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10,7/ddt11/ddtsym.mac
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;THIS SOFTWARE IS FURNISHED UNDER A LICENSE AND MAY ONLY BE USED
; OR COPIED IN ACCORDANCE WITH THE TERMS OF SUCH LICENSE.
;
;COPYRIGHT (c) DIGITAL EQUIPMENT CORPORATION 1984,1987.
;ALL RIGHTS RESERVED.
; THESE ARE THE SYMBOLS USED IN THE REPRESENTATION OF "."
; THE LEFT HALF OF DOT IS USED FOR FLAGS. THE SIGN BIT IS A "VALID" FLAG.
; THE 200K BIT INDICATED THAT THE ADDRESS IS AN "AC" ADDRESS AND SHOULD BE
; INCRIMENTED BY 1
; DOT (AC7) IS THE CURRENT SIMULATED PC
; DOTOLD MEM IS WHERE THE OLD DOT IS SAVES ON CASE OF A <ESC><LF>,
; A <ESC><CR>, OR A <ESC>^.
; DOTFOO MEM
; DTFOLD MEM
; ROUTINE DOTSAV
; MOVES DOT TO DOTOLD AND DOTFOO TO DTFOLD
; ROUTINE DOTINC
; IF THE SIGN BIT OF THE DOT WORD IS SET, DOTINC WILL USE IT, ELSE IT
; WILL START WITH DOT. IF THE SIGN BIT OF DOT IS NOT SET, IT WILL ALSO
; LOAD A -1 TO THE LEFT HALF OF THE ADDRESS. IT ALSO HAS THE OBNOXIOUS
; HABIT OF SCREWING WITH THE BITS, BASED ON THE TYPE OF FE IT THINKS
; IT IS PLAYING WITH
; ROUTINE NDTFOO
; ROUTINE TO UPDATE (WITH DOTINC) DOTFOO.
; ROUTINE NDTFIN
; UPDATES THE DOT POINTERS DTFINP (USED FOR INPUT)
; ROUTINE NXTDOT
; UPDATES DOT TO POINT TO THE NEXT WORD
UNIVERSAL DDTSYM SYMBOLS FOR DDT11
SEARCH MONSYM
SALL ;GET NICE LISTINGS FOR A CHANGE
.HWFRMT ;AND SKIP THE FANCY BITS
IFNDEF DEBUG,<DEBUG==0>
EXMAX== 140 ;MAXIMUM NUMBER OF BYTES TO EXAMINE AT ONCE
MASKSZ==10 ;NUMBER OF WORDS IN MASK
CMDSIZ==500 ;LARGEST COMMAND
NUMBUF==1 ;NUMBER OF BUFFERS FOR READING DUMPS, ETC.
; SETTING LARGER THAN 1 MAY CAUSE %GOTO TO FAIL
;REGISTER USAGE
AC0= 0 ; only for very tempory things
AC1= 1
AC2= AC1+1
AC3= AC2+1
AC4= AC3+1
SYM= 5 ;POINTER TO SYMBOL BLOCK
STATE= 6
DOT= 7 ;CURRENT LOCATION
DOT.AC==200000,,0 ;THE CURRENT LOCATION IS AN AC
DOT.OK==400000,,0 ;THE CURRENT DOT IS VALID
DOT.FG==777000,,0 ;ALL THE DOT FLAGS
; IF LH IS NONZERO IS A REGISTER ADR
FLG= 10
T1= 11
T2= T1+1
T3= T2+1 ; ALSO REFERED TO AS MA
T4= T3+1 ; ALSO REFERED TO AS MA+1
T5= T4+1
QX= 16 ; AN AC TO SCRATCH
P= 17
; THE AC'S WE DONT WANT TO HEAR ABOUT
.XCREF P,QX,T1,T2,T3,T4,T5,AC0,AC1,AC2,AC3,AC4,FLG
; THE MACROS WE DONT WANT TO HEAR ABOUT
.XCREF TYPE,CALL,RET
.XCREF TXN,TXNA,TXNN,TXNE,TXO,TXOA,TXOE,TXON
.XCREF TXC,TXCA,TXCN,TXCE,TXZ,TXZA,TXZE,TXZN
; SIMULATOR REGISTER USAGE
;WHEN SIMULATING REGS 0-7 ARE USED FOR CORRESPONDING PDP11 REG'S
; REGISTERS ALWAYS CLEAR EXCEPT FOR BITS 20-35
SP= 6 ;SIMULATED STACK POINTER
PC= 7 ;SIMULATED PC
; PC MUST ALWAYS BE EVEN
MA= T3 ;CONTAINS LAST ADR SETUP UP BY CALLS THROUGH RFETCH
; SO RSTORE USES SAME LOC. WORD ADDRESSES ARE LOADED THEN
; ROTATED RIGHT 2 POSITIONS. BYTE ADDRESS ARE DIVIDED BY 4.
; REMAINDER OF DIVISION IS KEPT IN MA+1
MA..UN==040000 ;ADDRESS IS A UNIBUS DEVICE
MA..RG==020000 ;LOCATION IS REGISTER
MA..IO==010000 ;LOCATION IS IN PERIPHERAL AREA (I.E. 170000-177777)
IR= T5 ;CONTAINS INSTRUCTION WHEN SIMULATING
PS= 16 ;SIMULATED PS
PS...T==000020 ;TRAP BIT
PS...N==000010 ;RESULT WAS NEGATIVE
PS...Z==000004 ;RESULT WAS ZERO
PS...V==000002 ;RESULT WAS ARITH OVERFLOW
PS...C==000001 ;RESULT WAS A CARRY
F.FLIP==1B35 ;LOCAL FLAG
; USED BY $V TO FLAG 1ST PASS
; USED BY $N TO DISTINGUISH FROM $W
; USED BY OPNFIL TO DEMAND PROMPT
; USED BY $D TO REMEMBER DOING COMMAND LOGGING
; USED WHEN READING BINARY FILE
F.FLOP==1B34 ;LOCAL FLAG
; SET IF USER SAYES /BINARY IN INITIAL COMMAND
; SET IF READING A PACKED FILE
F..FOO==1B33 ;LOCAL FLAG WHEN SET MEANS
; DUMP IS DISASSEMBLY
; READING A DTELDR DUMP
F.LOPN==1B32 ;CURRENT LOCATION IS OPEN
F.MOPN==1B31 ;MASK OPEN
F.MASK==1B30 ;ESCAPE M TYPED
F.TEXT==1B29 ;ASSEMBLING TEXT
F.IOCT==1B28 ;ASSEMBLING AN OCTAL NUMBER
F.IDEC==1B27 ;ASSEMBLING A DECIMAL NUMBER
F.IHEX==1B26 ;ASSEMBLING A HEX NUMBER
F.SYMB==1B25 ;ASSEMBLING A SYMBOL
F.CACH==1B24 ;USE CACHE IF POSSIBLE
F.WRIT==1B23 ;WE ARE OPENING FILE FOR OUTPUT
F.APND==1B22 ;APPEND TO TO FILE IF ALREADY EXISTS
F.LOCK==1B21 ;PROGRAM IS LOCKED
F.WENB==1B20 ;PATCHING WAS ENABLED WITH /PATCH
F..ESC==1B19 ;TYPED ESCAPE TWICE
F.PACK==1B18 ;BINARY FILE IS PACKED
F.LBKT==1B17 ;LOCATION OPENED WITH A LEFT BRACKET
F.HASH==1B16 ;OPCODE PRECEEDED BY A # SIGN
F.PERC==1B15 ;OPCODE PRECEEDED BY A % SIGN
F.LPAR==1B14 ;OPCODE PRECEEDED BY A ( SIGN
F.SYML==1B13 ;SYM HAS BEEN LOADED . SET BY GETEXP
F.GEXP==1B12 ;GOT AN EXPRESSION . SET BY GETEXP
F.TOPN==1B11 ;DID OPEN ON TTY(TO CONTROL ECHO)
F.SVIO==1B10 ;HIT A STACK VIOLATION
F.SREG==1B9 ;SYMBOLIC TYPEIN WAS A REGISTER NAME
F..SIM==1B8 ;AM RUNNING SIMULATION
F.EXEC==1B7 ;RUNNING IN EXEC MODE
F.RUNF==1B6 ;RUN FLOP FOR SIMULATION
F.CERR==1B5 ;HIT AN ERROR IN COMMAND FILE
F.FELE==1B4 ;HAVE DONE FIRST ELEMENT OF EXPRESSION
F.NOUT==1B0 ;SUPRESS OUTPUT
; RAMDOM FLAGS AND OTHER GARBAGE
IO.RLB==1000
IO.WLB==400
;TTYBIT FLAGS
TF.RUB==1B1 ;DO RUBOUTS WITH BACKSPACE-SPACE-BACKSPACE
; DEBUG FLAGS FOR USE WITH THE /DEBUG SWITCH
DB.INI==1B35 ; INIT CODE DEBUG MESSAGES
DB.SYM==1B34 ; SYMBOL TABLE INFORMATION
DB.MEM==1B33 ; MEMORY INFORMATION
DB.EXD==1B32 ; EXAMINE/ DEP CODE...
DB.CAL==1B31 ; REPORT ALL CALLS
;FLAGS FOR TYPE OF OPERATING SYSTEM
T.OTHER==1B0 ;THIS IS OTHER
T.TOP10==1B1 ;THIS IS TOPS-10
T.ITS==1B2 ;THIS IS ITS
T.TENEX==1B3 ;THIS IS TENEX
T.TOP20==1B4 ;THIS IS TOPS-20
T.EXEC==1B5 ;THIS IS EXEC MODE
; CPU TYPES THAT WE RUN ON...
P.KS10==1B0 ; KS10 - deliberately the sign bit
P.KL10==1B1 ; KL10
P.KI10==1B2 ; KI10
P.KA10==1B3 ; KA10
P.PDP6==1B4 ; PDP-6
; GENERAL ERROR CODES WE CAN SEE - USED BY THE PARSER, AND IN CALERR
ER.NXM==1 ; NONEXISTENT MEMORY REFERENCE
ER.ODD==2 ; ODD ADDRESS TRAP
ER.DTE==3 ; DTE TIME OUT ERROR
; VALUES FOR OUTPUT MODES
MODINS==0 ; INSTRUCTION MODE OUTPUT
MODADR==1 ; ADDRESS MODE OUTPUT
MODNUM==2 ; NUMERIC MODE OUTPUT
MODBYT==3 ; BYTE MODE OUTPUT
MODASC==4 ; ASCII MODE OUTPUT
MODEBC==5 ; EBCIDIC MODE OUTPUT
MODR50==6 ; RADIX 50 TYPEOUT
; DEFINE THE TYPES OF DATA THAT CAN BE STORED IN "DATA"
DAT.XX==0 ; NO DATA THERE, OR DONT KNOW
DAT.NU==1 ; A NUMBER
DAT.AS==2 ; AN ASCII STRING
DAT.IN==3 ; AN INSTRUCTION
;DEFINE THE TYPES OF EXAMINES WE CAN DO
EX.MEM== 0 ;MEMORY
EX.PORT== 1 ;CALL11 UUO
EX.NODE== 2 ;NODE UUO
EX.FE0== 3 ;RSX20F EXAMINE
EX.D61== 4 ;DN60 ON TOPS-10
EX.D62== 5 ;DN60 ON TOPS-20
EX.MCB== 6 ;DN20 DECNET 20 EXAMINE
EX.FE1== 7 ;RSX20F/TOPS-10
FE.MAX==40 ;Max data bytes 20F allows for ME msg
EX.MC1== 10 ;MCB running on TOPS-10
; SYMBOL TABLE FORMAT...
