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September 1992

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Document:	VAX 7000 Pocket Service Guide
Order Number:	EK-7000A-PG
Revision:	001
Pages:	175
Original Filename:

OCR Text

VAX 7000
Pocket Service Guide
Order Number EK–7000A–PG.001

This manual is intended for Digital service engineers. It supplies easy-toaccess key information on VAX 7000 systems.

digital equipment corporation
maynard, massachusetts

First Printing, September 1992
The information in this document is subject to change without notice and should
not be construed as a commitment by Digital Equipment Corporation.
Digital Equipment Corporation assumes no responsibility for any errors that may
appear in this document.
The software, if any, described in this document is furnished under a license and
may be used or copied only in accordance with the terms of such license. No responsibility is assumed for the use or reliability of software or equipment that is
not supplied by Digital Equipment Corporation or its affiliated companies.
Copyright © 1992 by Digital Equipment Corporation.
All Rights Reserved.
Printed in U.S.A.

The following are trademarks of Digital Equipment Corporation:
DEC
DEC LANcontroller
DECnet
DECUS
DWMVA

OpenVMS
PDP
ULTRIX
UNIBUS
VAX

VAXBI
VAXcluster
VAXELN
XMI

FCC NOTICE: The equipment described in this manual generates, uses, and may
emit radio frequency energy. The equipment has been type tested and found to
comply with the limits for a Class A computing device pursuant to Subpart J of
Part 15 of FCC Rules, which are designed to provide reasonable protection against
such radio frequency interference when operated in a commercial environment.
Operation of this equipment in a residential area may cause interference, in which
case the user at his own expense may be required to take measures to correct the
interference.

Contents
Preface ...................................................................................................... xi
Chapter 1 Registers
1.1
1.2
1.3
1.4

KA7AA Registers ................................................................... 1-2
MS7AA Registers ................................................................. 1-27
I/O Port Registers ................................................................. 1-35
DWLMA Registers ............................................................... 1-40

Chapter 2 Addressing
2.1
2.2
2.3
2.4

VAX 7000 Block Diagram ...................................................... 2-2
LSB Address Space ................................................................ 2-3
XMI Addresses ....................................................................... 2-6
VAXBI Addresses ................................................................... 2-7

Chapter 3 Console
3.1
3.2
3.3
3.4
3.5
3.6
3.7
3.8
3.9
3.10

Console Commands ................................................................ 3-2
Environment Variables .......................................................... 3-9
Device Name Fields ............................................................. 3-11
Command Syntax ................................................................. 3-12
Boot Command ..................................................................... 3-14
Cdp Command ...................................................................... 3-17
Show Configuration Command ........................................... 3-18
Show Device Command ....................................................... 3-19
Show Network Command .................................................... 3-20
Show Power Command ........................................................ 3-21

iii

Chapter 4 Diagnostics
4.1
4.2
4.3

Test Command ....................................................................... 4-2
Set Host Command — Running DUP-Based Diagnostics
and Utilities .......................................................................... 4-10
Set Host Command — Running Diagnostics on a Remote
XMI Adapter ........................................................................ 4-12

Chapter 5 FRU Locations
5.1
5.2
5.3
5.4
5.5

FRUs Common to Every Platform ........................................ 5-2
Platform Cables ...................................................................... 5-6
FRUs in the XMI Plug-In Unit.............................................. 5-8
FRUs in the Disk Plug-In Unit........................................... 5-10
FRUs in the Battery Plug-In Unit...................................... 5-12

Chapter 6 Controls and Indicators
6.1
6.2
6.3
6.4
6.5
6.6
6.7
6.8
6.9
6.10

Control Panel .......................................................................... 6-2
TF85 Removable Media Device ............................................. 6-3
Cabinet Control Logic Module ............................................... 6-4
IOP Module ............................................................................. 6-5
KA7AA Processor Module ...................................................... 6-6
Power Regulator ..................................................................... 6-8
AC Input Box .......................................................................... 6-9
BA651 XMI PIU Power Regulators ..................................... 6-10
DWLMA Module .................................................................. 6-12
BA654 Disk PIU ................................................................... 6-13

Chapter 7 Restoring Corrupted ROMs
7.1
7.2
7.3

Restoring a Corrupted EEPROM .......................................... 7-2
Restoring Corrupted Firmware on an Adapter .................... 7-3
Restoring Corrupted Firmware on a CPU ............................ 7-7

Chapter 8 System Errors
8.1
8.2
8.3

Machine Check Frame ........................................................... 8-2
Machine Check Parse Tree .................................................... 8-5
Hard Error Parse Tree ......................................................... 8-12

8.4
8.5
8.6

Soft Error Parse Tree ........................................................... 8-20
I/O Port Parse Tree .............................................................. 8-21
DWLMA Parse Tree ............................................................. 8-23

Examples
2-1
3-1
3-2
3-3
3-4
3-5
3-6
4-1
4-2
4-3
4-4
4-5
4-6
4-7
4-8
4-9
4-10
7-1
7-2
7-3
7-4
7-5
7-6
7-7
7-8

Examining the Device Register of VAXBI Node 7 ............... 2-7
Boot Command — Booting from an InfoServer .................. 3-14
Cdp Command ...................................................................... 3-17
Show Configuration Command ........................................... 3-18
Show Device Command ....................................................... 3-19
Show Network Command .................................................... 3-20
Show Power Command ........................................................ 3-21
Test Command — System Test ............................................. 4-2
Test Command — Write/Read/Compare Test of All Disks
Not Associated with Controller "a" ....................................... 4-4
Test Command — Destructive Exercising Selected, Then
Aborted ................................................................................... 4-6
Output from Test Command — Quiet Qualifier Set ............ 4-6
Test Command — Detection of Memory Data Compare
Error ....................................................................................... 4-7
Test Command — Use of Wildcard ....................................... 4-8
Test Command — Test All Devices Associated with XMI0 . 4-9
Set Host Command — Running DUP-Based Diagnostics
and Utilities .......................................................................... 4-10
Set Host Command — Running Diagnostics on a Remote
XMI Adapter, Failing Case .................................................. 4-12
Set Host Command — Running Diagnostics on a Remote
XMI Adapter, Passing Case ................................................. 4-13
Using the Build EEPROM Command to Restore a
Corrupted EEPROM .............................................................. 7-2
Booting LFU ........................................................................... 7-3
LFU Display and Show Commands ...................................... 7-5
LFU Update Command ......................................................... 7-6
LFU Exit Command ............................................................... 7-6
Preparing the Source System to Restore Corrupted
Firmware on a CPU ............................................................... 7-8
Running Kermit and Setting Parameters ............................ 7-8
Downline Loading Code to Corrupted FEPROMs ................ 7-9

Figures
1-1
1-2

LDEV — Device Register ....................................................... 1-3
LBER — Bus Error Register ................................................. 1-3

1-3
1-4
1-5
1-6
1-7
1-8
1-9
1-10
1-11
1-12
1-13
1-14
1-15
1-16
1-17
1-18
1-19
1-20
1-21
1-22
1-23
1-24
1-25
1-26
1-27
1-28
1-29
1-30
1-31
1-32
1-33
1-34
1-35
1-36
1-37
1-38
1-39
1-40
1-41
1-42
1-43
1-44
1-45

LCNR — Configuration Register .......................................... 1-4
LMMR0–7 — Memory Mapping Registers ........................... 1-4
LBESR0–3 — Bus Error Syndrome Registers ..................... 1-4
LBECR0–1 — Bus Error Command Registers ..................... 1-5
LIOINTR — I/O Interrupt Register ...................................... 1-5
LIPINTR — Interprocessor Interrupt Register .................... 1-5
LMODE — Mode Register ..................................................... 1-6
LMERR — Module Error Register ...................................... 1-7
LLOCK — Lock Address Register ......................................... 1-7
LDIAG — Diagnostic Control Register ................................. 1-8
LTAGA — Tag Address Register .......................................... 1-8
LTAGW — Tag Write Data Register .................................... 1-8
LCON — Console Communication Registers ....................... 1-9
LPERF — Performance Counter Control Register .............. 1-9
LCNTR — Performance Counter Registers .......................... 1-9
LMISSADDR — Last Miss Address Register ..................... 1-10
ICCS — Interval Clock Control and Status Register ......... 1-14
NICR — Next Interval Count Register ............................... 1-14
ICR — Interval Count Register ........................................... 1-15
TODR — Time-of-Day Register........................................... 1-15
MCESR — Machine Check Error Summary Register ....... 1-15
SID — System Identification Register ................................ 1-15
PCSCR — Patchable Control Store Control Register ........ 1-16
ECR — Ebox Control Register ............................................ 1-16
BIU_CTL — BIU Control Register ..................................... 1-17
DIAG_CTL — Diagnostic Control Register ........................ 1-17
BIU_STAT — BIU Status Register ..................................... 1-18
BIU_ADDR — BIU Address Register ................................. 1-18
FILL_SYND — Fill Syndrome Register ............................. 1-18
FILL_ADDR — Fill Address Register ................................. 1-19
CHALT — Console Halt Register ........................................ 1-19
VMAR — VIC Memory Address Register ........................... 1-19
VTAG — VIC Tag Register .................................................. 1-19
VDATA — VIC Data Register ............................................. 1-20
ICSR — Ibox Control and Status Register ......................... 1-20
BPCR — Ibox Branch Prediction Control Register ............ 1-20
MP0BR — Mbox P0 Base Register ..................................... 1-21
MP0LR — Mbox P0 Length Register .................................. 1-21
MP1BR — Mbox P1 Base Register ..................................... 1-21
MP1LR — Mbox P1 Length Register .................................. 1-21
MSBR — Mbox System Base Register ................................ 1-22
MSLR — Mbox System Length Register ............................ 1-22
MMAPEN — Mbox Memory Management Enable
Register ................................................................................. 1-22

1-46
1-47
1-48
1-49
1-50
1-51
1-52
1-53
1-54
1-55
1-56
1-57
1-58
1-59
1-60
1-61
1-62
1-63
1-64
1-65
1-66
1-67
1-68
1-69
1-70
1-71
1-72
1-73
1-74
1-75
1-76
1-77
1-78
1-79
1-80
1-81
1-82
1-83
1-84
1-85
1-86

PAMODE — Physical Address Mode Register ................... 1-22
MMEADR — Memory Management Exception Address
Register ................................................................................. 1-23
MMEPTE — Memory Management Exception PTE
Address Register .................................................................. 1-23
MMESTS — Memory Management Exception Status
Register ................................................................................. 1-23
TBADR — Translation Buffer Parity Address Register .... 1-24
TBSTS — Translation Buffer Parity Status Register ........ 1-24
PCADR — P-Cache Parity Address Register ..................... 1-24
PCSTS — P-Cache Status Register .................................... 1-25
PCCTL — P-Cache Control Register .................................. 1-25
LDEV — Device Register ..................................................... 1-28
LBER — Bus Error Register ............................................... 1-28
LCNR — Configuration Register ........................................ 1-29
IBR — Information Base Repair Register .......................... 1-29
LBESR0–3 — Bus Error Syndrome Registers ................... 1-29
LBECR0–1 — Bus Error Command Registers ................... 1-30
MCR — Memory Configuration Register ............................ 1-30
AMR — Address Mapping Register .................................... 1-30
MSTR0–1 — Memory Self-Test Registers .......................... 1-31
FADR — Failing Address Register ..................................... 1-31
MERA — Memory Error Register A ................................... 1-31
MSYNDA — Memory Syndrome Register A ...................... 1-32
MDRA — Memory Diagnostic Register A ........................... 1-32
MCBSA — Memory Check Bit Substitute Register A ....... 1-32
MERB — Memory Error Register B ................................... 1-33
MSYNDB — Memory Syndrome Register B ...................... 1-33
MDRB — Memory Diagnostic Register B ........................... 1-33
MCBSB — Memory Check Bit Substitute Register B ....... 1-34
IBR — Information Base Repair Register .......................... 1-36
LILID0–3 — Interrupt Level 0–3 IDENT Registers .......... 1-36
LCPUMASK — CPU Interrupt Mask Register .................. 1-37
LMBPR — Mailbox Pointer Register .................................. 1-37
IPCNSE — I/O Port Chip Node-Specific Error Register.... 1-37
IPCVR — I/O Port Chip Vector Register ............................ 1-37
IPCMSR — I/O Port Chip Mode Selection Register ........... 1-38
IPCHST — I/O Port Chip Hose Status Register ................ 1-38
IPCDR — I/O Port Chip Diagnostic Register ..................... 1-39
LDIAG — Diagnostic Register ............................................ 1-40
IMSK — Interrupt Mask Register ...................................... 1-41
LEVR — Error Vector Register ........................................... 1-41
LERR — Error Register ....................................................... 1-41
LGPR — General Purpose Register .................................... 1-42

vii

1-87
1-88
1-89
1-90
1-91
1-92
1-93
1-94
2-1
2-2
2-3
5-1
5-2
5-3
5-4
5-5
5-6
6-1
6-2
6-3
6-4
6-5
6-6
6-7
6-8
6-9
6-10
8-1
8-2
8-3
8-4
8-5
8-6

IPR1 — Interrupt Pending Register 1 ................................ 1-42
IPR2 — Interrupt Pending Register 2 ................................ 1-42
IIPR — Interrupt in Progress Register ............................... 1-42
XDEV — Device Register .................................................... 1-43
XBER — Bus Error Register ............................................... 1-44
XFADR — Failing Address Register ................................... 1-45
XFAER — Failing Address Extension Register ................. 1-45
IBR — Information Base Repair Register .......................... 1-45
VAX 7000 Block Diagram ...................................................... 2-2
Virtual Address Space Layout ............................................... 2-3
Physical Address Space Layouts ........................................... 2-3
Platform Cabinet (Front) Showing FRU Locations .............. 5-2
Platform Cabinet (Rear) Showing FRU Locations ............... 5-4
Platform Cabinet (Rear and Front) Showing Cables ........... 5-6
XMI Plug-In Unit (Front) Showing FRU Locations............. 5-8
Disk Plug-In Unit (Front) Showing FRU Locations........... 5-10
Battery Plug-In Unit (Rear) Showing FRU Locations....... 5-12
Control Panel ......................................................................... 6-2
TF85 Controls and Indicators ............................................... 6-3
CCL Module LEDs ................................................................. 6-4
IOP (E2044-AA) Module LED............................................... 6-5
Processor (E2045) LEDs After Self-Test............................... 6-6
Power Regulator LEDs .......................................................... 6-8
AC Input Box — Indicators on Circuit Breaker ................... 6-9
XMI PIU Power Regulators ................................................. 6-10
DWLMA (T2028-AA) Module LEDs.................................... 6-12
Disk Brick Control Panel ..................................................... 6-13
Machine Check Frame ........................................................... 8-2
Machine Check Parse Tree .................................................... 8-5
Hard Error Parse Tree ......................................................... 8-12
Soft Error Parse Tree ........................................................... 8-20
IOP Parse Tree ..................................................................... 8-21
DWLMA Parse Tree ............................................................. 8-23

Tables
1
2
1-1
1-2
1-3
1-4
1-5

viii

VAX 7000 Documentation ...................................................... xii
Related Documents ................................................................ xiv
LSB Required Registers ......................................................... 1-2
KA7AA-Specific Registers..................................................... 1-6
KA7AA Internal Processor Registers .................................. 1-11
Gbus Registers ..................................................................... 1-26
MS7AA Registers ................................................................. 1-27

1-6
1-7
1-8
2-1
2-2
2-3
2-4
2-5
2-6
3-1
3-2
3-3
3-4
3-5
3-6
3-7
3-8
3-9
3-10
3-11
3-12
3-13
3-14
3-15
3-16
3-17
6-1
6-2
6-3
6-4
6-5
6-6
6-7
6-8
6-9
6-10
6-11
6-12
8-1
8-2

I/O Port Registers ................................................................. 1-35
LSB Registers ....................................................................... 1-40
XMI Registers ....................................................................... 1-43
Address Mapping from 30-Bit Mode to 32-Bit Mode............ 2-4
LSB Node Base Addresses ..................................................... 2-4
Device Type Codes ................................................................. 2-5
XMI Node Addresses .............................................................. 2-6
Base Addresses of VAXBI Nodes ........................................... 2-8
Address Offsets of VAXBI Registers ..................................... 2-9
Console Commands ................................................................ 3-2
Boot Command Options ......................................................... 3-3
Cdp Command Options .......................................................... 3-4
Clear EEPROM Command Options ...................................... 3-4
Create Command Option ....................................................... 3-5
Deposit and Examine Command Options ............................. 3-5
Set EEPROM Command Options .......................................... 3-6
Set Host Command Options .................................................. 3-6
Show EEPROM Command Options ...................................... 3-6
Show Power Command Options ............................................ 3-7
Test Command Options ......................................................... 3-7
Update Command Options .................................................... 3-8
Environment Variables .......................................................... 3-9
Device Name Fields ............................................................. 3-11
Console Special Characters ................................................. 3-13
Sample Boot Commands ...................................................... 3-16
Abbreviations Used in Show Power Command Output ..... 3-22
Control Panel Indicator Lights .............................................. 6-2
TF85 Lights ............................................................................ 6-3
CCL Module LEDs ................................................................. 6-4
IOP (E2044-AA) Module LED............................................... 6-5
Processor (E2045) LEDs After Self-Test............................... 6-6
Self-Test LEDs Indicating Defective DC-to-DC Converter
.. 6-7
Power Regulator Lights ......................................................... 6-8
AC Input Box — Indicators on Circuit Breaker ................... 6-9
XMI PIU Power Regulator Lights (Regulators A and B) ... 6-11
XMI PIU Power Switches (Regulator B) ............................. 6-11
DWLMA (T2028-AA) Module LEDs.................................... 6-12
Disk Brick Controls and Indicators .................................... 6-13
Machine Check Frame Parameters ...................................... 8-3
Machine Check Codes in the Stack Frame ........................... 8-4

Preface
Intended Audience
This manual is written for the Digital service engineer.

Document Structure
This manual has eight chapters:
•

Chapter 1, Registers, lists the registers in this system and provides
an illustration of each.

•

Chapter 2, Addressing, provides information on address space layout, addresses, and device types.

•

Chapter 3, Console, contains a list of the console commands, syntax,
and error messages.

•

Chapter 4, Diagnostics, shows examples of running diagnostics on
adapters and device controllers.

•

Chapter 5, FRU Locations, identifies the field-replaceable units in
the platform.

•

Chapter 6, Controls and Indicators, discusses the controls and indicators on various components of the system.

•

Chapter 7, Restoring Corrupted ROMs, provides instructions for
restoring corrupted EEPROMs and for updating corrupted firmware.

•

Chapter 8, System Errors, includes the machine check frame and
the system parse trees.

Conventions Used in This Document
The text shown in command syntax uses these conventions:
•

Bold text indicates elements to be typed at the terminal.

•

Brackets ([]) indicate that an element is optional.

•

Braces ({}) indicate a choice from the enclosed list.

•

Angle brackets (<>) indicate that the enclosed text is not a literal depiction of the element but instead a reference to the kind of item that
can appear in that position.

The icons shown below are used in illustrations for designating part placement in the system described. A shaded area in the icon shows the location of the component or part being discussed.

Front

Rear

Document Titles
Table 1 lists the books in the VAX 7000 documentation set. Table 2 lists
other documents that you may find useful.

