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BB-D480F-SB_FORTRAN10_V10
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tables.bli
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!COPYRIGHT (C) DIGITAL EQUIPMENT CORPORATION 1972, 1985
!ALL RIGHTS RESERVED.
!
!THIS SOFTWARE IS FURNISHED UNDER A LICENSE AND MAY BE USED AND COPIED
!ONLY IN ACCORDANCE WITH THE TERMS OF SUCH LICENSE AND WITH THE
!INCLUSION OF THE ABOVE COPYRIGHT NOTICE. THIS SOFTWARE OR ANY OTHER
!COPIES THEREOF MAY NOT BE PROVIDED OR OTHERWISE MADE AVAILABLE TO ANY
!OTHER PERSON. NO TITLE TO AND OWNERSHIP OF THE SOFTWARE IS HEREBY
!TRANSFERRED.
!
!THE INFORMATION IN THIS SOFTWARE IS SUBJECT TO CHANGE WITHOUT NOTICE
!AND SHOULD NOT BE CONSTRUED AS A COMMITMENT BY DIGITAL EQUIPMENT
!CORPORATION.
!
!DIGITAL ASSUMES NO RESPONSIBILITY FOR THE USE OR RELIABILITY OF ITS
!SOFTWARE ON EQUIPMENT WHICH IS NOT SUPPLIED BY DIGITAL.
!AUTHOR: S. MURPHY/HPW/DCE/SJW/TFV/CKS/CDM/AHM/RVM/PLB/TJK/MEM
GLOBAL BIND TABLEV = #10^24 + 0^18 + #2475; ! Version Date: 5-Nov-84
%(
***** Begin Revision History *****
134 ----- ----- DEFINE FIELDS FOR E1LISTCALL AND
E2LISTCALL NODES
135 ----- ----- DEFINE DIMSUBSIZE
136 ----- ----- MODIFY DEFINITION OF DIMENSION TABLE ENTRIES
TO MAKE ROOM FOR "ARADLBL" FIELD
137 ----- ----- COMPLETE DEFINITIONS FOR I/O OPTIMIZATIONS
138 ----- ----- DEFINE NEW OPERSP EALISTCALL UNDER OPRCLS
IOLSCLS AND MOVE E2INCR FIELD
140 ---- ----- DEFINE THE MACROS "ADDRETREG" AND "REMRETREG" TO
ADD/REMOVE THE FN-VALUE RETURN REGISTERS TO A SET
OF FREE REGISTERS
141 ----- ----- CHANGE RGCENTBENTRY TO MAKE REGCANDIDATES
TABLES INTO A LINKED LIST
142 ----- ----- ADDITIONAL DEFINITIONS OF FIELDS
FOR IOLSCLS NODES
143 ----- ----- DEFINE OPRS FOR OPRCLS AND SRCID AND
OPERS MACRO TO DEFINE FIELDS FOR STATEMENT
NODES
FOR EACH STATEMENT TYPE APPROPRAITE BIND IS
CALLED XXXOS WHERE XXXX IS ID MNEMONIC
144 ----- ----- REWRITE MACROS ILFIX AND ILF1IX TO GENERATE
DABS IN LINE
145 ----- ----- ADDITIONAL DEFINITIONS TO GENERATE CMPLX
IN LINE
146 ----- ----- ADDITIONAL DEFINITIONS FOR CORRECT FOLDING
OF NESTED IMPLIED DO LOOPS WITH
DOUBLE AND SINGLE WORD DATA ITEMS
147 ----- ----- MODIFY THE MACRO "CLBNXREG" TO CALL THE
ROUTINE "CLOBBNX" - WE WERE NOT CATCHING
DIVISION OF LOGICALS AS CLOBBERING THE NEXT REG
148 ----- ----- ADD DVARFLGS TO THE DIMENSION TABLE ENTRY SO
THAT ACT1 WILL CLEAR THEM PROPERLY
149 ----- ----- REMOVE ALL REFERENCES TO "SQROP","CUBOP","P4OP"
(SINCE THEY ARE NOW UNDER EXPCIOP) -
DEFINE THE MACRO "KEXPIX" TO
DO EXPONEN OF CONSTS AT COMPILE TIME
150 ----- ----- DEFINE MACRO "POWEROF2" - TO USE IN REG
ALLOCATION OF INTEGER EXPONEN
151 ----- ----- REMOVE REFERENCE TO "CUBOP" FROM THE
DEFINITION OF "SPECOPIX"
152 ----- ----- RENAME THE MACRO "POWEROF2" TO "POWOF2" (HAD
A CONFLICT WITH A ROUTINE IN P2S2)
153 253 15425 ADD PUSHJOCD AND DIVOCD DEFINITIONS
154 261 15772 ADD XCTOCD DEFINITION
***** Begin Version 5A *****
155 551 21826 FIX DISPATCH FOR TYPE CONVERSION TO OCTAL/LOGICAL, (DCE)
156 571 22378 ADD ARALINK DEFINITION, (SJW)
***** Begin Version 5B *****
157 724 ----- MAKE TEST FOR N-ARY TREE TEST TYPE FIELD TOO, (DCE)
158 733 ----- FIX NOTCNST MACRO DEFINITION, (DCE)
***** Begin Version 6 *****
159 760 TFV 1-OCT-79 ------
Add keyword field definition and values for argument blocks in
I/O and OPEN/CLOSE statements
160 761 TFV 1-Mar-80 -----
Fix structure accesses removing KA code and adding /GFLOATING
161 1002 TFV 1-Jul-80 ------
Add a new structure to translate internal data type to
FOROTS argtype in arg block. It is used with EVALU.
162 1027 DCE 25-Nov-80 -----
Add various definitions pertaining to zero-trip DO loops (for V7).
***** Begin Version 7 *****
163 1212 TFV 29-Apr-81 ------
Add compile time data structures for CHARACTER data.
164 1214 CKS 11-May-81
Add data structures for DO/IF stack
165 1216 DCE 28-May-81 -----
Add OTSSLIST77 and OTSELIST77 entries for zero trip FOROTS calls.
166 ---- SRM 16-June-81
Add comments specifying OPERATOR values for arith ops
167 1240 CKS 28-Jul-81
Add BPADD macro to generate ADJBP instruction
168 1243 CKS/TFV 1-Aug-81
Change OPERSPs for CONCATENATION to CONCTF, CONCTM, and CONCTV.
(My full name is Thomas Francis Michael Vasak.)
169 1245 TFV 3-Aug-81 ------
Add CHARCONST for character constant operator fields. It is used
the same way as LITCONST is. Make ARASIZ a full word since character
data arrays have a size in characters.
170 1252 CDM 10-Aug-81 -----
Add inline functions op's (CMPDOP, CMPIOP, DBLCOP, DBLIOP, INTCOP,
REALIOP) for new generic functions.
171 1270 CDM 6-Oct-81
Add ATTSPGEN for bit to flag that function is generic but not
specific (octal argument is illegal).
172 1401 AHM 6-Oct-81 ------
Define OTSIFIW, OTSEIND, OPENGFIELD for arg block words.
Widen OTSKEY from 5 to 7 bits so there are no unnamed fields.
Narrow OTSIDN from 9 to 7 bits to leave room for the IFIW bits.
Delete OTSUNIT, OTSFORM, OTSARRFMTFLG for never being used.
173 1413 CDM/AHM 4-Nov-81
Add some argument node macros and increased the size of the argument
structure from 2 headers to 3 word headers.
174 1406 TFV 27-Oct-81 ------
Create the macro BPGEN to generate byte pointers that are output to
the .REL file. It will be used to generate one word global byte
pointers for extended addressing. Create the macro CHWORDLEN to
compute the number of words needed for a given length character
variable or constant.
175 1431 CKS 15-Dec-81
Add temporary CANTCONCAT macro to use as placeholder in CASE statements
1510 RVM 14-Mar-82
Add the flag ASSUMESIZFLG to identify assumed-size arrays.
1522 TFV 29-Mar-82
Remove CANTCONCAT macro.
1530 TFV 4-May-82
Add the and IOLSTATEMENT to IOLSCLS nodes. It points to the
parent I/O statement. Move E1INCR, ECNTPTR, and ELPFVLCHAIN
down by one word. They are used in E1LISTCALL and E2LISTCALL
nodes. Add the field ARGMARK to argument list nodes. It is
non-zero if the argument list contains CONCTV nodes. It
contains the pointer to the argument list for the calls to
CHMRK. and CHUNW. Also change the definitions for ARGLABEL,
ARGLINK, ARGPARENT, ARGCOUNT, ARGCHBLOCK, and ARGCALL. Finally
remove GETCORE macro and replace it in-line in SKSTMN (the
routine GETCORE in LISTNG does a CORE UUO).
1535 CDM 21-May-82
Change lots to enlarge OPERSP field from 3 to 5 bits for
additional inline functions and type conversions needed.
1573 CKS 1-Jul-82
Add fields of WHILE node in DOIFSTK
***** End V7 Development *****
1766 CDM 4-Aug-83
Compiler puts constant array ref offset calculations in TARGADDR
whenever possible. TARGADDR is a half word quantity (17 bit
plus 1 bit for sign) which can not store large numbers. A large
positive number will be truncated and appear to be a negative
number when retrieved, since the retrieved offset is sign
extended. (Also negative numbers can appear to be positive the
same way.) Before storing into TARGADDR, check if the offset
will fit.
Add STORETARGADDR, returns true if TARGADDR can be stored into.
1770 CDM 25-Jul-83
Perform argument checking for length of numeric arrays when the
length is known at compile time. Create SECDESC to return the
length needed for a secondary descriptor (or 0 if none is
needed).
Add ARRAYFL.
2007 CDM 6-Oct-83
Add DYNCONCAT for detecting dynamic concatenations.
2043 TJK 24-Feb-84
Have OPEN and CLOSE recognize the LIMIT= keyword once again.
This keyword takes an integer expression. Entries were added
to the tables OPNKWD and IOCKVEC in OPENCLOSE, and KEYWFLAG in
CFCHECK. LIMIT= is illegal for INQUIRE and is flagged as both
an ANSI and a VAX incompatibility. Note that this edit was
somewhat different for V7A and V10. Among other things, V7A
didn't have to change TABLES but V10 did.
***** Begin Version 10 *****
2200 TFV 11-Mar-83
Add INQUOS and IOCxxxx keywords for INQUIRE statement.
2202 CDM 7-Apr-83
Make use of DIMSUBSIZE in the dimension macro's. Also added
much needed comments about how subscripts are stored TWO
DIFFERENT WAYS!!
2205 CDM 21-JUN-83
Add symbols for EFIW table processing.
2216 PLB 27-Sep-83
Change BPGEN to generate OWG byte pointers to the section
given in OWGBPSECTION iff OWGBPSECTION NEQ 0. Removed
definition of BPADD MACRO, mad into a routine in OUTMOD.BLI
2230 CDM 1-Nov-83
Move DO node flags from TABLES to FIRST where they belong.
2244 CDM 13-Dec-83
Eliminate AOBJN DO loop register indexes into large arrays
(arrays in .LARG.) during code generation. Create a new
STORECLS node, STRHAOBJN to copy the right hand half of the
AOBJN register into another register. Otherwise, the negative
left half of the AOBJN register will appear to be an invalid
section number. This is to catch the cases that the skeleton
optimizer (edit 2243) can not.
2276 AlB 26-Jan-84
Added definitions which specify incompatibilities between Fortran-10/20
intrinsic functions & subroutines, and those for VAX and/or Fortran-77.
These new flags bits are placed in the table CFTABLEV in routine
CFSRCLIB, and are checked in various places by the compatibility
flagger feature.
2314 AHM 25-Feb-84
Eliminate immediate arguments for OTSKFSIZ (format size)
FOROTS arguments because size of large arrays don't fit in 18
bits. Add field named ARACONSIZ to dimension table entries,
which points to a constant table entry for ARASIZ. Also, put
dimension table declarations in the structure memory order,
and add a box for documentation.
2322 CDM 18-Apr-84
Fix array subscript calculations for /EXTEND. In PROCEQUIV and
BLDDIM, correct maximum size of an array of a legal array
declaration /EXTEND. In BLDDIM, call CNSTCM for array size
calculations to give proper underflow/overflow messages for
illegal declarations. Otherwise arrays that are too large may
not be detected.
2330 AHM 28-Mar-84
Remove reference to OWGBPSECTION in BPGEN macro - use IF
EXTENDED to decide when to generate OWGBPs. Also, define new
field macros for the P&S and address fields of OWGBPs.
2334 AHM 5-Apr-84
Define symbol ENTVECSIZE for the size of the object program's
entry vector under /EXTEND. Set it to 2 for now (start
instruction plus reenter instruction).
2336 CDM 8-Apr-84
Insert EXTERNAL command for external variables in marco
MAKECNST. This insures that they cannot be locals accidentally.
2352 CDM 1-May-84
Make intrinsic functions IAND, IOR, and IEOR inline functions. They
are converted to Fortran .AND., .OR., AND .XOR. within the skeleton
optimizer.
2355 AHM 1-May-84
Redefine ENTVECSIZE in order to make room for a version number
in the entry vector created under /EXTEND. Also, define
STARTOFF, REENTOFF, VERSIONOFF, ENTAUXSIZE and REEINDOFF to
describe the entry vector structure.
2371 TJK 14-Jun-84
Move defintions of DEFPT1 and DEFPT2 from OPTMAC to TABLES.
Also add definition of DEFPTSS, used to hold definition points
for substrings. These are all in TABLES to avoid hiding
overlapping fields.
2400 TJK 18-Jun-84
Add OTSNSLIST, OTSNELIST, OTSNSLIST77, and OTSNELIST77. These
are new IOLST. argument types for FOROTS. They are equivalent
in form to OTSSLIST, OTSELIST, OTSSLIST77, and OTSELIST77.
However, the interpretation of the increment field is
different. The old interpretation is that the increment is
the number of array elements to advance through each time
around. The new interpretation is that the increment is the
number of words (or bytes for CHARACTER data) to advance
through each time around. These new argument types are only
used by E1 and E2 lists. SLISTs still use the old types.
2413 MEM 5-Jul-84
Define OPNCTAPEFO to be the number of the keyword TAPEFORMAT
2423 AHM 19-Jul-84
Define more field names for parts of a byte pointer (prefix is
OWLBP). Also, define a symbol for the correct number of bits
in a word.
2426 MEM 16-Jul-84
Define OPNCNEDIALOG to be the number of the keyword DIALOG
(without =).
2455 MEM 30-Aug-84
Replace all occurrences of VAX with VMS.
2463 AHM 8-Oct-84
Define OPERSPs ARREFSMALL and ARREFBIG under OPRCLS ARRAYREF.
2475 MEM 5-Nov-84
Fix bugs with combinations of neg and not with double precision
octal constants.
***** End V10 Development *****
***** End Revision History *****
)%
BIND DEBUGFLG = 1; ! Compile switch to leave consistency checks in
!***************************************************************
! To optimally test whole word flags for true and false
!***************************************************************
BIND
TRUE = -1,
FALSE = 0;
MACRO
TRUTH(X) = ((X) NEQ 0)$,
FALSITY(X) = ((X) EQL 0)$;
BIND
AOBINCR = #1000001; ! Increment for AOBJN
!***************************************************************
! Define bytes for whole, left half, and right half
!***************************************************************
MACRO WHOLE=0,36$;
!***************************************************************
! Structure for an expression node
!***************************************************************
!***************************************************************
! Define the fields and subfields in an expression node
!***************************************************************
BIND EXOPWD = 1; ! Word in which the operator field and flags
! field are contained. When this number changes
! a large number of subfield definitions must be
! changed
!***************************************************************
! Define main fields
!***************************************************************
MACRO
FIRSTWORD = 0,0,FULL$,
PARENT = 0,0,RIGHT$, ! Pointer to parent node
OPERATOR = 0,EXOPWD,RIGHT$, ! Operator field
EXPFLAGS = 0,EXOPWD,LEFT$, ! Flags
OPERWORD = 0,EXOPWD,WHOLE$,
TARGET = 0,2,WHOLE$, ! Address word
ARGWD = 0,3,WHOLE$, ! Word holding pointers to the 2 args
ARGWDOFFSET = 3$,
ARG1PTR = 0,3,LEFT$,
ARG2PTR = 0,3,RIGHT$,
ARG3PTR = 0,4,LEFT$,
ARG4PTR = 0,4,RIGHT$,
COMPLEXITY = 0,0,30,6$, ! This field is used only during
! register allocation. It
! indicates the number of
! registers needed to evaluate
! this expression.
SONNXTUSE = 0,0,18,12$, ! ISN of the statment where the
! variable under this expression
! is next used (in this basic
! block) used by BB register
! allocator
%2371% ! Fields of an expression node used to hold the definition
%2371% ! points of the arguments. WARNING: These fields overlap
%2371% ! other fields of expression nodes.
%2371%
%2371% DEFPT1 = CW2L$, ! Definition point of ARG1PTR
%2371% DEFPT2 = CW0L$, ! Definition point of ARG2PTR
%2371% DEFPTSS = ARG3PTR$; ! Definition point of ARG4PTR (for SUBSTRINGs)
!***************************************************************
! Subfields in operator field
!
! 18 22 23 27 28 32 33 35
! +---------------+---------------+---------------+----+
! | VALTYPE | OPRCLS | OPERSP | |
! +---------------+---------------+---------------+----+
!