;SYMBOLS ARE KEPT IN FOUR WORD BLOCKS
; SYMBEG POINTS TO FIRST BLOCK
; SYMEND POINTS TO LAST BLOCK
; 1ST WORD IN BLOCK IS SIXBIT SYMBOL
; 2ND WORD IS VALUE
; 3RD WORD IS HALF WORD FLAGS,,MASK FOR MATCH
SMF.SU==000001 ;SYMBOL IS SUPPRESSED(DEFINED WITH =)
SMF.RG==000002 ;SYMBOL IS A REGISTER VALUE
SMF.IN==000004 ;SYMBOL IS AN INSTRUCTION
SMF.EI==000010 ;EIS INSTRUCTION FORMAT
SMF.DD==000020 ;LOW ORDER SIX BITS ARE DESTINATION
SMF.SS==000040 ;LOW ORDER 12 BITS ARE SSDD
SMF.BR==000100 ;LOW ORDER 8 BITS ARE XXX(I.E. BR)
SMF.SB==000200 ;SOB TYPE ADDRESS
SMF.RT==000400 ;RTS TYPE REGISTER USAGE
SMF.JS==001000 ;JSR TYPE REGISTER USAGE
SMF.EM==002000 ;EMT TYPE ARGUMENT
SMF.MK==010000 ;MARK
SMF.PL==020000 ;SET PROCESSOR LEVEL
SMF.P8==040000 ;PDP8 SYMBOL
SMF.11==100000 ;PDP11 SYMBOL
SMF.BY==200000 ;BYTE INSTRUCTION
; 4TH WORD IS SYMBOL SOURCE
OPDEF APRID [700000,,0] ;READ MICROCODE VERSION AND CPU SERIAL NU
OPDEF WRAPR [700200,,0] ;WRITE APR
;1B19 ;IO RESET
;1B20 ;ENABLE SELECTED CONDITIONS
;1B21 ;DISABLE SELECTED CONDITIONS
;1B22 ;CLEAR SELECTED CONDITIONS
;1B23 ;SET SELECTED CONDITIONS
;1B25 ;INTERRUPT 8080
;1B26 ;POWER FAIL
;1B27 ;NXM
;1B28 ;BAD MOS DATA
;1B29 ;CORRECTED MOS DATA
;1B30 ;TIMER
;1B31 ;8080 INTERRUPT
;1B32 ;GENERATE APR INTERRUPT
;7B35 ;APR LEVEL
OPDEF RDAPR [700240,,0] ;READ APR
OPDEF WRPI [700600,,0] ;WRITE PI
OPDEF PIOFF [700600,,400]
OPDEF PION [700600,,200]
OPDEF RDPI [700640,,0] ;READ PI
OPDEF WRUBR [701140,,0] ;WRITE USER BASE REGISTER
OPDEF CLRPT [701100,,0] ;CLEAR PAGE TABLE
OPDEF RDUBR [701040,,0] ;READ USER BASE REGISTER
OPDEF WREBR [701200,,0] ;WRITE
OPDEF RDEBR [701240,,0] ;READ
OPDEF TIOE [710000,,0] ;TEST UNIBUS, SKIP EQUAL
OPDEF TIOEB [720000,,0] ;TEST UNIBUS, SKIP EQUAL
OPDEF TION [711000,,0] ;TEST UNIBUS, SKIP NOT EQUAL
OPDEF TIONB [721000,,0] ;TEST UNIBUS, SKIP NOT EQUAL
OPDEF RDIO [712000,,0] ;READ UNIBUS
OPDEF RDIOB [722000,,0] ;READ UNIBUS BYTE
OPDEF WRIO [713000,,0] ;WRITE UNIBUS
OPDEF WRIOB [723000,,0] ;WRITE UNIBUS BYTE
OPDEF BSIO [714000,,0] ;BIT SET TO UNIBUS
OPDEF BSIOB [724000,,0] ;BIT SET TO UNIBUS BYTE
OPDEF BCIO [715000,,0] ;BIT CLEAR TO UNIBUS
OPDEF BCIOB [725000,,0] ;BIT CLEAR TO UNIBUS BYTE
OPDEF WRSPB [702400,,0] ;WRITE SPT BASE REGISTER
OPDEF RDSPB [702000,,0] ;READ SPT BASE REGISTER
OPDEF WRCSB [702440,,0] ;WRITE CORE STATUS TABLE BASE REGISTER
OPDEF RDCSB [702040,,0] ;READ CORE STATUS TABLE BASE REGISTER
OPDEF WRPUR [702500,,0] ;WRITE PROCESS USE REGISTER
OPDEF RDPUR [702100,,0] ;READ PROCESS USE REGISTER
OPDEF WRCSTM [702540,,0] ;WRITE CST MASK REGISTER
OPDEF RDCSTM [702140,,0] ;READ CST MASK REGISTER
OPDEF WRTIME [702600,,0] ;WRITE TIME BASE
OPDEF RDTIME [702200,,0] ;READ TIME BASE
OPDEF WRINT [702640,,0] ;WRITE INTERVAL TIMER
OPDEF RDINT [702240,,0] ;READ THE INTERVAL REGISTER
OPDEF UMOVE [704000,,0] ;MOVE FROM PREVIOUS CONTEXT
OPDEF UMOVEM [705000,,0] ;MOVE TO PREVIOUS CONTEXT
;EPT - EXECUTIVE PROCESS TABLE
;0-37 CHANNEL LOGOUT AREA
;40-41
EPTINT==42 ;42-57 INTERRUPT LOCATIONS
;60-77 (KL10 - DTE AREA)
EPTVEC==100 ;100 128 WORD TABLE OF VECTORS
;101-177 RESERVERED FOR FUTURE USE
;200-377 EXEC PAGE 400-777
;400-420
EPTAOV==421 ;421 EXEC ARITH OVERFLOW TRAP INS
EPTPDO==422 ;422 EXEC PUSHDOWN OVFL INS
EPTTP3==423 ;423 EXEC TRAP-3 INS
;424-427 HALT STATUS AREA
;430-437
;460-507
;510 TIME BASE HIGH-ORDER WORD
;511 TIME BASE LOW-ORDER WORD
;512 PERF ANA COUNTER HIGH-ORDER WORD
;513 " LOW-ORDER WORD
;514 INTERVAL TIMER VEC INT LOC
;515-577 RES FOR USE BY HDW
EPTSTP==540 ;540-557 SECTION TABLE POINTER FOR SECTION 0-17
EPM000==600 ;600-757 EXEC PAGE 0-337
;760-777 RESERVED
;UPT - USER PAGE TABLE
;0-377 USER PAGE 0-777
;400-417 EXEC PAGE 340-377
;420 FREE
;421 USER ARTIH OVFLW TRAP INST
;422 USER PUSHDOWN OVFLW TRAP INS
;423 USER TRAP-3 INS
.UPMUO==1424 ;424 USERS FLAGS,,MUUO OPCODE
.UPMUP==1425 ;425 PC WORD OF MUUO STORED HERE
;426 MUUO EFFECTIVE ADDR
;427 PROCESSOR CONTEXT
;430 KERNEL NO TRAP MUUO NEW PC WORD
;431 KERNEL TRAP MUUO NEW PC WORD
;432 SUPERVISOR TRAP MUUO NEW PC WORD
;433 SUPERVISOR NO TRAP MUUO NEW PC WORD
;434 CONCEALED TRAP MUUO NEW PC WORD
;435 CONCEALED NO TRAP MUUO NEW PC WORD
;436 PUBLIC TRAP MUUO NEW PC WORD
;437 PUBLIC NO TRAP MUUO NEW PC WORD
;440-477 FREE
UPTPFW==1500 ;500 EXEC OR USER PAGE FAILWORD STORED HERE
;B0 USER MODE
;B1 IO = ADAPTER
UPTPFL==1501 ;501 PAGE FAIL OLD FLAGS WORD
UPTPFO==1502 ;502 PAGE FAIL OLD PC WORD
UPTPFN==1503 ;503 PAGE FAIL NEW PC WORD
;504 EBOX CLOCK TICKMETER HIGH ORDER WORD
;505 EBOX CLOCK TICKMETER LOW-ORDER WORD
;506 MBOX CYCLEMETER HIGH ORDER WORD
;507 MBOX CYCLEMETER LOW-ORDER WORD
;510-577 RESERVED FOR HDW
;600-777 FREE
; PAGE TABLE WORDS
;400000 ACCESS ALLOWED
;200000 PUBLIC
;100000 WRITABLE
;040000 SOFTWARE
;020000 CACHE ENABLED
;017777 PHYSICAL PAGE ADR BITS 14-26
;UNIBUS ADAPTER
BR5LVL==4
BR5OFF==1B26!1B32
BR5ON== 1B25!1B32
BR5INT==1B24 ;INTERRUPT IN PROGRESS FOR BR5
BR7LVL==3
BR7OFF==1B26!1B31
BR7ON== 1B25!1B31
BR7INT==1B23 ;INTERRUPT IN PROGRESS FOR BR7
UBAMAP= 763000 ;MAPPING REGISTERS
UB.RPW==400000 ;MAINTENANCE PAUSE FOR EVEN AND ODD MEMORY WRITE
UB.16B==200000 ;DISABLE UPPER TWO BITS ON TRANSFER
UB.FST==100000 ;FAST XFER
UB.VLD==040000 ;VALID
;003777 ;PAGE NUMBER
UBA.SR= 763100 ;STATUS REGISTER
;400000 ;TIMEOUT
;200000 ;BAD MEMORY ON NPR TRANSFER
;100000 ;SM10 BACKPANEL BUS ERROR
;040000 ;CPU ADDRESSED NONEXISTENT DEVICE
;004000 ;BR6 OR BR7
;002000 ;BR5 OR BR4
;001000 ;AC OR DC LOW
;000200 ;DISABLE TRANSFER ON UNCORRECTABLE DATA
;000100 ;UBA INITIALIZE
UBA.B7==1B28+BR7LVL*10
UBA.B5==1B28+BR5LVL
UBALVL==1B28+BR7LVL*10+BR5LVL ;PI LVL ASSIGNMENTS
UBA.IR= 763200 ;VECTOR REGISTER
UBA.MR= 763101 ;MAINTENANCE REGISTER
;000001 ;CHANGE NPR REQUEST
;000002 ;ENABLE NPR WRAP AROUND
;DZ11
DZ.CSR==0 ;CONTROL AND STATUS REGISTER
DZ.RBF==2 ;READER BUFFER
DZ.LPR==2 ;LINE PARAMETER REGISTER
DZ.TCR==4 ;TRANSMIT CONTROL REGISTER
DZ.MSR==6 ;MODEM STATUS REGISTER
DZ.TDR==6 ;TRANSMIT DATA REGISTER
;RJP04
RPCS1== 776700
RPWC== 776702
RPBA== 776704
RPDA== 776706
RPCS2== 776710
RPDS== 776712
RPER1== 776714
RPAS== 776716
RPLA== 776720
RPDB== 776722
RPMR== 776724
RPDT== 776726
RPSN== 776730
RPOF== 776732
RPDC== 776734
RPCC== 776736
RPER2== 776740
RPER3== 776742
RPEC1== 776744
RPEC2== 776746
;INTERPROCESSOR COMMUNICATIONS AREA
;WORD 31 - KEEP ALIVE AND STATUS WORD
FEWSTS= 31
;WORD 32 - KS-10 INPUT WORD
FEWINP= 32
;BITS 20-27 = 0 NO ACTION
;BITS 20-27 = 1 CTY CHAR
;BITS 28-35 = CHAR
;WORD 33 - KS-10 OUTPUT WORD
FEWOUT= 33
;BITS 20-27 = 0 NO ACTION
;BITS 20-27 = 1 CTY CHAR
;BITS 28-35 = CHAR
;WORD 34 - KS-10 KLINIK LINE INPUT WORD
;WORD 35 - KS-10 KLINIK LINE OUTPUT WORD
;TOPS-20 version DN60 protocol definitions
.BTD60==16 ;DN60 PROTOCL OPERATION
.VND60==2 ;DN60 protocol type
;BTD60 ARG BLOCK
; DEFSTR (BT6DTE,0,35,36) ;DTE number
; DEFSTR (BT6ERR,1,35,36) ;returned error flags
; DEFSTR (BT6HBC,2,17,18) ;DN60 header byte count
; DEFSTR (BT6HDR,2,35,18) ;DN60 header address(begins on word)
; DEFSTR (BT6DBC,3,35,36) ;data byte count
; positive => write data mode
; zero => no data transfer
; negative => read data mode
; DEFSTR (BT6PTR,4,35,36) ;data byte ptr
;the following are returned for timing analysis
; DEFSTR (BT6TMR,5,35,36) ;time of request
; DEFSTR (BT6TAS,6,35,36) ;TIME DTE ASSIGNED
; DEFSTR (BT6THQ,7,35,36) ;time header queued to 11
; DEFSTR (BT6TRD,10,35,36) ;time of -10 done for response header
; DEFSTR (BT6TDD,11,35,36) ;time of -10 done for data
; DEFSTR (BT6TFR,12,35,36) ;time finished request
BT6DTE==0
BT6ERR==1
BT6HDR==2
BT6DBC==3
BT6PTR==4
BT6TMR==5
BT6TAS==6
BT6THQ==7
BT6TRD==10
BT6TDD==11
BT6TFR==12
BT6SIZ==13 ;size of BOOT arg block
;DN60 header definitions
; DEFSTR (D6FCN,0,15,16) ;xmitted function code
; DEFSTR (D6RSP,0,7,8) ;returned response code
; DEFSTR (D6FCD,0,15,8) ;returned function code
; DEFSTR (D6ADR,0,31,16) ;address for examine/deposit
; DEFSTR (D6DAT,1,15,16) ;data from examine/for deposit
; DEFSTR (D6DEV,0,23,8) ;device code
; DEFSTR (D6LIN,0,31,8) ;line number
; DEFSTR (D6CNT,1,15,16) ;requested byte count to transfer
;end of original header definitons
;begin extended header
; DEFSTR (D6AR3,1,31,16) ;reserved
; DEFSTR (D6DST,2,31,32) ;returned device status
; DEFSTR (D6LST,3,32,32) ;returned line status
D6HWSZ==4 ;number of 36 bit words in header
D6HBSZ==4*D6HWSZ ;number of 8 bit bytes in header
;DN60/DTE database/work space definitions
;D6STS below is returned in BT6ERR when an error occurs
; DEFSTR (D6STS,0,35,36) ;port status
;protocol flags
D6.BSY==1B0 ;port is busy - sign bitness is used in testing
D6.QHD==1B1 ;header has been queued
D6.HDD==1B2 ;to -11 done for header seen
D6.NDT==1B3 ;this is a no-data-transfer operation
D6.RED==1B4 ;this is a read data type operation
D6.QDT==1B5 ;data has been queued(for write fcn)
D6.DTD==1B6 ;to -11 done for write data seen
D6.RBL==1B7 ;to -10 doorbell for response header seen
D6.RDN==1B8 ;to -10 done for response header seen
D6.DBL==1B9 ;to -10 doorbell for read data seen
D6.DDN==1B10 ;to -10 done for read data seen
D6.FDN==1B11 ;to -10 done for read data was faked
;error flags
D6.BDP==1B30 ;bad data byte ptr
D6.ARD==1B31 ;11 attempted to send read data when
; when none was expected
D6.TRS==1B32 ;timed out waiting for response header
D6.TDT==1B33 ;timed out waiting for read data
D6.TPO==1B34 ;timed out waiting for port to be free
D6.NT6==1B35 ;not a DN60 front end
D6.SER==D6.BDP!D6.ARD!D6.TRS!D6.TDT!D6.TPO!D6.NT6 ;all errors
;DN60 function codes
D6.EXM==11 ; DN60 examine memory function code
D6.DEP==12 ; DN60 deposit memory function code
;FORMATS OF PDP-11 STB FILES (FROM VARIOUS SOURCES...
comment \
STB files are written in records of variable counted length. The format
in the file is :
two clear bits, high byte, low byte per halfword
The count, which is first, is two bytes long, and will be on a word
boundry. The records should be an even number of bytes long. The
following is a list of the record types available.
