Trailing-Edge
-
PDP-10 Archives
-
dec-10-omona-u-mc9
-
kaser.mac
There are 7 other files named kaser.mac in the archive. Click here to see a list.
TITLE KASER - PDP-6 AND KA10 PROCESSOR DEPENDENT CODE - V072
SUBTTL APRINT TH/TH/CHW/RCC/PFC/JE/DAL 20 JUL 75
SEARCH F,S
$RELOC
$HIGH
;***COPYRIGHT 1973,1974,1975,1976,1977 DIGITAL EQUIPMENT CORP., MAYNARD, MASS.***
XP VKASER,072
; PUT VERSION NUMBER IN GLOB LISTING AND LOADER STORAGE MAP
ENTRY KASER ;LOAD KASER IF LIBRARY SEARCH
KASER:
;THIS SERVICE ROUTINE RUNS ON A HIGH PRIORITY CHANNEL
;AND REQUESTS INTERRUPTS ON LOWER CLK CHANNEL
;FOR SCHEDULING JOBS AND ERROR HANDLING THAT THE USER
;IS NOT ENABLED TO HANDLE HIMSELF
SUBTTL CLOCK - LOW PRIORITY CLOCK SERVICE(CLK)
;THIS ROUTINE RUNS ON THE LOWEST PRIORITY PI CHANNEL AND AT UUO LEVEL
;TO CAUSE AN INTERRUPT ON CLK CHANNEL:
; SETOM CLKFLG ;FLAG THAT INTERRUPT HAS BEEN REQUESTED
; CONO PI,CLKREQ ;REQUEST PI INTERUPT ON LOWEST PI CHANNEL
;THE FOLLOWING OTHER FLAGS MUST ALSO BE SET
;APRERR-APR DETECTED ERROR IN CURRENT JOB
;SCHEDF-RESCHEDULING MUST TAKE PLACE(EVEN THOUGH PC IN EXEC MODE)
;TIMEF-APR CLOCK HAS TICKED ON HIGH PRIORITY CHANNEL
;SEE APRSER AND RUNCSS TO SEE HOW THIS ROUTINE IS CALLED
;CLK SERVICE PERFORMS THE FOLLOWING ON A REGULAR BASIS:
;PROCESSES CLOCK QUEUE REQUESTS
;CALLS CONSOLE MONITOR COMMAND DECODER
;CALLS CORE SHUFFLER
;THEN CALLS SCHEDULER
;IF THE CURRENT JOB IS IN EXEC MODE THE ABOVE 4 TASKS ARE
;DELAYED UNTIL THE CURRENT JOB ENTERS A STOPPABLE STATE: I.E., UNTIL
; 1. JOB STARTS TO WAIT FOR A BUSY SHARABLE DEVICE
; 2. JOB STARTS TO WAIT FOR IO TO COMPLETE
; 3. CONTROL ABOUT TO RETURN TO USER MODE
;THEN CLK SERVICE IS ENTERED AT THE UUO LEVEL
REPEAT 0,<
;*** OLD ACCUMULATOR ASSIGNMENTS, CHANGED JUNE 1, 1971
STOR=U
T=T1
T1=T2
JA=R
>
;THE CLOCK REQUEST QUEUE PROVIDES THE REST OF THE MONITOR
;WITH THE ABILITY TO BE TRAPPED TO AFTER A NUMBER OF CLOCK TICKS
;HAVE OCCURRED
;TO MAKE A REQUEST:
; CONO PI,PIOFF
; IDPB AC,CLOCK ;STORE CLOCK REQUEST IN QUEUE
; CONO PI,PION ;TURN PI BACK ON
;C(AC)=XWD ADDRESS,NO. OF CLOCK TICKS+DATA*10000
;WHERE DATA IS 6 BITS OF INFO NEEDED WHEN TIME RUNS OUT
;CLK SERVICE WILL PUSHJ P,ADR
;WHEN TIME RUNS OUT WITH DATA RIGHT JUSTIFIED IN AC T1
;ALL ACS ARE FREE TO USE WHEN CALL IS MADE
;HERE AT CLK INTERRUPT LEVEL
INTERNAL CK0INT,CIP8B
INTERNAL FTTIME
;************************************************
;THIS CODE IS DUPLICATED IN SLVSER FOR CPU1
CK0INT: SKIPN .C0CKF## ;CLK INTERRUPT REQUEST?
JRST CK0INT ;NO, CHECK OTHER DEVICES
MOVEM 17,.C0S17## ;SAVE AC 17
MOVE 17,CK0CHL ;IS CURRENT JOB IN USER MODE?
TLNN 17,USRMOD
SKIPE .C0SCF## ;NO, IS THIS A FORSCED RESCHEDULING INTERRUPT?
JRST SAVPC ;YES, IT IS OK TO RESCHEDULE NOW
MOVE 17,.C0S17## ;NO, LEAVE TIMEF SET AND DISMISS INT.
JEN @CK0CHL##
;HERE ON CLK (USUALLY PI7) INTERRUPT FOR CPU0 FOR KA10 OR KI10)
;NO ACS SAVED OR SETUP YET
SAVPC: MOVEM 17,.C0PC## ;SAVE PC IN PROTECTED PART OF SYSTEM DATA
; STORAGE FOR CURRENT JOB
;HERE ON APR ERROR WITH ALL AC RESTORED
SKIPN 17,.C0ADR## ;CURRENT JOB DATA AREA, IS THERE ONE?
MOVE 17,.C0NJD## ;NO, MUST BE NULL JOB OR CORE 0
; RUNS AT UUO LEVEL,REQUESTS CLK INT. TO STOP
MOVEM 16,JOBD16##(17) ;SAVE AC 16 IN DUMP AC PART OF JOB DATA AREA
MOVEI 16,JOBDAC##(17) ;SOURCE=0,DESTINATION=DUMP AC 0
BLT 16,JOBD15##(17) ;SAVE ACS 0-15 JUST BELOW AC 16
MOVE T1,.C0S17 ;NOW SAVE 17 IN JOB DATA AREA
MOVEM T1,JOBD17##(17) ;ALONG WITH OTHER ACS
CK0SPD::MOVE P,.C0NPD## ;SET UP PUSH DOWN LIST IN NULL JOB DATA
; AREA IN LOWER CORE
JRST CHKAPE## ;CHECK FOR APR ERRORS, DO COMMAND DECODING
; AND RESCHEDULE
;HERE AFTER CALLING SWAPPER, SCHEDULER, COMMAND DECODER, ETC.
