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d6dint.mac
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TITLE D6DINT -- UUO AND INTERRUPT SERVICE FOR THE DL10 DN60 SERIES - V014
SUBTTL ED FORTMILLER/EGF and JOHN SAUTER/JBS 3 JAN 84
SEARCH F,S
$RELOC
$HIGH
;THIS SOFTWARE IS FURNISHED UNDER A LICENSE AND MAY ONLY BE USED
; OR COPIED IN ACCORDANCE WITH THE TERMS OF SUCH LICENSE.
;
.CPYRT<
COPYRIGHT (C) 1976,1977,1978,1979,1980,1982,1984 BY DIGITAL EQUIPMENT CORPORATION, MAYNARD, MASS.
>
;
; DATE LOAD EDIT #
; ---- ---- ------
;
;13-JAN-81 70134 010
;12-JAN-82 70126 011
;29-JUN-82 70155 012
;10302
;5-APR-83 70134 013
;3-JAN-84 70173 014
;
XP V6DINT,014 ;VERSION NUMBER
ENTRY D6DINT
D6DINT:
SUBTTL DL10 BYTE POINTER DEFINITION
COMMENT \
0 2 3 5 6 13 14 35
--------------------------------------------------------
I I I I I
I P(3) I S(3) I WORD COUNT(8) I ADDRESS ADR (22) I
I I I I I
--------------------------------------------------------
P Position of byte in the PDP10 word
(except when S=0 OR S=7)
S Size of byte in number of bits
WC Maximum number of PDP-10 words required
for this transfer (in negative form)
ADR Address of indirect PDP-10 word when transfer
is not immediate. Data, when the transfer is immediate,
resides in bits 20 - 35.
S MODE BITS FUNCTION
0 I 16 The byte is put in the right-most 16
bits, 20-35, of the ADR field of
the Byte Pointer itself.
1 NI 16 The byte is in location at a
position determined by the P field. P
is not incremented.
2 NI I 16 The incremented pointer determines the
byte position. This is similar to the
PDP-10 ILDB or IDPB operation and is used
for packing or unpacking characters in
PDP-10 memory. The pointer is incremented
first before packing or unpacking. When
P=7, the P field is reset to 0 and no
increment to the address is performed.
3 NI I 12 Same as S = 2.
4 NI I 8 Same as S = 2.
5 NI I 7 Same as S = 2.
6 NI I 6 Same as S = 2.
7 I 16 Same as S = 0.
I = Immediate
NI = Not Immediate
NI I = Not Immediate incrementing Byte Pointer
\
;D60DSP ROUTINE CALLED BY NETSER THAT DISPATCHES TO THE PROPER FEK FUNCTION
;CALL T1 := FUNCTION CODE
; J := FEK ADDRESS
;RETURN CPOPJ
D60DSP::CAIL T1,FF.ONC ;RANGE CHECK THE FUNCTION
CAILE T1,FF.CPW ; CODE AND STOP IF BAD
STOPCD CPOPJ,DEBUG,BFC,;++ BAD FUNCTION CODE TO FEK
JRST @.+1(T1) ;DISPATCH TO APPRIOATE ROUTINE
JRST CPOPJ## ;ONCE ONLY CODE
JRST D60SEC ;ONCE/SECOND CODE
JRST CPOPJ## ;SET UP A READ REQUEST
JRST CPOPJ## ;SET UP A WRITE REQUEST
JRST CPOPJ## ;CRASH THE FEK (CPU WENT DOWN?)
JRST CPOPJ## ;EXIT PRIMARY PROTOCOL (DTE ONLY)
JRST CPOPJ## ;START PRIMARY PROTOCOL (DTE ONLY)
JRST CPOPJ## ;WE DON'T CARE ABOUT STATION CONTROL
JRST CPOPJ## ;SYSTEM SLEEP. WHAT SHOULD I DO?
JRST CPOPJ## ;SYSTEM WAKE. WHAT SHOULD I DO?