\
STB.XX==0 ; ILLEGAL RECORD TYPE
STB.GS==1 ; GLOBAL SYMBOL RECORD
STB.EG==2 ; END OF GLOBAL SYMBOLS
STB.TX==3 ; TEXT INFORMATION
STB.RL==4 ; RELOCATION INFORMATION
STB.IS==5 ; INTERNAL (LOCAL) SYMBOLS
STB.EM==6 ; END OF MODULE
STB.MX==6 ; MAXIMUM RECORD TYPE
; The following are the types defined for GSD (type 1) records
GSD.MN==0 ; MODULE NAME
GSD.CS==1 ; CSECT NAME
GSD.IS==2 ; INTERNAL SYMBOL
GSD.TA==3 ; TRANSFER ADDRESS (START ADDRESS)
GSD.GS==4 ; GLOBAL SYMBOL
GSD.PN==5 ; PROGRAM NAME
GSD.PV==6 ; PROGRAM VERSION
GSD.MA==7 ; MAPPED ARRAY
GSD.CR==10 ; COMPLEATION ROUTINE NAME
GSD.MX==10 ; MAX ALLOWED TYPE
; Within the global symbol, the following flags have significants
GS.WEA==1 ; WEAK REFERENCE (INTERNAL ONLY IF NEEDED)
GS.TYP==4 ; TYPE, DEFINITION/REFERENCE OR LIBRARY
GS.REF==10 ; REFERENCE OD DEFINITION
GS.REL==40 ; RELOCATABLE OR ABSOLUTE
; Within a Psect, the following flags hold
PS.MES==1 ; MEMORY SPEED 1==> FAST NEEDED
PS.LIB==2 ; REFERENCES LIBRARY OR COMMON BLOCK
PS.ALL==4 ; ALLOCATION: 0==> CONCATINATE 1==> OVERLAY
PS.RES==10 ; RESERVED FOR TKB INTERNAL USE
PS.ACC==20 ; ACCESS: 0==> READ/WRITE 1==> READ ONLY
PS.REL==40 ; RELOCATION: 0==> ABSOLUTE 1==> RELOCATABLE
PS.SCO==100 ; SCOPE: 0==> LOCAL 1==> GLOBAL
PS.TYP==200 ; TYPE: 0==> INSTRUCTIONS 1==> DATA
;FORMAT OF PDP-11 BINARY TAPES
; FRAME -1 001
; -2 000
; -3 BYTE COUNT - LOWER ORDER
; -4 BYTE COUNT - HIGHER ORDER
; -5 LOAD ADDRESS - LOWER ORDER
; -6 LOAD ADDRESS - HIGHER ORDER
; DATA
; CHKSUM
; THE BYTE COUNT COUNTS FRAME-1 THROUGH ALL DATA
; IF THE BYTE COUNT IS EQUAL TO 6 THE LOAD ADDRESS IS THE START ADDRESS
; UNLESS ODD.
; IF THE BYTE COUNT IS > 6, DATA WILL BE LOADED INTO MEMORY
; WHEN CHKSUM IS ADDED TO SUM OF PREVIOUS FRAMES RESULT IS 0
;PDP11 ADDRESSING MODES
; 0 Rn REGISTER
; 1 @Rn REGISTER DEFERRED
; 2 (Rn)+ AUTO-INCREMENT
; 3 @(Rn)+ AUTO-INCREMENT DEFERRED
; 4 -(Rn) AUTO-DECREMENT
; 5 @-(Rn) AUTO-DECREMENT DEFERRED
; 6 X(Rn) INDEX
; 7 @X(Rn) INDEX DEFERRED
; 27 #X IMMEDIATE
; 37 @#X ABSOLUTE
; 67 X RELATIVE
; 77 @X RELATIVE DEFERRED
;MACRO TO DEFINE SYMBOLS FOR INSTRUCTIONS
; 1ST ARGUMENT IS VALUE OF INSTRUCTION
; 2ND ARG IS MASK FOR VALUE
; 3RD ARG IS MNEMONIC
; 4TH ARG IS FLAG BITS
; 5TH ARG IS SIMULATION
DEFINE INSTRU <
XLIST
X 000000,007000,AND,<SMF.IN!SMF.P8>
X 000000,177777,HALT,<SMF.IN!SMF.11>
X 000000,177777,R0,<SMF.RG!SMF.11>
X 000001,177777,R1,<SMF.RG!SMF.11>
X 000001,177777,WAIT,<SMF.IN!SMF.11>
X 000002,177777,R2,<SMF.RG!SMF.11>
X 000002,177777,RTI,<SMF.IN!SMF.11>
X 000003,177777,BPT,<SMF.IN!SMF.11>
X 000003,177777,R3,<SMF.RG!SMF.11>
X 000004,177777,IOT,<SMF.IN!SMF.11>
X 000004,177777,R4,<SMF.RG!SMF.11>
X 000005,177777,R5,<SMF.RG!SMF.11>
X 000005,177777,RESET,<SMF.IN!SMF.11>
X 000006,177777,RTT,<SMF.IN!SMF.11>
X 000006,177777,SP,<SMF.RG!SMF.11>
X 000007,177777,PC,<SMF.RG!SMF.11>
X 000100,177700,JMP,<SMF.IN!SMF.DD!SMF.11>
X 000200,177770,RTS,<SMF.IN!SMF.RT!SMF.11>
X 000230,177770,SPL,<SMF.IN!SMF.PL!SMF.11>
X 000240,177777,NOP,<SMF.IN!SMF.11>
X 000241,177777,CLC,<SMF.IN!SMF.11>
X 000242,177777,CLV,<SMF.IN!SMF.11>
X 000244,177777,CLZ,<SMF.IN!SMF.11>
X 000250,177777,CLN,<SMF.IN!SMF.11>
X 000257,177777,CCC,<SMF.IN!SMF.11>
X 000261,177777,SEC,<SMF.IN!SMF.11>
X 000262,177777,SEV,<SMF.IN!SMF.11>
X 000264,177777,SEZ,<SMF.IN!SMF.11>
X 000270,177777,SEN,<SMF.IN!SMF.11>
X 000277,177777,SCC,<SMF.IN!SMF.11>
X 000300,177700,SWAB,<SMF.IN!SMF.DD!SMF.11>
X 000400,177400,BR,<SMF.IN!SMF.BR!SMF.11>
X 001000,177400,BNE,<SMF.IN!SMF.BR!SMF.11>
X 001000,007000,TAD,<SMF.IN!SMF.P8>
X 001400,177400,BEQ,<SMF.IN!SMF.BR!SMF.11>
X 002000,177400,BGE,<SMF.IN!SMF.BR!SMF.11>
X 002000,007000,ISZ,<SMF.IN!SMF.P8>
X 002400,177400,BLT,<SMF.IN!SMF.BR!SMF.11>
X 003000,177400,BGT,<SMF.IN!SMF.BR!SMF.11>
X 003000,007000,DCA,<SMF.IN!SMF.P8>
X 003400,177400,BLE,<SMF.IN!SMF.BR!SMF.11>
X 004000,177000,JSR,<SMF.IN!SMF.DD!SMF.JS!SMF.11>
X 004000,007000,JMS,<SMF.IN!SMF.P8>
X 005000,177700,CLR,<SMF.IN!SMF.DD!SMF.11>
X 005000,007000,JMP,<SMF.IN!SMF.P8>
X 005100,177700,COM,<SMF.IN!SMF.DD!SMF.11>
X 005200,177700,INC,<SMF.IN!SMF.DD!SMF.11>
X 005300,177700,DEC,<SMF.IN!SMF.DD!SMF.11>
X 005400,177700,NEG,<SMF.IN!SMF.DD!SMF.11>
X 005500,177700,ADC,<SMF.IN!SMF.DD!SMF.11>
X 005600,177700,SBC,<SMF.IN!SMF.DD!SMF.11>
X 005700,177700,TST,<SMF.IN!SMF.DD!SMF.11>
X 006000,177700,ROR,<SMF.IN!SMF.DD!SMF.11>
X 006000,007000,IOT,<SMF.IN!SMF.P8>
X 006100,177700,ROL,<SMF.IN!SMF.DD!SMF.11>
X 006200,177700,ASR,<SMF.IN!SMF.DD!SMF.11>
X 006300,177700,ASL,<SMF.IN!SMF.DD!SMF.11>
X 006400,177700,MARK,<SMF.IN!SMF.MK!SMF.11>
X 006700,177700,SXT,<SMF.IN!SMF.DD!SMF.11>
X 007000,007777,NOP,<SMF.IN!SMF.P8>
X 007001,007401,IAC,<SMF.IN!SMF.P8>
X 007002,007416,BSW,<SMF.IN!SMF.P8>
X 007004,007406,RAL,<SMF.IN!SMF.P8>
X 007006,007406,RTL,<SMF.IN!SMF.P8>
X 007010,007412,RAR,<SMF.IN!SMF.P8>
X 007012,007412,RTR,<SMF.IN!SMF.P8>
X 007020,007420,CML,<SMF.IN!SMF.P8>
X 007040,007440,CMA,<SMF.IN!SMF.P8>
X 007100,007500,CLL,<SMF.IN!SMF.P8>
X 007200,007600,CLA,<SMF.IN!SMF.P8>
X 007400,007777,NOP,<SMF.IN!SMF.P8>
X 007401,007777,NOP,<SMF.IN!SMF.P8>
X 007402,007403,HLT,<SMF.IN!SMF.P8>
X 007404,007405,OSR,<SMF.IN!SMF.P8>
X 007410,007571,SKP,<SMF.IN!SMF.P8>
X 007420,007431,SNL,<SMF.IN!SMF.P8>
X 007421,007521,MQL,<SMF.IN!SMF.P8>
X 007430,007431,SZL,<SMF.IN!SMF.P8>
X 007440,007451,SZA,<SMF.IN!SMF.P8>
X 007450,007451,SNA,<SMF.IN!SMF.P8>
X 007500,007511,SMA,<SMF.IN!SMF.P8>
X 007501,007521,MQA,<SMF.IN!SMF.P8>
X 007510,007511,SPA,<SMF.IN!SMF.P8>
X 007521,007521,SWP,<SMF.IN!SMF.P8>
X 007600,007601,CLA,<SMF.IN!SMF.P8>
X 007601,007601,CLA,<SMF.IN!SMF.P8>
X 010000,170000,MOV,<SMF.IN!SMF.SS!SMF.11>
X 020000,170000,CMP,<SMF.IN!SMF.SS!SMF.11>
X 030000,170000,BIT,<SMF.IN!SMF.SS!SMF.11>
X 040000,170000,BIC,<SMF.IN!SMF.SS!SMF.11>
X 050000,170000,BIS,<SMF.IN!SMF.SS!SMF.11>
X 060000,170000,ADD,<SMF.IN!SMF.SS!SMF.11>
X 070000,177000,MUL,<SMF.IN!SMF.EI!SMF.11>
X 071000,177000,DIV,<SMF.IN!SMF.EI!SMF.11>
X 072000,177000,ASH,<SMF.IN!SMF.EI!SMF.11>
X 073000,177000,ASHC,<SMF.IN!SMF.EI!SMF.11>
X 074000,177000,XOR,<SMF.IN!SMF.JS!SMF.DD!SMF.11>
X 075000,177770,FADD,<SMF.IN!SMF.RT!SMF.11>
X 075010,177770,FSUB,<SMF.IN!SMF.RT!SMF.11>
X 075020,177770,FMUL,<SMF.IN!SMF.RT!SMF.11>
X 075030,177770,FDIV,<SMF.IN!SMF.RT!SMF.11>
X 077000,177000,SOB,<SMF.IN!SMF.SB!SMF.11>
X 100000,177400,BPL,<SMF.IN!SMF.BR!SMF.11>
X 100400,177400,BMI,<SMF.IN!SMF.BR!SMF.11>
X 101000,177400,BHI,<SMF.IN!SMF.BR!SMF.11>
X 101400,177400,BLOS,<SMF.IN!SMF.BR!SMF.11>
X 102000,177400,BVC,<SMF.IN!SMF.BR!SMF.11>
X 102400,177400,BVS,<SMF.IN!SMF.BR!SMF.11>
X 103000,177400,BCC,<SMF.IN!SMF.BR!SMF.11>
X 103000,177400,BHIS,<SMF.IN!SMF.BR!SMF.11>
X 103400,177400,BCS,<SMF.IN!SMF.BR!SMF.11>
X 103400,177400,BLO,<SMF.IN!SMF.BR!SMF.11>
X 104000,177400,EMT,<SMF.IN!SMF.EM!SMF.11>
X 104400,177400,TRAP,<SMF.IN!SMF.EM!SMF.11>
X 105000,177700,CLRB,<SMF.IN!SMF.DD!SMF.BY!SMF.11>
X 105100,177700,COMB,<SMF.IN!SMF.DD!SMF.BY!SMF.11>
X 105200,177700,INCB,<SMF.IN!SMF.DD!SMF.BY!SMF.11>
X 105300,177700,DECB,<SMF.IN!SMF.DD!SMF.BY!SMF.11>
X 105400,177700,NEGB,<SMF.IN!SMF.DD!SMF.BY!SMF.11>
X 105500,177700,ADCB,<SMF.IN!SMF.DD!SMF.BY!SMF.11>
X 105600,177700,SBCB,<SMF.IN!SMF.DD!SMF.BY!SMF.11>
X 105700,177700,TSTB,<SMF.IN!SMF.DD!SMF.BY!SMF.11>
X 106000,177700,RORB,<SMF.IN!SMF.DD!SMF.BY!SMF.11>
X 106100,177700,ROLB,<SMF.IN!SMF.DD!SMF.BY!SMF.11>
X 106200,177700,ASRB,<SMF.IN!SMF.DD!SMF.BY!SMF.11>
X 106300,177700,ASLB,<SMF.IN!SMF.DD!SMF.BY!SMF.11>
X 106400,177700,MTPS,<SMF.IN!SMF.DD!SMF.11>
X 106700,177700,MFPS,<SMF.IN!SMF.DD!SMF.11>
X 110000,170000,MOVB,<SMF.IN!SMF.SS!SMF.BY!SMF.11>
X 120000,170000,CMPB,<SMF.IN!SMF.SS!SMF.BY!SMF.11>
X 130000,170000,BITB,<SMF.IN!SMF.SS!SMF.BY!SMF.11>
X 140000,170000,BICB,<SMF.IN!SMF.SS!SMF.BY!SMF.11>
X 150000,170000,BISB,<SMF.IN!SMF.SS!SMF.BY!SMF.11>
X 160000,170000,SUB,<SMF.IN!SMF.SS!SMF.11>
X 163000,177777,UBAMAP,<SMF.11>
X 163100,177777,UBA.SR,<SMF.11>
;X 163200,177777,UBA.VC,<SMF.11>
X 163300,177777,UBA.MR,<SMF.11>
X 177570,177777,SW,<SMF.11>
X 177776,177777,PS,<SMF.11>
LIST
>
DEFINE CALL (ADDR) <XLIST
.XCREF
IFE <DEBUG-2>,<CALLXX ADDR>
IFL <DEBUG-2>,<PUSHJ P,ADDR>
.CREF
LIST>
DEFINE CALLXX (ADDR,%FAKE,%FAKE1) <
SKIPA QX,F.DEBU
JRST %FAKE
TXNN QX,DB.CAL
JRST %FAKE1
PUSH P,T1
PUSH P,T2
MOVE T1,[SIXBIT \ADDR\]
MOVEI T2,ADDR
PUSHJ P,CALLTY
POP P,T2
POP P,T1
%FAKE1:!PUSHJ P,ADDR
%FAKE:!>
DEFINE RET (OPT,LABEL) <XLIST
.XCREF
IFE <DEBUG-2>,<RETXX (OPT,LABEL)>
IFL <DEBUG-2>,<IFNB <OPT>,< IFIDN <OPT><SKIP>,<
AOS (P)
POPJ P, >
IFIDN <OPT><SAFE>,<JRST RSKP>>
IFB <OPT>,<POPJ P,>>
.CREF
LIST>
DEFINE RETXX (OPT,LABEL,%FAKE,%FAKE1) <
IFNB <LABEL>,<
SKIPA QX,F.DEBU
JRST %FAKE
TXNN QX,DB.CAL
JRST %FAKE1
PUSH P,T1
MOVE T1,[SIXBIT /LABEL/]
IFB <OPT>,<PUSHJ P,RETTY1>
IFNB <OPT>,<PUSHJ P,RETTY2>
POP P,T1
>
IFNB <OPT>,<
IFIDN <OPT><SKIP>,<
%FAKE1:!AOS (P)
%FAKE:! POPJ P,
>
IFIDN <OPT><SAFE>,<
%FAKE1:!JRST RSKP
%FAKE:!>>
IFB <OPT>,<
%FAKE1:!POPJ P,
%FAKE:!>>
DEFINE TYPE (X) <XLIST
.XCREF
MOVEI T1,[ASCIZ \X\]
PUSHJ P,TYPSTR
.CREF
LIST>
DEFINE DEBTYP (X) <XLIST
.XCREF
IFN <DEBUG>,<
MOVEI T1,[ASCIZ \X\]
SKIPE F.DEBU
PUSHJ P,TYPSTR
>
.CREF
LIST>
DEFINE DBGTYP (TX,X) <XLIST
.XCREF
IFN <DEBUG>,<
MOVE QX,F.DEBU ; GET THE DEBUG FLAG
MOVEI T1,[ASCIZ \X\]
TRNE QX,TX ; IS THIS OPTION EMABLED ??
