Apple-2-SW/prog8
1
0
Fork 0
mirror of https://github.com/irmen/prog8.git synced 2025-06-13 20:23:46 +00:00
Code Issues Projects Releases Wiki Activity

Compare commits

base: Apple-2-SW:v1.9
Branches Tags
Apple-2-SW:master Apple-2-SW:structs Apple-2-SW:long-consts Apple-2-SW:languageServer
Apple-2-SW:v11.3.2 Apple-2-SW:v11.3.1 Apple-2-SW:v11.3 Apple-2-SW:v11.2 Apple-2-SW:v11.1 Apple-2-SW:v11.0.1 Apple-2-SW:v11.0 Apple-2-SW:v10.5.1 Apple-2-SW:v10.5 Apple-2-SW:v10.4.2 Apple-2-SW:v10.4.1 Apple-2-SW:v10.4 Apple-2-SW:v10.3.1 Apple-2-SW:v10.3 Apple-2-SW:v10.2.1 Apple-2-SW:v10.2 Apple-2-SW:v10.1 Apple-2-SW:v10.0 Apple-2-SW:v9.7 Apple-2-SW:v9.6 Apple-2-SW:v9.5.1 Apple-2-SW:v9.5 Apple-2-SW:v9.4.2 Apple-2-SW:v9.4.1 Apple-2-SW:v9.4 Apple-2-SW:v9.3 Apple-2-SW:v9.2.1 Apple-2-SW:v9.2 Apple-2-SW:v9.1 Apple-2-SW:v9.0 Apple-2-SW:v8.14 Apple-2-SW:v8.13 Apple-2-SW:v8.12 Apple-2-SW:v8.11 Apple-2-SW:v8.10 Apple-2-SW:v8.9 Apple-2-SW:v8.8.1 Apple-2-SW:v8.8 Apple-2-SW:v8.7 Apple-2-SW:v8.6.2 Apple-2-SW:v8.6.1 Apple-2-SW:v8.5 Apple-2-SW:v8.4 Apple-2-SW:v8.3.1 Apple-2-SW:v8.3 Apple-2-SW:v8.2 Apple-2-SW:v8.1 Apple-2-SW:v8.0 Apple-2-SW:v7.9 Apple-2-SW:v7.8 Apple-2-SW:v7.7.1 Apple-2-SW:v7.7 Apple-2-SW:v7.6 Apple-2-SW:v7.5 Apple-2-SW:v7.4.1 Apple-2-SW:v7.4 Apple-2-SW:v7.3 Apple-2-SW:v7.2 Apple-2-SW:version7.2 Apple-2-SW:version7.1 Apple-2-SW:v7.1-beta Apple-2-SW:v7.0 Apple-2-SW:v7.0-beta2 Apple-2-SW:v7.0-beta Apple-2-SW:v6.5-beta Apple-2-SW:v6.4 Apple-2-SW:v6.3 Apple-2-SW:v6.2 Apple-2-SW:v6.1 Apple-2-SW:v6.0 Apple-2-SW:v6.0-beta Apple-2-SW:v5.4 Apple-2-SW:v5.3 Apple-2-SW:v5.2 Apple-2-SW:v5.1 Apple-2-SW:v5.0 Apple-2-SW:v4.6 Apple-2-SW:v4.5 Apple-2-SW:v4.4 Apple-2-SW:v4.3 Apple-2-SW:v4.2 Apple-2-SW:v4.1 Apple-2-SW:v4.0 Apple-2-SW:v3.2 Apple-2-SW:v3.1 Apple-2-SW:v3.0 Apple-2-SW:v2.4 Apple-2-SW:v2.3 Apple-2-SW:v2.2 Apple-2-SW:v2.1 Apple-2-SW:v2.0 Apple-2-SW:v1.91 Apple-2-SW:v1.90 Apple-2-SW:v1.81 Apple-2-SW:v1.80 Apple-2-SW:v1.70 Apple-2-SW:v1.62 Apple-2-SW:v1.61 Apple-2-SW:v1.60 Apple-2-SW:v1.52 Apple-2-SW:v1.51 Apple-2-SW:v1.50 Apple-2-SW:v1.20 Apple-2-SW:v1.11 Apple-2-SW:v1.10 Apple-2-SW:v1.9 Apple-2-SW:v1.8 Apple-2-SW:v1.7 Apple-2-SW:v1.6 Apple-2-SW:v1.5-beta Apple-2-SW:v1.4-beta Apple-2-SW:v1.3-beta Apple-2-SW:v1.2-beta Apple-2-SW:v1.1-beta Apple-2-SW:v1.0-beta
...
compare: Apple-2-SW:v1.80
Branches Tags
Apple-2-SW:structs Apple-2-SW:master Apple-2-SW:long-consts Apple-2-SW:languageServer
Apple-2-SW:v11.3.2 Apple-2-SW:v11.3.1 Apple-2-SW:v11.3 Apple-2-SW:v11.2 Apple-2-SW:v11.1 Apple-2-SW:v11.0.1 Apple-2-SW:v11.0 Apple-2-SW:v10.5.1 Apple-2-SW:v10.5 Apple-2-SW:v10.4.2 Apple-2-SW:v10.4.1 Apple-2-SW:v10.4 Apple-2-SW:v10.3.1 Apple-2-SW:v10.3 Apple-2-SW:v10.2.1 Apple-2-SW:v10.2 Apple-2-SW:v10.1 Apple-2-SW:v10.0 Apple-2-SW:v9.7 Apple-2-SW:v9.6 Apple-2-SW:v9.5.1 Apple-2-SW:v9.5 Apple-2-SW:v9.4.2 Apple-2-SW:v9.4.1 Apple-2-SW:v9.4 Apple-2-SW:v9.3 Apple-2-SW:v9.2.1 Apple-2-SW:v9.2 Apple-2-SW:v9.1 Apple-2-SW:v9.0 Apple-2-SW:v8.14 Apple-2-SW:v8.13 Apple-2-SW:v8.12 Apple-2-SW:v8.11 Apple-2-SW:v8.10 Apple-2-SW:v8.9 Apple-2-SW:v8.8.1 Apple-2-SW:v8.8 Apple-2-SW:v8.7 Apple-2-SW:v8.6.2 Apple-2-SW:v8.6.1 Apple-2-SW:v8.5 Apple-2-SW:v8.4 Apple-2-SW:v8.3.1 Apple-2-SW:v8.3 Apple-2-SW:v8.2 Apple-2-SW:v8.1 Apple-2-SW:v8.0 Apple-2-SW:v7.9 Apple-2-SW:v7.8 Apple-2-SW:v7.7.1 Apple-2-SW:v7.7 Apple-2-SW:v7.6 Apple-2-SW:v7.5 Apple-2-SW:v7.4.1 Apple-2-SW:v7.4 Apple-2-SW:v7.3 Apple-2-SW:v7.2 Apple-2-SW:version7.2 Apple-2-SW:version7.1 Apple-2-SW:v7.1-beta Apple-2-SW:v7.0 Apple-2-SW:v7.0-beta2 Apple-2-SW:v7.0-beta Apple-2-SW:v6.5-beta Apple-2-SW:v6.4 Apple-2-SW:v6.3 Apple-2-SW:v6.2 Apple-2-SW:v6.1 Apple-2-SW:v6.0 Apple-2-SW:v6.0-beta Apple-2-SW:v5.4 Apple-2-SW:v5.3 Apple-2-SW:v5.2 Apple-2-SW:v5.1 Apple-2-SW:v5.0 Apple-2-SW:v4.6 Apple-2-SW:v4.5 Apple-2-SW:v4.4 Apple-2-SW:v4.3 Apple-2-SW:v4.2 Apple-2-SW:v4.1 Apple-2-SW:v4.0 Apple-2-SW:v3.2 Apple-2-SW:v3.1 Apple-2-SW:v3.0 Apple-2-SW:v2.4 Apple-2-SW:v2.3 Apple-2-SW:v2.2 Apple-2-SW:v2.1 Apple-2-SW:v2.0 Apple-2-SW:v1.91 Apple-2-SW:v1.90 Apple-2-SW:v1.81 Apple-2-SW:v1.80 Apple-2-SW:v1.70 Apple-2-SW:v1.62 Apple-2-SW:v1.61 Apple-2-SW:v1.60 Apple-2-SW:v1.52 Apple-2-SW:v1.51 Apple-2-SW:v1.50 Apple-2-SW:v1.20 Apple-2-SW:v1.11 Apple-2-SW:v1.10 Apple-2-SW:v1.9 Apple-2-SW:v1.8 Apple-2-SW:v1.7 Apple-2-SW:v1.6 Apple-2-SW:v1.5-beta Apple-2-SW:v1.4-beta Apple-2-SW:v1.3-beta Apple-2-SW:v1.2-beta Apple-2-SW:v1.1-beta Apple-2-SW:v1.0-beta

224 Commits
v1.9 ... v1.80

Author SHA1 Message Date
Irmen de Jong
b036e5ed72 refreshed the compiled examples 2020-03-12 01:14:10 +01:00
Irmen de Jong
5f1ec80ae0 improved array literal datatype handling, fixed some datatype compiler errors related to this 2020-03-12 01:10:19 +01:00
Irmen de Jong
fbecedaf41 added error for unsupported sort(floatarray) 2020-03-11 23:33:06 +01:00
Irmen de Jong
aa36acd65a implemented reverse(floatarray) builtin function 2020-03-11 23:18:03 +01:00
Irmen de Jong
8d1a4588d3 added 'downto' range expression 2020-03-11 20:59:14 +01:00
Irmen de Jong
66d2af4453 added '@' alternative string/char encoding 2020-03-11 00:41:58 +01:00
Irmen de Jong
ef6c731bb3 added '@' alternative string/char encoding 2020-03-11 00:32:50 +01:00
Irmen de Jong
98a638a2f3 split asmsub and romsub declarations 2020-03-10 23:09:31 +01:00
Irmen de Jong
96d8a7f0d7 float assembly code moved to separate library file 2020-03-10 22:03:24 +01:00
Irmen de Jong
3162b10392 optimize callgraph 2020-03-10 21:47:15 +01:00
Irmen de Jong
e2358de27c ver 2020-03-10 20:39:30 +01:00
Irmen de Jong
7facb4f372 correct version 1.70 2020-02-09 01:41:05 +01:00
Irmen de Jong
ee90fed489 readme 2020-02-09 01:33:20 +01:00
Irmen de Jong
4796c56c35 antlr code back 2020-02-09 01:29:58 +01:00
Irmen de Jong
e2cb031386 added 'void' keyword to explicitly ignore subroutine return values (and no longer get a warning) 2020-02-09 01:29:09 +01:00
Irmen de Jong
a0bc97b90c fix byte array iteration for bb in [1,2,3] 
improved array literal datatype detection
 2020-02-09 00:45:53 +01:00
Irmen de Jong
fd240899bd fix CHROUT in simulator 2020-02-09 00:12:50 +01:00
Irmen de Jong
885b22df40 fixed while and repeat warning messages line number 
fixed invalid while and repeat asm label names
fixed boolean checking of numbers
 2020-02-08 19:45:30 +01:00
Irmen de Jong
11de3db25f simplified heapId for arrayvalues 2020-02-08 18:49:48 +01:00
Irmen de Jong
14a13da7ec simplified heapId for stringvalue 2020-02-08 15:54:03 +01:00
Irmen de Jong
875a71c786 removed datatype from StringValue classes (is always STR now) 2020-02-08 02:21:18 +01:00
Irmen de Jong
0ff5b79353 code inspection cleanups 2020-02-08 01:31:41 +01:00
Irmen de Jong
8c4d276810 improvements to string encoding/decoding and text output in the simulator 2020-02-08 01:12:30 +01:00
Irmen de Jong
3dd38c0ac8 antlr library updated to 4.8 2020-02-07 23:58:07 +01:00
Irmen de Jong
b8816a0e2f got rid of separate str_s datatype 2020-02-07 20:47:38 +01:00
Irmen de Jong
a01a9e76f9 removed bogus clang target 
fixed various simulator bugs regarding strings and chars
 2020-02-07 01:22:07 +01:00
Irmen de Jong
357d704aec clean up version specifier 2020-02-02 19:33:40 +01:00
Irmen de Jong
868df1865c got rid of obsolete code 2020-02-02 19:18:40 +01:00
Irmen de Jong
654d74da1e automatic selection of best Vice C64 emulator executable 2020-02-02 13:39:56 +01:00
Irmen de Jong
59939c727a gradle updated 2020-02-02 13:39:25 +01:00
Irmen de Jong
fbcf190324 sync gradle version with my manjaro packaged gradle 2020-01-27 21:32:42 +01:00
Irmen de Jong
b9922a90cc update gradle wrapper to 6.1.1 2020-01-26 18:36:51 +01:00
Irmen de Jong
66e0b07428 gradle updates 2020-01-07 01:29:25 +01:00
Irmen de Jong
01e617ae8f new kotlin version 2019-12-09 16:17:20 +01:00
Irmen de Jong
52769decd4 fix assembler float truncation warning 2019-11-27 22:36:59 +01:00
Irmen de Jong
165eec4054 started a c++ language compiler code target 
(meant to be an intermediate step before direct Wasm/binaryen, via clang compilation to wasm)
 2019-10-30 00:15:03 +01:00
Irmen de Jong
8c2e602cc7 preparing for multiple compiler backends/targets 2019-10-26 23:41:15 +02:00
Irmen de Jong
b68f141568 some more old code cleanups 2019-10-21 00:12:26 +02:00
Irmen de Jong
b5d1e8653d tiny cleanups 2019-10-20 23:52:26 +02:00
Irmen de Jong
f6d4c90dea improved number-to-decimal routines 2019-09-23 20:44:41 +02:00
Irmen de Jong
b5b24636ae removed sim65 because it was moved to a separate repository 2019-09-11 02:24:44 +02:00
Irmen de Jong
9dedbbf47c use more modern java date/time api 2019-09-10 01:29:33 +02:00
Irmen de Jong
c493c3e5c6 implemented IRQ handling 2019-09-09 23:28:41 +02:00
Irmen de Jong
61d4ca1d24 added functional test files to git 2019-09-09 19:57:51 +02:00
Irmen de Jong
2cf9af4a6e implemented sim timer and clock 2019-09-09 04:51:18 +02:00
Irmen de Jong
bdcd10512f 6502 simulator passes all tests for regular opcodes 2019-09-09 00:27:06 +02:00
Irmen de Jong
fec8db6a75 fixed sbc and adc 2019-09-08 22:35:08 +02:00
Irmen de Jong
b400010426 separated the 6502 test suite into separate unit tests 2019-09-08 19:11:06 +02:00
Irmen de Jong
28109a39ac clean up of c64 tests 2019-09-08 17:19:40 +02:00
Irmen de Jong
651f0ec445 fixed IZY addressing mode address calc 
added test harness for Wolfgang Lorenz's 6502 test suite
 2019-09-08 16:40:46 +02:00
Irmen de Jong
e61d3df380 added missing testfiles 2019-09-06 01:09:23 +02:00
Irmen de Jong
15710207b2 fixed bcd (but the bcd test code still fails, strange) 2019-09-06 00:38:48 +02:00
Irmen de Jong
adfddddac6 attempt to fix bcd 2019-09-05 21:38:40 +02:00
Irmen de Jong
e46982f652 fixes 2019-09-05 01:41:48 +02:00
Irmen de Jong
900c2aea23 fixed all instructions except BCD arithmetic 2019-09-05 01:26:01 +02:00
Irmen de Jong
42f8e98cab cpu unit test suite ported from Py65 2019-09-04 22:23:31 +02:00
Irmen de Jong
bed0e33b4f unit test 2019-09-04 02:41:09 +02:00
Irmen de Jong
8d6542905d beginnings of 6502 cpu simulator 2019-09-03 23:58:46 +02:00
Irmen de Jong
39798a1a4f todos 2019-08-29 22:31:29 +02:00
Irmen de Jong
befe4b8e9f try to fix windows path issue with drive letter 2019-08-27 01:02:31 +02:00
Irmen de Jong
772e48105e fixed some type cast compiler errors in for loops 2019-08-26 23:38:59 +02:00
Irmen de Jong
9afe451b8d fix build script to target jdk 1.8 2019-08-26 21:27:45 +02:00
Irmen de Jong
89d469e77e examples 2019-08-25 00:46:46 +02:00
Irmen de Jong
59a43889a5 examples 2019-08-25 00:24:00 +02:00
Irmen de Jong
7caa0daffc examples 2019-08-24 21:40:50 +02:00
Irmen de Jong
5e854c2cf8 more forloop asm 2019-08-24 21:26:29 +02:00
Irmen de Jong
9edc92ec29 more bitshift asm stubs (actual functions still to be done) 2019-08-23 23:06:36 +02:00
Irmen de Jong
1d178080a3 more bitshift asm 2019-08-23 21:33:43 +02:00
Irmen de Jong
aa94300bdd added output directory command line option 
improved cli parser by using kotlinx.cli
 2019-08-23 00:11:08 +02:00
Irmen de Jong
2d768c3f28 code cleanups 2019-08-22 22:06:21 +02:00
Irmen de Jong
b79af624ae added more asmgen for bitshift operations 2019-08-22 00:34:17 +02:00
Irmen de Jong
38208a7c9e removed fake vm functions 2019-08-21 22:00:05 +02:00
Irmen de Jong
8eff51904e taking down the heapvalue mess further 2019-08-21 00:29:31 +02:00
Irmen de Jong
c717f4573d taking down the heapvalue mess further 2019-08-20 23:02:13 +02:00
Irmen de Jong
984d251a6d taking down the heapvalue mess, RuntimeValue class separation 2019-08-20 00:01:31 +02:00
Irmen de Jong
8c3b43f3ed taking down the heapvalue mess 2019-08-19 22:28:41 +02:00
Irmen de Jong
0f1485f30b added sorted, sgn, reverse to the AstVm 2019-08-18 16:39:08 +02:00
Irmen de Jong
eb94c678bd doc 2019-08-18 14:18:46 +02:00
Irmen de Jong
50d792a121 fix doc about for loops 2019-08-18 14:14:14 +02:00
Irmen de Jong
f0d4654917 v1.60 2019-08-18 14:06:30 +02:00
Irmen de Jong
4ce93b5d9d restored proper compiler error when trying to modify a constant 2019-08-18 14:05:20 +02:00
Irmen de Jong
fb0d7a1908 some array literals weren't put on the heap 2019-08-18 13:46:13 +02:00
Irmen de Jong
bb7b063757 revert inline var declaration in for loops 2019-08-18 03:16:23 +02:00
Irmen de Jong
c495f54bbb don't fall-through into nested subroutine 2019-08-18 02:33:42 +02:00
Irmen de Jong
1cc1f2d91d reverse() added (byte+word) 2019-08-18 02:05:51 +02:00
Irmen de Jong
d837cc11f9 sort() added (bytes+words) 2019-08-18 00:04:03 +02:00
Irmen de Jong
cbb7083307 fix problem with typechecking of const arrays 2019-08-17 21:43:48 +02:00
Irmen de Jong
d4a17dfad1 fixed builtin functions no longer const-folding over arrays 2019-08-17 20:16:39 +02:00
Irmen de Jong
59f8b91e25 tweak 2019-08-17 18:44:44 +02:00
Irmen de Jong
80113f9208 version 1.52 2019-08-17 16:44:46 +02:00
Irmen de Jong
27f987f0ae fixed bit shifts, added sgn() function 2019-08-17 16:44:28 +02:00
Irmen de Jong
3ae2597261 irq driven music player example 2019-08-17 13:13:15 +02:00
Irmen de Jong
248e7b808c split codegen 2019-08-16 22:49:29 +02:00
Irmen de Jong
a983a896f2 some asm and some for loop asm fixed, renamed asmgen2 back to just asmgen 2019-08-16 21:37:27 +02:00
Irmen de Jong
68df1730f5 cleaned up some stuff, improved checking of asmsub statement body 2019-08-14 23:17:50 +02:00
Irmen de Jong
d62ab93b24 word >> 8 optimized to msb(word) 2019-08-14 22:28:44 +02:00
Irmen de Jong
47297f7e31 improved handling of inferredType 2019-08-14 02:25:27 +02:00
Irmen de Jong
b64d611e02 split array and string literal classes 2019-08-13 03:00:17 +02:00
Irmen de Jong
9fb9bcfebd correction 2019-08-12 23:25:19 +02:00
Irmen de Jong
dff9c5f53e tweak travis 2019-08-11 22:58:45 +02:00
Irmen de Jong
d4a77321d2 tweak gradle to work with openjdk-11 2019-08-11 22:56:54 +02:00
Irmen de Jong
2665618fa6 zp test added, some cleanups 2019-08-11 22:23:18 +02:00
Irmen de Jong
b5c5560af8 info 2019-08-11 18:21:15 +02:00
Irmen de Jong
065587525e version 2019-08-11 17:43:14 +02:00
Irmen de Jong
58e5d5c071 hash 2019-08-11 17:32:28 +02:00
Irmen de Jong
b44e76db57 fix any/all assembly routine, added asm for min/max/sum/ etc aggregates 
removed avg function because of hidden internal overflow issues
 2019-08-11 16:13:09 +02:00
Irmen de Jong
2ce6bc5946 fix strlen 2019-08-11 14:02:53 +02:00
Irmen de Jong
fe5b225732 asmsub stack arg 2019-08-11 12:29:18 +02:00
Irmen de Jong
d499e40a4b doc tweaks 2019-08-11 10:56:36 +02:00
Irmen de Jong
62a66d89c6 was not needed 2019-08-11 10:15:34 +02:00
Irmen de Jong
e1b26ae287 readme 2019-08-10 21:38:08 +02:00
Irmen de Jong
1c151f4a3f remove dysfunctional repl 2019-08-10 21:36:26 +02:00
Irmen de Jong
8917926996 new version 2019-08-10 20:45:41 +02:00
Irmen de Jong
b54a9b9831 fix output of word arrays containing addressofs 2019-08-10 20:43:27 +02:00
Irmen de Jong
f08906dba1 fix byte->word typecast 2019-08-10 14:20:42 +02:00
Irmen de Jong
a6bba824d3 fixed some array codegen issues 2019-08-10 12:55:27 +02:00
Irmen de Jong
fd84152a2b import cleanups 2019-08-09 02:21:04 +02:00
Irmen de Jong
3466106119 fixed some array codegen issues 2019-08-09 02:15:31 +02:00
Irmen de Jong
c79b587eea nonconst forloops (bytes) 2019-08-08 23:13:02 +02:00
Irmen de Jong
4862fb7db1 asmsub return value in registers is now put on evalstack, and loopvar sequence numbering 2019-08-08 00:13:58 +02:00
Irmen de Jong
2136db0e61 fix auto var naming collisions 2019-08-07 22:25:57 +02:00
Irmen de Jong
2f0c0f6fcd fix function arguments 2019-08-07 02:31:27 +02:00
Irmen de Jong
7ddc01f883 added continuous compilation mode (file watching) 2019-08-05 23:36:24 +02:00
Irmen de Jong
126c2162f1 syntax fix in readme 2019-08-05 21:11:58 +02:00
Irmen de Jong
094c8ab94c Merge branch 'asmgen2-ast-only' 2019-08-05 21:07:32 +02:00
Irmen de Jong
efe2723874 version 2019-08-05 21:06:41 +02:00
Irmen de Jong
bccfeb2fa2 fix some unittests 2019-08-05 21:04:15 +02:00
Irmen de Jong
d498d5445c added more examples/test programs 2019-08-05 21:01:41 +02:00
Irmen de Jong
5095d090cc added optimized multiplications to asmgen2 2019-08-05 21:00:55 +02:00
Irmen de Jong
6544fcdc36 fixed output of force_output blocks 2019-08-04 23:08:58 +02:00
Irmen de Jong
e834924857 more ++ and -- code, 'dontuse' zeropage option 2019-08-04 22:44:20 +02:00
Irmen de Jong
2c3b8a9819 more ++ and -- code, 'dontuse' zeropage option 2019-08-04 22:35:27 +02:00
Irmen de Jong
309c82fc9e fixed some compiler errors 2019-08-04 19:54:32 +02:00
Irmen de Jong
0f91ce6441 removed a few more hazardous zp addresses 2019-08-04 19:40:31 +02:00
Irmen de Jong
f29ec3b4e1 relaxed symbol shadowing 2019-08-04 18:52:03 +02:00
Irmen de Jong
cc1fc869cf fix param type casts for builtin functions 2019-08-04 18:25:00 +02:00
Irmen de Jong
0431d3cddc implemented asm for continue and break 2019-08-04 16:05:50 +02:00
Irmen de Jong
a1cd202cd2 some more array asm 2019-08-04 15:33:00 +02:00
Irmen de Jong
b842493cf0 trying to fix arithmetic and funcion calls and var scoping issues 2019-08-03 13:21:38 +02:00
Irmen de Jong
4718f09cb7 trying to fix arithmetic and funcion calls 2019-08-03 01:51:12 +02:00
Irmen de Jong
e9c357a885 fix range typing issues and function call param cleanup bug for asmsub 2019-08-02 01:26:28 +02:00
Irmen de Jong
fb00ff74d1 simplistic repeat and while loops 2019-08-01 21:23:55 +02:00
Irmen de Jong
b740b079db simplified mapping of builtin functions to just a jsr 2019-08-01 21:03:21 +02:00
Irmen de Jong
6394841041 fix byte/word add/sub mixup 2019-08-01 20:42:09 +02:00
Irmen de Jong
3f4050c647 more for loops, words 2019-08-01 00:35:25 +02:00
Irmen de Jong
82f01d84c2 more for loops 2019-07-31 22:15:20 +02:00
Irmen de Jong
299ea72d70 various for loops 2019-07-31 21:47:30 +02:00
Irmen de Jong
50aa286d3a begin of for asm 2019-07-31 00:54:04 +02:00
Irmen de Jong
6f7322150f fix string literal replacing by identifierref 2019-07-31 00:14:12 +02:00
Irmen de Jong
cc9965cc96 improved deduction of array datatypes 2019-07-30 23:35:25 +02:00
Irmen de Jong
ae90a957c6 fix var prefix issues in asm gen of anonscopes 2019-07-30 21:13:52 +02:00
Irmen de Jong
8cec032e7d more asm for byte writes to memory 2019-07-30 02:49:13 +02:00
Irmen de Jong
3732ab1e62 fix compilation errors 2019-07-30 02:26:30 +02:00
Irmen de Jong
fba149ee28 removed the ~ before block names 2019-07-29 23:11:13 +02:00
Irmen de Jong
4661cba974 asm for when statements added 2019-07-29 22:47:04 +02:00
Irmen de Jong
025be8cb7c fix infinte loop in constantfolding of when choices 2019-07-29 22:06:59 +02:00
Irmen de Jong
3aea32551b fixes 2019-07-29 02:47:01 +02:00
Irmen de Jong
8e8c112ff0 improved subroutine param ast checks, added asm for Carry parameter 2019-07-29 00:33:19 +02:00
Irmen de Jong
b0dda08e74 assembler reserved symbols checked 2019-07-28 23:37:33 +02:00
Irmen de Jong
2c25df122a merge strings in asm output 2019-07-28 21:29:49 +02:00
Irmen de Jong
7cb5702b37 array asm 2019-07-28 21:03:09 +02:00
Irmen de Jong
b7502c7eaa fixed some node update issues in Modifying Ast visitor 2019-07-28 15:18:53 +02:00
Irmen de Jong
fed020825a some more asmgen v2; fixed duplicate label namings, if stmt, and vars in anon scopes 2019-07-28 13:12:13 +02:00
Irmen de Jong
1c411897df some more asmgen v2, and seemingly useless assignments to memory variables are no longer optimized away 2019-07-27 03:11:15 +02:00
Irmen de Jong
f94e241fb2 fix array datatypes in vardecls 2019-07-26 23:51:53 +02:00
Irmen de Jong
757cbfd1ba readme 2019-07-24 00:45:04 +02:00
Irmen de Jong
3de80319db readme 2019-07-24 00:43:37 +02:00
Irmen de Jong
f9617d777a floats from rom 2019-07-24 00:39:01 +02:00
Irmen de Jong
9961a404ae got rid of bytecode based compiler and vm 2019-07-23 20:44:11 +02:00
Irmen de Jong
776c844d02 more ast-codegen v2 2019-07-23 01:36:49 +02:00
Irmen de Jong
03782a37a2 begin of ast-codegen v2 2019-07-21 23:50:13 +02:00
Irmen de Jong
173663380b slight optimization for creating the asmpatterns list 2019-07-20 22:37:16 +02:00
Irmen de Jong
c6fdd65c63 shuffling some things around 2019-07-18 22:23:31 +02:00
Irmen de Jong
d9546f9dc7 version 2019-07-18 01:38:35 +02:00
Irmen de Jong
2a6b0f5db7 remove some more dead code 2019-07-18 01:31:12 +02:00
Irmen de Jong
b4e1b42cec remove some dead code 2019-07-17 22:35:38 +02:00
Irmen de Jong
a8898a5993 using sealed class instead of interface 2019-07-17 02:35:26 +02:00
Irmen de Jong
e03c68b632 optimize imports 2019-07-17 02:11:16 +02:00
Irmen de Jong
a0074de12b updated the compiled examples 2019-07-17 00:39:03 +02:00
Irmen de Jong
411bedcc46 fixed assignment type error with structs 
added structs example
 2019-07-16 23:56:00 +02:00
Irmen de Jong
07d8caf884 string literal concatenation and repeating added again 2019-07-16 23:34:43 +02:00
Irmen de Jong
c0e83ef8df wordings 2019-07-16 21:31:14 +02:00
Irmen de Jong
4dbf4b2005 tweaks about initialization values 2019-07-16 20:32:23 +02:00
Irmen de Jong
61af72b906 struct literals 2019-07-16 02:36:32 +02:00
Irmen de Jong
17be722e2b arrays without init value are once again cleared with zeros 2019-07-15 23:05:04 +02:00
Irmen de Jong
16d7927d2f fix arrays and some struct parsing issues 2019-07-15 22:28:05 +02:00
Irmen de Jong
55a7a5d9d5 fix aggregate functions in astvm 2019-07-15 03:57:51 +02:00
Irmen de Jong
78d7849197 fixes 2019-07-15 03:08:26 +02:00
Irmen de Jong
d5b12fb01d made astchecker readonly 2019-07-15 01:47:59 +02:00
Irmen de Jong
31f4e378aa split up Literalvalue into numeric and reference ones 2019-07-15 01:11:32 +02:00
Irmen de Jong
8a26b7b248 - fixed lookup of members in structs defined in another scope 
- preserve order of variable definitions in the Ast (and thus, the output)
 2019-07-13 23:03:22 +02:00
Irmen de Jong
87c28cfdbc restructure c64 machinedefinition 2019-07-13 03:16:48 +02:00
Irmen de Jong
1f5420010d prevent struct member vars from shuffling around, can take address of struct now 2019-07-13 01:16:34 +02:00
Irmen de Jong
a089c48378 finalize v 1.11 2019-07-12 20:31:18 +02:00
Irmen de Jong
3e5deda46c struct finished 2019-07-12 20:07:41 +02:00
Irmen de Jong
7500c6efd0 struct fixes 2019-07-12 17:57:56 +02:00
Irmen de Jong
717b5f3b07 struct fixes 2019-07-12 16:40:18 +02:00
Irmen de Jong
9f6fa60bf1 prepare 2019-07-12 14:38:37 +02:00
Irmen de Jong
1e9586f635 Structs can be compiled and executed in the vm! structs are just syntactic sugar for a set of variables for now. 2019-07-12 12:41:08 +02:00
Irmen de Jong
44f9d5e69e added struct syntax 2019-07-12 06:14:59 +02:00
Irmen de Jong
7c9b8f7d43 cleaned up some buildprocess scripts 2019-07-11 17:27:57 +02:00
Irmen de Jong
845a99d623 return statement only has one single possible value 
astvm can now more or less run all examples
 2019-07-10 19:27:44 +02:00
Irmen de Jong
3d7a4bf81a astvm can now more or less run all examples 2019-07-10 18:44:54 +02:00
Irmen de Jong
d4b3e35bd2 astvm almost complete 2019-07-10 16:50:41 +02:00
Irmen de Jong
a59f7c75dc fixed some compile time and vm arithmetic errors 2019-07-10 13:33:52 +02:00
Irmen de Jong
44fe2369d6 multitarget assignments removed 2019-07-10 10:11:37 +02:00
Irmen de Jong
aaaab2cfcf fix asm gen for loops when dealing with registers as loopvar 2019-07-10 08:51:05 +02:00
Irmen de Jong
9a3dab20dc extra warnings about register usage in loops 2019-07-10 08:30:17 +02:00
Irmen de Jong
20379b5927 fixed astvm postincrdecr and rsave/rrestore 2019-07-10 08:13:42 +02:00
Irmen de Jong
34dcce67e4 fixed petscii conversion when printing text 2019-07-10 07:10:34 +02:00
Irmen de Jong
0c7f107d01 fix irq routine removal 2019-07-10 03:57:03 +02:00
Irmen de Jong
1f89571aa5 proper NOP removal 2019-07-10 03:06:31 +02:00
Irmen de Jong
7eed1ebbf8 optimized typecasting more 2019-07-10 02:54:39 +02:00
Irmen de Jong
12cb7d7abe optimize redundant typecasts more 2019-07-10 01:52:04 +02:00
Irmen de Jong
c9b16dcbd9 nicer printing of arrays, fix inc/dec overflow issue in runtimevalue 2019-07-10 01:16:32 +02:00
Irmen de Jong
dcab6d00bb ver 2019-07-10 00:50:18 +02:00
Irmen de Jong
a85743f241 docs about 'when' statement 2019-07-10 00:45:53 +02:00
Irmen de Jong
14cabde5cf when statement extended with multiple choice values 2019-07-10 00:25:21 +02:00
Irmen de Jong
cc078503e3 tehtriz example uses when statement 2019-07-09 23:39:03 +02:00
Irmen de Jong
2a0c3377f9 fixed Nop statements without parent 2019-07-09 23:27:09 +02:00
Irmen de Jong
16454f5560 optimized when asm 2019-07-09 21:59:50 +02:00
Irmen de Jong
c1343a78f1 when working correctly in asm (corrected dup & cmp) 2019-07-09 21:41:47 +02:00
Irmen de Jong
9d0c65c682 when working correctly in stackvm and astvm 2019-07-09 20:39:08 +02:00
Irmen de Jong
9e6408244f fix scoping of variables in when statement 2019-07-09 19:44:59 +02:00
188 changed files with 17442 additions and 19626 deletions
Expand all files Collapse all files

14
.gitignore vendored
View File

@ -1,7 +1,8 @@
.idea/workspace.xml
/build/
/dist/
/output/
.idea/discord.xml
build/
dist/
output/
.*cache/
*.directory
*.prg
@ -11,8 +12,8 @@
*.vice-mon-list
docs/build
out/
**/*.interp
**/*.tokens
parser/**/*.interp
parser/**/*.tokens
*.py[cod]
*.egg
@ -24,10 +25,7 @@ __pycache__/
parser.out
parsetab.py
.pytest_cache/
compiler/src/prog8_kotlin.jar
compiler/src/compiled_java
.attach_pid*
.gradle
build/
/prog8compiler.jar

2
.idea/.gitignore generated vendored Normal file
View File

@ -0,0 +1,2 @@
# Default ignored files
/shelf/

10
.idea/inspectionProfiles/Project_Default.xml generated
View File

@ -1,6 +1,16 @@
<component name="InspectionProjectProfileManager">
<profile version="1.0">
<option name="myName" value="Project Default" />
<inspection_tool class="DuplicatedCode" enabled="true" level="WEAK WARNING" enabled_by_default="true">
<Languages>
<language minSize="100" isEnabled="false" name="JavaScript" />
<language isEnabled="false" name="Groovy" />
<language isEnabled="false" name="Style Sheets" />
<language minSize="70" name="Kotlin" />
<language isEnabled="false" name="TypeScript" />
<language isEnabled="false" name="ActionScript" />
</Languages>
</inspection_tool>
<inspection_tool class="SpellCheckingInspection" enabled="true" level="TYPO" enabled_by_default="true">
<option name="processCode" value="false" />
<option name="processLiterals" value="true" />

9
.idea/libraries/antlr_4_8_complete.xml generated Normal file
View File

@ -0,0 +1,9 @@
<component name="libraryTable">
<library name="antlr-4.8-complete">
<CLASSES>
<root url="jar://$PROJECT_DIR$/parser/antlr/lib/antlr-4.8-complete.jar!/" />
</CLASSES>
<JAVADOC />
<SOURCES />
</library>
</component>

9
.idea/libraries/antlr_runtime_4_8.xml generated Normal file
View File

@ -0,0 +1,9 @@
<component name="libraryTable">
<library name="antlr-runtime-4.8">
<CLASSES>
<root url="jar://$PROJECT_DIR$/parser/antlr/lib/antlr-runtime-4.8.jar!/" />
</CLASSES>
<JAVADOC />
<SOURCES />
</library>
</component>

9
.idea/libraries/kotlinx_cli_jvm_0_1_0_dev_5.xml generated Normal file
View File

@ -0,0 +1,9 @@
<component name="libraryTable">
<library name="kotlinx-cli-jvm-0.1.0-dev-5">
<CLASSES>
<root url="jar://$PROJECT_DIR$/compiler/lib/kotlinx-cli-jvm-0.1.0-dev-5.jar!/" />
</CLASSES>
<JAVADOC />
<SOURCES />
</library>
</component>

29
.idea/markdown-navigator-enh.xml generated Normal file
View File

@ -0,0 +1,29 @@
<?xml version="1.0" encoding="UTF-8"?>
<project version="4">
<component name="MarkdownEnhProjectSettings">
<AnnotatorSettings targetHasSpaces="true" linkCaseMismatch="true" wikiCaseMismatch="true" wikiLinkHasDashes="true" notUnderWikiHome="true" targetNotWikiPageExt="true" notUnderSourceWikiHome="true" targetNameHasAnchor="true" targetPathHasAnchor="true" wikiLinkHasSlash="true" wikiLinkHasSubdir="true" wikiLinkHasOnlyAnchor="true" linkTargetsWikiHasExt="true" linkTargetsWikiHasBadExt="true" notUnderSameRepo="true" targetNotUnderVcs="false" linkNeedsExt="true" linkHasBadExt="true" linkTargetNeedsExt="true" linkTargetHasBadExt="true" wikiLinkNotInWiki="true" imageTargetNotInRaw="true" repoRelativeAcrossVcsRoots="true" multipleWikiTargetsMatch="true" unresolvedLinkReference="true" linkIsIgnored="true" anchorIsIgnored="true" anchorIsUnresolved="true" anchorLineReferenceIsUnresolved="true" anchorLineReferenceFormat="true" anchorHasDuplicates="true" abbreviationDuplicates="true" abbreviationNotUsed="true" attributeIdDuplicateDefinition="true" attributeIdNotUsed="true" footnoteDuplicateDefinition="true" footnoteUnresolved="true" footnoteDuplicates="true" footnoteNotUsed="true" macroDuplicateDefinition="true" macroUnresolved="true" macroDuplicates="true" macroNotUsed="true" referenceDuplicateDefinition="true" referenceUnresolved="true" referenceDuplicates="true" referenceNotUsed="true" referenceUnresolvedNumericId="true" enumRefDuplicateDefinition="true" enumRefUnresolved="true" enumRefDuplicates="true" enumRefNotUsed="true" enumRefLinkUnresolved="true" enumRefLinkDuplicates="true" simTocUpdateNeeded="true" simTocTitleSpaceNeeded="true" />
<HtmlExportSettings updateOnSave="false" parentDir="" targetDir="" cssDir="css" scriptDir="js" plainHtml="false" imageDir="" copyLinkedImages="false" imagePathType="0" targetPathType="2" targetExt="" useTargetExt="false" noCssNoScripts="false" useElementStyleAttribute="false" linkToExportedHtml="true" exportOnSettingsChange="true" regenerateOnProjectOpen="false" linkFormatType="HTTP_ABSOLUTE" />
<LinkMapSettings>
<textMaps />
</LinkMapSettings>
</component>
<component name="MarkdownNavigatorHistory">
<PasteImageHistory checkeredTransparentBackground="false" filename="image" directory="" onPasteImageTargetRef="3" onPasteLinkText="0" onPasteImageElement="1" onPasteLinkElement="1" onPasteReferenceElement="2" cornerRadius="20" borderColor="0" transparentColor="16777215" borderWidth="1" trimTop="0" trimBottom="0" trimLeft="0" trimRight="0" transparent="false" roundCorners="false" showPreview="true" bordered="false" scaled="false" cropped="false" hideInapplicableOperations="false" preserveLinkFormat="false" scale="50" scalingInterpolation="1" transparentTolerance="0" saveAsDefaultOnOK="false" linkFormat="0" addHighlights="false" showHighlightCoordinates="true" showHighlights="false" mouseSelectionAddsHighlight="false" outerFilled="false" outerFillColor="0" outerFillTransparent="true" outerFillAlpha="30">
<highlightList />
<directories />
<filenames />
</PasteImageHistory>
<CopyImageHistory checkeredTransparentBackground="false" filename="image" directory="" onPasteImageTargetRef="3" onPasteLinkText="0" onPasteImageElement="1" onPasteLinkElement="1" onPasteReferenceElement="2" cornerRadius="20" borderColor="0" transparentColor="16777215" borderWidth="1" trimTop="0" trimBottom="0" trimLeft="0" trimRight="0" transparent="false" roundCorners="false" showPreview="true" bordered="false" scaled="false" cropped="false" hideInapplicableOperations="false" preserveLinkFormat="false" scale="50" scalingInterpolation="1" transparentTolerance="0" saveAsDefaultOnOK="false" linkFormat="0" addHighlights="false" showHighlightCoordinates="true" showHighlights="false" mouseSelectionAddsHighlight="false" outerFilled="false" outerFillColor="0" outerFillTransparent="true" outerFillAlpha="30">
<highlightList />
<directories />
<filenames />
</CopyImageHistory>
<PasteLinkHistory onPasteImageTargetRef="3" onPasteTargetRef="1" onPasteLinkText="0" onPasteImageElement="1" onPasteLinkElement="1" onPasteWikiElement="2" onPasteReferenceElement="2" hideInapplicableOperations="false" preserveLinkFormat="false" useHeadingForLinkText="false" linkFormat="0" saveAsDefaultOnOK="false" />
<TableToJsonHistory>
<entries />
</TableToJsonHistory>
<TableSortHistory>
<entries />
</TableSortHistory>
</component>
</project>

57
.idea/markdown-navigator.xml generated Normal file
View File

@ -0,0 +1,57 @@
<?xml version="1.0" encoding="UTF-8"?>
<project version="4">
<component name="FlexmarkProjectSettings">
<FlexmarkHtmlSettings flexmarkSpecExampleRendering="0" flexmarkSpecExampleRenderHtml="false">
<flexmarkSectionLanguages>
<option name="1" value="Markdown" />
<option name="2" value="HTML" />
<option name="3" value="flexmark-ast:1" />
</flexmarkSectionLanguages>
</FlexmarkHtmlSettings>
</component>
<component name="MarkdownProjectSettings">
<PreviewSettings splitEditorLayout="SPLIT" splitEditorPreview="PREVIEW" useGrayscaleRendering="false" zoomFactor="1.0" maxImageWidth="0" synchronizePreviewPosition="true" highlightPreviewType="LINE" highlightFadeOut="5" highlightOnTyping="true" synchronizeSourcePosition="true" verticallyAlignSourceAndPreviewSyncPosition="true" showSearchHighlightsInPreview="true" showSelectionInPreview="true" lastLayoutSetsDefault="false">
<PanelProvider>
<provider providerId="com.vladsch.md.nav.editor.javafx.html.panel" providerName="JavaFX WebView" />
</PanelProvider>
</PreviewSettings>
<ParserSettings gitHubSyntaxChange="false" correctedInvalidSettings="false" emojiShortcuts="1" emojiImages="0">
<PegdownExtensions>
<option name="ANCHORLINKS" value="true" />
<option name="ATXHEADERSPACE" value="true" />
<option name="FENCED_CODE_BLOCKS" value="true" />
<option name="INTELLIJ_DUMMY_IDENTIFIER" value="true" />
<option name="RELAXEDHRULES" value="true" />
<option name="STRIKETHROUGH" value="true" />
<option name="TABLES" value="true" />
<option name="TASKLISTITEMS" value="true" />
</PegdownExtensions>
<ParserOptions>
<option name="COMMONMARK_LISTS" value="true" />
<option name="EMOJI_SHORTCUTS" value="true" />
<option name="GFM_TABLE_RENDERING" value="true" />
<option name="PRODUCTION_SPEC_PARSER" value="true" />
<option name="SIM_TOC_BLANK_LINE_SPACER" value="true" />
</ParserOptions>
</ParserSettings>
<HtmlSettings headerTopEnabled="false" headerBottomEnabled="false" bodyTopEnabled="false" bodyBottomEnabled="false" addPageHeader="false" imageUriSerials="false" addDocTypeHtml="true" noParaTags="false" plantUmlConversion="0">
<GeneratorProvider>
<provider providerId="com.vladsch.md.nav.editor.javafx.html.generator" providerName="JavaFx HTML Generator" />
</GeneratorProvider>
<headerTop />
<headerBottom />
<bodyTop />
<bodyBottom />
</HtmlSettings>
<CssSettings previewScheme="UI_SCHEME" cssUri="" isCssUriEnabled="false" isCssUriSerial="true" isCssTextEnabled="false" isDynamicPageWidth="true">
<StylesheetProvider>
<provider providerId="com.vladsch.md.nav.editor.javafx.html.css" providerName="Default JavaFx Stylesheet" />
</StylesheetProvider>
<ScriptProviders>
<provider providerId="com.vladsch.md.nav.editor.hljs.html.script" providerName="HighlightJS Script" />
</ScriptProviders>
<cssText />
<cssUriHistory />
</CssSettings>
</component>
</project>

16
.idea/misc.xml generated
View File

@ -1,5 +1,21 @@
<?xml version="1.0" encoding="UTF-8"?>
<project version="4">
<component name="ANTLRGenerationPreferences">
<option name="perGrammarGenerationSettings">
<list>
<PerGrammarGenerationSettings>
<option name="fileName" value="$PROJECT_DIR$/parser/antlr/prog8.g4" />
<option name="autoGen" value="true" />
<option name="outputDir" value="$PROJECT_DIR$/parser/src/prog8/parser" />
<option name="libDir" value="" />
<option name="encoding" value="" />
<option name="pkg" value="" />
<option name="language" value="" />
<option name="generateListener" value="false" />
</PerGrammarGenerationSettings>
</list>
</option>
</component>
<component name="ProjectRootManager" version="2" languageLevel="JDK_1_8" default="false" project-jdk-name="Kotlin SDK" project-jdk-type="KotlinSDK">
<output url="file://$PROJECT_DIR$/out" />
</component>

2
.idea/vcs.xml generated
View File

@ -3,4 +3,4 @@
<component name="VcsDirectoryMappings">
<mapping directory="$PROJECT_DIR$" vcs="Git" />
</component>
</project>
</project>

4
.travis.yml
View File

@ -1,11 +1,11 @@
language: java
sudo: false
# jdk: openjdk8
# dist: xenial
# sudo: false
before_install:
- chmod +x gradlew
script:
- ./gradlew test
- gradle test

38
README.md
View File

@ -14,35 +14,39 @@ as used in many home computers from that era. It is a medium to low level progra
which aims to provide many conveniences over raw assembly code (even when using a macro assembler):
- reduction of source code length
- easier program understanding (because it's higher level, and way more compact)
- modularity, symbol scoping, subroutines
- subroutines have enforced input- and output parameter definitions
- various data types other than just bytes (16-bit words, floats, strings, 16-bit register pairs)
- automatic variable allocations, automatic string variables and string sharing
- constant folding in expressions (compile-time evaluation)
- various data types other than just bytes (16-bit words, floats, strings)
- automatic variable allocations, automatic string and array variables and string sharing
- subroutines with a input- and output parameter signature
- constant folding in expressions
- conditional branches
- automatic type conversions
- floating point operations (uses the C64 Basic ROM routines for this)
- 'when' statement to provide a concise jump table alternative to if/elseif chains
- structs to group together sets of variables and manipulate them at once
- floating point operations (requires the C64 Basic ROM routines for this)
- abstracting away low level aspects such as ZeroPage handling, program startup, explicit memory addresses
- various code optimizations (code structure, logical and numerical expressions, unused code removal...)
- various code optimizations (code structure, logical and numerical expressions, unused code removal...)
- inline assembly allows you to have full control when every cycle or byte matters
- many built-in functions such as ``sin``, ``cos``, ``rnd``, ``abs``, ``min``, ``max``, ``sqrt``, ``msb``, ``rol``, ``ror``, ``swap``, ``memset``, ``memcopy``, ``sort`` and ``reverse``
Rapid edit-compile-run-debug cycle:
- use modern PC to work on
- quick compilation times (less than 1 second)
- option to automatically run the program in the Vice emulator
- use modern PC to work on
- quick compilation times (seconds)
- option to automatically run the program in the Vice emulator
- breakpoints, that let the Vice emulator drop into the monitor if execution hits them
- source code labels automatically loaded in Vice emulator so it can show them in disassembly
- virtual machine that can execute compiled code directy on the host system,
without having to actually convert it to assembly to run on a real 6502
It is mainly targeted at the Commodore-64 machine at this time.
Contributions to add support for other 8-bit (or other?!) machines are welcome.
Documentation is online at https://prog8.readthedocs.io/
Documentation/manual
--------------------
This describes the language, but also how to build and run the compiler. See https://prog8.readthedocs.io/
Required tools:
---------------
Required tools
--------------
[64tass](https://sourceforge.net/projects/tass64/) - cross assembler. Install this on your shell path.
A recent .exe version of this tool for Windows can be obtained from my [clone](https://github.com/irmen/64tass/releases) of this project.
@ -64,7 +68,7 @@ This code calculates prime numbers using the Sieve of Eratosthenes algorithm::
%import c64utils
%zeropage basicsafe
~ main {
main {
ubyte[256] sieve
ubyte candidate_prime = 2

5
clean.sh
View File

@ -1,5 +0,0 @@
#!/usr/bin/env sh
rm *.jar *.asm *.prg *.vm.txt *.vice-mon-list
rm -r build

51
compiler/build.gradle
View File

@ -1,54 +1,61 @@
buildscript {
dependencies {
classpath "org.jetbrains.kotlin:kotlin-gradle-plugin:$kotlinVersion"
classpath "org.jetbrains.kotlin:kotlin-gradle-plugin:1.3.70"
}
}
plugins {
// id "org.jetbrains.kotlin.jvm" version $kotlinVersion
// id "org.jetbrains.kotlin.jvm" version "1.3.70"
id 'application'
id 'org.jetbrains.dokka' version "0.9.18"
id 'com.github.johnrengelman.shadow' version '5.1.0'
id 'com.github.johnrengelman.shadow' version '5.2.0'
id 'java'
}
apply plugin: "kotlin"
apply plugin: "java"
targetCompatibility = 1.8
sourceCompatibility = 1.8
repositories {
mavenLocal()
mavenCentral()
jcenter()
maven { url "https://dl.bintray.com/orangy/maven/" }
}
sourceCompatibility = 1.8
def prog8version = rootProject.file('compiler/res/version.txt').text.trim()
dependencies {
implementation project(':parser')
implementation "org.jetbrains.kotlin:kotlin-stdlib-jdk8:$kotlinVersion"
// implementation "org.jetbrains.kotlin:kotlin-reflect:$kotlinVersion"
// runtime "org.jetbrains.kotlin:kotlin-reflect:$kotlinVersion"
runtime 'org.antlr:antlr4-runtime:4.7.2'
runtime project(':parser')
implementation "org.jetbrains.kotlin:kotlin-stdlib-jdk8"
// implementation "org.jetbrains.kotlin:kotlin-reflect"
implementation 'org.antlr:antlr4-runtime:4.8'
implementation 'org.jetbrains.kotlinx:kotlinx-cli-jvm:0.1.0-dev-5'
// implementation 'net.razorvine:ksim65:1.6'
implementation project(':parser')
testImplementation "org.jetbrains.kotlin:kotlin-test-junit5:$kotlinVersion"
testImplementation "org.jetbrains.kotlin:kotlin-test-junit5"
testImplementation 'org.junit.jupiter:junit-jupiter-api:5.3.2'
testImplementation 'org.hamcrest:hamcrest-junit:2.0.0.0'
testRuntimeOnly 'org.junit.jupiter:junit-jupiter-engine:5.3.2'
}
compileKotlin {
kotlinOptions {
jvmTarget = "1.8"
verbose = true
// verbose = true
// freeCompilerArgs += "-XXLanguage:+NewInference"
}
}
compileTestKotlin {
kotlinOptions {
jvmTarget = "1.8"
}
}
sourceSets {
main {
java {
@ -76,24 +83,10 @@ artifacts {
archives shadowJar
}
task p8vmScript(type: CreateStartScripts) {
mainClassName = "prog8.vm.stackvm.MainKt"
applicationName = "p8vm"
outputDir = new File(project.buildDir, 'scripts')
classpath = jar.outputs.files + project.configurations.runtime
}
applicationDistribution.into("bin") {
from(p8vmScript)
fileMode = 0755
}
// To create a fat-jar use the 'create_compiler_jar' script for now
// @todo investigate https://imperceptiblethoughts.com/shadow/introduction/
shadowJar {
baseName = 'prog8compiler'
version = prog8version
archiveBaseName = 'prog8compiler'
archiveVersion = prog8version
// minimize()
}

5
compiler/compiler.iml
View File

@ -8,11 +8,12 @@
<sourceFolder url="file://$MODULE_DIR$/test" isTestSource="true" />
<excludeFolder url="file://$MODULE_DIR$/build" />
</content>
<orderEntry type="jdk" jdkName="1.8" jdkType="JavaSDK" />
<orderEntry type="jdk" jdkName="openjdk-11" jdkType="JavaSDK" />
<orderEntry type="sourceFolder" forTests="false" />
<orderEntry type="library" name="KotlinJavaRuntime" level="project" />
<orderEntry type="library" name="antlr-runtime-4.7.2" level="project" />
<orderEntry type="module" module-name="parser" />
<orderEntry type="library" name="unittest-libs" level="project" />
<orderEntry type="library" name="kotlinx-cli-jvm-0.1.0-dev-5" level="project" />
<orderEntry type="library" name="antlr-runtime-4.8" level="project" />
</component>
</module>

BIN
compiler/lib/kotlinx-cli-jvm-0.1.0-dev-5.jar Normal file
View File

Binary file not shown.

741
compiler/res/prog8lib/c64floats.asm Normal file
View File

@ -0,0 +1,741 @@
; --- low level floating point assembly routines for the C64
ub2float .proc
; -- convert ubyte in SCRATCH_ZPB1 to float at address A/Y
; clobbers A, Y
stx c64.SCRATCH_ZPREGX
sta c64.SCRATCH_ZPWORD2
sty c64.SCRATCH_ZPWORD2+1
ldy c64.SCRATCH_ZPB1
jsr FREADUY
_fac_to_mem ldx c64.SCRATCH_ZPWORD2
ldy c64.SCRATCH_ZPWORD2+1
jsr MOVMF
ldx c64.SCRATCH_ZPREGX
rts
.pend
b2float .proc
; -- convert byte in SCRATCH_ZPB1 to float at address A/Y
; clobbers A, Y
stx c64.SCRATCH_ZPREGX
sta c64.SCRATCH_ZPWORD2
sty c64.SCRATCH_ZPWORD2+1
lda c64.SCRATCH_ZPB1
jsr FREADSA
jmp ub2float._fac_to_mem
.pend
uw2float .proc
; -- convert uword in SCRATCH_ZPWORD1 to float at address A/Y
stx c64.SCRATCH_ZPREGX
sta c64.SCRATCH_ZPWORD2
sty c64.SCRATCH_ZPWORD2+1
lda c64.SCRATCH_ZPWORD1
ldy c64.SCRATCH_ZPWORD1+1
jsr GIVUAYFAY
jmp ub2float._fac_to_mem
.pend
w2float .proc
; -- convert word in SCRATCH_ZPWORD1 to float at address A/Y
stx c64.SCRATCH_ZPREGX
sta c64.SCRATCH_ZPWORD2
sty c64.SCRATCH_ZPWORD2+1
ldy c64.SCRATCH_ZPWORD1
lda c64.SCRATCH_ZPWORD1+1
jsr GIVAYF
jmp ub2float._fac_to_mem
.pend
stack_b2float .proc
; -- b2float operating on the stack
inx
lda c64.ESTACK_LO,x
stx c64.SCRATCH_ZPREGX
jsr FREADSA
jmp push_fac1_as_result
.pend
stack_w2float .proc
; -- w2float operating on the stack
inx
ldy c64.ESTACK_LO,x
lda c64.ESTACK_HI,x
stx c64.SCRATCH_ZPREGX
jsr GIVAYF
jmp push_fac1_as_result
.pend
stack_ub2float .proc
; -- ub2float operating on the stack
inx
lda c64.ESTACK_LO,x
stx c64.SCRATCH_ZPREGX
tay
jsr FREADUY
jmp push_fac1_as_result
.pend
stack_uw2float .proc
; -- uw2float operating on the stack
inx
lda c64.ESTACK_LO,x
ldy c64.ESTACK_HI,x
stx c64.SCRATCH_ZPREGX
jsr GIVUAYFAY
jmp push_fac1_as_result
.pend
stack_float2w .proc ; also used for float2b
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
jsr AYINT
ldx c64.SCRATCH_ZPREGX
lda $64
sta c64.ESTACK_HI,x
lda $65
sta c64.ESTACK_LO,x
dex
rts
.pend
stack_float2uw .proc ; also used for float2ub
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
jsr GETADR
ldx c64.SCRATCH_ZPREGX
sta c64.ESTACK_HI,x
tya
sta c64.ESTACK_LO,x
dex
rts
.pend
push_float .proc
; ---- push mflpt5 in A/Y onto stack
; (taking 3 stack positions = 6 bytes of which 1 is padding)
sta c64.SCRATCH_ZPWORD1
sty c64.SCRATCH_ZPWORD1+1
ldy #0
lda (c64.SCRATCH_ZPWORD1),y
sta c64.ESTACK_LO,x
iny
lda (c64.SCRATCH_ZPWORD1),y
sta c64.ESTACK_HI,x
dex
iny
lda (c64.SCRATCH_ZPWORD1),y
sta c64.ESTACK_LO,x
iny
lda (c64.SCRATCH_ZPWORD1),y
sta c64.ESTACK_HI,x
dex
iny
lda (c64.SCRATCH_ZPWORD1),y
sta c64.ESTACK_LO,x
dex
rts
.pend
func_rndf .proc
; -- put a random floating point value on the stack
stx c64.SCRATCH_ZPREG
lda #1
jsr FREADSA
jsr RND ; rng into fac1
ldx #<_rndf_rnum5
ldy #>_rndf_rnum5
jsr MOVMF ; fac1 to mem X/Y
ldx c64.SCRATCH_ZPREG
lda #<_rndf_rnum5
ldy #>_rndf_rnum5
jmp push_float
_rndf_rnum5 .byte 0,0,0,0,0
.pend
push_float_from_indexed_var .proc
; -- push the float from the array at A/Y with index on stack, onto the stack.
sta c64.SCRATCH_ZPWORD1
sty c64.SCRATCH_ZPWORD1+1
jsr prog8_lib.pop_index_times_5
jsr prog8_lib.add_a_to_zpword
lda c64.SCRATCH_ZPWORD1
ldy c64.SCRATCH_ZPWORD1+1
jmp push_float
.pend
pop_float .proc
; ---- pops mflpt5 from stack to memory A/Y
; (frees 3 stack positions = 6 bytes of which 1 is padding)
sta c64.SCRATCH_ZPWORD1
sty c64.SCRATCH_ZPWORD1+1
ldy #4
inx
lda c64.ESTACK_LO,x
sta (c64.SCRATCH_ZPWORD1),y
dey
inx
lda c64.ESTACK_HI,x
sta (c64.SCRATCH_ZPWORD1),y
dey
lda c64.ESTACK_LO,x
sta (c64.SCRATCH_ZPWORD1),y
dey
inx
lda c64.ESTACK_HI,x
sta (c64.SCRATCH_ZPWORD1),y
dey
lda c64.ESTACK_LO,x
sta (c64.SCRATCH_ZPWORD1),y
rts
.pend
pop_float_fac1 .proc
; -- pops float from stack into FAC1
lda #<fmath_float1
ldy #>fmath_float1
jsr pop_float
lda #<fmath_float1
ldy #>fmath_float1
jmp MOVFM
.pend
pop_float_to_indexed_var .proc
; -- pop the float on the stack, to the memory in the array at A/Y indexed by the byte on stack
sta c64.SCRATCH_ZPWORD1
sty c64.SCRATCH_ZPWORD1+1
jsr prog8_lib.pop_index_times_5
jsr prog8_lib.add_a_to_zpword
lda c64.SCRATCH_ZPWORD1
ldy c64.SCRATCH_ZPWORD1+1
jmp pop_float
.pend
copy_float .proc
; -- copies the 5 bytes of the mflt value pointed to by SCRATCH_ZPWORD1,
; into the 5 bytes pointed to by A/Y. Clobbers A,Y.
sta c64.SCRATCH_ZPWORD2
sty c64.SCRATCH_ZPWORD2+1
ldy #0
lda (c64.SCRATCH_ZPWORD1),y
sta (c64.SCRATCH_ZPWORD2),y
iny
lda (c64.SCRATCH_ZPWORD1),y
sta (c64.SCRATCH_ZPWORD2),y
iny
lda (c64.SCRATCH_ZPWORD1),y
sta (c64.SCRATCH_ZPWORD2),y
iny
lda (c64.SCRATCH_ZPWORD1),y
sta (c64.SCRATCH_ZPWORD2),y
iny
lda (c64.SCRATCH_ZPWORD1),y
sta (c64.SCRATCH_ZPWORD2),y
rts
.pend
inc_var_f .proc
; -- add 1 to float pointed to by A/Y
sta c64.SCRATCH_ZPWORD1
sty c64.SCRATCH_ZPWORD1+1
stx c64.SCRATCH_ZPREGX
jsr MOVFM
lda #<FL_FONE
ldy #>FL_FONE
jsr FADD
ldx c64.SCRATCH_ZPWORD1
ldy c64.SCRATCH_ZPWORD1+1
jsr MOVMF
ldx c64.SCRATCH_ZPREGX
rts
.pend
dec_var_f .proc
; -- subtract 1 from float pointed to by A/Y
sta c64.SCRATCH_ZPWORD1
sty c64.SCRATCH_ZPWORD1+1
stx c64.SCRATCH_ZPREGX
lda #<FL_FONE
ldy #>FL_FONE
jsr MOVFM
lda c64.SCRATCH_ZPWORD1
ldy c64.SCRATCH_ZPWORD1+1
jsr FSUB
ldx c64.SCRATCH_ZPWORD1
ldy c64.SCRATCH_ZPWORD1+1
jsr MOVMF
ldx c64.SCRATCH_ZPREGX
rts
.pend
inc_indexed_var_f .proc
; -- add 1 to float in array pointed to by A/Y, at index X
pha
txa
sta c64.SCRATCH_ZPB1
asl a
asl a
clc
adc c64.SCRATCH_ZPB1
sta c64.SCRATCH_ZPB1
pla
clc
adc c64.SCRATCH_ZPB1
bcc +
iny
+ jmp inc_var_f
.pend
dec_indexed_var_f .proc
; -- subtract 1 to float in array pointed to by A/Y, at index X
pha
txa
sta c64.SCRATCH_ZPB1
asl a
asl a
clc
adc c64.SCRATCH_ZPB1
sta c64.SCRATCH_ZPB1
pla
clc
adc c64.SCRATCH_ZPB1
bcc +
iny
+ jmp dec_var_f
.pend
pop_2_floats_f2_in_fac1 .proc
; -- pop 2 floats from stack, load the second one in FAC1 as well
lda #<fmath_float2
ldy #>fmath_float2
jsr pop_float
lda #<fmath_float1
ldy #>fmath_float1
jsr pop_float
lda #<fmath_float2
ldy #>fmath_float2
jmp MOVFM
.pend
fmath_float1 .byte 0,0,0,0,0 ; storage for a mflpt5 value
fmath_float2 .byte 0,0,0,0,0 ; storage for a mflpt5 value
push_fac1_as_result .proc
; -- push the float in FAC1 onto the stack, and return from calculation
ldx #<fmath_float1
ldy #>fmath_float1
jsr MOVMF
lda #<fmath_float1
ldy #>fmath_float1
ldx c64.SCRATCH_ZPREGX
jmp push_float
.pend
pow_f .proc
; -- push f1 ** f2 on stack
lda #<fmath_float2
ldy #>fmath_float2
jsr pop_float
lda #<fmath_float1
ldy #>fmath_float1
jsr pop_float
stx c64.SCRATCH_ZPREGX
lda #<fmath_float1
ldy #>fmath_float1
jsr CONUPK ; fac2 = float1
lda #<fmath_float2
ldy #>fmath_float2
jsr FPWR
ldx c64.SCRATCH_ZPREGX
jmp push_fac1_as_result
.pend
div_f .proc
; -- push f1/f2 on stack
jsr pop_2_floats_f2_in_fac1
stx c64.SCRATCH_ZPREGX
lda #<fmath_float1
ldy #>fmath_float1
jsr FDIV
jmp push_fac1_as_result
.pend
add_f .proc
; -- push f1+f2 on stack
jsr pop_2_floats_f2_in_fac1
stx c64.SCRATCH_ZPREGX
lda #<fmath_float1
ldy #>fmath_float1
jsr FADD
jmp push_fac1_as_result
.pend
sub_f .proc
; -- push f1-f2 on stack
jsr pop_2_floats_f2_in_fac1
stx c64.SCRATCH_ZPREGX
lda #<fmath_float1
ldy #>fmath_float1
jsr FSUB
jmp push_fac1_as_result
.pend
mul_f .proc
; -- push f1*f2 on stack
jsr pop_2_floats_f2_in_fac1
stx c64.SCRATCH_ZPREGX
lda #<fmath_float1
ldy #>fmath_float1
jsr FMULT
jmp push_fac1_as_result
.pend
neg_f .proc
; -- push -flt back on stack
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
jsr NEGOP
jmp push_fac1_as_result
.pend
abs_f .proc
; -- push abs(float) on stack (as float)
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
jsr ABS
jmp push_fac1_as_result
.pend
equal_f .proc
; -- are the two mflpt5 numbers on the stack identical?
inx
inx
inx
inx
lda c64.ESTACK_LO-3,x
cmp c64.ESTACK_LO,x
bne _equals_false
lda c64.ESTACK_LO-2,x
cmp c64.ESTACK_LO+1,x
bne _equals_false
lda c64.ESTACK_LO-1,x
cmp c64.ESTACK_LO+2,x
bne _equals_false
lda c64.ESTACK_HI-2,x
cmp c64.ESTACK_HI+1,x
bne _equals_false
lda c64.ESTACK_HI-1,x
cmp c64.ESTACK_HI+2,x
bne _equals_false
_equals_true lda #1
_equals_store inx
sta c64.ESTACK_LO+1,x
rts
_equals_false lda #0
beq _equals_store
.pend
notequal_f .proc
; -- are the two mflpt5 numbers on the stack different?
jsr equal_f
eor #1 ; invert the result
sta c64.ESTACK_LO+1,x
rts
.pend
less_f .proc
; -- is f1 < f2?
jsr compare_floats
cmp #255
beq compare_floats._return_true
bne compare_floats._return_false
.pend
lesseq_f .proc
; -- is f1 <= f2?
jsr compare_floats
cmp #255
beq compare_floats._return_true
cmp #0
beq compare_floats._return_true
bne compare_floats._return_false
.pend
greater_f .proc
; -- is f1 > f2?
jsr compare_floats
cmp #1
beq compare_floats._return_true
bne compare_floats._return_false
.pend
greatereq_f .proc
; -- is f1 >= f2?
jsr compare_floats
cmp #1
beq compare_floats._return_true
cmp #0
beq compare_floats._return_true
bne compare_floats._return_false
.pend
compare_floats .proc
lda #<fmath_float2
ldy #>fmath_float2
jsr pop_float
lda #<fmath_float1
ldy #>fmath_float1
jsr pop_float
lda #<fmath_float1
ldy #>fmath_float1
jsr MOVFM ; fac1 = flt1
lda #<fmath_float2
ldy #>fmath_float2
stx c64.SCRATCH_ZPREG
jsr FCOMP ; A = flt1 compared with flt2 (0=equal, 1=flt1>flt2, 255=flt1<flt2)
ldx c64.SCRATCH_ZPREG
rts
_return_false lda #0
_return_result sta c64.ESTACK_LO,x
dex
rts
_return_true lda #1
bne _return_result
.pend
func_sin .proc
; -- push sin(f) back onto stack
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
jsr SIN
jmp push_fac1_as_result
.pend
func_cos .proc
; -- push cos(f) back onto stack
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
jsr COS
jmp push_fac1_as_result
.pend
func_tan .proc
; -- push tan(f) back onto stack
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
jsr TAN
jmp push_fac1_as_result
.pend
func_atan .proc
; -- push atan(f) back onto stack
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
jsr ATN
jmp push_fac1_as_result
.pend
func_ln .proc
; -- push ln(f) back onto stack
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
jsr LOG
jmp push_fac1_as_result
.pend
func_log2 .proc
; -- push log base 2, ln(f)/ln(2), back onto stack
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
jsr LOG
jsr MOVEF
lda #<c64.FL_LOG2
ldy #>c64.FL_LOG2
jsr MOVFM
jsr FDIVT
jmp push_fac1_as_result
.pend
func_sqrt .proc
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
jsr SQR
jmp push_fac1_as_result
.pend
func_rad .proc
; -- convert degrees to radians (d * pi / 180)
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
lda #<_pi_div_180
ldy #>_pi_div_180
jsr FMULT
jmp push_fac1_as_result
_pi_div_180 .byte 123, 14, 250, 53, 18 ; pi / 180
.pend
func_deg .proc
; -- convert radians to degrees (d * (1/ pi * 180))
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
lda #<_one_over_pi_div_180
ldy #>_one_over_pi_div_180
jsr FMULT
jmp push_fac1_as_result
_one_over_pi_div_180 .byte 134, 101, 46, 224, 211 ; 1 / (pi * 180)
.pend
func_round .proc
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
jsr FADDH
jsr INT
jmp push_fac1_as_result
.pend
func_floor .proc
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
jsr INT
jmp push_fac1_as_result
.pend
func_ceil .proc
; -- ceil: tr = int(f); if tr==f -> return else return tr+1
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
ldx #<fmath_float1
ldy #>fmath_float1
jsr MOVMF
jsr INT
lda #<fmath_float1
ldy #>fmath_float1
jsr FCOMP
cmp #0
beq +
lda #<FL_FONE
ldy #>FL_FONE
jsr FADD
+ jmp push_fac1_as_result
.pend
func_any_f .proc
inx
lda c64.ESTACK_LO,x ; array size
sta c64.SCRATCH_ZPB1
asl a
asl a
clc
adc c64.SCRATCH_ZPB1 ; times 5 because of float
jmp prog8_lib.func_any_b._entry
.pend
func_all_f .proc
inx
jsr prog8_lib.peek_address
lda c64.ESTACK_LO,x ; array size
sta c64.SCRATCH_ZPB1
asl a
asl a
clc
adc c64.SCRATCH_ZPB1 ; times 5 because of float
tay
dey
- lda (c64.SCRATCH_ZPWORD1),y
clc
dey
adc (c64.SCRATCH_ZPWORD1),y
dey
adc (c64.SCRATCH_ZPWORD1),y
dey
adc (c64.SCRATCH_ZPWORD1),y
dey
adc (c64.SCRATCH_ZPWORD1),y
dey
cmp #0
beq +
cpy #255
bne -
lda #1
sta c64.ESTACK_LO+1,x
rts
+ sta c64.ESTACK_LO+1,x
rts
.pend
func_max_f .proc
lda #255
sta _minmax_cmp+1
lda #<_largest_neg_float
ldy #>_largest_neg_float
_minmax_entry jsr MOVFM
jsr prog8_lib.pop_array_and_lengthmin1Y
stx c64.SCRATCH_ZPREGX
- sty c64.SCRATCH_ZPREG
lda c64.SCRATCH_ZPWORD1
ldy c64.SCRATCH_ZPWORD1+1
jsr FCOMP
_minmax_cmp cmp #255 ; modified
bne +
lda c64.SCRATCH_ZPWORD1
ldy c64.SCRATCH_ZPWORD1+1
jsr MOVFM
+ lda c64.SCRATCH_ZPWORD1
clc
adc #5
sta c64.SCRATCH_ZPWORD1
bcc +
inc c64.SCRATCH_ZPWORD1+1
+ ldy c64.SCRATCH_ZPREG
dey
cpy #255
bne -
jmp push_fac1_as_result
_largest_neg_float .byte 255,255,255,255,255 ; largest negative float -1.7014118345e+38
.pend
func_min_f .proc
lda #1
sta func_max_f._minmax_cmp+1
lda #<_largest_pos_float
ldy #>_largest_pos_float
jmp func_max_f._minmax_entry
_largest_pos_float .byte 255,127,255,255,255 ; largest positive float
rts
.pend
func_sum_f .proc
lda #<FL_ZERO
ldy #>FL_ZERO
jsr MOVFM
jsr prog8_lib.pop_array_and_lengthmin1Y
stx c64.SCRATCH_ZPREGX
- sty c64.SCRATCH_ZPREG
lda c64.SCRATCH_ZPWORD1
ldy c64.SCRATCH_ZPWORD1+1
jsr FADD
ldy c64.SCRATCH_ZPREG
dey
cpy #255
beq +
lda c64.SCRATCH_ZPWORD1
clc
adc #5
sta c64.SCRATCH_ZPWORD1
bcc -
inc c64.SCRATCH_ZPWORD1+1
bne -
+ jmp push_fac1_as_result
.pend
sign_f .proc
jsr pop_float_fac1
jsr SIGN
sta c64.ESTACK_LO,x
dex
rts
.pend

839
compiler/res/prog8lib/c64flt.p8
View File

@ -7,7 +7,7 @@
%option enable_floats
~ c64flt {
c64flt {
; ---- this block contains C-64 floating point related functions ----
const float PI = 3.141592653589793
@ -41,25 +41,25 @@
; note: for subtraction and division, the left operand is in fac2, the right operand in fac1.
; checked functions below:
asmsub MOVFM (uword mflpt @ AY) clobbers(A,Y) = $bba2 ; load mflpt value from memory in A/Y into fac1
asmsub FREADMEM () clobbers(A,Y) = $bba6 ; load mflpt value from memory in $22/$23 into fac1
asmsub CONUPK (uword mflpt @ AY) clobbers(A,Y) = $ba8c ; load mflpt value from memory in A/Y into fac2
asmsub FAREADMEM () clobbers(A,Y) = $ba90 ; load mflpt value from memory in $22/$23 into fac2
asmsub MOVFA () clobbers(A,X) = $bbfc ; copy fac2 to fac1
asmsub MOVAF () clobbers(A,X) = $bc0c ; copy fac1 to fac2 (rounded)
asmsub MOVEF () clobbers(A,X) = $bc0f ; copy fac1 to fac2
asmsub MOVMF (uword mflpt @ XY) clobbers(A,Y) = $bbd4 ; store fac1 to memory X/Y as 5-byte mflpt
romsub $bba2 = MOVFM(uword mflpt @ AY) clobbers(A,Y) ; load mflpt value from memory in A/Y into fac1
romsub $bba6 = FREADMEM() clobbers(A,Y) ; load mflpt value from memory in $22/$23 into fac1
romsub $ba8c = CONUPK(uword mflpt @ AY) clobbers(A,Y) ; load mflpt value from memory in A/Y into fac2
romsub $ba90 = FAREADMEM() clobbers(A,Y) ; load mflpt value from memory in $22/$23 into fac2
romsub $bbfc = MOVFA() clobbers(A,X) ; copy fac2 to fac1
romsub $bc0c = MOVAF() clobbers(A,X) ; copy fac1 to fac2 (rounded)
romsub $bc0f = MOVEF() clobbers(A,X) ; copy fac1 to fac2
romsub $bbd4 = MOVMF(uword mflpt @ XY) clobbers(A,Y) ; store fac1 to memory X/Y as 5-byte mflpt
; fac1-> signed word in Y/A (might throw ILLEGAL QUANTITY)
; (tip: use c64flt.FTOSWRDAY to get A/Y output; lo/hi switched to normal little endian order)
asmsub FTOSWORDYA () clobbers(X) -> ubyte @ Y, ubyte @ A = $b1aa
romsub $b1aa = FTOSWORDYA() clobbers(X) -> ubyte @ Y, ubyte @ A ; note: calls AYINT.
; fac1 -> unsigned word in Y/A (might throw ILLEGAL QUANTITY) (result also in $14/15)
; (tip: use c64flt.GETADRAY to get A/Y output; lo/hi switched to normal little endian order)
asmsub GETADR () clobbers(X) -> ubyte @ Y, ubyte @ A = $b7f7
romsub $b7f7 = GETADR() clobbers(X) -> ubyte @ Y, ubyte @ A
asmsub QINT () clobbers(A,X,Y) = $bc9b ; fac1 -> 4-byte signed integer in 98-101 ($62-$65), with the MSB FIRST.
asmsub AYINT () clobbers(A,X,Y) = $b1bf ; fac1-> signed word in 100-101 ($64-$65) MSB FIRST. (might throw ILLEGAL QUANTITY)
romsub $bc9b = QINT() clobbers(A,X,Y) ; fac1 -> 4-byte signed integer in 98-101 ($62-$65), with the MSB FIRST.
romsub $b1bf = AYINT() clobbers(A,X,Y) ; fac1-> signed word in 100-101 ($64-$65) MSB FIRST. (might throw ILLEGAL QUANTITY)
; GIVAYF: signed word in Y/A (note different lsb/msb order) -> float in fac1
; (tip: use c64flt.GIVAYFAY to use A/Y input; lo/hi switched to normal order)
@ -67,50 +67,49 @@ asmsub AYINT () clobbers(A,X,Y) = $b1bf ; fac1-> signed word in 100-101 ($64
; there is also c64flt.FREADS32 that reads from 98-101 ($62-$65) MSB FIRST
; there is also c64flt.FREADUS32 that reads from 98-101 ($62-$65) MSB FIRST
; there is also c64flt.FREADS24AXY that reads signed int24 into fac1 from A/X/Y (lo/mid/hi bytes)
asmsub GIVAYF (ubyte lo @ Y, ubyte hi @ A) clobbers(A,X,Y) = $b391
romsub $b391 = GIVAYF(ubyte lo @ Y, ubyte hi @ A) clobbers(A,X,Y)
asmsub FREADUY (ubyte value @ Y) clobbers(A,X,Y) = $b3a2 ; 8 bit unsigned Y -> float in fac1
asmsub FREADSA (byte value @ A) clobbers(A,X,Y) = $bc3c ; 8 bit signed A -> float in fac1
asmsub FREADSTR (ubyte length @ A) clobbers(A,X,Y) = $b7b5 ; str -> fac1, $22/23 must point to string, A=string length
asmsub FPRINTLN () clobbers(A,X,Y) = $aabc ; print string of fac1, on one line (= with newline) destroys fac1. (consider FOUT + STROUT as well)
asmsub FOUT () clobbers(X) -> uword @ AY = $bddd ; fac1 -> string, address returned in AY ($0100)
romsub $b3a2 = FREADUY(ubyte value @ Y) clobbers(A,X,Y) ; 8 bit unsigned Y -> float in fac1
romsub $bc3c = FREADSA(byte value @ A) clobbers(A,X,Y) ; 8 bit signed A -> float in fac1
romsub $b7b5 = FREADSTR(ubyte length @ A) clobbers(A,X,Y) ; str -> fac1, $22/23 must point to string, A=string length
romsub $aabc = FPRINTLN() clobbers(A,X,Y) ; print string of fac1, on one line (= with newline) destroys fac1. (consider FOUT + STROUT as well)
romsub $bddd = FOUT() clobbers(X) -> uword @ AY ; fac1 -> string, address returned in AY ($0100)
asmsub FADDH () clobbers(A,X,Y) = $b849 ; fac1 += 0.5, for rounding- call this before INT
asmsub MUL10 () clobbers(A,X,Y) = $bae2 ; fac1 *= 10
asmsub DIV10 () clobbers(A,X,Y) = $bafe ; fac1 /= 10 , CAUTION: result is always positive!
asmsub FCOMP (uword mflpt @ AY) clobbers(X,Y) -> ubyte @ A = $bc5b ; A = compare fac1 to mflpt in A/Y, 0=equal 1=fac1 is greater, 255=fac1 is less than
romsub $b849 = FADDH() clobbers(A,X,Y) ; fac1 += 0.5, for rounding- call this before INT
romsub $bae2 = MUL10() clobbers(A,X,Y) ; fac1 *= 10
romsub $bafe = DIV10() clobbers(A,X,Y) ; fac1 /= 10 , CAUTION: result is always positive!
romsub $bc5b = 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
asmsub FADDT () clobbers(A,X,Y) = $b86a ; fac1 += fac2
asmsub FADD (uword mflpt @ AY) clobbers(A,X,Y) = $b867 ; fac1 += mflpt value from A/Y
asmsub FSUBT () clobbers(A,X,Y) = $b853 ; fac1 = fac2-fac1 mind the order of the operands
asmsub FSUB (uword mflpt @ AY) clobbers(A,X,Y) = $b850 ; fac1 = mflpt from A/Y - fac1
asmsub FMULTT () clobbers(A,X,Y) = $ba2b ; fac1 *= fac2
asmsub FMULT (uword mflpt @ AY) clobbers(A,X,Y) = $ba28 ; fac1 *= mflpt value from A/Y
asmsub FDIVT () clobbers(A,X,Y) = $bb12 ; fac1 = fac2/fac1 (remainder in fac2) mind the order of the operands
asmsub FDIV (uword mflpt @ AY) clobbers(A,X,Y) = $bb0f ; fac1 = mflpt in A/Y / fac1 (remainder in fac2)
asmsub FPWRT () clobbers(A,X,Y) = $bf7b ; fac1 = fac2 ** fac1
asmsub FPWR (uword mflpt @ AY) clobbers(A,X,Y) = $bf78 ; fac1 = fac2 ** mflpt from A/Y
romsub $b86a = FADDT() clobbers(A,X,Y) ; fac1 += fac2
romsub $b867 = FADD(uword mflpt @ AY) clobbers(A,X,Y) ; fac1 += mflpt value from A/Y
romsub $b853 = FSUBT() clobbers(A,X,Y) ; fac1 = fac2-fac1 mind the order of the operands
romsub $b850 = FSUB(uword mflpt @ AY) clobbers(A,X,Y) ; fac1 = mflpt from A/Y - fac1
romsub $ba2b = FMULTT() clobbers(A,X,Y) ; fac1 *= fac2
romsub $ba28 = FMULT(uword mflpt @ AY) clobbers(A,X,Y) ; fac1 *= mflpt value from A/Y
romsub $bb12 = FDIVT() clobbers(A,X,Y) ; fac1 = fac2/fac1 (remainder in fac2) mind the order of the operands
romsub $bb0f = FDIV(uword mflpt @ AY) clobbers(A,X,Y) ; fac1 = mflpt in A/Y / fac1 (remainder in fac2)
romsub $bf7b = FPWRT() clobbers(A,X,Y) ; fac1 = fac2 ** fac1
romsub $bf78 = FPWR(uword mflpt @ AY) clobbers(A,X,Y) ; fac1 = fac2 ** mflpt from A/Y
asmsub NOTOP () clobbers(A,X,Y) = $aed4 ; fac1 = NOT(fac1)
asmsub INT () clobbers(A,X,Y) = $bccc ; INT() truncates, use FADDH first to round instead of trunc
asmsub LOG () clobbers(A,X,Y) = $b9ea ; fac1 = LN(fac1) (natural log)
asmsub SGN () clobbers(A,X,Y) = $bc39 ; fac1 = SGN(fac1), result of SIGN (-1, 0 or 1)
asmsub SIGN () -> ubyte @ A = $bc2b ; SIGN(fac1) to A, $ff, $0, $1 for negative, zero, positive
asmsub ABS () = $bc58 ; fac1 = ABS(fac1)
asmsub SQR () clobbers(A,X,Y) = $bf71 ; fac1 = SQRT(fac1)
asmsub SQRA () clobbers(A,X,Y) = $bf74 ; fac1 = SQRT(fac2)
asmsub EXP () clobbers(A,X,Y) = $bfed ; fac1 = EXP(fac1) (e ** fac1)
asmsub NEGOP () clobbers(A) = $bfb4 ; switch the sign of fac1
asmsub RND () clobbers(A,X,Y) = $e097 ; fac1 = RND(fac1) float random number generator
asmsub COS () clobbers(A,X,Y) = $e264 ; fac1 = COS(fac1)
asmsub SIN () clobbers(A,X,Y) = $e26b ; fac1 = SIN(fac1)
asmsub TAN () clobbers(A,X,Y) = $e2b4 ; fac1 = TAN(fac1)
asmsub ATN () clobbers(A,X,Y) = $e30e ; fac1 = ATN(fac1)
romsub $aed4 = NOTOP() clobbers(A,X,Y) ; fac1 = NOT(fac1)
romsub $bccc = INT() clobbers(A,X,Y) ; INT() truncates, use FADDH first to round instead of trunc
romsub $b9ea = LOG() clobbers(A,X,Y) ; fac1 = LN(fac1) (natural log)
romsub $bc39 = SGN() clobbers(A,X,Y) ; fac1 = SGN(fac1), result of SIGN (-1, 0 or 1)
romsub $bc2b = SIGN() -> ubyte @ A ; SIGN(fac1) to A, $ff, $0, $1 for negative, zero, positive
romsub $bc58 = ABS() ; fac1 = ABS(fac1)
romsub $bf71 = SQR() clobbers(A,X,Y) ; fac1 = SQRT(fac1)
romsub $bf74 = SQRA() clobbers(A,X,Y) ; fac1 = SQRT(fac2)
romsub $bfed = EXP() clobbers(A,X,Y) ; fac1 = EXP(fac1) (e ** fac1)
romsub $bfb4 = NEGOP() clobbers(A) ; switch the sign of fac1
romsub $e097 = RND() clobbers(A,X,Y) ; fac1 = RND(fac1) float random number generator
romsub $e264 = COS() clobbers(A,X,Y) ; fac1 = COS(fac1)
romsub $e26b = SIN() clobbers(A,X,Y) ; fac1 = SIN(fac1)
romsub $e2b4 = TAN() clobbers(A,X,Y) ; fac1 = TAN(fac1)
romsub $e30e = ATN() clobbers(A,X,Y) ; fac1 = ATN(fac1)
asmsub FREADS32 () clobbers(A,X,Y) {
asmsub FREADS32() clobbers(A,X,Y) {
; ---- fac1 = signed int32 from $62-$65 big endian (MSB FIRST)
%asm {{
lda $62
@ -196,8 +195,8 @@ sub print_f (float value) {
; ---- prints the floating point value (without a newline) using basic rom routines.
%asm {{
stx c64.SCRATCH_ZPREGX
lda #<print_f_value
ldy #>print_f_value
lda #<value
ldy #>value
jsr MOVFM ; load float into fac1
jsr FOUT ; fac1 to string in A/Y
jsr c64.STROUT ; print string in A/Y
@ -220,740 +219,6 @@ sub print_fln (float value) {
}
; --- low level floating point assembly routines
%asm {{
ub2float .proc
; -- convert ubyte in SCRATCH_ZPB1 to float at address A/Y
; clobbers A, Y
stx c64.SCRATCH_ZPREGX
sta c64.SCRATCH_ZPWORD2
sty c64.SCRATCH_ZPWORD2+1
ldy c64.SCRATCH_ZPB1
jsr FREADUY
_fac_to_mem ldx c64.SCRATCH_ZPWORD2
ldy c64.SCRATCH_ZPWORD2+1
jsr MOVMF
ldx c64.SCRATCH_ZPREGX
rts
.pend
b2float .proc
; -- convert byte in SCRATCH_ZPB1 to float at address A/Y
; clobbers A, Y
stx c64.SCRATCH_ZPREGX
sta c64.SCRATCH_ZPWORD2
sty c64.SCRATCH_ZPWORD2+1
lda c64.SCRATCH_ZPB1
jsr FREADSA
jmp ub2float._fac_to_mem
.pend
uw2float .proc
; -- convert uword in SCRATCH_ZPWORD1 to float at address A/Y
stx c64.SCRATCH_ZPREGX
sta c64.SCRATCH_ZPWORD2
sty c64.SCRATCH_ZPWORD2+1
lda c64.SCRATCH_ZPWORD1
ldy c64.SCRATCH_ZPWORD1+1
jsr GIVUAYFAY
jmp ub2float._fac_to_mem
.pend
w2float .proc
; -- convert word in SCRATCH_ZPWORD1 to float at address A/Y
stx c64.SCRATCH_ZPREGX
sta c64.SCRATCH_ZPWORD2
sty c64.SCRATCH_ZPWORD2+1
ldy c64.SCRATCH_ZPWORD1
lda c64.SCRATCH_ZPWORD1+1
jsr GIVAYF
jmp ub2float._fac_to_mem
.pend
stack_b2float .proc
; -- b2float operating on the stack
inx
lda c64.ESTACK_LO,x
stx c64.SCRATCH_ZPREGX
jsr FREADSA
jmp push_fac1_as_result
.pend
stack_w2float .proc
; -- w2float operating on the stack
inx
ldy c64.ESTACK_LO,x
lda c64.ESTACK_HI,x
stx c64.SCRATCH_ZPREGX
jsr GIVAYF
jmp push_fac1_as_result
.pend
stack_ub2float .proc
; -- ub2float operating on the stack
inx
lda c64.ESTACK_LO,x
stx c64.SCRATCH_ZPREGX
tay
jsr FREADUY
jmp push_fac1_as_result
.pend
stack_uw2float .proc
; -- uw2float operating on the stack
inx
lda c64.ESTACK_LO,x
ldy c64.ESTACK_HI,x
stx c64.SCRATCH_ZPREGX
jsr GIVUAYFAY
jmp push_fac1_as_result
.pend
stack_float2w .proc
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
jsr AYINT
ldx c64.SCRATCH_ZPREGX
lda $64
sta c64.ESTACK_HI,x
lda $65
sta c64.ESTACK_LO,x
dex
rts
.pend
stack_float2uw .proc
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
jsr GETADR
ldx c64.SCRATCH_ZPREGX
sta c64.ESTACK_HI,x
tya
sta c64.ESTACK_LO,x
dex
rts
.pend
push_float .proc
; ---- push mflpt5 in A/Y onto stack
; (taking 3 stack positions = 6 bytes of which 1 is padding)
sta c64.SCRATCH_ZPWORD1
sty c64.SCRATCH_ZPWORD1+1
ldy #0
lda (c64.SCRATCH_ZPWORD1),y
sta c64.ESTACK_LO,x
iny
lda (c64.SCRATCH_ZPWORD1),y
sta c64.ESTACK_HI,x
dex
iny
lda (c64.SCRATCH_ZPWORD1),y
sta c64.ESTACK_LO,x
iny
lda (c64.SCRATCH_ZPWORD1),y
sta c64.ESTACK_HI,x
dex
iny
lda (c64.SCRATCH_ZPWORD1),y
sta c64.ESTACK_LO,x
dex
rts
.pend
func_rndf .proc
; -- put a random floating point value on the stack
stx c64.SCRATCH_ZPREG
lda #1
jsr FREADSA
jsr RND ; rng into fac1
ldx #<_rndf_rnum5
ldy #>_rndf_rnum5
jsr MOVMF ; fac1 to mem X/Y
ldx c64.SCRATCH_ZPREG
lda #<_rndf_rnum5
ldy #>_rndf_rnum5
jmp push_float
_rndf_rnum5 .byte 0,0,0,0,0
.pend
push_float_from_indexed_var .proc
; -- push the float from the array at A/Y with index on stack, onto the stack.
sta c64.SCRATCH_ZPWORD1
sty c64.SCRATCH_ZPWORD1+1
jsr prog8_lib.pop_index_times_5
jsr prog8_lib.add_a_to_zpword
lda c64.SCRATCH_ZPWORD1
ldy c64.SCRATCH_ZPWORD1+1
jmp push_float
.pend
pop_float .proc
; ---- pops mflpt5 from stack to memory A/Y
; (frees 3 stack positions = 6 bytes of which 1 is padding)
sta c64.SCRATCH_ZPWORD1
sty c64.SCRATCH_ZPWORD1+1
ldy #4
inx
lda c64.ESTACK_LO,x
sta (c64.SCRATCH_ZPWORD1),y
dey
inx
lda c64.ESTACK_HI,x
sta (c64.SCRATCH_ZPWORD1),y
dey
lda c64.ESTACK_LO,x
sta (c64.SCRATCH_ZPWORD1),y
dey
inx
lda c64.ESTACK_HI,x
sta (c64.SCRATCH_ZPWORD1),y
dey
lda c64.ESTACK_LO,x
sta (c64.SCRATCH_ZPWORD1),y
rts
.pend
pop_float_fac1 .proc
; -- pops float from stack into FAC1
lda #<fmath_float1
ldy #>fmath_float1
jsr pop_float
lda #<fmath_float1
ldy #>fmath_float1
jmp MOVFM
.pend
pop_float_to_indexed_var .proc
; -- pop the float on the stack, to the memory in the array at A/Y indexed by the byte on stack
sta c64.SCRATCH_ZPWORD1
sty c64.SCRATCH_ZPWORD1+1
jsr prog8_lib.pop_index_times_5
jsr prog8_lib.add_a_to_zpword
lda c64.SCRATCH_ZPWORD1
ldy c64.SCRATCH_ZPWORD1+1
jmp pop_float
.pend
copy_float .proc
; -- copies the 5 bytes of the mflt value pointed to by SCRATCH_ZPWORD1,
; into the 5 bytes pointed to by A/Y. Clobbers A,Y.
sta c64.SCRATCH_ZPWORD2
sty c64.SCRATCH_ZPWORD2+1
ldy #0
lda (c64.SCRATCH_ZPWORD1),y
sta (c64.SCRATCH_ZPWORD2),y
iny
lda (c64.SCRATCH_ZPWORD1),y
sta (c64.SCRATCH_ZPWORD2),y
iny
lda (c64.SCRATCH_ZPWORD1),y
sta (c64.SCRATCH_ZPWORD2),y
iny
lda (c64.SCRATCH_ZPWORD1),y
sta (c64.SCRATCH_ZPWORD2),y
iny
lda (c64.SCRATCH_ZPWORD1),y
sta (c64.SCRATCH_ZPWORD2),y
rts
.pend
inc_var_f .proc
; -- add 1 to float pointed to by A/Y
sta c64.SCRATCH_ZPWORD1
sty c64.SCRATCH_ZPWORD1+1
stx c64.SCRATCH_ZPREGX
jsr MOVFM
lda #<FL_FONE
ldy #>FL_FONE
jsr FADD
ldx c64.SCRATCH_ZPWORD1
ldy c64.SCRATCH_ZPWORD1+1
jsr MOVMF
ldx c64.SCRATCH_ZPREGX
rts
.pend
dec_var_f .proc
; -- subtract 1 from float pointed to by A/Y
sta c64.SCRATCH_ZPWORD1
sty c64.SCRATCH_ZPWORD1+1
stx c64.SCRATCH_ZPREGX
lda #<FL_FONE
ldy #>FL_FONE
jsr MOVFM
lda c64.SCRATCH_ZPWORD1
ldy c64.SCRATCH_ZPWORD1+1
jsr FSUB
ldx c64.SCRATCH_ZPWORD1
ldy c64.SCRATCH_ZPWORD1+1
jsr MOVMF
ldx c64.SCRATCH_ZPREGX
rts
.pend
inc_indexed_var_f .proc
; -- add 1 to float in array pointed to by A/Y, at index X
pha
txa
sta c64.SCRATCH_ZPB1
asl a
asl a
clc
adc c64.SCRATCH_ZPB1
sta c64.SCRATCH_ZPB1
pla
clc
adc c64.SCRATCH_ZPB1
bcc +
iny
+ jmp inc_var_f
.pend
dec_indexed_var_f .proc
; -- subtract 1 to float in array pointed to by A/Y, at index X
pha
txa
sta c64.SCRATCH_ZPB1
asl a
asl a
clc
adc c64.SCRATCH_ZPB1
sta c64.SCRATCH_ZPB1
pla
clc
adc c64.SCRATCH_ZPB1
bcc +
iny
+ jmp dec_var_f
.pend
pop_2_floats_f2_in_fac1 .proc
; -- pop 2 floats from stack, load the second one in FAC1 as well
lda #<fmath_float2
ldy #>fmath_float2
jsr pop_float
lda #<fmath_float1
ldy #>fmath_float1
jsr pop_float
lda #<fmath_float2
ldy #>fmath_float2
jmp MOVFM
.pend
fmath_float1 .byte 0,0,0,0,0 ; storage for a mflpt5 value
fmath_float2 .byte 0,0,0,0,0 ; storage for a mflpt5 value
push_fac1_as_result .proc
; -- push the float in FAC1 onto the stack, and return from calculation
ldx #<fmath_float1
ldy #>fmath_float1
jsr MOVMF
lda #<fmath_float1
ldy #>fmath_float1
ldx c64.SCRATCH_ZPREGX
jmp push_float
.pend
pow_f .proc
; -- push f1 ** f2 on stack
lda #<fmath_float2
ldy #>fmath_float2
jsr pop_float
lda #<fmath_float1
ldy #>fmath_float1
jsr pop_float
stx c64.SCRATCH_ZPREGX
lda #<fmath_float1
ldy #>fmath_float1
jsr CONUPK ; fac2 = float1
lda #<fmath_float2
ldy #>fmath_float2
jsr FPWR
ldx c64.SCRATCH_ZPREGX
jmp push_fac1_as_result
.pend
div_f .proc
; -- push f1/f2 on stack
jsr pop_2_floats_f2_in_fac1
stx c64.SCRATCH_ZPREGX
lda #<fmath_float1
ldy #>fmath_float1
jsr FDIV
jmp push_fac1_as_result
.pend
add_f .proc
; -- push f1+f2 on stack
jsr pop_2_floats_f2_in_fac1
stx c64.SCRATCH_ZPREGX
lda #<fmath_float1
ldy #>fmath_float1
jsr FADD
jmp push_fac1_as_result
.pend
sub_f .proc
; -- push f1-f2 on stack
jsr pop_2_floats_f2_in_fac1
stx c64.SCRATCH_ZPREGX
lda #<fmath_float1
ldy #>fmath_float1
jsr FSUB
jmp push_fac1_as_result
.pend
mul_f .proc
; -- push f1*f2 on stack
jsr pop_2_floats_f2_in_fac1
stx c64.SCRATCH_ZPREGX
lda #<fmath_float1
ldy #>fmath_float1
jsr FMULT
jmp push_fac1_as_result
.pend
neg_f .proc
; -- push -flt back on stack
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
jsr NEGOP
jmp push_fac1_as_result
.pend
abs_f .proc
; -- push abs(float) on stack (as float)
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
jsr ABS
jmp push_fac1_as_result
.pend
equal_f .proc
; -- are the two mflpt5 numbers on the stack identical?
inx
inx
inx
inx
lda c64.ESTACK_LO-3,x
cmp c64.ESTACK_LO,x
bne _equals_false
lda c64.ESTACK_LO-2,x
cmp c64.ESTACK_LO+1,x
bne _equals_false
lda c64.ESTACK_LO-1,x
cmp c64.ESTACK_LO+2,x
bne _equals_false
lda c64.ESTACK_HI-2,x
cmp c64.ESTACK_HI+1,x
bne _equals_false
lda c64.ESTACK_HI-1,x
cmp c64.ESTACK_HI+2,x
bne _equals_false
_equals_true lda #1
_equals_store inx
sta c64.ESTACK_LO+1,x
rts
_equals_false lda #0
beq _equals_store
.pend
notequal_f .proc
; -- are the two mflpt5 numbers on the stack different?
jsr equal_f
eor #1 ; invert the result
sta c64.ESTACK_LO+1,x
rts
.pend
less_f .proc
; -- is f1 < f2?
jsr compare_floats
cmp #255
beq compare_floats._return_true
bne compare_floats._return_false
.pend
lesseq_f .proc
; -- is f1 <= f2?
jsr compare_floats
cmp #255
beq compare_floats._return_true
cmp #0
beq compare_floats._return_true
bne compare_floats._return_false
.pend
greater_f .proc
; -- is f1 > f2?
jsr compare_floats
cmp #1
beq compare_floats._return_true
bne compare_floats._return_false
.pend
greatereq_f .proc
; -- is f1 >= f2?
jsr compare_floats
cmp #1
beq compare_floats._return_true
cmp #0
beq compare_floats._return_true
bne compare_floats._return_false
.pend
compare_floats .proc
lda #<fmath_float2
ldy #>fmath_float2
jsr pop_float
lda #<fmath_float1
ldy #>fmath_float1
jsr pop_float
lda #<fmath_float1
ldy #>fmath_float1
jsr MOVFM ; fac1 = flt1
lda #<fmath_float2
ldy #>fmath_float2
stx c64.SCRATCH_ZPREG
jsr FCOMP ; A = flt1 compared with flt2 (0=equal, 1=flt1>flt2, 255=flt1<flt2)
ldx c64.SCRATCH_ZPREG
rts
_return_false lda #0
_return_result sta c64.ESTACK_LO,x
dex
rts
_return_true lda #1
bne _return_result
.pend
func_sin .proc
; -- push sin(f) back onto stack
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
jsr SIN
jmp push_fac1_as_result
.pend
func_cos .proc
; -- push cos(f) back onto stack
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
jsr COS
jmp push_fac1_as_result
.pend
func_tan .proc
; -- push tan(f) back onto stack
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
jsr TAN
jmp push_fac1_as_result
.pend
func_atan .proc
; -- push atan(f) back onto stack
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
jsr ATN
jmp push_fac1_as_result
.pend
func_ln .proc
; -- push ln(f) back onto stack
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
jsr LOG
jmp push_fac1_as_result
.pend
func_log2 .proc
; -- push log base 2, ln(f)/ln(2), back onto stack
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
jsr LOG
jsr MOVEF
lda #<c64.FL_LOG2
ldy #>c64.FL_LOG2
jsr MOVFM
jsr FDIVT
jmp push_fac1_as_result
.pend
func_sqrt .proc
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
jsr SQR
jmp push_fac1_as_result
.pend
func_rad .proc
; -- convert degrees to radians (d * pi / 180)
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
lda #<_pi_div_180
ldy #>_pi_div_180
jsr FMULT
jmp push_fac1_as_result
_pi_div_180 .byte 123, 14, 250, 53, 18 ; pi / 180
.pend
func_deg .proc
; -- convert radians to degrees (d * (1/ pi * 180))
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
lda #<_one_over_pi_div_180
ldy #>_one_over_pi_div_180
jsr FMULT
jmp push_fac1_as_result
_one_over_pi_div_180 .byte 134, 101, 46, 224, 211 ; 1 / (pi * 180)
.pend
func_round .proc
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
jsr FADDH
jsr INT
jmp push_fac1_as_result
.pend
func_floor .proc
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
jsr INT
jmp push_fac1_as_result
.pend
func_ceil .proc
; -- ceil: tr = int(f); if tr==f -> return else return tr+1
jsr pop_float_fac1
stx c64.SCRATCH_ZPREGX
ldx #<fmath_float1
ldy #>fmath_float1
jsr MOVMF
jsr INT
lda #<fmath_float1
ldy #>fmath_float1
jsr FCOMP
cmp #0
beq +
lda #<FL_FONE
ldy #>FL_FONE
jsr FADD
+ jmp push_fac1_as_result
.pend
func_any_f .proc
inx
lda c64.ESTACK_LO,x ; array size
sta c64.SCRATCH_ZPB1
asl a
asl a
clc
adc c64.SCRATCH_ZPB1 ; times 5 because of float
jmp prog8_lib.func_any_b._entry
.pend
func_all_f .proc
inx
jsr prog8_lib.peek_address
lda c64.ESTACK_LO,x ; array size
sta c64.SCRATCH_ZPB1
asl a
asl a
clc
adc c64.SCRATCH_ZPB1 ; times 5 because of float
tay
dey
- lda (c64.SCRATCH_ZPWORD1),y
clc
dey
adc (c64.SCRATCH_ZPWORD1),y
dey
adc (c64.SCRATCH_ZPWORD1),y
dey
adc (c64.SCRATCH_ZPWORD1),y
dey
adc (c64.SCRATCH_ZPWORD1),y
dey
cmp #0
beq +
cpy #255
bne -
lda #1
sta c64.ESTACK_LO+1,x
rts
+ sta c64.ESTACK_LO+1,x
rts
.pend
func_max_f .proc
lda #255
sta _minmax_cmp+1
lda #<_largest_neg_float
ldy #>_largest_neg_float
_minmax_entry jsr MOVFM
jsr prog8_lib.pop_array_and_lengthmin1Y
stx c64.SCRATCH_ZPREGX
- sty c64.SCRATCH_ZPREG
lda c64.SCRATCH_ZPWORD1
ldy c64.SCRATCH_ZPWORD1+1
jsr FCOMP
_minmax_cmp cmp #255 ; modified
bne +
lda c64.SCRATCH_ZPWORD1
ldy c64.SCRATCH_ZPWORD1+1
jsr MOVFM
+ lda c64.SCRATCH_ZPWORD1
clc
adc #5
sta c64.SCRATCH_ZPWORD1
bcc +
inc c64.SCRATCH_ZPWORD1+1
+ ldy c64.SCRATCH_ZPREG
dey
cpy #255
bne -
jmp push_fac1_as_result
_largest_neg_float .byte 255,255,255,255,255 ; largest negative float -1.7014118345e+38
.pend
func_min_f .proc
lda #1
sta func_max_f._minmax_cmp+1
lda #<_largest_pos_float
ldy #>_largest_pos_float
jmp func_max_f._minmax_entry
_largest_pos_float .byte 255,127,255,255,255 ; largest positive float
rts
.pend
func_sum_f .proc
lda #<FL_ZERO
ldy #>FL_ZERO
jsr MOVFM
jsr prog8_lib.pop_array_and_lengthmin1Y
stx c64.SCRATCH_ZPREGX
- sty c64.SCRATCH_ZPREG
lda c64.SCRATCH_ZPWORD1
ldy c64.SCRATCH_ZPWORD1+1
jsr FADD
ldy c64.SCRATCH_ZPREG
dey
cpy #255
beq +
lda c64.SCRATCH_ZPWORD1
clc
adc #5
sta c64.SCRATCH_ZPWORD1
bcc -
inc c64.SCRATCH_ZPWORD1+1
bne -
+ jmp push_fac1_as_result
.pend
}}
%asminclude "library:c64floats.asm", ""
} ; ------ end of block c64flt