;CALL11 ENTRY VECTOR FOR DL10 BASED DN60
D60CEV::JRST D60UD ;CODE FOR UP/DOWN
JRST D60QU ;CODE FOR QUEUE11
JRST D60ED ;CODE FOR EXAMINE/DEPOSIT
D60SEC: SKIPN W,FEKUNI##(J) ;PICK UP POINTER TO BASE TABLE
POPJ P, ;NONE, DO NOTHING.
PUSHJ P,SAVE1## ;P1 USED FOR WINDOW POINTER
SKIPE P1,DLXWIN##(W) ;POINT P1 TO DL10 WINDOW
XCT DLXSTA##(W) ;MARK -10 AS BEING ALIVE
PUSHJ P,D60TMO## ;CHECK FOR TIME OUTS
POPJ P, ;RETURN
POPJ P, ;RETURN
SUBTTL PDP-11 INTERFACE
;COME HERE WHEN A PDP11 IS FIRST RECOGNIZED AS BEING A DN60 PDP11
;
D60III::MOVE J,DLXWIN##(W) ;POINT TO WINDOW
MOVE T1,DLXMOD##(J) ;PICK UP MOD NUMBER
CAIE T1,D60WVR## ;RIGHT?
STOPCD CPOPJ##,DEBUG,6VI, ;++DN60 WRONG PDP11 CODE
SETOM DLXTA##(J) ;MARK 10 AS ALIVE
SETZM DLXADR##(J) ;CLEAR EXAMINE ADDRESS
SETZM DLXDAT##(J) ;AND EXAMINE DATA
SETZM DLXRST##(J) ;AND RESULT CODE FROM 11
SETZM DLXOPX##(J) ;AND OPERATION CODE FOR 11
SETZM DLXSWD##(J) ;AND EXM/DEP STATUS WORD
MOVE T1,[PUSHJ P,D60KII]
MOVEM T1,DLXINI##(W) ;INTERRUPT INSTRUCTION
MOVE T1,[BYTE (3) 1,1 (8) 377 (4) 0 (18) DLIGTS]
MOVEM T1,DLXLT1##(J) ;POINTER TO LOW IDLE WORD
TLZ T1,(<BYTE (3) 1>) ;SET POSITION TO ZERO
MOVEM T1,DLXLT2##(J) ;POINTER TO HIGH IDLE WORD
MOVE T1,[PUSHJ P,REMPRG ] ;
MOVEM T1,DLXPRG##(W) ;PURGE INSTRUCTION
SETOM DLXTS##(J) ;MARK 10 AS RUNNING
PJRST D60SUP## ;GO FINISH SETUP
SUBTTL HERE WHEN A KNOWN DN60 INTERRUPTS
;HERE WHEN THE DL10 INTERRUPTS
;
D60KII:: ;INTERRUPT ROUTINE
PUSHJ P,SAVE1## ;SAVE P1
HRRZ J,DLXFEK##(W) ;GET FEK ADDRESS
MOVE P1,DLXWIN##(W) ;WINDOW ADDRESS
MOVE T1,DLXSWD##(P1) ;GET THE STATUS WORD FOR EXAMINE/DEPOSIT
ANDCMI T1,D60.ER## ;ZAP THE ERROR BIT
JUMPE T1,IWKJOB ;IF 0 STATUS OR ERROR WAKE THE JOB
SKIPN DLXRST##(P1) ;NOT EXM/DEP SO CHECK RESULT CODE
POPJ P, ;DISMISS THE INTERRUPT
IWKJOB: SKIPE T1,DLXCEU##(W) ;SEE IF JOB USING THE CAL11.
PJRST D60WAK## ;YES, GET JOB OUT OF EW
POPJ P, ;DISMISS THE INTERRUPT
;COME HERE WHEN A DN60 GOES DOWN
;
REMPRG: PUSH P,W ;SAVE W
MOVE W,P2 ;ROUTINES NEED BASE TABLE IN W
SKIPE T1,DLXCEU##(W) ;USER OF THE CAL11 UUO?
