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common.x22
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TITLE COMMON - MONITOR COMMON DATA AREA AND CONFIGURATION DEFINITION -V2370
SUBTTL PART 6 COMMON.MAC - T. HASTINGS/PH/TWE/DAL/EVS/JBS/EGF 10-JANUARY-89
SEARCH F,S,DEVPRM
IFN FTNET,<SEARCH NETPRM>
$RELOC
$ABS
;COPYRIGHT (c) DIGITAL EQUIPMENT CORPORATION
; 1973,1974,1975,1976,1977,1978,1979,1980,1982,1984,1986,1988.
;ALL RIGHTS RESERVED.
;
;
;THIS SOFTWARE IS FURNISHED UNDER A LICENSE AND MAY BE USED AND COPIED
;ONLY IN ACCORDANCE WITH THE TERMS OF SUCH LICENSE AND WITH THE
;INCLUSION OF THE ABOVE COPYRIGHT NOTICE. THIS SOFTWARE OR ANY OTHER
;COPIES THEREOF MAY NOT BE PROVIDED OR OTHERWISE MADE AVAILABLE TO ANY
;OTHER PERSON. NO TITLE TO AND OWNERSHIP OF THE SOFTWARE IS HEREBY
;TRANSFERRED.
;
;THE INFORMATION IN THIS SOFTWARE IS SUBJECT TO CHANGE WITHOUT NOTICE
;AND SHOULD NOT BE CONSTRUED AS A COMMITMENT BY DIGITAL EQUIPMENT
;CORPORATION.
;
;DIGITAL ASSUMES NO RESPONSIBILITY FOR THE USE OR RELIABILITY OF ITS
;SOFTWARE ON EQUIPMENT THAT IS NOT SUPPLIED BY DIGITAL.
XP VCOMMN,2370 ;PUT VERSION NUMBER IN GLOB AND LOADER STORAGE MAP
SUBTTL SET PSECT ORIGINS
;MONITOR PSECT ORIGINS MAY BE CHANGED BY EDITTING THE FOLLOWING DEFINITIONS.
;THE DEFINITIONS OF THE ORIGINS MAY APPEAR IN THE HARDWARE CONFIGURATION FILE
;SYSCNF.MAC TO OVER-RIDE THE DEFAULT ORIGINS DEFINED BELOW.
IFN FTXMON,<
ND CSBORG,330000 ;ORIGIN OF COMMON SUBROUTINES
>; END IFN FTXMON
IFN M.KL10,<
ND MONORG,340000 ;ORIGIN OF HIGH SEGMENT ON KL
>; END IFN M.KL10
IFN M.KS10,<
ND MONORG,344000 ;ORIGIN OF HIGH SEGMENT ON KS
>; END IFN M.KS10
IFE FTXMON,<
XP CSBORG,MONORG ;JUST FOR THOSE WHO CARE
>; END IFE FTXMON
IFN FTXMON,<
ND XHIORG,<MS.HGH+630000> ;ORIGIN OF EXTENDED HIGH SEGMENT
>; END IFN FTXMON
;NOW SET THE PSECT ORIGINS BEFORE ANY CODE IS GENERATED.
;*** .HIGH. MUST BE FIRST DUE TO A LINK BUG ***
.PSECT .HIGH.,MONORG ;HIGH SEGMENT
.ENDPS
IFN FTXMON,<
.PSECT .CSUB.,CSBORG ;COMMON SUBROUTINES
.ENDPS
>; END IFN FTXMON
.PSECT .INIT.,FYSORG ;INITIALIZATION CODE OVERLAYS FUNNY SPACE
.ENDPS
.PSECT .TWIC.,.UPMAP ;USER MODE DISK ONCE-ONLY
.ENDPS
IFN FTXMON,< ;IF EXTENDED MONITOR
.PSECT .XHGH.,XHIORG ;EXTENDED HIGH SEGMENT
.ENDPS
.PSECT .SYMS.,MS.HGH ;EXTENDED SYMBOL TABLE
.ENDPS
>; END IFN FTXMON
;TELL LINK WHERE TO PUT SYMBOL TABLE. FOR SINGLE SECTION MONITOR SYMBOLS
;GO IN PSECT .LOW., FOR MULTI SECTION MONITOR SYMBOLS GO IN EXTENDED HIGH
;SEGMENT (AT BEGINNING OF THAT SECTION).
IFE FTXMON,<
.TEXT "/SYMSEG:PSECT:.LOW."
>; END IFE FTXMON
IFN FTXMON,<
.TEXT "/SYMSEG:PSECT:.SYMS."
>; END IFN FTXMON
;*** CODE TO SET PSECT LIMITS IS AT THE END OF COMMON.MAC ***
SUBTTL HISTORICAL NOTES
REPEAT 0, <
;THE COMMON SUBPROGRAM CONSISTS OF 6 FILES ASSEMBLED TOGETHER AS ONE SUBPROGRAM
1. F.MAC -- FEATURE TESTS (OUTPUT OF MONGEN).
2. S.MAC -- THE USUAL SYSTEM SYMBOL DEFINITIONS ASSEMBLED WITH
EVERY MONITOR SUBPROGRAM
3. SYSCNF.MAC -- SYSTEM CONFIGURATION
4. COMMON.MAC - THE REST OF THIS PROGRAM WHICH IS THE SAME SOURCE FOR
ALL CONFIGURATIONS. HOWEVER, THE ASSEMBLIES ARE CONDITIONED BY
SYMBOLS AND MACROS DEFINED IN 2.
THE FOLLOWING SYMBOLS AND TABLES ARE GENERATED BELOW:
A. MONITOR STARTUP LOCATIONS (400-407), HENCE LOAD THIS FIRST.
B. JOB TABLES - LENGTH DEPENDENT ON MAXIMUM NUMBER OF JOBS ALLOWED
C. ALL VARIABLE STORAGE NOT ASSOCIATED WITH A PARTICULAR DEVICE
D. COMMON SUBROUTETURNS
E. COMMON BYTE POINTERS
F. TABLE OF SERVICE ROUTINE INTERRUPT LOCS TO BE LINKED BY ONCE ONLY CODE
G. TABLE OF DEVICE DATA BLOCK ADDRESSES AND NUMBER TO BE USED BY ONCE TO
LINK THEM TOGETHER AND GENERATE MULTIPLE COPIES.
H. ASSIGNMENT OF PI CHANNELS
I. PI CHANNEL SAVE AND RESTORE ROUTINES
J. UUO TRAP LOCATIONS 40/41, 60/61
K. APR INTERRUPT LOCATIONS CPU0,1, KA10/KI10
L. SYSTEM CRASH STOP CONI'S.
NOTE: SEE COMDEV FOR DEVICE DEPENDENT CODE, DATA, AND SYMBOLS
LEVEL D DISK SERVICE PARAMETERS:
ALL SYMBOLS ANAS ONATIONS ARE IN A SEPARATE FILE CALLED
COMMOD.MAC WHICH IS ALSO ASSEMBLED WITH S AND CONFIG (BUT NOT WITH FEATURS FILES).
THE SEPARATE FILE IS FOR TWO REASONS: 1. ANTICIPATING MULTIPROCESSING SYSTEMS WHICH SHARE DISKS AND 1 16K MEMORY
(THE DATA MUST BE IN THE COMMON MEMORY)
2. ELIMINATE THE NEED TO ASSEMBLE COMMOD IF NOT A DISK SYSTEM
(COMMOD.MAC TAKES LOTS OF CORE FOR ITS COMPLICATED MACROS)
>
IFE FTNET,<IFN M.NET,<PRINTX ?ASSEMBLE SOURCES WITH FTNET=-1
M.NET==0>>
;Verify that the correct version of MONGEN was used in making the SYSCNF
;files.
;
;Every time that MONGEN is edited, the following check "M.GEN-nnn" should
;also be updated to reflect the new MONGEN edit level (symbol 'EDITNO' in
;MONGEN.MAC).
IFN M.GEN-327,<
PRINTX ? Wrong version of MONGEN was used in SYS dialog
PASS2
END
>
IFN FTEMRT,<IFE M.KL10,<PRINTX ? CPU MUST BE A KL10 TO SELECT EBOX/MBOX RUNTIME>>
IFN FTCIDSK!FTCITAP,<IFE FTSCA,<PRINTX ?ASSEMBLE SOURCES WITH FTSCA=-1
XP FTCIDSK,0 ;FORCE MULTIPLY DEFINED GLOBALS
XP FTCITAP,0>>
IFN M.ENET,<IFE FTENET,<PRINTX ?ASSEMBLE SOURCES WITH FTENET=-1
XP M.ENET,0>>
IFE M.NET,<EQUATE (GLOBAL,0,<M.ENET,M.LAT,M.DECN,M.ANF,M.RTTY>)>
IFE M.ANF,<EQUATE (GLOBAL,0,<M.RMCR,M.RVTM>)>
SUBTTL CONVERT MONGEN SYMBOLS
;THIS SECTION CONVERTS NEW MONGEN SYMBOLS TO OLD MONGEN SYMBOLS
;SO THAT THE REST OF COMMON AND MONITOR CAN STILL USE THE OLD
;SYMBOLS. THIS WAS DONE RATHER THAN CONVERTING ALL OF THE
;MONITOR TO NEW SYMBOLS FOR TWO REASONS:
; 1. IT IS EASIER AND FASTER AND LESS LIKELY TO INTRODUCE BUGS, AND
; 2. IT ALLOWS CUSTOMERS TO USE OLD MONGEN WITH A MINIMUM
;OF TROUBLE: ONLY A FEW EXTRA SYMBOLS MUST BE DEFINED.
;THE MONITOR WILL PROBABLY BE CONVERTED TO THE NEW MONGEN SYMBOLS
;AFTER THE 5.04 RELEASE. THE ORDER HERE PARALLELS THE OLD
;MONGEN ORDER.
XP JOBN,M.JOB+1
IFG JOBN-^D512,<XP JOBN,^D512
PRINTX %NUMBER OF JOBS REDUCED TO MAX=511>
XP PDP10N,1
XP SEGN,MD.SEG
XP VBCN,M.VBXC
XP XTCN,M.XTC
IFE M.XTC,<
XP M.XTL,0
XP XTTDSP,CPOPJ
XP XTKLDB,CPOPJ
XP XTUUO,CPOPJ
XP XTCTTY,CPOPJ2
XP XTCIOS,CPOPJ
XP XTCSEC,CPOPJ
XP XTCLNK,CPOPJ
>
IFE M.DAS78,< ;IF NO DAS78 SUPPORT
CALL78==:CPOPJ ;CAL78. UUO IS A NOOP
D78SEC==:CPOPJ ;NO ONCE-A-SECOND CODE
D78MIN==:CPOPJ ;NO ONCE-A-MINUTE CODE
CWHD78==:CWHNCN## ;NOT CONNECTED IF NO DRIVER
> ;END IFE M.DAS78
IFN M.DAS78,< ;IF DAS78 SUPPORT
M.D78L==:M0D78L ;HACK FOR D78INT
> ;END IFN M.DAS78
XP DISN,M.DIS
XP PENN,M.DIS
XP T340N,M.340
XP TVP10N,M.VP10
XP T30N,0 ;NO TYPE 30
;DEFINE ALL DL10 SYMBOLS
DLX.CK(1) ;MACRO DEFINED IN S.MAC
INTERN DL10XI ;FOR UUOCON
IFN M.KL10!DLX.78,<
IFE M.KL10,<
PRINTX ?DEFINING A DAS78 REQUIRES FTKL10 TO BE ON
PDP11N==PDP11N-DLX.78
DLX.78=0 ;ACTUAL NUMBER
> ;END IFE M.KL10
> ;END IFN M.KL10!DLX.78
IFN DLX.76,<EXTERN D76INT>
IFE PDP11N,<
XP D76MIN,CPOPJ
XP D76SIL,CPOPJ
>
IFE PDP11N!M.KL10!M.DN60!M.KDUP!M.DMRN,<
XP CALL11,CPOPJ
XP DLXSEC,CPOPJ
XP DLXWIN,0
> ; END IFE PDP11N!M.DN60!M.KDUP!M.DMRN
IFE DL10XI,<
XP DLXBAT,0
IFN PDP11N,<
XP DLXDWN,0 ;;IF NO PDP-11S ON DL10'S
>>; END OF IFE DL10XI AND IFN PDP11N
DEFINE TDMAC(X),<
XP DT'X'N,M.DT'X
M.DTXN==M.DTXN+M.DT'X
>
ZZ=="A"
M.DTXN==0
REPEAT M.TD10,<
TDMAC(\"ZZ)
ZZ==ZZ+1
>
IFN FTKS10,<
DEFINE RX2MAC(X),<
XP RX'X'N,M.RX'X
M.RXXN==M.RXXN+M.RX'X
>
ZZ=="A"
M.RXXN==0
REPEAT M.RX20,<
RX2MAC(\"ZZ)
ZZ==ZZ+1
>
>;End FTKS10
IFNDEF M.SYSC,<M.SYSC==:0>
XP CMNN,M.MGC
XP RTTRPN,M.RTD
XP HPQN,M.HPQ
ND M.TTDN,0
XP TTD28N,M.XTL
IFN M.KS10,<
XP KLILIN,M.TLTL+M.RTTY ;LINE NO. FOR KS10 KLINIK
>
DEFINE OPRL(LINE),<
IFIDN <LINE> <CTY>,<SIXBIT /CTY/>
IFDIF <LINE> <CTY>,<
SIXBIT /TTY'LINE/
IFG LINE-M.TLTL,<PRINTX %OPR LINE NOT DEFINED TO BE A LOCAL TTY>
>;END IFDIF <LINE><CTY>
>
SUBTTL DEFAULT SYMBOLS
;THE FOLLOWING STANDARD SYMBOLS CAN BE SUPERSEDED BY A CUSTOMER HAVING
; PREVIOUSLY DEFINED THEM ON THE HDWGEN.MAC FILE USING THE MONGEN PROGRAM....
;**********************************************************************
;ADD NEW SYMBOLS AT END SO EASY TO UPDATE MONGEN APPENDIX *
;SYMBOLS SHOULD APPEAR HERE IN COMMON (AND NOT IN COMDEV, OR COMMOD) *
; UNLESS THEY REFER TO NON-DISK DEVICES OR DISKS RESPECTIVELY. *
; IF A SYMBOL IS IN COMDEV OR COMMOD, IT SHOULD NOT APPEAR HERE. *
;**********************************************************************
ND XPANDN,0 ;FORCE NO EXPANSION OF MACROS
; UNLESS XPANDN IS DEFINED NON-ZERO WITH MONGEN
ND M.C0SN,0 ;SERIAL NUMBER OF ARITHMETIC PROCESSOR
;STANDARD MAG TAPE DENSITY IN BITS PER INCH
ND STDENS,5 ;STANDARD = 6250 BPI
;1=200, 2=556, 3=800, 4=1600, 5=6250
;NUMBER OF TIMES TO TRY ON DECTAPE ERRORS
ND DTTRY,4 ;STANDARD == 4 TRIES
;NUMBER OF NANO-SECONDS PER MEMORY CYCLE
ND NSPMEM,^D1000 ;STANDARD == 1000 NANO-SECONDS PER MEMORY CYCLE
ND M.LPOK,1 ;DEFAULT IS TO LOG POKE UUOS VIA DAEMON
ND M.EDIT,0 ;TTY EDITOR EXCLUSION
ND TTXTRA,0 ;NUMBER OF EXTRA TTY DDBS FOR SLAVE LINES
; AND THE LIKE
ND M.CRSH,<SIXBIT/CRSCPY/> ;NAME OF PROGRAM TO COPY CRASHES
EXTERN MONBTS
ND M.MAIL,<SIXBIT/MS/> ;NAME OF MAIL PROGRAM
ND M.DTCK,0 ;OPR MUST VERIFY DATE/TIME IF NON-ZERO
;FREE CORE ALLOCATION REQUIREMENTS FOR SCA'S RANDOM SIZED POOL.
IFE M.SCA,< ;IF NO SCA SUPPORT
XP SCASIZ,0 ;NO SCA FREE POOL
>; END IFE M.SCA
IFN M.SCA,< ;IF SCA SUPPORT
ND M.SCSZ,4000 ;CAN BE REDEFINED AT MONGEN TIME
XP SCASIZ,<^D144*<<M.SCSZ+^D143>/^D144>>
>; END IFN M.SCA
;FREE CORE ALLOCATION REQUIREMENTS FOR DISK
; DEVICE DATA BLOCKS AND ACCESS TABLE ENTRIES.
XP CORSIZ,4 ;NO. OF WORDS IN MONITOR FREE CORE BLOCKS
ND LOGSIZ,^D41 ;STANDARD == 20K (CURRENT SIZE OF LOGIN CUSP)
;MINIMUM AMOUNT OF VIRTUAL CORE WHICH CAN REMAIN
; AND STILL LET THE SYSTEM PERMIT LOG-INS. MUST
; BE AT LEAST AS BIG AS LOGIN CUSP IN K.
XP MAXLVL,5 ;ABSOLUTE MAX LEVEL OF NESTED SFD'S
ND INDPPN,0 ;NON-ZERO IF CUSTOMER WANTS PROGRAMMER NOS
; IN PROJECT X TO BE INDEPENDENT OF THOSE IN
; PROJECT Y
IF1,<
IFNDEF SYSSEG,<XP SYSSEG,-1> ;MINUS ONE FOR FAST GETSEG FROM SYS
; WITH SOMEWHAT DIFFERENT BEHAVIOR
; WHEN SHR FILES ARE SUPERCEDED
IFDEF SYSSEG,<IFN <SYSSEG+1>,<XP SYSSEG,0>>
XP SYSSEG,SS.SYS&SYSSEG ;SYSSEG=:0 OR SS.SYS
>
ND CTYDCR,0 ;DELAY FOR CR ON LA36 CTY DURING ONCE
ND CTYDLF,0 ;DELAY FOR LF ON LA36 CTY DURING ONCE
ND RLDTIM,^D112 ;TIME TO AUTO-RELOAD
ND M.STOF,0 ;FREQUENCY TO CALL START TERMINAL OUTPUT
; (SHOULD BE 2**N-1)
ND M.RCMP,0 ;DEFAULT TO PERMISSIVE ACCESS
;SET TO 1 FOR MORE SECURE ACCESS
ND M.NPPC,0 ;DEFAULT TO PRIMARY PROTOCOL ON DTE'S
;SET TO 1 TO DISABLE PRIMARY PROTOCOL
ND M.NRQT,0 ;NUMBER OF TICKS BETWEEN CALLS TO CALCULATE
; WANT-TO-RUN TIME FOR ALL JOBS. ZERO IMPLIES
; NO (EXPENSIVE) CALCULATION.
ND MINMAX,^D1024*^D12 ;SMALLEST LEGAL CORMAX
;NOTE--IN ORDER TO RESERVE PI-CHANNELS FOR
;NON-STANDARD USAGE, FOR EACH CHANNEL (SAY N)
;DEFINE SYMBOL UNIQN==1 VIA MONGEN. FOR
;EXAMPLE, TO RESERVE CHANNEL 4, DEFINE
;UNIQ4==1.
;MOST OF THE SLAVE PROCESSOR CHANNELS ARE BUSIED OUT TO PREVENT CORE
;FROM BEING WASTED FOR CHANNEL SAVE ROUTINES
IFNDEF CPTOS,<XP CPTOS,0> ;CPTOS EQUAL TO ZERO MAKES CPU0 TRAP TO 40-61, CPU1 TO 140-161
;CPTOS NON-ZERO MAKES CPU0 TRAP TO 140-161, CPU1 TO 40-61
IFNDEF SFC0,<XP SFC0,^D20> ;CPU0 SCHEDULER FAIRNESS COUNT. PICK A JOB OUT OF
;PQ2 INSTEAD OF PQ1 IF 'SFC0' PICKS IN A ROW HAVE COME FROM PQ1 AND NULL JOB DID NOT RUN.
IFNDEF SFC1,<XP SFC1,^D20> ;CPU1 SCHEDULER FAIRNESS COUNT
;PICK THIS MANY JOBS TO RUN ON CPU0. WHICH
; CAME FROM CPU1 UUOS BEFORE PICKING OTHER JOBS
IFNDEF IFC0,<XP IFC0,^D5> ;SWAPPER FAIRNESS COUNT MAXIMUM
IFNDEF UFC0,<XP UFC0,^D10> ;UUO FAIRNESS COUNTER MAXIMUM
IFNDEF UFC1,<XP UFC1,^D10> ;UUO FAIRNESS COUNTER FOR SLAVE
;PICK UFC1 JOBS TO RUN ON CPU1
;WHICH CAME FROM CPU0 AND JUST FINISHED
;A UUO
IFNDEF MEMITL,<XP MEMITL,^D4> ;NUMBER OF WAYS MEMORY CAN BE INTERLEAVED
IFNDEF MLACTS,<XP MLACTS,^D39> ;MAXIMUM LENGTH OF THE ACCOUNT STRING
; IF NOT DEFINED, 39 CHARACTERS
IFNDEF SCHEDN,<SCHEDN==0> ;SCHEDULE VALUE
SCHEDN==SCHEDN&777777 ;ONLY A RIGHT HALF NUMBER
IFNDEF PAVJSP,<XP PAVJSP,^D20> ;PREDICTED AVERAGE JOB SIZE
IFG MLACTS-^D39,<XP MLACTS,^D39> ;MAXIMUM LENGTH IS 39 CHARACTERS
IFL MLACTS,<XP MLACTS,0>
IFG MLACTS,<XP ACTSTL, MLACTS/^D5+1> ;LENGTH OF ACCOUNT STRING IN WORDS
IFE MLACTS,<XP ACTSTL,0>
XP MACTSL,-ACTSTL
XP MAXACS,^D8 ;MAX LENGTH OF ACCOUNT STRING
IFNDEF M.CBAT,<XP M.CBAT,^D10> ;NO. OF BAD ADDRESSES IN PER CPU BAD
; ADDRESS TABLE FOR MEMORY PARITY RECORDING
IFNDEF M.BMAX,<XP M.BMAX,^D13> ;MAX. NO. OF SIMULTANEOUS BATCH JOB STREAM'S
; INITIATES LOC BATMAX, CHECKED BY BATCON
IFNDEF M.BMIN,<XP M.BMIN,0> ;MIN. NO. OF GUARRANTEED BATCH JOBS
IFNDEF M.EXE,<XP M.EXE,1> ;SYMBOL WHICH DETERMINES TYPE OF FILE
; CREATED ON "SAVE". IF OFF, NORMAL (SAV,HGH,
; LOW,..), IF ON AN EXE FILE IS CREATED
IFNDEF M.JMAX,<XP M.JMAX,M.JOB-M.BMIN> ;MAX. NO. OF SIMULTANEOUS INTERACTIVE JOBS
IFNDEF M.WCH,<XP M.WCH,JW.WMT> ;WATCH BITS USED TO SET INITIAL
; WATCHING. SINCE LOGIN SETS JBTWCH
; THIS IS USEFUL ONLY FOR LINES WHICH
; DON'T NEED LOGIN - INITIA.
;200000 = TIME OF DAY STARTED TO WAIT
;100000 = RUN TIME
;40000 = WAIT TIME
;20000 = BLOCKS READ
;10000 = BLOCKS WRITTEN
;4000 = VERSION NOS.
;2000 = MTA STATISTICS
IFNDEF M.CMCT,<XP M.CMCT,^D32> ;NO. OF CALLS TO CHKTAL ROUTINE
; BEFORE DOING 5 M.S. OF OVERHEAD
; CHECKING CORE TABLES. I.E. ONLY
; EVERY 32 TIME IS OVERHEAD PERFORMED
;THIS REDUCES CPU TIME FOR
; CORE, GETSEG, RUN UUOS
; SYMBOL CANNOT EXCEED 262,000.
IFNDEF M.EBPS,<XP M.EBPS,^D12500000> ;DEFAULT # EBOX TICKS PER SECOND
; (ACCT METER COUNTS AT 1/2 SYSTEM CLOCK RATE)
; SYSTEM CLOCK RATE IS 25MHZ
IFNDEF M.MBPS,<XP M.MBPS,^D9750000> ;DEFAULT MBOX REFS/SECOND
; THIS NUMBER WAS EXPERIMENTALLY
; DETERMINED AT A CPU CLOCK RATE
; OF 25MHZ SUCH THAT THE CPU TIME
; OF A JRST . MATCHED ELAPSED TIME.
; JRST . WAS ASSUMED TO BE A BEST CASE CONDITION.
; THIS TERM MAKES EBOX/MBOX RUNTIME
; PER REAL TIME UNIT DEPENDENT ON
; CACHE HIT RATE, ALTHOUGH INSTRUCTIONS
; PER E/MBOX RUNTIME UNIT SHOULD REMAIN CONSTANT.
IFNDEF M.EMRT,<XP M.EMRT,0> ;DEFAULT IS REGULAR RUNTIME
IFNDEF M.XPI,<XP M.XPI,0> ;AND INCLUDE PI TIME IN USER RUNTIME
IFNDEF M.ITA,<XP M.ITA,0> ;DEFAULT IS TO USE INTERVAL TIMER
IFNDEF M.XFFA,<XP M.XFFA,0> ;DO FILE ACCESS PROTACTION CHECKING ON [1,2] AND JACCT
IFN FTNSCHED,<
ND M.CLSN,^D16 ;DEFAULT NUMBER OF CPU CLASSES FOR SCHEDULER
ND M.CLSS,1 ;DEFAULT SCHEDULER IS CLASS SYSTEM SCHEDULER.
; IF THIS MONGEN SYMBOL IS DEFINED
; TO BE ZERO, THEN THE SCHEDULER WILL
; RUN IN WMU MODE.
ND M.DCLS,0 ;DEFAULT SCHEDULER CLASS FOR NEW JOBS.
; CAN OBTAIN THIS FROM GETTAB OR SCHED UUO
IFG M.DCLS-M.CLSN,<PRINTX VALUE OF M.DCLS EXCEEDS M.CLSN.
M.DCLS==M.CLSN-1>
>;END IFN FTNSCHED
IFE FTNSCHED,<
ND M.CLSN,1
ND M.CLSS,0
ND M.DCLS,0
XP SCHED.,CPOPJ ;NO SCHED. UUO
>;END IFE FTNSCHED
IFN FTKL10,<
IFNDEF TTDMOS,< XP TTDMOS,^D16> ;MAXIMUM OUTPUT STRING
; DEFINES THE NUMBER OF CHARACTERS THAT CAN
; BE SENT TO -20F IN A SINGLE BUFFER
> ;END OF FTKL10
IFNDEF HIGHXC,<XP HIGHXC,^D80> ;HIGHEST EXTENDED CHANNEL
IFG HIGHXC-^D512,<PRINTX HIGHEST EXTENDED CHANNEL IS GREATER THAN 512
PRINTX REDUCING IT TO 512
XP HIGHXC,^D512>
IFNDEF MAXNBP,<XP MAXNBP,^D64> ;MAXIMUM NUMBER OF SNOOP UUO
; BREAK POINTS ALLOWED
IFNDEF M.OMSM,<XP M.OMSM,^D60> ;NUMBER OF MINUTES BETWEEN CALLS
; TO BIGBEN TO TYPEOUT MONITOR NAME,
; UPTIME, AND DATE/TIME
;SET TO <-1>_-1 TO NEVER PRINT
IFNDEF M.DTLS,<XP M.DTLS,^D90> ;CPU TIME LIMIT (SECONDS) TO SET
; ON A FORCED DETACH (.BYE) COMMAND
IFNDEF LIM1MS,<XP LIM1MS,4> ;LIMIT OF STOPCD'S IN ANY 1 MINUTE PERIOD
IFNDEF LIM8MS,<XP LIM8MS,7> ;LIMIT OF STOPCD'S IN ANY 8 MINUTE PERIOD
IFNDEF LIM1HS,<XP LIM1HS,^D30> ;LIMIT OF STOPCD'S IN ANY 1 HOUR PERIOD
;THESE SYMBOLS DEFINE THE VALUES OF VERSION FROM MONGEN
AXXWHO==2
IFNDEF A00CVN,<IFNDEF A00CLH,<AXXWHO=0>>
ND A00CVN,0 ;CUSTOMER VERSION NUMBER (36-BITS)
ND A00MVN,704 ;MAJOR VERSION OF MONITOR--UPDATED AT
; START OF DEVELOPMENT CYCLE (9-BITS)
ND A00SVN,1 ;SOUP NUMBER--UPDATED AT START
; OF EACH SOUP DEVELOPMENT CYCLE (6-BITS)
ND A00MCO,^D14170 ;HIGHEST MCO IN THIS LOAD (26-BITS)
ND A00CLH,0 ;CUSTOMER LH (%CNVER) (18-BITS)
ND A00DLN,23 ;DEC LOAD NUMBER (6-BITS)
; SET TO ZERO FOR ANY RELEASE, ELSE
; 1-7 IF SOUP, 10-77 IF DEVELOPMENT
ND A00WHO,AXXWHO ;DEC LAST EDITED (3-BITS)
AXXVER==< BYTE (18) A00CLH (12) A00MVN-IFE A00SVN,<IFN A00DLN,<1>> (6) IFGE A00DLN*<A00DLN-10>,<A00DLN>>
ND A00VER,AXXVER ;DEFINES %CNVER
AXXDVN== BYTE (3) A00WHO (9) A00MVN (6) A00SVN (18) A00MCO
;DEFINE CNFDAE TO BE THE SIXBIT NAME OF THE MONITOR VERSION
;IN THE LEFT HALF, AND THE BINARY MONITOR VERISON IN THE RIGHT
;HALF. THE SYMBOL BECOMES THE VALUE OF THE %CNDAE GETTAB WHICH
;DAEMON (AND OTHER PROGRAMS) USES TO DETERMINE IF IT IS COMPATIBLE
;WITH THIS MONITOR. IF THE PROGRAM DECIDES IT ISN'T COMPATIBLE
;BY RANGE CHECKING THE RIGHT HALF, IT WILL USE THE LEFT HALF TO
;DETERMINE THE NAME OF THE PROGRAM TO RUN.
DEFINE ..CNFD(VERSION),<XWD SIXBIT \ VERSION\,VERSION>
CNFDAE==..CNFD(\A00MVN)
;DEFINE CTHR TO BE THE CTERM HOST REVISION STRING FOR NRTSER (AND GETTABS).
;THIS STRING IS ALWAYS EIGHT (8-BIT) BYTES IN LENGTH, AND IS OF THE FOLLOWING
;FORM:
;
; 7.03BK42
;
;WHERE THE "7.03" BYTES ARE TAKEN FROM A00MVN, THE "BK" BYTES ARE THE TRANSLATED
;FORM OF A00SVN, AND THE "42" BYTES ARE FROM A00DLN. THE A00SVN AND A00DLN
;FIELDS WILL BE BLANKS IF THEIR VALUES ARE ZERO.
IFN M.DECN,<
CCLEAR (CTHR) ;CLEAR OUT THE STRING ACCUMULATION
CONCAT (CTHR,<BYTE (8) ">) ;START OFF THE STRING
CONCAT (CTHR,\<A00MVN/100>) ;GET FIRST DIGIT
CONCAT (CTHR,<",".",">) ;ADD THE DOT FILLER
CONCAT (CTHR,\<<A00MVN/10>&7>) ;GET THE SECOND DIGIT
CONCAT (CTHR,<",">) ;MOVE TO NEXT BYTE FIELD
CONCAT (CTHR,\<A00MVN&7>) ;GET THE THIRD DIGIT
CONCAT (CTHR,<",">) ;MOVE TO NEXT BYTE
IFN A00SVN,<
IFG A00SVN-^D26,<
CONCAT (CTHR,\"<<A00SVN/^D26>+"A">) ;ADD IN FIRST OF 2-CHAR MINOR VERSION
CONCAT (CTHR,<",">) ;MOVE TO NEXT BYTE
>
CONCAT (CTHR,\"<A00SVN-1-<<A00SVN-1>/^D26>*^D26+"A">) ;ADD MINOR VERSION
IFLE A00SVN,<CONCAT (CTHR,<"," >)> ;PAD IF SHORT MINOR VERSION
CONCAT (CTHR,<",">) ;MOVE TO NEXT BYTE
> ;END OF IFN A00SVN
IFE A00SVN,<CONCAT (CTHR,< "," ",">)> ;PAD WITH SPACES IF NO MINOR VERSION
IFN A00DLN,<
CONCAT (CTHR,\<A00DLN/10>) ;ADD FIRST DIGIT OF LOAD NUMBER
CONCAT (CTHR,<",">) ;MOVE TO NEXT BYTE
CONCAT (CTHR,\<A00DLN&7>) ;ADD LAST DIGIT OF LOAD NUMBER
CONCAT (CTHR,<">) ;CLOSE THE STRING
>
IFE A00DLN,<
CONCAT (CTHR,< "," ">) ;PAD WITH SPACES IF NO LOAD NUMBER
>
;"CTHR" STRING COMPLETE
;DEFINE THE VALUE OF THE HIGH-AVAILABILITY OPTION FOR CTERM AS WELL
IFG M.CPU-1,<XP CTHOPT,1> ;ON IF MULTI-CPU
IFLE M.CPU-1,<XP CTHOPT,0> ;OFF IF SINGLE
> ;END OF IFN M.DECN
;DEFINE THE PFH TIMER TRAP INTERVAL IN TICKS
IFNDEF M.PFHT,<M.PFHT==:^D60>
;DEFINE DEFAULT VALUE OF DEBUGF TO STOP ON STOPCD'S DURING FIELD-TEST,
; BUT NOT TO STOP IN RELEASED VERSIONS OF MONITOR.
IFNDEF DEFDEB,<DEFDEB==0>
; DEFINE DEFAULT CPU MASK FOR EDDT. THIS MASK INDICATES WHICH CPUS
; MAY ENTER EDDT VIA THE UNSOLICITED BREAKPOINT FACILITY.
ZZ==<1+<ZZZ==-1>>
REPEAT M.CPU,<ZZ==<ZZ!<DF.BP0_-<ZZZ==ZZZ+1>>>>
IFNDEF DEFBPT,<DEFBPT==ZZ>
IFNDEF BPTBIT,<XP BPTBIT,0> ;VALUE OF JS.BPT FOR NEW JOBS
;PRIV BITS TO ALLOW CHGPPN TO WORK IF ALREADY LOGGED IN
IFNDEF CHGPPP,<CHGPPP==:0> ;DEFAULT TO ILLEGAL UNLESS LOGGED OUT
;ADD NEW MONGEN SYMBOLS HERE (SEE ALSO COMDEV FOR MONGEN SYMBOLS)
SUBTTL AUTOCONFIGURATION DEFINITIONS
EXTERN AUTCON ;FORCE LOADING AUTOCONFIGURATION CODE
IFNDEF M.GENL,<M.GENL==20> ;NUMBER OF FREE GENTAB ENTRIES FOR
; USE BY AUTCON
IFN M.KL10,<
IFNDEF M.FDVC,<M.FDVC==:034> ;FIRST DEVICE CODE TO SCAN
IFNDEF M.LDVC,<M.LDVC==:574> ;LAST DEVICE CODE TO SCAN
> ;END IFN M.KL10
IFN M.KS10,<
IFNDEF M.FDVC,<M.FDVC==:760000> ;FIRST UNIBUS ADDRESS TO SCAN
IFNDEF M.LDVC,<M.LDVC==:777777> ;LAST UNIBUS ADDRESS TO SCAN
> ;END IFN M.KS10
; CONTEXT SYMBOLS
IFNDEF M.CTX,<M.CTX==:1> ;LOAD CONTEXT SERVICE BY DEFAULT
; CONSTANTS USED TO MANIPULATE CONTEXT AND JOB NUMBERS IN A JOB/CONTEXT
; HANDLE (JCH). THE CONTEXT AND JOB MASKS MUST BE ADJACENT BYTES.
CTXMAX==:777 ;ABSOLUTE MAXIMUM CONTEXTS PER JOB
CTXMSK==:<CTXMAX>B26 ;MASK OF CTX #
JOBMSK==:777B35 ;MASK OF JOB #
JCHMSK==:CTXMSK!JOBMSK ;MASK OF JCH #
CTXWID==<^L<-<<CTXMSK>_<^L<CTXMSK>>>-1>> ;WIDTH OF CTX # MASK
JOBWID==<^L<-<<JOBMSK>_<^L<JOBMSK>>>-1>> ;WIDTH OF JOB # MASK
JCHWID==<^L<-<<JCHMSK>_<^L<JCHMSK>>>-1>> ;WIDTH OF JCH # MASK
CTXPOS==<^L<<CTXMSK>&<-<CTXMSK>>>> ;RIGHT MOST BIT IN CTX # MASK
JOBPOS==<^L<<JOBMSK>&<-<JOBMSK>>>> ;RIGHT MOST BIT IN JOB # MASK
JCHPOS==<^L<<JCHMSK>&<-<JCHMSK>>>> ;RIGHT MOST BIT IN JCH # MASK
CTXLSH==:^D36-CTXPOS-1 ;BITS TO SHIFT CTX # INTO POSITION
JOBLSH==:^D36-JOBPOS-1 ;BITS TO SHIFT JOB # INTO POSITION
JCHLSH==:^D36-JCHPOS-1 ;BITS TO SHIFT JCH # INTO POSITION
CTXPTR==:POINT CTXWID,,CTXPOS ;BYTE POINTER TO CTX # (OR WITH ADDR)
JOBPTR==:POINT JOBWID,,JOBPOS ;BYTE POINTER TO JOB # (OR WITH ADDR)
JCHPTR==:POINT JCHWID,,JCHPOS ;BYTE POINTER TO JCH # (OR WITH ADDR)
CTXCBP==:POINT CTXWID,,35 ;BYTE POINTER TO A CONTEXT QUOTA
CTXPBP==:POINT <^D36-CTXWID>,,<^D35-CTXWID> ;BYTE POINTER TO PAGE QUOTA
CTXBPW==:^D36/CTXWID ;BYTE PER WORD IN DIRECTORY MAP
CTXMAP==:<CTXMAX/CTXBPW>+1 ;SIZE OF A DIRECTORY MAP + TERMINATING NULL
CTXDIR==:POINT CTXWID,,<^D36-<^L<CTXMAX>>-1> ;BYTE POINTER TO A DIRECTORY MAP
IFN M.CTX,<
IFNDEF M.CTXC,<M.CTXC==:^D4> ;DEFAULT CONTEXT QUOTA
IFNDEF M.CTXP,<M.CTXP==:^D1000>;DEFAULT SAVED PAGE QUOTA
IFNDEF M.CTXR,<M.CTXR==:M.JOB/4> ;DEFAULT RESERVED CONTEXT BLOCK COUNT
EXTERN CTXSER ;FORCE LOADING OF CONTEXT SERVICE
> ;END IFN M.CTX
IFE M.CTX,< ;DEFINE DUMMY GLOBALS IF NOT LOADING CTXSER
CTXTAB==:NULGTB## ;GETTAB TABLE
CTXMXL==:0 ;GETTAB TABLE LENGTH
CTXINI==:CPOPJ ;INITIALIZATION AT SYSINI TIME
CTXBLK==:CPOPJ1 ;CONTEXT BLOCK CREATION
CTXPRT==:CPOPJ ;CONTROL-T DISPLAY
CTXLGO==:CPOPJ ;DELETE CONTEXT BLOCKS ON LOGOUT
CTXATO==:CPOPJ ;AUTO-SAVE
CTXSCD==:KCORE1## ;SCHEDULER CALL ON SWAP OUT
CTXPOP==:CPOPJ ;AUTO-RESTORE
CTXRUE==:CPOPJ ;RUN UUO ERROR RECOVERY
CTXUUO==:CPOPJ ;CTX. UUO
CTXMIG==:CPOPJ ;NO IDLE CONTEXTS TO MIGRATE
CTXMGN==:CPOPJ ;NO MORE CONTEXTS TO MIGRATE
CTXWKJ==:WAKEJ## ;LET CLOCK1 EXPIRE SLEEP REQUESTS
$HIGH
CTXJCJ::SKIPA T1,J ;SET TO CONTEXT 0 FOR THIS JOB
CTXNUM::TDZA T1,T1 ;CURRENT CTX IS ZERO
CTXJCH::JUMPLE T1,CPOPJ ;NO SUCH JOB
CAMG T1,HIGHJB ;IN RANGE?
AOS (P) ;YES, RETURN GOODNESS
POPJ P, ;RETURN
CTXPSI::PUSHJ P,CTXVAL ;VALIDITY CHECK
POPJ P, ;NO SUCH JCH
MOVE T1,J ;SET TO CONTEXT 0 FOR THIS JOB
MOVE T2,JBTPIA(J) ;GET PIT FOR JOB
JRST CPOPJ1 ;RETURN
CTXVAL::JUMPLE J,CPOPJ ;NO SUCH JOB
CAMG J,HIGHJB ;IN RANGE?
AOS (P) ;YES, RETURN CURRENT
POPJ P, ;NO, RETURN NONESUCH
CTXIPC::MOVE J,T1 ;SET TO CONTEXT 0 FOR THIS JOB
PUSHJ P,FNDPDB## ;FIND THE PDB
POPJ P, ;NO SUCH JOB
XMOVEI W,.PDIPC(W) ;POINT TO IPCF DATA BLOCK
JRST CPOPJ1 ;RETURN
CTXENQ::MOVE J,T1 ;SET TO CONTEXT 0 FOR THIS JOB
PUSHJ P,FNDPDB## ;FIND THE PDB
POPJ P, ;NO SUCH JOB
MOVE T2,.PDEQJ(W) ;GET ADDR OF QUEUE CHAIN
JRST CPOPJ1 ;RETURN
CTXJPK::PUSHJ P,CTXVAL ;VALIDITY CHECK
POPJ P, ;NO SUCH JCH
MOVE T1,J ;SET TO CONTEXT 0 FOR THIS JOB
MOVE T2,JBTSWP(J) ;GET DISK ADDRESS
JRST CPOPJ1 ;RETURN
CTXSGN::PUSHJ P,CTXJCH ;VALIDITY CHECK
POPJ P, ;NO SUCH JCH
HRRZ T1,JBTSGN(T1) ;GET JBTSGN
JRST CPOPJ1 ;RETURN
CTXWAK::PUSHJ P,WAKJOB## ;WAKE JOB UP
JRST CPOPJ1 ;RETURN
CTXCMD::
PSHCMD::
POPCMD::JSP T1,ERRMES## ;CAN'T DO THESE IF CONTEXT SERVICE NOT LOADED
ASCIZ /Job contexts not supported/
$ABS
> ;END IFE M.CTX
SUBTTL COMPUTE SPECIAL SYMBOLS
SEGN=JOBN+SEGN
IFN M.KL10,<
XP EBCPT,10000 ;KL10 EBOX CLOCK DOES THIS MANY COUNTS PER EBOX TICK
XP MBCPT,10000 ; MBOX CLOCK DOES THIS MANY COUNTS PER MBOX TICK
>;END IFN M.KL10
SUBTTL ABSOLUTE LOCATIONS IN LOWER MEMORY
;DATA STARTING AT 140:
LOC 41
JSR LUUOPC
LOC ARSLOC
HALT .
LOC KAFLOC
HALT .
IFN M.KL10,<
LOC WRSINS
HALT .
>
;SET JOBVER TO SYSTEM VERSION
LOC 136
A00CVN ;(136) CUSTOMER
AXXDVN ;(137) DEC
COMORG=140 ;ORIGIN OF COMMON IS 140
LOC COMORG ;MAKE LISTING BE SAME AS LOADING SO IT WILL BE EASY
; TO EXAMINE SYSTEM LOCATIONS WITH CONSOLE SWITCHES
; WITHOUT NEEDING A STORAGE MAP
SYSDSP=:400 ;FIRST STARTING LOCATION OF MONITOR
;LOWER CORE FROM 140 UP THRU 410 (START LOCATIONS):
ASCIZ /
THIS SOFTWARE IS FURNISHED UNDER LICENSE AND MAY BE USED
OR COPIED ONLY IN ACCORDANCE WITH THE TERMS OF SUCH LICENSE.
COPYRIGHT (c) DIGITAL EQUIPMENT CORPORATION 1969,1988.
ALL RIGHTS RESERVED.
/
SUBTTL EXECUTIVE PROCESS TABLE(S)
DEFINE EPT(N)<
.E'N'EPT:: ;ADDRESS OF EXECUTIVE PROCESS TABLE FOR CPU'N'
.E'N'MP==:.E'N'EPT ;FOR THOSE WHO CAN'T REMEMBER THE NEW NAME
IFN M.KL10,<
LOC .E'N'EPT+.EPLGO
BLOCK 40 ;LOGOUT AREAS FOR INTERNAL CHANNELS
>;END IFN M.KL10
LOC .E'N'EPT+.EPUUO
IOP ;CAUSE AN IOP STOPCD IF A DEVICE INTERRUPTS
; TO 40
JSR LUUOPC ;LUUO HANDLER
LOC .E'N'EPT+.EPPII ;STANDARD PRIORITY INTERRUPT INSTRUCTIONS
ZZ==10*N
REPEAT 7,<
ZZ==ZZ+1
INTINS \ZZ ;NON-VECTORED INTERRUPT LOCATIONS
; (INTINS GENERATES TWO WORDS PER PI CHANNEL)
>; END REPEAT 7
IFN M.KL10,<
LOC .E'N'EPT+.EPCFW ;LOCS USED BY RH20 FOR ZERO-FILL
0
0
0
0
>;END IFN M.KL10
IFN M.KS10,<
LOC .E'N'EPT+.EPVIT ;POINTERS TO UBA INTERRUPT VECTOR TABLES
VC'N'TB1 ;UBA 1
0 ;UBA 2
VC'N'TB3 ;UBA 3
0 ;UBA 4
>;END IFN M.KS10
IFN M.KL10,<
LOC .E'N'EPT+.EPDTM ;SCRATCH BUFFER FOR GET DATE/TIME
.E'N'DTM::BLOCK 3 ;CAN BE ANYWHERE IN EPT
LOC .E'N'EPT+.EPDCB ;START OF DTE0 HARDWARE LOCATIONS
.E'N'DCB::BLOCK ^D8*4 ;8 WORDS FOR EACH OF 4 DTE20S
>;END IFN M.KL10
LOC .E'N'EPT+.EPETL ;EXEC TRAPS
JFCL ;ARITHMETIC TRAP
EXP SEPDLO## ;PUSH DOWN OVERFLOW TRAP
JSR TRP3PC ;TRAP 3 TRAP
IFN M.KS10,<
LOC .E'N'EPT+.EPHSB
.E'N'HSB::BLOCK ^D18 ;HALT STATUS BLOCK AREA
>; END IFN M.KS10
IFN M.KL10,<
LOC .E'N'EPT+.EPDDG ;DTE AREA
.E'N'STD:JRST DEBUG## ;DIAGNOSTIC START
.E'N'DDT:XCT SYSDDT ;DDT START
.E'N'STL:XCT SYSCRH ;LOADER START ADDRESS (BOOTS)
.E'N'STM:XCT SYSDSP ;START MONITOR
LOC .E'N'EPT+.EPDSC ;SECONDARY PROTOCOL DTE CONTROL BLOCK AREA
.E'N'DSC::BLOCK ^D11 ;(MASTER FRONT-END ONLY)
LOC .E'N'EPT+.EPTMB
.E'N'TMB::BLOCK 2 ;TIME BASE WORD
.E'N'PAC::BLOCK 2 ;PERFORMANCE COUNTER WORD
LOC .E'N'EPT+.EPTII
.E'N'TII::XPCW TM'N'INT
>;END IFN M.KL10
LOC .E'N'EPT+.EPSTB
.E'N'STB::
EXP <PM.DCD>B2+PM.WRT+PM.CSH+.E'N'MAP/PAGSIZ
IFN FTXMON,<
EXP <PM.DCD>B2+PM.WRT+PM.CSH+.E'N'MAP/PAGSIZ
EXP <PM.DCD>B2+PM.WRT+PM.SWB+PM.CSH+<.E'N'MP1/PAGSIZ>
BLOCK ^D31-<.-.E'N'STB>
EXP <PM.DCD>B2+PM.WRT+PM.CSH+<.C'N'MMA/PAGSIZ>
>; END IFN FTXMON
IFN M.KL10,<
;GENERATE TABLE OF CONSTANTS USED BY KL10 MICROCODE FOR OWGBP
LOC .E'N'EPT+.EPOWG
.E'N'OWGP:
EXP 440606360607
EXP 300610220611
EXP 140612060613
EXP 000646441015
EXP 341016241017
EXP 141020041055
EXP 440722350723
EXP 260724170725
EXP 100726010762
EXP 441130331131
EXP 221132111133
EXP 001170442235
EXP 222236002275
EXP 000000000000
EXP 464750515253
EXP 626364656600
EXP 555657600000
EXP 707172730000
EXP 757600000000
>;END IFN M.KL10
;SECTION 0/1 MAP
LOC .E'N'EPT+PAGSIZ
.E'N'MAP::
;LOW SEGMENT MAPPING
DEFINE ONE41,<
EXP <PM.DCD>B2+PM.WRT+PM.PUB+<IFE <M.CPU-1>,<ZZCSH>>+ZZ
ZZCSH==PM.CSH
ZZ==ZZ+1
>
ZZ==0
IFN M.KS10,<ZZCSH==0> ;ON KS10, DON'T CACHE PAGE 0
IFE M.KS10,<ZZCSH==PM.CSH> ;OTHERWISE, DO
XLIST
REPEAT CSBORG/PAGSIZ,<ONE41> ;TRADITION HASN'T IT
LIST
;COMMON SUBROUTINES/HIGH SEGMENT MAPPING
DEFINE ONE41,<
EXP <PM.DCD>B2+PM.WRT+PM.PUB+PM.CSH+ZZ
ZZ==ZZ+1
>
LOC .E'N'MAP+CSBORG/PAGSIZ
ZZ==CSBORG/PAGSIZ
XLIST
REPEAT <FYSORG-CSBORG-EVAPGS*PAGSIZ>/PAGSIZ,<ONE41>
LIST
;FUNNY SPACE MAPPING
DEFINE ONE41,<
EXP <PM.ICD>B2+PM.WRT+PM.PUB+PM.CSH+<ZZ+.UMORG>B17+N
ZZ==ZZ+1
>
LOC .E'N'MAP+FYSORG/PAGSIZ
ZZ==0
XLIST
REPEAT PAGSIZ-<FYSORG/PAGSIZ>,<ONE41>
LIST
LOC .E'N'MAP+PAGSIZ ;GET TO END OF THE MAP
;SECTION 2 MAP
IFN FTXMON,<
LOC .E'N'EPT+<2*PAGSIZ>
.E'N'MP1::
DEFINE ONE41,<
EXP <PM.DCD>B2+PM.WRT+<IFE <M.CPU-1>,<PM.CSH>>+ZZ
ZZ==ZZ+1
>
ZZ==MS.HGH/PAGSIZ ;BOOT READ THIS IN 1:1
XLIST
REPEAT CSBORG/PAGSIZ,<ONE41> ;MAKE SECTION MAP 1:1
LIST
DEFINE ONE41,<
EXP <PM.ICD>B2+PM.WRT+PM.PUB+PM.CSH+PM.SWB+<ZZ+.UMORG>B17+N
ZZ==ZZ+1
>
LOC .E'N'MP1+FYSORG/PAGSIZ
ZZ==0
XLIST
REPEAT PAGSIZ-<FYSORG/PAGSIZ>,<ONE41>
LIST
LOC .E'N'MP1+PAGSIZ
>; END IFN FTXMON
>;END DEFINE EPT
DEFINE INTINS(X)<
XPCW CH'X ;DISPATCH TO START OF CONSO SKIP CHAIN
IFN M.KL10,<IOP> ;CAUSE AN IOP STOPCODE IF BLKO INTERRUPT
IFN M.KS10,<JSR PIERR##> ;SHOULDN'T GET A BLKO ON THE KS
>; END DEFINE INTINS
;NOW GENERATE EPT'S
IFN M.KL10,<
LOC 1000 ;START AT PAGE 1 (RESERVE PAGE 0 FOR IOWD SPACE)
>
IFN M.KS10,<
LOC 2000 ;START AT PAGE 2 (FE USES PAGE 1 FOR SOFT CRAM
; PARITY ERROR RECOVERY)
>
IFN XPANDN,<LALL>
ZZ1==0
REPEAT M.CPU,<
EPT(\ZZ1)
ZZ1==ZZ1+1
>; END REPEAT M.CPU
IFE M.CPU-1,<
EPTDIF==:0
>
IFG M.CPU-1,<
EPTDIF==:.E1MAP-.E0MAP
>
LOC 777000&<.+PG.BDY> ;ROUND UP TO NEXT PAGE BOUNDARY
NLUPMP:: ;NULL JOB USER PROCESS TABLE/PAGE MAP GOES HERE
SUBTTL INITIALIZATION DISPATCH TABLE, STARTING AT LOCATION 400
LOC SYSDSP ;ORIGIN START LOCATIONS TO 400
SYSDSP::XJRST [MCSEC0+SYSTRT] ;(400) INITIALIZE SYSTEM VARIABLES IF CPU0
SYSDDT::XJRST [MCSEC0+ENTDDT] ;(401) ENTER EXEC DDT
HALT . ;(402)
HALT . ;(403)
XJRST [MCSEC0+STPALL] ;(404) SET CRSHWD TO -1 AND DO A 406
; START TO STOP ALL OTHER CPU'S AND
; GET TO BOOTS. MOSTLY FOR DEBUGGING.
XJRST [MCSEC0+STPCPU] ;(405) STARTING THE BOOT CPU AT 405 IS THE SAME
; AS A 407 START. ON ALL OTHER CPUS, A 405
; START WILL CAUSE THE CPU TO SAVE THE
; MACHINE STATE AND JUMP INTO THE AC'S UNTIL
; MANUALLY RESTARTED THROUGH 400.
XJRST [MCSEC0+STPLDB] ;(406) SET SR.LBH IN .CPSBR AND DO A 407
; START TO FORCE BOOTS TO BE LOADED ON
; THIS CPU REGARDLESS OF WHO IS THE BOOT
; CPU NOW
SYSCRH::XJRST [MCSEC0+SYSTOP] ;(407) MONITOR CRASH AND RELOAD LOCATION
;START ABSOLUTE LOCATIONS HER TO BE PUBLISHED FOR USERS( UP TO 417)
ABSTAB::EXP NUMTAB## ;(410) ABSOLUTE LOCATION OF GETAB TABLE TABLE.
; USED TO BE LOC 151. NEEDED TO DO GETTAB UUO
; SIMULATION ON A CRASHED MONITOR.
MBTCOM::EXP 0 ;(411) ABSOLUTE LOCATION USED FOR MONBTS COMMUNICATION
;(417) CUSTOMER WORD
LOC 420 ;SKIP RESERVED SPACE
SUBTTL (NULL JOB AND) USER PROCESS TABLE(S)
;REDEFINE ONE41 FOR GENERATION OF THE NULL JOB'S MAP
DEFINE ONE41,<
EXP <PM.DCD>B2+PM.WRT+PM.PUB+ZZ
ZZ==ZZ+1
>
NUPMPP==:NLUPMP/PAGSIZ ;NULL JOB'S UPT PAGE NUMBER
LOC NLUPMP+0
LOC NLUPMP+.UMORG
NUPPPM:: ;PER-PROCESS MAPPING
ZZ==FYSORG/PAGSIZ
XLIST
REPEAT <.UPMAP/PAGSIZ>-<FYSORG/PAGSIZ>,<ONE41>
LIST
LOC NLUPMP+.UPTVC
NUPPMT:: ;USER TRAPS
EXP 0 ;(420) PAGE FAIL WORD (USER OR EXEC)
JFCL SAROVF## ;(421) ARITHMETIC TRAP
EXP SEPDLO## ;(422) PUSH DOWN LIST OVERFLOW TRAP
JFCL ;(423) TRAP 3 TRAP
EXP 0 ;(424) MUUO STORED HERE
EXP 0 ;(425) MUUO PC STORED HERE
EXP 0 ;(426) PROCESS CONTEXT WORD
IFE FTXMON,<
EXP 0 ;(427) UNUSED
>; END IFE FTXMON
IFN FTXMON,<
EXP LG.LAB+LG.LPC+1B8+1B11 ;(427) LOAD AC BLOCKS AND SET PCS
; TO DO A USERAC AND LOAD PCS=0 FOR NULL JOB
>; END IFN FTXMON
EXP MUUO ;(430) KERNEL NO TRAP MUUO NEW PC
EXP KTUUO ;(431) KERNEL TRAP MUUO NEW PC
EXP SNTUUO ;(432) SUPERVISOR NO TRAP MUUO NEW PC
EXP STUUO ;(433) SUPERVISOR TRAP MUUO NEW PC
EXP MUUO ;(434) CONCEALED NO TRAP MUUO NEW PC
EXP CTUUO ;(435) CONCEALED TRAP MUUO NEW PC
EXP MUUO ;(436) PUBLIC NO TRAP MUUO NEW PC
EXP PTUUO ;(437) PUBLIC TRAP MUUO NEW PC
LOC NLUPMP+.UPPFW ;GET TO PAGE FAIL WORD
EXP 0 ;(500) PAGE FAIL WORD
EXP 0 ;(501) PAGE FAIL OLD FLAGS/PC DOUBLEWORD
EXP 0 ;(502) ...
EXP SEILM## ;(503) PAGE FAIL NEW PC
NUPMPL==:.-NLUPMP
;HARDWARE LOCATIONS
;504 - 507 EBOX/MBOX METERS
;510 - 537 RESERVED
LOC NLUPMP+SECTAB
NULSTB:: ;SECTION TABLE ORIGIN
EXP <PM.DCD>B2+PM.PUB+PM.WRT+NLUPMP/PAGSIZ
BLOCK ^D31 ;RESERVE THE REST
;SOFTWARE LOCATIONS
.USPAT=:.USPAT ;FORCE DEFINITION FROM S
NULASW==:NLUPMP+PAGSIZ ;FIRST LOC AVAIL TO SOFTWARE
LOC NULASW
SUBTTL EXECUTIVE UUO DISPATCHERS
$HIGH
KTUUO: JRST @.USMUE ;E FIELD OF THE MUUO IS TRAP HANDLER ADDRESS
; N.B., USRIOT ISN'T ON
SNTUUO: HALT . ;NOT IMPLEMENTED
STUUO: HALT . ;NOT IMPLEMENTED
CTUUO:
PTUUO:
EXECAC
HRLZ T1,.USMUO
IOR T1,.USMUE
JUMPL T1,ILLTIN##
CAILE T1,UP.MLT
JRST ILLTIN##
JRSTF @UUTDSP(T1)
UUTDSP: IC.UOU+SEILM## ;PAGE FAULT
IC.UOU+ILLTIN## ;NOT IMPLEMENTED
IC.UOU+SEPDLO## ;PUSH DOWN LIST OVERFLOW
IC.UOU+ILLTIN## ;TRAP 3
IC.UOU+SUILMX## ;USER ENABLED PAGE FAULT
IC.UOU+SAROVF## ;USER ENABLED ARITHMETIC OVERFLOW
IC.UOU+SUPDLO## ;USER ENABLED PDL OVERFLOW
IC.UOU+ILLTIN## ;NOT IMPLEMENTED
IC.UOU+ILLTIN## ;NOT IMPLEMENTED
IC.UOU+PSIAPR ;PSI ENABLED ARITHMETIC OVERFLOW
$ABS
LUUOPC::0 ;JSR HERE ON A LUUO IN EXEC MODE
EXCH T1,LUUOPC
MOVEM T1,.USMUP
JRST UUOERR##
TRP3PC: 0 ;JSR HERE ON A TRAP 3 IN EXEC MODE
HALT .
SUBTTL SOME DEFINITIONS FOR KL10'S
IFN M.KL10,<
KLRELC==.
LOC 420
IFN ./2*2-.,<0> ;MAKE SURE THEY START ON EVEN LOCATION
FREORG: BLOCK 1000-. ;ICCW BLOCKS
FRE4LN==<.-FREORG>/4 ;NUMBER OF 4-WORD BLOCKS
LOC KLRELC
>;END IFN M.KL10
SUBTTL KS10 UBA INTERRUPT VECTOR TABLES
IFN M.KS10,<
;TABLES FOR DISPATCHING 11-STYLE VECTORED INTERRUPTS FROM THE
;KS10'S UNIBUS ADAPTORS. INITIALLY SET TO ZEROS.
;APPROPRIATE LOCATIONS WILL BE SET UP BY THE DEVICE SERVICE ROUTINES.
;MACRO TO GENERATE THE INTERRUPT VECTOR TABLES
DEFINE GENVCT(N),<
VC'N'TB1:: ;UBA 1 VECTOR TABLE
XLIST
REPEAT ^D128,<0>
LIST
VC'N'TB3:: ;UBA 3 VECTOR TABLE
XLIST
REPEAT ^D128,<0>
LIST
>; END DEFINE GENVCT
;NOW GENERATE THE TABLES (ONE PER CPU (HA!))
N==0 ;START WITH CPU0
REPEAT M.CPU,< ;ONCE PER CPU
GENVCT (\N)
N==N+1 ;NEXT CPU
>; END REPEAT M.CPU
>;END IFN M.KS10
SUBTTL VIRTUAL MEMORY DATA
EVTABL==^D512/^D36+1
EVMPTR::XWD -EVTABL,EVBTAB
EVBMAX::0 ;FILLED IN BY SYSINI
EVBTAB::BLOCK EVTABL
PAGPTR::0
PAGINQ::0 ;HEAD OF THE "IN" PAGE QUEUE
PAGINC::0 ;COUNT OF THE NUMBER OF PAGES IN THE "IN" QUEUE
PAGSNQ::0 ;HEAD OF THE SLOW SWAPPING "IN" PAGE QUEUE
PAGSNC::0 ;COUNT OF THE NUMBER OF PAGES IN THE SLOW SWAPPING
; "IN" QUEUE
PAGIPQ::0 ;HEAD OF THE "IN PROGRESS" PAGING QUEUE
PAGIPC::0 ;COUNT OF THE NUMBER OF PAGES IN "IP" QUEUE
PAGOUQ::0 ;HEAD OF THE "OUT" PAGE QUEUE
PAGOUC::0 ;COUNT OF THE NUMBER OF PAGES IN THE "OUT" QUEUE
LOKPTR::0 ;HEAD OF LOKCON'S QUEUE
LOKHOL::0 ;COUNT OF PAGES IN LOKCON'S QUEUE
LOKTAL::0 ;LOKCON'S VERSION OF CORTAL
ALPHA==1 ;FRACTIONAL PART OF TIME CONSTANT
EXPON==^D10 ;NEGATIVE EXPONENT OF TIME CONSTANT
.GTVM::
SWPCNT::0 ;(0)
SCNCNT::-1 ;(1)
SPRCNT::0 ;(2) COUNT OF SWAPS + PAGE OPERATIONS IN PROGRESS
; (SQREQ IS ONLY SWAPS)
SLECNT::0 ;(3) TOTAL NUMBER OF SWPLST ENTRIES
VMTOTL::0 ;(4) TOTAL AMOUNT OF VM CURRENTLY IN USE
VMCMAX::0 ;(5) MAX ALLOWABLE VALUE OF VMTOTL
VMRMAX::1 ;(6) OBSOLETE
VMCNST::ALPHA ;(7) CONSTANT USED TO COMPUTE SWAPPING RATE
VMQJOB::0 ;(10) OBSOLETE
JBRMAX::RTUPS/^D10 ;(11) OBSOLETE
LSFTIM::0 ;(12) TIME OF LAST FAULT
SYSVCT::0 ;(13) TOTAL NUMBER OF PAGE FAULTS (OBSOLETE)
EXP SWPLST ;(14) LCTN OF SWAP TABLE #1
EXP SW2LST ;(15) LCTN OF SWAP TABLE #2
EXP SW3LST ;(16) LCTN OF SWAP TABLE #3
VMCEXP::EXPON ;(17) TIME CONSTANT EXPONENT
VMCDIF::EXPON-ALPHA ;(20)
MAXINT::777777 ;(21) MAX INTERVAL FOR FAULT-RATE CALCULATION (ABOUT 8 SEC. BETWEEN FAULTS)
IPCCNT::0 ;(22) COUNT OF IPCF PAGES BEING SWAPPED OUT
EXP .UPJOB ;(23) OFFSET OF JOB NUMBER IN UPMP
EXP .UPREL ;(24) OFFSET OF END OF LOW SEG IN UPMP
EXP .UPLST ;(25) OFFSET OF POINTER TO SWAPABLE
EXP .UPMP ;(26) VIRTUAL ADDRESS OF PAGE MAP
EXP .UPLNM ;(27) OFFSET OF POINTER TO LOGICAL NAMES
SINCNT::0 ;(30) NUMBER OF SWAP INPUT REQUESTS IN SWPLST
EXP CSBORG-1 ;(31) HIGHEST "UNMAPPED" EXEC ADDRESS
EXP .FPPP ;(32) START OF "PER PROCESS" ADDRESS SPACE
EXP .LPPP ;(33) END (+1) OF "PER PROCESS" ADDRESS SPACE
EXP .JDAT ;(34) "PER PROCESS" ADDRESS OF USER JOBDAT
EXP .UPFCC ;(35) OFFSET IN UPMP FOR TMPCOR POINTERS
EXP .UPCTA ;(36) OFFSET IN UPMP FOR EXTENDED CHANNEL TABLE POINTER
EXP USRJDA ;(37) OFFSET IN UPMP FOR USRJDA
RMCMAX::0 ;(40) "REAL" MAXIMUM VALUE OF CORMAX
;(ADJUSTED FOR FUNNY SPACE)
SYSWLF::0 ;(41) SYSTEM WIDE COUNT OF PAGE FAULTS DUE TO
; WRITES INTO WRITE LOCKED PAGES (TO KEEP TRACK
; OF MODIFIED PAGES - NOT UWPOFF PAGES)
SYSIWS::0 ;(42) SYSTEM "IN WORKING SET" FAULTS
SYSNIW::0 ;(43) SYSTEM "NOT IN WORKING SET" FAULTS
GTVMXL==:<.-.GTVM-1>B26 ;MAXIMUM ENTRY IN GETTAB
SUBTTL IOWD SPACE ALLOCATION
IFN M.KL10,<
NPAGUC==^D512
IFL <2*M.NKC-^D512>,<NPAGUC==2*M.NKC>
IFNDEF XTR4WD,<XTR4WD==<<NPAGUC+3>/4-<FRE4LN>>>
LTINIT::
IFG FRE4LN,<XWD FRE4LN,FREORG>
IFG XTR4WD,<XWD XTR4WD,X4WORG>
0 ;END OF LTINIT XWD'S
XP X4WORG,<<.-1>/4*4+4>
LOC X4WORG
IFG XTR4WD,<BLOCK 4*XTR4WD>
IOWNUM==.-FREORG
NOIOWD::EXP FRE4LN+XTR4WD ;NUMBER OF FREE IOWD BLOCKS
DF10ZR::EXP 0 ;GUARANTEED ZERO FOR TERMINATING DF10C CCLS
>;END IFN M.KL10
XP CHKSHF,CPOPJ
XP UPMPSZ,1
XP UPMSZW,PAGSIZ*UPMPSZ
SUBTTL COMMON MEMORY FOR KDP (KMC-11/COM-IOP/DUP-11) & DMR11
;NOTE: TO AVOID WASTING SPACE THE VALUE OF "XTR4WD" ON
; THE LAST PAGE CAN BE ADJUSTED.
;NOTE: KDL PAGES ARE BOTH AS BUFFERS AND COMM REGIONS. SINCE THEY
; ARE MAPPED BY THE UBA, IT IS ASSUMED THAT THEY CAN BE TRASHED
; BY AN ERRANT UNIBUS DEVICE. FOR THIS REASON, THEY ARE NOT STATICALY
; INITIALIZED. INSTEAD, THERE IS CODE IN THE KDP UUO SERVICE
; TO CLEAR OUT AND INITIALIZE A KDL PAGE.
IFNDEF M.KDUP,<M.KDUP==0> ;MAKE SURE M.KDUP IS DEFINED
IFNDEF M.DMRN,<M.DMRN==0> ;Do the same for DMRs
IFE M.KDUP+M.DMRN,< ;IF NO KMC/DUP-11S THEN
KDLFST==:0 ; DEFINE THESE TWO SYMBOLS
KDLLST==:0 ; TO KEEP SYSINI HAPPY
>
IFN M.KDUP+M.DMRN,< ;ONLY ALLOCATE PAGES IF WE HAVE KDP'S or DMRs
BLOCK <PAGSIZ-<.&PG.BDY>> ;GO TO A PAGE BOUNDARY
KDLFST=:. ;DEFINE SYMBOL = TO FIRST LOC OF FIRST PAGE
BLOCK KDLLEN * M.KDUP ;ALLOCATE SPACE FOR THE I/O BUFFERS
BLOCK PAGSIZ * M.DMRN * DMRPPL ;Allocate space for DMR11 comm region
KDLLST=:.-1 ;REMEMBER LAST ADDRESS USED.
> ;END M.KDUP
DEFINE KDLDEF(N,V),< ;;MACRO TO DEFINE KDL'N'PG SYMBOLS
KDL'N'PG=:KDLFST+V
ZZZ==.
LOC KDL'N'PG+KDLUSR
EXP M.'N'KDP
LOC ZZZ
>
ZZ=0
Z=0
REPEAT M.KDUP,<
KDLDEF(\Z,\ZZ) ;DEFINE THE NEXT SYMBOL
Z=Z+1 ;STEP THE KDL INDEX
ZZ=ZZ+KDLLEN ;STEP THE PAGE ADDRESS
>;END REPEAT
;Do DMRs too
DEFINE DMRDEF(N,V),< ;;MACRO TO DEFINE DMR'N'PG SYMBOLS
DMR'N'PG=:KDLFST+V>
Z=0
REPEAT M.DMRN,<
DMRDEF(\Z,\ZZ)
Z=Z+1
ZZ=ZZ+<DMRPPL*1K>
>;End REPEAT (Note the DMRs start after KDPs)
SUBTTL COMMON MEMORY FOR PDP10/PDP11
;NOTE: TO AVOID WASTING SPACE BEFORE THE FIRST DL10 WINDOW
; THE VALUE OF "XTR4WD" ON THE LAST PAGE CAN BE ADJUSTED.
IFN PDP11N,<
;;THIS MACRO BUILDS THE DL10 MAP FOR A GIVEN PORT.
DEFINE BLDM76(CPU,PORT),<
;;COMPUTE THE SIZE OF THE MAP
DEFINE WORD(A,B),<A==ZZ ;;DEFINE THE OFFSET
XP DLX'A,ZZ ;DEFINE GLOBAL SYMBOL
ZZ==ZZ+1>
DEFINE DATA(A,B),<A==ZZ ;;DEFINE THE OFFSET
XP DLX'A,ZZ ;DEFINE GLOBAL SYMBOL
ZZ==ZZ+1>
DEFINE PNTR(A,B),<A==ZZ ;;DEFINE THE OFFSET
XP DLX'A,ZZ ;DEFINE GLOBAL SYMBOL
ZZ==ZZ+1>
DEFINE BLK(A,B),<
XP DLX'A,ZZ ;DEFINE GLOBAL SYMBOL
ZZ==ZZ+B>
;;SIZE OF TO -10 AND TO -11 QUEUES
TTBS'PORT==:<<M.D7'PORT'N!7>+1>*2
TEBS'PORT==:<<M.D7'PORT'N*2>!17>+21
;;EXPAND MAP76 TO SEE HOW BIG IT IS
ZZ==0
MAP76(CPU,PORT)
REPEAT ^D18,<ZZ==ZZ!<ZZ_<-1>>>
ZZ==ZZ!<<DLX8K*777>!77> ;MUST BE BIG ENOUGH
IFN M.DC75,<ZZ=ZZ!177> ;MIN OF 128 WORDS IF MAY BE DC75
LOC <<.-1>!ZZ>+1 ;LOC TO BEGINNING OF WINDOW
ZZ==ZZ_<-<6+<3*DLX8K>>> ;SIZE OF BLOCK
M7'PORT'END==<<<<ZZ+1>_<DLX8K*3>>*^D64>+.-1>
IFN ZZ&777760 <PRINTX ?DL10 MAPPED AREA IS TOO LARGE.>
XP M7'PORT'BAM,ZZ ;DL10 WINDOW MASK
ZZ=ZZ*4 ;SHIFT TO PROPER PLACE
ZZ=ZZ+<PORT&3> ;MASK OUT OVEERFLOW IN PORT
;;NOW LAY OUT THE MAP FOR REAL
DEFINE WORD(SYM),<
M7'PORT''SYM:: 0
>
DEFINE DATA(SYM,THING),<
IF2,< IFNDEF THING,<EXTERNAL THING>>
M7'PORT''SYM:: THING
>
DEFINE PNTR(SYM,PLACE),<
IF2,< IFNDEF PLACE,<EXTERNAL PLACE>>
M7'PORT''SYM:: <61B5>+PLACE
>
DEFINE BLK(SYM,SIZE),<
M7'PORT''SYM:: BLOCK SIZE
>
IFNDEF DLXFST,<DLXFST==:.> ;START OF DL10 UNCACHED SPACE
.DL'CPU'PORT'B:: ;;FIRST ADDRESS IN COMMON MEMORY
MAP76(CPU,PORT)
> ;END DEFINITION OF BLDM76
IFN XPANDN,<LALL> ;EXPAND LISTING IF WANTED FROM MONGEN
ZZD78L==0 ;LINE NUMBER CONCATENATOR
;THIS MACRO USES THE "MAP78" MACRO TO ACTUALLY BUILD THE
;THE WINDOW. IT CALLS "MAP78" TO FIRST CALCULATE THE WINDOW
;SIZE AND THEN IT CALLS "MAP78" AGAIN TO ACTUALLY BUILD THE
;THE DAS78 WINDOW.