PUSHJ P,TYPSTR ; YES, TYPE THE STRING
>
.CREF
LIST>
DEFINE DBG1TYP (TX,X) <XLIST
.XCREF
IFN <DEBUG>,<
PUSH P,T1
MOVE QX,F.DEBU ; GET THE DEBUG FLAG
MOVEI T1,[ASCIZ \X\]
TRNE QX,TX ; IS THIS OPTION ENABLED ??
PUSHJ P,TYPSTR ; YES, TYPE THE STRING
POP P,T1
>
.CREF
LIST>
DEFINE SWTCON (LABS,VALS) <IRP LABS,<Y'LABS::>
ZZ==0
IRP VALS,<ZZ=ZZ!Z'VALS>
EXP ZZ
>
DEFINE SWTCHK (SWT) <IF2 <
IFNDEF Z'SWT,<EXTERNAL Z'SWT>
IFNDEF Y'SWT,<EXTERNAL Y'SWT>>
XLIST
MOVE T1,[Z'SWT] ;; GET THIS SWITCH
MOVE T2,Y'SWT ;; GET THE DISALLOWED SWITCHES
CALL SWTTST ;; SEE IF THIS IS AN OK MATCH
POPJ P, ;; CONFLICT
LIST
>
DEFINE ENTEXT (TYPE,LLIST)<
IRP LLIST,<TYPE LLIST>
>
DEFINE ENT11 (MAGIC)<
XLIST
ENTEXT (MAGIC,<MEMORY,MEMLIM,MEMUSE,MOVMEM,MOVSMT,SYMBEG,SAVE4,SAVE35,POSYMT>)
ENTEXT (MAGIC,<DELSYM,OSTYPE,DDT11,LASTSW,LEVL.0,PDP8F,DAT,DATA,CALER0,R,RSKP>)
ENTEXT (MAGIC,<SWTMSK,SWTTST,SYMBOL,SYMBEG,SYMEND,SAVE2,SAVE34,LEVEL0,LEVEL2>)
ENTEXT (MAGIC,<VALFND,CMDLIM,O.MODE,DOTFOO,GOTO,INVLFN,RGFNDN,MOVMUS,TYPDAT>)
ENTEXT (MAGIC,<SYMFND,CNINWD,SBEGIN,DOTINC,CMDTKR,LSTADR,RSTART,ADDSYM,ORADIX>)
ENTEXT (MAGIC,<S..END,EXPRES,NDTFOO,ESC.Q.,BYTCNT,SAVE24,COMLF1,CORERR,CALERR>)
ENTEXT (MAGIC,<GENERR,F.DEBU,F.MSYS,F.DMCB,F.MCBD,TYPE11,F.MCB,F.HALT>)
IFN DEBUG,<
ENTEXT (MAGIC,<CALLTY,RETTY1,RETTY2>)
>
LIST
>
DEFINE ENTGP (MAGIC)<
XLIST
ENTEXT (MAGIC,<PUTFOO,DTEERR,QUED60,GETWRD,PUTBYT,SETUPN,CLRMEM,NODSET>)
ENTEXT (MAGIC,<GETMEM,ETYPE,CACHEL,CACHE,NODE.N,LINE,PORT,SET.FE,SETBIN>)
ENTEXT (MAGIC,<SETDFE,SETDMP,SETFOO,SETLIN,SETMCB,SETMCS,SETNOD,SETPRT,SETUBA>)
LIST
>
DEFINE ENTSIM (MAGIC)<
XLIST
ENTEXT (MAGIC,<UBACTL,SIMXCT,MAPCOR,UPTIME,INSRUN,WAITIM,SIMREG,SETUPC,SIMREL>)
ENTEXT (MAGIC,<IOBSTO,IOLOAD,IOSTOR,IOLDM1>)
LIST
>
DEFINE ENTFIL (MAGIC)<
XLIST
ENTEXT (MAGIC,<ADRTYP,B3.TYP,BLANKT,CMDCNT,CMDFIL,COLTYP,COMTYP,CRLTYP,CSECHO>)
ENTEXT (MAGIC,<DATYPE,DECINP,DECTYP,ESC..D,ESC..P,ESC..Y,FILPOS,IDTYPE,MRGFLG>)
ENTEXT (MAGIC,<MYPPN,OCTYPE,OHD,OPNFL0,PCNTYP,PDECTY,PERTYP,QESTYP,RADTYP>)
ENTEXT (MAGIC,<RDDUMP,RSTATE,SETFES,SETMRG,SETREL,SETRST,SETSYM,SIXIN,SIXTYP>)
ENTEXT (MAGIC,<TABTYP,TIMTY1,TYPCHR,TYPSTR,GETCHR,SIXOCT,FILDEV,DEFEXT,RATYPE>)
ENTEXT (MAGIC,<LATYPE>)
LIST
>
; DEFINE THE VARIOUS TYPES OF -11S WE CAN WORK WITH...
DEFINE CPUINF <
XLIST
; X A,B,C WHERE A IS THE CPU TYPE, B IS THE NUMBER TO TYPE FOR THIS CPU,
; AND C IS THE WIDTH OF THE LARGEST MEMORY ADDRESS
; CPU ID WIDTH
X 8, 8, 12 ; PDP8
X 02, 2, 16 ; 11/02
X 03, 3, 16 ; 11/03
X 04, 4, 16 ; 11/04
X 05, 5, 16 ; 11/05
X 10, 10, 16 ; 11/10
X 15, 15, 16 ; 11/15
X 20, 20, 16 ; 11/20
X 23, 23, 18 ; 11/23
X 3P, 231, 22 ; 11/23 PLUS
X 24, 24, 22 ; 11/24
X 34, 34, 16 ; 11/34
X 35, 35, 18 ; 11/35
X 40, 40, 18 ; 11/40
X 44, 44, 22 ; 11/44
X 45, 45, 18 ; 11/45
X 55, 55, 18 ; 11/55
X 60, 60, 22 ; 11/60
X 70, 70, 22 ; 11/70
X 74, 74, 22 ; 11/74
LIST
>
;MACRO TO REMEMBER REFERENCES TO SIMULATED CORE
DEFINE MEMREL (QQ) <XLIST
IF2 <Q=.
RELOC RLMTAB+RLMSIZ
QQ,,Q
RELOC Q>
RLMSIZ= RLMSIZ+1
LIST>
;MACRO TO GET A WORD FROM MEMORY
; FIRST ARG IS REGISTER TO USE AS AN INDEX ; 2ND ARG IS DESTINATION
DEFINE LOAD (Q,QQ) <
IFN <Q-PC> < TRNE Q,1
JRST NXM...>
IFN <MA-Q>,< HRRZ MA,Q>
MEMREL MEMLIM
CAIL MA,0
IFE <QQ-T1> < CALL IOLOAD
LODRET==4>
IFN <QQ-T1> < JRST [ MOVEM T1,IOLT1S# ;SAVE T1
CALL IOLOAD+2
HRRZ QQ,T1
MOVE T1,IOLT1S# ;RESTORE T1
JRST .+LODRET+1]>
ROT MA,-2
SKIPGE MA
MEMREL MEMORY
SKIPA QQ,0(MA)
MEMREL MEMORY
HLRZ QQ,0(MA)
ANDI QQ,177777 ;STRIP EXTRA BITS
IFE <QQ-PC> < TRNE PC,1
JRST NXM...>>
;MACRO TO GET A BYTE FROM MEMORY
; FIRST ARG IS REGISTER TO USE AS AN INDEX
; 2ND ARG IS DESTINATION
DEFINE BLOAD (Q,QQ) <
IFN <MA-Q>,< HRRZ MA,Q>
MEMREL MEMLIM
CAIL MA,0
CALL IOBLOD
BLDRET==7 ;NUMBER OF INSTRUCTIONS TO SKIP
LSHC MA,-2 ;IDIVI MA,4
LSH MA+1,-^D34
TRNE MA+1,2
MEMREL MEMORY
SKIPA QQ,0(MA) ;GET RH OF WORD
MEMREL MEMORY
HLRZ QQ,0(MA) ;GET LH OF WORD
TRNE MA+1,1 ;WANT ODD BYTE ?
LSH QQ,-^D8 ;YES
ANDI QQ,377> ;STRIP EXTRA BITS
;MACRO TO STORE WORD OR BYTE IN MEMORY AFTER DOING LOAD FROM SAME LOCATION
; ADDRESS IS IN MA, DATA IS FOUND IN T1 (LH MAY BE NONZERO E.G. SBC)
DEFINE RSTORE (FLAG,TYPE) <
IFE <<FLAG>&SMF.BY> <TLNE MA,MA..RG ;WAS LOCATION A REGISTER ?
JRST [ HRRM T1,(MA) ;DEPOSIT APPROPRIATE REG
TRNN PC,1 ;IN CASE SET PC
JRST SIM11 ;PC WAS GARBAGED
JRST NXM... ] ;TAKE A TRAP
TLNE MA,MA..IO ;WAS LOCATION AN IO REGISTER ?
JRST [ PUSH P,[EXP SIM11] ;PUSH RETURN ON STACK
JRST IOR.'TYPE ] ;RESTORE WORD TO MEMORY
SKIPGE MA
JRST .+3
MEMREL MEMORY
HRLM T1,0(MA)
JRST SIM11
MEMREL MEMORY
HRRM T1,0(MA)>
IFN <<FLAG>&SMF.BY> <TLNN MA,MA..RG ;WAS LOCATION A REGISTER ?
JRST .+5 ;NOT A REGISTER
DPB T1,[POINT 8,(MA),35] ;THIS IS SLOW BUT PROB BEST WAY
TRNN PC,1 ;CHECK PC NOT POLLUTED
JRST SIM11
JRST NXM... ;TAKE A BUS TRAP
TLNE MA,MA..IO ;WAS LOCATION AN IO REGISTER ?
JRST [PUSH P,[EXP SIM11] ;PUSH RETURN ON STACK
JRST IOBR.'TYPE ] ;RESTORE BYTE TO MEMORY
DPB T1,SIMPTR(MA+1)>> ;PUT BYTE BACK INTO MEMORY
;MACRO TO STORE A WORD IN MEMORY
; FIRST ARG IS REGISTER TO USE AS AN INDEX
; 2ND ARG IS DESTINATION
DEFINE STORE (Q,QQ) <
IFN <Q-PC> < TRNE Q,1
JRST NXM...>
IFN <MA-Q>,< HRRZ MA,Q>
MEMREL MEMLIM
CAIL MA,0
JRST [
IFN <T1-QQ>,< HRRZ T1,QQ>
Z= 7
IFE <Q-6> <Z=Z+2>
PUSH P,[EXP .+Z]
JRST IOSTOR ]
IFE <Q-6>,< CAIGE MA,400
JSR STCKVP>
ROT MA,-2
SKIPGE MA
JRST .+3
MEMREL MEMORY
HRLM QQ,0(MA)
JRST .+2
MEMREL MEMORY
HRRM QQ,0(MA)
>
;MACRO TO STORE A BYTE IN MEMORY
; FIRST ARG IS REGISTER TO USE AS AN INDEX
; 2ND ARG IS DESTINATION
DEFINE BSTORE (Q,QQ) <
IFN <MA-Q>,< HRRZ MA,Q>
MEMREL MEMLIM
CAIL MA,0
JRST [
IFN <T1-QQ>,< HRRZ T1,QQ>
Z= 4
IFE <Q-6>,<Z=Z+2>
PUSH P,[EXP .+Z]
JRST IOBSTO ]
IFE <Q-6>,< CAIGE MA,400
JSR STCKVP>
LSHC MA,-2
LSH MA+1,-^D34
DPB QQ,SIMPTR(MA+1)
>
;MACRO TO PUT PC AND PS ON STACK
DEFINE INTSAV (VEC) <
CAIG SP,177774
CAIG SP,400-40
JRST RSTACK ;RED STACK VIOLATION
MOVEI SP,-4(SP)
HRRZI MA,2(SP)
STORE MA,PS ;SAVE PS ON STACK
STORE SP,PC ;SAVE PC ON STACK
MOVEI MA,VEC
LOAD MA,T2 ;GET NEW PC IN TEMP REG
MOVEI MA,2+VEC
LOAD MA,T1 ;GET NEW PS
ANDI T1,377 ;ONLY HAVE A RH
EXCH PS,T1 ;SET NEW PS (AND PRESERVE OLD ONE)
MOVE PC,T2 ;LOAD NEW PC
CALL PS.CHK ;ADJUST FOR NEW PS LEVEL
TRNE PC,1 ;BE SURE OK
JRST NXM... ;TAKE A BUS TRAP
>
DEFINE ADC. (FLAG) <
JSR @RFETCH(IR) ;GET OPERAND
TRZ PS,PS...N!PS...Z!PS...V
TRZE PS,PS...C
JRST .+6
TRNE T1,100000
TRO PS,PS...N
JUMPN T1,SIM11
TRO PS,PS...Z
JRST SIM11
AOS T1
TRNE T1,100000
TRO PS,PS...N
TRZE T1,200000 ;OVERFLOW IFF WENT TO ZERO
TRO PS,PS...Z!PS...C
CAIN T1,100000
TRO PS,PS...V
RSTORE FLAG
>
DEFINE ADCB. (FLAG) <
JSR @BRFTCH(IR) ;GET OPERAND
TRZ PS,PS...N!PS...Z!PS...V
TRZE PS,PS...C
JRST .+6
TRNE T1,000200
TRO PS,PS...N
JUMPN T1,SIM11
TRO PS,PS...Z
JRST SIM11
AOS T1
TRNE T1,000200
TRO PS,PS...N
TRZE T1,000400 ;OVERFLOW IFF WENT TO ZERO
TRO PS,PS...Z!PS...C
CAIN T1,000200
TRO PS,PS...V
RSTORE FLAG
>
DEFINE ADD. (FLAG) <
MOVE T2,T1 ;SAVE SRC
JSR @RFETCH(IR) ;GET DST
MOVE IR,T1 ;SAVE COPY OF DST FOR PS...V CALC
ADD T1,T2 ;MAKES RESULT
TRZ PS,PS...N!PS...Z!PS...V!PS...C
TRNE T1,100000 ;CHECK FOR NEGATIVE
TRO PS,PS...N
TRZE T1,600000 ;CHECK FOR OVERFLOW
TRO PS,PS...C
SKIPN T1
TRO PS,PS...Z
EQV IR,T2 ;SRC EQV DST
XOR T2,T1 ;RESULT XOR SRC
AND T2,IR
TRNE T2,100000
TRO PS,PS...V
RSTORE FLAG
>
DEFINE ASH. (FLAG) <
ANDI T2,7 ;LEAVE ONLY REG FIELD
JSR @FETCH(IR) ;GET NN
TRZ PS,PS...N!PS...Z!PS...V!PS...C
MOVE MA,(T2) ;GET REGISTER TO SHIFT
TRNE MA,100000 ;WAS REGISTER NEGATIVE ?
