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base: Apple-2-SW:v1.60
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compare: Apple-2-SW:v4.1
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376 Commits
v1.60 ... v4.1

Author SHA1 Message Date
Irmen de Jong
809917f13b version 4.1 2020-08-31 21:44:38 +02:00
Irmen de Jong
2b35498370 added CX16 txt.setcc and swirl examples that use it 2020-08-31 21:01:18 +02:00
Irmen de Jong
f45eabdd9e added CX16 VERA registers, made txt.fill_screen work on CX16 2020-08-31 18:23:52 +02:00
Irmen de Jong
438f3ee8d2 make GIVUAYFAY work (unsigned word to float) 2020-08-31 17:16:51 +02:00
Irmen de Jong
4bea31f051 fl_zero fix 2020-08-31 01:04:04 +02:00
Irmen de Jong
5eae7a2b93 tweak mandelbrots and c64 graphics plot() doesnt work with XY parameter 2020-08-31 00:36:40 +02:00
Irmen de Jong
364ef3e55c tweak cx16 mandelbrots 2020-08-31 00:03:05 +02:00
Irmen de Jong
e61818f194 tweak cx16 mandelbrots 2020-08-30 19:31:20 +02:00
Irmen de Jong
0f9ce319d4 readme 2020-08-30 18:36:02 +02:00
Irmen de Jong
5d90871789 got floating points working in commanderx16, added txt.color() to set text color 2020-08-30 00:15:18 +02:00
Irmen de Jong
88a9e09918 got floating points working in commanderx16 2020-08-29 23:55:26 +02:00
Irmen de Jong
c50ecf6055 fix for loop asm creation with word loopvar 2020-08-29 02:05:24 +02:00
Irmen de Jong
a18de75da9 fix compiler loop and missing type checks on for loop range values 2020-08-29 01:48:41 +02:00
Irmen de Jong
e112dfd910 implemented signed byte and word division 2020-08-29 00:00:53 +02:00
Irmen de Jong
9154d8bd37 optimizing X register saving for 65c02 using phx/plx instead of zp location 2020-08-28 22:11:33 +02:00
Irmen de Jong
0b55372b3b cleanup cx16 things and added call signatures. c64graphics moved into built-in libraries. 2020-08-28 21:42:53 +02:00
Irmen de Jong
3ad7fb010f clearer about emulator 2020-08-27 21:09:59 +02:00
Irmen de Jong
3f64d1bb5a oops. 2020-08-27 21:04:08 +02:00
Irmen de Jong
a6f564ad88 version 4.0 2020-08-27 20:54:08 +02:00
Irmen de Jong
d97da3bb7b implemented almost all math operations 2020-08-27 20:47:22 +02:00
Irmen de Jong
a77d3c92ad implemented remaining float operations 2020-08-27 19:47:50 +02:00
Irmen de Jong
6d17e5307c fixed typecasting of const arguments once again 2020-08-27 19:06:27 +02:00
Irmen de Jong
c2205e473a fix example 2020-08-27 18:21:12 +02:00
Irmen de Jong
4ffb194847 readme and version 2020-08-27 18:18:29 +02:00
Irmen de Jong
744cd6ec42 updated examples 2020-08-27 18:11:49 +02:00
Irmen de Jong
f08fc18ab5 renamed c64scr. to txt. 2020-08-27 18:10:22 +02:00
Irmen de Jong
462af76770 cx16 link 2020-08-26 20:54:36 +02:00
Irmen de Jong
9cec554f7c moved the type conversion routines to their own library file to avoid duplication 2020-08-26 20:52:38 +02:00
Irmen de Jong
08b25e610d commander x16 improvements 2020-08-26 19:34:12 +02:00
Irmen de Jong
e896d5a1a6 ver 2020-08-26 02:03:18 +02:00
Irmen de Jong
b939562062 added preliminary CommanderX16 machine target support. Fixed nullpointer when importing a missing file. 2020-08-26 01:56:26 +02:00
Irmen de Jong
256781bba5 added missing in-place bitwise operator code 2020-08-25 22:26:05 +02:00
Irmen de Jong
19705196d6 separate varnames and other symbol names 2020-08-25 22:08:52 +02:00
Irmen de Jong
3ce692bb10 even better machinetarget independence 2020-08-25 19:56:53 +02:00
Irmen de Jong
78bdbde3ae refer to ZP scratch constants from asm code via the global P8ZP constants as well 2020-08-25 19:44:08 +02:00
Irmen de Jong
8d8c066447 made the ZP and compilation target more generic 2020-08-25 19:32:31 +02:00
Irmen de Jong
5da9379c37 making zeropage more configurable for future different machine targets 2020-08-25 18:10:06 +02:00
Irmen de Jong
032d20ff37 added the missing stack assignments 2020-08-25 17:43:35 +02:00
Irmen de Jong
d19b17cbfe optimize strlen() 2020-08-25 17:31:47 +02:00
Irmen de Jong
4a4f8ff5db subroutine parameters can be allocated on the zp now as well 2020-08-25 16:47:21 +02:00
Irmen de Jong
60a9209a14 plasma 2020-08-25 01:48:23 +02:00
Irmen de Jong
0f9e167df3 proper name 2020-08-25 00:59:02 +02:00
Irmen de Jong
2e2b8c498e slightly optimize loop 2020-08-25 00:35:51 +02:00
Irmen de Jong
144199730f refactored and optimized load/store byte from pointervar 2020-08-25 00:18:33 +02:00
Irmen de Jong
4bb4eab3b2 cleanup 2020-08-24 23:18:46 +02:00
Irmen de Jong
cf9151f669 use AsmAssignment preferrably over creating new ast node for codegen 2020-08-24 22:45:43 +02:00
Irmen de Jong
aef4598cec comments 2020-08-24 02:56:22 +02:00
Irmen de Jong
3ada0fdf84 function call register args code consolidation, fix asm for loading word value from variable into register 2020-08-24 01:42:44 +02:00
Irmen de Jong
a5d97b326e bugfix byte array assignment 2020-08-24 00:48:19 +02:00
Irmen de Jong
2640015fb1 move 2020-08-24 00:26:26 +02:00
Irmen de Jong
6cd42ddafe cleanup 2020-08-23 23:28:25 +02:00
Irmen de Jong
1f17c22132 more array access optimizations 2020-08-23 22:36:49 +02:00
Irmen de Jong
5c62f612cc cleanup 2020-08-23 20:34:27 +02:00
Irmen de Jong
b9ca1c2e2c more uniform code for array indexing (all using scaled offset now) 2020-08-23 20:25:00 +02:00
Irmen de Jong
93b2ff2e52 fix postincrdecr on array value 2020-08-23 18:52:19 +02:00
Irmen de Jong
3991d23a69 refactoring 2020-08-23 18:20:57 +02:00
Irmen de Jong
1be139759c better names 2020-08-23 16:08:31 +02:00
Irmen de Jong
d0674ad688 better names, reorder 2020-08-23 14:36:24 +02:00
Irmen de Jong
ffb47458ff better names 2020-08-23 13:56:21 +02:00
Irmen de Jong
84ec1be8a4 assign type relax 2020-08-23 13:31:14 +02:00
Irmen de Jong
f4dafec645 assign type assert 2020-08-23 12:52:27 +02:00
Irmen de Jong
97ce72521d for arrays, use the element's datatype more instead of the array decl type 2020-08-23 12:03:52 +02:00
Irmen de Jong
d2f0e74879 use sourcetype 2020-08-23 11:31:33 +02:00
Irmen de Jong
d9e3895c45 start with yet another codegen restructure, this time to make the assignment of values even more explicit for the codegen 2020-08-23 02:05:01 +02:00
Irmen de Jong
5075901830 work 2020-08-22 23:39:27 +02:00
Irmen de Jong
f1193bb5a0 Better error message 2020-08-22 23:13:53 +02:00
Irmen de Jong
d3dc279105 updated the compiled examples 2020-08-22 22:57:30 +02:00
Irmen de Jong
acc942f690 added some more asm code optimizations by splitting certain assignments 2020-08-22 22:53:21 +02:00
Irmen de Jong
e947067dcf fixed source code output issue 2020-08-22 22:23:00 +02:00
Irmen de Jong
bd9ebf4603 flipped the order of the parameters of mkword() so it's now mkword(msb, lsb) for easier readability 2020-08-22 21:13:38 +02:00
Irmen de Jong
f41192a52a added cube3d-gfx example 2020-08-22 19:00:03 +02:00
Irmen de Jong
ff54d6abd7 reorder const for all associative operators 2020-08-22 17:44:32 +02:00
Irmen de Jong
f40bcc219f better errormsg 2020-08-22 17:29:35 +02:00
Irmen de Jong
679965410a todo 2020-08-22 17:13:23 +02:00
Irmen de Jong
c6e13ae2a3 better error message 2020-08-22 17:12:09 +02:00
Irmen de Jong
20cdcc673b identifiers can no longer start with an underscore. (this interfered with 64tass syntax) 2020-08-22 17:03:40 +02:00
Irmen de Jong
89f46222d9 fix compiler crash when calling a non-subroutine 2020-08-22 17:01:47 +02:00
Irmen de Jong
b27cbfac5e removed lsl() and lsr() functions just use <<=1 and >>=1 2020-08-22 16:44:48 +02:00
Irmen de Jong
31c946aeeb bugfix 2020-08-22 16:39:17 +02:00
Irmen de Jong
bfc8a26381 implemented bit shifting for non-const amounts 2020-08-22 16:13:52 +02:00
Irmen de Jong
9d98746501 version 3.2 2020-08-21 18:02:49 +02:00
Irmen de Jong
63b03ba70c fix typecasting 2020-08-21 18:02:01 +02:00
Irmen de Jong
70bab76b36 added plasma example 2020-08-21 17:58:43 +02:00
Irmen de Jong
15d24d4308 adding plasma example 2020-08-21 17:27:18 +02:00
Irmen de Jong
9ec62eb045 fixed lsb(), fixed const value type mismatch, fixed and() const evaluation. 2020-08-21 16:26:40 +02:00
Irmen de Jong
12f841e30d just prints 2020-08-21 09:25:32 +02:00
Irmen de Jong
335599ed22 restored certain memoryread asm gen 2020-08-21 07:44:50 +02:00
Irmen de Jong
0b717f9e76 clear messages about slow expression code generation points 2020-08-21 05:45:39 +02:00
Irmen de Jong
e941f6ecca fix asm bug 2020-08-21 04:23:08 +02:00
Irmen de Jong
ef7744dbda asm fix 2020-08-21 04:02:10 +02:00
Irmen de Jong
c83a61c460 some float asm code added for in-place 2020-08-21 03:06:37 +02:00
Irmen de Jong
335684caf7 don't remove asmsub definitions... 2020-08-21 03:01:07 +02:00
Irmen de Jong
8d6220ce51 added most essential of the new in-place assignment code 2020-08-21 02:17:40 +02:00
Irmen de Jong
39ea5c5f99 fix parse error for <<= and >>= 2020-08-20 23:24:01 +02:00
Irmen de Jong
b03597ac13 fixed bug in operand equality comparison, could lead to compiler endless loop 2020-08-20 22:21:26 +02:00
Irmen de Jong
58f323c087 implemented missing memory postincrdecr codegen 2020-08-20 21:48:15 +02:00
Irmen de Jong
513a68584c implemented more optimized prefix expression codegen 2020-08-20 21:42:38 +02:00
Irmen de Jong
88d5c68b32 don't inc/dec a memory mapped register 2020-08-20 21:16:48 +02:00
Irmen de Jong
14f9382cf9 typecheck prefix expressions better 2020-08-20 20:46:28 +02:00
Irmen de Jong
cffb582568 added start of optimized in-place assignment code (for prefix expressions) 2020-08-20 18:43:10 +02:00
Irmen de Jong
e1812ce16c fix typecast removal error. 2020-08-20 18:07:48 +02:00
Irmen de Jong
7a3163f59a bugfix in direct memory assignment 2020-08-20 17:02:22 +02:00
Irmen de Jong
6f3b2749b0 refactoring assignments codegen 2020-08-20 16:47:43 +02:00
Irmen de Jong
c144d4e501 improved warnings about unreachable code 2020-08-20 14:28:17 +02:00
Irmen de Jong
edfd9d55ba added sizeof() function 2020-08-20 13:50:28 +02:00
Irmen de Jong
774897260e avoid silent type casts that remove precision (such as float -> word) 2020-08-20 12:49:48 +02:00
Irmen de Jong
65ba91411d improved function arg type checking and error message 2020-08-20 12:38:22 +02:00
Irmen de Jong
9cbb8e1a64 version 3.1 2020-08-18 16:26:23 +02:00
Irmen de Jong
53e9ad5088 better asm code for repeat loops 2020-08-18 16:02:40 +02:00
Irmen de Jong
cf6ea63fa6 forloop asm done 2020-08-18 15:29:39 +02:00
Irmen de Jong
1de0ebb7bc more forloop asm 2020-08-18 15:16:56 +02:00
Irmen de Jong
77c1376d6d proper error message for arrays that are declared too big 2020-08-18 14:47:52 +02:00
Irmen de Jong
353f1954a5 for loop codegen 2020-08-18 14:03:31 +02:00
Irmen de Jong
8bf3406cf8 gradle version 2020-08-18 00:53:14 +02:00
Irmen de Jong
936bf9a05c gradle version 2020-08-18 00:47:23 +02:00
Irmen de Jong
4487499663 more forloop codegen 2020-08-17 23:42:43 +02:00
Irmen de Jong
3976cc26a2 more forloop codegen 2020-08-17 23:19:23 +02:00
Irmen de Jong
e6ff87ecd0 upgraded to Kotlin 1.4, fixed several compilation warnings 2020-08-17 19:36:07 +02:00
Irmen de Jong
c0887b5f08 removed 'continue' statement to be able to generate more optimized loop assembly code. started with for loop optimizations 2020-08-17 19:22:29 +02:00
Irmen de Jong
f14dda4eca fix certain corruption of A register argument on asm sub call 2020-08-16 19:15:44 +02:00
Irmen de Jong
bd7f75c130 loop todos 2020-07-30 02:54:37 +02:00
Irmen de Jong
fbe3ce008b slight expression rewrite in case of certain in-place assignments, to try to get the in-place variable operand to the leftmost position 2020-07-30 01:30:21 +02:00
Irmen de Jong
7ac6c8f2d1 todo related to in-place assignment 2020-07-27 00:32:59 +02:00
Irmen de Jong
fdfbb7bdf0 improved call arguments type check 2020-07-27 00:28:48 +02:00
Irmen de Jong
1c16bbb742 tweaks for string handling as arguments 2020-07-27 00:12:27 +02:00
Irmen de Jong
9735527062 cleanup double code 2020-07-26 23:46:06 +02:00
Irmen de Jong
402827497e fix float array assignment 2020-07-26 23:32:20 +02:00
Irmen de Jong
f81aa0d867 Merge branch 'remove_aug_assign' 2020-07-26 19:23:34 +02:00
Irmen de Jong
d32a970101 partly optimize assignments so that simple increments and decrements can be done via separate statements (postincrdecr) 2020-07-26 19:22:12 +02:00
Irmen de Jong
cd651aa416 use repeat 2020-07-26 13:50:14 +02:00
Irmen de Jong
8a3189123a to reduce complexity, augmented assignment has been removed again from internal Ast and codegen for now. 2020-07-26 13:48:31 +02:00
Irmen de Jong
b37231d0f5 version 3.0 2020-07-26 01:33:02 +02:00
Irmen de Jong
3c55719bf1 finalize repeat asmgen 2020-07-26 01:32:27 +02:00
Irmen de Jong
af8279a9b9 empty for loops are removed 2020-07-25 22:54:50 +02:00
Irmen de Jong
c38508c262 introduced repeat loop. repeat-until changed to do-util. 
forever loop is gone (use repeat without iteration count).
struct literal is now same as array literal [...] to avoid parsing ambiguity with scope blocks.
 2020-07-25 16:56:34 +02:00
Irmen de Jong
b0e8738ab8 remove unused c64 resources 2020-07-25 14:47:31 +02:00
Irmen de Jong
cae480768e version is work in progress 2020-07-25 14:45:06 +02:00
Irmen de Jong
a70276c190 use indexOfFirst. Also avoid initializing a for loop variable twice in a row. 2020-07-25 14:44:24 +02:00
Irmen de Jong
0c461ffe2e removed Register expression (directly accessing cpu register) 2020-07-25 14:14:24 +02:00
Irmen de Jong
237511f2d6 v2.4 2020-07-04 18:56:47 +02:00
Irmen de Jong
cdcb652033 optimized arg passing if all args are registers 2020-07-04 18:56:30 +02:00
Irmen de Jong
71e678b382 fixed possible register subroutine arg clobbering 2020-07-04 17:05:36 +02:00
Irmen de Jong
3050156325 reverted subroutine inlining, it was a mistake 2020-07-04 01:02:36 +02:00
Irmen de Jong
4bfdbad2e4 added mandel gfx to examples 2020-07-03 23:56:36 +02:00
Irmen de Jong
06137ecdc4 v2.3 2020-07-03 23:51:27 +02:00
Irmen de Jong
d89f5b0df8 todo about fixing argclobbering 2020-07-03 23:49:17 +02:00
Irmen de Jong
b6e2b36692 refactor 2020-07-03 23:37:38 +02:00
Irmen de Jong
a6d789cfbc fixed function argument type cast bug 2020-07-03 17:24:43 +02:00
Irmen de Jong
c07907e7bd fixed missing shifts codegen 2020-07-02 21:28:48 +02:00
Irmen de Jong
7d8496c874 fixed missing shifts codegen 2020-07-02 19:18:47 +02:00
Irmen de Jong
164ac56db1 compiler error todos 2020-07-01 22:31:38 +02:00
Irmen de Jong
fdddb8ca64 slight optimization 2020-07-01 22:23:46 +02:00
Irmen de Jong
a9d4b8b0fa fixed ast modifications on node arrays, in particular function call parameter lists 2020-07-01 22:03:54 +02:00
Irmen de Jong
ec7b9f54c2 subroutine inlining is an optimizer step 2020-07-01 12:41:10 +02:00
Irmen de Jong
307558a7e7 removed some double code related to call tree 2020-06-30 20:42:55 +02:00
Irmen de Jong
febf423eab tehtriz compilation issues 2020-06-30 20:42:13 +02:00
Irmen de Jong
a999c23014 simple subroutine inlining added 2020-06-27 17:03:03 +02:00
Irmen de Jong
69f1ade595 gfx mandelbrot example added 2020-06-18 01:35:24 +02:00
Irmen de Jong
b166576e54 comments 2020-06-17 23:27:54 +02:00
Irmen de Jong
ee2ba5f398 some more optimizations for swap() function call asm code generation 2020-06-17 22:40:57 +02:00
Irmen de Jong
cb9825484d some more optimized in-array assignments codegeneration 2020-06-17 21:41:38 +02:00
Irmen de Jong
76cda82e23 v2.2 2020-06-16 01:43:44 +02:00
Irmen de Jong
37b61d9e6b v2.2 2020-06-16 01:39:11 +02:00
Irmen de Jong
52f0222a6d Got rid of old Ast transformer Api, some compiler error fixes 2020-06-16 01:25:49 +02:00
Irmen de Jong
75ccac2f2c refactoring last of old Ast modification Api 2020-06-16 00:36:02 +02:00
Irmen de Jong
5c771a91f7 refactoring last of old Ast modification Api 2020-06-14 16:56:48 +02:00
Irmen de Jong
a242ad10e6 fix double printing of sub param vardecl 2020-06-14 13:46:46 +02:00
Irmen de Jong
b5086b6a8f refactoring last of old Ast modification Api 2020-06-14 03:17:42 +02:00
Irmen de Jong
3e47dad12a clearer no modifications 2020-06-14 02:54:29 +02:00
Irmen de Jong
235610f40c refactored StatementOptimizer 2020-06-14 02:41:23 +02:00
Irmen de Jong
6b59559c65 memory address assignment codegen 2020-06-14 02:12:40 +02:00
Irmen de Jong
23e954f716 refactoring StatementOptimizer 2020-06-14 02:00:32 +02:00
Irmen de Jong
983c899cad refactor AstIdentifierChecker 2020-06-13 00:14:19 +02:00
Irmen de Jong
c2f9385965 refactor AstIdentifierChecker 2020-06-12 21:34:27 +02:00
Irmen de Jong
ceb2c9e4f8 added string value assignment, leftstr, rightstr, substr functions 2020-06-06 00:05:39 +02:00
Irmen de Jong
68a7f9c665 version 2.1 2020-06-04 23:03:18 +02:00
Irmen de Jong
ffd8d9c7c1 more assignment expression optimizations 2020-06-04 22:57:32 +02:00
Irmen de Jong
c66fc8630c fixed missing repeated constant folding in expression optimization 2020-06-04 20:22:37 +02:00
Irmen de Jong
9ca1c66f2b added some optimizations for >= 0 and <0 comparisons for integers 2020-06-04 01:43:37 +02:00
Irmen de Jong
33647a29d0 be smarter about certain implicit type casts 2020-06-03 23:55:41 +02:00
Irmen de Jong
02b12cc762 optimized swap() for byte and word vars, optimized graphics line routine 2020-06-03 23:27:50 +02:00
Irmen de Jong
3280993e2a stricter type checking in assignments (less implicit typecasts) 2020-06-02 22:36:57 +02:00
Irmen de Jong
3723c22054 fix string param type 2020-06-02 02:09:52 +02:00
Irmen de Jong
0a2c4ea0c4 improved ast printing 2020-06-02 01:51:27 +02:00
Irmen de Jong
58a83c0439 improved code gen for passing string and array types. 2020-06-02 01:44:42 +02:00
Irmen de Jong
d665489054 implemented asm for addressof-assignment 2020-06-02 00:31:56 +02:00
Irmen de Jong
9200992024 slightly improved asm gen error messages 2020-06-02 00:31:20 +02:00
Irmen de Jong
6408cc46a8 cmdrx16 github ref 2020-05-15 00:32:45 +02:00
Irmen de Jong
961bcdb7ae some more todo's noted down 2020-05-15 00:24:25 +02:00
Irmen de Jong
edee70cf31 use new api for ast mods in unused code remover 2020-05-15 00:16:53 +02:00
Irmen de Jong
1978a9815a version 2.0 2020-05-14 23:59:18 +02:00
Irmen de Jong
f5e6db9d66 big compiler speedup due to optimized scope lookups 2020-05-14 23:59:02 +02:00
Irmen de Jong
a94bc40ab0 performance todo's 2020-05-08 20:41:10 +02:00
Irmen de Jong
534b5ced8f updated the compiled examples 2020-04-10 23:36:29 +02:00
Irmen de Jong
5ebd9b54e4 added some more optimized array assignments 2020-04-10 23:30:19 +02:00
Irmen de Jong
cc4e272526 the new assignment code (once complete) really is a big enough change to bump the version to 2.0 2020-04-09 00:24:37 +02:00
Irmen de Jong
295e199bfa optimized asm output for unneeded typecasts, fixed parent node linking issues with replaceChildNode, Assignment aug_op field is now mutable to avoid having to recreate many Assignment nodes 2020-04-09 00:12:50 +02:00
Irmen de Jong
df3371b0f0 slight gfx optimizations 2020-04-08 22:53:23 +02:00
Irmen de Jong
e4fe1d2b8d attempts to optimize in-place assignments 2020-04-08 03:11:38 +02:00
Irmen de Jong
b8b9244ffa merged AddressOfInserter into StatementReorderer 2020-04-06 15:23:54 +02:00
Irmen de Jong
3be3989e1c version 2020-04-06 14:31:23 +02:00
Irmen de Jong
ed54cf680a fixed ast parent link bug in AstWalker, rewrote StatementReorderer using new API, when labels are sorted. 2020-04-06 14:31:02 +02:00
Irmen de Jong
95e76058d3 version 2020-04-03 23:55:29 +02:00
Irmen de Jong
a6bee6a860 some slight tweaks to asm for setting float value in array 2020-04-03 22:44:10 +02:00
Irmen de Jong
d22780ee44 implemented asm for lsl array values 2020-04-03 21:45:52 +02:00
Irmen de Jong
f8b0b9575d implemented asm for rol array values 2020-04-03 21:31:39 +02:00
Irmen de Jong
4274fd168e implemented asm for rol2 array values 2020-04-03 21:24:55 +02:00
Irmen de Jong
be7f5957f3 implemented asm for ror2 array values 2020-04-03 21:04:42 +02:00
Irmen de Jong
f2e5d987a9 implemented asm for ror array values 2020-04-03 00:03:42 +02:00
Irmen de Jong
f01173d8db fixed compilation of clear/set_carry() and clear/set_irqd() functions 2020-04-03 00:00:58 +02:00
Irmen de Jong
15e8e0bf6d implemented asm for lsr array values 2020-04-02 23:38:45 +02:00
Irmen de Jong
2c59cbdece fixed a crash in astchecking of array init values 2020-04-02 18:40:04 +02:00
Irmen de Jong
b73da4ed02 some more obvious optimizations for X+X and X-X 2020-03-31 23:54:01 +02:00
Irmen de Jong
267adb4612 doc 2020-03-29 03:06:51 +02:00
Irmen de Jong
05c73fa8bc version 2020-03-28 17:06:59 +01:00
Irmen de Jong
bfe9f442e6 balloon 2020-03-28 17:06:17 +01:00
Irmen de Jong
0deadb694b updated the compiled examples 2020-03-28 14:31:31 +01:00
Irmen de Jong
bed34378be doc 2020-03-28 14:24:00 +01:00
Irmen de Jong
5927cf2d43 added turtle graphics example 2020-03-28 14:17:35 +01:00
Irmen de Jong
fffe36e358 fix bresenham line 2020-03-28 13:42:24 +01:00
Irmen de Jong
fac2a2d7cb fast asm plot 2020-03-28 00:36:44 +01:00
Irmen de Jong
0af5582ca7 fix compiler crash for undefined symbol in expression 2020-03-27 23:09:46 +01:00
Irmen de Jong
582d31263c better lines and circles 2020-03-27 00:09:17 +01:00
Irmen de Jong
4108a528e1 proepr compiler error when there's no main module 2020-03-26 23:22:01 +01:00
Irmen de Jong
ab7d7c2907 fix comparison of memory expressions (this error prevented some optimizations) 2020-03-26 22:59:42 +01:00
Irmen de Jong
152888ee93 fix direcetmemoryread invalid asm 2020-03-26 22:46:05 +01:00
Irmen de Jong
22f8f4f359 fixed memory pointer access asm code for direct reads and direct assignments 2020-03-26 19:20:39 +01:00
Irmen de Jong
5f3a9e189a doc 2020-03-26 01:20:04 +01:00
Irmen de Jong
b734dc44fd fix invalid assembly for @(address)++/-- 2020-03-26 01:13:20 +01:00
Irmen de Jong
fab224f509 fix compiler crashing with invalid array initializer built from single integer 2020-03-25 01:23:54 +01:00
Irmen de Jong
2f05ebb966 bitmap lines and circles 2020-03-25 01:07:42 +01:00
Irmen de Jong
a335ba519a fix warnings about unreachable code 2020-03-24 22:37:42 +01:00
Irmen de Jong
8805693ed2 cleaned up the way return statements are added to avoid code falling through in/out of subroutines 2020-03-24 22:02:50 +01:00
Irmen de Jong
f2bb238e9b cleaned up various ast checks/mutations 2020-03-24 19:37:54 +01:00
Irmen de Jong
131fe670a4 optimized scroll routines by removing needless twin loops 2020-03-24 17:33:47 +01:00
Irmen de Jong
11e9539416 smooth scroll 2020-03-24 02:42:32 +01:00
Irmen de Jong
3881ebe429 begun skramble clone 2020-03-24 01:47:02 +01:00
Irmen de Jong
29d1b8802e whitespace 2020-03-24 00:24:51 +01:00
Irmen de Jong
bcc75732e9 optimize asm jsr+rts into jmp 2020-03-23 23:51:27 +01:00
Irmen de Jong
50a85ee6b0 attempt to optimize asm for bitshifts more. 2020-03-23 22:59:29 +01:00
Irmen de Jong
2c7424fd43 fix: datatype mismatch in optimized bitshift const value 2020-03-23 22:35:23 +01:00
Irmen de Jong
7426587c38 fix: add proper return statement type cast if needed, now also for non constant values 2020-03-23 19:49:11 +01:00
Irmen de Jong
1f39749a5e tweak bitshift asm 2020-03-23 17:35:58 +01:00
Irmen de Jong
ca63051c71 replaced todo's that aren't real todo's with regular exception 2020-03-23 13:00:44 +01:00
Irmen de Jong
6dd44aaf0d compiler main cleanup 2020-03-23 02:54:04 +01:00
Irmen de Jong
f89457ba68 fixed var initialization bug in anonymous scopes 2020-03-23 02:09:30 +01:00
Irmen de Jong
efef205fcf doc 2020-03-23 01:24:54 +01:00
Irmen de Jong
0c561d8528 fixed subroutine parameter value issue 2020-03-23 00:13:46 +01:00
Irmen de Jong
8bfa2c4c02 proper initialization of block-level global variables 2020-03-22 22:47:05 +01:00
Irmen de Jong
f0d4c3aba9 moved initialvalues to asmgen, fixed sgn bug and internal float 0.0 variable disappearing bug 2020-03-22 18:17:12 +01:00
Irmen de Jong
3a99115070 Initial variable values semantics changed: now always sets value at program (re)start (except strings/arrays). 
This may change later by introducing a compiler option to choose a strategy, perhaps.
 2020-03-22 15:12:26 +01:00
Irmen de Jong
7232134931 fix some compiler errors 2020-03-22 13:47:13 +01:00
Irmen de Jong
954e911eb3 optimized zeros array initializer 2020-03-22 02:58:51 +01:00
Irmen de Jong
63c073c93f got rid of the Simulator / AST VM 2020-03-22 02:50:34 +01:00
Irmen de Jong
78feef9d59 simplified handling of initial vardecl values in codegeneration 2020-03-22 02:45:42 +01:00
Irmen de Jong
4fbdd6d570 fix ubyte number print bug for 100-109 and 200-209 missing the tens digit 2020-03-22 01:49:05 +01:00
Irmen de Jong
4929c198ba tweak error reporting, expanded lines and circles example 2020-03-22 00:43:46 +01:00
Irmen de Jong
9409f17372 bugfixes in new optimization routines 2020-03-21 23:09:18 +01:00
Irmen de Jong
43781c02d0 tweaked ast modifications 2020-03-21 18:42:40 +01:00
Irmen de Jong
824f06e17f new var init values 2020-03-21 14:54:19 +01:00
Irmen de Jong
21dbc6da97 doc 2020-03-21 12:51:32 +01:00
Irmen de Jong
270ea54ff7 now properly compile assignment of struct literal value to struct variable (outside of vardecl) 2020-03-21 00:57:20 +01:00
Irmen de Jong
771ac7aba7 error when struct literal value element count doesn't match struct members in assignment 2020-03-20 23:14:03 +01:00
Irmen de Jong
97d36243f2 don't include the generated parser java files in git 2020-03-20 22:53:56 +01:00
Irmen de Jong
511b47bac4 fix compiler crash when initializing struct var with something other than a struct literal 2020-03-20 22:48:33 +01:00
Irmen de Jong
f265199fbe replaced typecastsAdder with version based on astwalker 2020-03-20 22:28:18 +01:00
Irmen de Jong
a191ec71a4 this is not modifying the ast 2020-03-19 23:16:58 +01:00
Irmen de Jong
82dce2dd53 added Foreverloop statement to the ast simulator 2020-03-19 22:45:27 +01:00
Irmen de Jong
29ac160811 applying new astwalker for modifications 2020-03-19 22:40:49 +01:00
Irmen de Jong
5e50ea14f8 applying new astwalker for modifications 2020-03-19 21:30:01 +01:00
Irmen de Jong
40e6091506 new astvisitor tryout 2020-03-19 00:01:57 +01:00
Irmen de Jong
0ee4d420b1 slight tweaks on the Ast, Program (the top level) is now a Node as well 2020-03-18 22:29:30 +01:00
Irmen de Jong
66acce9e8e doc 2020-03-15 01:49:16 +01:00
Irmen de Jong
6c23ae14ab ver 2020-03-15 01:37:01 +01:00
Irmen de Jong
6f000d0d26 fix datatype warning 2020-03-15 01:14:44 +01:00
Irmen de Jong
9d7eb3be5a fix error reporting of constantfolding, and number of errors printed 2020-03-15 01:10:08 +01:00
Irmen de Jong
835555171e fix function call arg type mismatch crash 2020-03-15 00:50:59 +01:00
Irmen de Jong
68ce4a1bf0 labels are now prefixed with underscore in assembly to fix undefined symbol errors from the assembler 2020-03-15 00:23:54 +01:00
Irmen de Jong
a995867deb added check for duplicate label definitions 2020-03-15 00:16:50 +01:00
Irmen de Jong
6bd99d63b4 cleanup of error reporting 2020-03-14 23:47:26 +01:00
Irmen de Jong
baf5d3041a cleanup of error reporting 2020-03-14 23:15:44 +01:00
Irmen de Jong
a326ffa00a added warning about sgn() of unsigned type 2020-03-14 21:09:34 +01:00
Irmen de Jong
d28dd92b47 refreshed examples 2020-03-14 18:11:38 +01:00
Irmen de Jong
1de328b2e8 added forever-loop and optimizer 2020-03-14 18:11:04 +01:00
Irmen de Jong
51bb902162 added bresenham and circle example 2020-03-14 17:11:10 +01:00
Irmen de Jong
4fd14f1366 doc updates 2020-03-14 15:20:04 +01:00
Irmen de Jong
91d9559f79 avoid pulling in the dbus libraries for now 2020-03-14 14:40:39 +01:00
Irmen de Jong
3245a9b157 restricted block to only directive/subroutine/vardecl/inlineasm 2020-03-14 14:20:55 +01:00
Irmen de Jong
2b28493bba simplified module grammar rules 2020-03-14 13:44:13 +01:00
Irmen de Jong
1382728bd2 warning about unreachable code after a return statement 
added some dbus experiments for future compilation service
 2020-03-14 13:12:01 +01:00
Irmen de Jong
0422ad080a added exit function to astvm simulator 2020-03-13 02:44:01 +01:00
Irmen de Jong
64d682bfde todo 2020-03-13 02:33:02 +01:00
Irmen de Jong
b182f7e693 optimizer removes unreachable code following call to exit() 2020-03-13 02:31:53 +01:00
Irmen de Jong
e6be428589 compiler warning for unreachable code following a call to exit() 2020-03-13 02:21:37 +01:00
Irmen de Jong
85c7f8314b added exit(rc) builtin function to immediately exit the program with a return code in A register 2020-03-13 02:08:18 +01:00
Irmen de Jong
796d07a7f8 fix crash in asm code generated for bitshift operation with memory address operand 2020-03-13 01:26:53 +01:00
Irmen de Jong
2af86a10b2 remove stack error comments 2020-03-13 00:52:52 +01:00
Irmen de Jong
7fbe486dff fix eval stack register X error in print_uw 2020-03-13 00:50:30 +01:00
Irmen de Jong
87e5a9859a remove autogenerated labels from vice mon list, fixes #17 2020-03-12 22:33:58 +01:00
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
224 changed files with 19578 additions and 31333 deletions
Expand all files Collapse all files

13
.gitignore vendored
View File

@ -1,8 +1,8 @@
.idea/workspace.xml
.idea/discord.xml
/build/
/dist/
/output/
build/
dist/
output/
.*cache/
*.directory
*.prg
@ -12,9 +12,9 @@
*.vice-mon-list
docs/build
out/
**/*.interp
**/*.tokens
parser/**/*.interp
parser/**/*.tokens
parser/**/*.java
*.py[cod]
*.egg
*.egg-info
@ -28,5 +28,4 @@ parsetab.py
.attach_pid*
.gradle
build/
/prog8compiler.jar

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>

1
.idea/modules.xml generated
View File

@ -2,7 +2,6 @@
<project version="4">
<component name="ProjectModuleManager">
<modules>
<module fileurl="file://$PROJECT_DIR$/DeprecatedStackVm/DeprecatedStackVm.iml" filepath="$PROJECT_DIR$/DeprecatedStackVm/DeprecatedStackVm.iml" />
<module fileurl="file://$PROJECT_DIR$/compiler/compiler.iml" filepath="$PROJECT_DIR$/compiler/compiler.iml" />
<module fileurl="file://$PROJECT_DIR$/docs/docs.iml" filepath="$PROJECT_DIR$/docs/docs.iml" />
<module fileurl="file://$PROJECT_DIR$/examples/examples.iml" filepath="$PROJECT_DIR$/examples/examples.iml" />

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

@ -4,8 +4,8 @@ sudo: false
# dist: xenial
before_install:
- chmod +x gradlew
- chmod +x ./gradlew
script:
- gradle test
- ./gradlew test

10
DeprecatedStackVm/DeprecatedStackVm.iml
View File

@ -1,10 +0,0 @@
<?xml version="1.0" encoding="UTF-8"?>
<module type="JAVA_MODULE" version="4">
<component name="NewModuleRootManager" inherit-compiler-output="true">
<exclude-output />
<content url="file://$MODULE_DIR$" />
<orderEntry type="inheritedJdk" />
<orderEntry type="sourceFolder" forTests="false" />
<orderEntry type="library" name="KotlinJavaRuntime" level="project" />
</component>
</module>

2106
DeprecatedStackVm/src/compiler/Compiler.kt
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File diff suppressed because it is too large Load Diff

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

@ -1,51 +0,0 @@
package 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:"
}
}

548
DeprecatedStackVm/src/compiler/intermediate/IntermediateProgram.kt
View File

@ -1,548 +0,0 @@
package compiler.intermediate
import prog8.ast.antlr.escape
import prog8.ast.base.*
import prog8.ast.expressions.NumericLiteralValue
import prog8.ast.expressions.ReferenceLiteralValue
import prog8.ast.statements.StructDecl
import prog8.ast.statements.VarDecl
import prog8.ast.statements.ZeropageWish
import prog8.compiler.CompilerException
import prog8.compiler.HeapValues
import prog8.compiler.Zeropage
import prog8.compiler.ZeropageDepletedError
import prog8.vm.RuntimeValue
import java.io.PrintStream
import java.nio.file.Path
class IntermediateProgram(val name: String, var loadAddress: Int, val heap: HeapValues, val source: Path) {
class VariableParameters (val zp: ZeropageWish, val memberOfStruct: StructDecl?)
class Variable(val scopedname: String, val value: RuntimeValue, val params: VariableParameters)
class ProgramBlock(val name: String,
var address: Int?,
val instructions: MutableList<Instruction> = mutableListOf(),
val variables: MutableList<Variable> = mutableListOf(),
val memoryPointers: MutableMap<String, Pair<Int, DataType>> = mutableMapOf(),
val labels: MutableMap<String, Instruction> = mutableMapOf(), // names are fully scoped
val force_output: Boolean)
val allocatedZeropageVariables = mutableMapOf<String, Pair<Int, DataType>>()
val blocks = mutableListOf<ProgramBlock>()
val memory = mutableMapOf<Int, List<RuntimeValue>>()
private lateinit var currentBlock: ProgramBlock
fun allocateZeropage(zeropage: Zeropage) { // TODO not used anymore???
// 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.params.zp==ZeropageWish.REQUIRE_ZEROPAGE || it.params.zp==ZeropageWish.PREFER_ZEROPAGE }
if (zpVariables.isNotEmpty()) {
for (variable in zpVariables) {
if(variable.params.zp==ZeropageWish.NOT_IN_ZEROPAGE || variable.params.memberOfStruct!=null)
throw CompilerException("zp conflict")
try {
val address = zeropage.allocate(variable.scopedname, variable.value.type, null)
allocatedZeropageVariables[variable.scopedname] = Pair(address, variable.value.type)
} catch (x: ZeropageDepletedError) {
printWarning(x.toString() + " variable ${variable.scopedname} 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 -> {
// var decls that are defined inside of a StructDecl are skipped in the output
// because every occurrence of the members will have a separate mangled vardecl for that occurrence
if(decl.parent is StructDecl)
return
val valueparams = VariableParameters(decl.zeropage, decl.struct)
val value = when(decl.datatype) {
in NumericDatatypes -> {
RuntimeValue(decl.datatype, (decl.value as NumericLiteralValue).number)
}
in StringDatatypes -> {
val litval = (decl.value as ReferenceLiteralValue)
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? ReferenceLiteralValue)
if(litval!=null && litval.heapId==null)
throw CompilerException("array should already be in the heap")
if(litval!=null){
RuntimeValue(decl.datatype, heapId = litval.heapId)
} else {
throw CompilerException("initialization value expected")
}
}
DataType.STRUCT -> {
// struct variables have been flattened already
return
}
else -> throw CompilerException("weird datatype")
}
currentBlock.variables.add(Variable(scopedname, value, valueparams))
}
VarDeclType.MEMORY -> {
// note that constants are all folded away, but assembly code may still refer to them
val lv = decl.value as NumericLiteralValue
if(lv.type!= DataType.UWORD && lv.type!= DataType.UBYTE)
throw CompilerException("expected integer memory address $lv")
currentBlock.memoryPointers[scopedname] = Pair(lv.number.toInt(), decl.datatype)
}
VarDeclType.CONST -> {
// note that constants are all folded away, but assembly code may still refer to them (if their integers)
// floating point constants are not generated at all!!
val lv = decl.value as NumericLiteralValue
if(lv.type in IntegerDatatypes)
currentBlock.memoryPointers[scopedname] = Pair(lv.number.toInt(), decl.datatype)
}
}
}
fun instr(opcode: Opcode, arg: RuntimeValue? = null, arg2: RuntimeValue? = null, callLabel: String? = null, callLabel2: String? = null) {
currentBlock.instructions.add(Instruction(opcode, arg, arg2, callLabel, callLabel2))
}
fun label(labelname: String, asmProc: Boolean=false) {
val instr = LabelInstr(labelname, asmProc)
currentBlock.instructions.add(instr)
currentBlock.labels[labelname] = instr
}
fun line(position: Position) {
currentBlock.instructions.add(Instruction(Opcode.LINE, callLabel = "${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'")
writeMemory(out)
writeHeap(out)
for(blk in blocks) {
writeBlock(out, blk, embeddedLabels)
}
}
private fun writeHeap(out: PrintStream) {
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")
}
private fun writeBlock(out: PrintStream, blk: ProgramBlock, embeddedLabels: Boolean) {
out.println("\n%block ${blk.name} ${blk.address?.toString(16) ?: ""}")
out.println("%variables")
for (variable in blk.variables) {
if(variable.params.zp==ZeropageWish.REQUIRE_ZEROPAGE)
throw CompilerException("zp conflict")
val valuestr = variable.value.toString()
val struct = if(variable.params.memberOfStruct==null) "" else "struct=${variable.params.memberOfStruct.name}"
out.println("${variable.scopedname} ${variable.value.type.name.toLowerCase()} $valuestr zp=${variable.params.zp} s=$struct")
}
out.println("%end_variables")
out.println("%memorypointers")
for (iconst in blk.memoryPointers) {
out.println("${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")
}
private fun writeMemory(out: PrintStream) {
out.println("%memory")
if (memory.isNotEmpty())
TODO("add support for writing/reading initial memory values")
out.println("%end_memory")
}
}

291
DeprecatedStackVm/src/compiler/intermediate/Opcode.kt
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@ -1,291 +0,0 @@
package 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
)