; RESTORE AC'S OF (NEW) CURRENT USER
CIP8B: MOVSI 17,JOBDAC##(R) ;RESTORE DUMP ACS
BLT 17,17
SKIPE .C0AEF## ;DID AN ERROR OCCUR WHILE CLK PI IN PROGRESS
; (ON CLK PI OR HIGHER) OR ON CPU1
JRST CK0SPD ;YES, GO PROCESS ERROR NOW THAT ON CPU0
JEN @.C0PC## ;DISMISS CHANNEL(IF INTERRUPT IN PROGRESS)
;ROUTINE TO SET HARDWARE AND SOFTWARE RELOCATION INFORMATION FOR CURRENT USER
;CALLED FROM:
; CLOCK ROUTINE WHEN NEW USER IS DIRRERENT FROM OLD USER
; CORE ROUTINE WHEN CORE REASSIGNED FOR CURRENT USER
; CORE UUO
; REMAP UUO
; CALL RESET UUO
; CALL SETUWP UUO
; CALL WHENEVER OLD HIGH SEG IS REMOVED FROM ADR. SPACE FOR CURRENT JOB
;CALL: STORE RELOCATION AND PROTECTION FOR LOW SEG IN JOBADR(JOB NUMBER)
; STORE LENGTH-1 AND ABS ORIGIN FOR HIGH SEG IN JBTADR(HIGH SEG NO)
; (MOVE J,JOB NUMBER - IF CALLING SETRL1)
; PUSHJ P,SETREL OR SETRL1
; ALWAYS RETURN, C(J)=JOB NUMBER, C(R)=XWD PROT,RELOC, FOR LOW SEG
INTERN SETREL,SETRL1
EXTERN JBTADR,JBTDAT,JOBREL,JOBENB
EXTERN JBTSGN,JOBHRL,JOBHCU
SETREL: PUSH P,P4 ;SAVE P4
MOVEI P4,.C0CDB ;SET UP CDB POINTER
SKIPA J,.C0JOB## ;CURRENT JOB NUMBER
SETRL1: PUSH P,P4 ;SAVE P4
MOVE R,JBTADR(J) ;XWD PROTECTION,RELOCATION FOR LOW SEG
MOVEM R,.CPADR##(P4) ;SAVE TO MAKE UUO HANDLER FASTER
HLRZM R,.CPREL##(P4) ;SAVE PROTECTION FOR ADDRESS CHECKING
; (HIGHEST LEGAL REL ADDRES FOR CURRENT USER IN LOW SEG)
JUMPN R,SETRLZ ;IF 0 (NULL JOB OR JOB DOING CORE 0 OR KJOB)
; DO NOT STORE IN JOB DATA AREA (SINCE IT WILL BE
; IN EXEC LOWER CORE. ALSO DO NOT STORE
; IN LOC 33, SO CAN SEE LAST REAL USER TO RUN
IFN FTTRPSET,<
SKIPE .CPSTS##(P4) ;IS TIME SHARING STOPPED BY TRPSET UUO?
JRST SETHD1 ;YES, DO NOT CHANGE RELOC FROM REAL TIME JOB
; SO CAN TRAP DIRECTLY TO HIM ON AN INTERRUPT
> ;END FTTRPSET COND
MOVE R,[XWD 777,776400] ;SET HIGH SEG TO POINT AT MONITOR
;WITH WRITE PROTECTION TURNED ON
;NO, SET RELOCATION HARDWARE TO NON-EXIST
; MEMORY, SO IF NULL JOB GETS CLOBBERRED, IT
; WILL GET A NXM INSTEAD OF HURTING MONITOR
; OR A USER.
JRST SETHRD ;DO DATAO
SETRLZ:
HLRZM R,JOBREL(R) ;SET PROTECTION IN USER JOB DATA AREA
; FOR HIM TO LOOK AT
IFN FT2REL,<
;HERE TO ADJUST AC R SO THAT IT HAS PROPER RELOCATION AND PROTECTION
;INFORMATION FOR CURRENT JOB, SO THAT A DATAO APR, R CAN BE DONE.
SETHGH: PUSH P,P1 ;SAVE P1
MOVE P1,JBTSGN##(J) ;HIGH SEG NUMBER
PUSHJ P,HSVAD## ;T1=STARTING ADDR. OF HIGH SEG, T2=
; HIGHEST LEGAL ADDR IN HI-SEG
SKIPGE JOBHCU(R) ;DO NOT STORE IN JOBHRL IF SAVE OR GET IN PROGRESS
JRST NOHGH1 ; BECAUSE IT USES THESE LOCATIONS FOR ZERO COMPRESSION
HRRM T1,JOBHRL(R) ;STORE IN USER AREA SO HE CAN LOOK AT IT.
;LH UNALTERED(HIGHESTREL LOC LOADED+1 BY LOADER)
;0 MEANS NO HIGH SEG
NOHGH1: LSH T1,-12 ;RIGHT JUSTIFY 8 BIT PROTECTION FOR HIG SEG
DPB T1,[POINT 8,R,16] ;STORE IN POSITION FOR DOING DATAO APR,R
;IF NO HIGH SEG, 0 WILL CAUSE FAILURE IF REF
SKIPGE P1 ;IS THIS ASPY SEG?
TDZA T1,T1 ;YES, ABS. ADR OF BEGINNING IS 0
; (P1 HAS HIGHEST PAT ADR USER WANTS
HRRZ T1,JBTADR(P1) ;ABSOLUTE ADR. OF BEG. OF HIGH SEG
SUBI T1,(T2) ;SUBTRACT 400000 OR LENGTH OF LOW SEG(IF GREATER)
LSH T1,-11 ;SHIFT RELOC. FOR HIGH SEG TO POSITION FOR DATAO
ANDI T1,776 ;MASK OUT ALL BUT 8 BITS
IOR R,T1 ;INSERT RELOC AND PROT FOR HIGH SEG IN R
TLO R,UWP ;ASSUME USER-MODE WRITE PROTECT IS ON
TLNE P1,UWPOFF ;HAS USER DONE A SETUWP UUO AND TURNED OFF UWP?
; (AND HAS NOT MEDDLED WITH PROGRAM)
TLZ R,UWP ;YES, SET UWP OFF FOR DATAO
POP P,P1
>
IFE FT2REL,<
TLZ R,1777 ;CLEAR OUT PROTECTION FOR HIGH SEG
; JUST IN CASE THIS IS A 2 REG. MACHINE(EVEN THOGH
; SOFTWARE CANNOT HANDLE 2 SEGS)
>
SETHRD: MOVEM R,.CPDTO##(P4) ;STORE IN LOWER CORE SO IT CAN BE FOUND OUT
; USING SWITCHES WHAT IS IN SECOND REGISTER
; OPTION DOES NOT COME WITH PANEL LIGHTS
; SO NOT STORE 0 FOR NULL JOB SO CAN SEE
; LAST JOB TO RUN IN LOC 33
DATAO APR,R ;SET APR HARDWARE FOR RELOCATION AND PROTECTION
; FOR LOW(AND HIGH SEGS)
SETHD1: SKIPN R,.CPADR##(P4) ;RESTORE R TO XWD PROT,RELOC FOR JUST LOW SEG
; (IS THERE ONE)?
