|
| Volume Number: | 5 | |
| Issue Number: | 2 | |
| Column Tag: | Forth Forum |
Record Definitions 
By Jörg Langowski, MacTutor Editorial Staff
“Record definitions in Mach2”
Record structures and arrays are not part of standard Forth implementations. More than two years ago, in V2#7, I had given an example how to implement records. Mach2 has evolved since then, and so have ways of implementing new data structures, as you can see in the Object Forth project by Wayne Joerding that we recently discussed. For those of you who do not want a full object-oriented system, but still ways of defining data structures in an easy way, I have found two examples on the GEnie bulletin boards. Those examples show two fundamentally different approaches to deal with record definitions.
‘Local’ field names - method 1
The problem in setting up the Forth compiler to deal with record definition in a proper way is somewhat similar to implementing an object-oriented programming system. That is, just like a message is local to an object, and the same message may cause different effects on different objects, a field name should be local to a record. In the Pascal record definitions
\1 rec1 = record x: real; i: integer; y: real; end; rec2 = record y: real; j: integer; x: real; end;
the field x would create a different offset into a record of type rec2 than for a rec1 type; and rec1.i, rec2.j would be valid while rec1.j, rec2.i would not. So if we define a field name as some kind of Forth word, this word should be in some ‘local vocabulary’ that belongs to the record definition and is only visible while the field reference is resolved.
The other requirement is that we should be able to pass a record as a parameter to a routine, so that given the pointer to a record on the stack, a Forth definition would know how to resolve the field reference. In a strongly typed language like Pascal this is easy; field references into record formal parameters can be resolved at compile time because the procedure arguments are of defined type. In Forth, typically the address of a data structure would be passed on the stack. However, at compile time there is no way we can restrict the type of argument that this address might later point to at run time! This problem could only be solved by type checking built into the record definition and deferring the resolution of the field reference to run time, some sort of ‘late binding’.
The first method of record definition (Listing 1), written by Waymen Askey of Palo Alto Shipping (I added some minor modifications, like floating point and array support), creates a local dictionary for each record template in the Forth dictionary space. When a record template is defined, using the syntax
\2 template rec1 :real x :word i :byte c tend
its field names x, i and c are compiled into the dictionary together with relevant information for resolving the references. At the end of the template declaration, the dictionary links are changed in such a way that the ‘local’ names are skipped when the dictionary is searched. Let’s declare a record:
\3 rec1 structure myRec
A field of this record is later accessed by using the structure fetch/store words, s@ and s!.
myRec x s@ will put the value in field x of myrec on the floating point stack, and myRec i s@ will put the word value of field i on the stack. The trick Waymen used was to build some intelligence into the fetch/store words. When the record and field words, myRec and x for example, are executed or compiled into a definition, field type and offset are determined and kept in global variables. The s@ word will check these variables and know how to access the field, whether - in immediate execution - to do a byte, word or long word fetch, addressing into an array, or a ten-byte fetch onto the floating point stack for a real number; or at compile time create code that will do these things later.
The drawback of this approach is that field references can only be resolved at compile or immediate execution time. If we wanted to write a word that operates on a record whose address is passed on the stack, we couldn’t use the field names that were defined in the record template - they are only valid right after a record name was executed or compiled. Therefore, a definition like
\4
: getX { myRec -- } myRec x s@ ;
must fail because myRec is a local variable, not a record name.
An example how to use this method of record declaration with various field types is given at the end of the listing. You see the drawback: Even though the record fields wavelength, temperature, and angle are all themselves structures of the same type parameter, there is no way to factor out the common code in
5 cr curve1 wavelength name s^ count type .” = “ curve1 wavelength value s@ f. curve1 wavelength unit s^ count type cr curve1 temperature name s^ count type .” = “ curve1 temperature value s@ f. curve1 temperature unit s^ count type cr curve1 angle name s^ count type .” = “ curve1 angle value s@ f. curve1 angle unit s^ count type
by using a word that would just print name, value and unit of any given parameter. If this problem was resolved, the record compiler would almost be perfect.
‘Global’ field names - method 2
Listing 2 shows a much simpler approach to structure definitions that does not do type checking. I downloaded this code from the Forth Roundtable on GEnie, and unfortunately have not the slightest idea who the author is. All I could find out was that the original code was probably posted on the East Coast Forth Board.