761
DeprecatedStackVm/src/compiler/target/c64/codegen/AsmGen.kt
View File

@ -1,761 +0,0 @@
package compiler.target.c64.codegen
// 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.ast.statements.ZeropageWish
import prog8.compiler.*
import prog8.compiler.intermediate.Instruction
import prog8.compiler.intermediate.IntermediateProgram
import prog8.compiler.intermediate.LabelInstr
import prog8.compiler.intermediate.Opcode
import prog8.compiler.target.c64.AssemblyProgram
import prog8.compiler.target.c64.MachineDefinition
import prog8.compiler.target.c64.Petscii
import prog8.vm.RuntimeValue
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 $into
"""
class AsmGen(private val options: CompilationOptions, private val program: IntermediateProgram,
private val heap: HeapValues, private val zeropage: Zeropage) {
private val assemblyLines = mutableListOf<String>()
private lateinit var block: IntermediateProgram.ProgramBlock
init {
// Convert invalid label names (such as "<anon-1>") to something that's allowed.
val newblocks = mutableListOf<IntermediateProgram.ProgramBlock>()
for(block in program.blocks) {
val newvars = block.variables.map { IntermediateProgram.Variable(symname(it.scopedname, block), it.value, it.params) }.toMutableList()
val newlabels = block.labels.map { symname(it.key, block) to it.value}.toMap().toMutableMap()
val newinstructions = block.instructions.asSequence().map {
when {
it is LabelInstr -> LabelInstr(symname(it.name, block), it.asmProc)
it.opcode == Opcode.INLINE_ASSEMBLY -> it
else ->
Instruction(it.opcode, it.arg, it.arg2,
callLabel = if (it.callLabel != null) symname(it.callLabel, block) else null,
callLabel2 = if (it.callLabel2 != null) symname(it.callLabel2, block) else null)
}
}.toMutableList()
val newMempointers = block.memoryPointers.map { symname(it.key, block) to it.value }.toMap().toMutableMap()
val newblock = IntermediateProgram.ProgramBlock(
block.name,
block.address,
newinstructions,
newvars,
newMempointers,
newlabels,
force_output = block.force_output)
newblocks.add(newblock)
}
program.blocks.clear()
program.blocks.addAll(newblocks)
val newAllocatedZp = program.allocatedZeropageVariables.map { symname(it.key, null) to it.value}
program.allocatedZeropageVariables.clear()
program.allocatedZeropageVariables.putAll(newAllocatedZp)
// make a list of all const floats that are used
for(block in program.blocks) {
for(ins in block.instructions.filter{it.arg?.type== DataType.FLOAT}) {
val float = ins.arg!!.numericValue().toDouble()
if(float !in globalFloatConsts)
globalFloatConsts[float] = "prog8_const_float_${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: MachineDefinition.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)
MachineDefinition.BASIC_LOAD_ADDRESS else MachineDefinition.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(MachineDefinition.Mflpt5.fromNumber(flt.key))
out("${flt.value}\t.byte $floatFill ; float ${flt.key}")
}
}
private fun block2asm(blk: IntermediateProgram.ProgramBlock) {
block = blk
out("\n\n; ---- block: '${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("* = ${block.address?.toHex()}")
}
// deal with zeropage variables
for(variable in blk.variables) {
val sym = symname(blk.name+"."+variable.scopedname, null)
val zpVar = program.allocatedZeropageVariables[sym]
if(zpVar==null) {
// This var is not on the ZP yet. Attempt to move it there (if it's not a float, those take up too much space)
if(variable.params.zp != ZeropageWish.NOT_IN_ZEROPAGE &&
variable.value.type in zeropage.allowedDatatypes
&& variable.value.type != DataType.FLOAT) {
try {
val address = zeropage.allocate(sym, variable.value.type, null)
out("${variable.scopedname} = $address\t; auto zp ${variable.value.type}")
// make sure we add the var to the set of zpvars for this block
program.allocatedZeropageVariables[sym] = Pair(address, variable.value.type)
} catch (x: ZeropageDepletedError) {
// leave it as it is.
}
}
}
else {
// it was already allocated on the zp
out("${variable.scopedname} = ${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} = ${m.value.first.toHex()}")
}
}
private fun vardecls2asm(block: IntermediateProgram.ProgramBlock) {
val uniqueNames = block.variables.map { it.scopedname }.toSet()
if (uniqueNames.size != block.variables.size)
throw AssemblyError("not all variables have unique names")
// these are the non-zeropage variables.
// first get all the flattened struct members, they MUST remain in order
out("; flattened struct members")
val (structMembers, normalVars) = block.variables.partition { it.params.memberOfStruct!=null }
structMembers.forEach { vardecl2asm(it.scopedname, it.value, it.params) }
// sort the other variables by type
out("; other variables sorted by type")
val sortedVars = normalVars.sortedBy { it.value.type }
for (variable in sortedVars) {
val sym = symname(block.name + "." + variable.scopedname, null)
if(sym in program.allocatedZeropageVariables)
continue // skip the ones that already belong in the zero page
vardecl2asm(variable.scopedname, variable.value, variable.params)
}
}
private fun vardecl2asm(varname: String, value: RuntimeValue, parameters: IntermediateProgram.VariableParameters) {
when (value.type) {
DataType.UBYTE -> out("$varname\t.byte 0")
DataType.BYTE -> out("$varname\t.char 0")
DataType.UWORD -> out("$varname\t.word 0")
DataType.WORD -> out("$varname\t.sint 0")
DataType.FLOAT -> out("$varname\t.byte 0,0,0,0,0 ; float")
DataType.STR, DataType.STR_S -> {
val rawStr = heap.get(value.heapId!!).str!!
val bytes = encodeStr(rawStr, value.type).map { "$" + it.toString(16).padStart(2, '0') }
out("$varname\t; ${value.type} \"${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(value)
if (data.size <= 16)
out("$varname\t.byte ${data.joinToString()}")
else {
out(varname)
for (chunk in data.chunked(16))
out(" .byte " + chunk.joinToString())
}
}
DataType.ARRAY_B -> {
// signed integer byte arraysize
val data = makeArrayFillDataSigned(value)
if (data.size <= 16)
out("$varname\t.char ${data.joinToString()}")
else {
out(varname)
for (chunk in data.chunked(16))
out(" .char " + chunk.joinToString())
}
}
DataType.ARRAY_UW -> {
// unsigned word arraysize
val data = makeArrayFillDataUnsigned(value)
if (data.size <= 16)
out("$varname\t.word ${data.joinToString()}")
else {
out(varname)
for (chunk in data.chunked(16))
out(" .word " + chunk.joinToString())
}
}
DataType.ARRAY_W -> {
// signed word arraysize
val data = makeArrayFillDataSigned(value)
if (data.size <= 16)
out("$varname\t.sint ${data.joinToString()}")
else {
out(varname)
for (chunk in data.chunked(16))
out(" .sint " + chunk.joinToString())
}
}
DataType.ARRAY_F -> {
// float arraysize
val array = heap.get(value.heapId!!).doubleArray!!
val floatFills = array.map { makeFloatFill(MachineDefinition.Mflpt5.fromNumber(it)) }
out(varname)
for (f in array.zip(floatFills))
out(" .byte ${f.second} ; float ${f.first}")
}
DataType.STRUCT -> throw AssemblyError("vars of type STRUCT should have been removed because flattened")
}
}
private fun encodeStr(str: String, dt: DataType): List<Short> {
return when(dt) {
DataType.STR -> {
val bytes = Petscii.encodePetscii(str, true)
bytes.plus(0)
}
DataType.STR_S -> {
val bytes = Petscii.encodeScreencode(str, true)
bytes.plus(0)
}
else -> throw AssemblyError("invalid str type")
}
}
private fun makeArrayFillDataUnsigned(value: RuntimeValue): List<String> {
val array = heap.get(value.heapId!!).array!!
return when {
value.type== DataType.ARRAY_UB ->
// byte array can never contain pointer-to types, so treat values as all integers
array.map { "$"+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.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 * MachineDefinition.Mflpt5.MemorySize})
ldy #>($variable+${index * MachineDefinition.Mflpt5.MemorySize})
jsr c64flt.inc_var_f
""")
Opcode.DEC_INDEXED_VAR_FLOAT -> AsmFragment(
"""
lda #<($variable+${index * MachineDefinition.Mflpt5.MemorySize})
ldy #>($variable+${index * MachineDefinition.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 ${MachineDefinition.C64Zeropage.SCRATCH_B1} |"
val restoreX = " | ldx ${MachineDefinition.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)
}

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DeprecatedStackVm/src/compiler/target/c64/codegen/AsmPatterns.kt
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package compiler.target.c64.codegen
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.target.c64.MachineDefinition.C64Zeropage
import prog8.compiler.target.c64.MachineDefinition.ESTACK_HI_HEX
import prog8.compiler.target.c64.MachineDefinition.ESTACK_HI_PLUS1_HEX
import prog8.compiler.target.c64.MachineDefinition.ESTACK_LO_HEX
import prog8.compiler.target.c64.MachineDefinition.ESTACK_LO_PLUS1_HEX
import prog8.compiler.target.c64.MachineDefinition.ESTACK_LO_PLUS2_HEX
import prog8.compiler.toHex
import prog8.vm.stackvm.Syscall
import prog8.vm.stackvm.syscallsForStackVm
// note: see https://wiki.nesdev.com/w/index.php/6502_assembly_optimisations
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.DISCARD_FLOAT -> " inx | inx | inx"
Opcode.DUP_B -> {
" lda $ESTACK_LO_PLUS1_HEX,x | sta $ESTACK_LO_HEX,x | dex | ;DUP_B "
}
Opcode.DUP_W -> {
" lda $ESTACK_LO_PLUS1_HEX,x | sta $ESTACK_LO_HEX,x | lda $ESTACK_HI_PLUS1_HEX,x | sta $ESTACK_HI_HEX,x | dex "
}
Opcode.CMP_B, Opcode.CMP_UB -> {
" inx | lda $ESTACK_LO_HEX,x | cmp #${ins.arg!!.integerValue().toHex()} | ;CMP_B "
}
Opcode.CMP_W, Opcode.CMP_UW -> {
"""
inx
lda $ESTACK_HI_HEX,x
cmp #>${ins.arg!!.integerValue().toHex()}
bne +
lda $ESTACK_LO_HEX,x
cmp #<${ins.arg.integerValue().toHex()}
; bne + not necessary?
; lda #0 not necessary?
+
"""
}
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 $ESTACK_LO_HEX,x | dex"
}
Opcode.PUSH_WORD -> {
val value = hexVal(ins)
" lda #<$value | sta $ESTACK_LO_HEX,x | lda #>$value | sta $ESTACK_HI_HEX,x | dex"
}
Opcode.PUSH_FLOAT -> {
val floatConst = getFloatConst(ins.arg!!)
" lda #<$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_HEX,x | dex"
"Y" -> " tya | sta $ESTACK_LO_HEX,x | dex"
else -> " lda ${ins.callLabel} | sta $ESTACK_LO_HEX,x | dex"
}
}
Opcode.PUSH_VAR_WORD -> {
" lda ${ins.callLabel} | sta $ESTACK_LO_HEX,x | lda ${ins.callLabel}+1 | sta $ESTACK_HI_HEX,x | dex"
}
Opcode.PUSH_VAR_FLOAT -> " lda #<${ins.callLabel} | ldy #>${ins.callLabel}| jsr c64flt.push_float"
Opcode.PUSH_MEM_B, Opcode.PUSH_MEM_UB -> {
"""
lda ${hexVal(ins)}
sta $ESTACK_LO_HEX,x
dex
"""
}
Opcode.PUSH_MEM_W, Opcode.PUSH_MEM_UW -> {
"""
lda ${hexVal(ins)}
sta $ESTACK_LO_HEX,x
lda ${hexValPlusOne(ins)}
sta $ESTACK_HI_HEX,x
dex
"""
}
Opcode.PUSH_MEM_FLOAT -> {
" lda #<${hexVal(ins)} | ldy #>${hexVal(ins)}| jsr c64flt.push_float"
}
Opcode.PUSH_MEMREAD -> {
"""
lda $ESTACK_LO_PLUS1_HEX,x
sta (+) +1
lda $ESTACK_HI_PLUS1_HEX,x
sta (+) +2
+ lda 65535 ; modified
sta $ESTACK_LO_PLUS1_HEX,x
"""
}
Opcode.PUSH_REGAY_WORD -> {
" sta $ESTACK_LO_HEX,x | tya | sta $ESTACK_HI_HEX,x | dex "
}
Opcode.PUSH_ADDR_HEAPVAR -> {
" lda #<${ins.callLabel} | sta $ESTACK_LO_HEX,x | lda #>${ins.callLabel} | sta $ESTACK_HI_HEX,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_HEX,x | ldy $ESTACK_HI_HEX,x "
}
Opcode.READ_INDEXED_VAR_BYTE -> {
"""
ldy $ESTACK_LO_PLUS1_HEX,x
lda ${ins.callLabel},y
sta $ESTACK_LO_PLUS1_HEX,x
"""
}
Opcode.READ_INDEXED_VAR_WORD -> {
"""
lda $ESTACK_LO_PLUS1_HEX,x
asl a
tay
lda ${ins.callLabel},y
sta $ESTACK_LO_PLUS1_HEX,x
lda ${ins.callLabel}+1,y
sta $ESTACK_HI_PLUS1_HEX,x
"""
}
Opcode.READ_INDEXED_VAR_FLOAT -> {
"""
lda #<${ins.callLabel}
ldy #>${ins.callLabel}
jsr c64flt.push_float_from_indexed_var
"""
}
Opcode.WRITE_INDEXED_VAR_BYTE -> {
"""
inx
ldy $ESTACK_LO_HEX,x
inx
lda $ESTACK_LO_HEX,x
sta ${ins.callLabel},y
"""
}
Opcode.WRITE_INDEXED_VAR_WORD -> {
"""
inx
lda $ESTACK_LO_HEX,x
asl a
tay
inx
lda $ESTACK_LO_HEX,x
sta ${ins.callLabel},y
lda $ESTACK_HI_HEX,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_HEX,x
sta ${hexVal(ins)}
"""
}
Opcode.POP_MEM_WORD -> {
"""
inx
lda $ESTACK_LO_HEX,x
sta ${hexVal(ins)}
lda $ESTACK_HI_HEX,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_HEX,x
sta (+) +1
lda $ESTACK_HI_HEX,x
sta (+) +2
inx
lda $ESTACK_LO_HEX,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_HEX,x"
"Y" -> " inx | ldy $ESTACK_LO_HEX,x"
else -> " inx | lda $ESTACK_LO_HEX,x | sta ${ins.callLabel}"
}
}
Opcode.POP_VAR_WORD -> {
" inx | lda $ESTACK_LO_HEX,x | ldy $ESTACK_HI_HEX,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_HEX,x
sta (+) +1
lda $ESTACK_HI_HEX,x
sta (+) +2
+ inc 65535 ; modified
"""
}
Opcode.POP_DEC_MEMORY -> {
"""
inx
lda $ESTACK_LO_HEX,x
sta (+) +1
lda $ESTACK_HI_HEX,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_HEX,x | tax | inc ${ins.callLabel},x | pla | tax"
Opcode.DEC_INDEXED_VAR_B, Opcode.DEC_INDEXED_VAR_UB -> " inx | txa | pha | lda $ESTACK_LO_HEX,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_PLUS1_HEX,x
eor #255
sta $ESTACK_LO_PLUS1_HEX,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_HEX,x
beq $label
"""
}
Opcode.JZW -> {
val label = ins.callLabel ?: hexVal(ins)
"""
inx
lda $ESTACK_LO_HEX,x
beq $label
lda $ESTACK_HI_HEX,x
beq $label
"""
}
Opcode.JNZ -> {
val label = ins.callLabel ?: hexVal(ins)
"""
inx
lda $ESTACK_LO_HEX,x
bne $label
"""
}
Opcode.JNZW -> {
val label = ins.callLabel ?: hexVal(ins)
"""
inx
lda $ESTACK_LO_HEX,x
bne $label
lda $ESTACK_HI_HEX,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_float2ub"
Opcode.CAST_F_TO_B -> " jsr c64flt.stack_float2b"
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_PLUS1_HEX,x" // clear the msb
Opcode.CAST_B_TO_UW, Opcode.CAST_B_TO_W -> " lda $ESTACK_LO_PLUS1_HEX,x | ${signExtendA("$ESTACK_HI_PLUS1_HEX,x")}" // sign extend the lsb
Opcode.MSB -> " lda $ESTACK_HI_PLUS1_HEX,x | sta $ESTACK_LO_PLUS1_HEX,x"
Opcode.MKWORD -> " inx | lda $ESTACK_LO_HEX,x | sta $ESTACK_HI_PLUS1_HEX,x "
Opcode.ADD_UB, Opcode.ADD_B -> { // TODO inline better (pattern with more opcodes)
"""
lda $ESTACK_LO_PLUS2_HEX,x
clc
adc $ESTACK_LO_PLUS1_HEX,x
inx
sta $ESTACK_LO_PLUS1_HEX,x
"""
}
Opcode.SUB_UB, Opcode.SUB_B -> { // TODO inline better (pattern with more opcodes)
"""
lda $ESTACK_LO_PLUS2_HEX,x
sec
sbc $ESTACK_LO_PLUS1_HEX,x
inx
sta $ESTACK_LO_PLUS1_HEX,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_PLUS1_HEX,x"
Opcode.SHIFTEDL_WORD -> " asl $ESTACK_LO_PLUS1_HEX,x | rol $ESTACK_HI_PLUS1_HEX,x"
Opcode.SHIFTEDR_SBYTE -> " lda $ESTACK_LO_PLUS1_HEX,x | asl a | ror $ESTACK_LO_PLUS1_HEX,x"
Opcode.SHIFTEDR_UBYTE -> " lsr $ESTACK_LO_PLUS1_HEX,x"
Opcode.SHIFTEDR_SWORD -> " lda $ESTACK_HI_PLUS1_HEX,x | asl a | ror $ESTACK_HI_PLUS1_HEX,x | ror $ESTACK_LO_PLUS1_HEX,x"
Opcode.SHIFTEDR_UWORD -> " lsr $ESTACK_HI_PLUS1_HEX,x | ror $ESTACK_LO_PLUS1_HEX,x"
else -> null
}
}

47
DeprecatedStackVm/src/prog8/vm/stackvm/Main.kt
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@ -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()
}
}

302
DeprecatedStackVm/src/prog8/vm/stackvm/Program.kt
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@ -1,302 +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.compiler.HeapValues
import prog8.compiler.IntegerOrAddressOf
import prog8.compiler.intermediate.Instruction
import prog8.compiler.intermediate.LabelInstr
import prog8.compiler.intermediate.Opcode
import prog8.compiler.intermediate.opcodesWithVarArgument
import prog8.vm.RuntimeValue
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).substringBefore(' ').toShort(16))// TODO process ZP and struct info?
DataType.BYTE -> RuntimeValue(DataType.BYTE, valueStr.substring(2).substringBefore(' ').toShort(16))// TODO process ZP and struct info?
DataType.UWORD -> RuntimeValue(DataType.UWORD, valueStr.substring(3).substringBefore(' ').toInt(16))// TODO process ZP and struct info?
DataType.WORD -> RuntimeValue(DataType.WORD, valueStr.substring(2).substringBefore(' ').toInt(16))// TODO process ZP and struct info?
DataType.FLOAT -> RuntimeValue(DataType.FLOAT, valueStr.substring(2).substringBefore(' ').toDouble())// TODO process ZP and struct info?
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).substringBefore(' ').toInt() // TODO process ZP and struct info?
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).substringBefore(' ').toInt() // TODO process ZP and struct info?
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
}
}
}
}
}

2439
DeprecatedStackVm/src/prog8/vm/stackvm/StackVm.kt
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1269
DeprecatedStackVm/test/StackVMOpcodeTests.kt
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75
README.md
View File

@ -1,23 +1,33 @@
[![saythanks](https://img.shields.io/badge/say-thanks-ff69b4.svg)](https://saythanks.io/to/irmen)
[![Build Status](https://travis-ci.org/irmen/prog8.svg?branch=master)](https://travis-ci.org/irmen/prog8)
[![Documentation](https://readthedocs.org/projects/prog8/badge/?version=latest)](https://prog8.readthedocs.io/)
Prog8 - Structured Programming Language for 8-bit 6502/6510 microprocessors
===========================================================================
Prog8 - Structured Programming Language for 8-bit 6502/65c02 microprocessors
============================================================================
*Written by Irmen de Jong (irmen@razorvine.net)*
*Software license: GNU GPL 3.0, see file LICENSE*
This is a structured programming language for the 8-bit 6502/6510 microprocessor from the late 1970's and 1980's
This is a structured programming language for the 8-bit 6502/6510/65c02 microprocessor from the late 1970's and 1980's
as used in many home computers from that era. It is a medium to low level programming language,
which aims to provide many conveniences over raw assembly code (even when using a macro assembler):
which aims to provide many conveniences over raw assembly code (even when using a macro assembler).
- reduction of source code length
Documentation
-------------
Full documentation (syntax reference, how to use the language and the compiler, etc.) can be found at:
https://prog8.readthedocs.io/
What use Prog8 provide?
-----------------------
- reduction of source code length over raw assembly
- modularity, symbol scoping, subroutines
- 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
- subroutines with an input- and output parameter signature
- constant folding in expressions
- conditional branches
- 'when' statement to provide a concise jump table alternative to if/elseif chains
@ -28,26 +38,24 @@ which aims to provide many conveniences over raw assembly code (even when using
- 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:
*Rapid edit-compile-run-debug cycle:*
- use modern PC to work on
- quick compilation times (seconds)
- option to automatically run the program in the Vice emulator
- use a modern PC to do the work on
- very quick compilation times
- can automatically run the program in the Vice emulator after succesful compilation
- 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.
*Two supported compiler targets* (contributions to improve these or to add support for other machines are welcome!):
Documentation/manual
--------------------
See https://prog8.readthedocs.io/
- "c64": Commodore-64 (6510 CPU = almost a 6502) premium support.
- "cx16": [CommanderX16](https://www.commanderx16.com) (65c02 CPU) experimental support.
Required tools
--------------
Additional 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.
@ -57,8 +65,9 @@ A **Java runtime (jre or jdk), version 8 or newer** is required to run a prepac
If you want to build it from source, you'll need a Java SDK + Kotlin 1.3.x SDK (or for instance,
IntelliJ IDEA with the Kotlin plugin).
It's handy to have a C-64 emulator or a real C-64 to run the programs on. The compiler assumes the presence
of the [Vice emulator](http://vice-emu.sourceforge.net/)
It's handy to have an emulator (or a real machine perhaps!) to run the programs on. The compiler assumes the presence
of the [Vice emulator](http://vice-emu.sourceforge.net/) for the C64 target,
and the [x16emu emulator](https://github.com/commanderx16/x16-emulator) for the CommanderX16 target.
Example code
@ -66,7 +75,7 @@ Example code
This code calculates prime numbers using the Sieve of Eratosthenes algorithm::
%import c64utils
%import c64textio
%zeropage basicsafe
main {
@ -75,35 +84,33 @@ This code calculates prime numbers using the Sieve of Eratosthenes algorithm::
ubyte candidate_prime = 2
sub start() {
memset(sieve, 256, false)
c64scr.print("prime numbers up to 255:\n\n")
memset(sieve, 256, false) ; clear the sieve
txt.print("prime numbers up to 255:\n\n")
ubyte amount=0
while true {
repeat {
ubyte prime = find_next_prime()
if prime==0
break
c64scr.print_ub(prime)
c64scr.print(", ")
txt.print_ub(prime)
txt.print(", ")
amount++
}
c64.CHROUT('\n')
c64scr.print("number of primes (expected 54): ")
c64scr.print_ub(amount)
txt.print("number of primes (expected 54): ")
txt.print_ub(amount)
c64.CHROUT('\n')
}
sub find_next_prime() -> ubyte {
while sieve[candidate_prime] {
candidate_prime++
if candidate_prime==0
return 0
return 0 ; we wrapped; no more primes available
}
; found next one, mark the multiples and return it.
sieve[candidate_prime] = true
uword multiple = candidate_prime
while multiple < len(sieve) {
sieve[lsb(multiple)] = true
multiple += candidate_prime

36
compiler/build.gradle
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@ -1,48 +1,52 @@
buildscript {
dependencies {
classpath "org.jetbrains.kotlin:kotlin-gradle-plugin:$kotlinVersion"
classpath "org.jetbrains.kotlin:kotlin-gradle-plugin:1.4.0"
}
}
plugins {
// id "org.jetbrains.kotlin.jvm" version $kotlinVersion
// id "org.jetbrains.kotlin.jvm" version "1.4.0"
id 'application'
id 'org.jetbrains.dokka' version "0.9.18"
id 'com.github.johnrengelman.shadow' version '5.1.0'
id 'com.github.johnrengelman.shadow' version '5.2.0'
id 'java'
}
apply plugin: "kotlin"
apply plugin: "java"
targetCompatibility = 1.8
sourceCompatibility = 1.8
repositories {
mavenLocal()
mavenCentral()
jcenter()
maven { url "https://dl.bintray.com/orangy/maven/" }
}
def prog8version = rootProject.file('compiler/res/version.txt').text.trim()
dependencies {
implementation project(':parser')
implementation "org.jetbrains.kotlin:kotlin-stdlib-jdk8:$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 "com.github.hypfvieh:dbus-java:3.2.0"
implementation project(':parser')
testImplementation "org.jetbrains.kotlin:kotlin-test-junit5:$kotlinVersion"
testImplementation "org.jetbrains.kotlin:kotlin-test-junit5"
testImplementation 'org.junit.jupiter:junit-jupiter-api:5.3.2'
testImplementation 'org.hamcrest:hamcrest-junit:2.0.0.0'
testRuntimeOnly 'org.junit.jupiter:junit-jupiter-engine:5.3.2'
}
compileKotlin {
kotlinOptions {
jvmTarget = "1.8"
verbose = true
// verbose = true
// freeCompilerArgs += "-XXLanguage:+NewInference"
}
}
@ -82,8 +86,8 @@ artifacts {
shadowJar {
baseName = 'prog8compiler'
version = prog8version
archiveBaseName = 'prog8compiler'
archiveVersion = prog8version
// minimize()
}
@ -97,7 +101,7 @@ test {
// Show test results.
testLogging {
events "passed", "skipped", "failed"
events "skipped", "failed"
}
}
@ -106,3 +110,7 @@ dokka {
outputFormat = 'html'
outputDirectory = "$buildDir/kdoc"
}
task wrapper(type: Wrapper) {
gradleVersion = '6.1.1'
}

3
compiler/compiler.iml
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@ -11,8 +11,9 @@
<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>

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753
compiler/res/prog8lib/c64floats.asm Normal file
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@ -0,0 +1,753 @@
; --- 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 P8ZP_SCRATCH_REG_X
sta P8ZP_SCRATCH_W2
sty P8ZP_SCRATCH_W2+1
ldy P8ZP_SCRATCH_B1
lda #0
jsr GIVAYF
_fac_to_mem ldx P8ZP_SCRATCH_W2
ldy P8ZP_SCRATCH_W2+1
jsr MOVMF
ldx P8ZP_SCRATCH_REG_X
rts
.pend
b2float .proc
; -- convert byte in SCRATCH_ZPB1 to float at address A/Y
; clobbers A, Y
stx P8ZP_SCRATCH_REG_X
sta P8ZP_SCRATCH_W2
sty P8ZP_SCRATCH_W2+1
lda P8ZP_SCRATCH_B1
jsr FREADSA
jmp ub2float._fac_to_mem
.pend
uw2float .proc
; -- convert uword in SCRATCH_ZPWORD1 to float at address A/Y
stx P8ZP_SCRATCH_REG_X
sta P8ZP_SCRATCH_W2
sty P8ZP_SCRATCH_W2+1
lda P8ZP_SCRATCH_W1
ldy P8ZP_SCRATCH_W1+1
jsr GIVUAYFAY
jmp ub2float._fac_to_mem
.pend
w2float .proc
; -- convert word in SCRATCH_ZPWORD1 to float at address A/Y
stx P8ZP_SCRATCH_REG_X
sta P8ZP_SCRATCH_W2
sty P8ZP_SCRATCH_W2+1
ldy P8ZP_SCRATCH_W1
lda P8ZP_SCRATCH_W1+1
jsr GIVAYF
jmp ub2float._fac_to_mem
.pend
stack_b2float .proc
; -- b2float operating on the stack
inx
lda P8ESTACK_LO,x
stx P8ZP_SCRATCH_REG_X
jsr FREADSA
jmp push_fac1_as_result
.pend
stack_w2float .proc
; -- w2float operating on the stack
inx
ldy P8ESTACK_LO,x
lda P8ESTACK_HI,x
stx P8ZP_SCRATCH_REG_X
jsr GIVAYF
jmp push_fac1_as_result
.pend
stack_ub2float .proc
; -- ub2float operating on the stack
inx
lda P8ESTACK_LO,x
stx P8ZP_SCRATCH_REG_X
tay
lda #0
jsr GIVAYF
jmp push_fac1_as_result
.pend
stack_uw2float .proc
; -- uw2float operating on the stack
inx
lda P8ESTACK_LO,x
ldy P8ESTACK_HI,x
stx P8ZP_SCRATCH_REG_X
jsr GIVUAYFAY
jmp push_fac1_as_result
.pend
stack_float2w .proc ; also used for float2b
jsr pop_float_fac1
stx P8ZP_SCRATCH_REG_X
jsr AYINT
ldx P8ZP_SCRATCH_REG_X
lda $64
sta P8ESTACK_HI,x
lda $65
sta P8ESTACK_LO,x
dex
rts
.pend
stack_float2uw .proc ; also used for float2ub
jsr pop_float_fac1
stx P8ZP_SCRATCH_REG_X
jsr GETADR
ldx P8ZP_SCRATCH_REG_X
sta P8ESTACK_HI,x
tya
sta P8ESTACK_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 P8ZP_SCRATCH_W1
sty P8ZP_SCRATCH_W1+1
ldy #0
lda (P8ZP_SCRATCH_W1),y
sta P8ESTACK_LO,x
iny
lda (P8ZP_SCRATCH_W1),y
sta P8ESTACK_HI,x
dex
iny
lda (P8ZP_SCRATCH_W1),y
sta P8ESTACK_LO,x
iny
lda (P8ZP_SCRATCH_W1),y
sta P8ESTACK_HI,x
dex
iny
lda (P8ZP_SCRATCH_W1),y
sta P8ESTACK_LO,x
dex
rts
.pend
func_rndf .proc
; -- put a random floating point value on the stack
stx P8ZP_SCRATCH_REG
lda #1
jsr FREADSA
jsr RND ; rng into fac1
ldx #<_rndf_rnum5
ldy #>_rndf_rnum5
jsr MOVMF ; fac1 to mem X/Y
ldx P8ZP_SCRATCH_REG
lda #<_rndf_rnum5
ldy #>_rndf_rnum5
jmp push_float
_rndf_rnum5 .byte 0,0,0,0,0
.pend
pop_float .proc
; ---- pops mflpt5 from stack to memory A/Y
; (frees 3 stack positions = 6 bytes of which 1 is padding)
sta P8ZP_SCRATCH_W1
sty P8ZP_SCRATCH_W1+1
ldy #4
inx
lda P8ESTACK_LO,x
sta (P8ZP_SCRATCH_W1),y
dey
inx
lda P8ESTACK_HI,x
sta (P8ZP_SCRATCH_W1),y
dey
lda P8ESTACK_LO,x
sta (P8ZP_SCRATCH_W1),y
dey
inx
lda P8ESTACK_HI,x
sta (P8ZP_SCRATCH_W1),y
dey
lda P8ESTACK_LO,x
sta (P8ZP_SCRATCH_W1),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_fac2 .proc
; -- pops float from stack into FAC2
lda #<fmath_float1
ldy #>fmath_float1
jsr pop_float
lda #<fmath_float1
ldy #>fmath_float1
jmp CONUPK
.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 P8ZP_SCRATCH_W1
sty P8ZP_SCRATCH_W1+1
jsr prog8_lib.pop_index_times_5
jsr prog8_lib.add_a_to_zpword
lda P8ZP_SCRATCH_W1
ldy P8ZP_SCRATCH_W1+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 _target+1
sty _target+2
ldy #4
_loop lda (P8ZP_SCRATCH_W1),y
_target sta $ffff,y ; modified
dey
bpl _loop
rts
.pend
inc_var_f .proc
; -- add 1 to float pointed to by A/Y
sta P8ZP_SCRATCH_W1
sty P8ZP_SCRATCH_W1+1
stx P8ZP_SCRATCH_REG_X
jsr MOVFM
lda #<FL_FONE
ldy #>FL_FONE
jsr FADD
ldx P8ZP_SCRATCH_W1
ldy P8ZP_SCRATCH_W1+1
jsr MOVMF
ldx P8ZP_SCRATCH_REG_X
rts
.pend
dec_var_f .proc
; -- subtract 1 from float pointed to by A/Y
sta P8ZP_SCRATCH_W1
sty P8ZP_SCRATCH_W1+1
stx P8ZP_SCRATCH_REG_X
lda #<FL_FONE
ldy #>FL_FONE
jsr MOVFM
lda P8ZP_SCRATCH_W1
ldy P8ZP_SCRATCH_W1+1
jsr FSUB
ldx P8ZP_SCRATCH_W1
ldy P8ZP_SCRATCH_W1+1
jsr MOVMF
ldx P8ZP_SCRATCH_REG_X
rts
.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 P8ZP_SCRATCH_REG_X
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 P8ZP_SCRATCH_REG_X
lda #<fmath_float1
ldy #>fmath_float1
jsr CONUPK ; fac2 = float1
lda #<fmath_float2
ldy #>fmath_float2
jsr FPWR
ldx P8ZP_SCRATCH_REG_X
jmp push_fac1_as_result
.pend
div_f .proc
; -- push f1/f2 on stack
jsr pop_2_floats_f2_in_fac1
stx P8ZP_SCRATCH_REG_X
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 P8ZP_SCRATCH_REG_X
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 P8ZP_SCRATCH_REG_X
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 P8ZP_SCRATCH_REG_X
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 P8ZP_SCRATCH_REG_X
jsr NEGOP
jmp push_fac1_as_result
.pend
abs_f .proc
; -- push abs(float) on stack (as float)
jsr pop_float_fac1
stx P8ZP_SCRATCH_REG_X
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 P8ESTACK_LO-3,x
cmp P8ESTACK_LO,x
bne _equals_false
lda P8ESTACK_LO-2,x
cmp P8ESTACK_LO+1,x
bne _equals_false
lda P8ESTACK_LO-1,x
cmp P8ESTACK_LO+2,x
bne _equals_false
lda P8ESTACK_HI-2,x
cmp P8ESTACK_HI+1,x
bne _equals_false
lda P8ESTACK_HI-1,x
cmp P8ESTACK_HI+2,x
bne _equals_false
_equals_true lda #1
_equals_store inx
sta P8ESTACK_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 P8ESTACK_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 P8ZP_SCRATCH_REG
jsr FCOMP ; A = flt1 compared with flt2 (0=equal, 1=flt1>flt2, 255=flt1<flt2)
ldx P8ZP_SCRATCH_REG
rts
_return_false lda #0
_return_result sta P8ESTACK_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 P8ZP_SCRATCH_REG_X
jsr SIN
jmp push_fac1_as_result
.pend
func_cos .proc
; -- push cos(f) back onto stack
jsr pop_float_fac1
stx P8ZP_SCRATCH_REG_X
jsr COS
jmp push_fac1_as_result
.pend
func_tan .proc
; -- push tan(f) back onto stack
jsr pop_float_fac1
stx P8ZP_SCRATCH_REG_X
jsr TAN
jmp push_fac1_as_result
.pend
func_atan .proc
; -- push atan(f) back onto stack
jsr pop_float_fac1
stx P8ZP_SCRATCH_REG_X
jsr ATN
jmp push_fac1_as_result
.pend
func_ln .proc
; -- push ln(f) back onto stack
jsr pop_float_fac1
stx P8ZP_SCRATCH_REG_X
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 P8ZP_SCRATCH_REG_X
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 P8ZP_SCRATCH_REG_X
jsr SQR
jmp push_fac1_as_result
.pend
func_rad .proc
; -- convert degrees to radians (d * pi / 180)
jsr pop_float_fac1
stx P8ZP_SCRATCH_REG_X
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 P8ZP_SCRATCH_REG_X
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 P8ZP_SCRATCH_REG_X
jsr FADDH
jsr INT
jmp push_fac1_as_result
.pend
func_floor .proc
jsr pop_float_fac1
stx P8ZP_SCRATCH_REG_X
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 P8ZP_SCRATCH_REG_X
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 P8ESTACK_LO,x ; array size
sta P8ZP_SCRATCH_B1
asl a
asl a
clc
adc P8ZP_SCRATCH_B1 ; times 5 because of float
jmp prog8_lib.func_any_b._entry
.pend
func_all_f .proc
inx
jsr prog8_lib.peek_address
lda P8ESTACK_LO,x ; array size
sta P8ZP_SCRATCH_B1
asl a
asl a
clc
adc P8ZP_SCRATCH_B1 ; times 5 because of float
tay
dey
- lda (P8ZP_SCRATCH_W1),y
clc
dey
adc (P8ZP_SCRATCH_W1),y
dey
adc (P8ZP_SCRATCH_W1),y
dey
adc (P8ZP_SCRATCH_W1),y
dey
adc (P8ZP_SCRATCH_W1),y
dey
cmp #0
beq +
cpy #255
bne -
lda #1
sta P8ESTACK_LO+1,x
rts
+ sta P8ESTACK_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 P8ZP_SCRATCH_REG_X
- sty P8ZP_SCRATCH_REG
lda P8ZP_SCRATCH_W1
ldy P8ZP_SCRATCH_W1+1
jsr FCOMP
_minmax_cmp cmp #255 ; modified
bne +
lda P8ZP_SCRATCH_W1
ldy P8ZP_SCRATCH_W1+1
jsr MOVFM
+ lda P8ZP_SCRATCH_W1
clc
adc #5
sta P8ZP_SCRATCH_W1
bcc +
inc P8ZP_SCRATCH_W1+1
+ ldy P8ZP_SCRATCH_REG
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 #<ZERO
ldy #>ZERO
jsr MOVFM
jsr prog8_lib.pop_array_and_lengthmin1Y
stx P8ZP_SCRATCH_REG_X
- sty P8ZP_SCRATCH_REG
lda P8ZP_SCRATCH_W1
ldy P8ZP_SCRATCH_W1+1
jsr FADD
ldy P8ZP_SCRATCH_REG
dey
cpy #255
beq +
lda P8ZP_SCRATCH_W1
clc
adc #5
sta P8ZP_SCRATCH_W1
bcc -
inc P8ZP_SCRATCH_W1+1
bne -
+ jmp push_fac1_as_result
.pend
sign_f .proc
jsr pop_float_fac1
jsr SIGN
sta P8ESTACK_LO,x
dex
rts
.pend
set_0_array_float .proc
; -- set a float in an array to zero (index on stack, array in SCRATCH_ZPWORD1)
inx
lda P8ESTACK_LO,x
asl a
asl a
clc
adc P8ESTACK_LO,x
tay
lda #0
sta (P8ZP_SCRATCH_W1),y
iny
sta (P8ZP_SCRATCH_W1),y
iny
sta (P8ZP_SCRATCH_W1),y
iny
sta (P8ZP_SCRATCH_W1),y
iny
sta (P8ZP_SCRATCH_W1),y
rts
.pend
set_array_float .proc
; -- set a float in an array to a value (index on stack, float in SCRATCH_ZPWORD1, array in SCRATCH_ZPWORD2)
inx
lda P8ESTACK_LO,x
asl a
asl a
clc
adc P8ESTACK_LO,x
adc P8ZP_SCRATCH_W2
ldy P8ZP_SCRATCH_W2+1
bcc +
iny
+ jmp copy_float
; -- 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.
.pend
swap_floats .proc
; -- swap floats pointed to by SCRATCH_ZPWORD1, SCRATCH_ZPWORD2
ldy #4
- lda (P8ZP_SCRATCH_W1),y
pha
lda (P8ZP_SCRATCH_W2),y
sta (P8ZP_SCRATCH_W1),y
pla
sta (P8ZP_SCRATCH_W2),y
dey
bpl -
rts
.pend

896
compiler/res/prog8lib/c64flt.p8
View File

@ -6,12 +6,12 @@
%option enable_floats
c64flt {
; ---- this block contains C-64 floating point related functions ----
const float PI = 3.141592653589793
const float TWOPI = 6.283185307179586
const float PI = 3.141592653589793
const float TWOPI = 6.283185307179586
const float ZERO = 0.0
; ---- C64 basic and kernal ROM float constants and functions ----
@ -34,32 +34,31 @@ c64flt {
&float FL_PIHALF = $e2e0 ; PI / 2
&float FL_TWOPI = $e2e5 ; 2 * PI
&float FL_FR4 = $e2ea ; .25
float FL_ZERO = 0.0 ; oddly enough 0.0 isn't available in the kernel
; oddly enough, 0.0 isn't available in the kernel.
; note: fac1/2 might get clobbered even if not mentioned in the function's name.
; 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 ; note: calls AYINT.
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 +66,50 @@ 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
romsub $bd7e = FINLOG(byte value @A) clobbers (A, X, Y) ; fac1 += signed byte in A
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
@ -163,9 +162,9 @@ asmsub GIVUAYFAY (uword value @ AY) clobbers(A,X,Y) {
asmsub GIVAYFAY (uword value @ AY) clobbers(A,X,Y) {
; ---- signed 16 bit word in A/Y (lo/hi) to float in fac1
%asm {{
sta c64.SCRATCH_ZPREG
sta P8ZP_SCRATCH_REG
tya
ldy c64.SCRATCH_ZPREG
ldy P8ZP_SCRATCH_REG
jmp GIVAYF ; this uses the inverse order, Y/A
}}
}
@ -174,9 +173,9 @@ asmsub FTOSWRDAY () clobbers(X) -> uword @ AY {
; ---- fac1 to signed word in A/Y
%asm {{
jsr FTOSWORDYA ; note the inverse Y/A order
sta c64.SCRATCH_ZPREG
sta P8ZP_SCRATCH_REG
tya
ldy c64.SCRATCH_ZPREG
ldy P8ZP_SCRATCH_REG
rts
}}
}
@ -185,785 +184,34 @@ asmsub GETADRAY () clobbers(X) -> uword @ AY {
; ---- fac1 to unsigned word in A/Y
%asm {{
jsr GETADR ; this uses the inverse order, Y/A
sta c64.SCRATCH_ZPB1
sta P8ZP_SCRATCH_B1
tya
ldy c64.SCRATCH_ZPB1
ldy P8ZP_SCRATCH_B1
rts
}}
}
sub print_f (float value) {
; ---- prints the floating point value (without a newline) using basic rom routines.
; ---- prints the floating point value (without a newline).
%asm {{
stx c64.SCRATCH_ZPREGX
stx P8ZP_SCRATCH_REG_X
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
ldx c64.SCRATCH_ZPREGX
rts
sta P8ZP_SCRATCH_B1
sty P8ZP_SCRATCH_REG
ldy #0
- lda (P8ZP_SCRATCH_B1),y
beq +
jsr c64.CHROUT
iny
bne -
ldx P8ZP_SCRATCH_REG_X
+ rts
}}
}
sub print_fln (float value) {
; ---- prints the floating point value (with a newline at the end) using basic rom routines
%asm {{
stx c64.SCRATCH_ZPREGX
lda #<print_fln_value
ldy #>print_fln_value
jsr MOVFM ; load float into fac1
jsr FPRINTLN ; print fac1 with newline
ldx c64.SCRATCH_ZPREGX
rts
}}
%asminclude "library:c64floats.asm", ""
}
; --- 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 ; 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
}}
} ; ------ end of block c64flt

