Bit 13
R/W
TDFQEE
0
Bit 12
R/W
TDQRDYE
0
Bit 11
R/W
TDQFE
0
Bit 10
R/W
RPDRQEE
0
Bit 9
R/W
RPDFQEE
0
Bit 8
R/W
RPQRDYE
0
Bit 7
R/W
RPQLFE
0
Bit 6
R/W
RPQSFE
0
Bit 5
R/W
RFOVRE
0
Bit 4
R/W
RPFEE
0
Bit 3
R/W
RABRTE
0
Bit 2
R/W
RFCSEE
0
Bit 1
R/W
PERRE
0
Bit 0
R/W
SERRE
0
This register provides interrupt enables for various events detected or initiated by
the FREEDM.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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SERRE:
The system error interrupt enable bit (SERRE) enables PCI system error
interrupts to the PCI host. When SERRE is set high, any address parity error,
data parity error on Special Cycle commands, reception of a master abort or
detection of a target abort will cause an interrupt to be generated on the
PCIINTB output. Interrupts are masked when SERRE is set low. However,
the SERRI bit remains valid when interrupts are disabled and may be polled
to detect PCI system error events.
PERRE:
The parity error interrupt enable bit (PERRE) enables PCI parity error
interrupts to the PCI host. When PERRE is set high, data parity errors
detected by the FREEDM-32 or parity errors reported by a target will cause
an interrupt to be generated on the PCIINTB output. Interrupts are masked
when PERRE is set low. However, the PERRI bit remains valid when
interrupts are disabled and may be polled to detect PCI parity error events.
RFCSEE:
The receive frame check sequence error interrupt enable bit (RFCSEE)
enables receive FCS error interrupts to the PCI host. When RFCSEE is set
high, a mismatch between the received FCS code and the computed CRC
residue will cause an interrupt to be generated on the PCIINTB output.
Interrupts are masked when RFCSEE is set low. However, the RFCSEI bit
remains valid when interrupts are disabled and may be polled to detect
receive FCS error events.
RABRTE:
The receive abort interrupt enable bit (RABRTE) enables receive HDLC abort
interrupts to the PCI host. When RABRTE is set high, receipt of an abort
code (at least 7 contiguous 1's) will cause an interrupt to be generated on the
PCIINTB output. Interrupts are masked when RABRTE is set low. However,
the RABRTI bit remains valid when interrupts are disabled and may be polled
to detect receive abort events.
RPFEE:
The receive packet format error interrupt enable bit (RPFEE) enables receive
packet format error interrupts to the PCI host. When RPFEE is set high,
receipt of a packet that is longer than the maximum specified in the RHDL
Maximum Packet Length register, of a packet that is shorter than 32 bits
(CRC-CCITT) or 48 bits (CRC-32), or of a packet that is not octet aligned will
cause an interrupt to be generated on the PCIINTB output. Interrupts are
masked when RPFEE is set low. However, the RPFEI bit remains valid when
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interrupts are disabled and may be polled to detect receive packet format
error events.
RFOVRE:
The receive FIFO overrun error interrupt enable bit (RFOVRE) enables
receive FIFO overrun error interrupts to the PCI host. When RFOVRE is set
high, attempts to write data into the logical FIFO of a channel when it is
already full will cause an interrupt to be generated on the PCIINTB output.
Interrupts are masked when RFOVRE is set low. However, the RFOVRI bit
remains valid when interrupts are disabled and may be polled to detect
receive FIFO overrun events.
RPQSFE:
The receive packet descriptor small buffer free queue cache read interrupt
enable bit (RPQSFE) enables receive packet descriptor small free queue
cache read interrupts to the PCI host. When RPQSFE is set high, reading a
programmable number of RPDR blocks from the RPDR Small Buffer Free
Queue will cause an interrupt to be generated on the PCIINTB output.
Interrupts are masked when RPQSFE is set low. However, the RPQSFI bit
remains valid when interrupts are disabled and may be polled to detect
RPDR small buffer free queue cache read events.
RPQLFE:
The receive packet descriptor large buffer free queue cache read interrupt
enable bit (RPQLFE) enables receive packet descriptor large free queue
cache read interrupts to the PCI host. When RPQLFE is set high, reading a
programmable number of RPDR blocks from the RPDR Large Buffer Free
Queue will cause an interrupt to be generated on the PCIINTB output.
Interrupts are masked when RPQLFE is set low. However, the RPQLFI bit
remains valid when interrupts are disabled and may be polled to detect
RPDR large buffer free queue cache read events.
RPQRDYE:
The receive packet descriptor ready queue write interrupt enable bit
(RPQRDYE) enables receive packet descriptor ready queue write interrupts
to the PCI host. When RPQRDYE is set high, writing a programmable
number of RPDRs to the RPDR Ready Queue will cause an interrupt to be
generated on the PCIINTB output. Interrupts are masked when RPQRDYE is
set low. However, the RPQRDYI bit remains valid when interrupts are
disabled and may be polled to detect RPDR ready queue write events.
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RPDFQEE:
The receive packet descriptor free queue error interrupt enable bit
(RPDFQEE) enables receive packet descriptor free queue error interrupts to
the PCI host. When RPDFQEE is set high, attempts to retrieve an RPDR
when both the large buffer and small buffer free queues are empty will cause
an interrupt to be generated on the PCIINTB output. Interrupts are masked
when RPDFQEE is set low. However, the RPDFQEI bit remains valid when
interrupts are disabled and may be polled to detect RPDR free queue empty
error events.
RPDRQEE:
The receive packet descriptor ready queue error interrupt enable bit
(RPDRQEE) enables receive packet descriptor ready queue error interrupts
to the PCI host. When RPDRQEE is set high, attempts to write an RPDR
when ready queue is ready full will cause an interrupt to be generated on the
PCIINTB output. Interrupts are masked when RPDRQEE is set low.
However, the RPDRQEI bit remains valid when interrupts are disabled and
may be polled to detect RPDR ready queue full error events.
TDQFE:
The transmit packet descriptor free queue write interrupt enable bit (TDQFE)
enables transmit packet descriptor free queue write interrupts to the PCI host.
When TDQFE is set high, writing a programmable number of TDRs to the
TDR Free Queue will cause an interrupt to be generated on the PCIINTB
output. Interrupts are masked when TDQFE is set low. However, the TDQFI
bit remains valid when interrupts are disabled and may be polled to detect
TDR free queue write events.
TDQRDYE:
The transmit descriptor ready queue cache read interrupt enable bit
(TDQRDYE) enables transmit descriptor ready queue cache read interrupts
to the PCI host. When TDQRDYE is set high, reading a programmable
number of TDRs from the TDR Ready Queue will cause an interrupt to be
generated on the PCIINTB output. Interrupts are masked when TDQRDYE is
set low. However, the TDQRDYI bit remains valid when interrupts are
disabled and may be polled to detect TDR ready queue cache read events.
TDFQEE:
The transmit descriptor free queue error interrupt enable bit (TDFQEE)
enables transmit descriptor free queue error interrupts to the PCI host. When
TDFQEE is set high, attempting to write to the transmit free queue while the
queue is full will cause an interrupt to be generated on the PCIINTB output.
Interrupts are masked when TDFQEE is set low. However, the TDFQEI bit
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remains valid when interrupts are disabled and may be polled to detect TD
free queue error events.
IOCE:
The transmit interrupt on complete enable bit (IOCE) enables transmission
complete interrupts to the PCI host. When IOCE is set high, complete
transmission of a packet with the IOC bit in the TD set high will cause an
interrupt to be generated on the PCIINTB output. Interrupts are masked
when IOCE is set low. However, the IOCI bit remains valid when interrupts
are disabled and may be polled to detect transmission of IOC tagged
packets.
TFUDRE:
The transmit FIFO underflow error interrupt enable bit (TFUDRE) enables
transmit FIFO underflow error interrupts to the PCI host. When TFUDRE is
set high, attempts to read data from the logical FIFO when it is already empty
will cause an interrupt to be generated on the PCIINTB output. Interrupts are
masked when TFUDRE is set low. However, the TFUDRI bit remains valid
when interrupts are disabled and may be polled to detect transmit FIFO
underflow events.
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Register 0x008 : FREEDM-32 Master Interrupt Status
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R
TFUDRI
X
Bit 14
R
IOCI
X
Bit 13
R
TDFQEI
X
Bit 12
R
TDQRDYI
X
Bit 11
R
TDQFI
X
Bit 10
R
RPDRQEI
X
Bit 9
R
RPDFQEI
X
Bit 8
R
RPQRDYI
X
Bit 7
R
RPQLFI
X
Bit 6
R
RPQSFI
X
Bit 5
R
RFOVRI
X
Bit 4
R
RPFEI
X
Bit 3
R
RABRTI
X
Bit 2
R
RFCSEI
X
Bit 1
R
PERRI
X
Bit 0
R
SERRI
X
This register reports the interrupt status for various events detected or initiated
by the FREEDM. Reading this registers acknowledges and clears the interrupts.
Note
This register is not byte addressable. Reading this register clears all the interrupt
bits in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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SERRI:
The system error interrupt status bit (SERRI) reports PCI system error
interrupts to the PCI host. SERRI is set high upon detection of any address
parity error, data parity error on Special Cycle commands, reception of a
master abort or detection of a target abort event. The SERRI bit remains
valid when interrupts are disabled and may be polled to detect PCI system
error events.
PERRI:
The parity error interrupt status bit (PERRI) reports PCI parity error interrupts
to the PCI host. PERRI is set high when data parity errors are detected by
the FREEDM-32 while acting as a master, and when parity errors are
reported to the FREEDM-32 by a target via the PERRB input. The PERRI bit
remains valid when interrupts are disabled and may be polled to detect PCI
parity error events.
RFCSEI:
The receive frame check sequence error interrupt status bit (RFCSEI) reports
receive FCS error interrupts to the PCI host. RFCSEI is set high, when a
mismatch between the received FCS code and the computed CRC residue is
detected. RFCSEI remains valid when interrupts are disabled and may be
polled to detect receive FCS error events.
RABRTI:
The receive abort interrupt status bit (RABRTI) reports receive HDLC abort
interrupts to the PCI host. RABRTI is set high upon receipt of an abort code
(at least 7 contiguous 1's). RABRTI remains valid when interrupts are
disabled and may be polled to detect receive abort events.
RPFEI:
The receive packet format error interrupt status bit (RPFEI) reports receive
packet format error interrupts to the PCI host. RPFEI is set high upon receipt
of a packet that is longer than the maximum programmed length, of a packet
that is shorter than 32 bits (CRC-CCITT) or 48 bits (CRC-32), or of a packet
that is not octet aligned. RPFEI remains valid when interrupts are disabled
and may be polled to detect receive packet format error events.
RFOVRI:
The receive FIFO overrun error interrupt status bit (RFOVRI) reports receive
FIFO overrun error interrupts to the PCI host. RFOVRI is set high on
attempts to write data into the logical FIFO of a channel when it is already full.
RFOVRI remains valid when interrupts are disabled and may be polled to
detect receive FIFO overrun events.
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RPQSFI:
The receive packet descriptor small buffer free queue cache read interrupt
status bit (RPQSFI) reports receive packet descriptor small free queue cache
read interrupts to the PCI host. RPQSFI is set high when the programmable
number of RPDR blocks is read from the RPDR Small Buffer Free Queue.
RPQSFI remains valid when interrupts are disabled and may be polled to
detect RPDR small buffer free queue cache read events.
RPQLFI:
The receive packet descriptor large buffer free queue cache read interrupt
status bit (RPQLFI) reports receive packet descriptor large free queue cache
read interrupts to the PCI host. RPQLFI is set high when the programmable
number of RPDR blocks is read from the RPDR Large Buffer Free Queue.
RPQLFI remains valid when interrupts are disabled and may be polled to
detect RPDR large buffer free queue cache read events.
RPQRDYI:
The receive packet descriptor ready queue write interrupt status bit
(RPQRDYI) reports receive packet descriptor ready queue write interrupts to
the PCI host. RPQRDYI is set high when the programmable number of
RPDRs is written to the RPDR Ready Queue. RPQRDYI remains valid when
interrupts are disabled and may be polled to detect RPDR ready queue write
events.
RPDFQEI:
The receive packet descriptor free queue error interrupt status bit (RPDFQEI)
reports receive packet descriptor free queue error interrupts to the PCI host.
RPDFQEI is set high upon attempts to retrieve an RPDR when both the large
buffer and small buffer free queues are empty. RPDFQEI remains valid when
interrupts are disabled and may be polled to detect RPDR free queue empty
error events.
RPDRQEI:
The receive packet descriptor ready queue error interrupt status bit
(RPDRQEI) reports receive packet descriptor ready queue error interrupts to
the PCI host. RPDRQEI is set high upon attempts to write an RPDR when
ready queue is ready full. RPDRQEI remains valid when interrupts are
disabled and may be polled to detect RPDR ready queue full error events.
TDQFI:
The transmit packet descriptor free queue write interrupt status bit (TDQFI)
reports transmit packet descriptor free queue write interrupts to the PCI host.
TDQFI is set high when the programmable number of TDRs is written to the
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TDR Free Queue. TDQFI remains valid when interrupts are disabled and
may be polled to detect TDR free queue write events.
TDQRDYI:
The transmit descriptor ready queue cache read interrupt status bit
(TDQRDYI) reports transmit descriptor ready queue cache read interrupts to
the PCI host. TDQRDYI is set high when the programmable number of TDRs
is read from the TDR Ready Queue. TDQRDYI remains valid when interrupts
are disabled and may be polled to detect TDR ready queue cache read
events.
TDFQEI:
The transmit descriptor free queue error interrupt status bit (TDFQEI) reports
transmit descriptor free queue error interrupts to the PCI host. TDFQEI is set
high when an attempt to write to the transmit free queue fail due to the queue
being already full. TDFQEI bit remains valid when interrupts are disabled and
may be polled to detect TD free queue error events.
IOCI:
The transmit interrupt on complete status bit (IOCI) reports transmission
complete interrupts to the PCI host. IOCI is set high, when a packet with the
IOC bit in the TD set high is completely transmitted. IOCI remains valid when
interrupts are disabled and may be polled to detect transmission of IOC
tagged packets.
TFUDRI:
The transmit FIFO underflow error interrupt status bit (TFUDRI) reports
transmit FIFO underflow error interrupts to the PCI host. TFUDRI is set high
upon attempts to read data from the logical FIFO when it is already empty.
TFUDRI remains valid when interrupts are disabled and may be polled to
detect transmit FIFO underflow events.
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Register 0x00C : FREEDM-32 Master Clock / BERT Activity Monitor and
Accumulation Trigger
Bit
Type
Function
Default
Bit 31
to
Bit 16
Unused
XXXXH
Bit 15
Unused
X
Bit 14
Unused
X
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
Bit 8
Unused
X
Bit 7
Unused
X
Bit 6
Unused
X
Bit 5
Unused
X
Bit 4
Unused
X
Bit 3
Unused
X
Bit 2
Unused
X
Bit 1
R
TBDA
X
Bit 0
R
SYSCLKA
X
This register provides activity monitoring on FREEDM-32 clock inputs and BERT
port input. When a monitored input makes a low to high transition, the
corresponding register bit is set high. The bit will remain high until this register is
read, at which point, all the bits in this register are cleared. A lack of transitions
is indicated by the corresponding register bit reading low. This register should be
read periodically to detect for stuck at conditions.
Writing to this register delimits the accumulation intervals in the PMON
accumulation registers. Counts accumulated in those registers are transferred to
holding registers where they can be read. The counters themselves are then
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cleared to begin accumulating events for a new accumulation interval. The bits
in this register are not affected by write accesses.
Note
This register is not byte addressable. Reading this register clears all the activity
bits in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
SYSCLKA:
The system clock active bit (SYSCLKA) monitors for low to high transitions on
the SYSCLK input. SYSCLKA is set high on a rising edge of SYSCLK, and is
set low when this register is read.
TBDA:
The transmit BERT data active bit (TBDA) monitors for low to high transitions
on the TBD input. TBDA is set high on a rising edge of TDB, and is set low
when this register is read.
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Register 0x010 : FREEDM-32 Master Link Activity Monitor
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R
TLGA[7]
X
Bit 14
R
TLGA[6]
X
Bit 13
R
TLGA[5]
X
Bit 12
R
TLGA[4]
X
Bit 11
R
TLGA[3]
X
Bit 10
R
TLGA[2]
X
Bit 9
R
TLGA[1]
X
Bit 8
R
TLGA[0]
X
Bit 7
R
RLGA[7]
X
Bit 6
R
RLGA[6]
X
Bit 5
R
RLGA[5]
X
Bit 4
R
RLGA[4]
X
Bit 3
R
RLGA[3]
X
Bit 2
R
RLGA[2]
X
Bit 1
R
RLGA[1]
X
Bit 0
R
RLGA[0]
X
This register provides activity monitoring on FREEDM-32 receive and transmit
link inputs. When a monitored input makes a low to high transition, the
corresponding register bit is set high. The bit will remain high until this register is
read, at which point, all the bits in this register are cleared. A lack of transitions
is indicated by the corresponding register bit reading low. This register should be
read at periodically to detect for stuck at conditions.
Note
This register is not byte addressable. Reading this register clears all the activity
bits in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
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implemented. However, when all four byte enables are negated, no access is
made to this register.
RLGA[0]:
The receive link group #0 active bit (RLGA[0]) monitors for transitions on the
RD[3:0] and RCLK[3:0] inputs. RLGA[0] is set high when each of RD[3:0]
has been sampled low and sampled high by rising edges of the
corresponding RCLK[3:0] inputs, and is set low when this register is read.
RLGA[1]:
The receive link group #1 active bit (RLGA[1]) monitors for transitions on the
RD[7:4] and RCLK[7:4] inputs. RLGA[1] is set high when each of RD[7:4]
has been sampled low and sampled high by rising edges of the
corresponding RCLK[7:4] inputs, and is set low when this register is read.
RLGA[2]:
The receive link group #2 active bit (RLGA[2]) monitors for transitions on the
RD[11:8] and RCLK[11:8] inputs. RLGA[2] is set high when each of RD[11:8]
has been sampled low and sampled high by rising edges of the
corresponding RCLK[11:8] inputs, and is set low when this register is read.
RLGA[3]:
The receive link group #3 active bit (RLGA[3]) monitors for transitions on the
RD[15:12] and RCLK[15:12] inputs. RLGA[3] is set high when each of
RD[15:12] has been sampled low and sampled high by rising edges of the
corresponding RCLK[15:12] inputs, and is set low when this register is read.
RLGA[4]:
The receive link group #4 active bit (RLGA[4]) monitors for transitions on the
RD[19:16] and RCLK[19:16] inputs. RLGA[4] is set high when each of
RD[19:16] has been sampled low and sampled high by rising edges of the
corresponding RCLK[19:16] inputs, and is set low when this register is read.
RLGA[5]:
The receive link group #5 active bit (RLGA[5]) monitors for transitions on the
RD[23:20] and RCLK[23:20] inputs. RLGA[5] is set high when each of
RD[23:20] has been sampled low and sampled high by rising edges of the
corresponding RCLK[23:20] inputs, and is set low when this register is read.
RLGA[6]:
The receive link group #6 active bit (RLGA[6]) monitors for transitions on the
RD[27:24] and RCLK[27:24] inputs. RLGA[6] is set high when each of
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RD[27:24] has been sampled low and sampled high by rising edges of the
corresponding RCLK[27:24] inputs, and is set low when this register is read.
RLGA[7]:
The receive link group #7 active bit (RLGA[7]) monitors for transitions on the
RD[31:28] and RCLK[31:28] inputs. RLGA[7] is set high when each of
RD[31:28] has been sampled low and sampled high by rising edges of the
corresponding RCLK[31:28] inputs, and is set low when this register is read.
TLGA[0]:
The transmit link group #0 active bit (TLGA[0]) monitors for low to high
transitions on the TCLK[3:0] inputs. TLGA[0] is set high when rising edges
have been observed on all the signals on the TCLK[3:0] inputs, and is set low
when this register is read.
TLGA[1]:
The transmit link group #1 active bit (TLGA[1]) monitors for low to high
transitions on the TCLK[7:4] inputs. TLGA[1] is set high when rising edges
have been observed on all the signals on the TCLK[7:4] inputs, and is set low
when this register is read.
TLGA[2]:
The transmit link group #2 active bit (TLGA[2]) monitors for low to high
transitions on the TCLK[11:8] inputs. TLGA[2] is set high when rising edges
have been observed on all the signals on the TCLK[11:8] inputs, and is set
low when this register is read.
TLGA[3]:
The transmit link group #3 active bit (TLGA[3]) monitors for low to high
transitions on the TCLK[15:12] inputs. TLGA[3] is set high when rising edges
have been observed on all the signals on the TCLK[15:12] inputs, and is set
low when this register is read.
TLGA[4]:
The transmit link group #4 active bit (TLGA[4]) monitors for low to high
transitions on the TCLK[19:16] inputs. TLGA[4] is set high when rising edges
have been observed on all the signals on the TCLK[19:16] inputs, and is set
low when this register is read.
TLGA[5]:
The transmit link group #5 active bit (TLGA[5]) monitors for low to high
transitions on the TCLK[23:20] inputs. TLGA[5] is set high when rising edges
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have been observed on all the signals on the TCLK[23:20] inputs, and is set
low when this register is read.
TLGA[6]:
The transmit link group #6 active bit (TLGA[6]) monitors for low to high
transitions on the TCLK[27:24] inputs. TLGA[6] is set high when rising edges
have been observed on all the signals on the TCLK[27:24] inputs, and is set
low when this register is read.
TLGA[7]:
The transmit link group #7 active bit (TLGA[7]) monitors for low to high
transitions on the TCLK[31:28] inputs. TLGA[7] is set high when rising edges
have been observed on all the signals on the TCLK[31:28] inputs, and is set
low when this register is read.
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Register 0x014 : FREEDM-32 Master Line Loopback #1
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
LLBEN[15]
0
Bit 14
R/W
LLBEN[14]
0
Bit 13
R/W
LLBEN[13]
0
Bit 12
R/W
LLBEN[12]
0
Bit 11
R/W
LLBEN[11]
0
Bit 10
R/W
LLBEN[10]
0
Bit 9
R/W
LLBEN[9]
0
Bit 8
R/W
LLBEN[8]
0
Bit 7
R/W
LLBEN[7]
0
Bit 6
R/W
LLBEN[6]
0
Bit 5
R/W
LLBEN[5]
0
Bit 4
R/W
LLBEN[4]
0
Bit 3
R/W
LLBEN[3]
0
Bit 2
R/W
LLBEN[2]
0
Bit 1
R/W
LLBEN[1]
0
Bit 0
R/W
LLBEN[0]
0
This register controls line loopback for links #0 to #15.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
LLBEN[15:0]:
The line loopback enable bits (LLBEN[15:0]) controls line loopback for
links #15 to #0. When LLBEN[n] is set high, the data on RD[n] is passed
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verbatim to TD[n] which is then updated on the falling edge of RCLK[n].
TCLK[n] is ignored. When LLBEN[n] is set low, TD[n] is processed normally.
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Register 0x018 : FREEDM-32 Master Line Loopback #2
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
LLBEN[31]
0
Bit 14
R/W
LLBEN[30]
0
Bit 13
R/W
LLBEN[29]
0
Bit 12
R/W
LLBEN[28]
0
Bit 11
R/W
LLBEN[27]
0
Bit 10
R/W
LLBEN[26]
0
Bit 9
R/W
LLBEN[25]
0
Bit 8
R/W
LLBEN[24]
0
Bit 7
R/W
LLBEN[23]
0
Bit 6
R/W
LLBEN[22]
0
Bit 5
R/W
LLBEN[21]
0
Bit 4
R/W
LLBEN[20]
0
Bit 3
R/W
LLBEN[19]
0
Bit 2
R/W
LLBEN[18]
0
Bit 1
R/W
LLBEN[17]
0
Bit 0
R/W
LLBEN[16]
0
This register controls line loopback for links #16 to #31.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
LLBEN[31:16]:
The line loopback enable bits (LLBEN[31:16]) controls line loopback for
links #31 to #16. When LLBEN[n] is set high, the data on RD[n] is passed
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verbatim to TD[n] which is then updated on the falling edge of RCLK[n].
TCLK[n] is ignored. When LLBEN[n] is set low, TD[n] is processed normally.
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Register 0x020 : FREEDM-32 Master BERT Control
Bit
Type
Function
Default
Unused
XXXXH
TBEN
0
Bit 14
Unused
X
Bit 13
Unused
X
Bit 31
to
Bit 16
Bit 15
R/W
Bit 12
R/W
TBSEL[4]
0
Bit 11
R/W
TBSEL[3]
0
Bit 10
R/W
TBSEL[2]
0
Bit 9
R/W
TBSEL[1]
0
Bit 8
R/W
TBSEL[0]
0
Bit 7
R/W
RBEN
0
Bit 6
Unused
X
Bit 5
Unused
X
Bit 4
R/W
RBSEL[4]
0
Bit 3
R/W
RBSEL[3]
0
Bit 2
R/W
RBSEL[2]
0
Bit 1
R/W
RBSEL[1]
0
Bit 0
R/W
RBSEL[0]
0
This register controls the bit error rate testing of the receive and transmit links.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
RBSEL[4:0]:
The receive bit error rates testing link select bits (RBSEL[4:0]) controls the
source of data on the RBD and RBCLK outputs when receive bit error rate
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testing is enabled (RBEN set high). RBSEL[4:0] is a binary number that
selects a receive link (RD[31:0]/RCLK[31:0]) to be the source of data for RBD
and RBCLK outputs. RBSEL[4:0] is ignored when RBEN is set low.
RBEN:
The receive bit error rates testing link enable bit (RBEN) controls the receive
bit error rate testing port. When RBEN is set high, RBSEL[4:0] is a binary
number that selects a receive link (RD[31:0]/RCLK[31:0]) to be the source of
data for RBD and RBCLK outputs. When RBEN is set low, RBD and RBCLK
are held tri-stated.
TBSEL[4:0]:
The transmit bit error rates testing link select bits (TBSEL[4:0]) controls the
over-writing of transmit data on TD[31:0] by data on TBD when transmit bit
error rate testing is enabled (TBEN set high) and the selected link is not in
line loopback (LLBEN[n] set low). TBSEL[4:0] is a binary number that selects
a transmit link (TD[31:0]/TCLK[31:0]) to carry the data on TBD. The TBCLK
output is a buffered version of the selected one of TCLK[31:0]. TBSEL[4:0] is
ignored when TBEN is set low.
TBEN:
The transmit bit error rates testing link enable bit (TBEN) controls the transmit
bit error rate testing port. When TBEN is set high and the associated link in
not in line loopback (LLBEN set low), TBSEL[4:0] is a binary number that
selects a transmit link data (TD[31:0]) to be the carry the data on TBD and
selects a transmit link clock (TCLK[31:0]) as the source of TBCLK. When
TBEN is set low, all transmit links are processed normally and TBCLK is held
tri-stated.
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Register 0x024 : FREEDM-32 Master Performance Monitor Control
Bit
Type
Function
Default
Bit 31
to
Bit 16
Unused
XXXXH
Bit 15
Unused
X
Bit 14
R/W
TP2EN
0
Bit 13
R/W
TABRT2EN
0
Bit 12
R/W
RP2EN
0
Bit 11
R/W
RLENE2EN
0
Bit 10
R/W
RABRT2EN
0
Bit 9
R/W
RFCSE2EN
0
Bit 8
R/W
RSPE2EN
0
Unused
X
Bit 7
Bit 6
R/W
TP1EN
0
Bit 5
R/W
TABRT1EN
0
Bit 4
R/W
RP1EN
0
Bit 3
R/W
RLENE1EN
0
Bit 2
R/W
RABRT1EN
0
Bit 1
R/W
RFCSE1EN
0
Bit 0
R/W
RSPE1EN
0
This register configures the events that are accumulated in the two configurable
performance monitor counters in the PMON block.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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RSPE1EN:
The receive small packet error accumulate enable bit (RSPE1EN) enables
counting of minimum packet size violation events. When RSPE1EN is set
high, receipt of a packet that is shorter than 32 bits (CRC-CCITT, Unspecified
CRC or no CRC) or 48 bits (CRC-32) will cause the PMON Configurable
Accumulator #1 register to increment. Small packet errors are ignored when
RSPE1EN is set low.
RFCSE1EN:
The receive frame check sequence error accumulate enable bit (RFCSE1EN)
enables counting of receive FCS error events. When RFCSE1EN is set high,
a mismatch between the received FCS code and the computed CRC residue
will cause the PMON Configurable Accumulator #1 register to increment.
Receive frame check sequence errors are ignored when RFCSE1EN is set
low.