390
compiler/res/prog8lib/c64lib.p8
View File

@ -6,179 +6,179 @@
; indent format: TABS, size=8
~ c64 {
const uword ESTACK_LO = $ce00 ; evaluation stack (lsb)
const uword ESTACK_HI = $cf00 ; evaluation stack (msb)
&ubyte SCRATCH_ZPB1 = $02 ; scratch byte 1 in ZP
&ubyte SCRATCH_ZPREG = $03 ; scratch register in ZP
&ubyte SCRATCH_ZPREGX = $fa ; temp storage for X register (stack pointer)
&uword SCRATCH_ZPWORD1 = $fb ; scratch word in ZP ($fb/$fc)
&uword SCRATCH_ZPWORD2 = $fd ; scratch word in ZP ($fd/$fe)
c64 {
const uword ESTACK_LO = $ce00 ; evaluation stack (lsb)
const uword ESTACK_HI = $cf00 ; evaluation stack (msb)
&ubyte SCRATCH_ZPB1 = $02 ; scratch byte 1 in ZP
&ubyte SCRATCH_ZPREG = $03 ; scratch register in ZP
&ubyte SCRATCH_ZPREGX = $fa ; temp storage for X register (stack pointer)
&uword SCRATCH_ZPWORD1 = $fb ; scratch word in ZP ($fb/$fc)
&uword SCRATCH_ZPWORD2 = $fd ; scratch word in ZP ($fd/$fe)
&ubyte TIME_HI = $a0 ; software jiffy clock, hi byte
&ubyte TIME_MID = $a1 ; .. mid byte
&ubyte TIME_LO = $a2 ; .. lo byte. Updated by IRQ every 1/60 sec
&ubyte STKEY = $91 ; various keyboard statuses (updated by IRQ)
&ubyte SFDX = $cb ; current key pressed (matrix value) (updated by IRQ)
&ubyte COLOR = $0286 ; cursor color
&ubyte HIBASE = $0288 ; screen base address / 256 (hi-byte of screen memory address)
&uword CINV = $0314 ; IRQ vector
&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
&ubyte TIME_HI = $a0 ; software jiffy clock, hi byte
&ubyte TIME_MID = $a1 ; .. mid byte
&ubyte TIME_LO = $a2 ; .. lo byte. Updated by IRQ every 1/60 sec
&ubyte STKEY = $91 ; various keyboard statuses (updated by IRQ)
&ubyte SFDX = $cb ; current key pressed (matrix value) (updated by IRQ)
; the default addresses for the character screen chars and colors
const uword Screen = $0400 ; to have this as an array[40*25] the compiler would have to support array size > 255
const uword Colors = $d800 ; to have this as an array[40*25] the compiler would have to support array size > 255
&ubyte COLOR = $0286 ; cursor color
&ubyte HIBASE = $0288 ; screen base address / 256 (hi-byte of screen memory address)
&uword CINV = $0314 ; IRQ vector
&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
; the default locations of the 8 sprite pointers (store address of sprite / 64)
&ubyte SPRPTR0 = 2040
&ubyte SPRPTR1 = 2041
&ubyte SPRPTR2 = 2042
&ubyte SPRPTR3 = 2043
&ubyte SPRPTR4 = 2044
&ubyte SPRPTR5 = 2045
&ubyte SPRPTR6 = 2046
&ubyte SPRPTR7 = 2047
&ubyte[8] SPRPTR = 2040 ; the 8 sprite pointers as an array.
; the default addresses for the character screen chars and colors
const uword Screen = $0400 ; to have this as an array[40*25] the compiler would have to support array size > 255
const uword Colors = $d800 ; to have this as an array[40*25] the compiler would have to support array size > 255
; the default locations of the 8 sprite pointers (store address of sprite / 64)
&ubyte SPRPTR0 = 2040
&ubyte SPRPTR1 = 2041
&ubyte SPRPTR2 = 2042
&ubyte SPRPTR3 = 2043
&ubyte SPRPTR4 = 2044
&ubyte SPRPTR5 = 2045
&ubyte SPRPTR6 = 2046
&ubyte SPRPTR7 = 2047
&ubyte[8] SPRPTR = 2040 ; the 8 sprite pointers as an array.
; ---- VIC-II 6567/6569/856x registers ----
&ubyte SP0X = $d000
&ubyte SP0Y = $d001
&ubyte SP1X = $d002
&ubyte SP1Y = $d003
&ubyte SP2X = $d004
&ubyte SP2Y = $d005
&ubyte SP3X = $d006
&ubyte SP3Y = $d007
&ubyte SP4X = $d008
&ubyte SP4Y = $d009
&ubyte SP5X = $d00a
&ubyte SP5Y = $d00b
&ubyte SP6X = $d00c
&ubyte SP6Y = $d00d
&ubyte SP7X = $d00e
&ubyte SP7Y = $d00f
&ubyte[16] SPXY = $d000 ; the 8 sprite X and Y registers as an array.
&uword[8] SPXYW = $d000 ; the 8 sprite X and Y registers as a combined xy word array.
&ubyte SP0X = $d000
&ubyte SP0Y = $d001
&ubyte SP1X = $d002
&ubyte SP1Y = $d003
&ubyte SP2X = $d004
&ubyte SP2Y = $d005
&ubyte SP3X = $d006
&ubyte SP3Y = $d007
&ubyte SP4X = $d008
&ubyte SP4Y = $d009
&ubyte SP5X = $d00a
&ubyte SP5Y = $d00b
&ubyte SP6X = $d00c
&ubyte SP6Y = $d00d
&ubyte SP7X = $d00e
&ubyte SP7Y = $d00f
&ubyte[16] SPXY = $d000 ; the 8 sprite X and Y registers as an array.
&uword[8] SPXYW = $d000 ; the 8 sprite X and Y registers as a combined xy word array.
&ubyte MSIGX = $d010
&ubyte SCROLY = $d011
&ubyte RASTER = $d012
&ubyte LPENX = $d013
&ubyte LPENY = $d014
&ubyte SPENA = $d015
&ubyte SCROLX = $d016
&ubyte YXPAND = $d017
&ubyte VMCSB = $d018
&ubyte VICIRQ = $d019
&ubyte IREQMASK = $d01a
&ubyte SPBGPR = $d01b
&ubyte SPMC = $d01c
&ubyte XXPAND = $d01d
&ubyte SPSPCL = $d01e
&ubyte SPBGCL = $d01f
&ubyte MSIGX = $d010
&ubyte SCROLY = $d011
&ubyte RASTER = $d012
&ubyte LPENX = $d013
&ubyte LPENY = $d014
&ubyte SPENA = $d015
&ubyte SCROLX = $d016
&ubyte YXPAND = $d017
&ubyte VMCSB = $d018
&ubyte VICIRQ = $d019
&ubyte IREQMASK = $d01a
&ubyte SPBGPR = $d01b
&ubyte SPMC = $d01c
&ubyte XXPAND = $d01d
&ubyte SPSPCL = $d01e
&ubyte SPBGCL = $d01f
&ubyte EXTCOL = $d020 ; border color
&ubyte BGCOL0 = $d021 ; screen color
&ubyte BGCOL1 = $d022
&ubyte BGCOL2 = $d023
&ubyte BGCOL4 = $d024
&ubyte SPMC0 = $d025
&ubyte SPMC1 = $d026
&ubyte SP0COL = $d027
&ubyte SP1COL = $d028
&ubyte SP2COL = $d029
&ubyte SP3COL = $d02a
&ubyte SP4COL = $d02b
&ubyte SP5COL = $d02c
&ubyte SP6COL = $d02d
&ubyte SP7COL = $d02e
&ubyte[8] SPCOL = $d027
&ubyte EXTCOL = $d020 ; border color
&ubyte BGCOL0 = $d021 ; screen color
&ubyte BGCOL1 = $d022
&ubyte BGCOL2 = $d023
&ubyte BGCOL4 = $d024
&ubyte SPMC0 = $d025
&ubyte SPMC1 = $d026
&ubyte SP0COL = $d027
&ubyte SP1COL = $d028
&ubyte SP2COL = $d029
&ubyte SP3COL = $d02a
&ubyte SP4COL = $d02b
&ubyte SP5COL = $d02c
&ubyte SP6COL = $d02d
&ubyte SP7COL = $d02e
&ubyte[8] SPCOL = $d027
; ---- end of VIC-II registers ----
; ---- CIA 6526 1 & 2 registers ----
&ubyte CIA1PRA = $DC00 ; CIA 1 DRA, keyboard column drive (and joystick control port #2)
&ubyte CIA1PRB = $DC01 ; CIA 1 DRB, keyboard row port (and joystick control port #1)
&ubyte CIA1DDRA = $DC02 ; CIA 1 DDRA, keyboard column
&ubyte CIA1DDRB = $DC03 ; CIA 1 DDRB, keyboard row
&ubyte CIA1TAL = $DC04 ; CIA 1 timer A low byte
&ubyte CIA1TAH = $DC05 ; CIA 1 timer A high byte
&ubyte CIA1TBL = $DC06 ; CIA 1 timer B low byte
&ubyte CIA1TBH = $DC07 ; CIA 1 timer B high byte
&ubyte CIA1TOD10 = $DC08 ; time of day, 1/10 sec.
&ubyte CIA1TODSEC = $DC09 ; time of day, seconds
&ubyte CIA1TODMMIN = $DC0A ; time of day, minutes
&ubyte CIA1TODHR = $DC0B ; time of day, hours
&ubyte CIA1SDR = $DC0C ; Serial Data Register
&ubyte CIA1ICR = $DC0D
&ubyte CIA1CRA = $DC0E
&ubyte CIA1CRB = $DC0F
&ubyte CIA1PRA = $DC00 ; CIA 1 DRA, keyboard column drive (and joystick control port #2)
&ubyte CIA1PRB = $DC01 ; CIA 1 DRB, keyboard row port (and joystick control port #1)
&ubyte CIA1DDRA = $DC02 ; CIA 1 DDRA, keyboard column
&ubyte CIA1DDRB = $DC03 ; CIA 1 DDRB, keyboard row
&ubyte CIA1TAL = $DC04 ; CIA 1 timer A low byte
&ubyte CIA1TAH = $DC05 ; CIA 1 timer A high byte
&ubyte CIA1TBL = $DC06 ; CIA 1 timer B low byte
&ubyte CIA1TBH = $DC07 ; CIA 1 timer B high byte
&ubyte CIA1TOD10 = $DC08 ; time of day, 1/10 sec.
&ubyte CIA1TODSEC = $DC09 ; time of day, seconds
&ubyte CIA1TODMMIN = $DC0A ; time of day, minutes
&ubyte CIA1TODHR = $DC0B ; time of day, hours
&ubyte CIA1SDR = $DC0C ; Serial Data Register
&ubyte CIA1ICR = $DC0D
&ubyte CIA1CRA = $DC0E
&ubyte CIA1CRB = $DC0F
&ubyte CIA2PRA = $DD00 ; CIA 2 DRA, serial port and video address
&ubyte CIA2PRB = $DD01 ; CIA 2 DRB, RS232 port / USERPORT
&ubyte CIA2DDRA = $DD02 ; CIA 2 DDRA, serial port and video address
&ubyte CIA2DDRB = $DD03 ; CIA 2 DDRB, RS232 port / USERPORT
&ubyte CIA2TAL = $DD04 ; CIA 2 timer A low byte
&ubyte CIA2TAH = $DD05 ; CIA 2 timer A high byte
&ubyte CIA2TBL = $DD06 ; CIA 2 timer B low byte
&ubyte CIA2TBH = $DD07 ; CIA 2 timer B high byte
&ubyte CIA2TOD10 = $DD08 ; time of day, 1/10 sec.
&ubyte CIA2TODSEC = $DD09 ; time of day, seconds
&ubyte CIA2TODMIN = $DD0A ; time of day, minutes
&ubyte CIA2TODHR = $DD0B ; time of day, hours
&ubyte CIA2SDR = $DD0C ; Serial Data Register
&ubyte CIA2ICR = $DD0D
&ubyte CIA2CRA = $DD0E
&ubyte CIA2CRB = $DD0F
&ubyte CIA2PRA = $DD00 ; CIA 2 DRA, serial port and video address
&ubyte CIA2PRB = $DD01 ; CIA 2 DRB, RS232 port / USERPORT
&ubyte CIA2DDRA = $DD02 ; CIA 2 DDRA, serial port and video address
&ubyte CIA2DDRB = $DD03 ; CIA 2 DDRB, RS232 port / USERPORT
&ubyte CIA2TAL = $DD04 ; CIA 2 timer A low byte
&ubyte CIA2TAH = $DD05 ; CIA 2 timer A high byte
&ubyte CIA2TBL = $DD06 ; CIA 2 timer B low byte
&ubyte CIA2TBH = $DD07 ; CIA 2 timer B high byte
&ubyte CIA2TOD10 = $DD08 ; time of day, 1/10 sec.
&ubyte CIA2TODSEC = $DD09 ; time of day, seconds
&ubyte CIA2TODMIN = $DD0A ; time of day, minutes
&ubyte CIA2TODHR = $DD0B ; time of day, hours
&ubyte CIA2SDR = $DD0C ; Serial Data Register
&ubyte CIA2ICR = $DD0D
&ubyte CIA2CRA = $DD0E
&ubyte CIA2CRB = $DD0F
; ---- end of CIA registers ----
; ---- SID 6581/8580 registers ----
&ubyte FREQLO1 = $D400 ; channel 1 freq lo
&ubyte FREQHI1 = $D401 ; channel 1 freq hi
&uword FREQ1 = $D400 ; channel 1 freq (word)
&ubyte PWLO1 = $D402 ; channel 1 pulse width lo (7-0)
&ubyte PWHI1 = $D403 ; channel 1 pulse width hi (11-8)
&uword PW1 = $D402 ; channel 1 pulse width (word)
&ubyte CR1 = $D404 ; channel 1 voice control register
&ubyte AD1 = $D405 ; channel 1 attack & decay
&ubyte SR1 = $D406 ; channel 1 sustain & release
&ubyte FREQLO2 = $D407 ; channel 2 freq lo
&ubyte FREQHI2 = $D408 ; channel 2 freq hi
&uword FREQ2 = $D407 ; channel 2 freq (word)
&ubyte PWLO2 = $D409 ; channel 2 pulse width lo (7-0)
&ubyte PWHI2 = $D40A ; channel 2 pulse width hi (11-8)
&uword PW2 = $D409 ; channel 2 pulse width (word)
&ubyte CR2 = $D40B ; channel 2 voice control register
&ubyte AD2 = $D40C ; channel 2 attack & decay
&ubyte SR2 = $D40D ; channel 2 sustain & release
&ubyte FREQLO3 = $D40E ; channel 3 freq lo
&ubyte FREQHI3 = $D40F ; channel 3 freq hi
&uword FREQ3 = $D40E ; channel 3 freq (word)
&ubyte PWLO3 = $D410 ; channel 3 pulse width lo (7-0)
&ubyte PWHI3 = $D411 ; channel 3 pulse width hi (11-8)
&uword PW3 = $D410 ; channel 3 pulse width (word)
&ubyte CR3 = $D412 ; channel 3 voice control register
&ubyte AD3 = $D413 ; channel 3 attack & decay
&ubyte SR3 = $D414 ; channel 3 sustain & release
&ubyte FCLO = $D415 ; filter cutoff lo (2-0)
&ubyte FCHI = $D416 ; filter cutoff hi (10-3)
&uword FC = $D415 ; filter cutoff (word)
&ubyte RESFILT = $D417 ; filter resonance and routing
&ubyte MVOL = $D418 ; filter mode and main volume control
&ubyte POTX = $D419 ; potentiometer X
&ubyte POTY = $D41A ; potentiometer Y
&ubyte OSC3 = $D41B ; channel 3 oscillator value read
&ubyte ENV3 = $D41C ; channel 3 envelope value read
&ubyte FREQLO1 = $D400 ; channel 1 freq lo
&ubyte FREQHI1 = $D401 ; channel 1 freq hi
&uword FREQ1 = $D400 ; channel 1 freq (word)
&ubyte PWLO1 = $D402 ; channel 1 pulse width lo (7-0)
&ubyte PWHI1 = $D403 ; channel 1 pulse width hi (11-8)
&uword PW1 = $D402 ; channel 1 pulse width (word)
&ubyte CR1 = $D404 ; channel 1 voice control register
&ubyte AD1 = $D405 ; channel 1 attack & decay
&ubyte SR1 = $D406 ; channel 1 sustain & release
&ubyte FREQLO2 = $D407 ; channel 2 freq lo
&ubyte FREQHI2 = $D408 ; channel 2 freq hi
&uword FREQ2 = $D407 ; channel 2 freq (word)
&ubyte PWLO2 = $D409 ; channel 2 pulse width lo (7-0)
&ubyte PWHI2 = $D40A ; channel 2 pulse width hi (11-8)
&uword PW2 = $D409 ; channel 2 pulse width (word)
&ubyte CR2 = $D40B ; channel 2 voice control register
&ubyte AD2 = $D40C ; channel 2 attack & decay
&ubyte SR2 = $D40D ; channel 2 sustain & release
&ubyte FREQLO3 = $D40E ; channel 3 freq lo
&ubyte FREQHI3 = $D40F ; channel 3 freq hi
&uword FREQ3 = $D40E ; channel 3 freq (word)
&ubyte PWLO3 = $D410 ; channel 3 pulse width lo (7-0)
&ubyte PWHI3 = $D411 ; channel 3 pulse width hi (11-8)
&uword PW3 = $D410 ; channel 3 pulse width (word)
&ubyte CR3 = $D412 ; channel 3 voice control register
&ubyte AD3 = $D413 ; channel 3 attack & decay
&ubyte SR3 = $D414 ; channel 3 sustain & release
&ubyte FCLO = $D415 ; filter cutoff lo (2-0)
&ubyte FCHI = $D416 ; filter cutoff hi (10-3)
&uword FC = $D415 ; filter cutoff (word)
&ubyte RESFILT = $D417 ; filter resonance and routing
&ubyte MVOL = $D418 ; filter mode and main volume control
&ubyte POTX = $D419 ; potentiometer X
&ubyte POTY = $D41A ; potentiometer Y
&ubyte OSC3 = $D41B ; channel 3 oscillator value read
&ubyte ENV3 = $D41C ; channel 3 envelope value read
; ---- end of SID registers ----
@ -186,8 +186,8 @@
; ---- C64 basic routines ----
asmsub CLEARSCR () clobbers(A,X,Y) = $E544 ; clear the screen
asmsub HOMECRSR () clobbers(A,X,Y) = $E566 ; cursor to top left of screen
romsub $E544 = CLEARSCR() clobbers(A,X,Y) ; clear the screen
romsub $E566 = HOMECRSR() clobbers(A,X,Y) ; cursor to top left of screen
; ---- end of C64 basic routines ----
@ -195,48 +195,48 @@ asmsub HOMECRSR () clobbers(A,X,Y) = $E566 ; cursor to top left of screen
; ---- C64 kernal routines ----
asmsub STROUT (uword strptr @ AY) clobbers(A, X, Y) = $AB1E ; print null-terminated string (use c64scr.print instead)
asmsub IRQDFRT () clobbers(A,X,Y) = $EA31 ; default IRQ routine
asmsub IRQDFEND () clobbers(A,X,Y) = $EA81 ; default IRQ end/cleanup
asmsub CINT () clobbers(A,X,Y) = $FF81 ; (alias: SCINIT) initialize screen editor and video chip
asmsub IOINIT () clobbers(A, X) = $FF84 ; initialize I/O devices (CIA, SID, IRQ)
asmsub RAMTAS () clobbers(A,X,Y) = $FF87 ; initialize RAM, tape buffer, screen
asmsub RESTOR () clobbers(A,X,Y) = $FF8A ; restore default I/O vectors
asmsub VECTOR (ubyte dir @ Pc, uword userptr @ XY) clobbers(A,Y) = $FF8D ; read/set I/O vector table
asmsub SETMSG (ubyte value @ A) = $FF90 ; set Kernal message control flag
asmsub SECOND (ubyte address @ A) clobbers(A) = $FF93 ; (alias: LSTNSA) send secondary address after LISTEN
asmsub TKSA (ubyte address @ A) clobbers(A) = $FF96 ; (alias: TALKSA) send secondary address after TALK
asmsub MEMTOP (ubyte dir @ Pc, uword address @ XY) -> uword @ XY = $FF99 ; read/set top of memory pointer
asmsub MEMBOT (ubyte dir @ Pc, uword address @ XY) -> uword @ XY = $FF9C ; read/set bottom of memory pointer
asmsub SCNKEY () clobbers(A,X,Y) = $FF9F ; scan the keyboard
asmsub SETTMO (ubyte timeout @ A) = $FFA2 ; set time-out flag for IEEE bus
asmsub ACPTR () -> ubyte @ A = $FFA5 ; (alias: IECIN) input byte from serial bus
asmsub CIOUT (ubyte databyte @ A) = $FFA8 ; (alias: IECOUT) output byte to serial bus
asmsub UNTLK () clobbers(A) = $FFAB ; command serial bus device to UNTALK
asmsub UNLSN () clobbers(A) = $FFAE ; command serial bus device to UNLISTEN
asmsub LISTEN (ubyte device @ A) clobbers(A) = $FFB1 ; command serial bus device to LISTEN
asmsub TALK (ubyte device @ A) clobbers(A) = $FFB4 ; command serial bus device to TALK
asmsub READST () -> ubyte @ A = $FFB7 ; read I/O status word
asmsub SETLFS (ubyte logical @ A, ubyte device @ X, ubyte address @ Y) = $FFBA ; set logical file parameters
asmsub SETNAM (ubyte namelen @ A, str filename @ XY) = $FFBD ; set filename parameters
asmsub OPEN () clobbers(A,X,Y) = $FFC0 ; (via 794 ($31A)) open a logical file
asmsub CLOSE (ubyte logical @ A) clobbers(A,X,Y) = $FFC3 ; (via 796 ($31C)) close a logical file
asmsub CHKIN (ubyte logical @ X) clobbers(A,X) = $FFC6 ; (via 798 ($31E)) define an input channel
asmsub CHKOUT (ubyte logical @ X) clobbers(A,X) = $FFC9 ; (via 800 ($320)) define an output channel
asmsub CLRCHN () clobbers(A,X) = $FFCC ; (via 802 ($322)) restore default devices
asmsub CHRIN () clobbers(Y) -> ubyte @ A = $FFCF ; (via 804 ($324)) input a character (for keyboard, read a whole line from the screen) A=byte read.
asmsub CHROUT (ubyte char @ A) = $FFD2 ; (via 806 ($326)) output a character
asmsub LOAD (ubyte verify @ A, uword address @ XY) -> ubyte @Pc, ubyte @ A, ubyte @ X, ubyte @ Y = $FFD5 ; (via 816 ($330)) load from device
asmsub SAVE (ubyte zp_startaddr @ A, uword endaddr @ XY) -> ubyte @ Pc, ubyte @ A = $FFD8 ; (via 818 ($332)) save to a device
asmsub SETTIM (ubyte low @ A, ubyte middle @ X, ubyte high @ Y) = $FFDB ; set the software clock
asmsub RDTIM () -> ubyte @ A, ubyte @ X, ubyte @ Y = $FFDE ; read the software clock
asmsub STOP () clobbers(A,X) -> ubyte @ Pz, ubyte @ Pc = $FFE1 ; (via 808 ($328)) check the STOP key
asmsub GETIN () clobbers(X,Y) -> ubyte @ A = $FFE4 ; (via 810 ($32A)) get a character
asmsub CLALL () clobbers(A,X) = $FFE7 ; (via 812 ($32C)) close all files
asmsub UDTIM () clobbers(A,X) = $FFEA ; update the software clock
asmsub SCREEN () -> ubyte @ X, ubyte @ Y = $FFED ; read number of screen rows and columns
asmsub PLOT (ubyte dir @ Pc, ubyte col @ Y, ubyte row @ X) -> ubyte @ X, ubyte @ Y = $FFF0 ; read/set position of cursor on screen. Use c64scr.plot for a 'safe' wrapper that preserves X.
asmsub IOBASE () -> uword @ XY = $FFF3 ; read base address of I/O devices
romsub $AB1E = STROUT(uword strptr @ AY) clobbers(A, X, Y) ; print null-terminated string (use c64scr.print instead)
romsub $EA31 = IRQDFRT() clobbers(A,X,Y) ; default IRQ routine
romsub $EA81 = IRQDFEND() clobbers(A,X,Y) ; default IRQ end/cleanup
romsub $FF81 = CINT() clobbers(A,X,Y) ; (alias: SCINIT) initialize screen editor and video chip
romsub $FF84 = IOINIT() clobbers(A, X) ; initialize I/O devices (CIA, SID, IRQ)
romsub $FF87 = RAMTAS() clobbers(A,X,Y) ; initialize RAM, tape buffer, screen
romsub $FF8A = RESTOR() clobbers(A,X,Y) ; restore default I/O vectors
romsub $FF8D = VECTOR(uword userptr @ XY, ubyte dir @ Pc) clobbers(A,Y) ; read/set I/O vector table
romsub $FF90 = SETMSG(ubyte value @ A) ; set Kernal message control flag
romsub $FF93 = SECOND(ubyte address @ A) clobbers(A) ; (alias: LSTNSA) send secondary address after LISTEN
romsub $FF96 = TKSA(ubyte address @ A) clobbers(A) ; (alias: TALKSA) send secondary address after TALK
romsub $FF99 = MEMTOP(uword address @ XY, ubyte dir @ Pc) -> uword @ XY ; read/set top of memory pointer
romsub $FF9C = MEMBOT(uword address @ XY, ubyte dir @ Pc) -> uword @ XY ; read/set bottom of memory pointer
romsub $FF9F = SCNKEY() clobbers(A,X,Y) ; scan the keyboard
romsub $FFA2 = SETTMO(ubyte timeout @ A) ; set time-out flag for IEEE bus
romsub $FFA5 = ACPTR() -> ubyte @ A ; (alias: IECIN) input byte from serial bus
romsub $FFA8 = CIOUT(ubyte databyte @ A) ; (alias: IECOUT) output byte to serial bus
romsub $FFAB = UNTLK() clobbers(A) ; command serial bus device to UNTALK
romsub $FFAE = UNLSN() clobbers(A) ; command serial bus device to UNLISTEN
romsub $FFB1 = LISTEN(ubyte device @ A) clobbers(A) ; command serial bus device to LISTEN
romsub $FFB4 = TALK(ubyte device @ A) clobbers(A) ; command serial bus device to TALK
romsub $FFB7 = READST() -> ubyte @ A ; read I/O status word
romsub $FFBA = SETLFS(ubyte logical @ A, ubyte device @ X, ubyte address @ Y) ; set logical file parameters
romsub $FFBD = SETNAM(ubyte namelen @ A, str filename @ XY) ; set filename parameters
romsub $FFC0 = OPEN() clobbers(A,X,Y) ; (via 794 ($31A)) open a logical file
romsub $FFC3 = CLOSE(ubyte logical @ A) clobbers(A,X,Y) ; (via 796 ($31C)) close a logical file
romsub $FFC6 = CHKIN(ubyte logical @ X) clobbers(A,X) ; (via 798 ($31E)) define an input channel
romsub $FFC9 = CHKOUT(ubyte logical @ X) clobbers(A,X) ; (via 800 ($320)) define an output channel
romsub $FFCC = CLRCHN() clobbers(A,X) ; (via 802 ($322)) restore default devices
romsub $FFCF = CHRIN() clobbers(Y) -> ubyte @ A ; (via 804 ($324)) input a character (for keyboard, read a whole line from the screen) A=byte read.
romsub $FFD2 = CHROUT(ubyte char @ A) ; (via 806 ($326)) output a character
romsub $FFD5 = LOAD(ubyte verify @ A, uword address @ XY) -> ubyte @Pc, ubyte @ A, ubyte @ X, ubyte @ Y ; (via 816 ($330)) load from device
romsub $FFD8 = SAVE(ubyte zp_startaddr @ A, uword endaddr @ XY) -> ubyte @ Pc, ubyte @ A ; (via 818 ($332)) save to a device
romsub $FFDB = SETTIM(ubyte low @ A, ubyte middle @ X, ubyte high @ Y) ; set the software clock
romsub $FFDE = RDTIM() -> ubyte @ A, ubyte @ X, ubyte @ Y ; read the software clock
romsub $FFE1 = STOP() clobbers(A,X) -> ubyte @ Pz, ubyte @ Pc ; (via 808 ($328)) check the STOP key
romsub $FFE4 = GETIN() clobbers(X,Y) -> ubyte @ A ; (via 810 ($32A)) get a character
romsub $FFE7 = CLALL() clobbers(A,X) ; (via 812 ($32C)) close all files
romsub $FFEA = UDTIM() clobbers(A,X) ; update the software clock
romsub $FFED = SCREEN() -> ubyte @ X, ubyte @ Y ; read number of screen rows and columns
romsub $FFF0 = PLOT(ubyte col @ Y, ubyte row @ X, ubyte dir @ Pc) -> ubyte @ X, ubyte @ Y ; read/set position of cursor on screen. Use c64scr.plot for a 'safe' wrapper that preserves X.
romsub $FFF3 = IOBASE() -> uword @ XY ; read base address of I/O devices
; ---- end of C64 kernal routines ----

391
compiler/res/prog8lib/c64utils.p8
View File

@ -9,34 +9,205 @@
%import c64lib
~ c64utils {
c64utils {
const uword ESTACK_LO = $ce00
const uword ESTACK_HI = $cf00
; ----- utility functions ----
; ----- number conversions to decimal strings
asmsub ubyte2decimal (ubyte value @ A) -> ubyte @ Y, ubyte @ X, ubyte @ A {
; ---- A to decimal string in Y/X/A (100s in Y, 10s in X, 1s in A)
%asm {{
ldy #$2f
ldx #$3a
sec
- iny
sbc #100
bcs -
- dex
adc #10
bmi -
adc #$2f
rts
asmsub ubyte2decimal (ubyte value @ A) -> ubyte @ Y, ubyte @ A, ubyte @ X {
; ---- A to decimal string in Y/A/X (100s in Y, 10s in A, 1s in X)
%asm {{
ldy #uword2decimal.ASCII_0_OFFSET
bne uword2decimal.hex_try200
rts
}}
}
asmsub byte2decimal (ubyte value @ A) -> ubyte @ Y, ubyte @ X, ubyte @ A {
; ---- A (signed byte) to decimal string in Y/X/A (100s in Y, 10s in X, 1s in A)
; note: the '-' is not part of the conversion here if it's a negative number
asmsub uword2decimal (uword value @ AY) -> ubyte @Y, ubyte @A, ubyte @X {
; ---- convert 16 bit uword in A/Y to decimal
; output in uword2decimal.decTenThousands, decThousands, decHundreds, decTens, decOnes
; (these are terminated by a zero byte so they can be easily printed)
; also returns Y = 100's, A = 10's, X = 1's
%asm {{
;Convert 16 bit Hex to Decimal (0-65535) Rev 2
;By Omegamatrix Further optimizations by tepples
; routine from http://forums.nesdev.com/viewtopic.php?f=2&t=11341&start=15
;HexToDec99
; start in A
; end with A = 10's, decOnes (also in X)
;HexToDec255
; start in A
; end with Y = 100's, A = 10's, decOnes (also in X)
;HexToDec999
; start with A = high byte, Y = low byte
; end with Y = 100's, A = 10's, decOnes (also in X)
; requires 1 extra temp register on top of decOnes, could combine
; these two if HexToDec65535 was eliminated...
;HexToDec65535
; start with A/Y (low/high) as 16 bit value
; end with decTenThousand, decThousand, Y = 100's, A = 10's, decOnes (also in X)
; (irmen: I store Y and A in decHundreds and decTens too, so all of it can be easily printed)
ASCII_0_OFFSET = $30
temp = c64.SCRATCH_ZPB1 ; byte in zeropage
hexHigh = c64.SCRATCH_ZPWORD1 ; byte in zeropage
hexLow = c64.SCRATCH_ZPWORD1+1 ; byte in zeropage
HexToDec65535; SUBROUTINE
sty hexHigh ;3 @9
sta hexLow ;3 @12
tya
tax ;2 @14
lsr a ;2 @16
lsr a ;2 @18 integer divide 1024 (result 0-63)
cpx #$A7 ;2 @20 account for overflow of multiplying 24 from 43,000 ($A7F8) onward,
adc #1 ;2 @22 we can just round it to $A700, and the divide by 1024 is fine...
;at this point we have a number 1-65 that we have to times by 24,
;add to original sum, and Mod 1024 to get a remainder 0-999
sta temp ;3 @25
asl a ;2 @27
adc temp ;3 @30 x3
tay ;2 @32
lsr a ;2 @34
lsr a ;2 @36
lsr a ;2 @38
lsr a ;2 @40
lsr a ;2 @42
tax ;2 @44
tya ;2 @46
asl a ;2 @48
asl a ;2 @50
asl a ;2 @52
clc ;2 @54
adc hexLow ;3 @57
sta hexLow ;3 @60
txa ;2 @62
adc hexHigh ;3 @65
sta hexHigh ;3 @68
ror a ;2 @70
lsr a ;2 @72
tay ;2 @74 integer divide 1,000 (result 0-65)
lsr a ;2 @76 split the 1,000 and 10,000 digit
tax ;2 @78
lda ShiftedBcdTab,x ;4 @82
tax ;2 @84
rol a ;2 @86
and #$0F ;2 @88
ora #ASCII_0_OFFSET
sta decThousands ;3 @91
txa ;2 @93
lsr a ;2 @95
lsr a ;2 @97
lsr a ;2 @99
ora #ASCII_0_OFFSET
sta decTenThousands ;3 @102
lda hexLow ;3 @105
cpy temp ;3 @108
bmi _doSubtract ;2³ @110/111
beq _useZero ;2³ @112/113
adc #23 + 24 ;2 @114
_doSubtract
sbc #23 ;2 @116
sta hexLow ;3 @119
_useZero
lda hexHigh ;3 @122
sbc #0 ;2 @124
Start100s
and #$03 ;2 @126
tax ;2 @128 0,1,2,3
cmp #2 ;2 @130
rol a ;2 @132 0,2,5,7
ora #ASCII_0_OFFSET
tay ;2 @134 Y = Hundreds digit
lda hexLow ;3 @137
adc Mod100Tab,x ;4 @141 adding remainder of 256, 512, and 256+512 (all mod 100)
bcs hex_doSub200 ;2³ @143/144
hex_try200
cmp #200 ;2 @145
bcc hex_try100 ;2³ @147/148
hex_doSub200
iny ;2 @149
iny ;2 @151
sbc #200 ;2 @153
hex_try100
cmp #100 ;2 @155
bcc HexToDec99 ;2³ @157/158
iny ;2 @159
sbc #100 ;2 @161
HexToDec99; SUBROUTINE
lsr a ;2 @163
tax ;2 @165
lda ShiftedBcdTab,x ;4 @169
tax ;2 @171
rol a ;2 @173
and #$0F ;2 @175
ora #ASCII_0_OFFSET
sta decOnes ;3 @178
txa ;2 @180
lsr a ;2 @182
lsr a ;2 @184
lsr a ;2 @186
ora #ASCII_0_OFFSET
; irmen: load X with ones, and store Y and A too, for easy printing afterwards
sty decHundreds
sta decTens
ldx decOnes
rts ;6 @192 Y=hundreds, A = tens digit, X=ones digit
HexToDec999; SUBROUTINE
sty hexLow ;3 @9
jmp Start100s ;3 @12
Mod100Tab
.byte 0,56,12,56+12
ShiftedBcdTab
.byte $00,$01,$02,$03,$04,$08,$09,$0A,$0B,$0C
.byte $10,$11,$12,$13,$14,$18,$19,$1A,$1B,$1C
.byte $20,$21,$22,$23,$24,$28,$29,$2A,$2B,$2C
.byte $30,$31,$32,$33,$34,$38,$39,$3A,$3B,$3C
.byte $40,$41,$42,$43,$44,$48,$49,$4A,$4B,$4C
decTenThousands .byte 0
decThousands .byte 0
decHundreds .byte 0
decTens .byte 0
decOnes .byte 0
.byte 0 ; zero-terminate the decimal output string
}}
}
; ----- utility functions ----
asmsub byte2decimal (byte value @ A) -> ubyte @ Y, ubyte @ A, ubyte @ X {
; ---- A (signed byte) to decimal string in Y/A/X (100s in Y, 10s in A, 1s in X)
; note: if the number is negative, you have to deal with the '-' yourself!
%asm {{
cmp #0
bpl +
@ -48,7 +219,7 @@ asmsub byte2decimal (ubyte value @ A) -> ubyte @ Y, ubyte @ X, ubyte @ A {
}
asmsub ubyte2hex (ubyte value @ A) -> ubyte @ A, ubyte @ Y {
; ---- A to hex string in AY (first hex char in A, second hex char in Y)
; ---- A to hex petscii string in AY (first hex char in A, second hex char in Y)
%asm {{
stx c64.SCRATCH_ZPREGX
pha
@ -69,7 +240,6 @@ _hex_digits .text "0123456789abcdef" ; can probably be reused for other stuff as
}}
}
asmsub uword2hex (uword value @ AY) clobbers(A,Y) {
; ---- convert 16 bit uword in A/Y into 4-character hexadecimal string 'uword2hex.output' (0-terminated)
%asm {{
@ -87,92 +257,6 @@ output .text "0000", $00 ; 0-terminated output buffer (to make printing ea
}}
}
asmsub uword2bcd (uword value @ AY) clobbers(A,Y) {
; Convert an 16 bit binary value to BCD
;
; This function converts a 16 bit binary value in A/Y into a 24 bit BCD. It
; works by transferring one bit a time from the source and adding it
; into a BCD value that is being doubled on each iteration. As all the
; arithmetic is being done in BCD the result is a binary to decimal
; conversion.
%asm {{
sta c64.SCRATCH_ZPB1
sty c64.SCRATCH_ZPREG
php
pla ; read status register
and #%00000100
sta _had_irqd
sei ; disable interrupts because of bcd math
sed ; switch to decimal mode
lda #0 ; ensure the result is clear
sta bcdbuff+0
sta bcdbuff+1
sta bcdbuff+2
ldy #16 ; the number of source bits
- asl c64.SCRATCH_ZPB1 ; shift out one bit
rol c64.SCRATCH_ZPREG
lda bcdbuff+0 ; and add into result
adc bcdbuff+0
sta bcdbuff+0
lda bcdbuff+1 ; propagating any carry
adc bcdbuff+1
sta bcdbuff+1
lda bcdbuff+2 ; ... thru whole result
adc bcdbuff+2
sta bcdbuff+2
dey ; and repeat for next bit
bne -
cld ; back to binary
lda _had_irqd
bne +
cli ; enable interrupts again (only if they were enabled before)
+ rts
_had_irqd .byte 0
bcdbuff .byte 0,0,0
}}
}
asmsub uword2decimal (uword value @ AY) clobbers(A) -> ubyte @ Y {
; ---- convert 16 bit uword in A/Y into 0-terminated decimal string into memory 'uword2decimal.output'
; returns length of resulting string in Y
%asm {{
jsr uword2bcd
lda uword2bcd.bcdbuff+2
clc
adc #'0'
sta output
ldy #1
lda uword2bcd.bcdbuff+1
jsr +
lda uword2bcd.bcdbuff+0
+ pha
lsr a
lsr a
lsr a
lsr a
clc
adc #'0'
sta output,y
iny
pla
and #$0f
adc #'0'
sta output,y
iny
lda #0
sta output,y
rts
output .text "00000", $00 ; 0 terminated
}}
}
asmsub str2uword(str string @ AY) -> uword @ AY {
; -- 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
@ -227,7 +311,6 @@ _result_times_10 ; (W*4 + W)*2
}}
}
asmsub str2word(str string @ AY) -> word @ AY {
; -- 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
@ -283,7 +366,6 @@ _negative .byte 0
}}
}
asmsub set_irqvec_excl() clobbers(A) {
%asm {{
sei
@ -341,6 +423,7 @@ _irq_handler_init
dex
dex
dex
cld
rts
_irq_handler_end
@ -372,7 +455,6 @@ IRQ_SCRATCH_ZPWORD2 .word 0
}}
}
asmsub restore_irqvec() {
%asm {{
sei
@ -389,7 +471,6 @@ asmsub restore_irqvec() {
}}
}
asmsub set_rasterirq(uword rasterpos @ AY) clobbers(A) {
%asm {{
sei
@ -454,14 +535,12 @@ _raster_irq_handler
}
} ; ------ end of block c64utils
~ c64scr {
c64scr {
; ---- this block contains (character) Screen and text I/O related functions ----
@ -480,7 +559,6 @@ asmsub clear_screen (ubyte char @ A, ubyte color @ Y) clobbers(A) {
}
asmsub clear_screenchars (ubyte char @ A) clobbers(Y) {
; ---- clear the character screen with the given fill character (leaves colors)
; (assumes screen matrix is at the default address)
@ -521,7 +599,6 @@ _loop sta c64.Colors,y
}}
}
asmsub scroll_left_full (ubyte alsocolors @ Pc) clobbers(A, Y) {
; ---- scroll the whole screen 1 character to the left
; contents of the rightmost column are unchanged, you should clear/refill this yourself
@ -582,7 +659,6 @@ _scroll_screen ; scroll the screen memory
}}
}
asmsub scroll_right_full (ubyte alsocolors @ Pc) clobbers(A) {
; ---- scroll the whole screen 1 character to the right
; contents of the leftmost column are unchanged, you should clear/refill this yourself
@ -635,7 +711,6 @@ _scroll_screen ; scroll the screen memory
}}
}
asmsub scroll_up_full (ubyte alsocolors @ Pc) clobbers(A) {
; ---- scroll the whole screen 1 character up
; contents of the bottom row are unchanged, you should refill/clear this yourself
@ -688,7 +763,6 @@ _scroll_screen ; scroll the screen memory
}}
}
asmsub scroll_down_full (ubyte alsocolors @ Pc) clobbers(A) {
; ---- scroll the whole screen 1 character down
; contents of the top row are unchanged, you should refill/clear this yourself
@ -742,7 +816,6 @@ _scroll_screen ; scroll the screen memory
}
asmsub print (str text @ AY) clobbers(A,Y) {
; ---- print null terminated string from A/Y
; note: the compiler contains an optimization that will replace
@ -761,7 +834,6 @@ asmsub print (str text @ AY) clobbers(A,Y) {
}}
}
asmsub print_ub0 (ubyte value @ A) clobbers(A,Y) {
; ---- print the ubyte in A in decimal form, with left padding 0s (3 positions total)
%asm {{
@ -770,16 +842,15 @@ asmsub print_ub0 (ubyte value @ A) clobbers(A,Y) {
pha
tya
jsr c64.CHROUT
txa
jsr c64.CHROUT
pla
jsr c64.CHROUT
txa
jsr c64.CHROUT
ldx c64.SCRATCH_ZPREGX
rts
}}
}
asmsub print_ub (ubyte value @ A) clobbers(A,Y) {
; ---- print the ubyte in A in decimal form, without left padding 0s
%asm {{
@ -788,15 +859,14 @@ asmsub print_ub (ubyte value @ A) clobbers(A,Y) {
_print_byte_digits
pha
cpy #'0'
bne _print_hundreds
cpx #'0'
bne _print_tens
jmp _end
_print_hundreds tya
beq +
tya
jsr c64.CHROUT
_print_tens txa
jsr c64.CHROUT
_end pla
+ pla
cmp #'0'
beq +
jsr c64.CHROUT
+ txa
jsr c64.CHROUT
ldx c64.SCRATCH_ZPREGX
rts
@ -820,8 +890,7 @@ asmsub print_b (byte value @ A) clobbers(A,Y) {
}}
}
asmsub print_ubhex (ubyte prefix @ Pc, ubyte value @ A) clobbers(A,Y) {
asmsub print_ubhex (ubyte value @ A, ubyte prefix @ Pc) clobbers(A,Y) {
; ---- print the ubyte in A in hex form (if Carry is set, a radix prefix '$' is printed as well)
%asm {{
stx c64.SCRATCH_ZPREGX
@ -839,8 +908,7 @@ asmsub print_ubhex (ubyte prefix @ Pc, ubyte value @ A) clobbers(A,Y) {
}}
}
asmsub print_ubbin (ubyte prefix @ Pc, ubyte value @ A) clobbers(A,Y) {
asmsub print_ubbin (ubyte value @ A, ubyte prefix @ Pc) clobbers(A,Y) {
; ---- print the ubyte in A in binary form (if Carry is set, a radix prefix '%' is printed as well)
%asm {{
stx c64.SCRATCH_ZPREGX
@ -861,8 +929,7 @@ asmsub print_ubbin (ubyte prefix @ Pc, ubyte value @ A) clobbers(A,Y) {
}}
}
asmsub print_uwbin (ubyte prefix @ Pc, uword value @ AY) clobbers(A,Y) {
asmsub print_uwbin (uword value @ AY, ubyte prefix @ Pc) clobbers(A,Y) {
; ---- print the uword in A/Y in binary form (if Carry is set, a radix prefix '%' is printed as well)
%asm {{
pha
@ -874,8 +941,7 @@ asmsub print_uwbin (ubyte prefix @ Pc, uword value @ AY) clobbers(A,Y) {
}}
}
asmsub print_uwhex (ubyte prefix @ Pc, uword value @ AY) clobbers(A,Y) {
asmsub print_uwhex (uword value @ AY, ubyte prefix @ Pc) clobbers(A,Y) {
; ---- print the uword in A/Y in hexadecimal form (4 digits)
; (if Carry is set, a radix prefix '$' is printed as well)
%asm {{
@ -888,51 +954,44 @@ asmsub print_uwhex (ubyte prefix @ Pc, uword value @ AY) clobbers(A,Y) {
}}
}
asmsub print_uw0 (uword value @ AY) clobbers(A,Y) {
; ---- print the uword in A/Y in decimal form, with left padding 0s (5 positions total)
%asm {{
stx c64.SCRATCH_ZPREGX
jsr c64utils.uword2decimal
ldy #0
- lda c64utils.uword2decimal.output,y
- lda c64utils.uword2decimal.decTenThousands,y
beq +
jsr c64.CHROUT
iny
cpy #5
bne -
+ ldx c64.SCRATCH_ZPREGX
rts
}}
}
asmsub print_uw (uword value @ AY) clobbers(A,Y) {
; ---- print the uword in A/Y in decimal form, without left padding 0s
%asm {{
stx c64.SCRATCH_ZPREGX
jsr c64utils.uword2decimal
ldy #0
lda c64utils.uword2decimal.output
- lda c64utils.uword2decimal.decTenThousands,y
beq _allzero
cmp #'0'
bne _pr_decimal
iny
lda c64utils.uword2decimal.output+1
cmp #'0'
bne _pr_decimal
iny
lda c64utils.uword2decimal.output+2
cmp #'0'
bne _pr_decimal
iny
lda c64utils.uword2decimal.output+3
cmp #'0'
bne _pr_decimal
bne _gotdigit
iny
bne -
_pr_decimal
lda c64utils.uword2decimal.output,y
_gotdigit
jsr c64.CHROUT
iny
cpy #5
bcc _pr_decimal
lda c64utils.uword2decimal.decTenThousands,y
bne _gotdigit
rts
_allzero
lda #'0'
jmp c64.CHROUT
}}
}
@ -1063,7 +1122,7 @@ _mod lda $ffff ; modified
sub setcc (ubyte column, ubyte row, ubyte char, ubyte color) {
; ---- set char+color at the given position on the screen
%asm {{
lda setcc_row
lda row
asl a
tay
lda setchr._screenrows+1,y
@ -1072,15 +1131,15 @@ sub setcc (ubyte column, ubyte row, ubyte char, ubyte color) {
sta _colormod+2
lda setchr._screenrows,y
clc
adc setcc_column
adc column
sta _charmod+1
sta _colormod+1
bcc +
inc _charmod+2
inc _colormod+2
+ lda setcc_char
+ lda char
_charmod sta $ffff ; modified
lda setcc_color
lda color
_colormod sta $ffff ; modified
rts
}}

37
compiler/res/prog8lib/math.asm
View File

@ -643,3 +643,40 @@ mul_word_40 .proc
sta c64.ESTACK_HI+1,x
rts
.pend
sign_b .proc
lda c64.ESTACK_LO+1,x
beq _sign_zero
bmi _sign_neg
_sign_pos lda #1
sta c64.ESTACK_LO+1,x
rts
_sign_neg lda #-1
_sign_zero sta c64.ESTACK_LO+1,x
rts
.pend
sign_ub .proc
lda c64.ESTACK_LO+1,x
beq sign_b._sign_zero
bne sign_b._sign_pos
.pend
sign_w .proc
lda c64.ESTACK_HI+1,x
bmi sign_b._sign_neg
beq sign_ub
bne sign_b._sign_pos
.pend
sign_uw .proc
lda c64.ESTACK_HI+1,x
beq _sign_possibly_zero
_sign_pos lda #1
sta c64.ESTACK_LO+1,x
rts
_sign_possibly_zero lda c64.ESTACK_LO+1,x
bne _sign_pos
sta c64.ESTACK_LO+1,x
rts
.pend

2
compiler/res/prog8lib/math.p8
View File

@ -6,6 +6,6 @@
%import c64lib
~ math {
math {
%asminclude "library:math.asm", ""
}

483
compiler/res/prog8lib/prog8lib.asm
View File

@ -36,6 +36,17 @@ init_system .proc
.pend
read_byte_from_address .proc
; -- read the byte from the memory address on the top of the stack, return in A (stack remains unchanged)
lda c64.ESTACK_LO+1,x
ldy c64.ESTACK_HI+1,x
sta (+) +1
sty (+) +2
+ lda $ffff ; modified
rts
.pend
add_a_to_zpword .proc
; -- add ubyte in A to the uword in c64.SCRATCH_ZPWORD1
clc
@ -705,7 +716,7 @@ func_sin8 .proc
lda _sinecos8,y
sta c64.ESTACK_LO+1,x
rts
_sinecos8 .char 127 * sin(range(256+64) * rad(360.0/256.0))
_sinecos8 .char trunc(127.0 * sin(range(256+64) * rad(360.0/256.0)))
.pend
func_sin8u .proc
@ -713,7 +724,7 @@ func_sin8u .proc
lda _sinecos8u,y
sta c64.ESTACK_LO+1,x
rts
_sinecos8u .byte 128 + 127.5 * sin(range(256+64) * rad(360.0/256.0))
_sinecos8u .byte trunc(128.0 + 127.5 * sin(range(256+64) * rad(360.0/256.0)))
.pend
func_sin16 .proc
@ -724,7 +735,7 @@ func_sin16 .proc
sta c64.ESTACK_HI+1,x
rts
_ := 32767 * sin(range(256+64) * rad(360.0/256.0))
_ := trunc(32767.0 * sin(range(256+64) * rad(360.0/256.0)))
_sinecos8lo .byte <_
_sinecos8hi .byte >_
.pend
@ -737,7 +748,7 @@ func_sin16u .proc
sta c64.ESTACK_HI+1,x
rts
_ := 32768 + 32767.5 * sin(range(256+64) * rad(360.0/256.0))
_ := trunc(32768.0 + 32767.5 * sin(range(256+64) * rad(360.0/256.0)))
_sinecos8ulo .byte <_
_sinecos8uhi .byte >_
.pend
@ -840,11 +851,12 @@ func_all_w .proc
bne +
iny
lda (c64.SCRATCH_ZPWORD1),y
bne +
bne ++
lda #0
sta c64.ESTACK_LO+1,x
rts
+ iny
+ iny
_cmp_mod cpy #255 ; modified
bne -
lda #1
@ -1372,3 +1384,464 @@ _mod2b lda #0 ; self-modified
_done rts
.pend
sort_ub .proc
; 8bit unsigned sort
; sorting subroutine coded by mats rosengren (mats.rosengren@esa.int)
; input: address of array to sort in c64.SCRATCH_ZPWORD1, length in c64.SCRATCH_ZPB1
; first, put pointer BEFORE array
lda c64.SCRATCH_ZPWORD1
bne +
dec c64.SCRATCH_ZPWORD1+1
+ dec c64.SCRATCH_ZPWORD1
_sortloop ldy c64.SCRATCH_ZPB1 ;start of subroutine sort
lda (c64.SCRATCH_ZPWORD1),y ;last value in (what is left of) sequence to be sorted
sta c64.SCRATCH_ZPREG ;save value. will be over-written by largest number
jmp _l2
_l1 dey
beq _l3
lda (c64.SCRATCH_ZPWORD1),y
cmp c64.SCRATCH_ZPWORD2+1
bcc _l1
_l2 sty c64.SCRATCH_ZPWORD2 ;index of potentially largest value
sta c64.SCRATCH_ZPWORD2+1 ;potentially largest value
jmp _l1
_l3 ldy c64.SCRATCH_ZPB1 ;where the largest value shall be put
lda c64.SCRATCH_ZPWORD2+1 ;the largest value
sta (c64.SCRATCH_ZPWORD1),y ;put largest value in place
ldy c64.SCRATCH_ZPWORD2 ;index of free space
lda c64.SCRATCH_ZPREG ;the over-written value
sta (c64.SCRATCH_ZPWORD1),y ;put the over-written value in the free space
dec c64.SCRATCH_ZPB1 ;end of the shorter sequence still left
bne _sortloop ;start working with the shorter sequence
rts
.pend
sort_b .proc
; 8bit signed sort
; sorting subroutine coded by mats rosengren (mats.rosengren@esa.int)
; input: address of array to sort in c64.SCRATCH_ZPWORD1, length in c64.SCRATCH_ZPB1
; first, put pointer BEFORE array
lda c64.SCRATCH_ZPWORD1
bne +
dec c64.SCRATCH_ZPWORD1+1
+ dec c64.SCRATCH_ZPWORD1
_sortloop ldy c64.SCRATCH_ZPB1 ;start of subroutine sort
lda (c64.SCRATCH_ZPWORD1),y ;last value in (what is left of) sequence to be sorted
sta c64.SCRATCH_ZPREG ;save value. will be over-written by largest number
jmp _l2
_l1 dey
beq _l3
lda (c64.SCRATCH_ZPWORD1),y
cmp c64.SCRATCH_ZPWORD2+1
bmi _l1
_l2 sty c64.SCRATCH_ZPWORD2 ;index of potentially largest value
sta c64.SCRATCH_ZPWORD2+1 ;potentially largest value
jmp _l1
_l3 ldy c64.SCRATCH_ZPB1 ;where the largest value shall be put
lda c64.SCRATCH_ZPWORD2+1 ;the largest value
sta (c64.SCRATCH_ZPWORD1),y ;put largest value in place
ldy c64.SCRATCH_ZPWORD2 ;index of free space
lda c64.SCRATCH_ZPREG ;the over-written value
sta (c64.SCRATCH_ZPWORD1),y ;put the over-written value in the free space
dec c64.SCRATCH_ZPB1 ;end of the shorter sequence still left
bne _sortloop ;start working with the shorter sequence
rts
.pend
sort_uw .proc
; 16bit unsigned sort
; sorting subroutine coded by mats rosengren (mats.rosengren@esa.int)
; input: address of array to sort in c64.SCRATCH_ZPWORD1, length in c64.SCRATCH_ZPB1
; first: subtract 2 of the pointer
asl c64.SCRATCH_ZPB1 ; *2 because words
lda c64.SCRATCH_ZPWORD1
sec
sbc #2
sta c64.SCRATCH_ZPWORD1
bcs _sort_loop
dec c64.SCRATCH_ZPWORD1+1
_sort_loop ldy c64.SCRATCH_ZPB1 ;start of subroutine sort
lda (c64.SCRATCH_ZPWORD1),y ;last value in (what is left of) sequence to be sorted
sta _work3 ;save value. will be over-written by largest number
iny
lda (c64.SCRATCH_ZPWORD1),y
sta _work3+1
dey
jmp _l2
_l1 dey
dey
beq _l3
iny
lda (c64.SCRATCH_ZPWORD1),y
dey
cmp c64.SCRATCH_ZPWORD2+1
bne +
lda (c64.SCRATCH_ZPWORD1),y
cmp c64.SCRATCH_ZPWORD2
+ bcc _l1
_l2 sty _work1 ;index of potentially largest value
lda (c64.SCRATCH_ZPWORD1),y
sta c64.SCRATCH_ZPWORD2 ;potentially largest value
iny
lda (c64.SCRATCH_ZPWORD1),y
sta c64.SCRATCH_ZPWORD2+1
dey
jmp _l1
_l3 ldy c64.SCRATCH_ZPB1 ;where the largest value shall be put
lda c64.SCRATCH_ZPWORD2 ;the largest value
sta (c64.SCRATCH_ZPWORD1),y ;put largest value in place
iny
lda c64.SCRATCH_ZPWORD2+1
sta (c64.SCRATCH_ZPWORD1),y
ldy _work1 ;index of free space
lda _work3 ;the over-written value
sta (c64.SCRATCH_ZPWORD1),y ;put the over-written value in the free space
iny
lda _work3+1
sta (c64.SCRATCH_ZPWORD1),y
dey
dec c64.SCRATCH_ZPB1 ;end of the shorter sequence still left
dec c64.SCRATCH_ZPB1
bne _sort_loop ;start working with the shorter sequence
rts
_work1 .byte 0
_work3 .word 0
.pend
sort_w .proc
; 16bit signed sort
; sorting subroutine coded by mats rosengren (mats.rosengren@esa.int)
; input: address of array to sort in c64.SCRATCH_ZPWORD1, length in c64.SCRATCH_ZPB1
; first: subtract 2 of the pointer
asl c64.SCRATCH_ZPB1 ; *2 because words
lda c64.SCRATCH_ZPWORD1
sec
sbc #2
sta c64.SCRATCH_ZPWORD1
bcs _sort_loop
dec c64.SCRATCH_ZPWORD1+1
_sort_loop ldy c64.SCRATCH_ZPB1 ;start of subroutine sort
lda (c64.SCRATCH_ZPWORD1),y ;last value in (what is left of) sequence to be sorted
sta _work3 ;save value. will be over-written by largest number
iny
lda (c64.SCRATCH_ZPWORD1),y
sta _work3+1
dey
jmp _l2
_l1 dey
dey
beq _l3
lda (c64.SCRATCH_ZPWORD1),y
cmp c64.SCRATCH_ZPWORD2
iny
lda (c64.SCRATCH_ZPWORD1),y
dey
sbc c64.SCRATCH_ZPWORD2+1
bvc +
eor #$80
+ bmi _l1
_l2 sty _work1 ;index of potentially largest value
lda (c64.SCRATCH_ZPWORD1),y
sta c64.SCRATCH_ZPWORD2 ;potentially largest value
iny
lda (c64.SCRATCH_ZPWORD1),y
sta c64.SCRATCH_ZPWORD2+1
dey
jmp _l1
_l3 ldy c64.SCRATCH_ZPB1 ;where the largest value shall be put
lda c64.SCRATCH_ZPWORD2 ;the largest value
sta (c64.SCRATCH_ZPWORD1),y ;put largest value in place
iny
lda c64.SCRATCH_ZPWORD2+1
sta (c64.SCRATCH_ZPWORD1),y
ldy _work1 ;index of free space
lda _work3 ;the over-written value
sta (c64.SCRATCH_ZPWORD1),y ;put the over-written value in the free space
iny
lda _work3+1
sta (c64.SCRATCH_ZPWORD1),y
dey
dec c64.SCRATCH_ZPB1 ;end of the shorter sequence still left
dec c64.SCRATCH_ZPB1
bne _sort_loop ;start working with the shorter sequence
rts
_work1 .byte 0
_work3 .word 0
.pend
reverse_b .proc
; --- reverse an array of bytes (in-place)
; inputs: pointer to array in c64.SCRATCH_ZPWORD1, length in A
_index_right = c64.SCRATCH_ZPWORD2
_index_left = c64.SCRATCH_ZPWORD2+1
_loop_count = c64.SCRATCH_ZPREG
sta _loop_count
lsr _loop_count
sec
sbc #1
sta _index_right
lda #0
sta _index_left
_loop ldy _index_right
lda (c64.SCRATCH_ZPWORD1),y
pha
ldy _index_left
lda (c64.SCRATCH_ZPWORD1),y
ldy _index_right
sta (c64.SCRATCH_ZPWORD1),y
pla
ldy _index_left
sta (c64.SCRATCH_ZPWORD1),y
inc _index_left
dec _index_right
dec _loop_count
bne _loop
rts
.pend
reverse_f .proc
; --- reverse an array of floats
_left_index = c64.SCRATCH_ZPWORD2
_right_index = c64.SCRATCH_ZPWORD2+1
_loop_count = c64.SCRATCH_ZPREG
pha
sta c64.SCRATCH_ZPREG
asl a
asl a
clc
adc c64.SCRATCH_ZPREG ; *5 because float
sec
sbc #5
sta _right_index
lda #0
sta _left_index
pla
lsr a
sta _loop_count
_loop ; push the left indexed float on the stack
ldy _left_index
lda (c64.SCRATCH_ZPWORD1),y
pha
iny
lda (c64.SCRATCH_ZPWORD1),y
pha
iny
lda (c64.SCRATCH_ZPWORD1),y
pha
iny
lda (c64.SCRATCH_ZPWORD1),y
pha
iny
lda (c64.SCRATCH_ZPWORD1),y
pha
; copy right index float to left index float
ldy _right_index
lda (c64.SCRATCH_ZPWORD1),y
ldy _left_index
sta (c64.SCRATCH_ZPWORD1),y
inc _left_index
inc _right_index
ldy _right_index
lda (c64.SCRATCH_ZPWORD1),y
ldy _left_index
sta (c64.SCRATCH_ZPWORD1),y
inc _left_index
inc _right_index
ldy _right_index
lda (c64.SCRATCH_ZPWORD1),y
ldy _left_index
sta (c64.SCRATCH_ZPWORD1),y
inc _left_index
inc _right_index
ldy _right_index
lda (c64.SCRATCH_ZPWORD1),y
ldy _left_index
sta (c64.SCRATCH_ZPWORD1),y
inc _left_index
inc _right_index
ldy _right_index
lda (c64.SCRATCH_ZPWORD1),y
ldy _left_index
sta (c64.SCRATCH_ZPWORD1),y
; pop the float off the stack into the right index float
ldy _right_index
pla
sta (c64.SCRATCH_ZPWORD1),y
dey
pla
sta (c64.SCRATCH_ZPWORD1),y
dey
pla
sta (c64.SCRATCH_ZPWORD1),y
dey
pla
sta (c64.SCRATCH_ZPWORD1),y
dey
pla
sta (c64.SCRATCH_ZPWORD1),y
inc _left_index
lda _right_index
sec
sbc #9
sta _right_index
dec _loop_count
bne _loop
rts
.pend
reverse_w .proc
; --- reverse an array of words (in-place)
; inputs: pointer to array in c64.SCRATCH_ZPWORD1, length in A
_index_first = c64.SCRATCH_ZPWORD2
_index_second = c64.SCRATCH_ZPWORD2+1
_loop_count = c64.SCRATCH_ZPREG
pha
asl a ; *2 because words
sec
sbc #2
sta _index_first
lda #0
sta _index_second
pla
lsr a
pha
sta _loop_count
; first reverse the lsbs
_loop_lo ldy _index_first
lda (c64.SCRATCH_ZPWORD1),y
pha
ldy _index_second
lda (c64.SCRATCH_ZPWORD1),y
ldy _index_first
sta (c64.SCRATCH_ZPWORD1),y
pla
ldy _index_second
sta (c64.SCRATCH_ZPWORD1),y
inc _index_second
inc _index_second
dec _index_first
dec _index_first
dec _loop_count
bne _loop_lo
; now reverse the msbs
dec _index_second
inc _index_first
inc _index_first
inc _index_first
pla
sta _loop_count
_loop_hi ldy _index_first
lda (c64.SCRATCH_ZPWORD1),y
pha
ldy _index_second
lda (c64.SCRATCH_ZPWORD1),y
ldy _index_first
sta (c64.SCRATCH_ZPWORD1),y
pla
ldy _index_second
sta (c64.SCRATCH_ZPWORD1),y
dec _index_second
dec _index_second
inc _index_first
inc _index_first
dec _loop_count
bne _loop_hi
rts
.pend
ror2_mem_ub .proc
; -- in-place 8-bit ror of byte at memory location on stack
inx
lda c64.ESTACK_LO,x
sta c64.SCRATCH_ZPWORD1
lda c64.ESTACK_HI,x
sta c64.SCRATCH_ZPWORD1+1
ldy #0
lda (c64.SCRATCH_ZPWORD1),y
lsr a
bcc +
ora #$80
+ sta (c64.SCRATCH_ZPWORD1),y
rts
.pend
rol2_mem_ub .proc
; -- in-place 8-bit rol of byte at memory location on stack
;" lda ${number.toHex()} | cmp #\$80 | rol a | sta ${number.toHex()}"
inx
lda c64.ESTACK_LO,x
sta c64.SCRATCH_ZPWORD1
lda c64.ESTACK_HI,x
sta c64.SCRATCH_ZPWORD1+1
ldy #0
lda (c64.SCRATCH_ZPWORD1),y
cmp #$80
rol a
sta (c64.SCRATCH_ZPWORD1),y
rts
.pend
lsl_array_b .proc
.warn "lsl_array_b" ; TODO
.pend
lsl_array_w .proc
.warn "lsl_array_w" ; TODO
.pend
lsr_array_ub .proc
.warn "lsr_array_ub" ; TODO
.pend
lsr_array_b .proc
.warn "lsr_array_b" ; TODO
.pend
lsr_array_uw .proc
.warn "lsr_array_uw" ; TODO
.pend
lsr_array_w .proc
.warn "lsr_array_w" ; TODO
.pend
rol_array_ub .proc
.warn "rol_array_ub" ; TODO
.pend
rol_array_uw .proc
.warn "rol_array_uw" ; TODO
.pend
rol2_array_ub .proc
.warn "rol2_array_ub" ; TODO
.pend
rol2_array_uw .proc
.warn "rol2_array_uw" ; TODO
.pend
ror_array_ub .proc
.warn "ror_array_ub" ; TODO
.pend
ror_array_uw .proc
.warn "ror_array_uw" ; TODO
.pend
ror2_array_ub .proc
.warn "ror2_array_ub" ; TODO
.pend
ror2_array_uw .proc
.warn "ror2_array_uw" ; TODO
.pend

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

@ -6,6 +6,6 @@
%import c64lib
~ prog8_lib {
prog8_lib {
%asminclude "library:prog8lib.asm", ""
}

2
compiler/res/version.txt
View File

@ -1 +1 @@
1.9
1.80

204
compiler/src/prog8/CompilerMain.kt
View File

@ -1,25 +1,25 @@
package prog8
import prog8.vm.astvm.AstVm
import prog8.vm.stackvm.stackVmMain
import kotlinx.cli.*
import prog8.ast.base.AstException
import prog8.compiler.*
import java.nio.file.Paths
import prog8.compiler.target.CompilationTarget
import prog8.compiler.target.c64.C64MachineDefinition
import prog8.compiler.target.c64.Petscii
import prog8.compiler.target.c64.codegen.AsmGen
import prog8.parser.ParsingFailedError
import prog8.vm.astvm.AstVm
import java.io.IOException
import java.nio.file.FileSystems
import java.nio.file.Path
import java.nio.file.StandardWatchEventKinds
import java.time.LocalDateTime
import kotlin.system.exitProcess
fun main(args: Array<String>) {
// check if the user wants to launch the VM instead
if("-vm" in args) {
val newArgs = args.toMutableList()
newArgs.remove("-vm")
return stackVmMain(newArgs.toTypedArray())
}
printSoftwareHeader("compiler")
if (args.isEmpty())
usage()
compileMain(args)
}
@ -30,72 +30,126 @@ internal fun printSoftwareHeader(what: String) {
}
fun pathFrom(stringPath: String, vararg rest: String): Path = FileSystems.getDefault().getPath(stringPath, *rest)
private fun compileMain(args: Array<String>) {
var emulatorToStart = ""
var moduleFile = ""
var writeVmCode = false
var writeAssembly = true
var optimize = true
var optimizeInlining = true
var launchAstVm = false
for (arg in args) {
if(arg=="-emu")
emulatorToStart = "x64"
else if(arg=="-emu2")
emulatorToStart = "x64sc"
else if(arg=="-writevm")
writeVmCode = true
else if(arg=="-noasm")
writeAssembly = false
else if(arg=="-noopt")
optimize = false
else if(arg=="-nooptinline")
optimizeInlining = false
else if(arg=="-avm")
launchAstVm = true
else if(!arg.startsWith("-"))
moduleFile = arg
else
usage()
}
if(moduleFile.isBlank())
usage()
val cli = CommandLineInterface("prog8compiler")
val startEmulator by cli.flagArgument("-emu", "auto-start the Vice C-64 emulator after successful compilation")
val outputDir by cli.flagValueArgument("-out", "directory", "directory for output files instead of current directory", ".")
val dontWriteAssembly by cli.flagArgument("-noasm", "don't create assembly code")
val dontOptimize by cli.flagArgument("-noopt", "don't perform any optimizations")
val launchSimulator by cli.flagArgument("-sim", "launch the builtin execution simulator after compilation")
val watchMode by cli.flagArgument("-watch", "continuous compilation mode (watches for file changes), greatly increases compilation speed")
val compilationTarget by cli.flagValueArgument("-target", "compilertarget", "target output of the compiler, currently only 'c64' (C64 6502 assembly) available", "c64")
val moduleFiles by cli.positionalArgumentsList("modules", "main module file(s) to compile", minArgs = 1)
val filepath = Paths.get(moduleFile).normalize()
val (programAst, programName) = compileProgram(filepath, optimize, optimizeInlining,
!launchAstVm, writeVmCode, writeAssembly)
if(launchAstVm) {
println("\nLaunching AST-based vm...")
val vm = AstVm(programAst)
vm.run()
try {
cli.parse(args)
} catch (e: Exception) {
exitProcess(1)
}
if(emulatorToStart.isNotEmpty()) {
if(programName==null)
println("\nCan't start emulator because no program was assembled.")
else {
println("\nStarting C-64 emulator $emulatorToStart...")
val cmdline = listOf(emulatorToStart, "-silent", "-moncommands", "$programName.vice-mon-list",
"-autostartprgmode", "1", "-autostart-warp", "-autostart", programName + ".prg")
val process = ProcessBuilder(cmdline).inheritIO().start()
process.waitFor()
when(compilationTarget) {
"c64" -> {
with(CompilationTarget) {
name = "c64"
machine = C64MachineDefinition
encodeString = { str, altEncoding ->
if(altEncoding) Petscii.encodeScreencode(str, true) else Petscii.encodePetscii(str, true)
}
decodeString = { bytes, altEncoding ->
if(altEncoding) Petscii.decodeScreencode(bytes, true) else Petscii.decodePetscii(bytes, true)
}
asmGenerator = ::AsmGen
}
}
else -> {
System.err.println("invalid compilation target")
exitProcess(1)
}
}
val outputPath = pathFrom(outputDir)
if(!outputPath.toFile().isDirectory) {
System.err.println("Output path doesn't exist")
exitProcess(1)
}
if(watchMode && moduleFiles.size<=1) {
val watchservice = FileSystems.getDefault().newWatchService()
while(true) {
val filepath = pathFrom(moduleFiles.single()).normalize()
println("Continuous watch mode active. Main module: $filepath")
try {
val compilationResult = compileProgram(filepath, !dontOptimize, !dontWriteAssembly, outputDir=outputPath)
println("Imported files (now watching:)")
for (importedFile in compilationResult.importedFiles) {
print(" ")
println(importedFile)
importedFile.parent.register(watchservice, StandardWatchEventKinds.ENTRY_MODIFY)
}
println("[${LocalDateTime.now().withNano(0)}] Waiting for file changes.")
val event = watchservice.take()
for(changed in event.pollEvents()) {
val changedPath = changed.context() as Path
println(" change detected: $changedPath")
}
event.reset()
println("\u001b[H\u001b[2J") // clear the screen
} catch (x: Exception) {
throw x
}
}
} else {
for(filepathRaw in moduleFiles) {
val filepath = pathFrom(filepathRaw).normalize()
val compilationResult: CompilationResult
try {
compilationResult = compileProgram(filepath, !dontOptimize, !dontWriteAssembly, outputDir=outputPath)
if(!compilationResult.success)
exitProcess(1)
} catch (x: ParsingFailedError) {
exitProcess(1)
} catch (x: AstException) {
exitProcess(1)
}
if (launchSimulator) {
// val c64 = razorvine.c64emu.C64Machine("C64 emulator launched from Prog8 compiler")
// c64.cpu.addBreakpoint(0xea31) { cpu, address ->
// println("zz")
// Cpu6502.BreakpointResultAction()
// }
// c64.start()
println("\nLaunching AST-based simulator...")
val vm = AstVm(compilationResult.programAst, compilationTarget)
vm.run()
}
if (startEmulator) {
if (compilationResult.programName.isEmpty())
println("\nCan't start emulator because no program was assembled.")
else if(startEmulator) {
for(emulator in listOf("x64sc", "x64")) {
println("\nStarting C-64 emulator $emulator...")
val cmdline = listOf(emulator, "-silent", "-moncommands", "${compilationResult.programName}.vice-mon-list",
"-autostartprgmode", "1", "-autostart-warp", "-autostart", compilationResult.programName + ".prg")
val processb = ProcessBuilder(cmdline).inheritIO()
val process: Process
try {
process=processb.start()
} catch(x: IOException) {
continue // try the next emulator executable
}
process.waitFor()
break
}
}
}
}
}
}
private fun usage() {
System.err.println("Missing argument(s):")
System.err.println(" [-emu] auto-start the 'x64' C-64 emulator after successful compilation")
System.err.println(" [-emu2] auto-start the 'x64sc' C-64 emulator after successful compilation")
System.err.println(" [-writevm] write intermediate vm code to a file as well")
System.err.println(" [-noasm] don't create assembly code")
System.err.println(" [-vm] launch the prog8 virtual machine instead of the compiler")
System.err.println(" [-avm] launch the prog8 ast-based virtual machine after compilation")
System.err.println(" [-noopt] don't perform any optimizations")
System.err.println(" [-nooptinline] don't perform subroutine inlining optimizations")
System.err.println(" modulefile main module file to compile")
exitProcess(1)
}

149
compiler/src/prog8/compiler/AstToSourceCode.kt → compiler/src/prog8/ast/AstToSourceCode.kt
View File

@ -1,22 +1,21 @@
package prog8.compiler
package prog8.ast
import prog8.ast.antlr.escape
import prog8.ast.IFunctionCall
import prog8.ast.IStatement
import prog8.ast.Module
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.base.DataType
import prog8.ast.base.NumericDatatypes
import prog8.ast.base.VarDeclType
import prog8.ast.expressions.*
import prog8.ast.processing.IAstVisitor
import prog8.ast.statements.*
import prog8.compiler.toHex
class AstToSourceCode(val output: (text: String) -> Unit): IAstVisitor {
var scopelevel = 0
class AstToSourceCode(val output: (text: String) -> Unit, val program: Program): IAstVisitor {
private var scopelevel = 0
fun indent(s: String) = " ".repeat(scopelevel) + s
fun outputln(text: String) = output(text + "\n")
fun outputlni(s: Any) = outputln(indent(s.toString()))
fun outputi(s: Any) = output(indent(s.toString()))
private fun indent(s: String) = " ".repeat(scopelevel) + s
private fun outputln(text: String) = output(text + "\n")
private fun outputlni(s: Any) = outputln(indent(s.toString()))
private fun outputi(s: Any) = output(indent(s.toString()))
override fun visit(program: Program) {
outputln("============= PROGRAM ${program.name} (FROM AST) ===============")
@ -76,30 +75,39 @@ class AstToSourceCode(val output: (text: String) -> Unit): IAstVisitor {
output("\n")
}
fun datatypeString(dt: DataType): String {
private fun datatypeString(dt: DataType): String {
return when(dt) {
in NumericDatatypes -> dt.toString().toLowerCase()
in StringDatatypes -> dt.toString().toLowerCase()
DataType.STR -> dt.toString().toLowerCase()
DataType.ARRAY_UB -> "ubyte["
DataType.ARRAY_B -> "byte["
DataType.ARRAY_UW -> "uword["
DataType.ARRAY_W -> "word["
DataType.ARRAY_F -> "float["
else -> "?????"
DataType.STRUCT -> "" // the name of the struct is enough
else -> "?????2"
}
}
override fun visit(decl: VarDecl) {
if(decl.autoGenerated) {
// skip autogenerated vardecl
return
override fun visit(structDecl: StructDecl) {
outputln("struct ${structDecl.name} {")
scopelevel++
for(decl in structDecl.statements) {
outputi("")
decl.accept(this)
output("\n")
}
scopelevel--
outputlni("}")
}
override fun visit(decl: VarDecl) {
when(decl.type) {
VarDeclType.VAR -> {}
VarDeclType.CONST -> output("const ")
VarDeclType.MEMORY -> output("&")
}
output(decl.struct?.name ?: "")
output(datatypeString(decl.datatype))
if(decl.arraysize!=null) {
decl.arraysize!!.index.accept(this)
@ -107,7 +115,7 @@ class AstToSourceCode(val output: (text: String) -> Unit): IAstVisitor {
if(decl.isArray)
output("]")
if(decl.zeropage)
if(decl.zeropage == ZeropageWish.REQUIRE_ZEROPAGE || decl.zeropage==ZeropageWish.PREFER_ZEROPAGE)
output(" @zp")
output(" ${decl.name} ")
if(decl.value!=null) {
@ -123,10 +131,10 @@ class AstToSourceCode(val output: (text: String) -> Unit): IAstVisitor {
for(param in subroutine.parameters.zip(subroutine.asmParameterRegisters)) {
val reg =
when {
true==param.second.stack -> "stack"
param.second.stack -> "stack"
param.second.registerOrPair!=null -> param.second.registerOrPair.toString()
param.second.statusflag!=null -> param.second.statusflag.toString()
else -> "?????"
else -> "?????1"
}
output("${datatypeString(param.first.type)} ${param.first.name} @$reg")
if(param.first!==subroutine.parameters.last())
@ -167,10 +175,10 @@ class AstToSourceCode(val output: (text: String) -> Unit): IAstVisitor {
}
}
private fun outputStatements(statements: List<IStatement>) {
private fun outputStatements(statements: List<Statement>) {
for(stmt in statements) {
if(stmt is VarDecl && stmt.autoGenerated)
continue // skip autogenerated decls
if(stmt is VarDecl && stmt.autogeneratedDontRemove)
continue // skip autogenerated decls (to avoid generating a newline)
outputi("")
stmt.accept(this)
output("\n")
@ -188,9 +196,9 @@ class AstToSourceCode(val output: (text: String) -> Unit): IAstVisitor {
private fun printout(call: IFunctionCall) {
call.target.accept(this)
output("(")
for(arg in call.arglist) {
for(arg in call.args) {
arg.accept(this)
if(arg!==call.arglist.last())
if(arg!==call.args.last())
output(", ")
}
output(")")
@ -243,27 +251,48 @@ class AstToSourceCode(val output: (text: String) -> Unit): IAstVisitor {
output("${label.name}:")
}
override fun visit(literalValue: LiteralValue) {
when {
literalValue.isNumeric -> output(literalValue.asNumericValue.toString())
literalValue.isString -> output("\"${escape(literalValue.strvalue!!)}\"")
literalValue.isArray -> {
if(literalValue.arrayvalue!=null) {
output("[")
for (v in literalValue.arrayvalue) {
v.accept(this)
if (v !== literalValue.arrayvalue.last())
output(", ")
}
output("]")
}
override fun visit(numLiteral: NumericLiteralValue) {
output(numLiteral.number.toString())
}
override fun visit(string: StringLiteralValue) {
output("\"${escape(string.value)}\"")
}
override fun visit(array: ArrayLiteralValue) {
outputListMembers(array.value.asSequence(), '[', ']')
}
private fun outputListMembers(array: Sequence<Expression>, openchar: Char, closechar: Char) {
var counter = 0
output(openchar.toString())
scopelevel++
for (v in array) {
v.accept(this)
if (v !== array.last())
output(", ")
counter++
if (counter > 16) {
outputln("")
outputi("")
counter = 0
}
}
scopelevel--
output(closechar.toString())
}
override fun visit(assignment: Assignment) {
assignment.singleTarget!!.accept(this)
if(assignment.aug_op!=null)
if(assignment is VariableInitializationAssignment) {
val targetVar = assignment.target.identifier?.targetVarDecl(program.namespace)
if(targetVar?.struct != null) {
// skip STRUCT init assignments
return
}
}
assignment.target.accept(this)
if (assignment.aug_op != null)
output(" ${assignment.aug_op} ")
else
output(" = ")
@ -285,13 +314,6 @@ class AstToSourceCode(val output: (text: String) -> Unit): IAstVisitor {
override fun visit(forLoop: ForLoop) {
output("for ")
if(forLoop.decltype!=null) {
output(datatypeString(forLoop.decltype))
if (forLoop.zeropage)
output(" @zp ")
else
output(" ")
}
if(forLoop.loopRegister!=null)
output(forLoop.loopRegister.toString())
else
@ -310,7 +332,7 @@ class AstToSourceCode(val output: (text: String) -> Unit): IAstVisitor {
}
override fun visit(repeatLoop: RepeatLoop) {
outputln("repeat ")
output("repeat ")
repeatLoop.body.accept(this)
output(" until ")
repeatLoop.untilCondition.accept(this)
@ -318,11 +340,7 @@ class AstToSourceCode(val output: (text: String) -> Unit): IAstVisitor {
override fun visit(returnStmt: Return) {
output("return ")
for(v in returnStmt.values) {
v.accept(this)
if(v!==returnStmt.values.last())
output(", ")
}
returnStmt.value?.accept(this)
}
override fun visit(arrayIndexedExpression: ArrayIndexedExpression) {
@ -351,8 +369,9 @@ class AstToSourceCode(val output: (text: String) -> Unit): IAstVisitor {
}
override fun visit(typecast: TypecastExpression) {
output("(")
typecast.expression.accept(this)
output(" as ${datatypeString(typecast.type)} ")
output(" as ${datatypeString(typecast.type)}) ")
}
override fun visit(memread: DirectMemoryRead) {
@ -397,11 +416,16 @@ class AstToSourceCode(val output: (text: String) -> Unit): IAstVisitor {
}
override fun visit(whenChoice: WhenChoice) {
if(whenChoice.value==null)
val choiceValues = whenChoice.values
if(choiceValues==null)
outputi("else -> ")
else {
outputi("")
whenChoice.value.accept(this)
for(value in choiceValues) {
value.accept(this)
if(value !== choiceValues.last())
output(",")
}
output(" -> ")
}
if(whenChoice.statements.statements.size==1)
@ -410,7 +434,12 @@ class AstToSourceCode(val output: (text: String) -> Unit): IAstVisitor {
whenChoice.statements.accept(this)
outputln("")
}
override fun visit(structLv: StructLiteralValue) {
outputListMembers(structLv.values.asSequence(), '{', '}')
}
override fun visit(nopStatement: NopStatement) {
TODO("NOP???")
output("; NOP @ ${nopStatement.position} $nopStatement")
}
}

208
compiler/src/prog8/ast/AstToplevel.kt
View File

@ -1,29 +1,182 @@
package prog8.ast
import prog8.ast.base.FatalAstException
import prog8.ast.base.NameError
import prog8.ast.base.ParentSentinel
import prog8.ast.base.Position
import prog8.ast.statements.Block
import prog8.ast.statements.Label
import prog8.ast.statements.Subroutine
import prog8.ast.statements.VarDecl
import prog8.compiler.HeapValues
import prog8.ast.base.*
import prog8.ast.expressions.Expression
import prog8.ast.expressions.IdentifierReference
import prog8.ast.statements.*
import prog8.functions.BuiltinFunctions
import java.nio.file.Path
interface Node {
val position: Position
var parent: Node // will be linked correctly later (late init)
fun linkParents(parent: Node)
fun definingModule(): Module {
if(this is Module)
return this
return findParentNode<Module>(this)!!
}
fun definingSubroutine(): Subroutine? = findParentNode<Subroutine>(this)
fun definingScope(): INameScope {
val scope = findParentNode<INameScope>(this)
if(scope!=null) {
return scope
}
if(this is Label && this.name.startsWith("builtin::")) {
return BuiltinFunctionScopePlaceholder
}
if(this is GlobalNamespace)
return this
throw FatalAstException("scope missing from $this")
}
}
interface IFunctionCall {
var target: IdentifierReference
var args: MutableList<Expression>
}
interface INameScope {
val name: String
val position: Position
val statements: MutableList<Statement>
val parent: Node
fun linkParents(parent: Node)
fun subScopes(): Map<String, INameScope> {
val subscopes = mutableMapOf<String, INameScope>()
for(stmt in statements) {
when(stmt) {
// NOTE: if other nodes are introduced that are a scope, or contain subscopes, they must be added here!
is ForLoop -> subscopes[stmt.body.name] = stmt.body
is RepeatLoop -> subscopes[stmt.body.name] = stmt.body
is WhileLoop -> subscopes[stmt.body.name] = stmt.body
is BranchStatement -> {
subscopes[stmt.truepart.name] = stmt.truepart
if(stmt.elsepart.containsCodeOrVars())
subscopes[stmt.elsepart.name] = stmt.elsepart
}
is IfStatement -> {
subscopes[stmt.truepart.name] = stmt.truepart
if(stmt.elsepart.containsCodeOrVars())
subscopes[stmt.elsepart.name] = stmt.elsepart
}
is WhenStatement -> {
stmt.choices.forEach { subscopes[it.statements.name] = it.statements }
}
is INameScope -> subscopes[stmt.name] = stmt
else -> {}
}
}
return subscopes
}
fun getLabelOrVariable(name: String): Statement? {
// this is called A LOT and could perhaps be optimized a bit more,
// but adding a memoization cache didn't make much of a practical runtime difference
for (stmt in statements) {
if (stmt is VarDecl && stmt.name==name) return stmt
if (stmt is Label && stmt.name==name) return stmt
if (stmt is AnonymousScope) {
val sub = stmt.getLabelOrVariable(name)
if(sub!=null)
return sub
}
}
return null
}
fun allDefinedSymbols(): List<Pair<String, Statement>> {
return statements.mapNotNull {
when (it) {
is Label -> it.name to it
is VarDecl -> it.name to it
is Subroutine -> it.name to it
is Block -> it.name to it
else -> null
}
}
}
fun lookup(scopedName: List<String>, localContext: Node) : Statement? {
if(scopedName.size>1) {
// a scoped name can a) refer to a member of a struct, or b) refer to a name in another module.
// try the struct first.
val thing = lookup(scopedName.dropLast(1), localContext) as? VarDecl
val struct = thing?.struct
if (struct != null) {
if(struct.statements.any { (it as VarDecl).name == scopedName.last()}) {
// return ref to the mangled name variable
val mangled = mangledStructMemberName(thing.name, scopedName.last())
return thing.definingScope().getLabelOrVariable(mangled)
}
}
// it's a qualified name, look it up from the root of the module's namespace (consider all modules in the program)
for(module in localContext.definingModule().program.modules) {
var scope: INameScope? = module
for(name in scopedName.dropLast(1)) {
scope = scope?.subScopes()?.get(name)
if(scope==null)
break
}
if(scope!=null) {
val result = scope.getLabelOrVariable(scopedName.last())
if(result!=null)
return result
return scope.subScopes()[scopedName.last()] as Statement?
}
}
return null
} else {
// unqualified name, find the scope the localContext is in, look in that first
var statementScope = localContext
while(statementScope !is ParentSentinel) {
val localScope = statementScope.definingScope()
val result = localScope.getLabelOrVariable(scopedName[0])
if (result != null)
return result
val subscope = localScope.subScopes()[scopedName[0]] as Statement?
if (subscope != null)
return subscope
// not found in this scope, look one higher up
statementScope = statementScope.parent
}
return null
}
}
fun containsCodeOrVars() = statements.any { it !is Directive || it.directive == "%asminclude" || it.directive == "%asm"}
fun containsNoCodeNorVars() = !containsCodeOrVars()
fun remove(stmt: Statement) {
if(!statements.remove(stmt))
throw FatalAstException("stmt to remove wasn't found in scope")
}
}
interface IAssignable {
// just a tag for now
}
/*********** Everything starts from here, the Program; zero or more modules *************/
class Program(val name: String, val modules: MutableList<Module>) {
val namespace = GlobalNamespace(modules)
val heap = HeapValues()
val loadAddress: Int
val definedLoadAddress: Int
get() = modules.first().loadAddress
var actualLoadAddress: Int = 0
fun entrypoint(): Subroutine? {
val mainBlocks = modules.flatMap { it.statements }.filter { b -> b is Block && b.name=="main" }.map { it as Block }
val mainBlocks = allBlocks().filter { it.name=="main" }
if(mainBlocks.size > 1)
throw FatalAstException("more than one 'main' block")
return if(mainBlocks.isEmpty()) {
@ -32,10 +185,12 @@ class Program(val name: String, val modules: MutableList<Module>) {
mainBlocks[0].subScopes()["start"] as Subroutine?
}
}
fun allBlocks(): List<Block> = modules.flatMap { it.statements.filterIsInstance<Block>() }
}
class Module(override val name: String,
override var statements: MutableList<IStatement>,
override var statements: MutableList<Statement>,
override val position: Position,
val isLibraryModule: Boolean,
val source: Path) : Node, INameScope {
@ -59,14 +214,14 @@ class Module(override val name: String,
class GlobalNamespace(val modules: List<Module>): Node, INameScope {
override val name = "<<<global>>>"
override val position = Position("<<<global>>>", 0, 0, 0)
override val statements = mutableListOf<IStatement>()
override val statements = mutableListOf<Statement>()
override var parent: Node = ParentSentinel
override fun linkParents(parent: Node) {
modules.forEach { it.linkParents(this) }
}
override fun lookup(scopedName: List<String>, localContext: Node): IStatement? {
override fun lookup(scopedName: List<String>, localContext: Node): Statement? {
if (scopedName.size == 1 && scopedName[0] in BuiltinFunctions) {
// builtin functions always exist, return a dummy localContext for them
val builtinPlaceholder = Label("builtin::${scopedName.last()}", localContext.position)
@ -74,8 +229,21 @@ class GlobalNamespace(val modules: List<Module>): Node, INameScope {
return builtinPlaceholder
}
val stmt = localContext.definingModule().lookup(scopedName, localContext)
return when (stmt) {
if(scopedName.size>1) {
// a scoped name can a) refer to a member of a struct, or b) refer to a name in another module.
// try the struct first.
val thing = lookup(scopedName.dropLast(1), localContext) as? VarDecl
val struct = thing?.struct
if (struct != null) {
if(struct.statements.any { (it as VarDecl).name == scopedName.last()}) {
// return ref to the mangled name variable
val mangled = mangledStructMemberName(thing.name, scopedName.last())
return thing.definingScope().getLabelOrVariable(mangled)
}
}
}
// lookup something from the module.
return when (val stmt = localContext.definingModule().lookup(scopedName, localContext)) {
is Label, is VarDecl, is Block, is Subroutine -> stmt
null -> null
else -> throw NameError("wrong identifier target: $stmt", stmt.position)
@ -86,7 +254,11 @@ class GlobalNamespace(val modules: List<Module>): Node, INameScope {
object BuiltinFunctionScopePlaceholder : INameScope {
override val name = "<<builtin-functions-scope-placeholder>>"
override val position = Position("<<placeholder>>", 0, 0, 0)
override var statements = mutableListOf<IStatement>()
override var statements = mutableListOf<Statement>()
override var parent: Node = ParentSentinel
override fun linkParents(parent: Node) {}
}
// prefix for struct member variables
internal fun mangledStructMemberName(varName: String, memberName: String) = "prog8struct_${varName}_$memberName"

197
compiler/src/prog8/ast/Interfaces.kt
View File

@ -1,197 +0,0 @@
package prog8.ast
import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.ast.processing.IAstModifyingVisitor
import prog8.ast.processing.IAstVisitor
import prog8.ast.statements.*
interface Node {
val position: Position
var parent: Node // will be linked correctly later (late init)
fun linkParents(parent: Node)
fun definingModule(): Module {
if(this is Module)
return this
return findParentNode<Module>(this)!!
}
fun definingSubroutine(): Subroutine? = findParentNode<Subroutine>(this)
fun definingScope(): INameScope {
val scope = findParentNode<INameScope>(this)
if(scope!=null) {
return scope
}
if(this is Label && this.name.startsWith("builtin::")) {
return BuiltinFunctionScopePlaceholder
}
if(this is GlobalNamespace)
return this
throw FatalAstException("scope missing from $this")
}
}
interface IStatement : Node {
fun accept(visitor: IAstModifyingVisitor) : IStatement
fun accept(visitor: IAstVisitor)
fun makeScopedName(name: String): String {
// easy way out is to always return the full scoped name.
// it would be nicer to find only the minimal prefixed scoped name, but that's too much hassle for now.
// and like this, we can cache the name even,
// like in a lazy property on the statement object itself (label, subroutine, vardecl)
val scope = mutableListOf<String>()
var statementScope = this.parent
while(statementScope !is ParentSentinel && statementScope !is Module) {
if(statementScope is INameScope) {
scope.add(0, statementScope.name)
}
statementScope = statementScope.parent
}
if(name.isNotEmpty())
scope.add(name)
return scope.joinToString(".")
}
val expensiveToInline: Boolean
fun definingBlock(): Block {
if(this is Block)
return this
return findParentNode<Block>(this)!!
}
}
interface IFunctionCall {
var target: IdentifierReference
var arglist: MutableList<IExpression>
}
interface INameScope {
val name: String
val position: Position
val statements: MutableList<IStatement>
val parent: Node
fun linkParents(parent: Node)
fun subScopes(): Map<String, INameScope> {
val subscopes = mutableMapOf<String, INameScope>()
for(stmt in statements) {
when(stmt) {
is INameScope -> subscopes[stmt.name] = stmt
is ForLoop -> subscopes[stmt.body.name] = stmt.body
is RepeatLoop -> subscopes[stmt.body.name] = stmt.body
is WhileLoop -> subscopes[stmt.body.name] = stmt.body
is BranchStatement -> {
subscopes[stmt.truepart.name] = stmt.truepart
if(stmt.elsepart.containsCodeOrVars())
subscopes[stmt.elsepart.name] = stmt.elsepart
}
is IfStatement -> {
subscopes[stmt.truepart.name] = stmt.truepart
if(stmt.elsepart.containsCodeOrVars())
subscopes[stmt.elsepart.name] = stmt.elsepart
}
}
}
return subscopes
}
fun getLabelOrVariable(name: String): IStatement? {
// TODO this is called A LOT and could perhaps be optimized a bit more, but adding a cache didn't make much of a practical runtime difference
for (stmt in statements) {
if (stmt is VarDecl && stmt.name==name) return stmt
if (stmt is Label && stmt.name==name) return stmt
}
return null
}
fun allDefinedSymbols(): List<Pair<String, IStatement>> {
return statements.mapNotNull {
when (it) {
is Label -> it.name to it
is VarDecl -> it.name to it
is Subroutine -> it.name to it
is Block -> it.name to it
else -> null
}
}
}
fun lookup(scopedName: List<String>, localContext: Node) : IStatement? {
if(scopedName.size>1) {
// it's a qualified name, look it up from the root of the module's namespace (consider all modules in the program)
for(module in localContext.definingModule().program.modules) {
var scope: INameScope? = module
for(name in scopedName.dropLast(1)) {
scope = scope?.subScopes()?.get(name)
if(scope==null)
break
}
if(scope!=null) {
val result = scope.getLabelOrVariable(scopedName.last())
if(result!=null)
return result
return scope.subScopes()[scopedName.last()] as IStatement?
}
}
return null
} else {
// unqualified name, find the scope the localContext is in, look in that first
var statementScope = localContext
while(statementScope !is ParentSentinel) {
val localScope = statementScope.definingScope()
val result = localScope.getLabelOrVariable(scopedName[0])
if (result != null)
return result
val subscope = localScope.subScopes()[scopedName[0]] as IStatement?
if (subscope != null)
return subscope
// not found in this scope, look one higher up
statementScope = statementScope.parent
}
return null
}
}
fun containsCodeOrVars() = statements.any { it !is Directive || it.directive == "%asminclude" || it.directive == "%asm"}
fun containsNoCodeNorVars() = !containsCodeOrVars()
fun remove(stmt: IStatement) {
if(!statements.remove(stmt))
throw FatalAstException("stmt to remove wasn't found in scope")
}
}
interface IExpression: Node {
fun constValue(program: Program): LiteralValue?
fun accept(visitor: IAstModifyingVisitor): IExpression
fun accept(visitor: IAstVisitor)
fun referencesIdentifier(name: String): Boolean
fun inferType(program: Program): DataType?
infix fun isSameAs(other: IExpression): Boolean {
if(this===other)
return true
when(this) {
is RegisterExpr ->
return (other is RegisterExpr && other.register==register)
is IdentifierReference ->
return (other is IdentifierReference && other.nameInSource==nameInSource)
is PrefixExpression ->
return (other is PrefixExpression && other.operator==operator && other.expression isSameAs expression)
is BinaryExpression ->
return (other is BinaryExpression && other.operator==operator
&& other.left isSameAs left
&& other.right isSameAs right)
is ArrayIndexedExpression -> {
return (other is ArrayIndexedExpression && other.identifier.nameInSource == identifier.nameInSource
&& other.arrayspec.index isSameAs arrayspec.index)
}
is LiteralValue -> return (other is LiteralValue && other==this)
}
return false
}
}

254
compiler/src/prog8/ast/antlr/Antr2Kotlin.kt
View File

@ -3,16 +3,16 @@ package prog8.ast.antlr
import org.antlr.v4.runtime.IntStream
import org.antlr.v4.runtime.ParserRuleContext
import org.antlr.v4.runtime.tree.TerminalNode
import prog8.ast.*
import prog8.ast.Module
import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.ast.statements.*
import prog8.compiler.target.CompilationTarget
import prog8.parser.CustomLexer
import prog8.parser.prog8Parser
import java.io.CharConversionException
import java.io.File
import java.nio.file.Path
import prog8.compiler.target.c64.Petscii
import prog8.parser.CustomLexer
import prog8.parser.prog8Parser
/***************** Antlr Extension methods to create AST ****************/
@ -39,7 +39,7 @@ private fun ParserRuleContext.toPosition() : Position {
}
private fun prog8Parser.ModulestatementContext.toAst(isInLibrary: Boolean) : IStatement {
private fun prog8Parser.ModulestatementContext.toAst(isInLibrary: Boolean) : Statement {
val directive = directive()?.toAst()
if(directive!=null) return directive
@ -50,74 +50,104 @@ private fun prog8Parser.ModulestatementContext.toAst(isInLibrary: Boolean) : ISt
}
private fun prog8Parser.BlockContext.toAst(isInLibrary: Boolean) : IStatement =
private fun prog8Parser.BlockContext.toAst(isInLibrary: Boolean) : Statement =
Block(identifier().text, integerliteral()?.toAst()?.number?.toInt(), statement_block().toAst(), isInLibrary, toPosition())
private fun prog8Parser.Statement_blockContext.toAst(): MutableList<IStatement> =
private fun prog8Parser.Statement_blockContext.toAst(): MutableList<Statement> =
statement().asSequence().map { it.toAst() }.toMutableList()
private fun prog8Parser.StatementContext.toAst() : IStatement {
vardecl()?.let {
return VarDecl(VarDeclType.VAR,
it.datatype().toAst(),
it.ZEROPAGE() != null,
it.arrayindex()?.toAst(),
it.identifier().text,
null,
it.ARRAYSIG() != null || it.arrayindex() != null,
false,
it.toPosition())
}
private fun prog8Parser.StatementContext.toAst() : Statement {
vardecl()?.let { return it.toAst() }
varinitializer()?.let {
val vd = it.vardecl()
return VarDecl(VarDeclType.VAR,
vd.datatype().toAst(),
vd.ZEROPAGE() != null,
return VarDecl(
VarDeclType.VAR,
vd.datatype()?.toAst() ?: DataType.STRUCT,
if(vd.ZEROPAGE() != null) ZeropageWish.PREFER_ZEROPAGE else ZeropageWish.DONTCARE,
vd.arrayindex()?.toAst(),
vd.identifier().text,
vd.varname.text,
null,
it.expression().toAst(),
vd.ARRAYSIG() != null || vd.arrayindex() != null,
false,
it.toPosition())
it.toPosition()
)
}
structvarinitializer()?.let {
val vd = it.structvardecl()
return VarDecl(
VarDeclType.VAR,
DataType.STRUCT,
ZeropageWish.NOT_IN_ZEROPAGE,
null,
vd.varname.text,
vd.structname.text,
it.expression().toAst(),
isArray = false,
autogeneratedDontRemove = false,
position = it.toPosition()
)
}
structvardecl()?.let {
return VarDecl(
VarDeclType.VAR,
DataType.STRUCT,
ZeropageWish.NOT_IN_ZEROPAGE,
null,
it.varname.text,
it.structname.text,
null,
isArray = false,
autogeneratedDontRemove = false,
position = it.toPosition()
)
}
constdecl()?.let {
val cvarinit = it.varinitializer()
val vd = cvarinit.vardecl()
return VarDecl(VarDeclType.CONST,
vd.datatype().toAst(),
vd.ZEROPAGE() != null,
return VarDecl(
VarDeclType.CONST,
vd.datatype()?.toAst() ?: DataType.STRUCT,
if(vd.ZEROPAGE() != null) ZeropageWish.PREFER_ZEROPAGE else ZeropageWish.DONTCARE,
vd.arrayindex()?.toAst(),
vd.identifier().text,
vd.varname.text,
null,
cvarinit.expression().toAst(),
vd.ARRAYSIG() != null || vd.arrayindex() != null,
false,
cvarinit.toPosition())
cvarinit.toPosition()
)
}
memoryvardecl()?.let {
val mvarinit = it.varinitializer()
val vd = mvarinit.vardecl()
return VarDecl(VarDeclType.MEMORY,
vd.datatype().toAst(),
vd.ZEROPAGE() != null,
return VarDecl(
VarDeclType.MEMORY,
vd.datatype()?.toAst() ?: DataType.STRUCT,
if(vd.ZEROPAGE() != null) ZeropageWish.PREFER_ZEROPAGE else ZeropageWish.DONTCARE,
vd.arrayindex()?.toAst(),
vd.identifier().text,
vd.varname.text,
null,
mvarinit.expression().toAst(),
vd.ARRAYSIG() != null || vd.arrayindex() != null,
false,
mvarinit.toPosition())
mvarinit.toPosition()
)
}
assignment()?.let {
return Assignment(it.assign_targets().toAst(), null, it.expression().toAst(), it.toPosition())
return Assignment(it.assign_target().toAst(), null, it.expression().toAst(), it.toPosition())
}
augassignment()?.let {
return Assignment(listOf(it.assign_target().toAst()),
return Assignment(it.assign_target().toAst(),
it.operator.text,
it.expression().toAst(),
it.toPosition())
@ -172,30 +202,59 @@ private fun prog8Parser.StatementContext.toAst() : IStatement {
val asmsubstmt = asmsubroutine()?.toAst()
if(asmsubstmt!=null) return asmsubstmt
val romsubstmt = romsubroutine()?.toAst()
if(romsubstmt!=null) return romsubstmt
val whenstmt = whenstmt()?.toAst()
if(whenstmt!=null) return whenstmt
structdecl()?.let {
return StructDecl(it.identifier().text,
it.vardecl().map { vd->vd.toAst() }.toMutableList(),
toPosition())
}
throw FatalAstException("unprocessed source text (are we missing ast conversion rules for parser elements?): $text")
}
private fun prog8Parser.Assign_targetsContext.toAst(): List<AssignTarget> = assign_target().map { it.toAst() }
private fun prog8Parser.AsmsubroutineContext.toAst(): Statement {
val subdecl = asmsub_decl().toAst()
val statements = statement_block()?.toAst() ?: mutableListOf()
return Subroutine(subdecl.name, subdecl.parameters, subdecl.returntypes,
subdecl.asmParameterRegisters, subdecl.asmReturnvaluesRegisters,
subdecl.asmClobbers, null, true, statements, toPosition())
}
private fun prog8Parser.RomsubroutineContext.toAst(): Statement {
val subdecl = asmsub_decl().toAst()
val address = integerliteral().toAst().number.toInt()
return Subroutine(subdecl.name, subdecl.parameters, subdecl.returntypes,
subdecl.asmParameterRegisters, subdecl.asmReturnvaluesRegisters,
subdecl.asmClobbers, address, true, mutableListOf(), toPosition())
}
private fun prog8Parser.AsmsubroutineContext.toAst(): IStatement {
private class AsmsubDecl(val name: String,
val parameters: List<SubroutineParameter>,
val returntypes: List<DataType>,
val asmParameterRegisters: List<RegisterOrStatusflag>,
val asmReturnvaluesRegisters: List<RegisterOrStatusflag>,
val asmClobbers: Set<Register>)
private fun prog8Parser.Asmsub_declContext.toAst(): AsmsubDecl {
val name = identifier().text
val address = asmsub_address()?.address?.toAst()?.number?.toInt()
val params = asmsub_params()?.toAst() ?: emptyList()
val returns = asmsub_returns()?.toAst() ?: emptyList()
val clobbers = asmsub_clobbers()?.clobber()?.toAst() ?: emptySet()
val normalParameters = params.map { SubroutineParameter(it.name, it.type, it.position) }
val normalReturnvalues = returns.map { it.type }
val normalReturntypes = returns.map { it.type }
val paramRegisters = params.map { RegisterOrStatusflag(it.registerOrPair, it.statusflag, it.stack) }
val returnRegisters = returns.map { RegisterOrStatusflag(it.registerOrPair, it.statusflag, it.stack) }
val clobbers = asmsub_clobbers()?.clobber()?.toAst() ?: emptySet()
val statements = statement_block()?.toAst() ?: mutableListOf()
return Subroutine(name, normalParameters, normalReturnvalues,
paramRegisters, returnRegisters, clobbers, address, true, statements, toPosition())
return AsmsubDecl(name, normalParameters, normalReturntypes, paramRegisters, returnRegisters, clobbers)
}
private class AsmSubroutineParameter(name: String,
type: DataType,
val registerOrPair: RegisterOrPair?,
@ -218,20 +277,25 @@ private fun prog8Parser.Asmsub_returnsContext.toAst(): List<AsmSubroutineReturn>
private fun prog8Parser.Asmsub_paramsContext.toAst(): List<AsmSubroutineParameter>
= asmsub_param().map {
AsmSubroutineParameter(it.vardecl().identifier().text, it.vardecl().datatype().toAst(),
it.registerorpair()?.toAst(), it.statusregister()?.toAst(), !it.stack?.text.isNullOrEmpty(), toPosition())
val vardecl = it.vardecl()
val datatype = vardecl.datatype()?.toAst() ?: DataType.STRUCT
AsmSubroutineParameter(vardecl.varname.text, datatype,
it.registerorpair()?.toAst(),
it.statusregister()?.toAst(),
!it.stack?.text.isNullOrEmpty(), toPosition())
}
private fun prog8Parser.StatusregisterContext.toAst() = Statusflag.valueOf(text)
private fun prog8Parser.Functioncall_stmtContext.toAst(): IStatement {
private fun prog8Parser.Functioncall_stmtContext.toAst(): Statement {
val void = this.VOID() != null
val location = scoped_identifier().toAst()
return if(expression_list() == null)
FunctionCallStatement(location, mutableListOf(), toPosition())
FunctionCallStatement(location, mutableListOf(), void, toPosition())
else
FunctionCallStatement(location, expression_list().toAst().toMutableList(), toPosition())
FunctionCallStatement(location, expression_list().toAst().toMutableList(), void, toPosition())
}
@ -249,8 +313,7 @@ private fun prog8Parser.InlineasmContext.toAst() =
private fun prog8Parser.ReturnstmtContext.toAst() : Return {
val values = expression_list()
return Return(values?.toAst() ?: emptyList(), toPosition())
return Return(expression()?.toAst(), toPosition())
}
private fun prog8Parser.UnconditionaljumpContext.toAst(): Jump {
@ -260,7 +323,7 @@ private fun prog8Parser.UnconditionaljumpContext.toAst(): Jump {
}
private fun prog8Parser.LabeldefContext.toAst(): IStatement =
private fun prog8Parser.LabeldefContext.toAst(): Statement =
Label(children[0].text, toPosition())
@ -285,7 +348,8 @@ private fun prog8Parser.Sub_return_partContext.toAst(): List<DataType> {
private fun prog8Parser.Sub_paramsContext.toAst(): List<SubroutineParameter> =
vardecl().map {
SubroutineParameter(it.identifier().text, it.datatype().toAst(), it.toPosition())
val datatype = it.datatype()?.toAst() ?: DataType.STRUCT
SubroutineParameter(it.varname.text, datatype, it.toPosition())
}
@ -316,8 +380,13 @@ private fun prog8Parser.DirectiveContext.toAst() : Directive =
Directive(directivename.text, directivearg().map { it.toAst() }, toPosition())
private fun prog8Parser.DirectiveargContext.toAst() : DirectiveArg =
DirectiveArg(stringliteral()?.text, identifier()?.text, integerliteral()?.toAst()?.number?.toInt(), toPosition())
private fun prog8Parser.DirectiveargContext.toAst() : DirectiveArg {
val str = stringliteral()
if(str?.ALT_STRING_ENCODING() != null)
throw AstException("${toPosition()} can't use alternate string encodings for directive arguments")
return DirectiveArg(stringliteral()?.text, identifier()?.text, integerliteral()?.toAst()?.number?.toInt(), toPosition())
}
private fun prog8Parser.IntegerliteralContext.toAst(): NumericLiteral {
@ -372,39 +441,46 @@ private fun prog8Parser.IntegerliteralContext.toAst(): NumericLiteral {
}
private fun prog8Parser.ExpressionContext.toAst() : IExpression {
private fun prog8Parser.ExpressionContext.toAst() : Expression {
val litval = literalvalue()
if(litval!=null) {
val booleanlit = litval.booleanliteral()?.toAst()
return if(booleanlit!=null) {
LiteralValue.fromBoolean(booleanlit, litval.toPosition())
NumericLiteralValue.fromBoolean(booleanlit, litval.toPosition())
}
else {
val intLit = litval.integerliteral()?.toAst()
when {
intLit!=null -> when(intLit.datatype) {
DataType.UBYTE -> LiteralValue(DataType.UBYTE, bytevalue = intLit.number.toShort(), position = litval.toPosition())
DataType.BYTE -> LiteralValue(DataType.BYTE, bytevalue = intLit.number.toShort(), position = litval.toPosition())
DataType.UWORD -> LiteralValue(DataType.UWORD, wordvalue = intLit.number.toInt(), position = litval.toPosition())
DataType.WORD -> LiteralValue(DataType.WORD, wordvalue = intLit.number.toInt(), position = litval.toPosition())
DataType.FLOAT -> LiteralValue(DataType.FLOAT, floatvalue = intLit.number.toDouble(), position = litval.toPosition())
DataType.UBYTE -> NumericLiteralValue(DataType.UBYTE, intLit.number.toShort(), litval.toPosition())
DataType.BYTE -> NumericLiteralValue(DataType.BYTE, intLit.number.toShort(), litval.toPosition())
DataType.UWORD -> NumericLiteralValue(DataType.UWORD, intLit.number.toInt(), litval.toPosition())
DataType.WORD -> NumericLiteralValue(DataType.WORD, intLit.number.toInt(), litval.toPosition())
DataType.FLOAT -> NumericLiteralValue(DataType.FLOAT, intLit.number.toDouble(), litval.toPosition())
else -> throw FatalAstException("invalid datatype for numeric literal")
}
litval.floatliteral()!=null -> LiteralValue(DataType.FLOAT, floatvalue = litval.floatliteral().toAst(), position = litval.toPosition())
litval.stringliteral()!=null -> LiteralValue(DataType.STR, strvalue = unescape(litval.stringliteral().text, litval.toPosition()), position = litval.toPosition())
litval.floatliteral()!=null -> NumericLiteralValue(DataType.FLOAT, litval.floatliteral().toAst(), litval.toPosition())
litval.stringliteral()!=null -> litval.stringliteral().toAst()
litval.charliteral()!=null -> {
try {
LiteralValue(DataType.UBYTE, bytevalue = Petscii.encodePetscii(unescape(litval.charliteral().text, litval.toPosition()), true)[0], position = litval.toPosition())
val cc=litval.charliteral()
NumericLiteralValue(DataType.UBYTE, CompilationTarget.encodeString(
unescape(litval.charliteral().SINGLECHAR().text, litval.toPosition()),
litval.charliteral().ALT_STRING_ENCODING()!=null)[0], litval.toPosition())
} catch (ce: CharConversionException) {
throw SyntaxError(ce.message ?: ce.toString(), litval.toPosition())
}
}
litval.arrayliteral()!=null -> {
val array = litval.arrayliteral()?.toAst()
val array = litval.arrayliteral().toAst()
// the actual type of the arraysize can not yet be determined here (missing namespace & heap)
// the ConstantFolder takes care of that and converts the type if needed.
LiteralValue(DataType.ARRAY_UB, arrayvalue = array, position = litval.toPosition())
// the ConstantFold takes care of that and converts the type if needed.
ArrayLiteralValue(InferredTypes.InferredType.unknown(), array, position = litval.toPosition())
}
litval.structliteral()!=null -> {
val values = litval.structliteral().expression().map { it.toAst() }
StructLiteralValue(values, litval.toPosition())
}
else -> throw FatalAstException("invalid parsed literal")
}
@ -427,7 +503,8 @@ private fun prog8Parser.ExpressionContext.toAst() : IExpression {
if(funcall!=null) return funcall
if (rangefrom!=null && rangeto!=null) {
val step = rangestep?.toAst() ?: LiteralValue(DataType.UBYTE, 1, position = toPosition())
val defaultstep = if(rto.text == "to") 1 else -1
val step = rangestep?.toAst() ?: NumericLiteralValue(DataType.UBYTE, defaultstep, toPosition())
return RangeExpr(rangefrom.toAst(), rangeto.toAst(), step, toPosition())
}
@ -450,6 +527,10 @@ private fun prog8Parser.ExpressionContext.toAst() : IExpression {
}
private fun prog8Parser.StringliteralContext.toAst(): StringLiteralValue =
StringLiteralValue(unescape(this.STRING().text, toPosition()), ALT_STRING_ENCODING()!=null, toPosition())
private fun prog8Parser.ArrayindexedContext.toAst(): ArrayIndexedExpression {
return ArrayIndexedExpression(scoped_identifier().toAst(),
arrayindex().toAst(),
@ -478,10 +559,9 @@ private fun prog8Parser.BooleanliteralContext.toAst() = when(text) {
}
private fun prog8Parser.ArrayliteralContext.toAst() : Array<IExpression> =
private fun prog8Parser.ArrayliteralContext.toAst() : Array<Expression> =
expression().map { it.toAst() }.toTypedArray()
private fun prog8Parser.If_stmtContext.toAst(): IfStatement {
val condition = expression().toAst()
val trueStatements = statement_block()?.toAst() ?: mutableListOf(statement().toAst())
@ -492,7 +572,7 @@ private fun prog8Parser.If_stmtContext.toAst(): IfStatement {
return IfStatement(condition, trueScope, elseScope, toPosition())
}
private fun prog8Parser.Else_partContext.toAst(): MutableList<IStatement> {
private fun prog8Parser.Else_partContext.toAst(): MutableList<Statement> {
return statement_block()?.toAst() ?: mutableListOf(statement().toAst())
}
@ -512,8 +592,6 @@ private fun prog8Parser.BranchconditionContext.toAst() = BranchCondition.valueOf
private fun prog8Parser.ForloopContext.toAst(): ForLoop {
val loopregister = register()?.toAst()
val datatype = datatype()?.toAst()
val zeropage = ZEROPAGE()!=null
val loopvar = identifier()?.toAst()
val iterable = expression()!!.toAst()
val scope =
@ -521,7 +599,7 @@ private fun prog8Parser.ForloopContext.toAst(): ForLoop {
AnonymousScope(mutableListOf(statement().toAst()), statement().toPosition())
else
AnonymousScope(statement_block().toAst(), statement_block().toPosition())
return ForLoop(loopregister, datatype, zeropage, loopvar, iterable, scope, toPosition())
return ForLoop(loopregister, loopvar, iterable, scope, toPosition())
}
@ -554,13 +632,28 @@ private fun prog8Parser.WhenstmtContext.toAst(): WhenStatement {
}
private fun prog8Parser.When_choiceContext.toAst(): WhenChoice {
val value = expression()?.toAst()
val values = expression_list()?.toAst()
val stmt = statement()?.toAst()
val stmt_block = statement_block()?.toAst()?.toMutableList() ?: mutableListOf()
val stmtBlock = statement_block()?.toAst()?.toMutableList() ?: mutableListOf()
if(stmt!=null)
stmt_block.add(stmt)
val scope = AnonymousScope(stmt_block, toPosition())
return WhenChoice(value, scope, toPosition())
stmtBlock.add(stmt)
val scope = AnonymousScope(stmtBlock, toPosition())
return WhenChoice(values, scope, toPosition())
}
private fun prog8Parser.VardeclContext.toAst(): VarDecl {
return VarDecl(
VarDeclType.VAR,
datatype()?.toAst() ?: DataType.STRUCT,
if(ZEROPAGE() != null) ZeropageWish.PREFER_ZEROPAGE else ZeropageWish.DONTCARE,
arrayindex()?.toAst(),
varname.text,
null,
null,
ARRAYSIG() != null || arrayindex() != null,
false,
toPosition()
)
}
internal fun escape(str: String) = str.replace("\t", "\\t").replace("\n", "\\n").replace("\r", "\\r")
@ -588,3 +681,4 @@ internal fun unescape(str: String, position: Position): String {
}
return result.joinToString("")
}

79
compiler/src/prog8/ast/base/Base.kt
View File

@ -1,22 +1,24 @@
package prog8.ast.base
import prog8.ast.Node
import prog8.compiler.target.CompilationTarget
/**************************** AST Data classes ****************************/
enum class DataType {
UBYTE,
BYTE,
UWORD,
WORD,
FLOAT,
STR,
STR_S,
ARRAY_UB,
ARRAY_B,
ARRAY_UW,
ARRAY_W,
ARRAY_F;
UBYTE, // pass by value
BYTE, // pass by value
UWORD, // pass by value
WORD, // pass by value
FLOAT, // pass by value
STR, // pass by reference
ARRAY_UB, // pass by reference
ARRAY_B, // pass by reference
ARRAY_UW, // pass by reference
ARRAY_W, // pass by reference
ARRAY_F, // pass by reference
STRUCT; // pass by reference
/**
* is the type assignable to the given other type?
@ -24,26 +26,42 @@ enum class DataType {
infix fun isAssignableTo(targetType: DataType) =
// what types are assignable to others without loss of precision?
when(this) {
UBYTE -> targetType == UBYTE || targetType == UWORD || targetType==WORD || targetType == FLOAT
BYTE -> targetType == BYTE || targetType == UBYTE || targetType == UWORD || targetType==WORD || targetType == FLOAT
UWORD -> targetType == UWORD || targetType == FLOAT
WORD -> targetType == WORD || targetType==UWORD || targetType == FLOAT
UBYTE -> targetType in setOf(UBYTE, WORD, UWORD, FLOAT)
BYTE -> targetType in setOf(BYTE, WORD, FLOAT)
UWORD -> targetType in setOf(UWORD, FLOAT)
WORD -> targetType in setOf(WORD, FLOAT)
FLOAT -> targetType == FLOAT
STR -> targetType == STR || targetType==STR_S
STR_S -> targetType == STR || targetType==STR_S
in ArrayDatatypes -> targetType === this
STR -> targetType == STR
in ArrayDatatypes -> targetType == this
else -> false
}
infix fun isAssignableTo(targetTypes: Set<DataType>) = targetTypes.any { this isAssignableTo it }
infix fun biggerThan(other: DataType) =
infix fun largerThan(other: DataType) =
when(this) {
in ByteDatatypes -> false
in WordDatatypes -> other in ByteDatatypes
else -> true
}
infix fun equalsSize(other: DataType) =
when(this) {
in ByteDatatypes -> other in ByteDatatypes
in WordDatatypes -> other in WordDatatypes
else -> false
}
fun memorySize(): Int {
return when(this) {
in ByteDatatypes -> 1
in WordDatatypes -> 2
FLOAT -> CompilationTarget.machine.FLOAT_MEM_SIZE
in PassByReferenceDatatypes -> 2
else -> -9999999
}
}
}
enum class Register {
@ -89,23 +107,32 @@ enum class VarDeclType {
MEMORY
}
val IterableDatatypes = setOf(
DataType.STR, DataType.STR_S,
DataType.ARRAY_UB, DataType.ARRAY_B,
DataType.ARRAY_UW, DataType.ARRAY_W,
DataType.ARRAY_F)
val ByteDatatypes = setOf(DataType.UBYTE, DataType.BYTE)
val WordDatatypes = setOf(DataType.UWORD, DataType.WORD)
val IntegerDatatypes = setOf(DataType.UBYTE, DataType.BYTE, DataType.UWORD, DataType.WORD)
val NumericDatatypes = setOf(DataType.UBYTE, DataType.BYTE, DataType.UWORD, DataType.WORD, DataType.FLOAT)
val StringDatatypes = setOf(DataType.STR, DataType.STR_S)
val ArrayDatatypes = setOf(DataType.ARRAY_UB, DataType.ARRAY_B, DataType.ARRAY_UW, DataType.ARRAY_W, DataType.ARRAY_F)
val IterableDatatypes = setOf(
DataType.STR,
DataType.ARRAY_UB, DataType.ARRAY_B,
DataType.ARRAY_UW, DataType.ARRAY_W,
DataType.ARRAY_F)
val PassByValueDatatypes = NumericDatatypes
val PassByReferenceDatatypes = IterableDatatypes.plus(DataType.STRUCT)
val ArrayElementTypes = mapOf(
DataType.STR to DataType.UBYTE,
DataType.ARRAY_B to DataType.BYTE,
DataType.ARRAY_UB to DataType.UBYTE,
DataType.ARRAY_W to DataType.WORD,
DataType.ARRAY_UW to DataType.UWORD,
DataType.ARRAY_F to DataType.FLOAT)
val ElementArrayTypes = mapOf(
DataType.BYTE to DataType.ARRAY_B,
DataType.UBYTE to DataType.ARRAY_UB,
DataType.WORD to DataType.ARRAY_W,
DataType.UWORD to DataType.ARRAY_UW,
DataType.FLOAT to DataType.ARRAY_F
)
// find the parent node of a specific type or interface
// (useful to figure out in what namespace/block something is defined, etc)

4
compiler/src/prog8/ast/base/ErrorReporting.kt
View File

@ -5,7 +5,7 @@ import prog8.parser.ParsingFailedError
fun printErrors(errors: List<Any>, moduleName: String) {
val reportedMessages = mutableSetOf<String>()
print("\u001b[91m") // bright red
System.err.print("\u001b[91m") // bright red
errors.forEach {
val msg = it.toString()
if(msg !in reportedMessages) {
@ -13,7 +13,7 @@ fun printErrors(errors: List<Any>, moduleName: String) {
reportedMessages.add(msg)
}
}
print("\u001b[0m") // reset color
System.err.print("\u001b[0m") // reset color
if(reportedMessages.isNotEmpty())
throw ParsingFailedError("There are ${reportedMessages.size} errors in module '$moduleName'.")
}

6
compiler/src/prog8/ast/base/Errors.kt
View File

@ -10,13 +10,13 @@ class SyntaxError(override var message: String, val position: Position) : AstExc
override fun toString() = "$position Syntax error: $message"
}
class NameError(override var message: String, val position: Position) : AstException(message) {
open class NameError(override var message: String, val position: Position) : AstException(message) {
override fun toString() = "$position Name error: $message"
}
open class ExpressionError(message: String, val position: Position) : AstException(message) {
class ExpressionError(message: String, val position: Position) : AstException(message) {
override fun toString() = "$position Error: $message"
}
class UndefinedSymbolError(symbol: IdentifierReference)
: ExpressionError("undefined symbol: ${symbol.nameInSource.joinToString(".")}", symbol.position)
: NameError("undefined symbol: ${symbol.nameInSource.joinToString(".")}", symbol.position)

57
compiler/src/prog8/ast/base/Extensions.kt
View File

@ -1,19 +1,20 @@
package prog8.ast.base
import prog8.ast.*
import prog8.ast.expressions.IdentifierReference
import prog8.ast.Module
import prog8.ast.Program
import prog8.ast.processing.*
import prog8.ast.statements.Assignment
import prog8.ast.statements.ForLoop
import prog8.compiler.CompilationOptions
import prog8.optimizer.FlattenAnonymousScopesAndRemoveNops
// the name of the subroutine that should be called for every block to initialize its variables
internal const val initvarsSubName="prog8_init_vars"
// prefix for literal values that are turned into a variable on the heap
internal const val autoHeapValuePrefix = "auto_heap_value_"
internal fun Program.removeNopsFlattenAnonScopes() {
val flattener = FlattenAnonymousScopesAndRemoveNops()
flattener.visit(this)
}
internal fun Program.checkValid(compilerOptions: CompilationOptions) {
@ -23,14 +24,26 @@ internal fun Program.checkValid(compilerOptions: CompilationOptions) {
}
internal fun Program.anonscopeVarsCleanup() {
val mover = AnonymousScopeVarsCleanup(this)
mover.visit(this)
printErrors(mover.result(), name)
}
internal fun Program.reorderStatements() {
val initvalueCreator = VarInitValueAndAddressOfCreator(namespace)
val initvalueCreator = VarInitValueAndAddressOfCreator(this)
initvalueCreator.visit(this)
val checker = StatementReorderer(this)
checker.visit(this)
}
internal fun Program.addTypecasts() {
val caster = TypecastsAdder(this)
caster.visit(this)
}
internal fun Module.checkImportedValid() {
val checker = ImportedModuleDirectiveRemover()
checker.visit(this)
@ -45,40 +58,12 @@ internal fun Program.checkRecursion() {
internal fun Program.checkIdentifiers() {
val checker = AstIdentifiersChecker(namespace)
val checker = AstIdentifiersChecker(this)
checker.visit(this)
if(modules.map {it.name}.toSet().size != modules.size) {
throw FatalAstException("modules should all be unique")
}
// add any anonymous variables for heap values that are used,
// and replace an iterable literalvalue by identifierref to new local variable
for (variable in checker.anonymousVariablesFromHeap.values) {
val scope = variable.first.definingScope()
scope.statements.add(variable.second)
val parent = variable.first.parent
when {
parent is Assignment && parent.value === variable.first -> {
val idref = IdentifierReference(listOf("$autoHeapValuePrefix${variable.first.heapId}"), variable.first.position)
idref.linkParents(parent)
parent.value = idref
}
parent is IFunctionCall -> {
val parameterPos = parent.arglist.indexOf(variable.first)
val idref = IdentifierReference(listOf("$autoHeapValuePrefix${variable.first.heapId}"), variable.first.position)
idref.linkParents(parent)
parent.arglist[parameterPos] = idref
}
parent is ForLoop -> {
val idref = IdentifierReference(listOf("$autoHeapValuePrefix${variable.first.heapId}"), variable.first.position)
idref.linkParents(parent)
parent.iterable = idref
}
else -> TODO("replace literalvalue by identifierref: $variable (in $parent)")
}
variable.second.linkParents(scope as Node)
}
printErrors(checker.result(), name)
}

848
compiler/src/prog8/ast/expressions/AstExpressions.kt
View File

File diff suppressed because it is too large Load Diff

60
compiler/src/prog8/ast/expressions/InferredTypes.kt Normal file
View File

@ -0,0 +1,60 @@
package prog8.ast.expressions
import java.util.Objects
import prog8.ast.base.DataType
object InferredTypes {
class InferredType private constructor(val isUnknown: Boolean, val isVoid: Boolean, private var datatype: DataType?) {
init {
require(!(datatype!=null && (isUnknown || isVoid))) { "invalid combination of args" }
}
val isKnown = datatype!=null
fun typeOrElse(alternative: DataType) = if(isUnknown || isVoid) alternative else datatype!!
infix fun istype(type: DataType): Boolean = if(isUnknown || isVoid) false else this.datatype==type
companion object {
fun unknown() = InferredType(isUnknown = true, isVoid = false, datatype = null)
fun void() = InferredType(isUnknown = false, isVoid = true, datatype = null)
fun known(type: DataType) = InferredType(isUnknown = false, isVoid = false, datatype = type)
}
override fun equals(other: Any?): Boolean {
if(other !is InferredType)
return false
return isVoid==other.isVoid && datatype==other.datatype
}
override fun toString(): String {
return when {
datatype!=null -> datatype.toString()
isVoid -> "<void>"
else -> "<unknown>"
}
}
override fun hashCode(): Int = Objects.hash(isVoid, datatype)
}
private val unknownInstance = InferredType.unknown()
private val voidInstance = InferredType.void()
private val knownInstances = mapOf(
DataType.UBYTE to InferredType.known(DataType.UBYTE),
DataType.BYTE to InferredType.known(DataType.BYTE),
DataType.UWORD to InferredType.known(DataType.UWORD),
DataType.WORD to InferredType.known(DataType.WORD),
DataType.FLOAT to InferredType.known(DataType.FLOAT),
DataType.STR to InferredType.known(DataType.STR),
DataType.ARRAY_UB to InferredType.known(DataType.ARRAY_UB),
DataType.ARRAY_B to InferredType.known(DataType.ARRAY_B),
DataType.ARRAY_UW to InferredType.known(DataType.ARRAY_UW),
DataType.ARRAY_W to InferredType.known(DataType.ARRAY_W),
DataType.ARRAY_F to InferredType.known(DataType.ARRAY_F),
DataType.STRUCT to InferredType.known(DataType.STRUCT)
)
fun void() = voidInstance
fun unknown() = unknownInstance
fun knownFor(type: DataType) = knownInstances.getValue(type)
}

47
compiler/src/prog8/ast/processing/AnonymousScopeVarsCleanup.kt Normal file
View File

@ -0,0 +1,47 @@
package prog8.ast.processing
import prog8.ast.Program
import prog8.ast.base.AstException
import prog8.ast.base.NameError
import prog8.ast.statements.AnonymousScope
import prog8.ast.statements.Statement
import prog8.ast.statements.VarDecl
class AnonymousScopeVarsCleanup(val program: Program): IAstModifyingVisitor {
private val checkResult: MutableList<AstException> = mutableListOf()
private val varsToMove: MutableMap<AnonymousScope, List<VarDecl>> = mutableMapOf()
fun result(): List<AstException> {
return checkResult
}
override fun visit(program: Program) {
varsToMove.clear()
super.visit(program)
for((scope, decls) in varsToMove) {
val sub = scope.definingSubroutine()!!
val existingVariables = sub.statements.filterIsInstance<VarDecl>().associateBy { it.name }
var conflicts = false
decls.forEach {
val existing = existingVariables[it.name]
if (existing!=null) {
checkResult.add(NameError("variable ${it.name} already defined in subroutine ${sub.name} at ${existing.position}", it.position))
conflicts = true
}
}
if (!conflicts) {
decls.forEach { scope.remove(it) }
sub.statements.addAll(0, decls)
decls.forEach { it.parent = sub }
}
}
}
override fun visit(scope: AnonymousScope): Statement {
val scope2 = super.visit(scope) as AnonymousScope
val vardecls = scope2.statements.filterIsInstance<VarDecl>()
varsToMove[scope2] = vardecls
return scope2
}
}