PUSHJ P,D60WAK## ;GO WAKE AND UNLOCK HIM IF NECESSARY
SETZM DLXTIM##(W) ;MAKE SURE TIMER IS CLEAR
HRRZ W,DLXFEK##(W) ;GET FEK POINTER
SETZM FEKUNI##(W) ;NO MORE ONCE-A-SECOND CODE
PJRST WPOPJ## ;RESTORE AC(W) AND RETURN TO
; THE CALLER
;HERE TO SEE IF THE PDP-11 IS UP OR DOWN
D60UD: MOVE P1,DLXWIN##(W) ;GET THE WINDOW ADDRESS
SKIPLE DLXDWN##(P1) ;SKIP IF DOWN
AOS (P) ;UP
POPJ P, ;RETURN
;HERE TO EXAMINE OR DEPOSIT PDP11 MEMORY
;
; CALL: JRST D6DED ;J CONTAINS JOB NUMBER
; ;T1 FUNCTION CODE
; ;T3 ADDRESS
; ;T4 DATA TO DEPOSIT
; ;W POINTS TO THE BASE TABLE
;
D60ED: HRRZM J,DLXCEU##(W) ;STORE OUR JOB NUMBER AND INDICATE
; EXM/DEP BY 0 IN THE (LH)
MOVE P1,DLXWIN##(W) ;GET THE WINDOW ADDRESS
MOVEM T3,DLXADR##(P1) ;PUT THE ADDRESS IN THE WINDOW
MOVEM T4,DLXDAT##(P1) ;PUT DATA TO DEPOSIT INTO THE WINDOW
MOVEM T1,DLXSWD##(P1) ;TELL THE PDP11 THE FUNCTION
MOVEI T1,2 ;TIME TO SLEEP WHILE WAITING FOR
; A RESPONSE TO THE EXAMINE OR
; DEPOSIT REQUEST.
PUSHJ P,D60EW ;GO OFF FOR A SNOOZE
HRRZ T1,DLXSWD##(P1) ;GET THE STATUS WORD
SETZM DLXSWD##(P1) ;NOW ZERO IT SO AT INTERRUPT
; LEVEL WHEN DOING A QUE11 WE WON'T
; GET FOOLED BY A BIT SET HERE
TRNE T1,D60.ER## ;SEE IF ERROR BIT UP
PJRST ECOD10## ;**ERROR-10** BECAUSE PDP11 SAID
; ILLEGAL ADDRESS.
PJUMPN T1,ECOD5## ;**ERROR-5** BECAUSE THE PDP11 DIDN'T
; ANSWER OUR DEPOSIT OR EXAMINE REQUEST
SKIPL T1,DLXDAT##(P1) ;GET EXAMINE DATA
; THIS WILL SKIP IF DEPOSIT
PJRST STOTC1## ;GIVE USER SKIP RETURN AND DATA
PJRST CPOPJ1## ;GIVE USER SKIP RETURN
;HERE FROM D60SER TO PERFORM THE DL10 PORTION OF
; THE .C11QU FUNCTION
;
;AC CONTENTS AT THIS TIME
;
; T1 FIRST ADDRESS IN THE BUFFER TO BE USED
; T2 POSITIVE COMPUTED WORD COUNT
; T3 N/A, WILL NOW BECOME A SCRATCH REGISTER
; T4 LENGTH, WILL NOW BECOME A SCRATCH REGISTER
; P2 LINE NUMBER,,DEVICE NUMBER
; P3 START OF BUFFER, WILL NOW BE COUNTER
; OF MAXIMUM BYTE COUNT AND BYTE POINTER ALLOWED
; P4 FUNCTION CODE,,NUMBER OF BYTES
; F POSITION OF FIRST BYTE, WILL NOW CONTAIN
; (BYTE POSITION)- REMAINDER OF (BYTE POSITION)/(BYTE SIZE)
; J JOB NUMBER, WILL NOW CONTAIN INDEX POINTER TO WINDOW
; S BYTE SIZE (THE NUMBER OF BYTES PER WORD)
; U REMAINDER FROM (BYTE POSITION)/(BYTE SIZE)
; W POINTER TO BASE TABLE
;
D60QU: MOVE P1,DLXWIN##(W) ;GET THE WINDOW ADDRESS
HLRZM P2,DLXLNX##(P1) ;STORE THE LINE NUMBER IN THE WINDOW
HRRZM P2,DLXDVX##(P1) ;STORE THE DEVICE NUMBER IN THE WINDOW
MOVE F,S ;COMPUTE (BYTE SIZE)-
SUB F,U ; REMAINDER OF (BYTE POSITION)/(BYTE SIZE)
MOVEI P3,^D15 ;MAXIMUM NUMBER OF BYTE COUNT AND BYTE
; POINTER PAIRS
MOVEI J,DLXCBP##(P1) ;WINDOW POINTER TO COUNT/POINTER PAIRS
QUE11L: MOVE T3,T1 ;GET THE ADDRESS
ANDI T3,777 ;MAKE IT ADDRESS WITHIN A PAGE
MOVEI T4,1000 ;FIGURE MAX NUMBER OF WORDS
SUBM T4,T3 ; THAT CAN BE USED IN THIS PAGE
CAILE T3,^D256 ;IS IT MORE THAN A DL10 CAN HANDLE?