;
DEFINE BLD78 (CPU,PORT),<
IFN <M'CPU'PORT'D78>,< ;ONLY BUILD IF THERE IS LINES ON PORT
;THESE MACRO'S ARE USED FOR COMPUTING THE SIZE OF THE MAP
;
DEFINE Q78BLK(A),<
ZZD78A==ZZD78A+A>
;
DEFINE Q78WRD(A),<
ZZD78A==ZZD78A+1>
;
DEFINE Q78DAT(A,B),<
ZZD78A==ZZD78A+1>
;
DEFINE Q78SYM(A,B),<
;A>
DEFINE Q78INC(A,B),<
;A==A+B>
;END OF MACRO'S THAT DETERMINE MAP SIZE
ZZD78A==0 ;START WITH 0
IFNDEF M78FPO,<M78FPO==:PORT> ;FIRST PORT INUSE BY DAS78.
M78HPO==:PORT ;FIGURE HIGHEST DAS78 PORT.
;CALL MAP78 TO CALCULATE WINDOW SIZE
;
MAP78 (CPU,PORT)
ZZD78A==<ZZD78A-1> ;ADJUST TO LAST USED LOCATION
REPEAT ^D18,<ZZD78A==ZZD78A!<ZZD78A_<-1>>>
ZZD78A==<ZZD78A!<<M78M8K*777>!77>> ;MAKE BIGGER IF 8K DL10
IFN <.&ZZD78A>,<
LOC <.!ZZD78A>+1
>;END IFN <.&ZZD78A>
ZZD78A==<ZZD78A_<-<6+<3*M78M8K>>>> ;SIZE OF BLOCK
M8'PORT'END==<<<<ZZD78A+1>_<M78M8K*3>>*^D64>+.-1>
IFN <ZZD78A&777760>,<PRINTX ?DAS78 DL10 MAPPED AREA TOO LARGE.>
M8'PORT'BAM==<ZZD78A*4> ;SHIFT TO CORRECT PLACE FOR BASE ADR MASK
DEFINE Q78BLK(A),<
BLOCK A>
DEFINE Q78WRD(A),<
A::!Z>
DEFINE Q78DAT(A,B),<
A::!B>
DEFINE Q78SYM(A,B),<
A'B::>
DEFINE Q78INC(A,B),<
A==A+B>
;CALL MAP78 NOW TO ACTUALLY BUILD THE WINDOW
;
.DL'CPU'PORT'B::
MAP78 (CPU,PORT)
M78NUM==:<-<M78HPO-M78FPO+1>> ;MINUS NUMBER OF POSSIBLE PDP11'S
LOC <M8'PORT'END>+1
>;END OF IFN M'CPU'PORT'D78
>;END OF DEFINITION OF BLD78
; CALCULATE WINDOW SIZE AND BUILD THE PDP11 WINDOW
;
DEFINE MAPIT (P),<
IFN TP.DL'P,<
IFE M0'P'D78,<BLDM76(0,P)>
IFN M0'P'D78,<BLD78(0,P)>
> ;;END IFN TP.DL'P
> ;END MAPIT
ZZZ=0 ;FIRST PORT
REPEAT 10,<
IFLE <ZZZ-3>,<
IFNDEF DLX08K,<DLX08K==0 ;;ASSUME JUMPERED FOR 1K MAXIMAL>
IFN DLX08K,<DLX08K==1 ;;FORCE TO 1 IF NOT ZERO>
DLX8K==DLX08K ;;USED BY BLDM76
M78M8K==DLX08K ;;USED BY BLD78
>
IFG <ZZZ-3>,<
IFNDEF DLX18K,<DLX18K==0 ;;ASSUME JUMPERED FOR 1K MAXIMAL>
IFN DLX18K,<DLX18K==1 ;;FORCE TO 1 IF NOT ZERO>
DLX8K==DLX18K ;;USED BY BLDM76
M78M8K==DLX18K ;;USED BY BLD78
>
MAPIT(\ZZZ) ;GET THE RIGHT MAP OR NOTHING
ZZZ=ZZZ+1
>
SUBTTL DL10 INTERRUPT HANDLING
;INTERRUPT ROUTINE FOR EACH DL10 BASED DAS78
DEFINE EACH78(PORTN),<
IFN M0'PORTN'D78,<
IFLE PORTN-3,<DLBD78=60
DLCD78=64> ;FIRST DL10
IFG PORTN-3,<DLBD78=160
DLCD78=164> ;SECOND DL10
$ABS
D80'PORTN'KI: ;DL10 FORCES JSR HERE
EXP 0,0,IC.UOU,<D80'PORTN'IN>
$HIGH
DEFINE D8.CH(A,B),<IF2,<A'B>>
IFNDEF DLXSCC,<DLXSCC:>
D80'PORTN'KA:
CONSO DLCD78,1B<32-<3*<PORTN&3>>> ;IS THIS PDP11 INTERRUPTING?
JRST DLX'PORTN'NX ;TRY THE NEXT ONE
CONSO DLCD78,1B31_<<PORTN&3>*3> ;PORT PORTN ENABLED?
JRST .-2 ;NO, IGNORE.
JRST D80'PORTN'CM ;ENTER COMMON CODE
D80'PORTN'IN:
CONO DLCD78,1B19+1B<32-<3*<PORTN&3>>>+XXICHN ;TURN OFF INTERRUPT
DMOVEM 0,D8.CH(SVAC,\XXICHN) ;SAVE ACS 0 AND 1
DMOVE 0,D80'PORTN'KI ;GET INPTERRUPT PC DOUBLE WORD
DMOVEM 0,D8.CH(CH,\XXICHN) ;STORE SO WE CAN USE CHN SAVE ROUTINES
DMOVE 0,D8.CH(SVAC,\XXICHN) ;RESTORE ACS 0 AND 1
D80'PORTN'CM:
CONO DLCD78,1B19+1B<32-<3*<PORTN&3>>>+XXICHN ;TURN OFF INTERRUPT
JSR D8.CH(SAV,\XXICHN) ;SAVE THE ACS AND SET UP P
SKIPE J,M78BT+PORTN ;J TO POINT TO WINDOW FOR PORT PORTN
PUSHJ P,D78KII## ;GO TO DAS78 INTERRUPT SERVICE ROUTINE
POPJ P, ;DISMISS INTERRUPT
;BASE TABLE FOR DAS78 DL10
;
M80'PORTN'BT:
PHASE 0
M78CPE::!CONO DLCD78,XXICHN+<1B31_<<PORTN&3>*3>> ;CLEAR PORT ENABLE FOR PORT PORTN
M78I10::!CONSO DLCD78,1B32_<<PORTN&3>*3> ;SEE IF PDP11 PORTN SET 10 INT
M78I11::!CONO DLCD78,1B19+1B20+XXICHN+<1B30_<<PORTN&3>*3>> ;SET PDP11 INTERRUPT ON PORTN
M78SWA::!CONO DLBD78,M8'PORTN'KII!M8'PORTN'BAM!<PORTN&3> ;LOAD ADDRESS FOR PORT PORTN
M78ENP::!CONO DLCD78,1B20+XXICHN+<1B31_<<PORTN&3>*3>> ;ENABLE PORT PORTN
M78CPI::!CONSO DLCD78,7 ;SEE IF PIA ASSIGNED
M78SPI::!CONO DLCD78,XXICHN ;GIVE PI CHN ASSIGNMENT
M78PNO::!PORTN,,.DL0'PORTN'B ;;PORT##,,WINDOW
IFN M.PSI,<
M78PSI::!DATAO DLCD78,[200001,,0] ;KA STYLE INTERRUPTS
> ; SO PSISER CAN FIND THE PC
IFE M.PSI,<
M78PSI::!JFCL
>
M78SER::!DATAO DLBD78,[<PORTN&3>_^D<35-5>] ;PUT PORT NUMBER IN THE "R" REGISTER
M78GWA::!CONI DLBD78,T1 ;GET BASE ADDRESS
DEPHASE
DLX'PORTN'NX::
$ABS
>;END IFN M0'PORTN'D78
>;END DEFINE EACH78
;INTERRUPT ROUTINE FOR EACH DL10 BASED ANF10 PDP11
DEFINE EACH76(N)<
IFN TP.DL'N,< ;IF PORT DEFINED
IFE M0'N'D78,< ;AND NOT A DAS78
IFLE N-3,<DLX=DLC
DLBX=DLB> ;FIRST DL10
IFG N-3,<DLX=DLC2
DLBX=DLB2> ;SECOND DL10
$ABS
D70'N'KI:Z ;DL10 FORCES JSR TO HERE
Z
IC.UOU
D70'N'IN
$HIGH
DEFINE D7.CH(A,B),<IF2,<A'B>>
IFNDEF DLXSCC,<DLXSCC==.> ;DEFINE START OF KA SYTLE DL10 CONSO CHAIN
D70'N'KA:CONSZ DLX,1B32_<<N&3>*3> ;IS THIS -11 INTERRUPTING
CONSO DLX,1B31_<<N&3>*3> ;YES, PORT ENABLED ?
JRST DLX'N'NX ;NO, TRY THE NEXT -11
JRST D70'N'CM ;JOIN COMMON CODE WITH VECTORED STYLE
D70'N'IN:
DMOVEM 0,D7.CH(SVAC,\SCNCHN)
DMOVE 0,D70'N'KI
DMOVEM 0,D7.CH(CH,\SCNCHN)
DMOVE 0,D7.CH(SVAC,\SCNCHN)
D70'N'CM:CONO DLX,1B19+<1B32_<<N&3>*3>>+SCNCHN ;TURN OFF INTERRUPT
JSR D7.CH(SAV,\SCNCHN) ;SAVE AC'S AND STUFF
SKIPE W,DLXBAT+N ;SET UP BASE ADDRESS
XCT DLXINI(W) ;TAKE ACTION FOR THIS INTERRUPT
POPJ P, ;DISMISS INTERRUPT
IFE TP.DL'N-TP.D76,< ;THIS IS A DC76 PORT
DC76'N'D::JRST [PUSHJ P,SETJ'N ;SET UP J AS BASE ADDRESS
PJRST D76TYP##];CALL TYPEOUT ROUTINE
JRST [PUSHJ P,SETJ'N
PJRST D76DSC##];MODEM CONTROL
POPJ P, ;NO PI CHANNEL TO CHECK ON
POPJ P,0 ;NO INIT
JRST [PUSHJ P,SETJ'N
PJRST D76CHP##];CHANGE HARDWARE PARAMETERS
JRST [PUSHJ P,SETJ'N
PJRST D76LPC##];LINE PARAMETER CONTROL
JFCL
JFCL
JRST [PUSHJ P,SETJ'N
PJRST D76OFL##]
SETJ'N: EXCH J,(P) ;SAVE J
MOVEM J,1(P) ;SAVE RETURN ADDRESS
MOVE J,DLXBAT+N ;POINT TO BASE OF MAP
MOVE J,DLXWIN(J) ; ..
PUSHJ P,@1(P) ;DO FUNCTION
PJRST IPOPJ ;RETURN
PJRST IPOPJ1 ;ALLOW CPOPJ1
> ;END OF IFE TP.DL'N-TP.D76
DLX'N'NX:
> ;END IFE M0'N'D78
> ;IFN TP.DL'N
> ;END OF DEFINITION OF EACH76
> ;END IFN PDP11N
; PDP11 BASE TABLE OFFSETS
PHASE 0 ;START BASE TABLE
DLXWIN::! BLOCK 1 ;STANDARD XWD CPU#,DTE#
DLXNMT::! BLOCK 1 ;FRONT END NAME
DLXSTA::! BLOCK 1 ;DTE KNOW'S WHEN THE -10'S ALIVE
DLXINI::! BLOCK 1 ;DO THIS ON INTERRUPT
DLXCAL::! BLOCK 1 ;POINTER TO CAL11. UUO TABLE
DLXCEU::! BLOCK 1 ;CAL11. USER'S JOB NUMBER
DLXPRG::! BLOCK 1 ;DO THIS WHEN PDP11 GOES DOWN
DLXTYP::! BLOCK 1 ;TYPE OF PDP11 (FOR CALL11)
DLXTIM::! BLOCK 1 ;CONTAINS UPTIME OF TIMEOUT, OR 0
DLXPRE::! BLOCK 1 ;
DLXCEV::! BLOCK 1 ;CAL11. UUO ENTRY VECTOR
DLXFEK::! BLOCK 1 ;ADDRESS OF ASSOCIATED FEK
DLXLEN::! ;LENGTH OF COMMON BASE TABLE AREA
DEPHASE
IFN FTKL10,< ;DL10 SPECIFIC BASE TABLE OFFSETS
PHASE DLXLEN
DLXMSK::! BLOCK 1 ;MASK OF FRONT END BITS
DLXKAX::! BLOCK 1 ;INSTRUCTION FOR NON-KA10 STYLE INTERRUPTS
DLXSWA::! BLOCK 1 ;WINDOW ADDRESS
DLXENB::! BLOCK 1 ;INSTRUCTION TO ENABLE WINDOW AND INTERRUPTS
DLXCLR::! BLOCK 1 ;INSTRUCTION TO CLEAR PORT ENABLE
DLXCNI::! BLOCK 1 ;INSTRUCTION TO READ DL10 CONDITIONS
DLXI11::! BLOCK 1 ;
DLXDBL::! ;LENGTH OF DL10 BASE TABLE
DEPHASE
> ;END IFN FTKL10
IFN FTKL10,< ;DTE SPECIFIC BASE TABLE OFFSETS
PHASE DLXLEN
DLXEVM::! BLOCK 1 ;REMEMBER NUMBER OF PAGES OF EVM AND THE EXEC
; VIRTUAL ADDR FOR RETURNING EVM
DLXOCN::! BLOCK 1 ;COUNT OF BYTES IN DIRECT OUT MSG
DLXODA::! BLOCK 2 ;BYTES TO BE PUT IN THE DIRECT MSG
DLXICI::! BLOCK 1 ;# BYTES EXPECTING IN THE INDIRECT INPUT MSG
DLXIBP::! BLOCK 1 ;BYTE PTR TO USER BUFFER PASSED TO DTESER
DLXICN::! BLOCK 1 ;COUNT OF BYTES RECEIVED IN INPUT DIRECT MSG
DLXIDA::! BLOCK 2 ;BYTES FROM THE INPUT DIRECT MSG
DLXETD::! BLOCK 1 ;POINTER TO CORRESONDING ETD
DLXSBL::! ;DTE BASE TABLE LENGTH
DEPHASE
> ;END IFN FTKL10
IFN FTKS10,< ;KMC/DUP SPECIFIC BASE TABLE OFFSETS
;D6RINT USES THE SAME OFFSETS...
PHASE DLXLEN
DLXFLG::! BLOCK 1 ;GENERAL PURPOSE FLAGS WORD (SEE D6KINT)
DLXICI::! BLOCK 1 ;# BYTES EXPECTING IN THE INDIRECT INPUT MSG
DLXIBP::! BLOCK 1 ;BYTE POINTER TO USER BUFFER PASSED TO KDPINT
DLXIMQ::! BLOCK 1 ;INPUT MESSAGE QUEUE (0 OR 1 LONG)
DLXKBL::! ;KMC/DUP (AND DMR) BASE TABLE LENGTH
DEPHASE
> ;END IFN FTKS10
SUBTTL BASE TABLE GENERATION -- DL10
DEFINE BASE11 (CPX,N),< ;;CPX = CPU NUMBER, N = PORT NUMBER
IFN TP.DL'N,< ;;IF A PDP11
IFE M'CPX'N'D78,< ;; BUT NOT A DAS78
DL'CPX'N'BS:
BLOCK DLXDBL ;;RESERVE SPACE FOR ONE DL10 BASE TABLE
IFLE N-3,< ;;DL10 #0
DLX=DLC ;;CONTROL REGISTER
DLBX=DLB ;;BASE ADDRESS REGISTER
>
IFG N-3,< ;;DL10 #1
DLX=DLC2 ;;CONTROL REGISTER
DLBX=DLB2 ;;BASE ADDRESS REGISTER
>
;; MACRO TO LOAD UP TABLE LOCATIONS
DEFINE X (OFS,DAT),<
LOC DL'CPX'N'BS+OFS
DAT
>
;; DATA COMMON TO ALL DL10 BASE TABLES
X DLXWIN,<.DL'CPX'N'B> ;;WINDOW ADDRESS
X DLXINI,<JFCL> ;;DO THIS ON INTERRUPT
X DLXPRG,<JFCL> ;;DO THIS WHEN THE -11 GOES DOWN
X DLXMSK,<777777700007!<70_<<N&3>*3>>>
;;"AND" OUT OTHER PDP11 BITS
X DLXKAX,<DATAO DLX,[XWD 400001,0]>
;;NON-KA10 STYLE INTERRUPTS
X DLXSWA,<CONO DLBX,.DL'CPX'N'B+<M7'N'BAM>_2+<N&3>>
;;WINDOW ADDRESS
X DLXENB,<CONO DLX,1B19+1B20+<1B31_<<N&3>*3>>+SCNCHN>
;;ENABLE WINDOW AND INTERRUPTS.
X DLXCLR,<CONO DLX,1B19+<70_<<N&3>*3>>+SCNCHN>
;;CLEAR PORT ENABLE
X DLXCNI,<CONI DLX,T1> ;;READ DL10 CONDITIONS
X DLXI11,<CONO DLX,1B19+1B20+<1B30_<<N&3>*3>>+SCNCHN>
;;INTERRUPT THE PDP11
IFN M'CPX'N'D85,< ;;ANF10 DC75/DN87 FRONT ENDS
X DLXSTA,<SETOM DLXTA(P1)>;;MARK -10 AS BEING ALIVE
X DLXTYP,.C1D75 ;;TYPE OF PDP11
X DLXPRE,<PUSHJ P,D85PRE##>;;
X DLXCEV,0 ;;CAL11. UUO ENTRY VECTOR
X DLXFEK,<D8'N'FEK> ;;ADDRESS OF ASSOCIATED FEK
>
IFN M'CPX'N'D60,< ;;DN60 FRONT ENDS
X DLXSTA,<SETOM DLXTA(P1)>;;MARK -10 AS BEING ALIVE
X DLXTYP,.C1D60 ;;TYPE OF PDP11
X DLXPRE,<JFCL> ;;
X DLXCEV,<JRST D60CEV##(P1)> ;;CAL11. UUO ENTRY VECTOR
X DLXFEK,<D8'N'FEK> ;;ADDRESS OF ASSOCIATED FEK
>
LOC DL'CPX'N'BS+DLXDBL
> ;END IFE M'CPX'N'D78
> ;END IFN TP.DL'N
> ;END BASE11 MACRO
SUBTTL BASE TABLE GENERATION -- DTE
DEFINE BASDTE (CPX,DTX),<
DS'CPX'DTX'BS::
BLOCK DLXSBL ;;RESERVE SPACE FOR ONE DTE BASE TABLE
; MACRO TO LOAD UP TABLE LOCATIONS
DEFINE X (OFS,DAT),<
LOC DS'CPX'DTX'BS+OFS
DAT
>
;; DATA COMMON TO ALL DTE BASE TABLES
X DLXWIN,<XWD CPX,DTX> ;;CPU#,,DTE#
X DLXSTA,<JFCL> ;;DTE KNOWS WHEN THE -10'S ALIVE
X DLXINI,<JFCL> ;;DO THIS ON INTERRUPT
X DLXPRG,<JFCL> ;;DO THIS WHEN THE -11 GOES DOWN
X DLXPRE,<JFCL> ;;
X DLXNMT,<SIXBIT /NOBODY/>;;NAME
X DLXTYP,.C1CFE ;;FRONT END TYPE
X DLXFEK,<S'CPX'DTX'FEK> ;;ADDRESS OF ASSOCIATED FEK
X DLXETD,<CONC(ETD'CPX,\<DTX+1>,B##)> ;;ADDRESS OF ASSOCIATED ETD
LOC DS'CPX'DTX'BS+DLXSBL
> ;END BASDTE MACRO
SUBTTL BASE TABLE GENERATION -- KMC/DUP
DEFINE BASKDP (KMX,KLX),< ;;KMX = KMC #, KLX = DUP # (KMX == 0)
DK'KMX'KLX'BS:
BLOCK DLXKBL ;;RESERVE SPACE FOR ONE KMC/DUP BASE TABLE
; MACRO TO LOAD UP TABLE LOCATIONS
DEFINE X (OFS,DAT),<
LOC DK'KMX'KLX'BS+OFS
DAT
>
;; DATA COMMON TO ALL KMC/DUP BASE TABLES
X DLXWIN,<KDL'KLX'PG> ;;KDL BASE TABLE
X DLXSTA,<JFCL> ;;KDP KNOWS WHEN THE -10 IS ALIVE
X DLXINI,<JFCL> ;;DO THIS ON INTERRUPT
X DLXPRG,<JFCL> ;;DO THIS WHEN THE -11 GOES DOWN
X DLXPRE,<JFCL> ;;
IFE <M.'KLX'KDP-KD.ANF>,< ;;ANF10 FRONT ENDS
X DLXNMT,<SIXBIT /ANF10/> ;;NAME
X DLXTYP,.C1D22 ;;TYPE OF PDP11
X DLXCEV,0 ;;CAL11. UUO ENTRY VECTOR
X DLXFEK,DK'KLX'FEK ;;ADDRESS OF ASSOCIATED FEK
>
IFE <M.'KLX'KDP-KD.DNT>,< ;;DECNET FRONT ENDS
X DLXNMT,<SIXBIT /DECNET/>;;NAME
X DLXTYP,.C1D22 ;;TYPE OF PDP11
X DLXCEV,0 ;;CAL11. UUO ENTRY VECTOR
X DLXFEK,0 ;;ADDRESS OF ASSOCIATED FEK
>
IFE <M.'KLX'KDP-KD.USR>,< ;;USER FRONT ENDS
X DLXNMT,<SIXBIT /USER/> ;;NAME
X DLXTYP,.C1D22 ;;TYPE OF PDP11
X DLXCEV,0 ;;CAL11. UUO ENTRY VECTOR
X DLXFEK,0 ;;ADDRESS OF ASSOCIATED FEK
>
IFE <M.'KLX'KDP-KD.IBM>,< ;;DN60 FRONT ENDS
X DLXNMT,<SIXBIT /DN60/> ;;NAME
X DLXTYP,.C1D60 ;;TYPE
X DLXCEV,<JRST D6KCEV##(P1)> ;;CAL11. UUO ENTRY VECTOR
X DLXFEK,0 ;;ADDRESS OF ASSOCIATED FEK
>
LOC DK'KMX'KLX'BS+DLXKBL
> ;END BASKDP MACRO
SUBTTL BASE TABLE GENERATION -- DMR
DEFINE BASDMR (DRX),< ;;DRX = DMR #
DMR'DRX'BS:
BLOCK DLXKBL ;;RESERVE SPACE FOR ONE DMR BASE TABLE
; MACRO TO LOAD UP TABLE LOCATIONS
DEFINE X (OFS,DAT),<
LOC DMR'DRX'BS+OFS
DAT
>
;; DATA COMMON TO ALL DMR BASE TABLES
X DLXWIN,<DMR'DRX> ;;DMR BASE TABLE
X DLXSTA,<JFCL> ;;DMR KNOWS WHEN THE -10 IS ALIVE
X DLXINI,<JFCL> ;;DO THIS ON INTERRUPT
X DLXPRG,<JFCL> ;;DO THIS WHEN THE -11 GOES DOWN
X DLXPRE,<JFCL> ;;
IFE <M.'DRX'DMR-RD.ANF>,< ;;ANF10 FRONT ENDS
X DLXNMT,<SIXBIT /ANF10/> ;;NAME
X DLXTYP,.C1D22 ;;TYPE OF PDP11
X DLXCEV,0 ;;CAL11. UUO ENTRY VECTOR
X DLXFEK,DR'DRX'FEK ;;ADDRESS OF ASSOCIATED FEK
>
IFE <M.'DRX'DMR-RD.DNT>,< ;;DECNET FRONT ENDS
X DLXNMT,<SIXBIT /DECNET/>;;NAME
X DLXTYP,.C1D22 ;;TYPE OF PDP11
X DLXCEV,0 ;;CAL11. UUO ENTRY VECTOR
X DLXFEK,0 ;;ADDRESS OF ASSOCIATED FEK
>
IFE <M.'DRX'DMR-RD.USR>,< ;;USER FRONT ENDS
X DLXNMT,<SIXBIT /USER/> ;;NAME
X DLXTYP,.C1D22 ;;TYPE OF PDP11
X DLXCEV,0 ;;CAL11. UUO ENTRY VECTOR
X DLXFEK,0 ;;ADDRESS OF ASSOCIATED FEK
>
IFE <M.'DRX'DMR-RD.IBM>,< ;;DN60 FRONT ENDS
X DLXNMT,<SIXBIT /DN60/> ;;NAME
X DLXTYP,.C1D60 ;;TYPE
X DLXCEV,<JRST D6RCEV##(P1)> ;;CAL11. UUO ENTRY VECTOR
X DLXFEK,0 ;;ADDRESS OF ASSOCIATED FEK
>
LOC DMR'DRX'BS+DLXKBL
> ;END BASDMR MACRO
IFN PDP11N,< ;IF DL10 BASED PDP11S
$HIGH
IFN M.DAS78,<XXIINT:> ;DAS78 XXI INTERRUPTS HERE
DLXINT: JRST DLXSCC ;START OF KA STYLE INTERRUPT CHAIN
JRST .-1 ;MAKE SYSINI HAPPY
IFN M.DAS78,<
DEFINE B78BT (CPU,PORT),<
IFNDEF M8'CPU'PORT'BT,<EXP Z>
IFDEF M8'CPU'PORT'BT,<EXP M8'CPU'PORT'BT>>
$HIGH
M78BT::
ZZZ=0
REPEAT 10,<
B78BT (0,\ZZZ)
ZZZ=ZZZ+1>
>;END IFN M.DAS78
$ABS
ZZZ==0 ;GENEATE INTERRUPT ROUTINE FOR EACH
REPEAT 10,< ; DL10 BASED DAS78
EACH78 (\ZZZ)
ZZZ==ZZZ+1
>
ZZZ=0 ;GENERATE INTERRUPT ROUTINE FOR EACH
REPEAT 10,< ; DL10 BASED ANF10 PDP11
EACH76(\ZZZ)
ZZZ==ZZZ+1
>
$HIGH
JRST DLXINT+1 ;CONSO CHAIN FALLS OUT HERE
$ABS
;
; GENERATE THE BASE TABLES. ONE FOR EACH DL10 PDP11 AND ONE
; FOR EACH PDP11 ON A DTE20 (EXCEPT FOR THE CONSOLE AND
; DN87S'S)
;FIRST THE DL-10 BASED FRONT ENDS
ZZZ==0 ;START WITH #0
REPEAT 8,<
BASE11(0,\ZZZ) ;BUILD THE NEXT BASE TABLE
ZZZ==ZZZ+1> ;STEP TO THE NEXT DL-10 PORT
> ;END OF IFN PDP11N
;NOW THE DTE-20 BASED FRONT ENDS
IFN FTKL10,<
ZZ==0 ;CPU #
REPEAT M.CPU,< ;FOR ALL CPU'S
ZZZ==0 ;DTE NUMBER
REPEAT 4,< ;FOR ALL DTE'S ON THIS CPU
BASDTE(\ZZ,\ZZZ) ;BUILD A BASE TABLE
ZZZ==ZZZ+1> ;STEP TO THE NEXT DTE
ZZ==ZZ+1> ;STEP TO THE NEXT CPU
> ;END FTKL10
$ABS
;BASE TABLES FOR KDP'S (IF USING IBM COMM)
IFN FTKS10,<
ZZ==0 ;START OUT ON LINE ZERO
REPEAT M.KDUP,< ;FOR ALL LINES
BASKDP(0,\ZZ) ;BUILD A BASE TABLE
ZZ==ZZ+1> ; AND STEP TO THE NEXT
ZZ==0 ;START OUT ON LINE ZERO
REPEAT M.DMRN,< ;FOR THE DMRS TOO
BASDMR(\ZZ) ;BUILD A BASE TABLE
ZZ=ZZ+1> ;AND STEP TO THE NEXT
>; END FTKS10
IFN PDP11N,<
$HIGH
; BUILD THE BASE TABLES FOR ANF10 AND DAS78 FRONT ENDS
DEFINE B78BAT (CPU,PORT),<
IFE TP.DL'PORT,<EXP 0>
IFN TP.DL'PORT,<
IFE M'CPU'PORT'D78,<EXP 0>
IFN M'CPU'PORT'D78,<XWD M8'PORT'DDB,.DL'CPU'PORT'B>
> ;;END IFN TP.DL'PORT
> ;END B78BAT
DEFINE BLXBAT (CPU,PORT),<
IFE TP.DL'PORT,<EXP 0>
IFN TP.DL'PORT,<
IFE M'CPU'PORT'D78,<EXP DL'CPU'PORT'BS>
IFN M'CPU'PORT'D78,<EXP 0>
> ;;END IFN TP.DL'PORT
> ;END BLXBAT
DLXBAT:: ;START OF THE ANF10 MAPPING TABLE
ZZZ==0 ;PORT COUNTER
REPEAT 8,< ;FOR ALL POSSIBLE PORTS
BLXBAT (0,\ZZZ) ;EXPAND THE MACRO
ZZZ==ZZZ+1> ;AND STEP TO THE NEXT PORT
IFN M.DAS78,<
M78BAT:: ;START OF THE DAS78 MAPPING TABLE
ZZZ==0 ;PORT COUNTER
REPEAT 8,< ;FOR ALL POSSIBLE PORTS
B78BAT (0,\ZZZ) ;EXPAND THE MACRO
ZZZ==ZZZ+1> ;AND STEP TO THE NEXT PORT
$ABS
; MACRO TO BUILD A TABLE CONTAINING DDB ADDRESSES FOR EACH DAS78
DEFINE B78DDB (CPU,PORT),<
IFDEF M8'PORT'KII,<M8'PORT'DDB::BLOCK M'CPU'PORT'D78>
> ;END B78DDB
M78DDB::
ZZZ==0
REPEAT 8,< ;FOR ALL POSSIBLE PORTS
B78DDB (0,\ZZZ) ;EXPAND THE MACRO
ZZZ==ZZZ+1> ;AND STEP TO THE NEXT PORT
$HIGH
; MACRO TO BUILD A TABLE WHICH CONTAINS THE LAST USED LOCATION IN
; THE DAS78 WINDOW FOR EACH PORT.
DEFINE B78END (CPU,PORT),<
IFNDEF M'CPU'PORT'END,<EXP 0>
IFDEF M'CPU'PORT'END,<EXP M'CPU'PORT'END>
> ;END B78END
M78END::
ZZZ==0
REPEAT 8,<
B78END (0,\ZZZ)
ZZZ==ZZZ+1>
; MACRO TO BUILD A TABLE WHICH CONTAINS THE NUMBER OF LINES
; ON EACH DAS78
DEFINE B78LIN (CPU,PORT),<EXP M'CPU'PORT'D78>
M78LIN::
ZZZ==0
REPEAT 8,< ;FOR ALL POSSIBLE PORTS
B78LIN (0,\ZZZ) ;EXPAND THE MACRO
ZZZ==ZZZ+1> ;AND STEP TO THE NEXT PORT
$ABS
D78NAM::BLOCK 10 ;TABLE OF NAMES FILLED IN BY THE PDP11
; THROUGH A POINTER IN THE DAS78 WINDOW
> ;END IFN M.DAS78
> ;END OF IFN PDP11N
$HIGH
;HELPER MACRO FOR SETTING UP THE DTE -- BASE TABLE CORRESPONDENCE MAP
DEFINE BLXBAT (CPX,DTX),<EXP DS'CPX'DTX'BS>
DTEBAS:: ;START OF THE DTE TO BASE TABLE MAPPING
IFN FTKL10,<
ZZ==0 ;CPU COUNTER
REPEAT M.CPU,< ;FOR ALL CPU'S
ZZZ==0 ;ZERO THE DTE COUNTER
REPEAT 4,< ;FOR ALL DTE-20S
BLXBAT(\ZZ,\ZZZ) ;MAKE THE MAP ENTRY
ZZZ==ZZZ+1> ; STEP TO THE NEXT DTE
ZZ==ZZ+1> ; STEP TO THE NEXT CPU
>
DEFINE BLXBAT(KMX,KLX),<EXP DK'KMX'KLX'BS> ;BASE TABLE ADDRESS
KDPBAS:: ;START OF THE KDP BASE TABLES
IFN M.DN60&M.DN6K,< ;IF WE HAVE IBM
ZZ==0 ;START AT THE FIRST LINE
REPEAT M.KDUP,< ;FOR ALL LINES
BLXBAT(0,\ZZ) ;EXPAND A POINTER TO THEM
ZZ==ZZ+1> ;STEP TO THE NEXT
>; END IFN M.DN60&M.DN6K
DEFINE BLXBAT(DRX),<EXP DMR'DRX'BS> ;BASE TABLE ADDRESS
DMRBAS:: ;START OF THE DMR BASE TABLES
IFN M.DN60&M.DN6R,< ;IF WE HAVE IBM
ZZ==0 ;START AT THE FIRST LINE
REPEAT M.DMR,< ;FOR ALL LINES
BLXBAT(\ZZ) ;EXPAND A POINTER TO THEM
ZZ==ZZ+1> ;STEP TO THE NEXT
>; END M.DN60&M.DN6R
$ABS
IFNDEF DLXFST,<DLXFST==:.> ;START OF DL10 UNCACHED SPACE
DLXLST:: ;END OF UN-CACHED AREA
IFN FTMP&M.KL10,<
OUCHTB::IFIW MONORG+0*PAGSIZ(T1) ;IFIW'S
IFIW MONORG+1*PAGSIZ(T1)
IFIW MONORG+2*PAGSIZ(T1)
IFIW MONORG+3*PAGSIZ(T1)
IFIW MONORG+4*PAGSIZ(T1)
IFIW MONORG+5*PAGSIZ(T1)
IFIW MONORG+6*PAGSIZ(T1)
IFIW MONORG+7*PAGSIZ(T1)
>
LIT ;FORCE ANY INITIALIZATION LITERALS INTO LOW SEGMENT
SUBTTL BACKGROUND PERFORMANCE ANALYSIS SELECTION TABLE
IFN M.KL10&FTRSP,<
$HIGH ;THE TABLE IS "PURE"
;BPATAB -- TABLE OF BACKGROUND PERFORMANCE ANALYSIS CONDITIONS
;
;THIS TABLE CONTAINS THE ORDERED LIST OF "ASPECTS" OF THE SYSTEM
;TO WATCH VIA THE PERFORMANCE ANALYSIS METER OF THE KL-10 CPU.
;
;EACH ITEM IN THE BPATAB TABLE HAS A CORRESPONDING 4-WORD BLOCK IN
;THE CDB VARIABLES AREA (SUBTABLE .CPBPV). THE FIRST TWO WORDS ARE
;THE RDTIME TOTAL FOR WHICH THE CONDITION(S) WAS(WERE) WATCHED, AND
;THE SECOND TWO WORDS ARE THE PERFORMANCE METER COUNT FOR THE ENABLED
;CONDITION(S) - EITHER AN INTEGER COUNT IF IN EVENT MODE OR ELAPSED
;TIME IF IN DURATION MODE. THE ORDER OF THE TABLE IS IMPORTANT SINCE
;THE NUMBERS ARE GETTAB'ED OUT OF THE .CPBPV SUBTABLE.
;
;ALTHOUGH THIS TABLE REALLY BELONGS IN APRSER IT MUST APPEAR IN COMMON
;BEFORE THE CDB DEFINITIONS AS THE LENGTH OF THE TABLE IS NEEDED TO
;DEFINE THE CDB VARIABLES SUBTABLE.
BPATAB::PE.CP0!PE.UCI!PE.PRI!PE.CCI!PE.PPI!PE.PCI!PE.CLR ;CH 0
PE.CP1!PE.UCI!PE.PRI!PE.CCI!PE.PPI!PE.PCI!PE.CLR ;CH 1
PE.CP2!PE.UCI!PE.PRI!PE.CCI!PE.PPI!PE.PCI!PE.CLR ;CH 2
PE.CP3!PE.UCI!PE.PRI!PE.CCI!PE.PPI!PE.PCI!PE.CLR ;CH 3
PE.CP4!PE.UCI!PE.PRI!PE.CCI!PE.PPI!PE.PCI!PE.CLR ;CH 4
PE.CP5!PE.UCI!PE.PRI!PE.CCI!PE.PPI!PE.PCI!PE.CLR ;CH 5
PE.CP6!PE.UCI!PE.PRI!PE.CCI!PE.PPI!PE.PCI!PE.CLR ;CH 6
PE.CP7!PE.UCI!PE.PRI!PE.CCI!PE.PPI!PE.PCI!PE.CLR ;CH 7
PE.CPI!PE.UCI!PE.PRI!PE.CCI!PE.PP0!PE.PCI!PE.CLR ;PI 0
PE.CPI!PE.UCI!PE.PRI!PE.CCI!PE.PP1!PE.PCI!PE.CLR ;PI 1
PE.CPI!PE.UCI!PE.PRI!PE.CCI!PE.PP2!PE.PCI!PE.CLR ;PI 2
PE.CPI!PE.UCI!PE.PRI!PE.CCI!PE.PP3!PE.PCI!PE.CLR ;PI 3
PE.CPI!PE.UCI!PE.PRI!PE.CCI!PE.PP4!PE.PCI!PE.CLR ;PI 4
PE.CPI!PE.UCI!PE.PRI!PE.CCI!PE.PP5!PE.PCI!PE.CLR ;PI 5
PE.CPI!PE.UCI!PE.PRI!PE.CCI!PE.PP6!PE.PCI!PE.CLR ;PI 6
PE.CPI!PE.UCI!PE.PRI!PE.CCI!PE.PP7!PE.PCI!PE.CLR ;PI 7
BPATLN==:.-BPATAB
$ABS ;BACK TO "IMPURE"
> ;END OF IFN M.KL10&FTRSP
SUBTTL CPU DATA BLOCK(S):
REPEAT 0,<
EACH CPU HAS ITS OWN DATA BLOCK, KNOWN AS A CDB. ALL .CP??? SYMBOLS ARE
DEFINED RELATIVE TO THE (MAPPED) CDB, .CN??? SYMBOLS ARE ABSOLUTE LOCATIONS.
A FEW LOCATIONS ARE REALLY SYSTEM PARAMETERS (EG. CORTAL), RATHER THAN CPU
PARAMETERS. HOWEVER, THEY WERE IN THE MIDDLE OF A GETTAB (NSWTBL) AND SO
COULD NOT BE SEPARATED OUT WITHOUT INVALIDATING SOME PROGRAMS.
WHEN ADDING CONSTANTS OR VARIABLES TO COMMON, GREAT CARE MUST BE EXERCISED
IN DECIDING WHETHER TO PUT IT IN THE CDB OR IN A SYSTEM DEPENDENT TABLE
(.SYTBL). IF THE CONTENTS COULD EVER BECOME CPU DEPENDENT IN THE FUTURE,
BE SURE TO PUT IT IN THE CDB INSTEAD OF .SYTBL. IF A MISTAKE IS MADE, THE
LOCATION WILL HAVE TO APPEAR IN THE CDBS AS WELL AS .SYTBL IN ORDER TO INSURE
COMPATIBLITY.
> ;END REPEAT 0
DEFINE CDB (N),<
;;MACRO TO GENERATE CPU DATA BLOCK LOCATIONS
;;ARGUMENTS:
;; NAM THREE LETTER SUFFIX FOR SYMBOL
;; VAL OPTIONAL VALUE TO STORE IN LOCATION (DEFAULT = ZERO)
;; LEN OPTIONAL LENGTH OF STORAGE AREA (DEFAULT = ONE WORD)
;; LBL OPTIONAL ALTERNATE LABEL FOR OLD-STYLE CPU0 REFERENCES
DEFINE CWRD (NAM,VAL,LEN,LBL,%X<N>),<
IFE %X,<IFNB <VAL>,<IFNB <LEN>,<PRINTX ? CDB location .CP'NAM defined with both a value and a length>>>
IFNB <NAM>,<
.C'%X'NAM:: ;;CREATE CPU-SPECIFIC SYMBOL
.CP'NAM=:.-.C'%X'CDB+.EVCDB ;;CREATE GENERIC CDB SYMBOL
> ;;END IFNB <NAM>
IFE %X,<IFNB <LBL>,<LBL==:.>> ;;GENERATE ALTERNATE LABEL
IFB <LEN>,<VAL> ;;STORE POSSIBLE VALUE
IFNB <LEN>,<REPEAT LEN,<EXP 0>> ;;CREATE STORAGE BLOCK
IFB <VAL>,<IFB <LEN>,<EXP 0>> ;;IF VALUE AND LENGTH BLANK, STORE A ZERO
> ;;END DEFINE CWRD
;;MACRO TO DEFINE A CONSTANT IF THIS IS THE CPU0 CDB
DEFINE CCON (A,B),<IFE N,<A==:B>>
;;MACRO TO DEFINE JSR ENTRY POINT
DEFINE CJSR (NAM,ADR),<
CWRD (NAM)
EXP <ADR>
> ;;END DEFINE CJSR
;;MACRO TO DEFINE AN XPCW ENTRY POINT
DEFINE CXPC (NAM,FLG,ADR),<
CWRD (NAM,,2)
EXP FLG,ADR
> ;;END DEFINE CXPC
;;MACRO TO DETDEFINE A PARAMETER BASED ON THE CPU TYPE
DEFINE KILS,<
IFN M.KL10,<KL>
IFN M.KS10,<KS>
> ;;END DEFINE KILS
CPU'N::
;CONSTANTS IN GETTAB UUO.(NOT CLEARED AT STARTUP OR 143 RESTART)
IFE <M.CPU-N-1>,<.XX==0>
IFG <M.CPU-N-1>,<.XX==<.C'N'CDB+.CPLEN,,0>>
CWRD (CDB,.XX) ;;(000) LH = ADR OF NEXT CDB
;; RH = 0
CWRD (ASN,M.C'N'SN) ;;(001) APR SERIAL NUMBER
CWRD (OK,1) ;;(002) THIS CPU RUNNING OK.
;; IF GREATER THAN 0, THIS CPU HAS STOPPED
;; RUNNING CORRECTLY. CONTENTS ARE NO. OF
;; JIFFIES CPU HAS BEEN STOPPED.
CWRD (EPT,.E'N'EPT) ;;(003) CONTAINS EPT ADDRESS
CWRD (LOG,<SIXBIT/CPU'N/>) ;;(004) LOGICAL CPU NAME (CPUN)
DEFINE KL,<SIXBIT /CPL'N/>
DEFINE KS,<SIXBIT /CPS'N/>
CWRD (PHY,<KILS>) ;;(005) PHYSICAL CPU NAME (CPXN)
DEFINE KL,<CT.KL>
DEFINE KS,<CT.KS>
CWRD (TYP,<KILS>) ;;(006) TYPE OF PROCESSOR
;; LH = CUSTOMER DEFINED
;; RH = DEC DEFINED
CWRD (MPT,<<M.CBAT-1>B8+.C'N'BAT-.C'N'VBG>) ;;(007) BAD ADDRESS SUBTABLE
CWRD (RTC,0) ;;(010) REAL TIME CLOCK (DK10) DDB
CWRD (RTD,0) ;;(011) DK10 DDB IF HI PREC TIME ACCOUNTING
CWRD (PAR,<<.CPPRL-1>B8+.C'N'LPA-.C'N'VBG>) ;;(012) PARITY SUBTABLE
IFE FTRSP,<.CPAOR==:.CPVBG> ;;NO SUBTABLE IF NO RESPONSE STUFF
IFE FTRSP,<.CPRSL==:1> ;;MAX IS 0
CWRD (RSP,<<.CPRSL-1>B8+.C'N'AOR-.C'N'VBG>) ;;(013) RESPONSE SUBTABLE
CWRD (DKX,0) ;;(014) NUMBER OF DK10S ON THIS CPU
DEFINE KL,<M.EBPS>
DEFINE KS,<0>
CWRD (EBS,<KILS>) ;;(015) EBOX TICKS PER SECOND
DEFINE KL,<M.MBPS>
DEFINE KS,<0>
CWRD (MBS,<KILS>) ;;(016) MBOX TICKS PER SECOND
CWRD (NMT,<<.CPNML-1>B8+.C'N'LNA-.C'N'VBG>) ;;(017) NXM SUBTABLE
CWRD (CSB,<<.CPCSL-1>B8+.C'N'APD-.C'N'VBG>) ;;(020) CPU STATUS SUBTABLE
CWRD (DSB,<<.CPDVL-1>B8+.C'N'DVS-.C'N'VBG>) ;;(021) DEVICE STATUS SUBTABLE
DEFINE KL,<<.CPSDL-1>B8+.C'N'SBD-.C'N'VBG>
DEFINE KS,<0>
CWRD (SDP,<KILS>) ;;(022) SBDIAG SUBTABLE
IFE M.KL10&FTRSP,<.XX==0>
IFN M.KL10&FTRSP,<.XX==<BPATLN*4>B8+.C'N'BPV-.C'N'VBG>
CWRD (BPA,<.XX>) ;;(023) PERORMANCE SUBTABLE
CWRD (PCB,0) ;;(024) ADDRESS OF CI PORT CONTROL BLOCK
CWRD (NPB,0) ;;(025) ADDRESS OF NI PORT CONTROL BLOCK
DEFINE KL,<0>
DEFINE KS,<<.CPSML-1>B8+.C'N'SME-.C'N'VBG>
CWRD (MSS,<KILS>) ;(026) SOFT MEMORY ERROR SUBTABLE
;;ADD CONSTANTS TO BE PUBLISHED ABOVE HERE:
CCON (.CPPCL,<<.-.C0CDB>B26>) ;;PUBLISHED CPU DEPENDANT CONSTANTS LENGTH
;UNPUBLISHED CONSTANTS:
CWRD (MAP,.E'N'MAP) ;;ADDRESS OF THIS CPU'S EXEC MAP
CWRD (SPT,<SPTTAB+N>) ;;SPECIAL PAGES TABLE
IFN FTMP,<
CWRD (CHX,0) ;;CACHE SWEEP FLAG FOR MAGTAPES AND DISKS
> ;END IFN FTMP
CWRD (CPN,<EXP N>) ;;CPU NUMBER
DEFINE CPUDEF(M)<
IFE N,<
IFE M,<CAIA>
IFN M,<CAI>>
IFN N,<
IFN M,<CAIA>
IFE M,<CAI>>
> ;;END DEFINE CPUDEF
CWRD (SK0,<CPUDEF(0)>) ;;GENERATE SKIP FOR "SKPCPU(0)"
CWRD (SK1,<CPUDEF(1)>) ;;AND FOR "SKPCPU(1)" **MAINTAIN ORDER**
CWRD (OK1,.C0OK) ;;CONTAINS ADR OF OTHER CPU
CWRD (SLF,.C'N'CDB) ;;POINTER TO START OF CDB
DEFINE SCNLOC,<
IFE N,<SSCAN>
IFN N,<SSCAN1>
>
CWRD (SCN,<SCNLOC>) ;;ADDRESS OF SCHEDULER RUN QUEUE SCAN LIST
IFN FTNSCHED,<
DEFINE SCN,<
IFE N,<SSSCAN>
IFN N,<SSSCN1>
>
CWRD (SST,<SCN>);
> ;END IFN M.CPU-1
CWRD (NPD,<MNULPD,,NU'N'PDL>) ;;NULL PDL POINTER
CWRD (EPD,<ERRPLL,,ER'N'PDL>) ;;ERROR PDL POINTER
CWRD (NJD,NU'N'DAT) ;;ADDRESS OF NULL JOB DATA AREA OFFSET BY 20
;; USED TO SAVE ACS IN 20-37.
CWRD (STO,SC'N'TIC##) ;;SCANNER ONCE A TICK ROUTINE FOR THIS CPU
CWRD (ISR,SC'N'SEC##) ;;SCANNER ONCE A SECOND
IFN FTMP,<
CWRD (DLK,-1) ;;DISK INTERLOCK NESTING FLAG
CWRD (SCD,-1) ;;PER CPU SCHEDULER INTERLOCK FLAG
CWRD (DIE,-1) ;;PER CPU DIE INTERLOCK FLAG
CWRD (RES,<HALT APRPFR##>) ;;RESTORE AFTER POWER FAIL
CWRD (NBI,0) ;;NUMBER OF INTERLOCKS THAT WERE OWNED
;; BY THIS CPU AND BROKEN BY BRKLOK
> ;END IFN FTMP
PWFLEN==:3 ;;NUMBER OF POWER FAIL DATA WORDS
CWRD (PFD,,PWFLEN) ;;POWER FAIL/RESTART DATA
CWRD (KAF,AP'N'KAF) ;;KEEP-ALIVE FAILURE TRAP ADDRESS
CWRD (SVP,0) ;;SAVED AC P ON KAF
CWRD (KFP,0) ;;KAF PDL
CWRD (EPL,EP'N'PDL) ;;PDL FOR PROCESSING PDL OVF
;;APR DEPENDENT CONSO AND CONO BITS
CWRD (CHL,<AP'N'CHL>) ;;ADDRESS OF INTERRUPT PC FOR APR
CWRD (CKL,<CK'N'CHL>) ;;ADDRESS OF INTERRUPT PC FOR CLOCK
CWRD (APP,<-PDL+1,,AP'N'PD1>) ;;PDP FOR APR CHANNEL
CWRD (CON,AP.CSO) ;;APR CONSO MASK
CWRD (EEB,AP.EEB) ;;EXEC ENABLED BITS
CWRD (IEF,AP.CAE) ;;MASK TO CLEAR APR ERROR BITS
CWRD (MPS,<CP.PXX+CP.PS'N'>) ;;LH=BITS TO REQUEST SCAN
;;DOORBELL WORDS
;CWRD (BIT,<1_M.CPU-1>) ;;CPU'S BIT
DEFINE EVENTM(LIST),<
NARGS==0
IRP LIST,<NARGS==NARGS+1>
IFG NARGS*M.CPU-^D36,<PRINTX ?DOORBELL BIT OVERFLOW>
ZZ==0
XX2==0
IRP LIST,<
XX1==1_<<ZZ*M.CPU>+N>
XX2==XX2+XX1
CWRD (LIST'S,<<<<1_M.CPU>-1>_<ZZ*M.CPU>>-XX1>)
CWRD (LIST'C,<XX1>)
ZZ==ZZ+1
>
CWRD (DBM,XX2)
.C'N'BIT==:.C'N'SCC
.CPBIT=:.C0BIT-.C0CDB+.EVCDB
>
EVENTM (<SC,QP>)
DEFINE KL,<LG.TEN+LG.KLP+.E'N'EPT/PAGSIZ>
DEFINE KS,<SG.TEN+SG.KLP+.E'N'EPT/PAGSIZ>
CWRD (EBR,<KILS>) ;;EXEC BASE REGISTER ON THIS CPU
IFN M.KS10,<
CWRD (FEF,0) ;;FLAG SET NON-ZERO WHEN FE INTERRUPTS
> ;END IFN M.KS10
CWRD (CTN,CT'N'LIN##) ;;RH = CTY NUMBER FOR THIS CPU
;;LH = DLS LINE NUMBER ON DTE
IFN M.KL10,<
CWRD (TTD,M'N'TTDN) ;TTYS ON THIS CFE
CWRD (ETD,<IFIW ETDTB'N'##(F)>) ;;ETD TABLE FOR THIS CPU
CWRD (SPF,0) ;;CFE SECONDARY PROTOCOL FLAGS (^-FEATURES)
CWRD (SCA,-1) ;;SCA INTERLOCK NESTING
IFN M.SCA,<
CWRD (SCP,0) ;;SCA CHANNEL ENABLE STATES
>; END IFN M.SCA
>; END IFN M.KL10
CWRD (SIN,-1) ;;SCNSER INTERLOCK NESTING
IFN M.TAPE,<
CWRD (TPN,-1) ;;MAGTAPE INTERLOCK NESTING
CWRD (TPP,0) ;;MAGTAPE CHANNEL ENABLE STATES
> ;END IFN M.TAPE
IFN FTENET,<
CWRD (ETH,-1) ;;ETHERNET INTERLOCK NESTING
>; END IFN FTENET
CWRD (CA0,,20,CRSHAC) ;AC BLOCK 0 ON A CRASH
.C'N'CAC==.C'N'CA0 ;;YET ANOTHER NAME
.CPCAC==:.C'N'CA0-.C'N'CDB+.EVCDB ;;...
CWRD (STT,0) ;;TEMP USED BY APRSER FOR TRAP PROCESSING
;;THE FOLLOWING TWO ENTRIES MUST BE CONTIGUOUS
CWRD (ST1,0) ;;PLACE TO SAVE T1 ON PAGE TRAPS
CWRD (ST2,0) ;;PLACE TO SAVE T2 ON PAGE TRAPS
;;THE FOLLOWING TWO ENTRIES MUST BE CONTIGUOUS
CWRD (TPC,0) ;;TEMP USED BY APRSER FOR IME PROCESSING
CWRD (TP1,0) ;;TEMP USED BY APRSER FOR IME PROCESSING
CWRD (TPF,0) ;;TEMP USED BY APRSER FOR IME PROCESSING
CWRD (EJT,0) ;;TEMP USED BY APRSER FOR IME PROCESSING
IFN FTRTTRP,<
IF1,<
CWRD (RCT,,6) ;;REAL TIME PI CHANNEL TABLE
CWRD (RDT,,6) ;;REAL TIME DISMISS TABLE
>
IF2,<
ZZ==10*N+1
DEFINE BLDTB1(ZZ)
<IFNDEF UNIQ'ZZ,<BLDTB2(ZZ)>
IFDEF UNIQ'ZZ,<IFE UNIQ'ZZ,<BLDTB2(ZZ)>
IFN UNIQ'ZZ,<EXP 0>>>
DEFINE BLDTB2(ZZ)
<IFN CUSD'ZZ,<EXP CH'ZZ>
IFE CUSD'ZZ,<XWD 400001,CH'ZZ>>
DEFINE BLDTB3(ZZ)
<IFDEF CHND'ZZ,<XWD RTSV'ZZ,CHND'ZZ>
IFNDEF CHND'ZZ,<EXP 0>>
CWRD (RCT,,0)
REPEAT 6,<
BLDTB1(\ZZ)
ZZ==ZZ+1>
ZZ==10*N+1
CWRD (RDT,,0)
REPEAT 6,<
BLDTB3(\ZZ)
ZZ==ZZ+1>
> ;;END IF2
> ;;END IFN FTRTTRP
CWRD (CPI,0) ;;PI STATUS
;;THE FOLLOWING TWO ENTRIES MUST BE CONTIGUOUS
CJSR (SVA,<JRST SVSETS>) ;;JSR HERE TO SAVE ALL AC SETS
CWRD (TRP,0) ;;MUUO DURING CRASH
CWRD (RTS,0) ;;TEMP USED DURING RTTRP ERROR PROCESSING
CWRD (RTT,0) ;;RTTRP IN PROGRESS FLAG (DEFINED
;; HERE BECAUSE IT MUST BE 0 DURING ONCE-ONLY)
CWRD (TML,0) ;;VALUE OF "TIME" AT LAST CLOCK TIC
;; USED FOR MAINTAINING CLOCK QUEUE AND
;; SMITHSONIAN DATE
CWRD (OCB,0) ;;0 IF THIS CDB ISN'T OWNED BY ANY CPU
CWRD (DWD,-1) ;;RECURSION INTERLOCK FOR DIE
;;PI SAVE ROUTINES
.C'N'SAV==:.
.CPSAV=:.-.C'N'CDB+.EVCDB
IFE N,<
SAV1,,SAV1
SAV2,,SAV2
SAV3,,SAV3
SAV4,,SAV4
SAV5,,SAV5
SAV6,,SAV6
> ;;END IFE N
IFN N,<
SAVB'N'1,,SAV'N'1
SAVB'N'2,,SAV'N'2
SAVB'N'3,,SAV'N'3
SAVB'N'4,,SAV'N'4
SAVB'N'5,,SAV'N'5
SAVB'N'6,,SAV'N'6
> ;;END IFN N
;;START OF AUTOCONFIGURE DATA
CWRD (ATR,<-1>) ;;DATA BASE INTERLOCK REQUEST COUNT
CWRD (ATO,<-1>) ;;DATA BASE INTERLOCK OWNER ID
CWRD (ATP,0) ;;SAVED PI SYSTEMS STATE
CWRD (ASC,<-1>) ;;NUMBER OF AUTO-CONFIGURED SOFTWARE CHANNELS
CWRD (DVC,0) ;;DEVICE CODE
CWRD (DRV,0) ;;DRIVER DISPATCH
CWRD (CHA,0) ;;CHANNEL DATA BLOCK ADDRESS
CWRD (TSN,,2) ;;TEMPORARY DRIVE SERIAL NUMBER STORAGE
IFN M.KL10,<
CWRD (CNI,<CONI 000,T1>) ;;CONI
CWRD (CNO,<CONO 000,(T1)>) ;;CONO
CWRD (DTI,<DATAI 000,T2>) ;;DATAI
CWRD (DTO,<DATAO 000,T2>) ;;DATAO
CWRD (BKI,<BLKI 000,T2>) ;;BLKI
CWRD (BKO,<BLKO 000,T2>) ;;BLKO
>; END IFN M.KL10
IFN M.KS10,<
CWRD (UMR,,MAXUBA) ;;HIGHEST MAPPING REGISTER ASSIGNED ON UBA
>; END IFN M.KS10
;;END OF AUTOCONFIGURE DATA
CWRD (CML,0) ;;LDB ADDRESS OF LINE ON WHICH COMMAND IS BEING
;; PROCESSED ON THIS CPU
;;KL10 ERROR REPORTING/RECOVERY
IFN M.KL10,<
CWRD (SB0,<100000,,0>) ;;DO SBDIAG 0 HERE ON ERRORS
CWRD (S0A,<0>) ;;ANSWER RETURNED HERE
CWRD (SB1,<100000,,1>) ;;SBDIAG FN 1 DONE HERE
CWRD (S1A,<0>) ;;ANSWER RETURNED HERE
>;END IFN M.KL10
CWRD (TOA,CCTYO##) ;;TYPE OUT ADDRESS FOR THIS CPU (OLD COMTOA)
CWRD (TIV,0) ;;ADDRESS OF VECTOR OF INPUT ROUTINES
CWRD (LFC,0) ;;LAST FORCED COMMAND INDEX FOR JOB IN COMCON
;EXEC DDT WORDS
CWRD (DDT,<BPTNOP>) ;;NOOP OR INSTRUCTION TO ENTER EDDT
;; THIS WORD MAY BE EXECUTED ANYTIME ANY
;; ROUTINE WANTS TO ENTER EDDT VIA THE
;; THE UNSOLICITED BREAKPOINT FACILITY.
;; SETUP BY CPUDDT.
;;EXEC DATA VECTOR FOR EDDT SYMBOL TABLE HIDING
CWRD (EDV,<XWD 'EDV',.EDLEN>) ;;CODE,,LENGTH OF EXEC DATA VECTOR
DEFINE HSBDEF<
IFE FTXMON,<.C'N'SYB>
IFN FTXMON,<0>
>
CWRD (ED1,<HSBDEF>) ;;ADDRESS OF THE ADDRESS SWAPPING BLOCK
CWRD (ED2,0) ;;RELOCATED CONTENTS OF .JBSYM
CWRD (ED3,0) ;;RELOCATED CONTENTS OF .JBUSY
CWRD (ED4,<.C'N'HSF>) ;;ADDRESS OF A WORD FOR DDT TO PLAY WITH
DEFINE KL,<CT.KL!ED.KLP!ED.XKL>
DEFINE KS,<CT.KS!ED.KLP>
CWRD (ED5,<KILS>) ;;CPU/PAGING/HARDWARE DATA
CWRD (ED6,<.E'N'EPT>) ;;PHYSICAL ADDRESS OF THE EPT
CWRD (ED7,<SPTTAB>) ;;PHYSICAL ADDRESS OF THE SPT
CWRD (ED8,0) ;;PHYSICAL ADDRESS OF THE CST
CWRD (ED9,<CPNDDT>) ;;PHYSICAL ADDRESS OF CPNDDT
CWRD (EDA,<-M.CPU,,ASNTAB>) ;;AOBJN TO CPU SERIAL NUMBERS
CWRD (EDB,.C'N'ACA) ;;PHYSICAL ADDR. OF VIRTUAL ADDR. OF CRASH ACS
IFE <M.CPU-N-1>,<.XX==.C0EDV>
IFG <M.CPU-N-1>,<.XX==.C'N'CDB+.CPLEN+<.C'N'EDV-.C'N'CDB>>
CWRD (EDC,.XX) ;;VIRTUAL ADDR OF NEXT EDV IN RING
CWRD (HSF,0) ;;DDT SCRATCH PAD
IFE FTXMON,<
CWRD (SYB,<1+4>) ;;# WORDS (INC THIS) IN HIDDEN SYMBOL BLOCK
;;FIRST SUB-BLOCK
CWRD (SY1,<SYMSIZ>) ;;(0) NUMBER OF WORDS TO SWAP
CWRD (SY2,<.E'N'MAP+<MONORG/PAGSIZ>>) ;;(1) FIRST WORD TO SWAP
CWRD (SY3,SYMBK1) ;;(2) PLACE WHERE NEW MAP MAY BE FOUND
CWRD (SY4,SYMBK2) ;;(3) PLACE TO SAVE OLD CONTENTS
;;END OF FIRST SUB BLOCK
>;; END IFE FTXMON
CXPC (SPC,<IC.UOU>,PERISH##) ;;XPCW ENTRY TO DIE
;;STOPCODE OLD FLAGS & PC, NEW FLAGS & PC
IFN M.KL10,<
CWRD (TMI,TM'N'INT) ;;ADDRESS OF TIMER INTERRUPT ROUTINE
>;; END IFN M.KL10
.CPCLN==.-.C0CDB ;;LENGTH OF CONSTANTS AREA
;;VARIABLES AREA FOR CPU0 (ALSO DEFINED SYMBOLS FOR CPU 1)
;;OLD NSWTBL GETTAB HAS SOME VARIABLES WHICH ARE SYSTEM RATHER THAN CPU
;;DEPENDENT. HOWEVER FOR COMPATIBILITY, THEY ARE KEPT TOGETHER. .SYTBL
;;HAS NEW SYSTEM VARIABLES DEFINED AFTER 5.03 RELEASE
IFE N,<
NSWTBL==:.-10 ;;GETTAB TABLE NO 12. VARIABLES PERTAINING
;; TO SWAPPING AND NON-SWAPPING SYSTEMS.
;; FIRST 10 LOCATION NO LONGER USED.
;;THE NUMBERS IN () ARE FOR NEW CPU DEPENDENT
;; GETTAB TABLE .GTC0V.
> ;;END IFE N
LOC==. ;;START LOC AT ABS. BEG OF VARIABLE AREA
;; LOC USED IN V MACRO AS A LOCATION COUNTER
CWRD (VBG,,0) ;;BEGINING OF VARIABLE AREA
;;START OF SYSTEM VARIABLES
CWRD (,,1,CORMAX) ;;(000) MAXIMUM CORE REQUEST+1 (IE LARGEST
;; RELATIVE ADDRESS + 1)
;; CAN BE RESTRICTED TO LESS THAN ALL
;; OF USER CORE BY BUILD AND/OR ONCE
CWRD (,,1,CORLST) ;;(001) 1 BIT BYTE POINTER TO LAST FREE
;; BLOCK POSSIBLE
CWRD (,,1,CORTAL) ;;(002) TOTAL NUMBER OF FREE+DORMANT+IDLE
;; CORE BLKS LEFT
CWRD (,,1,SHFWAT) ;;(003) JOB NUMBER SHUFFLER HAS TEMPORARILY
;; STOPPED FOR ITS I/O DEVICES TO BECOME
;; INACTIVE BEFORE SHUFFLING
CWRD (,0) ;;(004) OBSOLETE
CWRD (UPT) ;;(005) UPTIME FOR THIS CPU
CWRD (,,1,SHFWRD) ;;(006) TOTAL NUMBER OF WORDS SHUFFLED
CWRD (,,1,STUSER) ;;(007) JOB CURRENTLY USING THE SYSTEM TAPE
;; NEEDED SO CONTROL C WILL NOT TIE UP
;; SYSTEM TAPE
CWRD (,,1,HIGHJB) ;;(010) HIGHEST JOB NUMBER CURRENTLY ASSIGNED
CWRD (,,1,CLRWRD) ;;(011) TOTAL NUMBER OF WORDS CLEARED BY
;; 'CLRCOR' ROUTINE
CWRD (LST,,1,LSTWRD) ;;(012) LOST TIME ON THIS CPU. TOTAL NUMBER
;; OF CLOCK TICKS WHEN NULL JOB RAN BUT
;; OTHER JOBS WANTED TO RUN AND COULD NOT
;; DO SO BECAUSE: --
;; 1. SWAPPED OUT OR ON WAY IN OR OUT
;; 2. MONITOR WAITING FOR I/O TO STOP SO
;; IT CAN SHUFFLE OR SWAP
;; 3. JOB BEING SWAPPED OUT BECAUSE IT IS
;; EXPANDING CORE
CWRD (,,1,MEMSIZ) ;;(013) SIZE OF PHYSICAL MEMORY IN WORDS
CWRD (TPE) ;;(014) TOTAL PARITY ERROR WORDS IN MEMORY
;; DETECTED ON DURING ALL CPU SWEEP WHILE
;; PROCESSOR WAS IN EXEC OR USER MODE.
CWRD (SPE) ;;(015) TOTAL NON-REPRODUCING PARITY ERRORS
;; IN MEMORY. IE ONES WHICH DID NOT
;; REOCCUR WHEN SAME CPU SWEPT THRU CORE.
CWRD (MPC) ;;(016) MEMORY PARITY CONTINUES
;; COUNT OF NUMBER OF TIMES OPERATOR
;; PUSHED CONTINUE AFTER SERIOUS MEMORY
;; PARITY HALT. LH = -1 IF SERIOUS ERROR
;; ON THIS BAD PARITY (MUST HALT)
CWRD (MPA) ;;(017) FIRST BAD PHYSICAL MEMORY ADDRESS
;; FOUND WHEN MONITOR SWEPT THRU CORE
;; AFTER PROCESSOR DETECTED BAD PARITY
CWRD (MPW) ;;(020) MEMORY PARITY WORD. CONTENTS OF FIRST
;; BAD WORD FOUND BY MONITOR WHEN MONITOR
;; SWEPT THRU CORE AFTER FIRST PARITY
CWRD (MPP) ;;(021) PC OF LAST MEMORY PARITY NOT COUNTING
;; SWEEP THRU CORE
CWRD (,,1,EPOCNT) ;;(022) NUMBER OF PDL OVERFLOWS AT UUO LEVEL
;; IN EXEC MODE NOT RECOVERED
CWRD (,,1,EPOREC) ;;(023) NUMBER OF PDL OVERFLOWS AT UUO LEVEL
;; IN EXEC MODE RECOVERED
CWRD (,,1,MAXMAX) ;;(024) HIGHEST LEGAL VALUE OF CORMAX
CWRD (,,1,SYSKTM) ;;(025) KSYS COUNT-DOWN TIMER
CWRD (,,1,CORMIN) ;;(026) LOWER BOUND ON CORMAX. LOKCON WILL
;; NEVER ALLOW CORMAX TO BECOME SMALLER
;; THAN THE CONTENTS OF THIS LOCATION
CWRD (ABC) ;;(027) ADDRESS BREAK COUNT
CWRD (ABA) ;;(030) ADDRESS BREAK ADDRESS
CWRD (LJR) ;;(031) LAST JOB RUN ON THIS CPU. .CPJOB IS
;; COPIED TO .CPLJR WHENEVER JOB IS
;; CHANGED (INCLUDING TO NULL JOB)
CWRD (ODA,,3) ;;(032) OBSOLETE
CCON (NSWMXL,<<.-NSWTBL-1>B26>) ;;MAXIMUM NSWTBL ENTRY
;;NOTE: NO NEW ENTRIES MAY BE ADDED TO NSWTBL
CWRD (STS) ;;(035) STOP TIME SHARING ON THIS CPU.
;; CONTAINS JOB NO. WHICH DID TRPSET UUO.
CWRD (RUN) ;;(036) CPU SCHEDULING BITS (SEE .STRUN)
CWRD (NUL) ;;(037) NULL TIME IN JIFFIES
CWRD (EDI) ;;(040) NUMBER OF EXEC DON'T CARE INTERRUPTS.
;; IE USER ENABLED APR INTERRUPTS WHICH
;; MONITORS CAUSES (AOV,N,FOV).
;; LH = EXEC PC SO WE CAN FIX INEFFICIENT
;; CODE
CWRD (JOB) ;;(041) CURRENT JOB ON THIS CPU. REFERENCED
CWRD (OHT) ;;(042) OVERHEAD TIME IN JIFFIES
CWRD (EVM) ;;(043) MAXIMUM AMOUNT OF EXEC VIRTUAL
;; ADDRESS SPACE ALLOWED TO BE USED FOR
;; MAPPING USER SEGMENTS IN EXEC MODE BY
;; THE LOCK UUO.
CWRD (EVU) ;;(044) TOTAL AMOUNT OF EXEC VIRTUAL ADDRESS
;; SPACE CURRENTLY BEING USED TO MAP
;; USER SEGMENTS.
CWRD (LLC) ;;(045) LOCK LOOP COUNT. NUMBER OF TIMES THE
;; CPU HAS LOOPED WAITING FOR OTHER CPUS
CWRD (TUC) ;;(046) NUMBER. OF UUOS FROM EXEC AND USER
;; MODE SINCE SYSTEM WAS STARTED
CWRD (TJC) ;;(047) NUMBER OF JOB CONTEXT-SWITCHES
;; COUNT FOR THIS CPU INCLUDING NULL JOB
;; NULL JOB SINCE SYSTEM WAS STARTED
CWRD (TNE) ;;(050) TOTAL NXM'S THIS CPU
CWRD (SNE) ;;(051) TOTAL NON-REPRODUCIBLE NXM'S THIS CPU
CWRD (NJA) ;;(052) TOTAL JOBS CRASHED THIS NXM
CWRD (MNA) ;;(053) FIRST ADDRESS FOUND WITH NXM
CWRD (EBJ) ;;(054) EBOX TICKS/JIFFY (ONCE COMPUTED)
CWRD (MBJ) ;;(055) MBOX TICK/JIFFY
CWRD (PBA) ;;(056) PHYSICAL ADDR WITH BAD PARITY ON LAST
;; AR/ARX PARITY TRAP
CWRD (TBD) ;;(057) CONTENTS OF BAD WORD ON LAST AR/ARX
;; PARITY TRAP
CWRD (TGD) ;;(060) GOOD CONTENTS OF WORD AFTER RECOVERED
;; AR/ARX PARITY TRAP
CWRD (NPT) ;;(061) TOTAL NUMBER OF AR/ARX PARITY TRAPS
CWRD (AER) ;;(062) RDERA ON PARITY/NXM INTERRUPT
CWRD (PEF) ;;(063) CONI APR, ON PARITY/NXM INTERRUPT
CWRD (PSB,,4) ;;(064-067) OBSOLETE
CWRD (PPC) ;;(070) PC ON LAST AR/ARX PARITY TRAP
CWRD (PFW) ;;(071) PAGE FAIL WD ON LAST AR/ARX PARITY TRAP
CWRD (HPT) ;;(072) NUMBER OF HARD AR/ARX PARITY TRAPS
CWRD (SAR) ;;(073) NUMBER OF SOFT AR/ARX TRAPS
CWRD (PTP) ;;(074) NUMBER OF PAGE TABLE PARITY TRAPS
CWRD (CSN) ;;(075) NUMBER OF CACHE SWEEPS STARTED (CACHE
;; SWEEP SERIAL NUMBER)
CWRD (CLN) ;;(076) NUMBER OF TIMES SCHEDULER SKIPPED OVER
;; A JOB BECAUSE CACHE SWEEP HAD TO BE
;; DONE FIRST
CWRD (CLT) ;;(077) AMOUNT OF TIME IN JIFFIES THAT CPU RAN
;; NULL JOB BECAUSE OF STATE OF CACHE
CWRD (CSD) ;;(100) CACHE - SWAPPER DELAY COUNT-INCREMENT
;; ON 1088 SYSTEMS IF SWAPPER HAS TO WAIT
;; FOR ANOTHER CPU TO SWEEP ITS CACHE
;; BEFORE IT CAN START I/O
CWRD (CRN) ;;(101) CACHE SWEEP REQUEST SWEEP COUNT (SIC)
;; COMMANDING THIS VALUE TO .CPCSD+.CPCLN
;; (NUMBER OF SWEEP REQUESTS MADE) WILL
;; INDICATE TO WHAT EXTENT THE REQUEST
;; SCHEME IS A BOTTLENECK
CWRD (CEC) ;;(102) COUNT OF NON-RECOVERABLE AR/ARX
;; PARITY ERRORS WHICH INVOLVED CACHE.
;; AFTER 3 SUCH FAILURES CACHE IS TURNED
;; OFF IN TRAP ROUTINE WITH APPROPRIATE
;; MESSAGE TO OPERATOR.
CWRD (PTR) ;;(103) RETRY WORD FOR AR/ARX PARITY TRAP
;; ROUTINE. INCLUDES STATUS FLAGS IN LH
;; AND RETRY COUNT IN RH.
CWRD (TSD) ;;(104) AR/ARX TRAP ROUTINE HAS ALREADY
;; SAVED APR/ERA/SB DIAGS ETC FOR ERROR
;; REPORTING. WON'T BE DONE AGAIN AT
;; APR INTERRUPT.
CWRD (REP) ;;(105) USED BY PARITY/NXM RECOVERY ROUTINES
;; TO DETERMINE WHICH TYPE ERRORS SHOULD
;; BE LISTED.