RABRT1EN:
The receive abort accumulate enable bit (RABRT1EN) enables counting of
receive HDLC abort events. When RABRT1EN is set high, receipt of an
abort code (at least 7 contiguous 1's) will cause the PMON Configurable
Accumulator #1 register to increment. Receive aborts are ignored when
RABRT1EN is set low.
RLENE1EN:
The receive packet length error accumulate enable bit (RLENE1EN) enables
counting of receive packet length error events. When RLENE1EN is set high,
receipt of a packet that is longer than the programmable maximum or of a
packet that in not octet aligned will cause the PMON Configurable
Accumulator #1 register to increment. Receive packet length errors are
ignored when RLENE1EN is set low.
RP1EN:
The receive packet enable bit (RP1EN) enables counting of receive error-free
packets. When RP1EN is set high, receipt of an error-free packet will cause
the PMON Configurable Accumulator #1 register to increment. Receive errorfree packets are ignored when RP1EN is set low.
TABRT1EN:
The transmit abort accumulate enable bit (TABRT1EN) enables counting of
transmit HDLC abort events. When TABRT1EN is set high, insertion of an
abort in the outgoing stream will cause the PMON Configurable Accumulator
#1 register to increment. Transmit aborts are ignored when TABRT1EN is set
low.
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TP1EN:
The transmit packet enable bit (TP1EN) enables counting of transmit
error-free packets. When TP1EN is set high, transmission of an error-free
packet will cause the PMON Configurable Accumulator #1 register to
increment. Transmit error-free packets are ignored when TP1EN is set low.
RSPE2EN:
The receive small packet error accumulate enable bit (RSPE2EN) enables
counting of minimum packet size violation events. When RSPE2EN is set
high, receipt of a packet that is shorter than 32 bits (CRC-CCITT, Unspecified
CRC or no CRC) or 48 bits (CRC-32) will cause the PMON Configurable
Accumulator #2 register to increment. Small packet errors are ignored when
RSPE2EN is set low.
RFCSE2EN:
The receive frame check sequence error accumulate enable bit (RFCSE2EN)
enables counting of receive FCS error events. When RFCSE2EN is set high,
a mismatch between the received FCS code and the computed CRC residue
will cause the PMON Configurable Accumulator #2 register to increment.
Receive frame check sequence errors are ignored when RFCSE2EN is set
low.
RABRT2EN:
The receive abort accumulate enable bit (RABRT2EN) enables counting of
receive HDLC abort events. When RABRT2EN is set high, receipt of an
abort code (at least 7 contiguous 2's) will cause the PMON Configurable
Accumulator #2 register to increment. Receive aborts are ignored when
RABRT2EN is set low.
RLENE2EN:
The receive packet length error accumulate enable bit (RLENE2EN) enables
counting of receive packet length error events. When RLENE2EN is set high,
receipt of a packet that is longer than the programmable maximum or of a
packet that in not octet aligned will cause the PMON Configurable
Accumulator #2 register to increment. Receive packet length errors are
ignored when RLENE2EN is set low.
RP2EN:
The receive packet enable bit (RP2EN) enables counting of receive error-free
packets. When RP2EN is set high, receipt of an error-free packet will cause
the PMON Configurable Accumulator #2 register to increment. Receive errorfree packets are ignored when RP2EN is set low.
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TABRT2EN:
The transmit abort accumulate enable bit (TABRT2EN) enables counting of
transmit HDLC abort events. When TABRT2EN is set high, insertion of an
abort in the outgoing stream will cause the PMON Configurable Accumulator
#2 register to increment. Transmit aborts are ignored when TABRT2EN is set
low.
TP2EN:
The transmit packet enable bit (TP2EN) enables counting of transmit
error-free packets. When TP2EN is set high, transmission of an error-free
packet will cause the PMON Configurable Accumulator #2 register to
increment. Transmit error-free packets are ignored when TP2EN is set low.
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Register 0x040 : GPIC Control
Bit
Type
Function
Default
Bit 31
to
Bit 16
Unused
XXXXH
Bit 15
Unused
X
Bit 14
Unused
X
Bit 13
Unused
X
Bit 12
R/W
RPWTH[4]
0
Bit 11
R/W
RPWTH[3]
0
Bit 10
R/W
RPWTH[2]
0
Bit 9
R/W
RPWTH[1]
0
Bit 8
R/W
RPWTH[0]
0
Bit 7
Unused
X
Bit 6
Unused
X
Bit 5
Unused
X
Bit 4
Unused
X
Bit 3
R/W
PONS_E
0
Bit 2
R/W
SOE_E
0
Bit 1
R/W
LENDIAN
1
Bit 0
R/W
Reserved
0
This register configures the operation of the GPIC.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
Reserved:
The Reserved bit must be set low for correct operation of the FREEDM.
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LENDIAN:
The Little Endian mode bit (LENDIAN) selects between Big Endian or Little
Endian format when reading packet data from and writing packet data to PCI
host memory. When LENDIAN is set low, Big Endian format is selected.
When LENDIAN is set high, Little Endian format is selected. Descriptor
references and the contents of descriptors are always transferred in Little
Endian Format. Please refer below for each format's byte ordering.
Table 14 – Big Endian Format
00
DWORD Address
04
n-4
Bit 31
24
23
16
15
8
7
Bit 0
BYTE 0
BYTE 1
BYTE 2
BYTE 3
BYTE 4
BYTE 5
BYTE 6
BYTE 7
•
•
•
•
•
•
•
•
•
•
•
•
BYTE n-4
BYTE n-3
BYTE n-2
BYTE n-1
Table 15 – Little Endian Format
00
DWORD Address
04
n-4
Bit 31
24
23
16
15
8
7
Bit 0
BYTE 3
BYTE 2
BYTE 1
BYTE 0
BYTE 7
BYTE 6
BYTE 5
BYTE 4
•
•
•
•
•
•
•
•
•
•
•
•
BYTE n-1
BYTE n-2
BYTE n-3
BYTE n-4
SOE_E:
The stop on error enable (SOE_E) bit determines the action the PCI
controller will take when a system or parity error occurs. When set high the
PCI controller will disconnect the PCI REQB signal from the PCI bus. This
prevents the GPIC from the becoming a master device on the PCI bus in
event of one of the following bits in the PCI Configuration Command/Status
register being set: DPR, RTABT, MABT and SERR. When the SOE_E bit is
set low the PCI controller will continue to allow master transactions on the
PCI bus. Setting this bit low after an error has occurred or clearing the
appropriate bit the PCI Configuration Command/Status register will reactivate
the PCI REQB signal and allow the GPIC to resume servicing the local
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masters. In the event of a system or parity error it is recommended that the
core device be reset unless the cause of the fault can be determined.
PONS_E:
The Report PERR on SERR enable (PONS_E) bit controls the source of
system errors. When set high all parity errors will be signaled to the host via
the SERRB output signal.
RPWTH[4:0]:
The Receive Packet Write Threshold bits (RPWTH[4:0]) controls the amount
of data in the write FIFO before the GPIC begins arbitrating for the bus. The
GPIC will begin requesting access to the PCI bus when the number of dwords
of packet data loaded by the RMAC reaches the threshold specified by
RPWTH[4:0].
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Register 0x100 : RCAS Indirect Link and Time-slot Select
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R
BUSY
X
Bit 14
R/W
RWB
0
Unused
X
Bit 13
Bit 12
R/W
LINK[4]
0
Bit 11
R/W
LINK[3]
0
Bit 10
R/W
LINK[2]
0
Bit 9
R/W
LINK[1]
0
Bit 8
R/W
LINK[0]
0
Bit 7
Unused
X
Bit 6
Unused
X
Bit 5
Unused
X
Bit 4
R/W
TSLOT[4]
0
Bit 3
R/W
TSLOT[3]
0
Bit 2
R/W
TSLOT[2]
0
Bit 1
R/W
TSLOT[1]
0
Bit 0
R/W
TSLOT[0]
0
This register provides the receive link and time-slot number used to access the
channel provision RAM. Writing to this register triggers an indirect register
access.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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TSLOT[4:0]:
The indirect time-slot number bits (TSLOT[4:0]) indicate the time-slot to be
configured or interrogated in the indirect access. For a channelised T1 link,
time-slots 1 to 24 are valid. For a channelised E1 link, time-slots 1 to 31 are
valid. For unchannelised links, only time-slot 0 is valid.
LINK[4:0]:
The indirect link number bits (LINK[4:0]) select amongst the 32 receive links
to be configured or interrogated in the indirect access.
RWB:
The indirect access control bit (RWB) selects between a configure (write) or
interrogate (read) access to the channel provision RAM. The address to the
channel provision RAM is constructed by concatenating the TSLOT[4:0] and
LINK[4:0] bits. Writing a logic zero to RWB triggers an indirect write
operation. Data to be written is taken from the PROV, the CDLBEN and the
CHAN[6:0] bits of the RCAS Indirect Channel Data register. Writing a logic
one to RWB triggers an indirect read operation. Addressing of the RAM is the
same as in an indirect write operation. The data read can be found in the
PROV, the CDLBEN and the CHAN[6:0] bits of the RCAS Indirect Channel
Data register.
BUSY:
The indirect access status bit (BUSY) reports the progress of an indirect
access. BUSY is set high when this register is written to trigger an indirect
access, and will stay high until the access is complete. At which point, BUSY
will be set low. This register should be polled to determine when data from an
indirect read operation is available in the RCAS Indirect Channel Data
register or to determine when a new indirect write operation may commence.
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Register 0x104 : RCAS Indirect Channel Data
Bit
Type
Function
Default
Bit 31
to
Bit 16
Unused
XXXXH
Bit 15
Unused
X
Bit 14
Unused
X
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
R/W
CDLBEN
0
Bit 8
R/W
PROV
0
Unused
X
Bit 7
Bit 6
R/W
CHAN[6]
0
Bit 5
R/W
CHAN[5]
0
Bit 4
R/W
CHAN[4]
0
Bit 3
R/W
CHAN[3]
0
Bit 2
R/W
CHAN[2]
0
Bit 1
R/W
CHAN[1]
0
Bit 0
R/W
CHAN[0]
0
This register contains the data read from the channel provision RAM after an
indirect read operation or the data to be inserted into the channel provision RAM
in an indirect write operation.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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CHAN[6:0]:
The indirect data bits (CHAN[6:0]) report the channel number read from the
channel provision RAM after an indirect read operation has completed.
Channel number to be written to the channel provision RAM in an indirect
write operation must be set up in this register before triggering the write.
CHAN[6:0] reflects the value written until the completion of a subsequent
indirect read operation.
PROV:
The indirect provision enable bit (PROV) reports the channel provision enable
flag read from the channel provision RAM after an indirect read operation has
completed. The provision enable flag to be written to the channel provision
RAM, in an indirect write operation, must be set up in this register before
triggering the write. When PROV is set high, the current receive data byte is
processed as part of the channel as indicated by CHAN[6:0]. When PROV is
set low, the current time-slot does not belong to any channel and the receive
data byte ignored. PROV reflects the value written until the completion of a
subsequent indirect read operation.
CDLBEN:
The indirect channel based diagnostic loopback enable bit (CDLBEN) reports
the loopback enable flag read from channel provision RAM after an indirect
read operation has complete. The loopback enable flag to be written to the
channel provision RAM, in an indirect write operation, must be set up in this
register before triggering the write. When CDLBEN is set high, the current
receive data byte is to be over-written by data retrieved from the loopback
FIFO of the channel as indicated by CHAN[6:0]. When CDLBEN is set low,
the current receive data byte is processed normally. CDLBEN reflects the
value written until the completion of a subsequent indirect read operation.
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Register 0x108 : RCAS Framing Bit Threshold
Bit
Type
Function
Default
Bit 31
to
Bit 16
Unused
XXXXH
Bit 15
Unused
X
Bit 14
Unused
X
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
Bit 8
Unused
X
Bit 7
Unused
X
Bit 6
R/W
FTHRES[6]
0
Bit 5
R/W
FTHRES[5]
1
Bit 4
R/W
FTHRES[4]
1
Bit 3
R/W
FTHRES[3]
1
Bit 2
R/W
FTHRES[2]
1
Bit 1
R/W
FTHRES[1]
1
Bit 0
R/W
FTHRES[0]
1
This register contains the threshold used by the clock activity monitor to detect
for framing bits/bytes.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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FTHRES[6:0]:
The framing bit threshold bits (FTHRES[6:0]) contains the threshold used by
the clock activity monitor to detect for the presence of framing bits. A counter
in the clock activity monitor of each receive link increments at each SYSCLK
and is cleared, when the BSYNC bit of that link is set low, by each rising edge
of the corresponding RCLK[n]. When the BSYNC bit of that link is set high,
the counter is cleared at every fourth rising edge of the corresponding
RCLK[n]. When the counter exceeds the threshold given by FTHRES[6:0], a
framing bit/byte has been detected. FTHRES[6:0] should be set as a function
of the SYSCLK period and the expected gapping width of RCLK[n] during
data bits and during framing bits/bytes. Legal range of FTHRESH[6:0] is
'b0000001 to 'b1111110.
Note: For operation with T1 links and SYSCLK = 33 MHz, FTHRESH[6:0]
should be set to ‘b0011111’. The default value of this register is inconsistent
with that of the TCAS Framing Bit Threshold register 0x408.
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Register 0x10C : RCAS Channel Disable
Bit
Type
Function
Default
Unused
XXXXH
CHDIS
0
Bit 14
Unused
X
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
Bit 8
Unused
X
Bit 7
Unused
X
Bit 31
to
Bit 16
Bit 15
R/W
Bit 6
R/W
DCHAN[6]
0
Bit 5
R/W
DCHAN[5]
0
Bit 4
R/W
DCHAN[4]
0
Bit 3
R/W
DCHAN[3]
0
Bit 2
R/W
DCHAN[2]
0
Bit 1
R/W
DCHAN[1]
0
Bit 0
R/W
DCHAN[0]
0
This register controls the disabling of one specific channel to allow orderly
provisioning of timeslots associated with that channel.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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DCHAN[6:0]:
The disable channel number bits (DCHAN[6:0]) selects the channel to be
disabled. When CHDIS is set high, the channel specified by DCHAN[6:0] is
disabled. Data in timeslots associated with the specified channel is ignored.
When CHDIS is set low, the channel specified by DCHAN[6:0] operates
normally.
CHDIS:
The channel disable bit (CHDIS) controls the disabling of the channels
specified by DCHAN[6:0]. When CHDIS is set high, the channel selected by
DCHAN[6:0] is disabled. Data in timeslots associated with the specified
channel is ignored. When CHDIS is set low, the channel specified by
DCHAN[6:0] operates normally.
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Register 0x180 : RCAS Link #0 Configuration
Bit
Type
Function
Default
Bit 31
to
Bit 16
Unused
XXXXH
Bit 15
Unused
X
Bit 14
Unused
X
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
Bit 8
Unused
X
Bit 7
Unused
X
Bit 6
Unused
X
Bit 5
Unused
X
Bit 4
Unused
X
Bit 3
Unused
X
Bit 2
R/W
BSYNC
0
Bit 1
R/W
E1
0
Bit 0
R/W
CEN
0
This register configures operational modes of receive link #0 (RD[0] / RCLK[0]).
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
CEN:
The channelise enable bit (CEN) configures receive link #0 for channelised
operation. RCLK[0] is held quiescent during the T1 framing bit and during the
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E1 framing bytes. The data bit on RD[0] clocked in by the first rising edge of
RCLK[0] after an extended quiescent period is considered to be the most
significant bit of time-slot 1. When CEN is set low, receive link #0 is
unchannelised. The E1 register bit is ignored. RCLK[0] is gapped during
non-data bytes. The choice between treating all data bits as a contiguous
stream with arbitrary byte alignment or byte aligned to gaps in RCLK[0] is
controlled by the BSYNC bit.
E1:
The E1 frame structure select bit (E1) configures receive link #0 for
channelised E1 operation when CEN is set high. RCLK[0] is held quiescent
during the FAS and NFAS framing bytes. The data bit on RD[0] associated
with the first rising edge of RCLK[0] after an extended quiescent period is
considered to be the most significant bit of time-slot 1. Link data is present at
time-slots 1 to 31. When E1 is set low and CEN is set high, receive link #0 is
configured for channelised T1 operation. RCLK[0] is held quiescent during
the framing bit. The data bit on RD[0] associated with the first rising edge of
RCLK[0] after an extended quiescent period is considered to be the most
significant bit of time-slot 1. Link data is present at time-slots 1 to 24. E1 is
ignored when CEN is set low.
BSYNC:
The byte synchronisation enable bit (BSYNC) controls the interpretation of
gaps in RCLK[0] when link #0 is in unchannelised mode (CEN set low).
When BSYNC is set high, the data bit on RD[0] clocked in by the first rising
edge of RCLK[0] after an extended quiescent period is considered to be the
most significant bit of a data byte. When BSYNC is set low, gaps in RCLK[0]
carry no special significance. BSYNC is ignore when CEN is set high.
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Register 0x184 - 0x188 : RCAS Link #1 to #2 Configuration
Bit
Type
Function
Default
Bit 31
to
Bit 16
Unused
XXXXH
Bit 15
Unused
X
Bit 14
Unused
X
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
Bit 8
Unused
X
Bit 7
Unused
X
Bit 6
Unused
X
Bit 5
Unused
X
Bit 4
Unused
X
Bit 3
Unused
X
Bit 2
R/W
BSYNC
0
Bit 1
R/W
E1
0
Bit 0
R/W
CEN
0
This register set configures operational modes of receive link #1 to link #2
(RD[n] / RCLK[n]; where 1 £ n £ 2).
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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CEN:
The channelise enable bit (CEN) configures the corresponding receive link for
channelised operation. RCLK[n] is held quiescent during the T1 framing bit
and during the E1 framing bytes. The data bit on RD[n] clocked in by the first
rising edge of RCLK[n] after an extended quiescent period is considered to
be the most significant bit of time-slot 1. When CEN is set low, receive link
#n is unchannelised. The E1 register bit is ignored. RCLK[n] is gapped
during non-data bytes. The choice between treating all data bits as a
contiguous stream with arbitrary byte alignment or byte aligned to gaps in
RCLK[n] is controlled by the BSYNC bit.
E1:
The E1 frame structure select bit (E1) configures the corresponding receive
link for channelised E1 operation when CEN is set high. RCLK[n] is held
quiescent during the FAS and NFAS framing bytes. The data bit on RD[n]
associated with the first rising edge of RCLK[n] after an extended quiescent
period is considered to be the most significant bit of time-slot 1. Link data is
present at time-slots 1 to 31. When E1 is set low and CEN is set high, the
corresponding receive link is configured for channelised T1 operation.
RCLK[n] is held quiescent during the framing bit. The data bit on RD[n]
associated with the first rising edge of RCLK[n] after an extended quiescent
period is considered to be the most significant bit of time-slot 1. Link data is
present at time-slots 1 to 24. E1 is ignored when CEN is set low.
BSYNC:
The byte synchronisation enable bit (BSYNC) controls the interpretation of
gaps in RCLK[n] when the corresponding link is in unchannelised mode (CEN
set low). When BSYNC is set high, the data bit on RD[n] clocked in by the
first rising edge of RCLK[n] after an extended quiescent period is considered
to be the most significant bit of a data byte. When BSYNC is set low, gaps in
RCLK[n] carry no special significance. BSYNC is ignore when CEN is set
high.
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Register 0x18C : RCAS Link #3 Configuration
Bit
Type
Function
Default
Bit 31
to
Bit 16
Unused
XXXXH
Bit 15
Unused
X
Bit 14
Unused
X
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
Bit 8
Unused
X
Bit 7
Unused
X
Bit 6
Unused
X
Bit 5
Unused
X
Bit 4
Unused
X
Bit 3
Unused
X
Bit 2
Unused
X
Bit 1
R/W
E1
0
Bit 0
R/W
CEN
0
This register set configures operational modes of receive link #3
(RD[3] / RCLK[3]).
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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CEN:
The channelise enable bit (CEN) configures receive link #3 for channelised
operation. RCLK[3] is held quiescent during the T1 framing bit and the E1
framing bytes. The data bit on RD[3] clocked in by the first rising edge of
RCLK[3] after an extended quiescent period is considered to be the most
significant bit of time-slot 1. When CEN is set low, the corresponding receive
link is unchannelised. The E1 register bit is ignored. RCLK[3] is gapped
during non-data bytes. All data bits are treated as a contiguous stream with
arbitrary byte alignment.
E1:
The E1 frame structure select bit (E1) configures receive link #3 for
channelised E1 operation when CEN is set high. RCLK[3] is held quiescent
during the FAS and NFAS framing bytes. The data bit on RD[3] clocked in by
the first rising edge of RCLK[3] after an extended quiescent period is
considered to be the most significant bit of time-slot 1. Link data is present at
time-slots 1 to 31. When E1 is set low and CEN is set high, receive link #3 is
configured for channelised T1 operation. RCLK[3] is held quiescent during
the framing bit. The data bit on RD[3] clocked in by the first rising edge of
RCLK[3] after an extended quiescent period is considered to be the most
significant bit of time-slot 1. Link data is present at time-slots 1 to 24. E1 is
ignored when CEN is set low.
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Register 0x190-0x1FC : RCAS Link #4 to Link #31 Configuration
Bit
Type
Function
Default
Bit 31
to
Bit 16
Unused
XXXXH
Bit 15
Unused
X
Bit 14
Unused
X
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
Bit 8
Unused
X
Bit 7
Unused
X
Bit 6
Unused
X
Bit 5
Unused
X
Bit 4
Unused
X
Bit 3
Unused
X
Bit 2
Unused
X
Bit 1
R/W
E1
0
Bit 0
R/W
CEN
0
This register set configures operational modes of receive link #4 to link # 31
(RD[n] / RCLK[n]; where 4 £ n £ 31 ).
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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CEN:
The channelise enable bit (CEN) configures the corresponding receive link for
channelised operation. RCLK[n] is held quiescent during the T1 framing bit
and the E1 framing bytes. The data bit on RD[n] clocked in by the first rising
edge of RCLK[n] after an extended quiescent period is considered to be the
most significant bit of time-slot 1. When CEN is set low, the corresponding
receive link is unchannelised. The E1 register bit is ignored. RCLK[n] is
gapped during non-data bytes. All data bits are treated as a contiguous
stream with arbitrary byte alignment.
E1:
The E1 frame structure select bit (E1) configures the corresponding receive
link for channelised E1 operation when CEN is set high. RCLK[n] is held
quiescent during the FAS and NFAS framing bytes. The data bit on RD[n]
clocked in by the first rising edge of RCLK[n] after an extended quiescent
period is considered to be the most significant bit of time-slot 1. Link data is
present at time-slots 1 to 31. When E1 is set low and CEN is set high, the
corresponding receive link is configured for channelised T1 operation.
RCLK[n] is held quiescent during the framing bit. The data bit on RD[n]
clocked in by the first rising edge of RCLK[n] after an extended quiescent
period is considered to be the most significant bit of time-slot 1. Link data is
present at time-slots 1 to 24. E1 is ignored when CEN is set low.
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Register 0x200 : RHDL Indirect Channel Select
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R
BUSY
X
Bit 14
R/W
CRWB
0
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
Bit 8
Unused
X
Bit 7
Unused
X
Bit 6
R/W
CHAN[6]
0
Bit 5
R/W
CHAN[5]
0
Bit 4
R/W
CHAN[4]
0
Bit 3
R/W
CHAN[3]
0
Bit 2
R/W
CHAN[2]
0
Bit 1
R/W
CHAN[1]
0
Bit 0
R/W
CHAN[0]
0
This register provides the channel number used to access the receive channel
provision RAM. Writing to this register triggers an indirect channel register
access.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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CHAN[6:0]:
The indirect channel number bits (CHAN[6:0]) indicate the receive channel to
be configured or interrogated in the indirect access.
CRWB:
The channel indirect access control bit (CRWB) selects between a configure
(write) or interrogate (read) access to the receive channel provision RAM.
Writing a logic zero to CRWB triggers an indirect write operation. Data to be
written is taken from the Indirect Channel Data registers. Writing a logic one
to CRWB triggers an indirect read operation. The data read can be found in
the Indirect Channel Data registers.
BUSY:
The indirect access status bit (BUSY) reports the progress of an indirect
access. BUSY is set high when this register is written to trigger an indirect
access, and will stay high until the access is complete. At which point, BUSY
will be set low. This register should be polled to determine when data from an
indirect read operation is available in the RHDL Indirect Channel Data #1 and
#2 registers or to determine when a new indirect write operation may
commence.
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Register 0x204 : RHDL Indirect Channel Data Register #1
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
PROV
0
Bit 14
R/W
CRC[1]
0
Bit 13
R/W
CRC[0]
0
Bit 12
R/W
STRIP
0
Bit 11
R/W
DELIN
0
Bit 10
R
TAVAIL
X
Unused
X
Bit 9
Bit 8
W
FPTR[8]
X
Bit 7
W
FPTR[7]
X
Bit 6
W
FPTR[6]
X
Bit 5
W
FPTR[5]
X
Bit 4
W
FPTR[4]
X
Bit 3
W
FPTR[3]
X
Bit 2
W
FPTR[2]
X
Bit 1
W
FPTR[1]
X
Bit 0
W
FPTR[0]
X
This register contains data read from the channel provision RAM after an indirect
read operation or data to be inserted into the channel provision RAM in an
indirect write operation.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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FPTR[8:0]:
The indirect FIFO block pointer (FPTR[8:0]) identifies one of the blocks of the
circular linked list in the partial packet buffer used in the logical FIFO of the
current channel. The FIFO pointer to be written to the channel provision
RAM, in an indirect write operation, must be set up in this register before
triggering the write. The FIFO pointer value can be any one of the blocks
provisioned to form the circular buffer.
TAVAIL:
The indirect transaction available bit (TAVAIL) reports the fill level of the
partial packet buffer used in the logical FIFO of the current channel. TAVAIL
is set high when the FIFO of the current channel contains sufficient data, as
controlled by XFER[2:0], to request a DMA transfer to the host memory.
TAVAIL is set low when the amount of receive data is too small to require a
transfer to host memory. TAVAIL is update by an indirect channel read
operation.
DELIN:
The indirect delineate enable bit (DELIN) configures the HDLC processor to
perform flag sequence delineation and bit de-stuffing on the incoming data
stream. The delineate enable bit to be written to the channel provision RAM,
in an indirect channel write operation, must be set up in this register before
triggering the write. When DELIN is set high, flag sequence delineation and
bit de-stuffing is performed on the incoming data stream. When DELIN is set
low, the HDLC processor does not perform any processing (flag sequence
delineation, bit de-stuffing nor CRC verification) on the incoming stream.
DELIN reflects the value written until the completion of a subsequent indirect
channel read operation.
STRIP:
The indirect frame check sequence discard bit (STRIP) configures the HDLC
processor to remove the CRC from the incoming frame when writing the data
to the channel FIFO. The FCS discard bit to be written to the channel
provision RAM, in an indirect channel write operation, must be set up in this
register before triggering the write. When STRIP is set high and CRC[1:0] is
not equal to "00", the received CRC value is not written to the FIFO. When
STRIP is set low, the received CRC value is written to the FIFO. The bytes in
buffer field of the RPD correctly reflect the presence/absence of CRC bytes in
the buffer. The value of STRIP is ignored when DELIN is low. STRIP reflects
the value written until the completion of a subsequent indirect channel read
operation.
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CRC[1:0]:
The CRC algorithm bits (CRC[1:0]) configures the HDLC processor to
perform CRC verification on the incoming data stream. The value of
CRC[1:0] to be written to the channel provision RAM, in an indirect channel
write operation, must be set up in this register before triggering the write.
CRC[1:0] is ignored when DELIN is low. CRC[1:0] reflects the value written
until the completion of a subsequent indirect channel read operation.
Table 16 – CRC[1:0] Settings
CRC[1]
CRC[0]
Operation
0
0
No Verification
0
1
CRC-CCITT
1
0
CRC-32
1
1
Reserved
PROV:
The indirect provision enable bit (PROV) reports the channel provision enable
flag read from the channel provision RAM after an indirect channel read
operation has completed. The provision enable flag to be written to the
channel provision RAM, in an indirect write operation, must be set up in this
register before triggering the write. When PROV is set high, the HDLC
processor will process data on the channel specified by CHAN[6:0]. When
PROV is set low, the HDLC processor will ignore data on the channel
specified by CHAN[6:0]. PROV reflects the value written until the completion
of a subsequent indirect channel read operation.