Table 1 VAX 7000 Documentation
Title

Order Number

Installation Kit

EK–7000A–DK

Site Preparation Guide

EK–7000A–SP

Installation Guide

EK–700EA–IN

Hardware User Information Kit

EK–7001A–DK

Operations Manual

EK–7000A–OP

Basic Troubleshooting

EK–7000A–TS

xii

Table 1 VAX 7000 Documentation (Continued)
Title

Order Number

Service Information Kit

EK–7002A–DK

Pocket Service Guide

EK–7000A–PG

Advanced Troubleshooting

EK–7001A–TS

Platform Service Manual

EK–7000A–SV

System Service Manual

EK–7002A–SV

Reference Manuals
Console Reference Manual

EK–70C0A–TM

KA7AA CPU Technical Manual

EK–KA7AA–TM

MS7AA Technical Manual

EK–MS7AA–TM

I/O System Technical Manual

EK–70I0A–TM

Platform Technical Manual

EK–7000A–TM

Upgrade Manuals
KA7AA CPU Installation Guide

EK–KA7AA–IN

MS7AA Memory Installation Guide

EK–MS7AA–IN

DWLMA XMI PIU Installation Guide

EK–DWLMA–IN

H7237 Battery PIU Installation Guide

EK–H7237–IN

BA654 Disk PIU Installation Guide

EK–BA654–IN

DWMBB VAXBI PIU Installation Guide

EK–DWMBB–IN

Removable Media Installation Guide

EK–TFRRD–IN

xiii

Table 2 Related Documents
Title

Order Number

General Site Preparation
Site Environmental Preparation Guide

EK–CSEPG–MA

System I/O Options
CIXCD Interface User Guide

EK–CIXCD–UG

DEC FDDIcontroller 400 Installation/Problem
Solving

EK–DEMFA–IP

DEC LANcontroller 400 Installation Guide

EK–DEMNA–IN

DEC LANcontroller 400 Technical Manual

EK–DEMNA–TM

DSSI VAXcluster Installation and Troubleshooting Manual

EK–410AA–MG

InfoServer 150 Installation and Owner’s Guide

EK–INFSV–OM

KFMSA Module Installation and User Manual

EK–KFMSA–IM

KFMSA Module Service Guide

EK–KFMSA–SV

RF Series Integrated Storage Element User Guide

EK–RF72D–UG

TF85 Cartridge Tape Subsystem Owner’s Manual

EK–OTF85–OM

Operating System Manuals
VMS Upgrade and Installation Supplement:
VAX 7000–600 and VAX 10000–600 Series

AA–PRAHA–TE

VMS Network Control Program Manual

AA–LA50A–TE

VAXclusters and Networking
HSC Installation Manual

EK–HSCMN–IN

SC008 Star Coupler User’s Guide

EK–SC008–UG

VAX Volume Shadowing Manual

AA–PBTVA–TE

Peripherals
Installing and Using the VT420 Video Terminal

EK–VT420–UG

LA75 Companion Printer Installation and User
Guide

EK–LA75X–UG

xiv

Chapter 1
Registers
This chapter is a compilation of the major registers in components of the
VAX 7000 system. Each section consists of a list of the registers in the
component including register name, mnemonic, and address and illustrations of the major registers. Sections include:
•

KA7AA Registers
— LSB Required Registers
— CPU-Specific Registers
— Internal Processor Registers
— Gbus Registers

•

MS7AA Registers

•

I/O Port Registers

•

DWLMA Registers
— LSB Registers
— XMI Registers

Registers 1-1

1.1 KA7AA Registers
Table 1-1

LSB Required Registers

Mnemonic

Byte Offset

LDEV

Device

BB 1 + 0000

LBER

Bus Error

BB + 0040

LCNR

Configuration

BB + 0080

LMMR0

Memory Mapping 0

BB + 0200

LMMR1

Memory Mapping 1

BB + 0240

LMMR2

Memory Mapping 2

BB + 0280

LMMR3

Memory Mapping 3

BB + 02C0

LMMR4

Memory Mapping 4

BB + 0300

LMMR5

Memory Mapping 5

BB + 0340

LMMR6

Memory Mapping 6

BB + 0380

LMMR7

Memory Mapping 7

BB + 03C0

LBESR0

Bus Error Syndrome 0

BB + 0600

LBESR1

Bus Error Syndrome 1

BB + 0640

LBESR2

Bus Error Syndrome 2

BB + 0680

LBESR3

Bus Error Syndrome 3

BB + 06C0

LBECR0

Bus Error Command 0

BB + 0700

LBECR1

Bus Error Command 1

BB + 0740

LIOINTR

I/O Interrupt

BSB2 + 0000

LIPINTR

Interprocessor Interrupt

BSB + 0040

1 BB is the node space base address of the CPU module in hex.
2 BSB is the broadcast space base address in hex.

1-2 Registers

Figure 1-1

LDEV — Device Register

31 30

16 15

DREV

DTYPE
BXB-0100-92

Figure 1-2

LBER — Bus Error Register

18 17 16 15 14 13 12 11 10

RSVD
NSES <18>
CTCE <17>
DTCE <16>

DIE <15>
SHE <14>
CAE <13>
NXAE <12>
CNFE <11>
STE <10>
TDE <9>
CDPE2 <8>
CDPE <7>
CPE2 <6>
CPE <5>
CE2 <4>

CE <3>
UCE2 <2>
UCE <1>
E <0>
BXB-0101-92

Registers 1-3

Figure 1-3

LCNR — Configuration Register

31 30 29 28 27

MBZ
CEEN

RSTSTAT
NHALT
NRST
STF

BXB-0102-92

Figure 1-4

LMMR0–7 — Memory Mapping Registers

17 16

MODULE_ADDR

11 10

RSVD
NBANKS
AW
IA
INT
EN
BXB-0104-92

Figure 1-5

LBESR0–3 — Bus Error Syndrome Registers

RSVD

SYND_0

RSVD

SYND_1

RSVD

SYND_2

RSVD

SYND_3
BXB-0105-92

1-4 Registers

Figure 1-6

LBECR0–1 — Bus Error Command Registers

20 19

18 17 16 15 14

11 10

3 2

CA <31:0>
RSVD

P CMD

RSVD

CID

CNF
SHARED
DIRTY
DCYCLE

Figure 1-7

BXB-0106-92

LIOINTR — I/O Interrupt Register

16 15

MBZ

12 11

CPU 3

CPU 2

CPU 1

CPU 0
BXB-0109-92

Figure 1-8

LIPINTR — Interprocessor Interrupt Register

16 15

MBZ

MASK
BXB-0120-92

Registers 1-5

Table 1-2 KA7AA-Specific Registers
Mnemonic

Byte Offset

LMODE

Mode

BB + C00

LMERR

Module Error

BB + C40

LLOCK

Lock Address

BB + C80

LDIAG

Diagnostic Control

BB + D00

LTAGA

Tag Address

BB + D40

LTAGW

Tag Write Data

BB + D80

LCON

Console Communication

BB + E00
BB + E40

LPERF

Performance Counter Control

BB + F00

LCNTR

Performance Counter

BB + F40
BB + F80

LMISSADDR

Last Miss Address

BB + FC0

Figure 1-9

LMODE — Mode Register

17 16 15

MBZ

11 10

MBZ
LEVI_REV
CLR_LOCK
STCOND_TO
LOCK_MODE
PMODE
WMODE
BSIZE
BXB-0130-92

1-6 Registers

Figure 1-10 LMERR — Module Error Register
31

11 10

RSVD

ARBDROP
ARBCOL
BDATADBE
BDATASBE
BMAPPE
BSTATPE
BTAGPE
PMAPPE
BXB-0122-92

Figure 1-11 LLOCK — Lock Address Register
1

31 30 29 28

LADR
MBZ
LOCK

MBZ

BXB-0126-92

Registers 1-7

Figure 1-12 LDIAG — Diagnostic Control Register
31

11 10

MBZ
TAG_SEL
FRIGN
FBDP
FBCP

FDBE
FSBE
FSHARE
FDIRTY
SPARE
BXB-0121-92

Figure 1-13 LTAGA — Tag Address Register
31

19 18

MBZ

TAG_ADDR
BXB-0123-92

Figure 1-14 LTAGW — Tag Write Data Register
31 30 29 28 27 26 25 24 23

TAG_DATA
BTAGP
BSTATP
BMAPP
PMAPP
VALID
SHARED
DIRTY
MBZ
BXB-0124-92

1-8 Registers

Figure 1-15 LCON — Console Communication Registers
31

CON_COM_DATA0

CON_COM_DATA1

BXB-0129-92

Figure 1-16 LPERF — Performance Counter Control Register
31

24 23 22 21 20

N_MASK

16 15 14 13 12

LC1_SEL

LC1_HLT
LC1_RUN
MBZ

LC0_SEL

MBZ

MA_FREQ
LC1_OVFL
LC0_OVFL
LC0_HLT
LC0_RUN
MBZ

BXB-0229-92

Figure 1-17 LCNTR — Performance Counter Registers
31

EV_COUNT0
EV_COUNT1
BXB-0228-92

Registers 1-9

Figure 1-18 LMISSADDR — Last Miss Address Register
31

29 28

MBZ

MISS_ADDR
BXB-0227-92

1-10 Registers

Table 1-3 KA7AA Internal Processor Registers

Mnemonic

Address
Dec Hex

Type

KSP

Kernel Stack Pointer

R/W

ESP

Executive Stack Pointer

R/W

SSP

Supervisor Stack Pointer

R/W

USP

User Stack Pointer

R/W

ISP

Interrupt Stack Pointer

R/W

P0BR

P0 Base

R/W

P0LR

P0 Length

R/W

P1BR

P1 Base

R/W

P1LR

P1 Length

R/W

SBR

System Base

R/W

SLR

System Length

R/W

CPUID

CPU Identification

PCBB

Process Control Block Base

R/W

SCBB

System Control Block Base

R/W

IPL

Interrupt Priority Level

ASTLVL

AST Level

SIRR

Software Interrupt Request

Software Interrupt Summary

R/W

ICCS

Interval Clock Control/Status

R/W

NICR

Next Interval Count

ICR

Interval Count

TODR

Time-of-Day

R/W

MCESR

Machine Check Error Summary

SAVPC

Console Saved PC

SAVPSL

Console Saved PSL

SISR

1 Initialized on reset.

Registers 1-11

Table 1-3 KA7AA Internal Processor Registers (Continued)

Mnemonic

Address
Dec Hex

Type

MAPEN

Memory Management Enable 1

R/W

TBIA

Translation Buffer Invalidate
All

TBIS

Translation Buffer Invalidate
Single

PME

Performance Monitor Enable 1

R/W

SID

System Identification

TBCHK

Translation Buffer Check

LMBOX

Mailbox

121

122

R/W

INTSYS

Interrupt System Status

PMFCNT

Performance Monitoring Facility Count

123

R/W

PCSCR

Patchable Control Store Control2

124

R/W

ECR

Ebox Control

MTBTAG

Mbox TB Tag Fill

125

R/W

126

127

MTBPTE

Mbox TB PTE Fill

BIU_CTL

BIU Control

160

DIAG_CTL

Diagnostic Control

161

BC_TAG

B-Cache Error Tag

162

BIU_STAT

BIU Status

164

W1C

BIU_ADDR

BIU Address

166

FILL_SYN

Fill Syndrome

168

FILL_ADDR

Fill Address

170

IPR_STR_
COND

STxC Pass Fail/CEFSTS

172

R/W

1 Initialized on reset.

2 Testability and diagnostic use only; not for software use in normal operation.

1-12 Registers

Table 1-3 KA7AA Internal Processor Registers (Continued)

Mnemonic

Address
Dec Hex

Type

BCDECC

Software ECC

174

CHALT

Console Halt

176

R/W

SIO

Serial I/O

178

R/W

SOE_IE

SROM_OE_Serial I.E.

180

R/W

QW_PACK

Pack I/O to QW

184

CLR_IO_
PACK

Clear QW I/O Pack

185

VMAR

VIC Memory Address

208

R/W

VTAG

VIC Tag

209

R/W

VDATA

VIC Data

210

R/W

ICSR

Ibox Control and Status

211

R/W

212

R/W

BPCR

Ibox Branch Prediction Control

BPC

Ibox Backup PC

214

BPCUNW

Ibox Backup PC with RLOG
Unwind 3

215

MP0BR

Mbox P0 Base 2

224

R/W

225

R/W

226

R/W

227

R/W

228

R/W

229

R/W

MP0LR

Mbox P0 Length

MP1BR

Mbox P1 Base

MP1LR

Mbox P1 Length

MSBR

Mbox System Base 2
2

MSLR

Mbox System Length

MMAPEN

Mbox Memory Management
Enable 2

230

R/W

PAMODE

Physical Address Mode

231

R/W

MMEADR

Memory Management Exception Address

232

2 Testability and diagnostic use only; not for software use in normal operation.
3 Chip use only; not for software use.

Registers 1-13

Table 1-3 KA7AA Internal Processor Registers (Continued)
Address
Dec Hex

Type

Memory Management Exception PTE Address

233

MMESTS

Memory Management Exception Status

234

TBADR

Translation Buffer Parity Address

236

TBSTS

Translation Buffer Parity
Status

237

R/W

PCADR

P-Cache Parity Address

242

PCSTS

P-Cache Status

244

R/W

PCCTL

P-Cache Control

248

R/W

Mnemonic

MMEPTE

Figure 1-19 ICCS — Interval Clock Control and Status Register
31 30

MBZ

ERR

INTR
IE
SGL
XFR
RUN
BXB-0167-92

Figure 1-20 NICR — Next Interval Count Register
31

NINT_COUNT
BXB-0169-92

1-14 Registers

Figure 1-21 ICR — Interval Count Register
31

INT_COUNT
BXB-0168-92

Figure 1-22 TODR — Time-of-Day Register
31

TOD
BXB-0166-92

Figure 1-23 MCESR — Machine Check Error Summary Register
31

MCESR
BXB-0236-92

Figure 1-24 SID — System Identification Register
31

24 23

CPU_TYPE

16 15

0 0 0 0 0 0 0 0

MIC_OPTIONS

MIC_REV
BXB-0180-92

Registers 1-15

Figure 1-25 PCSCR — Patchable Control Store Control Register
31

13 12 11 10

0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0

0 0 0 0 0 0 0 0

PCS_DATA
SHIFT
PCS_WRITE
PCS_ENB
PAR_PORT_DIS

BXB-0137-92

Figure 1-26 ECR — Ebox Control Register
31 30

23 22 21

0 0 0 0 0 0 0 0

19 18 17 16 15 14 13 12

0 0

0 0 0 0 0 0

PMF_CLEAR
PMF_LFSR
PMF_EMUX
PMF_PMUX
PMF_ENB
FBOX_TEST_ENB
TO_CLOCK
TO_TEST
TO_OCCURRED
FBOX_ST4_BYPASS_ENB
TO_EXT
FBOX_ENB
BXB-0138-92

1-16 Registers

Figure 1-27 BIU_CTL — BIU Control Register
31 30

28 27

24 23

20 19

16 15 14 13 12 11 10

X X X X X X X 0 0 0 0 0 X
BC_SIZE
WS_IO

X X

IO_MAP
"PV"
QW_IO_RD
PCACHE_MODE

BC_SPD
BC_FHIT
OE
ECC
BC_ENB
BXB-0213-92

NOTE: X bits read inverted values from DIAG_CTL

Figure 1-28 DIAG_CTL — Diagnostic Control Register
31

28 27 26

24 23

X X X X
SW_ECC
PM_ACCS_TYPE
PM_HIT_TYPE
DIS_ECC_ERR

21 20

16 15 14 13 12 11 10

0 0 0 0 0

X X

X XX

X X X X X X
TODR_TEST
TODR_INC
PACK_DISABLE
MAB_EN
BXB-0212-92

Registers 1-17

Figure 1-29 BIU_STAT — BIU Status Register
31 30 29 28 27

21 20 19

0 0 0 0 0 0 0

16 15 14 13 12 11 10

LOST_WRITE
FILL_DSP_CMD

BIU_ADDR
FILL_ADDR

FILL_SEO
FILL_QW
FILL_IRD
FILL_DPERR
FILL_CRD
FILL_ECC
BIU_SEO
BIU_DSP_CMD
BC_TCPERR
BC_TPERR
BIU_SERR
BIU_HERR
BXB-0162-92

Figure 1-30 BIU_ADDR — BIU Address Register
31

X X X X X

BIU_ADDR

BXB-0186-92

Figure 1-31 FILL_SYND — Fill Syndrome Register
63

14 13

LO
BXB-0163-92

1-18 Registers

Figure 1-32 FILL_ADDR — Fill Address Register
31

X X X X X

FILL_ADDR

BXB-0187-92

Figure 1-33 CHALT — Console Halt Register
31

CON_BASE_ADDR
BXB-0170-92

Figure 1-34 VMAR — VIC Memory Address Register
31

11 10

ADDR

0 0
ROW_INDEX
SUB_BLOCK
LW
BXB-0132-92

Figure 1-35 VTAG — VIC Tag Register
31

11 10

TAG

0 0
TAG_P
DATA_P
DATA_V
BXB-0133-92

Registers 1-19

Figure 1-36 VDATA — VIC Data Register
31

VIC_DATA
BXB-0134-92

Figure 1-37 ICSR — Ibox Control and Status Register
31

0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0

TPERR
DPERR
LOCK
VIC_ACC_ENB
BXB-0135-92

Figure 1-38 BPCR — Ibox Branch Prediction Control Register
31

16 15

BPU_ALGORITHM

0 0 0 0 0 0 0

LOAD_HISTORY
FLUSH_CTR
FLUSH_BHT
MISPREDICT
HISTORY
As part of the power-up sequence, the microcode will write FECA0000, which is the following bit pattern:
31

28 27

24 23

20 19

16 15

1 1 1 1 1 1 1 0 1 1 0 0 1 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
F

0
BXB-0136-92

1-20 Registers

Figure 1-39 MP0BR — Mbox P0 Base Register
31 30 29

1 0

SYS_VA_P0

0 0 0 0 0 0 0 0 0
BXB-0139-92

Figure 1-40 MP0LR — Mbox P0 Length Register
31

22 21

0 0 0 0 0 0 0 0 0 0

P0_LENGTH_LW
BXB-0140-92

Figure 1-41 MP1BR — Mbox P1 Base Register
31 30 29

1 0

SYS_VA_P1

0 0 0 0 0 0 0 0 0
BXB-0141-92

Figure 1-42 MP1LR — Mbox P1 Length Register
31

22 21

0 0 0 0 0 0 0 0 0 0

P1_LENGTH_LW
BXB-0142-92

Registers 1-21

Figure 1-43 MSBR — Mbox System Base Register
31

SYS_PT_PA

0 0 0 0 0 0 0 0 0
BXB-0143-92

Figure 1-44 MSLR — Mbox System Length Register
31

22 21

0 0 0 0 0 0 0 0 0 0

SYS_PT_LENGTH_LW
BXB-0144-92

Figure 1-45 MMAPEN — Mbox Memory Management Enable
Register
31

0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
MEM_MNG_ENB
BXB-0145-92

Figure 1-46 PAMODE — Physical Address Mode Register
31

0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
PHYS_ADDR_MODE
BXB-0146-92

1-22 Registers

Figure 1-47 MMEADR — Memory Management Exception
Address Register
31

NME_FAULT_ADDR
BXB-0147-92

Figure 1-48 MMEPTE — Memory Management Exception PTE
Address Register
31

MIOD_FAULT_PTE_ADDR
BXB-0148-92

Figure 1-49 MMESTS — Memory Management Exception Status
Register
31

29 28

26 25

16 15 14 13

LOCK SRC 0 0 0 0 0 0 0 0 0 0
FAULT

0 0 0 0 0 0 0 0 0 0 0
M
PTE_REF
LV
BXB-0149-92

Registers 1-23

Figure 1-50 TBADR — Translation Buffer Parity Address Register
31

VA_TB_PE
BXB-0150-92

Figure 1-51 TBSTS — Translation Buffer Parity Status Register
31

29 28

SRC 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0

CMD

EM_VAL
TPERR
DPERR
LOCK
BXB-0151-92

Figure 1-52 PCADR — P-Cache Parity Address Register
31

PC_PE_PA

0 0 0
BXB-0152-92

1-24 Registers

Figure 1-53 PCSTS — P-Cache Status Register
31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10

