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UNIVER GLXMAC -- Parameter File For GLXLIB
SUBTTL /PJT/MLB/DC/PJT 3-Oct-79
;
;
; COPYRIGHT (c) 1975,1976,1977,1978,1979
; DIGITAL EQUIPMENT CORPORATION
;
; 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 WHICH IS NOT SUPPLIED BY
; DIGITAL.
SEARCH GALCNF ;SO WE CAN BE SYSTEM DEPENDENT
SALL ;SUPRESS MACRO EXPANSIONS
DEFINE TOPS10 <IFN FTUUOS,> ;SETUP CONDITIONAL MACROS
DEFINE TOPS20 <IFN FTJSYS,>
TOPS10 <
IF1,<PRINTX Building a GALAXY-10 library>
SEARCH UUOSYM> ;SEARCH PROPER
TOPS20 <
IF1,<PRINTX Building a GALAXY-20 library>
SEARCH MONSYM> ;UNIVERSAL FOR SYSTEM SYMBOLS
IFNDEF GLXVRS,<
IF1,<PRINTX ? Aborting... Must Compile "GLXVER+GLXMAC">
END>
CHKEDT (MAC) ;CHECK OUR EDIT NUMBER
MACEDT==0142 ;EDIT NUMBER
DEFINE VRSN.(PFX),<BYTE (3)PFX'WHO (9)PFX'VER (6)PFX'MIN (18)PFX'EDT>
;THIS FILE CONTAINS SYMBOL AND MACRO DEFINITIONS WHICH ARE COMMON TO
; ALL PROGRAMS DEVELOPED BY THE DECSYSTEM-10/20 SUBSYSTEMS
; GROUP. THESE PROGRAMS INCLUDE AT PRESENT:
;
; 1)ALL GALAXY COMPONENTS
; 2)TPS-20
;
;THIS FILE ALSO ACTS AS THE ADMINISTRATION MODULE FOR OTHER COMMON
; SUBSYSTEMS MODULES AS THEY ARE DEVELOPED.
XP FTUUOS,FTUUOS ;GLOBAL-IZE SYSTEM SWITCHES
XP FTJSYS,FTJSYS ;GOTTEN FROM GALCNF
SUBTTL Table of contents
; TABLE OF CONTENTS FOR GLXMAC
;
;
; SECTION PAGE
; 1. Accumulator Definitions................................... 3
; 2. JUMPx, SKIPx Instruction OPDEFS........................... 4
; 3. ND, XP, EXT, and GLOB Macros.............................. 5
; 4. CONT. LSTOF. LSTON. VRSN. Macro Definitions............... 6
; 5. PROLOG - Uniform assembly set up.......................... 7
; 6. SYSPRM - Set system dependent parameters.................. 8
; 7. MIN and MAX - Find minimum or maximum of vector of values. 8
; 8. LIBVEC - Library run-time system entry vector............. 9
; 9. PG2ADR,ADR2PG Macros...................................... 10
; 10. Standard Constants........................................ 11
; 11. Control Character Symbols................................. 12
; 12. PC WORD Flags............................................. 13
; 13. Field and Mask Macros..................................... 14
; 14. MOVX...................................................... 15
; 15. CAX - COMPARE MACROS...................................... 16
; 16. ADDX, SUBX, IMULX, MULX, IDIVX & DIVX MACROS.............. 17
; 17. TX -- TEST MASK........................................... 18
; 18. SUBFUNCTION MACROS........................................ 21
; 19. DEFSTR -- DEFINE DATA STRUCTURE........................... 22
; 20. STKVAR - STACK VARIABLE FACILITY.......................... 26
; 21. TRVAR - TRANSIENT VARIABLE FACILITY....................... 27
; 22. SAVE MACRO DEFINITION..................................... 29
; 23. LOAD,STORE,INCR,DECR,ZERO................................. 31
; 24. $BGINT,$DEBRK - Interrupt context switching............... 33
; 25. $BUILD,$SET,$EOB - Build pre-formed data blocks........... 34
; 26. $CALL,$RETT,$RETF,$RETE,$RET Uniform Call/Return Mechanisms 35
; 27. $DATA and $GDATA Macros - Runtime System Data Area control 36
; 28. $FATAL, and $WARN Macro definitions....................... 37
; 29. $STOP - Cause a STOP CODE to occur........................ 38
; 30. $TEXT - Interface to the T%TEXT routine................... 39
; 31. $WTO / $WTOJ / $WTOR / $ACK Macros........................ 49
; 32. GALAXY system error codes................................. 50
; 33. Canonical File Information................................ 51
; 34. Canonical Job Information................................. 52
; 35. Scanning and Command Module Symbols....................... 53
; 36. THE MESSAGE HEADER........................................ 56
; 37. ACK - THE GALAXY 'ACK' MESSAGE............................ 57
; 38. JIB - Job Information Block............................... 58
; 39. OBJ - Object Descriptor................................... 59
; 40. OBJCTS MACRO.............................................. 60
; 41. FD - File Descriptor...................................... 61
; 42. FOB - Parameter block passed to F%IOPN and F%OOPN......... 63
; 43. FRB - Parameter block passed to F%REN for renames......... 64
; 44. IB - Initialization Block for GALAXY programs............ 65
; 45. PIB - PID block........................................... 66
; 46. SAB - Send Argument Block passed to C%SEND................ 67
; 47. MDB - Message Descriptor Block returned by C%RECV......... 68
; 48. Special system PIDS....................................... 69
; 49. System Independent IPCF Codes and Constants............... 70
; 50. Program internal parameters of interest................... 71
; 51. $HALT -- Halt a Program without Reset................... 73
; 52. $HALT -- Halt a Program without Reset................... 76
SUBTTL Revision history
COMMENT \
0045 G044 Add new Routines S%TBAD and S%TBDL as well as their
new error codes
0046 Add a new block to the MDB and the supporting code in GLXIPC.
This new block will contain a pointer to the senders account
string when C%RECV is called on the -20.
0047 G045 Add MSKSTR,DEFSTR MACRO Defininitions from MACSYM.
Replaced definitions of LOAD,STORE,INCR,DECR with
Modified definitions from MACSYM.
0050 Cleanup New Macros just added.
0051 Make INCR, DECR, and SAVE Skippable
0052 Define ADDX, SUBX, MULX, DIVX, IMULX and IDIVX
Remove .RET from entry vector and $RET definition
0053 Add .OTIBM object type definitions
0054 Make JXo and JXF skippable
0055 Add $FATAL and $WARN definitions
0056 Add CHK.PM and AVLPAG definitions for GLXMEM
0057 Fix SAVE macro to use library co-routines
0060 Define $CALL $RETT $RETF to use indirect access
to entry vector for non-library components
0061 Add .OTMNT object type definitions
0062 Add indexes to special PID table for Accounting, File DAEMON,
tape labeller.
0063 Change definitions of JUMPT,JUMPF,SKIPT,SKIPF to opdefs
0064 Change definition of Call to do range check and
conditionally do PUSHJ @ if in entry vector
0065 Change ERICA$ to ERARG$
0066 Add New $TEXT Qualifier ^R for Displaying a Job Info Block (JIB)
and add Definitions for the JIB
0067 Add I%HOST call to entry vector
And Define $HALT pseudo instruction for exit without reset.
0070 Make SPIDS MACRO to define special PIDS
0071 Add I%JINF Call to return Job Info on a particular Job
0072 Add S%SIXB Call to convert ASCII to SIXBIT
0073 Remove I%%WTO, Rename I%%WTI to I%%WTO (not released)
0074 Remove I%IWTO,I%WTO,I%SWTO,I%WTO. Rename I%%WTO
(previously I%%WTI) to I%WTO. Leave I%SOPR in.
0075 Reorganize the IB to break out PID information into its own
PID block. Allows for multiple PIDs per program.
Add C%CPID (Create a PID), C%KPID (Kill a PID), C%SPID
(Set default sender PID).
This edit and 0073, 0074 go together and break everyone
who previously $BUILT IBs.
0076 Add .OTBIN and .OTXFR for archiving, file transfer
0077 Remove JX? and PJ? and ASUBR Macro definitions
Move them temporarily to a file called GLXEXT
0100 Change $SET to use DEFSTR and MSKSTR structure definitions
0101 CHANGE JOB IN WTO MACROS TO BE JBN. THUS WE WON'T
CONFLICT WITH WT.JOB (WE'LL BE WT.JBN INSTEAD)
0102 Change op-code names for WTO blocks from WT.xxx to WO.xxx
0103 Change defstr and mskstr to allow them to accept arguments
as GETLIM and STOLIM do.
0104 Change FLD to look exactly like INSVL.
0105 Bump edit by 1 to take up slack in GLXWTO removal
0106 Remove extra CRLF from definition of $TEXT, ITEXT,
$WARN, $FATAL, $STOP
Added Module name printout to $WARN, $FATAL
Defaulted %%.MOD to NONAME before PROLOG macro
0107 Add C%MAXP to get maximum packet small packet size
0110 RESTORE IB.PRG IN THE IB TO CONTAIN THE PROGRAM NAME
0111 Extend DEFSTR and MSKSTR definitions to allow index
specification within LOCN field.
0112 Made C%PIDJ entry point to get Pid Job number
0113 Remove name from $FATAL and $WARN
0114 Define .BGINT in Prolog so Library can use $BGINT
0115 Change $FATAL to use stop code processor
Change $WARN to expand name (again)
Change Proglog to define %%.OTS for library component
tests.
Change Prolog to use GLOB instead of IF2 for vector
expansion.
Change $CALL and $BGINT to define themselves properly
Change $BGINT, $RETT, $RETF and $RETE to define properly
0116 Changed SAVE macro to $SAVE
0117 Change LOAD, STORE, INCR and DECR to skip structure
stuff if called without a possible structure
0120 Changed Prolog to define Library entry points
as Macros to allow the Call/return mechanisms
to become simple OPDEFS
Changed $CALL, $RETT, $RETF to simple OPDEFS
Changed PROLOG to equate entry vector symbols
for GLXINI
0121 Change SZ.OBF and SZ.BUF values for new GLXFIL
0123 Add Support to WTO macros for new Object Type Block
0124 Add new Object type for DBMS queues (.OTDBM)
0125 Install the TRMTYP macro 'for all' terminal types
0126 Change $ACK macro to always turn on WT.SJI
0127 Change DCT.MN from 2 to 1.
0130 -10, Change TRMTYP for VT05 erase EOL sequence to be
37,177,177,177. (It somehow was 377,177,.. no good!)
0131 Add L%APOS to the entry vector.
0132 Change the text description of .OTMNT to from 'Tape-disk
mount' TO 'Device'
0133 Move the PFH into the library on the -10
Redefine $DATA and $GDATA to use PSECTs
Remove pointers from entry vector to PAGTBL.
No longer needed since PFH is in library
Introduce the GLXPURE assembly switch
0134 Make .REQUEST REL:GLXINI so people can find it
0135 Remove edit 134. It seems to be a bad idea
0136 Add code for .MSFLG in the WTO macros
0137 Change PROLOG to define %%.GLX for the module instead of in
GLXINI
0140 Add .NULIO for -10 definitions
0141 Add -10 symbold for .CMTAD
0142 Add PARUNV macros to GLXMAC
\ ;End of Revision History
SUBTTL Accumulator Definitions
;THE FOLLOWING ACCUMULATOR DEFINITIONS ARE STANDARD THROUGHOUT THE
; SUB-SYSTEMS GROUP AND MAY NOT BE CHANGED. THE ACCUMULATORS DEFINED ARE:
TF==0 ;TRUE/FALSE REGISTER, NEVER REFERENCED DIRECTLY
; USED BY $RETx AND JUMPT,JUMPF, SKIPT,SKIPF
.SAC==0 ;SCRATCH AC USED BY SOME NONE SKIPPABLE
;MACROS AND SOME MACRO CALLS TO GLXCOM
;.SAC MAY NOT BE CHANGED ON EXIT FROM A
;CO-ROUTINE SO THAT ANY ROUTINE MAY PASS
;A TRUE FALSE VALUE BACK TO IT'S CALLER.
S1==1 ;S1 & S2 ARE ARGUMENTS TO ROUTINES
S2==2 ;AND ARE OTHERWISE SCRATCH
T1==3 ;T1 - T4 ARE TEMPORARY REGS
T2==4
T3==5
T4==6
P1==7 ;P1 - P4 ARE PRESERVED REGS
P2==10
P3==11
P4==12
.A13==13 ;.A13 THRU .A16 NOT USED BY LIBRARY
.A14==14
.A15==15
.A16==16
.FP==16 ;FRAME POINTER USED BY TRVAR AND ASUBR
;MAY NOT BE CHANGED WITHIN THE SCOPE OF
;A ROUTINE USING TRVAR OR ASUBR
;HOWEVER -- IT IS PRESERVED OUTSIDE THE
;SCOPE OF THESE ROUTINES
P==17 ;PUSHDOWN POINTER
;THERE ARE CO-ROUTINES DEFINED IN GLXCOM TO SAVE AND AUTOMATICALLY
; RESTORE THE "T" AND "P" THAT ARE INVOKED BY THE SAVE MACRO
; CALLED AS FOLLOWS:
; $SAVE <P1,P2,P3,P4> ;TO SAVE P1-P4
; $SAVE <T1,T2,T3,T4> ;TO SAVE T1-T4
; $SAVE <P1> ;TO SAVE P1
; $SAVE <P1,P2,P3> ;TO SAVE P1-P3
; $SAVE <T1,T2> ;TO SAVE T1-T2
; $SAVE <TF,S1> ;TO SAVE TF AND S1 FOR RETURN TO CALLER
; ;AC'S ARE AUTOMATICALLY RESTORED ON RETURN
;AC'S 13,14,15 & 16 ARE AVAILABLE TO THE COMPONENT AND MAY BE USED
; TO ANY END WITH THE NOTEABLE EXCEPTION:
; * * * * N O T E * * * *
; AC16 IS USED AS A FRAME POINTER FOR TRVAR AND ASUBR DYNAMIC
; VARIABLE ALLOCATION. IT MAY NOT BE REFERENCED WITHIN THE
; RANGE OF THE TRVAR OR ASUBR, HOWEVER IT IS PRESERVED ON RETURN
; TO THE CALLER.
;REFER TO GLXLIB.MEM FOR A FULL DESCRIPTION OF MACROS AND AC USAGE
SUBTTL JUMPx, SKIPx Instruction OPDEFS
;All subroutines which follow GALAXY conventions return a "success/failure"
; value in the register TF. This is done by returning via one of
; the return instructions, $RETE, $RETT or $RETF (See next page).
;The value of TRUE or FALSE which a routine returns can be tested with one
;of the following instructions, which alter program flow according to
; the value currently in TF.
; Jump to location specified if TF contains TRUE
OPDEF JUMPT [JUMPN]
; Jump to location specified if TF contains FALSE
OPDEF JUMPF [JUMPE]
; Skip the next instruction if TF contains TRUE
OPDEF SKIPT [SKIPN]
; Skip the next instruction if TF contains FALSE
OPDEF SKIPF [SKIPE]
; PJRST instruction OPDEF
OPDEF PJRST [JRST]
SUBTTL ND, XP, EXT, and GLOB Macros
;Macro to Define a Symbol if not already defined
; ND SYMBOL,VALUE
DEFINE ND(SYM,VAL),<IF2,<IFDEF SYM,<SYM==SYM>> IFNDEF SYM,<SYM==VAL>>
;Macro to Define a Symbol and force it INTERN
; XP SYMBOL,VAL,PRINT
; Where PRINT is any Non-blank to allow printing from DDT
DEFINE XP(SYM,VAL,PRINT),<IFB <PRINT>,<SYM==:VAL> IFNB <PRINT>,<SYM=:VAL>>
;Macro to EXTERN a Symbol if not defined in this routine
; EXT SYMBOL
DEFINE EXT(SYMBOL),<IRP SYMBOL,<
IF2,<IFNDEF SYMBOL,<EXTERN SYMBOL>>>>
;Macro to EXTERN or INTERN a Symbol
; GLOB SYMBOL
DEFINE GLOB(SYMBOL),<IRP SYMBOL,<
IF2,<IFDEF SYMBOL,<.IFN SYMBOL,EXTERN,<INTERN SYMBOL>>
IFNDEF SYMBOL,<EXTERN SYMBOL>
SUPPRES SYMBOL>>>
SUBTTL CONT. LSTOF. LSTON. VRSN. Macro Definitions
;Macro to force page overflow with appropriate comments
DEFINE CONT.(NAME)<LALL
PAGE; (NAME Continued on next page)
SALL; (NAME Continued from previous page)>
;Macros to turn on and off listings with nesting and level control
; LSTOF. ;TURNS OFF LISTINGS ONLY
; LSTOF. XCREF ;TURNS OFF LISTINGS AND CREF
; LSTON. ;RESTORES LISTINGS AND CREF AT TOP LEVEL
;IF LSTIN. IS DEFINED AS .MINFI THEN ALL LISTINGS ARE ON
DEFINE LSTOF.(FOO),<
IFNDEF LSTIN.,LSTIN.==0 ;;INITIALIZE LEVEL COUNTER
IFE LSTIN.,<
IFIDN <XCREF><FOO>,<.XCREF> ;;CONDITIONALLY SUPPRESS CREF
XLIST> ;;TURN OFF LISTINGS
LSTIN.==LSTIN.+1> ;;BUMP LIST LEVEL
DEFINE LSTON.,<
IFG LSTIN.,LSTIN.==LSTIN.-1 ;;DECR LIST LEVEL
IFLE LSTIN.,<.CREF ;;RESUME CREFS
LIST>> ;;RESUME LISTS
;Macro to Generate Standard Version Word
;Assumes PFXWHO, PFXVER, PFXMIN, PFXEDT are defined.
; VRSN. (PFX)
DEFINE VRSN.(PFX),<BYTE (3)PFX'WHO (9)PFX'VER (6)PFX'MIN (18)PFX'EDT>
SUBTTL PROLOG - Uniform assembly set up
;The PROLOG macro is used to uniformly search all the right UNV files
; and setup the listing format and STOP CODE controls.
; The call is : PROLOG(xxxxxx,OTSCOD)
; where the 'xxxxxx' represents the module name,
; and OTSCOD (optional) indicates that this module is part
; of the GALAXY object time system. If present, this code
; should be the module name with the "GLX" taken off, for instance
; PROLOG(GLXIPC,IPC) would be the prolog for module "GLXIPC".
%%.MOD==SIXBIT/NONAME/ ;DEFAULT MODULE NAME BEFORE
; PROGRAM DOES PROLOG
%%.OTS==0 ;DEFAULT OTS CODE TO NULL
;The GLXPURE switch enables the library to be built as either a sharable
; high segment or as a linkable library.
; In the case of the high segment, the entry vector is established,
; and all library data space is allocated in the the DATA .PSECT
; In the case of the linkable library, no entry vector is generated,
; and data space is allocated in-line.
;
;For user programs, the GLXPURE switch controls whether references to
; library routines will be through the entry vector (for the high segment case)
; or simple external references (for linking the library)
IFNDEF GLXPURE,<GLXPURE==-1> ;Default to high segment assembly
; IFNDEF GLXPURE,<GLXPURE==0> ;Or ... default to impure
DEFINE PROLOG(MODULE,OTSCOD)<
SALL
LSTOF. XCREF
TOPS20 <SEARCH MONSYM> ;;LOAD O.S. SYMBOLS
TOPS10 <SEARCH UUOSYM> ;; FOR PROPER OPERATING SYSTEM
IFB <OTSCOD>,<
GLOB <I%INIT>
%%.GLX==:%%.GLX ;;DEFINE THE VERSION IN THE MODULE
;;FOR NON-LIBRARY COMPONENTS
DEFINE $DATA(NAM,SIZ<1>)<
NAM: BLOCK SIZ
>
IFN GLXPURE,<.REQUEST GLXINI ;;GETSEG GLXLIB
DEFINE ..ASGN(A,ADR)<DEFINE A<@^O'ADR>>
>;;END IFN GLXPURE
IFE GLXPURE,<.REQUIRE GLXLIB ;;LINK IN LIBRARY
DEFINE ..ASGN(A,ADDR) <GLOB(A)>
>;;END IFE GLXPURE
>;;END IFB <OTSCOD>
IFNB <OTSCOD>,<
CHKEDT(OTSCOD) ;;CHECK MODULE EDIT LEVEL
IFIDN <OTSCOD><OTS>,<EXTERN .RETT,.RETF>
IFDIF <OTSCOD><INI>,<
IFN GLXPURE,< .PSECT .HIGH.>;;BUILD A HIGH SEGMENT
IFE GLXPURE,<;;IF WE'RE GOING TO BE LINKED IN...
DEFINE $DATA(NAM,SIZ<1>)<
IFNDEF OTSCOD'%D,<OTSCOD'%D::! OTSCOD'%DL==:0>
NAM: BLOCK SIZ
IF1,<OTSCOD'%DL==:OTSCOD'%DL+SIZ>;;Count the length of the data space
>;;END DEFINE $DATA
>;;END IFE GLXPURE
GLOB <IIB> ;;GLOBALIZE IIB for $WARN
DEFINE ..ASGN(A,ADDR) <GLOB(A)>
>;;END IFDIF <OTSCOD><INI>
IFIDN <OTSCOD><INI>,<
DEFINE ..ASGN(A,ADDR) <A=ADDR>
>
>
IFNB <MODULE>,<%%.MOD==SIXBIT/MODULE/> ;;MAKE NAME AVAILABLE
IFNB <OTSCOD>,<%%.OTS==SIXBIT/OTSCOD/> ;;MAKE OTSCODE AVAILABLE
ZZ==VORG
DEFINE CDO (A) <IFNB <A>,<..ASGN(A,\ZZ)>
ZZ==ZZ+1>
LIBVEC
OPDEF $RETT [PJRST .RETT] ;;Pick up proper .RETT/.RETF
OPDEF $RETF [PJRST .RETF]
LSTON. ;;TURN LISTINGS BACK ON
> ;END OF PROLOG DEFINITION
SUBTTL SYSPRM - Set system dependent parameters
;THE SYSPRM MACRO IS USED TO DEFINE A SYMBOL WHOSE VALUE IS DIFFERENT
; DEPENDING ON THE OPERATING SYSTEM WHICH THE PROGRAM IS
; BEING ASSEMBLED FOR.