TDZA T1,T1 ;NO, MUST BE NULL JOB OR CORE0 OR KJOB
; SET FOR NO SPECIAL INTERRUPTS TO USER
MOVE T1,JOBENB(R) ;USER APR CONSO FLAGS (THE ONES HE WANTS TO HANDLE
JRST SETAP1 ;DON'T SET UP P4 AGAIN
;ROUTINE TO ENABLE/DISABLE APR FOR TRAPPING TO USER AND EXEC
;CALL: MOVEI T1, APR CONSO FLAGS FOR USER TRAPPING
; PUSHJ P,SETAPR
; RETURN WITH APR RESET AND INTERRUPT LOCATION CONSO'S SET
INTERN SETAPR,SETAP1
SETAPR: PUSH P,P4 ;SAVE P4
MOVEI P4,.C0CDB## ;SET UP CDB INDEX FOR CPU0
SETAP1: AND T1,.CPFO1##(P4)
;MASK OUT ALL BUT PD OVF, ILL MEM, NXM,
; CLOCK, FOV(ONLY PDP-10), AND AROVF CONSO FLAGS
; AND USER ENABLED MEM PARITY (UE.PEF)
; FOV=PC CHANGE ON PDP-6 WHICH IS NEVER ALLOWED
; UNDER TIME SHARING BECAUSE IT TRAPS MONITOR TOO
HRLS T1 ;PRESERVE USER BITS IN LH
TRO T1,AP.POV+AP.NXM+AP.ILM+XP.CLK+AP.ABK
;MAKE SURE MONITOR ALWAYS LOOKING FOR
; PD OVF, ILM, NXM, ADDRESS BREAK CLOCK FLAGS
MOVE T2,T1 ;DUPLICATE BITS IN T2 FOR CONO TO APR.
XOR T2,.CPFO2##(P4) ;COMPLEMENT FOV(PDP-10 ONLY) AND AROV FLAGS
ADDI T2, 330 ;SET DISABLE OR ENABLE FOR EACH
ANDI T2,660 ;MASK OUT ALL BUT DISABLE/ENABLE
; BITS FOR FOV(PDP-10 ONLY) AND AROVF
ADDI T2,@.CPAPI##(P4) ;ADD IN APR PI FOR THIS CPU
; (KI-10 HAS TWO PIS)
CONO PI,PIOFF## ;DISABLE PI'S SO NO INTS. MAY OCCUR WHILE
;CHANGING HARDWARE & SOFTWARE STATE FOR
;APR TRAPPING
HLRM T1,.CPCN1##(P4) ;STORE USER BITS
HRRM T1,.CPCON##(P4) ;STORE EXEC BITS
HRRZM T2,.CPLUC##(P4) ;STORE APR MASK FOR INTERRUPT LEVEL USE
TRO T2,AP.CAO+AP.CFO ;CLEAR POSSIBLE TRAP FLAGS
CONO APR,(T2) ;ENABLE OR DISABLE APR FOR
; FOV(PDP-10 ONLY) AND AR OVF SEPARATELY
CONO PI,PION## ;ENABLE PI'S AGAIN
POP P,P4 ;RESTORE P4
POPJ P,
;ROUTINE TO CAUSE CLK ROUTINE TO RESCHEDULE
;CALLED AT ANY LEVEL
;CALL: PUSHJ P,STOP2
; RETURN IMMEDIATELY EXCEPT IF AT UUO LEVEL
; IF AT UUO LEVEL, RETURN WHEN JOB IS RUNABLE AGAIN
INTERNAL STOP2
STOP2: CONO PI,PIOFF## ;PREVENT CLOCK INTERRUPT DURING STOP2 CODE
SETOM .C0CKF## ;SET FLAG TO INDICATE CLK INTERRUPT
; EVEN THOUGH CLK INTERRUPT IS NOT A TIME INTERRUPT
CONO PI,PICLK## ;TURN PI BACK ON AND REQUEST INTERRUPT TO
; CLK PI CHANNEL(LOWEST PRIORITY CHANNEL)
POPJ P, ;INTERRUPT IMMEDIATELY IF AT UUO LEVEL
SUBTTL CORE1 - CORE ALLOCATION MODULE
;SUBROUTINE TO SWEEP MEMORY TO FIND ADDRESS AND CONTENTS OF BAD WORDS
;IT CALLS CPU INDEPENDENT SUB.(PARERR##) TO RECORD DATA ON EACH BAD WORD
;CALL: MOVE P4,ADR OF CPU DATA BLOCK
; PUSHJ P,@.CPMPS##(P4)
; ALWAYS RETURN WHEN SWEEP OVER (EVEN IF SERIOUS ERROR)
;SWEEP CORE IN ASCENDING ADDRESSES EVEN THOUGH SLOWER, SO DATA STORED ASCENDING
; FOR ERROR REPORTING WITH DAEMON
IFN FTMEMPAR,< ;MEMORY PARITY ANALYSIS
INTERN CPAMPS
CPAMPS: PUSHJ P,SAVE3## ;SAVE P1,P2 FOR BAD ADR, CONTENTS
MOVEI P1,0 ;SCAN ALL OF CORE (INCLUDING ACS IN CASE FAST ACS OFF)
MOVE P3,[POINT 1,NXMTAB##] ;BYTE PTR TO NXMTAB
MPSLOP: CAML P1,MEMSIZ## ;SCANNED ALL OF MEMORY?
POPJ P, ;YES, RETURN
TRNE P1,PG.BDY## ;FIRST WORD OF THIS PAGE?
JRST MPSLP1 ;NO
ILDB T1,P3 ;GET BIT INDICATING WHETHER NXM
JUMPE T1,MPSLP1 ;JUMP IF NOT NXM
ADDI P1,PAGSIZ## ;NON-EXISTANT, SKIP THIS PAGE
JRST MPSLOP ;CHECK NEXT PAGE
MPSLP1:
IFN FTMEMNXM,<
TRNN S,UE.PEF ;NXM RATHER THAN PARITY ERROR?
JRST [CONSO APR,AP.NXM
JRST MPI
CONO APR,AP.CNM
SOJA P1,MPSBD1]
>
CONSZ PI,PI.PAR ;MEMORY PARITY FLAG ON (ONLY IF SWEEP AT APR PI)
JRST [CONO PI,XI.CPE ;CLEAR PARITY FLAG
SOJA P1,MPSBAD] ;DECREMENT SO ADR OF BAD WORD
;SPECIAL INSTRUCTION ADDRESS - REFERENCE MEMORY TO SEE IF BAD
XP CPAMPI,MPI+1 ;PC VALUE WHEN APR GETS PARITY INT.
;USED BY APR PI ROUTINE TO MAKE INSTR. SKIP
MPI: SKIP P2,(P1) ;DOES THIS LOC HAVE BAD PARITY (PICKUP IN P2)?
JFCL ;APR INT ADDS 2 TO PC INCASE THIS IS KI
AOJA P1,MPSLOP ;NO, KEEP LOOKING
;HERE ON BAD PARITY FOUND - APR OR PI 7 (APR INTERRUPT ADDED 2 TO PC)
MPSBAD: MOVEM P2,(P1) ;FIX UP BAD PARITY, SO THAT NUMBER OF BAD
; PARITY WORDS IN MEMORY IS MINIMIZED. THIS
; DECREASES CHANCES OF NOT DETECTING
; READ-PAUSE-WRITE SITUATION (0 ERRORS)
; BECAUSE ANOTHER BAD WORD IS PRESENT
MPSBD1: PUSHJ P,CPAASN ;YES, CONVERT TO SEG NUMBER, (J), REL ADR (T1)
SETOM T1 ;FLAG ABS. ADR NEITHER IN MONITOR NOR A SEGMENT.