243
compiler/res/prog8lib/c64graphics.p8 Normal file
View File

@ -0,0 +1,243 @@
%import c64textio
; bitmap pixel graphics module for the C64
; only black/white monchrome for now
; assumes bitmap screen memory is $2000-$3fff
graphics {
const uword bitmap_address = $2000
sub enable_bitmap_mode() {
; enable bitmap screen, erase it and set colors to black/white.
c64.SCROLY |= %00100000
c64.VMCSB = (c64.VMCSB & %11110000) | %00001000 ; $2000-$3fff
clear_screen(1, 0)
}
sub clear_screen(ubyte pixelcolor, ubyte bgcolor) {
memset(bitmap_address, 320*200/8, 0)
txt.fill_screen(pixelcolor << 4 | bgcolor, 0)
}
sub line(uword @zp x1, ubyte @zp y1, uword @zp x2, ubyte @zp y2) {
; Bresenham algorithm.
; This code special cases various quadrant loops to allow simple ++ and -- operations.
; TODO rewrite this in optimized assembly
if y1>y2 {
; make sure dy is always positive to avoid 8 instead of just 4 special cases
swap(x1, x2)
swap(y1, y2)
}
word @zp d = 0
ubyte positive_ix = true
word @zp dx = x2 - x1 as word
word @zp dy = y2 as word - y1 as word
if dx < 0 {
dx = -dx
positive_ix = false
}
dx *= 2
dy *= 2
internal_plotx = x1
if dx >= dy {
if positive_ix {
repeat {
internal_plot(y1)
if internal_plotx==x2
return
internal_plotx++
d += dy
if d > dx {
y1++
d -= dx
}
}
} else {
repeat {
internal_plot(y1)
if internal_plotx==x2
return
internal_plotx--
d += dy
if d > dx {
y1++
d -= dx
}
}
}
}
else {
if positive_ix {
repeat {
internal_plot(y1)
if y1 == y2
return
y1++
d += dx
if d > dy {
internal_plotx++
d -= dy
}
}
} else {
repeat {
internal_plot(y1)
if y1 == y2
return
y1++
d += dx
if d > dy {
internal_plotx--
d -= dy
}
}
}
}
}
sub circle(uword xcenter, ubyte ycenter, ubyte radius) {
; Midpoint algorithm
ubyte @zp ploty
ubyte @zp xx = radius
ubyte @zp yy = 0
byte @zp decisionOver2 = 1-xx as byte
while xx>=yy {
internal_plotx = xcenter + xx
ploty = ycenter + yy
internal_plot(ploty)
internal_plotx = xcenter - xx
internal_plot(ploty)
internal_plotx = xcenter + xx
ploty = ycenter - yy
internal_plot(ploty)
internal_plotx = xcenter - xx
internal_plot(ploty)
internal_plotx = xcenter + yy
ploty = ycenter + xx
internal_plot(ploty)
internal_plotx = xcenter - yy
internal_plot(ploty)
internal_plotx = xcenter + yy
ploty = ycenter - xx
internal_plot(ploty)
internal_plotx = xcenter - yy
internal_plot(ploty)
yy++
if decisionOver2<=0
decisionOver2 += 2*yy+1
else {
xx--
decisionOver2 += 2*(yy-xx)+1
}
}
}
sub disc(uword cx, ubyte cy, ubyte radius) {
; Midpoint algorithm, filled
ubyte xx = radius
ubyte yy = 0
byte decisionOver2 = 1-xx as byte
while xx>=yy {
ubyte cy_plus_yy = cy + yy
ubyte cy_min_yy = cy - yy
ubyte cy_plus_xx = cy + xx
ubyte cy_min_xx = cy - xx
for internal_plotx in cx to cx+xx {
internal_plot(cy_plus_yy)
internal_plot(cy_min_yy)
}
for internal_plotx in cx-xx to cx-1 {
internal_plot(cy_plus_yy)
internal_plot(cy_min_yy)
}
for internal_plotx in cx to cx+yy {
internal_plot(cy_plus_xx)
internal_plot(cy_min_xx)
}
for internal_plotx in cx-yy to cx {
internal_plot(cy_plus_xx)
internal_plot(cy_min_xx)
}
yy++
if decisionOver2<=0
decisionOver2 += 2*yy+1
else {
xx--
decisionOver2 += 2*(yy-xx)+1
}
}
}
; here is the non-asm code for the plot routine below:
; sub plot_nonasm(uword px, ubyte py) {
; ubyte[] ormask = [128, 64, 32, 16, 8, 4, 2, 1]
; uword addr = bitmap_address + 320*(py>>3) + (py & 7) + (px & %0000000111111000)
; @(addr) |= ormask[lsb(px) & 7]
; }
; TODO fix the use of X (or XY) as parameter so we can actually use this plot() routine
; calling it with a byte results in a compiler crash, calling it with word results in clobbering X register I think
asmsub plotXXX(uword plotx @XY, ubyte ploty @A) {
%asm {{
stx internal_plotx
sty internal_plotx+1
jmp internal_plot
}}
}
uword internal_plotx ; 0..319 ; separate 'parameter' for internal_plot()
asmsub internal_plot(ubyte ploty @A) { ; internal_plotx is 16 bits 0 to 319... doesn't fit in a register
%asm {{
tay
stx P8ZP_SCRATCH_REG_X
lda internal_plotx+1
sta P8ZP_SCRATCH_W2+1
lsr a ; 0
sta P8ZP_SCRATCH_W2
lda internal_plotx
pha
and #7
tax
lda _y_lookup_lo,y
clc
adc P8ZP_SCRATCH_W2
sta P8ZP_SCRATCH_W2
lda _y_lookup_hi,y
adc P8ZP_SCRATCH_W2+1
sta P8ZP_SCRATCH_W2+1
pla ; internal_plotx
and #%11111000
tay
lda (P8ZP_SCRATCH_W2),y
ora _ormask,x
sta (P8ZP_SCRATCH_W2),y
ldx P8ZP_SCRATCH_REG_X
rts
_ormask .byte 128, 64, 32, 16, 8, 4, 2, 1
; note: this can be even faster if we also have a 256 byte x-lookup table, but hey.
; see http://codebase64.org/doku.php?id=base:various_techniques_to_calculate_adresses_fast_common_screen_formats_for_pixel_graphics
; the y lookup tables encodes this formula: bitmap_address + 320*(py>>3) + (py & 7) (y from 0..199)
; We use the 64tass syntax for range expressions to calculate this table on assembly time.
_plot_y_values := $2000 + 320*(range(200)>>3) + (range(200) & 7)
_y_lookup_lo .byte <_plot_y_values
_y_lookup_hi .byte >_plot_y_values
}}
}
}

587
compiler/res/prog8lib/c64lib.p8
View File

@ -7,237 +7,426 @@
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 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.
; 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 ----
; ---- C64 ROM kernal routines ----
; ---- C64 basic routines ----
romsub $AB1E = STROUT(uword strptr @ AY) clobbers(A, X, Y) ; print null-terminated string (use c64scr.print instead)
romsub $E544 = CLEARSCR() clobbers(A,X,Y) ; clear the screen
romsub $E566 = HOMECRSR() clobbers(A,X,Y) ; cursor to top left of screen
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
asmsub CLEARSCR () clobbers(A,X,Y) = $E544 ; clear the screen
asmsub HOMECRSR () clobbers(A,X,Y) = $E566 ; cursor to top left of screen
; ---- end of C64 ROM kernal routines ----
; ---- end of C64 basic routines ----
; ---- C64 specific system utility routines: ----
asmsub init_system() {
; Initializes the machine to a sane starting state.
; Called automatically by the loader program logic.
; This means that the BASIC, KERNAL and CHARGEN ROMs are banked in,
; the VIC, SID and CIA chips are reset, screen is cleared, and the default IRQ is set.
; Also a different color scheme is chosen to identify ourselves a little.
; Uppercase charset is activated, and all three registers set to 0, status flags cleared.
%asm {{
sei
cld
lda #%00101111
sta $00
lda #%00100111
sta $01
jsr c64.IOINIT
jsr c64.RESTOR
jsr c64.CINT
lda #6
sta c64.EXTCOL
lda #7
sta c64.COLOR
lda #0
sta c64.BGCOL0
tax
tay
clc
clv
cli
rts
}}
}
; ---- C64 kernal routines ----
asmsub set_irqvec_excl() clobbers(A) {
%asm {{
sei
lda #<_irq_handler
sta c64.CINV
lda #>_irq_handler
sta c64.CINV+1
cli
rts
_irq_handler jsr set_irqvec._irq_handler_init
jsr irq.irq
jsr set_irqvec._irq_handler_end
lda #$ff
sta c64.VICIRQ ; acknowledge raster irq
lda c64.CIA1ICR ; acknowledge CIA1 interrupt
jmp c64.IRQDFEND ; end irq processing - don't call kernel
}}
}
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 (uword userptr @ XY, ubyte dir @ Pc) 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 (uword address @ XY, ubyte dir @ Pc) -> uword @ XY = $FF99 ; read/set top of memory pointer
asmsub MEMBOT (uword address @ XY, ubyte dir @ Pc) -> 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 col @ Y, ubyte row @ X, ubyte dir @ Pc) -> 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 = $FFF3 ; read base address of I/O devices
asmsub set_irqvec() clobbers(A) {
%asm {{
sei
lda #<_irq_handler
sta c64.CINV
lda #>_irq_handler
sta c64.CINV+1
cli
rts
_irq_handler jsr _irq_handler_init
jsr irq.irq
jsr _irq_handler_end
jmp c64.IRQDFRT ; continue with normal kernel irq routine
_irq_handler_init
; save all zp scratch registers and the X register as these might be clobbered by the irq routine
stx IRQ_X_REG
lda P8ZP_SCRATCH_B1
sta IRQ_SCRATCH_ZPB1
lda P8ZP_SCRATCH_REG
sta IRQ_SCRATCH_ZPREG
lda P8ZP_SCRATCH_REG_X
sta IRQ_SCRATCH_ZPREGX
lda P8ZP_SCRATCH_W1
sta IRQ_SCRATCH_ZPWORD1
lda P8ZP_SCRATCH_W1+1
sta IRQ_SCRATCH_ZPWORD1+1
lda P8ZP_SCRATCH_W2
sta IRQ_SCRATCH_ZPWORD2
lda P8ZP_SCRATCH_W2+1
sta IRQ_SCRATCH_ZPWORD2+1
; stack protector; make sure we don't clobber the top of the evaluation stack
dex
dex
dex
dex
dex
dex
cld
rts
_irq_handler_end
; restore all zp scratch registers and the X register
lda IRQ_SCRATCH_ZPB1
sta P8ZP_SCRATCH_B1
lda IRQ_SCRATCH_ZPREG
sta P8ZP_SCRATCH_REG
lda IRQ_SCRATCH_ZPREGX
sta P8ZP_SCRATCH_REG_X
lda IRQ_SCRATCH_ZPWORD1
sta P8ZP_SCRATCH_W1
lda IRQ_SCRATCH_ZPWORD1+1
sta P8ZP_SCRATCH_W1+1
lda IRQ_SCRATCH_ZPWORD2
sta P8ZP_SCRATCH_W2
lda IRQ_SCRATCH_ZPWORD2+1
sta P8ZP_SCRATCH_W2+1
ldx IRQ_X_REG
rts
IRQ_X_REG .byte 0
IRQ_SCRATCH_ZPB1 .byte 0
IRQ_SCRATCH_ZPREG .byte 0
IRQ_SCRATCH_ZPREGX .byte 0
IRQ_SCRATCH_ZPWORD1 .word 0
IRQ_SCRATCH_ZPWORD2 .word 0
}}
}
asmsub restore_irqvec() {
%asm {{
sei
lda #<c64.IRQDFRT
sta c64.CINV
lda #>c64.IRQDFRT
sta c64.CINV+1
lda #0
sta c64.IREQMASK ; disable raster irq
lda #%10000001
sta c64.CIA1ICR ; restore CIA1 irq
cli
rts
}}
}
asmsub set_rasterirq(uword rasterpos @ AY) clobbers(A) {
%asm {{
sei
jsr _setup_raster_irq
lda #<_raster_irq_handler
sta c64.CINV
lda #>_raster_irq_handler
sta c64.CINV+1
cli
rts
_raster_irq_handler
jsr set_irqvec._irq_handler_init
jsr irq.irq
jsr set_irqvec._irq_handler_end
lda #$ff
sta c64.VICIRQ ; acknowledge raster irq
jmp c64.IRQDFRT
_setup_raster_irq
pha
lda #%01111111
sta c64.CIA1ICR ; "switch off" interrupts signals from cia-1
sta c64.CIA2ICR ; "switch off" interrupts signals from cia-2
and c64.SCROLY
sta c64.SCROLY ; clear most significant bit of raster position
lda c64.CIA1ICR ; ack previous irq
lda c64.CIA2ICR ; ack previous irq
pla
sta c64.RASTER ; set the raster line number where interrupt should occur
cpy #0
beq +
lda c64.SCROLY
ora #%10000000
sta c64.SCROLY ; set most significant bit of raster position
+ lda #%00000001
sta c64.IREQMASK ;enable raster interrupt signals from vic
rts
}}
}
asmsub set_rasterirq_excl(uword rasterpos @ AY) clobbers(A) {
%asm {{
sei
jsr set_rasterirq._setup_raster_irq
lda #<_raster_irq_handler
sta c64.CINV
lda #>_raster_irq_handler
sta c64.CINV+1
cli
rts
_raster_irq_handler
jsr set_irqvec._irq_handler_init
jsr irq.irq
jsr set_irqvec._irq_handler_end
lda #$ff
sta c64.VICIRQ ; acknowledge raster irq
jmp c64.IRQDFEND ; end irq processing - don't call kernel
}}
}
; ---- end of C64 specific system utility routines ----
; ---- end of C64 kernal routines ----
}

557
compiler/res/prog8lib/c64textio.p8 Normal file
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; Prog8 definitions for the Text I/O and Screen routines for the Commodore-64
;
; Written by Irmen de Jong (irmen@razorvine.net) - license: GNU GPL 3.0
;
; indent format: TABS, size=8
%import c64lib
%import conv
txt {
asmsub clear_screen() {
%asm {{
lda #' '
jmp clear_screenchars
}}
}
asmsub fill_screen (ubyte char @ A, ubyte charcolor @ Y) clobbers(A) {
; ---- fill the character screen with the given fill character and character color.
; (assumes screen and color matrix are at their default addresses)
%asm {{
pha
tya
jsr clear_screencolors
pla
jsr clear_screenchars
rts
}}
}
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)
%asm {{
ldy #0
_loop sta c64.Screen,y
sta c64.Screen+$0100,y
sta c64.Screen+$0200,y
sta c64.Screen+$02e8,y
iny
bne _loop
rts
}}
}
asmsub clear_screencolors (ubyte scrcolor @ A) clobbers(Y) {
; ---- clear the character screen colors with the given color (leaves characters).
; (assumes color matrix is at the default address)
%asm {{
ldy #0
_loop sta c64.Colors,y
sta c64.Colors+$0100,y
sta c64.Colors+$0200,y
sta c64.Colors+$02e8,y
iny
bne _loop
rts
}}
}
sub color (ubyte txtcol) {
c64.COLOR = txtcol
}
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
; Carry flag determines if screen color data must be scrolled too
%asm {{
stx P8ZP_SCRATCH_REG_X
bcs +
jmp _scroll_screen
+ ; scroll the color memory
ldx #0
ldy #38
-
.for row=0, row<=24, row+=1
lda c64.Colors + 40*row + 1,x
sta c64.Colors + 40*row,x
.next
inx
dey
bpl -
_scroll_screen ; scroll the screen memory
ldx #0
ldy #38
-
.for row=0, row<=24, row+=1
lda c64.Screen + 40*row + 1,x
sta c64.Screen + 40*row,x
.next
inx
dey
bpl -
ldx P8ZP_SCRATCH_REG_X
rts
}}
}
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
; Carry flag determines if screen color data must be scrolled too
%asm {{
stx P8ZP_SCRATCH_REG_X
bcs +
jmp _scroll_screen
+ ; scroll the color memory
ldx #38
-
.for row=0, row<=24, row+=1
lda c64.Colors + 40*row + 0,x
sta c64.Colors + 40*row + 1,x
.next
dex
bpl -
_scroll_screen ; scroll the screen memory
ldx #38
-
.for row=0, row<=24, row+=1
lda c64.Screen + 40*row + 0,x
sta c64.Screen + 40*row + 1,x
.next
dex
bpl -
ldx P8ZP_SCRATCH_REG_X
rts
}}
}
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
; Carry flag determines if screen color data must be scrolled too
%asm {{
stx P8ZP_SCRATCH_REG_X
bcs +
jmp _scroll_screen
+ ; scroll the color memory
ldx #39
-
.for row=1, row<=24, row+=1
lda c64.Colors + 40*row,x
sta c64.Colors + 40*(row-1),x
.next
dex
bpl -
_scroll_screen ; scroll the screen memory
ldx #39
-
.for row=1, row<=24, row+=1
lda c64.Screen + 40*row,x
sta c64.Screen + 40*(row-1),x
.next
dex
bpl -
ldx P8ZP_SCRATCH_REG_X
rts
}}
}
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
; Carry flag determines if screen color data must be scrolled too
%asm {{
stx P8ZP_SCRATCH_REG_X
bcs +
jmp _scroll_screen
+ ; scroll the color memory
ldx #39
-
.for row=23, row>=0, row-=1
lda c64.Colors + 40*row,x
sta c64.Colors + 40*(row+1),x
.next
dex
bpl -
_scroll_screen ; scroll the screen memory
ldx #39
-
.for row=23, row>=0, row-=1
lda c64.Screen + 40*row,x
sta c64.Screen + 40*(row+1),x
.next
dex
bpl -
ldx P8ZP_SCRATCH_REG_X
rts
}}
}
asmsub print (str text @ AY) clobbers(A,Y) {
; ---- print null terminated string from A/Y
; note: the compiler contains an optimization that will replace
; a call to this subroutine with a string argument of just one char,
; by just one call to c64.CHROUT of that single char.
%asm {{
sta P8ZP_SCRATCH_B1
sty P8ZP_SCRATCH_REG
ldy #0
- lda (P8ZP_SCRATCH_B1),y
beq +
jsr c64.CHROUT
iny
bne -
+ rts
}}
}
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 {{
stx P8ZP_SCRATCH_REG_X
jsr conv.ubyte2decimal
pha
tya
jsr c64.CHROUT
pla
jsr c64.CHROUT
txa
jsr c64.CHROUT
ldx P8ZP_SCRATCH_REG_X
rts
}}
}
asmsub print_ub (ubyte value @ A) clobbers(A,Y) {
; ---- print the ubyte in A in decimal form, without left padding 0s
%asm {{
stx P8ZP_SCRATCH_REG_X
jsr conv.ubyte2decimal
_print_byte_digits
pha
cpy #'0'
beq +
tya
jsr c64.CHROUT
pla
jsr c64.CHROUT
jmp _ones
+ pla
cmp #'0'
beq _ones
jsr c64.CHROUT
_ones txa
jsr c64.CHROUT
ldx P8ZP_SCRATCH_REG_X
rts
}}
}
asmsub print_b (byte value @ A) clobbers(A,Y) {
; ---- print the byte in A in decimal form, without left padding 0s
%asm {{
stx P8ZP_SCRATCH_REG_X
pha
cmp #0
bpl +
lda #'-'
jsr c64.CHROUT
+ pla
jsr conv.byte2decimal
jsr print_ub._print_byte_digits
ldx P8ZP_SCRATCH_REG_X
rts
}}
}
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 P8ZP_SCRATCH_REG_X
bcc +
pha
lda #'$'
jsr c64.CHROUT
pla
+ jsr conv.ubyte2hex
jsr c64.CHROUT
tya
jsr c64.CHROUT
ldx P8ZP_SCRATCH_REG_X
rts
}}
}
asmsub print_ubbin (ubyte value @ A, ubyte prefix @ Pc) clobbers(A,Y) {
; ---- print the ubyte in A in binary form (if Carry is set, a radix prefix '%' is printed as well)
%asm {{
stx P8ZP_SCRATCH_REG_X
sta P8ZP_SCRATCH_B1
bcc +
lda #'%'
jsr c64.CHROUT
+ ldy #8
- lda #'0'
asl P8ZP_SCRATCH_B1
bcc +
lda #'1'
+ jsr c64.CHROUT
dey
bne -
ldx P8ZP_SCRATCH_REG_X
rts
}}
}
asmsub print_uwbin (uword value @ AY, ubyte prefix @ Pc) clobbers(A,Y) {
; ---- print the uword in A/Y in binary form (if Carry is set, a radix prefix '%' is printed as well)
%asm {{
pha
tya
jsr print_ubbin
pla
clc
jmp print_ubbin
}}
}
asmsub print_uwhex (uword value @ AY, ubyte prefix @ Pc) clobbers(A,Y) {
; ---- print the uword in A/Y in hexadecimal form (4 digits)
; (if Carry is set, a radix prefix '$' is printed as well)
%asm {{
pha
tya
jsr print_ubhex
pla
clc
jmp print_ubhex
}}
}
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 P8ZP_SCRATCH_REG_X
jsr conv.uword2decimal
ldy #0
- lda conv.uword2decimal.decTenThousands,y
beq +
jsr c64.CHROUT
iny
bne -
+ ldx P8ZP_SCRATCH_REG_X
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 P8ZP_SCRATCH_REG_X
jsr conv.uword2decimal
ldx P8ZP_SCRATCH_REG_X
ldy #0
- lda conv.uword2decimal.decTenThousands,y
beq _allzero
cmp #'0'
bne _gotdigit
iny
bne -
_gotdigit
jsr c64.CHROUT
iny
lda conv.uword2decimal.decTenThousands,y
bne _gotdigit
rts
_allzero
lda #'0'
jmp c64.CHROUT
}}
}
asmsub print_w (word value @ AY) clobbers(A,Y) {
; ---- print the (signed) word in A/Y in decimal form, without left padding 0's
%asm {{
cpy #0
bpl +
pha
lda #'-'
jsr c64.CHROUT
tya
eor #255
tay
pla
eor #255
clc
adc #1
bcc +
iny
+ jmp print_uw
}}
}
asmsub input_chars (uword buffer @ AY) clobbers(A) -> ubyte @ Y {
; ---- Input a string (max. 80 chars) from the keyboard. Returns length in Y. (string is terminated with a 0 byte as well)
; It assumes the keyboard is selected as I/O channel!
%asm {{
sta P8ZP_SCRATCH_W1
sty P8ZP_SCRATCH_W1+1
ldy #0 ; char counter = 0
- jsr c64.CHRIN
cmp #$0d ; return (ascii 13) pressed?
beq + ; yes, end.
sta (P8ZP_SCRATCH_W1),y ; else store char in buffer
iny
bne -
+ lda #0
sta (P8ZP_SCRATCH_W1),y ; finish string with 0 byte
rts
}}
}
asmsub setchr (ubyte col @Y, ubyte row @A) clobbers(A) {
; ---- set the character in SCRATCH_ZPB1 on the screen matrix at the given position
%asm {{
sty P8ZP_SCRATCH_REG
asl a
tay
lda _screenrows+1,y
sta _mod+2
lda _screenrows,y
clc
adc P8ZP_SCRATCH_REG
sta _mod+1
bcc +
inc _mod+2
+ lda P8ZP_SCRATCH_B1
_mod sta $ffff ; modified
rts
_screenrows .word $0400 + range(0, 1000, 40)
}}
}
asmsub getchr (ubyte col @Y, ubyte row @A) clobbers(Y) -> ubyte @ A {
; ---- get the character in the screen matrix at the given location
%asm {{
sty P8ZP_SCRATCH_B1
asl a
tay
lda setchr._screenrows+1,y
sta _mod+2
lda setchr._screenrows,y
clc
adc P8ZP_SCRATCH_B1
sta _mod+1
bcc _mod
inc _mod+2
_mod lda $ffff ; modified
rts
}}
}
asmsub setclr (ubyte col @Y, ubyte row @A) clobbers(A) {
; ---- set the color in SCRATCH_ZPB1 on the screen matrix at the given position
%asm {{
sty P8ZP_SCRATCH_REG
asl a
tay
lda _colorrows+1,y
sta _mod+2
lda _colorrows,y
clc
adc P8ZP_SCRATCH_REG
sta _mod+1
bcc +
inc _mod+2
+ lda P8ZP_SCRATCH_B1
_mod sta $ffff ; modified
rts
_colorrows .word $d800 + range(0, 1000, 40)
}}
}
asmsub getclr (ubyte col @Y, ubyte row @A) clobbers(Y) -> ubyte @ A {
; ---- get the color in the screen color matrix at the given location
%asm {{
sty P8ZP_SCRATCH_B1
asl a
tay
lda setclr._colorrows+1,y
sta _mod+2
lda setclr._colorrows,y
clc
adc P8ZP_SCRATCH_B1
sta _mod+1
bcc _mod
inc _mod+2
_mod lda $ffff ; modified
rts
}}
}
sub setcc (ubyte column, ubyte row, ubyte char, ubyte charcolor) {
; ---- set char+color at the given position on the screen
%asm {{
lda row
asl a
tay
lda setchr._screenrows+1,y
sta _charmod+2
adc #$d4
sta _colormod+2
lda setchr._screenrows,y
clc
adc column
sta _charmod+1
sta _colormod+1
bcc +
inc _charmod+2
inc _colormod+2
+ lda char
_charmod sta $ffff ; modified
lda charcolor
_colormod sta $ffff ; modified
rts
}}
}
asmsub plot (ubyte col @ Y, ubyte row @ A) clobbers(A) {
; ---- safe wrapper around PLOT kernel routine, to save the X register.
%asm {{
stx P8ZP_SCRATCH_REG_X
tax
clc
jsr c64.PLOT
ldx P8ZP_SCRATCH_REG_X
rts
}}
}
}

1102
compiler/res/prog8lib/c64utils.p8
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361
compiler/res/prog8lib/conv.p8 Normal file
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; Prog8 definitions for number conversions routines.
;
; Written by Irmen de Jong (irmen@razorvine.net) - license: GNU GPL 3.0
;
; indent format: TABS, size=8
conv {
; ----- number conversions to decimal strings
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 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 = $30
temp = P8ZP_SCRATCH_B1 ; byte in zeropage
hexHigh = P8ZP_SCRATCH_W1 ; byte in zeropage
hexLow = P8ZP_SCRATCH_W1+1 ; byte in zeropage
HexToDec65535; SUBROUTINE
sty hexHigh ;3 @9
sta hexLow ;3 @12
tya
tax ;2 @14
lsr a ;2 @16
lsr a ;2 @18 integer divide 1024 (result 0-63)
cpx #$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 +
eor #255
clc
adc #1
+ jmp ubyte2decimal
}}
}
asmsub ubyte2hex (ubyte value @ A) -> ubyte @ A, ubyte @ Y {
; ---- A to hex petscii string in AY (first hex char in A, second hex char in Y)
%asm {{
stx P8ZP_SCRATCH_REG_X
pha
and #$0f
tax
ldy _hex_digits,x
pla
lsr a
lsr a
lsr a
lsr a
tax
lda _hex_digits,x
ldx P8ZP_SCRATCH_REG_X
rts
_hex_digits .text "0123456789abcdef" ; can probably be reused for other stuff as well
}}
}
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 {{
sta P8ZP_SCRATCH_REG
tya
jsr ubyte2hex
sta output
sty output+1
lda P8ZP_SCRATCH_REG
jsr ubyte2hex
sta output+2
sty output+3
rts
output .text "0000", $00 ; 0-terminated output buffer (to make printing easier)
}}
}
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
; (any non-digit character will terminate the number string that is parsed)
%asm {{
_result = P8ZP_SCRATCH_W2
sta _mod+1
sty _mod+2
ldy #0
sty _result
sty _result+1
_mod lda $ffff,y ; modified
sec
sbc #48
bpl +
_done ; return result
lda _result
ldy _result+1
rts
+ cmp #10
bcs _done
; add digit to result
pha
jsr _result_times_10
pla
clc
adc _result
sta _result
bcc +
inc _result+1
+ iny
bne _mod
; never reached
_result_times_10 ; (W*4 + W)*2
lda _result+1
sta P8ZP_SCRATCH_REG
lda _result
asl a
rol P8ZP_SCRATCH_REG
asl a
rol P8ZP_SCRATCH_REG
clc
adc _result
sta _result
lda P8ZP_SCRATCH_REG
adc _result+1
asl _result
rol a
sta _result+1
rts
}}
}
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
; (any non-digit character will terminate the number string that is parsed)
%asm {{
_result = P8ZP_SCRATCH_W2
sta P8ZP_SCRATCH_W1
sty P8ZP_SCRATCH_W1+1
ldy #0
sty _result
sty _result+1
sty _negative
lda (P8ZP_SCRATCH_W1),y
cmp #'+'
bne +
iny
+ cmp #'-'
bne _parse
inc _negative
iny
_parse lda (P8ZP_SCRATCH_W1),y
sec
sbc #48
bpl _digit
_done ; return result
lda _negative
beq +
sec
lda #0
sbc _result
sta _result
lda #0
sbc _result+1
sta _result+1
+ lda _result
ldy _result+1
rts
_digit cmp #10
bcs _done
; add digit to result
pha
jsr str2uword._result_times_10
pla
clc
adc _result
sta _result
bcc +
inc _result+1
+ iny
bne _parse
; never reached
_negative .byte 0
}}
}
}

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; Prog8 definitions for floating point handling on the CommanderX16
;
; Written by Irmen de Jong (irmen@razorvine.net) - license: GNU GPL 3.0
;
; indent format: TABS, size=8
%option enable_floats
c64flt {
; ---- this block contains C-64 floating point related functions ----
const float PI = 3.141592653589793
const float TWOPI = 6.283185307179586
const float ZERO = 0.0
; ---- ROM float functions ----
; note: the fac1 and fac2 are working registers and take 6 bytes each,
; floats in memory (and rom) are stored in 5-byte MFLPT packed format.
; note: fac1/2 might get clobbered even if not mentioned in the function's name.
; note: for subtraction and division, the left operand is in fac2, the right operand in fac1.
romsub $fe00 = 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
; there is also c64flt.GIVUAYFAY - unsigned word in A/Y (lo/hi) to fac1
; (tip: use GIVAYFAY to use A/Y input; lo/hi switched to normal order)
romsub $fe03 = GIVAYF(ubyte lo @ Y, ubyte hi @ A) clobbers(A,X,Y)
; fac1 -> unsigned word in Y/A (might throw ILLEGAL QUANTITY) (result also in $14/15)
; (tip: use GETADRAY to get A/Y output; lo/hi switched to normal little endian order)
romsub $fe06 = GETADR() clobbers(X) -> ubyte @ Y, ubyte @ A
romsub $fe09 = FADDH() clobbers(A,X,Y) ; fac1 += 0.5, for rounding- call this before INT
romsub $fe0c = FSUB(uword mflpt @ AY) clobbers(A,X,Y) ; fac1 = mflpt from A/Y - fac1
romsub $fe0f = FSUBT() clobbers(A,X,Y) ; fac1 = fac2-fac1 mind the order of the operands
romsub $fe12 = FADD(uword mflpt @ AY) clobbers(A,X,Y) ; fac1 += mflpt value from A/Y
romsub $fe15 = FADDT() clobbers(A,X,Y) ; fac1 += fac2
romsub $fe1b = ZEROFC() clobbers(A,X,Y) ; fac1 = 0
romsub $fe1e = NORMAL() clobbers(A,X,Y) ; normalize fac1 (?)
romsub $fe24 = LOG() clobbers(A,X,Y) ; fac1 = LN(fac1) (natural log)
romsub $fe27 = FMULT(uword mflpt @ AY) clobbers(A,X,Y) ; fac1 *= mflpt value from A/Y
romsub $fe2a = FMULTT() clobbers(A,X,Y) ; fac1 *= fac2
romsub $fe33 = CONUPK(uword mflpt @ AY) clobbers(A,Y) ; load mflpt value from memory in A/Y into fac2
romsub $fe36 = MUL10() clobbers(A,X,Y) ; fac1 *= 10
romsub $fe3c = DIV10() clobbers(A,X,Y) ; fac1 /= 10 , CAUTION: result is always positive!
romsub $fe3f = FDIV(uword mflpt @ AY) clobbers(A,X,Y) ; fac1 = mflpt in A/Y / fac1 (remainder in fac2)
romsub $fe42 = FDIVT() clobbers(A,X,Y) ; fac1 = fac2/fac1 (remainder in fac2) mind the order of the operands
romsub $fe48 = MOVFM(uword mflpt @ AY) clobbers(A,Y) ; load mflpt value from memory in A/Y into fac1
romsub $fe4b = MOVMF(uword mflpt @ XY) clobbers(A,Y) ; store fac1 to memory X/Y as 5-byte mflpt
romsub $fe4e = MOVFA() clobbers(A,X) ; copy fac2 to fac1
romsub $fe51 = MOVAF() clobbers(A,X) ; copy fac1 to fac2 (rounded)
romsub $fe54 = MOVEF() clobbers(A,X) ; copy fac1 to fac2
romsub $fe5a = SIGN() -> ubyte @ A ; SIGN(fac1) to A, $ff, $0, $1 for negative, zero, positive
romsub $fe5d = SGN() clobbers(A,X,Y) ; fac1 = SGN(fac1), result of SIGN (-1, 0 or 1)
romsub $fe60 = FREADSA(byte value @ A) clobbers(A,X,Y) ; 8 bit signed A -> float in fac1
romsub $fe6c = ABS() ; fac1 = ABS(fac1)
romsub $fe6f = FCOMP(uword mflpt @ AY) clobbers(X,Y) -> ubyte @ A ; A = compare fac1 to mflpt in A/Y, 0=equal 1=fac1 is greater, 255=fac1 is less than
romsub $fe78 = INT() clobbers(A,X,Y) ; INT() truncates, use FADDH first to round instead of trunc
romsub $fe7e = FINLOG(byte value @A) clobbers (A, X, Y) ; fac1 += signed byte in A
romsub $fe81 = FOUT() clobbers(X) -> uword @ AY ; fac1 -> string, address returned in AY
romsub $fe8a = SQR() clobbers(A,X,Y) ; fac1 = SQRT(fac1)
romsub $fe8d = FPWRT() clobbers(A,X,Y) ; fac1 = fac2 ** fac1
romsub $fe93 = NEGOP() clobbers(A) ; switch the sign of fac1
romsub $fe96 = EXP() clobbers(A,X,Y) ; fac1 = EXP(fac1) (e ** fac1)
romsub $fe9f = RND2(byte value @A) clobbers(A,X,Y) ; fac1 = RND(A) float random number generator
romsub $fea2 = RND() clobbers(A,X,Y) ; fac1 = RND(fac1) float random number generator
romsub $fea5 = COS() clobbers(A,X,Y) ; fac1 = COS(fac1)
romsub $fea8 = SIN() clobbers(A,X,Y) ; fac1 = SIN(fac1)
romsub $feab = TAN() clobbers(A,X,Y) ; fac1 = TAN(fac1)
romsub $feae = ATN() clobbers(A,X,Y) ; fac1 = ATN(fac1)
asmsub GIVUAYFAY (uword value @ AY) clobbers(A,X,Y) {
; ---- unsigned 16 bit word in A/Y (lo/hi) to fac1
%asm {{
phx
sta P8ZP_SCRATCH_REG
sty P8ZP_SCRATCH_B1
tya
ldy P8ZP_SCRATCH_REG
jsr GIVAYF ; load it as signed... correct afterwards
lda P8ZP_SCRATCH_B1
bpl +
lda #<_flt65536
ldy #>_flt65536
jsr FADD
+ plx
rts
_flt65536 .byte 145,0,0,0,0 ; 65536.0
}}
}
asmsub GIVAYFAY (uword value @ AY) clobbers(A,X,Y) {
; ---- signed 16 bit word in A/Y (lo/hi) to float in fac1
%asm {{
sta P8ZP_SCRATCH_REG
tya
ldy P8ZP_SCRATCH_REG
jmp GIVAYF ; this uses the inverse order, Y/A
}}
}
asmsub FTOSWRDAY () clobbers(X) -> uword @ AY {
; ---- fac1 to signed word in A/Y
%asm {{
jsr FTOSWORDYA ; note the inverse Y/A order
sta P8ZP_SCRATCH_REG
tya
ldy P8ZP_SCRATCH_REG
rts
}}
}
asmsub GETADRAY () clobbers(X) -> uword @ AY {
; ---- fac1 to unsigned word in A/Y
%asm {{
jsr GETADR ; this uses the inverse order, Y/A
sta P8ZP_SCRATCH_B1
tya
ldy P8ZP_SCRATCH_B1
rts
}}
}
sub print_f (float value) {
; ---- prints the floating point value (without a newline).
%asm {{
stx P8ZP_SCRATCH_REG_X
lda #<value
ldy #>value
jsr MOVFM ; load float into fac1
jsr FOUT ; fac1 to string in A/Y
sta P8ZP_SCRATCH_B1
sty P8ZP_SCRATCH_REG
ldy #0
- lda (P8ZP_SCRATCH_B1),y
beq +
jsr c64.CHROUT
iny
bne -
ldx P8ZP_SCRATCH_REG_X
+ rts
}}
}
%asminclude "library:c64floats.asm", ""
}

221
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; Prog8 definitions for the CommanderX16
; Including memory registers, I/O registers, Basic and Kernal subroutines.
;
; Written by Irmen de Jong (irmen@razorvine.net) - license: GNU GPL 3.0
;
; indent format: TABS, size=8
c64 {
; ---- kernal routines, these are the same as on the Commodore-64 (hence the same block name) ----
; STROUT --> use screen.print
; CLEARSCR -> use screen.clear_screen
; HOMECRSR -> use screen.plot
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 screen.plot for a 'safe' wrapper that preserves X.
romsub $FFF3 = IOBASE() -> uword @ XY ; read base address of I/O devices
}
cx16 {
; ---- Commander X-16 additions on top of C64 kernal routines ----
; spelling of the names is taken from the Commander X-16 rom sources
; the sixteen virtual 16-bit registers
&uword r0 = $02
&uword r1 = $04
&uword r2 = $06
&uword r3 = $08
&uword r4 = $0a
&uword r5 = $0c
&uword r6 = $0e
&uword r7 = $10
&uword r8 = $12
&uword r9 = $14
&uword r10 = $16
&uword r11 = $18
&uword r12 = $1a
&uword r13 = $1c
&uword r14 = $1e
&uword r15 = $20
; VERA registers
const uword VERA_BASE = $9F20
&uword VERA_ADDR_L = VERA_BASE + $00
&uword VERA_ADDR_M = VERA_BASE + $01
&uword VERA_ADDR_H = VERA_BASE + $02
&uword VERA_DATA0 = VERA_BASE + $03
&uword VERA_DATA1 = VERA_BASE + $04
&uword VERA_CTRL = VERA_BASE + $05
&uword VERA_IEN = VERA_BASE + $06
&uword VERA_ISR = VERA_BASE + $07
&uword VERA_IRQ_LINE_L = VERA_BASE + $08
&uword VERA_DC_VIDEO = VERA_BASE + $09
&uword VERA_DC_HSCALE = VERA_BASE + $0A
&uword VERA_DC_VSCALE = VERA_BASE + $0B
&uword VERA_DC_BORDER = VERA_BASE + $0C
&uword VERA_DC_HSTART = VERA_BASE + $09
&uword VERA_DC_HSTOP = VERA_BASE + $0A
&uword VERA_DC_VSTART = VERA_BASE + $0B
&uword VERA_DC_VSTOP = VERA_BASE + $0C
&uword VERA_L0_CONFIG = VERA_BASE + $0D
&uword VERA_L0_MAPBASE = VERA_BASE + $0E
&uword VERA_L0_TILEBASE = VERA_BASE + $0F
&uword VERA_L0_HSCROLL_L = VERA_BASE + $10
&uword VERA_L0_HSCROLL_H = VERA_BASE + $11
&uword VERA_L0_VSCROLL_L = VERA_BASE + $12
&uword VERA_L0_VSCROLL_H = VERA_BASE + $13
&uword VERA_L1_CONFIG = VERA_BASE + $14
&uword VERA_L1_MAPBASE = VERA_BASE + $15
&uword VERA_L1_TILEBASE = VERA_BASE + $16
&uword VERA_L1_HSCROLL_L = VERA_BASE + $17
&uword VERA_L1_HSCROLL_H = VERA_BASE + $18
&uword VERA_L1_VSCROLL_L = VERA_BASE + $19
&uword VERA_L1_VSCROLL_H = VERA_BASE + $1A
&uword VERA_AUDIO_CTRL = VERA_BASE + $1B
&uword VERA_AUDIO_RATE = VERA_BASE + $1C
&uword VERA_AUDIO_DATA = VERA_BASE + $1D
&uword VERA_SPI_DATA = VERA_BASE + $1E
&uword VERA_SPI_CTRL = VERA_BASE + $1F
; VERA_PSG_BASE = $1F9C0
; VERA_PALETTE_BASE = $1FA00
; VERA_SPRITES_BASE = $1FC00
; supported C128 additions
romsub $ff4a = close_all()
romsub $ff59 = lkupla()
romsub $ff5c = lkupsa()
romsub $ff5f = screen_set_mode(ubyte mode @A) clobbers(A, X, Y) -> ubyte @Pc
romsub $ff62 = screen_set_charset(ubyte charset @A, uword charsetptr @XY) clobbers(A,X,Y) ; incompatible with C128 dlchr()
romsub $ff65 = pfkey()
romsub $ff6e = jsrfar()
romsub $ff74 = fetch()
romsub $ff77 = stash()
romsub $ff7a = cmpare()
romsub $ff7d = primm()
; X16 additions
romsub $ff44 = macptr()
romsub $ff47 = enter_basic(ubyte cold_or_warm @Pc)
romsub $ff68 = mouse_config(ubyte shape @A, ubyte scale @X) clobbers (A, X, Y)
romsub $ff6b = mouse_get(ubyte zpdataptr @X) clobbers(A)
romsub $ff71 = mouse_scan() clobbers(A, X, Y)
romsub $ff53 = joystick_scan() clobbers(A, X, Y)
romsub $ff56 = joystick_get(ubyte joynr @A) -> ubyte @A, ubyte @X, ubyte @Y
romsub $ff4d = clock_set_date_time() clobbers(A, X, Y) ; args: r0, r1, r2, r3L
romsub $ff50 = clock_get_date_time() clobbers(A) ; outout args: r0, r1, r2, r3L
; high level graphics & fonts
romsub $ff20 = GRAPH_init() ; uses vectors=r0
romsub $ff23 = GRAPH_clear()
romsub $ff26 = GRAPH_set_window() ; uses x=r0, y=r1, width=r2, height=r3
romsub $ff29 = GRAPH_set_colors(ubyte stroke @A, ubyte fill @X, ubyte background @Y)
romsub $ff2c = GRAPH_draw_line() ; uses x1=r0, y1=r1, x2=r2, y2=r3
romsub $ff2f = GRAPH_draw_rect(ubyte fill @Pc) ; uses x=r0, y=r1, width=r2, height=r3, cornerradius=r4
romsub $ff32 = GRAPH_move_rect() ; uses sx=r0, sy=r1, tx=r2, ty=r3, width=r4, height=r5
romsub $ff35 = GRAPH_draw_oval(ubyte fill @Pc) ; uses x=r0, y=r1, width=r2, height=r3
romsub $ff38 = GRAPH_draw_image() ; uses x=r0, y=r1, ptr=r2, width=r3, height=r4
romsub $ff3b = GRAPH_set_font() ; uses ptr=r0
romsub $ff3e = GRAPH_get_char_size(ubyte baseline @A, ubyte width @X, ubyte height_or_style @Y, ubyte is_control @Pc)
romsub $ff41 = GRAPH_put_char(ubyte char @A) ; uses x=r0, y=r1
; framebuffer
romsub $fef6 = FB_init()
romsub $fef9 = FB_get_info() -> byte @A ; also outputs width=r0, height=r1
romsub $fefc = FB_set_palette(ubyte index @A, ubyte bytecount @X) ; also uses pointer=r0
romsub $feff = FB_cursor_position() ; uses x=r0, y=r1
romsub $ff02 = FB_cursor_next_line() ; uses x=r0
romsub $ff05 = FB_get_pixel() -> ubyte @A
romsub $ff08 = FB_get_pixels() ; uses ptr=r0, count=r1
romsub $ff0b = FB_set_pixel(ubyte color @A)
romsub $ff0e = FB_set_pixels() ; uses ptr=r0, count=r1
romsub $ff11 = FB_set_8_pixels(ubyte pattern @A, ubyte color @X)
romsub $ff14 = FB_set_8_pixels_opaque(ubyte pattern @A, ubyte color1 @X, ubyte color2 @Y) ; also uses mask=r0L
romsub $ff17 = FB_fill_pixels(ubyte color @A) ; also uses count=r0, step=r1
romsub $ff1a = FB_filter_pixels() ; uses ptr=r0, count=r1
romsub $ff1d = FB_move_pixels() ; uses sx=r0, sy=r1, tx=r2, ty=r3, count=r4
; misc
romsub $fef0 = sprite_set_image(ubyte number @A, ubyte width @X, ubyte height @Y, ubyte apply_mask @Pc) -> ubyte @Pc ; also uses pixels=r0, mask=r1, bpp=r2L
romsub $fef3 = sprite_set_position(ubyte number @A) ; also uses x=r0 and y=r1
romsub $fee4 = memory_fill(ubyte value @A) ; uses address=r0, num_bytes=r1
romsub $fee7 = memory_copy() ; uses source=r0, target=r1, num_bytes=r2
romsub $feea = memory_crc() ; uses address=r0, num_bytes=r1 result->r2
romsub $feed = memory_decompress() ; uses input=r0, output=r1 result->r1
romsub $fedb = console_init() ; uses x=r0, y=r1, width=r2, height=r3
romsub $fede = console_put_char(ubyte char @A, ubyte wrapping @Pc)
romsub $fee1 = console_get_char() -> ubyte @A
romsub $fed8 = console_put_image() ; uses ptr=r0, width=r1, height=r2
romsub $fed5 = console_set_paging_message() ; uses messageptr=r0
romsub $fed2 = kbdbuf_put(ubyte key @A)
romsub $fecf = entropy_get() -> ubyte @A, ubyte @X, ubyte @Y
romsub $fecc = monitor()
; ---- end of kernal routines ----
asmsub init_system() {
; Initializes the machine to a sane starting state.
; Called automatically by the loader program logic.
%asm {{
sei
cld
stz $00
stz $01
jsr c64.IOINIT
jsr c64.RESTOR
jsr c64.CINT
lda #0
tax
tay
clc
clv
cli
rts
}}
}
}