!***************************************************************
MACRO
VALTYPE = 0,EXOPWD,13,5$, ! Type for value
OPRCLS = 0,EXOPWD,8,5$, ! Class of operator
%1535% OPERSP = 0,EXOPWD,3,5$, ! Specific operator within class
!***************************************************************
! Note that of the 3 free bits at the right end of the operator
! field, bit 35 is used as a special flag bit in type-conversion
! nodes - flag for no conversion
!***************************************************************
!***************************************************************
! Subfields of OPERSP field
!***************************************************************
%1535% OPRSP1 = 0,EXOPWD,4,2$, ! Third 2 bits of OPERSP (this
! field is 00 for add and sub,
! 01 for mul and div.
%1535% OPRSP2 = 0,EXOPWD,3,2$, ! Last 2 bits of OPERSP field -
! used to differentiate add,
! sub, mul, div also used in
! type conversion nodes to
! differentiate FROMINT,
! FROMREL, FROMDBLPRC, FROMCMPLX
%1535% OPRSMIDBIT = 0,EXOPWD,5,1$, ! Third bit of OPERSP field -
! for an arith node, this bit is
! set only for OPERSP exponen.
! For a type-conversion node
! this bit is set for FROMINT,
! FROMREAL, FROMDBLPRC,
! FROMCMPLX and not set for
! FROMOCT, FROMCTL, FROMLIT,
! FROMDOCT
%1535% OPRSLASTBIT = 0,EXOPWD,3,1$, ! Last bit of OPERSP field -
! for an arith node, this bit is
! set only for sub and div.
!***************************************************************
! Concatenation of OPRCLS and OPERSP
!***************************************************************
%1535% OPR1 = 0,EXOPWD,3,10$, ! OPRCLS and OPERSP fields
! concatenated
%1535% OPR2 = 0,EXOPWD,4,9$; ! OPRCLS field and first 4 bits
! of OPERSP field
!***************************************************************
! Subfields of the above "main" subfields
!***************************************************************
MACRO
VALTP1 = 0,EXOPWD,15,2$, ! Middle 2 bits of VALTYPE are
! all thats needed for GETA1OPIX
! and ARITHOPIX
VALTP2 = 0,EXOPWD,15,3$, ! First 3 bits of VALTYPE are
! identical to the OPERSP field
! for a typecnv node to convert
! from that VALTYPE
DBLFLG = 0,EXOPWD,16,1$, ! The second bit of valtype is a
! flag for second word value
! (double prec or complex)
%1535% SDBLFLG = 0,EXOPWD,4,1$; ! The fourth bit of OPERSP for a
! typeconv node is flag for
! source is a two word value
MACRO
%1535% BOOLOPR=0,EXOPWD,3,2$, ! Boolean operator is specified
! by right 2 bits of OPERSP
! field
%1535% BOOLCLS=0,EXOPWD,4,1$, ! Boolean class (AND/OR or
! XOR/EQV) is specified by the
! leftmost of these 2 bits
%1535% BOPRFLG=0,EXOPWD,3,1$; ! The last divides booleans into
! 2 other classes - OR/XOR and
! AND/EQV
MACRO
%1535% PARENLSTFLG=0,EXOPWD,5,1$; !Flag for name which should have
! an arglist following (this bit
! is 3rd bit of OPERSP field of
! a data item)
MACRO
%1535% FORMLFLG=0,EXOPWD,3,1$; ! In OPERSP field for a data
! item, flag for "formal" (note
! however that this bit is also
! set in the OPERSP field of a
! temporary)
!***************************************************************
! Macro to construct "OPR1" and "OPR2" fields
!***************************************************************
MACRO
%1535% OPR1C(OPCLS,OPSP)=(OPCLS^5 OR OPSP)$;
MACRO
%1535% OPR2C(OPCLS,OPSP)=(OPCLS^4 OR OPSP^(-1))$;
! Constructs an operator field for the entire operator half
! word.
MACRO OPERC(VTYP,OPCLS,OPSP)=
%1535% (VTYP^13 OR OPCLS^8 OR OPSP^3)$;
%(*** To get a VALTP1 field from a VALTYPE ****)%
MACRO VTP1(VLTP)=(VLTP^(-2) AND (#3))$;
%(*** To get a VALTP2 field (first 3 bits) from a VALTYPE ***)%
MACRO VTP2(VLTP)=(VLTP^(-2))$;
%(*******FLAGS IN EXPFLAG FIELD (THESE ARE SET BY PHASE 2 SKEL AND USED BY PHASE 3*******)%
MACRO
PARENFLG=0,EXOPWD,35,1$, !FLAG FOR PARENS AROUND THIS NODE (IN SOURCE)
PAIRMODEFLG=PARENFLG$, !IN ALL STATEMENTS TO INDICATE
!DOUBLE PRECISION
SAVREGFLG=0,EXOPWD,34,1$, !"SAVE THE REG CONTAINING THE VAL OF THE VAR
! UNDER THIS NODE FOR USE LATER IN THIS BASIC BLOCK"
RVRSFLG=0,EXOPWD,33,1$, !"VAL OF 2ND SON SHOULD BE
! COMPUTED BEFORE 1ST SON
STOREFLG=0,EXOPWD,32,1$, !RESULT MUST BE STORED AFTER IT IS COMPUTED
RESRFFLG=0,EXOPWD,31,1$, !FLAG FOR "UNDER THIS NODE THERE IS A
! REFERENCE TO THE VAR INTO WHICH THE RESULT
! OF THE WHOLE EXPRESSION WILL BE STORED
USRFNREF=RESRFFLG$, !STATEMENT CONTAINS A USER
!FUNCTION REFERENCE. ONLY ON
!A STATEMENT NODE.
FNCALLSFLG=0,EXOPWD,30,1$, !FLAG FOR "FN CALLS OCCUR UNDER THIS
! NODE
ALCRETREGFLG=0,EXOPWD,29,1$, !VAL OF THIS NODE IS TO BE COMPUTED
! IN THE "FN RETURN REG"
A1VALFLG=0,EXOPWD,28,1$, !FIRST ARG IS A COMMON SUBEXPR THAT
! WAS ALREADY COMPUTED ELSEWHERE
! OR A LEAF
VALINR0=A1VALFLG$, !SET IN ENTRY STATEMENT
!BY GLOBAL ALLOCATOR TO INDICATE
!FUNCTION VALUE IS ALREADY IN
!REGISTER ZERO
LABLARGS=A1VALFLG$, !SET ON A CALL STATEMENT
!ONLY TO INDICATE THERE
!ARE LABEL ARGS
TRUEISBR=A1VALFLG$, !SET ONLY ON LOGICAL IF
!TO INDICATE THE THE TRUE
!BRANCH IS A BRANCH.
A1NOTFLG=0,EXOPWD,27,1$, !APPLY 'NOT' TO 1ST ARG
A1NEGFLG=0,EXOPWD,26,1$, !NEGATE 1ST ARG
A1SAMEFLG=0,EXOPWD,25,1$, !LOC OF COMPUTATION FOR PARENT EQLS
! LOC OF VALUE OF FIRST ARG
A1IMMEDFLG=0,EXOPWD,24,1$, !1ST ARG IS IMMED CONSTANT
A2VALFLG=0,EXOPWD,23,1$, !2ND ARG IS A COMMON SUBEXPR THAT WAS ALREADY
! COMPUTED ELSEWHERE
! OR A LEAF
A2NOTFLG=0,EXOPWD,22,1$, ! APPLY NOT TO 2ND ARG
NOLBLLST=A2NOTFLG$, !USED BY OPTIMIZER ON AN
!ASSIGNED GO TO TO INDICATE
!THAT THE PROGRAMMER DID NOT
!SUPPLY A BRANCH LIST
A2NEGFLG=0,EXOPWD,21,1$, !NEGATE 2ND ARG
A2SAMEFLG=0,EXOPWD,20,1$, !LOC OF COMPUTATION FOR PARENT EQLS
! LOC OF VALUE OF 2ND ARG
OPTCONFLG=A2SAMEFLG$, !FLAG ON THE "CONTINUE" THAT WAS INSERTED BY THE OPTIMIZER
! AT THE END OF THE PROGRAM
A2IMMEDFLG=0,EXOPWD,19,1$, !2ND ARG IS AN IMMED CONSTANT
OPTOBOTHFLG=A2IMMEDFLG$, !IF THIS BIT IS SET **AND** MEMCMPFLG IS
! ALSO SET, THEN PERFORM OPERATION TO "BOTH"
MEMCMPFLG=0,EXOPWD,18,1$; !VALUE COMPUTED TO MEMORY
MACRO CSFULLWDFLG=RVRSFLG$; !IN A COMMON SUBEXPR NODEWHERE THE
! COMMON-SUBEXPR IS A SINGLE VARIABLE (EG A
! VAR USED IN RELATIONALS OR SUBSCRIPTS)
! THIS FLAG IS SET IF THE WHOLE VARIABLE MUST BE LOADED
! (EG IT IS USED IN A RELATIONAL), RATHER
! THAN THE RIGHT-HALF BEING USABLE REGARDLESS OF
! WHATS IN THE LEFT HALF (EG IT IS USED AS A SS ONLY)
MACRO CSSSFLG=A1NOTFLG$; !IN A COMMON SUBEXPR NODE, THIS FLAG IS SET IF THE
! COMMON SUB IS EVER USED AS A SUBSCRIPT
%(***DEFINE SUBFIELDS OF THE FLAGS FIELD***)%
%(*****FLAGS FOR EACH OF THE 2 ARGS***)%
MACRO
A1FLGS=0,EXOPWD,24,5$,
A2FLGS=0,EXOPWD,19,5$;
%(****LAST 4 FLAGS - NEG, NOT, SAME, IMMED****)%
MACRO
A1FLG1=0,EXOPWD,24,4$,
A2FLG1=0,EXOPWD,19,4$;
%(***A2IMMEDFLG CONCATENATED WITH MEMCMPFLG***)%
MACRO A2IMMEMCMPFLGS=0,EXOPWD,18,2$;
%(***NEG AND NOT FLAGS******************)%
MACRO
A1NGNTFLGS=0,EXOPWD,26,2$,
A2NGNTFLGS=0,EXOPWD,21,2$;
%(****TO CLEAR THE FLAGS FOR ARG1, OR FOR ARG2*****)%
MACRO CLRA1FLGS(ANODE)=
ANODE[EXPFLAGS]_.ANODE[EXPFLAGS] AND (NOT #003700)$;
MACRO CLRA2FLGS(ANODE)=
ANODE[EXPFLAGS]_.ANODE[EXPFLAGS] AND (NOT #000076)$;
%(******TO SWAP THE FLAGS FOR ARG1 AND ARG2 (WHEN ARE ALSO SWAPPIG THE 2 ARGS******)%
%(***VALUE FOR A1FLGS OR A2FLGS FIELD WHEN ONLY THE VAL FLG IS SET***)%
BIND VLFLSET=#20;
MACRO
SWAPFLGS(NODE) =
BEGIN
REGISTER T1;
T1_.NODE[A1FLGS];
NODE[A1FLGS]_.NODE[A2FLGS];
NODE[A2FLGS]_.T1;
END $;
%(****TO SET THE FLAGS FOR ARG1 TO THOSE FOR ARG2 AND CLEAR THOSE FOR ARG2 ****)%
MACRO A2TOA1FLGS(NODE)=
BEGIN
NODE[A1FLGS]_.NODE[A2FLGS];
CLRA2FLGS(NODE);
END$;
%(***TO MOVE FLAGS FOR A SON INTO THE FLAG FIELD OF ITS PARENT (WHEN
LINKING THE SON DIRECTLY UP TO THE PARENT'S PARENT***)%
MACRO
RAISEFLGS(PARFLGS,SONFLGS)=
BEGIN
REGISTER T1;
T1_(PARFLGS XOR SONFLGS) AND NGNTFLGMSK; !TAKE XOR OF NEGFLGS AND
! NOTFLGS OF PARENT AND SON
.T1 OR (SONFLGS AND VLIMSMMSK) !USE VALFLG, SAMEFLG
! AND IMMEDFLG FOR SON
END$;
%(***MASK FOR NEG AND NOT FLAGS WITHIN A1FLGS/A2FLGS FIELDS***)%
BIND NGNTFLGMSK=#14;
%(***MASK FOR VALFLG,SAMEFLG, AND IMMEDFLG FIELDS WITHIN A1FLG/A2FLG FIELDS***)%
BIND VLIMSMMSK=#23;
%(*********SUBFIELDS OF TARGET FIELD***********)%
MACRO
INREGFLG=0,2,35,1$, !FLAG FOR VAL LEFT IN A REG
TARGTAC=0,2,23,4$, !AC TO BE COMPUTED IN
TARGAUX=0,2,27,4$, !EXTRA AC TO COMPUTE IN, USED FOR
! RELATIONALS (WHICH ARE "COMPUTED" IN A DIFFERENT
! REG FROM THE ONE THAT HOLDS THE VALUE)
TARGTMEM=0,2,0,23$, !MEMORY REF TO GET AT FINAL RESULT
TARGADDR=0,2,0,18$, !ADDRESS FIELD FOR RETRIEVING RESULT
%1766% STORETARGADDR(OFFS) = (ABS(OFFS) LSS #400000)$,
%1766% ! Checks if we can store this
%1766% ! offset in TARGADDR. Offset
%1766% ! stored in TARGADDR has 17 bits
%1766% ! of data and 1 bit of sign.
TARGXF=0,2,18,4$, !INDEX FIELD FOR RETRIEVING RESULT
TARGIF=0,2,22,1$, !INDIRECT FIELD FOR RETRIEVING RESULT
TARGIXF=0,2,18,5$; !INDIRECT AND INDEX FIELDS
%(***TO GET TARGTAC, TARGXF, OR TARGAUX FIELD FROM A TARGET WD INTO THE AC BITS OF AN INSTR***)%
%(****OR TO GET TARGET-REG FOR AN ASSIGNMENT-STATEMENT NODE INTO THE AC BITS OF AN INSTR***)%
MACRO GETTAC(NODE)=(.NODE[TARGET] AND #17^23)$,
GETTXF(NODE)=((.NODE[TARGET] AND #17^18)^5)$,
GETTAUX(NODE)= ((.NODE[TARGET] AND #17^27)^(-4))$,
GETASMNREG(STMNTNODE)= (.STMNTNODE[CW4] AND #17^23)$,
GETAIFREG(AIFNODE)=(.AIFNODE[CW5] AND #17^23)$;
%(***GET THE INDEX AND INDIRECT BITS OF A TARGET WD***)%
MACRO GETTXFI(NODE)=(.NODE[TARGET] AND #37^18)$;
MACRO IXFLD(REG)=REG^18$;
%(************************************************************
DEFINE THE STRUCTURE FOR AN EXPRESSION NODE
************************************************************)%
STRUCTURE PEXPRNODE[FTP,WD,POS,SIZE]=
%(***THE ARG "FTP" SELECTS THE ACCESSING ALGORITHM***)%
CASE .FTP OF SET
%(****FOR MOST FIELDS****)%
(@.PEXPRNODE+.WD)<.POS,.SIZE>
TES;
%(********************************************************
VALUES FOR SUBFIELDS OF OPERATOR FIELD
************************************************************)%
%(*******VALUES FOR VALTYPE FIELD*****)%
![1212], Replace LITERAL with HOLLERITH and add CHARACTER
BIND
OCTAL=0, !00000
LOGICAL=1, !00001
CONTROL=4, !00100 - CONTROL-TYPE BOOLEAN
DOUBLOCT=8, !01000
%1212% HOLLERITH=12, !01100 - nHccc form
%1212% CHARACTER=13, !01101 - 'ccc' form
INTEGER=16, !10000
BYTE=17, !10001
INDEX=18, !10010
REAL=20, !10100
DOUBLPREC=24, !11000
COMPLEX=28; !11100
%(**NOTE THAT IN THE ABOVE THE 2ND BIT IS A FLAG FOR
DOUBLE WD***)%
%(***NOTE ALSO THAT THE 2ND AND 3RD BITS DETERMINE THE CODE TO BE
GENERATED IN MANY CASES (WHERE INDEX,BYTE,LOG ARE
TREATED AS INTEGER); AND THAT THESE 2 BITS ARE
REFERENCED AS THE FIELD "VALTP1" *******)%
%(***NOTE ALSO THAT IF THE FIRST 3 BITS OF THE VALTYPES OF 2 NODES
ARE IDENTICAL, NO TYPE-CONVERSION OPERATION IS NECESSARY
WHEN COMBINING THE 2 NODES ARITHMETICALLY
*****)%
%(***NOTE ALSO THAT THE OPERSP FIELD FOR A TYPE CONVERSION NODE IS EQUAL
TO THE FIRST 3 BITS OF THE ORIGINAL TYPE
****)%
%(***VALUES FOR VALTP1 FIELD (BITS 2 AND 3 OF VALTYPE)***)%
BIND
INTEG1=VTP1(INTEGER); !00
%(***VALUES FOR VALTP2 FIELD (BITS 1,2,3 OF VALTYPE)***)%
BIND
COMPLEX2=COMPLEX^(-2), %[1027]%
LOGICAL2=LOGICAL^(-2),
REAL2=REAL^(-2);
%(***TO TEST WHETHER A GIVEN VALTYPE IS DOUBLE-WD***)%
MACRO DBLFROMVAL(VLTP)=
(VLTP^(-3) AND 1)$;
%(***TO TEST WHETHER A VALTYPE IS ONE THAT IS NEVER "CONVERTED",
IE IS ALWAYS USED AS A BIT PATTERN. THE TYPES THAT THIS IS TRUE
OF ARE: LOGICAL,OCTAL,DOUBLE-OCTAL,LITERAL, AND CONTROL***)%
MACRO BITPTNVALTYP(VLTP)=
VLTP LSS INTEGER$;
%(******VALUES FOR OPRCLS FIELD********)%
![1212], Add SUBSTRING and CONCATENATION nodes for CHARACTER data.