CMD

1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1

PTE_ER
PTE_ER_WR

LEFT_BANK
RIGHT_BANK
DPERR
LOCK
BXB-0153-92

Figure 1-54 PCCTL — P-Cache Control Register
31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9

1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1

PMM

RED_ENB
ELEC_DISABLE
PC_PE_ENB
BANK_SEL
FORCE_HIT
I_STR_ENB
D_STR_ENB
BXB-0154-92

Registers 1-25

Table 1-4 Gbus Registers
Register

Address

Gbus$WHAMI

F700 0000

Gbus$LEDs

F700 0040

Gbus$PMask

F700 0800

Gbus$Intr

F700 00C0

Gbus$Halt

F700 0100

Gbus$LSBRST

F700 0140

Gbus$Misc

F700 0180

Gbus$RMode_ENA

F780 0000

1-26 Registers

1.2 MS7AA Registers
Table 1-5 MS7AA Registers
Mnemonic

Byte Offset

LDEV

Device

BB + 0000

LBER

Bus Error

BB + 0040

LCNR

Configuration

BB + 0080

IBR

Information Base Repair

BB + 00C0

LBESR0

Bus Error Syndrome 0

BB + 0600

LBESR1

Bus Error Syndrome 1

BB + 0640

LBESR2

Bus Error Syndrome 2

BB + 0680

LBESR3

Bus Error Syndrome 3

BB + 06C0

LBECR0

Bus Error Command 0

BB + 0700

LBECR1

Bus Error Command 1

BB + 0740

MCR

Memory Configuration

BB + 2000

AMR

Address Mapping

BB + 2040

MSTR0

Memory Self-Test 0

BB + 2080

MSTR1

Memory Self-Test 1

BB + 20C0

FADR

Failing Address

BB + 2100

MERA

Memory Error A

BB + 2140

MSYNDA

Memory Syndrome A

BB + 2180

MDRA

Memory Diagnostic A

BB + 21C0

MCBSA

Memory Check Bit Substitute A

BB + 2200

MERB

Memory Error B

BB + 4140

MSYNDB

Memory Syndrome B

BB + 4180

MDRB

Memory Diagnostic B

BB + 41C0

MCBSB

Memory Check Bit Substitute B

BB + 4200

Registers 1-27

Figure 1-55 LDEV — Device Register
31 30

16 15

DREV

DTYPE
BXB-0100-92

Figure 1-56 LBER — Bus Error Register
31

18 17 16 15 14 13 12 11 10

RSVD
NSES <18>
CTCE <17>
DTCE <16>

DIE <15>
SHE <14>
CAE <13>
NXAE <12>
CNFE <11>
STE <10>
TDE <9>
CDPE2 <8>
CDPE <7>
CPE2 <6>
CPE <5>
CE2 <4>

CE <3>
UCE2 <2>
UCE <1>
E <0>
BXB-0101-92

1-28 Registers

Figure 1-57 LCNR — Configuration Register
31 30 29 28 27

MBZ
CEEN

RSTSTAT
NHALT
NRST
STF

BXB-0102-92

Figure 1-58 IBR — Information Base Repair Register
31

MBZ
SCLK
XMT_SDAT
RCV_SDAT
BXB-0218-92

Figure 1-59 LBESR0–3 — Bus Error Syndrome Registers
31

RSVD

SYND_0

RSVD

SYND_1

RSVD

SYND_2

RSVD

SYND_3
BXB-0105-92

Registers 1-29

Figure 1-60 LBECR0–1 — Bus Error Command Registers
31

20 19

18 17 16 15 14

11 10

3 2

CA <31:0>
RSVD

CID

RSVD

P CMD

CNF
SHARED
DIRTY
DCYCLE

BXB-0106-92

Figure 1-61 MCR — Memory Configuration Register
31

RSVD
STRG
RSVD
DTYP
BXB-0217-92

Figure 1-62 AMR — Address Mapping Register
31

17 16

NADR

11 10

RSVD

NBANKS
INTL
BXB-0216-92

1-30 Registers

Figure 1-63 MSTR0–1 — Memory Self-Test Registers
31

MSTR0
31

MSTR1
BXB-0215-92

Figure 1-64 FADR — Failing Address Register
31

FADR
BXB-0214-92

Figure 1-65 MERA — Memory Error Register A
31

12 11 10

RSVD

FSTR
UCERB
UCERA
BNKER
CERB
CERA
APER
MULE
UCER
CER
BXB-0219 -92

Registers 1-31

Figure 1-66 MSYNDA — Memory Syndrome Register A
31

RSVD

SYNDA
BXB-0223-92

Figure 1-67 MDRA — Memory Diagnostic Register A
31 30 29 28 27 26

RFR

RSVD
DCRD
BRFSH
DRFSH

FCPE
FRPE
IGSB
MODE
STPM
EXST
BPAS
DWDC
DRDC
FCBS
BXB-0225-92

Figure 1-68 MCBSA — Memory Check Bit Substitute Register A
31

RSVD

SCB_A
BXB-0221-92

1-32 Registers

Figure 1-69 MERB — Memory Error Register B
31

RSVD
APER
MULE
UCER
CER
BXB-0220 -92

Figure 1-70 MSYNDB — Memory Syndrome Register B
31

RSVD

SYNDB
BXB-0224-92

Figure 1-71 MDRB — Memory Diagnostic Register B
31

RSVD
IGSB
MODE
STPM
EXST
BPAS
DWDC
DRDC
FCBS
BXB-0226-92

Registers 1-33

Figure 1-72 MCBSB — Memory Check Bit Substitute Register B
31

RSVD

SCB_B
BXB-0222-92

1-34 Registers

1.3 I/O Port Registers
Table 1-6 I/O Port Registers

Mnemonic

Physical
Address

Software
Address

LDEV

Device

50 0000

A00 0000

LBER

Bus Error

50 0002

A00 0040

LCNR

Configuration

50 0004

A00 0080

IBR

Information Base Repair

50 0006

A00 00C0

LMMR0

Memory Mapping 0

50 0010

A00 0200

LMMR1

Memory Mapping 1

50 0012

A00 0240

LMMR2

Memory Mapping 2

50 0014

A00 0280

LMMR3

Memory Mapping 3

50 0016

A00 02C0

LMMR4

Memory Mapping 4

50 0018

A00 0300

LMMR5

Memory Mapping 5

50 001A

A00 0340

LMMR6

Memory Mapping 6

50 001C

A00 0380

LMMR7

Memory Mapping 7

50 001E

A00 03C0

LBESR0

Bus Error Syndrome 0

50 0030

A00 0600

LBESR1

Bus Error Syndrome 1

50 0032

A00 0640

LBESR2

Bus Error Syndrome 2

50 0034

A00 0680

LBESR3

Bus Error Syndrome 3

50 0036

A00 06C0

LBECR0

Bus Error Command 0

50 0038

A00 0700

LBECR1

Bus Error Command 1

50 003A

A00 0740

LILID0

Interrupt Level 0 IDENT

50 0050

A00 0A00

LILID1

Interrupt Level 1 IDENT

50 0052

A00 0A40

LILID2

Interrupt Level 2 IDENT

50 0054

A00 0A80

LILID3

Interrupt Level 3 IDENT

50 0056

A00 0AC0

LCPUMASK

CPU Interrupt Mask

50 0058

A00 0B00

Registers 1-35

Table 1-6 I/O Port Registers (Continued)
Mnemonic

Physical
Address

Software
Address

LMBPR

Mailbox Pointer

50 0060

A00 0C00

IPCNSE

I/O Port Chip Node-Specific
Error

50 0100

A00 2000

IPCVR

I/O Port Chip Vector

50 0102

A00 2040

IPCMSR

I/O Port Chip Mode Selection

50 0104

A00 2080

IPCHST

I/O Port Chip Hose Status

50 0106

A00 20C0

IPCDR

I/O Port Chip Diagnostic

50 0108

A00 2100

Figure 1-73 IBR — Information Base Repair Register
31

MBZ
SCLK
XMT_SDAT
RCV_SDAT
BXB-0218-92

Figure 1-74 LILID0–3 — Interrupt Level 0–3 IDENT Registers
31 30

16 15

Reserved

IDENT
BXB-0107-92

1-36 Registers

Figure 1-75 LCPUMASK — CPU Interrupt Mask Register
31

16 15

MBZ

12 11

CPU 3

CPU 2

CPU 1

CPU 0
BXB-0109-92

Figure 1-76 LMBPR — Mailbox Pointer Register
31

Mailbox Address <37:6>

MBZ
BXB-0110-92

Figure 1-77 IPCNSE — I/O Port Chip Node-Specific Error Register
31 30

21 20 19 18 17 16 15

12 11

Reserved
INTR_NSES

MBX_TIP
UP_HOSE_OFLO
UP_HOSE_PKT_ERR
UP_HOSE_PAR_ERR

MULT_INTR_ERR
DN_VRTX_ERR
UP_VRTX_ERR
IPC_IE
UP_HIC_IE

BXB-112-92

Figure 1-78 IPCVR — I/O Port Chip Vector Register
31 30

16 15

Reserved

Vector
BXB-0108-92

Registers 1-37

Figure 1-79 IPCMSR — I/O Port Chip Mode Selection Register
31

Reserved

00 0
ARB HIGH
ARB CTL <1:0>
BXB-0113-92

Figure 1-80 IPCHST — I/O Port Chip Hose Status Register
31

28 27

16 15

12 11

HOSE RST <3:0>
H3 STAT <3:0>
H2 STAT <3:0>
H1 STAT <3:0>
H0 STAT <3:0>
BXB-0114-92

1-38 Registers

Figure 1-81 IPCDR — I/O Port Chip Diagnostic Register
31 30

24 23 22 21

14 13 12 11 10

Reserved

FRC CNFE
FRC CAE
DIAG ECC <6:0>
DIAG ECC EN

DIS LSB CMD
HIC LPBCK EN
FRS DAT PE
FRC CMD PE

FRC DN DPE <1:0>
FRS DN SEQ ERR
FRC DN ILL CMD
BXB-0115-92

Registers 1-39

1.4 DWLMA Registers
Table 1-7 LSB Registers
Mnemonic

Address

LDIAG

Diagnostic

BB + 40

IMSK

Interrupt Mask

BB + 44

LEVR

Error Vector

BB + 48

LERR

Error

BB + 4C

LGPR

General Purpose

BB + 50

IPR1

Interrupt Pending 1

BB + 54

IPR2

Interrupt Pending 2

BB + 58

IIPR

Interrupt in Progress

BB + 5C

Figure 1-82 LDIAG — Diagnostic Register
31

28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10

RSVD

NODE

STE
Force XMI Access
ASM0
ASM1
Force CNF Err
Disable Retries on NO ACK
RSVD

DLLF
AS
LOCK
LOOP
FRRM1
FRRM0
CRE
FPE3

1-40 Registers

FPE0
FPE1
FPE2

BXB-0209-92

Figure 1-83 IMSK — Interrupt Mask Register
31

28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12

RSVD

ICC
RSVD
IWEI
IIPE

ITTO
RSVD
ICNAK
IRER

IMBER
IRBDPE
IDFDPE

IXPE
IWSE
IRIDNAK

IRSE
INRR
ICRD
IWDNAK

BXB-0208-92

Figure 1-84 LEVR — Error Vector Register
31

16 15

RSVD

VECTOR

DWLMA Error Interrupt Vector

BXB-0202-92

Figure 1-85 LERR — Error Register
31 30 29 28 27

19 18

RSVD
DHDPE
XMIPE0
XMIPE1
XMIPE2

15 14 13 12 11

RSVD

IVID
MBPE
MBIC
MBIA
Data FIFO DPE
RBDPE
MBOF
FE
BXB-0207-92

Registers 1-41

Figure 1-86 LGPR — General Purpose Register
31

LGPR
BXB-0203-92

Figure 1-87 IPR1 — Interrupt Pending Register 1
31

28 27

24 23

IP8

IP7

20 19

IP6

16 15

IP5

12 11

IP4

IP3

IP2

IP1
BXB-0204-92

Figure 1-88 IPR2 — Interrupt Pending Register 2
31

24 23

RSVD

20 19

IP14

16 15

IP13

12 11

IP12

IP11

IP10

IP9

DWLMA Error Interrupt Pending

BXB-0205-92

Figure 1-89 IIPR — Interrupt in Progress Register
31

20 19

RSVD

16 15

12 11

IDENTID IPL17ID IPL16ID IPL15ID IPL14ID
BXB-0206-92

1-42 Registers

Table 1-8 XMI Registers
Mnemonic

Address

XDEV

Device

BB + 0000

XBER

Bus Error

BB + 0004

XFADR

Failing Address

BB + 0008

XFAER

Failing Address Extension

BB + 000C

IBR

Information Base Repair

BB + 0010

Figure 1-90 XDEV — Device Register
31

20 19

MBZ

16 15

DREV

Device Type
BXB-0233-92

Registers 1-43

Figure 1-91 XBER — Bus Error Register
31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10

FCID
EHWW
DXTO
EMP
RSVD
STF
ETF
NSES
Commander Errors
TTO
RSVD
CNAK
RER
RSE
NRR
CRD
WDNAK
Responder Errors
RIDNAK
WSE
PE
IPE
Miscellaneous
WEI
XFAULT
CC
XBAD
NHALT
NRST
ES

1-44 Registers

BXB-0234-92

Figure 1-92 XFADR — Failing Address Register
31 30 29

Failing Address

FLN

BXB-0235-92

Figure 1-93 XFAER — Failing Address Extension Register
31

28 27 26 25

CMD

16 15

0 0 ADDRESS EXTENSION

MASK
BXB-0230-92

Figure 1-94 IBR — Information Base Repair Register
31

MBZ
SCLK
XMT_SDAT
RCV_SDAT
BXB-0218-92

Registers 1-45

Chapter 2
Addressing
This chapter includes an overview of the VAX 7000 system and addressing
information for the buses used in the system. Sections include:
•

VAX 7000 Block Diagram

•

LSB Address Space

•

XMI Addresses

•

VAXBI Addresses

Addressing 2-1

2.1 VAX 7000 Block Diagram
Figure 2-1

VAX 7000 Block Diagram

Processors

Memory

LSB

IOP

DWLMA

CLOCK

XMI

DEMNA

DEMFA

DWMBB

CIXCD

KFMSA

KDM70
BXB-0054-92

2-2 Addressing

2.2 LSB Address Space
Figure 2-2

Virtual Address Space Layout
Length of P0 Region in pages (P0LR)

0000 0000
P0
Region
3FFF FFFF
4000 0000

P1
Region

P0 Region growth direction
P1 Region growth direction
Length of P1 Region in pages (2**21-P1LR)
Length of System Region in pages (SLR)

7FFF FFFF
8000 0000
System
Region
FFFF FDFE
FFFF FDFF Reserved Region

System Region growth direction

BXB-0199A-92

FFFF FFFF

Figure 2-3

0000 0000
1FFF FFFF

Physical Address Space Layouts

Physical Memory
Space
(512 Mbytes)

Physical Memory
Space
(3.5 Gbytes)

0000 0000

Inaccessible
Region
DFFF FFFF
E000 0000
FFFF FFFF

I/O Space
(512 Mbytes)

DFFF FFFF
E000 0000
FFFF FFFF
BXB-0198-92

Figure 2-3 shows 30-bit addressing mode on the left and 32-bit addressing
mode on the right.

Addressing 2-3

Table 2-1 Address Mapping from 30-Bit Mode to 32-Bit Mode
30-Bit Mode Address

32-Bit Mode Address

0000 0000 — 1FFF FFFF

2000 0000 — 3FFF FFFF

E000 0000 — FFFF FFFF

Table 2-2 LSB Node Base Addresses

Node

Module

Base Physical Address
(BB)

CPU 0

F800 0000

Processor or memory

F840 0000

Processor or memory

F880 0000

Processor or memory

F8C0 0000

Memory

F900 0000

Memory

F940 0000

Memory

F980 0000

Memory

F9C0 0000

IOP

FA00 0000

Broadcast Space
Base

BSB

FE00 0000

For more information:
KA7AA CPU Technical Manual

2-4 Addressing

Table 2-3 Device Type Codes
Device

Code (hex)

KA7AA

8002

MS7AA

4000

IOP

2000

DWLMA

102A

CIXCD

0C05

DEMFA

0823

DEMNA

0C03

DWMBB

2002

KDM70

0C22

KFMSA

0810

Addressing 2-5

2.3 XMI Addresses
Table 2-4

XMI Node Addresses

Node

Mailbox Base
Physical Address (BB)

XMI Base
Physical Address (BB)

6180 0000

80 0180 0000

6188 0000

80 0188 0000

6190 0000

80 0190 0000

6198 0000

80 0198 0000

61A0 0000

80 01A0 0000

61A8 0000

80 01A8 0000

61B0 0000

80 01B0 0000

61B8 0000

80 01B8 0000

61C0 0000

80 01C0 0000

61C8 0000

80 01C8 0000

61D0 0000

80 01D0 0000

61D8 0000

80 01D8 0000

61E0 0000

80 01E0 0000

61E8 0000

80 01E8 0000

2-6 Addressing

2.4 VAXBI Addresses
To examine a VAXBI register from the VAX 7000 console (see Example
2-1), you need three pieces of information:
1.

The XMI number (0–3) to which the VAXBI bus is connected.

The base address of the VAXBI node (see Table 2-5).

The offset of the VAXBI register to be examined (see Table 2-6).

The address of the register to be examined is expressed in this form:
xmin:220xxyyy
where:

n = the XMI number
xx = the base address of the VAXBI node
yyy = the address offset of the VAXBI register

To calculate the address of the VAXBI register, add 2200 0000 plus the
base address of the VAXBI node (Table 2-5) plus the address offset of the
VAXBI register (Table 2-6).
NOTE: You must look at the node ID plug on the backplane of the VAXBI
card cage to determine the node ID of the VAXBI option.

Example 2-1 Examining the Device Register of VAXBI Node 7
>>> e xmi1:2200E000
xmi1: 2200E000 131C010E
>>>

Addressing 2-7

Table 2-5 Base Addresses of VAXBI Nodes
Node ID

Base Address

0000 0000

0000 2000

0000 4000

0000 6000

0000 8000

0000 A000

0000 C000

0000 E000

0001 0000

0001 2000

0001 4000

0001 6000

0001 8000

0001 A000

0001 C000

0001 E000

2-8 Addressing

Table 2-6 Address Offsets of VAXBI Registers

Mnemonic

Address
Offset

DTYPE

Device

bb 1 + 00

VAXBICSR

VAXBI Control and Status

bb + 04

BER

Bus Error

bb + 08

EINTRSCR

Error Interrupt Control

bb + 0C

INTRDES

Interrupt Destination

bb + 10

IPINTRMSK

IPINTR Mask

bb + 14

FIPSDES

Force-Bit IPINTR/STOP Destination

bb + 18

IPINTRSRC

IPINTR Source

bb + 1C

SADR

Starting Address

bb + 20

EADR

Ending Address

bb + 24

BCICSR

BCI Control and Status

bb + 28

WSTAT

Write Status

bb + 2C

FIPSCMD

Force-Bit IPINTR/STOP Command

bb + 30

UINTRCSR

User Interface Interrupt Control

bb + 40

GPR0

General Purpose Register 0

bb + F0

GPR1

General Purpose Register 1

bb + F4

GPR2

General Purpose Register 2

bb + F8

GPR3

General Purpose Register 3

bb + FC

SOSR

Slave-Only Status

bb + 100

RXCD

Receive Console Data

bb + 200

1 bb is the base address of the VAXBI node (the address of the first location of the

nodespace).