MOVEI T3,^D256 ;YES, SO USE ONLY DL10 MAX
MOVE T4,T3 ;ASSUME RIGHT COUNT IS IN T3
CAMLE T3,T2 ;BUT IS WORD COUNT LESS?
MOVE T4,T2 ;YES, SO USE THE WORD COUNT
SUB T2,T4 ;COUNT-NUMBER OF WORDS FOR THIS POINTER
PUSH P,T1 ;SAVE THE ADDRESS
ADDM T3,(P) ;ADD COUNT TO MAKE NEXT FIRST ADDRESS
;
;TO COMPUTE THE BYTE COUNT
;
; ((WORD COUNT - 1)*(BYTE SIZE))+((BYTE SIZE)-
; (REMAINDER FROM (BYTE POSITION)/(BYTE SIZE)))
;
MOVEI T3,-1(T4) ;WORD COUNT - 1
IMUL T3,S ;MULTIPLY BY BYTE SIZE
ADD T3,F ;SEE DEFINITION OF F ABOVE
CAILE T3,(P4) ;IS COMPUTED BYTE COUNT
; .GT. REMAINING BYTE COUNT?
MOVEI T3,(P4) ;YES, USE REMAINING BYTE COUNT
SUB P4,T3 ;THE REMAINING BYTE COUNT FOR NEXT GO AROUND
MOVEM T3,(J) ;PUT BYTE COUNT IN THE WINDOW
PUSHJ P,MAKPHY ;MAKE USER VIRTUAL ADDRESS
; INTO A 22-BIT PHYSICAL ADDRESS
;
;TO COMPUTE THE DL10 WORD COUNT FROM A
; POSITIVE WORD COUNT
;
; 400 - POSITIVE WORD COUNT
;
MOVEI T3,400 ;MAKE COUNT IN T4 INTO
SUBM T3,T4 ; INTO A DL10 WORD COUNT
LSH T4,^D22 ;POSITION THE WORD COUNT
IOR T1,T4 ;BUILD WORD COUNT INTO DL10 POINTER
DPB S,[POINT 3,T1,5] ;PUT THE BYTE SIZE IN
;
;TO COMPUTE THE DL10 BYTE POSITION FIELD
;
; (BYTE SIZE) - (REMAINDER OF (BYTE POS)/(BYTE SIZE))
; IF RESULT IS 0 MAKE IT 10
; REGARDLESS SUBTRACT 1
;
SUBI U,1 ;MAKE 1 LESS TO POINT TO RIGHT BYTE
; IF WAS 0, IT IS NOW -1 WHICH TURNS
; INTO 7 WHEN SHIFTED LEFT
LSH U,^D33 ;POSITION FOR DL10 POINTER
IOR T1,U ;PUT THE POSITION FIELD IN THE DL10
; BYTE POINTER WORD
SETZ U, ;MAKE 0 FOR NEXT TIME AROUND
; NOW CAUSE WE'RE ALWAYS BEGINNING
; AT THE BEGINNING OF WORD
MOVE F,S ;SAVE AS BYTE SIZE
MOVEM T1,1(J) ;PUT THE BYTE POINTER INTO THE WINDOW
POP P,T1 ;GET THE NEXT ADDRESS
ADDI J,2 ;POINT TO NEXT SPACE IN WINDOW FOR A PAIR
JUMPLE T2,QUE11O ;JUMP IF ALL DONE
SOJG P3,QUE11L ;GO MAKE THE NEXT POINTER
PJRST ECOD11## ;**ERROR-11** BECAUSE OF BUFFER TO LARGE
QUE11O: SETZM (J) ;LAST WORD MUST BE ZERO
SETZM DLXRST##(P1) ;MAKE SURE RESULT CODE IS 0