BIND
BOOLEAN=0, !00000
DATAOPR=1, !00001
RELATIONAL=2, !00010
FNCALL=3, !00011 (OPERATOR=nn1400)
ARITHMETIC=4, !00100 (OPERATOR=nn2nnn)
TYPECNV=5, !00101
ARRAYREF=6, !00110 (OPERATOR=nn3000)
CMNSUB=7, !00111
NEGNOT=8, !01000
SPECOP=9, !01001 A SPECIAL CASE TO BE OPTIMIZED
! (P2MUL,SQUARE,...)
FIELDREF=10, !01010
STORECLS=11, !01011 Storeclass node.
! ARG2PTR> expression node to store.
REGCONTENTS=12, !01100 Variable lives in a register
! across some region of a program.
! ARG2PTR points to symbol table ref.
LABOP=13, !01101
STATEMENT=14, !01110
IOLSCLS=15, !01111 Element in an IOLIST
INLINFN=16, !10000 A function to be generated in line
%1212% SUBSTRING=17, !10001 Character substrings.
! ARG1PTR> Upper bound expression
! ARG2PTR> Lower bound expression
! ARG4PTR> ARRAYREF or DATAOPR
%1212% CONCATENATION=18, !10010 CHARACTER CONCATENATIONs
! ARG1PTR> Length of concatenation
! ARG2PTR> Argument list for concat
%2205% EFIWREF=19; !10011 EFIW reference
!***********************************************************************
! Values for OPERSP field
!***********************************************************************
%(****FOR OPRCLS BOOLEAN****)%
BIND
ANDOP=0, !000
OROP=1, !001
EQVOP=2, !010
XOROP=3; !011
%(***BIT 35 OF EXOPWD IS USED AS A FLAG IN A BOOLEAN NODE FOR "ARG2HAS VALTYPE
CONTROL, ARG1 IS A MASK" ****)%
%(****FOR OPRCLS DATA ITEM****)%
BIND
CONSTANT=0, !000
TEMPORARY=1, !001
VARIABLE=2, !010
FORMLVAR=3, !011
ARRAYNAME=4, !100
FORMLARRAY=5, !101
FNNAME=6, !110
FORMLFN=7; !111
%(***DEFINE SUBFIELD OF OPERSP FOR DATA-ITEMS THAT DIFFERENTIATES
FN AND FORMAL FN FROM ARRAY AND FORML ARRAY FROM VAR AND FORML VAR***)%
MACRO DATOPS1=OPRSP1$; !FIRST 2 BITS OF OPERSP
%(***DEFINE VALUES OF DATOPS1 FIELD***)%
BIND VARIABL1=1,
ARRAYNM1=2,
FNNAME1=3;
%(***TO TEST FOR AN DATA ITEM AN ENTRY IN THE SYMBOL TABLE (AS OPPOSED TO A
CONSTANT OR TEMPORARY*****)%
MACRO SYMBOL(NODE)=(.NODE[OPERSP] GEQ VARIABLE)$;
%(****FOR OPRCLS RELATIONAL****)%
BIND
L=1, !001
E=2, !010
LE=3, !011
GE=5, !101
N=6, !110
G=7; !111
MACRO
EQREL(MODE) = (MODE AND #1) EQL 0$; !E AND N HAVE LAST BIT=0
MACRO
REVREL(M) = M XOR #6$; !"REVERSE" RELATIONAL FROM M (EG FOR
! REVREL(GE) GET LE )
MACRO
CMREL(M)= M XOR 4$; !TO GET "COMPLEMENT" OF A CONDITION
%(****FOR OPRCLS FNCALL****)%
BIND
NONLIBARY=0, !NOT A LIBRARY FUNCTION
LIBARY=1; !A LIBARY FUNCTION
%(****FOR OPRCLS ARITHMETIC****)%
BIND
ADDOP=0, !000 (OPERATOR=nn2000
! where nn is the data type)
SUBOP=1, !001 (OPERATOR=nn2040)
MULOP=2, !010 (OPERATOR=nn2100)
DIVOP=3, !011 (OPERATOR=nn2140)
EXPONOP=4; !100 (OPERATOR=nn2200)
! To transform ADD to SUB, SUB to ADD; MUL to DIV, DIV to MUL,
! change the rightmost bit of OPERSP.
MACRO CMPLSP(NODE)=
%1535% (NODE[OPERSP] = .NODE[OPERSP] XOR #1)$;
%(***TEST FOR OPERATOR EITHER ADD OR SUB****)%
MACRO
ADDORSUB(NODE) = .NODE[OPR2] EQL OPR2C(ARITHMETIC,ADDOP)$;
%(***TEST FOR OPERATOR FIELD EITHER MUL OR DIV***)%
MACRO
MULORDIV(NODE) = .NODE[OPR2] EQL OPR2C(ARITHMETIC,MULOP)$;
%(***TO TEST FOR OPERATOR (*KNOWN TO BE ARITH*) EQUAL TO EXPONENTIATION***)%
MACRO
%1535% EXPONEN(NODE) = .NODE[OPRSMIDBIT]$; !SECOND BIT OF OPERSP FIELD
%(***TO TEST FOR OPERATOR (KNOWN TO BE ARITH) EQUAL TO SUB OR DIV****)%
MACRO
%1535% SUBORDIV(NODE)= (.NODE[OPRSLASTBIT])$; !LAST BIT OF OPERSP FIELD IS
! SET FOR DIV AND SUB
! Tests for an operator (of unknown OPRCLS) equal to ADD or
! MUL. OPRCLS must be ARITHMETIC, OPERSP must have its 3rd and
! 5th bits 0.
MACRO ADDORMUL(NODE) =
%1535% ( (.NODE[OPERWORD] AND OPERC(0,#37,#35))
%1535% EQL OPERC(0,ARITHMETIC,0) )$;
%(*****TO TEST FOR A NODE OF UNKNOWN OPRCLS TO BE COMMUTATIVE -
VAL IS TRUE FOR ALL BOOLEANS AND FOR ADD AND MUL*********)%
MACRO COMMUTATIVE(NODE)=
(.NODE[OPRCLS] EQL BOOLEAN OR ADDORMUL(NODE) )$;
%(****FOR OPRCLS TYPECNV****)%
BIND
FROMOCT=0, !000
FROMCTL=1, !001
FROMDOCT=2, !010
FROMLIT=3, !011
FROMINT=4, !100
FROMREAL=5, !101
FROMDBLPRC=6, !110
FROMCMPLX=7, !111
%1535% FROMCHAR=8; !1000
%(***NOTE THAT THIS FIELD IS EQUAL TO THE FIRST 3 BITS OF THE VALTYPE
FIELD FOR THE VALUE BEING CONVERTED FROM(THE VALTYPE FIELD
ON THIS NODE SPECIFIES THE TYPE TO CONVERT TO)****)%
MACRO NOCNVFLG=0,EXOPWD,0,1$; ! BIT 35 OF EXOPWD IS USED AS A
! FLAG FOR "NO ACTUAL CONVERSION
! TAKES PLACE"
%(***TEST WHETHER ANY CODE MUST BE GENERATED FOR A GIVEN TYPE-CONVERSION NODE***)%
MACRO NOCNV(TPCNODE)=
BEGIN
(
(.TPCNODE[NOCNVFLG]) !IF FLAG WAS SET TO NOT ACTUALLY CONVERT
OR
(.TPCNODE[VALTP2] EQL .TPCNODE[OPERSP])
OR
( (.TPCNODE[OPERSP] LSS FROMINT) !CONVERTING FROM LOGICAL/OCTAL
! OR DOUBLE-OCTAL OR CONTROL OR LITERAL
AND
( (NOT .TPCNODE[DBLFLG]) OR .TPCNODE[SDBLFLG]) !AND IF THE DESTIN IS
!DBL WD, SO IS THE SRC
)
)
AND (NOT .TPCNODE[A2IMMEDFLG]) !IF THE ARG UNDER THE TYPE-CNV
! IS THE RIGHT HALF OF AN AOBJN VAR,
! MUST LOAD IT
END$;
%(***** For OPRCLS ARRAYREF *****)%
BIND
%2463% ARREFSMALL = 0, ! TARGADDR is actual offset for Y field
%2463% ARREFBIG = 1, ! TARGADDR points to CTE for offset
%(***FOR OPRCLS NEGNOT***************************)%
NEGOP=0,
NOTOP=1;
%(****FOR OPRCLS SPECOP (SPECIAL OPS INTRODUCED BY PHASE 2 SKEL)***)%
BIND
P2MULOP=0, !MULTIPLY BY A POWER OF 2
P2DIVOP=1, !DIVIDE BY A POWER OF 2
P2PL1OP=2, !MULTIPLY BY A POWER OF 2 PLUS 1
EXPCIOP=6; !RAISE TO A CONSTANT INTEGER POWER
! (NOT HANDLED IN RELEASE 1)
%(***FOR OPRCLS STORECLS****************************)%
BIND
STARVAL=0, !STORE CONTENTS OF AN ARRAY ELEM
STARADDR=1, !STORE PTR TO AN ARRAY ELEMENT
%2244% STRHAOBJN=2; !Store right hand half of AOBJN AC
%2244% ! into another AC.
%(***FOR OPRCLS IOLSCLS (FOR IOLIST ELEMENTS)***)%
BIND
DATACALL=0, !SINGLE DATA ITEM
SLISTCALL=1, !ARRAY REFERENCED WITHOUT SUBSCRIPTS
IOLSTCALL=2, !GROUP OF OTHER IOLSTCALL NODES
E1LISTCALL=3, !FOLDED IMPLIED DO LOOPS CREATED
E2LISTCALL=4, !BY GLOBAL OPTIMIZER ONLY DURING PHASE2
ESNGLELEM=5, !SINGLE WORD ITEM UNDER AN ELISTCALL
EDBLELEM=6; !DOUBLE WORD ITEM UNDER AN ELISTCALL
%(***FOR OPRCLS INLINFN (FNS TO BE GENERATED IN LINE)****)%
BIND
ABSFN=0,
CMPLXFN=1,
SIGNFN=2,
DIMFN=3,
MODFN=4,
MAXFN=5,
MINFN=6,
%1567% CHARFN=7,
%1567% LENFN=8,
%1567% ICHARFN=9,
%2352% IORFN=10,
%2352% IANDFN=11,
%2352% ISHFTFN=12, !** NOT YET IMPLIMENTED
%2352% ISHFTCFN=13, !** NOT YET IMPLIMENTED
%2352% IBITSFN=14, !** NOT YET IMPLIMENTED
%2352% NOTFN=15, !** NOT YET IMPLIMENTED
%2352% IEORFN=16,
%2352% BTESTFN=17, !** NOT YET IMPLIMENTED
%2352% IBSETFN=18, !** NOT YET IMPLIMENTED
%2352% IBCLRFN=19; !** NOT YET IMPLIMENTED
! *** Macro to determine for a given in-line-fn whether the arg
! should be put into the reg-for-computation before the val is
! computed (for ABS, IABS, SIGN, and LEN do not want to load the
! arg in advance).
MACRO ILFINRFC(OPSP)=( (OPSP GEQ DIMFN)
%1535% AND (OPSP LSS LENFN) )$;
![1212], Add OPERSP definitions for CONCATENATION
%(***FOR OPRCLS CONCATENATION***)%
BIND
%1243% CONCTF = 1, ! Length of result is known to compiler
%1243% CONCTM = 2, ! Maximum length of result is known to compiler
%1243% CONCTV = 3; ! Length of result is calculated at runtime
%(****VALS FOR OPR1 FIELD FOR SOME OF THE OPERATORS*****)%
BIND
%2352% ANDOPFL =OPR1C(BOOLEAN,ANDOP),
%2352% OROPFL =OPR1C(BOOLEAN,OROP),
%2352% XOROPFL =OPR1C(BOOLEAN,XOROP),
ADDOPF=OPR1C(ARITHMETIC,ADDOP),
SUBOPF=OPR1C(ARITHMETIC,SUBOP),
MULOPF=OPR1C(ARITHMETIC,MULOP),
DIVOPF=OPR1C(ARITHMETIC,DIVOP),
EXPONOPF=OPR1C(ARITHMETIC,EXPONOP),
CONSTFL=OPR1C(DATAOPR,CONSTANT),
VARFL=OPR1C(DATAOPR,VARIABLE),
FMLVARFL=OPR1C(DATAOPR,FORMLVAR),
%1770% ARRAYFL=OPR1C(DATAOPR,ARRAYNAME),
FMLARRFL=OPR1C(DATAOPR,FORMLARRAY),
%2205% FNNAMFL=OPR1C(DATAOPR,FNNAME),
NEGFL =OPR1C(NEGNOT,NEGOP),
%1567% CHARFNFL=OPR1C(INLINFN,CHARFN),
%1567% ICHARFNFL=OPR1C(INLINFN,ICHARFN),
%1567% LENFNFL=OPR1C(INLINFN,LENFN),
MODFNFL=OPR1C(INLINFN,MODFN),
STARVLFL=OPR1C(STORECLS,STARADDR);
BIND
P2MULOPF=OPR1C(SPECOP,P2MULOP),
P2DIVOPF=OPR1C(SPECOP,P2DIVOP),
P2PL1OPF=OPR1C(SPECOP,P2PL1OP);
BIND
EXPCIF=OPR1C(SPECOP,EXPCIOP);
BIND
%2007% DYNCONCAT = OPR1C(CONCATENATION,CONCTV); ! Dynamic Concatenation
%(***VALUES OF OPERATOR FIELD FOR SOME OF THE OPERATORS***)%
BIND
REALCONST=OPERC(REAL,DATAOPR,CONSTANT),
INTCONST=OPERC(INTEGER,DATAOPR,CONSTANT),
DOUBLCONST=OPERC(DOUBLPREC,DATAOPR,CONSTANT),
CPLXCONST=OPERC(COMPLEX,DATAOPR,CONSTANT),
%1212% HOLLCONST=OPERC(HOLLERITH,DATAOPR,CONSTANT),
%1245% CHARCONST=OPERC(CHARACTER,DATAOPR,CONSTANT),
INTVAR=OPERC(INTEGER,DATAOPR,VARIABLE),
INDEXVAR=OPERC(INDEX,DATAOPR,VARIABLE);
BIND INTDIVIDE=OPERC(INTEGER,ARITHMETIC,DIVOP);
BIND INTADD=OPERC(INTEGER,ARITHMETIC,ADDOP);
BIND CMPMUL=OPERC(COMPLEX,ARITHMETIC,MULOP),
CMPDIV=OPERC(COMPLEX,ARITHMETIC,DIVOP);
! Inline functions
BIND ABSFNOP=OPERC(REAL,INLINFN,ABSFN),
AMAXFNOP=OPERC(REAL,INLINFN,MAXFN),
AMINFNOP=OPERC(REAL,INLINFN,MINFN),
%1567% CHARFNOP=OPERC(CHARACTER,INLINFN,CHARFN),
CMPLXFNOP=OPERC(COMPLEX,INLINFN,CMPLXFN),
DABSFNOP=OPERC(DOUBLPREC,INLINFN,ABSFN),
DIMFNOP=OPERC(REAL,INLINFN,DIMFN),
IABSFNOP=OPERC(INTEGER,INLINFN,ABSFN),
%2352% IANDFNOP=OPERC(LOGICAL,INLINFN,IANDFN),
%1567% ICHARFNOP=OPERC(INTEGER,INLINFN,ICHARFN),
IDIMFNOP=OPERC(INTEGER,INLINFN,DIMFN),
%2352% IEORFNOP=OPERC(LOGICAL,INLINFN,IEORFN),
%2352% IORFNOP =OPERC(LOGICAL,INLINFN,IORFN),
ISIGNFNOP=OPERC(INTEGER,INLINFN,SIGNFN),
%1535% LENFNOP=OPERC(INTEGER,INLINFN,LENFN),
MODFNOP=OPERC(INTEGER,INLINFN,MODFN),
MAXFNOP=OPERC(INTEGER,INLINFN,MAXFN),
MINFNOP=OPERC(INTEGER,INLINFN,MINFN),
SIGNFNOP=OPERC(REAL,INLINFN,SIGNFN);
BIND ! Type conversion
%1252% CMPIOP=OPERC(COMPLEX,TYPECNV,FROMINT),
%1252% CMPDOP=OPERC(COMPLEX,TYPECNV,FROMDBLPRC),
CMPLXOP=OPERC(COMPLEX,TYPECNV,FROMREAL),
%1252% DBLCOP=OPERC(DOUBLPREC,TYPECNV,FROMCMPLX),
DBLEOP=OPERC(DOUBLPREC,TYPECNV,FROMREAL),
%1252% DBLIOP=OPERC(DOUBLPREC,TYPECNV,FROMINT),
DFLOATOP=OPERC(DOUBLPREC,TYPECNV,FROMINT),
FLOATOP=OPERC(REAL,TYPECNV,FROMINT),
IDINTOP=OPERC(INTEGER,TYPECNV,FROMDBLPRC),
%1252% INTCOP=OPERC(INTEGER,TYPECNV,FROMCMPLX),
INTOP=OPERC(INTEGER,TYPECNV,FROMREAL),
IFIXOP=OPERC(INTEGER,TYPECNV,FROMREAL),
%1252% REALIOP=OPERC(REAL,TYPECNV,FROMINT),
REALOP=OPERC(REAL,TYPECNV,FROMCMPLX),
SNGLOP=OPERC(REAL,TYPECNV,FROMDBLPRC);
BIND LTOP=OPERC(CONTROL,RELATIONAL,L),
EQOP=OPERC(CONTROL,RELATIONAL,E),
LEOP=OPERC(CONTROL,RELATIONAL,LE),
GEOP=OPERC(CONTROL,RELATIONAL,GE),
NEOP=OPERC(CONTROL,RELATIONAL,N),
GTOP=OPERC(CONTROL,RELATIONAL,G);
BIND FIXOP=OPERC(INTEGER,TYPECNV,FROMREAL);
BIND
DATACLFL=OPERC(0,IOLSCLS,DATACALL),
SLISTCLFL=OPR1C(IOLSCLS,SLISTCALL),
IOLSTCFL=OPERC(0,IOLSCLS,IOLSTCALL),
E1LISTCFL=OPERC(0,IOLSCLS,E1LISTCALL),
E2LISTCFL=OPERC(0,IOLSCLS,E2LISTCALL);
BIND DOSTATEMENT=STOPERC(STATEMENT,DOID);
BIND CONTSTATEMENT=STOPERC(STATEMENT,CONTID);
%(***DEFINE OPRCLS+SRCID FOR STATEMENTS***)%
MACRO
OPERS(OPCLS,SORCID)=(OPCLS^7+SORCID)$, !DEFINE CONCATENATED FIELDS
OPRS=0,EXOPWD,1,12$; !DEFINE OPRS FIELD
BIND
ASGNOS=OPERS(STATEMENT,ASGNID),
ASSIOS=OPERS(STATEMENT,ASSIID),
CALLOS=OPERS(STATEMENT,CALLID),
CONTOS=OPERS(STATEMENT,CONTID),
DOOS=OPERS(STATEMENT,DOID),
ENTROS=OPERS(STATEMENT,ENTRID),
COMNOS=OPERS(STATEMENT,COMNSUB),
GOTOOS=OPERS(STATEMENT,GOTOID),
AGOOS=OPERS(STATEMENT,AGOID),
CGOOS=OPERS(STATEMENT,CGOID),
IFAOS=OPERS(STATEMENT,IFAID),
IFLOS=OPERS(STATEMENT,IFLID),
RETUOS=OPERS(STATEMENT,RETUID),
STOPOS=OPERS(STATEMENT,STOPID),
READOS=OPERS(STATEMENT,READID),
WRITOS=OPERS(STATEMENT,WRITID),
DECOOS=OPERS(STATEMENT,DECOID),
ENCOOS=OPERS(STATEMENT,ENCOID),
REREDOS=OPERS(STATEMENT,REREDID),
FINDOS=OPERS(STATEMENT,FINDID),
CLOSOS=OPERS(STATEMENT,CLOSID),
! INPUOS=OPERS(STATEMENT,INPUID),
! OUTPOS=OPERS(STATEMENT,OUTPID),