CWRD (NDB) ;;(106) NUMBER OF TIMES CPU'S DOORBELL WAS RUNG
CWRD (SBR) ;;(107) CPU/DEVICE STATUS BLOCKS READ
;; LH = UNUSED
;; RH = BITS TELLING WHICH STATUS BLOCKS
;; HAVE BEENREAD ON THIS CPU.
CWRD (BPF) ;;(110) BACKGROUND PERFORMANCE ANALYSIS FLAG
;; .LT. 0 IF METER ENABLED (SINCE COUNTED
;; UP AT CLOCK LEVEL ON EACH CPU.
;; PROGRAMS SHOULD CHECK FOR .LE. 0)
CWRD (FBI) ;;(111) FILE BLOCKS INPUT (READ)
CWRD (FBO) ;;(112) FILE BLOCKS OUTPUT (WRITTEN)
CWRD (SBI) ;;(113) SWAPPING BLOCKS INPUT (READ)
CWRD (SBO) ;;(114) SWAPPING BLOCKS OUTPUT (WRITTEN)
CWRD (SNC) ;;(115) NUMBER OF CPU STOPCDS
CWRD (SND) ;;(116) NUMBER OF DEBUG STOPCDS
CWRD (SNJ) ;;(117) NUMBER OF JOB STOPCDS
CWRD (SJN) ;;(120) JOB NUMBER OF LAST STOPCD
CWRD (SNM) ;;(121) NAME OF LAST STOPCD
CWRD (SPN) ;;(122) PROGRAM RUNNING AT LAST STOPCD
CWRD (SPP) ;;(123) PPN RUNNING AT LAST STOPCD
CWRD (STN) ;;(124) TTY NAME AT LAST STOPCD
CWRD (SUP) ;;(125) USER PC AT TIME OF LAST STOPCD
CWRD (SUU) ;;(126) UUO AT TIME OF LAST STOPCD
CWRD (EJN) ;;(127) JOB NUMBER AT LAST PARITY/NXM ERROR
CWRD (EPN) ;;(130) PROGRAM NAME AT LAST PARITY/NXM ERROR
CWRD (PPI) ;;(131) CONI PI, ON PARITY/NXM INTERRUPT
CWRD (TPI) ;;(132) CONI PI, ON PARITY/NXM TRAP
CWRD (RSI) ;;(133) NUMBER OF TIMES SCHEDULER INTERLOCK WAS
;; REQUESTED WHEN NOT OWNED
CWRD (TFI) ;;(134) NUMBER OF TAPE FRAMES READ
CWRD (TFO) ;;(135) NUMBER OF TAPE FRAMES WRITTEN
CWRD (SNI) ;;(136) NUMBER OF NODUMP STOPCDS
CWRD (STY) ;;(137) TYPE OF LAST STOPCODE
CWRD (SDT) ;;(140) UDT OF LAST STOPCODE ON THIS CPU
;;**********************************************************************
;;PUT NEW PUBLISHED VARIABLES ABOVE HERE
;;**********************************************************************
;;PUT NEW PUBLISHED SUBTABLES BELOW HERE (SO LAST BUT STILL
;;**********************************************************************
;; INSIDE LEGAL RANGE OF VARIABLE GETTAB FOR THIS CDB
;;**********************************************************************
;;RESPONSE SUBTABLE, POINTED TO BY .CPRSP
IFN FTRSP,<
;;INDICIES INTO 3 WORD BLOCKS:
RSPAXR==:0 ;;ACCUMULATE SUM OF RESPONSE
RSPNXR==:1 ;;NO. OF RESPONSES
RSPHXR==:2 ;;SUM OF SQUARES OF RESPONSE(HIGH ORDER HALF)
RSPLXR==:3 ;;SUM OF SQUARES OF RESPONSE(LOW ORDER HALF)
CWRD (AOR) ;;(R00) ACCUMULATED TTY OUTPUT UUO RESPONSE.
;; NUMBER. OF JIFFIES USERS HAVE SPENT
;; FOR THEIR JOBS TO DO A TTY OUTPUT UUO
;; AFTER TYPING INPUT (COMMAND OR USER
;; TTY)
CWRD (NOR) ;;(R01) NUMBER OF TTY OUTPUT UUO RESPONSES
CWRD (HOR) ;;(R02) SUM OF SQUARES OF TTY OUTPUT UUO
;; RESPONSES - HIGH ORDER WORD
CWRD (LOR) ;;(R03) SUM OF SQUARES OF TTY OUTPUT UUO
;; RESPONSES - LOW ORDER WORD
CWRD (AIR) ;;(R04) ACCUMULATED TTY INPUT UUO RESPONSES.
;; NUMBER OF JIFFIES USERS SPENT WAITING
;; FOR THEIR JOBS TO DO A TTY INPUT UUO
;; AFTER TYPING INPUT (COMMAND OR USER
;; TTY)
CWRD (NIR) ;;(R05) NUMBER OF TTY INPUT UUO RESPONSES
CWRD (HIR) ;;(R06) SUM OF SQUARES OF TTY INPUT UUO
;; RESPONSES - HIGH ORDER WORD
CWRD (LIR) ;;(R07) SUM OF SQUARES OF TTY INPUT UUO
;; RESPONSES - LOW ORDER WORD
CWRD (ARR) ;;(R10) ACCUMULATED CPU QUANTUM REQUE RESPONSES
;; NUMBER OF JIFFIES USERS SPENT WAITING
;; FOR THEIR JOBS TO EXCEED CPU QUANTUM
;; AFTER TYPING INPUT (COMMAND OR USER
;; TTY)
CWRD (NRR) ;;(R11) NUMBER OF CPU QUANTUM REQUEUE RESPONSES
CWRD (HRR) ;;(R12) SUM OF SQUARES OF CPU QUANT. REQUEUE
;; RESPONSES - HIGH ORDER WORD
CWRD (LRR) ;;(R13) SUM OF SQUARES OF CPU QUANT. REQUEUE
; RESPONSES - LOW ORDER WORD
CWRD (AXR) ;;(R14) ACCUMULATED RESPONSE TERMINATED BY
;; FIRST OF ABOVE 3 EVENTS (TTY OUTPUT
;; UUO,N, TTY INPUT UUO, OR CPU QUANTUM
;; REQUE)
CWRD (NXR) ;;(R15) NUMBER OF SUCH RESPONSES
CWRD (HXR) ;;(R16) SUM OF SQUARES OF ANY OF ABOVE - HIGH
;; ORDER WORD
CWRD (LXR) ;;(R17) SUM OF SQUARES OF ANY OF ABOVE - LOW
;; ORDER WORD
CWRD (ACR) ;;(R20) ACCUMULATED CPU RESPONSE. NUMBER OF
;; JIFFIES USERS HAVE SPENT WAITING FOR
;; THIS CPU
CWRD (NCR) ;;(R21) NUMBER OF CPU RESPONSES ON THIS CPU
CWRD (SCR) ;;(R22) HIGH ORDER WORD OF SQUARE OF CPU
;; RESPONSES
CWRD (SCL) ;;(R23) LOW ORDER WORD
CWRD (FADL) ;;(R24) NUMBER OF FADL INSTRUCTIONS SIMULATED
CWRD (FSBL) ;;(R25) NUMBER OF FSBL INSTRUCTIONS SIMULATED
CWRD (FMPL) ;;(R26) NUMBER OF FMPL INSTRUCTIONS SIMULATED
CWRD (FDVL) ;;(R27) NUMBER OF FDVL INSTRUCTIONS SIMULATED
CWRD (UFA) ;;(R30) NUMBER OF UFA INSTRUCTIONS SIMULATED
CWRD (DFN) ;;(R31) NUMBER OF DFN INSTRUCTIONS SIMULATED
CWRD (NRI) ;;(R32) NUMBER OF CHARS (EXCLUDING MIC)RECEIVED
CWRD (NXI) ;;(R33) NUMBER OF CHARS(INCLUDING FILL)XMITTED
CWRD (NEI) ;;(R34) NUMBER OF CHARS ECHOED
CCON (.CPRSL,<.-.C0AOR>) ;;SUBTABLE LENGTH
> ;;END FTRSP
;;MORE MEMORY PARITY ANALYSIS SUBTABLE, POINTED TO BY .CPPAR
CWRD (LPA) ;;(R00) LAST (HIGHEST) BAD MEM PARITY ADDRESS
;; ON LAST SWEEP OF MEMORY. USED TO TELL
;; OPERATOR RANGE OF BAD MEMORY
CWRD (MPR) ;;(R01) RELATVE. ADDRESS (NOT VIRTUAL) IN HIGH
;; OR LOW SEG OF LAST MEMORY PARITY ERROR
CWRD (PTS) ;;(R02) NUMBER OF PARITY ERROR THIS (LAST)
;; SWEEP OF CORE SET TO ZERO AT BEGNING
;; OF SWEEP
CWRD (PSC) ;;(R03) NUMBER OF PARITY SWEEPS BY MONITOR
CWRD (UEP) ;;(R04) NUMBER OF USER ENABLED PARITY ERRORS
CWRD (PAA) ;;(R05) AND OF BAD ADDRESSES THIS (LAST)
;; MEMORY PARITY SWEEP
CWRD (PAC) ;;(R06) AND OF BAD CONTENTS THIS (LAST)
;; MEMORY PARITY SWEEP
CWRD (POA) ;;(R07) OR OF BAD ADDRESSES THIS (LAST)
;; MEMORY PARITY SWEEP
CWRD (POC) ;;(R10) OR OF BAD CONTENTS THIS (LAST)
;; MEMORY PARITY SWEEP
CWRD (PCS) ;;(R11) NUMBER OF SPURIOUS PARITY ERRORS (APR
;; SWEEP FOUND NO BAD PARITY BUT CHANNEL
;; HAD REQUESTED SWEEP RATHER THAN
;; PROCESSOR. THIS INDICATES A CHANNEL
;; MEMORY PORT PROBLEM.
CWRD (MET) ;;(R12) MOS ERROR TIMER
CWRD (MEC) ;;(R13) MOS ERROR COUNTER
CWRD (TME) ;;(R14) TOTAL MOS ERRORS
CCON (.CPPRL,<.-.C0LPA>) ;;SUBTABLE LENGTH
;;BAD ADDRESS SUBTABLE, POINTED TO BY .CPPAR
CWRD (BAT,,M.CBAT) ;;(R00) TABLE OF BAD ADDRESSES ON LAST
;; MEMORY PARITY SWEEP. NOT CLEARED SO
;; NUMBER OF VALID ENTRIES KEPT IN .CPPTS
;;MEMORY NXM SUBTABLE, POINTED TO BY .CPNMT
CWRD (LNA) ;;(R00) LAST NXM ADDRESS
CWRD (MNR) ;;(R01) LAST NXM RELATIVE ADDRESS
CWRD (NTS) ;;(R02) NUMBER OF NXM'S FOUND THIS SWEEP
CWRD (NSC) ;;(R03) NUMBER OF NXM SWEEPS DONE
CWRD (UEN) ;;(R04) NUMBER OF USER ENABLED NXM'S
CWRD (NAA) ;;(R05) LOGICAL AND OF BAD ADDRESSES
CWRD (NOA) ;;(R06) INCLOSIVE OR OF BAD ADDRESSES
CWRD (NCS) ;;(R07) NUMBER OF SPURIOUS CHANNEL NXM'S
CCON (.CPNML,<.-.C0LNA>) ;;SUBTABLE LENGTH
;KS10 SOFT MEMORY ERROR TABLE POINTED TO BY .CPMSS
IFN M.KS10,<
CWRD (SME) ;;(R00) NUMBER OF SOFT MEMORY ERRORS
CWRD (SMS) ;;(R01) MEM STATUS REGISTER AT LAST SOFT ERROR
CWRD (HME) ;;(R02) NUMBER OF HARD MEMORY ERRORS
CWRD (HMS) ;;(R03) MEM STATUS REGISTER AT LAST HARD ERROR
CCON (.CPSML,<.-.C0SME>) ;;SUBTABLE LENGTH
CWRD (SMC) ;;NUMBER OF SOFT MEMORY ERRORS IN LAST MINUTE
>;; END IFN M.KS10
;APR STATUS SUBTABLE
CWRD (APD,,1,VERSTS) ;;(R000) APRID
CWRD (ACN,,1,APRSTS) ;;(R001) CONI APR,
CWRD (PIC,,1,PISTS) ;;(R002) CONI PI,
CWRD (PGD,,1,UPTSTS) ;;(R003) DATAI PAG,
CCON (LENSTS,<UPTSTS-VERSTS>) ;;SUBTABLE LENGTH
CWRD (PGC,,1,EPTSTS) ;;(R004) CONI PAG,
CWRD (UP0,,4) ;;(R005-R010) UPT LOCS 424-427
CWRD (ERA,,1,ERASTS) ;;(R011) RDERA
CWRD (RHC,,8) ;;(R012-R021) CONI RH20, FOR ALL RH20'S
CWRD (DTC,,4) ;;(R022-R025) CONI DTEN,
CWRD (EP0,,40) ;;(R026-R065) EPT LOCATIONS 0-37
CWRD (EP1,,40) ;;(R066-R125) EPT LOCATIONS 140-177
CWRD (UP1,,4) ;;(R126-R131) UPT LOCS 500-503
CWRD (6,,5) ;;(R132-R136) AC BLOCK 6 REGS 0-3 AND 12
CWRD (7,,3) ;;(R137-R141) AC BLOCK 7 REGS 0 THROUGH 2
IFN M.KL10,<
;;IN ADDITION TO BEING A PART OF THE CPU STATUS BLOCK SUBTABLE, THE
;;SBDIAG BLOCK IS A CDB SUBTABLE IN ITS OWN RIGHT. POINTER IS .CPSDP.
CWRD (SBD,,50) ;;(R142-R211) SBDIAG DATA
CCON (.CPSDL,<.-.C0SBD>) ;;SUBTABLE LENGTH
> ;END IFN M.KL10
CCON (.CPCSL,<.-.C0APD>) ;;SUBTABLE LENGTH
;;DEVICE STATUS BLOCK ENTRY FOR DEVICES ON THIS CPU. THE ORDER OF THESE
;;ENTRIES MUST EXACTLY MATCH THE ORDER OF THE INSTRUCTIONS IN DVSXCT THAT
;;FILL THE ENTRIES.
CWRD (DVS,,0) ;;START OF DEVICE STATUS SUBTABLE
IFN M.KL10,<
CWRD (TMR)
CWRD (MTR)
CWRD (TTY)
CWRD (PRA)
CWRD (PPA)
CWRD (DLS)
CWRD (DAC)
CWRD (DAS)
CWRD (CRA)
CWRD (LPT)
CWRD (PLA)
CWRD (TMS)
CWRD (TMC)
CWRD (DX1)
CWRD (DSK)
CWRD (FH2)
CWRD (FSD)
CWRD (FS2)
CWRD (FS3)
CWRD (DPC)
CWRD (DP2)
CWRD (DP3)
CWRD (DP4)
CWRD (2DS)
CWRD (2DC)
CWRD (DLC)
CWRD (DLB)
CWRD (DC2)
CWRD (DB2)
CWRD (CDP)
CWRD (CRB)
CWRD (LPB)
CWRD (LPC)
CWRD (PLB)
CWRD (DAK)
CWRD (DDK)
CWRD (DH2)
CWRD (DFS)
CWRD (DS2)
CWRD (DS3)
CWRD (DDP)
CWRD (DD2)
CWRD (DD3)
CWRD (DD4)
CWRD (DDC)
CWRD (DDB)
CWRD (D2C)
CWRD (D2B)
CWRD (IVI,,10)
> ;;END IFN M.KL10
IFN M.KS10,<
CWRD (TMR)
CWRD (TMB,,2)
CWRD (UB1)
CWRD (UB3)
CWRD (RH1,,2)
CWRD (RH3,,2)
CWRD (LPT,,2)
CWRD (CDR)
CWRD (PRA)
CWRD (PPA)
CWRD (RXA)
> ;;END IFN M.KS10
CCON (.CPDVL,<.-.C0DVS>) ;;SUBTABLE LENGTH
IFN M.KL10&FTRSP,<
CWRD (BPV,,<<BPATLN*4>>) ;;KL10 BACKGROUND PERFORMANCE NUMBERS
;; EACH ENTRY IS 4 WORDS LONG
;; 0'1 := RDTIME TOTAL ELAPSED TIME
;; 2'3 := TOTAL PERF METER COUNT
> ;;END IFN M.KL10&FTRSP
;;***********************************************************************
;;INSERT NEW SUB TABLES JUST ABOVE HERE - SO AT END OF VARIABLE TABLE
;;INSERT NEW VARIABLES A FEW PAGES BACK - SO NEXT TO OTHER VARIABLES
;;***********************************************************************
CCON (.CPPVL,<<.-.C0VBG>B26>) ;;PUBLISHED CPU DEPENDANT VARIABLE LENGTH
;;UNPUBLISHED CPU DEPENDENT VARIABLES:
CWRD (ADR,,1,JOBADR) ;;XWD PROTECTION, RELOCATION FOR CURRENT
;; JOB SAME AS JBTADR(JOB) AND AC R
CWRD (REL) ;;LH==0, RH CONTAINS CONTENTS OF PROTECTION
;; REGISTER LOW ORDER BITS==1777 (HIGHEST
;; RELATIVE LOC IN CURRENT USER AREA)
CWRD (PC,,2) ;;JOB PC WHEN SCHEDULER IS CALLED
XP USRPRT,JOBPRO
XP USRPR1,,USRPRT+1
XP USRHCU,USRPRT
XP USRPC,USRHCU+1
IFN FTMP,<IFE USRHCU&777770-USRPC&777770,<PRINTX ?USRHCU AND USRPC FALL IN THE SAME CACHE LINE (SEE PDLLEN IN S)>>
XP USRDDT,USRPC+2 ;THIS DEPENDS ON JOBDDT-JOBPC=1
XP USRJDA,USRDDT+1
XP USRLO,USRJDA ;FIRST LOC CLEARED BY SETUSR ROUTINE
; ON A CALL RESET. - ALSO CLEARS USRHCU
XP USRLO1,USRLO+1 ;FIRST LOC+1
XP USRHI,USRJDA+17 ;LAST LOC CLEARED BY SETUSR ROUTINE
CWRD (XTM) ;;TIME OF LAST SWITCH FROM MONITOR CYCLE TO
;; OR VICE VERSA IN (SECONDS*RTCSEC)
CWRD (QNT) ;;CURRENT QUANTUM RUN TIME. FORCE CPUTIM TO
;; WHEN NEGATIVE TO RECOMPUTE ACTUAL QUANTUM
;; RUN TIME LEFT
CWRD (LS2) ;;ADDITIONAL LOST TIME, IN JIFFIES*RTCSEC
;; BEYOND LAST JIFFY
CWRD (NL2) ;;ADDITIONAL NULL TIME, IN JIFFIES*RTCSEC
;; BEYOND LAST JIFFY
CWRD (OH2) ;;ADDITIONAL OVERHEAD TIME, IN JIFFIES*RTCSEC
;; BEYOND LAST JIFFY
CWRD (TNT) ;;TIME INTERVAL (TICKS)SINCE LAST @ CLOCK LEVEL
CWRD (HTM) ;;HUNG DEVICE TIME CHECK FOR HUNG IO
CWRD (SEC) ;;NUMBER OF SECONDS LEFT BEFORE DOING ONCE A
;; MINUTE CODE
IFN FTRTTRP,<
CWRD (RCU,,6) ;;COUNT OF REAL TIME CONSO'S ON SKIP CHAIN
CWRD (RIT,,6) ;;REAL TIME INITIALIZATION TABLE
CWRD (DMI) ;;REAL TIME DISMISS INSTRUCTION FOR CURRENT
;; INTERRUPT
> ;;END IFN FTRTTRP
;SCHEDULER FLAGS:
CWRD (CKF,,1,CLKFLG) ;;;NON-ZERO WHEN CLK INTERRUPT (PI7) REQUESTED
;; FOR ANY REASON
CWRD (TMF,,1,TIMEF) ;;NON-ZERO WHEN APR CLOCK TICKED ON THIS CPU.
;; SET SO CLOCK INTERRUPT ROUTINES WILL KNOW
;; ANOTHER JIFFY HAS PASTED. SET BY APRINT,
;; TESTED AND CLEARED BY CLKINT MODULE.
CWRD (SCF) ;;NON-ZERO AS A FLAG TO CLK ROUTINE TO FORCE
;; RESCHEDULING, ON THIS CPU, EVEN THOUGH
;; ITS CURRENT JOB IS IN EXEC MODE. CAN HAPPEN
;; ON MONITOR DETECTED ERRORS.
CWRD (CHT) ;;CLOCK HAS TICKED, START QUEUED I/O.
CWRD (RTF,,1,SCDRTF) ;;NON-ZERO ON REAL TIME RESCHEDULE REQUIRED
;; REALLY A SYSTEM VARIABLE
CWRD (ISF) ;;NON-ZERO IF IN THE SCHEDULAR OR WHEN IN
;; COMCON CONTAINS THE STACK POINTER JUST
;; BEFORE COMMAND DISPATCH
CWRD (SUD) ;;SCAN USED FOR THIS SCHEDULING SCAN
IFN FTHPQ!FTNSCHED,<
CWRD (HQU) ;;NON-ZERO IF CURRENT JOB ON THIS CPU DID A
;; HPQ UUO TO FORCE RESCHEDULING TO THE NEW HPQ
> ;;END IFN FTHPQ!FTNSCHED
CWRD (PLT) ;;POTENTIALLY LOST (WASTED) CLOCK TICK ON
;; THIS CPU IF NON-ZERO. NON-ZERO WHEN
;; SCHEDULER SEES THAT THERE ARE JOBS WHICH ARE
;; POTENTIALLY RUNABLE ON THIS CPU BUT HAS TO
;; RUN NULL JOB. ZERO WHEN IT FINDS A REAL
;; JOB TO RUN OR NULL JOB IS ONLY JOB WHICH
;; WANTS TO RUN ON THIS CPU.
IFN FTKL10,<
IFN FTMP,<
CWRD (CLF) ;;POTENTIAL CACHE LOST TIME FLAG (SEE .CPCLN)
CWRD (CL2) ;;LOW ORDER CACHE LOST TIME IN RTUPS UNITS
CWRD (SDA) ;;NUMBER OF TIMES CACHE WAS SWEPT BECAUSE OF
;; CORE DEALLOCATION
> ;;END IFN FTMP
CWRD (CSR) ;;CACHE SWEEP REQUEST FLAG IF .GE. CURRENT
;; SWEEP SERIAL NUMBER, MUST SWEEP AT CH7
;; LEVEL FOR ANOTHER CPU
CWRD (CSW) ;;SWEEP SERIAL NUMBER TO WAIT FOR
> ;;END IFN FTKL10
CWRD (AEF) ;;APR ERROR FLAG ON THIS CPU. CONTAINS APR
;; CONI IF NULL JOB WAS CURRENT JOB ON THIS
;; CPU WHEN APR ERROR OCCURRED SO COULD NOT
;; STORE IN JOB DATA AREA.
;; LEFT HALF USED FOR MEMORY PARITY CONTROL
;; TO REQUEST PARITY SWEEPS AND PRINTING.
CWRD (SAC) ;;SAVED COPY OF .CPAEF
CWRD (APC,,2) ;;APR ERROR PC ON THIS CPU WHEN ERROR WHILE
;; NULL JOB WAS CURRENT JOB ON THIS CPU.
CWRD (MDP,,2) ;;MEMORY PARITY ERROR DOUBLE WORD PC
CWRD (PPD,,2) ;;AR/ARX TRAP DOUBLE WORD PC
CWRD (NJE) ;;ERROR IN NULL JOB HAS OCCURRED IF NON-ZERO
CWRD (SFC) ;;SCHEDULER FAIRNESS COUNT. COUNT OF THE NUMBER
;; OF SCANS OF THE PRIMARY SCAN TABLE WITHOUT
;; GETTING TO THE LOWER QUEUES IN THE TABLE.
CWRD (SQF) ;;NON-ZERO IF CURRENT JOB WAS TAKEN FROM
;; SUBQUEUES
CWRD (APR) ;;CONI APR INTO THIS LOCATION TO READ THE
;; STATE OF MI PROG DIS SWITCH
IFN M.KL10,<
CWRD (IPI) ;;INTERVAL TIMER PI ASSIGNMENT
CWRD (DTT) ;;MINUTES TILL NEXT SEND DATE/TIME TO -20F
CWRD (EPW,,4) ;;SAVED DTE EXAMINE/PROTECTION WORD
;;EXEC MODE ADDRESS BREAK SCRATCH PATCH STORAGE
CWRD (ABF) ;;FLAGS (STOPCODE TYPE + CPU MASK)
CWRD (ABI) ;;INSTRUCTION TO XCT
CWRD (ABW) ;;ADDRESS BREAK WORD (CONDITIONS + ADDRESS)
CWRD (ABS,,S$MAXL) ;;STOPCODE
> ;;END IFN M.KL10
;PROCESSOR DEPENDENT VARIABLES FOR APR INTERRUPTS
CWRD (CN1) ;;CONTAINS CONSO MASK FOR APR INTERRUPTS,
CWRD (HRP) ;;LAST DATAO OUT TO SET HARDWARE RELOCATION
;; AND PROTECTION FOR THIS CPU.
CWRD (SP,,2) ;;PLACE TO SAVE P ON APR INTERRUPT
CWRD (S17,,2) ;;PLACE TO SAVE AC 17 ON CLK INTERRUPT
;MEMORY PARITY ANALYSIS VARIABLES
CWRD (A00,,17) ;;FIRST WORD TO STORE AC0 ON PARITY SWEEP ON
;; APR PI
CWRD (A17) ;;LAST WORD TO STORE AC17 ON PARITY SWEEP AT
;; APR PI
CWRD (LPP) ;;LAST MEM PARITY PC USED TO DETECT PI DISMISS
;; LOOPS
CWRD (LSB) ;;LAST SEG (HI OR LOW) WHICH IS (WAS) BLTED
;; USED TO DETECT BAD PARITY DURING BLT
CWRD (LCI) ;;TIME OF LAST PAR/NXM INTERRUPT CAUSED BY A
;; CHANNEL REFERENCE
CWRD (PIP) ;;POINTER TO REAL INTERRUPT PC
CWRD (PSP) ;;PARITY/NXM SWEEP IN PROGRESS
CWRD (CHE) ;;CHANNEL ERROR REPORTING IN PROGRESS
CWRD (TCX) ;;DATAI PAG, ON ERROR TRAP
CWRD (PFT) ;;PRE-EMPTIVE PAGE FAULT HANDLER (SEE SEILM)
IFN M.KL10,<
CWRD (TCT) ;;TRIAD COUNTER FOR 60HZ LEAP JIFFIES
CWRD (PJB) ;;JOB WHO OWNS PERFORMANCE METER (ZERO IF FREE)
CWRD (MJB) ;;MEASURED JOB (JOB ENABLE OF PERF. UUO)
;; -2 = NULL JOB, 0 = DON'T CARE
CWRD (MJ1) ;;JOB ENABLE CONDITION SET ONLY WHEN METER
;; IS RUNNING. (SEE APRSER)
CWRD (PMR) ;;NONZERO MEANS PERFORMANCE METER IS RUNNING
CWRD (PAE) ;;USED TO STORE PERFORMANCE ANALYSIS ENABLES
CWRD (PRQ) ;;SEMAPHORE USED TO TEST/GIVE METER AWAY
CWRD (APS) ;;NON ZERO MEANS ACCOUNTING AND PERFORMANCE
;; METERS SHOULD BE KEPT IN SYNC
CWRD (MM0) ;;"VIRTUAL PERFORMANCE METER" HIGH ORDER
;; MEMORY REFERENCE COUNT
CWRD (MM1) ;;"VIRTUAL PERFORMACE METER" LOW ORDER
;; MEMORY REFERENCE COUNT
CWRD (BPC) ;;BACKGROUND PERF ANAL SAMPLE INTERVAL (TICKS)
CWRD (BPI) ;;B.P.A. SAVED PACTAB INDEX
CWRD (BPT,,2) ;;B.P.A. SAVED RDTIME AT START OF SAMPLE
CWRD (TIM) ;;CLOCK INTERRUPT FLAG
CWRD (ETM) ;;SOSN DONE ON THIS LOCATION EVERY MINUTE TO
;; MAKE SURE CHUNKS DON'T STAY ALLOCATED
;; FOREVER IN THE CASE THAT DAEMON IS SICK,
;; WRONG VERSION, ETC.
CWRD (EAD) ;;LH = ADDRESS OF LAST KL ERROR CHUNK
;;RH = ADDRESS OF FIRST CHUNK
CWRD (KPB,,<<KPSLEN+3>/4>) ;;KLINIK PARAMETER BUFFER
CWRD (20F) ;;LH = FLAGS ABOUT RSX-20F FRONT END
;;RH = COUNT OF CHARACTERS CURRENTLY BEING
;; OUTPUT
CWRD (20S,,2) ;;SPACE FOR INCOMING LINE SPEEDS
CWRD (20B,,<<TTDMOS+3>/4>) ;;BUFFER FOR 16BIT DATA TO 20F
CWRD (20D) ;;CHAIN OF DEVICE STATUS MESSAGES
;;LOCATIONS USED BY CPU HARDWARE ERROR RECOVERY
CWRD (PTH) ;;AR/ARX TRAP HAPPENED DURING PARITY SWEEP
CWRD (STE) ;;ERA CONTENTS ON SWEEP TRAP
CWRD (PTF) ;;COUNT OF PAGE TABLE PARITY TRAPS BETWEEN
;; CLOCK TICKS USED TO CRASH SYSTEM IF TOO HIGH
CWRD (IOP) ;;API FUNCTION WORD ON I/O PAGE FAIL INTERRUPT
CWRD (IPG) ;;DATAI PAG, ON I/O PAGE FAIL INTERRUPT
CWRD (73) ;;CONTENTS OF AC BLOCK 7, AC 3 (IOP FNC WORD)
CWRD (CA1,,20) ;;POWER FAIL AC BLOCK SAVE AREA, ALSO AC BLOCK
;; 1 ON A CRASH
CWRD (CA2,,20) ;;AC BLOCK 2
CWRD (CA3,,20) ;;AC BLOCK 3
CWRD (CA4,,20) ;;AC BLOCK 4
> ;;END IFN M.KL10
IFN M.KS10,<
CWRD (TCT) ;;TRIAD COUNTER FOR 60HZ LEAP JIFFIES
CWRD (TIM) ;;CLOCK INTERRUPT FLAG FOR KS10S
CWRD (PTH) ;;HARD PARITY TRAP HAPPENED DURING PARITY SWEEP
CWRD (PTF) ;;COUNT OF PAGE TABLE PARITY TRAPS BETWEEN
;; CLOCK TICKS USED TO CRASH SYSTEM IF TOO HIGH
CWRD (LMC) ;;LEAP MILLISECOND COUNT FOR 4.1 MHZ CLOCK RATE
CWRD (CA1,,20) ;;POWER FAIL AC BLOCK SAVE AREA, ALSO AC BLOCK
; 1 ON A CRASH
CWRD (CA2,,20) ;;AC BLOCK 2
CWRD (CA3,,20) ;;AC BLOCK 3
CWRD (CA4,,20) ;;AC BLOCK 4
> ;;END IFN M.KS10
CWRD (CTQ,,2) ;;SCNSER OUTPUT QUEUE HEADER FOR CTY AND
;; RSX-20F LINES
CWRD (SWP) ;;NON-0 IF SWAP REQUEST TO BE CHECKED FOR AT
;; CLOCK LEVEL
IFN FTMP,<
CWRD (QUE) ;;QUEUE FOR IO REGS ON OTHER CPUS EMPTIED INTO
;; CPUDSQ ONCE A TICK
CWRD (QND) ;;END OF QUEUE ABOVE
CWRD (SWD) ;;FLAG FOR FILIO CACHE SWEEPS
CWRD (DRQ) ;;DISKS ON CPU NEED RECUING
CWRD (TAP) ;;0 IF NO TAPE IO WAITING FOR SWEEP
;;-1 IF TAPE IO WAITING, NEEDS SWEEP
;;0,,-1 IF TAPE WAITING, DSKTIC DID SWEEP
> ;;END IFN FTMP
IFN M.KL10,<
CWRD (PIB) ;;SAVE PI STATE FOR NBFOFF
> ;;END IFN M.KL10
CWRD (PIS) ;;SAVE PI STATE FOR SYSPIN
CWRD (DPI) ;;SAVE PI STATE FOR DEVPIN
CWRD (BTI) ;;SAVE PI STATE FOR BTSOFF
CWRD (SCI) ;;SAVE PI STATE FOR SCNOFF
CWRD (NTI) ;;SAVE PI STATE FOR NETOFF
CWRD (DBI) ;;SAVE PI STATE FOR DDBSRL
CWRD (IUT) ;;UPTIME A SECOND AGO
IFN FTNET,<
CWRD (NTF) ;;DEFINE THE ONE SOFTWARE INTERRUPT FLAG
> ;;END IFN FTNET
IFN M.EQDQ,<
QDBLEN==:23 ;;LENGTH OF QUESER DATABASE
CWRD (QTS,,QDBLEN) ;;QUESER VARIABLES
> ;;END IFN M.EQDQ
CWRD (CPG) ;;DATAI PAG, DONE BY SVSETS WITH BITS
;;SET SO THAT DATAO WILL RESTORE CURRENT AC
CWRD (ACA) ;; SET ADDRESS OF 20 WORD BLOCK IN WHICH
;; SVSETS SAVED THE CURRENT AC SET
CWRD (KPM) ;;CONTAINS PM.KPM IF CPU HAS AN MCA25 INSTALLED
CWRD (PMV) ;;NON-ZERO IF MICROCODE SUPPORTS PHYSICAL
;; MOVE/MOVEM INSTRUCTIONS
CWRD (JCH) ;;JOB/CONTEXT HANDLE FOR JOB ON THIS CPU
CWRD (CXJ) ;;JOB OWNING CX ON THIS CPU
IFN M.KL10,<
CWRD (DSN,,<<^D<8*2>+4>/4>) ;;;CONSOLE FRONT-END DISK DRIVE SERIAL NUMBERS
> ;;END IFN M.KL10
CWRD (EMU,,2) ;;+0 = PDL FOR CALLING DIE
;;+1 = SAVED P BEFORE CALLING DIE
IFN FTPATT,<
CWRD (PAT,,10) ;;PATCH SPACE
> ;;END IFN FTPATT
;;**********************************************************************
;;PUT NEW UNPUBLISHED VARIABLES ABOVE HERE
;;**********************************************************************
.C'N'END==:.
;;BEGINNING OF SPECIAL PER-CPU MAPPINGS. THESE VIRTUAL ADDRESSES APPEAR IN
;; SECTION 37 AND MUST BE LOCATED CORRESPONDING TO THEIR VIRTUAL ADDRESSES.
;; ADD NEW MAPPINGS ABOVE THIS ADJUSTING THE LOC STATEMENTS APPROPRIATELY.
IFN FTXMON,<
IFG <<.&PG.BDY> - MMAPS/PAGSIZ>,<LOC <.+PG.BDY>&777000>
LOC .&777000 + MMAPS/PAGSIZ
CWRD (MMA,,<MXSECN+1>) ;;MAP SLOTS FOR ALL MONITOR SECTION MAPS
> ;;END IFN FTXMON
IFG <<.&PG.BDY> - UMAPS/PAGSIZ>,<LOC <.+PG.BDY>&777000>
LOC .&777000 + UMAPS/PAGSIZ
CWRD (UMA,,<MXSECN+1>) ;;MAP SLOTS FOR ALL USER SECTION MAPS
> ;END OF CDB MACRO
IFN XPANDN,<LALL>
ZZZ==0
LOC <.+PG.BDY>&777000
REPEAT M.CPU,<
CDB(\ZZZ)
LOC <.+PG.BDY>&777000
IFE ZZZ,<.CPLEN==:.-.C0CDB> ;LENGTH OF CDB
ZZZ==ZZZ+1
>; END REPEAT M.CPU
.CPVLN==.-.C0VBG ;LENGTH OF VARIABLE AREA
.C0EVA==:.C0CDB+.CPLEN ;END OF CPU 0 VARIABLE AREA
CDBPGS==:.CPLEN/PAGSIZ ;LENGTH OF CDB IN PAGES
.EVCDB==:<FYSORG-<EVAPGS*PAGSIZ>>-.CPLEN ;EXEC VIRTUAL ADDRESS OF CDB
HLCSAD==:.EVCDB ;HIGHEST LEGAL CODE SECTION ADDRESS +1
$LIT ;ANY LITERALS IN CDB CAN GET CACHED IN HIGH SEG
$ABS ;BACK TO ABS CODE
LOC <.+PG.BDY>&777000
;NOW GENERATE REFERENCES FOR GETTAB TABLES 55 THRU 70
;WILL GENERATE A ZERO WORD FOR INDIRECT REFERENCES TO NON EXISTANT CDB'S
DEFINE CPUGTB(A,B)<
IFG <M.CPU-A>,<XP ITMC'B'C,.CPPCL
XP ITMC'B'V,.CPPVL>
IFLE <M.CPU-A>,<XP ITMC'B'C,0 ;MAKE LENGTH 0 SO ERROR RETURN
XP ITMC'B'V,0 ;MAKE LENGTH 0 SO ERROR RETURN
.C'B'CDB:: ;DEFINE ADR TO BE A WORD CONTAINING 0.
.C'B'VBG::
>>
ZZ==0
REPEAT 6,<
CPUGTB(ZZ,\ZZ)
ZZ==ZZ+1
>
IFLE <M.CPU-5>,<EXP 0> ;GETTABS FOR NON-EXISTANT CDB'S GET THEIR DATA HERE
IFN FTNSCHED,<
;TABLES INDEXED BY CLASS NUMBER
CLSSTS::BLOCK M.CLSN ;BITS IN LH, QUOTA (NUMBER FROM 0 TO 100) IN RH
CLSQTA::BLOCK M.CLSN ;COMPUTED QUOTA IN JIFFIES, FIGURED OUT
;FROM CLSSTS, RECOMPUTED AT THE
;BEGINNING OF EVERY SCHEDULING INTERVAL.
;DECREMENTED WHENEVER A CLASS USES A JIFFY
;OF RUNTIME.
CLSRTM::BLOCK M.CLSN ;RUNTIME FOR CLASSES SINCE ANY CHANGE IN CLSSTS
;MINUS ANY TIME LEFT OVER AFTER ALL QUOTAS
;WERE SATISFIED WITHIN AN INTERVAL
CLSMXL==:<M.CLSN-1>B26 ;MAXIMUM LENGTH OF PER CLASS TABLES FOR GETTAB
>;END IFN FTNSCHED
SUBTTL MONITOR TABLES WITH ONE ENTRY PER JOB
JOBMAX==:JOBN-1 ;MAXIMUM LEGAL JOB NUMBER
JOBMXL==:<JOBMAX>B26 ;HIGHEST JOB NUMBERSHIFTED LEFT 9 (FOR GETTAB UUO)
MJOBN==:-JOBN ;NEGATIVE NUMBERS OF JOBS (COUNTING NULL JOB)
JBTMAX==:JOBN+SEGN-1 ;HIGHEST INDEX IN JBT TABLES
MJBTMX==:-JBTMAX ;MINUS JBTMAX FOR AOBJN POINTER
JBTMXL==:<JBTMAX>B26 ;HIGHEST JBT ENTRY SHIFTED LEFT 9 (FOR GETTAB UUO)
JBTSTS::BLOCK JOBN+SEGN ;JOB AND HIGH SEG STATUS WORD
;THIS IS DOCEMENTED AS GETTAB TABLE NUMBER 0
;LH==STATUS BITS (SEE S.MAC FOR DESCRIPTION)
;BITS 18-23=EXTENDED JOB STATUS BITS
JBSSPR==^D9 ;SIZE OF ACCES PRIV FOR HIGH SEG
JBNSPR==^D17 ;BYTE PTR. POS.
;RH=IN CORE COUNT FOR HIGH SEGS
JBTVAD:: ;VIRTUAL ADDRESS FOR HIGH SEG TABLE
JBTST2::BLOCK JOBN+SEGN ;SECOND WORD OF JOB STATUS. USED BY SCHEDULER
; AND EVENT WAIT INFO
IFN M.KL10*<M.CPU-1>,<;IF KL10 SYSTEM WITH MORE THAN ONE CPU
JBTST3::BLOCK JOBN ;18-35 = CPU DATA BLOCK ADDR OF LAST
; CPU JOB RAN ON. CLEARED WHEN
; JOB GIVES UP ALL PHYSICAL CORE, OR
; DOES RUN, GET, ETC.
JBTCSN::BLOCK JOBN ;36 BIT SWEEP SERIAL NUMBER, TAKEN FROM
; CPU WHOSE CDB ADDRESS IS IN JBTST3
>;END IFN M.KL10*<M.CPU-1>
IFN FTNSCHED,<
JBTSCD::BLOCK JOBN ;SCHEDULER WORD CONTAINING EACH JOB'S
;CLASS AND TYPE.
>;END IFN FTNSCHED
JBTSPS::IFG <M.CPU-1>,< ;MULTI-PROCESSING SYSTEM?
BLOCK JOBN ;SECOND PROCESSOR STATUS BITS BOTH HALVES (PREFIX=.SP)
;RH=GETTAB BITS FOR 6 CPU'S.
;LH=UNPUBLISHED BITS
;SEE S.MAC FOR DEFINITIONS.
XP ITMSPS,JOBMXL ;LH SYMBOL FOR GETTAB UUO
>
IFLE <M.CPU-1>,< ;SINGLE-PROCESSOR SYSTEM?
0 ;DUMMY ENTRY
XP ITMSPS,0 ;DON'T ALLOW ANY REFERENCE IF NOT 2 CPU SYSTEM
>
JBTADR::BLOCK JOBN+SEGN ;JOB AND HIGH SEG CORE ASSIGNMENT
; LH==PROTECTION (LENGTH-1)
; RH==RELOCATION (ABSOLUTE LOCATION IN CORE)
; DURING BLT OF LOW OR HIGH SEG, THIS WORD
; CONTAINS THE SOURCE RELOCATION
;THIS IS DOCUMENTED AS GETTAB TABLE NUMBER 1
JBTCCC::BLOCK JOBN ;NON-CONTROL-C COUNT (NEGATIVECOUNT OF USERS
;WHO DON'T WANT USER TO GET OUT) (LH)
JBTSWI::
JBTSGN::IFG SEGN, <
BLOCK JOBN+SEGN ;RH=SEGMENT NUMBER OF HIGH SEGMENT THIS JOB
; IS USING IN CORE OR ON DISK
; 0 MEANS JOB DOES NOT HAVE HIGH SEG
;LH=USER DEPENDENT HIGH SEG STATUS BITS (SEE S.MAC)
;THIS IS DOCUMENTED AS GETTAB TABLE NUMBER 14
;INDEXED BY HIGH SEGMENT NUMBER THE TABLE (JBTSWI)
; CONTAINS THE LOW SEGMENT NUMBER OF THE SEGMENT
; WHICH THIS HIGH SEGMENT IS BEING SWAPPED IN FOR
>
IFE SEGN, <
0 ;SINGLE-ENTRY NULL JBTSGN TABLE....
XP ITMSGN,JOBMXL ;LH SYMBOL FOR GETTAB UUO SO THAT JBTSGN IS
; UNDEFINED, I.E., MAKE INDEXING BY J BE 0, BUT
; ALLOW REFERENCES UP TO JOBMXL.
>
JBTPPN:: ;HIGH SEGMENT DIRECTORY NAME IF , 0 IF DTA,MTA
JBTPPN::BLOCK JOBN+SEGN ;XWD PROJECT NUMBER, PROGRAMMER NUMBER
;THIS IS DOCUMENTED AT GETTAB TABLE NUMBER 2
IFG SEGN, < ;REENTRANT MONITOR CAPABILITY?
JBTDEV==:.-JOBN ;JUST HIGH HALF (NO ENTRIES FOR LOW SEGS)
BLOCK SEGN ;HIGH SEGMENT PHYSICAL DEVICE NAME
; OR FILE STRUCTURE NUMBER(DSKA,DSKB,DTAN,MTAN)
>
IFE SEGN,<
JBTDEV==:JBTSGN-JOBN ;USE THE DUMMY ENTRY IN JBTSGN
XP ITMDEV,JBTMXL ;LH SYMBOL FOR GETTAB UUO SO THAT JBTDEV IS
;UNDEFINED, IE. MAKE INDEXING BYITEM BE 0
>
IFN SEGN,< ;
JBTIDT==:.-JOBN ;MAKE FIRST HIGHSEG NUMBER POINT TO TABLE
BLOCK SEGN ;STORAGE FOR TIME SEGMENT LAST WENT DORMANT/IDLE
> ;
JBTVIR::BLOCK JOBN ;JOB'S VIRTUAL SIZE (SEE LOVSIZ/HIVSIZ)
SWPLST::BLOCK JOBN+SEGN
SW2LST::BLOCK JOBN+SEGN ;PARALLEL SWPLST TABLE FOR USE BY FILSER
SW3LST::BLOCK JOBN+SEGN ;PARALLEL SWPLST TABLE FOR ADDITIONAL INFO
; LH=C(SWPOUT) FOR SCHED1, RH=JOB NUMBER
JBTSWP::BLOCK JOBN+SEGN ; DISK ADDRESS WHILE SWAPPED OUT
;BIT 0=1 IF SEGMENT IS FRAGMENTED
;BITS 1-35 DISK ADDRESS IF NOT FRAGMENTED
;FOR LEVEL D,
; BITS 2-4=INDEX OF UNIT IN SWPTAB (JBYSUN)
; BITS 5-17=1ST LOGICAL K ON UNIT (JBYLKN)
; BITS 18-35 CORE ADR OF FRAGMENT TABLE IF FRAGMENTED
JBTIMI::BLOCK JOBN+SEGN ;IMAGE-IN SIZE (SEE IMGIN; SEE ALSO NZS?CN)
JBTIMO::BLOCK JOBN+SEGN ;IMAGE-OUT SIZE (SEE IMGOUT)
JBTCHK::BLOCK JOBN+SEGN ;CHECK SUM FOR SWAPPED OUT JOB DATA AREA OR
; SAME AREA FOR HIGH SEG
JBTNAM:: ;NAME OF HIGH SEGMENT (FILE IT WAS INITIALIZED FROM)
JBTPRG::BLOCK JOBN+SEGN ;NAME OF FILE USED IN LAST R,RUN,GET, ETC
; USED BY SYSTAT PROGRAM, AND AS DEFAULT FOR
; THESE COMMANDS
JBTWCH::BLOCK JOBN ;BITS 1-5 = ENABLE BITS - SEE S.MAC
;BITS 13-35 = TIME OF DAY IN JIFFIES USER
;STARTED TO WAIT FOR RESPONSE FROM SYSTEM
;REST UNUSED
IFN FTRSP,< ;USER TTY INPUT RESPONSE TIMES
JBTRSP::BLOCK JOBN ;UP TIME AT WHICH USER BEGAN TO WAIT
; FOR SYSTEM RESPONSE.
; SET WHEN USER JOB COMES OUT OF TTY INPUT WAIT
; OR TYPES A COMMAND WHICH RUNS A JOB.
;HIGH ORDER BITS SET TO 0 WHEN USER STARTS TO WAIT
; SET TO ONE AS EACH OF SEVERAL TYPES OF RESPONSE
; TERMINATION CONDITIONS OCCUR.
; SEE S.MAC FOR BITS OF FORM JR.R??
; SEE CPU DATA BLOCK (ACR, ADR, AIR, ARR, AXR)
; FOR DESCRIPTION OF TYPES OF RESPONSES GATHERED
JBTRQT::BLOCK JOBN ;'RUN QUEUE TIME' ACCUM. TIME (JIFFIES) THAT JOB
; HAS SPENT IN ONE OF THE RUN QUEUES (INCLUDING SWAPPED)
>
JBTSPL::BLOCK JOBN ;LH=INPUT FILE NAME COUNTER
;BITS 27-35 - WHAT DEVICES BEING SPOOLED
; (SEE S.MAC FOR DEF'NS)
;BITS 24-26 = DSK PRIORITY FOR JOB
; (SEE JBXPRI IN COMMOD)
JBTLIM::BLOCK JOBN ;TIME LIMIT, ETC. FOR JOB
; (SEE S.MAC FOR LAYOUT)
JBTPDB::BLOCK JOBN ;ADDRESS OF PDB
JBTPC:: BLOCK JOBN ;USER MODE PC
JBTCLM:: ;LH=CORE LIMIT (FORMERLY IN JBTLIM)
JBTDDB::BLOCK JOBN ;RH=DDB JOB IS IN I/O WAIT FOR
JBTDAU::BLOCK JOBN ;LH=UDB FOR WHICH JOB OWNS DA
;RH=PPB FOR WHICH JOB OWNS AU
IFG SEGN,< ;REENTRANT MONITOR CAPABILITY?
JBTSHR==:.-JOBN ;JUST HIGH HALF (NO ENTRIES FOR LOW SEGS)
BLOCK SEGN ;HIGH SEGMENT TOTAL SHARER COUNT
>
IFE SEGN,<
JBTSHR==:JBTSGN-JOBN ;USE THE DUMMY ENTRY IN JBTSGN
XP ITMSHR,JBTMXL ;LH SYMBOL FOR GETTAB UUO SO THAT JBTSHR IS
;UNDEFINED, IE. MAKE INDEXING BYITEM BE 0
>
JBTIPC:: ;RH=JCH WHOM WE WANT IPCF INTERLOCK FOR
JBTDTC::BLOCK JOBN ;LH=MASTER DECTAPE DDB JOB WANTS
IFN M.CTX,<
JBTCX::BLOCK JOBN ;LH=JOB # WHOSE CX RESOURCE OWNED BY INDEX
;RH=JOB # WHO OWNS CX RESOURCE OF INDEX
> ;END IFN M.CTX
JBTLOC::BLOCK JOBN ;JOB LOCATION TABLE
;JBTLOC+0 IS CENTRAL SITE STATION NUMBER
IFN M.PSI,<
JBTPIA::BLOCK JOBN ;LH HOLDS FLAGS (BITS 13-17 =0)
;RH IS POINTER TO PROGRAM INTERRUPT
; TABLE.
>
IFE M.PSI,<
XP JBTPIA,777000 ;CAUSE NXM IF REFERENCED
>
JBTJLT::BLOCK JOBN ;JOB "LOGIN" TIME IN INTERNAL FORMAT
JBTHSA:: ;FOR HIGH SEGS, PTR TO FIRST PAGE
JBTAD2::BLOCK JOBN+SEGN ;BIT 0 FREE
;BITS 1-21 DISK ADDR OF S0 MAP FOR JOB
;BITS 22-35 PHYSICAL PAGE ZERO OF JOBS LOW SEG
JBTJRQ::BLOCK JOBN ;LINKED LIST OF JOBS WAITING FOR REQUEUE
JBTPRV::BLOCK JOBN ;PRIVILEGE BITS FOR JOB SET BY LOGIN
;THE FOLLOWING ARE USED TO CREATE MXQUE
;THE MAXIMUM QUEUE SIZE, USED BY SWAPPING SCHEDULER (SCHED)
XP MXQUE,0
DEFINE X <MXQUE==MXQUE+1;>
QUEUES
RWAITS
DEFINE X (A)
<A'Z==MXQUE
MXQUE==MXQUE+1;>
CODES
MXQUE==MXQUE+3 ;LEAVE SPACE FOR PQ1,PQ2, AND CMMQ
IFG HPQN,<MXQUE=MXQUE+HPQN>
;LEAVE SPACE FOR HIGH PRIORITY QUEUES
XP MXQUE2,<2*MXQUE>
BLOCK MXQUE2 ;NUMBER OF QUEUES FOR SWAPPING SCHEDULER
QQQMXL==:<MXQUE-1>B26 ;NUMBER QUEUES FOR GETTAB
JBTCQ:: BLOCK JOBN ;ONE ENTRY PER JOB,
; LH=PREVIOUS JOB, RH=NEXT JOB IN QUEUE
; NEGATIVE MEANS THIS IS FIRST (LH) OR LAST (RH)
; JOB IN QUEUE
JBCQM1==:JBTCQ-1 ;
JBCQP1==:JBTCQ+1
NCNULQ==:NULZ+MXQUE ;NUMBER OF NULQ IN NO-CORE HEADER
JBCQMN==:JBTCQ-NCNULQ ;NUL QUEUE HEADER
JBCQOH==:JBTCQ-MXQUE ;WHAT TO INDEX TO GET SWAPPED OUT QUEUE HEADER
IFN FTNSCHED,<
BLOCK 2*M.CLSN ;HEADER FOR PQ2 SUBQUEUES
JBTCSQ::BLOCK JOBN ;SAME AS JBTCQ FOR SUBQUEUES
JBCSOH==:JBTCSQ-M.CLSN ;SWAPPED OUT SUB-QUE HEADER
>;END OF IFN FTNSCHED
JBTHSQ::BLOCK 1 ;HEADER FOR JOBS WAITING FOR A HIGH SEG
JBTBBQ::BLOCK 1 ;HEADER FOR BB JUST INPUT QUEUE
JBTJIQ::BLOCK 1 ;HEADER FOR PQ2 JUST INPUT QUEUE
JBTJIL::BLOCK JOBN ;LIST OF PQ2 JOBS JUST INPUT
HSQ==:JBTJIL-JBTHSQ
BBQ==:JBTJIL-JBTBBQ ;OFFSET FOR JBTBBQ
MBBQ==:-BBQ ;NEGATIVE OFFSET
JIQ==:JBTJIL-JBTJIQ ;OFFSET FOR JBTJIQ
JBTDIH::BLOCK 1 ;HEADER FOR QUEUE OF DORMANT/IDLE HISEGS
JBTOBQ::BLOCK 1 ;HEADER FOR BB OUTPUT SCAN LIST
JBTOLQ::BLOCK 1 ;HEADER FOR PQ2 OUTPUT SCAN LIST
JBTOLS::BLOCK JOBN ;LIST OF PQ2 IN ORDER TO BE SCANNED FOR OUTPUT
BLOCK SEGN ;ALSO, PUT QUEUE OF IDLE/DORMANT SEGMENTS HERE
JBTDIQ==:JBTOLS ;GIVE IT A DIFFERENT NAME
DISQ==:JBTDIQ-JBTDIH ;DORMANT/IDLE QUEUE HEAD
OBQ==:JBTOLS-JBTOBQ ;OFFSET FOR JBTOBQ
MOBQ==:-OBQ
OLQ==:JBTOLS-JBTOLQ ;OFFSET FOR JBTOLQ
;DATA STRUCTURE CLEARED ON SYSTEM STARTUP AND ON 143 RESTART
;TTYTAB IS A TABLE OF CONTROLLING (ATTACHED) TTY'S FOR EACH JOB,
;INDEXED BY JOB NUMBER. IF C(TTYTAB)=0 THEN THERE IS NO SUCH JOB.
;OTHERWISE, RH(TTYTAB(N)) IS CONTROLLING DDB FOR JOB N.
;THERE IS ALWAYS A TTY DDB FOR EVERY JOB, EVEN THOUGH NO TTY
; NEED BE ATTACHED. THUS UUOS LOOK THROUGH TTYTAB(N) FOR A DDB,
; SINCE UUO'S COME FROM JOBS. COMMANDS LOOK THROUGH LINTAB(LINENUMBER)
; TO THE LDB, SINCE COMMANDS COME FROM TTY'S (LINES).
; IF THE JOB IS DETACHED, THE LINKS FROM LDB TO DDB AND VICE VERSA
; ARE ZEROED (RH OF DDBLDB AND LDBDDB).
TTYTAB::BLOCK JOBN
TTYDDL::BLOCK 1 ;DIALLER INTERLOCK
TTYDDA::BLOCK 1 ;TTY DIALLER DATA ADDRESS, 4 WORD BLOCK
DSDUNI::BLOCK 1 ;TTY NUMBER USING DIALLER CODE
XPNMSZ==<JOBN/^D32>+1 ;SIZE OF BIT MAP
XPNMAP::BLOCK XPNMSZ ;BIT MAP OF EXPANDING JOBS
XP XPNMPT,-XPNMSZ ;FOR MAKING AOBJN POINTER
SPTTAB:: ;SPECIAL PAGES TABLE
;SPT ENTRIES FOR CURRENT CONTEXT MUST IMMEDIATELY PRECEDE JBTUPM
;(FUNNY SPACE MAPPED IN THROUGH THESE SPT ENTRIES)
REPEAT M.CPU,<
EXP NUPMPP
>; END REPEAT M.CPU
JBTUPM::BLOCK JOBN+SEGN ;ADDRESS OF THE UPMP
;SPT SLOTS FOR SPYING ON SECTION 0/1
;(INDIRECT POINTERS TO SECTION 0/1 LOW SEGMENT PAGES AND COMMON
;SUBROUTINE PAGES MAPPED IN THROUGH THESE SPT ENTRIES)
SPTLOW::
DEFINE SPTENT(N),<
EXP .E'N'MAP/PAGSIZ
>; END DEFINE SPTENT
ZZ==0
REPEAT M.CPU,<
SPTENT (\ZZ) ;GENERATE THEM
ZZ==ZZ+1
>; END REPEAT M.CPU
;SPT SLOTS FOR SPYING ON SECTION 2
SPTHGH::
DEFINE SPTENT(N),<
IFE FTXMON,<0>
IFN FTXMON,<
EXP .E'N'MP1/PAGSIZ
>; END IFN FTXMON
>; END DEFINE SPTENT
ZZ==0
REPEAT M.CPU,<
SPTENT (\ZZ) ;GENERATE THEM
ZZ==ZZ+1
>; END REPEAT M.CPU
;SPT SLOTS FOR SPYING ON COMMON DATA SECTIONS
IFN FTXMON,<
SPTCOM::
REPEAT <HLGSNO-<(MS.FMD)>>,<
XWD 1,0 ;GENERATE THEM (INVALID UNTIL SYSINI FILLS IN)
>; END REPEAT
>; END OF IFN FTXMON
SUBTTL SYSTEM WIDE VARIABLES
;SYSTEM WIDE VARIABLES:
; CLEARED AT SYSTEM STARTUP
;GETTAB FOR SYSTEM WIDE VARIABLES (AS OPPOSED TO PER CPU DATA)
; GETTAB TABLE NO(RH) IS .GTSYS=51
SYSTBL:: ;GETTAB TABLE NO. 51. ( .GTSYS = 51
SYSERR::0 ;(0) TOTAL NUMBER OF HARDWARE AND SOFTWARE ERRORS
; DETECTED BY THE MONITOR AND ENTERED IN DAEMON
; ERROR LOG FILE INCLUDING DAEMON ERRORS.
; INCLUDES HARD AND SOFT ERRORS
; HARD ERROR WITH 80 RETRIES ONLY COUNTS AS 1 ERROR IN SYSERR.
CMNOTF::0 ;(1) NUMBER OF TIMES SCNSER WAS CALLED TO
; FIND A COMMAND BECAUSE COMCNT WAS
; NON-ZERO AND NO COMMAND WAS FOUND
DELCNT::0 ; (2) DISABLED ERROR LOGGING COUNT
; INCREMENT INSTEAD OF SYSERR IF USER HAS DISABLED
; ERROR LOGGING IN OPEN UUO
%SYSPC::0 ;(3) FULLWORD PC OF LAST STOPCODE
%SYNDS::0 ;(4) NUMBER OF DEBUG STOPCD'S.
%SYNJS::0 ;(5) NUMBER OF STOPCD'S WHICH CAUSED A JOB TO BE
; STOPED.
COMTOT::0 ;(6) NUMBER OF COMMANDS PROCESSED
; (DELAYED COMMANDS ARE COUNTED ONCE WHEN PROCESSED)
%SYSJN::0 ;(7)JOB# OF JOB ON LAST STOPCD
%SYSTN::0 ;(10)TTY NAME FOR LAST STOPCD
%SYSPN::0 ;(11)PROGRAM NAME FOR LAST STOPCD
%SYSUU::0 ;(12)UUO ON LAST STOPCD
%SYSUP::0 ;(13)USER'S PC ON LAST STOPCD
%SYSPP::0 ;(14)USER'S PPN ON LAST STOPCD
%SYSCD::0 ;(15)NAME OF LAST STOPCODE
%SYNCS::0 ;(16)TOTAL NUMBER OF CPU STOPCODES
%SYNIS::0 ;(17)NUMBER OF NODUMP STOPCDS (BUGINFS)
%SYSTY::0 ;(20)TYPE OF LAST STOPCODE
%SYSDT::0 ;(21)UDT OF LAST STOPCODE
%SYSCP::-1 ;(22)CPU NUMBER OF LAST STOPCD
XP SYSMXL,<<.-SYSTBL-1>B26> ;MAX. ENTRY
;UNPUBLISHED SYSTEM VARIABLES:
;OTHER SYSTEM DATA STORAGE
COMCNT::0 ;NUMBER OF COMMANDS TYPED-IN BUT NOT DECODED
;SET BY SCNSER, DECREMENTED BY COMCON
IFN FTMP,<
COMJOB::0 ;JOB NUMBER OF JOB CURRENTLY EXECUTING
; A COMMAND USED TO AVOID JOBSTS UUO RACE
>
NFCNT:: 0 ;COUNT OF TIMES COMCNT NON-ZERO,
;BUT NO WAITING COMMANDS
HNGMIN::0 ;DO ONCE PER MINUTE FUNCTIONS WHEN THIS
;FLAG COUNTS NEGATIVE
; SCHEDULER SCANS ALL JOBS EVERY
; MINUTE TO SEE IF QJOB HAS BEEN COUNTED
; DOWN TOO FAR. MORE LIKELY IN DUAL CPU SYS.
CHKCNT::0 ;NO. OF CALLS TO CHKTAL TO CHECK CORE
; BEFORE ACTUALLY DOING THE OVERHEAD.
; RESET TO M.CMCT WHEN COUNTS TO 0.
DATREM::0 ;LAST REMAINDER IN UPDATING "DATE" (SMITHSONIAN DATE)
SCDTIM::0 ;DECREMENTED EVERY JIFFY, END OF MEDIUM
;TERM SCHED INTERVAL WHEN THIS REACHES ZERO.
;STORAGE FOR VARIOUS CORE ALLOCATION FUNCTIONS AND OTHER NON-SWAPPING DATA
XP CRSIZ,9
XP CRPOS,8
XP PP256K,^D512/<<PAGSIZ>_-^D9>
;MAXIMUM NUMBER OF PAGES OF PHYSICAL MEMORY POSSIBLE
IFN M.KL10,<
XP CORBLK,<1_<^D22-^D9>> ;22 BIT PHYSICAL ADDRESSES (4 MEGAWORD)
>
IFN M.KS10,<
XP CORBLK,<1_<^D20-^D9>> ;20 BIT PHYSICAL ADDRESSES (1 MEGAWORD)
>
IFN FTLOCK,<
LOCK:: 0 ;JOB#,,HIGH SEGMENT# OR
;0,,JOB# IF NO HIGH SEGMENT
;OF JOB CURRENTLY BEING LOCKED IN CORE
LOKREL::0 ;DESIRED PROTECTION,,RELOCATION
;FOR JOB CURRENTLY BEING LOCKED
PAGLOK==:1B18 ;FLAG THAT WE'RE LOCKING SPECIFIC PAGES
LASLOK::0 ;JOB # OF LAST JOB LOCKED
>;END IFN FTLOCK
MOFLPG::0 ;FLAG FOR SETTING MEMORY ON OR OFF LINE
LMPAG::0 ;LAST PAGE IN MONITOR'S PAGTAB CHAIN
DOORBL::0 ;SYSTEM DOORBELL
IFN FTKL10&FTMP,<
SAVCTL::0 ;VALUE OF CORTAL WHEN MM RESOURCE WAS OBTAINED
>
;GFWN?? ALLOCATION CONTROL STUFF
NZSFCA: BLOCK 1+MXSECN ;HEAD OF SECTION FREE CORE LISTS
$HIGH
DEFINE NZSMAC (SECT),<400000,,NZSFCA+SECT>
ZZ==0
NZSFCH:: ;POINTERS TO SECTION FREE CORE HEADERS
REPEAT 1+MXSECN,<
NZSMAC (\ZZ)
ZZ==ZZ+1
>
NZSFCL==:.-NZSFCH ;LENGTH OF TABLE
$ABS
NZSFCE:: ;TAIL POINTERS FOR NZS FREE CORE
BLOCK NZSFCL ;ACTUALLY FILLED IN BY SYSINI
;DATA LOCATIONS PRESENT ONLY IN SWAPPING SYSTEMS
SWPTBL::! ;FIRST LOCATION OF MONITOR DATA STORAGE
; RETURNED BY GETTAB UUO (THESE LOCATIONS
; PRESENT ONLY IN SWAP SYSTEMS)
; OCTAL NUMBERS IN () CORRESPOND TO GETTAB ARG
;THIS IS DOCUMENTED AS GETTAB TABLE NUMBER 13
BIGHOL::0 ;(0) CURRENT BIGGEST HOLE IN CORE (1K BLOCKS)
FINISH::0 ;(1) IF +, THEN JOB NUMBER OF JOB BEING SWAPPED IN,
;IF -, THEN JOB NUMBER OF JOB BEING SWAPPED OUT
FORCE:: 0 ;(2) JOB NUMBER BEING FORCED TO SWAP OUT
FIT:: 0 ;(3) JOB NUMBER WAITING TO BE FITTED INTO CORE
VIRTAL::0 ;(4) NUMBER OF FREE 1K BLOCKS OF SWAPPING SPACE LEFT
; (COUNTING DORMANT SEGMENTS AS IF FREE).
; PRINTED WITH CORE COMMAND (NO ARG) OR ERROR
; USUALLY THE SAME AS THE AMOUNT OF VIRTUAL CORE
; LEFT IN SYSTEM, EXCEPT WHILE R,RUN,KJOB,GET
; COMMAND ARE WAITING TO BE SWAPPED IN, BECAUSE
; THE OLD DISK SPACE HAS NOT BEEN RETURNED YET,
; BUT VIRTUAL CORE IS ONLY 140 WORDS FOR SWAPIN
SWPERC::0 ;(5) LH= NUMBER OF SWAPPER READ OR WRITE FAILURES
; RH= ERROR BITS (BITS 18-23) + NUMBER OF K OF
; IOCHNX=IO CHANNEL SWAP NON-EX MEM - BIT 23
; IOCHMP=IO CHANNEL SWAP OUT MEMORY PARITY - BIT 22
; BITS 18-22 = IOIMPM (SOFTWARE CHECKSUM),
; IODERR, IODTER, IOBKTL
; DISCARDED SWAPPING SPACE
SWAPIN::0 ;(6) IF THE SYSTEM HAS FTPDBS TURNED ON,
; THIS WORD IS -1 WHEN A SWAPIN IS
; IN PROGRESS AND ZERO WHEN A SWAP OUT
; IS IN PROGRESS. IF FINISH IS ZERO
; THEN NO SWAP IS IN PROGRESS. IF FTPDBS
; IS OFF THIS WORD IS ALWAYS ZERO.
;INSERT NEW LOCATIONS HERE WHICH ARE OF INTEREST
; TO USER PROGS IN SWAPPING SYSTEMS
SWPEUJ::0 ;(7)LH=J FOR JOB OR SEGMENT WHICH GOT A SWAP
; READ/WRITE ERROR, RH=UNIT THAT THE
; SWAPPING I/O WHICH RESULTED IN THE ERROR
; WAS DONE TO
SWPMXL==:<.-SWPTBL-1>B26 ;MAXIMUM ENTRY FOR GETTAB SHIFTED LEFT 9
;MORE SWAPPING SYSTEM LOCATIONS (NOT RETURNED BY GETTAB)
MAXJBN::0 ;NUMBER OF JOB TO SWAP OUT
SUMCOR::0 ;TEMPORARY STORAGE CELL USED BY SWAPPER FOR SUM OF
; CORE NEEDED FOR SWAP IN
FITLOW::0 ;NUMBER OF JOB BEING FIT (NEVER HI-SEG)
SWPIN:: 0 ;JOB NUMBER BEING SWAPPED IN IF IT HAS A HIGH SEG
SWPOUT::0 ;JOB NUMBER BEING SWAPPED OUT IF IT HAS A HIGH SEG
; (USED TO REMEMBER THE JOB NUMBER DURING HIGH SEG SWAP)
IFN FTRSP,<
SWPNU2::0 ;JIFFY REMAINDER FOR SWAP NULL TIME
SWPLS2::0 ;JIFFY REMAINDER FOR SWAP LOST TIME
SWPPLT::0 ;POTENTIAL LOST TIME FLAG FOR SWAPPER
;TO TELL CLOCK1 TO COUNT SOME LOST TIME
;(HAVE JOB TO SWAP IN BUT SWAPPER IDLE)
SWPNUF::0 ;NULL CYCLE FOR SWAPPER (AGAIN, SO CLOCK1
;CAN COUNT NULL TIME FOR SWAPPER)
>;END IFN FTRSP
IFN FTNSCHED,<
SCDSTS::0 ;TIME OF LAST SETTING OF PRIMARY PERCENTAGES
CNTSTS::0 ;COUNT OF CPU CLASSES WITH NON-ZERO QUOTA
TOTSTS::0 ;TOTAL OF ALL SUBCLASS PERCENTAGES
; (MUST BE 100 OR ZERO)
MAXQTA::0 ;NUMBER OF HIGHEST CLASS WITH SECONDARY QUOTA
CNTQTA::0 ;COUNT OF CLASSES WITH NON-ZERO SECONDARY QUOTA
TOTQTA::0 ;TOTAL OF ALL SECONDARY SUBCLASS PERCENTAGES
; NORMALLY 100%, BUT CAN BE ANY NON-NEGATIVE
>;END OF IFN FTNSCHED
$ABS
IFN M.FPS,<
EXTERN KASER ;CAUSE KA10 FP SIMULATION MODULE TO BE LOADED
>
IFE M.FPS,<
XP KALFPS,CPOPJ
XP SETFPS,CPOPJ
XP SETFPC,COMERA##
>
SUBTTL MACROS TO DEFINE PI CHANNELS
;MACROS TO DEFINE PI CHANNEL NUMBER AND GENERATE INTERRUPT CHAINING
; INFORMATION FOR AUTCON SO IT CAN LINK THE DEVICE INTERRUPT SERVICE
; ROUTINES AND THE DEVICE DATA BLOCKS
;TABLE INTTAB IS GENERATED WITH PAIRS OF ENTRIES FOR EACH DEVICE
;BYTE POINTERS TO INTTAB LOCATIONS USED BY AUTCON
PINTNO::POINT 11,INTTAB+0(P1),11 ;NUMBER OF DDBS TO CREATE
PINTCP::POINT 3,INTTAB+0(P1),14 ;CPU NUMBER
PINTCH::POINT 3,INTTAB+0(P1),17 ;PI CHANNEL
PINTIN::POINT 18,INTTAB+0(P1),35 ;INTERUPT ROUTINE ADDRESS
PINTSZ::POINT 9,INTTAB+1(P1),17 ;SIZE OF DDB TO CREATE
PINTDB::POINT 18,INTTAB+1(P1),35 ;ADDRESS OF PROTOTYPE DDB
;MACRO TO GENERATE SYMBOLS FOR AUTOCONFIGURED DEVICES
;ARGUMENTS:
; GEN MONGEN SYMBOL (M.XXXX)
; DEV 3 CHARACTER DEVICE PREFIX (I.E. 'TAP' FOR TAPE SERVICE)
; PI PI CHANNEL (USUALLY SPECIFIED AS "\.CH")
; BITS EXTRA PI CHANNEL BITS TO BE TURNED OFF OR ON (I.E. PI.SC7)
DEFINE ASGDEV (GEN,DEV,PI,BITS),<
IFN GEN,< ;;IF ANY OF THIS DEVICE
USED'PI==:1 ;;GENERATE CHANNEL SAVE ROUTINE
.CHAS==1 ;;CHANNEL HAS BEEN ASSIGNED
DEV'CHN==:PI ;;PI CHANNEL
DEV'CHL==:CH'PI ;;LOCATION WHERE INTERRUPT PC IS STORED
DEV'SAV==:SAV'PI ;;CHANNEL AC SAVE ROUTINE LOCATION
DEV'SAC==:SVAC'PI ;;STARTING CHANNEL SAVE LOCATION FOR ACS
DEV'PDP==:C'PI'PDP ;;LOCATION WHERE P STORED
DEV'PD1==:C'PI'PD1 ;;PUSHDOWN LIST
DEV'BIT==:PI.SC7_<7-'PI> ;;PI CHANNEL BIT
DEV'PIF==:PI.TFP!<DEV'BIT>!'BITS ;;MASK TO TURN PI CHANNEL(S) OFF
DEV'PIN==:PI.TNP!<DEV'BIT>!'BITS ;;MASK TO TURN PI CHANNEL(S) ON
> ;;END IFN GEN
> ;END DEFINE ASGDEV
;MACRO TO LINK A DDB WITHOUT A CORRESPONDING DEVICE DRIVER ONTO
;THE INTTAB CHAIN.