;
; THE CALL IS:
;
; SYSPRM 'SUBSYSTEM-NAME' , 'TOPS10 VALUE' , 'TOPS20 VALUE'
DEFINE SYSPRM(SYMBOL,UUOS,JSYS),<
IFNB <UUOS>,<TOPS10<SYMBOL==UUOS>>
IFNB <JSYS>,<TOPS20<SYMBOL==JSYS>>
> ;END DEFINE SYSPRM
SUBTTL MIN and MAX - Find minimum or maximum of vector of values
;THE MIN AND MAX MACROS FIND THE MIN OR MAX OF THE ITEMS IN THE FIRST
; ARGUMENT LIST. THE SYMBOL NAMED BY THE SECOND ARGUMENT WILL BE
; DEFINED AS THE MIN OR MAX OF THE LIST. IF THE SECOND ARGUMENT
; IS MISSING, "MINSIZ" OR "MAXSIZ" IS DEFINED.
DEFINE MAX(A,B),<
IFB <B>,<MAXSIZ==0
IRP A,<IFG <A-MAXSIZ>,<MAXSIZ==A>>>
IFNB <B>,<B==0
IRP A,<IFG <A-B>,<B==A>>>
> ;END OF DEFINE MAX
DEFINE MIN(A,B),<
IFB <B>,<MINSIZ==377777,,777777
IRP A,<IFG <MINSIZ-A>,<MINSIZ==A>>>
IFNB <B>,<B==377777,,777777
IRP A,<IFG <B-A>,<B==A>>>
> ;END OF DEFINE MIN
SUBTTL LIBVEC - Library run-time system entry vector
; Each entry in this macro represents a routine or variable that must
; be made available to the OTS itself or to programs using the OTS.
; For OTS programs, each entry is declared EXTERNAL if it does not appear
; in the module itself. For non-OTS code, the symbols are defined as offsets
; in the Library Dispatch vector as absolute symbols. This vector
; lives in GLXOTS
; Each modules entry points are grouped together. In order to allow for
; the addition of new routines for each module, there are blank places
; held open. When a new routine is added, remove one of the blank
; occurrences of "CDO". This will keep the vector straight and allow
; the running of older programs without their re-compilation.
DEFINE LIBVEC <
LSTOF. XCREF
CDO ;;GLXCOM
CDO .ZPAGA
CDO .ZPAGN
CDO .ZCHNK
CDO .SAVE1
CDO .SAVE2
CDO .SAVE3
CDO .SAVE4
CDO .SAVET
CDO .SV13
CDO .SV14
CDO .SV15
CDO .SV16
CDO .RETT
CDO .RETF
CDO .RETE
CDO .AOS ;;USED BY INCR
CDO .SOS ;;USED BY DECR
CDO .ZERO ;;USED BY ZERO
CDO .POPJ
CDO .STOP
CDO .SAVE8 ;;SAVES P1 THRU AC16
CDO .STKST ;;STKVAR SUPPORT CODE
CDO .TRSET ;;TRVAR SUPPORT CODE
CDO ;;OLD ASUBR SUPPORT CODE (REMOVED)
CDO .POPJ ;;OLD .RET (TO BE REMOVED)
CDO
CDO
CDO
CDO
CDO
CDO ;;GLXIPC
CDO C%RPRM
CDO C%INTR
CDO C%SEND
CDO C%RECV
CDO C%BRCV
CDO C%REL
CDO C%CPID
CDO C%KPID
CDO C%SPID
CDO C%MAXP
CDO C%PIDJ
CDO
CDO
CDO
CDO
CDO
CDO ;;GLXFIL
CDO F%IOPN
CDO F%AOPN
CDO F%OOPN
CDO F%IBYT
CDO F%OBYT
CDO F%IBUF
CDO F%OBUF
CDO F%REL
CDO F%DREL
CDO F%RREL
CDO F%REW
CDO F%POS
CDO F%CHKP
CDO F%INFO
CDO F%FD
CDO F%REN
CDO F%DEL
CDO F%FCHN
CDO
CDO
CDO
CDO
CDO
CDO
CDO
CDO
CDO
CDO ;;GLXMEM
CDO M%ACQP
CDO M%RELP
CDO M%IPSN
CDO M%NXPG
CDO M%IPRC
CDO M%IPRM
CDO M%AQNP
CDO M%RLNP
CDO M%CLNC
CDO M%FPGS
CDO M%GMEM
CDO M%RMEM
CDO
CDO
CDO
CDO
CDO
CDO
CDO M%GPAG
CDO M%RPAG
CDO
CDO
CDO
CDO
CDO
CDO
CDO
CDO
CDO ;;GLXTXT
CDO T%TEXT
CDO T%TTY
CDO
CDO
CDO
CDO
CDO
CDO
CDO
CDO
CDO
CDO
CDO ;;GLXLNK
CDO L%CLST
CDO L%DLST
CDO L%CENT
CDO L%CBFR
CDO L%DENT
CDO L%NEXT
CDO L%FIRS
CDO L%LAST
CDO L%PREV
CDO L%PREM
CDO L%CURR
CDO L%RENT
CDO L%SIZE
CDO L%APOS
CDO
CDO
CDO
CDO
CDO
CDO
CDO
CDO
CDO I%INI1 ;;GLXINT
CDO I%NOW
CDO I%EXIT
CDO I%ION
CDO I%IOFF
CDO I%SLP
CDO I%INT1
CDO I%INT2
CDO I%INT3
CDO
CDO
CDO
CDO I%SOPR
CDO I%WTO
CDO
CDO I%HOST
CDO I%JINF
CDO
CDO
CDO ;;GLXSCN
CDO
CDO
CDO S%SIXB
CDO S%CMND
CDO S%TBLK
CDO S%SCMP
CDO S%ERR
CDO S%INTR
CDO S%EXIT
CDO S%TBAD
CDO S%TBDL
CDO
CDO K%RCOC ;;GLXKBD
CDO K%WCOC
CDO K%SUET
CDO K%STYP
CDO K%TXTI
CDO K%SOUT
CDO K%BOUT
CDO K%BIN
CDO K%BACK
CDO K%TPOS
CDO
CDO
CDO
CDO
LSTON.
> ;END OF LIBVEC DEFINITION
SUBTTL PG2ADR,ADR2PG Macros
DEFINE PG2ADR(AC),<LSH AC,^D9>
DEFINE ADR2PG(AC),<LSH AC,-^D9>
SUBTTL Standard Constants
.INFIN==:377777,,777777 ;PLUS INFINITY
.MINFI==:1B0 ;MINUS INFINITY
LHMASK==:777777B17 ;LEFT HALF
RHMASK==:777777 ;RIGHT HALF
FWMASK==:-1 ;FULL WORD
; BYTE POINTER PARTS
BP.POS==77B5 ;POSITION (BITS TO THE RIGHT)
BP.SIZ==77B11 ;SIZE OF BYTE
BP.ADR==Z -1 ;ADDRESS PORTION
; DEFINE UNIVERSAL TRUE AND FALSE CONSTANTS
FALSE==0
TRUE=-1
; MEMORY CONSTANTS
PAGSIZ==^D512 ;SIZE OF ONE PAGE
MEMSIZ==^D512 ;PAGES IN THE ADDRESS SPACE
; DEBUGGING CONSTANTS
SYSPRM DDTADR,.JBDDT,770000 ;LOCATION CONTAINING START OF DDT
SYSPRM DEBUGW,.JBOPS,135 ;SPECIAL "DEBUGGING" WORD
SUBTTL Control Character Symbols
.CHNUL==:000 ;NULL
.CHCNA==:001
.CHCNB==:002
.CHCNC==:003
.CHCND==:004
.CHCNE==:005
.CHCNF==:006
.CHBEL==:007 ;BELL
.CHBSP==:010 ;BACKSPACE
.CHTAB==:011 ;TAB
.CHLFD==:012 ;LINE-FEED
.CHVTB==:013 ;VERTICAL TAB
.CHFFD==:014 ;FORM FEED
.CHCRT==:015 ;CARRIAGE RETURN
.CHCNN==:016
.CHCNO==:017
.CHCNP==:020
.CHCNQ==:021
.CHCNR==:022
.CHCNS==:023
.CHCNT==:024
.CHCNU==:025
.CHCNV==:026
.CHCNW==:027
.CHCNX==:030
.CHCNY==:031
.CHCNZ==:032
.CHESC==:033 ;ESCAPE
.CHCBS==:034 ;CONTROL BACK SLASH
.CHCRB==:035 ;CONTROL RIGHT BRACKET
.CHCCF==:036 ;CONTROL CIRCONFLEX
.CHCUN==:037 ;CONTROL UNDERLINE
.CHALT==:175 ;OLD ALTMODE
.CHAL2==:176 ;ALTERNATE OLD ALTMODE
.CHDEL==:177 ;DELETE
SUBTTL PC WORD Flags
;PC FLAGS
PC%OVF==:1B0 ;OVERFLOW
PC%CY0==:1B1 ;CARRY 0
PC%CY1==:1B2 ;CARRY 1
PC%FOV==:1B3 ;FLOATING OVERFLOW
PC%BIS==:1B4 ;BYTE INCREMENT SUPPRESSION
PC%USR==:1B5 ;USER MODE
PC%UIO==:1B6 ;USER IOT MODE
PC%LIP==:1B7 ;LAST INSTRUCTION PUBLIC
PC%AFI==:1B8 ;ADDRESS FAILURE INHIBIT
PC%ATN==:3B10 ;APR TRAP NUMBER
PC%FUF==:1B11 ;FLOATING UNDERFLOW
PC%NDV==:1B12 ;NO DIVIDE
SUBTTL Field and Mask Macros
;STANDARD MACROS
;MACROS TO HANDLE FIELD MASKS
;COMPUTE LENGTH OF MASK, I.E. LENGTH OF LEFTMOST STRING OF ONES
;REMEMBER THAT ^L DOES 'JFFO', I.E. HAS VALUE OF FIRST ONE BIT IN WORD
;COMPUTE WIDTH OF MASK, I.E. LENGTH OF LEFTMOST STRING OF ONES
DEFINE WID(MASK)<<^L<-<<MASK>_<^L<MASK>>>-1>>>
;COMPUTE POSITION OF MASK, I.E. BIT POSITION OF RIGHTMOST ONE IN MASK
DEFINE POS(MASK)<<^L<<MASK>&<-<MASK>>>>>
;CONSTRUCT BYTE POINTER TO MASK
DEFINE POINTR(LOC,MASK)<<POINT WID(MASK),LOC,POS(MASK)>>
;PUT RIGHT-JUSTIFIED VALUE INTO FIELD SPECIFIED BY MASK
DEFINE FLD(VALUE,MASK),<<<<VALUE>B<POS(<MASK>)>>&<MASK>>>
;MAKE VALUE BE RIGHT JUSTIFIED IN WORD.
DEFINE .RTJST(VAL,MSK)<<VAL>B<^D70-POS(MSK)>>
;CONSTRUCT MASK FROM BIT AA TO BIT BB. I.E. MASKB 0,8 = 777B8
DEFINE MASKB (AA,BB)<1B<<AA>-1>-1B<BB>>
;MODULE - GIVES REMAINDER OF DEND DIVIDED BY DSOR
DEFINE MOD. (DEND,DSOR)<<DEND-<DEND/DSOR>*DSOR>>
;OLD STYLE MACTEN TYPE CALLS
;MACRO TO BUILD A MASK "WID" BITS WIDE, WITH ITS RIGHTMOST BIT
; IN THE BIT POSITION "POS".
DEFINE MASK.(WID,POS),<<<<1_<WID>>-1>B<POS>>>
;INVSL. POSITIONS VALUE IN MASK TO BE REPLACED BY FLD(VALUE,MASK)
DEFINE INSVL.(VALUE,MASK),<<<<VALUE>B<POS(<MASK>)>>&<MASK>>>
SUBTTL MOVX
;MOVX - LOAD AC WITH CONSTANT
DEFINE MOVX (AC,MSK)<
..MX1==MSK ;;EVAL EXPRESSION IF ANY
IFDEF .PSECT,<
.IFN ..MX1,ABSOLUTE,<
MOVE AC,[MSK]>
.IF ..MX1,ABSOLUTE,<
..MX2==0 ;;FLAG SAYS HAVEN'T DONE IT YET
IFE <..MX1>B53,<
..MX2==1
MOVEI AC,..MX1> ;;LH 0, DO AS RH
IFE ..MX2,< ;;IF HAVEN'T DONE IT YET,
IFE <..MX1>B17,<
..MX2==1
MOVSI AC,(..MX1)>> ;;RH 0, DO AS LH
IFE ..MX2,< ;;IF HAVEN'T DONE IT YET,
IFE <<..MX1>B53-^O777777>,<
..MX2==1
HRROI AC,<..MX1>>> ;;LH -1
IFE ..MX2,< ;;IF HAVEN'T DONE IT YET,
IFE <<..MX1>B17-^O777777B17>,<
..MX2==1
HRLOI AC,(..MX1-^O777777)>> ;;RH -1
IFE ..MX2,< ;;IF STILL HAVEN'T DONE IT,
MOVE AC,[..MX1]> ;;GIVE UP AND USE LITERAL
>>
IFNDEF .PSECT,<
..MX2==0 ;;FLAG SAYS HAVEN'T DONE IT YET
IFE <..MX1>B53,<
..MX2==1
MOVEI AC,..MX1> ;;LH 0, DO AS RH
IFE ..MX2,< ;;IF HAVEN'T DONE IT YET,
IFE <..MX1>B17,<
..MX2==1
MOVSI AC,(..MX1)>> ;;RH 0, DO AS LH
IFE ..MX2,< ;;IF HAVEN'T DONE IT YET,
IFE <<..MX1>B53-^O777777>,<
..MX2==1
HRROI AC,<..MX1>>> ;;LH -1
IFE ..MX2,< ;;IF HAVEN'T DONE IT YET,
IFE <<..MX1>B17-^O777777B17>,<
..MX2==1
HRLOI AC,(..MX1-^O777777)>> ;;RH -1
IFE ..MX2,< ;;IF STILL HAVEN'T DONE IT,
MOVE AC,[..MX1]> ;;GIVE UP AND USE LITERAL
>
PURGE ..MX1,..MX2>
SUBTTL CAX - COMPARE MACROS
;CREATE THE CAX MACRO DEFINITIONS
DEFINE ..DOCX (T)<
IRP T,<
DEFINE CAX'T (AC,MSK)<
..CX(T,AC,MSK)>>>
..DOCX (<,L,LE,E,G,GE,N,A>) ;DO 8 DEFINITIONS
PURGE ..DOCX
DEFINE ..CX(T,AC,MSK)<
..CX1==MSK
IFDEF .PSECT,<
.IFN ..CX1,ABSOLUTE,<
CAM'T AC,[MSK]>
.IF ..CX1,ABSOLUTE,< ;;MASK IS TESTABLE
..CX2==0 ;;MARK NOT DONE
IFE <..CX1&^O777777B17>,<
..CX2==1 ;;LH 0 CAN DO CAI
CAI'T AC,MSK>
IFE ..CX2,< ;;MUST USE CAM
CAM'T AC,[MSK]>
PURGE ..CX1,..CX2>>
IFNDEF .PSECT,<
..CX2==0 ;;MARK NOT DONE
IFE <..CX1&^O777777B17>,<
..CX2==1 ;;LH 0 CAN USE CAI
CAI'T AC,MSK>
IFE ..CX2,< ;;MUST USE CAM
CAM'T AC,[MSK]>
PURGE ..CX1,..CX2>>
SUBTTL ADDX, SUBX, IMULX, MULX, IDIVX & DIVX MACROS
;ALL MACROS JUST CALL ..AS OR ..OP WHICH DO ALL THE WORK
DEFINE ADDX(AC,VAL) <..AS(AC,VAL,ADD,SUB)>
DEFINE SUBX(AC,VAL) <..AS(AC,VAL,SUB,ADD)>
DEFINE IMULX(AC,VAL) <..OP(AC,VAL,IMUL)>
DEFINE MULX(AC,VAL) <..OP(AC,VAL,MUL)>
DEFINE IDIVX(AC,VAL) <..OP(AC,VAL,IDIV)>
DEFINE DIVX(AC,VAL) <..OP(AC,VAL,DIV)>
DEFINE ..AS(AC,VAL,OPR,ALT)<
..AS1==-<VAL> ;;GET COMPLIMENT OF VALUE
IFDEF .PSECT,<
.IFN ..AS1,ABSOLUTE,<
OPR AC,[-..AS1]> ;;MUST USE LITERAL
.IF ..AS1,ABSOLUTE,<
..AS2==0 ;;MARK NOT DONE
IFE <..AS1&^O777777B17>,<
..AS2==1 ;;CAN USE ALTERNATE IMMEDIATE
ALT'I AC,..AS1>
IFE ..AS2,<
..OP(AC,VAL,OPR)> ;;MUST DO IMMEDIATE OR LITERAL
PURGE ..AS1,..AS2>>
IFNDEF .PSECT,<
..AS2==0 ;;MARK NOT DONE
IFE <..AS1&^O777777B17>,<
..AS2==1 ;;CAN DO ALTERNATE IMMEDIATE
ALT'I AC,..AS1>
IFE ..AS2,< ;;MUST DO IMMEDIATE OR LITERAL
..OP(AC,VAL,OPR)>
PURGE ..AS1,..AS2>>
DEFINE ..OP(AC,VAL,OPR)<
..OP1==VAL
IFDEF .PSECT,<
.IFN ..OP1,ABSOLUTE,<
OPR AC,[..OP1]>
.IF ..OP1,ABSOLUTE,< ;;MASK IS TESTABLE
..OP2==0 ;;MARK NOT DONE
IFE <..OP1&^O777777B17>,<
..OP2==1 ;;LH 0 CAN DO IMMEDIATE
OPR'I AC,..OP1>
IFE ..OP2,< ;;MUST USE LITERAL
OPR AC,[..OP1]>
PURGE ..OP1,..OP2>>
IFNDEF .PSECT,<
..OP2==0 ;;MARK NOT DONE
IFE <..OP1&^O777777B17>,<
..OP2==1 ;;LH 0 CAN USE IMMEDIATE
OPR'I AC,..OP1>
IFE ..OP2,< ;;MUST USE LITERAL
OPR AC,[..OP1]>
PURGE ..OP1,..OP2>>
SUBTTL TX -- TEST MASK
;CREATE THE TX MACRO DEFINITIONS
;THIS DOUBLE IRP CAUSES ALL COMBINATIONS OF MODIFICATION AND TESTING
;TO BE DEFINED
DEFINE ..DOTX (M,T)<
IRP M,<
IRP T,<
DEFINE TX'M'T (AC,MSK)<
..TX(M'T,AC,<MSK>)>>>>
..DOTX (<N,O,Z,C>,<,E,N,A>) ;DO ALL DEFINITIONS
PURGE ..DOTX
;..TX
;ALL TX MACROS JUST CALL ..TX WHICH DOES ALL THE WORK
DEFINE ..TX(MT,AC,MSK)<
..TX1==MSK ;;EVAL EXPRESSION IF ANY
IFDEF .PSECT,<
.IFN ..TX1,ABSOLUTE,<
TD'MT AC,[MSK]>
.IF ..TX1,ABSOLUTE,< ;;MASK MUST BE TESTABLE
..TX2==0 ;;FLAG SAYS HAVEN'T DONE IT YET
IFE <..TX1&^O777777B17>,<
..TX2==1 ;;LH 0, DO AS RH
TR'MT AC,..TX1>
IFE ..TX2,< ;;IF HAVEN'T DONE IT YET,
IFE <..TX1&^O777777>,<
..TX2==1 ;;RH 0, DO AS LH
TL'MT AC,(..TX1)>>
IFE ..TX2,< ;;IF HAVEN'T DONE IT YET,
IFE <<..TX1>B53-^O777777>,< ;;IF LH ALL ONES,
..TX3 (MT,AC)>> ;;TRY Z,O,C SPECIAL CASES
IFE ..TX2,< ;;IF STILL HAVEN'T DONE IT,
TD'MT AC,[..TX1]> ;;MUST GIVE UP AND USE LITERAL
PURGE ..TX1,..TX2>>
IFNDEF .PSECT,<
..TX2==0 ;;FLAG SAYS HAVEN'T DONE IT YET
IFE <..TX1&^O777777B17>,<
..TX2==1 ;;LH 0, DO AS RH
TR'MT AC,..TX1>
IFE ..TX2,< ;;IF HAVEN'T DONE IT YET,
IFE <..TX1&^O777777>,<
..TX2==1 ;;RH 0, DO AS LH
TL'MT AC,(..TX1)>>
IFE ..TX2,< ;;IF HAVEN'T DONE IT YET,
IFE <<..TX1>B53-^O777777>,< ;;IF LH ALL ONES,
..TX3 (MT,AC)>> ;;TRY Z,O,C SPECIAL CASES
IFE ..TX2,< ;;IF STILL HAVEN'T DONE IT,
TD'MT AC,[..TX1]> ;;MUST GIVE UP AND USE LITERAL
PURGE ..TX1,..TX2>>
;SPECIAL CASE FOR LH ALL ONES
DEFINE ..TX3 (MT,AC)<
IFIDN <MT><Z>,< ;;IF ZEROING WANTED
..TX2==1
ANDI AC,^-..TX1> ;;CAN DO IT WITH ANDI
IFIDN <MT><O>,< ;;IF SET TO ONES WANTED
..TX2==1
ORCMI AC,^-..TX1> ;;CAN DO IT WITH IORCM
IFIDN <MT><C>,< ;;IF COMPLEMENT WANTED
..TX2==1
EQVI AC,^-..TX1>> ;;CAN DO IT WITH EQV
;VARIENT MNEMONICS FOR TX DEFINITIONS
DEFINE IORX (AC,MSK)<
TXO AC,<MSK>>
DEFINE ANDX (AC,MSK)<
TXZ AC,<^-<MSK>>>
DEFINE XORX (AC,MSK)<
TXC AC,<MSK>>
SUBTTL SUBFUNCTION MACROS
;.IF0 CONDITION, ACTION IF CONDITION 0, ACTION OTHERWISE
DEFINE .IF0 (COND,THEN,ELSE)<
..IFT==COND ;;GET LOCAL VALUE FOR CONDITION
IFE ..IFT,<
THEN
..IFT==0> ;;RESTORE IN CASE CHANGED BY NESTED .IF0
IFN ..IFT,<
ELSE>>
;CASE (NUMBER,<FIRST,SECOND,...,NTH>)
DEFINE .CASE (NUM,LIST)<
..CSN==NUM
..CSC==0
IRP LIST,<
IFE ..CSN-..CSC,<
STOPI
..CAS1 (LIST)>
..CSC==..CSC+1>>
DEFINE ..CAS1 (LIST)<
LIST>
;TEST FOR FULL WORD, RH, LH, OR ARBITRARY BYTE
DEFINE ..TSIZ (SYM,MSK)<
SYM==3 ;;ASSUME BYTE UNLESS...
