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base: Apple-2-SW:v8.3.1
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compare: Apple-2-SW:v8.8
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250 Commits
v8.3.1 ... v8.8

Author SHA1 Message Date
Irmen de Jong
475e927178 version 8.8 2022-12-17 23:00:49 +01:00
Irmen de Jong
ca7932c4f0 no longer do return value optimization with tempvar, this caused invalid code sometimes. 2022-12-14 22:33:16 +01:00
Irmen de Jong
8ab47d3321 fix_autostart_square() now preserves X register correctly 2022-12-14 01:07:44 +01:00
Irmen de Jong
def7e87151 fixed silly if-goto expression code in IR codegen where it used too many branching instructions 2022-12-12 22:47:15 +01:00
Irmen de Jong
27568c2bef fixed silly code generated by some NOT-expressions (unused temporary) 2022-12-12 21:57:22 +01:00
Irmen de Jong
0694a187d7 unsigned>0 now optimized into unsigned!=0 2022-12-12 20:37:57 +01:00
Irmen de Jong
832601b36b workaround for black square issue at start 2022-12-11 11:48:41 +01:00
Irmen de Jong
578969c34c optimize redundant rts/bra or rts/jmp generation in when statement 2022-12-10 17:21:15 +01:00
Irmen de Jong
d1d0115aed removed unused option 'keepIR' 2022-12-09 18:44:44 +01:00
Irmen de Jong
c89e6ebfab clarify 2022-12-08 22:21:45 +01:00
Irmen de Jong
ca1089b881 optimized codegen for logical expressions with simple right operand (such as c64.READST() & $40 ) 2022-12-06 20:23:56 +01:00
Irmen de Jong
a1d04f2aad added more $03xx vector definitions to C64/C128/CX16 syslib 2022-12-06 20:23:56 +01:00
Irmen de Jong
bf0604133c fix error in IR for inline asm and BSS vars. 2022-12-04 16:48:44 +01:00
Irmen de Jong
a82b2da16e Fix some FP related assignment issues in 6502 codegen. 2022-12-04 13:03:38 +01:00
Irmen de Jong
f2273c0acc fix several FP rom routine addresses on cx16. 2022-12-03 19:56:54 +01:00
Irmen de Jong
17bedac96c vm: memory is randomized on start instead of 0. P8ir file now has BSS segment. Vm clears BSS vars to 0. 2022-12-03 17:46:06 +01:00
Irmen de Jong
4831fad27a x16 emulators are now launched with PULSE_LATENCY_MSEC=10 env setting to mitigate static noise 2022-12-03 16:19:26 +01:00
Irmen de Jong
5e896cf582 preparing to add Golden RAM 2022-12-03 00:21:31 +01:00
Irmen de Jong
add3491c57 fix possible vardecl issue for prefixed params 2022-11-30 22:56:54 +01:00
Irmen de Jong
f470576822 it's now possible to use symbols that are the same name as 6502 instructions 
because these are now prefixed internally before generating assembly.
 2022-11-30 18:39:56 +01:00
Irmen de Jong
10760a53a8 optimize cmp word equal/notequal 2022-11-29 20:14:35 +01:00
Irmen de Jong
eee805183c don't overwrite temp vars in complex comparison expressions. Fixes #89 2022-11-29 04:13:25 +01:00
Irmen de Jong
b8fb391022 - ir codegen now allows subroutine having the same name as its block 
this is not possible for the 6502 codegen due to 64tass scoping limitation
 2022-11-28 21:54:33 +01:00
Irmen de Jong
3c698f1584 fileseek for writing not right now 2022-11-27 21:52:18 +01:00
Irmen de Jong
2fad52d684 the adpcm example can now read wav files directly (so no need anymore to extract the binary frame data from them) 2022-11-27 21:37:40 +01:00
Irmen de Jong
ec64a68a71 fixed compiler crash: unsigned = (-(unsigned as word) as uword) 2022-11-27 17:25:47 +01:00
Irmen de Jong
db55562f6a fixed adpcm playback 2022-11-27 16:36:30 +01:00
Irmen de Jong
d8409a9d2b fix compiler crash: if uwordvar > label 2022-11-26 14:39:03 +01:00
Irmen de Jong
0d0ce6eec1 adpcm plays pcm 2022-11-24 21:03:50 +01:00
Irmen de Jong
483f313eda ir: keep correct child node order in blocks 2022-11-24 01:19:48 +01:00
Irmen de Jong
7b6c742178 fixed diskio.f_read() for small read sizes 2022-11-24 00:23:37 +01:00
Irmen de Jong
d4a35ba6ff got rid of diskio.have_first_byte overhead 2022-11-23 21:53:36 +01:00
Irmen de Jong
68b112837a fix cx16logo.logo() printing correct newlines 2022-11-23 02:25:20 +01:00
Irmen de Jong
e2f20ebf94 fix crash on empty conditional branch statement (if_cc { } ) 2022-11-23 02:14:48 +01:00
Irmen de Jong
f870e4965a added cx16diskio.f_seek() function to seek to a position in an opened file 
f_open uses channel 12 now, f_open_w uses 13
 2022-11-23 01:48:04 +01:00
Irmen de Jong
7ebcb219d6 void func() now gives warning if func doesn't return a value 2022-11-22 22:54:40 +01:00
Irmen de Jong
c21913a66b ir: keep order of children in block 2022-11-22 02:04:24 +01:00
Irmen de Jong
77e956a29f API change: diskio.list_files doesn't have an internal buffer anymore, you now have to supply a buffer + size yourself. Renamed to list_filenames 2022-11-20 23:27:22 +01:00
Irmen de Jong
08275c406a added chdir/mkdir/rmdir/relabel to cx16diskio 2022-11-20 22:59:44 +01:00
Irmen de Jong
2931e1b87b diskio file lister routines now also put file type (prg, seq, dir) in new diskio.list_filetype variable 2022-11-20 20:22:09 +01:00
Irmen de Jong
153b422496 cx16: retain display mode (composite etc) 2022-11-20 19:19:01 +01:00
Irmen de Jong
0f6a6d6fea attempt to make gfx2 screen mode 0 cleanup more robust on real hardware 2022-11-18 22:53:28 +01:00
Irmen de Jong
91fdb3e2d4 ir: store labels in blocks, but still useless 2022-11-17 00:37:45 +01:00
Irmen de Jong
d8e87bd881 make uword xx = 1<<shift into a word shifting 2022-11-16 01:39:34 +01:00
Irmen de Jong
922033c1b2 main block element order now remains the same as in source 2022-11-16 00:32:00 +01:00
Irmen de Jong
df1793efbf fixed: word << 12 is suddenly an uword (with optimizer on) 2022-11-15 03:00:41 +01:00
Irmen de Jong
836a2700f2 func(x>>1) no longer uses slow stack eval 2022-11-15 02:49:40 +01:00
Irmen de Jong
8f3aaf77a1 fix optimizer hanging on uword xx :: xx >>= 8 / xx=msb(xx) 2022-11-15 01:40:13 +01:00
Irmen de Jong
00c059e5b1 adding cx16/adpcm example 2022-11-15 01:17:28 +01:00
Irmen de Jong
f4f355c74a added cx16/diskspeed example 2022-11-14 17:55:55 +01:00
Irmen de Jong
b465fc5aaf fix bug in word array containment check (prog8_lib.containment_wordarray) that could hang the loop 2022-11-12 23:19:01 +01:00
Irmen de Jong
2d78eaa48d fix gfx2 text color, added cx16 snow example 2022-11-12 22:08:07 +01:00
Irmen de Jong
d08451bccc ir: Block can now contain inline binary 2022-11-12 20:17:23 +01:00
Irmen de Jong
d8e785aed0 ir: fix too greedy chunk removal 2022-11-12 19:56:54 +01:00
Irmen de Jong
267b6f49b5 IRFileReader parses the p8ir file with xml parser 2022-11-12 16:51:20 +01:00
Irmen de Jong
e6688f4b9d clearer error for VM limitation cannot load label address as value 2022-11-12 13:45:02 +01:00
Irmen de Jong
9d7b9771c2 p8ir file format is now valid XML 2022-11-11 23:35:52 +01:00
Irmen de Jong
136a9a39de kotlin 1.7.21 2022-11-10 22:52:07 +01:00
Irmen de Jong
3dcf628fdb fixed subroutine name shadow check 2022-11-10 22:51:37 +01:00
Irmen de Jong
e614e9787a ir: write values as hex into p8ir file 2022-11-08 21:59:05 +01:00
Irmen de Jong
e426fc0922 version 8.7 2022-11-06 22:58:39 +01:00
Irmen de Jong
5d4bfffc7e float.rndseedf() now takes float seed value and is consistent for all CBM compilation targets 2022-11-06 22:53:57 +01:00
Irmen de Jong
207cdaf7a4 fix kefrenbars example (use gfx2 instead of kernal routines) 2022-11-06 17:33:30 +01:00
Irmen de Jong
7315b581ce added gfx2.pget(x,y) to get the pixel color value 2022-11-06 13:40:55 +01:00
Irmen de Jong
38efaae7b2 ir/vm: syscall params in high base register to avoid push/pop 2022-11-06 12:52:09 +01:00
Irmen de Jong
469e042216 vm: replaced prog8_lib.string_compare and others with syscalls 2022-11-04 23:12:13 +01:00
Irmen de Jong
0f1a4b9d8f fixed certain type check error when passing boolean value to ubyte function parameter 
fixed virtual machine string comparison syscall
 2022-11-03 23:06:03 +01:00
Irmen de Jong
7303c00296 vm: prog8lib.wordarray_contains() fixed 2022-11-03 22:48:47 +01:00
Irmen de Jong
fc55b34d84 ir: fix asmsub multi-value return codegen 2022-11-03 22:29:41 +01:00
Irmen de Jong
6f67fc0e02 ir: get rid of '_' symbol prefix 2022-11-03 21:54:53 +01:00
Irmen de Jong
562d722ad5 codegen: added missing codegen for float array inplace modification 2022-11-03 20:08:46 +01:00
Irmen de Jong
144c1ba3a6 ir: fix float instruction value in formatspec 2022-11-03 19:08:38 +01:00
Irmen de Jong
06b032af91 refactor 2022-11-03 00:20:31 +01:00
Irmen de Jong
3603140114 ir: fix unused code remover 2022-11-02 23:54:52 +01:00
Irmen de Jong
e094785cbd ir: fix unused code remover 2022-11-02 23:16:51 +01:00
Irmen de Jong
e7408224ac ir: remove position tracking from codechunk for now 2022-11-02 22:12:42 +01:00
Irmen de Jong
e67c05c274 ir: fix asmsub contents not appearing in IR file 2022-11-02 20:50:51 +01:00
Irmen de Jong
b22804efaf ir: fix inlineasm linking 2022-10-31 23:59:33 +01:00
Irmen de Jong
890f55f91a fixup compiler internals diagram 2022-10-31 00:39:43 +01:00
Irmen de Jong
cc5fc0b892 Merge branch 'master' into labeledchunks 
# Conflicts:
#	examples/test.p8
 2022-10-30 23:46:44 +01:00
Irmen de Jong
5efe2b027a ir: fix chunk linkage in optimizer 2022-10-30 23:42:41 +01:00
Irmen de Jong
5b6569d0f9 ir: fix overwriting chunk label 2022-10-30 19:03:02 +01:00
Irmen de Jong
0eda7ac498 vm: don't crash on empty code chunks 2022-10-30 17:05:08 +01:00
Irmen de Jong
a5ef353484 ir: fix memory mapped var as for loop counter 2022-10-30 14:54:47 +01:00
Irmen de Jong
67a36d8d31 more robust 'return' statement checks in subroutines 2022-10-30 14:41:28 +01:00
Irmen de Jong
7cc3cc3990 ir: fix non-code chunk linkage 2022-10-30 12:55:06 +01:00
Irmen de Jong
dc0edc4c2b break also in for 2022-10-29 23:34:59 +02:00
Irmen de Jong
71d2f091e5 Merge pull request #88 from markjreed/fix-mouse_config2 
fix: don't ignore shape argument to cx16.mouse_config2
 2022-10-29 23:22:14 +02:00
Mark J. Reed
c2f062a391 fix: don't ignore shape argument to cx16.mouse_config2 2022-10-29 17:10:06 -04:00
Irmen de Jong
224f490455 Merge branch 'master' into labeledchunks 
# Conflicts:
#	codeGenIntermediate/src/prog8/codegen/intermediate/AssignmentGen.kt
#	codeGenIntermediate/src/prog8/codegen/intermediate/ExpressionGen.kt
#	examples/test.p8
 2022-10-29 18:26:09 +02:00
Irmen de Jong
5b35232ab4 fix "fpReg1 out of bounds" crash for vm target for in-place float array assignment. #85 2022-10-29 17:04:39 +02:00
Irmen de Jong
6d6db70e42 remove type widening for bit shifts, to be consistent with other arithmetic operations. Fixes #83 2022-10-29 16:29:41 +02:00
Irmen de Jong
6830e15b4e print warning when bit shifts are too large and result in 0. #83 2022-10-29 15:23:39 +02:00
Irmen de Jong
3f07cad35d remove missing feature from docs 2022-10-29 14:31:40 +02:00
Irmen de Jong
e951340033 BASIC, VICE, C64, zeropage spelling 2022-10-29 14:17:40 +02:00
Irmen de Jong
db8912a735 Kernal spelling 2022-10-29 14:10:11 +02:00
Irmen de Jong
0e297731a3 PETSCII spelling 2022-10-29 14:07:04 +02:00
Irmen de Jong
f20c4f98ac Merge pull request #86 from Frosty-J/docs 
Fix typos in documentation
 2022-10-29 12:57:55 +02:00
Irmen de Jong
05e60cc7c0 fix array type typo 2022-10-29 12:57:33 +02:00
Irmen de Jong
55b4469767 Merge pull request #87 from Frosty-J/basicsafe 
`%zeropage basicsafe` in Hello World
 2022-10-29 12:31:28 +02:00
Frosty-J
f15516e478 Bracket space 2022-10-29 00:25:54 +01:00
Frosty-J
17ceadbadf %zeropage basicsafe in Hello World 2022-10-28 22:49:23 +01:00
Frosty-J
8c25b2b316 CommanderX16 -> Commander X16 2022-10-28 22:47:14 +01:00
Frosty-J
8b1ae404a3 Commodore-64 -> Commodore 64 2022-10-28 22:45:09 +01:00
Frosty-J
13534cd4a9 lowlevel -> low-level 2022-10-28 22:40:36 +01:00
Frosty-J
abfb345503 ofcourse -> of course 2022-10-28 22:39:54 +01:00
Frosty-J
42ae935496 Various typo fixes 2022-10-28 22:39:15 +01:00
Irmen de Jong
434515d957 fix: array[x] = ~array[x] no longer crashes the codegen 2022-10-27 23:56:38 +02:00
Irmen de Jong
094f7803b7 fix: array[x] = -array[x] no longer crashes the codegen 2022-10-27 23:20:40 +02:00
Irmen de Jong
b0c7bad391 fix: array[x] = -value no longer crashes the codegen 2022-10-27 21:58:37 +02:00
Irmen de Jong
e9a4a905ef preparing to fix the array indexing compiler issue 2022-10-26 23:53:17 +02:00
Irmen de Jong
7b6cd0cfbe cx16.macptr() now has additional argument in the carry flag, to reflect recent X16 kernal api change. 
Also now allow bool type for status flag args and returnvalues.
 2022-10-26 20:41:10 +02:00
Irmen de Jong
b718b12083 ir/vm fix chunk linkage 2022-10-26 00:12:56 +02:00
Irmen de Jong
cfa7258ff4 various 2022-10-25 23:18:42 +02:00
Irmen de Jong
b70e0a0870 mention syntax highlighting files in the docs 2022-10-25 21:24:38 +02:00
Irmen de Jong
da8eb464b8 add cx16diskio.vload_raw() to load headerless files into vram 2022-10-25 21:12:11 +02:00
Irmen de Jong
8f9d1cfa30 fix regression: indexing pointer variable with word (>255) didn't work anymore since release 8.2 or so 2022-10-24 23:43:47 +02:00
Irmen de Jong
585009ac5c ir: fix syscall numbers and more 2022-10-24 01:57:37 +02:00
Irmen de Jong
30ee65fd14 ir: ensure that block and sub labels are also on the first chunk in said block/sub 2022-10-23 18:54:08 +02:00
Irmen de Jong
76428b16f0 Merge branch 'master' into labeledchunks 
# Conflicts:
#	codeGenIntermediate/src/prog8/codegen/intermediate/BuiltinFuncGen.kt
#	docs/source/todo.rst
#	examples/test.p8
#	virtualmachine/src/prog8/vm/VirtualMachine.kt
 2022-10-23 12:19:02 +02:00
Irmen de Jong
0d7b14e2d8 fix crash when assigning certain memory read to word variable. Fixes #82 2022-10-23 11:57:23 +02:00
Irmen de Jong
a9d19d02b3 helpful error for programs still using the old builtin rnd() and rndw() 2022-10-22 22:36:44 +02:00
Irmen de Jong
adcbe55307 replaced integer RNG with smaller and faster routine. 2022-10-22 22:01:57 +02:00
Irmen de Jong
aa99a7df64 seed info 2022-10-22 17:54:24 +02:00
Irmen de Jong
00afa1ce52 ir: replace RND opcode by syscalls 2022-10-22 17:20:46 +02:00
Irmen de Jong
e94bf4c63c replace rnd()/rndw() builtin functions by regular routines in math module 2022-10-22 17:02:43 +02:00
Irmen de Jong
ec5adffdc2 rnd()/rndf() routines can now be seeded with new rndseed()/rndseedf() routines. fixes #80 2022-10-22 13:34:22 +02:00
Irmen de Jong
733c17ad3a improve docs on if syntax. fixes #81 2022-10-19 23:53:15 +02:00
Irmen de Jong
53b0b562e6 fix check for routine that returns multiple values but in status bit. Fixes #79 2022-10-19 23:23:49 +02:00
Irmen de Jong
fabae6e970 ir: fix handling of labeled chunks 2022-10-16 23:53:17 +02:00
Irmen de Jong
a9f9c40d8a ir: fix handling of labeled chunks 2022-10-13 00:56:44 +02:00
Irmen de Jong
6fc89607d3 ir: moving to labeled chunks, no more IRLabel nodes 2022-10-07 00:34:56 +02:00
Irmen de Jong
2340760f53 rename 2022-10-04 22:54:14 +02:00
Irmen de Jong
39d6d2857e ir: change inline binary a bit 2022-10-04 00:57:08 +02:00
Irmen de Jong
7b722a0001 ir: fix count register uses 2022-10-04 00:25:55 +02:00
Irmen de Jong
e7682119e0 ir: count register uses 2022-10-02 15:56:06 +02:00
Irmen de Jong
af6be44676 ir: adding register usage inspections 
fix compiler problems with untrimmed inlined asm, and when only a single return statement is present in a subroutine
 2022-09-30 20:25:00 +02:00
Irmen de Jong
5a8f97a0b6 ir: adding last missing features to be able to encode all of Prog8 2022-09-30 16:01:00 +02:00
Irmen de Jong
0d4dd385b8 added '%ir' to write inline IR code, '%asm' is now only for real 6502 assembly. 
(%ir is probably only used in the library modules for the virtual machine target)
 2022-09-30 15:12:26 +02:00
Irmen de Jong
94f0f3e966 ir: join code chunks 2022-09-30 02:47:33 +02:00
Irmen de Jong
43e31765e5 kotlin 1.7.20 2022-09-29 18:41:20 +02:00
Irmen de Jong
7c1bdfe713 ir: uninitialized vars remain empty, bss section classifier (unused for now as there are no segements yet) 2022-09-28 16:56:50 +02:00
Irmen de Jong
9f09784b55 version 8.6.2 2022-09-27 22:45:48 +02:00
Irmen de Jong
e7a3a89bfb fix windows issue 2022-09-27 22:41:48 +02:00
Irmen de Jong
7ea7e63f44 use require() more often 2022-09-27 18:27:55 +02:00
Irmen de Jong
1d2ce2cbeb consolidate IR line parse function 2022-09-27 18:02:57 +02:00
Irmen de Jong
06cf2e0bd7 vm: fix memory slabs (bsieve example) 2022-09-27 16:32:44 +02:00
Irmen de Jong
9d219ae4b9 refactor 2022-09-27 03:32:39 +02:00
Irmen de Jong
71f5a6c50e remove p8virt from compiler diagram 2022-09-27 02:52:29 +02:00
Irmen de Jong
90b2be2bf4 vm: new memory initialization of array vars 2022-09-27 02:43:50 +02:00
Irmen de Jong
db1aa8fcbd vm: new translation of IRProgram into vm program list 2022-09-27 01:50:00 +02:00
Irmen de Jong
11c000f764 moved codeGenVirtual module into virtualmachine module 2022-09-26 20:00:40 +02:00
Irmen de Jong
4d6dcbd173 ir: consolidate IRCodeInstruction and Instruction 2022-09-26 19:46:44 +02:00
Irmen de Jong
0da117efd2 vm: get rid of .p8virt file and cruft 2022-09-26 19:28:40 +02:00
Irmen de Jong
533c368e32 make IRFileReader's file source more general 2022-09-26 14:47:28 +02:00
Irmen de Jong
8883513b0e attempt to fix readthedocs.io build 2022-09-25 22:19:32 +02:00
Irmen de Jong
dcc9a71455 version 8.6.1 2022-09-25 21:54:35 +02:00
Irmen de Jong
1a56743bb1 fix IR repeat loop codegen when amount is 0 2022-09-25 20:48:17 +02:00
Irmen de Jong
387a4b7c35 added string.lowerchar() and string.upperchar() 2022-09-25 20:20:38 +02:00
Irmen de Jong
1d65d63bd9 ir: making sure all names are scoped properly. textelite now runs in vm 2022-09-25 18:02:35 +02:00
Irmen de Jong
dda19c29fe vm: fix symbols to be case sensitive properly in p8virt assembler 2022-09-25 15:51:50 +02:00
Irmen de Jong
ca41669f4f vm: fix scoped name in address-of inside array 2022-09-24 18:26:35 +02:00
Irmen de Jong
0e1886e6bd vm: fix nested label prefixing 2022-09-24 16:00:25 +02:00
Irmen de Jong
c26e116f0e vm: fix crashes when array contains pointers/strings 2022-09-24 14:42:07 +02:00
Irmen de Jong
5c9c7f2c5e adding more complex vm examples 2022-09-23 14:56:06 +02:00
Irmen de Jong
ca2fb6cef3 IR no longer depends on VM syscalls but has its own syscall list for the few builtin functions that still require it 2022-09-23 14:27:51 +02:00
Irmen de Jong
46dac909ef vm/math.p8: complete the sin and cos routines 2022-09-22 15:49:19 +02:00
Irmen de Jong
b1e4347e10 fix compiler crash sometimes when casting byte to word 2022-09-22 13:00:47 +02:00
Irmen de Jong
97aa91c75e removed 16 bits sin/cos routines from math library (sin16, sin16r etc) 2022-09-22 12:55:00 +02:00
Irmen de Jong
4f8fb32136 some docs about compiler internal architecture 2022-09-21 17:34:52 +02:00
Irmen de Jong
e0fbce0087 few more unittests for IR 2022-09-21 02:59:36 +02:00
Irmen de Jong
fb22f78fb3 added '-keepIR' option to save the IR file if it's generated. 2022-09-20 12:30:22 +02:00
Irmen de Jong
d6393cdbe5 '-vm' option now also reads .p8ir files 2022-09-20 12:14:33 +02:00
Irmen de Jong
5167fdb3f0 docs 2022-09-20 04:10:49 +02:00
Irmen de Jong
ab00822764 move IR optimizer to IR Codegen module 2022-09-19 19:41:43 +02:00
Irmen de Jong
b4352ad38b refactor IR codegen into separate module 2022-09-19 19:24:24 +02:00
Irmen de Jong
d07d00fa41 Join codeAst and codeCore modules 2022-09-19 17:28:18 +02:00
Irmen de Jong
11d87e4725 VM: support cpu registers 2022-09-19 17:13:46 +02:00
Irmen de Jong
627ed51a1b IR: mem mapped vars and memory slabs 2022-09-19 15:20:40 +02:00
Irmen de Jong
c8f3bfa726 vm assembler now understands simple indexed addresses (symbol+number) 2022-09-18 02:17:42 +02:00
Irmen de Jong
3091e3a1c8 IR support for instructions operating on cpu regs 2022-09-18 01:51:04 +02:00
Irmen de Jong
2f3e7d1c27 IR support for storing incbins and romsubs 2022-09-17 16:07:41 +02:00
Irmen de Jong
0e831d4b92 fix superfluous usage of addressOf() 2022-09-16 00:31:04 +02:00
Irmen de Jong
7294ec9a3c working on address-of 2022-09-15 22:44:33 +02:00
Irmen de Jong
e34bab9585 change syntax of address-of in p8virt code to &X, instead of {X} 2022-09-13 23:28:52 +02:00
Irmen de Jong
7dd14955c1 added remaining signature stuff to IRAsmSubroutine 2022-09-13 23:06:05 +02:00
Irmen de Jong
6428ced157 added subroutine params to IRSubroutine 2022-09-13 23:06:05 +02:00
Irmen de Jong
30a42ec1bd IR tweak 2022-09-13 23:06:05 +02:00
Irmen de Jong
aacea3e9db incbin in IR 2022-09-13 23:06:05 +02:00
Irmen de Jong
6886b61186 also output inline asm chunks 2022-09-13 23:06:05 +02:00
Irmen de Jong
0744c9fa29 properly flatten label names for the IR code 2022-09-13 23:06:05 +02:00
Irmen de Jong
502a665ffc getting address-of into IR without allocations 2022-09-13 23:06:05 +02:00
Irmen de Jong
3c315703c0 making IR file reader 2022-09-13 23:06:05 +02:00
Irmen de Jong
12ed07a607 comments 2022-09-13 23:06:05 +02:00
Irmen de Jong
101b33c381 split intermediate representation into separate module 2022-09-13 23:06:05 +02:00
Irmen de Jong
97f4316653 rename IR classes 2022-09-13 23:06:05 +02:00
Irmen de Jong
b0704e86f0 block structure 2022-09-13 23:06:05 +02:00
Irmen de Jong
a182b13e5a fixup for memoryslabs 2022-09-13 23:06:05 +02:00
Irmen de Jong
80b630a1e4 added memoryslabs to symboltable 2022-09-13 23:06:05 +02:00
Irmen de Jong
475efbe007 steps to make actual IR based on VM code. For now, as experimental codegen. 2022-09-13 23:06:05 +02:00
Irmen de Jong
3ab5e5ac48 added cx16.kbdbuf_clear() 2022-09-01 18:40:17 +02:00
Irmen de Jong
c6c5ff2089 added joystick controls to cx16 tehtriz 2022-08-23 18:11:35 +02:00
Irmen de Jong
176ec8ac7d fix 6502 codegen bug: complex comparison expression is evaluated wrong. 
Fixed by reintroducing splitting of comparison expression in if statements by using a temporary variable and/or register to precompute left/right values.
 2022-08-23 00:05:57 +02:00
Irmen de Jong
dcdd4b3255 found bug in comparison expr codegen 2022-08-22 23:16:56 +02:00
Irmen de Jong
fc0a0105b3 move memoryslab administration from allocator to symboltable 2022-08-21 19:48:56 +02:00
Irmen de Jong
f3960d21a8 fix xmlwriter 2022-08-21 19:12:01 +02:00
Irmen de Jong
a44d853c1b added memoryslabs to symboltable 2022-08-21 19:05:01 +02:00
Irmen de Jong
6b41734d6a check memory() calls before entering codegen 2022-08-21 19:02:34 +02:00
Irmen de Jong
c33dc0f3be version 2022-08-21 14:37:10 +02:00
Irmen de Jong
bb5ffb24a8 add IDEA antlr parser build info to documentation 2022-08-21 13:32:31 +02:00
Irmen de Jong
a878c9a61d add some documentation to the psg module 2022-08-19 22:17:23 +02:00
Irmen de Jong
6454bf8ec4 added mouse cursor to amiga example 
slightly sped up text rendering in gfx2 highres mode
 2022-08-16 04:25:59 +02:00
Irmen de Jong
40aa733ea7 clearer name 2022-08-15 20:55:35 +02:00
Irmen de Jong
f37a822725 move 2022-08-14 13:17:03 +02:00
Irmen de Jong
f249ccd414 added asm optimization for same pointer index 2022-08-14 12:50:46 +02:00
Irmen de Jong
7ef4ddf0f3 fixed operator precedence: bitwise must come before comparisons 2022-08-14 12:34:00 +02:00
Irmen de Jong
d8e18df3a1 added c64 starfield example 2022-08-14 12:02:23 +02:00
Irmen de Jong
78d3d9d27d vm: get rid of jumpi traces, fix IR value issue with STOREIX 2022-08-13 20:00:13 +02:00
Irmen de Jong
0aa0ec5abd fix c64 zeropage locations of cx16 virtual registers 2022-08-13 00:14:19 +02:00
Irmen de Jong
b6eef3612f added some ported bench8 test programs 2022-08-12 22:08:27 +02:00
Irmen de Jong
666d62dd7a fix cx16.r0 base address to be $04 on the C-64, and fix zeropage duplicate free addresses 2022-08-12 17:49:31 +02:00
Irmen de Jong
44ee4b989f optimize code for logical expressions more if right operand is simple 2022-08-12 00:49:40 +02:00
Irmen de Jong
18790d867c optimize conditional expression WORD & $ff00 to just msb(WORD)&$ff 2022-08-12 00:21:44 +02:00
Irmen de Jong
d6b8936376 fix mkword(@(ptr), 0) wrong asm 2022-08-11 23:01:19 +02:00
Irmen de Jong
4d840c7db8 optimized mkword(0, X) 2022-08-11 22:51:09 +02:00
Irmen de Jong
4d2b21816d optimized uword <<8 and >>8 2022-08-11 22:25:15 +02:00
Irmen de Jong
2d34fdd28f in a block marked option force_output, make all subroutines in asm use .block rather than .proc 
this fixes some obscure assembly issues where subroutines were omitted from the output program by 64tass
 2022-08-10 21:28:40 +02:00
Irmen de Jong
68abda1219 fix a few small compiler errors (removing functioncall, removing block, assigning virtual register return value) 2022-08-09 23:38:29 +02:00
Irmen de Jong
f778f08f76 tweak 2022-08-08 21:09:49 +02:00
Irmen de Jong
ac1bd2fb7b virtual: properly output "memmapped" variables too 
still as regular variables though
 2022-08-08 20:42:17 +02:00
Irmen de Jong
4b7b1379d9 also binexpr split on and,or,xor if appropriate 2022-08-08 00:09:18 +02:00
Irmen de Jong
e560e2ab3f vm instructions now contain info on input/output registers 2022-08-07 18:49:16 +02:00
Irmen de Jong
1e441c2ddf tweak vm codegen 2022-08-07 13:45:03 +02:00
Irmen de Jong
93ce74eeb1 removed problematic expression "simplifications" (that introduced arbitrary r9 temp register usage) 2022-08-07 12:26:11 +02:00
Irmen de Jong
f718f4251b working on better encoding of romsub in new ast/vmtarget 2022-08-07 12:21:10 +02:00
Irmen de Jong
4644c9b621 got rid of GoSub ast node and codegen complexity related to that. 
sometimes programs get smaller, sometimes bigger.
 2022-08-07 03:24:20 +02:00
Irmen de Jong
197081f10d keyboardhandler 2022-08-04 23:04:16 +02:00
Irmen de Jong
00b717cde8 tweak 2022-08-04 18:35:10 +02:00
Irmen de Jong
34aa917ca4 allow bool return type (and arguments) for asmsub / romsub 2022-08-02 23:07:42 +02:00
Irmen de Jong
a38ddcb364 diskio use other filename buffer to avoid always having large buffer 2022-08-02 00:58:32 +02:00
Irmen de Jong
5b9576df4e added diskio.send_command() 
diskio now reuses some buffer internally for file names to save some memory
 2022-08-01 22:59:27 +02:00
Irmen de Jong
310219e5d7 make sure memory slabs block is at the bottom of the asm file to not allocate needless space in the resulting prg 2022-07-31 15:37:36 +02:00
Irmen de Jong
a0deb463c9 optimized codegen for some equality comparison expressions and some logical expressions 2022-07-31 15:25:54 +02:00
Irmen de Jong
90ddec2ad8 avoid multiple change events in watch mode 
added bsieve example
 2022-07-31 11:58:27 +02:00
Irmen de Jong
f6b03d5a78 added diskio.diskname(), improved error checking in diskio.directory() 2022-07-30 13:35:42 +02:00
Irmen de Jong
f531daa872 on C64, the cx16.r0...cx16.r15 virtual regs are now in zeropage as well when using kernalsafe or full 2022-07-28 19:13:33 +02:00
Irmen de Jong
046dceb5c2 added optimized case for signed division by 2 2022-07-24 13:59:35 +02:00
Irmen de Jong
dcc1f00048 fix rounding errors in signed divide by power-of-two 
The optimized bit-shifting division is removed (for now)
 2022-07-24 12:34:55 +02:00
Irmen de Jong
05f935b598 simplify & fix recursion detector 2022-07-22 22:22:43 +02:00
Irmen de Jong
f2d27403c5 add string.endswith() to efficiently test for a suffix without copying 
add string.startswith() to efficiently test for string prefix without copying
 2022-07-21 00:38:30 +02:00
241 changed files with 15210 additions and 8082 deletions
Expand all files Collapse all files

2
.idea/misc.xml generated
View File

@ -19,7 +19,7 @@
<component name="FrameworkDetectionExcludesConfiguration">
<type id="Python" />
</component>
<component name="ProjectRootManager" version="2" languageLevel="JDK_11" project-jdk-name="11" project-jdk-type="JavaSDK">
<component name="ProjectRootManager" version="2" languageLevel="JDK_11" default="true" project-jdk-name="11" project-jdk-type="JavaSDK">
<output url="file://$PROJECT_DIR$/out" />
</component>
</project>

3
.idea/modules.xml generated
View File

@ -2,10 +2,10 @@
<project version="4">
<component name="ProjectModuleManager">
<modules>
<module fileurl="file://$PROJECT_DIR$/codeAst/codeAst.iml" filepath="$PROJECT_DIR$/codeAst/codeAst.iml" />
<module fileurl="file://$PROJECT_DIR$/codeCore/codeCore.iml" filepath="$PROJECT_DIR$/codeCore/codeCore.iml" />
<module fileurl="file://$PROJECT_DIR$/codeGenCpu6502/codeGenCpu6502.iml" filepath="$PROJECT_DIR$/codeGenCpu6502/codeGenCpu6502.iml" />
<module fileurl="file://$PROJECT_DIR$/codeGenExperimental/codeGenExperimental.iml" filepath="$PROJECT_DIR$/codeGenExperimental/codeGenExperimental.iml" />
<module fileurl="file://$PROJECT_DIR$/codeGenIntermediate/codeGenIntermediate.iml" filepath="$PROJECT_DIR$/codeGenIntermediate/codeGenIntermediate.iml" />
<module fileurl="file://$PROJECT_DIR$/codeGenVirtual/codeGenVirtual.iml" filepath="$PROJECT_DIR$/codeGenVirtual/codeGenVirtual.iml" />
<module fileurl="file://$PROJECT_DIR$/codeOptimizers/codeOptimizers.iml" filepath="$PROJECT_DIR$/codeOptimizers/codeOptimizers.iml" />
<module fileurl="file://$PROJECT_DIR$/compiler/compiler.iml" filepath="$PROJECT_DIR$/compiler/compiler.iml" />
@ -14,6 +14,7 @@
<module fileurl="file://$PROJECT_DIR$/docs/docs.iml" filepath="$PROJECT_DIR$/docs/docs.iml" />
<module fileurl="file://$PROJECT_DIR$/examples/examples.iml" filepath="$PROJECT_DIR$/examples/examples.iml" />
<module fileurl="file://$PROJECT_DIR$/httpCompilerService/httpCompilerService.iml" filepath="$PROJECT_DIR$/httpCompilerService/httpCompilerService.iml" />
<module fileurl="file://$PROJECT_DIR$/intermediate/intermediate.iml" filepath="$PROJECT_DIR$/intermediate/intermediate.iml" />
<module fileurl="file://$PROJECT_DIR$/parser/parser.iml" filepath="$PROJECT_DIR$/parser/parser.iml" />
<module fileurl="file://$PROJECT_DIR$/virtualmachine/virtualmachine.iml" filepath="$PROJECT_DIR$/virtualmachine/virtualmachine.iml" />
</modules>

3
README.md
View File

@ -78,6 +78,9 @@ It's handy to have an emulator (or a real machine perhaps!) to run the programs
of the [Vice emulator](http://vice-emu.sourceforge.net/) for the C64 target,
and the [x16emu emulator](https://github.com/commanderx16/x16-emulator) for the CommanderX16 target.
**Syntax highlighting:** for a few different editors, syntax highlighting definition files are provided.
Look in the [syntax-files](https://github.com/irmen/prog8/tree/master/syntax-files) directory in the github repository to find them.
Example code
------------

3
compilerAst/src/prog8/Either.kt → codeCore/src/prog8/code/Either.kt
View File

@ -1,8 +1,7 @@
package prog8
package prog8.code
/**
* By convention, the right side of an `Either` is used to hold successful values.
*
*/
sealed class Either<out L, out R> {

98
codeAst/src/prog8/code/SymbolTable.kt → codeCore/src/prog8/code/SymbolTable.kt
View File

@ -5,13 +5,9 @@ import prog8.code.core.*
/**
* Tree structure containing all symbol definitions in the program
* (blocks, subroutines, variables (all types) and labels).
* (blocks, subroutines, variables (all types), memoryslabs, and labels).
*/
class SymbolTable : StNode("", StNodeType.GLOBAL, Position.DUMMY) {
fun print() = printIndented(0)
override fun printProperties() { }
/**
* The table as a flat mapping of scoped names to the StNode.
* This gives the fastest lookup possible (no need to traverse tree nodes)
@ -54,6 +50,10 @@ class SymbolTable : StNode("", StNodeType.GLOBAL, Position.DUMMY) {
vars
}
val allMemorySlabs: Collection<StMemorySlab> by lazy {
children.mapNotNull { if (it.value.type == StNodeType.MEMORYSLAB) it.value as StMemorySlab else null }
}
override fun lookup(scopedName: List<String>) = flat[scopedName]
}
@ -68,7 +68,8 @@ enum class StNodeType {
STATICVAR,
MEMVAR,
CONSTANT,
BUILTINFUNC
BUILTINFUNC,
MEMORYSLAB
}
@ -133,28 +134,6 @@ open class StNode(val name: String,
}
}
fun printIndented(indent: Int) {
print(" ".repeat(indent))
when(type) {
StNodeType.GLOBAL -> print("SYMBOL-TABLE:")
StNodeType.BLOCK -> print("(B) ")
StNodeType.SUBROUTINE -> print("(S) ")
StNodeType.LABEL -> print("(L) ")
StNodeType.STATICVAR -> print("(V) ")
StNodeType.MEMVAR -> print("(M) ")
StNodeType.CONSTANT -> print("(C) ")
StNodeType.BUILTINFUNC -> print("(F) ")
StNodeType.ROMSUB -> print("(R) ")
}
printProperties()
println()
children.forEach { (_, node) -> node.printIndented(indent+1) }
}
open fun printProperties() {
print("$name ")
}
fun add(child: StNode) {
children[child.name] = child
child.parent = this
@ -163,40 +142,43 @@ open class StNode(val name: String,
class StStaticVariable(name: String,
val dt: DataType,
val initialNumericValue: Double?,
val initialStringValue: StString?,
val initialArrayValue: StArray?,
val bss: Boolean,
val onetimeInitializationNumericValue: Double?, // regular (every-run-time) initialization is done via regular assignments
val onetimeInitializationStringValue: StString?,
val onetimeInitializationArrayValue: StArray?,
val length: Int?, // for arrays: the number of elements, for strings: number of characters *including* the terminating 0-byte
val zpwish: ZeropageWish,
position: Position) : StNode(name, StNodeType.STATICVAR, position) {
init {
if(bss) {
require(onetimeInitializationNumericValue==null)
require(onetimeInitializationStringValue==null)
require(onetimeInitializationArrayValue.isNullOrEmpty())
} else {
require(onetimeInitializationNumericValue!=null ||
onetimeInitializationStringValue!=null ||
onetimeInitializationArrayValue!=null)
}
if(length!=null) {
require(initialNumericValue == null)
if(initialArrayValue!=null)
require(length == initialArrayValue.size)
require(onetimeInitializationNumericValue == null)
if(onetimeInitializationArrayValue!=null)
require(onetimeInitializationArrayValue.isEmpty() ||onetimeInitializationArrayValue.size==length)
}
if(initialNumericValue!=null)
if(onetimeInitializationNumericValue!=null)
require(dt in NumericDatatypes)
if(initialArrayValue!=null)
if(onetimeInitializationArrayValue!=null)
require(dt in ArrayDatatypes)
if(initialStringValue!=null) {
if(onetimeInitializationStringValue!=null) {
require(dt == DataType.STR)
require(length == initialStringValue.first.length+1)
require(length == onetimeInitializationStringValue.first.length+1)
}
}
override fun printProperties() {
print("$name dt=$dt zpw=$zpwish")
}
}
class StConstant(name: String, val dt: DataType, val value: Double, position: Position) :
StNode(name, StNodeType.CONSTANT, position) {
override fun printProperties() {
print("$name dt=$dt value=$value")
}
}
@ -206,29 +188,33 @@ class StMemVar(name: String,
val length: Int?, // for arrays: the number of elements, for strings: number of characters *including* the terminating 0-byte
position: Position) :
StNode(name, StNodeType.MEMVAR, position) {
override fun printProperties() {
print("$name dt=$dt address=${address.toHex()}")
}
}
class StMemorySlab(
name: String,
val size: UInt,
val align: UInt,
position: Position
):
StNode(name, StNodeType.MEMORYSLAB, position) {
}
class StSub(name: String, val parameters: List<StSubroutineParameter>, position: Position) :
class StSub(name: String, val parameters: List<StSubroutineParameter>, val returnType: DataType?, position: Position) :
StNode(name, StNodeType.SUBROUTINE, position) {
override fun printProperties() {
print(name)
}
}
class StRomSub(name: String, val address: UInt, parameters: List<StSubroutineParameter>, position: Position) :
class StRomSub(name: String,
val address: UInt,
val parameters: List<StRomSubParameter>,
val returns: List<RegisterOrStatusflag>,
position: Position) :
StNode(name, StNodeType.ROMSUB, position) {
override fun printProperties() {
print("$name address=${address.toHex()}")
}
}
class StSubroutineParameter(val name: String, val type: DataType)
class StRomSubParameter(val register: RegisterOrStatusflag, val type: DataType)
class StArrayElement(val number: Double?, val addressOf: List<String>?)
typealias StString = Pair<String, Encoding>

11
codeAst/src/prog8/code/ast/AstBase.kt → codeCore/src/prog8/code/ast/AstBase.kt
View File

@ -3,7 +3,7 @@ package prog8.code.ast
import prog8.code.core.*
import java.nio.file.Path
// New (work-in-progress) simplified AST for the code generator.
// New simplified AST for the code generator.
sealed class PtNode(val position: Position) {
@ -42,7 +42,7 @@ class PtNodeGroup : PtNode(Position.DUMMY) {
}
abstract class PtNamedNode(val name: String, position: Position): PtNode(position) {
sealed class PtNamedNode(val name: String, position: Position): PtNode(position) {
val scopedName: List<String> by lazy {
var namedParent: PtNode = this.parent
if(namedParent is PtProgram)
@ -96,8 +96,13 @@ class PtBlock(name: String,
}
class PtInlineAssembly(val assembly: String, position: Position) : PtNode(position) {
class PtInlineAssembly(val assembly: String, val isIR: Boolean, position: Position) : PtNode(position) {
override fun printProperties() {}
init {
require(!assembly.startsWith('\n') && !assembly.startsWith('\r')) { "inline assembly should be trimmed" }
require(!assembly.endsWith('\n') && !assembly.endsWith('\r')) { "inline assembly should be trimmed" }
}
}

12
codeAst/src/prog8/code/ast/AstExpressions.kt → codeCore/src/prog8/code/ast/AstExpressions.kt
View File

@ -12,6 +12,15 @@ sealed class PtExpression(val type: DataType, position: Position) : PtNode(posit
init {
if(type==DataType.BOOL)
throw IllegalArgumentException("bool should have become ubyte @$position")
if(type==DataType.UNDEFINED) {
@Suppress("LeakingThis")
when(this) {
is PtBuiltinFunctionCall -> { /* void function call */ }
is PtFunctionCall -> { /* void function call */ }
is PtIdentifier -> { /* non-variable identifier */ }
else -> throw IllegalArgumentException("type should be known @$position")
}
}
}
override fun printProperties() {
@ -164,8 +173,7 @@ class PtPrefix(val operator: String, type: DataType, position: Position): PtExpr
init {
// note: the "not" operator may no longer occur in the ast; not x should have been replaced with x==0
if(operator !in setOf("+", "-", "~"))
throw IllegalArgumentException("invalid prefix operator: $operator")
require(operator in setOf("+", "-", "~")) { "invalid prefix operator: $operator" }
}
override fun printProperties() {

9
codeAst/src/prog8/code/ast/AstStatements.kt → codeCore/src/prog8/code/ast/AstStatements.kt
View File

@ -8,6 +8,7 @@ class PtAsmSub(
val address: UInt?,
val clobbers: Set<CpuRegister>,
val parameters: List<Pair<PtSubroutineParameter, RegisterOrStatusflag>>,
val returnTypes: List<DataType>, // TODO join with register as Pairs ?
val retvalRegisters: List<RegisterOrStatusflag>,
val inline: Boolean,
position: Position
@ -28,6 +29,14 @@ class PtSub(
override fun printProperties() {
print(name)
}
init {
// params and return value should not be str
if(parameters.any{ it.type !in NumericDatatypes })
throw AssemblyError("non-numeric parameter")
if(returntype!=null && returntype !in NumericDatatypes)
throw AssemblyError("non-numeric returntype $returntype")
}
}

15
codeCore/src/prog8/code/core/IMachineDefinition.kt
View File

@ -3,11 +3,6 @@ package prog8.code.core
import java.nio.file.Path
interface IMachineFloat {
fun toDouble(): Double
fun makeFloatFillAsm(): String
}
enum class CpuType {
CPU6502,
CPU65c02,
@ -22,12 +17,12 @@ interface IMachineDefinition {
var ESTACK_HI: UInt
val PROGRAM_LOAD_ADDRESS : UInt
val opcodeNames: Set<String>
var zeropage: Zeropage
val cpu: CpuType
var zeropage: Zeropage
var golden: GoldenRam
fun initializeZeropage(compilerOptions: CompilationOptions)
fun getFloat(num: Number): IMachineFloat
fun initializeMemoryAreas(compilerOptions: CompilationOptions)
fun getFloatAsmBytes(num: Number): String
fun importLibs(compilerOptions: CompilationOptions, compilationTargetName: String): List<String>
fun launchEmulator(selectedEmulator: Int, programNameWithPath: Path)
@ -36,5 +31,7 @@ interface IMachineDefinition {
require(evalStackBaseAddress and 255u == 0u)
ESTACK_LO = evalStackBaseAddress
ESTACK_HI = evalStackBaseAddress + 256u
require(ESTACK_LO !in golden.region && ESTACK_HI !in golden.region) { "user-set ESTACK can't be in GOLDEN ram" }
}
}

85
codeCore/src/prog8/code/core/Zeropage.kt → codeCore/src/prog8/code/core/MemoryRegions.kt
View File

@ -5,21 +5,31 @@ import com.github.michaelbull.result.Ok
import com.github.michaelbull.result.Result
class ZeropageAllocationError(message: String) : Exception(message)
class MemAllocationError(message: String) : Exception(message)
abstract class Zeropage(protected val options: CompilationOptions) {
abstract class MemoryAllocator(protected val options: CompilationOptions) {
data class VarAllocation(val address: UInt, val dt: DataType, val size: Int)
abstract fun allocate(name: List<String>,
datatype: DataType,
numElements: Int?,
position: Position?,
errors: IErrorReporter): Result<VarAllocation, MemAllocationError>
}
abstract class Zeropage(options: CompilationOptions): MemoryAllocator(options) {
abstract val SCRATCH_B1 : UInt // temp storage for a single byte
abstract val SCRATCH_REG : UInt // temp storage for a register, must be B1+1
abstract val SCRATCH_W1 : UInt // temp storage 1 for a word $fb+$fc
abstract val SCRATCH_W2 : UInt // temp storage 2 for a word $fb+$fc
data class ZpAllocation(val address: UInt, val dt: DataType, val size: Int)
// the variables allocated into Zeropage.
// name (scoped) ==> pair of address to (Datatype + bytesize)
val allocatedVariables = mutableMapOf<List<String>, ZpAllocation>()
val allocatedVariables = mutableMapOf<List<String>, VarAllocation>()
val free = mutableListOf<UInt>() // subclasses must set this to the appropriate free locations.
@ -41,17 +51,16 @@ abstract class Zeropage(protected val options: CompilationOptions) {
return free.windowed(2).any { it[0] == it[1] - 1u }
}
fun allocate(name: List<String>,
datatype: DataType,
numElements: Int?,
position: Position?,
errors: IErrorReporter
): Result<Pair<UInt, Int>, ZeropageAllocationError> {
override fun allocate(name: List<String>,
datatype: DataType,
numElements: Int?,
position: Position?,
errors: IErrorReporter): Result<VarAllocation, MemAllocationError> {
require(name.isEmpty() || name !in allocatedVariables) {"name can't be allocated twice"}
if(options.zeropage== ZeropageType.DONTUSE)
return Err(ZeropageAllocationError("zero page usage has been disabled"))
return Err(MemAllocationError("zero page usage has been disabled"))
val size: Int =
when (datatype) {
@ -72,9 +81,9 @@ abstract class Zeropage(protected val options: CompilationOptions) {
else
errors.warn("$name: allocating a large value in zeropage; float $memsize bytes", Position.DUMMY)
memsize
} else return Err(ZeropageAllocationError("floating point option not enabled"))
} else return Err(MemAllocationError("floating point option not enabled"))
}
else -> return Err(ZeropageAllocationError("cannot put datatype $datatype in zeropage"))
else -> throw MemAllocationError("weird dt")
}
synchronized(this) {
@ -82,18 +91,18 @@ abstract class Zeropage(protected val options: CompilationOptions) {
if(size==1) {
for(candidate in free.minOrNull()!! .. free.maxOrNull()!!+1u) {
if(oneSeparateByteFree(candidate))
return Ok(Pair(makeAllocation(candidate, 1, datatype, name), 1))
return Ok(VarAllocation(makeAllocation(candidate, 1, datatype, name), datatype,1))
}
return Ok(Pair(makeAllocation(free[0], 1, datatype, name), 1))
return Ok(VarAllocation(makeAllocation(free[0], 1, datatype, name), datatype,1))
}
for(candidate in free.minOrNull()!! .. free.maxOrNull()!!+1u) {
if (sequentialFree(candidate, size))
return Ok(Pair(makeAllocation(candidate, size, datatype, name), size))
return Ok(VarAllocation(makeAllocation(candidate, size, datatype, name), datatype, size))
}
}
}
return Err(ZeropageAllocationError("no more free space in ZP to allocate $size sequential bytes"))
return Err(MemAllocationError("no more free space in ZP to allocate $size sequential bytes"))
}
private fun reserve(range: UIntRange) = free.removeAll(range)
@ -103,9 +112,9 @@ abstract class Zeropage(protected val options: CompilationOptions) {
free.removeAll(address until address+size.toUInt())
if(name.isNotEmpty()) {
allocatedVariables[name] = when(datatype) {
in NumericDatatypes -> ZpAllocation(address, datatype, size) // numerical variables in zeropage never have an initial value here because they are set in separate initializer assignments
DataType.STR -> ZpAllocation(address, datatype, size)
in ArrayDatatypes -> ZpAllocation(address, datatype, size)
in NumericDatatypes -> VarAllocation(address, datatype, size) // numerical variables in zeropage never have an initial value here because they are set in separate initializer assignments
DataType.STR -> VarAllocation(address, datatype, size)
in ArrayDatatypes -> VarAllocation(address, datatype, size)
else -> throw AssemblyError("invalid dt")
}
}
@ -117,4 +126,40 @@ abstract class Zeropage(protected val options: CompilationOptions) {
require(size>0)
return free.containsAll((address until address+size.toUInt()).toList())
}
abstract fun allocateCx16VirtualRegisters()
}
class GoldenRam(options: CompilationOptions, val region: UIntRange): MemoryAllocator(options) {
private var nextLocation: UInt = region.first
override fun allocate(
name: List<String>,
datatype: DataType,
numElements: Int?,
position: Position?,
errors: IErrorReporter): Result<VarAllocation, MemAllocationError> {
val size: Int =
when (datatype) {
in IntegerDatatypes -> options.compTarget.memorySize(datatype)
DataType.STR, in ArrayDatatypes -> {
options.compTarget.memorySize(datatype, numElements!!)
}
DataType.FLOAT -> {
if (options.floats) {
options.compTarget.memorySize(DataType.FLOAT)
} else return Err(MemAllocationError("floating point option not enabled"))
}
else -> throw MemAllocationError("weird dt")
}
return if(nextLocation<=region.last && (region.last + 1u - nextLocation) >= size.toUInt()) {
val result = Ok(VarAllocation(nextLocation, datatype, size))
nextLocation += size.toUInt()
result
} else
Err(MemAllocationError("no more free space in Golden RAM to allocate $size sequential bytes"))
}
}

2
codeCore/src/prog8/code/core/Operators.kt
View File

@ -3,7 +3,7 @@ package prog8.code.core
val AssociativeOperators = setOf("+", "*", "&", "|", "^", "==", "!=")
val ComparisonOperators = setOf("==", "!=", "<", ">", "<=", ">=")
val LogicalOperators = setOf("and", "or", "xor", "not")
val AugmentAssignmentOperators = setOf("+", "-", "/", "*", "&", "|", "^", "<<", ">>", "%")
val AugmentAssignmentOperators = setOf("+", "-", "/", "*", "&", "|", "^", "<<", ">>", "%", "and", "or", "xor")
val BitwiseOperators = setOf("&", "|", "^", "~")
// val InvalidOperatorsForBoolean = setOf("+", "-", "*", "/", "%", "<<", ">>") + BitwiseOperators

4
codeCore/src/prog8/code/core/SourceCode.kt
View File

@ -106,7 +106,7 @@ sealed class SourceCode {
* [origin]: `library:/x/y/z.p8` for a given `pathString` of "x/y/z.p8"
*/
class Resource(pathString: String): SourceCode() {
private val normalized = "/" + Path.of(pathString).normalize().toMutableList().joinToString("/")
private val normalized = "/" + Path(pathString).normalize().toMutableList().joinToString("/")
override val isFromResources = true
override val isFromFilesystem = false
@ -125,7 +125,7 @@ sealed class SourceCode {
}
val stream = object {}.javaClass.getResourceAsStream(normalized)
text = stream!!.reader().use { it.readText() }
name = Path.of(pathString).toFile().nameWithoutExtension
name = Path(pathString).toFile().nameWithoutExtension
}
}

9
codeCore/src/prog8/code/target/atari/AtariMachineDefinition.kt
View File

@ -1,7 +1,6 @@
package prog8.code.target.atari
import prog8.code.core.*
import prog8.code.target.c64.normal6502instructions
import java.nio.file.Path
@ -19,8 +18,9 @@ class AtariMachineDefinition: IMachineDefinition {
override var ESTACK_HI = 0x1b00u // $1b00-$1bff inclusive // TODO
override lateinit var zeropage: Zeropage
override lateinit var golden: GoldenRam
override fun getFloat(num: Number) = TODO("float from number")
override fun getFloatAsmBytes(num: Number) = TODO("float asm bytes from number")
override fun importLibs(compilerOptions: CompilationOptions, compilationTargetName: String): List<String> {
return if (compilerOptions.output == OutputType.XEX)
@ -57,9 +57,8 @@ class AtariMachineDefinition: IMachineDefinition {
override fun isIOAddress(address: UInt): Boolean = address==0u || address==1u || address in 0xd000u..0xdfffu // TODO
override fun initializeZeropage(compilerOptions: CompilationOptions) {
override fun initializeMemoryAreas(compilerOptions: CompilationOptions) {
zeropage = AtariZeropage(compilerOptions)
golden = GoldenRam(compilerOptions, UIntRange.EMPTY)
}
override val opcodeNames = normal6502instructions
}

9
codeCore/src/prog8/code/target/atari/AtariZeropage.kt
View File

@ -12,7 +12,6 @@ class AtariZeropage(options: CompilationOptions) : Zeropage(options) {
override val SCRATCH_W1 = 0xcdu // temp storage 1 for a word $cd+$ce
override val SCRATCH_W2 = 0xcfu // temp storage 2 for a word $cf+$d0 TODO is $d0 okay to use?
init {
if (options.floats && options.zeropage !in arrayOf(
ZeropageType.FLOATSAFE,
@ -40,6 +39,14 @@ class AtariZeropage(options: CompilationOptions) : Zeropage(options) {
}
}
val distictFree = free.distinct()
free.clear()
free.addAll(distictFree)
removeReservedFromFreePool()
}
override fun allocateCx16VirtualRegisters() {
TODO("Not known if atari can put the virtual regs in ZP")
}
}

10
codeCore/src/prog8/code/target/c128/C128MachineDefinition.kt
View File

@ -1,7 +1,6 @@
package prog8.code.target.c128
import prog8.code.core.*
import prog8.code.target.c64.normal6502instructions
import prog8.code.target.cbm.Mflpt5
import java.nio.file.Path
@ -18,10 +17,10 @@ class C128MachineDefinition: IMachineDefinition {
// the 2*256 byte evaluation stack (on which bytes, words, and even floats are stored during calculations)
override var ESTACK_LO = 0x1a00u // $1a00-$1aff inclusive
override var ESTACK_HI = 0x1b00u // $1b00-$1bff inclusive
override lateinit var zeropage: Zeropage
override lateinit var golden: GoldenRam
override fun getFloat(num: Number) = Mflpt5.fromNumber(num)
override fun getFloatAsmBytes(num: Number) = Mflpt5.fromNumber(num).makeFloatFillAsm()
override fun importLibs(compilerOptions: CompilationOptions, compilationTargetName: String): List<String> {
return if (compilerOptions.launcher == CbmPrgLauncherType.BASIC || compilerOptions.output == OutputType.PRG)
@ -47,9 +46,8 @@ class C128MachineDefinition: IMachineDefinition {
override fun isIOAddress(address: UInt): Boolean = address==0u || address==1u || address in 0xd000u..0xdfffu
override fun initializeZeropage(compilerOptions: CompilationOptions) {
override fun initializeMemoryAreas(compilerOptions: CompilationOptions) {
zeropage = C128Zeropage(compilerOptions)
golden = GoldenRam(compilerOptions, UIntRange.EMPTY) // TODO does the c128 have some of this somewhere?
}
override val opcodeNames = normal6502instructions
}

8
codeCore/src/prog8/code/target/c128/C128Zeropage.kt
View File

@ -38,6 +38,14 @@ class C128Zeropage(options: CompilationOptions) : Zeropage(options) {
}
}
val distictFree = free.distinct()
free.clear()
free.addAll(distictFree)
removeReservedFromFreePool()
}
override fun allocateCx16VirtualRegisters() {
TODO("Not known if C128 can put the virtual regs in ZP")
}
}

21
codeCore/src/prog8/code/target/c64/C64MachineDefinition.kt
View File

@ -18,10 +18,10 @@ class C64MachineDefinition: IMachineDefinition {
// the 2*256 byte evaluation stack (on which bytes, words, and even floats are stored during calculations)
override var ESTACK_LO = 0xce00u // $ce00-$ceff inclusive
override var ESTACK_HI = 0xcf00u // $ce00-$ceff inclusive
override lateinit var zeropage: Zeropage
override lateinit var golden: GoldenRam
override fun getFloat(num: Number) = Mflpt5.fromNumber(num)
override fun getFloatAsmBytes(num: Number) = Mflpt5.fromNumber(num).makeFloatFillAsm()
override fun importLibs(compilerOptions: CompilationOptions, compilationTargetName: String): List<String> {
return if (compilerOptions.launcher == CbmPrgLauncherType.BASIC || compilerOptions.output == OutputType.PRG)
@ -55,22 +55,9 @@ class C64MachineDefinition: IMachineDefinition {
override fun isIOAddress(address: UInt): Boolean = address==0u || address==1u || address in 0xd000u..0xdfffu
override fun initializeZeropage(compilerOptions: CompilationOptions) {
override fun initializeMemoryAreas(compilerOptions: CompilationOptions) {
zeropage = C64Zeropage(compilerOptions)
golden = GoldenRam(compilerOptions, 0xc000u until ESTACK_LO)
}
override val opcodeNames = normal6502instructions
}
// 6502 opcodes (including aliases and illegal opcodes), these cannot be used as variable or label names
internal val normal6502instructions = setOf(
"adc", "ahx", "alr", "anc", "and", "ane", "arr", "asl", "asr", "axs", "bcc", "bcs",
"beq", "bge", "bit", "blt", "bmi", "bne", "bpl", "brk", "bvc", "bvs", "clc",
"cld", "cli", "clv", "cmp", "cpx", "cpy", "dcm", "dcp", "dec", "dex", "dey",
"eor", "gcc", "gcs", "geq", "gge", "glt", "gmi", "gne", "gpl", "gvc", "gvs",
"inc", "ins", "inx", "iny", "isb", "isc", "jam", "jmp", "jsr", "lae", "las",
"lax", "lda", "lds", "ldx", "ldy", "lsr", "lxa", "nop", "ora", "pha", "php",
"pla", "plp", "rla", "rol", "ror", "rra", "rti", "rts", "sax", "sbc", "sbx",
"sec", "sed", "sei", "sha", "shl", "shr", "shs", "shx", "shy", "slo", "sre",
"sta", "stx", "sty", "tas", "tax", "tay", "tsx", "txa", "txs", "tya", "xaa")

33
codeCore/src/prog8/code/target/c64/C64Zeropage.kt
View File

@ -1,9 +1,6 @@
package prog8.code.target.c64
import prog8.code.core.CompilationOptions
import prog8.code.core.InternalCompilerException
import prog8.code.core.Zeropage
import prog8.code.core.ZeropageType
import prog8.code.core.*
class C64Zeropage(options: CompilationOptions) : Zeropage(options) {
@ -59,7 +56,7 @@ class C64Zeropage(options: CompilationOptions) : Zeropage(options) {
if(options.zeropage!= ZeropageType.DONTUSE) {
// add the free Zp addresses
// these are valid for the C-64 but allow BASIC to keep running fully *as long as you don't use tape I/O*
free.addAll(listOf(0x04, 0x05, 0x06, 0x0a, 0x0e,
free.addAll(listOf(0x02, 0x03, 0x04, 0x05, 0x06, 0x0a, 0x0e,
0x92, 0x96, 0x9b, 0x9c, 0x9e, 0x9f, 0xa5, 0xa6,
0xb0, 0xb1, 0xbe, 0xbf, 0xf9).map{it.toUInt()})
} else {
@ -68,6 +65,32 @@ class C64Zeropage(options: CompilationOptions) : Zeropage(options) {
}
}
val distictFree = free.distinct()
free.clear()
free.addAll(distictFree)
removeReservedFromFreePool()
if(options.zeropage==ZeropageType.FULL || options.zeropage==ZeropageType.KERNALSAFE) {
// in these cases there is enough space on the zero page to stick the cx16 virtual registers in there as well.
allocateCx16VirtualRegisters()
}
}
override fun allocateCx16VirtualRegisters() {
// Note: the 16 virtual registers R0-R15 are not regular allocated variables, they're *memory mapped* elsewhere to fixed addresses.
// However, to be able for the compiler to "see" them as zero page variables, we have to register them here as well.
// This is important because the compiler sometimes treats ZP variables more efficiently (for example if it's a pointer)
// The base addres is $04. Unfortunately it cannot be the same as on the Commander X16 ($02).
for(reg in 0..15) {
allocatedVariables[listOf("cx16", "r${reg}")] = VarAllocation((4+reg*2).toUInt(), DataType.UWORD, 2) // cx16.r0 .. cx16.r15
allocatedVariables[listOf("cx16", "r${reg}s")] = VarAllocation((4+reg*2).toUInt(), DataType.WORD, 2) // cx16.r0s .. cx16.r15s
allocatedVariables[listOf("cx16", "r${reg}L")] = VarAllocation((4+reg*2).toUInt(), DataType.UBYTE, 1) // cx16.r0L .. cx16.r15L
allocatedVariables[listOf("cx16", "r${reg}H")] = VarAllocation((5+reg*2).toUInt(), DataType.UBYTE, 1) // cx16.r0H .. cx16.r15H
allocatedVariables[listOf("cx16", "r${reg}sL")] = VarAllocation((4+reg*2).toUInt(), DataType.BYTE, 1) // cx16.r0sL .. cx16.r15sL
allocatedVariables[listOf("cx16", "r${reg}sH")] = VarAllocation((5+reg*2).toUInt(), DataType.BYTE, 1) // cx16.r0sH .. cx16.r15sH
free.remove((4+reg*2).toUInt())
free.remove((5+reg*2).toUInt())
}
}
}