BACKOS=OPERS(STATEMENT,BACKID),
BKFILOS=OPERS(STATEMENT,BKFILID),
REWDOS=OPERS(STATEMENT,REWDID),
SKFILOS=OPERS(STATEMENT,SKFILID),
SKRECOS=OPERS(STATEMENT,SKRECID),
UNLODOS=OPERS(STATEMENT,UNLODID),
! RELSOS=OPERS(STATEMENT,RELSID),
ENDFOS=OPERS(STATEMENT,ENDFID),
ENDOS=OPERS(STATEMENT,ENDID),
PAUSOS=OPERS(STATEMENT,PAUSID),
OPENOS=OPERS(STATEMENT,OPENID),
SFNOS=OPERS(STATEMENT,SFNID),
FORMOS=OPERS(STATEMENT,FORMID),
! BLTOS=OPERS(STATEMENT,BLTID),
REGOS=OPERS(STATEMENT,REGMASK),
%2200% INQUOS=OPERS(STATEMENT,INQUID);
%(********VALUES FOR SPECIAL OPERATOR SUBFIELDS***********)%
%(****USED FOR OPRCLS BOOLEAN*****)%
BIND
ANDORCLS=0, !VALUE OF BOOLCLS FOR AND/OR NODES
ANDOPF=0, !VALUE OF BOPRFLG FOR AND/EQV NODES
XOROROPF=1; !VALUE OF BOPRFLG FOR OR/XOR NODES
%(****************************************
TO CHECK FOR VALUES THAT FIT IN SINGLE WD
****************************************)%
MACRO SINGLWD(NODE)= NOT (.NODE[DBLFLG])$;
%(***************************************************************************
TO TEST A CONSTANT NODE FOR BEING AN IMMEDIATE-SIZE CONSTANT
***************************************************************************)%
MACRO IMMEDCNST(NODE)=
BEGIN
EXTERNAL KDPRL; !THESE GLOBALS ARE USED IN CALLING THE MACRO MODULE
%[761]% EXTERNAL KGFRL; ! For folding /GFLOATING DP to SP
EXTERNAL C1H,C1L,C2H,COPRIX; ! THAT ROUNDS REAL NUMBERS
EXTERNAL CNSTCM;
CASE .NODE[VALTP1] OF SET
%(***INTEGER CONSTANTS ARE IMMED SIZE IFF LH OF ABSOLUTE VAL IS 0***)%
((ABS(.NODE[CONST2]) AND #777777000000) EQL 0);
%(***REAL CONSTANTS ARE IMMED SIZE IFF THE RIGHT HALF WD IS
ALL 0'S*******)%
BEGIN
%(***BECAUSE WE KEEP 2 WDS OF PRECISION THRUOUT COMPILE TIME,
WE MUST EXAMINE WHAT THE ROUNDED CONSTANT WILL BE***)%
C1H_.NODE[CONST1]; C1L_.NODE[CONST2];
![761] Round DP based on /GFLOATING flag
%[761]% IF .GFLOAT THEN COPRIX_KGFRL ELSE COPRIX_KDPRL; !ROUND THE NUMBER IN C1H-C1L
CNSTCM(); ! LEAVING THE RESULT IN C2H
(.C2H AND #777777) EQL 0
END;
%(***DOUBLE-PREC CONSTANTS CAN NOT BE TREATED IMMED MODE***)%
FALSE;
%(***COMPLEX CONSTANTS CAN BE TREATED IMMED MODE IFF THE REAL PART IS
IMMED SIZE AND THE IMAGINARY PART IS 0***)%
((.NODE[CONST1] AND #777777) EQL 0) AND (.NODE[CONST2] EQL 0)
TES
END$;
%(***TO TEST FOR A CONSTANT NEGATIVE***********)%
MACRO NEGATIVC(CNNODE)=
BEGIN
IF .CNNODE[VALTP1] EQL INTEG1
THEN
.CNNODE[CONST2] LSS 0
ELSE
.CNNODE[CONST1] LSS 0
END$;
%(*****************OPCODE FIELDS USED EXPLICITLY***************************)%
BIND
JRSTOC=#254^27,
JUMPOC=#320^27,
SKIPOC=#330^27,
SKIPGEOC=#335^27;
BIND
INDBIT=1^22; !INDIRECT BIT
BIND
ADDBOCD=#273,
ADDIOCD=#271,
ADDMOCD=#272,
AOJAOCD=#344,
AOSOCD=#350,
ASHOCD=#240,
CAIOCD=#300,
CAMOCD=#310,
DMOVEOCD=#120,
DMOVEMOCD=#124,
FADRBOCD=#147,
FADRMOCD=#146,
FDVRMOCD=#176,
FIXOCD=#122,
FLTROCD=#127,
FSCOCD=#132,
HRLZIOCD=#515,
IDIVMOCD=#232,
IMULMOCD=#222,
JRSTOCD=#254,
JUMPOCD=#320,
JUMPGEOCD=#325,
JUMPLOCD=#321,
MOVEIOCD=#201,
MOVEOCD=#200,
MOVEMOCD=#202,
MOVNOCD=#210,
MOVNIOCD=#211,
MOVNMOCD=#212,
MOVNSOCD=#213,
MOVSIOCD=#205,
SETCAMOCD=#452,
SETCMOCD=#460,
SETCMBOCD=#463,
SETZBOCD=#403,
SETOBOCD=#477,
SKIPOCD=#330,
SOJAOCD=#364,
SOSOCD=#370,
SUBIOCD=#275,
PUSHJOCD=#260,
DIVOCD=#230,
XCTOCD=#256,
SUBMOCD=#276;
!***************************************************************
! Define the fields for IOLSCLS nodes. DATACALLs and SLISTCALLs
! have 4 words, IOLISTCALLs, E1LISTCALLs, and E2LISTCALLs have 6
! words. The fields are:
!
! -------------------------------------------------
! 0 ! IOLSTLBL AND IOLCMPLX ! CLINK !
! -------------------------------------------------
! 1 ! DCALLELEM ! OPERATOR !
! ! SCALLELEM ! !
! ! IOLSTPTR ! !
! ! ELSTPTR ! !
! -------------------------------------------------
! 2 ! IOLALTCMPLX ! SCALLCT !
! ! ! IOLCOMNSUB !
! -------------------------------------------------
! 3 ! IOLFLAGS ! IOLSTATEMENT !
! ! IOLDYNFLG ! !
! -------------------------------------------------
! 4 ! E1INCR ! ECNTPTR !
! -------------------------------------------------
! 5 ! (not used) ! ELPFVLCHAIN !
! -------------------------------------------------
!
! The fields under ELSTPTR are:
!
! -------------------------------------------------
! 0 ! E2INCR ! CLINK !
! -------------------------------------------------
! 1 ! E2ARREFPTR ! OPERATOR !
! -------------------------------------------------
!
!***************************************************************
! Fields in all IOLSCLS nodes
MACRO
IOLSTLBL = 0,0,LEFT$, ! Pointer to the label used for the
! argument list to the IOLST. call
%1530% IOLFLAGS = 0,3,LEFT$, ! Flags field
%1530% IOLDYNFLG = 0,3,35,1$, ! Flag for this IOLST. call has
%1530% ! dynamic concatenations under it
%1530% IOLSTATEMENT = 0,3,RIGHT$, ! Pointer to the I/O statement above
%1530% ! this IOLSCLS node
! Fields in DATACALL nodes
DCALLELEM = 0,1,LEFT$, ! Pointer to the expression
! Fields in SLISTCALL nodes
SCALLELEM = 0,1,LEFT$, ! Pointer to the arrayname
SCALLCT = 0,2,RIGHT$, ! Number of elements in the array
! Fields in IOLSTCALL nodes
IOLSTPTR = 0,1,LEFT$, ! Pointer to linked list of subnodes
IOLCMPLX = SRCCMPLX$, ! Complexity for this iolist
IOLCOMNSUB = SRCCOMNSUB$, ! Pointer to common subexpressions
IOLALTCMPLX = 0,2,LEFT$, ! Alternate complexity in E1LISTCALL
! and E2LISTCALL nodes
! Fields in E1LISTCALL and E2LISTCALL nodes
%1530% ECNTPTR = 0,4,RIGHT$, ! Pointer to expression for number of
! elements of each array
ELSTPTR = 0,1,LEFT$, ! Pointer to linked list of ARRAYREFs
%1530% ELPFVLCHAIN = 0,5,RIGHT$, ! Pointer to linked list of statements
! setting up final loop index values
! Fields in E1LISTCALL nodes
%1530% E1INCR = 0,4,LEFT$, ! Pointer to the increment expression
! Fields of the elements of the linked list under an E2LISTCALL
E2INCR = 0,0,LEFT$, ! Pointer to the increment expression
E2ARREFPTR = 0,1,LEFT$; ! Pointer to the ARRAYREF node
! Define names for fields of a one word local byte pointer
! !=========================================================================!
! ! P ! S !G!I! X ! Y (Address) !
! !=========================================================================!
MACRO
%2423% OWLBPP = 30,6 $, ! Position field
%2423% OWLBPS = 24,6 $, ! Size field
! Local/global flag (unused)
! Indirect bit (unused)
! Index field (unused)
%2423% OWLBPADDR = 0,18 $, ! Address field
! Define names for fields of a one word global byte pointer
! !=========================================================================!
! ! P&S ! Y (Address) !
! !=========================================================================!
%2330% OWGBPADDR = 0,30 $, ! Address field
%2330% OWGBPP&S = 30,6 $; ! Combination P&S field
! Object program's entry vector:
! !=========================================================================!
! ! JRST (254000) ! Object program's start address !
! !-------------------------------------------------------------------------!
! ! JRST @ (254020) ! Address of EFIW (below) !
! !-------------------------------------------------------------------------!
! ! Space for a version number (compiler leaves it 0 for now) !
! !=========================================================================!
! ! .EFIW REENT.## !
! !=========================================================================!
BIND ! Object program entry vector
%2355% STARTOFF = 0, ! Start entry
%2355% REENTOFF = 1, ! Reenter entry
%2355% VERSIONOFF = 2, ! Version number entry
%2355% ENTVECSIZE = 3, ! Size of the entry vector
%2355% REEINDOFF = ENTVECSIZE+0, ! First word of the auxiliary block
! (indirect word for REENT.##)
%2355% ENTAUXSIZE = 1; ! Size of the auxiliary block after
! the entry vector
%(***************************************************************************
DEFINE AN OBJECT-CODE WORD AS A STRUCTURE.
DEFINE THE FIELDS OF THAT WORD FOR FOROTS ARG BLOCKS.
***************************************************************************)%
STRUCTURE OBJECTCODE[WD,POS,SIZE]=
(.OBJECTCODE+.WD)<.POS,.SIZE> ;
%(***DEFINE THE FIELDS OF AN INSTRUCTION***)%
MACRO
OBJADDR=0,0,18$, ! Address field
OBJIXF=0,18,5$, ! Indirect and index fields
OBJREG=0,23,4$, ! Register field
OBJOPCOD=0,27,9$; ! Opcode
%(***DEFINE THE FIELDS USED FOR ARG BLOCKS***)%
MACRO
OTSWHOLE=0,0,36$, ! Field for the whole word
OTSCNT=0,27,9$, ! Dimensions in a NAMELIST variable
OTSTYPE=0,23,4$, ! Value-type always goes in bits 9-12
OTSINX=0,18,4$, ! Index field
OTSIND=0,22,1$, ! Indirect bit
OTSADDR=0,0,18$, ! Address field
%1401% OTSFSIZ=0,18,18$, ! FORMAT size
%1401% OTSIDN=0,27,7$, ! Identifies IOLIST element class
%1401% OPENGFIELD=0,27,7$, ! Differentiates OPEN statement args
OTSMEMRF=0,0,23$, ! All 23 bits for memory references
%1401% OTSIFIW=0,35,1$, ! 0=>I+X+33 bit Y, 1=>I+X+18 bit Y
%1401% OTSEIND=0,34,1$, ! Indirect bit for EFIW, 0 for IFIW
![760] Field definitions and values for I/O keywords
%1401% OTSKEY=0,27,7$; ! Differentiates I/O arguments
%[760]%
%[760]% %(***Define values for OTSKEY field in I/O arg blocks***)%
%[760]%
%[760]% BIND
%[760]% OTSKUNIT = 1, ! UNIT=
%[760]% OTSKFMT = 2, ! FMT=
%[760]% OTSKFSIZ = 3, ! format length in words
%[760]% OTSKEND = 4, ! END=
%[760]% OTSKERR = 5, ! ERR=
%[760]% OTSKIOS = 6, ! IOSTAT=
%[760]% OTSKREC = 7, ! REC=
%[760]% OTSKNAME = #10, ! namelist name
%[760]% OTSKMTOP = #11, ! magtape opcode for REWIND, UNLOAD, etc.
%[760]% OTSKEDARR = #12, ! ENCODE/DECODE array name
%[760]% OTSKEDSIZ = #13; ! ENCODE/DECODE count
%(***DEFINE VALUES FOR IDN FIELD FOR IOLIST ELEMENTS***)%
![1216] Add OTSSLIST77 and OTSELIST77
BIND
OTSZER=0, ! Illegal
OTSDATA=1, ! DATA call
OTSSLIST=2, ! F66 SLIST (one-trip loops)
OTSELIST=3, ! F66 ELIST (one-trip loops)
OTSFIN=4, ! FIN call (end-of-list)
%1216% OTSSLIST77=5, ! F77 SLIST (potential zero trip)
%1216% OTSELIST77=6, ! F77 ELIST (potential zero trip)
%2400% OTSNSLIST=7, ! New F66 SLIST (one-trip loops) E1 lists only
%2400% OTSNELIST=8, ! New F66 ELIST (one-trip loops) E2 lists only
%2400% OTSNSLIST77=9, ! New F77 SLIST (potential zero-trip) E1 lists only
%2400% OTSNELIST77=10; ! New F77 ELIST (potential zero-trip) E2 lists only
BIND
OTSZERWD=OTSZER^27,
OTSFINWD=OTSFIN^27;
%(***DEFINE ARG TYPE CODES THAT ARE USED FOR FOROTS CALLS***)%
BIND ADDRTYPE=#7, !TYPE CODE FOR A LABEL
IMMEDTYPE=0; !TYPE CODE INDICATING TO PICK UP ARG IMMED MODE
%(***************************************************************************
SPECIFIC VALUES FOR FIELDS IN AN ARITHMETIC-IF NODE
***************************************************************************)%
%(***VALUES FOR AIFLBEQV FIELD****)%
BIND
NOLBEQV=0,
LELBEQV=1, !LSS LABEL SAME AS EQL LABEL
LGLBEQV=2, !LSS LABEL SAME AS GTR LABEL
GELBEQV=3; !GTR LABEL SAME AS EQL LABEL
%(***VALUES FOR AIFLBNXT FIELD*******)%
BIND
NOLBNXT=0,
LLBNXT=1, !LSS LABEL IS NEXT STMNT
ELBNXT=2, !EQL LABEL IS NEXT STMNT
GLBNXT=3; !GTR LABEL IS NEXT STMNT
%(***WHEN SWAP THE GTR AND LESS LABELS (BECAUSE MULTIPLY BY -1), USE THE
FOLLOWING MACRO TO ADJUST THE "AIFLBNXT" AND "AIFLBEQV" FIELDS***)%
MACRO SWPAIFFLGS(STMNT)=
BEGIN
IF .STMNT[AIFLBNXT] !IF LAST BIT OF AIFLBNXT IS ON
THEN
STMNT[AIFLBNXT]_.STMNT[AIFLBNXT] XOR #2; !THEN COMPLEMENT 1ST BIT
IF .STMNT[AIFLBEQV] !IF LAST BIT OF AIFLBEQV ON
THEN
STMNT[AIFLBEQV]_.STMNT[AIFLBEQV] XOR #2; !THEN COMPLEMENT 1ST BIT
END$;
!***************************************************************
! Define the structure of an argument list. Certain fixed
! fields on the list will be referenced simply by name. Fields
! corresponding to the nth arg will be referenced by [n,name].