;ARGUMENTS:
; GEN MONGEN SYMBOL (M.XXXX)
; DEV 3 CHARACTER DEVICE PREFIX (I.E. 'PTY' FOR PTY)
DEFINE ASGDDB (GEN,DEV),<
IFN GEN,< ;;IF ANY OF THIS DEVICE
IF2,<
IFNDEF DEV'DDB,<EXTERN DEV'DDB>
IFNDEF DEV'SER,<EXTERN DEV'SER>
>;; END IF2
.IFN DEV'N,EXTERNAL,< ;;IF NOT EXTERNAL
IFNDEF DEV'N,<DEV'N==1> ;;IF DEV'N NOT DEFINED, DEFAULT TO 1
IFE <DEV'N-1>,< ;;IF ONLY A SINGLE DEVICE
XWD 0,0 ;;NO DUPLICATES NEEDED, NO PI CHANNEL STUFF
XWD 0,DEV'DDB ;;ADDRESS OF PROTOTYPE DDB
>;; END IFE <DEV'N-1>
IFG <DEV'N-1>,<
IF2,<IFNDEF DEV'DDS,<EXTERN DEV'DDS>>
XWD DEV'N*100,0 ;;NUMBER OF DDBS TO CREATE
XWD DEV'DDS,DEV'DDB ;;SIZE,,ADDRESS OF PROTOTYPE DDB
>;; END IFG DEV'N-1
>;; END .IFN
.IF DEV'N,EXTERNAL,< ;;IF EXTERNAL
IF2,<IFNDEF DEV'DDS,<EXTERN DEV'DDS>>
XWD DEV'N*100,0 ;;NUMBER OF DDBS TO CREATE
XWD DEV'DDS,DEV'DDB ;;SIZE,,ADDRESS OF PROTOTYPE DDB
>;; END .IF
> ;;END IFN GEN
> ;END DEFINE ASGDDB
;;MACRO FOR DEVICES WHICH ARE ALWAYS PRESENT (AND WHICH DO NOT USE A
;; CHANNEL SAVE ROUTINE AND HAVE NO DDB) EXAMPLES ARE APR, CTY, PEN, CLK...
DEFINE SPAXGINT (DEV,PI) <
DEV'N==1
ASGINT DEV,PI
>
DEFINE ASGIN1 (DEV,PI) <
DEV'CHL==:CH'PI
>
DEFINE SPASGINT (DEV,PI) <
DEV'N==1
ASGINT DEV,PI
>
DEFINE ASGINT (DEV,PI) <
IFG DEV'N, <IFG PI, <
IFE <PI-.CH>, <.CHAS==1 ;;CHANNEL PI IN USE.
>
IF2,<IFNDEF DEV'INT,<EXTERN DEV'INT>>
DEV'CHN==:PI&7
DEV'CH1==PI ;DEFINE THIS FOR USE AFTER CHAN DEFINITIONS
XWD PI,DEV'INT ;;GENERATE INTERRUPT ENTRY POINT FOR ONCE
XWD 0,0
ASGIN1 DEV,\PI
>>
>
;;MACRO FOR OPTIONAL DEVICES WHICH ALWAYS USE A CHANNEL SAVE ROUTINE
;; (EXAMPLES: CDR, DSK, PTR, ETC. ALSO PTY WITH 0 PI)
DEFINE SPASGDDB (DEV,PI,NUM) <
DEV'N==NUM
NOSAV==1
ASGSAV DEV,PI
>
;MACRO TO GENERATE INTTAB ENTRY FOR SAVE ROUTINE BUT NO DDB
; ASGSVE & ASGSVI
DEFINE ASGSVE (DEV,PI) <
.CHAS==1
DEV'CHN==:PI&7
DEV'CH1==PI
DEV'HAC==:13
ASGSV2 DEV,\PI;
IFDIF <DEV><SCN>,<
IF2 < IFNDEF DEV'INT,<EXTERNAL DEV'INT>> ;DEFINE AS EXTERN IF NOT IN COMMON
XWD PI,DEV'INT
XWD 0,0
>
>
DEFINE ASGSAV (DEV,PI) <
IFG DEV'N, <
ASGSV1 DEV,\PI
>>
;;MACRO FOR: 1. COMPLETION OF THE DEFINITION REQUIRED FOR THOSE
;; DEVICES INVOKING THE ASGSAV MACRO
;; 2. DEFINE SYMBOLS FOR DISK (DEV'N=0)
DEFINE ASGSV1 (DEV,PI) <
IF2, < IFNDEF DEV'DDB, <EXTERNAL DEV'DDB>> ;;DEVICE DATA BLOCK ADDRESS
IFG PI, <
IFE <PI-.CH>, <.CHAS==1 ;;CHANNEL PI IN USE.
>
DEV'CHN==:PI&7 ;;DEFINE DEVICE CHANNEL NUMBER
DEV'CH1==PI ;;USED AFTER CH'PI DEFINITIONS
IFE NOSAV,<
ASGSV2 DEV,PI
>
>
IFG PI, <
IF2, < IFNDEF DEV'INT, <EXTERNAL DEV'INT>> ;;INTERRUPT SERVICE CONSO INSTRUCTION
>
IFE PI, <
XWD DEV'N*100+0,0 ;;NO PI CHANNEL FOR THIS DEVICE
>
IFG PI, <
XWD DEV'N*100+PI,DEV'INT ;;FIRST WORD OF INTTAB ENTRY
IFE DEV'N,<EXTERNAL DEV'INT> ;;LEVEL D DISK IN COMMOD
>
IFG DEV'N-1,<
XWD DEV'DDS##,DEV'DDB ;;MULTIPLE DEVICE SECOND WORD OF INTTAB ENTRY
>
IFE DEV'N-1, <
XWD 0,DEV'DDB ;;SINGLE DEVICE SECOND WORD OF INTTAB ENTRY
>
> ;;END ASGSV1 DEFINITION
DEFINE ASGSVN (DEV,X,PI) <
IFG PI, <
IFE <PI-.CH>, <.CHAS==1> ;;CHANNEL PI IN USE.
DEV'X'CHN==:PI&7 ;;DEFINE DEVICE CHANNEL NUMBER
DEV'X'CH1==PI ;;USED AFTER CH'PI DEFINITIONS
ASGSV2 DEV'X,\PI
IF2, < IFNDEF DEV'X'INT, <EXTERNAL DEV'X'INT>> ;;INTERRUPT SERVICE CONSO INSTRUCTION
>;END IFG PI
IFNDEF DEV'X'N,<DEV'X'N==1>
EXP <DEV'X'N>B11!<PI>B17!DEV'X'INT
IF2,<IFNDEF DEV'X'DDB,<EXTERN DEV'X'DDB>>
IFE DEV'X'N-1,<
EXP DEV'X'DDB
>;;END IFE DEV'X'N-1
IFN DEV'X'N-1,<
IF2,<IFNDEF DEV'X'DDS,<EXTERN DEV'X'DDS>>
EXP <DEV'X'DDS>B17!DEV'X'DDB
>;;END IFN DEV'X'N-1
>;;END ASGSVN DEFINITION
;;MACRO'S TO ALLOW GENERATION OF MULTIPLE INTTAB ENTRIES FOR MULTIPLE
;; DEVICES SUCH AS LINE-PRINTERS
DEFINE MULASG (DEV,DE,PI,DSKFL) <
IFG DEV'N, <
ZZ==0
REPEAT DEV'N, <
DEVASG DE,\ZZ,PI,DSKFL
ZZ==ZZ+1
>
>
>
DEFINE DEVASG (DE,X,PI,DSKFL) <
IFE DSKFL,<DE'X'N==1> ;;DSKFL=1 IF NOT LEVEL D DISK
IFN DSKFL,<DE'X'N==0> ;;DSKFL=ZERO IF LEVEL D DISK
ASGSV1 DE'X,\PI
>
;;MACROS TO CONTROL ASSIGNMENT OF PI CHANNELS TO DEVICES
DEFINE NEXTCH < .CH==.CH+1 ;;START ASSIGNING TO NEXT LOWER CHANNEL
.CHAS==0
NEXTCU \.CH
>
DEFINE NEXTCQ < IFN .CHAS, <NEXTCH>> ;;START ASSIGNING TO NEXT LOWER CHANNEL IF
;; CURRENT CHANNEL HAS BEEN USED.
DEFINE NEXTCU (N) < IFDEF UNIQ'N, < IFN UNIQ'N, <NEXTCH>> ;;TO SKIP OVER ANY
;; SPECIALLY SPECIFIED CHANNELS (RECURSIVELY!)
IFDEF RTCH'N,<IFN RTCH'N,<NEXTCH>>> ;IF RTCH'N IS DEFINED
;DURING MONGEN, THAT CHANNEL WILL BE FREE FOR RT DEVICES
DEFINE UNIQDEF(N)
< UNIQ'N==1
IFDEF RTCH'N,<IFN RTCH'N,<
PRINTX ?PI CHAN N CAN NOT BE RESERVED FOR REAL-TIME
PRINTX ?IT IS NEEDED FOR BLKI/BLKO
>>>
DEFINE MULFLG, (DE,X,PI) <
ASGSVE DE'X,\PI
>
;;INITIALLY ASSUME NO PI CHANNEL SAVE ROUTINES NEEDED
DEFINE USED(PI),<
USED'PI==0
>
ZZ==0
REPEAT M.CPU,<
ZZ==ZZ+1
REPEAT 7,<
USED \ZZ
ZZ==ZZ+1
>>
;MACRO TO ALLOW GENERATION OF CHANNEL SAVE ROUTINES ONLY
DEFINE SPASGSAV (DEV,PI,%ACNUM) <
HIAC'PI==:%ACNUM
DEV'HAC==:%ACNUM
ASGSV2 DEV,PI
>
DEFINE ASGSV2 (DEV,PI) <
USED'PI==:1 ;SET FLAG SO THAT A CHANNEL SAVE
; ROUTINE WILL BE GENERATED FOR
; THIS PI CHANNEL
IFDEF SAV'PI, < ;WAIT TILL CHANNEL SAVE ROUTINES
; ARE DEFINED BELOW (IN PASS 2)
DEV'SAV==:SAV'PI ;CHANNEL AC SAVE ROUTINE LOCATION
DEV'SV==:SAV'PI ;USED BY DISKS
DEV'RET==:RET'PI ;CHANNEL AC RESTORE ROUTINE LOCATION
; (USUALLY POPJ USED)
DEV'CHL==:CH'PI ;LOCATION WHERE INTERRUPT PC IS STORED
DEV'SAC==:SVAC'PI ;STARTING CHANNEL SAVE LOCATION FOR AC'S
DEV'PDP==:C'PI'PDP ;LOCATION WHERE P STORED
DEV'PD1==:C'PI'PD1 ;PUSHDOWN LIST
DEV'JEN==:C'PI'JEN ;LOCATION WHERE INT. IS DISMISSED
>>
;NOW GENERATE THE TABLE FOR ONCE AND DEFINE PI CHANNEL ASSIGNMENTS
CTYN==:1 ;ALWAYS ONE CTY
IFN M.ANF,< NETN==1> ;ONLY ONE DDB
DSKPIN==:PI.TNP ;SET PI ON BIT - WILL ALSO HAVE PI ON FOR DISK CONTOLLERS
DSKPIF==:PI.TFP ;AND FOR PI OFF
NOSAV==0 ;DO NOT SUPPRESS GENERATION OF SAVE ROUTINES
INTTAB:: ;TABLE OF DATA FOR DEFINING PI CHAN AND NUMBER OF DOB
ASGDDB (M.KDUP,KDP) ;KDP
ASGDDB (M.DMRN,DMR) ;DMR
IF2,<
IFN M.KDUP,<ASGSV2 KDP,\SCNCHN>
IFN M.DMRN,<ASGSV2 DMR,\SCNCHN>
>; END IF2
ASGDDB (M.KL10,DTE) ;DTE
;GROUP OTHER ASGDDB ENTRIES HERE BEFORE "REAL" ENTRIES
.CHAS==0
.CH==0
NEXTCH ;BEGIN AT CHANNEL 1
;THE FOLLOWING DEVICES MUST HAVE A UNIQUE, HIGH PRIORITY
; CHANNEL FOR BLOCK I/O TRANSFERS.
;PDP10 MAGTAPE BLKI/BLKO PI CHANNEL:
IFNDEF BLKMXC, <BLKMXC==.CH> ;REMEMBER THIS CHANNEL ON PASS 1
.CH==BLKMXC ;ON PASS 2, SKIP OVER BLKI CHANNELS
;THE FOLLOWING ARE GROUPED ON A HIGH PRIORITY CHANNEL, BUT DO NOT
; WRITE INTO THE INTERRUPT LOCATIONS
ASGDEV (M.CR10,CDR,\.CH,0) ;CARD READERS
DEFINE DTADF1(X),<
ASGSVE D'X'D,PI1
>
DEFINE DTADEF(CPU),<
REPEAT M'CPU'TD10,<
DTADF1(\"ZZZ)
ZZZ==ZZZ+1
>
>
DEFINE GENDTA,<
ZZ==0
ZZZ=="A"
PI1==.CH
REPEAT M.CPU,<
DTADEF(\ZZ)
ZZ==ZZ+1
PI1==PI1+10
>
>
GENDTA
NEXTCQ
;THE FOLLOWING ARE GROUPED ON A CHANNEL FOR HIGH-PRIORITY DEVICES
ASGDEV (M.CDP,CDP,\.CH,0) ;CARD PUNCHES
ZZ==0
PI1==.CH
REPEAT M.CPU,<
MULFLG AP,\ZZ,\PI1
ZZ==ZZ+1
PI1==PI1+10
>
NEXTCQ
;THE FOLLOWING ARE MEDIUM-PRIORITY DEVICES, AS A GROUP
ASGDEV (1,SCN,\.CH,0) ;TERMINAL SCANNER
IFN M.TTG0,<
ASGSVE DL0,.CH
>
IFN M.TTG1,<
ASGSVE DL1,.CH
>
IFN M.68L0,<
ASGSVE CC0,.CH
>
IFN M.68L1,<
ASGSVE CC1,.CH
>
ASGDEV (M.PTR,PTR,\.CH,0) ;PAPER TAPE READERS
ASGDEV (M.CR10,CRF,\.CH,0) ;CR10 FLAGS
IFN M.KS10,<
ASGDEV (M.PTP,PTP,\.CH,0) ;PAPER TAPE PUNCHES
ASGDEV (M.CR20,CDR,\.CH,0) ;CARD READERS
DEFINE RX2DF1(x),<
ASGSVN RX,x,PI1
>;RX2DF1
DEFINE RX2DEF(CPU),<
REPEAT M'CPU'RX20,<
RX2DF1(\"ZZZ)
ZZZ==ZZZ+1
>;;REPEAT
>;RX2DEF
DEFINE GENRX2,<
ZZ==0
ZZZ=="A"
PI1==.CH
REPEAT M.CPU,<
RX2DEF(\ZZ)
ZZ==ZZ+1
PI1==PI1+10
>;;REPEAT
>;GENRX2
GENRX2
>;M.KS10
ASGDEV (M.LP10!M.LP20,LPT,\.CH,0) ;I/O BUS LINE PRINTERS
DEFINE DTADF1(X),<
ASGSVN DT,X,PI1
>
GENDTA
IFE M.DSX&M.TS10,<
ASGDEV (M.TAPE,TAP,\.CH,0) ;MAGTAPES
IFN M.TS10,<
ASGDEV (M.SA10,SAX,\.CH,0) ;SA10 IBM CHANNEL ADAPTER
>; END IFN M.TS10
>; END IFE M.DSX&M.TS10
IFN M.KS10,<
DEFINE CTYDEF(X),<
SPAXGINT CT'X,PI1
>
PI1==.CH
ZZ==0
REPEAT M.CPU,<
CTYDEF \ZZ
ZZ==ZZ+1
PI1==PI1+10
>
>;END IFN M.KS10
IFN M.KL10,<
ASGDEV (M.ENET,KNI,\.CH,0) ;KLNI
; DEFINITIONS FOR THE DTE
XP SPCPI,.CH ;SECONDARY PROTOCOL PI ASSIGNMENT
XP PPCPI,.CH ;PRIMARY PROTOCOL PI ASSIGNMENT
DEFINE DTEDEF(X,Y,PI)<
ASGSV2 D'X'Y,PI
>
ZZ==0
PI1==.CH
REPEAT M.CPU,<
ZZZ==1
REPEAT 4,<
DTEDEF(\ZZ,\ZZZ,\PI1)
ZZZ==ZZZ+1
>
PI1==PI1+10
ZZ==ZZ+1
>
>;END IFN M.KL10
IFN DL10XI,<
;ADD THE DL10 AT THE END OF THE SCANNER CHANNEL. NOW YOU WOULD THINK THAT
; SINCE THE DL10 IS RUN IN VECTORED INTERRUPT MODE, YOU WOULDN'T NEED
; TO LOOK AT THE DL10 AT 40+2*N CONSO TIME BUT IT TURNS OUT THAT YOU
; DO. IT SEEMS THAT SOME (BUT NOT ALL) DL10'S LIKE TO IGNORE THE VECTOR
; ADDRESS AND CAUSE OLD STYLE INTERRUPTS AND EVEN THEN, NOT ALL THE TIME.
; THE DL10 ON OUR DEVELOPMENT SYSTEM ACTS LIKE THIS MOST OF THE TIME.
; IF YOUR DL10 ALWAYS (OR ALMOST ALWAYS) TAKES THE VECTORED INTERRUPT
; THIS CODE IS IN THE RIGHT PLACE (WILL HARDLY EVER GET THIS FAR ON THE
; CONSO SKIP CHAIN). IF IT LIKES TO ACT LIKE A KA-10 DEVICE, MOVE THIS
; UP (BEFORE "PTR" ASSIGNMENTS) TO SERVICE THEM A LITTLE FASTER.
ASGSVE DLX,.CH
IFN M.DAS78,< ;IF WE HAVE DAS78 SUPPORT
XXIN== M.D78L ;NUMBER OF LINES
ASGSAV XXI,.CH
XXON== M.D78L ;NUMBER OF LINES
ASGSAV XXO,0 ;JUST GENERATE DDB'S
> ;END IFN M.DAS78
> ;END IFN DL10XI
IFN M.ANF,<
;DEFINE THE SYMBOLS FOR THE "NETWORK FRONT END" CHANNEL
; NOTE THAT BOTH THE DTE-20 AND THE DL-10 MUST BE ON THE
; SAME CHANNEL
XP NTFCHN,.CH ;THE NETWORK FRONT END CHANNEL
XP NTFBIT,PI.SC7_<7-NTFCHN>
XP NTFIIP,PI.SC7_<7-NTFCHN+^D8> ;INTERRUPT IN PROGRESS
>
NEXTCQ
;THE FOLLOWING ARE LOWER-PRIORITY DEVICES, AS A GROUP
;FIRST ARE THE VARIOUS TYPES OF DISK CONTROLLERS....
ASGDEV (M.DISK,DSK,\.CH,0) ;DISKS
IFN M.DSX&M.TS10,<
ASGDEV (M.SA10,SAX,\.CH,0) ;SA10 IBM CHANNEL ADAPTER
ASGDEV (M.TAPE,TAP,\.CH,0) ;MAGTAPES
>; END IFN M.DSX&M.TS10
IFE M.TS10,<
ASGDEV (M.SA10,SAX,\.CH,0) ;SA10 IBM CHANNEL ADAPTER
>; END IFE M.TS10
IFN M.XTC,<
MULASG XTC,XT,.CH,0
XP XTCBIT,PI.SC7_<7-XT0CHN>
>
ASGSAV PEN,.CH
IFN M.KL10,<
ASGDEV (M.PTP,PTP,\.CH,0) ;PAPER TAPE PUNCHES
> ;END IFN M.KL10
ASGDEV (M.CDP,CPF,\.CH,0) ;CARD PUNCHES (DATA CHANNEL)
ASGDEV (M.PLT,PLT,\.CH,0) ;PLOTTERS
ASGSAV VBC,.CH
NEXTCQ
;THE DISPLAY GETS ITS OWN LOW-PRIORITY CHANNEL
ASGSAV DIS,.CH
NEXTCQ
;THE NETWORK WANT'S TO RUN ON ANY CHANNEL BETWEEN CLOCK(7) AND DISK
IFN M.ANF,<
;DEFINE THE NETWORK SOFTWARE INTERRUPTS. LINK CHAIN ON ALL CPU'S
DEFINE NETDEF(CPU),<
ASGSVE NT'CPU,\<.CH+<CPU_3>>
>
ZZ==0
REPEAT M.CPU,<
NETDEF \ZZ
ZZ==ZZ+1
>
XP NETCHN,NT0CHN
XP NETBIT,PI.SC7_<7-NT0CHN>
XP NETIIP,PI.SC7_<7-NT0CHN+^D8> ;INTERRUPT IN PROCESS
XP REQNET,PI.IIO+NETBIT ;CONO PI,REQDXX REQUEST INTERRUPT
XP CLRNET,II.CPP+NETBIT ;CONO PI,CLRDXX CLEAR INTERRUPT
IFN M.ANF,<ASGSAV NET,0> ;TO GENERATE A DDB AT THE END OF THE LIST
;NOTE!! THIS MUST BE THE LAST DDB.
>
NEXTCQ
;LAST IS THE SCHEDULER, ON CHANNEL 7 BY ITSELF
IFG <.CH-7>, < PRINTX ?NOT ENOUGH PI'S TO SERVICE THIS CONFIGURATION.
PRINTX ?SUGGEST EDITING COMMON TO PUT MORE DEVICES ON
PRINTX ? A SINGLE CHANNEL
>
.CH==7
DEFINE CLKDEF(X)<
CK'X'N==1
ASGINT CK'X,\PI1
>
ZZ==0
PI1==.CH
REPEAT M.CPU,<
CLKDEF(\ZZ)
ZZ==ZZ+1
PI1==PI1+10
>
;NOW FOR SOME PI SYSTEM MASKS FOR DISK, SCANNER, AND NETWORK INTERLOCKS
IFE M.ANF,< ;IF NO NETWORKS
NTFBIT==0 ; DON'T FOOL WITH ANY
NETBIT==0 ; PI CHANNELS
NTFCHN==0 ; ..
NETCHN==0 ; ..
>
IFG M.CPU-1,< ;FOR MULTI-PROCESSORS
XP DSKPIN,DSKPIN!NTFBIT!NETBIT!SCNBIT ;INCLUDE SCANNER AND NETWORKS
XP DSKPIF,DSKPIF!NTFBIT!NETBIT!SCNBIT
XP SCNPIN,DSKPIN!PI.SC7 ;INCLUDE DISKS, NETWORKS, CH7
XP SCNPIF,DSKPIF!PI.SC7
XP NETPIN,DSKPIN!PI.SC7 ;INCLUDE DISKS, SCANNER, CH7
XP NETPIF,DSKPIF!PI.SC7
>
IFE M.CPU-1,< ;FOR SINGLE PROCESSORS
XP SCNPIN,PI.TNP!SCNBIT!NTFBIT!NETBIT!PI.SC7 ;ONLY SCANNER, NETWORKS, CH7
XP SCNPIF,PI.TFP!SCNBIT!NTFBIT!NETBIT!PI.SC7
IFN M.ANF,<
XP NETPIN,PI.TNP!SCNBIT!NTFBIT!NETBIT!PI.SC7 ;ONLY NETWORKS, SCANNER, CH7
XP NETPIF,PI.TFP!SCNBIT!NTFBIT!NETBIT!PI.SC7
>
IFE M.ANF,<
XP NETPIN,PI.TNP!SCNBIT!PI.SC7 ;INCLIDE SCANNER
XP NETPIF,PI.TFP!SCNBIT!PI.SC7 ;AND CH7
>>
IFG M.TAPE,<
;IF THE PROCESSOR DOES A TAPOFF AT UUO LEVEL,
;THE TAPE CH IS TURNED OFF, BUT AN INTERRUPT
;ON THE DSK CH MIGHT STILL BE POSSIBLE (AND OTHERS).
;IF THE INTERRUPT DOES A DSKOFF/DSKON, THE
;TAPE CH MAY BE TURNED BACK ON.
;CURE: MAKE TAPOFF DISABLE DISK INTERRUPTS ETC.
DEFINE XX(AA,BB),<
IFN BB&TAPBIT,<XP AA,AA!BB>>
XP TPION,PI.TNP!TAPBIT
XX TPION,DSKPIN
XX TPION,SCNPIN
XP TPIOFF,PI.TFP!TAPBIT
XX TPIOFF,DSKPIF
XX TPIOFF,SCNPIF
IFN M.ANF,<
XX TPION,NETPIN
XX TPIOFF,NETPIF
>
> ;END IFG M.TAPE
SPCINT
;GENERATE ANY SPECIAL DEVICES CUSTOMER IS SUPPLYING
; WHICH DO NOT USE A CHANNEL SAVE ROUTINE AND HAVE
; NO DEVICE DATA BLOCK
SPCDDB
;GENERATE ANY SPECIAL DEVICES CUSTOMER IS SUPPLYING
;WHICH HAVE MULTIPLE DEVICE DATA BLOCKS (0 MEANS NONE)
SPCSAV
;GENERATE ANY SPECIAL DEVICES CUSTOMER IS SUPPLYING
; WHICH DO NEED A CHANNEL SAVE ROUTINE
;END OF THE ASSIGNMENT TABLE
INTNUM==:INTTAB-. ;-LENGTH OF INTERRUPT CHANNEL ASSIGNMENT TABLE
SUBTTL NON-ZEROED DATA BASE
$ABS
CLKNEW::0 ;FLAG TO FORCE RECOMP OF CLKMIN
CLKMIN::BLOCK M.CPU ;MIN TIME TO EXPIRE FOR THIS CPU
IFNDEF M.PWQC,< ;NUMBER OF EXTRA ENTRIES
IFE FTMP,<M.PWQC==1>
IFN FTMP,<M.PWQC==11>
>
SLJOBN=JOBN+M.PWQC ;NUMBER OF CLOCK ENTRIES
CIPWT:: BLOCK 2*<SLJOBN> ;CLOCK REQUEST QUEUE
;WORD 0 - RH=COUNT DOWN JIFFY TIMER
; - LH=ROUTINE TO CALL
;
;WORD 1 - RH=DATA MEM RETURNED
; - BIT 0=REQUEST IS CPU SPECIFIC
; - BITS 1-3=CPU#
; - BIT 4=SCANNED BY CLOCK1
CIPWTE::! ;FIRST WORD AFTER CIPWT. USED TO CHECK OVERFLOW
CIPWTM==:CIPWT-1 ;FIRST LOC-1 OF CLOCK QUEUE
DIECDB::0 ;POINTER (IN PHYSICAL MEMORY) TO CDB IN USE AT
;STOPCODE TIME. USED TO FACILITATE LOOKING AT
;DUMPS.
;SPECIAL DEVICE SYMBOLS WHICH INVOLVE PI ASSIGNMENTS
; GOAL: MINIMIZE NO. OF SYMBOLS DEFINED HERE:
; DECTAPE PI SYMBOLS
IFN M.DTXN,<
XP DTBOTH,DADCHN*10+DTACHN ;2ND DECTAPE PI
XP DTTURN,300200+DTBOTH
>
; DISPLAY PI SYMBOLS
IFG M.DIS,< ;DISPLAY
XP DISBLK,.E0EPT+40+2*DISCHN ;BLKI/BLKO LOCATION
XP PENPIA,PENCHN*10 ;PEN PI ASSIGNMENT FOR CONO
XP DISBTH,DISCHN+PENPIA ;BOTH DIS AND PEN PIS FOR CONO
XP DISBIT,1
REPEAT 7-DISCHN,<XP DISBIT,DISBIT*2>
>
IFN M.KS10,<
;UBA PI SYMBOLS
XP UBA1PI,DSKCHN*10 ;DISK PI
XP UBA2PI,0 ;UNUSED
XP UBA3PI,<IFDEF TAPCHN,<TAPCHN*10>+SCNCHN> ;TAPE, COMM & UNIT RCD PI'S
XP UBA4PI,0 ;UNUSED
>; END IFN M.KS10
;BLOCKS FOR SAVE/RESTORE OF MAPPING FOR EDDT
IFE FTXMON,<
SYMSIZ==:270
SYMBK1:: BLOCK SYMSIZ ;FILLED IN BY ONCE WITH NEW MAPPING INFO
SYMBK2:: BLOCK SYMSIZ ;WHERE DDT SAVES OLD CONTENTS OF MAP
>; END IFE FTXMON
ASNTAB: BLOCK M.CPU ;CPU SERIAL NUMBERS FOR EDDT
; FILLED IN BY SYSTR0
CNFTBL::! ;SYSTEM CONFIGURATION GETTAB TABLE
CONFIG::SYSNAM ;(000) ASCII
;(001) SYSTEM
;(002) NAME
;(003) (FIVE WORD QUANTITY)
;(004) ...
LOC CONFIG+5
SYSDAT::SYSDAT ;(005) ASCII SYSTEM BUILD DATE
;(006) (TWO WORD QUANTITY)
LOC SYSDAT+2
SYSTAP::SIXBIT /DSK/ ;(007) SIXBIT NAME OF SYSTEM DEVICE
TIME:: EXP 0 ;(010) TIME OF DAY IN JIFFIES
THSDAT::EXP 0 ;(011) TODAYS DATE ((Y-1964)*12+(M-1))*31+(D-1)
SYSSIZ::EXP PAT## ;(012) SIZE OF MONITOR
DEVOPR:: ;(013) SIXBIT NAME OF OPERATORS CONSOLE AT THE
IFNDEF OPRLIN,<SIXBIT /CTY/> ; CENTRAL (PDP10) SITE (IF THIS LOCATION
IFDEF OPRLIN,<OPRLIN> ; CONTAINS ZERO, NONE HAS BEEN DESIGNATED)
DEVLST::EXP 0 ;(014) LH=ADDRESS OF FIRST DEVICE DATA BLOCK
; RH=0
SEGPTR::XWD -SEGN,JOBN ;(015) AOBJN POINTER TO FIRST HIGH SEGMENT IN
; JBTXXX TABLES
EXP -1 ;(016) FLAG TO INDICATE WHETHER BOTH HARDWARE
; AND SOFTWARE HAVE 2 RELOC REG CAPACITY
; NON-ZERO IF BOTH DO, 0 IF EITHER OR BOTH
; DO NOT SET BY ONCE ONLY CODE
;STATES WORD LH BITS:
ZZ==0
ZZ==ZZ!ST.DSK ;DISK SYSTEM
ZZ==ZZ!ST.SWP ;SWAPPING SYSTEM
ZZ==ZZ!ST.LOG ;LOGIN
ZZ==ZZ!ST.FTT ;TTCALL, FULL DUPLEX
ZZ==ZZ!ST.PRV ;PRIVILEGE CHECKING
ZZ==ZZ!ST.TWR ;REENTRANT SOFTWARE
ZZ==ZZ!2B9 ;LEVEL D DISK SOFTWARE (ST.TDS)
IFN INDPPN,<ZZ==ZZ!ST.IND> ;1 IF INDEPENDENT PROJ-PROG NUMBERS
ZZ==ZZ!ST.IMG ;IMAGE, 8-BIT SCNSER
IFG M.CPU-1,<ZZ==ZZ!ST.DUL> ;1 IF DUAL CPU SYSTEM
ZZ==ZZ!ST.MRB ;MULTIPLE RIBS
ZZ==ZZ!ST.HPT ;HIGH PREC.TIME ATTC.
IFG M.RTCO,<ZZ==ZZ!ST.EMO> ;1 IF EXCLUDE MON.OVERHEAD FROM USER RUN TIME
ZZ==ZZ!ST.MBF ;MONITOR BUILT TO HANDLE FOROTS
STATES::EXP ZZ!SCHEDN ;(017) LH=BITS WHICH DEFINE TYPE OF SYSTEM
; RH=SET BY MONITOR "SCHED" COMMAND TO
; INDICATE OPERATIONAL STATE OF SYSTEM
; SEE ST.??? DEFINITIONS IN S.MAC
SERIAL::EXP M.C0SN ;(020) SERIAL NUMBER OF CENTRAL PROCESSOR
MEMNSP::EXP NSPMEM ;(021) NANOSECONDS PER MEMORY CYCLE
PTYPRM::EXP 0 ;(022) PTY PARAMETERS FOR BATCH
FREPTR::EXP 0 ;(023) AOBJN WORD POINTING TO USE BIT MAP OF
; MONITOR 4-WORD CORE BLOCKS
LOCORE::EXP 0 ;(024) ABSOLUTE ADDRESS IN MONITOR OF FIRST
; WORD OF MONITOR TO BE ALLOCATED IN 4
; WORD CHUNKS
STBPTR::EXP 0 ;(025) POINTER NOT USED WITH NETWORKS
OPRLDB::EXP 0 ;(026) LDB OF OPR TELETYPE
TTFREE::EXP 0 ;(027) FILLED IN AT ONCE TIME BY FREE LIST ADR
IFNDEF TTCHKN,<EXTERNAL TTCHKN>
TTCLST::XWD TTCHKN,0 ;(030) LH=NUMBER OF TTY CHUNKS
; RH=ADDRESS OF FIRST ONE
TTFREN::EXP 0 ;(031) NUMBER OF FREE TTY CHUNKS AT THE MOMENT
LINSAV::EXP 0 ;(032) POINTER TO CURRENT TTY SEEN BY COMCON
LINPTR::XWD -TTPLEN##,LINTAB## ;(033) POINTER TO EXAMINE TTY LINE TABLE
MONVER::EXP A00VER ;(034) VERSION OF MONITOR (LH FOR CUSTOMER)
DSCPTR::XWD MDSLN##,DSCTAB## ;(035) POINTER TO DATASET CONTROL TABLE
DLSRWD::EXP 0 ;(036) LAST RECEIVE INTERRUPT FROM DC10
CCIRWD::EXP 0 ;(037) LAST RECEIVE INTERRUPT FROM 680
SEGPT1::EXP JOBN ;(040) LAST DORMANT SEGMENT NUMBER THROWN AWAY
; TO FREE UP A SEGMENT NUMBER
LASPOK::EXP 0 ;(041) CONTAINS ADDRESS OF LAST WORD CHANGED
; IN MONITOR BY A SUCCESSFUL POKE UUO
LASPUC::EXP 0 ;(042) RH=COUNT OF SUCCESSFUL POKE UUOS SINCE
; SINCE SYSTEM WAS LOADED.
; LH=JOB NO. OF LAST JOB WHICH SUCCEEDED
; IN CHANGING MONITOR VIA POKE
WHYCOD::EXP 0 ;(043) CONTAINS SIXBIT UNABBREVIATED OPERATOR
; ANSWER FOR WHY RELOAD ONCE ONLY QUESTION
TICSEC::EXP 0 ;(044) CONTAINS NUMBER OF TICKS PER SECOND
; SET AT ONCE ONLY TIME BY MEASURING LINE
; FREQUENCY (50 OR 60 HERTZ)
PDBPTR: XWD 0,JBTPDB ;(045) RH=POINTER TO TABLE OF PDB'S FOR JOBS
; LH=0 FOR FUTURE EXPANSION
RTCUPS::EXP 0 ;(046) RESOLUTION (UNITS/SEC.) OF CLOCK
; USED FOR RUN TIME ACCOUNTING
; SET & CHANGED BY SETIME
SYSCHN::EXP 0 ;(047) LH=ADR OF FIRST CHANNEL DATA BLOCK
; RH IS UNUSED
LOGMAX::M.JMAX ;(050) MAX JOBS ALLOWED TO BE LOGGED IN
BATMAX::M.BMAX ;(051) MAX BATCH JOBS ALLOWED
BATMIN::M.BMIN ;(052) MIN BATCH JOBS GARENTEED (RESERVED)
DATE:: EXP 0 ;(053) DATE TIME IN NEW FORMAT
; LH = DAYS SINCE NOV. 17, 1858,
; RH = FRACTION OF A DAY (GMT)
LOGNUM::EXP 0 ;(054) NUMBER JOBS CURRENTLY LOGGED IN
BATNUM::EXP 0 ;(055) NUMBER BATCH JOBS CURRENTLY LOGGED IN.
LOCYER::EXP 0 ;(056) LOCAL YEAR
LOCMON::EXP 0 ;(057) LOCAL MONTH (1,2,...,12)
LOCDAY::EXP 0 ;(060) LOCAL DAY OF MONTH (1,2,3,...)
LOCHOR::EXP 0 ;(061) LOCAL HOUR (MIDNIGHT=0)
LOCMIN::EXP 0 ;(062) LOCAL MINUTE (0,1,...,59)
LOCSEC::EXP 0 ;(063) LOCAL SECOND (0,1,...,59)
GMTDIF::EXP 0 ;(064) DIFFERENCE BETWEEN LOCAL AND GMT TIME.
; IN SAME UNITS AS DATE --
; E.G. DATE + GMTDIF = LOCAL DATE-TIME
; (LH = DAY, RH = FRACT. OF DAY)
DEBUGF::EXP DEFDEB!DEFBPT ;(065) DEBUGGING STATES WORD
; SEE DF.??? DEFINITIONS IN S.MAC
FRUSED::EXP 0 ;(066) AMOUNT OF FREE CORE IN USE
; (FTRSP CONDITIONAL)
RCCMAX::EXP 0 ;(067) HIGHEST ADDRESS USED BY TTY CHUNKS
CNFCVN::EXP A00CVN ;(070) CUSTOMER VERSION (=C(136))
CNFDVN::EXP AXXDVN ;(071) DEC VERSION (=C(137))
CNFCHN::EXP 0 ;(072) NUMBER OF DATA CHANNELS
CNFRTD::EXP M.RTD ;(073) NUMBER OF REAL TIME DEVICES
CNFHPQ::EXP M.HPQ ;(074) NUMBER OF HPQ'S
CNFLDB::EXP DDBLDB## ;(075) WORD IN TTY DDB WHICH POINTS TO LDB
CNFMVO::EXP PSIMVO ;(076) MAX. VECTOR OFFSET FOR PISYS. UUO
CNFMIP::EXP PSIMPI ;(077) MAX. PRIORITY FOR PSISER
CNFMTA::EXP 0 ;(100) POINTER TO FIRST MTA DDB AND INDEX
; OF START OF DAEMON INFORMATION
CNFET1: EXP JOBDAC##+T1 ;(101) EXEC AC1 IN USER'S ADDRESS SPACE
CNFLSD: EXP DEVLSD ;(102) LENGTH OF SHORT DDB
CNFLLD: EXP DEVLLD ;(103) LENGTH OF LONG DDB
CNFLDD: EXP DDBLEN## ;(104) LENGTH OF DISK DDB
CNFEXM: EXP JOBEXM## ;(105) WORD IN JOBDAT WHICH HOLDS ADDRESS OF
; LAST EXAMINE OR DEPOSIT.
ZZ==0
ZZ==ZZ!1B35 ;BIT 35=1 IF SWAP SPACE ALLOCATED IN PAGES
ZZ==ZZ!1B34 ;BIT 34=1 IF MTA ERROR REPORTING
ZZ==ZZ!1B33 ;BIT 33=1 IF VM MONITOR
IFN M.IPCF,<ZZ==ZZ!1B32> ;BIT 32=1 IF IPCSER IS LOADED
IFN M.PSI,<ZZ==ZZ!1B31> ;BIT 31=1 IF PSISER IS LOADED
IFN M.MPX,<ZZ==ZZ!1B30> ;BIT 30=1 IF MPXSER IS LOADED
ZZ==ZZ!1B29 ;BIT 29=1 IF NON-SUPER ENTER IS SUPPORTED
IFN FTNSCHED,<ZZ==ZZ!1B28> ;BIT 28=1 IF NEW SCHEDULER IS PRESENT
IFN M.EQDQ,<ZZ==ZZ!1B27> ;BIT 27=1 IF ENQ/DEQ IS LOADED
IF2, <ZZ==ZZ!<<ZGAL>B26>> ;BIT 26=1 IF GALAXY-10 FEATURES
ZZ==ZZ!1B25 ;BIT 25=1 MASSBUS ERROR REPORTING
ZZ==ZZ!1B24 ;BIT 24=1 IF NEW TAPSER
ZZ==ZZ!1B23 ;BIT 23=1 IF NEW ERROR REPORTING
ZZ==ZZ!1B22 ;BIT 22=1 IF MORE THAN 127 JOBS SUPPORTED
IFN M.EXE,<ZZ==ZZ!1B21> ;BIT 21=1 IF "SAVE" COMMAND PRODUCES EXE FILE
IFN M.EMRT,<ZZ==ZZ!ST%EMR> ;BIT 20=1 IF EBOX/MBOX RUNTIME IS IN EFFECT
IFN M.XPI,<ZZ==ZZ!ST%XPI> ;BIT 19=1 IF PI TIME EXCLUDED FROM USER RUNTIME
ZZ==ZZ!1B18 ;BIT 18=1 IF FULL 6 CHAR DEVICE NAMES
IFN M.ITA,<ZZ==ZZ!ST%ITA> ;BIT 17=1 IF INTERVAL TIMER IS AVAILABLE
IFE M.CLSS,<ZZ==ZZ!ST%NCS> ;BIT 16=1 IF NOT CLASS SYSTEM SCHEDULER
ZZ==ZZ!ST%NER ;BIT 15=1 MONITOR SUPPORTS 6.03 ERROR REPORTING
IFN M.ACV,<ZZ==ZZ!ST%ACV> ;BIT 14=1 IF ACCOUNT VALIDATION SHOULD BE DONE
ZZ==ZZ!ST%LSC ;BIT 13=1 IF LOW SEGMENT OF MONITOR IS CACHED
IFN FTMDA,<ZZ==ZZ!ST%MDA> ;BIT 12=1 IF MOUNTABLE DEVICE ALLOCATOR SUPPORT
ZZ==ZZ!1B11 ;BIT 11=1 IF KL PAGING
IFN M.DECN,<ZZ==ZZ!1B10> ;BIT 10=1 IF DECNET LOADED
IFN FTXMON,<ZZ==ZZ!1B9> ;BIT 9=1 IF EXTENDED ADDRESSING MONITOR
IFN M.RCMP,<ZZ==ZZ!1B8> ;BIT 8=1 IF RESTRICTED COMMAND SET FOR REMOTES
IFN M.NPPC,<ZZ==ZZ!ST%NPP> ;BIT 7=1 IF DISABLING PRIMARY PROTOCOL
IFN M.DECN,<ZZ==ZZ!0B6> ;BIT 6=1 IF RUNNING AS DECNET ENDNODE (SET
; BY DECNET INITIALIZATION CODE)
CNFST2::EXP ZZ ;(106) FLAG BITS DEFINED ABOVE
EXP M.PSI*C$MIN ;(107) MINIMUM CONDITION FOR PISYS.UUO
EXP PITSIZ ;(110) LENGTH OF PI TABLE
CNFPIA::EXP JBTPIA ;(111) ADDRESS OF JBTPIA
%CNMNT: BYTE (1)0(17)0(6)1(6)0(6)0 ;(112) TYPE OF MONITOR
; (1)=STRANGE
; (17)=RESERVED TO DEC
; (6)=TYPE: 1=TOPS-10
; 2=I.T.S.
; 3=TENEX
; REST RESERVED TO DEC
; (6)=SUBTYPE (RESERVED TO DEC)
; (6)=RESERVED TO CUSTOMERS
CDROCR::EXP 0 ;(113) OFFSET TO CARD COUNT FOR CDR
CDPOCC::EXP 0 ;(114) OFFSET TO CARD COUNT FOR CDP
EXP PAGSIZ ;(115) BASIC UNIT OF CORE ALLOCATION
EXP MINMAX ;(116) MINIMUM VALUE FOR CORMAX
EXP M.CLSN ;(117) NUMBER OF SCHEDULER CLASSES
EXP 0 ;(120) EXPONENTIAL FACTOR FOR COMPUTING
; USER TIME
SYSORG::EXP 0 ;(121)
SYSLEN::EXP 0 ;(122)
NWCORE::EXP 2000*M.NKC ;(123) NUMBER OF WORDS OF CORE
NXMPTR::EXP 0 ;(124) AOBJN POINTER TO NXMTAB USED TO
; SCAN FOR ZEROES
EXP NETNDB## ;(125) POINTER TO THE FIRST NODE BLOCK
EXP 0 ;(126) OBSOLETE
EXP 0 ;(127) OBSOLETE
HNGLST::XWD 0,0 ;(130) LH = COPY OF DEVLST
; RH = UNUSED
EXP BOOTXT ;(131) ADDRESS OF RELOAD CCL TEXT
TAPDDP::EXP 0 ;(132) OFFSET OF DDB ADDRESS IN TUB
EXP 0 ;(133) OBSOLETE
NOCPUS::EXP M.CPU ;(134) NO OF CPUS MONITOR WAS BUILT FOR
XWD PJBNLH,DEVJOB ;(135) GETTABLE PJOBN (SANS INDEX FIELD)
SYSUPT::EXP 0 ;(136) SYSTEM UPTIME IN TICKS
BOOTCP::EXP -1 ;(137) BOOT CPU NUMBER
BOOTCT::EXP CTYLIN## ;(140) BOOT CPU CTY LINE NUMBER
NCPRUN::EXP M.CPU ;(141) NUMBER OF CPUS ALLOWED TO RUN
STRMON::SIXBIT /SYS/ ;(142) FILE STRUCTURE MONITOR WAS BOOTED FROM
FILMON::SIXBIT /SYSTEM/ ;(143) FILE NAME
EXTMON::SIXBIT /EXE/ ;(144) EXTENSION
PPNMON::XWD 1,4 ;(145) PPN
SYSNBP::EXP MAXNBP ;(146) MAXIMUM NUMBER OF BREAK POINTS SETTABLE
; BY THE SNOOP. UUO
MONVFF::EXP MONORG ;(147) FIRST FREE VIRTUAL ADDRESS ABOVE MONITOR
LDBVRG::EXP 0 ;(150) VIRTUAL ADDRESS OF THE ORGIN OF LDBS
FOPHXC::EXP HIGHXC-20 ;(151) NUMBER OF EXTENDED CHANNELS AVAILABLE
; VIA THE FILOP. UUO
MONHSO: EXP MONORG ;(152) VIRTUAL ADDRESS OF START OF MONITOR
; HIGH SEGMENT
RSDTTM::EXP 0 ;(153) UNIVERSAL DATE/TIME OF LAST ROLE SWITCH
; ON MULTIPLE CPU SYSTEMS
CNFDCH: EXP LDBDCH## ;(154) OFFSET OF LDBDCH IN LDB'S
SFDMON::EXP 0 ;(155) 1ST SFD MONITOR WAS BOOTED FROM
EXP 0 ;(156) 2ND SFD MONITOR WAS BOOTED FROM
EXP 0 ;(157) 3RD SFD MONITOR WAS BOOTED FROM
EXP 0 ;(160) 4TH SFD MONITOR WAS BOOTED FROM
EXP 0 ;(161) 5TH SFD MONITOR WAS BOOTED FROM
EXP FRCLIN## ;(162) TTY LINE NUMBER OF FRCLIN
PTYPTR::EXP 0 ;(163) POINTER TO PTY TABLE
-LATLEN##,,NETLAT## ;(164) -LENGTH,,LOCATION LINK ADDRESS TABLE
CNFLPD: EXP .PDLEN ;(165) LENGTH OF A PDB
XWD 0,PAGSIZ ;(166) LH=FLAG
; RH=SIZE OF LARGEST JOBPEK TRANSFER
; WHERE FLAG=0 IF SWAP SPACE JOBPEKS MAY
; NOT CROSS A PAGE BOUNDARY AND FLAG=1
; IF THEY MAY
EXP CNFDAE ;(167) LH=OLD DAEMON NAME
; RH=CURRENT MONITOR VERSION
; OLD DAEMON NAME IS THE SIXBIT NAME
; OF THE PREVIOUS MONITOR, E.G. 701
CNFHSH::XWD -HSHLEN,HSHTAB ;(170) AOBJN POINTER TO HSHTAB
EXP .PDACS ;(171) OFFSET IN PDB FOR ACCOUNT STRING
TOPLN1##,,TOPTB1## ;(172) POINTER TO TOPTB1, TRMOP DISPATCH
EXP JBTSFD## ;(173) POINTER TO JBTSFD
EXP CIPWT ;(174) POINTER TO CLOCK QUEUE
ND PRVPRV,<-1,,0> ;DEFINE DEFAULT PRIVS
CNFPRV::EXP PRVPRV ;(175) DEFINE PRIVED JOB PRIVS
IFN M.DECN,<
CTHREV::CTHR ;(176) CTERM HOST REVISION STRING
;(177) (TWO WORD QUANTITY)
>
IFE M.DECN,<
CTHREV::EXP 0,0 ;(176) NO CTERM SUPPORT
;(177) (TWO WORD QUANTITY)
>
LAHNDB::EXP 0 ;(200) LAT HOST NODE DATA BASE ADDRESS
EXP OUTMSK ;(201) 'AND' MASK FOR JBTIMI/JBTIMO/JBTVIR
; TO REDUCE TO ACTUAL PAGE COUNT
.LNKEND .LKACB,SYSACB
SYSACB::EXP 0 ;(202) FIRST ALLOCATION CONTROL BLOCK ADDRESS
.LNKEND .LKAHB,SYSAHB
SYSAHB::EXP 0 ;(203) FIRST ALLOCATION HEADER BLOCK ADDRESS
EXP IPKDDB ;(204) OFFSET OF DRAM DUMP BUFFER IN IPA20 KDB
DEFTTT::EXP M.DTTT ;(205) DEFAULT TTY TYPE FOR SYSTEM
SYSUTM::EXP 0 ;(206) SYSTEM UPTIME IN MILLISECONDS
CNFREM: EXP LDBREM## ;(207) OFFSET OF LDBREM IN LDB'S
CNUK4S: EXP UNIK4S ;(210) OFFSET OF UNIK4S IN UDB'S
STOPTN::EXP 0 ;(211) STARTUP OPTION
CNFMXL==:<.-CNFTBL-1>B26 ;MAXIMUM ENTRY IN CNFTBL FOR GETTAB UUO
LOWLIM::EXP 0 ;HIGHEST POSSIBLE ADDRESS IN LOW SEGMENT
USRCOR::EXP 0 ;TOTAL AMOUNT OF USER CORE AVAILABLE
; NOT CURRENTLY UPDATED BY SET MEMORY OFF
;----------------------------------
;INSERT HERE ANY NEW LOCATIONS OF INTEREST WHICH ARE SET UP BY ONCE ONLY CODE.
; OR ARE CONSTANTS WHICH ARE NOT CLEARED AT STARTUP
;-------------------------------------
DEBCPU::EXP -1 ;CPU NUMBER OF BOOT CPU FOR DEBUGGING SMP
WHYTXT::BLOCK <WHYSIZ==:20> ;WHY RELOAD TEXT
WHYMXL==:<WHYSIZ-1>B26 ;LENGTH FOR GETTAB
TICMIN::EXP 0 ;NUMBER OF TICKS PER MINUTE
;(CALCULATED BY ONCE)
TIMLST::0 ;VALUE OF "TIME" LAST TIME AT CLOCK LEVEL
; USED FOR ALL TIMING FUNCTIONS, E.G.,
; MAINTAINING CLOCK QUEUE AND SMITHSONIAN DATE
IFN M.KL10,<
NULJPC::EXP XC.USR+IC.LIP+1 ;PC FOR THE NULL JOB
NULDOP::EXP LG.LUB+LG.IAM+NLUPMP/PAGSIZ
>
IFN M.KS10,<
NULJPC::EXP XC.USR+IC.LIP+1
NULDOP::EXP SG.LUB+NLUPMP/PAGSIZ
>
SYSBPJ::0 ;SNOOP.ING JOB
SYSBPP::0 ;ADDRESS OF BREAK POINT TABLE,, NUMBER OF BREAK POINTS
MSTCKS::0 ;MONITOR SYMBOL TABLE CHECKSUM
LOWLOC::0
ONCCOM::0
IFN M.KL10,<
LOWLEN==<IOWNUM+^D143>/^D144
LOWPTR::XWD -LOWLEN,LOWTAB
LOWTAB: BLOCK LOWLEN
>
NXMTBL==:<CORBLK+^D35>/^D36
NXMTAB::BLOCK NXMTBL ;TABLE USED TO RECORD WHICH PAGES OF MEMORY EXIST
NXMMXL==:<NXMTBL-1>B26 ;MAXIMUM ITEM FOR GETTAB
CORLIM::EXP COREN
OMSMIN::EXP M.OMSM ;# MINUTES REMAINING BEFORE NEXT CALL
; TO BIGBEN
OMSINI::EXP M.OMSM ;TIME BETWEEN CALLS
SEGPT2::EXP JOBN ;ROUND ROBIN OVER IN-CORE DORMANT SEGMENTS
IFNDEF MFRHPQ,<MFRHPQ==2>;DEFAULT IS 2
FRSHPQ::EXP MFRHPQ ;MINIMUM HPQ FORCING SCHED
IFNDEF STHLOG,<STHLOG==0>
STHFLG::EXP STHLOG ;IF NON-ZERO,NRT CAN RUN W/O LOGIN
CLPTOP::0 ;POINTER TO BEGINNING OF CLP LIST
CLPBOT::CLPTOP ;POINTER TO END OF CLP LIST
IFN FTKL10&<FTSCA!FTENET>,<
IPAMSK::0 ;BIT MASK TO SKIP STARTING IPA DEVICE
; LH = CI (CPU0=1B17, CPU1=1B16, ETC.)
; RH = CI (CPU0=1B35, CPU1=1B34, ETC.)
>; END IFN FTKL10&<FTSCA!FTENET>
CSBLEN::0 ;LENGTH OF COMMON SUBROUTINES SEGMENT
;BITMAP MEMORY DEFINITIONS
IFN FTSCA,<
SCALOC::EXP 0 ;STARTING ADDRESS OF SCA FREE CORE
SCABTL==<SCASIZ+^D143>/^D144 ;SIZE OF THE BIT MAP FOR SCA FREE CORE
SCAPTR::XWD -SCABTL, .+1 ;AOBJN POINTER TO SCA FREE CORE BIT MAP
BLOCK SCABTL ;THE MAP ITSELF
>; END IFN FTSCA
;INTERLOCK WORDS AND OWNER WORDS MUST BE IN THE SAME ORDER
; "INTRLK" MUST BE FIRST
IFN FTMP,<
INTERN INTL0,INTO0
INTRLK::-1 ;CPU PI SYSTEM INTERLOCK
SCDLOK::-1 ;SCHEDULER INTERLOCK
SCNLOK::-1 ;SCNSER INTERLOCK
INTRDD::-1 ;DDB-SCAN INTERLOCK
INTRST: -1 ;CPU START-UP INTERLOCK
INTRUU::-1 ;GENERAL UUO-LEVEL LOCK
INTRDC::-1 ;DISK CACHE INTERLOCK
INTRDS::-1 ;DSKOFF INTERLOCK
INTRTP::-1 ;TAPOFF INTERLOCK
NETLOK::-1 ;USED IN NETOFF,NETOM MACROS
NTLOCK::-1 ;THE NETSER INTERLOCK
INTLBT::-1 ;BIT DIDDLER INTERLOCK (SETOS,CLRBTS)
IFN FTKL10,<
INTLNB::-1 ;BUFFER (CACHE) MANAGEMENT INTERLOCK
>
IFN FTDECNET,<
SCTLOK::-1 ;DECNET'S SESSION CONTROL INTERLOCK
NSPLOK::-1 ;DECNET'S NSP INTERLOCK
>
IFN FTSCA,<
INTLSC::-1 ;SCA BUFFER MANAGEMENT INTERLOCK
>; END IFN FTSCA
IFN FTENET,<
ETHLOK::-1 ;ETHERNET INTERLOCK
>; END IFN FTENET
IFN FTPATT,< ;FOR PATCHING
INTRP1::-1
INTRP2::-1
>
INTRCL::-1 ;CLOCK QUEUE PROCESSING
DEFINE INTLK(A,B)<
IFE A,<INTL'B: -1> ;PI LEVEL B ON CPU A PI INTERLOCK
IFN A,<INTL'A'B: -1>>
ZZ==0
REPEAT M.CPU,<
ZZZ==0
REPEAT 10,<
INTLK(\ZZ,\ZZZ)
ZZZ==ZZZ+1>
ZZ==ZZ+1>
;OWNING CPU OF INTERLOCKS (CONI PAG OR APRID)
INTOLK::-1 ;CPU PI-SYSTEM
INOSCD::-1 ;SCHEDULER
INOSCN::-1 ;SCNSER
INTODD::-1 ;DDB-SCAN
INTOST::-1 ;CPU START-UP
INTOUU::-1 ;GENERAL UUO-LEVEL
INTODC::-1 ;DISK CACHE
INTODS::-1 ;DSKOFF
INTOTP::-1 ;TAPOFF
INONET::-1 ;NETOFF
INONT:: -1 ;NETSER
INTOBT::-1 ;BIT DIDDLERS
IFN FTKL10,<
INTONB::-1 ;BUFFER (CACHE) MANAGEMENT
>
IFN FTDECNET,<
SCTLKO::-1 ;DECNET'S SESSION CONTROL
NSPLKO::-1 ;DECNET'S NSP INTERLOCK
>
IFN FTSCA,<
INTOSC::-1 ;SCA BUFFER MANAGEMENT OWNER
>; END IFN FTSCA
IFN FTENET,<
INOETH::-1 ;ETHERNET
>; END IFN FTENET
IFN FTPATT,< ;FOR PATCHING
INTOP1::-1
INTOP2::-1
>
INTOCL::-1 ;CLOCK QUEUE PROCESSING
DEFINE INTLKO(A,B)<
IFE A,<INTO'B:-1>
IFN A,<INTO'A'B:-1>>
ZZ==0
REPEAT M.CPU,<
ZZZ==0
REPEAT 10,<
INTLKO(\ZZ,\ZZZ)
ZZZ==ZZZ+1>
ZZ==ZZ+1>
;NOT CORRESPONDING TO ABOVE INTERLOCKS
SCNOWN::-1 ;OWNER OF SCNCNT (.CPCPU)
INTLMO::-1 ;OWNER OF THE MEMORY MANAGEMENT RESOURCE (APRID)
INTDIE::-1 ;DIE INTERLOCK
INODIE::-1 ;DIE OWNER
DIEFLG::0 ;DIE TYPE (-1=STOPCD, +1=EVENT, 0=UNKNOWN)
>;END FTMP
IFE FTMP,<
NTLOCK::-1 ;NTLOCK EXISTS ON SINGLE CPU'S TOO
SCTLOK::-1 ;DECNET INTERLOCKS EXIST ON SINGLE CPU's TOO
NSPLOK::-1
RTRLOK::-1
SCTLKO::-1
NSPLKO::-1
INTRDC::-1
RTRLKO::-1
>
;GETTAB TABLE OF QUEUE CODES FOR JOBS - TABLE(RH)=25
;MUST BE A SEPARATE TABLE SINCE THE NUMBER OF ENTRIES VARIES ACCORDING
;TO THE CONFIGURATION
;ENTRIES ARE 2 SIXBIT CHARACTERS, THREE PER WORD
;STATE CODE 0 IS LEFT THIRD, 1 IS MIDDLE THIRD, 2 IS RIGHT THIRD OF FIRST WORD
;STATE CODE 3 IS LEFT THIRD OF SECOND WORD, ETC.
STSTBL::
DEFINE X(A,B,C)
< IFE ZZ-ZZ/3*3-0,
< XX== <SIXBIT /A/&7777B11>B35>
IFE ZZ-ZZ/3*3-1,
< XX==XX!<SIXBIT /A/&7777B11>B47>
IFE ZZ-ZZ/3*3-2,
< XX==XX!<SIXBIT /A/&7777B11>B59
EXP XX>
ZZ==ZZ+1
>
ZZ==0
QUEUES
RWAITS
CODES
IFN ZZ-ZZ/3*3-0,<
EXP XX>
STSMXL==:<.-STSTBL-1>B26 ;MAX ENTRY IN STSTBL FOR GETTAB UUO
ODPTBL::! ;FIRST LOCATION IN MONITOR DATA AREA FOR DISK-
; RELATED LOCATIONS WHICH ARE NOT SET TO 0 WHEN
; THE SYSTEM IS STARTED UP.
; ODPTBL IS GETTAB UUO TABLE NUMBER 15.
SWPHGH::0 ;(0) HIGHEST LOGICAL BLOCK # ASSIGNED FOR SWAPPING.
; SPACE IS ASSIGNED FROM HIGHEST BLOCK # DOWNWARDS.
K4SWAP::0 ;(1) # OF K OF DISK WORDS SET ASIDE FOR SWAPPING.
; ASSIGNED AT ONCE ONLY REFRESH TIME.
KXFTIM==0 ;SET PROTECT TIMES TO 0
SEEKTM==0 ;ONCE ONLY CODE MUST SET PROT,PROT0
;DEPENDING ON FASTEST UNIT USED FOR SWAPPING
PROT:: EXP 0 ;(2) IN-CORE PROTECT TIME PARAMETER TO BE
; MULTIPLIED BY <K-1> OF CORE IN JOB.
PROT0:: EXP 0 ;(3) IN-CORE PROTECT TIME PARAMETER TO
; BE ADDED TO ABOVE RESULT.
PROT1:: EXP 0 ;(4) SWAPPABLE CYCLING TIME
PROTM:: EXP 0 ;(5) MAXIMUM IN-CORE PROTECT TIME
;INSERT HERE ANY NEW LOCATIONS OF INTEREST WHICH ARE SET UP BY
; ONCE ONLY CODE AND WHICH PERTAIN ONLY TO DISK SYSTEMS.
ODPMXL==:<.-ODPTBL-1>B26 ;MAXIMUM ENTRY IN ODPTBL FOR GETTAB UUO
;DISK LOCATIONS NOT IN GETTAB
REFLAG::Z ;FLAG LOCATION TO INDICATE WHETHER ANY REFRESHING
; OCCURRED AND TO CONTAIN THE [PROJ,PROG]
; NUMBERS FOR AUTOMATIC LOG-IN FOLLOWING REFRESH.
;MORE DATA LOCATIONS SETUP AT ASSEMBLY TIME OR ONCE ONLY TIME
; BUT NOT OF INTEREST TO USER PROGRAMS
$HIGH
XJBPFI::XWD JOBPFI##,0 ; JOBPFI==HIGHEST LOC, IN USER JOB DATA AREA
; PROTECTED FROM I/O
;MONTH TABLE FOR DAYTIME COMMAND PRINTING
PMONTB::POINT 6,MONTAB(T1),5 ;POINTER TO NUMBER OF DAYS IN MONTH
MONTAB::EXP ^D30B5+"Jan"
EXP ^D27B5+"Feb"
EXP ^D30B5+"Mar"
EXP ^D29B5+"Apr"
EXP ^D30B5+"May"
EXP ^D29B5+"Jun"
EXP ^D30B5+"Jul"
EXP ^D30B5+"Aug"
EXP ^D29B5+"Sep"
EXP ^D30B5+"Oct"
EXP ^D29B5+"Nov"
EXP ^D30B5+"Dec"
;DAY TABLE FOR DAYTIME COMMAND AND ONCE
DAYTAB::[ASCIZ/Wednesday/] ;INDEXED BY UDT REMAINDER
[ASCIZ/Thursday/] ;
[ASCIZ/Friday/] ;
[ASCIZ/Saturday/] ;
[ASCIZ/Sunday/] ;
[ASCIZ/Monday/] ;
[ASCIZ/Tuesday/] ;
MIDNIT::EXP 0 ;JIFFIES TILL MIDNIGHT (CALCULATED BY ONCE)
IFN FTMP,<
COKTAB::BLOCK M.CPU ;TABLE TO SET THE POLICY CPU'S OK WORD
;(INDEX BY THE NUMBER OF RUNNING CPUS-1)
> ;END IFN FTMP
$ABS
;TABLE OF SCHEDULER STATISTICS (CAN BE USED TO HELP TUNE SYSTEM)
.GTSST::! ;SCHEDULER STATISTICS TABLE - #115
FORCFC::0 ;(0)COUNT OF TIMES SCHEDULER RAN A JOB
;OUT OF ORDER SO THAT IT WOULD RELEASE
;A SHARABLE RESOURCE IN ORDER THAT IT
;COULD BE SWAPPED OUT.
UNWNDC::0 ;(1)COUNT OF TIMES SCHEDULER RAN A JOB
;OUT OF ORDER BECAUSE ANOTHER JOB HAS BEEN
;SELECTED THAT NEEDS A SHARABLE DISK
;RESOURCE THE FIRST JOB OWNED
SWPNUL::0 ;(2)SWAPPER NULL TIME (TIME WHEN SWAPPING
;LOGIC COULD NOT FIND ANYTHING TO DO.)
SWPLOS::0 ;(3)SWAPPER LOST TIME (TIME THAT SWAPPER
;WANTED TO SWAP A JOB IN BUT COULDN'T
RQCNT::0 ;(4)NUMBER OF PHYSICAL REQUEUES SINCE
;SYSTEM STARTUP
MCUINT::0 ;(5)INTERVAL AT WHICH MINIMUM CORE
;USAGE FUNCTION IS CALCULATED.
;ZERO MEANS DO NOT CALCULATE
SCDINT::0 ;(6)MICRO SCHEDULING INTERVAL. ZERO
;MEANS RUN ROUND ROBIN IGNORING CLASSES.
AVJSIZ::0 ;(7)AVERAGE JOB SIZE COMPUTED ONCE A MINUTE
TOTRTC::0 ;(10)TOTAL RUNTIME GIVEN TO ALL SUBCLASSES
;DOES NOT INCLUDE ANY PQ1 OR HPQ TIME
SCDEXF::0 ;(11)EXPONENTIAL FACTOR USED FOR COMPUTING
;EXPONENTIALLY AVERAGED RUNTIME FOR
;CPU CLASSES
UTMEAR::0 ;(12)EXPONENTIALLY AVERAGED USER TIME USED
;FOR THE ENFORCEMENT OF QUOTAS
RTCTOT::0 ;(13)TOTAL USER RUNTIME SINCE LAST
;SCHED UUO SET CLASS PARAMETERS
DEFCLS::M.DCLS ;(14)DEFAULT CLASS FOR NEW JOBS
SCDJIL::0 ;(15)PERCENT OF TIME SCHEDULER SCANS
;JUST SWAPPED IN QUEUE BEFORE SUBQUEUES
SCDSWP::0 ;(16)MINIMUM NUMBER OF TICKS
;SWAPPER SCANS THE SAME PRIMARY SUBQUEUE
BBSUBQ::0 ;(17)BACKGROUND BATCH SUBQUEUE
SCDBBS::0 ;(20)NUMBER OF TICKS BETWEEN
;BACKGROUND BATCH SWAPS
SCDIOF::0 ;(21)PERCENT OF TIME THAT SWAPPER SCANS PQ2
;INCORE CHAIN BEFORE OUTCORE CHAIN
SCDSET::0 ;(22)FLAG = 0 IF RUNNING ROUND ROBIN
;= DATE/TIME WHEN CLASS RUNTIME TABLE
;INITIALIZED IF RUNNING IN CLASS MODE
RRFLAG::0 ;(23)FLAG = 0 IF RUNNING ROUND ROBIN SCHEDULER
;= CNTSTS IF CLASS SCHEDULING
SCDCOR::0 ;(24) TIME TO WAIT AFTER SWAPPING OUT
;A RUNNABLE JOB BEFORE SETTING CORSCD
;FLAG
SSDMXL==:<.-.GTSST-1>B26 ;MAXIMUM LENGTH OF TABLE FOR GETTABS
;IPCF COMMON DATA
IFN M.IPCF,<
IFNDEF M.PKTL,<M.PKTL==12>
%IPMPL==:M.PKTL ;MAXIMUM PACKET LENGTH
IFNDEF M.PIDN,<XP M.PIDN,JOBN*2>
XP MIDMXL,<<M.PIDN>B26> ;FOR GETTAB
ND M.IPCR,5 ;DEFAULT RECEIVE QUOTA
ND M.IPCS,2 ;DEFAULT SEND QUOTA
ND M.IPCP,2 ;DEFAULT PID QUOTA
PIDMSK==JOBN
IFG <M.PIDN-JOBN>,<PIDMSK==M.PIDN> ;MAX (JOBN,M.PIDN)
PIDMSK==<1B<^L<PIDMSK>-1>>-1 ;MAKE INTO MASK
; MACRO TO DEFINE EXEC PROCESS PIDS
DEFINE PIDS,<
ZZ==0 ;;INIT COUNTER
X (IPC) ;;[SYSTEM]IPCC
X (GFR) ;;[SYSTEM]GOPHER
> ;END PID MACRO
DEFINE X (NAM),<XWD <NAM'PID==<ZZ==ZZ+1>>,0>
PIDTAB::PIDS ;GENERATE EXEC PROCESS PID ENTRIES
%IPCNS==:.-PIDTAB ;NUMBER OF SYSTEM PROCESSES
XLIST
REPEAT <M.PIDN-%IPCNS>,<Z> ;REMAINDER OF TABLE ZERO
LIST
DEFINE X (NAM),<EXP NAM'ADR>
EXPROC::PIDS ;GENERATE POINTERS TO EXEC PROCESS IPCF DATA
; EXEC PROCESS CONTROL BLOCK FOR [SYSTEM]IPCC
IPCADR: Z ;.EPIPC
Z ;.EPIPA
XWD 200000,-1 ;.EPIPQ
Z ;.EPIPL
Z ;.EPPID
Z ;.EPIPI
Z ;.EPIPN
Z ;.EPQSN
Z ;.EPEPA
IFIW IPCFPR## ;.EPADR
; EXEC PROCESS CONTROL BLOCK FOR [SYSTEM]GOPHER
GFRADR: Z ;.EPIPC
Z ;.EPIPA
XWD 200000,-1 ;.EPIPQ
Z ;.EPIPL
Z ;.EPPID
Z ;.EPIPI
Z ;.EPIPN
Z ;.EPQSN
Z ;.EPEPA
IFIW IPCSPR## ;.EPADR
EXTERN IPCSER
IPCTAB:: ;MISCELLANEOUS IPCF DATA
%CNIPL:: %IPMPL ;(0) MAX PACKET LENGTH
%CNIPI:: Z ;(1) PID OF SYS:INFO (0=NONE)
%CNIPQ::BYTE (2)1(16)(9)M.IPCS,M.IPCR ;(2) DEFAULT QUOTAS + IP.HBS BIT
%CNIPS:: Z ;(3) TOTAL PACKETS SENT
%CNIIP:: Z ;(4) NUMBER OF PACKETS OUTSTANDING
%IPCFP:: IPCPID,,0 ;(5) PID OF [SYSTEM]IPCC
%IPCPM:: PIDMSK ;(6) MASK FOR PID
%IPCMP:: M.PIDN ;(7) LENGTH OF PID TABLE
%IPCNP:: %IPCNS ;(10) CURRENT NUMBER OF PID'S
%IPCTP:: %IPCNS ;(11) TOTAL PID'S SINCE RELOAD
%CNPIC:: Z ;(12) NUMBER OF IPCF PAGES CURRENTLY IN CORE
%IPCSP:: GFRPID,,1 ;(13) PID OF [SYSTEM]GOPHER
%IPTWT:: Z ;(14) TOTAL WORDS PASSED (NON-PAGE MODE)
%IPTPT:: Z ;(15) TOTAL PAGES PASSED
%IPOPP:: .IPCFD## ;(16) OVERHEAD PER PACKET
%CNIPD:: M.IPCP ;(17) DEFAULT PID QUOTA
IPCMXL==:<.-IPCTAB-1>B26 ;FOR GETTAB
$HIGH
.GTQFC:: ;CUSTOMER SPECIAL QUEUE. FUNCTIONS GO HERE
IFN FTPATT,<
EXP 0
EXP 0
>
;INSERT REAL CUSTOMER FUNCTIONS HERE
.GTQFT::0 ;QUEUE. UUO FUNCTION TABLE (ZERO IS ILLEGAL)
%QPRNT::%SIQSR ;(1) PRINT A FILE
%QPCRD::%SIQSR ;(2) PUNCH A FILE ON CARDS
%QPTAP::%SIQSR ;(3) PUNCH A FILE ON PAPER TAPE
%QPLOT::%SIQSR ;(4) PLOT A FILE
%QSUBM::%SIQSR ;(5) SUBMIT A FILE
%QALLC::%SIQSR ;(6) ALLOCATE A VOLUME SET
%QDEAL::%SIQSR ;(7) DEALLOCATE A VOLUME SET
%QMOUN::%SIQSR ;(10) MOUNT A VOLUME
%QDMNT::%SIQSR ;(11) DISMOUNT A VOLUME
%QWTO:: %SIOPR ;(12) WRITE TO OPERATOR
%QWTOR::%SIOPR ;(13) WRITE TO OPERATOR WITH RESPONSE
%QVALA::%SIACT ;(14) VALIDATE AN ACCOUNT
%QMAUE::%SIACT ;(15) MAKE A USAGE ENTRY
%QCATV::%SICAT ;(16) CATALOG VALIDATION REQUEST
%QMAIL::%SIMAI ;(17) MAIL REQUEST
%QEVNT::%SIQSR ;(20) EVENT QUEUE REQUEST
;ADD NEW DEC FUNCTIONS HERE
IFN FTPATT,<
EXP 0
EXP 0
>
QUTBLN==:.-.GTQFT-1
$ABS
.GTCSD:: ;CUSTOMER SPECIAL PID'S GO HERE
IFN FTPATT,<
Z ;(-2) ALLOW ONE CUSTOMER PID
Z ;(-1) AND ANOTHER
>
.GTSID:: ;SPECIAL PID TABLE
%SIIPC::XWD IPCPID,0 ;(0) IPCC
%SIINF::Z ;(1) [SYSTEM] INFO
%SIQSR::Z ;(2) [SYSTEM] QUASAR
%SIMDA::Z ;(3) MOUNT DEV ALLOCOTOR
%SITLP::Z ;(4) MAGTAPE LABELING PROCESS
%SIFDA::Z ;(5) FILE DAEMON
%SITOL::Z ;(6) TAPE AVR PROCESS
%SIACT::Z ;(7) [SYSTEM] ACCOUNTING
%SIOPR::Z ;(10) OPERATOR INTERFACE PROCESS
%SISEL::Z ;(11) SYSTEM ERROR LOGGER
%SIDOL::Z ;(12) DISK AVR PROCESS
%SITGH::Z ;(13) [SYSTEM] TGHA
%SINML::Z ;(14) DECNET NETWORK MANAGEMENT LAYER
%SIGFR::XWD GFRPID,1 ;(15) PID OF [SYSTEM]GOPHER
%SICAT::Z ;(16) PID FOR [SYSTEM]CATALOG
%SIMAI::Z ;(17) PID FOR [SYSTEM]MAILER
SDTBLN==:.-.GTSID-1
SIDJOB==:.+<.GTSID-.GTCSD> ;ZERO 'TH SYSTEM JOB #
BLOCK <.-.GTCSD> ;SPACE FOR PARALLEL JOB
MDAJOB==:SIDJOB+<%SIMDA-.GTSID>
FDAJOB==:SIDJOB+<%SIFDA-.GTSID>
TLPJOB==:SIDJOB+<%SITLP-.GTSID>
ACTJOB==:SIDJOB+<%SIACT-.GTSID>
TGHJOB==:SIDJOB+<%SITGH-.GTSID>
NMLJOB==:SIDJOB+<%SINML-.GTSID>
CATJOB==:SIDJOB+<%SICAT-.GTSID>
MAIJOB==:SIDJOB+<%SIMAI-.GTSID>
>
IFE M.IPCF,<
XP UIPCFR,CPOPJ ;MAKE IPCF UUOS LOOK UNIMPLEMENTED
XP UIPCFS,CPOPJ
XP UIPCFQ,CPOPJ
XP IPCFRC,CPOPJ ;DO NOTHING ON RESET UUO
XP LOKIPC,CPOPJ
XP FNDIPC,CPOPJ
XP GLXINF,CPOPJ ;NO QUEUE. UUO
XP IPMCHK,CPOPJ ;NO IPCF QUEUE TO INTERLOCK
XP IPCULK,CPOPJ ;NO IPCF QUEUE TO UNLOCK
XP SNDFFC,CPOPJ ;SEND MESSAGE TO SPECIAL PID
XP IPCLGO,CPOPJ ;DO NOTHING ON LOGOUT UUO
XP SNDMDR,CPOPJ ;LOCKED STRUCTURE MESSAGE TO MDA
XP SNDMDN,CPOPJ ;SEARCH LIST CHANGE MESSAGE TO MDA
XP SNDFIN,CPOPJ ;DEVICE DEASSIGN MESSAGE TO MDA
XP SNDMDX,CPOPJ ;SEND MESSAGE TO SPECIAL SYSTEM PID
XP ATTMPA,CPOPJ ;DISK UNIT ATTACH MESSAGE TO MDA
XP DETMPA,CPOPJ ;DISK UNIT DETACH MESSAGE TO MDA
XP XCHMPA,CPOPJ ;DISK UNIT EXCHANGE MESSAGE TO MDA
XP REMMPA,CPOPJ ;STRUCTURE REMOVAL MESSAGE TO MDA
XP MTAMPA,CPOPJ ;MAGTAPE ACCESSIBLE MESSAGE TO MDA
XP MIDMXL,0 ;MAKE GETTABS FAIL
XP IPCMXL,0
XP PIDTAB,0
XP IPCTAB,0
XP .GTCSD,0 ;NO CUSTOMER PID TABLE
XP .GTSID,0 ;NO SPECIAL PID TABLE
XP .GTQFT,0 ;NO QUEUE. TABLE
XP %QWTO,0 ;NO QUEUE. TABLE OFFSET FOR WTO
XP SDTBLN,0
XP .IPCTL,0 ;NO MESSAGE CODE FOR TAPE LABELING
XP .IPCSC,0 ;NO CSHIFT MESSAGE TO ACCOUNTING DAEMON
XP .IPCGM,0 ;NO QUEUE. UUO MESSAGE TO GALAXY COMPONENTS
XP .IPCME,0 ;NO MOS MEMORY ERROR MESSAGE TO TGHA
XP FILMSG,0
XP .IPCFP,0
XP .IPCFD,0
XP SPBMAX,0
XP SPBCOR,0
%CNIPS:: ;NUMBER OF PACKETS SENT
%CNPIC:: ;NUMBER OF PIDS IN CORE
MDAJOB:: ;MDA
FDAJOB:: ;FILE DAEMON
TLPJOB:: ;TAPE LABELER
ACTJOB:: ;ACCCOUNTING DAEMON
NMLJOB:: ;DECNET NETWORK MANAGEMENT LAYER
%SIIPC:: ;(0) IPCC
%SIINF:: ;(1) [SYSTEM] INFO
%SIQSR:: ;(2) [SYSTEM] QUASAR
%SIMDA:: ;(3) MOUNT DEV ALLOCOTOR
%SITLP:: ;(4) MAGTAPE LABELING PROCESS
%SIFDA:: ;(5) FILE DAEMON
%SITOL:: ;(6) TAPE AVR PROCESS
%SIACT:: ;(7) [SYSTEM] ACCOUNTING
%SIOPR:: ;(10) OPERATOR INTERFACE PROCESS
%SISEL:: ;(11) SYSTEM ERROR LOGGER
%SIDOL:: ;(12) DISK AVR PROCESS
%SITGH:: ;(13) [SYSTEM] TGHA
%SINML:: ;(14) DECNET NETWORK MANAGEMENT LAYER
%SIGFR:: ;(15) PID OF [SYSTEM]GOPHER
%SICAT:: ;(16) PID OF [SYSTEM]CATALOG
%SIMAI:: ;(17) PID OF [SYSTEM]MAILER
EXP 0 ;ALL THOSE WHO DO SKIPE %SIXXX
XP STRSIG,CPOPJ ;MAKE IPCF CALL FOR PSISER
XP QSRSPL,CPOPJ ;MAKE IPCF CALL FOR FILUUO
XP SENDSP,CPOPJ
XP SNDMDC,CPOPJ
XP QSRLGI,CPOPJ
>
;36 BITS 1 PER WORD
$CSUB
BITTBL::
SALL
ZZ==1B0
REPEAT ^D36,<
EXP ZZ
ZZ==ZZ_<-1>
>
$ABS
;ENQUEUE/DEQUEUE COMMON DATA
IFN M.EQDQ,<
IFNDEF M.ENQD,<M.ENQD==:EQDFEQ##>;DEFAULT ENQ QUOTA
IFNDEF M.ENQM,<M.ENQM==:EQMXAQ##>;MAXIMUM NUMBER OF ACTIVE QUEUES
HSHLEN==:2*JOBMAX ;SIZE OF HASH TABLE
HSHTAB::BLOCK HSHLEN
EXTERN QUESER
>;END OF IFN M.EQDQ CONDITIONAL
IFE M.EQDQ,<
EQUATE (GLOBAL,CPOPJ,<UENQ,UDEQ,UENQC>)
EQUATE (GLOBAL,CPOPJ1,<ENQRST,ENQLGO,ENQPOP,ENQMIN,ENQSDT,ENQINI,ENQJBI>)
EQUATE (GLOBAL,CPOPJ1,<ENQCLS,ENQNDR>)
EQUATE (GLOBAL,0,<ENQMXL,ENQTAB,.EQTAB,HSHTAB,HSHLEN>)
>;END OF IFE M.EQDQ CONDITIONAL
;PSISER SYMBOLS
$CSUB
IFN M.PSI,<
EXTERN PSIAPR,PSISER,PSIMVO,PSIMPI,PITSIZ
IFE M.CTX,< ;ONLY IF SINGLE-CONTEXT MONITOR
NOPISK::SKIPE JBTPIA(J) ;SKIP IF USER IS NOT ENABLED FOR TRAPS
OKSGNL::SKIPN JBTPIA(J) ;SKIP IF USER IS ENABLED FOR TRAPS
>
IFN M.CTX,< ;ELSE NO WAY TO AVOID OVERHEAD
NOPISK::TRN ;ALWAYS TRY
OKSGNL::TRNA ;DITTO
>
PINOJN::SKIPGE JBTPIA(J) ;SKIP IF CANNOT GRANT AN INTERRUPT
> ;END M.PSI
IFE M.PSI,<
XP PSIMVO,0
XP PSIMPI,0
XP PITSIZ,0 ;DUMMY CODE
PSIIVR::
PSIIVA::SETZ T1, ;NOTHING TO TELL PFH
POPJ P,
PINOJN:: ;CAN NEVER GRANT AN INTERRUPT
NOPISK::CAIA ;NOBODY EVER ENABLED
OKSGNL::CAI ;...