7
codeCore/src/prog8/code/target/cbm/Mflpt5.kt
View File

@ -1,12 +1,11 @@
package prog8.code.target.cbm
import prog8.code.core.IMachineFloat
import prog8.code.core.InternalCompilerException
import kotlin.math.absoluteValue
import kotlin.math.pow
data class Mflpt5(val b0: UByte, val b1: UByte, val b2: UByte, val b3: UByte, val b4: UByte): IMachineFloat {
data class Mflpt5(val b0: UByte, val b1: UByte, val b2: UByte, val b3: UByte, val b4: UByte) {
companion object {
const val FLOAT_MAX_POSITIVE = 1.7014118345e+38 // bytes: 255,127,255,255,255
@ -58,7 +57,7 @@ data class Mflpt5(val b0: UByte, val b1: UByte, val b2: UByte, val b3: UByte, va
}
}
override fun toDouble(): Double {
fun toDouble(): Double {
if (this == zero) return 0.0
val exp = b0.toInt() - 128
val sign = (b1.toInt() and 0x80) > 0
@ -67,7 +66,7 @@ data class Mflpt5(val b0: UByte, val b1: UByte, val b2: UByte, val b3: UByte, va
return if (sign) -result else result
}
override fun makeFloatFillAsm(): String {
fun makeFloatFillAsm(): String {
val b0 = "$" + b0.toString(16).padStart(2, '0')
val b1 = "$" + b1.toString(16).padStart(2, '0')
val b2 = "$" + b2.toString(16).padStart(2, '0')

22
codeCore/src/prog8/code/target/cx16/CX16MachineDefinition.kt
View File

@ -17,10 +17,10 @@ class CX16MachineDefinition: IMachineDefinition {
// the 2*256 byte evaluation stack (on which bytes, words, and even floats are stored during calculations)
override var ESTACK_LO = 0x0400u // $0400-$04ff inclusive
override var ESTACK_HI = 0x0500u // $0500-$05ff inclusive
override lateinit var zeropage: Zeropage
override lateinit var golden: GoldenRam
override fun getFloat(num: Number) = Mflpt5.fromNumber(num)
override fun getFloatAsmBytes(num: Number) = Mflpt5.fromNumber(num).makeFloatFillAsm()
override fun importLibs(compilerOptions: CompilationOptions, compilationTargetName: String): List<String> {
return if (compilerOptions.launcher == CbmPrgLauncherType.BASIC || compilerOptions.output == OutputType.PRG)
listOf("syslib")
@ -50,28 +50,16 @@ class CX16MachineDefinition: IMachineDefinition {
println("\nStarting Commander X16 emulator $emulator...")
val cmdline = listOf(emulator, "-scale", "2", "-run", "-prg", "${programNameWithPath}.prg") + extraArgs
val processb = ProcessBuilder(cmdline).inheritIO()
processb.environment()["PULSE_LATENCY_MSEC"] = "10"
val process: Process = processb.start()
process.waitFor()
}
override fun isIOAddress(address: UInt): Boolean = address==0u || address==1u || address in 0x9f00u..0x9fffu
override fun initializeZeropage(compilerOptions: CompilationOptions) {
override fun initializeMemoryAreas(compilerOptions: CompilationOptions) {
zeropage = CX16Zeropage(compilerOptions)
golden = GoldenRam(compilerOptions, 0x0600u until 0x0800u)
}
// 65c02 opcodes, these cannot be used as variable or label names
override val opcodeNames = setOf("adc", "and", "asl", "bcc", "bcs",
"beq", "bge", "bit", "blt", "bmi", "bne", "bpl", "brk", "bvc", "bvs", "clc",
"cld", "cli", "clv", "cmp", "cpx", "cpy", "dec", "dex", "dey",
"eor", "gcc", "gcs", "geq", "gge", "glt", "gmi", "gne", "gpl", "gvc", "gvs",
"inc", "inx", "iny", "jmp", "jsr",
"lda", "ldx", "ldy", "lsr", "nop", "ora", "pha", "php",
"pla", "plp", "rol", "ror", "rti", "rts", "sbc",
"sec", "sed", "sei",
"sta", "stx", "sty", "tax", "tay", "tsx", "txa", "txs", "tya",
"bra", "phx", "phy", "plx", "ply", "stz", "trb", "tsb", "bbr", "bbs",
"rmb", "smb", "stp", "wai")
}

30
codeCore/src/prog8/code/target/cx16/CX16Zeropage.kt
View File

@ -43,19 +43,27 @@ class CX16Zeropage(options: CompilationOptions) : Zeropage(options) {
else -> throw InternalCompilerException("for this machine target, zero page type 'floatsafe' is not available. ${options.zeropage}")
}
val distictFree = free.distinct()
free.clear()
free.addAll(distictFree)
removeReservedFromFreePool()
// Note: the 16 virtual registers R0-R15 are not regular allocated variables, they're *memory mapped* elsewhere to fixed addresses.
// However, to be able for the compiler to "see" them as zero page variables, we have to register them here as well.
// This is important because the compiler sometimes treats ZP variables more efficiently (for example if it's a pointer)
for(reg in 0..15) {
allocatedVariables[listOf("cx16", "r${reg}")] = ZpAllocation((2+reg*2).toUInt(), DataType.UWORD, 2) // cx16.r0 .. cx16.r15
allocatedVariables[listOf("cx16", "r${reg}s")] = ZpAllocation((2+reg*2).toUInt(), DataType.WORD, 2) // cx16.r0s .. cx16.r15s
allocatedVariables[listOf("cx16", "r${reg}L")] = ZpAllocation((2+reg*2).toUInt(), DataType.UBYTE, 1) // cx16.r0L .. cx16.r15L
allocatedVariables[listOf("cx16", "r${reg}H")] = ZpAllocation((3+reg*2).toUInt(), DataType.UBYTE, 1) // cx16.r0H .. cx16.r15H
allocatedVariables[listOf("cx16", "r${reg}sL")] = ZpAllocation((2+reg*2).toUInt(), DataType.BYTE, 1) // cx16.r0sL .. cx16.r15sL
allocatedVariables[listOf("cx16", "r${reg}sH")] = ZpAllocation((3+reg*2).toUInt(), DataType.BYTE, 1) // cx16.r0sH .. cx16.r15sH
}
allocateCx16VirtualRegisters()
}
}
override fun allocateCx16VirtualRegisters() {
// Note: the 16 virtual registers R0-R15 are not regular allocated variables, they're *memory mapped* elsewhere to fixed addresses.
// However, to be able for the compiler to "see" them as zero page variables, we have to register them here as well.
// This is important because the compiler sometimes treats ZP variables more efficiently (for example if it's a pointer)
for(reg in 0..15) {
allocatedVariables[listOf("cx16", "r${reg}")] = VarAllocation((2+reg*2).toUInt(), DataType.UWORD, 2) // cx16.r0 .. cx16.r15
allocatedVariables[listOf("cx16", "r${reg}s")] = VarAllocation((2+reg*2).toUInt(), DataType.WORD, 2) // cx16.r0s .. cx16.r15s
allocatedVariables[listOf("cx16", "r${reg}L")] = VarAllocation((2+reg*2).toUInt(), DataType.UBYTE, 1) // cx16.r0L .. cx16.r15L
allocatedVariables[listOf("cx16", "r${reg}H")] = VarAllocation((3+reg*2).toUInt(), DataType.UBYTE, 1) // cx16.r0H .. cx16.r15H
allocatedVariables[listOf("cx16", "r${reg}sL")] = VarAllocation((2+reg*2).toUInt(), DataType.BYTE, 1) // cx16.r0sL .. cx16.r15sL
allocatedVariables[listOf("cx16", "r${reg}sH")] = VarAllocation((3+reg*2).toUInt(), DataType.BYTE, 1) // cx16.r0sH .. cx16.r15sH
}
}
}

36
codeCore/src/prog8/code/target/virtual/VirtualMachineDefinition.kt
View File

@ -1,12 +1,10 @@
package prog8.code.target.virtual
import prog8.code.core.CompilationOptions
import prog8.code.core.CpuType
import prog8.code.core.IMachineDefinition
import prog8.code.core.Zeropage
import java.io.File
import prog8.code.core.*
import java.nio.file.Path
import kotlin.io.path.isReadable
import kotlin.io.path.name
import kotlin.io.path.readText
class VirtualMachineDefinition: IMachineDefinition {
@ -19,10 +17,10 @@ class VirtualMachineDefinition: IMachineDefinition {
override var ESTACK_LO = 0u // not actually used
override var ESTACK_HI = 0u // not actually used
override lateinit var zeropage: Zeropage // not actually used
override lateinit var golden: GoldenRam // not actually used
override lateinit var zeropage: Zeropage // not actually used
override fun getFloat(num: Number) = TODO("float from number")
override fun getFloatAsmBytes(num: Number) = TODO("float asm bytes from number")
override fun importLibs(compilerOptions: CompilationOptions, compilationTargetName: String): List<String> {
return listOf("syslib")
@ -30,19 +28,25 @@ class VirtualMachineDefinition: IMachineDefinition {
override fun launchEmulator(selectedEmulator: Int, programNameWithPath: Path) {
println("\nStarting Virtual Machine...")
// to not have external module dependencies we launch the virtual machine via reflection
// to not have external module dependencies in our own module, we launch the virtual machine via reflection
val vm = Class.forName("prog8.vm.VmRunner").getDeclaredConstructor().newInstance() as IVirtualMachineRunner
val source = File("$programNameWithPath.p8virt").readText()
vm.runProgram(source, true)
val filename = programNameWithPath.name
if(programNameWithPath.isReadable()) {
vm.runProgram(programNameWithPath.readText())
} else {
val withExt = programNameWithPath.resolveSibling("$filename.p8ir")
if(withExt.isReadable())
vm.runProgram(withExt.readText())
else
throw NoSuchFileException(withExt.toFile(), reason="not a .p8ir file")
}
}
override fun isIOAddress(address: UInt): Boolean = false
override fun initializeZeropage(compilerOptions: CompilationOptions) {}
override val opcodeNames = emptySet<String>()
override fun initializeMemoryAreas(compilerOptions: CompilationOptions) {}
}
interface IVirtualMachineRunner {
fun runProgram(source: String, throttle: Boolean)
fun runProgram(irSource: String)
}

1
codeGenCpu6502/build.gradle
View File

@ -24,7 +24,6 @@ compileTestKotlin {
}
dependencies {
implementation project(':codeAst')
implementation project(':codeCore')
implementation project(':compilerAst')
implementation "org.jetbrains.kotlin:kotlin-stdlib-jdk8"

1
codeGenCpu6502/codeGenCpu6502.iml
View File

@ -9,7 +9,6 @@
<orderEntry type="inheritedJdk" />
<orderEntry type="sourceFolder" forTests="false" />
<orderEntry type="library" name="KotlinJavaRuntime" level="project" />
<orderEntry type="module" module-name="codeAst" />
<orderEntry type="module" module-name="codeCore" />
<orderEntry type="module" module-name="compilerAst" />
<orderEntry type="library" name="michael.bull.kotlin.result.jvm" level="project" />

326
codeGenCpu6502/src/prog8/codegen/cpu6502/AsmGen.kt
View File

@ -41,7 +41,7 @@ class AsmGen(internal val program: Program,
private val expressionsAsmGen = ExpressionsAsmGen(program, this, allocator)
private val programGen = ProgramAndVarsGen(program, options, errors, symbolTable, functioncallAsmGen, this, allocator, zeropage)
private val assignmentAsmGen = AssignmentAsmGen(program, this, allocator)
private val builtinFunctionsAsmGen = BuiltinFunctionsAsmGen(program, this, assignmentAsmGen, allocator)
private val builtinFunctionsAsmGen = BuiltinFunctionsAsmGen(program, this, assignmentAsmGen)
override fun compileToAssembly(): IAssemblyProgram? {
@ -77,7 +77,7 @@ class AsmGen(internal val program: Program,
}
internal fun out(str: String, splitlines: Boolean = true) {
val fragment = (if(splitlines && " | " in str) str.replace("|", "\n") else str).trim('\n')
val fragment = (if(splitlines && " | " in str) str.replace("|", "\n") else str).trim('\r', '\n')
if (splitlines) {
for (line in fragment.splitToSequence('\n')) {
val trimmed = if (line.startsWith(' ')) "\t" + line.trim() else line
@ -106,7 +106,7 @@ class AsmGen(internal val program: Program,
DataType.BYTE -> listOf("cx16", "r9sL")
DataType.UWORD -> listOf("cx16", "r9")
DataType.WORD -> listOf("cx16", "r9s")
DataType.FLOAT -> listOf("floats", "tempvar_swap_float") // defined in floats.p8
DataType.FLOAT -> TODO("no temporary float var available")
else -> throw FatalAstException("invalid dt $dt")
}
}
@ -311,13 +311,12 @@ class AsmGen(internal val program: Program,
is Subroutine -> programGen.translateSubroutine(stmt)
is InlineAssembly -> translate(stmt)
is BuiltinFunctionCallStatement -> builtinFunctionsAsmGen.translateFunctioncallStatement(stmt)
is FunctionCallStatement -> functioncallAsmGen.translateFunctionCallStatement(stmt) // TODO try to remove this last usage of FunctionCallStatement node in the codegen.
is FunctionCallStatement -> functioncallAsmGen.translateFunctionCallStatement(stmt)
is Assignment -> assignmentAsmGen.translate(stmt)
is Jump -> {
val (asmLabel, indirect) = getJumpTarget(stmt)
jmp(asmLabel, indirect)
}
is GoSub -> translate(stmt)
is PostIncrDecr -> postincrdecrAsmGen.translate(stmt)
is Label -> translate(stmt)
is ConditionalBranch -> translate(stmt)
@ -376,7 +375,7 @@ class AsmGen(internal val program: Program,
}
}
DataType.FLOAT -> {
require(options.compTarget.memorySize(DataType.FLOAT) == 5)
require(options.compTarget.memorySize(DataType.FLOAT) == 5) {"invalid float size ${expr.position}"}
out(
"""
lda $indexName
@ -407,7 +406,7 @@ class AsmGen(internal val program: Program,
}
}
DataType.FLOAT -> {
require(options.compTarget.memorySize(DataType.FLOAT) == 5)
require(options.compTarget.memorySize(DataType.FLOAT) == 5) {"invalid float size ${expr.position}"}
out(
"""
lda $indexName
@ -441,15 +440,9 @@ class AsmGen(internal val program: Program,
internal fun saveXbeforeCall(functionCall: IFunctionCall) =
functioncallAsmGen.saveXbeforeCall(functionCall)
internal fun saveXbeforeCall(gosub: GoSub) =
functioncallAsmGen.saveXbeforeCall(gosub)
internal fun restoreXafterCall(functionCall: IFunctionCall) =
functioncallAsmGen.restoreXafterCall(functionCall)
internal fun restoreXafterCall(gosub: GoSub) =
functioncallAsmGen.restoreXafterCall(gosub)
internal fun translateNormalAssignment(assign: AsmAssignment) =
assignmentAsmGen.translateNormalAssignment(assign)
@ -612,7 +605,7 @@ class AsmGen(internal val program: Program,
}
private fun repeatWordCount(count: Int, stmt: RepeatLoop) {
require(count in 257..65535)
require(count in 257..65535) { "invalid repeat count ${stmt.position}" }
val repeatLabel = program.makeLabel("repeat")
if(isTargetCpu(CpuType.CPU65c02)) {
val counterVar = createRepeatCounterVar(DataType.UWORD, true, stmt)
@ -674,7 +667,7 @@ $repeatLabel lda $counterVar
}
private fun repeatByteCount(count: Int, stmt: RepeatLoop) {
require(count in 2..256)
require(count in 2..256) { "invalid repeat count ${stmt.position}" }
val repeatLabel = program.makeLabel("repeat")
if(isTargetCpu(CpuType.CPU65c02)) {
val counterVar = createRepeatCounterVar(DataType.UBYTE, true, stmt)
@ -801,7 +794,7 @@ $repeatLabel lda $counterVar
if(stmt.truepart.isEmpty() && stmt.elsepart.isNotEmpty())
throw AssemblyError("only else part contains code, shoud have been switched already")
val jump = stmt.truepart.statements.first() as? Jump
val jump = stmt.truepart.statements.firstOrNull() as? Jump
if(jump!=null) {
// branch with only a jump (goto)
val instruction = branchInstruction(stmt.condition, false)
@ -819,11 +812,13 @@ $repeatLabel lda $counterVar
translate(stmt.elsepart)
} else {
if(stmt.elsepart.isEmpty()) {
val instruction = branchInstruction(stmt.condition, true)
val elseLabel = program.makeLabel("branch_else")
out(" $instruction $elseLabel")
translate(stmt.truepart)
out(elseLabel)
if(stmt.truepart.isNotEmpty()) {
val instruction = branchInstruction(stmt.condition, true)
val elseLabel = program.makeLabel("branch_else")
out(" $instruction $elseLabel")
translate(stmt.truepart)
out(elseLabel)
}
} else {
val instruction = branchInstruction(stmt.condition, true)
val elseLabel = program.makeLabel("branch_else")
@ -845,7 +840,7 @@ $repeatLabel lda $counterVar
if(stmt.definingModule.source is SourceCode.Generated)
throw AssemblyError("%asminclude inside non-library/non-filesystem module not yet supported")
loadAsmIncludeFile(includedName, stmt.definingModule.source).fold(
success = { assemblyLines.add(it.trimEnd().trimStart('\n')) },
success = { assemblyLines.add(it.trimEnd().trimStart('\r', '\n')) },
failure = { errors.err(it.toString(), stmt.position) }
)
}
@ -872,18 +867,6 @@ $repeatLabel lda $counterVar
}
}
private fun translate(gosub: GoSub) {
val tgt = gosub.identifier.targetSubroutine(program)
if(tgt!=null && tgt.isAsmSubroutine) {
// no need to rescue X , this has been taken care of already
out(" jsr ${getJumpTarget(gosub)}")
} else {
saveXbeforeCall(gosub)
out(" jsr ${getJumpTarget(gosub)}")
restoreXafterCall(gosub)
}
}
private fun getJumpTarget(jump: Jump): Pair<String, Boolean> {
val ident = jump.identifier
val label = jump.generatedLabel
@ -903,8 +886,6 @@ $repeatLabel lda $counterVar
}
}
private fun getJumpTarget(gosub: GoSub): String = asmSymbolName(gosub.identifier)
private fun translate(ret: Return, withRts: Boolean=true) {
ret.value?.let { returnvalue ->
val sub = ret.definingSubroutine!!
@ -930,8 +911,7 @@ $repeatLabel lda $counterVar
}
private fun translate(asm: InlineAssembly) {
val assembly = asm.assembly.trimEnd().trimStart('\n')
assemblyLines.add(assembly)
assemblyLines.add(asm.assembly.trimEnd().trimStart('\r', '\n'))
}
internal fun returnRegisterOfFunction(it: IdentifierReference): RegisterOrPair {
@ -1090,11 +1070,20 @@ $repeatLabel lda $counterVar
val saveA = evalBytevalueWillClobberA(ptrAndIndex.first) || evalBytevalueWillClobberA(ptrAndIndex.second)
if(saveA)
out(" pha")
assignExpressionToVariable(ptrAndIndex.first, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
assignExpressionToRegister(ptrAndIndex.second, RegisterOrPair.Y)
if(saveA)
out(" pla")
out(" sta (P8ZP_SCRATCH_W2),y")
if(ptrAndIndex.second.isSimple) {
assignExpressionToVariable(ptrAndIndex.first, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
assignExpressionToRegister(ptrAndIndex.second, RegisterOrPair.Y)
if(saveA)
out(" pla")
out(" sta (P8ZP_SCRATCH_W2),y")
} else {
pushCpuStack(DataType.UBYTE, ptrAndIndex.second)
assignExpressionToVariable(ptrAndIndex.first, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
restoreRegisterStack(CpuRegister.Y, true)
if(saveA)
out(" pla")
out(" sta (P8ZP_SCRATCH_W2),y")
}
}
} else {
if(pointervar!=null && isZpVar(pointervar)) {
@ -1102,9 +1091,16 @@ $repeatLabel lda $counterVar
out(" lda (${asmSymbolName(pointervar)}),y")
} else {
// copy the pointer var to zp first
assignExpressionToVariable(ptrAndIndex.first, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
assignExpressionToRegister(ptrAndIndex.second, RegisterOrPair.Y)
out(" lda (P8ZP_SCRATCH_W2),y")
if(ptrAndIndex.second.isSimple) {
assignExpressionToVariable(ptrAndIndex.first, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
assignExpressionToRegister(ptrAndIndex.second, RegisterOrPair.Y)
out(" lda (P8ZP_SCRATCH_W2),y")
} else {
pushCpuStack(DataType.UBYTE, ptrAndIndex.second)
assignExpressionToVariable(ptrAndIndex.first, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
restoreRegisterStack(CpuRegister.Y, false)
out(" lda (P8ZP_SCRATCH_W2),y")
}
}
}
return true
@ -1598,8 +1594,14 @@ $repeatLabel lda $counterVar
if(byteJumpForSimpleRightOperand(left, right, ::code))
return
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
assignExpressionToRegister(left, RegisterOrPair.A)
if(left.isSimple) {
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
assignExpressionToRegister(left, RegisterOrPair.A)
} else {
pushCpuStack(DataType.UBYTE, left)
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
out(" pla")
}
return code("P8ZP_SCRATCH_B1")
}
@ -1633,8 +1635,14 @@ $repeatLabel lda $counterVar
if(byteJumpForSimpleRightOperand(left, right, ::code))
return
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
assignExpressionToRegister(left, RegisterOrPair.A)
if(left.isSimple) {
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
assignExpressionToRegister(left, RegisterOrPair.A)
} else {
pushCpuStack(DataType.UBYTE, left)
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
out(" pla")
}
return code("P8ZP_SCRATCH_B1")
}
@ -1670,8 +1678,15 @@ $repeatLabel lda $counterVar
if(wordJumpForSimpleRightOperands(left, right, ::code))
return
assignExpressionToVariable(right, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
assignExpressionToRegister(left, RegisterOrPair.AY)
if(left.isSimple) {
assignExpressionToVariable(right, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
assignExpressionToRegister(left, RegisterOrPair.AY)
} else {
pushCpuStack(DataType.UWORD, left)
assignExpressionToVariable(right, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
restoreRegisterStack(CpuRegister.Y, false)
restoreRegisterStack(CpuRegister.A, false)
}
return out(" jsr prog8_lib.reg_less_uw | beq $jumpIfFalseLabel")
}
@ -1709,8 +1724,15 @@ $repeatLabel lda $counterVar
if(wordJumpForSimpleRightOperands(left, right, ::code))
return
assignExpressionToVariable(right, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
assignExpressionToRegister(left, RegisterOrPair.AY)
if(left.isSimple) {
assignExpressionToVariable(right, "P8ZP_SCRATCH_W2", DataType.WORD, null)
assignExpressionToRegister(left, RegisterOrPair.AY)
} else {
pushCpuStack(DataType.WORD, left)
assignExpressionToVariable(right, "P8ZP_SCRATCH_W2", DataType.WORD, null)
restoreRegisterStack(CpuRegister.Y, false)
restoreRegisterStack(CpuRegister.A, false)
}
return out(" jsr prog8_lib.reg_less_w | beq $jumpIfFalseLabel")
}
@ -1749,8 +1771,14 @@ $repeatLabel lda $counterVar
if(byteJumpForSimpleRightOperand(left, right, ::code))
return
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
assignExpressionToRegister(left, RegisterOrPair.A)
if(left.isSimple) {
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
assignExpressionToRegister(left, RegisterOrPair.A)
} else {
pushCpuStack(DataType.UBYTE, left)
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
out(" pla")
}
return code("P8ZP_SCRATCH_B1")
}
@ -1786,8 +1814,14 @@ $repeatLabel lda $counterVar
if(byteJumpForSimpleRightOperand(left, right, ::code))
return
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
assignExpressionToRegister(left, RegisterOrPair.A)
if(left.isSimple) {
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.BYTE, null)
assignExpressionToRegister(left, RegisterOrPair.A)
} else {
pushCpuStack(DataType.BYTE, left)
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.BYTE, null)
out(" pla")
}
return code("P8ZP_SCRATCH_B1")
}
@ -1829,8 +1863,15 @@ $repeatLabel lda $counterVar
if(wordJumpForSimpleRightOperands(left, right, ::code))
return
assignExpressionToVariable(right, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
assignExpressionToRegister(left, RegisterOrPair.AY)
if(left.isSimple) {
assignExpressionToVariable(right, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
assignExpressionToRegister(left, RegisterOrPair.AY)
} else {
pushCpuStack(DataType.UWORD, left)
assignExpressionToVariable(right, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
restoreRegisterStack(CpuRegister.Y, false)
restoreRegisterStack(CpuRegister.A, false)
}
return code("P8ZP_SCRATCH_W2+1", "P8ZP_SCRATCH_W2")
}
@ -1873,8 +1914,15 @@ $repeatLabel lda $counterVar
if(wordJumpForSimpleLeftOperand(left, right, ::code))
return
assignExpressionToVariable(left, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
assignExpressionToRegister(right, RegisterOrPair.AY)
if(right.isSimple) {
assignExpressionToVariable(left, "P8ZP_SCRATCH_W2", DataType.WORD, null)
assignExpressionToRegister(right, RegisterOrPair.AY)
} else {
pushCpuStack(DataType.WORD, right)
assignExpressionToVariable(left, "P8ZP_SCRATCH_W2", DataType.WORD, null)
restoreRegisterStack(CpuRegister.Y, false)
restoreRegisterStack(CpuRegister.A, false)
}
return out(" jsr prog8_lib.reg_less_w | beq $jumpIfFalseLabel")
}
@ -1914,8 +1962,14 @@ $repeatLabel lda $counterVar
if(byteJumpForSimpleRightOperand(left, right, ::code))
return
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
assignExpressionToRegister(left, RegisterOrPair.A)
if(left.isSimple) {
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
assignExpressionToRegister(left, RegisterOrPair.A)
} else {
pushCpuStack(DataType.UBYTE, left)
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
out(" pla")
}
return code("P8ZP_SCRATCH_B1")
}
@ -1951,8 +2005,14 @@ $repeatLabel lda $counterVar
if(byteJumpForSimpleRightOperand(left, right, ::code))
return
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
assignExpressionToRegister(left, RegisterOrPair.A)
if(left.isSimple) {
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.BYTE, null)
assignExpressionToRegister(left, RegisterOrPair.A)
} else {
pushCpuStack(DataType.BYTE, left)
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.BYTE, null)
out(" pla")
}
return code("P8ZP_SCRATCH_B1")
}
@ -1996,8 +2056,15 @@ $repeatLabel lda $counterVar
if(wordJumpForSimpleRightOperands(left, right, ::code))
return
assignExpressionToVariable(right, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
assignExpressionToRegister(left, RegisterOrPair.AY)
if(left.isSimple) {
assignExpressionToVariable(right, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
assignExpressionToRegister(left, RegisterOrPair.AY)
} else {
pushCpuStack(DataType.UWORD, left)
assignExpressionToVariable(right, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
restoreRegisterStack(CpuRegister.Y, false)
restoreRegisterStack(CpuRegister.A, false)
}
return out(" jsr prog8_lib.reg_lesseq_uw | beq $jumpIfFalseLabel")
}
@ -2044,8 +2111,15 @@ $repeatLabel lda $counterVar
return code(asmVariableName(left))
}
assignExpressionToVariable(left, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
assignExpressionToRegister(right, RegisterOrPair.AY)
if(right.isSimple) {
assignExpressionToVariable(left, "P8ZP_SCRATCH_W2", DataType.WORD, null)
assignExpressionToRegister(right, RegisterOrPair.AY)
} else {
pushCpuStack(DataType.WORD, right)
assignExpressionToVariable(left, "P8ZP_SCRATCH_W2", DataType.WORD, null)
restoreRegisterStack(CpuRegister.Y, false)
restoreRegisterStack(CpuRegister.A, false)
}
return out(" jsr prog8_lib.reg_lesseq_w | beq $jumpIfFalseLabel")
}
@ -2081,8 +2155,14 @@ $repeatLabel lda $counterVar
if(byteJumpForSimpleRightOperand(left, right, ::code))
return
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
assignExpressionToRegister(left, RegisterOrPair.A)
if(left.isSimple) {
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
assignExpressionToRegister(left, RegisterOrPair.A)
} else {
pushCpuStack(DataType.UBYTE, left)
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
out(" pla")
}
return code("P8ZP_SCRATCH_B1")
}
@ -2115,8 +2195,14 @@ $repeatLabel lda $counterVar
if(byteJumpForSimpleRightOperand(left, right, ::code))
return
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
assignExpressionToRegister(left, RegisterOrPair.A)
if(left.isSimple) {
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.BYTE, null)
assignExpressionToRegister(left, RegisterOrPair.A)
} else {
pushCpuStack(DataType.BYTE, left)
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.BYTE, null)
out(" pla")
}
return code("P8ZP_SCRATCH_B1")
}
@ -2151,8 +2237,15 @@ $repeatLabel lda $counterVar
if(wordJumpForSimpleRightOperands(left, right, ::code))
return
assignExpressionToVariable(left, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
assignExpressionToRegister(right, RegisterOrPair.AY)
if(right.isSimple) {
assignExpressionToVariable(left, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
assignExpressionToRegister(right, RegisterOrPair.AY)
} else {
pushCpuStack(DataType.UWORD, right)
assignExpressionToVariable(left, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
restoreRegisterStack(CpuRegister.Y, false)
restoreRegisterStack(CpuRegister.A, false)
}
return out(" jsr prog8_lib.reg_lesseq_uw | beq $jumpIfFalseLabel")
}
@ -2190,8 +2283,15 @@ $repeatLabel lda $counterVar
if(wordJumpForSimpleRightOperands(left, right, ::code))
return
assignExpressionToVariable(right, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
assignExpressionToRegister(left, RegisterOrPair.AY)
if(left.isSimple) {
assignExpressionToVariable(right, "P8ZP_SCRATCH_W2", DataType.WORD, null)
assignExpressionToRegister(left, RegisterOrPair.AY)
} else {
pushCpuStack(DataType.WORD, left)
assignExpressionToVariable(right, "P8ZP_SCRATCH_W2", DataType.WORD, null)
restoreRegisterStack(CpuRegister.Y, false)
restoreRegisterStack(CpuRegister.A, false)
}
return out(" jsr prog8_lib.reg_lesseq_w | beq $jumpIfFalseLabel")
}
@ -2226,8 +2326,17 @@ $repeatLabel lda $counterVar
if(byteJumpForSimpleRightOperand(left, right, ::code))
return
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
assignExpressionToRegister(left, RegisterOrPair.A)
if(left.isSimple) {
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
assignExpressionToRegister(left, RegisterOrPair.A)
} else if(right.isSimple) {
assignExpressionToVariable(left, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
assignExpressionToRegister(right, RegisterOrPair.A)
} else {
pushCpuStack(DataType.UBYTE, left)
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
restoreRegisterStack(CpuRegister.A, false)
}
out(" cmp P8ZP_SCRATCH_B1 | bne $jumpIfFalseLabel")
}
@ -2263,8 +2372,17 @@ $repeatLabel lda $counterVar
if(byteJumpForSimpleRightOperand(left, right, ::code))
return
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
assignExpressionToRegister(left, RegisterOrPair.A)
if(left.isSimple) {
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
assignExpressionToRegister(left, RegisterOrPair.A)
} else if(right.isSimple) {
assignExpressionToVariable(left, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
assignExpressionToRegister(right, RegisterOrPair.A)
} else {
pushCpuStack(DataType.UBYTE, left)
assignExpressionToVariable(right, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
restoreRegisterStack(CpuRegister.A, false)
}
return code("P8ZP_SCRATCH_B1")
}
@ -2330,8 +2448,18 @@ $repeatLabel lda $counterVar
""")
}
else -> {
assignExpressionToVariable(right, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
assignExpressionToRegister(left, RegisterOrPair.AY)
if(left.isSimple) {
assignExpressionToVariable(right, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
assignExpressionToRegister(left, RegisterOrPair.AY)
} else if(right.isSimple) {
assignExpressionToVariable(left, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
assignExpressionToRegister(right, RegisterOrPair.AY)
} else {
pushCpuStack(DataType.UWORD, left)
assignExpressionToVariable(right, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
restoreRegisterStack(CpuRegister.Y, false)
restoreRegisterStack(CpuRegister.A, false)
}
out("""
cmp P8ZP_SCRATCH_W2
bne $jumpIfFalseLabel
@ -2406,8 +2534,18 @@ $repeatLabel lda $counterVar
+""")
}
else -> {
assignExpressionToVariable(right, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
assignExpressionToRegister(left, RegisterOrPair.AY)
if(left.isSimple) {
assignExpressionToVariable(right, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
assignExpressionToRegister(left, RegisterOrPair.AY)
} else if (right.isSimple) {
assignExpressionToVariable(left, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
assignExpressionToRegister(right, RegisterOrPair.AY)
} else {
pushCpuStack(DataType.UWORD, left)
assignExpressionToVariable(right, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
restoreRegisterStack(CpuRegister.Y, false)
restoreRegisterStack(CpuRegister.A, false)
}
out("""
cmp P8ZP_SCRATCH_W2
bne +
@ -2802,7 +2940,7 @@ $repeatLabel lda $counterVar
val parameter = target.subroutineParameter
if(parameter!=null) {
val sub = parameter.definingSubroutine!!
require(sub.isAsmSubroutine) { "push/pop arg passing only supported on asmsubs" }
require(sub.isAsmSubroutine) { "push/pop arg passing only supported on asmsubs ${sub.position}" }
val shouldKeepA = sub.asmParameterRegisters.any { it.registerOrPair==RegisterOrPair.AX || it.registerOrPair==RegisterOrPair.AY }
val reg = sub.asmParameterRegisters[sub.parameters.indexOf(parameter)]
if(reg.statusflag!=null) {
@ -2874,7 +3012,7 @@ $repeatLabel lda $counterVar
}
}
} else {
val tgt = AsmAssignTarget(TargetStorageKind.VARIABLE, program, this, target.datatype, scope, variableAsmName = asmVariableName(target.scopedName))
val tgt = AsmAssignTarget(TargetStorageKind.VARIABLE, this, target.datatype, scope, variableAsmName = asmVariableName(target.scopedName))
if (dt in ByteDatatypes) {
out(" pla")
assignRegister(RegisterOrPair.A, tgt)
@ -2888,17 +3026,27 @@ $repeatLabel lda $counterVar
}
}
internal fun popCpuStack(dt: DataType, targetAsmVarName: String) {
when(dt) {
in ByteDatatypes -> out(" pla | sta $targetAsmVarName")
in WordDatatypes -> out(" pla | sta $targetAsmVarName+1 | pla | sta $targetAsmVarName")
else -> throw AssemblyError("can't pop $dt")
}
}
internal fun pushCpuStack(dt: DataType, value: Expression) {
val signed = value.inferType(program).oneOf(DataType.BYTE, DataType.WORD)
if(dt in ByteDatatypes) {
assignExpressionToRegister(value, RegisterOrPair.A, signed)
out(" pha")
} else {
} else if(dt in WordDatatypes) {
assignExpressionToRegister(value, RegisterOrPair.AY, signed)
if (isTargetCpu(CpuType.CPU65c02))
out(" pha | phy")
else
out(" pha | tya | pha")
} else {
throw AssemblyError("can't push $dt")
}
}

80
codeGenCpu6502/src/prog8/codegen/cpu6502/AsmOptimizer.kt
View File

@ -44,7 +44,7 @@ internal fun optimizeAssembly(lines: MutableList<String>, machine: IMachineDefin
numberOfOptimizations++
}
mods= optimizeJsrRts(linesByFour)
mods= optimizeJsrRtsAndOtherCombinations(linesByFour)
if(mods.isNotEmpty()) {
apply(mods, lines)
linesByFour = getLinesBy(lines, 4)
@ -59,7 +59,14 @@ internal fun optimizeAssembly(lines: MutableList<String>, machine: IMachineDefin
numberOfOptimizations++
}
// TODO more assembly optimizations
mods = optimizeSamePointerIndexing(linesByFourteen, machine, program)
if(mods.isNotEmpty()) {
apply(mods, lines)
linesByFourteen = getLinesBy(lines, 14)
numberOfOptimizations++
}
// TODO more assembly peephole optimizations
return numberOfOptimizations
}
@ -320,6 +327,48 @@ private fun optimizeSameAssignments(linesByFourteen: List<List<IndexedValue<Stri
return mods
}
private fun optimizeSamePointerIndexing(linesByFourteen: List<List<IndexedValue<String>>>, machine: IMachineDefinition, program: Program): List<Modification> {
// Optimize same pointer indexing where for instance we load and store to the same ptr index in Y
// if Y isn't modified in between we can omit the second LDY:
// ldy #0
// lda (ptr),y
// ora #3 ; <-- instruction(s) that don't modify Y
// ldy #0 ; <-- can be removed
// sta (ptr),y
val mods = mutableListOf<Modification>()
for (lines in linesByFourteen) {
val first = lines[0].value.trimStart()
val second = lines[1].value.trimStart()
val third = lines[2].value.trimStart()
val fourth = lines[3].value.trimStart()
val fifth = lines[4].value.trimStart()
val sixth = lines[5].value.trimStart()
if(first.startsWith("ldy") && second.startsWith("lda") && fourth.startsWith("ldy") && fifth.startsWith("sta")) {
val firstvalue = first.substring(4)
val secondvalue = second.substring(4)
val fourthvalue = fourth.substring(4)
val fifthvalue = fifth.substring(4)
if("y" !in third && firstvalue==fourthvalue && secondvalue==fifthvalue && secondvalue.endsWith(",y") && fifthvalue.endsWith(",y")) {
mods.add(Modification(lines[3].index, true, null))
}
}
if(first.startsWith("ldy") && second.startsWith("lda") && fifth.startsWith("ldy") && sixth.startsWith("sta")) {
val firstvalue = first.substring(4)
val secondvalue = second.substring(4)
val fifthvalue = fifth.substring(4)
val sixthvalue = sixth.substring(4)
if("y" !in third && "y" !in fourth && firstvalue==fifthvalue && secondvalue==sixthvalue && secondvalue.endsWith(",y") && sixthvalue.endsWith(",y")) {
mods.add(Modification(lines[4].index, true, null))
}
}
}
return mods
}
private fun optimizeStoreLoadSame(linesByFour: List<List<IndexedValue<String>>>, machine: IMachineDefinition, program: Program): List<Modification> {
// sta X + lda X, sty X + ldy X, stx X + ldx X -> the second instruction can OFTEN be eliminated
val mods = mutableListOf<Modification>()
@ -437,8 +486,11 @@ private fun optimizeIncDec(linesByFour: List<List<IndexedValue<String>>>): List<
return mods
}
private fun optimizeJsrRts(linesByFour: List<List<IndexedValue<String>>>): List<Modification> {
private fun optimizeJsrRtsAndOtherCombinations(linesByFour: List<List<IndexedValue<String>>>): List<Modification> {
// jsr Sub + rts -> jmp Sub
// rts + jmp -> remove jmp
// rts + bxx -> remove bxx
val mods = mutableListOf<Modification>()
for (lines in linesByFour) {
val first = lines[0].value
@ -447,6 +499,28 @@ private fun optimizeJsrRts(linesByFour: List<List<IndexedValue<String>>>): List<
mods += Modification(lines[0].index, false, lines[0].value.replace("jsr", "jmp"))
mods += Modification(lines[1].index, true, null)
}
else if (" rts" in first || "\trts" in first) {
if (" jmp" in second || "\tjmp" in second)
mods += Modification(lines[1].index, true, null)
else if (" bra" in second || "\tbra" in second)
mods += Modification(lines[1].index, true, null)
else if (" bcc" in second || "\tbcc" in second)
mods += Modification(lines[1].index, true, null)
else if (" bcs" in second || "\tbcs" in second)
mods += Modification(lines[1].index, true, null)
else if (" beq" in second || "\tbeq" in second)
mods += Modification(lines[1].index, true, null)
else if (" bne" in second || "\tbne" in second)
mods += Modification(lines[1].index, true, null)
else if (" bmi" in second || "\tbmi" in second)
mods += Modification(lines[1].index, true, null)
else if (" bpl" in second || "\tbpl" in second)
mods += Modification(lines[1].index, true, null)
else if (" bvs" in second || "\tbvs" in second)
mods += Modification(lines[1].index, true, null)
else if (" bvc" in second || "\tbvc" in second)
mods += Modification(lines[1].index, true, null)
}
}
return mods
}

108
codeGenCpu6502/src/prog8/codegen/cpu6502/BuiltinFunctionsAsmGen.kt
View File

@ -15,8 +15,7 @@ import prog8.compiler.FSignature
internal class BuiltinFunctionsAsmGen(private val program: Program,
private val asmgen: AsmGen,
private val assignAsmGen: AssignmentAsmGen,
private val allocations: VariableAllocator) {
private val assignAsmGen: AssignmentAsmGen) {
internal fun translateFunctioncallExpression(fcall: BuiltinFunctionCall, resultToStack: Boolean, resultRegister: RegisterOrPair?) {
val func = BuiltinFunctions.getValue(fcall.target.nameInSource.single())
@ -44,7 +43,6 @@ internal class BuiltinFunctionsAsmGen(private val program: Program,
"abs" -> funcAbs(fcall, func, resultToStack, resultRegister, sscope)
"any", "all" -> funcAnyAll(fcall, func, resultToStack, resultRegister, sscope)
"sgn" -> funcSgn(fcall, func, resultToStack, resultRegister, sscope)
"rnd", "rndw" -> funcRnd(func, resultToStack, resultRegister, sscope)
"sqrt16" -> funcSqrt16(fcall, func, resultToStack, resultRegister, sscope)
"rol" -> funcRol(fcall)
"rol2" -> funcRol2(fcall)
@ -256,15 +254,27 @@ internal class BuiltinFunctionsAsmGen(private val program: Program,
asmgen.assignExpressionToRegister(arg1, RegisterOrPair.A)
asmgen.out(" cmp ${arg2.addressExpression.constValue(program)!!.number.toHex()}")
} else {
asmgen.assignExpressionToVariable(arg2, "P8ZP_SCRATCH_B1", DataType.UBYTE, (fcall as Node).definingSubroutine)
asmgen.assignExpressionToRegister(arg1, RegisterOrPair.A)
asmgen.out(" cmp P8ZP_SCRATCH_B1")
if(arg1.isSimple) {
asmgen.assignExpressionToVariable(arg2, "P8ZP_SCRATCH_B1", DataType.UBYTE, (fcall as Node).definingSubroutine)
asmgen.assignExpressionToRegister(arg1, RegisterOrPair.A)
asmgen.out(" cmp P8ZP_SCRATCH_B1")
} else {
asmgen.pushCpuStack(DataType.UBYTE, arg1)
asmgen.assignExpressionToVariable(arg2, "P8ZP_SCRATCH_B1", DataType.UBYTE, (fcall as Node).definingSubroutine)
asmgen.out(" pla | cmp P8ZP_SCRATCH_B1")
}
}
}
else -> {
asmgen.assignExpressionToVariable(arg2, "P8ZP_SCRATCH_B1", DataType.UBYTE, (fcall as Node).definingSubroutine)
asmgen.assignExpressionToRegister(arg1, RegisterOrPair.A)
asmgen.out(" cmp P8ZP_SCRATCH_B1")
if(arg1.isSimple) {
asmgen.assignExpressionToVariable(arg2, "P8ZP_SCRATCH_B1", DataType.UBYTE, (fcall as Node).definingSubroutine)
asmgen.assignExpressionToRegister(arg1, RegisterOrPair.A)
asmgen.out(" cmp P8ZP_SCRATCH_B1")
} else {
asmgen.pushCpuStack(DataType.UBYTE, arg1)
asmgen.assignExpressionToVariable(arg2, "P8ZP_SCRATCH_B1", DataType.UBYTE, (fcall as Node).definingSubroutine)
asmgen.out(" pla | cmp P8ZP_SCRATCH_B1")
}
}
}
} else
@ -290,13 +300,25 @@ internal class BuiltinFunctionsAsmGen(private val program: Program,
+""")
}
else -> {
asmgen.assignExpressionToVariable(arg2, "P8ZP_SCRATCH_W1", DataType.UWORD, (fcall as Node).definingSubroutine)
asmgen.assignExpressionToRegister(arg1, RegisterOrPair.AY)
asmgen.out("""
cpy P8ZP_SCRATCH_W1+1
bne +
cmp P8ZP_SCRATCH_W1
+""")
if(arg1.isSimple) {
asmgen.assignExpressionToVariable(arg2, "P8ZP_SCRATCH_W1", DataType.UWORD, (fcall as Node).definingSubroutine)
asmgen.assignExpressionToRegister(arg1, RegisterOrPair.AY)
asmgen.out("""
cpy P8ZP_SCRATCH_W1+1
bne +
cmp P8ZP_SCRATCH_W1
+""")
} else {
asmgen.pushCpuStack(DataType.UWORD, arg1)
asmgen.assignExpressionToVariable(arg2, "P8ZP_SCRATCH_W1", DataType.UWORD, (fcall as Node).definingSubroutine)
asmgen.restoreRegisterStack(CpuRegister.Y, false)
asmgen.restoreRegisterStack(CpuRegister.A, false)
asmgen.out("""
cpy P8ZP_SCRATCH_W1+1
bne +
cmp P8ZP_SCRATCH_W1
+""")
}
}
}
} else
@ -308,25 +330,17 @@ internal class BuiltinFunctionsAsmGen(private val program: Program,
if(discardResult || fcall !is BuiltinFunctionCall)
throw AssemblyError("should not discard result of memory allocation at $fcall")
val name = (fcall.args[0] as StringLiteral).value
require(name.all { it.isLetterOrDigit() || it=='_' }) {"memory name should be a valid symbol name"}
val size = (fcall.args[1] as NumericLiteral).number.toUInt()
val align = (fcall.args[2] as NumericLiteral).number.toUInt()
val existing = allocations.getMemorySlab(name)
if(existing!=null && (existing.first!=size || existing.second!=align))
throw AssemblyError("memory slab '$name' already exists with a different size or alignment at ${fcall.position}")
val slabname = IdentifierReference(listOf("prog8_slabs", name), fcall.position)
require(name.all { it.isLetterOrDigit() || it=='_' }) {"memory name should be a valid symbol name ${fcall.position}"}
val slabname = IdentifierReference(listOf("prog8_slabs", "prog8_memoryslab_$name"), fcall.position)
slabname.linkParents(fcall)
val src = AsmAssignSource(SourceStorageKind.EXPRESSION, program, asmgen, DataType.UWORD, expression = AddressOf(slabname, fcall.position))
val target =
if(resultToStack)
AsmAssignTarget(TargetStorageKind.STACK, program, asmgen, DataType.UWORD, null)
AsmAssignTarget(TargetStorageKind.STACK, asmgen, DataType.UWORD, null)
else
AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.AY, false, null, program, asmgen)
AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.AY, false, null, asmgen)
val assign = AsmAssignment(src, target, false, program.memsizer, fcall.position)
asmgen.translateNormalAssignment(assign)
allocations.allocateMemorySlab(name, size, align)
}
private fun funcSqrt16(fcall: IFunctionCall, func: FSignature, resultToStack: Boolean, resultRegister: RegisterOrPair?, scope: Subroutine?) {
@ -335,7 +349,7 @@ internal class BuiltinFunctionsAsmGen(private val program: Program,
asmgen.out(" jsr prog8_lib.func_sqrt16_stack")
else {
asmgen.out(" jsr prog8_lib.func_sqrt16_into_A")
assignAsmGen.assignRegisterByte(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.A, false, scope, program, asmgen), CpuRegister.A)
assignAsmGen.assignRegisterByte(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.A, false, scope, asmgen), CpuRegister.A)
}
}
@ -648,7 +662,7 @@ internal class BuiltinFunctionsAsmGen(private val program: Program,
DataType.FLOAT -> asmgen.out(" jsr floats.func_sign_f_into_A")
else -> throw AssemblyError("weird type $dt")
}
assignAsmGen.assignRegisterByte(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.A, false, scope, program, asmgen), CpuRegister.A)
assignAsmGen.assignRegisterByte(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.A, false, scope, asmgen), CpuRegister.A)
}
}
@ -669,7 +683,7 @@ internal class BuiltinFunctionsAsmGen(private val program: Program,
DataType.ARRAY_F -> asmgen.out(" jsr floats.func_${function.name}_f_into_A | ldy #0")
else -> throw AssemblyError("weird type $dt")
}
assignAsmGen.assignRegisterByte(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.A, false, scope, program, asmgen), CpuRegister.A)
assignAsmGen.assignRegisterByte(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.A, false, scope, asmgen), CpuRegister.A)
}
}
@ -692,29 +706,7 @@ internal class BuiltinFunctionsAsmGen(private val program: Program,
DataType.WORD -> asmgen.out(" jsr prog8_lib.abs_w_into_AY")
else -> throw AssemblyError("weird type")
}
assignAsmGen.assignRegisterpairWord(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.AY, false, scope, program, asmgen), RegisterOrPair.AY)
}
}
private fun funcRnd(func: FSignature, resultToStack: Boolean, resultRegister: RegisterOrPair?, scope: Subroutine?) {
when(func.name) {
"rnd" -> {
if(resultToStack)
asmgen.out(" jsr prog8_lib.func_rnd_stack")
else {
asmgen.out(" jsr math.randbyte")
assignAsmGen.assignRegisterByte(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.A, false, scope, program, asmgen), CpuRegister.A)
}
}
"rndw" -> {
if(resultToStack)
asmgen.out(" jsr prog8_lib.func_rndw_stack")
else {
asmgen.out(" jsr math.randword")
assignAsmGen.assignRegisterpairWord(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.AY, false, scope, program, asmgen), RegisterOrPair.AY)
}
}
else -> throw AssemblyError("wrong func")
assignAsmGen.assignRegisterpairWord(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.AY, false, scope, asmgen), RegisterOrPair.AY)
}
}
@ -865,9 +857,9 @@ internal class BuiltinFunctionsAsmGen(private val program: Program,
val mr0 = fcall.args[0] as? DirectMemoryRead
val mr1 = fcall.args[1] as? DirectMemoryRead
if (mr0 != null)
needAsave = mr0.addressExpression !is NumericLiteral && mr0.addressExpression !is IdentifierReference
needAsave = mr0.addressExpression !is NumericLiteral
if (mr1 != null)
needAsave = needAsave or (mr1.addressExpression !is NumericLiteral && mr1.addressExpression !is IdentifierReference)
needAsave = needAsave or (mr1.addressExpression !is NumericLiteral)
}
when(reg) {
RegisterOrPair.AX -> {
@ -1084,7 +1076,7 @@ internal class BuiltinFunctionsAsmGen(private val program: Program,
AsmAssignSource.fromAstSource(value, program, asmgen)
}
}
val tgt = AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, conv.dt, null, variableAsmName = varname)
val tgt = AsmAssignTarget(TargetStorageKind.VARIABLE, asmgen, conv.dt, null, variableAsmName = varname)
val assign = AsmAssignment(src, tgt, false, program.memsizer, value.position)
asmgen.translateNormalAssignment(assign)
}
@ -1100,7 +1092,7 @@ internal class BuiltinFunctionsAsmGen(private val program: Program,
AsmAssignSource.fromAstSource(value, program, asmgen)
}
}
val tgt = AsmAssignTarget.fromRegisters(conv.reg!!, false, null, program, asmgen)
val tgt = AsmAssignTarget.fromRegisters(conv.reg!!, false, null, asmgen)
val assign = AsmAssignment(src, tgt, false, program.memsizer, value.position)
asmgen.translateNormalAssignment(assign)
}

37
codeGenCpu6502/src/prog8/codegen/cpu6502/ExpressionsAsmGen.kt
View File

@ -519,12 +519,37 @@ internal class ExpressionsAsmGen(private val program: Program,
val rightVal = expr.right.constValue(program)?.number?.toInt()
if(rightVal!=null && rightVal==2) {
translateExpressionInternal(expr.left)
when(leftDt) {
DataType.UBYTE -> asmgen.out(" lsr P8ESTACK_LO+1,x")
DataType.BYTE -> asmgen.out(" lda P8ESTACK_LO+1,x | asl a | ror P8ESTACK_LO+1,x")
DataType.UWORD -> asmgen.out(" lsr P8ESTACK_HI+1,x | ror P8ESTACK_LO+1,x")
DataType.WORD -> asmgen.out(" lda P8ESTACK_HI+1,x | asl a | ror P8ESTACK_HI+1,x | ror P8ESTACK_LO+1,x")
else -> throw AssemblyError("wrong dt")
when (leftDt) {
DataType.UBYTE -> {
asmgen.out(" lsr P8ESTACK_LO+1,x")
}
DataType.UWORD -> {
asmgen.out(" lsr P8ESTACK_HI+1,x | ror P8ESTACK_LO+1,x")
}
DataType.BYTE -> {
// signed divide using shift needs adjusting of negative value to get correct rounding towards zero
asmgen.out("""
lda P8ESTACK_LO+1,x
bpl +
inc P8ESTACK_LO+1,x
lda P8ESTACK_LO+1,x
+ asl a
ror P8ESTACK_LO+1,x""")
}
DataType.WORD -> {
// signed divide using shift needs adjusting of negative value to get correct rounding towards zero
asmgen.out("""
lda P8ESTACK_HI+1,x
bpl ++
inc P8ESTACK_LO+1,x
bne +
inc P8ESTACK_HI+1,x
+ lda P8ESTACK_HI+1,x
+ asl a
ror P8ESTACK_HI+1,x
ror P8ESTACK_LO+1,x""")
}
else -> throw AssemblyError("weird dt")
}
return
}

40
codeGenCpu6502/src/prog8/codegen/cpu6502/FunctionCallAsmGen.kt
View File

@ -7,7 +7,10 @@ import prog8.ast.expressions.AddressOf
import prog8.ast.expressions.Expression
import prog8.ast.expressions.IdentifierReference
import prog8.ast.expressions.NumericLiteral
import prog8.ast.statements.*
import prog8.ast.statements.FunctionCallStatement
import prog8.ast.statements.InlineAssembly
import prog8.ast.statements.Subroutine
import prog8.ast.statements.SubroutineParameter
import prog8.code.core.*
import prog8.codegen.cpu6502.assignment.AsmAssignSource
import prog8.codegen.cpu6502.assignment.AsmAssignTarget
@ -35,17 +38,6 @@ internal class FunctionCallAsmGen(private val program: Program, private val asmg
}
}
internal fun saveXbeforeCall(gosub: GoSub) {
val sub = gosub.identifier.targetSubroutine(program)
if(sub?.shouldSaveX()==true) {
val regSaveOnStack = sub.asmAddress==null // rom-routines don't require registers to be saved on stack, normal subroutines do because they can contain nested calls
if(regSaveOnStack)
asmgen.saveRegisterStack(CpuRegister.X, sub.shouldKeepA().saveOnEntry)
else
asmgen.saveRegisterLocal(CpuRegister.X, gosub.definingSubroutine!!)
}
}
internal fun restoreXafterCall(stmt: IFunctionCall) {
val sub = stmt.target.targetSubroutine(program) ?: throw AssemblyError("undefined subroutine ${stmt.target}")
if(sub.shouldSaveX()) {
@ -57,22 +49,11 @@ internal class FunctionCallAsmGen(private val program: Program, private val asmg
}
}
internal fun restoreXafterCall(gosub: GoSub) {
val sub = gosub.identifier.targetSubroutine(program)
if(sub?.shouldSaveX()==true) {
val regSaveOnStack = sub.asmAddress==null // rom-routines don't require registers to be saved on stack, normal subroutines do because they can contain nested calls
if(regSaveOnStack)
asmgen.restoreRegisterStack(CpuRegister.X, sub.shouldKeepA().saveOnReturn)
else
asmgen.restoreRegisterLocal(CpuRegister.X)
}
}
internal fun optimizeIntArgsViaRegisters(sub: Subroutine) =
(sub.parameters.size==1 && sub.parameters[0].type in IntegerDatatypes)
|| (sub.parameters.size==2 && sub.parameters[0].type in ByteDatatypes && sub.parameters[1].type in ByteDatatypes)
internal fun translateFunctionCall(call: IFunctionCall, isExpression: Boolean) {
internal fun translateFunctionCall(call: IFunctionCall, isExpression: Boolean) { // TODO remove isExpression unused parameter
// Output only the code to set up the parameters and perform the actual call
// NOTE: does NOT output the code to deal with the result values!
// NOTE: does NOT output code to save/restore the X register for this call! Every caller should deal with this in their own way!!
@ -81,11 +62,6 @@ internal class FunctionCallAsmGen(private val program: Program, private val asmg
val sub = call.target.targetSubroutine(program) ?: throw AssemblyError("undefined subroutine ${call.target}")
val subAsmName = asmgen.asmSymbolName(call.target)
if(!isExpression && !sub.isAsmSubroutine) {
if(!optimizeIntArgsViaRegisters(sub))
throw AssemblyError("functioncall statements to non-asmsub should have been replaced by GoSub $call")
}
if(sub.isAsmSubroutine) {
argumentsViaRegisters(sub, call)
if (sub.inline && asmgen.options.optimize) {
@ -148,7 +124,7 @@ internal class FunctionCallAsmGen(private val program: Program, private val asmg
// this is called when one or more of the arguments are 'complex' and
// cannot be assigned to a register easily or risk clobbering other registers.
require(callee.isAsmSubroutine)
require(callee.isAsmSubroutine) { "register args only for asm subroutine ${callee.position}" }
if(callee.parameters.isEmpty())
return
@ -234,10 +210,10 @@ internal class FunctionCallAsmGen(private val program: Program, private val asmg
} else {
val target: AsmAssignTarget =
if(parameter.value.type in ByteDatatypes && (register==RegisterOrPair.AX || register == RegisterOrPair.AY || register==RegisterOrPair.XY || register in Cx16VirtualRegisters))
AsmAssignTarget(TargetStorageKind.REGISTER, program, asmgen, parameter.value.type, sub, register = register)
AsmAssignTarget(TargetStorageKind.REGISTER, asmgen, parameter.value.type, sub, register = register)
else {
val signed = parameter.value.type == DataType.BYTE || parameter.value.type == DataType.WORD
AsmAssignTarget.fromRegisters(register, signed, sub, program, asmgen)
AsmAssignTarget.fromRegisters(register, signed, sub, asmgen)
}
val src = if(valueDt in PassByReferenceDatatypes) {
if(value is IdentifierReference) {

93
codeGenCpu6502/src/prog8/codegen/cpu6502/ProgramAndVarsGen.kt
View File

@ -44,6 +44,15 @@ internal class ProgramAndVarsGen(
if(errors.noErrors()) {
program.allBlocks.forEach { block2asm(it) }
// the global list of all floating point constants for the whole program
asmgen.out("; global float constants")
for (flt in allocator.globalFloatConsts) {
val floatFill = compTarget.machine.getFloatAsmBytes(flt.key)
val floatvalue = flt.key
asmgen.out("${flt.value}\t.byte $floatFill ; float $floatvalue")
}
memorySlabs()
footer()
}
@ -161,23 +170,15 @@ internal class ProgramAndVarsGen(
private fun memorySlabs() {
asmgen.out("; memory slabs")
asmgen.out("prog8_slabs\t.block")
for((name, info) in allocator.memorySlabs) {
if(info.second>1u)
asmgen.out("\t.align ${info.second.toHex()}")
asmgen.out("$name\t.fill ${info.first}")
for(slab in symboltable.allMemorySlabs) {
if(slab.align>1u)
asmgen.out("\t.align ${slab.align.toHex()}")
asmgen.out("${slab.name}\t.fill ${slab.size}")
}
asmgen.out("\t.bend")
}
private fun footer() {
// the global list of all floating point constants for the whole program
asmgen.out("; global float constants")
for (flt in allocator.globalFloatConsts) {
val floatFill = compTarget.machine.getFloat(flt.key).makeFloatFillAsm()
val floatvalue = flt.key
asmgen.out("${flt.value}\t.byte $floatFill ; float $floatvalue")
}
// program end
asmgen.out("prog8_program_end\t; end of program label for progend()")
}
@ -201,23 +202,17 @@ internal class ProgramAndVarsGen(
asmsubs2asm(block.statements)
asmgen.out("")
asmgen.out("; subroutines in this block")
// First translate regular statements, and then put the subroutines at the end.
// (regular statements = everything except the initialization assignments;
// these will be part of the prog8_init_vars init routine generated below)
val initializers = blockVariableInitializers.getValue(block)
val statements = block.statements.filterNot { it in initializers }
val (subroutine, stmts) = statements.partition { it is Subroutine }
stmts.forEach { asmgen.translate(it) }
subroutine.forEach { asmgen.translate(it) }
val notInitializers = block.statements.filterNot { it in initializers }
notInitializers.forEach { asmgen.translate(it) }
if(!options.dontReinitGlobals) {
// generate subroutine to initialize block-level (global) variables
if (initializers.isNotEmpty()) {
asmgen.out("prog8_init_vars\t.proc\n")
asmgen.out("prog8_init_vars\t.block\n")
initializers.forEach { assign -> asmgen.translate(assign) }
asmgen.out(" rts\n .pend")
asmgen.out(" rts\n .bend")
}
}
@ -269,17 +264,27 @@ internal class ProgramAndVarsGen(
asmgen.out("")
val asmStartScope: String
val asmEndScope: String
if(sub.definingBlock.options().contains("force_output")) {
asmStartScope = ".block"
asmEndScope = ".bend"
} else {
asmStartScope = ".proc"
asmEndScope = ".pend"
}
if(sub.isAsmSubroutine) {
if(sub.asmAddress!=null)
return // already done at the memvars section
// asmsub with most likely just an inline asm in it
asmgen.out("${sub.name}\t.proc")
asmgen.out("${sub.name}\t$asmStartScope")
sub.statements.forEach { asmgen.translate(it) }
asmgen.out(" .pend\n")
asmgen.out(" $asmEndScope\n")
} else {
// regular subroutine
asmgen.out("${sub.name}\t.proc")
asmgen.out("${sub.name}\t$asmStartScope")
val scope = symboltable.lookupOrElse(sub.scopedName) { throw AssemblyError("lookup") }
require(scope.type==StNodeType.SUBROUTINE)
@ -308,7 +313,7 @@ internal class ProgramAndVarsGen(
asmgen.out("; simple int arg(s) passed via register(s)")
if(sub.parameters.size==1) {
val dt = sub.parameters[0].type
val target = AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, dt, sub, variableAsmName = sub.parameters[0].name)
val target = AsmAssignTarget(TargetStorageKind.VARIABLE, asmgen, dt, sub, variableAsmName = sub.parameters[0].name)
if(dt in ByteDatatypes)
asmgen.assignRegister(RegisterOrPair.A, target)
else
@ -316,8 +321,8 @@ internal class ProgramAndVarsGen(
} else {
require(sub.parameters.size==2)
// 2 simple byte args, first in A, second in Y
val target1 = AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, sub.parameters[0].type, sub, variableAsmName = sub.parameters[0].name)
val target2 = AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, sub.parameters[1].type, sub, variableAsmName = sub.parameters[1].name)
val target1 = AsmAssignTarget(TargetStorageKind.VARIABLE, asmgen, sub.parameters[0].type, sub, variableAsmName = sub.parameters[0].name)
val target2 = AsmAssignTarget(TargetStorageKind.VARIABLE, asmgen, sub.parameters[1].type, sub, variableAsmName = sub.parameters[1].name)
asmgen.assignRegister(RegisterOrPair.A, target1)
asmgen.assignRegister(RegisterOrPair.Y, target2)
}
@ -356,7 +361,7 @@ internal class ProgramAndVarsGen(
.map { it.value as StStaticVariable }
nonZpVariables2asm(variables)
asmgen.out(" .pend\n")
asmgen.out(" $asmEndScope\n")
}
}
@ -424,13 +429,13 @@ internal class ProgramAndVarsGen(
private class ZpStringWithInitial(
val name: List<String>,
val alloc: Zeropage.ZpAllocation,
val alloc: MemoryAllocator.VarAllocation,
val value: Pair<String, Encoding>
)
private class ZpArrayWithInitial(
val name: List<String>,
val alloc: Zeropage.ZpAllocation,
val alloc: MemoryAllocator.VarAllocation,
val value: StArray
)
@ -438,9 +443,9 @@ internal class ProgramAndVarsGen(
val result = mutableListOf<ZpStringWithInitial>()
val vars = allocator.zeropageVars.filter { it.value.dt==DataType.STR }
for (variable in vars) {
val svar = symboltable.lookup(variable.key) as StStaticVariable // TODO faster in flat lookup table
if(svar.initialStringValue!=null)
result.add(ZpStringWithInitial(variable.key, variable.value, svar.initialStringValue!!))
val svar = symboltable.flat.getValue(variable.key) as StStaticVariable
if(svar.onetimeInitializationStringValue!=null)
result.add(ZpStringWithInitial(variable.key, variable.value, svar.onetimeInitializationStringValue!!))
}
return result
}
@ -449,9 +454,9 @@ internal class ProgramAndVarsGen(
val result = mutableListOf<ZpArrayWithInitial>()
val vars = allocator.zeropageVars.filter { it.value.dt in ArrayDatatypes }
for (variable in vars) {
val svar = symboltable.lookup(variable.key) as StStaticVariable // TODO faster in flat lookup table
if(svar.initialArrayValue!=null)
result.add(ZpArrayWithInitial(variable.key, variable.value, svar.initialArrayValue!!))
val svar = symboltable.flat.getValue(variable.key) as StStaticVariable
if(svar.onetimeInitializationArrayValue!=null)
result.add(ZpArrayWithInitial(variable.key, variable.value, svar.onetimeInitializationArrayValue!!))
}
return result
}
@ -470,7 +475,7 @@ internal class ProgramAndVarsGen(
asmgen.out("; non-zeropage variables")
val (stringvars, othervars) = variables.partition { it.dt==DataType.STR }
stringvars.forEach {
outputStringvar(it.name, it.initialStringValue!!.second, it.initialStringValue!!.first)
outputStringvar(it.name, it.onetimeInitializationStringValue!!.second, it.onetimeInitializationStringValue!!.first)
}
othervars.sortedBy { it.type }.forEach {
staticVariable2asm(it)
@ -480,11 +485,11 @@ internal class ProgramAndVarsGen(
private fun staticVariable2asm(variable: StStaticVariable) {
val name = variable.name
val initialValue: Number =
if(variable.initialNumericValue!=null) {
if(variable.onetimeInitializationNumericValue!=null) {
if(variable.dt== DataType.FLOAT)
variable.initialNumericValue!!
variable.onetimeInitializationNumericValue!!
else
variable.initialNumericValue!!.toInt()
variable.onetimeInitializationNumericValue!!.toInt()
} else 0
when (variable.dt) {
@ -496,14 +501,14 @@ internal class ProgramAndVarsGen(
if(initialValue==0) {
asmgen.out("$name\t.byte 0,0,0,0,0 ; float")
} else {
val floatFill = compTarget.machine.getFloat(initialValue).makeFloatFillAsm()
val floatFill = compTarget.machine.getFloatAsmBytes(initialValue)
asmgen.out("$name\t.byte $floatFill ; float $initialValue")
}
}
DataType.STR -> {
throw AssemblyError("all string vars should have been interned into prog")
}
in ArrayDatatypes -> arrayVariable2asm(name, variable.dt, variable.initialArrayValue, variable.length)
in ArrayDatatypes -> arrayVariable2asm(name, variable.dt, variable.onetimeInitializationArrayValue, variable.length)
else -> {
throw AssemblyError("weird dt")
}
@ -555,7 +560,7 @@ internal class ProgramAndVarsGen(
DataType.ARRAY_F -> {
val array = value ?: zeroFilledArray(orNumberOfZeros!!)
val floatFills = array.map {
compTarget.machine.getFloat(it.number!!).makeFloatFillAsm()
compTarget.machine.getFloatAsmBytes(it.number!!)
}
asmgen.out(varname)
for (f in array.zip(floatFills))