IFE <MSK>+1,<SYM=0> ;;FULL WORD IF MASK IS -1
IFE <MSK>-^O777777,<SYM==1> ;;RH IF MASK IS 777777
IFE <MSK>-^O777777B17,<SYM==2>> ;;LH IF MAST IS 777777,,0
;TEST FOR LOC BEING AN AC -- SET SYM TO 1 IF AC, 0 IF NOT AC
DEFINE ..TSAC (SYM,LOC)<
IFNDEF .PSECT,<
SYM==0 ;;ASSUME NOT AC UNLESS...
..TSA1==<Z LOC> ;;LOOK AT LOC
IFE ..TSA1&^O777777777760,<SYM==1> ;;AC IF VALUE IS 0-17
>
IFDEF .PSECT,<
SYM==0 ;;ASSUME NOT AC UNLESS...
..TSA1==<Z LOC> ;;LOOK AT LOC
.IF ..TSA1,ABSOLUTE,< ;;SEE IF WE CAN TEST VALUE
IFE ..TSA1&^O777777777760,<SYM==1>> ;;AC IF VALUE IS 0-17
PURGE ..TSA1>>
;FUNCTION TO TEST FOR MASK CONTAINING EXACTLY ONE BIT. RETURNS
;1 IFF LEFTMOST BIT AND RIGHTMOST BIT ARE SAME
DEFINE ..ONEB (SYM,MSK)<
SYM==<<<-<MSK>>&<MSK>>&<1B<^L<MSK>>>>>
SUBTTL DEFSTR -- DEFINE DATA STRUCTURE
;DEFINE DATA STRUCTURE
; NAM - NAME OF STRUCTURE AS USED IN CODE
; LOCN - ADDRESS OF DATA
; POS - POSITION OF DATA WITHIN WORD (RIGHTMOST BIT NUMBER)
; SIZ - SIZE OF DATA (IN BITS) WITHIN WORD
DEFINE DEFSTR (NAM,LOCN,POS,SIZ)<
NAM==<-1B<POS>+1B<POS-SIZ>> ;;ASSIGN SYMBOL TO HOLD MASK
IF1,<IFDEF %'NAM,<PRINTX ?NAM ALREADY DEFINED>>
DEFINE %'NAM (OP,AC,Y,MSK)< ;;DEFINE MACRO TO HOLD LOCATION
IFDIF <Y><>,<
OP (<AC>,LOCN'+'Y,MSK)>
IFIDN <Y><>,<
OP (<AC>,LOCN''Y,MSK)>>>
;ALTERNATE FORM OF DEFSTR -- TAKES MASK INSTEAD OF POS,SIZ
DEFINE MSKSTR (NAM,LOCN,MASK)<
NAM==MASK ;;ASSIGN SYMBOL TO HOLD MASK
IF1,<IFDEF %'NAM,<PRINTX ?NAM ALREADY DEFINED>>
DEFINE %'NAM (OP,AC,Y,MSK)< ;;DEFINE MACRO TO HOLD LOCATION
IFDIF <Y><>,<
OP (<AC>,LOCN'+'Y,MSK)>
IFIDN <Y><>,<
OP (<AC>,LOCN''Y,MSK)>>>
;..STR0 - PROCESS INSTANCE OF STRUCTURE USAGE, SINGLE STRUCTURE CASE.
DEFINE ..STR0 (OP,AC,STR,Y)<
IFNDEF STR,<PRINTX STR IS NOT DEFINED
OP (<AC>,Y,FWMASK)> ;;RESERVE A WORD, ASSUME WORD MASK
IFDEF STR,<
IFNDEF %'STR,<
OP (<AC>,Y,STR)> ;;ASSUME NO OTHER LOCN
IFDEF %'STR,<
%'STR (OP,<AC>,Y,STR)>>> ;;DO IT
;..STR1, ..STR2, ..STR3, AND ..STR4 ARE INTERNAL MACROS FOR PROCESSING
;INSTANCES OF STRUCTURE USAGE.
DEFINE ..STR1 (OP,AC,STR,Y,CLL)<
..NS==0 ;;INIT COUNT OF STR'S
IRP STR,<..NS=..NS+1> ;;COUNT STR'S
IFE ..NS,<PRINTX ?EMPTY STRUCTURE LIST, OP>
IFE ..NS-1,< ;;THE ONE CASE, CAN DO FAST
..STR0 (OP,<AC>,<STR>,Y)>
IFG ..NS-1,< ;;MORE THAN ONE, DO GENERAL CASE
..ICNS ;;INIT REMOTE MACRO
..CNS (<CLL (OP,<AC>,,>) ;;CONS ON CALL AND FIRST ARGS
IRP STR,< ;;DO ALL NAMES IN LIST
IFNDEF STR,<PRINTX STR NOT DEFINED>
IFDEF STR,<
IFNDEF %'STR,<
..CNS (<,STR,Y>)> ;;ASSUME NO OTHER LOCN
IFDEF %'STR,<
%'STR (..STR2,,Y,STR)> ;;STR MACRO WILL GIVE LOCN TO ..STR2
..CNS (<)>) ;;CLOSE ARG LIST
..GCNS ;;DO THIS AND PREVIOUS NAME
..ICNS ;;REINIT CONS
..CNS (<CLL (OP,<AC>>) ;;PUT ON FIRST ARGS
IFNDEF %'STR,<
..CNS (<,STR,Y>)> ;;ASSUME NO OTHER LOCN
IFDEF %'STR,<
%'STR (..STR2,,Y,STR)>>> ;;PUT ON THIS ARG, END IRP
..CNS (<,,)>) ;;CLOSE ARG LIST
..GCNS>> ;;DO LAST CALL
;..STR2 -- CALLED BY ABOVE TO APPEND STRUCTURE NAME AND LOC TO ARG LIST
DEFINE ..STR2 (AA,LOC,STR)<
..CNS (<,STR,LOC>)> ;;CONS ON NEXT ARG PAIR
;..STR3 -- CHECK FOR ALL STRUCTURES IN SAME REGISTER
DEFINE ..STR3 (OP,AC,S1,L1,S2,L2)<
IFDIF <L1><L2>,<
IFNB <L1>,<
OP (<AC>,L1,..MSK) ;;DO ACCUMULATED STUFF
IFNB <L2>,<PRINTX S1 AND S2 ARE IN DIFFERENT WORDS>>
..MSK==0> ;;INIT MASK
IFNB <L2>,<
..MSK=..MSK!<S2>>>
;..STR4 -- COMPARE SUCCESSIVE ITEMS, DO SEPARATE OPERATION IF
;DIFFERENT WORDS ENCOUNTERED
DEFINE ..STR4 (OP,AC,S1,L1,S2,L2)<
IFDIF <L1><L2>,< ;;IF THIS DIFFERENT FROM PREVIOUS
IFNB <L1>,<
OP (<AC>,L1,..MSK)> ;;DO PREVIOUS
..MSK==0> ;;REINIT MASK
IFNB <L2>,<
..MSK=..MSK!<S2>>> ;;ACCUMULATE MASK
;..STR5 - SAME AS ..STR4 EXCEPT GIVES EXTRA ARG IF MORE STUFF TO
;FOLLOW.
DEFINE ..STR5 (OP,AC,S1,L1,S2,L2)<
IFDIF <L1><L2>,< ;;IF THIS DIFFERENT FROM PREVIOUS,
IFNB <L1>,<
IFNB <L2>,< ;;IF MORE TO COME,
OP'1 (AC,L1,..MSK)> ;;DO VERSION 1
IFB <L2>,< ;;IF NO MORE,
OP'2 (AC,L1,..MSK)>> ;;DO VERSION 2
..MSK==0> ;;REINIT MASK
IFNB <L2>,<
..MSK=..MSK!<S2>>> ;;ACCUMULATE MASK
;'REMOTE' MACROS USED TO BUILD UP ARG LIST
;INITIALIZE CONS -- DEFINES CONS
DEFINE ..ICNS <
DEFINE ..CNS (ARG)<
..CNS2 <ARG>,>
DEFINE ..CNS2 (NEW,OLD)<
DEFINE ..CNS (ARG)<
..CNS2 <ARG>,<OLD'NEW>>>
>
;GET CONS -- EXECUTE STRING ACCUMULATED
DEFINE ..GCNS <
DEFINE ..CNS2 (NEW,OLD)<
OLD> ;;MAKE ..CNS2 DO THE STUFF
..CNS ()> ;;GET ..CNS2 CALLED WITH THE STUFF
SUBTTL STKVAR - STACK VARIABLE FACILITY
;MACRO FOR ALLOCATING VARIABLES ON THE STACK. ITS ARGUMENT IS
;A LIST OF ITEMS. EACH ITEM MAY BE:
; 1. A SINGLE VARIABLE WHICH WILL BE ALLOCATED ONE WORD
; 2. A VARIABLE AND SIZE PARAMETER WRITTEN AS <VAR,SIZ>. THE
; VARIABLE WILL BE ALLOCATED THE SPECIFIED NUMBER OF WORDS.
;RETURN FROM A SUBROUTINE USING THIS FACILITY MUST BE VIA
;RET OR RETSKP. A DUMMY RETURN WHICH FIXES UP THE STACK IS PUT ON
;THE STACK AT THE POINT THE STKVAR IS ENCOUNTERED.
;WITHIN THE RANGE OF A STKVAR, PUSH/POP CANNOT BE USED AS THEY WILL
;CAUSE THE VARIABLES (WHICH ARE DEFINED AS RELATIVE STACK LOCATIONS)
;TO REFERENCE THE WRONG PLACE.
;TYPICAL USE: STKVAR <AA,BB,<QQ,5>,ZZ>
DEFINE STKVAR (ARGS)<
..STKR==10 ;;REMEMBER RADIX
RADIX 8
..STKN==0
IRP ARGS,<
.STKV1 (ARGS)>
JSP .SAC,.STKST
..STKN,,..STKN
RADIX ..STKR
PURGE ..STKN,..STKR,..STKQ
>
;INTERMEDIATE MACRO TO PEAL OFF ANGLEBRACKETS IF ANY
DEFINE .STKV1 (ARG)<
.STKV2 (ARG)>
;INTERMEDIATE MACRO TO CALCULATE OFFSET AND COUNT VARIABLES
DEFINE .STKV2 (VAR,SIZ)<
IFB <SIZ>,<..STKN==..STKN+1>
IFNB <SIZ>,<..STKN==..STKN+SIZ>
..STKQ==..STKN+1
.STKV3 (VAR,\..STKQ)>
;INNERMOST MACRO TO DEFINE VARIABLE
DEFINE .STKV3 (VAR,LOC)<
IFDEF VAR,<.IF VAR,SYMBOL,<PRINTX STKVAR VAR ALREADY DEFINED>>
DEFINE VAR<-^O'LOC(P)>
$'VAR==<Z VAR>> ;SYMBOL FOR DDT
SUBTTL TRVAR - TRANSIENT VARIABLE FACILITY
;TRANSIENT (STACK) VARIABLE FACILITY - EQUIVALENT TO STKVAR
;EXCEPT ALLOWS VARIABLES TO BE USED WITHIN LOWER LEVEL ROUTINES
;AND AFTER OTHER THINGS HAVE BEEN PUSHED ON STACK.
;N.B. USES .FP AS FRAME POINTER - MUST NOT BE CHANGED WHILE
;VARIABLES IN USE.
DEFINE TRVAR (VARS)<
..TRR==10 ;;REMEMBER CURRENT RADIX
RADIX 8
..NV==1 ;;INIT COUNT OF STACK WORDS
IRP VARS,<
.TRV1 (VARS)> ;;PROCESS LIST
JSP .SAC,.TRSET ;;ALLOCATE STACK SPACE, SETUP .FP
..NV-1,,..NV-1
RADIX ..TRR ;;RESTORE RADIX
PURGE ..TRR,..NV> ;;CLEAN UP
DEFINE .TRV1 (VAR)<
.TRV2 (VAR)> ;;PEEL OFF ANGLEBRACKETS IF ANY
DEFINE .TRV2 (NAM,SIZ)<
.TRV3 (NAM,\..NV) ;;DEFINE VARIABLE
IFB <SIZ>,<..NV=..NV+1>
IFNB <SIZ>,<..NV=..NV+SIZ>>
DEFINE .TRV3 (NAM,LOC)<
IFDEF NAM,<.IF NAM,SYMBOL,<PRINTX TRVAR NAM ALREADY DEFINED>>
DEFINE NAM<^O'LOC(.FP)>
$'NAM==<Z NAM>> ;;SYMBOL FOR DDT
;AC VARIABLE FACILITY
.FPAC==P1 ;FIRST PRESERVED AC
.NPAC==10 ;NUMBER OF PRESERVED AC'S
DEFINE ACVAR (LIST)<
..NAC==0 ;;INIT NUMBER OF ACS USED
IRP LIST,<
.ACV1 (LIST)> ;;PROCESS ITEMS
.ACV3 (\..NAC)> ;;SAVE ACS USED
DEFINE .ACV1 (ITEM)<
.ACV2 (ITEM)> ;;PEEL OFF ANGLEBRACKETS IF ANY
DEFINE .ACV2 (NAM,SIZ)<
NAM=.FPAC+..NAC ;;DEFINE VARIABLE
IFB <SIZ>,<..NAC=..NAC+1>
IFNB <SIZ>,<..NAC=..NAC+SIZ>>
DEFINE .ACV3 (N)<
IFG N-.NPAC,<PRINTX ?TOO MANY ACS USED>
IFLE N-4,<
$CALL .SAVE'N> ;;SAVE ACTUAL NUMBER USED
IFG N-4,<
$CALL .SAVE8>> ;;SAVE ALL
SUBTTL SAVE MACRO DEFINITION
;VARIABLE SAVE FACILITY -- ACCEPTS A LIST OF ARGUMENTS
; $SAVE <LIST-OF-VARIABLES>
;AUTOMATICALLY RESTORES ALL NAMED VARIABLES ON RETURN FROM ROUTINE
; SUPPORTS +1 OR +2 RETURNS
;IF AN APPROPRIATE CO-ROUTINE IS DEFINED IN GLXCOM FOR THE DESIRED
;AC'S IT IS USED, OTHERWISE OPEN PUSHES AND A DUMMY RESTORE ROUTINE
;ARE GENERATED.
;IF THE SAME SET OF VARIABLES IS SAVED MORE THAN ONCE IN A PROGRAM,
;THE RESTORE ROUTINE GENERATED IN THE LITERALS IS SHARED BETWEEN THE
;TWO SAVES.
DEFINE SAVE (ARG) <PRINTX % Replacing SAVE with $SAVE
$SAVE <ARG>>
DEFINE $SAVE(ARG,%L1)<
.NVR==0 ;;INITILIZE VARIABLE COUNT
.ACM==0 ;;INITIALIZE AC MASK
IRP ARG,< ;;BUILD AC MASK AND PUSH OTHER VARIABLES
..TSAC(.ACB,ARG) ;;IS IT AN AC?
IFN .ACB,<.ACM==.ACM!1B<ARG>> ;;YES -- BUILD MASK
IFE .ACB,< ;;NO -- PUSH IT
IFE .NVR,< ;;FIRST VARIABLE?
CAIA ;;YES -- DO SKIP CODE
LSTOF.
JRST %L1>
..PUSH(ARG,\<.NVR+1>)>> ;;PUSH IT AND BUMP COUNT
IFN .ACM,< ;;CHECK FOR PROPER AC CO-ROUTINE
IFE <.ACM-17B<T4>>,<.ACM==0
$CALL .SAVET>
IFE <.ACM-377B<.A16>>,<.ACM==0
$CALL .SAVE8>
IFE <.ACM-17B<P4>>,<.ACM==0
$CALL .SAVE4>
IFE <.ACM-7B<P3>>,<.ACM==0
$CALL .SAVE3>
IFE .NVR,< ;;DON'T DO CO-ROUTINE IF OTHER VARIABLES
IFE <.ACM-3B<P2>>,<.ACM==0
$CALL .SAVE2>
IFE <.ACM-1B<P1>>,<.ACM==0
$CALL .SAVE1>
IFE <.ACM-1B<.A13>>,<.ACM==0
$CALL .SV13>
IFE <.ACM-1B<.A14>>,<.ACM==0
$CALL .SV14>
IFE <.ACM-1B<.A15>>,<.ACM==0
$CALL .SV15>
IFE <.ACM-1B<.A16>>,<.ACM==0
$CALL .SV16>
>>
;;SAVE IS CONITINUED ON NEXT PAGE
;;SAVE MACRO CONTINUED FROM PREVIOUS PAGE
IFN .ACM,< ;;PUSH THE AC'S IF NOT DONE BY CO-ROUTINE
IFE .NVR,< ;;FIRST ONE?
CAIA ;;YES -- DO SKIP CODE
LSTOF.
JRST %L1>
.ACB==0 ;;START AT AC0
REPEAT ^D16,< ;;LOOP THRU ALL 16
IFN <.ACM&1B<.ACB>>,< ;;WAS IT GIVEN?
..PUSH(\.ACB,\<.NVR+1>)>;;YES -- PUSH IT
.ACB==.ACB+1>> ;;STEP TO NEXT
IFN .NVR,< ;;BUILD DUMMY ROUTINE TO RESTORE ALL PUSHES
PUSH P,[[CAIA ;;HERE FOR NON SKIP RETURN
AOS -.NVR(P) ;;HANDLE SKIP RETURN
REPEAT .NVR,<..POP(\.NVR)> ;;POP ALL THINGS STACKED
POPJ P,0]]> ;;RETURN TO CALLER
LSTON.
%L1: SUPPRESS %L1>
DEFINE ..PUSH(ARG,.NVX)<
PUSH P,ARG
.NV'.NVX==ARG
.NVR==.NVR+1>
DEFINE ..POP(.NVX)<
POP P,.NV'.NVX
PURGE .NV'.NVX
.NVR==.NVR-1>
SUBTTL LOAD,STORE,INCR,DECR,ZERO
DEFINE LOAD (AC,Y,STR)<
IFNB <STR>,<..STR0 (..LDB,AC,STR,Y)>
IFB <STR>,<MOVE AC,Y>> ;;DEFAULT TO FULL WORD MOVE
DEFINE ..LDB (AC,LOC,MSK)<
..TSIZ (..PST,MSK)
.CASE ..PST,<<
MOVE AC,LOC>,<
HRRZ AC,LOC>,<
HLRZ AC,LOC>,<
LDB AC,[POINTR (LOC,MSK)]>>>
DEFINE STORE (AC,Y,STR)<
IFNB <STR>,<..STR0 (..DPB,AC,STR,Y)>
IFB <STR>,<MOVEM AC,Y>> ;;DEFAULT FULL WORD MOVE
DEFINE ..DPB (AC,LOC,MSK)<
..TSIZ (..PST,MSK)
.CASE ..PST,<<
MOVEM AC,LOC>,<
HRRM AC,LOC>,<
HRLM AC,LOC>,<
DPB AC,[POINTR (LOC,MSK)]>>>
DEFINE INCR (Y,STR)<
IFNB <STR>,<..STR0 (.INCR0,,<STR>,Y)>
IFB <STR>,<AOS Y>> ;;DEFAULT FULL WORD INCR
DEFINE .INCR0 (AC,LOC,MSK)<
..PST==MSK-FWMASK
.IF0 ..PST,<
AOS LOC>,< ;;FULL WORD, CAN USE AOS
$CALL .AOS ;;MUST USE SUPPORT CODE
LSTOF.
JUMP [POINTR(LOC,MSK)]
LSTON.>>
DEFINE DECR (Y,STR)<
IFNB <STR>,<..STR0 (.DECR0,,<STR>,Y)>
IFB <STR>,<SOS Y>> ;;DEFAULT FULL WORD DECR
DEFINE .DECR0 (AC,LOC,MSK)<
..PST==MSK-FWMASK
.IF0 ..PST,<
SOS LOC>,< ;;FULL WORD, CAN USE SOS
$CALL .SOS ;;MUST USE SUPPORT CODE
LSTOF.
JUMP [POINTR(LOC,MSK)]
LSTON.>>
DEFINE ZERO (Y,STR)<
IFNB <STR>,<..STR1 (..TQZ,,<STR>,Y,..STR4)>
IFB <STR>,<SETZM Y>> ;;DEFAULT FULL WORD ZERO
DEFINE ..TQZ (AC,LOC,MSK)<
..TSIZ (..PST,MSK) ;;SET ..PST TO CASE NUMBER
.CASE ..PST,<<
SETZM LOC>,< ;;FULL WORD
HLLZS LOC>,< ;;RH
HRRZS LOC>,< ;;LH
..TSAC (..ACT,LOC) ;;SEE IF LOC IS AC
.IF0 ..ACT,<
$CALL .ZERO ;;NO -- MUST USE SUPPORT CODE
LSTOF.