Addressing 2-9

Chapter 3
Console
This chapter contains an overview of the console command set and command syntax. It includes a section on device naming and examples of the
use of selected commands. Sections include:
•

Console Commands

•

Environment Variables

•

Device Name Fields

•

Command Syntax

•

Boot Command

•

Cdp Command

•

Show Configuration Command

•

Show Device Command

•

Show Network Command

•

Show Power Command

Console 3-1

3.1 Console Commands
Table 3-1

Console Commands

Command

Description

boot

Boot the operating system

build
eeprom

Create a new EEPROM image

cdp

Perform basic configuration management of DSSI devices

clear

Clear the specified EEPROM option, remove a boot specification environment variable, or clear the terminal screen

continue

Resume processing at the point it was interrupted by
Ctrl/P

create

Create an environment variable

deposit

Store data in a specified location

examine

Display contents of a memory location, a register, or a device

help

Provide basic information on the console commands when
the system is in console mode

initialize

Initialize the entire system or a specified device or subsystem

repeat

Repeat a command; stop by entering Ctrl/C

set

Record the current system configuration in the EEPROM,
set the selected EEPROM option, modify an environment
variable, or connect to another console or service

show

Display the last saved configuration, device information
for a disk or tape adapter, selected EEPROM information,
current state of an environment variable, memory module
information, information about network devices, or system
power status

start

Begin execution of an instruction at specified address;
does not initialize the system

stop

Stop a specified processor

3-2 Console

Table 3-1 Console Commands (Continued)
Command

Description

test

Test a specified device, a subsystem, or the entire system
(default)

update

Copy the contents of the EEPROM or FEPROMs on the
boot processor to the EEPROM or FEPROMs on the specified secondary processor(s)

# or !

Introduce a comment

Table 3-2 Boot Command Options
Option

Meaning

-file <file>

Boot from the file <file>

-flags <val>

Boot flags that qualify the bootstrap. If omitted, the
value of the environment variable boot_flags is used.

Console 3-3

Table 3-3 Cdp Command Options
Option

Meaning

-a

Set device allocation class, allclass

-i

Select interactive mode; set all parameters

-n

Set device node name, nodename (up to 16 characters)

-o

Overridde warning messages

-u

Set device unit number, unitnum

-sa allclass

Set allclass for all DSSI devices in the system to the
specified value

-sn

Set nodename to either RFhscn or TFhscn
h is the device hose number (0–3)
s is the device slot number (1–14)
c is the device channel number (0, 1)
n is the device node ID number (0–6)

-su
unitnum

Set the starting unitnum for the first DSSI device in
the system to the specified value. Subsequent DSSI unit
numbers are incremented from this base.

Table 3-4 Clear EEPROM Command Options
Option

Meaning

diag_sdd

Remove from EEPROM failure information logged by
symptom-directed diagnosis

diag_tdd

Remove from EEPROM failure information logged by
test-directed diagnosis

log

Remove from EEPROM all failure information
(symptom-directed diagnosis, test-directed diagnosis,
and operating system)

symptom

Remove from EEPROM all failure information on operating system

3-4 Console

Table 3-5 Create Command Option
Option

Meaning

-nv

Store the nonvolatile environment variable in EEPROM

Table 3-6 Deposit and Examine Command Options
Option

Meaning

-b

Define data size as a byte

-d

Disassemble instruction at current address
(examine command only)

-h

Define data size as a hexword

-l

Define data size as a longword; initial default

-o

Define data size as an octaword

-q

Define data size as a quadword

-w

Define data size as a word

-n val

Number of consecutive locations to modify

-s val

Address increment size. Default is data size.

-u

Allow access to console private memory, while disabling virtual address protection checks

space:

Device name and address space, as follows:

<dev_name>

Device name; for example, xmi0, ka7aa0, or demna0

gpr

Define the address space as the general register set,
R0 through R15. The data size is always a longword.

ipr

Define the address space as the internal processor
registers (IPRs). The data size is always a longword.

psl

Define the address space as the processor status
longword (PSL).

pmem

Define the address space as physical memory; initial
default

vmem

Define the address space as virtual memory. All access and protection checking occur.

Console 3-5

Table 3-7 Set EEPROM Command Options
Option

Meaning

field

Record the LARS report number and comment

manufacturing

Record manufacturing information: module serial
number, module part number, and module firmware
revision

serial

Record system serial number

Table 3-8 Set Host Command Options
Option

Meaning

-bus b

DSSI bus on which the node resides

-dup

Remote node is a DUP server

Table 3-9 Show EEPROM Command Options
Option

Meaning

diag_sdd

Display failure information logged by symptomdirected diagnosis

diag_tdd

Display failure information logged by test-directed diagnosis

field

Display LARS number and comment

manufacturing

Display manufacturing information: module serial
number, module part number, and module firmware
revision

serial

Display system serial number

symptom

Display failure information logged on operating system

3-6 Console

Table 3-10 Show Power Command Options
Option

Meaning

-h

History status — the value of each parameter at the last
system shutdown

-s

Current status (default)

main

Power status of the main cabinet (default)

right

Power status of the expander cabinet to the right of the
main cabinet

left

Power status of the expander cabinet to the left of the
main cabinet

Table 3-11 Test Command Options
Option

Meaning

-write

Select writes to media as well as reads (read-only is the
default). Applicable only to disk testing (ignored otherwise).

-nowrite
<list>

Used with -write to prevent selected devices or groups
of devices from being written to

-omit <list>

Specify device not to test; takes a single device or device
list as a qualifier

-t <time>

Run time in seconds for the test command; default for
system is 600 seconds (10 minutes).

-q

"Quiet" option prevents informational messages about
testing start and stop from being displayed on the console terminal. Error messages are always reported.

Console 3-7

Table 3-12 Update Command Options
Option

Meaning

-flash

Update the FEPROMs on the specified secondary processor

-eeprom

Update the EEPROM on the specified secondary processor

For more information:
VAX 7000 Console Reference Manual
VAX 7000 Advanced Troubleshooting

3-8 Console

3.2 Environment Variables
An environment variable is a name and a value association maintained by
the console program. The value associated with an environment variable is
an ASCII string (up to 128 characters) or an integer. Volatile environment
variables are initialized by a system reset; others are nonvolatile across
system failures.
Environment variables can be created, modified, displayed, and deleted using the console create, set, show, and clear commands.

Table 3-13 Environment Variables
Variable

Attribute

Function

auto_action

Nonvolatile

The action the console will take following
an error halt. Values are:
restart—Automatically restart. If restart
fails, boot the operating system.
boot—Automatically boot the operating
system
halt—Enter console mode (default)

baud

Nonvolatile

Sets the baud rate of the console terminal
port to 300, 600, 1200, 2400, 4800, or 9600
(default)

bootdef_dev

Nonvolatile

The default device or device list from which
booting is attempted when the boot command does not specify a device name

boot_file

Nonvolatile

The default file name used for the primary
bootstrap when the boot command does not
specify a file name

boot_osflags

Nonvolatile

Additional parameters passed to the system
during booting if none are specified by the
-flags qualifier to the boot command

boot_reset

Nonvolatile

Resets system and displays self-test results
during booting. Default is off.

cpu

Volatile

Selects the current boot processor

Console 3-9

Table 3-13 Environment Variables (Continued)
Variable

Attribute

Function

cpu_enabled

Nonvolatile

A bitmask indicating which processors are
enabled to run (leave console mode). If not
defined, all processors are considered enabled. Default is 0xFF.

cpu_primary

Nonvolatile

A bitmask indicating which processors are
enabled to become the next boot processor
after the next reset. If not defined, all
available processors are considered enabled. Default is 0xFF.

d_harderr

Volatile

Determines action taken following a hard
error. Values are halt (default) and continue. Applies only when using the test
command.

d_report

Volatile

Determines level of information provided
by the diagnostic reports. Values are summary (default) and full. Applies only
when using the test command.

d_softerr

Volatile

Determines action taken following a soft
error. Values are continue (default) and
full. Applies only when using the test
command.

enable_audit

Nonvolatile

When set to on, allows audit trail messages to be displayed during booting.

interleave

Nonvolatile

The memory interleave specification. Values must be default, none, or an explicit
interleave list. Default value is default.

language

Nonvolatile

Determines whether system displays message numbers or message text in English
(default).

For more information:
VAX 7000 Console Reference Manual

3-10 Console

3.3 Device Name Fields
Device names are used in several console commands. A device name is expressed in the form ddccuuuu.node.channel.slot.hose. Fields are separated by periods. Table 3-14 lists the field definitions.

Table 3-14 Device Name Fields
Field

Size

Definition

Protocol used to access the device:
du

MSCP disk (CI, SI, DSSI)

MSCP tape (CI, SI, DSSI)

XMI Ethernet

XMI FDDI

2 (max)

Controller letter (a–zz) assigned by console,
based on the system configuration

uuuu

4 (max)

Unit number of the device (0–9999) determined
by the I/O channel number and the XMI slot
number of the adapter

node

3 (max)

Node number (0–255) of the device on a remote
(CI or DSSI) bus. If the remote bus is a CI, this is
the CI node number of the HSC; if it is a DSSI,
this is the node number of the disk.

channel

Channel number (0–1); used only if the adapter
is a KFMSA

slot

2 (max)

XMI slot number (1–14) of the adapter

hose

Hose number (0–3) that connects to the XMI bus

For more information:
VAX 7000 Console Reference Manual
VAX 7000 Operations Manual

Console 3-11

3.4 Command Syntax
b[oot] [-fl[ags] <parameters>] [-fi[le] <filename>] <device_name>
bu[ild] ee[prom]
cdp [-{a,i,n,o,u}] [-sn] [-sa <val>] [<dssi_device>]
cl[ear] ee[prom] <option>
cl[ear] <envar>
cl[ear] sc[reen]
c[ontinue]
cr[eate] [-nv] <envar> [<value>]
d[eposit] [-{b,w,l,q,o,h,u}] [{-n val, -s val}] [<space>:]<adrs> <data>
e[xamine] [-{b,w,l,q,o,h,d,u}] [{-n val, -s val}] [<space>:]<adrs>
h[elp] [<option>]
i[nitialize] [<device_name>]
r[epeat] [<command>]
se[t] c[onfiguration]
se[t] ee[prom] [<option>]
se[t] <envar> [<value>]
se[t] h[ost] [-dup] [-bus <b>] node [<task>]
sh[ow] c[onfiguration]
sh[ow] dev[ice] [<dev_name>]
sh[ow] ee[prom] [<option>]
sh[ow] <envar>
sh[ow] m[emory]
sh[ow] ne[twork]
sh[ow] power [{-h, -s}] [{main, right, left}]
s[tart] <address>
sto[p] <cpu_device_name>
t[est] [-write] [-nowrite <list>] [-omit <list>] [-t <time>] [-q] [<dev_arg>]
upd[ate] [-{e[eprom], f[lash]}] [<device_name>]

3-12 Console

Table 3-15 Console Special Characters

Character

Function

Return

Carriage return; ends a command line

Backslash

Line continuation

Delete key; deletes previously typed character

Help

By itself, displays first-level help. When pressed after
part of a command, displays options available.

Ctrl/A, F14

Toggles between insertion and overstrike modes

Ctrl/B, ⇑

Recall previous command

Ctrl/C

Terminate running process

Ctrl/D, ⇐

Move cursor left one position

Ctrl/E

Move cursor to end of line

Ctrl/F, ⇒

Move cursor right one position

Ctrl/H, BS, F12

Move cursor to beginning of line

Ctrl/J

Delete word

Ctrl/O

Stop output to console terminal for current command.
Toggles between enable and disable.

Ctrl/P

In console mode, acts like Ctrl/C. In program mode,
causes the boot processor to halt and begin running
the console program.

Ctrl/Q

Resume output to console terminal

Ctrl/R

Redisplay the current line

Ctrl/S

Stop output to console terminal

Ctrl/U

Delete entire line

Wildcarding for some commands

Quotes for set environment variable name

#, !

Comment specifier
For more information:
VAX 7000 Console Reference Manual
VAX 7000 Advanced Troubleshooting

Console 3-13

3.5 Boot Command
Example 3-1 Boot Command — Booting from an InfoServer
>>> show network
polling for units on demna0, slot 3, xmi0...
exa0.0.0.3.0 08-00-2B-0B-BB-ED
>>> boot exa0 -file ISL_LVAX_BL10
Initializing...
F E D C B A 9 8 7 6 5 4 3 2 1 0
A M . . . . . P P
o + . . . . . + +
. . . . . . . E B
o + . . . . . + +
. . . . . . . E B
+ + . . . . . + +
. . . . . . . E B
.
.
.
.

.
.
.
.

+
.
.
.

.
.
.
.

+
.
.
.

.
.
.
.

+
.
.
.

.
.
.
.

+
.
.
.

NODE #
TYP
ST1
BPD
ST2
BPD
ST3
BPD
C0 XMI +
C1
C2
C3

. A0 . . . . . . . ILV
.128 . . . . . . . 128Mb
Firmware Rev = V1.0-1625 SROM Rev = V1.0-0 SYS SN = GAO1234567
Booting...
Connecting to boot device exa0 -file ISL_LVAX_BL10
Created boot device: exa0.0.0.3.0
Resulting file is mopd1:ISL_LVAX_BL10/exa0.0.0.3.0
.....
Load complete!
Network Initial System Load Function
Version 1.1
FUNCTION
FUNCTION
ID
1
Display Menu
2
Help
3
Choose Service
4
Select Options
5
Stop
Enter a function ID value: 3
OPTION
OPTION
ID
1
Find Services
2
Enter known Service Name
Enter an Option ID value: 1
Working
Servers found: 2

3-14 Console

Example 3-1 Boot Command — Booting from an InfoServer
(Continued)
Service Name Format:
Service Number
Service Name
Server Name
Ethernet ID
#1
VMS054
ESS_08002B0BBBED
08-00-2B-0B-BB-ED
#2
CD_BIN_83371
ESS_08002B0BBBED
08-00-2B-0B-BB-ED
#1
INFO3$RZ57
INFO3
08-00-2B-26-A6-98
#2
CD_DOC_0050
INFO3
08-00-2B-16-04-98
Enter a Service number or <CR> for more: 1
[operating system banner appears]

Console 3-15

Table 3-16 Sample Boot Commands
Boot From

Sample Boot Command

Local device

boot dua2.2.0.1.0

InfoServer on
Ethernet

boot exa0 -file ISL_LVAX_BL10

InfoServer on
FDDI

boot fxa0 -file ISL_LVAX_BL10

CI VAXcluster

boot -fl 0,4,0 dua20.14.0.2.0

Shadow set

b -fl 8DAC,2,0 dua3500.14.0.12.1, dua63.14.0.12.1

DSSI VAXcluster

boot -flags 0,3,0 dub1.1.0.6.0

For more information:
VAX 7000 Console Reference Manual
VAX 7000 Operations Manual

3-16 Console

3.6 Cdp Command
Example 3-2 Cdp Command
>>> show device
polling for units on kfmsa0, slot 0, xmi0...
dua5.0.0.13.0
BASHFL$DIA5
RF71
polling for units on cixcd0, slot 14, xmi1...
dub44.1.0.13.0
$1$DIA44 (BLANK4) RF71
>>> cdp -i
dua5.0.0.13.0:
Node Name [BASHFL]?
Allocation Class [0]?
Unit Number [5]?
dub44.1.0.13.0:
Node Name [BLANK4]?
Allocation Class [1]
Unit Number [44]?

! Interactive mode

>>> cdp -n dua5
dua5.0.0.13.0:
Node Name [BASHFL]?

! Set device node name of dua5.

>>> cdp -a
dua5.0.0.13.0:
Allocation Class [0]?
dub44.1.0.13.0:
Allocation Class [1]?

! Set device allocation class.

! Press Return to go to next
! field without making a
! change.

! Press Return to exit.

! Exit, no changes made.

For more information:
VAX 7000 Console Reference Manual

Console 3-17

3.7 Show Configuration Command
Example 3-3 Show Configuration Command
>>> show config
Name

Type

Rev

Mnemonic

KA7AA
MS7AA
MS7AA
IOP

(8002)
(4000)
(4000)
(2000)

0000
0000
0000
0001

ka7aa0
ms7aa0
ms7aa1
iop0

C0 XMI
8+
DWLMA
C+
KDM70
E+
DEMNA

(102A)
(0C22)
(0C03)

0104
1E11
0802

xmi0
dwlma0
kdm700
demna0

C1 XMI
2+
KFMSA
3+
DEMNA
8+
DWLMA
A+
CIXCD
C+
KDM70

(0810)
(0C03)
(102A)
(0C05)
(0C22)

A2A6
0802
0104
4611
1E11

xmi1
kfmsa0
demna1
dwlma1
cixcd0
kdm701

LSB
0+
1+
7+
8+

For more information:
VAX 7000 Console Reference Manual

3-18 Console

3.8 Show Device Command
Example 3-4 Show Device Command
>>> show device
polling for units on kfmsa0, slot 1, xmi0...
dub1.1.1.1.2
RF3101$DIA1
RF72
dub3.3.1.1.2
RF3103$DIA3
RF72
polling for units on kdm700, slot 11, xmi0...
duc1.0.0.11.2
DUC1
RA70
duc2.0.0.11.2
DUC2
RA70
duc3.0.0.11.2
DUC3
RA70
duc213.0.0.11.2
DUC213
RA82
>>>

For more information:
VAX 7000 Console Reference Manual

Console 3-19

3.9 Show Network Command
Example 3-5 Show Network Command
>>> show network
polling for units on demna0, slot 14, xmi0...
exa0.0.0.14.0: 08-00-2B-24-3F-E1
polling for units on demfa0, slot 1, xmi1...
fxa0.0.0.1.1: 08-00-2B-29-E0-FF
>>>

For more information:
VAX 7000 Console Reference Manual

3-20 Console

3.10 Show Power Command
Example 3-6 Show Power Command
>>> show power
Cabinet: Main
Regulator :
A
B
C
------------------------------------------------------------------------------Primary Micro Firmware Rev :
2.0
2.0
2.0
Secondary Micro Firmware Rev :
2.0
2.0
2.0
Power Supply State :
NORMAL
NORMAL
BBU MODE
AC Line Voltage (V RMS) :
113.71
114.35
115.93
DC Bulk Voltage (VDC) :
227.02
227.02
227.02
48V DC Bus Voltage (VDC) :
47.57
47.57
47.57
48V DC Bus Current (ADC) :
30.17
29.68
29.58
48V Battery Pack Voltage (VDC) :
50.85
50.72
47.91
24V Battery Pack Votlage (VDC) :
25.56
25.56
23.95
Battery Pack Charge Current (IDC) :
2.91
2.90
0
Ambient Temperature (Degree C) :
26.22
24.80
24.75
Elapsed Time (Hours) :
290.00
290.00
290.00
Remaining Battery Capacity (Minutes) :
8.00
8.00
8.00
Battery Cutoff Counter (Cycles) :
0
1.00
1.00
Battery Configuration : 4 Batteries 4 Batteries 4 Batteries
Heatsink Status :
NORMAL
NORMAL
NORMAL
Battery Pack Status :
CHARGING
CHARGING
DISCHG’G
Last UPS Test Status :
PASSED
PASSED
TESTING
LDC POWER Status
: 0
PIU Primary Status
: 0
PIU Secondary Status : 0

The cabinet in Example 3-6 has three power regulators. If the cabinet has
fewer than three regulators, the appropriate column (A, B, or C) is left
blank. The bottom three lines of the output, showing PIU power status,
apply only to the main cabinet.
Table 3-17 lists the abbreviations used in four lines of the Show Power
command: Power Supply State, Heatsink Status, Battery Pack Status,
and Last UPS Test Status.