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Register 0x208 : RHDL Indirect Channel Data Register #2
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
7BIT
0
Bit 14
R/W
PRIORITY
0
Bit 13
R/W
INVERT
0
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
R/W
OFFSET[1]
0
Bit 8
R/W
OFFSET[0]
0
Bit 7
Unused
X
Bit 6
Unused
X
Bit 5
Unused
X
Bit 4
Unused[
X
Bit 3
Unused
X
Bit 2
R/W
XFER[2]
X
Bit 1
R/W
XFER[1]
0
Bit 0
R/W
XFER[0]
0
This register contains data read from the channel provision RAM after an indirect
read operation or data to be inserted into the channel provision RAM in an
indirect write operation.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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XFER[2:0]:
The indirect channel transfer size (XFER[2:0]) configures the amount of data
transferred in each transaction. The channel transfer size to be written to the
channel provision RAM, in an indirect write operation, must be set up in this
register before triggering the write. When the channel FIFO depth reaches
the depth specified by XFER[2:0] or when an end-of-packet exists in the
FIFO, a request will be made to the RMAC to initiate a PCI write access to
transfer the data to the PCI host. Channel transfer size is measured in 16
byte blocks. The amount of data transferred and the depth threshold are
specified by given setting is:
XFER[2:0] + 1 blocks = 16 * (XFER[2:0] + 1) bytes
XFER[2:0] should be set such that the number of blocks transferred is at
least two fewer than the total allocated to the associated channel. XFER[2:0]
reflects the value written until the completion of a subsequent indirect channel
read operation.
OFFSET[1:0]:
The packet byte offset (OFFSET[1:0]) configures the partial packet processor
to insert invalid bytes at the beginning of a packet stored in the channel FIFO.
The value of OFFSET[1:0] to be written to the channel provision RAM, in an
indirect channel write operation, must be set up in this register before
triggering the write. The number of bytes inserted before the beginning of a
HDLC packet is defined by the binary value of OFFSET[1:0]. OFFSET[1:0]
reflects the value written until the completion of a subsequent indirect channel
read operation.
INVERT:
The HDLC data inversion bit (INVERT) configures the HDLC processor to
logically invert the incoming HDLC stream from the RCAS before processing
it. The value of INVERT to be written to the channel provision RAM, in an
indirect channel write operation, must be set up in this register before
triggering the write. When INVERT is set to one, the HDLC stream is logically
inverted before processing. When INVERT is set to zero, the HDLC stream
is not inverted before processing. INVERT reflects the value written until the
completion of a subsequent indirect channel read operation.
PRIORITY:
The channel FIFO priority bit (PRIORITY) informs the partial packet
processor that the channel has precedence over other channels when being
serviced by the RMAC block for transfer to the PCI host. The value of
PRIORITY to be written to the channel provision RAM, in an indirect channel
write operation, must be set up in this register before triggering the write.
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Channel FIFOs with PRIORITY set to one are serviced by the RMAC before
channel FIFOs with PRIORITY set to zero. Channels with an HDLC data rate
to FIFO size ratio that is significantly higher than other channels should have
PRIORITY set to one. PRIORITY reflects the value written until the
completion of a subsequent indirect channel read operation.
7BIT:
The 7BIT enable bit (7BIT) configures the HDLC processor to ignore the least
significant bit of each octet in the corresponding link RD[n]. The value of
7BIT to be written to the channel provision RAM, in an indirect channel write
operation, must be set up in this register before triggering the write. When
7BIT is set high, the least significant bit (last bit of each octet received), is
ignored. When 7BIT is set low, the entire receive data stream is processed.
7BIT reflects the value written until the completion of a subsequent indirect
channel read operation.
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Register 0x210 : RHDL Indirect Block Select
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R
BUSY
X
Bit 14
R/W
BRWB
X
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
Bit 8
R/W
BLOCK[8]
X
Bit 7
R/W
BLOCK[7]
X
Bit 6
R/W
BLOCK[6]
X
Bit 5
R/W
BLOCK[5]
X
Bit 4
R/W
BLOCK[4]
X
Bit 3
R/W
BLOCK[3]
X
Bit 2
R/W
BLOCK[2]
X
Bit 1
R/W
BLOCK[1]
X
Bit 0
R/W
BLOCK[0]
X
This register provides the block number used to access the block pointer RAM.
Writing to this register triggers an indirect block register access.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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BLOCK[8:0]:
The indirect block number (BLOCK[8:0]) indicate the block to be configured
or interrogated in the indirect access.
BRWB:
The block indirect access control bit (BRWB) selects between a configure
(write) or interrogate (read) access to the block pointer RAM. Writing a logic
zero to BRWB triggers an indirect block write operation. Data to be written is
taken from the Indirect Block Data register. Writing a logic one to BRWB
triggers an indirect block read operation. The data read can be found in the
Indirect Block Data register.
BUSY:
The indirect access status bit (BUSY) reports the progress of an indirect
access. BUSY is set high when this register is written to trigger an indirect
access, and will stay high until the access is complete. At which point, BUSY
will be set low. This register should be polled to determine when data from an
indirect read operation is available in the RHDL Indirect Block Data register or
to determine when a new indirect write operation may commence.
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Register 0x214 : RHDL Indirect Block Data
Bit
Type
Function
Default
Bit 31
to
Bit 16
Unused
XXXXH
Bit 15
Unused
X
Bit 14
Unused
X
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
Bit 8
R/W
BPTR[8]
0
Bit 7
R/W
BPTR[7]
0
Bit 6
R/W
BPTR[6]
0
Bit 5
R/W
BPTR[5]
0
Bit 4
R/W
BPTR[4]
0
Bit 3
R/W
BPTR[3]
0
Bit 2
R/W
BPTR[2]
0
Bit 1
R/W
BPTR[1]
0
Bit 0
R/W
BPTR[0]
0
This register contains data read from the block pointer RAM after an indirect
block read operation or data to be inserted into the block pointer RAM in an
indirect block write operation.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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BPTR[8:0]:
The indirect block pointer (BPTR[8:0]) configures the block pointer of the
block specified by the Indirect Block Select register. The block pointer to be
written to the block pointer RAM, in an indirect write operation, must be set up
in this register before triggering the write. The block pointer value is the block
number of the next block in the linked list. A circular list of blocks must be
formed in order to use the block list as a receive channel FIFO buffer.
BPTR[8:0] reflects the value written until the completion of a subsequent
indirect block read operation.
When provisioning a channel FIFO, all blocks pointers must be re-written to
properly initialize the FIFO.
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Register 0x220 : RHDL Configuration
Bit
Type
Function
Default
Bit 31
to
Bit 16
Unused
XXXXH
Bit 15
Unused
X
Bit 14
Unused
X
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
R/W
LENCHK
0
Bit 8
R/W
TSTD
0
Bit 7
Unused
X
Bit 6
Unused
X
Bit 5
Unused
X
Bit 4
Unused
X
Bit 3
Unused
X
Bit 2
R/W
Reserved[2]
1
Bit 1
R/W
Reserved[1]
1
Bit 0
R/W
Reserved[0]
1
This register configures all provisioned receive channels.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
Reserved[2:0]:
The reserved bits (Reserved[2:0]) must be set to all ones for correct
operation of the FREEDM-32 device.
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TSTD:
The telecom standard bit (TSTD) controls the bit ordering of the HDLC data
transferred to the PCI host. When TSTD is set low, the least significant bit of
the each byte on the PCI bus (AD[0], AD[8], AD[16] and AD[24]) is the first
HDLC bit received and the most significant bit of each byte (AD[7], AD[15],
AD[23] and AD[31]) is the last HDLC bit received (datacom standard). When
TSTD is set high, AD[0], AD[8], AD[16] and AD[24] are the last HDLC bit
received and AD[7], AD[15], AD[23] and AD[31] are the first HDLC bit
received (telecom standard).
LENCHK:
The packet length error check bit (LENCHK) controls the checking of receive
packets that are longer than the maximum programmed length. When
LENCHK is set high, receive packets are aborted and the remainder of the
frame discarded when the packet exceeds the maximum packet length given
by MAX[15:0]. When LENCHK is set low, receive packets are not checked
for maximum size and MAX[15:0] must be set to 'hFFFF.
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Register 0x224 : RHDL Maximum Packet Length
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
MAX[15]
1
Bit 14
R/W
MAX[14]
1
Bit 13
R/W
MAX[13]
1
Bit 12
R/W
MAX[12]
1
Bit 11
R/W
MAX[11]
1
Bit 10
R/W
MAX[10]
1
Bit 9
R/W
MAX[9]
1
Bit 8
R/W
MAX[8]
1
Bit 7
R/W
MAX[7]
1
Bit 6
R/W
MAX[6]
1
Bit 5
R/W
MAX[5]
1
Bit 4
R/W
MAX[4]
1
Bit 3
R/W
MAX[3]
1
Bit 2
R/W
MAX[2]
1
Bit 1
R/W
MAX[1]
1
Bit 0
R/W
MAX[0]
1
This register configures the maximum legal HDLC packet byte length.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
MAX[15:0]:
The maximum HDLC packet length (MAX[15:0]) configures the FREEDM-32
to reject HDLC packets longer than a maximum size when LENCHK is set
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high. Receive packets with total length, including address, control,
information and FCS fields, greater than MAX[15:0] bytes are aborted. When
LENCHK is set low, aborts are not generated regardless of packet length and
MAX[15:0] must be set to 'hFFFF.
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Register 0x280 : RMAC Control
Bit
Type
Function
Default
Bit 31
to
Bit 16
Unused
XXXXH
Bit 15
Unused
X
Bit 14
Unused
X
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
R/W
RPQ_SFN[1]
0
Bit 10
R/W
RPQ_SFN[0]
0
Bit 9
R/W
RPQ_LFN[1]
0
Bit 8
R/W
RPQ_LFN[0]
0
Bit 7
R/W
RPQ_RDYN[2]
0
Bit 6
R/W
RPQ_RDYN[1]
0
Bit 5
R/W
RPQ_RDYN[0]
0
Bit 4
R/W
RAWMAX[1]
1
Bit 3
R/W
RAWMAX[0]
1
Bit 2
R/W
SCACHE
1
Bit 1
R/W
LCACHE
1
Bit 0
R/W
ENABLE
0
This register configures the RMAC block.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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ENABLE:
The ENABLE bit determines whether or not the RMAC accepts data from the
RHDL block and sends it to host memory. When set to 1, these tasks are
enabled. When set to 0, they are disabled.
LCACHE:
The large buffer cache enable bit (LCACHE) enables caching of Large Buffer
RPDRs. When LCACHE is set high, RPDRs are fetched from the RPDR
Large Buffer Free Queue in groups of up to six. When LCACHE is set low,
RPDRs are fetched one at a time.
SCACHE:
The small buffer cache enable bit (SCACHE) enables caching of Small Buffer
RPDRs. When SCACHE is set high, RPDRs are fetched from the RPDR
Small Buffer Free Queue in groups of up to six. When SCACHE is set low,
RPDRs are fetched one at a time.
RAWMAX[1:0]:
The RAWMAX[1:0] field determines how ‘raw’ (i.e. non packet delimited) data
is written to host memory. Raw data is written to buffers in host memory in
the same manner as packet delimited data. Whenever RAWMAX[1:0] + 1
buffers have been filled, the resulting buffer chain is placed in the ready
queue.
RPQ_RDYN[2:0]:
The RPQ_RDYN[2:0] field sets the number of receive packet descriptor
references (RPDRs) that must be placed onto the RPDR ready queue before
the RPDR ready interrupt (RPQRDYI) is asserted, as follows:
Table 17 – RPQ_RDYN[2:0] settings
RPQ_RDYN[2:0]
No of RPDRs
000
1
001
4
010
6
011
8
100
16
101
32
110
Reserved
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RPQ_RDYN[2:0]
No of RPDRs
111
Reserved
RPQ_LFN[1:0]:
The RPQ_LFN[1:0] field sets the number of times that a block of RPDRs are
read from the Large Buffer Free Queue to the RMACs internal cache before
the RPDR Large Buffer Free Queue interrupt (RPQLFI) is asserted, as
follows:
Table 18 – RPQ_LFN[1:0] Settings
RPQ_LFN[1:0]
No of Reads
00
1
01
4
10
8
11
Reserved
RPQ_SFN[1:0]:
The RPQ_SFN[1:0] field sets the number of times that a block of RPDRs are
read from the Small Buffer Free Queue to the RMACs internal cache before
the RPDR Small Buffer Free Queue interrupt (RPQSFI) is asserted, as
follows:
Table 19 – RPQ_SFN[1:0] Settings
RPQ_SFN[1:0]
No of Reads
00
1
01
4
10
8
11
Reserved
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Register 0x284 : RMAC Indirect Channel Provisioning
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R
BUSY
X
Bit 14
R/W
RWB
0
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
Bit 8
Unused
X
Bit 7
R/W
PROV
1
Bit 6
R/W
CHAN[6]
0
Bit 5
R/W
CHAN[5]
0
Bit 4
R/W
CHAN[4]
0
Bit 3
R/W
CHAN[3]
0
Bit 2
R/W
CHAN[2]
0
Bit 1
R/W
CHAN[1]
0
Bit 0
R/W
CHAN[0]
0
The Channel Provisioning Register is used to temporarily unprovision channels,
and also to query the provision status of channels. Channel is permanently
provisioned and can only be unprovisioned transiently. When a channel is
unprovisioned, a partially received packet, if any, will be flushed and marked as
unprovisioned in the RPDRR queue status field. The channel then returns to
being provisioned automatically.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
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implemented. However, when all four byte enables are negated, no access is
made to this register.
CHAN[6:0]:
The indirect data bits (CHAN[6:0]) report the channel number read from the
RMAC internal memory after an indirect read operation has completed.
Channel number to be written to the RMAC internal memory in an indirect
write operation must be set up in this register before triggering the write.
CHAN[6:0] reflects the value written until the completion of a subsequent
indirect read operation.
PROV:
The indirect provision enable bit (PROV) reports the channel provision enable
flag read from the RMAC internal memory after an indirect read operation has
completed. The provision enable flag to be written to the RMAC internal
memory, in an indirect write operation, must be set up in this register before
triggering the write. When PROV is set high, the channel as indicated by
CHAN[6:0] is provisioned. When PROV is set low, the channel indicated by
CHAN[6:0] is unprovisioned temporarily. Any partially received packets are
flushed and the status in the RPDRR queue is marked unprovisioned. The
channel then returns to being provisioned and PROV will report a logic high at
the next indirect read operation. PROV reflects the value written until the
completion of a subsequent indirect read operation.
RWB:
The Read/Write Bar (RWB) bit selects between a provisioning/unprovisioning
operation (write) or a query operation (read). Writing a logic 0 to RWB
triggers the provisioning or unprovisioning of a channel as specified by
CHAN[6:0] and PROV. Writing a logic 1 to RWB triggers a query of the
channel specified by CHAN[6:0].
BUSY:
The indirect access status bit (BUSY) reports the progress of an indirect
access. BUSY is set high when this register is written to trigger an indirect
access, and will stay high until the access is complete. At which point, BUSY
will be set low. This register should be polled to determine when data from an
indirect read operation is available or to determine when a new indirect write
operation may commence.
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Register 0x288 : RMAC Packet Descriptor Table Base LSW
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
RPDTB[15]
0
Bit 14
R/W
RPDTB[14]
0
Bit 13
R/W
RPDTB[13]
0
Bit 12
R/W
RPDTB[12]
0
Bit 11
R/W
RPDTB[11]
0
Bit 10
R/W
RPDTB[10]
0
Bit 9
R/W
RPDTB[9]
0
Bit 8
R/W
RPDTB[8]
0
Bit 7
R/W
RPDTB[7]
0
Bit 6
R/W
RPDTB[6]
0
Bit 5
R/W
RPDTB[5]
0
Bit 4
R/W
RPDTB[4]
0
Bit 3
R/W
RPDTB[3]
0
Bit 2
R/W
RPDTB[2]
0
Bit 1
R/W
RPDTB[1]
0
Bit 0
R/W
RPDTB[0]
0
This register provides the less significant word of the Receive Descriptor Table
Base address. The contents of this register is held in a holding register until a
write access to the companion RMAC Receive Descriptor Table Base MSW
register.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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Register 0x28C : RMAC Packet Descriptor Table Base MSW
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
RPDTB[31]
0
Bit 14
R/W
RPDTB[30]
0
Bit 13
R/W
RPDTB[29]
0
Bit 12
R/W
RPDTB[28]
0
Bit 11
R/W
RPDTB[27]
0
Bit 10
R/W
RPDTB[26]
0
Bit 9
R/W
RPDTB[25]
0
Bit 8
R/W
RPDTB[24]
0
Bit 7
R/W
RPDTB[23]
0
Bit 6
R/W
RPDTB[22]
0
Bit 5
R/W
RPDTB[21]
0
Bit 4
R/W
RPDTB[20]
0
Bit 3
R/W
RPDTB[19]
0
Bit 2
R/W
RPDTB[18]
0
Bit 1
R/W
RPDTB[17]
0
Bit 0
R/W
RPDTB[16]
0
This register provides the more significant word of the Receive Descriptor Table
Base address. The contents of the companion RMAC Receive Descriptor Table
Base LSW register is held in a holding register until a write access to this
register, at which point, the base address of the receive packet descriptor table is
updated.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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RPDTB[31:0]:
The receive packet descriptor table base bits (RPDTB[31:0]) provides the
base address of the Receive Packet Descriptor Table in PCI host memory.
This register is initialised by the host. To calculate the physical address of a
RPD, the 14 bit RPD offset must be added to bits 31 to 4 of the Receive
Packet Descriptor Table Base (RPDTB[31:4]).
The table must be on a 16 byte boundary and thus the least significant four
bits must be written to logic zero.
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Register 0x290 : RMAC Queue Base LSW
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
RQB[15]
0
Bit 14
R/W
RQB[14]
0
Bit 13
R/W
RQB[13]
0
Bit 12
R/W
RQB[12]
0
Bit 11
R/W
RQB[11]
0
Bit 10
R/W
RQB[10]
0
Bit 9
R/W
RQB[9]
0
Bit 8
R/W
RQB[8]
0
Bit 7
R/W
RQB[7]
0
Bit 6
R/W
RQB[6]
0
Bit 5
R/W
RQB[5]
0
Bit 4
R/W
RQB[4]
0
Bit 3
R/W
RQB[3]
0
Bit 2
R/W
RQB[2]
0
Bit 1
R/W
RQB[1]
0
Bit 0
R/W
RQB[0]
0
This register provides the less significant word of the Receive Queue Base
address. The contents of this register is held in a holding register until a write
access to the companion RMAC Receive Queue Base MSW register.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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Register 0x294 : RMAC Queue Base MSW
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
RQB[31]
0
Bit 14
R/W
RQB[30]
0
Bit 13
R/W
RQB[29]
0
Bit 12
R/W
RQB[28]
0
Bit 11
R/W
RQB[27]
0
Bit 10
R/W
RQB[26]
0
Bit 9
R/W
RQB[25]
0
Bit 8
R/W
RQB[24]
0
Bit 7
R/W
RQB[23]
0
Bit 6
R/W
RQB[22]
0
Bit 5
R/W
RQB[21]
0
Bit 4
R/W
RQB[20]
0
Bit 3
R/W
RQB[19]
0
Bit 2
R/W
RQB[18]
0
Bit 1
R/W
RQB[17]
0
Bit 0
R/W
RQB[16]
0
This register provides the more significant word of the Receive Queue Base
address. The contents of the companion RMAC Receive Queue Base LSW
register is held in a holding register until a write access to this register, at which
point, the base address of the receive queue is updated.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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RQB[31:0]:
The receive queue base bits (RQB[31:0]) provides the base address of the
Large Buffer RPDR Free, Small Buffer RPDR Free and RPDR Ready queues
in PCI host memory. This register is initialised by the host. To calculate the
physical address of a particular receive queue element, the RQB bits are
added with the appropriate queue start, end, read or write index registers to
form the physical address.
The base address must be dword aligned and thus the least significant two
bits must be written to logic zero.
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Register 0x298 : RMAC Packet Descriptor Reference Large Buffer Free
Queue Start
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
RPDRLFQS[15]
0
Bit 14
R/W
RPDRLFQS[14]
0
Bit 13
R/W
RPDRLFQS[13]
0
Bit 12
R/W
RPDRLFQS[12]
0
Bit 11
R/W
RPDRLFQS[11]
0
Bit 10
R/W
RPDRLFQS[10]
0
Bit 9
R/W
RPDRLFQS[9]
0
Bit 8
R/W
RPDRLFQS[8]
0
Bit 7
R/W
RPDRLFQS[7]
0
Bit 6
R/W
RPDRLFQS[6]
0
Bit 5
R/W
RPDRLFQS[5]
0
Bit 4
R/W
RPDRLFQS[4]
0
Bit 3
R/W
RPDRLFQS[3]
0
Bit 2
R/W
RPDRLFQS[2]
0
Bit 1
R/W
RPDRLFQS[1]
0
Bit 0
R/W
RPDRLFQS[0]
0
This register provides the Packet Descriptor Reference Large Buffer Free Queue
start address.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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RPDRLFQS[15:0]:
The receive packet descriptor reference (RPDR) large buffer free queue start
bits (RPDRLFQS[15:0]) define bits 17 to 2 of the Receive Packet Descriptor
Reference Large Buffer Free Queue start address. This register is initialised
by the host. The physical start address of the RPDRLF queue is the sum of
RPDRLFQS[15:0] left shifted by 2 bits with the RQB[31:0] bits in the RMAC
Receive Queue Base register.
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Register 0x29C : RMAC Packet Descriptor Reference Large Buffer Free
Queue Write
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
RPDRLFQW[15]
0
Bit 14
R/W
RPDRLFQW[14]
0
Bit 13
R/W
RPDRLFQW[13]
0
Bit 12
R/W
RPDRLFQW[12]
0
Bit 11
R/W
RPDRLFQW[11]
0
Bit 10
R/W
RPDRLFQW[10]
0
Bit 9
R/W
RPDRLFQW[9]
0
Bit 8
R/W
RPDRLFQW[8]
0
Bit 7
R/W
RPDRLFQW[7]
0
Bit 6
R/W
RPDRLFQW[6]
0
Bit 5
R/W
RPDRLFQW[5]
0
Bit 4
R/W
RPDRLFQW[4]
0
Bit 3
R/W
RPDRLFQW[3]
0
Bit 2
R/W
RPDRLFQW[2]
0
Bit 1
R/W
RPDRLFQW[1]
0
Bit 0
R/W
RPDRLFQW[0]
0
This register provides the Packet Descriptor Reference Large Buffer Free Queue
write address.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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RPDRLFQW[15:0]:
The receive packet descriptor reference (RPDR) large buffer free queue write
bits (RPDRLFQW[15:0]) define bits 17 to 2 of the Receive Packet Descriptor
Reference Large Buffer Free Queue write pointer. This register is initialised
by the host. The physical write address in the RPDRLF queue is the sum of
RPDRLFQW[15:0] left shifted by 2 bits with the RQB[31:0] bits in the RMAC
Receive Queue Base register.
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Register 0x2A0 : RMAC Packet Descriptor Reference Large Buffer Free
Queue Read
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
RPDRLFQR[15]
0
Bit 14
R/W
RPDRLFQR[14]
0
Bit 13
R/W
RPDRLFQR[13]
0
Bit 12
R/W
RPDRLFQR[12]
0
Bit 11
R/W
RPDRLFQR[11]
0
Bit 10
R/W
RPDRLFQR[10]
0
Bit 9
R/W
RPDRLFQR[9]
0
Bit 8
R/W
RPDRLFQR[8]
0
Bit 7
R/W
RPDRLFQR[7]
0
Bit 6
R/W
RPDRLFQR[6]
0
Bit 5
R/W
RPDRLFQR[5]
0
Bit 4
R/W
RPDRLFQR[4]
0
Bit 3
R/W
RPDRLFQR[3]
0
Bit 2
R/W
RPDRLFQR[2]
0
Bit 1
R/W
RPDRLFQR[1]
0
Bit 0
R/W
RPDRLFQR[0]
0
This register provides the Packet Descriptor Reference Large Buffer Free Queue
read address.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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RPDRLFQR[15:0]:
The receive packet descriptor reference (RPDR) large buffer free queue read
bits (RPDRLFQR[15:0]) define bits 17 to 2 of the Receive Packet Descriptor
Reference Large Buffer Free Queue read pointer. This register is initialised
by the host. The physical read address in the RPDRLF queue is the sum of
RPDRLFQR[15:0] left shifted by 2 bits with the RQB[31:0] bits in the RMAC
Receive Queue Base register.
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Register 0x2A4 : RMAC Packet Descriptor Reference Large Buffer Free
Queue End
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
RPDRLFQE[15]
0
Bit 14
R/W
RPDRLFQE[14]
0
Bit 13
R/W
RPDRLFQE[13]
0
Bit 12
R/W
RPDRLFQE[12]
0
Bit 11
R/W
RPDRLFQE[11]
0
Bit 10
R/W
RPDRLFQE[10]
0
Bit 9
R/W
RPDRLFQE[9]
0
Bit 8
R/W
RPDRLFQE[8]
0
Bit 7
R/W
RPDRLFQE[7]
0
Bit 6
R/W
RPDRLFQE[6]
0
Bit 5
R/W
RPDRLFQE[5]
0
Bit 4
R/W
RPDRLFQE[4]
0
Bit 3
R/W
RPDRLFQE[3]
0
Bit 2
R/W
RPDRLFQE[2]
0
Bit 1
R/W
RPDRLFQE[1]
0
Bit 0
R/W
RPDRLFQE[0]
0
This register provides the Packet Descriptor Reference Large Buffer Free Queue
end address.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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RPDRLFQE[15:0]:
The receive packet descriptor reference (RPDR) large buffer free queue end
bits (RPDRLFQE[15:0]) define bits 17 to 2 of the Receive Packet Descriptor
Reference Large Buffer Free Queue end address. This register is initialised
by the host. The physical end address in the RPDRLF queue is the sum of
RPDRLFQE[15:0] left shifted by 2 bits with the RQB[31:0] bits in the RMAC
Receive Queue Base register.
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Register 0x2A8 : RMAC Packet Descriptor Reference Small Buffer Free
Queue Start
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
RPDRSFQS[15]
0
Bit 14
R/W
RPDRSFQS[14]
0
Bit 13
R/W
RPDRSFQS[13]
0
Bit 12
R/W
RPDRSFQS[12]
0
Bit 11
R/W
RPDRSFQS[11]
0
Bit 10
R/W
RPDRSFQS[10]
0
Bit 9
R/W
RPDRSFQS[9]
0
Bit 8
R/W
RPDRSFQS[8]
0
Bit 7
R/W
RPDRSFQS[7]
0
Bit 6
R/W
RPDRSFQS[6]
0
Bit 5
R/W
RPDRSFQS[5]
0
Bit 4
R/W
RPDRSFQS[4]
0
Bit 3
R/W
RPDRSFQS[3]
0
Bit 2
R/W
RPDRSFQS[2]
0
Bit 1
R/W
RPDRSFQS[1]
0
Bit 0
R/W
RPDRSFQS[0]
0
This register provides the Packet Descriptor Reference Small Buffer Free Queue
start address.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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RPDRSFQS[15:0]:
The receive packet descriptor reference (RPDR) small buffer free queue start
bits (RPDRSFQS[15:0]) define bits 17 to 2 of the Receive Packet Descriptor
Reference Small Buffer Free Queue start address. This register is initialised
by the host. The physical start address of the RPDRSF queue is the sum of
RPDRSFQS[15:0] left shifted by 2 bits with the RQB[31:0] bits in the RMAC
Receive Queue Base register.
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Register 0x2AC : RMAC Packet Descriptor Reference Small Buffer Free
Queue Write
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
RPDRSFQW[15]
0
Bit 14
R/W
RPDRSFQW[14]
0
Bit 13
R/W
RPDRSFQW[13]
0
Bit 12
R/W
RPDRSFQW[12]
0
Bit 11
R/W
RPDRSFQW[11]
0
Bit 10
R/W
RPDRSFQW[10]
0
Bit 9
R/W
RPDRSFQW[9]
0
Bit 8
R/W
RPDRSFQW[8]
0
Bit 7
R/W
RPDRSFQW[7]
0
Bit 6
R/W
RPDRSFQW[6]
0
Bit 5
R/W
RPDRSFQW[5]
0
Bit 4
R/W
RPDRSFQW[4]
0
Bit 3
R/W
RPDRSFQW[3]
0
Bit 2
R/W
RPDRSFQW[2]
0
Bit 1
R/W
RPDRSFQW[1]
0
Bit 0
R/W
RPDRSFQW[0]
0
This register provides the Packet Descriptor Reference Small Buffer Free Queue
write address.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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RPDRSFQW[15:0]:
The receive packet descriptor reference (RPDR) small buffer free queue write
bits (RPDRSFQW[15:0]) define bits 17 to 2 of the Receive Packet Descriptor
Reference Small Buffer Free Queue write pointer. This register is initialised
by the host. The physical write address in the RPDRSF queue is the sum of
RPDRSFQW[15:0] left shifted by 2 bits with the RQB[31:0] bits in the RMAC
Receive Queue Base register.