10
codeGenCpu6502/src/prog8/codegen/cpu6502/VariableAllocator.kt
View File

@ -15,21 +15,13 @@ internal class VariableAllocator(private val symboltable: SymbolTable,
) {
private val zeropage = options.compTarget.machine.zeropage
private val memorySlabsInternal = mutableMapOf<String, Pair<UInt, UInt>>()
internal val memorySlabs: Map<String, Pair<UInt, UInt>> = memorySlabsInternal
internal val globalFloatConsts = mutableMapOf<Double, String>() // all float values in the entire program (value -> varname)
internal val zeropageVars: Map<List<String>, Zeropage.ZpAllocation> = zeropage.allocatedVariables
internal val zeropageVars: Map<List<String>, MemoryAllocator.VarAllocation> = zeropage.allocatedVariables
init {
allocateZeropageVariables()
}
internal fun getMemorySlab(name: String) = memorySlabsInternal[name]
internal fun allocateMemorySlab(name: String, size: UInt, align: UInt) {
memorySlabsInternal[name] = Pair(size, align)
}
internal fun isZpVar(scopedName: List<String>) = scopedName in zeropage.allocatedVariables
internal fun getFloatAsmConst(number: Double): String {

21
codeGenCpu6502/src/prog8/codegen/cpu6502/assignment/AsmAssignment.kt
View File

@ -29,7 +29,6 @@ internal enum class SourceStorageKind {
}
internal class AsmAssignTarget(val kind: TargetStorageKind,
private val program: Program,
private val asmgen: AsmGen,
val datatype: DataType,
val scope: Subroutine?,
@ -70,28 +69,28 @@ internal class AsmAssignTarget(val kind: TargetStorageKind,
if(reg.statusflag!=null)
throw AssemblyError("can't assign value to processor statusflag directly")
else
return AsmAssignTarget(TargetStorageKind.REGISTER, program, asmgen, dt, assign.definingSubroutine, register=reg.registerOrPair, origAstTarget = this)
return AsmAssignTarget(TargetStorageKind.REGISTER, asmgen, dt, assign.definingSubroutine, register=reg.registerOrPair, origAstTarget = this)
}
}
return AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, dt, assign.definingSubroutine, variableAsmName = asmgen.asmVariableName(identifier!!), origAstTarget = this)
return AsmAssignTarget(TargetStorageKind.VARIABLE, asmgen, dt, assign.definingSubroutine, variableAsmName = asmgen.asmVariableName(identifier!!), origAstTarget = this)
}
arrayindexed != null -> return AsmAssignTarget(TargetStorageKind.ARRAY, program, asmgen, dt, assign.definingSubroutine, array = arrayindexed, origAstTarget = this)
memoryAddress != null -> return AsmAssignTarget(TargetStorageKind.MEMORY, program, asmgen, dt, assign.definingSubroutine, memory = memoryAddress, origAstTarget = this)
arrayindexed != null -> return AsmAssignTarget(TargetStorageKind.ARRAY, asmgen, dt, assign.definingSubroutine, array = arrayindexed, origAstTarget = this)
memoryAddress != null -> return AsmAssignTarget(TargetStorageKind.MEMORY, asmgen, dt, assign.definingSubroutine, memory = memoryAddress, origAstTarget = this)
else -> throw AssemblyError("weird target")
}
}
}
fun fromRegisters(registers: RegisterOrPair, signed: Boolean, scope: Subroutine?, program: Program, asmgen: AsmGen): AsmAssignTarget =
fun fromRegisters(registers: RegisterOrPair, signed: Boolean, scope: Subroutine?, asmgen: AsmGen): AsmAssignTarget =
when(registers) {
RegisterOrPair.A,
RegisterOrPair.X,
RegisterOrPair.Y -> AsmAssignTarget(TargetStorageKind.REGISTER, program, asmgen, if(signed) DataType.BYTE else DataType.UBYTE, scope, register = registers)
RegisterOrPair.Y -> AsmAssignTarget(TargetStorageKind.REGISTER, asmgen, if(signed) DataType.BYTE else DataType.UBYTE, scope, register = registers)
RegisterOrPair.AX,
RegisterOrPair.AY,
RegisterOrPair.XY -> AsmAssignTarget(TargetStorageKind.REGISTER, program, asmgen, if(signed) DataType.WORD else DataType.UWORD, scope, register = registers)
RegisterOrPair.XY -> AsmAssignTarget(TargetStorageKind.REGISTER, asmgen, if(signed) DataType.WORD else DataType.UWORD, scope, register = registers)
RegisterOrPair.FAC1,
RegisterOrPair.FAC2 -> AsmAssignTarget(TargetStorageKind.REGISTER, program, asmgen, DataType.FLOAT, scope, register = registers)
RegisterOrPair.FAC2 -> AsmAssignTarget(TargetStorageKind.REGISTER, asmgen, DataType.FLOAT, scope, register = registers)
RegisterOrPair.R0,
RegisterOrPair.R1,
RegisterOrPair.R2,
@ -107,7 +106,7 @@ internal class AsmAssignTarget(val kind: TargetStorageKind,
RegisterOrPair.R12,
RegisterOrPair.R13,
RegisterOrPair.R14,
RegisterOrPair.R15 -> AsmAssignTarget(TargetStorageKind.REGISTER, program, asmgen, if(signed) DataType.WORD else DataType.UWORD, scope, register = registers)
RegisterOrPair.R15 -> AsmAssignTarget(TargetStorageKind.REGISTER, asmgen, if(signed) DataType.WORD else DataType.UWORD, scope, register = registers)
}
}
}
@ -208,7 +207,7 @@ internal class AsmAssignment(val source: AsmAssignSource,
init {
if(target.register !in arrayOf(RegisterOrPair.XY, RegisterOrPair.AX, RegisterOrPair.AY))
require(source.datatype != DataType.UNDEFINED) { "must not be placeholder/undefined datatype" }
require(source.datatype != DataType.UNDEFINED) { "must not be placeholder/undefined datatype at $position" }
require(memsizer.memorySize(source.datatype) <= memsizer.memorySize(target.datatype)) {
"source dt size must be less or equal to target dt size at $position"
}

658
codeGenCpu6502/src/prog8/codegen/cpu6502/assignment/AssignmentAsmGen.kt
View File

@ -27,13 +27,6 @@ internal class AssignmentAsmGen(private val program: Program,
translateNormalAssignment(assign)
}
internal fun virtualRegsToVariables(origtarget: AsmAssignTarget): AsmAssignTarget {
return if(origtarget.kind==TargetStorageKind.REGISTER && origtarget.register in Cx16VirtualRegisters) {
AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, origtarget.datatype, origtarget.scope,
variableAsmName = "cx16.${origtarget.register!!.name.lowercase()}", origAstTarget = origtarget.origAstTarget)
} else origtarget
}
fun translateNormalAssignment(assign: AsmAssignment) {
if(assign.isAugmentable) {
augmentableAsmGen.translate(assign)
@ -220,9 +213,25 @@ internal class AssignmentAsmGen(private val program: Program,
RegisterOrPair.A -> assignRegisterByte(assign.target, CpuRegister.A)
RegisterOrPair.X -> assignRegisterByte(assign.target, CpuRegister.X)
RegisterOrPair.Y -> assignRegisterByte(assign.target, CpuRegister.Y)
RegisterOrPair.AX -> assignRegisterpairWord(assign.target, RegisterOrPair.AX)
RegisterOrPair.AY -> assignRegisterpairWord(assign.target, RegisterOrPair.AY)
RegisterOrPair.XY -> assignRegisterpairWord(assign.target, RegisterOrPair.XY)
RegisterOrPair.AX -> assignVirtualRegister(assign.target, RegisterOrPair.AX)
RegisterOrPair.AY -> assignVirtualRegister(assign.target, RegisterOrPair.AY)
RegisterOrPair.XY -> assignVirtualRegister(assign.target, RegisterOrPair.XY)
RegisterOrPair.R0 -> assignVirtualRegister(assign.target, RegisterOrPair.R0)
RegisterOrPair.R1 -> assignVirtualRegister(assign.target, RegisterOrPair.R1)
RegisterOrPair.R2 -> assignVirtualRegister(assign.target, RegisterOrPair.R2)
RegisterOrPair.R3 -> assignVirtualRegister(assign.target, RegisterOrPair.R3)
RegisterOrPair.R4 -> assignVirtualRegister(assign.target, RegisterOrPair.R4)
RegisterOrPair.R5 -> assignVirtualRegister(assign.target, RegisterOrPair.R5)
RegisterOrPair.R6 -> assignVirtualRegister(assign.target, RegisterOrPair.R6)
RegisterOrPair.R7 -> assignVirtualRegister(assign.target, RegisterOrPair.R7)
RegisterOrPair.R8 -> assignVirtualRegister(assign.target, RegisterOrPair.R8)
RegisterOrPair.R9 -> assignVirtualRegister(assign.target, RegisterOrPair.R9)
RegisterOrPair.R10 -> assignVirtualRegister(assign.target, RegisterOrPair.R10)
RegisterOrPair.R11 -> assignVirtualRegister(assign.target, RegisterOrPair.R11)
RegisterOrPair.R12 -> assignVirtualRegister(assign.target, RegisterOrPair.R12)
RegisterOrPair.R13 -> assignVirtualRegister(assign.target, RegisterOrPair.R13)
RegisterOrPair.R14 -> assignVirtualRegister(assign.target, RegisterOrPair.R14)
RegisterOrPair.R15 -> assignVirtualRegister(assign.target, RegisterOrPair.R15)
else -> {
val sflag = returnValue.second.statusflag
if(sflag!=null)
@ -271,18 +280,24 @@ internal class AssignmentAsmGen(private val program: Program,
}
}
is PrefixExpression -> {
// first assign the value to the target then apply the operator in place on the target.
translateNormalAssignment(AsmAssignment(
AsmAssignSource.fromAstSource(value.expression, program, asmgen),
assign.target,
false, program.memsizer, assign.position
))
val target = virtualRegsToVariables(assign.target)
when(value.operator) {
"+" -> {}
"-" -> augmentableAsmGen.inplaceNegate(target, target.datatype)
"~" -> augmentableAsmGen.inplaceInvert(target, target.datatype)
else -> throw AssemblyError("invalid prefix operator")
if(assign.target.array==null) {
// First assign the value to the target then apply the operator in place on the target.
// This saves a temporary variable
translateNormalAssignment(
AsmAssignment(
AsmAssignSource.fromAstSource(value.expression, program, asmgen),
assign.target,
false, program.memsizer, assign.position
)
)
when (value.operator) {
"+" -> {}
"-" -> augmentableAsmGen.inplaceNegate(assign, true)
"~" -> augmentableAsmGen.inplaceInvert(assign)
else -> throw AssemblyError("invalid prefix operator")
}
} else {
assignPrefixedExpressionToArrayElt(assign)
}
}
is ContainmentCheck -> {
@ -301,6 +316,39 @@ internal class AssignmentAsmGen(private val program: Program,
}
}
internal fun assignPrefixedExpressionToArrayElt(assign: AsmAssignment) {
require(assign.source.expression is PrefixExpression)
if(assign.source.datatype==DataType.FLOAT) {
// floatarray[x] = -value ... just use FAC1 to calculate the expression into and then store that back into the array.
assignExpressionToRegister(assign.source.expression, RegisterOrPair.FAC1, true)
assignFAC1float(assign.target)
} else {
// array[x] = -value ... use a tempvar then store that back into the array.
val tempvar = asmgen.getTempVarName(assign.target.datatype).joinToString(".")
val assignToTempvar = AsmAssignment(assign.source,
AsmAssignTarget(TargetStorageKind.VARIABLE, asmgen, assign.target.datatype, assign.target.scope, variableAsmName=tempvar, origAstTarget = assign.target.origAstTarget),
false, program.memsizer, assign.position)
asmgen.translateNormalAssignment(assignToTempvar)
when(assign.target.datatype) {
in ByteDatatypes -> assignVariableByte(assign.target, tempvar)
in WordDatatypes -> assignVariableWord(assign.target, tempvar)
DataType.FLOAT -> assignVariableFloat(assign.target, tempvar)
else -> throw AssemblyError("weird dt")
}
}
}
private fun assignVirtualRegister(target: AsmAssignTarget, register: RegisterOrPair) {
when(target.datatype) {
in ByteDatatypes -> {
asmgen.out(" lda cx16.${register.toString().lowercase()}L")
assignRegisterByte(target, CpuRegister.A)
}
in WordDatatypes -> assignRegisterpairWord(target, register)
else -> throw AssemblyError("expected byte or word")
}
}
private fun attemptAssignOptimizedBinexpr(expr: BinaryExpression, assign: AsmAssignment): Boolean {
if(expr.operator in ComparisonOperators) {
if(expr.right.constValue(program)?.number == 0.0) {
@ -330,140 +378,352 @@ internal class AssignmentAsmGen(private val program: Program,
if(!expr.inferType(program).isInteger)
return false
if(expr.operator!="+" && expr.operator!="-")
return false
val dt = expr.inferType(program).getOrElse { throw AssemblyError("invalid dt") }
val left = expr.left
val right = expr.right
if(dt in ByteDatatypes) {
when (right) {
is IdentifierReference -> {
assignExpressionToRegister(left, RegisterOrPair.A, dt==DataType.BYTE)
val symname = asmgen.asmVariableName(right)
if(expr.operator=="+")
asmgen.out(" clc | adc $symname")
else
asmgen.out(" sec | sbc $symname")
assignRegisterByte(assign.target, CpuRegister.A)
return true
fun simpleLogicalBytesExpr() {
// both left and right expression operands are simple.
if (expr.right is NumericLiteral || expr.right is IdentifierReference)
assignLogicalWithSimpleRightOperandByte(assign.target, expr.left, expr.operator, expr.right)
else if (expr.left is NumericLiteral || expr.left is IdentifierReference)
assignLogicalWithSimpleRightOperandByte(assign.target, expr.right, expr.operator, expr.left)
else {
assignExpressionToRegister(expr.left, RegisterOrPair.A, false)
asmgen.saveRegisterStack(CpuRegister.A, false)
assignExpressionToVariable(expr.right, "P8ZP_SCRATCH_B1", DataType.UBYTE, expr.definingSubroutine)
asmgen.restoreRegisterStack(CpuRegister.A, false)
when (expr.operator) {
"&", "and" -> asmgen.out(" and P8ZP_SCRATCH_B1")
"|", "or" -> asmgen.out(" ora P8ZP_SCRATCH_B1")
"^", "xor" -> asmgen.out(" eor P8ZP_SCRATCH_B1")
else -> throw AssemblyError("invalid operator")
}
is NumericLiteral -> {
assignExpressionToRegister(left, RegisterOrPair.A, dt==DataType.BYTE)
if(expr.operator=="+")
asmgen.out(" clc | adc #${right.number.toHex()}")
else
asmgen.out(" sec | sbc #${right.number.toHex()}")
assignRegisterByte(assign.target, CpuRegister.A)
return true
}
else -> return false
assignRegisterByte(assign.target, CpuRegister.A)
}
} else if(dt in WordDatatypes) {
when (right) {
is AddressOf -> {
assignExpressionToRegister(left, RegisterOrPair.AY, dt==DataType.WORD)
val symbol = asmgen.asmVariableName(right.identifier)
if(expr.operator=="+")
asmgen.out("""
clc
adc #<$symbol
pha
tya
adc #>$symbol
tay
pla""")
else
asmgen.out("""
sec
sbc #<$symbol
pha
tya
sbc #>$symbol
tay
pla""")
assignRegisterpairWord(assign.target, RegisterOrPair.AY)
}
fun simpleLogicalWordsExpr() {
// both left and right expression operands are simple.
if (expr.right is NumericLiteral || expr.right is IdentifierReference)
assignLogicalWithSimpleRightOperandWord(assign.target, expr.left, expr.operator, expr.right)
else if (expr.left is NumericLiteral || expr.left is IdentifierReference)
assignLogicalWithSimpleRightOperandWord(assign.target, expr.right, expr.operator, expr.left)
else {
assignExpressionToRegister(expr.left, RegisterOrPair.AY, false)
asmgen.saveRegisterStack(CpuRegister.A, false)
asmgen.saveRegisterStack(CpuRegister.Y, false)
assignExpressionToVariable(expr.right, "P8ZP_SCRATCH_W1", DataType.UWORD, expr.definingSubroutine)
when (expr.operator) {
"&", "and" -> asmgen.out(" pla | and P8ZP_SCRATCH_W1+1 | tay | pla | and P8ZP_SCRATCH_W1")
"|", "or" -> asmgen.out(" pla | ora P8ZP_SCRATCH_W1+1 | tay | pla | ora P8ZP_SCRATCH_W1")
"^", "xor" -> asmgen.out(" pla | eor P8ZP_SCRATCH_W1+1 | tay | pla | eor P8ZP_SCRATCH_W1")
else -> throw AssemblyError("invalid operator")
}
assignRegisterpairWord(assign.target, RegisterOrPair.AY)
}
}
if(expr.operator in setOf("&", "|", "^", "and", "or", "xor")) {
if (expr.left.inferType(program).isBytes && expr.right.inferType(program).isBytes) {
if (expr.right.isSimple) {
simpleLogicalBytesExpr()
return true
}
is IdentifierReference -> {
val symname = asmgen.asmVariableName(right)
assignExpressionToRegister(left, RegisterOrPair.AY, dt==DataType.WORD)
if(expr.operator=="+")
asmgen.out("""
clc
adc $symname
pha
tya
adc $symname+1
tay
pla""")
else
asmgen.out("""
sec
sbc $symname
pha
tya
sbc $symname+1
tay
pla""")
assignRegisterpairWord(assign.target, RegisterOrPair.AY)
}
if (expr.left.inferType(program).isWords && expr.right.inferType(program).isWords) {
if (expr.right.isSimple) {
simpleLogicalWordsExpr()
return true
}
is NumericLiteral -> {
assignExpressionToRegister(left, RegisterOrPair.AY, dt==DataType.WORD)
if(expr.operator=="+") {
asmgen.out("""
clc
adc #<${right.number.toHex()}
pha
tya
adc #>${right.number.toHex()}
tay
pla""")
} else if(expr.operator=="-") {
asmgen.out("""
sec
sbc #<${right.number.toHex()}
pha
tya
sbc #>${right.number.toHex()}
tay
pla""")
}
return false
}
if(expr.operator == "==" || expr.operator == "!=") {
// expression datatype is BOOL (ubyte) but operands can be anything
if(expr.left.inferType(program).isBytes && expr.right.inferType(program).isBytes &&
expr.left.isSimple && expr.right.isSimple) {
assignExpressionToRegister(expr.left, RegisterOrPair.A, false)
asmgen.saveRegisterStack(CpuRegister.A, false)
assignExpressionToVariable(expr.right, "P8ZP_SCRATCH_B1", DataType.UBYTE, expr.definingSubroutine)
asmgen.restoreRegisterStack(CpuRegister.A, false)
if(expr.operator=="==") {
asmgen.out("""
cmp P8ZP_SCRATCH_B1
bne +
lda #1
bne ++
+ lda #0
+""")
} else {
asmgen.out("""
cmp P8ZP_SCRATCH_B1
beq +
lda #1
bne ++
+ lda #0
+""")
}
assignRegisterByte(assign.target, CpuRegister.A)
return true
} else if(expr.left.inferType(program).isWords && expr.right.inferType(program).isWords &&
expr.left.isSimple && expr.right.isSimple) {
assignExpressionToRegister(expr.left, RegisterOrPair.AY, false)
asmgen.saveRegisterStack(CpuRegister.A, false)
asmgen.saveRegisterStack(CpuRegister.Y, false)
assignExpressionToVariable(expr.right, "P8ZP_SCRATCH_W1", DataType.UWORD, expr.definingSubroutine)
asmgen.restoreRegisterStack(CpuRegister.Y, false)
asmgen.restoreRegisterStack(CpuRegister.A, false)
if(expr.operator=="==") {
asmgen.out("""
cmp P8ZP_SCRATCH_W1
bne +
cpy P8ZP_SCRATCH_W1+1
bne +
lda #1
bne ++
+ lda #0
+""")
} else {
asmgen.out("""
cmp P8ZP_SCRATCH_W1
bne +
cpy P8ZP_SCRATCH_W1+1
bne +
lda #0
bne ++
+ lda #1
+""")
}
assignRegisterByte(assign.target, CpuRegister.A)
return true
}
return false
}
else if(expr.operator=="+" || expr.operator=="-") {
val dt = expr.inferType(program).getOrElse { throw AssemblyError("invalid dt") }
val left = expr.left
val right = expr.right
if(dt in ByteDatatypes) {
when (right) {
is IdentifierReference -> {
assignExpressionToRegister(left, RegisterOrPair.A, dt==DataType.BYTE)
val symname = asmgen.asmVariableName(right)
if(expr.operator=="+")
asmgen.out(" clc | adc $symname")
else
asmgen.out(" sec | sbc $symname")
assignRegisterByte(assign.target, CpuRegister.A)
return true
}
assignRegisterpairWord(assign.target, RegisterOrPair.AY)
return true
is NumericLiteral -> {
assignExpressionToRegister(left, RegisterOrPair.A, dt==DataType.BYTE)
if(expr.operator=="+")
asmgen.out(" clc | adc #${right.number.toHex()}")
else
asmgen.out(" sec | sbc #${right.number.toHex()}")
assignRegisterByte(assign.target, CpuRegister.A)
return true
}
else -> return false
}
is TypecastExpression -> {
val castedValue = right.expression
if(right.type in WordDatatypes && castedValue.inferType(program).isBytes) {
if(castedValue is IdentifierReference) {
val castedSymname = asmgen.asmVariableName(castedValue)
assignExpressionToRegister(left, RegisterOrPair.AY, dt==DataType.WORD)
if(expr.operator=="+")
asmgen.out("""
clc
adc $castedSymname
bcc +
iny
+""")
else
asmgen.out("""
sec
sbc $castedSymname
bcs +
dey
+""")
assignRegisterpairWord(assign.target, RegisterOrPair.AY)
return true
} else if(dt in WordDatatypes) {
when (right) {
is AddressOf -> {
assignExpressionToRegister(left, RegisterOrPair.AY, dt==DataType.WORD)
val symbol = asmgen.asmVariableName(right.identifier)
if(expr.operator=="+")
asmgen.out("""
clc
adc #<$symbol
pha
tya
adc #>$symbol
tay
pla""")
else
asmgen.out("""
sec
sbc #<$symbol
pha
tya
sbc #>$symbol
tay
pla""")
assignRegisterpairWord(assign.target, RegisterOrPair.AY)
return true
}
is IdentifierReference -> {
val symname = asmgen.asmVariableName(right)
assignExpressionToRegister(left, RegisterOrPair.AY, dt==DataType.WORD)
if(expr.operator=="+")
asmgen.out("""
clc
adc $symname
pha
tya
adc $symname+1
tay
pla""")
else
asmgen.out("""
sec
sbc $symname
pha
tya
sbc $symname+1
tay
pla""")
assignRegisterpairWord(assign.target, RegisterOrPair.AY)
return true
}
is NumericLiteral -> {
assignExpressionToRegister(left, RegisterOrPair.AY, dt==DataType.WORD)
if(expr.operator=="+") {
asmgen.out("""
clc
adc #<${right.number.toHex()}
pha
tya
adc #>${right.number.toHex()}
tay
pla""")
} else if(expr.operator=="-") {
asmgen.out("""
sec
sbc #<${right.number.toHex()}
pha
tya
sbc #>${right.number.toHex()}
tay
pla""")
}
assignRegisterpairWord(assign.target, RegisterOrPair.AY)
return true
}
is TypecastExpression -> {
val castedValue = right.expression
if(right.type in WordDatatypes && castedValue.inferType(program).isBytes) {
if(castedValue is IdentifierReference) {
val castedSymname = asmgen.asmVariableName(castedValue)
assignExpressionToRegister(left, RegisterOrPair.AY, dt==DataType.WORD)
if(expr.operator=="+")
asmgen.out("""
clc
adc $castedSymname
bcc +
iny
+""")
else
asmgen.out("""
sec
sbc $castedSymname
bcs +
dey
+""")
assignRegisterpairWord(assign.target, RegisterOrPair.AY)
return true
}
}
}
else -> return false
}
}
}
else if(expr.operator=="<<" || expr.operator==">>") {
val shifts = expr.right.constValue(program)?.number?.toInt()
if(shifts!=null) {
val dt = expr.left.inferType(program)
if(dt.isBytes && shifts in 0..7) {
val signed = dt istype DataType.BYTE
assignExpressionToRegister(expr.left, RegisterOrPair.A, signed)
if(expr.operator=="<<") {
repeat(shifts) {
asmgen.out(" asl a")
}
} else {
if(signed && shifts>0) {
asmgen.out(" ldy #$shifts | jsr math.lsr_byte_A")
} else {
repeat(shifts) {
asmgen.out(" lsr a")
}
}
}
assignRegisterByte(assign.target, CpuRegister.A)
return true
} else if(dt.isWords && shifts in 0..7) {
val signed = dt istype DataType.WORD
assignExpressionToRegister(expr.left, RegisterOrPair.AY, signed)
if(expr.operator=="<<") {
if(shifts>0) {
asmgen.out(" sty P8ZP_SCRATCH_B1")
repeat(shifts) {
asmgen.out(" asl a | rol P8ZP_SCRATCH_B1")
}
asmgen.out(" ldy P8ZP_SCRATCH_B1")
}
} else {
if(signed) {
// TODO("shift AY >> $shifts signed")
return false
} else {
if(shifts>0) {
asmgen.out(" sty P8ZP_SCRATCH_B1")
repeat(shifts) {
asmgen.out(" lsr P8ZP_SCRATCH_B1 | ror a")
}
asmgen.out(" ldy P8ZP_SCRATCH_B1")
}
}
}
assignRegisterpairWord(assign.target, RegisterOrPair.AY)
return true
}
else -> return false
}
}
return false
}
private fun assignLogicalWithSimpleRightOperandByte(target: AsmAssignTarget, left: Expression, operator: String, right: Expression) {
assignExpressionToRegister(left, RegisterOrPair.A, false)
val operand = when(right) {
is NumericLiteral -> "#${right.number.toHex()}"
is IdentifierReference -> asmgen.asmSymbolName(right)
else -> throw AssemblyError("wrong right operand type")
}
when (operator) {
"&", "and" -> asmgen.out(" and $operand")
"|", "or" -> asmgen.out(" ora $operand")
"^", "xor" -> asmgen.out(" eor $operand")
else -> throw AssemblyError("invalid operator")
}
assignRegisterByte(target, CpuRegister.A)
}
private fun assignLogicalWithSimpleRightOperandWord(target: AsmAssignTarget, left: Expression, operator: String, right: Expression) {
assignExpressionToRegister(left, RegisterOrPair.AY, false)
when(right) {
is NumericLiteral -> {
val number = right.number.toHex()
when (operator) {
"&", "and" -> asmgen.out(" and #<$number | pha | tya | and #>$number | tay | pla")
"|", "or" -> asmgen.out(" ora #<$number | pha | tya | ora #>$number | tay | pla")
"^", "xor" -> asmgen.out(" eor #<$number | pha | tya | eor #>$number | tay | pla")
else -> throw AssemblyError("invalid operator")
}
}
is IdentifierReference -> {
val name = asmgen.asmSymbolName(right)
when (operator) {
"&", "and" -> asmgen.out(" and $name | pha | tya | and $name+1 | tay | pla")
"|", "or" -> asmgen.out(" ora $name | pha | tya | ora $name+1 | tay | pla")
"^", "xor" -> asmgen.out(" eor $name | pha | tya | eor $name+1 | tay | pla")
else -> throw AssemblyError("invalid operator")
}
}
else -> throw AssemblyError("wrong right operand type")
}
assignRegisterpairWord(target, RegisterOrPair.AY)
}
private fun attemptAssignToByteCompareZero(expr: BinaryExpression, assign: AsmAssignment): Boolean {
when (expr.operator) {
"==" -> {
@ -536,8 +796,6 @@ internal class AssignmentAsmGen(private val program: Program,
}
private fun fallbackToStackEval(assign: AsmAssignment) {
// TODO DON'T STACK-EVAL... perhaps by using a temp var? so that it becomes augmentable assignment expression?
// or don't try to solve it here in this one case and rather rewrite the whole stack based value evaluation.
// this routine is called for assigning a binaryexpression value:
// - if it's a boolean comparison expression and the workaround isn't possible (no origTarget ast node)
// - for all other binary expressions.
@ -556,12 +814,12 @@ internal class AssignmentAsmGen(private val program: Program,
if(variable.origin!=VarDeclOrigin.USERCODE) {
when(variable.datatype) {
DataType.STR -> {
require(elementDt.isBytes)
require(elementDt.isBytes) { "must be byte string ${variable.position}" }
val stringVal = variable.value as StringLiteral
val varname = asmgen.asmVariableName(containment.iterable as IdentifierReference)
assignExpressionToRegister(containment.element, RegisterOrPair.A, elementDt istype DataType.BYTE)
asmgen.saveRegisterLocal(CpuRegister.A, containment.definingSubroutine!!)
assignAddressOf(AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, DataType.UWORD, containment.definingSubroutine, "P8ZP_SCRATCH_W1"), varname)
assignAddressOf(AsmAssignTarget(TargetStorageKind.VARIABLE, asmgen, DataType.UWORD, containment.definingSubroutine, "P8ZP_SCRATCH_W1"), varname)
asmgen.restoreRegisterLocal(CpuRegister.A)
asmgen.out(" ldy #${stringVal.value.length}")
asmgen.out(" jsr prog8_lib.containment_bytearray")
@ -572,7 +830,7 @@ internal class AssignmentAsmGen(private val program: Program,
throw AssemblyError("containment check of floats not supported")
}
in ArrayDatatypes -> {
require(elementDt.isInteger)
require(elementDt.isInteger) { "must be integer array ${variable.position}" }
val arrayVal = variable.value as ArrayLiteral
val dt = elementDt.getOr(DataType.UNDEFINED)
val varname = asmgen.asmVariableName(containment.iterable as IdentifierReference)
@ -580,14 +838,14 @@ internal class AssignmentAsmGen(private val program: Program,
in ByteDatatypes -> {
assignExpressionToRegister(containment.element, RegisterOrPair.A, elementDt istype DataType.BYTE)
asmgen.saveRegisterLocal(CpuRegister.A, containment.definingSubroutine!!)
assignAddressOf(AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, DataType.UWORD, containment.definingSubroutine, "P8ZP_SCRATCH_W1"), varname)
assignAddressOf(AsmAssignTarget(TargetStorageKind.VARIABLE, asmgen, DataType.UWORD, containment.definingSubroutine, "P8ZP_SCRATCH_W1"), varname)
asmgen.restoreRegisterLocal(CpuRegister.A)
asmgen.out(" ldy #${arrayVal.value.size}")
asmgen.out(" jsr prog8_lib.containment_bytearray")
}
in WordDatatypes -> {
assignExpressionToVariable(containment.element, "P8ZP_SCRATCH_W1", elementDt.getOr(DataType.UNDEFINED), containment.definingSubroutine)
assignAddressOf(AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, DataType.UWORD, containment.definingSubroutine, "P8ZP_SCRATCH_W2"), varname)
assignAddressOf(AsmAssignTarget(TargetStorageKind.VARIABLE, asmgen, DataType.UWORD, containment.definingSubroutine, "P8ZP_SCRATCH_W2"), varname)
asmgen.out(" ldy #${arrayVal.value.size}")
asmgen.out(" jsr prog8_lib.containment_wordarray")
}
@ -604,7 +862,7 @@ internal class AssignmentAsmGen(private val program: Program,
// use subroutine
assignExpressionToRegister(containment.element, RegisterOrPair.A, elementDt istype DataType.BYTE)
asmgen.saveRegisterLocal(CpuRegister.A, containment.definingSubroutine!!)
assignAddressOf(AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, DataType.UWORD, containment.definingSubroutine, "P8ZP_SCRATCH_W1"), varname)
assignAddressOf(AsmAssignTarget(TargetStorageKind.VARIABLE, asmgen, DataType.UWORD, containment.definingSubroutine, "P8ZP_SCRATCH_W1"), varname)
asmgen.restoreRegisterLocal(CpuRegister.A)
val stringVal = variable.value as StringLiteral
asmgen.out(" ldy #${stringVal.value.length}")
@ -618,7 +876,7 @@ internal class AssignmentAsmGen(private val program: Program,
val arrayVal = variable.value as ArrayLiteral
assignExpressionToRegister(containment.element, RegisterOrPair.A, elementDt istype DataType.BYTE)
asmgen.saveRegisterLocal(CpuRegister.A, containment.definingSubroutine!!)
assignAddressOf(AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, DataType.UWORD, containment.definingSubroutine, "P8ZP_SCRATCH_W1"), varname)
assignAddressOf(AsmAssignTarget(TargetStorageKind.VARIABLE, asmgen, DataType.UWORD, containment.definingSubroutine, "P8ZP_SCRATCH_W1"), varname)
asmgen.restoreRegisterLocal(CpuRegister.A)
asmgen.out(" ldy #${arrayVal.value.size}")
asmgen.out(" jsr prog8_lib.containment_bytearray")
@ -627,7 +885,7 @@ internal class AssignmentAsmGen(private val program: Program,
DataType.ARRAY_W, DataType.ARRAY_UW -> {
val arrayVal = variable.value as ArrayLiteral
assignExpressionToVariable(containment.element, "P8ZP_SCRATCH_W1", elementDt.getOr(DataType.UNDEFINED), containment.definingSubroutine)
assignAddressOf(AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, DataType.UWORD, containment.definingSubroutine, "P8ZP_SCRATCH_W2"), varname)
assignAddressOf(AsmAssignTarget(TargetStorageKind.VARIABLE, asmgen, DataType.UWORD, containment.definingSubroutine, "P8ZP_SCRATCH_W2"), varname)
asmgen.out(" ldy #${arrayVal.value.size}")
asmgen.out(" jsr prog8_lib.containment_wordarray")
return
@ -679,18 +937,17 @@ internal class AssignmentAsmGen(private val program: Program,
fun assignViaExprEval(addressExpression: Expression) {
asmgen.assignExpressionToVariable(addressExpression, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
asmgen.loadAFromZpPointerVar("P8ZP_SCRATCH_W2")
assignRegisterByte(target, CpuRegister.A)
asmgen.out(" ldy #0")
assignRegisterpairWord(target, RegisterOrPair.AY)
}
when (value.addressExpression) {
is NumericLiteral -> {
val address = (value.addressExpression as NumericLiteral).number.toUInt()
assignMemoryByteIntoWord(target, address, null)
return
}
is IdentifierReference -> {
assignMemoryByteIntoWord(target, null, value.addressExpression as IdentifierReference)
return
}
is BinaryExpression -> {
if(asmgen.tryOptimizedPointerAccessWithA(value.addressExpression as BinaryExpression, false)) {
@ -704,6 +961,7 @@ internal class AssignmentAsmGen(private val program: Program,
assignViaExprEval(value.addressExpression)
}
}
return
}
}
is NumericLiteral -> throw AssemblyError("a cast of a literal value should have been const-folded away")
@ -712,7 +970,7 @@ internal class AssignmentAsmGen(private val program: Program,
// special case optimizations
if(target.kind== TargetStorageKind.VARIABLE) {
if(target.kind == TargetStorageKind.VARIABLE) {
if(value is IdentifierReference && valueDt != DataType.UNDEFINED)
return assignTypeCastedIdentifier(target.asmVarname, targetDt, asmgen.asmVariableName(value), valueDt)
@ -790,54 +1048,100 @@ internal class AssignmentAsmGen(private val program: Program,
assignExpressionToRegister(value, RegisterOrPair.FAC1, target.datatype in SignedDatatypes)
assignTypeCastedFloatFAC1("P8ZP_SCRATCH_W1", target.datatype)
assignVariableToRegister("P8ZP_SCRATCH_W1", target.register!!, target.datatype in SignedDatatypes)
return
} else {
if(!(valueDt isAssignableTo targetDt)) {
if(valueDt in WordDatatypes && targetDt in ByteDatatypes) {
return if(valueDt in WordDatatypes && targetDt in ByteDatatypes) {
// word to byte, just take the lsb
return assignCastViaLsbFunc(value, target)
assignCastViaLsbFunc(value, target)
} else if(valueDt in WordDatatypes && targetDt in WordDatatypes) {
// word to word, just assign
assignExpressionToRegister(value, target.register!!, targetDt==DataType.BYTE || targetDt==DataType.WORD)
} else if(valueDt in ByteDatatypes && targetDt in ByteDatatypes) {
// byte to byte, just assign
assignExpressionToRegister(value, target.register!!, targetDt==DataType.BYTE || targetDt==DataType.WORD)
}
else
} else if(valueDt in ByteDatatypes && targetDt in WordDatatypes) {
// byte to word, just assign
assignExpressionToRegister(value, target.register!!, targetDt==DataType.WORD)
} else
throw AssemblyError("can't cast $valueDt to $targetDt, this should have been checked in the astchecker")
}
assignExpressionToRegister(value, target.register!!, targetDt==DataType.BYTE || targetDt==DataType.WORD)
}
return
}
if(targetDt in IntegerDatatypes && valueDt in IntegerDatatypes && valueDt.isAssignableTo(targetDt)) {
require(targetDt in WordDatatypes && valueDt in ByteDatatypes) { "should be byte to word assignment ${origTypeCastExpression.position}"}
when(target.kind) {
// TargetStorageKind.VARIABLE -> {
// This has been handled already earlier on line 961.
// // byte to word, just assign to registers first, then assign to variable
// assignExpressionToRegister(value, RegisterOrPair.AY, targetDt==DataType.WORD)
// assignTypeCastedRegisters(target.asmVarname, targetDt, RegisterOrPair.AY, targetDt)
// return
// }
TargetStorageKind.ARRAY -> {
// byte to word, just assign to registers first, then assign into array
assignExpressionToRegister(value, RegisterOrPair.AY, targetDt==DataType.WORD)
assignRegisterpairWord(target, RegisterOrPair.AY)
return
}
TargetStorageKind.REGISTER -> {
// byte to word, just assign to registers
assignExpressionToRegister(value, target.register!!, targetDt==DataType.WORD)
return
}
TargetStorageKind.STACK -> {
// byte to word, just assign to registers first, then push onto stack
assignExpressionToRegister(value, RegisterOrPair.AY, targetDt==DataType.WORD)
asmgen.out("""
sta P8ESTACK_LO,x
tya
sta P8ESTACK_HI,x
dex""")
return
}
else -> throw AssemblyError("weird target")
}
}
if(targetDt==DataType.FLOAT && (target.register==RegisterOrPair.FAC1 || target.register==RegisterOrPair.FAC2)) {
when(valueDt) {
DataType.UBYTE -> {
assignExpressionToRegister(value, RegisterOrPair.Y, false)
asmgen.saveRegisterLocal(CpuRegister.X, origTypeCastExpression.definingSubroutine!!)
asmgen.out(" jsr floats.FREADUY")
asmgen.restoreRegisterLocal(CpuRegister.X)
}
DataType.BYTE -> {
assignExpressionToRegister(value, RegisterOrPair.A, true)
asmgen.saveRegisterLocal(CpuRegister.X, origTypeCastExpression.definingSubroutine!!)
asmgen.out(" jsr floats.FREADSA")
asmgen.restoreRegisterLocal(CpuRegister.X)
}
DataType.UWORD -> {
assignExpressionToRegister(value, RegisterOrPair.AY, false)
asmgen.saveRegisterLocal(CpuRegister.X, origTypeCastExpression.definingSubroutine!!)
asmgen.out(" jsr floats.GIVUAYFAY")
asmgen.restoreRegisterLocal(CpuRegister.X)
}
DataType.WORD -> {
assignExpressionToRegister(value, RegisterOrPair.AY, true)
asmgen.saveRegisterLocal(CpuRegister.X, origTypeCastExpression.definingSubroutine!!)
asmgen.out(" jsr floats.GIVAYFAY")
asmgen.restoreRegisterLocal(CpuRegister.X)
}
else -> throw AssemblyError("invalid dt")
}
if(target.register==RegisterOrPair.FAC2) {
asmgen.out(" jsr floats.MOVEF")
}
return
} else {
// No more special optmized cases yet. Do the rest via more complex evaluation
// note: cannot use assignTypeCastedValue because that is ourselves :P
// NOTE: THIS MAY TURN INTO A STACK OVERFLOW ERROR IF IT CAN'T SIMPLIFY THE TYPECAST..... :-/
asmgen.assignExpressionTo(origTypeCastExpression, target)
return
}
}
@ -994,14 +1298,10 @@ internal class AssignmentAsmGen(private val program: Program,
DataType.UWORD, DataType.WORD -> {
if(asmgen.isTargetCpu(CpuType.CPU65c02))
asmgen.out(
" st${
regs.toString().lowercase()
} $targetAsmVarName | stz $targetAsmVarName+1")
" st${regs.toString().lowercase()} $targetAsmVarName | stz $targetAsmVarName+1")
else
asmgen.out(
" st${
regs.toString().lowercase()
} $targetAsmVarName | lda #0 | sta $targetAsmVarName+1")
" st${regs.toString().lowercase()} $targetAsmVarName | lda #0 | sta $targetAsmVarName+1")
}
DataType.FLOAT -> {
when(regs) {
@ -1796,18 +2096,10 @@ internal class AssignmentAsmGen(private val program: Program,
}
internal fun assignRegisterByte(target: AsmAssignTarget, register: CpuRegister) {
// we make an exception in the type check for assigning something to a cx16 virtual register, or a register pair
// these will be correctly typecasted from a byte to a word value
if(target.register !in Cx16VirtualRegisters &&
target.register!=RegisterOrPair.AX && target.register!=RegisterOrPair.AY && target.register!=RegisterOrPair.XY) {
if(target.kind== TargetStorageKind.VARIABLE) {
val parts = target.asmVarname.split('.')
if (parts.size != 2 || parts[0] != "cx16")
require(target.datatype in ByteDatatypes)
} else {
require(target.datatype in ByteDatatypes)
}
}
// we make an exception in the type check for assigning something to a register pair AX, AY or XY
// these will be correctly typecasted from a byte to a word value here
if(target.register !in setOf(RegisterOrPair.AX, RegisterOrPair.AY, RegisterOrPair.XY))
require(target.datatype in ByteDatatypes) { "assign target must be byte type ${target.origAstTarget?.position ?: ""}"}
when(target.kind) {
TargetStorageKind.VARIABLE -> {
@ -1896,7 +2188,9 @@ internal class AssignmentAsmGen(private val program: Program,
}
internal fun assignRegisterpairWord(target: AsmAssignTarget, regs: RegisterOrPair) {
require(target.datatype in NumericDatatypes || target.datatype in PassByReferenceDatatypes)
require(target.datatype in NumericDatatypes || target.datatype in PassByReferenceDatatypes) {
"assign target must be word type ${target.origAstTarget?.position ?: ""}"
}
if(target.datatype==DataType.FLOAT)
throw AssemblyError("float value should be from FAC1 not from registerpair memory pointer")
@ -2579,7 +2873,7 @@ internal class AssignmentAsmGen(private val program: Program,
internal fun assignExpressionToRegister(expr: Expression, register: RegisterOrPair, signed: Boolean) {
val src = AsmAssignSource.fromAstSource(expr, program, asmgen)
val tgt = AsmAssignTarget.fromRegisters(register, signed, null, program, asmgen)
val tgt = AsmAssignTarget.fromRegisters(register, signed, null, asmgen)
val assign = AsmAssignment(src, tgt, false, program.memsizer, expr.position)
translateNormalAssignment(assign)
}
@ -2589,14 +2883,14 @@ internal class AssignmentAsmGen(private val program: Program,
throw AssemblyError("can't directly assign a FLOAT expression to an integer variable $expr")
} else {
val src = AsmAssignSource.fromAstSource(expr, program, asmgen)
val tgt = AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, dt, scope, variableAsmName = asmVarName)
val tgt = AsmAssignTarget(TargetStorageKind.VARIABLE, asmgen, dt, scope, variableAsmName = asmVarName)
val assign = AsmAssignment(src, tgt, false, program.memsizer, expr.position)
translateNormalAssignment(assign)
}
}
internal fun assignVariableToRegister(asmVarName: String, register: RegisterOrPair, signed: Boolean) {
val tgt = AsmAssignTarget.fromRegisters(register, signed, null, program, asmgen)
val tgt = AsmAssignTarget.fromRegisters(register, signed, null, asmgen)
val src = AsmAssignSource(SourceStorageKind.VARIABLE, program, asmgen, tgt.datatype, variableAsmName = asmVarName)
val assign = AsmAssignment(src, tgt, false, program.memsizer, Position.DUMMY)
translateNormalAssignment(assign)

60
codeGenCpu6502/src/prog8/codegen/cpu6502/assignment/AugmentableAssignmentAsmGen.kt
View File

@ -16,18 +16,17 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
) {
fun translate(assign: AsmAssignment) {
require(assign.isAugmentable)
require(assign.source.kind== SourceStorageKind.EXPRESSION)
require(assign.source.kind == SourceStorageKind.EXPRESSION) {
"non-expression assign value should be handled elsewhere ${assign.position}"
}
when (val value = assign.source.expression!!) {
is PrefixExpression -> {
// A = -A , A = +A, A = ~A, A = not A
val target = assignmentAsmGen.virtualRegsToVariables(assign.target)
val itype = value.inferType(program)
val type = itype.getOrElse { throw AssemblyError("unknown dt") }
when (value.operator) {
"+" -> {}
"-" -> inplaceNegate(target, type)
"~" -> inplaceInvert(target, type)
"-" -> inplaceNegate(assign, false)
"~" -> inplaceInvert(assign)
else -> throw AssemblyError("invalid prefix operator")
}
}
@ -236,7 +235,7 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
}
else -> {
// TODO use some other evaluation here; don't use the estack to transfer the address to read/write from
asmgen.assignExpressionTo(memory.addressExpression, AsmAssignTarget(TargetStorageKind.STACK, program, asmgen, DataType.UWORD, memory.definingSubroutine))
asmgen.assignExpressionTo(memory.addressExpression, AsmAssignTarget(TargetStorageKind.STACK, asmgen, DataType.UWORD, memory.definingSubroutine))
asmgen.out(" jsr prog8_lib.read_byte_from_address_on_stack | sta P8ZP_SCRATCH_B1")
when {
valueLv != null -> inplaceModification_byte_litval_to_variable("P8ZP_SCRATCH_B1", DataType.UBYTE, operator, valueLv.toInt())
@ -305,7 +304,6 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
AsmAssignTarget.fromRegisters(
RegisterOrPair.A,
target.datatype == DataType.BYTE, null,
program,
asmgen
)
val assign = AsmAssignment(target.origAssign.source, tgt, false, program.memsizer, value.position)
@ -317,7 +315,6 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
AsmAssignTarget.fromRegisters(
RegisterOrPair.AY,
target.datatype == DataType.WORD, null,
program,
asmgen
)
val assign = AsmAssignment(target.origAssign.source, tgt, false, program.memsizer, value.position)
@ -329,7 +326,6 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
AsmAssignTarget.fromRegisters(
RegisterOrPair.FAC1,
true, null,
program,
asmgen
)
val assign = AsmAssignment(target.origAssign.source, tgt, false, program.memsizer, value.position)
@ -1799,8 +1795,9 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
}
}
internal fun inplaceInvert(target: AsmAssignTarget, dt: DataType) {
when (dt) {
internal fun inplaceInvert(assign: AsmAssignment) {
val target = assign.target
when (assign.target.datatype) {
DataType.UBYTE -> {
when (target.kind) {
TargetStorageKind.VARIABLE -> {
@ -1843,7 +1840,8 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
}
}
TargetStorageKind.STACK -> TODO("no asm gen for byte stack invert")
else -> throw AssemblyError("no asm gen for in-place invert ubyte for ${target.kind}")
TargetStorageKind.ARRAY -> assignmentAsmGen.assignPrefixedExpressionToArrayElt(assign)
else -> throw AssemblyError("weird target")
}
}
DataType.UWORD -> {
@ -1867,15 +1865,24 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
}
}
TargetStorageKind.STACK -> TODO("no asm gen for word stack invert")
else -> throw AssemblyError("no asm gen for in-place invert uword for ${target.kind}")
TargetStorageKind.ARRAY -> assignmentAsmGen.assignPrefixedExpressionToArrayElt(assign)
else -> throw AssemblyError("weird target")
}
}
else -> throw AssemblyError("invert of invalid type")
}
}
internal fun inplaceNegate(target: AsmAssignTarget, dt: DataType) {
when (dt) {
internal fun inplaceNegate(assign: AsmAssignment, ignoreDatatype: Boolean) {
val target = assign.target
val datatype = if(ignoreDatatype) {
when(target.datatype) {
DataType.UBYTE, DataType.BYTE -> DataType.BYTE
DataType.UWORD, DataType.WORD -> DataType.WORD
else -> target.datatype
}
} else target.datatype
when (datatype) {
DataType.BYTE -> {
when (target.kind) {
TargetStorageKind.VARIABLE -> {
@ -1899,9 +1906,10 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
else -> throw AssemblyError("invalid reg dt for byte negate")
}
}
TargetStorageKind.MEMORY -> throw AssemblyError("memory is ubyte, can't in-place negate")
TargetStorageKind.MEMORY -> throw AssemblyError("memory is ubyte, can't negate that")
TargetStorageKind.STACK -> TODO("no asm gen for byte stack negate")
else -> throw AssemblyError("no asm gen for in-place negate byte")
TargetStorageKind.ARRAY -> assignmentAsmGen.assignPrefixedExpressionToArrayElt(assign)
else -> throw AssemblyError("weird target")
}
}
DataType.WORD -> {
@ -1958,12 +1966,21 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
else -> throw AssemblyError("invalid reg dt for word neg")
}
}
TargetStorageKind.MEMORY -> throw AssemblyError("memory is ubyte, can't negate that")
TargetStorageKind.STACK -> TODO("no asm gen for word stack negate")
else -> throw AssemblyError("no asm gen for in-place negate word")
TargetStorageKind.ARRAY -> assignmentAsmGen.assignPrefixedExpressionToArrayElt(assign)
else -> throw AssemblyError("weird target")
}
}
DataType.FLOAT -> {
when (target.kind) {
TargetStorageKind.REGISTER -> {
when(target.register!!) {
RegisterOrPair.FAC1 -> asmgen.out(" jsr floats.NEGOP")
RegisterOrPair.FAC2 -> asmgen.out(" jsr floats.MOVFA | jsr floats.NEGOP | jsr floats.MOVEF")
else -> throw AssemblyError("invalid float register")
}
}
TargetStorageKind.VARIABLE -> {
// simply flip the sign bit in the float
asmgen.out("""
@ -1973,10 +1990,11 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
""")
}
TargetStorageKind.STACK -> TODO("no asm gen for float stack negate")
else -> throw AssemblyError("weird target kind for inplace negate float ${target.kind}")
TargetStorageKind.ARRAY -> assignmentAsmGen.assignPrefixedExpressionToArrayElt(assign)
else -> throw AssemblyError("weird target for in-place float negation")
}
}
else -> throw AssemblyError("negate of invalid type $dt")
else -> throw AssemblyError("negate of invalid type")
}
}

3
codeGenExperimental/build.gradle
View File

@ -24,8 +24,9 @@ compileTestKotlin {
}
dependencies {
implementation project(':codeAst')
implementation project(':codeCore')
implementation project(':intermediate')
implementation project(':codeGenIntermediate')
implementation "org.jetbrains.kotlin:kotlin-stdlib-jdk8"
// implementation "org.jetbrains.kotlin:kotlin-reflect"
implementation "com.michael-bull.kotlin-result:kotlin-result-jvm:1.1.16"

3
codeGenExperimental/codeGenExperimental.iml
View File

@ -10,7 +10,8 @@
<orderEntry type="sourceFolder" forTests="false" />
<orderEntry type="library" name="KotlinJavaRuntime" level="project" />
<orderEntry type="library" name="michael.bull.kotlin.result.jvm" level="project" />
<orderEntry type="module" module-name="codeAst" />
<orderEntry type="module" module-name="codeGenIntermediate" />
<orderEntry type="module" module-name="intermediate" />
<orderEntry type="module" module-name="codeCore" />
</component>
</module>

39
codeGenExperimental/src/prog8/codegen/experimental/AsmGen.kt
View File

@ -1,39 +0,0 @@
package prog8.codegen.experimental
import prog8.code.SymbolTable
import prog8.code.ast.PtProgram
import prog8.code.core.CompilationOptions
import prog8.code.core.IAssemblyGenerator
import prog8.code.core.IAssemblyProgram
import prog8.code.core.IErrorReporter
/*
NOTE: The goal is to keep the dependencies as lean as possible! For now, we depend only on:
- codeAst (the 'lean' new AST and the SymbolTable)
- codeCore (various base enums and interfaces)
This *should* be enough to build a complete code generator with. But we'll see :)
*/
class AsmGen(internal val program: PtProgram,
internal val symbolTable: SymbolTable,
internal val options: CompilationOptions,
internal val errors: IErrorReporter
): IAssemblyGenerator {
override fun compileToAssembly(): IAssemblyProgram? {
println("\n** experimental code generator **\n")
println("Writing AST into XML form...")
val xmlConv = AstToXmlConverter(program, symbolTable, options)
xmlConv.writeXml()
println("..todo: create assembly program into ${options.outputDir.toAbsolutePath()}..")
return AssemblyProgram("dummy")
}
}

13
codeGenExperimental/src/prog8/codegen/experimental/AssemblyProgram.kt
View File

@ -1,13 +0,0 @@
package prog8.codegen.experimental
import prog8.code.core.CompilationOptions
import prog8.code.core.IAssemblyProgram
internal class AssemblyProgram(override val name: String) : IAssemblyProgram
{
override fun assemble(options: CompilationOptions): Boolean {
println("..todo: assemble code into binary..")
return true
}
}

668
codeGenExperimental/src/prog8/codegen/experimental/AstToXmlConverter.kt
View File