For more information:
VAX 7000 Console Reference Manual

Console 3-21

Table 3-17 Abbreviations Used in Show Power Command Output
Abbreviation

Meaning

Power Supply State
NORMAL

Normal AC operation

BBU MODE

UPS mode

BRKR OPEN

Breaker open

NO AC IN

No AC voltage

KEYSW OFF

Keyswitch off

NON FATAL

Nonfatal fault

FATAL

Fatal fault

SPARE
Heatsink Status
BROKEN

Broken

FAULT

Fault (red zone)

WARNING

Warning

NORMAL

Normal operation

Battery Pack Status
NO BATTERY

Battery pack not installed

BATT FLT

Battery pack failure

BBU INH

UPS inhibit

CHG INH

Charger inhibit

BATT EOL

Battery at end of life

DISCHARG

Battery discharged

DISCHG’G

Discharging

CHARGING

Charging

OVER 24HRS

Charge mode longer than 24 hours

FULL CHG’D

Fully charged

3-22 Console

Table 3-17 Abbreviations Used in Show Power Command Output
(Continued)
Abbreviation

Meaning

Last UPS Test Status
NO BATTER

Battery pack not installed

NOT READY

Battery pack not ready
(only if test requested)

ABORTED

Test aborted

TESTING

Test in progress

FAILED

Test failed

PASSED

Test passed

Console 3-23

Chapter 4
Diagnostics
Diagnostics are run using console commands. This chapter contains examples of diagnostic sessions. Sections include:
•

Test Command

•

Set Host Command — Running DUP-Based Diagnostics and Utilities

•

Set Host Command — Running Diagnostics on a Remote XMI Adapter

Diagnostics 4-1

4.1 Test Command
Example 4-1 Test Command — System Test
>>> test -t 120
Configuring system...
Default system exerciser selected for run time of 120 seconds
Type Ctrl/C to abort
Starting floating point exerciser on ka7aa0 (id #57)
Starting floating point exerciser on ka7aa1 (id #58)
Starting memory exerciser, running on ka7aa0 (id #59)
Starting memory exerciser, running on ka7aa1 (id #60)
Starting multiprocessor exerciser on ka7aa* (id #61)
Starting network exerciser on exa0.0.0.4.0 in internal mode (id #62)
Starting network exerciser on exb0.0.0.5.0 in external mode (id #63)
Starting network exerciser on exc0.0.0.4.1 in external mode (id #64)
Starting network exerciser on fxa0.0.0.2.1 in external mode (id #65)
Starting network exerciser on fxb0.0.0.3.2 in external mode (id #66)
Starting device exerciser on dua10.14.0.1.0 (id #67)
Starting device exerciser on dub0.15.0.2.0 (id #68)
Starting device exerciser on duc0.0.0.3.0 (id #69)
Starting device exerciser on dud0.0.0.E.0 (id #70)
Starting device exerciser on dua11.14.0.1.0 (id #71)
Starting device exerciser on dub1.15.0.2.0 (id #72)
Starting device exerciser on duc1.1.0.3.0 (id #73)
Starting device exerciser on dud1.1.0.E.0 (id #74)
Starting device exerciser on dua12.14.0.1.0 (id #75)
Starting device exerciser on dub2.15.0.2.0 (id #76)
Starting device exerciser on dua13.14.0.1.0 (id #77)
Starting device exerciser on dub19.15.0.2.0 (id #78)
Stopping device exerciser on dua10.14.0.1.0 (id #67)
Stopping device exerciser on dub0.15.0.2.0 (id #68)
Stopping device exerciser on duc0.0.0.3.0 (id #69)
Stopping device exerciser on dud0.0.0.E.0 (id #70)
Stopping device exerciser on dua11.14.0.1.0 (id #71)
Stopping device exerciser on dub1.15.0.2.0 (id #72)
Stopping device exerciser on duc1.1.0.3.0 (id #73)
Stopping device exerciser on dud1.1.0.E.0 (id #74)
Stopping device exerciser on dua12.14.0.1.0 (id #75)
Stopping device exerciser on dub2.15.0.2.0 (id #76)
Stopping device exerciser on dua13.14.0.1.0 (id #77)
Stopping device exerciser on dub3.15.0.2.0 (id #78)
Starting device exerciser on dua20.14.0.1.0 (id #79)
Starting device exerciser on dub4.15.0.2.0 (id #80)
Starting device exerciser on dua21.14.0.1.0 (id #81)
Starting device exerciser on dub5.15.0.2.0 (id #82)
Starting device exerciser on dua22.14.0.1.0 (id #83)
Starting device exerciser on dub6.15.0.2.0 (id #84)
Starting device exerciser on dua23.14.0.1.0 (id #85)

4-2 Diagnostics

Example 4-1 Test Command — System Test (Continued)
Starting device exerciser on dua30.14.0.1.0 (id #86)
Test time has expired...
Stopping floating point exerciser on ka7aa0 (id #57)
Stopping floating point exerciser on ka7aa1 (id #58)
Stopping memory exerciser on ka7aa0 (id #59)
Stopping memory exerciser on ka7aa1 (id #60)
Stopping multiprocessor exerciser (id #61)
Stopping network exerciser on exa0.0.0.4.0 (id #62)
Stopping network exerciser on exb0.0.0.5.0 (id #63)
Stopping network exerciser on exc0.0.0.4.1 (id #64)
Stopping network exerciser on fxa0.0.0.2.1 (id #65)
Stopping network exerciser on fxb0.0.0.3.2 (id #66)
Stopping device exerciser on dua20.14.0.1.0 (id #79)
Stopping device exerciser on dub4.15.0.2.0 (id #80)
Stopping device exerciser on dua21.14.0.1.0 (id #81)
Stopping device exerciser on dub5.15.0.2.0 (id #82)
Stopping device exerciser on dua22.14.0.1.0 (id #83)
Stopping device exerciser on dub6.15.0.2.0 (id #84)
Stopping device exerciser on dua23.14.0.1.0 (id #85)
Stopping device exerciser on dua30.14.0.1.0 (id #86)
Done testing...
The following devices were not tested:
dua36.14.0.1.0
dua37.14.0.1.0
dua38.14.0.1.0
.
.
dua77.15.0.1.0
>>>

Diagnostics 4-3

Example 4-2 Test Command — Write/Read/Compare Test of All
Disks Not Associated with Controller "a"
>>> test -nowrite "dua*" -write -t 120
Configuring system...
Default system exerciser selected for run time of 120 seconds
Type Ctrl/C to abort
You have selected destructive testing of the following devices:
dub0.0.0.2.0
dub1.1.0.2.0
dub2.2.0.2.0
dub3.3.0.2.0
duc0.0.0.3.0
duc1.1.0.3.0
dud0.0.0.E.0
dud1.1.0.E.0
Are you sure you want to perform writes to these disks? [yes/(no)] yes
User data on all selected devices may be lost. Continue? [yes/(no)] yes
Testing...
Starting floating point exerciser on ka7aa0 (id #213)
Starting floating point exerciser on ka7aa1 (id #214)
Starting memory exerciser, running on ka7aa0 (id #215)
Starting memory exerciser, running on ka7aa1 (id #216)
Starting multiprocessor exerciser on ka7aa* (id #217)
Starting network exerciser on exa0.0.0.4.0 in internal mode (id #218)
Starting network exerciser on exb0.0.0.5.0 in external mode (id #219)
Starting network exerciser on exc0.0.0.4.1 in external mode (id #220)
Starting network exerciser on fxa0.0.0.2.1 in external mode (id #221)
Starting network exerciser on fxb0.0.0.3.2 in external mode (id #222)
Starting device exerciser on dua10.14.0.1.0 (id #223)
Starting device exerciser in DESTRUCT mode on dub0.15.0.2.0 (id 224)
Starting device exerciser in DESTRUCT mode on duc0.0.0.3.0 (id #225)
Starting device exerciser in DESTRUCT mode on dud0.0.0.E.0 (id #226)
Starting device exerciser on dua11.14.0.1.0 (id #227)
Starting device exerciser in DESTRUCT mode on dub1.15.0.2.0 (id #228)
Starting device exerciser in DESTRUCT mode on duc1.1.0.3.0 (id #229)
Starting device exerciser in DESTRUCT mode on dud1.1.0.E.0 (id #230)
Starting device exerciser on dua12.14.0.1.0 (id #231)
Starting device exerciser in DESTRUCT mode on dub2.15.0.2.0 (id #232)
Starting device exerciser on dua13.14.0.1.0 (id #233)
Starting device exerciser in DESTRUCT mode on dub3.15.0.2.0 (id #234)
Stopping device exerciser on dua10.14.0.1.0 (id #223)
Stopping device exerciser on dub0.15.0.2.0 (id #224)
Stopping device exerciser on duc0.0.0.3.0 (id #225)
Stopping device exerciser on dud0.0.0.E.0 (id #226)
Stopping device exerciser on dua11.14.0.1.0 (id #227)

4-4 Diagnostics

Example 4-2 Test Command — Write/Read/Compare Test of All
Disks Not Associated with Controller "a" (Continued)
Stopping device exerciser on dub1.15.0.2.0 (id #228)
Stopping device exerciser on duc1.1.0.3.0 (id #229)
Stopping device exerciser on dud1.1.0.E.0 (id #230)
Stopping device exerciser on dua12.14.0.1.0 (id #231)
Stopping device exerciser on dub2.15.0.2.0 (id #232)
Stopping device exerciser on dua13.14.0.1.0 (id #233)
Stopping device exerciser on dub3.15.0.2.0 (id #234)
Starting device exerciser on dua20.14.0.1.0 (id #235)
Starting device exerciser in DESTRUCT mode on dub4.15.0.2.0 (id #236)
Starting device exerciser on dua21.14.0.1.0 (id #237)
Starting device exerciser in DESTRUCT mode on dub5.15.0.2.0 (id #238)
Starting device exerciser on dua22.14.0.1.0 (id #239)
Starting device exerciser in DESTRUCT mode on dub6.15.0.2.0 (id #240)
Starting device exerciser on dua23.14.0.1.0 (id #241)
Starting device exerciser on dua30.14.0.1.0 (id #242)
Test time has expired...
Stopping floating point exerciser on ka7aa0 (id #213)
Stopping floating point exerciser on ka7aa1 (id #214)
Stopping memory exerciser on ka7aa0 (id #215)
Stopping memory exerciser on ka7aa1 (id #216)
Stopping multiprocessor exerciser (id #217)
Stopping network exerciser on exa0.0.0.4.0 (id #218)
Stopping network exerciser on exb0.0.0.5.0 (id #219)
Stopping network exerciser on exc0.0.0.4.1 (id #220)
Stopping network exerciser on fxa0.0.0.2.1 (id #221)
Stopping network exerciser on fxb0.0.0.3.2 (id #222)
Stopping device exerciser on dua20.14.0.1.0 (id #235)
Stopping device exerciser on dub4.15.0.2.0 (id #236)
Stopping device exerciser on dua21.14.0.1.0 (id #237)
Stopping device exerciser on dub5.15.0.2.0 (id #238)
Stopping device exerciser on dua22.14.0.1.0 (id #239)
Stopping device exerciser on dub6.15.0.2.0 (id #240)
Stopping device exerciser on dua23.14.0.1.0 (id #241)
Stopping device exerciser on dua30.14.0.1.0 (id #242)
Done testing...
>>>

Diagnostics 4-5

Example 4-3 Test Command — Destructive Exercising Selected,
Then Aborted
>>> test -w -n "dua*"
Configuring system...
Default system exerciser selected for run time of 600 seconds
Type Ctrl/C to abort
You have selected destructive testing of the following devices:
dub0.0.0.2.0
dub1.1.0.2.0
dub2.2.0.2.0
dub3.3.0.2.0
duc0.0.0.3.0
duc1.1.0.3.0
dud0.0.0.E.0
dud1.1.0.E.0
Are you sure you want to perform writes to these disks? [yes/(no)] no
Testing aborted...
>>>

Example 4-4 Output from Test Command — Quiet Qualifier Set
>>> test -q -t 300
Configuring system...
Default system exerciser selected for run time of 300 seconds
Type Ctrl/C to abort
Done testing...
>>>

4-6 Diagnostics

Example 4-5 Test Command — Detection of Memory Data
Compare Error
>>> set d_report full
>>> test ms7aa*
Configuring system...
Testing ms7aa*
Type Ctrl/C to abort
Starting memory exerciser, running on ka7aa0 (id #77)
Starting memory exerciser, running on ka7aa1 (id #78)
Starting memory exerciser, running on ka7aa2 (id #79)

*** Hard Error - Error #23 on FRU: ka7aa0
Data compare error
ID Program
Device
Pass Hard/Soft Test
Time
-------- -------- --------------- -------- --------- ---- -------00000078
mem_ex
memory
433
1
0
4 10:23:51
Expected value: FFFFFFE0
Received value: FFF7FFE0
Failing addr:
047C87C8
*** End of Error ***
Testing aborted - halt-on-error selected...
Stopping memory exerciser on ka7aa1 (id #77)
Stopping memory exerciser on ka7aa2 (id #79)
Done testing...
>>>

Diagnostics 4-7

Example 4-6 Test Command — Use of Wildcard
>>> test dem*a*
Configuring system...
Testing dem*a*
Type Ctrl/C to abort
Initializing DEMNA0
Initializing DEMNA1
Initializing DEMFA0
DEMNA0 self-test passed
DEMNA1 self-test passed
DEMFA0 self-test passed
Starting network exerciser on exa0.0.0.4.0 in internal mode (id #144)
Starting network exerciser on exb0.0.0.5.0 in external mode (id #145)
Starting network exerciser on fxa0.0.0.2.1 in external mode (id #146)
Test time has expired...
Stopping network exerciser on exa0.0.0.4.0 (id #144)
Stopping network exerciser on exb0.0.0.5.0 (id #145)
Stopping network exerciser on fxa0.0.0.2.1 (id #146)
Done testing...
>>>

4-8 Diagnostics

Example 4-7 Test Command — Test All Devices Associated with
XMI0
>>> test xmi0 -omit demna2
Configuring system...
Testing xmi0
Type Ctrl/C to abort
KA7AA0 running module tests on DWLMA0
DWLMA0 module tests passed
Initializing DEMNA0
Initializing DEMNA1
Initializing CIXCD0
Initializing KDM700
Initializing DEMFA0
DEMNA0 self-test passed
DEMNA1 self-test passed
CIXCD0 self-test passed
KDM700 self-test passed
DEMFA0 self-test passed
Starting network exerciser on exa0.0.0.4.0 in internal mode (id #31)
Starting network exerciser on exb0.0.0.5.0 in external mode (id #32)
Starting network exerciser on fxa0.0.0.e.0 in external mode (id #33)
Starting device exerciser on dua0.0.0.6.0 (id #34)
Starting device exerciser on dub0.0.0.a.0 (id #35)
Starting device exerciser on dua1.1.0.6.0 (id #38)
Starting device exerciser on dub1.1.0.a.0 (id #39)
Starting device exerciser on dua2.2.0.6.0 (id #42)
Starting device exerciser on dub2.2.0.a.0 (id #43)
Starting device exerciser on dua3.3.0.6.0 (id #44)
Starting device exerciser on dub3.3.0.a.0 (id #45)
Test time has expired...
Stopping network exerciser on exa0.0.0.4.0 (id #31)
Stopping network exerciser on exb0.0.0.5.0 (id #32)
Stopping network exerciser on fxa0.0.0.e.0 (id #33)
Stopping device exerciser on dua0.0.0.6.0 (id #34)
Stopping device exerciser on dub0.0.0.a.0 (id #35)
Stopping device exerciser on dua1.1.0.6.0 (id #38)
Stopping device exerciser on dub1.1.0.a.0 (id #39)
Stopping device exerciser on dua2.2.0.6.0 (id #42)
Stopping device exerciser on dub2.2.0.a.0 (id #43)
Stopping device exerciser on dua3.3.0.6.0 (id #44)
Stopping device exerciser on dub3.3.0.a.0 (id #45)
Done testing...
>>>

Diagnostics 4-9

4.2 Set Host Command — Running DUP-Based
Diagnostics and Utilities
Example 4-8 Set Host Command — Running DUP-Based
Diagnostics and Utilities
>>> show device kdm700
polling for units on kdm700, slot 12, xmi0...
dua32.0.0.12.0
DUA32
RA70
dua34.0.0.12.0
DUA34
RA70
dua77.0.0.12.0
DUA77
RA70
>>> set host -dup dua32.0.0.12.0
dup: starting DIRECT on kdm70_a.0.0.12.0 ()
DIRECT

D Directory Utility

ILEXER

D InLine Exerciser

Task? ilexer
dup: starting ILEXER on kdm70_a.0.0.12.0 ()
***
*** ILEXER (InLine Exerciser) V 001
***

*** 17-NOV-1992 10:21:57 ***

Enable Bad Block Replacement (Y/N) [N] ?
Available Disk Drives: D0032 D0034 D0077
Available Tape Drives: NONE
Select next drive to test (Tnnnn/Dnnnn) [] ? d0032
Write enable drive (Y/N) [N] ?
*** Available tests are:
1. Random I/O
2. Seek Intensive I/O
3. Data Intensive I/O
4. Oscillatory Seek

4-10 Diagnostics

Example 4-8 Set Host Command — Running DUP-Based
Diagnostics and Utilities (Continued)
Select test number (1:4) [1] ?
Select start block number (0:547040) [0] ?
Select end block number (0:547040) [547040] ? 500
Select data pattern number 0=ALL (0:15) [0] ?
Select another drive (Y/N) [] ?
*** No default is allowed.
Select another drive (Y/N) [] ? n
Select execution time limit, 0=Infinite, minutes (0:65535) [0] ? 1
Select report interval, minutes (0:65535) [1] ? 1
Select hard error limit (0:32) [0] ?
Report soft errors (Y/N) [N] ? y
Execution Performance Summary at 17-NOV-1992 10:23:57
D0032

193832346

4315

9713

Execution Performance Summary at 17-NOV-1992 10:23:57
D0032 *

193832346

4320

9723

***
*** ILEXER is exiting.
***
Task?

Diagnostics 4-11

4.3 Set Host Command — Running Diagnostics on
a Remote XMI Adapter
Example 4-9 Set Host Command — Running Diagnostics on a
Remote XMI Adapter, Failing Case
>>> set host demna0
Connecting to remote node, ^Y to disconnect.
t/r
RBDE> ST0/TR
;Selftest

3.00

; T0001 T0002 T0003 T0004 T0005 T0006 T0007 T0008 T0009 T0010
; T0011 T0012 T0013 T0014 T0015 T0016 T0017 T0018
;
;
;

F
E
0C03
1
HE
XNAGA
XX
T0018
03 00000000 0000A000 00000000 20150004 20051D97 08

;
;
;

F
E
0C03
1
HE
XNAGA
XX
T0018
05 00020000 80020000 00000000 20150204 200524A4 01

;
F
E
0C03
1
;00000000 00000002 00000000 00000000 00000000 00000000 00000000
RBDE> ^Y
>>>

4-12 Diagnostics

Example 4-10 Set Host Command — Running Diagnostics on a
Remote XMI Adapter, Passing Case
>>> set h demna0
Connecting to remote node, ^Y to disconnect.
t/r
RBDE> ST0/TR
;Selftest

3.00

; T0001 T0002 T0003 T0004 T0005 T0006 T0007 T0008 T0009 T0010
; T0011 T0012 T0013 T0014 T0015 T0016 T0017 T0018
;
P
E
0C03
1
;00000000 00000000 00000000 00000000 00000000 00000000 00000000
RBDE> ^Y
>>>

Diagnostics 4-13

Chapter 5
FRU Locations
This chapter shows the location of these field-replaceable units:
•

FRUs Common to Every Platform
— FRUs Accessible from the Front of the Cabinet
— FRUs Accessible from the Rear of the Cabinet

•

Platform Cables

•

FRUs in the XMI Plug-In Unit

•

FRUs in the Disk Plug-In Unit

•

FRUs in the Battery Plug-In Unit

FRU Locations 5-1

5.1 FRUs Common to Every Platform
Platform Cabinet (Front) Showing FRU Locations

Figure 5-1

or 8
4

Front

or 3

or 9

BXB-0021C-92

5-2 FRU Locations

70–28574–01

LSB centerplane and card cage 1, 2

E2045–AA

CPU module

E2043–AA or
E2043–BA or
E2043–CA or
E2046–AA

Memory module 64 Mbytes 3
Memory module 128 Mbytes 3
Memory module 256 Mbytes 3
Memory module 512 Mbytes 3

54–20306–01

Control panel 2

30–33796–01 or
30–33796–02

Power regulator

12–35173–01

Blower 1

DWLMA–AA/BA XMI plug-in unit 1 (see page 5-8 for FRUs in this
PIU)

BA654–AA

Disk plug-in unit 3, 4 (see page 5-10)

H7237–AA

Battery plug-in unit 1 (see page 5-12)

4
5

1 Removal and replacement of this FRU requires access to both the front and the rear of the
cabinet.
2 This FRU is in the main cabinet only (cannot be located in the expander cabinet).
3 This FRU can be located in either the front or the rear of the cabinet.
4 This FRU can be located in the top portion (front or rear) only in the expander cabinet.