IOR MA,[-1,,700000] ;EXTEND SIGN
TRNE T1,40 ;RIGHT OR LEFT SHIFT ?
JRST [IORI T1,777740 ;SHIFT RIGHT
ASHC MA,(T1) ;SHIFT IT
TLNE MA+1,200000 ;WAS LAST BIT OUT A 1 ?
TRO PS,PS...C ;REMEMBER LAST BIT OUT
JRST .+13 ]
ANDI T1,37 ;SHIFT LEFT
;JUMPE T1, ???? *****
; ***** *****
; ***** WHAT IF SHIFT 0 ??? *****
; ***** *****
JOV .+1 ;CLEAR FLAG
ASH MA,(T1) ;SHIFT IT
TRNE MA,200000 ;WAS LAST BIT OUT SET ?
TRO PS,PS...C ;LAST BIT OUT WAS SET
JOV .+4 ;LOSE ANY BITS ?
SKIPGE T1,MA ;NEGATIVE ?
XOR T1,[-1,,700000]
TDNE T1,[-1,,700000]
TRO PS,PS...V
ANDI MA,177777 ;STRIP EXTRA BITS
TRNE MA,100000 ;IS RESULT NEGATIVE ?
TRO PS,PS...N ;WAS NEGATIVE RESULT
SKIPN MA ;WAS RESULT ZERO ?
TRO PS,PS...Z ;YES
MOVEM MA,(T2) ;UPDATE ORIGINAL REGISTER
TRNE PC,1 ;DID THAT POLLUTE THE PC ?
JRST NXM... ;GIVE A BUS TRAP
>
DEFINE ASHC. (FLAG) <
; ***** *****
; ***** WHAT IF REG IS ODD ?? *****
; ***** *****
ANDI T2,7 ;LEAVE ONLY REG FIELD
JSR @FETCH(IR) ;GET NN
TRZ PS,PS...N!PS...Z!PS...V!PS...C
MOVE MA,(T2) ;GET HIGH ORDER BITS
LSH MA,^D16 ;POSITION
MOVE IR,T2 ;COPY REGISTER ADR
IORI IR,1 ;MAKE LOW ORDER BITS ADR
IOR MA,(IR) ;GET LOW ORDER BITS
TLNE MA,020000 ;WAS REG NEGATIVE ?
TLO MA,740000 ;EXTEND SIGN
TRNE T1,40 ;RIGHT OR LEFT SHIFT ?
JRST [IORI T1,777740 ;SHIFT RIGHT
ASHC MA,(T1) ;SHIFT IT
TLNE MA+1,200000 ;WAS LAST BIT OUT A 1 ?
TRO PS,PS...C
JRST .+13 ]
ANDI T1,37 ;SHIFT LEFT
;JUMPE T1, ???? *****
; ***** *****
; ***** WHAT IF SHIFT 0 ??? *****
; ***** *****
JOV .+1 ;CLEAR FLAG
ASH MA,(T1) ;SHIFT IT
TLNE MA,040000 ;WIN A CARRY BIT ?
TRO PS,PS...C ;WON A CARRY
JOV .+4
SKIPGE T1,MA ;WAS THAT NEGATIVE ?
TLC T1,760000 ;CL7AR EXTENDED SIGN
TLNE T1,760000 ;DID WE LOSE BITS ?
TRO PS,PS...V ;LOST BITS
TLNE MA,020000 ;IS RESULT NEGATIVE ?
TRO PS,PS...N ;WAS NEGATIVE RESULT
TLZ MA,740000 ;STRIP EXTRA BITS
SKIPN MA ;WAS RESULT ZERO ?
TRO PS,PS...Z ;YES
MOVE T1,MA ;COPY RESULT
ANDI T1,177777 ;STRIP EXTRA BITS
MOVEM T1,(IR) ;RESTORE LOW ORDER BITS
LSH MA,-^D16 ;POSITION HIGH ORDER BITS
MOVEM MA,(T2) ;RESTORE NEW HIGH ORDER BITS
TRNE PC,1 ;DID THAT POLLUTE THE PC ?
JRST NXM... ;GIVE A BUS TRAP
>
DEFINE ASL. (FLAG) <
JSR @RFETCH(IR) ;GET OPERAND
TRZ PS,PS...N!PS...Z!PS...V!PS...C
TRNN T1,040000 ;CHECK NEW N BIT
JRST .+5 ;NO NEW N BIT
TRZE T1,100000 ;CHECK NEW C BIT
TROA PS,PS...N!PS...C
TRO PS,PS...N!PS...V
JRST .+3
TRZE T1,100000 ;CHECK NEW C BIT
TRO PS,PS...C!PS...V
LSH T1,1
SKIPN T1
TRO PS,PS...Z
RSTORE FLAG
>
DEFINE ASLB. (FLAG) <
JSR @BRFTCH(IR) ;GET OPERAND
TRZ PS,PS...N!PS...Z!PS...V!PS...C
TRNN T1,000100 ;CHECK NEW N BIT
JRST .+5 ;NO NEW N BIT
TRZE T1,000200 ;CHECK NEW C BIT
TROA PS,PS...N!PS...C
TRO PS,PS...N!PS...V
JRST .+3
TRZE T1,000200 ;CHECK NEW C BIT
TRO PS,PS...C!PS...V
LSH T1,1
SKIPN T1
TRO PS,PS...Z
RSTORE FLAG
>
DEFINE ASR. (FLAG) <
JSR @RFETCH(IR) ;GET OPERAND
TRZ PS,PS...N!PS...Z!PS...V!PS...C
TRNN T1,100000 ;CHECK NEW N BIT
JRST .+6 ;NO NEW N BIT
TRO T1,200000 ;SET NEW SIGN BIT
TRZE T1,1 ;CHECK NEW C BIT
TROA PS,PS...N!PS...C
TRO PS,PS...N!PS...V
JRST .+3
TRZE T1,1 ;CHECK NEW C BIT
TRO PS,PS...C!PS...V
LSH T1,-1
SKIPN T1
TRO PS,PS...Z
RSTORE FLAG
>
DEFINE ASRB. (FLAG) <
JSR @BRFTCH(IR) ;GET OPERAND
TRZ PS,PS...N!PS...Z!PS...V!PS...C
TRNN T1,000200 ;CHECK NEW N BIT
JRST .+6 ;NO NEW N BIT
TRO T1,000400 ;SET NEW SIGN BIT
TRZE T1,1 ;CHECK NEW C BIT
TROA PS,PS...N!PS...C
TRO PS,PS...N!PS...V
JRST .+3
TRZE T1,1 ;CHECK NEW C BIT
TRO PS,PS...C!PS...V
LSH T1,-1
SKIPN T1
TRO PS,PS...Z
RSTORE FLAG
>
DEFINE BIC. (FLAG) <
MOVE T2,T1 ;COPY SRC
JSR @RFETCH(IR) ;GET DST
ANDCM T1,T2 ;CLEAR SOME BITS
TRZ PS,PS...N!PS...Z!PS...V
TRNE T1,100000
TRO PS,PS...N
SKIPN T1
TRO PS,PS...Z
RSTORE FLAG,C
>
DEFINE BICB. (FLAG) <
MOVE T2,T1 ;COPY SRC
JSR @BRFTCH(IR) ;GET DST
ANDCM T1,T2 ;CLEAR SOME BITS
TRZ PS,PS...N!PS...Z!PS...V
TRNE T1,000200
TRO PS,PS...N
SKIPN T1
TRO PS,PS...Z
RSTORE FLAG,C
>
DEFINE BIS. (FLAG) <
MOVE T2,T1 ;COPY SRC
JSR @RFETCH(IR) ;GET DST
IOR T1,T2 ;SET NEW BITS
TRZ PS,PS...N!PS...Z!PS...V
TRNE T1,100000
TRO PS,PS...N
SKIPN T1
TRO PS,PS...Z
RSTORE FLAG,S
>
DEFINE BISB. (FLAG) <
MOVE T2,T1 ;COPY SRC
JSR @BRFTCH(IR) ;GET DST
IOR T1,T2 ;SET NEW BITS
TRZ PS,PS...N!PS...Z!PS...V
TRNE T1,000200
TRO PS,PS...N
SKIPN T1
TRO PS,PS...Z
RSTORE FLAG,S
>
DEFINE BIT. (FLAG) <
MOVE T2,T1 ;COPY FIRST OPERAND
JSR @FETCH(IR) ;GET 2ND OPERAND
TRZ PS,PS...N!PS...Z!PS...V
AND T1,T2 ;MASK THE BITS
SKIPN T1
TRO PS,PS...Z
TRNE T1,100000
TRO PS,PS...N
>
DEFINE BITB. (FLAG) <
MOVE T2,T1 ;COPY FIRST OPERAND
JSR @BFETCH(IR) ;GET 2ND OPERAND
TRZ PS,PS...N!PS...Z!PS...V
AND T1,T2 ;MASK THE BITS
SKIPN T1
TRO PS,PS...Z
TRNE T1,000200
TRO PS,PS...N
>
;DEFINE CCC. (FLAG) <> ;HANDLED BY .CCCLR
;DEFINE CLC. (FLAG) <> ;HANDLED BY .CCCLR
;DEFINE CLN. (FLAG) <> ;HANDLED BY .CCCLR
DEFINE CLR. (FLAG) <
HRRM PS,PS.REG+1 ;IN CASE OF BUS TRAP
SETZ T1,
TRZ PS,PS...N!PS...V!PS...C
TRO PS,PS...Z
JRST @STUFF(IR)
ZZRET== -1
>
DEFINE CLRB. (FLAG) <
HRRM PS,PS.REG+1 ;IN CASE OF BUS TRAP
SETZ T1,
TRZ PS,PS...N!PS...V!PS...C
TRO PS,PS...Z
JRST @BSTUFF(IR)
ZZRET== -1
>
;DEFINE CLV. (FLAG) <> ;HANDLED BY .CCCLR
;DEFINE CLZ. (FLAG) <> ;HANDLED BY .CCCLR
DEFINE CMP. (FLAG) <
MOVE T2,T1 ;COPY FIRST OPERAND
JSR @FETCH(IR) ;GET 2ND OPERAND
MOVE IR,T2 ;ANOTHER COPY OF SRC FOR PS...V CALC
TRZ PS,PS...N!PS...Z!PS...V!PS...C
SUB T2,T1
TRNE T2,100000
TRO PS,PS...N
TRNN T2,177777
TRO PS,PS...Z
TRNE T2,200000
TRO PS,PS...C
XOR IR,T1 ;SRC XOR DST
EQV T1,T2 ;CHECK RESULT AND DST
AND T1,IR
TRNE T1,100000
TRO PS,PS...V ;SAME SIGN SO OVERFLOW
>
DEFINE CMPB. (FLAG) <
MOVE T2,T1 ;COPY FIRST OPERAND
JSR @BFETCH(IR) ;GET 2ND OPERAND
MOVE IR,T2 ;ANOTHER COPY OF SRC FOR PS...V CALC
TRZ PS,PS...N!PS...Z!PS...V!PS...C
SUB T2,T1
TRNE T2,000200
TRO PS,PS...N
TRNN T2,000377
TRO PS,PS...Z
TRNE T2,000400
TRO PS,PS...C
XOR IR,T1 ;SRC XOR DST
EQV T1,T2 ;CHECK RESULT AND DST
AND T1,IR
TRNE T1,000200
TRO PS,PS...V ;SAME SIGN SO OVERFLOW
>
DEFINE COM. (FLAG) <
JSR @RFETCH(IR) ;GET OPERAND
TRZ PS,PS...N!PS...Z!PS...V
TRO PS,PS...C
TRCE T1,177777 ;PERFORM COMPLEMENT AND CHECK FOR -1 RESULT
TRNE T1,100000
TRO PS,PS...N
SKIPN T1
TRO PS,PS...Z
RSTORE FLAG
>
DEFINE COMB. (FLAG) <
JSR @BRFTCH(IR) ;GET OPERAND
TRZ PS,PS...N!PS...Z!PS...V
TRO PS,PS...C
TRCE T1,000377 ;PERFORM COMPLEMENT AND CHECK FOR -1 RESULT
TRNE T1,000200
TRO PS,PS...N
SKIPN T1
TRO PS,PS...Z
RSTORE FLAG
>
DEFINE DEC. (FLAG) <
JSR @RFETCH(IR) ;GET OPERAND
TRZ PS,PS...N!PS...Z!PS...V
SOSN T1
TRO PS,PS...Z
ANDI T1,177777
TRNE T1,100000
TRO PS,PS...N
CAIN T1,077777
TRO PS,PS...V
RSTORE FLAG
>
DEFINE DECB. (FLAG) <
JSR @BRFTCH(IR) ;GET OPERAND
TRZ PS,PS...N!PS...Z!PS...V
SOSN T1
TRO PS,PS...Z
ANDI T1,000377
TRNE T1,000200
TRO PS,PS...N
CAIN T1,000177
TRO PS,PS...V
RSTORE FLAG
>
DEFINE DIV. (FLAG) <
ANDI T2,7 ;LEAVE REGISTER FIELD
JSR @FETCH(IR) ;GET DIVISOR
TRZ PS,PS...N!PS...Z!PS...V!PS...C
JUMPE T1,[TRO PS,PS...C!PS...V ;SET FLAGS
JRST SIM11 ]
TRNE T1,100000 ;NEGATIVE DIVSOR ?