PUSHJ P,PARRBD## ;RECORD BAD DATA (T1=REL ADR, P1=BAD ADR,P2=
; BAD CONTENTS)
AOJA P1,MPSLOP ;STEP TO NEXT ABSOLUTE ADDRESS
;SUBROUTINE - ABSOLUTE (ADDRESS TO) SEGMENT NUMBER
;CALL: MOVE P1,ABS.ADR(18 BIT FOR KA-10, 22 BIT FOR KI10)
; PUSHJ P,@CP.ASN(P4)
; ERROR RETURN IF NOT IN MONITOR OR A HIGH OR LOW SEGMENT,
; OK RETURN J=0 IF IN MONITOR, OR HIGH OR LOW SEG, T1=REL. ADR
;CAN BE CALLED AT APR PI OR CLK PI(7)
;NOTE: REL ADR. IS NOT VIRTUAL ADR ON HIGH SEGS
; SINCE THAT IS JOB DEPENDENT IF LOW SEG GR 400000
INTERN CPAASN
CPAASN: MOVEI J,0 ;ASSUME IN MONITOR (JOB 0 NOT LEGAL JOB#)
MOVE T1,P1 ;SET REL. ADR. FROM ABS ADDRESS IN MONITOR
CAMGE P1,SYSSIZ## ;IS ABS ADR IN MONITOR?
JRST CPOPJ1## ;YES, GIVE OK RETURN WITH J=0
MOVEI J,JBTMAX## ;NO, MAX NO. OF JOBS AND HIGH SEGS
;LOOP - SCAN ALL HIGH AND LOW SEGS
ASNLOP: SKIPE T1,JBTADR##(J) ;IS THIS JOB OR HIGH SEG IN CORE?
CAIGE P1,(T1) ;YES, IS ABS. ADR ABOVE SEG ORIGIN?
ASNSOJ: SOJG J,ASNLOP ;NO, LOOK FOR ANOTHER SEG
JUMPLE J,CPOPJ## ;YES, FINISHED SCAN
HLRZ T2,T1 ;PROTECTION - HIGHEST LEGAL REL ADR.
HRRZ T1,T1 ;FORM JUST ORIGIN
SUBM P1,T1 ;REL. ADR=ABS ADR - ORIGIN
CAMLE T1,T2 ;REL ADR LESS THAN OR EQ TO HIGHEST REL ADR?
JRST ASNSOJ ;NO, NOT RIGHT SEG, GO LOOK FOR ANOTHER
JRST CPOPJ1## ;YES, GIVE OK RETURN, J SET TO SEG#, T1=REL. ADR.
> ;END FTMEMPAR
IFN FTMEMNXM,<
;SUBROUTINE TO FIX CORE ALLOCATION TABLE AND VARIABLES AFTER NON-EXISTANT
; MEMORY IS ENCOUNTERED
;CALLING SEQUENCE:
; MAKE NXMTAB REFLECT CURRENT STATE OF MEMORY, GIVE BACK CORE
; BELONGING TO SEGMENTS WHICH OVERLAP NXM, AND
; PUSHJ P,CPANXF ;FIX UP RELEVANT TABLES AND VARIABLES
;RETURNS CPOPJ IF NEW VALUE OF CORMAX .LT. OLD VALUE OF CORMAX (SOME
; JOB MAY BE TOO BIG TO SWAP IN), CPOPJ1 IF ALL IS OK
CPANXF::PUSHJ P,SAVE3## ;SAVE WORKING ACS
MOVE T1,[POINT 2,CORTAB##]
MOVE T2,[POINT 1,NXMTAB##]
CPANX1: ILDB T3,T1 ;BYTE FROM CORTAB
ILDB T4,T2 ;BYTE FROM NXMTAB
JUMPE T4,CPANX2 ;JUMP IF THIS K OF MEMORY EXISTS
CAIN T3,CTNXMI## ;ALREADY MARKED AS NON-EXISTANT?
JRST CPANX2 ;YES, NOTHING TO DO
SKIPE T3 ;IS THIS K OF MEMORY FREE?
STOPCD .,STOP,NPN, ;++NON-EXISTANT K NOT FREE
MOVEI T3,CTNXMI## ;MARK IT AS NON-EXISTANT
DPB T3,T1 ; ..
SOS CORTAL## ;DECREMENT COUNT OF FREE+DORMANT+IDLE K
CPANX2: CAME T1,CORLST## ;LOOKED AT ALL OF MEMORY?
JRST CPANX1 ;NO, CHECK THE NEXT K
;HERE TO UPDATE MEMSIZ, CORLST
MOVEI P3,1 ;SEARCH FOR EXISTANT MEMORY
MOVEI T1,-1 ;FIND THE LARGEST CHUNK
PUSHJ P,HOLSRT ; ..
MOVEI T1,-1(P2) ;ALWAYS NON-SKIP RETURN
PUSHJ P,HOLSRT ;NOW FIND OUT WHERE IT IS
JFCL ; ..
IFN FTLOCK,<
MOVEM T3,HOLEF1## ;STORE THE ADDRESS OF THE LARGEST HOLE
>
ADDI T3,1(T4) ;HIGHEST ADDRESS IN THE LARGEST HOLE
IFN FTLOCK,<
MOVEM T3,HOLTOP## ;REMEMBER THAT
>
PUSH P,P1 ;SAVE THE BYTE POINTER TO THE TOP OF THE HOLE
CPANX3: CAMN P1,CORLST## ;REACHED THE TOP OF CORE WHICH WAS THERE?
JRST CPANX4 ;YES
ILDB T1,P1 ;NEXT BYTE FROM CORTAB
CAIL T1,CTNXMI## ;DOES THIS K EXIST?
JRST CPANX3 ;NO, LOOK AT THE NEXT 1K BLOCK
MOVEM P1,(P) ;YES, SAVE BYTE POINTER TO HIGHEST EXISTANT BLOCK
ADDI T3,PAGSIZ## ;UPDATE HIGHEST ADDRESS IN MEMORY
JRST CPANX3 ;LOOP OVER ALL OF MEMORY
CPANX4: POP P,CORLST## ;SET BYTE POINTER TO HIGHEST EXISTANT BYTE
MOVEM T3,MEMSIZ## ;NEW HIGHEST ADDRESS IN MEMORY + 1
CAML T4,CORMAX## ;TOTAL NUMBER OF PAGES OF EXISTANT MEMORY
; LESS THAN CORMAX?