933
compiler/src/prog8/ast/processing/AstChecker.kt
View File

File diff suppressed because it is too large Load Diff

296
compiler/src/prog8/ast/processing/AstIdentifiersChecker.kt
View File

@ -1,32 +1,43 @@
package prog8.ast.processing
import prog8.ast.*
import prog8.ast.INameScope
import prog8.ast.Module
import prog8.ast.Node
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.base.autoHeapValuePrefix
import prog8.ast.expressions.*
import prog8.ast.statements.*
import prog8.compiler.target.CompilationTarget
import prog8.functions.BuiltinFunctions
internal class AstIdentifiersChecker(private val namespace: INameScope) : IAstModifyingVisitor {
internal class AstIdentifiersChecker(private val program: Program) : IAstModifyingVisitor {
private val checkResult: MutableList<AstException> = mutableListOf()
private var blocks: MutableMap<String, Block> = mutableMapOf()
private var blocks = mutableMapOf<String, Block>()
private val vardeclsToAdd = mutableMapOf<INameScope, MutableList<VarDecl>>()
internal fun result(): List<AstException> {
return checkResult
}
private fun nameError(name: String, position: Position, existing: IStatement) {
private fun nameError(name: String, position: Position, existing: Statement) {
checkResult.add(NameError("name conflict '$name', also defined in ${existing.position.file} line ${existing.position.line}", position))
}
override fun visit(module: Module) {
vardeclsToAdd.clear()
blocks.clear() // blocks may be redefined within a different module
super.visit(module)
// add any new vardecls to the various scopes
for((where, decls) in vardeclsToAdd) {
where.statements.addAll(0, decls)
decls.forEach { it.linkParents(where as Node) }
}
}
override fun visit(block: Block): IStatement {
override fun visit(block: Block): Statement {
val existing = blocks[block.name]
if(existing!=null)
nameError(block.name, block.position, existing)
@ -36,17 +47,17 @@ internal class AstIdentifiersChecker(private val namespace: INameScope) : IAstMo
return super.visit(block)
}
override fun visit(functionCall: FunctionCall): IExpression {
override fun visit(functionCall: FunctionCall): Expression {
if(functionCall.target.nameInSource.size==1 && functionCall.target.nameInSource[0]=="lsb") {
// lsb(...) is just an alias for type cast to ubyte, so replace with "... as ubyte"
val typecast = TypecastExpression(functionCall.arglist.single(), DataType.UBYTE, false, functionCall.position)
val typecast = TypecastExpression(functionCall.args.single(), DataType.UBYTE, false, functionCall.position)
typecast.linkParents(functionCall.parent)
return super.visit(typecast)
}
return super.visit(functionCall)
}
override fun visit(decl: VarDecl): IStatement {
override fun visit(decl: VarDecl): Statement {
// first, check if there are datatype errors on the vardecl
decl.datatypeErrors.forEach { checkResult.add(it) }
@ -55,25 +66,65 @@ internal class AstIdentifiersChecker(private val namespace: INameScope) : IAstMo
// the builtin functions can't be redefined
checkResult.add(NameError("builtin function cannot be redefined", decl.position))
val existing = namespace.lookup(listOf(decl.name), decl)
if(decl.name in CompilationTarget.machine.opcodeNames)
checkResult.add(NameError("can't use a cpu opcode name as a symbol: '${decl.name}'", decl.position))
// is it a struct variable? then define all its struct members as mangled names,
// and include the original decl as well.
if(decl.datatype==DataType.STRUCT) {
if(decl.structHasBeenFlattened)
return super.visit(decl) // don't do this multiple times
if(decl.struct==null) {
checkResult.add(NameError("undefined struct type", decl.position))
return super.visit(decl)
}
if(decl.struct!!.statements.any { (it as VarDecl).datatype !in NumericDatatypes})
return super.visit(decl) // a non-numeric member, not supported. proper error is given by AstChecker later
if(decl.value is NumericLiteralValue) {
checkResult.add(ExpressionError("you cannot initialize a struct using a single value", decl.position))
return super.visit(decl)
}
val decls = decl.flattenStructMembers()
decls.add(decl)
val result = AnonymousScope(decls, decl.position)
result.linkParents(decl.parent)
return result
}
val existing = program.namespace.lookup(listOf(decl.name), decl)
if (existing != null && existing !== decl)
nameError(decl.name, decl.position, existing)
return super.visit(decl)
}
override fun visit(subroutine: Subroutine): IStatement {
if(subroutine.name in BuiltinFunctions) {
override fun visit(subroutine: Subroutine): Statement {
if(subroutine.name in CompilationTarget.machine.opcodeNames) {
checkResult.add(NameError("can't use a cpu opcode name as a symbol: '${subroutine.name}'", subroutine.position))
} else if(subroutine.name in BuiltinFunctions) {
// the builtin functions can't be redefined
checkResult.add(NameError("builtin function cannot be redefined", subroutine.position))
} else {
if (subroutine.parameters.any { it.name in BuiltinFunctions })
checkResult.add(NameError("builtin function name cannot be used as parameter", subroutine.position))
// already reported elsewhere:
// if (subroutine.parameters.any { it.name in BuiltinFunctions })
// checkResult.add(NameError("builtin function name cannot be used as parameter", subroutine.position))
val existing = namespace.lookup(listOf(subroutine.name), subroutine)
val existing = program.namespace.lookup(listOf(subroutine.name), subroutine)
if (existing != null && existing !== subroutine)
nameError(subroutine.name, subroutine.position, existing)
// does the parameter redefine a variable declared elsewhere?
for(param in subroutine.parameters) {
val existingVar = subroutine.lookup(listOf(param.name), subroutine)
if (existingVar != null && existingVar.parent !== subroutine) {
nameError(param.name, param.position, existingVar)
}
}
// check that there are no local variables, labels, or other subs that redefine the subroutine's parameters
val symbolsInSub = subroutine.allDefinedSymbols()
val namesInSub = symbolsInSub.map{ it.first }.toSet()
@ -92,69 +143,64 @@ internal class AstIdentifiersChecker(private val namespace: INameScope) : IAstMo
// NOTE:
// - numeric types BYTE and WORD and FLOAT are passed by value;
// - strings, arrays, matrices are passed by reference (their 16-bit address is passed as an uword parameter)
// - do NOT do this is the statement can be transformed into an asm subroutine later!
if(subroutine.asmAddress==null && !subroutine.canBeAsmSubroutine) {
if(subroutine.asmAddress==null) {
if(subroutine.asmParameterRegisters.isEmpty()) {
subroutine.parameters
.filter { it.name !in namesInSub }
.forEach {
val vardecl = VarDecl(VarDeclType.VAR, it.type, false, null, it.name, null,
isArray = false, autoGenerated = true, position = subroutine.position)
val vardecl = VarDecl(VarDeclType.VAR, it.type, ZeropageWish.NOT_IN_ZEROPAGE, null, it.name, null, null,
isArray = false, autogeneratedDontRemove = true, position = subroutine.position)
vardecl.linkParents(subroutine)
subroutine.statements.add(0, vardecl)
}
}
}
if(subroutine.isAsmSubroutine && subroutine.statements.any{it !is InlineAssembly}) {
checkResult.add(SyntaxError("asmsub can only contain inline assembly (%asm)", subroutine.position))
}
}
return super.visit(subroutine)
}
override fun visit(label: Label): IStatement {
override fun visit(label: Label): Statement {
if(label.name in CompilationTarget.machine.opcodeNames)
checkResult.add(NameError("can't use a cpu opcode name as a symbol: '${label.name}'", label.position))
if(label.name in BuiltinFunctions) {
// the builtin functions can't be redefined
checkResult.add(NameError("builtin function cannot be redefined", label.position))
} else {
val existing = namespace.lookup(listOf(label.name), label)
val existing = program.namespace.lookup(listOf(label.name), label)
if (existing != null && existing !== label)
nameError(label.name, label.position, existing)
}
return super.visit(label)
}
override fun visit(forLoop: ForLoop): IStatement {
override fun visit(forLoop: ForLoop): Statement {
// If the for loop has a decltype, it means to declare the loopvar inside the loop body
// rather than reusing an already declared loopvar from an outer scope.
// For loops that loop over an interable variable (instead of a range of numbers) get an
// additional interation count variable in their scope.
if(forLoop.loopRegister!=null) {
if(forLoop.decltype!=null)
checkResult.add(SyntaxError("register loop variables have a fixed implicit datatype", forLoop.position))
if(forLoop.loopRegister == Register.X)
printWarning("writing to the X register is dangerous, because it's used as an internal pointer", forLoop.position)
} else if(forLoop.loopVar!=null) {
val varName = forLoop.loopVar.nameInSource.last()
if(forLoop.decltype!=null) {
val existing = if(forLoop.body.containsNoCodeNorVars()) null else forLoop.body.lookup(forLoop.loopVar.nameInSource, forLoop.body.statements.first())
if(existing==null) {
// create the local scoped for loop variable itself
val vardecl = VarDecl(VarDeclType.VAR, forLoop.decltype, forLoop.zeropage, null, varName, null,
isArray = false, autoGenerated = true, position = forLoop.loopVar.position)
vardecl.linkParents(forLoop.body)
forLoop.body.statements.add(0, vardecl)
forLoop.loopVar.parent = forLoop.body // loopvar 'is defined in the body'
}
}
if(forLoop.iterable !is RangeExpr) {
val existing = if(forLoop.body.containsNoCodeNorVars()) null else forLoop.body.lookup(listOf(ForLoop.iteratorLoopcounterVarname), forLoop.body.statements.first())
if(existing==null) {
// create loop iteration counter variable (without value, to avoid an assignment)
val vardecl = VarDecl(VarDeclType.VAR, DataType.UBYTE, true, null, ForLoop.iteratorLoopcounterVarname, null,
isArray = false, autoGenerated = true, position = forLoop.loopVar.position)
vardecl.linkParents(forLoop.body)
forLoop.body.statements.add(0, vardecl)
forLoop.loopVar.parent = forLoop.body // loopvar 'is defined in the body'
} else {
val loopVar = forLoop.loopVar
if (loopVar != null) {
val validName = forLoop.body.name.replace("<", "").replace(">", "").replace("-", "")
val loopvarName = "prog8_loopvar_$validName"
if (forLoop.iterable !is RangeExpr) {
val existing = if (forLoop.body.containsNoCodeNorVars()) null else forLoop.body.lookup(listOf(loopvarName), forLoop.body.statements.first())
if (existing == null) {
// create loop iteration counter variable (without value, to avoid an assignment)
val vardecl = VarDecl(VarDeclType.VAR, DataType.UBYTE, ZeropageWish.PREFER_ZEROPAGE, null, loopvarName, null, null,
isArray = false, autogeneratedDontRemove = true, position = loopVar.position)
vardecl.linkParents(forLoop.body)
forLoop.body.statements.add(0, vardecl)
loopVar.parent = forLoop.body // loopvar 'is defined in the body'
}
}
}
}
@ -167,50 +213,138 @@ internal class AstIdentifiersChecker(private val namespace: INameScope) : IAstMo
return super.visit(assignTarget)
}
override fun visit(returnStmt: Return): IStatement {
if(returnStmt.values.isNotEmpty()) {
override fun visit(returnStmt: Return): Statement {
if(returnStmt.value!=null) {
// possibly adjust any literal values returned, into the desired returning data type
val subroutine = returnStmt.definingSubroutine()!!
if(subroutine.returntypes.size!=returnStmt.values.size)
if(subroutine.returntypes.size!=1)
return returnStmt // mismatch in number of return values, error will be printed later.
val newValues = mutableListOf<IExpression>()
for(returnvalue in returnStmt.values.zip(subroutine.returntypes)) {
val lval = returnvalue.first as? LiteralValue
if(lval!=null) {
val adjusted = lval.cast(returnvalue.second)
if(adjusted!=null && adjusted !== lval)
newValues.add(adjusted)
else
newValues.add(lval)
}
else
newValues.add(returnvalue.first)
}
returnStmt.values = newValues
val lval = returnStmt.value as? NumericLiteralValue
returnStmt.value = lval?.cast(subroutine.returntypes.single()) ?: returnStmt.value!!
}
return super.visit(returnStmt)
}
internal val anonymousVariablesFromHeap = mutableMapOf<String, Pair<LiteralValue, VarDecl>>()
override fun visit(literalValue: LiteralValue): LiteralValue {
if(literalValue.heapId!=null && literalValue.parent !is VarDecl) {
// a literal value that's not declared as a variable, which refers to something on the heap.
// we need to introduce an auto-generated variable for this to be able to refer to the value!
val variable = VarDecl(VarDeclType.VAR, literalValue.type, false, null, "$autoHeapValuePrefix${literalValue.heapId}", literalValue,
isArray = false, autoGenerated = false, position = literalValue.position)
anonymousVariablesFromHeap[variable.name] = Pair(literalValue, variable)
override fun visit(arrayLiteral: ArrayLiteralValue): Expression {
val array = super.visit(arrayLiteral)
if(array is ArrayLiteralValue) {
val vardecl = array.parent as? VarDecl
// adjust the datatype of the array (to an educated guess)
if(vardecl!=null) {
val arrayDt = array.type
if(!arrayDt.istype(vardecl.datatype)) {
val cast = array.cast(vardecl.datatype)
if (cast != null) {
vardecl.value = cast
cast.linkParents(vardecl)
return cast
}
}
return array
}
else {
val arrayDt = array.guessDatatype(program)
if(arrayDt.isKnown) {
// this array literal is part of an expression, turn it into an identifier reference
val litval2 = array.cast(arrayDt.typeOrElse(DataType.STRUCT))
return if (litval2 != null) {
litval2.parent = array.parent
makeIdentifierFromRefLv(litval2)
} else array
}
}
}
return super.visit(literalValue)
return array
}
override fun visit(addressOf: AddressOf): IExpression {
// register the scoped name of the referenced identifier
val variable= addressOf.identifier.targetVarDecl(namespace) ?: return addressOf
addressOf.scopedname = variable.scopedname
return super.visit(addressOf)
override fun visit(stringLiteral: StringLiteralValue): Expression {
val string = super.visit(stringLiteral)
if(string is StringLiteralValue) {
val vardecl = string.parent as? VarDecl
// intern the string; move it into the heap
if (string.value.length !in 1..255)
checkResult.add(ExpressionError("string literal length must be between 1 and 255", string.position))
return if (vardecl != null)
string
else
makeIdentifierFromRefLv(string) // replace the literal string by a identifier reference.
}
return string
}
private fun makeIdentifierFromRefLv(array: ArrayLiteralValue): IdentifierReference {
// a referencetype literal value that's not declared as a variable
// we need to introduce an auto-generated variable for this to be able to refer to the value
// note: if the var references the same literal value, it is not yet de-duplicated here.
val scope = array.definingScope()
val variable = VarDecl.createAuto(array)
return replaceWithIdentifier(variable, scope, array.parent)
}
private fun makeIdentifierFromRefLv(string: StringLiteralValue): IdentifierReference {
// a referencetype literal value that's not declared as a variable
// we need to introduce an auto-generated variable for this to be able to refer to the value
// note: if the var references the same literal value, it is not yet de-duplicated here.
val scope = string.definingScope()
val variable = VarDecl.createAuto(string)
return replaceWithIdentifier(variable, scope, string.parent)
}
private fun replaceWithIdentifier(variable: VarDecl, scope: INameScope, parent: Node): IdentifierReference {
val variable1 = addVarDecl(scope, variable)
// replace the reference literal by a identifier reference
val identifier = IdentifierReference(listOf(variable1.name), variable1.position)
identifier.parent = parent
return identifier
}
override fun visit(structDecl: StructDecl): Statement {
for(member in structDecl.statements){
val decl = member as? VarDecl
if(decl!=null && decl.datatype !in NumericDatatypes)
checkResult.add(SyntaxError("structs can only contain numerical types", decl.position))
}
return super.visit(structDecl)
}
override fun visit(expr: BinaryExpression): Expression {
return when {
expr.left is StringLiteralValue ->
processBinaryExprWithString(expr.left as StringLiteralValue, expr.right, expr)
expr.right is StringLiteralValue ->
processBinaryExprWithString(expr.right as StringLiteralValue, expr.left, expr)
else -> super.visit(expr)
}
}
private fun processBinaryExprWithString(string: StringLiteralValue, operand: Expression, expr: BinaryExpression): Expression {
val constvalue = operand.constValue(program)
if(constvalue!=null) {
if (expr.operator == "*") {
// repeat a string a number of times
return StringLiteralValue(string.value.repeat(constvalue.number.toInt()), string.altEncoding, expr.position)
}
}
if(expr.operator == "+" && operand is StringLiteralValue) {
// concatenate two strings
return StringLiteralValue("${string.value}${operand.value}", string.altEncoding, expr.position)
}
return expr
}
private fun addVarDecl(scope: INameScope, variable: VarDecl): VarDecl {
if(scope !in vardeclsToAdd)
vardeclsToAdd[scope] = mutableListOf()
val declList = vardeclsToAdd.getValue(scope)
val existing = declList.singleOrNull { it.name==variable.name }
return if(existing!=null) {
existing
} else {
declList.add(variable)
variable
}
}
}

2
compiler/src/prog8/ast/processing/AstRecursionChecker.kt
View File

@ -1,6 +1,6 @@
package prog8.ast.processing
import prog8.ast.*
import prog8.ast.INameScope
import prog8.ast.base.AstException
import prog8.ast.expressions.FunctionCall
import prog8.ast.statements.FunctionCallStatement

154
compiler/src/prog8/ast/processing/IAstModifyingVisitor.kt
View File

@ -1,6 +1,8 @@
package prog8.ast.processing
import prog8.ast.*
import prog8.ast.Module
import prog8.ast.Program
import prog8.ast.base.FatalAstException
import prog8.ast.expressions.*
import prog8.ast.statements.*
@ -10,63 +12,67 @@ interface IAstModifyingVisitor {
}
fun visit(module: Module) {
module.statements = module.statements.asSequence().map { it.accept(this) }.toMutableList()
module.statements = module.statements.map { it.accept(this) }.toMutableList()
}
fun visit(expr: PrefixExpression): IExpression {
fun visit(expr: PrefixExpression): Expression {
expr.expression = expr.expression.accept(this)
return expr
}
fun visit(expr: BinaryExpression): IExpression {
fun visit(expr: BinaryExpression): Expression {
expr.left = expr.left.accept(this)
expr.right = expr.right.accept(this)
return expr
}
fun visit(directive: Directive): IStatement {
fun visit(directive: Directive): Statement {
return directive
}
fun visit(block: Block): IStatement {
block.statements = block.statements.asSequence().map { it.accept(this) }.toMutableList()
fun visit(block: Block): Statement {
block.statements = block.statements.map { it.accept(this) }.toMutableList()
return block
}
fun visit(decl: VarDecl): IStatement {
fun visit(decl: VarDecl): Statement {
decl.value = decl.value?.accept(this)
decl.arraysize?.accept(this)
return decl
}
fun visit(subroutine: Subroutine): IStatement {
subroutine.statements = subroutine.statements.asSequence().map { it.accept(this) }.toMutableList()
fun visit(subroutine: Subroutine): Statement {
subroutine.statements = subroutine.statements.map { it.accept(this) }.toMutableList()
return subroutine
}
fun visit(functionCall: FunctionCall): IExpression {
fun visit(functionCall: FunctionCall): Expression {
val newtarget = functionCall.target.accept(this)
if(newtarget is IdentifierReference)
functionCall.target = newtarget
functionCall.arglist = functionCall.arglist.map { it.accept(this) }.toMutableList()
else
throw FatalAstException("cannot change class of function call target")
functionCall.args = functionCall.args.map { it.accept(this) }.toMutableList()
return functionCall
}
fun visit(functionCallStatement: FunctionCallStatement): IStatement {
fun visit(functionCallStatement: FunctionCallStatement): Statement {
val newtarget = functionCallStatement.target.accept(this)
if(newtarget is IdentifierReference)
functionCallStatement.target = newtarget
functionCallStatement.arglist = functionCallStatement.arglist.map { it.accept(this) }.toMutableList()
else
throw FatalAstException("cannot change class of function call target")
functionCallStatement.args = functionCallStatement.args.map { it.accept(this) }.toMutableList()
return functionCallStatement
}
fun visit(identifier: IdentifierReference): IExpression {
fun visit(identifier: IdentifierReference): Expression {
// note: this is an identifier that is used in an expression.
// other identifiers are simply part of the other statements (such as jumps, subroutine defs etc)
return identifier
}
fun visit(jump: Jump): IStatement {
fun visit(jump: Jump): Statement {
if(jump.identifier!=null) {
val ident = jump.identifier.accept(this)
if(ident is IdentifierReference && ident!==jump.identifier) {
@ -76,107 +82,123 @@ interface IAstModifyingVisitor {
return jump
}
fun visit(ifStatement: IfStatement): IStatement {
fun visit(ifStatement: IfStatement): Statement {
ifStatement.condition = ifStatement.condition.accept(this)
ifStatement.truepart = ifStatement.truepart.accept(this) as AnonymousScope
ifStatement.elsepart = ifStatement.elsepart.accept(this) as AnonymousScope
return ifStatement
}
fun visit(branchStatement: BranchStatement): IStatement {
fun visit(branchStatement: BranchStatement): Statement {
branchStatement.truepart = branchStatement.truepart.accept(this) as AnonymousScope
branchStatement.elsepart = branchStatement.elsepart.accept(this) as AnonymousScope
return branchStatement
}
fun visit(range: RangeExpr): IExpression {
fun visit(range: RangeExpr): Expression {
range.from = range.from.accept(this)
range.to = range.to.accept(this)
range.step = range.step.accept(this)
return range
}
fun visit(label: Label): IStatement {
fun visit(label: Label): Statement {
return label
}
fun visit(literalValue: LiteralValue): LiteralValue {
if(literalValue.arrayvalue!=null) {
for(av in literalValue.arrayvalue.withIndex()) {
val newvalue = av.value.accept(this)
literalValue.arrayvalue[av.index] = newvalue
}
}
fun visit(literalValue: NumericLiteralValue): NumericLiteralValue {
return literalValue
}
fun visit(assignment: Assignment): IStatement {
assignment.targets = assignment.targets.map { it.accept(this) }
fun visit(stringLiteral: StringLiteralValue): Expression {
return stringLiteral
}
fun visit(arrayLiteral: ArrayLiteralValue): Expression {
for(av in arrayLiteral.value.withIndex()) {
val newvalue = av.value.accept(this)
arrayLiteral.value[av.index] = newvalue
}
return arrayLiteral
}
fun visit(assignment: Assignment): Statement {
assignment.target = assignment.target.accept(this)
assignment.value = assignment.value.accept(this)
return assignment
}
fun visit(postIncrDecr: PostIncrDecr): IStatement {
fun visit(postIncrDecr: PostIncrDecr): Statement {
postIncrDecr.target = postIncrDecr.target.accept(this)
return postIncrDecr
}
fun visit(contStmt: Continue): IStatement {
fun visit(contStmt: Continue): Statement {
return contStmt
}
fun visit(breakStmt: Break): IStatement {
fun visit(breakStmt: Break): Statement {
return breakStmt
}
fun visit(forLoop: ForLoop): IStatement {
forLoop.loopVar?.accept(this)
fun visit(forLoop: ForLoop): Statement {
when(val newloopvar = forLoop.loopVar?.accept(this)) {
is IdentifierReference -> forLoop.loopVar = newloopvar
null -> forLoop.loopVar = null
else -> throw FatalAstException("can't change class of loopvar")
}
forLoop.iterable = forLoop.iterable.accept(this)
forLoop.body = forLoop.body.accept(this) as AnonymousScope
return forLoop
}
fun visit(whileLoop: WhileLoop): IStatement {
fun visit(whileLoop: WhileLoop): Statement {
whileLoop.condition = whileLoop.condition.accept(this)
whileLoop.body = whileLoop.body.accept(this) as AnonymousScope
return whileLoop
}
fun visit(repeatLoop: RepeatLoop): IStatement {
fun visit(repeatLoop: RepeatLoop): Statement {
repeatLoop.untilCondition = repeatLoop.untilCondition.accept(this)
repeatLoop.body = repeatLoop.body.accept(this) as AnonymousScope
return repeatLoop
}
fun visit(returnStmt: Return): IStatement {
returnStmt.values = returnStmt.values.map { it.accept(this) }
fun visit(returnStmt: Return): Statement {
returnStmt.value = returnStmt.value?.accept(this)
return returnStmt
}
fun visit(arrayIndexedExpression: ArrayIndexedExpression): IExpression {
arrayIndexedExpression.identifier.accept(this)
fun visit(arrayIndexedExpression: ArrayIndexedExpression): ArrayIndexedExpression {
val ident = arrayIndexedExpression.identifier.accept(this)
if(ident is IdentifierReference)
arrayIndexedExpression.identifier = ident
arrayIndexedExpression.arrayspec.accept(this)
return arrayIndexedExpression
}
fun visit(assignTarget: AssignTarget): AssignTarget {
assignTarget.arrayindexed?.accept(this)
assignTarget.identifier?.accept(this)
when (val ident = assignTarget.identifier?.accept(this)) {
is IdentifierReference -> assignTarget.identifier = ident
null -> assignTarget.identifier = null
else -> throw FatalAstException("can't change class of assign target identifier")
}
assignTarget.arrayindexed = assignTarget.arrayindexed?.accept(this)
assignTarget.memoryAddress?.let { visit(it) }
return assignTarget
}
fun visit(scope: AnonymousScope): IStatement {
scope.statements = scope.statements.asSequence().map { it.accept(this) }.toMutableList()
fun visit(scope: AnonymousScope): Statement {
scope.statements = scope.statements.map { it.accept(this) }.toMutableList()
return scope
}
fun visit(typecast: TypecastExpression): IExpression {
fun visit(typecast: TypecastExpression): Expression {
typecast.expression = typecast.expression.accept(this)
return typecast
}
fun visit(memread: DirectMemoryRead): IExpression {
fun visit(memread: DirectMemoryRead): Expression {
memread.addressExpression = memread.addressExpression.accept(this)
return memread
}
@ -185,35 +207,55 @@ interface IAstModifyingVisitor {
memwrite.addressExpression = memwrite.addressExpression.accept(this)
}
fun visit(addressOf: AddressOf): IExpression {
addressOf.identifier.accept(this)
fun visit(addressOf: AddressOf): Expression {
val ident = addressOf.identifier.accept(this)
if(ident is IdentifierReference)
addressOf.identifier = ident
else
throw FatalAstException("can't change class of addressof identifier")
return addressOf
}
fun visit(inlineAssembly: InlineAssembly): IStatement {
fun visit(inlineAssembly: InlineAssembly): Statement {
return inlineAssembly
}
fun visit(registerExpr: RegisterExpr): IExpression {
fun visit(registerExpr: RegisterExpr): Expression {
return registerExpr
}
fun visit(builtinFunctionStatementPlaceholder: BuiltinFunctionStatementPlaceholder): IStatement {
fun visit(builtinFunctionStatementPlaceholder: BuiltinFunctionStatementPlaceholder): Statement {
return builtinFunctionStatementPlaceholder
}
fun visit(nopStatement: NopStatement): IStatement {
fun visit(nopStatement: NopStatement): Statement {
return nopStatement
}
fun visit(whenStatement: WhenStatement): IStatement {
whenStatement.condition.accept(this)
fun visit(whenStatement: WhenStatement): Statement {
whenStatement.condition = whenStatement.condition.accept(this)
whenStatement.choices.forEach { it.accept(this) }
return whenStatement
}
fun visit(whenChoice: WhenChoice) {
whenChoice.value?.accept(this)
whenChoice.statements.accept(this)
whenChoice.values = whenChoice.values?.map { it.accept(this) }
val stmt = whenChoice.statements.accept(this)
if(stmt is AnonymousScope)
whenChoice.statements = stmt
else {
whenChoice.statements = AnonymousScope(mutableListOf(stmt), stmt.position)
whenChoice.statements.linkParents(whenChoice)
}
}
fun visit(structDecl: StructDecl): Statement {
structDecl.statements = structDecl.statements.map{ it.accept(this) }.toMutableList()
return structDecl
}
fun visit(structLv: StructLiteralValue): Expression {
structLv.values = structLv.values.map { it.accept(this) }
return structLv
}
}

31
compiler/src/prog8/ast/processing/IAstVisitor.kt
View File

@ -1,6 +1,7 @@
package prog8.ast.processing
import prog8.ast.*
import prog8.ast.Module
import prog8.ast.Program
import prog8.ast.expressions.*
import prog8.ast.statements.*
@ -40,12 +41,12 @@ interface IAstVisitor {
fun visit(functionCall: FunctionCall) {
functionCall.target.accept(this)
functionCall.arglist.forEach { it.accept(this) }
functionCall.args.forEach { it.accept(this) }
}
fun visit(functionCallStatement: FunctionCallStatement) {
functionCallStatement.target.accept(this)
functionCallStatement.arglist.forEach { it.accept(this) }
functionCallStatement.args.forEach { it.accept(this) }
}
fun visit(identifier: IdentifierReference) {
@ -75,12 +76,18 @@ interface IAstVisitor {
fun visit(label: Label) {
}
fun visit(literalValue: LiteralValue) {
literalValue.arrayvalue?.let { it.forEach { v->v.accept(this) }}
fun visit(numLiteral: NumericLiteralValue) {
}
fun visit(string: StringLiteralValue) {
}
fun visit(array: ArrayLiteralValue) {
array.value.forEach { v->v.accept(this) }
}
fun visit(assignment: Assignment) {
assignment.targets.forEach { it.accept(this) }
assignment.target.accept(this)
assignment.value.accept(this)
}
@ -111,7 +118,7 @@ interface IAstVisitor {
}
fun visit(returnStmt: Return) {
returnStmt.values.forEach { it.accept(this) }
returnStmt.value?.accept(this)
}
fun visit(arrayIndexedExpression: ArrayIndexedExpression) {
@ -163,7 +170,15 @@ interface IAstVisitor {
}
fun visit(whenChoice: WhenChoice) {
whenChoice.value?.accept(this)
whenChoice.values?.forEach { it.accept(this) }
whenChoice.statements.accept(this)
}
fun visit(structDecl: StructDecl) {
structDecl.statements.forEach { it.accept(this) }
}
fun visit(structLv: StructLiteralValue) {
structLv.values.forEach { it.accept(this) }
}
}

5
compiler/src/prog8/ast/processing/ImportedModuleDirectiveRemover.kt
View File

@ -1,9 +1,10 @@
package prog8.ast.processing
import prog8.ast.*
import prog8.ast.Module
import prog8.ast.base.SyntaxError
import prog8.ast.base.printWarning
import prog8.ast.statements.Directive
import prog8.ast.statements.Statement
internal class ImportedModuleDirectiveRemover : IAstModifyingVisitor {
private val checkResult: MutableList<SyntaxError> = mutableListOf()
@ -17,7 +18,7 @@ internal class ImportedModuleDirectiveRemover : IAstModifyingVisitor {
*/
override fun visit(module: Module) {
super.visit(module)
val newStatements : MutableList<IStatement> = mutableListOf()
val newStatements : MutableList<Statement> = mutableListOf()
val moduleLevelDirectives = listOf("%output", "%launcher", "%zeropage", "%zpreserved", "%address")
for (sourceStmt in module.statements) {

247
compiler/src/prog8/ast/processing/StatementReorderer.kt
View File

@ -1,16 +1,51 @@
package prog8.ast.processing
import kotlin.comparisons.nullsLast
import prog8.ast.*
import prog8.ast.base.DataType
import prog8.ast.base.FatalAstException
import prog8.ast.base.initvarsSubName
import prog8.ast.base.printWarning
import prog8.ast.expressions.BinaryExpression
import prog8.ast.expressions.FunctionCall
import prog8.ast.expressions.TypecastExpression
import prog8.ast.expressions.*
import prog8.ast.statements.*
import prog8.functions.BuiltinFunctions
private fun flattenStructAssignmentFromIdentifier(structAssignment: Assignment, program: Program): List<Assignment> {
val identifier = structAssignment.target.identifier!!
val identifierName = identifier.nameInSource.single()
val targetVar = identifier.targetVarDecl(program.namespace)!!
val struct = targetVar.struct!!
when (structAssignment.value) {
is IdentifierReference -> {
val sourceVar = (structAssignment.value as IdentifierReference).targetVarDecl(program.namespace)!!
if (sourceVar.struct == null)
throw FatalAstException("can only assign arrays or structs to structs")
// struct memberwise copy
val sourceStruct = sourceVar.struct!!
if(sourceStruct!==targetVar.struct) {
// structs are not the same in assignment
return listOf() // error will be printed elsewhere
}
return struct.statements.zip(sourceStruct.statements).map { member ->
val targetDecl = member.first as VarDecl
val sourceDecl = member.second as VarDecl
if(targetDecl.name != sourceDecl.name)
throw FatalAstException("struct member mismatch")
val mangled = mangledStructMemberName(identifierName, targetDecl.name)
val idref = IdentifierReference(listOf(mangled), structAssignment.position)
val sourcemangled = mangledStructMemberName(sourceVar.name, sourceDecl.name)
val sourceIdref = IdentifierReference(listOf(sourcemangled), structAssignment.position)
val assign = Assignment(AssignTarget(null, idref, null, null, structAssignment.position),
null, sourceIdref, member.second.position)
assign.linkParents(structAssignment)
assign
}
}
is StructLiteralValue -> {
throw IllegalArgumentException("not going to flatten a structLv assignment here")
}
else -> throw FatalAstException("strange struct value")
}
}
internal class StatementReorderer(private val program: Program): IAstModifyingVisitor {
// Reorders the statements in a way the compiler needs.
@ -24,13 +59,13 @@ internal class StatementReorderer(private val program: Program): IAstModifyingVi
// - the 'start' subroutine in the 'main' block will be moved to the top immediately following the directives.
// - all other subroutines will be moved to the end of their block.
// - sorts the choices in when statement.
//
// Also, makes sure any value assignments get the proper type casts if needed to cast them into the target variable's type.
// (this includes function call arguments)
private val directivesToMove = setOf("%output", "%launcher", "%zeropage", "%zpreserved", "%address", "%option")
private val addReturns = mutableListOf<Pair<INameScope, Int>>()
override fun visit(module: Module) {
addReturns.clear()
super.visit(module)
val (blocks, other) = module.statements.partition { it is Block }
@ -58,9 +93,16 @@ internal class StatementReorderer(private val program: Program): IAstModifyingVi
val directives = module.statements.filter {it is Directive && it.directive in directivesToMove}
module.statements.removeAll(directives)
module.statements.addAll(0, directives)
for(pos in addReturns) {
println(pos)
val returnStmt = Return(null, pos.first.position)
returnStmt.linkParents(pos.first as Node)
pos.first.statements.add(pos.second, returnStmt)
}
}
override fun visit(block: Block): IStatement {
override fun visit(block: Block): Statement {
val subroutines = block.statements.filterIsInstance<Subroutine>()
var numSubroutinesAtEnd = 0
@ -91,7 +133,7 @@ internal class StatementReorderer(private val program: Program): IAstModifyingVi
&& stmtBeforeFirstSub !is Jump
&& stmtBeforeFirstSub !is Subroutine
&& stmtBeforeFirstSub !is BuiltinFunctionStatementPlaceholder) {
val ret = Return(emptyList(), stmtBeforeFirstSub.position)
val ret = Return(null, stmtBeforeFirstSub.position)
ret.linkParents(block)
block.statements.add(block.statements.size - numSubroutinesAtEnd, ret)
}
@ -124,9 +166,22 @@ internal class StatementReorderer(private val program: Program): IAstModifyingVi
return super.visit(block)
}
override fun visit(subroutine: Subroutine): IStatement {
override fun visit(subroutine: Subroutine): Statement {
super.visit(subroutine)
val scope = subroutine.definingScope()
if(scope is Subroutine) {
for(stmt in scope.statements.withIndex()) {
if(stmt.index>0 && stmt.value===subroutine) {
val precedingStmt = scope.statements[stmt.index-1]
if(precedingStmt !is Jump && precedingStmt !is Subroutine) {
// insert a return statement before a nested subroutine, to avoid falling trough inside the subroutine
addReturns.add(Pair(scope, stmt.index))
}
}
}
}
val varDecls = subroutine.statements.filterIsInstance<VarDecl>()
subroutine.statements.removeAll(varDecls)
subroutine.statements.addAll(0, varDecls)
@ -139,7 +194,7 @@ internal class StatementReorderer(private val program: Program): IAstModifyingVi
// and if an assembly block doesn't contain a rts/rti
if(subroutine.asmAddress==null && subroutine.amountOfRtsInAsm()==0) {
if (subroutine.statements.lastOrNull {it !is VarDecl } !is Return) {
val returnStmt = Return(emptyList(), subroutine.position)
val returnStmt = Return(null, subroutine.position)
returnStmt.linkParents(subroutine)
subroutine.statements.add(returnStmt)
}
@ -149,137 +204,55 @@ internal class StatementReorderer(private val program: Program): IAstModifyingVi
return subroutine
}
override fun visit(expr: BinaryExpression): IExpression {
val leftDt = expr.left.inferType(program)
val rightDt = expr.right.inferType(program)
if(leftDt!=null && rightDt!=null && leftDt!=rightDt) {
// determine common datatype and add typecast as required to make left and right equal types
val (commonDt, toFix) = expr.commonDatatype(leftDt, rightDt, expr.left, expr.right)
if(toFix!=null) {
when {
toFix===expr.left -> {
expr.left = TypecastExpression(expr.left, commonDt, true, expr.left.position)
expr.left.linkParents(expr)
}
toFix===expr.right -> {
expr.right = TypecastExpression(expr.right, commonDt, true, expr.right.position)
expr.right.linkParents(expr)
}
else -> throw FatalAstException("confused binary expression side")
override fun visit(assignment: Assignment): Statement {
val assg = super.visit(assignment)
if(assg !is Assignment)
return assg
// see if a typecast is needed to convert the value's type into the proper target type
val valueItype = assg.value.inferType(program)
val targetItype = assg.target.inferType(program, assg)
if(targetItype.isKnown && valueItype.isKnown) {
val targettype = targetItype.typeOrElse(DataType.STRUCT)
val valuetype = valueItype.typeOrElse(DataType.STRUCT)
// struct assignments will be flattened (if it's not a struct literal)
if (valuetype == DataType.STRUCT && targettype == DataType.STRUCT) {
if (assg.value is StructLiteralValue)
return assg // do NOT flatten it at this point!! (the compiler will take care if it, later, if needed)
val assignments = flattenStructAssignmentFromIdentifier(assg, program) // 'structvar1 = structvar2'
return if (assignments.isEmpty()) {
// something went wrong (probably incompatible struct types)
// we'll get an error later from the AstChecker
assg
} else {
val scope = AnonymousScope(assignments.toMutableList(), assg.position)
scope.linkParents(assg.parent)
scope
}
}
}
return super.visit(expr)
}
override fun visit(assignment: Assignment): IStatement {
val target=assignment.singleTarget
if(target!=null) {
// see if a typecast is needed to convert the value's type into the proper target type
val valuetype = assignment.value.inferType(program)
val targettype = target.inferType(program, assignment)
if(targettype!=null && valuetype!=null && valuetype!=targettype) {
if(valuetype isAssignableTo targettype) {
assignment.value = TypecastExpression(assignment.value, targettype, true, assignment.value.position)
assignment.value.linkParents(assignment)
}
// if they're not assignable, we'll get a proper error later from the AstChecker
}
} else TODO("multi-target assign")
return super.visit(assignment)
}
override fun visit(functionCallStatement: FunctionCallStatement): IStatement {
checkFunctionCallArguments(functionCallStatement, functionCallStatement.definingScope())
return super.visit(functionCallStatement)
}
override fun visit(functionCall: FunctionCall): IExpression {
checkFunctionCallArguments(functionCall, functionCall.definingScope())
return super.visit(functionCall)
}
private fun checkFunctionCallArguments(call: IFunctionCall, scope: INameScope) {
// see if a typecast is needed to convert the arguments into the required parameter's type
when(val sub = call.target.targetStatement(scope)) {
is Subroutine -> {
for(arg in sub.parameters.zip(call.arglist.withIndex())) {
val argtype = arg.second.value.inferType(program)
if(argtype!=null) {
val requiredType = arg.first.type
if (requiredType != argtype) {
if (argtype isAssignableTo requiredType) {
val typecasted = TypecastExpression(arg.second.value, requiredType, true, arg.second.value.position)
typecasted.linkParents(arg.second.value.parent)
call.arglist[arg.second.index] = typecasted
}
// if they're not assignable, we'll get a proper error later from the AstChecker
}
if(assg.aug_op!=null) {
// transform augmented assg into normal assg so we have one case less to deal with later
val newTarget: Expression =
when {
assg.target.register != null -> RegisterExpr(assg.target.register!!, assg.target.position)
assg.target.identifier != null -> assg.target.identifier!!
assg.target.arrayindexed != null -> assg.target.arrayindexed!!
assg.target.memoryAddress != null -> DirectMemoryRead(assg.target.memoryAddress!!.addressExpression, assg.value.position)
else -> throw FatalAstException("strange assg")
}
}
}
is BuiltinFunctionStatementPlaceholder -> {
// if(sub.name in setOf("lsl", "lsr", "rol", "ror", "rol2", "ror2", "memset", "memcopy", "memsetw", "swap"))
val func = BuiltinFunctions.getValue(sub.name)
if(func.pure) {
// non-pure functions don't get automatic typecasts because sometimes they act directly on their parameters
for (arg in func.parameters.zip(call.arglist.withIndex())) {
val argtype = arg.second.value.inferType(program)
if (argtype != null) {
if (arg.first.possibleDatatypes.any { argtype == it })
continue
for (possibleType in arg.first.possibleDatatypes) {
if (argtype isAssignableTo possibleType) {
val typecasted = TypecastExpression(arg.second.value, possibleType, true, arg.second.value.position)
typecasted.linkParents(arg.second.value.parent)
call.arglist[arg.second.index] = typecasted
break
}
}
}
}
}
}
null -> {}
else -> TODO("call to something weird $sub ${call.target}")
}
}
private fun sortConstantAssignmentSequence(first: Assignment, stmtIter: MutableIterator<IStatement>): Pair<List<Assignment>, IStatement?> {
val sequence= mutableListOf(first)
var trailing: IStatement? = null
while(stmtIter.hasNext()) {
val next = stmtIter.next()
if(next is Assignment) {
val constValue = next.value.constValue(program)
if(constValue==null) {
trailing = next
break
}
sequence.add(next)
}
else {
trailing=next
break
}
val expression = BinaryExpression(newTarget, assg.aug_op.substringBeforeLast('='), assg.value, assg.position)
expression.linkParents(assg.parent)
val convertedAssignment = Assignment(assg.target, null, expression, assg.position)
convertedAssignment.linkParents(assg.parent)
return super.visit(convertedAssignment)
}
val sorted = sequence.sortedWith(compareBy({it.value.inferType(program)}, {it.singleTarget?.shortString(true)}))
return Pair(sorted, trailing)
}
override fun visit(typecast: TypecastExpression): IExpression {
// warn about any implicit type casts to Float, because that may not be intended
if(typecast.implicit && typecast.type in setOf(DataType.FLOAT, DataType.ARRAY_F)) {
printWarning("byte or word value implicitly converted to float. Suggestion: use explicit cast as float, a float number, or revert to integer arithmetic", typecast.position)
}
return super.visit(typecast)
}
override fun visit(whenStatement: WhenStatement): IStatement {
// sort the choices in low-to-high value order
whenStatement.choices
.sortWith(compareBy<WhenChoice, Int?>(nullsLast(), {it.value?.constValue(program)?.asIntegerValue}))
return super.visit(whenStatement)
return assg
}
}

198
compiler/src/prog8/ast/processing/TypecastsAdder.kt Normal file
View File

@ -0,0 +1,198 @@
package prog8.ast.processing
import prog8.ast.IFunctionCall
import prog8.ast.INameScope
import prog8.ast.Program
import prog8.ast.base.DataType
import prog8.ast.base.FatalAstException
import prog8.ast.base.printWarning
import prog8.ast.expressions.*
import prog8.ast.statements.*
import prog8.functions.BuiltinFunctions
internal class TypecastsAdder(private val program: Program): IAstModifyingVisitor {
// Make sure any value assignments get the proper type casts if needed to cast them into the target variable's type.
// (this includes function call arguments)
override fun visit(expr: BinaryExpression): Expression {
val expr2 = super.visit(expr)
if(expr2 !is BinaryExpression)
return expr2
val leftDt = expr2.left.inferType(program)
val rightDt = expr2.right.inferType(program)
if(leftDt.isKnown && rightDt.isKnown && leftDt!=rightDt) {
// determine common datatype and add typecast as required to make left and right equal types
val (commonDt, toFix) = BinaryExpression.commonDatatype(leftDt.typeOrElse(DataType.STRUCT), rightDt.typeOrElse(DataType.STRUCT), expr2.left, expr2.right)
if(toFix!=null) {
when {
toFix===expr2.left -> {
expr2.left = TypecastExpression(expr2.left, commonDt, true, expr2.left.position)
expr2.left.linkParents(expr2)
}
toFix===expr2.right -> {
expr2.right = TypecastExpression(expr2.right, commonDt, true, expr2.right.position)
expr2.right.linkParents(expr2)
}
else -> throw FatalAstException("confused binary expression side")
}
}
}
return expr2
}
override fun visit(assignment: Assignment): Statement {
val assg = super.visit(assignment)
if(assg !is Assignment)
return assg
// see if a typecast is needed to convert the value's type into the proper target type
val valueItype = assg.value.inferType(program)
val targetItype = assg.target.inferType(program, assg)
if(targetItype.isKnown && valueItype.isKnown) {
val targettype = targetItype.typeOrElse(DataType.STRUCT)
val valuetype = valueItype.typeOrElse(DataType.STRUCT)
if (valuetype != targettype) {
if (valuetype isAssignableTo targettype) {
assg.value = TypecastExpression(assg.value, targettype, true, assg.value.position)
assg.value.linkParents(assg)
}
// if they're not assignable, we'll get a proper error later from the AstChecker
}
}
return assg
}
override fun visit(functionCallStatement: FunctionCallStatement): Statement {
checkFunctionCallArguments(functionCallStatement, functionCallStatement.definingScope())
return super.visit(functionCallStatement)
}
override fun visit(functionCall: FunctionCall): Expression {
checkFunctionCallArguments(functionCall, functionCall.definingScope())
return super.visit(functionCall)
}
private fun checkFunctionCallArguments(call: IFunctionCall, scope: INameScope) {
// see if a typecast is needed to convert the arguments into the required parameter's type
when(val sub = call.target.targetStatement(scope)) {
is Subroutine -> {
for(arg in sub.parameters.zip(call.args.withIndex())) {
val argItype = arg.second.value.inferType(program)
if(argItype.isKnown) {
val argtype = argItype.typeOrElse(DataType.STRUCT)
val requiredType = arg.first.type
if (requiredType != argtype) {
if (argtype isAssignableTo requiredType) {
val typecasted = TypecastExpression(arg.second.value, requiredType, true, arg.second.value.position)
typecasted.linkParents(arg.second.value.parent)
call.args[arg.second.index] = typecasted
}
// if they're not assignable, we'll get a proper error later from the AstChecker
}
}
}
}
is BuiltinFunctionStatementPlaceholder -> {
val func = BuiltinFunctions.getValue(sub.name)
if(func.pure) {
// non-pure functions don't get automatic typecasts because sometimes they act directly on their parameters
for (arg in func.parameters.zip(call.args.withIndex())) {
val argItype = arg.second.value.inferType(program)
if (argItype.isKnown) {
val argtype = argItype.typeOrElse(DataType.STRUCT)
if (arg.first.possibleDatatypes.any { argtype == it })
continue
for (possibleType in arg.first.possibleDatatypes) {
if (argtype isAssignableTo possibleType) {
val typecasted = TypecastExpression(arg.second.value, possibleType, true, arg.second.value.position)
typecasted.linkParents(arg.second.value.parent)
call.args[arg.second.index] = typecasted
break
}
}
}
}
}
}
null -> {}
else -> throw FatalAstException("call to something weird $sub ${call.target}")
}
}
override fun visit(typecast: TypecastExpression): Expression {
// warn about any implicit type casts to Float, because that may not be intended
if(typecast.implicit && typecast.type in setOf(DataType.FLOAT, DataType.ARRAY_F)) {
printWarning("byte or word value implicitly converted to float. Suggestion: use explicit cast as float, a float number, or revert to integer arithmetic", typecast.position)
}
return super.visit(typecast)
}
override fun visit(memread: DirectMemoryRead): Expression {
// make sure the memory address is an uword
val dt = memread.addressExpression.inferType(program)
if(dt.isKnown && dt.typeOrElse(DataType.UWORD)!=DataType.UWORD) {
val literaladdr = memread.addressExpression as? NumericLiteralValue
if(literaladdr!=null) {
memread.addressExpression = literaladdr.cast(DataType.UWORD)
} else {
memread.addressExpression = TypecastExpression(memread.addressExpression, DataType.UWORD, true, memread.addressExpression.position)
memread.addressExpression.parent = memread
}
}
return super.visit(memread)
}
override fun visit(memwrite: DirectMemoryWrite) {
val dt = memwrite.addressExpression.inferType(program)
if(dt.isKnown && dt.typeOrElse(DataType.UWORD)!=DataType.UWORD) {
val literaladdr = memwrite.addressExpression as? NumericLiteralValue
if(literaladdr!=null) {
memwrite.addressExpression = literaladdr.cast(DataType.UWORD)
} else {
memwrite.addressExpression = TypecastExpression(memwrite.addressExpression, DataType.UWORD, true, memwrite.addressExpression.position)
memwrite.addressExpression.parent = memwrite
}
}
super.visit(memwrite)
}
override fun visit(structLv: StructLiteralValue): Expression {
val litval = super.visit(structLv)
if(litval !is StructLiteralValue)
return litval
val decl = litval.parent as? VarDecl
if(decl != null) {
val struct = decl.struct
if(struct != null) {
addTypecastsIfNeeded(litval, struct)
}
} else {
val assign = litval.parent as? Assignment
if (assign != null) {
val decl2 = assign.target.identifier?.targetVarDecl(program.namespace)
if(decl2 != null) {
val struct = decl2.struct
if(struct != null) {
addTypecastsIfNeeded(litval, struct)
}
}
}
}
return litval
}
private fun addTypecastsIfNeeded(structLv: StructLiteralValue, struct: StructDecl) {
structLv.values = struct.statements.zip(structLv.values).map {
val memberDt = (it.first as VarDecl).datatype
val valueDt = it.second.inferType(program)
if (valueDt.typeOrElse(memberDt) != memberDt)
TypecastExpression(it.second, memberDt, true, it.second.position)
else
it.second
}
}
}

134
compiler/src/prog8/ast/processing/VarInitValueAndAddressOfCreator.kt
View File

@ -1,15 +1,18 @@
package prog8.ast.processing
import prog8.ast.*
import prog8.ast.INameScope
import prog8.ast.Module
import prog8.ast.Node
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.base.autoHeapValuePrefix
import prog8.ast.expressions.AddressOf
import prog8.ast.expressions.FunctionCall
import prog8.ast.expressions.IdentifierReference
import prog8.ast.expressions.LiteralValue
import prog8.ast.expressions.*
import prog8.ast.statements.*
import prog8.compiler.CompilerException
import prog8.functions.BuiltinFunctions
import prog8.functions.FunctionSignature
internal class VarInitValueAndAddressOfCreator(private val namespace: INameScope): IAstModifyingVisitor {
internal class VarInitValueAndAddressOfCreator(private val program: Program): IAstModifyingVisitor {
// For VarDecls that declare an initialization value:
// Replace the vardecl with an assignment (to set the initial value),
// and add a new vardecl with the default constant value of that type (usually zero) to the scope.
@ -21,22 +24,30 @@ internal class VarInitValueAndAddressOfCreator(private val namespace: INameScope
// Also takes care to insert AddressOf (&) expression where required (string params to a UWORD function param etc).
private val vardeclsToAdd = mutableMapOf<INameScope, MutableMap<String, VarDecl>>()
private val vardeclsToAdd = mutableMapOf<INameScope, MutableList<VarDecl>>()
override fun visit(module: Module) {
vardeclsToAdd.clear()
super.visit(module)
// add any new vardecls to the various scopes
for(decl in vardeclsToAdd)
for(d in decl.value) {
d.value.linkParents(decl.key as Node)
decl.key.statements.add(0, d.value)
}
for((where, decls) in vardeclsToAdd) {
where.statements.addAll(0, decls)
decls.forEach { it.linkParents(where as Node) }
}
}
override fun visit(decl: VarDecl): IStatement {
override fun visit(decl: VarDecl): Statement {
super.visit(decl)
if(decl.isArray && decl.value==null) {
// array datatype without initialization value, add list of zeros
val arraysize = decl.arraysize!!.size()!!
val array = ArrayLiteralValue(InferredTypes.InferredType.known(decl.datatype),
Array(arraysize) { NumericLiteralValue.optimalInteger(0, decl.position) },
decl.position)
decl.value = array
}
if(decl.type!= VarDeclType.VAR || decl.value==null)
return decl
@ -45,13 +56,11 @@ internal class VarInitValueAndAddressOfCreator(private val namespace: INameScope
addVarDecl(scope, decl.asDefaultValueDecl(null))
val declvalue = decl.value!!
val value =
if(declvalue is LiteralValue) {
val converted = declvalue.cast(decl.datatype)
converted ?: declvalue
}
if(declvalue is NumericLiteralValue)
declvalue.cast(decl.datatype)
else
declvalue
val identifierName = listOf(decl.name) // // TODO this was: (scoped name) decl.scopedname.split(".")
val identifierName = listOf(decl.name) // this was: (scoped name) decl.scopedname.split(".")
return VariableInitializationAssignment(
AssignTarget(null, IdentifierReference(identifierName, decl.position), null, null, decl.position),
null,
@ -59,68 +68,89 @@ internal class VarInitValueAndAddressOfCreator(private val namespace: INameScope
decl.position
)
}
return decl
}
override fun visit(functionCall: FunctionCall): IExpression {
val targetStatement = functionCall.target.targetSubroutine(namespace)
override fun visit(functionCall: FunctionCall): Expression {
var parentStatement: Node = functionCall
while(parentStatement !is Statement)
parentStatement = parentStatement.parent
val targetStatement = functionCall.target.targetSubroutine(program.namespace)
if(targetStatement!=null) {
var node: Node = functionCall
while(node !is IStatement)
node=node.parent
addAddressOfExprIfNeeded(targetStatement, functionCall.arglist, node)
addAddressOfExprIfNeeded(targetStatement, functionCall.args, parentStatement)
} else {
val builtinFunc = BuiltinFunctions[functionCall.target.nameInSource.joinToString (".")]
if(builtinFunc!=null)
addAddressOfExprIfNeededForBuiltinFuncs(builtinFunc, functionCall.args, parentStatement)
}
return functionCall
}
override fun visit(functionCallStatement: FunctionCallStatement): IStatement {
val targetStatement = functionCallStatement.target.targetSubroutine(namespace)
if(targetStatement!=null)
addAddressOfExprIfNeeded(targetStatement, functionCallStatement.arglist, functionCallStatement)
override fun visit(functionCallStatement: FunctionCallStatement): Statement {
val targetStatement = functionCallStatement.target.targetSubroutine(program.namespace)
if(targetStatement!=null) {
addAddressOfExprIfNeeded(targetStatement, functionCallStatement.args, functionCallStatement)
} else {
val builtinFunc = BuiltinFunctions[functionCallStatement.target.nameInSource.joinToString (".")]
if(builtinFunc!=null)
addAddressOfExprIfNeededForBuiltinFuncs(builtinFunc, functionCallStatement.args, functionCallStatement)
}
return functionCallStatement
}
private fun addAddressOfExprIfNeeded(subroutine: Subroutine, arglist: MutableList<IExpression>, parent: IStatement) {
private fun addAddressOfExprIfNeeded(subroutine: Subroutine, arglist: MutableList<Expression>, parent: Statement) {
// functions that accept UWORD and are given an array type, or string, will receive the AddressOf (memory location) of that value instead.
for(argparam in subroutine.parameters.withIndex().zip(arglist)) {
if(argparam.first.value.type== DataType.UWORD || argparam.first.value.type in StringDatatypes) {
if(argparam.first.value.type==DataType.UWORD || argparam.first.value.type == DataType.STR) {
if(argparam.second is AddressOf)
continue
val idref = argparam.second as? IdentifierReference
val strvalue = argparam.second as? LiteralValue
val strvalue = argparam.second as? StringLiteralValue
if(idref!=null) {
val variable = idref.targetVarDecl(namespace)
if(variable!=null && (variable.datatype in StringDatatypes || variable.datatype in ArrayDatatypes)) {
val variable = idref.targetVarDecl(program.namespace)
if(variable!=null && variable.datatype in IterableDatatypes) {
val pointerExpr = AddressOf(idref, idref.position)
pointerExpr.scopedname = parent.makeScopedName(idref.nameInSource.single())
pointerExpr.linkParents(arglist[argparam.first.index].parent)
arglist[argparam.first.index] = pointerExpr
}
}
else if(strvalue!=null) {
if(strvalue.isString) {
// replace the argument with &autovar
val autoVarName = "$autoHeapValuePrefix${strvalue.heapId}"
val autoHeapvarRef = IdentifierReference(listOf(autoVarName), strvalue.position)
val pointerExpr = AddressOf(autoHeapvarRef, strvalue.position)
pointerExpr.scopedname = parent.makeScopedName(autoVarName)
pointerExpr.linkParents(arglist[argparam.first.index].parent)
arglist[argparam.first.index] = pointerExpr
// add a vardecl so that the autovar can be resolved in later lookups
val variable = VarDecl(VarDeclType.VAR, strvalue.type, false, null, autoVarName, strvalue,
isArray = false, autoGenerated = false, position = strvalue.position)
addVarDecl(strvalue.definingScope(), variable)
// println("MADE ANONVAR $variable") // XXX
}
// add a vardecl so that the autovar can be resolved in later lookups
val variable = VarDecl.createAuto(strvalue)
addVarDecl(strvalue.definingScope(), variable)
// replace the argument with &autovar
val autoHeapvarRef = IdentifierReference(listOf(variable.name), strvalue.position)
val pointerExpr = AddressOf(autoHeapvarRef, strvalue.position)
pointerExpr.linkParents(arglist[argparam.first.index].parent)
arglist[argparam.first.index] = pointerExpr
}
}
}
}
private fun addAddressOfExprIfNeededForBuiltinFuncs(signature: FunctionSignature, args: MutableList<Expression>, parent: Statement) {
// val paramTypesForAddressOf = PassByReferenceDatatypes + DataType.UWORD
for(arg in args.withIndex().zip(signature.parameters)) {
val argvalue = arg.first.value
val argDt = argvalue.inferType(program)
if(argDt.typeOrElse(DataType.UBYTE) in PassByReferenceDatatypes && DataType.UWORD in arg.second.possibleDatatypes) {
if(argvalue !is IdentifierReference)
throw CompilerException("pass-by-reference parameter isn't an identifier? $argvalue")
val addrOf = AddressOf(argvalue, argvalue.position)
args[arg.first.index] = addrOf
addrOf.linkParents(parent)
}
}
}
private fun addVarDecl(scope: INameScope, variable: VarDecl) {
if(scope !in vardeclsToAdd)
vardeclsToAdd[scope] = mutableMapOf()
vardeclsToAdd.getValue(scope)[variable.name]=variable
vardeclsToAdd[scope] = mutableListOf()
val declList = vardeclsToAdd.getValue(scope)
if(declList.all{it.name!=variable.name})
declList.add(variable)
}
}

409
compiler/src/prog8/ast/statements/AstStatements.kt
View File

@ -5,12 +5,39 @@ import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.ast.processing.IAstModifyingVisitor
import prog8.ast.processing.IAstVisitor
import prog8.compiler.HeapValues
import kotlin.math.max
import kotlin.math.min
class BuiltinFunctionStatementPlaceholder(val name: String, override val position: Position) : IStatement {
sealed class Statement : Node {
abstract fun accept(visitor: IAstModifyingVisitor) : Statement
abstract fun accept(visitor: IAstVisitor)
fun makeScopedName(name: String): String {
// easy way out is to always return the full scoped name.
// it would be nicer to find only the minimal prefixed scoped name, but that's too much hassle for now.
// and like this, we can cache the name even,
// like in a lazy property on the statement object itself (label, subroutine, vardecl)
val scope = mutableListOf<String>()
var statementScope = this.parent
while(statementScope !is ParentSentinel && statementScope !is Module) {
if(statementScope is INameScope) {
scope.add(0, statementScope.name)
}
statementScope = statementScope.parent
}
if(name.isNotEmpty())
scope.add(name)
return scope.joinToString(".")
}
abstract val expensiveToInline: Boolean
fun definingBlock(): Block {
if(this is Block)
return this
return findParentNode<Block>(this)!!
}
}
class BuiltinFunctionStatementPlaceholder(val name: String, override val position: Position) : Statement() {
override var parent: Node = ParentSentinel
override fun linkParents(parent: Node) {}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
@ -19,15 +46,13 @@ class BuiltinFunctionStatementPlaceholder(val name: String, override val positio
override val expensiveToInline = false
}
data class RegisterOrStatusflag(val registerOrPair: RegisterOrPair?, val statusflag: Statusflag?, val stack: Boolean?)
data class RegisterOrStatusflag(val registerOrPair: RegisterOrPair?, val statusflag: Statusflag?, val stack: Boolean)
class Block(override val name: String,
val address: Int?,
override var statements: MutableList<IStatement>,
override var statements: MutableList<Statement>,
val isInLibrary: Boolean,
override val position: Position) : IStatement, INameScope {
override val position: Position) : Statement(), INameScope {
override lateinit var parent: Node
override val expensiveToInline
get() = statements.any { it.expensiveToInline }
@ -47,7 +72,7 @@ class Block(override val name: String,
fun options() = statements.filter { it is Directive && it.directive == "%option" }.flatMap { (it as Directive).args }.map {it.name!!}.toSet()
}
data class Directive(val directive: String, val args: List<DirectiveArg>, override val position: Position) : IStatement {
data class Directive(val directive: String, val args: List<DirectiveArg>, override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline = false
@ -68,7 +93,7 @@ data class DirectiveArg(val str: String?, val name: String?, val int: Int?, over
}
}
data class Label(val name: String, override val position: Position) : IStatement {
data class Label(val name: String, override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline = false
@ -82,28 +107,26 @@ data class Label(val name: String, override val position: Position) : IStatement
override fun toString(): String {
return "Label(name=$name, pos=$position)"
}
val scopedname: String by lazy { makeScopedName(name) }
}
open class Return(var values: List<IExpression>, override val position: Position) : IStatement {
open class Return(var value: Expression?, override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline = values.any { it !is LiteralValue }
override val expensiveToInline = value!=null && value !is NumericLiteralValue
override fun linkParents(parent: Node) {
this.parent = parent
values.forEach {it.linkParents(this)}
value?.linkParents(this)
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun toString(): String {
return "Return(values: $values, pos=$position)"
return "Return($value, pos=$position)"
}
}
class ReturnFromIrq(override val position: Position) : Return(emptyList(), position) {
class ReturnFromIrq(override val position: Position) : Return(null, position) {
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
@ -112,7 +135,7 @@ class ReturnFromIrq(override val position: Position) : Return(emptyList(), posit
}
}
class Continue(override val position: Position) : IStatement {
class Continue(override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline = false
@ -124,7 +147,7 @@ class Continue(override val position: Position) : IStatement {
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
}
class Break(override val position: Position) : IStatement {
class Break(override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline = false
@ -136,18 +159,52 @@ class Break(override val position: Position) : IStatement {
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
}
enum class ZeropageWish {
REQUIRE_ZEROPAGE,
PREFER_ZEROPAGE,
DONTCARE,
NOT_IN_ZEROPAGE
}
class VarDecl(val type: VarDeclType,
private val declaredDatatype: DataType,
val zeropage: Boolean,
val zeropage: ZeropageWish,
var arraysize: ArrayIndex?,
val name: String,
var value: IExpression?,
private val structName: String?,
var value: Expression?,
val isArray: Boolean,
val autoGenerated: Boolean,
override val position: Position) : IStatement {
val autogeneratedDontRemove: Boolean,
override val position: Position) : Statement() {
override lateinit var parent: Node
var struct: StructDecl? = null // set later (because at parse time, we only know the name)
private set
var structHasBeenFlattened = false // set later
private set
override val expensiveToInline
get() = value!=null && value !is LiteralValue
get() = value!=null && value !is NumericLiteralValue
// prefix for literal values that are turned into a variable on the heap
companion object {
private var autoHeapValueSequenceNumber = 0
fun createAuto(string: StringLiteralValue): VarDecl {
val autoVarName = "auto_heap_value_${++autoHeapValueSequenceNumber}"
return VarDecl(VarDeclType.VAR, DataType.STR, ZeropageWish.NOT_IN_ZEROPAGE, null, autoVarName, null, string,
isArray = false, autogeneratedDontRemove = true, position = string.position)
}
fun createAuto(array: ArrayLiteralValue): VarDecl {
val autoVarName = "auto_heap_value_${++autoHeapValueSequenceNumber}"
val declaredType = ArrayElementTypes.getValue(array.type.typeOrElse(DataType.STRUCT))
val arraysize = ArrayIndex.forArray(array)
return VarDecl(VarDeclType.VAR, declaredType, ZeropageWish.NOT_IN_ZEROPAGE, arraysize, autoVarName, null, array,
isArray = true, autogeneratedDontRemove = true, position = array.position)
}
}
val datatypeErrors = mutableListOf<SyntaxError>() // don't crash at init time, report them in the AstChecker
val datatype =
@ -160,7 +217,7 @@ class VarDecl(val type: VarDeclType,
DataType.FLOAT -> DataType.ARRAY_F
else -> {
datatypeErrors.add(SyntaxError("array can only contain bytes/words/floats", position))
DataType.UBYTE
DataType.ARRAY_UB
}
}
@ -168,6 +225,11 @@ class VarDecl(val type: VarDeclType,
this.parent = parent
arraysize?.linkParents(this)
value?.linkParents(this)
if(structName!=null) {
val structStmt = definingScope().lookup(listOf(structName), this)
if(structStmt!=null)
struct = definingScope().lookup(listOf(structName), this) as StructDecl
}
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
@ -176,26 +238,47 @@ class VarDecl(val type: VarDeclType,
val scopedname: String by lazy { makeScopedName(name) }
override fun toString(): String {
return "VarDecl(name=$name, vartype=$type, datatype=$datatype, array=$isArray, value=$value, pos=$position)"
return "VarDecl(name=$name, vartype=$type, datatype=$datatype, struct=$structName, value=$value, pos=$position)"
}
fun asDefaultValueDecl(parent: Node?): VarDecl {
val constValue = when(declaredDatatype) {
DataType.UBYTE -> LiteralValue(DataType.UBYTE, 0, position = position)
DataType.BYTE -> LiteralValue(DataType.BYTE, 0, position = position)
DataType.UWORD -> LiteralValue(DataType.UWORD, wordvalue = 0, position = position)
DataType.WORD -> LiteralValue(DataType.WORD, wordvalue = 0, position = position)
DataType.FLOAT -> LiteralValue(DataType.FLOAT, floatvalue = 0.0, position = position)
DataType.UBYTE -> NumericLiteralValue(DataType.UBYTE, 0, position)
DataType.BYTE -> NumericLiteralValue(DataType.BYTE, 0, position)
DataType.UWORD -> NumericLiteralValue(DataType.UWORD, 0, position)
DataType.WORD -> NumericLiteralValue(DataType.WORD, 0, position)
DataType.FLOAT -> NumericLiteralValue(DataType.FLOAT, 0.0, position)
else -> throw FatalAstException("can only set a default value for a numeric type")
}
val decl = VarDecl(type, declaredDatatype, zeropage, arraysize, name, constValue, isArray, true, position)
val decl = VarDecl(type, declaredDatatype, zeropage, arraysize, name, structName, constValue, isArray, false, position)
if(parent!=null)
decl.linkParents(parent)
return decl
}
fun flattenStructMembers(): MutableList<Statement> {
val result = struct!!.statements.withIndex().map {
val member = it.value as VarDecl
val initvalue = if(value!=null) (value as StructLiteralValue).values[it.index] else null
VarDecl(
VarDeclType.VAR,
member.datatype,
ZeropageWish.NOT_IN_ZEROPAGE,
member.arraysize,
mangledStructMemberName(name, member.name),
struct!!.name,
initvalue,
member.isArray,
true,
member.position
) as Statement
}.toMutableList()
structHasBeenFlattened = true
return result
}
}
class ArrayIndex(var index: IExpression, override val position: Position) : Node {
class ArrayIndex(var index: Expression, override val position: Position) : Node {
override lateinit var parent: Node
override fun linkParents(parent: Node) {
@ -204,15 +287,15 @@ class ArrayIndex(var index: IExpression, override val position: Position) : Node
}
companion object {
fun forArray(v: LiteralValue, heap: HeapValues): ArrayIndex {
val arraySize = v.arrayvalue?.size ?: heap.get(v.heapId!!).arraysize
return ArrayIndex(LiteralValue.optimalNumeric(arraySize, v.position), v.position)
fun forArray(v: ArrayLiteralValue): ArrayIndex {
return ArrayIndex(NumericLiteralValue.optimalNumeric(v.value.size, v.position), v.position)
}
}
fun accept(visitor: IAstModifyingVisitor) {
index = index.accept(visitor)
}
fun accept(visitor: IAstVisitor) {
index.accept(visitor)
}
@ -221,17 +304,17 @@ class ArrayIndex(var index: IExpression, override val position: Position) : Node
return("ArrayIndex($index, pos=$position)")
}
fun size() = (index as? LiteralValue)?.asIntegerValue
fun size() = (index as? NumericLiteralValue)?.number?.toInt()
}
open class Assignment(var targets: List<AssignTarget>, val aug_op : String?, var value: IExpression, override val position: Position) : IStatement {
open class Assignment(var target: AssignTarget, val aug_op : String?, var value: Expression, override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline
get() = value !is LiteralValue
get() = value !is NumericLiteralValue
override fun linkParents(parent: Node) {
this.parent = parent
targets.forEach { it.linkParents(this) }
this.target.linkParents(this)
value.linkParents(this)
}
@ -239,24 +322,19 @@ open class Assignment(var targets: List<AssignTarget>, val aug_op : String?, var
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun toString(): String {
return("Assignment(augop: $aug_op, targets: $targets, value: $value, pos=$position)")
return("Assignment(augop: $aug_op, target: $target, value: $value, pos=$position)")
}
val singleTarget: AssignTarget?
get() {
return targets.singleOrNull() // common case
}
}
// This is a special class so the compiler can see if the assignments are for initializing the vars in the scope,
// or just a regular assignment. It may optimize the initialization step from this.
class VariableInitializationAssignment(target: AssignTarget, aug_op: String?, value: IExpression, position: Position)
: Assignment(listOf(target), aug_op, value, position)
class VariableInitializationAssignment(target: AssignTarget, aug_op: String?, value: Expression, position: Position)
: Assignment(target, aug_op, value, position)
data class AssignTarget(val register: Register?,
val identifier: IdentifierReference?,
val arrayindexed: ArrayIndexedExpression?,
var memoryAddress: DirectMemoryWrite?,
var identifier: IdentifierReference?,
var arrayindexed: ArrayIndexedExpression?,
val memoryAddress: DirectMemoryWrite?,
override val position: Position) : Node {
override lateinit var parent: Node
@ -271,7 +349,7 @@ data class AssignTarget(val register: Register?,
fun accept(visitor: IAstVisitor) = visitor.visit(this)
companion object {
fun fromExpr(expr: IExpression): AssignTarget {
fun fromExpr(expr: Expression): AssignTarget {
return when (expr) {
is RegisterExpr -> AssignTarget(expr.register, null, null, null, expr.position)
is IdentifierReference -> AssignTarget(null, expr, null, null, expr.position)
@ -282,53 +360,35 @@ data class AssignTarget(val register: Register?,
}
}
fun inferType(program: Program, stmt: IStatement): DataType? {
fun inferType(program: Program, stmt: Statement): InferredTypes.InferredType {
if(register!=null)
return DataType.UBYTE
return InferredTypes.knownFor(DataType.UBYTE)
if(identifier!=null) {
val symbol = program.namespace.lookup(identifier.nameInSource, stmt) ?: return null
if (symbol is VarDecl) return symbol.datatype
val symbol = program.namespace.lookup(identifier!!.nameInSource, stmt) ?: return InferredTypes.unknown()
if (symbol is VarDecl) return InferredTypes.knownFor(symbol.datatype)
}
if(arrayindexed!=null) {
val dt = arrayindexed.inferType(program)
if(dt!=null)
return dt
return arrayindexed!!.inferType(program)
}
if(memoryAddress!=null)
return DataType.UBYTE
return InferredTypes.knownFor(DataType.UBYTE)
return null
return InferredTypes.unknown()
}
fun shortString(withTypePrefix: Boolean=false): String {
if(register!=null)
return (if(withTypePrefix) "0register::" else "") + register.name
if(identifier!=null)
return (if(withTypePrefix) "3identifier::" else "") + identifier.nameInSource.last()
if(arrayindexed!=null)
return (if(withTypePrefix) "2arrayidx::" else "") + arrayindexed.identifier.nameInSource.last()
val address = memoryAddress?.addressExpression
if(address is LiteralValue)
return (if(withTypePrefix) "1address::" else "") +address.asIntegerValue.toString()
return if(withTypePrefix) "???::???" else "???"
}
fun isMemoryMapped(namespace: INameScope): Boolean =
memoryAddress!=null || (identifier?.targetVarDecl(namespace)?.type== VarDeclType.MEMORY)
infix fun isSameAs(value: IExpression): Boolean {
infix fun isSameAs(value: Expression): Boolean {
return when {
this.memoryAddress!=null -> false
this.register!=null -> value is RegisterExpr && value.register==register
this.identifier!=null -> value is IdentifierReference && value.nameInSource==identifier.nameInSource
this.identifier!=null -> value is IdentifierReference && value.nameInSource==identifier!!.nameInSource
this.arrayindexed!=null -> value is ArrayIndexedExpression &&
value.identifier.nameInSource==arrayindexed.identifier.nameInSource &&
value.identifier.nameInSource==arrayindexed!!.identifier.nameInSource &&
value.arrayspec.size()!=null &&
arrayindexed.arrayspec.size()!=null &&
value.arrayspec.size()==arrayindexed.arrayspec.size()
arrayindexed!!.arrayspec.size()!=null &&
value.arrayspec.size()==arrayindexed!!.arrayspec.size()
else -> false
}
}
@ -339,16 +399,16 @@ data class AssignTarget(val register: Register?,
if(this.register!=null && other.register!=null)
return this.register==other.register
if(this.identifier!=null && other.identifier!=null)
return this.identifier.nameInSource==other.identifier.nameInSource
return this.identifier!!.nameInSource==other.identifier!!.nameInSource
if(this.memoryAddress!=null && other.memoryAddress!=null) {
val addr1 = this.memoryAddress!!.addressExpression.constValue(program)
val addr2 = other.memoryAddress!!.addressExpression.constValue(program)
val addr1 = this.memoryAddress.addressExpression.constValue(program)
val addr2 = other.memoryAddress.addressExpression.constValue(program)
return addr1!=null && addr2!=null && addr1==addr2
}
if(this.arrayindexed!=null && other.arrayindexed!=null) {
if(this.arrayindexed.identifier.nameInSource == other.arrayindexed.identifier.nameInSource) {
val x1 = this.arrayindexed.arrayspec.index.constValue(program)
val x2 = other.arrayindexed.arrayspec.index.constValue(program)
if(this.arrayindexed!!.identifier.nameInSource == other.arrayindexed!!.identifier.nameInSource) {
val x1 = this.arrayindexed!!.arrayspec.index.constValue(program)
val x2 = other.arrayindexed!!.arrayspec.index.constValue(program)
return x1!=null && x2!=null && x1==x2
}
}
@ -361,12 +421,12 @@ data class AssignTarget(val register: Register?,
if(this.memoryAddress!=null)
return false
if(this.arrayindexed!=null) {
val targetStmt = this.arrayindexed.identifier.targetVarDecl(namespace)
val targetStmt = this.arrayindexed!!.identifier.targetVarDecl(namespace)
if(targetStmt!=null)
return targetStmt.type!= VarDeclType.MEMORY
}
if(this.identifier!=null) {
val targetStmt = this.identifier.targetVarDecl(namespace)
val targetStmt = this.identifier!!.targetVarDecl(namespace)
if(targetStmt!=null)
return targetStmt.type!= VarDeclType.MEMORY
}
@ -374,7 +434,7 @@ data class AssignTarget(val register: Register?,
}
}
class PostIncrDecr(var target: AssignTarget, val operator: String, override val position: Position) : IStatement {
class PostIncrDecr(var target: AssignTarget, val operator: String, override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline = false
@ -394,7 +454,7 @@ class PostIncrDecr(var target: AssignTarget, val operator: String, override val
class Jump(val address: Int?,
val identifier: IdentifierReference?,
val generatedLabel: String?, // used in code generation scenarios
override val position: Position) : IStatement {
override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline = false
@ -412,16 +472,17 @@ class Jump(val address: Int?,
}
class FunctionCallStatement(override var target: IdentifierReference,
override var arglist: MutableList<IExpression>,
override val position: Position) : IStatement, IFunctionCall {
override var args: MutableList<Expression>,
val void: Boolean,
override val position: Position) : Statement(), IFunctionCall {
override lateinit var parent: Node
override val expensiveToInline
get() = arglist.any { it !is LiteralValue }
get() = args.any { it !is NumericLiteralValue }
override fun linkParents(parent: Node) {
this.parent = parent
target.linkParents(this)
arglist.forEach { it.linkParents(this) }
args.forEach { it.linkParents(this) }
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
@ -432,7 +493,7 @@ class FunctionCallStatement(override var target: IdentifierReference,
}
}
class InlineAssembly(val assembly: String, override val position: Position) : IStatement {
class InlineAssembly(val assembly: String, override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline = true
@ -444,22 +505,22 @@ class InlineAssembly(val assembly: String, override val position: Position) : IS
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
}
class AnonymousScope(override var statements: MutableList<IStatement>,
override val position: Position) : INameScope, IStatement {
class AnonymousScope(override var statements: MutableList<Statement>,
override val position: Position) : INameScope, Statement() {
override val name: String
override lateinit var parent: Node
override val expensiveToInline
get() = statements.any { it.expensiveToInline }
companion object {
private var sequenceNumber = 1
}
init {
name = "<anon-$sequenceNumber>" // make sure it's an invalid soruce code identifier so user source code can never produce it
sequenceNumber++
}
companion object {
private var sequenceNumber = 1
}
override fun linkParents(parent: Node) {
this.parent = parent
statements.forEach { it.linkParents(this) }
@ -469,7 +530,7 @@ class AnonymousScope(override var statements: MutableList<IStatement>,
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
}
class NopStatement(override val position: Position): IStatement {
class NopStatement(override val position: Position): Statement() {
override lateinit var parent: Node
override val expensiveToInline = false
@ -479,6 +540,14 @@ class NopStatement(override val position: Position): IStatement {
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
companion object {
fun insteadOf(stmt: Statement): NopStatement {
val nop = NopStatement(stmt.position)
nop.parent = stmt.parent
return nop
}
}
}
// the subroutine class covers both the normal user-defined subroutines,
@ -492,8 +561,8 @@ class Subroutine(override val name: String,
val asmClobbers: Set<Register>,
val asmAddress: Int?,
val isAsmSubroutine: Boolean,
override var statements: MutableList<IStatement>,
override val position: Position) : IStatement, INameScope {
override var statements: MutableList<Statement>,
override val position: Position) : Statement(), INameScope {
var keepAlways: Boolean = false
override val expensiveToInline
@ -523,42 +592,9 @@ class Subroutine(override val name: String,
.filter { it is InlineAssembly }
.map { (it as InlineAssembly).assembly }
.count { " rti" in it || "\trti" in it || " rts" in it || "\trts" in it || " jmp" in it || "\tjmp" in it }
val canBeAsmSubroutine =false // TODO disabled for now, see below about problem with converting to asm subroutine
// !isAsmSubroutine
// && ((parameters.size == 1 && parameters[0].type in setOf(DataType.BYTE, DataType.UBYTE, DataType.WORD, DataType.UWORD))
// || (parameters.size == 2 && parameters.map { it.type }.all { it == DataType.BYTE || it == DataType.UBYTE }))
fun intoAsmSubroutine(): Subroutine {
// TODO turn subroutine into asm calling convention. Requires rethinking of how parameters are handled (conflicts with local vardefs now, see AstIdentifierChecker...)
return this // TODO
// println("TO ASM $this") // TODO
// val paramregs = if (parameters.size == 1 && parameters[0].type in setOf(DataType.BYTE, DataType.UBYTE))
// listOf(RegisterOrStatusflag(RegisterOrPair.Y, null, null))
// else if (parameters.size == 1 && parameters[0].type in setOf(DataType.WORD, DataType.UWORD))
// listOf(RegisterOrStatusflag(RegisterOrPair.AY, null, null))
// else if (parameters.size == 2 && parameters.map { it.type }.all { it == DataType.BYTE || it == DataType.UBYTE })
// listOf(RegisterOrStatusflag(RegisterOrPair.A, null, null), RegisterOrStatusflag(RegisterOrPair.Y, null, null))
// else throw FatalAstException("cannot convert subroutine to asm parameters")
//
// val asmsub=Subroutine(
// name,
// parameters,
// returntypes,
// paramregs,
// emptyList(),
// emptySet(),
// null,
// true,
// statements,
// position
// )
// asmsub.linkParents(parent)
// return asmsub
}
}
open class SubroutineParameter(val name: String,
val type: DataType,
override val position: Position) : Node {
@ -569,10 +605,10 @@ open class SubroutineParameter(val name: String,
}
}
class IfStatement(var condition: IExpression,
class IfStatement(var condition: Expression,
var truepart: AnonymousScope,
var elsepart: AnonymousScope,
override val position: Position) : IStatement {
override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline: Boolean
get() = truepart.expensiveToInline || elsepart.expensiveToInline
@ -591,7 +627,7 @@ class IfStatement(var condition: IExpression,
class BranchStatement(var condition: BranchCondition,
var truepart: AnonymousScope,
var elsepart: AnonymousScope,
override val position: Position) : IStatement {
override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline: Boolean
get() = truepart.expensiveToInline || elsepart.expensiveToInline
@ -607,18 +643,16 @@ class BranchStatement(var condition: BranchCondition,
}
class ForLoop(val loopRegister: Register?,
val decltype: DataType?,
val zeropage: Boolean,
val loopVar: IdentifierReference?,
var iterable: IExpression,
var loopVar: IdentifierReference?,
var iterable: Expression,
var body: AnonymousScope,
override val position: Position) : IStatement {
override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline = true
override fun linkParents(parent: Node) {
this.parent=parent
loopVar?.linkParents(if(decltype==null) this else body)
loopVar?.linkParents(this)
iterable.linkParents(this)
body.linkParents(this)
}
@ -630,14 +664,16 @@ class ForLoop(val loopRegister: Register?,
return "ForLoop(loopVar: $loopVar, loopReg: $loopRegister, iterable: $iterable, pos=$position)"
}
companion object {
const val iteratorLoopcounterVarname = "prog8forloopcounter"
fun loopVarDt(program: Program): InferredTypes.InferredType {
val lv = loopVar
return if(loopRegister!=null) InferredTypes.InferredType.known(DataType.UBYTE)
else lv?.inferType(program) ?: InferredTypes.InferredType.unknown()
}
}
class WhileLoop(var condition: IExpression,
class WhileLoop(var condition: Expression,
var body: AnonymousScope,
override val position: Position) : IStatement {
override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline = true
@ -652,8 +688,8 @@ class WhileLoop(var condition: IExpression,
}
class RepeatLoop(var body: AnonymousScope,
var untilCondition: IExpression,
override val position: Position) : IStatement {
var untilCondition: Expression,
override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline = true
@ -667,9 +703,9 @@ class RepeatLoop(var body: AnonymousScope,
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
}
class WhenStatement(val condition: IExpression,
val choices: MutableList<WhenChoice>,
override val position: Position): IStatement {
class WhenStatement(var condition: Expression,
var choices: MutableList<WhenChoice>,
override val position: Position): Statement() {
override lateinit var parent: Node
override val expensiveToInline: Boolean = true
@ -679,35 +715,40 @@ class WhenStatement(val condition: IExpression,
choices.forEach { it.linkParents(this) }
}
fun choiceValues(program: Program): List<Pair<Int?, WhenChoice>> {
fun choiceValues(program: Program): List<Pair<List<Int>?, WhenChoice>> {
// only gives sensible results when the choices are all valid (constant integers)
return choices
.map {
val cv = it.value?.constValue(program)
if(cv==null)
null to it
else
cv.asNumericValue!!.toInt() to it
}
val result = mutableListOf<Pair<List<Int>?, WhenChoice>>()
for(choice in choices) {
if(choice.values==null)
result.add(null to choice)
else {
val values = choice.values!!.map { it.constValue(program)?.number?.toInt() }
if(values.contains(null))
result.add(null to choice)
else
result.add(values.filterNotNull() to choice)
}
}
return result
}
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
}
class WhenChoice(val value: IExpression?, // if null, this is the 'else' part
val statements: AnonymousScope,
class WhenChoice(var values: List<Expression>?, // if null, this is the 'else' part
var statements: AnonymousScope,
override val position: Position) : Node {
override lateinit var parent: Node
override fun linkParents(parent: Node) {
value?.linkParents(this)
values?.forEach { it.linkParents(this) }
statements.linkParents(this)
this.parent = parent
}
override fun toString(): String {
return "Choice($value at $position)"
return "Choice($values at $position)"
}
fun accept(visitor: IAstVisitor) = visitor.visit(this)
@ -715,7 +756,28 @@ class WhenChoice(val value: IExpression?, // if null, this is the 'el
}
class DirectMemoryWrite(var addressExpression: IExpression, override val position: Position) : Node {
class StructDecl(override val name: String,
override var statements: MutableList<Statement>, // actually, only vardecls here
override val position: Position): Statement(), INameScope {
override lateinit var parent: Node
override val expensiveToInline: Boolean = true
override fun linkParents(parent: Node) {
this.parent = parent
this.statements.forEach { it.linkParents(this) }
}
val numberOfElements: Int
get() = this.statements.size
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
fun nameOfFirstMember() = (statements.first() as VarDecl).name
}
class DirectMemoryWrite(var addressExpression: Expression, override val position: Position) : Node {
override lateinit var parent: Node
override fun linkParents(parent: Node) {
@ -730,4 +792,3 @@ class DirectMemoryWrite(var addressExpression: IExpression, override val positio
fun accept(visitor: IAstVisitor) = visitor.visit(this)
fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
}

3
compiler/src/prog8/compiler/AssemblyError.kt Normal file
View File

@ -0,0 +1,3 @@
package prog8.compiler
internal class AssemblyError(msg: String) : RuntimeException(msg)

2160
compiler/src/prog8/compiler/Compiler.kt
View File

File diff suppressed because it is too large Load Diff

74
compiler/src/prog8/compiler/Main.kt
View File

@ -1,13 +1,10 @@
package prog8.compiler
import prog8.ast.AstToSourceCode
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.base.checkIdentifiers
import prog8.ast.base.checkValid
import prog8.ast.base.reorderStatements
import prog8.ast.statements.Directive
import prog8.compiler.target.c64.AsmGen
import prog8.compiler.target.c64.C64Zeropage
import prog8.compiler.target.CompilationTarget
import prog8.optimizer.constantFold
import prog8.optimizer.optimizeStatements
import prog8.optimizer.simplifyExpressions
@ -15,20 +12,26 @@ import prog8.parser.ParsingFailedError
import prog8.parser.importLibraryModule
import prog8.parser.importModule
import prog8.parser.moduleName
import java.io.File
import java.io.PrintStream
import java.lang.Exception
import java.nio.file.Path
import kotlin.system.exitProcess
import kotlin.system.measureTimeMillis
class CompilationResult(val success: Boolean,
val programAst: Program,
val programName: String,
val importedFiles: List<Path>)
fun compileProgram(filepath: Path,
optimize: Boolean, optimizeInlining: Boolean,
generateVmCode: Boolean, writeVmCode: Boolean,
writeAssembly: Boolean): Pair<Program, String?> {
optimize: Boolean,
writeAssembly: Boolean,
outputDir: Path): CompilationResult {
lateinit var programAst: Program
var programName: String? = null
var importedFiles: List<Path> = emptyList()
var success=false
try {
val totalTime = measureTimeMillis {
// import main module and everything it needs
@ -36,6 +39,8 @@ fun compileProgram(filepath: Path,
programAst = Program(moduleName(filepath.fileName), mutableListOf())
importModule(programAst, filepath)
importedFiles = programAst.modules.filter { !it.source.startsWith("@embedded@") }.map{ it.source }
val compilerOptions = determineCompilationOptions(programAst)
if (compilerOptions.launcher == LauncherType.BASIC && compilerOptions.output != OutputType.PRG)
throw ParsingFailedError("${programAst.modules.first().position} BASIC launcher requires output type PRG.")
@ -63,7 +68,9 @@ fun compileProgram(filepath: Path,
}
//println(" time2: $time2")
val time3 = measureTimeMillis {
programAst.reorderStatements() // reorder statements and add type casts, to please the compiler later
programAst.removeNopsFlattenAnonScopes()
programAst.reorderStatements()
programAst.addTypecasts()
}
//println(" time3: $time3")
val time4 = measureTimeMillis {
@ -78,41 +85,28 @@ fun compileProgram(filepath: Path,
while (true) {
// keep optimizing expressions and statements until no more steps remain
val optsDone1 = programAst.simplifyExpressions()
val optsDone2 = programAst.optimizeStatements(optimizeInlining)
val optsDone2 = programAst.optimizeStatements()
if (optsDone1 + optsDone2 == 0)
break
}
}
programAst.addTypecasts()
programAst.removeNopsFlattenAnonScopes()
programAst.checkValid(compilerOptions) // check if final tree is valid
programAst.checkRecursion() // check if there are recursive subroutine calls
// printAst(programAst)
// namespace.debugPrint()
if(generateVmCode) {
// compile the syntax tree into stackvmProg form, and optimize that
val compiler = Compiler(programAst)
val intermediate = compiler.compile(compilerOptions)
if (optimize)
intermediate.optimize()
if (writeVmCode) {
val stackVmFilename = intermediate.name + ".vm.txt"
val stackvmFile = PrintStream(File(stackVmFilename), "utf-8")
intermediate.writeCode(stackvmFile)
stackvmFile.close()
println("StackVM program code written to '$stackVmFilename'")
}
if (writeAssembly) {
val zeropage = C64Zeropage(compilerOptions)
intermediate.allocateZeropage(zeropage)
val assembly = AsmGen(compilerOptions, intermediate, programAst.heap, zeropage).compileToAssembly(optimize)
assembly.assemble(compilerOptions)
programName = assembly.name
}
if(writeAssembly) {
// asm generation directly from the Ast, no need for intermediate code
val zeropage = CompilationTarget.machine.getZeropage(compilerOptions)
programAst.anonscopeVarsCleanup()
val assembly = CompilationTarget.asmGenerator(programAst, zeropage, compilerOptions, outputDir).compileToAssembly(optimize)
assembly.assemble(compilerOptions)
programName = assembly.name
}
success = true
}
println("\nTotal compilation+assemble time: ${totalTime / 1000.0} sec.")
@ -120,12 +114,10 @@ fun compileProgram(filepath: Path,
System.err.print("\u001b[91m") // bright red
System.err.println(px.message)
System.err.print("\u001b[0m") // reset
exitProcess(1)
} catch (ax: AstException) {
System.err.print("\u001b[91m") // bright red
System.err.println(ax.toString())
System.err.print("\u001b[0m") // reset
exitProcess(1)
} catch (x: Exception) {
print("\u001b[91m") // bright red
println("\n* internal error *")
@ -139,12 +131,12 @@ fun compileProgram(filepath: Path,
System.out.flush()
throw x
}
return Pair(programAst, programName)
return CompilationResult(success, programAst, programName ?: "", importedFiles)
}
fun printAst(programAst: Program) {
println()
val printer = AstToSourceCode(::print)
val printer = AstToSourceCode(::print, programAst)
printer.visit(programAst)
println()
}

6
compiler/src/prog8/compiler/Zeropage.kt
View File

@ -1,7 +1,6 @@
package prog8.compiler
import prog8.ast.base.*
import prog8.ast.base.printWarning
class ZeropageDepletedError(message: String) : Exception(message)
@ -14,11 +13,14 @@ abstract class Zeropage(protected val options: CompilationOptions) {
val allowedDatatypes = NumericDatatypes
fun available() = free.size
fun available() = if(options.zeropage==ZeropageType.DONTUSE) 0 else free.size
fun allocate(scopedname: String, datatype: DataType, position: Position?): Int {
assert(scopedname.isEmpty() || !allocations.values.any { it.first==scopedname } ) {"isSameAs scopedname can't be allocated twice"}
if(options.zeropage==ZeropageType.DONTUSE)
throw CompilerException("zero page usage has been disabled")
val size =
when (datatype) {
in ByteDatatypes -> 1

51
compiler/src/prog8/compiler/intermediate/Instruction.kt
View File

@ -1,51 +0,0 @@
package prog8.compiler.intermediate
import prog8.vm.RuntimeValue
import prog8.vm.stackvm.Syscall
open class Instruction(val opcode: Opcode,
val arg: RuntimeValue? = null,
val arg2: RuntimeValue? = null,
val callLabel: String? = null,
val callLabel2: String? = null)
{
var branchAddress: Int? = null
override fun toString(): String {
val argStr = arg?.toString() ?: ""
val result =
when {
opcode==Opcode.LINE -> "_line $callLabel"
opcode==Opcode.INLINE_ASSEMBLY -> {
// inline assembly is not written out (it can't be processed as intermediate language)
// instead, it is converted into a system call that can be intercepted by the vm
if(callLabel!=null)
"syscall SYSASM.$callLabel\n return"
else
"inline_assembly"
}
opcode==Opcode.INCLUDE_FILE -> {
"include_file \"$callLabel\" $arg $arg2"
}
opcode==Opcode.SYSCALL -> {
val syscall = Syscall.values().find { it.callNr==arg!!.numericValue() }
"syscall $syscall"
}
opcode in opcodesWithVarArgument -> {
// opcodes that manipulate a variable
"${opcode.name.toLowerCase()} ${callLabel?:""} ${callLabel2?:""}".trimEnd()
}
callLabel==null -> "${opcode.name.toLowerCase()} $argStr"
else -> "${opcode.name.toLowerCase()} $callLabel $argStr"
}
.trimEnd()
return " $result"
}
}
class LabelInstr(val name: String, val asmProc: Boolean) : Instruction(Opcode.NOP, null, null) {
override fun toString(): String {
return "\n$name:"
}
}

524
compiler/src/prog8/compiler/intermediate/IntermediateProgram.kt
View File

@ -1,524 +0,0 @@
package prog8.compiler.intermediate
import prog8.ast.antlr.escape
import prog8.ast.base.*
import prog8.ast.base.printWarning
import prog8.ast.expressions.LiteralValue
import prog8.ast.statements.VarDecl
import prog8.vm.RuntimeValue
import prog8.compiler.CompilerException
import prog8.compiler.HeapValues
import prog8.compiler.Zeropage
import prog8.compiler.ZeropageDepletedError
import java.io.PrintStream
import java.nio.file.Path
class IntermediateProgram(val name: String, var loadAddress: Int, val heap: HeapValues, val source: Path) {
class ProgramBlock(val name: String,
var address: Int?,
val instructions: MutableList<Instruction> = mutableListOf(),
val variables: MutableMap<String, RuntimeValue> = mutableMapOf(), // names are fully scoped
val memoryPointers: MutableMap<String, Pair<Int, DataType>> = mutableMapOf(),
val labels: MutableMap<String, Instruction> = mutableMapOf(), // names are fully scoped
val force_output: Boolean)
{
val numVariables: Int
get() { return variables.size }
val numInstructions: Int
get() { return instructions.filter { it.opcode!= Opcode.LINE }.size }
val variablesMarkedForZeropage: MutableSet<String> = mutableSetOf()
}
val allocatedZeropageVariables = mutableMapOf<String, Pair<Int, DataType>>()
val blocks = mutableListOf<ProgramBlock>()
val memory = mutableMapOf<Int, List<RuntimeValue>>()
private lateinit var currentBlock: ProgramBlock
val numVariables: Int
get() = blocks.sumBy { it.numVariables }
val numInstructions: Int
get() = blocks.sumBy { it.numInstructions }
fun allocateZeropage(zeropage: Zeropage) {
// allocates all @zp marked variables on the zeropage (for all blocks, as long as there is space in the ZP)
var notAllocated = 0
for(block in blocks) {
val zpVariables = block.variables.filter { it.key in block.variablesMarkedForZeropage }
if (zpVariables.isNotEmpty()) {
for (variable in zpVariables) {
try {
val address = zeropage.allocate(variable.key, variable.value.type, null)
allocatedZeropageVariables[variable.key] = Pair(address, variable.value.type)
} catch (x: ZeropageDepletedError) {
printWarning(x.toString() + " variable ${variable.key} type ${variable.value.type}")
notAllocated++
}
}
}
}
if(notAllocated>0)
printWarning("$notAllocated variables marked for Zeropage could not be allocated there")
}
fun optimize() {
println("Optimizing stackVM code...")
// remove nops (that are not a label)
for (blk in blocks) {
blk.instructions.removeIf { it.opcode== Opcode.NOP && it !is LabelInstr }
}
optimizeDataConversionAndUselessDiscards()
optimizeVariableCopying()
optimizeMultipleSequentialLineInstrs()
optimizeCallReturnIntoJump()
optimizeConditionalBranches()
// todo: add more optimizations to intermediate code!
optimizeRemoveNops() // must be done as the last step
optimizeMultipleSequentialLineInstrs() // once more
optimizeRemoveNops() // once more
}
private fun optimizeConditionalBranches() {
// conditional branches that consume the value on the stack
// sometimes these are just constant values, so we can statically determine the branch
// or, they are preceded by a NOT instruction so we can simply remove that and flip the branch condition
val pushvalue = setOf(Opcode.PUSH_BYTE, Opcode.PUSH_WORD)
val notvalue = setOf(Opcode.NOT_BYTE, Opcode.NOT_WORD)
val branchOpcodes = setOf(Opcode.JZ, Opcode.JNZ, Opcode.JZW, Opcode.JNZW)
for(blk in blocks) {
val instructionsToReplace = mutableMapOf<Int, Instruction>()
blk.instructions.asSequence().withIndex().filter {it.value.opcode!=Opcode.LINE}.windowed(2).toList().forEach {
if (it[1].value.opcode in branchOpcodes) {
if (it[0].value.opcode in pushvalue) {
val value = it[0].value.arg!!.asBoolean
instructionsToReplace[it[0].index] = Instruction(Opcode.NOP)
val replacement: Instruction =
if (value) {
when (it[1].value.opcode) {
Opcode.JNZ -> Instruction(Opcode.JUMP, callLabel = it[1].value.callLabel)
Opcode.JNZW -> Instruction(Opcode.JUMP, callLabel = it[1].value.callLabel)
else -> Instruction(Opcode.NOP)
}
} else {
when (it[1].value.opcode) {
Opcode.JZ -> Instruction(Opcode.JUMP, callLabel = it[1].value.callLabel)
Opcode.JZW -> Instruction(Opcode.JUMP, callLabel = it[1].value.callLabel)
else -> Instruction(Opcode.NOP)
}
}
instructionsToReplace[it[1].index] = replacement
}
else if (it[0].value.opcode in notvalue) {
instructionsToReplace[it[0].index] = Instruction(Opcode.NOP)
val replacement: Instruction =
when (it[1].value.opcode) {
Opcode.JZ -> Instruction(Opcode.JNZ, callLabel = it[1].value.callLabel)
Opcode.JZW -> Instruction(Opcode.JNZW, callLabel = it[1].value.callLabel)
Opcode.JNZ -> Instruction(Opcode.JZ, callLabel = it[1].value.callLabel)
Opcode.JNZW -> Instruction(Opcode.JZW, callLabel = it[1].value.callLabel)
else -> Instruction(Opcode.NOP)
}
instructionsToReplace[it[1].index] = replacement
}
}
}
for (rins in instructionsToReplace) {
blk.instructions[rins.key] = rins.value
}
}
}
private fun optimizeRemoveNops() {
// remove nops (that are not a label)
for (blk in blocks)
blk.instructions.removeIf { it.opcode== Opcode.NOP && it !is LabelInstr }
}
private fun optimizeCallReturnIntoJump() {
// replaces call X followed by return, by jump X
for(blk in blocks) {
val instructionsToReplace = mutableMapOf<Int, Instruction>()
blk.instructions.asSequence().withIndex().filter {it.value.opcode!=Opcode.LINE}.windowed(2).toList().forEach {
if(it[0].value.opcode==Opcode.CALL && it[1].value.opcode==Opcode.RETURN) {
instructionsToReplace[it[1].index] = Instruction(Opcode.JUMP, callLabel = it[0].value.callLabel)
instructionsToReplace[it[0].index] = Instruction(Opcode.NOP)
}
}
for (rins in instructionsToReplace) {
blk.instructions[rins.key] = rins.value
}
}
}
private fun optimizeMultipleSequentialLineInstrs() {
for(blk in blocks) {
val instructionsToReplace = mutableMapOf<Int, Instruction>()
blk.instructions.asSequence().withIndex().windowed(2).toList().forEach {
if (it[0].value.opcode == Opcode.LINE && it[1].value.opcode == Opcode.LINE)
instructionsToReplace[it[0].index] = Instruction(Opcode.NOP)
}
for (rins in instructionsToReplace) {
blk.instructions[rins.key] = rins.value
}
}
}
private fun optimizeVariableCopying() {
for(blk in blocks) {
val instructionsToReplace = mutableMapOf<Int, Instruction>()
blk.instructions.asSequence().withIndex().windowed(2).toList().forEach {
when (it[0].value.opcode) {
Opcode.PUSH_VAR_BYTE ->
if (it[1].value.opcode == Opcode.POP_VAR_BYTE) {
if (it[0].value.callLabel == it[1].value.callLabel) {
instructionsToReplace[it[0].index] = Instruction(Opcode.NOP)
instructionsToReplace[it[1].index] = Instruction(Opcode.NOP)
}
}
Opcode.PUSH_VAR_WORD ->
if (it[1].value.opcode == Opcode.POP_VAR_WORD) {
if (it[0].value.callLabel == it[1].value.callLabel) {
instructionsToReplace[it[0].index] = Instruction(Opcode.NOP)
instructionsToReplace[it[1].index] = Instruction(Opcode.NOP)
}
}
Opcode.PUSH_VAR_FLOAT ->
if (it[1].value.opcode == Opcode.POP_VAR_FLOAT) {
if (it[0].value.callLabel == it[1].value.callLabel) {
instructionsToReplace[it[0].index] = Instruction(Opcode.NOP)
instructionsToReplace[it[1].index] = Instruction(Opcode.NOP)
}
}
Opcode.PUSH_MEM_B, Opcode.PUSH_MEM_UB ->
if(it[1].value.opcode == Opcode.POP_MEM_BYTE) {
if(it[0].value.arg == it[1].value.arg) {
instructionsToReplace[it[0].index] = Instruction(Opcode.NOP)
instructionsToReplace[it[1].index] = Instruction(Opcode.NOP)
}
}
Opcode.PUSH_MEM_W, Opcode.PUSH_MEM_UW ->
if(it[1].value.opcode == Opcode.POP_MEM_WORD) {
if(it[0].value.arg == it[1].value.arg) {
instructionsToReplace[it[0].index] = Instruction(Opcode.NOP)
instructionsToReplace[it[1].index] = Instruction(Opcode.NOP)
}
}
Opcode.PUSH_MEM_FLOAT ->
if(it[1].value.opcode == Opcode.POP_MEM_FLOAT) {
if(it[0].value.arg == it[1].value.arg) {
instructionsToReplace[it[0].index] = Instruction(Opcode.NOP)
instructionsToReplace[it[1].index] = Instruction(Opcode.NOP)
}
}
else -> {}
}
}
for (rins in instructionsToReplace) {
blk.instructions[rins.key] = rins.value
}
}
}
private fun optimizeDataConversionAndUselessDiscards() {
// - push value followed by a data type conversion -> push the value in the correct type and remove the conversion
// - push something followed by a discard -> remove both
val instructionsToReplace = mutableMapOf<Int, Instruction>()
fun optimizeDiscardAfterPush(index0: Int, index1: Int, ins1: Instruction) {
if (ins1.opcode == Opcode.DISCARD_FLOAT || ins1.opcode == Opcode.DISCARD_WORD || ins1.opcode == Opcode.DISCARD_BYTE) {
instructionsToReplace[index0] = Instruction(Opcode.NOP)
instructionsToReplace[index1] = Instruction(Opcode.NOP)
}
}
fun optimizeFloatConversion(index0: Int, index1: Int, ins1: Instruction) {
when (ins1.opcode) {
Opcode.DISCARD_FLOAT -> {
instructionsToReplace[index0] = Instruction(Opcode.NOP)
instructionsToReplace[index1] = Instruction(Opcode.NOP)
}
Opcode.DISCARD_BYTE, Opcode.DISCARD_WORD -> throw CompilerException("invalid discard type following a float")
else -> throw CompilerException("invalid conversion opcode ${ins1.opcode} following a float")
}
}
fun optimizeWordConversion(index0: Int, ins0: Instruction, index1: Int, ins1: Instruction) {
when (ins1.opcode) {
Opcode.CAST_UW_TO_B, Opcode.CAST_W_TO_B -> {
val ins = Instruction(Opcode.PUSH_BYTE, ins0.arg!!.cast(DataType.BYTE))
instructionsToReplace[index0] = ins
instructionsToReplace[index1] = Instruction(Opcode.NOP)
}
Opcode.CAST_W_TO_UB, Opcode.CAST_UW_TO_UB -> {
val ins = Instruction(Opcode.PUSH_BYTE, RuntimeValue(DataType.UBYTE, ins0.arg!!.integerValue() and 255))
instructionsToReplace[index0] = ins
instructionsToReplace[index1] = Instruction(Opcode.NOP)
}
Opcode.MSB -> {
val ins = Instruction(Opcode.PUSH_BYTE, RuntimeValue(DataType.UBYTE, ins0.arg!!.integerValue() ushr 8 and 255))
instructionsToReplace[index0] = ins
instructionsToReplace[index1] = Instruction(Opcode.NOP)
}
Opcode.CAST_W_TO_F, Opcode.CAST_UW_TO_F -> {
val ins = Instruction(Opcode.PUSH_FLOAT, RuntimeValue(DataType.FLOAT, ins0.arg!!.integerValue().toDouble()))
instructionsToReplace[index0] = ins
instructionsToReplace[index1] = Instruction(Opcode.NOP)
}
Opcode.CAST_UW_TO_W -> {
val cv = ins0.arg!!.cast(DataType.WORD)
instructionsToReplace[index0] = Instruction(Opcode.PUSH_WORD, cv)
instructionsToReplace[index1] = Instruction(Opcode.NOP)
}
Opcode.CAST_W_TO_UW -> {
val cv = ins0.arg!!.cast(DataType.UWORD)
instructionsToReplace[index0] = Instruction(Opcode.PUSH_WORD, cv)
instructionsToReplace[index1] = Instruction(Opcode.NOP)
}
Opcode.DISCARD_WORD -> {
instructionsToReplace[index0] = Instruction(Opcode.NOP)
instructionsToReplace[index1] = Instruction(Opcode.NOP)
}
Opcode.DISCARD_BYTE, Opcode.DISCARD_FLOAT -> throw CompilerException("invalid discard type following a byte")
else -> throw CompilerException("invalid conversion opcode ${ins1.opcode} following a word")
}
}
fun optimizeByteConversion(index0: Int, ins0: Instruction, index1: Int, ins1: Instruction) {
when (ins1.opcode) {
Opcode.CAST_B_TO_UB, Opcode.CAST_UB_TO_B,
Opcode.CAST_W_TO_B, Opcode.CAST_W_TO_UB,
Opcode.CAST_UW_TO_B, Opcode.CAST_UW_TO_UB -> instructionsToReplace[index1] = Instruction(Opcode.NOP)
Opcode.MSB -> throw CompilerException("msb of a byte")
Opcode.CAST_UB_TO_UW -> {
val ins = Instruction(Opcode.PUSH_WORD, RuntimeValue(DataType.UWORD, ins0.arg!!.integerValue()))
instructionsToReplace[index0] = ins
instructionsToReplace[index1] = Instruction(Opcode.NOP)
}
Opcode.CAST_B_TO_W -> {
val ins = Instruction(Opcode.PUSH_WORD, RuntimeValue(DataType.WORD, ins0.arg!!.integerValue()))
instructionsToReplace[index0] = ins
instructionsToReplace[index1] = Instruction(Opcode.NOP)
}
Opcode.CAST_B_TO_UW -> {
val ins = Instruction(Opcode.PUSH_WORD, ins0.arg!!.cast(DataType.UWORD))
instructionsToReplace[index0] = ins
instructionsToReplace[index1] = Instruction(Opcode.NOP)
}
Opcode.CAST_UB_TO_W -> {
val ins = Instruction(Opcode.PUSH_WORD, ins0.arg!!.cast(DataType.WORD))
instructionsToReplace[index0] = ins
instructionsToReplace[index1] = Instruction(Opcode.NOP)
}
Opcode.CAST_B_TO_F, Opcode.CAST_UB_TO_F-> {
val ins = Instruction(Opcode.PUSH_FLOAT, RuntimeValue(DataType.FLOAT, ins0.arg!!.integerValue().toDouble()))
instructionsToReplace[index0] = ins
instructionsToReplace[index1] = Instruction(Opcode.NOP)
}
Opcode.CAST_W_TO_F, Opcode.CAST_UW_TO_F-> throw CompilerException("invalid conversion following a byte")
Opcode.DISCARD_BYTE -> {
instructionsToReplace[index0] = Instruction(Opcode.NOP)
instructionsToReplace[index1] = Instruction(Opcode.NOP)
}
Opcode.DISCARD_WORD, Opcode.DISCARD_FLOAT -> throw CompilerException("invalid discard type following a byte")
Opcode.MKWORD -> {}
else -> throw CompilerException("invalid conversion opcode ${ins1.opcode}")
}
}
for(blk in blocks) {
instructionsToReplace.clear()
val typeConversionOpcodes = setOf(
Opcode.MSB,
Opcode.MKWORD,
Opcode.CAST_UB_TO_B,
Opcode.CAST_UB_TO_UW,
Opcode.CAST_UB_TO_W,
Opcode.CAST_UB_TO_F,
Opcode.CAST_B_TO_UB,
Opcode.CAST_B_TO_UW,
Opcode.CAST_B_TO_W,
Opcode.CAST_B_TO_F,
Opcode.CAST_UW_TO_UB,
Opcode.CAST_UW_TO_B,
Opcode.CAST_UW_TO_W,
Opcode.CAST_UW_TO_F,
Opcode.CAST_W_TO_UB,
Opcode.CAST_W_TO_B,
Opcode.CAST_W_TO_UW,
Opcode.CAST_W_TO_F,
Opcode.CAST_F_TO_UB,
Opcode.CAST_F_TO_B,
Opcode.CAST_F_TO_UW,
Opcode.CAST_F_TO_W,
Opcode.DISCARD_BYTE,
Opcode.DISCARD_WORD,
Opcode.DISCARD_FLOAT
)
blk.instructions.asSequence().withIndex().windowed(2).toList().forEach {
if (it[1].value.opcode in typeConversionOpcodes) {
when (it[0].value.opcode) {
Opcode.PUSH_BYTE -> optimizeByteConversion(it[0].index, it[0].value, it[1].index, it[1].value)
Opcode.PUSH_WORD -> optimizeWordConversion(it[0].index, it[0].value, it[1].index, it[1].value)
Opcode.PUSH_FLOAT -> optimizeFloatConversion(it[0].index, it[1].index, it[1].value)
Opcode.PUSH_VAR_FLOAT,
Opcode.PUSH_VAR_WORD,
Opcode.PUSH_VAR_BYTE,
Opcode.PUSH_MEM_B, Opcode.PUSH_MEM_UB,
Opcode.PUSH_MEM_W, Opcode.PUSH_MEM_UW,
Opcode.PUSH_MEM_FLOAT -> optimizeDiscardAfterPush(it[0].index, it[1].index, it[1].value)
else -> {
}
}
}
}
for (rins in instructionsToReplace) {
blk.instructions[rins.key] = rins.value
}
}
}
fun variable(scopedname: String, decl: VarDecl) {
when(decl.type) {
VarDeclType.VAR -> {
val value = when(decl.datatype) {
in NumericDatatypes -> RuntimeValue(decl.datatype, (decl.value as LiteralValue).asNumericValue!!)
in StringDatatypes -> {
val litval = (decl.value as LiteralValue)
if(litval.heapId==null)
throw CompilerException("string should already be in the heap")
RuntimeValue(decl.datatype, heapId = litval.heapId)
}
in ArrayDatatypes -> {
val litval = (decl.value as LiteralValue)
if(litval.heapId==null)
throw CompilerException("array should already be in the heap")
RuntimeValue(decl.datatype, heapId = litval.heapId)
}
else -> throw CompilerException("weird datatype")
}
currentBlock.variables[scopedname] = value
if(decl.zeropage)
currentBlock.variablesMarkedForZeropage.add(scopedname)
}
VarDeclType.MEMORY -> {
// note that constants are all folded away, but assembly code may still refer to them
val lv = decl.value as LiteralValue
if(lv.type!= DataType.UWORD && lv.type!= DataType.UBYTE)
throw CompilerException("expected integer memory address $lv")
currentBlock.memoryPointers[scopedname] = Pair(lv.asIntegerValue!!, decl.datatype)
}
VarDeclType.CONST -> {
// note that constants are all folded away, but assembly code may still refer to them (if their integers)
// floating point constants are not generated at all!!
val lv = decl.value as LiteralValue
if(lv.type in IntegerDatatypes)
currentBlock.memoryPointers[scopedname] = Pair(lv.asIntegerValue!!, decl.datatype)
}
}
}
fun instr(opcode: Opcode, arg: RuntimeValue? = null, arg2: RuntimeValue? = null, callLabel: String? = null, callLabel2: String? = null) {
currentBlock.instructions.add(Instruction(opcode, arg, arg2, callLabel, callLabel2))
}
fun label(labelname: String, asmProc: Boolean=false) {
val instr = LabelInstr(labelname, asmProc)
currentBlock.instructions.add(instr)
currentBlock.labels[labelname] = instr
}
fun line(position: Position) {
currentBlock.instructions.add(Instruction(Opcode.LINE, callLabel = "${position.line} ${position.file}"))
}
fun removeLastInstruction() {
currentBlock.instructions.removeAt(currentBlock.instructions.lastIndex)
}
fun memoryPointer(name: String, address: Int, datatype: DataType) {
currentBlock.memoryPointers[name] = Pair(address, datatype)
}
fun newBlock(name: String, address: Int?, options: Set<String>) {
currentBlock = ProgramBlock(name, address, force_output="force_output" in options)
blocks.add(currentBlock)
}
fun writeCode(out: PrintStream, embeddedLabels: Boolean=true) {
out.println("; stackVM program code for '$name'")
out.println("%memory")
if(memory.isNotEmpty())
TODO("add support for writing/reading initial memory values")
out.println("%end_memory")
out.println("%heap")
heap.allEntries().forEach {
out.print("${it.key} ${it.value.type.name.toLowerCase()} ")
when {
it.value.str!=null ->
out.println("\"${escape(it.value.str!!)}\"")
it.value.array!=null -> {
// this array can contain both normal integers, and pointer values
val arrayvalues = it.value.array!!.map { av ->
when {
av.integer!=null -> av.integer.toString()
av.addressOf!=null -> {
if(av.addressOf.scopedname==null)
throw CompilerException("AddressOf scopedname should have been set")
else
"&${av.addressOf.scopedname}"
}
else -> throw CompilerException("weird array value")
}
}
out.println(arrayvalues)
}
it.value.doubleArray!=null ->
out.println(it.value.doubleArray!!.toList())
else -> throw CompilerException("invalid heap entry $it")
}
}
out.println("%end_heap")
for(blk in blocks) {
out.println("\n%block ${blk.name} ${blk.address?.toString(16) ?: ""}")
out.println("%variables")
for(variable in blk.variables) {
val valuestr = variable.value.toString()
out.println("${variable.key} ${variable.value.type.name.toLowerCase()} $valuestr")
}
out.println("%end_variables")
out.println("%memorypointers")
for(iconst in blk.memoryPointers) {
out.println("${iconst.key} ${iconst.value.second.name.toLowerCase()} uw:${iconst.value.first.toString(16)}")
}
out.println("%end_memorypointers")
out.println("%instructions")
val labels = blk.labels.entries.associateBy({it.value}) {it.key}
for(instr in blk.instructions) {
if(!embeddedLabels) {
val label = labels[instr]
if (label != null)
out.println("$label:")
} else {
out.println(instr)
}
}
out.println("%end_instructions")
out.println("%end_block")
}
}
}