! Note that the first arg has N = 1 (not!!!! 0). Note that the
! count field of the list will be positive and equal to the
! number of args.
!***************************************************************
%1530% BIND ARGHDRSIZ = 4; ! The fixed size of the argument list
STRUCTURE ARGUMENTLIST[ARGINDEX,WD,POS,SIZE]=
%1413% (@.ARGUMENTLIST+ARGHDRSIZ+(.ARGINDEX-1)+.WD)<.POS,.SIZE>;
!***************************************************************
! This macro defines the number of words necessary in an ARGLIST
! in terms of the number of args.
!***************************************************************
%1413% MACRO ARGLSTSIZE(ARGCNT)=(ARGHDRSIZ+(ARGCNT))$;
!***************************************************************
! Define the fixed fields that occur at the start of every
! argument list - Define all these fields in terms of a negative
! number of words from the entry for the first argument (hence
! have the ARGINDEX field be 1).
!
! ---------------------------------
! -4 ! ARGLABEL ! ARGLINK !
! ---------------------------------
! -3 ! ARGPARENT ! ARGCOUNT !
! ---------------------------------
! -2 ! ARGCHBLOCK ! ARGCALL !
! ---------------------------------
! -1 ! ARGMARK ! unused !
! ---------------------------------
! 0 ! AVALFLG ! ARGNPTR ! (first argument)
! ---------------------------------
! 1 ! AVALFLG ! ARGNPTR ! (second argument)
! ---------------------------------
! etc.
!
!***************************************************************
MACRO
%1530% ARGLABEL = 1,-4,LEFT$, ! Pointer to label table for arguments
%1530% ARGLINK = 1,-4,RIGHT$, ! Link to next arg node
%1530% ARGPARENT = 1,-3,LEFT$, ! Pointer to parent subroutine/function
%1530% ARGCOUNT = 1,-3,RIGHT$, ! Count of number of args
%1530% ARGCHBLOCK = 1,-2,35,1$, ! Flag - "Create arg check block for
! this arg list"
%1530% ARGCALL = 1,-2,RIGHT$, ! Address in object code of last call
%1530% ARGMARK = 1,-1,LEFT$, ! Pointer to the argument list for the
! calls to CHMRK. and CHUNW. for calls
! with CONCTV nodes as arguments
!***************************************************************
! Define the fields that are repeated for each argument. Will
! always reference these fields by a ref of the form:
! ALIST[N,FIELDNAME] where N is the number of the argument
! desired.
!***************************************************************
%1413% ARGFULL = 0,FULL$, ! Full argument field
AFLGFLD = 0,LEFT$, ! Argument flags
AVALFLG = 0,35,1$, ! Flag for argument is a DATAOPR
! or a common subexpression.
ARGNPTR = 0,RIGHT$, ! Pointer to the expression node
! for the argument
P1AVALFLG = 0,0,35,1$; ! Field to reference the AVALFLG
! by using the BASE structure on
! a given word. Used in PHAS1.
%(*******DEFINE FIELDS USED IN THE ARGUMENT LIST AT AN ENTRY STATEMENT*****)%
MACRO ENTGALLOCFLG=0,35,1$, !FLAG FOR "GLOBAL ALLOCATOR HAS ASSIGNED THIS
! VAR TO LIVE IN A REGISTER"
ENTSAVREGFLG=0,34,1$, !FLAG INDICATING THAT IT WILL BE USEFUL TO
! HAVE THIS VAR IN A REG LATER IN THIS BASIC
! BLOCK (FLAG IS SET BY BASIC BLOCK ALLOCATOR)
ENTNOCOPYFLG=0,33,1$, !FLAG INDICATING THAT NO LOCAL COPY OF THE ARG
! SHOULD BE MADE
ENTSONNXTUSE=0,22,11$, !BLOCK-INTERNAL-SEQ-NUMBER OF THE STMNT
! WHERE THIS VAR IS NEXT USED (0 IF IT IS
! NOT USED IN THE 1ST BASIC BLOCK)
ENTAC=0,18,4$; !AC TO BE USED WHEN PICKING
! UP THIS ARG
%(***************************************************************************
DEFINE THE STRUCTURE THAT WILL BE MAPPED ON THE LIBRARY FN ATTRIBUTE
TABLE.
FOR EACH LIBRARY-FN WILL HAVE A "LIBRARY-FN-INDEX" THAT INDICATES ITS
POSITION IN THIS TABLE. THE FIRST ENTRY HAS INDEX =0.
***************************************************************************)%
STRUCTURE LIBATTSTR[FNINDEX,WD,POS,SIZE,CODE,ARGTYP1]=
%(***FOR MOST FIELDS BOTH "CODE" AND "ARGTYP1" ARE 0***)%
IF .CODE EQL 0
THEN
(.LIBATTSTR+2*.FNINDEX+.WD)<.POS,.SIZE>
%(***FOR GENERIC FUNCTIONS ONLY - TO PICK UP THE NAME OF THE ACTUAL
FUNCTION TO USE FOR A GIVEN ARG-TYPE.
HAVE "CODE" EQUAL TO 1, "ARGTYP1" EQUAL TO THE VALTP1
FIELD OF THE ARGUMENT.
**********)%
ELSE
%(***GO INDIRECT THRU THE "ATTGENPTR" FIELD - ADD "ARGTYP1" TO
THE PTR IN THAT FIELD TO GET A PTR TO THE WD THAT
INDICATES THE ACTUAL FN TO USE (THAT WD WILL ITSELF CONTAIN
A PTR BACK TO A FUNCTION-TABLE ENTRY)
*******)%
(.(.LIBATTSTR+2*.FNINDEX+.WD)<.POS,.SIZE> + .ARGTYP1)<0,36>;
%(***DEFINE MACROS THAT DESCRIBE THE FIELDS FOR A GIVEN FUNCTION INDEX***)%
MACRO
ATTFNATTRIB=0,0,36,0,0$, !THE FIRST WORD OF THE ENTRY WILL BE
! COPIED INTO THE SYMBOL TABLE ENTRY
! FOR THE FUNCTION NAME (INTO THE IDFNATTRIB FIELD)
ATTINLINFLG=0,35,1,0,0$, !BIT 0 OF 1ST WD IS FLAG FOR IN-LINE-FN
ATTGENERFLG=0,33,1,0,0$, ! GENERIC FN FLAG
ATTARGTYP=0,28,5,0,0$, ! VALTYPE FOR EXPECTED ARG
ATTRESTYPE=0,23,5,0,0$, ! VALTYPE OF RESULT
ATTARGCT=0,18,5,0,0$, ! NUMBER OF ARGS EXPECTED
ATTNEWOPR=0,0,18,0,0$, !OPERATOR TO BE SUBSTITUTED FOR FN CALL
! IF THIS FN IS TO BE GENERATED IN LINE
%1270% ATTSPGEN=1,35,1,0,0$, ! Bit 0 of 2nd word is flag for generic
! but not specfic function. (octal
! argument is illegal)
%1567% ATTFNFOLD=1,34,1,0,0$, ! May be able to fold fn call into a
! constant.
ATTGENPTR=1,0,18,0,0$, ! For generic fns only - ptr to subtable
! describing which fns to use for each
! arg type
ATTACTFN=1,0,18,1$; ! For generic fns only - to get a ptr to
! the actual fn to use will go indirect
! thru the "ATTGENPTR" field and then
! add on the type of the arg
BIND ILGARGTYPE=-1; ! For generic fns - If a given arg type
! is illegal the "ATTACTFN" field for
! that type will contain this code
BIND VARGCTFLG=#37; ! Functions that can take an arbitrary
! number of args (eg MAX,MIN) have the
! "ATTARGCT" set to this val
%(*************************************************************************
Define the bits in CFTABLEV which describe the differences
between Fortran-10/20 intrinsic functions and subroutines
and those of VMS and the Fortran-77 standard.
These bits are used in compatibility flagging.
These definitions were added in edit [2276]
*************************************************************************)%
BIND
%2455% CFFNVMS=1^0, ! Intrinsic function on VMS, but not us
%2455% CFNOTFNVMS=1^1, ! Intrinsic function for us, but not VMS
CFNOTFNF77=1^2, ! Intrinsic function for us, but not Fortran-77
%2455% CFSBVMS=1^3, ! Subroutine on VMS, but not for us
%2455% CFNOTSBVMS=1^4, ! Subroutine for us, but not VMS
CFNOTSBF77=1^5, ! Subroutine for us, but not Fortran-77
%2455% CFNOTGNUS=1^6, ! Function is generic on VMS, but not us
%2455% CFNOTGNVMS=1^7, ! Function is generic for us, but not VMS
CFNOTGNF77=1^8, ! Function is generic for us, but not Fortran-77
%2455% CFSBDIFF=1^9; ! Subroutine supplied by VMS, but is not
! entirely compatible with us
%(***************************************************************************
DEFINE THE STRUCTURE TO BE MAPPED ON THE LIST OF ARGTYPES
TO GET THE VALUES THAT OCCUR IN AN ARGBLOCK
***************************************************************************)%
%[1002]% STRUCTURE EVALTAB[IDX]=
%[1002]% IF .GFLOAT
%[1002]% THEN (.EVALTAB + .IDX + 32)<WHOLE>
%[1002]% ELSE (.EVALTAB + .IDX)<WHOLE>;
%(***************************************************************************
DEFINE THE STRUCTURE TO BE MAPPED ON THE LIST OF ARG-CODES
AND CORRESPONDING VALUES THAT OCCURS UNDER AN OPEN STATEMENT
***************************************************************************)%
STRUCTURE OPENLIST[ARGINDEX,WD,POS,SIZE]=
(@.OPENLIST+.ARGINDEX+.WD)<.POS,.SIZE>;
%(***DEFINE THE FIELDS USED FOR A GIVEN INDEX***)%
MACRO OPENLCODE=0,LEFT$, !CODE FOR FOROTS FOR THIS ARG
OPENLPTR=0,RIGHT$; !PTR TO THE CONSTANT TABLE OR SYMBOLTABLE
! ENTRY FOR THE VALUE FOR THIS ARG TO FOROTS
%(***DEFINE VALUES FOR OPENLCODE***)%
BIND OPNCDIALOG=#53, !DIALOG
%2426% OPNCNEDIALOG=#1, ! dialog without =
OPNCACCESS=#2, !ACCESS
OPNCDEVICE=#3, !DEVICE
OPNCBUFCOUNT=#4, !BUFFER COUNT
OPNCBLOCKSIZE=#5, !BLOCK SIZE
OPNCFILE=#6, !FILE
OPNCPROTECTION=#7, !PROTECTION
OPNCDIRECT=#10, !DIRECT
%2043% OPNCLIMIT=#11, !LIMIT - back again
OPNCMODE=#12, !MODE
OPNCFILESIZE=#13, !FILE SIZE
OPNCRECORDSIZE=#14, !RECORD SIZE
OPNCDISPOSE=#15, !DISPOSE
OPNCVERSION=#16, !VERSION
! OPNCREELS=#17, !REELS - gone
! OPNCMOUNT=#20, !MOUNT - gone
![760] Values for new keys on OPEN/CLOSE
%[760]% OPNCIOSTAT=#21, ! iostat
OPNCASSOCIATE=#22, ! associate variable
%[760]% OPNCPARITY=#23, ! parity
%[760]% OPNCDENSITY=#24, ! density
%[760]% OPNCBLANK=#25, ! blank
%[760]% OPNCCARRIAGE=#26, ! carriage control
%[760]% OPNCFORM=#27, ! format
!%760% OPNCLABELS=#30, ! labels - gone
%[760]% OPNCPADCHAR=#31, ! padchar
%[760]% OPNCRECTYPE=#32, ! rectype
%[760]% OPNCSTATUS=#33, ! status
%2413% OPNCTAPEFO=#34, ! tape format
%[760]% OPNCREADONLY=#35, ! readonly
%[760]% OPNCUNIT=#36, ! unit
%[760]% OPNCERREQ=#37, ! err=
%2200% IOCEXIST=#40, ! exist
%2200% IOCFORMATTED=#41, ! formatted
%2200% IOCNAMED=#42, ! named
%2200% IOCNEXTREC=#43, ! nextrec
%2200% IOCNUMBER=#44, ! number
%2200% IOCOPENED=#45, ! opened
%2200% IOCSEQUENTIAL=#46, ! sequential
%2200% IOCUNFORMATTED=#47, ! unformatted
%2200% IOCNAME=#50; ! name
BIND
%2426% MAXOTSKWD=#53; ! maximum keyword number in above list
%(***************************************************************************
DEFINE THE STRUCTURE OF THE SYMBOL TABLE
***************************************************************************)%
STRUCTURE SYMTABENTRY[DMY,WD,POS,SIZE]=
(@.SYMTABENTRY+.WD)<.POS,.SIZE>;
! Define the structures for the dimension table
! (DIMENTRY and DIMSUBENTRY)
!
![2314] Pretty things up
! !=========================================================================!
! 0 !ADJ!ASS! DIMNUM ! ARACONSIZ !
! !-------------------------------------------------------------------------!
! 1 ! ARAOFFSET ! ARADDRVAR !
! !-------------------------------------------------------------------------!
! 2 ! ARADLBL ! ARALINK !
! !-------------------------------------------------------------------------!
! 3 ! ARASIZ !
! !=========================================================================!
! 4 ! DIMLB ! DIMUB !
! !-------------------------------------------------------------------------!
! 5 !F!L!U! ! DIMFACTOR !
! !-------------------------------------------------------------------------!
! \ \
! \ More subscript entries \
! \ \
! !=========================================================================!
STRUCTURE DIMENTRY[DMY,WD,POS,SIZE] = (@.DIMENTRY+.WD)<.POS,.SIZE>;
BIND DIMSUBSIZE=2; ! Number of words in each subscript entry
MACRO ADJDIMFLG=0,0,35,1 $, !Flag for adjustably dimensioned
%1510% ASSUMESIZFLG=0,0,34,1 $, !Flag for Assumed Size Array
DIMNUM=0,0,18,16 $, !NUMBER OF DIMENSIONS
%2314% ARACONSIZ = 0,0,RIGHT$, ! If not adjustably dimensioned, pointer to a
! constant table entry containing the value of
! ARASIZ. Used for OTSKFSIZ FOROTS argument.
! Valid only after complexity walk sees array
! used for Hollerith array format.
ARAOFFSET=0,1,LEFT$, ! VALUE OF OFFSET FOR THIS ARRAY IF
! DIMENSIONS ARE CONSTANT; POINTER TO
! LOC IN WHICH THE OFFSET WILL BE STORED
! IF DIMENSIONS ARE VARIABLE
ARADDRVAR=0,1,RIGHT$, ! FOR FORMAL ARRAYS THAT ARE NOT
! ADJUSTABLY DIMENSIONED, THIS FIELD
! POINTS TO A "PSEUDO" SYMBOL TABLE
! ENTRY FOR THE ARRAY NAME WITH THE TYPE
! FIELD SET TO INTEGER. IT IS THIS
! SYMBOL THAT IS USED IN THE ADDRESS
! CALC
ARADLBL=0,2,LEFT$, ! PTR TO LABEL TABLE ENTRY FOR LABEL ON
! THE ARG-BLOCK DESCRIBING THE
! DIMENSIONS OF THIS ARRAY THAT WILL BE
! OUTPUT IF THE ARRAY WAS PROTECTED OR
! THE USER SPECIFIED THE DEBUG SWITCH
ARALINK = 0,2,RIGHT$, ! LINK TO NEXT DIM TABLE ENTRY GLOBAL
! DTABPTR IS HEAD OF LIST
%1245% ! Move ARASIZ to word 3 since character array size is in characters
ARASIZ=0,3,FULL$, ! Number of words or characters in the
! array. If array is adjustably
! dimensioned, have ptr to a tmp table
! entry.
%1245% ! Dimension info starts in word 4; ARASIZ is now word 3.
FIRSTDIM=0,4,WHOLE$, ! First dimension's subscript.
! *** Note that THIS INFORMATION IS DUPLICATED in the
! *** DIMSUBENTRY structure definition BELOW!!!! Any changes
! *** here MUST be made there also!!!!