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Register 0x2B0 : RMAC Packet Descriptor Reference Small Buffer Free
Queue Read
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
RPDRSFQR[15]
0
Bit 14
R/W
RPDRSFQR[14]
0
Bit 13
R/W
RPDRSFQR[13]
0
Bit 12
R/W
RPDRSFQR[12]
0
Bit 11
R/W
RPDRSFQR[11]
0
Bit 10
R/W
RPDRSFQR[10]
0
Bit 9
R/W
RPDRSFQR[9]
0
Bit 8
R/W
RPDRSFQR[8]
0
Bit 7
R/W
RPDRSFQR[7]
0
Bit 6
R/W
RPDRSFQR[6]
0
Bit 5
R/W
RPDRSFQR[5]
0
Bit 4
R/W
RPDRSFQR[4]
0
Bit 3
R/W
RPDRSFQR[3]
0
Bit 2
R/W
RPDRSFQR[2]
0
Bit 1
R/W
RPDRSFQR[1]
0
Bit 0
R/W
RPDRSFQR[0]
0
This register provides the Packet Descriptor Reference Small Buffer Free Queue
read address.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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RPDRSFQR[15:0]:
The receive packet descriptor reference (RPDR) small buffer free queue read
bits (RPDRSFQR[15:0]) define bits 17 to 2 of the Receive Packet Descriptor
Reference Small Buffer Free Queue read pointer. This register is initialised
by the host. The physical read address in the RPDRSF queue is the sum of
RPDRSFQR[15:0] left shifted by 2 bits with the RQB[31:0] bits in the RMAC
Receive Queue Base register.
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Register 0x2B4 : RMAC Packet Descriptor Reference Small Buffer Free
Queue End
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
RPDRSFQE[15]
0
Bit 14
R/W
RPDRSFQE[14]
0
Bit 13
R/W
RPDRSFQE[13]
0
Bit 12
R/W
RPDRSFQE[12]
0
Bit 11
R/W
RPDRSFQE[11]
0
Bit 10
R/W
RPDRSFQE[10]
0
Bit 9
R/W
RPDRSFQE[9]
0
Bit 8
R/W
RPDRSFQE[8]
0
Bit 7
R/W
RPDRSFQE[7]
0
Bit 6
R/W
RPDRSFQE[6]
0
Bit 5
R/W
RPDRSFQE[5]
0
Bit 4
R/W
RPDRSFQE[4]
0
Bit 3
R/W
RPDRSFQE[3]
0
Bit 2
R/W
RPDRSFQE[2]
0
Bit 1
R/W
RPDRSFQE[1]
0
Bit 0
R/W
RPDRSFQE[0]
0
This register provides the Packet Descriptor Reference Small Buffer Free Queue
end address.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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RPDRSFQE[15:0]:
The receive packet descriptor reference (RPDR) small buffer free queue end
bits (RPDRSFQE[15:0]) define bits 17 to 2 of the Receive Packet Descriptor
Reference Small Buffer Free Queue end address. This register is initialised
by the host. The physical end address in the RPDRSF queue is the sum of
RPDRSFQE[15:0] left shifted by 2 bits with the RQB[31:0] bits in the RMAC
Receive Queue Base register.
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Register 0x2B8 : RMAC Packet Descriptor Reference Ready Queue Start
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
RPDRRQS[15]
0
Bit 14
R/W
RPDRRQS[14]
0
Bit 13
R/W
RPDRRQS[13]
0
Bit 12
R/W
RPDRRQS[12]
0
Bit 11
R/W
RPDRRQS[11]
0
Bit 10
R/W
RPDRRQS[10]
0
Bit 9
R/W
RPDRRQS[9]
0
Bit 8
R/W
RPDRRQS[8]
0
Bit 7
R/W
RPDRRQS[7]
0
Bit 6
R/W
RPDRRQS[6]
0
Bit 5
R/W
RPDRRQS[5]
0
Bit 4
R/W
RPDRRQS[4]
0
Bit 3
R/W
RPDRRQS[3]
0
Bit 2
R/W
RPDRRQS[2]
0
Bit 1
R/W
RPDRRQS[1]
0
Bit 0
R/W
RPDRRQS[0]
0
This register provides the Packet Descriptor Reference Ready Queue start
address.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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RPDRRQS[15:0]:
The receive packet descriptor reference (RPDR) ready queue start bits
(RPDRRQS[15:0]) define bits 17 to 2 of the Receive Packet Descriptor
Reference Ready Queue start address. This register is initialised by the
host. The physical start address of the RPDRR queue is the sum of
RPDRRQS[15:0] left shifted by 2 bits with the RQB[31:0] bits in the RMAC
Receive Queue Base register.
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Register 0x2BC : RMAC Packet Descriptor Reference Ready Queue Write
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
RPDRRQW[15]
0
Bit 14
R/W
RPDRRQW[14]
0
Bit 13
R/W
RPDRRQW[13]
0
Bit 12
R/W
RPDRRQW[12]
0
Bit 11
R/W
RPDRRQW[11]
0
Bit 10
R/W
RPDRRQW[10]
0
Bit 9
R/W
RPDRRQW[9]
0
Bit 8
R/W
RPDRRQW[8]
0
Bit 7
R/W
RPDRRQW[7]
0
Bit 6
R/W
RPDRRQW[6]
0
Bit 5
R/W
RPDRRQW[5]
0
Bit 4
R/W
RPDRRQW[4]
0
Bit 3
R/W
RPDRRQW[3]
0
Bit 2
R/W
RPDRRQW[2]
0
Bit 1
R/W
RPDRRQW[1]
0
Bit 0
R/W
RPDRRQW[0]
0
This register provides the Packet Descriptor Reference Ready Queue write
address.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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RPDRRQW[15:0]:
The receive packet descriptor reference (RPDR) ready queue write bits
(RPDRRQW[15:0]) define bits 17 to 2 of the Receive Packet Descriptor
Reference Ready Queue write pointer. This register is initialised by the host.
The physical write address in the RPDRR queue is the sum of
RPDRRQW[15:0] left shifted by 2 bits with the RQB[31:0] bits in the RMAC
Receive Queue Base register.
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Register 0x2C0 : RMAC Packet Descriptor Reference Ready Queue Read
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
RPDRRQR[15]
0
Bit 14
R/W
RPDRRQR[14]
0
Bit 13
R/W
RPDRRQR[13]
0
Bit 12
R/W
RPDRRQR[12]
0
Bit 11
R/W
RPDRRQR[11]
0
Bit 10
R/W
RPDRRQR[10]
0
Bit 9
R/W
RPDRRQR[9]
0
Bit 8
R/W
RPDRRQR[8]
0
Bit 7
R/W
RPDRRQR[7]
0
Bit 6
R/W
RPDRRQR[6]
0
Bit 5
R/W
RPDRRQR[5]
0
Bit 4
R/W
RPDRRQR[4]
0
Bit 3
R/W
RPDRRQR[3]
0
Bit 2
R/W
RPDRRQR[2]
0
Bit 1
R/W
RPDRRQR[1]
0
Bit 0
R/W
RPDRRQR[0]
0
This register provides the Packet Descriptor Reference Ready Queue read
address.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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RPDRRQR[15:0]:
The receive packet descriptor reference (RPDR) ready queue read bits
(RPDRRQR[15:0]) define bits 17 to 2 of the Receive Packet Descriptor
Reference Ready Queue read pointer. This register is initialised by the host.
The physical read address in the RPDRR queue is the sum of
RPDRRQR[15:0] left shifted by 2 bits with the RQB[31:0] bits in the RMAC
Receive Queue Base register.
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Register 0x2C4 : RMAC Packet Descriptor Reference Ready Queue End
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
RPDRRQE[15]
0
Bit 14
R/W
RPDRRQE[14]
0
Bit 13
R/W
RPDRRQE[13]
0
Bit 12
R/W
RPDRRQE[12]
0
Bit 11
R/W
RPDRRQE[11]
0
Bit 10
R/W
RPDRRQE[10]
0
Bit 9
R/W
RPDRRQE[9]
0
Bit 8
R/W
RPDRRQE[8]
0
Bit 7
R/W
RPDRRQE[7]
0
Bit 6
R/W
RPDRRQE[6]
0
Bit 5
R/W
RPDRRQE[5]
0
Bit 4
R/W
RPDRRQE[4]
0
Bit 3
R/W
RPDRRQE[3]
0
Bit 2
R/W
RPDRRQE[2]
0
Bit 1
R/W
RPDRRQE[1]
0
Bit 0
R/W
RPDRRQE[0]
0
This register provides the Packet Descriptor Reference Ready Queue end
address.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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RPDRRQE[15:0]:
The receive packet descriptor reference (RPDR) ready queue end bits
(RPDRRQE[15:0]) define bits 17 to 2 of the Receive Packet Descriptor
Reference Ready Queue end address. This register is initialised by the host.
The physical end address in the RPDRR queue is the sum of
RPDRRQE[15:0] left shifted by 2 bits with the RQB[31:0] bits in the RMAC
Receive Queue Base register.
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Register 0x300 : TMAC Control
Bit
Type
Function
Default
Bit 31
to
Bit 16
Unused
XXXXH
Bit 15
Unused
X
Bit 14
Unused
X
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
Bit 8
Unused
X
Bit 7
Unused
X
Bit 6
R/W
TDQ_FRN[1]
0
Bit 5
R/W
TDQ_FRN[0]
0
Bit 4
R/W
TDQ_RDYN[2]
0
Bit 3
R/W
TDQ_RDYN[1]
0
Bit 2
R/W
TDQ_RDYN[0]
0
Bit 1
R/W
CACHE
1
Bit 0
R/W
ENABLE
0
This register provides control of the TMAC block.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
ENABLE:
The transmit DMA controller enable bit (ENABLE) enables the TMAC to
accept TDRs from the TDR Ready Queue and reads packet data from host
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memory. When ENABLE is set high, the TMAC is enabled. When ENABLE
is set low, the TDR Ready Queue is ignored. Once all linked lists of TDs built
up by the TMAC have been exhausted, no more data will be transmitted on
the TD[31:0] links.
CACHE:
The transmit descriptor reference cache enable bit (CACHE) controls the
frequency at which TDRs are written to the TDR Free Queue. When CACHE
is set high, freed TDRs are cache and then written up to six at a time. When
CACHE is set low, freed TDRs are written one at a time.
TDQ_RDYN[2:0]:
The TDQ_RDYN[2:0] field sets the number of transmit descriptor references
(TDRs) that must be read from the TDR Ready Queue before the TDR Ready
interrupt (TDQRDYI) is asserted, as follows:
Table 20 – TDQ_RDYN[2:0] Settings
TDQ_RDYN[2:0]
No of TDRs
000
1
001
4
010
6
011
8
100
16
101
32
110
Reserved
111
Reserved
TDQ_FRN[1:0]:
The TDQ_FRN[1:0] field sets the number of times that a block of TDRs are
written to the TDR Free Queue from the TMACs internal cache before the
TDR Free Queue Interrupt (TDQFI) is asserted, as follows:
Table 21 – TDQ_FRN[1:0] Settings
TDQ_FRN[1:0]
No of Reads
00
1
01
4
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TDQ_FRN[1:0]
No of Reads
10
8
11
Reserved
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Register 0x304 : TMAC Indirect Channel Provisioning
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R
BUSY
X
Bit 14
R/W
RWB
0
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
Bit 8
Unused
X
Bit 7
R/W
PROV
0
Bit 6
R/W
CHAN[6]
0
Bit 5
R/W
CHAN[5]
0
Bit 4
R/W
CHAN[4]
0
Bit 3
R/W
CHAN[3]
0
Bit 2
R/W
CHAN[2]
0
Bit 1
R/W
CHAN[1]
0
Bit 0
R/W
CHAN[0]
0
The Channel Provisioning Register is used to provision and unprovision
channels, and also to query the provision status of channels. When a channel is
provisioned, chains of packet data for that channel will be accepted by the TMAC
and placed on the channel’s linked list of packets to be transmitted. When a
channel is unprovisioned, chains of packet data for that channel will be rejected
by the TMAC and returned to the TDR Free Queue with the status bits in the
queue element set to indicate the rejection.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
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implemented. However, when all four byte enables are negated, no access is
made to this register.
CHAN[6:0]:
The indirect data bits (CHAN[6:0]) report the channel number read from the
TMAC internal memory after an indirect read operation has completed.
Channel number to be written to the TMAC internal memory in an indirect
write operation must be set up in this register before triggering the write.
CHAN[6:0] reflects the value written until the completion of a subsequent
indirect read operation.
PROV:
The indirect provision enable bit (PROV) reports the channel provision enable
flag read from the TMAC internal memory after an indirect read operation has
completed. The provision enable flag to be written to the TMAC internal
memory, in an indirect write operation, must be set up in this register before
triggering the write. When PROV is set high, the channel as indicated by
CHAN[6:0] is provisioned. When PROV is set low, the channel indicated by
CHAN[6:0] is unprovisioned. PROV reflects the value written until the
completion of a subsequent indirect read operation.
RWB:
The Read/Write Bar (RWB) bit selects between a provisioning/unprovisioning
operation (write) or a query operation (read). Writing a logic 0 to RWB
triggers the provisioning or unprovisioning of a channel as specified by
CHAN[6:0] and PROV. Writing a logic 1 to RWB triggers a query of the
channel specified by CHAN[6:0].
BUSY:
The indirect access status bit (BUSY) reports the progress of an indirect
access. BUSY is set high when this register is written to trigger an indirect
access, and will stay high until the access is complete. At which point, BUSY
will be set low. This register should be polled to determine when data from an
indirect read operation is available or to determine when a new indirect write
operation may commence.
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FRAME ENGINE AND DATA LINK MANAGER
Register 0x308 : TMAC Descriptor Table Base LSW
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
TDTB[15]
0
Bit 14
R/W
TDTB[14]
0
Bit 13
R/W
TDTB[13]
0
Bit 12
R/W
TDTB[12]
0
Bit 11
R/W
TDTB[11]
0
Bit 10
R/W
TDTB[10]
0
Bit 9
R/W
TDTB[9]
0
Bit 8
R/W
TDTB[8]
0
Bit 7
R/W
TDTB[7]
0
Bit 6
R/W
TDTB[6]
0
Bit 5
R/W
TDTB[5]
0
Bit 4
R/W
TDTB[4]
0
Bit 3
R/W
TDTB[3]
0
Bit 2
R/W
TDTB[2]
0
Bit 1
R/W
TDTB[1]
0
Bit 0
R/W
TDTB[0]
0
This register provides the less significant word of the Transmit Descriptor Table
Base address. The contents of this register is held in a holding register until a
write access to the companion TMAC Transmit Descriptor Table Base MSW
register.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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Register 0x30C : TMAC Descriptor Table Base MSW
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
TDTB[31]
0
Bit 14
R/W
TDTB[30]
0
Bit 13
R/W
TDTB[29]
0
Bit 12
R/W
TDTB[28]
0
Bit 11
R/W
TDTB[27]
0
Bit 10
R/W
TDTB[26]
0
Bit 9
R/W
TDTB[25]
0
Bit 8
R/W
TDTB[24]
0
Bit 7
R/W
TDTB[23]
0
Bit 6
R/W
TDTB[22]
0
Bit 5
R/W
TDTB[21]
0
Bit 4
R/W
TDTB[20]
0
Bit 3
R/W
TDTB[19]
0
Bit 2
R/W
TDTB[18]
0
Bit 1
R/W
TDTB[17]
0
Bit 0
R/W
TDTB[16]
0
This register provides the more significant word of the Transmit Descriptor Table
Base address. The contents of the companion TMAC Transmit Descriptor Table
Base LSW register is held in a holding register until a write access to this
register, at which point, the base address of the transmit descriptor table is
updated.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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TDTB[31:0]:
The transmit descriptor table base bits (TDTB[31:0]) provides the base
address of the Transmit Descriptor Table in PCI host memory. This register is
initialised by the host. To calculate the physical address of a TD, the 14 bit TD
offset must be added to bits 31 to 4 of the Transmit Descriptor Table Base
(TDTB[31:4]).
The table must be on a 16 byte boundary and thus the least significant four
bits must be written to logic zero.
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Register 0x310 : TMAC Queue Base LSW
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
TQB[15]
0
Bit 14
R/W
TQB[14]
0
Bit 13
R/W
TQB[13]
0
Bit 12
R/W
TQB[12]
0
Bit 11
R/W
TQB[11]
0
Bit 10
R/W
TQB[10]
0
Bit 9
R/W
TQB[9]
0
Bit 8
R/W
TQB[8]
0
Bit 7
R/W
TQB[7]
0
Bit 6
R/W
TQB[6]
0
Bit 5
R/W
TQB[5]
0
Bit 4
R/W
TQB[4]
0
Bit 3
R/W
TQB[3]
0
Bit 2
R/W
TQB[2]
0
Bit 1
R/W
TQB[1]
0
Bit 0
R/W
TQB[0]
0
This register provides the less significant word of the Transmit Queue Base
address. The contents of this register is held in a holding register until a write
access to the companion TMAC Transmit Queue Base MSW register.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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Register 0x314 : TMAC Queue Base MSW
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
TQB[31]
0
Bit 14
R/W
TQB[30]
0
Bit 13
R/W
TQB[29]
0
Bit 12
R/W
TQB[28]
0
Bit 11
R/W
TQB[27]
0
Bit 10
R/W
TQB[26]
0
Bit 9
R/W
TQB[25]
0
Bit 8
R/W
TQB[24]
0
Bit 7
R/W
TQB[23]
0
Bit 6
R/W
TQB[22]
0
Bit 5
R/W
TQB[21]
0
Bit 4
R/W
TQB[20]
0
Bit 3
R/W
TQB[19]
0
Bit 2
R/W
TQB[18]
0
Bit 1
R/W
TQB[17]
0
Bit 0
R/W
TQB[16]
0
This register provides the more significant word of the Transmit Queue Base
address. The contents of the companion TMAC Transmit Descriptor Table Base
LSW register is held in a holding register until a write access to this register, at
which point, the base address of the transmit queue is updated.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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TQB[31:0]:
The transmit queue base bits (TQB[31:0]) provides the base address of the
Transmit Descriptor Reference Free and Transmit Descriptor Reference
Ready queue in PCI host memory. This register is initialised by the host. To
calculate the physical address of a particular transmit queue element, the
TQB bits are added with the appropriate queue start, end, read or write index
registers to form the physical address.
The base address must be dword aligned and thus the least significant two
bits must be written to logic zero.
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Register 0x318 : TMAC Descriptor Reference Free Queue Start
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
TDRFQS[15]
0
Bit 14
R/W
TDRFQS[14]
0
Bit 13
R/W
TDRFQS[13]
0
Bit 12
R/W
TDRFQS[12]
0
Bit 11
R/W
TDRFQS[11]
0
Bit 10
R/W
TDRFQS[10]
0
Bit 9
R/W
TDRFQS[9]
0
Bit 8
R/W
TDRFQS[8]
0
Bit 7
R/W
TDRFQS[7]
0
Bit 6
R/W
TDRFQS[6]
0
Bit 5
R/W
TDRFQS[5]
0
Bit 4
R/W
TDRFQS[4]
0
Bit 3
R/W
TDRFQS[3]
0
Bit 2
R/W
TDRFQS[2]
0
Bit 1
R/W
TDRFQS[1]
0
Bit 0
R/W
TDRFQS[0]
0
This register provides the Transmit Descriptor Reference Free Queue start
address.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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TDRFQS[15:0]:
The transmit packet descriptor reference (TDR) free queue start bits
(TDRFQS[15:0]) define bits 17 to 2 of the Transmit Packet Descriptor
Reference Free Queue start address. This register is initialised by the host.
The physical start address of the TDRF queue is the sum of TDRFQS[15:0]
left shifted by 2 bits with the TQB[31:0] bits in the TMAC Transmit Queue
Base register.
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Register 0x31C TMAC Descriptor Reference Free Queue Write
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
TDRFQW[15]
0
Bit 14
R/W
TDRFQW[14]
0
Bit 13
R/W
TDRFQW[13]
0
Bit 12
R/W
TDRFQW[12]
0
Bit 11
R/W
TDRFQW[11]
0
Bit 10
R/W
TDRFQW[10]
0
Bit 9
R/W
TDRFQW[9]
0
Bit 8
R/W
TDRFQW[8]
0
Bit 7
R/W
TDRFQW[7]
0
Bit 6
R/W
TDRFQW[6]
0
Bit 5
R/W
TDRFQW[5]
0
Bit 4
R/W
TDRFQW[4]
0
Bit 3
R/W
TDRFQW[3]
0
Bit 2
R/W
TDRFQW[2]
0
Bit 1
R/W
TDRFQW[1]
0
Bit 0
R/W
TDRFQW[0]
0
This register provides the Transmit Descriptor Reference Free Queue write
address.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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TDRFQW[15:0]:
The transmit packet descriptor reference (TPDR) free queue write bits
(TDRFQW[15:0]) define bits 17 to 2 of the Transmit Packet Descriptor
Reference Free Queue write pointer. This register is initialised by the host.
The physical write address in the TDRF queue is the sum of TDRFQW[15:0]
left shifted by 2 bits with the TQB[31:0] bits in the TMAC Transmit Queue
Base register.
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ISSUE 6
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Register 0x320 : TMAC Descriptor Reference Free Queue Read
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
TDRFQR[15]
0
Bit 14
R/W
TDRFQR[14]
0
Bit 13
R/W
TDRFQR[13]
0
Bit 12
R/W
TDRFQR[12]
0
Bit 11
R/W
TDRFQR[11]
0
Bit 10
R/W
TDRFQR[10]
0
Bit 9
R/W
TDRFQR[9]
0
Bit 8
R/W
TDRFQR[8]
0
Bit 7
R/W
TDRFQR[7]
0
Bit 6
R/W
TDRFQR[6]
0
Bit 5
R/W
TDRFQR[5]
0
Bit 4
R/W
TDRFQR[4]
0
Bit 3
R/W
TDRFQR[3]
0
Bit 2
R/W
TDRFQR[2]
0
Bit 1
R/W
TDRFQR[1]
0
Bit 0
R/W
TDRFQR[0]
0
This register provides the Transmit Descriptor Reference Free Queue read
address.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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TDRFQR[15:0]:
The transmit packet descriptor reference (TPDR) free queue read bits
(TDRFQR[15:0]) define bits 17 to 2 of the Transmit Packet Descriptor
Reference Free Queue read pointer. This register is initialised by the host.
The physical read address in the TDRF queue is the sum of TDRFQR[15:0]
left shifted by 2 bits with the TQB[31:0] bits in the TMAC Transmit Queue
Base register.
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Register 0x324 : TMAC Descriptor Reference Free Queue End
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
TDRFQE[15]
0
Bit 14
R/W
TDRFQE[14]
0
Bit 13
R/W
TDRFQE[13]
0
Bit 12
R/W
TDRFQE[12]
0
Bit 11
R/W
TDRFQE[11]
0
Bit 10
R/W
TDRFQE[10]
0
Bit 9
R/W
TDRFQE[9]
0
Bit 8
R/W
TDRFQE[8]
0
Bit 7
R/W
TDRFQE[7]
0
Bit 6
R/W
TDRFQE[6]
0
Bit 5
R/W
TDRFQE[5]
0
Bit 4
R/W
TDRFQE[4]
0
Bit 3
R/W
TDRFQE[3]
0
Bit 2
R/W
TDRFQE[2]
0
Bit 1
R/W
TDRFQE[1]
0
Bit 0
R/W
TDRFQE[0]
0
This register provides the Transmit Descriptor Reference Free Queue end
address.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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TDRFQE[15:0]:
The transmit packet descriptor reference (TDR) free queue end bits
(TDRFQE[15:0]) define bits 17 to 2 of the Transmit Packet Descriptor
Reference Free Queue end address. This register is initialised by the host.
The physical end address of the TDRF queue is the sum of TDRFQE[15:0]
left shifted by 2 bits with the TQB[31:0] bits in the TMAC Transmit Queue
Base register.
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Register 0x328 :TMAC Descriptor Reference Ready Queue Start
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
TDRRQS[15]
0
Bit 14
R/W
TDRRQS[14]
0
Bit 13
R/W
TDRRQS[13]
0
Bit 12
R/W
TDRRQS[12]
0
Bit 11
R/W
TDRRQS[11]
0
Bit 10
R/W
TDRRQS[10]
0
Bit 9
R/W
TDRRQS[9]
0
Bit 8
R/W
TDRRQS[8]
0
Bit 7
R/W
TDRRQS[7]
0
Bit 6
R/W
TDRRQS[6]
0
Bit 5
R/W
TDRRQS[5]
0
Bit 4
R/W
TDRRQS[4]
0
Bit 3
R/W
TDRRQS[3]
0
Bit 2
R/W
TDRRQS[2]
0
Bit 1
R/W
TDRRQS[1]
0
Bit 0
R/W
TDRRQS[0]
0
This register provides the Transmit Descriptor Reference Ready Queue start
address.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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TDRRQS[15:0]:
The transmit packet descriptor reference (TDR) ready queue start bits
(TDRRQS[15:0]) define bits 17 to 2 of the Transmit Packet Descriptor
Reference Ready Queue start address. This register is initialised by the host.
The physical start address of the TDRF queue is the sum of TDRRQS[15:0]
left shifted by 2 bits with the TQB[31:0] bits in the TMAC Transmit Queue
Base register.
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Register 0x32C : TMAC Descriptor Reference Ready Queue Write
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
TDRRQW[15]
0
Bit 14
R/W
TDRRQW[14]
0
Bit 13
R/W
TDRRQW[13]
0
Bit 12
R/W
TDRRQW[12]
0
Bit 11
R/W
TDRRQW[11]
0
Bit 10
R/W
TDRRQW[10]
0
Bit 9
R/W
TDRRQW[9]
0
Bit 8
R/W
TDRRQW[8]
0
Bit 7
R/W
TDRRQW[7]
0
Bit 6
R/W
TDRRQW[6]
0
Bit 5
R/W
TDRRQW[5]
0
Bit 4
R/W
TDRRQW[4]
0
Bit 3
R/W
TDRRQW[3]
0
Bit 2
R/W
TDRRQW[2]
0
Bit 1
R/W
TDRRQW[1]
0
Bit 0
R/W
TDRRQW[0]
0
This register provides the Transmit Descriptor Reference Ready Queue write
address.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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TDRRQW[15:0]:
The transmit packet descriptor reference (TPDR) ready queue write bits
(TDRRQW[15:0]) define bits 17 to 2 of the Transmit Packet Descriptor
Reference Ready Queue write pointer. This register is initialised by the host.
The physical write address in the TDRF queue is the sum of TDRRQW[15:0]
left shifted by 2 bits with the TQB[31:0] bits in the TMAC Transmit Queue
Base register.
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Register 0x330 : TMAC Descriptor Reference Ready Queue Read
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
TDRRQR[15]
0
Bit 14
R/W
TDRRQR[14]
0
Bit 13
R/W
TDRRQR[13]
0
Bit 12
R/W
TDRRQR[12]
0
Bit 11
R/W
TDRRQR[11]
0
Bit 10
R/W
TDRRQR[10]
0
Bit 9
R/W
TDRRQR[9]
0
Bit 8
R/W
TDRRQR[8]
0
Bit 7
R/W
TDRRQR[7]
0
Bit 6
R/W
TDRRQR[6]
0
Bit 5
R/W
TDRRQR[5]
0
Bit 4
R/W
TDRRQR[4]
0
Bit 3
R/W
TDRRQR[3]
0
Bit 2
R/W
TDRRQR[2]
0
Bit 1
R/W
TDRRQR[1]
0
Bit 0
R/W
TDRRQR[0]
0
This register provides the Transmit Descriptor Reference Ready Queue read
address.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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TDRRQR[15:0]:
The transmit packet descriptor reference (TPDR) ready queue read bits
(TDRRQR[15:0]) define bits 17 to 2 of the Transmit Packet Descriptor
Reference Ready Queue read pointer. This register is initialised by the host.
The physical read address in the TDRF queue is the sum of TDRRQR[15:0]
left shifted by 2 bits with the TQB[31:0] bits in the TMAC Transmit Queue
Base register.
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Register 0x334 : TMAC Descriptor Reference Ready Queue End
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
TDRRQE[15]
0
Bit 14
R/W
TDRRQE[14]
0
Bit 13
R/W
TDRRQE[13]
0
Bit 12
R/W
TDRRQE[12]
0
Bit 11
R/W
TDRRQE[11]
0
Bit 10
R/W
TDRRQE[10]
0
Bit 9
R/W
TDRRQE[9]
0
Bit 8
R/W
TDRRQE[8]
0
Bit 7
R/W
TDRRQE[7]
0
Bit 6
R/W
TDRRQE[6]
0
Bit 5
R/W
TDRRQE[5]
0
Bit 4
R/W
TDRRQE[4]
0
Bit 3
R/W
TDRRQE[3]
0
Bit 2
R/W
TDRRQE[2]
0
Bit 1
R/W
TDRRQE[1]
0
Bit 0
R/W
TDRRQE[0]
0
This register provides the Transmit Descriptor Reference Ready Queue end
address.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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TDRRQE[15:0]:
The transmit packet descriptor reference (TDR) ready queue end bits
(TDRRQE[15:0]) define bits 17 to 2 of the Transmit Packet Descriptor
Reference Ready Queue end address. This register is initialised by the host.