291
compiler/src/prog8/compiler/intermediate/Opcode.kt
View File

@ -1,291 +0,0 @@
package prog8.compiler.intermediate
enum class Opcode {
// pushing values on the (evaluation) stack
PUSH_BYTE, // push byte value
PUSH_WORD, // push word value (or 'address' of string / array)
PUSH_FLOAT, // push float value
PUSH_MEM_B, // push byte value from memory to stack
PUSH_MEM_UB, // push unsigned byte value from memory to stack
PUSH_MEM_W, // push word value from memory to stack
PUSH_MEM_UW, // push unsigned word value from memory to stack
PUSH_MEM_FLOAT, // push float value from memory to stack
PUSH_MEMREAD, // push memory value from address that's on the stack
PUSH_VAR_BYTE, // push byte variable (ubyte, byte)
PUSH_VAR_WORD, // push word variable (uword, word)
PUSH_VAR_FLOAT, // push float variable
PUSH_REGAX_WORD, // push registers A/X as a 16-bit word
PUSH_REGAY_WORD, // push registers A/Y as a 16-bit word
PUSH_REGXY_WORD, // push registers X/Y as a 16-bit word
PUSH_ADDR_HEAPVAR, // push the address of the variable that's on the heap (string or array)
DUP_B, // duplicate the top byte on the stack
DUP_W, // duplicate the top word on the stack
// popping values off the (evaluation) stack, possibly storing them in another location
DISCARD_BYTE, // discard top byte value
DISCARD_WORD, // discard top word value
DISCARD_FLOAT, // discard top float value
POP_MEM_BYTE, // pop (u)byte value into destination memory address
POP_MEM_WORD, // pop (u)word value into destination memory address
POP_MEM_FLOAT, // pop float value into destination memory address
POP_MEMWRITE, // pop address and byte stack and write the byte to the memory address
POP_VAR_BYTE, // pop (u)byte value into variable
POP_VAR_WORD, // pop (u)word value into variable
POP_VAR_FLOAT, // pop float value into variable
POP_REGAX_WORD, // pop uword from stack into A/X registers
POP_REGAY_WORD, // pop uword from stack into A/Y registers
POP_REGXY_WORD, // pop uword from stack into X/Y registers
// numeric arithmetic
ADD_UB,
ADD_B,
ADD_UW,
ADD_W,
ADD_F,
SUB_UB,
SUB_B,
SUB_UW,
SUB_W,
SUB_F,
MUL_UB,
MUL_B,
MUL_UW,
MUL_W,
MUL_F,
IDIV_UB,
IDIV_B,
IDIV_UW,
IDIV_W,
DIV_F,
REMAINDER_UB, // signed remainder is undefined/unimplemented
REMAINDER_UW, // signed remainder is undefined/unimplemented
POW_F,
NEG_B,
NEG_W,
NEG_F,
ABS_B,
ABS_W,
ABS_F,
// bit shifts and bitwise arithmetic
SHIFTEDL_BYTE, // shifts stack value rather than in-place mem/var
SHIFTEDL_WORD, // shifts stack value rather than in-place mem/var
SHIFTEDR_UBYTE, // shifts stack value rather than in-place mem/var
SHIFTEDR_SBYTE, // shifts stack value rather than in-place mem/var
SHIFTEDR_UWORD, // shifts stack value rather than in-place mem/var
SHIFTEDR_SWORD, // shifts stack value rather than in-place mem/var
SHL_BYTE,
SHL_WORD,
SHL_MEM_BYTE,
SHL_MEM_WORD,
SHL_VAR_BYTE,
SHL_VAR_WORD,
SHR_UBYTE,
SHR_SBYTE,
SHR_UWORD,
SHR_SWORD,
SHR_MEM_UBYTE,
SHR_MEM_SBYTE,
SHR_MEM_UWORD,
SHR_MEM_SWORD,
SHR_VAR_UBYTE,
SHR_VAR_SBYTE,
SHR_VAR_UWORD,
SHR_VAR_SWORD,
ROL_BYTE,
ROL_WORD,
ROL_MEM_BYTE,
ROL_MEM_WORD,
ROL_VAR_BYTE,
ROL_VAR_WORD,
ROR_BYTE,
ROR_WORD,
ROR_MEM_BYTE,
ROR_MEM_WORD,
ROR_VAR_BYTE,
ROR_VAR_WORD,
ROL2_BYTE,
ROL2_WORD,
ROL2_MEM_BYTE,
ROL2_MEM_WORD,
ROL2_VAR_BYTE,
ROL2_VAR_WORD,
ROR2_BYTE,
ROR2_WORD,
ROR2_MEM_BYTE,
ROR2_MEM_WORD,
ROR2_VAR_BYTE,
ROR2_VAR_WORD,
BITAND_BYTE,
BITAND_WORD,
BITOR_BYTE,
BITOR_WORD,
BITXOR_BYTE,
BITXOR_WORD,
INV_BYTE,
INV_WORD,
// numeric type conversions
MSB, // note: lsb is equivalent to CAST_UW_TO_UB or CAST_W_TO_UB
MKWORD, // create a word from lsb + msb
CAST_UB_TO_B,
CAST_UB_TO_UW,
CAST_UB_TO_W,
CAST_UB_TO_F,
CAST_B_TO_UB,
CAST_B_TO_UW,
CAST_B_TO_W,
CAST_B_TO_F,
CAST_W_TO_UB,
CAST_W_TO_B,
CAST_W_TO_UW,
CAST_W_TO_F,
CAST_UW_TO_UB,
CAST_UW_TO_B,
CAST_UW_TO_W,
CAST_UW_TO_F,
CAST_F_TO_UB,
CAST_F_TO_B,
CAST_F_TO_UW,
CAST_F_TO_W,
// logical operations
AND_BYTE,
AND_WORD,
OR_BYTE,
OR_WORD,
XOR_BYTE,
XOR_WORD,
NOT_BYTE,
NOT_WORD,
// increment, decrement
INC_VAR_B,
INC_VAR_UB,
INC_VAR_W,
INC_VAR_UW,
INC_VAR_F,
DEC_VAR_B,
DEC_VAR_UB,
DEC_VAR_W,
DEC_VAR_UW,
DEC_VAR_F,
INC_MEMORY, // increment direct address
DEC_MEMORY, // decrement direct address
POP_INC_MEMORY, // increment address from stack
POP_DEC_MEMORY, // decrement address from address
// comparisons
LESS_B,
LESS_UB,
LESS_W,
LESS_UW,
LESS_F,
GREATER_B,
GREATER_UB,
GREATER_W,
GREATER_UW,
GREATER_F,
LESSEQ_B,
LESSEQ_UB,
LESSEQ_W,
LESSEQ_UW,
LESSEQ_F,
GREATEREQ_B,
GREATEREQ_UB,
GREATEREQ_W,
GREATEREQ_UW,
GREATEREQ_F,
EQUAL_BYTE,
EQUAL_WORD,
EQUAL_F,
NOTEQUAL_BYTE,
NOTEQUAL_WORD,
NOTEQUAL_F,
CMP_B, // sets processor status flags based on comparison, instead of pushing a result value
CMP_UB, // sets processor status flags based on comparison, instead of pushing a result value
CMP_W, // sets processor status flags based on comparison, instead of pushing a result value
CMP_UW, // sets processor status flags based on comparison, instead of pushing a result value
// array access and simple manipulations
READ_INDEXED_VAR_BYTE,
READ_INDEXED_VAR_WORD,
READ_INDEXED_VAR_FLOAT,
WRITE_INDEXED_VAR_BYTE,
WRITE_INDEXED_VAR_WORD,
WRITE_INDEXED_VAR_FLOAT,
INC_INDEXED_VAR_B,
INC_INDEXED_VAR_UB,
INC_INDEXED_VAR_W,
INC_INDEXED_VAR_UW,
INC_INDEXED_VAR_FLOAT,
DEC_INDEXED_VAR_B,
DEC_INDEXED_VAR_UB,
DEC_INDEXED_VAR_W,
DEC_INDEXED_VAR_UW,
DEC_INDEXED_VAR_FLOAT,
// branching, without consuming a value from the stack
JUMP,
BCS, // branch if carry set
BCC, // branch if carry clear
BZ, // branch if zero flag
BNZ, // branch if not zero flag
BNEG, // branch if negative flag
BPOS, // branch if not negative flag
BVS, // branch if overflow flag
BVC, // branch if not overflow flag
// branching, based on value on the stack (which is consumed)
JZ, // branch if value is zero (byte)
JNZ, // branch if value is not zero (byte)
JZW, // branch if value is zero (word)
JNZW, // branch if value is not zero (word)
// subroutines
CALL,
RETURN,
SYSCALL,
START_PROCDEF,
END_PROCDEF,
// misc
SEC, // set carry status flag NOTE: is mostly fake, carry flag is not affected by any numeric operations
CLC, // clear carry status flag NOTE: is mostly fake, carry flag is not affected by any numeric operations
SEI, // set irq-disable status flag
CLI, // clear irq-disable status flag
CARRY_TO_A, // load var/register A with carry status bit
RSAVE, // save all internal registers and status flags
RSAVEX, // save just X (the evaluation stack pointer)
RRESTORE, // restore all internal registers and status flags
RRESTOREX, // restore just X (the evaluation stack pointer)
NOP, // do nothing
BREAKPOINT, // breakpoint
TERMINATE, // end the program
LINE, // track source file line number
INLINE_ASSEMBLY, // container to hold inline raw assembly code
INCLUDE_FILE // directive to include a file at this position in the memory of the program
}
val opcodesWithVarArgument = setOf(
Opcode.INC_VAR_B, Opcode.INC_VAR_W, Opcode.DEC_VAR_B, Opcode.DEC_VAR_W,
Opcode.INC_VAR_UB, Opcode.INC_VAR_UW, Opcode.DEC_VAR_UB, Opcode.DEC_VAR_UW,
Opcode.SHR_VAR_SBYTE, Opcode.SHR_VAR_UBYTE, Opcode.SHR_VAR_SWORD, Opcode.SHR_VAR_UWORD,
Opcode.SHL_VAR_BYTE, Opcode.SHL_VAR_WORD,
Opcode.ROL_VAR_BYTE, Opcode.ROL_VAR_WORD, Opcode.ROR_VAR_BYTE, Opcode.ROR_VAR_WORD,
Opcode.ROL2_VAR_BYTE, Opcode.ROL2_VAR_WORD, Opcode.ROR2_VAR_BYTE, Opcode.ROR2_VAR_WORD,
Opcode.POP_VAR_BYTE, Opcode.POP_VAR_WORD, Opcode.POP_VAR_FLOAT,
Opcode.PUSH_VAR_BYTE, Opcode.PUSH_VAR_WORD, Opcode.PUSH_VAR_FLOAT, Opcode.PUSH_ADDR_HEAPVAR,
Opcode.READ_INDEXED_VAR_BYTE, Opcode.READ_INDEXED_VAR_WORD, Opcode.READ_INDEXED_VAR_FLOAT,
Opcode.WRITE_INDEXED_VAR_BYTE, Opcode.WRITE_INDEXED_VAR_WORD, Opcode.WRITE_INDEXED_VAR_FLOAT,
Opcode.INC_INDEXED_VAR_UB, Opcode.INC_INDEXED_VAR_B, Opcode.INC_INDEXED_VAR_UW,
Opcode.INC_INDEXED_VAR_W, Opcode.INC_INDEXED_VAR_FLOAT,
Opcode.DEC_INDEXED_VAR_UB, Opcode.DEC_INDEXED_VAR_B, Opcode.DEC_INDEXED_VAR_UW,
Opcode.DEC_INDEXED_VAR_W, Opcode.DEC_INDEXED_VAR_FLOAT
)
val branchOpcodes = setOf(
Opcode.BCS, Opcode.BCC, Opcode.BZ, Opcode.BNZ,
Opcode.BNEG, Opcode.BPOS, Opcode.BVS, Opcode.BVC
)

16
compiler/src/prog8/compiler/target/CompilationTarget.kt Normal file
View File

@ -0,0 +1,16 @@
package prog8.compiler.target
import prog8.ast.Program
import prog8.compiler.CompilationOptions
import prog8.compiler.Zeropage
import java.nio.file.Path
internal interface CompilationTarget {
companion object {
lateinit var name: String
lateinit var machine: IMachineDefinition
lateinit var encodeString: (str: String, altEncoding: Boolean) -> List<Short>
lateinit var decodeString: (bytes: List<Short>, altEncoding: Boolean) -> String
lateinit var asmGenerator: (Program, Zeropage, CompilationOptions, Path) -> IAssemblyGenerator
}
}

12
compiler/src/prog8/compiler/target/IAssemblyGenerator.kt Normal file
View File

@ -0,0 +1,12 @@
package prog8.compiler.target
import prog8.compiler.CompilationOptions
internal interface IAssemblyGenerator {
fun compileToAssembly(optimize: Boolean): IAssemblyProgram
}
internal interface IAssemblyProgram {
val name: String
fun assemble(options: CompilationOptions)
}

15
compiler/src/prog8/compiler/target/IMachineDefinition.kt Normal file
View File

@ -0,0 +1,15 @@
package prog8.compiler.target
import prog8.compiler.CompilationOptions
import prog8.compiler.Zeropage
interface IMachineDefinition {
val FLOAT_MAX_NEGATIVE: Double
val FLOAT_MAX_POSITIVE: Double
val FLOAT_MEM_SIZE: Int
val opcodeNames: Set<String>
fun getZeropage(compilerOptions: CompilationOptions): Zeropage
}

735
compiler/src/prog8/compiler/target/c64/AsmGen.kt
View File

@ -1,735 +0,0 @@
package prog8.compiler.target.c64
// note: to put stuff on the stack, we use Absolute,X addressing mode which is 3 bytes / 4 cycles
// possible space optimization is to use zeropage (indirect),Y which is 2 bytes, but 5 cycles
import prog8.ast.antlr.escape
import prog8.ast.base.DataType
import prog8.ast.base.initvarsSubName
import prog8.vm.RuntimeValue
import prog8.compiler.*
import prog8.compiler.intermediate.*
import java.io.File
import java.util.*
import kotlin.math.abs
class AssemblyError(msg: String) : RuntimeException(msg)
internal fun intVal(valueInstr: Instruction) = valueInstr.arg!!.integerValue()
internal fun hexVal(valueInstr: Instruction) = valueInstr.arg!!.integerValue().toHex()
internal fun hexValPlusOne(valueInstr: Instruction) = (valueInstr.arg!!.integerValue()+1).toHex()
internal fun getFloatConst(value: RuntimeValue): String =
globalFloatConsts[value.numericValue().toDouble()]
?: throw AssemblyError("should have a global float const for number $value")
internal val globalFloatConsts = mutableMapOf<Double, String>()
internal fun signExtendA(into: String) =
"""
ora #$7f
bmi +
lda #0
+ sta $into
"""
class AsmGen(private val options: CompilationOptions, private val program: IntermediateProgram,
private val heap: HeapValues, private val zeropage: Zeropage) {
private val assemblyLines = mutableListOf<String>()
private lateinit var block: IntermediateProgram.ProgramBlock
init {
// Convert invalid label names (such as "<anon-1>") to something that's allowed.
val newblocks = mutableListOf<IntermediateProgram.ProgramBlock>()
for(block in program.blocks) {
val newvars = block.variables.map { symname(it.key, block) to it.value }.toMap().toMutableMap()
val newvarsZeropaged = block.variablesMarkedForZeropage.map{symname(it, block)}.toMutableSet()
val newlabels = block.labels.map { symname(it.key, block) to it.value}.toMap().toMutableMap()
val newinstructions = block.instructions.asSequence().map {
when {
it is LabelInstr -> LabelInstr(symname(it.name, block), it.asmProc)
it.opcode == Opcode.INLINE_ASSEMBLY -> it
else ->
Instruction(it.opcode, it.arg, it.arg2,
callLabel = if (it.callLabel != null) symname(it.callLabel, block) else null,
callLabel2 = if (it.callLabel2 != null) symname(it.callLabel2, block) else null)
}
}.toMutableList()
val newMempointers = block.memoryPointers.map { symname(it.key, block) to it.value }.toMap().toMutableMap()
val newblock = IntermediateProgram.ProgramBlock(
block.name,
block.address,
newinstructions,
newvars,
newMempointers,
newlabels,
force_output = block.force_output)
newblock.variablesMarkedForZeropage.clear()
newblock.variablesMarkedForZeropage.addAll(newvarsZeropaged)
newblocks.add(newblock)
}
program.blocks.clear()
program.blocks.addAll(newblocks)
val newAllocatedZp = program.allocatedZeropageVariables.map { symname(it.key, null) to it.value}
program.allocatedZeropageVariables.clear()
program.allocatedZeropageVariables.putAll(newAllocatedZp)
// make a list of all const floats that are used
for(block in program.blocks) {
for(ins in block.instructions.filter{it.arg?.type== DataType.FLOAT}) {
val float = ins.arg!!.numericValue().toDouble()
if(float !in globalFloatConsts)
globalFloatConsts[float] = "prog8_const_float_${globalFloatConsts.size}"
}
}
}
fun compileToAssembly(optimize: Boolean): AssemblyProgram {
println("Generating assembly code from intermediate code... ")
assemblyLines.clear()
header()
for(b in program.blocks)
block2asm(b)
if(optimize) {
var optimizationsDone = 1
while (optimizationsDone > 0) {
optimizationsDone = optimizeAssembly(assemblyLines)
}
}
File("${program.name}.asm").printWriter().use {
for (line in assemblyLines) { it.println(line) }
}
return AssemblyProgram(program.name)
}
private fun out(str: String, splitlines: Boolean=true) {
if(splitlines) {
for (line in str.split('\n')) {
val trimmed = if (line.startsWith(' ')) "\t" + line.trim() else line.trim()
// trimmed = trimmed.replace(Regex("^\\+\\s+"), "+\t") // sanitize local label indentation
assemblyLines.add(trimmed)
}
} else assemblyLines.add(str)
}
// convert a fully scoped name (defined in the given block) to a valid assembly symbol name
private fun symname(scoped: String, block: IntermediateProgram.ProgramBlock?): String {
if(' ' in scoped)
return scoped
val blockLocal: Boolean
var name = if (block!=null && scoped.startsWith("${block.name}.")) {
blockLocal = true
scoped.substring(block.name.length+1)
}
else {
blockLocal = false
scoped
}
name = name.replace("<", "prog8_").replace(">", "") // take care of the autogenerated invalid (anon) label names
if(name=="-")
return "-"
if(blockLocal)
name = name.replace(".", "_")
else {
val parts = name.split(".", limit=2)
if(parts.size>1)
name = "${parts[0]}.${parts[1].replace(".", "_")}"
}
return name.replace("-", "")
}
private fun makeFloatFill(flt: Mflpt5): String {
val b0 = "$"+flt.b0.toString(16).padStart(2, '0')
val b1 = "$"+flt.b1.toString(16).padStart(2, '0')
val b2 = "$"+flt.b2.toString(16).padStart(2, '0')
val b3 = "$"+flt.b3.toString(16).padStart(2, '0')
val b4 = "$"+flt.b4.toString(16).padStart(2, '0')
return "$b0, $b1, $b2, $b3, $b4"
}
private fun header() {
val ourName = this.javaClass.name
out("; 6502 assembly code for '${program.name}'")
out("; generated by $ourName on ${Date()}")
out("; assembler syntax is for the 64tasm cross-assembler")
out("; output options: output=${options.output} launcher=${options.launcher} zp=${options.zeropage}")
out("\n.cpu '6502'\n.enc 'none'\n")
if(program.loadAddress==0) // fix load address
program.loadAddress = if(options.launcher==LauncherType.BASIC) BASIC_LOAD_ADDRESS else RAW_LOAD_ADDRESS
when {
options.launcher == LauncherType.BASIC -> {
if (program.loadAddress != 0x0801)
throw AssemblyError("BASIC output must have load address $0801")
out("; ---- basic program with sys call ----")
out("* = ${program.loadAddress.toHex()}")
val year = Calendar.getInstance().get(Calendar.YEAR)
out(" .word (+), $year")
out(" .null $9e, format(' %d ', _prog8_entrypoint), $3a, $8f, ' prog8 by idj'")
out("+\t.word 0")
out("_prog8_entrypoint\t; assembly code starts here\n")
out(" jsr prog8_lib.init_system")
}
options.output == OutputType.PRG -> {
out("; ---- program without basic sys call ----")
out("* = ${program.loadAddress.toHex()}\n")
out(" jsr prog8_lib.init_system")
}
options.output == OutputType.RAW -> {
out("; ---- raw assembler program ----")
out("* = ${program.loadAddress.toHex()}\n")
}
}
if(zeropage.exitProgramStrategy!=Zeropage.ExitProgramStrategy.CLEAN_EXIT) {
// disable shift-commodore charset switching and run/stop key
out(" lda #$80")
out(" lda #$80")
out(" sta 657\t; disable charset switching")
out(" lda #239")
out(" sta 808\t; disable run/stop key")
}
out(" ldx #\$ff\t; init estack pointer")
out(" ; initialize the variables in each block")
for(block in program.blocks) {
val initVarsLabel = block.instructions.firstOrNull { it is LabelInstr && it.name== initvarsSubName } as? LabelInstr
if(initVarsLabel!=null)
out(" jsr ${block.name}.${initVarsLabel.name}")
}
out(" clc")
when(zeropage.exitProgramStrategy) {
Zeropage.ExitProgramStrategy.CLEAN_EXIT -> {
out(" jmp main.start\t; jump to program entrypoint")
}
Zeropage.ExitProgramStrategy.SYSTEM_RESET -> {
out(" jsr main.start\t; call program entrypoint")
out(" jmp (c64.RESET_VEC)\t; cold reset")
}
}
out("")
// the global list of all floating point constants for the whole program
for(flt in globalFloatConsts) {
val floatFill = makeFloatFill(Mflpt5.fromNumber(flt.key))
out("${flt.value}\t.byte $floatFill ; float ${flt.key}")
}
}
private fun block2asm(blk: IntermediateProgram.ProgramBlock) {
block = blk
out("\n; ---- block: '${block.name}' ----")
if(!blk.force_output)
out("${block.name}\t.proc\n")
if(block.address!=null) {
out(".cerror * > ${block.address?.toHex()}, 'block address overlaps by ', *-${block.address?.toHex()},' bytes'")
out("* = ${block.address?.toHex()}")
}
// deal with zeropage variables
for(variable in blk.variables) {
val sym = symname(blk.name+"."+variable.key, null)
val zpVar = program.allocatedZeropageVariables[sym]
if(zpVar==null) {
// This var is not on the ZP yet. Attempt to move it there (if it's not a float, those take up too much space)
if(variable.value.type in zeropage.allowedDatatypes && variable.value.type != DataType.FLOAT) {
try {
val address = zeropage.allocate(sym, variable.value.type, null)
out("${variable.key} = $address\t; auto zp ${variable.value.type}")
// make sure we add the var to the set of zpvars for this block
blk.variablesMarkedForZeropage.add(variable.key)
program.allocatedZeropageVariables[sym] = Pair(address, variable.value.type)
} catch (x: ZeropageDepletedError) {
// leave it as it is.
}
}
}
else {
// it was already allocated on the zp
out("${variable.key} = ${zpVar.first}\t; zp ${zpVar.second}")
}
}
out("\n; memdefs and kernel subroutines")
memdefs2asm(block)
out("\n; non-zeropage variables")
vardecls2asm(block)
out("")
val instructionPatternWindowSize = 8 // increase once patterns occur longer than this.
var processed = 0
for (ins in block.instructions.windowed(instructionPatternWindowSize, partialWindows = true)) {
if (processed == 0) {
processed = instr2asm(ins)
if (processed == 0) {
// the instructions are not recognised yet and can't be translated into assembly
throw CompilerException("no asm translation found for instruction pattern: $ins")
}
}
processed--
}
if(!blk.force_output)
out("\n\t.pend\n")
}
private fun memdefs2asm(block: IntermediateProgram.ProgramBlock) {
for(m in block.memoryPointers) {
out(" ${m.key} = ${m.value.first.toHex()}")
}
}
private fun vardecls2asm(block: IntermediateProgram.ProgramBlock) {
// these are the non-zeropage variables
val sortedVars = block.variables.filter{it.key !in block.variablesMarkedForZeropage}.toList().sortedBy { it.second.type }
for (v in sortedVars) {
when (v.second.type) {
DataType.UBYTE -> out("${v.first}\t.byte 0")
DataType.BYTE -> out("${v.first}\t.char 0")
DataType.UWORD -> out("${v.first}\t.word 0")
DataType.WORD -> out("${v.first}\t.sint 0")
DataType.FLOAT -> out("${v.first}\t.byte 0,0,0,0,0 ; float")
DataType.STR, DataType.STR_S -> {
val rawStr = heap.get(v.second.heapId!!).str!!
val bytes = encodeStr(rawStr, v.second.type).map { "$" + it.toString(16).padStart(2, '0') }
out("${v.first}\t; ${v.second.type} \"${escape(rawStr).replace("\u0000", "<NULL>")}\"")
for (chunk in bytes.chunked(16))
out(" .byte " + chunk.joinToString())
}
DataType.ARRAY_UB -> {
// unsigned integer byte arraysize
val data = makeArrayFillDataUnsigned(v.second)
if (data.size <= 16)
out("${v.first}\t.byte ${data.joinToString()}")
else {
out(v.first)
for (chunk in data.chunked(16))
out(" .byte " + chunk.joinToString())
}
}
DataType.ARRAY_B -> {
// signed integer byte arraysize
val data = makeArrayFillDataSigned(v.second)
if (data.size <= 16)
out("${v.first}\t.char ${data.joinToString()}")
else {
out(v.first)
for (chunk in data.chunked(16))
out(" .char " + chunk.joinToString())
}
}
DataType.ARRAY_UW -> {
// unsigned word arraysize
val data = makeArrayFillDataUnsigned(v.second)
if (data.size <= 16)
out("${v.first}\t.word ${data.joinToString()}")
else {
out(v.first)
for (chunk in data.chunked(16))
out(" .word " + chunk.joinToString())
}
}
DataType.ARRAY_W -> {
// signed word arraysize
val data = makeArrayFillDataSigned(v.second)
if (data.size <= 16)
out("${v.first}\t.sint ${data.joinToString()}")
else {
out(v.first)
for (chunk in data.chunked(16))
out(" .sint " + chunk.joinToString())
}
}
DataType.ARRAY_F -> {
// float arraysize
val array = heap.get(v.second.heapId!!).doubleArray!!
val floatFills = array.map { makeFloatFill(Mflpt5.fromNumber(it)) }
out(v.first)
for(f in array.zip(floatFills))
out(" .byte ${f.second} ; float ${f.first}")
}
}
}
}
private fun encodeStr(str: String, dt: DataType): List<Short> {
return when(dt) {
DataType.STR -> {
val bytes = Petscii.encodePetscii(str, true)
bytes.plus(0)
}
DataType.STR_S -> {
val bytes = Petscii.encodeScreencode(str, true)
bytes.plus(0)
}
else -> throw AssemblyError("invalid str type")
}
}
private fun makeArrayFillDataUnsigned(value: RuntimeValue): List<String> {
val array = heap.get(value.heapId!!).array!!
return when {
value.type== DataType.ARRAY_UB ->
// byte array can never contain pointer-to types, so treat values as all integers
array.map { "$"+it.integer!!.toString(16).padStart(2, '0') }
value.type== DataType.ARRAY_UW -> array.map {
when {
it.integer!=null -> "$"+it.integer.toString(16).padStart(2, '0')
it.addressOf!=null -> symname(it.addressOf.scopedname!!, block)
else -> throw AssemblyError("weird type in array")
}
}
else -> throw AssemblyError("invalid arraysize type")
}
}
private fun makeArrayFillDataSigned(value: RuntimeValue): List<String> {
val array = heap.get(value.heapId!!).array!!
// note: array of signed value can never contain pointer-to type, so simply accept values as being all integers
return if (value.type == DataType.ARRAY_B || value.type == DataType.ARRAY_W) {
array.map {
if(it.integer!!>=0)
"$"+it.integer.toString(16).padStart(2, '0')
else
"-$"+abs(it.integer).toString(16).padStart(2, '0')
}
}
else throw AssemblyError("invalid arraysize type")
}
private fun instr2asm(ins: List<Instruction>): Int {
// find best patterns (matching the most of the lines, then with the smallest weight)
val fragments = findPatterns(ins).sortedByDescending { it.segmentSize }
if(fragments.isEmpty()) {
// we didn't find any matching patterns (complex multi-instruction fragments), try simple ones
val firstIns = ins[0]
val singleAsm = simpleInstr2Asm(firstIns, block)
if(singleAsm != null) {
outputAsmFragment(singleAsm)
return 1
}
return 0
}
val best = fragments[0]
outputAsmFragment(best.asm)
return best.segmentSize
}
private fun outputAsmFragment(singleAsm: String) {
if (singleAsm.isNotEmpty()) {
if(singleAsm.startsWith("@inline@"))
out(singleAsm.substring(8), false)
else {
val withNewlines = singleAsm.replace('|', '\n')
out(withNewlines)
}
}
}
private fun findPatterns(segment: List<Instruction>): List<AsmFragment> {
val opcodes = segment.map { it.opcode }
val result = mutableListOf<AsmFragment>()
// check for operations that modify a single value, by putting it on the stack (and popping it afterwards)
if((opcodes[0]==Opcode.PUSH_VAR_BYTE && opcodes[2]==Opcode.POP_VAR_BYTE) ||
(opcodes[0]==Opcode.PUSH_VAR_WORD && opcodes[2]==Opcode.POP_VAR_WORD) ||
(opcodes[0]==Opcode.PUSH_VAR_FLOAT && opcodes[2]==Opcode.POP_VAR_FLOAT)) {
if (segment[0].callLabel == segment[2].callLabel) {
val fragment = sameVarOperation(segment[0].callLabel!!, segment[1])
if (fragment != null) {
fragment.segmentSize = 3
result.add(fragment)
}
}
}
else if((opcodes[0]==Opcode.PUSH_BYTE && opcodes[1] in setOf(Opcode.INC_INDEXED_VAR_B, Opcode.INC_INDEXED_VAR_UB,
Opcode.INC_INDEXED_VAR_UW, Opcode.INC_INDEXED_VAR_W, Opcode.INC_INDEXED_VAR_FLOAT,
Opcode.DEC_INDEXED_VAR_B, Opcode.DEC_INDEXED_VAR_UB, Opcode.DEC_INDEXED_VAR_W,
Opcode.DEC_INDEXED_VAR_UW, Opcode.DEC_INDEXED_VAR_FLOAT))) {
val fragment = sameConstantIndexedVarOperation(segment[1].callLabel!!, segment[0].arg!!.integerValue(), segment[1])
if(fragment!=null) {
fragment.segmentSize=2
result.add(fragment)
}
}
else if((opcodes[0]==Opcode.PUSH_VAR_BYTE && opcodes[1] in setOf(Opcode.INC_INDEXED_VAR_B, Opcode.INC_INDEXED_VAR_UB,
Opcode.INC_INDEXED_VAR_UW, Opcode.INC_INDEXED_VAR_W, Opcode.INC_INDEXED_VAR_FLOAT,
Opcode.DEC_INDEXED_VAR_B, Opcode.DEC_INDEXED_VAR_UB, Opcode.DEC_INDEXED_VAR_W,
Opcode.DEC_INDEXED_VAR_UW, Opcode.DEC_INDEXED_VAR_FLOAT))) {
val fragment = sameIndexedVarOperation(segment[1].callLabel!!, segment[0].callLabel!!, segment[1])
if(fragment!=null) {
fragment.segmentSize=2
result.add(fragment)
}
}
else if((opcodes[0]==Opcode.PUSH_MEM_UB && opcodes[2]==Opcode.POP_MEM_BYTE) ||
(opcodes[0]==Opcode.PUSH_MEM_B && opcodes[2]==Opcode.POP_MEM_BYTE) ||
(opcodes[0]==Opcode.PUSH_MEM_UW && opcodes[2]==Opcode.POP_MEM_WORD) ||
(opcodes[0]==Opcode.PUSH_MEM_W && opcodes[2]==Opcode.POP_MEM_WORD) ||
(opcodes[0]==Opcode.PUSH_MEM_FLOAT && opcodes[2]==Opcode.POP_MEM_FLOAT)) {
if(segment[0].arg==segment[2].arg) {
val fragment = sameMemOperation(segment[0].arg!!.integerValue(), segment[1])
if(fragment!=null) {
fragment.segmentSize = 3
result.add(fragment)
}
}
}
else if((opcodes[0]==Opcode.PUSH_BYTE && opcodes[1]==Opcode.READ_INDEXED_VAR_BYTE &&
opcodes[3]==Opcode.PUSH_BYTE && opcodes[4]==Opcode.WRITE_INDEXED_VAR_BYTE) ||
(opcodes[0]==Opcode.PUSH_BYTE && opcodes[1]==Opcode.READ_INDEXED_VAR_WORD &&
opcodes[3]==Opcode.PUSH_BYTE && opcodes[4]==Opcode.WRITE_INDEXED_VAR_WORD)) {
if(segment[0].arg==segment[3].arg && segment[1].callLabel==segment[4].callLabel) {
val fragment = sameConstantIndexedVarOperation(segment[1].callLabel!!, segment[0].arg!!.integerValue(), segment[2])
if(fragment!=null){
fragment.segmentSize = 5
result.add(fragment)
}
}
}
else if((opcodes[0]==Opcode.PUSH_VAR_BYTE && opcodes[1]==Opcode.READ_INDEXED_VAR_BYTE &&
opcodes[3]==Opcode.PUSH_VAR_BYTE && opcodes[4]==Opcode.WRITE_INDEXED_VAR_BYTE) ||
(opcodes[0]==Opcode.PUSH_VAR_BYTE && opcodes[1]==Opcode.READ_INDEXED_VAR_WORD &&
opcodes[3]==Opcode.PUSH_VAR_BYTE && opcodes[4]==Opcode.WRITE_INDEXED_VAR_WORD)) {
if(segment[0].callLabel==segment[3].callLabel && segment[1].callLabel==segment[4].callLabel) {
val fragment = sameIndexedVarOperation(segment[1].callLabel!!, segment[0].callLabel!!, segment[2])
if(fragment!=null){
fragment.segmentSize = 5
result.add(fragment)
}
}
}
// add any matching patterns from the big list
for(pattern in patterns) {
if(pattern.sequence.size > segment.size || (pattern.altSequence!=null && pattern.altSequence.size > segment.size))
continue // don't accept patterns that don't fit
val opcodesList = opcodes.subList(0, pattern.sequence.size)
if(pattern.sequence == opcodesList) {
val asm = pattern.asm(segment)
if(asm!=null)
result.add(AsmFragment(asm, pattern.sequence.size))
} else if(pattern.altSequence!=null) {
val opcodesListAlt = opcodes.subList(0, pattern.altSequence.size)
if(pattern.altSequence == opcodesListAlt) {
val asm = pattern.asm(segment)
if (asm != null)
result.add(AsmFragment(asm, pattern.sequence.size))
}
}
}
return result
}
private fun sameConstantIndexedVarOperation(variable: String, index: Int, ins: Instruction): AsmFragment? {
// an in place operation that consists of a push-value / op / push-index-value / pop-into-indexed-var
return when(ins.opcode) {
Opcode.SHL_BYTE -> AsmFragment(" asl $variable+$index", 8)
Opcode.SHR_UBYTE -> AsmFragment(" lsr $variable+$index", 8)
Opcode.SHR_SBYTE -> AsmFragment(" lda $variable+$index | asl a | ror $variable+$index")
Opcode.SHL_WORD -> AsmFragment(" asl $variable+${index*2+1} | rol $variable+${index*2}", 8)
Opcode.SHR_UWORD -> AsmFragment(" lsr $variable+${index*2+1} | ror $variable+${index*2}", 8)
Opcode.SHR_SWORD -> AsmFragment(" lda $variable+${index*2+1} | asl a | ror $variable+${index*2+1} | ror $variable+${index*2}", 8)
Opcode.ROL_BYTE -> AsmFragment(" rol $variable+$index", 8)
Opcode.ROR_BYTE -> AsmFragment(" ror $variable+$index", 8)
Opcode.ROL_WORD -> AsmFragment(" rol $variable+${index*2+1} | rol $variable+${index*2}", 8)
Opcode.ROR_WORD -> AsmFragment(" ror $variable+${index*2+1} | ror $variable+${index*2}", 8)
Opcode.ROL2_BYTE -> AsmFragment(" lda $variable+$index | cmp #\$80 | rol $variable+$index", 8)
Opcode.ROR2_BYTE -> AsmFragment(" lda $variable+$index | lsr a | bcc + | ora #\$80 |+ | sta $variable+$index", 10)
Opcode.ROL2_WORD -> AsmFragment(" asl $variable+${index*2+1} | rol $variable+${index*2} | bcc + | inc $variable+${index*2+1} |+",20)
Opcode.ROR2_WORD -> AsmFragment(" lsr $variable+${index*2+1} | ror $variable+${index*2} | bcc + | lda $variable+${index*2+1} | ora #\$80 | sta $variable+${index*2+1} |+", 30)
Opcode.INC_INDEXED_VAR_B, Opcode.INC_INDEXED_VAR_UB -> AsmFragment(" inc $variable+$index", 2)
Opcode.DEC_INDEXED_VAR_B, Opcode.DEC_INDEXED_VAR_UB -> AsmFragment(" dec $variable+$index", 5)
Opcode.INC_INDEXED_VAR_W, Opcode.INC_INDEXED_VAR_UW -> AsmFragment(" inc $variable+${index*2} | bne + | inc $variable+${index*2+1} |+")
Opcode.DEC_INDEXED_VAR_W, Opcode.DEC_INDEXED_VAR_UW -> AsmFragment(" lda $variable+${index*2} | bne + | dec $variable+${index*2+1} |+ | dec $variable+${index*2}")
Opcode.INC_INDEXED_VAR_FLOAT -> AsmFragment(
"""
lda #<($variable+${index*Mflpt5.MemorySize})
ldy #>($variable+${index*Mflpt5.MemorySize})
jsr c64flt.inc_var_f
""")
Opcode.DEC_INDEXED_VAR_FLOAT -> AsmFragment(
"""
lda #<($variable+${index*Mflpt5.MemorySize})
ldy #>($variable+${index*Mflpt5.MemorySize})
jsr c64flt.dec_var_f
""")
else -> null
}
}
private fun sameIndexedVarOperation(variable: String, indexVar: String, ins: Instruction): AsmFragment? {
// an in place operation that consists of a push-value / op / push-index-var / pop-into-indexed-var
val saveX = " stx ${C64Zeropage.SCRATCH_B1} |"
val restoreX = " | ldx ${C64Zeropage.SCRATCH_B1}"
val loadXWord: String
val loadX: String
when(indexVar) {
"X" -> {
loadX = ""
loadXWord = " txa | asl a | tax |"
}
"Y" -> {
loadX = " tya | tax |"
loadXWord = " tya | asl a | tax |"
}
"A" -> {
loadX = " tax |"
loadXWord = " asl a | tax |"
}
else -> {
// the indexvar is a real variable, not a register
loadX = " ldx $indexVar |"
loadXWord = " lda $indexVar | asl a | tax |"
}
}
return when (ins.opcode) {
Opcode.SHL_BYTE -> AsmFragment(" txa | $loadX asl $variable,x | tax", 10)
Opcode.SHR_UBYTE -> AsmFragment(" txa | $loadX lsr $variable,x | tax", 10)
Opcode.SHR_SBYTE -> AsmFragment("$saveX $loadX lda $variable,x | asl a | ror $variable,x $restoreX", 10)
Opcode.SHL_WORD -> AsmFragment("$saveX $loadXWord asl $variable,x | rol $variable+1,x $restoreX", 10)
Opcode.SHR_UWORD -> AsmFragment("$saveX $loadXWord lsr $variable+1,x | ror $variable,x $restoreX", 10)
Opcode.SHR_SWORD -> AsmFragment("$saveX $loadXWord lda $variable+1,x | asl a | ror $variable+1,x | ror $variable,x $restoreX", 10)
Opcode.ROL_BYTE -> AsmFragment(" txa | $loadX rol $variable,x | tax", 10)
Opcode.ROR_BYTE -> AsmFragment(" txa | $loadX ror $variable,x | tax", 10)
Opcode.ROL_WORD -> AsmFragment("$saveX $loadXWord rol $variable,x | rol $variable+1,x $restoreX", 10)
Opcode.ROR_WORD -> AsmFragment("$saveX $loadXWord ror $variable+1,x | ror $variable,x $restoreX", 10)
Opcode.ROL2_BYTE -> AsmFragment("$saveX $loadX lda $variable,x | cmp #\$80 | rol $variable,x $restoreX", 10)
Opcode.ROR2_BYTE -> AsmFragment("$saveX $loadX lda $variable,x | lsr a | bcc + | ora #\$80 |+ | sta $variable,x $restoreX", 10)
Opcode.ROL2_WORD -> AsmFragment(" txa | $loadXWord asl $variable,x | rol $variable+1,x | bcc + | inc $variable,x |+ | tax", 30)
Opcode.ROR2_WORD -> AsmFragment("$saveX $loadXWord lsr $variable+1,x | ror $variable,x | bcc + | lda $variable+1,x | ora #\$80 | sta $variable+1,x |+ $restoreX", 30)
Opcode.INC_INDEXED_VAR_B, Opcode.INC_INDEXED_VAR_UB -> AsmFragment(" txa | $loadX inc $variable,x | tax", 10)
Opcode.DEC_INDEXED_VAR_B, Opcode.DEC_INDEXED_VAR_UB -> AsmFragment(" txa | $loadX dec $variable,x | tax", 10)
Opcode.INC_INDEXED_VAR_W, Opcode.INC_INDEXED_VAR_UW -> AsmFragment("$saveX $loadXWord inc $variable,x | bne + | inc $variable+1,x |+ $restoreX", 10)
Opcode.DEC_INDEXED_VAR_W, Opcode.DEC_INDEXED_VAR_UW -> AsmFragment("$saveX $loadXWord lda $variable,x | bne + | dec $variable+1,x |+ | dec $variable,x $restoreX", 10)
Opcode.INC_INDEXED_VAR_FLOAT -> AsmFragment(" lda #<$variable | ldy #>$variable | $saveX $loadX jsr c64flt.inc_indexed_var_f $restoreX")
Opcode.DEC_INDEXED_VAR_FLOAT -> AsmFragment(" lda #<$variable | ldy #>$variable | $saveX $loadX jsr c64flt.dec_indexed_var_f $restoreX")
else -> null
}
}
private fun sameMemOperation(address: Int, ins: Instruction): AsmFragment? {
// an in place operation that consists of push-mem / op / pop-mem
val addr = address.toHex()
val addrHi = (address+1).toHex()
return when(ins.opcode) {
Opcode.SHL_BYTE -> AsmFragment(" asl $addr", 10)
Opcode.SHR_UBYTE -> AsmFragment(" lsr $addr", 10)
Opcode.SHR_SBYTE -> AsmFragment(" lda $addr | asl a | ror $addr", 10)
Opcode.SHL_WORD -> AsmFragment(" asl $addr | rol $addrHi", 10)
Opcode.SHR_UWORD -> AsmFragment(" lsr $addrHi | ror $addr", 10)
Opcode.SHR_SWORD -> AsmFragment(" lda $addrHi | asl a | ror $addrHi | ror $addr", 10)
Opcode.ROL_BYTE -> AsmFragment(" rol $addr", 10)
Opcode.ROR_BYTE -> AsmFragment(" ror $addr", 10)
Opcode.ROL_WORD -> AsmFragment(" rol $addr | rol $addrHi", 10)
Opcode.ROR_WORD -> AsmFragment(" ror $addrHi | ror $addr", 10)
Opcode.ROL2_BYTE -> AsmFragment(" lda $addr | cmp #\$80 | rol $addr", 10)
Opcode.ROR2_BYTE -> AsmFragment(" lda $addr | lsr a | bcc + | ora #\$80 |+ | sta $addr", 10)
Opcode.ROL2_WORD -> AsmFragment(" lda $addr | cmp #\$80 | rol $addr | rol $addrHi", 10)
Opcode.ROR2_WORD -> AsmFragment(" lsr $addrHi | ror $addr | bcc + | lda $addrHi | ora #$80 | sta $addrHi |+", 20)
else -> null
}
}
private fun sameVarOperation(variable: String, ins: Instruction): AsmFragment? {
// an in place operation that consists of a push-var / op / pop-var
return when(ins.opcode) {
Opcode.SHL_BYTE -> {
when (variable) {
"A" -> AsmFragment(" asl a", 10)
"X" -> AsmFragment(" txa | asl a | tax", 10)
"Y" -> AsmFragment(" tya | asl a | tay", 10)
else -> AsmFragment(" asl $variable", 10)
}
}
Opcode.SHR_UBYTE -> {
when (variable) {
"A" -> AsmFragment(" lsr a", 10)
"X" -> AsmFragment(" txa | lsr a | tax", 10)
"Y" -> AsmFragment(" tya | lsr a | tay", 10)
else -> AsmFragment(" lsr $variable", 10)
}
}
Opcode.SHR_SBYTE -> {
// arithmetic shift right (keep sign bit)
when (variable) {
"A" -> AsmFragment(" cmp #$80 | ror a", 10)
"X" -> AsmFragment(" txa | cmp #$80 | ror a | tax", 10)
"Y" -> AsmFragment(" tya | cmp #$80 | ror a | tay", 10)
else -> AsmFragment(" lda $variable | asl a | ror $variable", 10)
}
}
Opcode.SHL_WORD -> {
AsmFragment(" asl $variable | rol $variable+1", 10)
}
Opcode.SHR_UWORD -> {
AsmFragment(" lsr $variable+1 | ror $variable", 10)
}
Opcode.SHR_SWORD -> {
// arithmetic shift right (keep sign bit)
AsmFragment(" lda $variable+1 | asl a | ror $variable+1 | ror $variable", 10)
}
Opcode.ROL_BYTE -> {
when (variable) {
"A" -> AsmFragment(" rol a", 10)
"X" -> AsmFragment(" txa | rol a | tax", 10)
"Y" -> AsmFragment(" tya | rol a | tay", 10)
else -> AsmFragment(" rol $variable", 10)
}
}
Opcode.ROR_BYTE -> {
when (variable) {
"A" -> AsmFragment(" ror a", 10)
"X" -> AsmFragment(" txa | ror a | tax", 10)
"Y" -> AsmFragment(" tya | ror a | tay", 10)
else -> AsmFragment(" ror $variable", 10)
}
}
Opcode.ROL_WORD -> {
AsmFragment(" rol $variable | rol $variable+1", 10)
}
Opcode.ROR_WORD -> {
AsmFragment(" ror $variable+1 | ror $variable", 10)
}
Opcode.ROL2_BYTE -> { // 8-bit rol
when (variable) {
"A" -> AsmFragment(" cmp #\$80 | rol a", 10)
"X" -> AsmFragment(" txa | cmp #\$80 | rol a | tax", 10)
"Y" -> AsmFragment(" tya | cmp #\$80 | rol a | tay", 10)
else -> AsmFragment(" lda $variable | cmp #\$80 | rol $variable", 10)
}
}
Opcode.ROR2_BYTE -> { // 8-bit ror
when (variable) {
"A" -> AsmFragment(" lsr a | bcc + | ora #\$80 |+", 10)
"X" -> AsmFragment(" txa | lsr a | bcc + | ora #\$80 |+ | tax", 10)
"Y" -> AsmFragment(" tya | lsr a | bcc + | ora #\$80 |+ | tay", 10)
else -> AsmFragment(" lda $variable | lsr a | bcc + | ora #\$80 |+ | sta $variable", 10)
}
}
Opcode.ROL2_WORD -> {
AsmFragment(" lda $variable | cmp #\$80 | rol $variable | rol $variable+1", 10)
}
Opcode.ROR2_WORD -> {
AsmFragment(" lsr $variable+1 | ror $variable | bcc + | lda $variable+1 | ora #\$80 | sta $variable+1 |+", 30)
}
else -> null
}
}
private class AsmFragment(val asm: String, var segmentSize: Int=0)
}

2294
compiler/src/prog8/compiler/target/c64/AsmPatterns.kt
View File

File diff suppressed because it is too large Load Diff

30
compiler/src/prog8/compiler/target/c64/AssemblyProgram.kt
View File

@ -2,31 +2,35 @@ package prog8.compiler.target.c64
import prog8.compiler.CompilationOptions
import prog8.compiler.OutputType
import java.io.File
import prog8.compiler.target.IAssemblyProgram
import java.nio.file.Path
import kotlin.system.exitProcess
class AssemblyProgram(val name: String) {
private val assemblyFile = "$name.asm"
private val viceMonListFile = "$name.vice-mon-list"
class AssemblyProgram(override val name: String, outputDir: Path): IAssemblyProgram {
private val assemblyFile = outputDir.resolve("$name.asm")
private val prgFile = outputDir.resolve("$name.prg")
private val binFile = outputDir.resolve("$name.bin")
private val viceMonListFile = outputDir.resolve("$name.vice-mon-list")
fun assemble(options: CompilationOptions) {
override fun assemble(options: CompilationOptions) {
// add "-Wlong-branch" to see warnings about conversion of branch instructions to jumps
val command = mutableListOf("64tass", "--ascii", "--case-sensitive", "--long-branch", "-Wall", "-Wno-strict-bool",
"-Werror", "-Wno-error=long-branch", "--dump-labels", "--vice-labels", "-l", viceMonListFile, "--no-monitor")
val command = mutableListOf("64tass", "--ascii", "--case-sensitive", "--long-branch",
"-Wall", "-Wno-strict-bool", "-Wno-shadow", "-Werror", "-Wno-error=long-branch",
"--dump-labels", "--vice-labels", "-l", viceMonListFile.toString(), "--no-monitor")
val outFile = when(options.output) {
OutputType.PRG -> {
command.add("--cbm-prg")
println("\nCreating C-64 prg.")
"$name.prg"
prgFile
}
OutputType.RAW -> {
command.add("--nostart")
println("\nCreating raw binary.")
"$name.bin"
binFile
}
}
command.addAll(listOf("--output", outFile, assemblyFile))
command.addAll(listOf("--output", outFile.toString(), assemblyFile.toString()))
val proc = ProcessBuilder(command).inheritIO().start()
val result = proc.waitFor()
@ -41,8 +45,8 @@ class AssemblyProgram(val name: String) {
private fun generateBreakpointList() {
// builds list of breakpoints, appends to monitor list file
val breakpoints = mutableListOf<String>()
val pattern = Regex("""al (\w+) \S+_prog8_breakpoint_\d+.?""") // gather breakpoints by the source label that's generated for them
for(line in File(viceMonListFile).readLines()) {
val pattern = Regex("""al (\w+) \S+_prog8_breakpoint_\d+.?""") // gather breakpoints by the source label that"s generated for them
for(line in viceMonListFile.toFile().readLines()) {
val match = pattern.matchEntire(line)
if(match!=null)
breakpoints.add("break \$" + match.groupValues[1])
@ -51,6 +55,6 @@ class AssemblyProgram(val name: String) {
breakpoints.add(0, "; vice monitor breakpoint list now follows")
breakpoints.add(1, "; $num breakpoints have been defined")
breakpoints.add(2, "del")
File(viceMonListFile).appendText(breakpoints.joinToString("\n")+"\n")
viceMonListFile.toFile().appendText(breakpoints.joinToString("\n")+"\n")
}
}

266
compiler/src/prog8/compiler/target/c64/C64MachineDefinition.kt Normal file
View File

@ -0,0 +1,266 @@
package prog8.compiler.target.c64
import prog8.compiler.CompilationOptions
import prog8.compiler.CompilerException
import prog8.compiler.Zeropage
import prog8.compiler.ZeropageType
import prog8.compiler.target.IMachineDefinition
import java.awt.Color
import java.awt.image.BufferedImage
import javax.imageio.ImageIO
import kotlin.math.absoluteValue
import kotlin.math.pow
object C64MachineDefinition: IMachineDefinition {
// 5-byte cbm MFLPT format limitations:
override val FLOAT_MAX_POSITIVE = 1.7014118345e+38 // bytes: 255,127,255,255,255
override val FLOAT_MAX_NEGATIVE = -1.7014118345e+38 // bytes: 255,255,255,255,255
override val FLOAT_MEM_SIZE = 5
const val BASIC_LOAD_ADDRESS = 0x0801
const val RAW_LOAD_ADDRESS = 0xc000
// the 2*256 byte evaluation stack (on which bytes, words, and even floats are stored during calculations)
// and some heavily used string constants derived from the two values above
const val ESTACK_LO_VALUE = 0xce00 // $ce00-$ceff inclusive
const val ESTACK_HI_VALUE = 0xcf00 // $cf00-$cfff inclusive
const val ESTACK_LO_HEX = "\$ce00"
const val ESTACK_LO_PLUS1_HEX = "\$ce01"
const val ESTACK_LO_PLUS2_HEX = "\$ce02"
const val ESTACK_HI_HEX = "\$cf00"
const val ESTACK_HI_PLUS1_HEX = "\$cf01"
const val ESTACK_HI_PLUS2_HEX = "\$cf02"
override fun getZeropage(compilerOptions: CompilationOptions) = C64Zeropage(compilerOptions)
// 6502 opcodes (including aliases and illegal opcodes), these cannot be used as variable or label names
override val opcodeNames = 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")
class C64Zeropage(options: CompilationOptions) : Zeropage(options) {
companion object {
const val SCRATCH_B1 = 0x02
const val SCRATCH_REG = 0x03 // temp storage for a register
const val SCRATCH_REG_X = 0xfa // temp storage for register X (the evaluation stack pointer)
const val SCRATCH_W1 = 0xfb // $fb+$fc
const val SCRATCH_W2 = 0xfd // $fd+$fe
}
override val exitProgramStrategy: ExitProgramStrategy = when (options.zeropage) {
ZeropageType.BASICSAFE, ZeropageType.DONTUSE -> ExitProgramStrategy.CLEAN_EXIT
ZeropageType.FLOATSAFE, ZeropageType.KERNALSAFE, ZeropageType.FULL -> ExitProgramStrategy.SYSTEM_RESET
}
init {
if (options.floats && options.zeropage !in setOf(ZeropageType.FLOATSAFE, ZeropageType.BASICSAFE, ZeropageType.DONTUSE ))
throw CompilerException("when floats are enabled, zero page type should be 'floatsafe' or 'basicsafe' or 'dontuse'")
if (options.zeropage == ZeropageType.FULL) {
free.addAll(0x04..0xf9)
free.add(0xff)
free.removeAll(listOf(SCRATCH_B1, SCRATCH_REG, SCRATCH_REG_X, SCRATCH_W1, SCRATCH_W1 + 1, SCRATCH_W2, SCRATCH_W2 + 1))
free.removeAll(listOf(0xa0, 0xa1, 0xa2, 0x91, 0xc0, 0xc5, 0xcb, 0xf5, 0xf6)) // these are updated by IRQ
} else {
if (options.zeropage == ZeropageType.KERNALSAFE || options.zeropage == ZeropageType.FLOATSAFE) {
free.addAll(listOf(0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f, 0x10, 0x11,
0x14, 0x15, 0x16, 0x17, 0x18, 0x19, 0x1a, 0x1b, 0x1c, 0x1d, 0x1e, 0x1f, 0x20, 0x21,
0x22, 0x23, 0x24, 0x25,
0x39, 0x3a, 0x3b, 0x3c, 0x3d, 0x3e, 0x3f, 0x40, 0x41, 0x42, 0x43, 0x44, 0x45, 0x46,
0x47, 0x48, 0x4b, 0x4c, 0x4d, 0x4e, 0x4f, 0x51, 0x52, 0x53,
0x57, 0x58, 0x59, 0x5a, 0x5b, 0x5c, 0x5d, 0x5e, 0x5f, 0x60,
0x61, 0x62, 0x63, 0x64, 0x65, 0x66, 0x67, 0x68,
0x69, 0x6a, 0x6b, 0x6c, 0x6d, 0x6e, 0x6f, 0x70, 0x71, 0x72,
0x73, 0x74, 0x75, 0x76, 0x77, 0x78, 0x79, 0x7a, 0x7b, 0x7c,
0x7d, 0x7e, 0x7f, 0x80, 0x81, 0x82, 0x83, 0x84, 0x85, 0x86, 0x87, 0x88, 0x89, 0x8a,
0x8b, 0x8c, 0x8d, 0x8e, 0x8f, 0xff
// 0x90-0xfa is 'kernel work storage area'
))
}
if (options.zeropage == ZeropageType.FLOATSAFE) {
// remove the zero page locations used for floating point operations from the free list
free.removeAll(listOf(
0x12, 0x26, 0x27, 0x28, 0x29, 0x2a,
0x57, 0x58, 0x59, 0x5a, 0x5b, 0x5c, 0x5d, 0x5e, 0x5f, 0x60,
0x61, 0x62, 0x63, 0x64, 0x65, 0x66, 0x67, 0x68,
0x69, 0x6a, 0x6b, 0x6c, 0x6d, 0x6e, 0x6f, 0x70, 0x71, 0x72,
0x8b, 0x8c, 0x8d, 0x8e, 0x8f, 0xf
))
}
if(options.zeropage!=ZeropageType.DONTUSE) {
// add the other free Zp addresses,
// these are valid for the C-64 (when no RS232 I/O is performed) but to keep BASIC running fully:
free.addAll(listOf(0x04, 0x05, 0x06, 0x0a, 0x0e,
0x94, 0x95, 0xa7, 0xa8, 0xa9, 0xaa,
0xb5, 0xb6, 0xf7, 0xf8, 0xf9))
} else {
// don't use the zeropage at all
free.clear()
}
}
assert(SCRATCH_B1 !in free)
assert(SCRATCH_REG !in free)
assert(SCRATCH_REG_X !in free)
assert(SCRATCH_W1 !in free)
assert(SCRATCH_W2 !in free)
for (reserved in options.zpReserved)
reserve(reserved)
}
}
data class Mflpt5(val b0: Short, val b1: Short, val b2: Short, val b3: Short, val b4: Short) {
companion object {
val zero = Mflpt5(0, 0, 0, 0, 0)
fun fromNumber(num: Number): Mflpt5 {
// see https://en.wikipedia.org/wiki/Microsoft_Binary_Format
// and https://sourceforge.net/p/acme-crossass/code-0/62/tree/trunk/ACME_Lib/cbm/mflpt.a
// and https://en.wikipedia.org/wiki/IEEE_754-1985
val flt = num.toDouble()
if (flt < FLOAT_MAX_NEGATIVE || flt > FLOAT_MAX_POSITIVE)
throw CompilerException("floating point number out of 5-byte mflpt range: $this")
if (flt == 0.0)
return zero
val sign = if (flt < 0.0) 0x80L else 0x00L
var exponent = 128 + 32 // 128 is cbm's bias, 32 is this algo's bias
var mantissa = flt.absoluteValue
// if mantissa is too large, shift right and adjust exponent
while (mantissa >= 0x100000000) {
mantissa /= 2.0
exponent++
}
// if mantissa is too small, shift left and adjust exponent
while (mantissa < 0x80000000) {
mantissa *= 2.0
exponent--
}
return when {
exponent < 0 -> zero // underflow, use zero instead
exponent > 255 -> throw CompilerException("floating point overflow: $this")
exponent == 0 -> zero
else -> {
val mantLong = mantissa.toLong()
Mflpt5(
exponent.toShort(),
(mantLong.and(0x7f000000L) ushr 24).or(sign).toShort(),
(mantLong.and(0x00ff0000L) ushr 16).toShort(),
(mantLong.and(0x0000ff00L) ushr 8).toShort(),
(mantLong.and(0x000000ffL)).toShort())
}
}
}
}
fun toDouble(): Double {
if (this == zero) return 0.0
val exp = b0 - 128
val sign = (b1.toInt() and 0x80) > 0
val number = 0x80000000L.or(b1.toLong() shl 24).or(b2.toLong() shl 16).or(b3.toLong() shl 8).or(b4.toLong())
val result = number.toDouble() * (2.0).pow(exp) / 0x100000000
return if (sign) -result else result
}
}
object Charset {
private val normalImg = ImageIO.read(javaClass.getResource("/charset/c64/charset-normal.png"))
private val shiftedImg = ImageIO.read(javaClass.getResource("/charset/c64/charset-shifted.png"))
private fun scanChars(img: BufferedImage): Array<BufferedImage> {
val transparent = BufferedImage(img.width, img.height, BufferedImage.TYPE_INT_ARGB)
transparent.createGraphics().drawImage(img, 0, 0, null)
val black = Color(0, 0, 0).rgb
val nopixel = Color(0, 0, 0, 0).rgb
for (y in 0 until transparent.height) {
for (x in 0 until transparent.width) {
val col = transparent.getRGB(x, y)
if (col == black)
transparent.setRGB(x, y, nopixel)
}
}
val numColumns = transparent.width / 8
val charImages = (0..255).map {
val charX = it % numColumns
val charY = it / numColumns
transparent.getSubimage(charX * 8, charY * 8, 8, 8)
}
return charImages.toTypedArray()
}
val normalChars = scanChars(normalImg)
val shiftedChars = scanChars(shiftedImg)
private val coloredNormalChars = mutableMapOf<Short, Array<BufferedImage>>()
fun getColoredChar(screenCode: Short, color: Short): BufferedImage {
val colorIdx = (color % colorPalette.size).toShort()
val chars = coloredNormalChars[colorIdx]
if (chars != null)
return chars[screenCode.toInt()]
val coloredChars = mutableListOf<BufferedImage>()
val transparent = Color(0, 0, 0, 0).rgb
val rgb = colorPalette[colorIdx.toInt()].rgb
for (c in normalChars) {
val colored = c.copy()
for (y in 0 until colored.height)
for (x in 0 until colored.width) {
if (colored.getRGB(x, y) != transparent) {
colored.setRGB(x, y, rgb)
}
}
coloredChars.add(colored)
}
coloredNormalChars[colorIdx] = coloredChars.toTypedArray()
return coloredNormalChars.getValue(colorIdx)[screenCode.toInt()]
}
}
private fun BufferedImage.copy(): BufferedImage {
val bcopy = BufferedImage(this.width, this.height, this.type)
val g = bcopy.graphics
g.drawImage(this, 0, 0, null)
g.dispose()
return bcopy
}
val colorPalette = listOf( // this is Pepto's Commodore-64 palette http://www.pepto.de/projects/colorvic/
Color(0x000000), // 0 = black
Color(0xFFFFFF), // 1 = white
Color(0x813338), // 2 = red
Color(0x75cec8), // 3 = cyan
Color(0x8e3c97), // 4 = purple
Color(0x56ac4d), // 5 = green
Color(0x2e2c9b), // 6 = blue
Color(0xedf171), // 7 = yellow
Color(0x8e5029), // 8 = orange
Color(0x553800), // 9 = brown
Color(0xc46c71), // 10 = light red
Color(0x4a4a4a), // 11 = dark grey
Color(0x7b7b7b), // 12 = medium grey
Color(0xa9ff9f), // 13 = light green
Color(0x706deb), // 14 = light blue
Color(0xb2b2b2) // 15 = light grey
)
}

242
compiler/src/prog8/compiler/target/c64/Commodore64.kt
View File

@ -1,242 +0,0 @@
package prog8.compiler.target.c64
import prog8.compiler.CompilationOptions
import prog8.compiler.CompilerException
import prog8.compiler.Zeropage
import prog8.compiler.ZeropageType
import java.awt.Color
import java.awt.image.BufferedImage
import javax.imageio.ImageIO
import kotlin.math.absoluteValue
import kotlin.math.pow
// 5-byte cbm MFLPT format limitations:
const val FLOAT_MAX_POSITIVE = 1.7014118345e+38 // bytes: 255,127,255,255,255
const val FLOAT_MAX_NEGATIVE = -1.7014118345e+38 // bytes: 255,255,255,255,255
const val BASIC_LOAD_ADDRESS = 0x0801
const val RAW_LOAD_ADDRESS = 0xc000
// the 2*256 byte evaluation stack (on which bytes, words, and even floats are stored during calculations)
const val ESTACK_LO = 0xce00 // $ce00-$ceff inclusive
const val ESTACK_HI = 0xcf00 // $cf00-$cfff inclusive
class C64Zeropage(options: CompilationOptions) : Zeropage(options) {
companion object {
const val SCRATCH_B1 = 0x02
const val SCRATCH_REG = 0x03 // temp storage for a register
const val SCRATCH_REG_X = 0xfa // temp storage for register X (the evaluation stack pointer)
const val SCRATCH_W1 = 0xfb // $fb+$fc
const val SCRATCH_W2 = 0xfd // $fd+$fe
}
override val exitProgramStrategy: ExitProgramStrategy = when(options.zeropage) {
ZeropageType.BASICSAFE -> ExitProgramStrategy.CLEAN_EXIT
ZeropageType.FLOATSAFE, ZeropageType.KERNALSAFE, ZeropageType.FULL -> ExitProgramStrategy.SYSTEM_RESET
}
init {
if(options.floats && options.zeropage!=ZeropageType.FLOATSAFE && options.zeropage!=ZeropageType.BASICSAFE)
throw CompilerException("when floats are enabled, zero page type should be 'floatsafe' or 'basicsafe'")
if(options.zeropage == ZeropageType.FULL) {
free.addAll(0x04 .. 0xf9)
free.add(0xff)
free.removeAll(listOf(SCRATCH_B1, SCRATCH_REG, SCRATCH_REG_X, SCRATCH_W1, SCRATCH_W1+1, SCRATCH_W2, SCRATCH_W2+1))
free.removeAll(listOf(0xa0, 0xa1, 0xa2, 0x91, 0xc0, 0xc5, 0xcb, 0xf5, 0xf6)) // these are updated by IRQ
} else {
if(options.zeropage == ZeropageType.KERNALSAFE || options.zeropage == ZeropageType.FLOATSAFE) {
free.addAll(listOf(0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f, 0x10, 0x11,
0x14, 0x15, 0x16, 0x17, 0x18, 0x19, 0x1a, 0x1b, 0x1c, 0x1d, 0x1e, 0x1f, 0x20, 0x21,
0x22, 0x23, 0x24, 0x25,
0x39, 0x3a, 0x3b, 0x3c, 0x3d, 0x3e, 0x3f, 0x40, 0x41, 0x42, 0x43, 0x44, 0x45, 0x46,
0x47, 0x48, 0x4b, 0x4c, 0x4d, 0x4e, 0x4f, 0x51, 0x52, 0x53,
0x57, 0x58, 0x59, 0x5a, 0x5b, 0x5c, 0x5d, 0x5e, 0x5f, 0x60,
0x61, 0x62, 0x63, 0x64, 0x65, 0x66, 0x67, 0x68,
0x69, 0x6a, 0x6b, 0x6c, 0x6d, 0x6e, 0x6f, 0x70, 0x71, 0x72,
0x73, 0x74, 0x75, 0x76, 0x77, 0x78, 0x79, 0x7a, 0x7b, 0x7c,
0x7d, 0x7e, 0x7f, 0x80, 0x81, 0x82, 0x83, 0x84, 0x85, 0x86, 0x87, 0x88, 0x89, 0x8a,
0x8b, 0x8c, 0x8d, 0x8e, 0x8f, 0xff
// 0x90-0xfa is 'kernel work storage area'
))
}
if(options.zeropage == ZeropageType.FLOATSAFE) {
// remove the zero page locations used for floating point operations from the free list
free.removeAll(listOf(
0x12, 0x26, 0x27, 0x28, 0x29, 0x2a,
0x57, 0x58, 0x59, 0x5a, 0x5b, 0x5c, 0x5d, 0x5e, 0x5f, 0x60,
0x61, 0x62, 0x63, 0x64, 0x65, 0x66, 0x67, 0x68,
0x69, 0x6a, 0x6b, 0x6c, 0x6d, 0x6e, 0x6f, 0x70, 0x71, 0x72,
0x8b, 0x8c, 0x8d, 0x8e, 0x8f, 0xf
))
}
// add the other free Zp addresses,
// these are valid for the C-64 (when no RS232 I/O is performed) but to keep BASIC running fully:
free.addAll(listOf(0x04, 0x05, 0x06, 0x07, 0x08, 0x09, 0x0a, 0x0d, 0x0e,
0x94, 0x95, 0xa7, 0xa8, 0xa9, 0xaa,
0xb5, 0xb6, 0xf7, 0xf8, 0xf9))
}
assert(SCRATCH_B1 !in free)
assert(SCRATCH_REG !in free)
assert(SCRATCH_REG_X !in free)
assert(SCRATCH_W1 !in free)
assert(SCRATCH_W2 !in free)
for(reserved in options.zpReserved)
reserve(reserved)
}
}
data class Mflpt5(val b0: Short, val b1: Short, val b2: Short, val b3: Short, val b4: Short) {
companion object {
const val MemorySize = 5
val zero = Mflpt5(0, 0,0,0,0)
fun fromNumber(num: Number): Mflpt5 {
// see https://en.wikipedia.org/wiki/Microsoft_Binary_Format
// and https://sourceforge.net/p/acme-crossass/code-0/62/tree/trunk/ACME_Lib/cbm/mflpt.a
// and https://en.wikipedia.org/wiki/IEEE_754-1985
val flt = num.toDouble()
if(flt < FLOAT_MAX_NEGATIVE || flt > FLOAT_MAX_POSITIVE)
throw CompilerException("floating point number out of 5-byte mflpt range: $this")
if(flt==0.0)
return zero
val sign = if(flt<0.0) 0x80L else 0x00L
var exponent = 128 + 32 // 128 is cbm's bias, 32 is this algo's bias
var mantissa = flt.absoluteValue
// if mantissa is too large, shift right and adjust exponent
while(mantissa >= 0x100000000) {
mantissa /= 2.0
exponent ++
}
// if mantissa is too small, shift left and adjust exponent
while(mantissa < 0x80000000) {
mantissa *= 2.0
exponent --
}
return when {
exponent<0 -> zero // underflow, use zero instead
exponent>255 -> throw CompilerException("floating point overflow: $this")
exponent==0 -> zero
else -> {
val mantLong = mantissa.toLong()
Mflpt5(
exponent.toShort(),
(mantLong.and(0x7f000000L) ushr 24).or(sign).toShort(),
(mantLong.and(0x00ff0000L) ushr 16).toShort(),
(mantLong.and(0x0000ff00L) ushr 8).toShort(),
(mantLong.and(0x000000ffL)).toShort())
}
}
}
}
fun toDouble(): Double {
if(this == zero) return 0.0
val exp = b0 - 128
val sign = (b1.toInt() and 0x80) > 0
val number = 0x80000000L.or(b1.toLong() shl 24).or(b2.toLong() shl 16).or(b3.toLong() shl 8).or(b4.toLong())
val result = number.toDouble() * (2.0).pow(exp) / 0x100000000
return if(sign) -result else result
}
}
object Charset {
private val normalImg = ImageIO.read(javaClass.getResource("/charset/c64/charset-normal.png"))
private val shiftedImg = ImageIO.read(javaClass.getResource("/charset/c64/charset-shifted.png"))
private fun scanChars(img: BufferedImage): Array<BufferedImage> {
val transparent = BufferedImage(img.width, img.height, BufferedImage.TYPE_INT_ARGB)
transparent.createGraphics().drawImage(img, 0, 0, null)
val black = Color(0,0,0).rgb
val nopixel = Color(0,0,0,0).rgb
for(y in 0 until transparent.height) {
for(x in 0 until transparent.width) {
val col = transparent.getRGB(x, y)
if(col==black)
transparent.setRGB(x, y, nopixel)
}
}
val numColumns = transparent.width / 8
val charImages = (0..255).map {
val charX = it % numColumns
val charY = it/ numColumns
transparent.getSubimage(charX*8, charY*8, 8, 8)
}
return charImages.toTypedArray()
}
val normalChars = scanChars(normalImg)
val shiftedChars = scanChars(shiftedImg)
private val coloredNormalChars = mutableMapOf<Short, Array<BufferedImage>>()
fun getColoredChar(screenCode: Short, color: Short): BufferedImage {
val colorIdx = (color % Colors.palette.size).toShort()
val chars = coloredNormalChars[colorIdx]
if(chars!=null)
return chars[screenCode.toInt()]
val coloredChars = mutableListOf<BufferedImage>()
val transparent = Color(0,0,0,0).rgb
val rgb = Colors.palette[colorIdx.toInt()].rgb
for(c in normalChars) {
val colored = c.copy()
for(y in 0 until colored.height)
for(x in 0 until colored.width) {
if(colored.getRGB(x, y)!=transparent) {
colored.setRGB(x, y, rgb)
}
}
coloredChars.add(colored)
}
coloredNormalChars[colorIdx] = coloredChars.toTypedArray()
return coloredNormalChars.getValue(colorIdx)[screenCode.toInt()]
}
}
private fun BufferedImage.copy(): BufferedImage {
val bcopy = BufferedImage(this.width, this.height, this.type)
val g = bcopy.graphics
g.drawImage(this, 0, 0, null)
g.dispose()
return bcopy
}
object Colors {
val palette = listOf( // this is Pepto's Commodore-64 palette http://www.pepto.de/projects/colorvic/
Color(0x000000), // 0 = black
Color(0xFFFFFF), // 1 = white
Color(0x813338), // 2 = red
Color(0x75cec8), // 3 = cyan
Color(0x8e3c97), // 4 = purple
Color(0x56ac4d), // 5 = green
Color(0x2e2c9b), // 6 = blue
Color(0xedf171), // 7 = yellow
Color(0x8e5029), // 8 = orange
Color(0x553800), // 9 = brown
Color(0xc46c71), // 10 = light red
Color(0x4a4a4a), // 11 = dark grey
Color(0x7b7b7b), // 12 = medium grey
Color(0xa9ff9f), // 13 = light green
Color(0x706deb), // 14 = light blue
Color(0xb2b2b2) // 15 = light grey
)
}

2179
compiler/src/prog8/compiler/target/c64/Petscii.kt
View File

File diff suppressed because it is too large Load Diff

531
compiler/src/prog8/compiler/target/c64/SimpleAsm.kt
View File

@ -1,531 +0,0 @@
package prog8.compiler.target.c64
import prog8.compiler.CompilerException
import prog8.compiler.intermediate.Instruction
import prog8.compiler.intermediate.IntermediateProgram
import prog8.compiler.intermediate.LabelInstr
import prog8.compiler.intermediate.Opcode
import prog8.compiler.toHex
import prog8.vm.stackvm.Syscall
import prog8.vm.stackvm.syscallsForStackVm
private var breakpointCounter = 0
internal fun simpleInstr2Asm(ins: Instruction, block: IntermediateProgram.ProgramBlock): String? {
// a label 'instruction' is simply translated into a asm label
if(ins is LabelInstr) {
val labelresult =
if(ins.name.startsWith("${block.name}."))
ins.name.substring(block.name.length+1)
else
ins.name
return if(ins.asmProc) labelresult+"\t\t.proc" else labelresult
}
// simple opcodes that are translated directly into one or a few asm instructions
return when(ins.opcode) {
Opcode.LINE -> " ;\tsrc line: ${ins.callLabel}"
Opcode.NOP -> " nop" // shouldn't be present anymore though
Opcode.START_PROCDEF -> "" // is done as part of a label
Opcode.END_PROCDEF -> " .pend"
Opcode.TERMINATE -> " brk"
Opcode.SEC -> " sec"
Opcode.CLC -> " clc"
Opcode.SEI -> " sei"
Opcode.CLI -> " cli"
Opcode.CARRY_TO_A -> " lda #0 | adc #0"
Opcode.JUMP -> {
if(ins.callLabel!=null)
" jmp ${ins.callLabel}"
else
" jmp ${hexVal(ins)}"
}
Opcode.CALL -> {
if(ins.callLabel!=null)
" jsr ${ins.callLabel}"
else
" jsr ${hexVal(ins)}"
}
Opcode.RETURN -> " rts"
Opcode.RSAVE -> {
// save cpu status flag and all registers A, X, Y.
// see http://6502.org/tutorials/register_preservation.html
" php | sta ${C64Zeropage.SCRATCH_REG} | pha | txa | pha | tya | pha | lda ${C64Zeropage.SCRATCH_REG}"
}
Opcode.RRESTORE -> {
// restore all registers and cpu status flag
" pla | tay | pla | tax | pla | plp"
}
Opcode.RSAVEX -> " sta ${C64Zeropage.SCRATCH_REG} | txa | pha | lda ${C64Zeropage.SCRATCH_REG}"
Opcode.RRESTOREX -> " sta ${C64Zeropage.SCRATCH_REG} | pla | tax | lda ${C64Zeropage.SCRATCH_REG}"
Opcode.DISCARD_BYTE -> " inx"
Opcode.DISCARD_WORD -> " inx"
Opcode.DUP_B -> {
" dex | lda ${(ESTACK_LO+1).toHex()},x | sta ${ESTACK_LO.toHex()},x"
}
Opcode.DUP_W -> {
" dex | lda ${(ESTACK_LO+1).toHex()},x | sta ${ESTACK_LO.toHex()},x | lda ${(ESTACK_HI+1).toHex()},x | sta ${ESTACK_HI.toHex()},x "
}
Opcode.DISCARD_FLOAT -> " inx | inx | inx"
Opcode.INLINE_ASSEMBLY -> "@inline@" + (ins.callLabel2 ?: "") // All of the inline assembly is stored in the calllabel2 property. the '@inline@' is a special marker to accept it.
Opcode.INCLUDE_FILE -> {
val offset = if(ins.arg==null) "" else ", ${ins.arg.integerValue()}"
val length = if(ins.arg2==null) "" else ", ${ins.arg2.integerValue()}"
" .binary \"${ins.callLabel}\" $offset $length"
}
Opcode.SYSCALL -> {
if (ins.arg!!.numericValue() in syscallsForStackVm.map { it.callNr })
throw CompilerException("cannot translate vm syscalls to real assembly calls - use *real* subroutine calls instead. Syscall ${ins.arg.numericValue()}")
val call = Syscall.values().find { it.callNr==ins.arg.numericValue() }
when(call) {
Syscall.FUNC_SIN,
Syscall.FUNC_COS,
Syscall.FUNC_ABS,
Syscall.FUNC_TAN,
Syscall.FUNC_ATAN,
Syscall.FUNC_LN,
Syscall.FUNC_LOG2,
Syscall.FUNC_SQRT,
Syscall.FUNC_RAD,
Syscall.FUNC_DEG,
Syscall.FUNC_ROUND,
Syscall.FUNC_FLOOR,
Syscall.FUNC_CEIL,
Syscall.FUNC_RNDF,
Syscall.FUNC_ANY_F,
Syscall.FUNC_ALL_F,
Syscall.FUNC_MAX_F,
Syscall.FUNC_MIN_F,
Syscall.FUNC_SUM_F -> " jsr c64flt.${call.name.toLowerCase()}"
null -> ""
else -> " jsr prog8_lib.${call.name.toLowerCase()}"
}
}
Opcode.BREAKPOINT -> {
breakpointCounter++
"_prog8_breakpoint_$breakpointCounter\tnop"
}
Opcode.PUSH_BYTE -> {
" lda #${hexVal(ins)} | sta ${ESTACK_LO.toHex()},x | dex"
}
Opcode.PUSH_WORD -> {
val value = hexVal(ins)
" lda #<$value | sta ${ESTACK_LO.toHex()},x | lda #>$value | sta ${ESTACK_HI.toHex()},x | dex"
}
Opcode.PUSH_FLOAT -> {
val floatConst = getFloatConst(ins.arg!!)
" lda #<$floatConst | ldy #>$floatConst | jsr c64flt.push_float"
}
Opcode.PUSH_VAR_BYTE -> {
when(ins.callLabel) {
"X" -> throw CompilerException("makes no sense to push X, it's used as a stack pointer itself. You should probably not use the X register (or only in trivial assignments)")
"A" -> " sta ${ESTACK_LO.toHex()},x | dex"
"Y" -> " tya | sta ${ESTACK_LO.toHex()},x | dex"
else -> " lda ${ins.callLabel} | sta ${ESTACK_LO.toHex()},x | dex"
}
}
Opcode.PUSH_VAR_WORD -> {
" lda ${ins.callLabel} | sta ${ESTACK_LO.toHex()},x | lda ${ins.callLabel}+1 | sta ${ESTACK_HI.toHex()},x | dex"
}
Opcode.PUSH_VAR_FLOAT -> " lda #<${ins.callLabel} | ldy #>${ins.callLabel}| jsr c64flt.push_float"
Opcode.PUSH_MEM_B, Opcode.PUSH_MEM_UB -> {
"""
lda ${hexVal(ins)}
sta ${ESTACK_LO.toHex()},x
dex
"""
}
Opcode.PUSH_MEM_W, Opcode.PUSH_MEM_UW -> {
"""
lda ${hexVal(ins)}
sta ${ESTACK_LO.toHex()},x
lda ${hexValPlusOne(ins)}
sta ${ESTACK_HI.toHex()},x
dex
"""
}
Opcode.PUSH_MEM_FLOAT -> {
" lda #<${hexVal(ins)} | ldy #>${hexVal(ins)}| jsr c64flt.push_float"
}
Opcode.PUSH_MEMREAD -> {
"""
lda ${(ESTACK_LO+1).toHex()},x
sta (+) +1
lda ${(ESTACK_HI+1).toHex()},x
sta (+) +2
+ lda 65535 ; modified
sta ${(ESTACK_LO+1).toHex()},x
"""
}
Opcode.PUSH_REGAY_WORD -> {
" sta ${ESTACK_LO.toHex()},x | tya | sta ${ESTACK_HI.toHex()},x | dex "
}
Opcode.PUSH_ADDR_HEAPVAR -> {
" lda #<${ins.callLabel} | sta ${ESTACK_LO.toHex()},x | lda #>${ins.callLabel} | sta ${ESTACK_HI.toHex()},x | dex"
}
Opcode.POP_REGAX_WORD -> throw AssemblyError("cannot load X register from stack because it's used as the stack pointer itself")
Opcode.POP_REGXY_WORD -> throw AssemblyError("cannot load X register from stack because it's used as the stack pointer itself")
Opcode.POP_REGAY_WORD -> {
" inx | lda ${ESTACK_LO.toHex()},x | ldy ${ESTACK_HI.toHex()},x "
}
Opcode.READ_INDEXED_VAR_BYTE -> {
"""
ldy ${(ESTACK_LO+1).toHex()},x
lda ${ins.callLabel},y
sta ${(ESTACK_LO+1).toHex()},x
"""
}
Opcode.READ_INDEXED_VAR_WORD -> {
"""
lda ${(ESTACK_LO+1).toHex()},x
asl a
tay
lda ${ins.callLabel},y
sta ${(ESTACK_LO+1).toHex()},x
lda ${ins.callLabel}+1,y
sta ${(ESTACK_HI+1).toHex()},x
"""
}
Opcode.READ_INDEXED_VAR_FLOAT -> {
"""
lda #<${ins.callLabel}
ldy #>${ins.callLabel}
jsr c64flt.push_float_from_indexed_var
"""
}
Opcode.WRITE_INDEXED_VAR_BYTE -> {
"""
inx
ldy ${ESTACK_LO.toHex()},x
inx
lda ${ESTACK_LO.toHex()},x
sta ${ins.callLabel},y
"""
}
Opcode.WRITE_INDEXED_VAR_WORD -> {
"""
inx
lda ${ESTACK_LO.toHex()},x
asl a
tay
inx
lda ${ESTACK_LO.toHex()},x
sta ${ins.callLabel},y
lda ${ESTACK_HI.toHex()},x
sta ${ins.callLabel}+1,y
"""
}
Opcode.WRITE_INDEXED_VAR_FLOAT -> {
"""
lda #<${ins.callLabel}
ldy #>${ins.callLabel}
jsr c64flt.pop_float_to_indexed_var
"""
}
Opcode.POP_MEM_BYTE -> {
"""
inx
lda ${ESTACK_LO.toHex()},x
sta ${hexVal(ins)}
"""
}
Opcode.POP_MEM_WORD -> {
"""
inx
lda ${ESTACK_LO.toHex()},x
sta ${hexVal(ins)}
lda ${ESTACK_HI.toHex()},x
sta ${hexValPlusOne(ins)}
"""
}
Opcode.POP_MEM_FLOAT -> {
" lda ${hexVal(ins)} | ldy ${hexValPlusOne(ins)} | jsr c64flt.pop_float"
}
Opcode.POP_MEMWRITE -> {
"""
inx
lda ${ESTACK_LO.toHex()},x
sta (+) +1
lda ${ESTACK_HI.toHex()},x
sta (+) +2
inx
lda ${ESTACK_LO.toHex()},x
+ sta 65535 ; modified
"""
}
Opcode.POP_VAR_BYTE -> {
when (ins.callLabel) {
"X" -> throw CompilerException("makes no sense to pop X, it's used as a stack pointer itself")
"A" -> " inx | lda ${ESTACK_LO.toHex()},x"
"Y" -> " inx | ldy ${ESTACK_LO.toHex()},x"
else -> " inx | lda ${ESTACK_LO.toHex()},x | sta ${ins.callLabel}"
}
}
Opcode.POP_VAR_WORD -> {
" inx | lda ${ESTACK_LO.toHex()},x | ldy ${ESTACK_HI.toHex()},x | sta ${ins.callLabel} | sty ${ins.callLabel}+1"
}
Opcode.POP_VAR_FLOAT -> {
" lda #<${ins.callLabel} | ldy #>${ins.callLabel} | jsr c64flt.pop_float"
}
Opcode.INC_VAR_UB, Opcode.INC_VAR_B -> {
when (ins.callLabel) {
"A" -> " clc | adc #1"
"X" -> " inx"
"Y" -> " iny"
else -> " inc ${ins.callLabel}"
}
}
Opcode.INC_VAR_UW, Opcode.INC_VAR_W -> {
" inc ${ins.callLabel} | bne + | inc ${ins.callLabel}+1 |+"
}
Opcode.INC_VAR_F -> {
"""
lda #<${ins.callLabel}
ldy #>${ins.callLabel}
jsr c64flt.inc_var_f
"""
}
Opcode.POP_INC_MEMORY -> {
"""
inx
lda ${ESTACK_LO.toHex()},x
sta (+) +1
lda ${ESTACK_HI.toHex()},x
sta (+) +2
+ inc 65535 ; modified
"""
}
Opcode.POP_DEC_MEMORY -> {
"""
inx
lda ${ESTACK_LO.toHex()},x
sta (+) +1
lda ${ESTACK_HI.toHex()},x
sta (+) +2
+ dec 65535 ; modified
"""
}
Opcode.DEC_VAR_UB, Opcode.DEC_VAR_B -> {
when (ins.callLabel) {
"A" -> " sec | sbc #1"
"X" -> " dex"
"Y" -> " dey"
else -> " dec ${ins.callLabel}"
}
}
Opcode.DEC_VAR_UW, Opcode.DEC_VAR_W -> {
" lda ${ins.callLabel} | bne + | dec ${ins.callLabel}+1 |+ | dec ${ins.callLabel}"
}
Opcode.DEC_VAR_F -> {
"""
lda #<${ins.callLabel}
ldy #>${ins.callLabel}
jsr c64flt.dec_var_f
"""
}
Opcode.INC_MEMORY -> " inc ${hexVal(ins)}"
Opcode.DEC_MEMORY -> " dec ${hexVal(ins)}"
Opcode.INC_INDEXED_VAR_B, Opcode.INC_INDEXED_VAR_UB -> " inx | txa | pha | lda ${ESTACK_LO.toHex()},x | tax | inc ${ins.callLabel},x | pla | tax"
Opcode.DEC_INDEXED_VAR_B, Opcode.DEC_INDEXED_VAR_UB -> " inx | txa | pha | lda ${ESTACK_LO.toHex()},x | tax | dec ${ins.callLabel},x | pla | tax"
Opcode.NEG_B -> " jsr prog8_lib.neg_b"
Opcode.NEG_W -> " jsr prog8_lib.neg_w"
Opcode.NEG_F -> " jsr c64flt.neg_f"
Opcode.ABS_B -> " jsr prog8_lib.abs_b"
Opcode.ABS_W -> " jsr prog8_lib.abs_w"
Opcode.ABS_F -> " jsr c64flt.abs_f"
Opcode.POW_F -> " jsr c64flt.pow_f"
Opcode.INV_BYTE -> {
"""
lda ${(ESTACK_LO + 1).toHex()},x
eor #255
sta ${(ESTACK_LO + 1).toHex()},x
"""
}
Opcode.INV_WORD -> " jsr prog8_lib.inv_word"
Opcode.NOT_BYTE -> " jsr prog8_lib.not_byte"
Opcode.NOT_WORD -> " jsr prog8_lib.not_word"
Opcode.BCS -> {
val label = ins.callLabel ?: hexVal(ins)
" bcs $label"
}
Opcode.BCC -> {
val label = ins.callLabel ?: hexVal(ins)
" bcc $label"
}
Opcode.BNEG -> {
val label = ins.callLabel ?: hexVal(ins)
" bmi $label"
}
Opcode.BPOS -> {
val label = ins.callLabel ?: hexVal(ins)
" bpl $label"
}
Opcode.BVC -> {
val label = ins.callLabel ?: hexVal(ins)
" bvc $label"
}
Opcode.BVS -> {
val label = ins.callLabel ?: hexVal(ins)
" bvs $label"
}
Opcode.BZ -> {
val label = ins.callLabel ?: hexVal(ins)
" beq $label"
}
Opcode.BNZ -> {
val label = ins.callLabel ?: hexVal(ins)
" bne $label"
}
Opcode.JZ -> {
val label = ins.callLabel ?: hexVal(ins)
"""
inx
lda ${(ESTACK_LO).toHex()},x
beq $label
"""
}
Opcode.JZW -> {
val label = ins.callLabel ?: hexVal(ins)
"""
inx
lda ${(ESTACK_LO).toHex()},x
beq $label
lda ${(ESTACK_HI).toHex()},x
beq $label
"""
}
Opcode.JNZ -> {
val label = ins.callLabel ?: hexVal(ins)
"""
inx
lda ${(ESTACK_LO).toHex()},x
bne $label
"""
}
Opcode.JNZW -> {
val label = ins.callLabel ?: hexVal(ins)
"""
inx
lda ${(ESTACK_LO).toHex()},x
bne $label
lda ${(ESTACK_HI).toHex()},x
bne $label
"""
}
Opcode.CAST_B_TO_UB -> "" // is a no-op, just carry on with the byte as-is
Opcode.CAST_UB_TO_B -> "" // is a no-op, just carry on with the byte as-is
Opcode.CAST_W_TO_UW -> "" // is a no-op, just carry on with the word as-is
Opcode.CAST_UW_TO_W -> "" // is a no-op, just carry on with the word as-is
Opcode.CAST_W_TO_UB -> "" // is a no-op, just carry on with the lsb of the word as-is
Opcode.CAST_W_TO_B -> "" // is a no-op, just carry on with the lsb of the word as-is
Opcode.CAST_UW_TO_UB -> "" // is a no-op, just carry on with the lsb of the uword as-is
Opcode.CAST_UW_TO_B -> "" // is a no-op, just carry on with the lsb of the uword as-is
Opcode.CAST_UB_TO_F -> " jsr c64flt.stack_ub2float"
Opcode.CAST_B_TO_F -> " jsr c64flt.stack_b2float"
Opcode.CAST_UW_TO_F -> " jsr c64flt.stack_uw2float"
Opcode.CAST_W_TO_F -> " jsr c64flt.stack_w2float"
Opcode.CAST_F_TO_UB -> " jsr c64flt.stack_float2uw"
Opcode.CAST_F_TO_B -> " jsr c64flt.stack_float2w"
Opcode.CAST_F_TO_UW -> " jsr c64flt.stack_float2uw"
Opcode.CAST_F_TO_W -> " jsr c64flt.stack_float2w"
Opcode.CAST_UB_TO_UW, Opcode.CAST_UB_TO_W -> " lda #0 | sta ${(ESTACK_HI+1).toHex()},x" // clear the msb
Opcode.CAST_B_TO_UW, Opcode.CAST_B_TO_W -> " lda ${(ESTACK_LO+1).toHex()},x | ${signExtendA("${(ESTACK_HI+1).toHex()},x")}" // sign extend the lsb
Opcode.MSB -> " lda ${(ESTACK_HI+1).toHex()},x | sta ${(ESTACK_LO+1).toHex()},x"
Opcode.MKWORD -> " inx | lda ${ESTACK_LO.toHex()},x | sta ${(ESTACK_HI+1).toHex()},x "
Opcode.ADD_UB, Opcode.ADD_B -> { // TODO inline better (pattern with more opcodes)
"""
lda ${(ESTACK_LO + 2).toHex()},x
clc
adc ${(ESTACK_LO + 1).toHex()},x
inx
sta ${(ESTACK_LO + 1).toHex()},x
"""
}
Opcode.SUB_UB, Opcode.SUB_B -> { // TODO inline better (pattern with more opcodes)
"""
lda ${(ESTACK_LO + 2).toHex()},x
sec
sbc ${(ESTACK_LO + 1).toHex()},x
inx
sta ${(ESTACK_LO + 1).toHex()},x
"""
}
Opcode.ADD_W, Opcode.ADD_UW -> " jsr prog8_lib.add_w"
Opcode.SUB_W, Opcode.SUB_UW -> " jsr prog8_lib.sub_w"
Opcode.MUL_B, Opcode.MUL_UB -> " jsr prog8_lib.mul_byte"
Opcode.MUL_W, Opcode.MUL_UW -> " jsr prog8_lib.mul_word"
Opcode.MUL_F -> " jsr c64flt.mul_f"
Opcode.ADD_F -> " jsr c64flt.add_f"
Opcode.SUB_F -> " jsr c64flt.sub_f"
Opcode.DIV_F -> " jsr c64flt.div_f"
Opcode.IDIV_UB -> " jsr prog8_lib.idiv_ub"
Opcode.IDIV_B -> " jsr prog8_lib.idiv_b"
Opcode.IDIV_W -> " jsr prog8_lib.idiv_w"
Opcode.IDIV_UW -> " jsr prog8_lib.idiv_uw"
Opcode.AND_BYTE -> " jsr prog8_lib.and_b"
Opcode.OR_BYTE -> " jsr prog8_lib.or_b"
Opcode.XOR_BYTE -> " jsr prog8_lib.xor_b"
Opcode.AND_WORD -> " jsr prog8_lib.and_w"
Opcode.OR_WORD -> " jsr prog8_lib.or_w"
Opcode.XOR_WORD -> " jsr prog8_lib.xor_w"
Opcode.BITAND_BYTE -> " jsr prog8_lib.bitand_b"
Opcode.BITOR_BYTE -> " jsr prog8_lib.bitor_b"
Opcode.BITXOR_BYTE -> " jsr prog8_lib.bitxor_b"
Opcode.BITAND_WORD -> " jsr prog8_lib.bitand_w"
Opcode.BITOR_WORD -> " jsr prog8_lib.bitor_w"
Opcode.BITXOR_WORD -> " jsr prog8_lib.bitxor_w"
Opcode.REMAINDER_UB -> " jsr prog8_lib.remainder_ub"
Opcode.REMAINDER_UW -> " jsr prog8_lib.remainder_uw"
Opcode.GREATER_B -> " jsr prog8_lib.greater_b"
Opcode.GREATER_UB -> " jsr prog8_lib.greater_ub"
Opcode.GREATER_W -> " jsr prog8_lib.greater_w"
Opcode.GREATER_UW -> " jsr prog8_lib.greater_uw"
Opcode.GREATER_F -> " jsr c64flt.greater_f"
Opcode.GREATEREQ_B -> " jsr prog8_lib.greatereq_b"
Opcode.GREATEREQ_UB -> " jsr prog8_lib.greatereq_ub"
Opcode.GREATEREQ_W -> " jsr prog8_lib.greatereq_w"
Opcode.GREATEREQ_UW -> " jsr prog8_lib.greatereq_uw"
Opcode.GREATEREQ_F -> " jsr c64flt.greatereq_f"
Opcode.EQUAL_BYTE -> " jsr prog8_lib.equal_b"
Opcode.EQUAL_WORD -> " jsr prog8_lib.equal_w"
Opcode.EQUAL_F -> " jsr c64flt.equal_f"
Opcode.NOTEQUAL_BYTE -> " jsr prog8_lib.notequal_b"
Opcode.NOTEQUAL_WORD -> " jsr prog8_lib.notequal_w"
Opcode.NOTEQUAL_F -> " jsr c64flt.notequal_f"
Opcode.LESS_UB -> " jsr prog8_lib.less_ub"
Opcode.LESS_B -> " jsr prog8_lib.less_b"
Opcode.LESS_UW -> " jsr prog8_lib.less_uw"
Opcode.LESS_W -> " jsr prog8_lib.less_w"
Opcode.LESS_F -> " jsr c64flt.less_f"
Opcode.LESSEQ_UB -> " jsr prog8_lib.lesseq_ub"
Opcode.LESSEQ_B -> " jsr prog8_lib.lesseq_b"
Opcode.LESSEQ_UW -> " jsr prog8_lib.lesseq_uw"
Opcode.LESSEQ_W -> " jsr prog8_lib.lesseq_w"
Opcode.LESSEQ_F -> " jsr c64flt.lesseq_f"
Opcode.SHIFTEDL_BYTE -> " asl ${(ESTACK_LO+1).toHex()},x"
Opcode.SHIFTEDL_WORD -> " asl ${(ESTACK_LO+1).toHex()},x | rol ${(ESTACK_HI+1).toHex()},x"
Opcode.SHIFTEDR_SBYTE -> " lda ${(ESTACK_LO+1).toHex()},x | asl a | ror ${(ESTACK_LO+1).toHex()},x"
Opcode.SHIFTEDR_UBYTE -> " lsr ${(ESTACK_LO+1).toHex()},x"
Opcode.SHIFTEDR_SWORD -> " lda ${(ESTACK_HI+1).toHex()},x | asl a | ror ${(ESTACK_HI+1).toHex()},x | ror ${(ESTACK_LO+1).toHex()},x"
Opcode.SHIFTEDR_UWORD -> " lsr ${(ESTACK_HI+1).toHex()},x | ror ${(ESTACK_LO+1).toHex()},x"
else -> null
}
}

874
compiler/src/prog8/compiler/target/c64/codegen/AsmGen.kt Normal file
View File

@ -0,0 +1,874 @@
package prog8.compiler.target.c64.codegen
import prog8.ast.Node
import prog8.ast.Program
import prog8.ast.antlr.escape
import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.ast.statements.*
import prog8.compiler.*
import prog8.compiler.target.IAssemblyGenerator
import prog8.compiler.target.IAssemblyProgram
import prog8.compiler.target.c64.AssemblyProgram
import prog8.compiler.target.c64.C64MachineDefinition
import prog8.compiler.target.c64.C64MachineDefinition.ESTACK_LO_HEX
import prog8.compiler.target.c64.C64MachineDefinition.ESTACK_HI_HEX
import prog8.compiler.target.c64.Petscii
import prog8.functions.BuiltinFunctions
import prog8.functions.FunctionSignature
import java.math.RoundingMode
import java.nio.file.Path
import java.time.LocalDate
import java.time.LocalDateTime
import java.util.ArrayDeque
import kotlin.math.absoluteValue
internal class AsmGen(private val program: Program,
private val zeropage: Zeropage,
private val options: CompilationOptions,
private val outputDir: Path): IAssemblyGenerator {
private val assemblyLines = mutableListOf<String>()
private val globalFloatConsts = mutableMapOf<Double, String>() // all float values in the entire program (value -> varname)
private val allocatedZeropageVariables = mutableMapOf<String, Pair<Int, DataType>>()
private val breakpointLabels = mutableListOf<String>()
private val builtinFunctionsAsmGen = BuiltinFunctionsAsmGen(program, this)
private val forloopsAsmGen = ForLoopsAsmGen(program, this)
private val postincrdecrAsmGen = PostIncrDecrAsmGen(program, this)
private val functioncallAsmGen = FunctionCallAsmGen(program, this)
private val assignmentAsmGen = AssignmentAsmGen(program, this)
private val expressionsAsmGen = ExpressionsAsmGen(program, this)
internal val loopEndLabels = ArrayDeque<String>()
internal val loopContinueLabels = ArrayDeque<String>()
override fun compileToAssembly(optimize: Boolean): IAssemblyProgram {
assemblyLines.clear()
loopEndLabels.clear()
loopContinueLabels.clear()
println("Generating assembly code... ")
header()
val allBlocks = program.allBlocks()
if(allBlocks.first().name != "main")
throw AssemblyError("first block should be 'main'")
for(b in program.allBlocks())
block2asm(b)
footer()
if(optimize) {
var optimizationsDone = 1
while (optimizationsDone > 0) {
optimizationsDone = optimizeAssembly(assemblyLines)
}
}
val outputFile = outputDir.resolve("${program.name}.asm").toFile()
outputFile.printWriter().use {
for (line in assemblyLines) { it.println(line) }
}
return AssemblyProgram(program.name, outputDir)
}
private fun header() {
val ourName = this.javaClass.name
out("; 6502 assembly code for '${program.name}'")
out("; generated by $ourName on ${LocalDateTime.now().withNano(0)}")
out("; assembler syntax is for the 64tasm cross-assembler")
out("; output options: output=${options.output} launcher=${options.launcher} zp=${options.zeropage}")
out("\n.cpu '6502'\n.enc 'none'\n")
program.actualLoadAddress = program.definedLoadAddress
if (program.actualLoadAddress == 0) // fix load address
program.actualLoadAddress = if (options.launcher == LauncherType.BASIC)
C64MachineDefinition.BASIC_LOAD_ADDRESS else C64MachineDefinition.RAW_LOAD_ADDRESS
when {
options.launcher == LauncherType.BASIC -> {
if (program.actualLoadAddress != 0x0801)
throw AssemblyError("BASIC output must have load address $0801")
out("; ---- basic program with sys call ----")
out("* = ${program.actualLoadAddress.toHex()}")
val year = LocalDate.now().year
out(" .word (+), $year")
out(" .null $9e, format(' %d ', _prog8_entrypoint), $3a, $8f, ' prog8 by idj'")
out("+\t.word 0")
out("_prog8_entrypoint\t; assembly code starts here\n")
out(" jsr prog8_lib.init_system")
}
options.output == OutputType.PRG -> {
out("; ---- program without basic sys call ----")
out("* = ${program.actualLoadAddress.toHex()}\n")
out(" jsr prog8_lib.init_system")
}
options.output == OutputType.RAW -> {
out("; ---- raw assembler program ----")
out("* = ${program.actualLoadAddress.toHex()}\n")
}
}
if (zeropage.exitProgramStrategy != Zeropage.ExitProgramStrategy.CLEAN_EXIT) {
// disable shift-commodore charset switching and run/stop key
out(" lda #$80")
out(" lda #$80")
out(" sta 657\t; disable charset switching")
out(" lda #239")
out(" sta 808\t; disable run/stop key")
}
out(" ldx #\$ff\t; init estack pointer")
out(" ; initialize the variables in each block")
for (block in program.allBlocks()) {
val initVarsSub = block.statements.singleOrNull { it is Subroutine && it.name == initvarsSubName }
if(initVarsSub!=null)
out(" jsr ${block.name}.$initvarsSubName")
}
out(" clc")
when (zeropage.exitProgramStrategy) {
Zeropage.ExitProgramStrategy.CLEAN_EXIT -> {
out(" jmp main.start\t; jump to program entrypoint")
}
Zeropage.ExitProgramStrategy.SYSTEM_RESET -> {
out(" jsr main.start\t; call program entrypoint")
out(" jmp (c64.RESET_VEC)\t; cold reset")
}
}
out("")
}
private fun footer() {
// the global list of all floating point constants for the whole program
out("; global float constants")
for (flt in globalFloatConsts) {
val mflpt5 = C64MachineDefinition.Mflpt5.fromNumber(flt.key)
val floatFill = makeFloatFill(mflpt5)
val floatvalue = flt.key
out("${flt.value}\t.byte $floatFill ; float $floatvalue")
}
}
private fun block2asm(block: Block) {
out("\n\n; ---- block: '${block.name}' ----")
out("${block.name}\t" + (if("force_output" in block.options()) ".block\n" else ".proc\n"))
if(block.address!=null) {
out(".cerror * > ${block.address.toHex()}, 'block address overlaps by ', *-${block.address.toHex()},' bytes'")
out("* = ${block.address.toHex()}")
}
outputSourceLine(block)
zeropagevars2asm(block.statements)
memdefs2asm(block.statements)
vardecls2asm(block.statements)
out("\n; subroutines in this block")
// first translate regular statements, and then put the subroutines at the end.
val (subroutine, stmts) = block.statements.partition { it is Subroutine }
stmts.forEach { translate(it) }
subroutine.forEach { translateSubroutine(it as Subroutine) }
out(if("force_output" in block.options()) "\n\t.bend\n" else "\n\t.pend\n")
}
private var generatedLabelSequenceNumber: Int = 0
internal fun makeLabel(postfix: String): String {
generatedLabelSequenceNumber++
return "_prog8_label_${generatedLabelSequenceNumber}_$postfix"
}
private fun outputSourceLine(node: Node) {
out(" ;\tsrc line: ${node.position.file}:${node.position.line}")
}
internal fun out(str: String, splitlines: Boolean = true) {
val fragment = (if(" | " in str) str.replace("|", "\n") else str).trim('\n')
if (splitlines) {
for (line in fragment.split('\n')) {
val trimmed = if (line.startsWith(' ')) "\t" + line.trim() else line.trim()
// trimmed = trimmed.replace(Regex("^\\+\\s+"), "+\t") // sanitize local label indentation
assemblyLines.add(trimmed)
}
} else assemblyLines.add(fragment)
}
private fun makeFloatFill(flt: C64MachineDefinition.Mflpt5): String {
val b0 = "$" + flt.b0.toString(16).padStart(2, '0')
val b1 = "$" + flt.b1.toString(16).padStart(2, '0')
val b2 = "$" + flt.b2.toString(16).padStart(2, '0')
val b3 = "$" + flt.b3.toString(16).padStart(2, '0')
val b4 = "$" + flt.b4.toString(16).padStart(2, '0')
return "$b0, $b1, $b2, $b3, $b4"
}
private fun encode(str: String, altEncoding: Boolean): List<Short> {
val bytes = if(altEncoding) Petscii.encodeScreencode(str, true) else Petscii.encodePetscii(str, true)
return bytes.plus(0)
}
private fun zeropagevars2asm(statements: List<Statement>) {
out("; vars allocated on zeropage")
val variables = statements.filterIsInstance<VarDecl>().filter { it.type==VarDeclType.VAR }
for(variable in variables) {
// should NOT allocate subroutine parameters on the zero page
val fullName = variable.scopedname
val zpVar = allocatedZeropageVariables[fullName]
if(zpVar==null) {
// This var is not on the ZP yet. Attempt to move it there (if it's not a float, those take up too much space)
if(variable.zeropage != ZeropageWish.NOT_IN_ZEROPAGE &&
variable.datatype in zeropage.allowedDatatypes
&& variable.datatype != DataType.FLOAT
&& options.zeropage != ZeropageType.DONTUSE) {
try {
val address = zeropage.allocate(fullName, variable.datatype, null)
out("${variable.name} = $address\t; auto zp ${variable.datatype}")
// make sure we add the var to the set of zpvars for this block
allocatedZeropageVariables[fullName] = Pair(address, variable.datatype)
} catch (x: ZeropageDepletedError) {
// leave it as it is.
}
}
}
}
}
private fun vardecl2asm(decl: VarDecl) {
when (decl.datatype) {
DataType.UBYTE -> out("${decl.name}\t.byte 0")
DataType.BYTE -> out("${decl.name}\t.char 0")
DataType.UWORD -> out("${decl.name}\t.word 0")
DataType.WORD -> out("${decl.name}\t.sint 0")
DataType.FLOAT -> out("${decl.name}\t.byte 0,0,0,0,0 ; float")
DataType.STRUCT -> {} // is flattened
DataType.STR -> {
val str = decl.value as StringLiteralValue
outputStringvar(decl, encode(str.value, str.altEncoding))
}
DataType.ARRAY_UB -> {
val data = makeArrayFillDataUnsigned(decl)
if (data.size <= 16)
out("${decl.name}\t.byte ${data.joinToString()}")
else {
out(decl.name)
for (chunk in data.chunked(16))
out(" .byte " + chunk.joinToString())
}
}
DataType.ARRAY_B -> {
val data = makeArrayFillDataSigned(decl)
if (data.size <= 16)
out("${decl.name}\t.char ${data.joinToString()}")
else {
out(decl.name)
for (chunk in data.chunked(16))
out(" .char " + chunk.joinToString())
}
}
DataType.ARRAY_UW -> {
val data = makeArrayFillDataUnsigned(decl)
if (data.size <= 16)
out("${decl.name}\t.word ${data.joinToString()}")
else {
out(decl.name)
for (chunk in data.chunked(16))
out(" .word " + chunk.joinToString())
}
}
DataType.ARRAY_W -> {
val data = makeArrayFillDataSigned(decl)
if (data.size <= 16)
out("${decl.name}\t.sint ${data.joinToString()}")
else {
out(decl.name)
for (chunk in data.chunked(16))
out(" .sint " + chunk.joinToString())
}
}
DataType.ARRAY_F -> {
val array = (decl.value as ArrayLiteralValue).value
val floatFills = array.map {
val number = (it as NumericLiteralValue).number
makeFloatFill(C64MachineDefinition.Mflpt5.fromNumber(number))
}
out(decl.name)
for (f in array.zip(floatFills))
out(" .byte ${f.second} ; float ${f.first}")
}
}
}
private fun memdefs2asm(statements: List<Statement>) {
out("\n; memdefs and kernel subroutines")
val memvars = statements.filterIsInstance<VarDecl>().filter { it.type==VarDeclType.MEMORY || it.type==VarDeclType.CONST }
for(m in memvars) {
out(" ${m.name} = ${(m.value as NumericLiteralValue).number.toHex()}")
}
val asmSubs = statements.filterIsInstance<Subroutine>().filter { it.isAsmSubroutine }
for(sub in asmSubs) {
if(sub.asmAddress!=null) {
if(sub.statements.isNotEmpty())
throw AssemblyError("kernel subroutine cannot have statements")
out(" ${sub.name} = ${sub.asmAddress.toHex()}")
}
}
}
private fun vardecls2asm(statements: List<Statement>) {
out("\n; non-zeropage variables")
val vars = statements.filterIsInstance<VarDecl>().filter { it.type==VarDeclType.VAR }
// first output the flattened struct member variables *in order*
// after that, the other variables sorted by their datatype
val (structMembers, normalVars) = vars.partition { it.struct!=null }
structMembers.forEach { vardecl2asm(it) }
// special treatment for string types: merge strings that are identical
val encodedstringVars = normalVars
.filter {it.datatype == DataType.STR }
.map {
val str = it.value as StringLiteralValue
it to encode(str.value, str.altEncoding)
}
.groupBy({it.second}, {it.first})
for((encoded, variables) in encodedstringVars) {
variables.dropLast(1).forEach { out(it.name) }
val lastvar = variables.last()
outputStringvar(lastvar, encoded)
}
// non-string variables
normalVars.filter{ it.datatype != DataType.STR }.sortedBy { it.datatype }.forEach {
if(it.scopedname !in allocatedZeropageVariables)
vardecl2asm(it)
}
}
private fun outputStringvar(lastvar: VarDecl, encoded: List<Short>) {
val string = (lastvar.value as StringLiteralValue).value
out("${lastvar.name}\t; ${lastvar.datatype} \"${escape(string).replace("\u0000", "<NULL>")}\"")
val outputBytes = encoded.map { "$" + it.toString(16).padStart(2, '0') }
for (chunk in outputBytes.chunked(16))
out(" .byte " + chunk.joinToString())
}
private fun makeArrayFillDataUnsigned(decl: VarDecl): List<String> {
val array = (decl.value as ArrayLiteralValue).value
return when (decl.datatype) {
DataType.ARRAY_UB ->
// byte array can never contain pointer-to types, so treat values as all integers
array.map {
val number = (it as NumericLiteralValue).number.toInt()
"$"+number.toString(16).padStart(2, '0')
}
DataType.ARRAY_UW -> array.map {
if(it is NumericLiteralValue) {
"$" + it.number.toInt().toString(16).padStart(4, '0')
} else {
(it as AddressOf).identifier.nameInSource.joinToString(".")
}
}
else -> throw AssemblyError("invalid arraysize type")
}
}
private fun makeArrayFillDataSigned(decl: VarDecl): List<String> {
val array = (decl.value as ArrayLiteralValue).value
return when {
decl.datatype == DataType.ARRAY_UB ->
// byte array can never contain pointer-to types, so treat values as all integers
array.map {
val number = (it as NumericLiteralValue).number.toInt()
val hexnum = number.toString(16).padStart(2, '0')
"$$hexnum"
}
decl.datatype == DataType.ARRAY_B ->
// byte array can never contain pointer-to types, so treat values as all integers
array.map {
val number = (it as NumericLiteralValue).number.toInt()
val hexnum = number.absoluteValue.toString(16).padStart(2, '0')
if(number>=0)
"$$hexnum"
else
"-$$hexnum"
}
decl.datatype== DataType.ARRAY_UW -> array.map {
val number = (it as NumericLiteralValue).number.toInt()
val hexnum = number.toString(16).padStart(4, '0')
"$$hexnum"
}
decl.datatype== DataType.ARRAY_W -> array.map {
val number = (it as NumericLiteralValue).number.toInt()
val hexnum = number.absoluteValue.toString(16).padStart(4, '0')
if(number>=0)
"$$hexnum"
else
"-$$hexnum"
}
else -> throw AssemblyError("invalid arraysize type ${decl.datatype}")
}
}
internal fun getFloatConst(number: Double): String {
// try to match the ROM float constants to save memory
val mflpt5 = C64MachineDefinition.Mflpt5.fromNumber(number)
val floatbytes = shortArrayOf(mflpt5.b0, mflpt5.b1, mflpt5.b2, mflpt5.b3, mflpt5.b4)
when {
floatbytes.contentEquals(shortArrayOf(0x00, 0x00, 0x00, 0x00, 0x00)) -> return "c64flt.FL_ZERO"
floatbytes.contentEquals(shortArrayOf(0x82, 0x49, 0x0f, 0xda, 0xa1)) -> return "c64flt.FL_PIVAL"
floatbytes.contentEquals(shortArrayOf(0x90, 0x80, 0x00, 0x00, 0x00)) -> return "c64flt.FL_N32768"
floatbytes.contentEquals(shortArrayOf(0x81, 0x00, 0x00, 0x00, 0x00)) -> return "c64flt.FL_FONE"
floatbytes.contentEquals(shortArrayOf(0x80, 0x35, 0x04, 0xf3, 0x34)) -> return "c64flt.FL_SQRHLF"
floatbytes.contentEquals(shortArrayOf(0x81, 0x35, 0x04, 0xf3, 0x34)) -> return "c64flt.FL_SQRTWO"
floatbytes.contentEquals(shortArrayOf(0x80, 0x80, 0x00, 0x00, 0x00)) -> return "c64flt.FL_NEGHLF"
floatbytes.contentEquals(shortArrayOf(0x80, 0x31, 0x72, 0x17, 0xf8)) -> return "c64flt.FL_LOG2"
floatbytes.contentEquals(shortArrayOf(0x84, 0x20, 0x00, 0x00, 0x00)) -> return "c64flt.FL_TENC"
floatbytes.contentEquals(shortArrayOf(0x9e, 0x6e, 0x6b, 0x28, 0x00)) -> return "c64flt.FL_NZMIL"
floatbytes.contentEquals(shortArrayOf(0x80, 0x00, 0x00, 0x00, 0x00)) -> return "c64flt.FL_FHALF"
floatbytes.contentEquals(shortArrayOf(0x81, 0x38, 0xaa, 0x3b, 0x29)) -> return "c64flt.FL_LOGEB2"
floatbytes.contentEquals(shortArrayOf(0x81, 0x49, 0x0f, 0xda, 0xa2)) -> return "c64flt.FL_PIHALF"
floatbytes.contentEquals(shortArrayOf(0x83, 0x49, 0x0f, 0xda, 0xa2)) -> return "c64flt.FL_TWOPI"
floatbytes.contentEquals(shortArrayOf(0x7f, 0x00, 0x00, 0x00, 0x00)) -> return "c64flt.FL_FR4"
else -> {
// attempt to correct for a few rounding issues
when (number.toBigDecimal().setScale(10, RoundingMode.HALF_DOWN).toDouble()) {
3.1415926536 -> return "c64flt.FL_PIVAL"
1.4142135624 -> return "c64flt.FL_SQRTWO"
0.7071067812 -> return "c64flt.FL_SQRHLF"
0.6931471806 -> return "c64flt.FL_LOG2"
else -> {}
}
// no ROM float const for this value, create our own
val name = globalFloatConsts[number]
if(name!=null)
return name
val newName = "prog8_float_const_${globalFloatConsts.size}"
globalFloatConsts[number] = newName
return newName
}
}
}
internal fun signExtendAtoMsb(destination: String) =
"""
ora #$7f
bmi +
lda #0
+ sta $destination
"""
internal fun asmIdentifierName(identifier: IdentifierReference): String {
val name = if(identifier.memberOfStruct(program.namespace)!=null) {
identifier.targetVarDecl(program.namespace)!!.name
} else {
identifier.nameInSource.joinToString(".")
}
return fixNameSymbols(name)
}
internal fun fixNameSymbols(name: String) = name.replace("<", "prog8_").replace(">", "") // take care of the autogenerated invalid (anon) label names
private fun branchInstruction(condition: BranchCondition, complement: Boolean) =
if(complement) {
when (condition) {
BranchCondition.CS -> "bcc"
BranchCondition.CC -> "bcs"
BranchCondition.EQ, BranchCondition.Z -> "beq"
BranchCondition.NE, BranchCondition.NZ -> "bne"
BranchCondition.VS -> "bvc"
BranchCondition.VC -> "bvs"
BranchCondition.MI, BranchCondition.NEG -> "bmi"
BranchCondition.PL, BranchCondition.POS -> "bpl"
}
} else {
when (condition) {
BranchCondition.CS -> "bcs"
BranchCondition.CC -> "bcc"
BranchCondition.EQ, BranchCondition.Z -> "beq"
BranchCondition.NE, BranchCondition.NZ -> "bne"
BranchCondition.VS -> "bvs"
BranchCondition.VC -> "bvc"
BranchCondition.MI, BranchCondition.NEG -> "bmi"
BranchCondition.PL, BranchCondition.POS -> "bpl"
}
}
internal fun readAndPushArrayvalueWithIndexA(arrayDt: DataType, variable: IdentifierReference) {
val variablename = asmIdentifierName(variable)
when (arrayDt) {
DataType.STR, DataType.ARRAY_UB, DataType.ARRAY_B ->
out(" tay | lda $variablename,y | sta $ESTACK_LO_HEX,x | dex")
DataType.ARRAY_UW, DataType.ARRAY_W ->
out(" asl a | tay | lda $variablename,y | sta $ESTACK_LO_HEX,x | lda $variablename+1,y | sta $ESTACK_HI_HEX,x | dex")
DataType.ARRAY_F ->
// index * 5 is done in the subroutine that's called
out("""
sta $ESTACK_LO_HEX,x
dex
lda #<$variablename
ldy #>$variablename
jsr c64flt.push_float_from_indexed_var
""")
else ->
throw AssemblyError("weird array type")
}
}
internal fun saveRegister(register: Register) {
when(register) {
Register.A -> out(" pha")
Register.X -> out(" txa | pha")
Register.Y -> out(" tya | pha")
}
}
internal fun restoreRegister(register: Register) {
when(register) {
Register.A -> out(" pla")
Register.X -> out(" pla | tax")
Register.Y -> out(" pla | tay")
}
}
private fun translateSubroutine(sub: Subroutine) {
out("")
outputSourceLine(sub)
if(sub.isAsmSubroutine) {
if(sub.asmAddress!=null)
return // already done at the memvars section
// asmsub with most likely just an inline asm in it
out("${sub.name}\t.proc")
sub.statements.forEach{ translate(it) }
out(" .pend\n")
} else {
// regular subroutine
out("${sub.name}\t.proc")
zeropagevars2asm(sub.statements)
memdefs2asm(sub.statements)
out("; statements")
sub.statements.forEach{ translate(it) }
out("; variables")
vardecls2asm(sub.statements)
out(" .pend\n")
}
}
internal fun translate(stmt: Statement) {
outputSourceLine(stmt)
when(stmt) {
is VarDecl, is StructDecl, is NopStatement -> {}
is Directive -> translate(stmt)
is Return -> translate(stmt)
is Subroutine -> translateSubroutine(stmt)
is InlineAssembly -> translate(stmt)
is FunctionCallStatement -> {
val functionName = stmt.target.nameInSource.last()
val builtinFunc = BuiltinFunctions[functionName]
if(builtinFunc!=null) {
builtinFunctionsAsmGen.translateFunctioncallStatement(stmt, builtinFunc)
} else {
functioncallAsmGen.translateFunctionCall(stmt)
// discard any results from the stack:
val sub = stmt.target.targetSubroutine(program.namespace)!!
val returns = sub.returntypes.zip(sub.asmReturnvaluesRegisters)
for((t, reg) in returns) {
if(reg.stack) {
if (t in IntegerDatatypes || t in PassByReferenceDatatypes) out(" inx")
else if (t == DataType.FLOAT) out(" inx | inx | inx")
}
}
}
}
is Assignment -> assignmentAsmGen.translate(stmt)
is Jump -> translate(stmt)
is PostIncrDecr -> postincrdecrAsmGen.translate(stmt)
is Label -> translate(stmt)
is BranchStatement -> translate(stmt)
is IfStatement -> translate(stmt)
is ForLoop -> forloopsAsmGen.translate(stmt)
is Continue -> out(" jmp ${loopContinueLabels.peek()}")
is Break -> out(" jmp ${loopEndLabels.peek()}")
is WhileLoop -> translate(stmt)
is RepeatLoop -> translate(stmt)
is WhenStatement -> translate(stmt)
is BuiltinFunctionStatementPlaceholder -> throw AssemblyError("builtin function should not have placeholder anymore?")
is AnonymousScope -> translate(stmt)
is Block -> throw AssemblyError("block should have been handled elsewhere")
}
}
private fun translate(stmt: IfStatement) {
expressionsAsmGen.translateExpression(stmt.condition)
translateTestStack(stmt.condition.inferType(program).typeOrElse(DataType.STRUCT))
val elseLabel = makeLabel("if_else")
val endLabel = makeLabel("if_end")
out(" beq $elseLabel")
translate(stmt.truepart)
out(" jmp $endLabel")
out(elseLabel)
translate(stmt.elsepart)
out(endLabel)
}
private fun translateTestStack(dataType: DataType) {
when(dataType) {
in ByteDatatypes -> out(" inx | lda $ESTACK_LO_HEX,x")
in WordDatatypes -> out(" inx | lda $ESTACK_LO_HEX,x | ora $ESTACK_HI_HEX,x")
DataType.FLOAT -> throw AssemblyError("conditional value should be an integer (boolean)")
else -> throw AssemblyError("non-numerical dt")
}
}
private fun translate(stmt: WhileLoop) {
val whileLabel = makeLabel("while")
val endLabel = makeLabel("whileend")
loopEndLabels.push(endLabel)
loopContinueLabels.push(whileLabel)
out(whileLabel)
// TODO optimize for the simple cases, can we avoid stack use?
expressionsAsmGen.translateExpression(stmt.condition)
val conditionDt = stmt.condition.inferType(program)
if(!conditionDt.isKnown)
throw AssemblyError("unknown condition dt")
if(conditionDt.typeOrElse(DataType.BYTE) in ByteDatatypes) {
out(" inx | lda $ESTACK_LO_HEX,x | beq $endLabel")
} else {
out("""
inx
lda $ESTACK_LO_HEX,x
bne +
lda $ESTACK_HI_HEX,x
beq $endLabel
+ """)
}
translate(stmt.body)
out(" jmp $whileLabel")
out(endLabel)
loopEndLabels.pop()
loopContinueLabels.pop()
}
private fun translate(stmt: RepeatLoop) {
val repeatLabel = makeLabel("repeat")
val endLabel = makeLabel("repeatend")
loopEndLabels.push(endLabel)
loopContinueLabels.push(repeatLabel)
out(repeatLabel)
// TODO optimize this for the simple cases, can we avoid stack use?
translate(stmt.body)
expressionsAsmGen.translateExpression(stmt.untilCondition)
val conditionDt = stmt.untilCondition.inferType(program)
if(!conditionDt.isKnown)
throw AssemblyError("unknown condition dt")
if(conditionDt.typeOrElse(DataType.BYTE) in ByteDatatypes) {
out(" inx | lda $ESTACK_LO_HEX,x | beq $repeatLabel")
} else {
out("""
inx
lda $ESTACK_LO_HEX,x
bne +
lda $ESTACK_HI_HEX,x
beq $repeatLabel
+ """)
}
out(endLabel)
loopEndLabels.pop()
loopContinueLabels.pop()
}
private fun translate(stmt: WhenStatement) {
expressionsAsmGen.translateExpression(stmt.condition)
val endLabel = makeLabel("choice_end")
val choiceBlocks = mutableListOf<Pair<String, AnonymousScope>>()
val conditionDt = stmt.condition.inferType(program)
if(!conditionDt.isKnown)
throw AssemblyError("unknown condition dt")
if(conditionDt.typeOrElse(DataType.BYTE) in ByteDatatypes)
out(" inx | lda $ESTACK_LO_HEX,x")
else
out(" inx | lda $ESTACK_LO_HEX,x | ldy $ESTACK_HI_HEX,x")
for(choice in stmt.choices) {
val choiceLabel = makeLabel("choice")
if(choice.values==null) {
// the else choice
translate(choice.statements)
out(" jmp $endLabel")
} else {
choiceBlocks.add(Pair(choiceLabel, choice.statements))
for (cv in choice.values!!) {
val value = (cv as NumericLiteralValue).number.toInt()
if(conditionDt.typeOrElse(DataType.BYTE) in ByteDatatypes) {
out(" cmp #${value.toHex()} | beq $choiceLabel")
} else {
out("""
cmp #<${value.toHex()}
bne +
cpy #>${value.toHex()}
beq $choiceLabel
+
""")
}
}
}
}
for(choiceBlock in choiceBlocks) {
out(choiceBlock.first)
translate(choiceBlock.second)
out(" jmp $endLabel")
}
out(endLabel)
}
private fun translate(stmt: Label) {
out(stmt.name)
}
private fun translate(scope: AnonymousScope) {
// note: the variables defined in an anonymous scope have been moved to their defining subroutine's scope
scope.statements.forEach{ translate(it) }
}
private fun translate(stmt: BranchStatement) {
if(stmt.truepart.containsNoCodeNorVars() && stmt.elsepart.containsCodeOrVars())
throw AssemblyError("only else part contains code, shoud have been switched already")
val jump = stmt.truepart.statements.first() as? Jump
if(jump!=null) {
// branch with only a jump
val instruction = branchInstruction(stmt.condition, false)
out(" $instruction ${getJumpTarget(jump)}")
translate(stmt.elsepart)
} else {
if(stmt.elsepart.containsNoCodeNorVars()) {
val instruction = branchInstruction(stmt.condition, true)
val elseLabel = makeLabel("branch_else")
out(" $instruction $elseLabel")
translate(stmt.truepart)
out(elseLabel)
} else {
val instruction = branchInstruction(stmt.condition, false)
val trueLabel = makeLabel("branch_true")
val endLabel = makeLabel("branch_end")
out(" $instruction $trueLabel")
translate(stmt.elsepart)
out(" jmp $endLabel")
out(trueLabel)
translate(stmt.truepart)
out(endLabel)
}
}
}
private fun translate(stmt: Directive) {
when(stmt.directive) {
"%asminclude" -> {
val sourcecode = loadAsmIncludeFile(stmt.args[0].str!!, stmt.definingModule().source)
val scopeprefix = stmt.args[1].str ?: ""
if(!scopeprefix.isBlank())
out("$scopeprefix\t.proc")
assemblyLines.add(sourcecode.trimEnd().trimStart('\n'))
if(!scopeprefix.isBlank())
out(" .pend\n")
}
"%asmbinary" -> {
val offset = if(stmt.args.size>1) ", ${stmt.args[1].int}" else ""
val length = if(stmt.args.size>2) ", ${stmt.args[2].int}" else ""
out(" .binary \"${stmt.args[0].str}\" $offset $length")
}
"%breakpoint" -> {
val label = "_prog8_breakpoint_${breakpointLabels.size+1}"
breakpointLabels.add(label)
out("$label\tnop")
}
}
}
private fun translate(jmp: Jump) {
out(" jmp ${getJumpTarget(jmp)}")
}
private fun getJumpTarget(jmp: Jump): String {
return when {
jmp.identifier!=null -> asmIdentifierName(jmp.identifier)
jmp.generatedLabel!=null -> jmp.generatedLabel
jmp.address!=null -> jmp.address.toHex()
else -> "????"
}
}
private fun translate(ret: Return) {
ret.value?.let { expressionsAsmGen.translateExpression(it) }
out(" rts")
}
private fun translate(asm: InlineAssembly) {
val assembly = asm.assembly.trimEnd().trimStart('\n')
assemblyLines.add(assembly)
}
internal fun translateArrayIndexIntoA(expr: ArrayIndexedExpression) {
when (val index = expr.arrayspec.index) {
is NumericLiteralValue -> throw AssemblyError("this should be optimized directly")
is RegisterExpr -> {
when (index.register) {
Register.A -> {}
Register.X -> out(" txa")
Register.Y -> out(" tya")
}
}
is IdentifierReference -> {
val indexName = asmIdentifierName(index)
out(" lda $indexName")
}
else -> {
expressionsAsmGen.translateExpression(index)
out(" inx | lda $ESTACK_LO_HEX,x")
}
}
}
internal fun translateExpression(expression: Expression) =
expressionsAsmGen.translateExpression(expression)
internal fun translateFunctioncallExpression(functionCall: FunctionCall, signature: FunctionSignature) =
builtinFunctionsAsmGen.translateFunctioncallExpression(functionCall, signature)
internal fun translateFunctionCall(functionCall: FunctionCall) =
functioncallAsmGen.translateFunctionCall(functionCall)
internal fun assignFromEvalResult(target: AssignTarget) =
assignmentAsmGen.assignFromEvalResult(target)
fun assignFromByteConstant(target: AssignTarget, value: Short) =
assignmentAsmGen.assignFromByteConstant(target, value)
fun assignFromWordConstant(target: AssignTarget, value: Int) =
assignmentAsmGen.assignFromWordConstant(target, value)
fun assignFromFloatConstant(target: AssignTarget, value: Double) =
assignmentAsmGen.assignFromFloatConstant(target, value)
fun assignFromByteVariable(target: AssignTarget, variable: IdentifierReference) =
assignmentAsmGen.assignFromByteVariable(target, variable)
fun assignFromWordVariable(target: AssignTarget, variable: IdentifierReference) =
assignmentAsmGen.assignFromWordVariable(target, variable)
fun assignFromFloatVariable(target: AssignTarget, variable: IdentifierReference) =
assignmentAsmGen.assignFromFloatVariable(target, variable)
fun assignFromRegister(target: AssignTarget, register: Register) =
assignmentAsmGen.assignFromRegister(target, register)
fun assignFromMemoryByte(target: AssignTarget, address: Int?, identifier: IdentifierReference?) =
assignmentAsmGen.assignFromMemoryByte(target, address, identifier)
}