JRST CORPRM ;NO, ALL JOBS CAN CONTINUE TO RUN
MOVEM T4,CORMAX## ;STORE NEW SMALLER CORMAX
MOVEM T4,MAXMAX## ;AND MAX FOR CORMAX
SOS (P) ;INDICATE THAT SOME JOBS MAY NOT BE ABLE
; TO RUN (THEY MIGHT BE TOO BIG TO SWAP IN)
JRST CORPRM ;GO ADJUST OTHER PARAMETERS AND RETURN
> ;END FTMEMNXM
;ROUTINE TO CHECK JOBS TO SEE IF ANY JOB CAN BE SHUFFLED
;IT IS CALLED EVERY 60TH OF A SECOND BY CLOCK ROUTINE
;PROVIDING CURRENT JOB IS IN USER MODE OR JUST ENTERING
;IO WAIT OR SHARABLE DEVICE WAIT OR RETURNING ON UUO CALLS
;IE CURRENT JOB AND ALL OTHER JOB ARE SHUFFABLE WITH RESPECT
;TO RELOCATION INFO IN MONITOR
;SINCE RESCHEDULING IS NEVER DONE WHEN CURRENT JOB
;IS NOT SHUFFABLE, ALL JOBS ARE SHUFFABLE WHEN
;CHKSHF IS CALLED.
;THE NOSHUFFLE MACRO SHOULD STILL BE USED WHEN EVER
;THE MONITOR MOVES RELOCATION OUT OF ACS P OR R
;IN CASE IT SHOULD PROVE DESIRABLE IN THE FUTURE TO SHUFFLE
;MORE FREQUENTLY THAN AT THE ABOVE TIMES
;FINALLY A JOB MUST HAVE ALL DEVICES INACTIVE(SINCE SOME
;OF THEM USE ABSOLUTE ADDRESSES)BEFORE IT CAN BE MOVED
;SO CORE CANNOT BE REASSIGNED WHILE DEVICES ARE ACTIVE
;IF DEVICES ARE ACTIVE, JOB WILL BE STOPPED SO THAT IO WILL
;CEASE SOON SO JOB CAN BE SHUFFLED
;ALL DEVICES LOOK AT SHF BIT IN JBTSTS(ADVBFF OR ADVBFE)
;TO SEE IF MONITOR IS WAITING TO SHUFFLE JOB
;THE NSHF BIT IN JBTSTS WHOULD BE SET FOR JOBS USING DISPLAYS
;SINCE DISSER CONTINUALLY REFERENCES USER AREA EVEN THOUGH
;IOACT IS OFF.
;THIS VERSION OF THE CORE SHUFFLER WORKS AS FOLLOWS:
;EVERY CLOCK TICK FOR WHICH ALL JOBS ARE SHUFFABLE(NOT COUNTING ACTIVE
;IO DEVICES), THE HIGHEST JOB IN CORE WHICH WILL EXACTLY
;FIT IN THE LOWEST HOLE IN CORE IS MOVED DOWN INTO THE HOLE (TRY TO FIND ONE WITHOUT
;ACTIVE IO DEVICES). IF NONE EXACTLY FIT THE ONE ABOVE THE LOWEST HOLE
;(IF ANY) WILL BE MOVED DOWN INTO HOLE. THE HOLEF IS SET NON-ZERO
;TO THE ADDRESS OF JOB IMMEDIATELY ABOVE THE LOWEST
;HOLE(0 IF NONE), EVERY TIME CORE IS REASSIGNED. HOLES IS SET TO THE SIZE OF THE HOLE.
;CANNOT BE CALLED WHILE SWAPPING IN PROGRESS FOR THIS JOB(BECAUSE IT CALLS CORE0)
INTERN FTSWAP,FTLOCK
EXTERN SHFWAT,HOLEF,JBTADR,JBTSTS,JBTMAX,HOLES
IFN FTLOCK,<
INTERN SHFLOP,CORSTG,CORST0,CORST1,CORST2,DIDLE
>
IFN FTSHFL,< ;SHUFFLER PRESENT?
CHKSHF::SKIPE J,SHFWAT ;HAS CHKSHF STOPPED A JOB AND IS WAITING FOR
; DEVICES TO BECOME INACTIVE?
JRST SHFLOP ;YES, SEE IF IO HAS STOPPED YET
SKIPN HOLEF ;NO, DOES CORE HAVE A HOLE IN IT
POPJ P, ;NO
MOVEI J,JBTMAX ;SEARCH FOR HIGHEST JOB THAT WILL EXACTLY FIT
MOVSI P1,-1 ;TRY TO PICK ONE THATS NOT IN IO WAIT
MOVEI T2,0 ;P1 WILL CONTAIN ADDRESS OF JOB, T2 JOB#
IFN FTLOCK,<
MOVSI T3,NSHF ;LOCKED JOBS ARE NEVER CANDIDATES
>
CHKSH1: HRRZ T1,JBTADR(J) ;T1_ADDRESS OF THIS JOB
MOVE P2,HOLEF ;P2_ADDRESS OF THE HOLE
IFN FTLOCK,<
TDNN T3,JBTSTS(J) ;IS IT LOCKED?
>
CAILE P2,(T1) ;IS JOB BELOW THE HOLE?
JRST CHKSH3 ;YES, CAN'T POSSIBLY FIT
JUMPN T2,CHKSH2 ;DON'T CHECK JOB ABOVE THE HOLE IF ONE ALREADY FOUND
CAIN P2,(T1) ;DEFAULT IS JOB ABOVE THE HOLE
MOVE T2,J ;REMEMBER JOB NUMBER, DON'T KNOW IO STATE
CHKSH2: HLRZ P2,JBTADR(J) ;P2_SIZE OF THIS SEGMENT
CAME P2,HOLES ;SAME SIZE AS HOLE
JRST CHKSH3 ;NO, KEEP LOOKING
MOVE R,JBTDAT(J) ;ANYACT REQUIRES R
PUSHJ P,ANYACT## ;ANY ACTIVE IO DEVICES?
HRROS T1 ;YES, REMEMBER THIS JOB IS IN IO WAIT
CAMG T1,P1 ;HIGHEST SO FAR?
JRST CHKSH3 ;NO, DOESN'T QUALIFY AS BEST CHOICE
HRRO T2,J ;REMEMBER JOB NUMBER AND INDICATE IO STATE KNOWN
MOVE P1,T1 ;SAVE ADDRESS AND IO STATE
CHKSH3: SOJG J,CHKSH1 ;LOOK AT ALL SEGMENTS
MOVEI J,(T2) ;J_0,,JOB#
JUMPG T2,SHFLOP ;NONE FIT EXACTLY, MOVE JOB ABOVE THE HOLE
JUMPE J,CHKSH4 ;NONE FOUND - SYSTEM ERROR OR CORE FRAGMENTED
; BY LOCKED SEGMENTS
JUMPL P1,NOTSHF ;THE ONE THAT FITS IS NOT SHUFFABLE NOW
MOVE R,JBTADR(J) ;SETUP SEGMENT RELOCATION
JRST SHFL ;ONE FITS AND IT CAN BE SHUFFLED
;HERE IF NO SHUFFLABLE JOB WAS FOUND-MEMORY IS FRAGMENTED DUE TO
; LOCKED JOBS OR MEMORY OF LINE
CHKSH4: MOVE T3,HOLEF ;TOP OF THIS HOLE
SETZB T4,HOLEF ;ASSUME NO HOLE AND SETUP TO
PUSHJ P,CORST2 ; CALCULATE A BYTE POINTER TO 1ST K ABOVE HOLE
MOVE P1,T1 ;MOVE BYTE POINTER TO P1 FOR HOLSRP
SETZB T1,P3 ;FIND ANY UNOCCUPIED CORE
PUSHJ P,HOLSRP ;SEARCH FOR A HOLE ABOVE THE CURRENT ONE
POPJ P, ;NONE-RETURN
ADDI T3,1(T4) ;HIGHEST ADDRESS IN THE HOLE
IFN FTLOCK,<
CAMN T3,HOLTOP## ;IS IT AT THE TOP OF UNLOCKED MEMORY?