PSITST==:CPOPJ ;...
PSIERR==:CPOPJ2 ;ALWAYS STOP THE JOB
USREIJ==:CPOPJ1 ;...
PSIJBI==:CPOPJ1 ;...
PSIIOD==:CPOPJ ;NO DEVICE INTERRUPTS
PSIIDN==:CPOPJ ;...
PSIONL==:CPOPJ ;...
PSIODN==:CPOPJ ;...
PSIDWN==:CPOPJ ;...
PSIEDN==:CPOPJ ;...
PSIDVB==:CPOPJ ;...
PISYS==:CPOPJ ;UUOS FAIL
PIINI==:CPOPJ ;...
PIRST==:CPOPJ ;...
PISAVE==:CPOPJ ;...
DEBRK==:CPOPJ ;...
PIJOB==:CPOPJ ;...
PITMR==:CPOPJ ;...
PIBLK==:CPOPJ ;...
PSINTC==:CPOPJ ;NO NETWORK INTERRUPTS
PSIDVT==:CPOPJ ;NO DECNET EVENTS
APPSI==:CPOPJ ;NO APR TRAPS
PSIAPR==:ILLTIN## ;...
ANYUUO==:CPOPJ ;NO UUO TRAPS
CLRPSI==:CPOPJ ;NOTHING TO CLEAR
PSIRMV==:CPOPJ ;NOTHING TO REMOVE
PSIGEN==:CPOPJ ;NOTHING TO GRANT
PSICND==:CPOPJ ;NOTHING TO SIGNAL
PSIKSY==:CPOPJ ;NO KSYS INTERRUPTS
PSISDT==:CPOPJ ;NO DATE/TIME INTERRUPTS
> ;END M.PSI
$ABS
;TABLE OF MAPPINGS FROM 2-CHARACTER DEVICE NAMES
; TO 3-CHARACTER NAMES. EACH 2-CHAR NAME IS IN
; RIGHT OF WORD AND 3-CHAR EQUIVALENT IS
; IN LEFT HALF.
;
$HIGH
SPCTAB::XWD 'LPT','LP ' ;LINE PRINTER
XWD 'CDP','CP ' ;CARD PUNCH
XWD 'CDR','CR ' ;CARD READER
XWD 'PTP','PP ' ;PAPER-TAPE PUNCH
XWD 'PTR','PR ' ;PAPER-TAPE READER
XWD 'SYS','SY ' ;SYSTEM DEVICE
XWD 'TTY','TT ' ;TELETYPE
STEND==:.
STLEN==:STEND-SPCTAB
;TABLE OF GENERIC DEVICE NAMES USED TO SPEED UP GENERIC DEVICE SEARCH
;
;THE TABLE CONSISTS OF TWO-WORD PAIRS. THE FIRST WORD CONTAINS A
;RIGHT JUSTIFIED THREE-CHARACTER SIXBIT GENERIC DEVICE NAME. THE
;SECOND WORD CONTAINS A 30-BIT ADDRESS OF THE FIRST DDB OF THAT
;TYPE. THE TABLE IS BUILT AND MAINTAINED IN SORTED ORDER BY AUTCON.
DEFINE GNRIC(DEV,SYM),<
IFNDEF M.R'DEV,<M.R'DEV==0> ;DEFINE REMOTE DEVICES
IFN M.'DEV+M.R'DEV+SYM,<
XWD 0,''DEV''
EXP 0
>>
DEFINE DGNRIC(X),<
GNRIC DT'X
>
$ABS
GENPTR::EXP 0 ;AOBJN POINTER TO GENTAB
GENTAB::
REPEAT M.GENL,<EXP <0,,-1>,0> ;RESERVE EMPTY SPACE FOR AUTCON
ZZ=="A"
REPEAT M.TD10,<
DGNRIC(\"ZZ)
ZZ==ZZ+1
>
DEFINE RGNRIC(Y),<
GNRIC RX'Y
>
ZZ=="A"
REPEAT M.RX20,<
RGNRIC(\"ZZ)
ZZ==ZZ+1
>
GNRIC(PTY) ;PSEUDO-TTY
IFN M.DAS78,< ;IF DAS78 SUPPORT
GNRIC(XXI) ;XXI DEVICE
GNRIC(XXO) ;XXO DEVICE
> ;END IFN M.DAS78
GENLEN==:.-GENTAB
;DATA BASE TO LIMIT THE NUMBER OF STOPCD'S PER UNIT TIME SO THAT
;WE DON'T KEEP GETTING "CONTINUABLE" STOPCD'S THAT REALLY AREN'T.
;THE DATA BASE CONSISTS OF TWO TABLES, SCCTAB AND SCLTAB. SCCTAB
;IS THE COUNT OF THE NUMBER OF STOPCD'S PROCESSED DURING THE PERIOD
;INDICATED BY THE OFFSET IT THE TABLE. SCLTAB CONTAINS, IN THE
;LEFT HALF, THE PERIOD FOR THIS ENTRY AND, IN THE RIGHT HALF, THE
;LIMIT FOR THE NUMBER OF STOPCD'S DURING THE PERIOD. BOTH TABLES
;MUST BE ORDERED SUCH THAT THE PERIOD OF EACH ENTRY IS MONOTONICALLY
;INCREASING. THE LIMITS FOR EACH PERIOD ARE CHANGABLE VIA THE MONGEN
;DIALOG AND MAY BE CHANGED BY THE CUSTOMER. WHEN A STOPCD IS PROCESSED
;BY DIE, STCLIM INCREMENTS THE COUNTS OF STOPCD'S FOR EACH ENTRY
;AND COMPARES EACH WITH THE LIMIT FOR THE ENTRY. IF A LIMIT HAS BEEN
;EXCEEDED, DIE TURNS THE CONTINUABLE STOPCD INTO A STOP STOPCD. IF
;NO LIMIT HAS BEEN EXCEEDED, STCLIM PUTS IN A CLOCK REQUEST TO CALL
;DECSCC AFTER THE PERIOD OF THE LOWEST ENTRY IN THE TABLE. DECSCC
;DECREMENTS THE COUNT OF STOPCDS FOR THIS ENTRY AND PUTS IN A CLOCK
;REQUEST TO DECREMENT THE NEXT HIGHER COUNT. THIS CONTINUES UNTIL ALL
;HAVE BEEN DECREMENTED. NOTE, THAT SINCE THE CLOCK QUEUE IS USED TO
;DECREMENT THE STOPCD COUNTS, THE PERIOD OF THE LARGEST ENTRY CANNOT
;BE LARGER THAN 2**18-1 TICKS.
SCCTAB::EXP 0 ;1 MINUTE COUNT OF STOPCD'S
EXP 0 ;8 MINUTE COUNT OF STOPCD'S
EXP 0 ;1 HOUR COUNT OF STOPCD'S
SCCTBL==:.-SCCTAB ;LENGTH OF TABLE
SCLTAB::XWD ^D60, LIM1MS ;PERIOD:=1 MINUTE, LIMIT:=LIM1MS
XWD ^D480, LIM8MS ;PERIOD:=8 MINUTES, LIMIT:=LIM8MS
XWD ^D3600,LIM1HS ;PERIOD:=1 HOUR, LIMIT:=LIM1HS
;GALAXY-10 PARAMETERS
DEFINE GPARM(Z1),<
IFE Z1,<
ZGAL==0
>>
ZGAL==1
GPARM(M.IPCF)
GPARM(M.PSI)
GPARM(M.PTY)
IFN M.IPCF,<
IFG ^D10-%IPMPL,<ZGAL==0>
>
;DEFINE IPCF SYMBOLS IF NOT AROUND
$HIGH
;TABLE FOR SPOOLING DEVICES
SPLNAM==:0 ;NAME OF SPOOLING DEVICE
SPLBIT==:2 ;SPOOLING BIT
SPLLEN==:DEVMOD+1 ;LENGTH OF EACH ENTRY
;NOTE THAT WORD 1 (DEVCHR) MUST BE 0
SPLTAB::SIXBIT .LPT.
0
XWD .TYLPT,.SPLPT
0 ;NO REAL DEVSER
LPTMOD==1_A+1_AL+1_I
XWD DVOUT+DVLPT,ASSCON!ASSPRG!LPTMOD
SIXBIT .PLT.
0
XWD .TYPLT,.SPPLT
0
XWD DVOUT,ASSCON!ASSPRG!14403
SIXBIT .CDP.
0
XWD .TYCDP,.SPCDP
0
XWD DVOUT+DVCDR,ASSCON!ASSPRG!14403
SIXBIT .PTP.
0
XWD .TYPTP,.SPPTP
0
XWD DVOUT+DVPTP,ASSCON!ASSPRG!14403
SIXBIT .CDR.
0
XWD .TYCDR,.SPCDR
0
SPLTOP::XWD DVIN+DVCDR,ASSCON!ASSPRG!14403
$ABS
SUBTTL CPU START-UP CODE
;NOTE: CODE AT ENTDDT SHOULD MATCH CODE FROM SYSTRT THROUGH CALL TO SYSTR0
SYSTRT::JSP T1,.+1 ;GET THE FLAGS
TLNE T1,(XC.USR) ;ARE WE IN USER MODE?
JRST USRONC## ;YES, THEN THIS MUST BE TWICE
EXECAC ;GET AC SET RIGHT
CONO APR,AP.IOR ;BLAST
CONO PI,CLRPIS ;BLAST
IFN M.KL10,<
CONO PAG,0 ;INSURE THAT THE CACHE IS OFF
DATAO APR,[EXP 0] ;CLEAR OLD ADDRESS BREAK
>
JSP T4,SYSTR0 ;SEE WHICH CPU THIS IS AND SETUP THE EBR
JRST SYSINI## ;BOOT CPU
IFG <M.CPU-1>,<
JRST SPRINI ;NON-BOOT CPU
>
IFLE <M.CPU-1>,<
HALT . ;ATTEMPT TO START NON-BOOT CPU WITH A SINGLE CPU MONITOR
>
;SUBROUTINE TO SEE WHICH CPU THIS IS (CALLED ON SYSTEM
; STARTUP AND POWER FAIL AUTO-RESTART)
;CALLING SEQUENCE:
; JSP T4,SYSTR0
; RETURN HERE IF BOOT CPU
; RETURN HERE IF NON-BOOT CPU
SYSTR0::TLO T4,(IC.UOU) ;TURN ON USRIOT FOR RETURN
IFN M.KL10,<
CONO APR,LP.CSF!LP.CSD
DATAI CCA, ;INVALIDATE CACHE, NOT VALIDATING CORE
CONSO APR,LP.CSD
JRST .-1
CONO APR,LP.CSF!LP.CSD
>
IFN M.KS10,<
RDUBR T2 ;INVALIDATE CACHE
WRUBR T2
>
SYSTR1::APRID T1 ;READ CPU SERIAL #
MOVE T3,T1 ;COPY
ANDI T1,ID.PSN ;JUST SERIAL # BITS
IFN FTMP,<
SKIPGE INTRST
AOSE INTRST
JRST .-2
>
MOVEI T2,.C0CDB ;START WITH FIRST CDB
SYSTR2: CAME T1,.CPASN-.EVCDB(T2) ;THIS CPU THE OWNER OF THE CDB?
JRST SYSTR6 ;NO
SYSTR3: MOVEM T3,.CPAPD-.EVCDB(T2) ;YES, STORE APRID
SETOM .CPOCB-.EVCDB(T2) ;MARK THIS CDB AS OWNED
SETZM .CPPFT-.EVCDB(T2) ;CLEAR PRE-EMPTIVE PAGE FAULT HANDLER
IFN M.KL10,<
MOVE T1,.CPAPD-.EVCDB(T2) ;GET OPTION BITS
TLNE T1,(ID.PMV) ;UCODE SUPPORT PHYSICAL MOVE/MOVEM?
SETOM .CPPMV-.EVCDB(T2) ;YES, FLAG FOR PHMOV/PHMOVM
TRNN T1,ID.MCA ;MCA25 INSTALLED?
TDZA T1,T1 ;NO
MOVSI T1,(PM.KPM) ;YES
MOVEM T1,.CPKPM-.EVCDB(T2)
>; END IFN M.KL10
;MAP THE CDB VIA EXEC VIRTUAL ADDRESS .EVCDB ('CDBPGS' PAGES)
MOVE T3,.CPMAP-.EVCDB(T2) ;GET ADDRESS OF EXEC MAP
MOVE T1,T2 ;GET CDB ADDRESS
LSH T1,W2PLSH ;CONVERT TO A PAGE NUMBER
TLO T1,(<PM.DCD>B2+PM.WRT+PM.PUB) ;MAKE IT ACCESSIBLE AND WRITABLE
IFN M.KL10,<
IOR T1,.CPKPM-.EVCDB(T2) ;INCLUDE "KEEP ME" IF MCA25
>; END IFN M.KL10
HRLI T3,-CDBPGS ;NUMBER OF ENTRIES TO COPY
MOVEM T1,.EVCDB/PAGSIZ(T3) ;SET UP MAPPING FOR CDB VIA .CPXXX
AOBJP T3,.+2 ;COPY ALL ENTRIES
AOJA T1,.-2 ;LOOP FOR ANOTHER
IFN M.KL10,<
MOVE T1,.CPKPM-.EVCDB(T2) ;GET "KEEP ME" BIT OR ZERO
MOVE T3,.CPEPT-.EVCDB(T2) ;GET ADDRESS OF EPT
IORM T1,SECTAB+0(T3) ;TURN ON "KEEP ME" IN SECTION 0 AND 1 MAP POINTERS
IORM T1,SECTAB+1(T3)
XJRSTF [EXP XC.UOU,.+1] ;SET PRVIOUS CONTEXT USER, PCS =0
DATAI PAG,P3 ;SET PREVIOUS CONTEXT AC SET TO 6
AND P3,[LG.CAC]
TLO P3,(LG.LAB+6B11)
DATAO PAG,P3
MOVSI T1,[EXP -1,0,0] ;NO CST UPDATE(AND MASK,OR MASK,BASE ADDR 0=NONE)
EXCTXU <BLT T1,2> ;SET LOCATIONS IN AC SET 6, FOR CSTS
MOVEI T1,SPTTAB ;MAKE A POINTER TO THE SPT FOR THIS CPU
EXCTXU <MOVEM T1,3> ;SET IT UP IN AC SET 6 LOCATION 3
TLC P3,(7B11) ;PREVIOUS AC SET TO 1
DATAO PAG,P3
>
IFN FTKS10,<
CONO PAG,0 ;OTHERWISE THE UCODE GETS HUNG
WRCSTM [-1] ;KEEP ALL CST BITS (AND MASK)
WRPUR [0] ;SET NOTHING FOR REF'D PAGES (OR MASK)
WRCSB [0] ;NO CST PRESENT REQUIRES UCODE 124
;WITH INHCST OR NOCST TURNED ON
APRID 0 ;READ OUR ID
TLNE 0,(ID.KLP) ;BETTER SAY KLP IS AVAIL
TLNN 0,(ID.NCU) ;AND SOME WAY TO TURN OFF CST
STOPCD .+1,HALT,WNGUCV ;++WRONG UCODE VERSION
MOVEI 0,@.CPSPT-.EVCDB(T2) ;POINT TO OUR SMALL SPT
WRSPB 0 ;TELL THE MICROCODE
>
MOVE P3,@.CPSPT-.EVCDB(T2) ;SAVE ORIGINAL CONTENTS
MOVEI T1,NLUPMP/PAGSIZ ;ESTABLISH AN SPT
MOVEM T1,@.CPSPT-.EVCDB(T2)
IFN M.KL10,<
IFN FTXMON,<
;NOW SETUP THE MAPPING TO MAKE ALL OF THE USER SECTION MAPS ADDRESSABLE IN EXEC MODE
; THE MAPS START AT VIRTUAL ADDRESS UMAPS IN SECTION 37.
MOVEI T1,<SECTAB+(<PM.ICD>B2+PM.WRT+IFE FTMP,<PM.CSH>)>
HRL T1,.CPCPN-.EVCDB(T2) ;@THRU CURRENT CPU'S ASSIGNED SPT SLOT
MOVEI T3,.CPUMA-.EVCDB(T2)
SYSTR4: MOVSM T1,(T3) ;POINTER FOR NEXT USER SECTION MAP
ADDI T1,1 ;NEXT SECTION
CAIE T3,.CPUMA-.EVCDB+MXSECN(T2) ;MAPPED ALL SECTIONS?
AOJA T3,SYSTR4 ;NO, LOOP OVER ALL SECTIONS
> ;END IFN FTXMON
CONO PAG,@.CPEBR-.EVCDB(T2)
DATAO PAG,NULDOP ;SETUP UBR TO
; NULL JOB'S UPT SO THAT MUUO'S, ACCOUNTING
; METERS, EXEC PAGE FAILS DURING ONCE ONLY
; WORK CORRECTLY. INHIBIT ACCOUNTING STORE
>
IFN M.KS10,<
WREBR 0 ;DO THIS IN CASE POWER UP. KS10 MICRO-CODE V111
; HAS BUG THAT WILL CAUSE BOGUS PAR ERR
; IF THIS ISN'T DONE
WREBR @.CPEBR-.EVCDB(T2) ;SET UP EXEC BASE REGISTER
WRUBR NULDOP ;SET UP USER BASE REGISTER TO NULL JOB
; SO THAT MUUO'S & PAGE FAILS WORK DURING ONCE
MOVE T3,.CPEPT ;GET EPT ADDRESS
MOVEI T1,.EPHSB(T3) ;GET HALT STATUS BLOCK ADDRESS
WRHSB T1 ; DUMP ADDRESS
>
IFG <M.CPU-1>,<
MOVE T2,BOOTWD
IFN M.KL10,<
ANDI T2,ID.PSN
>
SKIPGE BOOTCP ;IS THERE ALREADY SOMEBODY AS THE BOOT CPU
CAME T2,.CPASN ;SAME AS THE CURRENT CPU?
AOJA T4,SYSTR5 ;NO, THIS MUST BE CPU1
>
IFE <M.CPU-1>,<
MOVE T2,.CPASN
>
MOVEM T2,SERIAL ;STORE FOR SECOND GETTAB
MOVE T1,.CPCPN ;OUR CPU NUMBER
MOVEM T1,BOOTCP ;NOBODY ELSE DURING SYSTEM STARTUP
MOVE T1,[<PM.DCD>B2+PM.WRT+NUPMPP]
MOVEM T1,NLUPMP+.UMUPT
SYSTR5: MOVE T1,.CPCPN ;GET OUR CPU NUMBER
MOVE T2,.CPASN ;AND OUR SERIAL NUMBER
MOVEM T2,ASNTAB(T1) ;SAVE FOR EDDT
IFN FTMP,<
SETOM INTRST
>
JRSTF @T4 ;DO CPU1 INITIALIZATION
SYSTR6: HLRZ T2,.EVCDB-.EVCDB(T2)
JUMPN T2,SYSTR2
MOVEI T2,.C0CDB
SYSTR7: SKIPE .CPOCB-.EVCDB(T2)
JRST SYSTR8
MOVEM T1,.CPASN-.EVCDB(T2)
JRST SYSTR3
SYSTR8: HLRZ T2,.EVCDB-.EVCDB(T2)
JUMPN T2,SYSTR7
IFN FTMP,<
SETOM INTRST
>
HALT .
APRRES::EXECAC ;SWITCH TO EXEC AC BLOCK ON PWR FAIL RESTART
JSP T4,SYSTR0 ;THIS DOES THAT (AND TURNS PAGING ON)
IFE M.CPU-1,<JRSTF @[IC.UOU+APRPFR##]> ;RESTART PROCESSOR
IFN M.CPU-1,<
JFCL ;NON-BOOT CPU RETURN
XCT .CPRES ;RESTART PROCESSOR
> ;END IFN M.CPU-1
;HERE ON A RESTART AFTER SYSTEM SLEEP, REBOOT
SYSRST::EXECAC ;GET AC SET RIGHT
CONO APR,AP.IOR ;BLAST
CONO PI,CLRPIS ;BLAST
IFN M.KL10,<CONO PAG,0> ;INSURE THAT THE CACHE IS OFF
JSP T4,SYSTR0 ;SEE WHICH CPU THIS IS AND SETUP THE EBR
JFCL ;ALWAYS RESTART VIA SPRINI
SETZM MBTCOM ;MAKE SURE THAT DUMPED CRASHES DON'T LOOK REBOOTABLE
SETZM CLKDDT ;ZERO CLKDDT SO WE DON'T JUMP TO EDDT
IFN FTKL10,<
JSP T4,ZAPICH ;MAKE SURE INT CHANS ARE IN A REASONABLE STATE
>;END IFN FTKL10
IFG <M.CPU-1>,<
HRRZ T1,.CPCPN ;WHERE WE ARE
CAMN T1,BOOTCP ;SAME CPU AS WE SUSPENDED ON?
JRST SPRINI ;YES - REINITIALIZE
MOVE P,.CPNPD ;ANY OLD PUSH DOWN LIST WILL DO
MOVEI T1,[ASCIZ/?Must REBOOT on the Policy CPU
/]
PUSHJ P,CTYTYP## ;EXPLAIN THE ERROR
PUSHJ P,RMVCPU## ;AND GO AWAY
>
;FALL INTO SPRINI ON SINGLE CPU SYSTEMS
SUBTTL INITIALIZATION ON STARTUP/RESTART AFTER SYSTEM SLEEP
;NON-BOOT PROCESSOR INITIALIZATION. REINITIALZATION FOR ALL CPUS
; AFTER SYSTEM SLEEP
SPRINI::CONO PI,CLRPIS ;CLEAR PI AND PARITY ERROR FLAG
CONO APR,APRRST ;RESET EVERYTHING AND ENABLE CLOCK
EXECAC ;MAKE SURE AC BLOCKS ARE OK
MOVSI P,(CR.RMV!CR.DET) ;"CPU IS DOWN" OR "DETACHED" BITS
TDNE P,.CPRUN ;CAN THIS CPU RUN YET
JRST .-1 ;NO, WAIT UNTIL IT CAN
MOVE P,.CPNPD ;SET UP PUSH DOWN POINTER
IFN FTKL10,<
DATAO APR,[EXP 0] ;CLEAR OLD ADDRESS BREAK
MOVSI T1,(1B0) ;CLEAR ADDRESS BREAK SETUP BIT IN CASE RESTART
ANDCAM T1,.CPABF ; AFTER REBOOT SO ADDR BREAK GETS SET UP AGAIN
MOVE T1,.CPCPN
PUSHJ P,DTEINI##
PUSHJ P,ENTSPC## ;ENTER SECONDARY PROTOCOL
>;END IFN FTKL10
MOVSI T1,(CR.TSS) ;SUCCESSFUL DUMP BIT
TDNN T1,.CPRUN ;SET AFTER A SUSPEND?
JRST SPRIN0 ;NO - CONTINUE
PUSHJ P,SUSDTM ;YES - ASK FOR DATE & TIME
MOVSI T1,(CR.TSS) ;SUCCESSFUL DUMP BIT
ANDCAB T1,.CPRUN ;CLEAR IT
IFG <M.CPU-1>,<
JRST SPRIN1 ;CONTINUE WITHOUT WITING ON THIS CPU
>
SPRIN0:
IFG <M.CPU-1>,<
PUSHJ P,PRTCPU## ;TELL OPR WHO WE ARE
MOVE 12,[ACLOOP##,,2];LOAD AC'S WITH WAIT LOOP
BLT 12,12 ;CPU1 WILL WAIT UNTIL CPU0 IS GOING
MOVE 12,[JRST SPRIN1];TO EXIT LOOP
SJSP 0,3 ;ENTER LOOP
;INITIALIZE PD LIST
SPRIN1: MOVE P,.CPNPD ;SET UP PUSH DOWN POINTER
PUSHJ P,MAPINI## ;COPY THE BOOT CPU'S MAP INTO THE CURRENT CPU'S MAP
JRSTF @[EXP IC.UOU+.+1] ;TURN ON USER IOT SO EXECUTE PAGED WORKS
; CORRECTLY AND PROCEED WITH INITIALIZATION
CLRPGT
CONO PI,PI.CPI ;AND CLEAR PI SYSTEM
MOVSI T1,(CR.SPD) ;SUSPENDED BIT
TDNE T1,.CPRUN ;RESTART AFTER REBOOT?
JRST SPRIN5 ;YES, DISKS ARE INITIALIZED
SPRIN2: MOVE 17,[ONCLOP##,,1] ;WAIT IN ACS FOR CPU0 TO REQUEST IO
BLT 17,16 ; DO IT (AT SPRIN3) WHEN REQUESTED
SJSP 0,3
;HERE FROM LOOP IN THE ACS TO DO DISK I/O DURING ONCE-ONLY ON NON-BOOT CPUS
SPROIO::
SPRIN3: MOVE P,.CPNPD ;SET UP A PDL
SKIPN T1,ONCCOM ;WHAT CPU0 WANTS US TO DO
JRST SPRIN2 ;NOTHING TO DO
AOJE T1,SPRIN2 ;RESTARTED IF -1
SOS F,T1 ;COMM WORD INTO F
SOJE T1,SPRIN5 ;DONE IF +1
PUSHJ P,MAPINI## ;SOME OTHER NON BOOT CPU MAY
; HAVE CHANGED MAPS
PUSHJ P,CPUDSP## ;GO DO SOME WORK
JRST SPRIN2 ;AND WAIT SOME MORE
;HERE TO SET UP TO RUN NULL JOB, & SETUP PI
SPRIN5: PUSHJ P,MAPINI##
CONO PI,PI.ON+DSKPIN ;TURN ON THE PI SYSTEM AND THE DISK PI'S
MOVSI T1,(CR.SPD) ;SUSPENDED BIT
TDNN T1,.CPRUN ;RESTART AFTER REBOOT?
JRST SPRI5A ;NO
IFN M.SCA,<
PUSHJ P,PPDINX## ;INITIALIZE THE PHYSICAL PORT DRIVER
>; END IFN M.SCA
IFN M.ENET,<
PUSHJ P,KNIINI## ;INITIALIZE THE KLNI PORT DRIVER
>; END IFN M.ENET
SPRI5A:
IFN FTKL10,<
PUSHJ P,CSDMP## ;ONCE ONLY/FILSER MAY HAVE DRAGGED
; SOMETHING INTO THE CACHE
>
>
MOVEI T1,CCTYO## ;GET ADDRESS OF TYPEOUT ROUTINE
MOVEM T1,.CPTOA ; AND TELL SCNSER
MOVEI T1,COMTIV## ;GET ADDRESS OF COMMAND INPUT ROUTINES
MOVEM T1,.CPTIV ; AND TELL SCNSER TO USE LDB'S NOW.
SETZM .CPTNT ;JUST STARTING
MOVE J,.CPCPN ; FOR THIS CPU
SETZM CLKMIN(J) ;CLEAR MIN REQUEST
IFN FTMP,<
SETOM .CPDIE ;CLEAR DIE NESTING
SETOM .CPSCD ;CLEAR SCHED NESTING
SETZM .CPNBI ;CLEAR NUMBER OF BROKEN INTERLOCKS
SETOM .CPDLK ;CLEAR DSKOFF NESTING
IFN FTSCA,<
SETOM .CPSCA ;CLEAR SCA BUFFER MANAGEMENT NESTING
>; END IFN FTSCA
IFN FTENET,<
SETOM .CPETH ;CLEAR ETHERNET NESTING
>; END IFN FTENET
>;END IFN FTMP
SETOM .CPDWD ;GIVE UP DIE RECURSION INTERLOCK
SETOM .CPSIN ;CLEAR SCNSER NESTING
SETZM .CPAEF ;CLEAR CPU ERROR/SWEEP FLAGS
HRRZS .CPMPC ;CLEAR SERIOUS MEMORY PARITY HALT FLAG
; HALT AFTER PRINTING ON CPU0 CTY
MOVE T1,TIME ;GET CURRENT TIME
MOVEM T1,.CPTML ;STORE FOR TICKS GONE BY
MOVE T2,TICSEC ;TICK PER SECOND
LSH T2,-1 ;DIVIDE BY 2
ADD T1,T2 ;AND ROUND
IDIV T1,TICMIN ;T2 = PARTIAL MINUTE (IN TICKS)
IDIV T2,TICSEC ;T2 = SECONDS, T3 = REMAINDER IN TICKS
SUBI T2,^D60 ;COMPUTE TIME TO NEXT MINUTE
MOVNM T2,.CPSEC ;STORE FOR ONCE-A-MINUTE UPDATE
SUB T3,TICSEC ;TIME TO NEXT SECOND
MOVNM T3,.CPHTM ;STORE FOR ONCE-A-SECOND UPDATE
MOVEI T1,SR.STS!SR.DIE!SR.ACL ;CLEAR THESE BITS WHEN WE
ANDCAM T1,.CPSBR ; RESTART THE PROCESSOR
IFG <M.CPU-1>,<
MOVEI J,JOBMAX ;MAX JOB NO.
MOVSI T1,(SP.CJ0) ;JOB RUNNING ON CPU1 BIT
LSH T1,@.CPCPN
SPRLP1: ANDCAM T1,JBTSPS(J) ;CLEAR FOR ALL JOB IN SYSTEM
; (IN CASE THIS IS A 450 RESTART ON CPU1)
SOJGE J,SPRLP1 ;MORE?
>
IFN FTKL10,<
APRID T3 ;PROCESSOR HARDWARE OPTIONS
DMOVE T1,[M.EBPS ;ASSUME A MODEL A PROCESSOR
M.MBPS]
TRNE T3,ID.XKL ;IS IT A MODEL B PROCESSOR?
DMOVE T1,[^D30*M.EBPS/^D25 ;YES, USE DIFFERENT EBOX/MBOX CALABRATION CONSTANTS
^D30*M.MBPS/^D25]
MOVEM T1,.CPEBS ;STORE AS EBOX TICS/SEC
MOVEM T2,.CPMBS ;STORE AS MBOX TICS/SEC
IDIV T1,TICSEC ;AND NOW GET EBOX COUNTS/JIFFY
IMULI T1,.EBCPT ;MULTIPLY BY EBOX COUNTS/TICK
MOVEM T1,.CPEBJ ;STORE IN CDB VARIABLE
MOVE T1,.CPMBS ;GET MBOX TICKS/SECOND
IDIV T1,TICSEC ;GET MBOX COUNTS/JIFFY
IMULI T1,.MBCPT ;MULTIPLY BY MBOX COUNTS/TICK
MOVEM T1,.CPMBJ ;SAVE
PUSHJ P,SETCLK ;SETUP CLOCKS, PI, APR
>
IFN FTKS10,<PUSHJ P,UBAPIS> ;MAKE SURE UBA'S HAVE A PIA
SETZB S,P1 ;ALWAYS CALL INI ROUTINE ONCE
HLRZ P3,HNGLST ;LOOK ONLY AT REAL HARDWARE
SPRIN9: MOVE F,P3 ;SETUP F FOR INI CODE
MOVE P3,DEVSER(P3) ;ADDRESS OF DEVICE DISPATCH VECTOR
IFN FTMP,<
LDB T1,DEYCPF ;CPU OWNING THE DEVICE
CAMN T1,.CPCPN ;CURRENT CPU?
>;END IFN FTMP
CAIN P1,(P3) ;YES, ALREADY CALLED INI ROUTINE?
JRST SPRI10 ;YES, SKIP ON
PUSHJ P,DINI(P3) ;NO, CALL INI ROUTINE
HRRZ P1,P3 ;NEEDN'T CALL IT AGAIN
SPRI10: HLRZS P3 ;NEXT DDB
JUMPN P3,SPRIN9 ;LOOP IF THERE IS ONE
IFN FTKL10,<
PUSHJ P,SETCSH## ;SET CACHE STRATEGY AS ESTABLISHED BY KLI
PUSHJ P,STAPPC## ;START PRIMARY PROTOCOL
>; END IFN FTKL10
IFN FTKS10,<PUSHJ P,ENAKAL##> ;ENABLE KEEP ALIVE
MOVSI T1,(CR.SPD) ;BIT TO TEST
TDNN T1,.CPRUN ;RESTARTING SUSPENDED MONITOR?
JRST SPRI11 ;NO
PUSHJ P,DSKRCL ;YES, GENERATE A FREE INTERRUPT FROM ALL DSKS
; SO FILIO WILL REREAD THE HOME BLOCK AND
; VERIFY THAT PACKS WEREN'T MOVED WHILE ASLEEP
IFN FTXMON,<XJRST [MCSEC1+.+1]> ;RUN IN SECTION ONE
PUSHJ P,SETBFL## ;RELOAD MONITOR FILESPEC INTO BOOT VECTOR
PUSHJ P,SSLBLD## ;AND SSL
JFCL
PUSHJ P,ASLBLD## ;AND ASL
JFCL
PUSHJ P,SDLBLD## ;AND FINALLY THE SDL
JFCL
IFN FTNET,< PUSHJ P,FEKCPW##> ;TEL THE FRONT ENDS WE ARE BACK
IFN FTENET,<PUSHJ P,KNIMON##> ;TELL KLNI WE ARE BACK
IFN FTSCA,< PUSHJ P,PPDMON##> ;TELL KLIPA WE ARE BACK
MOVSI T1,(CR.SPD) ;SUSPEND BIT
ANDCAM T1,.CPRUN ;CLEAR IT SINCE RESUMING
IFN FTXMON,<XJRST [MCSEC0+.+1]> ;BACK TO SECTION ZERO
SPRI11:
IFG <M.CPU-1>,<
SKIPE J,.CPJOB ;IF A RESTART AND A JOB WAS RUNNING,
PUSHJ P,CPUZAP## ; ZAP IT AND INFORM THE USER
SETZM .CPJOB ;NO PREVIOUS JOB
SETZM .CPDRQ ;NO MORE DISKS TO RESCUE
>
CLRPGT
IFN FTKL10,<PUSHJ P,ABKCHK##> ;CHECK & POSSIBLY SET EXEC MODE ADDRESS BREAK
SJSP U,NULJB1 ;GO START NULL JOB
;ROUTINE TO GET THE DATE: & TIME: FROM THE OPERATOR AFTER A /REBOOT
;OF A SUSPENDED SYSTEM.
SUSDTM: SE1ENT ;NEED LDB'S
HRRZ T1,.CPCTN ;GET CTY LINE NUMBER FOR THIS CPU
MOVE U,LINTAB##(T1) ;SETUP U FOR CTY
MOVEI T1,CTYWAT## ;ADDRESS OF TYPEOUT ROUTINE TO USE
MOVEM T1,.CPTOA ; AND TELL SCNSER
MOVEI T1,COMTIV## ;GET ADDRESS OF COMMAND INPUT ROUTINES
MOVEM T1,.CPTIV ; AND TELL SCNSER TO USE LDB'S
PUSHJ P,TSETBI## ;CLRBFI INPUT FROM THE CHUNKS
PUSHJ P,TSETBO## ;DON'T WANT ANY OUTPUT FROM BEFORE
PUSH P,LDBDCH##(U) ;SAVE STATE OF LINE
MOVSI T1,LDLCOM## ;COMMAND MODE BIT
TDNN T1,LDBDCH##(U) ;IF NOT ON THEN
PUSHJ P,TTYSTC## ; GET LINE INTO COMMAND MODE
PUSHJ P,INLMES## ;GET FROMT-END IN THE MOOD
BYTE(7)177
CAIA ;ASK FOR DATE
SUSDT0: PUSHJ P,TTYCMR## ;SAY PREVIOUS COMMAND IS COMPLETED
PUSHJ P,INLMES## ;ASK FOR THE DATE
ASCIZ /Date: /
PUSHJ P,PCOMM ;TAKE A COMMAND LINE FROM CTY
MOVEI T1,LOCYER
PUSHJ P,GTDATE## ;GET THE DATE IN LOCYER,LOCMON,LOCDAY
JRST [PUSHJ P,INLMES## ;BAD FORMAT
ASCIZ /Please type today's date as MON-DD(-YY)
/
JRST SUSDT0] ;AND ASK AGAIN
SUSTM: PUSHJ P,TTYCMR## ;SAY PREVIOUS COMMAND IS COMPLETED
PUSHJ P,INLMES## ;ASK FOR TIME
ASCIZ /Time: /
PUSHJ P,PCOMM ;TAKE A COMMAND LINE FROM CTY
PUSHJ P,RDTIM## ;GET TIME OF DAY IN T1
SETO T1, ;BAD FORMAT
JUMPLE T1,[PUSHJ P,INLMES## ; OR NEGATIVE OR JUST RETURN
ASCIZ /Please type time as HHMMSS or HH:MM:SS
/
JRST SUSTM] ;ASK AGAIN
PUSH P,U ;SAVE LDB ADDRESS
PUSHJ P,SETDA3## ;DO THE SETUUO STUFF
JFCL ;SKIP RETURNS
POP P,U ;RESTORE ADDR OF LDB
PUSHJ P,TTYCMR## ;SAY PREVIOUS COMMAND IS COMPLETED
PUSHJ P,TYIEAT## ;AND EAT PREVIOUS COMMAND LINE
POP P,T1 ;GET BACK STATE OF LINE
HRRZ F,LDBDDB##(U) ;GET THE DDT
JUMPE F,CPOPJ ;NONE - JUST RETURN
LDB J,PJOBN ;SETUP JOB INCASE WE CALL TTYUSW
TLNN T1,LDLCOM## ;IF IT WAS IN USER MODE THEN
PUSHJ P,TTYUSW## ; SET THE LINE BACK THE WAY IT WAS
POPJ P, ;RETURN
;ROUTINE TO TAKE A COMMAND LINE FROM THE CTY WITH INTERRUPTS OFF
PCOMM: PUSHJ P,TYIEAT## ;EAT ANY PREVIOUS COMMAND LINE
PUSHJ P,PLINE ;TAKE AN INPUT LINE INTO THE CHUNKS
MOVE T1,LDBTIT##(U) ;BYTE POINTER TO LINE JUST READ IN
PUSHJ P,CTISBP## ;TELL COMCON
MOVEI T3," " ;PRIME THE COMMAND SCANNER
PUSHJ P,CTISLC## ;BY MAKING THE LAST CHR A BLANK
POPJ P, ;RETURN
;ROUTINE TO TAKE A LINE OF INPUT FROM THIS CPU'S CTY WITHOUT INTERRUPTS
;TURNED ON. INPUTTED CHARACTERS ARE STORED IN THE CHUNKS AND ECHO IS
;HANDLED THROUGH CTYWAT.
PLINE: PUSHJ P,PTYI ;GET A POLLED CHARACTER
HRRZ U,.CPCTN ;GET CTY LINE NUMBER FOR THIS CPU
PUSHJ P,RECINT## ;GIVE CHR TO SCNSER - RETURNS LDB IN U AGAIN
PLINEC: PUSHJ P,XMTCHR## ;GET ANY ECHO
JRST PLINBK ;NOTHING LEFT TO ECHO
PUSHJ P,CTYWAT## ;ECHO IT
JRST PLINEC ;CHECK FOR MORE TO ECHO
PLINBK: PUSHJ P,TTLCHK## ;CHECK FOR END OF LINE
JRST PLINE ;NOT A LINE YET - GET ANOTHER CHARACTER
POPJ P, ;RETURN WITH A LINE IN THE CHUNKS
;ROUTINE TO INPUT ONE POLLED CHARACTER FROM THE CTY
PTYI:
IFN FTKL10,<
PUSHJ P,SPCGTI## ;SKIP IF CHAR PRESENT, WITH IT IN T3
>; END IFN FTKL10
IFN FTKS10,<
SKIPN T3,CTYIWD ;SKIP IF CHAR PRESENT, WITH IT IN T3
>; END IFN FTKS10
JRST PTYI ;NONE THERE - LOOP
IFN FTKS10,<
SETZM CTYIWD ;CLEAR FOR NEXT TIME
>; END IFN FTKS10
ANDI T3,CK.CHR ;JUST CHARACTER BITS
POPJ P, ;RETURN WITH CHR IN T3
SETCLK:
IFN FTEMRT,<
PUSHJ P,ACCMON## ;START UP ACCOUNTING METERS
PUSHJ P,CLREMB## ;CLEAR OUT E AND MBOX ACCOUNTING METERS
>;END IFN FTEMRT
PUSHJ P,SETIME ;TO INITILIZE 'GGTIME' CLOCK (IN SYSINI)
IFN FTKL10,<
CONI MTR,T1 ;PRESERVE TIME BASE INFO
CONO MTR,APRCHN(T1) ;SETUP INTERVAL TIMER PI
IFG <M.CPU-1>,<
MOVE T1,BOOTCP ;BOOT CPU
MOVSI T2,(CR.SPD) ;SUSPENDED BIT
TDNN T2,.CPRUN ;THERE MIGHT NOT BE A BOOT CPU AFTER A REBOOT
CAMN T1,.CPCPN ;ALSO COULD BE THE BOOT - WARM RESTART
JRST SETCL1 ; SO DON'T WAIT ON IT
IMULI T1,.CPLEN ;OFFSET TO ITS CDB
SKIPE T2,.C0TMF(T1) ;WAIT UNTIL CLOCK FLAG CLEARS, ZERO T2
JRST .-1
SKIPN .C0TMF(T1) ;TIME FROM SET UNTIL SET
JRST .-1
SKIPE .C0TMF(T1)
AOJA T2,.-1
SKIPN .C0TMF(T1)
AOJA T2,.-1
MOVE T3,.CPCPN ;OUR CPU NUMBER
SUB T3,BOOTCP ; MINUS THE BOOT CPU NUMBER
SKIPG T3 ;IF NEGATIVE, (NEVER EQUALS ZERO)
ADDI T3,M.CPU ; MODULO THE NUMBER OF CPU'S
IMULI T2,(T3)
IDIVI T2,M.CPU ;FRACTION OF A TIC TO WAIT
SOJG T2,. ; BEFORE STARTING THE CLOCK
>
SETCL1: MOVEI T1,^D1666 ;ASSUME 60HZ
MOVE T2,STATES
TLNE T2,(ST.CYC) ;IS OUR ASSUMPTION CORRECT?
MOVEI T1,^D2000 ;NO, 2000 IS INTERVAL
CONO TIM,TO.CTD!TO.CIT!TO.SIT(T1) ;START TIMER GOING
>
CONO APR,APRNUL
CONO PI,PI.CPI!PI.TNP!PI.ON!II.ACO!IFE FTKS10,<PI.EPE>
;TURN ON ALL PI, ENABLE MEMORY PARITY
POPJ P,
;SUBROUTINE TO DO A RECAL ON EVERY DISK THAT THE SYSTEM KNOWS ABOUT
; THIS WILL CAUSE A FREE INTERRUPT TO BE GENERATED BY EACH DISK WHICH
; WILL CAUSE FILIO TO REREAD AND VERIFY HOME BLOCKS ON EVERY PACK
; CURRENTLY SPINNING. THUS IF SOME PACKS WERE REMOVED OR MOVED DURING
; THE SYSTEM SLEEP OR POWER FAIL, THE OPERATOR WILL BE COMPLAINED AT
; AND THERE WILL BE NO CHANCE OF COMPROMISING DATA INTEGRITY.
DSKRCL::MOVEI U,SYSUNI##-UNISYS ;START AT FIRST UNIT ON SYSTEM
DSKRC1: HLRZ U,UNISYS(U) ;NEXT UNIT
JUMPE U,CPOPJ ;DONE IF LAST UNIT
MOVE J,UDBKDB(U) ;KONTROLLER THIS UNIT IS CONNECTED TO
MOVSI T1,U2PNRM## ;FIXED MEDIA BIT
IFG <M.CPU-1>,<
MOVE T2,UDBCAM(U) ;CPU THAT THIS UNIT IS ON
TDNE T2,.CPBIT ;THIS CPU?
>
TDNE T1,UNIDS2(U) ;AND NOT FIXED MEDIA (THAT BETTER NOT MOVE)
JRST DSKRC1 ;NEXT UNIT IF NOT THE RIGHT CPU OR FIXED MEDIA
SKIPN UNISTS(U) ;DON'T RECAL IF NOT IDLE (POWER FAIL)
PUSHJ P,@KONRCL##(J) ;RECALIBRATE SO WE WILL GET A FREE INTERRUPT AND
; REREAD THE HOME BLOCKS IN CASE A PACK WAS MOVED
JFCL ;DON'T CARE IF OFF-LINE
JRST DSKRC1 ;LOOK AT NEXT UNIT
SUBTTL EXEC DATA VECTOR SETUP
; HERE TO SET UP SOME EXEC DATA VECTOR QUANTITIES. THESE VARIABLES
; ARE REQUIRED TO SET UP PAGING SO THAT GETTAB AND JOBPEK UUOS MAY
; BE SIMULATED ON A MONITOR CRASH FILE. THESE WORDS CONTAIN CPU
; DEPENDANT INFORMATION. THE EXEC DATA VECTOR FOR THE BOOT CPU, NOT
; THE CRASHING CPU, WILL BE POINTED TO BY .JBEDV IN JOBDAT. ON ALL
; SYSTEMS, .JBEDV IS SET UP AT SYSTEM STARTUP. ON MULTI-CPU SYSTEMS,
; .JBEDV IS RESET ON EVERY ROLE SWITCH. .JBEDV (AND THE CPU DEPENDANT
; EDVS) WILL REQUIRE ADDRESS FIXUPS IF A "SET MEMORY OFFLINE" COMMAND
; IS EXECUTED. THIS BE BECAUSE THE EDVS CONTAIN PHYSICAL ADDRESSES.
;
SETEDV::PUSH P,T1 ;SAVE T1
PUSH P,T2 ;SAVE T2
MOVEI T1,EDVSET ;POINT TO SUBROUTINE
PUSHJ P,CPUAPP ;EXECUTE IT OVER ALL CPUS
IFN FTMP,<
SKPCPU (0) ;ARE WE THE BOOT CPU?
JRST TTPOPJ ;NO--JUST RETURN
>
MOVEI T1,.CPEDV ;POINT TO OUR EDV BLOCK
PUSHJ P,EDVMAP ;MAP THE ADDRESS
MOVEM T2,.JBEDV## ;STASH IT AWAY FOR CURIOUS PROGRAMS
JRST TTPOPJ ;RESTORE ACS AND RETURN
EDVSET: HRRZ T2,.CPTYP-.EVCDB(P1) ;GET DEC CPU TYPE CODE
APRID T1 ;READ SERIAL NUMBER
TLO T2,(ED.KLP) ;ONLY KL-PAGING IS SUPPORTED
IFN FTKL10,<
TRNE T1,ID.XKL ;EXTENDED KL10?
TLO T2,(ED.XKL) ;YES
>
MOVEM T2,.CPEDV-.CPCDB+.EDDAT(P1) ;SAVE IT
MOVE T1,.CPEPT-.CPCDB(P1) ;GET VIRTUAL ADDRESS OF OUR EPT
PUSHJ P,EDVMAP ;MAP PHYSICAL
MOVEM T2,.CPEDV-.CPCDB+.EDEPT(P1) ;SAVE IT
MOVEI T1,SPTTAB ;GET VIRTUAL ADDRESS OF THE SPT
PUSHJ P,EDVMAP ;MAP PHYSICAL
MOVEM T2,.CPEDV-.CPCDB+.EDSPT(P1) ;SAVE IT
SETZM .CPEDV-.CPCDB+.EDCST(P1) ;NO CST NONSENSE ON TOPS-10
MOVEI T1,.CPACA-.CPCDB(P1) ;GET VIRTUAL ADDRESS OF CRASH ACS POINTER
PUSHJ P,EDVMAP ;MAP PHYSICAL
MOVEM T2,.CPEDV-.CPCDB+.EDCAC(P1) ;SAVE IT
POPJ P, ;RETURN
EDVMAP: MAP T2,(T1) ;CONVERT VIRTUAL ADDRESS TO PHYSICAL
TLZ T2,777000 ;STRIP OFF PAGE MAP FLAGS
POPJ P, ;RETURN
;DTE20 DEVICE CODES FROM DTEPRM.MAC
DTE0==200
DTE1==204
DTE2==210
DTE3==214
;RH20 DEVICE CODES
RH2==540
RH21==544
RH22==550
RH23==554
RH24==560
RH25==564
RH26==570
RH27==574
;OTHER DEVICES
FHD2==174 ;DEVICE CODE FOR SECOND FIXED HEAD CONTROLLER
DPC==250 ;DISK PACK CONTROL - NOT IN MACRO.SVE FOR SPMON
DPC2==254 ;DEVICE CODE FOR SECOND DISK PACK CONTROLLER
DPC3==260
DPC4==264
DAS==324
FSD==270
FSD2==274
FSD3==360
DAC==320
DBS==334
DBC==330
DLC==64
DLC2==164
DLB==60
DLB2==160
CDR2==154
LPT2==234
LPT3==230
LPT3==230
PLT2==144
DX10==220
;SUBROUTINE TO STORE INFORMATION IN THE CPU STATUS BLOCK
CPUSTS::APRID .CPAPD ;(0) APRID
CONI APR,.CPACN ;(1) CONI APR,
CONI PI,.CPPIC ;(2) CONI PI,
DATAI PAG,.CPPGD ;(3) DATAI PAG,
CONI PAG,.CPPGC ;(4) CONI PAG,
MOVE T1,[.USMUO,,.CPUP0] ;(5) UPT LOCS 424-427
BLT T1,.CPUP0+3
IFN M.KL10,<
RDERA .CPERA ;(11) RDERA
CONI RH2,.CPRHC ;(12) CONI RH20, FOR ALL 8 RH'S
CONI RH21,.CPRHC+1
CONI RH22,.CPRHC+2
CONI RH23,.CPRHC+3
CONI RH24,.CPRHC+4
CONI RH25,.CPRHC+5
CONI RH26,.CPRHC+6
CONI RH27,.CPRHC+7
CONI DTE0,.CPDTC ;(22) CONI DTEn
CONI DTE1,.CPDTC+1
CONI DTE2,.CPDTC+2
CONI DTE3,.CPDTC+3
HRLZ T1,.CPEPT ;(26) EPT LOCS 0-37
HRRI T1,.CPEP0
BLT T1,.CPEP0+37
MOVE T1,.CPEPT ;(66) EPT LOCS 140-147
HRLI T1,140(T1)
HRRI T1,.CPEP1
BLT T1,.CPEP1+37
>
MOVE T1,[.UPMP+500,,.CPUP1] ;(126) UPT LOCS 500-503
BLT T1,.CPUP1+3
IFN M.KL10,<
EXECAC (6) ;(132) AC BLOCK 6, REGS 0-3 AND 12
MOVEM 0,.CP6
MOVEM 1,.CP6+1
MOVEM 2,.CP6+2
MOVEM 3,.CP6+3
MOVEM 12,.CP6+4
>
IFN M.KS10,<
RDCSTM .CP6
RDPUR .CP6+1
RDCSB .CP6+2
RDSPB .CP6+3
>
EXECAC (7) ;(136) AC BLOCK 7, REGS 0-2
MOVEM 0,.CP7
MOVEM 1,.CP7+1
MOVEM 2,.CP7+2
IFN M.KL10,<MOVEM 3,.CP73> ;*** NOT IN CSB, BUT USEFUL
DATAO PAG,.CPPGD ;RESTORE ORIGIONAL AC BLOCK
IFN M.KL10,<
PUSHJ P,REDSBD ;READ SBDIAG INFO
>
REPEAT 0,<
MOVE T1,.CPCPN ;CURRENT CPU NUMBER
LSH T1,1 ;MULTIPLY BY 2
MOVE T2,.CPSLF ;ADDRESS OF THIS CPU'S CDB
ADDI T2,.CPAPD-.CPCDB ;OFFSET OF CPU STATUS BLOCK IN CDB
MOVEM T2,110(T1) ;STORE ADDRESS OF CPU STATUS BLOCK FOR F/S
MAP T2,(T2) ;ABSOLUTE ADDRESS OF CPU STATUS BLOCK
MOVEM T2,111(T1) ;STORE IT FOR FIELD SERVICE
>;END REPEAT 0
MOVEI T1,SR.CSB ;SET FLAG TO INDICATE CPU
IORM T1,.CPSBR ;STATUS BLOCK READ ON THIS CPU
POPJ P,
IFN M.KL10,<
;ROUTINE TO CLEAR SBUS ERRORS IN EACH MEMORY CONTROLLER. RETURNS
;CPOPJ ALWAYS AND PRESERVES ALL AC'S.
CLRSBD::PUSHJ P,SAVE3 ;SAVE P1-P3
MOVSI P1,-.SBNMC ;MAKE AOBJN POINTER TO ALL MEM CONTROLLERS
MOVSI P2,SB.CLR ;BIT TO CLEAR ALL ERRORS
CLRSB1: DPB P1,[POINT 5,P2,4] ;STORE MEMORY CONTROLLER NUMBER
SBDIAG P2 ;CLEAR THE ERROR BITS
AOBJN P1,CLRSB1 ;LOOP FOR ALL CONTROLLERS
POPJ P, ;RETURN
;ROUTINES TO PERFORM SBDIAG FUNCTIONS 0 AND 1 FOR EACH MEMORY CONTROLLER.
;CALL REDSBD TO JUST READ THE DATA. CALL REDSBC TO READ THE DATA AND
;CLEAR THE ERRORS. THE FORMAT OF THE SBDIAG STATUS BLOCK IS AS FOLLOWS:
; WORD 0: -NUMBER OF DATA BLOCKS,,OFFSET TO FIRST BLOCK
;EACH DATA BLOCK HAS THE FOLLOWING FORMAT:
; WORD 0: -NUMBER OF WORDS FOLLOWING,,CONTROLLER NUMBER
; WORD 1: SBDIAG FUNCTION 0 FROM-MEMORY WORD
; WORD 2: SBDIAG FUNCTION 1 FROM-MEMORY WORD
;DESTROYS T1, PRESERVES ALL OTHERS
REDSBD::TDZA T1,T1 ;CLEAR T1 AND SKIP
REDSBC::MOVSI T1,SB.CLR ;BIT TO CLEAR ERRORS
PUSHJ P,SAVE4 ;SAVE P1-P4
SETZM .CPSBD ;CLEAR FIRST WORD OF BLOCK FOR COUNT
MOVSI P1,-.SBNMC ;AOBJN POINTER TO MEMORY CONTROLLERS
MOVEI P2,.CPSBD+1 ;START FIRST BLOCK HERE
HRLI P2,-.SBFNC ;-FUNCTIONS TO LH
REDSB1: MOVEI P3,0 ;SET TO BUILD TO-MEMORY WORD
DPB P1,[POINT 5,P3,4] ;STORE MEMORY CONTROLLER
SBDIAG P3 ;DO FUNCTION 0
PUSH P,P4 ;SAVE FUNCTION 0 FROM-MEMORY WORD
JUMPE T1,REDSB2 ;AVOID 2ND SBDIAG IF NOT CLEARING CONTROLLER
IOR P3,T1 ;SET SB.CLR
SBDIAG P3 ;DO FUNCTION 0 TO CLEAR CONTROLLER
REDSB2: TRO P3,1 ;MAKE IT FUNCTION 1
SBDIAG P3 ;DO FUNCTION 1
POP P,P3 ;RESTORE FUNCTION 0 FROM-MEMORY WORD
SKIPN P3 ;ANYTHING THERE?
JUMPE P4,REDSB3 ;NO, NO MEMORY CONTROLLER IF BOTH ZERO
MOVEM P3,1(P2) ;SAVE FUNCTION 0 WORD IN THE BLOCK
MOVEM P4,2(P2) ; ALONG WITH FUNCTION 1 WORD
HRRZM P1,0(P2) ;SAVE CONTROLLER NUMBER AS WORD 0
HLLM P2,0(P2) ;MAKE IT -WORDS,,CONTROLLER
AOS .CPSBD ;COUNT THIS CONTROLLER
ADDI P2,.SBFNC+1 ;INCREMENT TO NEXT BLOCK
REDSB3: AOBJN P1,REDSB1 ;LOOP FOR NEXT CONTROLLER
MOVN P1,.CPSBD ;GET NUMBER OF BLOCKS WE STORED
JUMPE P1,CPOPJ ;LEAVE IT ZERO IF NONE
HRLI P1,1 ;MAKE SWAPPED HEADER WORD
MOVSM P1,.CPSBD ;SAVE IN WORD 0
POPJ P, ;RETURN
>;END IFN M.KL10
;SUBROUTINE TO READ AND STORE DEVICE STATUS
DVCSTS::MOVSI T1,-DVSLEN ;LENGTH OF DEVICE STATUS TABLE
XCT DVSXCT(T1) ;DO THE I/O INSTRUCTION
AOBJN T1,.-1 ;LOOP FOR ALL OF THEM
IFN M.KL10,<
HRLI T1,-10 ;NOW DO THE EIGHT RH20'S
DVCST1: LDB T2,[POINT 7,DVSXCT(T1),9] ;GET THE DEVICE CODE
MOVE T3,[CONI RH2,T3] ;LOAD CONI INSTRUCTION
DPB T2,[POINT 7,T3,9] ;MAKE IT SPECIFIC TO THIS RH20
XCT T3 ;DO THE CONI
JUMPL T3,DVCST2 ;JUMP IF NOT AN RH20 (CI/NI)
MOVE T3,[DATAO RH2,RH2IVI] ;LOAD DATAO INSTRUCTION
DPB T2,[POINT 7,T3,9] ;MAKE IT SPECIFIC TO THIS RH20
XCT T3 ;DO THE DATAO TO SELECT IVI REGISTER
XCT DVSXCT(T1) ;NOW DO THE DATAI TO READ THE IVI
DVCST2: AOBJN T1,DVCST1 ;LOOP FOR ALL EIGHT RH20'S
>; END IFN M.KL10
IFN M.KS10,<
PUSH P,.USPFP ;SAVE PREVIOUS PC
PUSH P,.USPFP+1
PUSH P,.USPFW ;SAVE PREVIOUS PAGE FAIL WORD
MOVSI T1,-KSRTBL ;POINTER TO DEVICE ADDRESS TABLE
MOVEI T2,DVCST2 ;TRAP ADDRESS FOR NX DEVICES
EXCH T2,.USPFN ;SET IT AND SAVE CURRENT ONE
DVCST1: RDIO T4,@KSRTAB(T1) ;READ SOME REGISTER
MOVEM T4,.CPUB1(T1) ;SAVE IT IN RIGHT SLOT
;*** HERE ON NX DEVICE TRAP
DVCST2: AOBJN T1,DVCST1 ;DO NEXT
EXCH T2,.USPFN ;RESTORE TRAP ADDRESS
POP P,.USPFW ;RESTORE PREVIOUS PAGE FAIL WORD
POP P,.USPFP+1 ;RESTORE PREVIOUS PC
POP P,.USPFP
>;END IFN M.KS10
IFN M.SA10,<PUSHJ P,SAXDMP##> ;PRESERVE SA10 STUFF
MOVEI T1,SR.DSB ;SET FLAG TO INDICATE
IORM T1,.CPSBR ;DEVICE STATUS BLOCK READ
POPJ P,
IFN M.KL10,<
RH2IVI: .DOIVI ;DATAO TO SELECT IVI
>
;TABLE OF INSTRUCTIONS TO EXECUTE TO FILL IN CDB ENTRIES BEGINNING
;AT CDB VARIABLE .CPDVS. THE ORDER OF THIS TABLE MUST MATCH THE
;ORDERING OF ENTRIES IN THE CDB AT CDB VARIABLE .CPDVS.
;FOR THE KS10 THIS TABLE IS USED A LITTLE DIFFERENTLY. THE FIRST
;PART OF THE TABLE CONTAINS I/O INSTRUCTIONS JUST LIKE FOR THE
;KL10. THE SECOND PART OF THE TABLE CONTAINS THE DEVICE REGISTER
;ADDRESS FOR UNIBUS DEVICES.
DVSXCT::
IFN M.KL10,<
CONI TIM,.CPTMR ;INTERVAL TIMER STATUS
CONI MTR,.CPMTR ;METER STATUS
CONI TTY,.CPTTY
CONI PTR,.CPPRA
CONI PTP,.CPPPA
CONI DLS,.CPDLS
CONI DAC,.CPDAC
CONI DAS,.CPDAS
CONI CR,.CPCRA
CONI LPT,.CPLPT
CONI PLT,.CPPLA
CONI TMS,.CPTMS
CONI TMC,.CPTMC
CONI DX10,.CPDX1
CONI DSK,.CPDSK
CONI FHD2,.CPFH2
CONI FSD,.CPFSD
CONI FSD2,.CPFS2
CONI FSD3,.CPFS3
CONI DPC,.CPDPC
CONI DPC2,.CPDP2
CONI DPC3,.CPDP3
CONI DPC4,.CPDP4
CONI DBS,.CP2DS ;2ND TD10
CONI DBC,.CP2DC
CONI DLC,.CPDLC
CONI DLB,.CPDLB
CONI DLC2,.CPDC2
CONI DLB2,.CPDB2
CONI CDP,.CPCDP
CONI CDR2,.CPCRB ;CDR1
CONI LPT2,.CPLPB ;LPT1
CONI LPT3,.CPLPC ;LPT2
CONI PLT2,.CPPLB ;PLT1
DATAI APR,.CPDAK ;ADDRESS BREAK CONDITIONS
DATAI DSK,.CPDDK
DATAI FHD2,.CPDH2
DATAI FSD,.CPDFS
DATAI FSD2,.CPDS2
DATAI FSD3,.CPDS3
DATAI DPC,.CPDDP
DATAI DPC2,.CPDD2
DATAI DPC3,.CPDD3
DATAI DPC4,.CPDD4
DATAI DLC,.CPDDC
DATAI DLB,.CPDDB
DATAI DLC2,.CPD2C
DATAI DLB2,.CPD2B
DVSLEN==.-DVSXCT ;LENGTH OF (NON-RH20) I/O INSTRUCTION TABLE
DATAI RH2,.CPIVI
DATAI RH21,.CPIVI+1
DATAI RH22,.CPIVI+2
DATAI RH23,.CPIVI+3
DATAI RH24,.CPIVI+4
DATAI RH25,.CPIVI+5
DATAI RH26,.CPIVI+6
DATAI RH27,.CPIVI+7
>;END IFN M.KL10
IFN M.KS10,<
RDINT .CPTMR
RDTIME .CPTMB
DVSLEN==.-DVSXCT ;LENGTH OF I/O INSTRUCTION TABLE
RDTIME .CPTMB+1 ;THIS IS A DUMMY AS RDTIME RETURNS 2 WORDS
KSRTAB: XWD 1,UNBSTW ;UBA1 STATUS REGISTER
XWD 3,UNBSTW ;UBA3 STATUS REGISTER
RH11CA ;RPCS1
RH11CA+10 ;RPCS2
RH21CA ;MTCS1
RH21CA+10 ;MTCS2
LP11CA ;LPT CSRA
LP11CA+2 ;LPT CSRB
CD11BA ;CDR CDST
PR11CA ;PTR CSR
PP11CA ;PTP CSR
RX21BA ;RXA CSR
KSRTBL==.-KSRTAB ;LENGTH OF REGISTER TABLE
>; END IFN M.KS10
IF1,<IFN <.-DVSXCT>-.CPDVL,<PRINTX ?DVSXCT TABLE IS INCORRECT>>
LENDVS==:<.-DVSXCT-1>B26 ;LENGTH OF TABLE OF INSTRUCTIONS FOR GETTAB
;HERE FROM THE DIAG. UUO IN FILIO (FUNCTION 10) TO READ THE CPU STATUS
;BLOCK.
DIACSB::PUSHJ P,CPUSTS ;READ CPU STATUS BLOCK
MOVEI T1,.ERCSB ;DAEMON ERROR CODE
JRST DIADS1 ;JOIN COMMON CODE
;HERE FROM THE DIAG. UUO IN FILIO (FUNCTION 11) TO READ THE DEVICE
;STATUS BLOCK.
DIADSB::PUSHJ P,DVCSTS ;READ DEVICE STATUS BLOCK
MOVEI T1,.ERDSB ;DAEMON ERROR CODE
DIADS1: HRL T1,.CPSLF ;CDB ADDRESS TO LH
PUSHJ P,DAEEIM## ;PLACE IN DAEMON ERROR QUEUE
JRST CPOPJ1 ;GIVE SUCCESS RETURN FROM UUO
;ROUTINE TO TYPE RELEVANT PARTS OF THE CPU STATUS BLOCK ON THE CTY
;WHEN A CRASH OCCURS.
TYPCSB::PUSHJ P,INLMES##
ASCIZ/
CPU Status Block
/
PUSHJ P,INLMES##
ASCIZ/
APRID = /
MOVE T1,.CPAPD ;GET APRID
PUSHJ P,HWDPNT## ;TYPE IT
IFN M.KL10,<
PUSHJ P,INLMES##
ASCIZ/
ERA = /
SKIPN T1,.CPAER
MOVE T1,.CPERA ;GET ERA
PUSHJ P,HWDPNT## ;TYPE IT
>;END IFN M.KL10
PUSHJ P,INLMES##
ASCIZ/
CONI APR, = /
MOVE T1,.CPACN ;GET CONI APR
PUSHJ P,HWDPNT## ;TYPE IT
PUSHJ P,INLMES##
ASCIZ/
CONI PI, = /
SKIPN T1,.CPCPI
MOVE T1,.CPPIC ;GET CONI PI
PUSHJ P,HWDPNT## ;TYPE IT
PUSHJ P,INLMES##
ASCIZ/
CONI PAG, = /
MOVE T1,.CPPGC ;GET CONI PAG
PUSHJ P,HWDPNT## ;TYPE IT
PUSHJ P,INLMES##
ASCIZ/
DATAI PAG, = /
MOVE T1,.CPPGD ;GET DATAI PAG
PUSHJ P,HWDPNT## ;TYPE IT
IFN M.KL10,<
PUSHJ P,INLMES##
ASCIZ/
AR ARX Data Word = /
MOVE T1,.CP7 ;GET AC BLOCK 7 LOC 0
PUSHJ P,HWDPNT## ;TYPE IT
PUSHJ P,INLMES##
ASCIZ/
IO Page Fail Word = /
MOVE T1,.CP7+2 ;GET AC BLOCK 7 LOC 2
PUSHJ P,HWDPNT## ;TYPE IT
PUSHJ P,INLMES##
ASCIZ/
SBUS Diags:
CNTRLR FNC 0 FNC 1
/
PUSHJ P,TYPSBD ;TYPE SBDIAG INFORMATION
>;END IFN M.KL10
PJRST CRLF## ;END WITH CRLF AND RETURN
;ROUTINE TO TYPE THE SBDIAG FUNCTIONS AND VALUES ON THE CTY WHEN
;A CRASH OCCURS.