IOR T1,[-1,,700000] ;EXTEND SIGN
MOVE MA,(T2) ;GET HIGH ORDER BITS OF DIVIDEND
LSH MA,^D16 ;POSITION
TLNE MA,020000 ;NEGATIVE ?
TLO MA,760000 ;EXTEND SIGN
MOVE IR,T2 ;COPY REG ADR
IORI IR,1
IOR MA,(IR) ;GET LOW ORDER BITS
IDIV MA,T1 ;DO THE DIVISION
ANDI MA,177777 ;STRIP EXTRA BITS
MOVEM MA,(T2)
TRO T1,1 ;OTHER REGISTER
ANDI MA+1,177777 ;STRIP OTHER BITS
MOVEM MA+1,(T2) ;AND SAVE THESE AS WELL
TRNE MA,100000 ;NEGATIVE RESULT ?
TRO PS,PS...N ;REMEMBER NEGATIVE
ANDI MA,177777 ;STRIP EXTRA BITS
SKIPN MA
TRO PS,PS...Z ;REMEMBER ZERO RESULT
TRNE PC,1 ;DID THAT POLLUTE THE PC ?
JRST NXM... ;GIVE A BUS TRAP
>
DEFINE FADD. (FLAG) <
JRST ILLINS
ZZRET== -1
>
DEFINE FDIV. (FLAG) <
JRST ILLINS
ZZRET== -1
>
DEFINE FMUL. (FLAG) <
JRST ILLINS
ZZRET== -1
>
DEFINE FSUB. (FLAG) <
JRST ILLINS
ZZRET== -1
>
DEFINE HALT. (FLAG) <
TXZ FLG,F.RUNF
SETOM F.HALT ;FLAG THE HALT INSTRUCTION
HRROS INTDLY ;SO WE NOTICE RUN FLOP
>
DEFINE INC. (FLAG) <
JSR @RFETCH(IR) ;GET OPERAND
TRZ PS,PS...N!PS...Z!PS...V
AOS T1
TRNE T1,100000
TRO PS,PS...N
TRZE T1,200000 ;HAPPENS IIF
TRO PS,PS...Z ; OPERAND NOW ZERO
CAIN T1,100000
TRO PS,PS...V
RSTORE FLAG
>
DEFINE INCB. (FLAG) <
JSR @BRFTCH(IR) ;GET OPERAND
TRZ PS,PS...N!PS...Z!PS...V
AOS T1
TRNE T1,000200
TRO PS,PS...N
TRZE T1,000400 ;HAPPENS IFF
TRO PS,PS...Z ; OPERAND NOW ZERO
CAIN T1,000200
TRO PS,PS...V
RSTORE FLAG
>
DEFINE JMP. (FLAG) <
JSR @JMPCLC(IR) ;CALCULATE ADDR
MOVE PC,T1 ;SET NEW PC
TRNE PC,1 ;BE SURE KOSHER PC
JRST NXM...
>
DEFINE MOV. (FLAG) <
HRRM PS,PS.REG+1 ;SAVE PS IN CASE OF STACK VIOLATION
TRZ PS,PS...N!PS...Z!PS...V
TRNE T1,100000 ;DO WE WANT N BIT
TRO PS,PS...N ;SET N BIT
SKIPN T1
TRO PS,PS...Z ;SET Z BIT
JRST @STUFF(IR)
ZZRET== -1
>
DEFINE MOVB. (FLAG) <
HRRM PS,PS.REG+1 ;SAVE PS IN CASE OF STACK VIOLATION
TRZ PS,PS...N!PS...Z!PS...V
TRNE T1,000200 ;DO WE WANT N BIT
TRO PS,PS...N ;SET N BIT
SKIPN T1
TRO PS,PS...Z ;SET Z BIT
TRNE IR,70 ;CHECK FOR REGISTER DST
JRST @BSTUFF(IR)
TRNE T1,200 ;WANT TO EXTEND SIGN ?
TRO T1,177600 ;EXTEND SIGN
HRRM T1,(IR)
>
DEFINE MUL. (FLAG) <
ANDI T2,7 ;LEAVE ONLY REGISTER FIELD
JSR @FETCH(IR) ;GET THE SOURCE OPERAND
TRZ PS,PS...N!PS...Z!PS...V!PS...C
TRNE T1,100000 ;NEGATIVE VALUE ?
IOR T1,[-1,,700000] ;EXTEND SIGN
MOVE MA,(T2) ;GET REGISTER ARGUMENT
TRNE MA,100000 ;NEGATIVE ARGUMENT ?
IOR MA,[-1,,700000] ;EXTEND SIGN
IMULB T1,MA ;DO THE MULTIPLICATION
SKIPN T1 ;WAS RESULT ZERO
TRO PS,PS...Z ;REMEMBER IT WAS ZERO
TLNE T1,020000 ;IS RESULT NEGATIVE ?
TRO PS,PS...N ;REMEMBER IT WAS NEGATIVE
CAML T1,[-1,,700000]
CAILE T1,077777
TRO PS,PS...C ;NEED MORE THAN 16 BITS
ANDI MA,177777 ;LEAVES LOW ORDER PORTION
LSH T1,-^D16 ;LEAVES HIGH ORDER PORTION
ANDI T1,177777 ;STRIP EXTRA IF ANY
MOVEM T1,(T2) ;STORE HIGH ORDER PORTION
IORI T2,1 ;OTHER REG ADDRESS
MOVEM MA,(T2)
TRNE PC,1 ;DID THAT CORRUPT THE PC ?
JRST NXM... ;YES SO TAKE A BUS TRAP
>
DEFINE NEG. (FLAG) <
JSR @RFETCH(IR) ;GET OPERAND
TRZ PS,PS...N!PS...Z!PS...V!PS...C
MOVNS T1
ANDI T1,177777
TRNE T1,100000
TRO PS,PS...N
SKIPN T1
TROA PS,PS...Z
TRO PS,PS...C
CAIN T1,100000
TRO PS,PS...V
RSTORE FLAG
>
DEFINE NEGB. (FLAG) <
JSR @BRFTCH(IR) ;GET OPERAND
TRZ PS,PS...N!PS...Z!PS...V!PS...C
MOVNS T1
ANDI T1,000377
TRNE T1,000200
TRO PS,PS...N
SKIPN T1
TROA PS,PS...Z
TRO PS,PS...C
CAIN T1,000200
TRO PS,PS...V
RSTORE FLAG
>
;DEFINE NOP. (FLAG) <> ;HANDLED BY .CCCLR
DEFINE RESET. (FLAG) <
CALL R.SET ;DO COMMON STUFF
>
DEFINE ROL. (FLAG) <
JSR @RFETCH(IR) ;GET OPERAND
TRZ PS,PS...N!PS...Z!PS...V
TRZE PS,PS...C
TLO T1,400000 ;CARRY BIT GOES TO SIGN BIT
TRZE T1,100000 ;CHECK NEW CARRY
TRO PS,PS...C!PS...V ;NEW CARRY AND OVERFLOW (MAYBE)
ROT T1,1
TRNE T1,100000 ;GET A NEGATIVE RESULT ?
TRC PS,PS...N!PS...V ;WIN NEGATIVE AND COMPLEMENT OVERFLOW
SKIPN T1
TRO PS,PS...Z
RSTORE FLAG
>
DEFINE ROLB. (FLAG) <
JSR @BRFTCH(IR) ;GET OPERAND
TRZ PS,PS...N!PS...Z!PS...V
TRZE PS,PS...C
TLO T1,400000 ;CARRY BIT GOES TO SIGN BIT
TRZE T1,000200 ;CHECK NEW CARRY
TRO PS,PS...C!PS...V ;NEW CARRY AND OVERFLOW (MAYBE)
ROT T1,1
TRNE T1,000200 ;GET A NEGATIVE RESULT ?
TRC PS,PS...N!PS...V ;WIN NEGATIVE AND COMPLEMENT OVERFLOW
SKIPN T1
TRO PS,PS...Z
RSTORE FLAG
>
DEFINE ROR. (FLAG) <
JSR @RFETCH(IR) ;GET OPERAND
TRZ PS,PS...N!PS...Z!PS...V
TRZE PS,PS...C
JRST .+4
TRZE T1,1 ;DO WE GET A NEW CARRY ?
TRO PS,PS...C!PS...V
JRST .+5
TRO T1,200000 ;CARRY BIT GOES TO SIGN BIT
TRZE T1,1 ;CHECK NEW CARRY
TROA PS,PS...C!PS...N ;NEW CARRY AND NEGATIVE
TRO PS,PS...V!PS...N ;OVERFLOW AND NEGATIVE
LSH T1,-1
SKIPN T1
TRO PS,PS...Z
RSTORE FLAG
>
DEFINE RORB. (FLAG) <
JSR @BRFTCH(IR) ;GET OPERAND
TRZ PS,PS...N!PS...Z!PS...V
TRZE PS,PS...C
JRST .+4
TRZE T1,1 ;DO WE GET A NEW CARRY ?
TRO PS,PS...C!PS...V
JRST .+5
TRO T1,000400 ;CARRY BIT GOES TO SIGN BIT
TRZE T1,1 ;CHECK NEW CARRY
TROA PS,PS...C!PS...N ;NEW CARRY AND NEGATIVE
TRO PS,PS...V!PS...N ;OVERFLOW AND NEGATIVE
LSH T1,-1
SKIPN T1
TRO PS,PS...Z
RSTORE FLAG
>
DEFINE RTI. (FLAG) <
LOAD SP,T1 ;PUT RESTORED PC IN TEMP REG
MOVEI SP,2(SP)
ANDI SP,177776
LOAD SP,T2 ;GET NEW PS
ANDI T2,377 ;WE DON'T HAVE A LH
HRRM PS,PS.REG+1 ;SAVE OLD PS
MOVE PS,T2 ;LOAD NEW PS
MOVEI SP,2(SP)
ANDI SP,177776
MOVE PC,T1 ;LOAD NEW PC
TRNE PC,1 ;CHECK PC OK
JRST NXM... ;TAKE A BUS TRAP
CALL PS.CHK ;SEE IF THERE ARE INTERRUPTS TO TAKE
>
DEFINE RTS. (FLAG) <
ANDI IR,7
MOVE PC,(IR)
LOAD SP,T1 ;GET OLD REG FROM STACK
MOVEM T1,(IR) ;LOAD REG FROM STACK
MOVEI SP,2(SP) ;FINISH POP
ANDI SP,177777 ;IN CASE OVERFLOWED
TRNE PC,1 ;BE SURE NEW PC OK
JRST NXM... ;TAKE A BUS TRAP
>
DEFINE RTT. (FLAG) <
LOAD SP,T1
MOVEI SP,2(SP)
ANDI SP,177776
LOAD SP,T2 ;GET NEW PS
ANDI T2,377 ;WE DON'T HAVE A LH
HRRM PS,PS.REG+1 ;SAVE OLD PS
MOVE PS,T2 ;LOAD NEW PS
MOVEI SP,2(SP)
ANDI SP,177776
HRRZ PC,T1 ;LOAD NEW PC
TRNE PC,1 ;CHECK NEW PC OK
JRST NXM... ;TAKE A BUS TRAP
CALL PS.CHK ;SEE IF THERE ARE INTERRUPTS TO TAKE
JRST SIM11A ;INHIBIT TRACE TRAP
ZZRET== -1
>
DEFINE SBC. (FLAG) <
JSR @RFETCH(IR) ;GET OPERAND
TRZ PS,PS...N!PS...Z!PS...V
TRZE PS,PS...C
JRST .+8
TRNE T1,100000
TRO PS,PS...N
CAIN T1,100000
TRO PS,PS...V
JUMPN T1,SIM11
TRO PS,PS...Z
JRST SIM11
SOSN T1
TRO PS,PS...Z
TRNE T1,100000
TRO PS,PS...N
CAIN T1,100000-1
TRO PS,PS...V
TRZE T1,600000
TRO PS,PS...C
RSTORE FLAG
>
DEFINE SBCB. (FLAG) <
JSR @BRFTCH(IR) ;GET OPERAND
TRZ PS,PS...N!PS...Z!PS...V
TRZE PS,PS...C
JRST .+8
TRNE T1,000200
TRO PS,PS...N
CAIN T1,000200
TRO PS,PS...V
JUMPN T1,SIM11
TRO PS,PS...Z
JRST SIM11
SOSN T1
TRO PS,PS...Z
TRNE T1,000200
TRO PS,PS...N
CAIN T1,000200-1
TRO PS,PS...V
TRZE T1,777400
TRO PS,PS...C
RSTORE FLAG
>
;DEFINE SCC. (FLAG) <> ;HANDLED BY .CCSET
;DEFINE SEC. (FLAG) <> ;HANDLED BY .CCSET
;DEFINE SEN. (FLAG) <> ;HANDLED BY .CCSET
;DEFINE SEV. (FLAG) <> ;HANDLED BY .CCSET
;DEFINE SEZ. (FLAG) <> ;HANDLED BY .CCSET
DEFINE SOB. (FLAG) <
ANDI T2,7 ;GET REGISTER DESIGNATION
SOSN T1,(T2)
JRST SIM11 ;DON'T TAKE BRANCH
ANDI T1,177777 ;IN CASE OF OVERFLOW
MOVEM T1,(T2)
ANDI IR,77
LSH IR,1
SUBI PC,(IR)
ANDI PC,177777 ;ONLY NEEDED IF PC .LT. 200 !