The physical end address of the TDRF queue is the sum of TDRRQE[15:0]
left shifted by 2 bits with the TQB[31:0] bits in the TMAC Transmit Queue
Base register.
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Register 0x380 : THDL Indirect Channel Select
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R
BUSY
X
Bit 14
R/W
CRWB
0
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
Bit 8
Unused
X
Bit 7
Unused
X
Bit 6
R/W
CHAN[6]
0
Bit 5
R/W
CHAN[5]
0
Bit 4
R/W
CHAN[4]
0
Bit 3
R/W
CHAN[3]
0
Bit 2
R/W
CHAN[2]
0
Bit 1
R/W
CHAN[1]
0
Bit 0
R/W
CHAN[0]
0
This register provides the channel number used to access the transmit channel
provision RAM. Writing to this register triggers an indirect channel register
access.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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CHAN[6:0]:
The indirect channel number bits (CHAN[6:0]) indicate the channel to be
configured or interrogated in the indirect access.
CRWB:
The channel indirect access control bit (CRWB) selects between a configure
(write) or interrogate (read) access to the channel provision RAM. Writing a
logic zero to CRWB triggers an indirect write operation. Data to be written is
taken from the Indirect Channel Data registers. Writing a logic one to CRWB
triggers an indirect read operation. The data read can be found in the Indirect
Channel Data registers.
BUSY:
The indirect access status bit (BUSY) reports the progress of an indirect
access. BUSY is set high when this register is written to trigger an indirect
access, and will stay high until the access is complete. At which point, BUSY
will be set low. This register should be polled to determine when data from an
indirect read operation is available in the THDL Indirect Channel Data #1, #2
and #3 registers or to determine when a new indirect write operation may
commence.
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Register 0x384 : THDL Indirect Channel Data #1
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
PROV
0
Bit 14
R/W
CRC[1]
0
Bit 13
R/W
CRC[0]
0
Bit 12
R/W
IDLE
0
Bit 11
R/W
DELIN
0
Bit 10
Unused
X
Bit 9
Unused
X
Bit 8
W
FPTR[8]
0
Bit 7
W
FPTR[7]
0
Bit 6
W
FPTR[6]
0
Bit 5
W
FPTR[5]
0
Bit 4
W
FPTR[4]
0
Bit 3
W
FPTR[3]
0
Bit 2
W
FPTR[2]
0
Bit 1
W
FPTR[1]
0
Bit 0
W
FPTR[0]
0
This register contains data read from the channel provision RAM after an indirect
channel read operation or data to be inserted into the channel provision RAM in
an indirect channel write operation.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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FPTR[8:0]:
The indirect FIFO block pointer (FPTR[8:0]) informs the partial packet buffer
processor the circular linked list of blocks to use for a FIFO for the channel.
The FIFO pointer to be written to the channel provision RAM, in an indirect
write operation, must be set up in this register before triggering the write. The
FIFO pointer value can be any one of the block numbers provisioned, by
indirect block write operations, to form the circular buffer.
DELIN:
The indirect delineate enable bit (DELIN) configures the HDLC processor to
perform flag sequence insertion and bit stuffing on the outgoing data stream.
The delineate enable bit to be written to the channel provision RAM, in an
indirect channel write operation, must be set up in this register before
triggering the write. When DELIN is set high, flag sequence insertion, bit
stuffing and ,optionally, CRC generation is performed on the outgoing HDLC
data stream. When DELIN is set low, the HDLC processor does not perform
any processing (flag sequence insertion, bit stuffing nor CRC generation) on
the outgoing stream. DELIN reflects the value written until the completion of
a subsequent indirect channel read operation.
IDLE:
The interframe time fill bit (IDLE) configures the HDLC processor to use flag
bytes or HDLC idle as the interframe time fill between HDLC packets. The
value of IDLE to be written to the channel provision RAM, in an indirect
channel write operation, must be set up in this register before triggering the
write. When IDLE is set low, the HDLC processor uses flag bytes as the
interframe time fill. When IDLE is set high, the HDLC processor uses HDLC
idle (all one's bit with no bit-stuffing pattern is transmitted) as the interframe
time fill. IDLE reflects the value written until the completion of a subsequent
indirect channel read operation.
CRC[1:0]:
The CRC algorithm (CRC[1:0]) configures the HDLC processor to perform
CRC generation on the outgoing HDLC data stream. The value of CRC[1:0]
to be written to the channel provision RAM, in an indirect channel write
operation, must be set up in this register before triggering the write. CRC[1:0]
is ignored when DELIN is low. CRC[1:0] reflects the value written until the
completion of a subsequent indirect channel read operation.
Table 22 – CRC[1:0] Settings
CRC[1]
CRC[0]
Operation
0
0
No CRC
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CRC[1]
CRC[0]
Operation
0
1
CRC-CCITT
1
0
CRC-32
1
1
Reserved
PROV:
The indirect provision enable bit (PROV) reports the channel provision enable
flag read from the channel provision RAM after an indirect channel read
operation has completed. The provision enable flag to be written to the
channel provision RAM, in an indirect write operation, must be set up in this
register before triggering the write. When PROV is set high, the HDLC
processor will service requests for data from the TCAS block. When PROV is
set low, the HDLC processor will ignore requests from the TCAS block.
PROV reflects the value written until the completion of a subsequent indirect
channel read operation.
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Register 0x388 : THDL Indirect Channel Data #2
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R/W
7BIT
0
Bit 14
R/W
PRIORITYB
0
Bit 13
R/W
INVERT
0
Bit 12
R/W
DFCS
0
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
Bit 8
W
FLEN[8]
0
Bit 7
W
FLEN[7]
0
Bit 6
W
FLEN[6]
0
Bit 5
W
FLEN[5]
0
Bit 4
W
FLEN[4]
0
Bit 3
W
FLEN[3]
0
Bit 2
W
FLEN[2]
0
Bit 1
W
FLEN[1]
0
Bit 0
W
FLEN[0]
0
This register contains data to be inserted into the channel provision RAM in an
indirect write operation.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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FLEN[8:0]:
The indirect FIFO length (FLEN[8:0]) is the number of blocks, less one, that is
provisioned to the circular channel FIFO specified by the FPTR[8:0] block
pointer. The FIFO length to be written to the channel provision RAM, in an
indirect channel write operation, must be set up in this register before
triggering the write.
DFCS:
The diagnose frame check sequence bit (DFCS) controls the inversion of the
FCS field inserted into the transmit packet. The value of DFCS to be written
to the channel provision RAM, in an indirect channel write operation, must be
set up in this register before triggering the write. When DFCS is set to one,
the FCS field in the outgoing HDLC stream is logically inverted allowing
diagnosis of downstream FCS verification logic. The outgoing FCS field is
not inverted when DFCS is set to zero. DFCS reflects the value written until
the completion of a subsequent indirect channel read operation.
INVERT:
The HDLC data inversion bit (INVERT) configures the HDLC processor to
logically invert the outgoing HDLC stream. The value of INVERT to be written
to the channel provision RAM, in an indirect channel write operation, must be
set up in this register before triggering the write. When INVERT is set to one,
the outgoing HDLC stream is logically inverted. The outgoing HDLC stream
is not inverted when INVERT is set to zero. INVERT reflects the value written
until the completion of a subsequent indirect channel read operation.
PRIORITYB:
The active low channel FIFO expedite enable bit (PRIORITYB) informs the
partial packet processor of the priority of the channel relative to other
channels when requesting data from the DMA port. The value of PRIORITYB
to be written to the channel provision RAM, in an indirect channel write
operation, must be set up in this register before triggering the write. Channel
FIFOs with PRIORITYB set to one are inhibited from making expedited
requests for data to the TMAC. When PRIORITYB is set to zero, both normal
and expedited requests can be made to the TMAC. Channels with HDLC
data rate to FIFO size ratio that is significantly lower than other channels
should have PRIORITYB set to one. PRIORITYB reflects the value written
until the completion of a subsequent indirect channel read operation.
7BIT:
The least significant stuff enable bit (7BIT) configures the HDLC processor to
stuff the least significant bit of each octet in the corresponding transmit link
(TD[n]). The value of 7BIT to be written to the channel provision RAM, in an
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indirect channel write operation, must be set up in this register before
triggering the write. When 7BIT is set high, the least significant bit (last bit of
each octet transmitted) does not contain channel data and is forced to the
value configured by the BIT8 register bit. When 7BIT is set low, the entire
octet contains valid data and BIT8 is ignored. 7BIT reflects the value written
until the completion of a subsequent indirect channel read operation.
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Register 0x38C : THDL Indirect Channel Data #3
Bit
Type
Function
Default
Unused
XXXXH
TRANS
0
Bit 14
Unused
X
Bit 13
Unused
X
Bit 12
Unused
X
Bit 31
to
Bit 16
Bit 15
R/W
Bit 11
R/W
LEVEL[3]
0
Bit 10
R/W
LEVEL[2]
0
Bit 9
R/W
LEVEL[1]
0
Bit 8
R/W
LEVEL[0]
0
Bit 7
R/W
FLAG[2]
0
Bit 6
R/W
FLAG[1]
0
Bit 5
R/W
FLAG[0]
0
Bit 4
Unused[
X
Bit 3
Unused
X
Bit 2
R/W
XFER[2]
0
Bit 1
R/W
XFER[1]
0
Bit 0
R/W
XFER[0]
0
This register contains data read from the channel provision RAM after an indirect
read operation or data to be inserted into the channel provision RAM in an
indirect write operation.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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XFER[2:0]:
The indirect channel transfer size (XFER[2:0]) specifies the amount of data
the partial packet processor requests from the TMAC block. The channel
transfer size to be written to the channel provision RAM, in an indirect write
operation, must be set up in this register before triggering the write. When
the channel FIFO free space reaches or exceeds the limit specified by
XFER[2:0], the partial packet processor will make a request for data to the
TMAC to retrieve the XFER[2:0] + 1 blocks of data. FIFO free space and
transfer size are measured in the number of 16-byte blocks. XFER[2:0]
reflects the value written until the completion of a subsequent indirect channel
read operation.
To prevent lockup, the channel transfer size (XFER[2:0]) can be configured to
be less than or equal to the start transmission level set by LEVEL[3:0] and
TRANS. Alternatively, the channel transfer size can be set, such that, the
total number of blocks in the logical channel FIFO minus the start
transmission level is an integer multiple of the channel transfer size.
The case of a single block transfer size is a special. When BURSTEN is set
high and XFER[2:0] = 'b000, the transfer size is variable. The THDL will
request the TMAC to transfer as much data as there is free space in the
FIFO, up to a maximum set by BURST[2:0].
FLAG[2:0]:
The flag insertion control (FLAG[2:0]) configures the minimum number of
flags or bytes of idle bits the HDLC processor inserts between HDLC packets.
The value of FLAG[2:0] to be written to the channel provision RAM, in an
indirect channel write operation, must be set up in this register before
triggering the write. The minimum number of flags or bytes of idle (8 bits of
1's) inserted between HDLC packets is shown in the table below. FLAG[2:0]
reflects the value written until the completion of a subsequent indirect channel
read operation.
Table 23 – FLAG[2:0] Settings
FLAG[2:0]
Minimum Number of Flag/Idle Bytes
000
1 flag / 0 Idle byte
001
2 flags / 0 idle byte
010
4 flags / 2 idle bytes
011
8 flags / 6 idle bytes
100
16 flags / 14 idle bytes
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FLAG[2:0]
Minimum Number of Flag/Idle Bytes
101
32 flags / 30 idle bytes
110
64 flags / 62 idle bytes
111
128 flags / 126 idle bytes
LEVEL[3:0]:
The indirect channel FIFO trigger level (LEVEL[3:0]), in concert with the
TRANS bit, configure the various channel FIFO free space levels which
trigger the HDLC processor to start transmission of a HDLC packet as well as
trigger the partial packet buffer to make DMA request for data as shown in the
following table. The channel FIFO trigger level to be written to the channel
provision RAM, in an indirect write operation, must be set up in this register
before triggering the write. LEVEL[3:0] reflects the value written until the
completion of a subsequent indirect channel read operation.
The HDLC processor starts transmitting a packet when the channel FIFO free
space is less than or equal to the level specified in the appropriate Start
Transmission Level column of the following table or when an end of a packet
is stored in the channel FIFO. When the channel FIFO free space is less
than or equal to the level specified in the Expedite Trigger Level column of
the following table and the HDLC processor is transmitting a packet and an
end of a packet is not stored in the channel FIFO, the partial packet buffer
makes expedite requests to the TMAC to retrieve XFER[2:0] + 1 blocks of
data.
To prevent lockup, the channel transfer size (XFER[2:0]) can be configured to
be less than or equal to the start transmission level set by LEVEL[3:0] and
TRANS. Alternatively, the channel transfer size can be set, such that, the
total number of blocks in the logical channel FIFO minus the start
transmission level is an integer multiple of the channel transfer size.
TRANS:
The indirect transmission start bit (TRANS), in concert with the LEVEL[3:0]
bits, configure the various channel FIFO free space levels which trigger the
HDLC processor to start transmission of a HDLC packet as well as trigger the
partial packet buffer to make DMA request for data as shown in the following
table. The transmission start mode to be written to the channel provision
RAM, in an indirect write operation, must be set up in this register before
triggering the write. TRANS reflects the value written until the completion of a
subsequent indirect channel read operation.
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The HDLC processor starts transmitting a packet when the channel FIFO free
space is less than or equal to the level specified in the appropriate Start
Transmission Level column of the following table or when an end of a packet
is stored in the channel FIFO. When the channel FIFO free space is greater
than the level specified in the Expedite Trigger Level column of the following
table and the HDLC processor is transmitting a packet and an end of a
packet is not stored in the channel FIFO, the partial packet buffer makes
expedited requests to the TMAC to retrieve XFER[2:0] + 1 blocks of data.
To prevent lockup, the channel transfer size (XFER[2:0]) can be configured to
be less than or equal to the start transmission level set by LEVEL[3:0] and
TRANS. Alternatively, the channel transfer size can be set, such that, the
total number of blocks in the logical channel FIFO minus the start
transmission level is an integer multiple of the channel transfer size.
Table 24 – Level[3:0]/TRANS Settings
LEVEL[3:0]
Expedite
Trigger Level
Start
Transmission
Level (TRANS=0)
Start Transmission
Level (TRANS=1)
0000
2 Blocks
(32 bytes free)
1 Block
(16 bytes free)
1 Block
(16 bytes free)
0001
3 Blocks
(48 bytes free)
2 Blocks
(32 bytes free)
1 Block
(16 bytes free)
0010
4 Blocks
(64 bytes free)
3 Blocks
(48 bytes free)
2 Blocks
(32 bytes free)
0011
6 Blocks
(96 bytes free)
4 Blocks
(64 bytes free)
3 Blocks
(48 bytes free)
0100
8 Blocks
(128 bytes free)
6 Blocks
(96 bytes free)
4 Blocks
(64 bytes free)
0101
12 Blocks
(192 bytes free)
8 Blocks
(128 bytes free)
6 Blocks
(96 bytes free)
0110
16 Blocks
(256 bytes free)
12 Blocks
(192 bytes free)
8 Blocks
(128 bytes free)
0111
24 Blocks
(384 bytes free)
16 Blocks
(256 bytes free)
12 Blocks
(192 bytes free)
1000
32 Blocks
(512 bytes free)
24 Blocks
(384 bytes free)
16 Blocks
(256 bytes free)
1001
48 Blocks
(768 bytes free)
32 Blocks
(512 bytes free)
24 Blocks
(384 bytes free)
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LEVEL[3:0]
Expedite
Trigger Level
Start
Transmission
Level (TRANS=0)
Start Transmission
Level (TRANS=1)
1010
64 Blocks
(1 Kbytes free)
48 Blocks
(768 bytes free)
32 Blocks
(512 bytes free)
1011
96 Blocks
(1.5 Kbytes free)
64 Blocks
(1 Kbytes free)
48 Blocks
(768 bytes free)
1100
128 Blocks
(2 Kbytes free)
96 Blocks
(1.5 Kbytes free)
64 Blocks
(1 Kbytes free)
1101
192 Blocks
(3 Kbytes free)
128 Blocks
(2 Kbytes free)
96 Blocks
(1.5 Kbytes free)
1110
256 Blocks
(4 Kbytes free)
192 Blocks
(3 Kbytes free)
128 Blocks
(2 Kbytes free)
1111
384 Blocks
(6 Kbytes free)
256 Blocks
(4 Kbytes free)
192 Blocks
(3 Kbytes free)
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Register 0x3A0 : THDL Indirect Block Select
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R
BUSY
X
Bit 14
R/W
BRWB
0
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
Bit 8
R/W
BLOCK[8]
0
Bit 7
R/W
BLOCK[7]
0
Bit 6
R/W
BLOCK[6]
0
Bit 5
R/W
BLOCK[5]
0
Bit 4
R/W
BLOCK[4]
0
Bit 3
R/W
BLOCK[3]
0
Bit 2
R/W
BLOCK[2]
0
Bit 1
R/W
BLOCK[1]
0
Bit 0
R/W
BLOCK[0]
0
This register provides the block number used to access the block pointer RAM.
Writing to this register triggers an indirect block register access.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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BLOCK[8:0]:
The indirect block number (BLOCK[8:0]) indicate the block to be configured
or interrogated in the indirect access.
BRWB:
The block indirect access control bit (BRWB) selects between a configure
(write) or interrogate (read) access to the block pointer RAM. Writing a logic
zero to BRWB triggers an indirect block write operation. Data to be written is
taken from the Indirect Block Data register. Writing a logic one to BRWB
triggers an indirect block read operation. The data read can be found in the
Indirect Block Data register.
BUSY:
The indirect access status bit (BUSY) reports the progress of an indirect
access. BUSY is set high when this register is written to trigger an indirect
access, and will stay high until the access is complete. At which point, BUSY
will be set low. This register should be polled to determine when data from an
indirect read operation is available in the THDL Indirect Block Data register or
to determine when a new indirect write operation may commence.
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Register 0x3A4 : THDL Indirect Block Data
Bit
Type
Function
Default
Unused
XXXXH
Reserved
0
Bit 14
Unused
X
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
Bit 31
to
Bit 16
Bit 15
R/W
Bit 8
R/W
BPTR[8]
0
Bit 7
R/W
BPTR[7]
0
Bit 6
R/W
BPTR[6]
0
Bit 5
R/W
BPTR[5]
0
Bit 4
R/W
BPTR[4]
0
Bit 3
R/W
BPTR[3]
0
Bit 2
R/W
BPTR[2]
0
Bit 1
R/W
BPTR[1]
0
Bit 0
R/W
BPTR[0]
0
This register contains data read from the transmit block pointer RAM after an
indirect block read operation or data to be inserted into the transmit block pointer
RAM in an indirect block write operation.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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BPTR[8:0]:
The indirect block pointer (BPTR[8:0]) configures the block pointer of the
block specified by the Indirect Block Select register. The block pointer to be
written to the transmit block pointer RAM, in an indirect write operation, must
be set up in this register before triggering the write. The block pointer value is
the block number of the next block in the linked list. A circular list of blocks
must be formed in order to use the block list as a channel FIFO buffer.
FPTR[8:0] reflects the value written until the completion of a subsequent
indirect block read operation.
When provisioning a channel FIFO, all blocks pointers must be re-written to
properly initialize the FIFO.
Reserved:
The reserved bit (Reserved) must be set low for correct operation of the
FREEDM-32 device.
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Register 0x3B0 : THDL Configuration
Bit
Type
Function
Default
Bit 31
to
Bit 16
Unused
XXXXH
Bit 15
Unused
X
Bit 14
Unused
X
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
R/W
BIT8
0
Bit 8
R/W
TSTD
0
Bit 7
R/W
BURSTEN
0
Bit 6
Unused
X
Bit 5
Unused
X
Bit 4
Unused
X
Bit 3
Unused
X
Bit 2
R/W
BURST[2]
0
Bit 1
R/W
BURST[1]
0
Bit 0
R/W
BURST[0]
0
This register configures all provisioned channels.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
BURST[2:0]:
The DMA burst length bits (BURST[2:0]) configure the maximum amount of
transmit data that can be requested in a single DMA transaction for channels
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whose channel transfer size is set to one block (XFER[2:0] = 'b000).
BURST[2:0] has no effect when BURSTEN is set low, nor on channels
configured with other transfer sizes. BURST[2:0] defines the maximum
number of 16 byte blocks, less one, that is transferred in each DMA
transaction. Thus, the minimum number of blocks is one (16 bytes) and the
maximum is eight (128 bytes).
BURSTEN:
The burst length enable bit (BURSTEN) controls the use of BURST[2:0] in
determining the amount of data requested in a single DMA transaction for
channels whose channel transfer size is set to one block (XFER[2:0] = 'b000).
BURSTEN has no effect on channels configured with other transfer sizes.
When BURSTEN is set high, the maximum size of DMA transfer is limited by
BURST[2:0]. The transmit HDLC processor may combine several channel
transfer size amounts into a single transaction. When BURSTEN is set low,
the amount of data in a DMA transfer is limited to one block.
TSTD:
The telecom standard bit (TSTD) controls the bit ordering of the HDLC data
transferred from the PCI host. When TSTD is set low, the least significant bit
of the each byte on the PCI bus (AD[0], AD[8], AD[16] and AD[24]) is the first
HDLC bit transmitted and the most significant bit of each byte (AD[7], AD[15],
AD[23] and AD[31]) is the last HDLC bit transmitted (datacom standard).
When TSTD is set high, AD[0], AD[8], AD[16] and AD[24] are the last HDLC
bit transmitted and AD[7], AD[15], AD[23] and AD[31] are the first HDLC bit
transmitted (telecom standard).
BIT8:
The least significant stuff control bit (BIT8) carries the value placed in the
least significant bit of each octet when the HDLC processor is configured
(7BIT set high) to stuff the least significant bit of each octet in the
corresponding transmit link (TD[n]). When BIT8 is set high, the least
significant bit (last bit of each octet transmitted) is forced high. When BIT8 is
set low, the least significant bit is forced low. BIT8 is ignored when 7BIT is set
low.
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Register 0x400 : TCAS Indirect Link and Time-slot Select
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R
BUSY
X
Bit 14
R/W
RWB
0
Unused
X
Bit 13
Bit 12
R/W
LINK[4]
0
Bit 11
R/W
LINK[3]
0
Bit 10
R/W
LINK[2]
0
Bit 9
R/W
LINK[1]
0
Bit 8
R/W
LINK[0]
0
Bit 7
Unused
X
Bit 6
Unused
X
Bit 5
Unused
X
Bit 4
R/W
TSLOT[4]
0
Bit 3
R/W
TSLOT[3]
0
Bit 2
R/W
TSLOT[2]
0
Bit 1
R/W
TSLOT[1]
0
Bit 0
R/W
TSLOT[0]
0
This register provides the link number and time-slot number used to access the
transmit channel provision RAM. Writing to this register triggers an indirect
register access and transfers the contents of the Indirect Channel Data register
to an internal holding register.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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TSLOT[4:0]:
The indirect time-slot number bits (TSLOT[4:0]) indicate the time-slot to be
configured or interrogated in the indirect access. For a channelised T1 link,
time-slots 1 to 24 are valid. For a channelised E1 link, time-slots 1 to 31 are
valid. For unchannelised links, only time-slot 0 is valid.
LINK[4:0]:
The indirect link number bits (LINK[4:0]) select amongst the 32 transmit links
to be configured or interrogated in the indirect access.
RWB:
The indirect access control bit (RWB) selects between a configure (write) or
interrogate (read) access to the transmit channel provision RAM. The
address to the transmit channel provision RAM is constructed by
concatenating the TSLOT[4:0] and LINK[4:0] bits. Writing a logic zero to
RWB triggers an indirect write operation. Data to be written is taken from the
PROV and the CHAN[6:0] bits of the Indirect Data register. Writing a logic
one to RWB triggers an indirect read operation. Addressing of the RAM is the
same as in an indirect write operation. The data read can be found in the
PROV and the CHAN[6:0] bits of the Indirect Channel Data register.
BUSY:
The indirect access status bit (BUSY) reports the progress of an indirect
access. BUSY is set high when this register is written to trigger an indirect
access, and will stay high until the access is complete. At which point, BUSY
will be set low. This register should be polled to determine when data from an
indirect read operation is available in the TCAS Indirect Channel Data register
or to determine when a new indirect write operation may commence.
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Register 0x404 : TCAS Indirect Channel Data
Bit
Function
Default
Bit 31
to
Bit 16
Unused
XXXXH
Bit 15
Unused
X
Bit 14
Unused
X
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
PROV
0
Unused
X
Bit 8
Type
R/W
Bit 7
Bit 6
R/W
CHAN[6]
0
Bit 5
R/W
CHAN[5]
0
Bit 4
R/W
CHAN[4]
0
Bit 3
R/W
CHAN[3]
0
Bit 2
R/W
CHAN[2]
0
Bit 1
R/W
CHAN[1]
0
Bit 0
R/W
CHAN[0]
0
This register contains the data read from the transmit channel provision RAM
after an indirect read operation or the data to be inserted into the transmit
channel provision RAM in an indirect write operation.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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CHAN[6:0]:
The indirect data bits (CHAN[6:0]) report the channel number read from the
transmit channel provision RAM after an indirect read operation has
completed. Channel number to be written to the transmit channel provision
RAM in an indirect write operation must be set up in this register before
triggering the write. CHAN[6:0] reflects the value written until the completion
of a subsequent indirect read operation.
PROV:
The indirect provision enable bit (PROV) reports the channel provision enable
flag read from transmit channel provision RAM after an indirect read
operation has completed. The provision enable flag to be written to the
transmit channel provision RAM in an indirect write operation must be set up
in this register before triggering the write. When PROV is set high, the
current time-slot is assigned to the channel as indicated by CHAN[6:0].
When PROV is set low, the time-slot does not belong to any channel. The
transmit link data is set to the contents of the Idle Time-slot Fill Data register.
PROV reflects the value written until the completion of a subsequent indirect
read operation.
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Register 0x408 : TCAS Framing Bit Threshold
Bit
Type
Function
Default
Bit 31
to
Bit 16
Unused
XXXXH
Bit 15
Unused
X
Bit 14
Unused
X
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
Bit 8
Unused
X
Bit 7
Unused
X
Bit 6
R/W
FTHRES[6]
0
Bit 5
R/W
FTHRES[5]
0
Bit 4
R/W
FTHRES[4]
1
Bit 3
R/W
FTHRES[3]
1
Bit 2
R/W
FTHRES[2]
1
Bit 1
R/W
FTHRES[1]
1
Bit 0
R/W
FTHRES[0]
1
This register contains the threshold used by the clock activity monitors to detect
for framing bits/bytes.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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FTHRES[6:0]:
The framing bit threshold bits (FTHRES[6:0]) contains the threshold used by
the clock activity monitor to detect for the presence of framing bits. A counter
in the clock activity monitor of each receive link increments at each SYSCLK
and is cleared, when the BSYNC bit of that link is set low, by each rising edge
of the corresponding TCLK[n]. When the BSYNC bit of that link is set high,
the counter is cleared at every fourth rising edge of the corresponding
TCLK[n]. When the counter exceeds the threshold given by FTHRES[6:0], a
framing bit/byte has been detected. FTHRES[6:0] should be set as a function
of the SYSCLK period and the expected gapping width of TCLK[n] during
data bits and during framing bits/bytes. Legal range of FTHRES[6:0] is
'b0000001 to 'b1111110.
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Register 0x40C : TCAS Idle Time-slot Fill Data
Bit
Type
Function
Default
Bit 31
to
Bit 16
Unused
XXXXH
Bit 15
Unused
X
Bit 14
Unused
X
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
Bit 8
Unused
X
Bit 7
R/W
FDATA[7]
1
Bit 6
R/W
FDATA[6]
1
Bit 5
R/W
FDATA[5]
1
Bit 4
R/W
FDATA[4]
1
Bit 3
R/W
FDATA[3]
1
Bit 2
R/W
FDATA[2]
1
Bit 1
R/W
FDATA[1]
1
Bit 0
R/W
FDATA[0]
1
This register contains the data to be written to disabled time-slots of a
channelised link.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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FDATA[7:0]:
The fill data bits (FDATA[7:0]) are transmitted during disabled (PROV set low)
time-slots of channelised links.