JUMP [POINTR(LOC,MSK)]
LSTON.>,<
..TX (Z,LOC,MSK)>>>>
SUBTTL $BGINT,$DEBRK - Interrupt context switching
;At the beginning of each interrupt level routine, the first instruction
; is a $BGINT, with the address field indicating which priority level
; this interrupt is on. When the interrupt is over, the $DEBRK instruction
; is used, which resumes non-interrupt level context and dismisses the
; interrupt. Interrupt context gives all ACs and a new Stack for use.
;Establish interrupt level context
DEFINE $BGINT(LVL)<
IFG LVL-INT.LV,<PRINTX ?Level LVL interrupts not supported>
.BGINT.(\LVL) > ;;END OF $BGINT DEFINITION
DEFINE .BGINT.(A)<JSR I%INT'A>
;Return to normal (non-interrupt) level
DEFINE $DEBRK<
$RET ;WILL INVOKE RIGHT ROUTINE
> ;END OF $DEBRK DEFINITION
SUBTTL $BUILD,$SET,$EOB - Build pre-formed data blocks
;Many components have a need to build simple and complex blocks which
; contain pre-formatted data, such as FOBs,IBs and other blocks
; which are made up of several words, each containing from 1 to several
; fields. Since data structures change, these blocks should not be
; just created using EXP or whatever. These macros will take values
; and install them in the right field and word of a structure.
; Start off a structure, argument is the size of the structure.
DEFINE $BUILD(SIZE)<
IFDEF ..BSIZ,<PRINTX ?Missing $EOB after a $BUILD>
..BSIZ==0 ;;START COUNTER
..BLOC==. ;;REMEMBER OUR STARTING ADDRESS
REPEAT SIZE,< ;;FOR EACH WORD IN THE BLOCK
BLD0.(\..BSIZ,0) ;;ZERO OUT IT'S ACCUMULATOR
..BSIZ==..BSIZ+1> ;;AND STEP TO NEXT
>;END OF $BUILD DEFINITION
; For each value installed somewhere in the structure, set it into the block
; Arguments are word offset,field in word (optional) and value to set.
DEFINE $SET(OFFSET,STR,VALUE),<
IFNDEF ..BSIZ,<PRINTX ?$SET without previous $BUILD>
IFNB <STR>,<..STR0 (..SET,<VALUE>,STR,OFFSET)>
IFB <STR>,<..STR0 (..SET,<VALUE>,FWMASK,OFFSET)>
> ; END OF $SET DEFINITION
DEFINE ..SET (VALUE,LOC,MSK) <
IFGE <<<LOC>&777777>-..BSIZ>,<
PRINTX ?WORD offset greater than $BUILD size parameter>
SET0. (\<LOC>,MSK,<VALUE>)
> ;END ..SET DEFINITION
; After all values are declared, the block must be closed to do its actual
; creation.
DEFINE $EOB,<
IFNDEF ..BSIZ,<PRINTX ?$EOB without previous $BUILD>
IFN <.-..BLOC>,<PRINTX ?Address change between $BUILD and $EOB>
LSTOF. ;;DON'T SHOW THE BLOCK
..T==0
REPEAT ..BSIZ,<
BLD0.(\..T,1) ;;STORE EACH WORD
..T==..T+1 >
PURGE ..BSIZ,..T,..BLOC ;;REMOVE SYMBOLS
LSTON.
>; END OF $EOB DEFINITION
DEFINE BLD0.(N,WHAT),<
IFE WHAT,<..T'N==0>
IFN WHAT,<EXP ..T'N
PURGE ..T'N>
> ;END OF BLD0. DEFINITION
DEFINE SET0.(LOC,MSK,VALUE),<
IFN <<..T'LOC>&MSK>,<PRINTX ?Initial field not zero in $SET>
..TVAL==<VALUE>
..TMSK==<MSK>
..T'LOC==..T'LOC!<FLD(..TVAL,..TMSK)>
PURGE ..TVAL,..TMSK
>;END OF SET0. DEFINITION
SUBTTL $CALL,$RETT,$RETF,$RETE,$RET Uniform Call/Return Mechanisms
; All routines which follow GALAXY Conventions should call
; library routines and internal routines which return TRUE/FALSE
; values with the $CALL Macro. This provides a uniform calling
; mechanism.
; All routines which follow GALAXY conventions should return
; via one of the return instructions. These instructions set the contents
; of the true/false register, TF and then return via POPJ P,.
; If a routine wishes to merely pass on the value of the TF register
; it should return using a $RET
OPDEF $CALL [PUSHJ P,0]
; $RETE is the instruction used to return FALSE from a routine and also
; set a specific error code in the first status register, S1. The argument
; provided to the instruction is a 3 letter GLXLIB canonical error code.
; The effect of the $RETE instruction is to place the value of the
; GLXLIB error code into S1, place FALSE into TF and return via POPJ.
DEFINE $RETE (COD) <
JSP TF,.RETE ;;GO TO SUPPORT COD
LSTOF.
JUMP ER'COD'$
LSTON.> ;;END OF $RETE DEFINITION
;$RETT is the instruction used to place a value of TRUE into the TF register
; and return from the routine. This instruction is used when a routine
; wishes to indicate to its caller that it is returning successfully.
; $RETT is defined during the PROLOG macro
; OPDEF $RETT PJRST .RETT]
;$RETF is the instruction used to place a value of FALSE into the TF register
; and return from the routine. This instruction is used when a routine
; wishes to indicate to its caller that is returning unsuccessfully.
; $RETF is defined during the PROLOG macro
; OPDEF $RETF [PJRST .RETF]
;$RET is the instruction used to return the last value of TF to the caller
OPDEF $RET [POPJ P,] ;;RETURN CURRENT VALUE OF TF
SUBTTL $DATA and $GDATA Macros - Runtime System Data Area control
;This macro is used to define impure storage areas. The actual
;areas are created at run-time by the memory manager. The first argument
; is the name of the word(s) to be allocated. This name may be referenced
; as any other labelled location. The second argument is the number of
; words to allocate. If omitted, this defaults to 1.
;In order to facilitate debugging of new library routines, the $DATA and
; $GDATA macros produce BLOCK pseudo-op type locations when used
; in a module whose PROLOG indicates it is not part of the library.
; This means that a new library module may be loaded with a test program
; as a non-library piece of code while it is being debugged.
DEFINE $DATA(NAM,SIZ<1>)<
.PSECT DATA
NAM: BLOCK SIZ
.ENDPS
> ;END OF $DATA DEFINITION
; $GDATA is exactly like $DATA, except that the location defined
; is GLOBAL, that is, available to other programs.
DEFINE $GDATA(NAM,SIZ<1>)<
INTERN NAM
$DATA(NAM,<SIZ>)
> ;END OF $GDATA DEFINITION
SUBTTL $FATAL, and $WARN Macro definitions
;$FATAL is provided as a short form STOP code. It should
;be used when it is impossible to proceed because
;the program doesn't have proper priviledges or can't find a required
;file -- or any other occassion where the full stopcode information
;is irrelevant or misleading
;CALL $FATAL <any valid $TEXT string argument>
;
DEFINE $FATAL (STRING) <
$CALL .STOP
LSTOF.
JUMP [XWD 0,[ITEXT (<STRING>)]
EXP %%.MOD]
LSTON. > ;END OF $FATAL DEFINITION
;$WARN May be used when it is desired to issue a warning on the
;users terminal.
;CALL $WARN <any valid $TEXT string argument>
;
DEFINE $WARN (STRING) <
IFE %%.OTS,<DEFINE $WARN (MSG) <
$TEXT (T%TTY,<% ^W6/[%%.MOD]/ MSG>)>>
IFN %%.OTS,<DEFINE $WARN (MSG) <
$TEXT (T%TTY,<% ^W6/IIB+IB.PRG/ ^W/[%%.MOD]/ MSG>)>>
$WARN <STRING>> ;END OF $WARN DEFINITION
SUBTTL $STOP - Cause a STOP CODE to occur
; The $STOP macro generates a call to the .STOP routine in GLXCOM,
; which processes the information imbedded in the $STOP parameter
; area. Modules using the $STOP macro should begin with a PROLOG
; to set up the module name symbol %%.MOD or should define this
; symbol separately.
;For each $STOP there is a unique label made, using the 3 letter
; code provided. The label is 'S..xxx' where the xxx is the 3 letter
; code. This label is declared global, to insure unique STOP
; CODE names.
;The macro call is:
; $STOP(CODE,STRING)
;WHERE CODE = A UNIQUE 3 CHARACTER INDICATION OF THE STOP CODE
; AND
;STRING IS AN EXPANDED STRING ASSOCIATED WITH THE ERROR CONDITION
; I.E.: $STOP(NFP,No free pages)
; WILL EXPAND TO: PUSHJ P,.STOP
; JUMP [XWD 'NFP',[ITEXT (No free pages)]
; EXP %%.MOD ]
DEFINE $STOP(CODE,STRING),<
S..'CODE::! $CALL .STOP
LSTOF.
JUMP [XWD ''CODE'',[ITEXT (<STRING>)]
EXP %%.MOD]
LSTON. > ;END OF $STOP DEFINITION
SUBTTL $TEXT - Interface to the T%TEXT routine
; The $TEXT macro is used to do all formatted ASCII output involving
; strings and/or variables. The macro takes two arguments.
; The first argument is the address of a routine to call when T%TEXT
; actually has a single right justified 7 bit ASCII character to output
; from its arguments. The specified routine will be called with the
; character in S1 and should return TRUE or FALSE in S1. A value of
; FALSE will cause a STOP CODE to occur.
; If the first argument is null, i.e. left blank, then a default
; routine will be called, specified at initialization.
; If the first argument is <-1,,ADDR>, it is a IDPB style byte pointer
; for GLXTXT to store bytes into.
; The second argument is a text string containing characters to output
; and imbedded argument specifiers for substitutable parameters to be
; merged with constant data.
; If no specifier precedes a string in the second argument, it is
; assumed to be straight string data to be passed to the output routine
; directly. On the other hand, substitutable parameters are described
; by: ^<QUALIFIER>[OPT. SPACING]/<ADDRESS-OF-VARIABLE>[OPTIONAL <,MASK>]/
; Where the qualifier is one of the recognized single letter argument
; types (See next page), and the address and optional mask are two
; 36 bit quantities, such as might be passed to LOAD/STORE. These
; addresses can contain indexing and/or indirection ,may point to
; the accumulators or the stack.
; Each $TEXT instruction normally ends in a "free" carriage return
; line feed sequence. That is, each $TEXT instruction produces one
; line of output. However, through use of the qualifiers 0,A,M,J,K and L,
; output can be formatted to produce multiple lines via a single $TEXT
; or one line via multiple $TEXTS. ^0 gives a null (0) terminator in place of CRLF.
; NOTE: The $TEXT macro is a pseudo-instruction, and as such, it may be skipped
; over to avoid its execution. Also, all accumulators are guaranteed
; preserved .
; Example:
; $TEXT(PUTCHR,<This is your PPN: ^P/MYPPN/ for today.>)
; 1. Prints (using the routine PUTCHR for output) the string,
; "This is your PPN: "
; 2. Prints the contents of location MYPPN as a TOPS-10 PPN.
; 3. Prints the string " for today."
; 4. Prints a <CRLF> to produce the end of the line.
; Example:
; $TEXT(<-1,,LINBUF>,<File ^D/FB%STS(P1),FBS%FN/ is named ^F/@S1/^A>)
; 1. Prints the string "File ", depositing chars into the user buffer LINBUF
; 2. Prints the "loaded" contents of FB%STS(P1),FBS%FN as
; a decimal number
; 3. Prints the string " is named "
; 4. Prints the contents of the FD pointed to by AC S1 as
; a file specification.
; 5. Does not produce a <CRLF> sequence, since the ^A qualifier
; specifies that we supress it.
; Optionally, any output field may be right or left justified or
; centered. The information used to do this appears between the
; qualifier symbol and the slash which starts the address of the
; field to be output. The justification information consists of
; three parts, two of which are optional. The first piece of the
; justification information is the width of the field. This is given
; in Radix 10. and can be any number greater than zero. The second
; piece is a one letter code telling the Text processor which type
; of justification to use. This can be "L" for left justification,
; "R" for right justification or "C" for centering. If this field
; is omitted, the default is right justification for numeric items
; (I.E. ^O and ^D), and left justification for all other types.
; The third, optional, part is a single character which will be the
; character used to do any padding necessary for the justification.
; If the character is given, the justification code must be given also.
; If the padding character is omitted, it defaults to blanks.
; Example:
; $TEXT(PUTCHR,<^D10L*/S1/ ^F30/@FILSPC/ ^T40C/FOO(S2)>)
; 1. Prints the decimal number in S1, in a field of 10. characters.
; The number will be left justified, the remainder of the
; field will be filled with the character "*".
; 2. After printing one space, the file specification pointed
; to by location FILSPC will be printed in a 30 character
; field. The justification defaults to left justification,
; and the fill character is a space.
; 3. After printing another space, the ASCIZ string starting
; at location FOO(S2) will be printed in a 40 character
; field. The resulting output will be centered in the field
; and filled with blanks as necessary.
;
; NOTE: If output overflows a field, then no justification is done.
;
; The actual $TEXT macro
DEFINE $TEXT(ROUTINE,STRING,%L1)<
$CALL T%TEXT ;;CALL THE OUTPUT ROUTINE
LSTOF. XCREF ;;DONT LIST THIS MESS
JRST %L1 ;;SKIP OVER THE ARGUMENTS
..CN..==0
..KN..==0
EFLG==1
IRP ROUTINE,<..CN..==..CN..+1>
IFE <..CN..>,<SETZ 0, ;;NO PARM,,DEFAULT TO IB ROUTINE.
EFLG==0> ;;SET TO SHOW PARM OK.
IFE <..CN..-1>,<MOVEI 0,ROUTINE ;;1 PARM,,USE THIS AS $TEXT OUT ROUT.
EFLG==0> ;;SET TO SHOW PARM OK.
IFE <..CN..-3>,<IRP ROUTINE,< ;;FIND THE 3RD PARM.
..KN..==..KN..+1
IFE <..KN..-..CN..>,<
EFLG==0 ;;SET TO SHOW PARM OK.
HRROI 0,ROUTINE >>>
IFN <EFLG>,<IF1,<
PRINTX ?Invalid syntax in $TEXT parameter ROUTINE.
PRINTX >
HALT . > ;;STOP HERE WHEN EXEC.
FTEXT.(<STRING>) ;;PARSE THE STRING
IFN EFLG,<ETEXT.($TEXT,<STRING>)> ;;IF ANY ERRORS, DESCRIBE THEM
%L1: ;;PLACE LABEL
SUPPRESS %L1 ;;DON'T CONFUSE DDT OR ME
LSTON. > ;END OF $TEXT DEFINITION
; Define legal qualifers for argument types
;
; The first argument is the qualifier, the second is a flag telling
; the macro that this qualifer takes no arguments.
; Remember to add new qualifiers to the end, in order to keep older
; programs working.
DEFINE TQUALS,<
LSTOF.
X(T,TXT.A) ;;ASCIZ STRING
X(O,TXT.A) ;;UNSIGNED OCTAL NUMBER
X(D,TXT.A) ;;DECIMAL NUMBER
X(F,TXT.A) ;;FILE SPECIFICATION
X(7,TXT.A) ;;ONE RIGHT JUSTIFIED 7 BIT CHARACTER
X(6,TXT.A) ;;ONE RIGHT JUSTIFIED 6 BIT CHARACTER
X(W,TXT.A) ;;SIXBIT WORD
X(5,TXT.A) ;;ASCIZ, ONLY 1 WORD
X(P,TXT.A) ;;PPN OR DIRECTORY NUMBER
X(U,TXT.A) ;;PPN OR USER NUMBER
X(H,TXT.A) ;;UDT TO BE TYPED AS DD-MON-YY HH:MM:SS
X(C,TXT.A) ;;TIME FROM UDT TO BE TYPED AS HH:MM:SS
X(E,TXT.A) ;;TYPE OUT STRING FOR ERxxx$ ERROR CODE
X(I,TXT.A) ;;POINTER TO ITEXT (INDIRECT TEXT) BLOCK
X(M,TXT.NA) ;;TYPE ^M (CARRIAGE RETURN)
X(J,TXT.NA) ;;TYPE ^J (LINE-FEED)
X(L,TXT.NA) ;;TYPE ^L (FORM FEED)
X(K,TXT.NA) ;;TYPE ^K (VERTICAL TAB)
X(A,TXT.NA) ;;(APPEND) SUPPRESS FREE CARRIAGE RET.-LINE FEED
X(0,TXT.NA) ;;NULL CHAR INSTEAD OF CR-LF AT END
X(3,TXT.A) ;;INTERNAL STRING (DO NOT USE AS QUALIFIER)
X(V,TXT.A) ;;PROGRAM VERSION NUMBER
X(2,TXT.NA) ;;INTERNAL UP-ARROW (DO NOT USE AS QUALIFIER)
X(Q,TXT.A) ;;BYTE POINTER TO ASCIZ STRING
X(B,TXT.A) ;;OBJECT BLOCK
X(1,TXT.A) ;;OBJECT TYPE
X(N,TXT.A) ;;TYPE A NODE NAME/NUMBER
X(R,TXT.A) ;;TYPE OUT JOB INFO BLOCK (JIB)
LSTON.
> ;END OF TQUALS DEFINITION
DEFINE X(A,ARG)<TXTF.'A==<ZZ>B8+ARG
ZZ==ZZ+1>
TXT.A==0B0 ;FLAG THAT SAYS TAKES ARGUMENTS
TXT.NA==1B0 ;FLAG THAT SAYS DOESNT TAKE ARGS
TXT.P==1B1 ;FLAG THAT SAYS TWO WORD BLOCK NEEDED
TXT.S==1B2 ;FLAG THAT SAYS WANTS SPACING
TXT.SC==177B6 ;MASK TO GET CHARACTER FOR SPACING
TXT.SS==3B17 ;MASK TO GET SIDE FOR SPACING
TXT.SL==1 ;CODE TO SPACE LEFT
TXT.SR==2 ;CODE TO SPACE RIGHT
TXT.SM==3 ;CODE TO SPACE MIDDLE (CENTER)
TXT.SP==777777 ;MASK TO GET POSITIONS FOR SPACING
TXT.M==77B8 ;MASK TO QUALIFIER PART
; CREATE THE TXTF SYMBOLS
ZZ==1
TQUALS
; Definitions of Macros used by $TEXT
; CLEAR THE TEXT GATHERING MECHANISM
DEFINE CTEXT. <
DEFINE XTEXT.(OPCODE,NEW)<
OPCODE <<NEW>>>>
; ADD TEXT OR DEFINE IT
DEFINE ATEXT.(OLD)<
DEFINE XTEXT.(OPCODE,NEW)<
OPCODE <OLD,<NEW>>>>
; MACRO TO STRIP OFF ONE PAIR OF BRACKETS
DEFINE TEXT.(A),<TXT1. (A)>
; MACRO TO CREATE THE TWO WORD BLOCK NEEDED FOR LOAD/STORE PAIRS
DEFINE PTEXT.(A,B)<
OPC A
POINTR(0,B)
> ;END OF PTEXT. DEFINITION
;; CONTINUED ON NEXT PAGE
; DUMP ACCUMULATED TEXT INTO WHERE ITS GOING TO BE USED
DEFINE DTEXT.(TYPE)<
IFN TFLG,<
DEFINE TXT1.(A,B,C,D,E,F,G,H,I,J,K,L,M,N,O,P,Q,R,S,T,U,V,W,X,Y,ZZ,A1,B1,C1,D1,E1)<
TYPE+[ASCIZ\A'B'C'D'E'F'G'H'I'J'K'L'M'N'O'P'Q'R'S'T'U'V'W'X'Y'ZZ'A1'B1'C1'D1'E1\]
>>
IFE TFLG,<
DEFINE TXT1.(A,B,C,D,E,F,G,H,I,J,K,L,M,N,O,P,Q,R,S,T,U,V,W,X,Y,ZZ,A1,B1,C1,D1,E1)<
IFE ZFLG,<
OPDEF OPC [TYPE]
OPC A'B'C'D'E'F'G'H'I'J'K'L'M'N'O'P'Q'R'S'T'U'V'W'X'Y'ZZ'A1'B1'C1'D1'E1
>
IFN ZFLG,<
OPDEF OPC [ZFLG+TYPE]
PTEXT.(A'B'C'D'E'F'G'H'I'J'K'L'M'N'O'P'Q'R'S'T'U'V'W'X'Y'ZZ'A1'B1'C1'D1'E1)
>
>>
IFE TYPE&TXT.NA,<
.CREF
XTEXT. TEXT.
.XCREF
>
IFN TYPE&TXT.NA,<
EXP TYPE
>
IFN TYPE&TXT.S,<
IFE SCHAR,<SCHAR==" ">
IFE SSIDE,< IFE TXTF.D-<TYPE&TXT.M>,< SSIDE==TXT.SR>>
IFE SSIDE,< IFE TXTF.O-<TYPE&TXT.M>,< SSIDE==TXT.SR>>
IFE SSIDE,< SSIDE==TXT.SL>
EXP <<INSVL.(SCHAR,TXT.SC)>+<INSVL.(SSIDE,TXT.SS)>+<INSVL.(SWIDTH,TXT.SP)>>
SSIDE==0
SWIDTH==0
SCHAR==0
>
CTEXT.
TFLG==0
ZFLG==0
PURGE OPC
> ;END OF DTEXT. DEFINITION
; DO ERROR PROCESSING IF AN ERROR IS DETECTED DURING ASSEMBLY
DEFINE ETEXT.(NAME,STRING)<
IF1,<
IFN EFLG&1,<PRINTX ?Uknown qualifier in NAME call of STRING
PRINTX
>
IFN EFLG&2,<PRINTX ?Bad spacing specification in NAME call of STRING
PRINTX
>
IFN EFLG&4,<PRINTX ?Premature end of text in NAME call of STRING
PRINTX
>
IFN EFLG&10,<PRINTX ?Bad address in NAME call of STRING
PRINTX
>
IFN EFLG&20,<PRINTX ?Variable address too long in NAME call of STRING
PRINTX
>
IFN EFLG&40,<PRINTX ?Spacing on I qualifier in NAME call of STRING
PRINTX
>
> ;END OF IF1
> ;END OF ETEXT. DEFINITION
; ALLOW A T%TEXT ARGUMENT BLOCK TO BE BUILT OUTSIDE OF THE $TEXT
; CALL. THIS IS USED FOR THE "I" QUALIFIER, WHERE THE ADDRESS
; SPECIFIED IS THAT OF A T%TEXT ARGUMENT BLOCK, BUILT BY THIS MACRO.