MOVE J,.CPJOB## ;GET OUR JOB NUMBER
TLO J,D6.Q11## ;INDICATE QUE11 FUNCTION
MOVSI T1,NSHF!NSWP ;NO SHUFFLE AND NO SWAP
TDNE T1,JBTSTS##(J) ;SEE IF ALREADY LOCKED
TLO J,D6.ALK## ;INDICATE ALREADY LOCKED
IORM T1,JBTSTS##(J) ;LOCK THE JOB
MOVEM J,DLXCEU##(W) ;STORE OUR JOB NUMBER
IFN FTKL10,<
PUSHJ P,CSDMP## ;INVALIDATE THE CACHE (THE USERS
; DATA MAY BE IN THE CACHE AND THE
; PDP11 WILL GET DATA FROM REAL
; MEMORY.
>;END IFN FTKL10
HLRZM P4,DLXOPX##(P1) ;TELL THE 11 THE FUNCTION CODE
MOVEI T1,2 ;TIME TO SLEEP WHILE WAITING FOR
; A RESPONSE TO REQUESTED OPERATION
PUSHJ P,D60EW ;GO OFF FOR A SNOOZE
; DLXCEU WILL BE CLEARED UPON RETURN
IFN FTKL10,<
PUSHJ P,CSDMP## ;INVALIDATE THE CACHE
>;END IFN FTKL10
SKIPN T1,DLXRST##(P1) ;SEE IF RESULT CODE FROM THE 11
PJRST ECOD5## ;**ERROR-5** BECAUSE PDP11 DIDN'T RESPOND
HRL T1,DLXXFR##(P1) ;GET NUMBER OF BYTES TRANSFERRED
SETZM DLXRST##(P1) ;CLEAR THE RESULT CODE
PUSHJ P,PUTWD1## ;GIVE THE USER THE RESULT CODE
PJRST CPOPJ1## ; AND SKIP RETURN
;THIS ROUTINE IS CALLED TO WAKE THE PDP11
; AND PUT THE JOB INTO EVENT WAIT
;
; CALL: PUSHJ P,D60EW ;T1 CONTAINS NUMBER OF SECONDS
; ; TILL WE TIME-OUT
; ;W POINTS TO THE BASE TABLE
; RETURN ;ALWAYS WITH DLXCEU CLEAR
;
D60EW: PUSHJ P,D60TIM## ;PUT TIME IN THE BASE TABLE
; THAT WE TIME-OUT AT.
XCT DLXI11##(W) ;TELL PDP11 THAT WE HAVE
; SOMETHING FOR HIM TO DO.
PJRST D60EVW## ;GO WAIT FOR SOMETHING TO HAPPEN
;SUBROUTINE TO CONVERT A USER VIRTUAL ADDRESS INTO
; A 22-BIT PHYSICAL ADDRESS
;
; CALL PUSHJ P,MAKPHY ;T1 CONTAINS THE USER VIRTUAL ADDRESS
; RETURN ;T1 CONTAINS THE 22-BIT PHYSICAL ADDRESS
;
;DOESN'T WORK ON A KI10
MAKPHY: SE1ENT ;ALLOW NON-ZERO SECTION VIRTUAL ADDRESSES
EXCTUX <MAP T1,(T1)> ;GET PHYSICAL ADDRESS
TLZ T1,777760 ;CLEAR JUNK
POPJ P, ;RETURN WITH 22-BIT PHYSICAL ADDRESS IN IT
;LOW SEGMENT STORAGE
$LOW
DLIGTS: EXP -1 ;PDP-10 WORD FOR DL10 IDLE LIGHTS
$HIGH
$LIT
D6DEND::END