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Register 0x410 : TCAS Channel Disable
Bit
Type
Function
Default
Unused
XXXXH
CHDIS
0
Bit 14
Unused
X
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
Bit 8
Unused
X
Bit 7
Unused
X
Bit 31
to
Bit 16
Bit 15
R/W
Bit 6
R/W
DCHAN[6]
0
Bit 5
R/W
DCHAN[5]
0
Bit 4
R/W
DCHAN[4]
0
Bit 3
R/W
DCHAN[3]
0
Bit 2
R/W
DCHAN[2]
0
Bit 1
R/W
DCHAN[1]
0
Bit 0
R/W
DCHAN[0]
0
This register controls the disabling of one specific channel to allow orderly
provisioning of timeslots.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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DCHAN[6:0]:
The disable channel number bits (DCHAN[6:0]) selects the channel to be
disabled. When CHDIS is set high, the channel specified by DCHAN[6:0] is
disabled. Data in timeslots associated with the specified channel is set to
FDATA[7:0] in the Idle Time-slot Fill Data register. When CHDIS is set low,
the channel specified by DCHAN[6:0] operates normally.
CHDIS:
The channel disable bit (CHDIS) controls the disabling of the channels
specified by DCHAN[6:0]. When CHDIS is set high, the channel selected by
DCHAN[6:0] is disabled. Data in timeslots associated with the specified
channel is set to FDATA[7:0] in the Idle Time-slot Fill Data register. When
CHDIS is set low, the channel specified by DCHAN[6:0] operates normally.
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Register 0x480 : TCAS Link #0 Configuration
Bit
Type
Function
Default
Bit 31
to
Bit 16
Unused
XXXXH
Bit 15
Unused
X
Bit 14
Unused
X
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
Bit 8
Unused
X
Bit 7
Unused
X
Bit 6
Unused
X
Bit 5
Unused
X
Bit 4
Unused
X
Bit 3
Unused
X
Bit 2
R/W
BSYNC
0
Bit 1
R/W
E1
0
Bit 0
R/W
CEN
0
This register configures operational modes of transmit link #0 (TD[0] / TCLK[0]).
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
CEN:
The channelise enable bit (CEN) configures transmit link #0 for channelised
operation. TCLK[0] is held quiescent during the T1 framing bit or the E1
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framing byte. Thus, on the first rising edge of TCLK[0] after the extended
quiescent period, a downstream block can sample the m.s.b. of time-slot 1.
When CEN is set low, link #0 is unchannelised and the E1 register bit is
ignored. TCLK[0] is gapped during non-data bytes. The choice between
treating all data bits as a contiguous stream with arbitrary byte alignment or
byte aligned to gaps in TCLK[0] is controlled by the BSYNC bit.
E1:
The E1 frame structure select bit (E1) configures link #0 for channelised E1
operation when CEN is set high. TCLK[0] is held quiescent during the FAS
and NFAS framing bytes. The most significant bit of time-slot 1 is placed on
TD[0] on the last falling edge of TCLK[0] ahead of the extended quiescent
period. Link data is present at time-slots 1 to 31. When E1 is set low and
CEN is set high, link #0 is configured for channelised T1 operation. TCLK[0]
is held quiescent during the framing bit. The m.s.b. of time-slot 1 is placed on
TD[0] on the last falling edge of TCLK[0] ahead of the extended quiescent
period. Link data is present at time-slots 1 to 24. E1 is ignored when CEN is
set low.
BSYNC:
The byte synchronisation enable bit (BSYNC) controls the interpretation of
gaps in TCLK[0] when link #0 is in unchannelised mode (CEN set low).
When BSYNC is set high, the data bit on TD[0] clocked in by a downstream
device on the first rising edge of TCLK[0] after an extended quiescent period
is considered to be the most significant bit of a data byte. When BSYNC is
set quiescent , gaps in TCLK[0] carry no special significance. BSYNC is
ignored when CEN is set high.
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Register 0x484-0x488 : TCAS Link #1 to Link #2 Configuration
Bit
Type
Function
Default
Bit 31
to
Bit 16
Unused
XXXXH
Bit 15
Unused
X
Bit 14
Unused
X
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
Bit 8
Unused
X
Bit 7
Unused
X
Bit 6
Unused
X
Bit 5
Unused
X
Bit 4
Unused
X
Bit 3
Unused
X
Bit 2
R/W
BSYNC
0
Bit 1
R/W
E1
0
Bit 0
R/W
CEN
0
This register set configures operational modes of transmit link #1 to link # 2
(TD[n] / TCLK[n]; where 1 £ n £ 2).
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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CEN:
The channelise enable bit (CEN) configures the corresponding transmit link
for channelised operation. TCLK[n] is held quiescent during the T1 framing
bit or the E1 framing byte. Thus, on the first rising edge of TCLK[n] after the
extended quiescent period, a downstream block can sample the m.s.b. of
time-slot 1. When CEN is set low, the corresponding link is unchannelised
and the E1 register bit is ignored. TCLK[n] is gapped during non-data bytes.
The choice between treating all data bits as a contiguous stream with
arbitrary byte alignment or byte aligned to gaps in TCLK[n] is controlled by
the BSYNC bit.
E1:
The E1 frame structure select bit (E1) configures the corresponding link for
channelised E1 operation when CEN is set high. TCLK[n] is held quiescent
during the FAS and NFAS framing bytes. The most significant bit of time-slot
1 is placed on TD[n] on the last falling edge of TCLK[n] ahead of the
extended quiescent period. Link data is present at time-slots 1 to 31. When
E1 is set low and CEN is set high, the corresponding link is configured for
channelised T1 operation. TCLK[n] is held quiescent during the framing bit.
The m.s.b. of time-slot 1 is placed on TD[n] on the last falling edge of
TCLK[n] ahead of the extended quiescent period. Link data is present at
time-slots 1 to 24. E1 is ignored when CEN is set low.
BSYNC:
The byte synchronisation enable bit (BSYNC) controls the interpretation of
gaps in TCLK[n] when the corresponding link is in unchannelised mode (CEN
set low). When BSYNC is set high, the data bit on TD[n] clocked in by a
downstream device on the first rising edge of TCLK[n] after an extended
quiescent period is considered to be the most significant bit of a data byte.
When BSYNC is set low, gaps in TCLK[n] carry no special significance.
BSYNC is ignored when CEN is set high.
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Register 0x48C : TCAS Link #3 Configuration
Bit
Type
Function
Default
Bit 31
to
Bit 16
Unused
XXXXH
Bit 15
Unused
X
Bit 14
Unused
X
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
Bit 8
Unused
X
Bit 7
Unused
X
Bit 6
Unused
X
Bit 5
Unused
X
Bit 4
Unused
X
Bit 3
Unused
X
Bit 2
Unused
0
Bit 1
R/W
E1
0
Bit 0
R/W
CEN
0
This register set configures operational modes of transmit link #3.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
CEN:
The channelise enable bit (CEN) configures transmit link #3 for channelised
operation. TCLK[3] is held quiescent during the T1 framing bit or the E1
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framing byte. Thus, on the first rising edge of TCLK[3] after the extended
quiescent period, a downstream device can sample the m.s.b. of time-slot 1.
When CEN is set low, link #3 is unchannelised and the E1 register bit is
ignored. TCLK[3] is gapped during non-data bytes. All data bits are treated
as a contiguous stream with arbitrary byte alignment.
E1:
The E1 frame structure select bit (E1) configures link #3 for channelised E1
operation when CEN is set high. TCLK[3] is held quiescent during the FAS
and NFAS framing bytes. The most significant bit of time-slot 1 is placed on
TD[3] on the last falling edge of TCLK[3] ahead of the extended quiescent
period. Link data is present at time-slots 1 to 31. When E1 is set low and
CEN is set high, link #3 is configured for channelised T1 operation. TCLK[3]
is held quiescent during the framing bit. The m.s.b. of time-slot 1 is placed on
TD[3] on the last falling edge of TCLK[3] ahead of the extended quiescent
period. Link data is present at time-slots 1 to 24. E1 is ignored when CEN is
set low.
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Register 0x490-0x4FC : TCAS Link #4 to Link #31 Configuration
Bit
Type
Function
Default
Bit 31
to
Bit 16
Unused
XXXXH
Bit 15
Unused
X
Bit 14
Unused
X
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
Bit 8
Unused
X
Bit 7
Unused
X
Bit 6
Unused
X
Bit 5
Unused
X
Bit 4
Unused
X
Bit 3
Unused
X
Bit 2
Unused
0
Bit 1
R/W
E1
0
Bit 0
R/W
CEN
0
This register set configures operational modes of transmit link #4 to link # 31
(TD[n] / TCLK[n]; where 4 £ n £ 31 ).
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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CEN:
The channelise enable bit (CEN) configures the corresponding transmit link
for channelised operation. TCLK[n] is held quiescent during the T1 framing
bit or the E1 framing byte. Thus, on the first rising edge of TCLK[n] after the
extended quiescent period, a downstream device can sample the m.s.b. of
time-slot 1. When CEN is set low, the corresponding link is unchannelised
and the E1 register bit is ignored. TCLK[n] is gapped during non-data bytes.
All data bits are treated as a contiguous stream with arbitrary byte alignment.
E1:
The E1 frame structure select bit (E1) configures the corresponding link for
channelised E1 operation when CEN is set high. TCLK[n] is held quiescent
during the FAS and NFAS framing bytes. The most significant bit of time-slot
1 is placed on TD[n] on the last falling edge of TCLK[n] ahead of the
extended quiescent period. Link data is present at time-slots 1 to 31. When
E1 is set low and CEN is set high, the corresponding link is configured for
channelised T1 operation. TCLK[n] is held quiescent during the framing bit.
The m.s.b. of time-slot 1 is placed on TD[n] on the last falling edge of
TCLK[n] ahead of the extended low period. Link data is present at time-slots
1 to 24. E1 is ignored when CEN is set low.
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Register 0x500 : PMON Status
Bit
Type
Function
Default
Bit 31
to
Bit 16
Unused
XXXXH
Bit 15
Unused
X
Bit 14
Unused
X
Bit 13
Unused
X
Bit 12
Unused
X
Bit 11
Unused
X
Bit 10
Unused
X
Bit 9
Unused
X
Bit 8
Unused
X
Bit 7
Unused
X
Bit 6
Unused
X
Bit 5
R
C2DET
X
Bit 4
R
C1DET
X
Bit 3
R
UFDET
X
Bit 2
R
OFDET
X
Bit 1
Unused
X
Bit 0
Unused
X
This register contains status information indicating whether a non-zero count has
been latched in the count registers.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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OFDET:
The overflow detect bit (OFDET) indicates the status of the PMON Receive
FIFO Overflow Count register. OFDET is set high when overflow events have
occurred during the latest PMON accumulation interval. OFDET is set low if
no overflow events are detected.
UFDET:
The underflow detect bit (UFDET) indicates the status of the PMON Transmit
FIFO Underflow Count register. UFDET is set high when underflow events
have occurred during the latest PMON accumulation interval. UFDET is set
low if no underflow events are detected.
C1DET:
The configurable event #1 detect bit (C1DET) indicates the status of the
PMON Configurable Count #1 register. C1DET is set high when selected
events have occurred during the latest PMON accumulation interval. C1DET
is set low if no selected events are detected.
C2DET:
The configurable event #2 detect bit (C2DET) indicates the status of the
PMON Configurable Count #2 register. C2DET is set high when selected
events have occurred during the latest PMON accumulation interval. C2DET
is set low if no selected events are detected.
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Register 0x504 : PMON Receive FIFO Overflow Count
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R
OF[15]
X
Bit 14
R
OF[14]
X
Bit 13
R
OF[13]
X
Bit 12
R
OF[12]
X
Bit 11
R
OF[11]
X
Bit 10
R
OF[10]
X
Bit 9
R
OF[9]
X
Bit 8
R
OF[8]
X
Bit 7
R
OF[7]
X
Bit 6
R
OF[6]
X
Bit 5
R
OF[5]
X
Bit 4
R
OF[4]
X
Bit 3
R
OF[3]
X
Bit 2
R
OF[2]
X
Bit 1
R
OF[1]
X
Bit 0
R
OF[0]
X
This register reports the number of receive FIFO overflow events in the previous
accumulation interval.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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OF[15:0]:
The OF[15:0] bits reports the number of receive FIFO overflow events that
have been detected since the last time this register was polled. This register
is polled by writing to the FREEDM-32 Master Clock / BERT Activity Monitor
and Accumulation Trigger register. The write access transfers the internally
accumulated error count to the FIFO overflow register and simultaneously
resets the internal counter to begin a new cycle of error accumulation.
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Register 0x508 : PMON Receive FIFO Underflow Count
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R
UF[15]
X
Bit 14
R
UF[14]
X
Bit 13
R
UF[13]
X
Bit 12
R
UF[12]
X
Bit 11
R
UF[11]
X
Bit 10
R
UF[10]
X
Bit 9
R
UF[9]
X
Bit 8
R
UF[8]
X
Bit 7
R
UF[7]
X
Bit 6
R
UF[6]
X
Bit 5
R
UF[5]
X
Bit 4
R
UF[4]
X
Bit 3
R
UF[3]
X
Bit 2
R
UF[2]
X
Bit 1
R
UF[1]
X
Bit 0
R
UF[0]
X
This register reports the number of transmit FIFO underflow events in the
previous accumulation interval.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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UF[15:0]:
The UF[15:0] bits reports the number of transmit FIFO underflow events that
have been detected since the last time this register was polled. This register
is polled by writing to the FREEDM-32 Master Clock / BERT Activity Monitor
and Accumulation Trigger register. The write access transfers the internally
accumulated error count to the FIFO underflow register and simultaneously
resets the internal counter to begin a new cycle of error accumulation.
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Register 0x50C : PMON Configurable Count #1
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R
C1[15]
X
Bit 14
R
C1[14]
X
Bit 13
R
C1[13]
X
Bit 12
R
C1[12]
X
Bit 11
R
C1[11]
X
Bit 10
R
C1[10]
X
Bit 9
R
C1[9]
X
Bit 8
R
C1[8]
X
Bit 7
R
C1[7]
X
Bit 6
R
C1[6]
X
Bit 5
R
C1[5]
X
Bit 4
R
C1[4]
X
Bit 3
R
C1[3]
X
Bit 2
R
C1[2]
X
Bit 1
R
C1[1]
X
Bit 0
R
C1[0]
X
This register reports the number events, selected by the FREEDM-32 Master
Performance Monitor Control register, that occurred in the previous accumulation
interval.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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C1[15:0]:
The C1[15:0] bits reports the number of selected events that have been
detected since the last time this register was polled. This register is polled by
writing to the FREEDM-32 Master Clock / BERT Activity Monitor and
Accumulation Trigger register. The write access transfers the internally
accumulated error count to the configurable count #1 register and
simultaneously resets the internal counter to begin a new cycle of event
accumulation.
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Register 0x510 : PMON Configurable Count #2
Bit
Type
Bit 31
to
Bit 16
Function
Default
Unused
XXXXH
Bit 15
R
C2[15]
X
Bit 14
R
C2[14]
X
Bit 13
R
C2[13]
X
Bit 12
R
C2[12]
X
Bit 11
R
C2[11]
X
Bit 10
R
C2[10]
X
Bit 9
R
C2[9]
X
Bit 8
R
C2[8]
X
Bit 7
R
C2[7]
X
Bit 6
R
C2[6]
X
Bit 5
R
C2[5]
X
Bit 4
R
C2[4]
X
Bit 3
R
C2[3]
X
Bit 2
R
C2[2]
X
Bit 1
R
C2[1]
X
Bit 0
R
C2[0]
X
This register reports the number events, selected by the FREEDM-32 Master
Performance Monitor Control register, that occurred in the previous accumulation
interval.
Note
This register is not byte addressable. Writing to this register modifies all the bits
in the register. Byte selection using byte enable signals (CBEB[3:0]) are not
implemented. However, when all four byte enables are negated, no access is
made to this register.
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C2[15:0]:
The C2[15:0] bits reports the number of selected events that have been
detected since the last time this register was polled. This register is polled by
writing to the FREEDM-32 Master Clock / BERT Activity Monitor and
Accumulation Trigger register. The write access transfers the internally
accumulated error count to the configurable count #2 register and
simultaneously resets the internal counter to begin a new cycle of event
accumulation.
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PCI CONFIGURATION REGISTER DESCRIPTION
PCI configuration registers are implemented by the PCI Interface. These
registers can only be accessed when the PCI Interface is a target and a
configuration cycle is in progress as indicated using the IDSEL input.
Notes on PCI Configuration Register Bits:
1. Writing values into unused register bits has no effect. However, to ensure
software compatibility with future, feature-enhanced versions of the product,
unused register bits must be written with logic zero. Reading back unused
bits can produce either a logic one or a logic zero; hence unused register bits
should be masked off by software when read.
2. Except where noted, all configuration bits that can be written into can also be
read back. This allows the processor controlling the FREEDM-32 to
determine the programming state of the block.
3. Writable PCI configuration register bits are cleared to logic zero upon reset
unless otherwise noted.
4. Writing into read-only PCI configuration register bit locations does not affect
FREEDM-32 operation unless otherwise noted.
5. Certain register bits are reserved. These bits are associated with megacell
functions that are unused in this application. To ensure that the FREEDM-32
operates as intended, reserved register bits must only be written with their
default values. Similarly, writing to reserved registers should be avoided.
11.1 PCI Configuration Registers
PCI configuration registers can only be accessed by the PCI host. For each
register description below, the hexadecimal register number indicates the PCI
offset.
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Register 0x00 : Vendor Identification/Device Identification
Bit
Type
Function
Default
Bit 31
to
Bit 16
R
DEVID[15:0]
7364H
Bit 15
to
Bit 0
R
VNDRID[15:0]
11F8H
VNDRID[15:0]:
The VNDRID[15:0] bits identifies the manufacturer of the device. Valid vendor
identifiers are allocated by the PCI SIG.
DEVID[15:0]:
The DEVID[15:0] bits define the particular device. Valid device identifiers will
be specified by PMC-Sierra. The default value of DEVID[15:0] is that of the
FREEDM-32 device.
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Register 0x04 : Command/Status
Bit
Type
Function
Default
Bit 31
R/W
PERR
0
Bit 30
R/W
SERR
0
Bit 29
R/W
MABT
0
Bit 28
R/W
RTABT
0
Bit 27
R/W
TABT
0
Bit 26
R
DVSLT[1]
0
Bit 25
R
DVSLT[0]
1
Bit 24
R/W
DPR
0
Bit 23
R
FBTBE
1
Bit 22
to
Bit 16
R
Reserved
00H
Bit 15
to
Bit 10
R
Reserved
00H
Bit 9
R
FBTBEN
0
Bit 8
R/W
SERREN
0
Bit 7
R
ADSTP
0
Bit 6
R/W
PERREN
0
Bit 5
R
VGASNP
0
Bit 4
R
MWAI
0
Bit 3
R
SPCEN
0
Bit 2
R/W
MSTREN
0
Bit 1
R/W
MCNTRL
0
Bit 0
R
IOCNTRL
0
The lower 16 bits of this register make up the Command register which provides
basic control over the GPIC's ability to respond to PCI accesses. When a 0 is
written to all bits in the command register, the GPIC is logically disconnected
from the PCI bus for all accesses except configuration accesses. The upper 16-
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bits is used to record status information for PCI bus related events. Reads to the
status portion of this register behave normally. Writes are slightly different in that
bits can be reset, but not set. A bit is reset whenever the register is written, and
the data in the corresponding bit location is a 1.
IOCNTRL:
When IOCNTRL is set to zero, the GPIC will not respond to PCI bus I/O
accesses.
MCNTRL:
When MCNTRL is set to one, the GPIC will respond to PCI bus memory
accesses. Clearing MCNTRL disables memory accesses.
MSTREN:
When MSTREN is set to one, the GPIC can act as a Master. Clearing
MSTREN disables the GPIC from becoming a Master.
SPCEN:
The GPIC does not decode PCI special cycles. The SPCEN bit is forced low.
MWAI:
The GPIC does not generate memory-write-and-invalidate commands. The
MWAI bit is forced low.
VGASNP:
The GPIC is not a VGA device. The VGASNP bit is forced low.
PERREN:
When the PERREN bit is set to one, the GPIC can report parity errors.
Clearing the PERREN bit causes the GPIC to ignore parity errors.
ADSTP:
The GPIC does not perform address and data stepping. The ADSTP bit is
forced low.
SERREN:
When the SERREN bit is set high, the GPIC can drive the SERRB line.
Clearing the SERREN bit disables the SERRB line. SERREN and PERREN
must be set to report an address parity error.
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FBTBEN:
As a master, the GPIC does not generate fast back-to-back cycles to different
devices. This bit is forced low.
The upper 16-bits make up the PCI Status field. The status field tracks the status
of PCI bus related events. Reads to this register behave normally. Writes are
slightly different in that bits can be reset, but not set. A bit is reset whenever the
register is written, and the data in the corresponding bit location is a one.
FBTBE:
The FBTBE bit is hardwired to one to indicate the GPIC supports fast backto-back transactions with other targets.
DPR:
The Data Parity Reported (DPR) bit is set high if the GPIC is an initiator and
asserts or detects a parity error on the PERRB signal while the PERREN bit
is set in the Command register. The DPR bit is cleared by the PCI Host.
DVSLT[1:0]:
The Device Select Timing (DEVSLT) bits specify the allowable timings for the
assertion of DEVSELB by the GPIC as a target. These are encoded as 00B
for fast, 01B for medium, 10B for slow and 11B is not used. The GPIC allows
for medium timing.
TABT:
The Target Abort (TABT) bit is set high by the GPIC when as a target, it
terminates a transaction with a target abort. The TABT bit is cleared by the
PCI Host.
RTABT:
The Received Target Abort (RTABT) bit is set high by the GPIC when as an
initiator, its transaction is terminated by a target abort. The RTABT bit is
cleared by the PCI Host.
MABT:
The Master Abort (MABT) bit is set high by the GPIC when as an initiator, its
transaction is terminated by a master abort and a special cycle was not in
progress. The MABT bit is cleared by the PCI Host.
SERR:
The System Error (SERR) bit is set high whenever the GPIC asserts the
SERRB output. The SERR bit is cleared by the PCI Host.
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PERR:
The Parity Error (PERR) bit is set high whenever the GPIC detects a parity
error, even if parity error handling is disabled by clearing PERREN in the
Command register. The PERR bit is cleared by the PCI Host.
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Register 0x08 : Revision Identifier/Class Code
Bit
Type
Function
Default
Bit 31
to
Bit 24
R
CCODE[23:16]
02H
Bit 23
to
Bit 16
R
CCODE[15:8]
80H
Bit 15
to
Bit 8
R
CCODE[7:0]
00H
Bit 7
to
Bit 0
R
REVID[7:0]
01H
REVID[7:0]:
The Revision Identifier (REVID[7:0]) bits specify a device specific revision
identifier and are chosen by PMC-Sierra.
CCODE[23:0]:
The class code (CCODE[23:0]) bits are divided into three groupings:
CCODE[23:16] define the base class of the device, CCODE[15:8] define the
sub-class of the device and CCODE[7:0] specify a register specific
programming interface.
Note:
Base Class Code:
02H
Network Controller
Sub-Class Code:
80H
Other Controllers
Register Class Code:
00H
None defined.
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Register 0x0C : Cache Line Size/Latency Timer/Header Type
Bit
Type
Function
Default
Bit 31
to
Bit 24
R
Reserved
00H
Bit 23
R
MLTFNC
0
Bit 22
to
Bit 16
R
HDTYPE[6:0]
00H
Bit 15
to
Bit 8
R/W
LT[7:0]
00H
Bit 7
to
Bit 0
R/W
CLSIZE
00H
CLSIZE[7:0]:
The Cache Line Size (CLSIZE[7:0]) bits specify the size of the system
cacheline in units of dwords. The GPIC uses this value to determine the type
of read command to issue in a Master Read transfer. If the transfer size is
equal to one, the GPIC will issue a Memory Read command. If the transfer
size is equal to or less than the CLSIZE, the GPIC will issue a Memory Read
Line command. For transfers larger than CLSIZE, the GPIC issues a
Memory Read Multiple command.
LT[7:0]:
The Latency Timer (LT[7:0]) bits specify in units of the PCI clock, the value of
the Latency Timer for the GPIC. At reset the value is zero.
HDTYPE[6:0]:
The Header Type (HDTYPE[7:0]) bits specify the layout of the base address
registers. Only the 00H encoding is supported.
MLTFNC:
The Multi-Function (MLTFNC) bit specifies if the GPIC supports multiple PCI
functions. If this bit is set low, the device only supports one function and if the
bit is set high, the device supports multi-functions. The MLTFNC bit is set low
to indicate the GPIC only supports one PCI function.
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Register 0x10 : CBI Memory Base Address Register
Bit
Type
Function
Default
Bit 31
to
Bit 12
R/W
BSAD[27:8]
00000H
Bit 11
to
Bit 4
R
BSAD[7:0]
00H
Bit 3
R
PRFTCH
0
Bit 2
R
TYPE[1]
0
Bit 1
R
TYPE[0]
0
Bit 0
R
MSI
0
The GPIC supports memory mapping only. At boot-up the internal registers
space is mapped to memory space. The device driver can disable memory space
through the PCI Configuration Command register.
MSI:
MSI is forced low to indicate that the internal registers map into memory
space.
TYPE[1:0]:
The TYPE field indicates where the internal registers can be mapped. The
encoding 00B indicates the registers may be located anywhere in the 32 bit
address space, 01B indicates that the registers must be mapped below 1
Meg in memory space, 10B indicates the base register is 64 bits and the
encoding 11B is reserved.
The TYPE field is set to 00B to indicate that the CBI registers can be mapped
anywhere in the 32 bit address space.
PRFTCH:
The Prefetchable (PRFTCH) bit is set if there are no side effects on reads
and data is returned on all the lanes regardless of the byte enables.
Otherwise the bit is cleared. TSBs contain registers, such as interrupt status
registers, in which bits are cleared on a read. If the PCI Host is caching data
there is a possibility an interrupt status could be lost if data is prefetched, but
the cache is flushed and the data is not used. The PRFTCH bit is forced low
to indicate that prefetching of data is not supported for internal registers.
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BSAD[27:0]:
The Base Address (BSAD[27:0]) bits defines the size and location of the
memory space required for the CBI registers. The BSAD[27:0] bits
correspond to the most significant 28 bits of the PCI address space.
The size of the address space required can be determined by writing all ones to
Base Address register and then reading from it. By scanning the returned value
from the least significant bit upwards, the size of the required address space can
be determined. The binary weighted value of the first one bit found (after the
configuration bits) indicates the required amount of space. The BSAD[7:0] bits
are forced low to indicate that the CBI registers require 4K bytes of memory
space.
After determining the memory requirements of the CBI registers, the PCI Host
can map them to its desired location by modifying the BSAD[27:8] bits in the
Base Address register.
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Register 0x3C : Interrupt Line / Interrupt Pin / MIN_GNT / MAX_LAT
Bit
Type
Function
Default
Bit 31
to
Bit 24
R
MAXLAT[7:0]
0FH
Bit 23
to
Bit 16
R
MINGNT[7:0]
05H
Bit 15
to
Bit 8
R
INTPIN[7:0]
01H
Bit 7
to
Bit 0
R/W
INTLNE[7:0]
00H
INTLNE[7:0]:
The Interrupt Line (INTLNE[7:0]) field is used to indicate interrupt line routing
information. The values in this register are system specific and set by the PCI
Host.
INTPIN[7:0]:
The Interrupt Pin (INTPIN[7:0]) field is used to specify the interrupt pin the
GPIC uses. Since the GPIC will use INTAB on the PCI bus, the value in this
register is set to one.
MINGNT[7:0]:
The Minimum Grant (MINGNT[7:0]) field specifies how long of a burst period
the bus master needs (in increments of 250 nsec).
MAXLAT[7:0]:
The Maximum Latency (MAXLAT[7:0]) field specifies how often a bus master
needs access to the PCI bus (in increments of 250 nsec).
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TEST FEATURES DESCRIPTION
The FREEDM-32 also supports a standard IEEE 1149.1 five signal JTAG
boundary scan test port for use in board testing. All device inputs may be read
and all device outputs may be forced via the JTAG test port.
12.1 Test Mode Registers
Test mode registers are used to apply test vectors during production testing of
the FREEDM. Production testing is enabled by asserting the PMCTEST pin.
During production tests, FREEDM-32 registers are selected by the TA[11:0] pins.
The address of a register on TA[11:0] is identical to the PCI offset of that register
when production testing is disabled (PMCTEST low). Read accesses are
enabled by asserting TRDB low while write accesses are enabled by asserting
TWRB low. Test mode register data is conveyed on the TDAT[15:0] pins. Test
mode registers (as opposed to normal mode registers) are selected when
TA[11]/TRS is set high.