; THIS ALLOWS MORE COMPLEX STRINGS THAN ^T TYPE STRINGS TO BE INCLUDED
; IN $TEXT INSTRUCTIONS.
; THE SINGLE ARGUMENT IS A $TEXT TYPE STRING, ENCLOSED IN A <> PAIR.
DEFINE ITEXT(STRING)<
LSTOF. XCREF ;;TURN OFF LISTINGS
FTEXT.(<STRING>) ;;PARSE THE ARGUMENT STRING
IFN EFLG,< ETEXT.(ITEXT,<STRING>)> ;IF ERROR, DESCRIBE IT
EXP 0 ;;STORE NULL WORD AS TERMINATOR
LSTON. > ;END OF ITEXT DEFINITION
; THE ACTUAL PARSE MACRO USED TO BREAK UP THE STRING
; NOTE: THE MACRO IS MADE AS SMALL AS POSSIBLE TO CONSERVE SPACE AND
; MAKE IT FASTER.
DEFINE FTEXT.($A),<
TFLG==0 ;;NOT ACCUMULATING TEXT
AFLG==0 ;;NOT ACCUMULATING ARGUMENT ADDRESS
SFLG==0 ;;NOT LOOKING FOR QUALIFIER
IFLG==0 ;;CLEAR SLASH/INGORE FLAG
ZFLG==0 ;;CLEAR TWO PART ADDRESS FLAG
EFLG==0
SCHAR==0;;CLEAR CHARACTER
SWIDTH==0;;AND SPACING
SSIDE==0;;AND THE SIDE TO SPACE ON
CTEXT.
IRPC $A,< ;;MAIN LOOP, REPEAT FOR EACH CHARACTER
IFN SFLG,< ;;IS QUALIFER EXPECTED?
FTEX1.(<$A>) ;;YES, CALL QUALIFER PARSER
> ;;END OF IFN SFLG
IFE SFLG+AFLG+IFLG,< ;;IF NO QUALIFER,OR ADDRESS OR IGNORING
IFIDN <$A>,<^>,< ;;LOOK FOR QUALIFIER
IFN TFLG,<DTEXT.(TXTF.3)>;;FOUND IT, DUMP ANY TEXT SO FAR
SFLG==1 ;;AND LOOK FOR QUALIFER NEXT TIME
> ;;END OF IFIDN FOR CARET
IFE SFLG,< ;;UNLESS JUST FOUND QUALIFIER,
IFE ^D29-TFLG,<;;CHECK FOR TEXT OVERFLOW
DTEXT.(TXTF.3);;SO WE DONT LOSE IT
> ;;END OF IFE
TFLG==TFLG+1 ;;COUNT ADDED CHARACTER
XTEXT. ATEXT.,<$A> ;;ADD THE CHARACTER
> ;;END OF IFE SFLG
> ;;END OF IFE SFLG+AFLG+IFLG
IFE SFLG+IFLG+TFLG,< ;;IF NOT QUAL. NEXT, IGNORE OR DOING TEXT
FTEX2.(<$A>) ;;PROCESS ADDRESS BUILDING
> ;;END OF IFE SFLG+IFLG+TFLG
IFN IFLG,<;;IGNORE FLAG LIT, SEE WHY
FTEX3.(<$A>) ;;IN SLASH PROCESSOR
> ;;END OF IFN IFLG
>;;END OF IRPC
IFN TFLG,<DTEXT.(TXTF.3)>;;AT THE END, DUMP ANY LEFT OVER TEXT
IFN AFLG+SFLG+IFLG,<EFLG==EFLG!4>;;MAKE SURE WE WERE NOT LEFT HANGING
> ;END FTEXT. DEFINTION
; THESE "SUBROUTINE" MACROS ARE USED TO PROCESS INFREQUENT OCCURENCES
; IN THE STRING PASSED TO THE FTEXT. MACRO. PUTTING THEM HERE,
; RATHER THAN IN THE MAIN FTEXT. MACRO MAKES ASSEMBLY FASTER.
DEFINE FTEX1.($A)< ;;PROCESS QUALIFIER SYMBOL
SFLG==0 ;;CLEAR QUALIFER EXPECTED
STYP==0 ;;CLEAR QUALIFER
IFIDN <$A><^>,<STYP==TXTF.2> ;;FAKE THE ^^ QUALIFER TO BE 2
IFE STYP,<IFDEF TXTF.'$A,<STYP==TXTF.'$A>>;;IF LEGAL SET TYPE
IFE STYP,<EFLG==EFLG!1> ;;ELSE SET "ILLEGAL QUALIFER"
IFN STYP&TXT.NA,< ;;IF THIS QUALIFER HAS NO ARGUMENTS
DTEXT.(STYP) ;;THEN DUMP THE QUALIFER NUMBER AND FLAGS NOW
IFLG==3 ;;AND SET TO IGNORE REST OF PASS
> ;;END OF IFN STYP&TXT.NA
IFE STYP&TXT.NA,< ;;IF THERE IS AN ARGUMENT,
IFLG==1 ;;IGNORE THIS PASS, GET SLASH NEXT TIME
AFLG==1 ;;AND START ACCUMULATING ADDRESS OF ARG
SWIDTH==0 ;;CLEAR SPACING WIDTH
> ;;END OF IFE STYP&TXT.NA
ZFLG==0 ;;IN ANY CASE, CLEAR 2-PART ADDR FLAG
>;END OF FTEX1. DEFINITION
DEFINE FTEX2.($A)< ;;PROCESS ARG ADDRESS
IFIDN <$A></>,< ;;ARE WE AT END?
AFLG==0 ;;YES, SO CLEAR ACCUMULATING ADDRESS FLAG
IFLG==3 ;;IGNORE THE SLASH
DTEXT.(STYP) ;;AND DUMP THE WHOLE ^X/FOO/ THING
> ;;END OF IFIDN
IFN AFLG,< ;;OTHER WISE, JUST ACCUMULATE ADDRESS
XTEXT. ATEXT.,<$A>
AFLG==AFLG+1 ;;TRACK LETTERS IN ADDRESS
IFE AFLG-^D31,<EFLG==EFLG!20> ;;IF TOO LONG, COMPLAIN
IFIDN <$A><,>,< ;;DO WE HAVE A COMMA? (2 PART ADDR)
IFN ZFLG,<EFLG==EFLG!10> ;;DONT ALLOW TWICE
ZFLG==TXT.P
> ;;END OF IFIDN ,COMMA
> ;;END OF IFN AFLG
> ;END OF FTEX2. DEFINTION
DEFINE FTEX3.($A)< ;;PROCESS SPECIAL SLASH REQUEST
IFE IFLG-3, < ;;VALUE OF 3 SAYS JUST TURN IT OFF
IFLG==0 ;; GIVES A WAY TO FLUSH THE PASS
> ;;END IFE IFLG-3
IFE IFLG-2,< ;;VALUE=2 MEANS
IFLG==0 ;;TURN IT OFF
IFDIF<$A></>,<FTEX4.(<$A>)> ;;CHECK FOR SLASH, IF NOT THERE CHECK IT
> ;;END OF IFE IFLG-2
IFE IFLG-1,< ;;VALUE=2 MEANS, IGNORE THIS PASS BUT
IFLG==2 ;;ON NEXT, CHECK FOR SLASH
> ;;END OF IFE IFLG-2
>;END OF FTEX3. DEFINITION
DEFINE FTEX4.($A)< ;;PROCESS SPACING SPECIFICATIONS
EFLG==EFLG!2 ;;ASSUME AN ERROR
IFE SSIDE,< ;;IF HAVE NOT SEEN SIDE YET,
IFLE "0"-"$A",< ;;IF NUMERIC
IFGE "9"-"$A",<SWIDTH==SWIDTH*^D10+^D'$A ;;ACCUMULATE SPACING
IFE STYP-TXTF.I<EFLG==EFLG!40> ;;DON'T ALLOW ON INDIRECT
STYP==STYP!TXT.S ;;INDICATE SPACING WANTED
EFLG==EFLG&<^-2> ;;CLEAR ERROR FLAG
> ;;END OF IFGE 9
> ;;END OF IGLE 0
> ;;END OF IFE SSIDE
IFIDN <$A><R>,< ;;IF ITS AN R,
IFN SWIDTH,< ;;AND WE HAVE SEEN A WIDTH
SSIDE==TXT.SR ;;SET TO THE RIGHT
EFLG==EFLG&<^-2> ;;CLEAR ERROR FLAG
> ;;END OF IFN SWIDTH
> ;;END OF IFIDN R
IFIDN <$A><L>,< ;;IF ITS AN L,
IFN SWIDTH,< ;;AND WE HAVE SEEN A WIDTH
SSIDE==TXT.SL ;;SET TO THE LEFT
EFLG==EFLG&<^-2> ;;CLEAR ERROR FLAG
> ;;END OF IFN SWIDTH
> ;;END OF IFIDN L
IFIDN <$A><C>,< ;;IF ITS AN C,
IFN SWIDTH,< ;;AND WE HAVE SEEN A WIDTH
SSIDE==TXT.SM ;;SET TO THE MIDDLE
EFLG==EFLG&<^-2> ;;CLEAR ERROR FLAG
> ;;END OF IFN SWIDTH
> ;;END OF IFIDN C
IFN SWIDTH, < ;;IF WE HAVE A WIDTH,
IFN SSIDE,< ;;AND A SIDE,
IFN EFLG&2,< ;;AND NOTHING THIS PASS,
IFE SCHAR,< SCHAR=="$A" ;;BUT NOT A CHAR, SET IT UP NOW
EFLG==EFLG&<^-2>;;CLEAR ERROR
> ;;END OF IFE SCHAR
> ;;END OF IFN EFLG
> ;;END OF IFN SSIDE
> ;;END OF IFN SWIDTH
IFE EFLG&2,< IFLG==2> ;;IF NO ERRORS, STILL LOOK FOR SLASH
> ;END OF FTEX4. DEFINITION
SUBTTL $WTO / $WTOJ / $WTOR / $ACK Macros
COMMENT /
THE CALLING FORMAT IS:
$WTO (<Type line>,<Text line>,OBJ Blk address,Optional args)
$WTOJ (<Type line>,<Text line>,OBJ Blk address,Optional args)
$WTOR (<Type line>,<Text line>,OBJ Blk address,ACK code addr,Optional args)
$ACK (<Type line>,<Text line>,OBJ Blk address,ACK code addr,Optional args)
$LOG (<Type line>,<Text line>,OBJ Blk address,Optional args)
$KWTOR (ACK Code Addr,Optional args) ;KILL A WTOR REQUEST
ANY OR ALL OF THE PARAMETERS AND THEIR COMBINATIONS ARE
ACCEPTABLE AS INPUT.
THE TYPE-LINE OR TEXT-LINE ARE STRUCTURED
THE SAME AS $TEXT CODE. ALL POSSIBLE COMBINATIONS OF
$TEXT AND ITEXT CODES ARE ACCEPTABLE.
The 'optional args' consist of
<arg1,arg2,...,argn> where each of the arg'i is
of the form: $WTxxx(y), where xxx is one of the
valid suffixes from the ALLWTO macro, and y is
the address of a block, or a flag bit, or some
ITEXT, depending on the meaning of xxx
/
;First, define the 'for all WTO parameters' macro
;The code types are as follows:
;0 - Takes an address
;1 - Takes an 'OR-able' flag word
;2 - Takes an ITEXT
;(It turns out that 0 and 1 are today indistinguishable during assembly)
DEFINE ALLWTO,<
.EAWTO(MTY,0)
.EAWTO(TYP,2)
.EAWTO(TXT,2)
.EAWTO(OBJ,0)
.EAWTO(ACK,0)
.EAWTO(FLG,1)
.EAWTO(NOD,0)
.EAWTO(JBN,0)
.EAWTO(ACD,0)
.EAWTO(OCD,0)
.EAWTO(MFL,1)
>;End define ALLWTO
;Then define the individual setting macros
DEFINE .EAWTO(SUFFIX,CODE),<
DEFINE $WT'SUFFIX' (ARG),<
IFB <ARG>,<.WF'SUFFIX'==0
IFN <CODE-2>,<.$W'SUFFIX'==0>>
IFNB <ARG>,<.WF'SUFFIX'==-1
IFN <CODE-2>,<.$W'SUFFIX'==.$W'SUFFIX'!<ARG>>
IFE <CODE-2>,<DEFINE .$W'SUFFIX',<<WO.'SUFFIX'>B8+[ITEXT (<ARG>)]>>
>;;End IFNB
>;;End of define $WTSUFFIX
>;End define .EAWTO
ALLWTO ;Define the $WTxxx macros
;Then define the 'RESET' macro
DEFINE $WTRST<
DEFINE .EAWTO(SUFFIX),<$WT'SUFFIX' <>>
ALLWTO ;;Reset all the $WTxxx macros
>;End define $WTRST
;Generate the op-codes for the argument block
DEFINE .EAWTO(SUFFIX),<
.OPCD==.OPCD+1
WO.'SUFFIX'==.OPCD
>;End define .EAWTO
.OPCD==0 ;Initialize the op-code counter
WO.MIN==.OPCD+1 ;Anticipate the minimum opcode
ALLWTO ;Generate the opcodes
WO.MAX==.OPCD ;Define the largest, too
PURGE .OPCD ;Flush this sym
;And define the Action routine to generate the in-line blocks
DEFINE $WTBLD<
IFE <.WFMTY>,<PRINTX ?No message type in $WTBLD>
DEFINE .EAWTO(SUFFIX,ARGCOD),<
IFN .WF'SUFFIX',<
IFE <ARGCOD-0>,<<WO.'SUFFIX'>B8+ .$W'SUFFIX'>
IFE <ARGCOD-1>,<<WO.'SUFFIX'>B8+ [EXP .$W'SUFFIX']>
IFE <ARGCOD-2>,<.$W'SUFFIX'>
>;;END IFN .WFSUFFIX
>;;End define .EAWTO
ALLWTO ;;Build each arg block, if neccessary
EXP 0 ;;Finish the arg list
>;End define $WTBLD
;Now define the most commonly used forms of these macros
DEFINE $WTO(TYPE,TEXT,OBJADR,ARGS),<.WTOX.(.OMWTO,<TYPE>,<TEXT>,<OBJADR>,,<ARGS>)>
DEFINE $WTOR(TYPE,TEXT,OBJADR,ACKADR,ARGS),<.WTOX.(.OMWTR,<TYPE>,<TEXT>,<OBJADR>,<ACKADR>,<ARGS>)>
DEFINE $ACK(TYPE,TEXT,OBJADR,ACKADR,ARGS),<.WTOX.(.OMACK,<TYPE>,<TEXT>,<OBJADR>,<ACKADR>,<$WTFLG(WT.SJI),ARGS>)>
DEFINE $WTOJ(TYPE,TEXT,OBJADR,ARGS),<.WTOX.(.OMWTO,<TYPE>,<TEXT>,<OBJADR>,,<$WTFLG(WT.JOB),ARGS>)>
DEFINE $LOG(TYPE,TEXT,OBJADR,ARGS),<.WTOX.(.OMLOG,<TYPE>,<TEXT>,<OBJADR>,,<ARGS>)>
DEFINE $KWTOR(ACKADR,ARGS),<.WTOX.(.OMWTR,,,,<ACKADR>,<$WTFLG(WT.KIL),ARGS>)>
DEFINE .WTOX.(TYP,HDR,TXT,OBJ,ACK,ARG,%LLN),<
$CALL I%WTO ;;INIT THE MSG BLKS AND LETERRIP.
LSTOF. ;;TURN OFF THE LISTING.
JRST %LLN ;;MAKE THE MACRO SKIP-ABLE.
$WTRST ;;Reset the WTO macros
IFNB <TYP>,<$WTMTY (<TYP>)> ;;Put in the message type
IFNB <HDR>,<$WTTYP (<HDR>)> ;;Add the 'type' line of text
IFNB <TXT>,<$WTTXT (<TXT>)> ;;Add the 'text' line of text
IFNB <OBJ>,<$WTOBJ (<OBJ>)> ;;And the object block address
IFNB <ACK>,<$WTACK (<ACK>)> ;;And the ack code
IRP ARG,<ARG> ;;And do all the extra stuff
$WTBLD ;;Then put in the blocks
%LLN: LSTON. > ;;RESUME LISTINGS
SUBTTL GALAXY system error codes
DEFINE ERRORS,<
ERR EOF,<End Of File>
ERR IFP,<Illegal file position>
ERR FDE,<File Data Error>
ERR FND,<File is not on disk>
ERR NSD,<No such device>
ERR FCF,<File checkpoint failed>
ERR SLE,<A System Limit Was Exceeded>
ERR IFS,<Illegal File Specification>
ERR FNF,<File Not Found>
ERR PRT,<Protection Violation>
ERR DNA,<Device Was Not Available>
ERR NCE,<No "current" entry in list>
ERR NMA,<No IPCF message is available>
ERR FDS,<Files are on different structures>
ERR FAE,<File already exists>
ERR USE,<Unexpected System Error>
ERR NSP,<No Such Pid>
ERR BOL,<Beginning of list reached>
ERR EOL,<End of list reached>
ERR RQF,<Receiver's quota full>
ERR SQF,<Sender's quota full>
ERR NRE,<No Remembered Entry>
ERR TBF,<The Command Table is full>
ERR EIT,<Entry already exists in the table>
ERR ITE,<Invalid Table Entry>
ERR QEF,<Quota Exceeded or Disk Full>
ERR ARG,<Invalid Argument>
ERR UJI,<Invalid I%JINF Function>
ERR IJN,<Invalid Job Number Specified for I%JINF>
> ;END DEFINE ERRORS
;GENERATE THE ERROR SYMBOLS
ER%%%==1 ;DON'T USE ERROR CODE 0
DEFINE ERR(A,B),<
ER'A'$==ER%%%
ER%%%==ER%%%+1
> ;END DEFINE ERR
ERRORS
SUBTTL Canonical File Information
;In order to bring the number of feature test switches needed to the
;absolute minimum, the GLXFIL (file handler) module makes information
;about open files available through the F%INFO routine call. The
;particular piece of information desired is designated by providing
;a canonical descriptor for that piece of information.
;These FI.xxx symbols, defined here, are the F%INFO descriptors
DEFINE CFI<
LSTOF.
X CRE ;;UDT FORMAT CREATION DATE/TIME OF FILE
X GEN ;;VERSION/GENERATION NUMBER OF FILE
X PRT ;;PROTECTION OF THE FILE
X CLS ;;CLASS OF FILE (TOPS-20) ONLY
X AUT ;;AUTHOR OF THE FILE
X USW ;;USER SETTABLE WORD
X SPL ;;SPOOL WORD (TOPS-10)
X SIZ ;;SIZE OF FILE, IN BYTES
X MOD ;;DATA MODE
X CHN ;;FILE CHANNEL # (CHN OR JFN)
LSTON.
> ;END OF CFI DEFINITION
;CREATE THE SYMBOLS
FI.%%%==0
DEFINE X(A)<
FI.'A==FI.%%%
FI.%%%==FI.%%%+1
>
CFI
SUBTTL Canonical Job Information
;In order to bring the number of feature test switches needed to the
;absolute minimum, GLXINT (Initialization) module makes information
;about jobs available through the I%JINF routine call. The
;particular piece of information desired is designated by providing
;a canonical descriptor for that piece of information.
;These JI.XXX symbols, defined here, are the I%JINF descriptors
DEFINE JBTAB<
LSTOF.
X JNO,.JIJNO,<-1,,GJBJNO> ;;JOB NUMBER
X TNO,.JITNO,<-1,,GJBTTY> ;;TERMINAL NUMBER
X USR,.JIUNO,.GTPPN ;;LOGGED IN DIRECTORY NUMBER
X CDN,.JIDNO,<-1,,GJBPTH> ;;CONNECTED DIRECTORY NUMBER
X PRG,.JIPNM,.GTPRG ;;SIXBIT PROGRAM NAME
X CJN,.JICPJ,<-1,,GJBCJB> ;;CONTROLLING JOB NUMBER (IF CONTROLLED BY PTY)
X BAT,.JIBCH,.GTOBI ;;BATCH DATA WORD..STREAM # AND WTO DATA
X JLT,.JISTM,.GTJLT ;;JOB LOGGED IN TIME
X LOC,<-1,,GJBLOC>,.GTLOC ;;JOB LOCATION INFORMATION
X RTM,.JIRT,<-1,,GJBRTM> ;;JOB RUNTIME IN MILLISECS
LSTON.
> ;END OF CJI DEFINITION
;CREATE THE SYMBOLS
.ZZ==1
JI.MIN==.ZZ ;smallest accepted value
DEFINE X(A,B,C)<
JI.'A==.ZZ
.ZZ==.ZZ+1
>
JBTAB
JI.MAX==.ZZ-1 ;LARGEST ACCEPTED VALUE
SUBTTL Scanning and Command Module Symbols
;Define the major macro to expand X(y,z,...) for each terminal type
;Note well: the items in the TRMTYP macro MUST be in Alphabetical order
; so that TRMTYP can be used to build parse tables.
DEFINE TRMTYP,<
LSTOF.
X(33,TTY33,33,) ;;MODEL 33
X(35,TTY35,35,) ;;MODEL 35
TOPS20<
X(37,TTY37,37,) ;;MODEL 37
X(EXECUPORT,EXEC,EXE,) ;;TI EXECUPORT
>
X(LA36,LA36,L36,) ;;LA36
X(VT05,VT05,V05,<37,177,177,177>) ;;VT05
X(VT100,VT100,100,<.CHESC,"[","K">) ;;VT100
X(VT50,VT50,V50,<.CHESC,"J">) ;;VT50
X(VT52,VT52,V52,<.CHESC,"J">) ;;VT52
LSTON.