314
compiler/res/prog8lib/cx16textio.p8 Normal file
View File

@ -0,0 +1,314 @@
; Prog8 definitions for the Text I/O and Screen routines for the CommanderX16
;
; Written by Irmen de Jong (irmen@razorvine.net) - license: GNU GPL 3.0
;
; indent format: TABS, size=8
%import cx16lib
%import conv
txt {
sub clear_screen() {
c64.CHROUT(147) ; clear screen (spaces)
}
asmsub fill_screen (ubyte char @ A, ubyte txtcolor @ Y) clobbers(A) {
; ---- fill the character screen with the given fill character and character color.
%asm {{
sta P8ZP_SCRATCH_W1 ; fillchar
sty P8ZP_SCRATCH_W1+1 ; textcolor
phx
jsr c64.SCREEN ; get dimensions in X/Y
dex
dey
txa
asl a
adc #1
sta P8ZP_SCRATCH_B1
- ldx P8ZP_SCRATCH_B1
- stz cx16.VERA_ADDR_H
stx cx16.VERA_ADDR_L
sty cx16.VERA_ADDR_M
lda cx16.VERA_DATA0
and #$f0
ora P8ZP_SCRATCH_W1+1
sta cx16.VERA_DATA0
dex
stz cx16.VERA_ADDR_H
stx cx16.VERA_ADDR_L
sty cx16.VERA_ADDR_M
lda P8ZP_SCRATCH_W1
sta cx16.VERA_DATA0
dex
cpx #255
bne -
dey
bpl --
plx
rts
}}
}
ubyte[16] color_to_charcode = [$90,$05,$1c,$9f,$9c,$1e,$1f,$9e,$81,$95,$96,$97,$98,$99,$9a,$9b]
sub color (ubyte txtcol) {
c64.CHROUT(color_to_charcode[txtcol & 15])
}
sub color2 (ubyte txtcol, ubyte bgcol) {
c64.CHROUT(color_to_charcode[bgcol & 15])
c64.CHROUT(1) ; switch fg and bg colors
c64.CHROUT(color_to_charcode[txtcol & 15])
}
asmsub print (str text @ AY) clobbers(A,Y) {
; ---- print null terminated string from A/Y
; note: the compiler contains an optimization that will replace
; a call to this subroutine with a string argument of just one char,
; by just one call to c64.CHROUT of that single char.
%asm {{
sta P8ZP_SCRATCH_B1
sty P8ZP_SCRATCH_REG
ldy #0
- lda (P8ZP_SCRATCH_B1),y
beq +
jsr c64.CHROUT
iny
bne -
+ rts
}}
}
asmsub print_ub0 (ubyte value @ A) clobbers(A,Y) {
; ---- print the ubyte in A in decimal form, with left padding 0s (3 positions total)
%asm {{
phx
jsr conv.ubyte2decimal
pha
tya
jsr c64.CHROUT
pla
jsr c64.CHROUT
txa
jsr c64.CHROUT
plx
rts
}}
}
asmsub print_ub (ubyte value @ A) clobbers(A,Y) {
; ---- print the ubyte in A in decimal form, without left padding 0s
%asm {{
phx
jsr conv.ubyte2decimal
_print_byte_digits
pha
cpy #'0'
beq +
tya
jsr c64.CHROUT
pla
jsr c64.CHROUT
jmp _ones
+ pla
cmp #'0'
beq _ones
jsr c64.CHROUT
_ones txa
jsr c64.CHROUT
plx
rts
}}
}
asmsub print_b (byte value @ A) clobbers(A,Y) {
; ---- print the byte in A in decimal form, without left padding 0s
%asm {{
phx
pha
cmp #0
bpl +
lda #'-'
jsr c64.CHROUT
+ pla
jsr conv.byte2decimal
jmp print_ub._print_byte_digits
}}
}
asmsub print_ubhex (ubyte value @ A, ubyte prefix @ Pc) clobbers(A,Y) {
; ---- print the ubyte in A in hex form (if Carry is set, a radix prefix '$' is printed as well)
%asm {{
phx
bcc +
pha
lda #'$'
jsr c64.CHROUT
pla
+ jsr conv.ubyte2hex
jsr c64.CHROUT
tya
jsr c64.CHROUT
plx
rts
}}
}
asmsub print_ubbin (ubyte value @ A, ubyte prefix @ Pc) clobbers(A,Y) {
; ---- print the ubyte in A in binary form (if Carry is set, a radix prefix '%' is printed as well)
%asm {{
phx
sta P8ZP_SCRATCH_B1
bcc +
lda #'%'
jsr c64.CHROUT
+ ldy #8
- lda #'0'
asl P8ZP_SCRATCH_B1
bcc +
lda #'1'
+ jsr c64.CHROUT
dey
bne -
plx
rts
}}
}
asmsub print_uwbin (uword value @ AY, ubyte prefix @ Pc) clobbers(A,Y) {
; ---- print the uword in A/Y in binary form (if Carry is set, a radix prefix '%' is printed as well)
%asm {{
pha
tya
jsr print_ubbin
pla
clc
jmp print_ubbin
}}
}
asmsub print_uwhex (uword value @ AY, ubyte prefix @ Pc) clobbers(A,Y) {
; ---- print the uword in A/Y in hexadecimal form (4 digits)
; (if Carry is set, a radix prefix '$' is printed as well)
%asm {{
pha
tya
jsr print_ubhex
pla
clc
jmp print_ubhex
}}
}
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 {{
phx
jsr conv.uword2decimal
ldy #0
- lda conv.uword2decimal.decTenThousands,y
beq +
jsr c64.CHROUT
iny
bne -
+ plx
rts
}}
}
asmsub print_uw (uword value @ AY) clobbers(A,Y) {
; ---- print the uword in A/Y in decimal form, without left padding 0s
%asm {{
phx
jsr conv.uword2decimal
plx
ldy #0
- lda conv.uword2decimal.decTenThousands,y
beq _allzero
cmp #'0'
bne _gotdigit
iny
bne -
_gotdigit
jsr c64.CHROUT
iny
lda conv.uword2decimal.decTenThousands,y
bne _gotdigit
rts
_allzero
lda #'0'
jmp c64.CHROUT
}}
}
asmsub print_w (word value @ AY) clobbers(A,Y) {
; ---- print the (signed) word in A/Y in decimal form, without left padding 0's
%asm {{
cpy #0
bpl +
pha
lda #'-'
jsr c64.CHROUT
tya
eor #255
tay
pla
eor #255
clc
adc #1
bcc +
iny
+ jmp print_uw
}}
}
; TODO implement the "missing" txtio subroutines
sub setcc (ubyte column, ubyte row, ubyte char, ubyte charcolor) {
; ---- set char+color at the given position on the screen
%asm {{
phx
lda column
asl a
tax
ldy row
lda charcolor
and #$0f
sta P8ZP_SCRATCH_B1
stz cx16.VERA_ADDR_H
stx cx16.VERA_ADDR_L
sty cx16.VERA_ADDR_M
lda char
sta cx16.VERA_DATA0
inx
stz cx16.VERA_ADDR_H
stx cx16.VERA_ADDR_L
sty cx16.VERA_ADDR_M
lda cx16.VERA_DATA0
and #$f0
ora P8ZP_SCRATCH_B1
sta cx16.VERA_DATA0
plx
rts
}}
}
asmsub plot (ubyte col @ Y, ubyte row @ A) clobbers(A) {
; ---- safe wrapper around PLOT kernel routine, to save the X register.
%asm {{
phx
tax
clc
jsr c64.PLOT
plx
rts
}}
}
}

727
compiler/res/prog8lib/math.asm
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2
compiler/res/prog8lib/math.p8
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@ -4,8 +4,6 @@
;
; indent format: TABS, size=8
%import c64lib
math {
%asminclude "library:math.asm", ""
}

1683
compiler/res/prog8lib/prog8lib.asm
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2
compiler/res/prog8lib/prog8lib.p8
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@ -4,8 +4,6 @@
;
; indent format: TABS, size=8
%import c64lib
prog8_lib {
%asminclude "library:prog8lib.asm", ""
}

3
compiler/res/version.txt
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@ -1,2 +1 @@
1.60
4.1

160
compiler/src/prog8/CompilerMain.kt
View File

@ -1,24 +1,26 @@
package prog8
import kotlinx.cli.*
import prog8.ast.base.AstException
import prog8.compiler.CompilationResult
import prog8.compiler.compileProgram
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.compiler.target.cx16.CX16MachineDefinition
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.Paths
import java.nio.file.StandardWatchEventKinds
import java.util.*
import java.time.LocalDateTime
import kotlin.system.exitProcess
fun main(args: Array<String>) {
printSoftwareHeader("compiler")
if (args.isEmpty())
usage()
compileMain(args)
}
@ -29,51 +31,80 @@ 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 writeAssembly = true
var optimize = true
var launchAstVm = false
var watchMode = false
for (arg in args) {
if(arg=="-emu")
emulatorToStart = "x64"
else if(arg=="-emu2")
emulatorToStart = "x64sc"
else if(arg=="-noasm")
writeAssembly = false
else if(arg=="-noopt")
optimize = false
else if(arg=="-avm")
launchAstVm = true
else if(arg=="-watch")
watchMode = true
else if(!arg.startsWith("-"))
moduleFile = arg
else
usage()
val cli = CommandLineInterface("prog8compiler")
val startEmulator by cli.flagArgument("-emu", "auto-start 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 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 'c64' and 'cx16' available", "c64")
val moduleFiles by cli.positionalArgumentsList("modules", "main module file(s) to compile", minArgs = 1)
try {
cli.parse(args)
} catch (e: Exception) {
exitProcess(1)
}
if(watchMode) {
if(moduleFile.isBlank())
usage()
when(compilationTarget) {
"c64" -> {
with(CompilationTarget) {
name = "Commodore-64"
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
}
}
"cx16" -> {
with(CompilationTarget) {
name = "Commander X16"
machine = CX16MachineDefinition
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. Available are: c64, cx16")
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 = Paths.get(moduleFile).normalize()
val filepath = pathFrom(moduleFiles.single()).normalize()
println("Continuous watch mode active. Main module: $filepath")
try {
val compilationResult = compileProgram(filepath, optimize, writeAssembly)
val compilationResult = compileProgram(filepath, !dontOptimize, !dontWriteAssembly, outputDir=outputPath)
println("Imported files (now watching:)")
for (importedFile in compilationResult.importedFiles) {
print(" ")
println(importedFile)
importedFile.parent.register(watchservice, StandardWatchEventKinds.ENTRY_MODIFY)
}
println("${Date()}: Waiting for file changes.")
println("[${LocalDateTime.now().withNano(0)}] Waiting for file changes.")
val event = watchservice.take()
for(changed in event.pollEvents()) {
val changedPath = changed.context() as Path
@ -87,51 +118,26 @@ private fun compileMain(args: Array<String>) {
}
} else {
if(moduleFile.isBlank())
usage()
val filepath = Paths.get(moduleFile).normalize()
val compilationResult: CompilationResult
try {
compilationResult = compileProgram(filepath, optimize, writeAssembly)
if(!compilationResult.success)
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: ParsingFailedError) {
exitProcess(1)
} catch (x: AstException) {
exitProcess(1)
}
} catch (x: AstException) {
exitProcess(1)
}
if (launchAstVm) {
println("\nLaunching AST-based vm...")
val vm = AstVm(compilationResult.programAst)
vm.run()
}
if (emulatorToStart.isNotEmpty()) {
if (compilationResult.programName.isEmpty())
println("\nCan't start emulator because no program was assembled.")
else {
println("\nStarting C-64 emulator $emulatorToStart...")
val cmdline = listOf(emulatorToStart, "-silent", "-moncommands", "${compilationResult.programName}.vice-mon-list",
"-autostartprgmode", "1", "-autostart-warp", "-autostart", compilationResult.programName + ".prg")
val process = ProcessBuilder(cmdline).inheritIO().start()
process.waitFor()
if (startEmulator) {
if (compilationResult.programName.isEmpty())
println("\nCan't start emulator because no program was assembled.")
else if(startEmulator) {
CompilationTarget.machine.launchEmulator(compilationResult.programName)
}
}
}
}
}
private fun usage() {
System.err.println("Missing argument(s):")
System.err.println(" [-noasm] don't create assembly code")
System.err.println(" [-noopt] don't perform any optimizations")
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(" [-avm] launch the prog8 ast-based virtual machine after compilation")
System.err.println(" [-watch] continuous compilation mode (watches for file changes)")
System.err.println(" modulefile main module file to compile")
exitProcess(1)
}

78
compiler/src/prog8/ast/AstToSourceCode.kt
View File

@ -3,7 +3,6 @@ package prog8.ast
import prog8.ast.antlr.escape
import prog8.ast.base.DataType
import prog8.ast.base.NumericDatatypes
import prog8.ast.base.StringDatatypes
import prog8.ast.base.VarDeclType
import prog8.ast.expressions.*
import prog8.ast.processing.IAstVisitor
@ -79,7 +78,7 @@ class AstToSourceCode(val output: (text: String) -> Unit, val program: Program):
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["
@ -103,6 +102,12 @@ class AstToSourceCode(val output: (text: String) -> Unit, val program: Program):
}
override fun visit(decl: VarDecl) {
// if the vardecl is a parameter of a subroutine, don't output it again
val paramNames = (decl.definingScope() as? Subroutine)?.parameters?.map { it.name }
if(paramNames!=null && decl.name in paramNames)
return
when(decl.type) {
VarDeclType.VAR -> {}
VarDeclType.CONST -> output("const ")
@ -178,8 +183,6 @@ class AstToSourceCode(val output: (text: String) -> Unit, val program: Program):
private fun outputStatements(statements: List<Statement>) {
for(stmt in statements) {
if(stmt is VarDecl && stmt.autogeneratedDontRemove)
continue // skip autogenerated decls (to avoid generating a newline)
outputi("")
stmt.accept(this)
output("\n")
@ -197,9 +200,9 @@ class AstToSourceCode(val output: (text: String) -> Unit, val program: Program):
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(")")
@ -284,20 +287,19 @@ class AstToSourceCode(val output: (text: String) -> Unit, val program: Program):
}
override fun visit(assignment: Assignment) {
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
val binExpr = assignment.value as? BinaryExpression
if(binExpr!=null && binExpr.left isSameAs assignment.target
&& binExpr.operator !in setOf("and", "or", "xor")
&& binExpr.operator !in comparisonOperators) {
// we only support the inplace assignments of the form A = A <operator> <value>
assignment.target.accept(this)
output(" ${binExpr.operator}= ")
binExpr.right.accept(this)
} else {
assignment.target.accept(this)
output(" = ")
assignment.value.accept(this)
assignment.value.accept(this)
}
}
override fun visit(postIncrDecr: PostIncrDecr) {
@ -305,20 +307,13 @@ class AstToSourceCode(val output: (text: String) -> Unit, val program: Program):
output(postIncrDecr.operator)
}
override fun visit(contStmt: Continue) {
output("continue")
}
override fun visit(breakStmt: Break) {
output("break")
}
override fun visit(forLoop: ForLoop) {
output("for ")
if(forLoop.loopRegister!=null)
output(forLoop.loopRegister.toString())
else
forLoop.loopVar!!.accept(this)
forLoop.loopVar.accept(this)
output(" in ")
forLoop.iterable.accept(this)
output(" ")
@ -334,9 +329,16 @@ class AstToSourceCode(val output: (text: String) -> Unit, val program: Program):
override fun visit(repeatLoop: RepeatLoop) {
output("repeat ")
repeatLoop.iterations?.accept(this)
output(" ")
repeatLoop.body.accept(this)
}
override fun visit(untilLoop: UntilLoop) {
output("do ")
untilLoop.body.accept(this)
output(" until ")
repeatLoop.untilCondition.accept(this)
untilLoop.untilCondition.accept(this)
}
override fun visit(returnStmt: Return) {
@ -352,12 +354,8 @@ class AstToSourceCode(val output: (text: String) -> Unit, val program: Program):
}
override fun visit(assignTarget: AssignTarget) {
if(assignTarget.register!=null)
output(assignTarget.register.toString())
else {
assignTarget.memoryAddress?.accept(this)
assignTarget.identifier?.accept(this)
}
assignTarget.memoryAddress?.accept(this)
assignTarget.identifier?.accept(this)
assignTarget.arrayindexed?.accept(this)
}
@ -398,10 +396,6 @@ class AstToSourceCode(val output: (text: String) -> Unit, val program: Program):
outputlni("}}")
}
override fun visit(registerExpr: RegisterExpr) {
output(registerExpr.register.toString())
}
override fun visit(builtinFunctionStatementPlaceholder: BuiltinFunctionStatementPlaceholder) {
output(builtinFunctionStatementPlaceholder.name)
}
@ -435,12 +429,4 @@ class AstToSourceCode(val output: (text: String) -> Unit, val program: Program):
whenChoice.statements.accept(this)
outputln("")
}
override fun visit(structLv: StructLiteralValue) {
outputListMembers(structLv.values.asSequence(), '{', '}')
}
override fun visit(nopStatement: NopStatement) {
output("; NOP @ ${nopStatement.position} $nopStatement")
}
}

125
compiler/src/prog8/ast/AstToplevel.kt
View File

@ -3,8 +3,9 @@ package prog8.ast
import prog8.ast.base.*
import prog8.ast.expressions.Expression
import prog8.ast.expressions.IdentifierReference
import prog8.ast.processing.AstWalker
import prog8.ast.processing.IAstVisitor
import prog8.ast.statements.*
import prog8.compiler.HeapValues
import prog8.functions.BuiltinFunctions
import java.nio.file.Path
@ -34,11 +35,13 @@ interface Node {
return this
throw FatalAstException("scope missing from $this")
}
fun replaceChildNode(node: Node, replacement: Node)
}
interface IFunctionCall {
var target: IdentifierReference
var arglist: MutableList<Expression>
var args: MutableList<Expression>
}
interface INameScope {
@ -49,32 +52,31 @@ interface INameScope {
fun linkParents(parent: Node)
fun subScopes(): Map<String, INameScope> {
val subscopes = mutableMapOf<String, INameScope>()
fun subScope(name: 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 ForLoop -> if(stmt.body.name==name) return stmt.body
is UntilLoop -> if(stmt.body.name==name) return stmt.body
is WhileLoop -> if(stmt.body.name==name) return stmt.body
is BranchStatement -> {
subscopes[stmt.truepart.name] = stmt.truepart
if(stmt.elsepart.containsCodeOrVars())
subscopes[stmt.elsepart.name] = stmt.elsepart
if(stmt.truepart.name==name) return stmt.truepart
if(stmt.elsepart.containsCodeOrVars() && stmt.elsepart.name==name) return stmt.elsepart
}
is IfStatement -> {
subscopes[stmt.truepart.name] = stmt.truepart
if(stmt.elsepart.containsCodeOrVars())
subscopes[stmt.elsepart.name] = stmt.elsepart
if(stmt.truepart.name==name) return stmt.truepart
if(stmt.elsepart.containsCodeOrVars() && stmt.elsepart.name==name) return stmt.elsepart
}
is WhenStatement -> {
stmt.choices.forEach { subscopes[it.statements.name] = it.statements }
val scope = stmt.choices.firstOrNull { it.statements.name==name }
if(scope!=null)
return scope.statements
}
is INameScope -> subscopes[stmt.name] = stmt
is INameScope -> if(stmt.name==name) return stmt
else -> {}
}
}
return subscopes
return null
}
fun getLabelOrVariable(name: String): Statement? {
@ -122,7 +124,7 @@ interface INameScope {
for(module in localContext.definingModule().program.modules) {
var scope: INameScope? = module
for(name in scopedName.dropLast(1)) {
scope = scope?.subScopes()?.get(name)
scope = scope?.subScope(name)
if(scope==null)
break
}
@ -130,7 +132,7 @@ interface INameScope {
val result = scope.getLabelOrVariable(scopedName.last())
if(result!=null)
return result
return scope.subScopes()[scopedName.last()] as Statement?
return scope.subScope(scopedName.last()) as Statement?
}
}
return null
@ -142,7 +144,7 @@ interface INameScope {
val result = localScope.getLabelOrVariable(scopedName[0])
if (result != null)
return result
val subscope = localScope.subScopes()[scopedName[0]] as Statement?
val subscope = localScope.subScope(scopedName[0]) as Statement?
if (subscope != null)
return subscope
// not found in this scope, look one higher up
@ -153,20 +155,57 @@ interface INameScope {
}
fun containsCodeOrVars() = statements.any { it !is Directive || it.directive == "%asminclude" || it.directive == "%asm"}
fun containsNoVars() = statements.all { it !is VarDecl }
fun containsNoCodeNorVars() = !containsCodeOrVars()
fun remove(stmt: Statement) {
if(!statements.remove(stmt))
throw FatalAstException("stmt to remove wasn't found in scope")
}
fun getAllLabels(label: String): List<Label> {
val result = mutableListOf<Label>()
fun find(scope: INameScope) {
scope.statements.forEach {
when(it) {
is Label -> result.add(it)
is INameScope -> find(it)
is IfStatement -> {
find(it.truepart)
find(it.elsepart)
}
is UntilLoop -> find(it.body)
is RepeatLoop -> find(it.body)
is WhileLoop -> find(it.body)
is WhenStatement -> it.choices.forEach { choice->find(choice.statements) }
else -> { /* do nothing */ }
}
}
}
find(this)
return result
}
fun nextSibling(stmt: Statement): Statement? {
val nextIdx = statements.indexOfFirst { it===stmt } + 1
return if(nextIdx < statements.size)
statements[nextIdx]
else
null
}
}
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>) {
class Program(val name: String, val modules: MutableList<Module>): Node {
val namespace = GlobalNamespace(modules)
val heap = HeapValues()
val definedLoadAddress: Int
get() = modules.first().loadAddress
@ -174,17 +213,35 @@ class Program(val name: String, val modules: MutableList<Module>) {
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()) {
null
} else {
mainBlocks[0].subScopes()["start"] as Subroutine?
mainBlocks[0].subScope("start") as Subroutine?
}
}
fun allBlocks(): List<Block> = modules.flatMap { it.statements.filterIsInstance<Block>() }
override val position: Position = Position.DUMMY
override var parent: Node
get() = throw FatalAstException("program has no parent")
set(value) = throw FatalAstException("can't set parent of program")
override fun linkParents(parent: Node) {
modules.forEach {
it.linkParents(this)
}
}
override fun replaceChildNode(node: Node, replacement: Node) {
require(node is Module && replacement is Module)
val idx = modules.indexOfFirst { it===node }
modules[idx] = replacement
replacement.parent = this
}
}
class Module(override val name: String,
@ -192,6 +249,7 @@ class Module(override val name: String,
override val position: Position,
val isLibraryModule: Boolean,
val source: Path) : Node, INameScope {
override lateinit var parent: Node
lateinit var program: Program
val importedBy = mutableListOf<Module>()
@ -205,10 +263,20 @@ class Module(override val name: String,
}
override fun definingScope(): INameScope = program.namespace
override fun replaceChildNode(node: Node, replacement: Node) {
require(node is Statement && replacement is Statement)
val idx = statements.indexOfFirst { it===node }
statements[idx] = replacement
replacement.parent = this
}
override fun toString() = "Module(name=$name, pos=$position, lib=$isLibraryModule)"
fun accept(visitor: IAstVisitor) = visitor.visit(this)
fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
}
class GlobalNamespace(val modules: List<Module>): Node, INameScope {
override val name = "<<<global>>>"
override val position = Position("<<<global>>>", 0, 0, 0)
@ -219,6 +287,10 @@ class GlobalNamespace(val modules: List<Module>): Node, INameScope {
modules.forEach { it.linkParents(this) }
}
override fun replaceChildNode(node: Node, replacement: Node) {
throw FatalAstException("cannot replace anything in the namespace")
}
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
@ -241,11 +313,10 @@ class GlobalNamespace(val modules: List<Module>): Node, INameScope {
}
}
// lookup something from the module.
val stmt = localContext.definingModule().lookup(scopedName, localContext)
return when (stmt) {
is Label, is VarDecl, is Block, is Subroutine -> stmt
return when (val stmt = localContext.definingModule().lookup(scopedName, localContext)) {
is Label, is VarDecl, is Block, is Subroutine, is StructDecl -> stmt
null -> null
else -> throw NameError("wrong identifier target: $stmt", stmt.position)
else -> throw SyntaxError("invalid identifier target type", stmt.position)
}
}
}

265
compiler/src/prog8/ast/antlr/Antr2Kotlin.kt
View File

@ -7,7 +7,7 @@ import prog8.ast.Module
import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.ast.statements.*
import prog8.compiler.target.c64.Petscii
import prog8.compiler.target.CompilationTarget
import prog8.parser.CustomLexer
import prog8.parser.prog8Parser
import java.io.CharConversionException
@ -19,13 +19,13 @@ import java.nio.file.Path
private data class NumericLiteral(val number: Number, val datatype: DataType)
fun prog8Parser.ModuleContext.toAst(name: String, isLibrary: Boolean, source: Path) : Module {
internal fun prog8Parser.ModuleContext.toAst(name: String, isLibrary: Boolean, source: Path) : Module {
val nameWithoutSuffix = if(name.endsWith(".p8")) name.substringBeforeLast('.') else name
return Module(nameWithoutSuffix, modulestatement().asSequence().map { it.toAst(isLibrary) }.toMutableList(), toPosition(), isLibrary, source)
val directives = this.directive().map { it.toAst() }
val blocks = this.block().map { it.toAst(isLibrary) }
return Module(nameWithoutSuffix, (directives + blocks).toMutableList(), toPosition(), isLibrary, source)
}
private fun ParserRuleContext.toPosition() : Position {
val customTokensource = this.start.tokenSource as? CustomLexer
val filename =
@ -38,27 +38,23 @@ private fun ParserRuleContext.toPosition() : Position {
return Position(filename, start.line, start.charPositionInLine, stop.charPositionInLine + stop.text.length)
}
private fun prog8Parser.ModulestatementContext.toAst(isInLibrary: Boolean) : Statement {
val directive = directive()?.toAst()
if(directive!=null) return directive
val block = block()?.toAst(isInLibrary)
if(block!=null) return block
throw FatalAstException(text)
private fun prog8Parser.BlockContext.toAst(isInLibrary: Boolean) : Statement {
val blockstatements = block_statement().map {
when {
it.variabledeclaration()!=null -> it.variabledeclaration().toAst()
it.subroutinedeclaration()!=null -> it.subroutinedeclaration().toAst()
it.directive()!=null -> it.directive().toAst()
it.inlineasm()!=null -> it.inlineasm().toAst()
else -> throw FatalAstException("weird block statement $it")
}
}
return Block(identifier().text, integerliteral()?.toAst()?.number?.toInt(), blockstatements.toMutableList(), isInLibrary, toPosition())
}
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<Statement> =
statement().asSequence().map { it.toAst() }.toMutableList()
private fun prog8Parser.StatementContext.toAst() : Statement {
private fun prog8Parser.VariabledeclarationContext.toAst() : Statement {
vardecl()?.let { return it.toAst() }
varinitializer()?.let {
@ -66,7 +62,7 @@ private fun prog8Parser.StatementContext.toAst() : Statement {
return VarDecl(
VarDeclType.VAR,
vd.datatype()?.toAst() ?: DataType.STRUCT,
if(vd.ZEROPAGE() != null) ZeropageWish.PREFER_ZEROPAGE else ZeropageWish.DONTCARE,
if (vd.ZEROPAGE() != null) ZeropageWish.PREFER_ZEROPAGE else ZeropageWish.DONTCARE,
vd.arrayindex()?.toAst(),
vd.varname.text,
null,
@ -114,7 +110,7 @@ private fun prog8Parser.StatementContext.toAst() : Statement {
return VarDecl(
VarDeclType.CONST,
vd.datatype()?.toAst() ?: DataType.STRUCT,
if(vd.ZEROPAGE() != null) ZeropageWish.PREFER_ZEROPAGE else ZeropageWish.DONTCARE,
if (vd.ZEROPAGE() != null) ZeropageWish.PREFER_ZEROPAGE else ZeropageWish.DONTCARE,
vd.arrayindex()?.toAst(),
vd.varname.text,
null,
@ -131,7 +127,7 @@ private fun prog8Parser.StatementContext.toAst() : Statement {
return VarDecl(
VarDeclType.MEMORY,
vd.datatype()?.toAst() ?: DataType.STRUCT,
if(vd.ZEROPAGE() != null) ZeropageWish.PREFER_ZEROPAGE else ZeropageWish.DONTCARE,
if (vd.ZEROPAGE() != null) ZeropageWish.PREFER_ZEROPAGE else ZeropageWish.DONTCARE,
vd.arrayindex()?.toAst(),
vd.varname.text,
null,
@ -142,15 +138,38 @@ private fun prog8Parser.StatementContext.toAst() : Statement {
)
}
structdecl()?.let {
return StructDecl(it.identifier().text,
it.vardecl().map { vd->vd.toAst() }.toMutableList(),
toPosition())
}
throw FatalAstException("weird variable decl $this")
}
private fun prog8Parser.SubroutinedeclarationContext.toAst() : Subroutine {
return when {
subroutine()!=null -> subroutine().toAst()
asmsubroutine()!=null -> asmsubroutine().toAst()
romsubroutine()!=null -> romsubroutine().toAst()
else -> throw FatalAstException("weird subroutine decl $this")
}
}
private fun prog8Parser.StatementContext.toAst() : Statement {
val vardecl = variabledeclaration()?.toAst()
if(vardecl!=null) return vardecl
assignment()?.let {
return Assignment(it.assign_target().toAst(), null, it.expression().toAst(), it.toPosition())
return Assignment(it.assign_target().toAst(), it.expression().toAst(), it.toPosition())
}
augassignment()?.let {
return Assignment(it.assign_target().toAst(),
it.operator.text,
it.expression().toAst(),
it.toPosition())
// replace A += X with A = A + X
val target = it.assign_target().toAst()
val oper = it.operator.text.substringBefore('=')
val expression = BinaryExpression(target.toExpression(), oper, it.expression().toAst(), it.expression().toPosition())
return Assignment(it.assign_target().toAst(), expression, it.toPosition())
}
postincrdecr()?.let {
@ -175,8 +194,8 @@ private fun prog8Parser.StatementContext.toAst() : Statement {
val returnstmt = returnstmt()?.toAst()
if(returnstmt!=null) return returnstmt
val sub = subroutine()?.toAst()
if(sub!=null) return sub
val subroutine = subroutinedeclaration()?.toAst()
if(subroutine!=null) return subroutine
val asm = inlineasm()?.toAst()
if(asm!=null) return asm
@ -187,46 +206,57 @@ private fun prog8Parser.StatementContext.toAst() : Statement {
val forloop = forloop()?.toAst()
if(forloop!=null) return forloop
val repeatloop = repeatloop()?.toAst()
if(repeatloop!=null) return repeatloop
val untilloop = untilloop()?.toAst()
if(untilloop!=null) return untilloop
val whileloop = whileloop()?.toAst()
if(whileloop!=null) return whileloop
val repeatloop = repeatloop()?.toAst()
if(repeatloop!=null) return repeatloop
val breakstmt = breakstmt()?.toAst()
if(breakstmt!=null) return breakstmt
val continuestmt = continuestmt()?.toAst()
if(continuestmt!=null) return continuestmt
val asmsubstmt = asmsubroutine()?.toAst()
if(asmsubstmt!=null) return asmsubstmt
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.AsmsubroutineContext.toAst(): Statement {
private fun prog8Parser.AsmsubroutineContext.toAst(): Subroutine {
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(): Subroutine {
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 class AsmsubDecl(val name: String,
val parameters: List<SubroutineParameter>,
val returntypes: List<DataType>,
val asmParameterRegisters: List<RegisterOrStatusflag>,
val asmReturnvaluesRegisters: List<RegisterOrStatusflag>,
val asmClobbers: Set<CpuRegister>)
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,
@ -242,36 +272,52 @@ private class AsmSubroutineReturn(val type: DataType,
val stack: Boolean,
val position: Position)
private fun prog8Parser.ClobberContext.toAst(): Set<Register>
= this.register().asSequence().map { it.toAst() }.toSet()
private fun prog8Parser.Asmsub_returnsContext.toAst(): List<AsmSubroutineReturn>
= asmsub_return().map { AsmSubroutineReturn(it.datatype().toAst(), it.registerorpair()?.toAst(), it.statusregister()?.toAst(), !it.stack?.text.isNullOrEmpty(), toPosition()) }
= asmsub_return().map {
val register = it.identifier()?.toAst()
var registerorpair: RegisterOrPair? = null
var statusregister: Statusflag? = null
if(register!=null) {
when (val name = register.nameInSource.single()) {
in RegisterOrPair.names -> registerorpair = RegisterOrPair.valueOf(name)
in Statusflag.names -> statusregister = Statusflag.valueOf(name)
else -> throw FatalAstException("invalid register or status flag in $it")
}
}
AsmSubroutineReturn(
it.datatype().toAst(),
registerorpair,
statusregister,
!it.stack?.text.isNullOrEmpty(), toPosition())
}
private fun prog8Parser.Asmsub_paramsContext.toAst(): List<AsmSubroutineParameter>
= asmsub_param().map {
val vardecl = it.vardecl()
val datatype = vardecl.datatype()?.toAst() ?: DataType.STRUCT
AsmSubroutineParameter(vardecl.varname.text, datatype,
it.registerorpair()?.toAst(),
it.statusregister()?.toAst(),
val register = it.identifier()?.toAst()
var registerorpair: RegisterOrPair? = null
var statusregister: Statusflag? = null
if(register!=null) {
when (val name = register.nameInSource.single()) {
in RegisterOrPair.names -> registerorpair = RegisterOrPair.valueOf(name)
in Statusflag.names -> statusregister = Statusflag.valueOf(name)
else -> throw FatalAstException("invalid register or status flag '$name'")
}
}
AsmSubroutineParameter(vardecl.varname.text, datatype, registerorpair, statusregister,
!it.stack?.text.isNullOrEmpty(), toPosition())
}
private fun prog8Parser.StatusregisterContext.toAst() = Statusflag.valueOf(text)
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())
}
private fun prog8Parser.FunctioncallContext.toAst(): FunctionCall {
val location = scoped_identifier().toAst()
return if(expression_list() == null)
@ -280,11 +326,9 @@ private fun prog8Parser.FunctioncallContext.toAst(): FunctionCall {
FunctionCall(location, expression_list().toAst().toMutableList(), toPosition())
}
private fun prog8Parser.InlineasmContext.toAst() =
InlineAssembly(INLINEASMBLOCK().text, toPosition())
private fun prog8Parser.ReturnstmtContext.toAst() : Return {
return Return(expression()?.toAst(), toPosition())
}
@ -295,11 +339,9 @@ private fun prog8Parser.UnconditionaljumpContext.toAst(): Jump {
return Jump(address, identifier, null, toPosition())
}
private fun prog8Parser.LabeldefContext.toAst(): Statement =
Label(children[0].text, toPosition())
private fun prog8Parser.SubroutineContext.toAst() : Subroutine {
return Subroutine(identifier().text,
sub_params()?.toAst() ?: emptyList(),
@ -318,44 +360,42 @@ private fun prog8Parser.Sub_return_partContext.toAst(): List<DataType> {
return returns.datatype().map { it.toAst() }
}
private fun prog8Parser.Sub_paramsContext.toAst(): List<SubroutineParameter> =
vardecl().map {
val datatype = it.datatype()?.toAst() ?: DataType.STRUCT
SubroutineParameter(it.varname.text, datatype, it.toPosition())
}
private fun prog8Parser.Assign_targetContext.toAst() : AssignTarget {
val register = register()?.toAst()
val identifier = scoped_identifier()
return when {
register!=null -> AssignTarget(register, null, null, null, toPosition())
identifier!=null -> AssignTarget(null, identifier.toAst(), null, null, toPosition())
arrayindexed()!=null -> AssignTarget(null, null, arrayindexed().toAst(), null, toPosition())
directmemory()!=null -> AssignTarget(null, null, null, DirectMemoryWrite(directmemory().expression().toAst(), toPosition()), toPosition())
else -> AssignTarget(null, scoped_identifier()?.toAst(), null, null, toPosition())
identifier!=null -> AssignTarget(identifier.toAst(), null, null, toPosition())
arrayindexed()!=null -> AssignTarget(null, arrayindexed().toAst(), null, toPosition())
directmemory()!=null -> AssignTarget(null, null, DirectMemoryWrite(directmemory().expression().toAst(), toPosition()), toPosition())
else -> AssignTarget(scoped_identifier()?.toAst(), null, null, toPosition())
}
}
private fun prog8Parser.RegisterContext.toAst() = Register.valueOf(text.toUpperCase())
private fun prog8Parser.ClobberContext.toAst() : Set<CpuRegister> {
val names = this.identifier().map { it.toAst().nameInSource.single() }
return names.map { CpuRegister.valueOf(it) }.toSet()
}
private fun prog8Parser.DatatypeContext.toAst() = DataType.valueOf(text.toUpperCase())
private fun prog8Parser.RegisterorpairContext.toAst() = RegisterOrPair.valueOf(text.toUpperCase())
private fun prog8Parser.ArrayindexContext.toAst() : ArrayIndex =
ArrayIndex(expression().toAst(), toPosition())
private fun prog8Parser.DirectiveContext.toAst() : Directive =
Directive(directivename.text, directivearg().map { it.toAst() }, 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")
private fun prog8Parser.DirectiveargContext.toAst() : DirectiveArg =
DirectiveArg(stringliteral()?.text, identifier()?.text, integerliteral()?.toAst()?.number?.toInt(), toPosition())
return DirectiveArg(stringliteral()?.text, identifier()?.text, integerliteral()?.toAst()?.number?.toInt(), toPosition())
}
private fun prog8Parser.IntegerliteralContext.toAst(): NumericLiteral {
fun makeLiteral(text: String, radix: Int, forceWord: Boolean): NumericLiteral {
@ -408,7 +448,6 @@ private fun prog8Parser.IntegerliteralContext.toAst(): NumericLiteral {
}
}
private fun prog8Parser.ExpressionContext.toAst() : Expression {
val litval = literalvalue()
@ -429,10 +468,13 @@ private fun prog8Parser.ExpressionContext.toAst() : Expression {
else -> throw FatalAstException("invalid datatype for numeric literal")
}
litval.floatliteral()!=null -> NumericLiteralValue(DataType.FLOAT, litval.floatliteral().toAst(), litval.toPosition())
litval.stringliteral()!=null -> StringLiteralValue(DataType.STR, unescape(litval.stringliteral().text, litval.toPosition()), position = litval.toPosition())
litval.stringliteral()!=null -> litval.stringliteral().toAst()
litval.charliteral()!=null -> {
try {
NumericLiteralValue(DataType.UBYTE, Petscii.encodePetscii(unescape(litval.charliteral().text, litval.toPosition()), true)[0], 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())
}
@ -441,20 +483,13 @@ private fun prog8Parser.ExpressionContext.toAst() : Expression {
val array = litval.arrayliteral().toAst()
// the actual type of the arraysize can not yet be determined here (missing namespace & heap)
// the ConstantFold takes care of that and converts the type if needed.
ArrayLiteralValue(DataType.ARRAY_UB, array, position = litval.toPosition())
}
litval.structliteral()!=null -> {
val values = litval.structliteral().expression().map { it.toAst() }
StructLiteralValue(values, litval.toPosition())
ArrayLiteralValue(InferredTypes.InferredType.unknown(), array, position = litval.toPosition())
}
else -> throw FatalAstException("invalid parsed literal")
}
}
}
if(register()!=null)
return RegisterExpr(register().toAst(), register().toPosition())
if(scoped_identifier()!=null)
return scoped_identifier().toAst()
@ -468,7 +503,8 @@ private fun prog8Parser.ExpressionContext.toAst() : Expression {
if(funcall!=null) return funcall
if (rangefrom!=null && rangeto!=null) {
val step = rangestep?.toAst() ?: NumericLiteralValue(DataType.UBYTE, 1, 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())
}
@ -490,6 +526,8 @@ private fun prog8Parser.ExpressionContext.toAst() : Expression {
throw FatalAstException(text)
}
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(),
@ -497,28 +535,22 @@ private fun prog8Parser.ArrayindexedContext.toAst(): ArrayIndexedExpression {
toPosition())
}
private fun prog8Parser.Expression_listContext.toAst() = expression().map{ it.toAst() }
private fun prog8Parser.IdentifierContext.toAst() : IdentifierReference =
IdentifierReference(listOf(text), toPosition())
private fun prog8Parser.Scoped_identifierContext.toAst() : IdentifierReference =
IdentifierReference(NAME().map { it.text }, toPosition())
private fun prog8Parser.FloatliteralContext.toAst() = text.toDouble()
private fun prog8Parser.BooleanliteralContext.toAst() = when(text) {
"true" -> true
"false" -> false
else -> throw FatalAstException(text)
}
private fun prog8Parser.ArrayliteralContext.toAst() : Array<Expression> =
expression().map { it.toAst() }.toTypedArray()
@ -536,7 +568,6 @@ private fun prog8Parser.Else_partContext.toAst(): MutableList<Statement> {
return statement_block()?.toAst() ?: mutableListOf(statement().toAst())
}
private fun prog8Parser.Branch_stmtContext.toAst(): BranchStatement {
val branchcondition = branchcondition().toAst()
val trueStatements = statement_block()?.toAst() ?: mutableListOf(statement().toAst())
@ -549,25 +580,19 @@ private fun prog8Parser.Branch_stmtContext.toAst(): BranchStatement {
private fun prog8Parser.BranchconditionContext.toAst() = BranchCondition.valueOf(text.substringAfter('_').toUpperCase())
private fun prog8Parser.ForloopContext.toAst(): ForLoop {
val loopregister = register()?.toAst()
val loopvar = identifier()?.toAst()
val loopvar = identifier().toAst()
val iterable = expression()!!.toAst()
val scope =
if(statement()!=null)
AnonymousScope(mutableListOf(statement().toAst()), statement().toPosition())
else
AnonymousScope(statement_block().toAst(), statement_block().toPosition())
return ForLoop(loopregister, loopvar, iterable, scope, toPosition())
return ForLoop(loopvar, iterable, scope, toPosition())
}
private fun prog8Parser.ContinuestmtContext.toAst() = Continue(toPosition())
private fun prog8Parser.BreakstmtContext.toAst() = Break(toPosition())
private fun prog8Parser.WhileloopContext.toAst(): WhileLoop {
val condition = expression().toAst()
val statements = statement_block()?.toAst() ?: mutableListOf(statement().toAst())
@ -576,13 +601,20 @@ private fun prog8Parser.WhileloopContext.toAst(): WhileLoop {
return WhileLoop(condition, scope, toPosition())
}
private fun prog8Parser.RepeatloopContext.toAst(): RepeatLoop {
val iterations = expression()?.toAst()
val statements = statement_block()?.toAst() ?: mutableListOf(statement().toAst())
val scope = AnonymousScope(statements, statement_block()?.toPosition()
?: statement().toPosition())
return RepeatLoop(iterations, scope, toPosition())
}
private fun prog8Parser.UntilloopContext.toAst(): UntilLoop {
val untilCondition = expression().toAst()
val statements = statement_block()?.toAst() ?: mutableListOf(statement().toAst())
val scope = AnonymousScope(statements, statement_block()?.toPosition()
?: statement().toPosition())
return RepeatLoop(scope, untilCondition, toPosition())
return UntilLoop(scope, untilCondition, toPosition())
}
private fun prog8Parser.WhenstmtContext.toAst(): WhenStatement {
@ -641,4 +673,3 @@ internal fun unescape(str: String, position: Position): String {
}
return result.joinToString("")
}