>
DEFINE SPL. (FLAG) <
ANDI IR,7 ;LEAVE ONLY NEW PRIORITY
DPB IR,P.PLVL
CALL PS.CHK
>
DEFINE SUB. (FLAG) <
MOVE T2,T1 ;SAVE SRC
JSR @RFETCH(IR) ;GET DST
MOVE IR,T1 ;SAVE COPY OF DST FOR PS...V CALC
SUB T1,T2 ;MAKES RESULT
TRZ PS,PS...N!PS...Z!PS...V!PS...C
TRNE T1,100000 ;CHECK FOR NEGATIVE
TRO PS,PS...N
TRZE T1,600000 ;CHECK FOR OVERFLOW
TRO PS,PS...C
SKIPN T1
TRO PS,PS...Z
XOR IR,T2 ;DST XOR SRC
EQV T2,T1 ;SRC EQV RESULT
AND T2,IR
TRNE T2,100000
TRO PS,PS...V
RSTORE FLAG
>
DEFINE SWAB. (FLAG) <
JSR @RFETCH(IR) ;GET ARGUMENT
DPB T1,[POINT 8,T1,19]
LSH T1,-10
TRZ PS,PS...N!PS...Z!PS...V!PS...C
TRNE T1,000200
TRO PS,PS...N
TRNN T1,377
TRO PS,PS...Z
RSTORE FLAG
>
DEFINE SXT. (FLAG) <
HRRM PS,PS.REG+1 ;IN CASE OF BUS TRAP
TRZ PS,PS...V ;ALWAYS CLEARED
TRNN PS,PS...N
TROA PS,PS...Z ;WIN A Z BIT
TRZA PS,PS...Z ;LOST THE Z BIT
TDZA T1,T1
MOVEI T1,177777
JRST @STUFF(IR)
ZZRET== -1
>
DEFINE TST. (FLAG) <
JSR @FETCH(IR) ;GET OPERAND
TRZ PS,PS...N!PS...Z!PS...V!PS...C
TRNE T1,100000
TRO PS,PS...N
SKIPN T1
TRO PS,PS...Z
>
DEFINE TSTB. (FLAG) <
JSR @BFETCH(IR) ;GET OPERAND
TRZ PS,PS...N!PS...Z!PS...V!PS...C
TRNE T1,000200
TRO PS,PS...N
SKIPN T1
TRO PS,PS...Z
>
DEFINE WAIT. (FLAG) <
TADJUS
WAIT0:
TXNN FLG,F.EXEC ;RUNNING IN EXEC MODE ?
JRST WAIT1 ;NO
SKIPN BR7PND ;CHECK FOR INTERUPTS HAPPENED
SKIPE BR5PND ;CHECK OTHER FLAVOUR
JRST SIM11 ;GO TAKE INTERRUPT
SOSLE T1,INTDLY
JRST WAIT0 ;NOT YET
TADJUS
HRRZ T1,CTISPD
MOVEM T1,INTDLY
MOVEM T1,INTDLY+1
CALL TIMCHK
JRST WAIT0
JRST SIM11
WAIT1: HRRE T1,INTDLY+1
ADDM T1,INSRUN ;ACCUMULATE NUMBER OF INSTRUCTIONS EXECUTED
ADDM T1,WAITIM ;ACCUMULATE WAIT TIME
MOVE T1,CTISPD
HRRM T1,INTDLY
HRRM T1,INTDLY+1
CALL TIMCHK
JRST WAIT0
>
DEFINE XOR. (FLAG) <
MOVE T2,-740(T2) ;GET REGISTER
JSR @RFETCH(IR) ;GET OPERAND
TRZ PS,PS...N!PS...Z!PS...V
XOR T1,T2
TRNE T1,100000
TRO PS,PS...N
SKIPN T1
TRO PS,PS...Z
RSTORE FLAG
>
; STACK MODIFICATION INSTRUCTIONS
DEFINE JSR. (FLAG) <
JSR @JMPCLC(IR) ;GET ADR OF JSR
TRZ T2,777770 ;REG IN JSR REG,FOO
HRLM T1,T2 ;SAVE SUBROUTINE ADR
MOVE T1,(T2) ;GET CURRENT REG CONTENTS
MOVEI SP,-2(SP) ;START PUSHING OLD REG ON STACK
ANDI SP,177777 ;BE SURE DIDN'T PUSH TO FAR
HRRZM PC,(T2) ;PUT PC IN REG
HLRZ PC,T2 ;GET SUBROUTINE ADR BACK
HRRM PS,PS.REG+1 ;SAVE PS IN CASE OF STACK VIOLATION
STORE SP,T1 ;FINISH PUSHING REG ON STACK
TRNE PC,1 ;BE SURE NEW PC KOSHER
JRST NXM... ;DIE
>
DEFINE MARK. (FLAG) <
ANDI IR,77 ;LEAVES N
LSH IR,1 ;MAKES N*2
HRRZ SP,IR
ADDI SP,(PC) ;SP FROM PC + 2*NN
HRRZ PC,5 ;PC FROM R5
LOAD SP,5
MOVEI SP,2(SP)
ANDI SP,177777
TRNE PC,1 ;IS NEW PC OK
JRST NXM... ;TAKE A BUS TRAP
>
DEFINE MFPS. (FLAG) <
HRRM PS,PS.REG+1 ;IN CASE OF BUS TRAP
HRRZ T1,PS ;GET DATA TO STORE
TRZ PS,PS...N!PS...Z!PS...V
TRNE T1,200
TRO PS,PS...N
TRNN T1,377
TRO PS,PS...Z
JRST @BSTUFF(IR) ;NOW STORE THE DATA
ZZRET== -1
>
DEFINE MTPS. (FLAG) <
JSR @BFETCH(IR) ;GET WHAT TO SET PS TO
HRRM PS,PS.REG+1 ;SAVE ORIGINAL PS
HRRZ PS,T1 ;SET NEW PS
CALL PS.CHK ;TAKE AN INTERRUPT MAYBE
>
; THE INTERUPT INSTRUCTIONS
DEFINE BPT. (FLAG) <
INTSAV 14
>
DEFINE IOT. (FLAG) <
INTSAV 20
>
DEFINE EMT. (FLAG) <
INTSAV 30
>
DEFINE TRAP. (FLAG) <
INTSAV 34
>
; THE BRANCH INSTRUCTIONS
DEFINE BCC. (FLAG) <
TRNE PS,PS...C
JRST SIM11 ;NO BRANCH
>
DEFINE BCS. (FLAG) <
TRNN PS,PS...C
JRST SIM11 ;NO BRANCH
>
DEFINE BEQ. (FLAG) <
TRNN PS,PS...Z
JRST SIM11
>
DEFINE BGE. (FLAG) <
TRNN PS,PS...N
JRST [TRNE PS,PS...V
JRST SIM11 ;NO BRANCH
JRST .+3 ]
TRNN PS,PS...V
JRST SIM11 ;NO BRANCH
>
DEFINE BGT. (FLAG) <
TRNE PS,PS...Z
JRST SIM11 ;NO BRANCH
TRNN PS,PS...N
JRST [TRNE PS,PS...V
JRST SIM11 ;NO BRANCH
JRST .+3 ]
TRNN PS,PS...V
JRST SIM11 ;NO BRANCH
>
DEFINE BHI. (FLAG) <
TRNE PS,PS...Z!PS...C
JRST SIM11 ;NO BRANCH
>
DEFINE BHIS. (FLAG) <
TRNE PS,PS...C
JRST SIM11 ;NO BRANCH
>
DEFINE BLE. (FLAG) <
TRNE PS,PS...Z
JRST .+5 ;BRANCH
TRNE PS,PS...N
JRST [TRNE PS,PS...V
JRST SIM11 ;NO BRANCH
JRST .+3 ]
TRNN PS,PS...V
JRST SIM11 ;NO BRANCH
>
DEFINE BLO. (FLAG) <
TRNN PS,PS...C
JRST SIM11 ;NO BRANCH
>
DEFINE BLOS. (FLAG) <
TRNN PS,PS...Z!PS...C
JRST SIM11 ;NO BRANCH
>
DEFINE BLT. (FLAG) <
TRNE PS,PS...N
JRST [TRNE PS,PS...V
JRST SIM11 ;NO BRANCH
JRST .+3 ]
TRNN PS,PS...V
JRST SIM11 ;NO BRANCH
>
DEFINE BMI. (FLAG) <
TRNN PS,PS...N
JRST SIM11 ;NO BRANCH
>
DEFINE BNE. (FLAG) <
TRNE PS,PS...Z
JRST SIM11
>
DEFINE BPL. (FLAG) <
TRNE PS,PS...N
JRST SIM11 ;NO BRANCH
>
DEFINE BR. (FLAG) <
>
DEFINE BVC. (FLAG) <
TRNE PS,PS...V
JRST SIM11 ;NO BRANCH
>
DEFINE BVS. (FLAG) <
TRNN PS,PS...V
JRST SIM11 ;NO BRANCH
>
;MACROS TO BUILD DISPATCH TABLES
DEFINE TAGDSP (TAG) <Q=0
REPEAT 10,<QQ=0
REPEAT 10,< TAGDS2 TAG,\Q,\QQ
QQ=QQ+1>
Q=Q+1>>
DEFINE TAGDS2 (TAG,Q,QQ) <EXP TAG'Q'QQ>
;MACRO TO DEFINE GET, RGET, AND PUT
; GET AND RGET RETURN DATA IN T1
; RGET ALSO SETS UP MA
; PUT STORES DATA IN T1
DEFINE MODES (Q) <
XLIST
;MODE 0 - REGISTER MODE
SGET0'Q:Z
HRRZ T1,(T2) ;GET REGISTER
HRRZ MA+1,IR ;COPY DEST MODE
ANDI MA+1,7 ;LEAVE ONLY DEST REGISTER
CAME MA+1,T2 ;SAME AS SRC REGISTER ?
JRST @SGET0'Q ;NO SO DONE
CAIL IR,20 ;MAYBE DEST IS REG OR @REG ?
CAILE IR,57 ;OR IS INDEXED OR @INDEXED ?
JRST @SGET0'Q ;ONE OF THOSE SO DONE
CAIGE IR,30
ADDI T1,4 ;WAS AUTO INCREMENT MODE
SUBI T1,2
ANDI T1,177777 ;STRIP EXTRA BITS
JRST @SGET0'Q
GET0'Q: Z
HRRZ T1,Q
JRST @GET0'Q
RGET0'Q:Z
HRROI MA,Q
HRRZ T1,Q
JRST @RGET0'Q
SBGT0'Q:Z
HRRZ T1,(T2) ;GET REGISTER
ANDI T1,377 ;STRIP EXTRA BITS
HRRZ MA+1,IR ;COPY DEST MODE
ANDI MA+1,7 ;LEAVE ONLY DEST REGISTER
CAME MA+1,T2 ;SAME AS SRC REGISTER ?
JRST @SBGT0'Q ;NO SO DONE
CAIL IR,20 ;MAYBE DEST IS REG OR @REG ?
CAILE IR,57 ;OR IS INDEXED OR @INDEXED ?