However, since this code solves one of our problems, record passing as formal parameters, I’d like to print it here. Its strategy is much more like that of the structure words built into MacForth Plus. Here, a record template is defined like
\6
RECORD Rectangle
Global SHORT: Top
Global Short: Left
Global Short: Bottom
Global SHORT: RIght
ENd.RECORD
Variable myRect Rectangle 4 - VALLOT ;
so the record name, when executed, simply leaves the record length on the stack for later ALLOT or VALLOT. The field names are words which add the field offset to an existing address on the stack, so they can be used in any context. We have to check ourselves whether the address is a valid record address and whether the field referenced actually exists in that record (if we care at all). All field names are global, and therefore must be unique; no two different record declarations can have fields of the same name at different offsets.
This approach is not so different from the very basic one that I used in most of my examples, where I simply defined field names as constants and added the offset to the record address.
What the Macintosh Forth world needs is really a combination of the two approaches, with type checking at compile time and local field names for convenience, and a possibility to resolve field references on record addresses at compile time without too much overhead. If one knew the type of the record passed on the stack ahead of time (which is usually the case), one could probably define some ‘field reference resolution word’ which computes an offset given a template and a field name. I hope I can show you an example in one of my next columns.
Upcoming: an update to Wayne Joerding’s Object Forth, and a review of PocketForth, a public domain 16-bit Forth that comes as an application and a desk accessory. Stay tuned.
Listing 1: Structure definitions with local field names
\ STRUCTUREs 2.5 for the Macintosh MACH2
\ Jan 3, 1987 by Waymen Askey
\ edited, floating point & array addition by
\ J. Langowski @ MacTutor
\ This MACH2 extension is released for the public good;
\ however, for those planning commercial use of this code,
\ please notify me so that I might know of its intended use.
\ Waymen Askey @ PASC
\ also GEnie MACH2 RoundTable.
only mac also sane also forth definitions
( VARIABLES used in STRUCTURE 2.5 )
decimal
variable current.template
variable op.type
variable A5offset ( holds the A5 offset to a structure )
( CODE word utilities used in STRUCTURE 2.5 )
code var.link ( -- a | variable link pointer )
lea $F7F8(A5),A0
move.l A0,-(A6)
rts
end-code
code a5@ ( -- a )
move.l A5,-(A6)
rts
end-code mach
code get.field ( a1 a2 -- a3 -1 or 0 | searches templates )
( a1=template, a2= pad, a3=field pointer, 0 if not found )
move.l (A6)+,D2
move.l (A6)+,D3
moveq.l #0,D1
moveq.l #0,D0
@start movea.l D3,A1
movea.l D2,A0
move.b (A1)+,D1 ( link to next field )
beq.s @end ( if link=0, field not found )
move.b (A1),D0
@loop cmpm.b (A1)+,(A0)+
dbne D0,@loop
beq.s @found
add.l D1,D3 ( increment field pointer )
bra.s @start
@found movea.l D3,A1
move.b 1(A1),D1 ( get string count )
addq.w #2,D1
btst #0,D1 ( test for odd count )
beq.s @even
addq.w #1,D1
@even add.l D1,D3
moveq.l #-1,D1
move.l D3,-(A6)
@end move.l D1,-(A6)
rts
end-code
code >sr ( n -- | push value onto subroutine stack )
move.l (A6)+,-(A7)
rts
end-code mach
code sr> ( -- n | pop value from subroutine stack )
move.l (A7)+,-(A6)
rts
end-code mach
code sr@ ( -- n | copy value from subroutine stack )
move.l (A7),-(A6)
rts
end-code mach
( Miscellaneous utility words used in STRUCTURE 2.5 )
: >even ( a -- a’ |
word aligns address, i.e. rounds up to even)
dup 1 and + ;
: >odd ( a -- a’ | odd aligns address, rounds up to odd )
1 or ;
: needed ( n -- | checks for at least n items on stack )
depth 1- > abort” Missing needed stack item(s)! “ ;
( Brute-force machine code words )
: ncode,
( n1...n -- | machine code defining word, stuffs n words )
create dup needed dup 2* w,
0 do w, loop
does> ( -- | compiles machine code )
dup 2+ swap dup w@ +
do i w@ w, -2 +loop ;
hex
( define some machine code “stuff” words )
41ED 1 ncode, lea_d(a5),a0
4EBA 1 ncode, jsr_d(PC)
4EAD 1 ncode, jsr_d(A5)
( LEA and JSR also need a word of extension for displacement )
2D3C 1 ncode, move.l_#,-(A6)
( plus a long extension for # )
2D08 1 ncode, move.l_a0,-(a6)
4E75 1 ncode, rts,
( The following expect an address to be in A0 )
7000 1010 2D00 3 ncode, byte@
7000 3010 2D00 3 ncode, word@
2D10 1 ncode, long@
201E 1080 2 ncode, byte!