IFN M.KL10,<
TYPSBD::PUSH P,P1 ;SAVE P1
PUSH P,P2 ; AND P2
MOVE P1,.CPSBD ;GET -# BLOCKS,, OFFSET TO FIRST
HRRZI P2,.CPSBD(P1) ;POINT AT FIRST BLOCK
TYPSB1: HLL P2,0(P2) ;MAKE P2 BE AOBJN POINTER TO THIS BLOCK
HRRZ T1,0(P2) ;GET CONTROLLER LOGICAL ADDRESS
PUSHJ P,OCTPNT## ;PRINT IT
HRRI P2,1(P2) ;ADVANCE TO FIRST OF FUNCTION WORDS
TYPSB2: PUSHJ P,PRSPC## ;SEPARATE FIELDS WITH A SPACE
MOVE T1,0(P2) ;GET NEXT FUNCTION WORD
PUSHJ P,HWDPNT## ;TYPE IT
AOBJN P2,TYPSB2 ;LOOP FOR ALL WORDS IN THIS BLOCK
PUSHJ P,CRLF## ;TYPE CRLF AT END OF LINE
AOBJN P1,TYPSB1 ;LOOP FOR ALL BLOCKS
POP P,P2 ;RESTORE P2
POP P,P1 ; AND P1
POPJ P, ;RETURN
>;END IFN M.KL10
;ROUTINE TO READ THE CPU AND DEVICE STATUS BLOCKS.
;CALL: PUSHJ P,RCDSTB
; RETURN
RCDSTB::PUSHJ P,CPUSTS ;READ CPU STATUS BLOCK
PUSHJ P,DVCSTS ;READ DEVICE STATUS BLOCK
RCDSTD::MOVEI T1,.ERCSB ;CPU STATUS BLOCK ERROR CODE
HRL T1,.CPSLF ;CDB ADDRESS TO LH
PUSHJ P,DAEDIE## ;STORE ENTRY FOR DAEMON
MOVEI T1,.ERDSB ;DEVICE STATUS BLOCK ERROR CODE
HRL T1,.CPSLF ;CDB ADDRESS TO LH
PUSHJ P,DAEDIE## ;STORE ENTRY
POPJ P, ;RETURN
SUBTTL STOP PROCEDURE WHEN SHUTTING DOWN SYSTEM
;TRANSFER HERE ON 404, 405, 406, OR 407 START OR LOCATION 30 BEING
;SET NON-ZERO.
;PROCEDURE TO SAVE CRASHED MONITOR ON DISK FOR LATER DEBUGGING UNDER
;TIMESHARING. OPERATOR SHOULD:
; 1. TRY TO FORCE THE SYSTEM TO TAKE A DUMP BY CAUSING LOCATION
; 30 TO BE SET NON-ZERO. THIS CAN BE DONE FROM THE KEYS ON
; A KI10 OR THROUGH COMMANDS TO THE FRONT-END ON KL10 OR KS10
; SYSTEMS.
; 2. IF THIS DOESN'T WORK, TRY STARTING THE MACHINE AT 406 OR
; 407 (FOR SINGLE CPU SYSTEMS). THIS SHOULD GET US HERE.
; 3. IF ALL ELSE FAILS, LOAD BOOT WITH READ-IN OR VIA THE
; FRONT-END. THIS HAS THE DISADVANTAGE THAT SOME MACHINE
; STATE, THE AC SETS, ETC. ARE LOST.
;HERE ON A 405 START TO SAVE THE MACHINE STATE AND JUMP INTO THE AC'S
STPCPU: DMOVEM P1,RBTSVA ;SAVE P1,P2 IN A VERY TEMPORARY PLACE
JSP P1,PAGENB ;MAKE SURE PAGING IS ON
MOVEI P1,SR.DIE ;SET BIT TO FORCE CPNSER TO LOOP
IORB P1,.CPSBR ; IN THE AC'S UNTIL EXPLICITLY RESTARTED
JRST SYSTO1 ;JOIN COMMON CODE
;HERE ON A 404 START TO SET 30 TO -1 TO FORCE ALL OTHER CPU'S INTO
;THEIR AC'S
STPALL: SETOM CRSHWD ;FORCE ALL OTHER CPU'S INTO THE AC'S
;HERE ON A 406 START TO GET TO MONBTS ON THIS CPU REGARDLESS OF WHO
;THE BOOT CPU IS.
STPLDB: DMOVEM P1,RBTSVA ;SAVE P1,P2 IN A VERY TEMPORARY PLACE
JSP P1,PAGENB ;MAKE SURE PAGING IS ON
MOVEI P1,SR.LBH ;SET BIT TO GET TO MONBTS ON THIS CPU
IORB P1,.CPSBR ; REGARDLESS OF WHO THE BOOT CPU IS
JRST SYSTO1 ;JOIN COMMON CODE
;HERE ON A 407 START OR 30 NON-ZERO AT APR INTERRUPT LEVEL
SYSTOP::DMOVEM P1,RBTSVA ;SAVE P1, P2 IN A VERY TEMPORARY AREA
JSP P1,PAGENB ;MAKE SURE PAGING IS TURNED ON
MOVE P1,.CPSBR ;GET STATUS BITS
SYSTO1: TRNE P1,SR.ACL ;THIS CPU LOOPING IN THE AC'S?
JRST [DMOVE P1,RBTSVA ;YES, AC'S SAVED BY AC LOOP SETUP
JRST SYSTO2] ;SO DON'T SAVE THEM AGAIN
DMOVE P1,RBTSVA ;RESTORE P1 AND P2
JSR .CPSVA ;SAVE ALL AC SETS
SYSTO2: MOVE P,.CPEPD ;SETUP P TO ERRPDL
MOVEI P1,SR.STS ;BIT SET IF MACHINE STATE ALREADY SAVED
TDNN P1,.CPSBR ;ALREADY SAVE MACHINE STATE?
SKIPGE BOOTCP ;NO, MAP SETUP YET?
CAIA ;NO, CAN'T READ DATA BLOCKS
PUSHJ P,RCDSTB ;READ CPU AND DEVICE STATUS BLOCKS
IORM P1,.CPSBR ;SET THE BIT FOR THE NEXT TIME
;FALL INTO REBOOT
;HERE ON ANY CPU FROM DIE OR FALL INTO FROM ABOVE TO RELOAD THE MONITOR.
;IN MULTIPROCESSOR SYSTEMS, ALL BUT THE BOOT CPU ARE DISPATCHED TO
;CP1CRS IN CPNSER. IT IS THE CALLERS RESPONSIBILITY TO SAVE ALL AC
;SETS (WITH .CPSVA) BEFORE GETTING HERE.
REBOOT::EXECAC
MOVE P1,BOOTCP ;SAVE CURRENT VALUE OF BOOTCP
SETZM BOOTCP ;CAUSE SYSTR1 TO NOT CHANGE SERIAL, BOOTCP
JSP T4,SYSTR1 ;TURN ON PAGING FOR THIS CPU
JFCL ;IGNORE RETURN
MOVEM P1,BOOTCP ;RESTORE BOOTCP
MOVEM P3,@.CPSPT ;RESTORE FROM VALUE SYSTR1 SAVE FOR US
IFN M.KL10,<
DATAO DLB,[0]
DATAO DLB2,[0]
>
IFN M.KL10,<
CONO PI,PI.OFF ;TURN OFF PI
SWPUA ;SWEEP CACHE
CONSZ APR,LP.CSB ;WAIT UNTIL DONE
JRST .-1 ; ..
CONI PAG,T1 ;GET PAGING STATE
TRZ T1,LG.CSL!LG.CSW ;TURN OFF, LOOK AND LOAD
CONO PAG,(T1) ;MAINTAIN PAGING BUT WITHOUT CACHE
JSP T4,ZAPICH ;FIX UP INTERNAL CHANNELS
>
IFN M.KS10,<
CONO PI,PI.OFF ;TURN OFF PI
WRUBR NULDOP ;SWEEP CACHE
>
CONO APR,APRRST ;RESET SYSTEM
CONO PI,CLRPIS ;WIPEOUT PI-SYSTEM
IFN FTMP,<
IFG <M.CPU-1>,<
MOVEI T1,SR.LBH ;DO WE WANT TO GET TO MONBTS ON THIS
TDNE T1,.CPSBR ; CPU REGARDLESS OF WHO THE BOOT CPU IS?
JRST REBOO1 ;YES, SKIP THE REST OF THE CHECKS
SKIPL BOOTCP ;MAP SETUP YET?
SKPCPU(1) ;YES, ON ANY BUT THE BOOT CPU?
CAIA ;NO, LOAD BOOTS AND RELOAD
PJRST CP1CRS## ;GO TO CPNSER AND LOOP IN THE AC'S
REBOO1:>>
;CALL TO METINI REMOVED SO METER POINTS WILL BE PRESERVED IN
;THE CRASH DUMP--THIS REQUIRES THAT NONE OF THE ROUTINES
;CALLED BELOW (E.G. GETZ) SHOULD CONTAIN METER POINTS.
MOVE P,.CPEPD ;SETUP P TO SPARE AREA
MOVE T1,[<PM.DCD>B2+PM.WRT+NUPMPP]
;*********
MOVEM T1,NLUPMP+.UMUPT
MOVE T1,LOCYER ;GET YEAR
SUBI T1,^D1970 ;SUBTRACT BASE
JUMPL T1,RLDMON## ;DON'T STORE IF BAD
LSH T1,5 ;SHIFT OVER
IOR T1,LOCDAY ;ADD IN DAY
LSH T1,4 ;AND
IOR T1,LOCMON ;MONTH
HRLZM T1,CRSDTM ;SAVE FOR ONCE AFTER RELOAD
MOVE T2,TIME ;GET TIME IN JIFFIES
IDIV T2,TICSEC ;CONVERT TO SECONDS TO FIT
ADDI T2,RLDTIM
HRRM T2,CRSDTM ;SAVE FOR ONCE AFTER RELOAD
ADD T1,T2 ;ADD DATE AND TIME TOGETHER
HLRZ T2,CRSWHY ;GET LEFT THREE CHARACTERS OF STOPCODE NAME
ADD T1,T2 ;PLUS STOPCD NAME
HRRZ T2,STATES ;GET SCHED SETTING
HRRM T2,CRSSTS ;SAVE FOR RELOAD
ADD T1,T2 ;AND ADD INTO CHECKSUM
ADDI T1,507601 ;ADD IN THE MAGIC CONSTANT
HRRZM T1,CRSCHK ;SAVE CHECKSUM FOR ONCE AFTER
; RELOAD SO IT CAN DEFEND AGAINST
; JUNK OR NON-MONITOR PREDECESSORS.
PJRST RLDMON## ;GO RELOAD MONITOR
SUBTTL FATAL SYSTEM HALT
;THE STOPCODE MACRO DISPATCHES HERE FOR "HALT" TYPE STOPCODES. ONLY
;ESSENTIAL HALT ACTIONS SHOULD BE TAKEN BEFORE EXECUTING THE HALT
;INSTRUCTION AT THE END OF THIS ROUTINE.
DOHALT::EXP 0,0 ;XPCW HERE
EXP IC.UOU,.+1
MOVEM 17,.CPCAC+17 ;SAVE AC 17
MOVEI 17,.CPCAC ;SET UP BLT
BLT 17,.CPCAC+16 ;SAVE ACS 0-16
IFN FTKL10,<JSP T4,ZAPICH> ;ZAP INTERNAL CHANNELS
;HERE TO FORCE A RELOAD BY THE FRONT END
DOLOAD::
IFN FTKL10,<PUSHJ P,LOAD10##> ;TELL MASTER-11 TO RELOAD US
IFN FTKS10,<
MOVSI T1,(KSRLD) ;RELOAD REQUEST BIT
IORM T1,RLWORD ;SET IT FOR THE 8080
WRAPR SP.SSF+SP.IFE ;BANG ON THE 8080'S BELL (POINTLESS TRADITION)
> ;END IFN FTKS10
HALT . ;TERMINATE THIS NONSENSE
IFN FTKL10,<
;SUBROUTINE TO GET THE INTERNAL CHANNELS BACK INTO A KNOWN STATE
;FOR RH20'S DOES A MASSBUS INIT, THEN STOPS RH20 AND CLEARS DONE
;FOR IPA'S (NIA-20 OR CI-20) DOES A PORT CLEAR
ZAPICH::MOVEI T1,FSTICD/4 ;GET FIRST INTERNAL CHANNEL NUMBER
ZPICH1: MOVE T2,[CONI FSTICD,T3] ;GET CONI INSTRUCTION
DPB T1,[POINT 7,T2,9] ;MAKE IT SPECIFIC TO THIS CHANNEL
XCT T2 ;READ CONI
JUMPE T3,ZPICH3 ;JUMP IF NOTHING OUT THERE
MOVE T2,[CONO FSTICD,(T3)] ;GET CONO INSTRUCTION
DPB T1,[POINT 7,T2,9] ;MAKE IT SPECIFIC TO THIS CHANNEL
.CREF CI.PPT ;BIT WE'RE TESTING
JUMPL T3,ZPICH2 ;IF SIGN BIT SET THIS IS A KLNI OR KLIPA
MOVEI T3,CO.MBI ;MASSBUS INIT
XCT T2
MOVEI T3,CO.STP ;STOP
XCT T2
MOVEI T3,CO.CCD ;CLEAR DONE
XCT T2
JRST ZPICH3 ;SKIP IPA STUFF
ZPICH2: MOVEI T3,CO.CPT ;CLEAR PORT
XCT T2
ZPICH3: CAIGE T1,LSTICD/4
AOJA T1,ZPICH1 ;LOOP FOR ALL INTERNAL CHANNELS
JRSTF @T4 ;RETURN
>
;SUBROUTINE TO INSURE THAT PAGING IS ON WHEN WE COME THROUGH
;SYSTOP.
;CALL: JSP P1,PAGENB
; RETURN HERE ALWAYS
PAGENB: DMOVEM T1,RBTSVA+2 ;SAVE AC'S WHICH WILL BE
DMOVEM T3,RBTSVA+4 ; DESTROYED BY SYSTR1
IFN FTKL10,<
CONI PAG,T1 ;GET CURRENT MAPPING
TRNE T1,LG.TEN ;PAGING ALREADY ON?
>
IFN FTKS10,<
RDEBR T1 ;GET CURRENT MAPPING
TRNE T1,SG.TEN ;PAGING ALREADY ON?
>
JRST PAGEN1 ;YES, DON'T ALTER CURRENT STATE
MOVE P2,BOOTCP ;GET CURRENT VALUE OF BOOTCP
SETZM BOOTCP ;MAKE SURE SYSTR1 WILL NOT CHANGE SERIAL, BOOTCP
JSP T4,SYSTR1 ;TURN ON PAGING FOR THIS CPU
JFCL ;IGNORE RETURN
MOVEM P2,BOOTCP ;RESTORE BOOTCP
PAGEN1: DMOVE T1,RBTSVA+2 ;RESTORE T1,T2
DMOVE T3,RBTSVA+4 ; AND T3,T4
JRSTF @P1 ;RETURN
RBTSVA: BLOCK 6 ;STORE P1-P2 AND T1-T4 HERE
ARFLAG::-5 ;TESTED TO SEE IF AUTO RELOAD NEEDED
; COUNTED UP ONE EVERY 60 SEC.
BTXLEN==:^D16 ;MAX LENGTH OF BOOTXT
BTXMXL==:<BTXLEN-1>B26 ;MAXIMUM FOR GETTAB
;THIS BLOCK MAY BE OVERWRITTEN BY ONCE
ZZ1==.
ASCIZ "/D SYSTEM.EXE[1,4] "
BLOCK ZZ1+BTXLEN-.
ZZZ==.-1
IFN <ZZ1&-PAGSIZ-ZZZ&-PAGSIZ>,<
LOC ZZZ&-PAGSIZ
BOOTXT::
ASCIZ "/D SYSTEM.EXE[1,4] "
BLOCK BOOTXT+BTXLEN-.
>
IFE <ZZ1&-PAGSIZ-ZZZ&-PAGSIZ>,<BOOTXT==:ZZ1>
$ABS
LIT ;FORCE INITIALIZATION AND READ BOOTS LITERALS
; INTO THE LOW SEGMENT
SUBTTL COMMON SUBROUTINES
; SET UP AN INSTUCTION TO ENTER DDT VIA THE UNSOLICITED BREAKPOINT.
; THE CDBS ARE INITIALLY BUILT WITH .CPDDT CONTAINING A NOOP. THE
; NOOP MUST BE A TRN. THIS ALLOWS ANY ROUTINE TO DETERMINE IF IT'S
; CPU MAY ENTER EDDT BY DOING A SKIPL .CPDDT (TRN HAS THE SIGN BIT ON).
;
; DEBUGF CONTAINS A MASK OF THE CPUS WHICH MAY ENTER EDDT VIA THE
; UNSOLICITED BREAKPOINT. INITIALLY, THIS MASK IS SET TO ALLOW
; BREAKPOINTS ON ALL CPUS, BUT MAY BE CHANGED AT ANY TIME.
;
$HIGH
CPUDDT::MOVE T1,DEBUGF ;GET DEBUGGING FLAGS
ANDI T1,DF.BPT ;KEEP JUST THE CPU BREAKPOINT MASK
MOVE T2,T1 ;COPY MASK
XOR T1,BPTMSK ;COMPARE
JUMPE T1,CPOPJ ;RETURN IF NO CHANGE
MOVEM T2,BPTMSK ;SAVE NEW MASK
MOVEI T1,.C0CDB ;POINT TO START OF CDB CHAIN
CPUDD1: MOVEI T3,DF.BP0 ;GET BIT FOR CPU0
MOVN T4,.CPCPN-.CPCDB(T1) ;GET A CPU NUMBER
LSH T3,(T4) ;SHIFT TO FIND THIS CPU'S BIT IN MASK
TDNE T3,DEBUGF ;WANT TO ALLOW BREAKPOINTS ON THIS CPU?
SKIPA T2,BPTXCT ;YES--GET INSTRUCTION TO ENTER DDT
MOVE T2,[BPTNOP] ;NO--GET SPECIAL NOOP
MOVEM T2,.CPDDT-.CPCDB(T1) ;SAVE INSTRUCTION
HLRZ T1,.CPCDB-.CPCDB(T1) ;GET ADDRESS OF NEXT CDB
JUMPN T1,CPUDD1 ;LOOP FOR ALL CPUS
POPJ P, ;RETURN
BPTXCT::JSR $0BPT## ;INSTRUCTION TO ENTER DDT
BPTNOP==<TRN 0,0> ;NOOP
$ABS
BPTMSK::EXP -1 ;MASK OF OLD CPU BREAKPOINT BITS
$HIGH
SUBTTL COMMON SUBROUTINES - EXTENDED ADDRESSING
IFN FTXMON,<
$CSUB ;MUST BE ADDRESSABLE BY ALL CODE SEGMENTS
;COROUTINE TO SAVE AND RESTORE THE CALLER'S PC SECTION NUMBER AND
; CALL THE CALLER AS A COROUTINE IN SECTION 1.
;CALLING SEQUENCE:
; PUSHJ P,SSEC1
; ALWAYS RETURNS HERE IN SECTION 1
;RESTORES PC SECTION ON RETURN
SSEC1:: PUSH P,T1 ;SAVE A TEMP
XMOVEI T1,. ;CURRENT SECTION
TLNE T1,MXSECN ;ARE WE ALREADY EXTENDED?
JRST TPOPJ ;YES, GO HOME
HRRZS -2(P) ;MAKE CALLER RETURN TO SECTION 0
MOVSI T1,(MCSEC1) ;A SECTION 1 PC
HLLM T1,-1(P) ; FOR OUR POPJ
XJRST [MCSEC1+TPOPJ] ;ENTER SECTION 1 AND RETURN
;COROUTINE TO SAVE AND RESTORE THE CALLER'S PC SECTION NUMBER AND
; CALL THE SUBROUTINE SPECIFIED IN THE ARGUMENT LIST IN THE SECTION
; SPECIFIED IN THE ARGUMENT LIST
;CALLING SEQUENCE:
; XCT [PUSHJ P,SENCAL
; SN,,ADDR] ;CALL SUBROUTINE AT ADDR IN SECTION SN
; RETURNS AS SUBROUTINE RETURNS
;RESTORES CALLER'S PC SECTION ON RETURN
SENCAL::PUSH P,T1 ;SAVE A TEMP
MOVE T1,-1(P) ;CALLER'S PC
TLNN T1,MXSECN ;ADDRESS OF THE XCT, SKIP IF NOT IN SECTION 0
HRRZS T1,-1(P) ;ADDRESS OF THE XCT, ZERO SECTION NUMBER FOR RETURN
HRRZ T1,-1(T1) ;TARGET OF THE XCT
MOVE T1,1(T1) ;SN,,ADDR
MOVEM T1,1(P) ;SAVE FOR CALL
TLNN T1,MXSECN ;CALL TO SECTION 0?
JRST SSEC0C ;YES, DO REST OF SSEC0
POP P,T1 ;NO, RESTORE T1
XJRST 2(P) ;AND CALL THE SUBROUTINE IN SN SECTION
;COROUTINE TO SAVE AND RESTORE THE CALLER'S PC SECTION NUMBER AND
; CALL THE CALLER AS A COROUTINE IN SECTION 0
;CALLING SEQUENCE:
; PUSHJ P,SSEC0
; ALWAYS RETURN HERE IN SECTION 0.
;RESTORES PC SECTION ON RETURN.
SSEC0:: EXCH T1,(P) ;GET PC WE WERE CALLED AT
TLZN T1,MXSECN ;MAKE SURE IT IS AN EXTENDED PC
JRST [EXCH T1,(P) ;RESTORE T1
POPJ P,] ;AND RETURN IN SECTION 0 (ROUTINE IS A NOOP).
SSEC0C: PUSH P,T1 ;SAVE AS A SECTION 0 PC.
HRRZI T1,SSEC0E ;NOTE SECTION 0 PC.
EXCH T1,-1(P) ;RESTORE T1, LEAVE A RETURN PATH TO US.
POPJ P, ;"RETURN" TO CALLER.
;RETURN HERE IN SECTION 0 ON RETURN FROM ROUTINE WHICH CALLED SSEC0.
SSEC0E: SKIPA ;RETURNED NON-SKIP, LEAVE EVERYTHING ALONE
AOS (P) ;SKIP RETURN, BUMP CALLERS PC
EXCH T1,(P) ;GET RETURN PC TO HIGHER LEVEL ROUTINE.
TLZ T1,-1-MXSECN ;WIPE FLAGS IN CASE SECTION 0 PC
MOVEM T1,1(P) ;SAVE AS PC PART OF XJRSTF DUO-WORD
POP P,T1 ;RESTORE T1
XJRST 2(P) ;RETURN IN PROPER SECTION
>; END IFN FTXMON
IFE FTXMON,<
SSEC0==:CPOPJ ;THESE ARE NO-OPS
SSEC1==:CPOPJ ; ON THE KS
>; END IFE FTXMON
SUBTTL COMMON SUBROUTINES - ERROR RECOVERY
$HIGH
;ERROR RECOVERY - TRY TO START NULL JOB
NULJB1::SETZB J,.CPJOB ;ZERO J AND JOB NUMBER FOR NULJOB
JRST NULJOB## ;GO RESTORE NULL JOB
SUBTTL COMMON SUBROUTINE RETURNS
$CSUB ;MUST BE ADDRESSABLE BY ALL CODE SEGMENTS
CPOPJ2::AOS (P) ;DOUBLE SKIP SUBROUTINE RETURN
RSKP::! ;FOR MACSYM USERS
CPOPJ1::AOSA (P) ;SKIP SUBROUTINE RETURN
DPOPJ:: MOVEM S,DEVIOS(F) ;DEPOSIT I/O STATUS WORD IN DDB
RTN::!
CPOPJ:: POPJ P,
TTPOJ1::AOSA -2(P) ;RESTORE T2, T1 SKIP RETURN
TPOPJ1::AOSA -1(P) ;RESTORE T1 THEN SKIP RETURN
TTPOPJ::POP P,T2
TPOPJ:: POP P,T1 ;RESTORE T1
POPJ P, ;AND RETURN
IPOPJ1::! ;DUPLICATE NAME
JPOPJ1::AOS -1(P) ;SET FOR SKIP RETURN
IPOPJ::! ;DUPLICATE NAME
JPOPJ:: POP P,J ;RESTORE J (USUALLY JOB OR HIGH SEG NUMBER)
POPJ P,
T2POJ1::AOS -1(P)
T2POPJ::POP P,T2 ;RESTORE T2
POPJ P,
MPOPJ1::AOS -1(P)
MPOPJ:: POP P,M
POPJ P,
WPOPJX::CAIA ;NETSER PUSHES THIS ADDR ON THE STACK THEN
WPOPJ1::AOS -1(P) ; EVENTUALLY DOES A CPOPJ1 RETURN
WPOPJ:: POP P,W
POPJ P,
T3POJ1::AOS -1(P)
T3POPJ::POP P,T3
POPJ P,
P3POPJ::POP P,P3
POPJ P,
FUPOJ1::POP P,F
LPOPJ1::!
UPOPJ1::AOSA -1(P) ;SKIP AND RESTORE LINE
FUPOPJ::POP P,F
LPOPJ::!
UPOPJ:: POP P,U ;RESTORE LINE AND RETURN
POPJ P, ;RETURN
FPOPJ1::AOS -1(P)
FPOPJ:: POP P,F ;RESTORE F
POPJ P, ;RETURN
ZPOPJ:: TDZA T1,T1
M1POPJ::SETOM T1
POPJ P,
;GENERATE AND/OR STORE UUO ERROR CODES
ERCALC(ECDMAX)
ERCALX(ECDMAX)
$ABS
SUBTTL COMMON SUBROUTINES - SAVE AC SETS
;ROUTINE TO SAVE ALL AC SETS IN .CPCAC AND .CPCAn. RETURNS WITH
;NO AC'S IN ANY SET CHANGED AND THE FOLLOWING LOCATIONS SETUP:
;
; .CPCPG - ARGUMENT TO DATAO PAG, TO RESTORE CURRENT AC SET
; .CPACA - ADDRESS OF SAVED VALUES FOR CURRENT AC SET.
;
;CALL:
; JSR .CPSVA
; RETURN HERE ALWAYS
SVSETS: DATAI PAG,.CPCPG ;SAVE CURRENT STATE OF AC BLOCKS
SAVE (1,.CPCA1) ;SAVE ALL AC SETS
SAVE (2,.CPCA2) ;...
SAVE (3,.CPCA3) ;...
SAVE (4,.CPCA4) ;...
SAVE (0,.CPCAC) ;AND LEAVE AC SET 0 AC THE CURRENT ONE
LDB 17,[POINT 3,.CPCPG,8] ;GET NUMBER OF CURRENT AC SET
JUMPN 17,SVSET1 ;GO IF NOT AC SET 0
MOVEI 17,.CPCAC ;AC SET 0 IS SAVED AT .CPCAC
JRST SVSET2 ;CONTINUE
SVSET1: IMULI 17,20 ;COMPUTE OFFSET INTO .CPCA1 OF THIS SET
ADDI 17,.CPCA1-20 ;COMPUTE ADDRESS OF THIS SET
SVSET2: MOVEM 17,.CPACA ;SAVE ADDRESS OF WHERE AC SET WAS SAVED
MOVE 17,.CPCAC+17 ;RESTORE AC 17 OF SET 0
DATAO PAG,.CPCPG ;RESTORE CURRENT AC SET
JRSTF @.CPSVA ;RETURN TO CALLER
$ABS
LIT
SUBTTL COMMON SUBROUTINES - SAVE AND RESTORE PRESERVED ACS
;SUBROUTINES TO SAVE AND RESTORE PRESERVED ACS
;SAVEN IS CALLED AT THE BEGINNING OF A SUBROUTINE
;FOR CONVENIENCE NO MATCHING SUB IS NEEDED TO BE CALLED
;TO RESTORE THIS ACS.
;INSTEAD AN EXTRA RETURN IS PUT ON STACK
;5 CHAR NAME INDICATES IT VIOLATES
;SUBROUTINE CALLING CONVENTIONS
;CALL: PUSHJ P,SAVEN
; RETURN HERE IMMEDIATELY WITH EXTRA RETURN ON STACK
; RESPECTS ALL ACS
;NOTE: THIS CODE USES 1 LOC BEYOND END OF STACK BUT THEN PUSHES ON TOP OF IT
;SO GET OVERFLOW INTERUPT IF TOO FULL. OK TO DO 1(P) SINCE THIS WORD WRITTEN ON OVERFLOW
$CSUB ;MUST BE ADDRESSABLE BY ALL CODE SEGMENTS
SAVE1:: EXCH P1,(P) ;SAVE P1, GET CALLER PC
MOVEM P1,1(P) ;SAVE CALLER PC ONE BEYOND END
MOVE P1,(P) ;RESTORE P1
PUSHJ P,@1(P) ;GO BACK TO CALLER, OVERWRITE CALLER PC WITH .+1
JRST RES1
AOS -1(P)
JRST RES1
SAVE2:: EXCH P1,(P) ;SAVE P1, GET CALLER PC
PUSH P,P2
MOVEM P1,1(P) ;SAVE CALLER PC ONE BEYOND END
MOVE P1,-1(P) ;RESTORE P1
PUSHJ P,@1(P) ;GO BACK TO CALLER, OVERWRITE CALLER PC WITH .+1
JRST RES2
AOS -2(P)
JRST RES2
SAVE3:: EXCH P1,(P) ;SAVE P1, GET CALLER PC
PUSH P,P2
PUSH P,P3
MOVEM P1,1(P) ;SAVE CALLER PC ONE BEYOND END
MOVE P1,-2(P) ;RESTORE P1
PUSHJ P,@1(P) ;GO BACK TO CALLER, OVERWRITE CALLER PC WITH .+1
JRST RES3
AOS -3(P)
JRST RES3
SAVE4:: EXCH P1,(P) ;SAVE P1, GET CALLER PC
PUSH P,P2
PUSH P,P3
PUSH P,P4
MOVEM P1,1(P) ;SAVE CALLER PC ONE BEYOND END
MOVE P1,-3(P) ;RESTORE P1
PUSHJ P,@1(P) ;GO BACK TO CALLER, OVERWRITE CALLER PC WITH .+1
JRST RES4
AOS -4(P)
RES4: POP P,P4
RES3: POP P,P3
RES2: POP P,P2
P1POPJ::
RES1: POP P,P1
POPJ P,
;COROUTINE TO SAVE AND RESTORE P2
SAVP2:: EXCH P2,(P) ;SAVE P2, GET CALLER PC
MOVEM P2,1(P) ;SAVE CALLER PC ONE BEYOND END
MOVE P2,(P) ;RESTORE P2
PUSHJ P,@1(P) ;CALL OUR CALLER, OVERWRITE CALLER PC WITH .+1
SKIPA ;PROPOGATE SKIP/NON-SKIP RETURN
AOS -1(P) ;...
P2POPJ::POP P,P2 ;RESTORE P2
POPJ P, ;AND RETURN
;COROUTINE TO SAVE AND RESTORE P3
SAVP3:: EXCH P3,(P) ;SAVE P3, GET CALLER PC
MOVEM P3,1(P) ;SAVE CALLER PC ONE BEYOND END
MOVE P3,(P) ;RESTORE P3
PUSHJ P,@1(P) ;CALL OUR CALLER, OVERWRITE CALLER PC WITH .+1
SKIPA ;PROPOGATE SKIP/NON-SKIP RETURN
AOS -1(P) ;...
POP P,P3 ;RESTORE P3
POPJ P, ;AND RETURN
;COROUTINE TO SAVE AND RESTORE P4
SAVP4:: EXCH P4,(P) ;SAVE P4, GET CALLER PC
MOVEM P4,1(P) ;SAVE CALLER PC ONE BEYOND END
MOVE P4,(P) ;GET BACK P4
PUSHJ P,@1(P) ;GO BACK TO CALLER, OVERWRITE CALLER PC WITH .+1
JRST P4POPJ ;NON-SKIP RETURN
P4PPJ1: AOS -1(P) ;INCREMENT RETURN PC
P4POPJ::POP P,P4 ;RESTORE OLD VALUE OF P4
POPJ P,
;SUBROUTINE TO SAVE AND RESTORE TEMP ACS
;CALLED BY PUSHJ P,SAVT RETURN EITHER CPOPJ OR CPOPJ1 WHEN THROUGH
SAVT:: EXCH T4,(P) ;SAVE T4, GET RETURN ADR.
PUSH P,T3 ;SAVE T3
PUSH P,T2 ;AND T2
PUSH P,T1 ;AND T1
MOVEM T4,1(P) ;STORE PC
MOVE T4,-3(P) ;RESTORE T4
PUSHJ P,@1(P) ;RETURN TO CALLER
SKIPA ;POPJ RETURN
AOS -4(P) ;CPOPJ1 - SET SKIP RETURN
POP P,T1 ;RESTORE T1
POP P,T2 ;RESTORE T3 ACS
POP P,T3
T4POPJ::POP P,T4
POPJ P, ;AND RETURN
;SUBROUTINE TO SAVE AND RESTORE AC'S J AND W
SAVJW:: EXCH J,(P) ;SAVE J AND GET THE RETURN
PUSH P,W ;SAVE W
MOVEM J,1(P) ;SAVE THE RETURN
MOVE J,-1(P) ;RESTORE J
PUSHJ P,@1(P) ;RETURN
SKIPA ;SKIP RETURN NO
AOS -2(P) ;SKIP RETURN YES
POP P,W ;RESTORE W
PJRST JPOPJ ;RESTORE J AND EXIT
;SUBROUTINE TO SAVE U.
SAVU:: EXCH U,(P) ;SAVE U AND GET THE RETURN
MOVEM U,1(P) ;SAVE THE RETURN TO CALLER
MOVE U,(P) ;RESET CALLER'S VALUE OF U
PUSHJ P,@1(P) ;CO-RETURN
JRST UPOPJ ;NON-SKIP, RESTORE U
JRST UPOPJ1 ;SKIP & RESTORE U
;SUBROUTINE TO SAVE U,M, and W. USED MAINLY BY DECNET.
SAVUM:: EXCH U,(P) ;SAVE U AND GET THE RETURN
PUSH P,M ;SAVE M
PUSH P,W ;SAVE W
MOVEM U,1(P) ;SAVE THE RETURN TO USER
MOVE U,-2(P) ;GET ORIGINAL VALUE OF U
PUSHJ P,@1(P) ;RETURN TO CALLING ROUTINE.
SKIPA ;NON-SKIP RETURN
AOS -3(P) ;SKIP RETURN, BUMP RETURN PC
POP P,W ;GET BACK VALUE OF W
POP P,M ;GET BACK VALUE OF M
JRST UPOPJ ;GET BACK VALUE OF U AND RETURN
;COROUTINE TO SAVE AND RESTORE R
SAVR:: EXCH R,(P) ;SAVE R, GET CALLER PC
MOVEM R,1(P) ;SAVE CALLER PC ONE BEYOND END
MOVE R,(P) ;RESTORE R
PUSHJ P,@1(P) ;GO BACK TO CALLER, OVERWRITE CALLER PC WITH .+1
JRST RPOPJ
RPOPJ1::AOS -1(P)
RPOPJ:: POP P,R
POPJ P,
;COROUTINE TO SAVE AND RESTORE W
SAVW:: EXCH W,(P) ;SAVE W, GET CALLER PC
MOVEM W,1(P) ;SAVE CALLER PC ONE BEYOND END
MOVE W,(P) ;RESTORE W
PUSHJ P,@1(P) ;GO BACK TO CALLER, OVERWRITE CALLER PC WITH .+1
JRST WPOPJ
JRST WPOPJ1
;TOPS-20 AC SAVE ROUTINES
T20SYM ;SWITCH TO TOPS-20 AC NAMES
IFN FTSCA!FTENET,<
;SAVE Q1 - Q3
SAVQ:: ADJSP P,3 ;ADJUST STACK
DMOVEM Q1,-2(P) ;SAVE Q1 AND Q2
MOVEM Q3,0(P) ;SAVE Q3
PUSHJ P,@-3(P) ;CALL THE CALLER
SKIPA ;NON-SKIP RETURN
AOS -4(P) ;ADJUST RETURN PC
DMOVE Q1,-2(P) ;RESTORE Q1 AND Q2
MOVE Q3,0(P) ;RESTORE Q3
ADJSP P,-4 ;ADJUST STACK
POPJ P, ;RETURN
;SAVE Q1
SAVQ1:: PUSH P,Q1 ;SAVE Q1
PUSHJ P,@-1(P) ;CALL THE CALLER
SKIPA ;NON-SKIP RETURN
AOS -2(P) ;ADJUST RETURN PC
POP P,Q1 ;RESTORE Q1
ADJSP P,-1 ;ADJUST STACK
POPJ P, ;RETURN
> ;END IFN FTSCA!FTENET
IFN FTSCA,<
;SAVE P1 - P6
SAVP:: ADJSP P,6 ;ADJUST STACK
DMOVEM P1,-5(P) ;SAVE P1 AND P2
DMOVEM P3,-3(P) ;SAVE P3 AND P4
DMOVEM P5,-1(P) ;SAVE P5 AND P6
PUSHJ P,@-6(P) ;CALL THE CALLER
SKIPA ;NON-SKIP RETURN
AOS -7(P) ;ADJUST RETURN PC
DMOVE P1,-5(P) ;RESTORE P1 AND P2
DMOVE P3,-3(P) ;RESTORE P3 AND P4
DMOVE P5,-1(P) ;RESTORE P5 AND P6
ADJSP P,-7 ;ADJUST STACK
POPJ P, ;RETURN
;SAVE P1 - P6 AND Q1 - Q3
SAVPQ:: ADJSP P,^D9 ;ADJUST STACK
DMOVEM P1,-^D8(P) ;SAVE P1 AND P2
DMOVEM P3,-6(P) ;SAVE P3 AND P4
DMOVEM P5,-4(P) ;SAVE P5 AND P6
DMOVEM Q1,-2(P) ;SAVE Q1 AND Q2
MOVEM Q3,0(P) ;SAVE Q3
PUSHJ P,@-^D9(P) ;CALL THE CALLER
SKIPA ;NON-SKIP RETURN
AOS -^D10(P) ;ADJUST RETURN PC
DMOVE P1,-^D8(P) ;RESTORE P1 AND P2
DMOVE P3,-6(P) ;RESTORE P3 AND P4
DMOVE P5,-4(P) ;RESTORE P5 AND P6
DMOVE Q1,-2(P) ;RESTORE Q1 AND Q2
MOVE Q3,0(P) ;RESTORE Q3
ADJSP P,-^D10 ;ADJUST STACK
POPJ P, ;RETURN
> ;END FTSCA
SUBTTL COMMON SUBROUTINES - BLSUB SUPPORT
IFN FTSCA,<
;SUBROUTINE TO SUPPORT BLSUB. USES .A16 AS A TRASH AC,
; AND .FP AS A FRAME POINTER.
.ENTER::PUSH P,.FP ;SAVE THE OLD FRAME POINTER
MOVE .FP,P ;MAKE A NEW FRAME POINTER
ADD P,0(.A16) ;ALLOCATE LOCAL STORAGE
JUMPGE P,ENTOV ;JUMP IF OVERFLOW
ENTOV1: PUSHJ P,1(.A16) ;AND RETURN TO USER
SKIPA ;NON-SKIP RETURN
AOS -1(.FP) ;SKIP RETURN, BUMP RETURN PC
MOVE P,.FP ;RESTORE OLD STACK POINTER
POP P,.FP ;RESTORE SAVED FRAME POINTER
MOVN .A16,-1(P) ;GET -<N,,N>
HRRZM .A16,-1(P) ;STORE 0,,-N
POP P,.A16 ;RECOVER RETURN ADDRESS
ADJSP P,@0(P) ;CLEAN UP THE STACK
JRST 0(.A16) ;RETURN
ENTOV: MOVE P,.FP ;STACK OVERFLOW, UNDO ADD
PUSH P,.A16 ;SAVE LOCAL RETURN IN 1(.FP)
HRRZ .A16,0(.A16) ;GET COUNT
ADJSP P,-1(.A16) ;ALLOCATE SPACE, GET TRAP HERE OR ON PUSH
MOVE .A16,1(.FP) ;RESTORE LOCAL RETURN
JRST ENTOV1 ;CHARGE AHEAD
> ;END IFN FTSCA
SUBTTL COMMON SUBROUTINES - TRVAR/STKVAR
;SUBROUTINE TO HANDLE "TRVAR". USES .A16 AS A TRASH AC,
; AND .FP AS A FRAME POINTER.
T20SYM
.XTRST::
.TRSET::PUSH P,.FP ;SAVE THE OLD FRAME POINTER
MOVE .FP,P ;MAKE A NEW FRAME POINTER
ADJSP P,@(CX) ;ALLOCATE SIZE OFF OF STACK
PUSHJ P,1(CX) ;AND RETURN TO USER
.TRRET: TRNA ;NON SKIP RETURN.
AOS -1(.FP) ;SKIP RETURN, BUMP RETURN PC
MOVE P,.FP ;RESTORE STACK POINTER TO OLD POINTER
POP P,.FP ;RESTORE OLD FRAME POINTER
POPJ P, ;AND RETURN
;SUBROUTINE TO HANDLE "STKVAR". USES R AS A TRASH AC
.XSTKS::
.STKST::ADJSP P,@(CX) ;ADD SOME WORDS ONTO THE STACK
PUSH P,(CX) ;SAVE NUMBER OF WORDS ON STACK
PUSHJ P,1(CX) ;AND RETURN TO CALLER
.STKRT: JRST .STKVT ;NON SKIP RETURN
MOVN CX,(P) ;GET NEGATIVE WORDS SAVED
ADJSP P,-1(CX) ;RETURN THEM, INCLUDING COUNT WORD
AOS (P) ;SKIP RETURN
POPJ P, ;RETURN
.STKVT: MOVN CX,(P) ;GET NEGATIVE WORDS SAVED
ADJSP P,-1(CX) ;RETURN THEM
POPJ P, ;RETURN
PURGEACS
T10SYM
SUBTTL COMMON SUBROUTINES - EXTENDED BLT
;Extended BLT routine. Used mostly by DECnet.
XBLTAT::
XBLTA::
IFN FTXMON,<
EXTEND T1,[XBLT] ;COPY FROM LAST MSD TO NEW USER DATA
>;END IFN FTXMON
IFE FTXMON,<
HRLZS T2 ;SOURCE IN LEFT HALF
HRRI T2,(T3) ;DESTINATION IN RIGHT HALF
ADDI T3,(T1) ;LAST WORD BEYOND DESTINATION
BLT T2,-1(T3) ;COPY THE WORDS
SETZ T1, ;CLEAR NUMBER OF WORDS COPIED
HLRZS T2 ;AND LEAVE LAST SOURCE WORD COPIED HERE
>;END IFE FTXMON
POPJ P, ;RETURN (IMPORTANT!)
;PXCT'ED XBLT SIMULATORS. FOR USE BY UUOS WHICH ALLOW GLOBAL ADDRESSES.
;USED ONLY WHEN FTXMON IS OFF.
IFE FTXMON,<
PBLTXU::HRLZS T2 ;SOURCE IN LEFT HALF
HRRI T2,(T3) ;DESTINATION IN RIGHT HALF
ADDI T3,(T1) ;LAST WORD BEYOND DESTINATION
EXCTXU <BLT T2,-1(T3)> ;DO THE APPROPRIATE FLAVOR OF PXCT
SETZ T1, ;CLEAR NUMBER OF WORDS COPIED
HLRZS T2 ;AND LEAVE LAST SOURCE WORD COPIED HERE
POPJ P, ;RETURN TO CALLER
PBLTUX::HRLZS T2 ;SOURCE IN LEFT HALF
HRRI T2,(T3) ;DESTINATION IN RIGHT HALF
ADDI T3,(T1) ;LAST WORD BEYOND DESTINATION
EXCTUX <BLT T2,-1(T3)> ;DO THE APPROPRIATE FLAVOR OF PXCT
SETZ T1, ;CLEAR NUMBER OF WORDS COPIED
HLRZS T2 ;AND LEAVE LAST SOURCE WORD COPIED HERE
POPJ P, ;RETURN TO CALLER
>;END IF IFE FTXMON
SUBTTL INTERLOCKING ROUTINES
$CSUB
;THIS ROUTINE IMPLEMENTS A SYSTEM WIDE INTERLOCK. IT IS EXACTLY
; SYNONUMOUS TO TURNING THE PI SYSTEM OFF ON A SINGLE PROCESSOR SYSTEM
; EXCEPT IT DOES NOT ALLOW NESTING, I.E., A CALL TO UNLSPI MUST BE
; EXECUTED BEFORE LOKSPI CAN BE CALLED AGAIN.
LOKSPI::CONO PI,PI.OFF ;NO PIS
CONI PI,.CPPIS ;READ CURRENT STATE OF CHANNEL ENABLES
CONO PI,PI.ON+SYSOFF ;TURN THE PI SYSTEM ON,
; LEAVING OFF CHANNELS WHICH OBTAIN THE INTERLOCK
IFG <M.CPU-1>,<
LOKSP1: SKIPGE INTRLK ;DON'T TRY UNLESS ITS POSSIBLE TO GET IT (TIES UP MEMORY)
AOSE INTRLK ;INTERLOCK AVAILABLE?
JRST LOKSP1 ;NO, WAIT UNTIL IT IS
APRID INTOLK ;SERIAL NUMBER OF OWNING CPU
>; END IFG <M.CPU-1>
POPJ P, ;RETURN WITH THE INTERLOCK
;THIS ROUTINE RETURNS THE SYSTEM WIDE INTERLOCK AND EXITS WITH THE PI
; SYSTEM TURNED OFF
UNLSPT::EXCH T1,.CPPIS ;SAVE T1, GET STATE OF THE PI WHEN INTERLOCK WAS OBTAINED
ANDI T1,177 ;ISOLATE CHANNEL ENABLES
TRO T1,PI.OFF ;EXIT WITH PI OFF
JRST UNLSP1 ;JOIN COMMON CODE
;COMMON EXIT ROUTINE TO RETURN SYSTEM WIDE INTERLOCK AND POPJ
ONPOPJ:: ;FALL INTO UNLSPI
; SYSPIN
; POPJ P,
;ROUTINE TO GIVE UP THE SYSTEM WIDE INTERLOCK, RESTORE THE CHANNELS WHICH
; WERE ENABLED WHEN THE INTERLOCK WAS OBTAINED, AND EXIT WITH THE PI IN
; THE STATE IT WAS IN WHEN THE INTERLOCK WAS OBTAINED - ON IF ON/OFF IF OFF
UNLSPI::EXCH T1,.CPPIS ;SAVE T1, GET STATE OF THE PI WHEN INTERLOCK WAS OBTAINED
ANDI T1,177 ;ISOLATE CHANNEL ENABLES
UNLSP1: TRO T1,PI.TNP ;TURN ON SELECTED CHANNELS
EXCH T1,.CPPIS ;RESTORE T1, SET TO RESTORE PI SYSTEM
IFG <M.CPU-1>,<
SETOM INTOLK ;NO LONGER THE OWNER OF THE INTERLOCK
SETOM INTRLK ;RELINQUISH INTERLOCK
>; END IFG <M.CPU-1>
CONO PI,@.CPPIS ;RESTORE THE PI SYSTEM
POPJ P, ;AND RETURN
;ROUTINE TO INTERLOCK ON A DEVICE TO ENSURE THAT THE USER PROGRAM USING
; THE DEVICE IS NOT RUNNING AT UUO LEVEL ON ONE PROCESSOR "PIOFF" WHILE AN
; INTERRUPT FROM THE DEVICE IS BEING SERVICED ON ANOTHER PROCESSOR.
; THIS CAN NOT HAPPEN ON A SINGLE CPU BECAUSE OF CONO PI,PI.OFF.
; THE INTERLOCK IS ONLY BETWEEN UUO LEVEL AND THE INTERRUPT LEVEL WHICH
; THE DEVICE INTERRUPTS TO. THE INTERLOCK IS ONLY ON THE CHANNEL THAT THE DEVICE
; INTERRUPTS ON, I.E., IF A PROCESSOR IS WAITING AT AN INTERUPT LEVEL
; FOR AN INTERLOCK OWNED BY SOME OTHER PROCESSOR AT UUO LEVEL, INTERRUPTS
; AT HIGHER PI LEVELS ON THE WAITING PROCESSOR CAN STILL BE SERVICED.
LOKDPI::CONO PI,PI.OFF ;TURN THE PI SYSTEM OFF
CONI PI,.CPDPI ;READ PI CHANNEL ENABLES
CONO PI,PI.ON+SYSOFF ;TURN PI ON WITH DEVICE CHANNELS OFF
IFG <M.CPU-1>,<
PUSH P,T1 ;SAVE A TEMPORARY
HRRZ T1,DEVCPU(F) ;ADDRESS OF THIS DDB'S INTERLOCK WORD
LOKDP1: SKIPGE (T1) ;ONLY TRY IF ITS POSSIBLE TO GET IT
AOSE (T1) ;DDB INTERLOCK AVAILABLE?
JRST LOKDP1 ;NO, WAIT FOR IT
SUBI T1,INTL0 ;OFFSET INTO INTERLOCKS
APRID INTO0(T1) ;REMEMBER WHICH CPU OWNS THE INTERLOCK
POP P,T1 ;RESTORE T1
>; END IFG <M.CPU-1>
POPJ P, ;RETURN
;COMMON EXIT ROUTINE TO RETURN DEVICE PI INTERLOCK
; AND RETURN WITH PI RESTORED
ONPOPD:: ;FALL INTO UNLDPI
; PION
; POPJ P,
;ROUTINE TO RETURN THE DEVICE INTERLOCK, MARK IT AS UNOWNED, AND
; RESTORE THE PI SYSTEM TO THE STATE IT WAS IN WHEN THE DEVICE WAS
; LOCKED
UNLDPI::PUSH P,T1 ;SAVE A WORKING AC
MOVE T1,.CPDPI ;CHANNEL ENABLES WHEN INTERLOCK WAS OBTAINED
ANDI T1,177 ;ONLY CHANNEL ENABLES
TRO T1,PI.TNP ;TURN ON SELECTED CHANNELS
MOVEM T1,.CPDPI ;FOR CONO
IFG <M.CPU-1>,<
HRRZ T1,DEVCPU(F) ;ADDRESS OF THIS DDB'S INTERLOCK WORD
SUBI T1,INTL0 ;OFFSET INTO INTERLOCK TABLES
SETOM INTO0(T1) ;AND INDICATE NO LONGER OWNED BY THIS CPU
SETOM INTL0(T1) ;RETURN THE DDB INTERLOCK
>; END IFG <M.CPU-1>
CONO PI,@.CPDPI ;RESTORE SELECTED PI CHANNELS
JRST TPOPJ ;RESTORE TEMPORARY AND RETURN
;THIS ROUTINE IMPLEMENTS AN INTERLOCK FOR BIT DIDDLERS (SETOS,CLRBTS).
; IT IS SIMILAR TO LOKSPI AND LOKDPI.
LOKBTI::CONO PI,PI.OFF ;NO PIS
CONI PI,.CPBTI ;READ CURRENT STATE OF CHANNEL ENABLES
CONO PI,PI.ON+SYSOFF ;TURN THE PI SYSTEM ON
IFG <M.CPU-1>,<
LOKBT1: SKIPGE INTLBT ;DON'T TRY IF CAN'T POSSIBLY GET IT (TIES UP MEMORY)
AOSE INTLBT ;INTERLOCK AVAILABLE?
JRST LOKBT1 ;NO, WAIT UNTIL IT IS
APRID INTOBT ;SERIAL NUMBER OF OWNING CPU
>; END IFG <M.CPU-1>
POPJ P, ;RETURN WITH THE INTERLOCK
;COMMON EXIT ROUTINE TO RETURN BIT DIDDLER INTERLOCK AND POPJ
ONPOPB:: ;FALL INTO UNLBTI
; BTSON
; POPJ P,
;ROUTINE TO GIVE UP THE BIT DIDDLER INTERLOCK AND RESTORE THE PI CHANNELS
UNLBTI::EXCH T1,.CPBTI ;SAVE T1, GET STATE OF THE PI WHEN INTERLOCK WAS OBTAINED
ANDI T1,177 ;ISOLATE CHANNEL ENABLES
TRO T1,PI.TNP ;TURN ON SELECTED CHANNELS
EXCH T1,.CPBTI ;RESTORE T1, SET TO RESTORE PI SYSTEM
IFG <M.CPU-1>,<
SETOM INTOBT ;NO LONGER THE OWNER OF THE INTERLOCK
SETOM INTLBT ;RELINQUISH INTERLOCK
>; END IFG <M.CPU-1>
CONO PI,@.CPBTI ;RESTORE THE PI SYSTEM
POPJ P, ;AND RETURN
;THIS ROUTINE IMPLEMENTS AN INTERLOCK FOR BUFFER MANAGEMENT.
; IT IS SIMILAR TO LOKSPI AND LOKDPI.
IFN M.KL10,<
LOKNBI::CONO PI,PI.OFF ;NO PIS
CONI PI,.CPPIB ;READ CURRENT STATE OF CHANNEL ENABLES
CONO PI,PI.ON+SYSOFF ;TURN THE PI SYSTEM ON
IFG <M.CPU-1>,<
LOKNB1: SKIPGE INTLNB ;DON'T TRY IF NOT POSSIBLE TO GET IT
AOSE INTLNB ;INTERLOCK AVAILABLE?
JRST LOKNB1 ;NO, WAIT UNTIL IT IS
APRID INTONB ;SERIAL NUMBER OF OWNING CPU
>; END IFG <M.CPU-1>
POPJ P, ;RETURN WITH THE INTERLOCK
;COMMON EXIT ROUTINE TO RETURN BUFFER MANAGEMENT INTERLOCK AND POPJ
ONPOPN:: ;FALL INTO UNLNBI
; NBFON
; POPJ P,
;ROUTINE TO GIVE UP THE BUFFER MANAGEMENT INTERLOCK AND RESTORE THE PI CHANNELS
UNLNBI::EXCH T1,.CPPIB ;SAVE T1, GET STATE OF THE PI WHEN INTERLOCK WAS OBTAINED
ANDI T1,177 ;ISOLATE CHANNEL ENABLES
TRO T1,PI.TNP ;TURN ON SELECTED CHANNELS
EXCH T1,.CPPIB ;RESTORE T1, SET TO RESTORE PI SYSTEM
IFG <M.CPU-1>,<
SETOM INTONB ;NO LONGER THE OWNER OF THE INTERLOCK
SETOM INTLNB ;RELINQUISH INTERLOCK
>; END IFG <M.CPU-1>
CONO PI,@.CPPIB ;RESTORE THE PI SYSTEM
POPJ P, ;AND RETURN
>; END IFN M.KL10
;ROUTINES TO INTERLOCK/RELEASE SCNSER'S DATA
LOKSCI::CONO PI,PI.OFF ;NO PIS
AOSE .CPSIN ;BUMP LEVEL OF NESTING
JRST [SKIPGE .CPDWD ;IN MIDDLE OF A STOPCODE?
STOPCD .,STOP,SCNRIA, ;++RECURSIVE INTERLOCK ATTEMPT
CONO PI,PI.ON ;JUST NESTING, RETURN, ALREADY HAVE INTERLOCK
POPJ P,] ;...
CONI PI,.CPSCI ;READ CURRENT STATE OF CHANNEL ENABLES
CONO PI,PI.ON+SCNPIF ;TURN THE PI SYSTEM ON
IFG <M.CPU-1>,<
LOCSC1: SKIPGE SCNLOK
AOSE SCNLOK
JRST LOCSC1
APRID INOSCN
>; END IFG <M.CPU-1>
POPJ P,
UNLSCI::PUSH P,T1 ;SAVE A REGISTER
SOSL T1,.CPSIN ;DECREMENT LEVEL OF NESTING, SEE IF DONE
PJRST TPOPJ ;STILL NESTING, JUST RETURN
EXCH T1,.CPSCI ;GET CHANNEL ENABLE STATES
ANDI T1,177 ;KEEP JUST THE CHANNELS WHICH WERE ON
TRO T1,PI.TNP ;TURN THEM BACK ON
EXCH T1,.CPSCI ;RESTORE T1, SET TO RESTORE PI SYSTEM
IFG <M.CPU-1>,<
SETOM INOSCN
EXCH T1,SCNLOK ;RESET THE INTERLOCK
SKIPGE T1 ;MAKE SURE IT WAS OWNED
STOPCD .,CPU,SCNIU, ;++ SCNSER INTERLOCK UNOWNED
>; END IFG <M.CPU-1>
CONO PI,@.CPSCI ;PUT THE PI SYSTEM BACK THE WAY IT WAS
PJRST TPOPJ ;RESTORE T1 AND RETURN
;ROUTINES TO INTERLOCK/RELEASE NETSER'S DATA
LOKNPI::CONO PI,PI.OFF ;TURN PI SYSTEM OFF
CONI PI,.CPNTI ;SAVE CHANNEL ENABLE STATE
CONO PI,PI.ON+NETPIF ;TURN PI SYSTEM BACK ON, LEAVE NET CHANS OFF
IFG <M.CPU-1>,<
LOKNP1: SKIPGE NETLOK
AOSE NETLOK
JRST LOKNP1
APRID INONET
>; END IFG <M.CPU-1>
POPJ P,
UNLNPI::EXCH T1,.CPNTI ;SAVE T1, GET CHANNEL ENABLE STATE
ANDI T1,177 ;KEEP JUST CHANNELS
TRO T1,PI.TNP ;TURN THEM BACK ON
EXCH T1,.CPNTI ;RESTORE T1, SAVE CHANNEL ENABLE STATE
IFG <M.CPU-1>,<
SETOM INONET
SETOM NETLOK
>; END IFG <M.CPU-1>
CONO PI,@.CPNTI ;TURN THE CHANNELS BACK ON
POPJ P,
;ROUTINES TO INTERLOCK/RELEASE ETHSER'S DATA
IFN FTENET,<
LOKETH::AOSE .CPETH ;BUMP NESTING INTERLOCK
POPJ P, ;STILL NESTING, RETURN
CONO PI,PI.OFF ;DISABLE INTERRUPTS
IFG <M.CPU-1>,<
LOKET1: SKIPGE ETHLOK ;INTERLOCK POSSIBLY AVAILABLE
AOSE ETHLOK ;YES, TRY FOR INTERLOCK
JRST LOKET1 ;DIDN'T SUCCEED, LOOP
APRID INOETH ;RECORD INTERLOCK OWNER
>; END IFG <M.CPU-1>
POPJ P, ;AND RETURN
UNLETH::SOSL .CPETH ;DECREMENT NESTING COUNT
POPJ P, ;STILL NESTED, RETURN
IFG <M.CPU-1>,<
SETOM INOETH ;...
SETOM ETHLOK ;RELEASE INTERLOCK
>; END IFG <M.CPU-1>
CONO PI,PI.ON ;RE-ENABLE INTERRUPTS
POPJ P, ;AND RETURN
>; END IFN FTENET
SUBTTL COMPUTE NUMBER OF WORDS DESCRIBED IN AN IOLIST
IFN M.KL10,<
;ROUTINE TO COMPUTE THE NUMBER OF WORDS DESCRIBED IN AN IOLIST
;ENTER WITH T1=ADDR OF THE INITIAL CONTROL WORD
; AND WITH P1=LOC OF CHANNEL DATA BLOCK
;EXIT WITH T1=NUMBER OF GOOD WORDS TRNSFERRED
; T2=CORRECTIVE DATA FOR IOWD
; T3= N,,LOC OF FAILING IOWD WHERE N=0 IF RH10, N=-1 FOR RH20
WRDCNT::TDZA T2,T2
WRDCNX::MOVSI T2,200000
PUSHJ P,SAVE4 ;SAVE P1,P2
MOVEI P3,-1 ;SET UP MASK
HLLZ P2,T2 ;ASSUME 22 BIT CHAN
MOVE T2,CHNTYP(P1) ;GET CHANNEL TYPE BITS
TLNE T2,CP.RH2 ;RH20?
HRROI P2,2 ;YES, SPECIAL STUFF
ASH P3,@ASH22B(P2) ;SHIFT MASK
SETZ P1, ;P1 WILL ACCUMULATE WRDCNT
LDB T3,CNTPT1(P2) ;L(IOWD)+1
CAILE T3,20 ;IS IOWD LOC LEGAL?
CAMLE T3,SYSSIZ
JRST WRDCN5 ;NO, WORD-COUNT=0
LDB T2,CNTPT2(P2)
JUMPN T2,WRDCN0
MOVE T3,T1 ;YES, GET START OF LIST
WRDCNA: LDB T2,CNTPT3(P2)
JUMPN T2,WRDCNB
SKIPN (T3)
JRST WRDCNC
MOVE T3,(T3) ;YES, GET ITS ADDRESS
JRST WRDCNA ; AND TEST IT
WRDCNB: MOVE T4,T3 ;YES, SAVE LOC OF REAL IOWD IN T4
AOJA T3,WRDCNA ; AND TEST NEXT
WRDCNC: AOS T3,T4 ;END - T3=L(LAST IOWD)+1
WRDCN0: LDB T4,ADRPT2(P2)
LDB T2,ADRPT1(P2) ;LOC+1 OF GOOD DATA WRD
JUMPL P2,[CAMLE T4,T2 ;RH20 ADR IS 1 HIGHER
JRST WRDCN5 ; SO EQUALS IS OK
MOVE P4,2(T1) ;SAVE ENDING CHAN DATA FOR TEST
LDB T3,CNTPT2(P2) ;WORDCOUNT
ADD T4,T3 ;TOP ADDR +1 OF IOWD
JRST WRDCND] ;CARRY ON
CAML T4,T2 ;IS LAST DATA WRD IN BOUNDS?
JRST WRDCN5 ;NO, ASSUME THAT IOWD IS NG
HLRO T3,-1(T3) ;MAYBE
ASH T3,@ASH22B(P2) ;WORD COUNT
SUB T4,T3 ;LAST GOOD ADR IN IOWD+1
WRDCND: CAMGE T4,T2 ;IS WORD IN BOUNDS?
JRST WRDCN5 ;NO
LDB T1,ADRPT3(P2)
WRDCN1: SKIPN (T1) ;IS THERE AN IOWD?
JRST WRDCN5 ;NO, THE DF10 LIED!
JUMPL P2,[CAMN P4,(T1) ;THIS IOWD WHAT THE RH20 STORED?
JRST WRDCNF ;YES. THE LAST IOWD IS LAST IT DID
LDB T4,[POINT 11,(T1),13]
MOVNS T4 ;11 BITS OF NEGATIVE WDCNT
JRST WRDCNE]
HLRO T4,(T1) ;WDCNT OF IOWD
ASH T4,@ASH22B(P2) ;WORD COUNT
WRDCNE: LDB T3,ADRPT3(P2) ;1ST ADDR OF IOWD -1
TRNN T4,(P3) ;IF RH 14 BITS=0
JRST WRDCN3 ; ITS A CHAN JUMP
CAMG T2,T3 ;GOOD DATA WD IN THIS IOWD?
JUMPN T3,WRDCN2 ;YES, COUNT THE DATA AND STEP TO NEXT
SUB T3,T4 ;MAYBE. ADR OF TOP WD IN IOWD
CAMG T2,T3 ;LAST GOOD DATA IN IOWD?
JRST WRDCN4 ;YES
WRDCN2: SUB P1,T4 ;THIS IOWD IS GOOD. COUNT # OF WDS
HRLS T1 ;SAVE LOC OF GOOD IOWD
AOJA T1,WRDCN1 ;AND GO TEST NEXT IOWD
WRDCN3: JUMPE T3,WRDCN5 ;DF10 BLEW IT IF THIS THE END OF THE LIST
MOVE T1,T3 ;CHAN JUMP - SET T1 TO ADR
JRST WRDCN1 ;OF IOWD AND TEST IT
;HERE WITH T1=LOC OF FAILING IOWD, P1=NO OF WDS IN PREVIOUS IOWDS
;T2=TERMINATION WORD, T3=ADDR+COUNT
;I.E. ON RH10 T3=<LAST WORD>, ON RH20 T3=<LAST WORD>+1
;IF THE ERROR IS IN THE MIDDLE OF AN IOWD,
;THE RH10 STORES <LAST WORD XFERED>+1 IN THE
;TERMINATION WORD. BUT IF THE ERROR IS IN THE LAST
;SECTOR OF THE LAST IOWD, THEN THE RH10 MERELY
;STORES <LAST WORD XFERED>
WRDCN4: CAMN T2,T3 ;LAST SECTOR OF IOWD?
TLNE P2,600000 ;AND RH10?
CAIA ;NO, RH20 OR NOT LAST
ADDI T2,1 ;YES, ADD FUDGE FACTOR
LDB T3,ADRPT3(P2)
TLNN P2,600000
ADDI T3,1
SUB T2,T3 ;NO OF GOOD DATA WDS IN IOWD
ADD P1,T2 ;P1=TOTAL GOOD WORDCOUNT
JUMPE P1,WRDCN6 ;NO CORRECTION IF NO DATA
CAIG T2,1 ;IF ONLY 1 WORD
TRNE P1,BLKSIZ##-1 ;OR NOT AN EVEN MULTIPLE OF 200 WORDS
JRST WRDCN6 ;NO CORRECTION DATA (CHANNEL BLEW IT)
SUB P1,T2 ;NUMBER OF REMAINING WORDS
WRDCNF: HLRZS T3,T1 ;ADDRESS OF IOWD
LDB T2,CNTPT3(P2) ;GET ORIGINAL COUNT OF THIS IOWD
JUMPL P2,WRDCN6 ;GO IF RH20
HLRO T2,(T3) ;RH10, MUST GET +COUNT
ASH T2,@ASH22B(P2)
MOVNS T2
WRDCN6: MOVEI T3,T2 ;T2 WILL GET THE ANSWER
SKIPL P2 ;RH10?
SKIPA T4,T2 ;YES, GET - COUNT
MOVN T4,T2 ;NO, ALREADY HAVE -COUNT
DPB T4,CNTPT3(P2) ;SAVE LH CORRECTION DATA
SKIPGE T3,P2 ;RH20?
TLO T2,700000 ;YES, ALLOW FOR CARRY INTO BIT 2
HRR T3,T1 ;RH OF CORRECTION DATA
SKIPA T1,P1 ;TOTAL NO OF GOOD WORDS
WRDCN5: SETZB T1,T3 ;WE LOSE, ZERO MEANINGFUL ACS
POPJ P, ;RETURN WITH ANSWER
;BYTE POINTERS INDEXED BY CHANNEL TYPE 0 = DF10C, 1 = DX10, 2 = RH20
ADRPT1::POINT 22,1(T1),35
EXP -1
POINT 22,2(T1),35
ADRPT2::POINT 22,-1(T3),35
EXP -1
POINT 22,-1(T3),35
ADRPT3: POINT 22,(T1),35
EXP -1
POINT 22,(T1),35
ADRPT4::POINT 14,T1,13
EXP -1
POINT 14,T1,13
CNTPT1::POINT 14,1(T1),13
EXP -1
POINT 22,1(T1),35
CNTPT2::POINT 14,-1(T3),13
EXP -1
POINT 11,-1(T3),13
CNTPT3::POINT 14,(T3),13
EXP -1
POINT 11,(T3),13
ASH22B::0,,-4
0,,-4
0,,-7
CNTFIL::XWD -1,740000
MSK22B::XWD 17,-1
WDCPNT::POINT 14,0(P1),13
POINT 14,0(P1),13
POINT 14,0(P1),13
>;END IFN M.KL10
SUBTTL COMMON SUBROUTINES - CPUAPP
;SUBROUTINE TO EXECUTE A SUBROUTINE OVER ALL CPU'S
;CALLING SEQUENCE:
; MOVEI T1,SUBROUTINE TO BE EXECUTED, OR
; HRROI T1,IF SUBROUTINE SHOULDN'T BE EXECUTED ON THIS CPU
; PUSHJ P,CPUAPP
;SUBROUTINE IS CALLED WITH P1 POINTING AT A CPU CDB
; FOR WHICH THE DESIRED ACTION IS TO BE APPLIED
$CSUB ;MUST BE ADDRESSABLE BY ALL CODE SEGMENTS
CPUAPP::PUSHJ P,SAVE1 ;SAVE P1
IFE M.CPU-1,<
JUMPL T1,CPOPJ ;RETURN IF NOT TO BE APPLIED TO .CPSLF
MOVEI P1,.C0CDB ;ONLY CPU0
TLO T1,(IFIW) ;STAY IN CALLER'S SECTION
JRST (T1) ;DO IT
>
IFN M.CPU-1,<
PUSH P,T1 ;SAVE ADDRESS OF SUB
SKIPL T1 ;CALL SUB ON SELF CPU?
TDZA T1,T1 ;YES, CLEAR T1 AND SKIP
MOVE T1,.CPSLF ;NO, GET ADDRESS OF SELF CDB
PUSH P,T1 ;SAVE ON STACK
HLLZ T1,-2(P) ;GET RETURN PC OF SAVE1 CALL
TLZ T1,-1-MXSECN ;STAY IN CALLER'S SECTION
HRR T1,-1(P) ;CALLER'S SECTION NUMBER + PC
EXCH T1,-1(P) ;RESTORE T1, SAVE CALLER'S PC
MOVEI P1,.C0CDB ;START WITH CPU0
CPUAP1: CAME P1,(P) ;POSSIBLY SKIP CALL ON SELF CPU
PUSHJ P,@-1(P) ;CALL THE SUBROUTINE
JFCL ;ALLOW FOR A SKIP RETURN
HLRZ P1,.CPCDB-.CPCDB(P1) ;NEXT CDB
JUMPN P1,CPUAP1 ;NEXT CPU
ADJSP P,-2 ;SO CALLED ROUTINE CAN RETURN AN ANSWER IN T1
POPJ P, ;RETURN
>
$ABS ;MUST BE IN LOW SEG FOR ONCE REFERENCES
;SUBROUTINE TO REFERENCE A MEMORY LOCATION IN PHYSICAL MEMORY
;CALLING SEQUENCE:
; MOVE U,ABSOLUTE ADDRESS TO REFERENCE
; PUSHJ P,REFMEM
; ... RETURN HERE
;T1 CONTAINS THE CONTENTS OF THE LOCATION SPECIFIED BY U
REFMEM::PUSH P,P1 ;CAN'T USE SAVE1
MOVE P1,U ;COPY ADDRESS
LSH P1,W2PLSH ;ISOLATE PAGE NUMBER
HRLI P1,(<PM.DCD>B2+PM.WRT) ;MAKE IT ACCESSIBLE AND WRITABLE
PUSH P,P3 ;SAVE AN AC
MOVE P3,.CPMAP ;GET ADDRESS OF S0 MAP
MOVEM P1,.EUPMP/PAGSIZ(P3) ;MAKE ADDRESSABLE VIA .EUPMP
CLRPT .EUPMP ;FLUSH MAPPING FOR THAT PAGE
MOVE P1,U ;COPY ADDRESS
ANDI P1,PG.BDY ;KEEP JUST LINE NUMBER WITHIN PAGE
IORI P1,.EUPMP ;PLUG IN REST OF VIRTUAL ADDRESS
MOVEI P3,REFME2 ;SET UP PAGE FAULT ADDRESS SINCE NXM MAY CAUSE
; AR/ARX PARITY TRAP
PUSH P,.USPFN ;SAVE NEW PC
MOVEM P3,.USPFN ;STORE NEW TRAP ADDRESS
SETZ T1, ;RETURN A ZERO IF NXM
MOVES T1,(P1) ;REFERENCE THE ADDRESS AND UPDATE CONTENTS
REFME2: POP P,.USPFN ;RESTORE NEW PC
POP P,P3 ;RESTORE ACS
POP P,P1
POPJ P, ;RETURN
$HIGH
IFN M.KS10,<
;ROUTINE TO COMPUTE THE NUMBER OF WORDS TRANSFERRED IN THE LAST I/O OPERATION
;THROUGH THE UNIBUS ADAPTER LINKED TO THE CHANNEL DATA BLOCK POINTER TO BY
;P1. FINAL ADDRESS IS IN T1.
;RETURNS CPOPJ ALWAYS WITH THE NUMBER OF GOOD WORDS TRANSFERRED IN T1.