@ -1,668 +0,0 @@
package prog8.codegen.experimental
import prog8.code.*
import prog8.code.ast.*
import prog8.code.core.*
import javax.xml.stream.XMLOutputFactory
import kotlin.io.path.Path
import kotlin.io.path.absolutePathString
import kotlin.io.path.div
/*
NOTE: The goal is to keep the dependencies as lean as possible! For now, we depend only on:
- codeAst (the 'lean' new AST and the SymbolTable)
- codeCore (various base enums and interfaces)
This *should* be enough to build a complete code generator with. But we'll see :)
*/
class AstToXmlConverter(internal val program: PtProgram,
internal val symbolTable: SymbolTable,
internal val options: CompilationOptions
) {
private lateinit var xml: IndentingXmlWriter
fun writeXml() {
val writer = (options.outputDir / Path(program.name+"-ast.xml")).toFile().printWriter()
xml = IndentingXmlWriter(XMLOutputFactory.newFactory().createXMLStreamWriter(writer))
xml.doc()
xml.elt("program")
xml.attr("name", program.name)
xml.startChildren()
writeOptions(options)
program.children.forEach { writeNode(it) }
writeSymboltable(symbolTable)
xml.endElt()
xml.endDoc()
xml.close()
}
private fun writeSymboltable(st: SymbolTable) {
xml.elt("symboltable")
xml.startChildren()
st.flat.forEach{ (name, entry) ->
xml.elt("entry")
xml.attr("name", name.joinToString("."))
xml.attr("type", entry.type.name)
xml.startChildren()
writeStNode(entry)
xml.endElt()
}
xml.endElt()
}
private fun writeStNode(node: StNode) {
when(node.type) {
StNodeType.GLOBAL,
StNodeType.LABEL,
StNodeType.BLOCK,
StNodeType.BUILTINFUNC,
StNodeType.SUBROUTINE -> {/* no additional info*/}
StNodeType.ROMSUB -> {
node as StRomSub
xml.elt("romsub")
xml.attr("address", node.address.toString())
xml.endElt()
}
StNodeType.STATICVAR -> {
node as StStaticVariable
xml.elt("var")
xml.attr("type", node.dt.name)
xml.attr("zpwish", node.zpwish.name)
if(node.length!=null)
xml.attr("length", node.length.toString())
if(node.initialNumericValue!=null || node.initialArrayValue!=null || node.initialStringValue!=null) {
xml.startChildren()
if(node.initialNumericValue!=null) {
writeNumber(node.dt, node.initialNumericValue!!)
}
if(node.initialStringValue!=null) {
xml.writeTextNode(
"string",
listOf(Pair("encoding", node.initialStringValue!!.second.name)),
node.initialStringValue!!.first,
false
)
}
if(node.initialArrayValue!=null) {
xml.elt("array")
xml.startChildren()
val eltDt = ArrayToElementTypes.getValue(node.dt)
node.initialArrayValue!!.forEach {
if(it.number!=null) {
writeNumber(eltDt, it.number!!)
}
if(it.addressOf!=null) {
xml.elt("addressof")
xml.attr("symbol", it.addressOf!!.joinToString("."))
xml.endElt()
}
}
xml.endElt()
}
}
xml.endElt()
}
StNodeType.MEMVAR -> {
node as StMemVar
xml.writeTextNode("memvar",
listOf(Pair("type", node.dt.name)),
node.address.toString(),
false)
}
StNodeType.CONSTANT -> {
node as StConstant
xml.writeTextNode("const",
listOf(Pair("type", node.dt.name)),
intOrDouble(node.dt, node.value).toString(),
false)
}
}
}
private fun writeOptions(options: CompilationOptions) {
xml.elt("options")
xml.attr("target", options.compTarget.name)
xml.attr("output", options.output.name)
xml.attr("launcher", options.launcher.name)
xml.attr("zeropage", options.zeropage.name)
xml.attr("loadaddress", options.loadAddress.toString())
xml.attr("floatsenabled", options.floats.toString())
xml.attr("nosysinit", options.noSysInit.toString())
xml.attr("dontreinitglobals", options.dontReinitGlobals.toString())
xml.attr("optimize", options.optimize.toString())
if(options.evalStackBaseAddress!=null)
xml.attr("evalstackbase", options.evalStackBaseAddress!!.toString())
if(options.zpReserved.isNotEmpty()) {
xml.startChildren()
options.zpReserved.forEach {
xml.elt("zpreserved")
xml.attr("from", it.first.toString())
xml.attr("to", it.last.toString())
xml.endElt()
}
}
if(options.symbolDefs.isNotEmpty()) {
xml.startChildren()
options.symbolDefs.forEach { name, value ->
xml.elt("symboldef")
xml.attr("name", name)
xml.attr("value", value)
xml.endElt()
}
}
xml.endElt()
}
private fun writeNode(it: PtNode) {
when(it) {
is PtBlock -> write(it)
is PtSub -> write(it)
is PtVariable -> write(it)
is PtAssignment -> write(it)
is PtConstant -> write(it)
is PtAsmSub -> write(it)
is PtAddressOf -> write(it)
is PtArrayIndexer -> write(it)
is PtArray -> write(it)
is PtBinaryExpression -> write(it)
is PtBuiltinFunctionCall -> write(it)
is PtConditionalBranch -> write(it)
is PtContainmentCheck -> write(it)
is PtForLoop -> write(it)
is PtFunctionCall -> write(it)
is PtIdentifier -> write(it)
is PtIfElse -> write(it)
is PtInlineAssembly -> write(it)
is PtIncludeBinary -> write(it)
is PtJump -> write(it)
is PtMemoryByte -> write(it)
is PtMemMapped -> write(it)
is PtNumber -> write(it)
is PtPostIncrDecr -> write(it)
is PtPrefix -> write(it)
is PtRange -> write(it)
is PtRepeatLoop -> write(it)
is PtReturn -> write(it)
is PtString -> write(it)
is PtTypeCast -> write(it)
is PtWhen -> write(it)
is PtWhenChoice -> write(it)
is PtLabel -> write(it)
is PtNop -> {}
is PtBreakpoint -> write(it)
is PtScopeVarsDecls -> write(it)
is PtNodeGroup -> it.children.forEach { writeNode(it) }
else -> TODO("$it")
}
}
private fun write(vars: PtScopeVarsDecls) {
xml.elt("vars")
xml.startChildren()
vars.children.forEach { writeNode(it) }
xml.endElt()
}
private fun write(breakPt: PtBreakpoint) {
xml.elt("breakpoint")
xml.pos(breakPt.position)
xml.endElt()
}
private fun write(array: PtArray) {
xml.elt("array")
xml.attr("type", array.type.name)
xml.startChildren()
array.children.forEach { writeNode(it) }
xml.endElt()
}
private fun write(prefix: PtPrefix) {
xml.elt("prefix")
xml.attr("op", prefix.operator)
xml.attr("type", prefix.type.name)
xml.startChildren()
xml.elt("value")
xml.startChildren()
writeNode(prefix.value)
xml.endElt()
xml.endElt()
}
private fun write(string: PtString) =
xml.writeTextNode("string", listOf(Pair("encoding", string.encoding.name)), string.value, false)
private fun write(rept: PtRepeatLoop) {
xml.elt("repeat")
xml.pos(rept.position)
xml.startChildren()
xml.elt("count")
xml.startChildren()
writeNode(rept.count)
xml.endElt()
writeNode(rept.statements)
xml.endElt()
}
private fun write(branch: PtConditionalBranch) {
xml.elt("conditionalbranch")
xml.attr("condition", branch.condition.name)
xml.pos(branch.position)
xml.startChildren()
xml.elt("true")
xml.startChildren()
writeNode(branch.trueScope)
xml.endElt()
if(branch.falseScope.children.isNotEmpty()) {
xml.elt("false")
xml.startChildren()
writeNode(branch.falseScope)
xml.endElt()
}
xml.endElt()
}
private fun write(check: PtContainmentCheck) {
xml.elt("containment")
xml.attr("type", check.type.name)
xml.startChildren()
xml.elt("element")
xml.startChildren()
writeNode(check.children[0])
xml.endElt()
xml.elt("iterable")
xml.startChildren()
writeNode(check.children[1])
xml.endElt()
xml.endElt()
}
private fun write(range: PtRange) {
xml.elt("range")
xml.attr("type", range.type.name)
xml.startChildren()
xml.elt("from")
xml.startChildren()
writeNode(range.from)
xml.endElt()
xml.elt("to")
xml.startChildren()
writeNode(range.to)
xml.endElt()
xml.elt("step")
xml.startChildren()
writeNode(range.step)
xml.endElt()
xml.endElt()
}
private fun write(forLoop: PtForLoop) {
xml.elt("for")
xml.attr("loopvar", strTargetName(forLoop.variable))
xml.pos(forLoop.position)
xml.startChildren()
xml.elt("iterable")
xml.startChildren()
writeNode(forLoop.iterable)
xml.endElt()
writeNode(forLoop.statements)
xml.endElt()
}
private fun write(membyte: PtMemoryByte) {
xml.elt("membyte")
xml.attr("type", membyte.type.name)
xml.startChildren()
xml.elt("address")
xml.startChildren()
writeNode(membyte.address)
xml.endElt()
xml.endElt()
}
private fun write(whenStmt: PtWhen) {
xml.elt("when")
xml.pos(whenStmt.position)
xml.startChildren()
xml.elt("value")
xml.startChildren()
writeNode(whenStmt.value)
xml.endElt()
xml.elt("choices")
xml.startChildren()
writeNode(whenStmt.choices)
xml.endElt()
xml.endElt()
}
private fun write(choice: PtWhenChoice) {
xml.elt("choice")
if(choice.isElse) {
xml.attr("else", "true")
xml.startChildren()
} else {
xml.startChildren()
xml.elt("values")
xml.startChildren()
writeNode(choice.values)
xml.endElt()
}
writeNode(choice.statements)
xml.endElt()
}
private fun write(inlineAsm: PtInlineAssembly) {
xml.elt("assembly")
xml.pos(inlineAsm.position)
xml.startChildren()
xml.writeTextNode("code", emptyList(), inlineAsm.assembly)
xml.endElt()
}
private fun write(inlineBinary: PtIncludeBinary) {
xml.elt("binary")
xml.attr("filename", inlineBinary.file.absolutePathString())
if(inlineBinary.offset!=null)
xml.attr("offset", inlineBinary.offset!!.toString())
if(inlineBinary.length!=null)
xml.attr("length", inlineBinary.length!!.toString())
xml.pos(inlineBinary.position)
xml.endElt()
}
private fun write(fcall: PtBuiltinFunctionCall) {
xml.elt("builtinfcall")
xml.attr("name", fcall.name)
if(fcall.void)
xml.attr("type", "VOID")
else
xml.attr("type", fcall.type.name)
xml.startChildren()
fcall.children.forEach { writeNode(it) }
xml.endElt()
}
private fun write(cast: PtTypeCast) {
xml.elt("cast")
xml.attr("type", cast.type.name)
xml.startChildren()
writeNode(cast.value)
xml.endElt()
}
private fun write(aix: PtArrayIndexer) {
xml.elt("arrayindexed")
xml.attr("type", aix.type.name)
xml.startChildren()
write(aix.variable)
writeNode(aix.index)
xml.endElt()
}
private fun write(binexpr: PtBinaryExpression) {
xml.elt("binexpr")
xml.attr("op", binexpr.operator)
xml.attr("type", binexpr.type.name)
xml.startChildren()
writeNode(binexpr.left)
writeNode(binexpr.right)
xml.endElt()
}
private fun write(addrof: PtAddressOf) {
xml.elt("addressof")
xml.attr("symbol", strTargetName(addrof.identifier))
xml.endElt()
}
private fun write(fcall: PtFunctionCall) {
xml.elt("fcall")
xml.attr("name", strTargetName(fcall))
if(fcall.void)
xml.attr("type", "VOID")
else
xml.attr("type", fcall.type.name)
xml.pos(fcall.position)
xml.startChildren()
fcall.children.forEach { writeNode(it) }
xml.endElt()
}
private fun write(number: PtNumber) = writeNumber(number.type, number.number)
private fun writeNumber(type: DataType, number: Double) =
xml.writeTextNode("number", listOf(Pair("type", type.name)), intOrDouble(type, number).toString(), false)
private fun write(symbol: PtIdentifier) {
xml.elt("symbol")
xml.attr("name", strTargetName(symbol))
xml.attr("type", symbol.type.name)
xml.endElt()
}
private fun write(assign: PtAssignment) {
xml.elt("assign")
xml.pos(assign.position)
xml.startChildren()
write(assign.target)
writeNode(assign.value)
xml.endElt()
}
private fun write(ifElse: PtIfElse) {
xml.elt("ifelse")
xml.pos(ifElse.position)
xml.startChildren()
xml.elt("condition")
xml.startChildren()
writeNode(ifElse.condition)
xml.endElt()
xml.elt("true")
xml.pos(ifElse.ifScope.position)
xml.startChildren()
writeNode(ifElse.ifScope)
xml.endElt()
if(ifElse.elseScope.children.isNotEmpty()) {
xml.elt("false")
xml.pos(ifElse.elseScope.position)
xml.startChildren()
writeNode(ifElse.elseScope)
xml.endElt()
}
xml.endElt()
}
private fun write(ret: PtReturn) {
xml.elt("return")
if(ret.hasValue) {
xml.startChildren()
writeNode(ret.value!!)
}
xml.endElt()
}
private fun write(incdec: PtPostIncrDecr) {
if(incdec.operator=="++") xml.elt("inc") else xml.elt("dec")
xml.startChildren()
write(incdec.target)
xml.endElt()
}
private fun write(label: PtLabel) {
xml.elt("label")
xml.attr("name", label.scopedName.joinToString("."))
xml.pos(label.position)
xml.endElt()
}
private fun write(block: PtBlock) {
xml.elt("block")
xml.attr("name", block.scopedName.joinToString("."))
if(block.address!=null)
xml.attr("address", block.address!!.toString())
xml.attr("library", block.library.toString())
xml.pos(block.position)
xml.startChildren()
block.children.forEach { writeNode(it) }
xml.endElt()
}
private fun write(memMapped: PtMemMapped) {
xml.writeTextNode("memvar",
listOf(
Pair("name", memMapped.scopedName.joinToString(".")),
Pair("type", memMapped.type.name)
),
memMapped.address.toString(),
false)
}
private fun write(target: PtAssignTarget) {
xml.elt("target")
xml.startChildren()
if(target.identifier!=null) {
writeNode(target.identifier!!)
} else if(target.memory!=null) {
writeNode(target.memory!!)
} else if(target.array!=null) {
writeNode(target.array!!)
} else
throw InternalCompilerException("weird assign target")
xml.endElt()
}
private fun write(jump: PtJump) {
xml.elt("jump")
if(jump.identifier!=null) xml.attr("symbol", strTargetName(jump.identifier!!))
else if(jump.address!=null) xml.attr("address", jump.address!!.toString())
else if(jump.generatedLabel!=null) xml.attr("label", jump.generatedLabel!!)
else
throw InternalCompilerException("weird jump target")
xml.endElt()
}
private fun write(sub: PtSub) {
xml.elt("sub")
xml.attr("name", sub.scopedName.joinToString("."))
if(sub.inline)
xml.attr("inline", "true")
xml.attr("returntype", sub.returntype?.toString() ?: "VOID")
xml.pos(sub.position)
xml.startChildren()
if(sub.parameters.isNotEmpty()) {
xml.elt("parameters")
xml.startChildren()
sub.parameters.forEach { write(it) }
xml.endElt()
}
sub.children.forEach { writeNode(it) }
xml.endElt()
}
private fun write(parameter: PtSubroutineParameter, registerOrStatusflag: RegisterOrStatusflag? = null) {
xml.elt("param")
xml.attr("name", parameter.name)
xml.attr("type", parameter.type.name)
if(registerOrStatusflag?.statusflag!=null) {
xml.attr("statusflag", registerOrStatusflag.statusflag!!.toString())
}
if(registerOrStatusflag?.registerOrPair!=null){
xml.attr("registers", registerOrStatusflag.registerOrPair!!.name)
}
xml.endElt()
}
private fun write(asmSub: PtAsmSub) {
if(asmSub.address!=null) {
xml.elt("romsub")
xml.attr("name", asmSub.scopedName.joinToString("."))
xml.attr("address", asmSub.address!!.toString())
if(asmSub.inline)
xml.attr("inline", "true")
xml.pos(asmSub.position)
xml.startChildren()
paramsEtcetera(asmSub)
xml.endElt()
}
else {
xml.elt("asmsub")
xml.attr("name", asmSub.scopedName.joinToString("."))
if(asmSub.inline)
xml.attr("inline", "true")
xml.pos(asmSub.position)
xml.startChildren()
paramsEtcetera(asmSub)
xml.elt("code")
xml.startChildren()
asmSub.children.forEach { writeNode(it) }
xml.endElt()
xml.endElt()
}
}
private fun paramsEtcetera(asmSub: PtAsmSub) {
if(asmSub.parameters.isNotEmpty()) {
xml.elt("parameters")
xml.startChildren()
asmSub.parameters.forEach { (param, reg) -> write(param, reg) }
xml.endElt()
}
if(asmSub.clobbers.isNotEmpty()) {
xml.elt("clobbers")
xml.attr("registers", asmSub.clobbers.joinToString(",") { it.name })
xml.endElt()
}
if(asmSub.retvalRegisters.isNotEmpty()) {
xml.elt("returns")
xml.startChildren()
asmSub.retvalRegisters.forEach {
xml.elt("register")
if(it.statusflag!=null)
xml.attr("statusflag", it.statusflag!!.toString())
if(it.registerOrPair!=null)
xml.attr("registers", it.registerOrPair!!.toString())
xml.endElt()
}
xml.endElt()
}
}
private fun write(constant: PtConstant) {
xml.writeTextNode("const",
listOf(
Pair("name", constant.scopedName.joinToString(".")),
Pair("type", constant.type.name)
),
intOrDouble(constant.type, constant.value).toString(), false)
}
private fun write(variable: PtVariable) {
// the variable declaration nodes are still present in the Ast,
// but the Symboltable should be used look up their details.
xml.elt("vardecl")
xml.attr("name", variable.scopedName.joinToString("."))
xml.attr("type", variable.type.name)
if(variable.arraySize!=null)
xml.attr("arraysize", variable.arraySize.toString())
if(variable.value!=null) {
// static initialization value
xml.startChildren()
writeNode(variable.value!!)
}
xml.endElt()
}
private fun strTargetName(ident: PtIdentifier): String = ident.targetName.joinToString(".")
private fun strTargetName(call: PtFunctionCall): String = call.functionName.joinToString(".")
private fun intOrDouble(type: DataType, value: Double): Number =
if(type in IntegerDatatypes) value.toInt() else value
}

30
codeGenExperimental/src/prog8/codegen/experimental/CodeGen.kt Normal file
View File

@ -0,0 +1,30 @@
package prog8.codegen.experimental
import prog8.code.SymbolTable
import prog8.code.ast.PtProgram
import prog8.code.core.CompilationOptions
import prog8.code.core.IAssemblyGenerator
import prog8.code.core.IAssemblyProgram
import prog8.code.core.IErrorReporter
import prog8.codegen.intermediate.IRCodeGen
import prog8.intermediate.IRFileWriter
class CodeGen(private val program: PtProgram,
private val symbolTable: SymbolTable,
private val options: CompilationOptions,
private val errors: IErrorReporter
): IAssemblyGenerator {
override fun compileToAssembly(): IAssemblyProgram? {
// you could write a code generator directly on the PtProgram AST,
// but you can also use the Intermediate Representation to build a codegen on:
val irCodeGen = IRCodeGen(program, symbolTable, options, errors)
val irProgram = irCodeGen.generate()
// this stub only writes the IR program to disk but doesn't generate anything else.
IRFileWriter(irProgram, null).write()
println("** experimental codegen stub: no assembly generated **")
return null
}
}

89
codeGenExperimental/src/prog8/codegen/experimental/IndentingXmlWriter.kt
View File

@ -1,89 +0,0 @@
package prog8.codegen.experimental
import prog8.code.core.Position
import java.util.*
import javax.xml.stream.XMLStreamWriter
class IndentingXmlWriter(val xml: XMLStreamWriter): XMLStreamWriter by xml {
private var indent = 0
private var content = Stack<Boolean>()
fun doc(version: String? = null) = if(version==null) writeStartDocument() else writeStartDocument(version)
fun endDoc() = writeEndDocument()
fun elt(name: String) = writeStartElement(name)
fun attr(name: String, value: String) = writeAttribute(name, value)
fun attrs(attributes: List<Pair<String, String>>) = attributes.forEach { writeAttribute(it.first, it.second) }
fun startChildren() {
xml.writeCharacters("\n")
content.pop()
content.push(true)
}
fun endElt(writeIndent: Boolean=true) = writeEndElement(writeIndent)
fun pos(pos: Position) = writeAttribute("src", pos.toString())
fun comment(text: String) {
writeComment(text)
writeCharacters("\n")
}
override fun writeStartDocument() {
xml.writeStartDocument()
xml.writeCharacters("\n")
content.push(true)
}
override fun writeStartDocument(version: String) {
xml.writeStartDocument(version)
xml.writeCharacters("\n")
content.push(true)
}
override fun writeEndDocument() {
xml.writeEndDocument()
xml.writeCharacters("\n")
require(indent==0)
require(content.size==1)
}
override fun writeStartElement(name: String) {
xml.writeCharacters(" ".repeat(indent))
xml.writeStartElement(name)
indent++
content.push(false)
}
override fun writeStartElement(name: String, ns: String) {
xml.writeCharacters(" ".repeat(indent))
xml.writeStartElement(name, ns)
indent++
content.push(false)
}
fun writeEndElement(writeIndents: Boolean) {
indent--
if(content.pop() && writeIndents)
xml.writeCharacters(" ".repeat(indent))
xml.writeEndElement()
xml.writeCharacters("\n")
}
override fun writeEndElement() = writeEndElement(true)
override fun writeStartElement(name: String, ns: String, p2: String) {
xml.writeCharacters(" ".repeat(indent))
xml.writeStartElement(name, ns, p2)
indent++
content.push(false)
}
fun writeTextNode(name: String, attrs: List<Pair<String, String>>, text: String, cdata: Boolean = true) {
xml.writeCharacters(" ".repeat(indent))
xml.writeStartElement(name)
attrs.forEach { (name, value) -> xml.writeAttribute(name, value) }
if(cdata)
xml.writeCData(text)
else
xml.writeCharacters(text)
xml.writeEndElement()
xml.writeCharacters("\n")
}
}

6
codeGenVirtual/build.gradle → codeGenIntermediate/build.gradle
View File

@ -3,7 +3,6 @@ plugins {
id 'java'
id 'application'
id "org.jetbrains.kotlin.jvm"
id "io.kotest" version "0.3.9"
}
java {
@ -25,9 +24,8 @@ compileTestKotlin {
}
dependencies {
implementation project(':codeAst')
implementation project(':codeCore')
implementation project(':virtualmachine')
implementation project(':intermediate')
implementation "org.jetbrains.kotlin:kotlin-stdlib-jdk8"
// implementation "org.jetbrains.kotlin:kotlin-reflect"
implementation "com.michael-bull.kotlin-result:kotlin-result-jvm:1.1.16"
@ -62,4 +60,4 @@ test {
testLogging {
events "skipped", "failed"
}
}
}

7
codeGenVirtual/codeGenVirtual.iml → codeGenIntermediate/codeGenIntermediate.iml
View File

@ -5,15 +5,14 @@
<content url="file://$MODULE_DIR$">
<sourceFolder url="file://$MODULE_DIR$/src" isTestSource="false" />
<sourceFolder url="file://$MODULE_DIR$/test" isTestSource="true" />
<excludeFolder url="file://$MODULE_DIR$/build" />
</content>
<orderEntry type="inheritedJdk" />
<orderEntry type="sourceFolder" forTests="false" />
<orderEntry type="library" name="KotlinJavaRuntime" level="project" />
<orderEntry type="library" name="michael.bull.kotlin.result.jvm" level="project" />
<orderEntry type="module" module-name="codeCore" />
<orderEntry type="module" module-name="intermediate" />
<orderEntry type="library" name="io.kotest.assertions.core.jvm" level="project" />
<orderEntry type="library" name="io.kotest.runner.junit5.jvm" level="project" />
<orderEntry type="module" module-name="codeAst" />
<orderEntry type="module" module-name="codeCore" />
<orderEntry type="module" module-name="virtualmachine" />
</component>
</module>

298
codeGenIntermediate/src/prog8/codegen/intermediate/AssignmentGen.kt Normal file
View File

@ -0,0 +1,298 @@
package prog8.codegen.intermediate
import prog8.code.ast.*
import prog8.code.core.AssemblyError
import prog8.code.core.DataType
import prog8.code.core.SignedDatatypes
import prog8.intermediate.*
internal class AssignmentGen(private val codeGen: IRCodeGen, private val expressionEval: ExpressionGen) {
internal fun translate(assignment: PtAssignment): IRCodeChunks {
if(assignment.target.children.single() is PtMachineRegister)
throw AssemblyError("assigning to a register should be done by just evaluating the expression into resultregister")
return if (assignment.isInplaceAssign)
translateInplaceAssign(assignment)
else
translateRegularAssign(assignment)
}
private fun translateInplaceAssign(assignment: PtAssignment): IRCodeChunks {
val ident = assignment.target.identifier
val memory = assignment.target.memory
val array = assignment.target.array
return if(ident!=null) {
assignSelfInMemory(ident.targetName.joinToString("."), assignment.value, assignment)
} else if(memory != null) {
if(memory.address is PtNumber)
assignSelfInMemoryKnownAddress((memory.address as PtNumber).number.toInt(), assignment.value, assignment)
else
fallbackAssign(assignment)
} else if(array!=null) {
// NOTE: naive fallback assignment here will sometimes generate code that loads the index value multiple times
// in a register. It's way too much work to optimize that here - instead, we trust that the generated IL assembly
// will be optimized later and have the double assignments removed.
fallbackAssign(assignment)
} else {
fallbackAssign(assignment)
}
}
private fun assignSelfInMemoryKnownAddress(
address: Int,
value: PtExpression,
origAssign: PtAssignment
): IRCodeChunks {
val vmDt = codeGen.irType(value.type)
when(value) {
is PtIdentifier -> return emptyList() // do nothing, x=x null assignment.
is PtMachineRegister -> return emptyList() // do nothing, reg=reg null assignment
is PtPrefix -> return inplacePrefix(value.operator, vmDt, address, null)
is PtBinaryExpression -> return inplaceBinexpr(value.operator, value.right, vmDt, value.type in SignedDatatypes, address, null, origAssign)
is PtMemoryByte -> {
return if (!codeGen.options.compTarget.machine.isIOAddress(address.toUInt()))
emptyList() // do nothing, mem=mem null assignment.
else {
// read and write a (i/o) memory location to itself.
val tempReg = codeGen.registers.nextFree()
val code = IRCodeChunk(null, null)
code += IRInstruction(Opcode.LOADM, vmDt, reg1 = tempReg, value = address)
code += IRInstruction(Opcode.STOREM, vmDt, reg1 = tempReg, value = address)
listOf(code)
}
}
else -> return fallbackAssign(origAssign)
}
}
private fun assignSelfInMemory(
symbol: String,
value: PtExpression,
origAssign: PtAssignment
): IRCodeChunks {
val vmDt = codeGen.irType(value.type)
return when(value) {
is PtIdentifier -> emptyList() // do nothing, x=x null assignment.
is PtMachineRegister -> emptyList() // do nothing, reg=reg null assignment
is PtPrefix -> inplacePrefix(value.operator, vmDt, null, symbol)
is PtBinaryExpression -> inplaceBinexpr(value.operator, value.right, vmDt, value.type in SignedDatatypes, null, symbol, origAssign)
is PtMemoryByte -> {
val code = IRCodeChunk(null, null)
val tempReg = codeGen.registers.nextFree()
code += IRInstruction(Opcode.LOADM, vmDt, reg1 = tempReg, labelSymbol = symbol)
code += IRInstruction(Opcode.STOREM, vmDt, reg1 = tempReg, labelSymbol = symbol)
listOf(code)
}
else -> fallbackAssign(origAssign)
}
}
private fun fallbackAssign(origAssign: PtAssignment): IRCodeChunks {
if (codeGen.options.slowCodegenWarnings)
codeGen.errors.warn("indirect code for in-place assignment", origAssign.position)
return translateRegularAssign(origAssign)
}
private fun inplaceBinexpr(
operator: String,
operand: PtExpression,
vmDt: IRDataType,
signed: Boolean,
knownAddress: Int?,
symbol: String?,
origAssign: PtAssignment
): IRCodeChunks {
if(knownAddress!=null) {
when (operator) {
"+" -> return expressionEval.operatorPlusInplace(knownAddress, null, vmDt, operand)
"-" -> return expressionEval.operatorMinusInplace(knownAddress, null, vmDt, operand)
"*" -> return expressionEval.operatorMultiplyInplace(knownAddress, null, vmDt, operand)
"/" -> return expressionEval.operatorDivideInplace(knownAddress, null, vmDt, signed, operand)
"|" -> return expressionEval.operatorOrInplace(knownAddress, null, vmDt, operand)
"&" -> return expressionEval.operatorAndInplace(knownAddress, null, vmDt, operand)
"^" -> return expressionEval.operatorXorInplace(knownAddress, null, vmDt, operand)
"<<" -> return expressionEval.operatorShiftLeftInplace(knownAddress, null, vmDt, operand)
">>" -> return expressionEval.operatorShiftRightInplace(knownAddress, null, vmDt, signed, operand)
else -> {}
}
} else {
symbol!!
when (operator) {
"+" -> return expressionEval.operatorPlusInplace(null, symbol, vmDt, operand)
"-" -> return expressionEval.operatorMinusInplace(null, symbol, vmDt, operand)
"*" -> return expressionEval.operatorMultiplyInplace(null, symbol, vmDt, operand)
"/" -> return expressionEval.operatorDivideInplace(null, symbol, vmDt, signed, operand)
"|" -> return expressionEval.operatorOrInplace(null, symbol, vmDt, operand)
"&" -> return expressionEval.operatorAndInplace(null, symbol, vmDt, operand)
"^" -> return expressionEval.operatorXorInplace(null, symbol, vmDt, operand)
"<<" -> return expressionEval.operatorShiftLeftInplace(null, symbol, vmDt, operand)
">>" -> return expressionEval.operatorShiftRightInplace(null, symbol, vmDt, signed, operand)
else -> {}
}
}
return fallbackAssign(origAssign)
}
private fun inplacePrefix(operator: String, vmDt: IRDataType, knownAddress: Int?, addressSymbol: String?): IRCodeChunks {
val code= IRCodeChunk(null, null)
when(operator) {
"+" -> { }
"-" -> {
code += if(knownAddress!=null)
IRInstruction(Opcode.NEGM, vmDt, value = knownAddress)
else
IRInstruction(Opcode.NEGM, vmDt, labelSymbol = addressSymbol)
}
"~" -> {
val regMask = codeGen.registers.nextFree()
val mask = if(vmDt==IRDataType.BYTE) 0x00ff else 0xffff
code += IRInstruction(Opcode.LOAD, vmDt, reg1=regMask, value = mask)
code += if(knownAddress!=null)
IRInstruction(Opcode.XORM, vmDt, reg1=regMask, value = knownAddress)
else
IRInstruction(Opcode.XORM, vmDt, reg1=regMask, labelSymbol = addressSymbol)
}
else -> throw AssemblyError("weird prefix operator")
}
return listOf(code)
}
private fun translateRegularAssign(assignment: PtAssignment): IRCodeChunks {
// note: assigning array and string values is done via an explicit memcopy/stringcopy function call.
val ident = assignment.target.identifier
val memory = assignment.target.memory
val array = assignment.target.array
val vmDt = codeGen.irType(assignment.value.type)
val result = mutableListOf<IRCodeChunkBase>()
var resultRegister = -1
var resultFpRegister = -1
val zero = codeGen.isZero(assignment.value)
if(!zero) {
// calculate the assignment value
if (vmDt == IRDataType.FLOAT) {
resultFpRegister = codeGen.registers.nextFreeFloat()
result += expressionEval.translateExpression(assignment.value, -1, resultFpRegister)
} else {
resultRegister = if (assignment.value is PtMachineRegister) {
(assignment.value as PtMachineRegister).register
} else {
val reg = codeGen.registers.nextFree()
result += expressionEval.translateExpression(assignment.value, reg, -1)
reg
}
}
}
if(ident!=null) {
val symbol = ident.targetName.joinToString(".")
val instruction = if(zero) {
IRInstruction(Opcode.STOREZM, vmDt, labelSymbol = symbol)
} else {
if (vmDt == IRDataType.FLOAT)
IRInstruction(Opcode.STOREM, vmDt, fpReg1 = resultFpRegister, labelSymbol = symbol)
else
IRInstruction(Opcode.STOREM, vmDt, reg1 = resultRegister, labelSymbol = symbol)
}
result += IRCodeChunk(null, null).also { it += instruction }
return result
}
else if(array!=null) {
val variable = array.variable.targetName.joinToString(".")
val itemsize = codeGen.program.memsizer.memorySize(array.type)
if(array.variable.type==DataType.UWORD) {
// indexing a pointer var instead of a real array or string
if(itemsize!=1)
throw AssemblyError("non-array var indexing requires bytes dt")
if(array.index.type!=DataType.UBYTE)
throw AssemblyError("non-array var indexing requires bytes index")
val idxReg = codeGen.registers.nextFree()
result += expressionEval.translateExpression(array.index, idxReg, -1)
val code = IRCodeChunk(null, null)
if(zero) {
// there's no STOREZIX instruction
resultRegister = codeGen.registers.nextFree()
code += IRInstruction(Opcode.LOAD, vmDt, reg1=resultRegister, value=0)
}
code += IRInstruction(Opcode.STOREIX, vmDt, reg1=resultRegister, reg2=idxReg, labelSymbol = variable)
result += code
return result
}
val fixedIndex = constIntValue(array.index)
if(zero) {
if(fixedIndex!=null) {
val offset = fixedIndex*itemsize
val chunk = IRCodeChunk(null, null).also { it += IRInstruction(Opcode.STOREZM, vmDt, labelSymbol = "$variable+$offset") }
result += chunk
} else {
val indexReg = codeGen.registers.nextFree()
result += loadIndexReg(array, itemsize, indexReg)
result += IRCodeChunk(null, null).also { it += IRInstruction(Opcode.STOREZX, vmDt, reg1=indexReg, labelSymbol = variable) }
}
} else {
if(vmDt== IRDataType.FLOAT) {
if(fixedIndex!=null) {
val offset = fixedIndex*itemsize
val chunk = IRCodeChunk(null, null).also { it += IRInstruction(Opcode.STOREM, vmDt, fpReg1 = resultFpRegister, labelSymbol = "$variable+$offset") }
result += chunk
} else {
val indexReg = codeGen.registers.nextFree()
result += loadIndexReg(array, itemsize, indexReg)
result += IRCodeChunk(null, null).also { it += IRInstruction(Opcode.STOREX, vmDt, reg1 = indexReg, fpReg1 = resultFpRegister, labelSymbol = variable) }
}
} else {
if(fixedIndex!=null) {
val offset = fixedIndex*itemsize
val chunk = IRCodeChunk(null, null).also { it += IRInstruction(Opcode.STOREM, vmDt, reg1 = resultRegister, labelSymbol = "$variable+$offset") }
result += chunk
} else {
val indexReg = codeGen.registers.nextFree()
result += loadIndexReg(array, itemsize, indexReg)
result += IRCodeChunk(null, null).also { it += IRInstruction(Opcode.STOREX, vmDt, reg1 = resultRegister, reg2=indexReg, labelSymbol = variable) }
}
}
}
return result
}
else if(memory!=null) {
require(vmDt== IRDataType.BYTE) { "must be byte type ${memory.position}"}
if(zero) {
if(memory.address is PtNumber) {
val chunk = IRCodeChunk(null, null).also { it += IRInstruction(Opcode.STOREZM, vmDt, value=(memory.address as PtNumber).number.toInt()) }
result += chunk
} else {
val addressReg = codeGen.registers.nextFree()
result += expressionEval.translateExpression(memory.address, addressReg, -1)
result += IRCodeChunk(null, null).also { it += IRInstruction(Opcode.STOREZI, vmDt, reg1=addressReg) }
}
} else {
if(memory.address is PtNumber) {
val chunk = IRCodeChunk(null, null).also { it += IRInstruction(Opcode.STOREM, vmDt, reg1=resultRegister, value=(memory.address as PtNumber).number.toInt()) }
result += chunk
} else {
val addressReg = codeGen.registers.nextFree()
result += expressionEval.translateExpression(memory.address, addressReg, -1)
result += IRCodeChunk(null, null).also { it += IRInstruction(Opcode.STOREI, vmDt, reg1=resultRegister, reg2=addressReg) }
}
}
return result
}
else
throw AssemblyError("weird assigntarget")
}
private fun loadIndexReg(array: PtArrayIndexer, itemsize: Int, indexReg: Int): IRCodeChunks {
return if(itemsize==1) {
expressionEval.translateExpression(array.index, indexReg, -1)
} else {
val mult = PtBinaryExpression("*", DataType.UBYTE, array.position)
mult.children += array.index
mult.children += PtNumber(DataType.UBYTE, itemsize.toDouble(), array.position)
expressionEval.translateExpression(mult, indexReg, -1)
}
}
}

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codeGenIntermediate/src/prog8/codegen/intermediate/BuiltinFuncGen.kt Normal file
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package prog8.codegen.intermediate
import prog8.code.StStaticVariable
import prog8.code.ast.*
import prog8.code.core.AssemblyError
import prog8.code.core.DataType
import prog8.intermediate.*
internal class BuiltinFuncGen(private val codeGen: IRCodeGen, private val exprGen: ExpressionGen) {
fun translate(call: PtBuiltinFunctionCall, resultRegister: Int): IRCodeChunks {
return when(call.name) {
"any" -> funcAny(call, resultRegister)
"all" -> funcAll(call, resultRegister)
"abs" -> funcAbs(call, resultRegister)
"cmp" -> funcCmp(call)
"sgn" -> funcSgn(call, resultRegister)
"sqrt16" -> funcSqrt16(call, resultRegister)
"pop" -> funcPop(call)
"popw" -> funcPopw(call)
"push" -> funcPush(call)
"pushw" -> funcPushw(call)
"rsave",
"rsavex",
"rrestore",
"rrestorex" -> emptyList() // vm doesn't have registers to save/restore
"callfar" -> throw AssemblyError("callfar() is for cx16 target only")
"callrom" -> throw AssemblyError("callrom() is for cx16 target only")
"msb" -> funcMsb(call, resultRegister)
"lsb" -> funcLsb(call, resultRegister)
"memory" -> funcMemory(call, resultRegister)
"peek" -> funcPeek(call, resultRegister)
"peekw" -> funcPeekW(call, resultRegister)
"poke" -> funcPoke(call)
"pokew" -> funcPokeW(call)
"pokemon" -> emptyList()
"mkword" -> funcMkword(call, resultRegister)
"sort" -> funcSort(call)
"reverse" -> funcReverse(call)
"rol" -> funcRolRor(Opcode.ROXL, call, resultRegister)
"ror" -> funcRolRor(Opcode.ROXR, call, resultRegister)
"rol2" -> funcRolRor(Opcode.ROL, call, resultRegister)
"ror2" -> funcRolRor(Opcode.ROR, call, resultRegister)
else -> throw AssemblyError("missing builtinfunc for ${call.name}")
}
}
private fun funcCmp(call: PtBuiltinFunctionCall): IRCodeChunks {
val leftRegister = codeGen.registers.nextFree()
val rightRegister = codeGen.registers.nextFree()
val result = mutableListOf<IRCodeChunkBase>()
result += exprGen.translateExpression(call.args[0], leftRegister, -1)
result += exprGen.translateExpression(call.args[1], rightRegister, -1)
result += IRCodeChunk(null, null).also {
it += IRInstruction(Opcode.CMP, codeGen.irType(call.args[0].type), reg1=leftRegister, reg2=rightRegister)
}
return result
}
private fun funcAny(call: PtBuiltinFunctionCall, resultRegister: Int): IRCodeChunks {
val arrayName = call.args[0] as PtIdentifier
val array = codeGen.symbolTable.flat.getValue(arrayName.targetName) as StStaticVariable
val syscall =
when (array.dt) {
DataType.ARRAY_UB,
DataType.ARRAY_B -> IMSyscall.ANY_BYTE
DataType.ARRAY_UW,
DataType.ARRAY_W -> IMSyscall.ANY_WORD
DataType.ARRAY_F -> IMSyscall.ANY_FLOAT
else -> throw IllegalArgumentException("weird type")
}
val result = mutableListOf<IRCodeChunkBase>()
result += exprGen.translateExpression(call.args[0], SyscallRegisterBase, -1)
result += IRCodeChunk(null, null).also {
it += IRInstruction(Opcode.LOAD, IRDataType.BYTE, reg1 = SyscallRegisterBase+1, value = array.length)
it += IRInstruction(Opcode.SYSCALL, value = syscall.number)
if(resultRegister!=0)
it += IRInstruction(Opcode.LOADR, IRDataType.BYTE, reg1 = resultRegister, reg2 = 0)
}
return result
}
private fun funcAll(call: PtBuiltinFunctionCall, resultRegister: Int): IRCodeChunks {
val arrayName = call.args[0] as PtIdentifier
val array = codeGen.symbolTable.flat.getValue(arrayName.targetName) as StStaticVariable
val syscall =
when(array.dt) {
DataType.ARRAY_UB,
DataType.ARRAY_B -> IMSyscall.ALL_BYTE
DataType.ARRAY_UW,
DataType.ARRAY_W -> IMSyscall.ALL_WORD
DataType.ARRAY_F -> IMSyscall.ALL_FLOAT
else -> throw IllegalArgumentException("weird type")
}
val result = mutableListOf<IRCodeChunkBase>()
result += exprGen.translateExpression(call.args[0], SyscallRegisterBase, -1)
result += IRCodeChunk(null, null).also {
it += IRInstruction(Opcode.LOAD, IRDataType.BYTE, reg1 = SyscallRegisterBase+1, value = array.length)
it += IRInstruction(Opcode.SYSCALL, value = syscall.number)
if(resultRegister!=0)
it += IRInstruction(Opcode.LOADR, IRDataType.BYTE, reg1 = resultRegister, reg2 = 0)
}
return result
}
private fun funcAbs(call: PtBuiltinFunctionCall, resultRegister: Int): IRCodeChunks {
val sourceDt = call.args.single().type
val result = mutableListOf<IRCodeChunkBase>()
if(sourceDt!=DataType.UWORD) {
result += exprGen.translateExpression(call.args[0], resultRegister, -1)
when (sourceDt) {
DataType.UBYTE -> {
result += IRCodeChunk(null, null).also {
it += IRInstruction(Opcode.EXT, IRDataType.BYTE, reg1 = resultRegister)
}
}
DataType.BYTE -> {
val notNegativeLabel = codeGen.createLabelName()
val compareReg = codeGen.registers.nextFree()
result += IRCodeChunk(null, null).also {
it += IRInstruction(Opcode.LOADR, IRDataType.BYTE, reg1=compareReg, reg2=resultRegister)
it += IRInstruction(Opcode.AND, IRDataType.BYTE, reg1=compareReg, value=0x80)
it += IRInstruction(Opcode.BZ, IRDataType.BYTE, reg1=compareReg, labelSymbol = notNegativeLabel)
it += IRInstruction(Opcode.NEG, IRDataType.BYTE, reg1=resultRegister)
it += IRInstruction(Opcode.EXT, IRDataType.BYTE, reg1=resultRegister)
}
result += IRCodeChunk(notNegativeLabel, null)
}
DataType.WORD -> {
val notNegativeLabel = codeGen.createLabelName()
val compareReg = codeGen.registers.nextFree()
result += IRCodeChunk(null, null).also {
it += IRInstruction(Opcode.LOADR, IRDataType.WORD, reg1=compareReg, reg2=resultRegister)
it += IRInstruction(Opcode.AND, IRDataType.WORD, reg1=compareReg, value=0x8000)
it += IRInstruction(Opcode.BZ, IRDataType.WORD, reg1=compareReg, labelSymbol = notNegativeLabel)
it += IRInstruction(Opcode.NEG, IRDataType.WORD, reg1=resultRegister)
}
result += IRCodeChunk(notNegativeLabel, null)
}
else -> throw AssemblyError("weird type")
}
}
return result
}
private fun funcSgn(call: PtBuiltinFunctionCall, resultRegister: Int): IRCodeChunks {
val reg = codeGen.registers.nextFree()
val result = mutableListOf<IRCodeChunkBase>()
result += exprGen.translateExpression(call.args.single(), reg, -1)
result += IRCodeChunk(null, null).also {
it += IRInstruction(Opcode.SGN, codeGen.irType(call.type), reg1 = resultRegister, reg2 = reg)
}
return result
}
private fun funcSqrt16(call: PtBuiltinFunctionCall, resultRegister: Int): IRCodeChunks {
val reg = codeGen.registers.nextFree()
val result = mutableListOf<IRCodeChunkBase>()
result += exprGen.translateExpression(call.args.single(), reg, -1)
result += IRCodeChunk(null, null).also {
it += IRInstruction(Opcode.SQRT, IRDataType.WORD, reg1=resultRegister, reg2=reg)
}
return result
}
private fun funcPop(call: PtBuiltinFunctionCall): IRCodeChunks {
val code = IRCodeChunk(null, null)
val reg = codeGen.registers.nextFree()
code += IRInstruction(Opcode.POP, IRDataType.BYTE, reg1=reg)
val result = mutableListOf<IRCodeChunkBase>(code)
result += assignRegisterTo(call.args.single(), reg)
return result
}
private fun funcPopw(call: PtBuiltinFunctionCall): IRCodeChunks {
val code = IRCodeChunk(null, null)
val reg = codeGen.registers.nextFree()
code += IRInstruction(Opcode.POP, IRDataType.WORD, reg1=reg)
val result = mutableListOf<IRCodeChunkBase>(code)
result += assignRegisterTo(call.args.single(), reg)
return result
}
private fun funcPush(call: PtBuiltinFunctionCall): IRCodeChunks {
val result = mutableListOf<IRCodeChunkBase>()
val reg = codeGen.registers.nextFree()
result += exprGen.translateExpression(call.args.single(), reg, -1)
result += IRCodeChunk(null, null).also {
it += IRInstruction(Opcode.PUSH, IRDataType.BYTE, reg1=reg)
}
return result
}
private fun funcPushw(call: PtBuiltinFunctionCall): IRCodeChunks {
val result = mutableListOf<IRCodeChunkBase>()
val reg = codeGen.registers.nextFree()
result += exprGen.translateExpression(call.args.single(), reg, -1)
result += IRCodeChunk(null, null).also {
it += IRInstruction(Opcode.PUSH, IRDataType.WORD, reg1 = reg)
}
return result
}
private fun funcReverse(call: PtBuiltinFunctionCall): IRCodeChunks {
val arrayName = call.args[0] as PtIdentifier
val array = codeGen.symbolTable.flat.getValue(arrayName.targetName) as StStaticVariable
val syscall =
when(array.dt) {
DataType.ARRAY_UB, DataType.ARRAY_B, DataType.STR -> IMSyscall.REVERSE_BYTES
DataType.ARRAY_UW, DataType.ARRAY_W -> IMSyscall.REVERSE_WORDS
DataType.ARRAY_F -> IMSyscall.REVERSE_FLOATS
else -> throw IllegalArgumentException("weird type to reverse")
}
val result = mutableListOf<IRCodeChunkBase>()
result += exprGen.translateExpression(call.args[0], SyscallRegisterBase, -1)
result += IRCodeChunk(null, null).also {
it += IRInstruction(Opcode.LOAD, IRDataType.BYTE, reg1 = SyscallRegisterBase+1, value = array.length)
it += IRInstruction(Opcode.SYSCALL, value = syscall.number)
}
return result
}
private fun funcSort(call: PtBuiltinFunctionCall): IRCodeChunks {
val arrayName = call.args[0] as PtIdentifier
val array = codeGen.symbolTable.flat.getValue(arrayName.targetName) as StStaticVariable
val syscall =
when(array.dt) {
DataType.ARRAY_UB -> IMSyscall.SORT_UBYTE
DataType.ARRAY_B -> IMSyscall.SORT_BYTE
DataType.ARRAY_UW -> IMSyscall.SORT_UWORD
DataType.ARRAY_W -> IMSyscall.SORT_WORD
DataType.STR -> IMSyscall.SORT_UBYTE
DataType.ARRAY_F -> throw IllegalArgumentException("sorting a floating point array is not supported")
else -> throw IllegalArgumentException("weird type to sort")
}
val result = mutableListOf<IRCodeChunkBase>()
result += exprGen.translateExpression(call.args[0], SyscallRegisterBase, -1)
result += IRCodeChunk(null, null).also {
it += IRInstruction(Opcode.LOAD, IRDataType.BYTE, reg1 = SyscallRegisterBase+1, value = array.length)
it += IRInstruction(Opcode.SYSCALL, value = syscall.number)
}
return result
}
private fun funcMkword(call: PtBuiltinFunctionCall, resultRegister: Int): IRCodeChunks {
val msbReg = codeGen.registers.nextFree()
val result = mutableListOf<IRCodeChunkBase>()
result += exprGen.translateExpression(call.args[0], msbReg, -1)
result += exprGen.translateExpression(call.args[1], resultRegister, -1)
result += IRCodeChunk(null, null).also {
it += IRInstruction(Opcode.CONCAT, IRDataType.BYTE, reg1 = resultRegister, reg2 = msbReg)
}
return result
}
private fun funcPokeW(call: PtBuiltinFunctionCall): IRCodeChunks {
val result = mutableListOf<IRCodeChunkBase>()
if(codeGen.isZero(call.args[1])) {
if (call.args[0] is PtNumber) {
val address = (call.args[0] as PtNumber).number.toInt()
result += IRCodeChunk(null, null).also {
it += IRInstruction(Opcode.STOREZM, IRDataType.WORD, value = address)
}
} else {
val addressReg = codeGen.registers.nextFree()
result += exprGen.translateExpression(call.args[0], addressReg, -1)
result += IRCodeChunk(null, null).also {
it += IRInstruction(Opcode.STOREZI, IRDataType.WORD, reg2 = addressReg)
}
}
} else {
val valueReg = codeGen.registers.nextFree()
if (call.args[0] is PtNumber) {
val address = (call.args[0] as PtNumber).number.toInt()
result += exprGen.translateExpression(call.args[1], valueReg, -1)
result += IRCodeChunk(null, null).also {
it += IRInstruction(Opcode.STOREM, IRDataType.WORD, reg1 = valueReg, value = address)
}
} else {
val addressReg = codeGen.registers.nextFree()
result += exprGen.translateExpression(call.args[0], addressReg, -1)
result += exprGen.translateExpression(call.args[1], valueReg, -1)
result += IRCodeChunk(null, null).also {
it += IRInstruction(Opcode.STOREI, IRDataType.WORD, reg1 = valueReg, reg2 = addressReg)
}
}
}
return result
}
private fun funcPoke(call: PtBuiltinFunctionCall): IRCodeChunks {
val result = mutableListOf<IRCodeChunkBase>()
if(codeGen.isZero(call.args[1])) {
if (call.args[0] is PtNumber) {
val address = (call.args[0] as PtNumber).number.toInt()
result += IRCodeChunk(null, null).also {
it += IRInstruction(Opcode.STOREZM, IRDataType.BYTE, value = address)
}
} else {
val addressReg = codeGen.registers.nextFree()
result += exprGen.translateExpression(call.args[0], addressReg, -1)
result += IRCodeChunk(null, null).also {
it += IRInstruction(Opcode.STOREZI, IRDataType.BYTE, reg2 = addressReg)
}
}
} else {
val valueReg = codeGen.registers.nextFree()
if (call.args[0] is PtNumber) {
val address = (call.args[0] as PtNumber).number.toInt()
result += exprGen.translateExpression(call.args[1], valueReg, -1)
result += IRCodeChunk(null, null).also {
it += IRInstruction(Opcode.STOREM, IRDataType.BYTE, reg1 = valueReg, value = address)
}
} else {
val addressReg = codeGen.registers.nextFree()
result += exprGen.translateExpression(call.args[0], addressReg, -1)
result += exprGen.translateExpression(call.args[1], valueReg, -1)
result += IRCodeChunk(null, null).also {
it += IRInstruction(Opcode.STOREI, IRDataType.BYTE, reg1 = valueReg, reg2 = addressReg)
}
}
}
return result
}
private fun funcPeekW(call: PtBuiltinFunctionCall, resultRegister: Int): IRCodeChunks {
val result = mutableListOf<IRCodeChunkBase>()
if(call.args[0] is PtNumber) {
val address = (call.args[0] as PtNumber).number.toInt()
result += IRCodeChunk(null, null).also {
it += IRInstruction(Opcode.LOADM, IRDataType.WORD, reg1 = resultRegister, value = address)
}
} else {
val addressReg = codeGen.registers.nextFree()
result += exprGen.translateExpression(call.args.single(), addressReg, -1)
result += IRCodeChunk(null, null).also {
it += IRInstruction(Opcode.LOADI, IRDataType.WORD, reg1 = resultRegister, reg2 = addressReg)
}
}
return result
}
private fun funcPeek(call: PtBuiltinFunctionCall, resultRegister: Int): IRCodeChunks {
val result = mutableListOf<IRCodeChunkBase>()
if(call.args[0] is PtNumber) {
val address = (call.args[0] as PtNumber).number.toInt()
result += IRCodeChunk(null, null).also {
it += IRInstruction(Opcode.LOADM, IRDataType.BYTE, reg1 = resultRegister, value = address)
}
} else {
val addressReg = codeGen.registers.nextFree()
result += exprGen.translateExpression(call.args.single(), addressReg, -1)
result += IRCodeChunk(null, null).also {
it += IRInstruction(Opcode.LOADI, IRDataType.BYTE, reg1 = resultRegister, reg2 = addressReg)
}
}
return result
}
private fun funcMemory(call: PtBuiltinFunctionCall, resultRegister: Int): IRCodeChunks {
val name = (call.args[0] as PtString).value
val code = IRCodeChunk(null, null)
code += IRInstruction(Opcode.LOAD, IRDataType.WORD, reg1=resultRegister, labelSymbol = "prog8_slabs.prog8_memoryslab_$name")
return listOf(code)
}
private fun funcLsb(call: PtBuiltinFunctionCall, resultRegister: Int): IRCodeChunks {
return exprGen.translateExpression(call.args.single(), resultRegister, -1)
// note: if a word result is needed, the upper byte is cleared by the typecast that follows. No need to do it here.
}
private fun funcMsb(call: PtBuiltinFunctionCall, resultRegister: Int): IRCodeChunks {
val result = mutableListOf<IRCodeChunkBase>()
result += exprGen.translateExpression(call.args.single(), resultRegister, -1)
result += IRCodeChunk(null, null).also {
it += IRInstruction(Opcode.MSIG, IRDataType.BYTE, reg1 = resultRegister, reg2 = resultRegister)
}
// note: if a word result is needed, the upper byte is cleared by the typecast that follows. No need to do it here.
return result
}
private fun funcRolRor(opcode: Opcode, call: PtBuiltinFunctionCall, resultRegister: Int): IRCodeChunks {
val vmDt = codeGen.irType(call.args[0].type)
val result = mutableListOf<IRCodeChunkBase>()
result += exprGen.translateExpression(call.args[0], resultRegister, -1)
result += IRCodeChunk(null, null).also {
it += IRInstruction(opcode, vmDt, reg1 = resultRegister)
}
result += assignRegisterTo(call.args[0], resultRegister)
return result
}
private fun assignRegisterTo(target: PtExpression, register: Int): IRCodeChunks {
val assignment = PtAssignment(target.position)
val assignTarget = PtAssignTarget(target.position)
assignTarget.children.add(target)
assignment.children.add(assignTarget)
assignment.children.add(PtMachineRegister(register, target.type, target.position))
val result = mutableListOf<IRCodeChunkBase>()
result += codeGen.translateNode(assignment)
return result
}
}

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codeGenIntermediate/src/prog8/codegen/intermediate/IRCodeGen.kt Normal file
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codeGenIntermediate/src/prog8/codegen/intermediate/IRPeepholeOptimizer.kt Normal file
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package prog8.codegen.intermediate
import prog8.intermediate.*
internal class IRPeepholeOptimizer(private val irprog: IRProgram) {
fun optimize() {
irprog.blocks.asSequence().flatMap { it.children.filterIsInstance<IRSubroutine>() }.forEach { sub ->
removeEmptyChunks(sub)
joinChunks(sub)
sub.chunks.withIndex().forEach { (index, chunk1) ->
// we don't optimize Inline Asm chunks here.
val chunk2 = if(index<sub.chunks.size-1) sub.chunks[index+1] else null
if(chunk1 is IRCodeChunk) {
do {
val indexedInstructions = chunk1.instructions.withIndex()
.map { IndexedValue(it.index, it.value) }
val changed = removeNops(chunk1, indexedInstructions)
|| removeDoubleLoadsAndStores(chunk1, indexedInstructions) // TODO not yet implemented
|| removeUselessArithmetic(chunk1, indexedInstructions)
|| removeWeirdBranches(chunk1, chunk2, indexedInstructions)
|| removeDoubleSecClc(chunk1, indexedInstructions)
|| cleanupPushPop(chunk1, indexedInstructions)
// TODO other optimizations:
// more complex optimizations such as unused registers
} while (changed)
}
}
removeEmptyChunks(sub)
}
irprog.linkChunks() // re-link
}
private fun removeEmptyChunks(sub: IRSubroutine) {
if(sub.chunks.isEmpty())
return
/*
Empty Code chunk with label ->
If next chunk has no label -> move label to next chunk, remove original
If next chunk has label -> label name should be the same, remove original. Otherwise FOR NOW leave it in place. (TODO: consolidate labels into 1)
If is last chunk -> keep chunk in place because of the label.
Empty Code chunk without label ->
should not have been generated! ERROR.
*/
val relabelChunks = mutableListOf<Pair<Int, String>>()
val removeChunks = mutableListOf<Int>()
sub.chunks.withIndex().forEach { (index, chunk) ->
if(chunk is IRCodeChunk && chunk.instructions.isEmpty()) {
if(chunk.label==null) {
removeChunks += index
} else {
if (index < sub.chunks.size - 1) {
val nextchunk = sub.chunks[index + 1]
if (nextchunk.label == null) {
// can transplant label to next chunk and remove this empty one.
relabelChunks += Pair(index + 1, chunk.label!!)
removeChunks += index
} else {
if (chunk.label == nextchunk.label)
removeChunks += index
else {
// TODO: consolidate labels on same chunk
}
}
}
}
}
}
relabelChunks.forEach { (index, label) ->
val chunk = IRCodeChunk(label, null)
chunk.instructions += sub.chunks[index].instructions
sub.chunks[index] = chunk
}
removeChunks.reversed().forEach { index -> sub.chunks.removeAt(index) }
}
private fun joinChunks(sub: IRSubroutine) {
// Subroutine contains a list of chunks. Some can be joined into one.
if(sub.chunks.isEmpty())
return
fun mayJoin(previous: IRCodeChunkBase, chunk: IRCodeChunkBase): Boolean {
if(chunk.label!=null)
return false
if(previous is IRCodeChunk && chunk is IRCodeChunk) {
// if the previous chunk doesn't end in a jump or a return, flow continues into the next chunk
val lastInstruction = previous.instructions.lastOrNull()
if(lastInstruction!=null)
return lastInstruction.opcode !in OpcodesThatJump
return true
}
return false
}
val chunks = mutableListOf<IRCodeChunkBase>()
chunks += sub.chunks[0]
for(ix in 1 until sub.chunks.size) {
val lastChunk = chunks.last()
if(mayJoin(lastChunk, sub.chunks[ix])) {
lastChunk.instructions += sub.chunks[ix].instructions
lastChunk.next = sub.chunks[ix].next
}
else
chunks += sub.chunks[ix]
}
sub.chunks.clear()
sub.chunks += chunks
}
private fun cleanupPushPop(chunk: IRCodeChunk, indexedInstructions: List<IndexedValue<IRInstruction>>): Boolean {
// push followed by pop to same target, or different target->replace with load
var changed = false
indexedInstructions.reversed().forEach { (idx, ins) ->
if(ins.opcode== Opcode.PUSH) {
if(idx < chunk.instructions.size-1) {
val insAfter = chunk.instructions[idx+1] as? IRInstruction
if(insAfter!=null && insAfter.opcode == Opcode.POP) {
if(ins.reg1==insAfter.reg1) {
chunk.instructions.removeAt(idx)
chunk.instructions.removeAt(idx)
} else {
chunk.instructions[idx] = IRInstruction(Opcode.LOADR, ins.type, reg1=insAfter.reg1, reg2=ins.reg1)
chunk.instructions.removeAt(idx+1)
}
changed = true
}
}
}
}
return changed
}
private fun removeDoubleSecClc(chunk: IRCodeChunk, indexedInstructions: List<IndexedValue<IRInstruction>>): Boolean {
// double sec, clc
// sec+clc or clc+sec
var changed = false
indexedInstructions.reversed().forEach { (idx, ins) ->
if(ins.opcode== Opcode.SEC || ins.opcode== Opcode.CLC) {
if(idx < chunk.instructions.size-1) {
val insAfter = chunk.instructions[idx+1] as? IRInstruction
if(insAfter?.opcode == ins.opcode) {
chunk.instructions.removeAt(idx)
changed = true
}
else if(ins.opcode== Opcode.SEC && insAfter?.opcode== Opcode.CLC) {
chunk.instructions.removeAt(idx)
changed = true
}
else if(ins.opcode== Opcode.CLC && insAfter?.opcode== Opcode.SEC) {
chunk.instructions.removeAt(idx)
changed = true
}
}
}
}
return changed
}
private fun removeWeirdBranches(chunk: IRCodeChunk, nextChunk: IRCodeChunkBase?, indexedInstructions: List<IndexedValue<IRInstruction>>): Boolean {
var changed = false
indexedInstructions.reversed().forEach { (idx, ins) ->
val labelSymbol = ins.labelSymbol
// remove jump/branch to label immediately below (= next chunk if it has that label)
if(ins.opcode== Opcode.JUMP && labelSymbol!=null) {
if(idx==chunk.instructions.size-1 && ins.branchTarget===nextChunk) {
chunk.instructions.removeAt(idx)
changed = true
}
}
// remove useless RETURN
if(ins.opcode == Opcode.RETURN && idx>0) {
val previous = chunk.instructions[idx-1] as? IRInstruction
if(previous?.opcode in OpcodesThatJump) {
chunk.instructions.removeAt(idx)
changed = true
}
}
}
return changed
}
private fun removeUselessArithmetic(chunk: IRCodeChunk, indexedInstructions: List<IndexedValue<IRInstruction>>): Boolean {
// note: this is hard to solve for the non-immediate instructions atm because the values are loaded into registers first
var changed = false
indexedInstructions.reversed().forEach { (idx, ins) ->
when (ins.opcode) {
Opcode.DIV, Opcode.DIVS, Opcode.MUL, Opcode.MOD -> {
if (ins.value == 1) {
chunk.instructions.removeAt(idx)
changed = true
}
}
Opcode.ADD, Opcode.SUB -> {
if (ins.value == 1) {
chunk.instructions[idx] = IRInstruction(
if (ins.opcode == Opcode.ADD) Opcode.INC else Opcode.DEC,
ins.type,
ins.reg1
)
changed = true
} else if (ins.value == 0) {
chunk.instructions.removeAt(idx)
changed = true
}
}
Opcode.AND -> {
if (ins.value == 0) {
chunk.instructions[idx] = IRInstruction(Opcode.LOAD, ins.type, reg1 = ins.reg1, value = 0)
changed = true
} else if (ins.value == 255 && ins.type == IRDataType.BYTE) {
chunk.instructions.removeAt(idx)
changed = true
} else if (ins.value == 65535 && ins.type == IRDataType.WORD) {
chunk.instructions.removeAt(idx)
changed = true
}
}
Opcode.OR -> {
if (ins.value == 0) {
chunk.instructions.removeAt(idx)
changed = true
} else if ((ins.value == 255 && ins.type == IRDataType.BYTE) || (ins.value == 65535 && ins.type == IRDataType.WORD)) {
chunk.instructions[idx] = IRInstruction(Opcode.LOAD, ins.type, reg1 = ins.reg1, value = ins.value)
changed = true
}
}
Opcode.XOR -> {
if (ins.value == 0) {
chunk.instructions.removeAt(idx)
changed = true
}
}
else -> {}
}
}
return changed
}
private fun removeNops(chunk: IRCodeChunk, indexedInstructions: List<IndexedValue<IRInstruction>>): Boolean {
var changed = false
indexedInstructions.reversed().forEach { (idx, ins) ->
if (ins.opcode == Opcode.NOP) {
changed = true
chunk.instructions.removeAt(idx)
}
}
return changed
}
private fun removeDoubleLoadsAndStores(chunk: IRCodeChunk, indexedInstructions: List<IndexedValue<IRInstruction>>): Boolean {
var changed = false
indexedInstructions.forEach { (idx, ins) ->
// TODO: detect multiple loads to the same target registers, only keep first (if source is not I/O memory)
// TODO: detect multiple stores to the same target, only keep first (if target is not I/O memory)
// TODO: detect multiple float ffrom/fto to the same target, only keep first
// TODO: detect multiple sequential rnd with same reg1, only keep one
// TODO: detect subsequent same xors/nots/negs, remove the pairs completely as they cancel out
// TODO: detect multiple same ands, ors; only keep first
// TODO: (hard) detect multiple registers being assigned the same value (and not changed) - use only 1 of them
// ...
}
return changed
}
}

123
codeGenIntermediate/src/prog8/codegen/intermediate/IRUnusedCodeRemover.kt Normal file
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package prog8.codegen.intermediate
import prog8.code.core.IErrorReporter
import prog8.code.core.SourceCode.Companion.libraryFilePrefix
import prog8.intermediate.*
internal class IRUnusedCodeRemover(private val irprog: IRProgram, private val errors: IErrorReporter) {
fun optimize(): Int {
val allLabeledChunks = mutableMapOf<String, IRCodeChunkBase>()
irprog.blocks.asSequence().flatMap { it.children.filterIsInstance<IRSubroutine>() }.forEach { sub ->
sub.chunks.forEach { chunk ->
chunk.label?.let { allLabeledChunks[it] = chunk }
}
}
var numRemoved = removeSimpleUnlinked(allLabeledChunks) + removeUnreachable(allLabeledChunks)
// remove empty subs
irprog.blocks.forEach { block ->
block.children.filterIsInstance<IRSubroutine>().reversed().forEach { sub ->
if(sub.isEmpty()) {
if(!sub.position.file.startsWith(libraryFilePrefix))
errors.warn("unused subroutine ${sub.label}", sub.position)
block.children.remove(sub)
numRemoved++
}
}
}
// remove empty blocks
irprog.blocks.reversed().forEach { block ->
if(block.isEmpty()) {
irprog.blocks.remove(block)
numRemoved++
}
}
return numRemoved
}
private fun removeUnreachable(allLabeledChunks: MutableMap<String, IRCodeChunkBase>): Int {
val entrypointSub = irprog.blocks.single { it.name=="main" }.children.single { it is IRSubroutine && it.label=="main.start" }
val reachable = mutableSetOf((entrypointSub as IRSubroutine).chunks.first())
fun grow() {
val new = mutableSetOf<IRCodeChunkBase>()
reachable.forEach {
it.next?.let { next -> new += next }
it.instructions.forEach { instr ->
if (instr.branchTarget == null)
instr.labelSymbol?.let { label -> allLabeledChunks[label]?.let { chunk -> new += chunk } }
else
new += instr.branchTarget!!
}
}
reachable += new
}
var previousCount = reachable.size
while(true) {
grow()
if(reachable.size<=previousCount)
break
previousCount = reachable.size
}
return removeUnlinkedChunks(reachable)
}
private fun removeSimpleUnlinked(allLabeledChunks: Map<String, IRCodeChunkBase>): Int {
val linkedChunks = mutableSetOf<IRCodeChunkBase>()
irprog.blocks.asSequence().flatMap { it.children.filterIsInstance<IRSubroutine>() }.forEach { sub ->
sub.chunks.forEach { chunk ->
chunk.next?.let { next -> linkedChunks += next }
chunk.instructions.forEach {
if(it.branchTarget==null) {
it.labelSymbol?.let { label -> allLabeledChunks[label]?.let { cc -> linkedChunks += cc } }
} else {
linkedChunks += it.branchTarget!!
}
}
if (chunk.label == "main.start")
linkedChunks += chunk
}
}
return removeUnlinkedChunks(linkedChunks)
}
private fun removeUnlinkedChunks(
linkedChunks: MutableSet<IRCodeChunkBase>
): Int {
var numRemoved = 0
irprog.blocks.asSequence().flatMap { it.children.filterIsInstance<IRSubroutine>() }.forEach { sub ->
sub.chunks.withIndex().reversed().forEach { (index, chunk) ->
if (chunk !in linkedChunks) {
if (chunk === sub.chunks[0]) {
when(chunk) {
is IRCodeChunk -> {
if (chunk.isNotEmpty()) {
// don't remove the first chunk of the sub itself because it has to have the name of the sub as label
chunk.instructions.clear()
numRemoved++
}
}
is IRInlineAsmChunk, is IRInlineBinaryChunk -> {
sub.chunks[index] = IRCodeChunk(chunk.label, chunk.next)
numRemoved++
}
}
} else {
sub.chunks.removeAt(index)
numRemoved++
}
}
}
}
return numRemoved
}
}

29
codeGenIntermediate/src/prog8/codegen/intermediate/RegisterPool.kt Normal file
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package prog8.codegen.intermediate
import prog8.code.core.AssemblyError
import prog8.intermediate.SyscallRegisterBase
internal class RegisterPool {
// reserve 0,1,2 for return values of subroutine calls and syscalls
private var firstFree: Int=3
private var firstFreeFloat: Int=3
fun peekNext() = firstFree
fun peekNextFloat() = firstFreeFloat
fun nextFree(): Int {
val result = firstFree
firstFree++
if(firstFree >= SyscallRegisterBase)
throw AssemblyError("out of virtual registers (int)")
return result
}
fun nextFreeFloat(): Int {
val result = firstFreeFloat
firstFreeFloat++
if(firstFreeFloat >= SyscallRegisterBase)
throw AssemblyError("out of virtual registers (fp)")
return result
}
}

35
codeGenIntermediate/src/prog8/codegen/vm/VmCodeGen.kt Normal file
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package prog8.codegen.vm
import prog8.code.SymbolTable
import prog8.code.ast.PtProgram
import prog8.code.core.CompilationOptions
import prog8.code.core.IAssemblyGenerator
import prog8.code.core.IAssemblyProgram
import prog8.code.core.IErrorReporter
import prog8.codegen.intermediate.IRCodeGen
import prog8.intermediate.IRFileWriter
import prog8.intermediate.IRProgram
class VmCodeGen(private val program: PtProgram,
private val symbolTable: SymbolTable,
private val options: CompilationOptions,
private val errors: IErrorReporter
): IAssemblyGenerator {
override fun compileToAssembly(): IAssemblyProgram? {
val irCodeGen = IRCodeGen(program, symbolTable, options, errors)
val irProgram = irCodeGen.generate()
return VmAssemblyProgram(irProgram.name, irProgram)
}
}
internal class VmAssemblyProgram(override val name: String, private val irProgram: IRProgram): IAssemblyProgram {
override fun assemble(options: CompilationOptions): Boolean {
// the VM reads the IR file from disk.
IRFileWriter(irProgram, null).write()
return true
}
}

7
codeGenVirtual/test/Dummies.kt → codeGenIntermediate/test/Dummies.kt
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@ -1,6 +1,7 @@
package prog8tests.vm.helpers
import prog8.code.core.*
import prog8.code.core.DataType
import prog8.code.core.Encoding
import prog8.code.core.IMemSizer
import prog8.code.core.IStringEncoding
internal object DummyMemsizer : IMemSizer {