201E 3080 2 ncode, word!
209E 1 ncode, long!
\ disassemble the following to check how they work.
\ Exercise for the reader... - JL
5187 5587 2247 22d8 22d8 32d8 6 ncode, real@
2247 20d9 20d9 30d9 5087 5487 6 ncode, real!
201e e580 2d30 0000 4 ncode, array@
201e e580 219e 0000 4 ncode, array!
201e e380 4281 3230 0000 2d01 6 ncode, warray@
201e e380 221e 3181 0000 5 ncode, warray!
decimal
( Dictionary header, name, and struct link words )
: link>name ( lfa -- ‘nf | ‘nf points to header length byte)
4 + ;
: name.count
( ‘nf -- ‘nf+1 n | dictionary header name count)
count 31 and ;
: link>segment
( lfa -- ‘sf | ‘sf is the dictionary segment field address)
link>name name.count + >even ;
: link>parameter
( lfa -- ‘pf | ‘pf is the parameter field pointer)
link>segment 2+ ;
: link>struct ( lfa -- struct.fields )
link>segment 4 + ;
: jsr_d(PC), ( lfa -- | compiles PC relative JSR)
jsr_d(PC)
link>body here - w, ;
: jsr_d(A5),
( lfa -- | compiles A5 relative JSR, i.e. jump table )
jsr_d(A5)
link>parameter w@ w, ;
: struct.zero ( -- lfa | returns lfa of struct.zero )
“ struct.zero” find drop ;
: nallot ( n -- | allots n bytes in name space )
np +! ;
: name, ( -- parses and compiles text into name space.)
32 word np @ over c@ 1+ dup >odd nallot cmove ;
: nc, ( n -- | compiles byte into name space )
np @ c! 1 nallot ;
: nw, ( n -- | compiles word into name space )
np @ w! 2 nallot ;
: n, ( n -- | compiles long into name space )
np @ ! 4 nallot ;
( TEMPLATE, STRUCTURE and field words )
: struct.error ( -- )
cr pad count type
.” ? Error, unknown field or incomplete structure path! “
abort ;
global
: template ( -- here 0 | begins TEMPLATE definition )
create here 0 2 allot
does> ( -- template.size )
dup w@ swap 4 - body>link current.template ! ;
: tend
( here n -- | (T)emplate(END) ends template definition )
swap w! 0 nw, ;
global
: afield ( size op.type -- )
create w, >even w,
does> ( here Toffset -- here new.Toffset )
( Toffset means (T)emplate(OFFSET) )
2dup 2+ w@ + >sr
w@ np @ >sr 1 nallot name,
0 nc, ( field type=0 ) nc, ( op.type )
nw, ( Toffset ) np @ sr@ - sr> c! ( field link )
sr> ;
( The following op.types are reserved and defined below )
( 06 byte, 12 word, 18 long, 24 string,
30 real, 36 struct, 42 array, 48 warray )
( size.in.bytes op.type AFIELD named.afield.type )
1 06 afield :byte
2 12 afield :word
4 18 afield :long
10 30 afield :real
: :string ( here Toffset size -- here Toffset+size+1 )
3 needed 1+ over + >even swap
np @ >sr 1 nallot name,
0 nc, ( field type=0 ) 24 nc, ( op.type=24)
nw, ( Toffset ) np @ sr@ - sr> c! ( field link ) ;
: :array ( here Toffset size -- here Toffset+size+1 )
3 needed 4* over + swap np @ >sr 1 nallot name,
0 nc, ( field type=0 ) 42 nc, ( op.type=42)
nw, ( Toffset ) np @ sr@ - sr> c! ( field link ) ;
: :warray ( here Toffset size -- here Toffset+size+1 )
3 needed 2* over + swap np @ >sr 1 nallot name,
0 nc, ( field type=0 ) 48 nc, ( op.type=48)
nw, ( Toffset ) np @ sr@ - sr> c! ( field link ) ;
: :struct ( here Toffset size -- here Toffset+size )
3 needed over + >even swap
np @ >sr 1 nallot name,
06 nc, ( field type=06 ) 36 nc, ( op.type=36 )
nw, ( Toffset )
current.template @ struct.zero - n, ( template link )
np @ sr@ - sr> c! ( field link ) ;
: >pad ( a -- | moves string to pad )
pad over c@ 1+ cmove ;
: make.var.link { | name.pointer var.pointer vlink -- }
np @ -> name.pointer var.link @ -> var.pointer
name.pointer var.link !
name.pointer var.pointer - -> vlink
name.pointer dup 1 and + -> name.pointer
vlink name.pointer !
name.pointer 4 + np ! ;
( Decision table for field type decode )
: do.afield ( ^field.type -- true )
1+ dup c@ op.type ! 1+ w@ A5offset +! -1 ;
: do.bfield ( ^field.type -- new.template false )
dup 1+ dup c@ op.type ! 1+ w@ A5offset +!