JRST @SBGT0'Q ;ONE OF THOSE SO DONE
CAIGE IR,30
IFL <Q-6>,<ADDI T1,2
SOS T1>
IFGE <Q-6>,< ADDI T1,4 ;WAS AUTO INCREMENT MODE
SUBI T1,2>
ANDI T1,377 ;STRIP EXTRA BITS
JRST @SBGT0'Q
BGET0'Q:Z
HRRZ T1,Q
ANDI T1,377
JRST @BGET0'Q
BRGT0'Q:Z
HRROI MA,Q
HRRZ T1,Q
ANDI T1,000377
JRST @BRGT0'Q
JMP0'Q==JMPREG ;REGISTER MODE ILLEGAL FOR JMP & JSR
PUT0'Q: HRRZ Q,T1 ;LOAD REGISTER
IFE <Q-PC> <TRNE PC,1 ;BE SURE PC NOT CORRUPTED
JRST NXM...>
JRST SIM11
BPUT0'Q:TRZ Q,377 ;STRIP OLD BITS
TRO Q,(T1) ;SET NEW BITS
IFE <Q-PC> <TRNE PC,1 ;BE SURE PC NOT CORRUPTED
JRST NXM...>
JRST SIM11
;MODE 1 - REGISTER DEFERRED
RGET1'Q:IFE <Q-6>,<Z
HRRZ MA,Q ;COPY CONTENTS OF REGISTER
CAIGE MA,400
JSR STACKV ;WE'RE GONNA VIOLATE STACK
LOAD MA,T1
JRST @RGET1'Q>
SGET1'Q:GET1'Q: Z
LOAD Q,T1
JRST @GET1'Q
BRGT1'Q:IFE <Q-6>,<Z
HRRZ MA,Q ;COPY STACK POINTER
CAIGE MA,400
JSR STACKV ;WE'RE GONNA VIOLATE STACK
BLOAD MA,T1
JRST @BRGT1'Q>
SBGT1'Q:BGET1'Q:Z
BLOAD Q,T1
JRST @BGET1'Q
JMP1'Q: Z
HRRZ T1,Q
JRST @JMP1'Q
PUT1'Q: STORE Q,T1
JRST SIM11
BPUT1'Q:BSTORE Q,T1
JRST SIM11
;MODE 2 - AUTO-INCREMENT
RGET2'Q:IFE <Q-6>,<Z
HRRZ MA,Q ;COPY STACK POINTER
ADDI Q,2
IFL <Q-6>,<ANDI Q,177777>
CAIGE MA,400
JSR STACKV ;WE'RE GONNA VIOLATE STACK
LOAD MA,T1
JRST @RGET2'Q>
SGET2'Q:
GET2'Q: Z
HRRZ MA,Q ;COPY REGISTER
ADDI Q,2
IFL <Q-6>,<ANDI Q,177777>
LOAD MA,T1
JRST @GET2'Q
BRGT2'Q:IFE <Q-6>,<Z
HRRZ MA,Q ;COPY STACK POINTER
IFGE <Q-6>,<ADDI Q,2>
IFL <Q-6>,< AOS Q>
IFL <Q-6>,<ANDI Q,177777>
CAIGE MA,400
JSR STACKV ;WE'RE GONNA VIOLATE STACK
BLOAD MA,T1
JRST @BRGT2'Q>
SBGT2'Q:BGET2'Q:
Z
HRRZ MA,Q ;COPY REGISTER
IFGE <Q-6>,<ADDI Q,2>
IFL <Q-6>,< AOS Q>
IFL <Q-6>,<ANDI Q,177777>
BLOAD MA,T1
JRST @BGET2'Q
JMP2'Q: Z
HRRZ T1,Q
ADDI Q,2
IFL <Q-6>,<ANDI Q,177777>
JRST @JMP2'Q
PUT2'Q: HRRZ MA,Q ;COPY REGISTER
ADDI Q,2
IFL <Q-6>,<ANDI Q,177777>
STORE MA,T1
JRST SIM11
BPUT2'Q:HRRZ MA,Q ;COPY REGISTER
IFGE <Q-6>,<ADDI Q,2>
IFL <Q-6>,<AOS Q
ANDI Q,177777>
BSTORE MA,T1
JRST SIM11
;MODE 3 - AUTO-INCREMENT DEFERRED
SGET3'Q:GET3'Q:RGET3'Q:Z
HRRZ MA,Q ;COPY REGISTER
ADDI Q,2
IFL <Q-6>,<ANDI Q,177777>
LOAD MA,MA
LOAD MA,T1
JRST @GET3'Q
SBGT3'Q:BGET3'Q:BRGT3'Q:Z
HRRZ MA,Q ;COPY REGISTER
ADDI Q,2 ;;2 (NOT 1) BECAUSE DEFERRED
IFL <Q-6>,<ANDI Q,177777>
LOAD MA,MA
BLOAD MA,T1
JRST @BGET3'Q
JMP3'Q: Z
HRRZ MA,Q ;COPY REGISTER
ADDI Q,2
IFL <Q-6>,<ANDI Q,177777>
LOAD MA,T1
JRST @JMP3'Q
PUT3'Q: HRRZ MA,Q ;COPY REGISTER
ADDI Q,2
IFL <Q-6>,<ANDI Q,177777>
LOAD MA,MA
STORE MA,T1
JRST SIM11
BPUT3'Q:HRRZ MA,Q ;COPY REGISTER
ADDI Q,2 ;2 (NOT 1) BECAUSE DEFERRED
IFL <Q-6>,<ANDI Q,177777>
LOAD MA,MA
BSTORE MA,T1
JRST SIM11
;MODE 4 - AUTO-DECREMENT
RGET4'Q:
IFE <Q-6>,<Z
SUBI Q,2
IFL <Q-7>,<ANDI Q,177777>
HRRZ MA,Q ;COPY SP IN CASE OF STACK VIOLATION
CAIGE MA,400
JSR STACKV ;WE'RE GONNA VIOLATE STACK
LOAD MA,T1
JRST @RGET4'Q>
SGET4'Q:GET4'Q: Z
SUBI Q,2
IFL <Q-7>,<ANDI Q,177777>
LOAD Q,T1
JRST @GET4'Q
BRGT4'Q:
IFE <Q-6>,<Z
IFGE <Q-6>,<SUBI Q,2>
IFL <Q-6>,<SOSGE Q>
IFL <Q-7>,<ANDI Q,177777>
HRRZ MA,Q
CAIGE MA,400
JSR STACKV ;WE'RE GONNA VIOLATE STACK
BLOAD MA,T1
JRST @BRGT4'Q>
SBGT4'Q:BGET4'Q:Z
IFGE <Q-6>,<SUBI Q,2>
IFL <Q-6>,<SOSGE Q>
IFL <Q-7>,<ANDI Q,177777>
BLOAD Q,T1
JRST @BGET4'Q
JMP4'Q: Z
IFL <Q-7>,<ANDI Q,177777>
HRRZ T1,Q
JRST @JMP4'Q
PUT4'Q: SUBI Q,2
IFL <Q-7>,<ANDI Q,177777>
STORE Q,T1
JRST SIM11
BPUT4'Q:
IFGE <Q-6>,<SUBI Q,2>
IFL <Q-6>,<SOSGE Q>
IFL <Q-7>,<ANDI Q,177777>
BSTORE Q,T1
JRST SIM11
;MODE 5 - AUTO-DECREMENT DEFERRED
SGET5'Q:GET5'Q:RGET5'Q:Z
SUBI Q,2
IFL <Q-7>,<ANDI Q,177777>
LOAD Q,MA
LOAD MA,T1
JRST @GET5'Q
SBGT5'Q:BGET5'Q:BRGT5'Q:Z
SUBI Q,2 ;2 (NOT 1) BECAUSE DEFERRED
IFL <Q-7>,<ANDI Q,177777>
LOAD Q,MA
BLOAD MA,T1
JRST @BGET5'Q
JMP5'Q: Z
SUBI Q,2
IFL <Q-7>,<ANDI Q,177777>
LOAD Q,T1
JRST @JMP5'Q
PUT5'Q: SUBI Q,2
IFL <Q-7>,<ANDI Q,177777>
LOAD Q,MA
STORE MA,T1
JRST SIM11
BPUT5'Q:SUBI Q,2 ;2 (NOT 1) BECAUSE DEFERRED
IFL <Q-7>,<ANDI Q,177777>
LOAD Q,MA
BSTORE MA,T1
JRST SIM11
;MODE 6 - INDEXED
RGET6'Q:
IFE <Q-6>,<Z
LOAD PC,MA
ADDI PC,2
ADD MA,Q
ANDI MA,177777
CAIGE MA,400
JSR STACKV ;WE'RE GONNA VIOLATE STACK
LOAD MA,T1
JRST @RGET6'Q>
SGET6'Q:GET6'Q: Z
LOAD PC,MA
ADDI PC,2
ADD MA,Q
ANDI MA,177777
LOAD MA,T1
JRST @GET6'Q
BRGT6'Q:
IFE <Q-6>,<Z
LOAD PC,MA
ADDI PC,2
ADD MA,Q
ANDI MA,177777
CAIGE MA,400
JSR STACKV ;WE'RE GONNA VIOLATE STACK
BLOAD MA,T1
JRST @BRGT6'Q>
SBGT6'Q:BGET6'Q:Z
LOAD PC,MA
ADDI PC,2
ADD MA,Q
ANDI MA,177777
BLOAD MA,T1
JRST @BGET6'Q
JMP6'Q: Z
LOAD PC,T1
ADDI PC,2
ADD T1,Q
ANDI T1,177777
JRST @JMP6'Q
PUT6'Q: LOAD PC,MA
ADDI PC,2
ADD MA,Q
ANDI MA,177777
IFE <Q-6>,<CAIGE MA,400
JSR STCKVP>
STORE MA,T1
JRST SIM11
BPUT6'Q:LOAD PC,MA
ADDI PC,2
ADD MA,Q
ANDI MA,177777
IFE <Q-6>,<CAIGE MA,400
JSR STCKVP>
BSTORE MA,T1
JRST SIM11
;MODE 7 - INDEXED DEFERRED
SGET7'Q:GET7'Q:RGET7'Q:Z
LOAD PC,MA
ADDI PC,2
ADD MA,Q
ANDI MA,177777
LOAD MA,MA
LOAD MA,T1
JRST @GET7'Q
SBGT7'Q:BGET7'Q:BRGT7'Q:Z
LOAD PC,MA
ADDI PC,2
ADD MA,Q
ANDI MA,177777
LOAD MA,MA
BLOAD MA,T1
JRST @BGET7'Q
JMP7'Q: Z
LOAD PC,MA
ADDI PC,2
ADD MA,Q
ANDI MA,177777
LOAD MA,T1
JRST @JMP7'Q
PUT7'Q: LOAD PC,MA
ADDI PC,2
ADD MA,Q
ANDI MA,177777
LOAD MA,MA
STORE MA,T1
JRST SIM11
BPUT7'Q:LOAD PC,MA
ADDI PC,2
ADD MA,Q
ANDI MA,177777
LOAD MA,MA
BSTORE MA,T1
JRST SIM11
LIST
>
;TRANSLATION OF IO ADDRESS SPACE
DEFINE DDBGEN (DEV,WRDS) <
IF2,<IFGE <DEV'ADR-DDBADR>
<PRINTX ERROR BUILDING IOMAP>
IFNDEF DEV'TIM,<DEV'TIM==R> ;DEFAULT TIMER ROUTINE
IFNDEF DEV'RST,<DEV'RST==R> ;DEFAULT RESET ROUTINE
IFNDEF DEV'LVL,<DEV'LVL==0 ;DEFAULT INTERRUPT LEVEL
DEV'INT==0>> ;DEFAULT INTERRUPT ROUTINE
DEV'DDB: PHASE 0
0,,DEV'ADR ;FIRST ADR IN DEVICE
0,,DEV'ADR+WRDS+WRDS-1 ;HIGHEST ADR IN DEVICE
DDBADR==DEV'ADR
DV.LNK:! DDBLNK,,DDBLNK ;LINK TO NEXT DEVICE BLOCK
DDBLNK==DEV'DDB
DV.LOD:! EXP DEV'LOD ;DISPATCH FOR LOAD
DV.BLD:! EXP DEV'BLD ;DISPATCH FOR BYTE LOAD
DV.WRT:! EXP DEV'WRT ;DISPATCH FOR WRITING WORDS
DV.BWR:! EXP DEV'BWR ;DISPATCH FOR WRITING BYTES
DV.TIM:! EXP DEV'TIM ;DISPATCH WHEN TIMER GOES OFF
; RETURNS WITH SKIP IF INTERRUPTED
Z ;TIME TO TAKE TIMER DISPATCH
DV.RST:! EXP DEV'RST ;DISPATCH FOR RESET
DV.LVL:! EXP DEV'LVL ;CONTAINS DEVICE LEVEL
DV.INT:! EXP DEV'INT ;DISPATCH IF WANT TO CHECK FOR INTERRUPTS
DV.SIZ:!
DEPHASE
>
;FOLLOWING DDBGEN ARE SIMULATED DEVICES TO USE STANDARD READ, WRITE ROUTINES
; 0,,0 ;LH IS WRITEABLE BY PROGRAM BITS,,RH IS REGISTER
; 0,,0 ;LH IS WRITEABLE BY OPERATORE BITS,,RH IS OLD REGISTER
UBXADR==163000
MMVEC==250 ; VECTOR FOR AN INTERUPT FROM MEMORY MANAGEMENT
KG.ADR==170700
SIPDR==172200 ; SUPERVISOR INST PDR
SDPDR==172220 ; SUPERVISOR DATA PDR
SIPAR==172240 ; SUPERVISOR INST PAR
SDPAR==172260 ; SUPERVISPR DATA PAR
KIPDR==172300 ; KERNAL INST PDR
KDPDR==172320 ; KERNAL DATA PDR
KIPAR==172340 ; KERNAL INST PAR
KDPAR==172360 ; KERNAL DATA PAR
MMR3==172516 ; MEMORY MANAGEMENT REGISTER 3
CLKADR==177546 ; KW11-L
CLKLVL==6
CTYADR==177560 ; DL11 NUMBER 0
CTYLVL==4
SW.ADR==177570 ; SWITCH REGISTER AND LIGHTS
MMR0==177572 ; MEMORY MANAGEMENT REGISTER 0
MMR1==177574 ; MEMORY MANAGEMENT REGISTER 1
MMR2==177576 ; MEMORY MANAGEMENT REGISTER 2
UIPDR==177600 ; USER INST PDR
UDPRD==177620 ; USER DATA PDR
UIPAR==177640 ; USER INST PAR
UDPAR==177660 ; USER DATA PAR
CMHADH==177752 ; CACHE HIT/MISS COUNTS
SIZADR==177760 ; SYSTEM SIZE, TWO WORDS
SIDADR==177764 ; SYSTEM I/D WORD
CPUADR==177766 ; CPU ERROR ADDRESS
MPBADR==177770 ; MICROPROGRAM BREAK
PIRADR==177772 ; PROGRAM INTERUPT REQUESTS
SL.ADR==177774 ; STACK LIMIT
PS.ADR==177776 ; PROCESOR STATUS WORD
; EPTBLK POINTS TO THE START OF:
EPT...==0 ;PAGE FOR EXEC PROCESS TABLE
UPT...==1000 ;PAGE FOR USER PROCESS TABLE
STB...==2000 ;PAGE FOR SECTION TABLE FOR SECTION 0
CST...==3000 ;PAGE FOR CORE STATUS TABLE
VECTAB==4000 ;3000 WORDS FOR VECTORED INTERRUPTS
DSKPAG==7000 ;PAGE FOR DISK IO
EBLKSZ==10000 ;SIZE OF BLOCK FOR EXEC USAGE
APRLVL==2
DEFINE MOVX (AC,MSK)<
.XCREF
..MX1==MSK
.IFN ..MX1,ABSOLUTE,<MOVE AC,[MSK]>
.IF ..MX1,ABSOLUTE,<..MX2==0
IFE <..MX1>B53,<..MX2==1
MOVEI AC,..MX1>
IFE ..MX2,<IFE <..MX1>B17,<..MX2==1
MOVSI AC,(..MX1)>>
IFE ..MX2,<IFE <<..MX1>B53-^O777777>,<..MX2==1
HRROI AC,<..MX1>>>
IFE ..MX2,<IFE <<..MX1>B17-^O777777B17>,<..MX2==1
HRLOI AC,(..MX1-^O777777)>>
IFE ..MX2,<MOVE AC,[..MX1]>>
.CREF
>
DEFINE ..DOTX (M,T) <
IRP M,<
IRP T,<
DEFINE TX'M'T (AC,MSK)<.XCREF
..TX(M'T,AC,<MSK>)
.CREF>
>>>
..DOTX (<N,O,Z,C>,<,E,N,A>) ;DO ALL DEFINITIONS
PURGE ..DOTX
DEFINE ..TX(MT,AC,MSK)<
..TX1==MSK
.IFN ..TX1,ABSOLUTE,<TD'MT AC,[MSK]>
.IF ..TX1,ABSOLUTE,<..TX2==0
IFE <..TX1&^O777777B17>,<..TX2==1
TR'MT AC,..TX1>
IFE ..TX2,<IFE <..TX1&^O777777>,<..TX2==1
TL'MT AC,(..TX1)>>
IFE ..TX2,<IFE <<..TX1>B53-^O777777>,<..TX3 (MT,AC)>>
IFE ..TX2,<IFE <..TX1+1>,<..TX4 (MT,AC)>>
IFE ..TX2,<TD'MT AC,[..TX1]>>
>
DEFINE ..TX3 (MT,AC)<
IFIDN <MT><Z>,< ..TX2==1
ANDI AC,^-..TX1>
IFIDN <MT><O>,< ..TX2==1
ORCMI AC,^-..TX1>
IFIDN <MT><C>,< ..TX2==1
EQVI AC,^-..TX1>
>
DEFINE ..TX4 (MT,AC)<IFIDN <MT><NN>,<..TX2==1
CAIN AC,0>
IFIDN <MT><NE>,<..TX2==1
CAIE AC,0>>
END