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Table 25 – Test Mode Register Memory Map
Address TA[10:0]
Register
0x000 - 0x7FC
Normal Mode Registers
0x800 - 0x83C
Reserved
0x840 - 0x87C
GPIC Test Registers
0x880 - 0x8FC
Reserved
0x900 - 0x9FC
RCAS Test Registers
0xA00 - 0xA3C
RHDL Test Registers
0xA40 - 0xA7C
Reserved
0xA80 - 0xAFC
RMAC Test Registers
0xB00 - 0xB7C
TMAC Test Registers
0xB80 - 0xBBC
THDL Test Registers
0xBC0 - 0xBFF
Reserved
0xC00 - 0xCFC
TCAS Test Registers
0xD00 - 0xD1C
PMON Test Registers
0xD20 - 0xFFF
Reserved
Notes on Test Mode Register Bits:
1. Writing values into unused register bits has no effect. However, to ensure
software compatibility with future, feature-enhanced versions of the product,
unused register bits must be written with logic zero. Reading back unused
bits can produce either a logic one or a logic zero; hence unused register bits
should be masked off by software when read.
2. Writable test mode register bits are not initialized upon reset unless otherwise
noted.
12.2 JTAG Test Port
The FREEDM-32 JTAG Test Access Port (TAP) allows access to the TAP
controller and the 4 TAP registers: instruction, bypass, device identification and
boundary scan. Using the TAP, device input logic levels can be read, device
outputs can be forced, the device can be identified and the device scan path can
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be bypassed. For more details on the JTAG port, please refer to the Operations
section.
Table 26 – Instruction Register
Length - 3 bits
Instructions
Selected Register
Instruction Code IR[2:0]
EXTEST
Boundary Scan
000
IDCODE
Identification
001
SAMPLE
Boundary Scan
010
BYPASS
Bypass
011
BYPASS
Bypass
100
STCTEST
Boundary Scan
101
BYPASS
Bypass
110
BYPASS
Bypass
111
12.2.1 Identification Register
Length - 32 bits
Version number - 1H
Part Number - 7364H
Manufacturer's identification code - 0CDH
Device identification - 173640CDH
12.2.2 Boundary Scan Register
The boundary scan register is made up of 268 boundary scan cells, divided into
input observation (in_cell), output (out_cell), and bi-directional (io_cell) cells.
These cells are detailed in the pages which follow. The first 32 cells form the ID
code register, and carry the code 173640CDH. The cells are arranged as
follows:
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Table 27 – Boundary Scan Chain
Pin/ Enable
Register Bit
Cell Type
Device I.D.
RD[0]
267
IN_CELL
0
RCLK[0]
266
IN_CELL
0
RD[1]
265
IN_CELL
0
RCLK[1]
264
IN_CELL
1
RD[2]
263
IN_CELL
0
RCLK[2]
262
IN_CELL
1
RD[3]
261
IN_CELL
1
RCLK[3]
260
IN_CELL
1
RD[4]
259
IN_CELL
0
RCLK[4]
258
IN_CELL
0
RD[5]
257
IN_CELL
1
RCLK[5]
256
IN_CELL
1
RD[6]
255
IN_CELL
0
RCLK[6]
254
IN_CELL
1
RD[7]
253
IN_CELL
1
RCLK[7]
252
IN_CELL
0
RD[8]
251
IN_CELL
0
RCLK[8]
250
IN_CELL
1
RD[9]
249
IN_CELL
0
RCLK[9]
248
IN_CELL
0
RD[10]
247
IN_CELL
0
RCLK[10]
246
IN_CELL
0
RD[11]
245
IN_CELL
0
RCLK[11]
244
IN_CELL
0
RD[12]
243
IN_CELL
1
RCLK[12]
242
IN_CELL
1
RD[13]
241
IN_CELL
0
RCLK[13]
240
IN_CELL
0
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Pin/ Enable
FRAME ENGINE AND DATA LINK MANAGER
Register Bit
Cell Type
Device I.D.
RD[14]
239
IN_CELL
1
RCLK[14]
238
IN_CELL
1
RD[15]
237
IN_CELL
0
RCLK[15]
236
IN_CELL
1
RD[16]
235
IN_CELL
-
RCLK[16]
234
IN_CELL
-
RD[17]
233
IN_CELL
-
RCLK[17]
232
IN_CELL
-
RD[18]
231
IN_CELL
-
RCLK[18]
230
IN_CELL
-
RD[19]
229
IN_CELL
-
RCLK[19]
228
IN_CELL
-
RD[20]
227
IN_CELL
-
RCLK[20]
226
IN_CELL
-
RD[21]
225
IN_CELL
-
RCLK[21]
224
IN_CELL
-
RD[22]
223
IN_CELL
-
RCLK[22]
222
IN_CELL
-
RD[23]
221
IN_CELL
-
RCLK[23]
220
IN_CELL
-
RD[24]
219
IN_CELL
-
RCLK[24]
218
IN_CELL
-
RD[25]
217
IN_CELL
-
RCLK[25]
216
IN_CELL
-
RD[26]
215
IN_CELL
-
RCLK[26]
214
IN_CELL
-
RD[27]
213
IN_CELL
-
RCLK[27]
212
IN_CELL
-
RD[28]
211
IN_CELL
-
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Pin/ Enable
FRAME ENGINE AND DATA LINK MANAGER
Register Bit
Cell Type
Device I.D.
RCLK[28]
210
IN_CELL
-
RD[29]
209
IN_CELL
-
RCLK[29]
208
IN_CELL
-
PCICLKO
207
OUT_CELL
-
PCICLKO_OEN
206
OUT_CELL
-
PCICLK
205
IN_CELL
-
GNTB
204
IN_CELL
-
REQB[0]
203
OUT_CELL
-
REQB_OEN[0]
202
OUT_CELL
-
AD[31]
201
IO_CELL
-
AD_OEN[31]
200
OUT_CELL
-
AD[30]
199
IO_CELL
-
AD_OEN[30]
198
OUT_CELL
-
AD[29]
197
IO_CELL
-
AD_OEN[29]
196
OUT_CELL
-
AD[28]
195
IO_CELL
-
AD_OEN[28]
194
OUT_CELL
-
AD[27]
193
IO_CELL
-
AD_OEN[27]
192
OUT_CELL
-
AD[26]
191
IO_CELL
-
AD_OEN[26]
190
OUT_CELL
-
AD[25]
189
IO_CELL
-
AD_OEN[25]
188
OUT_CELL
-
AD[24]
187
IO_CELL
-
AD_OEN[24]
186
OUT_CELL
-
CBEB[3]
185
IO_CELL
-
CBEB_OEN[3]
184
OUT_CELL
-
IDSEL
183
IN_CELL
-
AD[23]
182
IO_CELL
-
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Pin/ Enable
FRAME ENGINE AND DATA LINK MANAGER
Register Bit
Cell Type
Device I.D.
AD_OEN[23]
181
OUT_CELL
-
AD[22]
180
IO_CELL
-
AD_OEN[22]
179
OUT_CELL
-
AD[21]
178
IO_CELL
-
AD_OEN[21]
177
OUT_CELL
-
AD[20]
176
IO_CELL
-
AD_OEN[20]
175
OUT_CELL
-
AD[19]
174
IO_CELL
-
AD_OEN[19]
173
OUT_CELL
-
AD[18]
172
IO_CELL
-
AD_OEN[18]
171
OUT_CELL
-
AD[17]
170
IO_CELL
-
AD_OEN[17]
169
OUT_CELL
-
AD[16]
168
IO_CELL
-
AD_OEN[16]
167
OUT_CELL
-
CBEB[2]
166
IO_CELL
-
CBEB[2]_OEN
165
OUT_CELL
-
FREMEB
164
IO_CELL
-
FRAMEB_OEN
163
OUT_CELL
-
IRDYB
162
IO_CELL
-
IRDY_OEN
161
OUT_CELL
-
TRDYB
160
IO_CELL
-
TRDYB_OEN
159
OUT_CELL
-
DEVSELB
158
IO_CELL
-
DEVSELB_OEN
157
OUT_CELL
-
STOPB
156
IO_CELL
-
STOPB_OEN
155
OUT_CELL
-
LOCKB
154
IN_CELL
-
PERRB
153
IO_CELL
-
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Pin/ Enable
FRAME ENGINE AND DATA LINK MANAGER
Register Bit
Cell Type
Device I.D.
PERRB_OEN
152
OUT_CELL
-
SERRB
151
IO_CELL
-
SERRB_OEN
150
OUT_CELL
-
PAR
149
IO_CELL
-
PAR_OEN
148
OUT_CELL
-
CBEB[1]
147
IO_CELL
-
CBEB_OEN[1]
146
OUT_CELL
-
AD[15]
145
IO_CELL
-
AD_OEN[15]
144
OUT_CELL
-
AD[14]
143
IO_CELL
-
AD_OEN[14]
142
OUT_CELL
-
AD[13]
141
IO_CELL
-
AD_OEN[13]
140
OUT_CELL
-
AD[12]
139
IO_CELL
-
AD_OEN[12]
138
OUT_CELL
-
AD[11]
137
IO_CELL
-
AD_OEN[11]
136
OUT_CELL
-
AD[10]
135
IO_CELL
-
AD_OEN[10]
134
OUT_CELL
-
AD[9]
133
IO_CELL
-
AD_OEN[9]
132
OUT_CELL
-
AD[8]
131
IO_CELL
-
AD_OEN[8]
130
OUT_CELL
-
CBEB[0]
129
IO_CELL
-
CBEB_OEN[0]
128
OUT_CELL
-
AD[7]
127
IO_CELL
-
AD_OEN[7]
126
OUT_CELL
-
AD[6]
125
IO_CELL
-
AD_OEN[6]
124
OUT_CELL
-
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Pin/ Enable
FRAME ENGINE AND DATA LINK MANAGER
Register Bit
Cell Type
Device I.D.
AD[5]
123
IO_CELL
-
AD_OEN[5]
122
OUT_CELL
-
AD[4]
121
IO_CELL
-
AD_OEN[4]
120
OUT_CELL
-
AD[3]
119
IO_CELL
-
AD_OEN[3]
118
OUT_CELL
-
AD[2]
117
IO_CELL
-
AD_OEN[2]
116
OUT_CELL
-
AD[1]
115
IO_CELL
-
AD_OEN[1]
114
OUT_CELL
-
AD[0]
113
IO_CELL
-
AD_OEN[0]
112
OUT_CELL
-
RD[30]
111
IN_CELL
-
RCLK[30]
110
IN_CELL
-
RD[31]
109
IN_CELL
-
RCLK[31]
108
IN_CELL
-
PCIINTB
107
OUT_CELL
PCIINTB_OEN
106
OUT_CELL
-
PMCTEST
105
IN_CELL
-
RSTB
104
IN_CELL
-
TBCLK
103
OUT_CELL
-
TBCLK_OEN
102
OUT_CELL
-
TBD
101
IN_CELL
-
TCLK[31]
100
IN_CELL
-
TD[31]
99
OUT_CELL
-
TD_OEN[31]
98
OUT_CELL
-
TCLK[30]
97
IN_CELL
-
TD[30]
96
OUT_CELL
-
TD_OEN[30]
95
OUT_CELL
-
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Pin/ Enable
FRAME ENGINE AND DATA LINK MANAGER
Register Bit
Cell Type
Device I.D.
TCLK[29]
94
IN_CELL
-
TD[29]
93
OUT_CELL
-
TD_OEN[29]
92
OUT_CELL
-
TCLK[28]
91
IN_CELL
-
TD[28]
90
OUT_CELL
-
TD_OEN[28]
89
OUT_CELL
-
TCLK[27]
88
IN_CELL
-
TD[27]
87
OUT_CELL
-
TD_OEN[27]
86
OUT_CELL
-
TCLK[26]
85
IN_CELL
-
TD[26]
84
OUT_CELL
-
TD_OEN[26]
83
OUT_CELL
-
TCLK[25]
82
IN_CELL
-
TD[25]
81
OUT_CELL
-
TD_OEN[25]
80
OUT_CELL
-
TCLK[24]
79
IN_CELL
-
TD[24]
78
OUT_CELL
-
TD_OEN[24]
77
OUT_CELL
-
TCLK[23]
76
IN_CELL
-
TD[23]
75
OUT_CELL
-
TD_OEN[23]
74
OUT_CELL
-
TCLK[22]
73
IN_CELL
-
TD[22]
72
OUT_CELL
-
TD_OEN[22]
71
OUT_CELL
-
TCLK[21]
70
IN_CELL
-
TD[21]
69
OUT_CELL
-
TD_OEN[21]
68
OUT_CELL
-
TCLK[20]
67
IN_CELL
-
TD[20]
66
OUT_CELL
-
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Pin/ Enable
FRAME ENGINE AND DATA LINK MANAGER
Register Bit
Cell Type
Device I.D.
TD_OEN[20]
65
OUT_CELL
-
TCLK[19]
64
IN_CELL
-
TD[19]
63
OUT_CELL
-
TD_OEN[19]
62
OUT_CELL
-
TCLK[18]
61
IN_CELL
-
TD[18]
60
OUT_CELL
-
TD_OEN[18]
59
OUT_CELL
-
TCLK[17]
58
IN_CELL
-
TD[17]
57
OUT_CELL
-
TD_OEN[17]
56
OUT_CELL
-
TCLK[16]
55
IN_CELL
-
TD[16]
54
OUT_CELL
-
TD_OEN[16]
53
OUT_CELL
-
TCLK[15]
52
IN_CELL
-
TD[15]
51
OUT_CELL
-
TD_OEN[15]
50
OUT_CELL
-
TCLK[14]
49
IN_CELL
-
TD[14]
48
OUT_CELL
-
TD_OEN[14]
47
OUT_CELL
-
TCLK[13]
46
IN_CELL
-
TD[13]
45
OUT_CELL
-
TD_OEN[13]
44
OUT_CELL
-
TCLK[12]
43
IN_CELL
-
TD[12]
42
OUT_CELL
-
TD_OEN[12]
41
OUT_CELL
-
TCLK[11]
40
IN_CELL
-
TD[11]
39
OUT_CELL
-
TD_OEN[11]
38
OUT_CELL
-
TCLK[10]
37
IN_CELL
-
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Pin/ Enable
FRAME ENGINE AND DATA LINK MANAGER
Register Bit
Cell Type
Device I.D.
TD[10]
36
OUT_CELL
-
TD_OEN[10]
35
OUT_CELL
-
TCLK[9]
34
IN_CELL
-
TD[9]
33
OUT_CELL
-
TD_OEN[9]
32
OUT_CELL
-
TCLK[8]
31
IN_CELL
-
TD[8]
30
OUT_CELL
-
TD_OEN[8]
29
OUT_CELL
-
TCLK[7]
28
IN_CELL
-
TD[7]
27
OUT_CELL
-
TD_OEN[7]
26
OUT_CELL
-
TCLK[6]
25
IN_CELL
-
TD[6]
24
OUT_CELL
-
TD_OEN[6]
23
OUT_CELL
-
TCLK[5]
22
IN_CELL
-
TD[5]
21
OUT_CELL
-
TD_OEN[5]
20
OUT_CELL
-
TCLK[4]
19
IN_CELL
-
TD[4]
18
OUT_CELL
-
TD_OEN[4]
17
OUT_CELL
-
TCLK[3]
16
IN_CELL
-
TD[3]
15
OUT_CELL
-
TD_OEN[3]
14
OUT_CELL
-
TCLK[2]
13
IN_CELL
-
TD[2]
12
OUT_CELL
-
TD_OEN[2]
11
OUT_CELL
-
TCLK[1]
10
IN_CELL
-
TD[1]
9
OUT_CELL
-
TD_OEN[1]
8
OUT_CELL
-
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Pin/ Enable
FRAME ENGINE AND DATA LINK MANAGER
Register Bit
Cell Type
Device I.D.
TCLK[0]
7
IN_CELL
-
TD[0]
6
OUT_CELL
-
TD_OEN[0]
5
OUT_CELL
-
TDO
TAP Output
-
TDI
TAP Input
-
TCK
TAP Clock
-
TMS
TAP Input
-
TRSTB
TAP Input
-
SYSCLK
4
IN_CELL
-
RBD
3
OUT_CELL
-
RBD_OEN
2
OUT_CELL
-
RBCLK
1
OUT_CELL
-
RBCLK_OEN
0
OUT_CELL
-
Notes:
1. RD[0] is the first bit of the scan chain (closest to TDI).
2. Enable cell pinname_OEN, tristates pin pinname when set high.
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Figure 16 – Input Observation Cell (IN_CELL)
IDCODE
Scan Chain Out
INPUT
to internal
logic
Input
Pad
G1
G2
SHIFT-DR
I.D. Code bit
12
1 2 MUX
12
12
D
C
CLOCK-DR
Scan Chain In
In this diagram and those that follow, CLOCK-DR is equal to TCK when the
current controller state is SHIFT-DR or CAPTURE-DR, and unchanging
otherwise. The multiplexor in the center of the diagram selects one of four
inputs, depending on the status of select lines G1 and G2. The ID Code bit is as
listed in the table above.
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Figure 17 – Output Cell (OUT_CELL)
Scan Chain Out
G1
EXTEST
Output or Enable
from system logic
IDCODE
SHIFT-DR
I.D. code bit
1
1
G1
G2
1
1
1
1
2
2 MUX
2
2
Output or
Enable
MUX
D
D
C
C
CLOCK-DR
UPDATE-DR
Scan Chain In
Figure 18 – Bi-directional Cell (IO_CELL)
Scan Chain Out
G1
EXTEST
OUTPUT from
internal logic
IDCODE
SHIFT-DR
INPUT
from pin
I.D. code bit
1
12
1 2 MUX
12
12
MUX
1
G1
G2
D
C
INPUT
to internal
logic
OUTPUT
to pin
D
C
CLOCK-DR
UPDATE-DR
Scan Chain In
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Figure 19 – Layout of Output Enable and Bi-directional Cells
Scan Chain Out
OUTPUT ENABLE
from internal
logic (0 = drive)
OUT_CELL
Scan Chain In
Scan Chain Out
INPUT to
internal logic
OUTPUT from
internal logic
IO_CELL
I/O
PAD
Scan Chain In
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13
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FRAME ENGINE AND DATA LINK MANAGER
OPERATIONS
This section presents connection details to the PM6344 EQUAD and PM4388
TOCTL devices, and operating details for the JTAG boundary scan feature.
13.1 EQUAD Connections
The required connections between the PM6344 EQUAD and the FREEDM-32
are shown in the following table:
Table 28 – FREEDM–EQUAD Connections
FREEDM Pin
Direction
EQUAD Pin
RCLK[n]
¬
RDLCLK/RDLEOM[m]
RD[n]
¬
RDLSIG/RDLINT[m]
n.c.
¬
RFP[m]
n.c.
¬
RCLKO[m]
TCLK[n]
¬
TDLCLK/TDLURD[m]
TD[n]
®
TDLSIG/TDLINT[m]
The RFRACE1 and TFRACE1 bits in the EQUAD’s Datalink Options Register
should be set to ‘1’. In addition, the EQUAD’s Channel Select Registers should
be programmed such that timeslot 0 is disabled and timeslots 1 to 31 enabled.
13.2 TOCTL Connections
The required connections between the PM4388 TOCTAL and the FREEDM-32
are shown in the following table:
Table 29 – FREEDM–TOCTAL Connections
FREEDM Pin
Direction
TOCTAL Pin
RCLK[n]
¬
ICLK/ISIG[m]
RD[n]
¬
ID[m]
n.c.
¬
IFP[m]
TCLK[n]
¬
EFP/RCLK/ESIG[m]
TD[n]
®
ED[m]
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All 8 framers in the TOCTAL should be programmed to operate in “Clock Master:
NxDS0” mode in both the ingress and egress direction.
13.3 JTAG Support
The FREEDM-32 supports the IEEE Boundary Scan Specification as described
in the IEEE 1149.1 standards. The Test Access Port (TAP) consists of the five
standard pins, TRSTB, TCK, TMS, TDI and TDO used to control the TAP
controller and the boundary scan registers. The TRSTB input is the active low
reset signal used to reset the TAP controller. TCK is the test clock used to
sample data on input, TDI and to output data on output, TDO. The TMS input is
used to direct the TAP controller through its states. The basic boundary scan
architecture is shown below.
Figure 20 – Boundary Scan Architecture
Boundary Scan
Register
TDI
Device Identification
Register
Bypass
Register
Instruction
Register
and
Decode
Mux
DFF
TDO
Control
TMS
Test
Access
Port
Controller
Select
Tri-state Enable
TRSTB
TCK
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The boundary scan architecture consists of a TAP controller, an instruction
register with instruction decode, a bypass register, a device identification register
and a boundary scan register. The TAP controller interprets the TMS input and
generates control signals to load the instruction and data registers. The
instruction register with instruction decode block is used to select the test to be
executed and/or the register to be accessed. The bypass register offers a single
bit delay from primary input, TDI to primary output , TDO. The device
identification register contains the device identification code.
The boundary scan register allows testing of board inter-connectivity. The
boundary scan register consists of a shift register placed in series with device
inputs and outputs. Using the boundary scan register, all digital inputs can be
sampled and shifted out on primary output TDO. In addition, patterns can be
shifted in on primary input, TDI and forced onto all digital outputs.
TAP Controller
The TAP controller is a synchronous finite state machine clocked by the rising
edge of primary input, TCK. All state transitions are controlled using primary
input, TMS. The finite state machine is described below.
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Figure 21 – TAP Controller Finite State Machine
TRSTB=0
Test-Logic-Reset
1
0
1
1
Run-Test-Idle
1
Select-IR-Scan
Select-DR-Scan
0
0
0
1
1
Capture-IR
Capture-DR
0
0
Shift-IR
Shift-DR
1
1
0
1
1
Exit1-IR
Exit1-DR
0
0
Pause-IR
Pause-DR
0
1
Exit2-DR
0
1
0
0
Exit2-IR
1
1
Update-DR
1
0
0
Update-IR
1
0
All transitions dependent on input TMS
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Test-Logic-Reset
The test logic reset state is used to disable the TAP logic when the device is in
normal mode operation. The state is entered asynchronously by asserting input,
TRSTB. The state is entered synchronously regardless of the current TAP
controller state by forcing input, TMS high for 5 TCK clock cycles. While in this
state, the instruction register is set to the IDCODE instruction.
Run-Test-Idle
The run test/idle state is used to execute tests.
Capture-DR
The capture data register state is used to load parallel data into the test data
registers selected by the current instruction. If the selected register does not
allow parallel loads or no loading is required by the current instruction, the test
register maintains its value. Loading occurs on the rising edge of TCK.
Shift-DR
The shift data register state is used to shift the selected test data registers by
one stage. Shifting is from MSB to LSB and occurs on the rising edge of TCK.
Update-DR
The update data register state is used to load a test register's parallel output
latch. In general, the output latches are used to control the device. For
example, for the EXTEST instruction, the boundary scan test register's parallel
output latches are used to control the device's outputs. The parallel output
latches are updated on the falling edge of TCK.
Capture-IR
The capture instruction register state is used to load the instruction register with
a fixed instruction. The load occurs on the rising edge of TCK.
Shift-IR
The shift instruction register state is used to shift both the instruction register and
the selected test data registers by one stage. Shifting is from MSB to LSB and
occurs on the rising edge of TCK.
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Update-IR
The update instruction register state is used to load a new instruction into the
instruction register. The new instruction must be scanned in using the Shift-IR
state. The load occurs on the falling edge of TCK.
The Pause-DR and Pause-IR states are provided to allow shifting through the
test data and/or instruction registers to be momentarily paused.
Boundary Scan Instructions
The following is a description of the standard instructions. Each instruction
selects a serial test data register path between input, TDI and output, TDO.
BYPASS
The bypass instruction shifts data from input, TDI to output, TDO with one TCK
clock period delay. The instruction is used to bypass the device.
EXTEST
The external test instruction allows testing of the interconnection to other
devices. When the current instruction is the EXTEST instruction, the boundary
scan register is place between input, TDI and output, TDO. Primary device
inputs can be sampled by loading the boundary scan register using the
Capture-DR state. The sampled values can then be viewed by shifting the
boundary scan register using the Shift-DR state. Primary device outputs can be
controlled by loading patterns shifted in through input TDI into the boundary scan
register using the Update-DR state.
SAMPLE
The sample instruction samples all the device inputs and outputs. For this
instruction, the boundary scan register is placed between TDI and TDO. Primary
device inputs and outputs can be sampled by loading the boundary scan register
using the Capture-DR state. The sampled values can then be viewed by shifting
the boundary scan register using the Shift-DR state.
IDCODE
The identification instruction is used to connect the identification register
between TDI and TDO. The device's identification code can then be shifted out
using the Shift-DR state.
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STCTEST
The single transport chain instruction is used to test out the TAP controller and
the boundary scan register during production test. When this instruction is the
current instruction, the boundary scan register is connected between TDI and
TDO. During the Capture-DR state, the device identification code is loaded into
the boundary scan register. The code can then be shifted out output, TDO using
the Shift-DR state.
INTEST
The internal test instruction is used to exercise the device's internal core logic.
When this instruction is the current instruction, the boundary scan register is
connected between TDI and TDO. During the Update-DR state, patterns shifted
in on input, TDI are used to drive primary inputs. During the Capture-DR state,
primary outputs are sampled and loaded into the boundary scan register.
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FUNCTIONAL TIMING
14.1 Receive Link Input Timing
The timing relationship of the receive clock (RCLK[n]) and data (RD[n]) signals of
an unchannelised link is shown in Figure 22. The receive data is viewed as a
contiguous serial stream. There is no concept of time-slots in an unchannelised
link. Every eight bits are grouped together into a byte with arbitrary alignment.
The first bit received (B1 in Figure 22) is deemed the most significant bit of an
octet. The last bit received (B8) is deemed the least significant bit. Bits that are
to be processed by the FREEDM-32 are clocked in on the rising edge of
RCLK[n]. Bits that should be ignored (X in Figure 22) are squelched by holding
RCLK[n] quiescent. In Figure 22, the quiescent period is shown to be a low level
on RCLK[n]. A high level, effected by extending the high phase of the previous
valid bit, is also acceptable. Selection of bits for processing is arbitrary and is
not subject to any byte alignment nor frame boundary considerations.
Figure 22 – Unchannelised Receive Link Timing
RCLK[n]
RD[n]
B1 B2 B3 B4 X B5 X X X B6 B7 B8 B1 X
The timing relationship of the receive clock (RCLK[n]) and data (RD[n]) signals of
a channelised T1 link is shown in Figure 23. The receive data stream is a T1
frame with a single framing bit (F in Figure 23) followed by octet bound time-slots
1 to 24. RCLK[n] is held quiescent during the framing bit. The RD[n] data bit (B1
of TS1) clocked in by the first rising edge of RCLK[n] after the framing bit is the
most significant bit of time-slot 1. The RD[n] bit (B8 of TS24) clocked in by the
last rising edge of RCLK[n] before the framing bit is the least significant bit of
time-slot 24. In Figure 23, the quiescent period is shown to be a low level on
RCLK[n]. A high level, effected by extending the high phase of bit B8 of time-slot
TS24, is equally acceptable. In channelised T1 mode, RCLK[n] can only be
gapped during the framing bit. It must be active continuously at 1.544 MHz
during all time-slot bits. Time-slots can be ignored by setting the PROV bit in the
corresponding word of the receive channel provision RAM in the RCAS block to
low.
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Figure 23 – Channelised T1 Receive Link Timing
RCLK[n]
RD[n]
B7 B8 F B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3
TS 24
TS 1
TS 2
The timing relationship of the receive clock (RCLK[n]) and data (RD[n]) signals of
a channelised E1 link is shown in Figure 24. The receive data stream is an E1
frame with a singe framing byte (F1 to F8 in Figure 24) followed by octet bound
time-slots 1 to 31. RCLK[n] is held quiescent during the framing byte. The RD[n]
data bit (B1 of TS1) clocked in by the first rising edge of RCLK[n] after the
framing byte is the most significant bit of time-slot 1. The RD[n] bit (B8 of TS31)
clocked in by the last rising edge of RLCLK[n] before the framing byte is the least
significant bit of time-slot 31. In Figure 24, the quiescent period is shown to be a
low level on RCLK[n]. A high level, effected by extending the high phase of bit
B8 of time-slot TS31, is equally acceptable. In channelised E1 mode, RCLK[n]
can only be gapped during the framing byte. It must be active continuously at
2.048 MHz during all time-slot bits. Time-slots can be ignored by setting the
PROV bit in the corresponding word of the receive channel provision RAM in the
RCAS block to low.