189
codeGenIntermediate/test/TestIRPeepholeOpt.kt Normal file
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import io.kotest.core.spec.style.FunSpec
import io.kotest.matchers.shouldBe
import prog8.code.core.*
import prog8.code.target.VMTarget
import prog8.codegen.intermediate.IRPeepholeOptimizer
import prog8.intermediate.*
class TestIRPeepholeOpt: FunSpec({
fun makeIRProgram(chunks: List<IRCodeChunkBase>): IRProgram {
require(chunks.first().label=="main.start")
val block = IRBlock("main", null, IRBlock.BlockAlignment.NONE, Position.DUMMY)
val sub = IRSubroutine("main.start", emptyList(), null, Position.DUMMY)
chunks.forEach { sub += it }
block += sub
val target = VMTarget()
val options = CompilationOptions(
OutputType.RAW,
CbmPrgLauncherType.NONE,
ZeropageType.DONTUSE,
emptyList(),
floats = false,
noSysInit = true,
compTarget = target,
loadAddress = target.machine.PROGRAM_LOAD_ADDRESS
)
val prog = IRProgram("test", IRSymbolTable(null), options, target)
prog.addBlock(block)
prog.linkChunks()
prog.validate()
return prog
}
fun makeIRProgram(instructions: List<IRInstruction>): IRProgram {
val chunk = IRCodeChunk("main.start", null)
instructions.forEach { chunk += it }
return makeIRProgram(listOf(chunk))
}
fun IRProgram.chunks(): List<IRCodeChunkBase> = this.blocks.flatMap { it.children.filterIsInstance<IRSubroutine>() }.flatMap { it.chunks }
test("remove nops") {
val irProg = makeIRProgram(listOf(
IRInstruction(Opcode.LOAD, IRDataType.BYTE, reg1=1, value=42),
IRInstruction(Opcode.NOP),
IRInstruction(Opcode.NOP)
))
irProg.chunks().single().instructions.size shouldBe 3
val opt = IRPeepholeOptimizer(irProg)
opt.optimize()
irProg.chunks().single().instructions.size shouldBe 1
}
test("remove jmp to label below") {
val c1 = IRCodeChunk("main.start", null)
c1 += IRInstruction(Opcode.JUMP, labelSymbol = "label") // removed, but chunk stays because of label
val c2 = IRCodeChunk("label", null)
c2 += IRInstruction(Opcode.JUMP, labelSymbol = "label2") // removed, but chunk stays because of label
c2 += IRInstruction(Opcode.NOP) // removed
val c3 = IRCodeChunk("label2", null)
c3 += IRInstruction(Opcode.JUMP, labelSymbol = "label3")
c3 += IRInstruction(Opcode.INC, IRDataType.BYTE, reg1=1)
val c4 = IRCodeChunk("label3", null)
val irProg = makeIRProgram(listOf(c1, c2, c3, c4))
irProg.chunks().size shouldBe 4
irProg.chunks().flatMap { it.instructions }.size shouldBe 5
val opt = IRPeepholeOptimizer(irProg)
opt.optimize()
irProg.chunks().size shouldBe 4
irProg.chunks()[0].label shouldBe "main.start"
irProg.chunks()[1].label shouldBe "label"
irProg.chunks()[2].label shouldBe "label2"
irProg.chunks()[3].label shouldBe "label3"
irProg.chunks()[0].isEmpty() shouldBe true
irProg.chunks()[1].isEmpty() shouldBe true
irProg.chunks()[2].isEmpty() shouldBe false
irProg.chunks()[3].isEmpty() shouldBe true
val instr = irProg.chunks().flatMap { it.instructions }
instr.size shouldBe 2
instr[0].opcode shouldBe Opcode.JUMP
instr[1].opcode shouldBe Opcode.INC
}
test("remove double sec/clc") {
val irProg = makeIRProgram(listOf(
IRInstruction(Opcode.SEC),
IRInstruction(Opcode.SEC),
IRInstruction(Opcode.SEC),
IRInstruction(Opcode.CLC),
IRInstruction(Opcode.CLC),
IRInstruction(Opcode.CLC)
))
irProg.chunks().single().instructions.size shouldBe 6
val opt = IRPeepholeOptimizer(irProg)
opt.optimize()
val instr = irProg.chunks().single().instructions
instr.size shouldBe 1
instr[0].opcode shouldBe Opcode.CLC
}
test("push followed by pop") {
val irProg = makeIRProgram(listOf(
IRInstruction(Opcode.PUSH, IRDataType.BYTE, reg1=42),
IRInstruction(Opcode.POP, IRDataType.BYTE, reg1=42),
IRInstruction(Opcode.PUSH, IRDataType.BYTE, reg1=99),
IRInstruction(Opcode.POP, IRDataType.BYTE, reg1=222)
))
irProg.chunks().single().instructions.size shouldBe 4
val opt = IRPeepholeOptimizer(irProg)
opt.optimize()
val instr = irProg.chunks().single().instructions
instr.size shouldBe 1
instr[0].opcode shouldBe Opcode.LOADR
instr[0].reg1 shouldBe 222
instr[0].reg2 shouldBe 99
}
test("remove useless div/mul, add/sub") {
val irProg = makeIRProgram(listOf(
IRInstruction(Opcode.DIV, IRDataType.BYTE, reg1=42, value = 1),
IRInstruction(Opcode.DIVS, IRDataType.BYTE, reg1=42, value = 1),
IRInstruction(Opcode.MUL, IRDataType.BYTE, reg1=42, value = 1),
IRInstruction(Opcode.MOD, IRDataType.BYTE, reg1=42, value = 1),
IRInstruction(Opcode.DIV, IRDataType.BYTE, reg1=42, value = 2),
IRInstruction(Opcode.DIVS, IRDataType.BYTE, reg1=42, value = 2),
IRInstruction(Opcode.MUL, IRDataType.BYTE, reg1=42, value = 2),
IRInstruction(Opcode.MOD, IRDataType.BYTE, reg1=42, value = 2),
IRInstruction(Opcode.ADD, IRDataType.BYTE, reg1=42, value = 0),
IRInstruction(Opcode.SUB, IRDataType.BYTE, reg1=42, value = 0)
))
irProg.chunks().single().instructions.size shouldBe 10
val opt = IRPeepholeOptimizer(irProg)
opt.optimize()
irProg.chunks().single().instructions.size shouldBe 4
}
test("replace add/sub 1 by inc/dec") {
val irProg = makeIRProgram(listOf(
IRInstruction(Opcode.ADD, IRDataType.BYTE, reg1=42, value = 1),
IRInstruction(Opcode.SUB, IRDataType.BYTE, reg1=42, value = 1)
))
irProg.chunks().single().instructions.size shouldBe 2
val opt = IRPeepholeOptimizer(irProg)
opt.optimize()
val instr = irProg.chunks().single().instructions
instr.size shouldBe 2
instr[0].opcode shouldBe Opcode.INC
instr[1].opcode shouldBe Opcode.DEC
}
test("remove useless and/or/xor") {
val irProg = makeIRProgram(listOf(
IRInstruction(Opcode.AND, IRDataType.BYTE, reg1=42, value = 255),
IRInstruction(Opcode.AND, IRDataType.WORD, reg1=42, value = 65535),
IRInstruction(Opcode.OR, IRDataType.BYTE, reg1=42, value = 0),
IRInstruction(Opcode.XOR, IRDataType.BYTE, reg1=42, value = 0),
IRInstruction(Opcode.AND, IRDataType.BYTE, reg1=42, value = 200),
IRInstruction(Opcode.AND, IRDataType.WORD, reg1=42, value = 60000),
IRInstruction(Opcode.OR, IRDataType.BYTE, reg1=42, value = 1),
IRInstruction(Opcode.XOR, IRDataType.BYTE, reg1=42, value = 1)
))
irProg.chunks().single().instructions.size shouldBe 8
val opt = IRPeepholeOptimizer(irProg)
opt.optimize()
irProg.chunks().single().instructions.size shouldBe 4
}
test("replace and/or/xor by constant number") {
val irProg = makeIRProgram(listOf(
IRInstruction(Opcode.AND, IRDataType.BYTE, reg1=42, value = 0),
IRInstruction(Opcode.AND, IRDataType.WORD, reg1=42, value = 0),
IRInstruction(Opcode.OR, IRDataType.BYTE, reg1=42, value = 255),
IRInstruction(Opcode.OR, IRDataType.WORD, reg1=42, value = 65535)
))
irProg.chunks().single().instructions.size shouldBe 4
val opt = IRPeepholeOptimizer(irProg)
opt.optimize()
val instr = irProg.chunks().single().instructions
instr.size shouldBe 4
instr[0].opcode shouldBe Opcode.LOAD
instr[1].opcode shouldBe Opcode.LOAD
instr[2].opcode shouldBe Opcode.LOAD
instr[3].opcode shouldBe Opcode.LOAD
instr[0].value shouldBe 0
instr[1].value shouldBe 0
instr[2].value shouldBe 255
instr[3].value shouldBe 65535
}
})

138
codeGenVirtual/src/prog8/codegen/virtual/AssemblyProgram.kt
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@ -1,138 +0,0 @@
package prog8.codegen.virtual
import prog8.code.core.AssemblyError
import prog8.code.core.CompilationOptions
import prog8.code.core.IAssemblyProgram
import prog8.vm.Instruction
import prog8.vm.Opcode
import prog8.vm.OpcodesWithAddress
import prog8.vm.VmDataType
import java.io.BufferedWriter
import java.nio.file.Path
import kotlin.io.path.bufferedWriter
import kotlin.io.path.div
class AssemblyProgram(override val name: String, private val allocations: VariableAllocator
) : IAssemblyProgram {
private val globalInits = mutableListOf<VmCodeLine>()
private val blocks = mutableListOf<VmCodeChunk>()
override fun assemble(options: CompilationOptions): Boolean {
val outfile = options.outputDir / ("$name.p8virt")
println("write code to $outfile")
outfile.bufferedWriter().use { out ->
allocations.asVmMemory().forEach { (name, alloc) ->
out.write("; ${name.joinToString(".")}\n")
out.write(alloc + "\n")
}
out.write("------PROGRAM------\n")
if(!options.dontReinitGlobals) {
out.write("; global var inits\n")
globalInits.forEach { out.writeLine(it) }
}
out.write("; actual program code\n")
blocks.asSequence().flatMap { it.lines }.forEach { line->out.writeLine(line) }
}
return true
}
private fun BufferedWriter.writeLine(line: VmCodeLine) {
when(line) {
is VmCodeComment -> write("; ${line.comment}\n")
is VmCodeInstruction -> {
write(line.ins.toString() + "\n")
}
is VmCodeLabel -> write("_" + line.name.joinToString(".") + ":\n")
is VmCodeInlineAsm -> {
val asm = line.assembly.replace("""\{[a-zA-Z\d_\.]+\}""".toRegex()) { matchResult ->
val name = matchResult.value.substring(1, matchResult.value.length-1).split('.')
allocations.get(name).toString() }
write(asm+"\n")
}
is VmCodeInlineBinary -> {
write("incbin \"${line.file}\"")
if(line.offset!=null)
write(",${line.offset}")
if(line.length!=null)
write(",${line.length}")
write("\n")
}
else -> throw AssemblyError("invalid vm code line")
}
}
fun addGlobalInits(chunk: VmCodeChunk) = globalInits.addAll(chunk.lines)
fun addBlock(block: VmCodeChunk) = blocks.add(block)
fun getBlocks(): List<VmCodeChunk> = blocks
}
sealed class VmCodeLine
class VmCodeInstruction(
opcode: Opcode,
type: VmDataType?=null,
reg1: Int?=null, // 0-$ffff
reg2: Int?=null, // 0-$ffff
fpReg1: Int?=null, // 0-$ffff
fpReg2: Int?=null, // 0-$ffff
value: Int?=null, // 0-$ffff
fpValue: Float?=null,
labelSymbol: List<String>?=null // alternative to value for branch/call/jump labels
): VmCodeLine() {
val ins = Instruction(opcode, type, reg1, reg2, fpReg1, fpReg2, value, fpValue, labelSymbol)
init {
if(reg1!=null && (reg1<0 || reg1>65536))
throw IllegalArgumentException("reg1 out of bounds")
if(reg2!=null && (reg2<0 || reg2>65536))
throw IllegalArgumentException("reg2 out of bounds")
if(fpReg1!=null && (fpReg1<0 || fpReg1>65536))
throw IllegalArgumentException("fpReg1 out of bounds")
if(fpReg2!=null && (fpReg2<0 || fpReg2>65536))
throw IllegalArgumentException("fpReg2 out of bounds")
if(value!=null && opcode !in OpcodesWithAddress) {
when (type) {
VmDataType.BYTE -> {
if (value < -128 || value > 255)
throw IllegalArgumentException("value out of range for byte: $value")
}
VmDataType.WORD -> {
if (value < -32768 || value > 65535)
throw IllegalArgumentException("value out of range for word: $value")
}
VmDataType.FLOAT, null -> {}
}
}
}
}
class VmCodeLabel(val name: List<String>): VmCodeLine()
internal class VmCodeComment(val comment: String): VmCodeLine()
class VmCodeChunk(initial: VmCodeLine? = null) {
val lines = mutableListOf<VmCodeLine>()
init {
if(initial!=null)
lines.add(initial)
}
operator fun plusAssign(line: VmCodeLine) {
lines.add(line)
}
operator fun plusAssign(chunk: VmCodeChunk) {
lines.addAll(chunk.lines)
}
}
internal class VmCodeInlineAsm(asm: String): VmCodeLine() {
val assembly: String = asm.trimIndent()
}
internal class VmCodeInlineBinary(val file: Path, val offset: UInt?, val length: UInt?): VmCodeLine()

242
codeGenVirtual/src/prog8/codegen/virtual/AssignmentGen.kt
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@ -1,242 +0,0 @@
package prog8.codegen.virtual
import prog8.code.ast.*
import prog8.code.core.AssemblyError
import prog8.code.core.DataType
import prog8.code.core.SignedDatatypes
import prog8.vm.Opcode
import prog8.vm.VmDataType
internal class AssignmentGen(private val codeGen: CodeGen, private val expressionEval: ExpressionGen) {
internal fun translate(assignment: PtAssignment): VmCodeChunk {
if(assignment.target.children.single() is PtMachineRegister)
throw AssemblyError("assigning to a register should be done by just evaluating the expression into resultregister")
return if (assignment.isInplaceAssign)
translateInplaceAssign(assignment)
else
translateRegularAssign(assignment)
}
private fun translateInplaceAssign(assignment: PtAssignment): VmCodeChunk {
val ident = assignment.target.identifier
val memory = assignment.target.memory
val array = assignment.target.array
return if(ident!=null) {
val address = codeGen.allocations.get(ident.targetName)
assignSelfInMemory(address, assignment.value, assignment)
} else if(memory != null) {
if(memory.address is PtNumber)
assignSelfInMemory((memory.address as PtNumber).number.toInt(), assignment.value, assignment)
else
fallbackAssign(assignment)
} else if(array!=null) {
// TODO in-place array element assignment?
fallbackAssign(assignment)
} else {
fallbackAssign(assignment)
}
}
private fun assignSelfInMemory(
address: Int,
value: PtExpression,
origAssign: PtAssignment
): VmCodeChunk {
val vmDt = codeGen.vmType(value.type)
val code = VmCodeChunk()
when(value) {
is PtIdentifier -> return code // do nothing, x=x null assignment.
is PtMachineRegister -> return code // do nothing, reg=reg null assignment
is PtPrefix -> return inplacePrefix(value.operator, vmDt, address)
is PtBinaryExpression -> return inplaceBinexpr(value.operator, value.right, vmDt, value.type in SignedDatatypes, address, origAssign)
is PtMemoryByte -> {
return if (!codeGen.options.compTarget.machine.isIOAddress(address.toUInt()))
code // do nothing, mem=mem null assignment.
else {
// read and write a (i/o) memory location to itself.
val tempReg = codeGen.vmRegisters.nextFree()
code += VmCodeInstruction(Opcode.LOADM, vmDt, reg1 = tempReg, value = address)
code += VmCodeInstruction(Opcode.STOREM, vmDt, reg1 = tempReg, value = address)
code
}
}
else -> return fallbackAssign(origAssign)
}
}
private fun fallbackAssign(origAssign: PtAssignment): VmCodeChunk {
if (codeGen.options.slowCodegenWarnings)
codeGen.errors.warn("indirect code for in-place assignment", origAssign.position)
return translateRegularAssign(origAssign)
}
private fun inplaceBinexpr(
operator: String,
operand: PtExpression,
vmDt: VmDataType,
signed: Boolean,
address: Int,
origAssign: PtAssignment
): VmCodeChunk {
when(operator) {
"+" -> return expressionEval.operatorPlusInplace(address, vmDt, operand)
"-" -> return expressionEval.operatorMinusInplace(address, vmDt, operand)
"*" -> return expressionEval.operatorMultiplyInplace(address, vmDt, operand)
"/" -> return expressionEval.operatorDivideInplace(address, vmDt, signed, operand)
"|" -> return expressionEval.operatorOrInplace(address, vmDt, operand)
"&" -> return expressionEval.operatorAndInplace(address, vmDt, operand)
"^" -> return expressionEval.operatorXorInplace(address, vmDt, operand)
"<<" -> return expressionEval.operatorShiftLeftInplace(address, vmDt, operand)
">>" -> return expressionEval.operatorShiftRightInplace(address, vmDt, signed, operand)
else -> {}
}
return fallbackAssign(origAssign)
}
private fun inplacePrefix(operator: String, vmDt: VmDataType, address: Int): VmCodeChunk {
val code= VmCodeChunk()
when(operator) {
"+" -> { }
"-" -> {
code += VmCodeInstruction(Opcode.NEGM, vmDt, value = address)
}
"~" -> {
val regMask = codeGen.vmRegisters.nextFree()
val mask = if(vmDt==VmDataType.BYTE) 0x00ff else 0xffff
code += VmCodeInstruction(Opcode.LOAD, vmDt, reg1=regMask, value = mask)
code += VmCodeInstruction(Opcode.XORM, vmDt, reg1=regMask, value = address)
}
else -> throw AssemblyError("weird prefix operator")
}
return code
}
private fun translateRegularAssign(assignment: PtAssignment): VmCodeChunk {
// note: assigning array and string values is done via an explicit memcopy/stringcopy function call.
val ident = assignment.target.identifier
val memory = assignment.target.memory
val array = assignment.target.array
val vmDt = codeGen.vmType(assignment.value.type)
val code = VmCodeChunk()
var resultRegister = -1
var resultFpRegister = -1
val zero = codeGen.isZero(assignment.value)
if(!zero) {
// calculate the assignment value
if (vmDt == VmDataType.FLOAT) {
resultFpRegister = codeGen.vmRegisters.nextFreeFloat()
code += expressionEval.translateExpression(assignment.value, -1, resultFpRegister)
} else {
resultRegister = if (assignment.value is PtMachineRegister) {
(assignment.value as PtMachineRegister).register
} else {
val reg = codeGen.vmRegisters.nextFree()
code += expressionEval.translateExpression(assignment.value, reg, -1)
reg
}
}
}
if(ident!=null) {
val address = codeGen.allocations.get(ident.targetName)
code += if(zero) {
VmCodeInstruction(Opcode.STOREZM, vmDt, value = address)
} else {
if (vmDt == VmDataType.FLOAT)
VmCodeInstruction(Opcode.STOREM, vmDt, fpReg1 = resultFpRegister, value = address)
else
VmCodeInstruction(Opcode.STOREM, vmDt, reg1 = resultRegister, value = address)
}
}
else if(array!=null) {
val variable = array.variable.targetName
var variableAddr = codeGen.allocations.get(variable)
val itemsize = codeGen.program.memsizer.memorySize(array.type)
if(array.variable.type==DataType.UWORD) {
// indexing a pointer var instead of a real array or string
if(itemsize!=1)
throw AssemblyError("non-array var indexing requires bytes dt")
if(array.index.type!=DataType.UBYTE)
throw AssemblyError("non-array var indexing requires bytes index")
val idxReg = codeGen.vmRegisters.nextFree()
code += expressionEval.translateExpression(array.index, idxReg, -1)
code += VmCodeInstruction(Opcode.STOREIX, vmDt, reg1=resultRegister, reg2=idxReg, value = variableAddr)
return code
}
val fixedIndex = constIntValue(array.index)
if(zero) {
if(fixedIndex!=null) {
variableAddr += fixedIndex*itemsize
code += VmCodeInstruction(Opcode.STOREZM, vmDt, value=variableAddr)
} else {
val indexReg = codeGen.vmRegisters.nextFree()
code += loadIndexReg(array, itemsize, indexReg)
code += VmCodeInstruction(Opcode.STOREZX, vmDt, reg1=indexReg, value=variableAddr)
}
} else {
if(vmDt== VmDataType.FLOAT) {
if(fixedIndex!=null) {
variableAddr += fixedIndex*itemsize
code += VmCodeInstruction(Opcode.STOREM, vmDt, fpReg1 = resultFpRegister, value=variableAddr)
} else {
val indexReg = codeGen.vmRegisters.nextFree()
code += loadIndexReg(array, itemsize, indexReg)
code += VmCodeInstruction(Opcode.STOREX, vmDt, reg1 = resultRegister, reg2=indexReg, value=variableAddr)
}
} else {
if(fixedIndex!=null) {
variableAddr += fixedIndex*itemsize
code += VmCodeInstruction(Opcode.STOREM, vmDt, reg1 = resultRegister, value=variableAddr)
} else {
val indexReg = codeGen.vmRegisters.nextFree()
code += loadIndexReg(array, itemsize, indexReg)
code += VmCodeInstruction(Opcode.STOREX, vmDt, reg1 = resultRegister, reg2=indexReg, value=variableAddr)
}
}
}
}
else if(memory!=null) {
require(vmDt== VmDataType.BYTE)
if(zero) {
if(memory.address is PtNumber) {
code += VmCodeInstruction(Opcode.STOREZM, vmDt, value=(memory.address as PtNumber).number.toInt())
} else {
val addressReg = codeGen.vmRegisters.nextFree()
code += expressionEval.translateExpression(memory.address, addressReg, -1)
code += VmCodeInstruction(Opcode.STOREZI, vmDt, reg1=addressReg)
}
} else {
if(memory.address is PtNumber) {
code += VmCodeInstruction(Opcode.STOREM, vmDt, reg1=resultRegister, value=(memory.address as PtNumber).number.toInt())
} else {
val addressReg = codeGen.vmRegisters.nextFree()
code += expressionEval.translateExpression(memory.address, addressReg, -1)
code += VmCodeInstruction(Opcode.STOREI, vmDt, reg1=resultRegister, reg2=addressReg)
}
}
}
else
throw AssemblyError("weird assigntarget")
return code
}
private fun loadIndexReg(array: PtArrayIndexer, itemsize: Int, indexReg: Int): VmCodeChunk {
val code = VmCodeChunk()
if(itemsize==1) {
code += expressionEval.translateExpression(array.index, indexReg, -1)
}
else {
val mult = PtBinaryExpression("*", DataType.UBYTE, array.position)
mult.children += array.index
mult.children += PtNumber(DataType.UBYTE, itemsize.toDouble(), array.position)
code += expressionEval.translateExpression(mult, indexReg, -1)
}
return code
}
}

376
codeGenVirtual/src/prog8/codegen/virtual/BuiltinFuncGen.kt
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@ -1,376 +0,0 @@
package prog8.codegen.virtual
import prog8.code.StStaticVariable
import prog8.code.ast.*
import prog8.code.core.AssemblyError
import prog8.code.core.DataType
import prog8.vm.Opcode
import prog8.vm.Syscall
import prog8.vm.VmDataType
internal class BuiltinFuncGen(private val codeGen: CodeGen, private val exprGen: ExpressionGen) {
fun translate(call: PtBuiltinFunctionCall, resultRegister: Int): VmCodeChunk {
return when(call.name) {
"any" -> funcAny(call, resultRegister)
"all" -> funcAll(call, resultRegister)
"abs" -> funcAbs(call, resultRegister)
"cmp" -> funcCmp(call)
"sgn" -> funcSgn(call, resultRegister)
"sqrt16" -> funcSqrt16(call, resultRegister)
"pop" -> funcPop(call)
"popw" -> funcPopw(call)
"push" -> funcPush(call)
"pushw" -> funcPushw(call)
"rsave",
"rsavex",
"rrestore",
"rrestorex" -> VmCodeChunk() // vm doesn't have registers to save/restore
"rnd" -> funcRnd(resultRegister)
"rndw" -> funcRndw(resultRegister)
"callfar" -> throw AssemblyError("callfar() is for cx16 target only")
"callrom" -> throw AssemblyError("callrom() is for cx16 target only")
"msb" -> funcMsb(call, resultRegister)
"lsb" -> funcLsb(call, resultRegister)
"memory" -> funcMemory(call, resultRegister)
"peek" -> funcPeek(call, resultRegister)
"peekw" -> funcPeekW(call, resultRegister)
"poke" -> funcPoke(call)
"pokew" -> funcPokeW(call)
"pokemon" -> VmCodeChunk()
"mkword" -> funcMkword(call, resultRegister)
"sort" -> funcSort(call)
"reverse" -> funcReverse(call)
"rol" -> funcRolRor(Opcode.ROXL, call, resultRegister)
"ror" -> funcRolRor(Opcode.ROXR, call, resultRegister)
"rol2" -> funcRolRor(Opcode.ROL, call, resultRegister)
"ror2" -> funcRolRor(Opcode.ROR, call, resultRegister)
else -> TODO("builtinfunc ${call.name}")
}
}
private fun funcCmp(call: PtBuiltinFunctionCall): VmCodeChunk {
val code = VmCodeChunk()
val leftRegister = codeGen.vmRegisters.nextFree()
val rightRegister = codeGen.vmRegisters.nextFree()
code += exprGen.translateExpression(call.args[0], leftRegister, -1)
code += exprGen.translateExpression(call.args[1], rightRegister, -1)
code += VmCodeInstruction(Opcode.CMP, codeGen.vmType(call.args[0].type), reg1=leftRegister, reg2=rightRegister)
return code
}
private fun funcAny(call: PtBuiltinFunctionCall, resultRegister: Int): VmCodeChunk {
val arrayName = call.args[0] as PtIdentifier
val array = codeGen.symbolTable.flat.getValue(arrayName.targetName) as StStaticVariable
val code = VmCodeChunk()
val syscall =
when (array.dt) {
DataType.ARRAY_UB,
DataType.ARRAY_B -> Syscall.ANY_BYTE
DataType.ARRAY_UW,
DataType.ARRAY_W -> Syscall.ANY_WORD
DataType.ARRAY_F -> Syscall.ANY_FLOAT
else -> throw IllegalArgumentException("weird type")
}
code += exprGen.translateExpression(call.args[0], 0, -1)
code += VmCodeInstruction(Opcode.LOAD, VmDataType.BYTE, reg1 = 1, value = array.length)
code += VmCodeInstruction(Opcode.SYSCALL, value = syscall.ordinal)
if (resultRegister != 0)
code += VmCodeInstruction(Opcode.LOADR, VmDataType.BYTE, reg1 = resultRegister, reg2 = 0)
return code
}
private fun funcAll(call: PtBuiltinFunctionCall, resultRegister: Int): VmCodeChunk {
val arrayName = call.args[0] as PtIdentifier
val array = codeGen.symbolTable.flat.getValue(arrayName.targetName) as StStaticVariable
val syscall =
when(array.dt) {
DataType.ARRAY_UB,
DataType.ARRAY_B -> Syscall.ALL_BYTE
DataType.ARRAY_UW,
DataType.ARRAY_W -> Syscall.ALL_WORD
DataType.ARRAY_F -> Syscall.ALL_FLOAT
else -> throw IllegalArgumentException("weird type")
}
val code = VmCodeChunk()
code += exprGen.translateExpression(call.args[0], 0, -1)
code += VmCodeInstruction(Opcode.LOAD, VmDataType.BYTE, reg1=1, value=array.length)
code += VmCodeInstruction(Opcode.SYSCALL, value=syscall.ordinal)
if(resultRegister!=0)
code += VmCodeInstruction(Opcode.LOADR, VmDataType.BYTE, reg1=resultRegister, reg2=0)
return code
}
private fun funcAbs(call: PtBuiltinFunctionCall, resultRegister: Int): VmCodeChunk {
val code = VmCodeChunk()
val sourceDt = call.args.single().type
if(sourceDt!=DataType.UWORD) {
code += exprGen.translateExpression(call.args[0], resultRegister, -1)
when (sourceDt) {
DataType.UBYTE -> {
code += VmCodeInstruction(Opcode.EXT, VmDataType.BYTE, reg1=resultRegister)
}
DataType.BYTE -> {
val notNegativeLabel = codeGen.createLabelName()
val compareReg = codeGen.vmRegisters.nextFree()
code += VmCodeInstruction(Opcode.LOADR, VmDataType.BYTE, reg1=compareReg, reg2=resultRegister)
code += VmCodeInstruction(Opcode.AND, VmDataType.BYTE, reg1=compareReg, value=0x80)
code += VmCodeInstruction(Opcode.BZ, VmDataType.BYTE, reg1=compareReg, labelSymbol = notNegativeLabel)
code += VmCodeInstruction(Opcode.NEG, VmDataType.BYTE, reg1=resultRegister)
code += VmCodeInstruction(Opcode.EXT, VmDataType.BYTE, reg1=resultRegister)
code += VmCodeLabel(notNegativeLabel)
}
DataType.WORD -> {
val notNegativeLabel = codeGen.createLabelName()
val compareReg = codeGen.vmRegisters.nextFree()
code += VmCodeInstruction(Opcode.LOADR, VmDataType.WORD, reg1=compareReg, reg2=resultRegister)
code += VmCodeInstruction(Opcode.AND, VmDataType.WORD, reg1=compareReg, value=0x8000)
code += VmCodeInstruction(Opcode.BZ, VmDataType.WORD, reg1=compareReg, labelSymbol = notNegativeLabel)
code += VmCodeInstruction(Opcode.NEG, VmDataType.WORD, reg1=resultRegister)
code += VmCodeLabel(notNegativeLabel)
}
else -> throw AssemblyError("weird type")
}
}
return code
}
private fun funcSgn(call: PtBuiltinFunctionCall, resultRegister: Int): VmCodeChunk {
val code = VmCodeChunk()
val reg = codeGen.vmRegisters.nextFree()
code += exprGen.translateExpression(call.args.single(), reg, -1)
code += VmCodeInstruction(Opcode.SGN, codeGen.vmType(call.type), reg1=resultRegister, reg2=reg)
return code
}
private fun funcSqrt16(call: PtBuiltinFunctionCall, resultRegister: Int): VmCodeChunk {
val code = VmCodeChunk()
val reg = codeGen.vmRegisters.nextFree()
code += exprGen.translateExpression(call.args.single(), reg, -1)
code += VmCodeInstruction(Opcode.SQRT, VmDataType.WORD, reg1=resultRegister, reg2=reg)
return code
}
private fun funcPop(call: PtBuiltinFunctionCall): VmCodeChunk {
val code = VmCodeChunk()
val reg = codeGen.vmRegisters.nextFree()
code += VmCodeInstruction(Opcode.POP, VmDataType.BYTE, reg1=reg)
code += assignRegisterTo(call.args.single(), reg)
return code
}
private fun funcPopw(call: PtBuiltinFunctionCall): VmCodeChunk {
val code = VmCodeChunk()
val reg = codeGen.vmRegisters.nextFree()
code += VmCodeInstruction(Opcode.POP, VmDataType.WORD, reg1=reg)
code += assignRegisterTo(call.args.single(), reg)
return code
}
private fun funcPush(call: PtBuiltinFunctionCall): VmCodeChunk {
val code = VmCodeChunk()
val reg = codeGen.vmRegisters.nextFree()
code += exprGen.translateExpression(call.args.single(), reg, -1)
code += VmCodeInstruction(Opcode.PUSH, VmDataType.BYTE, reg1=reg)
return code
}
private fun funcPushw(call: PtBuiltinFunctionCall): VmCodeChunk {
val code = VmCodeChunk()
val reg = codeGen.vmRegisters.nextFree()
code += exprGen.translateExpression(call.args.single(), reg, -1)
code += VmCodeInstruction(Opcode.PUSH, VmDataType.WORD, reg1=reg)
return code
}
private fun funcReverse(call: PtBuiltinFunctionCall): VmCodeChunk {
val arrayName = call.args[0] as PtIdentifier
val array = codeGen.symbolTable.flat.getValue(arrayName.targetName) as StStaticVariable
val sortSyscall =
when(array.dt) {
DataType.ARRAY_UB, DataType.ARRAY_B, DataType.STR -> Syscall.REVERSE_BYTES
DataType.ARRAY_UW, DataType.ARRAY_W -> Syscall.REVERSE_WORDS
DataType.ARRAY_F -> Syscall.REVERSE_FLOATS
else -> throw IllegalArgumentException("weird type to reverse")
}
val code = VmCodeChunk()
code += exprGen.translateExpression(call.args[0], 0, -1)
code += VmCodeInstruction(Opcode.LOAD, VmDataType.BYTE, reg1=1, value=array.length)
code += VmCodeInstruction(Opcode.SYSCALL, value=sortSyscall.ordinal)
return code
}
private fun funcSort(call: PtBuiltinFunctionCall): VmCodeChunk {
val arrayName = call.args[0] as PtIdentifier
val array = codeGen.symbolTable.flat.getValue(arrayName.targetName) as StStaticVariable
val sortSyscall =
when(array.dt) {
DataType.ARRAY_UB -> Syscall.SORT_UBYTE
DataType.ARRAY_B -> Syscall.SORT_BYTE
DataType.ARRAY_UW -> Syscall.SORT_UWORD
DataType.ARRAY_W -> Syscall.SORT_WORD
DataType.STR -> Syscall.SORT_UBYTE
DataType.ARRAY_F -> throw IllegalArgumentException("sorting a floating point array is not supported")
else -> throw IllegalArgumentException("weird type to sort")
}
val code = VmCodeChunk()
code += exprGen.translateExpression(call.args[0], 0, -1)
code += VmCodeInstruction(Opcode.LOAD, VmDataType.BYTE, reg1=1, value=array.length)
code += VmCodeInstruction(Opcode.SYSCALL, value=sortSyscall.ordinal)
return code
}
private fun funcMkword(call: PtBuiltinFunctionCall, resultRegister: Int): VmCodeChunk {
val msbReg = codeGen.vmRegisters.nextFree()
val code = VmCodeChunk()
code += exprGen.translateExpression(call.args[0], msbReg, -1)
code += exprGen.translateExpression(call.args[1], resultRegister, -1)
code += VmCodeInstruction(Opcode.CONCAT, VmDataType.BYTE, reg1=resultRegister, reg2=msbReg)
return code
}
private fun funcPokeW(call: PtBuiltinFunctionCall): VmCodeChunk {
val code = VmCodeChunk()
if(codeGen.isZero(call.args[1])) {
if (call.args[0] is PtNumber) {
val address = (call.args[0] as PtNumber).number.toInt()
code += VmCodeInstruction(Opcode.STOREZM, VmDataType.WORD, value = address)
} else {
val addressReg = codeGen.vmRegisters.nextFree()
code += exprGen.translateExpression(call.args[0], addressReg, -1)
code += VmCodeInstruction(Opcode.STOREZI, VmDataType.WORD, reg2 = addressReg)
}
} else {
val valueReg = codeGen.vmRegisters.nextFree()
if (call.args[0] is PtNumber) {
val address = (call.args[0] as PtNumber).number.toInt()
code += exprGen.translateExpression(call.args[1], valueReg, -1)
code += VmCodeInstruction(Opcode.STOREM, VmDataType.WORD, reg1 = valueReg, value = address)
} else {
val addressReg = codeGen.vmRegisters.nextFree()
code += exprGen.translateExpression(call.args[0], addressReg, -1)
code += exprGen.translateExpression(call.args[1], valueReg, -1)
code += VmCodeInstruction(Opcode.STOREI, VmDataType.WORD, reg1 = valueReg, reg2 = addressReg)
}
}
return code
}
private fun funcPoke(call: PtBuiltinFunctionCall): VmCodeChunk {
val code = VmCodeChunk()
if(codeGen.isZero(call.args[1])) {
if (call.args[0] is PtNumber) {
val address = (call.args[0] as PtNumber).number.toInt()
code += VmCodeInstruction(Opcode.STOREZM, VmDataType.BYTE, value = address)
} else {
val addressReg = codeGen.vmRegisters.nextFree()
code += exprGen.translateExpression(call.args[0], addressReg, -1)
code += VmCodeInstruction(Opcode.STOREZI, VmDataType.BYTE, reg2 = addressReg)
}
} else {
val valueReg = codeGen.vmRegisters.nextFree()
if (call.args[0] is PtNumber) {
val address = (call.args[0] as PtNumber).number.toInt()
code += exprGen.translateExpression(call.args[1], valueReg, -1)
code += VmCodeInstruction(Opcode.STOREM, VmDataType.BYTE, reg1 = valueReg, value = address)
} else {
val addressReg = codeGen.vmRegisters.nextFree()
code += exprGen.translateExpression(call.args[0], addressReg, -1)
code += exprGen.translateExpression(call.args[1], valueReg, -1)
code += VmCodeInstruction(Opcode.STOREI, VmDataType.BYTE, reg1 = valueReg, reg2 = addressReg)
}
}
return code
}
private fun funcPeekW(call: PtBuiltinFunctionCall, resultRegister: Int): VmCodeChunk {
val code = VmCodeChunk()
if(call.args[0] is PtNumber) {
val address = (call.args[0] as PtNumber).number.toInt()
code += VmCodeInstruction(Opcode.LOADM, VmDataType.WORD, reg1 = resultRegister, value = address)
} else {
val addressReg = codeGen.vmRegisters.nextFree()
code += exprGen.translateExpression(call.args.single(), addressReg, -1)
code += VmCodeInstruction(Opcode.LOADI, VmDataType.WORD, reg1 = resultRegister, reg2 = addressReg)
}
return code
}
private fun funcPeek(call: PtBuiltinFunctionCall, resultRegister: Int): VmCodeChunk {
val code = VmCodeChunk()
if(call.args[0] is PtNumber) {
val address = (call.args[0] as PtNumber).number.toInt()
code += VmCodeInstruction(Opcode.LOADM, VmDataType.BYTE, reg1 = resultRegister, value = address)
} else {
val addressReg = codeGen.vmRegisters.nextFree()
code += exprGen.translateExpression(call.args.single(), addressReg, -1)
code += VmCodeInstruction(Opcode.LOADI, VmDataType.BYTE, reg1 = resultRegister, reg2 = addressReg)
}
return code
}
private fun funcRnd(resultRegister: Int): VmCodeChunk {
val code = VmCodeChunk()
code += VmCodeInstruction(Opcode.RND, VmDataType.BYTE, reg1=resultRegister)
return code
}
private fun funcRndw(resultRegister: Int): VmCodeChunk {
val code = VmCodeChunk()
code += VmCodeInstruction(Opcode.RND, VmDataType.WORD, reg1=resultRegister)
return code
}
private fun funcMemory(call: PtBuiltinFunctionCall, resultRegister: Int): VmCodeChunk {
val name = (call.args[0] as PtString).value
val size = (call.args[1] as PtNumber).number.toUInt()
val align = (call.args[2] as PtNumber).number.toUInt()
val existing = codeGen.allocations.getMemorySlab(name)
val address = if(existing==null)
codeGen.allocations.allocateMemorySlab(name, size, align)
else if(existing.second!=size || existing.third!=align) {
codeGen.errors.err("memory slab '$name' already exists with a different size or alignment", call.position)
return VmCodeChunk()
}
else
existing.first
val code = VmCodeChunk()
code += VmCodeInstruction(Opcode.LOAD, VmDataType.WORD, reg1=resultRegister, value=address.toInt())
return code
}
private fun funcLsb(call: PtBuiltinFunctionCall, resultRegister: Int): VmCodeChunk {
val code = VmCodeChunk()
code += exprGen.translateExpression(call.args.single(), resultRegister, -1)
// note: if a word result is needed, the upper byte is cleared by the typecast that follows. No need to do it here.
return code
}
private fun funcMsb(call: PtBuiltinFunctionCall, resultRegister: Int): VmCodeChunk {
val code = VmCodeChunk()
code += exprGen.translateExpression(call.args.single(), resultRegister, -1)
code += VmCodeInstruction(Opcode.MSIG, VmDataType.BYTE, reg1 = resultRegister, reg2=resultRegister)
// note: if a word result is needed, the upper byte is cleared by the typecast that follows. No need to do it here.
return code
}
private fun funcRolRor(opcode: Opcode, call: PtBuiltinFunctionCall, resultRegister: Int): VmCodeChunk {
val vmDt = codeGen.vmType(call.args[0].type)
val code = VmCodeChunk()
code += exprGen.translateExpression(call.args[0], resultRegister, -1)
code += VmCodeInstruction(opcode, vmDt, reg1=resultRegister)
code += assignRegisterTo(call.args[0], resultRegister)
return code
}
private fun assignRegisterTo(target: PtExpression, register: Int): VmCodeChunk {
val code = VmCodeChunk()
val assignment = PtAssignment(target.position)
val assignTarget = PtAssignTarget(target.position)
assignTarget.children.add(target)
assignment.children.add(assignTarget)
assignment.children.add(PtMachineRegister(register, target.type, target.position))
code += codeGen.translateNode(assignment)
return code
}
}

830
codeGenVirtual/src/prog8/codegen/virtual/CodeGen.kt
View File

@ -1,830 +0,0 @@
package prog8.codegen.virtual
import prog8.code.StStaticVariable
import prog8.code.SymbolTable
import prog8.code.ast.*
import prog8.code.core.*
import prog8.vm.Opcode
import prog8.vm.VmDataType
import kotlin.math.pow
internal class VmRegisterPool {
private var firstFree: Int=3 // integer registers 0,1,2 are reserved
private var firstFreeFloat: Int=0
fun peekNext() = firstFree
fun peekNextFloat() = firstFreeFloat
fun nextFree(): Int {
val result = firstFree
firstFree++
if(firstFree>65535)
throw AssemblyError("out of virtual registers (int)")
return result
}
fun nextFreeFloat(): Int {
val result = firstFreeFloat
firstFreeFloat++
if(firstFreeFloat>65535)
throw AssemblyError("out of virtual registers (fp)")
return result
}
}
class CodeGen(internal val program: PtProgram,
internal val symbolTable: SymbolTable,
internal val options: CompilationOptions,
internal val errors: IErrorReporter
): IAssemblyGenerator {
internal val allocations = VariableAllocator(symbolTable, program)
private val expressionEval = ExpressionGen(this)
private val builtinFuncGen = BuiltinFuncGen(this, expressionEval)
private val assignmentGen = AssignmentGen(this, expressionEval)
internal val vmRegisters = VmRegisterPool()
override fun compileToAssembly(): IAssemblyProgram? {
val vmprog = AssemblyProgram(program.name, allocations)
if(!options.dontReinitGlobals) {
// collect global variables initializers
program.allBlocks().forEach {
val code = VmCodeChunk()
it.children.filterIsInstance<PtAssignment>().forEach { assign -> code += assignmentGen.translate(assign) }
vmprog.addGlobalInits(code)
}
}
if(options.symbolDefs.isNotEmpty())
throw AssemblyError("virtual target doesn't support symbols defined on the commandline")
if(options.evalStackBaseAddress!=null)
throw AssemblyError("virtual target doesn't use eval-stack")
for (block in program.allBlocks()) {
vmprog.addBlock(translate(block))
}
if(options.optimize) {
val optimizer = VmPeepholeOptimizer(vmprog, allocations)
optimizer.optimize()
}
println("Vm codegen: virtual registers=${vmRegisters.peekNext()} memory usage=${allocations.freeMem}")
return vmprog
}
internal fun translateNode(node: PtNode): VmCodeChunk {
val code = when(node) {
is PtBlock -> translate(node)
is PtSub -> translate(node)
is PtScopeVarsDecls -> VmCodeChunk() // vars should be looked up via symbol table
is PtVariable -> VmCodeChunk() // var should be looked up via symbol table
is PtMemMapped -> VmCodeChunk() // memmapped var should be looked up via symbol table
is PtConstant -> VmCodeChunk() // constants have all been folded into the code
is PtAssignment -> assignmentGen.translate(node)
is PtNodeGroup -> translateGroup(node.children)
is PtBuiltinFunctionCall -> translateBuiltinFunc(node, 0)
is PtFunctionCall -> expressionEval.translate(node, 0, 0)
is PtNop -> VmCodeChunk()
is PtReturn -> translate(node)
is PtJump -> translate(node)
is PtWhen -> translate(node)
is PtForLoop -> translate(node)
is PtIfElse -> translate(node)
is PtPostIncrDecr -> translate(node)
is PtRepeatLoop -> translate(node)
is PtLabel -> VmCodeChunk(VmCodeLabel(node.scopedName))
is PtBreakpoint -> VmCodeChunk(VmCodeInstruction(Opcode.BREAKPOINT))
is PtConditionalBranch -> translate(node)
is PtInlineAssembly -> VmCodeChunk(VmCodeInlineAsm(node.assembly))
is PtIncludeBinary -> VmCodeChunk(VmCodeInlineBinary(node.file, node.offset, node.length))
is PtAsmSub -> TODO("asmsub not yet supported on virtual machine target ${node.position}")
is PtAddressOf,
is PtContainmentCheck,
is PtMemoryByte,
is PtProgram,
is PtArrayIndexer,
is PtBinaryExpression,
is PtIdentifier,
is PtWhenChoice,
is PtPrefix,
is PtRange,
is PtAssignTarget,
is PtTypeCast,
is PtSubroutineParameter,
is PtNumber,
is PtArray,
is PtString -> throw AssemblyError("should not occur as separate statement node ${node.position}")
else -> TODO("missing codegen for $node")
}
if(code.lines.isNotEmpty() && node.position.line!=0)
code.lines.add(0, VmCodeComment(node.position.toString()))
return code
}
private fun translate(branch: PtConditionalBranch): VmCodeChunk {
val code = VmCodeChunk()
val elseLabel = createLabelName()
// note that the branch opcode used is the opposite as the branch condition, because the generated code jumps to the 'else' part
code += when(branch.condition) {
BranchCondition.CS -> VmCodeInstruction(Opcode.BSTCC, labelSymbol = elseLabel)
BranchCondition.CC -> VmCodeInstruction(Opcode.BSTCS, labelSymbol = elseLabel)
BranchCondition.EQ, BranchCondition.Z -> VmCodeInstruction(Opcode.BSTNE, labelSymbol = elseLabel)
BranchCondition.NE, BranchCondition.NZ -> VmCodeInstruction(Opcode.BSTEQ, labelSymbol = elseLabel)
BranchCondition.MI, BranchCondition.NEG -> VmCodeInstruction(Opcode.BSTPOS, labelSymbol = elseLabel)
BranchCondition.PL, BranchCondition.POS -> VmCodeInstruction(Opcode.BSTNEG, labelSymbol = elseLabel)
BranchCondition.VC,
BranchCondition.VS -> throw AssemblyError("conditional branch ${branch.condition} not supported in vm target due to lack of cpu V flag ${branch.position}")
}
code += translateNode(branch.trueScope)
if(branch.falseScope.children.isNotEmpty()) {
val endLabel = createLabelName()
code += VmCodeInstruction(Opcode.JUMP, labelSymbol = endLabel)
code += VmCodeLabel(elseLabel)
code += translateNode(branch.falseScope)
code += VmCodeLabel(endLabel)
} else {
code += VmCodeLabel(elseLabel)
}
return code
}
private fun translate(whenStmt: PtWhen): VmCodeChunk {
if(whenStmt.choices.children.isEmpty())
return VmCodeChunk()
val code = VmCodeChunk()
val valueReg = vmRegisters.nextFree()
val choiceReg = vmRegisters.nextFree()
val valueDt = vmType(whenStmt.value.type)
code += expressionEval.translateExpression(whenStmt.value, valueReg, -1)
val choices = whenStmt.choices.children.map {it as PtWhenChoice }
val endLabel = createLabelName()
for (choice in choices) {
if(choice.isElse) {
code += translateNode(choice.statements)
} else {
val skipLabel = createLabelName()
val values = choice.values.children.map {it as PtNumber}
if(values.size==1) {
code += VmCodeInstruction(Opcode.LOAD, valueDt, reg1=choiceReg, value=values[0].number.toInt())
code += VmCodeInstruction(Opcode.BNE, valueDt, reg1=valueReg, reg2=choiceReg, labelSymbol = skipLabel)
code += translateNode(choice.statements)
if(choice.statements.children.last() !is PtReturn)
code += VmCodeInstruction(Opcode.JUMP, labelSymbol = endLabel)
} else {
val matchLabel = createLabelName()
for (value in values) {
code += VmCodeInstruction(Opcode.LOAD, valueDt, reg1=choiceReg, value=value.number.toInt())
code += VmCodeInstruction(Opcode.BEQ, valueDt, reg1=valueReg, reg2=choiceReg, labelSymbol = matchLabel)
}
code += VmCodeInstruction(Opcode.JUMP, labelSymbol = skipLabel)
code += VmCodeLabel(matchLabel)
code += translateNode(choice.statements)
if(choice.statements.children.last() !is PtReturn)
code += VmCodeInstruction(Opcode.JUMP, labelSymbol = endLabel)
}
code += VmCodeLabel(skipLabel)
}
}
code += VmCodeLabel(endLabel)
return code
}
private fun translate(forLoop: PtForLoop): VmCodeChunk {
val loopvar = symbolTable.lookup(forLoop.variable.targetName) as StStaticVariable
val iterable = forLoop.iterable
val code = VmCodeChunk()
when(iterable) {
is PtRange -> {
if(iterable.from is PtNumber && iterable.to is PtNumber)
code += translateForInConstantRange(forLoop, loopvar)
else
code += translateForInNonConstantRange(forLoop, loopvar)
}
is PtIdentifier -> {
val arrayAddress = allocations.get(iterable.targetName)
val iterableVar = symbolTable.lookup(iterable.targetName) as StStaticVariable
val loopvarAddress = allocations.get(loopvar.scopedName)
val indexReg = vmRegisters.nextFree()
val tmpReg = vmRegisters.nextFree()
val loopLabel = createLabelName()
val endLabel = createLabelName()
if(iterableVar.dt==DataType.STR) {
// iterate over a zero-terminated string
code += VmCodeInstruction(Opcode.LOAD, VmDataType.BYTE, reg1=indexReg, value=0)
code += VmCodeLabel(loopLabel)
code += VmCodeInstruction(Opcode.LOADX, VmDataType.BYTE, reg1=tmpReg, reg2=indexReg, value = arrayAddress)
code += VmCodeInstruction(Opcode.BZ, VmDataType.BYTE, reg1=tmpReg, labelSymbol = endLabel)
code += VmCodeInstruction(Opcode.STOREM, VmDataType.BYTE, reg1=tmpReg, value = loopvarAddress)
code += translateNode(forLoop.statements)
code += VmCodeInstruction(Opcode.INC, VmDataType.BYTE, reg1=indexReg)
code += VmCodeInstruction(Opcode.JUMP, labelSymbol = loopLabel)
code += VmCodeLabel(endLabel)
} else {
// iterate over array
val elementDt = ArrayToElementTypes.getValue(iterable.type)
val elementSize = program.memsizer.memorySize(elementDt)
val lengthBytes = iterableVar.length!! * elementSize
if(lengthBytes<256) {
val lengthReg = vmRegisters.nextFree()
code += VmCodeInstruction(Opcode.LOAD, VmDataType.BYTE, reg1=indexReg, value=0)
code += VmCodeInstruction(Opcode.LOAD, VmDataType.BYTE, reg1=lengthReg, value=lengthBytes)
code += VmCodeLabel(loopLabel)
code += VmCodeInstruction(Opcode.LOADX, vmType(elementDt), reg1=tmpReg, reg2=indexReg, value=arrayAddress)
code += VmCodeInstruction(Opcode.STOREM, vmType(elementDt), reg1=tmpReg, value = loopvarAddress)
code += translateNode(forLoop.statements)
code += addConstReg(VmDataType.BYTE, indexReg, elementSize)
code += VmCodeInstruction(Opcode.BNE, VmDataType.BYTE, reg1=indexReg, reg2=lengthReg, labelSymbol = loopLabel)
} else if(lengthBytes==256) {
code += VmCodeInstruction(Opcode.LOAD, VmDataType.BYTE, reg1=indexReg, value=0)
code += VmCodeLabel(loopLabel)
code += VmCodeInstruction(Opcode.LOADX, vmType(elementDt), reg1=tmpReg, reg2=indexReg, value=arrayAddress)
code += VmCodeInstruction(Opcode.STOREM, vmType(elementDt), reg1=tmpReg, value = loopvarAddress)
code += translateNode(forLoop.statements)
code += addConstReg(VmDataType.BYTE, indexReg, elementSize)
code += VmCodeInstruction(Opcode.BNZ, VmDataType.BYTE, reg1=indexReg, labelSymbol = loopLabel)
} else {
throw AssemblyError("iterator length should never exceed 256")
}
}
}
else -> throw AssemblyError("weird for iterable")
}
return code
}
private fun translateForInNonConstantRange(forLoop: PtForLoop, loopvar: StStaticVariable): VmCodeChunk {
val iterable = forLoop.iterable as PtRange
val step = iterable.step.number.toInt()
if (step==0)
throw AssemblyError("step 0")
val indexReg = vmRegisters.nextFree()
val endvalueReg = vmRegisters.nextFree()
val loopvarAddress = allocations.get(loopvar.scopedName)
val loopvarDt = vmType(loopvar.dt)
val loopLabel = createLabelName()
val code = VmCodeChunk()
code += expressionEval.translateExpression(iterable.to, endvalueReg, -1)
code += expressionEval.translateExpression(iterable.from, indexReg, -1)
code += VmCodeInstruction(Opcode.STOREM, loopvarDt, reg1=indexReg, value=loopvarAddress)
code += VmCodeLabel(loopLabel)
code += translateNode(forLoop.statements)
if(step<3) {
code += addConstMem(loopvarDt, loopvarAddress.toUInt(), step)
code += VmCodeInstruction(Opcode.LOADM, loopvarDt, reg1 = indexReg, value = loopvarAddress)
} else {
// TODO WHY THID DISTINCTION?
code += VmCodeInstruction(Opcode.LOADM, loopvarDt, reg1 = indexReg, value = loopvarAddress)
code += addConstReg(loopvarDt, indexReg, step)
code += VmCodeInstruction(Opcode.STOREM, loopvarDt, reg1 = indexReg, value = loopvarAddress)
}
val branchOpcode = if(loopvar.dt in SignedDatatypes) Opcode.BLES else Opcode.BLE
code += VmCodeInstruction(branchOpcode, loopvarDt, reg1=indexReg, reg2=endvalueReg, labelSymbol=loopLabel)
return code
}
private fun translateForInConstantRange(forLoop: PtForLoop, loopvar: StStaticVariable): VmCodeChunk {
val loopLabel = createLabelName()
val loopvarAddress = allocations.get(loopvar.scopedName)
val indexReg = vmRegisters.nextFree()
val loopvarDt = vmType(loopvar.dt)
val iterable = forLoop.iterable as PtRange
val step = iterable.step.number.toInt()
val rangeStart = (iterable.from as PtNumber).number.toInt()
val rangeEndUntyped = (iterable.to as PtNumber).number.toInt() + step
if(step==0)
throw AssemblyError("step 0")
if(step>0 && rangeEndUntyped<rangeStart || step<0 && rangeEndUntyped>rangeStart)
throw AssemblyError("empty range")
val rangeEndWrapped = if(loopvarDt==VmDataType.BYTE) rangeEndUntyped and 255 else rangeEndUntyped and 65535
val code = VmCodeChunk()
val endvalueReg: Int
if(rangeEndWrapped!=0) {
endvalueReg = vmRegisters.nextFree()
code += VmCodeInstruction(Opcode.LOAD, loopvarDt, reg1 = endvalueReg, value = rangeEndWrapped)
} else {
endvalueReg = -1 // not used
}
code += VmCodeInstruction(Opcode.LOAD, loopvarDt, reg1=indexReg, value=rangeStart)
code += VmCodeInstruction(Opcode.STOREM, loopvarDt, reg1=indexReg, value=loopvarAddress)
code += VmCodeLabel(loopLabel)
code += translateNode(forLoop.statements)
if(step<3) {
code += addConstMem(loopvarDt, loopvarAddress.toUInt(), step)
code += VmCodeInstruction(Opcode.LOADM, loopvarDt, reg1 = indexReg, value = loopvarAddress)
} else {
// TODO WHY THIS DISTICTION ?
code += VmCodeInstruction(Opcode.LOADM, loopvarDt, reg1 = indexReg, value = loopvarAddress)
code += addConstReg(loopvarDt, indexReg, step)
code += VmCodeInstruction(Opcode.STOREM, loopvarDt, reg1 = indexReg, value = loopvarAddress)
}
code += if(rangeEndWrapped==0) {
VmCodeInstruction(Opcode.BNZ, loopvarDt, reg1 = indexReg, labelSymbol = loopLabel)
} else {
VmCodeInstruction(Opcode.BNE, loopvarDt, reg1 = indexReg, reg2 = endvalueReg, labelSymbol = loopLabel)
}
return code
}
private fun addConstReg(dt: VmDataType, reg: Int, value: Int): VmCodeChunk {
val code = VmCodeChunk()
when(value) {
0 -> { /* do nothing */ }
1 -> {
code += VmCodeInstruction(Opcode.INC, dt, reg1=reg)
}
2 -> {
code += VmCodeInstruction(Opcode.INC, dt, reg1=reg)
code += VmCodeInstruction(Opcode.INC, dt, reg1=reg)
}
-1 -> {
code += VmCodeInstruction(Opcode.DEC, dt, reg1=reg)
}
-2 -> {
code += VmCodeInstruction(Opcode.DEC, dt, reg1=reg)
code += VmCodeInstruction(Opcode.DEC, dt, reg1=reg)
}
else -> {
code += if(value>0) {
VmCodeInstruction(Opcode.ADD, dt, reg1 = reg, value=value)
} else {
VmCodeInstruction(Opcode.SUB, dt, reg1 = reg, value=-value)
}
}
}
return code
}
private fun addConstMem(dt: VmDataType, address: UInt, value: Int): VmCodeChunk {
val code = VmCodeChunk()
when(value) {
0 -> { /* do nothing */ }
1 -> {
code += VmCodeInstruction(Opcode.INCM, dt, value=address.toInt())
}
2 -> {
code += VmCodeInstruction(Opcode.INCM, dt, value=address.toInt())
code += VmCodeInstruction(Opcode.INCM, dt, value=address.toInt())
}
-1 -> {
code += VmCodeInstruction(Opcode.DECM, dt, value=address.toInt())
}
-2 -> {
code += VmCodeInstruction(Opcode.DECM, dt, value=address.toInt())
code += VmCodeInstruction(Opcode.DECM, dt, value=address.toInt())
}
else -> {
val valueReg = vmRegisters.nextFree()
val operandReg = vmRegisters.nextFree()
if(value>0) {
code += VmCodeInstruction(Opcode.LOADM, dt, reg1=valueReg, value=address.toInt())
code += VmCodeInstruction(Opcode.LOAD, dt, reg1=operandReg, value=value)
code += VmCodeInstruction(Opcode.ADDR, dt, reg1 = valueReg, reg2 = operandReg) // TODO USE ADDM?
code += VmCodeInstruction(Opcode.STOREM, dt, reg1=valueReg, value=address.toInt())
}
else {
code += VmCodeInstruction(Opcode.LOADM, dt, reg1=valueReg, value=address.toInt())
code += VmCodeInstruction(Opcode.LOAD, dt, reg1=operandReg, value=-value)
code += VmCodeInstruction(Opcode.SUBR, dt, reg1 = valueReg, reg2 = operandReg) // TODO USE ADDM?
code += VmCodeInstruction(Opcode.STOREM, dt, reg1=valueReg, value=address.toInt())
}
}
}
return code
}
internal fun multiplyByConstFloat(fpReg: Int, factor: Float): VmCodeChunk {
val code = VmCodeChunk()
if(factor==1f)
return code
code += if(factor==0f) {
VmCodeInstruction(Opcode.LOAD, VmDataType.FLOAT, fpReg1 = fpReg, fpValue = 0f)
} else {
VmCodeInstruction(Opcode.MUL, VmDataType.FLOAT, fpReg1 = fpReg, fpValue=factor)
}
return code
}
internal fun multiplyByConstFloatInplace(address: Int, factor: Float): VmCodeChunk {
val code = VmCodeChunk()
if(factor==1f)
return code
if(factor==0f) {
code += VmCodeInstruction(Opcode.STOREZM, VmDataType.FLOAT, value = address)
} else {
val factorReg = vmRegisters.nextFreeFloat()
code += VmCodeInstruction(Opcode.LOAD, VmDataType.FLOAT, fpReg1=factorReg, fpValue = factor)
code += VmCodeInstruction(Opcode.MULM, VmDataType.FLOAT, fpReg1 = factorReg, value = address)
}
return code
}
internal val powersOfTwo = (0..16).map { 2.0.pow(it.toDouble()).toInt() }
internal fun multiplyByConst(dt: VmDataType, reg: Int, factor: Int): VmCodeChunk {
val code = VmCodeChunk()
if(factor==1)
return code
val pow2 = powersOfTwo.indexOf(factor)
if(pow2==1) {
// just shift 1 bit
code += VmCodeInstruction(Opcode.LSL, dt, reg1=reg)
}
else if(pow2>=1) {
// just shift multiple bits
val pow2reg = vmRegisters.nextFree()
code += VmCodeInstruction(Opcode.LOAD, dt, reg1=pow2reg, value=pow2)
code += VmCodeInstruction(Opcode.LSLN, dt, reg1=reg, reg2=pow2reg)
} else {
code += if (factor == 0) {
VmCodeInstruction(Opcode.LOAD, dt, reg1=reg, value=0)
} else {
VmCodeInstruction(Opcode.MUL, dt, reg1=reg, value=factor)
}
}
return code
}
internal fun multiplyByConstInplace(dt: VmDataType, address: Int, factor: Int): VmCodeChunk {
val code = VmCodeChunk()
if(factor==1)
return code
val pow2 = powersOfTwo.indexOf(factor)
if(pow2==1) {
// just shift 1 bit
code += VmCodeInstruction(Opcode.LSLM, dt, value = address)
}
else if(pow2>=1) {
// just shift multiple bits
val pow2reg = vmRegisters.nextFree()
code += VmCodeInstruction(Opcode.LOAD, dt, reg1=pow2reg, value=pow2)
code += VmCodeInstruction(Opcode.LSLNM, dt, reg1=pow2reg, value=address)
} else {
if (factor == 0) {
code += VmCodeInstruction(Opcode.STOREZM, dt, value=address)
}
else {
val factorReg = vmRegisters.nextFree()
code += VmCodeInstruction(Opcode.LOAD, dt, reg1=factorReg, value = factor)
code += VmCodeInstruction(Opcode.MULM, dt, reg1=factorReg, value = address)
}
}
return code
}
internal fun divideByConstFloat(fpReg: Int, factor: Float): VmCodeChunk {
val code = VmCodeChunk()
if(factor==1f)
return code
code += if(factor==0f) {
VmCodeInstruction(Opcode.LOAD, VmDataType.FLOAT, fpReg1 = fpReg, fpValue = Float.MAX_VALUE)
} else {
VmCodeInstruction(Opcode.DIVS, VmDataType.FLOAT, fpReg1 = fpReg, fpValue=factor)
}
return code
}
internal fun divideByConstFloatInplace(address: Int, factor: Float): VmCodeChunk {
val code = VmCodeChunk()
if(factor==1f)
return code
if(factor==0f) {
val maxvalueReg = vmRegisters.nextFreeFloat()
code += VmCodeInstruction(Opcode.LOAD, VmDataType.FLOAT, fpReg1 = maxvalueReg, fpValue = Float.MAX_VALUE)
code += VmCodeInstruction(Opcode.STOREM, VmDataType.FLOAT, fpReg1 = maxvalueReg, value=address)
} else {
val factorReg = vmRegisters.nextFreeFloat()
code += VmCodeInstruction(Opcode.LOAD, VmDataType.FLOAT, fpReg1=factorReg, fpValue = factor)
code += VmCodeInstruction(Opcode.DIVSM, VmDataType.FLOAT, fpReg1 = factorReg, value=address)
}
return code
}
internal fun divideByConst(dt: VmDataType, reg: Int, factor: Int, signed: Boolean): VmCodeChunk {
val code = VmCodeChunk()
if(factor==1)
return code
val pow2 = powersOfTwo.indexOf(factor)
if(pow2==1) {
// just shift 1 bit
code += if(signed)
VmCodeInstruction(Opcode.ASR, dt, reg1=reg)
else
VmCodeInstruction(Opcode.LSR, dt, reg1=reg)
}
else if(pow2>=1) {
// just shift multiple bits
val pow2reg = vmRegisters.nextFree()
code += VmCodeInstruction(Opcode.LOAD, dt, reg1=pow2reg, value=pow2)
code += if(signed)
VmCodeInstruction(Opcode.ASRN, dt, reg1=reg, reg2=pow2reg)
else
VmCodeInstruction(Opcode.LSRN, dt, reg1=reg, reg2=pow2reg)
} else {
code += if (factor == 0) {
VmCodeInstruction(Opcode.LOAD, dt, reg1=reg, value=0xffff)
} else {
if(signed)
VmCodeInstruction(Opcode.DIVS, dt, reg1=reg, value=factor)
else
VmCodeInstruction(Opcode.DIV, dt, reg1=reg, value=factor)
}
}
return code
}
internal fun divideByConstInplace(dt: VmDataType, address: Int, factor: Int, signed: Boolean): VmCodeChunk {
val code = VmCodeChunk()
if(factor==1)
return code
val pow2 = powersOfTwo.indexOf(factor)
if(pow2==1) {
// just shift 1 bit
code += if(signed)
VmCodeInstruction(Opcode.ASRM, dt, value=address)
else
VmCodeInstruction(Opcode.LSRM, dt, value=address)
}
else if(pow2>=1) {
// just shift multiple bits
val pow2reg = vmRegisters.nextFree()
code += VmCodeInstruction(Opcode.LOAD, dt, reg1=pow2reg, value=pow2)
code += if(signed)
VmCodeInstruction(Opcode.ASRNM, dt, reg1=pow2reg, value=address)
else
VmCodeInstruction(Opcode.LSRNM, dt, reg1=pow2reg, value=address)
} else {
if (factor == 0) {
val reg = vmRegisters.nextFree()
code += VmCodeInstruction(Opcode.LOAD, dt, reg1=reg, value=0xffff)
code += VmCodeInstruction(Opcode.STOREM, dt, reg1=reg, value=address)
}
else {
val factorReg = vmRegisters.nextFree()
code += VmCodeInstruction(Opcode.LOAD, dt, reg1=factorReg, value= factor)
code += if(signed)
VmCodeInstruction(Opcode.DIVSM, dt, reg1=factorReg, value=address)
else
VmCodeInstruction(Opcode.DIVM, dt, reg1=factorReg, value=address)
}
}
return code
}
private fun translate(ifElse: PtIfElse): VmCodeChunk {
if(ifElse.condition.operator !in ComparisonOperators)
throw AssemblyError("if condition should only be a binary comparison expression")
val signed = ifElse.condition.left.type in arrayOf(DataType.BYTE, DataType.WORD, DataType.FLOAT)
val vmDt = vmType(ifElse.condition.left.type)
val code = VmCodeChunk()
fun translateNonZeroComparison(): VmCodeChunk {
val elseBranch = when(ifElse.condition.operator) {
"==" -> Opcode.BNE
"!=" -> Opcode.BEQ
"<" -> if(signed) Opcode.BGES else Opcode.BGE
">" -> if(signed) Opcode.BLES else Opcode.BLE
"<=" -> if(signed) Opcode.BGTS else Opcode.BGT
">=" -> if(signed) Opcode.BLTS else Opcode.BLT
else -> throw AssemblyError("invalid comparison operator")
}
val leftReg = vmRegisters.nextFree()
val rightReg = vmRegisters.nextFree()
code += expressionEval.translateExpression(ifElse.condition.left, leftReg, -1)
code += expressionEval.translateExpression(ifElse.condition.right, rightReg, -1)
if(ifElse.elseScope.children.isNotEmpty()) {
// if and else parts
val elseLabel = createLabelName()
val afterIfLabel = createLabelName()
code += VmCodeInstruction(elseBranch, vmDt, reg1=leftReg, reg2=rightReg, labelSymbol = elseLabel)
code += translateNode(ifElse.ifScope)
code += VmCodeInstruction(Opcode.JUMP, labelSymbol = afterIfLabel)
code += VmCodeLabel(elseLabel)
code += translateNode(ifElse.elseScope)
code += VmCodeLabel(afterIfLabel)
} else {
// only if part
val afterIfLabel = createLabelName()
code += VmCodeInstruction(elseBranch, vmDt, reg1=leftReg, reg2=rightReg, labelSymbol = afterIfLabel)
code += translateNode(ifElse.ifScope)
code += VmCodeLabel(afterIfLabel)
}
return code
}
fun translateZeroComparison(): VmCodeChunk {
fun equalOrNotEqualZero(elseBranch: Opcode): VmCodeChunk {
val leftReg = vmRegisters.nextFree()
code += expressionEval.translateExpression(ifElse.condition.left, leftReg, -1)
if(ifElse.elseScope.children.isNotEmpty()) {
// if and else parts
val elseLabel = createLabelName()
val afterIfLabel = createLabelName()
code += VmCodeInstruction(elseBranch, vmDt, reg1=leftReg, labelSymbol = elseLabel)
code += translateNode(ifElse.ifScope)
code += VmCodeInstruction(Opcode.JUMP, labelSymbol = afterIfLabel)
code += VmCodeLabel(elseLabel)
code += translateNode(ifElse.elseScope)
code += VmCodeLabel(afterIfLabel)
} else {
// only if part
val afterIfLabel = createLabelName()
code += VmCodeInstruction(elseBranch, vmDt, reg1=leftReg, labelSymbol = afterIfLabel)
code += translateNode(ifElse.ifScope)
code += VmCodeLabel(afterIfLabel)
}
return code
}
return when (ifElse.condition.operator) {
"==" -> {
// if X==0 ... so we just branch on left expr is Not-zero.
equalOrNotEqualZero(Opcode.BNZ)
}
"!=" -> {
// if X!=0 ... so we just branch on left expr is Zero.
equalOrNotEqualZero(Opcode.BZ)
}
else -> {
// another comparison against 0, just use regular codegen for this.
translateNonZeroComparison()
}
}
}
return if(constValue(ifElse.condition.right)==0.0)
translateZeroComparison()
else
translateNonZeroComparison()
}
private fun translate(postIncrDecr: PtPostIncrDecr): VmCodeChunk {
val code = VmCodeChunk()
val operationMem: Opcode
val operationRegister: Opcode
when(postIncrDecr.operator) {
"++" -> {
operationMem = Opcode.INCM
operationRegister = Opcode.INC
}
"--" -> {
operationMem = Opcode.DECM
operationRegister = Opcode.DEC
}
else -> throw AssemblyError("weird operator")
}
val ident = postIncrDecr.target.identifier
val memory = postIncrDecr.target.memory
val array = postIncrDecr.target.array
val vmDt = vmType(postIncrDecr.target.type)
if(ident!=null) {
val address = allocations.get(ident.targetName)
code += VmCodeInstruction(operationMem, vmDt, value = address)
} else if(memory!=null) {
if(memory.address is PtNumber) {
val address = (memory.address as PtNumber).number.toInt()
code += VmCodeInstruction(operationMem, vmDt, value = address)
} else {
val incReg = vmRegisters.nextFree()
val addressReg = vmRegisters.nextFree()
code += expressionEval.translateExpression(memory.address, addressReg, -1)
code += VmCodeInstruction(Opcode.LOADI, vmDt, reg1 = incReg, reg2 = addressReg)
code += VmCodeInstruction(operationRegister, vmDt, reg1 = incReg)
code += VmCodeInstruction(Opcode.STOREI, vmDt, reg1 = incReg, reg2 = addressReg)
}
} else if (array!=null) {
val variable = array.variable.targetName
var variableAddr = allocations.get(variable)
val itemsize = program.memsizer.memorySize(array.type)
val fixedIndex = constIntValue(array.index)
if(fixedIndex!=null) {
variableAddr += fixedIndex*itemsize
code += VmCodeInstruction(operationMem, vmDt, value=variableAddr)
} else {
val incReg = vmRegisters.nextFree()
val indexReg = vmRegisters.nextFree()
code += expressionEval.translateExpression(array.index, indexReg, -1)
code += VmCodeInstruction(Opcode.LOADX, vmDt, reg1=incReg, reg2=indexReg, value=variableAddr)
code += VmCodeInstruction(operationRegister, vmDt, reg1=incReg)
code += VmCodeInstruction(Opcode.STOREX, vmDt, reg1=incReg, reg2=indexReg, value=variableAddr)
}
} else
throw AssemblyError("weird assigntarget")
return code
}
private fun translate(repeat: PtRepeatLoop): VmCodeChunk {
when (constIntValue(repeat.count)) {
0 -> return VmCodeChunk()
1 -> return translateGroup(repeat.children)
256 -> {
// 256 iterations can still be done with just a byte counter if you set it to zero as starting value.
repeat.children[0] = PtNumber(DataType.UBYTE, 0.0, repeat.count.position)
}
}
val code = VmCodeChunk()
val counterReg = vmRegisters.nextFree()
val vmDt = vmType(repeat.count.type)
code += expressionEval.translateExpression(repeat.count, counterReg, -1)
val repeatLabel = createLabelName()
code += VmCodeLabel(repeatLabel)
code += translateNode(repeat.statements)
code += VmCodeInstruction(Opcode.DEC, vmDt, reg1=counterReg)
code += VmCodeInstruction(Opcode.BNZ, vmDt, reg1=counterReg, labelSymbol = repeatLabel)
return code
}
private fun translate(jump: PtJump): VmCodeChunk {
val code = VmCodeChunk()
if(jump.address!=null)
throw AssemblyError("cannot jump to memory location in the vm target")
code += if(jump.generatedLabel!=null)
VmCodeInstruction(Opcode.JUMP, labelSymbol = listOf(jump.generatedLabel!!))
else if(jump.identifier!=null)
VmCodeInstruction(Opcode.JUMP, labelSymbol = jump.identifier!!.targetName)
else
throw AssemblyError("weird jump")
return code
}
private fun translateGroup(group: List<PtNode>): VmCodeChunk {
val code = VmCodeChunk()
group.forEach { code += translateNode(it) }
return code
}
private fun translate(ret: PtReturn): VmCodeChunk {
val code = VmCodeChunk()
val value = ret.value
if(value!=null) {
// Call Convention: return value is always returned in r0 (or fr0 if float)
code += if(value.type==DataType.FLOAT)
expressionEval.translateExpression(value, -1, 0)
else
expressionEval.translateExpression(value, 0, -1)
}
code += VmCodeInstruction(Opcode.RETURN)
return code
}
private fun translate(sub: PtSub): VmCodeChunk {
val code = VmCodeChunk()
code += VmCodeComment("SUB: ${sub.scopedName} -> ${sub.returntype}")
code += VmCodeLabel(sub.scopedName)
for (child in sub.children) {
code += translateNode(child)
}
code += VmCodeComment("SUB-END '${sub.name}'")
return code
}
private fun translate(block: PtBlock): VmCodeChunk {
val code = VmCodeChunk()
code += VmCodeComment("BLOCK '${block.name}' addr=${block.address} lib=${block.library}")
for (child in block.children) {
if(child !is PtAssignment) // global variable initialization is done elsewhere
code += translateNode(child)
}
code += VmCodeComment("BLOCK-END '${block.name}'")
return code
}
internal fun vmType(type: DataType): VmDataType {
return when(type) {
DataType.BOOL,
DataType.UBYTE,
DataType.BYTE -> VmDataType.BYTE
DataType.UWORD,
DataType.WORD -> VmDataType.WORD
DataType.FLOAT -> VmDataType.FLOAT
in PassByReferenceDatatypes -> VmDataType.WORD
else -> throw AssemblyError("no vm datatype for $type")
}
}
private var labelSequenceNumber = 0
internal fun createLabelName(): List<String> {
labelSequenceNumber++
return listOf("prog8_label_gen_$labelSequenceNumber")
}
internal fun translateBuiltinFunc(call: PtBuiltinFunctionCall, resultRegister: Int): VmCodeChunk =
builtinFuncGen.translate(call, resultRegister)
internal fun isZero(expression: PtExpression): Boolean = expression is PtNumber && expression.number==0.0
internal fun isOne(expression: PtExpression): Boolean = expression is PtNumber && expression.number==1.0
}