>
IFE FTLOCK,<
CAMN P1,CORLST ;IS IT AT THE TOP OF MEMORY?
>
POPJ P, ;YES, RETURN
MOVEM T3,HOLEF ;NO, STORE ADDRESS OF TOP OF THE HOLE
MOVEM T4,HOLES ; AND THE SIZE OF THE HOLE
JRST CHKSHF ; AND TRY AGAIN
> ;END SHUFFLER
IFN FTLOCK!FTSHFL,< ;LOCK FEATURE OR SHUFFLER
SHFLOP: SKIPN R,JBTADR(J) ;JOB ABOVE HOLE STILL IN CORE?
JRST NOTSHF ;NO
MOVSI T1,SHF ;GET SHF BIT
IORM T1,JBTSTS(J) ;SET SHF SO JOB IS UN RUNNABLE ON SLAVE
PUSHJ P,ANYACT## ;YES ALL DEVICES FINISHED ?
JRST NOTSHF ;NO, GO SEE IF HOLE STILL THERE
SHFL:
IFN FTMS,< EXTERN ANYRUN
MOVSI T1,SHF ;SET SHF BIT SO SLAVE WILL NOT
IORM T1,JBTSTS(J) ;TRY TO RUN THIS JOB.
PUSHJ P,ANYRUN ;IS SLAVE RUNNING THIS JOB?
JRST NOTSHF ;YES, DO NOT SHUFFLE (SINCE SLAVE HARDWARE
> ; WOULD NOT GET CHANGED.
HLRZ T1,R ;YES, REASSIGN SAME AMOUNT OF CORE.
PUSHJ P,SCORE1## ;IN A LOWER POSITION IN CORE
NOTSH1: SETZM SHFWAT ;JOB SHUFFLED, CLEAR FLAG
MOVSI T1,SHF ;CLEAR SHUFFLE WAIT BIT IN CASE IT WAS ON
ANDCAM T1,JBTSTS(J)
POPJ P,
;JOB CANNOT BE MOVED BECAUSE IT HAS ACTIVE DEVICES OR NSHF BIT SET(DISPLAY,REALTIME)
; SO JOB CANNOT BY SHUFFLED AT THIS TIME
NOTSHF:
SKIPN HOLEF ;IS HOLE STILL THERE?
JRST NOTSH1 ;NO
IFN FTSWAP,<
EXTERN FIT,FORCE
MOVM T1,FORCE
CAME J,FIT
CAMN J,T1
JRST NOTSH1
>
MOVEM J,SHFWAT ;SET SHUFFLE WAIT FLAG WITH JOB NO.
POPJ P, ;AND IO WILL STOP SOON
> ;END LOCK OR SHUFFLER
;HERE TO ASSIGN PHYSICAL CORE IN CORE OR ON THE DISK
INTERN CORE1A,CORGET
CORE1A: NOSCHEDULE ;PREVENT JOB SCHEDULING
PUSHJ P,SAVE1## ;SAVE P1
JUMPE R,CORGET ;OLD ASSIGNMENT 0?
; IF YES, DO NOT ATTEMPT TO RETURN OLD CORE
MOVEI P1,0 ;CLEAR FOR CORSTG CALL
PUSHJ P,CORST0 ;RETURN OLD CORE TO FREE STORAGE
;CORGET IS CALLED BY SWAPPER WHEN JOB IS ON DISC AND IS
;WANTED IN CORE.
CORGET: SETZB T3,R ;SET NEW ASSIGNMENT TO 0 AND DIST. MOVED
JUMPE T1,DIDLE1 ;IS ZERO CORE BEING REQUESTED?
IFN FTLOCK,<
EXTERN SETLPR
PUSHJ P,SETLPR ;IF THIS IS THE JOB BEING LOCKED
JRST CORGT1 ;LET LOCK SPECIFY WHERE TO PUT IT
>
PUSHJ P,HOLSRC ;NO, SEARCH FOR HOLE BIG ENOUGH
JRST BAKOLD ;NONE, GIVE BACK OLD AMOUNT
CORGT1:
INTERN FTTRACK
IFN FTTRACK,<
EXTERN LASCOR
MOVEM J,LASCOR ;LEAVE TRACKS FOR LAST JOB USING
; PHYSICAL CORE ALLOCATION
; (FOR DEBUGGING ONLY)
>
MOVEM T3,R ;SETUP NEW RELOC
HRLM T1,R ;AND NEW PROTECT.
MOVEI T4,(T1) ;HIGHEST REL ADR. BEING REQUESTED
MOVEI P1,1 ;SET USE BITS IN CORE TABLE
INTERN FTLOCK
IFN FTLOCK,<
EXTERN LOCK
HRRZ T2,LOCK ;IF THIS IS THE JOB BEING LOCKED
CAMN T2,J ;INDICATE THAT THE CORE IT OCCUPIES
MOVEI P1,2 ;IS NOT AVAILABLE FOR OTHER JOBS BEING LOCKED
>
PUSHJ P,CORSTG
MOVE T4,JBTADR(J) ;OLD CORE ASSIGNMENT
JUMPN T4,MOVCOR ;WAS THERE OLD MEMORY ASSIGNED?
; NO,
IFN FTSWAP,<
LDB T2,IMGOUT## ;SIZE(IN K) OF SEG ON DISK TO BE SWAPPED IN
LSH T2,P2WLSH## ;CONVERT TO WORDS
>
IFE FTSWAP,<
MOVEI T2,0 ;JOB HAS NO PREVIOUS VIRT. CORE(NON-SWAP SYS)
>
MOVE T4,R ;MAKE OLD ASSIGNMENT(T4) APPEAR TO START
; AT SAME PLACE AS NEW ASSIGNMENT(FOR CLEARING)
SOJA T2,CLRCR1 ;IF NEW CORE SIZE IS BIGGER THAN
;OLD, CLEAR OUT INCREASE SO SECURITY WILL
; BE MAINTAINED. T2 IS SIZE-1 OF OLD
; ASSIGNMENT. -1 OF NO OLD ASSIGNMENT
;HERE WHEN FREE CORE TABLE DOES NOT HAVE ENOUGH ROOM FOR REQUEST
BAKOLD:
IFN FTSWAP,<
EXTERN XPAND
PUSHJ P,XPAND ;TELL SWAPPER TO SWAP OUT
>
IFE FTSWAP,< ;(DO NOT DELETE DORMANT SEGS IF SWAPPING SYSTEM
; SINCE SWAPPER DOES IT TOO)
IFE FT2REL,<
SOS (P) ;SET FOR ERROR RETURN AND GET BACK LD CORE
>
IFN FT2REL,<
EXTERN FRECOR
PUSHJ P,FRECOR ;TRY TO DELETE 1 DORMANT HIGH SEGMENT,
; IF REQUEST DOES NOT EXCEED FREE CORE+DORMANT SEGS
SOSA (P) ;ERROR RETURN-NOT ENOUGH CORE, GET OLD AMOUNT BACK
JRST CORGET ;1 DORMANT SEG DELETED, TRY REQUEST AGAIN
>
>
BKOLD1: HLRZ T1,JBTADR(J) ;GET BACK OLD CORE.