47
compiler/src/prog8/ast/base/Base.kt
View File

@ -1,7 +1,8 @@
package prog8.ast.base
import prog8.ast.Node
import prog8.compiler.target.c64.MachineDefinition
import prog8.compiler.target.CompilationTarget
/**************************** AST Data classes ****************************/
@ -12,7 +13,6 @@ enum class DataType {
WORD, // pass by value
FLOAT, // pass by value
STR, // pass by reference
STR_S, // pass by reference
ARRAY_UB, // pass by reference
ARRAY_B, // pass by reference
ARRAY_UW, // pass by reference
@ -21,18 +21,16 @@ enum class DataType {
STRUCT; // pass by reference
/**
* is the type assignable to the given other type?
* is the type assignable to the given other type (perhaps via a typecast) without loss of precision?
*/
infix fun isAssignableTo(targetType: DataType) =
// what types are assignable to others without loss of precision?
when(this) {
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
STR -> targetType == STR
in ArrayDatatypes -> targetType == this
else -> false
}
@ -58,14 +56,14 @@ enum class DataType {
return when(this) {
in ByteDatatypes -> 1
in WordDatatypes -> 2
FLOAT -> MachineDefinition.Mflpt5.MemorySize
in PassByReferenceDatatypes -> 2
FLOAT -> CompilationTarget.machine.FLOAT_MEM_SIZE
in PassByReferenceDatatypes -> CompilationTarget.machine.POINTER_MEM_SIZE
else -> -9999999
}
}
}
enum class Register {
enum class CpuRegister {
A,
X,
Y
@ -77,14 +75,23 @@ enum class RegisterOrPair {
Y,
AX,
AY,
XY
XY;
companion object {
val names by lazy { values().map { it.toString()} }
}
} // only used in parameter and return value specs in asm subroutines
enum class Statusflag {
Pc,
Pz,
Pv,
Pn
Pn;
companion object {
val names by lazy { values().map { it.toString()} }
}
}
enum class BranchCondition {
@ -112,10 +119,9 @@ 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.STR_S,
DataType.STR,
DataType.ARRAY_UB, DataType.ARRAY_B,
DataType.ARRAY_UW, DataType.ARRAY_W,
DataType.ARRAY_F)
@ -123,12 +129,18 @@ val PassByValueDatatypes = NumericDatatypes
val PassByReferenceDatatypes = IterableDatatypes.plus(DataType.STRUCT)
val ArrayElementTypes = mapOf(
DataType.STR to DataType.UBYTE,
DataType.STR_S 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)
@ -146,8 +158,15 @@ object ParentSentinel : Node {
override val position = Position("<<sentinel>>", 0, 0, 0)
override var parent: Node = this
override fun linkParents(parent: Node) {}
override fun replaceChildNode(node: Node, replacement: Node) {
replacement.parent = this
}
}
data class Position(val file: String, val line: Int, val startCol: Int, val endCol: Int) {
override fun toString(): String = "[$file: line $line col ${startCol+1}-${endCol+1}]"
companion object {
val DUMMY = Position("<dummy>", 0, 0, 0)
}
}

67
compiler/src/prog8/ast/base/ErrorReporting.kt
View File

@ -3,35 +3,42 @@ package prog8.ast.base
import prog8.parser.ParsingFailedError
fun printErrors(errors: List<Any>, moduleName: String) {
val reportedMessages = mutableSetOf<String>()
print("\u001b[91m") // bright red
errors.forEach {
val msg = it.toString()
if(msg !in reportedMessages) {
System.err.println(msg)
reportedMessages.add(msg)
}
class ErrorReporter {
private enum class MessageSeverity {
WARNING,
ERROR
}
print("\u001b[0m") // reset color
if(reportedMessages.isNotEmpty())
throw ParsingFailedError("There are ${reportedMessages.size} errors in module '$moduleName'.")
}
fun printWarning(msg: String, position: Position, detailInfo: String?=null) {
print("\u001b[93m") // bright yellow
print("$position Warning: $msg")
if(detailInfo==null)
print("\n")
else
println(": $detailInfo\n")
print("\u001b[0m") // normal
}
fun printWarning(msg: String) {
print("\u001b[93m") // bright yellow
print("Warning: $msg")
print("\u001b[0m\n") // normal
private class CompilerMessage(val severity: MessageSeverity, val message: String, val position: Position)
private val messages = mutableListOf<CompilerMessage>()
private val alreadyReportedMessages = mutableSetOf<String>()
fun err(msg: String, position: Position) = messages.add(CompilerMessage(MessageSeverity.ERROR, msg, position))
fun warn(msg: String, position: Position) = messages.add(CompilerMessage(MessageSeverity.WARNING, msg, position))
fun handle() {
var numErrors = 0
var numWarnings = 0
messages.forEach {
when(it.severity) {
MessageSeverity.ERROR -> System.err.print("\u001b[91m") // bright red
MessageSeverity.WARNING -> System.err.print("\u001b[93m") // bright yellow
}
val msg = "${it.position} ${it.severity} ${it.message}".trim()
if(msg !in alreadyReportedMessages) {
System.err.println(msg)
alreadyReportedMessages.add(msg)
when(it.severity) {
MessageSeverity.WARNING -> numWarnings++
MessageSeverity.ERROR -> numErrors++
}
}
System.err.print("\u001b[0m") // reset color
}
messages.clear()
if(numErrors>0)
throw ParsingFailedError("There are $numErrors errors and $numWarnings warnings.")
}
fun isEmpty() = messages.isEmpty()
}

10
compiler/src/prog8/ast/base/Errors.kt
View File

@ -2,21 +2,17 @@ package prog8.ast.base
import prog8.ast.expressions.IdentifierReference
class FatalAstException (override var message: String) : Exception(message)
open class FatalAstException (override var message: String) : Exception(message)
open class AstException (override var message: String) : Exception(message)
class SyntaxError(override var message: String, val position: Position) : AstException(message) {
open class SyntaxError(override var message: String, val position: Position) : AstException(message) {
override fun toString() = "$position Syntax error: $message"
}
open class NameError(override var message: String, val position: Position) : AstException(message) {
override fun toString() = "$position Name error: $message"
}
class ExpressionError(message: String, val position: Position) : AstException(message) {
override fun toString() = "$position Error: $message"
}
class UndefinedSymbolError(symbol: IdentifierReference)
: NameError("undefined symbol: ${symbol.nameInSource.joinToString(".")}", symbol.position)
: SyntaxError("undefined symbol: ${symbol.nameInSource.joinToString(".")}", symbol.position)

80
compiler/src/prog8/ast/base/Extensions.kt
View File

@ -4,67 +4,67 @@ import prog8.ast.Module
import prog8.ast.Program
import prog8.ast.processing.*
import prog8.compiler.CompilationOptions
import prog8.compiler.target.c64.codegen.AnonymousScopeVarsCleanup
import prog8.optimizer.FlattenAnonymousScopesAndRemoveNops
import prog8.compiler.BeforeAsmGenerationAstChanger
// the name of the subroutine that should be called for every block to initialize its variables
internal const val initvarsSubName="prog8_init_vars"
internal fun Program.removeNopsFlattenAnonScopes() {
val flattener = FlattenAnonymousScopesAndRemoveNops()
flattener.visit(this)
}
internal fun Program.checkValid(compilerOptions: CompilationOptions) {
val checker = AstChecker(this, compilerOptions)
internal fun Program.checkValid(compilerOptions: CompilationOptions, errors: ErrorReporter) {
val checker = AstChecker(this, compilerOptions, errors)
checker.visit(this)
printErrors(checker.result(), name)
}
internal fun Program.anonscopeVarsCleanup() {
val mover = AnonymousScopeVarsCleanup(this)
mover.visit(this)
printErrors(mover.result(), name)
internal fun Program.processAstBeforeAsmGeneration(errors: ErrorReporter) {
val fixer = BeforeAsmGenerationAstChanger(this, errors)
fixer.visit(this)
fixer.applyModifications()
}
internal fun Program.reorderStatements() {
val initvalueCreator = VarInitValueAndAddressOfCreator(this)
initvalueCreator.visit(this)
val checker = StatementReorderer(this)
checker.visit(this)
val reorder = StatementReorderer(this)
reorder.visit(this)
reorder.applyModifications()
}
internal fun Program.addTypecasts() {
val caster = TypecastsAdder(this)
internal fun Program.addTypecasts(errors: ErrorReporter) {
val caster = TypecastsAdder(this, errors)
caster.visit(this)
caster.applyModifications()
}
internal fun Program.verifyFunctionArgTypes() {
val fixer = VerifyFunctionArgTypes(this)
fixer.visit(this)
}
internal fun Module.checkImportedValid() {
val checker = ImportedModuleDirectiveRemover()
checker.visit(this)
printErrors(checker.result(), name)
val imr = ImportedModuleDirectiveRemover()
imr.visit(this, this.parent)
imr.applyModifications()
}
internal fun Program.checkRecursion() {
val checker = AstRecursionChecker(namespace)
internal fun Program.checkRecursion(errors: ErrorReporter) {
val checker = AstRecursionChecker(namespace, errors)
checker.visit(this)
printErrors(checker.result(), name)
checker.processMessages(name)
}
internal fun Program.checkIdentifiers(errors: ErrorReporter) {
internal fun Program.checkIdentifiers() {
val checker = AstIdentifiersChecker(this)
checker.visit(this)
val checker2 = AstIdentifiersChecker(this, errors)
checker2.visit(this)
if(modules.map {it.name}.toSet().size != modules.size) {
throw FatalAstException("modules should all be unique")
if(errors.isEmpty()) {
val transforms = AstVariousTransforms(this)
transforms.visit(this)
transforms.applyModifications()
}
printErrors(checker.result(), name)
if (modules.map { it.name }.toSet().size != modules.size) {
throw FatalAstException("modules should all be unique")
}
}
internal fun Program.variousCleanups() {
val process = VariousCleanups()
process.visit(this)
process.applyModifications()
}

450
compiler/src/prog8/ast/expressions/AstExpressions.kt
View File

@ -1,21 +1,14 @@
package prog8.ast.expressions
import prog8.ast.IFunctionCall
import prog8.ast.INameScope
import prog8.ast.Node
import prog8.ast.Program
import prog8.ast.*
import prog8.ast.antlr.escape
import prog8.ast.base.*
import prog8.ast.processing.IAstModifyingVisitor
import prog8.ast.processing.AstWalker
import prog8.ast.processing.IAstVisitor
import prog8.ast.statements.ArrayIndex
import prog8.ast.statements.BuiltinFunctionStatementPlaceholder
import prog8.ast.statements.Subroutine
import prog8.ast.statements.VarDecl
import prog8.compiler.HeapValues
import prog8.compiler.IntegerOrAddressOf
import prog8.compiler.target.c64.Petscii
import prog8.ast.statements.*
import prog8.compiler.target.CompilationTarget
import prog8.functions.BuiltinFunctions
import prog8.functions.CannotEvaluateException
import prog8.functions.NotConstArgumentException
import prog8.functions.builtinFunctionReturnType
import java.util.*
@ -23,34 +16,52 @@ import kotlin.math.abs
val associativeOperators = setOf("+", "*", "&", "|", "^", "or", "and", "xor", "==", "!=")
val comparisonOperators = setOf("==", "!=", "<", ">", "<=", ">=")
sealed class Expression: Node {
abstract fun constValue(program: Program): NumericLiteralValue?
abstract fun accept(visitor: IAstModifyingVisitor): Expression
abstract fun accept(visitor: IAstVisitor)
abstract fun referencesIdentifiers(vararg name: String): Boolean // todo: remove this and add identifier usage tracking into CallGraph instead
abstract fun accept(visitor: AstWalker, parent: Node)
abstract fun referencesIdentifiers(vararg name: String): Boolean
abstract fun inferType(program: Program): InferredTypes.InferredType
infix fun isSameAs(assigntarget: AssignTarget) = assigntarget.isSameAs(this)
infix fun isSameAs(other: Expression): Boolean {
if(this===other)
return true
when(this) {
is RegisterExpr ->
return (other is RegisterExpr && other.register==register)
return when(this) {
is IdentifierReference ->
return (other is IdentifierReference && other.nameInSource==nameInSource)
(other is IdentifierReference && other.nameInSource==nameInSource)
is PrefixExpression ->
return (other is PrefixExpression && other.operator==operator && other.expression isSameAs expression)
(other is PrefixExpression && other.operator==operator && other.expression isSameAs expression)
is BinaryExpression ->
return (other is BinaryExpression && other.operator==operator
(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 is ArrayIndexedExpression && other.identifier.nameInSource == identifier.nameInSource
&& other.arrayspec.index isSameAs arrayspec.index)
}
else -> return other==this
is DirectMemoryRead -> {
(other is DirectMemoryRead && other.addressExpression isSameAs addressExpression)
}
is TypecastExpression -> {
(other is TypecastExpression && other.implicit==implicit && other.type==type && other.expression isSameAs expression)
}
is AddressOf -> {
(other is AddressOf && other.identifier.nameInSource == identifier.nameInSource)
}
is RangeExpr -> {
(other is RangeExpr && other.from==from && other.to==to && other.step==step)
}
is FunctionCall -> {
(other is FunctionCall && other.target.nameInSource == target.nameInSource
&& other.args.size == args.size
&& other.args.zip(args).all { it.first isSameAs it.second } )
}
else -> other==this
}
}
}
@ -64,11 +75,38 @@ class PrefixExpression(val operator: String, var expression: Expression, overrid
expression.linkParents(this)
}
override fun replaceChildNode(node: Node, replacement: Node) {
require(node === expression && replacement is Expression)
expression = replacement
replacement.parent = this
}
override fun constValue(program: Program): NumericLiteralValue? = null
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node)= visitor.visit(this, parent)
override fun referencesIdentifiers(vararg name: String) = expression.referencesIdentifiers(*name)
override fun inferType(program: Program): InferredTypes.InferredType = expression.inferType(program)
override fun inferType(program: Program): InferredTypes.InferredType {
val inferred = expression.inferType(program)
return when(operator) {
"+" -> inferred
"~", "not" -> {
when(inferred.typeOrElse(DataType.STRUCT)) {
in ByteDatatypes -> InferredTypes.knownFor(DataType.UBYTE)
in WordDatatypes -> InferredTypes.knownFor(DataType.UWORD)
else -> inferred
}
}
"-" -> {
when(inferred.typeOrElse(DataType.STRUCT)) {
in ByteDatatypes -> InferredTypes.knownFor(DataType.BYTE)
in WordDatatypes -> InferredTypes.knownFor(DataType.WORD)
else -> inferred
}
}
else -> throw FatalAstException("weird prefix expression operator")
}
}
override fun toString(): String {
return "Prefix($operator $expression)"
@ -84,6 +122,16 @@ class BinaryExpression(var left: Expression, var operator: String, var right: Ex
right.linkParents(this)
}
override fun replaceChildNode(node: Node, replacement: Node) {
require(replacement is Expression)
when {
node===left -> left = replacement
node===right -> right = replacement
else -> throw FatalAstException("invalid replace, no child $node")
}
replacement.parent = this
}
override fun toString(): String {
return "[$left $operator $right]"
}
@ -91,8 +139,9 @@ class BinaryExpression(var left: Expression, var operator: String, var right: Ex
// binary expression should actually have been optimized away into a single value, before const value was requested...
override fun constValue(program: Program): NumericLiteralValue? = null
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node)= visitor.visit(this, parent)
override fun referencesIdentifiers(vararg name: String) = left.referencesIdentifiers(*name) || right.referencesIdentifiers(*name)
override fun inferType(program: Program): InferredTypes.InferredType {
val leftDt = left.inferType(program)
@ -185,7 +234,7 @@ class BinaryExpression(var left: Expression, var operator: String, var right: Ex
class ArrayIndexedExpression(var identifier: IdentifierReference,
val arrayspec: ArrayIndex,
override val position: Position) : Expression() {
override val position: Position) : Expression(), IAssignable {
override lateinit var parent: Node
override fun linkParents(parent: Node) {
this.parent = parent
@ -193,16 +242,26 @@ class ArrayIndexedExpression(var identifier: IdentifierReference,
arrayspec.linkParents(this)
}
override fun replaceChildNode(node: Node, replacement: Node) {
when {
node===identifier -> identifier = replacement as IdentifierReference
node===arrayspec.index -> arrayspec.index = replacement as Expression
else -> throw FatalAstException("invalid replace")
}
replacement.parent = this
}
override fun constValue(program: Program): NumericLiteralValue? = null
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node)= visitor.visit(this, parent)
override fun referencesIdentifiers(vararg name: String) = identifier.referencesIdentifiers(*name)
override fun inferType(program: Program): InferredTypes.InferredType {
val target = identifier.targetStatement(program.namespace)
if (target is VarDecl) {
return when (target.datatype) {
in StringDatatypes -> InferredTypes.knownFor(DataType.UBYTE)
DataType.STR -> InferredTypes.knownFor(DataType.UBYTE)
in ArrayDatatypes -> InferredTypes.knownFor(ArrayElementTypes.getValue(target.datatype))
else -> InferredTypes.unknown()
}
@ -223,15 +282,24 @@ class TypecastExpression(var expression: Expression, var type: DataType, val imp
expression.linkParents(this)
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun replaceChildNode(node: Node, replacement: Node) {
require(replacement is Expression && node===expression)
expression = replacement
replacement.parent = this
}
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node)= visitor.visit(this, parent)
override fun referencesIdentifiers(vararg name: String) = expression.referencesIdentifiers(*name)
override fun inferType(program: Program): InferredTypes.InferredType = InferredTypes.knownFor(type)
override fun constValue(program: Program): NumericLiteralValue? {
val cv = expression.constValue(program) ?: return null
return cv.cast(type)
// val value = RuntimeValue(cv.type, cv.asNumericValue!!).cast(type)
// return LiteralValue.fromNumber(value.numericValue(), value.type, position).cast(type)
val cast = cv.cast(type)
return if(cast.isValid)
cast.valueOrZero()
else
null
}
override fun toString(): String {
@ -247,14 +315,20 @@ data class AddressOf(var identifier: IdentifierReference, override val position:
identifier.parent=this
}
override fun replaceChildNode(node: Node, replacement: Node) {
require(replacement is IdentifierReference && node===identifier)
identifier = replacement
replacement.parent = this
}
override fun constValue(program: Program): NumericLiteralValue? = null
override fun referencesIdentifiers(vararg name: String) = false
override fun inferType(program: Program): InferredTypes.InferredType = InferredTypes.knownFor(DataType.UWORD)
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node)= visitor.visit(this, parent)
}
class DirectMemoryRead(var addressExpression: Expression, override val position: Position) : Expression() {
class DirectMemoryRead(var addressExpression: Expression, override val position: Position) : Expression(), IAssignable {
override lateinit var parent: Node
override fun linkParents(parent: Node) {
@ -262,8 +336,15 @@ class DirectMemoryRead(var addressExpression: Expression, override val position:
this.addressExpression.linkParents(this)
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun replaceChildNode(node: Node, replacement: Node) {
require(replacement is Expression && node===addressExpression)
addressExpression = replacement
replacement.parent = this
}
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node)= visitor.visit(this, parent)
override fun referencesIdentifiers(vararg name: String) = false
override fun inferType(program: Program): InferredTypes.InferredType = InferredTypes.knownFor(DataType.UBYTE)
override fun constValue(program: Program): NumericLiteralValue? = null
@ -307,17 +388,21 @@ class NumericLiteralValue(val type: DataType, // only numerical types allowed
}
}
val asBooleanValue: Boolean = number!=0
val asBooleanValue: Boolean = number.toDouble() != 0.0
override fun linkParents(parent: Node) {
this.parent = parent
}
override fun replaceChildNode(node: Node, replacement: Node) {
throw FatalAstException("can't replace here")
}
override fun referencesIdentifiers(vararg name: String) = false
override fun constValue(program: Program) = this
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node)= visitor.visit(this, parent)
override fun toString(): String = "NumericLiteral(${type.name}:$number)"
@ -333,138 +418,129 @@ class NumericLiteralValue(val type: DataType, // only numerical types allowed
operator fun compareTo(other: NumericLiteralValue): Int = number.toDouble().compareTo(other.number.toDouble())
fun cast(targettype: DataType): NumericLiteralValue {
class CastValue(val isValid: Boolean, private val value: NumericLiteralValue?) {
fun valueOrZero() = if(isValid) value!! else NumericLiteralValue(DataType.UBYTE, 0, Position.DUMMY)
}
fun cast(targettype: DataType): CastValue {
if(type==targettype)
return this
return CastValue(true, this)
val numval = number.toDouble()
when(type) {
DataType.UBYTE -> {
if(targettype== DataType.BYTE && numval <= 127)
return NumericLiteralValue(targettype, number.toShort(), position)
return CastValue(true, NumericLiteralValue(targettype, number.toShort(), position))
if(targettype== DataType.WORD || targettype== DataType.UWORD)
return NumericLiteralValue(targettype, number.toInt(), position)
return CastValue(true, NumericLiteralValue(targettype, number.toInt(), position))
if(targettype== DataType.FLOAT)
return NumericLiteralValue(targettype, number.toDouble(), position)
return CastValue(true, NumericLiteralValue(targettype, number.toDouble(), position))
}
DataType.BYTE -> {
if(targettype== DataType.UBYTE && numval >= 0)
return NumericLiteralValue(targettype, number.toShort(), position)
return CastValue(true, NumericLiteralValue(targettype, number.toShort(), position))
if(targettype== DataType.UWORD && numval >= 0)
return NumericLiteralValue(targettype, number.toInt(), position)
return CastValue(true, NumericLiteralValue(targettype, number.toInt(), position))
if(targettype== DataType.WORD)
return NumericLiteralValue(targettype, number.toInt(), position)
return CastValue(true, NumericLiteralValue(targettype, number.toInt(), position))
if(targettype== DataType.FLOAT)
return NumericLiteralValue(targettype, number.toDouble(), position)
return CastValue(true, NumericLiteralValue(targettype, number.toDouble(), position))
}
DataType.UWORD -> {
if(targettype== DataType.BYTE && numval <= 127)
return NumericLiteralValue(targettype, number.toShort(), position)
return CastValue(true, NumericLiteralValue(targettype, number.toShort(), position))
if(targettype== DataType.UBYTE && numval <= 255)
return NumericLiteralValue(targettype, number.toShort(), position)
return CastValue(true, NumericLiteralValue(targettype, number.toShort(), position))
if(targettype== DataType.WORD && numval <= 32767)
return NumericLiteralValue(targettype, number.toInt(), position)
return CastValue(true, NumericLiteralValue(targettype, number.toInt(), position))
if(targettype== DataType.FLOAT)
return NumericLiteralValue(targettype, number.toDouble(), position)
return CastValue(true, NumericLiteralValue(targettype, number.toDouble(), position))
}
DataType.WORD -> {
if(targettype== DataType.BYTE && numval >= -128 && numval <=127)
return NumericLiteralValue(targettype, number.toShort(), position)
return CastValue(true, NumericLiteralValue(targettype, number.toShort(), position))
if(targettype== DataType.UBYTE && numval >= 0 && numval <= 255)
return NumericLiteralValue(targettype, number.toShort(), position)
return CastValue(true, NumericLiteralValue(targettype, number.toShort(), position))
if(targettype== DataType.UWORD && numval >=0)
return NumericLiteralValue(targettype, number.toInt(), position)
return CastValue(true, NumericLiteralValue(targettype, number.toInt(), position))
if(targettype== DataType.FLOAT)
return NumericLiteralValue(targettype, number.toDouble(), position)
return CastValue(true, NumericLiteralValue(targettype, number.toDouble(), position))
}
DataType.FLOAT -> {
if (targettype == DataType.BYTE && numval >= -128 && numval <=127)
return NumericLiteralValue(targettype, number.toShort(), position)
return CastValue(true, NumericLiteralValue(targettype, number.toShort(), position))
if (targettype == DataType.UBYTE && numval >=0 && numval <= 255)
return NumericLiteralValue(targettype, number.toShort(), position)
return CastValue(true, NumericLiteralValue(targettype, number.toShort(), position))
if (targettype == DataType.WORD && numval >= -32768 && numval <= 32767)
return NumericLiteralValue(targettype, number.toInt(), position)
return CastValue(true, NumericLiteralValue(targettype, number.toInt(), position))
if (targettype == DataType.UWORD && numval >=0 && numval <= 65535)
return NumericLiteralValue(targettype, number.toInt(), position)
return CastValue(true, NumericLiteralValue(targettype, number.toInt(), position))
}
else -> {}
}
throw ExpressionError("can't cast $type into $targettype", position)
return CastValue(false, null)
}
}
class StructLiteralValue(var values: List<Expression>,
override val position: Position): Expression() {
override lateinit var parent: Node
private var heapIdSequence = 0 // unique ids for strings and arrays "on the heap"
override fun linkParents(parent: Node) {
this.parent=parent
values.forEach { it.linkParents(this) }
}
override fun constValue(program: Program): NumericLiteralValue? = null
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun referencesIdentifiers(vararg name: String) = values.any { it.referencesIdentifiers(*name) }
override fun inferType(program: Program): InferredTypes.InferredType = InferredTypes.knownFor(DataType.STRUCT)
override fun toString(): String {
return "struct{ ${values.joinToString(", ")} }"
}
}
class StringLiteralValue(val type: DataType, // only string types
val value: String,
initHeapId: Int? =null,
class StringLiteralValue(val value: String,
val altEncoding: Boolean, // such as: screencodes instead of Petscii for the C64
override val position: Position) : Expression() {
override lateinit var parent: Node
var heapId = initHeapId
private set
val heapId = ++heapIdSequence
override fun linkParents(parent: Node) {
this.parent = parent
}
override fun replaceChildNode(node: Node, replacement: Node) {
throw FatalAstException("can't replace here")
}
override fun referencesIdentifiers(vararg name: String) = false
override fun constValue(program: Program): NumericLiteralValue? = null
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node)= visitor.visit(this, parent)
override fun toString(): String = "'${escape(value)}'"
override fun inferType(program: Program): InferredTypes.InferredType = InferredTypes.knownFor(type)
override fun inferType(program: Program): InferredTypes.InferredType = InferredTypes.knownFor(DataType.STR)
operator fun compareTo(other: StringLiteralValue): Int = value.compareTo(other.value)
override fun hashCode(): Int = Objects.hash(value, type)
override fun hashCode(): Int = Objects.hash(value, altEncoding)
override fun equals(other: Any?): Boolean {
if(other==null || other !is StringLiteralValue)
return false
return value==other.value && type==other.type
}
fun addToHeap(heap: HeapValues) {
if (heapId != null)
return
else
heapId = heap.addString(type, value)
return value==other.value && altEncoding == other.altEncoding
}
}
class ArrayLiteralValue(val type: DataType, // only array types
class ArrayLiteralValue(val type: InferredTypes.InferredType, // inferred because not all array literals hava a known type yet
val value: Array<Expression>,
initHeapId: Int? =null,
override val position: Position) : Expression() {
override lateinit var parent: Node
var heapId = initHeapId
private set
val heapId = ++heapIdSequence
override fun linkParents(parent: Node) {
this.parent = parent
value.forEach {it.linkParents(this)}
}
override fun replaceChildNode(node: Node, replacement: Node) {
require(replacement is Expression)
val idx = value.indexOfFirst { it===node }
value[idx] = replacement
replacement.parent = this
}
override fun referencesIdentifiers(vararg name: String) = value.any { it.referencesIdentifiers(*name) }
override fun constValue(program: Program): NumericLiteralValue? = null
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node)= visitor.visit(this, parent)
override fun toString(): String = "$value"
override fun inferType(program: Program): InferredTypes.InferredType = InferredTypes.knownFor(type)
override fun inferType(program: Program): InferredTypes.InferredType = if(type.isKnown) type else guessDatatype(program)
operator fun compareTo(other: ArrayLiteralValue): Int = throw ExpressionError("cannot order compare arrays", position)
override fun hashCode(): Int = Objects.hash(value, type)
override fun equals(other: Any?): Boolean {
@ -473,58 +549,58 @@ class ArrayLiteralValue(val type: DataType, // only array types
return type==other.type && value.contentEquals(other.value)
}
fun guessDatatype(program: Program): InferredTypes.InferredType {
// Educated guess of the desired array literal's datatype.
// If it's inside a for loop, assume the data type of the loop variable is what we want.
val forloop = parent as? ForLoop
if(forloop != null) {
val loopvarDt = forloop.loopVarDt(program)
if(loopvarDt.isKnown) {
return if(loopvarDt.typeOrElse(DataType.STRUCT) !in ElementArrayTypes)
InferredTypes.InferredType.unknown()
else
InferredTypes.InferredType.known(ElementArrayTypes.getValue(loopvarDt.typeOrElse(DataType.STRUCT)))
}
}
// otherwise, select the "biggegst" datatype based on the elements in the array.
val datatypesInArray = value.map { it.inferType(program) }
require(datatypesInArray.isNotEmpty() && datatypesInArray.all { it.isKnown }) { "can't determine type of empty array" }
val dts = datatypesInArray.map { it.typeOrElse(DataType.STRUCT) }
return when {
DataType.FLOAT in dts -> InferredTypes.InferredType.known(DataType.ARRAY_F)
DataType.WORD in dts -> InferredTypes.InferredType.known(DataType.ARRAY_W)
DataType.UWORD in dts -> InferredTypes.InferredType.known(DataType.ARRAY_UW)
DataType.BYTE in dts -> InferredTypes.InferredType.known(DataType.ARRAY_B)
DataType.UBYTE in dts -> InferredTypes.InferredType.known(DataType.ARRAY_UB)
else -> InferredTypes.InferredType.unknown()
}
}
fun cast(targettype: DataType): ArrayLiteralValue? {
if(type==targettype)
if(type.istype(targettype))
return this
if(targettype in ArrayDatatypes) {
val elementType = ArrayElementTypes.getValue(targettype)
val castArray = value.map{
val num = it as? NumericLiteralValue
if(num==null) {
// an array of UWORDs could possibly also contain AddressOfs
// an array of UWORDs could possibly also contain AddressOfs, other stuff can't be casted
if (elementType != DataType.UWORD || it !is AddressOf)
throw FatalAstException("weird array element $it")
return null // can't cast a value of the array, abort
it
} else {
try {
num.cast(elementType)
} catch(x: ExpressionError) {
return null
}
val cast = num.cast(elementType)
if(cast.isValid)
cast.valueOrZero()
else
return null // can't cast a value of the array, abort
}
}.toTypedArray()
return ArrayLiteralValue(targettype, castArray, position = position)
return ArrayLiteralValue(InferredTypes.InferredType.known(targettype), castArray, position = position)
}
return null // invalid type conversion from $this to $targettype
}
fun addToHeap(heap: HeapValues) {
if (heapId != null)
return
else {
if(value.any {it is AddressOf }) {
val intArrayWithAddressOfs = value.map {
when (it) {
is AddressOf -> IntegerOrAddressOf(null, it)
is NumericLiteralValue -> IntegerOrAddressOf(it.number.toInt(), null)
else -> throw FatalAstException("invalid datatype in array")
}
}
heapId = heap.addIntegerArray(type, intArrayWithAddressOfs.toTypedArray())
} else {
val valuesInArray = value.map { (it as? NumericLiteralValue)?.number }
if(null !in valuesInArray) {
heapId = if (type == DataType.ARRAY_F) {
val doubleArray = valuesInArray.map { it!!.toDouble() }.toDoubleArray()
heap.addDoublesArray(doubleArray)
} else {
val integerArray = valuesInArray.map { it!!.toInt() }
heap.addIntegerArray(type, integerArray.map { IntegerOrAddressOf(it, null) }.toTypedArray())
}
}
}
}
}
}
class RangeExpr(var from: Expression,
@ -540,9 +616,21 @@ class RangeExpr(var from: Expression,
step.linkParents(this)
}
override fun replaceChildNode(node: Node, replacement: Node) {
require(replacement is Expression)
when {
from===node -> from=replacement
to===node -> to=replacement
step===node -> step=replacement
else -> throw FatalAstException("invalid replacement")
}
replacement.parent = this
}
override fun constValue(program: Program): NumericLiteralValue? = null
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node)= visitor.visit(this, parent)
override fun referencesIdentifiers(vararg name: String): Boolean = from.referencesIdentifiers(*name) || to.referencesIdentifiers(*name)
override fun inferType(program: Program): InferredTypes.InferredType {
val fromDt=from.inferType(program)
@ -552,10 +640,16 @@ class RangeExpr(var from: Expression,
fromDt istype DataType.UBYTE && toDt istype DataType.UBYTE -> InferredTypes.knownFor(DataType.ARRAY_UB)
fromDt istype DataType.UWORD && toDt istype DataType.UWORD -> InferredTypes.knownFor(DataType.ARRAY_UW)
fromDt istype DataType.STR && toDt istype DataType.STR -> InferredTypes.knownFor(DataType.STR)
fromDt istype DataType.STR_S && toDt istype DataType.STR_S -> InferredTypes.knownFor(DataType.STR_S)
fromDt istype DataType.WORD || toDt istype DataType.WORD -> InferredTypes.knownFor(DataType.ARRAY_W)
fromDt istype DataType.BYTE || toDt istype DataType.BYTE -> InferredTypes.knownFor(DataType.ARRAY_B)
else -> InferredTypes.knownFor(DataType.ARRAY_UB)
else -> {
val fdt = fromDt.typeOrElse(DataType.STRUCT)
val tdt = toDt.typeOrElse(DataType.STRUCT)
if(fdt largerThan tdt)
InferredTypes.knownFor(ElementArrayTypes.getValue(fdt))
else
InferredTypes.knownFor(ElementArrayTypes.getValue(tdt))
}
}
}
override fun toString(): String {
@ -576,9 +670,9 @@ class RangeExpr(var from: Expression,
val fromString = from as? StringLiteralValue
val toString = to as? StringLiteralValue
if(fromString!=null && toString!=null ) {
// string range -> int range over petscii values
fromVal = Petscii.encodePetscii(fromString.value, true)[0].toInt()
toVal = Petscii.encodePetscii(toString.value, true)[0].toInt()
// string range -> int range over character values
fromVal = CompilationTarget.encodeString(fromString.value, fromString.altEncoding)[0].toInt()
toVal = CompilationTarget.encodeString(toString.value, fromString.altEncoding)[0].toInt()
} else {
val fromLv = from as? NumericLiteralValue
val toLv = to as? NumericLiteralValue
@ -608,25 +702,7 @@ internal fun makeRange(fromVal: Int, toVal: Int, stepVal: Int): IntProgression {
}
}
class RegisterExpr(val register: Register, override val position: Position) : Expression() {
override lateinit var parent: Node
override fun linkParents(parent: Node) {
this.parent = parent
}
override fun constValue(program: Program): NumericLiteralValue? = null
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun referencesIdentifiers(vararg name: String): Boolean = register.name in name
override fun toString(): String {
return "RegisterExpr(register=$register, pos=$position)"
}
override fun inferType(program: Program): InferredTypes.InferredType = InferredTypes.knownFor(DataType.UBYTE)
}
data class IdentifierReference(val nameInSource: List<String>, override val position: Position) : Expression() {
data class IdentifierReference(val nameInSource: List<String>, override val position: Position) : Expression(), IAssignable {
override lateinit var parent: Node
fun targetStatement(namespace: INameScope) =
@ -638,10 +714,17 @@ data class IdentifierReference(val nameInSource: List<String>, override val posi
fun targetVarDecl(namespace: INameScope): VarDecl? = targetStatement(namespace) as? VarDecl
fun targetSubroutine(namespace: INameScope): Subroutine? = targetStatement(namespace) as? Subroutine
override fun equals(other: Any?) = other is IdentifierReference && other.nameInSource==nameInSource
override fun hashCode() = nameInSource.hashCode()
override fun linkParents(parent: Node) {
this.parent = parent
}
override fun replaceChildNode(node: Node, replacement: Node) {
throw FatalAstException("can't replace here")
}
override fun constValue(program: Program): NumericLiteralValue? {
val node = program.namespace.lookup(nameInSource, this)
?: throw UndefinedSymbolError(this)
@ -658,16 +741,16 @@ data class IdentifierReference(val nameInSource: List<String>, override val posi
return "IdentifierRef($nameInSource)"
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node)= visitor.visit(this, parent)
override fun referencesIdentifiers(vararg name: String): Boolean = nameInSource.last() in name
override fun inferType(program: Program): InferredTypes.InferredType {
val targetStmt = targetStatement(program.namespace)
if(targetStmt is VarDecl) {
return InferredTypes.knownFor(targetStmt.datatype)
} else {
throw FatalAstException("cannot get datatype from identifier reference ${this}, pos=$position")
return when (val targetStmt = targetStatement(program.namespace)) {
is VarDecl -> InferredTypes.knownFor(targetStmt.datatype)
is StructDecl -> InferredTypes.knownFor(DataType.STRUCT)
else -> InferredTypes.InferredType.unknown()
}
}
@ -678,22 +761,32 @@ data class IdentifierReference(val nameInSource: List<String>, override val posi
val value = (node as? VarDecl)?.value ?: throw FatalAstException("requires a reference value")
return when (value) {
is IdentifierReference -> value.heapId(namespace)
is StringLiteralValue -> value.heapId ?: throw FatalAstException("string is not on the heap: $value")
is ArrayLiteralValue -> value.heapId ?: throw FatalAstException("array is not on the heap: $value")
is StringLiteralValue -> value.heapId
is ArrayLiteralValue -> value.heapId
else -> throw FatalAstException("requires a reference value")
}
}
}
class FunctionCall(override var target: IdentifierReference,
override var arglist: MutableList<Expression>,
override var args: MutableList<Expression>,
override val position: Position) : Expression(), IFunctionCall {
override lateinit var parent: Node
override fun linkParents(parent: Node) {
this.parent = parent
target.linkParents(this)
arglist.forEach { it.linkParents(this) }
args.forEach { it.linkParents(this) }
}
override fun replaceChildNode(node: Node, replacement: Node) {
if(node===target)
target=replacement as IdentifierReference
else {
val idx = args.indexOfFirst { it===node }
args[idx] = replacement as Expression
}
replacement.parent = this
}
override fun constValue(program: Program) = constValue(program, true)
@ -708,7 +801,7 @@ class FunctionCall(override var target: IdentifierReference,
if(func!=null) {
val exprfunc = func.constExpressionFunc
if(exprfunc!=null)
resultValue = exprfunc(arglist, position, program)
resultValue = exprfunc(args, position, program)
else if(func.returntype==null)
throw ExpressionError("builtin function ${target.nameInSource[0]} can't be used here because it doesn't return a value", position)
}
@ -726,15 +819,20 @@ class FunctionCall(override var target: IdentifierReference,
// const-evaluating the builtin function call failed.
return null
}
catch(x: CannotEvaluateException) {
// const-evaluating the builtin function call failed.
return null
}
}
override fun toString(): String {
return "FunctionCall(target=$target, pos=$position)"
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun referencesIdentifiers(vararg name: String): Boolean = target.referencesIdentifiers(*name) || arglist.any{it.referencesIdentifiers(*name)}
override fun accept(visitor: AstWalker, parent: Node)= visitor.visit(this, parent)
override fun referencesIdentifiers(vararg name: String): Boolean = target.referencesIdentifiers(*name) || args.any{it.referencesIdentifiers(*name)}
override fun inferType(program: Program): InferredTypes.InferredType {
val constVal = constValue(program ,false)
@ -747,7 +845,7 @@ class FunctionCall(override var target: IdentifierReference,
target.nameInSource[0] == "clear_carry" || target.nameInSource[0]=="clear_irqd") {
return InferredTypes.void() // these have no return value
}
return builtinFunctionReturnType(target.nameInSource[0], this.arglist, program)
return builtinFunctionReturnType(target.nameInSource[0], this.args, program)
}
is Subroutine -> {
if(stmt.returntypes.isEmpty())

10
compiler/src/prog8/ast/expressions/InferredTypes.kt
View File

@ -1,12 +1,13 @@
package prog8.ast.expressions
import prog8.ast.base.DataType
import java.util.*
object InferredTypes {
class InferredType private constructor(val isUnknown: Boolean, val isVoid: Boolean, private var datatype: DataType?) {
init {
if(datatype!=null && (isUnknown || isVoid))
throw IllegalArgumentException("invalid combination of args")
require(!(datatype!=null && (isUnknown || isVoid))) { "invalid combination of args" }
}
val isKnown = datatype!=null
@ -29,9 +30,11 @@ object InferredTypes {
return when {
datatype!=null -> datatype.toString()
isVoid -> "<void>"
else -> "<unkonwn>"
else -> "<unknown>"
}
}
override fun hashCode(): Int = Objects.hash(isVoid, datatype)
}
private val unknownInstance = InferredType.unknown()
@ -43,7 +46,6 @@ object InferredTypes {
DataType.WORD to InferredType.known(DataType.WORD),
DataType.FLOAT to InferredType.known(DataType.FLOAT),
DataType.STR to InferredType.known(DataType.STR),
DataType.STR_S to InferredType.known(DataType.STR_S),
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),