FRU Locations 5-3

Figure 5-2

Platform Cabinet (Rear) Showing FRU Locations

5
Rear

or 11

7
8

10 11 or 12

BXB-0032F-92

5-4 FRU Locations

70–28574–01

LSB centerplane and card cage 1, 2

E2044–AA

IOP module

E2043–AA or
E2043–BA or
E2043–CA or
E2046–AA

Memory module 64 Mbytes 3
Memory module 128 Mbytes 3
Memory module 256 Mbytes 3
Memory module 512 Mbytes 3

54–20300–01

Cabinet control logic module (CCL)

54–36203–04

CCL pressure sensor

TF85–AA

Removable media device 1

Includes these FRUs:
TK85
54–19089–01
54–20868–01
17–03123–01
17–03164–01
17–03348–01
17–03443–01
17–03444–01
17–03448–01
17–03505–01
17–03508–01

Disk drive
DSSI controller module
Local disk converter
LDC to CCL signal
LDC to TF power +5/+12
DSSI signal to bulkhead (TK85)
Power LDC to bulkhead
Signal LDC to bulkhead
DSSI bus TF to bulkhead
5V VTERM power
48V power regulator to bulkhead

30–35143–01

DC distribution box

30–33798–01 or
30–33798–02 or
30–33798–03

AC input box

12–35173–01

Blower 1

DWLMA–AA/BA XMI plug-in unit 1 (see page 5-8)

BA654–AA

Disk plug-in unit 3, 4 (see page 5-10)

H7237–AA

Battery plug-in unit 1 (see page 5-12)

7
8

1 Removal and replacement of this FRU requires access to both the front and the rear of the

cabinet.
2 This FRU is in the main cabinet only (cannot be located in the expander cabinet).
3 This FRU can be located in either the front or the rear of the cabinet.
4 This FRU can be located in the top portion (front or rear) only in the expander cabinet.

FRU Locations 5-5

5.2 Platform Cables
Platform Cabinet (Rear and Front) Showing Cables

Figure 5-3

6
10

10 11

15 16 17
4
7
18

2
4
6

5
8

BXB-0021D-92

5-6 FRU Locations

17–03118–01

48V LSB power (gray)

17–03118–02

48V LSB power (yellow)

17–03119–01

48V power/signal to PIU

17–03127–01

AC to LDC

17–03126–01

48V power/sense to blower

17–03124–01

AC to CCL signal

17–03120–01

Control panel to CCL signal

17–03123–01

LDC to CCL signal

17–03164–01

+5/+12 LDC to tape power

17–03121–01

CCL to LSB bulkhead signal

17–03122–01

LSB bulkhead to LSB backplane

17–03085–01

I/O cable, long (to expander cabinet — 114 in)

17–03085–02

I/O cable, short (53 in)

17–03201–01

DEC power bus

17–03348–01

DSSI bulkhead signal

17–03443–01

LDC bulkhead power

17–03444–01

LDC bulkhead signal

17–03511–01

Control panel to CCL in expander cabinet

FRU Locations 5-7

5.3 FRUs in the XMI Plug-In Unit
Figure 5-4

XMI Plug-In Unit (Front) Showing FRU Locations

3
8

2
1

BXB-0343-92

5-8 FRU Locations

70–30396–01

XMI backplane assembly

30–36010–01

Module A (power regulator)

30–36009–01

Module B (power regulator)

T2028–AA

DWLMA module (LSB to XMI — slot 8)

T2030–YA

Clock and arbitration module (slot 7)

These FRUs can reside in any1 XMI slot except 7 or 8:
T2020–00

XMI to NI controller

T2027–00

XMI to FDDI controller

T2080–YA

XMI to CI controller

T2036–AA

XMI to DSSI controller

17–03162–01

Signal cable

17–03163–01

48V power cable

17–03202–01

Power distribution cable (rear of PIU)

17–03416–01

+5VB jumper (rear of PIU)

17–03533–01

Bulkhead to XMI signal (rear of PIU)

1 A module with an XMI corner must be in slot 1 or 14. For more information, see the VAX
7000 Platform Service Manual.

FRU Locations 5-9

5.4 FRUs in the Disk Plug-In Unit
Figure 5-5

Disk Plug-In Unit (Front) Showing FRU Locations

4
1
5
8
11

5
8

Underside of brick cover

11
3
5

8
BXB-0345-92

5-10 FRU Locations

RF73–EA

RF73 disk drive

Includes these FRUs:
54–19119–01
70–28814–01

RF73–EA ECM module
RF73 HDA

54–20868–01

Local disk converter (LDC)

54–21664–01

Disk control panel

17–02382–0x

DSSI brick jumper cable (BC21Q-xx)

17–03417–01

RF73 signal

17–03418–01

LDC power

17–03419–01

LDC signal

17–03420–01

RF73 power

17–03422–01

Signal and power

17–03423–01

Disk control panel to bulkhead

17–03424–01

DSSI bus

1 through 3 , 5 through 8 , 10 , and 11 are in each brick.
4 connects the bricks to each other.
9 runs up the center rear of the PIU.

FRU Locations 5-11

5.5 FRUs in the Battery Plug-In Unit
Figure 5-6

Battery Plug-In Unit (Rear) Showing FRU Locations

(Block B)
1

3
5

3
2
6
4
5
8
1
(Block A)

1
(Block C)

3
BXB-0344-92

NOTE: The battery plug-in unit is shown in Figure 5-6 without its enclosure.

5-12 FRU Locations

12–36168–02

Battery

12–39982–01

Fuse (LPN–RK–90)

17–03421–01

Battery sensor cable

17–03492–01

Intermediate cable, battery block A

17–03493–01

Intermediate cable, battery block B or C

17–03494–01

Power regulator A to battery block A

17–03494–02

Power regulator B to battery block B

17–03494–03

Power regulator C to battery block C

FRU Locations 5-13

Chapter 6
Controls and Indicators
This chapter describes controls and indicators on these system components:
•

Control Panel

•

TF85 Removable Media Device

•

Cabinet Control Logic Module

•

IOP Module

•

KA7AA Processor Module

•

Power Regulator

•

AC Input Box

•

BA651 XMI PIU Power Regulators

•

DWLMA Module

•

BA654 Disk PIU

Controls and Indicators 6-1

6.1 Control Panel
Figure 6-1

Control Panel

Disable
Secure

Front

Enable
Restart

Key On
Run
Fault

BXB-0015B-92

Table 6-1 Control Panel Indicator Lights
Light

State

Meaning

Key On

Power supplied to entire system; blower running.

(Green)

Off

Power supplied only to CCL module.

Run

Primary processor is running the operating system or user programs.

(Green)

Off

Primary processor is in console mode.

Fault

Fault on LSB, XMI, or an I/O bus.

(Yellow)

Slow flash

Power sequencing in progress or airflow error.

Fast flash

Power system error, airflow error, or detected
transition to keyswitch in Disable position.

Off

The system passed self-test.

6-2 Controls and Indicators

6.2 TF85 Removable Media Device
Figure 6-2

TF85 Controls and Indicators

se
d
g
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te le
in
e ec
ra nd
an e
rit ot ape
pe a
se le p
W Pr
T
U C Ta O H

ad ht
Lo
g
Li
To
t
ai s
W thi
n
pe e
O n dl e
p
a
H Ta
rt
se
In this
se
lo e
C dl
an
H
d
oa
nl on
U
t
t
To Bu ht
s
g
Li
es
Pr
t
ai s
W thi
n
pe e
O ndl ape
T
a
H ve
o
em

Front

85 nload
TF U
BXB0017-92

Table 6-2 TF85 Lights
Light

Color

State

Meaning

Write Protected

Orange

On
Off

Tape write protected
Tape write enabled

Tape in
Use

Yellow

Steady
Blinking

Drive ready
Drive in use

Use Cleaning Tape

Orange

On
Off

Drive needs cleaning
No cleaning needed

Operate
Handle

Green

On
Off
Blinking

OK to operate handle
Do not operate handle
Defective cartridge. Pull handle
to the open position and remove
cartridge. Try another cartridge.

Blinking

Drive fault. Reset by pressing the
Unload button.

All four
lights

Controls and Indicators 6-3

6.3 Cabinet Control Logic Module
Figure 6-3

CCL Module LEDs

Rear

Power LED
PIU 1
PIU 2
PIU 3
PIU 4

BXB-0044D-92

Table 6-3 CCL Module LEDs
LED

Meaning

Power LED

Power is present on the CCL module.

PIU 1 – 4

Power is present in the PIU regulators in the
quadrant indicated. (Q1 is to the left when viewing the cabinet from the front, Q2 is behind Q1,
Q3 is in the front right, and Q4 is behind Q3.)

6-4 Controls and Indicators

6.4 IOP Module
Figure 6-4

IOP (E2044-AA) Module LED

Table 6-4 IOP (E2044-AA) Module LED
Condition

Meaning

One of the following:
• All IOP-specific and I/O adapter tests passed.
• An I/O adapter test failed, and the error was isolated
to the adapter.

Off

One of the following:
• An IOP-specific test failed.
• An I/O adapter test failed, and the error could not be
isolated to the adapter.
• The processor module failed.

Controls and Indicators 6-5

6.5 KA7AA Processor Module
Figure 6-5

Processor (E2045) LEDs After Self-Test
Self-test passed

Self-test failed
MSB

Failing test number

LSB

STP

Table 6-5 Processor (E2045) LEDs After Self-Test
Test Result

LEDs

Self-test passed —
boot processor

STP LED and two LEDs above it are on.
All others are off.

Self-test passed —
secondary processor

STP LED and one LED above it are on.
All others are off.

Self-test failed

STP LED and two LEDs above it are off.
Failing test number1 is in top seven LEDs:
1 – 55

SROM/self-test tests 1 – 55

56 – 65

CPU/memory interaction tests 1 – 10

66 – 72

Multiprocessor tests 1 – 7

1 The failing test number is in binary-coded decimal.

6-6 Controls and Indicators

Table 6-6 Self-Test LEDs Indicating Defective DC-to-DC
Converter
Defective Converter on This
Module

Processor
Modules

Memory
Modules

One module’s
STP LED is off;
all others are
on.

All STP LEDs
are on.

STP LED is off.

Processor module with STP
LED off

All STP LEDs
are on.

One module’s
STP LED is off;
all others are
on.

STP LED is off.

Memory module
with STP LED
off

All STP LEDs
are on.

STP LED is off.

IOP module

IOP Module

Each module on the LSB has an on-board DC-to-DC converter. If the converter on one module is defective, the 2V reference voltage is disabled for
all nodes, preventing any node from using the LSB. Table 6-6 indicates
which module has the defective converter based on the state of the STP
LEDs of all modules in the LSB.
Use Table 6-6 when the Fault light on the control panel is on (see Section
6.1) and the console prompt is displayed but the self-test map is not. This
indicates that the LSB is good, but access to the bus is not possible.

Controls and Indicators 6-7

6.6 Power Regulator
Figure 6-6

Power Regulator LEDs

Run Light
Fault Light

Front

BXB-0064A-92

Table 6-7 Power Regulator Lights
Run Light
(Green)

Fault Light
(Yellow)

Meaning

Off

No AC power

Off

Fatal fault

Fast flash

Off

AC power present and keyswitch
in Disable position

Fast flash

Nonfatal fault or battery at end
of life

Slow flash

Battery discharge mode

Off

Normal operation

6-8 Controls and Indicators

6.7 AC Input Box
Figure 6-7

AC Input Box — Indicators on Circuit Breaker

Rear

A - Regulator slot A
B - Regulator slot B
C - Regulator slot C
S - Sensor circuit

Breaker
Indicator
C

BXB-0049A-92

Table 6-8 AC Input Box — Indicators on Circuit Breaker
Color

Meaning

Red

Pole is in on position; not tripped.

Green

Pole is in off position or tripped due to an overload.

NOTE: In the Japanese version (30–33798–03), all poles trip if one does,
causing all indicators to turn green.
Controls and Indicators 6-9

6.8 BA651 XMI PIU Power Regulators
Figure 6-8

XMI PIU Power Regulators
Regulator B

Regulator A

digital
INPUT VOLTAGE
48 VDC
INPUT CURRENT
28A MAX

Front

MOD OK
OC
OT
OV
48V

INPUT VOLTAGE
48 VDC
INPUT CURRENT
5A MAX
MOD OK
OC
OT
OV
48V

RESET
V-OUT
DISABLE

MOD OK
OC
OT
OV
48V

RESET
V-OUT
DISABLE
BXB-0074C-92

6-10 Controls and Indicators

Table 6-9 XMI PIU Power Regulator Lights (Regulators A and B)

Light

Color

State

Meaning

Does light
latch?

MOD OK

Green

Regulator is working.

Off

Regulator is not working.

Yellow

Overcurrent condition

Yes

Yellow

Overtemperature condition

Yes

Yellow

Overvoltage condition

Yes

48V

Green

48V is present.

Table 6-10 XMI PIU Power Switches (Regulator B)
Switch

Function

Reset

Momentary switch resets all lights on regulators
A and B.

Enable/Disable

When this switch is in the Disable position, the
output of both PIU power supplies is inhibited.

Controls and Indicators 6-11

6.9 DWLMA Module
Figure 6-9

DWLMA (T2028-AA) Module LEDs

STP
DBGDIS
POK
FTLERR
ES

Table 6-11 DWLMA (T2028-AA) Module LEDs
LED

Color

Desired Condition

STP — Self-Test Passed

Yellow

DBGDIS — Debug Disable

Green

POK — Power OK

Green

FTLERR — Fatal Error

Red

Off

ES — Error Summary

Red

Off

6-12 Controls and Indicators

6.10 BA654 Disk PIU
Figure 6-10 Disk Brick Control Panel
Power
Ready
Write Protect
Fault

Ready
Write Protect
Fault
Power

BXB-0045A-92

Table 6-12 Disk Brick Controls and Indicators

Control

Pushbutton
Position

Light

Function

Power
(Green)

In
Out

On
Off

DC power present
DC power not present

Ready
(Green)

In
Out

On
Off

ISE is on-line
ISE is off-line

Wrt Prot
(Yellow)

In
Out

On
Off

Write-protect enabled
Write-protect disabled

Fault
(Red)

Momentary
switch

On
Off
Slow flash
Fast flash

Fault condition
Normal operation
ISE calibrations in progress
Disk control panel failure

Controls and Indicators 6-13

Chapter 7
Restoring Corrupted ROMs
The following list tells you how to determine when to use these sections of
this chapter:
•

Restoring a Corrupted EEPROM
Use this section when the message "EEPROM image failed to verify" is
displayed on the console terminal.

•

Restoring Corrupted Firmware on an Adapter
Use this section when an adapter fails self-test and the problem is corrupted firmware.

•

Restoring Corrupted Firmware on a CPU
Use this section when you power up the system and the prompt
VAX-7000/10000-FRRC> is displayed on the console terminal.

Restoring Corrupted ROMs 7-1

7.1 Restoring a Corrupted EEPROM
Example 7-1 Using the Build EEPROM Command to Restore a
Corrupted EEPROM
EEPROM image failed to verify
EEPROM environment parameters not set up
Fail to update EEPROM envar on CPU 1
>>> build eeprom
Creating new EEPROM image
System Serial Number> gao1234567
Module Serial Number> sgo0000001
Module Unified 2-5-2-4 Part Number> 80-E2045-AA-0E04
Module Firmware Revision> 1.00
>>> initialize

NOTE: See Chapter 3 for more information on the console commands for
the EEPROM.

For more information:
VAX 7000 System Service Manual
VAX 7000 Console Reference Manual

7-2 Restoring Corrupted ROMs

7.2 Restoring Corrupted Firmware on an Adapter
If an adapter fails self-test, use this procedure to determine if the firmware
is corrupted, and if it is, to update the firmware:
1.

Boot the console CD-ROM (Example 7-2).

Use the LFU display or show command to indicate (by returning the
mnemonic "unknown") if firmware has been corrupted (Example 7-3).

Use the LFU update command to write the new firmware (Example
7-4).

Exit (Example 7-5).

Example 7-2 Booting LFU
>>> boot exa0 -file ISL_LVAX_V01
resulting file is mopdl:ISL_LVAX_V01/exa0
...... Load complete!
[boot information]
Network Initial System Load Function
Version 1.1
FUNCTION
FUNCTION
ID
1
Display Menu
2
Help
3
Choose Service
4
Select Options
5
Stop
Enter a function ID value: 3
OPTION
OPTION
ID
1
Find Services
2
Enter known Service Name
Enter an Option ID value: 1
Working
Servers found: 3
Service Name Format:
Service Number
Service Name
Server Name
Ethernet ID
#1
INFO4$RZ57
INFO4
08-00-2B-26-A6-98
#2
6000_DIAG_H

Restoring Corrupted ROMs 7-3

Example 7-2 Booting LFU (Continued)
INFO3
08-00-2B-16-04-D4
#3
VAX7000_V01
OPUS_ESS
08-00-2B-18-A9-75
Enter a Service Number or <CR> for more: 3
Copyright Digital Equipment Corporation
1992
All Rights Reserved.
Loadable Environment Rev: V1.0-1625
Jul 12 1992

10:50:56

***** Loadable Firmware Update Utility *****
Version 2.01
16-jun-1992
---------------------------------------------------------------Function
Description
---------------------------------------------------------------Display
Exit
List

Displays the system’s configuration table.
Return to loadable offline operating environment.
Lists the device types and firmware revisions
supported by this revision of LFU.
Modify
Modifies port parameters and device attributes.
Show
Displays device mnemonic, hardware and firmware
revisions.
Update
Replaces current firmware with loadable data
image.
Verify
Compares loadable and device images.
? or Help
Scrolls the function table.
---------------------------------------------------------------Function?

7-4 Restoring Corrupted ROMs

Example 7-3 LFU Display and Show Commands
Function? disp
Name
Type
LSB
0+
KA7AA (8002)
7+
MS7AA (4000)
8+
IOP
(2000)

Rev

Mnemonic

FW Rev

HW Rev

0000
0000
0001

ka7aa0
ms7aa1
iop0

1.00
N/A
N/A

E04
A01
A

C0 XMI
8+
DWLMA
C+
KDM70
E+
DEMNA

(102A)
(0C22)
(0C03)

A5A6
1E11
060B

xmi0
dwlma0
kdm700
demna0

N/A
3.00
6.08

C1 XMI
1+
?????
8+
DWLMA
A+
CIXCD

(0000)
(102A)
(0C05)

0000
A5A6
EB11

xmi1
unknown0
dwlma1
cixcd0

N/A
69.00

A
A01

Function? sho *
Firmware
Revision
ka7aa0 +
ms7aa0
iop0
xmi0
kdm700
demna0
unknown0
cixcd0 +

1.00
---3.00
--69.00

Hardware
Revision
E04
---Cannot be read
--A01

not supported.
not supported.
not supported.
not supported.
Updates only.