51
compiler/src/prog8/compiler/target/c64/AsmOptimizer.kt → compiler/src/prog8/compiler/target/c64/codegen/AsmOptimizer.kt
View File

@ -1,6 +1,11 @@
package prog8.compiler.target.c64
package prog8.compiler.target.c64.codegen
import prog8.compiler.target.c64.C64MachineDefinition.ESTACK_LO_HEX
import prog8.compiler.target.c64.C64MachineDefinition.ESTACK_LO_PLUS1_HEX
// note: see https://wiki.nesdev.com/w/index.php/6502_assembly_optimisations
import prog8.compiler.toHex
fun optimizeAssembly(lines: MutableList<String>): Int {
@ -24,10 +29,19 @@ fun optimizeAssembly(lines: MutableList<String>): Int {
numberOfOptimizations++
}
removeLines = optimizeCmpSequence(linesByFour)
if(removeLines.isNotEmpty()) {
for (i in removeLines.reversed())
lines.removeAt(i)
linesByFour = getLinesBy(lines, 4)
numberOfOptimizations++
}
removeLines = optimizeStoreLoadSame(linesByFour)
if(removeLines.isNotEmpty()) {
for (i in removeLines.reversed())
lines.removeAt(i)
linesByFour = getLinesBy(lines, 4)
numberOfOptimizations++
}
@ -36,24 +50,45 @@ fun optimizeAssembly(lines: MutableList<String>): Int {
if(removeLines.isNotEmpty()) {
for (i in removeLines.reversed())
lines.removeAt(i)
linesByFourteen = getLinesBy(lines, 14)
numberOfOptimizations++
}
// TODO more assembly optimizations?
// TODO more assembly optimizations
return numberOfOptimizations
}
fun optimizeCmpSequence(linesByFour: List<List<IndexedValue<String>>>): List<Int> {
// the when statement (on bytes) generates a sequence of:
// lda $ce01,x
// cmp #$20
// beq check_prog8_s72choice_32
// lda $ce01,x
// cmp #$21
// beq check_prog8_s73choice_33
// the repeated lda can be removed
val removeLines = mutableListOf<Int>()
for(lines in linesByFour) {
if(lines[0].value.trim()=="lda $ESTACK_LO_PLUS1_HEX,x" &&
lines[1].value.trim().startsWith("cmp ") &&
lines[2].value.trim().startsWith("beq ") &&
lines[3].value.trim()=="lda $ESTACK_LO_PLUS1_HEX,x") {
removeLines.add(lines[3].index) // remove the second lda
}
}
return removeLines
}
fun optimizeUselessStackByteWrites(linesByFour: List<List<IndexedValue<String>>>): List<Int> {
// sta on stack, dex, inx, lda from stack -> eliminate this useless stack byte write
// this is a lot harder for word values because the instruction sequence varies.
val removeLines = mutableListOf<Int>()
for(lines in linesByFour) {
if(lines[0].value.trim()=="sta ${ESTACK_LO.toHex()},x" &&
if(lines[0].value.trim()=="sta $ESTACK_LO_HEX,x" &&
lines[1].value.trim()=="dex" &&
lines[2].value.trim()=="inx" &&
lines[3].value.trim()=="lda ${ESTACK_LO.toHex()},x") {
removeLines.add(lines[0].index)
lines[3].value.trim()=="lda $ESTACK_LO_HEX,x") {
removeLines.add(lines[1].index)
removeLines.add(lines[2].index)
removeLines.add(lines[3].index)
@ -66,7 +101,7 @@ fun optimizeSameAssignments(linesByFourteen: List<List<IndexedValue<String>>>):
// optimize sequential assignments of the isSameAs value to various targets (bytes, words, floats)
// the float one is the one that requires 2*7=14 lines of code to check...
// @todo a better place to do this is in the Compiler instead and work on opcodes, and never even create the inefficient asm...
// @todo a better place to do this is in the Compiler instead and transform the Ast, or the AsmGen, and never even create the inefficient asm in the first place...
val removeLines = mutableListOf<Int>()
for (pair in linesByFourteen) {
@ -128,7 +163,7 @@ fun optimizeSameAssignments(linesByFourteen: List<List<IndexedValue<String>>>):
}
private fun getLinesBy(lines: MutableList<String>, windowSize: Int) =
// all lines (that aren't empty or comments) in sliding pairs of 2
// all lines (that aren't empty or comments) in sliding windows of certain size
lines.withIndex().filter { it.value.isNotBlank() && !it.value.trimStart().startsWith(';') }.windowed(windowSize, partialWindows = false)
private fun optimizeStoreLoadSame(linesByFour: List<List<IndexedValue<String>>>): List<Int> {

750
compiler/src/prog8/compiler/target/c64/codegen/AssignmentAsmGen.kt Normal file
View File

@ -0,0 +1,750 @@
package prog8.compiler.target.c64.codegen
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.ast.statements.AssignTarget
import prog8.ast.statements.Assignment
import prog8.ast.statements.DirectMemoryWrite
import prog8.ast.statements.VarDecl
import prog8.compiler.toHex
import prog8.compiler.AssemblyError
import prog8.compiler.target.c64.C64MachineDefinition
import prog8.compiler.target.c64.C64MachineDefinition.C64Zeropage
import prog8.compiler.target.c64.C64MachineDefinition.ESTACK_HI_HEX
import prog8.compiler.target.c64.C64MachineDefinition.ESTACK_LO_HEX
internal class AssignmentAsmGen(private val program: Program, private val asmgen: AsmGen) {
internal fun translate(assign: Assignment) {
if(assign.aug_op!=null)
throw AssemblyError("aug-op assignments should have been transformed to normal ones")
when(assign.value) {
is NumericLiteralValue -> {
val numVal = assign.value as NumericLiteralValue
when(numVal.type) {
DataType.UBYTE, DataType.BYTE -> assignFromByteConstant(assign.target, numVal.number.toShort())
DataType.UWORD, DataType.WORD -> assignFromWordConstant(assign.target, numVal.number.toInt())
DataType.FLOAT -> assignFromFloatConstant(assign.target, numVal.number.toDouble())
else -> throw AssemblyError("weird numval type")
}
}
is RegisterExpr -> {
assignFromRegister(assign.target, (assign.value as RegisterExpr).register)
}
is IdentifierReference -> {
val type = assign.target.inferType(program, assign).typeOrElse(DataType.STRUCT)
when(type) {
DataType.UBYTE, DataType.BYTE -> assignFromByteVariable(assign.target, assign.value as IdentifierReference)
DataType.UWORD, DataType.WORD -> assignFromWordVariable(assign.target, assign.value as IdentifierReference)
DataType.FLOAT -> assignFromFloatVariable(assign.target, assign.value as IdentifierReference)
else -> throw AssemblyError("unsupported assignment target type $type")
}
}
is AddressOf -> {
val identifier = (assign.value as AddressOf).identifier
assignFromAddressOf(assign.target, identifier)
}
is DirectMemoryRead -> {
val read = (assign.value as DirectMemoryRead)
when(read.addressExpression) {
is NumericLiteralValue -> {
val address = (read.addressExpression as NumericLiteralValue).number.toInt()
assignFromMemoryByte(assign.target, address, null)
}
is IdentifierReference -> {
assignFromMemoryByte(assign.target, null, read.addressExpression as IdentifierReference)
}
else -> {
asmgen.translateExpression(read.addressExpression)
TODO("read memory byte from result and put that in ${assign.target}")
}
}
}
is PrefixExpression -> {
// TODO optimize common cases
asmgen.translateExpression(assign.value as PrefixExpression)
assignFromEvalResult(assign.target)
}
is BinaryExpression -> {
// TODO optimize common cases
asmgen.translateExpression(assign.value as BinaryExpression)
assignFromEvalResult(assign.target)
}
is ArrayIndexedExpression -> {
// TODO optimize common cases
val arrayExpr = assign.value as ArrayIndexedExpression
val arrayDt = arrayExpr.identifier.targetVarDecl(program.namespace)!!.datatype
val index = arrayExpr.arrayspec.index
if(index is NumericLiteralValue) {
// constant array index value
val arrayVarName = asmgen.asmIdentifierName(arrayExpr.identifier)
val indexValue = index.number.toInt() * ArrayElementTypes.getValue(arrayDt).memorySize()
when (arrayDt) {
DataType.STR, DataType.ARRAY_UB, DataType.ARRAY_B ->
asmgen.out(" lda $arrayVarName+$indexValue | sta $ESTACK_LO_HEX,x | dex")
DataType.ARRAY_UW, DataType.ARRAY_W ->
asmgen.out(" lda $arrayVarName+$indexValue | sta $ESTACK_LO_HEX,x | lda $arrayVarName+$indexValue+1 | sta $ESTACK_HI_HEX,x | dex")
DataType.ARRAY_F ->
asmgen.out(" lda #<$arrayVarName+$indexValue | ldy #>$arrayVarName+$indexValue | jsr c64flt.push_float")
else ->
throw AssemblyError("weird array type")
}
} else {
asmgen.translateArrayIndexIntoA(arrayExpr)
asmgen.readAndPushArrayvalueWithIndexA(arrayDt, arrayExpr.identifier)
}
assignFromEvalResult(assign.target)
}
is TypecastExpression -> {
val cast = assign.value as TypecastExpression
val sourceType = cast.expression.inferType(program)
val targetType = assign.target.inferType(program, assign)
if(sourceType.isKnown && targetType.isKnown &&
(sourceType.typeOrElse(DataType.STRUCT) in ByteDatatypes && targetType.typeOrElse(DataType.STRUCT) in ByteDatatypes) ||
(sourceType.typeOrElse(DataType.STRUCT) in WordDatatypes && targetType.typeOrElse(DataType.STRUCT) in WordDatatypes)) {
// no need for a type cast
assign.value = cast.expression
translate(assign)
} else {
asmgen.translateExpression(assign.value as TypecastExpression)
assignFromEvalResult(assign.target)
}
}
is FunctionCall -> {
asmgen.translateExpression(assign.value as FunctionCall)
assignFromEvalResult(assign.target)
}
is ArrayLiteralValue, is StringLiteralValue -> TODO("string/array/struct assignment?")
is StructLiteralValue -> throw AssemblyError("struct literal value assignment should have been flattened")
is RangeExpr -> throw AssemblyError("range expression should have been changed into array values")
}
}
internal fun assignFromEvalResult(target: AssignTarget) {
val targetIdent = target.identifier
when {
target.register!=null -> {
if(target.register== Register.X)
throw AssemblyError("can't pop into X register - use variable instead")
asmgen.out(" inx | ld${target.register.name.toLowerCase()} $ESTACK_LO_HEX,x ")
}
targetIdent!=null -> {
val targetName = asmgen.asmIdentifierName(targetIdent)
val targetDt = targetIdent.inferType(program).typeOrElse(DataType.STRUCT)
when(targetDt) {
DataType.UBYTE, DataType.BYTE -> {
asmgen.out(" inx | lda $ESTACK_LO_HEX,x | sta $targetName")
}
DataType.UWORD, DataType.WORD -> {
asmgen.out("""
inx
lda $ESTACK_LO_HEX,x
sta $targetName
lda $ESTACK_HI_HEX,x
sta $targetName+1
""")
}
DataType.FLOAT -> {
asmgen.out("""
lda #<$targetName
ldy #>$targetName
jsr c64flt.pop_float
""")
}
else -> throw AssemblyError("weird target variable type $targetDt")
}
}
target.memoryAddress!=null -> {
asmgen.out(" inx | ldy $ESTACK_LO_HEX,x")
storeRegisterInMemoryAddress(Register.Y, target.memoryAddress)
}
target.arrayindexed!=null -> {
val arrayDt = target.arrayindexed!!.identifier.targetVarDecl(program.namespace)!!.datatype
val arrayVarName = asmgen.asmIdentifierName(target.arrayindexed!!.identifier)
asmgen.translateExpression(target.arrayindexed!!.arrayspec.index)
asmgen.out(" inx | lda $ESTACK_LO_HEX,x")
popAndWriteArrayvalueWithIndexA(arrayDt, arrayVarName)
}
else -> throw AssemblyError("weird assignment target $target")
}
}
internal fun assignFromAddressOf(target: AssignTarget, name: IdentifierReference) {
val targetIdent = target.identifier
val targetArrayIdx = target.arrayindexed
val struct = name.memberOfStruct(program.namespace)
val sourceName = if(struct!=null) {
// take the address of the first struct member instead
val decl = name.targetVarDecl(program.namespace)!!
val firstStructMember = struct.nameOfFirstMember()
// find the flattened var that belongs to this first struct member
val firstVarName = listOf(decl.name, firstStructMember)
val firstVar = name.definingScope().lookup(firstVarName, name) as VarDecl
firstVar.name
} else {
asmgen.fixNameSymbols(name.nameInSource.joinToString ("."))
}
when {
targetIdent!=null -> {
val targetName = asmgen.asmIdentifierName(targetIdent)
asmgen.out("""
lda #<$sourceName
ldy #>$sourceName
sta $targetName
sty $targetName+1
""")
}
target.memoryAddress!=null -> {
TODO("assign address $sourceName to memory word $target")
}
targetArrayIdx!=null -> {
val index = targetArrayIdx.arrayspec.index
val targetName = asmgen.asmIdentifierName(targetArrayIdx.identifier)
TODO("assign address $sourceName to array $targetName [ $index ]")
}
else -> TODO("assign address $sourceName to $target")
}
}
internal fun assignFromWordVariable(target: AssignTarget, variable: IdentifierReference) {
val sourceName = asmgen.asmIdentifierName(variable)
val targetIdent = target.identifier
val targetArrayIdx = target.arrayindexed
when {
targetIdent!=null -> {
val targetName = asmgen.asmIdentifierName(targetIdent)
asmgen.out("""
lda $sourceName
ldy $sourceName+1
sta $targetName
sty $targetName+1
""")
}
target.memoryAddress!=null -> {
TODO("assign wordvar $sourceName to memory ${target.memoryAddress}")
}
targetArrayIdx!=null -> {
val index = targetArrayIdx.arrayspec.index
val targetName = asmgen.asmIdentifierName(targetArrayIdx.identifier)
asmgen.out(" lda $sourceName | sta $ESTACK_LO_HEX,x | lda $sourceName+1 | sta $ESTACK_HI_HEX,x | dex")
asmgen.translateExpression(index)
asmgen.out(" inx | lda $ESTACK_LO_HEX,x")
val arrayDt = targetArrayIdx.identifier.inferType(program).typeOrElse(DataType.STRUCT)
popAndWriteArrayvalueWithIndexA(arrayDt, targetName)
}
else -> TODO("assign wordvar to $target")
}
}
internal fun assignFromFloatVariable(target: AssignTarget, variable: IdentifierReference) {
val sourceName = asmgen.asmIdentifierName(variable)
val targetIdent = target.identifier
val targetArrayIdx = target.arrayindexed
when {
targetIdent!=null -> {
val targetName = asmgen.asmIdentifierName(targetIdent)
asmgen.out("""
lda $sourceName
sta $targetName
lda $sourceName+1
sta $targetName+1
lda $sourceName+2
sta $targetName+2
lda $sourceName+3
sta $targetName+3
lda $sourceName+4
sta $targetName+4
""")
}
targetArrayIdx!=null -> {
val index = targetArrayIdx.arrayspec.index
val targetName = asmgen.asmIdentifierName(targetArrayIdx.identifier)
asmgen.out(" lda #<$sourceName | ldy #>$sourceName | jsr c64flt.push_float")
asmgen.translateExpression(index)
asmgen.out(" lda #<$targetName | ldy #>$targetName | jsr c64flt.pop_float_to_indexed_var")
}
else -> TODO("assign floatvar to $target")
}
}
internal fun assignFromByteVariable(target: AssignTarget, variable: IdentifierReference) {
val sourceName = asmgen.asmIdentifierName(variable)
val targetIdent = target.identifier
val targetArrayIdx = target.arrayindexed
when {
target.register!=null -> {
asmgen.out(" ld${target.register.name.toLowerCase()} $sourceName")
}
targetIdent!=null -> {
val targetName = asmgen.asmIdentifierName(targetIdent)
asmgen.out("""
lda $sourceName
sta $targetName
""")
}
targetArrayIdx!=null -> {
val index = targetArrayIdx.arrayspec.index
val targetName = asmgen.asmIdentifierName(targetArrayIdx.identifier)
val arrayDt = targetArrayIdx.identifier.inferType(program).typeOrElse(DataType.STRUCT)
asmgen.out(" lda $sourceName | sta $ESTACK_LO_HEX,x | dex")
asmgen.translateExpression(index)
asmgen.out(" inx | lda $ESTACK_LO_HEX,x")
popAndWriteArrayvalueWithIndexA(arrayDt, targetName)
}
target.memoryAddress != null -> {
val addressExpr = target.memoryAddress.addressExpression
val addressLv = addressExpr as? NumericLiteralValue
when {
addressLv != null -> asmgen.out(" lda $sourceName | sta ${addressLv.number.toHex()}")
addressExpr is IdentifierReference -> {
val targetName = asmgen.asmIdentifierName(addressExpr)
asmgen.out(" lda $sourceName | sta $targetName")
}
else -> {
asmgen.translateExpression(addressExpr)
asmgen.out("""
inx
lda $ESTACK_LO_HEX,x
ldy $ESTACK_HI_HEX,x
sta (+) +1
sty (+) +2
lda $sourceName
+ sta ${65535.toHex()} ; modified
""")
}
}
}
else -> TODO("assign bytevar to $target")
}
}
internal fun assignFromRegister(target: AssignTarget, register: Register) {
val targetIdent = target.identifier
val targetArrayIdx = target.arrayindexed
when {
targetIdent!=null -> {
val targetName = asmgen.asmIdentifierName(targetIdent)
asmgen.out(" st${register.name.toLowerCase()} $targetName")
}
target.register!=null -> {
when(register) {
Register.A -> when(target.register) {
Register.A -> {}
Register.X -> asmgen.out(" tax")
Register.Y -> asmgen.out(" tay")
}
Register.X -> when(target.register) {
Register.A -> asmgen.out(" txa")
Register.X -> {}
Register.Y -> asmgen.out(" txy")
}
Register.Y -> when(target.register) {
Register.A -> asmgen.out(" tya")
Register.X -> asmgen.out(" tyx")
Register.Y -> {}
}
}
}
target.memoryAddress!=null -> {
storeRegisterInMemoryAddress(register, target.memoryAddress)
}
targetArrayIdx!=null -> {
val index = targetArrayIdx.arrayspec.index
val targetName = asmgen.asmIdentifierName(targetArrayIdx.identifier)
when (index) {
is NumericLiteralValue -> {
val memindex = index.number.toInt()
when(register) {
Register.A -> asmgen.out(" sta $targetName+$memindex")
Register.X -> asmgen.out(" stx $targetName+$memindex")
Register.Y -> asmgen.out(" sty $targetName+$memindex")
}
}
is RegisterExpr -> {
when(register) {
Register.A -> asmgen.out(" sta ${C64Zeropage.SCRATCH_B1}")
Register.X -> asmgen.out(" stx ${C64Zeropage.SCRATCH_B1}")
Register.Y -> asmgen.out(" sty ${C64Zeropage.SCRATCH_B1}")
}
when(index.register) {
Register.A -> {}
Register.X -> asmgen.out(" txa")
Register.Y -> asmgen.out(" tya")
}
asmgen.out("""
tay
lda ${C64Zeropage.SCRATCH_B1}
sta $targetName,y
""")
}
is IdentifierReference -> {
when(register) {
Register.A -> asmgen.out(" sta ${C64Zeropage.SCRATCH_B1}")
Register.X -> asmgen.out(" stx ${C64Zeropage.SCRATCH_B1}")
Register.Y -> asmgen.out(" sty ${C64Zeropage.SCRATCH_B1}")
}
asmgen.out("""
lda ${asmgen.asmIdentifierName(index)}
tay
lda ${C64Zeropage.SCRATCH_B1}
sta $targetName,y
""")
}
else -> {
asmgen.saveRegister(register)
asmgen.translateExpression(index)
asmgen.restoreRegister(register)
when(register) {
Register.A -> asmgen.out(" sta ${C64Zeropage.SCRATCH_B1}")
Register.X -> asmgen.out(" stx ${C64Zeropage.SCRATCH_B1}")
Register.Y -> asmgen.out(" sty ${C64Zeropage.SCRATCH_B1}")
}
asmgen.out("""
inx
lda $ESTACK_LO_HEX,x
tay
lda ${C64Zeropage.SCRATCH_B1}
sta $targetName,y
""")
}
}
}
else -> TODO("assign register $register to $target")
}
}
private fun storeRegisterInMemoryAddress(register: Register, memoryAddress: DirectMemoryWrite) {
val addressExpr = memoryAddress.addressExpression
val addressLv = addressExpr as? NumericLiteralValue
val registerName = register.name.toLowerCase()
when {
addressLv != null -> asmgen.out(" st$registerName ${addressLv.number.toHex()}")
addressExpr is IdentifierReference -> {
val targetName = asmgen.asmIdentifierName(addressExpr)
when(register) {
Register.A -> asmgen.out("""
ldy $targetName
sty ${C64Zeropage.SCRATCH_W1}
ldy $targetName+1
sty ${C64Zeropage.SCRATCH_W1+1}
ldy #0
sta (${C64Zeropage.SCRATCH_W1}),y
""")
Register.X -> asmgen.out("""
txa
ldy $targetName
sty ${C64Zeropage.SCRATCH_W1}
ldy $targetName+1
sty ${C64Zeropage.SCRATCH_W1+1}
ldy #0
sta (${C64Zeropage.SCRATCH_W1}),y
""")
Register.Y -> asmgen.out("""
tya
ldy $targetName
sty ${C64Zeropage.SCRATCH_W1}
ldy $targetName+1
sty ${C64Zeropage.SCRATCH_W1+1}
ldy #0
sta (${C64Zeropage.SCRATCH_W1}),y
""")
}
}
else -> {
asmgen.saveRegister(register)
asmgen.translateExpression(addressExpr)
asmgen.restoreRegister(register)
when (register) {
Register.A -> asmgen.out(" tay")
Register.X -> throw AssemblyError("can't use X register here")
Register.Y -> {}
}
asmgen.out("""
inx
lda $ESTACK_LO_HEX,x
sta (+) +1
lda $ESTACK_HI_HEX,x
sta (+) +2
+ sty ${65535.toHex()} ; modified
""")
}
}
}
internal fun assignFromWordConstant(target: AssignTarget, word: Int) {
val targetIdent = target.identifier
val targetArrayIdx = target.arrayindexed
when {
targetIdent!=null -> {
val targetName = asmgen.asmIdentifierName(targetIdent)
if(word ushr 8 == word and 255) {
// lsb=msb
asmgen.out("""
lda #${(word and 255).toHex()}
sta $targetName
sta $targetName+1
""")
} else {
asmgen.out("""
lda #<${word.toHex()}
ldy #>${word.toHex()}
sta $targetName
sty $targetName+1
""")
}
}
target.memoryAddress!=null -> {
TODO("assign word $word to memory ${target.memoryAddress}")
}
targetArrayIdx!=null -> {
val index = targetArrayIdx.arrayspec.index
val targetName = asmgen.asmIdentifierName(targetArrayIdx.identifier)
// TODO optimize common cases
asmgen.translateExpression(index)
asmgen.out("""
inx
lda $ESTACK_LO_HEX,x
asl a
tay
lda #<${word.toHex()}
sta $targetName,y
lda #>${word.toHex()}
sta $targetName+1,y
""")
}
else -> TODO("assign word $word to $target")
}
}
internal fun assignFromByteConstant(target: AssignTarget, byte: Short) {
val targetIdent = target.identifier
val targetArrayIdx = target.arrayindexed
when {
target.register!=null -> {
asmgen.out(" ld${target.register.name.toLowerCase()} #${byte.toHex()}")
}
targetIdent!=null -> {
val targetName = asmgen.asmIdentifierName(targetIdent)
asmgen.out(" lda #${byte.toHex()} | sta $targetName ")
}
target.memoryAddress!=null -> {
asmgen.out(" ldy #${byte.toHex()}")
storeRegisterInMemoryAddress(Register.Y, target.memoryAddress)
}
targetArrayIdx!=null -> {
val index = targetArrayIdx.arrayspec.index
val targetName = asmgen.asmIdentifierName(targetArrayIdx.identifier)
// TODO optimize common cases
asmgen.translateExpression(index)
asmgen.out("""
inx
ldy $ESTACK_LO_HEX,x
lda #${byte.toHex()}
sta $targetName,y
""")
}
else -> TODO("assign byte $byte to $target")
}
}
internal fun assignFromFloatConstant(target: AssignTarget, float: Double) {
val targetIdent = target.identifier
val targetArrayIdx = target.arrayindexed
if(float==0.0) {
// optimized case for float zero
when {
targetIdent != null -> {
val targetName = asmgen.asmIdentifierName(targetIdent)
asmgen.out("""
lda #0
sta $targetName
sta $targetName+1
sta $targetName+2
sta $targetName+3
sta $targetName+4
""")
}
targetArrayIdx!=null -> {
val index = targetArrayIdx.arrayspec.index
val targetName = asmgen.asmIdentifierName(targetArrayIdx.identifier)
if(index is NumericLiteralValue) {
val indexValue = index.number.toInt() * C64MachineDefinition.FLOAT_MEM_SIZE
asmgen.out("""
lda #0
sta $targetName+$indexValue
sta $targetName+$indexValue+1
sta $targetName+$indexValue+2
sta $targetName+$indexValue+3
sta $targetName+$indexValue+4
""")
} else {
asmgen.translateExpression(index)
asmgen.out("""
inx
lda $ESTACK_LO_HEX,x
asl a
asl a
clc
adc $ESTACK_LO_HEX,x
tay
lda #0
sta $targetName,y
sta $targetName+1,y
sta $targetName+2,y
sta $targetName+3,y
sta $targetName+4,y
""") // TODO use a subroutine for this
}
}
else -> TODO("assign float 0.0 to $target")
}
} else {
// non-zero value
val constFloat = asmgen.getFloatConst(float)
when {
targetIdent != null -> {
val targetName = asmgen.asmIdentifierName(targetIdent)
asmgen.out("""
lda $constFloat
sta $targetName
lda $constFloat+1
sta $targetName+1
lda $constFloat+2
sta $targetName+2
lda $constFloat+3
sta $targetName+3
lda $constFloat+4
sta $targetName+4
""")
}
targetArrayIdx!=null -> {
val index = targetArrayIdx.arrayspec.index
val arrayVarName = asmgen.asmIdentifierName(targetArrayIdx.identifier)
if(index is NumericLiteralValue) {
val indexValue = index.number.toInt() * C64MachineDefinition.FLOAT_MEM_SIZE
asmgen.out("""
lda $constFloat
sta $arrayVarName+$indexValue
lda $constFloat+1
sta $arrayVarName+$indexValue+1
lda $constFloat+2
sta $arrayVarName+$indexValue+2
lda $constFloat+3
sta $arrayVarName+$indexValue+3
lda $constFloat+4
sta $arrayVarName+$indexValue+4
""")
} else {
asmgen.translateArrayIndexIntoA(targetArrayIdx)
asmgen.out("""
sta ${C64Zeropage.SCRATCH_REG}
asl a
asl a
clc
adc ${C64Zeropage.SCRATCH_REG}
tay
lda $constFloat
sta $arrayVarName,y
lda $constFloat+1
sta $arrayVarName+1,y
lda $constFloat+2
sta $arrayVarName+2,y
lda $constFloat+3
sta $arrayVarName+3,y
lda $constFloat+4
sta $arrayVarName+4,y
""") // TODO use a subroutine for this
}
}
else -> TODO("assign float $float to $target")
}
}
}
internal fun assignFromMemoryByte(target: AssignTarget, address: Int?, identifier: IdentifierReference?) {
val targetIdent = target.identifier
val targetArrayIdx = target.arrayindexed
if(address!=null) {
when {
target.register!=null -> {
asmgen.out(" ld${target.register.name.toLowerCase()} ${address.toHex()}")
}
targetIdent!=null -> {
val targetName = asmgen.asmIdentifierName(targetIdent)
asmgen.out("""
lda ${address.toHex()}
sta $targetName
""")
}
target.memoryAddress!=null -> {
asmgen.out(" ldy ${address.toHex()}")
storeRegisterInMemoryAddress(Register.Y, target.memoryAddress)
}
targetArrayIdx!=null -> {
val index = targetArrayIdx.arrayspec.index
val targetName = asmgen.asmIdentifierName(targetArrayIdx.identifier)
TODO("assign memory byte at $address to array $targetName [ $index ]")
}
else -> TODO("assign memory byte $target")
}
}
else if(identifier!=null) {
val sourceName = asmgen.asmIdentifierName(identifier)
when {
target.register!=null -> {
asmgen.out("""
ldy #0
lda ($sourceName),y
""")
when(target.register){
Register.A -> {}
Register.X -> asmgen.out(" tax")
Register.Y -> asmgen.out(" tay")
}
}
targetIdent!=null -> {
val targetName = asmgen.asmIdentifierName(targetIdent)
asmgen.out("""
ldy #0
lda ($sourceName),y
sta $targetName
""")
}
target.memoryAddress!=null -> {
asmgen.out(" ldy $sourceName")
storeRegisterInMemoryAddress(Register.Y, target.memoryAddress)
}
targetArrayIdx!=null -> {
val index = targetArrayIdx.arrayspec.index
val targetName = asmgen.asmIdentifierName(targetArrayIdx.identifier)
TODO("assign memory byte $sourceName to array $targetName [ $index ]")
}
else -> TODO("assign memory byte $target")
}
}
}
private fun popAndWriteArrayvalueWithIndexA(arrayDt: DataType, variablename: String) {
when (arrayDt) {
DataType.STR, DataType.ARRAY_UB, DataType.ARRAY_B ->
asmgen.out(" tay | inx | lda $ESTACK_LO_HEX,x | sta $variablename,y")
DataType.ARRAY_UW, DataType.ARRAY_W ->
asmgen.out(" asl a | tay | inx | lda $ESTACK_LO_HEX,x | sta $variablename,y | lda $ESTACK_HI_HEX,x | sta $variablename+1,y")
DataType.ARRAY_F ->
// index * 5 is done in the subroutine that's called
asmgen.out("""
sta $ESTACK_LO_HEX,x
dex
lda #<$variablename
ldy #>$variablename
jsr c64flt.pop_float_to_indexed_var
""")
else ->
throw AssemblyError("weird array type")
}
}
}

612
compiler/src/prog8/compiler/target/c64/codegen/BuiltinFunctionsAsmGen.kt Normal file
View File

@ -0,0 +1,612 @@
package prog8.compiler.target.c64.codegen
import prog8.ast.IFunctionCall
import prog8.ast.Program
import prog8.ast.base.ByteDatatypes
import prog8.ast.base.DataType
import prog8.ast.base.Register
import prog8.ast.base.WordDatatypes
import prog8.ast.expressions.*
import prog8.ast.statements.AssignTarget
import prog8.ast.statements.FunctionCallStatement
import prog8.compiler.target.c64.C64MachineDefinition.C64Zeropage
import prog8.compiler.target.c64.C64MachineDefinition.ESTACK_HI_HEX
import prog8.compiler.target.c64.C64MachineDefinition.ESTACK_HI_PLUS1_HEX
import prog8.compiler.target.c64.C64MachineDefinition.ESTACK_LO_HEX
import prog8.compiler.target.c64.C64MachineDefinition.ESTACK_LO_PLUS1_HEX
import prog8.compiler.toHex
import prog8.compiler.AssemblyError
import prog8.functions.FunctionSignature
internal class BuiltinFunctionsAsmGen(private val program: Program, private val asmgen: AsmGen) {
internal fun translateFunctioncallExpression(fcall: FunctionCall, func: FunctionSignature) {
translateFunctioncall(fcall, func, false)
}
internal fun translateFunctioncallStatement(fcall: FunctionCallStatement, func: FunctionSignature) {
translateFunctioncall(fcall, func, true)
}
private fun translateFunctioncall(fcall: IFunctionCall, func: FunctionSignature, discardResult: Boolean) {
val functionName = fcall.target.nameInSource.last()
if (discardResult) {
if (func.pure)
return // can just ignore the whole function call altogether
else if (func.returntype != null)
throw AssemblyError("discarding result of non-pure function $fcall")
}
when (functionName) {
"msb" -> {
val arg = fcall.args.single()
if (arg.inferType(program).typeOrElse(DataType.STRUCT) !in WordDatatypes)
throw AssemblyError("msb required word argument")
if (arg is NumericLiteralValue)
throw AssemblyError("should have been const-folded")
if (arg is IdentifierReference) {
val sourceName = asmgen.asmIdentifierName(arg)
asmgen.out(" lda $sourceName+1 | sta $ESTACK_LO_HEX,x | dex")
} else {
asmgen.translateExpression(arg)
asmgen.out(" lda $ESTACK_HI_PLUS1_HEX,x | sta $ESTACK_LO_PLUS1_HEX,x")
}
}
"mkword" -> {
translateFunctionArguments(fcall.args, func)
asmgen.out(" inx | lda $ESTACK_LO_HEX,x | sta $ESTACK_HI_PLUS1_HEX,x")
}
"abs" -> {
translateFunctionArguments(fcall.args, func)
val dt = fcall.args.single().inferType(program)
when (dt.typeOrElse(DataType.STRUCT)) {
in ByteDatatypes -> asmgen.out(" jsr prog8_lib.abs_b")
in WordDatatypes -> asmgen.out(" jsr prog8_lib.abs_w")
DataType.FLOAT -> asmgen.out(" jsr c64flt.abs_f")
else -> throw AssemblyError("weird type")
}
}
"swap" -> {
val first = fcall.args[0]
val second = fcall.args[1]
asmgen.translateExpression(first)
asmgen.translateExpression(second)
// pop in reverse order
val firstTarget = AssignTarget.fromExpr(first)
val secondTarget = AssignTarget.fromExpr(second)
asmgen.assignFromEvalResult(firstTarget)
asmgen.assignFromEvalResult(secondTarget)
}
"strlen" -> {
outputPushAddressOfIdentifier(fcall.args[0])
asmgen.out(" jsr prog8_lib.func_strlen")
}
"min", "max", "sum" -> {
outputPushAddressAndLenghtOfArray(fcall.args[0])
val dt = fcall.args.single().inferType(program)
when (dt.typeOrElse(DataType.STRUCT)) {
DataType.ARRAY_UB, DataType.STR -> asmgen.out(" jsr prog8_lib.func_${functionName}_ub")
DataType.ARRAY_B -> asmgen.out(" jsr prog8_lib.func_${functionName}_b")
DataType.ARRAY_UW -> asmgen.out(" jsr prog8_lib.func_${functionName}_uw")
DataType.ARRAY_W -> asmgen.out(" jsr prog8_lib.func_${functionName}_w")
DataType.ARRAY_F -> asmgen.out(" jsr c64flt.func_${functionName}_f")
else -> throw AssemblyError("weird type $dt")
}
}
"any", "all" -> {
outputPushAddressAndLenghtOfArray(fcall.args[0])
val dt = fcall.args.single().inferType(program)
when (dt.typeOrElse(DataType.STRUCT)) {
DataType.ARRAY_B, DataType.ARRAY_UB, DataType.STR -> asmgen.out(" jsr prog8_lib.func_${functionName}_b")
DataType.ARRAY_UW, DataType.ARRAY_W -> asmgen.out(" jsr prog8_lib.func_${functionName}_w")
DataType.ARRAY_F -> asmgen.out(" jsr c64flt.func_${functionName}_f")
else -> throw AssemblyError("weird type $dt")
}
}
"sgn" -> {
translateFunctionArguments(fcall.args, func)
val dt = fcall.args.single().inferType(program)
when(dt.typeOrElse(DataType.STRUCT)) {
DataType.UBYTE -> asmgen.out(" jsr math.sign_ub")
DataType.BYTE -> asmgen.out(" jsr math.sign_b")
DataType.UWORD -> asmgen.out(" jsr math.sign_uw")
DataType.WORD -> asmgen.out(" jsr math.sign_w")
DataType.FLOAT -> asmgen.out(" jsr c64flt.sign_f")
else -> throw AssemblyError("weird type $dt")
}
}
"sin", "cos", "tan", "atan",
"ln", "log2", "sqrt", "rad",
"deg", "round", "floor", "ceil",
"rdnf" -> {
translateFunctionArguments(fcall.args, func)
asmgen.out(" jsr c64flt.func_$functionName")
}
"lsl" -> {
// in-place
val what = fcall.args.single()
val dt = what.inferType(program)
when (dt.typeOrElse(DataType.STRUCT)) {
in ByteDatatypes -> {
when (what) {
is RegisterExpr -> {
when (what.register) {
Register.A -> asmgen.out(" asl a")
Register.X -> asmgen.out(" txa | asl a | tax")
Register.Y -> asmgen.out(" tya | asl a | tay")
}
}
is IdentifierReference -> asmgen.out(" asl ${asmgen.asmIdentifierName(what)}")
is DirectMemoryRead -> {
if (what.addressExpression is NumericLiteralValue) {
val number = (what.addressExpression as NumericLiteralValue).number
asmgen.out(" asl ${number.toHex()}")
} else {
asmgen.translateExpression(what.addressExpression)
asmgen.out("""
inx
lda $ESTACK_LO_HEX,x
sta (+) + 1
lda $ESTACK_HI_HEX,x
sta (+) + 2
+ asl 0 ; modified
""")
}
}
is ArrayIndexedExpression -> {
asmgen.translateExpression(what.identifier)
asmgen.translateExpression(what.arrayspec.index)
asmgen.out(" jsr prog8_lib.lsl_array_b")
}
else -> throw AssemblyError("weird type")
}
}
in WordDatatypes -> {
when (what) {
is ArrayIndexedExpression -> {
asmgen.translateExpression(what.identifier)
asmgen.translateExpression(what.arrayspec.index)
asmgen.out(" jsr prog8_lib.lsl_array_w")
}
is IdentifierReference -> {
val variable = asmgen.asmIdentifierName(what)
asmgen.out(" asl $variable | rol $variable+1")
}
else -> throw AssemblyError("weird type")
}
}
else -> throw AssemblyError("weird type")
}
}
"lsr" -> {
// in-place
val what = fcall.args.single()
val dt = what.inferType(program)
when (dt.typeOrElse(DataType.STRUCT)) {
DataType.UBYTE -> {
when (what) {
is RegisterExpr -> {
when (what.register) {
Register.A -> asmgen.out(" lsr a")
Register.X -> asmgen.out(" txa | lsr a | tax")
Register.Y -> asmgen.out(" tya | lsr a | tay")
}
}
is IdentifierReference -> asmgen.out(" lsr ${asmgen.asmIdentifierName(what)}")
is DirectMemoryRead -> {
if (what.addressExpression is NumericLiteralValue) {
val number = (what.addressExpression as NumericLiteralValue).number
asmgen.out(" lsr ${number.toHex()}")
} else {
asmgen.translateExpression(what.addressExpression)
asmgen.out("""
inx
lda $ESTACK_LO_HEX,x
sta (+) + 1
lda $ESTACK_HI_HEX,x
sta (+) + 2
+ lsr 0 ; modified
""")
}
}
is ArrayIndexedExpression -> {
asmgen.translateExpression(what.identifier)
asmgen.translateExpression(what.arrayspec.index)
asmgen.out(" jsr prog8_lib.lsr_array_ub")
}
else -> throw AssemblyError("weird type")
}
}
DataType.BYTE -> {
when (what) {
is ArrayIndexedExpression -> {
asmgen.translateExpression(what.identifier)
asmgen.translateExpression(what.arrayspec.index)
asmgen.out(" jsr prog8_lib.lsr_array_b")
}
is IdentifierReference -> {
val variable = asmgen.asmIdentifierName(what)
asmgen.out(" lda $variable | asl a | ror $variable")
}
else -> throw AssemblyError("weird type")
}
}
DataType.UWORD -> {
when (what) {
is ArrayIndexedExpression -> {
asmgen.translateExpression(what.identifier)
asmgen.translateExpression(what.arrayspec.index)
asmgen.out(" jsr prog8_lib.lsr_array_uw")
}
is IdentifierReference -> {
val variable = asmgen.asmIdentifierName(what)
asmgen.out(" lsr $variable+1 | ror $variable")
}
else -> throw AssemblyError("weird type")
}
}
DataType.WORD -> {
when (what) {
is ArrayIndexedExpression -> {
asmgen.translateExpression(what.identifier)
asmgen.translateExpression(what.arrayspec.index)
asmgen.out(" jsr prog8_lib.lsr_array_w")
}
is IdentifierReference -> {
val variable = asmgen.asmIdentifierName(what)
asmgen.out(" lda $variable+1 | asl a | ror $variable+1 | ror $variable")
}
else -> throw AssemblyError("weird type")
}
}
else -> throw AssemblyError("weird type")
}
}
"rol" -> {
// in-place
val what = fcall.args.single()
val dt = what.inferType(program)
when (dt.typeOrElse(DataType.STRUCT)) {
DataType.UBYTE -> {
when(what) {
is ArrayIndexedExpression -> {
asmgen.translateExpression(what.identifier)
asmgen.translateExpression(what.arrayspec.index)
asmgen.out(" jsr prog8_lib.rol_array_ub")
}
is DirectMemoryRead -> {
if (what.addressExpression is NumericLiteralValue) {
val number = (what.addressExpression as NumericLiteralValue).number
asmgen.out(" rol ${number.toHex()}")
} else {
asmgen.translateExpression(what.addressExpression)
asmgen.out("""
inx
lda $ESTACK_LO_HEX,x
sta (+) + 1
lda $ESTACK_HI_HEX,x
sta (+) + 2
+ rol 0 ; modified
""")
}
}
is RegisterExpr -> {
when(what.register) {
Register.A -> asmgen.out(" rol a")
Register.X -> asmgen.out(" txa | rol a | tax")
Register.Y -> asmgen.out(" tya | rol a | tay")
}
}
is IdentifierReference -> {
val variable = asmgen.asmIdentifierName(what)
asmgen.out(" rol $variable")
}
else -> throw AssemblyError("weird type")
}
}
DataType.UWORD -> {
when(what) {
is ArrayIndexedExpression -> {
asmgen.translateExpression(what.identifier)
asmgen.translateExpression(what.arrayspec.index)
asmgen.out(" jsr prog8_lib.rol_array_uw")
}
is IdentifierReference -> {
val variable = asmgen.asmIdentifierName(what)
asmgen.out(" rol $variable | rol $variable+1")
}
else -> throw AssemblyError("weird type")
}
}
else -> throw AssemblyError("weird type")
}
}
"rol2" -> {
// in-place
val what = fcall.args.single()
val dt = what.inferType(program)
when (dt.typeOrElse(DataType.STRUCT)) {
DataType.UBYTE -> {
when(what) {
is ArrayIndexedExpression -> {
asmgen.translateExpression(what.identifier)
asmgen.translateExpression(what.arrayspec.index)
asmgen.out(" jsr prog8_lib.rol2_array_ub")
}
is DirectMemoryRead -> {
if (what.addressExpression is NumericLiteralValue) {
val number = (what.addressExpression as NumericLiteralValue).number
asmgen.out(" lda ${number.toHex()} | cmp #\$80 | rol a | sta ${number.toHex()}")
} else {
asmgen.translateExpression(what.addressExpression)
asmgen.out(" jsr prog8_lib.rol2_mem_ub")
}
}
is RegisterExpr -> {
when(what.register) {
Register.A -> asmgen.out(" cmp #\$80 | rol a ")
Register.X -> asmgen.out(" txa | cmp #\$80 | rol a | tax")
Register.Y -> asmgen.out(" tya | cmp #\$80 | rol a | tay")
}
}
is IdentifierReference -> {
val variable = asmgen.asmIdentifierName(what)
asmgen.out(" lda $variable | cmp #\$80 | rol a | sta $variable")
}
else -> throw AssemblyError("weird type")
}
}
DataType.UWORD -> {
when(what) {
is ArrayIndexedExpression -> {
asmgen.translateExpression(what.identifier)
asmgen.translateExpression(what.arrayspec.index)
asmgen.out(" jsr prog8_lib.rol2_array_uw")
}
is IdentifierReference -> {
val variable = asmgen.asmIdentifierName(what)
asmgen.out(" asl $variable | rol $variable+1 | bcc + | inc $variable |+ ")
}
else -> throw AssemblyError("weird type")
}
}
else -> throw AssemblyError("weird type")
}
}
"ror" -> {
// in-place
val what = fcall.args.single()
val dt = what.inferType(program)
when (dt.typeOrElse(DataType.STRUCT)) {
DataType.UBYTE -> {
when(what) {
is ArrayIndexedExpression -> {
asmgen.translateExpression(what.identifier)
asmgen.translateExpression(what.arrayspec.index)
asmgen.out(" jsr prog8_lib.ror_array_ub")
}
is DirectMemoryRead -> {
if (what.addressExpression is NumericLiteralValue) {
val number = (what.addressExpression as NumericLiteralValue).number
asmgen.out(" ror ${number.toHex()}")
} else {
asmgen.translateExpression(what.addressExpression)
asmgen.out("""
inx
lda $ESTACK_LO_HEX,x
sta (+) + 1
lda $ESTACK_HI_HEX,x
sta (+) + 2
+ ror 0 ; modified
""") }
}
is RegisterExpr -> {
when(what.register) {
Register.A -> asmgen.out(" ror a")
Register.X -> asmgen.out(" txa | ror a | tax")
Register.Y -> asmgen.out(" tya | ror a | tay")
}
}
is IdentifierReference -> {
val variable = asmgen.asmIdentifierName(what)
asmgen.out(" ror $variable")
}
else -> throw AssemblyError("weird type")
}
}
DataType.UWORD -> {
when(what) {
is ArrayIndexedExpression -> {
asmgen.translateExpression(what.identifier)
asmgen.translateExpression(what.arrayspec.index)
asmgen.out(" jsr prog8_lib.ror_array_uw")
}
is IdentifierReference -> {
val variable = asmgen.asmIdentifierName(what)
asmgen.out(" ror $variable+1 | ror $variable")
}
else -> throw AssemblyError("weird type")
}
}
else -> throw AssemblyError("weird type")
}
}
"ror2" -> {
// in-place
val what = fcall.args.single()
val dt = what.inferType(program)
when (dt.typeOrElse(DataType.STRUCT)) {
DataType.UBYTE -> {
when(what) {
is ArrayIndexedExpression -> {
asmgen.translateExpression(what.identifier)
asmgen.translateExpression(what.arrayspec.index)
asmgen.out(" jsr prog8_lib.ror2_array_ub")
}
is DirectMemoryRead -> {
if (what.addressExpression is NumericLiteralValue) {
val number = (what.addressExpression as NumericLiteralValue).number
asmgen.out(" lda ${number.toHex()} | lsr a | bcc + | ora #\$80 |+ | sta ${number.toHex()}")
} else {
asmgen.translateExpression(what.addressExpression)
asmgen.out(" jsr prog8_lib.ror2_mem_ub")
}
}
is RegisterExpr -> {
when(what.register) {
Register.A -> asmgen.out(" lsr a | bcc + | ora #\$80 |+ ")
Register.X -> asmgen.out(" txa | lsr a | bcc + | ora #\$80 |+ tax ")
Register.Y -> asmgen.out(" tya | lsr a | bcc + | ora #\$80 |+ tay ")
}
}
is IdentifierReference -> {
val variable = asmgen.asmIdentifierName(what)
asmgen.out(" lda $variable | lsr a | bcc + | ora #\$80 |+ | sta $variable")
}
else -> throw AssemblyError("weird type")
}
}
DataType.UWORD -> {
when(what) {
is ArrayIndexedExpression -> {
asmgen.translateExpression(what.identifier)
asmgen.translateExpression(what.arrayspec.index)
asmgen.out(" jsr prog8_lib.ror2_array_uw")
}
is IdentifierReference -> {
val variable = asmgen.asmIdentifierName(what)
asmgen.out(" lsr $variable+1 | ror $variable | bcc + | lda $variable+1 | ora #\$80 | sta $variable+1 |+ ")
}
else -> throw AssemblyError("weird type")
}
}
else -> throw AssemblyError("weird type")
}
}
"sort" -> {
val variable = fcall.args.single()
if(variable is IdentifierReference) {
val decl = variable.targetVarDecl(program.namespace)!!
val varName = asmgen.asmIdentifierName(variable)
val numElements = decl.arraysize!!.size()
when(decl.datatype) {
DataType.ARRAY_UB, DataType.ARRAY_B -> {
asmgen.out("""
lda #<$varName
ldy #>$varName
sta ${C64Zeropage.SCRATCH_W1}
sty ${C64Zeropage.SCRATCH_W1+1}
lda #$numElements
sta ${C64Zeropage.SCRATCH_B1}
""")
asmgen.out(if(decl.datatype==DataType.ARRAY_UB) " jsr prog8_lib.sort_ub" else " jsr prog8_lib.sort_b")
}
DataType.ARRAY_UW, DataType.ARRAY_W -> {
asmgen.out("""
lda #<$varName
ldy #>$varName
sta ${C64Zeropage.SCRATCH_W1}
sty ${C64Zeropage.SCRATCH_W1+1}
lda #$numElements
sta ${C64Zeropage.SCRATCH_B1}
""")
asmgen.out(if(decl.datatype==DataType.ARRAY_UW) " jsr prog8_lib.sort_uw" else " jsr prog8_lib.sort_w")
}
DataType.ARRAY_F -> throw AssemblyError("sorting of floating point array is not supported")
else -> throw AssemblyError("weird type")
}
}
else
throw AssemblyError("weird type")
}
"reverse" -> {
val variable = fcall.args.single()
if (variable is IdentifierReference) {
val decl = variable.targetVarDecl(program.namespace)!!
val varName = asmgen.asmIdentifierName(variable)
val numElements = decl.arraysize!!.size()
when (decl.datatype) {
DataType.ARRAY_UB, DataType.ARRAY_B -> {
asmgen.out("""
lda #<$varName
ldy #>$varName
sta ${C64Zeropage.SCRATCH_W1}
sty ${C64Zeropage.SCRATCH_W1 + 1}
lda #$numElements
jsr prog8_lib.reverse_b
""")
}
DataType.ARRAY_UW, DataType.ARRAY_W -> {
asmgen.out("""
lda #<$varName
ldy #>$varName
sta ${C64Zeropage.SCRATCH_W1}
sty ${C64Zeropage.SCRATCH_W1 + 1}
lda #$numElements
jsr prog8_lib.reverse_w
""")
}
DataType.ARRAY_F -> {
asmgen.out("""
lda #<$varName
ldy #>$varName
sta ${C64Zeropage.SCRATCH_W1}
sty ${C64Zeropage.SCRATCH_W1 + 1}
lda #$numElements
jsr prog8_lib.reverse_f
""")
}
else -> throw AssemblyError("weird type")
}
}
}
"rsave" -> {
// save cpu status flag and all registers A, X, Y.
// see http://6502.org/tutorials/register_preservation.html
asmgen.out(" php | sta ${C64Zeropage.SCRATCH_REG} | pha | txa | pha | tya | pha | lda ${C64Zeropage.SCRATCH_REG}")
}
"rrestore" -> {
// restore all registers and cpu status flag
asmgen.out(" pla | tay | pla | tax | pla | plp")
}
else -> {
translateFunctionArguments(fcall.args, func)
asmgen.out(" jsr prog8_lib.func_$functionName")
}
}
}
private fun outputPushAddressAndLenghtOfArray(arg: Expression) {
arg as IdentifierReference
val identifierName = asmgen.asmIdentifierName(arg)
val size = arg.targetVarDecl(program.namespace)!!.arraysize!!.size()!!
asmgen.out("""
lda #<$identifierName
sta $ESTACK_LO_HEX,x
lda #>$identifierName
sta $ESTACK_HI_HEX,x
dex
lda #$size
sta $ESTACK_LO_HEX,x
dex
""")
}
private fun outputPushAddressOfIdentifier(arg: Expression) {
val identifierName = asmgen.asmIdentifierName(arg as IdentifierReference)
asmgen.out("""
lda #<$identifierName
sta $ESTACK_LO_HEX,x
lda #>$identifierName
sta $ESTACK_HI_HEX,x
dex
""")
}
private fun translateFunctionArguments(args: MutableList<Expression>, signature: FunctionSignature) {
args.forEach {
asmgen.translateExpression(it)
}
}
}

438
compiler/src/prog8/compiler/target/c64/codegen/ExpressionsAsmGen.kt Normal file
View File

@ -0,0 +1,438 @@
package prog8.compiler.target.c64.codegen
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.compiler.toHex
import prog8.compiler.AssemblyError
import prog8.compiler.target.c64.C64MachineDefinition.ESTACK_HI_HEX
import prog8.compiler.target.c64.C64MachineDefinition.ESTACK_HI_PLUS1_HEX
import prog8.compiler.target.c64.C64MachineDefinition.ESTACK_LO_HEX
import prog8.compiler.target.c64.C64MachineDefinition.ESTACK_LO_PLUS1_HEX
import prog8.compiler.target.c64.C64MachineDefinition.ESTACK_LO_PLUS2_HEX
import prog8.functions.BuiltinFunctions
import kotlin.math.absoluteValue
internal class ExpressionsAsmGen(private val program: Program, private val asmgen: AsmGen) {
internal fun translateExpression(expression: Expression) {
when(expression) {
is PrefixExpression -> translateExpression(expression)
is BinaryExpression -> translateExpression(expression)
is ArrayIndexedExpression -> translatePushFromArray(expression)
is TypecastExpression -> translateExpression(expression)
is AddressOf -> translateExpression(expression)
is DirectMemoryRead -> translateExpression(expression)
is NumericLiteralValue -> translateExpression(expression)
is RegisterExpr -> translateExpression(expression)
is IdentifierReference -> translateExpression(expression)
is FunctionCall -> translateExpression(expression)
is ArrayLiteralValue, is StringLiteralValue -> TODO("string/array/struct assignment?")
is StructLiteralValue -> throw AssemblyError("struct literal value assignment should have been flattened")
is RangeExpr -> throw AssemblyError("range expression should have been changed into array values")
}
}
private fun translateExpression(expression: FunctionCall) {
val functionName = expression.target.nameInSource.last()
val builtinFunc = BuiltinFunctions[functionName]
if (builtinFunc != null) {
asmgen.translateFunctioncallExpression(expression, builtinFunc)
} else {
asmgen.translateFunctionCall(expression)
val sub = expression.target.targetSubroutine(program.namespace)!!
val returns = sub.returntypes.zip(sub.asmReturnvaluesRegisters)
for ((_, reg) in returns) {
if (!reg.stack) {
// result value in cpu or status registers, put it on the stack
if (reg.registerOrPair != null) {
when (reg.registerOrPair) {
RegisterOrPair.A -> asmgen.out(" sta $ESTACK_LO_HEX,x | dex")
RegisterOrPair.Y -> asmgen.out(" tya | sta $ESTACK_LO_HEX,x | dex")
RegisterOrPair.AY -> asmgen.out(" sta $ESTACK_LO_HEX,x | tya | sta $ESTACK_HI_HEX,x | dex")
RegisterOrPair.X, RegisterOrPair.AX, RegisterOrPair.XY -> throw AssemblyError("can't push X register - use a variable")
}
}
// return value from a statusregister is not put on the stack, it should be acted on via a conditional branch such as if_cc
}
}
}
}
private fun translateExpression(expr: TypecastExpression) {
translateExpression(expr.expression)
when(expr.expression.inferType(program).typeOrElse(DataType.STRUCT)) {
DataType.UBYTE -> {
when(expr.type) {
DataType.UBYTE, DataType.BYTE -> {}
DataType.UWORD, DataType.WORD -> asmgen.out(" lda #0 | sta $ESTACK_HI_PLUS1_HEX,x")
DataType.FLOAT -> asmgen.out(" jsr c64flt.stack_ub2float")
in PassByReferenceDatatypes -> throw AssemblyError("cannot cast to a pass-by-reference datatype")
else -> throw AssemblyError("weird type")
}
}
DataType.BYTE -> {
when(expr.type) {
DataType.UBYTE, DataType.BYTE -> {}
DataType.UWORD, DataType.WORD -> asmgen.out(" lda $ESTACK_LO_PLUS1_HEX,x | ${asmgen.signExtendAtoMsb("$ESTACK_HI_PLUS1_HEX,x")}")
DataType.FLOAT -> asmgen.out(" jsr c64flt.stack_b2float")
in PassByReferenceDatatypes -> throw AssemblyError("cannot cast to a pass-by-reference datatype")
else -> throw AssemblyError("weird type")
}
}
DataType.UWORD -> {
when(expr.type) {
DataType.BYTE, DataType.UBYTE -> {}
DataType.WORD, DataType.UWORD -> {}
DataType.FLOAT -> asmgen.out(" jsr c64flt.stack_uw2float")
in PassByReferenceDatatypes -> throw AssemblyError("cannot cast to a pass-by-reference datatype")
else -> throw AssemblyError("weird type")
}
}
DataType.WORD -> {
when(expr.type) {
DataType.BYTE, DataType.UBYTE -> {}
DataType.WORD, DataType.UWORD -> {}
DataType.FLOAT -> asmgen.out(" jsr c64flt.stack_w2float")
in PassByReferenceDatatypes -> throw AssemblyError("cannot cast to a pass-by-reference datatype")
else -> throw AssemblyError("weird type")
}
}
DataType.FLOAT -> {
when(expr.type) {
DataType.UBYTE -> asmgen.out(" jsr c64flt.stack_float2uw")
DataType.BYTE -> asmgen.out(" jsr c64flt.stack_float2w")
DataType.UWORD -> asmgen.out(" jsr c64flt.stack_float2uw")
DataType.WORD -> asmgen.out(" jsr c64flt.stack_float2w")
DataType.FLOAT -> {}
in PassByReferenceDatatypes -> throw AssemblyError("cannot cast to a pass-by-reference datatype")
else -> throw AssemblyError("weird type")
}
}
in PassByReferenceDatatypes -> throw AssemblyError("cannot case a pass-by-reference datatypes into something else")
else -> throw AssemblyError("weird type")
}
}
private fun translateExpression(expr: AddressOf) {
val name = asmgen.asmIdentifierName(expr.identifier)
asmgen.out(" lda #<$name | sta $ESTACK_LO_HEX,x | lda #>$name | sta $ESTACK_HI_HEX,x | dex")
}
private fun translateExpression(expr: DirectMemoryRead) {
when(expr.addressExpression) {
is NumericLiteralValue -> {
val address = (expr.addressExpression as NumericLiteralValue).number.toInt()
asmgen.out(" lda ${address.toHex()} | sta $ESTACK_LO_HEX,x | dex")
}
is IdentifierReference -> {
val sourceName = asmgen.asmIdentifierName(expr.addressExpression as IdentifierReference)
asmgen.out(" lda $sourceName | sta $ESTACK_LO_HEX,x | dex")
}
else -> {
translateExpression(expr.addressExpression)
asmgen.out(" jsr prog8_lib.read_byte_from_address")
asmgen.out(" sta $ESTACK_LO_PLUS1_HEX,x")
}
}
}
private fun translateExpression(expr: NumericLiteralValue) {
when(expr.type) {
DataType.UBYTE, DataType.BYTE -> asmgen.out(" lda #${expr.number.toHex()} | sta $ESTACK_LO_HEX,x | dex")
DataType.UWORD, DataType.WORD -> asmgen.out("""
lda #<${expr.number.toHex()}
sta $ESTACK_LO_HEX,x
lda #>${expr.number.toHex()}
sta $ESTACK_HI_HEX,x
dex
""")
DataType.FLOAT -> {
val floatConst = asmgen.getFloatConst(expr.number.toDouble())
asmgen.out(" lda #<$floatConst | ldy #>$floatConst | jsr c64flt.push_float")
}
else -> throw AssemblyError("weird type")
}
}
private fun translateExpression(expr: RegisterExpr) {
when(expr.register) {
Register.A -> asmgen.out(" sta $ESTACK_LO_HEX,x | dex")
Register.X -> throw AssemblyError("cannot push X - use a variable instead of the X register")
Register.Y -> asmgen.out(" tya | sta $ESTACK_LO_HEX,x | dex")
}
}
private fun translateExpression(expr: IdentifierReference) {
val varname = asmgen.asmIdentifierName(expr)
when(expr.inferType(program).typeOrElse(DataType.STRUCT)) {
DataType.UBYTE, DataType.BYTE -> {
asmgen.out(" lda $varname | sta $ESTACK_LO_HEX,x | dex")
}
DataType.UWORD, DataType.WORD -> {
asmgen.out(" lda $varname | sta $ESTACK_LO_HEX,x | lda $varname+1 | sta $ESTACK_HI_HEX,x | dex")
}
DataType.FLOAT -> {
asmgen.out(" lda #<$varname | ldy #>$varname| jsr c64flt.push_float")
}
in IterableDatatypes -> {
asmgen.out(" lda #<$varname | sta $ESTACK_LO_HEX,x | lda #>$varname | sta $ESTACK_HI_HEX,x | dex")
}
else -> throw AssemblyError("stack push weird variable type $expr")
}
}
private val optimizedByteMultiplications = setOf(3,5,6,7,9,10,11,12,13,14,15,20,25,40)
private val optimizedWordMultiplications = setOf(3,5,6,7,9,10,12,15,20,25,40)
private val powersOfTwo = setOf(0,1,2,4,8,16,32,64,128,256)
private fun translateExpression(expr: BinaryExpression) {
val leftIDt = expr.left.inferType(program)
val rightIDt = expr.right.inferType(program)
if(!leftIDt.isKnown || !rightIDt.isKnown)
throw AssemblyError("can't infer type of both expression operands")
val leftDt = leftIDt.typeOrElse(DataType.STRUCT)
val rightDt = rightIDt.typeOrElse(DataType.STRUCT)
// see if we can apply some optimized routines
when(expr.operator) {
">>" -> {
// bit-shifts are always by a constant number (for now)
translateExpression(expr.left)
val amount = expr.right.constValue(program)!!.number.toInt()
when (leftDt) {
DataType.UBYTE -> repeat(amount) { asmgen.out(" lsr $ESTACK_LO_PLUS1_HEX,x") }
DataType.BYTE -> repeat(amount) { asmgen.out(" lda $ESTACK_LO_PLUS1_HEX,x | asl a | ror $ESTACK_LO_PLUS1_HEX,x") }
DataType.UWORD -> repeat(amount) { asmgen.out(" lsr $ESTACK_HI_PLUS1_HEX,x | ror $ESTACK_LO_PLUS1_HEX,x") }
DataType.WORD -> repeat(amount) { asmgen.out(" lda $ESTACK_HI_PLUS1_HEX,x | asl a | ror $ESTACK_HI_PLUS1_HEX,x | ror $ESTACK_LO_PLUS1_HEX,x") }
else -> throw AssemblyError("weird type")
}
return
}
"<<" -> {
// bit-shifts are always by a constant number (for now)
translateExpression(expr.left)
val amount = expr.right.constValue(program)!!.number.toInt()
if (leftDt in ByteDatatypes)
repeat(amount) { asmgen.out(" asl $ESTACK_LO_PLUS1_HEX,x") }
else
repeat(amount) { asmgen.out(" asl $ESTACK_LO_PLUS1_HEX,x | rol $ESTACK_HI_PLUS1_HEX,x") }
return
}
"*" -> {
val value = expr.right.constValue(program)
if(value!=null) {
if(rightDt in IntegerDatatypes) {
val amount = value.number.toInt()
if(amount in powersOfTwo)
printWarning("${expr.right.position} multiplication by power of 2 should have been optimized into a left shift instruction: $amount")
when(rightDt) {
DataType.UBYTE -> {
if(amount in optimizedByteMultiplications) {
translateExpression(expr.left)
asmgen.out(" jsr math.mul_byte_$amount")
return
}
}
DataType.BYTE -> {
if(amount in optimizedByteMultiplications) {
translateExpression(expr.left)
asmgen.out(" jsr math.mul_byte_$amount")
return
}
if(amount.absoluteValue in optimizedByteMultiplications) {
translateExpression(expr.left)
asmgen.out(" jsr prog8_lib.neg_b | jsr math.mul_byte_${amount.absoluteValue}")
return
}
}
DataType.UWORD -> {
if(amount in optimizedWordMultiplications) {
translateExpression(expr.left)
asmgen.out(" jsr math.mul_word_$amount")
return
}
}
DataType.WORD -> {
if(amount in optimizedWordMultiplications) {
translateExpression(expr.left)
asmgen.out(" jsr math.mul_word_$amount")
return
}
if(amount.absoluteValue in optimizedWordMultiplications) {
translateExpression(expr.left)
asmgen.out(" jsr prog8_lib.neg_w | jsr math.mul_word_${amount.absoluteValue}")
return
}
}
else -> {}
}
}
}
}
}
// the general, non-optimized cases
translateExpression(expr.left)
translateExpression(expr.right)
if(leftDt!=rightDt)
throw AssemblyError("binary operator ${expr.operator} left/right dt not identical") // is this strictly required always?
when (leftDt) {
in ByteDatatypes -> translateBinaryOperatorBytes(expr.operator, leftDt)
in WordDatatypes -> translateBinaryOperatorWords(expr.operator, leftDt)
DataType.FLOAT -> translateBinaryOperatorFloats(expr.operator)
else -> throw AssemblyError("non-numerical datatype")
}
}
private fun translateExpression(expr: PrefixExpression) {
translateExpression(expr.expression)
val type = expr.inferType(program).typeOrElse(DataType.STRUCT)
when(expr.operator) {
"+" -> {}
"-" -> {
when(type) {
in ByteDatatypes -> asmgen.out(" jsr prog8_lib.neg_b")
in WordDatatypes -> asmgen.out(" jsr prog8_lib.neg_w")
DataType.FLOAT -> asmgen.out(" jsr c64flt.neg_f")
else -> throw AssemblyError("weird type")
}
}
"~" -> {
when(type) {
in ByteDatatypes ->
asmgen.out("""
lda $ESTACK_LO_PLUS1_HEX,x
eor #255
sta $ESTACK_LO_PLUS1_HEX,x
""")
in WordDatatypes -> asmgen.out(" jsr prog8_lib.inv_word")
else -> throw AssemblyError("weird type")
}
}
"not" -> {
when(type) {
in ByteDatatypes -> asmgen.out(" jsr prog8_lib.not_byte")
in WordDatatypes -> asmgen.out(" jsr prog8_lib.not_word")
else -> throw AssemblyError("weird type")
}
}
else -> throw AssemblyError("invalid prefix operator ${expr.operator}")
}
}
private fun translatePushFromArray(arrayExpr: ArrayIndexedExpression) {
// assume *reading* from an array
val index = arrayExpr.arrayspec.index
val arrayDt = arrayExpr.identifier.targetVarDecl(program.namespace)!!.datatype
val arrayVarName = asmgen.asmIdentifierName(arrayExpr.identifier)
if(index is NumericLiteralValue) {
val elementDt = ArrayElementTypes.getValue(arrayDt)
val indexValue = index.number.toInt() * elementDt.memorySize()
when(elementDt) {
in ByteDatatypes -> {
asmgen.out(" lda $arrayVarName+$indexValue | sta $ESTACK_LO_HEX,x | dex")
}
in WordDatatypes -> {
asmgen.out(" lda $arrayVarName+$indexValue | sta $ESTACK_LO_HEX,x | lda $arrayVarName+$indexValue+1 | sta $ESTACK_HI_HEX,x | dex")
}
DataType.FLOAT -> {
asmgen.out(" lda #<$arrayVarName+$indexValue | ldy #>$arrayVarName+$indexValue | jsr c64flt.push_float")
}
else -> throw AssemblyError("weird type")
}
} else {
asmgen.translateArrayIndexIntoA(arrayExpr)
asmgen.readAndPushArrayvalueWithIndexA(arrayDt, arrayExpr.identifier)
}
}
private fun translateBinaryOperatorBytes(operator: String, types: DataType) {
when(operator) {
"**" -> throw AssemblyError("** operator requires floats")
"*" -> asmgen.out(" jsr prog8_lib.mul_byte") // the optimized routines should have been checked earlier
"/" -> asmgen.out(if(types==DataType.UBYTE) " jsr prog8_lib.idiv_ub" else " jsr prog8_lib.idiv_b")
"%" -> {
if(types==DataType.BYTE)
throw AssemblyError("remainder of signed integers is not properly defined/implemented, use unsigned instead")
asmgen.out(" jsr prog8_lib.remainder_ub")
}
"+" -> asmgen.out("""
lda $ESTACK_LO_PLUS2_HEX,x
clc
adc $ESTACK_LO_PLUS1_HEX,x
inx
sta $ESTACK_LO_PLUS1_HEX,x
""")
"-" -> asmgen.out("""
lda $ESTACK_LO_PLUS2_HEX,x
sec
sbc $ESTACK_LO_PLUS1_HEX,x
inx
sta $ESTACK_LO_PLUS1_HEX,x
""")
"<<", ">>" -> throw AssemblyError("bit-shifts not via stack")
"<" -> asmgen.out(if(types==DataType.UBYTE) " jsr prog8_lib.less_ub" else " jsr prog8_lib.less_b")
">" -> asmgen.out(if(types==DataType.UBYTE) " jsr prog8_lib.greater_ub" else " jsr prog8_lib.greater_b")
"<=" -> asmgen.out(if(types==DataType.UBYTE) " jsr prog8_lib.lesseq_ub" else " jsr prog8_lib.lesseq_b")
">=" -> asmgen.out(if(types==DataType.UBYTE) " jsr prog8_lib.greatereq_ub" else " jsr prog8_lib.greatereq_b")
"==" -> asmgen.out(" jsr prog8_lib.equal_b")
"!=" -> asmgen.out(" jsr prog8_lib.notequal_b")
"&" -> asmgen.out(" jsr prog8_lib.bitand_b")
"^" -> asmgen.out(" jsr prog8_lib.bitxor_b")
"|" -> asmgen.out(" jsr prog8_lib.bitor_b")
"and" -> asmgen.out(" jsr prog8_lib.and_b")
"or" -> asmgen.out(" jsr prog8_lib.or_b")
"xor" -> asmgen.out(" jsr prog8_lib.xor_b")
else -> throw AssemblyError("invalid operator $operator")
}
}
private fun translateBinaryOperatorWords(operator: String, types: DataType) {
when(operator) {
"**" -> throw AssemblyError("** operator requires floats")
"*" -> asmgen.out(" jsr prog8_lib.mul_word")
"/" -> asmgen.out(if(types==DataType.UWORD) " jsr prog8_lib.idiv_uw" else " jsr prog8_lib.idiv_w")
"%" -> {
if(types==DataType.WORD)
throw AssemblyError("remainder of signed integers is not properly defined/implemented, use unsigned instead")
asmgen.out(" jsr prog8_lib.remainder_uw")
}
"+" -> asmgen.out(" jsr prog8_lib.add_w")
"-" -> asmgen.out(" jsr prog8_lib.sub_w")
"<<" -> throw AssemblyError("<< should not operate via stack")
">>" -> throw AssemblyError(">> should not operate via stack")
"<" -> asmgen.out(if(types==DataType.UWORD) " jsr prog8_lib.less_uw" else " jsr prog8_lib.less_w")
">" -> asmgen.out(if(types==DataType.UWORD) " jsr prog8_lib.greater_uw" else " jsr prog8_lib.greater_w")
"<=" -> asmgen.out(if(types==DataType.UWORD) " jsr prog8_lib.lesseq_uw" else " jsr prog8_lib.lesseq_w")
">=" -> asmgen.out(if(types==DataType.UWORD) " jsr prog8_lib.greatereq_uw" else " jsr prog8_lib.greatereq_w")
"==" -> asmgen.out(" jsr prog8_lib.equal_w")
"!=" -> asmgen.out(" jsr prog8_lib.notequal_w")
"&" -> asmgen.out(" jsr prog8_lib.bitand_w")
"^" -> asmgen.out(" jsr prog8_lib.bitxor_w")
"|" -> asmgen.out(" jsr prog8_lib.bitor_w")
"and" -> asmgen.out(" jsr prog8_lib.and_w")
"or" -> asmgen.out(" jsr prog8_lib.or_w")
"xor" -> asmgen.out(" jsr prog8_lib.xor_w")
else -> throw AssemblyError("invalid operator $operator")
}
}
private fun translateBinaryOperatorFloats(operator: String) {
when(operator) {
"**" -> asmgen.out(" jsr c64flt.pow_f")
"*" -> asmgen.out(" jsr c64flt.mul_f")
"/" -> asmgen.out(" jsr c64flt.div_f")
"+" -> asmgen.out(" jsr c64flt.add_f")
"-" -> asmgen.out(" jsr c64flt.sub_f")
"<" -> asmgen.out(" jsr c64flt.less_f")
">" -> asmgen.out(" jsr c64flt.greater_f")
"<=" -> asmgen.out(" jsr c64flt.lesseq_f")
">=" -> asmgen.out(" jsr c64flt.greatereq_f")
"==" -> asmgen.out(" jsr c64flt.equal_f")
"!=" -> asmgen.out(" jsr c64flt.notequal_f")
"%", "<<", ">>", "&", "^", "|", "and", "or", "xor" -> throw AssemblyError("requires integer datatype")
else -> throw AssemblyError("invalid operator $operator")
}
}
}

700
compiler/src/prog8/compiler/target/c64/codegen/ForLoopsAsmGen.kt Normal file
View File

@ -0,0 +1,700 @@
package prog8.compiler.target.c64.codegen
import prog8.ast.Program
import prog8.ast.base.DataType
import prog8.ast.base.Register
import prog8.ast.expressions.IdentifierReference
import prog8.ast.expressions.RangeExpr
import prog8.ast.statements.AssignTarget
import prog8.ast.statements.Assignment
import prog8.ast.statements.ForLoop
import prog8.compiler.target.c64.C64MachineDefinition.ESTACK_LO_HEX
import prog8.compiler.target.c64.C64MachineDefinition.ESTACK_LO_PLUS1_HEX
import prog8.compiler.target.c64.C64MachineDefinition.ESTACK_HI_PLUS1_HEX
import prog8.compiler.toHex
import prog8.compiler.AssemblyError
import kotlin.math.absoluteValue
// todo choose more efficient comparisons to avoid needless lda's
// todo optimize common case step == 2 / -2
internal class ForLoopsAsmGen(private val program: Program, private val asmgen: AsmGen) {
internal fun translate(stmt: ForLoop) {
val iterableDt = stmt.iterable.inferType(program)
if(!iterableDt.isKnown)
throw AssemblyError("can't determine iterable dt")
when(stmt.iterable) {
is RangeExpr -> {
val range = (stmt.iterable as RangeExpr).toConstantIntegerRange()
if(range==null) {
translateForOverNonconstRange(stmt, iterableDt.typeOrElse(DataType.STRUCT), stmt.iterable as RangeExpr)
} else {
translateForOverConstRange(stmt, iterableDt.typeOrElse(DataType.STRUCT), range)
}
}
is IdentifierReference -> {
translateForOverIterableVar(stmt, iterableDt.typeOrElse(DataType.STRUCT), stmt.iterable as IdentifierReference)
}
else -> throw AssemblyError("can't iterate over ${stmt.iterable}")
}
}
private fun translateForOverNonconstRange(stmt: ForLoop, iterableDt: DataType, range: RangeExpr) {
val loopLabel = asmgen.makeLabel("for_loop")
val endLabel = asmgen.makeLabel("for_end")
val continueLabel = asmgen.makeLabel("for_continue")
asmgen.loopEndLabels.push(endLabel)
asmgen.loopContinueLabels.push(continueLabel)
val stepsize=range.step.constValue(program)!!.number.toInt()
when(iterableDt) {
DataType.ARRAY_B, DataType.ARRAY_UB -> {
if (stepsize==1 || stepsize==-1) {
// bytes, step 1 or -1
val incdec = if(stepsize==1) "inc" else "dec"
if (stmt.loopRegister != null) {
// loop register over range
if(stmt.loopRegister!= Register.A)
throw AssemblyError("can only use A")
asmgen.translateExpression(range.to)
asmgen.translateExpression(range.from)
asmgen.out("""
inx
lda ${ESTACK_LO_HEX},x
sta $loopLabel+1
$loopLabel lda #0 ; modified""")
asmgen.translate(stmt.body)
asmgen.out("""
$continueLabel lda $loopLabel+1
cmp $ESTACK_LO_PLUS1_HEX,x
beq $endLabel
$incdec $loopLabel+1
jmp $loopLabel
$endLabel inx""")
} else {
// loop over byte range via loopvar
val varname = asmgen.asmIdentifierName(stmt.loopVar!!)
asmgen.translateExpression(range.to)
asmgen.translateExpression(range.from)
asmgen.out("""
inx
lda ${ESTACK_LO_HEX},x
sta $varname
$loopLabel""")
asmgen.translate(stmt.body)
asmgen.out("""
$continueLabel lda $varname
cmp $ESTACK_LO_PLUS1_HEX,x
beq $endLabel
$incdec $varname
jmp $loopLabel
$endLabel inx""")
}
}
else {
// bytes, step >= 2 or <= -2
if (stmt.loopRegister != null) {
// loop register over range
if(stmt.loopRegister!= Register.A)
throw AssemblyError("can only use A")
asmgen.translateExpression(range.to)
asmgen.translateExpression(range.from)
asmgen.out("""
inx
lda ${ESTACK_LO_HEX},x
sta $loopLabel+1
$loopLabel lda #0 ; modified""")
asmgen.translate(stmt.body)
asmgen.out("""
$continueLabel lda $loopLabel+1""")
if(stepsize>0) {
asmgen.out("""
clc
adc #$stepsize
sta $loopLabel+1
cmp $ESTACK_LO_PLUS1_HEX,x
bcc $loopLabel
beq $loopLabel""")
} else {
asmgen.out("""
sec
sbc #${stepsize.absoluteValue}
sta $loopLabel+1
cmp $ESTACK_LO_PLUS1_HEX,x
bcs $loopLabel""")
}
asmgen.out("""
$endLabel inx""")
} else {
// loop over byte range via loopvar
val varname = asmgen.asmIdentifierName(stmt.loopVar!!)
asmgen.translateExpression(range.to)
asmgen.translateExpression(range.from)
asmgen.out("""
inx
lda ${ESTACK_LO_HEX},x
sta $varname
$loopLabel""")
asmgen.translate(stmt.body)
asmgen.out("""
$continueLabel lda $varname""")
if(stepsize>0) {
asmgen.out("""
clc
adc #$stepsize
sta $varname
cmp $ESTACK_LO_PLUS1_HEX,x
bcc $loopLabel
beq $loopLabel""")
} else {
asmgen.out("""
sec
sbc #${stepsize.absoluteValue}
sta $varname
cmp $ESTACK_LO_PLUS1_HEX,x
bcs $loopLabel""")
}
asmgen.out("""
$endLabel inx""")
}
}
}
DataType.ARRAY_W, DataType.ARRAY_UW -> {
when {
// words, step 1 or -1
stepsize == 1 || stepsize == -1 -> {
asmgen.translateExpression(range.to)
val varname = asmgen.asmIdentifierName(stmt.loopVar!!)
val assignLoopvar = Assignment(AssignTarget(null, stmt.loopVar, null, null, stmt.loopVar!!.position),
null, range.from, range.position)
assignLoopvar.linkParents(stmt)
asmgen.translate(assignLoopvar)
asmgen.out(loopLabel)
asmgen.translate(stmt.body)
asmgen.out("""
lda $varname+1
cmp $ESTACK_HI_PLUS1_HEX,x
bne +
lda $varname
cmp $ESTACK_LO_PLUS1_HEX,x
beq $endLabel""")
if(stepsize==1) {
asmgen.out("""
+ inc $varname
bne +
inc $varname+1
""")
} else {
asmgen.out("""
+ lda $varname
bne +
dec $varname+1
+ dec $varname""")
}
asmgen.out("""
+ jmp $loopLabel
$endLabel inx""")
}
stepsize > 0 -> {
// (u)words, step >= 2
asmgen.translateExpression(range.to)
val varname = asmgen.asmIdentifierName(stmt.loopVar!!)
val assignLoopvar = Assignment(AssignTarget(null, stmt.loopVar, null, null, stmt.loopVar!!.position),
null, range.from, range.position)
assignLoopvar.linkParents(stmt)
asmgen.translate(assignLoopvar)
asmgen.out(loopLabel)
asmgen.translate(stmt.body)
if (iterableDt == DataType.ARRAY_UW) {
asmgen.out("""
lda $varname
clc
adc #<$stepsize
sta $varname
lda $varname+1
adc #>$stepsize
sta $varname+1
lda $ESTACK_HI_PLUS1_HEX,x
cmp $varname+1
bcc $endLabel
bne $loopLabel
lda $varname
cmp $ESTACK_LO_PLUS1_HEX,x
bcc $endLabel
bcs $loopLabel
$endLabel inx""")
} else {
asmgen.out("""
lda $varname
clc
adc #<$stepsize
sta $varname
lda $varname+1
adc #>$stepsize
sta $varname+1
lda $ESTACK_LO_PLUS1_HEX,x
cmp $varname
lda $ESTACK_HI_PLUS1_HEX,x
sbc $varname+1
bvc +
eor #$80
+ bpl $loopLabel
$endLabel inx""")
}
}
else -> {
// (u)words, step <= -2
asmgen.translateExpression(range.to)
val varname = asmgen.asmIdentifierName(stmt.loopVar!!)
val assignLoopvar = Assignment(AssignTarget(null, stmt.loopVar, null, null, stmt.loopVar!!.position),
null, range.from, range.position)
assignLoopvar.linkParents(stmt)
asmgen.translate(assignLoopvar)
asmgen.out(loopLabel)
asmgen.translate(stmt.body)
if(iterableDt==DataType.ARRAY_UW) {
asmgen.out("""
lda $varname
sec
sbc #<${stepsize.absoluteValue}
sta $varname
lda $varname+1
sbc #>${stepsize.absoluteValue}
sta $varname+1
cmp $ESTACK_HI_PLUS1_HEX,x
bcc $endLabel
bne $loopLabel
lda $varname
cmp $ESTACK_LO_PLUS1_HEX,x
bcs $loopLabel
$endLabel inx""")
} else {
asmgen.out("""
lda $varname
sec
sbc #<${stepsize.absoluteValue}
sta $varname
pha
lda $varname+1
sbc #>${stepsize.absoluteValue}
sta $varname+1
pla
cmp $ESTACK_LO_PLUS1_HEX,x
lda $varname+1
sbc $ESTACK_HI_PLUS1_HEX,x
bvc +
eor #$80
+ bpl $loopLabel
$endLabel inx""")
}
}
}
}
else -> throw AssemblyError("range expression can only be byte or word")
}
asmgen.loopEndLabels.pop()
asmgen.loopContinueLabels.pop()
}
private fun translateForOverIterableVar(stmt: ForLoop, iterableDt: DataType, ident: IdentifierReference) {
val loopLabel = asmgen.makeLabel("for_loop")
val endLabel = asmgen.makeLabel("for_end")
val continueLabel = asmgen.makeLabel("for_continue")
asmgen.loopEndLabels.push(endLabel)
asmgen.loopContinueLabels.push(continueLabel)
val iterableName = asmgen.asmIdentifierName(ident)
val decl = ident.targetVarDecl(program.namespace)!!
when(iterableDt) {
DataType.STR -> {
if(stmt.loopRegister!=null && stmt.loopRegister!= Register.A)
throw AssemblyError("can only use A")
asmgen.out("""
lda #<$iterableName
ldy #>$iterableName
sta $loopLabel+1
sty $loopLabel+2
$loopLabel lda ${65535.toHex()} ; modified
beq $endLabel""")
if(stmt.loopVar!=null)
asmgen.out(" sta ${asmgen.asmIdentifierName(stmt.loopVar!!)}")
asmgen.translate(stmt.body)
asmgen.out("""
$continueLabel inc $loopLabel+1
bne $loopLabel
inc $loopLabel+2
bne $loopLabel
$endLabel""")
}
DataType.ARRAY_UB, DataType.ARRAY_B -> {
// TODO: optimize loop code when the length of the array is < 256, don't need a separate counter in such cases
val length = decl.arraysize!!.size()!!
if(stmt.loopRegister!=null && stmt.loopRegister!= Register.A)
throw AssemblyError("can only use A")
val counterLabel = asmgen.makeLabel("for_counter")
val modifiedLabel = asmgen.makeLabel("for_modified")
asmgen.out("""
lda #<$iterableName
ldy #>$iterableName
sta $modifiedLabel+1
sty $modifiedLabel+2
ldy #0
$loopLabel sty $counterLabel
$modifiedLabel lda ${65535.toHex()},y ; modified""")
if(stmt.loopVar!=null)
asmgen.out(" sta ${asmgen.asmIdentifierName(stmt.loopVar!!)}")
asmgen.translate(stmt.body)
asmgen.out("""
$continueLabel ldy $counterLabel
iny
cpy #${length and 255}
beq $endLabel
jmp $loopLabel
$counterLabel .byte 0
$endLabel""")
}
DataType.ARRAY_W, DataType.ARRAY_UW -> {
// TODO: optimize loop code when the length of the array is < 256, don't need a separate counter in such cases
val length = decl.arraysize!!.size()!! * 2
if(stmt.loopRegister!=null)
throw AssemblyError("can't use register to loop over words")
val counterLabel = asmgen.makeLabel("for_counter")
val modifiedLabel = asmgen.makeLabel("for_modified")
val modifiedLabel2 = asmgen.makeLabel("for_modified2")
val loopvarName = asmgen.asmIdentifierName(stmt.loopVar!!)
asmgen.out("""
lda #<$iterableName
ldy #>$iterableName
sta $modifiedLabel+1
sty $modifiedLabel+2
lda #<$iterableName+1
ldy #>$iterableName+1
sta $modifiedLabel2+1
sty $modifiedLabel2+2
ldy #0
$loopLabel sty $counterLabel
$modifiedLabel lda ${65535.toHex()},y ; modified
sta $loopvarName
$modifiedLabel2 lda ${65535.toHex()},y ; modified
sta $loopvarName+1""")
asmgen.translate(stmt.body)
asmgen.out("""
$continueLabel ldy $counterLabel
iny
iny
cpy #${length and 255}
beq $endLabel
jmp $loopLabel
$counterLabel .byte 0
$endLabel""")
}
DataType.ARRAY_F -> {
throw AssemblyError("for loop with floating point variables is not supported")
}
else -> throw AssemblyError("can't iterate over $iterableDt")
}
asmgen.loopEndLabels.pop()
asmgen.loopContinueLabels.pop()
}
private fun translateForOverConstRange(stmt: ForLoop, iterableDt: DataType, range: IntProgression) {
// TODO: optimize loop code when the range is < 256 iterations, don't need a separate counter in such cases
if (range.isEmpty())
throw AssemblyError("empty range")
val loopLabel = asmgen.makeLabel("for_loop")
val endLabel = asmgen.makeLabel("for_end")
val continueLabel = asmgen.makeLabel("for_continue")
asmgen.loopEndLabels.push(endLabel)
asmgen.loopContinueLabels.push(continueLabel)
when(iterableDt) {
DataType.ARRAY_B, DataType.ARRAY_UB -> {
val counterLabel = asmgen.makeLabel("for_counter")
if(stmt.loopRegister!=null) {
// loop register over range
if(stmt.loopRegister!= Register.A)
throw AssemblyError("can only use A")
when {
range.step==1 -> {
// step = 1
asmgen.out("""
lda #${range.first}
sta $loopLabel+1
lda #${range.last-range.first+1 and 255}
sta $counterLabel
$loopLabel lda #0 ; modified""")
asmgen.translate(stmt.body)
asmgen.out("""
$continueLabel dec $counterLabel
beq $endLabel
inc $loopLabel+1
jmp $loopLabel
$counterLabel .byte 0
$endLabel""")
}
range.step==-1 -> {
// step = -1
asmgen.out("""
lda #${range.first}
sta $loopLabel+1
lda #${range.first-range.last+1 and 255}
sta $counterLabel
$loopLabel lda #0 ; modified """)
asmgen.translate(stmt.body)
asmgen.out("""
$continueLabel dec $counterLabel
beq $endLabel
dec $loopLabel+1
jmp $loopLabel
$counterLabel .byte 0
$endLabel""")
}
range.step >= 2 -> {
// step >= 2
asmgen.out("""
lda #${(range.last-range.first) / range.step + 1}
sta $counterLabel
lda #${range.first}
$loopLabel pha""")
asmgen.translate(stmt.body)
asmgen.out("""
$continueLabel pla
dec $counterLabel
beq $endLabel
clc
adc #${range.step}
jmp $loopLabel
$counterLabel .byte 0
$endLabel""")
}
else -> {
// step <= -2
asmgen.out("""
lda #${(range.first-range.last) / range.step.absoluteValue + 1}
sta $counterLabel
lda #${range.first}
$loopLabel pha""")
asmgen.translate(stmt.body)
asmgen.out("""
$continueLabel pla
dec $counterLabel
beq $endLabel
sec
sbc #${range.step.absoluteValue}
jmp $loopLabel
$counterLabel .byte 0
$endLabel""")
}
}
} else {
// loop over byte range via loopvar
val varname = asmgen.asmIdentifierName(stmt.loopVar!!)
when {
range.step==1 -> {
// step = 1
asmgen.out("""
lda #${range.first}
sta $varname
lda #${range.last-range.first+1 and 255}
sta $counterLabel
$loopLabel""")
asmgen.translate(stmt.body)
asmgen.out("""
$continueLabel dec $counterLabel
beq $endLabel
inc $varname
jmp $loopLabel
$counterLabel .byte 0
$endLabel""")
}
range.step==-1 -> {
// step = -1
asmgen.out("""
lda #${range.first}
sta $varname
lda #${range.first-range.last+1 and 255}
sta $counterLabel
$loopLabel""")
asmgen.translate(stmt.body)
asmgen.out("""
$continueLabel dec $counterLabel
beq $endLabel
dec $varname
jmp $loopLabel
$counterLabel .byte 0
$endLabel""")
}
range.step >= 2 -> {
// step >= 2
asmgen.out("""
lda #${(range.last-range.first) / range.step + 1}
sta $counterLabel
lda #${range.first}
sta $varname
$loopLabel""")
asmgen.translate(stmt.body)
asmgen.out("""
$continueLabel dec $counterLabel
beq $endLabel
lda $varname
clc
adc #${range.step}
sta $varname
jmp $loopLabel
$counterLabel .byte 0
$endLabel""")
}
else -> {
// step <= -2
asmgen.out("""
lda #${(range.first-range.last) / range.step.absoluteValue + 1}
sta $counterLabel
lda #${range.first}
sta $varname
$loopLabel""")
asmgen.translate(stmt.body)
asmgen.out("""
$continueLabel dec $counterLabel
beq $endLabel
lda $varname
sec
sbc #${range.step.absoluteValue}
sta $varname
jmp $loopLabel
$counterLabel .byte 0
$endLabel""")
}
}
}
}
DataType.ARRAY_W, DataType.ARRAY_UW -> {
// loop over word range via loopvar
val varname = asmgen.asmIdentifierName(stmt.loopVar!!)
when {
range.step == 1 -> {
// word, step = 1
val lastValue = range.last+1
asmgen.out("""
lda #<${range.first}
ldy #>${range.first}
sta $varname
sty $varname+1
$loopLabel""")
asmgen.translate(stmt.body)
asmgen.out("""
$continueLabel inc $varname
bne +
inc $varname+1
+ lda $varname
cmp #<$lastValue
bne +
lda $varname+1
cmp #>$lastValue
beq $endLabel
+ jmp $loopLabel
$endLabel""")
}
range.step == -1 -> {
// word, step = 1
val lastValue = range.last-1
asmgen.out("""
lda #<${range.first}
ldy #>${range.first}
sta $varname
sty $varname+1
$loopLabel""")
asmgen.translate(stmt.body)
asmgen.out("""
$continueLabel lda $varname
bne +
dec $varname+1
+ dec $varname
lda $varname
cmp #<$lastValue
bne +
lda $varname+1
cmp #>$lastValue
beq $endLabel
+ jmp $loopLabel
$endLabel""")
}
range.step >= 2 -> {
// word, step >= 2
// note: range.last has already been adjusted by kotlin itself to actually be the last value of the sequence
val lastValue = range.last+range.step
asmgen.out("""
lda #<${range.first}
ldy #>${range.first}
sta $varname
sty $varname+1
$loopLabel""")
asmgen.translate(stmt.body)
asmgen.out("""
$continueLabel clc
lda $varname
adc #<${range.step}
sta $varname
lda $varname+1
adc #>${range.step}
sta $varname+1
lda $varname
cmp #<$lastValue
bne +
lda $varname+1
cmp #>$lastValue
beq $endLabel
+ jmp $loopLabel
$endLabel""")
}
else -> {
// step <= -2
// note: range.last has already been adjusted by kotlin itself to actually be the last value of the sequence
val lastValue = range.last+range.step
asmgen.out("""
lda #<${range.first}
ldy #>${range.first}
sta $varname
sty $varname+1
$loopLabel""")
asmgen.translate(stmt.body)
asmgen.out("""
$continueLabel sec
lda $varname
sbc #<${range.step.absoluteValue}
sta $varname
lda $varname+1
sbc #>${range.step.absoluteValue}
sta $varname+1
lda $varname
cmp #<$lastValue
bne +
lda $varname+1
cmp #>$lastValue
beq $endLabel
+ jmp $loopLabel
$endLabel""")
}
}
}
else -> throw AssemblyError("range expression can only be byte or word")
}
asmgen.loopEndLabels.pop()
asmgen.loopContinueLabels.pop()
}
}

238
compiler/src/prog8/compiler/target/c64/codegen/FunctionCallAsmGen.kt Normal file
View File

@ -0,0 +1,238 @@
package prog8.compiler.target.c64.codegen
import prog8.ast.IFunctionCall
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.ast.statements.AssignTarget
import prog8.ast.statements.Subroutine
import prog8.ast.statements.SubroutineParameter
import prog8.compiler.toHex
import prog8.compiler.AssemblyError
import prog8.compiler.target.c64.C64MachineDefinition.ESTACK_HI_HEX
import prog8.compiler.target.c64.C64MachineDefinition.ESTACK_LO_HEX
internal class FunctionCallAsmGen(private val program: Program, private val asmgen: AsmGen) {
internal fun translateFunctionCall(stmt: IFunctionCall) {
// output the code to setup the parameters and perform the actual call
// does NOT output the code to deal with the result values!
val sub = stmt.target.targetSubroutine(program.namespace) ?: throw AssemblyError("undefined subroutine ${stmt.target}")
if(Register.X in sub.asmClobbers)
asmgen.out(" stx c64.SCRATCH_ZPREGX") // we only save X for now (required! is the eval stack pointer), screw A and Y...
val subName = asmgen.asmIdentifierName(stmt.target)
if(stmt.args.isNotEmpty()) {
for(arg in sub.parameters.withIndex().zip(stmt.args)) {
translateFuncArguments(arg.first, arg.second, sub)
}
}
asmgen.out(" jsr $subName")
if(Register.X in sub.asmClobbers)
asmgen.out(" ldx c64.SCRATCH_ZPREGX") // restore X again
}
private fun translateFuncArguments(parameter: IndexedValue<SubroutineParameter>, value: Expression, sub: Subroutine) {
val sourceIDt = value.inferType(program)
if(!sourceIDt.isKnown)
throw AssemblyError("arg type unknown")
val sourceDt = sourceIDt.typeOrElse(DataType.STRUCT)
if(!argumentTypeCompatible(sourceDt, parameter.value.type))
throw AssemblyError("argument type incompatible")
if(sub.asmParameterRegisters.isEmpty()) {
// pass parameter via a variable
val paramVar = parameter.value
val scopedParamVar = (sub.scopedname+"."+paramVar.name).split(".")
val target = AssignTarget(null, IdentifierReference(scopedParamVar, sub.position), null, null, sub.position)
target.linkParents(value.parent)
when (value) {
is NumericLiteralValue -> {
// optimize when the argument is a constant literal
when(parameter.value.type) {
in ByteDatatypes -> asmgen.assignFromByteConstant(target, value.number.toShort())
in WordDatatypes -> asmgen.assignFromWordConstant(target, value.number.toInt())
DataType.FLOAT -> asmgen.assignFromFloatConstant(target, value.number.toDouble())
in PassByReferenceDatatypes -> throw AssemblyError("can't pass string/array as arguments?")
else -> throw AssemblyError("weird parameter datatype")
}
}
is IdentifierReference -> {
// optimize when the argument is a variable
when (parameter.value.type) {
in ByteDatatypes -> asmgen.assignFromByteVariable(target, value)
in WordDatatypes -> asmgen.assignFromWordVariable(target, value)
DataType.FLOAT -> asmgen.assignFromFloatVariable(target, value)
in PassByReferenceDatatypes -> throw AssemblyError("can't pass string/array as arguments?")
else -> throw AssemblyError("weird parameter datatype")
}
}
is RegisterExpr -> {
asmgen.assignFromRegister(target, value.register)
}
is DirectMemoryRead -> {
when(value.addressExpression) {
is NumericLiteralValue -> {
val address = (value.addressExpression as NumericLiteralValue).number.toInt()
asmgen.assignFromMemoryByte(target, address, null)
}
is IdentifierReference -> {
asmgen.assignFromMemoryByte(target, null, value.addressExpression as IdentifierReference)
}
else -> {
asmgen.translateExpression(value.addressExpression)
asmgen.out(" jsr prog8_lib.read_byte_from_address | inx")
asmgen.assignFromRegister(target, Register.A)
}
}
}
else -> {
asmgen.translateExpression(value)
asmgen.assignFromEvalResult(target)
}
}
} else {
// pass parameter via a register parameter
val paramRegister = sub.asmParameterRegisters[parameter.index]
val statusflag = paramRegister.statusflag
val register = paramRegister.registerOrPair
val stack = paramRegister.stack
when {
stack -> {
// push arg onto the stack
// note: argument order is reversed (first argument will be deepest on the stack)
asmgen.translateExpression(value)
}
statusflag!=null -> {
if (statusflag == Statusflag.Pc) {
// this param needs to be set last, right before the jsr
// for now, this is already enforced on the subroutine definition by the Ast Checker
when(value) {
is NumericLiteralValue -> {
val carrySet = value.number.toInt() != 0
asmgen.out(if(carrySet) " sec" else " clc")
}
is IdentifierReference -> {
val sourceName = asmgen.asmIdentifierName(value)
asmgen.out("""
lda $sourceName
beq +
sec
bcs ++
+ clc
+
""")
}
is RegisterExpr -> {
when(value.register) {
Register.A -> asmgen.out(" cmp #0")
Register.X -> asmgen.out(" txa")
Register.Y -> asmgen.out(" tya")
}
asmgen.out("""
beq +
sec
bcs ++
+ clc
+
""")
}
else -> {
asmgen.translateExpression(value)
asmgen.out("""
inx
lda $ESTACK_LO_HEX,x
beq +
sec
bcs ++
+ clc
+
""")
}
}
}
else throw AssemblyError("can only use Carry as status flag parameter")
}
register!=null && register.name.length==1 -> {
when (value) {
is NumericLiteralValue -> {
val target = AssignTarget(Register.valueOf(register.name), null, null, null, sub.position)
target.linkParents(value.parent)
asmgen.assignFromByteConstant(target, value.number.toShort())
}
is IdentifierReference -> {
val target = AssignTarget(Register.valueOf(register.name), null, null, null, sub.position)
target.linkParents(value.parent)
asmgen.assignFromByteVariable(target, value)
}
else -> {
asmgen.translateExpression(value)
when(register) {
RegisterOrPair.A -> asmgen.out(" inx | lda $ESTACK_LO_HEX,x")
RegisterOrPair.X -> throw AssemblyError("can't pop into X register - use a variable instead")
RegisterOrPair.Y -> asmgen.out(" inx | ldy $ESTACK_LO_HEX,x")
else -> throw AssemblyError("cannot assign to register pair")
}
}
}
}
register!=null && register.name.length==2 -> {
// register pair as a 16-bit value (only possible for subroutine parameters)
when (value) {
is NumericLiteralValue -> {
// optimize when the argument is a constant literal
val hex = value.number.toHex()
when (register) {
RegisterOrPair.AX -> asmgen.out(" lda #<$hex | ldx #>$hex")
RegisterOrPair.AY -> asmgen.out(" lda #<$hex | ldy #>$hex")
RegisterOrPair.XY -> asmgen.out(" ldx #<$hex | ldy #>$hex")
else -> {}
}
}
is AddressOf -> {
// optimize when the argument is an address of something
val sourceName = asmgen.asmIdentifierName(value.identifier)
when (register) {
RegisterOrPair.AX -> asmgen.out(" lda #<$sourceName | ldx #>$sourceName")
RegisterOrPair.AY -> asmgen.out(" lda #<$sourceName | ldy #>$sourceName")
RegisterOrPair.XY -> asmgen.out(" ldx #<$sourceName | ldy #>$sourceName")
else -> {}
}
}
is IdentifierReference -> {
val sourceName = asmgen.asmIdentifierName(value)
when (register) {
RegisterOrPair.AX -> asmgen.out(" lda $sourceName | ldx $sourceName+1")
RegisterOrPair.AY -> asmgen.out(" lda $sourceName | ldy $sourceName+1")
RegisterOrPair.XY -> asmgen.out(" ldx $sourceName | ldy $sourceName+1")
else -> {}
}
}
else -> {
asmgen.translateExpression(value)
if (register == RegisterOrPair.AX || register == RegisterOrPair.XY)
throw AssemblyError("can't use X register here - use a variable")
else if (register == RegisterOrPair.AY)
asmgen.out(" inx | lda $ESTACK_LO_HEX,x | ldy $ESTACK_HI_HEX,x")
}
}
}
}
}
}
private fun argumentTypeCompatible(argType: DataType, paramType: DataType): Boolean {
if(argType isAssignableTo paramType)
return true
// we have a special rule for some types.
// strings are assignable to UWORD, for example, and vice versa
if(argType==DataType.STR && paramType==DataType.UWORD)
return true
if(argType==DataType.UWORD && paramType == DataType.STR)
return true
return false
}
}

150
compiler/src/prog8/compiler/target/c64/codegen/PostIncrDecrAsmGen.kt Normal file
View File

@ -0,0 +1,150 @@
package prog8.compiler.target.c64.codegen
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.expressions.IdentifierReference
import prog8.ast.expressions.NumericLiteralValue
import prog8.ast.expressions.RegisterExpr
import prog8.ast.statements.PostIncrDecr
import prog8.compiler.toHex
import prog8.compiler.AssemblyError
import prog8.compiler.target.c64.C64MachineDefinition.C64Zeropage
internal class PostIncrDecrAsmGen(private val program: Program, private val asmgen: AsmGen) {
internal fun translate(stmt: PostIncrDecr) {
val incr = stmt.operator=="++"
val targetIdent = stmt.target.identifier
val targetMemory = stmt.target.memoryAddress
val targetArrayIdx = stmt.target.arrayindexed
val targetRegister = stmt.target.register
when {
targetRegister!=null -> {
when(targetRegister) {
Register.A -> {
if(incr)
asmgen.out(" clc | adc #1 ")
else
asmgen.out(" sec | sbc #1 ")
}
Register.X -> {
if(incr) asmgen.out(" inx") else asmgen.out(" dex")
}
Register.Y -> {
if(incr) asmgen.out(" iny") else asmgen.out(" dey")
}
}
}
targetIdent!=null -> {
val what = asmgen.asmIdentifierName(targetIdent)
val dt = stmt.target.inferType(program, stmt).typeOrElse(DataType.STRUCT)
when (dt) {
in ByteDatatypes -> asmgen.out(if (incr) " inc $what" else " dec $what")
in WordDatatypes -> {
if(incr)
asmgen.out(" inc $what | bne + | inc $what+1 |+")
else
asmgen.out("""
lda $what
bne +
dec $what+1
+ dec $what
""")
}
DataType.FLOAT -> {
asmgen.out(" lda #<$what | ldy #>$what")
asmgen.out(if(incr) " jsr c64flt.inc_var_f" else " jsr c64flt.dec_var_f")
}
else -> throw AssemblyError("need numeric type")
}
}
targetMemory!=null -> {
when (val addressExpr = targetMemory.addressExpression) {
is NumericLiteralValue -> {
val what = addressExpr.number.toHex()
asmgen.out(if(incr) " inc $what" else " dec $what")
}
is IdentifierReference -> {
val what = asmgen.asmIdentifierName(addressExpr)
asmgen.out(if(incr) " inc $what" else " dec $what")
}
else -> throw AssemblyError("weird target type $targetMemory")
}
}
targetArrayIdx!=null -> {
val index = targetArrayIdx.arrayspec.index
val what = asmgen.asmIdentifierName(targetArrayIdx.identifier)
val arrayDt = targetArrayIdx.identifier.inferType(program).typeOrElse(DataType.STRUCT)
val elementDt = ArrayElementTypes.getValue(arrayDt)
when(index) {
is NumericLiteralValue -> {
val indexValue = index.number.toInt() * elementDt.memorySize()
when(elementDt) {
in ByteDatatypes -> asmgen.out(if (incr) " inc $what+$indexValue" else " dec $what+$indexValue")
in WordDatatypes -> {
if(incr)
asmgen.out(" inc $what+$indexValue | bne + | inc $what+$indexValue+1 |+")
else
asmgen.out("""
lda $what+$indexValue
bne +
dec $what+$indexValue+1
+ dec $what+$indexValue
""")
}
DataType.FLOAT -> {
asmgen.out(" lda #<$what+$indexValue | ldy #>$what+$indexValue")
asmgen.out(if(incr) " jsr c64flt.inc_var_f" else " jsr c64flt.dec_var_f")
}
else -> throw AssemblyError("need numeric type")
}
}
is RegisterExpr -> {
// TODO optimize common cases
asmgen.translateArrayIndexIntoA(targetArrayIdx)
incrDecrArrayvalueWithIndexA(incr, arrayDt, what)
}
is IdentifierReference -> {
// TODO optimize common cases
asmgen.translateArrayIndexIntoA(targetArrayIdx)
incrDecrArrayvalueWithIndexA(incr, arrayDt, what)
}
else -> {
// TODO optimize common cases
asmgen.translateArrayIndexIntoA(targetArrayIdx)
incrDecrArrayvalueWithIndexA(incr, arrayDt, what)
}
}
}
else -> throw AssemblyError("weird target type ${stmt.target}")
}
}
private fun incrDecrArrayvalueWithIndexA(incr: Boolean, arrayDt: DataType, arrayVarName: String) {
asmgen.out(" stx ${C64Zeropage.SCRATCH_REG_X} | tax")
when(arrayDt) {
DataType.STR,
DataType.ARRAY_UB, DataType.ARRAY_B -> {
asmgen.out(if(incr) " inc $arrayVarName,x" else " dec $arrayVarName,x")
}
DataType.ARRAY_UW, DataType.ARRAY_W -> {
if(incr)
asmgen.out(" inc $arrayVarName,x | bne + | inc $arrayVarName+1,x |+")
else
asmgen.out("""
lda $arrayVarName,x
bne +
dec $arrayVarName+1,x
+ dec $arrayVarName
""")
}
DataType.ARRAY_F -> {
asmgen.out(" lda #<$arrayVarName | ldy #>$arrayVarName")
asmgen.out(if(incr) " jsr c64flt.inc_indexed_var_f" else " jsr c64flt.dec_indexed_var_f")
}
else -> throw AssemblyError("weird array dt")
}
asmgen.out(" ldx ${C64Zeropage.SCRATCH_REG_X}")
}
}