>;END DEFINE TRMTYP
;The general form of the X macro (which must be redefined just before invoking
;TRMTYP) is:
;X(PARNAM,SIXNAM,SUF,EOLSEQ)
;Where,
; PARNAM is the parseable name
; SIXNAM is the (TOPS-10) SIXBIT name for TRMOP. .TOTRM
; SUF is a 3-char suffix for .TTsuf and .TIsuf
; EOLSEQ is a sequence of bytes which will clear to end of line
;Note:
; .TTsuf is the code to be passed to K%STYP
; This value need not be the same on the -10 and the -20,
; but today, they are.
; .TIsuf is a number between 0 and .TIMAX (inclusive) which may
; be used to $BUILD and $SETup dispatch tables
;Now, define the .TIsuf symbols which are indicies into tables
;which contain 1 entry for each type of terminal
DEFINE X(PARNAM,SIXNAM,SUF,EOLSEQ),<
.TI'SUF==..Z
..Z==..Z+1>
..Z==0
LALL
TRMTYP ;Do 'em all!
.TIMAX==..Z-1 ;Set the max (must $BUILD (.TIMAX+1) still!)
PURGE ..Z
TOPS10<
;Define the .TTsuf symbols, since they're not in UUOSYM
DEFINE X(PARNAM,SIXNAM,SUF,EOLSEQ),<
.TT'SUF==..Z
..Z==..Z+1
>;END DEFINE X
..Z==0 ;Start at 0
TRMTYP ;Do 'em all!
PURGE ..Z
>;END TOPS10
; The following TOPS-20 symbols are defined when building a TOPS-10 library
; so that the emulation routines provided for scanning and command
; parsing can use the same symbols on both systems.
TOPS10 < ;ALREADY DEFINED ON THE -20
; RDTTY flags and argument offsets
.RDCWB==0 ;COUNT OF WORDS FOLLOWING
.RDFLG==1 ;FLAG BITS
RD%BRK==1B0 ; BREAK ON ^Z OR ESC
RD%TOP==1B1 ; BREAK ON TOPS-10 BREAK SET
RD%PUN==1B2 ; BREAK ON PUNCTUATION
RD%BEL==1B3 ; BREAK ON EOL
RD%CRF==1B4 ; EAT CARRIAGE RETURNS
RD%RND==1B5 ; RETURN IF EDITED TO BEGINNING
RD%JFN==1B6 ; IFN RATHER THAN STRING PTR
RD%RIE==1B7 ; NON-BLOCKING, I.E. RETURN IF EMPTY
RD%BBG==1B8 ; PTR TO DEST BUFFER IS IN .RDBFP
RD%RAI==1B10 ; CONVERT LOWER TO UPPER CASE
RD%SUI==1B11 ; SUPRESS ^U (RUBOUT LINE) HANDLING
RD%BTM==1B12 ; INPUT ENDED ON A BREAK
RD%BFE==1B13 ; USER DELETED TO BEGINNING
RD%BLR==1B14 ; BACKUP LIMIT REACHED
RD%NEC==1B35 ; NO ECHO ON ANYTHING (TOPS-10)
.RDIOJ==2 ;INPUT AND OUTPUT IFNS OR STRING POINTER
.RDDBP==3 ;DESTINATION BYTE POINTER
.RDDBC==4 ;NUMBER OF BYTES LEFT AFTER POINTER
.RDBFP==5 ;BEGINNING BYTE POINTER
.RDRTY==6 ;RE-TYPE PROMPT POINTER
.RDBRK==7 ;LOCATION OF 4 WORD BREAK SET TABLE
.RDBKL==10 ;REAL (ARBITRARY) BACKUP LIMIT
;; STILL UNDER TOPS10 CONDITIONAL
; COMMAND SCANNING (S%CMND) INTERFACE
;FORMAT OF COMND STATE BLOCK:
.CMFLG==:0 ;USER FLAGS,,REPARSE DISPATCH ADDRESS
.CMIOJ==:1 ;INJFN,,OUTJFN
.CMRTY==:2 ;^R BUFFER POINTER
.CMBFP==:3 ;PTR TO TOP OF BUFFER
.CMPTR==:4 ;PTR TO NEXT INPUT TO BE PARSED
.CMCNT==:5 ;COUNT OF SPACE LEFT IN BUFFER AFTER PTR
.CMINC==:6 ;COUNT OF CHARACTERS FOLLOWING PTR
.CMABP==:7 ;ATOM BUFFER POINTER
.CMABC==:10 ;ATOM BUFFER SIZE
.CMGJB==:11 ;ADR OF GTJFN ARG BLOCK
CM%GJB==:777777 ;ADR OF GTJFN ARG BLOCK
;FUNCTION DESCRIPTOR BLOCK
.CMFNP==:0 ;FUNCTION AND POINTER
CM%FNC==:777B8 ;FUNCTION CODE
CM%FFL==:377B17 ;FUNCTION-SPECIFIC FLAGS
CM%LST==:777777 ;LIST POINTER
.CMDAT==:1 ;DATA FOR FUNCTION
.CMHLP==:2 ;HELP TEXT POINTER
.CMDEF==:3 ;DEFAULT STRING POINTER
.CMBRK==4 ;BREAK SET FOR CM%BRK
; FUNCTION CODES
;Note: The following function code symbols must agree with analogous
;definitions found in MONSYM.
.CMKEY==0 ;KEYWORD
.CMNUM==1 ;NUMBER
.CMNOI==2 ;NOISE WORD
.CMSWI==3 ;SWITCH
.CMIFI==4 ;INPUT FILE
.CMOFI==5 ;OUTPUT FILE
.CMFIL==6 ;GENERAL FILESPEC
.CMFLD==7 ;ARBITRARY FIELD
.CMCFM==10 ;CONFIRM
.CMDIR==11 ;DIRECTORY NAME (PPN)
.CMUSR==12 ;USER NAME (PPN)
.CMCMA==13 ;COMMA
.CMINI==14 ;INITIALIZE COMMAND
;.CMFLT IS NOT PROVIDED
.CMDEV==16 ;DEVICE NAME
.CMTXT==17 ;TEXT
;.CMTAD IS NOT PROVIDED
.CMQST==21 ;QUOTED STRING
.CMUQS==22 ;UNQUOTED STRING
.CMTOK==23 ;TOKEN
.CMNUX==24 ;NUMBER DELIMITED BY NON-DIGIT
.CMACT==25 ;ACCOUNT
.CMNOD==26 ;NODE
> ;END TOPS10
.RDSIZ==.RDBKL+1 ;SIZE OF ARGUMENT BLOCK
TOPS10 <
;Null JFN
;FLAGS
CM%ESC==:1B0 ;ESC SEEN
CM%NOP==:1B1 ;NO PARSE
CM%EOC==:1B2 ;END OF COMMAND SEEN
CM%RPT==:1B3 ;REPEAT PARSE NEEDED
CM%SWT==:1B4 ;SWITCH TERMINATED WITH ":"
CM%PFE==:1B5 ;PREVIOUS FIELD ENDED WITH ESC
CM%RAI==:1B6 ;RAISE INPUT
CM%XIF==:1B7 ;NO INDIRECT FILES
CM%WKF==:1B8 ;WAKEUP AFTER EACH FIELD
;REMOVE CM%NJF 9/21/79 MLB
CM%BRK==:1B13 ;INDICATES .CMBRK HAS DATA
CM%PO==:1B14 ;PARSE ONLY FLAG
CM%HPP==:1B15 ;HELP PTR PRESENT
CM%DPP==:1B16 ;DEFAULT PTR PRESENT
CM%SDH==:1B17 ;SUPPRESS DEFAULT HELP MESSAGE
;FLAGS FOR CMSWI FUNCTION
CM%VRQ==:1B0 ;VALUE REQUIRED
;FLAGS FOR TIME AND DATE
CM%IDA==1B0 ;INPUT DATE
CM%ITM==1B1 ;INPUT TIME
CM%NCI==1B2 ;NO CONVERT TO INTERNAL
;FLAGS IN KEYWORD TABLE (FIRST WORD OF STRING IF B0-6 = 0)
CM%INV==:1B35 ;INVISIBLE
CM%NOR==:1B34 ;NO-RECOGNIZE (PLACE HOLDER)
CM%ABR==:1B33 ;ABBREVIATION
CM%FW==:1B7 ;FLAG WORD (ALWAYS SET)
; STRING COMPARE (S%SCMP) FLAGS
SC%LSS==1B0 ;TEST STRING LESS THAN BASE STRING
SC%SUB==1B1 ;TEST STRING SUBSET OF BASE STRING
SC%GTR==1B2 ;TEST STRING GREATER THAN BASE STRING
;(IF NONE, EXACT MATCH IS RESULT)
; TABLE LOOK UP (S%TBLK) FLAGS
TL%NOM==1B0 ;NO MATCH
TL%AMB==1B1 ;AMBIGUOUS
TL%ABR==1B2 ;UNIQUE ABBREVIATION
TL%EXM==1B3 ;EXACT MATCH
> ;END TOPS10
CM%INT==:1B9 ;INTERRUPT RET. (10 AND 20..GALAXY DEFINED)
; COMMAND REPLY
CR.FLG==0 ;OFFSET TO FLAG WORD
CR.RES==1 ;OFFSET TO RESULT WORD
CR.PDB==2 ;GIVEN PDB,,USED PDB
CR.COD==3 ;CODE TYPE OF PROCESSED FIELD
CR.SIZ==CR.COD+1 ;SIZE OF COMMAND REPLY BLOCK
;COMMAND ERROR BUFFER SIZE
ERRBSZ==20 ;SETUP 20 WORDS FOR NOW
SUBTTL THE MESSAGE HEADER
;Among GALAXY programs, there is a common message header format
; so that communication and error checking is easier. There are
; also some common function codes (currently only TEXT) which are
; defined across program lines. The specific data (if any) associated
; with each message type follows the standard header. Note also
; that MESSAGE LENGTH includes the header itself.
; !=======================================================!
; ! Message Length ! Message Type !
; !-------------------------------------------------------!
; !ACK!NOM!FAT!WRN!MOR! ! Sixbit Suffix !
; !-------------------------------------------------------!
; ! Acknowledgement code !
; !=======================================================!
PHASE 0
.MSTYP:! BLOCK 1
MS.CNT==-1,,0 ;MESSAGE LENGTH
MS.TYP==0,,-1 ;MESSAGE TYPE
MT.OFF==700000 ;OFFSET TO THE COMMON CODES
MT.TXT==700000 ;TEXT MESSAGE
.MSFLG:!BLOCK 1 ;FLAGS WORD
MF.ACK==1B0 ;ACKNOWLEDGEMENT REQUESTED
MF.NOM==1B1 ;NO MESSAGE, JUST AN ACK
MF.FAT==1B2 ;FATAL MESSAGE
MF.WRN==1B3 ;WARNING MESSAGE
MF.MOR==1B4 ;MORE MESSAGE FOLLOWS
MF.SUF==777777 ;SUFFIX FOR TEXT MESSAGE
.MSCOD:!BLOCK 1 ;USER SUPPLIED CODE USED FOR ACK'ING
MSHSIZ:! ;LENGTH OF MESSAGE
.MSDAT:!BLOCK 0 ;START OF MESSAGE CONTENTS
DEPHASE
SUBTTL ACK - THE GALAXY 'ACK' MESSAGE
; !=======================================================!
; \ \
; \ THE MESSAGE HEADER \
; \ \
; !-------------------------------------------------------!
; ! FLAG WORD (.OFLAG) !
; !-------------------------------------------------------!
; ! ARGUMENT COUNT (.OARGC) !
; !-------------------------------------------------------!
;
; THE MESSAGE BODY BLOCK
;
; !-------------------------------------------------------!
; ! BLOCK LENGTH ! .CMTXT !
; !-------------------------------------------------------!
; \ \
; \ ASCIZ TEXT MESSAGE \
; \ \
; !-------------------------------------------------------!
;
; THE MESSAGE HEADER BLOCK
;
; !-------------------------------------------------------!
; ! BLOCK LENGTH ! .ORDSP !
; !-------------------------------------------------------!
; \ \
; \ ASCIZ MESSAGE HEADER \
; \ \
; !-------------------------------------------------------!
; NOTE:::: * * * * * N O T E W E L L * * * * *
;
; THE 'ACK' CODE THAT WAS SUPPLIED BY THE USER IN THE ORIGIONAL
; REQUEST WILL BE RETURNED IN .MSCOD
;
;
; THE MESSAGE TYPE MAY BE MT.TXT (OLD MSG TYPE) OR
; .OMTXT OR .OMACS (NEW ACK MESSAGE TYPE(S))
;
;
; THE .ORDSP BLOCK WILL ONLY BE FOUND IN A .OMACS MESSAGE
;
;
; THE .MSCOD FIELD MAY HAVE BITS MF.NOM, MF.FAT, MF.WRN,
; MF.MOR LIT.
; THE .MSCOD FIELD MAY ALSO HAVE MF.SUF FILLED IN.
SUBTTL JIB - Job Information Block
;The foJob Information Block contains the GALAXY Information to describe
;a job to the system. This block will be used to pass this information
;between all Galaxy Components.
; !=======================================================!
; ! JOBNAME IN SIXBIT !
; !-------------------------------------------------------!
; ! SEQUENCE NUMBER OF JOB ! QUASAR DEFINED FIELDS !
; !-------------------------------------------------------!
; ! USER NUMBER ON -20 OR PPN ON -10 !
; !-------------------------------------------------------!
; ! REQUEST IDENTIFIER FOR JOB !
; !=======================================================!
;
;
;
; !=======================================================!
; ! !
; ! USER NAME (TOPS-10 ONLY) !
; ! !
; !=======================================================!
PHASE 0
JIB.JN:! BLOCK 1 ;JOB NAME IN SIXBIT
JIB.SQ:! BLOCK 1 ;SEQUENCE NUMBER FIELD
JB.SEQ==-1,,0 ;SEQUENCE NUMBER (QUASAR RESTRICTION)
JIB.US:! BLOCK 1 ;USER NUMBER OR PPN
JIB.ID:! BLOCK 1 ;REQUEST IDENTIFIER NUMBER
TOPS10<
JIB.NM:! BLOCK 2 ;USER NAME 2 SIXBIT WORDS (TOPS-10 ONLY)
>;END TOPS10
JIBSIZ:! ;SIZE OF THE JOB INFO BLOCK
SUBTTL OBJ - Object Descriptor
; Various programs must use a device/object designator which fully
; describes a an entity as to its type,unit number and node. The canonical
; object descriptor is used for this purpose
; The object/device designator:
; !=======================================================!
; ! Object type descriptor code !
; !-------------------------------------------------------!
; ! Low Bound unit number ! High Bound unit number !
; !-------------------------------------------------------!
; ! Node name in SIXBIT !
; !=======================================================!
PHASE 0
OBJ.TY:! BLOCK 1 ;OBJECT TYPE CODE WORD
.OTRDR==1 ;TYPE READER
.OTNCU==2 ;TYPE NETWORK CONTROLLER
.OTLPT==3 ;TYPE PRINTER
.OTBAT==4 ;TYPE BATCH CONTROLLER
.OTCDP==5 ;TYPE CARD PUNCH
.OTPTP==6 ;TYPE PAPER TAPE PUNCH
.OTPLT==7 ;TYPE PLOTTER
.OTTRM==10 ;TYPE TERMINAL
.OTJOB==11 ;TYPE JOB (T/S)
.OTOPR==12 ;TYPE OPERATOR
.OTIBM==13 ;TYPE IBM
.OTMNT==14 ;TYPE MOUNT
.OTXFR==15 ;TYPE FILE TRANSFER
.OTBIN==16 ;TYPE CARD INTERPRETER PROGRAM
.OTRET==17 ;TYPE FILE RETRIEVAL
.OTNOT==20 ;TYPE RETRIEVAL NOTIFICATION
.OTDBM==21 ;TYPE DBMS
.OTMAX==.OTDBM ;SET THE LARGEST ONE DEFINED
OBJ.UN:! BLOCK 1 ;UNIT NUMBER WORD
OU.HRG==-1,,0 ;MASK FOR HIGH RANGE OF UNIT
OU.LRG==0,,-1 ;MASK FOR LOW RANGE OF UNIT
;HRG=0 MEANS ONLY ONE ITEM
;HRG=-1MEANS UP TO HIGHEST EXISTING
OBJ.ND:! BLOCK 1 ;NODE NAME, KEPT IN SIXBIT
OBJ.SZ:! ;SIZE OF THE OBJECT DESIGNATOR
DEPHASE
SUBTTL OBJCTS MACRO
;THIS MACRO ASSOCIATES ALL LEGAL OBJECT CODES (SEE OBJECT DESCRIPTOR
; DEFINITION) WITH A TEXT STRING FOR THE OBJECT TYPE
DEFINE OBJCTS,<
X .OTRDR,Reader
X .OTNCU,Network-Controller
X .OTLPT,Printer
X .OTBAT,Batch-Stream
X .OTCDP,Card-Punch
X .OTPTP,Papertape
X .OTPLT,Plotter
X .OTJOB,Job
X .OTTRM,Terminal
X .OTOPR,Operator
X .OTIBM,<IBM Remote>
X .OTMNT,<Device>
X .OTXFR,<File Transfer>
X .OTBIN,<Card Reader Interpreter>
X .OTRET,<File Retrieval>
X .OTNOT,<Retrieval Notification>
X .OTDBM,<DBMS System>
> ;END OF OBJCTS DEFINITION
SUBTTL FD - File Descriptor
; The FD (File Descriptor) is the data structure used to pass a system
; dependent file description to subroutines or as part of a larger
; message or data structure.
PHASE 0
.FDLEN:! BLOCK 1 ;LENGTH WORD
FD.LEN==-1,,0 ;MASK TO LENGTH FIELD
.FDFIL:! ;FIRST WORD OF FILESPECIFICATION
DEPHASE
TOPS10 < ;FILE DESCRIPTOR FOR TOPS10
; !=======================================================!
; ! LENGTH OF THE FD !
; !-------------------------------------------------------!
; ! STRUCTURE CONTAINING THE FILE !
; !-------------------------------------------------------!
; ! FILE NAME !
; !-------------------------------------------------------!
; ! EXTENSION !
; !-------------------------------------------------------!
; ! [P,PN] !
; !=======================================================!
; ! !
; ! SFD PATH FOR THE FILE !
; ! THESE WORDS ARE OPTIONAL !
; ! AND CAN BE OF LENGTH 0 TO 5 !
; ! !
; !=======================================================!
PHASE .FDFIL
.FDSTR:! BLOCK 1 ;STRUCTURE CONTAINING THE FILE
.FDNAM:! BLOCK 1 ;THE FILE NAME
.FDEXT:! BLOCK 1 ;THE EXTENSION
.FDPPN:! BLOCK 1 ;THE OWNER OF THE FILE
FDMSIZ:! ;MINUMUM SIZE OF A FILE DESCRIPTOR
.FDPAT:! BLOCK 5 ;PATH (OPTIONAL AND FROM 0 TO 5 WORDS)
FDXSIZ:! ;MAXIMUM FD AREA SIZE
DEPHASE
> ;END OF TOPS10
;CONTINUED ON FOLLOWING PAGE
TOPS20 < ;FILE DESCRIPTOR FOR TOPS20
; !=======================================================!
; / /
; / /
; / THE FILE DESCRIPTOR ON TOPS20 IS AN ASCIZ STRING /
; / OF VARIABLE LENGTH AND READY TO BE GTJFN'ED /
; / /
; / /
; !=======================================================!
PHASE .FDFIL
.FDSTG:! BLOCK 1 ;ASCIZ STRING FOR GTJFN/OPENF SEQUENCE
FDMSIZ:! ;MINIMUM SIZE OF A FILE DESCRIPTOR
FDXSIZ==^D300/^D5 ;RESERVE ROOM FOR 300 CHARACTERS
DEPHASE
> ;END OF TOPS20
SUBTTL FOB - Parameter block passed to F%IOPN and F%OOPN
; THE FOLLOWING IS A DESCRIPTION OF THE BLOCK USED AS A PARAMETER
; PASSING AREA TO THE TWO FILE OPEN ROUTINES IN GLXFIL.
; !=======================================================!
; ! ADDRESS OF FD TO USE FOR FILE SPECIFICATION !
; !-------------------------------------------------------!
; ! !LSN!NFO!BYTE SIZE!
; !-------------------------------------------------------!
; ! FIRST HALF OF USER ID FOR "IN BEHALF OF" !
; !-------------------------------------------------------!
; ! CONNECTED DIRECTORY (TOPS-20 ONLY) !
; !=======================================================!
PHASE 0
FOB.FD:! BLOCK 1 ;POINTER TO FD AREA
FOB.CW:! BLOCK 1 ;CONTROL WORD
FB.LSN==1B28 ;LINE SEQUENCE NUMBERS APPEAR (IGNORE)
FB.NFO==1B29 ;NEW FILE ONLY (NON-SUPERSEDING)
FB.BSZ==77B35 ;BYTE SIZE OF THE FILE
FOB.MZ:! ;MINIMUM SIZE OF A FOB
FOB.US:! BLOCK 1 ;(OPTIONAL) USER ID FOR "IN BEHALF" OPERATIONS
FOB.CD:! BLOCK 1 ;(OPTIONAL) CONNECTED DIRECTORY (TOPS20)
FOB.SZ:! ;SIZE OF AN FOB
DEPHASE
SUBTTL FRB - Parameter block passed to F%REN for renames
; THE FOLLOWING BLOCK IS SET UP BY THE CALLER OF F%REN IN GLXFIL.
; THE BLOCK PROVIDES THE SOURCE AND DESTINATION OF THE RENAME, AS
; WELL AS NEEDED PROTECTION INFORMATION.
; !=======================================================!
; ! POINTER TO FD DESCRIBING SOURCE OF THE RENAME !
; !-------------------------------------------------------!
; ! POINTER TO FD DESCRIBING DESTINATION OF THE RENAME !
; !-------------------------------------------------------!
; ! USER ID FOR AN "IN BEHALF" RENAME !