! X is the subscript number.
%2202% DIMENS(X)=0,4+DIMSUBSIZE*X,FULL$, !X's dimensions (up & lower)
%2202% DIMENL(X)=0,4+DIMSUBSIZE*X,LEFT$, !Ptr to X's lower bound
%2202% DIMENU(X)=0,4+DIMSUBSIZE*X,RIGHT$, !Ptr to X's upper bound
%2202% DVARFLGS(X)=0,5+DIMSUBSIZE*X,LEFT$, !Used to clear flags
%2202% DVARLBFLG(X)=0,5+DIMSUBSIZE*X,34,1$, !Flag: lower bound a variable
%2202% DVARUBFLG(X)=0,5+DIMSUBSIZE*X,33,1$, ! upper bound a variable
%2202% DVARFACTFLG(X)=0,5+DIMSUBSIZE*X,35,1$, ! factor a variable
%2202% DFACTOR(X)=0,5+DIMSUBSIZE*X,RIGHT$; !Factor that subscript
! for this dimension is
! multiplied by. This
! is a ptr to a constant
! table entry if
! preceeding dimensions
! were constant, a ptr
! to a symbol table
! entry for a var in
! which the val is
! stored if variable.
! The subscript entry for a given dimension
STRUCTURE DIMSUBENTRY[WD,POS,SIZE]=
(@.DIMSUBENTRY+.WD)<.POS,.SIZE>;
! *** Note that THIS INFORMATION IS DUPLICATED DIRECTLY ABOVE in
! *** the DIMENTRY structure references!!!! Any changes in
! *** these macro's MUST be made to the other dimension macros
! *** too!!!!
MACRO
DIMLB=0,LEFT$, !Ptr to lower bound
DIMUB=0,RIGHT$, !Ptr to upper bound
VARFACTFLG=1,35,1$, !Factor for this dimension a variable
VARLBFLG=1,34,1$, !Flag for "lower bound on this dimension
! is a variable.
VARUBFLG=1,33,1$, !Upper bound a variable
DIMFACTOR=1,RIGHT$; !Factor to multiply ss of this dimension
!***********************************************************************
![1214], Add structure for DO/IF stack
!***********************************************************************
STRUCTURE DINODE [OFFS, P, S] = [1] (@.DINODE+.OFFS)<.P,.S>;
! FIELDS IN ALL NODES
MACRO DILINK = 0,RIGHT$, ! LINK TO ENCLOSING DINODE
DIBLINK = 0,LEFT$, ! BACK LINK (TO NEXT INNER DINODE)
DISTMT = 1,LEFT$, ! POINTER BACK TO STMT NODE OF DO OR IF
DITYPE = 1,RIGHT$; ! DO OR IF OR WHILE
BIND DISIZE = 4; ! NODE SIZE, WORDS
! DITYPE VALUES
BIND DIIFTYPE = 0, ! BLOCK IF
DIDOTYPE = 1, ! DO
DIWHILETYPE = 2; ! DO WHILE
! IF NODE
MACRO THENLBL = 2,LEFT$, ! LABEL IN THE GOTO GENERATED BY THE
! MOST RECENT THEN
ENDLBL = 2,RIGHT$; ! LABEL TO BE ATTACHED TO THE CONTINUE
! GENERATED BY THE ENDIF
! DO NODE
MACRO LASTDOLBL = 2,RIGHT$, ! LASDOLABEL
CURDONDX = 3,FULL$; ! CURDOINDEX
! WHILE NODE
MACRO TOPLBL = 2,LEFT$, ! nM label on IF stmt at top of loop
BOTLBL = 2,RIGHT$, ! nM label on CONTINUE after bottom of loop
BOTSTMT = 3,LEFT$; ! label of terminal statement (DO 10 WHILE)
%(*********
DEFINE VALUES OF LABEL TABLE FIELDS USED FOR PEEPHOLING
**********)%
%(***VALUES FOR SNSTATUS FIELD***)%
BIND OUTPBUFF=2, !LABEL IS OUT OF THE PEEPHOLE BUFFER
INPBUFF=1, !LABEL IS STILL IN THE PEEPHOLE BUFFER
UNRESOLVED=0; !LABEL IS UNRESOLVED
BIND LBTBENDMK=0; !VALUE OF NXTLAB FIELD
! FOR LAST LINK
%(**************
DEFINE STRUCTURE FOR PEEPHOLE BUFFER
****************)%
%(***SIZE OF PEEPHOLE BUFFER ENTRIES****)%
BIND PBFENTSIZE=3; !NUMBER OF WORDS IN EACH PEEPHOLE BUFFER ENTRY
BIND PBFENTCT=50; !NUMBER OF ENTRIES IN THE PEEPHOLE BUFFER
BIND PBFOUTCT=25; !NUMBER OF ENTRIES FROM THE BUFFER THAT WE OUTPUT
! AT A TIME. WHEN THE 50 ENTRIES ARE FULL, WE OUTPUT
! THE 1ST 25 INSTRS, AND LEAVE THE REMAINING 25
! TO BE PEEPHOLED WITH ANY FURTHER INSTRS THAT WIL
! BE ENTERED
BIND PBFOUTSIZ=PBFOUTCT*PBFENTSIZE; !SIZE OF THE BLOCK OF ENTRIES
! AT THE TOP OF THE BUFFER THAT WE
! OUTPUT AT A ONE TIME
BIND PBFSIZE=PBFENTCT*PBFENTSIZE + 2; !NUMBER OF WORDS IN THE PEEPHOLE BUFFER
! (KEEP 1 WD AFTER THE LAST ENTRY TO HOLD
! A POSSIBLE LABEL AND A POSSIBLE ISN)
%(****STRUCTURE FOR LOOKING AT A PEEPHOLE*******)%
%(*******THE ARG INST INDICATES WHICH INSTRUCTION OF THE PEEPHOLE***)%
STRUCTURE PEEPHOLE[INST,WD,POS,SIZE]=
(@.PEEPHOLE + PBFENTSIZE*.INST +.WD)<.POS,.SIZE>;
%(****STRUCTURE FOR A PEEPHOLE BUFFER ENTRY***)%
STRUCTURE PEEPFRAME[WD,POS,SIZE]=
(.PEEPFRAME+.WD)<.POS,.SIZE>;
%(***STRUCTURE FOR A PTR TO A PEEPHOLE BUFFER ENTRY*****)%
STRUCTURE PPEEPFRAME[WD,POS,SIZE]=
(@.PPEEPFRAME+.WD)<.POS,.SIZE>;
%(*****DEFINE FIELDS FOR PEEPHOLE BUFFER FRAME*****)%
MACRO PBFISN=0,WHOLE$, !ISN FOR STMNT BEGUN BY THIS INSTR
! -1 FOR INSTRS THAT DO NOT START STMNTS
PBFLABEL=1,LEFT$, !PTR TO LABEL TABLE ENTRY FOR THE 1ST
! LABEL ASSOCIATED WITH THIS
! LOC
PBFSYMPTR=1,RIGHT$, !0 IF ADDR FIELD IS A LABEL
!1 IF ADDR FIELD HAS NO SYMBOLIC REPR
!2 IF ADDR FIED IS A PTR TO THE SIXBIT
! FOR AN IMPLICITLY CALLED FUNCTION
!3 IF ADDR IS A PTR TO A SYMBOL TABLE ENTRY
! FOR AN EXPLICITLY CALLED FN
! OTHERWISE A PTR TO THE SYMBOL TABLE,CONSTANT
! TABLE OR TEMP TABLE ENTRY FOR THIS ADDR FIELD
PBFINSTR=2,WHOLE$,
PBFADDR=2,RIGHT$, !ADDRESS FIELD OF THE INSTR
PBFOPCOD=2,27,9$, ! OP-CODE
PBFOPKEY=2,27,5$, ! LAST 5 BITS OF OPCODE, USED AS
! KEY IN PEEPHOLE OPTIMIZER
PBFREG=2,23,4$, !REG FIELD
PBFINDEX=2,18,4$, !INDEX AND INDIRECT FIELDS
PBFMEMREF=2,0,23$; !ADDRESS,INDIRECT, AND INDEX FIELDS
BIND NOLABEL=0; !FLAG FOR "NO LABEL YET ASSOCIATED
! WITH THIS LOC"
BIND NOISN=-1; !CODE FOR "NO ISN ASSOCIATED WITH THIS INSTR"
! (IE THE INSTR IS IN THE MIDDLE OF A STMNT)
%(*******SPECIAL VALS FOR PBFSYMPTR FIELD*******)%
BIND
PBFLABREF=0, !ADDRESS FIELD IS A LABEL, RH IS AN INSTRUCTION
PBFNOSYM=1, !ADDRESS FIELD IS AN OCTAL CONSTANT, RH IS AN INSTR
PBFIMFN=2, !ADDR FIELD IS A PTR TO AN IMPLICITLY CALLED FN
PBFEXFN=3, !ADDR FIELD IS A PTR TO AN EXPLICITLY CALLED FN
PBF2LABREF=4, !BOTH HALVES OF WD ARE PTRS TO LABEL TABLE
! ENTRIES
PBF2NOSYM=5, !BOTH HALVES OF WD ARE OCTAL CONSTANTS WITH
! NO SYMBOLIC REPRESENTATION
PBFFORMAT=6, !RIGHT HALF WORD IS FORMAT ADDRESS
PBFLLABREF=7, !LEFT HALF IS A LABEL REFERENCE
!USED PRIMARILY FOR ARGUMENT BLOCKS TO
!FOROTS FOR THE END=,ERR= WORD
PBFENTRY=8; !FOR A GLOBAL ENTRY (AS SUBROUTINE
!OR ENTRY NAME).
BIND PBFCODMAX=16; !CAN NEVER USE ANY NUMBER GTR THAN 16 AS A SPECIAL
! CODE VALUE FOR PSYMPTR, BECAUSE ANY NUMBER GTR
! THAN 16 MIGHT BE THE ADDRESS OF A NODE
%(***************************************************************************
TO GENERATE A JRST INSTRUCTION
***************************************************************************)%
MACRO JRSTGEN(ADDR)=
BEGIN
PBOPWD_JRSTOC OR ADDR;
PSYMPTR_PBFLABREF; !FLAG FOR "ADDRESS FIELD OF THIS INSTR IS
! A LABEL"
OBUFF();
END$;
%(***TO GENERATE JRST INDIRECT***)%
MACRO JRSTIGEN(ADDR)=
BEGIN
PBOPWD_JRSTOC OR INDBIT OR ADDR;
PSYMPTR_PBFLABREF;
OBUFF();
END$;
%(***************************************************************************
DEFINE THE VARIOUS WAYS OF BUILDING INDICES INTO THE OPGENDISPATCH TABLE.
EACH KIND OF INDEX IS COMPOSED OF SOME COMBINATION OF THE FLAG AND OPERATOR
FIELDS OF THE NODES FOR WHICH CODE IS TO BE GENERATED.
***************************************************************************)%
%(****TO GET THE VAL OF AN ARGNODE INTO THE REG FOR COMPUTATION OF THE PARENT (WHEN
THE VAL OF THE SON IS WITHIN REACH OF 1 INSTR.
DEPENDS ON THE VALS OF NEGFLG,NOTFLG,SAMEFLG,IMMEDFLG
FOR THE ARG INVOLVED, ALSO ON THE VALUE-TYPE OF THE ARG.
*******)%
MACRO GETA1OPIX(PNODE,ANODE)=
BEGIN
(.PNODE[A1FLG1]^2 + .ANODE[VALTP1] + OPGETI)
END$;
MACRO GETA2OPIX(PNODE,ANODE)=
BEGIN
(.PNODE[A2FLG1]^2 + .ANODE[VALTP1] + OPGETI)
END$;
%(***FOR DO-LOOPS - DONT ACTUALLY HAVE AN EXPRESSION NODE BUT WANT TO GET VAL
HOW TO DO SO DEPENDS ON VAL OF IMMEDFLG, VALTYPE AND NEGATE FLAG***)%
MACRO DOGETAOPIX(IMFLG,VLTP,NEGFLAG)=
(NEGFLAG^4+IMFLG^2 + VLTP + OPGETI)$;
%(****TO COMPUTE THE VALUE OF A NON-CONTROL BOOLEAN NODE. CODE TO BE GENERATED
DEPENDS ON A2NOTFLG, A2IMMEDFLG, AND MEMCMPFLG AND THE OPERSP***)%
MACRO BOOLOPIX(PNODE)=
(.PNODE[A2NOTFLG]^4 + .PNODE[A2IMMEMCMPFLGS]^2 + .PNODE[OPERSP] + OPGBOO)$;
%(******TO SKIP THE NEXT INSTRUCTION WHEN A RELATIONAL HAS THE VAL INDICATED
BY 'SKPCND'. CODE TO BE GENERATED DEPENDS ON WHETHER THE ARGS
OF THE RELATIONAL ARE SINGLE OR DOUBLE WD AND WHETHER
THE 2ND ARG IS IMMED*******)%
%(*****(NOTE THAT IF THIS IS EVER CHANGED, THEN DPIMMRELOPIX DEFINED
BELOW SHOULD ALSO BE CHANGED)***)%
MACRO RELOPIX(PNODE,ANODE,SKPCND)=
BEGIN
REGISTER MODE; !MODE ON WHICH TO SKIP
MODE_.PNODE[OPERSP]; !MODE SPECIFIED IN RELATIONAL
IF FALSITY(SKPCND)
THEN MODE_CMREL(.MODE); !IF WANT TO SKIP ON REL FALSE
.ANODE[DBLFLG]^4 + .PNODE[A2IMMEDFLG]^3 + .MODE + OPGREL
END$;
%(****FOR A RELATIONAL BETWEEN A DOUBLE-PREC AND ZERO. CAN USE SAME
CODE AS USE TO COMPARE A REAL TO ZERO (SEE RELOPIX ABOVE)***)%
MACRO DPIMMRELOPIX(PNODE,SKPCND)=
BEGIN
REGISTER MODE; !MODE ON WHICH TO SKIP
MODE_.PNODE[OPERSP];
IF FALSITY(SKPCND)
THEN MODE_CMREL(.MODE); !IF WANT TO SKIP ON RELATIONAL FALSE
1^3 + .MODE + OPGREL !HAVE A2IMMEDFLG (SINCE COMPARE TO 0)
! AND DO NOT HAVE DOUBLE-WD COMPARE)
END$;
%(*****TO COMPUTE THE VAL OF AN ARITHMETIC NODE.
DEPENDS ON THE VALS A2IMMEDFLG,MEMCMPFLG,VALTYPE, AND OPERSP OF THE PARENT
NOTE THAT EXPONENTIATION NODES WERE CONVERTED TO FUNCTION-CALLS DURING
THE COMPLEXITY WALK. HENCE NEVER HAVE TO GET OPGNTA INDEX FOR EXPONEN
********)%
MACRO ARITHOPIX(PNODE)=
BEGIN
(.PNODE[A2IMMEMCMPFLGS]^4+.PNODE[OPRSP2]^2+.PNODE[VALTP1]+
![761] Choose index based on /GFLOATING
%[761]% (IF .GFLOAT THEN OPGARG ELSE OPGARI))
END$;
%(*********FOR THE ADD TO THE INDEX FOR A DO-LOOP********)%
MACRO DOARITHOPIX(VLTP,MCPFLG,IMFLG,NEGFLAG)=
%(***HAVE A2IMMEDFLG=IMFLG, MEMCMPFLG=MCPFLG,
OPERATOR IS ADD IF NEGFLAG IS 0, SUB IF NEGFLAG IS 1***)%
(IMFLG^5 + MCPFLG^4 + (ADDOP+NEGFLAG)^2 + VLTP +
![761] Choose index based on /GFLOATING
%[761]% (IF .GFLOAT THEN OPGARG ELSE OPGARI))$;
%(***FOR THE ADD TO BOTH AT THE END OF A MATERIALIZED DO LOOP
WHEN THE INDEX IS REAL OR INTEGER***)%
MACRO DOARBOTHOPIX(VLTP)=
(3^4 !SET BITS FOR MEMCMPFLG AND OPTOBOTHFLG
+ADDOP^2 ! ADD
+VLTP ! INTEGER OR REAL
+OPGARI ! BASE OF TABLE FOR CODE FOR KI10 (SINCE NO DP,
! CAN ALWAYS USE KI10 CODE)
)$;
%1431% %(***FOR THE SUBTRACT IN SUBSTRING CALCULATION***)%
MACRO
SSSUBOPIX(CNODE)= (.CNODE[A2IMMEDFLG]^5 + (1-.CNODE[A2NEGFLG])^2
+ VTP1(INTEGER) + OPGARI)$,
SSADDOPIX(CNODE)= (.CNODE[A2IMMEDFLG]^5 + .CNODE[A2NEGFLG]^2
+ VTP1(INTEGER) + OPGARI)$;
%(*****TO COMPUTE THE VAL OF A TYPE CONVERSION NODE.
WILL BE GENERATING CODE ONLY WHEN DESTIN TYPE
IS REAL,INTEGER,DOUBLEPREC,OR COMPLEX (IE NEVER HAVE
TO DEAL WITH OCTAL,DOUBLE-OCTAL,LOGICAL,LITERAL,OR CONTROL)
THUS ONLY NEED TO DIFFERENTIATE BETWEEN THESE 4 TYPES
THE TYPE TO BE CONVERTED TO (SPECIFIED BY THE VALTYPE FIELD OF THE
TYPE-CONVERION NODE).