856
codeGenVirtual/src/prog8/codegen/virtual/ExpressionGen.kt
View File

@ -1,856 +0,0 @@
package prog8.codegen.virtual
import prog8.code.StStaticVariable
import prog8.code.StSub
import prog8.code.ast.*
import prog8.code.core.*
import prog8.vm.Opcode
import prog8.vm.VmDataType
internal class ExpressionGen(private val codeGen: CodeGen) {
fun translateExpression(expr: PtExpression, resultRegister: Int, resultFpRegister: Int): VmCodeChunk {
require(codeGen.vmRegisters.peekNext() > resultRegister)
val code = VmCodeChunk()
when (expr) {
is PtMachineRegister -> {
if(resultRegister!=expr.register) {
val vmDt = codeGen.vmType(expr.type)
code += VmCodeInstruction(Opcode.LOADR, vmDt, reg1=resultRegister, reg2=expr.register)
}
}
is PtNumber -> {
val vmDt = codeGen.vmType(expr.type)
code += if(vmDt==VmDataType.FLOAT)
VmCodeInstruction(Opcode.LOAD, vmDt, fpReg1 = resultFpRegister, fpValue = expr.number.toFloat())
else
VmCodeInstruction(Opcode.LOAD, vmDt, reg1=resultRegister, value=expr.number.toInt())
}
is PtIdentifier -> {
val vmDt = codeGen.vmType(expr.type)
val mem = codeGen.allocations.get(expr.targetName)
code += if (expr.type in PassByValueDatatypes) {
if(vmDt==VmDataType.FLOAT)
VmCodeInstruction(Opcode.LOADM, vmDt, fpReg1 = resultFpRegister, value = mem)
else
VmCodeInstruction(Opcode.LOADM, vmDt, reg1 = resultRegister, value = mem)
} else {
// for strings and arrays etc., load the *address* of the value instead
VmCodeInstruction(Opcode.LOAD, vmDt, reg1 = resultRegister, value = mem)
}
}
is PtAddressOf -> {
val vmDt = codeGen.vmType(expr.type)
val mem = codeGen.allocations.get(expr.identifier.targetName)
code += VmCodeInstruction(Opcode.LOAD, vmDt, reg1=resultRegister, value=mem)
}
is PtMemoryByte -> {
if(expr.address is PtNumber) {
val address = (expr.address as PtNumber).number.toInt()
code += VmCodeInstruction(Opcode.LOADM, VmDataType.BYTE, reg1=resultRegister, value = address)
} else {
val addressRegister = codeGen.vmRegisters.nextFree()
code += translateExpression(expr.address, addressRegister, -1)
code += VmCodeInstruction(Opcode.LOADI, VmDataType.BYTE, reg1=resultRegister, reg2=addressRegister)
}
}
is PtTypeCast -> code += translate(expr, resultRegister, resultFpRegister)
is PtPrefix -> code += translate(expr, resultRegister)
is PtArrayIndexer -> code += translate(expr, resultRegister, resultFpRegister)
is PtBinaryExpression -> code += translate(expr, resultRegister, resultFpRegister)
is PtBuiltinFunctionCall -> code += codeGen.translateBuiltinFunc(expr, resultRegister)
is PtFunctionCall -> code += translate(expr, resultRegister, resultFpRegister)
is PtContainmentCheck -> code += translate(expr, resultRegister, resultFpRegister)
is PtRange,
is PtArray,
is PtString -> throw AssemblyError("range/arrayliteral/string should no longer occur as expression")
else -> throw AssemblyError("weird expression")
}
return code
}
private fun translate(check: PtContainmentCheck, resultRegister: Int, resultFpRegister: Int): VmCodeChunk {
val code = VmCodeChunk()
code += translateExpression(check.element, resultRegister, -1) // load the element to check in resultRegister
val iterable = codeGen.symbolTable.flat.getValue(check.iterable.targetName) as StStaticVariable
when(iterable.dt) {
DataType.STR -> {
val call = PtFunctionCall(listOf("prog8_lib", "string_contains"), false, DataType.UBYTE, check.position)
call.children.add(check.element)
call.children.add(check.iterable)
code += translate(call, resultRegister, resultFpRegister)
}
DataType.ARRAY_UB, DataType.ARRAY_B -> {
val call = PtFunctionCall(listOf("prog8_lib", "bytearray_contains"), false, DataType.UBYTE, check.position)
call.children.add(check.element)
call.children.add(check.iterable)
call.children.add(PtNumber(DataType.UBYTE, iterable.length!!.toDouble(), iterable.position))
code += translate(call, resultRegister, resultFpRegister)
}
DataType.ARRAY_UW, DataType.ARRAY_W -> {
val call = PtFunctionCall(listOf("prog8_lib", "wordarray_contains"), false, DataType.UBYTE, check.position)
call.children.add(check.element)
call.children.add(check.iterable)
call.children.add(PtNumber(DataType.UBYTE, iterable.length!!.toDouble(), iterable.position))
code += translate(call, resultRegister, resultFpRegister)
}
DataType.ARRAY_F -> throw AssemblyError("containment check in float-array not supported")
else -> throw AssemblyError("weird iterable dt ${iterable.dt} for ${check.iterable.targetName}")
}
return code
}
private fun translate(arrayIx: PtArrayIndexer, resultRegister: Int, resultFpRegister: Int): VmCodeChunk {
val eltSize = codeGen.program.memsizer.memorySize(arrayIx.type)
val vmDt = codeGen.vmType(arrayIx.type)
val code = VmCodeChunk()
val idxReg = codeGen.vmRegisters.nextFree()
val arrayLocation = codeGen.allocations.get(arrayIx.variable.targetName)
if(arrayIx.variable.type==DataType.UWORD) {
// indexing a pointer var instead of a real array or string
if(eltSize!=1)
throw AssemblyError("non-array var indexing requires bytes dt")
if(arrayIx.index.type!=DataType.UBYTE)
throw AssemblyError("non-array var indexing requires bytes index")
code += translateExpression(arrayIx.index, idxReg, -1)
code += VmCodeInstruction(Opcode.LOADIX, vmDt, reg1=resultRegister, reg2=idxReg, value = arrayLocation)
return code
}
if(arrayIx.index is PtNumber) {
// optimized code when index is known - just calculate the memory address here
val memOffset = (arrayIx.index as PtNumber).number.toInt() * eltSize
if(vmDt==VmDataType.FLOAT)
code += VmCodeInstruction(Opcode.LOADM, VmDataType.FLOAT, fpReg1=resultFpRegister, value=arrayLocation+memOffset)
else
code += VmCodeInstruction(Opcode.LOADM, vmDt, reg1=resultRegister, value=arrayLocation+memOffset)
} else {
code += translateExpression(arrayIx.index, idxReg, -1)
if(eltSize>1)
code += codeGen.multiplyByConst(VmDataType.BYTE, idxReg, eltSize)
if(vmDt==VmDataType.FLOAT)
code += VmCodeInstruction(Opcode.LOADX, VmDataType.FLOAT, fpReg1 = resultFpRegister, reg1=idxReg, value = arrayLocation)
else
code += VmCodeInstruction(Opcode.LOADX, vmDt, reg1=resultRegister, reg2=idxReg, value = arrayLocation)
}
return code
}
private fun translate(expr: PtPrefix, resultRegister: Int): VmCodeChunk {
val code = VmCodeChunk()
code += translateExpression(expr.value, resultRegister, -1)
val vmDt = codeGen.vmType(expr.type)
when(expr.operator) {
"+" -> { }
"-" -> {
code += VmCodeInstruction(Opcode.NEG, vmDt, reg1=resultRegister)
}
"~" -> {
val mask = if(vmDt==VmDataType.BYTE) 0x00ff else 0xffff
code += VmCodeInstruction(Opcode.XOR, vmDt, reg1=resultRegister, value=mask)
}
else -> throw AssemblyError("weird prefix operator")
}
return code
}
private fun translate(cast: PtTypeCast, predefinedResultRegister: Int, predefinedResultFpRegister: Int): VmCodeChunk {
val code = VmCodeChunk()
if(cast.type==cast.value.type)
return code
val actualResultFpReg = if(predefinedResultFpRegister>=0) predefinedResultFpRegister else codeGen.vmRegisters.nextFreeFloat()
val actualResultReg = if(predefinedResultRegister>=0) predefinedResultRegister else codeGen.vmRegisters.nextFree()
if(cast.value.type==DataType.FLOAT) {
// a cast from float to integer, so evaluate the value into a float register first
code += translateExpression(cast.value, -1, actualResultFpReg)
}
else
code += translateExpression(cast.value, actualResultReg, -1)
when(cast.type) {
DataType.UBYTE -> {
when(cast.value.type) {
DataType.BYTE, DataType.UWORD, DataType.WORD -> { /* just keep the LSB as it is */ }
DataType.FLOAT -> code += VmCodeInstruction(Opcode.FTOUB, VmDataType.FLOAT, reg1=actualResultReg, fpReg1 = actualResultFpReg)
else -> throw AssemblyError("weird cast value type")
}
}
DataType.BYTE -> {
when(cast.value.type) {
DataType.UBYTE, DataType.UWORD, DataType.WORD -> { /* just keep the LSB as it is */ }
DataType.FLOAT -> code += VmCodeInstruction(Opcode.FTOSB, VmDataType.FLOAT, reg1=actualResultReg, fpReg1 = actualResultFpReg)
else -> throw AssemblyError("weird cast value type")
}
}
DataType.UWORD -> {
when(cast.value.type) {
DataType.BYTE -> {
// byte -> uword: sign extend
code += VmCodeInstruction(Opcode.EXTS, type = VmDataType.BYTE, reg1 = actualResultReg)
}
DataType.UBYTE -> {
// ubyte -> uword: sign extend
code += VmCodeInstruction(Opcode.EXT, type = VmDataType.BYTE, reg1 = actualResultReg)
}
DataType.WORD -> { }
DataType.FLOAT -> {
code += VmCodeInstruction(Opcode.FTOUW, VmDataType.FLOAT, reg1=actualResultReg, fpReg1 = actualResultFpReg)
}
else -> throw AssemblyError("weird cast value type")
}
}
DataType.WORD -> {
when(cast.value.type) {
DataType.BYTE -> {
// byte -> word: sign extend
code += VmCodeInstruction(Opcode.EXTS, type = VmDataType.BYTE, reg1 = actualResultReg)
}
DataType.UBYTE -> {
// byte -> word: sign extend
code += VmCodeInstruction(Opcode.EXT, type = VmDataType.BYTE, reg1 = actualResultReg)
}
DataType.UWORD -> { }
DataType.FLOAT -> {
code += VmCodeInstruction(Opcode.FTOSW, VmDataType.FLOAT, reg1=actualResultReg, fpReg1 = actualResultFpReg)
}
else -> throw AssemblyError("weird cast value type")
}
}
DataType.FLOAT -> {
code += when(cast.value.type) {
DataType.UBYTE -> {
VmCodeInstruction(Opcode.FFROMUB, VmDataType.FLOAT, reg1=actualResultReg, fpReg1 = actualResultFpReg)
}
DataType.BYTE -> {
VmCodeInstruction(Opcode.FFROMSB, VmDataType.FLOAT, reg1=actualResultReg, fpReg1 = actualResultFpReg)
}
DataType.UWORD -> {
VmCodeInstruction(Opcode.FFROMUW, VmDataType.FLOAT, reg1=actualResultReg, fpReg1 = actualResultFpReg)
}
DataType.WORD -> {
VmCodeInstruction(Opcode.FFROMSW, VmDataType.FLOAT, reg1=actualResultReg, fpReg1 = actualResultFpReg)
}
else -> throw AssemblyError("weird cast value type")
}
}
else -> throw AssemblyError("weird cast type")
}
return code
}
private fun translate(binExpr: PtBinaryExpression, resultRegister: Int, resultFpRegister: Int): VmCodeChunk {
val vmDt = codeGen.vmType(binExpr.left.type)
val signed = binExpr.left.type in SignedDatatypes
return when(binExpr.operator) {
"+" -> operatorPlus(binExpr, vmDt, resultRegister, resultFpRegister)
"-" -> operatorMinus(binExpr, vmDt, resultRegister, resultFpRegister)
"*" -> operatorMultiply(binExpr, vmDt, resultRegister, resultFpRegister)
"/" -> operatorDivide(binExpr, vmDt, resultRegister, resultFpRegister, signed)
"%" -> operatorModulo(binExpr, vmDt, resultRegister)
"|" -> operatorOr(binExpr, vmDt, resultRegister)
"&" -> operatorAnd(binExpr, vmDt, resultRegister)
"^" -> operatorXor(binExpr, vmDt, resultRegister)
"<<" -> operatorShiftLeft(binExpr, vmDt, resultRegister)
">>" -> operatorShiftRight(binExpr, vmDt, resultRegister, signed)
"==" -> operatorEquals(binExpr, vmDt, resultRegister, false)
"!=" -> operatorEquals(binExpr, vmDt, resultRegister, true)
"<" -> operatorLessThan(binExpr, vmDt, resultRegister, signed, false)
">" -> operatorGreaterThan(binExpr, vmDt, resultRegister, signed, false)
"<=" -> operatorLessThan(binExpr, vmDt, resultRegister, signed, true)
">=" -> operatorGreaterThan(binExpr, vmDt, resultRegister, signed, true)
else -> throw AssemblyError("weird operator ${binExpr.operator}")
}
}
private fun operatorGreaterThan(
binExpr: PtBinaryExpression,
vmDt: VmDataType,
resultRegister: Int,
signed: Boolean,
greaterEquals: Boolean
): VmCodeChunk {
val code = VmCodeChunk()
if(vmDt==VmDataType.FLOAT) {
val leftFpReg = codeGen.vmRegisters.nextFreeFloat()
val rightFpReg = codeGen.vmRegisters.nextFreeFloat()
val zeroRegister = codeGen.vmRegisters.nextFree()
code += translateExpression(binExpr.left, -1, leftFpReg)
code += translateExpression(binExpr.right, -1, rightFpReg)
code += VmCodeInstruction(Opcode.FCOMP, VmDataType.FLOAT, reg1=resultRegister, fpReg1 = leftFpReg, fpReg2 = rightFpReg)
code += VmCodeInstruction(Opcode.LOAD, VmDataType.BYTE, reg1=zeroRegister, value=0)
val ins = if (signed) {
if (greaterEquals) Opcode.SGES else Opcode.SGTS
} else {
if (greaterEquals) Opcode.SGE else Opcode.SGT
}
code += VmCodeInstruction(ins, VmDataType.BYTE, reg1 = resultRegister, reg2 = zeroRegister)
} else {
if(binExpr.left.type==DataType.STR && binExpr.right.type==DataType.STR) {
val comparisonCall = PtFunctionCall(listOf("prog8_lib", "string_compare"), false, DataType.BYTE, Position.DUMMY)
comparisonCall.children.add(binExpr.left)
comparisonCall.children.add(binExpr.right)
code += translate(comparisonCall, resultRegister, -1)
val zeroRegister = codeGen.vmRegisters.nextFree()
code += VmCodeInstruction(Opcode.LOAD, VmDataType.BYTE, reg1=zeroRegister, value=0)
code += if(greaterEquals)
VmCodeInstruction(Opcode.SGES, VmDataType.BYTE, reg1=resultRegister, reg2=zeroRegister)
else
VmCodeInstruction(Opcode.SGTS, VmDataType.BYTE, reg1=resultRegister, reg2=zeroRegister)
} else {
val rightResultReg = codeGen.vmRegisters.nextFree()
code += translateExpression(binExpr.left, resultRegister, -1)
code += translateExpression(binExpr.right, rightResultReg, -1)
val ins = if (signed) {
if (greaterEquals) Opcode.SGES else Opcode.SGTS
} else {
if (greaterEquals) Opcode.SGE else Opcode.SGT
}
code += VmCodeInstruction(ins, vmDt, reg1 = resultRegister, reg2 = rightResultReg)
}
}
return code
}
private fun operatorLessThan(
binExpr: PtBinaryExpression,
vmDt: VmDataType,
resultRegister: Int,
signed: Boolean,
lessEquals: Boolean
): VmCodeChunk {
val code = VmCodeChunk()
if(vmDt==VmDataType.FLOAT) {
val leftFpReg = codeGen.vmRegisters.nextFreeFloat()
val rightFpReg = codeGen.vmRegisters.nextFreeFloat()
val zeroRegister = codeGen.vmRegisters.nextFree()
code += translateExpression(binExpr.left, -1, leftFpReg)
code += translateExpression(binExpr.right, -1, rightFpReg)
code += VmCodeInstruction(Opcode.FCOMP, VmDataType.FLOAT, reg1=resultRegister, fpReg1 = leftFpReg, fpReg2 = rightFpReg)
code += VmCodeInstruction(Opcode.LOAD, VmDataType.BYTE, reg1=zeroRegister, value=0)
val ins = if (signed) {
if (lessEquals) Opcode.SLES else Opcode.SLTS
} else {
if (lessEquals) Opcode.SLE else Opcode.SLT
}
code += VmCodeInstruction(ins, VmDataType.BYTE, reg1 = resultRegister, reg2 = zeroRegister)
} else {
if(binExpr.left.type==DataType.STR && binExpr.right.type==DataType.STR) {
val comparisonCall = PtFunctionCall(listOf("prog8_lib", "string_compare"), false, DataType.BYTE, Position.DUMMY)
comparisonCall.children.add(binExpr.left)
comparisonCall.children.add(binExpr.right)
code += translate(comparisonCall, resultRegister, -1)
val zeroRegister = codeGen.vmRegisters.nextFree()
code += VmCodeInstruction(Opcode.LOAD, VmDataType.BYTE, reg1=zeroRegister, value=0)
code += if(lessEquals)
VmCodeInstruction(Opcode.SLES, VmDataType.BYTE, reg1=resultRegister, reg2=zeroRegister)
else
VmCodeInstruction(Opcode.SLTS, VmDataType.BYTE, reg1=resultRegister, reg2=zeroRegister)
} else {
val rightResultReg = codeGen.vmRegisters.nextFree()
code += translateExpression(binExpr.left, resultRegister, -1)
code += translateExpression(binExpr.right, rightResultReg, -1)
val ins = if (signed) {
if (lessEquals) Opcode.SLES else Opcode.SLTS
} else {
if (lessEquals) Opcode.SLE else Opcode.SLT
}
code += VmCodeInstruction(ins, vmDt, reg1 = resultRegister, reg2 = rightResultReg)
}
}
return code
}
private fun operatorEquals(binExpr: PtBinaryExpression, vmDt: VmDataType, resultRegister: Int, notEquals: Boolean): VmCodeChunk {
val code = VmCodeChunk()
if(vmDt==VmDataType.FLOAT) {
val leftFpReg = codeGen.vmRegisters.nextFreeFloat()
val rightFpReg = codeGen.vmRegisters.nextFreeFloat()
code += translateExpression(binExpr.left, -1, leftFpReg)
code += translateExpression(binExpr.right, -1, rightFpReg)
if (notEquals) {
code += VmCodeInstruction(Opcode.FCOMP, VmDataType.FLOAT, reg1=resultRegister, fpReg1 = leftFpReg, fpReg2 = rightFpReg)
} else {
val label = codeGen.createLabelName()
val valueReg = codeGen.vmRegisters.nextFree()
code += VmCodeInstruction(Opcode.LOAD, VmDataType.BYTE, reg1=resultRegister, value=1)
code += VmCodeInstruction(Opcode.FCOMP, VmDataType.FLOAT, reg1=valueReg, fpReg1 = leftFpReg, fpReg2 = rightFpReg)
code += VmCodeInstruction(Opcode.BZ, VmDataType.BYTE, reg1=valueReg, labelSymbol = label)
code += VmCodeInstruction(Opcode.LOAD, VmDataType.BYTE, reg1=resultRegister, value=0)
code += VmCodeLabel(label)
}
} else {
if(binExpr.left.type==DataType.STR && binExpr.right.type==DataType.STR) {
val comparisonCall = PtFunctionCall(listOf("prog8_lib", "string_compare"), false, DataType.BYTE, Position.DUMMY)
comparisonCall.children.add(binExpr.left)
comparisonCall.children.add(binExpr.right)
code += translate(comparisonCall, resultRegister, -1)
if(!notEquals)
code += VmCodeInstruction(Opcode.INV, vmDt, reg1=resultRegister)
code += VmCodeInstruction(Opcode.AND, vmDt, reg1=resultRegister, value=1)
} else {
val rightResultReg = codeGen.vmRegisters.nextFree()
code += translateExpression(binExpr.left, resultRegister, -1)
code += translateExpression(binExpr.right, rightResultReg, -1)
val opcode = if (notEquals) Opcode.SNE else Opcode.SEQ
code += VmCodeInstruction(opcode, vmDt, reg1 = resultRegister, reg2 = rightResultReg)
}
}
return code
}
private fun operatorShiftRight(binExpr: PtBinaryExpression, vmDt: VmDataType, resultRegister: Int, signed: Boolean): VmCodeChunk {
val code = VmCodeChunk()
if(codeGen.isOne(binExpr.right)) {
code += translateExpression(binExpr.left, resultRegister, -1)
val opc = if (signed) Opcode.ASR else Opcode.LSR
code += VmCodeInstruction(opc, vmDt, reg1 = resultRegister)
} else {
val rightResultReg = codeGen.vmRegisters.nextFree()
code += translateExpression(binExpr.left, resultRegister, -1)
code += translateExpression(binExpr.right, rightResultReg, -1)
val opc = if (signed) Opcode.ASRN else Opcode.LSRN
code += VmCodeInstruction(opc, vmDt, reg1 = resultRegister, reg2 = rightResultReg)
}
return code
}
internal fun operatorShiftRightInplace(address: Int, vmDt: VmDataType, signed: Boolean, operand: PtExpression): VmCodeChunk {
val code = VmCodeChunk()
if(codeGen.isOne(operand)) {
val opc = if (signed) Opcode.ASRM else Opcode.LSRM
code += VmCodeInstruction(opc, vmDt, value=address)
} else {
val operandReg = codeGen.vmRegisters.nextFree()
code += translateExpression(operand, operandReg, -1)
val opc = if (signed) Opcode.ASRNM else Opcode.LSRNM
code += VmCodeInstruction(opc, vmDt, reg1 = operandReg, value=address)
}
return code
}
private fun operatorShiftLeft(binExpr: PtBinaryExpression, vmDt: VmDataType, resultRegister: Int): VmCodeChunk {
val code = VmCodeChunk()
if(codeGen.isOne(binExpr.right)){
code += translateExpression(binExpr.left, resultRegister, -1)
code += VmCodeInstruction(Opcode.LSL, vmDt, reg1=resultRegister)
} else {
val rightResultReg = codeGen.vmRegisters.nextFree()
code += translateExpression(binExpr.left, resultRegister, -1)
code += translateExpression(binExpr.right, rightResultReg, -1)
code += VmCodeInstruction(Opcode.LSLN, vmDt, reg1=resultRegister, rightResultReg)
}
return code
}
internal fun operatorShiftLeftInplace(address: Int, vmDt: VmDataType, operand: PtExpression): VmCodeChunk {
val code = VmCodeChunk()
if(codeGen.isOne(operand)){
code += VmCodeInstruction(Opcode.LSLM, vmDt, value=address)
} else {
val operandReg = codeGen.vmRegisters.nextFree()
code += translateExpression(operand, operandReg, -1)
code += VmCodeInstruction(Opcode.LSLNM, vmDt, reg1=operandReg, value=address)
}
return code
}
private fun operatorXor(binExpr: PtBinaryExpression, vmDt: VmDataType, resultRegister: Int): VmCodeChunk {
val code = VmCodeChunk()
if(binExpr.right is PtNumber) {
code += translateExpression(binExpr.left, resultRegister, -1)
code += VmCodeInstruction(Opcode.XOR, vmDt, reg1 = resultRegister, value=(binExpr.right as PtNumber).number.toInt())
} else {
val rightResultReg = codeGen.vmRegisters.nextFree()
code += translateExpression(binExpr.left, resultRegister, -1)
code += translateExpression(binExpr.right, rightResultReg, -1)
code += VmCodeInstruction(Opcode.XORR, vmDt, reg1 = resultRegister, reg2 = rightResultReg)
}
return code
}
internal fun operatorXorInplace(address: Int, vmDt: VmDataType, operand: PtExpression): VmCodeChunk {
val code = VmCodeChunk()
val operandReg = codeGen.vmRegisters.nextFree()
code += translateExpression(operand, operandReg, -1)
code += VmCodeInstruction(Opcode.XORM, vmDt, reg1=operandReg, value = address)
return code
}
private fun operatorAnd(binExpr: PtBinaryExpression, vmDt: VmDataType, resultRegister: Int): VmCodeChunk {
val code = VmCodeChunk()
if(binExpr.right is PtNumber) {
code += translateExpression(binExpr.left, resultRegister, -1)
code += VmCodeInstruction(Opcode.AND, vmDt, reg1 = resultRegister, value=(binExpr.right as PtNumber).number.toInt())
} else {
val rightResultReg = codeGen.vmRegisters.nextFree()
code += translateExpression(binExpr.left, resultRegister, -1)
code += translateExpression(binExpr.right, rightResultReg, -1)
code += VmCodeInstruction(Opcode.ANDR, vmDt, reg1 = resultRegister, reg2 = rightResultReg)
}
return code
}
internal fun operatorAndInplace(address: Int, vmDt: VmDataType, operand: PtExpression): VmCodeChunk {
val code = VmCodeChunk()
val operandReg = codeGen.vmRegisters.nextFree()
code += translateExpression(operand, operandReg, -1)
code += VmCodeInstruction(Opcode.ANDM, vmDt, reg1=operandReg, value=address)
return code
}
private fun operatorOr(binExpr: PtBinaryExpression, vmDt: VmDataType, resultRegister: Int): VmCodeChunk {
val code = VmCodeChunk()
if(binExpr.right is PtNumber) {
code += translateExpression(binExpr.left, resultRegister, -1)
code += VmCodeInstruction(Opcode.OR, vmDt, reg1 = resultRegister, value=(binExpr.right as PtNumber).number.toInt())
} else {
val rightResultReg = codeGen.vmRegisters.nextFree()
code += translateExpression(binExpr.left, resultRegister, -1)
code += translateExpression(binExpr.right, rightResultReg, -1)
code += VmCodeInstruction(Opcode.ORR, vmDt, reg1 = resultRegister, reg2 = rightResultReg)
}
return code
}
internal fun operatorOrInplace(address: Int, vmDt: VmDataType, operand: PtExpression): VmCodeChunk {
val code = VmCodeChunk()
val operandReg = codeGen.vmRegisters.nextFree()
code += translateExpression(operand, operandReg, -1)
code += VmCodeInstruction(Opcode.ORM, vmDt, reg1=operandReg, value = address)
return code
}
private fun operatorModulo(binExpr: PtBinaryExpression, vmDt: VmDataType, resultRegister: Int): VmCodeChunk {
if(vmDt==VmDataType.FLOAT)
throw IllegalArgumentException("floating-point modulo not supported")
val code = VmCodeChunk()
val rightResultReg = codeGen.vmRegisters.nextFree()
if(binExpr.right is PtNumber) {
code += translateExpression(binExpr.left, resultRegister, -1)
code += VmCodeInstruction(Opcode.MOD, vmDt, reg1 = resultRegister, value=(binExpr.right as PtNumber).number.toInt())
} else {
code += translateExpression(binExpr.left, resultRegister, -1)
code += translateExpression(binExpr.right, rightResultReg, -1)
code += VmCodeInstruction(Opcode.MODR, vmDt, reg1 = resultRegister, reg2 = rightResultReg)
}
return code
}
private fun operatorDivide(binExpr: PtBinaryExpression,
vmDt: VmDataType,
resultRegister: Int,
resultFpRegister: Int,
signed: Boolean): VmCodeChunk {
val code = VmCodeChunk()
val constFactorRight = binExpr.right as? PtNumber
if(vmDt==VmDataType.FLOAT) {
if(constFactorRight!=null && constFactorRight.type!=DataType.FLOAT) {
code += translateExpression(binExpr.left, -1, resultFpRegister)
val factor = constFactorRight.number.toFloat()
code += codeGen.divideByConstFloat(resultFpRegister, factor)
} else {
val rightResultFpReg = codeGen.vmRegisters.nextFreeFloat()
code += translateExpression(binExpr.left, -1, resultFpRegister)
code += translateExpression(binExpr.right, -1, rightResultFpReg)
code += if(signed)
VmCodeInstruction(Opcode.DIVSR, vmDt, fpReg1 = resultFpRegister, fpReg2=rightResultFpReg)
else
VmCodeInstruction(Opcode.DIVR, vmDt, fpReg1 = resultFpRegister, fpReg2=rightResultFpReg)
}
} else {
if(constFactorRight!=null && constFactorRight.type!=DataType.FLOAT) {
code += translateExpression(binExpr.left, resultRegister, -1)
val factor = constFactorRight.number.toInt()
code += codeGen.divideByConst(vmDt, resultRegister, factor, signed)
} else {
val rightResultReg = codeGen.vmRegisters.nextFree()
if(binExpr.right is PtNumber) {
code += translateExpression(binExpr.left, resultRegister, -1)
code += if (signed)
VmCodeInstruction(Opcode.DIVS, vmDt, reg1 = resultRegister, value=(binExpr.right as PtNumber).number.toInt())
else
VmCodeInstruction(Opcode.DIV, vmDt, reg1 = resultRegister, value=(binExpr.right as PtNumber).number.toInt())
} else {
code += translateExpression(binExpr.left, resultRegister, -1)
code += translateExpression(binExpr.right, rightResultReg, -1)
code += if (signed)
VmCodeInstruction(Opcode.DIVSR, vmDt, reg1 = resultRegister, reg2 = rightResultReg)
else
VmCodeInstruction(Opcode.DIVR, vmDt, reg1 = resultRegister, reg2 = rightResultReg)
}
}
}
return code
}
internal fun operatorDivideInplace(address: Int, vmDt: VmDataType, signed: Boolean, operand: PtExpression): VmCodeChunk {
val code = VmCodeChunk()
val constFactorRight = operand as? PtNumber
if(vmDt==VmDataType.FLOAT) {
if(constFactorRight!=null && constFactorRight.type!=DataType.FLOAT) {
val factor = constFactorRight.number.toFloat()
code += codeGen.divideByConstFloatInplace(address, factor)
} else {
val operandFpReg = codeGen.vmRegisters.nextFreeFloat()
code += translateExpression(operand, -1, operandFpReg)
code += if(signed)
VmCodeInstruction(Opcode.DIVSM, vmDt, fpReg1 = operandFpReg, value=address)
else
VmCodeInstruction(Opcode.DIVM, vmDt, fpReg1 = operandFpReg, value=address)
}
} else {
if(constFactorRight!=null && constFactorRight.type!=DataType.FLOAT) {
val factor = constFactorRight.number.toInt()
code += codeGen.divideByConstInplace(vmDt, address, factor, signed)
} else {
val operandReg = codeGen.vmRegisters.nextFree()
code += translateExpression(operand, operandReg, -1)
code += if(signed)
VmCodeInstruction(Opcode.DIVSM, vmDt, reg1=operandReg, value = address)
else
VmCodeInstruction(Opcode.DIVM, vmDt, reg1=operandReg, value = address)
}
}
return code
}
private fun operatorMultiply(binExpr: PtBinaryExpression, vmDt: VmDataType, resultRegister: Int, resultFpRegister: Int): VmCodeChunk {
val code = VmCodeChunk()
val constFactorLeft = binExpr.left as? PtNumber
val constFactorRight = binExpr.right as? PtNumber
if(vmDt==VmDataType.FLOAT) {
if(constFactorLeft!=null) {
code += translateExpression(binExpr.right, -1, resultFpRegister)
val factor = constFactorLeft.number.toFloat()
code += codeGen.multiplyByConstFloat(resultFpRegister, factor)
} else if(constFactorRight!=null) {
code += translateExpression(binExpr.left, -1, resultFpRegister)
val factor = constFactorRight.number.toFloat()
code += codeGen.multiplyByConstFloat(resultFpRegister, factor)
} else {
val rightResultFpReg = codeGen.vmRegisters.nextFreeFloat()
code += translateExpression(binExpr.left, -1, resultFpRegister)
code += translateExpression(binExpr.right, -1, rightResultFpReg)
code += VmCodeInstruction(Opcode.MULR, vmDt, fpReg1 = resultFpRegister, fpReg2 = rightResultFpReg)
}
} else {
if(constFactorLeft!=null && constFactorLeft.type!=DataType.FLOAT) {
code += translateExpression(binExpr.right, resultRegister, -1)
val factor = constFactorLeft.number.toInt()
code += codeGen.multiplyByConst(vmDt, resultRegister, factor)
} else if(constFactorRight!=null && constFactorRight.type!=DataType.FLOAT) {
code += translateExpression(binExpr.left, resultRegister, -1)
val factor = constFactorRight.number.toInt()
code += codeGen.multiplyByConst(vmDt, resultRegister, factor)
} else {
val rightResultReg = codeGen.vmRegisters.nextFree()
code += translateExpression(binExpr.left, resultRegister, -1)
code += translateExpression(binExpr.right, rightResultReg, -1)
code += VmCodeInstruction(Opcode.MULR, vmDt, reg1 = resultRegister, reg2 = rightResultReg)
}
}
return code
}
internal fun operatorMultiplyInplace(address: Int, vmDt: VmDataType, operand: PtExpression): VmCodeChunk {
val code = VmCodeChunk()
val constFactorRight = operand as? PtNumber
if(vmDt==VmDataType.FLOAT) {
if(constFactorRight!=null) {
val factor = constFactorRight.number.toFloat()
code += codeGen.multiplyByConstFloatInplace(address, factor)
} else {
val operandFpReg = codeGen.vmRegisters.nextFreeFloat()
code += translateExpression(operand, -1, operandFpReg)
code += VmCodeInstruction(Opcode.MULM, vmDt, fpReg1 = operandFpReg, value = address)
}
} else {
if(constFactorRight!=null && constFactorRight.type!=DataType.FLOAT) {
val factor = constFactorRight.number.toInt()
code += codeGen.multiplyByConstInplace(vmDt, address, factor)
} else {
val operandReg = codeGen.vmRegisters.nextFree()
code += translateExpression(operand, operandReg, -1)
code += VmCodeInstruction(Opcode.MULM, vmDt, reg1=operandReg, value = address)
}
}
return code
}
private fun operatorMinus(binExpr: PtBinaryExpression, vmDt: VmDataType, resultRegister: Int, resultFpRegister: Int): VmCodeChunk {
val code = VmCodeChunk()
if(vmDt==VmDataType.FLOAT) {
if((binExpr.right as? PtNumber)?.number==1.0) {
code += translateExpression(binExpr.left, -1, resultFpRegister)
code += VmCodeInstruction(Opcode.DEC, vmDt, fpReg1 = resultFpRegister)
}
else {
if(binExpr.right is PtNumber) {
code += translateExpression(binExpr.left, -1, resultFpRegister)
code += VmCodeInstruction(Opcode.SUB, vmDt, fpReg1 = resultFpRegister, fpValue = (binExpr.right as PtNumber).number.toFloat())
} else {
val rightResultFpReg = codeGen.vmRegisters.nextFreeFloat()
code += translateExpression(binExpr.left, -1, resultFpRegister)
code += translateExpression(binExpr.right, -1, rightResultFpReg)
code += VmCodeInstruction(Opcode.SUBR, vmDt, fpReg1 = resultFpRegister, fpReg2 = rightResultFpReg)
}
}
} else {
if((binExpr.right as? PtNumber)?.number==1.0) {
code += translateExpression(binExpr.left, resultRegister, -1)
code += VmCodeInstruction(Opcode.DEC, vmDt, reg1=resultRegister)
}
else {
if(binExpr.right is PtNumber) {
code += translateExpression(binExpr.left, resultRegister, -1)
code += VmCodeInstruction(Opcode.SUB, vmDt, reg1 = resultRegister, value = (binExpr.right as PtNumber).number.toInt())
} else {
val rightResultReg = codeGen.vmRegisters.nextFree()
code += translateExpression(binExpr.left, resultRegister, -1)
code += translateExpression(binExpr.right, rightResultReg, -1)
code += VmCodeInstruction(Opcode.SUBR, vmDt, reg1 = resultRegister, reg2 = rightResultReg)
}
}
}
return code
}
internal fun operatorMinusInplace(address: Int, vmDt: VmDataType, operand: PtExpression): VmCodeChunk {
val code = VmCodeChunk()
if(vmDt==VmDataType.FLOAT) {
if((operand as? PtNumber)?.number==1.0) {
code += VmCodeInstruction(Opcode.DECM, vmDt, value=address)
}
else {
val operandFpReg = codeGen.vmRegisters.nextFreeFloat()
code += translateExpression(operand, -1, operandFpReg)
code += VmCodeInstruction(Opcode.SUBM, vmDt, fpReg1=operandFpReg, value=address)
}
} else {
if((operand as? PtNumber)?.number==1.0) {
code += VmCodeInstruction(Opcode.DECM, vmDt, value=address)
}
else {
val operandReg = codeGen.vmRegisters.nextFree()
code += translateExpression(operand, operandReg, -1)
code += VmCodeInstruction(Opcode.SUBM, vmDt, reg1=operandReg, value = address)
}
}
return code
}
private fun operatorPlus(binExpr: PtBinaryExpression, vmDt: VmDataType, resultRegister: Int, resultFpRegister: Int): VmCodeChunk {
val code = VmCodeChunk()
if(vmDt==VmDataType.FLOAT) {
if((binExpr.left as? PtNumber)?.number==1.0) {
code += translateExpression(binExpr.right, -1, resultFpRegister)
code += VmCodeInstruction(Opcode.INC, vmDt, fpReg1=resultFpRegister)
}
else if((binExpr.right as? PtNumber)?.number==1.0) {
code += translateExpression(binExpr.left, -1, resultFpRegister)
code += VmCodeInstruction(Opcode.INC, vmDt, fpReg1=resultFpRegister)
}
else {
if(binExpr.right is PtNumber) {
code += translateExpression(binExpr.left, -1, resultFpRegister)
code += VmCodeInstruction(Opcode.ADD, vmDt, fpReg1 = resultFpRegister, fpValue = (binExpr.right as PtNumber).number.toFloat())
} else {
val rightResultFpReg = codeGen.vmRegisters.nextFreeFloat()
code += translateExpression(binExpr.left, -1, resultFpRegister)
code += translateExpression(binExpr.right, -1, rightResultFpReg)
code += VmCodeInstruction(Opcode.ADDR, vmDt, fpReg1 = resultFpRegister, fpReg2 = rightResultFpReg)
}
}
} else {
if((binExpr.left as? PtNumber)?.number==1.0) {
code += translateExpression(binExpr.right, resultRegister, -1)
code += VmCodeInstruction(Opcode.INC, vmDt, reg1=resultRegister)
}
else if((binExpr.right as? PtNumber)?.number==1.0) {
code += translateExpression(binExpr.left, resultRegister, -1)
code += VmCodeInstruction(Opcode.INC, vmDt, reg1=resultRegister)
}
else {
if(binExpr.right is PtNumber) {
code += translateExpression(binExpr.left, resultRegister, -1)
code += VmCodeInstruction(Opcode.ADD, vmDt, reg1 = resultRegister, value=(binExpr.right as PtNumber).number.toInt())
} else {
val rightResultReg = codeGen.vmRegisters.nextFree()
code += translateExpression(binExpr.left, resultRegister, -1)
code += translateExpression(binExpr.right, rightResultReg, -1)
code += VmCodeInstruction(Opcode.ADDR, vmDt, reg1 = resultRegister, reg2 = rightResultReg)
}
}
}
return code
}
internal fun operatorPlusInplace(address: Int, vmDt: VmDataType, operand: PtExpression): VmCodeChunk {
val code = VmCodeChunk()
if(vmDt==VmDataType.FLOAT) {
if((operand as? PtNumber)?.number==1.0) {
code += VmCodeInstruction(Opcode.INCM, vmDt, value = address)
}
else {
val operandFpReg = codeGen.vmRegisters.nextFreeFloat()
code += translateExpression(operand, -1, operandFpReg)
code += VmCodeInstruction(Opcode.ADDM, vmDt, fpReg1=operandFpReg, value=address)
}
} else {
if((operand as? PtNumber)?.number==1.0) {
code += VmCodeInstruction(Opcode.INCM, vmDt, value = address)
}
else {
val operandReg = codeGen.vmRegisters.nextFree()
code += translateExpression(operand, operandReg, -1)
code += VmCodeInstruction(Opcode.ADDM, vmDt, reg1=operandReg, value=address)
}
}
return code
}
fun translate(fcall: PtFunctionCall, resultRegister: Int, resultFpRegister: Int): VmCodeChunk {
val subroutine = codeGen.symbolTable.flat.getValue(fcall.functionName) as StSub
val code = VmCodeChunk()
for ((arg, parameter) in fcall.args.zip(subroutine.parameters)) {
val paramDt = codeGen.vmType(parameter.type)
if(codeGen.isZero(arg)) {
if (paramDt == VmDataType.FLOAT) {
val mem = codeGen.allocations.get(fcall.functionName + parameter.name)
code += VmCodeInstruction(Opcode.STOREZM, paramDt, value = mem)
} else {
val mem = codeGen.allocations.get(fcall.functionName + parameter.name)
code += VmCodeInstruction(Opcode.STOREZM, paramDt, value = mem)
}
} else {
if (paramDt == VmDataType.FLOAT) {
val argFpReg = codeGen.vmRegisters.nextFreeFloat()
code += translateExpression(arg, -1, argFpReg)
val mem = codeGen.allocations.get(fcall.functionName + parameter.name)
code += VmCodeInstruction(Opcode.STOREM, paramDt, fpReg1 = argFpReg, value = mem)
} else {
val argReg = codeGen.vmRegisters.nextFree()
code += translateExpression(arg, argReg, -1)
val mem = codeGen.allocations.get(fcall.functionName + parameter.name)
code += VmCodeInstruction(Opcode.STOREM, paramDt, reg1 = argReg, value = mem)
}
}
}
code += VmCodeInstruction(Opcode.CALL, labelSymbol=fcall.functionName)
if(fcall.type==DataType.FLOAT) {
if (!fcall.void && resultFpRegister != 0) {
// Call convention: result value is in fr0, so put it in the required register instead.
code += VmCodeInstruction(Opcode.LOADR, VmDataType.FLOAT, fpReg1 = resultFpRegister, fpReg2 = 0)
}
} else {
if (!fcall.void && resultRegister != 0) {
// Call convention: result value is in r0, so put it in the required register instead.
code += VmCodeInstruction(Opcode.LOADR, codeGen.vmType(fcall.type), reg1 = resultRegister, reg2 = 0)
}
}
return code
}
}

103
codeGenVirtual/src/prog8/codegen/virtual/VariableAllocator.kt
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@ -1,103 +0,0 @@
package prog8.codegen.virtual
import prog8.code.SymbolTable
import prog8.code.ast.PtProgram
import prog8.code.core.*
class VariableAllocator(private val st: SymbolTable, private val program: PtProgram) {
private val allocations = mutableMapOf<List<String>, Int>()
private var freeMemoryStart: Int
val freeMem: Int
get() = freeMemoryStart
init {
var nextLocation = 0
for (variable in st.allVariables) {
val memsize =
when (variable.dt) {
DataType.STR -> variable.initialStringValue!!.first.length + 1 // include the zero byte
in NumericDatatypes -> program.memsizer.memorySize(variable.dt)
in ArrayDatatypes -> program.memsizer.memorySize(variable.dt, variable.length!!)
else -> throw InternalCompilerException("weird dt")
}
allocations[variable.scopedName] = nextLocation
nextLocation += memsize
}
for (memvar in st.allMemMappedVariables) {
// TODO virtual machine doesn't have memory mapped variables, so treat them as regular allocated variables for now
val memsize =
when (memvar.dt) {
in NumericDatatypes -> program.memsizer.memorySize(memvar.dt)
in ArrayDatatypes -> program.memsizer.memorySize(memvar.dt, memvar.length!!)
else -> throw InternalCompilerException("weird dt")
}
allocations[memvar.scopedName] = nextLocation
nextLocation += memsize
}
freeMemoryStart = nextLocation
}
fun get(name: List<String>) = allocations.getValue(name)
fun asVmMemory(): List<Pair<List<String>, String>> {
val mm = mutableListOf<Pair<List<String>, String>>()
for (variable in st.allVariables) {
val location = allocations.getValue(variable.scopedName)
val typeStr = when(variable.dt) {
DataType.UBYTE, DataType.ARRAY_UB, DataType.STR -> "ubyte"
DataType.BYTE, DataType.ARRAY_B -> "byte"
DataType.UWORD, DataType.ARRAY_UW -> "uword"
DataType.WORD, DataType.ARRAY_W -> "word"
DataType.FLOAT, DataType.ARRAY_F -> "float"
else -> throw InternalCompilerException("weird dt")
}
val value = when(variable.dt) {
DataType.FLOAT -> (variable.initialNumericValue ?: 0.0).toString()
in NumericDatatypes -> (variable.initialNumericValue ?: 0).toHex()
DataType.STR -> {
val encoded = program.encoding.encodeString(variable.initialStringValue!!.first, variable.initialStringValue!!.second)
encoded.joinToString(",") { it.toInt().toHex() } + ",0"
}
DataType.ARRAY_F -> {
if(variable.initialArrayValue!=null) {
variable.initialArrayValue!!.joinToString(",") { it.number!!.toString() }
} else {
(1..variable.length!!).joinToString(",") { "0" }
}
}
in ArrayDatatypes -> {
if(variable.initialArrayValue!==null) {
variable.initialArrayValue!!.joinToString(",") { it.number!!.toHex() }
} else {
(1..variable.length!!).joinToString(",") { "0" }
}
}
else -> throw InternalCompilerException("weird dt")
}
mm.add(Pair(variable.scopedName, "$location $typeStr $value"))
}
return mm
}
private val memorySlabsInternal = mutableMapOf<String, Triple<UInt, UInt, UInt>>()
internal val memorySlabs: Map<String, Triple<UInt, UInt, UInt>> = memorySlabsInternal
fun allocateMemorySlab(name: String, size: UInt, align: UInt): UInt {
val address =
if(align==0u || align==1u)
freeMemoryStart.toUInt()
else
(freeMemoryStart.toUInt() + align-1u) and (0xffffffffu xor (align-1u))
memorySlabsInternal[name] = Triple(address, size, align)
freeMemoryStart = (address + size).toInt()
return address
}
fun getMemorySlab(name: String): Triple<UInt, UInt, UInt>? = memorySlabsInternal[name]
}

189
codeGenVirtual/src/prog8/codegen/virtual/VmPeepholeOptimizer.kt
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@ -1,189 +0,0 @@
package prog8.codegen.virtual
import prog8.vm.Instruction
import prog8.vm.Opcode
import prog8.vm.VmDataType
internal class VmOptimizerException(msg: String): Exception(msg)
class VmPeepholeOptimizer(private val vmprog: AssemblyProgram, private val allocations: VariableAllocator) {
fun optimize() {
vmprog.getBlocks().forEach { block ->
do {
val indexedInstructions = block.lines.withIndex()
.filter { it.value is VmCodeInstruction }
.map { IndexedValue(it.index, (it.value as VmCodeInstruction).ins) }
val changed = removeNops(block, indexedInstructions)
|| removeDoubleLoadsAndStores(block, indexedInstructions) // TODO not yet implemented
|| removeUselessArithmetic(block, indexedInstructions)
|| removeWeirdBranches(block, indexedInstructions)
|| removeDoubleSecClc(block, indexedInstructions)
|| cleanupPushPop(block, indexedInstructions)
// TODO other optimizations:
// more complex optimizations such as unused registers
} while(changed)
}
}
private fun cleanupPushPop(block: VmCodeChunk, indexedInstructions: List<IndexedValue<Instruction>>): Boolean {
// push followed by pop to same target, or different target->replace with load
var changed = false
indexedInstructions.reversed().forEach { (idx, ins) ->
if(ins.opcode==Opcode.PUSH) {
if(idx < block.lines.size-1) {
val insAfter = block.lines[idx+1] as? VmCodeInstruction
if(insAfter!=null && insAfter.ins.opcode ==Opcode.POP) {
if(ins.reg1==insAfter.ins.reg1) {
block.lines.removeAt(idx)
block.lines.removeAt(idx)
} else {
block.lines[idx] = VmCodeInstruction(Opcode.LOADR, ins.type, reg1=insAfter.ins.reg1, reg2=ins.reg1)
block.lines.removeAt(idx+1)
}
changed = true
}
}
}
}
return changed
}
private fun removeDoubleSecClc(block: VmCodeChunk, indexedInstructions: List<IndexedValue<Instruction>>): Boolean {
// double sec, clc
// sec+clc or clc+sec
var changed = false
indexedInstructions.reversed().forEach { (idx, ins) ->
if(ins.opcode==Opcode.SEC || ins.opcode==Opcode.CLC) {
if(idx < block.lines.size-1) {
val insAfter = block.lines[idx+1] as? VmCodeInstruction
if(insAfter?.ins?.opcode == ins.opcode) {
block.lines.removeAt(idx)
changed = true
}
else if(ins.opcode==Opcode.SEC && insAfter?.ins?.opcode==Opcode.CLC) {
block.lines.removeAt(idx)
changed = true
}
else if(ins.opcode==Opcode.CLC && insAfter?.ins?.opcode==Opcode.SEC) {
block.lines.removeAt(idx)
changed = true
}
}
}
}
return changed
}
private fun removeWeirdBranches(block: VmCodeChunk, indexedInstructions: List<IndexedValue<Instruction>>): Boolean {
// jump/branch to label immediately below
var changed = false
indexedInstructions.reversed().forEach { (idx, ins) ->
if(ins.opcode==Opcode.JUMP && ins.labelSymbol!=null) {
// if jumping to label immediately following this
if(idx < block.lines.size-1) {
val label = block.lines[idx+1] as? VmCodeLabel
if(label?.name == ins.labelSymbol) {
block.lines.removeAt(idx)
changed = true
}
}
}
}
return changed
}
private fun removeUselessArithmetic(block: VmCodeChunk, indexedInstructions: List<IndexedValue<Instruction>>): Boolean {
// note: this is hard to solve for the non-immediate instructions atm because the values are loaded into registers first
var changed = false
indexedInstructions.reversed().forEach { (idx, ins) ->
when (ins.opcode) {
Opcode.DIV, Opcode.DIVS, Opcode.MUL, Opcode.MOD -> {
if (ins.value == 1) {
block.lines.removeAt(idx)
changed = true
}
}
Opcode.ADD, Opcode.SUB -> {
if (ins.value == 1) {
block.lines[idx] = VmCodeInstruction(
if (ins.opcode == Opcode.ADD) Opcode.INC else Opcode.DEC,
ins.type,
ins.reg1
)
changed = true
} else if (ins.value == 0) {
block.lines.removeAt(idx)
changed = true
}
}
Opcode.AND -> {
if (ins.value == 0) {
block.lines[idx] = VmCodeInstruction(Opcode.LOAD, ins.type, reg1 = ins.reg1, value = 0)
changed = true
} else if (ins.value == 255 && ins.type == VmDataType.BYTE) {
block.lines.removeAt(idx)
changed = true
} else if (ins.value == 65535 && ins.type == VmDataType.WORD) {
block.lines.removeAt(idx)
changed = true
}
}
Opcode.OR -> {
if (ins.value == 0) {
block.lines.removeAt(idx)
changed = true
} else if ((ins.value == 255 && ins.type == VmDataType.BYTE) || (ins.value == 65535 && ins.type == VmDataType.WORD)) {
block.lines[idx] = VmCodeInstruction(Opcode.LOAD, ins.type, reg1 = ins.reg1, value = ins.value)
changed = true
}
}
Opcode.XOR -> {
if (ins.value == 0) {
block.lines.removeAt(idx)
changed = true
}
}
else -> {}
}
}
return changed
}
private fun removeNops(block: VmCodeChunk, indexedInstructions: List<IndexedValue<Instruction>>): Boolean {
var changed = false
indexedInstructions.reversed().forEach { (idx, ins) ->
if (ins.opcode == Opcode.NOP) {
changed = true
block.lines.removeAt(idx)
}
}
return changed
}
private fun removeDoubleLoadsAndStores(block: VmCodeChunk, indexedInstructions: List<IndexedValue<Instruction>>): Boolean {
var changed = false
indexedInstructions.forEach { (idx, ins) ->
// TODO: detect multiple loads to the same target registers, only keep first (if source is not I/O memory)
// TODO: detect multiple stores to the same target, only keep first (if target is not I/O memory)
// TODO: detect multiple float ffrom/fto to the same target, only keep first
// TODO: detect multiple sequential rnd with same reg1, only keep one
// TODO: detect subsequent same xors/nots/negs, remove the pairs completely as they cancel out
// TODO: detect multiple same ands, ors; only keep first
// ...
}
return changed
}
}
private interface ICodeChange { // TODO not used? remove?
fun perform(block: VmCodeChunk)
class Remove(val idx: Int): ICodeChange {
override fun perform(block: VmCodeChunk) {
block.lines.removeAt(idx)
}
}
}