Figure 24 – Channelised E1 Receive Link Timing
RCLK[n]
RD[n]
B6 B7 B8 F1 F2 F3 F4 F5 F6 F7 F8 B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4
TS 31
FAS / NFAS
TS 1
TS 2
14.2 Transmit Link Output Timing
The timing relationship of the transmit clock (TCLK[n]) and data (TD[n]) signals
of a unchannelised link is shown in Figure 25. The transmit data is viewed as a
contiguous serial stream. There is no concept of time-slots in an unchannelised
link. Every eight bits are grouped together into a byte with arbitrary byte
alignment. Octet data is transmitted from most significant bit (B1 in Figure 25)
and ending with the least significant bit (B8 in Figure 25). Bits are updated on
the falling edge of TCLK[n]. A transmit link may be stalled by holding the
corresponding TCLK[n] quiescent. In Figure 25, bits B5 and B2 are shown to be
stalled for one cycle while bit B6 is shown to be stalled for three cycles. In Figure
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25, the quiescent period is shown to be a low level on TCLK[n]. A high level,
effected by extending the high phase of the previous valid bit, is also acceptable.
Gapping of TCLK[n] can occur arbitrarily without regard to byte nor frame
boundaries.
Figure 25 – Unchannelised Transmit Link Timing
TCLK[n]
TD[n]
B1 B2 B3 B4
B5
B6
B7 B8 B1
B2
The timing relationship of the transmit clock (TCLK[n]) and data (TD[n]) signals
of a channelised T1 link is shown in Figure 26. The transmit data stream is a T1
frame with a single framing bit (F in Figure 26) followed by octet bound time-slots
1 to 24. TCLK[n] is held quiescent during the framing bit. The most significant
bit of each time-slot is transmitted first (B1 in Figure 26). The least significant bit
of each time-slot is transmitted last (B8 in Figure 26). The TD[n] bit (B8 of TS24)
before the framing bit is the least significant bit of time-slot 24. In Figure 26, the
quiescent period is shown to be a low level on TCLK[n]. A high level, effected by
extending the high phase of bit B8 of time-slot TS24, is equally acceptable. In
channelised T1 mode, TCLK[n] can only be gapped during the framing bit. It
must be active continuously at 1.544MHz during all time-slot bits. Time-slots that
are not provisioned to belong to any channel (PROV bit in the corresponding
word of the transmit channel provision RAM in the TCAS block set low) transmit
the contents of the Idle Fill Time-slot Data register.
Figure 26 – Channelised T1 Transmit Link Timing
TCLK[n]
TD[n]
B7 B8
TS 24
B1
F
B2 B3 B4 B5 B6 B7 B8 B1 B2 B3
TS 1
TS 2
The timing relationship of the transmit clock (TCLK[n]) and data (TD[n]) signals
of a channelised E1 link is shown in Figure 27. The transmit data stream is an
E1 frame with a singe framing byte (FAS/NFAS in Figure 27) followed by octet
bound time-slots 1 to 31. TCLK[n] is held quiescent during the framing byte.
The most significant bit of each time-slot is transmitted first (B1 in Figure 27).
The least significant bit of each time-slot is transmitted last (B8 in Figure 27).
The TD[n] bit (B8 of TS31) before the framing byte is the least significant bit of
time-slot 31. In Figure 27, the quiescent period is shown to be a low level on
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TCLK[n]. A high level, effected by extending the high phase of bit B8 of time-slot
31, is equally acceptable. In channelised E1 mode, TCLK[n] can only be gapped
during the framing byte. It must be active continuously at 2.048 MHz during all
time-slot bits. Time-slots that are not provisioned to belong to any channel
(PROV bit in the corresponding word of the transmit channel provision RAM in
the TCAS block set low) transmit the contents of the Idle Time-slot Fill Data
register.
Figure 27 – Channelised E1 Transmit Link Timing
TCLK[n]
TD[n]
B6 B7 B8
TS 31
B1
FAS / NFAS
B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4
TS 1
TS 2
14.3 PCI Interface
A PCI burst read cycle is shown In Figure 28. The cycle is valid for target and
initiator accesses. The target is responsible for incrementing the address during
the data burst. The 'T' symbol stands for a turn around cycle. A turn around
cycle is required on all signals which can be driven by more than one agent.
During Clock 1, the initiator drives FRAMEB to indicate the start of a cycle. It
also drives the address onto the AD[31:0] bus and drives the C/BEB[3:0] lines
with the read command. In the example below, the command would indicate a
burst read. The IRDYB, TRDYB and DEVSELB signals are in turnaround mode
(i.e. no agent is driving the signals for this clock cycle). This cycle on the PCI
bus is called the address phase.
During Clock 2, the initiator ceases to drive the AD[31:0] bus in order that the
target can drive it in the next cycle. The initiator also drives the C/BEB[3:0] lines
with the byte enables for the read data. IRDYB is driven active by the initiator to
indicate it is ready to accept the data transfer. All subsequent cycles on the PCI
bus are called data phases.
During Clock 3, the target claims the transaction by driving DEVSELB active. It
also places the first data word onto the AD[31:0] bus and drives TRDYB to
indicate to the initiator that the data is valid.
During Clock 4, the initiator latches in the first data word. The target negates
TRDYB to indicate to the initiator that it is not ready to transfer another data
word.
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During Clock 5, the target places the second data word onto the AD[31:0] bus
and drives TRDYB to indicate to the initiator that the data is valid.
During Clock 6, the initiator latches the second data word and negates IRDYB to
indicate to the target that it is not ready for the next transfer. The target shall
drive the third data word until the initiator accepts it.
During Clock 7, the initiator asserts IRDYB to indicate to the target it is ready for
the third data word. It also negates FRAMEB since this shall be the last transfer.
During Clock 8, the initiator latches in the last word and negates IRDYB. The
target, having seen FRAMEB negated in the last clock cycle, negates TRDYB
and DEVSELB. All of the above signals shall be driven to their inactive state in
this clock cycle, except for FRAMEB which shall be tri-stated. The target shall
stop driving the AD[31:0] bus and the initiator shall stop driving the C/BEB[3:0]
bus; this shall be the turnaround cycle for these signals.
Figure 28 – PCI Read Cycle
1
2
3
4
5
6
7
8
9
PCICLK
T
FRAMEB
AD[31:0]
Address
T
C/BEB[3:0]
Bus Cmd
Byte Enable
IRDYB
TRDYB
DEVSELB
Data 1
Data 2
Byte Enable
Data 3
T
Byte Enable
T
T
T
T
A PCI burst write transaction is shown in Figure 29. The cycle is valid for target
and initiator accesses. The target is responsible for incrementing the address for
the duration of the data burst. The 'T' symbol stands for a turn around cycle. A
turn around cycle is required on all signals which can be driven by more than one
agent.
During clock 1, the initiator drives FRAMEB to indicate the start of a cycle. It also
drives the address onto the AD[31:0] bus and drives the C/BEB[3:0] lines with
the write command (in the above example the command would indicate a burst
write). The IRDYB, TRDYB and DEVSELB signals are in turnaround mode (no
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agent is driving the signals for this clock cycle). This cycle on the PCI bus is
called the address phase.
During clock 2, the initiator ceases to drive the address onto the AD[31:0] bus
and starts driving the first data word. The initiator also drives the C/BEB[3:0]
lines with the byte enables for the write data. IRDYB is driven active by the
initiator to indicate it is ready to accept the data transfer. The target claims the
transaction by driving DEVSELB active and drives TRDYB to indicate to the
initiator that it is ready to accept the data. All subsequent cycles on the PCI bus
are called data phases.
During clock 3, the target latches in the first data word. The initiator starts to
drive the next data word onto the AD[31:0] lines.
During clock 4, the target latches in the second data word. Both the initiator and
the target indicate that they are not ready to transfer any more data by negating
the ready lines.
During clock 5, the initiator is ready to transfer the next data word so it drives the
AD[31:0] lines with the third data word and asserts IRDYB. The initiator negates
FRAMEB since this is the last data phase of this cycle. The target is still not
ready so a wait state shall be added.
During clock 6, the target is still not ready so another wait state is added.
During clock 7, the target asserts TRDYB to indicate that it is ready to complete
the transfer.
During clock 8, the target latches in the last word and negates TRDYB and
DEVSELB, having seen FRAMEB negated previously. The initiator negates
IRDYB. All of the above signals shall be driven to their inactive state in this clock
cycle except for FRAMEB which shall be tri-stated.
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Figure 29 – PCI Write Cycle
1
2
3
4
5
6
7
8
9
PCICLK
T
FRAMEB
AD[31:0]
C/BEB[3:0]
IRDYB
TRDYB
DEVSELB
Address Data 1
Data 2
Bus Cmd Byte En Byte En
Data 3
Byte Enable
T
T
T
T
T
The PCI Target Disconnect (Figure 30) illustrates the case when the target wants
to prematurely terminate the current cycle. Note, when the FREEDM-32 is the
target, it never prematurely terminates the current cycle.
A target can terminate the current cycle by asserting the STOPB signal to the
initiator. Whether data is transferred or not depends on the state of the ready
signals at the time that the target disconnects. If the FREEDM-32 is the initiator
and the target terminates the current access, the FREEDM-32 will retry the
access after two PCI bus cycles.
During clock 1, an access is in progress.
During clock 2, the target indicates that it wishes to disconnect by asserting
STOPB. Data may be transferred depending on the state of the ready lines.
During clock 3, the initiator negates FRAMEB to signal the end of the cycle.
During clock 4, the target negates STOPB and DEVSELB in response to the
FRAMEB signal being negated.
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Figure 30 – PCI Target Disconnect
1
2
3
4
5
6
PCICLK
T
FRAMEB
STOPB
DEVSELB
The PCI Target Abort Diagram (Figure 31) illustrates the case when the target
wants to abort the current cycle. Note, when the FREEDM-32 is the target, it
never aborts the current cycle. A target abort is an indication of a serious error
and no data is transferred.
A target can terminate the current cycle by asserting STOPB and negating
DEVSELB. If the FREEDM-32 is the initiator and the target aborts the current
access, the abort condition is reported to the PCI Host.
During clock 1, a cycle is in progress.
During clock 2, the target negates DEVSELB and TRDYB and asserts STOPB to
indicate an abort condition to the initiator.
During clock 3, the initiator negates FRAMEB in response to the abort request.
During clock 4, the target negates STOPB signal in response to the FRAMEB
signal being negated.
Figure 31 – PCI Target Abort
1
2
3
4
5
6
PCICLK
FRAMEB
T
TRDYB
STOPB
DEVSELB
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The PCI Bus Request Cycle Diagram (Figure 32) illustrates the case when the
initiator is requesting the bus from the bus arbiter.
When the FREEDM-32 is the initiator, it requests the PCI bus by asserting its
REQB output to the central arbiter. The arbiter grants the bus to the FREEDM32 by asserting the GNTB line. The FREEDM-32 will wait till both the FRAMEB
and IRDYB lines are idle before starting its access on the PCI bus. The arbiter
can remove the GNTB signal at any time, but the FREEDM-32 will complete the
current transfer before relinquishing the bus.
Figure 32 – PCI Bus Request Cycle
1
2
3
4
5
6
PCICLK
REQB
GNTB
FRAMEB
T
The PCI Initiator Abort Termination Diagram (Figure 33) illustrates the case when
the initiator aborts a transaction on the PCI bus.
An initiator may terminate a cycle if no target claims it within five clock cycles. A
target may not have responded because it was incapable of dealing with the
request or a bad address was generated by the initiator. IRDYB must be valid
one clock after FRAMEB is deasserted as in a normal cycle. When the
FREEDM-32 is the initiator and aborts the transaction, it reports the error
condition to the PCI Host.
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Figure 33 – PCI Initiator Abort Termination
1
2
3
4
5
6
7
PCICLK
T
FRAMEB
TRDYB
IRDYB
DEVSELB
T
T
T
The PCI Exclusive Lock Cycle Diagram (Figure 34) illustrates the case when the
current initiator locks the PCI bus. The FREEDM-32 will never initiate an lock,
but will behave appropriately when acting as a target.
During clock 1, the present initiator has gained access of the LOCKB signal and
the PCI bus. The first cycle of a locked access must be a read cycle. The
initiator asserts FRAMEB and drives the address of the target on the AD[31:0]
lines.
During clock 2, the present initiator asserts LOCKB to indicate to the target that a
locked cycle is in progress.
During clock 3, the target samples the asserted LOCKB signal and marks itself
locked. The data cycle has to complete in order for the lock to be maintained. If
for some reason the cycle was aborted, the initiator must negate LOCKB.
During clock 4, the data transfer completes and the target is locked.
During clock 6, another initiator may use the PCI bus but it cannot use the
LOCKB signal. If the other initiator attempts to access the locked target that it
did not lock, the target would reject the access.
During clock 7, the same initiator that locked this target accesses the target. The
initiator asserts FRAMEB and negates LOCKB to re-establish the lock.
During clock 8, the target samples LOCKB deasserted and locks itself.
During clock 9, the initiator does not want to continue the lock so it negates
LOCKB. The target samples LOCKB and FRAMEB deasserted it removes its
lock.
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Figure 34 – PCI Exclusive Lock Cycle
1
2
3
4
5
6
7
8
9
PCICLK
T
FRAMEB
AD[31:0]
LOCKB
IRDYB
TRDYB
DEVSELB
Address
Data
T
T
Address
T
Data
T
T
T
T
T
T
T
Fast back-to-back transactions are used by an initiator to conduct two
consecutive transactions on the PCI bus without the required idle cycle between
them. This can only occur if there is a guarantee that there will be no contention
between the initiator or targets involved in the two transactions. In the first case,
an initiator may perform fast back-to-back transactions if the first transaction is a
write and the second transaction is to the same target. All targets must be able
to decode the above transaction. In the second case, all of the targets on the
PCI bus support fast back-to-back transactions, as indicated in the PCI Status
configuration register. The FREEDM-32 only supports the first type of fast backto-back transactions and is shown in Figure 35.
During clock 1, the initiator drives FRAMEB to indicate the start of a cycle. It also
drives the address onto the AD[31:0] bus and drives the C/BEB[3:0] lines with
the write command. In this example the command would indicate a single write.
The IRDYB, TRDYB and DEVSELB signals are in turnaround mode and are not
being driven for this clock cycle. This cycle on the PCI bus is called the address
phase.
During clock 2, the initiator ceases to drive the address onto the AD[31:0] bus
and starts driving the data element. The initiator also drives the C/BEB[3:0] lines
with the byte enables for the write data. IRDYB is driven active by the initiator to
indicate that the data is valid.
The initiator negates FRAMEB since this the last data phase of this cycle. The
target claims the transaction by driving DEVSELB active and drives TRDYB to
indicate to the initiator that it is ready to accept the data.
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During clock 3, the target latches in the data element and negates TRDYB and
DEVSELB, having seen FRAMEB negated previously. The initiator negates
IRDYB and drives FRAMEB to start the next cycle. It also drives the address
onto the AD[31:0] bus and drives the C/BEB[3:0] lines with the write command.
In this example the command would indicate a burst write.
During clock 4, the initiator ceases to drive the address onto the AD[31:0] bus
and starts driving the first data element. The initiator also drives the C/BEB[3:0]
lines with the byte enables for the write data. IRDYB is driven active by the
initiator to indicate that the data is valid. The target claims the transaction by
driving DEVSELB active and drives TRDYB to indicate to the initiator that it is
ready to accept the data.
During clock 5, the initiator is ready to transfer the next data element so it drives
the AD[31:0] lines with the second data element. The initiator negates FRAMEB
since this is the last data phase of this cycle. The target accepts the first data
element and negates TRDYB to indicate its is not ready for the next data
element.
During clock 6, the target is still not ready so a wait state shall be added.
During clock 7, the target asserts TRDYB to indicate that it is ready to complete
the transfer.
During clock 8, the target latches in the last element and negates TRDYB and
DEVSELB, having seen FRAMEB negated previously. The initiator negates
IRDYB. All of the above signals shall be driven to their inactive state in this clock
cycle, except for FRAMEB which shall be tri-stated. The target stops driving the
AD[31:0] bus and the initiator stops driving the C/BEB[3:0] bus. This shall be the
turnaround cycle for these signals.
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Figure 35 – PCI Fast Back to Back
1
2
3
4
5
6
7
8
9
PCICLK
T
FRAMEB
AD[31:0]
C/BEB[3:0]
IRDYB
TRDYB
DEVSELB
Address
Data
Address
Data
Bus Cmd Byte En Bus Cmd
T
Data
T
Byte Enable
T
T
T
14.4 BERT Interface
The timing relationship between the receive link clock and data (RCLK[n] /
RD[n]) and the receive BERT port signals (RBCLK / RBD) is shown in Figure 36.
The selected RCLK[n] is placed on RBCLK after an asynchronous delay. The
selected receive link data (RD[n]) is sampled on the rising edge of the associated
RCLK[n] and transferred to RBD on the falling edge of RBCLK.
Figure 36 – Receive BERT Port Timing
RCLK[n]
RD[n]
B1 B2 B3 B4 X B5 X X
X B6 B7 B8 B1 X
RBCLK
RBD
B1 B2 B3
B4
B5
B6 B7 B8
B1
The timing relationship between the transmit link clock and data (TCLK[n] /
TD[n]) and the transmit BERT port signals (TBCLK / TBD) is shown in Figure 37.
TCLK[n] is shown to have an arbitrary gapping. When TCLK[n] is quiescent,
TBD is ignored (X in Figure 37). The selected TCLK[n] is buffered and placed on
TBCLK. The transmit BERT data (TBD) is sampled on the rising edge of the
TBCLK and transferred to the selected TD[n] on the falling edge of TCLK[n].
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Figure 37 – Transmit BERT Port Timing
TCLK[n]
TBCLK
TBD
TD[n]
B1 B2 B3 B4 X B5 X X X B6 B7 B8 B1 X B2
B1 B2 B3
B4
B5
B6 B7 B8
B1
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ABSOLUTE MAXIMUM RATINGS
Maximum rating are the worst case limits that the device can withstand without
sustaining permanent damage. They are not indicative of normal operating
conditions.
Table 30 – FREEDM-32 Absolute Maximum Ratings
Case Temperature under Bias
-40°C to +85°C
Storage Temperature
-40°C to +125°C
Supply Voltage (VDD)
-0.3V to +4.6V
Bias Voltage (VBIAS)
(VDD - 0.3) to +5.5V
Voltage on Any Pin
-0.3V to VBIAS + 0.3V
Static Discharge Voltage
±1000 V
Latch-Up Current
±100 mA
DC Input Current
±20 mA
Lead Temperature
+230°C
Absolute Maximum Junction
Temperature
+150°C
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D.C. CHARACTERISTICS
(TA = -40°C to +85°C, VDD = 3.3 V ±10%)
Table 31 – FREEDM-32 D.C. Characteristics
Symbol
Parameter
Min
Typ
Max
Units
Conditions
VDD
Power Supply
3.0
3.3
3.6
Volts
Note 5.
VBIAS
5V Bias Supply
VDD
5.0
5.5
Volts
Note 5.
VIL
PCI Input Low
Voltage
-0.2
0.8
Volts
Guaranteed Input LOW
Voltage for PCI inputs.
VIH
PCI Input High
Voltage
2.0
VBIAS Volts
Guaranteed Input HIGH
Voltage for PCI inputs.
VOL
Output or Bidirectional Low
Voltage
VOH
Output or Bidirectional High
Voltage
2.4
VT+
Schmitt Triggered
Input High Voltage
2.0
VT-
Schmitt Triggered
Input Low Voltage
-0.2
IILPU
Input Low Current
10
IIHPU
Input High Current
IIL
IIH
0.26
0.4
2.52
Volts
IOL = -4 mA for all outputs
except TBCLK, RBCLK,
RBD, PCICLKO, PCIINTB,
where IOL = -6 mA and
TD[2:0], where IOL = -8
mA. Notes 3, 5.
Volts
IOH = 4 mA for all outputs
except TBCLK, RBCLK,
RBD, PCICLKO, PCIINTB,
where IOH = 6 mA and
TD[2:0], where IOH = 8
mA. Notes 3, 5.
VBIAS Volts
0.8
Volts
45
100
µA
VIL = GND, Notes 1, 3, 5.
-10
0
+10
µA
VIH = VDD, Notes 1, 3
Input Low Current
-10
0
+10
µA
VIL = GND, Notes 2, 3
Input High Current
-10
0
+10
µA
VIH = VDD, Notes 2, 3
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Symbol
ISSUE 6
Parameter
Min
FRAME ENGINE AND DATA LINK MANAGER
Typ
Max
Units
Conditions
CIN
Input Capacitance
5
pF
Excludes package.
Package typically 2 pF.
Note 5.
COUT
Output
Capacitance
5
pF
All pins. Excludes
package. Package typically
2 pF. Note 5.
CIO
Bi-directional
Capacitance
5
pF
All pins. Excludes
package. Package typically
2 pF. Note 5.
LPIN
Pin Inductance
2
nH
All pins. Note 5.
IDDOP
Operating Current.
285
360.2 mA
VDD = 3.6V, Outputs
Unloaded. Aggregate link
clock rate = 64 MHz
Notes on D.C. Characteristics:
1. Input pin or bi-directional pin with internal pull-up resistor.
2. Input pin or bi-directional pin without internal pull-up resistor
3. Negative currents flow into the device (sinking), positive currents flow out of
the device (sourcing).
4. Input pin or bi-directional pin with internal pull-down resistor.
5. Typical values are given as a design aid. The product is not tested to the
typical values given in the data sheet.
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FREEDM-32 TIMING CHARACTERISTICS
(TA = -40°C to +85°C, VDD = 3.3 V ±10%, VBIAS = 5.0V ±10%)
Table 32 – FREEDM-32 Link Input (Figure 38, Figure 39)
Symbol
Description
Min
Max
Units
RCLK[31:0] Frequency (See Note 3)
1.542
1.546
MHz
RCLK[31:0] Frequency (See Note 4)
2.046
2.05
MHz
RCLK[2:0] Frequency (See Note 5)
52
MHz
RCLK[31:3] Frequency (See Note 5)
10
MHz
RCLK[31:0] Duty Cycle
40
60
%
SYSCLK Frequency
25
33
MHz
SYSCLK Duty Cycle
40
60
%
tSRD
RD[31:3] Set-Up Time
5
ns
tHRD
RD[31:3] Hold Time
5
ns
tSRD
RD[2:0] Set-Up Time
2
ns
tHRD
RD[2:0] Hold Time
2
ns
tSTBD
TBD Set-Up Time (See Note 6)
15
ns
tHTBD
TBD Hold Time
0
ns
Notes on Input Timing:
1. When a set-up time is specified between an input and a clock, the set-up
time is the time in nanoseconds from the 1.4 Volt point of the input to the 1.4
Volt point of the clock.
2. When a hold time is specified between an input and a clock, the hold time is
the time in nanoseconds from the 1.4 Volt point of the clock to the 1.4 Volt
point of the input.
3. Applicable only to channelised T1 links and measured between framing bits.
4. Applicable only to channelised E1 links and measured between framing
bytes.
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5. Applicable only to unchannelised links of any format and measured between
any two RCLK rising edges.
6. TBD set-up time is measured with a 20 pF load on TBCLK. The set-up time
increases by 1 ns for each 10 pF of extra load on TBCLK.
Figure 38 – Receive Link Input Timing
RCLK[n]
tS RD
tH RD
tS TBD
tH TBD
RD[n]
Figure 39 – BERT Input Timing
TBCLK
TBD
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Table 33 – FREEDM-32 Link Output (Figure 40, Figure 41)
Symbol
Description
Min
Max
Units
TCLK[31:0] Frequency (See Note 4)
1.542
1.546
MHz
TCLK[31:0] Frequency (See Note 5)
2.046
2.05
MHz
TCLK[2:0] Frequency (See Note 6)
52
MHz
TCLK[31:3] Frequency (See Note 6)
10
MHz
TCLK[31:0] Duty Cycle
40
60
%
tPTD
TCLK[2:0] Low to TD[2:0] Valid
3
15
ns
tPTD
TCLK[31:3] Low to TD[31:3] Valid
5
27
ns
tPRBD
RBCLK Low to RBD Valid
-5
5
ns
Notes on Output Timing:
1. Output propagation delay time is the time in nanoseconds from the 1.4 Volt
point of the reference signal to the 1.4 Volt point of the output.
2. Maximum and minimum output propagation delays are measured with a 50
pF load on all the outputs, except for PCI Bus outputs and TD[2:0] outputs.
For PCI Bus outputs, maximum output propagation delays are measured with
a 50 pF load while minimum output propagation delays are measured with a
0 pF load. For TD[2:0] outputs, propagation delays are measured with a 20
pF load. Maximum propagation delay for TD[2:0] increases by 1.0 ns for
each 10 pF of extra load.
3. Output propagation delays of signal outputs that are specified in relation to a
reference output are measured with a 50 pF load on both the signal output
and the reference output.
4. Applicable only to channelised T1 links and measured between framing bits.
5. Applicable only to channelised E1 links and measured between framing bytes.
6. Applicable only to unchannelised links of any format and measured between
any two TCLK rising edges.
7. Output tri-state delay is the time in nanoseconds from the 1.4 Volt point of the
reference signal to the point where the total current delivered through the
output is less than or equal to the leakage current.
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Figure 40 – Transmit Link Output Timing
TCLK[n]
tP TD
TD[n]
Figure 41 – BERT Output Timing
RBCLK
tP RBD
RBD
Table 34 – PCI Interface (Figure 42)
Symbol
Description
Min
PCICLK Frequency
Max
Units
33
MHz
60
%
PCICLK Duty Cycle
40
tSPCI
All PCI Input and Bi-directional Setup time to PCICLK
7
ns
tHPCI
All PCI Output and Bi-directional
Hold time to PCICLK
0
ns
tPPCI
PCICLK to all PCI Outputs Valid
2
tZPCI
All PCI Output PCICLK to Tri-state
tZNPCI
All PCI Output Tri-state from
PCICLK to active
11
ns
28
ns
2
PROPRIETARY AND CONFIDENTIAL TO PMC-SIERRA, INC., AND FOR ITS CUSTOMER’S INTERNAL USE
ns
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Figure 42 – PCI Interface Timing
PCICLK
tS
tH
PCI
PCI
PCI INPUT
tP
PCI
PCI OUTPUT
tZ
PCI TRISTATE
OUTPUT
PCI
Data Valid
tZN
PCI
PCI TRISTATE
OUTPUT
Data Valid
Table 35 – JTAG Port Interface (Figure 43)
Symbol
Description
Min
TCK Frequency
Max
Units
1
MHz
60
%
TCK Duty Cycle
40
tSTMS
TMS Set-up time to TCK
50
ns
tHTMS
TMS Hold time to TCK
50
ns
tSTDI
TDI Set-up time to TCK
50
ns
tHTDI
TDI Hold time to TCK
50
ns
tPTDO
TCK Low to TDO Valid
2
50
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Figure 43 – JTAG Port Interface Timing
TCK
tS TMS
tH TMS
tS TDI
tH TDI
TMS
TDI
TCK
tP TDO
TDO
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ORDERING AND THERMAL INFORMATION
Table 36 – FREEDM-32 Ordering Information
PART NO.
DESCRIPTION
PM7364-BI
256 Enhanced Ball Grid Array (SBGA)
Table 37 – FREEDM-32 Thermal Information
PART NO.
CASE TEMPERATURE
Theta Ja
Theta Jc
PM7364-BI
-40°C to +85°C
24 °C/W
2 °C/W
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MECHANICAL INFORMATION
Figure 44 – 256 Pin Enhanced Ball Grid Array (SBGA)
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NOTES
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CONTACTING PMC-SIERRA, INC.
PMC-Sierra, Inc.
8555 Baxter Place Burnaby, BC
Canada V5A 4V7
Tel:
(604) 415-6000
Fax:
(604) 415-6200
Document Information:
Corporate Information:
Application Information:
Web Site:
[email protected]
[email protected]
[email protected]
http://www.pmc-sierra.com
None of the information contained in this document constitutes an express or implied warranty by PMC-Sierra, Inc. as to the sufficiency, fitness or
suitability for a particular purpose of any such information or the fitness, or suitability for a particular purpose, merchantability, performance, compatibility
with other parts or systems, of any of the products of PMC-Sierra, Inc., or any portion thereof, referred to in this document. PMC-Sierra, Inc. expressly
disclaims all representations and warranties of any kind regarding the contents or use of the information, including, but not limited to, express and
implied warranties of accuracy, completeness, merchantability, fitness for a particular use, or non-infringement.
In no event will PMC-Sierra, Inc. be liable for any direct, indirect, special, incidental or consequential damages, including, but not limited to, lost profits,
lost business or lost data resulting from any use of or reliance upon the information, whether or not PMC-Sierra, Inc. has been advised of the possibility
of such damage.
The technology discussed is protected by one or more of the following Patents:
U.S. Patent Nos. 5,640,398 and 6,188,699
Can. Patent No. 2,161,921
Relevant patent applications and other patents may also exist.
© 2001PMC-Sierra, Inc
PMC-1960758 (R6)
ref PMC-1960113 (R10) Issue date: August 2001
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