THE OPERSP FIELD OF THE TYPE CONVERSION NODE, INDICATES
THE ORIGINAL TYPE BEING CONVERTED.
*******)%
MACRO TPCNVIX(PNODE)= (.PNODE[OPERSP]^2 +
!WHEN CONVERTING TO OCTAL/LOGICAL, MUST BE MORE CAREFUL
(IF .PNODE[OPERSP] GTR 4 !COMING FROM REAL, DP, COMPLEX
AND .PNODE[VALTP2] EQL 0 !GOING TO OCTAL, LOGICAL
THEN .PNODE[OPRSP2] !MATCH TYPES TO GET NO CONVERSION
ELSE .PNODE[VALTP1])+ !ELSE DISPATCH NORMALLY
![761] Choose index based on /GFLOATING
%[761]% (IF .GFLOAT THEN OPGTCG ELSE OPGTCI))$;
%(****TO COMPUTE THE VALUE OF A NEGNOT NODE. WHEN PHASE 2 SKELETON IS PRESENT,
THERE WILL BE FEW OF THESE. (EG FOR F(-X), NOT(-X))*********)%
%(***WHEN A2NEG,A2NOT, OR A2SAMEFLG IS SET, WILL USE GETA2OPIX TO GET THE ARG
INTO A REG, AND THEN USE THE FOLLOWING INDEX*****)%
MACRO NEGNOT1IX(PNODE)=
(.PNODE[MEMCMPFLG]^3 + .PNODE[OPERSP]^2 + .PNODE[VALTP1] + OPGN1I)$;
%(***OTHERWISE, USE AN INDEX BASED ON A2IMMED, MEMCMP, OPERSP, VALTP1****)%
MACRO NEGNOT2IX(PNODE)=
(.PNODE[A2IMMEMCMPFLGS]^3 + .PNODE[OPERSP]^2 + .PNODE[VALTP1] + OPGN2I)$;
%(***TO COMPUTE THE VALUE OF A P2MUL OR P2PL1MUL -
CODE TO BE GENERATED DEPENDS ON VALTYPE OF THE NODE AND
ON WHICH OP IS TO BE PERFORMED****)%
MACRO SPECOPIX(PNODE)=
BEGIN
%(***IF ARG IS IMMEDIATE AND OPERATION IS P2PLUS1-MULTIPLY , HAVE A
SPECIAL CASE***)%
IF .PNODE[A1IMMEDFLG]
THEN
BEGIN
IF .PNODE[OPERSP] EQL P2PL1OP
THEN (.PNODE[A1NEGFLG]^2 + .PNODE[VALTP1] + OPP21I)
ELSE
(.PNODE[OPERSP]^3 + .PNODE[A1NEGFLG]^2 +.PNODE[VALTP1]
![761] Choose index based on /GFLOATING
%[761]% +(IF .GFLOAT THEN OPGSPG ELSE OPGSPI))
END
ELSE
(.PNODE[OPERSP]^3 + .PNODE[A1NEGFLG]^2 +.PNODE[VALTP1]
+(IF .PNODE[MEMCMPFLG] THEN OPGSPM !FOR OPS DONE TO MEMORY DONT CARE
! WHETHER ARE KA OR KI
![761] Choose index based on /GFLOATING
%[761]% ELSE IF .GFLOAT THEN OPGSPG ELSE OPGSPI))
END$;
%(***TO GENERATE CODE FOR AN IN-LINE FUNCTION WHEN ARG1 FOR THAT FN IS ALREADY IN REGFORC**)%
MACRO ILFIX(PNODE)=
BEGIN
IF .PNODE[A2IMMEDFLG]
THEN
.PNODE[OPERSP] + OPGILI
ELSE
IF .PNODE[OPERATOR] EQL DABSFNOP
THEN OPGDBF ELSE .PNODE[OPERSP]+OPGILF
END$;
%(***TO GENERATE CODE FOR AN IN-LINE FN WHEN ARG IS NOT IN REGFORCOMP (USED FOR
ABS,IABS (NOT IN RELEASE 1), AND SIGN ***)%
MACRO ILF1IX(PNODE)=
IF .PNODE[OPERATOR] EQL DABSFNOP
THEN OPGDB1 ELSE .PNODE[OPERSP]+OPGIL1$;
%(*****TO PERFORM THE ACTION SPECIFIED FOR A "STORECLS" NODE (WHICH IS USED
WHEN EITHER A PTR TO AN ARRAY ENTRY OR THE CONTENTS OF THAT
ENTRY MUST BE STORED IN A TEMPORARY************)%
MACRO STCLSOPIX(PNODE)=
(IF .PNODE[DBLFLG] AND (.PNODE[OPERSP] EQL STARVAL) !FOR STORING A DOUBL-WD VAL
THEN (.PNODE[A2SAMEFLG] + OPGSTD)
ELSE (.PNODE[OPERSP]^1 + .PNODE[A2SAMEFLG] + OPGSTC))$;
%(*****TO STORE A VALUE THAT HAS BEEN COMPUTED****)%
MACRO STOROPIX(PNODE)=
BEGIN
.PNODE[DBLFLG] + OPGSTI
END$;
%(******TO STORE THE VALUE OF THE RHS OF AN ASSIGNMENT STMNT
INTO THE LHS. CODE TO BE GENERATED DEPENDS ON WHETHER THE VAL MUST
BE NEGATED OR COMPLEMENTED, AND ON THE VALTYPE*****)%
MACRO ASNOPIX(PNODE,LHSNODE)=
BEGIN
%(***IF THIS STATEMENT HAS A2IMMEDFLG AND A2SAMEFLG BOTH SET, IT
MUST BE THAT THE RHS IS A REGCONTENTS NODE FROM WHICH WE
ONLY WANT TO USE THE RIGHT HALF (BECAUSE IT IS AN AOBJN WD).***)%
IF .PNODE[A2IMMEDFLG] AND .PNODE[A2SAMEFLG]
THEN
OPGASR
ELSE
.PNODE[A1NGNTFLGS]^2 + .LHSNODE[VALTP1] + OPGASI
END$;
%(****TO GENERATE CODE FOR AN ARITHMETIC-IF STATEMENT**********)%
MACRO
AIFIX(STMNODE,CNEXPR)=
(.STMNODE[AIFFLGS]^1 +
.STMNODE[A1SAMEFLG]
+ OPGAIF)$;
%(***TO INIT A LOGICAL VALUE TO TRUE OR FALSE (-1 OR 0). CODE
TO BE GENERATED DEPENDS ON WHETHER VAL IS TO BE LEFT IN A REG AND
ON THE VAL TO BE STORED
NOTE THAT "LOGVAL" IS EXPECTED TO BE 777777777777 FOR "TRUE"
*****)%
MACRO SETLOGIX(PNODE,LOGVAL)=
((LOGVAL AND #2) + .PNODE[INREGFLG] + OPGSET)$;
%(*****TO TRANSFER CONTROL WHEN ARG1 UNDER PNODE HAS THE SPECIFIED VAL TRUE OR FALSE.
JMPCND WIL BE 777777777777 WHEN TRANSFER ON "TRUE" IS DESIRED, 0
FOR TRANSFER ON FALSE.
********)%
MACRO TSTARGTRIX(PNODE,JMPCND)=
((JMPCND AND #2) + .PNODE[A1SAMEFLG] + OPGVTS)$; !IF PNODE A1SAMEFLG IS SET
! THEN THE ARG IS IN A REG
%(*****TO TRANSFER CONTROL WHEN A SPECIFIED VAR HAS THE SPECIFIED VAL TRUE OR FALSE.
CODE TO BE GENERATED DEPENDS ON WHICH CONDITION TRANSFER IS DESIRED
AND ON WHETHER THE VAL IS IN A REG
NOTE THAT "JMPCND" IS EXPECTED TO BE 777777777777 FOR "TRUE"
****)%
MACRO CNDVTRIX(NODE,JMPCND)=
BEGIN
IF .NODE[OPRCLS] EQL DATAOPR
THEN
((JMPCND AND #2) + OPGVTS)
ELSE
((JMPCND AND #2) + .NODE[INREGFLG] + OPGVTS)
END$;
%(*******TO TRANSFER TO ONE LABEL IF A SPECIFIED VALUE IS TRUE
AND TO ANOTHER IF THE VAL IS FALSE.
CODE TO BE GENERATED DEPENDS ON WHETHER THE VAL TO BE GENERATED
IS IN A REG.
********)%
MACRO ALTTRIX(NODE)=
BEGIN
IF .NODE[OPRCLS] EQL DATAOPR
THEN
OPGALT
ELSE
(.NODE[INREGFLG] + OPGALT)
END$;
%(**************************************************
DEFINE STRUCTURE FOR OPGENTABLE ENTRY -
FOR A GIVEN TYPE OF NODE, WILL HAVE A SERIES OF SUCH ENTRIES, ONE
FOR EACH INSTRUCTION TO BE GENERATED
******************************************************)%
STRUCTURE OPGENTRY[WD,POS,SIZE]=
(@.OPGENTRY+.WD)<.POS,.SIZE>;
%(**************FIELDS FOR AN OPGENTRY***********)%
MACRO
REGSPEC=0,LEFT$, !SPECIFIES WHERE TO GET
! REG TO BE USED
MEMSPEC=0,RIGHT$, !SPECIFIES WHERE TO GET
! MEMREF TO BE USED
PATTERN=1,WHOLE$; !PATTERN WORD FOR INSTR TO
! BE GENERATED
%(*********DEFINE VALUES FOR REGSPEC AND MEMSPEC FIELDS*********)%
BIND
FRPTN=0, !REG OR MEMREF FIELD USED AS IS IN WD 1 OF OPGENTABLE ENTRY
FRRFC=1, !REG FIELD IN THE GLOBAL "REGFORCOMP" SHOULD BE
! ADDED IN TO THE REG FIELD IN WD 1
! (OR THE REG SPECIFIED BY "REGFORCOMP"
! SHOULD BE USED AS THE MEMREF FIELD
IMFN=2, !USE THE IMPLICIT FN NAME PTED TO BY TREEPTR
WD1IMF=3, !USE THE IMPLICIT-FN NAME POINTED TO BY THE RH OF THE PATTERN WD
RGIMFN=4, !USE THE IMPLICIT-FN NAME POINTED TO BY THE RH OF
! THE PATTERN WD INDEXED BY THE "REGFORCOMP"
A1CNST=5, !ARG1 IS IMMED CNST
A2CNST=6, !ARG2 IS IMMED CNST
A1CNNG=7, !USE NEG OF THE IMMED CNST ARG1
A2CNNG=10, !USE NEG OF THE IMMED CNST ARG2
PTRA2=#11, !USE THE ARG2PTR FIELD IN THE PARENT
NGPTR2=#12, !USE THE NEG OF THE ARG2PTR FIELD OF THE PARENT
P2PTR2=#13, !USE 2**(VAL OF ARG2PTR) MINUS 1
! (THIS IS USED FOR P2DIV)
A1LAB=#14, !USE THE LABEL INDICATED BY A1LABEL
A2LAB=#15, !USE THE LABEL INDICATED BY A2LABEL
A3LAB=#16, !USE THE LABEL INDICATED BY A3LABEL
FROMC1H=#17, !USE THE CONTENTS OF THE GLOBAL C1H,
! THERE IS NO SYMBOL ASSOCIATED WITH THIS ADDR FIELD
PARTMP=#20, !USE THE TMP POINTED TO BY THE ADDR PART
! OF THE TARGET WD OF THE PARENT NODE (IE THE NODE
! POINTED TO BY TREEPTR); IGNORE THE INDIRECT BIT
! OF THE TARGET WD
FROMA1=#21, !TARGET FIELD OF ARG1 IS MEMREF FIELD
FROMA2=#22, !TARGET FIELD OF ARG2
FROMPAR=#23; !TARGET FIELD OF PARENT (IE NODE PTED TO BY TREEPTR)
%(***********************************************************************
TO GET REG OR MEMREF OR OPERATOR FIELD FROM EITHER A TARGET WD IN AN EXPRESSION
NODE OR A PATTERN WORD IN AN OPGENTABLE ENTRY
*****************************************************************)%
MACRO
OPFLD(WORD) = WORD AND #777^27$,
REGFLD(WORD) = WORD AND #17^23$,
MEMFLD(WORD) = WORD AND #37777777$;
%(****DEFINES SPECIFIC REGS USED FOR COMPILED CODE*****)%
BIND RETREG=0; !REG IN WHICH THE VAL OF A FN IS RETURNED
BIND STKREG=17; !STACK REG FOR FNS/SUBRS
BIND ARGREG=16; !CONTAINS PTR TO ARGLIST FOR FNS/SUBRS
%(*********MACROS USED FOR REGISTER ALLOCATION***********************)%
%(*****TO DETERMINE WHETHER A NODE IS EVALUATED BY MEANS OF A CALL TO A LIBRARY FN,
(IF SO THEN IF THE 2ND ARG IS A CONSTANT WILL HAVE TO ALLOCATE CORE FOR IT)***)%
MACRO USEFNCALL(PNODE)=
BEGIN
%(***COMPLEX MUL AND DIV ARE EVALUATED BY LIBRARY FNS**)%
.PNODE[OPERATOR] EQL OPERC(COMPLEX,ARITHMETIC,MULOP) OR.PNODE[OPERATOR] EQL OPERC(COMPLEX,ARITHMETIC,DIVOP)
OR
%(****EXPONENTIATION IS PERFORMED BY LIBRARY FNS***)%
(.PNODE[OPR1] EQL EXPONOPF)
END$;
%(****TO DETERMINE WHETHER THE REGISTER AFTER THE REGISTER RG IS
FREE. BITS 0-15 OF 'BSYRS' REPRESENT REGISTERS 0-15.
THE BIT FOR A REGISTER IS SET IFF THAT REG IS FREE*******)%
MACRO NXREGFREE(BSYRS,RG)=BITSET(BSYRS,RG+1)$;
%(****TO TEST WHETHER AN OPERATION 'CLOBBERS' THE REGISTER FOLLOWING THE ONE IN
WHICH IS IS PERFORMED.
THIS TEST DOES NOT INCLUDE DOUBLE-PREC (OR COMPLEX) OPERATIONS,
WHICH THE REGISTER ALLOCATOR HANDLES BY SIMPLY NEVER
ASSIGNING ODD REGISTERS WHEN IN "DOUBLE-WD MODE"
********)%
MACRO CLBNXREG(NODE)=
(CLOBBNX(.NODE))$; !(THIS TEST GOT SO COMPILICATED WE MADE IT A ROUTINE)
%(******MACROS FOR GOING BETWEEN "DOUBLE-WD MODE" REGISTER ALLOCATION AND
"SINGLE-WD MODE" REGISTER ALLOCATION.
FOR DOUBLE-WORD OPERATIONS, NEVER ASSIGN ODD REGISTERS TO
ANY COMPUTATIONS.
THE "SET OF BUSY REGS" MAY NEED TO HAVE THESE TRANSFORMATIONS PERFORMED ON IT
1. ACROSS A TYPE CONVERSION NODE (WHEN CONVERTING BETWEEN DOUBLE-WD
AND SINGLE-WD VALUES
2. ACROSS A RELATIONAL NODE THAT COMPARES DOUBLE-WD VALUES (BUT
HAS A SINGLE-WD RESULT)
3. ACROSS AN ARRAY-REF NODE FOR A DOUBLE-PREC ARRAY (THE ADDRESS ARITHMETIC
IS SINGLE-WD)
4. ACROSS A BOOLEAN WHOSE ARGS ARE DOUBLE-WD (RESULT IS ALWAYS SINGLE-WD
*************)%
%(******WHEN GOING DOWN FROM SINGLE-WD CALCULATIONS TO DOUBLE-WD CALCULATIONS
THE SET OF REGISTERS THAT CANNOT BE ASSIGNED MUST
NOW INCLUDE
1. ANY REGISTER THAT PRECEEDS A REGISTER HOLDING A VAL TO
BE PRESERVED (SINCE A DOUBLE-WD COMPUTATION
ON THE PRECEEDING REG CLOBBERS THE FOLLOWING ONE)
2. ANY ODD REGISTER.
***********)%
MACRO DPBSYREGS(SPBSYRS)=
((SPBSYRS AND SPBSYRS^1) AND #525252525252)$;
%(*********WHEN GOING DOWN FROM DOUBLE-WD CALCULATION TO SINGLE-WD
CALCULATIONS.
THE SET OF REGISTERS AVAILABLE ONCE AGAIN CAN INCLUDE
THEN ODD REGISTERS EXCEPT FOR THOSE REGISTERS CONTAINING THE RIGHT-HALF
OF A DOUBLE-WD RESULT WHICH WAS BEING SAVED.