’+’ indicates the update firmware revision
is greater than the adapter’s firmware revision.
Function?

Restoring Corrupted ROMs 7-5

Example 7-4 LFU Update Command
Function? update unknown0
Enter device name or ’exit’ to skip this device.
Device name? cixcd
Hardware revision? A01
WARNING: updates may take several minutes to complete for each device
DO NOT ABORT!
unknown0 Updating to 70.00... Reading Device... Verifying 70.00...
PASSED.
Function?

Example 7-5 LFU Exit Command
Function? exit
Initializing...
F

8
A
o
.
o
.
+
.

7
M
+
.
+
.
+
.

6
.
.
.
.
.
.
.

5
.
.
.
.
.
.
.

4
.
.
.
.
.
.
.

3
.
.
.
.
.
.
.

2
.
.
.
.
.
.
.

1
P
+
E
+
E
+
E

.
.
.
.

+
.
.
.

.
.
.
.

+
.
.
.

.
.
.
.

+
.
.
.

.
.
.
.

+
.
.
.

.
.
.
.

0
P
+
B
+
B
+
B

NODE #
TYP
ST1
BPD
ST2
BPD
ST3
BPD
C0 XMI +
C1
C2
C3

. A0 . . . . . . . ILV
.128 . . . . . . . 128Mb
Firmware Rev = V1.0-1625 SROM Rev = V1.0-0 SYS SN = GAO1234567
>>>

For more information:
VAX 7000 System Service Manual
VAX 7000 Operations Manual

7-6 Restoring Corrupted ROMs

7.3 Restoring Corrupted Firmware on a CPU
Use this procedure when the prompt VAX-7000/10000-FRRC> appears at
the console terminal after power-up. (This prompt appears only if the console terminal is set at 9600 baud.) This prompt indicates that the firmware
in the FEPROMs on the processor module has been corrupted.
The following must be available for you to use this procedure:
•

A source system that can logically connect, through the console port, to
the system that has the corrupted firmware.
— The source system can be on site or remote.
— The source system must have access to an InfoServer.
— The program Kermit must reside on the source system.

•

The VAX 7000 console CD-ROM with the file
VAX7000_10000_CONSOLE_IMAGE.GROM.

Do the following to restore the corrupted firmware. All work is done at the
source system, and the procedure takes approximately 10 minutes.
1.

Set up the source system (Example 7-6):
a. Set the speed of the terminal at which you are working to 9600
baud.
b. Bind the CD-ROM volume name to a virtual disk container.
c. Mount the InfoServer.

Make a physical connection from the source system to the system with
the corrupted firmware. For example, use an RS232 cable to connect
from a DMB32 on the source system to the console port on the system
with the corrupted firmware.

Run Kermit (Example 7-7) and set the parameters as shown in the response to the show all command in the example.

Connect to the system with the corrupted firmware and downline load
the correct code (Example 7-8).

Restoring Corrupted ROMs 7-7

Example 7-6 Preparing the Source System to Restore Corrupted
Firmware on a CPU
$ set term/speed=9600/perm txa3:
$ mcr ess$ladcp
LADCP> bind VAX7000_V01
VAX7000_V01 is bound to DAD104
LADCP> exit
$ mount/ov=id dad104
$ dir dad104:[sys0.sysexe]
Directory DAD104:[SYS0.SYSEXE]
VAX7000_1000_CONSOLE_IMAGE.GROM

Example 7-7 Running Kermit and Setting Parameters
$ kermit
Kermit-32> set file type binary
Kermit-32> set retry packet 5
Kermit-32> set send time 5
Kermit-32> show all
VMS Kermit-32 version 3.3.111
Block check type
One character checksum
Debugging
OFF
Delay
5 (sec)
Server sends NAKs every 75 seconds while waiting for a
command
Escape character
035 (octal)
File type
BINARY
File naming
Normal form
Handshaking character
None
Incomplete file disposition
Discard
Line used
(Optional)
Local echo
OFF
Parity type
None
Retry maximums
Initial connection
Sending a packet

5 (dec)
5 (dec)

Send parameters
Packet length
Padding length

7-8 Restoring Corrupted ROMs

80 (dec)
0 (dec)

Example 7-7 Running Kermit and Setting Parameters (Cont)
Padding character
Time out
End of line character
Quoting character
Start of packet

000 (octal)
5 (sec)
015 (octal)
043 (octal)
001 (octal)

Receive parameters
Packet length
Padding length
Padding character
Time out
End of line character
Quoting character
8-bit quoting character
Start of packet

80 (dec)
0 (dec)
000 (octal)
5 (sec)
015 (octal)
043 (octal)
046 (octal)
001 (octal)

Transmit parameters
Delay
Echo
Repeat quoting character

0.0 (sec)
OFF
176 (octal)

Example 7-8 Downline Loading Code to Corrupted FEPROMs
Kermit-32> connect txa5:
VAX-7000/10000-FRRC> r
!Prepare system to receive
VAX-7000/10000-FRRC> Ctrl/] C !Return to Kermit
Kermit-32> send vax7000_10000_console_image.grom
!Transmit code
Kermit-32> connect
!Reconnect to target system
VAX-7000/10000-FRRC> c
!Verify checksum of image
VAX-7000/10000-FRRC> p
!Copy program image to
!FEPROMs
VAX-7000/10000-FRRC> i
!Reset node
VAX-7000/10000-FRRC> Ctrl/] C !Return to Kermit
Kermit-32> exit
!Return to DCL
$
For more information:
VAX 7000 System Service Manual

Restoring Corrupted ROMs 7-9

Chapter 8
System Errors
This chapter includes information on the machine check frame and the
parse trees. Sections include:
•

Machine Check Frame

•

Machine Check Parse Tree

•

Hard Error Parse Tree

•

Soft Error Parse Tree

•

I/O Port Parse Tree

•

DWLMA Parse Tree

System Errors 8-1

8.1 Machine Check Frame
Machine Check Frame

Figure 8-1
31

29 28

26 25

16 15

0
:SP

Parameter Byte Count (18 Hex)
AST

MCHK Code

Mod

CPU_ID

:SP + 4

INT SYS Register

:SP + 8

SAVEPC Register

:SP + 12

VA Register

:SP + 16

Q Register

:SP + 20

Opcode

:SP + 24

:SP + 28

PSL

:SP + 32

BXB-0196-92

For more information:
KA7AA CPU Technical Manual
VAX 7000 Advanced Troubleshooting

8-2 System Errors

Table 8-1 Machine Check Frame Parameters
Longword Bits

Contents

SP+0

<31:0>

Byte count. The size of the stack frame in bytes,
not including the PC, PSL, or the byte count longword. Stack frame PC and PSL values should always be referenced using this count as an offset
from the stack pointer.

SP+4

<31:29>

AST LVL. The current value of the register.

<23:16>

Machine check code. The reason for the machine
check, as listed in Table 8-2.

<7:0>

CPUID. Contains the current value of the CPUID
register.

SP+8

<31:0>

INT.SYS register. The value of the INT.SYS register, which is read onto the A-bus by the microcode.

SP+12

<31:0>

SAVEPC register. The SAVEPC register, which is
loaded by microcode with the PC value in certain
circumstances. It is used in error handling for PTE
read errors with PSL <FPD> set in this stack
frame.

SP+16

<31:0>

VA register. The contents of the Ebox VA register,
which may be loaded from the output of the ALU.

SP+20

<31:0>

Q register. The contents of the Ebox Q register,
which may be loaded from the output of the shifter.

SP+24

<31:28>

Rn. The value of the Rn register, which is used to
obtain the register number for the CVTPL and
EDIV instructions. In general, the value of this
field is unpredictable.

<25:24>

Mod. A copy of the currrent mode field, PSL
<CUR_MOD>.

<23:16>

Opcode. Bits <7:0> of the instruction opcode. The
FD bit is not included.

System Errors 8-3

Table 8-1

Machine Check Frame Parameters (Continued)

Longword Bits

Contents

<7>

VR. The VAX Restart bit, which is used to communicate restart information between the microcode
and the operating system. When set, this bit indicates that no architectural state has been changed
by the instruction that was executing when the error was detected. When clear, it indicates that architectural state was modified by the instruction.

SP+28

<31:0>

PC. The value of the program counter at the time
of the fault.

SP+32

<31:0>

PSL. The value of the processor status longword at
the time of the fault.

Table 8-2 Machine Check Codes in the Stack Frame
Code

Description

Restart Condition

Unknown memory management fault parameter returned by Mbox

(VR1 = 1) or (PSL<FPD>2 = 1)

Illegal interrupt ID value returned in INT.SYS

(VR = 1) or (PSL<FPD> = 1)

Illegal microcode dispatch

(VR = 1) or (PSL<FPD> = 1)

Illegal combination of state
bits detected during string
instruction

(PSL<FPD> = 1)

Asynchronous hardware error

Recovery is generally not possible.

Synchronous hardware error

Recovery and retry are possible.

1 VR is the VAX restart bit in the machine check stack frame.
2 FPD (First Part Done) is PSL <27>.

8-4 System Errors

8.2 Machine Check Parse Tree
Figure 8-2

Machine Check Parse Tree
Code
(Hex)

EXE$MCHK
MCHK_UNKNOWN_MSTATUS

MCHK_INT.ID_VALUE

MCHK_CANT_GET_HERE

MCHK_MOVC.STATUS

MCHK_ASYNC_ERROR

TBSTS.LOCK <0>
TBSTS.DPERR <1>

Select ONE
Unknown memory
management status error
Illegal interrupt ID error
Impossible microcode address
MOVCx status encoding error

Select ALL
TB PTE data parity error

TBSTS.DPERR <2>

TB tag parity error

None of the above

Inconsistent error

ECR.S3_STALL_TIMEOUT

S3 stall timeout

None of the above

Inconsistent error

MCHK_SYNC_ERROR

ICSR.LOCK <2>
ICSR.DPERR <3>
ICSR.TPERR <4>
Otherwise...
not PCSRS.PTE_ER <10>
BIU_STATE.FILL_ECC <8> and
not BIU_STAT.FILL_CRD <9>

Select ALL, at least one.
Select ALL
VIC data parity error
VIC tag parity error
Inconsistent error
Select ONE
Select ONE

BIU_STAT.FILL_DSP_CMD <19:16> = DREAD

BIU_STAT.FILL_DSP_CMD <19:16> = IREAD
Otherwise...

1 2 3

Inconsistent error
BXB-0301-92

System Errors 8-5

Figure 8-2 Machine Check Parse Tree (Continued)
1 2 3
BIU_STAT.FILL_SEO <14>
BIU_STAT.BIU_SEO <7>
BIU_STAT.BC_TPERR <2>

Lost B-cache ECC error
Lost B-cache fill error
Select ONE

BIU_STAT/BIU_DSP_CMD <6:4> = DREAD
D-stream read B-tag parity error

BIU_STAT/BIU_DSP_CMD <6:4> = IREAD
I-stream read B-tag parity error

BIU_STAT.BC_TCPERR <3>

Select ONE

BIU_STAT/BIU_DSP_CMD <6:4> = DREAD
D-stream read B-tag parity error

BIU_STAT/BIU_DSP_CMD <6:4> = IREAD
I-stream read B-tag parity error

BIU_STAT.BIU_HERR <0>
None of the above
PCSTS.PTE_ER <10>
BIU_STAT.FILL_ECC <8>
not BIU_STAT.CRD <9>

E
Inconsistent error
Select ONE
Select ONE

BIU_STAT.FILL_DSP_CMD<19:16> = DREAD
BIU_STAT.FILL_DSP_CMD<19:16> = IREAD
BIU_STAT.FILL_SEC <14>
BIU_STAT.BC_TPERR <2>
BIU_STAT.BIU_DSP_CMD<6:4>
= DREAD

C
D

Lost ECC errors during PTE read
Select ONE

PTE D-stream read B-tag parity error

BIU_STATE.BIU_DSP_CMD<6:4>
= IREAD
Otherwise...

1 2 3

8-6 System Errors

PTE I-stream read B-tag parity error
PTE write B-tag parity error
BXB-0302-92

Figure 8-2 Machine Check Parse Tree (Continued)
1 2 3
BIU_STAT.BC_TCPERR <3>

Select ONE

BIU_STAT.BIU_DSP_CMD<6:4>
= DREAD

PTE B-tag control parity error
during D-stream read

BIU_STATE.BIU_DSP_CMD<6:4>
= IREAD
Otherwise...

PTE B-tag control parity error
during I-stream read
PTE B-tag control parity error
during write

BIU_STAT.BIU_HERR<0>
Else
Else
Else

F
Inconsistent error
Inconsistent error
Inconsistent error
BXB-0309-92

System Errors 8-7

Figure 8-2 Machine Check Parse Tree (Continued)
A
BC_TAG <11>
LBER.UCE <1>
MERA.UCER
Other CPU LMERR.BDATA_DBE
Else

D-stream cache
double-bit error

D-stream read double-bit error
D-stream error on other CPU
D-stream read LSB
double-bit error

B
BC_TAG <11>
LBER.UCE <1>
MERA.UCER
Other CPU LMERR.BDATA_DBE
Else

C
BC_TAG <11>

LBER.UCE <1>
MERA.UCER
Other CPU LMERR.BDATA_DBE
Else

D
BC_TAG <11>

LBER.UCE <1>
MERA.UCER
Other CPU LMERR.BDATA_DBE
Else

8-8 System Errors

I-stream cache
double-bit error

I-stream read double-bit error
I-stream error on other CPU
I-stream read LSB
double-bit error
PTE D-stream cache
double-bit error

PTE D-stream read double-bit error
PTE D-stream error on other CPU
PTE D-stream read LSB
double-bit error
PTE I-stream cache
double-bit error

PTE I-stream read double-bit error
PTE I-stream error on other CPU
PTE I-stream read LSB
double-bit error BXB-0310-92

Figure 8-2 Machine Check Parse Tree (Continued)
E
BIU_STAT.BIU_DSP_CMD<6:4> = Read
LBER.NSES<18>
IMERR.ARBDROP<12>

Read ARB drop

Else
Inconsistent error

LBER.E<0> and LBERCR1.CID<10:7> = This_CPU
LBER.NXAE<12>
LBECR.CA<37:35> = CSR Read
LBER.CA<37:35> = Read
LBER.CA<37:35> = Private
LBER.CPE<5>
Else

NXM to LSB I/O space
NXM to LSB memory
NXM to self I/O space
LSB command parity error
Inconsistent

LBER.E
Else

Previous system error latched
Inconsistent

BIU.STAT.BIU_DSP_CMD<6:4>=Loadlock
LBER.NSES<18>
IMERR.ARBDROP<10>
IMERR.BTAGPE<5>
IMERR.BSTATPE<4>
Else

1 2

Read ARB drop
LEVI B-cache tag parity
error (lookup)
LEVI B-cache status parity
error (lookup)
Inconsistent

BXB-0312-92

System Errors 8-9

Figure 8-2 Machine Check Parse Tree (Continued)
1 2

E Continued
LBER.E<0> and
LBECR.CA<37:35> = Read and
LBECR1.CID<10:7> = This_CPU
LBER.NXAE<12>
LBER.CPE<5>
Else
LBER.3
Else
Else

Memory data
Write LSB NXM
LSB command parity error
Inconsistent
Previous system error latched
Inconsistent
Inconsistent
BXB-0313-92

8-10 System Errors

Figure 8-2 Machine Check Parse Tree (Continued)
F
BIU_STAT.BIU_DSP_CMD<6:4>=Read
LBER.NSES<18>
IMERR.ARBDROP<12>
Else

PTE read ARB drop
Inconsistent error

LBER.E<0> and
LBECR1.CID<10:7> = This_CPU
LBER.NXAE<12>
LBER.CPE<5>
Else

PTE NXM to LSB memory
PTE LSB command parity error
Inconsistent

LBER.E
Else

Previous system error latched
Inconsistent

BIU_STAT.BIU_DSP_CMB<6:4>=Loadlock
IMERR.ARBDROP<10>

PTE read ARB drop

IMERR.BTAGPE<5>

PTE LEVI B-cache tag parity
error (lookup)
PTE LEVI B-cache status parity
error (lookup)
Inconsistent

IMERR.BSTATPE<4>
Else
LBER.E<0> and
LBECR.CA<37:35> = Read and
LBECR1.CID<10:7> = This_CPU
LBER.NXAE<12>
LBER.CPE<5>
Else
LBER.E
Else

(Memory data)
PTE write LSB NXM
PTE LSB command parity error
Inconsistent
Previous system error latched
Inconsistent
BXB-0314-92

System Errors 8-11

8.3 Hard Error Parse Tree
Figure 8-3

Hard Error Parse Tree

EXE$HERR
BIU_STAT.LOST_WRITE_ERR
BIU_STAT.BC_TPERR and
BIU_STAT.BIU_DSP_CMD<6:4> = WRITE
BIU_STAT.BC_TCPERR and
BIU_STAT.BIU_DSP_CMD<6:4> = WRITE

Select ALL, at least one...
Uncorrectable ECC error on a
write from MBOX
B-cache tag parity error on a
write from MBOX
B-cache tag control parity error
on a write from MBOX

BIU_STAT.FILL_ECC
and not BIU_STAT.CRD
and BIU_STAT.BIU_DSP_CMD<6:4> = WRITE

Uncorrectable ECC error on a
write from MBOX

BIU_STAT.BIU_HERR
and BIU_STAT.BIU_DSP_CMD<6:4> = WRITE
LBER.E or LBER.NSES
Else

A
B

Inconsistent error
BXB-0318-92

8-12 System Errors

Figure 8-3 Hard Error Parse Tree (Continued)
A
BIU_STAT.BIU_DSP_CMD<6:4>=Write
LBER.NSES<18> and
LBECR.CA<37:35> = Read and
LBERC1.CID = This_CPU
IMERR.ARBDROP<10>
Else
LBER.NSES<18> and
LBERCR.CA<37:35> = Write and
LBECR1.CID<10:7> = This_CPU

Read ARB drop
Inconsistent error
(B-cache contains shared data)

IMERR.ARBDROP<10>

Write ARB drop

Else

Inconsistent error

LBER.E<0> and
LBECR.CA<37:35> = Read and
LBECR1.CID<10:7> = This_CPU
LBER.NXAE<12>

(LSB problem getting data)
Read LSB NXM

LBER.CPE<5>

LSB read command parity error

Else

Inconsistent error

LBER.E<0> and
LBECR.CA<37:35>=Write and
LBECR1.CID<10:7>=This CPU

(B-cache contains shared data)

LBER.NXAE<12>

Write LSB NXM

LBER<CPE<5>

LSB command parity error

Else
LBER.E<0> and
LBECR.CA=CSR Write and
LBECR1<10:7>=This CPU
LBER.CDPE
LBER.NXAE<12>
Else

1 2

(getting memory data for write)

Inconsistent
(I/O Cycle)
Write CSR data parity error
Write CSR NXM
Inconsistent
BXB-0319-92

System Errors 8-13

Figure 8-3 Hard Error Parse Tree (Continued)
1 2

A Continued
LBER.O
Else

Previous system error latched
Inconsistent

BIU_STAT.BIU_DSP_CMD<6:4>=Write Unlock
LBER.NSES<18>
IMERR.ARBDROP<10>
IMERR.BTAGPE<5>
IMMER.BSTATPE<4>
Else
Else
Else

Read ARB drop
LEVI B-cache tag parity
error (lookup)
LEVI B-cache status parity
error (lookup)
Inconsistent
Inconsistent
Inconsistent
BXB-0320-92

8-14 System Errors

Figure 8-3 Hard Error Parse Tree (Continued)
B
LBER.NSES
LMERR.ARBDROP or
LMERR.ARBCOL

Select ALL, at least one...
Serious LEVI failure

LMERR.PMAPPE<3:0>

P-cache backmap parity error

LMERR.BTAGPE

B-cache tag parity error

LMERR.BDATASBE

LMERR.BDATADBE

D
E

LMERR.BMAPPE
LMERR.BSTATPE
None of the above...
LBER.E
LBER.SHE
or LBER.DIE
LBER.STE or
LBER.CNFE or
LBER.CAE
LBER.TDE
LBER.CTCE
LBER.DTCE
LBER.CE
LBER.UCE
LBER.CDPE
None of the above...
LBER.CE
LBER.UCE
None of the above...