397
compiler/src/prog8/functions/BuiltinFunctions.kt
View File

@ -1,21 +1,22 @@
package prog8.functions
import prog8.ast.*
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.expressions.DirectMemoryRead
import prog8.ast.expressions.IdentifierReference
import prog8.ast.expressions.LiteralValue
import prog8.ast.statements.VarDecl
import prog8.ast.expressions.*
import prog8.compiler.CompilerException
import kotlin.math.*
class BuiltinFunctionParam(val name: String, val possibleDatatypes: Set<DataType>)
typealias ConstExpressionCaller = (args: List<Expression>, position: Position, program: Program) -> NumericLiteralValue
class FunctionSignature(val pure: Boolean, // does it have side effects?
val parameters: List<BuiltinFunctionParam>,
val returntype: DataType?,
val constExpressionFunc: ((args: List<IExpression>, position: Position, program: Program) -> LiteralValue)? = null)
val constExpressionFunc: ConstExpressionCaller? = null)
val BuiltinFunctions = mapOf(
@ -26,13 +27,16 @@ val BuiltinFunctions = mapOf(
"ror2" to FunctionSignature(false, listOf(BuiltinFunctionParam("item", setOf(DataType.UBYTE, DataType.UWORD))), null),
"lsl" to FunctionSignature(false, listOf(BuiltinFunctionParam("item", IntegerDatatypes)), null),
"lsr" to FunctionSignature(false, listOf(BuiltinFunctionParam("item", IntegerDatatypes)), null),
"sort" to FunctionSignature(false, listOf(BuiltinFunctionParam("array", ArrayDatatypes)), null),
"reverse" to FunctionSignature(false, listOf(BuiltinFunctionParam("array", ArrayDatatypes)), null),
// these few have a return value depending on the argument(s):
"max" to FunctionSignature(true, listOf(BuiltinFunctionParam("values", ArrayDatatypes)), null) { a, p, prg -> collectionArgOutputNumber(a, p, prg) { it.max()!! }}, // type depends on args
"min" to FunctionSignature(true, listOf(BuiltinFunctionParam("values", ArrayDatatypes)), null) { a, p, prg -> collectionArgOutputNumber(a, p, prg) { it.min()!! }}, // type depends on args
"sum" to FunctionSignature(true, listOf(BuiltinFunctionParam("values", ArrayDatatypes)), null) { a, p, prg -> collectionArgOutputNumber(a, p, prg) { it.sum() }}, // type depends on args
"max" to FunctionSignature(true, listOf(BuiltinFunctionParam("values", ArrayDatatypes)), null) { a, p, prg -> collectionArg(a, p, prg, ::builtinMax) }, // type depends on args
"min" to FunctionSignature(true, listOf(BuiltinFunctionParam("values", ArrayDatatypes)), null) { a, p, prg -> collectionArg(a, p, prg, ::builtinMin) }, // type depends on args
"sum" to FunctionSignature(true, listOf(BuiltinFunctionParam("values", ArrayDatatypes)), null) { a, p, prg -> collectionArg(a, p, prg, ::builtinSum) }, // type depends on args
"abs" to FunctionSignature(true, listOf(BuiltinFunctionParam("value", NumericDatatypes)), null, ::builtinAbs), // type depends on argument
"len" to FunctionSignature(true, listOf(BuiltinFunctionParam("values", IterableDatatypes)), null, ::builtinLen), // type is UBYTE or UWORD depending on actual length
// normal functions follow:
"sgn" to FunctionSignature(true, listOf(BuiltinFunctionParam("value", NumericDatatypes)), DataType.BYTE, ::builtinSgn ),
"sin" to FunctionSignature(true, listOf(BuiltinFunctionParam("rads", setOf(DataType.FLOAT))), DataType.FLOAT) { a, p, prg -> oneDoubleArg(a, p, prg, Math::sin) },
"sin8" to FunctionSignature(true, listOf(BuiltinFunctionParam("angle8", setOf(DataType.UBYTE))), DataType.BYTE, ::builtinSin8 ),
"sin8u" to FunctionSignature(true, listOf(BuiltinFunctionParam("angle8", setOf(DataType.UBYTE))), DataType.UBYTE, ::builtinSin8u ),
@ -51,12 +55,11 @@ val BuiltinFunctions = mapOf(
"sqrt" to FunctionSignature(true, listOf(BuiltinFunctionParam("value", setOf(DataType.FLOAT))), DataType.FLOAT) { a, p, prg -> oneDoubleArg(a, p, prg, Math::sqrt) },
"rad" to FunctionSignature(true, listOf(BuiltinFunctionParam("value", setOf(DataType.FLOAT))), DataType.FLOAT) { a, p, prg -> oneDoubleArg(a, p, prg, Math::toRadians) },
"deg" to FunctionSignature(true, listOf(BuiltinFunctionParam("value", setOf(DataType.FLOAT))), DataType.FLOAT) { a, p, prg -> oneDoubleArg(a, p, prg, Math::toDegrees) },
"avg" to FunctionSignature(true, listOf(BuiltinFunctionParam("values", ArrayDatatypes)), DataType.FLOAT, ::builtinAvg),
"round" to FunctionSignature(true, listOf(BuiltinFunctionParam("value", setOf(DataType.FLOAT))), DataType.FLOAT) { a, p, prg -> oneDoubleArgOutputWord(a, p, prg, Math::round) },
"floor" to FunctionSignature(true, listOf(BuiltinFunctionParam("value", setOf(DataType.FLOAT))), DataType.FLOAT) { a, p, prg -> oneDoubleArgOutputWord(a, p, prg, Math::floor) },
"ceil" to FunctionSignature(true, listOf(BuiltinFunctionParam("value", setOf(DataType.FLOAT))), DataType.FLOAT) { a, p, prg -> oneDoubleArgOutputWord(a, p, prg, Math::ceil) },
"any" to FunctionSignature(true, listOf(BuiltinFunctionParam("values", ArrayDatatypes)), DataType.UBYTE) { a, p, prg -> collectionArgOutputBoolean(a, p, prg) { it.any { v -> v != 0.0} }},
"all" to FunctionSignature(true, listOf(BuiltinFunctionParam("values", ArrayDatatypes)), DataType.UBYTE) { a, p, prg -> collectionArgOutputBoolean(a, p, prg) { it.all { v -> v != 0.0} }},
"any" to FunctionSignature(true, listOf(BuiltinFunctionParam("values", ArrayDatatypes)), DataType.UBYTE) { a, p, prg -> collectionArg(a, p, prg, ::builtinAny) },
"all" to FunctionSignature(true, listOf(BuiltinFunctionParam("values", ArrayDatatypes)), DataType.UBYTE) { a, p, prg -> collectionArg(a, p, prg, ::builtinAll) },
"lsb" to FunctionSignature(true, listOf(BuiltinFunctionParam("value", setOf(DataType.UWORD, DataType.WORD))), DataType.UBYTE) { a, p, prg -> oneIntArgOutputInt(a, p, prg) { x: Int -> x and 255 }},
"msb" to FunctionSignature(true, listOf(BuiltinFunctionParam("value", setOf(DataType.UWORD, DataType.WORD))), DataType.UBYTE) { a, p, prg -> oneIntArgOutputInt(a, p, prg) { x: Int -> x ushr 8 and 255}},
"mkword" to FunctionSignature(true, listOf(
@ -74,64 +77,52 @@ val BuiltinFunctions = mapOf(
"read_flags" to FunctionSignature(false, emptyList(), DataType.UBYTE),
"swap" to FunctionSignature(false, listOf(BuiltinFunctionParam("first", NumericDatatypes), BuiltinFunctionParam("second", NumericDatatypes)), null),
"memcopy" to FunctionSignature(false, listOf(
BuiltinFunctionParam("from", IterableDatatypes + setOf(DataType.UWORD)),
BuiltinFunctionParam("to", IterableDatatypes + setOf(DataType.UWORD)),
BuiltinFunctionParam("from", IterableDatatypes + DataType.UWORD),
BuiltinFunctionParam("to", IterableDatatypes + DataType.UWORD),
BuiltinFunctionParam("numbytes", setOf(DataType.UBYTE))), null),
"memset" to FunctionSignature(false, listOf(
BuiltinFunctionParam("address", IterableDatatypes + setOf(DataType.UWORD)),
BuiltinFunctionParam("address", IterableDatatypes + DataType.UWORD),
BuiltinFunctionParam("numbytes", setOf(DataType.UWORD)),
BuiltinFunctionParam("bytevalue", ByteDatatypes)), null),
"memsetw" to FunctionSignature(false, listOf(
BuiltinFunctionParam("address", IterableDatatypes + setOf(DataType.UWORD)),
BuiltinFunctionParam("address", IterableDatatypes + DataType.UWORD),
BuiltinFunctionParam("numwords", setOf(DataType.UWORD)),
BuiltinFunctionParam("wordvalue", setOf(DataType.UWORD, DataType.WORD))), null),
"strlen" to FunctionSignature(true, listOf(BuiltinFunctionParam("string", StringDatatypes)), DataType.UBYTE, ::builtinStrlen),
"vm_write_memchr" to FunctionSignature(false, listOf(BuiltinFunctionParam("address", setOf(DataType.UWORD))), null),
"vm_write_memstr" to FunctionSignature(false, listOf(BuiltinFunctionParam("address", setOf(DataType.UWORD))), null),
"vm_write_num" to FunctionSignature(false, listOf(BuiltinFunctionParam("number", NumericDatatypes)), null),
"vm_write_char" to FunctionSignature(false, listOf(BuiltinFunctionParam("char", setOf(DataType.UBYTE))), null),
"vm_write_str" to FunctionSignature(false, listOf(BuiltinFunctionParam("string", StringDatatypes)), null),
"vm_input_str" to FunctionSignature(false, listOf(BuiltinFunctionParam("intovar", StringDatatypes)), null),
"vm_gfx_clearscr" to FunctionSignature(false, listOf(BuiltinFunctionParam("color", setOf(DataType.UBYTE))), null),
"vm_gfx_pixel" to FunctionSignature(false, listOf(
BuiltinFunctionParam("x", IntegerDatatypes),
BuiltinFunctionParam("y", IntegerDatatypes),
BuiltinFunctionParam("color", IntegerDatatypes)), null),
"vm_gfx_line" to FunctionSignature(false, listOf(
BuiltinFunctionParam("x1", IntegerDatatypes),
BuiltinFunctionParam("y1", IntegerDatatypes),
BuiltinFunctionParam("x2", IntegerDatatypes),
BuiltinFunctionParam("y2", IntegerDatatypes),
BuiltinFunctionParam("color", IntegerDatatypes)), null),
"vm_gfx_text" to FunctionSignature(false, listOf(
BuiltinFunctionParam("x", IntegerDatatypes),
BuiltinFunctionParam("y", IntegerDatatypes),
BuiltinFunctionParam("color", IntegerDatatypes),
BuiltinFunctionParam("text", StringDatatypes)),
null)
"strlen" to FunctionSignature(true, listOf(BuiltinFunctionParam("string", setOf(DataType.STR))), DataType.UBYTE, ::builtinStrlen)
)
fun builtinMax(array: List<Number>): Number = array.maxBy { it.toDouble() }!!
fun builtinFunctionReturnType(function: String, args: List<IExpression>, program: Program): DataType? {
fun builtinMin(array: List<Number>): Number = array.minBy { it.toDouble() }!!
fun datatypeFromIterableArg(arglist: IExpression): DataType {
if(arglist is LiteralValue) {
if(arglist.type== DataType.ARRAY_UB || arglist.type== DataType.ARRAY_UW || arglist.type== DataType.ARRAY_F) {
val dt = arglist.arrayvalue!!.map {it.inferType(program)}
if(dt.any { it!= DataType.UBYTE && it!= DataType.UWORD && it!= DataType.FLOAT}) {
throw FatalAstException("fuction $function only accepts arraysize of numeric values")
}
if(dt.any { it== DataType.FLOAT }) return DataType.FLOAT
if(dt.any { it== DataType.UWORD }) return DataType.UWORD
return DataType.UBYTE
fun builtinSum(array: List<Number>): Number = array.sumByDouble { it.toDouble() }
fun builtinAny(array: List<Number>): Number = if(array.any { it.toDouble()!=0.0 }) 1 else 0
fun builtinAll(array: List<Number>): Number = if(array.all { it.toDouble()!=0.0 }) 1 else 0
fun builtinFunctionReturnType(function: String, args: List<Expression>, program: Program): InferredTypes.InferredType {
fun datatypeFromIterableArg(arglist: Expression): DataType {
if(arglist is ArrayLiteralValue) {
val dt = arglist.value.map {it.inferType(program).typeOrElse(DataType.STRUCT)}.toSet()
if(dt.any { it !in NumericDatatypes }) {
throw FatalAstException("fuction $function only accepts array of numeric values")
}
if(DataType.FLOAT in dt) return DataType.FLOAT
if(DataType.UWORD in dt) return DataType.UWORD
if(DataType.WORD in dt) return DataType.WORD
if(DataType.BYTE in dt) return DataType.BYTE
return DataType.UBYTE
}
if(arglist is IdentifierReference) {
val dt = arglist.inferType(program)
return when(dt) {
in NumericDatatypes -> dt!!
in StringDatatypes -> dt!!
in ArrayDatatypes -> ArrayElementTypes.getValue(dt!!)
val idt = arglist.inferType(program)
if(!idt.isKnown)
throw FatalAstException("couldn't determine type of iterable $arglist")
return when(val dt = idt.typeOrElse(DataType.STRUCT)) {
DataType.STR, in NumericDatatypes -> dt
in ArrayDatatypes -> ArrayElementTypes.getValue(dt)
else -> throw FatalAstException("function '$function' requires one argument which is an iterable")
}
}
@ -140,46 +131,43 @@ fun builtinFunctionReturnType(function: String, args: List<IExpression>, program
val func = BuiltinFunctions.getValue(function)
if(func.returntype!=null)
return func.returntype
return InferredTypes.knownFor(func.returntype)
// function has return values, but the return type depends on the arguments
return when (function) {
"abs" -> {
val dt = args.single().inferType(program)
when(dt) {
in ByteDatatypes -> DataType.UBYTE
in WordDatatypes -> DataType.UWORD
DataType.FLOAT -> DataType.FLOAT
else -> throw FatalAstException("weird datatype passed to abs $dt")
}
if(dt.typeOrElse(DataType.STRUCT) in NumericDatatypes)
return dt
else
throw FatalAstException("weird datatype passed to abs $dt")
}
"max", "min" -> {
val dt = datatypeFromIterableArg(args.single())
when(dt) {
in NumericDatatypes -> dt
in StringDatatypes -> DataType.UBYTE
in ArrayDatatypes -> ArrayElementTypes.getValue(dt)
else -> null
when(val dt = datatypeFromIterableArg(args.single())) {
DataType.STR -> InferredTypes.knownFor(DataType.UBYTE)
in NumericDatatypes -> InferredTypes.knownFor(dt)
in ArrayDatatypes -> InferredTypes.knownFor(ArrayElementTypes.getValue(dt))
else -> InferredTypes.unknown()
}
}
"sum" -> {
when(datatypeFromIterableArg(args.single())) {
DataType.UBYTE, DataType.UWORD -> DataType.UWORD
DataType.BYTE, DataType.WORD -> DataType.WORD
DataType.FLOAT -> DataType.FLOAT
DataType.ARRAY_UB, DataType.ARRAY_UW -> DataType.UWORD
DataType.ARRAY_B, DataType.ARRAY_W -> DataType.WORD
DataType.ARRAY_F -> DataType.FLOAT
in StringDatatypes -> DataType.UWORD
else -> null
DataType.UBYTE, DataType.UWORD -> InferredTypes.knownFor(DataType.UWORD)
DataType.BYTE, DataType.WORD -> InferredTypes.knownFor(DataType.WORD)
DataType.FLOAT -> InferredTypes.knownFor(DataType.FLOAT)
DataType.ARRAY_UB, DataType.ARRAY_UW -> InferredTypes.knownFor(DataType.UWORD)
DataType.ARRAY_B, DataType.ARRAY_W -> InferredTypes.knownFor(DataType.WORD)
DataType.ARRAY_F -> InferredTypes.knownFor(DataType.FLOAT)
DataType.STR -> InferredTypes.knownFor(DataType.UWORD)
else -> InferredTypes.unknown()
}
}
"len" -> {
// a length can be >255 so in that case, the result is an UWORD instead of an UBYTE
// but to avoid a lot of code duplication we simply assume UWORD in all cases for now
return DataType.UWORD
return InferredTypes.knownFor(DataType.UWORD)
}
else -> return null
else -> return InferredTypes.unknown()
}
}
@ -187,182 +175,104 @@ fun builtinFunctionReturnType(function: String, args: List<IExpression>, program
class NotConstArgumentException: AstException("not a const argument to a built-in function")
private fun oneDoubleArg(args: List<IExpression>, position: Position, program: Program, function: (arg: Double)->Number): LiteralValue {
private fun oneDoubleArg(args: List<Expression>, position: Position, program: Program, function: (arg: Double)->Number): NumericLiteralValue {
if(args.size!=1)
throw SyntaxError("built-in function requires one floating point argument", position)
val constval = args[0].constValue(program) ?: throw NotConstArgumentException()
val float = getFloatArg(constval, args[0].position)
val float = constval.number.toDouble()
return numericLiteral(function(float), args[0].position)
}
private fun getFloatArg(v: LiteralValue, position: Position): Double {
val nv = v.asNumericValue ?: throw SyntaxError("numerical argument required", position)
return nv.toDouble()
}
private fun oneDoubleArgOutputWord(args: List<IExpression>, position: Position, program: Program, function: (arg: Double)->Number): LiteralValue {
private fun oneDoubleArgOutputWord(args: List<Expression>, position: Position, program: Program, function: (arg: Double)->Number): NumericLiteralValue {
if(args.size!=1)
throw SyntaxError("built-in function requires one floating point argument", position)
val constval = args[0].constValue(program) ?: throw NotConstArgumentException()
val float = getFloatArg(constval, args[0].position)
return LiteralValue(DataType.WORD, wordvalue = function(float).toInt(), position = args[0].position)
val float = constval.number.toDouble()
return NumericLiteralValue(DataType.WORD, function(float).toInt(), args[0].position)
}
private fun oneIntArgOutputInt(args: List<IExpression>, position: Position, program: Program, function: (arg: Int)->Number): LiteralValue {
private fun oneIntArgOutputInt(args: List<Expression>, position: Position, program: Program, function: (arg: Int)->Number): NumericLiteralValue {
if(args.size!=1)
throw SyntaxError("built-in function requires one integer argument", position)
val constval = args[0].constValue(program) ?: throw NotConstArgumentException()
if(constval.type!= DataType.UBYTE && constval.type!= DataType.UWORD)
if(constval.type != DataType.UBYTE && constval.type!= DataType.UWORD)
throw SyntaxError("built-in function requires one integer argument", position)
val integer = constval.asNumericValue?.toInt()!!
val integer = constval.number.toInt()
return numericLiteral(function(integer).toInt(), args[0].position)
}
private fun collectionArgOutputNumber(args: List<IExpression>, position: Position,
program: Program,
function: (arg: Collection<Double>)->Number): LiteralValue {
private fun collectionArg(args: List<Expression>, position: Position, program: Program, function: (arg: List<Number>)->Number): NumericLiteralValue {
if(args.size!=1)
throw SyntaxError("builtin function requires one non-scalar argument", position)
val iterable = args[0].constValue(program) ?: throw NotConstArgumentException()
val result = if(iterable.arrayvalue != null) {
val constants = iterable.arrayvalue.map { it.constValue(program)?.asNumericValue }
if(null in constants)
throw NotConstArgumentException()
function(constants.map { it!!.toDouble() }).toDouble()
} else {
when(iterable.type) {
DataType.UBYTE, DataType.UWORD, DataType.FLOAT -> throw SyntaxError("function expects an iterable type", position)
else -> {
val heapId = iterable.heapId ?: throw FatalAstException("iterable value should be on the heap")
val array = program.heap.get(heapId).array ?: throw SyntaxError("function expects an iterable type", position)
function(array.map {
if(it.integer!=null)
it.integer.toDouble()
else
throw FatalAstException("cannot perform function over array that contains other values besides constant integers")
})
}
}
}
return numericLiteral(result, args[0].position)
val array= args[0] as? ArrayLiteralValue ?: throw NotConstArgumentException()
val constElements = array.value.map{it.constValue(program)?.number}
if(constElements.contains(null))
throw NotConstArgumentException()
return NumericLiteralValue.optimalNumeric(function(constElements.mapNotNull { it }), args[0].position)
}
private fun collectionArgOutputBoolean(args: List<IExpression>, position: Position,
program: Program,
function: (arg: Collection<Double>)->Boolean): LiteralValue {
if(args.size!=1)
throw SyntaxError("builtin function requires one non-scalar argument", position)
val iterable = args[0].constValue(program) ?: throw NotConstArgumentException()
val result = if(iterable.arrayvalue != null) {
val constants = iterable.arrayvalue.map { it.constValue(program)?.asNumericValue }
if(null in constants)
throw NotConstArgumentException()
function(constants.map { it!!.toDouble() })
} else {
val array = program.heap.get(iterable.heapId!!).array ?: throw SyntaxError("function requires array argument", position)
function(array.map {
if(it.integer!=null)
it.integer.toDouble()
else
throw FatalAstException("cannot perform function over array that contains other values besides constant integers")
})
}
return LiteralValue.fromBoolean(result, position)
}
private fun builtinAbs(args: List<IExpression>, position: Position, program: Program): LiteralValue {
private fun builtinAbs(args: List<Expression>, position: Position, program: Program): NumericLiteralValue {
// 1 arg, type = float or int, result type= isSameAs as argument type
if(args.size!=1)
throw SyntaxError("abs requires one numeric argument", position)
val constval = args[0].constValue(program) ?: throw NotConstArgumentException()
val number = constval.asNumericValue
return when (number) {
is Int, is Byte, is Short -> numericLiteral(abs(number.toInt()), args[0].position)
is Double -> numericLiteral(abs(number.toDouble()), args[0].position)
return when (constval.type) {
in IntegerDatatypes -> numericLiteral(abs(constval.number.toInt()), args[0].position)
DataType.FLOAT -> numericLiteral(abs(constval.number.toDouble()), args[0].position)
else -> throw SyntaxError("abs requires one numeric argument", position)
}
}
private fun builtinAvg(args: List<IExpression>, position: Position, program: Program): LiteralValue {
if(args.size!=1)
throw SyntaxError("avg requires array argument", position)
val iterable = args[0].constValue(program) ?: throw NotConstArgumentException()
val result = if(iterable.arrayvalue!=null) {
val constants = iterable.arrayvalue.map { it.constValue(program)?.asNumericValue }
if (null in constants)
throw NotConstArgumentException()
(constants.map { it!!.toDouble() }).average()
}
else {
val heapId = iterable.heapId!!
val integerarray = program.heap.get(heapId).array
if(integerarray!=null) {
if (integerarray.all { it.integer != null }) {
integerarray.map { it.integer!! }.average()
} else {
throw ExpressionError("cannot avg() over array that does not only contain constant numerical values", position)
}
} else {
val doublearray = program.heap.get(heapId).doubleArray
doublearray?.average() ?: throw SyntaxError("avg requires array argument", position)
}
}
return numericLiteral(result, args[0].position)
}
private fun builtinStrlen(args: List<IExpression>, position: Position, program: Program): LiteralValue {
private fun builtinStrlen(args: List<Expression>, position: Position, program: Program): NumericLiteralValue {
if (args.size != 1)
throw SyntaxError("strlen requires one argument", position)
val argument = args[0].constValue(program) ?: throw NotConstArgumentException()
if(argument.type !in StringDatatypes)
if(argument.type != DataType.STR)
throw SyntaxError("strlen must have string argument", position)
val string = argument.strvalue!!
val zeroIdx = string.indexOf('\u0000')
return if(zeroIdx>=0)
LiteralValue.optimalInteger(zeroIdx, position=position)
else
LiteralValue.optimalInteger(string.length, position=position)
throw NotConstArgumentException() // this function is not considering the string argument a constant
}
private fun builtinLen(args: List<IExpression>, position: Position, program: Program): LiteralValue {
private fun builtinLen(args: List<Expression>, position: Position, program: Program): NumericLiteralValue {
// note: in some cases the length is > 255 and then we have to return a UWORD type instead of a UBYTE.
if(args.size!=1)
throw SyntaxError("len requires one argument", position)
var argument = args[0].constValue(program)
if(argument==null) {
val directMemVar = ((args[0] as? DirectMemoryRead)?.addressExpression as? IdentifierReference)?.targetVarDecl(program.namespace)
val arraySize = directMemVar?.arraysize?.size()
if(arraySize != null)
return LiteralValue.optimalInteger(arraySize, position)
if(args[0] !is IdentifierReference)
throw SyntaxError("len argument should be an identifier, but is ${args[0]}", position)
val target = (args[0] as IdentifierReference).targetStatement(program.namespace)
val argValue = (target as? VarDecl)?.value
argument = argValue?.constValue(program)
?: throw NotConstArgumentException()
}
return when(argument.type) {
val constArg = args[0].constValue(program)
if(constArg!=null)
throw SyntaxError("len of weird argument ${args[0]}", position)
val directMemVar = ((args[0] as? DirectMemoryRead)?.addressExpression as? IdentifierReference)?.targetVarDecl(program.namespace)
var arraySize = directMemVar?.arraysize?.size()
if(arraySize != null)
return NumericLiteralValue.optimalInteger(arraySize, position)
if(args[0] is ArrayLiteralValue)
return NumericLiteralValue.optimalInteger((args[0] as ArrayLiteralValue).value.size, position)
if(args[0] !is IdentifierReference)
throw SyntaxError("len argument should be an identifier, but is ${args[0]}", position)
val target = (args[0] as IdentifierReference).targetVarDecl(program.namespace)!!
return when(target.datatype) {
DataType.ARRAY_UB, DataType.ARRAY_B, DataType.ARRAY_UW, DataType.ARRAY_W -> {
val arraySize = argument.arrayvalue?.size ?: program.heap.get(argument.heapId!!).arraysize
arraySize = target.arraysize!!.size()!!
if(arraySize>256)
throw CompilerException("array length exceeds byte limit ${argument.position}")
LiteralValue.optimalInteger(arraySize, args[0].position)
throw CompilerException("array length exceeds byte limit ${target.position}")
NumericLiteralValue.optimalInteger(arraySize, args[0].position)
}
DataType.ARRAY_F -> {
val arraySize = argument.arrayvalue?.size ?: program.heap.get(argument.heapId!!).arraysize
arraySize = target.arraysize!!.size()!!
if(arraySize>256)
throw CompilerException("array length exceeds byte limit ${argument.position}")
LiteralValue.optimalInteger(arraySize, args[0].position)
throw CompilerException("array length exceeds byte limit ${target.position}")
NumericLiteralValue.optimalInteger(arraySize, args[0].position)
}
in StringDatatypes -> {
val str = argument.strvalue!!
if(str.length>255)
throw CompilerException("string length exceeds byte limit ${argument.position}")
LiteralValue.optimalInteger(str.length, args[0].position)
DataType.STR -> {
val refLv = target.value as StringLiteralValue
if(refLv.value.length>255)
throw CompilerException("string length exceeds byte limit ${refLv.position}")
NumericLiteralValue.optimalInteger(refLv.value.length, args[0].position)
}
in NumericDatatypes -> throw SyntaxError("len of weird argument ${args[0]}", position)
else -> throw CompilerException("weird datatype")
@ -370,80 +280,87 @@ private fun builtinLen(args: List<IExpression>, position: Position, program: Pro
}
private fun builtinMkword(args: List<IExpression>, position: Position, program: Program): LiteralValue {
private fun builtinMkword(args: List<Expression>, position: Position, program: Program): NumericLiteralValue {
if (args.size != 2)
throw SyntaxError("mkword requires lsb and msb arguments", position)
val constLsb = args[0].constValue(program) ?: throw NotConstArgumentException()
val constMsb = args[1].constValue(program) ?: throw NotConstArgumentException()
val result = (constMsb.asIntegerValue!! shl 8) or constLsb.asIntegerValue!!
return LiteralValue(DataType.UWORD, wordvalue = result, position = position)
val result = (constMsb.number.toInt() shl 8) or constLsb.number.toInt()
return NumericLiteralValue(DataType.UWORD, result, position)
}
private fun builtinSin8(args: List<IExpression>, position: Position, program: Program): LiteralValue {
private fun builtinSin8(args: List<Expression>, position: Position, program: Program): NumericLiteralValue {
if (args.size != 1)
throw SyntaxError("sin8 requires one argument", position)
val constval = args[0].constValue(program) ?: throw NotConstArgumentException()
val rad = constval.asNumericValue!!.toDouble() /256.0 * 2.0 * PI
return LiteralValue(DataType.BYTE, bytevalue = (127.0 * sin(rad)).toShort(), position = position)
val rad = constval.number.toDouble() /256.0 * 2.0 * PI
return NumericLiteralValue(DataType.BYTE, (127.0 * sin(rad)).toShort(), position)
}
private fun builtinSin8u(args: List<IExpression>, position: Position, program: Program): LiteralValue {
private fun builtinSin8u(args: List<Expression>, position: Position, program: Program): NumericLiteralValue {
if (args.size != 1)
throw SyntaxError("sin8u requires one argument", position)
val constval = args[0].constValue(program) ?: throw NotConstArgumentException()
val rad = constval.asNumericValue!!.toDouble() /256.0 * 2.0 * PI
return LiteralValue(DataType.UBYTE, bytevalue = (128.0 + 127.5 * sin(rad)).toShort(), position = position)
val rad = constval.number.toDouble() /256.0 * 2.0 * PI
return NumericLiteralValue(DataType.UBYTE, (128.0 + 127.5 * sin(rad)).toShort(), position)
}
private fun builtinCos8(args: List<IExpression>, position: Position, program: Program): LiteralValue {
private fun builtinCos8(args: List<Expression>, position: Position, program: Program): NumericLiteralValue {
if (args.size != 1)
throw SyntaxError("cos8 requires one argument", position)
val constval = args[0].constValue(program) ?: throw NotConstArgumentException()
val rad = constval.asNumericValue!!.toDouble() /256.0 * 2.0 * PI
return LiteralValue(DataType.BYTE, bytevalue = (127.0 * cos(rad)).toShort(), position = position)
val rad = constval.number.toDouble() /256.0 * 2.0 * PI
return NumericLiteralValue(DataType.BYTE, (127.0 * cos(rad)).toShort(), position)
}
private fun builtinCos8u(args: List<IExpression>, position: Position, program: Program): LiteralValue {
private fun builtinCos8u(args: List<Expression>, position: Position, program: Program): NumericLiteralValue {
if (args.size != 1)
throw SyntaxError("cos8u requires one argument", position)
val constval = args[0].constValue(program) ?: throw NotConstArgumentException()
val rad = constval.asNumericValue!!.toDouble() /256.0 * 2.0 * PI
return LiteralValue(DataType.UBYTE, bytevalue = (128.0 + 127.5 * cos(rad)).toShort(), position = position)
val rad = constval.number.toDouble() /256.0 * 2.0 * PI
return NumericLiteralValue(DataType.UBYTE, (128.0 + 127.5 * cos(rad)).toShort(), position)
}
private fun builtinSin16(args: List<IExpression>, position: Position, program: Program): LiteralValue {
private fun builtinSin16(args: List<Expression>, position: Position, program: Program): NumericLiteralValue {
if (args.size != 1)
throw SyntaxError("sin16 requires one argument", position)
val constval = args[0].constValue(program) ?: throw NotConstArgumentException()
val rad = constval.asNumericValue!!.toDouble() /256.0 * 2.0 * PI
return LiteralValue(DataType.WORD, wordvalue = (32767.0 * sin(rad)).toInt(), position = position)
val rad = constval.number.toDouble() /256.0 * 2.0 * PI
return NumericLiteralValue(DataType.WORD, (32767.0 * sin(rad)).toInt(), position)
}
private fun builtinSin16u(args: List<IExpression>, position: Position, program: Program): LiteralValue {
private fun builtinSin16u(args: List<Expression>, position: Position, program: Program): NumericLiteralValue {
if (args.size != 1)
throw SyntaxError("sin16u requires one argument", position)
val constval = args[0].constValue(program) ?: throw NotConstArgumentException()
val rad = constval.asNumericValue!!.toDouble() /256.0 * 2.0 * PI
return LiteralValue(DataType.UWORD, wordvalue = (32768.0 + 32767.5 * sin(rad)).toInt(), position = position)
val rad = constval.number.toDouble() /256.0 * 2.0 * PI
return NumericLiteralValue(DataType.UWORD, (32768.0 + 32767.5 * sin(rad)).toInt(), position)
}
private fun builtinCos16(args: List<IExpression>, position: Position, program: Program): LiteralValue {
private fun builtinCos16(args: List<Expression>, position: Position, program: Program): NumericLiteralValue {
if (args.size != 1)
throw SyntaxError("cos16 requires one argument", position)
val constval = args[0].constValue(program) ?: throw NotConstArgumentException()
val rad = constval.asNumericValue!!.toDouble() /256.0 * 2.0 * PI
return LiteralValue(DataType.WORD, wordvalue = (32767.0 * cos(rad)).toInt(), position = position)
val rad = constval.number.toDouble() /256.0 * 2.0 * PI
return NumericLiteralValue(DataType.WORD, (32767.0 * cos(rad)).toInt(), position)
}
private fun builtinCos16u(args: List<IExpression>, position: Position, program: Program): LiteralValue {
private fun builtinCos16u(args: List<Expression>, position: Position, program: Program): NumericLiteralValue {
if (args.size != 1)
throw SyntaxError("cos16u requires one argument", position)
val constval = args[0].constValue(program) ?: throw NotConstArgumentException()
val rad = constval.asNumericValue!!.toDouble() /256.0 * 2.0 * PI
return LiteralValue(DataType.UWORD, wordvalue = (32768.0 + 32767.5 * cos(rad)).toInt(), position = position)
val rad = constval.number.toDouble() /256.0 * 2.0 * PI
return NumericLiteralValue(DataType.UWORD, (32768.0 + 32767.5 * cos(rad)).toInt(), position)
}
private fun numericLiteral(value: Number, position: Position): LiteralValue {
private fun builtinSgn(args: List<Expression>, position: Position, program: Program): NumericLiteralValue {
if (args.size != 1)
throw SyntaxError("sgn requires one argument", position)
val constval = args[0].constValue(program) ?: throw NotConstArgumentException()
return NumericLiteralValue(DataType.BYTE, constval.number.toDouble().sign.toShort(), position)
}
private fun numericLiteral(value: Number, position: Position): NumericLiteralValue {
val floatNum=value.toDouble()
val tweakedValue: Number =
if(floatNum== floor(floatNum) && (floatNum>=-32768 && floatNum<=65535))
@ -452,11 +369,11 @@ private fun numericLiteral(value: Number, position: Position): LiteralValue {
floatNum
return when(tweakedValue) {
is Int -> LiteralValue.optimalNumeric(value.toInt(), position)
is Short -> LiteralValue.optimalNumeric(value.toInt(), position)
is Byte -> LiteralValue(DataType.UBYTE, bytevalue = value.toShort(), position = position)
is Double -> LiteralValue(DataType.FLOAT, floatvalue = value.toDouble(), position = position)
is Float -> LiteralValue(DataType.FLOAT, floatvalue = value.toDouble(), position = position)
is Int -> NumericLiteralValue.optimalNumeric(value.toInt(), position)
is Short -> NumericLiteralValue.optimalNumeric(value.toInt(), position)
is Byte -> NumericLiteralValue(DataType.UBYTE, value.toShort(), position)
is Double -> NumericLiteralValue(DataType.FLOAT, value.toDouble(), position)
is Float -> NumericLiteralValue(DataType.FLOAT, value.toDouble(), position)
else -> throw FatalAstException("invalid number type ${value::class}")
}
}

82
compiler/src/prog8/optimizer/CallGraph.kt
View File

@ -1,6 +1,10 @@
package prog8.optimizer
import prog8.ast.*
import prog8.ast.INameScope
import prog8.ast.Module
import prog8.ast.Node
import prog8.ast.Program
import prog8.ast.base.DataType
import prog8.ast.base.ParentSentinel
import prog8.ast.base.VarDeclType
import prog8.ast.base.initvarsSubName
@ -10,14 +14,25 @@ import prog8.ast.processing.IAstVisitor
import prog8.ast.statements.*
import prog8.compiler.loadAsmIncludeFile
private val alwaysKeepSubroutines = setOf(
Pair("main", "start"),
Pair("irq", "irq"),
Pair("prog8_lib", "init_system")
)
class CallGraph(private val program: Program): IAstVisitor {
private val asmJumpRx = Regex("""[\-+a-zA-Z0-9_ \t]+(jmp|jsr)[ \t]+(\S+).*""", RegexOption.IGNORE_CASE)
private val asmRefRx = Regex("""[\-+a-zA-Z0-9_ \t]+(...)[ \t]+(\S+).*""", RegexOption.IGNORE_CASE)
class CallGraph(private val program: Program) : IAstVisitor {
val modulesImporting = mutableMapOf<Module, List<Module>>().withDefault { mutableListOf() }
val modulesImportedBy = mutableMapOf<Module, List<Module>>().withDefault { mutableListOf() }
val subroutinesCalling = mutableMapOf<INameScope, List<Subroutine>>().withDefault { mutableListOf() }
val subroutinesCalledBy = mutableMapOf<Subroutine, List<Node>>().withDefault { mutableListOf() }
val usedSymbols = mutableSetOf<IStatement>()
// TODO add dataflow graph: what statements use what variables
val usedSymbols = mutableSetOf<Statement>()
init {
visit(program)
@ -26,9 +41,9 @@ class CallGraph(private val program: Program): IAstVisitor {
fun forAllSubroutines(scope: INameScope, sub: (s: Subroutine) -> Unit) {
fun findSubs(scope: INameScope) {
scope.statements.forEach {
if(it is Subroutine)
if (it is Subroutine)
sub(it)
if(it is INameScope)
if (it is INameScope)
findSubs(it)
}
}
@ -60,7 +75,7 @@ class CallGraph(private val program: Program): IAstVisitor {
}
override fun visit(block: Block) {
if(block.definingModule().isLibraryModule) {
if (block.definingModule().isLibraryModule) {
// make sure the block is not removed
addNodeAndParentScopes(block)
}
@ -70,11 +85,11 @@ class CallGraph(private val program: Program): IAstVisitor {
override fun visit(directive: Directive) {
val thisModule = directive.definingModule()
if(directive.directive=="%import") {
val importedModule: Module = program.modules.single { it.name==directive.args[0].name }
if (directive.directive == "%import") {
val importedModule: Module = program.modules.single { it.name == directive.args[0].name }
modulesImporting[thisModule] = modulesImporting.getValue(thisModule).plus(importedModule)
modulesImportedBy[importedModule] = modulesImportedBy.getValue(importedModule).plus(thisModule)
} else if (directive.directive=="%asminclude") {
} else if (directive.directive == "%asminclude") {
val asm = loadAsmIncludeFile(directive.args[0].str!!, thisModule.source)
val scope = directive.definingScope()
scanAssemblyCode(asm, directive, scope)
@ -86,26 +101,26 @@ class CallGraph(private val program: Program): IAstVisitor {
override fun visit(identifier: IdentifierReference) {
// track symbol usage
val target = identifier.targetStatement(this.program.namespace)
if(target!=null) {
if (target != null) {
addNodeAndParentScopes(target)
}
super.visit(identifier)
}
private fun addNodeAndParentScopes(stmt: IStatement) {
private fun addNodeAndParentScopes(stmt: Statement) {
usedSymbols.add(stmt)
var node: Node=stmt
var node: Node = stmt
do {
if(node is INameScope && node is IStatement) {
if (node is INameScope && node is Statement) {
usedSymbols.add(node)
}
node=node.parent
node = node.parent
} while (node !is Module && node !is ParentSentinel)
}
override fun visit(subroutine: Subroutine) {
if((subroutine.name=="start" && subroutine.definingScope().name=="main")
|| subroutine.name== initvarsSubName || subroutine.definingModule().isLibraryModule) {
if (Pair(subroutine.definingScope().name, subroutine.name) in alwaysKeepSubroutines
|| subroutine.name == initvarsSubName || subroutine.definingModule().isLibraryModule) {
// make sure the entrypoint is mentioned in the used symbols
addNodeAndParentScopes(subroutine)
}
@ -113,16 +128,20 @@ class CallGraph(private val program: Program): IAstVisitor {
}
override fun visit(decl: VarDecl) {
if(decl.autoGenerated || (decl.definingModule().isLibraryModule && decl.type!=VarDeclType.VAR)) {
if (decl.autogeneratedDontRemove || (decl.definingModule().isLibraryModule && decl.type != VarDeclType.VAR)) {
// make sure autogenerated vardecls are in the used symbols
addNodeAndParentScopes(decl)
}
if (decl.datatype == DataType.STRUCT)
addNodeAndParentScopes(decl)
super.visit(decl)
}
override fun visit(functionCall: FunctionCall) {
val otherSub = functionCall.target.targetSubroutine(program.namespace)
if(otherSub!=null) {
if (otherSub != null) {
functionCall.definingSubroutine()?.let { thisSub ->
subroutinesCalling[thisSub] = subroutinesCalling.getValue(thisSub).plus(otherSub)
subroutinesCalledBy[otherSub] = subroutinesCalledBy.getValue(otherSub).plus(functionCall)
@ -133,7 +152,7 @@ class CallGraph(private val program: Program): IAstVisitor {
override fun visit(functionCallStatement: FunctionCallStatement) {
val otherSub = functionCallStatement.target.targetSubroutine(program.namespace)
if(otherSub!=null) {
if (otherSub != null) {
functionCallStatement.definingSubroutine()?.let { thisSub ->
subroutinesCalling[thisSub] = subroutinesCalling.getValue(thisSub).plus(otherSub)
subroutinesCalledBy[otherSub] = subroutinesCalledBy.getValue(otherSub).plus(functionCallStatement)
@ -144,7 +163,7 @@ class CallGraph(private val program: Program): IAstVisitor {
override fun visit(jump: Jump) {
val otherSub = jump.identifier?.targetSubroutine(program.namespace)
if(otherSub!=null) {
if (otherSub != null) {
jump.definingSubroutine()?.let { thisSub ->
subroutinesCalling[thisSub] = subroutinesCalling.getValue(thisSub).plus(otherSub)
subroutinesCalledBy[otherSub] = subroutinesCalledBy.getValue(otherSub).plus(jump)
@ -153,6 +172,11 @@ class CallGraph(private val program: Program): IAstVisitor {
super.visit(jump)
}
override fun visit(structDecl: StructDecl) {
usedSymbols.add(structDecl)
usedSymbols.addAll(structDecl.statements)
}
override fun visit(inlineAssembly: InlineAssembly) {
// parse inline asm for subroutine calls (jmp, jsr)
val scope = inlineAssembly.definingScope()
@ -160,9 +184,7 @@ class CallGraph(private val program: Program): IAstVisitor {
super.visit(inlineAssembly)
}
private fun scanAssemblyCode(asm: String, context: IStatement, scope: INameScope) {
val asmJumpRx = Regex("""[\-+a-zA-Z0-9_ \t]+(jmp|jsr)[ \t]+(\S+).*""", RegexOption.IGNORE_CASE)
val asmRefRx = Regex("""[\-+a-zA-Z0-9_ \t]+(...)[ \t]+(\S+).*""", RegexOption.IGNORE_CASE)
private fun scanAssemblyCode(asm: String, context: Statement, scope: INameScope) {
asm.lines().forEach { line ->
val matches = asmJumpRx.matchEntire(line)
if (matches != null) {
@ -172,7 +194,7 @@ class CallGraph(private val program: Program): IAstVisitor {
if (node is Subroutine) {
subroutinesCalling[scope] = subroutinesCalling.getValue(scope).plus(node)
subroutinesCalledBy[node] = subroutinesCalledBy.getValue(node).plus(context)
} else if(jumptarget.contains('.')) {
} else if (jumptarget.contains('.')) {
// maybe only the first part already refers to a subroutine
val node2 = program.namespace.lookup(listOf(jumptarget.substringBefore('.')), context)
if (node2 is Subroutine) {
@ -184,12 +206,14 @@ class CallGraph(private val program: Program): IAstVisitor {
} else {
val matches2 = asmRefRx.matchEntire(line)
if (matches2 != null) {
val target= matches2.groups[2]?.value
val target = matches2.groups[2]?.value
if (target != null && (target[0].isLetter() || target[0] == '_')) {
val node = program.namespace.lookup(listOf(target.substringBefore('.')), context)
if (node is Subroutine) {
subroutinesCalling[scope] = subroutinesCalling.getValue(scope).plus(node)
subroutinesCalledBy[node] = subroutinesCalledBy.getValue(node).plus(context)
if (target.contains('.')) {
val node = program.namespace.lookup(listOf(target.substringBefore('.')), context)
if (node is Subroutine) {
subroutinesCalling[scope] = subroutinesCalling.getValue(scope).plus(node)
subroutinesCalledBy[node] = subroutinesCalledBy.getValue(node).plus(context)
}
}
}
}

261
compiler/src/prog8/optimizer/ConstExprEvaluator.kt
View File

@ -1,17 +1,14 @@
package prog8.optimizer
import prog8.ast.*
import prog8.ast.base.DataType
import prog8.ast.base.ExpressionError
import prog8.ast.base.FatalAstException
import prog8.ast.base.Position
import prog8.ast.expressions.LiteralValue
import prog8.ast.base.*
import prog8.ast.expressions.Expression
import prog8.ast.expressions.NumericLiteralValue
import kotlin.math.pow
class ConstExprEvaluator {
fun evaluate(left: LiteralValue, operator: String, right: LiteralValue): IExpression {
fun evaluate(left: NumericLiteralValue, operator: String, right: NumericLiteralValue): Expression {
return when(operator) {
"+" -> plus(left, right)
"-" -> minus(left, right)
@ -25,200 +22,188 @@ class ConstExprEvaluator {
"and" -> logicaland(left, right)
"or" -> logicalor(left, right)
"xor" -> logicalxor(left, right)
"<" -> LiteralValue.fromBoolean(left < right, left.position)
">" -> LiteralValue.fromBoolean(left > right, left.position)
"<=" -> LiteralValue.fromBoolean(left <= right, left.position)
">=" -> LiteralValue.fromBoolean(left >= right, left.position)
"==" -> LiteralValue.fromBoolean(left == right, left.position)
"!=" -> LiteralValue.fromBoolean(left != right, left.position)
"<" -> NumericLiteralValue.fromBoolean(left < right, left.position)
">" -> NumericLiteralValue.fromBoolean(left > right, left.position)
"<=" -> NumericLiteralValue.fromBoolean(left <= right, left.position)
">=" -> NumericLiteralValue.fromBoolean(left >= right, left.position)
"==" -> NumericLiteralValue.fromBoolean(left == right, left.position)
"!=" -> NumericLiteralValue.fromBoolean(left != right, left.position)
"<<" -> shiftedleft(left, right)
">>" -> shiftedright(left, right)
else -> throw FatalAstException("const evaluation for invalid operator $operator")
}
}
private fun shiftedright(left: LiteralValue, amount: LiteralValue): IExpression {
if(left.asIntegerValue==null || amount.asIntegerValue==null)
private fun shiftedright(left: NumericLiteralValue, amount: NumericLiteralValue): Expression {
if(left.type !in IntegerDatatypes || amount.type !in IntegerDatatypes)
throw ExpressionError("cannot compute $left >> $amount", left.position)
val result =
if(left.type== DataType.UBYTE || left.type== DataType.UWORD)
left.asIntegerValue.ushr(amount.asIntegerValue)
left.number.toInt().ushr(amount.number.toInt())
else
left.asIntegerValue.shr(amount.asIntegerValue)
return LiteralValue.fromNumber(result, left.type, left.position)
left.number.toInt().shr(amount.number.toInt())
return NumericLiteralValue(left.type, result, left.position)
}
private fun shiftedleft(left: LiteralValue, amount: LiteralValue): IExpression {
if(left.asIntegerValue==null || amount.asIntegerValue==null)
private fun shiftedleft(left: NumericLiteralValue, amount: NumericLiteralValue): Expression {
if(left.type !in IntegerDatatypes || amount.type !in IntegerDatatypes)
throw ExpressionError("cannot compute $left << $amount", left.position)
val result = left.asIntegerValue.shl(amount.asIntegerValue)
return LiteralValue.fromNumber(result, left.type, left.position)
val result = left.number.toInt().shl(amount.number.toInt())
return NumericLiteralValue(left.type, result, left.position)
}
private fun logicalxor(left: LiteralValue, right: LiteralValue): LiteralValue {
private fun logicalxor(left: NumericLiteralValue, right: NumericLiteralValue): NumericLiteralValue {
val error = "cannot compute $left locical-bitxor $right"
return when {
left.asIntegerValue!=null -> when {
right.asIntegerValue!=null -> LiteralValue.fromBoolean((left.asIntegerValue != 0) xor (right.asIntegerValue != 0), left.position)
right.floatvalue!=null -> LiteralValue.fromBoolean((left.asIntegerValue != 0) xor (right.floatvalue != 0.0), left.position)
return when (left.type) {
in IntegerDatatypes -> when (right.type) {
in IntegerDatatypes -> NumericLiteralValue.fromBoolean((left.number.toInt() != 0) xor (right.number.toInt() != 0), left.position)
DataType.FLOAT -> NumericLiteralValue.fromBoolean((left.number.toInt() != 0) xor (right.number.toDouble() != 0.0), left.position)
else -> throw ExpressionError(error, left.position)
}
left.floatvalue!=null -> when {
right.asIntegerValue!=null -> LiteralValue.fromBoolean((left.floatvalue != 0.0) xor (right.asIntegerValue != 0), left.position)
right.floatvalue!=null -> LiteralValue.fromBoolean((left.floatvalue != 0.0) xor (right.floatvalue != 0.0), left.position)
DataType.FLOAT -> when (right.type) {
in IntegerDatatypes -> NumericLiteralValue.fromBoolean((left.number.toDouble() != 0.0) xor (right.number.toInt() != 0), left.position)
DataType.FLOAT -> NumericLiteralValue.fromBoolean((left.number.toDouble() != 0.0) xor (right.number.toDouble() != 0.0), left.position)
else -> throw ExpressionError(error, left.position)
}
else -> throw ExpressionError(error, left.position)
}
}
private fun logicalor(left: LiteralValue, right: LiteralValue): LiteralValue {
private fun logicalor(left: NumericLiteralValue, right: NumericLiteralValue): NumericLiteralValue {
val error = "cannot compute $left locical-or $right"
return when {
left.asIntegerValue!=null -> when {
right.asIntegerValue!=null -> LiteralValue.fromBoolean(left.asIntegerValue != 0 || right.asIntegerValue != 0, left.position)
right.floatvalue!=null -> LiteralValue.fromBoolean(left.asIntegerValue != 0 || right.floatvalue != 0.0, left.position)
return when (left.type) {
in IntegerDatatypes -> when (right.type) {
in IntegerDatatypes -> NumericLiteralValue.fromBoolean(left.number.toInt() != 0 || right.number.toInt() != 0, left.position)
DataType.FLOAT -> NumericLiteralValue.fromBoolean(left.number.toInt() != 0 || right.number.toDouble() != 0.0, left.position)
else -> throw ExpressionError(error, left.position)
}
left.floatvalue!=null -> when {
right.asIntegerValue!=null -> LiteralValue.fromBoolean(left.floatvalue != 0.0 || right.asIntegerValue != 0, left.position)
right.floatvalue!=null -> LiteralValue.fromBoolean(left.floatvalue != 0.0 || right.floatvalue != 0.0, left.position)
DataType.FLOAT -> when (right.type) {
in IntegerDatatypes -> NumericLiteralValue.fromBoolean(left.number.toDouble() != 0.0 || right.number.toInt() != 0, left.position)
DataType.FLOAT -> NumericLiteralValue.fromBoolean(left.number.toDouble() != 0.0 || right.number.toDouble() != 0.0, left.position)
else -> throw ExpressionError(error, left.position)
}
else -> throw ExpressionError(error, left.position)
}
}
private fun logicaland(left: LiteralValue, right: LiteralValue): LiteralValue {
private fun logicaland(left: NumericLiteralValue, right: NumericLiteralValue): NumericLiteralValue {
val error = "cannot compute $left locical-and $right"
return when {
left.asIntegerValue!=null -> when {
right.asIntegerValue!=null -> LiteralValue.fromBoolean(left.asIntegerValue != 0 && right.asIntegerValue != 0, left.position)
right.floatvalue!=null -> LiteralValue.fromBoolean(left.asIntegerValue != 0 && right.floatvalue != 0.0, left.position)
return when (left.type) {
in IntegerDatatypes -> when (right.type) {
in IntegerDatatypes -> NumericLiteralValue.fromBoolean(left.number.toInt() != 0 && right.number.toInt() != 0, left.position)
DataType.FLOAT -> NumericLiteralValue.fromBoolean(left.number.toInt() != 0 && right.number.toDouble() != 0.0, left.position)
else -> throw ExpressionError(error, left.position)
}
left.floatvalue!=null -> when {
right.asIntegerValue!=null -> LiteralValue.fromBoolean(left.floatvalue != 0.0 && right.asIntegerValue != 0, left.position)
right.floatvalue!=null -> LiteralValue.fromBoolean(left.floatvalue != 0.0 && right.floatvalue != 0.0, left.position)
DataType.FLOAT -> when (right.type) {
in IntegerDatatypes -> NumericLiteralValue.fromBoolean(left.number.toDouble() != 0.0 && right.number.toInt() != 0, left.position)
DataType.FLOAT -> NumericLiteralValue.fromBoolean(left.number.toDouble() != 0.0 && right.number.toDouble() != 0.0, left.position)
else -> throw ExpressionError(error, left.position)
}
else -> throw ExpressionError(error, left.position)
}
}
private fun bitwisexor(left: LiteralValue, right: LiteralValue): LiteralValue {
private fun bitwisexor(left: NumericLiteralValue, right: NumericLiteralValue): NumericLiteralValue {
if(left.type== DataType.UBYTE) {
if(right.asIntegerValue!=null) {
return LiteralValue(DataType.UBYTE, bytevalue = (left.bytevalue!!.toInt() xor (right.asIntegerValue and 255)).toShort(), position = left.position)
if(right.type in IntegerDatatypes) {
return NumericLiteralValue(DataType.UBYTE, (left.number.toInt() xor (right.number.toInt() and 255)).toShort(), left.position)
}
} else if(left.type== DataType.UWORD) {
if(right.asIntegerValue!=null) {
return LiteralValue(DataType.UWORD, wordvalue = left.wordvalue!! xor right.asIntegerValue, position = left.position)
if(right.type in IntegerDatatypes) {
return NumericLiteralValue(DataType.UWORD, left.number.toInt() xor right.number.toInt(), left.position)
}
}
throw ExpressionError("cannot calculate $left ^ $right", left.position)
}
private fun bitwiseor(left: LiteralValue, right: LiteralValue): LiteralValue {
private fun bitwiseor(left: NumericLiteralValue, right: NumericLiteralValue): NumericLiteralValue {
if(left.type== DataType.UBYTE) {
if(right.asIntegerValue!=null) {
return LiteralValue(DataType.UBYTE, bytevalue = (left.bytevalue!!.toInt() or (right.asIntegerValue and 255)).toShort(), position = left.position)
if(right.type in IntegerDatatypes) {
return NumericLiteralValue(DataType.UBYTE, (left.number.toInt() or (right.number.toInt() and 255)).toShort(), left.position)
}
} else if(left.type== DataType.UWORD) {
if(right.asIntegerValue!=null) {
return LiteralValue(DataType.UWORD, wordvalue = left.wordvalue!! or right.asIntegerValue, position = left.position)
if(right.type in IntegerDatatypes) {
return NumericLiteralValue(DataType.UWORD, left.number.toInt() or right.number.toInt(), left.position)
}
}
throw ExpressionError("cannot calculate $left | $right", left.position)
}
private fun bitwiseand(left: LiteralValue, right: LiteralValue): LiteralValue {
private fun bitwiseand(left: NumericLiteralValue, right: NumericLiteralValue): NumericLiteralValue {
if(left.type== DataType.UBYTE) {
if(right.asIntegerValue!=null) {
return LiteralValue(DataType.UBYTE, bytevalue = (left.bytevalue!!.toInt() or (right.asIntegerValue and 255)).toShort(), position = left.position)
if(right.type in IntegerDatatypes) {
return NumericLiteralValue(DataType.UBYTE, (left.number.toInt() or (right.number.toInt() and 255)).toShort(), left.position)
}
} else if(left.type== DataType.UWORD) {
if(right.asIntegerValue!=null) {
return LiteralValue(DataType.UWORD, wordvalue = left.wordvalue!! or right.asIntegerValue, position = left.position)
if(right.type in IntegerDatatypes) {
return NumericLiteralValue(DataType.UWORD, left.number.toInt() or right.number.toInt(), left.position)
}
}
throw ExpressionError("cannot calculate $left & $right", left.position)
}
private fun power(left: LiteralValue, right: LiteralValue): LiteralValue {
private fun power(left: NumericLiteralValue, right: NumericLiteralValue): NumericLiteralValue {
val error = "cannot calculate $left ** $right"
return when {
left.asIntegerValue!=null -> when {
right.asIntegerValue!=null -> LiteralValue.optimalNumeric(left.asIntegerValue.toDouble().pow(right.asIntegerValue), left.position)
right.floatvalue!=null -> LiteralValue(DataType.FLOAT, floatvalue = left.asIntegerValue.toDouble().pow(right.floatvalue), position = left.position)
return when (left.type) {
in IntegerDatatypes -> when (right.type) {
in IntegerDatatypes -> NumericLiteralValue.optimalNumeric(left.number.toInt().toDouble().pow(right.number.toInt()), left.position)
DataType.FLOAT -> NumericLiteralValue(DataType.FLOAT, left.number.toInt().toDouble().pow(right.number.toDouble()), left.position)
else -> throw ExpressionError(error, left.position)
}
left.floatvalue!=null -> when {
right.asIntegerValue!=null -> LiteralValue(DataType.FLOAT, floatvalue = left.floatvalue.pow(right.asIntegerValue), position = left.position)
right.floatvalue!=null -> LiteralValue(DataType.FLOAT, floatvalue = left.floatvalue.pow(right.floatvalue), position = left.position)
DataType.FLOAT -> when (right.type) {
in IntegerDatatypes -> NumericLiteralValue(DataType.FLOAT, left.number.toDouble().pow(right.number.toInt()), left.position)
DataType.FLOAT -> NumericLiteralValue(DataType.FLOAT, left.number.toDouble().pow(right.number.toDouble()), left.position)
else -> throw ExpressionError(error, left.position)
}
else -> throw ExpressionError(error, left.position)
}
}
private fun plus(left: LiteralValue, right: LiteralValue): LiteralValue {
private fun plus(left: NumericLiteralValue, right: NumericLiteralValue): NumericLiteralValue {
val error = "cannot add $left and $right"
return when {
left.asIntegerValue!=null -> when {
right.asIntegerValue!=null -> LiteralValue.optimalNumeric(left.asIntegerValue + right.asIntegerValue, left.position)
right.floatvalue!=null -> LiteralValue(DataType.FLOAT, floatvalue = left.asIntegerValue + right.floatvalue, position = left.position)
return when (left.type) {
in IntegerDatatypes -> when (right.type) {
in IntegerDatatypes -> NumericLiteralValue.optimalNumeric(left.number.toInt() + right.number.toInt(), left.position)
DataType.FLOAT -> NumericLiteralValue(DataType.FLOAT, left.number.toInt() + right.number.toDouble(), left.position)
else -> throw ExpressionError(error, left.position)
}
left.floatvalue!=null -> when {
right.asIntegerValue!=null -> LiteralValue(DataType.FLOAT, floatvalue = left.floatvalue + right.asIntegerValue, position = left.position)
right.floatvalue!=null -> LiteralValue(DataType.FLOAT, floatvalue = left.floatvalue + right.floatvalue, position = left.position)
else -> throw ExpressionError(error, left.position)
}
left.isString -> when {
right.isString -> {
val newStr = left.strvalue!! + right.strvalue!!
if(newStr.length > 255) throw ExpressionError("string too long", left.position)
LiteralValue(DataType.STR, strvalue = newStr, position = left.position)
}
DataType.FLOAT -> when (right.type) {
in IntegerDatatypes -> NumericLiteralValue(DataType.FLOAT, left.number.toDouble() + right.number.toInt(), left.position)
DataType.FLOAT -> NumericLiteralValue(DataType.FLOAT, left.number.toDouble() + right.number.toDouble(), left.position)
else -> throw ExpressionError(error, left.position)
}
else -> throw ExpressionError(error, left.position)
}
}
private fun minus(left: LiteralValue, right: LiteralValue): LiteralValue {
private fun minus(left: NumericLiteralValue, right: NumericLiteralValue): NumericLiteralValue {
val error = "cannot subtract $left and $right"
return when {
left.asIntegerValue!=null -> when {
right.asIntegerValue!=null -> LiteralValue.optimalNumeric(left.asIntegerValue - right.asIntegerValue, left.position)
right.floatvalue!=null -> LiteralValue(DataType.FLOAT, floatvalue = left.asIntegerValue - right.floatvalue, position = left.position)
return when (left.type) {
in IntegerDatatypes -> when (right.type) {
in IntegerDatatypes -> NumericLiteralValue.optimalNumeric(left.number.toInt() - right.number.toInt(), left.position)
DataType.FLOAT -> NumericLiteralValue(DataType.FLOAT, left.number.toInt() - right.number.toDouble(), left.position)
else -> throw ExpressionError(error, left.position)
}
left.floatvalue!=null -> when {
right.asIntegerValue!=null -> LiteralValue(DataType.FLOAT, floatvalue = left.floatvalue - right.asIntegerValue, position = left.position)
right.floatvalue!=null -> LiteralValue(DataType.FLOAT, floatvalue = left.floatvalue - right.floatvalue, position = left.position)
DataType.FLOAT -> when (right.type) {
in IntegerDatatypes -> NumericLiteralValue(DataType.FLOAT, left.number.toDouble() - right.number.toInt(), left.position)
DataType.FLOAT -> NumericLiteralValue(DataType.FLOAT, left.number.toDouble() - right.number.toDouble(), left.position)
else -> throw ExpressionError(error, left.position)
}
else -> throw ExpressionError(error, left.position)
}
}
private fun multiply(left: LiteralValue, right: LiteralValue): LiteralValue {
private fun multiply(left: NumericLiteralValue, right: NumericLiteralValue): NumericLiteralValue {
val error = "cannot multiply ${left.type} and ${right.type}"
return when {
left.asIntegerValue!=null -> when {
right.asIntegerValue!=null -> LiteralValue.optimalNumeric(left.asIntegerValue * right.asIntegerValue, left.position)
right.floatvalue!=null -> LiteralValue(DataType.FLOAT, floatvalue = left.asIntegerValue * right.floatvalue, position = left.position)
right.isString -> {
if(right.strvalue!!.length * left.asIntegerValue > 255) throw ExpressionError("string too long", left.position)
LiteralValue(DataType.STR, strvalue = right.strvalue.repeat(left.asIntegerValue), position = left.position)
}
return when (left.type) {
in IntegerDatatypes -> when (right.type) {
in IntegerDatatypes -> NumericLiteralValue.optimalNumeric(left.number.toInt() * right.number.toInt(), left.position)
DataType.FLOAT -> NumericLiteralValue(DataType.FLOAT, left.number.toInt() * right.number.toDouble(), left.position)
else -> throw ExpressionError(error, left.position)
}
left.floatvalue!=null -> when {
right.asIntegerValue!=null -> LiteralValue(DataType.FLOAT, floatvalue = left.floatvalue * right.asIntegerValue, position = left.position)
right.floatvalue!=null -> LiteralValue(DataType.FLOAT, floatvalue = left.floatvalue * right.floatvalue, position = left.position)
DataType.FLOAT -> when (right.type) {
in IntegerDatatypes -> NumericLiteralValue(DataType.FLOAT, left.number.toDouble() * right.number.toInt(), left.position)
DataType.FLOAT -> NumericLiteralValue(DataType.FLOAT, left.number.toDouble() * right.number.toDouble(), left.position)
else -> throw ExpressionError(error, left.position)
}
else -> throw ExpressionError(error, left.position)
@ -228,29 +213,29 @@ class ConstExprEvaluator {
private fun divideByZeroError(pos: Position): Unit =
throw ExpressionError("division by zero", pos)
private fun divide(left: LiteralValue, right: LiteralValue): LiteralValue {
private fun divide(left: NumericLiteralValue, right: NumericLiteralValue): NumericLiteralValue {
val error = "cannot divide $left by $right"
return when {
left.asIntegerValue!=null -> when {
right.asIntegerValue!=null -> {
if(right.asIntegerValue==0) divideByZeroError(right.position)
val result: Int = left.asIntegerValue / right.asIntegerValue
LiteralValue.optimalNumeric(result, left.position)
return when (left.type) {
in IntegerDatatypes -> when (right.type) {
in IntegerDatatypes -> {
if(right.number.toInt()==0) divideByZeroError(right.position)
val result: Int = left.number.toInt() / right.number.toInt()
NumericLiteralValue.optimalNumeric(result, left.position)
}
right.floatvalue!=null -> {
if(right.floatvalue==0.0) divideByZeroError(right.position)
LiteralValue(DataType.FLOAT, floatvalue = left.asIntegerValue / right.floatvalue, position = left.position)
DataType.FLOAT -> {
if(right.number.toDouble()==0.0) divideByZeroError(right.position)
NumericLiteralValue(DataType.FLOAT, left.number.toInt() / right.number.toDouble(), left.position)
}
else -> throw ExpressionError(error, left.position)
}
left.floatvalue!=null -> when {
right.asIntegerValue!=null -> {
if(right.asIntegerValue==0) divideByZeroError(right.position)
LiteralValue(DataType.FLOAT, floatvalue = left.floatvalue / right.asIntegerValue, position = left.position)
DataType.FLOAT -> when (right.type) {
in IntegerDatatypes -> {
if(right.number.toInt()==0) divideByZeroError(right.position)
NumericLiteralValue(DataType.FLOAT, left.number.toDouble() / right.number.toInt(), left.position)
}
right.floatvalue!=null -> {
if(right.floatvalue==0.0) divideByZeroError(right.position)
LiteralValue(DataType.FLOAT, floatvalue = left.floatvalue / right.floatvalue, position = left.position)
DataType.FLOAT -> {
if(right.number.toDouble()==0.0) divideByZeroError(right.position)
NumericLiteralValue(DataType.FLOAT, left.number.toDouble() / right.number.toDouble(), left.position)
}
else -> throw ExpressionError(error, left.position)
}
@ -258,28 +243,28 @@ class ConstExprEvaluator {
}
}
private fun remainder(left: LiteralValue, right: LiteralValue): LiteralValue {
private fun remainder(left: NumericLiteralValue, right: NumericLiteralValue): NumericLiteralValue {
val error = "cannot compute remainder of $left by $right"
return when {
left.asIntegerValue!=null -> when {
right.asIntegerValue!=null -> {
if(right.asIntegerValue==0) divideByZeroError(right.position)
LiteralValue.optimalNumeric(left.asIntegerValue.toDouble() % right.asIntegerValue.toDouble(), left.position)
return when (left.type) {
in IntegerDatatypes -> when (right.type) {
in IntegerDatatypes -> {
if(right.number.toInt()==0) divideByZeroError(right.position)
NumericLiteralValue.optimalNumeric(left.number.toInt().toDouble() % right.number.toInt().toDouble(), left.position)
}
right.floatvalue!=null -> {
if(right.floatvalue==0.0) divideByZeroError(right.position)
LiteralValue(DataType.FLOAT, floatvalue = left.asIntegerValue % right.floatvalue, position = left.position)
DataType.FLOAT -> {
if(right.number.toDouble()==0.0) divideByZeroError(right.position)
NumericLiteralValue(DataType.FLOAT, left.number.toInt() % right.number.toDouble(), left.position)
}
else -> throw ExpressionError(error, left.position)
}
left.floatvalue!=null -> when {
right.asIntegerValue!=null -> {
if(right.asIntegerValue==0) divideByZeroError(right.position)
LiteralValue(DataType.FLOAT, floatvalue = left.floatvalue % right.asIntegerValue, position = left.position)
DataType.FLOAT -> when (right.type) {
in IntegerDatatypes -> {
if(right.number.toInt()==0) divideByZeroError(right.position)
NumericLiteralValue(DataType.FLOAT, left.number.toDouble() % right.number.toInt(), left.position)
}
right.floatvalue!=null -> {
if(right.floatvalue==0.0) divideByZeroError(right.position)
LiteralValue(DataType.FLOAT, floatvalue = left.floatvalue % right.floatvalue, position = left.position)
DataType.FLOAT -> {
if(right.number.toDouble()==0.0) divideByZeroError(right.position)
NumericLiteralValue(DataType.FLOAT, left.number.toDouble() % right.number.toDouble(), left.position)
}
else -> throw ExpressionError(error, left.position)
}

459
compiler/src/prog8/optimizer/ConstantFolding.kt
View File

@ -1,21 +1,19 @@
package prog8.optimizer
import prog8.ast.*
import prog8.ast.IFunctionCall
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.ast.processing.IAstModifyingVisitor
import prog8.ast.statements.*
import prog8.compiler.HeapValues
import prog8.compiler.IntegerOrAddressOf
import prog8.compiler.target.c64.FLOAT_MAX_NEGATIVE
import prog8.compiler.target.c64.FLOAT_MAX_POSITIVE
import prog8.compiler.target.CompilationTarget
import prog8.functions.BuiltinFunctions
import kotlin.math.floor
class ConstantFolding(private val program: Program) : IAstModifyingVisitor {
var optimizationsDone: Int = 0
var errors : MutableList<AstException> = mutableListOf()
private val reportedErrorMessages = mutableSetOf<String>()
fun addError(x: AstException) {
@ -26,30 +24,27 @@ class ConstantFolding(private val program: Program) : IAstModifyingVisitor {
}
}
override fun visit(decl: VarDecl): IStatement {
override fun visit(decl: VarDecl): Statement {
// the initializer value can't refer to the variable itself (recursive definition)
if(decl.value?.referencesIdentifier(decl.name) == true || decl.arraysize?.index?.referencesIdentifier(decl.name) == true) {
// TODO: use call tree for this?
if(decl.value?.referencesIdentifiers(decl.name) == true || decl.arraysize?.index?.referencesIdentifiers(decl.name) == true) {
errors.add(ExpressionError("recursive var declaration", decl.position))
return decl
}
if(decl.type==VarDeclType.CONST || decl.type==VarDeclType.VAR) {
val litval = decl.value as? LiteralValue
if(litval!=null && litval.isArray && litval.heapId!=null)
fixupArrayTypeOnHeap(decl, litval)
if(decl.isArray){
// for arrays that have no size specifier (or a non-constant one) attempt to deduce the size
if(decl.arraysize==null) {
val arrayval = (decl.value as? LiteralValue)?.arrayvalue
// for arrays that have no size specifier (or a non-constant one) attempt to deduce the size
val arrayval = decl.value as? ArrayLiteralValue
if(arrayval!=null) {
decl.arraysize = ArrayIndex(LiteralValue.optimalInteger(arrayval.size, decl.position), decl.position)
decl.arraysize = ArrayIndex(NumericLiteralValue.optimalInteger(arrayval.value.size, decl.position), decl.position)
optimizationsDone++
}
}
else if(decl.arraysize?.size()==null) {
val size = decl.arraysize!!.index.accept(this)
if(size is LiteralValue) {
if(size is NumericLiteralValue) {
decl.arraysize = ArrayIndex(size, decl.position)
optimizationsDone++
}
@ -59,92 +54,98 @@ class ConstantFolding(private val program: Program) : IAstModifyingVisitor {
when(decl.datatype) {
DataType.FLOAT -> {
// vardecl: for scalar float vars, promote constant integer initialization values to floats
if (litval != null && litval.type in IntegerDatatypes) {
val newValue = LiteralValue(DataType.FLOAT, floatvalue = litval.asNumericValue!!.toDouble(), position = litval.position)
val litval = decl.value as? NumericLiteralValue
if (litval!=null && litval.type in IntegerDatatypes) {
val newValue = NumericLiteralValue(DataType.FLOAT, litval.number.toDouble(), litval.position)
decl.value = newValue
optimizationsDone++
return decl
return super.visit(decl)
}
}
DataType.ARRAY_UB, DataType.ARRAY_B, DataType.ARRAY_UW, DataType.ARRAY_W -> {
val numericLv = decl.value as? NumericLiteralValue
val rangeExpr = decl.value as? RangeExpr
if(rangeExpr!=null) {
// convert the initializer range expression to an actual array (will be put on heap later)
// convert the initializer range expression to an actual array
val declArraySize = decl.arraysize?.size()
if(declArraySize!=null && declArraySize!=rangeExpr.size())
errors.add(ExpressionError("range expression size doesn't match declared array size", decl.value?.position!!))
val constRange = rangeExpr.toConstantIntegerRange()
if(constRange!=null) {
val eltType = rangeExpr.inferType(program)!!
val eltType = rangeExpr.inferType(program).typeOrElse(DataType.UBYTE)
if(eltType in ByteDatatypes) {
decl.value = LiteralValue(decl.datatype,
arrayvalue = constRange.map { LiteralValue(eltType, bytevalue = it.toShort(), position = decl.value!!.position) }
.toTypedArray(), position = decl.value!!.position)
decl.value = ArrayLiteralValue(InferredTypes.InferredType.known(decl.datatype),
constRange.map { NumericLiteralValue(eltType, it.toShort(), decl.value!!.position) }.toTypedArray(),
position = decl.value!!.position)
} else {
decl.value = LiteralValue(decl.datatype,
arrayvalue = constRange.map { LiteralValue(eltType, wordvalue = it, position = decl.value!!.position) }
.toTypedArray(), position = decl.value!!.position)
decl.value = ArrayLiteralValue(InferredTypes.InferredType.known(decl.datatype),
constRange.map { NumericLiteralValue(eltType, it, decl.value!!.position) }.toTypedArray(),
position = decl.value!!.position)
}
decl.value!!.linkParents(decl)
optimizationsDone++
return decl
return super.visit(decl)
}
}
if(litval?.type== DataType.FLOAT)
errors.add(ExpressionError("arraysize requires only integers here", litval.position))
if(numericLv!=null && numericLv.type== DataType.FLOAT)
errors.add(ExpressionError("arraysize requires only integers here", numericLv.position))
val size = decl.arraysize?.size() ?: return decl
if ((litval==null || !litval.isArray) && rangeExpr==null) {
if (rangeExpr==null && numericLv!=null) {
// arraysize initializer is empty or a single int, and we know the size; create the arraysize.
val fillvalue = if (litval == null) 0 else litval.asIntegerValue ?: 0
val fillvalue = numericLv.number.toInt()
when(decl.datatype){
DataType.ARRAY_UB -> {
if(fillvalue !in 0..255)
errors.add(ExpressionError("ubyte value overflow", litval?.position
?: decl.position))
errors.add(ExpressionError("ubyte value overflow", numericLv.position))
}
DataType.ARRAY_B -> {
if(fillvalue !in -128..127)
errors.add(ExpressionError("byte value overflow", litval?.position
?: decl.position))
errors.add(ExpressionError("byte value overflow", numericLv.position))
}
DataType.ARRAY_UW -> {
if(fillvalue !in 0..65535)
errors.add(ExpressionError("uword value overflow", litval?.position
?: decl.position))
errors.add(ExpressionError("uword value overflow", numericLv.position))
}
DataType.ARRAY_W -> {
if(fillvalue !in -32768..32767)
errors.add(ExpressionError("word value overflow", litval?.position
?: decl.position))
errors.add(ExpressionError("word value overflow", numericLv.position))
}
else -> {}
}
val heapId = program.heap.addIntegerArray(decl.datatype, Array(size) { IntegerOrAddressOf(fillvalue, null) })
decl.value = LiteralValue(decl.datatype, initHeapId = heapId, position = litval?.position
?: decl.position)
// create the array itself, filled with the fillvalue.
val array = Array(size) {fillvalue}.map { NumericLiteralValue.optimalInteger(it, numericLv.position) as Expression}.toTypedArray()
val refValue = ArrayLiteralValue(InferredTypes.InferredType.known(decl.datatype), array, position = numericLv.position)
decl.value = refValue
refValue.parent=decl
optimizationsDone++
return decl
return super.visit(decl)
}
}
DataType.ARRAY_F -> {
val size = decl.arraysize?.size() ?: return decl
if (litval==null || !litval.isArray) {
// arraysize initializer is empty or a single int, and we know the size; create the arraysize.
val fillvalue = if (litval == null) 0.0 else litval.asNumericValue?.toDouble() ?: 0.0
if(fillvalue< FLOAT_MAX_NEGATIVE || fillvalue> FLOAT_MAX_POSITIVE)
errors.add(ExpressionError("float value overflow", litval?.position
?: decl.position))
val litval = decl.value as? NumericLiteralValue
if(litval==null) {
// there's no initialization value, but the size is known, so we're ok.
return super.visit(decl)
} else {
// arraysize initializer is a single int, and we know the size.
val fillvalue = litval.number.toDouble()
if (fillvalue < CompilationTarget.machine.FLOAT_MAX_NEGATIVE || fillvalue > CompilationTarget.machine.FLOAT_MAX_POSITIVE)
errors.add(ExpressionError("float value overflow", litval.position))
else {
val heapId = program.heap.addDoublesArray(DoubleArray(size) { fillvalue })
decl.value = LiteralValue(DataType.ARRAY_F, initHeapId = heapId, position = litval?.position
?: decl.position)
// create the array itself, filled with the fillvalue.
val array = Array(size) {fillvalue}.map { NumericLiteralValue(DataType.FLOAT, it, litval.position) as Expression}.toTypedArray()
val refValue = ArrayLiteralValue(InferredTypes.InferredType.known(DataType.ARRAY_F), array, position = litval.position)
decl.value = refValue
refValue.parent=decl
optimizationsDone++
return decl
return super.visit(decl)
}
}
}
else -> {
// nothing to do for this type
// this includes strings and structs
}
}
}
@ -152,55 +153,40 @@ class ConstantFolding(private val program: Program) : IAstModifyingVisitor {
return super.visit(decl)
}
private fun fixupArrayTypeOnHeap(decl: VarDecl, litval: LiteralValue) {
// fix the type of the array value that's on the heap, to match the vardecl.
// notice that checking the bounds of the actual values is not done here, but in the AstChecker later.
if(decl.datatype==litval.type)
return // already correct datatype
val heapId = litval.heapId ?: throw FatalAstException("expected array to be on heap $litval")
val array = program.heap.get(heapId)
when(decl.datatype) {
DataType.ARRAY_UB, DataType.ARRAY_B, DataType.ARRAY_UW, DataType.ARRAY_W -> {
if(array.array!=null) {
program.heap.update(heapId, HeapValues.HeapValue(decl.datatype, null, array.array, null))
decl.value = LiteralValue(decl.datatype, initHeapId = heapId, position = litval.position)
}
}
DataType.ARRAY_F -> {
if(array.array!=null) {
// convert a non-float array to floats
val doubleArray = array.array.map { it.integer!!.toDouble() }.toDoubleArray()
program.heap.update(heapId, HeapValues.HeapValue(DataType.ARRAY_F, null, null, doubleArray))
decl.value = LiteralValue(decl.datatype, initHeapId = heapId, position = litval.position)
}
}
else -> throw FatalAstException("invalid array vardecl type ${decl.datatype}")
}
}
/**
* replace identifiers that refer to const value, with the value itself (if it's a simple type)
*/
override fun visit(identifier: IdentifierReference): IExpression {
override fun visit(identifier: IdentifierReference): Expression {
// don't replace when it's an assignment target or loop variable
if(identifier.parent is AssignTarget)
return identifier
var forloop = identifier.parent as? ForLoop
if(forloop==null)
forloop = identifier.parent.parent as? ForLoop
if(forloop!=null && identifier===forloop.loopVar)
return identifier
return try {
val cval = identifier.constValue(program) ?: return identifier
return if(cval.isNumeric) {
val copy = LiteralValue(cval.type, cval.bytevalue, cval.wordvalue, cval.floatvalue, null, cval.arrayvalue, position = identifier.position)
copy.parent = identifier.parent
copy
} else
identifier
return when (cval.type) {
in NumericDatatypes -> {
val copy = NumericLiteralValue(cval.type, cval.number, identifier.position)
copy.parent = identifier.parent
copy
}
in PassByReferenceDatatypes -> throw FatalAstException("pass-by-reference type should not be considered a constant")
else -> identifier
}
} catch (ax: AstException) {
addError(ax)
identifier
}
}
override fun visit(functionCall: FunctionCall): IExpression {
override fun visit(functionCall: FunctionCall): Expression {
super.visit(functionCall)
typeCastConstArguments(functionCall)
return try {
super.visit(functionCall)
typeCastConstArguments(functionCall)
functionCall.constValue(program) ?: functionCall
} catch (ax: AstException) {
addError(ax)
@ -208,31 +194,46 @@ class ConstantFolding(private val program: Program) : IAstModifyingVisitor {
}
}
override fun visit(functionCallStatement: FunctionCallStatement): IStatement {
override fun visit(functionCallStatement: FunctionCallStatement): Statement {
super.visit(functionCallStatement)
typeCastConstArguments(functionCallStatement)
return functionCallStatement
}
private fun typeCastConstArguments(functionCall: IFunctionCall) {
if(functionCall.target.nameInSource.size==1) {
val builtinFunction = BuiltinFunctions[functionCall.target.nameInSource.single()]
if(builtinFunction!=null) {
// match the arguments of a builtin function signature.
for(arg in functionCall.args.withIndex().zip(builtinFunction.parameters)) {
val possibleDts = arg.second.possibleDatatypes
val argConst = arg.first.value.constValue(program)
if(argConst!=null && argConst.type !in possibleDts) {
val convertedValue = argConst.cast(possibleDts.first())
functionCall.args[arg.first.index] = convertedValue
optimizationsDone++
}
}
return
}
}
// match the arguments of a subroutine.
val subroutine = functionCall.target.targetSubroutine(program.namespace)
if(subroutine!=null) {
// if types differ, try to typecast constant arguments to the function call to the desired data type of the parameter
for(arg in functionCall.arglist.withIndex().zip(subroutine.parameters)) {
for(arg in functionCall.args.withIndex().zip(subroutine.parameters)) {
val expectedDt = arg.second.type
val argConst = arg.first.value.constValue(program)
if(argConst!=null && argConst.type!=expectedDt) {
val convertedValue = argConst.cast(expectedDt)
if(convertedValue!=null) {
functionCall.arglist[arg.first.index] = convertedValue
optimizationsDone++
}
functionCall.args[arg.first.index] = convertedValue
optimizationsDone++
}
}
}
}
override fun visit(memread: DirectMemoryRead): IExpression {
override fun visit(memread: DirectMemoryRead): Expression {
// @( &thing ) --> thing
val addrOf = memread.addressExpression as? AddressOf
if(addrOf!=null)
@ -245,48 +246,43 @@ class ConstantFolding(private val program: Program) : IAstModifyingVisitor {
* Compile-time constant sub expressions will be evaluated on the spot.
* For instance, the expression for "- 4.5" will be optimized into the float literal -4.5
*/
override fun visit(expr: PrefixExpression): IExpression {
override fun visit(expr: PrefixExpression): Expression {
return try {
super.visit(expr)
val prefixExpr=super.visit(expr)
if(prefixExpr !is PrefixExpression)
return prefixExpr
val subexpr = expr.expression
if (subexpr is LiteralValue) {
val subexpr = prefixExpr.expression
if (subexpr is NumericLiteralValue) {
// accept prefixed literal values (such as -3, not true)
return when {
expr.operator == "+" -> subexpr
expr.operator == "-" -> when {
subexpr.asIntegerValue!= null -> {
return when (prefixExpr.operator) {
"+" -> subexpr
"-" -> when (subexpr.type) {
in IntegerDatatypes -> {
optimizationsDone++
LiteralValue.optimalNumeric(-subexpr.asIntegerValue, subexpr.position)
NumericLiteralValue.optimalNumeric(-subexpr.number.toInt(), subexpr.position)
}
subexpr.floatvalue != null -> {
DataType.FLOAT -> {
optimizationsDone++
LiteralValue(DataType.FLOAT, floatvalue = -subexpr.floatvalue, position = subexpr.position)
NumericLiteralValue(DataType.FLOAT, -subexpr.number.toDouble(), subexpr.position)
}
else -> throw ExpressionError("can only take negative of int or float", subexpr.position)
}
expr.operator == "~" -> when {
subexpr.asIntegerValue != null -> {
"~" -> when (subexpr.type) {
in IntegerDatatypes -> {
optimizationsDone++
LiteralValue.optimalNumeric(subexpr.asIntegerValue.inv(), subexpr.position)
NumericLiteralValue.optimalNumeric(subexpr.number.toInt().inv(), subexpr.position)
}
else -> throw ExpressionError("can only take bitwise inversion of int", subexpr.position)
}
expr.operator == "not" -> when {
subexpr.asIntegerValue != null -> {
optimizationsDone++
LiteralValue.fromBoolean(subexpr.asIntegerValue == 0, subexpr.position)
}
subexpr.floatvalue != null -> {
optimizationsDone++
LiteralValue.fromBoolean(subexpr.floatvalue == 0.0, subexpr.position)
}
else -> throw ExpressionError("can not take logical not of $subexpr", subexpr.position)
"not" -> {
optimizationsDone++
NumericLiteralValue.fromBoolean(subexpr.number.toDouble() == 0.0, subexpr.position)
}
else -> throw ExpressionError(expr.operator, subexpr.position)
else -> throw ExpressionError(prefixExpr.operator, subexpr.position)
}
}
return expr
return prefixExpr
} catch (ax: AstException) {
addError(ax)
expr
@ -310,9 +306,14 @@ class ConstantFolding(private val program: Program) : IAstModifyingVisitor {
* (X / c1) * c2 -> X / (c2/c1)
* (X + c1) - c2 -> X + (c1-c2)
*/
override fun visit(expr: BinaryExpression): IExpression {
override fun visit(expr: BinaryExpression): Expression {
return try {
super.visit(expr)
if(expr.left is StringLiteralValue || expr.left is ArrayLiteralValue
|| expr.right is StringLiteralValue || expr.right is ArrayLiteralValue)
throw FatalAstException("binexpr with reference litval instead of numeric")
val leftconst = expr.left.constValue(program)
val rightconst = expr.right.constValue(program)
@ -333,12 +334,13 @@ class ConstantFolding(private val program: Program) : IAstModifyingVisitor {
}
// const fold when both operands are a const
val evaluator = ConstExprEvaluator()
return when {
leftconst != null && rightconst != null -> {
optimizationsDone++
val evaluator = ConstExprEvaluator()
evaluator.evaluate(leftconst, expr.operator, rightconst)
}
else -> expr
}
} catch (ax: AstException) {
@ -352,9 +354,9 @@ class ConstantFolding(private val program: Program) : IAstModifyingVisitor {
leftIsConst: Boolean,
rightIsConst: Boolean,
subleftIsConst: Boolean,
subrightIsConst: Boolean): IExpression
subrightIsConst: Boolean): Expression
{
// @todo this implements only a small set of possible reorderings for now
// todo: this implements only a small set of possible reorderings at this time
if(expr.operator==subExpr.operator) {
// both operators are the isSameAs.
// If + or *, we can simply swap the const of expr and Var in subexpr.
@ -539,177 +541,170 @@ class ConstantFolding(private val program: Program) : IAstModifyingVisitor {
}
}
override fun visit(forLoop: ForLoop): IStatement {
override fun visit(forLoop: ForLoop): Statement {
fun adjustRangeDt(rangeFrom: LiteralValue, targetDt: DataType, rangeTo: LiteralValue, stepLiteral: LiteralValue?, range: RangeExpr): RangeExpr {
val newFrom = rangeFrom.cast(targetDt)
val newTo = rangeTo.cast(targetDt)
if (newFrom != null && newTo != null) {
val newStep: IExpression =
if (stepLiteral != null) (stepLiteral.cast(targetDt) ?: stepLiteral) else range.step
return RangeExpr(newFrom, newTo, newStep, range.position)
fun adjustRangeDt(rangeFrom: NumericLiteralValue, targetDt: DataType, rangeTo: NumericLiteralValue, stepLiteral: NumericLiteralValue?, range: RangeExpr): RangeExpr {
val newFrom: NumericLiteralValue
val newTo: NumericLiteralValue
try {
newFrom = rangeFrom.cast(targetDt)
newTo = rangeTo.cast(targetDt)
} catch (x: ExpressionError) {
return range
}
val newStep: Expression = try {
stepLiteral?.cast(targetDt)?: range.step
} catch(ee: ExpressionError) {
range.step
}
return RangeExpr(newFrom, newTo, newStep, range.position)
}
val forLoop2 = super.visit(forLoop) as ForLoop
// check if we need to adjust an array literal to the loop variable's datatype
val array = forLoop2.iterable as? ArrayLiteralValue
if(array!=null) {
val loopvarDt: DataType = when {
forLoop.loopVar!=null -> forLoop.loopVar!!.inferType(program).typeOrElse(DataType.UBYTE)
forLoop.loopRegister!=null -> DataType.UBYTE
else -> throw FatalAstException("weird for loop")
}
val arrayType = when(loopvarDt) {
DataType.UBYTE -> DataType.ARRAY_UB
DataType.BYTE -> DataType.ARRAY_B
DataType.UWORD -> DataType.ARRAY_UW
DataType.WORD -> DataType.ARRAY_W
DataType.FLOAT -> DataType.ARRAY_F
else -> throw FatalAstException("invalid array elt type")
}
val array2 = array.cast(arrayType)
if(array2!=null && array2!==array) {
forLoop2.iterable = array2
array2.linkParents(forLoop2)
}
return range
}
// adjust the datatype of a range expression in for loops to the loop variable.
val resultStmt = super.visit(forLoop) as ForLoop
val iterableRange = resultStmt.iterable as? RangeExpr ?: return resultStmt
val rangeFrom = iterableRange.from as? LiteralValue
val rangeTo = iterableRange.to as? LiteralValue
if(rangeFrom==null || rangeTo==null) return resultStmt
val iterableRange = forLoop2.iterable as? RangeExpr ?: return forLoop2
val rangeFrom = iterableRange.from as? NumericLiteralValue
val rangeTo = iterableRange.to as? NumericLiteralValue
if(rangeFrom==null || rangeTo==null) return forLoop2
val loopvar = resultStmt.loopVar?.targetVarDecl(program.namespace)
val loopvar = forLoop2.loopVar?.targetVarDecl(program.namespace)
if(loopvar!=null) {
val stepLiteral = iterableRange.step as? LiteralValue
val stepLiteral = iterableRange.step as? NumericLiteralValue
when(loopvar.datatype) {
DataType.UBYTE -> {
if(rangeFrom.type!= DataType.UBYTE) {
// attempt to translate the iterable into ubyte values
resultStmt.iterable = adjustRangeDt(rangeFrom, loopvar.datatype, rangeTo, stepLiteral, iterableRange)
forLoop2.iterable = adjustRangeDt(rangeFrom, loopvar.datatype, rangeTo, stepLiteral, iterableRange)
}
}
DataType.BYTE -> {
if(rangeFrom.type!= DataType.BYTE) {
// attempt to translate the iterable into byte values
resultStmt.iterable = adjustRangeDt(rangeFrom, loopvar.datatype, rangeTo, stepLiteral, iterableRange)
forLoop2.iterable = adjustRangeDt(rangeFrom, loopvar.datatype, rangeTo, stepLiteral, iterableRange)
}
}
DataType.UWORD -> {
if(rangeFrom.type!= DataType.UWORD) {
// attempt to translate the iterable into uword values
resultStmt.iterable = adjustRangeDt(rangeFrom, loopvar.datatype, rangeTo, stepLiteral, iterableRange)
forLoop2.iterable = adjustRangeDt(rangeFrom, loopvar.datatype, rangeTo, stepLiteral, iterableRange)
}
}
DataType.WORD -> {
if(rangeFrom.type!= DataType.WORD) {
// attempt to translate the iterable into word values
resultStmt.iterable = adjustRangeDt(rangeFrom, loopvar.datatype, rangeTo, stepLiteral, iterableRange)
forLoop2.iterable = adjustRangeDt(rangeFrom, loopvar.datatype, rangeTo, stepLiteral, iterableRange)
}
}
else -> throw FatalAstException("invalid loopvar datatype $loopvar")
}
}
return resultStmt
return forLoop2
}
override fun visit(literalValue: LiteralValue): LiteralValue {
val litval = super.visit(literalValue)
if(litval.isString) {
// intern the string; move it into the heap
if(litval.strvalue!!.length !in 1..255)
addError(ExpressionError("string literal length must be between 1 and 255", litval.position))
else {
litval.addToHeap(program.heap) // TODO: we don't know the actual string type yet, STR != STR_S etc...
override fun visit(arrayLiteral: ArrayLiteralValue): Expression {
// because constant folding can result in arrays that are now suddenly capable
// of telling the type of all their elements (for instance, when they contained -2 which
// was a prefix expression earlier), we recalculate the array's datatype.
val array = super.visit(arrayLiteral)
if(array is ArrayLiteralValue) {
if(array.type.isKnown)
return array
val arrayDt = array.guessDatatype(program)
if(arrayDt.isKnown) {
val newArray = arrayLiteral.cast(arrayDt.typeOrElse(DataType.STRUCT))
if(newArray!=null)
return newArray
}
} else if(litval.arrayvalue!=null) {
// first, adjust the array datatype
val litval2 = adjustArrayValDatatype(litval)
litval2.addToHeap(program.heap)
return litval2
}
return litval
return array
}
private fun adjustArrayValDatatype(litval: LiteralValue): LiteralValue {
val array = litval.arrayvalue!!
val typesInArray = array.mapNotNull { it.inferType(program) }.toSet()
val arrayDt =
when {
array.any { it is AddressOf } -> DataType.ARRAY_UW
DataType.FLOAT in typesInArray -> DataType.ARRAY_F
DataType.WORD in typesInArray -> DataType.ARRAY_W
else -> {
val allElementsAreConstantOrAddressOf = array.fold(true) { c, expr-> c and (expr is LiteralValue || expr is AddressOf)}
if(!allElementsAreConstantOrAddressOf) {
addError(ExpressionError("array literal can only consist of constant primitive numerical values or memory pointers", litval.position))
return litval
} else {
val integerArray = array.map { it.constValue(program)!!.asIntegerValue!! }
val maxValue = integerArray.max()!!
val minValue = integerArray.min()!!
if (minValue >= 0) {
// unsigned
if (maxValue <= 255)
DataType.ARRAY_UB
else
DataType.ARRAY_UW
} else {
// signed
if (maxValue <= 127)
DataType.ARRAY_B
else
DataType.ARRAY_W
}
}
}
}
if(arrayDt!=litval.type) {
return LiteralValue(arrayDt, arrayvalue = litval.arrayvalue, position = litval.position)
}
return litval
}
override fun visit(assignment: Assignment): IStatement {
override fun visit(assignment: Assignment): Statement {
super.visit(assignment)
val lv = assignment.value as? LiteralValue
val lv = assignment.value as? NumericLiteralValue
if(lv!=null) {
// see if we can promote/convert a literal value to the required datatype
when(assignment.singleTarget?.inferType(program, assignment)) {
val idt = assignment.target.inferType(program, assignment)
if(!idt.isKnown)
return assignment
when(idt.typeOrElse(DataType.STRUCT)) {
DataType.UWORD -> {
// we can convert to UWORD: any UBYTE, BYTE/WORD that are >=0, FLOAT that's an integer 0..65535,
if(lv.type== DataType.UBYTE)
assignment.value = LiteralValue(DataType.UWORD, wordvalue = lv.asIntegerValue, position = lv.position)
else if(lv.type== DataType.BYTE && lv.bytevalue!!>=0)
assignment.value = LiteralValue(DataType.UWORD, wordvalue = lv.asIntegerValue, position = lv.position)
else if(lv.type== DataType.WORD && lv.wordvalue!!>=0)
assignment.value = LiteralValue(DataType.UWORD, wordvalue = lv.asIntegerValue, position = lv.position)
assignment.value = NumericLiteralValue(DataType.UWORD, lv.number.toInt(), lv.position)
else if(lv.type== DataType.BYTE && lv.number.toInt()>=0)
assignment.value = NumericLiteralValue(DataType.UWORD, lv.number.toInt(), lv.position)
else if(lv.type== DataType.WORD && lv.number.toInt()>=0)
assignment.value = NumericLiteralValue(DataType.UWORD, lv.number.toInt(), lv.position)
else if(lv.type== DataType.FLOAT) {
val d = lv.floatvalue!!
val d = lv.number.toDouble()
if(floor(d)==d && d>=0 && d<=65535)
assignment.value = LiteralValue(DataType.UWORD, wordvalue = floor(d).toInt(), position = lv.position)
assignment.value = NumericLiteralValue(DataType.UWORD, floor(d).toInt(), lv.position)
}
}
DataType.UBYTE -> {
// we can convert to UBYTE: UWORD <=255, BYTE >=0, FLOAT that's an integer 0..255,
if(lv.type== DataType.UWORD && lv.wordvalue!! <= 255)
assignment.value = LiteralValue(DataType.UBYTE, lv.wordvalue.toShort(), position = lv.position)
else if(lv.type== DataType.BYTE && lv.bytevalue!! >=0)
assignment.value = LiteralValue(DataType.UBYTE, lv.bytevalue.toShort(), position = lv.position)
if(lv.type== DataType.UWORD && lv.number.toInt() <= 255)
assignment.value = NumericLiteralValue(DataType.UBYTE, lv.number.toShort(), lv.position)
else if(lv.type== DataType.BYTE && lv.number.toInt() >=0)
assignment.value = NumericLiteralValue(DataType.UBYTE, lv.number.toShort(), lv.position)
else if(lv.type== DataType.FLOAT) {
val d = lv.floatvalue!!
val d = lv.number.toDouble()
if(floor(d)==d && d >=0 && d<=255)
assignment.value = LiteralValue(DataType.UBYTE, floor(d).toShort(), position = lv.position)
assignment.value = NumericLiteralValue(DataType.UBYTE, floor(d).toShort(), lv.position)
}
}
DataType.BYTE -> {
// we can convert to BYTE: UWORD/UBYTE <= 127, FLOAT that's an integer 0..127
if(lv.type== DataType.UWORD && lv.wordvalue!! <= 127)
assignment.value = LiteralValue(DataType.BYTE, lv.wordvalue.toShort(), position = lv.position)
else if(lv.type== DataType.UBYTE && lv.bytevalue!! <= 127)
assignment.value = LiteralValue(DataType.BYTE, lv.bytevalue, position = lv.position)
if(lv.type== DataType.UWORD && lv.number.toInt() <= 127)
assignment.value = NumericLiteralValue(DataType.BYTE, lv.number.toShort(), lv.position)
else if(lv.type== DataType.UBYTE && lv.number.toInt() <= 127)
assignment.value = NumericLiteralValue(DataType.BYTE, lv.number.toShort(), lv.position)
else if(lv.type== DataType.FLOAT) {
val d = lv.floatvalue!!
val d = lv.number.toDouble()
if(floor(d)==d && d>=0 && d<=127)
assignment.value = LiteralValue(DataType.BYTE, floor(d).toShort(), position = lv.position)
assignment.value = NumericLiteralValue(DataType.BYTE, floor(d).toShort(), lv.position)
}
}
DataType.WORD -> {
// we can convert to WORD: any UBYTE/BYTE, UWORD <= 32767, FLOAT that's an integer -32768..32767,
if(lv.type== DataType.UBYTE || lv.type== DataType.BYTE)
assignment.value = LiteralValue(DataType.WORD, wordvalue = lv.bytevalue!!.toInt(), position = lv.position)
else if(lv.type== DataType.UWORD && lv.wordvalue!! <= 32767)
assignment.value = LiteralValue(DataType.WORD, wordvalue = lv.wordvalue, position = lv.position)
assignment.value = NumericLiteralValue(DataType.WORD, lv.number.toInt(), lv.position)
else if(lv.type== DataType.UWORD && lv.number.toInt() <= 32767)
assignment.value = NumericLiteralValue(DataType.WORD, lv.number.toInt(), lv.position)
else if(lv.type== DataType.FLOAT) {
val d = lv.floatvalue!!
val d = lv.number.toDouble()
if(floor(d)==d && d>=-32768 && d<=32767)
assignment.value = LiteralValue(DataType.BYTE, floor(d).toShort(), position = lv.position)
assignment.value = NumericLiteralValue(DataType.BYTE, floor(d).toShort(), lv.position)
}
}
DataType.FLOAT -> {
if(lv.isNumeric)
assignment.value = LiteralValue(DataType.FLOAT, floatvalue = lv.asNumericValue?.toDouble(), position = lv.position)
assignment.value = NumericLiteralValue(DataType.FLOAT, lv.number.toDouble(), lv.position)
}
else -> {}
}

15
compiler/src/prog8/optimizer/Extensions.kt
View File

@ -1,8 +1,7 @@
package prog8.optimizer
import prog8.ast.*
import prog8.ast.Program
import prog8.ast.base.AstException
import prog8.ast.statements.NopStatement
import prog8.parser.ParsingFailedError
@ -28,17 +27,9 @@ internal fun Program.constantFold() {
}
internal fun Program.optimizeStatements(optimizeInlining: Boolean): Int {
val optimizer = StatementOptimizer(this, optimizeInlining)
internal fun Program.optimizeStatements(): Int {
val optimizer = StatementOptimizer(this)
optimizer.visit(this)
for(scope in optimizer.scopesToFlatten.reversed()) {
val namescope = scope.parent as INameScope
val idx = namescope.statements.indexOf(scope as IStatement)
if(idx>=0) {
namescope.statements[idx] = NopStatement(scope.position)
namescope.statements.addAll(idx, scope.statements)
}
}
modules.forEach { it.linkParents(this.namespace) } // re-link in final configuration
return optimizer.optimizationsDone

347
compiler/src/prog8/optimizer/SimplifyExpressions.kt
View File

@ -1,33 +1,32 @@
package prog8.optimizer
import prog8.ast.*
import prog8.ast.base.AstException
import prog8.ast.base.DataType
import prog8.ast.base.IntegerDatatypes
import prog8.ast.base.NumericDatatypes
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.ast.processing.IAstModifyingVisitor
import prog8.ast.statements.Assignment
import prog8.ast.statements.Statement
import kotlin.math.abs
import kotlin.math.log2
import kotlin.math.pow
/*
todo advanced expression optimization: common (sub) expression elimination (turn common expressions into single subroutine call + introduce variable to hold it)
todo add more expression optimizations
Also see https://egorbo.com/peephole-optimizations.html
Investigate what optimizations binaryen has, also see https://egorbo.com/peephole-optimizations.html
*/
internal class SimplifyExpressions(private val program: Program) : IAstModifyingVisitor {
var optimizationsDone: Int = 0
override fun visit(assignment: Assignment): IStatement {
override fun visit(assignment: Assignment): Statement {
if (assignment.aug_op != null)
throw AstException("augmented assignments should have been converted to normal assignments before this optimizer")
throw AstException("augmented assignments should have been converted to normal assignments before this optimizer: $assignment")
return super.visit(assignment)
}
override fun visit(memread: DirectMemoryRead): IExpression {
override fun visit(memread: DirectMemoryRead): Expression {
// @( &thing ) --> thing
val addrOf = memread.addressExpression as? AddressOf
if(addrOf!=null)
@ -35,28 +34,53 @@ internal class SimplifyExpressions(private val program: Program) : IAstModifying
return super.visit(memread)
}
override fun visit(typecast: TypecastExpression): IExpression {
// remove redundant typecasts
override fun visit(typecast: TypecastExpression): Expression {
var tc = typecast
// try to statically convert a literal value into one of the desired type
val literal = tc.expression as? NumericLiteralValue
if(literal!=null) {
val newLiteral = literal.cast(tc.type)
if(newLiteral!==literal) {
optimizationsDone++
return newLiteral
}
}
// remove redundant typecasts
while(true) {
val expr = tc.expression
if(expr !is TypecastExpression || expr.type!=tc.type) {
val assignment = typecast.parent as? Assignment
if(assignment!=null) {
val targetDt = assignment.singleTarget?.inferType(program, assignment)
val targetDt = assignment.target.inferType(program, assignment)
if(tc.expression.inferType(program)==targetDt) {
optimizationsDone++
return tc.expression
}
}
val subTc = tc.expression as? TypecastExpression
if(subTc!=null) {
// if the previous typecast was casting to a 'bigger' type, just ignore that one
// if the previous typecast was casting to a similar type, ignore that one
if(subTc.type largerThan tc.type || subTc.type equalsSize tc.type) {
subTc.type = tc.type
subTc.parent = tc.parent
optimizationsDone++
return subTc
}
}
return super.visit(tc)
}
optimizationsDone++
tc = expr
}
}
override fun visit(expr: PrefixExpression): IExpression {
override fun visit(expr: PrefixExpression): Expression {
if (expr.operator == "+") {
// +X --> X
optimizationsDone++
@ -103,16 +127,21 @@ internal class SimplifyExpressions(private val program: Program) : IAstModifying
return super.visit(expr)
}
override fun visit(expr: BinaryExpression): IExpression {
override fun visit(expr: BinaryExpression): Expression {
super.visit(expr)
val leftVal = expr.left.constValue(program)
val rightVal = expr.right.constValue(program)
val constTrue = LiteralValue.fromBoolean(true, expr.position)
val constFalse = LiteralValue.fromBoolean(false, expr.position)
val constTrue = NumericLiteralValue.fromBoolean(true, expr.position)
val constFalse = NumericLiteralValue.fromBoolean(false, expr.position)
val leftDt = expr.left.inferType(program)
val rightDt = expr.right.inferType(program)
if (leftDt != null && rightDt != null && leftDt != rightDt) {
val leftIDt = expr.left.inferType(program)
val rightIDt = expr.right.inferType(program)
if(!leftIDt.isKnown || !rightIDt.isKnown)
throw FatalAstException("can't determine datatype of both expression operands $expr")
val leftDt = leftIDt.typeOrElse(DataType.STRUCT)
val rightDt = rightIDt.typeOrElse(DataType.STRUCT)
if (leftDt != rightDt) {
// try to convert a datatype into the other (where ddd
if (adjustDatatypes(expr, leftVal, leftDt, rightVal, rightDt)) {
optimizationsDone++
@ -149,10 +178,10 @@ internal class SimplifyExpressions(private val program: Program) : IAstModifying
// X + (-value) --> X - value
if (expr.operator == "+" && rightVal != null) {
val rv = rightVal.asNumericValue?.toDouble()
if (rv != null && rv < 0.0) {
val rv = rightVal.number.toDouble()
if (rv < 0.0) {
expr.operator = "-"
expr.right = LiteralValue.fromNumber(-rv, rightVal.type, rightVal.position)
expr.right = NumericLiteralValue(rightVal.type, -rv, rightVal.position)
optimizationsDone++
return expr
}
@ -160,10 +189,10 @@ internal class SimplifyExpressions(private val program: Program) : IAstModifying
// (-value) + X --> X - value
if (expr.operator == "+" && leftVal != null) {
val lv = leftVal.asNumericValue?.toDouble()
if (lv != null && lv < 0.0) {
val lv = leftVal.number.toDouble()
if (lv < 0.0) {
expr.operator = "-"
expr.right = LiteralValue.fromNumber(-lv, leftVal.type, leftVal.position)
expr.right = NumericLiteralValue(leftVal.type, -lv, leftVal.position)
optimizationsDone++
return expr
}
@ -179,10 +208,10 @@ internal class SimplifyExpressions(private val program: Program) : IAstModifying
// X - (-value) --> X + value
if (expr.operator == "-" && rightVal != null) {
val rv = rightVal.asNumericValue?.toDouble()
if (rv != null && rv < 0.0) {
val rv = rightVal.number.toDouble()
if (rv < 0.0) {
expr.operator = "+"
expr.right = LiteralValue.fromNumber(-rv, rightVal.type, rightVal.position)
expr.right = NumericLiteralValue(rightVal.type, -rv, rightVal.position)
optimizationsDone++
return expr
}
@ -200,7 +229,7 @@ internal class SimplifyExpressions(private val program: Program) : IAstModifying
val x = expr.right
val y = determineY(x, leftBinExpr)
if(y!=null) {
val yPlus1 = BinaryExpression(y, "+", LiteralValue.fromNumber(1, leftDt!!, y.position), y.position)
val yPlus1 = BinaryExpression(y, "+", NumericLiteralValue(leftDt, 1, y.position), y.position)
return BinaryExpression(x, "*", yPlus1, x.position)
}
} else {
@ -209,7 +238,7 @@ internal class SimplifyExpressions(private val program: Program) : IAstModifying
val x = expr.right
val y = determineY(x, leftBinExpr)
if(y!=null) {
val yMinus1 = BinaryExpression(y, "-", LiteralValue.fromNumber(1, leftDt!!, y.position), y.position)
val yMinus1 = BinaryExpression(y, "-", NumericLiteralValue(leftDt, 1, y.position), y.position)
return BinaryExpression(x, "*", yMinus1, x.position)
}
}
@ -221,7 +250,7 @@ internal class SimplifyExpressions(private val program: Program) : IAstModifying
val x = expr.left
val y = determineY(x, rightBinExpr)
if(y!=null) {
val yPlus1 = BinaryExpression(y, "+", LiteralValue.optimalInteger(1, y.position), y.position)
val yPlus1 = BinaryExpression(y, "+", NumericLiteralValue.optimalInteger(1, y.position), y.position)
return BinaryExpression(x, "*", yPlus1, x.position)
}
} else {
@ -230,7 +259,7 @@ internal class SimplifyExpressions(private val program: Program) : IAstModifying
val x = expr.left
val y = determineY(x, rightBinExpr)
if(y!=null) {
val oneMinusY = BinaryExpression(LiteralValue.optimalInteger(1, y.position), "-", y, y.position)
val oneMinusY = BinaryExpression(NumericLiteralValue.optimalInteger(1, y.position), "-", y, y.position)
return BinaryExpression(x, "*", oneMinusY, x.position)
}
}
@ -312,11 +341,13 @@ internal class SimplifyExpressions(private val program: Program) : IAstModifying
"-" -> return optimizeSub(expr, leftVal, rightVal)
"**" -> return optimizePower(expr, leftVal, rightVal)
"%" -> return optimizeRemainder(expr, leftVal, rightVal)
">>" -> return optimizeShiftRight(expr, rightVal)
"<<" -> return optimizeShiftLeft(expr, rightVal)
}
return expr
}
private fun determineY(x: IExpression, subBinExpr: BinaryExpression): IExpression? {
private fun determineY(x: Expression, subBinExpr: BinaryExpression): Expression? {
return when {
subBinExpr.left isSameAs x -> subBinExpr.right
subBinExpr.right isSameAs x -> subBinExpr.left
@ -325,58 +356,58 @@ internal class SimplifyExpressions(private val program: Program) : IAstModifying
}
private fun adjustDatatypes(expr: BinaryExpression,
leftConstVal: LiteralValue?, leftDt: DataType,
rightConstVal: LiteralValue?, rightDt: DataType): Boolean {
leftConstVal: NumericLiteralValue?, leftDt: DataType,
rightConstVal: NumericLiteralValue?, rightDt: DataType): Boolean {
fun adjust(value: LiteralValue, targetDt: DataType): Pair<Boolean, LiteralValue>{
fun adjust(value: NumericLiteralValue, targetDt: DataType): Pair<Boolean, NumericLiteralValue>{
if(value.type==targetDt)
return Pair(false, value)
when(value.type) {
DataType.UBYTE -> {
if (targetDt == DataType.BYTE) {
if(value.bytevalue!! < 127)
return Pair(true, LiteralValue(targetDt, value.bytevalue, position = value.position))
if(value.number.toInt() < 127)
return Pair(true, NumericLiteralValue(targetDt, value.number.toShort(), value.position))
}
else if (targetDt == DataType.UWORD || targetDt == DataType.WORD)
return Pair(true, LiteralValue(targetDt, wordvalue = value.bytevalue!!.toInt(), position = value.position))
return Pair(true, NumericLiteralValue(targetDt, value.number.toInt(), value.position))
}
DataType.BYTE -> {
if (targetDt == DataType.UBYTE) {
if(value.bytevalue!! >= 0)
return Pair(true, LiteralValue(targetDt, value.bytevalue, position = value.position))
if(value.number.toInt() >= 0)
return Pair(true, NumericLiteralValue(targetDt, value.number.toInt(), value.position))
}
else if (targetDt == DataType.UWORD) {
if(value.bytevalue!! >= 0)
return Pair(true, LiteralValue(targetDt, wordvalue = value.bytevalue.toInt(), position = value.position))
if(value.number.toInt() >= 0)
return Pair(true, NumericLiteralValue(targetDt, value.number.toInt(), value.position))
}
else if (targetDt == DataType.WORD) return Pair(true, LiteralValue(targetDt, wordvalue = value.bytevalue!!.toInt(), position = value.position))
else if (targetDt == DataType.WORD) return Pair(true, NumericLiteralValue(targetDt, value.number.toInt(), value.position))
}
DataType.UWORD -> {
if (targetDt == DataType.UBYTE) {
if(value.wordvalue!! <= 255)
return Pair(true, LiteralValue(targetDt, value.wordvalue.toShort(), position = value.position))
if(value.number.toInt() <= 255)
return Pair(true, NumericLiteralValue(targetDt, value.number.toShort(), value.position))
}
else if (targetDt == DataType.BYTE) {
if(value.wordvalue!! <= 127)
return Pair(true, LiteralValue(targetDt, value.wordvalue.toShort(), position = value.position))
if(value.number.toInt() <= 127)
return Pair(true, NumericLiteralValue(targetDt, value.number.toShort(), value.position))
}
else if (targetDt == DataType.WORD) {
if(value.wordvalue!! <= 32767)
return Pair(true, LiteralValue(targetDt, wordvalue = value.wordvalue, position = value.position))
if(value.number.toInt() <= 32767)
return Pair(true, NumericLiteralValue(targetDt, value.number.toInt(), value.position))
}
}
DataType.WORD -> {
if (targetDt == DataType.UBYTE) {
if(value.wordvalue!! in 0..255)
return Pair(true, LiteralValue(targetDt, value.wordvalue.toShort(), position = value.position))
if(value.number.toInt() in 0..255)
return Pair(true, NumericLiteralValue(targetDt, value.number.toShort(), value.position))
}
else if (targetDt == DataType.BYTE) {
if(value.wordvalue!! in -128..127)
return Pair(true, LiteralValue(targetDt, value.wordvalue.toShort(), position = value.position))
if(value.number.toInt() in -128..127)
return Pair(true, NumericLiteralValue(targetDt, value.number.toShort(), value.position))
}
else if (targetDt == DataType.UWORD) {
if(value.wordvalue!! >= 0)
return Pair(true, LiteralValue(targetDt, value.wordvalue.toShort(), position = value.position))
if(value.number.toInt() >= 0)
return Pair(true, NumericLiteralValue(targetDt, value.number.toShort(), value.position))
}
}
else -> {}
@ -385,7 +416,7 @@ internal class SimplifyExpressions(private val program: Program) : IAstModifying
}
if(leftConstVal==null && rightConstVal!=null) {
if(leftDt biggerThan rightDt) {
if(leftDt largerThan rightDt) {
val (adjusted, newValue) = adjust(rightConstVal, leftDt)
if (adjusted) {
expr.right = newValue
@ -395,7 +426,7 @@ internal class SimplifyExpressions(private val program: Program) : IAstModifying
}
return false
} else if(leftConstVal!=null && rightConstVal==null) {
if(rightDt biggerThan leftDt) {
if(rightDt largerThan leftDt) {
val (adjusted, newValue) = adjust(leftConstVal, rightDt)
if (adjusted) {
expr.left = newValue
@ -409,9 +440,9 @@ internal class SimplifyExpressions(private val program: Program) : IAstModifying
}
}
private data class ReorderedAssociativeBinaryExpr(val expr: BinaryExpression, val leftVal: LiteralValue?, val rightVal: LiteralValue?)
private data class ReorderedAssociativeBinaryExpr(val expr: BinaryExpression, val leftVal: NumericLiteralValue?, val rightVal: NumericLiteralValue?)
private fun reorderAssociative(expr: BinaryExpression, leftVal: LiteralValue?): ReorderedAssociativeBinaryExpr {
private fun reorderAssociative(expr: BinaryExpression, leftVal: NumericLiteralValue?): ReorderedAssociativeBinaryExpr {
if(expr.operator in associativeOperators && leftVal!=null) {
// swap left and right so that right is always the constant
val tmp = expr.left
@ -423,15 +454,15 @@ internal class SimplifyExpressions(private val program: Program) : IAstModifying
return ReorderedAssociativeBinaryExpr(expr, leftVal, expr.right.constValue(program))
}
private fun optimizeAdd(pexpr: BinaryExpression, pleftVal: LiteralValue?, prightVal: LiteralValue?): IExpression {
private fun optimizeAdd(pexpr: BinaryExpression, pleftVal: NumericLiteralValue?, prightVal: NumericLiteralValue?): Expression {
if(pleftVal==null && prightVal==null)
return pexpr
val (expr, _, rightVal) = reorderAssociative(pexpr, pleftVal)
if(rightVal!=null) {
// right value is a constant, see if we can optimize
val rightConst: LiteralValue = rightVal
when(rightConst.asNumericValue?.toDouble()) {
val rightConst: NumericLiteralValue = rightVal
when(rightConst.number.toDouble()) {
0.0 -> {
// left
optimizationsDone++
@ -444,14 +475,14 @@ internal class SimplifyExpressions(private val program: Program) : IAstModifying
return expr
}
private fun optimizeSub(expr: BinaryExpression, leftVal: LiteralValue?, rightVal: LiteralValue?): IExpression {
private fun optimizeSub(expr: BinaryExpression, leftVal: NumericLiteralValue?, rightVal: NumericLiteralValue?): Expression {
if(leftVal==null && rightVal==null)
return expr
if(rightVal!=null) {
// right value is a constant, see if we can optimize
val rightConst: LiteralValue = rightVal
when(rightConst.asNumericValue?.toDouble()) {
val rightConst: NumericLiteralValue = rightVal
when(rightConst.number.toDouble()) {
0.0 -> {
// left
optimizationsDone++
@ -461,7 +492,7 @@ internal class SimplifyExpressions(private val program: Program) : IAstModifying
}
if(leftVal!=null) {
// left value is a constant, see if we can optimize
when(leftVal.asNumericValue?.toDouble()) {
when(leftVal.number.toDouble()) {
0.0 -> {
// -right
optimizationsDone++
@ -473,38 +504,38 @@ internal class SimplifyExpressions(private val program: Program) : IAstModifying
return expr
}
private fun optimizePower(expr: BinaryExpression, leftVal: LiteralValue?, rightVal: LiteralValue?): IExpression {
private fun optimizePower(expr: BinaryExpression, leftVal: NumericLiteralValue?, rightVal: NumericLiteralValue?): Expression {
if(leftVal==null && rightVal==null)
return expr
if(rightVal!=null) {
// right value is a constant, see if we can optimize
val rightConst: LiteralValue = rightVal
when(rightConst.asNumericValue?.toDouble()) {
val rightConst: NumericLiteralValue = rightVal
when(rightConst.number.toDouble()) {
-3.0 -> {
// -1/(left*left*left)
optimizationsDone++
return BinaryExpression(LiteralValue(DataType.FLOAT, floatvalue = -1.0, position = expr.position), "/",
return BinaryExpression(NumericLiteralValue(DataType.FLOAT, -1.0, expr.position), "/",
BinaryExpression(expr.left, "*", BinaryExpression(expr.left, "*", expr.left, expr.position), expr.position),
expr.position)
}
-2.0 -> {
// -1/(left*left)
optimizationsDone++
return BinaryExpression(LiteralValue(DataType.FLOAT, floatvalue = -1.0, position = expr.position), "/",
return BinaryExpression(NumericLiteralValue(DataType.FLOAT, -1.0, expr.position), "/",
BinaryExpression(expr.left, "*", expr.left, expr.position),
expr.position)
}
-1.0 -> {
// -1/left
optimizationsDone++
return BinaryExpression(LiteralValue(DataType.FLOAT, floatvalue = -1.0, position = expr.position), "/",
return BinaryExpression(NumericLiteralValue(DataType.FLOAT, -1.0, expr.position), "/",
expr.left, expr.position)
}
0.0 -> {
// 1
optimizationsDone++
return LiteralValue.fromNumber(1, rightConst.type, expr.position)
return NumericLiteralValue(rightConst.type, 1, expr.position)
}
0.5 -> {
// sqrt(left)
@ -530,21 +561,21 @@ internal class SimplifyExpressions(private val program: Program) : IAstModifying
}
if(leftVal!=null) {
// left value is a constant, see if we can optimize
when(leftVal.asNumericValue?.toDouble()) {
when(leftVal.number.toDouble()) {
-1.0 -> {
// -1
optimizationsDone++
return LiteralValue(DataType.FLOAT, floatvalue = -1.0, position = expr.position)
return NumericLiteralValue(DataType.FLOAT, -1.0, expr.position)
}
0.0 -> {
// 0
optimizationsDone++
return LiteralValue.fromNumber(0, leftVal.type, expr.position)
return NumericLiteralValue(leftVal.type, 0, expr.position)
}
1.0 -> {
//1
optimizationsDone++
return LiteralValue.fromNumber(1, leftVal.type, expr.position)
return NumericLiteralValue(leftVal.type, 1, expr.position)
}
}
@ -553,22 +584,22 @@ internal class SimplifyExpressions(private val program: Program) : IAstModifying
return expr
}
private fun optimizeRemainder(expr: BinaryExpression, leftVal: LiteralValue?, rightVal: LiteralValue?): IExpression {
private fun optimizeRemainder(expr: BinaryExpression, leftVal: NumericLiteralValue?, rightVal: NumericLiteralValue?): Expression {
if(leftVal==null && rightVal==null)
return expr
// simplify assignments A = B <operator> C
val cv = rightVal?.asIntegerValue?.toDouble()
val cv = rightVal?.number?.toInt()?.toDouble()
when(expr.operator) {
"%" -> {
if (cv == 1.0) {
optimizationsDone++
return LiteralValue.fromNumber(0, expr.inferType(program)!!, expr.position)
return NumericLiteralValue(expr.inferType(program).typeOrElse(DataType.STRUCT), 0, expr.position)
} else if (cv == 2.0) {
optimizationsDone++
expr.operator = "&"
expr.right = LiteralValue.optimalInteger(1, expr.position)
expr.right = NumericLiteralValue.optimalInteger(1, expr.position)
return expr
}
}
@ -577,17 +608,22 @@ internal class SimplifyExpressions(private val program: Program) : IAstModifying
}
private fun optimizeDivision(expr: BinaryExpression, leftVal: LiteralValue?, rightVal: LiteralValue?): IExpression {
private val powersOfTwo = (1 .. 16).map { (2.0).pow(it) }.toSet()
private val negativePowersOfTwo = powersOfTwo.map { -it }.toSet()
private fun optimizeDivision(expr: BinaryExpression, leftVal: NumericLiteralValue?, rightVal: NumericLiteralValue?): Expression {
if(leftVal==null && rightVal==null)
return expr
// cannot shuffle assiciativity with division!
if(rightVal!=null) {
// right value is a constant, see if we can optimize
val rightConst: LiteralValue = rightVal
val cv = rightConst.asNumericValue?.toDouble()
val leftDt = expr.left.inferType(program)
val rightConst: NumericLiteralValue = rightVal
val cv = rightConst.number.toDouble()
val leftIDt = expr.left.inferType(program)
if(!leftIDt.isKnown)
return expr
val leftDt = leftIDt.typeOrElse(DataType.STRUCT)
when(cv) {
-1.0 -> {
// '/' -> -left
@ -603,45 +639,45 @@ internal class SimplifyExpressions(private val program: Program) : IAstModifying
return expr.left
}
}
2.0, 4.0, 8.0, 16.0, 32.0, 64.0, 128.0, 256.0, 512.0, 1024.0, 2048.0, 4096.0, 8192.0, 16384.0, 32768.0, 65536.0 -> {
in powersOfTwo -> {
if(leftDt in IntegerDatatypes) {
// divided by a power of two => shift right
optimizationsDone++
val numshifts = log2(cv).toInt()
return BinaryExpression(expr.left, ">>", LiteralValue.optimalInteger(numshifts, expr.position), expr.position)
return BinaryExpression(expr.left, ">>", NumericLiteralValue.optimalInteger(numshifts, expr.position), expr.position)
}
}
-2.0, -4.0, -8.0, -16.0, -32.0, -64.0, -128.0, -256.0, -512.0, -1024.0, -2048.0, -4096.0, -8192.0, -16384.0, -32768.0, -65536.0 -> {
in negativePowersOfTwo -> {
if(leftDt in IntegerDatatypes) {
// divided by a negative power of two => negate, then shift right
optimizationsDone++
val numshifts = log2(-cv).toInt()
return BinaryExpression(PrefixExpression("-", expr.left, expr.position), ">>", LiteralValue.optimalInteger(numshifts, expr.position), expr.position)
return BinaryExpression(PrefixExpression("-", expr.left, expr.position), ">>", NumericLiteralValue.optimalInteger(numshifts, expr.position), expr.position)
}
}
}
if (leftDt == DataType.UBYTE) {
if(abs(rightConst.asNumericValue!!.toDouble()) >= 256.0) {
if(abs(rightConst.number.toDouble()) >= 256.0) {
optimizationsDone++
return LiteralValue(DataType.UBYTE, 0, position = expr.position)
return NumericLiteralValue(DataType.UBYTE, 0, expr.position)
}
}
else if (leftDt == DataType.UWORD) {
if(abs(rightConst.asNumericValue!!.toDouble()) >= 65536.0) {
if(abs(rightConst.number.toDouble()) >= 65536.0) {
optimizationsDone++
return LiteralValue(DataType.UBYTE, 0, position = expr.position)
return NumericLiteralValue(DataType.UBYTE, 0, expr.position)
}
}
}
if(leftVal!=null) {
// left value is a constant, see if we can optimize
when(leftVal.asNumericValue?.toDouble()) {
when(leftVal.number.toDouble()) {
0.0 -> {
// 0
optimizationsDone++
return LiteralValue.fromNumber(0, leftVal.type, expr.position)
return NumericLiteralValue(leftVal.type, 0, expr.position)
}
}
}
@ -649,16 +685,16 @@ internal class SimplifyExpressions(private val program: Program) : IAstModifying
return expr
}
private fun optimizeMultiplication(pexpr: BinaryExpression, pleftVal: LiteralValue?, prightVal: LiteralValue?): IExpression {
private fun optimizeMultiplication(pexpr: BinaryExpression, pleftVal: NumericLiteralValue?, prightVal: NumericLiteralValue?): Expression {
if(pleftVal==null && prightVal==null)
return pexpr
val (expr, _, rightVal) = reorderAssociative(pexpr, pleftVal)
if(rightVal!=null) {
// right value is a constant, see if we can optimize
val leftValue: IExpression = expr.left
val rightConst: LiteralValue = rightVal
when(val cv = rightConst.asNumericValue?.toDouble()) {
val leftValue: Expression = expr.left
val rightConst: NumericLiteralValue = rightVal
when(val cv = rightConst.number.toDouble()) {
-1.0 -> {
// -left
optimizationsDone++
@ -667,27 +703,27 @@ internal class SimplifyExpressions(private val program: Program) : IAstModifying
0.0 -> {
// 0
optimizationsDone++
return LiteralValue.fromNumber(0, rightConst.type, expr.position)
return NumericLiteralValue(rightConst.type, 0, expr.position)
}
1.0 -> {
// left
optimizationsDone++
return expr.left
}
2.0, 4.0, 8.0, 16.0, 32.0, 64.0, 128.0, 256.0, 512.0, 1024.0, 2048.0, 4096.0, 8192.0, 16384.0, 32768.0, 65536.0 -> {
if(leftValue.inferType(program) in IntegerDatatypes) {
in powersOfTwo -> {
if(leftValue.inferType(program).typeOrElse(DataType.STRUCT) in IntegerDatatypes) {
// times a power of two => shift left
optimizationsDone++
val numshifts = log2(cv).toInt()
return BinaryExpression(expr.left, "<<", LiteralValue.optimalInteger(numshifts, expr.position), expr.position)
return BinaryExpression(expr.left, "<<", NumericLiteralValue.optimalInteger(numshifts, expr.position), expr.position)
}
}
-2.0, -4.0, -8.0, -16.0, -32.0, -64.0, -128.0, -256.0, -512.0, -1024.0, -2048.0, -4096.0, -8192.0, -16384.0, -32768.0, -65536.0 -> {
if(leftValue.inferType(program) in IntegerDatatypes) {
in negativePowersOfTwo -> {
if(leftValue.inferType(program).typeOrElse(DataType.STRUCT) in IntegerDatatypes) {
// times a negative power of two => negate, then shift left
optimizationsDone++
val numshifts = log2(-cv).toInt()
return BinaryExpression(PrefixExpression("-", expr.left, expr.position), "<<", LiteralValue.optimalInteger(numshifts, expr.position), expr.position)
return BinaryExpression(PrefixExpression("-", expr.left, expr.position), "<<", NumericLiteralValue.optimalInteger(numshifts, expr.position), expr.position)
}
}
}
@ -696,4 +732,97 @@ internal class SimplifyExpressions(private val program: Program) : IAstModifying
return expr
}
private fun optimizeShiftLeft(expr: BinaryExpression, amountLv: NumericLiteralValue?): Expression {
if(amountLv==null)
return expr
val amount=amountLv.number.toInt()
if(amount==0) {
optimizationsDone++
return expr.left
}
val targetDt = expr.left.inferType(program).typeOrElse(DataType.STRUCT)
when(targetDt) {
DataType.UBYTE, DataType.BYTE -> {
if(amount>=8) {
optimizationsDone++
return NumericLiteralValue.optimalInteger(0, expr.position)
}
}
DataType.UWORD, DataType.WORD -> {
if(amount>=16) {
optimizationsDone++
return NumericLiteralValue.optimalInteger(0, expr.position)
}
else if(amount>=8) {
optimizationsDone++
val lsb=TypecastExpression(expr.left, DataType.UBYTE, true, expr.position)
if(amount==8) {
return FunctionCall(IdentifierReference(listOf("mkword"), expr.position), mutableListOf(NumericLiteralValue.optimalInteger(0, expr.position), lsb), expr.position)
}
val shifted = BinaryExpression(lsb, "<<", NumericLiteralValue.optimalInteger(amount-8, expr.position), expr.position)
return FunctionCall(IdentifierReference(listOf("mkword"), expr.position), mutableListOf(NumericLiteralValue.optimalInteger(0, expr.position), shifted), expr.position)
}
}
else -> {}
}
return expr
}
private fun optimizeShiftRight(expr: BinaryExpression, amountLv: NumericLiteralValue?): Expression {
if(amountLv==null)
return expr
val amount=amountLv.number.toInt()
if(amount==0) {
optimizationsDone++
return expr.left
}
val targetDt = expr.left.inferType(program).typeOrElse(DataType.STRUCT)
when(targetDt) {
DataType.UBYTE -> {
if(amount>=8) {
optimizationsDone++
return NumericLiteralValue.optimalInteger(0, expr.position)
}
}
DataType.BYTE -> {
if(amount>8) {
expr.right = NumericLiteralValue.optimalInteger(8, expr.right.position)
return expr
}
}
DataType.UWORD -> {
if(amount>=16) {
optimizationsDone++
return NumericLiteralValue.optimalInteger(0, expr.position)
}
else if(amount>=8) {
optimizationsDone++
val msb=FunctionCall(IdentifierReference(listOf("msb"), expr.position), mutableListOf(expr.left), expr.position)
if(amount==8)
return msb
return BinaryExpression(msb, ">>", NumericLiteralValue.optimalInteger(amount-8, expr.position), expr.position)
}
}
DataType.WORD -> {
if(amount>16) {
expr.right = NumericLiteralValue.optimalInteger(16, expr.right.position)
return expr
} else if(amount>=8) {
optimizationsDone++
val msbAsByte = TypecastExpression(
FunctionCall(IdentifierReference(listOf("msb"), expr.position), mutableListOf(expr.left), expr.position),
DataType.BYTE,
true, expr.position)
if(amount==8)
return msbAsByte
return BinaryExpression(msbAsByte, ">>", NumericLiteralValue.optimalInteger(amount-8, expr.position), expr.position)
}
}
else -> {}
}
return expr
}
}