WRDCNT::HRRZ T2,CHNIEA(P1) ;GET INITIAL ELEVEN STYLE ADDRESS
SUB T1,T2 ;SUBTRACT FROM FINAL ADDRESS
LSH T1,-2 ;GET INTO TEN STYLE WORDS
POPJ P, ;AND RETURN
>;END IFN M.KS10
SUBTTL DAEMON ERROR REPORT BLOCK
$ABS
IFNDEF ERPTMX,<ERPTMX==:^D80> ;LENGTH OF BLOCK FOR ERRORS
ERPTBK::BLOCK ERPTMX ;BLOCK FOR ERRPT. UUO
ESVIDX::EXP 0 ;POINTER FOR STORING IN ERPTBK
EPKIDX::EXP 0 ;POINTER FOR PICKING UP FROM ERPTBK
ERRLAP::EXP 0 ;COUNTER FOR OVERFLOWS OF ERPTBK (LOST ERRORS)
SUBTTL SYSTEM BYTE POINTERS
$CSUB
PUUOAC::POINT 4,M,12 ;UUO AC FIELD
PIOMOD::POINT 4,S,35 ;MODE BITS
XP PJBNLH,001100 ;LEFT HALF OF "POINT 9,XXX,35"
PUNIT:: POINT 9,DEVJOB(F),17 ;DEVICE UNIT NUMBER
PCTXN:: POINT 9,DEVJOB(F),26 ;DEVICE CONTEXT ASSIGNMENT
PJOBN:: POINT 9,DEVJOB(F),35 ;DEVICE JOB ASSIGNMENT
PJCHN:: POINT 18,DEVJOB(F),35 ;DEVICE JOB/CONTEXT HANDLE ASSIGNMENT
PJBSTS::POINT JWSIZ,JBTSTS(J),JWPOS ;JOB WAIT STATE (QUEUE) CODE
;IN JOB STATUS WORD
PJBST2::POINT JS.SIZ,JBTST2(J),JS.POS ; JOB QUEUE NUMBER (NOT STATE CODE)
PJ2ST1::POINT JS.SIZ,JBTST2(T1),JS.POS ;SAME AS PJBST2 FOR IDX T1
JBYEWT::POINT ESLPSZ,JBTST2(J),ESLPBP ;EVENT WAIT REASON
JBYICC::POINT ICCSIZ,JBTSTS(J),ICCPOS ;POINTER TO HIGH
; SEGMENT IN CORE COUNT
PDVSTA::POINT 6,DEVSTA(F),35 ;STATION NUMBER OF DEVICE
PBUFSZ::POINT 17,DEVCHR(F),35 ;BUFFER SIZE
PDVTIM::POINT 3,DEVCHR(F),9 ;CODE FOR TIME DEVICE MAY
;BE ACTIVE BEFORE BEING DECLARED
;HUNG. N MEANS 2^N-1 SECONDS
PDVCNT::POINT 7,DEVCHR(F),16 ;COUNTED DOWN EACH SECOND,
;1 TO 0 TRANSITION MEANS HUNG DEVICE
IADPTR::POINT 2,DEVIAD(F),2 ;COUNT OF NUMBER OF USER CHANNELS INITED
; ON THIS DEVICE (DECTAPE ONLY)
DEYSPL::POINT 8,DEVSPL(F),17 ;SPOOL BIT ASSOCIATED WITH DEVICE
DEYISN::POINT 5,DEVISN(F),17 ;POINTER TO SECTION OFFSET FOR MULTI-SECTION I/O
DEYTYP::POINT 8,DEVTYP(F),9 ;POINTER TO DEVICE-TYPE BIT (+.TYVAR & .TYRAS)
PDVTYP::POINT 6,DEVTYP(F),9 ;JUST DEVICE TYPE
PCORSZ::POINT CRSIZ,JBTADR(J),CRPOS ;BYTE POINTER TO LOW OR HIGH SEG CORE SIZE-1
PCORSR::POINT CRSIZ,R,CRPOS ;SAME FROM R
PDYQT2::POINT PDSQNT,.PDQNT(T2),PDNQNT
PDYQNT::POINT PDSQNT,.PDQNT(W),PDNQNT ;POINTER TO QUANTUM RUN TIME FOR JOB
PDYIPT::POINT PDSIPT,.PDIPT(W),PDNIPT ;POINTER TO INCORE PROTECT TIME
PDYIP2::POINT PDSIPT,.PDIPT(T1),PDNIPT ;POINTER TO INCORE PROTECT TIME
PDYDPT::POINT 9,.PDDFL(W),8 ;DEFAULT PROTECTION
PDYBFN::POINT 9,.PDDFL(W),35 ;DEFAULT NUMBER OF DISK BUFFERS
IFN FTFDAE,<
PDYFSP::POINT 9,.PDDFL(W),26 ;FILE DAEMON SUPPLIED PROTECTION
>
PDYBSN::JBPBSN+.PDOBI(W) ;POINTER TO BATCH STREAM NUMBER
PDYOPP::JBPOPP+.PDOBI(W) ;POINTER TO OPERATOR PRIVILEGES BYTE
PDYWTO::JBPWTO+.PDOBI(W) ;POINTER TO WRITE-TO-OPR TYPE
PIEVM:: POINT 9,DEVEVM(F),8 ;VIRTUAL PAGE NUMBER OF STARTING PAGE IN THE
; EXEC MAP ALLOCATED TO THIS DEVICE FOR BUFFERED INPUT
PIEVMS::POINT 9,DEVEVM(F),17 ;NUMBER OF PAGES IN THE EXEC MAP ALLOCATED TO
; THIS DEVICE FOR BUFFERED INPUT
POEVM:: POINT 9,DEVEVM(F),26 ;VIRTUAL PAGE NUMBER OF STARTING PAGE IN THE
; EXEC MAP ALLOCATED TO THIS DEVICE FOR BUFFERED OUTPUT
POEVMS::POINT 9,DEVEVM(F),35 ;NUMBER OF PAGES IN THE EXEC MAP ALLOCATED TO
; THIS DEVICE FOR BUFFERED OUTPUT
XP PDEVM,POEVM ;VIRTUAL PAGE NUMBER OF STARTING PAGE IN THE EXEC
; MAP ALLOCATED TO THIS DEVICE FOR DUMP I/O
XP PDEVMS,POEVMS ;NUMBER OF PAGES IN THE EXEC MAP ALLOCATED TO
; THIS DEVICE FOR DUMP I/O
PDVESE::POINT 9,DEVESE(F),35 ;EXTENDED ERROR STATUS
IFN FTMP,<
DEYCPF::POINT 3,DEVCPU(F),2 ;1ST CPU OWNING DEVICE
CPFBOO==:7 ;CODE NUMBER FOR BOOT CPU
CPFBIT==:6 ;CODE NUMBER FOR CI DEVICE
;MUST USE BIT MASK FOR ALL CI DEVICES
DEYCPS::POINT 3,DEVCPU(F),5 ;2ND CPU OWNING DEVICE
;THIS FIELD IS NO LONGER USED
;FOR HISTORICAL PURPOSES THE CODE HAS
;BEEN REPEAT ZEROED. SEE CHKCPI AND CPUDDB
DEYPCL::POINT 3,DEVCPU(F),8 ;0 FOR NON-Q PROTOCOL, CPU DOING IO FOR QUEUED
PCLCP0==:7 ;CODE NUMBER FOR CPU0
PCLDKY==:6 ;CODE NUMBER FOR "I DON'T KNOW YET"
DEYCPU::POINT 3,DEVCPU(F),11 ;CPU WHICH LAST DID INPUT OR OUTPUT UUO
MPYNRN::POINT 6,JBTSPS(J),5 ;NOT RUNNABLE ON CPUN FIELD
>
NFYPGS::POINT MCPSIZ,JBTPDB(J),MCPBPP ;POINTER TO NUMBER OF FUNNY PAGES
IFYPGS::POINT MCPSIZ,JBTPDB(J),IMCPBP ;NUMBER OF FUNNY PAGES TO SWAP IN
IMGIN::POINT 21,JBTIMI(J),35 ;SIZE OF USER JOB IN P IN CORE
IMGOUT::POINT 21,JBTIMO(J),35 ;SIZE OF USER JOB IN P ON DISK
OUTMSK==:7,,777777 ;MASK OF IMAGE SIZE IN JBTIMI/JBTIMO/JBTVIR
NZSICN::POINT 6,JBTIMI(J),8 ;NUMBER OF NZS MAPS FOR SWAPIN
NZSSCN::POINT 6,JBTIMI(J),14 ;NUMBER OF NZS MAPS
NZSXCN::POINT 12,JBTIMI(J),14 ;ALL NZS MAP COUNT
LOVSIZ::POINT 21,JBTVIR(J),35 ;VIRTUAL LOW SEG SIZE
HIVSIZ::POINT 9,JBTVIR(J),14 ;VIRTUAL HI SEG SIZE
JBYSPR::POINT JBSSPR,JBTSTS(J),JBNSPR ;HIGH SEG ACCESS PRIVILEGES
JBYSUN::POINT 3,JBTSWP(J),17
JBYLKN::POINT 18,JBTSWP(J),35
SSUNT1::POINT 3,T1,17 ;SWAPPING UNIT FROM ADDRESS IN T1
SSUNT4::POINT 3,T4,17 ;ALSO FROM T4
SLKNT1::POINT 18,T1,35 ;SWAPPING ADDRESS ON UNIT FROM T1
JBYWCH::POINT 23,JBTWCH(J),35 ;BYTE POINTER TO TIME OF DAY STARTED WAITING
;END FT WATCH
JBYLCR::POINT 18,JBTCLM(J),17 ;CORE LIMIT POINTER
JBYLTM::POINT 36-^L<JB.LTM>,JBTLIM(J),35 ;TIME LIMIT POINTER
IFN FTNSCHED,<
JBYCLS::POINT 5,JBTSCD(J),17 ;POINTER TO CLASS FOR JOB.
JBYCL1::POINT 5,JBTSCD(T1),17 ;DITTO FOR IDX T1
JBYCL4::POINT 5,JBTSCD(T4),17 ;DITTO FOR IDX T4
>;END IFN FTNSCHED
PDVIAD::POINT 22,DEVIAD(F),35 ;POINTER FOR STORING EVA OF CURRENT INPUT BUFFER
PDVOAD::POINT 22,DEVOAD(F),35 ;POINTER FOR STORING EVA OF CURRENT
; OUTPUT BUFFER
JBYSSA::
JBYHSA::
JBYLSA::POINT 14,JBTAD2(J),35 ;POINTER TO PHYSICAL PAGE NO. OF FIRST PAGE
; OF THIS LOW SEGMENT
JBYMAP::POINT 21,JBTAD2(J),21 ;SWAPPED OUT LOCATION OF .UPMAP
JBYMT4::POINT 21,JBTAD2(T4),21 ;FOR VMSER
JBYVAD::POINT 21,JBTVAD(J),35 ;VIRTUAL ADDRESS OF HIGH SEG MAP
JBYOFF::POINT 9,JBTVAD(J),35 ;OFFSET IN PAGE ADDR OF START OF 2NDARY MAP
POFFLH==:<POINT 9,,35> ;BYTE POINTER FOR ABOVE
JBYHSO::POINT 9,JBTUPM(J),8 ;VIRTUAL PAGE NUMBER OF HIGH SEGMENT ORIGIN
; LAST TIME THE MAP WAS SET UP
LSTBAS::POINT 7,.PDACS+ACTSTL-1(W),34 ;LAST BYTE IN ACCOUNT STRING
JBYDEB::POINT 2,JBTST2(J),2 ;DEFERRED ECHO BITS
FRGAP3::POINT 21,(P3),35 ;DISK ADDR IN FRAGMENT TABLE (P3)
FRGUP3::POINT 3,(P3),17 ;DISK UNIT IN FRAGMENT TABLE (P3)
FRGCP3::POINT 9,(P3),14 ;FRAGMENT SIZE IN FRAGMENT TABLE (P3)
FRGAP1::POINT 21,(P1),35 ;SAMAE AS ABOVE CORRESPONDING FOR (P1)
FRGUP1::POINT 3,(P1),17
FRGCP1::POINT 9,(P1),14
FRGUT1::POINT 3,T1,17 ;BYTE POINTER FOR UNIT IN FRAG PTR IN T1
FRGUT2::POINT 3,T2,17
FRGCT4::POINT 9,T4,14 ;BYTE POINTER FOR COUNT IN FRAG PTR IN T4
$ABS
SUBTTL PI CHANNEL SAVE/RESTORE
;DEFINE PI CHANNEL SAVE AND RESTORE ROUTINES IF A DEVICE IS ON THE CHANNEL
PDL==201 ;LENGTH OF INTERRUPT PI PUSH DOWN LIST
DEFINE CHAN (PI)<
; XLIST
HIGHAC==17
HIACBL==17
CH'PI:: 0 ;PC STORED HERE BY JSR ON INTERRUPT TO CHANNEL PI
0
EXP IC.UOU
EXP .+1
XJEN CH'PI
DEFINE FSTCHN,<
ZZS==0
IFE <PI&7-SCNCHN>,<ZZS==2> ;USE EXEC AC BLOCK 2 ON SCANNER CHANNEL
IFE <PI&7-DSKCHN>,<ZZS==3> ;USE EXEC AC BLOCK 3 ON DSK CHANNEL
IFE <PI&7-NETCHN>,<ZZS==4> ;USE EXEC AC BLOCK 4 ON NETWORK
>
DEFINE INTL.(X)<INTL'X>
DEFINE INTL<INTL'PI>
DEFINE INTO.(X)<INTO'X>
DEFINE INTO<INTO'PI>
;CHAN DEFINITION CON'T ON NEXT PAGE
;CONTINUE CHAN DEFINITION
;HERE FROM AN INTERRUPT ROUTINE WHICH HAS FOUND ITS DEVICE NEEDS SERVICE
;SAVE ACS 0 THRU HIGHAC, CALLED BY JSR, SETS UP P TO PUSH DOWN LIST FOR THIS PI
FSTCHN ;ZZS NON-ZERO IF SCANNER OR DSK PI SAVE ROUTINE
SAV'PI::0 ;CALLED BY JSR
IFN M.KL10,<
DATAI PAG,SVPG'PI ;REMEMBER OLD AC BLOCK #
EXECAC (ZZS) ;SET EXEC AC BLOCK
; XLIST
>
IFN M.KS10,<
RDUBR SVPG'PI ;REMEMBER OLD AC BLOCK #
EXECAC (ZZS)
XLIST
>
IFE ZZS,<
MOVEM HIGHAC,SVAC'PI+HIGHAC ;SAVE AC HIGHAC
IFG RTTRPN,<
SKIPN HIGHAC,.CPRTT ;ALWAYS SAVE ACS IF RTTRP IS IN PROGRESS
>
MOVE HIGHAC,CH'PI ;GET INTERRUPT PC
TLNE HIGHAC,(XC.USR) ;WAS THE INTERRUPT OUT OF EXEC MODE
JRST SAV'PI'A ;NO, DON'T NEED TO SAVE AC'S
MOVEI HIGHAC,SVAC'PI ;SETUP TO SAVE 0 THRU HIGHAC-1
BLT HIGHAC,SVAC'PI+HIGHAC-1 ;SAVE ACS
>
SAV'PI'A:MOVE P,C'PI'PDP ;SETUP PUSH DOWN POINTER
MOVSI (IC.UOU) ;TURN ON USER IOT SO XCT PAGED WILL
HLLM SAV'PI ; REFERENCE USER RATHER THAN EXEC VIRTUAL MEMORY
IFN M.KL10,<
MOVE [LG.LPC!LG.LUB!LG.IAM]
XORM SVPG'PI
>
IFN FTMP,<
SKIPGE INTL ;DON'T TRY UNLESS ITS POSSIBLE TO GET IT
AOSE INTL ;WAIT FOR INTERLOCK
JRST .-2
APRID INTO
>
JRSTF @SAV'PI ;RETURN TO CALLER AND PROCESS INTERRUPT
;HERE FROM INTERRUPT ROUTINE WHEN IT HAS FINISHED SERVICING INTERRUPT
;RESTORE ACS AND DISMISS INTERRUPT
;USUALLY TRANSFERRED TO BY POPJ P,
$HIGH
RET'PI::
IFN FTMP,<
SETOM INTO ;NO LONGER OWN
SETOM INTL ;GIVE UP INTERLOCK
RET'PI'B:
> ;END IFN FTMP
IFE ZZS,<
IFN M.KL10,<
IFG RTTRPN,<
SKIPN HIGHAC,.CPRTT ;RESTORE SAVED ACS IF RTTRP IS IN PROGRESS
> ;END IFG RTTRPN
MOVE HIGHAC,CH'PI ;GET INTERRUPT PC
TLNE HIGHAC,(XC.USR) ;WAS THE INTERRUPT OUT OF USER MODE?
JRST CH'PI'XIT ;YES--AC'S WERE NOT SAVED
> ;END IFN M.KL10
> ;END IFE ZZS
IFE ZZS,<
MOVSI HIGHAC,SVAC'PI ;RESTORE ACS 0 THRU HIGHAC
BLT HIGHAC,HIGHAC
> ;END IFE ZZS
IFN M.KL10,<
CH'PI'XIT:
DATAO PAG,SVPG'PI ;RESTORE OLD AC BLOCK #
> ;END IFN M.KL10
IFN M.KS10,<
IFE ZZS,<
WRUBR SVPG'PI ;RESTORE OLD AC BLOCK #
> ;END IFE ZZS
IFN ZZS,<
MOVE 17,SVPG'PI ;CONTENTS OF THE UBR AT THE INTERRUPT
TLZ 17,(SG.LUB) ;ONLY RESTORE AC SETS
WRUBR 17 ;RESTORE ACS AT INTERRUPT TIME
> ;END IFN ZZS
> ;END IFN M.KS10
C'PI'JEN::
XJEN CH'PI
$ABS
;;CHANNEL SAVE ROUTINES FOR MULTI-CPU DEVICES
IFN PI&70,<
SAVB'PI::0 ;;CALLED BY JSR
IFN M.KL10,<
DATAI PAG,SVPG'PI ;;REMEMBER OLD AC BLOCK #
EXECAC (ZZS) ;;SET EXEC AC BLOCK
;; XLIST
>
IFN M.KS10,<
RDUBR SVPG'PI ;;REMEMBER OLD AC BLOCK #
EXECAC (ZZS)
XLIST
>
IFE ZZS,<
MOVEM HIGHAC,SVAC'PI+HIGHAC ;;SAVE AC HIGHAC
IFG RTTRPN,<
SKIPN HIGHAC,.CPRTT ;;ALWAYS SAVE ACS IF RTTRP IS IN PROGRESS
>
MOVE HIGHAC,CH'PI ;;GET INTERRUPT PC
TLNE HIGHAC,(XC.USR) ;;WAS THE INTERRUPT OUT OF EXEC MODE
JRST SVB'PI'A ;;NO, DON'T NEED TO SAVE AC'S
MOVEI HIGHAC,SVAC'PI ;;SETUP TO SAVE 0 THRU HIGHAC-1
BLT HIGHAC,SVAC'PI+HIGHAC-1 ;;SAVE ACS
>
SVB'PI'A:MOVE P,C'PI'PDP ;;SETUP PUSH DOWN POINTER
MOVSI (IC.UOU) ;;TURN ON USER IOT SO XCT PAGED WILL REFERENCE
HLLM SAVB'PI ;; USER RATHER THAN EXEC VIRTUAL MEMORY
IFN M.KL10,<
MOVE [LG.LPC!LG.LUB!LG.IAM]
XORM SVPG'PI
>
SKIPGE INTL.(\<PI&7>) ;;DON'T TRY UNLESS ITS POSSIBLE TO GET IT
AOSE INTL.(\<PI&7>) ;;WAIT FOR INTERLOCK
JRST .-2
APRID INTO.(\<PI&7>) ;;ADMIT TO OWNERSHIP
PUSH P,[EXP RETB'PI] ;;SAVE OUR (ALTERNATE) RESTORATION ROUTINE
JRSTF @SAVB'PI ;;RETURN TO CALLER AND PROCESS INTERRUPT
;;HERE FROM INTERRUPT ROUTINE WHEN IT HAS FINISHED SERVICING INTERRUPT
;;RESTORE ACS AND DISMISS INTERRUPT
;;TRANSFERRED TO BY POPJ P,
$HIGH
RETB'PI::
SETOM INTO.(\<PI&7>) ;;NO LONGER OWN
SETOM INTL.(\<PI&7>) ;;GIVE UP INTERLOCK
JRST RET'PI'B ;;JOIN COMMON RESTORATION CODE
$ABS
> ;;END OF IFN PI&70
IFG RTTRPN,<
IFN M.KL10,<
RTPOPN==30
> ;END IFN M.KL10
IFN M.KS10,<
RTPOPN==0
>
RTOFST==:CHD'PI-CHND'PI
CHND'PI:: MOVE P,C'PI'RTP
IFLE PI-APRCHN,<JSP J,DSMAPR>
IFG PI-APRCHN,<JSP J,DISMIS>
RTRT'PI:: MOVSI 17,SVAC'PI ;RESTORE ALL OF THE AC'S
BLT 17,17
IFN M.KL10,<
DATAO PAG,SVPG'PI ;RESTORE AC BLOCK
> ;END IFN M.KL10
IFN M.KS10,<
WRUBR SVPG'PI ;RESTORE AC BLOCK
>
XJEN CH'PI
C'PI'RTP: XWD -<PDL-RTPOPN>+1,C'PI'PD1+RTPOPN
RTSV'PI:: 0 ;COME HERE TO SAVE ALL AC'S
IFN M.KL10,<
DATAI PAG,SVPG'PI ;SAVE AC BLOCK
EXECAC ;SET EXEC AC BLOCK
> ;END IFN M.KL10
IFN M.KS10,<
RDUBR SVPG'PI ;SAVE AC BLOCK
EXECAC ;SET EXEC AC BLOCK
>
MOVEM 17,SVAC'PI+17 ;SAVE 17
MOVEI 17,SVAC'PI ;SET UP BLT POINTER
BLT 17,SVAC'PI+16 ;SAVE THE AC'S
MOVE P,C'PI'PDP ;SET UP P POINTER
MOVSI (IC.UOU) ;TURN ON USER IOT SO PAGED XCT
HLLM RTSV'PI ; WILL REFERENCE USER VIRTUAL
JRST 2,@RTSV'PI ;RETURN TO CALLER
CHD'PI:: EXP ENBSTD
Z ;STORAGE LOCATION FOR PROTECTION-RELOCATION VALUE.
Z ;STORAGE LOCATION FOR APR ENABLE BITS.
> ;IFG RTTRPN
SVPG'PI:: BLOCK 1
SVAC'PI:: BLOCK HIACBL+1 ;PLACE TO SAVE ACS 0 THRU HIGHAC
C'PI'PDP:: XWD -PDL+1,.+1 ;INITIAL PUSH DOWN POINTER
C'PI'PD1:: EXP RET'PI ;FIRST WORD ON LIST,
; POPJ WILL RETURN TO DISMISS INTERRUPT
BLOCK PDL-1 ;PUSHDOWN LIST SPACE
LIST
> ;END OF CHAN DEFINITION
;SET USED'N TO BE NON-ZERO FOR ALL CHANNELS
;THAT NEED CHANNEL SAVE ROUTINES
;THIS INCLUDES ALL CHANNELS WHICH RTTRP MAY USE
IFN FTRTTRP,<
DEFINE SETUSED(PI)
<CUSD'PI==:USED'PI
IFE USED'PI,<IFDEF UNIQ'PI,<IFE UNIQ'PI,<USED'PI=:-1>>
IFN M.TD10,<
IFE PI-DADCHN,<CUSD'PI==:1 ;DON'T ALLOW FAST BLOCK MODE ON DTA DATA CHN
>>
IFNDEF UNIQ'PI,<USED'PI=:-1>>
> ;DEFINE SETUSED
ZZ==-1
REPEAT M.CPU,<
ZZ==ZZ+2
REPEAT 6,<
SETUSED(\ZZ)
ZZ==ZZ+1
>>
> ;IFN FTRTTRP
IFG M.CPU-1,<LOC <.+PG.BDY>&777000>
CSHFIR==:.
;NULL JOB DUMP AC AREA:
DEFINE NULDAC(N)<
NU'N'DAC::BLOCK 20
XP NU'N'DAT,NU'N'DAC-20
>
ZZ==0
REPEAT M.CPU,<
NULDAC(\ZZ)
ZZ==ZZ+1
>
ERPDLL==143
ERRPLL==:-ERPDLL+1
DEFINE PDLDEF(N)<
ER'N'PDL::
BLOCK ERPDLL
>
ZZ==0
REPEAT M.CPU,<
PDLDEF (\ZZ)
ZZ==ZZ+1
>
MNULPD=:-205+1 ;LENGTH OF NULL PDL
DEFINE PDLDEF(N)<
NU'N'PDL::
MNU'N'PD==MNULPD
BLOCK -MNULPD+2
>
ZZ==0
REPEAT M.CPU,<
PDLDEF (\ZZ)
ZZ==ZZ+1
>
IFLE <M.CPU-1>,<NU1PDL==:NU0PDL>
;GENERATE THE CHANNEL SAVE ROUTINE ONLY FOR PI WHICH NEED THEM (ASGSAV MACRO USED)
;GENERATE NULL CHANNEL SAVE ROUTINES FOR THOSE CHANNELS NOT USED
DEFINE NULL (PI)<
SAV'PI==PIERR##
IFN PI&70,<SAVB'PI==PIERR##>
CH'PI:: 0
0
EXP 0
EXP .+1
XJEN CH'PI
>
DEFINE USED(PI)<
IFN USED'PI, <CHAN PI>
IFE USED'PI, <NULL PI>
>;END DEFINE USED
ZZ==0
REPEAT M.CPU,<
ZZ==ZZ+1
REPEAT 7,<
USED \ZZ
ZZ==ZZ+1
>
>
;NOW DEFINE DURING PASS 1 A FEW NECESSARY SYMBOLS
DEFINE DEFCHL(A,B),<
A'CHL==:CH'B
IFDEF C'B'PD1,<A'PD1==:C'B'PD1>
>
DEFINE CALCHL(A,B)<
DEFCHL (<A'B>,\A'B'CH1)
>;END DEFINE CALCHL
ZZ==0
REPEAT M.CPU,<
CALCHL(AP,\ZZ)
CALCHL(CK,\ZZ)
ZZ==ZZ+1
>;END REPEAT M.CPU
SUBTTL GENERATE COMMON INTERRUPT ROUTINES FOR ALL PROCESSORS
;MACRO TO MAKE THE INTERRUPT SKIP CHAIN ENTRY'S FOR THE NETSER
; SOFTWARE INTERRUPT. (ONE ENTRY PER CPU)
DEFINE GCNET(CPU,CHN),<
IFN M.ANF,<
NT'CPU'INT::SKIPN .CPNTF
JRST .-1
JSR SAV'CHN
PJRST NETINT##
>> ;END M.ANF AND DEFINE GCNET
;MACRO TO GENERATE CLOCK (CH7) INTERRUPT CHAIN
DEFINE GCCLK(CPU),<
CK'CPU'INT:SKIPN .CPCKF
JRST .-1
JRST CLKINT##
> ;END GCCLK MACRO
;NOW EXPAND ALL THE ABOVE MACROS FOR EACH CPU IN THE CONFIG.
$HIGH
ZZ==0
REPEAT M.CPU,<
GCNET(\ZZ,\<ZZ*10+NETCHN>)
GCCLK(\ZZ)
ZZ==ZZ+1
> ;END REPEAT M.CPU
$ABS
SUBTTL COMMAND TABLE
;THE NEW FORMAT OF THE COMMAND TABLES IS AS FOLLOWS:
;COMTAB - CONTAINS SIXBIT COMMAND NAME
;DISP - CONTAINS THE DISPATCH ADDRESS
;UNQTAB - CONTAINS THE DISPATCH BITS AS WELL AS THE UNIQUENESS BITS IN
; THE RIGHTMOST BITS. THE LEFT HALF OF THIS WORD ARE POST
; DISPATCH BITS, THE RIGHT HALF PREDISPATCH.
;CUSTOMER-DEFINED COMMAND NAME MACRO
;COMMAND NAME, PROGRAM TO RUN IF DISPATCH ADDRESS NOT SPECIFIED, DISPATCH
; ADDRESS, DISPATCH FLAGS, UNIQUENESS BITS, PRVTAB NAME
DEFINE UCMDNM(NM,PR,AD,FL,UN,PV),<
IFNB <NM>,<
IFNB <AD>,<C <NM>,AD,FL,UN>
IFB <AD>,<
IFB <PR>,<C <NM>,RUNAME,FL,UN>
IFNB <PR>,<
IFIDN <NM>,<PR>,<C <NM>,RUNAME,FL,UN>
IFDIF <NM>,<PR>,<C <NM>,%'PR,FL,UN>
>
>
>
>
;MONITOR COMMANDS
DEFINE NAMES,<
C <>,CBLANK,<<NOFLM!NOINCK!NOCRLF>_^D18>!NOCORE!NOJOBN!NOLOGIN!NORCMP
C START,START,<<NOPER!TTYRNU>_^D18>!INCORE!NOACT!NORUN!NOLOGIN!NOJOBN,UNIQ.2
C .HALT,STOPF,<<NOINCK!CMWRQ>_^D18>!NOCORE!NOJOBN!NOLOGIN!NORCMP
C HALT,STOP,<<NOINCK!CMWRQ>_^D18>!NOCORE!NOJOBN!NOLOGIN!NORCMP,,HALTXT
C KJOB,KJOB,<<NOINCK!NOCRLP!NOMESS>_^D18>!NOCORE!NOJOBN!NOLOGIN!NOACT!INCORE!NORUN!NORCMP
C R,RCOM,<<NOPER!TTYRNU>_^D18>!NOCORE!NOACT!NORUN!INCORE
C RUN,RUNCOM,<<NOPER!TTYRNU>_^D18>!NOCORE!NOACT!NORUN!INCORE,UNIQ.2
C CORE,CORE,<<CMWRQ>_^D18>!NOCORE!INCORE!NOACT
C GET,GET,RUNFLG,UNIQ.1!UNIQ.2
C SAVE,CSAVE,<<NOCRLP!TTYRNU>_^D18>!INCORE!NOACT!NORUN!NXONLY
C SSAVE,SSAVE,<<NOCRLP!TTYRNU>_^D18>!INCORE!NOACT!NORUN!NXONLY
C MERGE,CMERGE,<<NOCRLP!TTYRNU>_^D18>!INCORE!NOACT!NORUN!NXONLY
C CONTINUE,CONT,<<NOINCK!NOPER!TTYRNW>_^D18>!INCORE!NORUN!NOJOBN!NOLOGIN,UNIQ.1!UNIQ.3!UNIQ.4,CONTXT
C JCONTINUE,JCONT,<<NOINCK>_^D18>!NOCORE!NOJOBN!NOLOGIN
C .FCONT,FCONT,<<NOINCK!NOCRLP!CMWRQ!NOMESS>_^D18>!NORUN!INCORE!NOJOBN!NOLOGIN!NORCMP,,FCOTXT
C DEPOSIT,DCOM,<<CMWRQ>_^D18>!INCORE!NXONLY,UNIQ.1
C EXAMINE,ECOM,<<NOFLM!CMWRQ>_^D18>!INCORE!NXONLY,UNIQ.1
C PJOB,PJOBX,<<NOINCK>_^D18>!NOCORE!NOJOBN!NOLOGIN
C .HELLO,HELLO,RUNFLG!NOLOGIN!NORCMP
C .BYE,BYECOM,<<NOINCK>_^D18>!NOCORE!NOLOGIN!NOJOBN!NORCMP
C DEASSI,DEASSIG,<<NOINCK!CMWRQ>_^D18>!NOCORE!INCORE,UNIQ.3
C ASSIGN,ASSIGN,<<CMWRQ>_^D18>!NOCORE!INCORE
C DDT,DDTGO,<<NOPER!TTYRNU>_^D18>!INCORE!NORUN!NOLOGIN!NOJOBN
C .BPT,CDBPT,<<NOINCK!CMWRQ!NOMESS!NOCRLP>_^D18>!INCORE!NOCORE!NOJOBN!NOLOGI!NORCMP
C FINISH,CFINI,<<NOCRLP!TTYRNU>_^D18>!NOACT!INCORE!NORUN
C CLOSE,CLSCOM,<<NOCRLP!TTYRNU>_^D18>!NOACT!INCORE!NORUN
C REENTER,REENTER,<<NOPER!TTYRNU>_^D18>!INCORE!NORUN!NOLOGIN!NOJOBN
C CSTART,STARTC,<<TTYRNC>_^D18>!INCORE!NOACT!NORUN!NBATCH
C CCONTINUE,CONTC,<<TTYRNC>_^D18>!INCORE!NORUN!NBATCH
C DETACH,DETACH,<<NOINCK>_^D18>!NOCORE!NBATCH!NOLOGIN
C ATTACH,ATTACH,<<NOINCK>_^D18>!NOCORE!INCORE!NOLOGIN!NBATCH!NORCMP
C XCHNGE,XCHDSK,<<NOINCK>_^D18>!NOCORE!NOJOBN!NOLOGIN!NBATCH
C ENABLE,ENABLE,NOCORE
C DISABL,DISABL,NOCORE
C DAYTIME,DAYTIM,<<NOINCK>_^D18>!NOCORE!NOJOBN!NOLOGIN!NORCMP
C .RESTA,RESTRT,<<NOINCK>_^D18>!NOCORE!NOJOBN!NOLOGIN!NORCMP
C TIME,RUNTIM,<<NOINCK>_^D18>!NOCORE!NOLOGIN!NOJOBN
C RESOURCES,FREDEV,<<NOINCK>_^D18>!NOCORE!NOJOBN!NOLOGIN
C USESTAT,USECOM,<<NOINCK!NOPER!NOMESS>_^D18>!NOCORE!NOJOBN!NOLOGIN!NORCMP
C VERSION,VERCOM,<<CMWRQ>_^D18>!INCORE,,VERTXT
C DSK,DSKCOM,<<NOINCK>_^D18>!NOCORE
C MOUNT,MNTCOM,RUNFLG,UNIQ.2
C DISMOUNT,MNTCOM,RUNFLG,UNIQ.3!UNIQ.4
IFN FTMDA,<
C ALLOCA,RUNMDA,RUNFLG
C DEALLO,RUNMDA,RUNFLG
C SHOW,RUNMDA,RUNFLG
C CANCEL,RUNMDA,RUNFLG
>
C QUEUE,RUNQUE,RUNFLG!NOLOGIN,,QUEUE
C CPUNCH,RUNQUE,RUNFLG!NOLOGIN
C PLOT,RUNQUE,RUNFLG!NOLOGIN
C PRINT,RUNQUE,RUNFLG!NOLOGIN
C PUNCH,RUNQUE,RUNFLG!NOLOGIN
C SUBMIT,RUNQUE,RUNFLG!NOLOGIN
C TPUNCH,RUNQUE,RUNFLG!NOLOGIN
C SEND,SEND,<<NOINCK>_^D18>!NOCORE!NOLOGIN!NBATCH
C .TYPE,RETYPE,<<NOINCK!NOCRLP!NOMESS>_^D18>!NOCORE!NOJOBN!NOLOGIN!NORCMP
IFN FTMIC,<
C COJOB,RUNMIC,RUNFLG
C WHENEVER,RUNMIC,RUNFLG
C ON,RUNMIC,RUNFLG
C LET,RUNMIC,RUNFLG
C IF,RUNMIC,RUNFLG
C GOTO,RUNMIC,RUNFLG
C BACKTO,RUNMIC,RUNFLG
C OPERATOR,RUNMIC,RUNFLG
C NOOPERATOR,RUNMIC,RUNFLG
C ERROR,RUNMIC,RUNFLG
C NOERROR,RUNMIC,RUNFLG
C SILENCE,RUNMIC,RUNFLG
C PLEASE,RUNPLS,RUNFLG
C REVIVE,RUNMIC,RUNFLG
C MIC,RUNMIC,RUNFLG
C DO,RUNMIC,RUNFLG
C <@>,RUNMIC,RUNFLG
>;END OF FTMIC STUFF
C SCHEDULE,SKEDUL,<<NOINCK>_^D18>!NOCORE!NOJOBN!NOLOGIN!NORCMP
C LOGIN,CLOGIN,RUNFLG!NOLOGIN!NORCMP,,LOGTXT
C PASSWORD,RUNLGN,RUNFLG
C REATTA,RUNLGN,<<SACFLG>_^D18>!RUNFLG
C REASSI,REASS,<<CMWRQ>_^D18>!NOCORE!NOACT!INCORE!NORUN
C SET,SET,<<NOINCK>_^D18>!NOCORE!NOJOBN!NOLOGIN!NORCMP
C TTY,TTYCMD,<<NOINCK>_^D18>!NOCORE!NOLOGIN!NOJOBN!NORCMP
C TERMINAL,TTYCMD,<<NOINCK>_^D18>!NOCORE!NOLOGIN!NOJOBN!NORCMP
IFN FTNET,<
C .NETLD,RUNNET,RUNFLG!NOLOGIN!NORCMP
C NETWORK,RUNAME,RUNFLG!NOLOGIN!NORCMP
C NODE,CNODE,<<NOCRLP!CMWRQ>_^D18>!INCORE!NOCORE!NOLOGIN!NORCMP,UNIQ.2
> ;END FTNET
C LOCATE,CLOCATE,NOCORE!INCORE
C WHERE,CWHERE,<<CMWRQ>_^D18>!INCORE!NOCORE!NOLOGIN
C INITIA,RUNAME,RUNFLG!NOLOGIN!NORCMP,UNIQ.1!UNIQ.2!UNIQ.3!UNIQ.4,INITIA
C DIRECT,RUNAME,RUNFLG,UNIQ.2!UNIQ.3!UNIQ.4
C HELP,RUNAME,<<NOCRLP!TTYRNU!SACFLG>_^D18>!NOCORE!NOLOGIN!NOACT!NORUN!INCORE!NORCMP
C SYSTAT,RUNAME,RUNFLG!NOLOGIN
C FILE,RECALL,RUNFLG
IFE FTMIC,<
C PLEASE,RUNAME,<<NOCRLP!TTYRNU>_^D18>!NOCORE!INCORE!NOACT!NORUN!NBATCH
>
C FUDGE,RUNPIC,RUNFLG
C CREF,RUNAMC,RUNFLG
C SOS,RUNAME,RUNFLG
C ACCOUNT,CACCT,NOCORE
C SESSION,RUNLGN,RUNFLG
C DECLARE,RUNAME,RUNFLG
C MAIL,RUNMAI,RUNFLG
C .RUN,RUNAME,RUNFLG!NOLOGIN,,.RNTXT
C CONTEXT,CTXCMD,<<NOCRLP!NOINCK>_^D18>!NOCORE!INCORE,UNIQ.2
C PUSH,PSHCMD,<<NOCRLP!NOMESS>_^D18>!NOCORE!NORUN!INCORE
C POP,POPCMD,<<NOCRLP!NOMESS>_^D18>!NORUN!INCORE
IFN FTPATT,<
C .PATCH,CPOPJ,<<NOINCK>_^D18>!NOCORE!NOJOBN!NOLOGIN!NORCMP
>
C .PLRUN,PLNCOM,RUNFLG,,PLNTXT
;COMPIL-CLASS COMMANDS
C COMPILE,CCLRUN,RUNFLG,,COMPIL
C DEBUG,CCLRUN,RUNFLG
C EXECUTE,CCLRUN,RUNFLG,UNIQ.2
C LOAD,CCLRUN,RUNFLG
C CREATE,CCLRUN,RUNFLG
C DELETE,CCLRUN,RUNFLG
C EDIT,CCLRUN,RUNFLG
C LIST,CCLRUN,RUNFLG
C MAKE,CCLRUN,RUNFLG,UNIQ.2
C RENAME,CCLRUN,RUNFLG
C TECO,CCLRUN,RUNFLG,UNIQ.2!UNIQ.3
C TYPE,CCLRUN,RUNFLG,UNIQ.2
C COPY,CCLRUN,RUNFLG
C PRESERVE,CCLRUN,RUNFLG
C REWIND,CCLRUN,RUNFLG
C UNLOAD,CCLRUN,RUNFLG
C ZERO,CCLRUN,RUNFLG
C SKIP,CCLRUN,RUNFLG
C BACKSPACE,CCLRUN,RUNFLG,UNIQ.2!UNIQ.3!UNIQ.4
C EOF,CCLRUN,RUNFLG
C PROTECT,CCLRUN,RUNFLG
C LABEL,CCLRUN,RUNFLG
C CTEST,CCLRUN,RUNFLG ;ALWAYS LAST CCLRUN
>; END NAMES MACRO
;SET COMMANDS
DEFINE SNAMES,<
C WATCH,SETWAT,NOCORE
C TIME,SETRTM,NOCORE
C SPOOL,SETSPL,NOCORE
C CDR,SETCDR,NOCORE
C SCHEDULE,SETSCD,<<NOINCK>_^D18>!NOCORE!NOJOBN!NOLOGIN
C CORMAX,SETMAX,<<NOINCK>_^D18>!NOCORE!NOJOBN!NOLOGIN
IFN FTLOCK,<
C CORMIN,SETMIN,<<NOINCK>_^D18>!NOCORE!NOJOBN!NOLOGIN
>
C DAYTIM,SETDAY,<<NOINCK>_^D18>!NOCORE!NOJOBN!NOLOGIN
C DATE,SETDAT,<<NOINCK>_^D18>!NOCORE!NOJOBN!NOLOGIN
C OPR,SETOPR,<<NOINCK>_^D18>!NOCORE!NOJOBN!NOLOGIN
C TTY,TTYCMD,<<NOINCK>_^D18>!NOCORE!NOJOBN!NOLOGIN!NORCMP
C TERMINAL,TTYCMD,<<NOINCK>_^D18>!NOCORE!NOJOBN!NOLOGIN!NORCMP
IFN FTHPQ,<
C HPQ,HPQCMD,NOCORE
>
C DENSITY,MTADEN,<<CMWRQ>_^D18>!NOCORE!INCORE!NOACT
C BLOCKSIZE,MTABLK,<<CMWRQ>_^D18>!NOCORE!INCORE!NOACT
C FORMAT,MTAMOD,<<CMWRQ>_^D18>!NOCORE!INCORE!NOACT
C RETRY,MTARTY,<<CMWRQ>_^D18>!NOCORE!INCORE!NOACT
IFN FTMP,<
C CPU,CPUCMD,NOCORE
>
C NOMESS,DSKSIL,<<NOINCK>_^D18>!NOCORE!NOJOBN!NOLOGIN
C DSKPRI,DSKPRI,NOCORE
C DSKFUL,FULSTP,NOCORE
C BREAK,SETBRK,NOCORE
C VMMAX,SETVMX,<<NOINCK>_^D18>!NOCORE!NOJOBN!NOLOGIN
C VIRTUAL,SETUVC,NOCORE
C PHYSICAL,SETUPC,NOCORE
IFN FTNET!FTDECNET,<
C HOSTESS,DAASTH,RUNFLG!NOLOGIN!NORCMP
>
C MEMORY,SETMEM,<<CMWRQ>_^D18>!NOCORE!NOLOGIN!INCORE
C DEFER,SETDFC,NOCORE
C NODEFER,SETNDC,NOCORE
C DEFAULT,SETDFL,NOCORE!NOLOGIN
C FLOATING,SETFPC,NOCORE
C DDT,SETBPT,NOCORE
C EDDT,SETEBP,NOCORE!NOLOGIN!NOJOBN!NBATCH
IFN FTPATT,<
C CTEST,CPOPJ,<<NOINCK>_^D18>!NOCORE!NOJOBN!NOLOGIN ;ALWAYS LAST
>
>; END SNAMES MACRO
;CUSTOMER DEFINED COMMANDS
DEFINE CNAMES,<
SPCCMD ;;EXPAND CUSTOMER DEFINED COMMANDS
>; END CNAMES MACRO
;GENERATE TABLE OF SIXBIT COMMAND NAMES
DEFINE C(A,B,D,E,F)<
IFNB<F>,<F::>
IFDIF <A><>,<IFDIF <A><>,<
<SIXBIT A>
>>
IFIDN <A><>,<BYTE(6)34,0>
IFIDN <A><>,<BYTE(6)36,0>
>
XALL
COMTB2::SNAMES
DISPL2==:.-COMTB2 ;LENGTH
COMMX2==:<DISPL2-1>B26
CSTTAB::CNAMES ;CUSTOMER DEFINED NAMES
DISPLC==:.-CSTTAB ;LENGTH OF TABLE
COMMXC==:<DISPLC-1>B26
COMTAB::NAMES
LASCCL==:.
DISPL==:.-COMTAB ;LENGTH OF TABLE
COMMXL==:<DISPL-1>B26
$HIGH
;GENERATE THE DISPATCH TABLE PLUS SPECIAL BITS
DEFINE C(A,B,D,E,F) <
IF2,<IFNDEF B,<EXTERN B>>
EXP B ;A
>
DISP2:: SNAMES
DISPC:: CNAMES ;CUSTOMER TABLE
DEFINE C(A,B,D,E,F) <
IF2,<IFNDEF B,<EXTERN B>>
IFG .-DISP-COMPIL+COMTAB,<
IFDIF <B><CCLRUN>,<PRINTX ? B DOES NOT PRECEDE CCLRUN IN COMTAB>>
IFLE .-DISP-COMPIL+COMTAB,<
EXP B ;A
>>
DISP:: NAMES
;AND ONE MORE FOR AN UNKNOWN COMMAND DISPATCH
COMERD::EXP NOCOM##
;GENERATE TABLE OF UNIQUENESS BITS FOR SIXBIT COMMAND NAMES
DEFINE C(A,B,D,E,F)<
EXP D!E ;A
>
UNQTAB::NAMES
EXP NOCORE+NOJOBN+NOLOGIN+NOINCK ;UNKNOWN COMMAND DISPATCH
UNQTB2::SNAMES
UNQTBC::CNAMES
;GENERATE COMMAND DISPATCHES FOR USER DEFINED COMMANDS
DEFINE UCMDNM(NM,PR,AD,FL,UN,PV),<
IFNB <NM>,<
IFB <AD>,<
IFNB <PR>,<
IFDIF <NM>,<PR>,<
IFNDEF %'PR,< %'PR: >
IFE %'PR-.,<
%'PR: MOVE P2,[SIXBIT/PR/]
JRST RUNAME##
>
>
>
>
>
>
SPCCMD
SALL
;TABLE OF PRIVILEGED CUSPS
;USED TO TURN ON JACCT WHEN R OR RUN COMMAND OR RUN UUO
PRVTAB::
LGONAM::SIXBIT /LOGOUT/ ;NAME FOR "LOGOUT" (TURN OFF JLOG TOO)
LGINAM::SIXBIT /LOGIN/ ;NAME FOR "LOGIN" (ALSO LOGS OUT JOBS)
SIXBIT /UMOUNT/
SIXBIT /DAEMON/
SIXBIT /SYSTAT/ ;FOR PEEK UUO PRIVILEGE
IFN FTNET,<
SIXBIT /NETLDR/
IFN FTKS10,<
SIXBIT /KDPLDR/ ;KMC-11 MICRO-CODE LOADER TO RUN ON FRCLIN
>
>; END IFN FTNET
IFN M.DN60,< ;IF WE HAVE A DN60...
SIXBIT /D60RTV/ ; RETRIEVAL PGM MUST HAVE FULL FILE ACCESS
>
CCPNAM::EXP M.CRSH ;AUTO CRASH COPY PROGRAM. (MAY BE CHANGED
;WITH MONGEN BY DEFINING THE SYMBOL M.CRSH IN
;THE SIXBIT DEFINITION SECTION TO BE THE NAME
;OF THE PROGRAM TO RUN)
IFN M.ENET&M.KL10,<
SIXBIT/KNILDR/ ;KLNI MICROCODE LOADER
>
DEFINE UCMDNM(NM,PR,AD,FL,UN,PV),<
IFNB <PV>,<EXP SIXBIT/PV/>
>
SPCCMD ;GENERATE PRVTAB ENTRIES FOR CUSTOMER
; DEFINED COMMANDS
IFN FTPATT,<0> ;SAVE A WORD FOR PATCHING OVER
PRVTBL==:.-PRVTAB ;NO. OF PRIVILEGED CUSPS
DAASTH::
IFE M.RMCR!M.DECN,< ;IF NO NETWORK SUPPORT
JSP T1,ERRMES## ;CAN'T DO THESE IF NO NETWORK
ASCIZ |No network software|
> ;END IFN M.RMCR!M.DECN
IFN M.RMCR!M.DECN,< ;IF NETWORKS
PUSHJ P,SAVE4 ;SAVE P1-P4
PUSHJ P,CTEXT1## ;GET NEXT ARGUMENT
JUMPE T2,NOTENF## ;IF NO ARGUMENT
MOVE T1,T2 ;T1=NAME
PUSHJ P,CVTOCT## ;CONVERT IF NUMBER
JFCL ;MUST BE A NUMBER
IFN M.RMCR,<IFN M.DECN,<
NETOFF ;INTERLOCK
IFE M.RVTM,< ;IF NO LOCAL ANF SET HOST
SKIPL LDBTTW##(U) ;IF THIS ISN'T AN ANF LINE,
JRST HOST.D ;DON'T BOTHER ANF WITH IT
>
PUSHJ P,SRCND0## ;SEARCH ANF TABLE
PJRST HOST.D ;IF NOT FOUND
NETON ;FREE INTERLOCK
>;END IFN M.DECN
PJRST HOST.A## ;ANF HOST
>;END IFN M.RMCR
IFN M.DECN,<
HOST.D:IFN M.RMCR,<NETON>
HOSTD0:
IFN FTXMON,<
SNCALL (SCTN2A##,MS.HGH) ;CONVERT NODE NAME TO NODE ADDRESS
>
IFE FTXMON,<
DNCALL SCTN2A## ;CONVERT NODE NAME TO NODE ADDRESS
>
JRST [MOVEI T1,[ASCIZ /Undefined Network Node/]
PJRST ERRMES##] ;GIVE USER AN ERROR
MOVSI T1,LTLNRT## ;LETS SEE IF WE ARE ALREADY NRTED IN
SE1XCT <TDNE T1,LDBTTW##(U)> ;AND DON'T ALLOW IT IF SO
JRST [MOVEI T1,[ ;NRTED IN, DON'T LET HIM NRT OUT
ASCIZ \Cannot SET HOST to a DECnet node from a NRT line\]
PJRST ERRMES##] ;&&ADD CODE HERE TO DISCONNECT LINE&&
PUSHJ P,FNDPDS## ;RESTORE W
MOVE P2,[SIXBIT /CTHNRT/] ;PROGRAM NAME
MOVE T1,JBTSTS(J) ;JOB STATUS WORD
TLNN T1,JLOG ;LOGGED IN
SKIPE STHFLG ; OR NOT REQUIRED
PJRST RUNAME## ;RUN NRT PROGRAM
MOVEI T1,LOGPLM## ;ELSE TYPE
PJRST ERRMES## ; "LOGIN PLEASE"
>
>
$ABS
IFN FTKL10,<IFG M.CPU-1,<
LOC <.+PG.BDY>&777000
>
CSHLAS==:.-1 ;CACHE FROM CSHFIR TO HERE
>
SUBTTL COMMON -- CODE IN COMMON TO BUILD FEK'S
FEKFST==:0 ;START CHAIN OF FEKS BY ASSUMING
; THAT NO FEK'S WILL BE DEFINED
DEFINE FEKGEN(NAM,NM,TYPE,CPU,UNIT),< ;;MACRO TO LAY OUT FEK BLOCKS
;;ARGUMENTS ARE:
;; NAM 3 CHARACTER GENERIC FEK TYPE (IE D8S)
;; NM 3 CHARACTER "PARTICULAR" NAME FOR THIS FEK (IE "S01")
;; TYPE LEGAL NAME OF FEK (IE. NULL, KMCDUP DTE20 ...)
;; CPU NUMBER OF THE CPU THAT THIS FEK IS ON
;; UNIT UNIT NUMBER OF THIS FEK
;;FIRST VERIFY THAT THE FEK IS ONE OF A VALID TYPE
IFDIF <TYPE>,<NULL>,<
IFDIF <TYPE>,<DL10>,<
IFDIF <TYPE>,<DTE20>,<
IFDIF <TYPE>,<KMCDUP>,<
IFDIF <TYPE>,<DMR11>,<
IFDIF <TYPE>,<ENET>,<
PRINTX ? Illegal third argument TYPE to FEKGEN macro.?
>;DMR11
>;DMR11
>;KMCDUP
>;DTE20
>;DL10
>;NULL
DEFINE X(OFFSET,EXPR)< ;;MACRO TO SET SELECTED LOCATIONS IN THE BLOCK
LOC NM'FEK+OFFSET ;;GO TO THE RIGHT WORD
EXPR ;;ASSEMBLE IN THE EXPRESSION
>
IFNDEF NAM'DSP,<EXTERNAL NAM'DSP> ;;RESOLVE DISPATCH VECTOR ADDRESS
ND NM'CST,NAM'CST ;;COST MAY BE MONGEN'ED
Q==0 ;;DEFINE DEFAULT FEKBLK BITS
IFIDN <TYPE>,<NULL>,<
Q==<FK.NUL!FK.ONL!FK.NID> ;;STATUS BITS FOR NULL FEK
>;NULL
NM'FEK::BLOCK 0 ;;RESERVE STORAGE FOR THIS FEK
X FEKBLK,<XWD Q,FEKFST> ;;STATUS BITS AND LINK TO LAST FEK
X FEKDSP,<PUSHJ P,NAM'DSP>;;ONCE-ONLY CODE
X FEKUNI,<XWD CPU,UNIT> ;;XWD CPU,UNIT
X FEKCST,<XWD NM'CST,0> ;;SET COST FOR THIS FEK
X FEKHTM,<EXP 0> ;;INITIALIZE WITH HUNG TIME OF ZERO
X FEKIAD,<EXP 0> ;;NO INPUT BUFFERS (ADDRESS)
X FEKIDN,<EXP 0> ;;NO INPUT BUFFERS FILLED
X FEKBSI,<EXP -1> ;;INPUT IS IDLE
X FEKOAD,<EXP 0> ;;NO OUTPUT BUFFERS (ADDRESS)
X FEKOCT,<EXP 0> ;;NO OUTPUT BUFFERS (COUNT)
X FEKODN,<EXP 0> ;;NO EMPTY OUTPUT BUFFERS EITHER
X FEKBSO,<EXP -1> ;;OUTPUT IS IDLE
IFIDN <TYPE>,<DL10>,< ;;IF THIS IS A DL10
X FEKDLX,<CONC(DL'CPU,\<UNIT>,BS)> ;;BACK POINTER
> ;END IFIDN <TYPE><DL10>
IFIDN <TYPE>,<DTE20>,< ;;IF THIS IS A DTE 20
X FEKIBP,<EXP 0> ;;WE HAVE NO INPUT BYTE POINTER
X FEKAKC,<EXP 0> ;;THE "ACK" INTERLOCK IS FREE
X FEKDLX,<EXP D'NM'BS> ;;RUDE HACK TO GET BACK POINTER
X FEKETD,<CONC(ETD'CPU,\<UNIT+1>,B##)> ;;ETD ADDRESS
> ;END IFIDN <TYPE><DL10>
IFIDN <TYPE>,<ENET>,<
X FEKNIA,<EXP 0,0> ;;REMOTE ETHERNET ADDRESS
X FEKNIC,<EXP 0> ;;ETHERNET "CHANNEL" ID
X FEKNID,<EXP 0> ;;ETHERNET "PORTAL" ID
X FEKNIF,<EXP 0> ;;ETHERNET MASTER FEK ADDRESS
X FEKNIQ,<EXP 0> ;;ETHERNET INPUT PCBS QUEUED COUNT
X FEKNIS,<EXP 0> ;;ETHERNET NODEID SERIAL NUMBER
X FEKNIT,<EXP 0> ;;ETHERNET TIMERS
> ;END IFIDN <TYPE><ENET>
LOC NM'FEK+FEKLEN ;;GO TO THE END OF THE BLOCK
FEKFST==:NM'FEK ;;REDEFINE THE "FIRST" FEK TO KEEP CHAIN ALIVE
PURGE X ;;UNDEFINE THE "X" MACRO
>;FEKGEN
SUBTTL DN87 (ANF-10) AND DN60 (IBM) FEKS
$ABS
;NOW DEFINE 4 HELPER MACROS. ONE EACH FOR DN87(85), DC76, DN60 AND DN6S
;NOTE -- THESE FEKS MAY ONLY GO ON CPU #0.
DEFINE FEK85(P),< ;;MACRO TO BUILD DN85 FEKS
IRP P,< ;;FOR EACH ARGUMENT,
IFE <TP.DL'P-TP.D85>,< ;; IF THE -11 IS A DN85 (DN87),
ND D85CST,^D5 ;; DEFAULT COST
FEKGEN (D85,D8'P,DL10,0,0);; THEN BUILD THE FEK, AND
EXTERN D85INT>>> ;; MAKE SURE THE SERVICE ROUTINE IS LOADED
DEFINE FEK76(P),< ;;MACRO TO BUILD DC76 FEKS
IRP P,< ;;FOR EACH ARGUMENT,
IFE <TP.DL'P-TP.D76>,< ;; IF THIS -11 IS SUPPOSED TO BE A DC76
ND D76CST,^D5 ;; DEFAULT COST
FEKGEN (D76,D8'P,DL10,0,0);; THEN BUILD THE FEK, AND
EXTERN D76INT>>> ;; MAKE SURE THE SERVICE ROUTINE IS LOADED
DEFINE FEK60(P),< ;;MACRO FOR DN60 FEKS (DL-10 BASED IBM COMM)
IRP P,< ;;FOR EACH POSSIBLE -11,
IFE <TP.DL'P-TP.D60>,< ;;IF THIS -11 IS TO BE A DN60,
ND D60CST,^D5 ;; DEFAULT COST
FEKGEN (D60,D8'P,DL10,0,0);; THEN BUILD IT'S FEK, AND
EXTERN D60SER,D6DINT>>> ;; MAKE SURE THE SERVICE ROUTINES ARE IN
;NOW ACTUALLY BUILD THE FEKS.
FEK85 <0,1,2,3,4,5,6,7> ;;LEGAL FRONT ENDS FOR DN87(85) FEKS
FEK76 <0,1,2,3,4,5,6,7> ;;LEGAL FRONT ENDS FOR DC76 FEKS
FEK60 <0,1,2,3,4,5,6,7> ;;LEGAL FRONT ENDS FOR DN60 FEKS
IFN FTKL10,<
;NOW BUILD THE DN87S AND DN60S FEKS (DTE-20 BASED ANF AND IBM FRONT ENDS)
;NOTE -- THESE FEKS MAY BE ON ANY CPU.
IFN M.DN8S,<EXTERN D8SINT,D8SDSP> ;LOAD D8SINT
IFN M.DN6S,<EXTERN D6SINT,D6SDSP,D60SER> ;LOAD IBMCOMM
;;IFN M.DDCN,<EXTERN MCBINT,MCBDSP> ;;THERE SHOULD HAVE BEEN ONE OF THESE
DEFINE FEKDTE(CPX,DTX),< ;;MACRO TO BUILD DTE-BASED FEKS
ND DFKCST,^D7 ;;DEFAULT COST
FEKGEN(DFK,S'CPX'DTX,DTE20,CPX,DTX) ;;BUILD THE FEK
>
;NOW FOR ALL CPUS, FOR ALL DTES, BUILD THEIR FEKS
ZZ==0
REPEAT M.CPU,<Z=0 ;;FOR ALL CPUS,
REPEAT 4,< ;; FOR EACH DTE ON THIS CPU
FEKDTE(\ZZ,\Z) ;; BUILD A FEK FOR THE -11
Z==Z+1> ;;STEP TO THE NEXT DTE
ZZ=ZZ+1> ;; AND STEP TO THE NEXT CPU
> ;IFN FTKL10
;Define the DMR11 FEKs
;Put them so they will be after the KDPs for FEK2LN
IFN M.DMRN,<
EXTERN D8RINT,DMRINT,DMRSER ;; LOAD THE SERVICE ROUTINES
IFN M.DN6R,<
EXTERN D6RINT> ;; LOAD SERVICE ROUTINE FOR IBM
DEFINE FEK8R(N),<
ND D8RCST,^D8 ;;DEFAULT COST
FEKGEN(D8R,DR'N,DMR11,0,DMR'N)>
ZZ==0
REPEAT M.DMRN,<
FEK8R(\ZZ)
ZZ==ZZ+1>
>;IFN M.DMRN
;DEFINE THE KMC/DUP-11 FEK'S
;FOR NOW, THE NAMES ARE JUST DK<NNM>FEK
IFN M.KDUP,< ;;IF THERE ARE KMC/DUP-11 FEK'S
DEFINE FEK8K(N),< ;;DEFINE A HELPER MACRO TO DEFINE FEK'S
ND D8KCST,^D10 ;; DEFAULT COST
FEKGEN(D8K,DK'N,KMCDUP,0,KDL'N'PG) ;; BUILD THE D8K FEK
EXTERNAL D8KINT,KDPINT,KDPSER> ;; AND FORCE LOADING
ZZ==0 ;;COUNTER FOR FEK NUMBER
REPEAT M.KDUP,< ;;FOR ALL KMCDUP FEK'S
FEK8K(\ZZ) ;; BUILD THE FEK
ZZ==ZZ+1> ;; AND STEP TO THE NEXT
>;M.KDUP
;NOW THE ETHERNET PROTOTYPE (AND ETH-0 MASTER) FEK
IFG M.ENET,< ;AND IT IS LOADED
ND ANFNIP,NCLNIP ;DEFAULT TO BE EXCLUDED
ND ANFNIM,<<ANFNIP>B15> ;DEFAULT LOW ORDER MULTICAST ADDRESS
IFN ANFNIP!ANFNIM,< ;AND USER HAS DEFINED ANF NI SERVICE
IFN M.ANF,<
ND D8ECST,^D2 ;DEFAULT COST
FEKGEN(D8E,ET0,ENET,-1,0) ;THEN BUILD A PROTOTYPE ETHERNET FEK
EXTERN D8EINT ;AND LOAD ANF'S ETHERNET FEK SERVICE
> ;IFN M.ANF
> ;IFDEF ANFNIP
> ;IFG M.ENET
;BUILD THE "NULL" FEK.
IFN M.ANF,<
ND NLFCST,^D1 ;;DEFAULT COST
FEKGEN(NLF,NL0,NULL,-1,0) ;;GENERATE THE NULL FEK'S FEK
EXTERN NULFEK ;; AND LOAD THE SERVICE ROUTINE
>;M.ANF
$HIGH
IFN FTKL10,<
;GENERATE TABLE TO MAP FROM DTE AND CPU # TO FEK ADDRESS
DEFINE FEKPNT(DTX,CPX),<EXP S'CPX'DTX'FEK>
DTEFEK::
Z==-4
REPEAT M.CPU,<
CONC(<IFIW DTEFEX+>,\<Z==Z+4>,<(P1)>)
>
DTEFEX:
ZZ==0 ;CPU INDEX
REPEAT M.CPU,< ;FOR ALL CPUS
ZZZ==0 ;DTE INDEX
REPEAT 4,< ;FOR ALL DTE'S
FEKPNT(\ZZZ,\ZZ) ;BUILD THE NEXT POINTER
ZZZ==ZZZ+1> ;STEP TO THE NEXT DTE
ZZ==ZZ+1> ;STEP TO THE NEXT CPU
>;END IFN FTKL10
SUBTTL KDP BLOCKS FOR THE KMC-11/DUP-11
$ABS
IFN M.KDUP,< ;ONLY ASSEMBLE IF WE HAVE KMC-DUPS
;SINCE THE KS10 MAY HAVE AT MOST ONE KMC-11, THIS CODE DOES NOT
; EASILY PROVIDE FOR MORE THAN ONE "KDP" BLOCK.
KDPTBL::EXP KDP0 ;WE ONLY HAVE ONE KDP(KMC)
KDPMAX==:0 ;THE HIGHEST ONE IS "0"
DEFINE X(OFFSET,VALUE),< ;;HELPER MACRO FOR FILLING IN KDP BLOCK
LOC KDP0+OFFSET ;;GO TO THE APPROIATE LOCATION IN THE BLOCK
VALUE ;;AND ASSEMBLE IN THIS "VALUE"
>
DEFINE XX(DUPN),< ;;HELPER MACRO FOR FILLING IN KDPKDL SUB-TABLE
X(KDPKDL+DUPN,<XWD DK'DUPN'FEK,KDL'DUPN'PG>) ;; FILL IN FEK AND PAGE
>
;NOW LAY OUT THE KDP BLOCK
KDP0:: X(KDPCSR,<EXP KMC1BA>) ;CSR ADDRESS OF THE KMC-11
X(KDPVEC,<EXP KMC1IV>) ;INTERRUPT VECTOR ADDRESS
X(KDPDPN,<EXP M.KDUP>) ;NUMBER OF DUP-11'S ON THIS KMC
X(KDP1DP,<EXP DUP1BA>) ;BASE ADDRESS OF THE FIRST DUP-11
X(KDPNUM,<EXP 0>) ;NUMBER OF THIS KDP
Q==0 ;NOW LOOP OVER ALL KDL(DUPS) START WITH ZERO
REPEAT M.KDUP,<
XX(\Q) ;BUILD THE NEXT KDL ENTRY (XWD FEK,KDL)
Q==Q+1 ;STEP TO THE NEXT KDL
> ;LOOP UNTIL DONE
;NOW LAY OUT THE INTERRUPT ROUTINES (THEY LIVE IN THE KDP BLOCK)
X(KDPIVA,<EXP 0>) ;VECTOR A. JSR COMES HERE
EXP 0 ;SECOND WORD OF OLD PC
EXP IC.UOU,EXP .+1 ;NEW PC
EXCH T1,KDP0+KDPIVA ;SAVE T1, GET ADDR WE INTERRUPED OUT OF
MOVEM T1,KDPCHL ;PUT IT BACK WHER A POPJ WILL RETURN
MOVE T1,KDP0+KDPIVA+1;TWO WORD PC
MOVEM T1,KDPCHL+1 ;SAVE FOR XJEN
MOVE T1,KDP0+KDPIVA ;GET T1 BACK
JSR KDPSV ;GO SAVE THE AC'S
MOVEI W,KDP0 ;LOAD W FOR D8KINT
JRST KDPAIV## ;GO TO THE INTERRUPT VECTOR "A" ROUTINE
X(KDPIVB,<EXP 0>) ;VECTOR B. JSR COMES HERE
EXP 0 ;SECOND WORD OF OLD PC
EXP IC.UOU,EXP .+1 ;NEW PC
EXCH T1,KDP0+KDPIVB ;SAVE T1, GET ADDR WE CAME FROM
MOVEM T1,KDPCHL ;SAVE ADDR FOR WHEN WE EXIT INTERRUPT
MOVE T1,KDP0+KDPIVB+1;TWO WORD PC
MOVEM T1,KDPCHL+1 ;SAVE FOR XJEN
MOVE T1,KDP0+KDPIVB ;GET T1 BACK
JSR KDPSV ;SAVE THE AC'S
MOVEI W,KDP0 ;LOAD W FOR D8KINT
JRST KDPBIV## ;GO TO INTERRUPT VECTOR "B" CODE
LOC KDP0+KDPLEN ;SKIP OVER THE BLOCK
PURGE X,XX ;UNDEFINE THE "HELPER" MACROS
>;M.KDUP
IFE M.KDUP,< ;IF NO KDP'S
TSTKDP==:CPOPJ ;DEFAULT KDP CHECK ROUTINE
KDPSEC==:CPOPJ ;KDP ONCE/SECOND ROUTINE
ZAPKDP==:CPOPJ ; KDP KILL ROUTINE
>
SUBTTL DMR Blocks for the DMR11 lines
IFE M.DMRN,< ;IF NO DMR'S
TSTDMR==:CPOPJ ;DEFAULT DMR CHECK ROUTINE
DMRSEC==:CPOPJ ;DMR ONCE/SECOND ROUTINE
ZAPDMR==:CPOPJ ;DMR KILL ROUTINE
>
IFN M.DMRN,<
DEFINE X(N),<EXP DMR'N>
ZZ==0
DMRTBL::REPEAT M.DMRN,<
X(\ZZ)
ZZ==ZZ+1>
DEFINE X(N,OFFSET,VALUE),<;;Standard macro
LOC DMR'N+OFFSET
VALUE>
DEFINE XX(N,FT,DEF),<
IFNDEF DMR'N'FT,<DMR'N'FT==<DEF>>
IFN DMR'N'FT,<ZZZ==ZZZ+DMRS'FT>>
DEFINE $DMR(N),<
DMR'N:: X(N,DMRUSR,<EXP M.'N'DMR>) ;;Initial use of this line
X(N,DMRCSR,<EXP DMR1BA+<N*10>>) ;;CSR address of this DMR
X(N,DMRVEC,<EXP DMR1IV+<N*10>>) ;;Vector
X(N,DMRTAD,<EXP DMR'N'PG>) ;;10 address of this DMR's com region
X(N,DMRLIN,<XWD M.KDUP+N,N>) ;;Line # on node,,DMR #
X(N,DMRIVA,<EXP 0>) ;;Vector "A" Interrupt header
EXP 0,IC.UOU,.+1 ;;This is an XPCW block
EXCH T1,DMR'N+DMRIVA ;;GET INTERRUPT PC
MOVEM T1,DMRCHL ;;SAVE FOR DMRSV
MOVE T1,DMR'N+DMRIVA+1;;GET SECOND WORD OF PC
MOVEM T1,DMRCHL+1 ;;SAVE IT TOO
MOVE T1,DMR'N+DMRIVA ;;Restore T1
JSR DMRSV ;;Get our AC block
MOVEI W,DMR'N ;;Point to this DMR block
MOVE F,DMRTAD(W) ;; and communications page
JRST DMRAIV## ;;Process interrupt
X(N,DMRIVB,<EXP 0>) ;;Vector "B" Interrupt header
EXP 0,IC.UOU,.+1 ;;This is an XPCW block
EXCH T1,DMR'N+DMRIVB ;;GET INTERRUPT PC
MOVEM T1,DMRCHL ;;SAVE FOR DMRSV
MOVE T1,DMR'N+DMRIVB+1;;GET SECOND WORD OF PC
MOVEM T1,DMRCHL+1 ;;SAVE IT TOO
MOVE T1,DMR'N+DMRIVB ;;Restore T1
JSR DMRSV ;;Get our AC block
MOVEI W,DMR'N ;;Point to this DMR block
MOVE F,DMRTAD(W) ;; and communications page
JRST DMRBIV## ;;Process interrupt
ZZZ==0
XX(N,HD,0);;Default HDX setting
XX(N,SW,0);;Default switched line setting
XX(N,LS,1);;Default Long start select
XX(N,MT,0);;Default maintenance mode
X(N,DMRSTS,<EXP ZZZ>) ;;Initial status
X(N,DMRFEK,<EXP DR'N'FEK>) ;;Address of our FEK
X(N,DMRLEN,<BLOCK 0>)
>;Define $DMR
ZZ==0
REPEAT M.DMRN,<
$DMR(\ZZ)
ZZ==ZZ+1>
PURGE X,$DMR,XX,ZZZ
>;IFN M.DMRN
SUBTTL MUUO PROCESSING
$HIGH
MUUO: EXECAC ;EXEC ACS
JRSTF @[XWD XC.UOU,.+1];HAVE TO DO THIS BY HAND
MOVE T1,.USMUO ;GET THE MUUO PC FLAGS
MOVE R,.CPADR
TLNN T1,(XC.USR) ;WAS THE MUUO DONE IN USER MODE?
JRST UUOSY1## ;NO, DISPATCH TO EXEC MODE MUUO HANDLER
JUMPE R,MUUO1 ;IS THERE A JOB DATA AREA FOR THE JOB DOING THE UUO?
;NO, MUST BE THE DOORBELL OR ERROR IN THE
; NULL JOB
AOS .CPTUC ;ACCUMULATE THE NUMBER OF UUOS ON THIS CPU
SKIPN P,.USEPL ;USE EXTENDED PDL IF THERE IS ONE
MOVE P,[XWD MJOBPD##,.JDAT+JOBPDL##]
MOVEI F,0 ;FLAG NO DDB IN CASE ILLEGAL UUO
MOVE J,.CPJOB ;JOB NUMBER OF CURRENT JOB
JRST UUOSY1## ;DISPATCH TO MUUO HANDLER
MUUO1: HRLZ T1,.USMUO
IOR T1,.USMUE
CAME T1,WAKINS## ;DOORBELL CALLI
STOPCD .+1,STOP,UNJ, ;NO, ILLEGAL NULL JOB UUO
MUUO1A:
IFN FTMP,<
AOS .CPNDB ;COUNT NUMBER OF DOORBELLS
MOVE P,.CPNPD
JRSTF @[IC.UOU+.+1]
MOVE T1,.CPQPC
TDNN T1,DOORBL
JRST MUUO1B
ANDCAM T1,DOORBL
PUSHJ P,DSKTIC##
PUSHJ P,TAPTIC##
IFN M.ENET,<PUSHJ P,KNITIC##> ;KLNI QUEUED I/O
IFN M.SCA,<PUSHJ P,PPDTIC##> ;KLIPA QUEUED I/O
MUUO1B: MOVE T1,.CPSCC
TDNN T1,DOORBL
JRST [USERAC
XJEN .USMUO]
ANDCAM T1,DOORBL
>
DMOVE T1,.USMUO
DMOVEM T1,.CPPC
JRST CLKSPD## ;DISPATCH TO THE SCHEDULAR SINCE SOME
; JOB IS POSSIBLY NOW RUNNABLE ON THIS CPU
UMPRET:: ;HERE ON RETURN FROM MUUO PROCESSING
POP P,.USMUP ;RESTORE THE MUUO PC
POP P,.USMUO ;RESTORE FLAGS
IFN FTHPQ,<
SKIPGE SCDRTF ;HPQ JOB WAKE UP AND IN CORE?