774
compiler/src/prog8/ast/processing/AstChecker.kt
View File

File diff suppressed because it is too large Load Diff

381
compiler/src/prog8/ast/processing/AstIdentifiersChecker.kt
View File

@ -1,113 +1,84 @@
package prog8.ast.processing
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.statements.*
import prog8.compiler.target.c64.AssemblyProgram
import prog8.compiler.target.CompilationTarget
import prog8.functions.BuiltinFunctions
internal class AstIdentifiersChecker(private val program: Program) : IAstModifyingVisitor {
private val checkResult: MutableList<AstException> = mutableListOf()
internal class AstIdentifiersChecker(private val program: Program, private val errors: ErrorReporter) : IAstVisitor {
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: Statement) {
checkResult.add(NameError("name conflict '$name', also defined in ${existing.position.file} line ${existing.position.line}", position))
errors.err("name conflict '$name', also defined in ${existing.position.file} line ${existing.position.line}", position)
}
override fun visit(module: Module) {
vardeclsToAdd.clear()
blocks.clear() // blocks may be redefined within a different module
super.visit(module)
// add any new vardecls to the various scopes
for((where, decls) in vardeclsToAdd) {
where.statements.addAll(0, decls)
decls.forEach { it.linkParents(where as Node) }
}
}
override fun visit(block: Block): Statement {
override fun visit(block: Block) {
if(block.name in CompilationTarget.machine.opcodeNames)
errors.err("can't use a cpu opcode name as a symbol: '${block.name}'", block.position)
val existing = blocks[block.name]
if(existing!=null)
nameError(block.name, block.position, existing)
else
blocks[block.name] = block
return super.visit(block)
super.visit(block)
}
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)
typecast.linkParents(functionCall.parent)
return super.visit(typecast)
}
return super.visit(functionCall)
}
override fun visit(decl: VarDecl) {
decl.datatypeErrors.forEach { errors.err(it.message, it.position) }
override fun visit(decl: VarDecl): Statement {
// first, check if there are datatype errors on the vardecl
decl.datatypeErrors.forEach { checkResult.add(it) }
// now check the identifier
if(decl.name in BuiltinFunctions)
// the builtin functions can't be redefined
checkResult.add(NameError("builtin function cannot be redefined", decl.position))
errors.err("builtin function cannot be redefined", decl.position)
if(decl.name in AssemblyProgram.opcodeNames)
checkResult.add(NameError("can't use a cpu opcode name as a symbol: '${decl.name}'", decl.position))
if(decl.name in CompilationTarget.machine.opcodeNames)
errors.err("can't use a cpu opcode name as a symbol: '${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)
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))
if (decl.struct == null) {
errors.err("undefined struct type", decl.position)
return super.visit(decl)
}
if(decl.struct!!.statements.any { (it as VarDecl).datatype !in NumericDatatypes})
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))
if (decl.value is NumericLiteralValue) {
errors.err("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
if (decl.value != null && decl.value !is ArrayLiteralValue) {
errors.err("initializing a struct requires array literal value", decl.value?.position ?: decl.position)
return super.visit(decl)
}
}
val existing = program.namespace.lookup(listOf(decl.name), decl)
if (existing != null && existing !== decl)
nameError(decl.name, decl.position, existing)
return super.visit(decl)
super.visit(decl)
}
override fun visit(subroutine: Subroutine): Statement {
if(subroutine.name in AssemblyProgram.opcodeNames) {
checkResult.add(NameError("can't use a cpu opcode name as a symbol: '${subroutine.name}'", subroutine.position))
override fun visit(subroutine: Subroutine) {
if(subroutine.name in CompilationTarget.machine.opcodeNames) {
errors.err("can't use a cpu opcode name as a symbol: '${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))
errors.err("builtin function cannot be redefined", subroutine.position)
} else {
// already reported elsewhere:
// if (subroutine.parameters.any { it.name in BuiltinFunctions })
@ -139,296 +110,50 @@ internal class AstIdentifiersChecker(private val program: Program) : IAstModifyi
nameError(name, sub.position, subroutine)
}
// inject subroutine params as local variables (if they're not there yet) (for non-kernel subroutines and non-asm parameters)
// 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)
if(subroutine.asmAddress==null) {
if(subroutine.asmParameterRegisters.isEmpty()) {
subroutine.parameters
.filter { it.name !in namesInSub }
.forEach {
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))
errors.err("asmsub can only contain inline assembly (%asm)", subroutine.position)
}
}
return super.visit(subroutine)
super.visit(subroutine)
}
override fun visit(label: Label): Statement {
if(label.name in AssemblyProgram.opcodeNames)
checkResult.add(NameError("can't use a cpu opcode name as a symbol: '${label.name}'", label.position))
override fun visit(label: Label) {
if(label.name in CompilationTarget.machine.opcodeNames)
errors.err("can't use a cpu opcode name as a symbol: '${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))
errors.err("builtin function cannot be redefined", label.position)
} else {
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): 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.loopRegister == Register.X)
printWarning("writing to the X register is dangerous, because it's used as an internal pointer", forLoop.position)
} 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'
}
val existing = label.definingSubroutine()?.getAllLabels(label.name) ?: emptyList()
for(el in existing) {
if(el === label || el.name != label.name)
continue
else {
nameError(label.name, label.position, el)
break
}
}
}
return super.visit(forLoop)
super.visit(label)
}
override fun visit(assignTarget: AssignTarget): AssignTarget {
if(assignTarget.register== Register.X)
printWarning("writing to the X register is dangerous, because it's used as an internal pointer", assignTarget.position)
return super.visit(assignTarget)
override fun visit(string: StringLiteralValue) {
if (string.value.length !in 1..255)
errors.err("string literal length must be between 1 and 255", string.position)
super.visit(string)
}
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!=1)
return returnStmt // mismatch in number of return values, error will be printed later.
val newValue: Expression
val lval = returnStmt.value as? NumericLiteralValue
if(lval!=null) {
newValue = lval.cast(subroutine.returntypes.single())
} else {
newValue = returnStmt.value!!
}
returnStmt.value = newValue
}
return super.visit(returnStmt)
}
override fun visit(arrayLiteral: ArrayLiteralValue): Expression {
val array = super.visit(arrayLiteral)
if(array is ArrayLiteralValue) {
val vardecl = array.parent as? VarDecl
return if (vardecl!=null) {
fixupArrayDatatype(array, vardecl, program)
} else if(array.heapId!=null) {
// fix the datatype of the array (also on the heap) to the 'biggest' datatype in the array
// (we don't know the desired datatype here exactly so we guess)
val datatype = determineArrayDt(array.value)
val litval2 = array.cast(datatype)!!
litval2.parent = array.parent
// finally, replace the literal array by a identifier reference.
makeIdentifierFromRefLv(litval2)
} else
array
}
return array
}
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))
else {
string.addToHeap(program.heap)
}
return if (vardecl != null)
string
else
makeIdentifierFromRefLv(string) // replace the literal string by a identifier reference.
}
return string
}
private fun determineArrayDt(array: Array<Expression>): DataType {
val datatypesInArray = array.map { it.inferType(program) }
if(datatypesInArray.isEmpty() || datatypesInArray.any { !it.isKnown })
throw IllegalArgumentException("can't determine type of empty array")
val dts = datatypesInArray.map { it.typeOrElse(DataType.STRUCT) }
return when {
DataType.FLOAT in dts -> DataType.ARRAY_F
DataType.WORD in dts -> DataType.ARRAY_W
DataType.UWORD in dts -> DataType.ARRAY_UW
DataType.BYTE in dts -> DataType.ARRAY_B
DataType.UBYTE in dts -> DataType.ARRAY_UB
else -> throw IllegalArgumentException("can't determine type of array")
}
}
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.
array.addToHeap(program.heap)
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.
string.addToHeap(program.heap)
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 {
override fun visit(structDecl: StructDecl) {
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))
errors.err("structs can only contain numerical types", decl.position)
}
return super.visit(structDecl)
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
val idt = string.inferType(program)
return StringLiteralValue(idt.typeOrElse(DataType.STR),
string.value.repeat(constvalue.number.toInt()), null, expr.position)
}
}
if(expr.operator == "+" && operand is StringLiteralValue) {
// concatenate two strings
val idt = string.inferType(program)
return StringLiteralValue(idt.typeOrElse(DataType.STR),
"${string.value}${operand.value}", null, 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
}
}
}
internal fun fixupArrayDatatype(array: ArrayLiteralValue, program: Program): ArrayLiteralValue {
val dts = array.value.map {it.inferType(program).typeOrElse(DataType.STRUCT)}.toSet()
if(dts.any { it !in NumericDatatypes }) {
return array
}
val dt = when {
DataType.FLOAT in dts -> DataType.ARRAY_F
DataType.WORD in dts -> DataType.ARRAY_W
DataType.UWORD in dts -> DataType.ARRAY_UW
DataType.BYTE in dts -> DataType.ARRAY_B
else -> DataType.ARRAY_UB
}
if(dt==array.type)
return array
// convert values and array type
val elementType = ArrayElementTypes.getValue(dt)
val values = array.value.map { (it as NumericLiteralValue).cast(elementType) as Expression}.toTypedArray()
val array2 = ArrayLiteralValue(dt, values, array.heapId, array.position)
array2.linkParents(array.parent)
return array2
}
internal fun fixupArrayDatatype(array: ArrayLiteralValue, vardecl: VarDecl, program: Program): ArrayLiteralValue {
if(array.heapId!=null) {
val arrayDt = array.type
if(arrayDt!=vardecl.datatype) {
// fix the datatype of the array (also on the heap) to match the vardecl
val litval2 =
try {
val result = array.cast(vardecl.datatype)
if(result==null) {
val constElements = array.value.mapNotNull { it.constValue(program) }
val elementDts = constElements.map { it.type }
if(DataType.FLOAT in elementDts) {
array.cast(DataType.ARRAY_F) ?: ArrayLiteralValue(DataType.ARRAY_F, array.value, array.heapId, array.position)
} else {
val numbers = constElements.map { it.number.toInt() }
val minValue = numbers.min()!!
val maxValue = numbers.max()!!
if (minValue >= 0) {
// only positive values, so uword or ubyte
val dt = if(maxValue<256) DataType.ARRAY_UB else DataType.ARRAY_UW
array.cast(dt) ?: ArrayLiteralValue(dt, array.value, array.heapId, array.position)
} else {
// negative value present, so word or byte
val dt = if(minValue >= -128 && maxValue<=127) DataType.ARRAY_B else DataType.ARRAY_W
array.cast(dt) ?: ArrayLiteralValue(dt, array.value, array.heapId, array.position)
}
}
}
else result
} catch(x: ExpressionError) {
// couldn't cast permanently.
// instead, simply adjust the array type and trust the AstChecker to report the exact error
ArrayLiteralValue(vardecl.datatype, array.value, array.heapId, array.position)
}
vardecl.value = litval2
litval2.linkParents(vardecl)
litval2.addToHeap(program.heap)
return litval2
}
}
return array
}

13
compiler/src/prog8/ast/processing/AstRecursionChecker.kt
View File

@ -1,21 +1,23 @@
package prog8.ast.processing
import prog8.ast.INameScope
import prog8.ast.base.AstException
import prog8.ast.base.ErrorReporter
import prog8.ast.base.Position
import prog8.ast.expressions.FunctionCall
import prog8.ast.statements.FunctionCallStatement
import prog8.ast.statements.Subroutine
internal class AstRecursionChecker(private val namespace: INameScope) : IAstVisitor {
internal class AstRecursionChecker(private val namespace: INameScope,
private val errors: ErrorReporter) : IAstVisitor {
private val callGraph = DirectedGraph<INameScope>()
internal fun result(): List<AstException> {
fun processMessages(modulename: String) {
val cycle = callGraph.checkForCycle()
if(cycle.isEmpty())
return emptyList()
return
val chain = cycle.joinToString(" <-- ") { "${it.name} at ${it.position}" }
return listOf(AstException("Program contains recursive subroutine calls, this is not supported. Recursive chain:\n (a subroutine call in) $chain"))
errors.err("Program contains recursive subroutine calls, this is not supported. Recursive chain:\n (a subroutine call in) $chain", Position.DUMMY)
}
override fun visit(functionCallStatement: FunctionCallStatement) {
@ -44,7 +46,6 @@ internal class AstRecursionChecker(private val namespace: INameScope) : IAstVisi
super.visit(functionCall)
}
private class DirectedGraph<VT> {
private val graph = mutableMapOf<VT, MutableSet<VT>>()
private var uniqueVertices = mutableSetOf<VT>()

161
compiler/src/prog8/ast/processing/AstVariousTransforms.kt Normal file
View File

@ -0,0 +1,161 @@
package prog8.ast.processing
import prog8.ast.Node
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.ast.statements.*
internal class AstVariousTransforms(private val program: Program) : AstWalker() {
private val noModifications = emptyList<IAstModification>()
override fun after(functionCallStatement: FunctionCallStatement, parent: Node): Iterable<IAstModification> {
if(functionCallStatement.target.nameInSource == listOf("swap")) {
// if x and y are both just identifiers, do not rewrite (there should be asm generation for that)
// otherwise:
// rewrite swap(x,y) as follows:
// - declare a temp variable of the same datatype
// - temp = x, x = y, y= temp
val first = functionCallStatement.args[0]
val second = functionCallStatement.args[1]
if(first !is IdentifierReference && second !is IdentifierReference) {
val dt = first.inferType(program).typeOrElse(DataType.STRUCT)
val tempname = "prog8_swaptmp_${functionCallStatement.hashCode()}"
val tempvardecl = VarDecl(VarDeclType.VAR, dt, ZeropageWish.DONTCARE, null, tempname, null, null, isArray = false, autogeneratedDontRemove = true, position = first.position)
val tempvar = IdentifierReference(listOf(tempname), first.position)
val assignTemp = Assignment(
AssignTarget(tempvar, null, null, first.position),
first,
first.position
)
val assignFirst = Assignment(
AssignTarget.fromExpr(first),
second,
first.position
)
val assignSecond = Assignment(
AssignTarget.fromExpr(second),
tempvar,
first.position
)
val scope = AnonymousScope(mutableListOf(tempvardecl, assignTemp, assignFirst, assignSecond), first.position)
return listOf(IAstModification.ReplaceNode(functionCallStatement, scope, parent))
}
}
return noModifications
}
override fun before(decl: VarDecl, parent: Node): Iterable<IAstModification> {
// 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 && !decl.structHasBeenFlattened) {
val decls = decl.flattenStructMembers()
decls.add(decl)
val result = AnonymousScope(decls, decl.position)
return listOf(IAstModification.ReplaceNode(
decl, result, parent
))
}
return noModifications
}
override fun after(subroutine: Subroutine, parent: Node): Iterable<IAstModification> {
// For non-kernel subroutines and non-asm parameters:
// inject subroutine params as local variables (if they're not there yet).
val symbolsInSub = subroutine.allDefinedSymbols()
val namesInSub = symbolsInSub.map{ it.first }.toSet()
if(subroutine.asmAddress==null) {
if(subroutine.asmParameterRegisters.isEmpty() && subroutine.parameters.isNotEmpty()) {
val vars = subroutine.statements.filterIsInstance<VarDecl>().map { it.name }.toSet()
if(!vars.containsAll(subroutine.parameters.map{it.name})) {
return subroutine.parameters
.filter { it.name !in namesInSub }
.map {
val vardecl = ParameterVarDecl(it.name, it.type, subroutine.position)
IAstModification.InsertFirst(vardecl, subroutine)
}
}
}
}
return noModifications
}
override fun before(expr: BinaryExpression, parent: Node): Iterable<IAstModification> {
when {
expr.left is StringLiteralValue ->
return listOf(IAstModification.ReplaceNode(
expr,
processBinaryExprWithString(expr.left as StringLiteralValue, expr.right, expr),
parent
))
expr.right is StringLiteralValue ->
return listOf(IAstModification.ReplaceNode(
expr,
processBinaryExprWithString(expr.right as StringLiteralValue, expr.left, expr),
parent
))
}
return noModifications
}
override fun after(string: StringLiteralValue, parent: Node): Iterable<IAstModification> {
if(string.parent !is VarDecl) {
// replace the literal string by a identifier reference to a new local vardecl
val vardecl = VarDecl.createAuto(string)
val identifier = IdentifierReference(listOf(vardecl.name), vardecl.position)
return listOf(
IAstModification.ReplaceNode(string, identifier, parent),
IAstModification.InsertFirst(vardecl, string.definingScope() as Node)
)
}
return noModifications
}
override fun after(array: ArrayLiteralValue, parent: Node): Iterable<IAstModification> {
val vardecl = array.parent as? VarDecl
if(vardecl!=null) {
// adjust the datatype of the array (to an educated guess)
val arrayDt = array.type
if(!arrayDt.istype(vardecl.datatype)) {
val cast = array.cast(vardecl.datatype)
if (cast != null && cast!=array)
return listOf(IAstModification.ReplaceNode(vardecl.value!!, cast, vardecl))
}
} 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))
if(litval2!=null && litval2!=array) {
val vardecl2 = VarDecl.createAuto(litval2)
val identifier = IdentifierReference(listOf(vardecl2.name), vardecl2.position)
return listOf(
IAstModification.ReplaceNode(array, identifier, parent),
IAstModification.InsertFirst(vardecl2, array.definingScope() as Node)
)
}
}
}
return noModifications
}
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
}
}

442
compiler/src/prog8/ast/processing/AstWalker.kt Normal file
View File

@ -0,0 +1,442 @@
package prog8.ast.processing
import prog8.ast.*
import prog8.ast.base.FatalAstException
import prog8.ast.expressions.*
import prog8.ast.statements.*
interface IAstModification {
fun perform()
class Remove(val node: Node, val parent: Node) : IAstModification {
override fun perform() {
if(parent is INameScope) {
if (!parent.statements.remove(node) && parent !is GlobalNamespace)
throw FatalAstException("attempt to remove non-existing node $node")
} else {
throw FatalAstException("parent of a remove modification is not an INameScope")
}
}
}
class SetExpression(val setter: (newExpr: Expression) -> Unit, val newExpr: Expression, val parent: Node) : IAstModification {
override fun perform() {
setter(newExpr)
newExpr.linkParents(parent)
}
}
class InsertFirst(val stmt: Statement, val parent: Node) : IAstModification {
override fun perform() {
if(parent is INameScope) {
parent.statements.add(0, stmt)
stmt.linkParents(parent)
} else {
throw FatalAstException("parent of an insert modification is not an INameScope")
}
}
}
class InsertLast(val stmt: Statement, val parent: Node) : IAstModification {
override fun perform() {
if(parent is INameScope) {
parent.statements.add(stmt)
stmt.linkParents(parent)
} else {
throw FatalAstException("parent of an insert modification is not an INameScope")
}
}
}
class InsertAfter(val after: Statement, val stmt: Statement, val parent: Node) : IAstModification {
override fun perform() {
if(parent is INameScope) {
val idx = parent.statements.indexOfFirst { it===after } + 1
parent.statements.add(idx, stmt)
stmt.linkParents(parent)
} else {
throw FatalAstException("parent of an insert modification is not an INameScope")
}
}
}
class InsertBefore(val before: Statement, val stmt: Statement, val parent: Node) : IAstModification {
override fun perform() {
if(parent is INameScope) {
val idx = parent.statements.indexOfFirst { it===before }
parent.statements.add(idx, stmt)
stmt.linkParents(parent)
} else {
throw FatalAstException("parent of an insert modification is not an INameScope")
}
}
}
class ReplaceNode(val node: Node, val replacement: Node, val parent: Node) : IAstModification {
override fun perform() {
parent.replaceChildNode(node, replacement)
replacement.linkParents(parent)
}
}
class SwapOperands(val expr: BinaryExpression): IAstModification {
override fun perform() {
val tmp = expr.left
expr.left = expr.right
expr.right = tmp
}
}
}
abstract class AstWalker {
open fun before(addressOf: AddressOf, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(array: ArrayLiteralValue, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(arrayIndexedExpression: ArrayIndexedExpression, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(assignTarget: AssignTarget, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(assignment: Assignment, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(block: Block, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(branchStatement: BranchStatement, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(breakStmt: Break, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(builtinFunctionStatementPlaceholder: BuiltinFunctionStatementPlaceholder, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(decl: VarDecl, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(directive: Directive, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(expr: BinaryExpression, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(expr: PrefixExpression, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(forLoop: ForLoop, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(repeatLoop: RepeatLoop, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(functionCall: FunctionCall, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(functionCallStatement: FunctionCallStatement, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(identifier: IdentifierReference, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(ifStatement: IfStatement, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(inlineAssembly: InlineAssembly, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(jump: Jump, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(label: Label, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(memread: DirectMemoryRead, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(memwrite: DirectMemoryWrite, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(module: Module, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(nopStatement: NopStatement, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(numLiteral: NumericLiteralValue, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(postIncrDecr: PostIncrDecr, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(program: Program, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(range: RangeExpr, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(untilLoop: UntilLoop, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(returnStmt: Return, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(scope: AnonymousScope, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(string: StringLiteralValue, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(structDecl: StructDecl, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(subroutine: Subroutine, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(typecast: TypecastExpression, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(whenChoice: WhenChoice, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(whenStatement: WhenStatement, parent: Node): Iterable<IAstModification> = emptyList()
open fun before(whileLoop: WhileLoop, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(addressOf: AddressOf, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(array: ArrayLiteralValue, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(arrayIndexedExpression: ArrayIndexedExpression, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(assignTarget: AssignTarget, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(assignment: Assignment, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(block: Block, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(branchStatement: BranchStatement, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(breakStmt: Break, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(builtinFunctionStatementPlaceholder: BuiltinFunctionStatementPlaceholder, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(decl: VarDecl, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(directive: Directive, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(expr: BinaryExpression, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(expr: PrefixExpression, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(forLoop: ForLoop, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(repeatLoop: RepeatLoop, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(functionCall: FunctionCall, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(functionCallStatement: FunctionCallStatement, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(identifier: IdentifierReference, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(ifStatement: IfStatement, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(inlineAssembly: InlineAssembly, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(jump: Jump, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(label: Label, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(memread: DirectMemoryRead, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(memwrite: DirectMemoryWrite, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(module: Module, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(nopStatement: NopStatement, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(numLiteral: NumericLiteralValue, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(postIncrDecr: PostIncrDecr, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(program: Program, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(range: RangeExpr, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(untilLoop: UntilLoop, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(returnStmt: Return, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(scope: AnonymousScope, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(string: StringLiteralValue, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(structDecl: StructDecl, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(subroutine: Subroutine, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(typecast: TypecastExpression, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(whenChoice: WhenChoice, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(whenStatement: WhenStatement, parent: Node): Iterable<IAstModification> = emptyList()
open fun after(whileLoop: WhileLoop, parent: Node): Iterable<IAstModification> = emptyList()
private val modifications = mutableListOf<Triple<IAstModification, Node, Node>>()
private fun track(mods: Iterable<IAstModification>, node: Node, parent: Node) {
for (it in mods) modifications += Triple(it, node, parent)
}
fun applyModifications(): Int {
modifications.forEach {
it.first.perform()
}
val amount = modifications.size
modifications.clear()
return amount
}
fun visit(program: Program) {
track(before(program, program), program, program)
program.modules.forEach { it.accept(this, program) }
track(after(program, program), program, program)
}
fun visit(module: Module, parent: Node) {
track(before(module, parent), module, parent)
module.statements.forEach{ it.accept(this, module) }
track(after(module, parent), module, parent)
}
fun visit(expr: PrefixExpression, parent: Node) {
track(before(expr, parent), expr, parent)
expr.expression.accept(this, expr)
track(after(expr, parent), expr, parent)
}
fun visit(expr: BinaryExpression, parent: Node) {
track(before(expr, parent), expr, parent)
expr.left.accept(this, expr)
expr.right.accept(this, expr)
track(after(expr, parent), expr, parent)
}
fun visit(directive: Directive, parent: Node) {
track(before(directive, parent), directive, parent)
track(after(directive, parent), directive, parent)
}
fun visit(block: Block, parent: Node) {
track(before(block, parent), block, parent)
block.statements.forEach { it.accept(this, block) }
track(after(block, parent), block, parent)
}
fun visit(decl: VarDecl, parent: Node) {
track(before(decl, parent), decl, parent)
decl.value?.accept(this, decl)
decl.arraysize?.accept(this, decl)
track(after(decl, parent), decl, parent)
}
fun visit(subroutine: Subroutine, parent: Node) {
track(before(subroutine, parent), subroutine, parent)
subroutine.statements.forEach { it.accept(this, subroutine) }
track(after(subroutine, parent), subroutine, parent)
}
fun visit(functionCall: FunctionCall, parent: Node) {
track(before(functionCall, parent), functionCall, parent)
functionCall.target.accept(this, functionCall)
functionCall.args.forEach { it.accept(this, functionCall) }
track(after(functionCall, parent), functionCall, parent)
}
fun visit(functionCallStatement: FunctionCallStatement, parent: Node) {
track(before(functionCallStatement, parent), functionCallStatement, parent)
functionCallStatement.target.accept(this, functionCallStatement)
functionCallStatement.args.forEach { it.accept(this, functionCallStatement) }
track(after(functionCallStatement, parent), functionCallStatement, parent)
}
fun visit(identifier: IdentifierReference, parent: Node) {
track(before(identifier, parent), identifier, parent)
track(after(identifier, parent), identifier, parent)
}
fun visit(jump: Jump, parent: Node) {
track(before(jump, parent), jump, parent)
jump.identifier?.accept(this, jump)
track(after(jump, parent), jump, parent)
}
fun visit(ifStatement: IfStatement, parent: Node) {
track(before(ifStatement, parent), ifStatement, parent)
ifStatement.condition.accept(this, ifStatement)
ifStatement.truepart.accept(this, ifStatement)
ifStatement.elsepart.accept(this, ifStatement)
track(after(ifStatement, parent), ifStatement, parent)
}
fun visit(branchStatement: BranchStatement, parent: Node) {
track(before(branchStatement, parent), branchStatement, parent)
branchStatement.truepart.accept(this, branchStatement)
branchStatement.elsepart.accept(this, branchStatement)
track(after(branchStatement, parent), branchStatement, parent)
}
fun visit(range: RangeExpr, parent: Node) {
track(before(range, parent), range, parent)
range.from.accept(this, range)
range.to.accept(this, range)
range.step.accept(this, range)
track(after(range, parent), range, parent)
}
fun visit(label: Label, parent: Node) {
track(before(label, parent), label, parent)
track(after(label, parent), label, parent)
}
fun visit(numLiteral: NumericLiteralValue, parent: Node) {
track(before(numLiteral, parent), numLiteral, parent)
track(after(numLiteral, parent), numLiteral, parent)
}
fun visit(string: StringLiteralValue, parent: Node) {
track(before(string, parent), string, parent)
track(after(string, parent), string, parent)
}
fun visit(array: ArrayLiteralValue, parent: Node) {
track(before(array, parent), array, parent)
array.value.forEach { v->v.accept(this, array) }
track(after(array, parent), array, parent)
}
fun visit(assignment: Assignment, parent: Node) {
track(before(assignment, parent), assignment, parent)
assignment.target.accept(this, assignment)
assignment.value.accept(this, assignment)
track(after(assignment, parent), assignment, parent)
}
fun visit(postIncrDecr: PostIncrDecr, parent: Node) {
track(before(postIncrDecr, parent), postIncrDecr, parent)
postIncrDecr.target.accept(this, postIncrDecr)
track(after(postIncrDecr, parent), postIncrDecr, parent)
}
fun visit(breakStmt: Break, parent: Node) {
track(before(breakStmt, parent), breakStmt, parent)
track(after(breakStmt, parent), breakStmt, parent)
}
fun visit(forLoop: ForLoop, parent: Node) {
track(before(forLoop, parent), forLoop, parent)
forLoop.loopVar.accept(this, forLoop)
forLoop.iterable.accept(this, forLoop)
forLoop.body.accept(this, forLoop)
track(after(forLoop, parent), forLoop, parent)
}
fun visit(whileLoop: WhileLoop, parent: Node) {
track(before(whileLoop, parent), whileLoop, parent)
whileLoop.condition.accept(this, whileLoop)
whileLoop.body.accept(this, whileLoop)
track(after(whileLoop, parent), whileLoop, parent)
}
fun visit(repeatLoop: RepeatLoop, parent: Node) {
track(before(repeatLoop, parent), repeatLoop, parent)
repeatLoop.iterations?.accept(this, repeatLoop)
repeatLoop.body.accept(this, repeatLoop)
track(after(repeatLoop, parent), repeatLoop, parent)
}
fun visit(untilLoop: UntilLoop, parent: Node) {
track(before(untilLoop, parent), untilLoop, parent)
untilLoop.untilCondition.accept(this, untilLoop)
untilLoop.body.accept(this, untilLoop)
track(after(untilLoop, parent), untilLoop, parent)
}
fun visit(returnStmt: Return, parent: Node) {
track(before(returnStmt, parent), returnStmt, parent)
returnStmt.value?.accept(this, returnStmt)
track(after(returnStmt, parent), returnStmt, parent)
}
fun visit(arrayIndexedExpression: ArrayIndexedExpression, parent: Node) {
track(before(arrayIndexedExpression, parent), arrayIndexedExpression, parent)
arrayIndexedExpression.identifier.accept(this, arrayIndexedExpression)
arrayIndexedExpression.arrayspec.accept(this, arrayIndexedExpression)
track(after(arrayIndexedExpression, parent), arrayIndexedExpression, parent)
}
fun visit(assignTarget: AssignTarget, parent: Node) {
track(before(assignTarget, parent), assignTarget, parent)
assignTarget.arrayindexed?.accept(this, assignTarget)
assignTarget.identifier?.accept(this, assignTarget)
assignTarget.memoryAddress?.accept(this, assignTarget)
track(after(assignTarget, parent), assignTarget, parent)
}
fun visit(scope: AnonymousScope, parent: Node) {
track(before(scope, parent), scope, parent)
scope.statements.forEach { it.accept(this, scope) }
track(after(scope, parent), scope, parent)
}
fun visit(typecast: TypecastExpression, parent: Node) {
track(before(typecast, parent), typecast, parent)
typecast.expression.accept(this, typecast)
track(after(typecast, parent), typecast, parent)
}
fun visit(memread: DirectMemoryRead, parent: Node) {
track(before(memread, parent), memread, parent)
memread.addressExpression.accept(this, memread)
track(after(memread, parent), memread, parent)
}
fun visit(memwrite: DirectMemoryWrite, parent: Node) {
track(before(memwrite, parent), memwrite, parent)
memwrite.addressExpression.accept(this, memwrite)
track(after(memwrite, parent), memwrite, parent)
}
fun visit(addressOf: AddressOf, parent: Node) {
track(before(addressOf, parent), addressOf, parent)
addressOf.identifier.accept(this, addressOf)
track(after(addressOf, parent), addressOf, parent)
}
fun visit(inlineAssembly: InlineAssembly, parent: Node) {
track(before(inlineAssembly, parent), inlineAssembly, parent)
track(after(inlineAssembly, parent), inlineAssembly, parent)
}
fun visit(builtinFunctionStatementPlaceholder: BuiltinFunctionStatementPlaceholder, parent: Node) {
track(before(builtinFunctionStatementPlaceholder, parent), builtinFunctionStatementPlaceholder, parent)
track(after(builtinFunctionStatementPlaceholder, parent), builtinFunctionStatementPlaceholder, parent)
}
fun visit(nopStatement: NopStatement, parent: Node) {
track(before(nopStatement, parent), nopStatement, parent)
track(after(nopStatement, parent), nopStatement, parent)
}
fun visit(whenStatement: WhenStatement, parent: Node) {
track(before(whenStatement, parent), whenStatement, parent)
whenStatement.condition.accept(this, whenStatement)
whenStatement.choices.forEach { it.accept(this, whenStatement) }
track(after(whenStatement, parent), whenStatement, parent)
}
fun visit(whenChoice: WhenChoice, parent: Node) {
track(before(whenChoice, parent), whenChoice, parent)
whenChoice.values?.forEach { it.accept(this, whenChoice) }
whenChoice.statements.accept(this, whenChoice)
track(after(whenChoice, parent), whenChoice, parent)
}
fun visit(structDecl: StructDecl, parent: Node) {
track(before(structDecl, parent), structDecl, parent)
structDecl.statements.forEach { it.accept(this, structDecl) }
track(after(structDecl, parent), structDecl, parent)
}
}

263
compiler/src/prog8/ast/processing/IAstModifyingVisitor.kt
View File

@ -1,263 +0,0 @@
package prog8.ast.processing
import prog8.ast.Module
import prog8.ast.Program
import prog8.ast.base.FatalAstException
import prog8.ast.expressions.*
import prog8.ast.statements.*
interface IAstModifyingVisitor {
fun visit(program: Program) {
program.modules.forEach { visit(it) }
}
fun visit(module: Module) {
module.statements = module.statements.map { it.accept(this) }.toMutableList()
}
fun visit(expr: PrefixExpression): Expression {
expr.expression = expr.expression.accept(this)
return expr
}
fun visit(expr: BinaryExpression): Expression {
expr.left = expr.left.accept(this)
expr.right = expr.right.accept(this)
return expr
}
fun visit(directive: Directive): Statement {
return directive
}
fun visit(block: Block): Statement {
block.statements = block.statements.map { it.accept(this) }.toMutableList()
return block
}
fun visit(decl: VarDecl): Statement {
decl.value = decl.value?.accept(this)
decl.arraysize?.accept(this)
return decl
}
fun visit(subroutine: Subroutine): Statement {
subroutine.statements = subroutine.statements.map { it.accept(this) }.toMutableList()
return subroutine
}
fun visit(functionCall: FunctionCall): Expression {
val newtarget = functionCall.target.accept(this)
if(newtarget is IdentifierReference)
functionCall.target = newtarget
else
throw FatalAstException("cannot change class of function call target")
functionCall.arglist = functionCall.arglist.map { it.accept(this) }.toMutableList()
return functionCall
}
fun visit(functionCallStatement: FunctionCallStatement): Statement {
val newtarget = functionCallStatement.target.accept(this)
if(newtarget is IdentifierReference)
functionCallStatement.target = newtarget
else
throw FatalAstException("cannot change class of function call target")
functionCallStatement.arglist = functionCallStatement.arglist.map { it.accept(this) }.toMutableList()
return functionCallStatement
}
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): Statement {
if(jump.identifier!=null) {
val ident = jump.identifier.accept(this)
if(ident is IdentifierReference && ident!==jump.identifier) {
return Jump(null, ident, null, jump.position)
}
}
return jump
}
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): Statement {
branchStatement.truepart = branchStatement.truepart.accept(this) as AnonymousScope
branchStatement.elsepart = branchStatement.elsepart.accept(this) as AnonymousScope
return branchStatement
}
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): Statement {
return label
}
fun visit(literalValue: NumericLiteralValue): NumericLiteralValue {
return literalValue
}
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): Statement {
postIncrDecr.target = postIncrDecr.target.accept(this)
return postIncrDecr
}
fun visit(contStmt: Continue): Statement {
return contStmt
}
fun visit(breakStmt: Break): Statement {
return breakStmt
}
fun visit(forLoop: ForLoop): Statement {
val newloopvar = forLoop.loopVar?.accept(this)
when(newloopvar) {
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): Statement {
whileLoop.condition = whileLoop.condition.accept(this)
whileLoop.body = whileLoop.body.accept(this) as AnonymousScope
return whileLoop
}
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): Statement {
returnStmt.value = returnStmt.value?.accept(this)
return returnStmt
}
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 {
val ident = assignTarget.identifier?.accept(this)
when (ident) {
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): Statement {
scope.statements = scope.statements.map { it.accept(this) }.toMutableList()
return scope
}
fun visit(typecast: TypecastExpression): Expression {
typecast.expression = typecast.expression.accept(this)
return typecast
}
fun visit(memread: DirectMemoryRead): Expression {
memread.addressExpression = memread.addressExpression.accept(this)
return memread
}
fun visit(memwrite: DirectMemoryWrite) {
memwrite.addressExpression = memwrite.addressExpression.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): Statement {
return inlineAssembly
}
fun visit(registerExpr: RegisterExpr): Expression {
return registerExpr
}
fun visit(builtinFunctionStatementPlaceholder: BuiltinFunctionStatementPlaceholder): Statement {
return builtinFunctionStatementPlaceholder
}
fun visit(nopStatement: NopStatement): Statement {
return nopStatement
}
fun visit(whenStatement: WhenStatement): Statement {
whenStatement.condition = whenStatement.condition.accept(this)
whenStatement.choices.forEach { it.accept(this) }
return whenStatement
}
fun visit(whenChoice: WhenChoice) {
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
}
}

25
compiler/src/prog8/ast/processing/IAstVisitor.kt
View File

@ -7,7 +7,7 @@ import prog8.ast.statements.*
interface IAstVisitor {
fun visit(program: Program) {
program.modules.forEach { visit(it) }
program.modules.forEach { it.accept(this) }
}
fun visit(module: Module) {
@ -41,12 +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) {
@ -95,14 +95,11 @@ interface IAstVisitor {
postIncrDecr.target.accept(this)
}
fun visit(contStmt: Continue) {
}
fun visit(breakStmt: Break) {
}
fun visit(forLoop: ForLoop) {
forLoop.loopVar?.accept(this)
forLoop.loopVar.accept(this)
forLoop.iterable.accept(this)
forLoop.body.accept(this)
}
@ -113,10 +110,15 @@ interface IAstVisitor {
}
fun visit(repeatLoop: RepeatLoop) {
repeatLoop.untilCondition.accept(this)
repeatLoop.iterations?.accept(this)
repeatLoop.body.accept(this)
}
fun visit(untilLoop: UntilLoop) {
untilLoop.untilCondition.accept(this)
untilLoop.body.accept(this)
}
fun visit(returnStmt: Return) {
returnStmt.value?.accept(this)
}
@ -155,9 +157,6 @@ interface IAstVisitor {
fun visit(inlineAssembly: InlineAssembly) {
}
fun visit(registerExpr: RegisterExpr) {
}
fun visit(builtinFunctionStatementPlaceholder: BuiltinFunctionStatementPlaceholder) {
}
@ -177,8 +176,4 @@ interface IAstVisitor {
fun visit(structDecl: StructDecl) {
structDecl.statements.forEach { it.accept(this) }
}
fun visit(structLv: StructLiteralValue) {
structLv.values.forEach { it.accept(this) }
}
}

33
compiler/src/prog8/ast/processing/ImportedModuleDirectiveRemover.kt
View File

@ -1,36 +1,21 @@
package prog8.ast.processing
import prog8.ast.Module
import prog8.ast.base.SyntaxError
import prog8.ast.base.printWarning
import prog8.ast.Node
import prog8.ast.statements.Directive
import prog8.ast.statements.Statement
internal class ImportedModuleDirectiveRemover : IAstModifyingVisitor {
private val checkResult: MutableList<SyntaxError> = mutableListOf()
internal fun result(): List<SyntaxError> {
return checkResult
}
internal class ImportedModuleDirectiveRemover: AstWalker() {
/**
* Most global directives don't apply for imported modules, so remove them
*/
override fun visit(module: Module) {
super.visit(module)
val newStatements : MutableList<Statement> = mutableListOf()
val moduleLevelDirectives = listOf("%output", "%launcher", "%zeropage", "%zpreserved", "%address")
for (sourceStmt in module.statements) {
val stmt = sourceStmt.accept(this)
if(stmt is Directive && stmt.parent is Module) {
if(stmt.directive in moduleLevelDirectives) {
printWarning("ignoring module directive because it was imported", stmt.position, stmt.directive)
continue
}
}
newStatements.add(stmt)
private val moduleLevelDirectives = listOf("%output", "%launcher", "%zeropage", "%zpreserved", "%address")
private val noModifications = emptyList<IAstModification>()
override fun before(directive: Directive, parent: Node): Iterable<IAstModification> {
if(directive.directive in moduleLevelDirectives) {
return listOf(IAstModification.Remove(directive, parent))
}
module.statements = newStatements
return noModifications
}
}

71
compiler/src/prog8/ast/processing/ReflectionAstWalker.kt Normal file
View File

@ -0,0 +1,71 @@
package prog8.ast.processing
/*
This is here for reference only, reflection based ast walking is very slow
when compared to the more verbose visitor pattern interfaces.
Too bad, because the code is very small
*/
//import prog8.ast.NoAstWalk
//import prog8.ast.Node
//import prog8.ast.Program
//import prog8.ast.base.Position
//import prog8.ast.expressions.BinaryExpression
//import prog8.ast.expressions.NumericLiteralValue
//import kotlin.reflect.KClass
//import kotlin.reflect.KVisibility
//import kotlin.reflect.full.declaredMemberProperties
//import kotlin.reflect.full.isSubtypeOf
//import kotlin.reflect.full.starProjectedType
//
//
//class ReflectionAstWalker {
// private val nodeType = Node::class.starProjectedType
// private val collectionType = Collection::class.starProjectedType
//
//
// fun walk(node: Node, nesting: Int) {
// val nodetype: KClass<out Node> = node::class
// val indent = " ".repeat(nesting)
// //println("$indent VISITING ${nodetype.simpleName}")
// val visibleAstMembers = nodetype.declaredMemberProperties.filter {
// it.visibility!=KVisibility.PRIVATE && !it.isLateinit &&
// !(it.annotations.any{a->a is NoAstWalk})
// }
// for(prop in visibleAstMembers) {
// if(prop.returnType.isSubtypeOf(nodeType)) {
// // println("$indent +PROP: ${prop.name}")
// walk(prop.call(node) as Node, nesting + 1)
// }
// else if(prop.returnType.isSubtypeOf(collectionType)) {
// val elementType = prop.returnType.arguments.single().type
// if(elementType!=null && elementType.isSubtypeOf(nodeType)) {
// val nodes = prop.call(node) as Collection<Node>
// nodes.forEach { walk(it, nesting+1) }
// }
// }
// }
// }
// fun walk(program: Program) {
// for(module in program.modules) {
// println("---MODULE $module---")
// walk(module, 0)
// }
// }
//}
//
//
//fun main() {
// val ast = BinaryExpression(
// NumericLiteralValue.optimalInteger(100, Position.DUMMY),
// "+",
// NumericLiteralValue.optimalInteger(200, Position.DUMMY),
// Position.DUMMY
// )
//
// val walker = ReflectionAstWalker()
// walker.walk(ast,0)
//
//}