1 2

F
Inconsistent
Select ALL, at least one...
LSB cache protocol error

LSB synchronization failure
Select ONE...
Control transmit check errors
Select ONE...
Correctable datacheck error
on LSB write
Uncorrectable datacheck error
on LSB write
LSB write CSR data parity error
Inconsistent error
Correctable ECC error on LSB
Uncorrectable ECC error on LSB
Inconsistent error
BXB-0322-92

System Errors 8-15

Figure 8-3 Hard Error Parse Tree (Continued)
1 2

B Continued
LBER.CPE2
LBER.CDPE2
LBER.CE2
LBER.UCE2
LBER.UCE and not LBER.TDE
LBECR1.CA<37:35>=READ
LBECR1.CID=THIS_LNP
Otherwise...

Otherwise...
LBECR1.SHARED
Otherwise...
LBER.UCE and not LBER.TDE
LBECR1.CA<37:35>=Read
LBECR1.CID=This_CPU
Otherwise...
Otherwise...
LBECR1.SHARED
Otherwise...
LBER.CDPE
Any Adapter - LBER.E Set
None of the Above...

1 2

8-16 System Errors

Lost LSB command parity error
Lost LSB CSR data parity error
Lost LSB correctable ECC error
Lost LSB uncorrectable ECC error

Correctable ECC error
on LSB read fill
Bystander - correctable ECC error
on LSB read
Correctable ECC error during
B-cache update
Bystander - correctable ECC error
on LSB write

Uncorrectable ECC error
on LSB read fill
Bystander - uncorrectable ECC
error on LSB read
Uncorrectable ECC during
B-cache update
Bystander - uncorrectable ECC
error on LSB write
Bystander - LSB read CSR
data parity error
LSB ERR asserted by other node(s)
Inconsistent error

BXB-0323-92

Figure 8-3 Hard Error Parse Tree (Continued)
1

B Continued
LBER.E<0> and LBECR1.CID=IOP_node (IOP is cmdr)
IOP_LBER.STE<10>
IOP_LBER.CAE<13>
IOP_LBER.CNFE<11>
IOP_LBECR1.CA<37:35>=Write
IOP_LBER.NXAE<12>
IOP_LBER.CPE<5>
IOP_LBER.CE<3>
IOP_LBER.UCE<1>

Else

Inconsistent

IOP_LBERCR1.CA<37:35> = Read
IOP_LBER.NXAE<12>
IOP_LBER.CPE<5>
IOP_LBER.CE<3>
IOP_LBER.UCE<1>

Else

Inconsistent

IOP_LBECR1.CA<37:35> = Wrt CSR
IOP_LBER.NXAE<12>
IOP_LBER.CPE<5>
IOP.LBER.CE<3>
IOP_LBER.UCE<1>

Else

1 2

Inconsistent
BXB-0324-92

System Errors 8-17

Figure 8-3 Hard Error Parse Tree (Continued)
1 2

B Continued
IOP_LBER.CPE2<6>
IOP_LBER.CDPE2<8>
IOP_LBER.CE2<4>
IOP_LBER.UCE2<2>

Else

IOP_LBER.NESES<18>
Inconsistent
Inconsistent
BXB-0325-92

8-18 System Errors

Figure 8-3 Hard Error Parse Tree (Continued)
C
LBECR1.CA<37:35> = Read and
LBECR1.CID = not this node
LBECR1.CA<37:35> = Write and
LBECR1.CID<10:7> = This node
Else

LEVI read of B-cache correctable
error from LSB request
(dirty block)
LEVI LSB write correctable error
Inconsistent

D
LBECR1.CA<37:35> = Read and
LBECR1.CID = not this node
LBECR1.CA<37:35> = Write and
LBECR1.CID <10:7> = This node
Else

LEVI read of B-cache uncorrectable
error from LSB request
(dirty block)
LEVI LSB write uncorrectable error
Inconsistent

E
LBECR1.CA<37:35> = Read and
LBECR1.CID = not this node
LBECR1.CA<37:35> = Write and
LBECR1.CID<10:7> = not this node
Else

LEVI lookup B-cache B-map parity
error from LSB read request
LEVI lookup B-cache B-map parity
error from write request
LEVI lookup B-cache B-map parity
error from write

F
LBECR1.CA<37:35> = Read and
LBECR1.CID = not this node
LBECR1.CA<37:35> = Write and
LBECR1.CID<10:7> = not this node
Else

LEVI lookup B-cache STS parity
error from LSB read request
LEVI lookup B-cache STS parity
error from LSB write request
LEVI lookup B-cache STS parity
error from LSB write
BXB-0326-92

System Errors 8-19

8.4 Soft Error Parse Tree
Figure 8-4

Soft Error Parse Tree

EXE$SERR
ICR.LOCK
ICSR.DPERR0
ICSR.TPERR0
ICSR.DPERR1
ICSR.TPERR1
None of the above...
PCSTS.LOCK
PCSTS.DPERR
PCSTS.RIGHT_BANK
PCSTS.LEFT_BANK
Otherwise...
BIU_STAT.LOST_WRITE_ERR
PCSTS.PTE_ER_WR
not PCSTS.PTE_ER_WR
BIU_STAT.BIU_HERR and
BIU_STAT.BIU_CMD = READ
BIU_STAT.BIU_TPERR and
BIU_STAT.BIU_CMD = READ

Select ALL, at least one...
VIC data parity error - bank 0
VIC tag parity error - bank 0
VIC data parity error - bank 1
VIC tag parity error - bank 1
Inconsistent error
Select ALL, at least one...
P-cache data parity error
P-cache tag parity error in right bank
P-cache tag parity error in left bank
Inconsistent error
Write error after SERR
Hard error on a PTE DREAD for write or
write unlock
Select ALL, at least one...
Read timeout

Tag parity error on read

BIU_STAT.BIU_TCERR and
BIU_STAT.BIU_CMD = READ
BIU.STAT.FILL_ECC and BIU_STAT.CRD
BIU_STAT.FILL_CERR and not
BIU_STAT.CRD and
BIU_STAT.ARB_CMD = READ

Tag control parity error on read
Correctable ECC error on fill or
write merge
Uncorrectable ECC error on fill

BIU_STAT.BIU_SERR

System soft error interrupt (not used)

None of the above...

Inconsistent error

None of the above...

Inconsistent error
BXB-0329 -92

8-20 System Errors

8.5 I/O Port Parse Tree
Figure 8-5

IOP Parse Tree

IPL 17
IOP
IOP_LBER.NES<18>
IPCNSE.MULT_INTR_ERR<20>
IPCNSE.DN VRTX ERR<19>
IPCNSE.UP VRTX ERR<18>
IPCNSE.IPC IE<17>
IPCNSE.UP_HIC_IE<16>

Multiple interrupt error
Down vortex error
Up vortex error
IPC internal error
UP HIC internal error

IPCNSE.UP_CHAN_PAR_ERROR_3<15>
IPCNSE.UP_CHAN_PAR_ERROR_2<14>
IPCNSE.UP_CHAN_PAR_ERROR_1<13>
IPCNSE.UP_CHAN_PAR_ERROR_0<12>

Up channel 3 parity error
Up channel 2 parity error
Up channel 1 parity error
Up channel 0 parity error

IPCNSE.UP_CHAN_PKT_ERROR_3<11>
IPCNSE.UP_CHAN_PKT_ERROR_2<10>
IPCNSE.UP_CHAN_PKT_ERROR_1<9>
IPCNSE.UP_CHAN_PKT_ERROR_0<8>_

Up channel 3 packet error
Up channel 2 packet error
Up channel 1 packet error
Up channel 0 packet error

IPCNSE.UP_CHAN_OVFLO_3<7>
IPCNSE.UP_CHAN_OVFLO_2<6>
IPCNSE.UP_CHAN_OVFLO_1<5>
IPCNSE.UP_CHAN_OVFLO_0<4>
IPCNSE.MBX_TIP_3<3>
IPCNSE.MBX_TIP_2<2>
IPCNSE.MBX_TIP_1<1>
IPCNSE.MBX_TIP_0<0>

1 2

Up channel 3 FIFO overflow
Up channel 2 FIFO overflow
Up channel 1 FIFO overflow
Up channel 0 FIFO overflow
Mailbox transaction channel 3
in progress
Mailbox transaction channel 2 in
progress
Mailbox transaction channel 1
in progress
Mailbox transaction channel 0 in
progress
BXB-0316-92

System Errors 8-21

Figure 8-5 IOP Parse Tree (Continued)
1 2

IPL17 / IOP Continued

IPCHST.C3_STAT_ERROR<12>
IPCHST.C2_STAT_ERROR<8>
IPCHST.C1_STAT_ERROR<4>
IPCHST.C0_STAT_ERROR<0>
IPCHST.C3_STAT_PWROK_TRANS<15>
IPCHST.C2_STAT_PWROK_TRANS<11>
IPCHST.C1_STAT_PWROK_TRANS<7>
IPCHST.C0_STAT_PWROK_TRANS<3>

Channel 3 error line asserted
Channel 2 error line asserted
Channel 1 error line asserted
Channel 0 error line asserted
Channel 3 PWR transitioned
Channel 2 PWR transitioned
Channel 1 PWR transitioned
Channel 0 PWR transitioned

Else
Else

Inconsistent
Inconsistent
BXB-0317-92

8-22 System Errors

8.6 DWLMA Parse Tree
Figure 8-6

DWLMA Parse Tree

IPL17
DWLMA
XBER.NSES<12>
LBERR.DHDPE<28>
LBERR.MBPE<14>
LBERR.MBIC<13>
LBERR.MBIA<12>
LBERR.DFDPE<6>
LBERR.RBDPE<5>
LBERR.MBOF<4>
LBERR.FE<3>
Else

DOWN channel data parity error
Mailbox parity error
Mailbox illegal command
Mailbox illegal address
DOWN channel FIFO
data parity error
Read buffer data parity error
Mailbox overflow
DWLMA fatal error
Inconsistent

XBER.E<31>
XBER.WEI<25>
XBER.CC<27>
XBER.IPE<24>
XBER.CRD<19>
XBER.REP<16>

XMI write error interrupt
XMI corrected confirmation
XMI inconsistent parity error
XMI corrected read data response
XMI read error response

LBER.RSE<17>
XBER.PE<23>
Else

1 2

Read sequence error parity error
Read sequence error
BXB-0333-92

System Errors 8-23

Figure 8-6 DWLMA Parse Tree (Continued)
1 2
XBER.TTO
XBER.WDNAK<20>
XBER.PE<23>
Else

Write data NO ACK parity error
Write data NO ACK

XBER.CNAK<15>
XFAER.FCMD<31:28=Write>
XBER.PE<23>
Else

CNAK on write
Command NO ACK parity error
Command NO ACK

XBER.NRR<18>
XBER.PE<23>
Else
Else

No read response parity error
No read response
No XMI grant

XBER.RIDNAK<21>
XBER.PE<23>
Else

Read/IDENT data NO ACK
parity error
Read/IDENT data NO ACK

XBER.WSE<22>
XBER.PE<23>
Else
XBER.PS<23>
Else
Else

Write sequence error parity error
Write sequence error
XMI parity error
Inconsistent
Inconsistent

BXB-0334-92

8-24 System Errors

Index
A

AC input box, 5-5, 6-9
Addressing
LSB, 2-3
VAXBI, 2-7
XMI, 2-6
AMR, 1-30

Cabinet control logic module, 5-5,
6-4
Cables, platform, 5-6
CCL, 5-5, 6-4
CCL pressure sensor, 5-5
Cdp command
description, 3-2
example, 3-17
options, 3-4
syntax, 3-12
CHALT, 1-19
Clear command
description, 3-2
syntax, 3-12
Clear EEPROM command, 3-4
Console
commands, 3-2
command syntax, 3-12
special characters, 3-13
Continue command
description, 3-2
syntax, 3-12
Controls and indicators, 6-1
Control panel, 5-3, 6-2
Fault light, 6-7
CPU module, 5-3, 6-6
CPU specific registers, 1-6
Create command
description, 3-2
option, 3-5
syntax, 3-12

B
Battery plug-in unit, 5-3, 5-5
field-replaceable units, 5-12
BA650 battery plug-in unit
field-replaceable units, 5-12
BA651 XMI plug-in unit
field-replaceable units, 5-8
power regulators, 6-10
BA654 disk plug-in unit, 6-13
field-replaceable units, 5-10
BIU_ADDR, 1-18
BIU_CTL, 1-17
BIU_STAT, 1-18
Block diagram, 2-2
Blower, 5-3, 5-5
Boot command
description, 3-2
example, 3-14
options, 3-3
samples, 3-16
syntax, 3-12
BPCR, 1-20
Build EEPROM command
description, 3-2
example, 7-2
syntax, 3-12

Index-1

D
DC distribution box, 5-5
Deposit command
description, 3-2
options, 3-5
syntax, 3-12
Device names, 3-11
Device types, 2-5
Diagnostics
disk or tape drive, 4-10
remote node, 4-12
DIAG_CTL, 1-17
Disk brick control panel, 6-13
Disk plug-in unit, 5-3, 5-5, 6-13
field-replaceable units, 5-10
DWLMA module, 6-12
DWLMA parse tree, 8-23
DWLMA registers
LSB, 1-40
XMI, 1-43

E
ECR, 1-16
EEPROM, restoring corrupted, 7-2
Environment variables, 3-9
Examine command
description, 3-2
options, 3-5
syntax, 3-12
E2044 module, 6-5
E2045 module, 6-6

F
FADR, 1-31
Fault light, 6-7
Field-replaceable units, 5-1
FILL_ADDR, 1-19
FILL_SYND, 1-18
Firmware, restoring corrupted
on adapter, 7-3
on CPU, 7-7
FRRC, 7-7

Index-2

FRUs
in battery plug-in unit, 5-12
in disk plug-in unit, 5-10
in platform cabinet, 5-2, 5-4, 5-6
in XMI plug-in unit, 5-8

G
Gbus registers, 1-26

H
Hard error parse tree, 8-12
Help command
description, 3-2
syntax, 3-12

I
IBR, 1-29, 1-36, 1-45
ICCS, 1-14
ICR, 1-15
ICSR, 1-20
IIPR, 1-42
IMSK, 1-41
Initialize command
description, 3-2
syntax, 3-12
Internal processor registers, 1-11
IOP module, 5-5, 6-5
IOP parse tree, 8-21
IOP registers, 1-35
IPCDR, 1-39
IPCHST, 1-38
IPCMSR, 1-38
IPCNSE, 1-37
IPCVR, 1-37
IPRs, 1-11
IPR1, 1-42
IPR2, 1-42
I/O port module, 5-5, 6-5
I/O port parse tree, 8-21
I/O port registers, 1-35

K
KA7AA module, 6-6
KA7AA registers, 1-2
KA7AA specific registers, 1-6

L
LBECR0-1, 1-5, 1-30
LBER, 1-3, 1-28
LBESR0-3, 1-4, 1-29
LCNR, 1-4, 1-29
LCNTR, 1-9
LCON, 1-9
LCPUMASK, 1-37
LDEV, 1-3, 1-28
LDIAG, 1-8, 1-40
LEDs, 6-1
LERR, 1-41
LEVR, 1-41
LFU, booting, 7-3
LFU commands
Display, 7-5
Show, 7-5
Update, 7-6
LGPR, 1-42
LILID0-3, 1-36
LIOINTR, 1-5
LIPINTR, 1-5
LLOCK, 1-7
LMBPR, 1-37
LMERR, 1-7
LMISSADDR, 1-10
LMMR0-7, 1-4
LMODE, 1-6
LPERF, 1-9
LSB
address mapping, 2-4
address space
physical, 2-3
virtual, 2-3
device types, 2-5
node base addresses, 2-4
LSB card cage, 5-3, 5-5
LSB required registers, 1-2

LTAGA, 1-8
LTAGW, 1-8

M
Machine check frame, 8-2
Machine check parse tree, 8-5
MCBSA, 1-32
MCBSB, 1-34
MCESR, 1-15
MCR, 1-30
MDRA, 1-32
MDRB, 1-33
Memory module, 5-3, 5-5
MERA, 1-31
MERB, 1-33
MMAPEN, 1-22
MMEADR, 1-23
MMEPTE, 1-23
MMESTS, 1-23
MP0BR, 1-21
MP0LR, 1-21
MP1BR, 1-21
MP1LR, 1-21
MSBR, 1-22
MSLR, 1-22
MSTR0-1, 1-31
MSYNDA, 1-32
MSYNDB, 1-33
MS7AA registers, 1-27

N
Naming conventions, 3-11
NICR, 1-14
Node addresses
LSB, 2-4
VAXBI, 2-8
XMI, 2-6

P
PAMODE, 1-22
Parse trees
DWLMA, 8-23

Index-3

hard error, 8-12
I/O port, 8-21
machine check, 8-5
soft error, 8-20
PCADR, 1-24
PCCTL, 1-25
PCSCR, 1-16
PCSTS, 1-25
Physical address space, 2-3
Plug-in units
battery, 5-3, 5-5
disk, 5-3, 5-5
XMI, 5-3, 5-5
Power regulator, 5-3, 6-8
on LSB module, 6-7
Power regulators, XMI, 6-10
Processor module, 5-3, 6-6

R
Registers
CPU-specific, 1-6
DWLMA LSB, 1-40
DWLMA XMI, 1-43
Gbus, 1-26
IPRs, 1-11
I/O port, 1-35
KA7AA, 1-2
LSB required, 1-2
MS7AA, 1-27
VAXBI, 2-9
Removable media device, 5-5, 6-3
Repeat command
description, 3-2
syntax, 3-12

S
Self-test LED, 6-7
Self-test map not displayed, 6-7
Set command
description, 3-2
syntax, 3-12
Set EEPROM command
options, 3-6

Index-4

syntax, 3-12
Set host command
examples, 4-10
options, 3-6
syntax, 3-12
Show command
description, 3-2
syntax, 3-12
Show configuration command
example, 3-18
syntax, 3-12
Show device command
example, 3-19
syntax, 3-12
Show EEPROM command, 3-6
Show network command
example, 3-20
syntax, 3-12
Show power command
abbreviations in output, 3-22
example, 3-21
options, 3-7
syntax, 3-12
SID, 1-15
Soft error parse tree, 8-20
Start command
description, 3-2
syntax, 3-12
Stop command
description, 3-2
syntax, 3-12
STP LED, 6-7
System errors, 8-1

T
TBADR, 1-24
TBSTS, 1-24
Test command
description, 3-3
examples, 4-2
options, 3-7
syntax, 3-12
TF85, 6-3

TODR, 1-15
T2028 module, 6-12

U
Update command
description, 3-3
options, 3-8
syntax, 3-12

V
VAXBI
addresses, 2-7
node base addresses, 2-8
register address offsets, 2-9
VDATA, 1-20
Virtual address space, 2-3
VMAR, 1-19
VTAG, 1-19

X
XBER, 1-44
XDEV, 1-43
XFADR, 1-45
XFAER, 1-45
XMI addresses, 2-6
XMI plug-in unit, 5-3, 5-5
field-replaceable units, 5-8
power regulators, 6-10
XMI registers, 1-43

Index-5