PUSHJ P,USCHD1## ;YES
>
USERAC ;RESET USER AC BLOCK
XJEN .USMUO
$LIT ;FORCE LITERALS INTO THE HIGH SEGMENT
SUBTTL APR INTERRUPTS
;DEFINE MACRO TO CALL KL OR KI OR KS CODE FOR EACH CPU
DEFINE KILS(N)<
IFN M.KL10,<KL(N)>
IFN M.KS10,<KS(N)>
> ;END KILS MACRO DEF
$ABS
;HERE TO TRY TO CONTINUE THE SYSTEM AFTER A CLOCK ERROR STOP
IFN M.KL10,<
APRWRS::EXECAC ;GET CORRECT AC SET
CONO APR,AP.IOR ;CLEAR THE WORLD (ACTUALLY, RSX20F ALREADY DID)
CONO PI,CLRPIS
CONO PAG,0
JSP T4,SYSTR0 ;SETUP PAGING, FIND OUT WHAT CPU WE ARE
JFCL ;DON'T CARE WHETHER BOOT OR NOT
MOVE T1,.CPCPN ;CURRENT CPU NUMBER
MOVEI P,WRSPTB-1(T1) ;SETUP A VERY SHORT STACK
LSH T1,1 ;DOUBLE WORD PC
LDB T2,[POINT 18,WRSLOC(T1),35] ;CODE FOR RESTART
DMOVE T3,WRSLOC(T1) ;GET DOUBLE WORD PC
DMOVEM T3,@.CPKAF ;STORE IN KAF LOC
CAIN T2,.WRKAC ;IF KAF, REPORT AS SUCH
XCT KAF## ;BUTCHERY
CAIE T2,.WRPTO ;IF PROTOCOL TIMED OUT, CAN'T RECOVER
TLNN T3,(XC.USR) ;PC IN USER MODE?
STOPCD .,CPU,WRF,WRSF ;++WARM RESTART FAILED
SKIPN J,.CPJOB ;NULL JOB RUNNING?
JRST SPRINI ;YES, JUST RESTART IT
HRRZ T1,JBTUPM(J) ;USER PROCESS TABLE
HRRM T1,@.CPSPT ;SETUP SPT
TLO T1,(LG.LUB) ;LOAD USER BASE REGISTER
DATAO PAG,T1 ;ZAP, ADDRESSABLE
MOVE P,[MJOBPD##,,.JDAT+JOBPDL##] ;ESTABLISH A USER CONTEXT STACK
PUSH P,T3 ;SAVE FLAGS
PUSH P,T4 ;AND PC
IFN FTMP,<
SETZM .CPNBI ;SINCE ESSENTIALLY STARTING OVER, NO BROKEN INTERLOCKS
>;END IFN FTMP
PUSHJ P,SETCLK ;SETUP CLOCKS, APR, AND PI
PUSHJ P,ENTSPC## ;ENTER SECONDARY PROTOCOL, MAKE SURE 20F IN SAME STATE
PUSHJ P,STAPPC## ;NOW, START PRIMARY PROTOCAL
STOPCD .,JOB,WRJ,WRSF ;++WARM RESTART GOT JOB
;HERE TO PRINT WARM RESTART CODE
WRSF: PUSHJ P,INLMES## ;TELL WHAT'S BEING REPORTED
ASCIZ /code = /
MOVE T1,.CPCPN ;CURRENT CPU NUMBER
LSH T1,1 ;TIMES 2
LDB T1,[POINT 18,WRSLOC(T1),35] ;WARM RESTART CODE
PJRST PRTDI8## ;REPORT IT
WRSPTB: REPEAT M.CPU,<
BLOCK 1 ;VERY SHORT PDL TO USE DURING WARM RESTART
>
LIT
> ;END IFN M.KL10
$HIGH
IFN M.KS10,<
;ROUTINE TO SET UP PI ASSIGNMENTS ON UNIBUS ADAPTERS
UBAPIS::PUSHJ P,SAVE1 ;FREE UP P1
MOVEI P1,1 ;START WITH FIRST UNIBUS ADAPTER
UBAPI1: MOVS T1,P1 ;GET ADAPTER NUMBER,,0
HRRI T1,UNBSTW ;ADDRESS OF STATUS REGISTER
PUSHJ P,UBGOOD## ;IS UNIBUS ADAPTER THERE?
JRST UBAPI2 ;NO--SO DON'T TRY TO INIT IT
MOVEI T2,UBINIT ;UNIBUS INIT
WRIO T2,(T1) ;DO IT
MOVE T2,UBAPIT-1(P1) ;GET PI ASSIGNMENTS FOR THIS ADAPTER
IORI T2,UNBDTR ;SET DISABLE XFER BIT
WRIO T2,(T1) ;SET UP AND INIT UNIBUS ADAPTER
UBAPI2: CAIGE P1,MAXUBA ;DONE ALL ADAPTERS?
AOJA P1,UBAPI1 ;NO, DO NEXT
POPJ P, ;RETURN
UBAPIT::EXP UBA1PI ;PI ASSIGNMENT FOR ADAPTER 1
EXP UBA2PI ;PI ASSIGNMENT FOR ADAPTER 2
EXP UBA3PI ;PI ASSIGNMENT FOR ADAPTER 3
EXP UBA4PI ;PI ASSIGNMENT FOR ADAPTER 4
>; END IFN M.KS10
;DEFINE KL10 APR INTERRUPT HANDLER
; IT CALLS CPU INDEPENDENT CODE AS SOON AS POSSIBLE
DEFINE KL(N)<
$ABS
AP'N'INT:CONSO APR,@.C'N'CON ;INTERRUPT FOR APR (MONITOR OR USER ENABLED)
JRST .-1 ;NO, TRY NEXT DEVICE ON THIS PI CHANNEL
JRST APRINT## ;ENTER COMMON CODE
TM'N'INT::EXP 0,0,IC.UOU,TIMINT## ;KL10 INTERVAL TIMER INTERRUPT HANDLER
AP'N'KAF:EXP 0,0,IC.UOU,APRKAF## ;KL10 KEEP-ALIVE FAILURE TRAP HANDLER
EP'N'PDL::BLOCK <EPLLEN==:60> ;;FIRST WORD IS "P" OF OVERFLOW
> ;END KL10 MACRO
;DEFINE KS10 APR INTERRUPT HANDLER
; IT CALLS CPU INDEPENDENT CODE AS SOON AS POSSIBLE
DEFINE KS(N)<
$ABS
AP'N'INT:CONSO APR,@.C'N'CON ;INTERRUPT FOR APR (MONITOR OR USER ENABLED)
JRST .-1 ;NO, TRY NEXT DEVICE ON THIS PI CHANNEL
JRST APRINT## ;ENTER COMMON CODE
AP'N'KAF:EXP 0,0,IC.UOU,APRKAF## ;KS10 KEEP-ALIVE FAILURE TRAP HANDLER
EP'N'PDL::BLOCK <EPLLEN==:10> ;;FIRST WORD IS "P" OF OVERFLOW
$HIGH
>;END KS10 MACRO
;GENERATE APR INTERRUPT CODE DEPENDING ON M.CPU AND KL VS KS
ZZ==0
REPEAT M.CPU,< ;NO OF CPUS IN SYSTEM
KILS(\ZZ) ;GENERATE INTERRUPT CODE
ZZ==ZZ+1 ;STEP TO NEXT CPU NUMBER
>
$ABS
SUBTTL EXTERNS TO FORCE LIBRARY LOADING
$HIGH
;GENERATE EXTERNAL GLOBALS TO CAUSE LOADING OF PROPER ROUTINES FROM
; MONITOR LIBRARY TAPE IF THERE IS ONE
;ALWAYS LOAD CLOCK1,COMCON,CORE1,ERRCON,JOBDAT,PATCH,UUOCON,DATMAN,TMPUUO,
; AND APRSER
EXTERNAL VMSER,VMDTJB,PFH,APRSER
IFE M.KL10,<
XP UDTE,CPOPJ ;NO DTE. UUO
>
IFN M.KL10,<
EXTERNAL DTESER,TTDINT,FEDSER
>
EXTERNAL CLOCK1,COMCON,CORE1,ERRCON,PATCH,UUOCON,DATMAN,TMPUUO,MONEND
;LOAD FILE SERVICE ROUTINES, REFRESHER & ONCMOD (EXTRA ONCE ONLY CODE) FOR LEVEL D
;LEVEL D ALSO REQUIRES COMMOD, WHICH IS A SEPARATE FILE OF DISK PARAMETERS
EXTERN COMMOD, FILFND, FILIO, FILUUO, ONCMOD, REFSTR
$ABS
;ENTER DDT
ENTDDT: JFCL DDTX ;FIRST ENTRY PATCHES THIS TO JRST
EXECAC ;GET AC SET RIGHT
CONO APR,AP.IOR ;BLAST
CONO PI,CLRPIS ;BLAST
IFN M.KL10,<
CONO PAG,0 ;INSURE THAT THE CACHE IS OFF
>
JSP T4,SYSTR0 ;SEE WHICH CPU THIS IS AND SETUP THE EBR
JFCL ;REALLY SHOULD BE THE BOOT CPU
SETZM .JBEDV## ;PREVENT JUNK FROM SAVE/GET FROM CONFUSING EDDT
MOVSI T1,(JRST) ;ONLY NEED (WANT) TO DO THIS ONCE
HLLM T1,ENTDDT ; AS MONITOR WILL TURN ON PAGING FOR US
JRST DDTX ;ENTER DDT
EXTERN DDTX ;LOAD EXEC DDT
EXTERN SCHED ;LOAD SCHEDULER
EXTERN SWPSER ;LOAD SWAPPER
EXTERN SEGCON ;LOAD SEGMENT CONTROL
SUBTTL KL10 SYSTEM TIME BASE ROUTINES
$HIGH
IFN M.KL10,<
;ROUTINE TO SETUP INITIAL TIME BASE VALUE, CALLED BY SYSINI AFTER ONCE
; COMPUTES DATE BY CALLING SUDATE
SETIME::MOVE T1,DATE ;GET UNIVERSAL DATE/TIME
MULI T1,^D86400 ;GET SECONDS SINCE NOV 17,1858
ASHC T1,^D17 ;PUT BINARY POINT AFTER BIT
; 35 OF T1 YIELDING
; SECONDS SINCE NOV 17, 1858
; IN T1
MUL T1,[RTUPS*^D10] ;CONVERT TO 1 USEC UNITS FOR TIME BASE
ASHC T1,<^D35-TB.LTP>;ACCOUNT FOR COUNTS/TICK
CONO MTR,MO.TOF!MO.CTB ;TURN OFF TIME BASE, CLEAR IT.
MOVE T3,.CPEPT ;ADDRESS OF THIS PROCESSOR'S EPT
DMOVEM T1,.EPTMB(T3) ;STORE UNIVERSAL DATE TIME BASE (RUNS OUT IN 5028
MOVEI T2,MO.LAC!MO.AO!MO.AEN!MO.AIP ;INITIALIZE ACCOUNTING
MOVEI T1,ST%XPI ;CHECK IF PI TIME IS EXCLUDED
TDNE T1,CNFST2 ;SKIP IF IT IS NOT EXCLUDED
TRZ T2,MO.AIP ;IT IS, DO NOT INCLUDE
CONO MTR,MO.TON(T2) ;TURN TIME BASE ON, DO GOOD STUFF
PUSHJ P,GETIME ;GET TIME SO WE CAN
MOVEM T1,.CPXTM ;SET UP THE FIRST LAST TIME
POPJ P,
RTUPS==:^D100000 ;RESOLUTION OF ACCOUNTING
RTUPS3==:RTUPS/^D1000 ;FOR USE IN JOBTIM: ROUTINE
RTUPS5==:RTUPS/^D100000
;GET TIME OF DAY IN RTUPS UNITS/SECOND
; USES ACS T1-T4
GETIME::SETZB T1,T2 ;CLEAR T1,T2 FOR DDIV
RDTIME T3 ;GET UNIVERSAL TIME IN TIME BASE UNITS
ASHC T3,<TB.LTP-^D35> ;ACCOUNT FOR COUNT/TIME BASE TICK
DDIV T1,RTCMTT ;DIVIDE BY RTCMAX*10, YIELDING UNIVERSAL
; DATE IN T1,T2 AND USECS SINCE MIDNITE IN T3,T4
DIVI T3,^D10 ;CONVERT TO RTUPS UNITS (10 USECS)
MOVE T1,T3 ;AND GET FINAL ANSWER IN T1
POPJ P, ;RETURN
RTCMAX::RTUPS*^D3600*^D24 ;RTUPS UNITS/DAY
RTCMTT: EXP 2,203565660000 ;RTUPS*^D3600*^D24*^D10 (MICROSECS/DAY)
>;END IFN M.KL10
SUBTTL KS10 SYSTEM TIME BASE ROUTINES
IFN M.KS10,<
;ROUTINE TO SETUP INITIAL TIME BASE VALUE, CALLED BY SYSINI AFTER ONCE
; COMPUTES DATE BY CALLING SUDATE
SETIME::MOVE T1,DATE ;GET UNIVERSAL DATE/TIME
MULI T1,^D86400 ;GET SECONDS SINCE NOV 17,1858
ASHC T1,^D17 ;PUT BINARY POINT AFTER BIT
; 35 OF T1 YIELDING
; SECONDS SINCE NOV 17, 1858
; IN T1
MULI T1,^D1000 ;MILLISECOND RESOLUTION
ASHC T1,^D12 ;ACCOUNT FOR COUNTS/TICK
WRTIME T1 ;LOAD TIME BASE
MOVEI T1,<^D17>B23 ;INTERVAL FOR TIMER
WRINT T1 ;LOAD INVERVAL FOR TIMER
WRAPR SP.CSF+SP.ESF+SP.ITI+APRCHN ;TURN INTERVAL TIMER ON
PUSHJ P,GETIME ;GET TIME SO WE CAN
MOVEM T1,.CPXTM ;SET UP THE FIRST LAST TIME
POPJ P, ;END RETURN
RTUPS==:^D100000 ;RESOLUTION OF ACCOUNTING
RTUPS3==:RTUPS/^D1000 ;FOR USE IN JOBTIM: ROUTINE
RTUPS5==:RTUPS/^D100000
;GET TIME OF DAY IN RTUPS UNITS/SECOND
; USES ACS T1-T4
GETIME::SETZB T1,T2 ;CLEAR T1,T2 FOR DDIV
RDTIME T3 ;GET UNIVERSAL TIME IN TIME BASE UNITS
DDIV T1,RTCMTT ;DIVIDE BY TICS/DAY, YIELDING UNIVERSAL
; DATE IN T1,T2 AND TICS SINCE MIDNITE IN T3,T4
DIVI T3,^D41 ;CONVERT TO RTWPS UNITS
MOVE T1,T3 ;GET INTO T1 (IN 10 USEC UNITS)
POPJ P, ;RETURN
RTCMAX::RTUPS*^D3600*^D24 ;RTUPS UNITS/DAY
RTCMTT: EXP 12,117226200000 ;CLOCK TICS PER DAY AT 4.1 MHZ
RTCDAY==:CPOPJ
>;END IFN M.KS10
;MOS MEMORY
IFN M.MOS,<EXTERN MOSSER>
IFE M.MOS,<EQUATE (GLOBAL,CPOPJ,<SBERR,MOSGTM,MOSGVM,MOSMIN>)>
;DEFINE GLOBALS IF NO EXTENDED ADDRESSING SUPPORT
IFE FTXMON,<
XP SSPCS,CPOPJ
XP SVPCS,CPOPJ
XP STPCS,CPOPJ
XP SPCS,CPOPJ
>
SUBTTL PROCESSOR STUFF
;MAKE SURE THAT PROPER VERSION OF FEATURE SWITCH FILES WERE USED TO ASSEMBLE
;THE REST OF THE MONITOR
;THE LOADER WILL PRINT MUL. DEF. GLOBAL IF A MISTAKE HAS BEEN MADE
;DUAL PROCESSOR SYSTEM ROUTINE GETS LOADED HERE
IFG <M.CPU-1>,<EXTERN CPNSER>
;DEFINE GLOBAL RESTRICTING MAXIMUM SIZE OF CORE FOR ANY SINGLE USER.
;THIS CAN BE ALTERED AT SYSINI TIME BY PATCHING THE RIGHT HALF OF CORLIM.
IFE M.CORE, <
IFE FTXMON,<COREN==^D256_K2PLSH>
IFN FTXMON,<COREN==<<MXSECN+1>*^D256>_K2PLSH>
> ;END IFE M.CORE
IFN M.CORE,<COREN==M.CORE>
$ABS
;NOTE: THESE SYMBOLS WILL GO AWAY SOON SO THAT AP.??? SYMBOLS
; WILL BE USED INSTEAD AS DEFINED IN S.MAC
;APR AND PI BITS
;APR BITS FOR BOTH PDP-6 AND KA10
CLKBIT==:1
REPEAT 7-CK0CHN, <CLKBIT==:CLKBIT*2>
REQCLK==:PI.IIO+CLKBIT ;REQUEST INTERRUPT ON LOW PRIORITY CLK CHANNEL
ZZ==1
REPEAT 7-SCNCHN,<ZZ==ZZ*2>
REQCTY==:PI.IIO+ZZ ;FOR KL10 CTY, MUST INTERRUPT ON SCANNER PI BY HAND
CLRCTY==:II.CPP+ZZ ;CLEAR PSEUDO-CTY INTERRUPT (KL10)
CLRPIS==:11577 ;CLEAR THE PI SYSTEM
;NOW HARDWARE BITS WHICH DEPEND ON SOFTWARE CONFIGURATION:
XP XI.RQC,REQCLK ;CONO PI.XI.RQC REQUESTS CLK INTERRUPT
XP II.CCI,II.CPP+CLKBIT
XP XC.UOU,UIOMOD
;DEFINE APR SYMBOLS
APRCHN==:AP0CHN ;PI CHANNEL
PIPROG==:77400 ;PI STATUS REGISTER
SYSOFF==:<177_-APRCHN>+PI.TFP ;TURNS OFF ALL PI CHANNELS BELOW APR
SYSON==:<177_-APRCHN>+PI.TNP ;TURNS ON ALL PI CHANNELS BELOW APR
AP.NOT==:PIPROG-<400_<7-APRCHN>> ;ALL PI IN PROGRESS FLAGS EXCEPT APR
AP.APP==:1_<7-APRCHN+10> ;APR PI IN PROGRESS
AP.ACO==:1_<7-APRCHN> ;APR CHANNEL ON
;NON-EXISTANT MEMORY BIT
IFN M.KL10,<AP.NXM==:LP.NXM> ;NON-EX MEM (APR STATUS WORD)
IFN M.KS10,<AP.NXM==:SP.NXM>
;MASK TO TEST/CLEAR NON-EXISTANT MEMORY ERRORS
IFN M.KL10,<AP.NXE==:LP.CSF+LP.NXM>
IFN M.KS10,<AP.NXE==:SP.CSF+SP.NXM>
;MASK TO TEST/CLEAR MEMORY PARITY ERRORS
IFN M.KL10,<AP.MPE==:LP.CSF!LP.PAR>
IFN M.KS10,<AP.MPE==:SP.CSF!SP.HMP>
;MASK TO RESET APR FOR NULL JOB
IFN M.KL10,<APRNUL==:LP.ESF!LP.CSF+LP.SBE+LP.NXM+LP.PAR+LP.IOF+LP.PWF+LP.CDP+LP.ADP+LP.CSD+APRCHN>
IFN M.KS10,<APRNUL==:SP.ESF!SP.CSF!SP.PWF!SP.ITI!SP.FEI+APRCHN>
APRRST==:APRNUL+AP.IOR ;RESET APR FOR SYSINI (I/O RESET TOO)
;APR CONSO MASK
IFN M.KL10,<AP.CSO==LP.PAR+LP.PWF+LP.SBE+LP.NXM+LP.IOF+LP.CDP+LP.ADP>
IFN M.KS10,<AP.CSO==SP.PWF+SP.ITI+SP.FEI>
;APR ENABLE BITS
IFN M.KL10,<AP.EEB==LP.NXM+LP.SBE+LP.PAR+LP.PWF+LP.IOF+LP.CDP+LP.ADP+LP.CSD>
IFN M.KS10,<AP.EEB==SP.PWF+SP.ITI+SP.FEI>
;MASK TO CLEAR APR ERRORS
IFN M.KL10,<AP.CAE==LP.CSF+LP.NXM+LP.PAR+LP.IOF+LP.PWF+LP.SBE+LP.CDP+LP.ADP>
IFN M.KS10,<AP.CAE==SP.CSF+SP.PWF+SP.HMP+SP.NXM>
;IF THERE IS ONLY ONE CPU IN THIS SYSTEM DEFINE ALL NECESSARY GLOBALS
IFE <M.CPU-1>,< ;NO SECOND CPU?
$HIGH
STMPEC::MOVE P4,.C0EPT
DPB P3,P2
CLRPGT
POPJ P,
IFN FTMP,<
$CSUB
XP MSCHED,SCHEDJ##
XP CP1CRS,SAVPC2##
XP BECOM0,CPOPJ
XP BECOM1,CPOPJ
XP BRKLOK,CPOPJ
XP BRKSIW,CPOPJ
XP LOKDIE,CPOPJ
XP ULKDIE,CPOPJ
XP BRKDIE,CPOPJ
XP UXITMP,CPOPJ1
XP MSTUUO,CPOPJ
XP CP0RC,CPOPJ1
XP CP1AC,CPOPJ1
XP SPSTOP,CPOPJ1
XP DPXST,CPOPJ
XP CLRJSP,CPOPJ
XP SETJSP,CPOPJ
XP ALLJSP,CPOPJ
XP CLRSJ0,CPOPJ
XP SETSJ0,CPOPJ
XP DXRUN,CPOPJ1
XP CPUOFS,CPOPJ
XP CPUFND,CPOPJ
XP CPUDET,CPOPJ
XP CPUDTU,CPOPJ
XP CPUATT,CPOPJ
XP CPUATU,CPOPJ
XP GETMM,CPOPJ1
XP GIVMM,CPOPJ
XP SCDMM,CPOPJ1
XP MMOWN,CPOPJ1
XP DIFMM,CPOPJ
XP UIFMM,CPOPJ
XP REMMM,CPOPJ
XP GGVMM,CPOPJ
XP UPMM,CPOPJ
XP TGVMM,CPOPJ
XP DWNMM,CPOPJ
XP UPMC,CPOPJ
XP DWNMC,CPOPJ
XP LOKSCD,CPOPJ
XP ULKSCD,CPOPJ
XP SBSCD,CPOPJ
XP CLRCCB,CPOPJ
XP CPUCMD,CPOPJ
XP CPLCK,CPOPJ1
XP MAPUEC,CPOPJ
XP MAPUC,CPOPJ
XP CP1MFL,SAVPC2##
XP CHKDIE,CPOPJ
XP ONCPU0,CPOPJ
XP CP1STP,CPOPJ1
XP SETCPF,CPOPJ
XP SETCPP,CPOPJ1
XP SCDSS1,CPOPJ
XP SETQPB,CPOPJ
XP SETQP1,CPOPJ
XP ONCPUL,CPOPJ
XP ONCPUD,CPOPJ
XP ONCPUS,CPOPJ1
XP ONCPUN,CPOPJ
XP SETCPN,CPOPJ
XP CP1CHK,CPOPJ
XP BUFSSN,CPOPJ1
XP RWRTCH,CPOPJ
XP MAPINI,CPOPJ
XP CPNBPT,APRABK##
;LOCATIONS IN SLAVE CDB WHICH ARE CHECKED INDIVIDUALLY BY MASTER:
;FOLLOWING LOC ALWAYS ZERO (SINCE NO CPU1)
.E1MP==:0
JBTST3==:0
IFN M.KL10,<
XP CLCSN,CPOPJ ;IF CPNSER NOT LOADED AND KL10
XP SETCSN,CPOPJ
XP SETCSJ,CPOPJ
XP SCDCSH,CPOPJ1
XP SWPCSH,CPOPJ1
XP CTXSWP,CPOPJ
XP CSREQS,CPOPJ
XP CLRCSH,CPOPJ
XP CKCP1C,CPOPJ
XP CHKSWS,CPOPJ
XP CHKCSH,CPOPJ
XP SBCCSH,CPOPJ
XP CHKCSH,CPOPJ
XP SETCSB,CPOPJ
XP SETPCP,CPOPJ
XP UNCACH,CPOPJ
XP MLSCSH,CPOPJ1
$HIGH
CKNBF::
CHKNB:: HRLZ T1,DEVNBF(F)
HRRZS DEVNBF(F)
ADDM T1,DEVNBF(F)
STONBF::POPJ P,
$ABS
DT1CMD::
DT1MTD::0
$HIGH
>;END IFN M.KL10
CHKCPI::AOS (P)
GETCAM::MOVE T1,.CPBIT
POPJ P,
CHKCPU::
CPUOK:: AOS (P)
CAMCPU::SETZ T1,
POPJ P,
CRESET::
SETZM .C0STS
POPJ P,
> ;END IFN FTMP
$CSUB
XP LSTCPU,CPOPJ1
XP ANYRUN,CPOPJ1
XP SETCPU,CPOPJ1
XP SETCRN,CPOPJ1
XP SETCDN,CPOPJ
XP CPSCHK,CPOPJ1
XP SCDOWN,CPOPJ1
XP CPUDIA,0
$HIGH
ANYCPU::CAME J,.CPJOB
AOS (P)
POPJ P, ;TURN ON DEVICE PI LEVEL
GIVLOK::NTGIVE
POPJ P,
$ABS
BCOM0:: POPJ P,
> ;END IFE M.CPU-1
;INTERNAL HERE FOR 10/40N, MUST BE SAME AS IN COMMOD
FNCEXC==:1 ;EXECUTE ONLY
FNCRED==:2 ;READ
FNCALL==:3 ;ALLOCATE
FNCDLL==:4 ;DEALLOCATE
FNCAPP==:5 ;APPEND
FNCUPD==:6 ;UPDATE
FNCCRE==:7 ;CREATE
FNCSUP==:10 ;SUPERSEDE
FNCTRN==:11 ;TRUNCATE
FNCCAT==:12 ;CHANGE ATTRIBUTES(EXCEPT PRIVILEGE,NAME,DIR)
FNCDEL==:13 ;DELETE
FNCCNM==:14 ;CHANGE NAME
FNCCPR==:15 ;CHANGE PRIVILEGE
SUBTTL REAL TIME TRAPPING
IFN FTRTTRP,<
IFG RTTRPN,<
EXTERN RTTRP
$HIGH
RTMCAN==:.USMUE
RTMUAC::POINT 4,.USMUO,30 ;UUO AC FIELD
RTMUOC::POINT 9,.USMUO,26 ;UUO OPCODE FIELD
;TRPGO IS ENTERED FROM THE CHANNEL SAVE ROUTINE DURING A REAL TIME DEVICE
; INTERRUPT. RELAVENT LOCATIONS FROM THE USER PAGE MAP PAGE, TRPFLG, AND
; LOCATION 61 ARE SAVED. THE REAL TIME USER'S UPMP AND TRAP LOCATIONS ARE
; SETUP AND CONTROL IS TRANSFERRED TO THE USER'S INTERRUPT ROUTINE IN USER
; MODE.
TRPGO:: MOVE T1,@.CPSPT ;SPT
MOVEM T1,1(P) ;SAVE THAT
MOVE T1,RELTB1##(J) ;REAL TIME PROGRAM'S PROCESS TABLE
HRRM T1,@.CPSPT ;PART OF MAKING THE JOB ADDRESSABLE
DATAO PAG,RELTB1##(J) ;SETUP THE INTERRUPT LEVEL USER'S BASE REGISTER
ADD P,[XWD 22,22] ;OFFSET THE STACK FOR SAVING BACKGROUND
; CONTEXT OF THE INTERRUPT LEVEL USER
MOVSI T1,.USPFT ;STARTING AT THE PAGE FAULT TRAP INSTRUCTION
HRRI T1,-20(P) ; THROUGH THE PUBLIC TRAP NEW MUUO PC
BLT T1,(P) ; SAVE THE BACKGROUNG UPMP
MOVE T1,[XWD RTTUPM,.USPFT]
BLT T1,.UPMP+437 ;SETUP THE INTERRUPT LEVEL UPMP
PUSH P,.USPFW ;SAVE PAGE FAIL WORD
PUSH P,.USPFP ; AND OLD P.F. PC
PUSH P,.USPFP+1 ; ...
PUSH P,.USPFN ; AND NEW P.F. PC
MOVEI T1,RTTILM ;WHERE TO GO ON ILM
MOVEM T1,.USPFN ;STORE THAT
HRRI T1,RTTAOF ;ADDRESS OF INTERRUPT LEVEL ARITHMETIC
; EXCEPTION PROCESSING ROUTINE
IFN M.KL10,<HLL T1,-22(P)>
MOVEM T1,.USAOT ;ENABLE OR DISABLE INTERRUPT LEVEL ARITHMETIC
; TRAPPING
PUSH P,.CPDMI ;SAVE 61
PUSH P,.CPRTT ;AND LOWER LEVEL TRPFLG
HRLI J,400000 ;MAKE TRPFLG NEGATIVE, USER MODE OFF
; FOR CHN TEST ON WHETHER TO SAVE ACS
MOVEM J,.CPRTT ;SETUP TRPFLG FOR THIS INTERRUPT LEVEL USER
MOVE T1,DISMT1##(J) ;GET THE DISMISS INSTRUCTION FOR THIS INTERRUPT
; LEVEL
MOVEM T1,.CPDMI ;STORE IT IN 61
JRST 2,@TRPTB1##(J) ;ENTER THE USER'S INTERRUPT ROUTINE IN USER MODE
;DISMIS IS ENTERED FROM THE CHANNEL DISMISS ROUTINE BY A JSP J,DISMIS.
; THE STATE OF THE MACHINE IS RESTORED AND THE ROUTINE RETURNS TO THE
; CHANNEL DISMISS ROUTINE TO RESTORE THE AC'S AND DISMISS THE INTERRUPT.
DSMAPR:
DISMIS: POP P,.CPRTT ;RESTORE LOWER LEVEL TRPFLG
POP P,.CPDMI ;RESTORE 61
POP P,.USPFN ;RESTORE NEW P.F. PC
POP P,.USPFP+1 ;RESTORE OLD P.F. PC
POP P,.USPFP ;...
POP P,.USPFW ;RESTORE P.F. WORD
SUB P,[XWD 20,20] ;SET STACK OFFSET FOR RESTORING BACKGROUND
; UPMP
MOVSI T1,(P) ; ..
HRRI T1,.USPFT ;STARTING AT PAGE FAULT TRAP INSTRUCTION
BLT T1,.UPMP+437 ; RESTORE UPMP THROUGH PUBLIC TRAP NEW MUUO PC
MOVE T1,-1(P) ;SPT AT INTERRUPT
HRRM T1,@.CPSPT ;RESTORE THAT
JRST (J) ;RESTORE AC'S AND DISMISS THE INTERRUPT
;INTERRUPT LEVEL USER PAGE MAP PAGE
RTTUPM: RTTILM
RTTAOF
RTTPOF
JFCL
0
0
IC.UOU+RTTILM
RTTILM
EXP MUUO
EXP KTUUO
EXP SNTUUO
EXP STUUO
EXP RTCNTU
EXP KTUUO
EXP RTPNTU
EXP KTUUO
;HERE ON A UUO AT INTERRUPT LEVEL
RTCNTU:RTPNTU:
MOVE 17,.USMUP ;30 BIT PC, NOT REALLY, MUST BE IN SECTION 0
HLL 17,.USMUO ;UUO FLAGS
JRSTF @[IC.UOU+UUOHND##] ;TURN ON USRIOT BY HAND AND DISPATCH TO UUO HANDLER
;HERE ON AN ARITHMETIC EXCEPTION AT INTERRUPT LEVEL
RTTAOF: SKIPL .CPRTT ;INTERRUPT IN PROGRESS?
JRST .CPDMI ;NO, JUST DISMISS
MOVEM T1,.JDAT+.JBCNI##
MOVEI T1,AP.AOV+AP.FOV;REASON FOR THE TRAP
JRST ERRGO ;JOIN COMMON CODE
;HERE ON A PUSH DOWN LIST OVERFLOW AT INTERRUPT LEVEL
RTTPOF: SKIPL .CPRTT ;INTERRUPT IN PROGRESS?
JRST .CPDMI ;NO, JUST DISMISS
MOVEM T1,.JDAT+.JBCNI##
MOVEI T1,AP.POV ;TELL USER THE REASON FOR THE TRAP
JRST ERRGO ;JOIN COMMON CODE
;HERE ON AN ILLEGAL MEMORY REFERENCE (PAGE FAULT) AT INTERRUPT LEVEL
RTTILM: SKIPL .CPRTT ;INTERRUPT IN PROGRESS?
JRST .CPDMI ;NO, JUST DISMISS
MOVEM T1,.JDAT+.JBCNI##
MOVE T1,.USPFP
TLNN T1,(XC.USR) ;PC IN EXEC MODE?
STOPCD .,STOP,RTTIME, ;++ILLEGAL (REAL-TIME) MEMORY REFERENCE FROM EXEC
MOVEM T1,.USMUO
MOVE T1,.USPFP+1
MOVEM T1,.USMUP
MOVEI T1,AP.ILM ;TELL USER THE REASON FOR THE TRAP
ERRGO: MOVEM J,.CPRTS ;SAVE AN AC
MOVE J,.CPRTT ;GET INDEX INTO REAL TIME BLOCK
EXCH T1,.JDAT+.JBCNI##
EXCH T1,.USMUP ;GET THE TRAP PC
HLL T1,.USMUO ;FLAGS
EXCTXU <MOVEM T1,@APRTB1##(J)>
HRR T1,APRTB1##(J) ;ADDRESS OF THE USER'S TRAP HANDLING ROUTINE
HRRI T1,1(T1) ;CLEAR ALL FLAGS WHICH COULD CAUSE A TRAP
TLZ T1,(XC.OVF+XC.FOV+XC.TRP+XC.FUF+XC.NDV)
EXCH T1,.USMUP ;RESTORE T1 AND STORE PC
MOVE J,.CPRTS ;RESTORE J
JRSTF @.USMUP ;AND ENTER USER'S TRAP HANDLING ROUTINE
$ABS
ENBSTD==470550+APRCHN
RTBSIZ==:23
RTBLK:: BLOCK RTTRPN*RTBSIZ
>>
IFE FTRTTRP,<IFN RTTRPN,<
PRINTX ;PLEASE ASSEMBLE SOURCES WITH FTRTTRP=-1
>>
IFN FTRTTRP,<IFE RTTRPN,<
SAV41==:CPOPJ
SAV61==:CPOPJ
>>
;CREATE JBTRTD TABLE ONLY IF THERE ARE REAL TIME DEVICES OR
;HIGH PRIORITY QUEUES OR THE HIBERNATE-WAKE FEATURE.
;LH(JBTRTD) = REAL TIME STATUS BITS FOR HPQ AND HIBERNATE-WAKE
;RH(JBTRTD) = COUNT OF REAL TIME DEVICES OWNED BY EACH JOB
JBTRTD:: BLOCK JOBN
CLRRTD::SETZM JBTRTD(J)
;JBTRTD BIT DEFINITIONS
;BITS 27-35 ARE THE COUNT OF THE NUMBER OF REAL TIME DEVICES OWNED BY THIS JOB
;BITS 23-26 ARE TEMPORARY HPQ (SHARABLE DEVICE OWNER)
;BITS 15-17 ARE THE HIBERNATE PROTECTION CODE FOR THIS JOB
;BIT 14 IS TTY INPUT ACTIVITY ENABLE - CHARACTER MODE
;BIT 13 IS TTY INPUT ACTIVITY ENABLE - LINE MODE
;BIT 12 IS PTY ACTIVITY ENABLE
;BIT 11 IS I/O ACTIVITY ENABLE
;BIT 10 IF HIBER UUO AC IS AN ALIAS FOR IPCACE IN JBTRTD
;BIT 10 IS THE WAKE BIT - THIS BIT IS SET TO WAKE THE JOB UP BY HIBER
;BITS 6-9 ARE THE CURRENT HIGH PRIORITY QUEUE POSITION OF THIS JOB
;BITS 2-5 ARE THE CONSOLE COMMAND SETTING OF HPQ FOR THIS JOB
;BIT 1 IS IPCF EVENT ENABLE
;BIT 0 IS ONLY AN EXEC PROCESS CAN WAKE THE JOB
;BIT 0 OF HIBER UUO AC ARG IS 1 IF JOB IS TO BE SWAPPED IMMEDIATELY
;BUT NEVER STORED IN JBTRTD
$HIGH
TTIALE==:20 ;TTY INPUT ACTIVITY - LINE MODE
TTIACE==:10 ;TTYINPUT ACTIVITY - CHARACTER MODE
TTILCE==:TTIALE!TTIACE ;TTY INPUT - LINE AND CHARACTER MODE ENABLE
PTYWUE==:40 ;PTY WAKE UP ENABLE BIT
IOACE==:100 ;I/O ACTIVITY ENABLE BIT
WAKEB==:200 ;WAKE UP BIT
IPCACE==:200000 ;IPC EVENT ENABLE
IPCUUB==:200 ;USERS ARG FOR IPC ACTIVITY
TTIUDI==:1B18 ;BATCON/MIC ENABLE FLAG
UDIUUB==:(1B9) ;USERS ARG FOR DEMANDING INPUT
MONHBR==:400000 ;ONLY THE MONITOR CAN WAKE THIS JOB
; (STORED IN JBTRTD)
HBRSWP==:400000 ;SWAP ME OUT IMMEDIATELY
; (NOT STORED IN JBTRTD)
HBRSEC==:200000 ;TIME IS IN SECONDS
HIBPRT::POINT 7,JBTRTD(J),17 ;HIBERNATE PROTECTION CODE
IFN FTHPQ,<
HPQPNT::POINT 4,JBTRTD(J),9 ;CURRENT HIGH PRIORITY QUEUE
HPQPT1::POINT 4,JBTRTD(T1),9
HPQPT2::POINT 4,JBTRTD(T2),9
HPQSPT::POINT 4,JBTRTD(J),5 ;HIGH PRIORITY QUEUE SET BY CONSOLE COMMAND
HPQPN3::POINT 4,JBTRTD(T3),9
HPQMSK==:170000 ;BIT FIELD OF CONSOLE COMMAND HPQ
HPUMSK==:(17B9) ;CURRENT HPQ MASK
>
IFE FTHPQ,<
XP HPQMSK,0 ;NO MASK IF NO HIGH PRIORITY QUEUE
>
IFE RTTRPN,<
RTINI==:CPOPJ
RTREL==:CPOPJ
RTTRP==:CPOPJ
>
IFE FTLOCK,<
LOKJOB==:CPOPJ
UUNLOK==:CPOPJ
IFN M.LOK,<
PRINTX ;PLEASE ASSEMBLE SOURCES WITH FTLOCK=-1
>>
IFN M.LOK,<
EXTERN LOKCON
PDLPNO==:.UUPMP/PAGSIZ
>
IFN FTLOCK,<
IFE M.LOK,<
LOKJOB::MOVEI T1,0 ;ERROR CODE 0 MEANS NOT IMPLEMENTED
JRST STOTAC##
UNLOCK::MOVSI T1,NSHF!NSWP
ANDCAM T1,JBTSTS(J)
POPJ P,
MOVPAG::STOPCD .,STOP,SMP, ;++ SHOULDN'T MOVE PAGE
EQUATE (GLOBAL,CPOPJ,<CHKLPG,CKLJB,CKMOL,CONEVA,LOCK0,LOKEVX,LOKINI>)
EQUATE (GLOBAL,CPOPJ,<LOKPHY,MEMOFL,MEMOFU,NEWCMX,UNLOKH,UUNLOK>)
EQUATE (GLOBAL,CPOPJ1,<LOKCHK,LOKEVC,LOKHGH,LOKSWP,SETLPR>)
EQUATE (GLOBAL,0,<EVLPTR,LOKINS>)
>
IFNDEF CMNN,<CMNN==0>
LOKASK==:M.LOK
LOKMAX==:CMNN
IFE CMNN,<LOKMAX==:-1>
>
IFN M.LOK!<M.CPU-1>,< ;ROUTINE REQUIRED IF LOCK OR MULTIPLE CPUS
;SUBROUTINE TO SLEEP A TICK AND THEN RETRY AN OPERATION. ALWAYS RETURNS TO
; CALL MINUS ONE
DELAY1::PUSHJ P,SAVT ;DON'T CLOBBER CALLERS ACS
MOVEI T1,0 ;SLEEP 1 TIC
S0PSHJ SLEEPF## ;SLEEP BUT DON'T CLOBBER F
SOS -5(P) ;BACK UP PC TO THE TEST
SOS -5(P) ; ..
POPJ P, ;RETURN TO CHECK AGAIN
>;END IFN M.LOK!<M.CPU-1>
SUBTTL HIGH PRIORITY QUEUE UUO
IFNDEF HPQN,<HPQN==5> ;DEFAULT VALUE IS 5 HP QUEUES
IFN FTHPQ,<
IFG HPQN,<
HPQ:: PUSHJ P,HPQST1 ;CHECK HPQ LEGALITY
JRST RTM1## ;NO, GIVE ERROR RETURN
JUMPE T2,CPOPJ1 ;IF NO PRIVILEGES DONT RESCHEDULE
SYSPIF
SKIPN SCDRTF ;IS THERE A FORCED SCHEDULE BEING DONE
SETOM SCDRTF ;NO, SO START ONE
SYSPIN
SETOM .CPHQU ;FLAG HPQ UUO DONE SO SCHEDULER WILL
; REQUEUE CURRENT JOB TO NEW HPQ
JRST CPOPJ1 ;SKIP RETURN TO USER
HPQPRV: POINT 4,JBTPRV(J),3+^L<PVHPQ>-^D18 ;MAXIMUM HPQ ATTAINABLE BY THIS JOB
HPQSET: TDZA T2,T2 ;SKIP JACCT TEST
HPQST1: MOVSI T2,JACCT ;SET FOR JACCT TEST
MOVE T3,JBTPPN(J) ;GET JOB'S ACCOUNT
CAME T3,FFAPPN## ;IF OPERATOR ("FULL FILE ACCESS"), OR
TDNE T2,JBTSTS(J) ;IF JACCT
SKIPA T2,[HPQN] ;ASSUME HIGH
LDB T2,HPQPRV ;GET HPQ PRIVILEGES FOR THIS JOB
CAMLE T1,T2 ;IS THIS JOB PRIVILEGED ENOUGH?
POPJ P, ;NO, GIVE ERROR RETURN
SKIPL T1 ;CORRECT FORMAT?
CAILE T1,HPQN ;LEGAL QUEUE?
POPJ P, ;NO
DPB T1,HPQPNT ;YES, STORE NEW HPQ VALUE
JRST CPOPJ1 ;GIVE SUCCESSFUL RETURN
HPQCMD::PUSHJ P,DECIN1## ;PICK UP HPQ VALUE IN T2
JRST .+2 ;NO ARGUMENT, ASSUME 0
PJRST COMERA## ;ILLEGAL ARGUMENT
MOVE T1,T2 ;
PUSHJ P,HPQSET ;GO CHECK HPQ LEGALITY
PJRST PRIERR## ;NOT LEGAL!
DPB T1,HPQSPT ;STORE THIS NEW VALUE
POPJ P, ;RETURN
> ;IFG HPQN
> ;IFN FTHPQ
IFE HPQN,<
HPQ==:CPOPJ
HPQCMD::PJRST COMERA##
>
IFE FTHPQ,<IFG HPQN,<
PRINTX? ;PLEASE ASSEMBLE SOURCES WITH FTHPQ = -1
>>
SUBTTL PROCESS DATA BLOCK
;PDB
;PROTOTYPE PROCESS DATA BLOCK
;THIS DESCRIBES THE FORMAT OF A PDB, AND IS THE PDB FOR THE NULL JOB
; IF PDBS ARE SWAPPED. IT IS THE PROTOTYPE PDB IF PDBS ARE BUILT
; IN CORE.
PDBPRO::PHASE 0
.PDIPT::!BLOCK 1 ;IN CORE PROTECT TIME -- NUMBER OF
; JIFFIES BEFORE JOB CAN BE SWAPPED OUT.
.PDQNT==:.PDIPT ;QUANTUM RUN TIME -- JIFFIES UNTIL
; JOB SHOULD GO TO DIFFERENT RUN QUEUE
.PDCNO::!BLOCK 1 ;USER'S CHARGE NUMBER
.PDKCT::!BLOCK 1 ;PRODUCT OF CORE LENGTH (IN K) * NUMBER OF CLOCK TICKS
; PROGRAM USED CPU. USED FOR TIME ACCOUNTING.
.PDNM1::!BLOCK 1 ;FIRST HALF OF USER'S NAME IN SIXBIT
.PDNM2::!BLOCK 1 ;SECOND HALF OF USER'S NAME
.PDRTM::!BLOCK 1 ;TOTAL RUNTIME SINCE LAST RUNTIME OR KJOB
;NULL TIME FOR TOTAL SYSTEM IS KEPT FOR JOB 0
;COUNTED BY BOTH CPU'S
;SEE .CPNUL FOR INDIVIDUAL NULL TIME
.PDTTM::!BLOCK 1 ;TOTAL RUNTIME SINCE LAST KJOB IN JIFFIES
.PDTT2::!BLOCK 1 ;ADDITIONAL RUNTIME IN JIFFIES *10^-5
IFN FTKL10,<
.PDEBT::!BLOCK 1 ;(KL10) TOTAL EBOX TIME USED IN JIFFIES
.PDEB2::!BLOCK 1 ;REMAINDER IN EBOX COUNTS
.PDMBT::!BLOCK 1 ;(KL10) TOTAL MBOX TIME USED IN JIFFIES
.PDMB2::!BLOCK 1 ;REMAINDER IN MBOX COUNTS
>;END IFN FTKL10
.PDPGM::!BLOCK 1 ;PROGRAM TO RUN ON CONTROL-C OR
; RUN COMMAND
IFN M.KL10,<
.PDABS::!BLOCK 1 ;ADDRESS BREAK SETTINGS (ZERO IF USER IS
; NOT ENABLED FOR ADDRESS BREAK). 1B0=1
; IF BREAKING ON INSTRUCTION FETCH, 1B1=1
; IF BREAKING ON DATA FETCH, 1B2=1 IF
; BREAKING ON A WRITE, 1B6 (USER PAGING)
; ALWAYS A 1, BIT 18-35=BREAK
; ADDRESS
>; END IFN M.KL10
.PDCVL::!BLOCK 1 ;CVPL,,CPPL
.PDMVL::!BLOCK 1 ;MVPL,,MPPL
; NOTE THAT THE FOLLOWING ITEMS MUST REMAIN IN THE ORDER AND THAT .EPADR
; MUST BE LAST.
;
; .PDIPC, .PDIPA, .PDIPQ, .PDIPL, .PDPID, .PDIPI, .PDIPN, .PDQSN, .PDEPA
; .EPIPC, .EPIPA, .EPIPQ, .EPIPL, .EPPID, .EPIPI, .EPIPN, .EPQSN, .EPEPA .EPADR
.PDIPC::!BLOCK 1 ;LH=POINTER TO FIRST PACKET
;RH=SEND AND RECEIVE COUNTERS
.PDIPA::!BLOCK 1 ;IPCF STATISTICS
.PDIPQ::!BLOCK 1 ;FLAGS AND QUOTAS
.PDIPL::!BLOCK 1 ;IPCF QUEUE INTERLOCK WORD
;LH = JCH WHOSE QUEUE WE HAVE INTERLOCKED
;RH = JCH WHO INTERLOCKED OUR QUEUE
.PDPID::!BLOCK 1 ;PID FOR PID SPECIFIC RECEIVES
.PDIPI::!BLOCK 1 ;PID OF THIS JOB'S SYS:INFO
.PDIPN::!BLOCK 1 ;LH=POINTER TO LAST IN QUEUE
;RH=0
.PDQSN::!BLOCK 1 ;LH=FILE DAEMON SEQUENCE NUMBER
;RH=QUEUE. UUO SEQUENCE NUMBER
.PDEPA::!BLOCK 1 ;RH=ADDRESS OF PACKET SENT IN RESPONSE TO AN
; EXEC PSUEDO-PROCESS IPCF MESSAGE
;LH=0
.PDEQJ::!BLOCK 1 ;LH=0
;RH=POINTER TO JOB QUEUE
.PDEQQ::!BLOCK 1 ;LH=FLAGS
;RH=ENQ QUOTA
;FLAGS IN LEFT HALF OF PDEQQ:
EQ.HBS==:(1B0) ;THE QUOTA HAS BEEN SET
.PDJSL::!BLOCK <.SLWDJ> ;JOB SEARCH LIST
.PDJSE==:. ;FIRST WORD PAST SEARCH LIST
.PDTSL::!BLOCK 1 ;TEMPORARY SEARCH LIST POINTER
.PDNET==:. ;LEFT HALF IS THE ADDRESS OF A DDB WHICH
; HAS AN ACTIVE CONNECT/DISCONNECT IN PROCESS.
.PDSCX::!BLOCK 1 ;RIGHT HALF WORD IS ADDRESS OF JOB'S SAVED CONTEXT
.PDDIA::!BLOCK 1 ;LOC OF DIAG. DDB FOR JOB
.PDSTR::!BLOCK 1 ;STR PROGRAM CAME FROM
.PDNAM::!BLOCK 1 ;NAME OF THE PROGRAM
.PDDIR::!BLOCK 1 ;DIRECTORY PROGRAM CAME FROM
.PDSFD::!BLOCK MAXLVL ;PATH TO PROGRAM
.PDDFL::!BLOCK 1 ;WORD CONTAINING USER DEFINED DEFAULTS
; 0-8 = DEFAULT FILE PROTECTION (MUST BE HIGH 9 BITS)
; 1B9 IS NON-ZERO IF DEFAULT PROTECTION WAS SPECIFIED
; 1B10 IS NON-ZERO IF FILE DAEMON SPECIFIED PROTECTION
; 1B11 USE DEFAULT FILE SPEC ON RUN,GET
; 1B12 DON'T ASK ABOUT DETACHED JOBS ON "LOGIN"
; 1B13 PD.LGN
; 1B14 .STPGM RUN IN PROGRESS
; 1B15 LOGOUT UUO IN PROGRESS
; 18-26 = FILE DAEMON SUPPLIED PROTECTION
; (MUST BE HIGH 9 BIT OF RH)
; 27-35 DEFAULT NUMBER OF DISK BUFFERS
.PDCAP::!BLOCK 1 ;MAXIMUM PRIVILEGES ALLOWED
.PDACS::!BLOCK ACTSTL ;ACCOUNT STRING
.PDVKC::!BLOCK 1 ;VIRTUAL TIME-CORE INTEGRAL
.PDUUC::!BLOCK 1 ;COUNT OF UUOS DONE BY THIS JOB
IFN FTHPQ,<
.PDHZF::!BLOCK 1 ;ORIGINAL VALUE OF TIME IF FIT WAS
; ZEROED BY HPQ JOB
>
IFN FTPSCD,<
.PDPST::!BLOCK 1 ;NEGATIVE OF SWAPOUT TIME
>
.PDOBI::!BLOCK 1 ;OPERATOR/BATCH INFO
IFN FTMDA,<
.PDSTM::!BLOCK 1 ;TIME OF LAST RESET
>
.PDLBS::!BLOCK 1 ;DEFAULT SIZE OF LARGE DISK BUFFER
;LH=SET BY UUO, RH=SET BY COMMAND
.PDOSL::!BLOCK 1 ;OLD-STYLE LIB PPN
.PDSJB::!BLOCK 1 ;PTR TO DECNET SESSION CONTROL JOB BLOCK
.PDCMN::!BLOCK 1 ;AOBJN POINTER TO USER-DEFINABLE COMMAND NAMES
.PDUNQ::!BLOCK 1 ;POINTER TO LOCAL UNQTAB,,TABLE OF UDC BLOCKS
IFN M.CTX,<
.PDSAC::!BLOCK 1 ;ADDRESS OF FIRST CONTEXT BLOCK
.PDCTC::!BLOCK 1 ;ADDRESS OF CURRENT CONTEXT BLOCK
.PDCTQ::!BLOCK 1 ;CONTEXT QUOTA WORD
.PDCTU::!BLOCK 1 ;CONTEXT USE WORD
> ;END IFN M.CTX
.PDCTX::!BLOCK 1 ;CONTEXT FLAG WORD (MUST ALWAYS BE ASSEMBLED)
.PDTMI::!BLOCK 1 ;VIRTUAL TIMER TRAP INITIAL VALUE
.PDTMC::!BLOCK 1 ;COUNTDOWN FOR VIRTUAL TIMER TRAPS OR OLD PC
.PDVRT::!BLOCK 1 ;JOB PAGING RATE
IFN FTSCA,<
.PDSCS::!BLOCK 1 ;ADDRESS OF PROCESS QUEUE BLOCK FOR SCS. UUO
>; END IFN FTSCA
IFN FTENET,<
.PDEJB::!BLOCK 1 ;ADDRESS OF ETHERNET JOB BLOCK
>; END IFN FTENET
.PDLPN::!BLOCK 1 ;LOGGED-IN PPN
; *** ADD NEW PDB ENTRIES BEFORE HERE ***
IFDEF M.PCST,<IFN M.PCST,< ;DEFINE PDB SPACE FOR CUSTOMER USE
.PDCST::!BLOCK M.PCST ;CUSTOMER-SPECIFIC PDB STORAGE
>> ;END IFDEF/IFN M.PCST
.PDLEN::! ;LENGTH OF A PDB IN WORDS
DEPHASE
$ABS
SUBTTL SCHEDULER QUEUE DEFINITIONS
;SHARABLE DEVICE JUST BECOME AVAILABLE
;APPROPRIATE ENTRY IS SET NON-ZERO WHEN SCHEDULER SHOULD LOOK
;AT THAT QUEUE TO FIND A JOB TO RUN
DEFINE X(A,B,C)
<A'Q==:ZZ
ZZ==ZZ+1>
ZZ==0
QUEUES
DEFINE X(A,B,C)
<A'Q==:.-AVALTB+ZZ
A'AVAL::0
>
AVALTB::RWAITS ;GENERATE THE AVAL FLAGS
LOC=.-AVALTB+ZZ
XP AVTBMQ,AVALTB-ZZ
;TABLE CONTAINING JOB NUMBER OF THE OWNER OF A
; SHARABLE RESOURCE. THE RIGHT HALF WORD CONTAINS
; THE JOB NUMBER OF THE JOB THAT CURRENTLY
; OWNS THE RESOURCE OR ZERO IF THE RESOURCE IS
; AVAILABLE. THE LEFT HALF WORD CONTAINS THE JOB
; NUMBER OF THE LAST JOB WHICH GAVE UP THE RESOURCE.
; THIS TABLE IS USEFUL FOR DEBUGGING AND REQUIRED
; SO THAT IN THE EVENT OF CATASTROPIC ERROR, E.G.,
; SWAP READ ERROR, THE RESOURCE MAY BE FREED UP.
DEFINE X(A,B,C)
< ZZ==ZZ+1>
ZZ==0
QUEUES
DEFINE X(A,B,C)
<A'USER:: 0
>
USRTAB::RWAITS
XP USTBMQ,USRTAB-ZZ
;DEFINE STATE CODES WHICH DO NOT HAVE AVAL AND REQ FLAGS
DEFINE X(A,B,C)
<A'Q==:LOC
LOC==LOC+1
>
CODES
XP MXCODE,LOC-1 ;MAX. JOB STATE CODE
;ANY QUEUES GREATER THAN CMQ MUST BE PROCESSOR QUEUES
CMQ==:LOC ;COMMAND DELAY QUEUE
LOC=LOC+1
PQ1==:LOC
LOC=LOC+1
PQ2==:LOC
LOC=LOC+1
DEFINE HPQCOD(A)
< HPQ'A==LOC
LOC==LOC+1>
IFG HPQN,<ZZ==1
REPEAT HPQN,<HPQCOD(\ZZ)
ZZ==ZZ+1
>
>
;DEFINE SYMBOLS FOR PQ2 SUBQUEUES. SQ0=-1, SQ1=-2, ETC.
; USED FOR NEGATIVE INDICES TO JBTSQ.
DEFINE CLSGEN(A)
<SQ'A==:A+1>
ZZ==0
REPEAT M.CLSN,<
CLSGEN(\ZZ)
ZZ==ZZ+1>
$HIGH
;PUT JOB DOWN A Q IF EXCEEDS QUANT. TIME
QRQTAB::XWD PQ2,-PQ2 ;FROM PQ1
XWD PQ2,-PQ2 ;FROM PQ2
QTTAB::
DEFINE HPQTTB(A)
< XWD HPQ'A,-HPQ'A>
IFG HPQN,<ZZ==1
REPEAT HPQN,<HPQTTB(\ZZ)
ZZ==ZZ+1
>
>
XP QRQTBL,QRQTAB-PQ1 ;TABLE MINUS OFFSET
$ABS
; BASE QUANTA FOR QUEUES
QADTAB::EXP 0 ;PQ1
EXP 0 ;PQ2
QQSTAB::
DEFINE HPQJIF(A)
< EXP JIFY'A>
IFG HPQN,<ZZ==0
REPEAT HPQN,<ZZZ==HPQN-ZZ
HPQJIF(\ZZZ)
ZZ==ZZ+1
>
>
DEFINE JIFDEF(A)
<JIFY'A==A*2>
ZZ==1
REPEAT HPQN,<JIFDEF(\ZZ)
ZZ==ZZ+1>
XP QADTBL,QADTAB-PQ1 ;TABLE MINUS PQ1
; MULTIPLIER TABLE FOR RUN QUANTA BY QUEUES
QRANGE:: ^D45 ;RANGE IN K BETWEEN SMALLEST AND LARGEST QUANTUM
; RUN TIME ASSIGNMENT
; ENTRIES ARE RANGE IN TICKS BETWEEN SMALLEST QUANTUM TO ASSIGN (QADTAB)
; AND LARGEST QUANTUM TO ASSIGN (QMXTAB)
QMLTAB::EXP 0 ;PQ1
EXP 0 ;PQ2
REPEAT HPQN,<EXP 0> ;NO MULTIPLIER FOR HPQS
XP QMLTBL,QMLTAB-PQ1 ;TABLE MINUS PQ1
;MAXIMUM ALLOWABLE RUN QUANTO FOR QUEUES
QMXTAB::EXP 0 ;PQ1
EXP 0 ;PQ2
IFG HPQN,<ZZ==0
REPEAT HPQN,<ZZZ==HPQN-ZZ
HPQJIF(\ZZZ)
ZZ==ZZ+1
>
>
XP QMXTBL,QMXTAB-PQ1 ;TABLE MINUS PQ1
$HIGH
ISCAN:: ;SCAN FOR INPUT - GETTAB TABLE 45
DEFINE HPQSCN(A)
< XWD -HPQ'A,QFOR##>
IFG HPQN,<ZZ==0
REPEAT HPQN,<ZZZ=HPQN-ZZ
HPQSCN(\ZZZ)
ZZ==ZZ+1
>
>
XWD -CMQ,QFOR## ;MONITOR COMMAND WHICH NEEDS CORE IMAGE IN CORE
XWD -PQ1,IQFOR## ;GET PEOPLE WHO GETSEGED FIRST
XWD -PQ2,IGFOR## ;BUT JUST THOSE WITH QUANTA LEFT
FISCAN::XWD -PQ1,OQFOR##
IFE FTNSCHED,<
XWD -PQ2,FOQFOR## ;FAIRNESS HERE
>
IFN FTNSCHED,<
XWD -PQ2,FSQFOR## ;FAIRNESS HERE
>
XWD -PQ2,IQFOR##
IFN FTNSCHED,<
XWD -PQ2,BQFOR##
>
ISTMXL==:<.-ISCAN-1>B26 ;MAKE ENTRY IN GETTAB FOR INPUT SWAP SCAN LIST
IFN FTPATT,<
Z ;PATCH SPACE
Z
>
Z ;FINAL ZERO TO FLAG END
ISCAN1:: ;ALTERNATE INPUT SCAN
IFG HPQN,<ZZ==0
REPEAT HPQN,<ZZZ=HPQN-ZZ
HPQSCN(\ZZZ)
ZZ==ZZ+1
>
>
XWD -CMQ,QFOR## ;MONITOR COMMAND WHICH NEEDS CORE IN
IFE FTNSCHED,<
XWD -PQ2,FOQFOR##
>
IFN FTNSCHED,<
XWD -PQ2,FSQFOR##
>
XWD -PQ1,OQFOR##
XWD -PQ2,IGFOR##
XWD -PQ1,IQFOR##
XWD -PQ2,IQFOR##
IFN FTNSCHED,<
XWD -PQ2,BQFOR##
>
IFN FTPATT,<
Z ;PATCH SPACE
Z
>
Z ;FINAL ZERO TO FLAG END
;TABLE FOR SCHED. FUNCTION 30 (SELECT ON A /CPU BASIS ORDER OF Q SCAN
CPSCAN::SSCAN ;SUBFUNCTION 0,SCAN USING SSCAN,(P01,PQ2)
SSCAN1 ;SUBFUNCTION 1,SCAN USING SSCAN1,(PQ2,PQ1)
IFN FTPATT,<
Z ;PATCH SPACE
Z
>
CPSTBL==:.-CPSCAN-1 ;LENGTH
$ABS
SSCN=:-3 ;SECONDARY SCAN TABLE ADDRESS
EXP SSCAN1
MFC=:-2 ;MAXIMUM FAIRNESS COUNT
EXP SFC0
FSCN=:-1 ;ENTRY IN SCAN TABLE OF FIRST FAIR LOCATION
EXP FSCAN
SSCAN:: ;SCHEDULER SCAN LIST - GETTAB TABLE 47
DEFINE HPQSCN(A)
< XWD -HPQ'A,IQFOR##>
IFG HPQN,<ZZ=0
REPEAT HPQN,<ZZZ=HPQN-ZZ
HPQSCN(\ZZZ)
ZZ=ZZ+1
>
>
XWD -PQ1,IQFOR## ;SCHEDULER'S SCAN FOR NEXT JOB TO RUN
FSCAN:
IFE FTNSCHED,<
XWD -PQ2,IRRFOR
>
IFN FTNSCHED,<
XWD -PQ2,ISSFOR##
XWD -PQ2,IBBFOR##
>
SSTMXL==:<.-SSCAN-1>B26 ;MAX ENTRY FOR GETTAB
IFN FTPATT,<
Z ;FOR PATCHING
Z
>
Z ;FINAL ZERO TO FLAG END
;SLAVE PROCESSOR SCAN TABLE FOR CPU SCHEDULING
EXP SSCAN ;SECONDARY SCAN TABLE FOR SLAVE
EXP SFC1 ;MAXIMUM FAIRNESS COUNT
EXP FSCAN1 ;ENTRY POINT IN SCAN TABLE OF FIRST FAIR TABLE
SSCAN1:
IFG HPQN,<
ZZ==0
REPEAT HPQN,<ZZZ=HPQN-ZZ
HPQSCN(\ZZZ)
ZZ==ZZ+1
>
>
IFE FTNSCHED,<
XWD -PQ2,IRRFOR
>
IFN FTNSCHED,<
XWD -PQ2,ISSFOR##
>
FSCAN1: XWD -PQ1,IQFOR## ;IF NO JOBS TRY PQ1
IFN FTNSCHED,<
XWD -PQ2,IBBFOR##
>
IFN FTPATT,<
Z ;FOR PATCHING
Z
>
0
$HIGH
LSCAN:: ;SCAN FOR LOST TIME
DEFINE HPQSCN(A)
< XWD -HPQ'A,OQFOR##>
IFG HPQN,<
ZZ==0
REPEAT HPQN,<ZZZ=HPQN-ZZ
HPQSCN(\ZZZ)
ZZ==ZZ+1
>
>
XWD -PQ1,OQFOR## ;PQ1 NO CORE FORWARD
IFE FTNSCHED,<
XWD -PQ2,OQFOR## ;PQ2 NO CORE FORWARD
>
IFN FTNSCHED,<
XWD -PQ2,OSSFOR## ;PQ2 NO CORE SUB QUEUES FORWARD
;INCLUDES NO CORE BACKGROUND BATCH
>
0
;NOTE - FOR BEST RESULTS OSCAN SHOULD BE IN
; REVERSE ORDER OF ISCAN, ELSE SCHEDULER BINDS
OSCAN:: ;SCAN FOR OUTPUT - GETTAB TABLE 46
XWD -STOPQ,IQFOR## ;UNRUNABLE JOBS FIRST
XWD -SLPQ,IQFOR##
XWD -EWQ,IQFOR## ;EVENT WAITERS
XWD -JDCQ,IQBAK1##
XWD -TIOWQ,IQFOR## ;TTY IOW
XWD -JDCQ,IQFOR1##
XWD -PQIOQ,IQFOR## ;PAGE QUEUE WAIT
OTHQUE==.-1
PQ2QUE: XWD -PQ2,OLFOR## ;INCLUDES -PQ2,IQBAK AS SUBCASE
PQ1QUE: XWD -PQ1,IQBAK##
CMQUE: XWD -CMQ,IQBAK##
DEFINE HPQSCN(A)
<HPQU'A: XWD -HPQ'A,IQBAK##>
IFG HPQN,<ZZ=1
REPEAT HPQN,<HPQSCN(\ZZ)
ZZ=ZZ+1
>
>
OSTMXL==:<.-OSCAN-1>B26 ;MAX. ENTRY IN GETTABS
IFN FTPATT,<
Z ;PATCH SPACE
Z
>
Z ;FINAL ZERO TO FLAG END
; TABLE OF WHAT QUE ENTRY IS LAST TO SCAN FOR SWAP OUT
OSCANT::OTHQUE ;WHERE TO STOP IF NOT CMQ OR PROCESSOR QUEUE
CMQUE ;WHERE TO STOP IF CMQ
PQ1QUE ;WHERE TO STOP IF PQ1
PQ2QUE ;WHERE TO STOP IF PQ2
DEFINE HPQSTP(A)
< HPQU'A>
IFG HPQN,<
ZZ=1
REPEAT HPQN,<HPQSTP(\ZZ)
ZZ=ZZ+1
>
>
OSCNTQ=:OSCANT+1-CMQ ;MAKE AN INDEX INTO STOP TABLE
; SPECIAL SCAN TABLE FOR DECREMENTING IN CORE PROTECT TIMES
; PROCESSOR QUEUES MUST BE IN REVERSE ORDER SO THAT REQUEING
; DUE TO EXPIRATION OF ICPT DOES NOT PUT JOB WHERE WE WILL SEE
; IT AGAIN (QUEUES ARE ALSO SCANNED IN REVERSE)
; MUST ALSO CONTAIN ANY OTHER PHYSICAL QUEUE WHICH IS ALLOWED TO
; RETAIN ICPT. CURRENTLY THIS IS ONLY SLP AND EW.
DCSCAN::EXP -EWQ ;EVENT WAIT QUEUE
EXP -SLPQ ;SLEEP QUEUE
EXP -PQ2 ;PQ2
EXP -PQ1 ;PQ1
DEFINE HPQSCN(A)
< EXP -HPQ'A>
IFG HPQN,<
ZZ==1
REPEAT HPQN,<HPQSCN(\ZZ)
ZZ==ZZ+1
>
>
IFN FTPATT,<
0
0
>
0
IFN FTNSCHED,<
$ABS
;SUBQUEUE INPUT SCAN TABLE
;
;FOR GENERATING PRIMARY SCAN TABLE, ENTRIES CONTAIN:
; PRIORITY COUNTER IN LEFT HALF,
; SUBCLASS NUMBER IN RIGHT HALF.
;
;FOR GENERATING SECONDARY INPUT SCAN, ENTRIES CONTAIN:
; MINUS SUBQUEUE NUMBER IN LEFT HALF,
; SECONDARY QUOTA IN RIGHT HALF.
SQSCAN::BLOCK M.CLSN
SQCNT:: 0 ;COUNTER OF LOCATIONS LEFT IN PRIMARY SCAN TABLE
SQPNT:: 0 ;POINTER TO CURRENT LOC IN PRIMARY SCAN TABLE
SQSUM:: 0 ;SUM OF SECONDARY PERCENTS
SQSAVJ::0 ;NUMBER OF CLASS ALREADY SCANNED
SCNJIL::0 ;TIME TO STOP SCANNING JBTJIL
SCNSWP::0 ;# TICS SAME PRIMARY SUBQUEUE HAS BEEN SCANNED
SCNBBS::0 ;TIME TO SWAP NEXT BB JOB
BBFIT:: 0 ;NON-ZERO IF BACKGROUND BATCH JOB BEING FIT
BBFLAG::0 ;NON-ZERO IF BACKGROUND BATCH QUEUE BEING SCANNED
>;END IFN FTNSCHED
$ABS
SEED:: 377775 ;SEED FOR RANDOM NUMBER
$HIGH
IFN FTNSCHED,<
$ABS
;SUBQUEUE SCAN TABLE FOR CPU0
;
;ENTRIES CONTAIN:
; MINUS SUBQUEUE NUMBER.
; TABLE TERMINATES WITH A ZERO.
SSSCAN::BLOCK M.CLSN
0 ;ZERO TERMINATES TABLE
SSCNT:: 0 ;COUNTER OF ENTRIES LEFT IN PRIMARY SCAN TABLE
SSPNT:: 0 ;POINTER TO PRIMARY SCAN TABLE FOR CPU0
SSSUM:: 0 ;SUM OF SECONDARY PERCENTS
IFN FTMP,<
;SUBQUEUE SCAN TABLE FOR CPU1
SSSCN1::BLOCK M.CLSN
0 ;ZERO TERMINATES TABLE
SSPNT1::0 ;POINTER TO PRIMARY SCAN TABLE FOR CPU1
>
;PRIMARY SCAN TABLE
;STORED AS 101 5-BIT ENTRIES, ONE FOR EACH PERCENT OF THE SYSTEM RESOURCES
; ENTRY 101 IS A DUPLICATE OF ENTRY 1.
PSQTAB::BLOCK ^D15 ;ROOM FOR 101 ENTRIES
$HIGH
>;END IFN FTNSCHED
SUBTTL MINIMUM CORE USAGE DATA TABLES
;TABLE OF INDICES TO FIRST POSITION ON TABLES BELOW FOR VARIOUS KONTROLLER TYPES
TYPTAB::EXP FRSTDR ;TYPE 0 (DR) FUTURE DRUM, IF ANY
EXP FRSTFH ;TYPE 1 (FH) BURROUGHS DISK OR BRYANT DRUM
EXP FRSTDP ;TYPE 2 (DP) RP10 KONTROLLER RP01, RP02, RP03 DRIVES
EXP FRSTMD ;TYPE 3 (MD) BRYANT MASS DISK
EXP FRSTFS ;TYPE 4 (FS) RH10/RS04
EXP FRSTRP ;TYPE 5 (RP) RH10/RP04
EXP FRSTRN ;TYPE 6 (RN) RP20
EXP FRSTRA ;TYPE 7 (RA) RA80/81/60
;TABLES COMPUTED BY ONCMOD
;UNITS ARE MICROSECONDS
;AVERAGE TIME PER PAGE (K) TABLE COMPUTED BY ONCMOD
MCUATP:: Z ;FUTURE DRUM
Z ;DITTO
Z ;RD10
Z ;RM10B
Z ;RP01
Z ;RP02
Z ;RP03
Z ;DUAL POSITIONER MD10
Z ;SINGLE POSITIONER MD10
Z ;RS04
Z ;RP04
Z ;RP06
Z ;RM03
Z ;RP07
Z ;RP20
Z ;RA80
Z ;RA81
Z ;RA60
;AVERAGE LATENCY TIME TABLE COMPUTED BY ONCMOD
MCUALT:: Z ;FUTURE DRUM
Z ;DITTO
Z ;RD10
Z ;RM10B
Z ;RP01
Z ;RP02
Z ;RP03
Z ;DUAL POSITIONER MD10
Z ;SINGLE POS. MD10
Z ;RS04
Z ;RP04
Z ;RP06
Z ;RM03
Z ;RP07
Z ;RP20
Z ;RA80
Z ;RA81
Z ;RA60
SUBTTL SET PSECT LIMITS
;MACRO TO ACCEPT SYMBOLIC VALUES FOR PSECT LIMITS AND PASS THEM TO LINK
;VIA THE .TEXT PSUEDO-OP.
DEFINE SETPSL(NAME,MAX),<
.TEXT "/LIMIT:'NAME':'MAX'"
>; END DEFINE
;DEFINE LIMIT FOR PSECT .LOW. SO SYMBOLS DON'T OVERLAP PSECT .CSUB. (OR .HIGH.)
IFE FTXMON,<
SETPSL (.LOW.,\MONORG)
>; END IFE FTXMON
IFN FTXMON,<
SETPSL (.LOW.,\CSBORG)
>; END IFN FTXMON
;DEFINE LIMIT FOR PSECT .HIGH. SO CODE DOESN'T OVERLAP FUNNY SPACE
SETPSL (.HIGH.,\HLCSAD)
;DEFINE LIMIT FOR PSECT .INIT. SO CODE DOESN'T OVERLAP RESERVED MAPPINGS
SETPSL (.INIT.,\.UPMAP)
;DEFINE LIMIT FOR PSECT .SYMS. SO SYMBOLS DON'T OVERLAP PSECT .XHGH.
IFN FTXMON,<
SETPSL (.SYMS.,\XHIORG)
>; END IFN FTXMON
;NOTE THAT THE ABOVE IS INEFFECTIVE, THUS THE FOLLOWING:
IFN FTXMON,<
CONC(<.TEXT "/UPTO:>,\XHIORG,<">)
>
IFE FTXMON,<
CONC(<.TEXT "/UPTO:>,\MONORG,<">)
>
;DEFINE LIMIT FOR PSECT .XHGH. SO EXTENDED HIGH SEGMENT DOESN'T
;OVERLAP FUNNY SPACE
IFN FTXMON,<
SETPSL (.XHGH.,\<MS.HGH+HLCSAD>)
>; END IFN FTXMON
;DEFINE LIMIT FOR PSECT CSUB SO COMMON SUBROUTINES DON'T OVERLAP PSECT .HIGH.
IFN FTXMON,<
SETPSL (.CSUB.,\MONORG)
>; END IFN FTXMON
$LIT ;GENERATE ALL LITERALS BEFORE RELOC
LOLOC==ABSLOC-COMORG ;HIGHEST ABSOLUTE ADDRESS USED
$LOW
RELOC LOLOC ;MAKE SURE .LOW. INCLUDES ALL ABSOLUTE CODE
END SYSTRT