; !-------------------------------------------------------!
; !CONNECTED DIRECTORY FOR AN "IN BEHALF" RENAME (TOPS-20)!
; !=======================================================!
PHASE 0
FRB.SF:! BLOCK 1 ;POINTER TO FD OF SOURCE FILE
FRB.DF:! BLOCK 1 ;POINTER TO FD OF DESTINATION FILE
FRB.MZ:! ;MINIMUM SIZE OF AN FRB
FRB.US:! BLOCK 1 ;(OPTIONAL) USER ID FOR IN BEHALF
FRB.CD:! BLOCK 1 ;(OPTIONAL) CONNECTED DIRECTORY (TOPS20)
FRB.SZ:! ;SIZE OF AN FRB
DEPHASE
SUBTTL IB - Initialization Block for GALAXY programs
;All programs which make use of the GALAXY library or runtime system
; must go through an initialization call to insure that the
; modules are in a determinant state, and also to set up the
; profile that this program wants. This initialization is
; carried out using a communications area, the Initialization
; Block, from which parameters are read and information filled in.
;
; The initialization call to I%INIT is made with S1 containing the
; size of the IB and S2 containing its address.
; Initialization Block (IB):
; !=======================================================!
; ! Address of output routine for defaulted $TEXTs !
; !-------------------------------------------------------!
; !OCT!STP! program-wide flags !
; !-------------------------------------------------------!
; ! Base of program's interrupt vector(s) !
; !-------------------------------------------------------!
; ! PID block address !
; !-------------------------------------------------------!
; ! $TEXT error exit routine !
; !=======================================================!
PHASE 0
IB.OUT:! BLOCK 1 ;ADDRESS OF ROUTINE TO CALL FROM
;OUTPUT ROUTINE IF $TEXT SPECIFIES NONE
IB.FLG:! BLOCK 1 ;Program-wide flag word
IT.OCT==1B0 ; OPEN COMMAND TERMINAL
IP.STP==1B1 ;SEND STOPCODES TO ORION AS WTO IF SET
IB.INT:! BLOCK 1 ;BASE OF INTERRUPT VECTOR(S)
IB.PIB:! BLOCK 1 ;Address of PID block
IB.ERR:! BLOCK 1 ;USER $TEXT ERROR EXIT ROUTINE ADDRESS.
IB.PRG:! BLOCK 1 ;PROGRAM NAME
IB.SZ:! ;SIZE OF THE IB
DEPHASE
SUBTTL PIB - PID block
;This block describes the PID that the program wishes to become, and
;other assorted flavors of IPCF parameters. It is a parameter
;for the C%CPID, C%KIPD, C%SPID calls, and is aimed at by the IB.
; !=======================================================!
; ! Length ! !
; !-------------------------------------------------------!
; ! PID (filled by GLXLIB) !
; !-------------------------------------------------------!
; !PSI!JWP!RSE!SPI!CFV!SPB! !
; !-------------------------------------------------------!
; ! System index ! !Chan or offst!
; !-------------------------------------------------------!
; ! Max # of PIDs ! Send quota !Receive quota!
; !-------------------------------------------------------!
; ! Pointer to INFO NAME (optional) !
; !-------------------------------------------------------!
; ! Pointer to ACCOUNT string (optional) !
; !-------------------------------------------------------!
; ! Pointer to LOCATION string (optional) !
; !=======================================================!
PHASE 0
PB.HDR:! BLOCK 1 ;The PID block header word
PB.LEN==LHMASK ;Length of this block
PB.PID:! BLOCK 1 ;The PID assigned (filled by GLXLIB)
PB.FLG:! BLOCK 1 ;Flags
IP.PSI==1B0 ;Connect this PID to the PSI system
IP.JWP==1B1 ;Get a job-wide PID (good till logout)
IP.RSE==1B2 ;Return to caller if send fails
IP.SPF==1B3 ;Special PID Flag (caller wants to
; be a system PID)
IP.SPB==1B5 ;SET IF CALLER IS PRIVELEGED AND WISHES
; TO SEE IF SENDER SET IP.CFP
PB.INT:! BLOCK 1 ;Interrupt channel or offset
IP.SPI==LHMASK ;Special PID index
IP.CHN==77 ;Channel
PB.SYS:! BLOCK 1 ;Special index, quotas
IP.MNP==LHMASK ;Max # PIDs for this job
IP.SQT==777B26 ;Send Quota
IP.RQT==777B35 ;Receive Quota
IP.BQT==IP.SQT!IP.RQT ;Both Quotas
PB.MNS:! ;Minimum size of a PIB
PB.NAM:! BLOCK 1 ;Pointer to Name string
PB.ACT:! BLOCK 1 ;Pointer to Account string
PB.LOC:! BLOCK 1 ;Pointer to Location string
PB.MXS:! ;Maximum size of PIB
DEPHASE
SUBTTL SAB - Send Argument Block passed to C%SEND
;This block describes the IPCF message being sent
; !=======================================================!
; ! DESTINATION PID !
; !-------------------------------------------------------!
; ! LENGTH OF MESSAGE !
; !-------------------------------------------------------!
; ! ADDRESS OF MESSAGE !
; !-------------------------------------------------------!
; !FLG! SYSTEM PID INDEX !
; !-------------------------------------------------------!
; ! 0 or PID Block address to send for !
; !=======================================================!
PHASE 0
SAB.PD:! BLOCK 1 ;PID TO SEND MESSAGE TO
SAB.LN:! BLOCK 1 ;LENGTH OF MESSAGE TO SEND
; THIS FIELD DEFINES IF THE MESSAGE IS
; TO BE SENT AS A PAGE OR A PACKET
; A LENGTH OF EXACTLY 1000 WILL
; CAUSE A PAGE-MODE SEND OF THE
; THE PAGE POINTED TO BY SAB.MS
; OTHERWISE THE MESSAGE WILL BE
; SENT AS A PACKET IF POSSIBLE OR
; COPIED TO A NEW PAGE IF NECESSARY
SAB.MS:! BLOCK 1 ;STARTING ADDRESS OF MESSAGE
; IF SAB.LN CONTAINS 1000, AN ERROR
; WILL OCCUR IF THIS IS NOT THE
; FIRST ADDRESS OF A PAGE
SAB.SI:! BLOCK 1 ;INFORMATION ON SPECIAL SYSTEM PID
SI.FLG==1B0 ;SET IF SI.IDX IS TO BE USED
SI.IDX==0,,-1 ;SENDER'S INDEX IN SYSTEM PID TABLE
;NOTE, SETTING SP.FLG AND FILLING IN A
;VALID INDEX IS SUFFICIENT TO IDENTIFY
;THE DESTINATION OF A SEND. IN THIS CASE,
;THE DESTINATION PID NEED NOT BE FILLED IN
SAB.PB:! BLOCK 1 ;0, or address of PIB describing PID
;for which send is to be done
SAB.SZ:! ;LENGTH OF THE SAB
DEPHASE
SUBTTL MDB - Message Descriptor Block returned by C%RECV
;This block describes the IPCF message received by C%RECV or C%BRCV
; !=======================================================!
; ! FLAGS !
; !-------------------------------------------------------!
; ! SENDER'S PID !
; !-------------------------------------------------------!
; ! RECEIVER'S PID !
; !-------------------------------------------------------!
; ! LENGTH OF MESSAGE ! ADDRESS OF MESSAGE !
; !-------------------------------------------------------!
; ! SENDER'S LOGGED-IN DIRECTORY !
; !-------------------------------------------------------!
; ! SENDER'S PRIVILEGES !
; !-------------------------------------------------------!
; ! SENDER'S CONNECTED DIRECTORY !
; !-------------------------------------------------------!
; !FLG! SYSTEM PID INDEX !
; !=======================================================!
PHASE 0
MDB.FG:! BLOCK 1 ;MESSAGE FLAGS (SEE UUOSYM.MAC)
MDB.SP:! BLOCK 1 ;SENDER'S PID
MDB.RP:! BLOCK 1 ;RECEIVER'S PID
MDB.MS:! BLOCK 1 ;MESSAGE INFORMATION
MD.CNT==-1,,0 ;WORD COUNT OF MESSAGE
MD.ADR==0,,-1 ;ADDRESS OF MESSAGE
MDB.SD:! BLOCK 1 ;SENDER'S LOGGED IN DIRECTORY
MDB.PV:! BLOCK 1 ;SENDER'S PRIVILEGES
MD.PWH==1B0 ;PROCESS HAS WHEEL PRIVILEGES
MD.POP==1B1 ;PROCESS HAS OPERATOR PRIV.
MD.PMT==1B2 ;PROCESS HAS MAINTENANCE PRIV.
MD.PJB==0,,-1 ;JOB NUMBER OF SENDER
MDB.CD:! BLOCK 1 ;SENDER'S CONNECTED DIRECTORY
MDB.SI:! BLOCK 1 ;SENDER'S SPECIAL SYSTEM PID TABLE INFO
SI.FLG==1B0 ;SET IF SI.IDX IS TO BE USED
SI.IDX==0,,-1 ;SENDER'S INDEX IN SYSTEM PID TABLE
MDB.SZ:! ;MDB LENGTH
DEPHASE
SUBTTL Special system PIDS
;For convenience, we define a macro which can generate code or data
;for all system PIDS which are of interest to the GALAXY library.
;Anyone interested in generating data or code for all special PIDS should
;define the .SPID macro, and invoke SPIDS
;The .SPID MACRO will take 4 params, a canonical index name, TOPS10 value,
;TOPS20 value, SIXBIT name of debugging component
DEFINE SPIDS,<
.SPID (SP.QSR,.IPCPQ,.SPQSR,QUASAR) ;;QUASAR
.SPID (SP.OPR,.IPCPO,.SPOPR,ORION) ;;ORION
.SPID (SP.INF,.IPCPI,.SPINF,INFO) ;;INFO
.SPID (SP.MDA,.IPCPM,.SPMDA,MDA) ;;Mountable device allocator
TOPS10<
.SPID (SP.IPC,.IPCPS,,IPCC) ;;IPC Controller
.SPID (SP.ACT,.IPCPA,,ACTDAE) ;;Accouting DAEMON
.SPID (SP.TLP,.IPCPT,,TAPLAB) ;;Tape labelling process
.SPID (SP.TOL,.IPCPC,,TAPAVR) ;;Tape Auto-Vol-Recognizer
.SPID (SP.DOL,.IPCPD,,DSKAVR) ;;Disk Auto-Vol-Recognizer
.SPID (SP.FIL,.IPCPF,,FILDAE) ;;File DAEMON
>;;End TOPS10
>;End DEFINE SPIDS
SUBTTL System Independent IPCF Codes and Constants
;The constants and codes presented here are used to prevent
;too many feature test switches in the various modules. When the two
;operating systems present two different codes for the same error
;situation, or two different indices for the same type of entry in a table,
;we can use SYSPRM to make up a canonical code for use by the GALAXY system.
;This makes for more readable code and lessens the chance of error.
;IPCF error messages
SYSPRM IPE.SQ,IPCRS%,IPCFX6 ;SENDER'S QUOTA EXHAUSTED
SYSPRM IPE.RQ,IPCRR%,IPCFX7 ;RECEIVER'S QUOTA EXHAUSTED
SYSPRM IPE.SF,IPCRY%,IPCFX8 ;SYSTEM FREE SPACE EXHAUSTED
SYSPRM IPE.DU,IPCDU%,IPCFX4 ;DESTINATION PID IS UNKNOWN
SYSPRM IPE.DD,IPCDD%,IPCFX5 ;DESTINAION PID IS DISABLED
SYSPRM IPE.WM,IPCPR%,IPCF16 ;RECEPTION IN THE WRONG MODE
SYSPRM IPE.NR,IPCUP%,777777 ;NO ROOM IN CORE (TOPS-10 ONLY)
SYSPRM IPE.NM,IPCNP%,IPCFX2 ;NO MESSAGE IS AVAILABLE
;IPCF codes
SYSPRM IP.CFV,IP.CFV,IP%CFV ;PAGE MODE BIT
SYSPRM IP.CFC,IP.CFC,IP%CFC ;FROM SYSTEM INFO OR IPCC
SYSPRM IP.CFE,IP.CFE,IP%CFE ;ERROR INDICATOR'S IN DESCRIPTOR
SYSPRM IP.CFM,IP.CFM,IP%CFM ;A RETURNED MESSAGE
SYSPRM IP.CFP,IP.CFP,IP%CFP ;PRIVILEGED SEND
SYSPRM IP.TTL,IP.CFT,IP%TTL ;TRUNCATE IF TOO LONG
SYSPRM IP.CFB,IP.CFB,IP%CFB ;DO NOT BLOCK ON RECEIVE
SYSPRM IP.CFS,IP.CFS,IP%CFS ;INDIRECT SENDERS PID
SYSPRM IP.CFR,IP.CFR,IP%CFR ;INDIRECT RECIEVERS PID
;Special System PID table indices
DEFINE .SPID(CANNAM,T10IDX,T20IDX,SYMBOL),<
SYSPRM CANNAM,T10IDX,T20IDX
>;END DEFINE .SPID
SPIDS ;Generate the special PIDS
DEFINE .SPID(CANNAM,T10IDX,T20IDX,SYMBOL),<
IFG CANNAM-MX.PID,<MX.PID==CANNAM>
>;END DEFINE .SPID
MX.PID==0 ;Start with 0 as the max
SPIDS ;Find the maximum
MX.PID==MX.PID ;Publish the maximum
SUBTTL Program internal parameters of interest
; IN ORDER THAT CALLERS OF GLXLIB PROGRAMS CAN MAKE THE MOST EFFICIENT
; USE OF THEM, SEVERAL PARAMETERS WHICH ARE REALLY INTERNAL TO THE
; SEPARATE COMPONENTS ARE DECLARED HERE, SO THAT THEY ARE ACCESSIBLE.
;
; VALUES DECLARED HERE ARE "READ-ONLY" AND SHOULD NOT BE CHANGED
; WITHOUT CONSULTING THE LISTING OF THE ACTUAL GLXLIB COMPONENT.
; PARAMETERS USED BY: GLXFIL
SYSPRM SZ.IFN,^D30,^D30 ;NUMBER OF FILES OPEN SIMULTANEOUSLY
SYSPRM SZ.BUF,406,400 ;SIZE OF BUFFER AREA
SYSPRM SZ.OBF,200,400 ;MAXIMUM WORDS XFERRED ON F%?BUF CALL
SYSPRM .PRIIN,377776,.PRIIN ;PRIMARY INPUT JFN
SYSPRM .PRIOU,377777,.PRIOU ;PRIMARY OUTPUT JFN
SYSPRM .NULIO,377775,.NULIO ;NULL I/O JFN
; PARAMETERS USED BY: GLXIPC
ND SZ.PAK,^D50 ;MAXIMUM SIZE OF A SHORT PACKET
ND SZ.PID,MX.PID+1 ;MAXIMUM NUMBER OF SYSTEM PIDS
ND RT.SLP,^D3 ;TIME TO SLEEP (SECS) BETWEEN RETRIES
ND RT.SFL,^D5 ;RETRIES ON A SEND FAILURE
ND RT.SCL,^D60 ;RETRIES ON A SYSTEM-COMPONENT TIME-OUT
; PARAMETERS USED BY: GLXMEM
ND DDCNT,5 ;PAGES ADDED TO FREE POOL BEFORE
;DUMPING DICTIONARY
ND DCT.MN,1 ;MINIMUM SIZE OF ENTRIES IN DICTIONARY
ND DCT.MX,^D50 ;MAXIMUM SIZE OF ENTRY IN DICT
ND IPCPAD,1 ;MINIMUM NUMBER OF PAGES THAT MUST BE FREE
;BEFORE M%NXPG WILL RETURN ONE
ND CNK.PM,^D24 ;CHUNK MANAGERS PAGE COUNT BEFORE CLEANUP
ND PAGAVL,^D10 ;MAX PAGES IN MEM MANAGER BEFORE CLEANUP
PT.FLG==777 ;FLAG FIELD OF PAGE TABLE ENTRY
PT.USE==1B35 ;INDICATES PAGE IS IN USE
PT.WRK==1B34 ;PAGE IS IN WORKING SET (I.E. IN CORE)
PT.ADR==1B33 ;PAGE IS ADDRESSABLE (I.E. EXISTS)
PT.INI==1B32 ;PART OF INITIAL IMAGE (I.E. CODE, ETC.)
PT.SWP==1B31 ;SWAPPABLE ON A TIMER TRAP (SYMBOLS ETC)
; PARAMETERS USED BY: GLXOTS & GLXINI
ND DORG,600000 ;ADDRESS TO BUILD DATA PAGES AT
ND CORG,400000 ;ADDRESS TO START OTS AT
ND VORG,400010 ;ADDRESS OTS DISPATCH VECTOR STARTS AT
DEFINE CDO (X)<ZZ==ZZ+1> ;COUNT ENTRIES IN DISPATCH VECTOR
ZZ==VORG
LIBVEC ;COMPUTE LAST ENTRY ADDRESS
ND VMAX,ZZ ;ADDRESS OTS DISPATCH VECTOR ENDS AT
TOPS10 < OTSNAM==SIXBIT /GLXLIB/> ;LIBRARY NAME
TOPS20 < DEFINE OTSNAM,< [ASCIZ \GLXLIB.EXE\]>>
; PARAMETERS USED BY: GLXINT
INT.MX==3 ;INTERRUPT LEVELS TO INCLUDE
SYSPRM INT.LV,1,3 ;MAXIMUM NUMBER OF ACTIVE INTERRUPT LEVELS
ND IPL.SZ,^D30 ;INTERRUPT STACK DEPTH
SUBTTL $HALT -- Halt a Program without Reset
SYSPRM $HALT,<EXIT 1,>,<HALTF> ;EXIT WITHOUT RESET
SUBTTL PDB - PARSER DESCRIPTOR BLOCK DEFINITION
; THE PARSER DESCRIPTOR BLOCK (PDB) IS THE BASIC DATA STRUCTURE USED TO
;CONTROL THE ACTION OF THE PARSER ROUTINE. THE PDB CONSISTS OF THE STANDARD
;FUNCTION DESCRIPTOR BLOCK (FDB) AS USED BY THE COMND JSYS, PLUS FOUR
;ADDITIONAL WORDS USED BY THE PARSER ROUTINE TO CONTROL THE PARSE. THE PDBDEF
;MACRO IS USED TO BUILD A PDB AND ALLOWS THE PROGRAMMER TO SPECIFY ALL OF
;THE FIELD PARAMETERS. IN ADDITION, THERE ARE A NUMBER OF MNEMONIC MACROS
;WHICH ALLOW THE USER TO BUILD FUNCTION SPECIFIC PDBS' AND PROVIDE A COMMON
;SUBSET OF THE PARAMETER FIELDS. THE PDBS' ARE LINKED THROUGH A NEXT PDB
;CHAIN FIELD, AND AN ALTERNATE PDB CHAIN FIELD TO FORM A TREE LIKE STRUCTURE
;WHICH DEFINES THE COMMAND SYNTAX. THE PARSE ROUTINE, WHEN PASSED THE ADDRESS
;OF THE ROOT OF THE TREE, THEN PARSES ONE COMPLETE COMMAND AND RETURNS CONTROL
;TO THE CALLER. THERE IS A PROVISION FOR THE USER TO SPECIFY EXIT ROUTINES
;WITHIN EACH PDB WHICH WILL BE CALLED AT CRITICAL POINTS AS THE PARSE
;PROGRESSES.
;
; THE FORMAT OF THE PARSER DESCRIPTOR BLOCK IS SHOWN BELOW:
;
;
;
; !=======================================================!
; ! FUNCTION ! FUNCTION ! ADDRESS OF NEXT FUNCTION !
; ! CODE ! FLAGS ! DESCRIPTOR BLOCK !
; !-------------------------------------------------------!
; ! DATA FOR SPECIFIC FUNCTION !
; !-------------------------------------------------------!
; ! POINTER TO HELP TEXT FOR FIELD !
; !-------------------------------------------------------!
; ! POINTER TO DEFAULT STRING FOR FIELD !
; +-------------------------------------------------------+
; ! SPECIAL ACTION ROUTINE FOR THIS PDB !
; !-------------------------------------------------------!
; ! PDB DEFAULT FILLING ROUTINE !
; !-------------------------------------------------------!
; ! ERROR ROUTINE !
; !-------------------------------------------------------!
; ! CHAIN POINTER TO LINKED PDB'S !
; !=======================================================!
SUBTTL PDBDEF - PDBDEF MACRO DEFINITION
; THE FORM OF THE PDBDEF MACRO CALL IS:
;PDBDEF (TYP,FLGS,DATA,HLPM,DEFM,LST,NXT,ERRTN,RTN,DEFR)
; ARGUMENTS TO THE PDBDEF MACRO ARE:
;
;
; TYP TYPE OF FDB, IE. .CMKEY
; FLGS FUNCTION SPECIFIC FLAGS
; DATA FUNCTION SPECIFIC DATA
; HLPM BYTE POINTER FOR HELP TEXT
; DEFM POINTER TO DEFAULT
; LST POINTER TO ALTERNATE FDB
; NXT PTR TO NEXT FDB (OPTIONAL FOR TYPE .CMKEY OR .CMSWI)
; ERRTN ROUTINE IF AN ERROR IS GOTTEN POINTING TO THIS PDB
; RTN SPECIAL ACTION ROUTINE FOR THIS PDB
; DEFR SPECIAL ROUTINE TO FILL IN DEFAULTS FOR THIS PDB
DEFINE FLD(VAL,MSK)<<VAL>B<POS(MSK)>>
DEFINE PDBDEF(TYP,FLGS,DATA,HLPM,DEFM,LST,NXT,ERRTN,RTN,DEFR),<
..XX==<FLD(TYP,CM%FNC)>+FLGS+<Z LST> ;;DEFINE .CMFNP WORD OF COMND FDB
IFNB <HLPM>,<..XX=..XX!CM%HPP> ;;IF HELP TEXT, INCLUDE FLAG BIT
IFNB <DEFM>,<..XX=..XX!CM%DPP> ;;IF DEFAULT TEXT, INCLUDE FLAG BIT
EXP ..XX ;;ASSEMBLE THE .CMFNP WORD
IFNB <DATA>,<EXP DATA>
IFB <DATA>,<EXP 0>
IFNB <HLPM>,<POINT 7,[ASCIZ \HLPM\]>
IFB <HLPM>,<0>
IFNB <DEFM>,<POINT 7,[ASCIZ \DEFM\]>
IFB <DEFM>,<0>
;;THE REST OF THE DEFINITION IS NOT USED BY THE JSYS BUT ONLY BY THE PARSER
IFB <RTN>,<0>
IFNB <RTN>,<EXP RTN>
IFB <DEFR>,<0>
IFNB <DEFR>,<EXP DEFR>
IFB <ERRTN>,<0>
IFNB <ERRTN>,<EXP ERRTN>
IFB <NXT>,<0>
IFNB <NXT>,<EXP NXT>
>;END OF DEFINITION OF PDBDEF MACRO
SUBTTL PDB -- PARSER DESCRIPTOR BLOCK
;THIS BLOCK DEFINES THE OFFSETS AFTER THE FDB FOR THE PDB
;RELATED ROUTINES.