494
compiler/src/prog8/optimizer/StatementOptimizer.kt
View File

@ -1,106 +1,42 @@
package prog8.optimizer
import prog8.ast.*
import prog8.ast.INameScope
import prog8.ast.Module
import prog8.ast.Node
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.ast.processing.IAstModifyingVisitor
import prog8.ast.processing.IAstVisitor
import prog8.ast.statements.*
import prog8.compiler.target.c64.Petscii
import prog8.compiler.target.CompilationTarget
import prog8.functions.BuiltinFunctions
import kotlin.math.floor
/*
todo: subroutines with 1 or 2 byte args or 1 word arg can be converted to asm sub calling convention (args in registers)
todo analyse for unreachable code and remove that (f.i. code after goto or return that has no label so can never be jumped to) + print warning about this
TODO: remove unreachable code?
TODO: proper inlining of tiny subroutines (at first, restrict to subs without parameters and variables in them, and build it up from there: correctly renaming/relocating all variables in them and refs to those as well)
*/
internal class StatementOptimizer(private val program: Program, private val optimizeInlining: Boolean) : IAstModifyingVisitor {
internal class StatementOptimizer(private val program: Program) : IAstModifyingVisitor {
var optimizationsDone: Int = 0
private set
var scopesToFlatten = mutableListOf<INameScope>()
val nopStatements = mutableListOf<NopStatement>()
private val pureBuiltinFunctions = BuiltinFunctions.filter { it.value.pure }
private val callgraph = CallGraph(program)
companion object {
private var generatedLabelSequenceNumber = 0
}
private val vardeclsToRemove = mutableListOf<VarDecl>()
override fun visit(program: Program) {
removeUnusedCode(callgraph)
if(optimizeInlining) {
inlineSubroutines(callgraph)
}
super.visit(program)
// at the end, remove the encountered NOP statements
this.nopStatements.forEach { it.definingScope().remove(it) }
}
private fun inlineSubroutines(callgraph: CallGraph) {
val entrypoint = program.entrypoint()
program.modules.forEach {
callgraph.forAllSubroutines(it) { sub ->
if(sub!==entrypoint && !sub.isAsmSubroutine) {
if (sub.statements.size <= 3 && !sub.expensiveToInline) {
sub.calledBy.toList().forEach { caller -> inlineSubroutine(sub, caller) }
} else if (sub.calledBy.size==1 && sub.statements.size < 50) {
inlineSubroutine(sub, sub.calledBy[0])
} else if(sub.calledBy.size<=3 && sub.statements.size < 10 && !sub.expensiveToInline) {
sub.calledBy.toList().forEach { caller -> inlineSubroutine(sub, caller) }
}
}
}
for(decl in vardeclsToRemove) {
decl.definingScope().remove(decl)
}
}
private fun inlineSubroutine(sub: Subroutine, caller: Node) {
// if the sub is called multiple times from the isSameAs scope, we can't inline (would result in duplicate definitions)
// (unless we add a sequence number to all vars/labels and references to them in the inlined code, but I skip that for now)
val scope = caller.definingScope()
if(sub.calledBy.count { it.definingScope()===scope } > 1)
return
if(caller !is IFunctionCall || caller !is IStatement || sub.statements.any { it is Subroutine })
return
if(sub.parameters.isEmpty() && sub.returntypes.isEmpty()) {
// sub without params and without return value can be easily inlined
val parent = caller.parent as INameScope
val inlined = AnonymousScope(sub.statements.toMutableList(), caller.position)
parent.statements[parent.statements.indexOf(caller)] = inlined
// replace return statements in the inlined sub by a jump to the end of it
var haveNewEndLabel = false
var endLabelUsed = false
var endlabel = inlined.statements.last() as? Label
if(endlabel==null) {
endlabel = makeLabel("_prog8_auto_sub_end", inlined.statements.last().position)
endlabel.parent = inlined
haveNewEndLabel = true
}
val returns = inlined.statements.withIndex().filter { iv -> iv.value is Return }.map { iv -> Pair(iv.index, iv.value as Return)}
for(returnIdx in returns) {
assert(returnIdx.second.values.isEmpty())
val jump = Jump(null, IdentifierReference(listOf(endlabel.name), returnIdx.second.position), null, returnIdx.second.position)
inlined.statements[returnIdx.first] = jump
endLabelUsed = true
}
if(endLabelUsed && haveNewEndLabel)
inlined.statements.add(endlabel)
inlined.linkParents(caller.parent)
sub.calledBy.remove(caller) // if there are no callers left, the sub will be removed automatically later
optimizationsDone++
} else {
// TODO inline subroutine that has params or returnvalues or both
}
}
private fun makeLabel(name: String, position: Position): Label {
generatedLabelSequenceNumber++
return Label("${name}_$generatedLabelSequenceNumber", position)
}
private fun removeUnusedCode(callgraph: CallGraph) {
// remove all subroutines that aren't called, or are empty
val removeSubroutines = mutableSetOf<Subroutine>()
@ -140,32 +76,32 @@ internal class StatementOptimizer(private val program: Program, private val opti
}
}
override fun visit(block: Block): IStatement {
override fun visit(block: Block): Statement {
if("force_output" !in block.options()) {
if (block.containsNoCodeNorVars()) {
optimizationsDone++
printWarning("removing empty block '${block.name}'", block.position)
return NopStatement(block.position)
return NopStatement.insteadOf(block)
}
if (block !in callgraph.usedSymbols) {
optimizationsDone++
printWarning("removing unused block '${block.name}'", block.position)
return NopStatement(block.position) // remove unused block
return NopStatement.insteadOf(block) // remove unused block
}
}
return super.visit(block)
}
override fun visit(subroutine: Subroutine): IStatement {
override fun visit(subroutine: Subroutine): Statement {
super.visit(subroutine)
val forceOutput = "force_output" in subroutine.definingBlock().options()
if(subroutine.asmAddress==null && !forceOutput) {
if(subroutine.containsNoCodeNorVars()) {
printWarning("removing empty subroutine '${subroutine.name}'", subroutine.position)
optimizationsDone++
return NopStatement(subroutine.position)
return NopStatement.insteadOf(subroutine)
}
}
@ -174,54 +110,42 @@ internal class StatementOptimizer(private val program: Program, private val opti
linesToRemove.reversed().forEach{subroutine.statements.removeAt(it)}
}
if(subroutine.canBeAsmSubroutine) {
optimizationsDone++
return subroutine.intoAsmSubroutine() // TODO this doesn't work yet due to parameter vardecl issue
// TODO fix parameter passing so this also works:
// asmsub aa(byte arg @ Y) -> clobbers() -> () {
// byte local = arg ; @todo fix 'undefined symbol arg' by some sort of alias name for the parameter
// A=44
// }
}
if(subroutine !in callgraph.usedSymbols && !forceOutput) {
printWarning("removing unused subroutine '${subroutine.name}'", subroutine.position)
optimizationsDone++
return NopStatement(subroutine.position) // remove unused subroutine
return NopStatement.insteadOf(subroutine)
}
return subroutine
}
override fun visit(decl: VarDecl): IStatement {
override fun visit(decl: VarDecl): Statement {
val forceOutput = "force_output" in decl.definingBlock().options()
if(decl !in callgraph.usedSymbols && !forceOutput) {
if(decl.type!=VarDeclType.CONST)
printWarning("removing unused variable '${decl.name}'", decl.position)
if(decl.type == VarDeclType.VAR)
printWarning("removing unused variable ${decl.type} '${decl.name}'", decl.position)
optimizationsDone++
return NopStatement(decl.position) // remove unused variable
return NopStatement.insteadOf(decl)
}
return super.visit(decl)
}
private fun deduplicateAssignments(statements: List<IStatement>): MutableList<Int> {
private fun deduplicateAssignments(statements: List<Statement>): MutableList<Int> {
// removes 'duplicate' assignments that assign the isSameAs target
val linesToRemove = mutableListOf<Int>()
var previousAssignmentLine: Int? = null
for (i in 0 until statements.size) {
for (i in statements.indices) {
val stmt = statements[i] as? Assignment
if (stmt != null && stmt.value is LiteralValue) {
if (stmt != null && stmt.value is NumericLiteralValue) {
if (previousAssignmentLine == null) {
previousAssignmentLine = i
continue
} else {
val prev = statements[previousAssignmentLine] as Assignment
if (prev.targets.size == 1 && stmt.targets.size == 1 && prev.targets[0].isSameAs(stmt.targets[0], program)) {
if (prev.target.isSameAs(stmt.target, program)) {
// get rid of the previous assignment, if the target is not MEMORY
if (prev.targets[0].isNotMemory(program.namespace))
if (prev.target.isNotMemory(program.namespace))
linesToRemove.add(previousAssignmentLine)
}
previousAssignmentLine = i
@ -232,39 +156,47 @@ internal class StatementOptimizer(private val program: Program, private val opti
return linesToRemove
}
override fun visit(functionCallStatement: FunctionCallStatement): IStatement {
override fun visit(functionCallStatement: FunctionCallStatement): Statement {
if(functionCallStatement.target.nameInSource.size==1 && functionCallStatement.target.nameInSource[0] in BuiltinFunctions) {
val functionName = functionCallStatement.target.nameInSource[0]
if (functionName in pureBuiltinFunctions) {
printWarning("statement has no effect (function return value is discarded)", functionCallStatement.position)
optimizationsDone++
return NopStatement(functionCallStatement.position)
return NopStatement.insteadOf(functionCallStatement)
}
}
if(functionCallStatement.target.nameInSource==listOf("c64scr", "print") ||
functionCallStatement.target.nameInSource==listOf("c64scr", "print_p")) {
// printing a literal string of just 2 or 1 characters is replaced by directly outputting those characters
if(functionCallStatement.arglist.single() is LiteralValue)
throw AstException("string argument should be on heap already")
val stringVar = functionCallStatement.arglist.single() as? IdentifierReference
val arg = functionCallStatement.args.single()
val stringVar: IdentifierReference?
stringVar = if(arg is AddressOf) {
arg.identifier
} else {
arg as? IdentifierReference
}
if(stringVar!=null) {
val heapId = stringVar.heapId(program.namespace)
val string = program.heap.get(heapId).str!!
if(string.length==1) {
val petscii = Petscii.encodePetscii(string, true)[0]
functionCallStatement.arglist.clear()
functionCallStatement.arglist.add(LiteralValue.optimalInteger(petscii, functionCallStatement.position))
val vardecl = stringVar.targetVarDecl(program.namespace)!!
val string = vardecl.value!! as StringLiteralValue
if(string.value.length==1) {
val firstCharEncoded = CompilationTarget.encodeString(string.value, string.altEncoding)[0]
functionCallStatement.args.clear()
functionCallStatement.args.add(NumericLiteralValue.optimalInteger(firstCharEncoded.toInt(), functionCallStatement.position))
functionCallStatement.target = IdentifierReference(listOf("c64", "CHROUT"), functionCallStatement.target.position)
vardeclsToRemove.add(vardecl)
optimizationsDone++
return functionCallStatement
} else if(string.length==2) {
val petscii = Petscii.encodePetscii(string, true)
} else if(string.value.length==2) {
val firstTwoCharsEncoded = CompilationTarget.encodeString(string.value.take(2), string.altEncoding)
val scope = AnonymousScope(mutableListOf(), functionCallStatement.position)
scope.statements.add(FunctionCallStatement(IdentifierReference(listOf("c64", "CHROUT"), functionCallStatement.target.position),
mutableListOf(LiteralValue.optimalInteger(petscii[0], functionCallStatement.position)), functionCallStatement.position))
mutableListOf(NumericLiteralValue.optimalInteger(firstTwoCharsEncoded[0].toInt(), functionCallStatement.position)),
functionCallStatement.void, functionCallStatement.position))
scope.statements.add(FunctionCallStatement(IdentifierReference(listOf("c64", "CHROUT"), functionCallStatement.target.position),
mutableListOf(LiteralValue.optimalInteger(petscii[1], functionCallStatement.position)), functionCallStatement.position))
mutableListOf(NumericLiteralValue.optimalInteger(firstTwoCharsEncoded[1].toInt(), functionCallStatement.position)),
functionCallStatement.void, functionCallStatement.position))
vardeclsToRemove.add(vardecl)
optimizationsDone++
return scope
}
@ -279,18 +211,18 @@ internal class StatementOptimizer(private val program: Program, private val opti
val first = subroutine.statements.asSequence().filterNot { it is VarDecl || it is Directive }.firstOrNull()
if(first is Jump && first.identifier!=null) {
optimizationsDone++
return FunctionCallStatement(first.identifier, functionCallStatement.arglist, functionCallStatement.position)
return FunctionCallStatement(first.identifier, functionCallStatement.args, functionCallStatement.void, functionCallStatement.position)
}
if(first is ReturnFromIrq || first is Return) {
optimizationsDone++
return NopStatement(functionCallStatement.position)
return NopStatement.insteadOf(functionCallStatement)
}
}
return super.visit(functionCallStatement)
}
override fun visit(functionCall: FunctionCall): IExpression {
override fun visit(functionCall: FunctionCall): Expression {
// if it calls a subroutine,
// and the first instruction in the subroutine is a jump, call that jump target instead
// if the first instruction in the subroutine is a return statement with constant value, replace with the constant value
@ -299,10 +231,10 @@ internal class StatementOptimizer(private val program: Program, private val opti
val first = subroutine.statements.asSequence().filterNot { it is VarDecl || it is Directive }.firstOrNull()
if(first is Jump && first.identifier!=null) {
optimizationsDone++
return FunctionCall(first.identifier, functionCall.arglist, functionCall.position)
return FunctionCall(first.identifier, functionCall.args, functionCall.position)
}
if(first is Return && first.values.size==1) {
val constval = first.values[0].constValue(program)
if(first is Return && first.value!=null) {
val constval = first.value?.constValue(program)
if(constval!=null)
return constval
}
@ -310,12 +242,12 @@ internal class StatementOptimizer(private val program: Program, private val opti
return super.visit(functionCall)
}
override fun visit(ifStatement: IfStatement): IStatement {
override fun visit(ifStatement: IfStatement): Statement {
super.visit(ifStatement)
if(ifStatement.truepart.containsNoCodeNorVars() && ifStatement.elsepart.containsNoCodeNorVars()) {
optimizationsDone++
return NopStatement(ifStatement.position)
return NopStatement.insteadOf(ifStatement)
}
if(ifStatement.truepart.containsNoCodeNorVars() && ifStatement.elsepart.containsCodeOrVars()) {
@ -344,18 +276,18 @@ internal class StatementOptimizer(private val program: Program, private val opti
return ifStatement
}
override fun visit(forLoop: ForLoop): IStatement {
override fun visit(forLoop: ForLoop): Statement {
super.visit(forLoop)
if(forLoop.body.containsNoCodeNorVars()) {
// remove empty for loop
optimizationsDone++
return NopStatement(forLoop.position)
return NopStatement.insteadOf(forLoop)
} else if(forLoop.body.statements.size==1) {
val loopvar = forLoop.body.statements[0] as? VarDecl
if(loopvar!=null && loopvar.name==forLoop.loopVar?.nameInSource?.singleOrNull()) {
// remove empty for loop
optimizationsDone++
return NopStatement(forLoop.position)
return NopStatement.insteadOf(forLoop)
}
}
@ -365,7 +297,7 @@ internal class StatementOptimizer(private val program: Program, private val opti
if(range.size()==1) {
// for loop over a (constant) range of just a single value-- optimize the loop away
// loopvar/reg = range value , follow by block
val assignment = Assignment(listOf(AssignTarget(forLoop.loopRegister, forLoop.loopVar, null, null, forLoop.position)), null, range.from, forLoop.position)
val assignment = Assignment(AssignTarget(forLoop.loopRegister, forLoop.loopVar, null, null, forLoop.position), null, range.from, forLoop.position)
forLoop.body.statements.add(0, assignment)
optimizationsDone++
return forLoop.body
@ -374,39 +306,40 @@ internal class StatementOptimizer(private val program: Program, private val opti
return forLoop
}
override fun visit(whileLoop: WhileLoop): IStatement {
override fun visit(whileLoop: WhileLoop): Statement {
super.visit(whileLoop)
val constvalue = whileLoop.condition.constValue(program)
if(constvalue!=null) {
return if(constvalue.asBooleanValue){
// always true -> print a warning, and optimize into body + jump (if there are no continue and break statements)
printWarning("condition is always true", whileLoop.position)
printWarning("condition is always true", whileLoop.condition.position)
if(hasContinueOrBreak(whileLoop.body))
return whileLoop
val label = Label("__back", whileLoop.condition.position)
val backLabelName = "_prog8_back${whileLoop.position.line}"
val label = Label(backLabelName, whileLoop.condition.position)
whileLoop.body.statements.add(0, label)
whileLoop.body.statements.add(Jump(null,
IdentifierReference(listOf("__back"), whileLoop.condition.position),
IdentifierReference(listOf(backLabelName), whileLoop.condition.position),
null, whileLoop.condition.position))
optimizationsDone++
return whileLoop.body
} else {
// always false -> ditch whole statement
printWarning("condition is always false", whileLoop.position)
printWarning("condition is always false", whileLoop.condition.position)
optimizationsDone++
NopStatement(whileLoop.position)
NopStatement.insteadOf(whileLoop)
}
}
return whileLoop
}
override fun visit(repeatLoop: RepeatLoop): IStatement {
override fun visit(repeatLoop: RepeatLoop): Statement {
super.visit(repeatLoop)
val constvalue = repeatLoop.untilCondition.constValue(program)
if(constvalue!=null) {
return if(constvalue.asBooleanValue){
// always true -> keep only the statement block (if there are no continue and break statements)
printWarning("condition is always true", repeatLoop.position)
printWarning("condition is always true", repeatLoop.untilCondition.position)
if(hasContinueOrBreak(repeatLoop.body))
repeatLoop
else {
@ -415,13 +348,14 @@ internal class StatementOptimizer(private val program: Program, private val opti
}
} else {
// always false -> print a warning, and optimize into body + jump (if there are no continue and break statements)
printWarning("condition is always false", repeatLoop.position)
printWarning("condition is always false", repeatLoop.untilCondition.position)
if(hasContinueOrBreak(repeatLoop.body))
return repeatLoop
val label = Label("__back", repeatLoop.untilCondition.position)
val backLabelName = "_prog8_back${repeatLoop.position.line}"
val label = Label(backLabelName, repeatLoop.untilCondition.position)
repeatLoop.body.statements.add(0, label)
repeatLoop.body.statements.add(Jump(null,
IdentifierReference(listOf("__back"), repeatLoop.untilCondition.position),
IdentifierReference(listOf(backLabelName), repeatLoop.untilCondition.position),
null, repeatLoop.untilCondition.position))
optimizationsDone++
return repeatLoop.body
@ -430,12 +364,7 @@ internal class StatementOptimizer(private val program: Program, private val opti
return repeatLoop
}
override fun visit(nopStatement: NopStatement): IStatement {
this.nopStatements.add(nopStatement)
return nopStatement
}
override fun visit(whenStatement: WhenStatement): IStatement {
override fun visit(whenStatement: WhenStatement): Statement {
val choices = whenStatement.choices.toList()
for(choice in choices) {
if(choice.statements.containsNoCodeNorVars())
@ -450,12 +379,12 @@ internal class StatementOptimizer(private val program: Program, private val opti
{
var count=0
override fun visit(breakStmt: Break): IStatement {
override fun visit(breakStmt: Break): Statement {
count++
return super.visit(breakStmt)
}
override fun visit(contStmt: Continue): IStatement {
override fun visit(contStmt: Continue): Statement {
count++
return super.visit(contStmt)
}
@ -469,7 +398,7 @@ internal class StatementOptimizer(private val program: Program, private val opti
return s.count > 0
}
override fun visit(jump: Jump): IStatement {
override fun visit(jump: Jump): Statement {
val subroutine = jump.identifier?.targetSubroutine(program.namespace)
if(subroutine!=null) {
// if the first instruction in the subroutine is another jump, shortcut this one
@ -486,136 +415,139 @@ internal class StatementOptimizer(private val program: Program, private val opti
if(label!=null) {
if(scope.statements.indexOf(label) == scope.statements.indexOf(jump)+1) {
optimizationsDone++
return NopStatement(jump.position)
return NopStatement.insteadOf(jump)
}
}
return jump
}
override fun visit(assignment: Assignment): IStatement {
override fun visit(assignment: Assignment): Statement {
if(assignment.aug_op!=null)
throw AstException("augmented assignments should have been converted to normal assignments before this optimizer")
throw AstException("augmented assignments should have been converted to normal assignments before this optimizer: $assignment")
if(assignment.targets.size==1) {
val target=assignment.targets[0]
if(target isSameAs assignment.value) {
if(assignment.target isSameAs assignment.value) {
if(assignment.target.isNotMemory(program.namespace)) {
optimizationsDone++
return NopStatement(assignment.position)
return NopStatement.insteadOf(assignment)
}
val targetDt = target.inferType(program, assignment)
val bexpr=assignment.value as? BinaryExpression
if(bexpr!=null) {
val cv = bexpr.right.constValue(program)?.asNumericValue?.toDouble()
if(cv==null) {
if(bexpr.operator=="+" && targetDt!= DataType.FLOAT) {
if (bexpr.left isSameAs bexpr.right && target isSameAs bexpr.left) {
bexpr.operator = "*"
bexpr.right = LiteralValue.optimalInteger(2, assignment.value.position)
optimizationsDone++
return assignment
}
}
val targetIDt = assignment.target.inferType(program, assignment)
if(!targetIDt.isKnown)
throw FatalAstException("can't infer type of assignment target")
val targetDt = targetIDt.typeOrElse(DataType.STRUCT)
val bexpr=assignment.value as? BinaryExpression
if(bexpr!=null) {
val cv = bexpr.right.constValue(program)?.number?.toDouble()
if (cv == null) {
if (bexpr.operator == "+" && targetDt != DataType.FLOAT) {
if (bexpr.left isSameAs bexpr.right && assignment.target isSameAs bexpr.left) {
bexpr.operator = "*"
bexpr.right = NumericLiteralValue.optimalInteger(2, assignment.value.position)
optimizationsDone++
return assignment
}
} else {
if (target isSameAs bexpr.left) {
// remove assignments that have no effect X=X , X+=0, X-=0, X*=1, X/=1, X//=1, A |= 0, A ^= 0, A<<=0, etc etc
// A = A <operator> B
val vardeclDt = (target.identifier?.targetVarDecl(program.namespace))?.type
}
} else {
if (assignment.target isSameAs bexpr.left) {
// remove assignments that have no effect X=X , X+=0, X-=0, X*=1, X/=1, X//=1, A |= 0, A ^= 0, A<<=0, etc etc
// A = A <operator> B
val vardeclDt = (assignment.target.identifier?.targetVarDecl(program.namespace))?.type
when (bexpr.operator) {
"+" -> {
if (cv == 0.0) {
optimizationsDone++
return NopStatement(assignment.position)
} else if (targetDt in IntegerDatatypes && floor(cv) == cv) {
if((vardeclDt == VarDeclType.MEMORY && cv in 1.0..3.0) || (vardeclDt!=VarDeclType.MEMORY && cv in 1.0..8.0)) {
// replace by several INCs (a bit less when dealing with memory targets)
val decs = AnonymousScope(mutableListOf(), assignment.position)
repeat(cv.toInt()) {
decs.statements.add(PostIncrDecr(target, "++", assignment.position))
}
return decs
when (bexpr.operator) {
"+" -> {
if (cv == 0.0) {
optimizationsDone++
return NopStatement.insteadOf(assignment)
} else if (targetDt in IntegerDatatypes && floor(cv) == cv) {
if ((vardeclDt == VarDeclType.MEMORY && cv in 1.0..3.0) || (vardeclDt != VarDeclType.MEMORY && cv in 1.0..8.0)) {
// replace by several INCs (a bit less when dealing with memory targets)
val decs = AnonymousScope(mutableListOf(), assignment.position)
repeat(cv.toInt()) {
decs.statements.add(PostIncrDecr(assignment.target, "++", assignment.position))
}
return decs
}
}
"-" -> {
if (cv == 0.0) {
optimizationsDone++
return NopStatement(assignment.position)
} else if (targetDt in IntegerDatatypes && floor(cv) == cv) {
if((vardeclDt == VarDeclType.MEMORY && cv in 1.0..3.0) || (vardeclDt!=VarDeclType.MEMORY && cv in 1.0..8.0)) {
// replace by several DECs (a bit less when dealing with memory targets)
val decs = AnonymousScope(mutableListOf(), assignment.position)
repeat(cv.toInt()) {
decs.statements.add(PostIncrDecr(target, "--", assignment.position))
}
return decs
}
"-" -> {
if (cv == 0.0) {
optimizationsDone++
return NopStatement.insteadOf(assignment)
} else if (targetDt in IntegerDatatypes && floor(cv) == cv) {
if ((vardeclDt == VarDeclType.MEMORY && cv in 1.0..3.0) || (vardeclDt != VarDeclType.MEMORY && cv in 1.0..8.0)) {
// replace by several DECs (a bit less when dealing with memory targets)
val decs = AnonymousScope(mutableListOf(), assignment.position)
repeat(cv.toInt()) {
decs.statements.add(PostIncrDecr(assignment.target, "--", assignment.position))
}
return decs
}
}
"*" -> if (cv == 1.0) {
}
"*" -> if (cv == 1.0) {
optimizationsDone++
return NopStatement.insteadOf(assignment)
}
"/" -> if (cv == 1.0) {
optimizationsDone++
return NopStatement.insteadOf(assignment)
}
"**" -> if (cv == 1.0) {
optimizationsDone++
return NopStatement.insteadOf(assignment)
}
"|" -> if (cv == 0.0) {
optimizationsDone++
return NopStatement.insteadOf(assignment)
}
"^" -> if (cv == 0.0) {
optimizationsDone++
return NopStatement.insteadOf(assignment)
}
"<<" -> {
if (cv == 0.0) {
optimizationsDone++
return NopStatement(assignment.position)
return NopStatement.insteadOf(assignment)
}
"/" -> if (cv == 1.0) {
if (((targetDt == DataType.UWORD || targetDt == DataType.WORD) && cv > 15.0) ||
((targetDt == DataType.UBYTE || targetDt == DataType.BYTE) && cv > 7.0)) {
assignment.value = NumericLiteralValue.optimalInteger(0, assignment.value.position)
assignment.value.linkParents(assignment)
optimizationsDone++
return NopStatement(assignment.position)
}
"**" -> if (cv == 1.0) {
optimizationsDone++
return NopStatement(assignment.position)
}
"|" -> if (cv == 0.0) {
optimizationsDone++
return NopStatement(assignment.position)
}
"^" -> if (cv == 0.0) {
optimizationsDone++
return NopStatement(assignment.position)
}
"<<" -> {
if (cv == 0.0) {
optimizationsDone++
return NopStatement(assignment.position)
}
if (((targetDt == DataType.UWORD || targetDt == DataType.WORD) && cv > 15.0) ||
((targetDt == DataType.UBYTE || targetDt == DataType.BYTE) && cv > 7.0)) {
assignment.value = LiteralValue.optimalInteger(0, assignment.value.position)
assignment.value.linkParents(assignment)
optimizationsDone++
} else {
// replace by in-place lsl(...) call
val scope = AnonymousScope(mutableListOf(), assignment.position)
var numshifts = cv.toInt()
while (numshifts > 0) {
scope.statements.add(FunctionCallStatement(IdentifierReference(listOf("lsl"), assignment.position), mutableListOf(bexpr.left), assignment.position))
numshifts--
}
optimizationsDone++
return scope
} else {
// replace by in-place lsl(...) call
val scope = AnonymousScope(mutableListOf(), assignment.position)
var numshifts = cv.toInt()
while (numshifts > 0) {
scope.statements.add(FunctionCallStatement(IdentifierReference(listOf("lsl"), assignment.position),
mutableListOf(bexpr.left), true, assignment.position))
numshifts--
}
optimizationsDone++
return scope
}
">>" -> {
if (cv == 0.0) {
optimizationsDone++
return NopStatement(assignment.position)
}
if (((targetDt == DataType.UWORD || targetDt == DataType.WORD) && cv > 15.0) ||
((targetDt == DataType.UBYTE || targetDt == DataType.BYTE) && cv > 7.0)) {
assignment.value = LiteralValue.optimalInteger(0, assignment.value.position)
assignment.value.linkParents(assignment)
optimizationsDone++
} else {
// replace by in-place lsr(...) call
val scope = AnonymousScope(mutableListOf(), assignment.position)
var numshifts = cv.toInt()
while (numshifts > 0) {
scope.statements.add(FunctionCallStatement(IdentifierReference(listOf("lsr"), assignment.position), mutableListOf(bexpr.left), assignment.position))
numshifts--
}
optimizationsDone++
return scope
}
">>" -> {
if (cv == 0.0) {
optimizationsDone++
return NopStatement.insteadOf(assignment)
}
if ((targetDt == DataType.UWORD && cv > 15.0) || (targetDt == DataType.UBYTE && cv > 7.0)) {
assignment.value = NumericLiteralValue.optimalInteger(0, assignment.value.position)
assignment.value.linkParents(assignment)
optimizationsDone++
} else {
// replace by in-place lsr(...) call
val scope = AnonymousScope(mutableListOf(), assignment.position)
var numshifts = cv.toInt()
while (numshifts > 0) {
scope.statements.add(FunctionCallStatement(IdentifierReference(listOf("lsr"), assignment.position),
mutableListOf(bexpr.left), true, assignment.position))
numshifts--
}
optimizationsDone++
return scope
}
}
}
@ -623,28 +555,24 @@ internal class StatementOptimizer(private val program: Program, private val opti
}
}
return super.visit(assignment)
}
override fun visit(scope: AnonymousScope): IStatement {
override fun visit(scope: AnonymousScope): Statement {
val linesToRemove = deduplicateAssignments(scope.statements)
if(linesToRemove.isNotEmpty()) {
linesToRemove.reversed().forEach{scope.statements.removeAt(it)}
}
if(scope.parent is INameScope) {
scopesToFlatten.add(scope) // get rid of the anonymous scope
}
return super.visit(scope)
}
override fun visit(label: Label): IStatement {
override fun visit(label: Label): Statement {
// remove duplicate labels
val stmts = label.definingScope().statements
val startIdx = stmts.indexOf(label)
if(startIdx<(stmts.size-1) && stmts[startIdx+1] == label)
return NopStatement(label.position)
return NopStatement.insteadOf(label)
return super.visit(label)
}
@ -652,3 +580,39 @@ internal class StatementOptimizer(private val program: Program, private val opti
internal class FlattenAnonymousScopesAndRemoveNops: IAstVisitor {
private var scopesToFlatten = mutableListOf<INameScope>()
private val nopStatements = mutableListOf<NopStatement>()
override fun visit(program: Program) {
super.visit(program)
for(scope in scopesToFlatten.reversed()) {
val namescope = scope.parent as INameScope
val idx = namescope.statements.indexOf(scope as Statement)
if(idx>=0) {
val nop = NopStatement.insteadOf(namescope.statements[idx])
nop.parent = namescope as Node
namescope.statements[idx] = nop
namescope.statements.addAll(idx, scope.statements)
scope.statements.forEach { it.parent = namescope }
visit(nop)
}
}
this.nopStatements.forEach {
it.definingScope().remove(it)
}
}
override fun visit(scope: AnonymousScope) {
if(scope.parent is INameScope) {
scopesToFlatten.add(scope) // get rid of the anonymous scope
}
return super.visit(scope)
}
override fun visit(nopStatement: NopStatement) {
nopStatements.add(nopStatement)
}
}

14
compiler/src/prog8/parser/ModuleParsing.kt
View File

@ -1,13 +1,15 @@
package prog8.parser
import org.antlr.v4.runtime.*
import prog8.ast.*
import prog8.ast.Module
import prog8.ast.Program
import prog8.ast.antlr.toAst
import prog8.ast.base.Position
import prog8.ast.base.SyntaxError
import prog8.ast.base.checkImportedValid
import prog8.ast.statements.Directive
import prog8.ast.statements.DirectiveArg
import prog8.pathFrom
import java.io.InputStream
import java.nio.file.Files
import java.nio.file.Path
@ -90,18 +92,18 @@ internal fun importModule(program: Program, stream: CharStream, modulePath: Path
private fun discoverImportedModuleFile(name: String, source: Path, position: Position?): Path {
val fileName = "$name.p8"
val locations = mutableListOf(Paths.get(source.parent.toString()))
val locations = mutableListOf(source.parent)
val propPath = System.getProperty("prog8.libdir")
if(propPath!=null)
locations.add(Paths.get(propPath))
locations.add(pathFrom(propPath))
val envPath = System.getenv("PROG8_LIBDIR")
if(envPath!=null)
locations.add(Paths.get(envPath))
locations.add(pathFrom(envPath))
locations.add(Paths.get(Paths.get("").toAbsolutePath().toString(), "prog8lib"))
locations.forEach {
val file = Paths.get(it.toString(), fileName)
val file = pathFrom(it.toString(), fileName)
if (Files.isReadable(file)) return file
}
@ -119,7 +121,7 @@ private fun executeImportDirective(program: Program, import: Directive, source:
if(existing!=null)
return null
val resource = tryGetEmbeddedResource(moduleName+".p8")
val resource = tryGetEmbeddedResource("$moduleName.p8")
val importedModule =
if(resource!=null) {
// load the module from the embedded resource

582
compiler/src/prog8/vm/RuntimeValue.kt
View File

@ -1,19 +1,30 @@
package prog8.vm
import prog8.ast.base.*
import prog8.ast.expressions.LiteralValue
import prog8.compiler.HeapValues
import prog8.compiler.target.c64.Petscii
import prog8.ast.base.ByteDatatypes
import prog8.ast.base.DataType
import prog8.ast.base.WordDatatypes
import prog8.ast.expressions.ArrayLiteralValue
import prog8.ast.expressions.NumericLiteralValue
import prog8.ast.expressions.StringLiteralValue
import prog8.vm.astvm.VmExecutionException
import java.util.Objects
import kotlin.math.abs
import kotlin.math.pow
/**
* Rather than a literal value (LiteralValue) that occurs in the parsed source code,
* Rather than a literal value (NumericLiteralValue) that occurs in the parsed source code,
* this runtime value can be used to *execute* the parsed Ast (or another intermediary form)
* It contains a value of a variable during run time of the program and provides arithmetic operations on the value.
*/
open class RuntimeValue(val type: DataType, num: Number?=null, val str: String?=null, val array: Array<Number>?=null, val heapId: Int?=null) {
abstract class RuntimeValueBase(val type: DataType) {
abstract fun numericValue(): Number
abstract fun integerValue(): Int
}
class RuntimeValueNumeric(type: DataType, num: Number): RuntimeValueBase(type) {
val byteval: Short?
val wordval: Int?
@ -21,116 +32,78 @@ open class RuntimeValue(val type: DataType, num: Number?=null, val str: String?=
val asBoolean: Boolean
companion object {
fun from(literalValue: LiteralValue, heap: HeapValues): RuntimeValue {
return when(literalValue.type) {
in NumericDatatypes -> RuntimeValue(literalValue.type, num = literalValue.asNumericValue!!)
in StringDatatypes -> from(literalValue.heapId!!, heap)
in ArrayDatatypes -> from(literalValue.heapId!!, heap)
else -> TODO("type")
}
fun fromLv(literalValue: NumericLiteralValue): RuntimeValueNumeric {
return RuntimeValueNumeric(literalValue.type, num = literalValue.number)
}
fun from(heapId: Int, heap: HeapValues): RuntimeValue {
val value = heap.get(heapId)
return when {
value.type in StringDatatypes ->
RuntimeValue(value.type, str = value.str!!, heapId = heapId)
value.type in ArrayDatatypes ->
if (value.type == DataType.ARRAY_F) {
RuntimeValue(value.type, array = value.doubleArray!!.toList().toTypedArray(), heapId = heapId)
} else {
val array = value.array!!
if (array.any { it.addressOf != null })
TODO("addressof values")
RuntimeValue(value.type, array = array.map { it.integer!! }.toTypedArray(), heapId = heapId)
}
else -> TODO("weird type on heap")
}
}
}
init {
when(type) {
when (type) {
DataType.UBYTE -> {
byteval = (num!!.toInt() and 255).toShort()
val inum = num.toInt()
require(inum in 0..255) { "invalid value for ubyte: $inum" }
byteval = inum.toShort()
wordval = null
floatval = null
asBoolean = byteval != 0.toShort()
}
DataType.BYTE -> {
val v = num!!.toInt() and 255
byteval = (if(v<128) v else v-256).toShort()
val inum = num.toInt()
require(inum in -128..127) { "invalid value for byte: $inum" }
byteval = inum.toShort()
wordval = null
floatval = null
asBoolean = byteval != 0.toShort()
}
DataType.UWORD -> {
wordval = num!!.toInt() and 65535
val inum = num.toInt()
require(inum in 0..65535) { "invalid value for uword: $inum" }
wordval = inum
byteval = null
floatval = null
asBoolean = wordval != 0
}
DataType.WORD -> {
val v = num!!.toInt() and 65535
wordval = if(v<32768) v else v - 65536
val inum = num.toInt()
require(inum in -32768..32767) { "invalid value for word: $inum" }
wordval = inum
byteval = null
floatval = null
asBoolean = wordval != 0
}
DataType.FLOAT -> {
floatval = num!!.toDouble()
floatval = num.toDouble()
byteval = null
wordval = null
asBoolean = floatval != 0.0
}
else -> {
if(heapId==null)
throw IllegalArgumentException("for non-numeric types, a heapId should be given")
byteval = null
wordval = null
floatval = null
asBoolean = true
}
}
}
fun asLiteralValue(): LiteralValue {
return when(type) {
in ByteDatatypes -> LiteralValue(type, byteval, position = Position("", 0, 0, 0))
in WordDatatypes -> LiteralValue(type, wordvalue = wordval, position = Position("", 0, 0, 0))
DataType.FLOAT -> LiteralValue(type, floatvalue = floatval, position = Position("", 0, 0, 0))
in StringDatatypes -> LiteralValue(type, strvalue = str, position = Position("", 0, 0, 0))
in ArrayDatatypes -> LiteralValue(type,
arrayvalue = array?.map { LiteralValue.optimalNumeric(it, Position("", 0, 0, 0)) }?.toTypedArray(),
position = Position("", 0, 0, 0))
else -> TODO("strange type")
else -> throw VmExecutionException("not a numeric value")
}
}
override fun toString(): String {
return when(type) {
return when (type) {
DataType.UBYTE -> "ub:%02x".format(byteval)
DataType.BYTE -> {
if(byteval!!<0)
if (byteval!! < 0)
"b:-%02x".format(abs(byteval.toInt()))
else
"b:%02x".format(byteval)
}
DataType.UWORD -> "uw:%04x".format(wordval)
DataType.WORD -> {
if(wordval!!<0)
if (wordval!! < 0)
"w:-%04x".format(abs(wordval))
else
"w:%04x".format(wordval)
}
DataType.FLOAT -> "f:$floatval"
else -> "heap:$heapId"
else -> "???"
}
}
fun numericValue(): Number {
return when(type) {
override fun numericValue(): Number {
return when (type) {
in ByteDatatypes -> byteval!!
in WordDatatypes -> wordval!!
DataType.FLOAT -> floatval!!
@ -138,8 +111,8 @@ open class RuntimeValue(val type: DataType, num: Number?=null, val str: String?=
}
}
fun integerValue(): Int {
return when(type) {
override fun integerValue(): Int {
return when (type) {
in ByteDatatypes -> byteval!!.toInt()
in WordDatatypes -> wordval!!
DataType.FLOAT -> throw ArithmeticException("float to integer loss of precision")
@ -147,59 +120,72 @@ open class RuntimeValue(val type: DataType, num: Number?=null, val str: String?=
}
}
override fun hashCode(): Int {
val bh = byteval?.hashCode() ?: 0x10001234
val wh = wordval?.hashCode() ?: 0x01002345
val fh = floatval?.hashCode() ?: 0x00103456
return bh xor wh xor fh xor heapId.hashCode() xor type.hashCode()
}
override fun hashCode(): Int = Objects.hash(byteval, wordval, floatval, type)
override fun equals(other: Any?): Boolean {
if(other==null || other !is RuntimeValue)
if (other == null || other !is RuntimeValueNumeric)
return false
if(type==other.type)
return if (type in IterableDatatypes) heapId==other.heapId else compareTo(other)==0
return compareTo(other)==0 // note: datatype doesn't matter
return compareTo(other) == 0 // note: datatype doesn't matter
}
operator fun compareTo(other: RuntimeValue): Int {
return if (type in NumericDatatypes && other.type in NumericDatatypes)
numericValue().toDouble().compareTo(other.numericValue().toDouble())
else throw ArithmeticException("comparison can only be done between two numeric values")
}
operator fun compareTo(other: RuntimeValueNumeric): Int = numericValue().toDouble().compareTo(other.numericValue().toDouble())
private fun arithResult(leftDt: DataType, result: Number, rightDt: DataType, op: String): RuntimeValue {
if(leftDt!=rightDt)
private fun arithResult(leftDt: DataType, result: Number, rightDt: DataType, op: String): RuntimeValueNumeric {
if (leftDt != rightDt)
throw ArithmeticException("left and right datatypes are not the same")
if(result.toDouble() < 0 ) {
return when(leftDt) {
if (result.toDouble() < 0) {
return when (leftDt) {
DataType.UBYTE, DataType.UWORD -> {
// storing a negative number in an unsigned one is done by storing the 2's complement instead
val number = abs(result.toDouble().toInt())
if(leftDt== DataType.UBYTE)
RuntimeValue(DataType.UBYTE, (number xor 255) + 1)
if (leftDt == DataType.UBYTE)
RuntimeValueNumeric(DataType.UBYTE, (number xor 255) + 1)
else
RuntimeValue(DataType.UBYTE, (number xor 65535) + 1)
RuntimeValueNumeric(DataType.UWORD, (number xor 65535) + 1)
}
DataType.BYTE -> RuntimeValue(DataType.BYTE, result.toInt())
DataType.WORD -> RuntimeValue(DataType.WORD, result.toInt())
DataType.FLOAT -> RuntimeValue(DataType.FLOAT, result)
DataType.BYTE -> {
val v = result.toInt() and 255
if (v < 128)
RuntimeValueNumeric(DataType.BYTE, v)
else
RuntimeValueNumeric(DataType.BYTE, v - 256)
}
DataType.WORD -> {
val v = result.toInt() and 65535
if (v < 32768)
RuntimeValueNumeric(DataType.WORD, v)
else
RuntimeValueNumeric(DataType.WORD, v - 65536)
}
DataType.FLOAT -> RuntimeValueNumeric(DataType.FLOAT, result)
else -> throw ArithmeticException("$op on non-numeric type")
}
}
return when(leftDt) {
DataType.UBYTE -> RuntimeValue(DataType.UBYTE, result.toInt())
DataType.BYTE -> RuntimeValue(DataType.BYTE, result.toInt())
DataType.UWORD -> RuntimeValue(DataType.UWORD, result.toInt())
DataType.WORD -> RuntimeValue(DataType.WORD, result.toInt())
DataType.FLOAT -> RuntimeValue(DataType.FLOAT, result)
return when (leftDt) {
DataType.UBYTE -> RuntimeValueNumeric(DataType.UBYTE, result.toInt() and 255)
DataType.BYTE -> {
val v = result.toInt() and 255
if (v < 128)
RuntimeValueNumeric(DataType.BYTE, v)
else
RuntimeValueNumeric(DataType.BYTE, v - 256)
}
DataType.UWORD -> RuntimeValueNumeric(DataType.UWORD, result.toInt() and 65535)
DataType.WORD -> {
val v = result.toInt() and 65535
if (v < 32768)
RuntimeValueNumeric(DataType.WORD, v)
else
RuntimeValueNumeric(DataType.WORD, v - 65536)
}
DataType.FLOAT -> RuntimeValueNumeric(DataType.FLOAT, result)
else -> throw ArithmeticException("$op on non-numeric type")
}
}
fun add(other: RuntimeValue): RuntimeValue {
if(other.type == DataType.FLOAT && (type!= DataType.FLOAT))
fun add(other: RuntimeValueNumeric): RuntimeValueNumeric {
if (other.type == DataType.FLOAT && (type != DataType.FLOAT))
throw ArithmeticException("floating point loss of precision on type $type")
val v1 = numericValue()
val v2 = other.numericValue()
@ -207,8 +193,8 @@ open class RuntimeValue(val type: DataType, num: Number?=null, val str: String?=
return arithResult(type, result, other.type, "add")
}
fun sub(other: RuntimeValue): RuntimeValue {
if(other.type == DataType.FLOAT && (type!= DataType.FLOAT))
fun sub(other: RuntimeValueNumeric): RuntimeValueNumeric {
if (other.type == DataType.FLOAT && (type != DataType.FLOAT))
throw ArithmeticException("floating point loss of precision on type $type")
val v1 = numericValue()
val v2 = other.numericValue()
@ -216,8 +202,8 @@ open class RuntimeValue(val type: DataType, num: Number?=null, val str: String?=
return arithResult(type, result, other.type, "sub")
}
fun mul(other: RuntimeValue): RuntimeValue {
if(other.type == DataType.FLOAT && (type!= DataType.FLOAT))
fun mul(other: RuntimeValueNumeric): RuntimeValueNumeric {
if (other.type == DataType.FLOAT && (type != DataType.FLOAT))
throw ArithmeticException("floating point loss of precision on type $type")
val v1 = numericValue()
val v2 = other.numericValue()
@ -225,279 +211,352 @@ open class RuntimeValue(val type: DataType, num: Number?=null, val str: String?=
return arithResult(type, result, other.type, "mul")
}
fun div(other: RuntimeValue): RuntimeValue {
if(other.type == DataType.FLOAT && (type!= DataType.FLOAT))
fun div(other: RuntimeValueNumeric): RuntimeValueNumeric {
if (other.type == DataType.FLOAT && (type != DataType.FLOAT))
throw ArithmeticException("floating point loss of precision on type $type")
val v1 = numericValue()
val v2 = other.numericValue()
if(v2.toDouble()==0.0) {
if (v2.toDouble() == 0.0) {
when (type) {
DataType.UBYTE -> return RuntimeValue(DataType.UBYTE, 255)
DataType.BYTE -> return RuntimeValue(DataType.BYTE, 127)
DataType.UWORD -> return RuntimeValue(DataType.UWORD, 65535)
DataType.WORD -> return RuntimeValue(DataType.WORD, 32767)
else -> {}
DataType.UBYTE -> return RuntimeValueNumeric(DataType.UBYTE, 255)
DataType.BYTE -> return RuntimeValueNumeric(DataType.BYTE, 127)
DataType.UWORD -> return RuntimeValueNumeric(DataType.UWORD, 65535)
DataType.WORD -> return RuntimeValueNumeric(DataType.WORD, 32767)
else -> {
}
}
}
val result = v1.toDouble() / v2.toDouble()
// NOTE: integer division returns integer result!
return when(type) {
DataType.UBYTE -> RuntimeValue(DataType.UBYTE, result)
DataType.BYTE -> RuntimeValue(DataType.BYTE, result)
DataType.UWORD -> RuntimeValue(DataType.UWORD, result)
DataType.WORD -> RuntimeValue(DataType.WORD, result)
DataType.FLOAT -> RuntimeValue(DataType.FLOAT, result)
return when (type) {
DataType.UBYTE -> RuntimeValueNumeric(DataType.UBYTE, result)
DataType.BYTE -> RuntimeValueNumeric(DataType.BYTE, result)
DataType.UWORD -> RuntimeValueNumeric(DataType.UWORD, result)
DataType.WORD -> RuntimeValueNumeric(DataType.WORD, result)
DataType.FLOAT -> RuntimeValueNumeric(DataType.FLOAT, result)
else -> throw ArithmeticException("div on non-numeric type")
}
}
fun remainder(other: RuntimeValue): RuntimeValue {
fun remainder(other: RuntimeValueNumeric): RuntimeValueNumeric {
val v1 = numericValue()
val v2 = other.numericValue()
val result = v1.toDouble() % v2.toDouble()
return arithResult(type, result, other.type, "remainder")
}
fun pow(other: RuntimeValue): RuntimeValue {
fun pow(other: RuntimeValueNumeric): RuntimeValueNumeric {
val v1 = numericValue()
val v2 = other.numericValue()
val result = v1.toDouble().pow(v2.toDouble())
return arithResult(type, result, other.type,"pow")
return arithResult(type, result, other.type, "pow")
}
fun shl(): RuntimeValue {
fun shl(): RuntimeValueNumeric {
val v = integerValue()
return when (type) {
DataType.UBYTE,
DataType.BYTE,
DataType.UWORD,
DataType.WORD -> RuntimeValue(type, v shl 1)
DataType.UBYTE -> RuntimeValueNumeric(type, (v shl 1) and 255)
DataType.UWORD -> RuntimeValueNumeric(type, (v shl 1) and 65535)
DataType.BYTE -> {
val value = v shl 1
if (value < 128)
RuntimeValueNumeric(type, value)
else
RuntimeValueNumeric(type, value - 256)
}
DataType.WORD -> {
val value = v shl 1
if (value < 32768)
RuntimeValueNumeric(type, value)
else
RuntimeValueNumeric(type, value - 65536)
}
else -> throw ArithmeticException("invalid type for shl: $type")
}
}
fun shr(): RuntimeValue {
fun shr(): RuntimeValueNumeric {
val v = integerValue()
return when(type){
DataType.UBYTE -> RuntimeValue(type, v ushr 1)
DataType.BYTE -> RuntimeValue(type, v shr 1)
DataType.UWORD -> RuntimeValue(type, v ushr 1)
DataType.WORD -> RuntimeValue(type, v shr 1)
return when (type) {
DataType.UBYTE -> RuntimeValueNumeric(type, v ushr 1)
DataType.BYTE -> RuntimeValueNumeric(type, v shr 1)
DataType.UWORD -> RuntimeValueNumeric(type, v ushr 1)
DataType.WORD -> RuntimeValueNumeric(type, v shr 1)
else -> throw ArithmeticException("invalid type for shr: $type")
}
}
fun rol(carry: Boolean): Pair<RuntimeValue, Boolean> {
fun rol(carry: Boolean): Pair<RuntimeValueNumeric, Boolean> {
// 9 or 17 bit rotate left (with carry))
return when(type) {
return when (type) {
DataType.UBYTE, DataType.BYTE -> {
val v = byteval!!.toInt()
val newCarry = (v and 0x80) != 0
val newval = (v and 0x7f shl 1) or (if(carry) 1 else 0)
Pair(RuntimeValue(DataType.UBYTE, newval), newCarry)
val newval = (v and 0x7f shl 1) or (if (carry) 1 else 0)
Pair(RuntimeValueNumeric(DataType.UBYTE, newval), newCarry)
}
DataType.UWORD, DataType.WORD -> {
val v = wordval!!
val newCarry = (v and 0x8000) != 0
val newval = (v and 0x7fff shl 1) or (if(carry) 1 else 0)
Pair(RuntimeValue(DataType.UWORD, newval), newCarry)
val newval = (v and 0x7fff shl 1) or (if (carry) 1 else 0)
Pair(RuntimeValueNumeric(DataType.UWORD, newval), newCarry)
}
else -> throw ArithmeticException("rol can only work on byte/word")
}
}
fun ror(carry: Boolean): Pair<RuntimeValue, Boolean> {
fun ror(carry: Boolean): Pair<RuntimeValueNumeric, Boolean> {
// 9 or 17 bit rotate right (with carry)
return when(type) {
return when (type) {
DataType.UBYTE, DataType.BYTE -> {
val v = byteval!!.toInt()
val newCarry = v and 1 != 0
val newval = (v ushr 1) or (if(carry) 0x80 else 0)
Pair(RuntimeValue(DataType.UBYTE, newval), newCarry)
val newval = (v ushr 1) or (if (carry) 0x80 else 0)
Pair(RuntimeValueNumeric(DataType.UBYTE, newval), newCarry)
}
DataType.UWORD, DataType.WORD -> {
val v = wordval!!
val newCarry = v and 1 != 0
val newval = (v ushr 1) or (if(carry) 0x8000 else 0)
Pair(RuntimeValue(DataType.UWORD, newval), newCarry)
val newval = (v ushr 1) or (if (carry) 0x8000 else 0)
Pair(RuntimeValueNumeric(DataType.UWORD, newval), newCarry)
}
else -> throw ArithmeticException("ror2 can only work on byte/word")
}
}
fun rol2(): RuntimeValue {
fun rol2(): RuntimeValueNumeric {
// 8 or 16 bit rotate left
return when(type) {
return when (type) {
DataType.UBYTE, DataType.BYTE -> {
val v = byteval!!.toInt()
val carry = (v and 0x80) ushr 7
val newval = (v and 0x7f shl 1) or carry
RuntimeValue(DataType.UBYTE, newval)
RuntimeValueNumeric(DataType.UBYTE, newval)
}
DataType.UWORD, DataType.WORD -> {
val v = wordval!!
val carry = (v and 0x8000) ushr 15
val newval = (v and 0x7fff shl 1) or carry
RuntimeValue(DataType.UWORD, newval)
RuntimeValueNumeric(DataType.UWORD, newval)
}
else -> throw ArithmeticException("rol2 can only work on byte/word")
}
}
fun ror2(): RuntimeValue {
fun ror2(): RuntimeValueNumeric {
// 8 or 16 bit rotate right
return when(type) {
return when (type) {
DataType.UBYTE, DataType.BYTE -> {
val v = byteval!!.toInt()
val carry = v and 1 shl 7
val newval = (v ushr 1) or carry
RuntimeValue(DataType.UBYTE, newval)
RuntimeValueNumeric(DataType.UBYTE, newval)
}
DataType.UWORD, DataType.WORD -> {
val v = wordval!!
val carry = v and 1 shl 15
val newval = (v ushr 1) or carry
RuntimeValue(DataType.UWORD, newval)
RuntimeValueNumeric(DataType.UWORD, newval)
}
else -> throw ArithmeticException("ror2 can only work on byte/word")
}
}
fun neg(): RuntimeValue {
return when(type) {
DataType.BYTE -> RuntimeValue(DataType.BYTE, -(byteval!!))
DataType.WORD -> RuntimeValue(DataType.WORD, -(wordval!!))
DataType.FLOAT -> RuntimeValue(DataType.FLOAT, -(floatval)!!)
fun neg(): RuntimeValueNumeric {
return when (type) {
DataType.BYTE -> RuntimeValueNumeric(DataType.BYTE, -(byteval!!))
DataType.WORD -> RuntimeValueNumeric(DataType.WORD, -(wordval!!))
DataType.FLOAT -> RuntimeValueNumeric(DataType.FLOAT, -(floatval)!!)
else -> throw ArithmeticException("neg can only work on byte/word/float")
}
}
fun abs(): RuntimeValue {
return when(type) {
DataType.BYTE -> RuntimeValue(DataType.BYTE, abs(byteval!!.toInt()))
DataType.WORD -> RuntimeValue(DataType.WORD, abs(wordval!!))
DataType.FLOAT -> RuntimeValue(DataType.FLOAT, abs(floatval!!))
fun abs(): RuntimeValueNumeric {
return when (type) {
DataType.BYTE -> RuntimeValueNumeric(DataType.BYTE, abs(byteval!!.toInt()))
DataType.WORD -> RuntimeValueNumeric(DataType.WORD, abs(wordval!!))
DataType.FLOAT -> RuntimeValueNumeric(DataType.FLOAT, abs(floatval!!))
else -> throw ArithmeticException("abs can only work on byte/word/float")
}
}
fun bitand(other: RuntimeValue): RuntimeValue {
fun bitand(other: RuntimeValueNumeric): RuntimeValueNumeric {
val v1 = integerValue()
val v2 = other.integerValue()
val result = v1 and v2
return RuntimeValue(type, result)
return RuntimeValueNumeric(type, result)
}
fun bitor(other: RuntimeValue): RuntimeValue {
fun bitor(other: RuntimeValueNumeric): RuntimeValueNumeric {
val v1 = integerValue()
val v2 = other.integerValue()
val result = v1 or v2
return RuntimeValue(type, result)
return RuntimeValueNumeric(type, result)
}
fun bitxor(other: RuntimeValue): RuntimeValue {
fun bitxor(other: RuntimeValueNumeric): RuntimeValueNumeric {
val v1 = integerValue()
val v2 = other.integerValue()
val result = v1 xor v2
return RuntimeValue(type, result)
return RuntimeValueNumeric(type, result)
}
fun and(other: RuntimeValue) = RuntimeValue(DataType.UBYTE, if (this.asBoolean && other.asBoolean) 1 else 0)
fun or(other: RuntimeValue) = RuntimeValue(DataType.UBYTE, if (this.asBoolean || other.asBoolean) 1 else 0)
fun xor(other: RuntimeValue) = RuntimeValue(DataType.UBYTE, if (this.asBoolean xor other.asBoolean) 1 else 0)
fun not() = RuntimeValue(DataType.UBYTE, if (this.asBoolean) 0 else 1)
fun and(other: RuntimeValueNumeric) = RuntimeValueNumeric(DataType.UBYTE, if (this.asBoolean && other.asBoolean) 1 else 0)
fun or(other: RuntimeValueNumeric) = RuntimeValueNumeric(DataType.UBYTE, if (this.asBoolean || other.asBoolean) 1 else 0)
fun xor(other: RuntimeValueNumeric) = RuntimeValueNumeric(DataType.UBYTE, if (this.asBoolean xor other.asBoolean) 1 else 0)
fun not() = RuntimeValueNumeric(DataType.UBYTE, if (this.asBoolean) 0 else 1)
fun inv(): RuntimeValue {
return when(type) {
in ByteDatatypes -> RuntimeValue(type, byteval!!.toInt().inv())
in WordDatatypes -> RuntimeValue(type, wordval!!.inv())
fun inv(): RuntimeValueNumeric {
return when (type) {
DataType.UBYTE -> RuntimeValueNumeric(type, byteval!!.toInt().inv() and 255)
DataType.UWORD -> RuntimeValueNumeric(type, wordval!!.inv() and 65535)
DataType.BYTE -> RuntimeValueNumeric(type, byteval!!.toInt().inv())
DataType.WORD -> RuntimeValueNumeric(type, wordval!!.inv())
else -> throw ArithmeticException("inv can only work on byte/word")
}
}
fun inc(): RuntimeValue {
return when(type) {
in ByteDatatypes -> RuntimeValue(type, byteval!! + 1)
in WordDatatypes -> RuntimeValue(type, wordval!! + 1)
DataType.FLOAT -> RuntimeValue(DataType.FLOAT, floatval!! + 1)
fun inc(): RuntimeValueNumeric {
return when (type) {
DataType.UBYTE -> RuntimeValueNumeric(type, (byteval!! + 1) and 255)
DataType.UWORD -> RuntimeValueNumeric(type, (wordval!! + 1) and 65535)
DataType.BYTE -> {
val newval = byteval!! + 1
if (newval == 128)
RuntimeValueNumeric(type, -128)
else
RuntimeValueNumeric(type, newval)
}
DataType.WORD -> {
val newval = wordval!! + 1
if (newval == 32768)
RuntimeValueNumeric(type, -32768)
else
RuntimeValueNumeric(type, newval)
}
DataType.FLOAT -> RuntimeValueNumeric(DataType.FLOAT, floatval!! + 1)
else -> throw ArithmeticException("inc can only work on numeric types")
}
}
fun dec(): RuntimeValue {
return when(type) {
in ByteDatatypes -> RuntimeValue(type, byteval!! - 1)
in WordDatatypes -> RuntimeValue(type, wordval!! - 1)
DataType.FLOAT -> RuntimeValue(DataType.FLOAT, floatval!! - 1)
fun dec(): RuntimeValueNumeric {
return when (type) {
DataType.UBYTE -> RuntimeValueNumeric(type, (byteval!! - 1) and 255)
DataType.UWORD -> RuntimeValueNumeric(type, (wordval!! - 1) and 65535)
DataType.BYTE -> {
val newval = byteval!! - 1
if (newval == -129)
RuntimeValueNumeric(type, 127)
else
RuntimeValueNumeric(type, newval)
}
DataType.WORD -> {
val newval = wordval!! - 1
if (newval == -32769)
RuntimeValueNumeric(type, 32767)
else
RuntimeValueNumeric(type, newval)
}
DataType.FLOAT -> RuntimeValueNumeric(DataType.FLOAT, floatval!! - 1)
else -> throw ArithmeticException("dec can only work on numeric types")
}
}
fun msb(): RuntimeValue {
return when(type) {
in ByteDatatypes -> RuntimeValue(DataType.UBYTE, 0)
in WordDatatypes -> RuntimeValue(DataType.UBYTE, wordval!! ushr 8 and 255)
fun msb(): RuntimeValueNumeric {
return when (type) {
in ByteDatatypes -> RuntimeValueNumeric(DataType.UBYTE, 0)
in WordDatatypes -> RuntimeValueNumeric(DataType.UBYTE, wordval!! ushr 8 and 255)
else -> throw ArithmeticException("msb can only work on (u)byte/(u)word")
}
}
fun cast(targetType: DataType): RuntimeValue {
fun cast(targetType: DataType): RuntimeValueNumeric {
return when (type) {
DataType.UBYTE -> {
when (targetType) {
DataType.UBYTE -> this
DataType.BYTE -> RuntimeValue(DataType.BYTE, byteval)
DataType.UWORD -> RuntimeValue(DataType.UWORD, numericValue())
DataType.WORD -> RuntimeValue(DataType.WORD, numericValue())
DataType.FLOAT -> RuntimeValue(DataType.FLOAT, numericValue())
DataType.BYTE -> {
val nval = byteval!!.toInt()
if (nval < 128)
RuntimeValueNumeric(DataType.BYTE, nval)
else
RuntimeValueNumeric(DataType.BYTE, nval - 256)
}
DataType.UWORD -> RuntimeValueNumeric(DataType.UWORD, numericValue())
DataType.WORD -> {
val nval = numericValue().toInt()
if (nval < 32768)
RuntimeValueNumeric(DataType.WORD, nval)
else
RuntimeValueNumeric(DataType.WORD, nval - 65536)
}
DataType.FLOAT -> RuntimeValueNumeric(DataType.FLOAT, numericValue())
else -> throw ArithmeticException("invalid type cast from $type to $targetType")
}
}
DataType.BYTE -> {
when (targetType) {
DataType.BYTE -> this
DataType.UBYTE -> RuntimeValue(DataType.UBYTE, integerValue())
DataType.UWORD -> RuntimeValue(DataType.UWORD, integerValue())
DataType.WORD -> RuntimeValue(DataType.WORD, integerValue())
DataType.FLOAT -> RuntimeValue(DataType.FLOAT, numericValue())
DataType.UBYTE -> RuntimeValueNumeric(DataType.UBYTE, integerValue() and 255)
DataType.UWORD -> RuntimeValueNumeric(DataType.UWORD, integerValue() and 65535)
DataType.WORD -> RuntimeValueNumeric(DataType.WORD, integerValue())
DataType.FLOAT -> RuntimeValueNumeric(DataType.FLOAT, numericValue())
else -> throw ArithmeticException("invalid type cast from $type to $targetType")
}
}
DataType.UWORD -> {
when (targetType) {
DataType.BYTE -> RuntimeValue(DataType.BYTE, integerValue())
DataType.UBYTE -> RuntimeValue(DataType.UBYTE, integerValue())
DataType.BYTE -> {
val v = integerValue()
if (v < 128)
RuntimeValueNumeric(DataType.BYTE, v)
else
RuntimeValueNumeric(DataType.BYTE, v - 256)
}
DataType.UBYTE -> RuntimeValueNumeric(DataType.UBYTE, integerValue() and 255)
DataType.UWORD -> this
DataType.WORD -> RuntimeValue(DataType.WORD, integerValue())
DataType.FLOAT -> RuntimeValue(DataType.FLOAT, numericValue())
DataType.WORD -> {
val v = integerValue()
if (v < 32768)
RuntimeValueNumeric(DataType.WORD, v)
else
RuntimeValueNumeric(DataType.WORD, v - 65536)
}
DataType.FLOAT -> RuntimeValueNumeric(DataType.FLOAT, numericValue())
else -> throw ArithmeticException("invalid type cast from $type to $targetType")
}
}
DataType.WORD -> {
when (targetType) {
DataType.BYTE -> RuntimeValue(DataType.BYTE, integerValue())
DataType.UBYTE -> RuntimeValue(DataType.UBYTE, integerValue())
DataType.UWORD -> RuntimeValue(DataType.UWORD, integerValue())
DataType.BYTE -> {
val v = integerValue() and 255
if (v < 128)
RuntimeValueNumeric(DataType.BYTE, v)
else
RuntimeValueNumeric(DataType.BYTE, v - 256)
}
DataType.UBYTE -> RuntimeValueNumeric(DataType.UBYTE, integerValue() and 65535)
DataType.UWORD -> RuntimeValueNumeric(DataType.UWORD, integerValue())
DataType.WORD -> this
DataType.FLOAT -> RuntimeValue(DataType.FLOAT, numericValue())
DataType.FLOAT -> RuntimeValueNumeric(DataType.FLOAT, numericValue())
else -> throw ArithmeticException("invalid type cast from $type to $targetType")
}
}
DataType.FLOAT -> {
when (targetType) {
DataType.BYTE -> {
val integer=numericValue().toInt()
if(integer in -128..127)
RuntimeValue(DataType.BYTE, integer)
val integer = numericValue().toInt()
if (integer in -128..127)
RuntimeValueNumeric(DataType.BYTE, integer)
else
throw ArithmeticException("overflow when casting float to byte: $this")
}
DataType.UBYTE -> RuntimeValue(DataType.UBYTE, numericValue().toInt())
DataType.UWORD -> RuntimeValue(DataType.UWORD, numericValue().toInt())
DataType.UBYTE -> RuntimeValueNumeric(DataType.UBYTE, numericValue().toInt())
DataType.UWORD -> RuntimeValueNumeric(DataType.UWORD, numericValue().toInt())
DataType.WORD -> {
val integer=numericValue().toInt()
if(integer in -32768..32767)
RuntimeValue(DataType.WORD, integer)
val integer = numericValue().toInt()
if (integer in -32768..32767)
RuntimeValueNumeric(DataType.WORD, integer)
else
throw ArithmeticException("overflow when casting float to word: $this")
}
@ -508,22 +567,91 @@ open class RuntimeValue(val type: DataType, num: Number?=null, val str: String?=
else -> throw ArithmeticException("invalid type cast from $type to $targetType")
}
}
}
open fun iterator(): Iterator<Number> {
return when (type) {
in StringDatatypes -> {
Petscii.encodePetscii(str!!, true).iterator()
}
in ArrayDatatypes -> {
array!!.iterator()
}
else -> throw IllegalArgumentException("cannot iterate over $this")
class RuntimeValueString(val str: String, val altEncoding: Boolean, val heapId: Int?): RuntimeValueBase(DataType.STR) {
companion object {
fun fromLv(string: StringLiteralValue): RuntimeValueString {
return RuntimeValueString(string.value, string.altEncoding, string.heapId)
}
}
override fun toString(): String = if(type==DataType.STR) "str:$str" else "???"
override fun hashCode(): Int = Objects.hash(type, str)
override fun equals(other: Any?): Boolean {
if (other == null || other !is RuntimeValueString)
return false
return type == other.type && str == other.str
}
fun iterator(): Iterator<Number> = str.map { it.toShort() }.iterator()
override fun numericValue(): Number {
throw VmExecutionException("string is not a number")
}
override fun integerValue(): Int {
throw VmExecutionException("string is not a number")
}
}
class RuntimeValueRange(type: DataType, val range: IntProgression): RuntimeValue(type, 0) {
open class RuntimeValueArray(type: DataType, val array: Array<Number>, val heapId: Int?): RuntimeValueBase(type) {
companion object {
fun fromLv(array: ArrayLiteralValue): RuntimeValueArray {
return if (array.type.istype(DataType.ARRAY_F)) {
val doubleArray = array.value.map { (it as NumericLiteralValue).number }.toTypedArray()
RuntimeValueArray(DataType.ARRAY_F, doubleArray, array.heapId)
} else {
val resultArray = mutableListOf<Number>()
for (elt in array.value.withIndex()) {
if (elt.value is NumericLiteralValue)
resultArray.add((elt.value as NumericLiteralValue).number.toInt())
else {
resultArray.add((elt.hashCode())) // ...poor man's implementation of ADDRESSOF(array), it probably won't work very well
}
}
RuntimeValueArray(array.type.typeOrElse(DataType.STRUCT), resultArray.toTypedArray(), array.heapId)
}
}
}
override fun toString(): String {
return when (type) {
DataType.ARRAY_UB -> "array_ub:..."
DataType.ARRAY_B -> "array_b:..."
DataType.ARRAY_UW -> "array_uw:..."
DataType.ARRAY_W -> "array_w:..."
DataType.ARRAY_F -> "array_f:..."
else -> "???"
}
}
override fun hashCode(): Int = Objects.hash(type, array)
override fun equals(other: Any?): Boolean {
if (other == null || other !is RuntimeValueArray)
return false
return type == other.type && array.contentEquals(other.array)
}
open fun iterator(): Iterator<Number> = array.iterator()
override fun numericValue(): Number {
throw VmExecutionException("array is not a number")
}
override fun integerValue(): Int {
throw VmExecutionException("array is not a number")
}
}
class RuntimeValueRange(type: DataType, val range: IntProgression): RuntimeValueArray(type, range.toList().toTypedArray(), null) {
override fun iterator(): Iterator<Number> {
return range.iterator()
}

699
compiler/src/prog8/vm/astvm/AstVm.kt
View File

File diff suppressed because it is too large Load Diff

204
compiler/src/prog8/vm/astvm/BuiltinFunctions.kt
View File

@ -1,204 +0,0 @@
package prog8.vm.astvm
import prog8.ast.base.DataType
import prog8.vm.RuntimeValue
import java.lang.Math.toDegrees
import java.lang.Math.toRadians
import java.util.*
import kotlin.math.*
import kotlin.random.Random
class BuiltinFunctions {
private val rnd = Random(0)
private val statusFlagsSave = Stack<StatusFlags>()
fun performBuiltinFunction(name: String, args: List<RuntimeValue>, statusflags: StatusFlags): RuntimeValue? {
return when (name) {
"rnd" -> RuntimeValue(DataType.UBYTE, rnd.nextInt() and 255)
"rndw" -> RuntimeValue(DataType.UWORD, rnd.nextInt() and 65535)
"rndf" -> RuntimeValue(DataType.FLOAT, rnd.nextDouble())
"lsb" -> RuntimeValue(DataType.UBYTE, args[0].integerValue() and 255)
"msb" -> RuntimeValue(DataType.UBYTE, (args[0].integerValue() ushr 8) and 255)
"sin" -> RuntimeValue(DataType.FLOAT, sin(args[0].numericValue().toDouble()))
"sin8" -> {
val rad = args[0].numericValue().toDouble() / 256.0 * 2.0 * PI
RuntimeValue(DataType.BYTE, (127.0 * sin(rad)).toShort())
}
"sin8u" -> {
val rad = args[0].numericValue().toDouble() / 256.0 * 2.0 * PI
RuntimeValue(DataType.UBYTE, (128.0 + 127.5 * sin(rad)).toShort())
}
"sin16" -> {
val rad = args[0].numericValue().toDouble() / 256.0 * 2.0 * PI
RuntimeValue(DataType.BYTE, (32767.0 * sin(rad)).toShort())
}
"sin16u" -> {
val rad = args[0].numericValue().toDouble() / 256.0 * 2.0 * PI
RuntimeValue(DataType.UBYTE, (32768.0 + 32767.5 * sin(rad)).toShort())
}
"cos" -> RuntimeValue(DataType.FLOAT, cos(args[0].numericValue().toDouble()))
"cos8" -> {
val rad = args[0].numericValue().toDouble() / 256.0 * 2.0 * PI
RuntimeValue(DataType.BYTE, (127.0 * cos(rad)).toShort())
}
"cos8u" -> {
val rad = args[0].numericValue().toDouble() / 256.0 * 2.0 * PI
RuntimeValue(DataType.UBYTE, (128.0 + 127.5 * cos(rad)).toShort())
}
"cos16" -> {
val rad = args[0].numericValue().toDouble() / 256.0 * 2.0 * PI
RuntimeValue(DataType.BYTE, (32767.0 * cos(rad)).toShort())
}
"cos16u" -> {
val rad = args[0].numericValue().toDouble() / 256.0 * 2.0 * PI
RuntimeValue(DataType.UBYTE, (32768.0 + 32767.5 * cos(rad)).toShort())
}
"tan" -> RuntimeValue(DataType.FLOAT, tan(args[0].numericValue().toDouble()))
"atan" -> RuntimeValue(DataType.FLOAT, atan(args[0].numericValue().toDouble()))
"ln" -> RuntimeValue(DataType.FLOAT, ln(args[0].numericValue().toDouble()))
"log2" -> RuntimeValue(DataType.FLOAT, log2(args[0].numericValue().toDouble()))
"sqrt" -> RuntimeValue(DataType.FLOAT, sqrt(args[0].numericValue().toDouble()))
"sqrt16" -> RuntimeValue(DataType.UBYTE, sqrt(args[0].wordval!!.toDouble()).toInt())
"rad" -> RuntimeValue(DataType.FLOAT, toRadians(args[0].numericValue().toDouble()))
"deg" -> RuntimeValue(DataType.FLOAT, toDegrees(args[0].numericValue().toDouble()))
"round" -> RuntimeValue(DataType.FLOAT, round(args[0].numericValue().toDouble()))
"floor" -> RuntimeValue(DataType.FLOAT, floor(args[0].numericValue().toDouble()))
"ceil" -> RuntimeValue(DataType.FLOAT, ceil(args[0].numericValue().toDouble()))
"rol" -> {
val (result, newCarry) = args[0].rol(statusflags.carry)
statusflags.carry = newCarry
return result
}
"rol2" -> args[0].rol2()
"ror" -> {
val (result, newCarry) = args[0].ror(statusflags.carry)
statusflags.carry = newCarry
return result
}
"ror2" -> args[0].ror2()
"lsl" -> args[0].shl()
"lsr" -> args[0].shr()
"abs" -> {
when (args[0].type) {
DataType.UBYTE -> args[0]
DataType.BYTE -> RuntimeValue(DataType.UBYTE, abs(args[0].numericValue().toDouble()))
DataType.UWORD -> args[0]
DataType.WORD -> RuntimeValue(DataType.UWORD, abs(args[0].numericValue().toDouble()))
DataType.FLOAT -> RuntimeValue(DataType.FLOAT, abs(args[0].numericValue().toDouble()))
else -> TODO("strange abs type")
}
}
"max" -> {
val numbers = args.map { it.numericValue().toDouble() }
RuntimeValue(args[0].type, numbers.max())
}
"min" -> {
val numbers = args.map { it.numericValue().toDouble() }
RuntimeValue(args[0].type, numbers.min())
}
"avg" -> {
val numbers = args.map { it.numericValue().toDouble() }
RuntimeValue(DataType.FLOAT, numbers.average())
}
"sum" -> {
val sum = args.map { it.numericValue().toDouble() }.sum()
when (args[0].type) {
DataType.UBYTE -> RuntimeValue(DataType.UWORD, sum)
DataType.BYTE -> RuntimeValue(DataType.WORD, sum)
DataType.UWORD -> RuntimeValue(DataType.UWORD, sum)
DataType.WORD -> RuntimeValue(DataType.WORD, sum)
DataType.FLOAT -> RuntimeValue(DataType.FLOAT, sum)
else -> TODO("weird sum type")
}
}
"any" -> {
val numbers = args.map { it.numericValue().toDouble() }
RuntimeValue(DataType.UBYTE, if (numbers.any { it != 0.0 }) 1 else 0)
}
"all" -> {
val numbers = args.map { it.numericValue().toDouble() }
RuntimeValue(DataType.UBYTE, if (numbers.all { it != 0.0 }) 1 else 0)
}
"swap" ->
throw VmExecutionException("swap() cannot be implemented as a function")
"strlen" -> {
val zeroIndex = args[0].str!!.indexOf(0.toChar())
if (zeroIndex >= 0)
RuntimeValue(DataType.UBYTE, zeroIndex)
else
RuntimeValue(DataType.UBYTE, args[0].str!!.length)
}
"memset" -> {
val target = args[0].array!!
val amount = args[1].integerValue()
val value = args[2].integerValue()
for (i in 0 until amount) {
target[i] = value
}
null
}
"memsetw" -> {
val target = args[0].array!!
val amount = args[1].integerValue()
val value = args[2].integerValue()
for (i in 0 until amount step 2) {
target[i * 2] = value and 255
target[i * 2 + 1] = value ushr 8
}
null
}
"memcopy" -> {
val source = args[0].array!!
val dest = args[1].array!!
val amount = args[2].integerValue()
for(i in 0 until amount) {
dest[i] = source[i]
}
null
}
"mkword" -> {
val result = (args[1].integerValue() shl 8) or args[0].integerValue()
RuntimeValue(DataType.UWORD, result)
}
"set_carry" -> {
statusflags.carry=true
null
}
"clear_carry" -> {
statusflags.carry=false
null
}
"set_irqd" -> {
statusflags.irqd=true
null
}
"clear_irqd" -> {
statusflags.irqd=false
null
}
"read_flags" -> {
val carry = if(statusflags.carry) 1 else 0
val zero = if(statusflags.zero) 2 else 0
val irqd = if(statusflags.irqd) 4 else 0
val negative = if(statusflags.negative) 128 else 0
RuntimeValue(DataType.UBYTE, carry or zero or irqd or negative)
}
"rsave" -> {
statusFlagsSave.push(statusflags)
null
}
"rrestore" -> {
val flags = statusFlagsSave.pop()
statusflags.carry = flags.carry
statusflags.negative = flags.negative
statusflags.zero = flags.zero
statusflags.irqd = flags.irqd
null
}
else -> TODO("builtin function $name")
}
}
}

18
compiler/src/prog8/vm/astvm/CallStack.kt
View File

@ -1,18 +0,0 @@
package prog8.vm.astvm
import prog8.ast.INameScope
import java.util.*
class CallStack {
private val stack = Stack<Pair<INameScope, Int>>()
fun pop(): Pair<INameScope, Int> {
return stack.pop()
}
fun push(scope: INameScope, index: Int) {
stack.push(Pair(scope, index))
}
}

150
compiler/src/prog8/vm/astvm/Expressions.kt
View File

@ -1,50 +1,55 @@
package prog8.vm.astvm
import prog8.ast.*
import prog8.ast.Program
import prog8.ast.base.ArrayElementTypes
import prog8.ast.base.DataType
import prog8.ast.base.FatalAstException
import prog8.ast.base.VarDeclType
import prog8.ast.expressions.*
import prog8.ast.statements.BuiltinFunctionStatementPlaceholder
import prog8.ast.statements.Label
import prog8.ast.statements.Subroutine
import prog8.ast.statements.VarDecl
import prog8.vm.RuntimeValue
import prog8.vm.RuntimeValueRange
import kotlin.math.abs
import prog8.vm.*
typealias BuiltinfunctionCaller = (name: String, args: List<RuntimeValueNumeric>, flags: StatusFlags) -> RuntimeValueNumeric?
typealias SubroutineCaller = (sub: Subroutine, args: List<RuntimeValueNumeric>, startAtLabel: Label?) -> RuntimeValueNumeric?
class EvalContext(val program: Program, val mem: Memory, val statusflags: StatusFlags,
val runtimeVars: RuntimeVariables, val functions: BuiltinFunctions,
val executeSubroutine: (sub: Subroutine, args: List<RuntimeValue>, startlabel: Label?) -> List<RuntimeValue>)
val runtimeVars: RuntimeVariables,
val performBuiltinFunction: BuiltinfunctionCaller,
val executeSubroutine: SubroutineCaller)
fun evaluate(expr: IExpression, ctx: EvalContext): RuntimeValue {
fun evaluate(expr: Expression, ctx: EvalContext): RuntimeValueBase {
val constval = expr.constValue(ctx.program)
if(constval!=null)
return RuntimeValue.from(constval, ctx.program.heap)
return RuntimeValueNumeric.fromLv(constval)
when(expr) {
is LiteralValue -> {
return RuntimeValue.from(expr, ctx.program.heap)
}
is NumericLiteralValue -> return RuntimeValueNumeric.fromLv(expr)
is StringLiteralValue -> return RuntimeValueString.fromLv(expr)
is ArrayLiteralValue -> return RuntimeValueArray.fromLv(expr)
is PrefixExpression -> {
return when(expr.operator) {
"-" -> evaluate(expr.expression, ctx).neg()
"~" -> evaluate(expr.expression, ctx).inv()
"not" -> evaluate(expr.expression, ctx).not()
"-" -> (evaluate(expr.expression, ctx) as RuntimeValueNumeric).neg()
"~" -> (evaluate(expr.expression, ctx) as RuntimeValueNumeric).inv()
"not" -> (evaluate(expr.expression, ctx) as RuntimeValueNumeric).not()
// unary '+' should have been optimized away
else -> throw VmExecutionException("unsupported prefix operator "+expr.operator)
}
}
is BinaryExpression -> {
val left = evaluate(expr.left, ctx)
val right = evaluate(expr.right, ctx)
val left = evaluate(expr.left, ctx) as RuntimeValueNumeric
val right = evaluate(expr.right, ctx) as RuntimeValueNumeric
return when(expr.operator) {
"<" -> RuntimeValue(DataType.UBYTE, if (left < right) 1 else 0)
"<=" -> RuntimeValue(DataType.UBYTE, if (left <= right) 1 else 0)
">" -> RuntimeValue(DataType.UBYTE, if (left > right) 1 else 0)
">=" -> RuntimeValue(DataType.UBYTE, if (left >= right) 1 else 0)
"==" -> RuntimeValue(DataType.UBYTE, if (left == right) 1 else 0)
"!=" -> RuntimeValue(DataType.UBYTE, if (left != right) 1 else 0)
"<" -> RuntimeValueNumeric(DataType.UBYTE, if (left < right) 1 else 0)
"<=" -> RuntimeValueNumeric(DataType.UBYTE, if (left <= right) 1 else 0)
">" -> RuntimeValueNumeric(DataType.UBYTE, if (left > right) 1 else 0)
">=" -> RuntimeValueNumeric(DataType.UBYTE, if (left >= right) 1 else 0)
"==" -> RuntimeValueNumeric(DataType.UBYTE, if (left == right) 1 else 0)
"!=" -> RuntimeValueNumeric(DataType.UBYTE, if (left != right) 1 else 0)
"+" -> left.add(right)
"-" -> left.sub(right)
"*" -> left.mul(right)
@ -72,40 +77,56 @@ fun evaluate(expr: IExpression, ctx: EvalContext): RuntimeValue {
}
is ArrayIndexedExpression -> {
val array = evaluate(expr.identifier, ctx)
val index = evaluate(expr.arrayspec.index, ctx)
val value = array.array!![index.integerValue()]
return RuntimeValue(ArrayElementTypes.getValue(array.type), value)
val index = evaluate(expr.arrayspec.index, ctx) as RuntimeValueNumeric
return when (array) {
is RuntimeValueString -> {
val value = array.str[index.integerValue()]
RuntimeValueNumeric(ArrayElementTypes.getValue(array.type), value.toShort())
}
is RuntimeValueArray -> {
val value = array.array[index.integerValue()]
RuntimeValueNumeric(ArrayElementTypes.getValue(array.type), value)
}
else -> throw VmExecutionException("weird type")
}
}
is TypecastExpression -> {
return evaluate(expr.expression, ctx).cast(expr.type)
return (evaluate(expr.expression, ctx) as RuntimeValueNumeric).cast(expr.type)
}
is AddressOf -> {
// we support: address of heap var -> the heap id
val heapId = expr.identifier.heapId(ctx.program.namespace)
return RuntimeValue(DataType.UWORD, heapId)
return try {
val heapId = expr.identifier.heapId(ctx.program.namespace)
RuntimeValueNumeric(DataType.UWORD, heapId)
} catch( f: FatalAstException) {
// fallback: use the hash of the name, so we have at least *a* value...
val address = expr.identifier.hashCode() and 65535
RuntimeValueNumeric(DataType.UWORD, address)
}
}
is DirectMemoryRead -> {
val address = evaluate(expr.addressExpression, ctx).wordval!!
return RuntimeValue(DataType.UBYTE, ctx.mem.getUByte(address))
val address = (evaluate(expr.addressExpression, ctx) as RuntimeValueNumeric).wordval!!
return RuntimeValueNumeric(DataType.UBYTE, ctx.mem.getUByte(address))
}
is RegisterExpr -> return ctx.runtimeVars.get(ctx.program.namespace, expr.register.name)
is IdentifierReference -> {
val scope = expr.definingScope()
val variable = scope.lookup(expr.nameInSource, expr)
if(variable is VarDecl) {
if(variable.type==VarDeclType.VAR)
return ctx.runtimeVars.get(variable.definingScope(), variable.name)
else {
val address = ctx.runtimeVars.getMemoryAddress(variable.definingScope(), variable.name)
return when(variable.datatype) {
DataType.UBYTE -> RuntimeValue(DataType.UBYTE, ctx.mem.getUByte(address))
DataType.BYTE -> RuntimeValue(DataType.BYTE, ctx.mem.getSByte(address))
DataType.UWORD -> RuntimeValue(DataType.UWORD, ctx.mem.getUWord(address))
DataType.WORD -> RuntimeValue(DataType.WORD, ctx.mem.getSWord(address))
DataType.FLOAT -> RuntimeValue(DataType.FLOAT, ctx.mem.getFloat(address))
DataType.STR -> RuntimeValue(DataType.STR, str = ctx.mem.getString(address))
DataType.STR_S -> RuntimeValue(DataType.STR_S, str = ctx.mem.getScreencodeString(address))
else -> throw VmExecutionException("unexpected datatype $variable")
when {
variable.type==VarDeclType.VAR -> return ctx.runtimeVars.get(variable.definingScope(), variable.name)
variable.datatype==DataType.STRUCT -> throw VmExecutionException("cannot process structs by-value. at ${expr.position}")
else -> {
val address = ctx.runtimeVars.getMemoryAddress(variable.definingScope(), variable.name)
return when(variable.datatype) {
DataType.UBYTE -> RuntimeValueNumeric(DataType.UBYTE, ctx.mem.getUByte(address))
DataType.BYTE -> RuntimeValueNumeric(DataType.BYTE, ctx.mem.getSByte(address))
DataType.UWORD -> RuntimeValueNumeric(DataType.UWORD, ctx.mem.getUWord(address))
DataType.WORD -> RuntimeValueNumeric(DataType.WORD, ctx.mem.getSWord(address))
DataType.FLOAT -> RuntimeValueNumeric(DataType.FLOAT, ctx.mem.getFloat(address))
DataType.STR -> RuntimeValueString(ctx.mem.getString(address, false), false, null)
else -> throw VmExecutionException("unexpected datatype $variable")
}
}
}
} else
@ -113,16 +134,15 @@ fun evaluate(expr: IExpression, ctx: EvalContext): RuntimeValue {
}
is FunctionCall -> {
val sub = expr.target.targetStatement(ctx.program.namespace)
val args = expr.arglist.map { evaluate(it, ctx) }
val args = expr.args.map { evaluate(it, ctx) as RuntimeValueNumeric }
return when(sub) {
is Subroutine -> {
val results = ctx.executeSubroutine(sub, args, null)
if(results.size!=1)
throw VmExecutionException("expected 1 result from functioncall $expr")
results[0]
val result = ctx.executeSubroutine(sub, args, null)
?: throw VmExecutionException("expected a result from functioncall $expr")
result
}
is BuiltinFunctionStatementPlaceholder -> {
val result = ctx.functions.performBuiltinFunction(sub.name, args, ctx.statusflags)
val result = ctx.performBuiltinFunction(sub.name, args, ctx.statusflags)
?: throw VmExecutionException("expected 1 result from functioncall $expr")
result
}
@ -133,24 +153,22 @@ fun evaluate(expr: IExpression, ctx: EvalContext): RuntimeValue {
}
is RangeExpr -> {
val cRange = expr.toConstantIntegerRange()
if(cRange!=null)
return RuntimeValueRange(expr.inferType(ctx.program)!!, cRange)
val fromVal = evaluate(expr.from, ctx).integerValue()
val toVal = evaluate(expr.to, ctx).integerValue()
val stepVal = evaluate(expr.step, ctx).integerValue()
val range = when {
fromVal <= toVal -> when {
stepVal <= 0 -> IntRange.EMPTY
stepVal == 1 -> fromVal..toVal
else -> fromVal..toVal step stepVal
}
else -> when {
stepVal >= 0 -> IntRange.EMPTY
stepVal == -1 -> fromVal downTo toVal
else -> fromVal downTo toVal step abs(stepVal)
}
if(cRange!=null) {
val dt = expr.inferType(ctx.program)
if(dt.isKnown)
return RuntimeValueRange(dt.typeOrElse(DataType.UBYTE), cRange)
else
throw VmExecutionException("couldn't determine datatype")
}
return RuntimeValueRange(expr.inferType(ctx.program)!!, range)
val fromVal = (evaluate(expr.from, ctx) as RuntimeValueNumeric).integerValue()
val toVal = (evaluate(expr.to, ctx) as RuntimeValueNumeric).integerValue()
val stepVal = (evaluate(expr.step, ctx) as RuntimeValueNumeric).integerValue()
val range = makeRange(fromVal, toVal, stepVal)
val dt = expr.inferType(ctx.program)
if(dt.isKnown)
return RuntimeValueRange(dt.typeOrElse(DataType.UBYTE), range)
else
throw VmExecutionException("couldn't determine datatype")
}
else -> {
throw VmExecutionException("unimplemented expression node $expr")

48
compiler/src/prog8/vm/astvm/Memory.kt
View File

@ -1,7 +1,7 @@
package prog8.vm.astvm
import prog8.compiler.target.c64.Mflpt5
import prog8.compiler.target.c64.Petscii
import prog8.compiler.target.CompilationTarget
import prog8.compiler.target.c64.C64MachineDefinition
import kotlin.math.abs
class Memory(private val readObserver: (address: Int, value: Short) -> Short,
@ -21,7 +21,7 @@ class Memory(private val readObserver: (address: Int, value: Short) -> Short,
else mem[address]
}
fun getUByte_DMA(address: Int): Short {
fun getUByteDirectly(address: Int): Short {
return mem[address]
}
@ -39,7 +39,7 @@ class Memory(private val readObserver: (address: Int, value: Short) -> Short,
else value
}
fun setUByte_DMA(address: Int, value: Short) {
fun setUByteDirectly(address: Int, value: Short) {
if(value !in 0..255)
throw VmExecutionException("ubyte value out of range $value")
mem[address] = value
@ -80,7 +80,7 @@ class Memory(private val readObserver: (address: Int, value: Short) -> Short,
}
fun setFloat(address: Int, value: Double) {
val mflpt5 = Mflpt5.fromNumber(value)
val mflpt5 = C64MachineDefinition.Mflpt5.fromNumber(value)
setUByte(address, mflpt5.b0)
setUByte(address+1, mflpt5.b1)
setUByte(address+2, mflpt5.b2)
@ -89,28 +89,26 @@ class Memory(private val readObserver: (address: Int, value: Short) -> Short,
}
fun getFloat(address: Int): Double {
return Mflpt5(getUByte(address), getUByte(address + 1), getUByte(address + 2),
return C64MachineDefinition.Mflpt5(getUByte(address), getUByte(address + 1), getUByte(address + 2),
getUByte(address + 3), getUByte(address + 4)).toDouble()
}
fun setString(address: Int, str: String) {
// lowercase PETSCII
val petscii = Petscii.encodePetscii(str, true)
fun setString(address: Int, str: String, altEncoding: Boolean) {
val encoded = CompilationTarget.encodeString(str, altEncoding)
var addr = address
for (c in petscii) setUByte(addr++, c)
for (c in encoded) setUByte(addr++, c)
setUByte(addr, 0)
}
fun getString(strAddress: Int): String {
// lowercase PETSCII
val petscii = mutableListOf<Short>()
fun getString(strAddress: Int, altEncoding: Boolean): String {
val encoded = mutableListOf<Short>()
var addr = strAddress
while(true) {
val byte = getUByte(addr++)
if(byte==0.toShort()) break
petscii.add(byte)
encoded.add(byte)
}
return Petscii.decodePetscii(petscii, true)
return CompilationTarget.decodeString(encoded, altEncoding)
}
fun clear() {
@ -121,24 +119,4 @@ class Memory(private val readObserver: (address: Int, value: Short) -> Short,
for(i in 0 until numbytes)
setUByte(to+i, getUByte(from+i))
}
fun getScreencodeString(strAddress: Int): String? {
// lowercase Screencodes
val screencodes = mutableListOf<Short>()
var addr = strAddress
while(true) {
val byte = getUByte(addr++)
if(byte==0.toShort()) break
screencodes.add(byte)
}
return Petscii.decodeScreencode(screencodes, true)
}
fun setScreencodeString(address: Int, str: String) {
// lowercase screencodes
val screencodes = Petscii.encodeScreencode(str, true)
var addr = address
for (c in screencodes) setUByte(addr++, c)
setUByte(addr, 0)
}
}

105
compiler/src/prog8/vm/astvm/ScreenDialog.kt
View File

@ -1,12 +1,12 @@
package prog8.vm.astvm
import prog8.compiler.target.c64.Charset
import prog8.compiler.target.c64.Colors
import prog8.compiler.target.c64.C64MachineDefinition
import prog8.compiler.target.c64.Petscii
import java.awt.*
import java.awt.event.KeyEvent
import java.awt.event.KeyListener
import java.awt.image.BufferedImage
import java.util.ArrayDeque
import javax.swing.JFrame
import javax.swing.JPanel
import javax.swing.Timer
@ -18,6 +18,7 @@ class BitmapScreenPanel : KeyListener, JPanel() {
private val g2d = image.graphics as Graphics2D
private var cursorX: Int=0
private var cursorY: Int=0
val keyboardBuffer = ArrayDeque<Char>()
init {
val size = Dimension(image.width * SCALING, image.height * SCALING)
@ -30,14 +31,14 @@ class BitmapScreenPanel : KeyListener, JPanel() {
addKeyListener(this)
}
override fun keyTyped(p0: KeyEvent?) {}
override fun keyTyped(p0: KeyEvent) {
keyboardBuffer.add(p0.keyChar)
}
override fun keyPressed(p0: KeyEvent?) {
println("pressed: $p0.k")
override fun keyPressed(p0: KeyEvent) {
}
override fun keyReleased(p0: KeyEvent?) {
println("released: $p0")
}
override fun paint(graphics: Graphics?) {
@ -49,61 +50,57 @@ class BitmapScreenPanel : KeyListener, JPanel() {
}
fun clearScreen(color: Short) {
g2d.background = Colors.palette[color % Colors.palette.size]
g2d.background = C64MachineDefinition.colorPalette[color % C64MachineDefinition.colorPalette.size]
g2d.clearRect(0, 0, SCREENWIDTH, SCREENHEIGHT)
cursorX = 0
cursorY = 0
}
fun setPixel(x: Int, y: Int, color: Short) {
image.setRGB(x, y, Colors.palette[color % Colors.palette.size].rgb)
image.setRGB(x, y, C64MachineDefinition.colorPalette[color % C64MachineDefinition.colorPalette.size].rgb)
}
fun drawLine(x1: Int, y1: Int, x2: Int, y2: Int, color: Short) {
g2d.color = Colors.palette[color % Colors.palette.size]
g2d.color = C64MachineDefinition.colorPalette[color % C64MachineDefinition.colorPalette.size]
g2d.drawLine(x1, y1, x2, y2)
}
fun printText(text: String, color: Short, lowercase: Boolean) {
fun printAsciiText(text: String) {
val t2 = text.substringBefore(0.toChar())
val lines = t2.split('\n')
for(line in lines.withIndex()) {
printTextSingleLine(line.value, color, lowercase)
if(line.index<lines.size-1) {
cursorX=0
cursorY++
}
}
}
private fun printTextSingleLine(text: String, color: Short, lowercase: Boolean) {
for(clearx in cursorX until cursorX+text.length) {
g2d.clearRect(8*clearx, 8*y, 8, 8)
}
for(sc in Petscii.encodeScreencode(text, lowercase)) {
setChar(cursorX, cursorY, sc, color)
cursorX++
if(cursorX>=(SCREENWIDTH /8)) {
cursorY++
cursorX=0
}
}
val petscii = Petscii.encodePetscii(t2, true)
petscii.forEach { printPetsciiChar(it) }
}
fun printChar(char: Short) {
if(char==13.toShort() || char==141.toShort()) {
fun printPetsciiChar(petscii: Short) {
if(petscii in listOf(0x0d.toShort(), 0x8d.toShort())) {
// Return and shift-Return
cursorX=0
cursorY++
} else {
setChar(cursorX, cursorY, char, 1)
val scr = Petscii.petscii2scr(petscii, false)
setScreenChar(cursorX, cursorY, scr, 1)
cursorX++
if (cursorX >= (SCREENWIDTH / 8)) {
cursorY++
cursorX = 0
}
}
while(cursorY>=(SCREENHEIGHT/8)) {
// scroll the screen up because the cursor went past the last line
Thread.sleep(10)
val screen = image.copy()
val graphics = image.graphics as Graphics2D
graphics.drawImage(screen, 0, -8, null)
val color = graphics.color
graphics.color = C64MachineDefinition.colorPalette[6]
graphics.fillRect(0, 24*8, SCREENWIDTH, 25*8)
graphics.color=color
cursorY--
}
}
fun setChar(x: Int, y: Int, screenCode: Short, color: Short) {
fun setScreenChar(x: Int, y: Int, screencode: Short, color: Short) {
g2d.clearRect(8*x, 8*y, 8, 8)
val colorIdx = (color % Colors.palette.size).toShort()
val coloredImage = Charset.getColoredChar(screenCode, colorIdx)
val colorIdx = (color % C64MachineDefinition.colorPalette.size).toShort()
val coloredImage = C64MachineDefinition.Charset.getColoredChar(screencode, colorIdx)
g2d.drawImage(coloredImage, 8*x, 8*y , null)
}
@ -116,20 +113,6 @@ class BitmapScreenPanel : KeyListener, JPanel() {
return Pair(cursorX, cursorY)
}
fun writeText(x: Int, y: Int, text: String, color: Short, lowercase: Boolean) {
val colorIdx = (color % Colors.palette.size).toShort()
var xx=x
for(clearx in xx until xx+text.length) {
g2d.clearRect(8*clearx, 8*y, 8, 8)
}
for(sc in Petscii.encodeScreencode(text, lowercase)) {
if(sc==0.toShort())
break
setChar(xx++, y, sc, colorIdx)
}
}
companion object {
const val SCREENWIDTH = 320
const val SCREENHEIGHT = 200
@ -140,29 +123,30 @@ class BitmapScreenPanel : KeyListener, JPanel() {
class ScreenDialog(title: String) : JFrame(title) {
val canvas = BitmapScreenPanel()
val keyboardBuffer = canvas.keyboardBuffer
init {
val borderWidth = 16
layout = GridBagLayout()
defaultCloseOperation = JFrame.EXIT_ON_CLOSE
defaultCloseOperation = EXIT_ON_CLOSE
isResizable = false
// the borders (top, left, right, bottom)
val borderTop = JPanel().apply {
preferredSize = Dimension(BitmapScreenPanel.SCALING * (BitmapScreenPanel.SCREENWIDTH +2*borderWidth), BitmapScreenPanel.SCALING * borderWidth)
background = Colors.palette[14]
background = C64MachineDefinition.colorPalette[14]
}
val borderBottom = JPanel().apply {
preferredSize =Dimension(BitmapScreenPanel.SCALING * (BitmapScreenPanel.SCREENWIDTH +2*borderWidth), BitmapScreenPanel.SCALING * borderWidth)
background = Colors.palette[14]
background = C64MachineDefinition.colorPalette[14]
}
val borderLeft = JPanel().apply {
preferredSize =Dimension(BitmapScreenPanel.SCALING * borderWidth, BitmapScreenPanel.SCALING * BitmapScreenPanel.SCREENHEIGHT)
background = Colors.palette[14]
background = C64MachineDefinition.colorPalette[14]
}
val borderRight = JPanel().apply {
preferredSize =Dimension(BitmapScreenPanel.SCALING * borderWidth, BitmapScreenPanel.SCALING * BitmapScreenPanel.SCREENHEIGHT)
background = Colors.palette[14]
background = C64MachineDefinition.colorPalette[14]
}
var c = GridBagConstraints()
c.gridx=0; c.gridy=1; c.gridwidth=3
@ -189,3 +173,12 @@ class ScreenDialog(title: String) : JFrame(title) {
repaintTimer.start()
}
}
private fun BufferedImage.copy(): BufferedImage {
val bcopy = BufferedImage(this.width, this.height, this.type)
val g = bcopy.graphics
g.drawImage(this, 0, 0, null)
g.dispose()
return bcopy
}

87
compiler/src/prog8/vm/astvm/VariablesCreator.kt
View File

@ -1,25 +1,37 @@
package prog8.vm.astvm
import prog8.ast.*
import prog8.ast.base.*
import prog8.ast.expressions.LiteralValue
import prog8.ast.Program
import prog8.ast.base.DataType
import prog8.ast.base.Position
import prog8.ast.base.Register
import prog8.ast.base.VarDeclType
import prog8.ast.expressions.ArrayLiteralValue
import prog8.ast.expressions.NumericLiteralValue
import prog8.ast.expressions.StringLiteralValue
import prog8.ast.processing.IAstModifyingVisitor
import prog8.ast.statements.Statement
import prog8.ast.statements.StructDecl
import prog8.ast.statements.VarDecl
import prog8.compiler.HeapValues
import prog8.vm.RuntimeValue
import prog8.ast.statements.ZeropageWish
import prog8.vm.RuntimeValueArray
import prog8.vm.RuntimeValueNumeric
import prog8.vm.RuntimeValueString
class VariablesCreator(private val runtimeVariables: RuntimeVariables, private val heap: HeapValues) : IAstModifyingVisitor {
class VariablesCreator(private val runtimeVariables: RuntimeVariables) : IAstModifyingVisitor {
override fun visit(program: Program) {
// define the three registers as global variables
runtimeVariables.define(program.namespace, Register.A.name, RuntimeValue(DataType.UBYTE, 0))
runtimeVariables.define(program.namespace, Register.X.name, RuntimeValue(DataType.UBYTE, 255))
runtimeVariables.define(program.namespace, Register.Y.name, RuntimeValue(DataType.UBYTE, 0))
runtimeVariables.define(program.namespace, Register.A.name, RuntimeValueNumeric(DataType.UBYTE, 0))
runtimeVariables.define(program.namespace, Register.X.name, RuntimeValueNumeric(DataType.UBYTE, 255))
runtimeVariables.define(program.namespace, Register.Y.name, RuntimeValueNumeric(DataType.UBYTE, 0))
val globalpos = Position("<<global>>", 0, 0, 0)
val vdA = VarDecl(VarDeclType.VAR, DataType.UBYTE, false, null, Register.A.name, LiteralValue.optimalInteger(0, globalpos), isArray = false, autoGenerated = true, position = globalpos)
val vdX = VarDecl(VarDeclType.VAR, DataType.UBYTE, false, null, Register.X.name, LiteralValue.optimalInteger(255, globalpos), isArray = false, autoGenerated = true, position = globalpos)
val vdY = VarDecl(VarDeclType.VAR, DataType.UBYTE, false, null, Register.Y.name, LiteralValue.optimalInteger(0, globalpos), isArray = false, autoGenerated = true, position = globalpos)
val vdA = VarDecl(VarDeclType.VAR, DataType.UBYTE, ZeropageWish.DONTCARE, null, Register.A.name, null,
NumericLiteralValue.optimalInteger(0, globalpos), isArray = false, autogeneratedDontRemove = true, position = globalpos)
val vdX = VarDecl(VarDeclType.VAR, DataType.UBYTE, ZeropageWish.DONTCARE, null, Register.X.name, null,
NumericLiteralValue.optimalInteger(255, globalpos), isArray = false, autogeneratedDontRemove = true, position = globalpos)
val vdY = VarDecl(VarDeclType.VAR, DataType.UBYTE, ZeropageWish.DONTCARE, null, Register.Y.name, null,
NumericLiteralValue.optimalInteger(0, globalpos), isArray = false, autogeneratedDontRemove = true, position = globalpos)
vdA.linkParents(program.namespace)
vdX.linkParents(program.namespace)
vdY.linkParents(program.namespace)
@ -30,28 +42,39 @@ class VariablesCreator(private val runtimeVariables: RuntimeVariables, private v
super.visit(program)
}
override fun visit(decl: VarDecl): IStatement {
when(decl.type) {
// we can assume the value in the vardecl already has been converted into a constant LiteralValue here.
VarDeclType.VAR -> {
val value = RuntimeValue.from(decl.value as LiteralValue, heap)
runtimeVariables.define(decl.definingScope(), decl.name, value)
}
VarDeclType.MEMORY -> {
runtimeVariables.defineMemory(decl.definingScope(), decl.name, (decl.value as LiteralValue).asIntegerValue!!)
}
VarDeclType.CONST -> {
// consts should have been const-folded away
override fun visit(decl: VarDecl): Statement {
// if the decl is part of a struct, just skip it
if(decl.parent !is StructDecl) {
when (decl.type) {
VarDeclType.VAR -> {
if(decl.datatype!=DataType.STRUCT) {
val numericLv = decl.value as? NumericLiteralValue
val value = if(numericLv!=null) {
RuntimeValueNumeric.fromLv(numericLv)
} else {
val strLv = decl.value as? StringLiteralValue
val arrayLv = decl.value as? ArrayLiteralValue
when {
strLv!=null -> {
RuntimeValueString.fromLv(strLv)
}
arrayLv!=null -> {
RuntimeValueArray.fromLv(arrayLv)
}
else -> throw VmExecutionException("weird var type")
}
}
runtimeVariables.define(decl.definingScope(), decl.name, value)
}
}
VarDeclType.MEMORY -> {
runtimeVariables.defineMemory(decl.definingScope(), decl.name, (decl.value as NumericLiteralValue).number.toInt())
}
VarDeclType.CONST -> {
// consts should have been const-folded away
}
}
}
return super.visit(decl)
}
// override fun accept(assignment: Assignment): IStatement {
// if(assignment is VariableInitializationAssignment) {
// println("INIT VAR $assignment")
// }
// return super.accept(assignment)
// }
}