4 + @ struct.zero + link>struct 0 ;
: rts rts, ; immediate
( DO.FIELD table entries decode field data )
( afield’s are simple :BYTE, :WORD,
:LONG, :STRING types )
( bfield’s are :STRUCT fields )
create do.field ( field_type table_offset/type )
]do.afield rts ( afield 0 )
do.bfield rts ( bfield 6 )
[ ( end of current table )
global
: make.struct ( template.link A5offset -- )
( This is the word which must resolve a structure reference. )
A5offset ! ( A5 displacement for the struct )
36 op.type ! ( set default op.type to struct )
struct.zero + link>struct ( template.address -- )
begin
32 word >pad
pad get.field
if ( field found )
dup c@ do.field + execute
else ( field not found )
pad find 1 =
if
link>body execute -1
else
struct.error
then
then
until ;
hex
: structure
( n -- | creates structure alloting n bytes in variable space )
1 needed create immediate make.var.link
-4 allot lea_d(a5),a0 vp @ w, ( variable-like beginning )
move.l_#,-(A6) current.template @ struct.zero - ,
move.l_#,-(A6) vp @ ,
“ make.struct” find drop dup link>segment w@ 0=
if jsr_d(PC), else jsr_d(A5), then
rts,
vallot ;
decimal
( STRUCTURE operators )
: compileA5 ( -- | compiles A5 reference )
lea_d(a5),a0 a5offset @ w, ;
: pushA5 ( -- | executes A5 var reference )
a5offset @ a5@ + ;
: do.bit ( -- ) ( I’m lazy, define your own. W. Askey )
cr .” BIT operations are yet undefined!” abort ;
: do.struct ( -- ) ( Fetch/store doesn’t make sense here. )
cr .” STRUCTURE fetch/store operations are undefined! “ abort ;
: do.string ( -- ) ( If you wish, define your own. )
cr .” STRING fetch/store operations are undefined! “ abort ;
: do.byte@ ( f -- )
if compileA5 byte@ else pushA5 c@ then ;
: do.word@ ( f -- )
if compileA5 word@ else pushA5 w@ then ;
: do.long@ ( f -- )
if compileA5 long@ else pushA5 @ then ;
: do.array@ ( idx f -- )
if compileA5 array@ else 4* pushA5 + @ then ;
: do.warray@ ( idx f -- )
if compileA5 warray@ else 2* pushA5 + w@ then ;
: do.real@ ( f -- )
if compileA5 real@ else pushA5 f@ then ;
( Decision table for fetch )
create op.table@ ( op.types are offsets into this table )
] do.bit rts ( op.type = 0 )
do.byte@ rts ( “ “ = 6 )
do.word@ rts ( “ “ = 12 )
do.long@ rts ( “ “ = 18 etc, etc. )
do.string rts
do.real@ rts
do.struct rts
do.array@ rts
do.warray@ rts
[
: do.byte! ( f -- )
if compileA5 byte! else pushA5 c! then ;
: do.word! ( f -- )
if compileA5 word! else pushA5 w! then ;
: do.long! ( f -- )
if compileA5 long! else pushA5 ! then ;
: do.array! ( idx f -- )
if compileA5 array! else 4* pushA5 + ! then ;
: do.warray! ( idx f -- )
if compileA5 warray! else 2* pushA5 + w! then ;
: do.real! ( f -- )
if compileA5 real! else pushA5 f! then ;
create op.table! ( decision table for store )
]do.bit rts
do.byte! rts
do.word! rts
do.long! rts
do.string rts
do.real! rts
do.struct rts
do.array! rts
do.warray! rts
[
: s^ ( -- a | returns pointer to structure field )
( ALL field types are allowed. i.e. strings, struct, etc. )
state @
if compileA5 move.l_a0,-(a6) else pushA5 then
; immediate
: s@ ( -- data | Fetch field contents, data type smart)
state @
op.type @ op.table@ + execute ; immediate
: s! ( data -- | Store into field, data type smart)
state @
op.type @ op.table! + execute ; immediate
: stype ( -- op.type | returns the op.type of a field )
op.type @ state @
if [compile] literal then
; immediate
( Examples of structure usage. Data Storage is limited to the approximately