401
compiler/src/prog8/ast/processing/StatementReorderer.kt
View File

@ -1,259 +1,228 @@
package prog8.ast.processing
import prog8.ast.*
import prog8.ast.base.DataType
import prog8.ast.base.FatalAstException
import prog8.ast.base.initvarsSubName
import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.ast.mangledStructMemberName
import prog8.ast.statements.*
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
}
}
structAssignment.value 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 {
internal class StatementReorderer(val program: Program) : AstWalker() {
// Reorders the statements in a way the compiler needs.
// - 'main' block must be the very first statement UNLESS it has an address set.
// - blocks are ordered by address, where blocks without address are put at the end.
// - in every scope:
// -- the directives '%output', '%launcher', '%zeropage', '%zpreserved', '%address' and '%option' will come first.
// -- all vardecls then follow.
// -- the remaining statements then follow in their original order.
//
// - 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.
// - library blocks are put last.
// - blocks are ordered by address, where blocks without address are placed last.
// - in every scope, most directives and vardecls are moved to the top.
// - the 'start' subroutine is moved to the top.
// - (syntax desugaring) a vardecl with a non-const initializer value is split into a regular vardecl and an assignment statement.
// - (syntax desugaring) struct value assignment is expanded into several struct member assignments.
// - in-place assignments are reordered a bit so that they are mostly of the form A = A <operator> <rest>
// - sorts the choices in when statement.
// - insert AddressOf (&) expression where required (string params to a UWORD function param etc).
private val noModifications = emptyList<IAstModification>()
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)
override fun after(module: Module, parent: Node): Iterable<IAstModification> {
val (blocks, other) = module.statements.partition { it is Block }
module.statements = other.asSequence().plus(blocks.sortedBy { (it as Block).address ?: Int.MAX_VALUE }).toMutableList()
// make sure user-defined blocks come BEFORE library blocks, and move the "main" block to the top of everything
val nonLibraryBlocks = module.statements.withIndex()
.filter { it.value is Block && !(it.value as Block).isInLibrary }
.map { it.index to it.value }
.reversed()
for(nonLibBlock in nonLibraryBlocks)
module.statements.removeAt(nonLibBlock.first)
for(nonLibBlock in nonLibraryBlocks)
module.statements.add(0, nonLibBlock.second)
val mainBlock = module.statements.singleOrNull { it is Block && it.name=="main" }
if(mainBlock!=null && (mainBlock as Block).address==null) {
module.remove(mainBlock)
val mainBlock = module.statements.filterIsInstance<Block>().firstOrNull { it.name=="main" }
if(mainBlock!=null && mainBlock.address==null) {
module.statements.remove(mainBlock)
module.statements.add(0, mainBlock)
}
val varDecls = module.statements.filterIsInstance<VarDecl>()
module.statements.removeAll(varDecls)
module.statements.addAll(0, varDecls)
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)
}
reorderVardeclsAndDirectives(module.statements)
return noModifications
}
override fun visit(block: Block): Statement {
private fun reorderVardeclsAndDirectives(statements: MutableList<Statement>) {
val varDecls = statements.filterIsInstance<VarDecl>()
statements.removeAll(varDecls)
statements.addAll(0, varDecls)
val subroutines = block.statements.filterIsInstance<Subroutine>()
var numSubroutinesAtEnd = 0
// move all subroutines to the end of the block
for (subroutine in subroutines) {
if(subroutine.name!="start" || block.name!="main") {
block.remove(subroutine)
block.statements.add(subroutine)
}
numSubroutinesAtEnd++
val directives = statements.filterIsInstance<Directive>().filter {it.directive in directivesToMove}
statements.removeAll(directives)
statements.addAll(0, directives)
}
override fun before(block: Block, parent: Node): Iterable<IAstModification> {
parent as Module
if(block.isInLibrary) {
return listOf(
IAstModification.Remove(block, parent),
IAstModification.InsertLast(block, parent)
)
}
// move the "start" subroutine to the top
if(block.name=="main") {
block.statements.singleOrNull { it is Subroutine && it.name == "start" } ?.let {
block.remove(it)
block.statements.add(0, it)
numSubroutinesAtEnd--
reorderVardeclsAndDirectives(block.statements)
return noModifications
}
override fun before(subroutine: Subroutine, parent: Node): Iterable<IAstModification> {
if(subroutine.name=="start" && parent is Block) {
if(parent.statements.filterIsInstance<Subroutine>().first().name!="start") {
return listOf(
IAstModification.Remove(subroutine, parent),
IAstModification.InsertFirst(subroutine, parent)
)
}
}
return noModifications
}
override fun after(decl: VarDecl, parent: Node): Iterable<IAstModification> {
val declValue = decl.value
if(declValue!=null && decl.type== VarDeclType.VAR && decl.datatype in NumericDatatypes) {
val declConstValue = declValue.constValue(program)
if(declConstValue==null) {
// move the vardecl (without value) to the scope and replace this with a regular assignment
decl.value = null
val target = AssignTarget(IdentifierReference(listOf(decl.name), decl.position), null, null, decl.position)
val assign = Assignment(target, declValue, decl.position)
return listOf(
IAstModification.ReplaceNode(decl, assign, parent),
IAstModification.InsertFirst(decl, decl.definingScope() as Node)
)
}
}
return noModifications
}
override fun after(whenStatement: WhenStatement, parent: Node): Iterable<IAstModification> {
val choices = whenStatement.choiceValues(program).sortedBy {
it.first?.first() ?: Int.MAX_VALUE
}
whenStatement.choices.clear()
choices.mapTo(whenStatement.choices) { it.second }
return noModifications
}
override fun before(assignment: Assignment, parent: Node): Iterable<IAstModification> {
val valueType = assignment.value.inferType(program)
val targetType = assignment.target.inferType(program, assignment)
if(valueType.istype(DataType.STRUCT) && targetType.istype(DataType.STRUCT)) {
val assignments = if (assignment.value is ArrayLiteralValue) {
flattenStructAssignmentFromStructLiteral(assignment, program) // 'structvar = [ ..... ] '
} else {
flattenStructAssignmentFromIdentifier(assignment, program) // 'structvar1 = structvar2'
}
if(assignments.isNotEmpty()) {
val modifications = mutableListOf<IAstModification>()
assignments.reversed().mapTo(modifications) { IAstModification.InsertAfter(assignment, it, parent) }
modifications.add(IAstModification.Remove(assignment, parent))
return modifications
}
}
// make sure there is a 'return' in front of the first subroutine
// (if it isn't the first statement in the block itself, and isn't the program's entrypoint)
if(numSubroutinesAtEnd>0 && block.statements.size > (numSubroutinesAtEnd+1)) {
val firstSub = block.statements[block.statements.size - numSubroutinesAtEnd] as Subroutine
if(firstSub.name != "start" && block.name != "main") {
val stmtBeforeFirstSub = block.statements[block.statements.size - numSubroutinesAtEnd - 1]
if (stmtBeforeFirstSub !is Return
&& stmtBeforeFirstSub !is Jump
&& stmtBeforeFirstSub !is Subroutine
&& stmtBeforeFirstSub !is BuiltinFunctionStatementPlaceholder) {
val ret = Return(null, stmtBeforeFirstSub.position)
ret.linkParents(block)
block.statements.add(block.statements.size - numSubroutinesAtEnd, ret)
return noModifications
}
override fun after(assignment: Assignment, parent: Node): Iterable<IAstModification> {
// rewrite in-place assignment expressions a bit so that the assignment target usually is the leftmost operand
val binExpr = assignment.value as? BinaryExpression
if(binExpr!=null) {
if(binExpr.left isSameAs assignment.target) {
// A = A <operator> 5, unchanged
return noModifications
}
if(binExpr.operator in associativeOperators) {
if (binExpr.right isSameAs assignment.target) {
// A = v <associative-operator> A ==> A = A <associative-operator> v
return listOf(IAstModification.SwapOperands(binExpr))
}
}
}
val varDecls = block.statements.filterIsInstance<VarDecl>()
block.statements.removeAll(varDecls)
block.statements.addAll(0, varDecls)
val directives = block.statements.filter {it is Directive && it.directive in directivesToMove}
block.statements.removeAll(directives)
block.statements.addAll(0, directives)
block.linkParents(block.parent)
// create subroutine that initializes the block's variables (if any)
val varInits = block.statements.withIndex().filter { it.value is VariableInitializationAssignment }
if(varInits.isNotEmpty()) {
val statements = varInits.map{it.value}.toMutableList()
val varInitSub = Subroutine(initvarsSubName, emptyList(), emptyList(), emptyList(), emptyList(),
emptySet(), null, false, statements, block.position)
varInitSub.keepAlways = true
varInitSub.linkParents(block)
block.statements.add(varInitSub)
// remove the varinits from the block's statements
for(index in varInits.map{it.index}.reversed())
block.statements.removeAt(index)
}
return super.visit(block)
}
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 leftBinExpr = binExpr.left as? BinaryExpression
if(leftBinExpr?.operator == binExpr.operator) {
return if(leftBinExpr.left isSameAs assignment.target) {
// A = (A <associative-operator> x) <same-operator> y ==> A = A <associative-operator> (x <same-operator> y)
val newRight = BinaryExpression(leftBinExpr.right, binExpr.operator, binExpr.right, binExpr.position)
val newValue = BinaryExpression(leftBinExpr.left, binExpr.operator, newRight, binExpr.position)
listOf(IAstModification.ReplaceNode(binExpr, newValue, assignment))
} else {
// A = (x <associative-operator> A) <same-operator> y ==> A = A <associative-operator> (x <same-operator> y)
val newRight = BinaryExpression(leftBinExpr.left, binExpr.operator, binExpr.right, binExpr.position)
val newValue = BinaryExpression(leftBinExpr.right, binExpr.operator, newRight, binExpr.position)
listOf(IAstModification.ReplaceNode(binExpr, newValue, assignment))
}
}
val rightBinExpr = binExpr.right as? BinaryExpression
if(rightBinExpr?.operator == binExpr.operator) {
return if(rightBinExpr.left isSameAs assignment.target) {
// A = x <associative-operator> (A <same-operator> y) ==> A = A <associative-operator> (x <same-operator> y)
val newRight = BinaryExpression(binExpr.left, binExpr.operator, rightBinExpr.right, binExpr.position)
val newValue = BinaryExpression(rightBinExpr.left, binExpr.operator, newRight, binExpr.position)
listOf(IAstModification.ReplaceNode(binExpr, newValue, assignment))
} else {
// A = x <associative-operator> (y <same-operator> A) ==> A = A <associative-operator> (x <same-operator> y)
val newRight = BinaryExpression(binExpr.left, binExpr.operator, rightBinExpr.left, binExpr.position)
val newValue = BinaryExpression(rightBinExpr.right, binExpr.operator, newRight, binExpr.position)
listOf(IAstModification.ReplaceNode(binExpr, newValue, assignment))
}
}
}
}
val varDecls = subroutine.statements.filterIsInstance<VarDecl>()
subroutine.statements.removeAll(varDecls)
subroutine.statements.addAll(0, varDecls)
val directives = subroutine.statements.filter {it is Directive && it.directive in directivesToMove}
subroutine.statements.removeAll(directives)
subroutine.statements.addAll(0, directives)
if(subroutine.returntypes.isEmpty()) {
// add the implicit return statement at the end (if it's not there yet), but only if it's not a kernel routine.
// 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(null, subroutine.position)
returnStmt.linkParents(subroutine)
subroutine.statements.add(returnStmt)
}
}
}
return subroutine
return noModifications
}
override fun visit(assignment: Assignment): Statement {
val assg = super.visit(assignment)
if(assg !is Assignment)
return assg
private fun flattenStructAssignmentFromStructLiteral(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!!
// 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)
val slv = structAssignment.value as? ArrayLiteralValue
if(slv==null || slv.value.size != struct.numberOfElements)
throw FatalAstException("element count mismatch")
if(targetItype.isKnown && valueItype.isKnown) {
val targettype = targetItype.typeOrElse(DataType.STRUCT)
val valuetype = valueItype.typeOrElse(DataType.STRUCT)
return struct.statements.zip(slv.value).map { (targetDecl, sourceValue) ->
targetDecl as VarDecl
val mangled = mangledStructMemberName(identifierName, targetDecl.name)
val idref = IdentifierReference(listOf(mangled), structAssignment.position)
val assign = Assignment(AssignTarget(idref, null, null, structAssignment.position),
sourceValue, sourceValue.position)
assign.linkParents(structAssignment)
assign
}
}
// 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
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(idref, null, null, structAssignment.position), sourceIdref, member.second.position)
assign.linkParents(structAssignment)
assign
}
}
is ArrayLiteralValue -> {
throw IllegalArgumentException("not going to flatten a structLv assignment here")
}
else -> throw FatalAstException("strange struct value")
}
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")
}
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)
}
return assg
}
}

244
compiler/src/prog8/ast/processing/TypecastsAdder.kt
View File

@ -2,197 +2,205 @@ package prog8.ast.processing
import prog8.ast.IFunctionCall
import prog8.ast.INameScope
import prog8.ast.Node
import prog8.ast.Program
import prog8.ast.base.DataType
import prog8.ast.base.FatalAstException
import prog8.ast.base.printWarning
import prog8.ast.base.*
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)
class TypecastsAdder(val program: Program, val errors: ErrorReporter) : AstWalker() {
/*
* 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)
private val noModifications = emptyList<IAstModification>()
override fun after(expr: BinaryExpression, parent: Node): Iterable<IAstModification> {
val leftDt = expr.left.inferType(program)
val rightDt = expr.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)
val (commonDt, toFix) = BinaryExpression.commonDatatype(leftDt.typeOrElse(DataType.STRUCT), rightDt.typeOrElse(DataType.STRUCT), expr.left, expr.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)
}
return when {
toFix===expr.left -> listOf(IAstModification.ReplaceNode(
expr.left, TypecastExpression(expr.left, commonDt, true, expr.left.position), expr))
toFix===expr.right -> listOf(IAstModification.ReplaceNode(
expr.right, TypecastExpression(expr.right, commonDt, true, expr.right.position), expr))
else -> throw FatalAstException("confused binary expression side")
}
}
}
return expr2
return noModifications
}
override fun visit(assignment: Assignment): Statement {
val assg = super.visit(assignment)
if(assg !is Assignment)
return assg
override fun after(assignment: Assignment, parent: Node): Iterable<IAstModification> {
// 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)
val valueItype = assignment.value.inferType(program)
val targetItype = assignment.target.inferType(program, assignment)
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)
return listOf(IAstModification.ReplaceNode(
assignment.value,
TypecastExpression(assignment.value, targettype, true, assignment.value.position),
assignment))
} else {
fun castLiteral(cvalue: NumericLiteralValue): List<IAstModification.ReplaceNode> {
val cast = cvalue.cast(targettype)
return if(cast.isValid)
listOf(IAstModification.ReplaceNode(cvalue, cast.valueOrZero(), cvalue.parent))
else
emptyList()
}
val cvalue = assignment.value.constValue(program)
if(cvalue!=null) {
val number = cvalue.number.toDouble()
// more complex comparisons if the type is different, but the constant value is compatible
if (valuetype == DataType.BYTE && targettype == DataType.UBYTE) {
if(number>0)
return castLiteral(cvalue)
} else if (valuetype == DataType.WORD && targettype == DataType.UWORD) {
if(number>0)
return castLiteral(cvalue)
} else if (valuetype == DataType.UBYTE && targettype == DataType.BYTE) {
if(number<0x80)
return castLiteral(cvalue)
} else if (valuetype == DataType.UWORD && targettype == DataType.WORD) {
if(number<0x8000)
return castLiteral(cvalue)
}
}
}
// if they're not assignable, we'll get a proper error later from the AstChecker
}
}
return assg
return noModifications
}
override fun visit(functionCallStatement: FunctionCallStatement): Statement {
checkFunctionCallArguments(functionCallStatement, functionCallStatement.definingScope())
return super.visit(functionCallStatement)
override fun after(functionCallStatement: FunctionCallStatement, parent: Node): Iterable<IAstModification> {
return afterFunctionCallArgs(functionCallStatement, functionCallStatement.definingScope())
}
override fun visit(functionCall: FunctionCall): Expression {
checkFunctionCallArguments(functionCall, functionCall.definingScope())
return super.visit(functionCall)
override fun after(functionCall: FunctionCall, parent: Node): Iterable<IAstModification> {
return afterFunctionCallArgs(functionCall, functionCall.definingScope())
}
private fun checkFunctionCallArguments(call: IFunctionCall, scope: INameScope) {
private fun afterFunctionCallArgs(call: IFunctionCall, scope: INameScope): Iterable<IAstModification> {
// see if a typecast is needed to convert the arguments into the required parameter's type
val modifications = mutableListOf<IAstModification>()
when(val sub = call.target.targetStatement(scope)) {
is Subroutine -> {
for(arg in sub.parameters.zip(call.arglist.withIndex())) {
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.arglist[arg.second.index] = typecasted
modifications += IAstModification.ReplaceNode(
call.args[arg.second.index],
TypecastExpression(arg.second.value, requiredType, true, arg.second.value.position),
call as Node)
} else if(requiredType == DataType.UWORD && argtype in PassByReferenceDatatypes) {
// we allow STR/ARRAY values in place of UWORD parameters. Take their address instead.
modifications += IAstModification.ReplaceNode(
call.args[arg.second.index],
AddressOf(arg.second.value as IdentifierReference, arg.second.value.position),
call as Node)
} else if(arg.second.value is NumericLiteralValue) {
val cast = (arg.second.value as NumericLiteralValue).cast(requiredType)
if(cast.isValid)
modifications += IAstModification.ReplaceNode(
call.args[arg.second.index],
cast.valueOrZero(),
call as Node)
}
// 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.arglist.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.arglist[arg.second.index] = typecasted
break
}
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) {
modifications += IAstModification.ReplaceNode(
call.args[arg.second.index],
TypecastExpression(arg.second.value, possibleType, true, arg.second.value.position),
call as Node)
}
}
}
}
}
null -> {}
else -> throw FatalAstException("call to something weird $sub ${call.target}")
else -> { }
}
return modifications
}
override fun visit(typecast: TypecastExpression): Expression {
override fun after(typecast: TypecastExpression, parent: Node): Iterable<IAstModification> {
// 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)
errors.warn("integer implicitly converted to float. Suggestion: use float literals, add an explicit cast, or revert to integer arithmetic", typecast.position)
}
return super.visit(typecast)
return noModifications
}
override fun visit(memread: DirectMemoryRead): Expression {
override fun after(memread: DirectMemoryRead, parent: Node): Iterable<IAstModification> {
// 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
}
val typecast = (memread.addressExpression as? NumericLiteralValue)?.cast(DataType.UWORD)?.valueOrZero()
?: TypecastExpression(memread.addressExpression, DataType.UWORD, true, memread.addressExpression.position)
return listOf(IAstModification.ReplaceNode(memread.addressExpression, typecast, memread))
}
return super.visit(memread)
return noModifications
}
override fun visit(memwrite: DirectMemoryWrite) {
override fun after(memwrite: DirectMemoryWrite, parent: Node): Iterable<IAstModification> {
// make sure the memory address is an uword
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
}
val typecast = (memwrite.addressExpression as? NumericLiteralValue)?.cast(DataType.UWORD)?.valueOrZero()
?: TypecastExpression(memwrite.addressExpression, DataType.UWORD, true, memwrite.addressExpression.position)
return listOf(IAstModification.ReplaceNode(memwrite.addressExpression, typecast, memwrite))
}
super.visit(memwrite)
return noModifications
}
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)
}
override fun after(returnStmt: Return, parent: Node): Iterable<IAstModification> {
// add a typecast to the return type if it doesn't match the subroutine's signature
val returnValue = returnStmt.value
if(returnValue!=null) {
val subroutine = returnStmt.definingSubroutine()!!
if(subroutine.returntypes.size==1) {
val subReturnType = subroutine.returntypes.first()
if (returnValue.inferType(program).istype(subReturnType))
return noModifications
if (returnValue is NumericLiteralValue) {
val cast = returnValue.cast(subroutine.returntypes.single())
if(cast.isValid)
returnStmt.value = cast.valueOrZero()
} else {
return listOf(IAstModification.ReplaceNode(
returnValue,
TypecastExpression(returnValue, subReturnType, true, returnValue.position),
returnStmt))
}
}
}
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
}
return noModifications
}
}

157
compiler/src/prog8/ast/processing/VarInitValueAndAddressOfCreator.kt
View File

@ -1,157 +0,0 @@
package prog8.ast.processing
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.statements.*
import prog8.compiler.CompilerException
import prog8.functions.BuiltinFunctions
import prog8.functions.FunctionSignature
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.
// This makes sure the variables get reset to the intended value on a next run of the program.
// Variable decls without a value don't get this treatment, which means they retain the last
// value they had when restarting the program.
// This is done in a separate step because it interferes with the namespace lookup of symbols
// in other ast processors.
// Also takes care to insert AddressOf (&) expression where required (string params to a UWORD function param etc).
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((where, decls) in vardeclsToAdd) {
where.statements.addAll(0, decls)
decls.forEach { it.linkParents(where as Node) }
}
}
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(decl.datatype,
Array(arraysize) { NumericLiteralValue.optimalInteger(0, decl.position) },
null, decl.position)
array.addToHeap(program.heap)
decl.value = array
}
if(decl.type!= VarDeclType.VAR || decl.value==null)
return decl
if(decl.datatype in NumericDatatypes) {
val scope = decl.definingScope()
addVarDecl(scope, decl.asDefaultValueDecl(null))
val declvalue = decl.value!!
val value =
if(declvalue is NumericLiteralValue)
declvalue.cast(decl.datatype)
else
declvalue
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,
value,
decl.position
)
}
return decl
}
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) {
addAddressOfExprIfNeeded(targetStatement, functionCall.arglist, parentStatement)
} else {
val builtinFunc = BuiltinFunctions[functionCall.target.nameInSource.joinToString (".")]
if(builtinFunc!=null)
addAddressOfExprIfNeededForBuiltinFuncs(builtinFunc, functionCall.arglist, parentStatement)
}
return functionCall
}
override fun visit(functionCallStatement: FunctionCallStatement): Statement {
val targetStatement = functionCallStatement.target.targetSubroutine(program.namespace)
if(targetStatement!=null) {
addAddressOfExprIfNeeded(targetStatement, functionCallStatement.arglist, functionCallStatement)
} else {
val builtinFunc = BuiltinFunctions[functionCallStatement.target.nameInSource.joinToString (".")]
if(builtinFunc!=null)
addAddressOfExprIfNeededForBuiltinFuncs(builtinFunc, functionCallStatement.arglist, functionCallStatement)
}
return functionCallStatement
}
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.second is AddressOf)
continue
val idref = argparam.second as? IdentifierReference
val strvalue = argparam.second as? StringLiteralValue
if(idref!=null) {
val variable = idref.targetVarDecl(program.namespace)
if(variable!=null && (variable.datatype in StringDatatypes || variable.datatype in ArrayDatatypes)) {
val pointerExpr = AddressOf(idref, idref.position)
pointerExpr.linkParents(arglist[argparam.first.index].parent)
arglist[argparam.first.index] = pointerExpr
}
}
else if(strvalue!=null) {
// 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] = mutableListOf()
val declList = vardeclsToAdd.getValue(scope)
if(declList.all{it.name!=variable.name})
declList.add(variable)
}
}

44
compiler/src/prog8/ast/processing/VariousCleanups.kt Normal file
View File

@ -0,0 +1,44 @@
package prog8.ast.processing
import prog8.ast.INameScope
import prog8.ast.Node
import prog8.ast.expressions.NumericLiteralValue
import prog8.ast.expressions.TypecastExpression
import prog8.ast.statements.AnonymousScope
import prog8.ast.statements.NopStatement
internal class VariousCleanups: AstWalker() {
private val noModifications = emptyList<IAstModification>()
override fun before(nopStatement: NopStatement, parent: Node): Iterable<IAstModification> {
return listOf(IAstModification.Remove(nopStatement, parent))
}
override fun before(scope: AnonymousScope, parent: Node): Iterable<IAstModification> {
return if(parent is INameScope)
listOf(ScopeFlatten(scope, parent as INameScope))
else
noModifications
}
class ScopeFlatten(val scope: AnonymousScope, val into: INameScope) : IAstModification {
override fun perform() {
val idx = into.statements.indexOf(scope)
if(idx>=0) {
into.statements.addAll(idx+1, scope.statements)
into.statements.remove(scope)
}
}
}
override fun before(typecast: TypecastExpression, parent: Node): Iterable<IAstModification> {
if(typecast.expression is NumericLiteralValue) {
val value = (typecast.expression as NumericLiteralValue).cast(typecast.type)
if(value.isValid)
return listOf(IAstModification.ReplaceNode(typecast, value.valueOrZero(), parent))
}
return noModifications
}
}

61
compiler/src/prog8/ast/processing/VerifyFunctionArgTypes.kt Normal file
View File

@ -0,0 +1,61 @@
package prog8.ast.processing
import prog8.ast.IFunctionCall
import prog8.ast.INameScope
import prog8.ast.Program
import prog8.ast.base.DataType
import prog8.ast.expressions.FunctionCall
import prog8.ast.statements.BuiltinFunctionStatementPlaceholder
import prog8.ast.statements.FunctionCallStatement
import prog8.ast.statements.Subroutine
import prog8.compiler.CompilerException
import prog8.functions.BuiltinFunctions
class VerifyFunctionArgTypes(val program: Program) : IAstVisitor {
override fun visit(functionCall: FunctionCall) {
val error = checkTypes(functionCall as IFunctionCall, functionCall.definingScope(), program)
if(error!=null)
throw CompilerException(error)
}
override fun visit(functionCallStatement: FunctionCallStatement) {
val error = checkTypes(functionCallStatement as IFunctionCall, functionCallStatement.definingScope(), program)
if (error!=null)
throw CompilerException(error)
}
companion object {
fun checkTypes(call: IFunctionCall, scope: INameScope, program: Program): String? {
val argtypes = call.args.map { it.inferType(program).typeOrElse(DataType.STRUCT) }
val target = call.target.targetStatement(scope)
if (target is Subroutine) {
// asmsub types are not checked specifically at this time
if(call.args.size != target.parameters.size)
return "invalid number of arguments"
val paramtypes = target.parameters.map { it.type }
val mismatch = argtypes.zip(paramtypes).indexOfFirst { it.first != it.second}
if(mismatch>=0) {
val actual = argtypes[mismatch].toString()
val expected = paramtypes[mismatch].toString()
return "argument ${mismatch + 1} type mismatch, was: $actual expected: $expected"
}
}
else if (target is BuiltinFunctionStatementPlaceholder) {
val func = BuiltinFunctions.getValue(target.name)
if(call.args.size != func.parameters.size)
return "invalid number of arguments"
val paramtypes = func.parameters.map { it.possibleDatatypes }
for (x in argtypes.zip(paramtypes).withIndex()) {
if (x.value.first !in x.value.second) {
val actual = x.value.first.toString()
val expected = x.value.second.toString()
return "argument ${x.index + 1} type mismatch, was: $actual expected: $expected"
}
}
}
return null
}
}
}

495
compiler/src/prog8/ast/statements/AstStatements.kt
View File

@ -3,13 +3,14 @@ package prog8.ast.statements
import prog8.ast.*
import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.ast.processing.IAstModifyingVisitor
import prog8.ast.processing.AstWalker
import prog8.ast.processing.IAstVisitor
sealed class Statement : Node {
abstract fun accept(visitor: IAstModifyingVisitor) : Statement
abstract fun accept(visitor: IAstVisitor)
abstract fun accept(visitor: AstWalker, parent: Node)
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.
@ -28,8 +29,6 @@ sealed class Statement : Node {
return scope.joinToString(".")
}
abstract val expensiveToInline: Boolean
fun definingBlock(): Block {
if(this is Block)
return this
@ -41,32 +40,37 @@ sealed class Statement : Node {
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)
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
override fun definingScope(): INameScope = BuiltinFunctionScopePlaceholder
override val expensiveToInline = false
override fun replaceChildNode(node: Node, replacement: Node) {
replacement.parent = this
}
}
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<Statement>,
val isInLibrary: Boolean,
override val position: Position) : Statement(), INameScope {
override lateinit var parent: Node
override val expensiveToInline
get() = statements.any { it.expensiveToInline }
override fun linkParents(parent: Node) {
this.parent = parent
statements.forEach {it.linkParents(this)}
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun replaceChildNode(node: Node, replacement: Node) {
require(replacement is Statement)
val idx = statements.indexOfFirst { it ===node }
statements[idx] = replacement
replacement.parent = this
}
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
override fun toString(): String {
return "Block(name=$name, address=$address, ${statements.size} statements)"
@ -77,15 +81,15 @@ class Block(override val name: String,
data class Directive(val directive: String, val args: List<DirectiveArg>, override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline = false
override fun linkParents(parent: Node) {
this.parent = parent
args.forEach{it.linkParents(this)}
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun replaceChildNode(node: Node, replacement: Node) = throw FatalAstException("can't replace here")
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
}
data class DirectiveArg(val str: String?, val name: String?, val int: Int?, override val position: Position) : Node {
@ -94,18 +98,19 @@ data class DirectiveArg(val str: String?, val name: String?, val int: Int?, over
override fun linkParents(parent: Node) {
this.parent = parent
}
override fun replaceChildNode(node: Node, replacement: Node) = throw FatalAstException("can't replace here")
}
data class Label(val name: String, override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline = false
override fun linkParents(parent: Node) {
this.parent = parent
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun replaceChildNode(node: Node, replacement: Node) = throw FatalAstException("can't replace here")
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
override fun toString(): String {
return "Label(name=$name, pos=$position)"
@ -114,52 +119,36 @@ data class Label(val name: String, override val position: Position) : Statement(
open class Return(var value: Expression?, override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline = value!=null && value !is NumericLiteralValue
override fun linkParents(parent: Node) {
this.parent = parent
value?.linkParents(this)
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun replaceChildNode(node: Node, replacement: Node) {
require(replacement is Expression)
value = replacement
replacement.parent = this
}
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
override fun toString(): String {
return "Return($value, pos=$position)"
}
}
class ReturnFromIrq(override val position: Position) : Return(null, position) {
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun toString(): String {
return "ReturnFromIrq(pos=$position)"
}
}
class Continue(override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline = false
override fun linkParents(parent: Node) {
this.parent=parent
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
}
class Break(override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline = false
override fun linkParents(parent: Node) {
this.parent=parent
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun replaceChildNode(node: Node, replacement: Node) = throw FatalAstException("can't replace here")
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
}
@ -170,7 +159,8 @@ enum class ZeropageWish {
NOT_IN_ZEROPAGE
}
class VarDecl(val type: VarDeclType,
open class VarDecl(val type: VarDeclType,
private val declaredDatatype: DataType,
val zeropage: ZeropageWish,
var arraysize: ArrayIndex?,
@ -186,32 +176,33 @@ class VarDecl(val type: VarDeclType,
var structHasBeenFlattened = false // set later
private set
override val expensiveToInline
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 {
if(string.heapId==null)
throw FatalAstException("can only create autovar for a string that has a heapid $string")
val autoVarName = "auto_heap_value_${++autoHeapValueSequenceNumber}"
return VarDecl(VarDeclType.VAR, string.type, ZeropageWish.NOT_IN_ZEROPAGE, null, autoVarName, null, string,
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 {
if(array.heapId==null)
throw FatalAstException("can only create autovar for an array that has a heapid $array")
val autoVarName = "auto_heap_value_${++autoHeapValueSequenceNumber}"
val declaredType = ArrayElementTypes.getValue(array.type)
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)
}
fun defaultZero(dt: DataType, position: Position) = when(dt) {
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 determine default zero value for a numeric type")
}
}
val datatypeErrors = mutableListOf<SyntaxError>() // don't crash at init time, report them in the AstChecker
@ -240,34 +231,25 @@ class VarDecl(val type: VarDeclType,
}
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun replaceChildNode(node: Node, replacement: Node) {
require(replacement is Expression && node===value)
value = replacement
replacement.parent = this
}
val scopedname: String by lazy { makeScopedName(name) }
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
override fun toString(): String {
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 -> 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, structName, constValue, isArray, false, position)
if(parent!=null)
decl.linkParents(parent)
return decl
}
fun zeroElementValue() = defaultZero(declaredDatatype, position)
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
val initvalue = if(value!=null) (value as ArrayLiteralValue).value[it.index] else null
VarDecl(
VarDeclType.VAR,
member.datatype,
@ -279,13 +261,18 @@ class VarDecl(val type: VarDeclType,
member.isArray,
true,
member.position
) as Statement
}.toMutableList()
)
}.toMutableList<Statement>()
structHasBeenFlattened = true
return result
}
}
// a vardecl used only for subroutine parameters
class ParameterVarDecl(name: String, declaredDatatype: DataType, position: Position)
: VarDecl(VarDeclType.VAR, declaredDatatype, ZeropageWish.DONTCARE, null, name, null, null, false, true, position)
class ArrayIndex(var index: Expression, override val position: Position) : Node {
override lateinit var parent: Node
@ -294,31 +281,30 @@ class ArrayIndex(var index: Expression, override val position: Position) : Node
index.linkParents(this)
}
override fun replaceChildNode(node: Node, replacement: Node) {
require(replacement is Expression && node===index)
index = replacement
replacement.parent = this
}
companion object {
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)
}
fun accept(visitor: IAstVisitor) = index.accept(visitor)
fun accept(visitor: AstWalker, parent: Node) = index.accept(visitor, this)
override fun toString(): String {
return("ArrayIndex($index, pos=$position)")
}
fun size() = (index as? NumericLiteralValue)?.number?.toInt()
fun constIndex() = (index as? NumericLiteralValue)?.number?.toInt()
}
open class Assignment(var target: AssignTarget, val aug_op : String?, var value: Expression, override val position: Position) : Statement() {
open class Assignment(var target: AssignTarget, var value: Expression, override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline
get() = value !is NumericLiteralValue
override fun linkParents(parent: Node) {
this.parent = parent
@ -326,21 +312,71 @@ open class Assignment(var target: AssignTarget, val aug_op : String?, var value:
value.linkParents(this)
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun replaceChildNode(node: Node, replacement: Node) {
when {
node===target -> target = replacement as AssignTarget
node===value -> value = replacement as Expression
else -> throw FatalAstException("invalid replace")
}
replacement.parent = this
}
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
override fun toString(): String {
return("Assignment(augop: $aug_op, target: $target, value: $value, pos=$position)")
return("Assignment(target: $target, value: $value, pos=$position)")
}
/**
* Is the assigment value an expression that references the assignment target itself?
* The expression can be a BinaryExpression, PrefixExpression or TypecastExpression (possibly with one sub-cast).
*/
val isAugmentable: Boolean
get() {
val binExpr = value as? BinaryExpression
if(binExpr!=null) {
if(binExpr.left isSameAs target)
return true // A = A <operator> Something
if(binExpr.operator in associativeOperators) {
if (binExpr.left !is BinaryExpression && binExpr.right isSameAs target)
return true // A = v <associative-operator> A
val leftBinExpr = binExpr.left as? BinaryExpression
if(leftBinExpr?.operator == binExpr.operator) {
// one of these?
// A = (A <associative-operator> x) <same-operator> y
// A = (x <associative-operator> A) <same-operator> y
// A = (x <associative-operator> y) <same-operator> A
return leftBinExpr.left isSameAs target || leftBinExpr.right isSameAs target || binExpr.right isSameAs target
}
val rightBinExpr = binExpr.right as? BinaryExpression
if(rightBinExpr?.operator == binExpr.operator) {
// one of these?
// A = y <associative-operator> (A <same-operator> x)
// A = y <associative-operator> (x <same-operator> y)
// A = A <associative-operator> (x <same-operator> y)
return rightBinExpr.left isSameAs target || rightBinExpr.right isSameAs target || binExpr.left isSameAs target
}
}
}
val prefixExpr = value as? PrefixExpression
if(prefixExpr!=null)
return prefixExpr.expression isSameAs target
val castExpr = value as? TypecastExpression
if(castExpr!=null) {
val subCast = castExpr.expression as? TypecastExpression
return if(subCast!=null) subCast.expression isSameAs target else castExpr.expression isSameAs target
}
return false
}
}
// 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: Expression, position: Position)
: Assignment(target, aug_op, value, position)
data class AssignTarget(val register: Register?,
var identifier: IdentifierReference?,
data class AssignTarget(var identifier: IdentifierReference?,
var arrayindexed: ArrayIndexedExpression?,
val memoryAddress: DirectMemoryWrite?,
override val position: Position) : Node {
@ -353,25 +389,30 @@ data class AssignTarget(val register: Register?,
memoryAddress?.linkParents(this)
}
fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun replaceChildNode(node: Node, replacement: Node) {
when {
node===identifier -> identifier = replacement as IdentifierReference
node===arrayindexed -> arrayindexed = replacement as ArrayIndexedExpression
else -> throw FatalAstException("invalid replace")
}
replacement.parent = this
}
fun accept(visitor: IAstVisitor) = visitor.visit(this)
fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
companion object {
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)
is ArrayIndexedExpression -> AssignTarget(null, null, expr, null, expr.position)
is DirectMemoryRead -> AssignTarget(null, null, null, DirectMemoryWrite(expr.addressExpression, expr.position), expr.position)
is IdentifierReference -> AssignTarget(expr, null, null, expr.position)
is ArrayIndexedExpression -> AssignTarget(null, expr, null, expr.position)
is DirectMemoryRead -> AssignTarget(null, null, DirectMemoryWrite(expr.addressExpression, expr.position), expr.position)
else -> throw FatalAstException("invalid expression object $expr")
}
}
}
fun inferType(program: Program, stmt: Statement): InferredTypes.InferredType {
if(register!=null)
return InferredTypes.knownFor(DataType.UBYTE)
if(identifier!=null) {
val symbol = program.namespace.lookup(identifier!!.nameInSource, stmt) ?: return InferredTypes.unknown()
if (symbol is VarDecl) return InferredTypes.knownFor(symbol.datatype)
@ -387,16 +428,30 @@ data class AssignTarget(val register: Register?,
return InferredTypes.unknown()
}
fun toExpression(): Expression {
return when {
identifier!=null -> identifier!!
arrayindexed!=null -> arrayindexed!!
memoryAddress!=null -> DirectMemoryRead(memoryAddress.addressExpression, memoryAddress.position)
else -> throw FatalAstException("invalid assignmenttarget $this")
}
}
infix fun isSameAs(value: Expression): Boolean {
return when {
this.memoryAddress!=null -> false
this.register!=null -> value is RegisterExpr && value.register==register
this.memoryAddress!=null -> {
// if the target is a memory write, and the value is a memory read, they're the same if the address matches
if(value is DirectMemoryRead)
this.memoryAddress.addressExpression isSameAs value.addressExpression
else
false
}
this.identifier!=null -> value is IdentifierReference && value.nameInSource==identifier!!.nameInSource
this.arrayindexed!=null -> value is ArrayIndexedExpression &&
value.identifier.nameInSource==arrayindexed!!.identifier.nameInSource &&
value.arrayspec.size()!=null &&
arrayindexed!!.arrayspec.size()!=null &&
value.arrayspec.size()==arrayindexed!!.arrayspec.size()
value.arrayspec.constIndex()!=null &&
arrayindexed!!.arrayspec.constIndex()!=null &&
value.arrayspec.constIndex()==arrayindexed!!.arrayspec.constIndex()
else -> false
}
}
@ -404,8 +459,6 @@ data class AssignTarget(val register: Register?,
fun isSameAs(other: AssignTarget, program: Program): Boolean {
if(this===other)
return true
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
if(this.memoryAddress!=null && other.memoryAddress!=null) {
@ -424,8 +477,6 @@ data class AssignTarget(val register: Register?,
}
fun isNotMemory(namespace: INameScope): Boolean {
if(this.register!=null)
return true
if(this.memoryAddress!=null)
return false
if(this.arrayindexed!=null) {
@ -444,15 +495,20 @@ data class AssignTarget(val register: Register?,
class PostIncrDecr(var target: AssignTarget, val operator: String, override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline = false
override fun linkParents(parent: Node) {
this.parent = parent
target.linkParents(this)
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun replaceChildNode(node: Node, replacement: Node) {
require(replacement is AssignTarget && node===target)
target = replacement
replacement.parent = this
}
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
override fun toString(): String {
return "PostIncrDecr(op: $operator, target: $target, pos=$position)"
@ -464,15 +520,15 @@ class Jump(val address: Int?,
val generatedLabel: String?, // used in code generation scenarios
override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline = false
override fun linkParents(parent: Node) {
this.parent = parent
identifier?.linkParents(this)
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun replaceChildNode(node: Node, replacement: Node) = throw FatalAstException("can't replace here")
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
override fun toString(): String {
return "Jump(addr: $address, identifier: $identifier, label: $generatedLabel; pos=$position)"
@ -480,20 +536,29 @@ class Jump(val address: Int?,
}
class FunctionCallStatement(override var target: IdentifierReference,
override var arglist: MutableList<Expression>,
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 NumericLiteralValue }
override fun linkParents(parent: Node) {
this.parent = parent
target.linkParents(this)
arglist.forEach { it.linkParents(this) }
args.forEach { it.linkParents(this) }
}
override fun replaceChildNode(node: Node, replacement: Node) {
if(node===target)
target = replacement as IdentifierReference
else {
val idx = args.indexOfFirst { it===node }
args[idx] = replacement as Expression
}
replacement.parent = this
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
override fun toString(): String {
return "FunctionCallStatement(target=$target, pos=$position)"
@ -502,22 +567,20 @@ class FunctionCallStatement(override var target: IdentifierReference,
class InlineAssembly(val assembly: String, override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline = true
override fun linkParents(parent: Node) {
this.parent = parent
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun replaceChildNode(node: Node, replacement: Node) = throw FatalAstException("can't replace here")
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
}
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
@ -533,28 +596,27 @@ class AnonymousScope(override var statements: MutableList<Statement>,
statements.forEach { it.linkParents(this) }
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun replaceChildNode(node: Node, replacement: Node) {
require(replacement is Statement)
val idx = statements.indexOfFirst { it===node }
statements[idx] = replacement
replacement.parent = this
}
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
}
class NopStatement(override val position: Position): Statement() {
override lateinit var parent: Node
override val expensiveToInline = false
override fun linkParents(parent: Node) {
this.parent = parent
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun replaceChildNode(node: Node, replacement: Node) = throw FatalAstException("can't replace here")
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
}
}
override fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
}
// the subroutine class covers both the normal user-defined subroutines,
@ -565,20 +627,13 @@ class Subroutine(override val name: String,
val returntypes: List<DataType>,
val asmParameterRegisters: List<RegisterOrStatusflag>,
val asmReturnvaluesRegisters: List<RegisterOrStatusflag>,
val asmClobbers: Set<Register>,
val asmClobbers: Set<CpuRegister>,
val asmAddress: Int?,
val isAsmSubroutine: Boolean,
override var statements: MutableList<Statement>,
override val position: Position) : Statement(), INameScope {
var keepAlways: Boolean = false
override val expensiveToInline
get() = statements.any { it.expensiveToInline }
override lateinit var parent: Node
val calledBy = mutableListOf<Node>()
val calls = mutableSetOf<Subroutine>()
val scopedname: String by lazy { makeScopedName(name) }
override fun linkParents(parent: Node) {
@ -587,13 +642,23 @@ class Subroutine(override val name: String,
statements.forEach { it.linkParents(this) }
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun replaceChildNode(node: Node, replacement: Node) {
require(replacement is Statement)
val idx = statements.indexOfFirst { it===node }
statements[idx] = replacement
replacement.parent = this
}
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
override fun toString(): String {
return "Subroutine(name=$name, parameters=$parameters, returntypes=$returntypes, ${statements.size} statements, address=$asmAddress)"
}
fun regXasResult() = asmReturnvaluesRegisters.any { it.registerOrPair in setOf(RegisterOrPair.X, RegisterOrPair.AX, RegisterOrPair.XY) }
fun regXasParam() = asmParameterRegisters.any { it.registerOrPair in setOf(RegisterOrPair.X, RegisterOrPair.AX, RegisterOrPair.XY) }
fun amountOfRtsInAsm(): Int = statements
.asSequence()
.filter { it is InlineAssembly }
@ -601,6 +666,7 @@ class Subroutine(override val name: String,
.count { " rti" in it || "\trti" in it || " rts" in it || "\trts" in it || " jmp" in it || "\tjmp" in it }
}
open class SubroutineParameter(val name: String,
val type: DataType,
override val position: Position) : Node {
@ -609,6 +675,10 @@ open class SubroutineParameter(val name: String,
override fun linkParents(parent: Node) {
this.parent = parent
}
override fun replaceChildNode(node: Node, replacement: Node) {
throw FatalAstException("can't replace anything in a subroutineparameter node")
}
}
class IfStatement(var condition: Expression,
@ -616,8 +686,6 @@ class IfStatement(var condition: Expression,
var elsepart: AnonymousScope,
override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline: Boolean
get() = truepart.expensiveToInline || elsepart.expensiveToInline
override fun linkParents(parent: Node) {
this.parent = parent
@ -626,8 +694,19 @@ class IfStatement(var condition: Expression,
elsepart.linkParents(this)
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun replaceChildNode(node: Node, replacement: Node) {
when {
node===condition -> condition = replacement as Expression
node===truepart -> truepart = replacement as AnonymousScope
node===elsepart -> elsepart = replacement as AnonymousScope
else -> throw FatalAstException("invalid replace")
}
replacement.parent = this
}
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
}
class BranchStatement(var condition: BranchCondition,
@ -635,8 +714,6 @@ class BranchStatement(var condition: BranchCondition,
var elsepart: AnonymousScope,
override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline: Boolean
get() = truepart.expensiveToInline || elsepart.expensiveToInline
override fun linkParents(parent: Node) {
this.parent = parent
@ -644,38 +721,57 @@ class BranchStatement(var condition: BranchCondition,
elsepart.linkParents(this)
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun replaceChildNode(node: Node, replacement: Node) {
when {
node===truepart -> truepart = replacement as AnonymousScope
node===elsepart -> elsepart = replacement as AnonymousScope
else -> throw FatalAstException("invalid replace")
}
replacement.parent = this
}
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
}
class ForLoop(val loopRegister: Register?,
var loopVar: IdentifierReference?,
class ForLoop(var loopVar: IdentifierReference,
var iterable: Expression,
var body: AnonymousScope,
override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline = true
override fun linkParents(parent: Node) {
this.parent=parent
loopVar?.linkParents(this)
loopVar.linkParents(this)
iterable.linkParents(this)
body.linkParents(this)
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun replaceChildNode(node: Node, replacement: Node) {
when {
node===loopVar -> loopVar = replacement as IdentifierReference
node===iterable -> iterable = replacement as Expression
node===body -> body = replacement as AnonymousScope
else -> throw FatalAstException("invalid replace")
}
replacement.parent = this
}
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
override fun toString(): String {
return "ForLoop(loopVar: $loopVar, loopReg: $loopRegister, iterable: $iterable, pos=$position)"
return "ForLoop(loopVar: $loopVar, iterable: $iterable, pos=$position)"
}
fun loopVarDt(program: Program) = loopVar.inferType(program)
}
class WhileLoop(var condition: Expression,
var body: AnonymousScope,
override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline = true
override fun linkParents(parent: Node) {
this.parent = parent
@ -683,15 +779,45 @@ class WhileLoop(var condition: Expression,
body.linkParents(this)
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun replaceChildNode(node: Node, replacement: Node) {
when {
node===condition -> condition = replacement as Expression
node===body -> body = replacement as AnonymousScope
else -> throw FatalAstException("invalid replace")
}
replacement.parent = this
}
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
}
class RepeatLoop(var body: AnonymousScope,
var untilCondition: Expression,
override val position: Position) : Statement() {
class RepeatLoop(var iterations: Expression?, var body: AnonymousScope, override val position: Position) : Statement() {
override lateinit var parent: Node
override fun linkParents(parent: Node) {
this.parent = parent
iterations?.linkParents(this)
body.linkParents(this)
}
override fun replaceChildNode(node: Node, replacement: Node) {
when {
node===iterations -> iterations = replacement as Expression
node===body -> body = replacement as AnonymousScope
else -> throw FatalAstException("invalid replace")
}
replacement.parent = this
}
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
}
class UntilLoop(var body: AnonymousScope,
var untilCondition: Expression,
override val position: Position) : Statement() {
override lateinit var parent: Node
override val expensiveToInline = true
override fun linkParents(parent: Node) {
this.parent = parent
@ -699,15 +825,23 @@ class RepeatLoop(var body: AnonymousScope,
body.linkParents(this)
}
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun replaceChildNode(node: Node, replacement: Node) {
when {
node===untilCondition -> untilCondition = replacement as Expression
node===body -> body = replacement as AnonymousScope
else -> throw FatalAstException("invalid replace")
}
replacement.parent = this
}
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
}
class WhenStatement(var condition: Expression,
var choices: MutableList<WhenChoice>,
override val position: Position): Statement() {
override lateinit var parent: Node
override val expensiveToInline: Boolean = true
override fun linkParents(parent: Node) {
this.parent = parent
@ -715,6 +849,16 @@ class WhenStatement(var condition: Expression,
choices.forEach { it.linkParents(this) }
}
override fun replaceChildNode(node: Node, replacement: Node) {
if(node===condition)
condition = replacement as Expression
else {
val idx = choices.withIndex().find { it.value===node }!!.index
choices[idx] = replacement as WhenChoice
}
replacement.parent = this
}
fun choiceValues(program: Program): List<Pair<List<Int>?, WhenChoice>> {
// only gives sensible results when the choices are all valid (constant integers)
val result = mutableListOf<Pair<List<Int>?, WhenChoice>>()
@ -733,7 +877,7 @@ class WhenStatement(var condition: Expression,
}
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
}
class WhenChoice(var values: List<Expression>?, // if null, this is the 'else' part
@ -747,12 +891,18 @@ class WhenChoice(var values: List<Expression>?, // if null, this is t
this.parent = parent
}
override fun replaceChildNode(node: Node, replacement: Node) {
require(replacement is AnonymousScope && node===statements)
statements = replacement
replacement.parent = this
}
override fun toString(): String {
return "Choice($values at $position)"
}
fun accept(visitor: IAstVisitor) = visitor.visit(this)
fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
}
@ -761,18 +911,24 @@ class StructDecl(override val name: String,
override val position: Position): Statement(), INameScope {
override lateinit var parent: Node
override val expensiveToInline: Boolean = true
override fun linkParents(parent: Node) {
this.parent = parent
this.statements.forEach { it.linkParents(this) }
}
override fun replaceChildNode(node: Node, replacement: Node) {
require(replacement is Statement)
val idx = statements.indexOfFirst { it===node }
statements[idx] = replacement
replacement.parent = this
}
val numberOfElements: Int
get() = this.statements.size
override fun accept(visitor: IAstVisitor) = visitor.visit(this)
override fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
override fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
fun nameOfFirstMember() = (statements.first() as VarDecl).name
}
@ -785,11 +941,16 @@ class DirectMemoryWrite(var addressExpression: Expression, override val position
this.addressExpression.linkParents(this)
}
override fun replaceChildNode(node: Node, replacement: Node) {
require(replacement is Expression && node===addressExpression)
addressExpression = replacement
replacement.parent = this
}
override fun toString(): String {
return "DirectMemoryWrite($addressExpression)"
}
fun accept(visitor: IAstVisitor) = visitor.visit(this)
fun accept(visitor: IAstModifyingVisitor) = visitor.visit(this)
fun accept(visitor: AstWalker, parent: Node) = visitor.visit(this, parent)
}