47
compiler/src/prog8/vm/stackvm/Main.kt
View File

@ -1,47 +0,0 @@
package prog8.vm.stackvm
import prog8.printSoftwareHeader
import prog8.vm.astvm.ScreenDialog
import java.awt.EventQueue
import javax.swing.Timer
import kotlin.system.exitProcess
fun main(args: Array<String>) {
stackVmMain(args)
}
fun stackVmMain(args: Array<String>) {
printSoftwareHeader("StackVM")
if(args.size != 1) {
System.err.println("requires one argument: name of stackvm sourcecode file")
exitProcess(1)
}
val program = Program.load(args.first())
val vm = StackVm(traceOutputFile = null)
val dialog = ScreenDialog("StackVM")
vm.load(program, dialog.canvas)
EventQueue.invokeLater {
dialog.pack()
dialog.isVisible = true
dialog.start()
val programTimer = Timer(10) { a ->
try {
vm.step()
} catch(bp: VmBreakpointException) {
println("Breakpoint: execution halted. Press enter to resume.")
readLine()
} catch (tx: VmTerminationException) {
println("Execution halted: ${tx.message}")
(a.source as Timer).stop()
}
}
val irqTimer = Timer(1000/60) { a -> vm.irq(a.`when`) }
programTimer.start()
irqTimer.start()
}
}

299
compiler/src/prog8/vm/stackvm/Program.kt
View File

@ -1,299 +0,0 @@
package prog8.vm.stackvm
import prog8.ast.antlr.unescape
import prog8.ast.base.*
import prog8.ast.expressions.AddressOf
import prog8.ast.expressions.IdentifierReference
import prog8.vm.RuntimeValue
import prog8.compiler.HeapValues
import prog8.compiler.IntegerOrAddressOf
import prog8.compiler.intermediate.*
import java.io.File
import java.util.*
import java.util.regex.Pattern
class Program (val name: String,
val program: MutableList<Instruction>,
val variables: Map<String, RuntimeValue>,
val memoryPointers: Map<String, Pair<Int, DataType>>,
val labels: Map<String, Int>,
val memory: Map<Int, List<RuntimeValue>>,
val heap: HeapValues)
{
init {
// add end of program marker and some sentinel instructions, to correctly connect all others
program.add(LabelInstr("____program_end", false))
program.add(Instruction(Opcode.TERMINATE))
program.add(Instruction(Opcode.NOP))
}
companion object {
fun load(filename: String): Program {
val lines = File(filename).readLines().withIndex().iterator()
val memory = mutableMapOf<Int, List<RuntimeValue>>()
val heap = HeapValues()
val program = mutableListOf<Instruction>()
val variables = mutableMapOf<String, RuntimeValue>()
val memoryPointers = mutableMapOf<String, Pair<Int, DataType>>()
val labels = mutableMapOf<String, Int>()
while(lines.hasNext()) {
val (lineNr, line) = lines.next()
if(line.startsWith(';') || line.isEmpty())
continue
else if(line=="%memory")
loadMemory(lines, memory)
else if(line=="%heap")
loadHeap(lines, heap)
else if(line.startsWith("%block "))
loadBlock(lines, heap, program, variables, memoryPointers, labels)
else throw VmExecutionException("syntax error at line ${lineNr + 1}")
}
return Program(filename, program, variables, memoryPointers, labels, memory, heap)
}
private fun loadBlock(lines: Iterator<IndexedValue<String>>,
heap: HeapValues,
program: MutableList<Instruction>,
variables: MutableMap<String, RuntimeValue>,
memoryPointers: MutableMap<String, Pair<Int, DataType>>,
labels: MutableMap<String, Int>)
{
while(true) {
val (_, line) = lines.next()
if(line.isEmpty())
continue
else if(line=="%end_block")
return
else if(line=="%variables")
loadVars(lines, variables)
else if(line=="%memorypointers")
loadMemoryPointers(lines, memoryPointers, heap)
else if(line=="%instructions") {
val (blockInstructions, blockLabels) = loadInstructions(lines, heap)
val baseIndex = program.size
program.addAll(blockInstructions)
val labelsWithIndex = blockLabels.mapValues { baseIndex+blockInstructions.indexOf(it.value) }
labels.putAll(labelsWithIndex)
}
}
}
private fun loadHeap(lines: Iterator<IndexedValue<String>>, heap: HeapValues) {
val splitpattern = Pattern.compile("\\s+")
val heapvalues = mutableListOf<Triple<Int, DataType, String>>()
while(true) {
val (_, line) = lines.next()
if (line == "%end_heap")
break
val parts = line.split(splitpattern, limit=3)
val value = Triple(parts[0].toInt(), DataType.valueOf(parts[1].toUpperCase()), parts[2])
heapvalues.add(value)
}
heapvalues.sortedBy { it.first }.forEach {
when(it.second) {
DataType.STR, DataType.STR_S -> heap.addString(it.second, unescape(it.third.substring(1, it.third.length - 1), Position("<stackvmsource>", 0, 0, 0)))
DataType.ARRAY_UB, DataType.ARRAY_B,
DataType.ARRAY_UW, DataType.ARRAY_W -> {
val numbers = it.third.substring(1, it.third.length-1).split(',')
val intarray = numbers.map{number->
val num=number.trim()
if(num.startsWith("&")) {
// it's AddressOf
val scopedname = num.substring(1)
val iref = IdentifierReference(scopedname.split('.'), Position("<intermediate>", 0, 0, 0))
val addrOf = AddressOf(iref, Position("<intermediate>", 0, 0, 0))
addrOf.scopedname=scopedname
IntegerOrAddressOf(null, addrOf)
} else {
IntegerOrAddressOf(num.toInt(), null)
}
}.toTypedArray()
heap.addIntegerArray(it.second, intarray)
}
DataType.ARRAY_F -> {
val numbers = it.third.substring(1, it.third.length-1).split(',')
val doublearray = numbers.map{number->number.trim().toDouble()}.toDoubleArray()
heap.addDoublesArray(doublearray)
}
in NumericDatatypes -> throw VmExecutionException("invalid heap value type ${it.second}")
else -> throw VmExecutionException("weird datatype")
}
}
}
private fun loadInstructions(lines: Iterator<IndexedValue<String>>, heap: HeapValues): Pair<MutableList<Instruction>, Map<String, Instruction>> {
val instructions = mutableListOf<Instruction>()
val labels = mutableMapOf<String, Instruction>()
val splitpattern = Pattern.compile("\\s+")
val nextInstructionLabels = Stack<String>() // more than one label can occur on the isSameAs line
while(true) {
val (lineNr, line) = lines.next()
if(line.isEmpty())
continue
if(line=="%end_instructions")
return Pair(instructions, labels)
if(!line.startsWith(' ') && line.endsWith(':')) {
nextInstructionLabels.push(line.substring(0, line.length-1))
} else if(line.startsWith(' ')) {
val parts = line.trimStart().split(splitpattern, limit = 2)
val opcodeStr = parts[0].toUpperCase()
val opcode= Opcode.valueOf(if(opcodeStr.startsWith('_')) opcodeStr.substring(1) else opcodeStr)
val args = if(parts.size==2) parts[1] else null
val instruction = when(opcode) {
Opcode.LINE -> Instruction(opcode, null, callLabel = args)
Opcode.JUMP, Opcode.CALL, Opcode.BNEG, Opcode.BPOS,
Opcode.BZ, Opcode.BNZ, Opcode.BCS, Opcode.BCC,
Opcode.JZ, Opcode.JNZ, Opcode.JZW, Opcode.JNZW -> {
if(args!!.startsWith('$')) {
Instruction(opcode, RuntimeValue(DataType.UWORD, args.substring(1).toInt(16)))
} else {
Instruction(opcode, callLabel = args)
}
}
in opcodesWithVarArgument -> {
val withoutQuotes =
if(args!!.startsWith('"') && args.endsWith('"'))
args.substring(1, args.length-1) else args
Instruction(opcode, callLabel = withoutQuotes)
}
Opcode.SYSCALL -> {
if(args!! in syscallNames) {
val call = Syscall.valueOf(args)
Instruction(opcode, RuntimeValue(DataType.UBYTE, call.callNr))
} else {
val args2 = args.replace('.', '_')
if(args2 in syscallNames) {
val call = Syscall.valueOf(args2)
Instruction(opcode, RuntimeValue(DataType.UBYTE, call.callNr))
} else {
// the syscall is not yet implemented. emit a stub.
Instruction(Opcode.SYSCALL, RuntimeValue(DataType.UBYTE, Syscall.SYSCALLSTUB.callNr), callLabel = args2)
}
}
}
Opcode.INCLUDE_FILE -> {
val argparts = args!!.split(' ')
val filename = argparts[0]
val offset = if(argparts.size>=2 && argparts[1]!="null") getArgValue(argparts[1], heap) else null
val length = if(argparts.size>=3 && argparts[2]!="null") getArgValue(argparts[2], heap) else null
Instruction(opcode, offset, length, filename)
}
else -> {
Instruction(opcode, getArgValue(args, heap))
}
}
instructions.add(instruction)
while(nextInstructionLabels.isNotEmpty()) {
val label = nextInstructionLabels.pop()
labels[label] = instruction
}
} else throw VmExecutionException("syntax error at line ${lineNr + 1}")
}
}
private fun getArgValue(args: String?, heap: HeapValues): RuntimeValue? {
if(args==null)
return null
if(args[0]=='"' && args[args.length-1]=='"') {
throw VmExecutionException("encountered a string arg value, but all strings should already have been moved into the heap")
}
val (type, valueStr) = args.split(':')
return when(type) {
"b" -> RuntimeValue(DataType.BYTE, valueStr.toShort(16))
"ub" -> RuntimeValue(DataType.UBYTE, valueStr.toShort(16))
"w" -> RuntimeValue(DataType.WORD, valueStr.toInt(16))
"uw" -> RuntimeValue(DataType.UWORD, valueStr.toInt(16))
"f" -> RuntimeValue(DataType.FLOAT, valueStr.toDouble())
"heap" -> {
val heapId = valueStr.toInt()
RuntimeValue(heap.get(heapId).type, heapId = heapId)
}
else -> throw VmExecutionException("invalid datatype $type")
}
}
private fun loadVars(lines: Iterator<IndexedValue<String>>,
vars: MutableMap<String, RuntimeValue>) {
val splitpattern = Pattern.compile("\\s+")
while(true) {
val (_, line) = lines.next()
if(line=="%end_variables")
return
val (name, typeStr, valueStr) = line.split(splitpattern, limit = 3)
if(valueStr[0] !='"' && ':' !in valueStr)
throw VmExecutionException("missing value type character")
val value = when(val type = DataType.valueOf(typeStr.toUpperCase())) {
DataType.UBYTE -> RuntimeValue(DataType.UBYTE, valueStr.substring(3).toShort(16))
DataType.BYTE -> RuntimeValue(DataType.BYTE, valueStr.substring(2).toShort(16))
DataType.UWORD -> RuntimeValue(DataType.UWORD, valueStr.substring(3).toInt(16))
DataType.WORD -> RuntimeValue(DataType.WORD, valueStr.substring(2).toInt(16))
DataType.FLOAT -> RuntimeValue(DataType.FLOAT, valueStr.substring(2).toDouble())
in StringDatatypes -> {
if(valueStr.startsWith('"') && valueStr.endsWith('"'))
throw VmExecutionException("encountered a var with a string value, but all string values should already have been moved into the heap")
else if(!valueStr.startsWith("heap:"))
throw VmExecutionException("invalid string value, should be a heap reference")
else {
val heapId = valueStr.substring(5).toInt()
RuntimeValue(type, heapId = heapId)
}
}
in ArrayDatatypes -> {
if(!valueStr.startsWith("heap:"))
throw VmExecutionException("invalid array value, should be a heap reference")
else {
val heapId = valueStr.substring(5).toInt()
RuntimeValue(type, heapId = heapId)
}
}
else -> throw VmExecutionException("weird datatype")
}
vars[name] = value
}
}
private fun loadMemoryPointers(lines: Iterator<IndexedValue<String>>,
pointers: MutableMap<String, Pair<Int, DataType>>,
heap: HeapValues) {
val splitpattern = Pattern.compile("\\s+")
while(true) {
val (_, line) = lines.next()
if(line=="%end_memorypointers")
return
val (name, typeStr, valueStr) = line.split(splitpattern, limit = 3)
if(valueStr[0] !='"' && ':' !in valueStr)
throw VmExecutionException("missing value type character")
val type = DataType.valueOf(typeStr.toUpperCase())
val value = getArgValue(valueStr, heap)!!.integerValue()
pointers[name] = Pair(value, type)
}
}
private fun loadMemory(lines: Iterator<IndexedValue<String>>, memory: MutableMap<Int, List<RuntimeValue>>): Map<Int, List<RuntimeValue>> {
while(true) {
val (lineNr, line) = lines.next()
if(line=="%end_memory")
return memory
val address = line.substringBefore(' ').toInt(16)
val rest = line.substringAfter(' ').trim()
if(rest.startsWith('"')) {
TODO("memory init with char/string")
} else {
val valueStrings = rest.split(' ')
val values = mutableListOf<RuntimeValue>()
valueStrings.forEach {
when(it.length) {
2 -> values.add(RuntimeValue(DataType.UBYTE, it.toShort(16)))
4 -> values.add(RuntimeValue(DataType.UWORD, it.toInt(16)))
else -> throw VmExecutionException("invalid value at line $lineNr+1")
}
}
memory[address] = values
}
}
}
}
}

2438
compiler/src/prog8/vm/stackvm/StackVm.kt
View File

File diff suppressed because it is too large Load Diff

170
compiler/test/LiteralValueTests.kt
View File

@ -3,24 +3,30 @@ package prog8tests
import org.junit.jupiter.api.Test
import org.junit.jupiter.api.TestInstance
import prog8.ast.base.DataType
import prog8.ast.expressions.LiteralValue
import prog8.ast.base.Position
import kotlin.test.*
import prog8.ast.expressions.ArrayLiteralValue
import prog8.ast.expressions.InferredTypes
import prog8.ast.expressions.NumericLiteralValue
import prog8.ast.expressions.StringLiteralValue
import kotlin.test.assertEquals
import kotlin.test.assertFalse
import kotlin.test.assertNotEquals
import kotlin.test.assertTrue
private fun sameValueAndType(lv1: LiteralValue, lv2: LiteralValue): Boolean {
private fun sameValueAndType(lv1: NumericLiteralValue, lv2: NumericLiteralValue): Boolean {
return lv1.type==lv2.type && lv1==lv2
}
@TestInstance(TestInstance.Lifecycle.PER_CLASS)
class TestParserLiteralValue {
class TestParserNumericLiteralValue {
private val dummyPos = Position("test", 0, 0, 0)
@Test
fun testIdentity() {
val v = LiteralValue(DataType.UWORD, wordvalue = 12345, position = dummyPos)
val v = NumericLiteralValue(DataType.UWORD, 12345, dummyPos)
assertEquals(v, v)
assertFalse(v != v)
assertTrue(v <= v)
@ -28,104 +34,112 @@ class TestParserLiteralValue {
assertFalse(v < v)
assertFalse(v > v)
assertTrue(sameValueAndType(LiteralValue(DataType.UWORD, wordvalue = 12345, position = dummyPos), LiteralValue(DataType.UWORD, wordvalue = 12345, position = dummyPos)))
assertTrue(sameValueAndType(NumericLiteralValue(DataType.UWORD, 12345, dummyPos), NumericLiteralValue(DataType.UWORD, 12345, dummyPos)))
}
@Test
fun testEqualsAndNotEquals() {
assertEquals(LiteralValue(DataType.UBYTE, 100, position = dummyPos), LiteralValue(DataType.UBYTE, 100, position = dummyPos))
assertEquals(LiteralValue(DataType.UBYTE, 100, position = dummyPos), LiteralValue(DataType.UWORD, wordvalue = 100, position = dummyPos))
assertEquals(LiteralValue(DataType.UBYTE, 100, position = dummyPos), LiteralValue(DataType.FLOAT, floatvalue = 100.0, position = dummyPos))
assertEquals(LiteralValue(DataType.UWORD, wordvalue = 254, position = dummyPos), LiteralValue(DataType.UBYTE, 254, position = dummyPos))
assertEquals(LiteralValue(DataType.UWORD, wordvalue = 12345, position = dummyPos), LiteralValue(DataType.UWORD, wordvalue = 12345, position = dummyPos))
assertEquals(LiteralValue(DataType.UWORD, wordvalue = 12345, position = dummyPos), LiteralValue(DataType.FLOAT, floatvalue = 12345.0, position = dummyPos))
assertEquals(LiteralValue(DataType.FLOAT, floatvalue = 100.0, position = dummyPos), LiteralValue(DataType.UBYTE, 100, position = dummyPos))
assertEquals(LiteralValue(DataType.FLOAT, floatvalue = 22239.0, position = dummyPos), LiteralValue(DataType.UWORD, wordvalue = 22239, position = dummyPos))
assertEquals(LiteralValue(DataType.FLOAT, floatvalue = 9.99, position = dummyPos), LiteralValue(DataType.FLOAT, floatvalue = 9.99, position = dummyPos))
assertEquals(NumericLiteralValue(DataType.UBYTE, 100, dummyPos), NumericLiteralValue(DataType.UBYTE, 100, dummyPos))
assertEquals(NumericLiteralValue(DataType.UBYTE, 100, dummyPos), NumericLiteralValue(DataType.UWORD, 100, dummyPos))
assertEquals(NumericLiteralValue(DataType.UBYTE, 100, dummyPos), NumericLiteralValue(DataType.FLOAT, 100.0, dummyPos))
assertEquals(NumericLiteralValue(DataType.UWORD, 254, dummyPos), NumericLiteralValue(DataType.UBYTE, 254, dummyPos))
assertEquals(NumericLiteralValue(DataType.UWORD, 12345, dummyPos), NumericLiteralValue(DataType.UWORD, 12345, dummyPos))
assertEquals(NumericLiteralValue(DataType.UWORD, 12345, dummyPos), NumericLiteralValue(DataType.FLOAT, 12345.0, dummyPos))
assertEquals(NumericLiteralValue(DataType.FLOAT, 100.0, dummyPos), NumericLiteralValue(DataType.UBYTE, 100, dummyPos))
assertEquals(NumericLiteralValue(DataType.FLOAT, 22239.0, dummyPos), NumericLiteralValue(DataType.UWORD, 22239, dummyPos))
assertEquals(NumericLiteralValue(DataType.FLOAT, 9.99, dummyPos), NumericLiteralValue(DataType.FLOAT, 9.99, dummyPos))
assertTrue(sameValueAndType(LiteralValue(DataType.UBYTE, 100, position = dummyPos), LiteralValue(DataType.UBYTE, 100, position = dummyPos)))
assertFalse(sameValueAndType(LiteralValue(DataType.UBYTE, 100, position = dummyPos), LiteralValue(DataType.UWORD, wordvalue = 100, position = dummyPos)))
assertFalse(sameValueAndType(LiteralValue(DataType.UBYTE, 100, position = dummyPos), LiteralValue(DataType.FLOAT, floatvalue = 100.0, position = dummyPos)))
assertFalse(sameValueAndType(LiteralValue(DataType.UWORD, wordvalue = 254, position = dummyPos), LiteralValue(DataType.UBYTE, 254, position = dummyPos)))
assertTrue(sameValueAndType(LiteralValue(DataType.UWORD, wordvalue = 12345, position = dummyPos), LiteralValue(DataType.UWORD, wordvalue = 12345, position = dummyPos)))
assertFalse(sameValueAndType(LiteralValue(DataType.UWORD, wordvalue = 12345, position = dummyPos), LiteralValue(DataType.FLOAT, floatvalue = 12345.0, position = dummyPos)))
assertFalse(sameValueAndType(LiteralValue(DataType.FLOAT, floatvalue = 100.0, position = dummyPos), LiteralValue(DataType.UBYTE, 100, position = dummyPos)))
assertFalse(sameValueAndType(LiteralValue(DataType.FLOAT, floatvalue = 22239.0, position = dummyPos), LiteralValue(DataType.UWORD, wordvalue = 22239, position = dummyPos)))
assertTrue(sameValueAndType(LiteralValue(DataType.FLOAT, floatvalue = 9.99, position = dummyPos), LiteralValue(DataType.FLOAT, floatvalue = 9.99, position = dummyPos)))
assertTrue(sameValueAndType(NumericLiteralValue(DataType.UBYTE, 100, dummyPos), NumericLiteralValue(DataType.UBYTE, 100, dummyPos)))
assertFalse(sameValueAndType(NumericLiteralValue(DataType.UBYTE, 100, dummyPos), NumericLiteralValue(DataType.UWORD, 100, dummyPos)))
assertFalse(sameValueAndType(NumericLiteralValue(DataType.UBYTE, 100, dummyPos), NumericLiteralValue(DataType.FLOAT, 100.0, dummyPos)))
assertFalse(sameValueAndType(NumericLiteralValue(DataType.UWORD, 254, dummyPos), NumericLiteralValue(DataType.UBYTE, 254, dummyPos)))
assertTrue(sameValueAndType(NumericLiteralValue(DataType.UWORD, 12345, dummyPos), NumericLiteralValue(DataType.UWORD, 12345, dummyPos)))
assertFalse(sameValueAndType(NumericLiteralValue(DataType.UWORD, 12345, dummyPos), NumericLiteralValue(DataType.FLOAT, 12345.0, dummyPos)))
assertFalse(sameValueAndType(NumericLiteralValue(DataType.FLOAT, 100.0, dummyPos), NumericLiteralValue(DataType.UBYTE, 100, dummyPos)))
assertFalse(sameValueAndType(NumericLiteralValue(DataType.FLOAT, 22239.0, dummyPos), NumericLiteralValue(DataType.UWORD, 22239, dummyPos)))
assertTrue(sameValueAndType(NumericLiteralValue(DataType.FLOAT, 9.99, dummyPos), NumericLiteralValue(DataType.FLOAT, 9.99, dummyPos)))
assertNotEquals(LiteralValue(DataType.UBYTE, 100, position = dummyPos), LiteralValue(DataType.UBYTE, 101, position = dummyPos))
assertNotEquals(LiteralValue(DataType.UBYTE, 100, position = dummyPos), LiteralValue(DataType.UWORD, wordvalue = 101, position = dummyPos))
assertNotEquals(LiteralValue(DataType.UBYTE, 100, position = dummyPos), LiteralValue(DataType.FLOAT, floatvalue = 101.0, position = dummyPos))
assertNotEquals(LiteralValue(DataType.UWORD, wordvalue = 245, position = dummyPos), LiteralValue(DataType.UBYTE, 246, position = dummyPos))
assertNotEquals(LiteralValue(DataType.UWORD, wordvalue = 12345, position = dummyPos), LiteralValue(DataType.UWORD, wordvalue = 12346, position = dummyPos))
assertNotEquals(LiteralValue(DataType.UWORD, wordvalue = 12345, position = dummyPos), LiteralValue(DataType.FLOAT, floatvalue = 12346.0, position = dummyPos))
assertNotEquals(LiteralValue(DataType.FLOAT, floatvalue = 9.99, position = dummyPos), LiteralValue(DataType.UBYTE, 9, position = dummyPos))
assertNotEquals(LiteralValue(DataType.FLOAT, floatvalue = 9.99, position = dummyPos), LiteralValue(DataType.UWORD, wordvalue = 9, position = dummyPos))
assertNotEquals(LiteralValue(DataType.FLOAT, floatvalue = 9.99, position = dummyPos), LiteralValue(DataType.FLOAT, floatvalue = 9.0, position = dummyPos))
assertNotEquals(NumericLiteralValue(DataType.UBYTE, 100, dummyPos), NumericLiteralValue(DataType.UBYTE, 101, dummyPos))
assertNotEquals(NumericLiteralValue(DataType.UBYTE, 100, dummyPos), NumericLiteralValue(DataType.UWORD, 101, dummyPos))
assertNotEquals(NumericLiteralValue(DataType.UBYTE, 100, dummyPos), NumericLiteralValue(DataType.FLOAT, 101.0, dummyPos))
assertNotEquals(NumericLiteralValue(DataType.UWORD, 245, dummyPos), NumericLiteralValue(DataType.UBYTE, 246, dummyPos))
assertNotEquals(NumericLiteralValue(DataType.UWORD, 12345, dummyPos), NumericLiteralValue(DataType.UWORD, 12346, dummyPos))
assertNotEquals(NumericLiteralValue(DataType.UWORD, 12345, dummyPos), NumericLiteralValue(DataType.FLOAT, 12346.0, dummyPos))
assertNotEquals(NumericLiteralValue(DataType.FLOAT, 9.99, dummyPos), NumericLiteralValue(DataType.UBYTE, 9, dummyPos))
assertNotEquals(NumericLiteralValue(DataType.FLOAT, 9.99, dummyPos), NumericLiteralValue(DataType.UWORD, 9, dummyPos))
assertNotEquals(NumericLiteralValue(DataType.FLOAT, 9.99, dummyPos), NumericLiteralValue(DataType.FLOAT, 9.0, dummyPos))
assertFalse(sameValueAndType(LiteralValue(DataType.UBYTE, 100, position = dummyPos), LiteralValue(DataType.UBYTE, 101, position = dummyPos)))
assertFalse(sameValueAndType(LiteralValue(DataType.UBYTE, 100, position = dummyPos), LiteralValue(DataType.UWORD, wordvalue = 101, position = dummyPos)))
assertFalse(sameValueAndType(LiteralValue(DataType.UBYTE, 100, position = dummyPos), LiteralValue(DataType.FLOAT, floatvalue = 101.0, position = dummyPos)))
assertFalse(sameValueAndType(LiteralValue(DataType.UWORD, wordvalue = 245, position = dummyPos), LiteralValue(DataType.UBYTE, 246, position = dummyPos)))
assertFalse(sameValueAndType(LiteralValue(DataType.UWORD, wordvalue = 12345, position = dummyPos), LiteralValue(DataType.UWORD, wordvalue = 12346, position = dummyPos)))
assertFalse(sameValueAndType(LiteralValue(DataType.UWORD, wordvalue = 12345, position = dummyPos), LiteralValue(DataType.FLOAT, floatvalue = 12346.0, position = dummyPos)))
assertFalse(sameValueAndType(LiteralValue(DataType.FLOAT, floatvalue = 9.99, position = dummyPos), LiteralValue(DataType.UBYTE, 9, position = dummyPos)))
assertFalse(sameValueAndType(LiteralValue(DataType.FLOAT, floatvalue = 9.99, position = dummyPos), LiteralValue(DataType.UWORD, wordvalue = 9, position = dummyPos)))
assertFalse(sameValueAndType(LiteralValue(DataType.FLOAT, floatvalue = 9.99, position = dummyPos), LiteralValue(DataType.FLOAT, floatvalue = 9.0, position = dummyPos)))
assertFalse(sameValueAndType(NumericLiteralValue(DataType.UBYTE, 100, dummyPos), NumericLiteralValue(DataType.UBYTE, 101, dummyPos)))
assertFalse(sameValueAndType(NumericLiteralValue(DataType.UBYTE, 100, dummyPos), NumericLiteralValue(DataType.UWORD, 101, dummyPos)))
assertFalse(sameValueAndType(NumericLiteralValue(DataType.UBYTE, 100, dummyPos), NumericLiteralValue(DataType.FLOAT, 101.0, dummyPos)))
assertFalse(sameValueAndType(NumericLiteralValue(DataType.UWORD, 245, dummyPos), NumericLiteralValue(DataType.UBYTE, 246, dummyPos)))
assertFalse(sameValueAndType(NumericLiteralValue(DataType.UWORD, 12345, dummyPos), NumericLiteralValue(DataType.UWORD, 12346, dummyPos)))
assertFalse(sameValueAndType(NumericLiteralValue(DataType.UWORD, 12345, dummyPos), NumericLiteralValue(DataType.FLOAT, 12346.0, dummyPos)))
assertFalse(sameValueAndType(NumericLiteralValue(DataType.FLOAT, 9.99, dummyPos), NumericLiteralValue(DataType.UBYTE, 9, dummyPos)))
assertFalse(sameValueAndType(NumericLiteralValue(DataType.FLOAT, 9.99, dummyPos), NumericLiteralValue(DataType.UWORD, 9, dummyPos)))
assertFalse(sameValueAndType(NumericLiteralValue(DataType.FLOAT, 9.99, dummyPos), NumericLiteralValue(DataType.FLOAT, 9.0, dummyPos)))
assertTrue(sameValueAndType(LiteralValue(DataType.STR, strvalue = "hello", position = dummyPos), LiteralValue(DataType.STR, strvalue = "hello", position = dummyPos)))
assertFalse(sameValueAndType(LiteralValue(DataType.STR, strvalue = "hello", position = dummyPos), LiteralValue(DataType.STR, strvalue = "bye", position = dummyPos)))
val lvOne = LiteralValue(DataType.UBYTE, 1, position = dummyPos)
val lvTwo = LiteralValue(DataType.UBYTE, 2, position = dummyPos)
val lvThree = LiteralValue(DataType.UBYTE, 3, position = dummyPos)
val lvOneR = LiteralValue(DataType.UBYTE, 1, position = dummyPos)
val lvTwoR = LiteralValue(DataType.UBYTE, 2, position = dummyPos)
val lvThreeR = LiteralValue(DataType.UBYTE, 3, position = dummyPos)
val lvFour= LiteralValue(DataType.UBYTE, 4, position = dummyPos)
val lv1 = LiteralValue(DataType.ARRAY_UB, arrayvalue = arrayOf(lvOne, lvTwo, lvThree), position = dummyPos)
val lv2 = LiteralValue(DataType.ARRAY_UB, arrayvalue = arrayOf(lvOneR, lvTwoR, lvThreeR), position = dummyPos)
val lv3 = LiteralValue(DataType.ARRAY_UB, arrayvalue = arrayOf(lvOneR, lvTwoR, lvFour), position = dummyPos)
}
@Test
fun testEqualsRef() {
assertEquals(StringLiteralValue("hello", false, dummyPos), StringLiteralValue("hello", false, dummyPos))
assertNotEquals(StringLiteralValue("hello", false, dummyPos), StringLiteralValue("bye", false, dummyPos))
assertEquals(StringLiteralValue("hello", true, dummyPos), StringLiteralValue("hello", true, dummyPos))
assertNotEquals(StringLiteralValue("hello", true, dummyPos), StringLiteralValue("bye", true, dummyPos))
assertNotEquals(StringLiteralValue("hello", true, dummyPos), StringLiteralValue("hello", false, dummyPos))
val lvOne = NumericLiteralValue(DataType.UBYTE, 1, dummyPos)
val lvTwo = NumericLiteralValue(DataType.UBYTE, 2, dummyPos)
val lvThree = NumericLiteralValue(DataType.UBYTE, 3, dummyPos)
val lvOneR = NumericLiteralValue(DataType.UBYTE, 1, dummyPos)
val lvTwoR = NumericLiteralValue(DataType.UBYTE, 2, dummyPos)
val lvThreeR = NumericLiteralValue(DataType.UBYTE, 3, dummyPos)
val lvFour= NumericLiteralValue(DataType.UBYTE, 4, dummyPos)
val lv1 = ArrayLiteralValue(InferredTypes.InferredType.known(DataType.ARRAY_UB), arrayOf(lvOne, lvTwo, lvThree), dummyPos)
val lv2 = ArrayLiteralValue(InferredTypes.InferredType.known(DataType.ARRAY_UB), arrayOf(lvOneR, lvTwoR, lvThreeR), dummyPos)
val lv3 = ArrayLiteralValue(InferredTypes.InferredType.known(DataType.ARRAY_UB), arrayOf(lvOneR, lvTwoR, lvFour), dummyPos)
assertEquals(lv1, lv2)
assertNotEquals(lv1, lv3)
}
@Test
fun testGreaterThan(){
assertTrue(LiteralValue(DataType.UBYTE, 100, position = dummyPos) > LiteralValue(DataType.UBYTE, 99, position = dummyPos))
assertTrue(LiteralValue(DataType.UWORD, wordvalue = 254, position = dummyPos) > LiteralValue(DataType.UWORD, wordvalue = 253, position = dummyPos))
assertTrue(LiteralValue(DataType.FLOAT, floatvalue = 100.0, position = dummyPos) > LiteralValue(DataType.FLOAT, floatvalue = 99.9, position = dummyPos))
assertTrue(NumericLiteralValue(DataType.UBYTE, 100, dummyPos) > NumericLiteralValue(DataType.UBYTE, 99, dummyPos))
assertTrue(NumericLiteralValue(DataType.UWORD, 254, dummyPos) > NumericLiteralValue(DataType.UWORD, 253, dummyPos))
assertTrue(NumericLiteralValue(DataType.FLOAT, 100.0, dummyPos) > NumericLiteralValue(DataType.FLOAT, 99.9, dummyPos))
assertTrue(LiteralValue(DataType.UBYTE, 100, position = dummyPos) >= LiteralValue(DataType.UBYTE, 100, position = dummyPos))
assertTrue(LiteralValue(DataType.UWORD, wordvalue = 254, position = dummyPos) >= LiteralValue(DataType.UWORD, wordvalue = 254, position = dummyPos))
assertTrue(LiteralValue(DataType.FLOAT, floatvalue = 100.0, position = dummyPos) >= LiteralValue(DataType.FLOAT, floatvalue = 100.0, position = dummyPos))
assertTrue(NumericLiteralValue(DataType.UBYTE, 100, dummyPos) >= NumericLiteralValue(DataType.UBYTE, 100, dummyPos))
assertTrue(NumericLiteralValue(DataType.UWORD, 254, dummyPos) >= NumericLiteralValue(DataType.UWORD, 254, dummyPos))
assertTrue(NumericLiteralValue(DataType.FLOAT, 100.0, dummyPos) >= NumericLiteralValue(DataType.FLOAT, 100.0, dummyPos))
assertFalse(LiteralValue(DataType.UBYTE, 100, position = dummyPos) > LiteralValue(DataType.UBYTE, 100, position = dummyPos))
assertFalse(LiteralValue(DataType.UWORD, wordvalue = 254, position = dummyPos) > LiteralValue(DataType.UWORD, wordvalue = 254, position = dummyPos))
assertFalse(LiteralValue(DataType.FLOAT, floatvalue = 100.0, position = dummyPos) > LiteralValue(DataType.FLOAT, floatvalue = 100.0, position = dummyPos))
assertFalse(NumericLiteralValue(DataType.UBYTE, 100, dummyPos) > NumericLiteralValue(DataType.UBYTE, 100, dummyPos))
assertFalse(NumericLiteralValue(DataType.UWORD, 254, dummyPos) > NumericLiteralValue(DataType.UWORD, 254, dummyPos))
assertFalse(NumericLiteralValue(DataType.FLOAT, 100.0, dummyPos) > NumericLiteralValue(DataType.FLOAT, 100.0, dummyPos))
assertFalse(LiteralValue(DataType.UBYTE, 100, position = dummyPos) >= LiteralValue(DataType.UBYTE, 101, position = dummyPos))
assertFalse(LiteralValue(DataType.UWORD, wordvalue = 254, position = dummyPos) >= LiteralValue(DataType.UWORD, wordvalue = 255, position = dummyPos))
assertFalse(LiteralValue(DataType.FLOAT, floatvalue = 100.0, position = dummyPos) >= LiteralValue(DataType.FLOAT, floatvalue = 100.1, position = dummyPos))
assertFalse(NumericLiteralValue(DataType.UBYTE, 100, dummyPos) >= NumericLiteralValue(DataType.UBYTE, 101, dummyPos))
assertFalse(NumericLiteralValue(DataType.UWORD, 254, dummyPos) >= NumericLiteralValue(DataType.UWORD, 255, dummyPos))
assertFalse(NumericLiteralValue(DataType.FLOAT, 100.0, dummyPos) >= NumericLiteralValue(DataType.FLOAT, 100.1, dummyPos))
}
@Test
fun testLessThan() {
assertTrue(LiteralValue(DataType.UBYTE, 100, position = dummyPos) < LiteralValue(DataType.UBYTE, 101, position = dummyPos))
assertTrue(LiteralValue(DataType.UWORD, wordvalue = 254, position = dummyPos) < LiteralValue(DataType.UWORD, wordvalue = 255, position = dummyPos))
assertTrue(LiteralValue(DataType.FLOAT, floatvalue = 100.0, position = dummyPos) < LiteralValue(DataType.FLOAT, floatvalue = 100.1, position = dummyPos))
assertTrue(NumericLiteralValue(DataType.UBYTE, 100, dummyPos) < NumericLiteralValue(DataType.UBYTE, 101, dummyPos))
assertTrue(NumericLiteralValue(DataType.UWORD, 254, dummyPos) < NumericLiteralValue(DataType.UWORD, 255, dummyPos))
assertTrue(NumericLiteralValue(DataType.FLOAT, 100.0, dummyPos) < NumericLiteralValue(DataType.FLOAT, 100.1, dummyPos))
assertTrue(LiteralValue(DataType.UBYTE, 100, position = dummyPos) <= LiteralValue(DataType.UBYTE, 100, position = dummyPos))
assertTrue(LiteralValue(DataType.UWORD, wordvalue = 254, position = dummyPos) <= LiteralValue(DataType.UWORD, wordvalue = 254, position = dummyPos))
assertTrue(LiteralValue(DataType.FLOAT, floatvalue = 100.0, position = dummyPos) <= LiteralValue(DataType.FLOAT, floatvalue = 100.0, position = dummyPos))
assertTrue(NumericLiteralValue(DataType.UBYTE, 100, dummyPos) <= NumericLiteralValue(DataType.UBYTE, 100, dummyPos))
assertTrue(NumericLiteralValue(DataType.UWORD, 254, dummyPos) <= NumericLiteralValue(DataType.UWORD, 254, dummyPos))
assertTrue(NumericLiteralValue(DataType.FLOAT, 100.0, dummyPos) <= NumericLiteralValue(DataType.FLOAT, 100.0, dummyPos))
assertFalse(LiteralValue(DataType.UBYTE, 100, position = dummyPos) < LiteralValue(DataType.UBYTE, 100, position = dummyPos))
assertFalse(LiteralValue(DataType.UWORD, wordvalue = 254, position = dummyPos) < LiteralValue(DataType.UWORD, wordvalue = 254, position = dummyPos))
assertFalse(LiteralValue(DataType.FLOAT, floatvalue = 100.0, position = dummyPos) < LiteralValue(DataType.FLOAT, floatvalue = 100.0, position = dummyPos))
assertFalse(NumericLiteralValue(DataType.UBYTE, 100, dummyPos) < NumericLiteralValue(DataType.UBYTE, 100, dummyPos))
assertFalse(NumericLiteralValue(DataType.UWORD, 254, dummyPos) < NumericLiteralValue(DataType.UWORD, 254, dummyPos))
assertFalse(NumericLiteralValue(DataType.FLOAT, 100.0, dummyPos) < NumericLiteralValue(DataType.FLOAT, 100.0, dummyPos))
assertFalse(LiteralValue(DataType.UBYTE, 100, position = dummyPos) <= LiteralValue(DataType.UBYTE, 99, position = dummyPos))
assertFalse(LiteralValue(DataType.UWORD, wordvalue = 254, position = dummyPos) <= LiteralValue(DataType.UWORD, wordvalue = 253, position = dummyPos))
assertFalse(LiteralValue(DataType.FLOAT, floatvalue = 100.0, position = dummyPos) <= LiteralValue(DataType.FLOAT, floatvalue = 99.9, position = dummyPos))
assertFalse(NumericLiteralValue(DataType.UBYTE, 100, dummyPos) <= NumericLiteralValue(DataType.UBYTE, 99, dummyPos))
assertFalse(NumericLiteralValue(DataType.UWORD, 254, dummyPos) <= NumericLiteralValue(DataType.UWORD, 253, dummyPos))
assertFalse(NumericLiteralValue(DataType.FLOAT, 100.0, dummyPos) <= NumericLiteralValue(DataType.FLOAT, 99.9, dummyPos))
}
}

416
compiler/test/RuntimeValueTests.kt
View File

@ -3,84 +3,66 @@ package prog8tests
import org.junit.jupiter.api.Test
import org.junit.jupiter.api.TestInstance
import prog8.ast.base.DataType
import prog8.vm.RuntimeValue
import prog8.vm.RuntimeValueNumeric
import kotlin.test.*
private fun sameValueAndType(v1: RuntimeValue, v2: RuntimeValue): Boolean {
private fun sameValueAndType(v1: RuntimeValueNumeric, v2: RuntimeValueNumeric): Boolean {
return v1.type==v2.type && v1==v2
}
@TestInstance(TestInstance.Lifecycle.PER_CLASS)
class TestRuntimeValue {
class TestRuntimeValueNumeric {
@Test
fun testValueRanges() {
assertEquals(100, RuntimeValue(DataType.UBYTE, 100).integerValue())
assertEquals(100, RuntimeValue(DataType.BYTE, 100).integerValue())
assertEquals(10000, RuntimeValue(DataType.UWORD, 10000).integerValue())
assertEquals(10000, RuntimeValue(DataType.WORD, 10000).integerValue())
assertEquals(100.11, RuntimeValue(DataType.FLOAT, 100.11).numericValue())
assertEquals(0, RuntimeValueNumeric(DataType.UBYTE, 0).integerValue())
assertEquals(255, RuntimeValueNumeric(DataType.UBYTE, 255).integerValue())
assertFailsWith<IllegalArgumentException> { RuntimeValueNumeric(DataType.UBYTE, -1)}
assertFailsWith<IllegalArgumentException> { RuntimeValueNumeric(DataType.UBYTE, 256)}
assertEquals(200, RuntimeValue(DataType.UBYTE, 200).integerValue())
assertEquals(-56, RuntimeValue(DataType.BYTE, 200).integerValue())
assertEquals(50000, RuntimeValue(DataType.UWORD, 50000).integerValue())
assertEquals(-15536, RuntimeValue(DataType.WORD, 50000).integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.BYTE, 0).integerValue())
assertEquals(-128, RuntimeValueNumeric(DataType.BYTE, -128).integerValue())
assertEquals(127, RuntimeValueNumeric(DataType.BYTE, 127).integerValue())
assertFailsWith<IllegalArgumentException> { RuntimeValueNumeric(DataType.BYTE, -129)}
assertFailsWith<IllegalArgumentException> { RuntimeValueNumeric(DataType.BYTE, 128)}
assertEquals(44, RuntimeValue(DataType.UBYTE, 300).integerValue())
assertEquals(44, RuntimeValue(DataType.BYTE, 300).integerValue())
assertEquals(144, RuntimeValue(DataType.UBYTE, 400).integerValue())
assertEquals(-112, RuntimeValue(DataType.BYTE, 400).integerValue())
assertEquals(34463, RuntimeValue(DataType.UWORD, 99999).integerValue())
assertEquals(-31073, RuntimeValue(DataType.WORD, 99999).integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.UWORD, 0).integerValue())
assertEquals(65535, RuntimeValueNumeric(DataType.UWORD, 65535).integerValue())
assertFailsWith<IllegalArgumentException> { RuntimeValueNumeric(DataType.UWORD, -1)}
assertFailsWith<IllegalArgumentException> { RuntimeValueNumeric(DataType.UWORD, 65536)}
assertEquals(156, RuntimeValue(DataType.UBYTE, -100).integerValue())
assertEquals(-100, RuntimeValue(DataType.BYTE, -100).integerValue())
assertEquals(55536, RuntimeValue(DataType.UWORD, -10000).integerValue())
assertEquals(-10000, RuntimeValue(DataType.WORD, -10000).integerValue())
assertEquals(-100.11, RuntimeValue(DataType.FLOAT, -100.11).numericValue())
assertEquals(56, RuntimeValue(DataType.UBYTE, -200).integerValue())
assertEquals(56, RuntimeValue(DataType.BYTE, -200).integerValue())
assertEquals(45536, RuntimeValue(DataType.UWORD, -20000).integerValue())
assertEquals(-20000, RuntimeValue(DataType.WORD, -20000).integerValue())
assertEquals(212, RuntimeValue(DataType.UBYTE, -300).integerValue())
assertEquals(-44, RuntimeValue(DataType.BYTE, -300).integerValue())
assertEquals(42184, RuntimeValue(DataType.UWORD, -88888).integerValue())
assertEquals(-23352, RuntimeValue(DataType.WORD, -88888).integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.WORD, 0).integerValue())
assertEquals(-32768, RuntimeValueNumeric(DataType.WORD, -32768).integerValue())
assertEquals(32767, RuntimeValueNumeric(DataType.WORD, 32767).integerValue())
assertFailsWith<IllegalArgumentException> { RuntimeValueNumeric(DataType.WORD, -32769)}
assertFailsWith<IllegalArgumentException> { RuntimeValueNumeric(DataType.WORD, 32768)}
}
@Test
fun testTruthiness()
{
assertFalse(RuntimeValue(DataType.BYTE, 0).asBoolean)
assertFalse(RuntimeValue(DataType.UBYTE, 0).asBoolean)
assertFalse(RuntimeValue(DataType.WORD, 0).asBoolean)
assertFalse(RuntimeValue(DataType.UWORD, 0).asBoolean)
assertFalse(RuntimeValue(DataType.FLOAT, 0.0).asBoolean)
assertFalse(RuntimeValue(DataType.BYTE, 256).asBoolean)
assertFalse(RuntimeValue(DataType.UBYTE, 256).asBoolean)
assertFalse(RuntimeValue(DataType.WORD, 65536).asBoolean)
assertFalse(RuntimeValue(DataType.UWORD, 65536).asBoolean)
assertFalse(RuntimeValueNumeric(DataType.BYTE, 0).asBoolean)
assertFalse(RuntimeValueNumeric(DataType.UBYTE, 0).asBoolean)
assertFalse(RuntimeValueNumeric(DataType.WORD, 0).asBoolean)
assertFalse(RuntimeValueNumeric(DataType.UWORD, 0).asBoolean)
assertFalse(RuntimeValueNumeric(DataType.FLOAT, 0.0).asBoolean)
assertTrue(RuntimeValue(DataType.BYTE, 42).asBoolean)
assertTrue(RuntimeValue(DataType.UBYTE, 42).asBoolean)
assertTrue(RuntimeValue(DataType.WORD, 42).asBoolean)
assertTrue(RuntimeValue(DataType.UWORD, 42).asBoolean)
assertTrue(RuntimeValue(DataType.FLOAT, 42.0).asBoolean)
assertTrue(RuntimeValue(DataType.BYTE, -42).asBoolean)
assertTrue(RuntimeValue(DataType.UBYTE, -42).asBoolean)
assertTrue(RuntimeValue(DataType.WORD, -42).asBoolean)
assertTrue(RuntimeValue(DataType.UWORD, -42).asBoolean)
assertTrue(RuntimeValue(DataType.FLOAT, -42.0).asBoolean)
assertTrue(RuntimeValueNumeric(DataType.BYTE, 42).asBoolean)
assertTrue(RuntimeValueNumeric(DataType.UBYTE, 42).asBoolean)
assertTrue(RuntimeValueNumeric(DataType.WORD, 42).asBoolean)
assertTrue(RuntimeValueNumeric(DataType.UWORD, 42).asBoolean)
assertTrue(RuntimeValueNumeric(DataType.FLOAT, 42.0).asBoolean)
assertTrue(RuntimeValueNumeric(DataType.BYTE, -42).asBoolean)
assertTrue(RuntimeValueNumeric(DataType.WORD, -42).asBoolean)
assertTrue(RuntimeValueNumeric(DataType.FLOAT, -42.0).asBoolean)
}
@Test
fun testIdentity() {
val v = RuntimeValue(DataType.UWORD, 12345)
val v = RuntimeValueNumeric(DataType.UWORD, 12345)
assertEquals(v, v)
assertFalse(v != v)
assertTrue(v<=v)
@ -88,161 +70,283 @@ class TestRuntimeValue {
assertFalse(v<v)
assertFalse(v>v)
assertTrue(sameValueAndType(RuntimeValue(DataType.UBYTE, 100), RuntimeValue(DataType.UBYTE, 100)))
assertTrue(sameValueAndType(RuntimeValueNumeric(DataType.UBYTE, 100), RuntimeValueNumeric(DataType.UBYTE, 100)))
}
@Test
fun testEqualsAndNotEquals() {
assertEquals(RuntimeValue(DataType.UBYTE, 100), RuntimeValue(DataType.UBYTE, 100))
assertEquals(RuntimeValue(DataType.UBYTE, 100), RuntimeValue(DataType.UWORD, 100))
assertEquals(RuntimeValue(DataType.UBYTE, 100), RuntimeValue(DataType.FLOAT, 100))
assertEquals(RuntimeValue(DataType.UWORD, 254), RuntimeValue(DataType.UBYTE, 254))
assertEquals(RuntimeValue(DataType.UWORD, 12345), RuntimeValue(DataType.UWORD, 12345))
assertEquals(RuntimeValue(DataType.UWORD, 12345), RuntimeValue(DataType.FLOAT, 12345))
assertEquals(RuntimeValue(DataType.FLOAT, 100.0), RuntimeValue(DataType.UBYTE, 100))
assertEquals(RuntimeValue(DataType.FLOAT, 22239.0), RuntimeValue(DataType.UWORD, 22239))
assertEquals(RuntimeValue(DataType.FLOAT, 9.99), RuntimeValue(DataType.FLOAT, 9.99))
assertEquals(RuntimeValueNumeric(DataType.UBYTE, 100), RuntimeValueNumeric(DataType.UBYTE, 100))
assertEquals(RuntimeValueNumeric(DataType.UBYTE, 100), RuntimeValueNumeric(DataType.UWORD, 100))
assertEquals(RuntimeValueNumeric(DataType.UBYTE, 100), RuntimeValueNumeric(DataType.FLOAT, 100))
assertEquals(RuntimeValueNumeric(DataType.UWORD, 254), RuntimeValueNumeric(DataType.UBYTE, 254))
assertEquals(RuntimeValueNumeric(DataType.UWORD, 12345), RuntimeValueNumeric(DataType.UWORD, 12345))
assertEquals(RuntimeValueNumeric(DataType.UWORD, 12345), RuntimeValueNumeric(DataType.FLOAT, 12345))
assertEquals(RuntimeValueNumeric(DataType.FLOAT, 100.0), RuntimeValueNumeric(DataType.UBYTE, 100))
assertEquals(RuntimeValueNumeric(DataType.FLOAT, 22239.0), RuntimeValueNumeric(DataType.UWORD, 22239))
assertEquals(RuntimeValueNumeric(DataType.FLOAT, 9.99), RuntimeValueNumeric(DataType.FLOAT, 9.99))
assertTrue(sameValueAndType(RuntimeValue(DataType.UBYTE, 100), RuntimeValue(DataType.UBYTE, 100)))
assertFalse(sameValueAndType(RuntimeValue(DataType.UBYTE, 100), RuntimeValue(DataType.UWORD, 100)))
assertFalse(sameValueAndType(RuntimeValue(DataType.UBYTE, 100), RuntimeValue(DataType.FLOAT, 100)))
assertFalse(sameValueAndType(RuntimeValue(DataType.UWORD, 254), RuntimeValue(DataType.UBYTE, 254)))
assertTrue(sameValueAndType(RuntimeValue(DataType.UWORD, 12345), RuntimeValue(DataType.UWORD, 12345)))
assertFalse(sameValueAndType(RuntimeValue(DataType.UWORD, 12345), RuntimeValue(DataType.FLOAT, 12345)))
assertFalse(sameValueAndType(RuntimeValue(DataType.FLOAT, 100.0), RuntimeValue(DataType.UBYTE, 100)))
assertFalse(sameValueAndType(RuntimeValue(DataType.FLOAT, 22239.0), RuntimeValue(DataType.UWORD, 22239)))
assertTrue(sameValueAndType(RuntimeValue(DataType.FLOAT, 9.99), RuntimeValue(DataType.FLOAT, 9.99)))
assertTrue(sameValueAndType(RuntimeValueNumeric(DataType.UBYTE, 100), RuntimeValueNumeric(DataType.UBYTE, 100)))
assertFalse(sameValueAndType(RuntimeValueNumeric(DataType.UBYTE, 100), RuntimeValueNumeric(DataType.UWORD, 100)))
assertFalse(sameValueAndType(RuntimeValueNumeric(DataType.UBYTE, 100), RuntimeValueNumeric(DataType.FLOAT, 100)))
assertFalse(sameValueAndType(RuntimeValueNumeric(DataType.UWORD, 254), RuntimeValueNumeric(DataType.UBYTE, 254)))
assertTrue(sameValueAndType(RuntimeValueNumeric(DataType.UWORD, 12345), RuntimeValueNumeric(DataType.UWORD, 12345)))
assertFalse(sameValueAndType(RuntimeValueNumeric(DataType.UWORD, 12345), RuntimeValueNumeric(DataType.FLOAT, 12345)))
assertFalse(sameValueAndType(RuntimeValueNumeric(DataType.FLOAT, 100.0), RuntimeValueNumeric(DataType.UBYTE, 100)))
assertFalse(sameValueAndType(RuntimeValueNumeric(DataType.FLOAT, 22239.0), RuntimeValueNumeric(DataType.UWORD, 22239)))
assertTrue(sameValueAndType(RuntimeValueNumeric(DataType.FLOAT, 9.99), RuntimeValueNumeric(DataType.FLOAT, 9.99)))
assertNotEquals(RuntimeValue(DataType.UBYTE, 100), RuntimeValue(DataType.UBYTE, 101))
assertNotEquals(RuntimeValue(DataType.UBYTE, 100), RuntimeValue(DataType.UWORD, 101))
assertNotEquals(RuntimeValue(DataType.UBYTE, 100), RuntimeValue(DataType.FLOAT, 101))
assertNotEquals(RuntimeValue(DataType.UWORD, 245), RuntimeValue(DataType.UBYTE, 246))
assertNotEquals(RuntimeValue(DataType.UWORD, 12345), RuntimeValue(DataType.UWORD, 12346))
assertNotEquals(RuntimeValue(DataType.UWORD, 12345), RuntimeValue(DataType.FLOAT, 12346))
assertNotEquals(RuntimeValue(DataType.FLOAT, 9.99), RuntimeValue(DataType.UBYTE, 9))
assertNotEquals(RuntimeValue(DataType.FLOAT, 9.99), RuntimeValue(DataType.UWORD, 9))
assertNotEquals(RuntimeValue(DataType.FLOAT, 9.99), RuntimeValue(DataType.FLOAT, 9.0))
assertNotEquals(RuntimeValueNumeric(DataType.UBYTE, 100), RuntimeValueNumeric(DataType.UBYTE, 101))
assertNotEquals(RuntimeValueNumeric(DataType.UBYTE, 100), RuntimeValueNumeric(DataType.UWORD, 101))
assertNotEquals(RuntimeValueNumeric(DataType.UBYTE, 100), RuntimeValueNumeric(DataType.FLOAT, 101))
assertNotEquals(RuntimeValueNumeric(DataType.UWORD, 245), RuntimeValueNumeric(DataType.UBYTE, 246))
assertNotEquals(RuntimeValueNumeric(DataType.UWORD, 12345), RuntimeValueNumeric(DataType.UWORD, 12346))
assertNotEquals(RuntimeValueNumeric(DataType.UWORD, 12345), RuntimeValueNumeric(DataType.FLOAT, 12346))
assertNotEquals(RuntimeValueNumeric(DataType.FLOAT, 9.99), RuntimeValueNumeric(DataType.UBYTE, 9))
assertNotEquals(RuntimeValueNumeric(DataType.FLOAT, 9.99), RuntimeValueNumeric(DataType.UWORD, 9))
assertNotEquals(RuntimeValueNumeric(DataType.FLOAT, 9.99), RuntimeValueNumeric(DataType.FLOAT, 9.0))
assertFalse(sameValueAndType(RuntimeValue(DataType.UBYTE, 100), RuntimeValue(DataType.UBYTE, 101)))
assertFalse(sameValueAndType(RuntimeValue(DataType.UBYTE, 100), RuntimeValue(DataType.UWORD, 101)))
assertFalse(sameValueAndType(RuntimeValue(DataType.UBYTE, 100), RuntimeValue(DataType.FLOAT, 101)))
assertFalse(sameValueAndType(RuntimeValue(DataType.UWORD, 245), RuntimeValue(DataType.UBYTE, 246)))
assertFalse(sameValueAndType(RuntimeValue(DataType.UWORD, 12345), RuntimeValue(DataType.UWORD, 12346)))
assertFalse(sameValueAndType(RuntimeValue(DataType.UWORD, 12345), RuntimeValue(DataType.FLOAT, 12346)))
assertFalse(sameValueAndType(RuntimeValue(DataType.FLOAT, 9.99), RuntimeValue(DataType.UBYTE, 9)))
assertFalse(sameValueAndType(RuntimeValue(DataType.FLOAT, 9.99), RuntimeValue(DataType.UWORD, 9)))
assertFalse(sameValueAndType(RuntimeValue(DataType.FLOAT, 9.99), RuntimeValue(DataType.FLOAT, 9.0)))
}
@Test
fun testRequireHeap()
{
assertFailsWith<IllegalArgumentException> { RuntimeValue(DataType.STR, num = 999) }
assertFailsWith<IllegalArgumentException> { RuntimeValue(DataType.STR_S, num = 999) }
assertFailsWith<IllegalArgumentException> { RuntimeValue(DataType.ARRAY_F, num = 999) }
assertFailsWith<IllegalArgumentException> { RuntimeValue(DataType.ARRAY_W, num = 999) }
assertFailsWith<IllegalArgumentException> { RuntimeValue(DataType.ARRAY_UW, num = 999) }
assertFailsWith<IllegalArgumentException> { RuntimeValue(DataType.ARRAY_B, num = 999) }
assertFailsWith<IllegalArgumentException> { RuntimeValue(DataType.ARRAY_UB, num = 999) }
}
@Test
fun testEqualityHeapTypes()
{
assertTrue(sameValueAndType(RuntimeValue(DataType.STR, heapId = 999), RuntimeValue(DataType.STR, heapId = 999)))
assertFalse(sameValueAndType(RuntimeValue(DataType.STR, heapId = 999), RuntimeValue(DataType.STR, heapId = 222)))
assertTrue(sameValueAndType(RuntimeValue(DataType.ARRAY_UB, heapId = 99), RuntimeValue(DataType.ARRAY_UB, heapId = 99)))
assertFalse(sameValueAndType(RuntimeValue(DataType.ARRAY_UB, heapId = 99), RuntimeValue(DataType.ARRAY_UB, heapId = 22)))
assertTrue(sameValueAndType(RuntimeValue(DataType.ARRAY_UW, heapId = 999), RuntimeValue(DataType.ARRAY_UW, heapId = 999)))
assertFalse(sameValueAndType(RuntimeValue(DataType.ARRAY_UW, heapId = 999), RuntimeValue(DataType.ARRAY_UW, heapId = 222)))
assertTrue(sameValueAndType(RuntimeValue(DataType.ARRAY_F, heapId = 999), RuntimeValue(DataType.ARRAY_F, heapId = 999)))
assertFalse(sameValueAndType(RuntimeValue(DataType.ARRAY_F, heapId = 999), RuntimeValue(DataType.ARRAY_UW, heapId = 999)))
assertFalse(sameValueAndType(RuntimeValue(DataType.ARRAY_F, heapId = 999), RuntimeValue(DataType.ARRAY_F, heapId = 222)))
assertFalse(sameValueAndType(RuntimeValueNumeric(DataType.UBYTE, 100), RuntimeValueNumeric(DataType.UBYTE, 101)))
assertFalse(sameValueAndType(RuntimeValueNumeric(DataType.UBYTE, 100), RuntimeValueNumeric(DataType.UWORD, 101)))
assertFalse(sameValueAndType(RuntimeValueNumeric(DataType.UBYTE, 100), RuntimeValueNumeric(DataType.FLOAT, 101)))
assertFalse(sameValueAndType(RuntimeValueNumeric(DataType.UWORD, 245), RuntimeValueNumeric(DataType.UBYTE, 246)))
assertFalse(sameValueAndType(RuntimeValueNumeric(DataType.UWORD, 12345), RuntimeValueNumeric(DataType.UWORD, 12346)))
assertFalse(sameValueAndType(RuntimeValueNumeric(DataType.UWORD, 12345), RuntimeValueNumeric(DataType.FLOAT, 12346)))
assertFalse(sameValueAndType(RuntimeValueNumeric(DataType.FLOAT, 9.99), RuntimeValueNumeric(DataType.UBYTE, 9)))
assertFalse(sameValueAndType(RuntimeValueNumeric(DataType.FLOAT, 9.99), RuntimeValueNumeric(DataType.UWORD, 9)))
assertFalse(sameValueAndType(RuntimeValueNumeric(DataType.FLOAT, 9.99), RuntimeValueNumeric(DataType.FLOAT, 9.0)))
}
@Test
fun testGreaterThan(){
assertTrue(RuntimeValue(DataType.UBYTE, 100) > RuntimeValue(DataType.UBYTE, 99))
assertTrue(RuntimeValue(DataType.UWORD, 254) > RuntimeValue(DataType.UWORD, 253))
assertTrue(RuntimeValue(DataType.FLOAT, 100.0) > RuntimeValue(DataType.FLOAT, 99.9))
assertTrue(RuntimeValueNumeric(DataType.UBYTE, 100) > RuntimeValueNumeric(DataType.UBYTE, 99))
assertTrue(RuntimeValueNumeric(DataType.UWORD, 254) > RuntimeValueNumeric(DataType.UWORD, 253))
assertTrue(RuntimeValueNumeric(DataType.FLOAT, 100.0) > RuntimeValueNumeric(DataType.FLOAT, 99.9))
assertTrue(RuntimeValue(DataType.UBYTE, 100) >= RuntimeValue(DataType.UBYTE, 100))
assertTrue(RuntimeValue(DataType.UWORD, 254) >= RuntimeValue(DataType.UWORD, 254))
assertTrue(RuntimeValue(DataType.FLOAT, 100.0) >= RuntimeValue(DataType.FLOAT, 100.0))
assertTrue(RuntimeValueNumeric(DataType.UBYTE, 100) >= RuntimeValueNumeric(DataType.UBYTE, 100))
assertTrue(RuntimeValueNumeric(DataType.UWORD, 254) >= RuntimeValueNumeric(DataType.UWORD, 254))
assertTrue(RuntimeValueNumeric(DataType.FLOAT, 100.0) >= RuntimeValueNumeric(DataType.FLOAT, 100.0))
assertFalse(RuntimeValue(DataType.UBYTE, 100) > RuntimeValue(DataType.UBYTE, 100))
assertFalse(RuntimeValue(DataType.UWORD, 254) > RuntimeValue(DataType.UWORD, 254))
assertFalse(RuntimeValue(DataType.FLOAT, 100.0) > RuntimeValue(DataType.FLOAT, 100.0))
assertFalse(RuntimeValueNumeric(DataType.UBYTE, 100) > RuntimeValueNumeric(DataType.UBYTE, 100))
assertFalse(RuntimeValueNumeric(DataType.UWORD, 254) > RuntimeValueNumeric(DataType.UWORD, 254))
assertFalse(RuntimeValueNumeric(DataType.FLOAT, 100.0) > RuntimeValueNumeric(DataType.FLOAT, 100.0))
assertFalse(RuntimeValue(DataType.UBYTE, 100) >= RuntimeValue(DataType.UBYTE, 101))
assertFalse(RuntimeValue(DataType.UWORD, 254) >= RuntimeValue(DataType.UWORD, 255))
assertFalse(RuntimeValue(DataType.FLOAT, 100.0) >= RuntimeValue(DataType.FLOAT, 100.1))
assertFalse(RuntimeValueNumeric(DataType.UBYTE, 100) >= RuntimeValueNumeric(DataType.UBYTE, 101))
assertFalse(RuntimeValueNumeric(DataType.UWORD, 254) >= RuntimeValueNumeric(DataType.UWORD, 255))
assertFalse(RuntimeValueNumeric(DataType.FLOAT, 100.0) >= RuntimeValueNumeric(DataType.FLOAT, 100.1))
}
@Test
fun testLessThan() {
assertTrue(RuntimeValue(DataType.UBYTE, 100) < RuntimeValue(DataType.UBYTE, 101))
assertTrue(RuntimeValue(DataType.UWORD, 254) < RuntimeValue(DataType.UWORD, 255))
assertTrue(RuntimeValue(DataType.FLOAT, 100.0) < RuntimeValue(DataType.FLOAT, 100.1))
assertTrue(RuntimeValueNumeric(DataType.UBYTE, 100) < RuntimeValueNumeric(DataType.UBYTE, 101))
assertTrue(RuntimeValueNumeric(DataType.UWORD, 254) < RuntimeValueNumeric(DataType.UWORD, 255))
assertTrue(RuntimeValueNumeric(DataType.FLOAT, 100.0) < RuntimeValueNumeric(DataType.FLOAT, 100.1))
assertTrue(RuntimeValue(DataType.UBYTE, 100) <= RuntimeValue(DataType.UBYTE, 100))
assertTrue(RuntimeValue(DataType.UWORD, 254) <= RuntimeValue(DataType.UWORD, 254))
assertTrue(RuntimeValue(DataType.FLOAT, 100.0) <= RuntimeValue(DataType.FLOAT, 100.0))
assertTrue(RuntimeValueNumeric(DataType.UBYTE, 100) <= RuntimeValueNumeric(DataType.UBYTE, 100))
assertTrue(RuntimeValueNumeric(DataType.UWORD, 254) <= RuntimeValueNumeric(DataType.UWORD, 254))
assertTrue(RuntimeValueNumeric(DataType.FLOAT, 100.0) <= RuntimeValueNumeric(DataType.FLOAT, 100.0))
assertFalse(RuntimeValue(DataType.UBYTE, 100) < RuntimeValue(DataType.UBYTE, 100))
assertFalse(RuntimeValue(DataType.UWORD, 254) < RuntimeValue(DataType.UWORD, 254))
assertFalse(RuntimeValue(DataType.FLOAT, 100.0) < RuntimeValue(DataType.FLOAT, 100.0))
assertFalse(RuntimeValueNumeric(DataType.UBYTE, 100) < RuntimeValueNumeric(DataType.UBYTE, 100))
assertFalse(RuntimeValueNumeric(DataType.UWORD, 254) < RuntimeValueNumeric(DataType.UWORD, 254))
assertFalse(RuntimeValueNumeric(DataType.FLOAT, 100.0) < RuntimeValueNumeric(DataType.FLOAT, 100.0))
assertFalse(RuntimeValue(DataType.UBYTE, 100) <= RuntimeValue(DataType.UBYTE, 99))
assertFalse(RuntimeValue(DataType.UWORD, 254) <= RuntimeValue(DataType.UWORD, 253))
assertFalse(RuntimeValue(DataType.FLOAT, 100.0) <= RuntimeValue(DataType.FLOAT, 99.9))
assertFalse(RuntimeValueNumeric(DataType.UBYTE, 100) <= RuntimeValueNumeric(DataType.UBYTE, 99))
assertFalse(RuntimeValueNumeric(DataType.UWORD, 254) <= RuntimeValueNumeric(DataType.UWORD, 253))
assertFalse(RuntimeValueNumeric(DataType.FLOAT, 100.0) <= RuntimeValueNumeric(DataType.FLOAT, 99.9))
}
@Test
fun testNoDtConversion() {
assertFailsWith<ArithmeticException> {
RuntimeValue(DataType.UWORD, 100).add(RuntimeValue(DataType.UBYTE, 120))
RuntimeValueNumeric(DataType.UWORD, 100).add(RuntimeValueNumeric(DataType.UBYTE, 120))
}
assertFailsWith<ArithmeticException> {
RuntimeValue(DataType.UBYTE, 100).add(RuntimeValue(DataType.UWORD, 120))
RuntimeValueNumeric(DataType.UBYTE, 100).add(RuntimeValueNumeric(DataType.UWORD, 120))
}
assertFailsWith<ArithmeticException> {
RuntimeValue(DataType.FLOAT, 100.22).add(RuntimeValue(DataType.UWORD, 120))
RuntimeValueNumeric(DataType.FLOAT, 100.22).add(RuntimeValueNumeric(DataType.UWORD, 120))
}
assertFailsWith<ArithmeticException> {
RuntimeValue(DataType.UWORD, 1002).add(RuntimeValue(DataType.FLOAT, 120.22))
RuntimeValueNumeric(DataType.UWORD, 1002).add(RuntimeValueNumeric(DataType.FLOAT, 120.22))
}
assertFailsWith<ArithmeticException> {
RuntimeValue(DataType.FLOAT, 100.22).add(RuntimeValue(DataType.UBYTE, 120))
RuntimeValueNumeric(DataType.FLOAT, 100.22).add(RuntimeValueNumeric(DataType.UBYTE, 120))
}
assertFailsWith<ArithmeticException> {
RuntimeValue(DataType.UBYTE, 12).add(RuntimeValue(DataType.FLOAT, 120.22))
RuntimeValueNumeric(DataType.UBYTE, 12).add(RuntimeValueNumeric(DataType.FLOAT, 120.22))
}
}
@Test
fun testNoAutoFloatConversion() {
assertFailsWith<ArithmeticException> {
RuntimeValue(DataType.UBYTE, 233).add(RuntimeValue(DataType.FLOAT, 1.234))
RuntimeValueNumeric(DataType.UBYTE, 233).add(RuntimeValueNumeric(DataType.FLOAT, 1.234))
}
assertFailsWith<ArithmeticException> {
RuntimeValue(DataType.UWORD, 233).add(RuntimeValue(DataType.FLOAT, 1.234))
RuntimeValueNumeric(DataType.UWORD, 233).add(RuntimeValueNumeric(DataType.FLOAT, 1.234))
}
assertFailsWith<ArithmeticException> {
RuntimeValue(DataType.UBYTE, 233).mul(RuntimeValue(DataType.FLOAT, 1.234))
RuntimeValueNumeric(DataType.UBYTE, 233).mul(RuntimeValueNumeric(DataType.FLOAT, 1.234))
}
assertFailsWith<ArithmeticException> {
RuntimeValue(DataType.UWORD, 233).mul(RuntimeValue(DataType.FLOAT, 1.234))
RuntimeValueNumeric(DataType.UWORD, 233).mul(RuntimeValueNumeric(DataType.FLOAT, 1.234))
}
assertFailsWith<ArithmeticException> {
RuntimeValue(DataType.UBYTE, 233).div(RuntimeValue(DataType.FLOAT, 1.234))
RuntimeValueNumeric(DataType.UBYTE, 233).div(RuntimeValueNumeric(DataType.FLOAT, 1.234))
}
assertFailsWith<ArithmeticException> {
RuntimeValue(DataType.UWORD, 233).div(RuntimeValue(DataType.FLOAT, 1.234))
RuntimeValueNumeric(DataType.UWORD, 233).div(RuntimeValueNumeric(DataType.FLOAT, 1.234))
}
val result = RuntimeValue(DataType.FLOAT, 233.333).add(RuntimeValue(DataType.FLOAT, 1.234))
val result = RuntimeValueNumeric(DataType.FLOAT, 233.333).add(RuntimeValueNumeric(DataType.FLOAT, 1.234))
}
@Test
fun arithmetictestUbyte() {
assertEquals(255, RuntimeValueNumeric(DataType.UBYTE, 200).add(RuntimeValueNumeric(DataType.UBYTE, 55)).integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.UBYTE, 200).add(RuntimeValueNumeric(DataType.UBYTE, 56)).integerValue())
assertEquals(1, RuntimeValueNumeric(DataType.UBYTE, 200).add(RuntimeValueNumeric(DataType.UBYTE, 57)).integerValue())
assertEquals(1, RuntimeValueNumeric(DataType.UBYTE, 2).sub(RuntimeValueNumeric(DataType.UBYTE, 1)).integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.UBYTE, 2).sub(RuntimeValueNumeric(DataType.UBYTE, 2)).integerValue())
assertEquals(255, RuntimeValueNumeric(DataType.UBYTE, 2).sub(RuntimeValueNumeric(DataType.UBYTE, 3)).integerValue())
assertEquals(255, RuntimeValueNumeric(DataType.UBYTE, 254).inc().integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.UBYTE, 255).inc().integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.UBYTE, 1).dec().integerValue())
assertEquals(255, RuntimeValueNumeric(DataType.UBYTE, 0).dec().integerValue())
assertEquals(255, RuntimeValueNumeric(DataType.UBYTE, 0).inv().integerValue())
assertEquals(0b00110011, RuntimeValueNumeric(DataType.UBYTE, 0b11001100).inv().integerValue())
// assertEquals(0, RuntimeValueNumeric(DataType.UBYTE, 0).neg().integerValue())
// assertEquals(0, RuntimeValueNumeric(DataType.UBYTE, 0).neg().integerValue())
assertEquals(1, RuntimeValueNumeric(DataType.UBYTE, 0).not().integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.UBYTE, 1).not().integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.UBYTE, 111).not().integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.UBYTE, 255).not().integerValue())
assertEquals(200, RuntimeValueNumeric(DataType.UBYTE, 20).mul(RuntimeValueNumeric(DataType.UBYTE, 10)).integerValue())
assertEquals(144, RuntimeValueNumeric(DataType.UBYTE, 20).mul(RuntimeValueNumeric(DataType.UBYTE, 20)).integerValue())
assertEquals(25, RuntimeValueNumeric(DataType.UBYTE, 5).pow(RuntimeValueNumeric(DataType.UBYTE, 2)).integerValue())
assertEquals(125, RuntimeValueNumeric(DataType.UBYTE, 5).pow(RuntimeValueNumeric(DataType.UBYTE, 3)).integerValue())
assertEquals(113, RuntimeValueNumeric(DataType.UBYTE, 5).pow(RuntimeValueNumeric(DataType.UBYTE, 4)).integerValue())
assertEquals(100, RuntimeValueNumeric(DataType.UBYTE, 50).shl().integerValue())
assertEquals(200, RuntimeValueNumeric(DataType.UBYTE, 100).shl().integerValue())
assertEquals(144, RuntimeValueNumeric(DataType.UBYTE, 200).shl().integerValue())
}
@Test
fun arithmetictestUWord() {
assertEquals(65535, RuntimeValueNumeric(DataType.UWORD, 60000).add(RuntimeValueNumeric(DataType.UWORD, 5535)).integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.UWORD, 60000).add(RuntimeValueNumeric(DataType.UWORD, 5536)).integerValue())
assertEquals(1, RuntimeValueNumeric(DataType.UWORD, 60000).add(RuntimeValueNumeric(DataType.UWORD, 5537)).integerValue())
assertEquals(1, RuntimeValueNumeric(DataType.UWORD, 2).sub(RuntimeValueNumeric(DataType.UWORD, 1)).integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.UWORD, 2).sub(RuntimeValueNumeric(DataType.UWORD, 2)).integerValue())
assertEquals(65535, RuntimeValueNumeric(DataType.UWORD, 2).sub(RuntimeValueNumeric(DataType.UWORD, 3)).integerValue())
assertEquals(65535, RuntimeValueNumeric(DataType.UWORD, 65534).inc().integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.UWORD, 65535).inc().integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.UWORD, 1).dec().integerValue())
assertEquals(65535, RuntimeValueNumeric(DataType.UWORD, 0).dec().integerValue())
assertEquals(65535, RuntimeValueNumeric(DataType.UWORD, 0).inv().integerValue())
assertEquals(0b0011001101010101, RuntimeValueNumeric(DataType.UWORD, 0b1100110010101010).inv().integerValue())
// assertEquals(0, RuntimeValueNumeric(DataType.UWORD, 0).neg().integerValue())
// assertEquals(0, RuntimeValueNumeric(DataType.UWORD, 0).neg().integerValue())
assertEquals(1, RuntimeValueNumeric(DataType.UWORD, 0).not().integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.UWORD, 1).not().integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.UWORD, 11111).not().integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.UWORD, 65535).not().integerValue())
assertEquals(2000, RuntimeValueNumeric(DataType.UWORD, 200).mul(RuntimeValueNumeric(DataType.UWORD, 10)).integerValue())
assertEquals(40000, RuntimeValueNumeric(DataType.UWORD, 200).mul(RuntimeValueNumeric(DataType.UWORD, 200)).integerValue())
assertEquals(14464, RuntimeValueNumeric(DataType.UWORD, 200).mul(RuntimeValueNumeric(DataType.UWORD, 400)).integerValue())
assertEquals(15625, RuntimeValueNumeric(DataType.UWORD, 5).pow(RuntimeValueNumeric(DataType.UWORD, 6)).integerValue())
assertEquals(12589, RuntimeValueNumeric(DataType.UWORD, 5).pow(RuntimeValueNumeric(DataType.UWORD, 7)).integerValue())
assertEquals(10000, RuntimeValueNumeric(DataType.UWORD, 5000).shl().integerValue())
assertEquals(60000, RuntimeValueNumeric(DataType.UWORD, 30000).shl().integerValue())
assertEquals(14464, RuntimeValueNumeric(DataType.UWORD, 40000).shl().integerValue())
}
@Test
fun arithmetictestByte() {
assertEquals(127, RuntimeValueNumeric(DataType.BYTE, 100).add(RuntimeValueNumeric(DataType.BYTE, 27)).integerValue())
assertEquals(-128, RuntimeValueNumeric(DataType.BYTE, 100).add(RuntimeValueNumeric(DataType.BYTE, 28)).integerValue())
assertEquals(-127, RuntimeValueNumeric(DataType.BYTE, 100).add(RuntimeValueNumeric(DataType.BYTE, 29)).integerValue())
assertEquals(1, RuntimeValueNumeric(DataType.BYTE, 2).sub(RuntimeValueNumeric(DataType.BYTE, 1)).integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.BYTE, 2).sub(RuntimeValueNumeric(DataType.BYTE, 2)).integerValue())
assertEquals(-1, RuntimeValueNumeric(DataType.BYTE, 2).sub(RuntimeValueNumeric(DataType.BYTE, 3)).integerValue())
assertEquals(-128, RuntimeValueNumeric(DataType.BYTE, -100).sub(RuntimeValueNumeric(DataType.BYTE, 28)).integerValue())
assertEquals(127, RuntimeValueNumeric(DataType.BYTE, -100).sub(RuntimeValueNumeric(DataType.BYTE, 29)).integerValue())
assertEquals(127, RuntimeValueNumeric(DataType.BYTE, 126).inc().integerValue())
assertEquals(-128, RuntimeValueNumeric(DataType.BYTE, 127).inc().integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.BYTE, 1).dec().integerValue())
assertEquals(-1, RuntimeValueNumeric(DataType.BYTE, 0).dec().integerValue())
assertEquals(-128, RuntimeValueNumeric(DataType.BYTE, -127).dec().integerValue())
assertEquals(127, RuntimeValueNumeric(DataType.BYTE, -128).dec().integerValue())
assertEquals(-1, RuntimeValueNumeric(DataType.BYTE, 0).inv().integerValue())
assertEquals(-103, RuntimeValueNumeric(DataType.BYTE, 0b01100110).inv().integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.BYTE, 0).neg().integerValue())
assertEquals(-2, RuntimeValueNumeric(DataType.BYTE, 2).neg().integerValue())
assertEquals(1, RuntimeValueNumeric(DataType.BYTE, 0).not().integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.BYTE, 1).not().integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.BYTE, 111).not().integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.BYTE, -33).not().integerValue())
assertEquals(100, RuntimeValueNumeric(DataType.BYTE, 10).mul(RuntimeValueNumeric(DataType.BYTE, 10)).integerValue())
assertEquals(-56, RuntimeValueNumeric(DataType.BYTE, 20).mul(RuntimeValueNumeric(DataType.BYTE, 10)).integerValue())
assertEquals(25, RuntimeValueNumeric(DataType.BYTE, 5).pow(RuntimeValueNumeric(DataType.BYTE, 2)).integerValue())
assertEquals(125, RuntimeValueNumeric(DataType.BYTE, 5).pow(RuntimeValueNumeric(DataType.BYTE, 3)).integerValue())
assertEquals(113, RuntimeValueNumeric(DataType.BYTE, 5).pow(RuntimeValueNumeric(DataType.BYTE, 4)).integerValue())
assertEquals(100, RuntimeValueNumeric(DataType.BYTE, 50).shl().integerValue())
assertEquals(-56, RuntimeValueNumeric(DataType.BYTE, 100).shl().integerValue())
assertEquals(-2, RuntimeValueNumeric(DataType.BYTE, -1).shl().integerValue())
}
@Test
fun arithmetictestWorrd() {
assertEquals(32767, RuntimeValueNumeric(DataType.WORD, 32700).add(RuntimeValueNumeric(DataType.WORD, 67)).integerValue())
assertEquals(-32768, RuntimeValueNumeric(DataType.WORD, 32700).add(RuntimeValueNumeric(DataType.WORD, 68)).integerValue())
assertEquals(-32767, RuntimeValueNumeric(DataType.WORD, 32700).add(RuntimeValueNumeric(DataType.WORD, 69)).integerValue())
assertEquals(1, RuntimeValueNumeric(DataType.WORD, 2).sub(RuntimeValueNumeric(DataType.WORD, 1)).integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.WORD, 2).sub(RuntimeValueNumeric(DataType.WORD, 2)).integerValue())
assertEquals(-1, RuntimeValueNumeric(DataType.WORD, 2).sub(RuntimeValueNumeric(DataType.WORD, 3)).integerValue())
assertEquals(-32768, RuntimeValueNumeric(DataType.WORD, -32700).sub(RuntimeValueNumeric(DataType.WORD, 68)).integerValue())
assertEquals(32767, RuntimeValueNumeric(DataType.WORD, -32700).sub(RuntimeValueNumeric(DataType.WORD, 69)).integerValue())
assertEquals(32767, RuntimeValueNumeric(DataType.WORD, 32766).inc().integerValue())
assertEquals(-32768, RuntimeValueNumeric(DataType.WORD, 32767).inc().integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.WORD, 1).dec().integerValue())
assertEquals(-1, RuntimeValueNumeric(DataType.WORD, 0).dec().integerValue())
assertEquals(-32768, RuntimeValueNumeric(DataType.WORD, -32767).dec().integerValue())
assertEquals(32767, RuntimeValueNumeric(DataType.WORD, -32768).dec().integerValue())
assertEquals(-1, RuntimeValueNumeric(DataType.WORD, 0).inv().integerValue())
assertEquals(-103, RuntimeValueNumeric(DataType.WORD, 0b01100110).inv().integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.WORD, 0).neg().integerValue())
assertEquals(-2, RuntimeValueNumeric(DataType.WORD, 2).neg().integerValue())
assertEquals(1, RuntimeValueNumeric(DataType.WORD, 0).not().integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.WORD, 1).not().integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.WORD, 111).not().integerValue())
assertEquals(0, RuntimeValueNumeric(DataType.WORD, -33).not().integerValue())
assertEquals(10000, RuntimeValueNumeric(DataType.WORD, 100).mul(RuntimeValueNumeric(DataType.WORD, 100)).integerValue())
assertEquals(-25536, RuntimeValueNumeric(DataType.WORD, 200).mul(RuntimeValueNumeric(DataType.WORD, 200)).integerValue())
assertEquals(15625, RuntimeValueNumeric(DataType.WORD, 5).pow(RuntimeValueNumeric(DataType.WORD, 6)).integerValue())
assertEquals(-6487, RuntimeValueNumeric(DataType.WORD, 9).pow(RuntimeValueNumeric(DataType.WORD, 5)).integerValue())
assertEquals(18000, RuntimeValueNumeric(DataType.WORD, 9000).shl().integerValue())
assertEquals(-25536, RuntimeValueNumeric(DataType.WORD, 20000).shl().integerValue())
assertEquals(-2, RuntimeValueNumeric(DataType.WORD, -1).shl().integerValue())
}
}

1269
compiler/test/StackVMOpcodeTests.kt
View File

File diff suppressed because it is too large Load Diff

96
compiler/test/UnitTests.kt
View File

@ -7,14 +7,18 @@ import org.junit.jupiter.api.Test
import org.junit.jupiter.api.TestInstance
import prog8.ast.base.DataType
import prog8.ast.base.Position
import prog8.ast.expressions.LiteralValue
import prog8.vm.RuntimeValue
import prog8.ast.expressions.NumericLiteralValue
import prog8.ast.expressions.StringLiteralValue
import prog8.compiler.*
import prog8.compiler.target.c64.*
import prog8.compiler.target.c64.C64MachineDefinition.C64Zeropage
import prog8.compiler.target.c64.C64MachineDefinition.FLOAT_MAX_NEGATIVE
import prog8.compiler.target.c64.C64MachineDefinition.FLOAT_MAX_POSITIVE
import prog8.compiler.target.c64.C64MachineDefinition.Mflpt5
import prog8.compiler.target.c64.Petscii
import prog8.vm.RuntimeValueNumeric
import java.io.CharConversionException
import kotlin.test.*
@TestInstance(TestInstance.Lifecycle.PER_CLASS)
class TestCompiler {
@Test
@ -49,7 +53,6 @@ class TestCompiler {
assertFailsWith<CompilerException> { 65536L.toHex() }
}
@Test
fun testFloatToMflpt5() {
assertThat(Mflpt5.fromNumber(0), equalTo(Mflpt5(0x00, 0x00, 0x00, 0x00, 0x00)))
@ -92,29 +95,29 @@ class TestCompiler {
@Test
fun testMflpt5ToFloat() {
val PRECISION=0.000000001
val epsilon=0.000000001
assertThat(Mflpt5(0x00, 0x00, 0x00, 0x00, 0x00).toDouble(), equalTo(0.0))
assertThat(Mflpt5(0x82, 0x49, 0x0F, 0xDA, 0xA1).toDouble(), closeTo(3.141592653, PRECISION))
assertThat(Mflpt5(0x82, 0x49, 0x0F, 0xDA, 0xA2).toDouble(), closeTo(3.141592653589793, PRECISION))
assertThat(Mflpt5(0x82, 0x49, 0x0F, 0xDA, 0xA1).toDouble(), closeTo(3.141592653, epsilon))
assertThat(Mflpt5(0x82, 0x49, 0x0F, 0xDA, 0xA2).toDouble(), closeTo(3.141592653589793, epsilon))
assertThat(Mflpt5(0x90, 0x00, 0x00, 0x00, 0x00).toDouble(), equalTo(32768.0))
assertThat(Mflpt5(0x90, 0x80, 0x00, 0x00, 0x00).toDouble(), equalTo(-32768.0))
assertThat(Mflpt5(0x81, 0x00, 0x00, 0x00, 0x00).toDouble(), equalTo(1.0))
assertThat(Mflpt5(0x80, 0x35, 0x04, 0xF3, 0x34).toDouble(), closeTo(0.7071067812, PRECISION))
assertThat(Mflpt5(0x80, 0x35, 0x04, 0xF3, 0x33).toDouble(), closeTo(0.7071067811865476, PRECISION))
assertThat(Mflpt5(0x81, 0x35, 0x04, 0xF3, 0x34).toDouble(), closeTo(1.4142135624, PRECISION))
assertThat(Mflpt5(0x81, 0x35, 0x04, 0xF3, 0x33).toDouble(), closeTo(1.4142135623730951, PRECISION))
assertThat(Mflpt5(0x80, 0x35, 0x04, 0xF3, 0x34).toDouble(), closeTo(0.7071067812, epsilon))
assertThat(Mflpt5(0x80, 0x35, 0x04, 0xF3, 0x33).toDouble(), closeTo(0.7071067811865476, epsilon))
assertThat(Mflpt5(0x81, 0x35, 0x04, 0xF3, 0x34).toDouble(), closeTo(1.4142135624, epsilon))
assertThat(Mflpt5(0x81, 0x35, 0x04, 0xF3, 0x33).toDouble(), closeTo(1.4142135623730951, epsilon))
assertThat(Mflpt5(0x80, 0x80, 0x00, 0x00, 0x00).toDouble(), equalTo(-.5))
assertThat(Mflpt5(0x80, 0x31, 0x72, 0x17, 0xF8).toDouble(), closeTo(0.69314718061, PRECISION))
assertThat(Mflpt5(0x80, 0x31, 0x72, 0x17, 0xF7).toDouble(), closeTo(0.6931471805599453, PRECISION))
assertThat(Mflpt5(0x80, 0x31, 0x72, 0x17, 0xF8).toDouble(), closeTo(0.69314718061, epsilon))
assertThat(Mflpt5(0x80, 0x31, 0x72, 0x17, 0xF7).toDouble(), closeTo(0.6931471805599453, epsilon))
assertThat(Mflpt5(0x84, 0x20, 0x00, 0x00, 0x00).toDouble(), equalTo(10.0))
assertThat(Mflpt5(0x9E, 0x6E, 0x6B, 0x28, 0x00).toDouble(), equalTo(1000000000.0))
assertThat(Mflpt5(0x80, 0x00, 0x00, 0x00, 0x00).toDouble(), equalTo(.5))
assertThat(Mflpt5(0x81, 0x38, 0xAA, 0x3B, 0x29).toDouble(), closeTo(1.4426950408889634, PRECISION))
assertThat(Mflpt5(0x81, 0x49, 0x0F, 0xDA, 0xA2).toDouble(), closeTo(1.5707963267948966, PRECISION))
assertThat(Mflpt5(0x83, 0x49, 0x0F, 0xDA, 0xA2).toDouble(), closeTo(6.283185307179586, PRECISION))
assertThat(Mflpt5(0x81, 0x38, 0xAA, 0x3B, 0x29).toDouble(), closeTo(1.4426950408889634, epsilon))
assertThat(Mflpt5(0x81, 0x49, 0x0F, 0xDA, 0xA2).toDouble(), closeTo(1.5707963267948966, epsilon))
assertThat(Mflpt5(0x83, 0x49, 0x0F, 0xDA, 0xA2).toDouble(), closeTo(6.283185307179586, epsilon))
assertThat(Mflpt5(0x7F, 0x00, 0x00, 0x00, 0x00).toDouble(), equalTo(.25))
assertThat(Mflpt5(0xd1, 0x02, 0xb7, 0x06, 0xfb).toDouble(), closeTo(123.45678e22, 1.0e15))
assertThat(Mflpt5(0x3e, 0xe9, 0x34, 0x09, 0x1b).toDouble(), closeTo(-123.45678e-22, PRECISION))
assertThat(Mflpt5(0x3e, 0xe9, 0x34, 0x09, 0x1b).toDouble(), closeTo(-123.45678e-22, epsilon))
}
}
@ -140,8 +143,12 @@ class TestZeropage {
assertFailsWith<CompilerException> {
zp.allocate("", DataType.FLOAT, null)
}
val zp2 = C64Zeropage(CompilationOptions(OutputType.RAW, LauncherType.NONE, ZeropageType.FLOATSAFE, emptyList(), true))
zp2.allocate("", DataType.FLOAT, null)
val zp2 = C64Zeropage(CompilationOptions(OutputType.RAW, LauncherType.NONE, ZeropageType.DONTUSE, emptyList(), true))
assertFailsWith<CompilerException> {
zp2.allocate("", DataType.FLOAT, null)
}
val zp3 = C64Zeropage(CompilationOptions(OutputType.RAW, LauncherType.NONE, ZeropageType.FLOATSAFE, emptyList(), true))
zp3.allocate("", DataType.FLOAT, null)
}
@Test
@ -160,14 +167,24 @@ class TestZeropage {
}
}
@Test
fun testZpDontuse() {
val zp = C64Zeropage(CompilationOptions(OutputType.RAW, LauncherType.NONE, ZeropageType.DONTUSE, emptyList(), false))
println(zp.free)
assertEquals(0, zp.available())
assertFailsWith<CompilerException> {
zp.allocate("", DataType.BYTE, null)
}
}
@Test
fun testFreeSpaces() {
val zp1 = C64Zeropage(CompilationOptions(OutputType.RAW, LauncherType.NONE, ZeropageType.BASICSAFE, emptyList(), true))
assertEquals(20, zp1.available())
assertEquals(16, zp1.available())
val zp2 = C64Zeropage(CompilationOptions(OutputType.RAW, LauncherType.NONE, ZeropageType.FLOATSAFE, emptyList(), false))
assertEquals(95, zp2.available())
assertEquals(91, zp2.available())
val zp3 = C64Zeropage(CompilationOptions(OutputType.RAW, LauncherType.NONE, ZeropageType.KERNALSAFE, emptyList(), false))
assertEquals(129, zp3.available())
assertEquals(125, zp3.available())
val zp4 = C64Zeropage(CompilationOptions(OutputType.RAW, LauncherType.NONE, ZeropageType.FULL, emptyList(), false))
assertEquals(238, zp4.available())
}
@ -197,11 +214,10 @@ class TestZeropage {
@Test
fun testBasicsafeAllocation() {
val zp = C64Zeropage(CompilationOptions(OutputType.RAW, LauncherType.NONE, ZeropageType.BASICSAFE, emptyList(), true))
assertEquals(20, zp.available())
assertEquals(16, zp.available())
zp.allocate("", DataType.FLOAT, null)
assertFailsWith<ZeropageDepletedError> {
// in regular zp there aren't 5 sequential bytes free after we take the first sequence
// in regular zp there aren't 5 sequential bytes free
zp.allocate("", DataType.FLOAT, null)
}
@ -251,16 +267,16 @@ class TestZeropage {
@Test
fun testEfficientAllocation() {
val zp = C64Zeropage(CompilationOptions(OutputType.RAW, LauncherType.NONE, ZeropageType.BASICSAFE, emptyList(), true))
assertEquals(20, zp.available())
assertEquals(0x04, zp.allocate("", DataType.FLOAT, null))
assertEquals(0x09, zp.allocate("", DataType.UBYTE, null))
assertEquals(0x0d, zp.allocate("", DataType.UWORD, null))
assertEquals(16, zp.available())
assertEquals(0x04, zp.allocate("", DataType.WORD, null))
assertEquals(0x06, zp.allocate("", DataType.UBYTE, null))
assertEquals(0x0a, zp.allocate("", DataType.UBYTE, null))
assertEquals(0x94, zp.allocate("", DataType.UWORD, null))
assertEquals(0xa7, zp.allocate("", DataType.UWORD, null))
assertEquals(0xa9, zp.allocate("", DataType.UWORD, null))
assertEquals(0xb5, zp.allocate("", DataType.UWORD, null))
assertEquals(0xf7, zp.allocate("", DataType.UWORD, null))
assertEquals(0x0a, zp.allocate("", DataType.UBYTE, null))
assertEquals(0x0e, zp.allocate("", DataType.UBYTE, null))
assertEquals(0xf9, zp.allocate("", DataType.UBYTE, null))
assertEquals(0, zp.available())
}
@ -336,8 +352,8 @@ class TestPetscii {
@Test
fun testLiteralValueComparisons() {
val ten = LiteralValue(DataType.UWORD, wordvalue = 10, position = Position("", 0, 0, 0))
val nine = LiteralValue(DataType.UBYTE, bytevalue = 9, position = Position("", 0, 0, 0))
val ten = NumericLiteralValue(DataType.UWORD, 10, Position("", 0, 0, 0))
val nine = NumericLiteralValue(DataType.UBYTE, 9, Position("", 0, 0, 0))
assertEquals(ten, ten)
assertNotEquals(ten, nine)
assertFalse(ten != ten)
@ -353,23 +369,17 @@ class TestPetscii {
assertTrue(ten <= ten)
assertFalse(ten < ten)
val abc = LiteralValue(DataType.STR, strvalue = "abc", position = Position("", 0, 0, 0))
val abd = LiteralValue(DataType.STR, strvalue = "abd", position = Position("", 0, 0, 0))
val abc = StringLiteralValue("abc", false, Position("", 0, 0, 0))
val abd = StringLiteralValue("abd", false, Position("", 0, 0, 0))
assertEquals(abc, abc)
assertTrue(abc!=abd)
assertFalse(abc!=abc)
assertTrue(abc < abd)
assertTrue(abc <= abd)
assertFalse(abd <= abc)
assertTrue(abd >= abc)
assertTrue(abd > abc)
assertFalse(abc > abd)
}
@Test
fun testStackvmValueComparisons() {
val ten = RuntimeValue(DataType.FLOAT, 10)
val nine = RuntimeValue(DataType.UWORD, 9)
val ten = RuntimeValueNumeric(DataType.FLOAT, 10)
val nine = RuntimeValueNumeric(DataType.UWORD, 9)
assertEquals(ten, ten)
assertNotEquals(ten, nine)
assertFalse(ten != ten)

21
create_compiler_jar.sh
View File

@ -1,21 +0,0 @@
#!/bin/sh
# this script uses the Gradle build to compile the code,
# and then adds the contents of several jar files into one output jar.
./gradlew jar
mkdir -p compiler_jar/extracted
mkdir -p compiler_jar/source
cp compiler/build/libs/compiler.jar parser/build/libs/parser.jar parser/antlr/lib/antlr-runtime-4.7.2.jar compiler_jar/source/
KOTLINLIBS=$(kotlinc -verbose -script 2>&1 | grep home | cut -d ' ' -f 6-)/lib
cp ${KOTLINLIBS}/kotlin-stdlib-jdk8.jar ${KOTLINLIBS}/kotlin-stdlib.jar compiler_jar/source/
pushd compiler_jar/extracted
for i in ../source/*.jar; do jar xf $i; done
cd ..
jar cfe ../prog8compiler.jar prog8.CompilerMainKt -C extracted .
popd
rm -r compiler_jar
ls -l prog8compiler.jar

6
docs/docs.iml
View File

@ -2,8 +2,10 @@
<module type="PYTHON_MODULE" version="4">
<component name="NewModuleRootManager" inherit-compiler-output="true">
<exclude-output />
<content url="file://$MODULE_DIR$" />
<orderEntry type="jdk" jdkName="Python 3.7 (py3)" jdkType="Python SDK" />
<content url="file://$MODULE_DIR$">
<excludeFolder url="file://$MODULE_DIR$/build" />
</content>
<orderEntry type="jdk" jdkName="Python 3.8 virtualenv" jdkType="Python SDK" />
<orderEntry type="sourceFolder" forTests="false" />
</component>
</module>

86
docs/source/building.rst
View File

@ -2,6 +2,8 @@
Writing and building a program
==============================
.. _building_compiler:
First, getting a working compiler
---------------------------------
@ -11,20 +13,38 @@ Then you can choose a few ways to get a compiler:
**Download a precompiled version from github:**
#. download a recent "prog8compiler.jar" from `the releases on Github <https://github.com/irmen/prog8/releases>`_
#. run the compiler with "java -jar prog8compiler.jar" to see how you can use it.
#. download a recent "fat-jar" (called something like "prog8compiler-all.jar") from `the releases on Github <https://github.com/irmen/prog8/releases>`_
#. run the compiler with "java -jar prog8compiler-all.jar" to see how you can use it.
**Using the shell scripts:**
**using the Gradle build system to make it yourself:**
#. run the "create_compiler_jar.sh" shell script and have a little patience while everything is built
#. it will output "prog8compiler.jar" file which contains everything.
#. run the compiler with "java -jar prog8compiler.jar" to see how you can use it.
The Gradle build system is used to build the compiler.
The most interesting gradle commands to run are probably:
**using the Gradle build system directly:**
``./gradlew check``
Builds the compiler code and runs all available checks and unit-tests.
``./gradlew installDist``
Builds the compiler and installs it with scripts to run it, in the directory
``./compiler/build/install/p8compile``
``./gradlew installShadowDist``
Creates a 'fat-jar' that contains the compiler and all dependencies, in a single
executable .jar file, and includes few start scripts to run it.
The output can be found in ``.compiler/build/install/compiler-shadow/``
``./gradlew shadowDistZip``
Creates a zipfile with the above in it, for easy distribution.
This file can be found in ``./compiler/build/distributions/``
#. run the command "./gradlew installDist" and have a little patience while everything is built
#. it will create the commands and required libraries in the "./compiler/build/install/p8compile/" directory
#. run the compiler with the "./compiler/build/install/p8compile/bin/p8compile" command to see how you can use it.
For normal use, the ``installDist`` target should suffice and ater succesful completion
of that build task, you can start the compiler with:
``./compiler/build/install/p8compile/bin/p8compile <options> <sourcefile>``
(You should probably make an alias...)
.. note::
Development and testing is done on Linux, but the compiler should run on most
operating systems. If you do have trouble building or running
the compiler on another operating system, please let me know!
@ -54,14 +74,10 @@ The compiler will link everything together into one output program at the end.
If you start the compiler without arguments, it will print a short usage text.
For normal use the compiler is invoked with the command:
``$ java -jar prog8compiler.jar sourcefile.p8`` if you're using the packaged release version, or
``$ java -jar prog8compiler.jar sourcefile.p8``
``$ ./p8compile.sh sourcefile.p8`` if you're running an unpackaged development version.
If you tell it to save the intermediate code for the prog8 virtual machine, you can
actually run this code with the command:
``$ ./p8vm.sh sourcefile.vm.txt``
Other options are also available, see the introduction page about how
to build and run the compiler.
By default, assembly code is generated and written to ``sourcefile.asm``.
@ -71,6 +87,20 @@ If you use the option to let the compiler auto-start a C-64 emulator, it will do
a successful compilation. This will load your program and the symbol and breakpoint lists
(for the machine code monitor) into the emulator.
Continuous compilation mode
^^^^^^^^^^^^^^^^^^^^^^^^^^^
Almost instant compilation times (less than a second) can be achieved when using the continuous compilation mode.
Start the compiler with the ``-watch`` argument to enable this.
It will compile your program and then instead of exiting, it waits for any changes in the module source files.
As soon as a change happens, the program gets compiled again.
Other options
^^^^^^^^^^^^^
There's an option to specify the output directory if you're not happy with the default (the current working directory).
Also it is possible to specify more than one main module to compile:
this can be useful to quickly recompile multiple separate programs quickly.
(compiling in a batch like this is a lot faster than invoking the compiler again once per main file)
Module source code files
------------------------
@ -85,6 +115,13 @@ They are embedded into the packaged release version of the compiler so you don't
where they are, but their names are still reserved.
User defined library files
^^^^^^^^^^^^^^^^^^^^^^^^^^
You can create library files yourself too that can be shared among programs.
You can tell the compiler where it should look for these files, by setting the java command line property ``prog8.libdir``
or by setting the ``PROG8_LIBDIR`` environment variable to the correct directory.
.. _debugging:
Debugging (with Vice)
@ -131,3 +168,18 @@ or::
$ ./p8compile.sh -emu examples/rasterbars.p8
Virtual Machine / Simulator
---------------------------
You may have noticed the ``-sim`` command line option for the compiler:
-sim
Launches the "AST virtual machine Simulator" that directly executes the parsed program.
No compilation steps will be performed.
Allows for very fast testing and debugging before actually compiling programs
to machine code.
It simulates a bare minimum of features from the target platform, so most stuff
that calls ROM routines or writes into hardware registers won't work. But basic
system routines are emulated.

75
docs/source/index.rst
View File

@ -37,15 +37,15 @@ This software is licensed under the GNU GPL 3.0, see https://www.gnu.org/license
:alt: Fully playable tetris clone
Code example
------------
Code examples
-------------
This code calculates prime numbers using the Sieve of Eratosthenes algorithm::
%import c64utils
%zeropage basicsafe
~ main {
main {
ubyte[256] sieve
ubyte candidate_prime = 2
@ -89,13 +89,47 @@ This code calculates prime numbers using the Sieve of Eratosthenes algorithm::
}
when compiled an ran on a C-64 you'll get:
when compiled an ran on a C-64 you get this:
.. image:: _static/primes_example.png
:align: center
:alt: result when run on C-64
The following programs shows a use of the high level ``struct`` type::
%import c64utils
%zeropage basicsafe
main {
struct Color {
ubyte red
ubyte green
ubyte blue
}
sub start() {
Color purple = {255, 0, 255}
Color other
other = purple
other.red /= 2
other.green = 10 + other.green / 2
other.blue = 99
c64scr.print_ub(other.red)
c64.CHROUT(',')
c64scr.print_ub(other.green)
c64.CHROUT(',')
c64scr.print_ub(other.blue)
c64.CHROUT('\n')
}
}
when compiled and ran, it prints ``127,10,99`` on the screen.
Design principles and features
------------------------------
@ -106,7 +140,8 @@ Design principles and features
- 'One statement per line' code style, resulting in clear readable programs.
- Modular programming and scoping via modules, code blocks, and subroutines.
- Provide high level programming constructs but stay close to the metal;
still able to directly use memory addresses, CPU registers and ROM subroutines
still able to directly use memory addresses, CPU registers and ROM subroutines,
and inline assembly to have full control when every cycle or byte matters
- Arbitrary number of subroutine parameters (constrained only by available memory)
- Complex nested expressions are possible
- Values are typed. Types supported include signed and unsigned bytes and words, arrays, strings and floats.
@ -116,13 +151,14 @@ Design principles and features
the compiled program in an emulator and provide debugging information to the emulator.
- The compiler outputs a regular 6502 assembly source code file, but doesn't assemble this itself.
The (separate) '64tass' cross-assembler tool is used for that.
- Goto is usually considered harmful, but not here: arbitrary control flow jumps and branches are possible,
- Arbitrary control flow jumps and branches are possible,
and will usually translate directly into the appropriate single 6502 jump/branch instruction.
- There are no complicated built-in error handling or overflow checks, you'll have to take care
of this yourself if required. This keeps the language and code simple and efficient.
- The compiler tries to optimize the program and generated code, but hand-tuning of the
performance or space-critical parts will likely still be required. This is supported by
the ability to easily write embedded assembly code directly in the program source code.
- There are many built-in functions such as ``sin``, ``cos``, ``rnd``, ``abs``, ``min``, ``max``, ``sqrt``, ``msb``, ``rol``, ``ror``, ``swap``, ``memset``, ``memcopy``, ``sort`` and ``reverse``
.. _requirements:
@ -143,37 +179,14 @@ Finally: a **C-64 emulator** (or a real C-64 ofcourse) to run the programs on. T
of the `Vice emulator <http://vice-emu.sourceforge.net/>`_.
.. important::
**Building the compiler itself:**
**Building the compiler itself:** (*Only needed if you have not downloaded a pre-built 'fat-jar'*)
(re)building the compiler itself requires a recent Kotlin SDK.
The compiler is developed using the `IntelliJ IDEA <https://www.jetbrains.com/idea/>`_
IDE from Jetbrains, with the Kotlin plugin (free community edition of this IDE is available).
But a bare Kotlin SDK installation should work just as well.
A shell script (``create_compiler_jar.sh``) is provided to build and package the compiler from the command line.
If you have the 'fat-jar' you can run it with ``java -jar prog8compiler.jar``.
You can also use the Gradle build system to build the compiler (it will take care of
downloading all required libraries for you) by typing ``gradle build`` for instance.
The output of this gradle build will appear in the "./compiler/build/install/p8compile/" directory.
The most interesting gradle commands to run are probably:
``./gradlew check``
Builds the compiler code and runs all available checks and unit-tests.
``./gradlew installShadowDist``
Creates a 'fat-jar' that contains the compiler and all dependencies,
and a few start scripts to run it.
The output can be found in ``.compiler/build/install/compiler-shadow/``
and you can launch the compiler with the script
``./compiler/build/install/compiler-shadow/bin/p8compile``.
``./gradlew shadowDistZip``
Creates a zipfile with the above in it, for easy distribution.
This file can be found in ``./compiler/build/distributions/``
.. note::
Development and testing is done on Linux, but the compiler should run on most
operating systems. If you do have trouble building or running
the compiler on another operating system, please let me know!
Instructions on how to obtain a working compiler are in :ref:`building_compiler`.
.. toctree::

180
docs/source/programming.rst
View File

@ -93,7 +93,7 @@ Blocks, Scopes, and accessing Symbols
**Blocks** are the top level separate pieces of code and data of your program. They are combined
into a single output program. No code or data can occur outside a block. Here's an example::
~ main $c000 {
main $c000 {
; this is code inside the block...
}
@ -127,12 +127,20 @@ The address must be >= ``$0200`` (because ``$00``--``$ff`` is the ZP and ``$100`
to them by their 'short' name directly. If the symbol is not found in the same scope,
the enclosing scope is searched for it, and so on, until the symbol is found.
Scopes are created using several statements:
Scopes are created using either of these two statements:
- blocks (top-level named scope)
- subroutines (nested named scopes)
- for, while, repeat loops (anonymous scope)
- if statements and branching conditionals (anonymous scope)
- subroutines (nested named scope)
.. note::
In contrast to many other programming languages, a new scope is *not* created inside
for, while and repeat statements, nor for the if statement and branching conditionals.
This is a bit restrictive because you have to think harder about what variables you
want to use inside a subroutine. But it is done precisely for this reason; memory in the
target system is very limited and it would be a waste to allocate a lot of variables.
Right now the prog8 compiler is not advanced enough to be able to 'share' or 'overlap'
variables intelligently by itself. So for now, it's something the programmer has to think about.
Program Start and Entry Point
@ -151,7 +159,7 @@ taking no parameters and having no return value.
As any subroutine, it has to end with a ``return`` statement (or a ``goto`` call)::
~ main {
main {
sub start () {
; program entrypoint code here
return
@ -180,9 +188,11 @@ Values will usually be part of an expression or assignment statement::
12345 ; integer number
$aa43 ; hex integer number
%100101 ; binary integer number (% is also remainder operator so be careful)
"Hi, I am a string" ; text string
'a' ; petscii value (byte) for the letter a
-33.456e52 ; floating point number
"Hi, I am a string" ; text string, encoded with compiler target default encoding
'a' ; byte value (ubyte) for the letter a
@"Alternate" ; text string, encoded with alternate encoding
@'a' ; byte value of the letter a, using alternate encoding
byte counter = 42 ; variable of size 8 bits, with initial value 42
@ -237,6 +247,7 @@ Arrays
^^^^^^
Array types are also supported. They can be made of bytes, words or floats::
byte[10] array ; array of 10 bytes, initially set to 0
byte[] array = [1, 2, 3, 4] ; initialize the array, size taken from value
byte[99] array = 255 ; initialize array with 99 times 255 [255, 255, 255, 255, ...]
byte[] array = 100 to 199 ; initialize array with [100, 101, ..., 198, 199]
@ -262,15 +273,58 @@ Strings
Strings are a sequence of characters enclosed in ``"`` quotes. The length is limited to 255 characters.
They're stored and treated much the same as a byte array,
but they have some special properties because they are considered to be *text*.
Strings in your source code files will be encoded (translated from ASCII/UTF-8) into either CBM PETSCII or C-64 screencodes.
PETSCII is the default choice. If you need screencodes (also called 'poke' codes) instead,
you have to use the ``str_s`` variants of the string type identifier.
Strings in your source code files will be encoded (translated from ASCII/UTF-8) into bytes via the
default encoding that is used on the target platform. For the C-64, this is CBM PETSCII.
Alternate-encoding strings (prefixed with ``@``) will be encoded via the alternate encoding for the
platform (if defined). For the C-64, that is SCREEN CODES (also known as POKE codes).
This @-prefix can also be used for character byte values.
You can concatenate two string literals using '+' (not very useful though) or repeat
a string literal a given number of times using '*'::
str string1 = "first part" + "second part"
str string2 = "hello!" * 10
.. caution::
It's probably best that you don't change strings after they're created.
Avoid changing strings after they've been created.
This is because if your program exits and is restarted (without loading it again),
it will then operate on the changed strings instead of the original ones.
The same is true for arrays by the way.
it will then start working with the changed strings instead of the original ones.
The same is true for arrays.
Structs
^^^^^^^
A struct is a group of one or more other variables.
This allows you to reuse the definition and manipulate it as a whole.
Individual variables in the struct are accessed as you would expect, just
use a scoped name to refer to them: ``structvariable.membername``.
Structs are a bit limited in Prog8: you can only use numerical variables
as member of a struct, so strings and arrays and other structs can not be part of a struct.
Also, it is not possible to use a struct itself inside an array.
Structs are mainly syntactic sugar for repeated groups of vardecls
and assignments that belong together. However,
*they are layed out in sequence in memory as the members are defined*
which may be usefulif you want to pass pointers around.
To create a variable of a struct type you need to define the struct itself,
and then create a variable with it::
struct Color {
ubyte red
ubyte green
ubyte blue
}
Color rgb = {255,122,0} ; note the curly braces here instead of brackets
Color another ; the init value is optional, like arrays
another = rgb ; assign all of the values of rgb to another
another.blue = 255 ; set a single member
Special types: const and memory-mapped
@ -321,10 +375,17 @@ Initial values across multiple runs of the program
When declaring values with an initial value, this value will be set into the variable each time
the program reaches the declaration again. This can be in loops, multiple subroutine calls,
or even multiple invocations of the entire program. If you omit an initial value, it will
be set to zero only for the first run of the program. A second run will utilize the last value
be set to zero *but only for the first run of the program*. A second run will utilize the last value
where it left off (but your code will be a bit smaller because no initialization instructions
are generated)
This only works for simple types, *and not for string variables and arrays*.
It is assumed these are left unchanged by the program; they are not re-initialized on
a second run.
If you do modify them in-place, you should take care yourself that they work as
expected when the program is restarted.
(This is an optimization choice to avoid having to store two copies of every string and array)
.. caution::
variables that get allocated in zero-page will *not* have a zero starting value when you omit
the variable's initialization. They'll be whatever the last value in that zero page
@ -334,19 +395,12 @@ are generated)
this behavior may change in a future version so that subsequent runs always
use the same initial values
This only works for simple types, *and not for string variables and arrays*.
It is assumed these are left unchanged by the program.
If you do modify them in-place, you should take care yourself that they work as
expected when the program is restarted.
(This is an optimization choice to avoid having to store two copies of every string and array)
Loops
-----
The *for*-loop is used to let a variable (or register) iterate over a range of values. Iteration is done in steps of 1, but you can change this.
The loop variable can be declared as byte or word earlier so you can reuse it for multiple occasions,
or you can declare one directly in the for statement which will only be visible in the for loop body.
The loop variable must be declared as byte or word earlier so you can reuse it for multiple occasions.
Iterating with a floating point variable is not supported. If you want to loop over a floating-point array, use a loop with an integer index variable instead.
The *while*-loop is used to repeat a piece of code while a certain condition is still true.
@ -358,7 +412,6 @@ You can also create loops by using the ``goto`` statement, but this should usual
The value of the loop variable or register after executing the loop *is undefined*. Don't use it immediately
after the loop without first assigning a new value to it!
(this is an optimization issue to avoid having to deal with mostly useless post-loop logic to adjust the loop variable's value)
Loop variables that are declared inline are scoped in the loop body so they're not accessible at all after the loop finishes.
Conditional Execution
@ -416,15 +469,26 @@ So ``if_cc goto target`` will directly translate into the single CPU instruction
Maybe in the future this will be a separate nested scope, but for now, that is
only possible when defining a subroutine.
when statement (jumptable)
^^^^^^^^^^^^^^^^^^^^^^^^^^
when statement ('jump table')
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
.. attention::
TODO: docs for this this must still be written.
TODO: the code generator for this is not yet working.
Instead of writing a bunch of sequential if-elseif statements, it is more readable to
use a ``when`` statement. (It will also result in greatly improved assembly code generation)
Use a ``when`` statement if you have a set of fixed choices that each should result in a certain
action. It is possible to combine several choices to result in the same action::
Use a ``when`` statement if you have a set of choices that each should result in a certain
action. It's more readable (and results in faster code) than using a lot of if / else statements.
when value {
4 -> c64scr.print("four")
5 -> c64scr.print("five")
10,20,30 -> {
c64scr.print("ten or twenty or thirty")
}
else -> c64scr.print("don't know")
}
The when-*value* can be any expression but the choice values have to evaluate to
compile-time constant integers (bytes or words). They also have to be the same
datatype as the when-value, otherwise no efficient comparison can be done.
Assignments
@ -549,8 +613,8 @@ Calling a subroutine
^^^^^^^^^^^^^^^^^^^^
The arguments in parentheses after the function name, should match the parameters in the subroutine definition.
It is possible to not store the return value but the compiler
will issue a warning then telling you the result values of a subroutine call are discarded.
If you want to ignore a return value of a subroutine, you should prefix the call with the ``void`` keyword.
Otherwise the compiler will issue a warning about discarding a result value.
.. caution::
Note that due to the way parameters are processed by the compiler,
@ -600,55 +664,62 @@ cos16u(x)
Fast 16-bit uword cosine of angle 0..255, result is in range 0..65535
cos16(x)
Fast 16-bit word cosine of angle 0..255, result is in range -32767..32767
Fast 16-bit word cosine of angle 0..255, result is in range -32767..32767
abs(x)
Absolute value.
Absolute value.
tan(x)
Tangent.
Tangent.
atan(x)
Arctangent.
Arctangent.
ln(x)
Natural logarithm (base e).
Natural logarithm (base e).
log2(x)
Base 2 logarithm.
sqrt16(w)
16 bit unsigned integer Square root. Result is unsigned byte.
16 bit unsigned integer Square root. Result is unsigned byte.
sqrt(x)
Floating point Square root.
Floating point Square root.
round(x)
Rounds the floating point to the closest integer.
Rounds the floating point to the closest integer.
floor (x)
Rounds the floating point down to an integer towards minus infinity.
Rounds the floating point down to an integer towards minus infinity.
ceil(x)
Rounds the floating point up to an integer towards positive infinity.
Rounds the floating point up to an integer towards positive infinity.
rad(x)
Degrees to radians.
Degrees to radians.
deg(x)
Radians to degrees.
Radians to degrees.
max(x)
Maximum of the values in the array value x
Maximum of the values in the array value x
min(x)
Minimum of the values in the array value x
avg(x)
Average of the values in the array value x
Minimum of the values in the array value x
sum(x)
Sum of the values in the array value x
Sum of the values in the array value x
sort(array)
Sort the array in ascending order (in-place)
Note: sorting a floating-point array is not supported right now, as a general sorting routine for this will
be extremely slow. Either build one yourself or find another solution that doesn't require sorting
floating point values.
reverse(array)
Reverse the values in the array (in-place). Supports all data types including floats.
Can be used after sort() to sort an array in descending order.
len(x)
Number of values in the array value x, or the number of characters in a string (excluding the size or 0-byte).
@ -667,6 +738,9 @@ lsb(x)
msb(x)
Get the most significant byte of the word x.
sgn(x)
Get the sign of the value. Result is -1, 0 or 1 (negative, zero, positive).
mkword(lsb, msb)
Efficiently create a word value from two bytes (the lsb and the msb). Avoids multiplication and shifting.
@ -703,7 +777,7 @@ rol(x)
Modifies in-place, doesn't return a value (so can't be used in an expression).
rol2(x)
Like _rol but now as 8-bit or 16-bit rotation.
Like ``rol`` but now as 8-bit or 16-bit rotation.
It uses some extra logic to not consider the carry flag as extra rotation bit.
Modifies in-place, doesn't return a value (so can't be used in an expression).
@ -715,7 +789,7 @@ ror(x)
Modifies in-place, doesn't return a value (so can't be used in an expression).
ror2(x)
Like _ror but now as 8-bit or 16-bit rotation.
Like ``ror`` but now as 8-bit or 16-bit rotation.
It uses some extra logic to not consider the carry flag as extra rotation bit.
Modifies in-place, doesn't return a value (so can't be used in an expression).

Some files were not shown because too many files have changed in this diff Show More