32K global area referenced off of register A5 -- just as for regular
MACH2 variables. Structure references have a REQUIRED syntax, it is best
NOT to use any non-STRUCTURE Forth words when between field names in
a structure calling sequence. That is, please end each structure reference
prior to any DUP’s, SWAP’s, etc. The structure pointer operator -- S^
-- may be used at any place in the structure calling sequence. S^ will
return the address of the field or structure itself. Structures MUST
be terminated with a defined structure operator! The defined operators
in this upload are S^, S@, S!, and STYPE. WARNING, if you forget to
terminate a structure, no structure reference will be compiled and an
error message MAY NOT be given. Remember also that field names ARE CASE
SENSITIVE and LOCAL to the structure template. Last comment, structures
MAY be nested to any level. )
fp
template Point
:word x
:word y
tend
template Rect
:word top
:word left
:word bottom
:word right
tend ( TEND ends template definition )
\ example for FP parameters
template parameter
30 :string name
:real value
30 :string unit
tend
template measurement
:long date \ in internal Mac format
80 :string title
255 :string descriptor
parameter :struct wavelength
parameter :struct temperature
parameter :struct angle
256:array time
256:array counts
tend
measurement structure curve1
: testarray
100 0 do i 4* i curve1 time s! loop
100 0 do i curve1 time s@ . cr loop;
: .date ( DateTime DateForm ) { | [ 40 lallot ] mydate -- }
8 shift ^ mydate call IUDateString ^ mydate count type;
: read.int
begin
pad 1+ 80 expect span @ pad c! pad number? not while
drop cr .” Illegal number [integer], reenter - “
repeat;
: read.float
begin
pad 1+ 80 expect span @ pad c! pad fnumber? not while
fdrop cr .” Illegal number [float], reenter - “
repeat;
: setup.curve1 { | dattim -- }
^ dattim call readdatetime drop @
cr .” Today is “ 1 .date
cr .” Setting up parameters for curve 1.”
dattim curve1 date s!
“ lambda” dup c@ 1+ curve1 wavelength name s^ swap cmove
“ T” dup c@ 1+ curve1 temperature name s^ swap cmove
“ delta” dup c@ 1+ curve1 angle name s^ swap cmove
“ [nm]” dup c@ 1+ curve1 wavelength unit s^ swap cmove
“ [K]” dup c@ 1+ curve1 temperature unit s^ swap cmove
“ [°]” dup c@ 1+ curve1 angle unit s^ swap cmove
cr .” Title (one line) - “ cr pad 80 expect
span @ curve1 title s^ c!
pad curve1 title s^ 1+ span @ cmove
cr .” Description (one line) - “ cr pad 80 expect
span @ curve1 descriptor s^ c!
pad curve1 descriptor s^ 1+ span @ cmove
cr .” lambda [nm] - “ read.float curve1 wavelength value s!
cr .” T [K] - “ read.float curve1 temperature value s!
cr .” delta [°] - “ read.float curve1 angle value s!
\ example setup of ‘measurement data’
20 0 do
i i curve1 time s!
i 100 * i curve1 counts s!
loop
cr .” End setup -- “ cr;
: dump.curve1 { | [ 80 lallot ] mydate -- }
cr .” Data taken on “ curve1 date s@ 1 .date
cr curve1 title s^ count type
cr curve1 descriptor s^ count type
cr curve1 wavelength name s^ count type .” = “
curve1 wavelength value s@ f.
curve1 wavelength unit s^ count type
cr curve1 temperature name s^ count type .” = “
curve1 temperature value s@ f.
curve1 temperature unit s^ count type
cr curve1 angle name s^ count type .” = “
curve1 angle value s@ f.
curve1 angle unit s^ count type
cr .” data follows:”
20 0 do cr
i curve1 time s@ . space
i curve1 counts s@ .