PB%HDR==0 ;HEADER FOR THE BLOCK
PB.PDB==-1,,0 ;OFFSET FOR PDB LENGTH
PB.FDB==0,,-1 ;OFFSET FOR FDB LENGTH
PHASE 0
PB%NXT:! BLOCK 1 ;NEXT PDB TO USE
PB%RTN:! BLOCK 1 ;ACTION ROUTINE FOR THE PARSER
PB%ERR:! BLOCK 1 ;ERROR ROUTINE
PB%DEF:! BLOCK 1 ;DEFAILT FILLING ROUTINE
PB%SIZ:! ;SIZE OF MAXIMUM PDB DATA
DEPHASE
IFN FTUUOS,< .CMBRK==.CMDEF+1> ;DEFINE THE BREAK FIELD
IFN FTUUOS,< CM%BRK==1B13> ;BREAK BIT FOR THE -10
PDB.SZ==.CMBRK+PB%SIZ
COMMENT \
PDB.FD:! BLOCK .CMDEF+1 ;ALLOCATE SPACE FOR AN FDB
PDB.RT:! BLOCK 1 ;SPECIAL ACTION ROUTINE ADDRESS
PDB.DF:! BLOCK 1 ;DEFAULT FILLING ROUTINE ADDRESS
PDB.ER:! BLOCK 1 ;ERROR MESSAGE ROUTINE ADDRESS
PDB.NX:! BLOCK 1 ;ADDRESS OF PDB TO USE NEXT
PDB.SZ:! ;SIZE OF A PDB
DEPHASE
\;END OF COMMENT
SUBTTL COMMAND FUNCTION MACROS
; THE FOLLOWING FUNCTION SPECIFIC MACROS ARE PROVIDED FOR THE PURPOSE OF
;DEFINING THE PDB COMMAND TREE. THE MACROS AND THEIR SYNTAX IS SHOWN BELOW:
; Where upper case identifies keywords which must be coded as shown
;and lower case identifies variable information which must be provided
;by the programmer, e.g., a symbol which represents the address of a
;block.
; The variable parameters are as follows -
; "next__pdb_address" is the address of the next parser data block to use
;in the parse
; "table__address" is the address of keyword table in TBLUK format
; "radix" is the radix in which the number will be input, in octal
; "help__text" is a string to be output on a ?
; "noise__text" is string representing the noise phrase
; "keyword__list" is an optional list of keywords representing additional
;functions
; where the general form of a keyword parameter is
; KEYWORD (argument)
; the entire list of keywords must be enclosed by angle brackets "<", ">"
;and the keyword elements are separated blanks or a comma
; the valid keywords are
;
; $DEFAULT (default__string)
;
; $PDEFAULT (default__address)
;
; $ALTERNATE (alternate__pdb)
;
; $NEXT (next__pdb__address)
;
; $ERROR (error__routine)
;
; $ERRPDB (next_pdb)
;
; $ACTION (special__action__routine)
;
; $PREFILL (default__filling__routine)
; EXAMPLE:
; $KEY (NOIPDB,KYTBL1,<$ACTION(CHKIT)>)
;
;; $KEY (next__pdb__address,table__address,keyword__list)
;
;; $KEYDSP (table__address,keyword__list)
;
;; $NUMBER (next__pdb__address,radix,help__text,keyword__list)
;
;; $DIGIT (next__pdb__address,radix,help__text,keyword__list)
;
;; $NOISE (next__pdb__address,noise__text,keyword__list)
;
;; $SWITCH (next__pdb__address,table__address,keyword__list)
;
;; $IFILE (next__pdb__address,help__text,keyword__list)
;
;; $OFILE (next__pdb__address,help__text,keyword__list)
;
;; $FIELD (next__pdb__address,help__text,keyword__list)
;
;; $CRLF (,keyword__list)
;
;; $DIR (next__pdb__address,keyword__list)
;
;; $USER (next__pdb__address,keyword__list)
;
;; $COMMA (next__pdb__address,keyword__list)
;
;; $INIT (next__pdb__address,keyword__list)
;
;; $FLOAT (next__pdb__address,help__text,keyword__list)
;
;; $DEV (next__pdb__address,keyword__list)
;
;; $CTEXT (next__pdb__address,help__text,keyword__list)
;
;; $DATE (next__pdb__address,keyword__list)
;
;; $TIME (next__pdb__address,keyword__list)
;
;; $TAD (next__pdb__address,keyword__list)
;
;; $QUOTE (next__pdb__address,help__text,keyword__list)
;
;; $TOKEN (next__pdb__address,token__character,keyword__list)
;
;; $NODNM (next__pdb__address,help__text,keyword__list)
;
;; $ACCOUNT (next__pdb__address,help__text,keyword__list)
;
;; $UQSTR (next__pdb__address,BRKSET,help__text,keyword__list)
; THE FOLLOWING SUPPORT MACROS ARE DEFINED TO ALLOW THE USER TO DEFINE THE
;KEYWORD AND SWITCH TABLES USED BY THE KEYWORD AND SWITCH PDB'S:
;
;; DSPTAB (next__pdb__address,user__code,keyword__entry,[flags])
;
;; KEYTAB (user__code,keyword__entry)
;
;; $STAB
;
;; $ETAB
;
DEFINE $TYPE (ARG),<DEFINE .$TYP <ARG>
.%TYPE==1>
DEFINE $FLAGS (ARG),<DEFINE .$FLGS <ARG>
.%FLGS==1>
DEFINE $PDATA (ARG),<DEFINE .$DATA <ARG>
.%DATA==1>
DEFINE $HELP (ARG),<
IFDIF <ARG> <>,<
DEFINE .$HLPM <POINT 7,[ASCIZ\ARG\]>
.%HLPM==1>>
DEFINE $DEFAULT (ARG),<DEFINE .$DEFM <POINT 7,[ASCIZ\ARG\]>
.%DEFM==1>
DEFINE $PDEFAULT (ARG),<DEFINE .$DEFM <POINT 7,<ARG>>
.%DEFM==1>
DEFINE $ALTERNATE (ARG),<DEFINE .$LST <ARG+1>
.%LST==1>
DEFINE $NEXT (ARG),<DEFINE .$NXT <ARG>
.%NXT==1>
DEFINE $ERROR (ARG),<DEFINE .$ERTN <ARG>
.%ERTN==1>
DEFINE $BREAK (ARG),<DEFINE .$BREA <ARG>
.%BREA==1>
DEFINE $ERRPDB (ARG),<DEFINE .$ERTN <1B0+ARG+1>
.%ERTN==1>
DEFINE $ACTION (ARG),<DEFINE .$RTN <ARG>
.%RTN==1>
DEFINE $PREFILL (ARG),<DEFINE .$DEFR <ARG>
.%DEFR==1>
SUBTTL INITIALIZE PARSER MACRO MACROS
;INITIALIZE ALL THE INNER MACROS
;
$TYPE (0)
$FLAGS (0)
$HELP (<>)
$DEFAULT (0)
$ALTERNATE (0)
$NEXT (0)
$ERROR (0)
$BREAK (0)
$ACTION (0)
$PREFILL (0)
DEFINE NEXT(FOO),<TEMFDB##>
;***REMOVE THIS DEFINITION
C.SWIT==1B0
DEFINE SHRSWT,<C.SWIT+PDBCPY##>
DEFINE .$RESET <
SALL
XLIST
DEFINE .$TYP <0>
.%TYPE==0
DEFINE .$FLGS <0>
.%FLGS==0
DEFINE .$DATA <0>
.%DATA==0
DEFINE .$HLPM <>
.%HLPM==0
DEFINE .$DEFM <0>
.%DEFM==0
DEFINE .$LST <0>
.%LST==0
DEFINE .$BREA <0>
.%BREA==0
DEFINE .$NXT <0>
.%NXT==0
DEFINE .$ERTN <0>
.%ERTN==0
DEFINE .$RTN <0>
.%RTN==0
DEFINE .$DEFR <0>
.%DEFR==0>;END OF .$RESET
SUBTTL .$BUILD MACRO
;REDEFINE PDB.XX
DEFINE .$BUILD (%FDBL,%PDBL,%PDB,%FLAG) < ;;BUILD A PDB
%FLAG==<FLD(.$TYP,CM%FNC)>!.$FLGS!<.$LST> ;;DEFINE .CMFNP WORD OF FDB
IFN <.%BREA>,<%FLAG==%FLAG!CM%BRK> ;; IF BREAK SET IS PROVIDED
IFN <.%HLPM>,<%FLAG==%FLAG!CM%HPP!CM%SDH> ;;IF HELP TEXT, INCLUDE FLAG
;;BIT AND SUPPRESS HELP
IFN <.%DEFM>,<%FLAG==%FLAG!CM%DPP> ;;IF DEFAULT, INCLUDE FLAG BIT
%PDB: XWD %PDBL,%FDBL ;; LENGTH OF PDB,LENGTH OF FDB
EXP %FLAG ;;ASSEMBLE WORD .CMFNP OF FDB
EXP .$DATA ;;ASSEMBLE WORD .CMDAT OF FDB
IFN <.%HLPM!.%DEFM!.%BREA>,<
EXP .$HLPM> ;;ASSEMBLE WORD .CMHLP OF FDB
IFN <.%DEFM!.%BREA>,<
EXP .$DEFM> ;;ASSEMBLE WORD .CMDEF OF FDB
IFN <.%BREA>,< EXP .$BREA> ;;ASSEMBLE WORD .CMBRK FOR THE FDB
%FDBL==.-%PDB ;LENGTH OF THE FDB
IFN <.%NXT!.%DEFR!.%RTN!.%ERTN>,< EXP .$NXT > ;;ASSEMBLE WORD PDB.NX OF PDB
IFN <.%DEFR!.%RTN!.%ERTN>,<EXP .$RTN > ;;GENERTAT ACTION ROUTINE
IFN <.%DEFR!.%ERTN>,< EXP .$ERTN> ;;GENERATE THE ERROR ROUTINE
IFN <.%DEFR>,< EXP .$DEFR> ;;GENERATE DEFAULT FILLING ROUTINE
%PDBL==.-%PDB ;;LENGTH OF THE WHOLE BLOCK
IF2< PURGE %FDBL,%PDBL,%PDB,%FLAG>
LIST>;END .$BUILD
SUBTTL PARSER MACROS FOR EACH FUNCTION
DEFINE $KEYDSP (TABLE,ARGLST) <
.$RESET
$TYPE (.CMKEY)
$PDATA (TABLE)
$NEXT (0)
IRP ARGLST,<ARGLST>
.$BUILD>
DEFINE $KEY (NXT,TABLE,ARGLST) <
.$RESET
$TYPE (.CMKEY)
$PDATA (TABLE)
$NEXT (NXT)
IRP ARGLST,<ARGLST>
.$BUILD>
DEFINE $NUMBER (NXT,RADIX,HELP,ARGLST) <
.$RESET
$TYPE (.CMNUM)
$PDATA (RADIX)
$HELP (<>)
$NEXT (NXT)
IFIDN <HELP> <>,< IRP ARGLST,<ARGLST>
.$BUILD>
IFDIF <HELP> <>,<
$HELP (HELP)
IRP ARGLST,<ARGLST>
.$BUILD>>
DEFINE $DIGIT (NXT,RADIX,HELP,ARGLST) <
.$RESET
$TYPE (.CMNUX)
$PDATA (RADIX)
$HELP (<>)
$NEXT (NXT)
IFIDN <HELP> <>,< IRP ARGLST,<ARGLST>
.$BUILD>
IFDIF <HELP> <>,<
$HELP (HELP)
IRP ARGLST,<ARGLST>
.$BUILD>>
DEFINE $NOISE (NXT,TEXT,ARGLST) <
.$RESET
$TYPE (.CMNOI)
$PDATA (<POINT 7,[ASCIZ\TEXT\]>)
$NEXT (NXT)
IRP ARGLST,<ARGLST>
.$BUILD>
DEFINE $SWITCH (NXT,TABLE,ARGLST) <
.$RESET
$TYPE (.CMSWI)
$PDATA (TABLE)
$NEXT (NXT)
IRP ARGLST,<ARGLST>
.$BUILD>
DEFINE $SWIDSP (TABLE,ARGLST) <
.$RESET
$TYPE (.CMSWI)
$PDATA (TABLE)
$NEXT (0)
IRP ARGLST,<ARGLST>
.$BUILD>
DEFINE $IFILE (NXT,HELP,ARGLST) <
.$RESET
$TYPE (.CMIFI)
$HELP (<>)
$NEXT (NXT)
IFIDN <HELP> <>,< IRP ARGLST,<ARGLST>
.$BUILD>
IFDIF <HELP> <>,<
$HELP (HELP)
IRP ARGLST,<ARGLST>
.$BUILD>>
DEFINE $OFILE (NXT,HELP,ARGLST) <
.$RESET
$TYPE (.CMOFI)
$NEXT (NXT)
$HELP (<>)
IFIDN <HELP> <>,< IRP ARGLST,<ARGLST>
.$BUILD>
IFDIF <HELP> <>,<
$HELP (HELP)
IRP ARGLST,<ARGLST>
.$BUILD>>
DEFINE $FILE (NXT,HELP,ARGLST) <
.$RESET
$TYPE (.CMFIL)
$HELP (<>)
$NEXT (NXT)
IFIDN <HELP> <>,< IRP ARGLST,<ARGLST>
.$BUILD>
IFDIF <HELP> <>,<
$HELP (HELP)
IRP ARGLST,<ARGLST>
.$BUILD>>
DEFINE $FIELD (NXT,HELP,ARGLST) <
.$RESET
$TYPE (.CMFLD)
$NEXT (NXT)
$HELP (<>)
IFIDN <HELP> <>,< IRP ARGLST,<ARGLST>
.$BUILD>
IFDIF <HELP> <>,<
$HELP (HELP)
IRP ARGLST,<ARGLST>
.$BUILD>>
DEFINE $CRLF (ARGLST),<
.$RESET
$TYPE (.CMCFM)
IRP ARGLST,<ARGLST>
.$BUILD>
DEFINE $DIR (NXT,ARGLST) <
.$RESET
$TYPE (.CMDIR)
$NEXT (NXT)
IRP ARGLST,<ARGLST>
.$BUILD>
DEFINE $USER (NXT,ARGLST) <
.$RESET
$TYPE (.CMUSR)
$NEXT (NXT)
IRP ARGLST,<ARGLST>
.$BUILD>
DEFINE $COMMA (NXT,ARGLST) <
.$RESET
$TYPE (.CMCMA)
$NEXT (NXT)
IRP ARGLST,<ARGLST>
.$BUILD>
DEFINE $INIT (NXT,ARGLST) <
.$RESET
$NEXT (NXT)
$TYPE (.CMINI)
IRP ARGLST,<ARGLST>
.$BUILD>
DEFINE $FLOAT (NXT,HELP,ARGLST) <
.$RESET
$TYPE (.CMFLT)
$HELP (<>)
$NEXT (NXT)
IFIDN <HELP> <>,< IRP ARGLST,<ARGLST>
.$BUILD>
IFDIF <HELP> <>,<
$HELP (HELP)
IRP ARGLST,<ARGLST>
.$BUILD>>
DEFINE $DEV (NXT,ARGLST) <
.$RESET
$TYPE (.CMDEV)
$NEXT (NXT)
IRP ARGLST,<ARGLST>
.$BUILD>
DEFINE $CTEXT (NXT,HELP,ARGLST) <
.$RESET
$TYPE (.CMTXT)
$HELP (<>)
$NEXT (NXT)
IFIDN <HELP> <>,< IRP ARGLST,<ARGLST>
.$BUILD>
IFDIF <HELP> <>,<
$HELP (HELP)
IRP ARGLST,<ARGLST>
.$BUILD>>
DEFINE $DATE (NXT,ARGLST) <
.$RESET
$TYPE (.CMTAD)
$PDATA (CM%IDA)
$NEXT (NXT)
IRP ARGLST,<ARGLST>
.$BUILD>
DEFINE $TIME (NXT,ARGLST) <
.$RESET
$TYPE (.CMTAD)
$PDATA (CM%ITM)
$NEXT (NXT)
IRP ARGLST,<ARGLST>
.$BUILD>
DEFINE $TAD (NXT,ARGLST) <
.$RESET
$TYPE (.CMTAD)
$PDATA (<CM%IDA!CM%ITM>)
$NEXT (NXT)
IRP ARGLST,<ARGLST>
.$BUILD>
DEFINE $QUOTE (NXT,HELP,ARGLST) <
.$RESET
$TYPE (.CMQST)
$HELP (<>)
$NEXT (NXT)
IFIDN <HELP> <>,< IRP ARGLST,<ARGLST>
.$BUILD>
IFDIF <HELP> <>,<
$HELP (HELP)
IRP ARGLST,<ARGLST>
.$BUILD>>
DEFINE $UQSTR (NXT,BRKSET,HELP,ARGLST) <
.$RESET
$TYPE (.CMUQS)
$HELP (<>)
$NEXT (NXT)
$PDATA (BRKSET)
IFIDN <HELP> <>,< IRP ARGLST,<ARGLST>
.$BUILD>
IFDIF <HELP> <>,<
$HELP (HELP)
IRP ARGLST,<ARGLST>
.$BUILD>>
DEFINE $NODNM (NXT,HELP,ARGLST) <
.$RESET
$TYPE (.CMNOD)
$HELP (<>)
$NEXT (NXT)
IFIDN <HELP> <>,< IRP ARGLST,<ARGLST>
.$BUILD>
IFDIF <HELP> <>,<
$HELP (HELP)
; $FLAGS (CM%PO)
IRP ARGLST,<ARGLST>
.$BUILD>>
DEFINE $ACCOUNT (NXT,HELP,ARGLST) <
.$RESET
$TYPE (.CMACT)
$HELP (<>)
$NEXT (NXT)
IFIDN <HELP> <>,< IRP ARGLST,<ARGLST>
.$BUILD>
IFDIF <HELP> <>,<
$HELP (HELP)
IRP ARGLST,<ARGLST>
.$BUILD>>
DEFINE $TOKEN (NXT,CHAR,ARGLST) <
.$RESET
$TYPE (.CMTOK)
$PDATA (<POINT 7,[ASCIZ\CHAR\]>)
$NEXT (NXT)
IRP ARGLST,<ARGLST>
.$BUILD>
SUBTTL KEYWORD TABLE MACROS
;DSPTAB - MACRO TO BUILD A DISPATCH TABLE ENTRY
; USED IN CONJUNCTION WITH $KEYDSP MACRO
DEFINE DSPTAB (NXT,CODE,KEY,FLAGS),<
IFB <FLAGS>,<
XWD [ASCIZ\KEY\],[XWD CODE,NXT]>
IFNB <FLAGS>,<
XWD [EXP CM%FW!FLAGS
ASCIZ\KEY\],[XWD CODE,NXT]>
> ;END OF DSPTAB MACRO
;KEYTAB - MACRO TO BUILD A KEYWORD OR SWITCH TABLE ENTRY
; USED IN CONJUNCTION WITH $KEY OR $SWITCH MACRO
DEFINE KEYTAB (CODE,KEY,FLAGS),<
IFB <FLAGS>,<
XWD [ASCIZ\KEY\],CODE>
IFNB <FLAGS>,<
XWD [EXP CM%FW!FLAGS
ASCIZ\KEY\],CODE>
> ;END OF KEYTAB MACRO
;$STAB/$ETAB - MACROS TO DELINEATE START AND END OF KEYWORD TABLE
; USED IN CONJUNCTION WITH DSPTAB AND KEYTAB MACROS
DEFINE $STAB (%X,%Y) <
%X==.
XWD %Y-1,%Y-1
DEFINE $ETAB <
%Y==.-%X>>
END
; PARAMETERS USED BY: GLXOTS & GLXINI
ND DORG,600000 ;ADDRESS TO BUILD DATA PAGES AT
ND CORG,400000 ;ADDRESS TO START OTS AT
ND VORG,400010 ;ADDRESS OTS DISPATCH VECTOR STARTS AT
DEFINE CDO (X)<ZZ==ZZ+1> ;COUNT ENTRIES IN DISPATCH VECTOR
ZZ==VORG
LIBVEC ;COMPUTE LAST ENTRY ADDRESS
ND VMAX,ZZ ;ADDRESS OTS DISPATCH VECTOR ENDS AT
TOPS10 < OTSNAM==SIXBIT /GLXLIB/> ;LIBRARY NAME
TOPS20 < DEFINE OTSNAM,< [ASCIZ \GLXLIB.EXE\]>>
; PARAMETERS USED BY: GLXINT
INT.MX==3 ;INTERRUPT LEVELS TO INCLUDE
SYSPRM INT.LV,1,3 ;MAXIMUM NUMBER OF ACTIVE INTERRUPT LEVELS
ND IPL.SZ,^D30 ;INTERRUPT STACK DEPTH
SUBTTL $HALT -- Halt a Program without Reset
SYSPRM $HALT,<EXIT 1,>,<HALTF> ;EXIT WITHOUT RESET
END