171
codeGenVirtual/test/TestVmPeepholeOpt.kt
View File

@ -1,171 +0,0 @@
package prog8tests.vm
import io.kotest.assertions.fail
import io.kotest.core.spec.style.FunSpec
import io.kotest.matchers.shouldBe
import prog8.code.SymbolTable
import prog8.code.ast.PtProgram
import prog8.codegen.virtual.*
import prog8.vm.Opcode
import prog8.vm.VmDataType
import prog8tests.vm.helpers.DummyMemsizer
import prog8tests.vm.helpers.DummyStringEncoder
class TestVmPeepholeOpt: FunSpec({
fun makeVmProgram(lines: List<VmCodeLine>): Pair<AssemblyProgram, VariableAllocator> {
val st = SymbolTable()
val program = PtProgram("test", DummyMemsizer, DummyStringEncoder)
val allocations = VariableAllocator(st, program)
val asm = AssemblyProgram("test", allocations)
val block = VmCodeChunk()
for(line in lines)
block += line
asm.addBlock(block)
return Pair(asm, allocations)
}
fun AssemblyProgram.lines(): List<VmCodeLine> = this.getBlocks().flatMap { it.lines }
test("remove nops") {
val(asm, allocations) = makeVmProgram(listOf(
VmCodeInstruction(Opcode.JUMP, labelSymbol = listOf("dummy")),
VmCodeInstruction(Opcode.NOP),
VmCodeInstruction(Opcode.NOP)
))
asm.lines().size shouldBe 3
val opt = VmPeepholeOptimizer(asm, allocations)
opt.optimize()
asm.lines().size shouldBe 1
}
test("remove jmp to label below") {
val(asm, allocations) = makeVmProgram(listOf(
VmCodeInstruction(Opcode.JUMP, labelSymbol = listOf("label")), // removed
VmCodeLabel(listOf("label")),
VmCodeInstruction(Opcode.JUMP, labelSymbol = listOf("label2")), // removed
VmCodeInstruction(Opcode.NOP), // removed
VmCodeLabel(listOf("label2")),
VmCodeInstruction(Opcode.JUMP, labelSymbol = listOf("label3")),
VmCodeInstruction(Opcode.INC, VmDataType.BYTE, reg1=1),
VmCodeLabel(listOf("label3"))
))
asm.lines().size shouldBe 8
val opt = VmPeepholeOptimizer(asm, allocations)
opt.optimize()
val lines = asm.lines()
lines.size shouldBe 5
(lines[0] as VmCodeLabel).name shouldBe listOf("label")
(lines[1] as VmCodeLabel).name shouldBe listOf("label2")
(lines[2] as VmCodeInstruction).ins.opcode shouldBe Opcode.JUMP
(lines[3] as VmCodeInstruction).ins.opcode shouldBe Opcode.INC
(lines[4] as VmCodeLabel).name shouldBe listOf("label3")
}
test("remove double sec/clc") {
val(asm, allocations) = makeVmProgram(listOf(
VmCodeInstruction(Opcode.SEC),
VmCodeInstruction(Opcode.SEC),
VmCodeInstruction(Opcode.SEC),
VmCodeInstruction(Opcode.CLC),
VmCodeInstruction(Opcode.CLC),
VmCodeInstruction(Opcode.CLC)
))
asm.lines().size shouldBe 6
val opt = VmPeepholeOptimizer(asm, allocations)
opt.optimize()
val lines = asm.lines()
lines.size shouldBe 1
(lines[0] as VmCodeInstruction).ins.opcode shouldBe Opcode.CLC
}
test("push followed by pop") {
val(asm, allocations) = makeVmProgram(listOf(
VmCodeInstruction(Opcode.PUSH, VmDataType.BYTE, reg1=42),
VmCodeInstruction(Opcode.POP, VmDataType.BYTE, reg1=42),
VmCodeInstruction(Opcode.PUSH, VmDataType.BYTE, reg1=99),
VmCodeInstruction(Opcode.POP, VmDataType.BYTE, reg1=222)
))
asm.lines().size shouldBe 4
val opt = VmPeepholeOptimizer(asm, allocations)
opt.optimize()
val lines = asm.lines()
lines.size shouldBe 1
(lines[0] as VmCodeInstruction).ins.opcode shouldBe Opcode.LOADR
(lines[0] as VmCodeInstruction).ins.reg1 shouldBe 222
(lines[0] as VmCodeInstruction).ins.reg2 shouldBe 99
}
test("remove useless div/mul, add/sub") {
val(asm, allocations) = makeVmProgram(listOf(
VmCodeInstruction(Opcode.DIV, VmDataType.BYTE, reg1=42, value = 1),
VmCodeInstruction(Opcode.DIVS, VmDataType.BYTE, reg1=42, value = 1),
VmCodeInstruction(Opcode.MUL, VmDataType.BYTE, reg1=42, value = 1),
VmCodeInstruction(Opcode.MOD, VmDataType.BYTE, reg1=42, value = 1),
VmCodeInstruction(Opcode.DIV, VmDataType.BYTE, reg1=42, value = 2),
VmCodeInstruction(Opcode.DIVS, VmDataType.BYTE, reg1=42, value = 2),
VmCodeInstruction(Opcode.MUL, VmDataType.BYTE, reg1=42, value = 2),
VmCodeInstruction(Opcode.MOD, VmDataType.BYTE, reg1=42, value = 2),
VmCodeInstruction(Opcode.ADD, VmDataType.BYTE, reg1=42, value = 0),
VmCodeInstruction(Opcode.SUB, VmDataType.BYTE, reg1=42, value = 0)
))
asm.lines().size shouldBe 10
val opt = VmPeepholeOptimizer(asm, allocations)
opt.optimize()
val lines = asm.lines()
lines.size shouldBe 4
}
test("replace add/sub 1 by inc/dec") {
val(asm, allocations) = makeVmProgram(listOf(
VmCodeInstruction(Opcode.ADD, VmDataType.BYTE, reg1=42, value = 1),
VmCodeInstruction(Opcode.SUB, VmDataType.BYTE, reg1=42, value = 1)
))
asm.lines().size shouldBe 2
val opt = VmPeepholeOptimizer(asm, allocations)
opt.optimize()
val lines = asm.lines()
lines.size shouldBe 2
(lines[0] as VmCodeInstruction).ins.opcode shouldBe Opcode.INC
(lines[1] as VmCodeInstruction).ins.opcode shouldBe Opcode.DEC
}
test("remove useless and/or/xor") {
val(asm, allocations) = makeVmProgram(listOf(
VmCodeInstruction(Opcode.AND, VmDataType.BYTE, reg1=42, value = 255),
VmCodeInstruction(Opcode.AND, VmDataType.WORD, reg1=42, value = 65535),
VmCodeInstruction(Opcode.OR, VmDataType.BYTE, reg1=42, value = 0),
VmCodeInstruction(Opcode.XOR, VmDataType.BYTE, reg1=42, value = 0),
VmCodeInstruction(Opcode.AND, VmDataType.BYTE, reg1=42, value = 200),
VmCodeInstruction(Opcode.AND, VmDataType.WORD, reg1=42, value = 60000),
VmCodeInstruction(Opcode.OR, VmDataType.BYTE, reg1=42, value = 1),
VmCodeInstruction(Opcode.XOR, VmDataType.BYTE, reg1=42, value = 1)
))
asm.lines().size shouldBe 8
val opt = VmPeepholeOptimizer(asm, allocations)
opt.optimize()
val lines = asm.lines()
lines.size shouldBe 4
}
test("replace and/or/xor by constant number") {
val(asm, allocations) = makeVmProgram(listOf(
VmCodeInstruction(Opcode.AND, VmDataType.BYTE, reg1=42, value = 0),
VmCodeInstruction(Opcode.AND, VmDataType.WORD, reg1=42, value = 0),
VmCodeInstruction(Opcode.OR, VmDataType.BYTE, reg1=42, value = 255),
VmCodeInstruction(Opcode.OR, VmDataType.WORD, reg1=42, value = 65535)
))
asm.lines().size shouldBe 4
val opt = VmPeepholeOptimizer(asm, allocations)
opt.optimize()
val lines = asm.lines()
lines.size shouldBe 4
(lines[0] as VmCodeInstruction).ins.opcode shouldBe Opcode.LOAD
(lines[1] as VmCodeInstruction).ins.opcode shouldBe Opcode.LOAD
(lines[2] as VmCodeInstruction).ins.opcode shouldBe Opcode.LOAD
(lines[3] as VmCodeInstruction).ins.opcode shouldBe Opcode.LOAD
(lines[0] as VmCodeInstruction).ins.value shouldBe 0
(lines[1] as VmCodeInstruction).ins.value shouldBe 0
(lines[2] as VmCodeInstruction).ins.value shouldBe 255
(lines[3] as VmCodeInstruction).ins.value shouldBe 65535
}
})

9
codeOptimizers/src/prog8/optimizer/ConstantFoldingOptimizer.kt
View File

@ -1,15 +1,18 @@
package prog8.optimizer
import prog8.ast.*
import prog8.ast.Node
import prog8.ast.Program
import prog8.ast.base.FatalAstException
import prog8.ast.base.UndefinedSymbolError
import prog8.ast.expressions.*
import prog8.ast.statements.*
import prog8.ast.maySwapOperandOrder
import prog8.ast.statements.ForLoop
import prog8.ast.statements.VarDecl
import prog8.ast.statements.VarDeclType
import prog8.ast.walk.AstWalker
import prog8.ast.walk.IAstModification
import prog8.code.core.AssociativeOperators
import prog8.code.core.DataType
import prog8.compiler.BuiltinFunctions
class ConstantFoldingOptimizer(private val program: Program) : AstWalker() {

104
codeOptimizers/src/prog8/optimizer/ExpressionSimplifier.kt
View File

@ -13,13 +13,16 @@ import prog8.ast.statements.Jump
import prog8.ast.walk.AstWalker
import prog8.ast.walk.IAstModification
import prog8.code.core.*
import prog8.code.target.VMTarget
import kotlin.math.abs
import kotlin.math.log2
import kotlin.math.pow
// TODO add more peephole expression optimizations? Investigate what optimizations binaryen has, also see https://egorbo.com/peephole-optimizations.html
class ExpressionSimplifier(private val program: Program) : AstWalker() {
class ExpressionSimplifier(private val program: Program,
private val errors: IErrorReporter,
private val compTarget: ICompilationTarget) : AstWalker() {
private val powersOfTwo = (1..16).map { (2.0).pow(it) }.toSet()
private val negativePowersOfTwo = powersOfTwo.map { -it }.toSet()
@ -74,6 +77,22 @@ class ExpressionSimplifier(private val program: Program) : AstWalker() {
}
}
}
if(compTarget.name!=VMTarget.NAME) {
val booleanCondition = ifElse.condition as? BinaryExpression
if(booleanCondition!=null && booleanCondition.operator=="&") {
// special optimization of WORD & $ff00 -> just and the msb of WORD with $ff
val rightNum = booleanCondition.right as? NumericLiteral
if(rightNum!=null && rightNum.type==DataType.UWORD && (rightNum.number.toInt() and 0x00ff)==0) {
val msb = BuiltinFunctionCall(IdentifierReference(listOf("msb"), booleanCondition.left.position), mutableListOf(booleanCondition.left), booleanCondition.left.position)
val bytevalue = NumericLiteral(DataType.UBYTE, (rightNum.number.toInt() shr 8).toDouble(), booleanCondition.right.position)
return listOf(
IAstModification.ReplaceNode(booleanCondition.left, msb, booleanCondition),
IAstModification.ReplaceNode(booleanCondition.right, bytevalue, booleanCondition))
}
}
}
return noModifications
}
@ -174,11 +193,15 @@ class ExpressionSimplifier(private val program: Program) : AstWalker() {
return listOf(IAstModification.ReplaceNode(expr.right, NumericLiteral.optimalInteger(0, expr.right.position), expr))
}
if(expr.operator == ">=" && rightVal?.number == 0.0) {
if (leftDt == DataType.UBYTE || leftDt == DataType.UWORD) {
if (leftDt == DataType.UBYTE || leftDt == DataType.UWORD) {
if(expr.operator == ">=" && rightVal?.number == 0.0) {
// unsigned >= 0 --> true
return listOf(IAstModification.ReplaceNode(expr, NumericLiteral.fromBoolean(true, expr.position), parent))
}
else if(expr.operator == ">" && rightVal?.number == 0.0) {
// unsigned > 0 --> unsigned != 0
return listOf(IAstModification.SetExpression({expr.operator="!="}, expr, parent))
}
}
if(leftDt!=DataType.FLOAT && expr.operator == "<" && rightVal?.number == 1.0) {
@ -187,11 +210,15 @@ class ExpressionSimplifier(private val program: Program) : AstWalker() {
return listOf(IAstModification.ReplaceNode(expr.right, NumericLiteral.optimalInteger(0, expr.right.position), expr))
}
if(expr.operator == "<" && rightVal?.number == 0.0) {
if (leftDt == DataType.UBYTE || leftDt == DataType.UWORD) {
if (leftDt == DataType.UBYTE || leftDt == DataType.UWORD) {
if(expr.operator == "<" && rightVal?.number == 0.0) {
// unsigned < 0 --> false
return listOf(IAstModification.ReplaceNode(expr, NumericLiteral.fromBoolean(false, expr.position), parent))
}
else if(expr.operator == "<=" && rightVal?.number == 0.0) {
// unsigned <= 0 --> unsigned==0
return listOf(IAstModification.SetExpression({expr.operator="=="}, expr, parent))
}
}
// boolvar & 1 --> boolvar
@ -334,6 +361,14 @@ class ExpressionSimplifier(private val program: Program) : AstWalker() {
}
}
if(functionCallExpr.target.nameInSource == listOf("mkword")) {
if(functionCallExpr.args[0].constValue(program)?.number==0.0) {
// just cast the lsb to uword
val cast = TypecastExpression(functionCallExpr.args[1], DataType.UWORD, true, functionCallExpr.position)
return listOf(IAstModification.ReplaceNode(functionCallExpr, cast, parent))
}
}
return noModifications
}
@ -469,19 +504,14 @@ class ExpressionSimplifier(private val program: Program) : AstWalker() {
}
}
in powersOfTwo -> {
if (leftDt in IntegerDatatypes) {
// divided by a power of two => shift right
if (leftDt==DataType.UBYTE || leftDt==DataType.UWORD) {
// Unsigned number divided by a power of two => shift right
// Signed number can't simply be bitshifted in this case (due to rounding issues for negative values),
// so we leave that as is and let the code generator deal with it.
val numshifts = log2(cv).toInt()
return BinaryExpression(expr.left, ">>", NumericLiteral.optimalInteger(numshifts, expr.position), expr.position)
}
}
in negativePowersOfTwo -> {
if (leftDt in IntegerDatatypes) {
// divided by a negative power of two => negate, then shift right
val numshifts = log2(-cv).toInt()
return BinaryExpression(PrefixExpression("-", expr.left, expr.position), ">>", NumericLiteral.optimalInteger(numshifts, expr.position), expr.position)
}
}
}
if (leftDt == DataType.UBYTE) {
@ -539,9 +569,10 @@ class ExpressionSimplifier(private val program: Program) : AstWalker() {
}
in negativePowersOfTwo -> {
if (leftValue.inferType(program).isInteger) {
// times a negative power of two => negate, then shift left
// times a negative power of two => negate, then shift
val numshifts = log2(-cv).toInt()
return BinaryExpression(PrefixExpression("-", expr2.left, expr.position), "<<", NumericLiteral.optimalInteger(numshifts, expr.position), expr.position)
val negation = PrefixExpression("-", expr2.left, expr.position)
return BinaryExpression(negation, "<<", NumericLiteral.optimalInteger(numshifts, expr.position), expr.position)
}
}
}
@ -565,18 +596,46 @@ class ExpressionSimplifier(private val program: Program) : AstWalker() {
when (val targetDt = targetIDt.getOr(DataType.UNDEFINED)) {
DataType.UBYTE, DataType.BYTE -> {
if (amount >= 8) {
errors.warn("shift always results in 0", expr.position)
return NumericLiteral(targetDt, 0.0, expr.position)
}
}
DataType.UWORD, DataType.WORD -> {
DataType.UWORD -> {
if (amount >= 16) {
errors.warn("shift always results in 0", expr.position)
return NumericLiteral(targetDt, 0.0, expr.position)
} else if (amount > 8) {
}
else if(amount==8) {
// shift left by 8 bits is just a byte operation: mkword(lsb(X), 0)
val lsb = FunctionCallExpression(IdentifierReference(listOf("lsb"), expr.position), mutableListOf(expr.left), expr.position)
return FunctionCallExpression(IdentifierReference(listOf("mkword"), expr.position), mutableListOf(lsb, NumericLiteral(DataType.UBYTE, 0.0, expr.position)), expr.position)
}
else if (amount > 8) {
// same as above but with residual shifts.
val lsb = FunctionCallExpression(IdentifierReference(listOf("lsb"), expr.position), mutableListOf(expr.left), expr.position)
val shifted = BinaryExpression(lsb, "<<", NumericLiteral.optimalInteger(amount - 8, expr.position), expr.position)
return FunctionCallExpression(IdentifierReference(listOf("mkword"), expr.position), mutableListOf(shifted, NumericLiteral.optimalInteger(0, expr.position)), expr.position)
}
}
DataType.WORD -> {
if (amount >= 16) {
errors.warn("shift always results in 0", expr.position)
return NumericLiteral(targetDt, 0.0, expr.position)
}
else if(amount==8) {
// shift left by 8 bits is just a byte operation: mkword(lsb(X), 0)
val lsb = FunctionCallExpression(IdentifierReference(listOf("lsb"), expr.position), mutableListOf(expr.left), expr.position)
val mkword = FunctionCallExpression(IdentifierReference(listOf("mkword"), expr.position), mutableListOf(lsb, NumericLiteral(DataType.UBYTE, 0.0, expr.position)), expr.position)
return TypecastExpression(mkword, DataType.WORD, true, expr.position)
}
else if (amount > 8) {
// same as above but with residual shifts.
val lsb = FunctionCallExpression(IdentifierReference(listOf("lsb"), expr.position), mutableListOf(expr.left), expr.position)
val shifted = BinaryExpression(lsb, "<<", NumericLiteral.optimalInteger(amount - 8, expr.position), expr.position)
val mkword = FunctionCallExpression(IdentifierReference(listOf("mkword"), expr.position), mutableListOf(shifted, NumericLiteral.optimalInteger(0, expr.position)), expr.position)
return TypecastExpression(mkword, DataType.WORD, true, expr.position)
}
}
else -> {
}
}
@ -597,6 +656,7 @@ class ExpressionSimplifier(private val program: Program) : AstWalker() {
when (idt.getOr(DataType.UNDEFINED)) {
DataType.UBYTE -> {
if (amount >= 8) {
errors.warn("shift always results in 0", expr.position)
return NumericLiteral.optimalInteger(0, expr.position)
}
}
@ -608,14 +668,22 @@ class ExpressionSimplifier(private val program: Program) : AstWalker() {
}
DataType.UWORD -> {
if (amount >= 16) {
errors.warn("shift always results in 0", expr.position)
return NumericLiteral.optimalInteger(0, expr.position)
}
else if(amount==8) {
// shift right by 8 bits is just a byte operation: msb(X) as uword
val msb = FunctionCallExpression(IdentifierReference(listOf("msb"), expr.position), mutableListOf(expr.left), expr.position)
return TypecastExpression(msb, DataType.UWORD, true, expr.position)
}
else if (amount > 8) {
// same as above but with residual shifts.
val msb = FunctionCallExpression(IdentifierReference(listOf("msb"), expr.position), mutableListOf(expr.left), expr.position)
return TypecastExpression(BinaryExpression(msb, ">>", NumericLiteral.optimalInteger(amount - 8, expr.position), expr.position), DataType.UWORD, true, expr.position)
}
}
DataType.WORD -> {
// bit-shifting a signed value shouldn't be allowed by the compiler but here we go...
if (amount > 16) {
expr.right = NumericLiteral.optimalInteger(16, expr.right.position)
return null

4
codeOptimizers/src/prog8/optimizer/Extensions.kt
View File

@ -60,8 +60,8 @@ fun Program.inlineSubroutines(): Int {
return inliner.applyModifications()
}
fun Program.simplifyExpressions() : Int {
val opti = ExpressionSimplifier(this)
fun Program.simplifyExpressions(errors: IErrorReporter, target: ICompilationTarget) : Int {
val opti = ExpressionSimplifier(this, errors, target)
opti.visit(this)
return opti.applyModifications()
}

21
codeOptimizers/src/prog8/optimizer/Inliner.kt
View File

@ -38,6 +38,8 @@ class Inliner(val program: Program): AstWalker() {
is Return -> {
if(stmt.value is NumericLiteral)
true
else if(stmt.value==null)
true
else if (stmt.value is IdentifierReference) {
makeFullyScoped(stmt.value as IdentifierReference)
true
@ -106,7 +108,7 @@ class Inliner(val program: Program): AstWalker() {
} else
false
}
is Jump, is GoSub -> true
is Jump -> true
else -> false
}
}
@ -170,18 +172,11 @@ class Inliner(val program: Program): AstWalker() {
return super.before(program)
}
override fun after(gosub: GoSub, parent: Node): Iterable<IAstModification> {
val sub = gosub.identifier.targetStatement(program) as? Subroutine
return if(sub==null)
noModifications
else
possibleInlineFcallStmt(sub, gosub, parent)
}
private fun possibleInlineFcallStmt(sub: Subroutine, origNode: Node, parent: Node): Iterable<IAstModification> {
if(sub.inline && sub.parameters.isEmpty()) {
require(sub.statements.size == 1 || (sub.statements.size == 2 && isEmptyReturn(sub.statements[1])))
require(sub.statements.size == 1 || (sub.statements.size == 2 && isEmptyReturn(sub.statements[1]))) {
"invalid inline sub at ${sub.position}"
}
return if(sub.isAsmSubroutine) {
// simply insert the asm for the argument-less routine
listOf(IAstModification.ReplaceNode(origNode, sub.statements.single().copy(), parent))
@ -215,7 +210,9 @@ class Inliner(val program: Program): AstWalker() {
override fun before(functionCallExpr: FunctionCallExpression, parent: Node): Iterable<IAstModification> {
val sub = functionCallExpr.target.targetStatement(program) as? Subroutine
if(sub!=null && sub.inline && sub.parameters.isEmpty()) {
require(sub.statements.size==1 || (sub.statements.size==2 && isEmptyReturn(sub.statements[1])))
require(sub.statements.size == 1 || (sub.statements.size == 2 && isEmptyReturn(sub.statements[1]))) {
"invalid inline sub at ${sub.position}"
}
return if(sub.isAsmSubroutine) {
// cannot inline assembly directly in the Ast here as an Asm node is not an expression....
noModifications

111
codeOptimizers/src/prog8/optimizer/StatementOptimizer.kt
View File

@ -73,31 +73,6 @@ class StatementOptimizer(private val program: Program,
}
}
// if the first instruction in the called subroutine is a return statement, remove the jump altogeter
val subroutine = functionCallStatement.target.targetSubroutine(program)
if(subroutine!=null) {
val first = subroutine.statements.asSequence().filterNot { it is VarDecl || it is Directive }.firstOrNull()
if(first is Return)
return listOf(IAstModification.Remove(functionCallStatement, parent as IStatementContainer))
}
if(compTarget.name!=VMTarget.NAME) {
// see if we can optimize any complex argument expressions to be just a simple variable
// TODO for now, only works for single-argument functions because we use just 1 temp var: R9
if(functionCallStatement.target.nameInSource !in listOf(listOf("pop"), listOf("popw")) && functionCallStatement.args.size==1) {
val arg = functionCallStatement.args[0]
if(!arg.isSimple && arg !is IFunctionCall) {
val name = getTempRegisterName(arg.inferType(program))
val tempvar = IdentifierReference(name, functionCallStatement.position)
val assignTempvar = Assignment(AssignTarget(tempvar.copy(), null, null, functionCallStatement.position), arg, AssignmentOrigin.OPTIMIZER, functionCallStatement.position)
return listOf(
IAstModification.InsertBefore(functionCallStatement, assignTempvar, parent as IStatementContainer),
IAstModification.ReplaceNode(arg, tempvar, functionCallStatement)
)
}
}
}
return noModifications
}
@ -122,11 +97,13 @@ class StatementOptimizer(private val program: Program,
if(constvalue!=null) {
return if(constvalue.asBooleanValue){
// always true -> keep only if-part
errors.warn("condition is always true", ifElse.condition.position)
if(!ifElse.definingModule.isLibrary)
errors.warn("condition is always true", ifElse.condition.position)
listOf(IAstModification.ReplaceNode(ifElse, ifElse.truepart, parent))
} else {
// always false -> keep only else-part
errors.warn("condition is always false", ifElse.condition.position)
if(!ifElse.definingModule.isLibrary)
errors.warn("condition is always false", ifElse.condition.position)
listOf(IAstModification.ReplaceNode(ifElse, ifElse.elsepart, parent))
}
}
@ -244,25 +221,6 @@ class StatementOptimizer(private val program: Program,
return noModifications
}
// NOTE: do NOT remove a jump to the next statement, because this will lead to wrong code when this occurs at the end of a subroutine
// if we want to optimize this away, it can be done later at code generation time.
override fun after(gosub: GoSub, parent: Node): Iterable<IAstModification> {
// if the next statement is return with no returnvalue, change into a regular jump if there are no parameters as well.
val subroutineParams = gosub.identifier.targetSubroutine(program)?.parameters
if(subroutineParams!=null && subroutineParams.isEmpty()) {
val returnstmt = gosub.nextSibling() as? Return
if(returnstmt!=null && returnstmt.value==null) {
return listOf(
IAstModification.Remove(returnstmt, parent as IStatementContainer),
IAstModification.ReplaceNode(gosub, Jump(null, gosub.identifier, null, gosub.position), parent)
)
}
}
return noModifications
}
override fun before(assignment: Assignment, parent: Node): Iterable<IAstModification> {
val binExpr = assignment.value as? BinaryExpression
@ -335,9 +293,9 @@ class StatementOptimizer(private val program: Program,
val bexpr=assignment.value as? BinaryExpression
if(bexpr!=null) {
val rightCv = bexpr.right.constValue(program)?.number
if(bexpr.operator=="-" && rightCv==null) {
if(bexpr.right isSameAs assignment.target) {
// X = value - X --> X = -X ; X += value (to avoid need of stack-evaluation)
if(bexpr.operator=="-" && rightCv==null && targetIDt.isInteger) {
if(bexpr.right.isSimple && bexpr.right isSameAs assignment.target) {
// X = value - X --> X = -X ; X += value (to avoid need of stack-evaluation, for integers)
val negation = PrefixExpression("-", bexpr.right.copy(), bexpr.position)
val addValue = Assignment(assignment.target.copy(), BinaryExpression(bexpr.right, "+", bexpr.left, bexpr.position), AssignmentOrigin.OPTIMIZER, assignment.position)
return listOf(
@ -399,64 +357,21 @@ class StatementOptimizer(private val program: Program,
}
}
// word = msb(word) , word=lsb(word)
// word = lsb(word)
if(assignment.target.inferType(program).isWords) {
var fcall = assignment.value as? FunctionCallExpression
if (fcall == null)
fcall = (assignment.value as? TypecastExpression)?.expression as? FunctionCallExpression
if (fcall != null && (fcall.target.nameInSource == listOf("lsb") || fcall.target.nameInSource == listOf("msb"))) {
if (fcall != null && (fcall.target.nameInSource == listOf("lsb"))) {
if (fcall.args.single() isSameAs assignment.target) {
return if (fcall.target.nameInSource == listOf("lsb")) {
// optimize word=lsb(word) ==> word &= $00ff
val and255 = BinaryExpression(fcall.args[0], "&", NumericLiteral(DataType.UWORD, 255.0, fcall.position), fcall.position)
val newAssign = Assignment(assignment.target, and255, AssignmentOrigin.OPTIMIZER, fcall.position)
listOf(IAstModification.ReplaceNode(assignment, newAssign, parent))
} else {
// optimize word=msb(word) ==> word >>= 8
val shift8 = BinaryExpression(fcall.args[0], ">>", NumericLiteral(DataType.UBYTE, 8.0, fcall.position), fcall.position)
val newAssign = Assignment(assignment.target, shift8, AssignmentOrigin.OPTIMIZER, fcall.position)
listOf(IAstModification.ReplaceNode(assignment, newAssign, parent))
}
// optimize word=lsb(word) ==> word &= $00ff
val and255 = BinaryExpression(fcall.args[0], "&", NumericLiteral(DataType.UWORD, 255.0, fcall.position), fcall.position)
val newAssign = Assignment(assignment.target, and255, AssignmentOrigin.OPTIMIZER, fcall.position)
return listOf(IAstModification.ReplaceNode(assignment, newAssign, parent))
}
}
}
return noModifications
}
override fun after(returnStmt: Return, parent: Node): Iterable<IAstModification> {
if(compTarget.name==VMTarget.NAME)
return noModifications
fun returnViaIntermediaryVar(value: Expression): Iterable<IAstModification>? {
val subr = returnStmt.definingSubroutine!!
val returnDt = subr.returntypes.single()
if (returnDt in IntegerDatatypes) {
// first assign to intermediary variable, then return that
val (returnVarName, _) = program.getTempVar(returnDt)
val returnValueIntermediary = IdentifierReference(returnVarName, returnStmt.position)
val tgt = AssignTarget(returnValueIntermediary, null, null, returnStmt.position)
val assign = Assignment(tgt, value, AssignmentOrigin.OPTIMIZER, returnStmt.position)
val returnReplacement = Return(returnValueIntermediary.copy(), returnStmt.position)
return listOf(
IAstModification.InsertBefore(returnStmt, assign, parent as IStatementContainer),
IAstModification.ReplaceNode(returnStmt, returnReplacement, parent)
)
}
return null
}
// TODO decision when to use intermediary variable to calculate returnvalue seems a bit arbitrary...
val returnvalue = returnStmt.value
if (returnvalue!=null) {
if (returnvalue is BinaryExpression || (returnvalue is TypecastExpression && !returnvalue.expression.isSimple)) {
val mod = returnViaIntermediaryVar(returnvalue)
if(mod!=null)
return mod
}
}
return noModifications
}
}

5
compiler/build.gradle
View File

@ -27,19 +27,20 @@ compileTestKotlin {
def prog8version = rootProject.file('compiler/res/version.txt').text.trim()
dependencies {
implementation project(':codeAst')
implementation project(':codeCore')
implementation project(':codeOptimizers')
implementation project(':compilerAst')
implementation project(':codeGenCpu6502')
implementation project(':codeGenVirtual')
implementation project(':codeGenIntermediate')
implementation project(':codeGenExperimental')
implementation project(':virtualmachine')
implementation 'org.antlr:antlr4-runtime:4.10.1'
implementation "org.jetbrains.kotlin:kotlin-stdlib-jdk8"
// implementation "org.jetbrains.kotlin:kotlin-reflect"
implementation 'org.jetbrains.kotlinx:kotlinx-cli:0.3.4'
implementation "com.michael-bull.kotlin-result:kotlin-result-jvm:1.1.16"
testImplementation project(':intermediate')
testImplementation 'io.kotest:kotest-runner-junit5-jvm:5.3.2'
}

5
compiler/compiler.iml
View File

@ -17,11 +17,12 @@
<orderEntry type="library" name="io.kotest.runner.junit5.jvm" level="project" />
<orderEntry type="library" name="antlr.antlr4" level="project" />
<orderEntry type="module" module-name="codeCore" />
<orderEntry type="module" module-name="codeAst" />
<orderEntry type="module" module-name="compilerAst" />
<orderEntry type="module" module-name="codeOptimizers" />
<orderEntry type="module" module-name="codeGenCpu6502" />
<orderEntry type="module" module-name="codeGenExperimental" />
<orderEntry type="module" module-name="codeGenVirtual" />
<orderEntry type="module" module-name="codeGenIntermediate" />
<orderEntry type="module" module-name="virtualmachine" />
<orderEntry type="module" module-name="intermediate" scope="TEST" />
</component>
</module>

14
compiler/res/prog8lib/c128/floats.p8
View File

@ -56,7 +56,8 @@ romsub $af4b = ROUND() clobbers(A,X,Y) ; round fac1
romsub $af4e = ABS() clobbers(A,X,Y) ; fac1 = ABS(fac1)
romsub $af51 = SIGN() clobbers(X,Y) -> ubyte @ A ; SIGN(fac1) to A, $ff, $0, $1 for negative, zero, positive
romsub $af54 = FCOMP(uword mflpt @ AY) clobbers(X,Y) -> ubyte @ A ; A = compare fac1 to mflpt in A/Y, 0=equal 1=fac1 is greater, 255=fac1 is less than
romsub $af57 = RND_0() clobbers(A,X,Y) ; fac1 = RND(fac1) float random number generator NOTE: special cx16 setup required, use RND() stub instead!!
romsub $af57 = RND_0() clobbers(A,X,Y) ; fac1 = RND(fac1) float random number generator
romsub $af57 = RND() clobbers(A,X,Y) ; alias for RND_0
romsub $af5a = CONUPK(uword mflpt @ AY) clobbers(A,X,Y) ; load mflpt value from memory in A/Y into fac2
romsub $af5d = ROMUPK(uword mflpt @ AY) clobbers(A,X,Y) ; load mflpt value from memory in current bank in A/Y into fac2
romsub $af60 = MOVFRM(uword mflpt @ AY) clobbers(A,X,Y) ; load mflpt value from memory in A/Y into fac1 (use MOVFM instead)
@ -151,6 +152,17 @@ asmsub FREADUY (ubyte value @Y) {
&uword AYINT_facmo = $66 ; $66/$67 contain result of AYINT
sub rndf() -> float {
%asm {{
stx P8ZP_SCRATCH_REG
lda #1
jsr RND_0
ldx P8ZP_SCRATCH_REG
rts
}}
}
%asminclude "library:c128/floats.asm"
%asminclude "library:c64/floats_funcs.asm"

25
compiler/res/prog8lib/c128/syslib.p8
View File

@ -12,9 +12,34 @@ c64 {
&ubyte COLOR = $00f1 ; cursor color
;;&ubyte HIBASE = $0288 ; screen base address / 256 (hi-byte of screen memory address) // TODO c128 ??
&uword IERROR = $0300
&uword IMAIN = $0302
&uword ICRNCH = $0304
&uword IQPLOP = $0306
&uword IGONE = $0308
&uword IEVAL = $030a
&uword ICRNCH2 = $030c
&uword IQPLOP2 = $030e
&uword IGONE2 = $0310
; $0312 and $0313 are unused.
&uword CINV = $0314 ; IRQ vector (in ram)
&uword CBINV = $0316 ; BRK vector (in ram)
&uword NMINV = $0318 ; NMI vector (in ram)
&uword IOPEN = $031a
&uword ICLOSE = $031c
&uword ICHKIN = $031e
&uword ICKOUT = $0320
&uword ICLRCH = $0322
&uword IBASIN = $0324
&uword IBSOUT = $0326
&uword ISTOP = $0328
&uword IGETIN = $032a
&uword ICLALL = $032c
&uword IEXMON = $032e
&uword ILOAD = $0330
&uword ISAVE = $0332
&uword NMI_VEC = $FFFA ; 6502 nmi vector, determined by the kernal if banked in
&uword RESET_VEC = $FFFC ; 6502 reset vector, determined by the kernal if banked in
&uword IRQ_VEC = $FFFE ; 6502 interrupt vector, determined by the kernal if banked in

12
compiler/res/prog8lib/c64/floats.p8
View File

@ -171,6 +171,18 @@ asmsub GETADRAY () clobbers(X) -> uword @ AY {
&uword AYINT_facmo = $64 ; $64/$65 contain result of AYINT
sub rndf() -> float {
%asm {{
stx P8ZP_SCRATCH_REG
lda #1
jsr FREADSA
jsr RND ; rng into fac1
ldx P8ZP_SCRATCH_REG
rts
}}
}
%asminclude "library:c64/floats.asm"
%asminclude "library:c64/floats_funcs.asm"

2
compiler/res/prog8lib/c64/graphics.p8
View File

@ -315,7 +315,7 @@ hline_zero2
; for efficiency of internal algorithms here is the internal plot routine
; that takes the plotx coordinate in a separate variable instead of the XY register pair:
uword internal_plotx ; 0..319 ; separate 'parameter' for internal_plot()
uword @zp internal_plotx ; 0..319 ; separate 'parameter' for internal_plot()
asmsub internal_plot(ubyte ploty @A) clobbers (A, X, Y) { ; internal_plotx is 16 bits 0 to 319... doesn't fit in a register
%asm {{

27
compiler/res/prog8lib/c64/syslib.p8
View File

@ -11,9 +11,36 @@ c64 {
&ubyte COLOR = $0286 ; cursor color
&ubyte HIBASE = $0288 ; screen base address / 256 (hi-byte of screen memory address)
&uword IERROR = $0300
&uword IMAIN = $0302
&uword ICRNCH = $0304
&uword IQPLOP = $0306
&uword IGONE = $0308
&uword IEVAL = $030a
&ubyte SAREG = $030c ; register storage for A for SYS calls
&ubyte SXREG = $030d ; register storage for X for SYS calls
&ubyte SYREG = $030e ; register storage for Y for SYS calls
&ubyte SPREG = $030f ; register storage for P (status register) for SYS calls
&uword USRADD = $0311 ; vector for the USR() basic command
; $0313 is unused.
&uword CINV = $0314 ; IRQ vector (in ram)
&uword CBINV = $0316 ; BRK vector (in ram)
&uword NMINV = $0318 ; NMI vector (in ram)
&uword IOPEN = $031a
&uword ICLOSE = $031c
&uword ICHKIN = $031e
&uword ICKOUT = $0320
&uword ICLRCH = $0322
&uword IBASIN = $0324
&uword IBSOUT = $0326
&uword ISTOP = $0328
&uword IGETIN = $032a
&uword ICLALL = $032c
&uword USERCMD = $032e
&uword ILOAD = $0330
&uword ISAVE = $0332
&uword NMI_VEC = $FFFA ; 6502 nmi vector, determined by the kernal if banked in
&uword RESET_VEC = $FFFC ; 6502 reset vector, determined by the kernal if banked in
&uword IRQ_VEC = $FFFE ; 6502 interrupt vector, determined by the kernal if banked in

139
compiler/res/prog8lib/cx16/cx16diskio.p8
View File

@ -1,6 +1,7 @@
; Cx16 specific disk drive I/O routines.
%import diskio
%import string
cx16diskio {
@ -34,17 +35,22 @@ cx16diskio {
return $2000 * (cx16.getrambank() - startbank) + endaddress - startaddress
}
asmsub vload(str name @R0, ubyte device @Y, ubyte bank @A, uword address @R1) -> ubyte @A {
; -- like the basic command VLOAD "filename",device,bank,address
asmsub vload(str name @R0, ubyte drivenumber @Y, ubyte bank @A, uword address @R1) -> ubyte @A {
; -- like the basic command VLOAD "filename",drivenumber,bank,address
; loads a file into Vera's video memory in the given bank:address, returns success in A
; the file has to have the usual 2 byte header (which will be skipped)
%asm {{
; -- load a file into video ram
clc
internal_vload:
phx
pha
tya
tax
lda #1
ldy #0
bcc +
ldy #%00000010 ; headerless load mode
bne ++
+ ldy #0 ; normal load mode
+ lda #1
jsr c64.SETLFS
lda cx16.r0
ldy cx16.r0+1
@ -71,6 +77,15 @@ cx16diskio {
}}
}
asmsub vload_raw(str name @R0, ubyte drivenumber @Y, ubyte bank @A, uword address @R1) -> ubyte @A {
; -- like the basic command BVLOAD "filename",drivenumber,bank,address
; loads a file into Vera's video memory in the given bank:address, returns success in A
; the file is read fully including the first two bytes.
%asm {{
sec
jmp vload.internal_vload
}}
}
; replacement function that makes use of fast block read capability of the X16
; use this in place of regular diskio.f_read()
@ -81,15 +96,6 @@ cx16diskio {
return 0
diskio.list_blocks = 0 ; we reuse this variable for the total number of bytes read
if diskio.have_first_byte {
diskio.have_first_byte=false
@(bufferpointer) = diskio.first_byte
bufferpointer++
diskio.list_blocks++
num_bytes--
}
void c64.CHKIN(11) ; use #11 as input channel again
; commander X16 supports fast block-read via macptr() kernal call
uword size
@ -97,7 +103,7 @@ cx16diskio {
size = 255
if num_bytes<size
size = num_bytes
size = cx16.macptr(lsb(size), bufferpointer)
size = cx16.macptr(lsb(size), bufferpointer, false)
if_cs
goto byte_read_loop ; macptr block read not supported, do fallback loop
diskio.list_blocks += size
@ -119,29 +125,23 @@ byte_read_loop: ; fallback if macptr() isn't supported on the device
lda bufferpointer+1
sta m_in_buffer+2
}}
repeat num_bytes {
while num_bytes {
if c64.READST() {
diskio.f_close()
if c64.READST() & $40 ; eof?
return diskio.list_blocks ; number of bytes read
return 0 ; error.
}
%asm {{
jsr c64.CHRIN
sta cx16.r5
m_in_buffer sta $ffff
inc m_in_buffer+1
bne +
inc m_in_buffer+2
+ inc diskio.list_blocks
bne +
inc diskio.list_blocks+1
+
}}
if cx16.r5==$0d { ; chance on I/o error status?
diskio.first_byte = c64.READST()
if diskio.first_byte & $40 {
diskio.f_close() ; end of file, close it
diskio.list_blocks-- ; don't count that last CHRIN read
}
if diskio.first_byte
return diskio.list_blocks ; number of bytes read
}
diskio.list_blocks++
num_bytes--
}
return diskio.list_blocks ; number of bytes read
}
@ -154,19 +154,78 @@ m_in_buffer sta $ffff
return 0
uword total_read = 0
if diskio.have_first_byte {
diskio.have_first_byte=false
@(bufferpointer) = diskio.first_byte
bufferpointer++
total_read = 1
}
while not c64.READST() {
uword size = cx16diskio.f_read(bufferpointer, 256)
total_read += size
bufferpointer += size
cx16.r0 = cx16diskio.f_read(bufferpointer, 256)
total_read += cx16.r0
bufferpointer += cx16.r0
}
return total_read
}
sub chdir(ubyte drivenumber, str path) {
; -- change current directory.
diskio.list_filename[0] = 'c'
diskio.list_filename[1] = 'd'
diskio.list_filename[2] = ':'
void string.copy(path, &diskio.list_filename+3)
diskio.send_command(drivenumber, diskio.list_filename)
}
sub mkdir(ubyte drivenumber, str name) {
; -- make a new subdirectory.
diskio.list_filename[0] = 'm'
diskio.list_filename[1] = 'd'
diskio.list_filename[2] = ':'
void string.copy(name, &diskio.list_filename+3)
diskio.send_command(drivenumber, diskio.list_filename)
}
sub rmdir(ubyte drivenumber, str name) {
; -- remove a subdirectory.
void string.find(name, '*')
if_cs
return ; refuse to act on a wildcard *
diskio.list_filename[0] = 'r'
diskio.list_filename[1] = 'd'
diskio.list_filename[2] = ':'
void string.copy(name, &diskio.list_filename+3)
diskio.send_command(drivenumber, diskio.list_filename)
}
sub relabel(ubyte drivenumber, str name) {
; -- change the disk label.
diskio.list_filename[0] = 'r'
diskio.list_filename[1] = '-'
diskio.list_filename[2] = 'h'
diskio.list_filename[3] = ':'
void string.copy(name, &diskio.list_filename+4)
diskio.send_command(drivenumber, diskio.list_filename)
}
sub f_seek(uword pos_hiword, uword pos_loword) {
; -- seek in the reading file opened with f_open, to the given 32-bits position
ubyte[6] command = ['p',0,0,0,0,0]
command[1] = 12 ; f_open uses channel 12
command[2] = lsb(pos_loword)
command[3] = msb(pos_loword)
command[4] = lsb(pos_hiword)
command[5] = msb(pos_hiword)
send_command:
c64.SETNAM(sizeof(command), &command)
c64.SETLFS(15, diskio.last_drivenumber, 15)
void c64.OPEN()
c64.CLOSE(15)
}
; TODO see if we can get this to work as well:
; sub f_seek_w(uword pos_hiword, uword pos_loword) {
; ; -- seek in the output file opened with f_open_w, to the given 32-bits position
; cx16diskio.f_seek.command[1] = 13 ; f_open_w uses channel 13
; cx16diskio.f_seek.command[2] = lsb(pos_loword)
; cx16diskio.f_seek.command[3] = msb(pos_loword)
; cx16diskio.f_seek.command[4] = lsb(pos_hiword)
; cx16diskio.f_seek.command[5] = msb(pos_hiword)
; goto cx16diskio.f_seek.send_command
; }
}

50
compiler/res/prog8lib/cx16/floats.p8
View File

@ -29,7 +29,7 @@ romsub $fe03 = GIVAYF(ubyte lo @ Y, ubyte hi @ A) clobbers(A,X,Y)
romsub $fe06 = FOUT() clobbers(X) -> uword @ AY ; fac1 -> string, address returned in AY
; romsub $fe09 = VAL_1() clobbers(A,X,Y) ; convert ASCII string to floating point [not yet implemented!!!]
; fac1 -> unsigned word in Y/A (might throw ILLEGAL QUANTITY) (result also in $14/15)
; GETADR: fac1 -> unsigned word in Y/A (might throw ILLEGAL QUANTITY) (result also in $14/15)
; (tip: use GETADRAY to get A/Y output; lo/hi switched to normal little endian order)
romsub $fe0c = GETADR() clobbers(X) -> ubyte @ Y, ubyte @ A
romsub $fe0f = FLOATC() clobbers(A,X,Y) ; convert address to floating point
@ -57,7 +57,8 @@ romsub $fe4b = ROUND() clobbers(A,X,Y) ; round fac1
romsub $fe4e = ABS() clobbers(A,X,Y) ; fac1 = ABS(fac1)
romsub $fe51 = SIGN() clobbers(X,Y) -> ubyte @ A ; SIGN(fac1) to A, $ff, $0, $1 for negative, zero, positive
romsub $fe54 = FCOMP(uword mflpt @ AY) clobbers(X,Y) -> ubyte @ A ; A = compare fac1 to mflpt in A/Y, 0=equal 1=fac1 is greater, 255=fac1 is less than
romsub $fe57 = RND_0() clobbers(A,X,Y) ; fac1 = RND(fac1) float random number generator NOTE: special cx16 setup required, use RND() stub instead!!
romsub $fe57 = RND_0() clobbers(A,X,Y) ; fac1 = RND(fac1) float random number generator NOTE: incompatible with C64's RND routine
romsub $fe57 = RND() clobbers(A,X,Y) ; alias for RND_0
romsub $fe5a = CONUPK(uword mflpt @ AY) clobbers(A,X,Y) ; load mflpt value from memory in A/Y into fac2
romsub $fe5d = ROMUPK(uword mflpt @ AY) clobbers(A,X,Y) ; load mflpt value from memory in current bank in A/Y into fac2
romsub $fe60 = MOVFRM(uword mflpt @ AY) clobbers(A,X,Y) ; load mflpt value from memory in A/Y into fac1 (use MOVFM instead)
@ -67,18 +68,19 @@ romsub $fe69 = MOVFA() clobbers(A,X) ; copy fac2 to fac1
romsub $fe6c = MOVAF() clobbers(A,X) ; copy fac1 to fac2 (rounded)
; X16 additions
romsub $fe81 = FADDH() clobbers(A,X,Y) ; fac1 += 0.5, for rounding- call this before INT
romsub $fe84 = ZEROFC() clobbers(A,X,Y) ; fac1 = 0
romsub $fe87 = NORMAL() clobbers(A,X,Y) ; normalize fac1 (?)
romsub $fe8a = NEGFAC() clobbers(A) ; switch the sign of fac1 (fac1 = -fac1) (juse use NEGOP() instead!)
romsub $fe8d = MUL10() clobbers(A,X,Y) ; fac1 *= 10
romsub $fe90 = DIV10() clobbers(A,X,Y) ; fac1 /= 10 , CAUTION: result is always positive!
romsub $fe93 = MOVEF() clobbers(A,X) ; copy fac1 to fac2
romsub $fe96 = SGN() clobbers(A,X,Y) ; fac1 = SGN(fac1), result of SIGN (-1, 0 or 1)
romsub $fe99 = FLOAT() clobbers(A,X,Y) ; FAC = (u8).A
romsub $fe9c = FLOATS() clobbers(A,X,Y) ; FAC = (s16)facho+1:facho
romsub $fe9f = QINT() clobbers(A,X,Y) ; facho:facho+1:facho+2:facho+3 = u32(FAC)
romsub $fea2 = FINLOG(byte value @A) clobbers (A, X, Y) ; fac1 += signed byte in A
romsub $fe6f = FADDH() clobbers(A,X,Y) ; fac1 += 0.5, for rounding- call this before INT
romsub $fe72 = ZEROFC() clobbers(A,X,Y) ; fac1 = 0
romsub $fe75 = NORMAL() clobbers(A,X,Y) ; normalize fac1 (?)
romsub $fe78 = NEGFAC() clobbers(A) ; switch the sign of fac1 (fac1 = -fac1) (juse use NEGOP() instead!)
romsub $fe7b = MUL10() clobbers(A,X,Y) ; fac1 *= 10
romsub $fe7e = DIV10() clobbers(A,X,Y) ; fac1 /= 10 , CAUTION: result is always positive!
romsub $fe81 = MOVEF() clobbers(A,X) ; copy fac1 to fac2
romsub $fe84 = SGN() clobbers(A,X,Y) ; fac1 = SGN(fac1), result of SIGN (-1, 0 or 1)
romsub $fe87 = FLOAT() clobbers(A,X,Y) ; FAC = (u8).A
romsub $fe8a = FLOATS() clobbers(A,X,Y) ; FAC = (s16)facho+1:facho
romsub $fe8d = QINT() clobbers(A,X,Y) ; facho:facho+1:facho+2:facho+3 = u32(FAC)
romsub $fe90 = FINLOG(byte value @A) clobbers (A, X, Y) ; fac1 += signed byte in A
asmsub FREADSA (byte value @A) clobbers(A,X,Y) {
@ -147,19 +149,21 @@ asmsub FREADUY (ubyte value @Y) {
}}
}
asmsub RND() clobbers(A,X,Y) {
%asm {{
lda #0
php
jsr cx16.entropy_get
plp
jmp RND_0
}}
}
&uword AYINT_facmo = $c6 ; $c6/$c7 contain result of AYINT
sub rndf() -> float {
%asm {{
phx
lda #1
jsr RND_0
plx
rts
}}
}
%asminclude "library:c64/floats.asm"
%asminclude "library:c64/floats_funcs.asm"
}

133
compiler/res/prog8lib/cx16/gfx2.p8
View File

@ -82,9 +82,10 @@ gfx2 {
bpp = 2
}
else -> {
; back to default text mode and colors
cx16.VERA_CTRL = %10000000 ; reset VERA and palette
c64.CINT() ; back to text mode
; back to default text mode
cx16.r15L = cx16.VERA_DC_VIDEO & %00000111 ; retain chroma + output mode
c64.CINT()
cx16.VERA_DC_VIDEO = (cx16.VERA_DC_VIDEO & %11111000) | cx16.r15L
width = 0
height = 0
bpp = 0
@ -366,7 +367,7 @@ _done
position2(x,y,true)
set_both_strides(13) ; 160 increment = 1 line in 640 px 4c mode
color &= 3
color <<= gfx2.plot.shift4c[lsb(x) & 3]
color <<= gfx2.plot.shift4c[lsb(x) & 3] ; TODO with lookup table
ubyte @shared mask = gfx2.plot.mask4c[lsb(x) & 3]
repeat lheight {
%asm {{
@ -561,7 +562,11 @@ _done
and #1
}}
if_nz {
cx16.r0L = lsb(x) & 7 ; xbits
%asm {{
lda x
and #7
pha ; xbits
}}
x /= 8
x += y*(320/8)
%asm {{
@ -571,7 +576,7 @@ _done
sta cx16.VERA_ADDR_M
lda x
sta cx16.VERA_ADDR_L
ldy cx16.r0L ; xbits
ply ; xbits
lda bits,y
ldy color
beq +
@ -608,7 +613,11 @@ _done
and #1
}}
if_nz {
cx16.r0L = lsb(x) & 7 ; xbits
%asm {{
lda x
and #7
pha ; xbits
}}
x /= 8
x += y*(640/8)
%asm {{
@ -618,7 +627,7 @@ _done
sta cx16.VERA_ADDR_M
lda x
sta cx16.VERA_ADDR_L
ldy cx16.r0L ; xbits
ply ; xbits
lda bits,y
ldy color
beq +
@ -635,7 +644,7 @@ _done
void addr_mul_24_for_highres_4c(y, x) ; 24 bits result is in r0 and r1L (highest byte)
cx16.r2L = lsb(x) & 3 ; xbits
color &= 3
color <<= shift4c[cx16.r2L]
color <<= shift4c[cx16.r2L] ; TODO with lookup table
%asm {{
stz cx16.VERA_CTRL
lda cx16.r1L
@ -654,6 +663,93 @@ _done
}
}
sub pget(uword @zp x, uword y) -> ubyte {
when active_mode {
1 -> {
; lores monochrome
%asm {{
lda x
and #7
pha ; xbits
}}
x /= 8
x += y*(320/8)
%asm {{
stz cx16.VERA_CTRL
stz cx16.VERA_ADDR_H
lda x+1
sta cx16.VERA_ADDR_M
lda x
sta cx16.VERA_ADDR_L
ply ; xbits
lda plot.bits,y
and cx16.VERA_DATA0
beq +
lda #1
+
}}
}
; TODO mode 2 and 3
4 -> {
; lores 256c
void addr_mul_24_for_lores_256c(y, x) ; 24 bits result is in r0 and r1L (highest byte)
%asm {{
stz cx16.VERA_CTRL
lda cx16.r1
sta cx16.VERA_ADDR_H
lda cx16.r0+1
sta cx16.VERA_ADDR_M
lda cx16.r0
sta cx16.VERA_ADDR_L
lda cx16.VERA_DATA0
}}
}
5 -> {
; hires monochrome
%asm {{
lda x
and #7
pha ; xbits
}}
x /= 8
x += y*(640/8)
%asm {{
stz cx16.VERA_CTRL
stz cx16.VERA_ADDR_H
lda x+1
sta cx16.VERA_ADDR_M
lda x
sta cx16.VERA_ADDR_L
ply ; xbits
lda plot.bits,y
and cx16.VERA_DATA0
beq +
lda #1
+
}}
}
6 -> {
; hires 4c
void addr_mul_24_for_highres_4c(y, x) ; 24 bits result is in r0 and r1L (highest byte)
%asm {{
stz cx16.VERA_CTRL
lda cx16.r1L
sta cx16.VERA_ADDR_H
lda cx16.r0H
sta cx16.VERA_ADDR_M
lda cx16.r0L
sta cx16.VERA_ADDR_L
lda cx16.VERA_DATA0
sta cx16.r0L
}}
cx16.r1L = lsb(x) & 3
cx16.r0L >>= gfx2.plot.shift4c[cx16.r1L] ; TODO with lookup table
return cx16.r0L & 3
}
else -> return 0
}
}
sub position(uword @zp x, uword y) {
ubyte bank
when active_mode {
@ -823,7 +919,7 @@ _done
y++
%asm {{
phx
ldx #1
ldx color
lda cx16.VERA_DATA1
sta P8ZP_SCRATCH_B1
ldy #8
@ -844,25 +940,28 @@ _done
}
6 -> {
; hires 4c
; we're going to use a few cx16 registers to make sure every variable is in zeropage in the inner loop.
cx16.r11L = color
cx16.r8 = y
while @(sctextptr) {
chardataptr = charset_addr + (@(sctextptr) as uword)*8
repeat 8 {
; TODO rewrite this inner loop partly in assembly
; requires expanding the charbits to 2-bits per pixel (based on color)
; also it's way more efficient to draw whole horizontal spans instead of per-character
ubyte charbits = cx16.vpeek(charset_bank, chardataptr)
cx16.r9L = cx16.vpeek(charset_bank, chardataptr) ; get the 8 horizontal character bits
cx16.r7 = x
repeat 8 {
charbits <<= 1
cx16.r9L <<= 1
if_cs
plot(x, y, color)
x++
plot(cx16.r7, cx16.r8, cx16.r11L)
cx16.r7++
}
x-=8
chardataptr++
y++
cx16.r8++
}
x+=8
y-=8
cx16.r8-=8
sctextptr++
}
}

2
compiler/res/prog8lib/cx16/palette.p8
View File

@ -26,7 +26,7 @@ palette {
}
sub set_rgb(uword palette_words_ptr, uword num_colors) {
; 1 word per color entry (in little endian format as layed out in video memory, so $gb0r)
; 1 word per color entry (in little endian format as layed out in video memory, so $gb;$0r)
vera_palette_ptr = $fa00
repeat num_colors*2 {
cx16.vpoke(1, vera_palette_ptr, @(palette_words_ptr))

21
compiler/res/prog8lib/cx16/psg.p8
View File

@ -15,6 +15,12 @@ psg {
const ubyte RIGHT = %10000000
sub voice(ubyte voice_num, ubyte channel, ubyte volume, ubyte waveform, ubyte pulsewidth) {
; -- Enables a 'voice' on the PSG.
; voice_num = 0-15, the voice number.
; channel = either LEFT or RIGHT or (LEFT|RIGHT). Specifies the stereo channel(s) to use.
; volume = 0-63, the starting volume for the voice
; waveform = one of PULSE,SAWTOOTH,TRIANGLE,NOISE.
; pulsewidth = 0-63. Specifies the pulse width for waveform=PULSE.
envelope_states[voice_num] = 255
cx16.r0 = $f9c2 + voice_num * 4
cx16.VERA_CTRL = 0
@ -30,12 +36,15 @@ psg {
; sub freq_hz(ubyte voice_num, float hertz) {
; ; this would rely on floating point math to convert hertz to vera frequency
; ; TODO should be replaced by integer math maybe with a lookup table?
; ; could be replaced by integer math maybe with a lookup table?
; uword vera_freq = (hertz / 0.3725290298461914) as uword
; freq(voice_num, vera_freq)
; }
sub freq(ubyte voice_num, uword vera_freq) {
; -- Changes the frequency of the voice's sound.
; voice_num = 0-15, vera_freq = 0-65535 calculate this via the formula given in the Vera's PSG documentation.
; (https://github.com/commanderx16/x16-docs/blob/master/VERA%20Programmer's%20Reference.md)
cx16.r0 = $f9c0 + voice_num * 4
cx16.VERA_CTRL = 0
cx16.VERA_ADDR_L = lsb(cx16.r0)
@ -47,6 +56,8 @@ psg {
}
sub volume(ubyte voice_num, ubyte vol) {
; -- Modifies the volume of this voice.
; voice_num = 0-15, vol = 0-63 where 0=silent, 63=loudest.
cx16.r0 = $f9c2 + voice_num * 4
cx16.vpoke(1, cx16.r0, cx16.vpeek(1, cx16.r0) & %11000000 | vol)
envelope_volumes[voice_num] = mkword(vol, 0)
@ -54,11 +65,18 @@ psg {
}
sub pulse_width(ubyte voice_num, ubyte pw) {
; -- Modifies the pulse width of this voice (when waveform=PULSE)
; voice_num = 0-15, pw = 0-63 where 0=narrow, 63=50%cycle so square wave.
cx16.r0 = $f9c3 + voice_num * 4
cx16.vpoke(1, cx16.r0, cx16.vpeek(1, cx16.r0) & %11000000 | pw)
}
sub envelope(ubyte voice_num, ubyte maxvolume, ubyte attack, ubyte sustain, ubyte release) {
; -- Enables AttackSustainRelease volume envelope for a voice.
; Note: this requires setting up envelopes_irq() as well, read its description.
; voice_num = 0-15 maxvolume = 0-63
; attack, sustain, release = 0-255 that determine the speed of the A/D/R.
; TODO describe how the speeds are calculated. For now, experiment. Higher values means *slower* enveloping.
envelope_states[voice_num] = 255
envelope_attacks[voice_num] = attack
envelope_sustains[voice_num] = sustain
@ -73,6 +91,7 @@ psg {
}
sub silent() {
; -- Shut down all PSG voices.
for cx16.r1L in 0 to 15 {
envelope_states[cx16.r1L] = 255
envelope_volumes[cx16.r1L] = 0

48
compiler/res/prog8lib/cx16/syslib.p8
View File

@ -85,6 +85,18 @@ asmsub RDTIM16() -> uword @AY {
cx16 {
; irq, system and hardware vectors:
&uword IERROR = $0300
&uword IMAIN = $0302
&uword ICRNCH = $0304
&uword IQPLOP = $0306
&uword IGONE = $0308
&uword IEVAL = $030a
&ubyte SAREG = $030c ; register storage for A for SYS calls
&ubyte SXREG = $030d ; register storage for X for SYS calls
&ubyte SYREG = $030e ; register storage for Y for SYS calls
&ubyte SPREG = $030f ; register storage for P (status register) for SYS calls
&uword USRADD = $0311 ; vector for the USR() basic command
; $0313 is unused.
&uword CINV = $0314 ; IRQ vector (in ram)
&uword CBINV = $0316 ; BRK vector (in ram)
&uword NMINV = $0318 ; NMI vector (in ram)
@ -98,7 +110,7 @@ cx16 {
&uword ISTOP = $0328
&uword IGETIN = $032a
&uword ICLALL = $032c
&uword KEYHDL = $032e ; keyboard scan code handler
&uword KEYHDL = $032e ; keyboard scan code handler see examples/cx16/keyboardhandler.p8
&uword ILOAD = $0330
&uword ISAVE = $0332
&uword NMI_VEC = $FFFA ; 65c02 nmi vector, determined by the kernal if banked in
@ -290,8 +302,9 @@ cx16 {
&ubyte d2ier = via2+14
&ubyte d2ora = via2+15
&ubyte ym2151adr = $9f40
&ubyte ym2151dat = $9f41
; YM-2151 sound chip
&ubyte YM_ADDRESS = $9f40
&ubyte YM_DATA = $9f41
const uword extdev = $9f60
@ -306,7 +319,7 @@ romsub $ff5c = lkupsa(ubyte sa @Y) clobbers(A,X,Y)
romsub $ff5f = screen_mode(ubyte mode @A, ubyte getCurrent @Pc) clobbers(A, X, Y) -> ubyte @Pc
romsub $ff62 = screen_set_charset(ubyte charset @A, uword charsetptr @XY) clobbers(A,X,Y) ; incompatible with C128 dlchr()
; not yet supported: romsub $ff65 = pfkey() clobbers(A,X,Y)
romsub $ff6e = jsrfar()
romsub $ff6e = jsrfar() ; following word = address to call, byte after that=rom/ram bank it is in
romsub $ff74 = fetch(ubyte bank @X, ubyte index @Y) clobbers(X) -> ubyte @A
romsub $ff77 = stash(ubyte data @A, ubyte bank @X, ubyte index @Y) clobbers(X)
romsub $ff7a = cmpare(ubyte data @A, ubyte bank @X, ubyte index @Y) clobbers(X)
@ -363,12 +376,13 @@ romsub $fed5 = console_set_paging_message(uword msgptr @R0) clobbers(A,X,Y)
romsub $fecf = entropy_get() -> ubyte @A, ubyte @X, ubyte @Y
romsub $fecc = monitor() clobbers(A,X,Y)
romsub $ff44 = macptr(ubyte length @A, uword buffer @XY) clobbers(A) -> ubyte @Pc, uword @XY
romsub $ff44 = macptr(ubyte length @A, uword buffer @XY, bool dontAdvance @Pc) clobbers(A) -> bool @Pc, uword @XY
romsub $ff47 = enter_basic(ubyte cold_or_warm @Pc) clobbers(A,X,Y)
romsub $ff4d = clock_set_date_time(uword yearmonth @R0, uword dayhours @R1, uword minsecs @R2, ubyte jiffies @R3) clobbers(A, X, Y)
romsub $ff50 = clock_get_date_time() clobbers(A, X, Y) -> uword @R0, uword @R1, uword @R2, ubyte @R3 ; result registers see clock_set_date_time()
; keyboard, mouse, joystick
; note: also see the kbdbuf_clear() helper routine below!
romsub $febd = kbdbuf_peek() -> ubyte @A, ubyte @X ; key in A, queue length in X
romsub $febd = kbdbuf_peek2() -> uword @AX ; alternative to above to not have the hassle to deal with multiple return values
romsub $fec0 = kbdbuf_get_modifiers() -> ubyte @A
@ -380,12 +394,22 @@ romsub $ff53 = joystick_scan() clobbers(A, X, Y)
romsub $ff56 = joystick_get(ubyte joynr @A) -> ubyte @A, ubyte @X, ubyte @Y
romsub $ff56 = joystick_get2(ubyte joynr @A) clobbers(Y) -> uword @AX ; alternative to above to not have the hassle to deal with multiple return values
asmsub kbdbuf_clear() {
; -- convenience helper routine to clear the keyboard buffer
%asm {{
- jsr c64.GETIN
bne -
rts
}}
}
asmsub mouse_config2(ubyte shape @A) clobbers (A, X, Y) {
; -- convenience wrapper function that handles the screen resolution for mouse_config() for you
%asm {{
pha ; save shape
sec
jsr cx16.screen_mode ; set current screen mode and res in A, X, Y
lda #1
pla ; get shape back
jmp cx16.mouse_config
}}
}
@ -601,12 +625,22 @@ asmsub init_system() {
%asm {{
sei
cld
lda VERA_DC_VIDEO
and #%00000111 ; retain chroma + output mode
sta P8ZP_SCRATCH_REG
lda #$80
sta VERA_CTRL
sta VERA_CTRL ; reset vera
stz $01 ; select rom bank 0 (enable kernal)
jsr c64.IOINIT
jsr c64.RESTOR
jsr c64.CINT
lda VERA_DC_VIDEO
and #%11111000
ora P8ZP_SCRATCH_REG
sta VERA_DC_VIDEO ; keep old output mode
ldy #0
clc
jsr c64.PLOT ; force a call to PLOT to avoid autostart black square issue, also see textio.fix_autostart_square()
lda #$90 ; black
jsr c64.CHROUT
lda #1 ; swap fg/bg

20
compiler/res/prog8lib/cx16/textio.p8
View File

@ -21,6 +21,26 @@ sub home() {
txt.chrout(19)
}
asmsub fix_autostart_square() {
; Here's a possible work around for weird issue that prints a black character after first call to c64.PLOT()
; if you're also using c64.CINT() yourself. The default prog8 program initialization (which calls CINT) already performs this workaround.
; The problem occurs when a program is autostarded in the emulator with -run -prg test.prg,
; or when the program is saved as AUTOBOOT.X16 and loaded on boot like that.
%asm {{
phx
sec
jsr c64.PLOT
clc
jsr c64.PLOT
lda #' '
jsr c64.CHROUT ; overwrite the black square
clc
jsr c64.PLOT ; cursor back to original position
plx
rts
}}
}
sub nl() {
txt.chrout('\n')
}

5
compiler/res/prog8lib/cx16logo.p8
View File

@ -14,9 +14,10 @@ cx16logo {
sub logo() {
uword strptr
for strptr in logo_lines
for strptr in logo_lines {
txt.print(strptr)
txt.nl()
txt.nl()
}
}
str[] logo_lines = [