loop
cr
;
Listing 2: Structure definitions from ECFB
\ downloaded from GEnie J. L. Nov 1988
\ Originally from East Coast Forth Board,
\ author A. Nonymous
( This is a set of machforth routines for building records. They allow
you to build a named record with items of various sizes. Executing the
record name leaves the record size on the stack, executing an item name
leaves the offset of the item into the record on the stack. It creates
a template for the record but not the actual record. Create the record
with “ create <name> <record name> allot” or “variable <name> <record
name> 4 - vallot” depending if you want the entry in the dictionary or
variable space )
VOCABULARY RECORDS ( NEW VOCABULARY )
ALSO RECORDS
DEFINITIONS
Global
: Align ( n1 -- [n1] or [n1 + 1] makes n word aligned )
dup 2 mod + ; ( USED TO WORD ALIGN 2 & 4 BYTE ITEMS )
Global
: RECORD ( -- a 0)
HERE 4 + CREATE 0 dup W, DOES> W@ ;
( USED TO OPEN A RECORD )
Global
: BYTE: ( a n -- a n1+1)
CREATE DUP W, 1+ DOES> W@ + ;
Global
: BYTES: ( a n1 n2 -- a n1+n2 | AN ARRAY OF n2 bytes )
CREATE OVER Align W, swap Align + DOES> W@ + ;
Global
: SHORT: ( a n1 -- a n1+2 | 2 byte integer item )
CREATE Align DUP W, 2+ DOES> W@ + ;
Global
: WORD: ( a n1 -- a n1+2 | 2 byte integer item )
CREATE Align DUP W, 2+ DOES> W@ + ;
Global
: BOOLEAN: ( a n1 -- a n1+2 | 2 byte boolean item )
CREATE Align DUP W, 2+ DOES> W@ + ;
Global
: SHORTS: ( a n1 n2 -- a n1+n2*2 | an array of n2 shorts )
CREATE OVER Align W, 2* Swap Align + DOES> W@ + ;
Global
: LONG: ( a n1 -- a n1+4 | a 4 byte integer )
CREATE Align DUP W, 4 + DOES> W@ + ;
Global
: POINTER: ( a n1 -- a n1+4 | a 4 byte integer )
CREATE Align DUP W, 4 + DOES> W@ + ;
Global
: LONGS:
( a n1 n2 -- a n1+n2*4 | an array of n2 4 byte integers )
CREATE OVER Align W, 4 * swap Align + DOES> W@ + ;
Global
: HANDLE: ( a n1 -- a n1+4 | a handle, 4 byte, item )
CREATE Align DUP W, 4 + DOES> W@ + ;
Global
: HANDLES: ( a n1 n2 -- a n1+n2*4| array of n2 handles )
CREATE OVER Align W, 4 * swap Align + DOES> W@ + ;
Global
: ADDR: ( a n1 -- a n1+4 | 4 byte address item, ie pointer )
CREATE Align DUP W, 4 + DOES> W@ + ;
Global
: ADDRS: ( a n1 n2 -- a n1+n2*4 | array of n2 addresses )
CREATE OVER Align W, 4 * swap Align + DOES> W@ + ;
Global
: RECT: ( a n1 n2 -- a n1+8 | a rect item )
CREATE Align DUP W, 8 + DOES> W@ + ;
Global
: RECTS: ( a n1 n2 -- a n1+n2*8 | an array of n2 rects )
CREATE OVER Align W, 8 * swap Align + DOES> W@ + ;
Global
: STRING: ( a n1 n2 -- a n1+n2+1 | a string item n2+1 long )
CREATE OVER W, + 1+ DOES> W@ + ;
Global
: RECORD: ( a n1 n2 -- a n1+n2 | a record item of size n2)
CREATE OVER Align W, swap Align + DOES> W@ + ;
Global
: END.RECORD
{ Mainaddr size --|sets size of struct at a to n }
Mainaddr W@ Size <
IF Size MainAddr W! THen ;
( CLOSES RECORD, STORES RECORD SIZE IN RECORD NAME)
Global
: SUB.REC ( -- )
CReate 0 W, 2DUP Here 2- Rot Rot DOES> W@ ;
( USE TO CREATE VARIANT RECORD ON THE END OF A RECORD)
Global
: END.SUB { SubAddrs MainAddrs Size -- }
Size SubAddrs W!
MainAddrs W@ Size <
IF Size Align MainAddrs W! THen ;
( USE TO CLOSE VARIANT RECORD )
ONLY MAC
ALSO FORTH
DEFINITIONS
ALSO RECORDS
Global
RECORD Rectangle
Global SHORT: Top
Global Short: Left
Global Short: Bottom
Global SHORT: RIght
ENd.RECORD
Global
: rect Variable Rectangle 4 - VALLOT ;
( CREATES A RECTANGLE RECORD IN THE VARIABLE SPACE )
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