JRST CORGET
;MOVE OLD CORE TO NEW AREA
MOVCOR: CAIN T3,(T4) ;IS NEW CORE IN SAME PLACE AS OLD?
JRST CLRCOR ;YES, DO NOT MOVE IT,CLEAR IF INCREASE
HLRZ T2,T4 ;LENGTH OF OLD CORE
CAILE T2,(T1) ;IS OLD CORE LESS THAN NEW?
HRRZ T2,T1 ;NO, MOVE THE SHORTENED NEW CORE
IFN FTTIME,<
EXTERN SHFWRD
ADDM T2,SHFWRD ;INCREMENT TOTAL NO. WORDS SHUFFLED
>
ADD T2,T3 ;ADD IN NEW RELOC.
MOVE P1,T3 ;DEST.=NEW RELOC.
HRL P1,T4 ;SOURCE=OLD RELOC.
IFN FTMEMPAR,< ;MEMORY PARITY?
;THE FOLLOWING SYMBOLS ARE USED BY THE APR MEMORY PARITY ERROR INTERRUPT
; ROUTINE WHICH HAPPENS AT A HIGH PRIORITY PI LEVEL
INTERN BLTINS ;VALUE OF PC ON PARITY INTERRUPT DURING BLT
MOVEM J,.C0LSB## ;LAST SEG (HI OR LOW) TO BE BLTED
XP BLTAC,P1 ;AC USED AS BLT POINTER - MUL. DEF GLOBAL IF DOES
; NOT AGREE WITH APR INTERRUPT VALUE
BLTINS: ;ADDRESS OF BLT INSTR.
>
BLT P1,(T2) ;MOVE CORE TO NEW ASSIGNMENT
;CLEAR INCREASE IF NEW CORE IS BIGGER THAN OLD
CLRCOR: HLRZ T2,T4 ;OLD CORE SIZE-1
CLRCR1: CAMG T1,T2 ;IS NEW CORE SIZE-1 VREATER THAN OLD CORE SIZE-1
JRST DIDLE ;NO, DO NOT CLEAR ANY CORE
IFN FTTIME,<
MOVE P1,T1 ;NEW CORE SIZE
SUB P1,T2 ;LESS OLD CORE SIZE
ADDM P1,CLRWRD## ;ACCUMULATE NO. OF WORDS CLEARED
>
ADDI T2,2(R) ;YES, OLD SIZE-1+NEW RELOC+2=2ND T3 TO CLEAR
ADDI T1,(R) ;NEW SIZE-1+NEW RELOC=LAST T3 TO CLEAR
SETZM -1(T2) ;CLEAR FIRST WORD
HRLI T2,-1(T2) ;SET LH TO FIRST ADR. TO CLEAR
BLT T2,(T1) ;CLEAR THE INCREASE PORTION
;IF THE SHUFFLED JOB IS IN EXEC MODE, ITS DUMP ACS
;(P,R SAVED IN JOB DATA AREA) MUST BE
;ALTERED BY DISTANCE CORE WAS MOVED
;IF THE SHUFFLED JOB IS CURRENT JOB, THE SOFTWARE STATE OF
;THE MONITOR(IE SOFTWARE INFO OF JOB) MUST BE ALTERED BY AMOUNT
;CORE WAS MOVED
EXTERN SYSSIZ
DIDLE:
IFN FTPDBS,< ;IF WE SWAP PDBS WE MAY HAVE JUST GOTTEN ONE INTO CORE
JUMPL J,DIDLE1 ;NO JOBDATA AREA IN PDB
> ;END FTPDBS
SUBI T3,(T4) ;DISTANCE JOB WAS MOVED(DEST.-SOURCE)
MOVE T1,JOBPC##(R) ;GET PC IN JOB DATA AREA
CAMN J,JOB## ;IS THIS CURRENT JOB?
MOVE T1,USRPC## ;YES, PC IN PROTECTED SYSTEM AREA
IFN FT2REL,<
EXTERN JOBMAX
CAILE J,JOBMAX ;IS THIS A HIGH SEGMENT?
JRST DIDLE1 ;YES. DO NOT ALTER JOBREL
>
EXTERN JOBREL
HLRZM R,JOBREL(R) ;UPDATE JOBREL SO USER DOING E COMMAND AFTER A CORE
; COMMAND WON'T GET CONFUSED
TLNE T1,USRMOD ;NO, IS JOB IN USER MODE?
JRST DIDLE1 ;YES, DO NOT ALTER DUMP ACS
; BECAUSE THEY ARE THE USERS(OR HIGH SEG)
HRRZ T1,JOBDPD##(R) ;NO, CHECK DUMP P TO SEE IF IN EXEC CORE
; (PDL OV) INSTEAD OF USER CORE
CAMG T1,SYSSIZ ;IS IT IN ABS. EXEC CORE?
JRST DIDLE0 ;YES
ADDM T3,JOBDPD##(R) ;NO. ALTER DUMP P BY DIST. OF MOVE
DIDLE0:
ADDM T3,JOBDPG##(R) ;AND ALTER R BY DIST. MOVED
DIDLE1: MOVEM R,JBTADR(J) ;STORE NEW CORE ASSIGNMENT(LOW OR HIGH SEG)
CAME J,JOB## ;IS THIS CURRENT JOB?
JRST DIDLE3 ;NO, DO NOT ALTER STATE OF MONITOR
MOVE T1,SYSSIZ ;DONT CHANGE P IF LIST
CAIG T1,(P) ;IS IN SYSTEM
ADD P,T3 ;YES, ALTER PUSH DOWN POINTER BY AMOUNT OF MOVE
PUSHJ P,SETREL ;GO SETUP NEW HARDWARE AND SOFTWARE RELOCATION
; INFORMATION FOR HIGH AND LOW SEGS FOR CURRENT JOB
DIDLE3:
IFN FT2REL,<
EXTERN CURHGH
PUSHJ P,CURHGH ;CHECK TO SEE IF THIS CORE ASSIGNMENT IS FOR
; HIGH SEG WHICH CURRENT USER MAY ALSO BE USING
; IF YES, RESET HARDWARE AND SOFTWARE RELOC INFO.
; RETURN WITH J PRESERVED, R SET TO RELOC
; OF SEG WHICH HAS JUST HAD CORE REASSIGNED
>
CORPRM: SETZB T1,HOLEF ;CLEAR HOLE FLAG
PUSHJ P,HOLSRC ;IS THERE A NON-ZERO HOLE?