243
compiler/res/prog8lib/diskio.p8
View File

@ -10,11 +10,12 @@ diskio {
; -- Prints the directory contents of disk drive 8-11 to the screen. Returns success.
c64.SETNAM(1, "$")
c64.SETLFS(13, drivenumber, 0)
void c64.OPEN() ; open 13,8,0,"$"
c64.SETLFS(12, drivenumber, 0)
ubyte status = 1
void c64.OPEN() ; open 12,8,0,"$"
if_cs
goto io_error
void c64.CHKIN(13) ; use #13 as input channel
void c64.CHKIN(12) ; use #12 as input channel
if_cs
goto io_error
@ -23,8 +24,13 @@ diskio {
}
; while not key pressed / EOF encountered, read data.
ubyte status = c64.READST()
while not status {
status = c64.READST()
if status!=0 {
status = 1
goto io_error
}
while status==0 {
ubyte low = c64.CHRIN()
ubyte high = c64.CHRIN()
txt.print_uw(mkword(high, low))
@ -43,11 +49,11 @@ diskio {
if c64.STOP2()
break
}
status = c64.READST()
io_error:
status = c64.READST()
c64.CLRCHN() ; restore default i/o devices
c64.CLOSE(13)
c64.CLOSE(12)
if status and status & $40 == 0 { ; bit 6=end of file
txt.print("\ni/o error, status: ")
@ -59,40 +65,79 @@ io_error:
return true
}
sub diskname(ubyte drivenumber) -> uword {
; -- Returns pointer to disk name string or 0 if failure.
c64.SETNAM(1, "$")
c64.SETLFS(12, drivenumber, 0)
ubyte okay = false
void c64.OPEN() ; open 12,8,0,"$"
if_cs
goto io_error
void c64.CHKIN(12) ; use #12 as input channel
if_cs
goto io_error
repeat 6 {
void c64.CHRIN() ; skip the 6 prologue bytes
}
if c64.READST()!=0
goto io_error
; while not key pressed / EOF encountered, read data.
cx16.r0 = &list_filename
repeat {
@(cx16.r0) = c64.CHRIN()
if @(cx16.r0)==0
break
cx16.r0++
}
okay = true
io_error:
c64.CLRCHN() ; restore default i/o devices
c64.CLOSE(12)
if okay
return &list_filename
return 0
}
; internal variables for the iterative file lister / loader
bool list_skip_disk_name
uword list_pattern
uword list_blocks
bool iteration_in_progress = false
ubyte @zp first_byte
bool have_first_byte
str list_filename = "?" * 32
ubyte last_drivenumber = 8 ; which drive was last used for a f_open operation?
str list_filetype = "???" ; prg, seq, dir
str list_filename = "?" * 50
; ----- get a list of files (uses iteration functions internally) -----
sub list_files(ubyte drivenumber, uword pattern_ptr, uword name_ptrs, ubyte max_names) -> ubyte {
; -- fill the array 'name_ptrs' with (pointers to) the names of the files requested.
const uword names_buf_size = 800
uword names_buffer = memory("filenames", names_buf_size, 0)
uword buffer_start = names_buffer
sub list_filenames(ubyte drivenumber, uword pattern_ptr, uword filenames_buffer, uword filenames_buf_size) -> ubyte {
; -- fill the provided buffer with the names of the files on the disk (until buffer is full).
; Files in the buffer are separeted by a 0 byte. You can provide an optional pattern to match against.
; After the last filename one additional 0 byte is placed to indicate the end of the list.
; Returns number of files (it skips 'dir' entries i.e. subdirectories).
; Also sets carry on exit: Carry clear = all files returned, Carry set = directory has more files that didn't fit in the buffer.
uword buffer_start = filenames_buffer
ubyte files_found = 0
if lf_start_list(drivenumber, pattern_ptr) {
while lf_next_entry() {
@(name_ptrs) = lsb(names_buffer)
name_ptrs++
@(name_ptrs) = msb(names_buffer)
name_ptrs++
names_buffer += string.copy(diskio.list_filename, names_buffer) + 1
files_found++
if names_buffer - buffer_start > names_buf_size-18
break
if files_found == max_names
break
if list_filetype!="dir" {
filenames_buffer += string.copy(diskio.list_filename, filenames_buffer) + 1
files_found++
if filenames_buffer - buffer_start > filenames_buf_size-20 {
@(filenames_buffer)=0
lf_end_list()
sys.set_carry()
return files_found
}
}
}
lf_end_list()
}
@(filenames_buffer)=0
sys.clear_carry()
return files_found
}
@ -129,7 +174,7 @@ io_error:
sub lf_next_entry() -> bool {
; -- retrieve the next entry from an iterative file listing session.
; results will be found in list_blocks and list_filename.
; results will be found in list_blocks, list_filename, and list_filetype.
; if it returns false though, there are no more entries (or an error occurred).
if not iteration_in_progress
@ -166,6 +211,12 @@ io_error:
@(nameptr) = 0
do {
cx16.r15L = c64.CHRIN()
} until cx16.r15L!=' ' ; skip blanks up to 3 chars entry type
list_filetype[0] = cx16.r15L
list_filetype[1] = c64.CHRIN()
list_filetype[2] = c64.CHRIN()
while c64.CHRIN() {
; read the rest of the entry until the end
}
@ -197,7 +248,7 @@ close_end:
}
; ----- iterative file loader functions (uses io channel 11) -----
; ----- iterative file loader functions (uses io channel 12) -----
sub f_open(ubyte drivenumber, uword filenameptr) -> bool {
; -- open a file for iterative reading with f_read
@ -205,17 +256,19 @@ close_end:
f_close()
c64.SETNAM(string.length(filenameptr), filenameptr)
c64.SETLFS(11, drivenumber, 0)
void c64.OPEN() ; open 11,8,0,"filename"
c64.SETLFS(12, drivenumber, 12) ; note: has to be 12,x,12 because otherwise f_seek doesn't work
last_drivenumber = drivenumber
void c64.OPEN() ; open 12,8,12,"filename"
if_cc {
if c64.READST()==0 {
iteration_in_progress = true
have_first_byte = false
void c64.CHKIN(11) ; use #11 as input channel
void c64.CHKIN(12) ; use #12 as input channel
if_cc {
first_byte = c64.CHRIN() ; read first byte to test for file not found
void c64.CHRIN() ; read first byte to test for file not found
if not c64.READST() {
have_first_byte = true
c64.CLOSE(12) ; close file because we already consumed first byte
void c64.OPEN() ; re-open the file
void c64.CHKIN(12)
return true
}
}
@ -234,15 +287,6 @@ close_end:
return 0
list_blocks = 0 ; we reuse this variable for the total number of bytes read
if have_first_byte {
have_first_byte=false
@(bufferpointer) = first_byte
bufferpointer++
list_blocks++
num_bytes--
}
void c64.CHKIN(11) ; use #11 as input channel again
%asm {{
lda bufferpointer
@ -250,29 +294,23 @@ close_end:
lda bufferpointer+1
sta m_in_buffer+2
}}
repeat num_bytes {
while num_bytes {
if c64.READST() {
f_close()
if c64.READST() & $40 ; eof?
return list_blocks ; number of bytes read
return 0 ; error.
}
%asm {{
jsr c64.CHRIN
sta cx16.r5
m_in_buffer sta $ffff
inc m_in_buffer+1
bne +
inc m_in_buffer+2
+ inc list_blocks
bne +
inc list_blocks+1
+
}}
if cx16.r5==$0d { ; chance on I/o error status?
first_byte = c64.READST()
if first_byte & $40 {
f_close() ; end of file, close it
list_blocks-- ; don't count that last CHRIN read
}
if first_byte
return list_blocks ; number of bytes read
}
list_blocks++
num_bytes--
}
return list_blocks ; number of bytes read
}
@ -283,17 +321,10 @@ m_in_buffer sta $ffff
return 0
uword total_read = 0
if have_first_byte {
have_first_byte=false
@(bufferpointer) = first_byte
bufferpointer++
total_read = 1
}
while not c64.READST() {
uword size = f_read(bufferpointer, 256)
total_read += size
bufferpointer += size
cx16.r0 = f_read(bufferpointer, 256)
total_read += cx16.r0
bufferpointer += cx16.r0
}
return total_read
}
@ -307,16 +338,9 @@ m_in_buffer sta $ffff
%asm {{
sta P8ZP_SCRATCH_W1
sty P8ZP_SCRATCH_W1+1
ldx #11
jsr c64.CHKIN ; use channel 11 again for input
ldx #12
jsr c64.CHKIN ; use channel 12 again for input
ldy #0
lda have_first_byte
beq _loop
lda #0
sta have_first_byte
lda first_byte
sta (P8ZP_SCRATCH_W1),y
iny
_loop jsr c64.CHRIN
sta (P8ZP_SCRATCH_W1),y
beq _end
@ -337,23 +361,23 @@ _end rts
; -- end an iterative file loading session (close channels).
if iteration_in_progress {
c64.CLRCHN()
c64.CLOSE(11)
c64.CLOSE(12)
iteration_in_progress = false
}
}
; ----- iterative file saver functions (uses io channel 14) -----
; ----- iterative file writing functions (uses io channel 13) -----
sub f_open_w(ubyte drivenumber, uword filenameptr) -> bool {
; -- open a file for iterative writing with f_write
f_close_w()
c64.SETNAM(string.length(filenameptr), filenameptr)
c64.SETLFS(14, drivenumber, 1)
void c64.OPEN() ; open 14,8,1,"filename"
c64.SETLFS(13, drivenumber, 1)
void c64.OPEN() ; open 13,8,1,"filename"
if_cc {
void c64.CHKOUT(14) ; use #14 as input channel
c64.CHKOUT(13) ; use #13 as output channel
return not c64.READST()
}
f_close_w()
@ -361,9 +385,9 @@ _end rts
}
sub f_write(uword bufferpointer, uword num_bytes) -> bool {
; -- write the given umber of bytes to the currently open file
; -- write the given number of bytes to the currently open file
if num_bytes!=0 {
void c64.CHKOUT(14) ; use #14 as input channel again
c64.CHKOUT(13) ; use #13 as output channel again
repeat num_bytes {
c64.CHROUT(@(bufferpointer))
bufferpointer++
@ -376,7 +400,7 @@ _end rts
sub f_close_w() {
; -- end an iterative file writing session (close channels).
c64.CLRCHN()
c64.CLOSE(14)
c64.CLOSE(13)
}
@ -384,8 +408,8 @@ _end rts
sub status(ubyte drivenumber) -> uword {
; -- retrieve the disk drive's current status message
uword messageptr = &filename
c64.SETNAM(0, filename)
uword messageptr = &list_filename
c64.SETNAM(0, list_filename)
c64.SETLFS(15, drivenumber, 15)
void c64.OPEN() ; open 15,8,15
if_cs
@ -395,10 +419,10 @@ _end rts
goto io_error
while not c64.READST() {
first_byte = c64.CHRIN()
if first_byte=='\r' or first_byte=='\n'
cx16.r5L = c64.CHRIN()
if cx16.r5L=='\r' or cx16.r5L=='\n'
break
@(messageptr) = first_byte
@(messageptr) = cx16.r5L
messageptr++
}
@(messageptr) = 0
@ -406,10 +430,10 @@ _end rts
done:
c64.CLRCHN() ; restore default i/o devices
c64.CLOSE(15)
return filename
return list_filename
io_error:
filename = "?disk error"
list_filename = "?disk error"
goto done
}
@ -417,7 +441,7 @@ io_error:
c64.SETNAM(string.length(filenameptr), filenameptr)
c64.SETLFS(1, drivenumber, 0)
uword @shared end_address = address + size
first_byte = 0 ; result var reuse
cx16.r0L = 0
%asm {{
lda address
@ -435,12 +459,12 @@ io_error:
}}
if_cc
first_byte = c64.READST()==0
cx16.r0L = c64.READST()==0
c64.CLRCHN()
c64.CLOSE(1)
return first_byte
return cx16.r0L
}
; Use kernal LOAD routine to load the given program file in memory.
@ -511,10 +535,10 @@ io_error:
sub delete(ubyte drivenumber, uword filenameptr) {
; -- delete a file on the drive
filename[0] = 's'
filename[1] = ':'
ubyte flen = string.copy(filenameptr, &filename+2)
c64.SETNAM(flen+2, filename)
list_filename[0] = 's'
list_filename[1] = ':'
ubyte flen = string.copy(filenameptr, &list_filename+2)
c64.SETNAM(flen+2, list_filename)
c64.SETLFS(1, drivenumber, 15)
void c64.OPEN()
c64.CLRCHN()
@ -523,17 +547,24 @@ io_error:
sub rename(ubyte drivenumber, uword oldfileptr, uword newfileptr) {
; -- rename a file on the drive
filename[0] = 'r'
filename[1] = ':'
ubyte flen_new = string.copy(newfileptr, &filename+2)
filename[flen_new+2] = '='
ubyte flen_old = string.copy(oldfileptr, &filename+3+flen_new)
c64.SETNAM(3+flen_new+flen_old, filename)
list_filename[0] = 'r'
list_filename[1] = ':'
ubyte flen_new = string.copy(newfileptr, &list_filename+2)
list_filename[flen_new+2] = '='
ubyte flen_old = string.copy(oldfileptr, &list_filename+3+flen_new)
c64.SETNAM(3+flen_new+flen_old, list_filename)
c64.SETLFS(1, drivenumber, 15)
void c64.OPEN()
c64.CLRCHN()
c64.CLOSE(1)
}
str filename = "0:??????????????????????????????????????"
sub send_command(ubyte drivenumber, uword commandptr) {
; -- send a dos command to the drive
c64.SETNAM(string.length(commandptr), commandptr)
c64.SETLFS(15, drivenumber, 15)
void c64.OPEN()
c64.CLRCHN()
c64.CLOSE(15)
}
}

17
compiler/res/prog8lib/floats_functions.p8
View File

@ -221,13 +221,18 @@ sub ceil(float value) -> float {
}}
}
sub rndf() -> float {
sub rndseedf(float seed) {
if seed>0
seed = -seed ; make sure fp seed is always negative
%asm {{
stx P8ZP_SCRATCH_REG
lda #1
jsr FREADSA
jsr RND ; rng into fac1
ldx P8ZP_SCRATCH_REG
stx floats_store_reg
lda #<seed
ldy #>seed
jsr MOVFM ; load float into fac1
lda #-1
jsr floats.RND
ldx floats_store_reg
rts
}}
}

70
compiler/res/prog8lib/math.asm
View File

@ -229,60 +229,32 @@ _divisor .word 0
.pend
randseed .proc
; -- reset the random seeds for the byte and word random generators
; arguments: uword seed in A/Y clobbers A
; (default starting values are: A=$2c Y=$9e)
sta randword._seed
sty randword._seed+1
clc
adc #14
sta randbyte._seed
rts
.pend
randbyte .proc
; -- 8 bit pseudo random number generator into A (by just reusing randword)
jmp randword
.pend
randword .proc
; -- 16 bit pseudo random number generator into AY
; rand64k ;Factors of 65535: 3 5 17 257
lda sr1+1
asl a
asl a
eor sr1+1
asl a
eor sr1+1
asl a
asl a
eor sr1+1
asl a
rol sr1 ;shift this left, "random" bit comes from low
rol sr1+1
; rand32k ;Factors of 32767: 7 31 151 are independent and can be combined
lda sr2+1
asl a
eor sr2+1
asl a
asl a
ror sr2 ;shift this right, random bit comes from high - nicer when eor with sr1
rol sr2+1
lda sr1+1 ;can be left out
eor sr2+1 ;if you dont use
tay ;y as suggested
lda sr1 ;mix up lowbytes of SR1
eor sr2 ;and SR2 to combine both
; default seed = $00c2 $1137
; routine from https://codebase64.org/doku.php?id=base:x_abc_random_number_generator_8_16_bit
inc x1
clc
x1=*+1
lda #$00 ;x1
c1=*+1
eor #$c2 ;c1
a1=*+1
eor #$11 ;a1
sta a1
b1=*+1
adc #$37 ;b1
sta b1
lsr a
eor a1
adc c1
sta c1
ldy b1
rts
sr1 .word $a55a
sr2 .word $7653
.pend
randbyte = randword ; -- 8 bit pseudo random number generator into A (by just reusing randword)
; ----------- optimized multiplications (stack) : ---------
stack_mul_byte_3 .proc

109
compiler/res/prog8lib/math.p8
View File

@ -37,60 +37,6 @@ _sinecos8 .char trunc(127.0 * sin(range(256+64) * rad(360.0/256.0)))
}}
}
asmsub sin16(ubyte angle @A) -> word @AY {
%asm {{
tay
lda _sinecos8lo,y
pha
lda _sinecos8hi,y
tay
pla
rts
_ := trunc(32767.0 * sin(range(256+64) * rad(360.0/256.0)))
_sinecos8lo .byte <_
_sinecos8hi .byte >_
}}
}
asmsub cos16(ubyte angle @A) -> word @AY {
%asm {{
tay
lda sin16._sinecos8lo+64,y
pha
lda sin16._sinecos8hi+64,y
tay
pla
rts
}}
}
asmsub sin16u(ubyte angle @A) -> uword @AY {
%asm {{
tay
lda _sinecos8ulo,y
pha
lda _sinecos8uhi,y
tay
pla
rts
_ := trunc(32768.0 + 32767.5 * sin(range(256+64) * rad(360.0/256.0)))
_sinecos8ulo .byte <_
_sinecos8uhi .byte >_
}}
}
asmsub cos16u(ubyte angle @A) -> uword @AY {
%asm {{
tay
lda sin16u._sinecos8ulo+64,y
pha
lda sin16u._sinecos8uhi+64,y
tay
pla
rts
}}
}
asmsub sinr8u(ubyte radians @A) clobbers(Y) -> ubyte @A {
%asm {{
tay
@ -125,57 +71,28 @@ _sinecosR8 .char trunc(127.0 * sin(range(180+45) * rad(360.0/180.0)))
}}
}
asmsub sinr16(ubyte radians @A) -> word @AY {
asmsub rnd() -> ubyte @A {
%asm {{
tay
lda _sinecosR8lo,y
pha
lda _sinecosR8hi,y
tay
pla
rts
_ := trunc(32767.0 * sin(range(180+45) * rad(360.0/180.0)))
_sinecosR8lo .byte <_
_sinecosR8hi .byte >_
jmp math.randbyte
}}
}
asmsub cosr16(ubyte radians @A) -> word @AY {
asmsub rndw() -> uword @AY {
%asm {{
tay
lda sinr16._sinecosR8lo+45,y
pha
lda sinr16._sinecosR8hi+45,y
tay
pla
rts
jmp math.randword
}}
}
asmsub sinr16u(ubyte radians @A) -> uword @AY {
asmsub rndseed(uword seed1 @AY, uword seed2 @R0) clobbers(A,Y) {
; -- set new pseudo RNG's seed values. Defaults are: $00c2, $1137
%asm {{
tay
lda _sinecosR8ulo,y
pha
lda _sinecosR8uhi,y
tay
pla
rts
_ := trunc(32768.0 + 32767.5 * sin(range(180+45) * rad(360.0/180.0)))
_sinecosR8ulo .byte <_
_sinecosR8uhi .byte >_
}}
}
asmsub cosr16u(ubyte radians @A) -> uword @AY {
%asm {{
tay
lda sinr16u._sinecosR8ulo+45,y
pha
lda sinr16u._sinecosR8uhi+45,y
tay
pla
rts
sta math.randword.x1
sty math.randword.c1
lda cx16.r0L
sta math.randword.a1
lda cx16.r0H
sta math.randword.b1
rts
}}
}
}

18
compiler/res/prog8lib/prog8_funcs.asm
View File

@ -244,24 +244,6 @@ func_sqrt16_into_A .proc
rts
.pend
func_rnd_stack .proc
; -- put a random ubyte on the estack
jsr math.randbyte
sta P8ESTACK_LO,x
dex
rts
.pend
func_rndw_stack .proc
; -- put a random uword on the estack
jsr math.randword
sta P8ESTACK_LO,x
tya
sta P8ESTACK_HI,x
dex
rts
.pend
func_sort_ub .proc
; 8bit unsigned sort

1
compiler/res/prog8lib/prog8_lib.asm
View File

@ -1082,6 +1082,7 @@ containment_wordarray .proc
iny
cmp (P8ZP_SCRATCH_W2),y
beq _found
dey
+ dey
dey
cpy #254

49
compiler/res/prog8lib/string.p8
View File

@ -129,7 +129,7 @@ _startloop dey
asmsub find(uword string @R0, ubyte character @A) -> ubyte @A, ubyte @Pc {
; Locates the first position of the given character in the string,
; returns Carry set if found + index in A, or Carry clear if not found.
; returns Carry set if found + index in A, or A=0 + Carry clear if not found.
%asm {{
; need to copy the the cx16 virtual registers to zeropage to make this run on C64...
sta P8ZP_SCRATCH_B1
@ -144,7 +144,8 @@ _startloop dey
beq _found
iny
bne -
_notfound clc
_notfound lda #0
clc
rts
_found tya
sec
@ -223,6 +224,49 @@ _done rts
}}
}
asmsub lowerchar(ubyte char @A) -> ubyte @A {
%asm {{
and #$7f
cmp #97
bcc +
cmp #123
bcs +
and #%11011111
+ rts
}}
}
asmsub upperchar(ubyte char @A) -> ubyte @A {
%asm {{
cmp #65
bcc +
cmp #91
bcs +
ora #%00100000
+ rts
}}
}
sub startswith(str st, str prefix) -> bool {
ubyte prefix_len = length(prefix)
ubyte str_len = length(st)
if prefix_len > str_len
return false
cx16.r9L = st[prefix_len]
st[prefix_len] = 0
cx16.r9H = compare(st, prefix) as ubyte
st[prefix_len] = cx16.r9L
return cx16.r9H==0
}
sub endswith(str st, str suffix) -> bool {
ubyte suffix_len = length(suffix)
ubyte str_len = length(st)
if suffix_len > str_len
return false
return compare(st + str_len - suffix_len, suffix) == 0
}
asmsub pattern_match(str string @AY, str pattern @R0) clobbers(Y) -> ubyte @A {
%asm {{
; pattern matching of a string.
@ -293,5 +337,4 @@ fail clc ; yes, no match found, return with c=0
rts
}}
}
}

8
compiler/res/prog8lib/virtual/conv.p8
View File

@ -195,8 +195,8 @@ sub str2uword(str string) -> uword {
; -- returns the unsigned word value of the string number argument in AY
; the number may NOT be preceded by a + sign and may NOT contain spaces
; (any non-digit character will terminate the number string that is parsed)
%asm {{
loadm.w r0, {conv.str2uword.string}
%ir {{
loadm.w r65500,conv.str2uword.string
syscall 11
return
}}
@ -206,8 +206,8 @@ sub str2word(str string) -> word {
; -- returns the signed word value of the string number argument in AY
; the number may be preceded by a + or - sign but may NOT contain spaces
; (any non-digit character will terminate the number string that is parsed)
%asm {{
loadm.w r0, {conv.str2word.string}
%ir {{
loadm.w r65500,conv.str2word.string
syscall 12
return
}}

68
compiler/res/prog8lib/virtual/floats.p8
View File

@ -9,82 +9,82 @@ floats {
sub print_f(float value) {
; ---- prints the floating point value (without a newline).
%asm {{
loadm.f fr0,{floats.print_f.value}
%ir {{
loadm.f fr65500,floats.print_f.value
syscall 25
return
}}
}
sub pow(float value, float power) -> float {
%asm {{
loadm.f fr0,{floats.pow.value}
loadm.f fr1,{floats.pow.power}
%ir {{
loadm.f fr0,floats.pow.value
loadm.f fr1,floats.pow.power
fpow.f fr0,fr1
return
}}
}
sub fabs(float value) -> float {
%asm {{
loadm.f fr0,{floats.fabs.value}
%ir {{
loadm.f fr0,floats.fabs.value
fabs.f fr0,fr0
return
}}
}
sub sin(float angle) -> float {
%asm {{
loadm.f fr0,{floats.sin.angle}
%ir {{
loadm.f fr0,floats.sin.angle
fsin.f fr0,fr0
return
}}
}
sub cos(float angle) -> float {
%asm {{
loadm.f fr0,{floats.cos.angle}
%ir {{
loadm.f fr0,floats.cos.angle
fcos.f fr0,fr0
return
}}
}
sub tan(float value) -> float {
%asm {{
loadm.f fr0,{floats.tan.value}
%ir {{
loadm.f fr0,floats.tan.value
ftan.f fr0,fr0
return
}}
}
sub atan(float value) -> float {
%asm {{
loadm.f fr0,{floats.atan.value}
%ir {{
loadm.f fr0,floats.atan.value
fatan.f fr0,fr0
return
}}
}
sub ln(float value) -> float {
%asm {{
loadm.f fr0,{floats.ln.value}
%ir {{
loadm.f fr0,floats.ln.value
fln.f fr0,fr0
return
}}
}
sub log2(float value) -> float {
%asm {{
loadm.f fr0,{floats.log2.value}
%ir {{
loadm.f fr0,floats.log2.value
flog.f fr0,fr0
return
}}
}
sub sqrt(float value) -> float {
%asm {{
loadm.f fr0,{floats.sqrt.value}
fsqrt.f fr0,fr0
%ir {{
loadm.f fr0,floats.sqrt.value
sqrt.f fr0,fr0
return
}}
}
@ -100,16 +100,16 @@ sub deg(float angle) -> float {
}
sub round(float value) -> float {
%asm {{
loadm.f fr0,{floats.round.value}
%ir {{
loadm.f fr0,floats.round.value
fround.f fr0,fr0
return
}}
}
sub floor(float value) -> float {
%asm {{
loadm.f fr0,{floats.floor.value}
%ir {{
loadm.f fr0,floats.floor.value
ffloor.f fr0,fr0
return
}}
@ -117,17 +117,25 @@ sub floor(float value) -> float {
sub ceil(float value) -> float {
; -- ceil: tr = int(f); if tr==f -> return else return tr+1
%asm {{
loadm.f fr0,{floats.ceil.value}
%ir {{
loadm.f fr0,floats.ceil.value
fceil.f fr0,fr0
return
}}
}
sub rndf() -> float {
%asm {{
rnd.f fr0
%ir {{
syscall 35
return
}}
}
sub rndseedf(float seed) {
%ir {{
loadm.f fr65500,floats.rndseedf.seed
syscall 32
}}
}
}

122
compiler/res/prog8lib/virtual/math.p8
View File

@ -19,7 +19,7 @@ math {
$0f, $11, $12, $14, $15, $17, $19, $1b, $1d, $1f, $21, $23, $25, $28, $2a, $2c,
$2f, $31, $34, $36, $39, $3b, $3e, $41, $43, $46, $49, $4c, $4f, $52, $55, $58,
$5a, $5d, $61, $64, $67, $6a, $6d, $70, $73, $76, $79, $7c]
return sintab[angle]
return sintab[angle]
}
sub cos8u(ubyte angle) -> ubyte {
@ -40,31 +40,53 @@ math {
$bc, $be, $c1, $c4, $c6, $c9, $cb, $ce, $d0, $d3, $d5, $d7, $da, $dc, $de, $e0,
$e2, $e4, $e6, $e8, $ea, $eb, $ed, $ee, $f0, $f1, $f3, $f4, $f5, $f6, $f8, $f9,
$fa, $fa, $fb, $fc, $fd, $fd, $fe, $fe, $fe, $ff, $ff, $ff ]
return costab[angle]
return costab[angle]
}
sub sin8(ubyte angle) -> byte {
return 42 ; TODO
ubyte[256] sintab = [
$00, $03, $06, $09,
$0c, $0f, $12, $15, $18, $1b, $1e, $21, $24, $27, $2a, $2d, $30, $33, $36, $39,
$3b, $3e, $41, $43, $46, $49, $4b, $4e, $50, $52, $55, $57, $59, $5b, $5e, $60,
$62, $64, $66, $67, $69, $6b, $6c, $6e, $70, $71, $72, $74, $75, $76, $77, $78,
$79, $7a, $7b, $7b, $7c, $7d, $7d, $7e, $7e, $7e, $7e, $7e, $7f, $7e, $7e, $7e,
$7e, $7e, $7d, $7d, $7c, $7b, $7b, $7a, $79, $78, $77, $76, $75, $74, $72, $71,
$70, $6e, $6c, $6b, $69, $67, $66, $64, $62, $60, $5e, $5b, $59, $57, $55, $52,
$50, $4e, $4b, $49, $46, $43, $41, $3e, $3b, $39, $36, $33, $30, $2d, $2a, $27,
$24, $21, $1e, $1b, $18, $15, $12, $0f, $0c, $09, $06, $03, $00, $fd, $fa, $f7,
$f4, $f1, $ee, $eb, $e8, $e5, $e2, $df, $dc, $d9, $d6, $d3, $d0, $cd, $ca, $c7,
$c5, $c2, $bf, $bd, $ba, $b7, $b5, $b2, $b0, $ae, $ab, $a9, $a7, $a5, $a2, $a0,
$9e, $9c, $9a, $99, $97, $95, $94, $92, $90, $8f, $8e, $8c, $8b, $8a, $89, $88,
$87, $86, $85, $85, $84, $83, $83, $82, $82, $82, $82, $82, $81, $82, $82, $82,
$82, $82, $83, $83, $84, $85, $85, $86, $87, $88, $89, $8a, $8b, $8c, $8e, $8f,
$90, $92, $94, $95, $97, $99, $9a, $9c, $9e, $a0, $a2, $a5, $a7, $a9, $ab, $ae,
$b0, $b2, $b5, $b7, $ba, $bd, $bf, $c2, $c5, $c7, $ca, $cd, $d0, $d3, $d6, $d9,
$dc, $df, $e2, $e5, $e8, $eb, $ee, $f1, $f4, $f7, $fa, $fd
]
return sintab[angle] as byte
}
sub cos8(ubyte angle) -> byte {
return 42 ; TODO
}
sub sin16(ubyte angle) -> word {
return 4242 ; TODO
}
sub cos16(ubyte angle) -> word {
return 4242 ; TODO
}
sub sin16u(ubyte angle) -> uword {
return 4242 ; TODO
}
sub cos16u(ubyte angle) -> uword {
return 4242 ; TODO
ubyte[256] costab = [
$7f, $7e, $7e, $7e,
$7e, $7e, $7d, $7d, $7c, $7b, $7b, $7a, $79, $78, $77, $76, $75, $74, $72, $71,
$70, $6e, $6c, $6b, $69, $67, $66, $64, $62, $60, $5e, $5b, $59, $57, $55, $52,
$50, $4e, $4b, $49, $46, $43, $41, $3e, $3b, $39, $36, $33, $30, $2d, $2a, $27,
$24, $21, $1e, $1b, $18, $15, $12, $0f, $0c, $09, $06, $03, $00, $fd, $fa, $f7,
$f4, $f1, $ee, $eb, $e8, $e5, $e2, $df, $dc, $d9, $d6, $d3, $d0, $cd, $ca, $c7,
$c5, $c2, $bf, $bd, $ba, $b7, $b5, $b2, $b0, $ae, $ab, $a9, $a7, $a5, $a2, $a0,
$9e, $9c, $9a, $99, $97, $95, $94, $92, $90, $8f, $8e, $8c, $8b, $8a, $89, $88,
$87, $86, $85, $85, $84, $83, $83, $82, $82, $82, $82, $82, $81, $82, $82, $82,
$82, $82, $83, $83, $84, $85, $85, $86, $87, $88, $89, $8a, $8b, $8c, $8e, $8f,
$90, $92, $94, $95, $97, $99, $9a, $9c, $9e, $a0, $a2, $a5, $a7, $a9, $ab, $ae,
$b0, $b2, $b5, $b7, $ba, $bd, $bf, $c2, $c5, $c7, $ca, $cd, $d0, $d3, $d6, $d9,
$dc, $df, $e2, $e5, $e8, $eb, $ee, $f1, $f4, $f7, $fa, $fd, $00, $03, $06, $09,
$0c, $0f, $12, $15, $18, $1b, $1e, $21, $24, $27, $2a, $2d, $30, $33, $36, $39,
$3b, $3e, $41, $43, $46, $49, $4b, $4e, $50, $52, $55, $57, $59, $5b, $5e, $60,
$62, $64, $66, $67, $69, $6b, $6c, $6e, $70, $71, $72, $74, $75, $76, $77, $78,
$79, $7a, $7b, $7b, $7c, $7d, $7d, $7e, $7e, $7e, $7e, $7e
]
return costab[angle] as byte
}
sub sinr8u(ubyte radians) -> ubyte {
@ -102,26 +124,62 @@ math {
}
sub sinr8(ubyte radians) -> byte {
return 42 ; TODO
ubyte[180] sintab = [
$00, $04, $08, $0d,
$11, $16, $1a, $1e, $23, $27, $2b, $2f, $33, $37, $3b, $3f, $43, $47, $4a, $4e,
$51, $54, $58, $5b, $5e, $61, $64, $66, $69, $6b, $6d, $70, $72, $74, $75, $77,
$78, $7a, $7b, $7c, $7d, $7d, $7e, $7e, $7e, $7f, $7e, $7e, $7e, $7d, $7d, $7c,
$7b, $7a, $78, $77, $75, $74, $72, $70, $6d, $6b, $69, $66, $64, $61, $5e, $5b,
$58, $54, $51, $4e, $4a, $47, $43, $3f, $3b, $37, $33, $2f, $2b, $27, $23, $1e,
$1a, $16, $11, $0d, $08, $04, $00, $fc, $f8, $f3, $ef, $ea, $e6, $e2, $dd, $d9,
$d5, $d1, $cd, $c9, $c5, $c1, $bd, $b9, $b6, $b2, $af, $ac, $a8, $a5, $a2, $9f,
$9c, $9a, $97, $95, $93, $90, $8e, $8c, $8b, $89, $88, $86, $85, $84, $83, $83,
$82, $82, $82, $81, $82, $82, $82, $83, $83, $84, $85, $86, $88, $89, $8b, $8c,
$8e, $90, $93, $95, $97, $9a, $9c, $9f, $a2, $a5, $a8, $ac, $af, $b2, $b6, $b9,
$bd, $c1, $c5, $c9, $cd, $d1, $d5, $d9, $dd, $e2, $e6, $ea, $ef, $f3, $f8, $fc
]
return sintab[radians] as byte
}
sub cosr8(ubyte radians) -> byte {
return 42 ; TODO
ubyte[180] costab = [
$7f, $7e, $7e, $7e, $7d, $7d, $7c,
$7b, $7a, $78, $77, $75, $74, $72, $70, $6d, $6b, $69, $66, $64, $61, $5e, $5b,
$58, $54, $51, $4e, $4a, $47, $43, $3f, $3b, $37, $33, $2f, $2b, $27, $23, $1e,
$1a, $16, $11, $0d, $08, $04, $00, $fc, $f8, $f3, $ef, $ea, $e6, $e2, $dd, $d9,
$d5, $d1, $cd, $c9, $c5, $c1, $bd, $b9, $b6, $b2, $af, $ac, $a8, $a5, $a2, $9f,
$9c, $9a, $97, $95, $93, $90, $8e, $8c, $8b, $89, $88, $86, $85, $84, $83, $83,
$82, $82, $82, $81, $82, $82, $82, $83, $83, $84, $85, $86, $88, $89, $8b, $8c,
$8e, $90, $93, $95, $97, $9a, $9c, $9f, $a2, $a5, $a8, $ac, $af, $b2, $b6, $b9,
$bd, $c1, $c5, $c9, $cd, $d1, $d5, $d9, $dd, $e2, $e6, $ea, $ef, $f3, $f8, $fc,
$00, $04, $08, $0d, $11, $16, $1a, $1e, $23, $27, $2b, $2f, $33, $37, $3b, $3f,
$43, $47, $4a, $4e, $51, $54, $58, $5b, $5e, $61, $64, $66, $69, $6b, $6d, $70,
$72, $74, $75, $77, $78, $7a, $7b, $7c, $7d, $7d, $7e, $7e, $7e
]
return costab[radians] as byte
}
sub sinr16(ubyte radians) -> word {
return 4242 ; TODO
sub rnd() -> ubyte {
%ir {{
syscall 33
return
}}
}
sub cosr16(ubyte radians) -> word {
return 4242 ; TODO
sub rndw() -> uword {
%ir {{
syscall 34
return
}}
}
sub sinr16u(ubyte radians) -> uword {
return 4242 ; TODO
}
sub cosr16u(ubyte radians) -> uword {
return 4242 ; TODO
sub rndseed(uword seed1, uword seed2) {
; -- reset the pseudo RNG's seed values. Defaults are: $a55a, $7653.
%ir {{
loadm.w r65500,math.rndseed.seed1
loadm.w r65501,math.rndseed.seed2
syscall 31
return
}}
}
}

47
compiler/res/prog8lib/virtual/prog8_lib.p8
View File

@ -1,53 +1,6 @@
; Internal library routines - always included by the compiler
%import textio
prog8_lib {
%option force_output
sub string_contains(ubyte needle, str haystack) -> ubyte {
repeat {
if @(haystack)==0
return false
if @(haystack)==needle
return true
haystack++
}
}
sub bytearray_contains(ubyte needle, uword haystack_ptr, ubyte num_elements) -> ubyte {
haystack_ptr--
while num_elements {
if haystack_ptr[num_elements]==needle
return true
num_elements--
}
return false
}
sub wordarray_contains(ubyte needle, uword haystack_ptr, ubyte num_elements) -> ubyte {
haystack_ptr += (num_elements-1) * 2
while num_elements {
if peekw(haystack_ptr)==needle
return true
haystack_ptr -= 2
num_elements--
}
return false
}
sub string_compare(str st1, str st2) -> byte {
; Compares two strings for sorting.
; Returns -1 (255), 0 or 1 depending on wether string1 sorts before, equal or after string2.
; Note that you can also directly compare strings and string values with eachother using
; comparison operators ==, < etcetera (it will use strcmp for you under water automatically).
%asm {{
loadm.w r0, {prog8_lib.string_compare.st1}
loadm.w r1, {prog8_lib.string_compare.st2}
syscall 29
return
}}
}
}

39
compiler/res/prog8lib/virtual/string.p8
View File

@ -83,7 +83,12 @@ string {
; Returns -1 (255), 0 or 1 depending on wether string1 sorts before, equal or after string2.
; Note that you can also directly compare strings and string values with eachother using
; comparison operators ==, < etcetera (it will use strcmp for you under water automatically).
return prog8_lib.string_compare(st1, st2)
%ir {{
loadm.w r65500,string.compare.st1
loadm.w r65501,string.compare.st2
syscall 29
return
}}
}
sub lower(str st) -> ubyte {
@ -113,4 +118,36 @@ string {
ix++
}
}
sub lowerchar(ubyte char) -> ubyte {
if char >= 'A' and char <= 'Z'
char |= %00100000
return char
}
sub upperchar(ubyte char) -> ubyte {
if char >= 'a' and char <= 'z'
char &= %11011111
return char
}
sub startswith(str st, str prefix) -> bool {
ubyte prefix_len = length(prefix)
ubyte str_len = length(st)
if prefix_len > str_len
return false
cx16.r9L = st[prefix_len]
st[prefix_len] = 0
cx16.r9H = compare(st, prefix) as ubyte
st[prefix_len] = cx16.r9L
return cx16.r9H==0
}
sub endswith(str st, str suffix) -> bool {
ubyte suffix_len = length(suffix)
ubyte str_len = length(st)
if suffix_len > str_len
return false
return compare(st + str_len - suffix_len, suffix) == 0
}
}

233
compiler/res/prog8lib/virtual/syslib.p8
View File

@ -7,22 +7,22 @@ sys {
sub reset_system() {
; Soft-reset the system back to initial power-on Basic prompt.
%asm {{
%ir {{
syscall 0
}}
}
sub wait(uword jiffies) {
; --- wait approximately the given number of jiffies (1/60th seconds)
%asm {{
loadm.w r0, {sys.wait.jiffies}
%ir {{
loadm.w r65500,sys.wait.jiffies
syscall 13
}}
}
sub waitvsync() {
; --- busy wait till the next vsync has occurred (approximately), without depending on custom irq handling.
%asm {{
%ir {{
syscall 14
}}
}
@ -61,45 +61,52 @@ sys {
sub exit(ubyte returnvalue) {
; -- immediately exit the program with a return code in the A register
%asm {{
loadm.b r0,{sys.exit.returnvalue}
%ir {{
loadm.b r65500,sys.exit.returnvalue
syscall 1
}}
}
sub set_carry() {
%asm {{
%ir {{
sec
}}
}
sub clear_carry() {
%asm {{
%ir {{
clc
}}
}
sub gfx_enable(ubyte mode) {
%asm {{
loadm.b r0, {sys.gfx_enable.mode}
%ir {{
loadm.b r65500,sys.gfx_enable.mode
syscall 8
}}
}
sub gfx_clear(ubyte color) {
%ir {{
loadm.b r65500,sys.gfx_clear.color
syscall 9
}}
}
sub gfx_plot(uword xx, uword yy, ubyte color) {
%asm {{
loadm.w r0, {sys.gfx_plot.xx}
loadm.w r1, {sys.gfx_plot.yy}
loadm.b r2, {sys.gfx_plot.color}
%ir {{
loadm.w r65500,sys.gfx_plot.xx
loadm.w r65501,sys.gfx_plot.yy
loadm.b r65502,sys.gfx_plot.color
syscall 10
}}
}
sub gfx_getpixel(uword xx, uword yy) -> ubyte {
%asm {{
loadm.w r0, {sys.gfx_getpixel.xx}
loadm.w r1, {sys.gfx_getpixel.yy}
%ir {{
loadm.w r65500,sys.gfx_getpixel.xx
loadm.w r65501,sys.gfx_getpixel.yy
syscall 30
return
}}
@ -110,105 +117,105 @@ cx16 {
; the sixteen virtual 16-bit registers that the CX16 has defined in the zeropage
; they are simulated on the VirtualMachine as well but their location in memory is different
&uword r0 = $0002
&uword r1 = $0004
&uword r2 = $0006
&uword r3 = $0008
&uword r4 = $000a
&uword r5 = $000c
&uword r6 = $000e
&uword r7 = $0010
&uword r8 = $0012
&uword r9 = $0014
&uword r10 = $0016
&uword r11 = $0018
&uword r12 = $001a
&uword r13 = $001c
&uword r14 = $001e
&uword r15 = $0020
&uword r0 = $ff02
&uword r1 = $ff04
&uword r2 = $ff06
&uword r3 = $ff08
&uword r4 = $ff0a
&uword r5 = $ff0c
&uword r6 = $ff0e
&uword r7 = $ff10
&uword r8 = $ff12
&uword r9 = $ff14
&uword r10 = $ff16
&uword r11 = $ff18
&uword r12 = $ff1a
&uword r13 = $ff1c
&uword r14 = $ff1e
&uword r15 = $ff20
&word r0s = $0002
&word r1s = $0004
&word r2s = $0006
&word r3s = $0008
&word r4s = $000a
&word r5s = $000c
&word r6s = $000e
&word r7s = $0010
&word r8s = $0012
&word r9s = $0014
&word r10s = $0016
&word r11s = $0018
&word r12s = $001a
&word r13s = $001c
&word r14s = $001e
&word r15s = $0020
&word r0s = $ff02
&word r1s = $ff04
&word r2s = $ff06
&word r3s = $ff08
&word r4s = $ff0a
&word r5s = $ff0c
&word r6s = $ff0e
&word r7s = $ff10
&word r8s = $ff12
&word r9s = $ff14
&word r10s = $ff16
&word r11s = $ff18
&word r12s = $ff1a
&word r13s = $ff1c
&word r14s = $ff1e
&word r15s = $ff20
&ubyte r0L = $0002
&ubyte r1L = $0004
&ubyte r2L = $0006
&ubyte r3L = $0008
&ubyte r4L = $000a
&ubyte r5L = $000c
&ubyte r6L = $000e
&ubyte r7L = $0010
&ubyte r8L = $0012
&ubyte r9L = $0014
&ubyte r10L = $0016
&ubyte r11L = $0018
&ubyte r12L = $001a
&ubyte r13L = $001c
&ubyte r14L = $001e
&ubyte r15L = $0020
&ubyte r0L = $ff02
&ubyte r1L = $ff04
&ubyte r2L = $ff06
&ubyte r3L = $ff08
&ubyte r4L = $ff0a
&ubyte r5L = $ff0c
&ubyte r6L = $ff0e
&ubyte r7L = $ff10
&ubyte r8L = $ff12
&ubyte r9L = $ff14
&ubyte r10L = $ff16
&ubyte r11L = $ff18
&ubyte r12L = $ff1a
&ubyte r13L = $ff1c
&ubyte r14L = $ff1e
&ubyte r15L = $ff20
&ubyte r0H = $0003
&ubyte r1H = $0005
&ubyte r2H = $0007
&ubyte r3H = $0009
&ubyte r4H = $000b
&ubyte r5H = $000d
&ubyte r6H = $000f
&ubyte r7H = $0011
&ubyte r8H = $0013
&ubyte r9H = $0015
&ubyte r10H = $0017
&ubyte r11H = $0019
&ubyte r12H = $001b
&ubyte r13H = $001d
&ubyte r14H = $001f
&ubyte r15H = $0021
&ubyte r0H = $ff03
&ubyte r1H = $ff05
&ubyte r2H = $ff07
&ubyte r3H = $ff09
&ubyte r4H = $ff0b
&ubyte r5H = $ff0d
&ubyte r6H = $ff0f
&ubyte r7H = $ff11
&ubyte r8H = $ff13
&ubyte r9H = $ff15
&ubyte r10H = $ff17
&ubyte r11H = $ff19
&ubyte r12H = $ff1b
&ubyte r13H = $ff1d
&ubyte r14H = $ff1f
&ubyte r15H = $ff21
&byte r0sL = $0002
&byte r1sL = $0004
&byte r2sL = $0006
&byte r3sL = $0008
&byte r4sL = $000a
&byte r5sL = $000c
&byte r6sL = $000e
&byte r7sL = $0010
&byte r8sL = $0012
&byte r9sL = $0014
&byte r10sL = $0016
&byte r11sL = $0018
&byte r12sL = $001a
&byte r13sL = $001c
&byte r14sL = $001e
&byte r15sL = $0020
&byte r0sL = $ff02
&byte r1sL = $ff04
&byte r2sL = $ff06
&byte r3sL = $ff08
&byte r4sL = $ff0a
&byte r5sL = $ff0c
&byte r6sL = $ff0e
&byte r7sL = $ff10
&byte r8sL = $ff12
&byte r9sL = $ff14
&byte r10sL = $ff16
&byte r11sL = $ff18
&byte r12sL = $ff1a
&byte r13sL = $ff1c
&byte r14sL = $ff1e
&byte r15sL = $ff20
&byte r0sH = $0003
&byte r1sH = $0005
&byte r2sH = $0007
&byte r3sH = $0009
&byte r4sH = $000b
&byte r5sH = $000d
&byte r6sH = $000f
&byte r7sH = $0011
&byte r8sH = $0013
&byte r9sH = $0015
&byte r10sH = $0017
&byte r11sH = $0019
&byte r12sH = $001b
&byte r13sH = $001d
&byte r14sH = $001f
&byte r15sH = $0021
&byte r0sH = $ff03
&byte r1sH = $ff05
&byte r2sH = $ff07
&byte r3sH = $ff09
&byte r4sH = $ff0b
&byte r5sH = $ff0d
&byte r6sH = $ff0f
&byte r7sH = $ff11
&byte r8sH = $ff13
&byte r9sH = $ff15
&byte r10sH = $ff17
&byte r11sH = $ff19
&byte r12sH = $ff1b
&byte r13sH = $ff1d
&byte r14sH = $ff1f
&byte r15sH = $ff21
}

31
compiler/res/prog8lib/virtual/textio.p8
View File

@ -6,8 +6,8 @@ txt {
sub clear_screen() {
str @shared sequence = "\x1b[2J\x1B[H"
%asm {{
load.w r0, {txt.clear_screen.sequence}
%ir {{
load.w r65500,txt.clear_screen.sequence
syscall 3
}}
}
@ -29,15 +29,15 @@ sub uppercase() {
}
sub chrout(ubyte char) {
%asm {{
loadm.b r0, {txt.chrout.char}
%ir {{
loadm.b r65500,txt.chrout.char
syscall 2
}}
}
sub print (str text) {
%asm {{
loadm.w r0, {txt.print.text}
%ir {{
loadm.w r65500,txt.print.text
syscall 3
}}
}
@ -113,11 +113,26 @@ sub print_w (word value) {
sub input_chars (uword buffer) -> ubyte {
; ---- Input a string (max. 80 chars) from the keyboard. Returns length of input. (string is terminated with a 0 byte as well)
; It assumes the keyboard is selected as I/O channel!
%asm {{
loadm.w r0,{txt.input_chars.buffer}
%ir {{
loadm.w r65500,txt.input_chars.buffer
syscall 6
return
}}
}
sub plot (ubyte col, ubyte row) {
; use ANSI escape sequence to position the cursor
txt.chrout(27)
txt.chrout('[')
txt.print_ub(row)
txt.chrout(';')
txt.print_ub(col)
txt.chrout('H')
}
sub setchr (ubyte col, ubyte row, ubyte char) {
plot(col, row)
txt.chrout(char)
}
}

2
compiler/res/version.txt
View File

@ -1 +1 @@
8.3.1
8.8

67
compiler/src/prog8/CompilerMain.kt
View File

@ -12,9 +12,10 @@ import prog8.compiler.compileProgram
import java.io.File
import java.nio.file.FileSystems
import java.nio.file.Path
import java.nio.file.Paths
import java.nio.file.StandardWatchEventKinds
import java.nio.file.WatchKey
import java.time.LocalDateTime
import kotlin.io.path.Path
import kotlin.system.exitProcess
@ -34,23 +35,23 @@ fun pathFrom(stringPath: String, vararg rest: String): Path = FileSystems.getDe
private fun compileMain(args: Array<String>): Boolean {
val cli = ArgParser("prog8compiler", prefixStyle = ArgParser.OptionPrefixStyle.JVM)
val startEmulator1 by cli.option(ArgType.Boolean, fullName = "emu", description = "auto-start emulator after successful compilation")
val startEmulator2 by cli.option(ArgType.Boolean, fullName = "emu2", description = "auto-start alternative emulator after successful compilation")
val outputDir by cli.option(ArgType.String, fullName = "out", description = "directory for output files instead of current directory").default(".")
val dontWriteAssembly by cli.option(ArgType.Boolean, fullName = "noasm", description="don't create assembly code")
val dontOptimize by cli.option(ArgType.Boolean, fullName = "noopt", description = "don't perform any optimizations")
val dontReinitGlobals by cli.option(ArgType.Boolean, fullName = "noreinit", description = "don't create code to reinitialize globals on multiple runs of the program (experimental!)")
val optimizeFloatExpressions by cli.option(ArgType.Boolean, fullName = "optfloatx", description = "optimize float expressions (warning: can increase program size)")
val watchMode by cli.option(ArgType.Boolean, fullName = "watch", description = "continuous compilation mode (watch for file changes)")
val slowCodegenWarnings by cli.option(ArgType.Boolean, fullName = "slowwarn", description="show debug warnings about slow/problematic assembly code generation")
val quietAssembler by cli.option(ArgType.Boolean, fullName = "quietasm", description = "don't print assembler output results")
val asmListfile by cli.option(ArgType.Boolean, fullName = "asmlist", description = "make the assembler produce a listing file as well")
val experimentalCodegen by cli.option(ArgType.Boolean, fullName = "expericodegen", description = "use experimental/alternative codegen")
val compilationTarget by cli.option(ArgType.String, fullName = "target", description = "target output of the compiler (one of '${C64Target.NAME}', '${C128Target.NAME}', '${Cx16Target.NAME}', '${AtariTarget.NAME}', '${VMTarget.NAME}')").default(C64Target.NAME)
val sourceDirs by cli.option(ArgType.String, fullName="srcdirs", description = "list of extra paths, separated with ${File.pathSeparator}, to search in for imported modules").multiple().delimiter(File.pathSeparator)
val startVm by cli.option(ArgType.Boolean, fullName = "vm", description = "load and run a p8-virt listing in the VM instead")
val symbolDefs by cli.option(ArgType.String, fullName = "D", description = "define assembly symbol(s) with -D SYMBOL=VALUE").multiple()
val evalStackAddrString by cli.option(ArgType.String, fullName = "esa", description = "override the eval-stack base address (must be page aligned)")
val startEmulator1 by cli.option(ArgType.Boolean, fullName = "emu", description = "auto-start emulator after successful compilation")
val startEmulator2 by cli.option(ArgType.Boolean, fullName = "emu2", description = "auto-start alternative emulator after successful compilation")
val experimentalCodegen by cli.option(ArgType.Boolean, fullName = "expericodegen", description = "use experimental/alternative codegen")
val dontWriteAssembly by cli.option(ArgType.Boolean, fullName = "noasm", description="don't create assembly code")
val dontOptimize by cli.option(ArgType.Boolean, fullName = "noopt", description = "don't perform any optimizations")
val dontReinitGlobals by cli.option(ArgType.Boolean, fullName = "noreinit", description = "don't create code to reinitialize globals on multiple runs of the program (experimental)")
val outputDir by cli.option(ArgType.String, fullName = "out", description = "directory for output files instead of current directory").default(".")
val optimizeFloatExpressions by cli.option(ArgType.Boolean, fullName = "optfloatx", description = "optimize float expressions (warning: can increase program size)")
val quietAssembler by cli.option(ArgType.Boolean, fullName = "quietasm", description = "don't print assembler output results")
val slowCodegenWarnings by cli.option(ArgType.Boolean, fullName = "slowwarn", description="show debug warnings about slow/problematic assembly code generation")
val sourceDirs by cli.option(ArgType.String, fullName="srcdirs", description = "list of extra paths, separated with ${File.pathSeparator}, to search in for imported modules").multiple().delimiter(File.pathSeparator)
val compilationTarget by cli.option(ArgType.String, fullName = "target", description = "target output of the compiler (one of '${C64Target.NAME}', '${C128Target.NAME}', '${Cx16Target.NAME}', '${AtariTarget.NAME}', '${VMTarget.NAME}')").default(C64Target.NAME)
val startVm by cli.option(ArgType.Boolean, fullName = "vm", description = "load and run a .p8ir IR source file in the VM")
val watchMode by cli.option(ArgType.Boolean, fullName = "watch", description = "continuous compilation mode (watch for file changes)")
val moduleFiles by cli.argument(ArgType.String, fullName = "modules", description = "main module file(s) to compile").multiple(999)
try {
@ -143,21 +144,31 @@ private fun compileMain(args: Array<String>): Boolean {
for (importedFile in allImportedFiles) {
print(" ")
println(importedFile)
val watchDir = importedFile.parent ?: Path.of("")
val watchDir = importedFile.parent ?: Path("")
watchDir.register(watchservice, StandardWatchEventKinds.ENTRY_MODIFY)
}
println("[${LocalDateTime.now().withNano(0)}] Waiting for file changes.")
fun determineRecompilationNeeded(event: WatchKey): Boolean {
if(event.isValid) {
for (changed in event.pollEvents()) {
if (changed.kind() == StandardWatchEventKinds.ENTRY_MODIFY) {
val changedPath = changed.context() as Path
if (allImportedFiles.any { it.fileName == changedPath.fileName }) {
println(" change detected: $changedPath")
return true
}
}
}
}
return false
}
var recompile=false
while(!recompile) {
val event = watchservice.take()
for (changed in event.pollEvents()) {
val changedPath = changed.context() as Path
if(allImportedFiles.any { it.fileName == changedPath.fileName }) {
println(" change detected: $changedPath")
recompile = true
}
}
Thread.sleep(50) // avoid multiple events on same file
recompile = determineRecompilationNeeded(event)
event.reset()
}
@ -234,13 +245,9 @@ private fun processSymbolDefs(symbolDefs: List<String>): Map<String, String>? {
return result
}
fun runVm(listingFilename: String): Boolean {
val name =
if(listingFilename.endsWith(".p8virt"))
listingFilename.substring(0, listingFilename.length-7)
else
listingFilename
fun runVm(irFilename: String): Boolean {
val irFile = Path(irFilename)
val vmdef = VirtualMachineDefinition()
vmdef.launchEmulator(0, Paths.get(name))
vmdef.launchEmulator(0, irFile)
return true
}

30
compiler/src/prog8/compiler/Compiler.kt
View File

@ -14,6 +14,7 @@ import prog8.ast.walk.IAstVisitor
import prog8.code.SymbolTable
import prog8.code.core.*
import prog8.code.target.*
import prog8.codegen.vm.VmCodeGen
import prog8.compiler.astprocessing.*
import prog8.optimizer.*
import prog8.parser.ParseError
@ -92,7 +93,7 @@ fun compileProgram(args: CompilerArguments): CompilationResult? {
processAst(program, args.errors, compilationOptions)
if (compilationOptions.optimize) {
// println("*********** AST RIGHT BEFORE OPTIMIZING *************")
// println("*********** COMPILER AST RIGHT BEFORE OPTIMIZING *************")
// printProgram(program)
optimizeAst(
@ -105,7 +106,7 @@ fun compileProgram(args: CompilerArguments): CompilationResult? {
}
postprocessAst(program, args.errors, compilationOptions)
// println("*********** AST BEFORE ASSEMBLYGEN *************")
// println("*********** COMPILER AST BEFORE ASSEMBLYGEN *************")
// printProgram(program)
determineProgramLoadAddress(program, compilationOptions, args.errors)
@ -328,7 +329,7 @@ fun determineCompilationOptions(program: Program, compTarget: ICompilationTarget
private fun processAst(program: Program, errors: IErrorReporter, compilerOptions: CompilationOptions) {
println("Analyzing code...")
program.preprocessAst(errors, compilerOptions.compTarget)
program.preprocessAst(errors, compilerOptions)
program.checkIdentifiers(errors, compilerOptions)
errors.report()
program.charLiteralsToUByteLiterals(compilerOptions.compTarget, errors)
@ -339,7 +340,7 @@ private fun processAst(program: Program, errors: IErrorReporter, compilerOptions
errors.report()
program.reorderStatements(errors, compilerOptions)
errors.report()
program.changeNotExpression(errors)
program.changeNotExpressionAndIfComparisonExpr(errors, compilerOptions.compTarget)
errors.report()
program.addTypecasts(errors, compilerOptions)
errors.report()
@ -358,7 +359,7 @@ private fun optimizeAst(program: Program, compilerOptions: CompilationOptions, e
remover.applyModifications()
while (true) {
// keep optimizing expressions and statements until no more steps remain
val optsDone1 = program.simplifyExpressions()
val optsDone1 = program.simplifyExpressions(errors, compTarget)
val optsDone2 = program.splitBinaryExpressions(compilerOptions)
val optsDone3 = program.optimizeStatements(errors, functions, compTarget)
val optsDone4 = program.inlineSubroutines()
@ -379,7 +380,7 @@ private fun postprocessAst(program: Program, errors: IErrorReporter, compilerOpt
callGraph.checkRecursiveCalls(errors)
program.verifyFunctionArgTypes(errors)
errors.report()
program.moveMainAndStartToFirst()
program.moveMainBlockAsFirst()
program.checkValid(errors, compilerOptions) // check if final tree is still valid
errors.report()
}
@ -388,10 +389,10 @@ private fun createAssemblyAndAssemble(program: Program,
errors: IErrorReporter,
compilerOptions: CompilationOptions
): Boolean {
compilerOptions.compTarget.machine.initializeZeropage(compilerOptions)
compilerOptions.compTarget.machine.initializeMemoryAreas(compilerOptions)
program.processAstBeforeAsmGeneration(compilerOptions, errors)
errors.report()
val symbolTable = SymbolTableMaker().makeFrom(program)
val symbolTable = SymbolTableMaker().makeFrom(program, compilerOptions)
// TODO make removing all VarDecls work, but this needs inferType to be able to get its information from somewhere else as the VarDecl nodes in the Ast,
// or don't use inferType at all anymore and "bake the type information" into the Ast somehow.
@ -399,7 +400,7 @@ private fun createAssemblyAndAssemble(program: Program,
// to help clean up the code that still depends on them.
// removeAllVardeclsFromAst(program)
// println("*********** AST RIGHT BEFORE ASM GENERATION *************")
// println("*********** COMPILER AST RIGHT BEFORE ASM GENERATION *************")
// printProgram(program)
val assembly = asmGeneratorFor(program, errors, symbolTable, compilerOptions).compileToAssembly()
@ -445,18 +446,15 @@ internal fun asmGeneratorFor(program: Program,
options: CompilationOptions): IAssemblyGenerator
{
if(options.experimentalCodegen) {
if (options.compTarget.machine.cpu in arrayOf(CpuType.CPU6502, CpuType.CPU65c02)) {
// TODO for now, use the new Intermediary Ast for this experimental codegen:
val intermediateAst = IntermediateAstMaker(program).transform()
return prog8.codegen.experimental.AsmGen(intermediateAst, symbolTable, options, errors)
}
val intermediateAst = IntermediateAstMaker(program).transform()
return prog8.codegen.experimental.CodeGen(intermediateAst, symbolTable, options, errors)
} else {
if (options.compTarget.machine.cpu in arrayOf(CpuType.CPU6502, CpuType.CPU65c02))
// TODO rewrite 6502 codegen on new Intermediary Ast
// TODO rewrite 6502 codegen on new Intermediary Ast or on new Intermediate Representation
return prog8.codegen.cpu6502.AsmGen(program, symbolTable, options, errors)
if (options.compTarget.name == VMTarget.NAME) {
val intermediateAst = IntermediateAstMaker(program).transform()
return prog8.codegen.virtual.CodeGen(intermediateAst, symbolTable, options, errors)
return VmCodeGen(intermediateAst, symbolTable, options, errors)
}
}

49
compiler/src/prog8/compiler/astprocessing/AsmInstructionNamesFinder.kt Normal file
View File

@ -0,0 +1,49 @@
package prog8.compiler.astprocessing
import prog8.ast.statements.Block
import prog8.ast.statements.Label
import prog8.ast.statements.Subroutine
import prog8.ast.statements.VarDecl
import prog8.ast.walk.IAstVisitor
import prog8.code.core.ICompilationTarget
import prog8.code.target.VMTarget
class AsmInstructionNamesFinder(val target: ICompilationTarget): IAstVisitor {
val blocks = mutableSetOf<Block>()
val variables = mutableSetOf<VarDecl>()
val labels = mutableSetOf<Label>()
val subroutines = mutableSetOf<Subroutine>()
private fun isPossibleInstructionName(name: String) = name.length==3 && name.all { it.isLetter() }
fun foundAny(): Boolean = blocks.isNotEmpty() || variables.isNotEmpty() || subroutines.isNotEmpty() || labels.isNotEmpty()
override fun visit(block: Block) {
if(target.name!=VMTarget.NAME && !block.isInLibrary && isPossibleInstructionName(block.name)) {
blocks += block
}
super.visit(block)
}
override fun visit(decl: VarDecl) {
if(target.name!=VMTarget.NAME && !decl.definingModule.isLibrary && isPossibleInstructionName(decl.name)) {
variables += decl
}
super.visit(decl)
}
override fun visit(label: Label) {
if(target.name!=VMTarget.NAME && !label.definingModule.isLibrary && isPossibleInstructionName(label.name)) {
labels += label
}
super.visit(label)
}
override fun visit(subroutine: Subroutine) {
if(target.name!=VMTarget.NAME && !subroutine.definingModule.isLibrary && isPossibleInstructionName(subroutine.name)) {
subroutines += subroutine
}
super.visit(subroutine)
}
}

101
compiler/src/prog8/compiler/astprocessing/AsmInstructionNamesReplacer.kt Normal file
View File

@ -0,0 +1,101 @@
package prog8.compiler.astprocessing
import prog8.ast.Node
import prog8.ast.expressions.IdentifierReference
import prog8.ast.statements.*
import prog8.ast.walk.AstWalker
import prog8.ast.walk.IAstModification
class AsmInstructionNamesReplacer(
val blocks: Set<Block>,
val subroutines: Set<Subroutine>,
val variables: Set<VarDecl>,
val labels: Set<Label>): AstWalker() {
override fun after(identifier: IdentifierReference, parent: Node): Iterable<IAstModification> {
val newName = identifier.nameInSource.map { ident ->
if(ident.length==3 && !identifier.definingModule.isLibrary) {
val blockTarget = blocks.firstOrNull { it.name==ident }
val subTarget = subroutines.firstOrNull {it.name==ident }
val varTarget = variables.firstOrNull { it.name==ident }
val labelTarget = labels.firstOrNull { it.name==ident}
if(blockTarget!=null || subTarget!=null || varTarget!=null || labelTarget!=null) {
"p8p_$ident"
} else
ident
} else
ident
}
return if(newName!=identifier.nameInSource)
listOf(IAstModification.ReplaceNode(identifier, IdentifierReference(newName, identifier.position), parent))
else
noModifications
}
override fun after(label: Label, parent: Node): Iterable<IAstModification> {
return if(label in labels)
listOf(IAstModification.ReplaceNode(label, Label("p8p_${label.name}", label.position), parent))
else
noModifications
}
override fun after(block: Block, parent: Node): Iterable<IAstModification> {
return if(block in blocks)
listOf(IAstModification.ReplaceNode(block, Block("p8p_${block.name}", block.address, block.statements, block.isInLibrary, block.position), parent))
else
noModifications
}
override fun after(decl: VarDecl, parent: Node): Iterable<IAstModification> {
return if(decl in variables)
listOf(IAstModification.ReplaceNode(decl, decl.renamed("p8p_${decl.name}"), parent))
else
noModifications
}
private val subsWithParamRefsToFix = mutableListOf<Subroutine>()
override fun applyModifications(): Int {
var count = super.applyModifications()
subsWithParamRefsToFix.forEach { subroutine ->
subroutine.statements.withIndex().reversed().forEach { (index,stmt) ->
if(stmt is VarDecl && stmt.origin==VarDeclOrigin.SUBROUTINEPARAM) {
val param = subroutine.parameters.single { it.name == stmt.name}
val decl = VarDecl.fromParameter(param)
subroutine.statements[index] = decl
decl.linkParents(subroutine)
count++
}
}
}
return count
}
override fun after(subroutine: Subroutine, parent: Node): Iterable<IAstModification> {
val changedParams = mutableListOf<Pair<Int, SubroutineParameter>>()
subroutine.parameters.withIndex().forEach { (index, param) ->
if(param.name.length==3 && param.name.all { it.isLetter() } && !param.definingModule.isLibrary) {
changedParams.add(index to SubroutineParameter("p8p_${param.name}", param.type, param.position))
}
}
changedParams.forEach { (index, newParam) -> subroutine.parameters[index] = newParam }
val newName = if(subroutine in subroutines) "p8p_${subroutine.name}" else subroutine.name
return if(newName!=subroutine.name || changedParams.isNotEmpty()) {
val newSub = Subroutine(newName, subroutine.parameters, subroutine.returntypes,
subroutine.asmParameterRegisters, subroutine.asmReturnvaluesRegisters, subroutine.asmClobbers, subroutine.asmAddress, subroutine.isAsmSubroutine,
subroutine.inline, subroutine.statements, subroutine.position)
if(changedParams.isNotEmpty())
subsWithParamRefsToFix += newSub
listOf(IAstModification.ReplaceNode(subroutine, newSub, parent))
} else {
if(changedParams.isNotEmpty())
subsWithParamRefsToFix += subroutine
noModifications
}
}
}

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