************)%
MACRO SPBSYREGS(DPBSYRS)=
((DPBSYRS OR #252525252525) AND ((DPBSYRS OR #252525252525)^(-1) OR #400000000000))$;
%(***TO ADD THE FN RETURN REGISTER TO THE SET OF REGS AVAILABLE***)%
MACRO ADDRETREG(BSYR)=(BSYR OR #600000000000)$; !SET BITS FOR REGS 0 AND 1
%(***TO REMOVE THE FN RETURN REG FROM THE SET OF REGS AVAILABLE**)%
MACRO REMRETREG(BSYR)=(BSYR AND #177777777777)$; !CLEAR BITS FOR REGS 0 AND 1
%(***TO TEST WHETHER A POSITIVE INTEGER IS A POWER OF 2***)%
MACRO POWOF2(NUM)=((NUM AND -NUM) EQL NUM)$;
%(****TO SWAP HALVES OF A WORD IN MEMORY****)%
MACHOP MOVSS=#207;
MACHOP MOVE=#200;
%(*****TO SWAP THE 2 ARGS UNDER AN EXPRESSION NODE**************)%
MACRO
SWAPARGS(NODE)=
BEGIN
REGISTER T1;
MOVE(T1,NODE);
MOVSS(0,ARGWDOFFSET,T1);
SWAPFLGS(NODE);
END$;
%(****TO PERFORM A BLOCK TRANSFER *******)%
MACHOP BLT=#251;
MACRO BLOCKTR(SRCLOC,DESTIN,BLLNTH)=
BEGIN
REGISTER T1;
T1<LEFT>_SRCLOC;
T1<RIGHT>_DESTIN;
BLT(T1,(DESTIN)<0,0>+BLLNTH-1);
END$;
%(****TO PICK UP A HALF-WD VAL WITH SIGN EXTENDED****)%
MACHOP HRREI=#571;
MACRO EXTSIGN(VAL)=
BEGIN
REGISTER AA1;
AA1_VAL;
HRREI(AA1,0,AA1)
END$;
%(***TO DO AN ARITHMETIC SHIFT BY A COMPILE TIME CONSTANT***)%
MACHOP ASH=#240;
MACRO ARITHSHIFT(VAL,BITCT)=
BEGIN
REGISTER T1;
T1_VAL;
ASH(T1,(BITCT AND #777777))
END$;
%[1240] (***TO INCREMENT A BYTE POINTER N TIMES BY DOING AN ADJBP***)%
%2216% ! BPADD MACRO moved to OUTMOD.BLI
%1406% ! To generate a byte pointer that is output to the .REL file
MACRO BPGEN(ADDR)=
%1406% ! Written by TFV on 27-Oct-81
!Examples: SYMPTR[IDCHBP] = BPGEN(.SYMPTR[IDADDR]);
! SYMPTR[IDCHBP] = BPGEN(.LOWLOC);
(
%2330% (IF EXTENDED ! Compiling /EXTEND?
%2330% THEN #61^30 ! Yes, make one word globals
ELSE #4407^24 ! Local byte pointer
) OR (ADDR) ! Address
)$;
%1406% ! To compute the number of words needed for a character variable
%1406% ! or constant of length CHARS. Also define the number of bits
%1406% ! per character and the number of characters per word.
%1406% ! Written by TFV on 27-Oct-81
%2423% ! Parens added around macro formal by AHM on 19-Jul-84
BIND CHARSPERWORD = 5, ! Number of characters per word
BITSPERCHAR = 7, ! Number of bits per character
%2423% BITSPERWORD = 36; ! If your computer doesn't have 36 bits,
! you're not playing with a full DEC
MACRO
%2423% CHWORDLEN(CHARS)= (((CHARS) + CHARSPERWORD - 1) / CHARSPERWORD)$;
%(****TO COUNT THE NUMBER OF BITS THAT ARE ON IN A GIVEN WORD****)%
MACRO ONESCOUNT(WD)=
BEGIN
REGISTER COUNT;
REGISTER T1;
T1_WD;
COUNT_0;
UNTIL .T1 EQL 0
DO
BEGIN
T1_.T1 AND (NOT(-.T1));
COUNT_.COUNT+1;
END;
.COUNT
END$;
%(*******TO CLEAR A GIVEN BIT IN A GIVEN WORD (THE ARG IX INDICATES THE BIT
TO BE CLEARED, PTN1 IS THE WORD TO CLEAR IT FROM********)%
MACRO
CLRBIT(PTN1,IX)=BEGIN
EXTERNAL CLRWDS;
PTN1 AND .CLRWDS[IX]
END $;
%(*******TO SET A GIVEN BIT IN A GIVEN WD*******)%
MACRO
SETBIT(PTN1,IX) =BEGIN
EXTERNAL CLRWDS;
PTN1 OR NOT(.CLRWDS[IX])
END $;
%(****TO TEST A GIVEN BIT OF A GIVEN WD***********)%
MACRO
BITSET(PTN1,IX)=BEGIN
EXTERNAL CLRWDS;
((IX GEQ 0) AND (PTN1 AND NOT(.CLRWDS[IX])) NEQ 0)
END$;
%(*****TO MAKE AN ENTRY IN THE CONSTANT TABLE - SET UP GLOBALS FOR
TBLSEARCH AND CALL IT ****************)%
MACRO MAKECNST(TYPE,CNH,CNL) =
BEGIN
EXTERNAL TBLSEARCH;
%2336% EXTERNAL NAME, ENTRY, SYMTYPE;
NAME_CONTAB; ! Constant table entry
ENTRY[0]_CNH; ! High order word of constant
ENTRY[1]_CNL; ! Low order word of constant
SYMTYPE_TYPE; ! Type of constant
TBLSEARCH() ! Get a constant
END$;
%(**********TO MAKE A CONSTANT TABLE ENTRY FOR THE NEGATIVE OR THE
COMPLEMENT("NOT") OF SOME OTHER CONSTANT TABLE ENTRY*****)%
MACRO NEGCNST(CNNODE)=
BEGIN
IF .CNNODE[VALTYPE] EQL DOUBLPREC OR .CNNODE[VALTYPE] EQL REAL
%2475% OR .CNNODE[VALTYPE] EQL DOUBLOCT
THEN
%(***FOR DOUBLE-PREC NEG - USE ASSEMBLY LANG ROUTINE**)%
BEGIN
EXTERNAL C1H,C1L,C2H,C2L,COPRIX,KDNEGB,CNSTCM;
C1H_.CNNODE[CONST1];
C1L_.CNNODE[CONST2];
COPRIX_KDNEGB;
CNSTCM();
MAKECNST(.CNNODE[VALTYPE],.C2H,.C2L)
END
ELSE
MAKECNST(.CNNODE[VALTYPE], -.CNNODE[CONST1], -.CNNODE[CONST2])
END$;
%[733]% MACRO NOTCNST(CNNODE)=
%[733]% IF .CNNODE[VALTYPE] EQL DOUBLPREC OR .CNNODE[VALTYPE] EQL REAL
%2475% OR .CNNODE[VALTYPE] EQL DOUBLOCT
%[733]% THEN
%[733]% %(***FOR DOUBLE-PREC NOT - USE ASSEMBLY LANG ROUTINE**)%
%[733]% BEGIN
%[733]% EXTERNAL C1H,C1L,C2H,C2L,COPRIX,KDPRL,KGFRL,CNSTCM;
%[733]% C1H_.CNNODE[CONST1];
%[733]% C1L_.CNNODE[CONST2];
![761] Choose index based on /GFLOATING
%[761]% IF .GFLOAT THEN COPRIX_KGFRL ELSE COPRIX_KDPRL; !ROUND TO SINGLE
%[733]% CNSTCM();
%[733]% MAKECNST(LOGICAL,0, NOT .C2H)
%[733]% END
%[733]% ELSE MAKECNST(.CNNODE[VALTYPE], NOT .CNNODE[CONST1], NOT .CNNODE[CONST2])$;
%(****TO MAKE CONSTANT TABLE ENTRY FOR NOT(-X) - "NTNGCNST"
OR -(NOT X) - "NGNTCNST"*********)%
MACRO NTNGCNST(CNNODE)=
BEGIN
IF .CNNODE[VALTYPE] EQL DOUBLPREC OR .CNNODE[VALTYPE] EQL REAL
%2475% OR .CNNODE[VALTYPE] EQL DOUBLOCT
THEN
%(***FOR DOUBLE-PREC USE ASSEMBLY LANG ROUTINE TO GET NEG**)%
BEGIN
%(***DNEGCNST GETS ITS ARG IN THE GLOBALS C1H,C1L***)%
C1H_ .CNNODE[CONST1];
C1L_.CNNODE[CONST2];
COPRIX_KDNEGB;
CNSTCM();
MAKECNST(.CNNODE[VALTYPE],NOT .C2H, NOT .C2L)
END
ELSE
MAKECNST(.CNNODE[VALTYPE], NOT (-.CNNODE[CONST1]), NOT (-.CNNODE[CONST2]))
END$;
MACRO NGNTCNST(CNNODE)=
BEGIN
IF .CNNODE[VALTYPE] EQL DOUBLPREC OR .CNNODE[VALTYPE] EQL REAL
%2475% OR .CNNODE[VALTYPE] EQL DOUBLOCT
THEN
BEGIN
%(***DNEGCNST GETS ITS ARG IN THE GLOBALS C1H,C1L***)%
C1H_NOT .CNNODE[CONST1];
C1L_NOT .CNNODE[CONST2];
COPRIX_KDNEGB;
CNSTCM();
MAKECNST(.CNNODE[VALTYPE],.C1H,.C1L)
END
ELSE
MAKECNST(.CNNODE[VALTYPE],-(NOT .CNNODE[CONST1]), -(NOT .CNNODE[CONST2]))
END$;
%(******************************
MACROS TO FORM INDICES INTO THE TABLE FOR CONSTANT FOLDING
********************************)%
%(***TO FOLD BOOLEAN OPERATIONS***)%
MACRO KBOOLOPIX(PNODE)=
(.PNODE[OPERSP] + KBOOLBASE)$;
%(***TO FOLD ARITHMETIC OPERATIONS****)%
MACRO KARITHOPIX(PNODE)=
(.PNODE[OPRSP2]^2 + .PNODE[VALTP1] +
![761] Choose index based on /GFLOATING
%[761]% (IF .GFLOAT THEN KARIGB ELSE KARIIB) )$;
%(*******TO FOLD AN ARITH OP, WHEN NO EXPRESSION NODE WAS BUILT (VLTP IS THE VALTP1 FIELD)***)%
MACRO KKARITHOP(VLTP,OPSP)=
(
%2322% EXTERNAL KARIGB, KARIIB;
OPSP^2 + VLTP +
![761] Choose index based on /GFLOATING
%[761]% (IF .GFLOAT THEN KARIGB ELSE KARIIB)
)$;
%(****TO CONVERT A CONSTANT OF ONE VALUE TYPE TO ANOTHER****)%
MACRO KTPCNVIX(TPCNODE)=
(.TPCNODE[OPERSP]^3 + .TPCNODE[VALTP2]
![761] Choose index based on /GFLOATING
%[761]% + (IF .GFLOAT THEN KTYPCG ELSE KTYPCB))$;
%(****TO CONVERT A CONSTANT FROM ONE VALTYPE TO ANOTHER WHEN NO EXPRESSION
NODE WAS BUILT FOR THE TYPE CONVERSION. (VLTP IS THE VALTP2 FIELD)***)%
MACRO KKTPCNVIX(VLTP,OPSP)=
![761] Choose index based on /GFLOATING
%[761]% (OPSP^3 + VLTP + (IF .GFLOAT THEN KTYPCG ELSE KTYPCB))$;
%(***TO FOLD SPECIAL OPERATORS (P2MUL,P2DIV) - USED ONLY BY PHASE 2***)%
MACRO KSPECOPIX(PNODE)=
![761] Choose index based on /GFLOATING
%[761]% (.PNODE[OPERSP]^2 + .PNODE[VALTP1] + (IF .GFLOAT THEN KSPECG ELSE KSPECB))$;
MACRO KEXPIX(VLTP1)= !TO FOLD AN INTEGER EXPONENTIATION
![761] Choose index based on /GFLOATING
%[761]% (EXPCIOP^2 + VLTP1 + (IF .GFLOAT THEN KSPECG ELSE KSPECB))$; ! ("VLTP1" IS THE VALTP1 OF THE BASE)
%(***TO FOLD IN-LINE FNS********)%
MACRO KILFOPIX(PNODE)=
(.PNODE[OPERSP] + (IF .PNODE[VALTP1] EQL INTEG1 THEN KILFBA ELSE
(IF .gfloat THEN KILFBG ELSE KILFBR)))$;
%(*****FOR CNODE ARITHMETIC OR BOOLEAN
CHECK TO SEE IF A SKEWED TREE IS AN NARYNODE*****)%
MACRO NARYNODE(CNODE,AR1NODE)=
%[724]% (.CNODE[OPERATOR] EQL .AR1NODE[OPERATOR]
AND
.CNODE[OPR1] LSS DIVOPF
AND
NOT .CNODE[A1NEGFLG] AND NOT .CNODE[A1NOTFLG]
AND
NOT .AR1NODE[PARENFLG])$;
%(***************************************************************************
MACROS USED FOR CONSISTENCY CHECKING - FOR DEBUGGING THE COMPILER
***************************************************************************)%
%(***TO CHECK WHETHER ARE WALKING DOWN ONTO A LEGAL NODE***)%
MACRO DEBGNODETST(NODE)=
BEGIN
EXTERNAL NODERR;
IF DEBUGFLG !A COMPILE TIME CONSTANT
THEN
BEGIN
IF .NODE EQL 0
THEN NODERR();
END;
END$;
!***********************************************************************
!MACROS FOR THE FLAGS ASSOCIATED WITH A DO LOOP
!***********************************************************************
!***************************************************************
! To access right and left halves of a word through a
! CASE,WD,POS,SIZ structure. used on DOSP and SNDOLNK list.
!***************************************************************
MACRO
RIGHTP = 0,0,RIGHT$,
LEFTP =0,0,LEFT$;
!***************************************************************
! Fields in DOWDP used to determine if it is valid to keep the
! DO index variable in a register throughout the loop. Used
! during the skeleton optimization.
!***************************************************************
MACRO
DOISUBS=0,35,1$, ! Set FALSE if both loop index and count
! must be materialized. Set TRUE if
! index substitutions are performed.
DONOAOBJN=0,34,1$, ! Flag for "don't use AOBJN for this
! loop" if val of index is not
! materialized.
DOMTRLZIX=0,33,1$, ! Flag for "loop index must be
! materialized". This gets set if index
! is an arg to a fn or if loop has
! transfers out
DOINDUC=0,0,18$, ! Induction variable, pointer to symbol
! table reference.
DOREGPTR=0,18,18$; ! Point to regcontents node to be
! substitued.
%(*****DEFINE THE REGISTER TO BE USED FOR THE LOOP INDEX FOR ALL INNER DO
LOOPS****)%
BIND DOIXREG=2;
%(*****SOME FLAGS TO HELP THE GLOBAL ALLOCATOR. THESE FLAGS ARE IN THE
GLOBREG WORD OF AN ALLOCATED VARIABLE. SEE PH3G FOR DETAILS FOR THE
FLAGS)****%
MACRO
USED4ASGND=28,1$, !VARIABLE IS USED BEFORE ASSIGNED IN THIS LOOP
ASGND4USED=27,1$; !VARIABLE IS ASSIGNED BEFORE ITS FIRST USE
%(***************************************************************************
DEFINE THE TABLES USED BY THE BASIC BLOCK REGISTER ALLOCATOR
***************************************************************************)%
%(*****DEFINE THE STRUCTURE OF THE "REGCANDIDATES" TABLE. THIS TABLE IS USED
IN THE FIRST PASS OVER A BASIC BLOCK TO KEEP TRACK OF VARIABLES AND CONSTANTS
WHOSE VALUES ARE LEFT IN REGS BY RGE EVALUATION OF STMNTS IN THE BLOCK
********)%
STRUCTURE RGCTBL[ENTRIX,WD,POS,SIZE]=
(.RGCTBL + (.ENTRIX-1) + .WD)<.POS,.SIZE>; !1ST ENTRY HAS IX 1
MACRO
RGBAK=0,LEFT$,
RGFOR=0,RIGHT$,
RGVAR=1,LEFT$, !PTR TO THE SYMBOL/CONST TABLE ENTRY FOR A VAR/CONST
! WHOSE VAL IS LEFT IN A REG
RGINITUSE=1,RIGHT$; !PTR TO THE EXPRESSION/STMNT WHOSE EVALUATION LEFT THE VAR
! IN A REG
%(***DEFINE THE STRUCTURE FOR A POINTER TO A GIVEN ENTRY IN THE REGCANDIDATES TABLE**)%
STRUCTURE RGCTBLENTRY[WD,POS,SIZE]=
(@.RGCTBLENTRY+.WD)<.POS,.SIZE>;
BIND RGCENTSIZE=1; !NUMBER OF WDS IN EACH REGCANDIDATES TABLE ENTRY
%(**********DEFINE THE STRUCTURE OF THE "REGSTATE" TABLE. THIS TABLE IS USED
IN THE 2ND PASS OF TE BASIC BLOCK REG ALLOCATOR TO KEEP TRACK OF THE
CONTENTS OF EACH REG WHOSE VALUE IS OF FUTURE USE IN THE BASIC BLOCK
*************)%
STRUCTURE RGSTBL[REG,WD,POS,SIZE]=
(.RGSTBL + 2*.REG + .WD)<.POS,.SIZE>; !ENTRIES ARE INDEXED FROM 0 (FOR REG 0)
MACRO
RGVAR1=0,LEFT$, !PTR TO SYMBOL/CONST TABLE ENTRY FOR THE VAR/CONST
! WHOSE VAL IS IN THIS REG
RGVAR2=0,RIGHT$, !PTR TO A POSSIBLE 2ND SYMBOL/CONST TABLE ENTRY FOR A
! 2ND VAR WHOSE VAL IS IN THIS REG (EG FOR
! "A=B" BOTH A AND B ARE IN THE SAME REG)
RGNXUSE=1,WHOLE$; !THE BASIC-BLOCK SEQ NUMBER OF THE STMNT WHERE THE
! CONTENTS OF THE REG WILL NEXT BE USED. -1 IF THERE
! IS NO FUTURE USE