JRST COROK ;NO
ADDI T3,1(T4) ;YES, FORM ADR. OF JOB JUST ABOVE HOLE
CAME P1,CORLST## ;IS HOLE AT TOP OF MEMORY
MOVEM T3,HOLEF ;NO, FLAG WITH ADDRESS OF JOB ABOVE HOLE
MOVEM T4,HOLES ;SAVE THE SIZE OF THE HOLE
IFN FTSWAP,<
EXTERN BIGHOLE
MOVEI T1,-1 ;FIND BIGGEST HOLE
PUSHJ P,CORHOL ;ALWAYS GET ERROR RETURN
ASH P2,W2PLSH## ;CONVERT TO 1K BLOCKS
MOVEM P2,BIGHOLE
>
SCHEDULE
JRST CPOPJ1## ;SKIP RETURN(UNLESS ERROR)
COROK: SETZM HOLES ;NO HOLES IN MEMORY
SETZM BIGHOLE
JRST CPOPJ1## ;SKIP RETURN
;ROUTINE TO FIND HOLE BIG ENOUGH FOR REQUEST
;CALL: MOVE T1,HIGHEST REL. ADR. ASKING FOR
; PUSHJ P,HOLSRC
; RETURN1 ;NO HOLES BIG ENOUGH
; RETURN2 ;P1 BYTE SET TO LAST BLOCK+1 IN HOLE
; ;T3 SET TO ADDRESS OF FIRST BLOCK IN HOLE
; ;T4 SET TO HIGHEST REL. LOC. IN THAT HOLE
; ;P2=LARGEST HOLE SEEN
;USES T2
INTERN HOLSRT,HOLSRP,HOLSRC
HOLSRC: MOVEI P3,0 ;LOOK FOR EMPTY CORE ONLY
HOLSRT: MOVE T3,SYSSIZ ;STARTING AT SYSSIZ
MOVE P1,CORE2P## ;BYTE POINTER TO FIRST BIT-1
HOLSRP:
IFN FTSWAP,<
MOVEI P2,0 ;LARGEST HOLE SO FAR=0
>
CORHOL: TDZA T4,T4 ;START T4 AT 0 AND SKIP
CORHO0: ADDI T4,PAGSIZ## ;INCREMENT HIGHEST REL LOC.
CORHO1: CAMN P1,CORLST## ;BYTE POINTER TO 1ST NON-EXISTANT BLOCK
POPJ P, ;NO MORE CORE TO SEARCH
ILDB T2,P1 ;GET NEXT CORE USE BIT
ADDI T3,PAGSIZ## ;INCREMENT ADDRESS OF BLOCK
CAIN T2,(P3) ;COUNT IT IF ITS THE RIGHT TYPE
JRST CORHO0 ;IT IS
JUMPE T2,CORHO0 ;IS THIS BLOCK IN USE?
JUMPE T4,CORHO1 ;YES, HAVE ANY FREE BLOCKS BEEN SEEN YET?
IFN FTSWAP,<
CAMLE T4,P2 ;YES, BIGGEST SO FAR?
MOVEM T4,P2 ;YES, SAVE IN T1.
>
CAMG T4,T1 ;YES, IS THIS HOLE EQUAL OR GREATER THAN REQUEST?
JRST CORHOL ;NO, KEEP LOOKING FOR HOLES
SUBI T3,PAGSIZ##(T4) ;YES, SET T3 TO FIRST BLOCK IN HOLE
SOJA T4,CPOPJ1 ;SET T4 TO HIGHEST REL. LOC.
; AND RETURN
;ROUTINE TO SET AND CLEAR CORE USE TABLE
;CALL: MOVEI P1,2 ;TO INDICATE LOCKED JOB
; MOVEI P1,1 ;TO INDICATE IN USE
; MOVEI P1,0 ;TO INDICATE FREE
;BIT 33=1 OF P1 IF ONLY A CHANGE OF STATE
; OF ASSIGNED CORE (CORTAL NOT TO BE CHANGED)
; MOVE T3,ADDRESS OF FIRST BLOCK TO SET CLEAR
; MOVE T4,HIGHEST REL. LOC. IN USER AREA
EXTERN TPOPJ
EXTERN CTNBPW,CTNBSA,COREP,CPOPJ
CORST0::HRRZ T3,R ;ABS .ADR OF ORIGIN OF HI OR LOW SEG
HLRZ T4,R ;HIGHEST REL. LOC IN HI OR LOW SEG
CORSTG: ASH T4,W2PLSH## ;CONVERT TO NO. OF BLOCKS-1
ADDI T4,1 ;NO. OF BLOCKS
CORST1:
PUSH P,T1 ;SAVE HIGHEST LOC. BEING REQUESTED
SKIPE P1 ;UPDATE NO OF FREE BLOCKS
MOVNS T4 ;DECREASE IF SETTING BITS
IFN FTLOCK,< ;LOCK UUO FEATURE?
TRNN P1,4 ;IS THIS JUST A CHANGE OF STATE OF ASSIGNED CORE?
; (LOCKED TO UNLOCKED)
>
ADDM T4,CORTAL## ;INCREASE IF CLEARING,DECREASE IF SETTING BITS
CORST2: ;LOKCON MAY ENTER HERE TO COMPUTE A BYTE PTR. IF SO, T4=0
HRRZ T1,T3 ;ADDRESS OF FIRST BLOCK
ASH T1,W2PLSH## ;FORM BYTE POINTER TO BIT-1
IDIVI T1,CTNBPW ;T1=WORD,T2=BIT
ADD T1,COREP ;FORM BYTE POINTER
MOVNS T2
ADDI T2,CTNBPW
ASH T2,CTNBSA ;MULTIPLY BY NUMBER OF BITS PER ENTRY
;MUST BE A POWER OF TWO THAT DIVIDES ^D36
DPB T2,[POINT 6,T1,5]
IFN FTLOCK,<
JUMPE T4,CPOPJ ;RETURN IF BYTE POINTER IS ALL THATS NEEDED
>
MOVMS T4 ;GET MAG. OF NO. OF BLOCKS INVOLVED
IDPB P1,T1 ;SET OR CLEAR EACH USE BIT
SOJG T4,.-1
JRST TPOPJ ;RESTORE T1, AND POPJ
SUBTTL UUOCON - UUO HANDLING ROUTINES
;SUBROUTINE TO DO PROCESSOR DEPENDANT PORTION OF THE JOB PEEK UUO
;CALLING SEQUENCE:
; MOVE T4,JBTADR FOR SOURCE SEGMENT
; MOVE P3,JBTADR FOR DESTINATION SEGMENT
; MOVE P2,NUMBER OF WORDS TO TRANSFER
; PUSHJ P,JOBPKD
; ALWAYS RETURN HERE
IFN FTDAEM,<
INTERN JOBPKD
JOBPKD: HRLZ T2,T4 ;LH T2=ADDR OF SOURCE SEGMENT IN CORE
HRR T2,P3 ;RH T2=ADDR OF DESTINATION SEGMENT IN CORE
ADD T1,T2 ;XWD SOURCE,DESTINATION
ADDI P2,(T1)
BLT T1,-1(P2)
POPJ P,
> ;END IFN FTDAEM
LIT
KAEND: END