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)

132
compiler/src/prog8/compiler/BeforeAsmGenerationAstChanger.kt Normal file
View File

@ -0,0 +1,132 @@
package prog8.compiler
import prog8.ast.Node
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.ast.processing.AstWalker
import prog8.ast.processing.IAstModification
import prog8.ast.statements.*
internal class BeforeAsmGenerationAstChanger(val program: Program, val errors: ErrorReporter) : AstWalker() {
private val noModifications = emptyList<IAstModification>()
override fun after(decl: VarDecl, parent: Node): Iterable<IAstModification> {
if (decl.value == null && decl.type == VarDeclType.VAR && decl.datatype in NumericDatatypes) {
// a numeric vardecl without an initial value is initialized with zero.
decl.value = decl.zeroElementValue()
}
return noModifications
}
override fun after(assignment: Assignment, parent: Node): Iterable<IAstModification> {
// Try to replace A = B <operator> Something by A= B, A = A <operator> Something
// this triggers the more efficent augmented assignment code generation more often.
if(!assignment.isAugmentable
&& assignment.target.identifier != null
&& assignment.target.isNotMemory(program.namespace)) {
val binExpr = assignment.value as? BinaryExpression
if(binExpr!=null && binExpr.operator !in comparisonOperators) {
if(binExpr.left !is BinaryExpression) {
val assignLeft = Assignment(assignment.target, binExpr.left, assignment.position)
return listOf(
IAstModification.InsertBefore(assignment, assignLeft, parent),
IAstModification.ReplaceNode(binExpr.left, assignment.target.toExpression(), binExpr))
}
}
}
return noModifications
}
override fun after(scope: AnonymousScope, parent: Node): Iterable<IAstModification> {
val decls = scope.statements.filterIsInstance<VarDecl>()
val sub = scope.definingSubroutine()
if (sub != null) {
val existingVariables = sub.statements.filterIsInstance<VarDecl>().associateBy { it.name }
var conflicts = false
decls.forEach {
val existing = existingVariables[it.name]
if (existing != null) {
errors.err("variable ${it.name} already defined in subroutine ${sub.name} at ${existing.position}", it.position)
conflicts = true
}
}
if (!conflicts) {
val numericVarsWithValue = decls.filter { it.value != null && it.datatype in NumericDatatypes }
return numericVarsWithValue.map {
val initValue = it.value!! // assume here that value has always been set by now
it.value = null // make sure no value init assignment for this vardecl will be created later (would be superfluous)
val target = AssignTarget(IdentifierReference(listOf(it.name), it.position), null, null, it.position)
val assign = Assignment(target, initValue, it.position)
initValue.parent = assign
IAstModification.InsertFirst(assign, scope)
} + decls.map { IAstModification.ReplaceNode(it, NopStatement(it.position), scope) } +
decls.map { IAstModification.InsertFirst(it, sub) } // move it up to the subroutine
}
}
return noModifications
}
override fun after(subroutine: Subroutine, parent: Node): Iterable<IAstModification> {
// add the implicit return statement at the end (if it's not there yet), but only if it's not a kernel routine.
// and if an assembly block doesn't contain a rts/rti, and some other situations.
val mods = mutableListOf<IAstModification>()
val returnStmt = Return(null, subroutine.position)
if (subroutine.asmAddress == null
&& subroutine.statements.isNotEmpty()
&& subroutine.amountOfRtsInAsm() == 0
&& subroutine.statements.lastOrNull { it !is VarDecl } !is Return
&& subroutine.statements.last() !is Subroutine) {
mods += IAstModification.InsertLast(returnStmt, subroutine)
}
// precede a subroutine with a return to avoid falling through into the subroutine from code above it
val outerScope = subroutine.definingScope()
val outerStatements = outerScope.statements
val subroutineStmtIdx = outerStatements.indexOf(subroutine)
if (subroutineStmtIdx > 0
&& outerStatements[subroutineStmtIdx - 1] !is Jump
&& outerStatements[subroutineStmtIdx - 1] !is Subroutine
&& outerStatements[subroutineStmtIdx - 1] !is Return
&& outerScope !is Block) {
mods += IAstModification.InsertAfter(outerStatements[subroutineStmtIdx - 1], returnStmt, outerScope as Node)
}
return mods
}
override fun after(typecast: TypecastExpression, parent: Node): Iterable<IAstModification> {
// see if we can remove superfluous typecasts (outside of expressions)
// such as casting byte<->ubyte, word<->uword
// Also the special typecast of a reference type (str, array) to an UWORD will be changed into address-of.
val sourceDt = typecast.expression.inferType(program).typeOrElse(DataType.STRUCT)
if (typecast.type in ByteDatatypes && sourceDt in ByteDatatypes
|| typecast.type in WordDatatypes && sourceDt in WordDatatypes) {
if(typecast.parent !is Expression) {
return listOf(IAstModification.ReplaceNode(typecast, typecast.expression, parent))
}
}
// Note: for various reasons (most importantly, code simplicity), the code generator assumes/requires
// that the types of assignment values and their target are the same,
// and that the types of both operands of a binaryexpression node are the same.
// So, it is not easily possible to remove the typecasts that are there to make these conditions true.
if(sourceDt in PassByReferenceDatatypes) {
if(typecast.type==DataType.UWORD) {
return listOf(IAstModification.ReplaceNode(
typecast,
AddressOf(typecast.expression as IdentifierReference, typecast.position),
parent
))
} else {
errors.err("cannot cast pass-by-reference value to type ${typecast.type} (only to UWORD)", typecast.position)
}
}
return noModifications
}
}

81
compiler/src/prog8/compiler/Compiler.kt
View File

@ -1,13 +1,8 @@
package prog8.compiler
import prog8.ast.base.ArrayDatatypes
import prog8.ast.base.DataType
import prog8.ast.base.StringDatatypes
import prog8.ast.expressions.AddressOf
import java.io.File
import java.io.InputStream
import java.nio.file.Path
import java.util.*
import kotlin.math.abs
enum class OutputType {
@ -28,8 +23,6 @@ enum class ZeropageType {
DONTUSE
}
data class IntegerOrAddressOf(val integer: Int?, val addressOf: AddressOf?)
data class CompilationOptions(val output: OutputType,
val launcher: LauncherType,
val zeropage: ZeropageType,
@ -73,77 +66,3 @@ fun loadAsmIncludeFile(filename: String, source: Path): String {
internal fun tryGetEmbeddedResource(name: String): InputStream? {
return object{}.javaClass.getResourceAsStream("/prog8lib/$name")
}
class HeapValues {
data class HeapValue(val type: DataType, val str: String?, val array: Array<IntegerOrAddressOf>?, val doubleArray: DoubleArray?) {
override fun equals(other: Any?): Boolean {
if (this === other) return true
if (javaClass != other?.javaClass) return false
other as HeapValue
return type==other.type && str==other.str && Arrays.equals(array, other.array) && Arrays.equals(doubleArray, other.doubleArray)
}
override fun hashCode(): Int = Objects.hash(str, array, doubleArray)
val arraysize: Int = array?.size ?: doubleArray?.size ?: 0
}
private val heap = mutableMapOf<Int, HeapValue>()
private var heapId = 1
fun size(): Int = heap.size
fun addString(type: DataType, str: String): Int {
if (str.length > 255)
throw IllegalArgumentException("string length must be 0-255")
// strings are 'interned' and shared if they're the isSameAs
val value = HeapValue(type, str, null, null)
val existing = heap.filter { it.value==value }.map { it.key }.firstOrNull()
if(existing!=null)
return existing
val newId = heapId++
heap[newId] = value
return newId
}
fun addIntegerArray(type: DataType, array: Array<IntegerOrAddressOf>): Int {
// arrays are never shared, don't check for existing
if(type !in ArrayDatatypes)
throw CompilerException("wrong array type")
val newId = heapId++
heap[newId] = HeapValue(type, null, array, null)
return newId
}
fun addDoublesArray(darray: DoubleArray): Int {
// arrays are never shared, don't check for existing
val newId = heapId++
heap[newId] = HeapValue(DataType.ARRAY_F, null, null, darray)
return newId
}
fun update(heapId: Int, str: String) {
val oldVal = heap[heapId] ?: throw IllegalArgumentException("heapId not found in heap")
if(oldVal.type in StringDatatypes) {
if (oldVal.str!!.length != str.length)
throw IllegalArgumentException("heap string length mismatch")
heap[heapId] = oldVal.copy(str = str)
}
else throw IllegalArgumentException("heap data type mismatch")
}
fun update(heapId: Int, heapval: HeapValue) {
if(heapId !in heap)
throw IllegalArgumentException("heapId not found in heap")
heap[heapId] = heapval
}
fun get(heapId: Int): HeapValue {
return heap[heapId] ?:
throw IllegalArgumentException("heapId $heapId not found in heap")
}
fun allEntries() = heap.entries
}

203
compiler/src/prog8/compiler/Main.kt
View File

@ -4,14 +4,13 @@ import prog8.ast.AstToSourceCode
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.statements.Directive
import prog8.compiler.target.c64.MachineDefinition
import prog8.compiler.target.c64.codegen.AsmGen
import prog8.compiler.target.CompilationTarget
import prog8.optimizer.UnusedCodeRemover
import prog8.optimizer.constantFold
import prog8.optimizer.optimizeStatements
import prog8.optimizer.simplifyExpressions
import prog8.parser.ModuleImporter
import prog8.parser.ParsingFailedError
import prog8.parser.importLibraryModule
import prog8.parser.importModule
import prog8.parser.moduleName
import java.nio.file.Path
import kotlin.system.measureTimeMillis
@ -25,90 +24,33 @@ class CompilationResult(val success: Boolean,
fun compileProgram(filepath: Path,
optimize: Boolean,
writeAssembly: Boolean): CompilationResult {
writeAssembly: Boolean,
outputDir: Path): CompilationResult {
var programName = ""
lateinit var programAst: Program
var programName: String? = null
var importedFiles: List<Path> = emptyList()
var success=false
lateinit var importedFiles: List<Path>
val errors = ErrorReporter()
try {
val totalTime = measureTimeMillis {
// import main module and everything it needs
println("Parsing...")
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.")
// if we're producing a PRG or BASIC program, include the c64utils and c64lib libraries
if (compilerOptions.launcher == LauncherType.BASIC || compilerOptions.output == OutputType.PRG) {
importLibraryModule(programAst, "c64lib")
importLibraryModule(programAst, "c64utils")
}
// always import prog8lib and math
importLibraryModule(programAst, "math")
importLibraryModule(programAst, "prog8lib")
// perform initial syntax checks and constant folding
println("Syntax check...")
val time1 = measureTimeMillis {
programAst.checkIdentifiers()
}
//println(" time1: $time1")
val time2 = measureTimeMillis {
programAst.constantFold()
}
//println(" time2: $time2")
val time3 = measureTimeMillis {
programAst.removeNopsFlattenAnonScopes()
programAst.reorderStatements()
programAst.addTypecasts()
}
//println(" time3: $time3")
val time4 = measureTimeMillis {
programAst.checkValid(compilerOptions) // check if tree is valid
}
//println(" time4: $time4")
programAst.checkIdentifiers()
if (optimize) {
// optimize the parse tree
println("Optimizing...")
while (true) {
// keep optimizing expressions and statements until no more steps remain
val optsDone1 = programAst.simplifyExpressions()
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
val (ast, compilationOptions, imported) = parseImports(filepath, errors)
programAst = ast
importedFiles = imported
processAst(programAst, errors, compilationOptions)
if (optimize)
optimizeAst(programAst, errors)
postprocessAst(programAst, errors, compilationOptions)
// printAst(programAst)
if(writeAssembly) {
// asm generation directly from the Ast, no need for intermediate code
val zeropage = MachineDefinition.C64Zeropage(compilerOptions)
programAst.anonscopeVarsCleanup()
val assembly = AsmGen(programAst, compilerOptions, zeropage).compileToAssembly(optimize)
assembly.assemble(compilerOptions)
programName = assembly.name
}
success = true
if(writeAssembly)
programName = writeAssembly(programAst, errors, outputDir, optimize, compilationOptions)
}
System.out.flush()
System.err.flush()
println("\nTotal compilation+assemble time: ${totalTime / 1000.0} sec.")
return CompilationResult(true, programAst, programName, importedFiles)
} catch (px: ParsingFailedError) {
System.err.print("\u001b[91m") // bright red
@ -131,16 +73,32 @@ fun compileProgram(filepath: Path,
System.out.flush()
throw x
}
return CompilationResult(success, programAst, programName ?: "", importedFiles)
return CompilationResult(false, Program("failed", mutableListOf()), programName, emptyList())
}
fun printAst(programAst: Program) {
println()
val printer = AstToSourceCode(::print, programAst)
printer.visit(programAst)
println()
}
private fun parseImports(filepath: Path, errors: ErrorReporter): Triple<Program, CompilationOptions, List<Path>> {
println("Parsing...")
val importer = ModuleImporter()
val programAst = Program(moduleName(filepath.fileName), mutableListOf())
importer.importModule(programAst, filepath)
errors.handle()
val importedFiles = programAst.modules.filter { !it.source.startsWith("@embedded@") }.map { it.source }
val compilerOptions = determineCompilationOptions(programAst)
if (compilerOptions.launcher == LauncherType.BASIC && compilerOptions.output != OutputType.PRG)
throw ParsingFailedError("${programAst.modules.first().position} BASIC launcher requires output type PRG.")
// depending on the mach9ine and compiler options we may have to include some libraries
CompilationTarget.machine.importLibs(compilerOptions, importer, programAst)
// always import prog8lib and math
importer.importLibraryModule(programAst, "math")
importer.importLibraryModule(programAst, "prog8lib")
errors.handle()
return Triple(programAst, compilerOptions, importedFiles)
}
private fun determineCompilationOptions(program: Program): CompilationOptions {
val mainModule = program.modules.first()
@ -177,3 +135,78 @@ private fun determineCompilationOptions(program: Program): CompilationOptions {
zpType, zpReserved, floatsEnabled
)
}
private fun processAst(programAst: Program, errors: ErrorReporter, compilerOptions: CompilationOptions) {
// perform initial syntax checks and processings
println("Processing...")
programAst.checkIdentifiers(errors)
errors.handle()
programAst.constantFold(errors)
errors.handle()
programAst.reorderStatements()
programAst.addTypecasts(errors)
errors.handle()
programAst.variousCleanups()
programAst.checkValid(compilerOptions, errors)
errors.handle()
programAst.checkIdentifiers(errors)
errors.handle()
}
private fun optimizeAst(programAst: Program, errors: ErrorReporter) {
// optimize the parse tree
println("Optimizing...")
while (true) {
// keep optimizing expressions and statements until no more steps remain
val optsDone1 = programAst.simplifyExpressions()
val optsDone2 = programAst.optimizeStatements(errors)
programAst.constantFold(errors) // because simplified statements and expressions could give rise to more constants that can be folded away:
errors.handle()
if (optsDone1 + optsDone2 == 0)
break
}
val remover = UnusedCodeRemover(errors)
remover.visit(programAst)
remover.applyModifications()
errors.handle()
}
private fun postprocessAst(programAst: Program, errors: ErrorReporter, compilerOptions: CompilationOptions) {
programAst.addTypecasts(errors)
errors.handle()
programAst.variousCleanups()
programAst.checkValid(compilerOptions, errors) // check if final tree is still valid
errors.handle()
programAst.checkRecursion(errors) // check if there are recursive subroutine calls
errors.handle()
programAst.verifyFunctionArgTypes()
}
private fun writeAssembly(programAst: Program, errors: ErrorReporter, outputDir: Path,
optimize: Boolean, compilerOptions: CompilationOptions): String {
// asm generation directly from the Ast,
programAst.processAstBeforeAsmGeneration(errors)
errors.handle()
// printAst(programAst)
CompilationTarget.machine.initializeZeropage(compilerOptions)
val assembly = CompilationTarget.asmGenerator(
programAst,
errors,
CompilationTarget.machine.zeropage,
compilerOptions,
outputDir).compileToAssembly(optimize)
assembly.assemble(compilerOptions)
errors.handle()
return assembly.name
}
fun printAst(programAst: Program) {
println()
val printer = AstToSourceCode(::print, programAst)
printer.visit(programAst)
println()
}

19
compiler/src/prog8/compiler/Zeropage.kt
View File

@ -8,6 +8,13 @@ class ZeropageDepletedError(message: String) : Exception(message)
abstract class Zeropage(protected val options: CompilationOptions) {
abstract val SCRATCH_B1 : Int // temp storage for a single byte
abstract val SCRATCH_REG : Int // temp storage for a register
abstract val SCRATCH_REG_X : Int // temp storage for register X (the evaluation stack pointer)
abstract val SCRATCH_W1 : Int // temp storage 1 for a word $fb+$fc
abstract val SCRATCH_W2 : Int // temp storage 2 for a word $fb+$fc
private val allocations = mutableMapOf<Int, Pair<String, DataType>>()
val free = mutableListOf<Int>() // subclasses must set this to the appropriate free locations.
@ -15,8 +22,8 @@ abstract class Zeropage(protected val options: CompilationOptions) {
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"}
fun allocate(scopedname: String, datatype: DataType, position: Position?, errors: ErrorReporter): Int {
assert(scopedname.isEmpty() || !allocations.values.any { it.first==scopedname } ) {"scopedname can't be allocated twice"}
if(options.zeropage==ZeropageType.DONTUSE)
throw CompilerException("zero page usage has been disabled")
@ -28,9 +35,9 @@ abstract class Zeropage(protected val options: CompilationOptions) {
DataType.FLOAT -> {
if (options.floats) {
if(position!=null)
printWarning("allocated a large value (float) in zeropage", position)
errors.warn("allocated a large value (float) in zeropage", position)
else
printWarning("$scopedname: allocated a large value (float) in zeropage")
errors.warn("$scopedname: allocated a large value (float) in zeropage", position ?: Position.DUMMY)
5
} else throw CompilerException("floating point option not enabled")
}
@ -39,13 +46,13 @@ abstract class Zeropage(protected val options: CompilationOptions) {
if(free.size > 0) {
if(size==1) {
for(candidate in free.min()!! .. free.max()!!+1) {
for(candidate in free.minOrNull()!! .. free.maxOrNull()!!+1) {
if(loneByte(candidate))
return makeAllocation(candidate, 1, datatype, scopedname)
}
return makeAllocation(free[0], 1, datatype, scopedname)
}
for(candidate in free.min()!! .. free.max()!!+1) {
for(candidate in free.minOrNull()!! .. free.maxOrNull()!!+1) {
if (sequentialFree(candidate, size))
return makeAllocation(candidate, size, datatype, scopedname)
}

18
compiler/src/prog8/compiler/target/CompilationTarget.kt Normal file
View File

@ -0,0 +1,18 @@
package prog8.compiler.target
import prog8.ast.Program
import prog8.ast.base.ErrorReporter
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, ErrorReporter, Zeropage, CompilationOptions, Path) -> IAssemblyGenerator
}
}

14
compiler/src/prog8/compiler/target/IAssemblyGenerator.kt Normal file
View File

@ -0,0 +1,14 @@
package prog8.compiler.target
import prog8.compiler.CompilationOptions
internal interface IAssemblyGenerator {
fun compileToAssembly(optimize: Boolean): IAssemblyProgram
}
internal const val generatedLabelPrefix = "_prog8_label_"
internal interface IAssemblyProgram {
val name: String
fun assemble(options: CompilationOptions)
}

39
compiler/src/prog8/compiler/target/IMachineDefinition.kt Normal file
View File

@ -0,0 +1,39 @@
package prog8.compiler.target
import prog8.ast.Program
import prog8.compiler.CompilationOptions
import prog8.compiler.Zeropage
import prog8.parser.ModuleImporter
internal interface IMachineFloat {
fun toDouble(): Double
fun makeFloatFillAsm(): String
}
internal enum class CpuType {
CPU6502,
CPU65c02
}
internal interface IMachineDefinition {
val FLOAT_MAX_NEGATIVE: Double
val FLOAT_MAX_POSITIVE: Double
val FLOAT_MEM_SIZE: Int
val POINTER_MEM_SIZE: Int
val ESTACK_LO: Int
val ESTACK_HI: Int
val BASIC_LOAD_ADDRESS : Int
val RAW_LOAD_ADDRESS : Int
val opcodeNames: Set<String>
var zeropage: Zeropage
val initSystemProcname: String
val cpu: CpuType
fun initializeZeropage(compilerOptions: CompilationOptions)
fun getFloat(num: Number): IMachineFloat
fun getFloatRomConst(number: Double): String?
fun importLibs(compilerOptions: CompilationOptions, importer: ModuleImporter, program: Program)
fun launchEmulator(programName: String)
}

68
compiler/src/prog8/compiler/target/c64/AssemblyProgram.kt
View File

@ -2,70 +2,72 @@ package prog8.compiler.target.c64
import prog8.compiler.CompilationOptions
import prog8.compiler.OutputType
import java.io.File
import prog8.compiler.target.IAssemblyProgram
import prog8.compiler.target.generatedLabelPrefix
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")
companion object {
// 6502 opcodes (including aliases and illegal opcodes), these cannot be used as variable or label names
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")
}
fun assemble(options: CompilationOptions) {
// add "-Wlong-branch" to see warnings about conversion of branch instructions to jumps
override fun assemble(options: CompilationOptions) {
// add "-Wlong-branch" to see warnings about conversion of branch instructions to jumps (default = do this silently)
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, "--no-monitor")
"-Wall", "-Wno-strict-bool", "-Wno-shadow", // "-Werror",
"--dump-labels", "--vice-labels", "-l", viceMonListFile.toString(), "--no-monitor")
val outFile = when(options.output) {
val outFile = when (options.output) {
OutputType.PRG -> {
command.add("--cbm-prg")
println("\nCreating C-64 prg.")
"$name.prg"
println("\nCreating prg.")
prgFile
}
OutputType.RAW -> {
command.add("--nostart")
println("\nCreating raw binary.")
"$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()
if(result!=0) {
if (result != 0) {
System.err.println("assembler failed with returncode $result")
exitProcess(result)
}
removeGeneratedLabelsFromMonlist()
generateBreakpointList()
}
private fun removeGeneratedLabelsFromMonlist() {
val pattern = Regex("""al (\w+) \S+${generatedLabelPrefix}.+?""")
val lines = viceMonListFile.toFile().readLines()
viceMonListFile.toFile().outputStream().bufferedWriter().use {
for (line in lines) {
if(pattern.matchEntire(line)==null)
it.write(line+"\n")
}
}
}
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])
if (match != null)
breakpoints.add("break \$" + match.groupValues[1])
}
val num = breakpoints.size
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")
}
}

247
compiler/src/prog8/compiler/target/c64/C64MachineDefinition.kt Normal file
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package prog8.compiler.target.c64
import prog8.ast.Program
import prog8.compiler.*
import prog8.compiler.target.CpuType
import prog8.compiler.target.IMachineDefinition
import prog8.compiler.target.IMachineFloat
import prog8.parser.ModuleImporter
import java.io.IOException
import java.math.RoundingMode
import kotlin.math.absoluteValue
import kotlin.math.pow
internal object C64MachineDefinition: IMachineDefinition {
override val cpu = CpuType.CPU6502
// 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
override val POINTER_MEM_SIZE = 2
override val BASIC_LOAD_ADDRESS = 0x0801
override 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
override val ESTACK_LO = 0xce00 // $ce00-$ceff inclusive
override val ESTACK_HI = 0xcf00 // $ce00-$ceff inclusive
override lateinit var zeropage: Zeropage
override val initSystemProcname = "c64.init_system"
override fun getFloat(num: Number) = Mflpt5.fromNumber(num)
override fun getFloatRomConst(number: Double): String? {
// try to match the ROM float constants to save memory
val mflpt5 = 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.ZERO" // not a ROM const
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 -> {}
}
}
}
return null
}
override fun importLibs(compilerOptions: CompilationOptions, importer: ModuleImporter, program: Program) {
if (compilerOptions.launcher == LauncherType.BASIC || compilerOptions.output == OutputType.PRG)
importer.importLibraryModule(program, "c64lib")
}
override fun launchEmulator(programName: String) {
for(emulator in listOf("x64sc", "x64")) {
println("\nStarting C-64 emulator $emulator...")
val cmdline = listOf(emulator, "-silent", "-moncommands", "$programName.vice-mon-list",
"-autostartprgmode", "1", "-autostart-warp", "-autostart", 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
}
}
override fun initializeZeropage(compilerOptions: CompilationOptions) {
zeropage = 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")
internal class C64Zeropage(options: CompilationOptions) : Zeropage(options) {
override val SCRATCH_B1 = 0x02 // temp storage for a single byte
override val SCRATCH_REG = 0x03 // temp storage for a register
override val SCRATCH_REG_X = 0xfa // temp storage for register X (the evaluation stack pointer)
override val SCRATCH_W1 = 0xfb // temp storage 1 for a word $fb+$fc
override val SCRATCH_W2 = 0xfd // temp storage 2 for a word $fb+$fc
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()
}
}
require(SCRATCH_B1 !in free)
require(SCRATCH_REG !in free)
require(SCRATCH_REG_X !in free)
require(SCRATCH_W1 !in free)
require(SCRATCH_W2 !in free)
for (reserved in options.zpReserved)
reserve(reserved)
}
}
internal data class Mflpt5(val b0: Short, val b1: Short, val b2: Short, val b3: Short, val b4: Short): IMachineFloat {
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: $this")
exponent == 0 -> zero
else -> {
val mantLong = mantissa.toLong()
Mflpt5(
exponent.toShort(),
(mantLong.and(0x7f000000L) ushr 24).or(sign).toShort(),
(mantLong.and(0x00ff0000L) ushr 16).toShort(),
(mantLong.and(0x0000ff00L) ushr 8).toShort(),
(mantLong.and(0x000000ffL)).toShort())
}
}
}
}
override fun toDouble(): Double {
if (this == zero) return 0.0
val exp = b0 - 128
val sign = (b1.toInt() and 0x80) > 0
val number = 0x80000000L.or(b1.toLong() shl 24).or(b2.toLong() shl 16).or(b3.toLong() shl 8).or(b4.toLong())
val result = number.toDouble() * (2.0).pow(exp) / 0x100000000
return if (sign) -result else result
}
override fun makeFloatFillAsm(): String {
val b0 = "$" + b0.toString(16).padStart(2, '0')
val b1 = "$" + b1.toString(16).padStart(2, '0')
val b2 = "$" + b2.toString(16).padStart(2, '0')
val b3 = "$" + b3.toString(16).padStart(2, '0')
val b4 = "$" + b4.toString(16).padStart(2, '0')
return "$b0, $b1, $b2, $b3, $b4"
}
}
}

255
compiler/src/prog8/compiler/target/c64/MachineDefinition.kt
View File

@ -1,255 +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
object MachineDefinition {
// 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)
// 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"
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 {
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 % 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
)
}

4
compiler/src/prog8/compiler/target/c64/Petscii.kt
View File

@ -1058,7 +1058,7 @@ object Petscii {
0.toShort()
else {
val case = if (lowercase) "lower" else "upper"
throw CharConversionException("no ${case}case Petscii character for '$it'")
throw CharConversionException("no ${case}case Petscii character for '$it' (${it.toShort()})")
}
}
}
@ -1076,7 +1076,7 @@ object Petscii {
0.toShort()
else {
val case = if (lowercase) "lower" else "upper"
throw CharConversionException("no ${case}Screencode character for '$it'")
throw CharConversionException("no ${case}Screencode character for '$it' (${it.toShort()})")
}
}
}

48
compiler/src/prog8/compiler/target/c64/codegen/AnonymousScopeVarsCleanup.kt
View File

@ -1,48 +0,0 @@
package prog8.compiler.target.c64.codegen
import prog8.ast.Program
import prog8.ast.base.AstException
import prog8.ast.base.NameError
import prog8.ast.processing.IAstModifyingVisitor
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
}
}

872
compiler/src/prog8/compiler/target/c64/codegen/AsmGen.kt
View File

File diff suppressed because it is too large Load Diff

154
compiler/src/prog8/compiler/target/c64/codegen/AsmOptimizer.kt
View File

@ -1,8 +1,5 @@
package prog8.compiler.target.c64.codegen
import prog8.compiler.target.c64.MachineDefinition.ESTACK_LO_HEX
import prog8.compiler.target.c64.MachineDefinition.ESTACK_LO_PLUS1_HEX
// note: see https://wiki.nesdev.com/w/index.php/6502_assembly_optimisations
@ -13,43 +10,45 @@ fun optimizeAssembly(lines: MutableList<String>): Int {
var linesByFour = getLinesBy(lines, 4)
var removeLines = optimizeUselessStackByteWrites(linesByFour)
if(removeLines.isNotEmpty()) {
for (i in removeLines.reversed())
lines.removeAt(i)
var mods = optimizeUselessStackByteWrites(linesByFour)
if(mods.isNotEmpty()) {
apply(mods, lines)
linesByFour = getLinesBy(lines, 4)
numberOfOptimizations++
}
removeLines = optimizeIncDec(linesByFour)
if(removeLines.isNotEmpty()) {
for (i in removeLines.reversed())
lines.removeAt(i)
mods = optimizeIncDec(linesByFour)
if(mods.isNotEmpty()) {
apply(mods, lines)
linesByFour = getLinesBy(lines, 4)
numberOfOptimizations++
}
removeLines = optimizeCmpSequence(linesByFour)
if(removeLines.isNotEmpty()) {
for (i in removeLines.reversed())
lines.removeAt(i)
mods = optimizeCmpSequence(linesByFour)
if(mods.isNotEmpty()) {
apply(mods, lines)
linesByFour = getLinesBy(lines, 4)
numberOfOptimizations++
}
removeLines = optimizeStoreLoadSame(linesByFour)
if(removeLines.isNotEmpty()) {
for (i in removeLines.reversed())
lines.removeAt(i)
mods = optimizeStoreLoadSame(linesByFour)
if(mods.isNotEmpty()) {
apply(mods, lines)
linesByFour = getLinesBy(lines, 4)
numberOfOptimizations++
}
mods= optimizeJsrRts(linesByFour)
if(mods.isNotEmpty()) {
apply(mods, lines)
linesByFour = getLinesBy(lines, 4)
numberOfOptimizations++
}
var linesByFourteen = getLinesBy(lines, 14)
removeLines = optimizeSameAssignments(linesByFourteen)
if(removeLines.isNotEmpty()) {
for (i in removeLines.reversed())
lines.removeAt(i)
mods = optimizeSameAssignments(linesByFourteen)
if(mods.isNotEmpty()) {
apply(mods, lines)
linesByFourteen = getLinesBy(lines, 14)
numberOfOptimizations++
}
@ -59,7 +58,22 @@ fun optimizeAssembly(lines: MutableList<String>): Int {
return numberOfOptimizations
}
fun optimizeCmpSequence(linesByFour: List<List<IndexedValue<String>>>): List<Int> {
private class Modification(val lineIndex: Int, val remove: Boolean, val replacement: String?)
private fun apply(modifications: List<Modification>, lines: MutableList<String>) {
for (modification in modifications.sortedBy { it.lineIndex }.reversed()) {
if(modification.remove)
lines.removeAt(modification.lineIndex)
else
lines[modification.lineIndex] = modification.replacement!!
}
}
private fun getLinesBy(lines: MutableList<String>, windowSize: Int) =
// 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 optimizeCmpSequence(linesByFour: List<List<IndexedValue<String>>>): List<Modification> {
// the when statement (on bytes) generates a sequence of:
// lda $ce01,x
// cmp #$20
@ -68,42 +82,42 @@ fun optimizeCmpSequence(linesByFour: List<List<IndexedValue<String>>>): List<Int
// cmp #$21
// beq check_prog8_s73choice_33
// the repeated lda can be removed
val removeLines = mutableListOf<Int>()
val mods = mutableListOf<Modification>()
for(lines in linesByFour) {
if(lines[0].value.trim()=="lda $ESTACK_LO_PLUS1_HEX,x" &&
if(lines[0].value.trim()=="lda P8ESTACK_LO+1,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
lines[3].value.trim()=="lda P8ESTACK_LO+1,x") {
mods.add(Modification(lines[3].index, true, null)) // remove the second lda
}
}
return removeLines
return mods
}
fun optimizeUselessStackByteWrites(linesByFour: List<List<IndexedValue<String>>>): List<Int> {
private fun optimizeUselessStackByteWrites(linesByFour: List<List<IndexedValue<String>>>): List<Modification> {
// 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>()
val mods = mutableListOf<Modification>()
for(lines in linesByFour) {
if(lines[0].value.trim()=="sta $ESTACK_LO_HEX,x" &&
if(lines[0].value.trim()=="sta P8ESTACK_LO,x" &&
lines[1].value.trim()=="dex" &&
lines[2].value.trim()=="inx" &&
lines[3].value.trim()=="lda $ESTACK_LO_HEX,x") {
removeLines.add(lines[1].index)
removeLines.add(lines[2].index)
removeLines.add(lines[3].index)
lines[3].value.trim()=="lda P8ESTACK_LO,x") {
mods.add(Modification(lines[1].index, true, null))
mods.add(Modification(lines[2].index, true, null))
mods.add(Modification(lines[3].index, true, null))
}
}
return removeLines
return mods
}
fun optimizeSameAssignments(linesByFourteen: List<List<IndexedValue<String>>>): List<Int> {
private fun optimizeSameAssignments(linesByFourteen: List<List<IndexedValue<String>>>): List<Modification> {
// 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 transform the Ast, and never even create the inefficient asm in the first place...
// @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>()
val mods = mutableListOf<Modification>()
for (pair in linesByFourteen) {
val first = pair[0].value.trimStart()
val second = pair[1].value.trimStart()
@ -122,8 +136,8 @@ fun optimizeSameAssignments(linesByFourteen: List<List<IndexedValue<String>>>):
val fourthvalue = sixth.substring(4)
if(firstvalue==thirdvalue && secondvalue==fourthvalue) {
// lda/ldy sta/sty twice the isSameAs word --> remove second lda/ldy pair (fifth and sixth lines)
removeLines.add(pair[4].index)
removeLines.add(pair[5].index)
mods.add(Modification(pair[4].index, true, null))
mods.add(Modification(pair[5].index, true, null))
}
}
@ -132,12 +146,13 @@ fun optimizeSameAssignments(linesByFourteen: List<List<IndexedValue<String>>>):
val secondvalue = third.substring(4)
if(firstvalue==secondvalue) {
// lda value / sta ? / lda isSameAs-value / sta ? -> remove second lda (third line)
removeLines.add(pair[2].index)
mods.add(Modification(pair[2].index, true, null))
}
}
if(first.startsWith("lda") && second.startsWith("ldy") && third.startsWith("sta") && fourth.startsWith("sty") &&
fifth.startsWith("lda") && sixth.startsWith("ldy") && seventh.startsWith("jsr c64flt.copy_float")) {
fifth.startsWith("lda") && sixth.startsWith("ldy") &&
(seventh.startsWith("jsr c64flt.copy_float") || seventh.startsWith("jsr cx16flt.copy_float"))) {
val nineth = pair[8].value.trimStart()
val tenth = pair[9].value.trimStart()
@ -147,28 +162,25 @@ fun optimizeSameAssignments(linesByFourteen: List<List<IndexedValue<String>>>):
val fourteenth = pair[13].value.trimStart()
if(eighth.startsWith("lda") && nineth.startsWith("ldy") && tenth.startsWith("sta") && eleventh.startsWith("sty") &&
twelveth.startsWith("lda") && thirteenth.startsWith("ldy") && fourteenth.startsWith("jsr c64flt.copy_float")) {
twelveth.startsWith("lda") && thirteenth.startsWith("ldy") &&
(fourteenth.startsWith("jsr c64flt.copy_float") || fourteenth.startsWith("jsr cx16flt.copy_float"))) {
if(first.substring(4) == eighth.substring(4) && second.substring(4)==nineth.substring(4)) {
// identical float init
removeLines.add(pair[7].index)
removeLines.add(pair[8].index)
removeLines.add(pair[9].index)
removeLines.add(pair[10].index)
mods.add(Modification(pair[7].index, true, null))
mods.add(Modification(pair[8].index, true, null))
mods.add(Modification(pair[9].index, true, null))
mods.add(Modification(pair[10].index, true, null))
}
}
}
}
return removeLines
return mods
}
private fun getLinesBy(lines: MutableList<String>, windowSize: Int) =
// 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> {
private fun optimizeStoreLoadSame(linesByFour: List<List<IndexedValue<String>>>): List<Modification> {
// sta X + lda X, sty X + ldy X, stx X + ldx X -> the second instruction can be eliminated
val removeLines = mutableListOf<Int>()
val mods = mutableListOf<Modification>()
for (pair in linesByFour) {
val first = pair[0].value.trimStart()
val second = pair[1].value.trimStart()
@ -186,26 +198,40 @@ private fun optimizeStoreLoadSame(linesByFour: List<List<IndexedValue<String>>>)
val firstLoc = first.substring(4)
val secondLoc = second.substring(4)
if (firstLoc == secondLoc) {
removeLines.add(pair[1].index)
mods.add(Modification(pair[1].index, true, null))
}
}
}
return removeLines
return mods
}
private fun optimizeIncDec(linesByTwo: List<List<IndexedValue<String>>>): List<Int> {
private fun optimizeIncDec(linesByFour: List<List<IndexedValue<String>>>): List<Modification> {
// sometimes, iny+dey / inx+dex / dey+iny / dex+inx sequences are generated, these can be eliminated.
val removeLines = mutableListOf<Int>()
for (pair in linesByTwo) {
val mods = mutableListOf<Modification>()
for (pair in linesByFour) {
val first = pair[0].value
val second = pair[1].value
if ((" iny" in first || "\tiny" in first) && (" dey" in second || "\tdey" in second)
|| (" inx" in first || "\tinx" in first) && (" dex" in second || "\tdex" in second)
|| (" dey" in first || "\tdey" in first) && (" iny" in second || "\tiny" in second)
|| (" dex" in first || "\tdex" in first) && (" inx" in second || "\tinx" in second)) {
removeLines.add(pair[0].index)
removeLines.add(pair[1].index)
mods.add(Modification(pair[0].index, true, null))
mods.add(Modification(pair[1].index, true, null))
}
}
return removeLines
return mods
}
private fun optimizeJsrRts(linesByFour: List<List<IndexedValue<String>>>): List<Modification> {
// jsr Sub + rts -> jmp Sub
val mods = mutableListOf<Modification>()
for (pair in linesByFour) {
val first = pair[0].value
val second = pair[1].value
if ((" jsr" in first || "\tjsr" in first ) && (" rts" in second || "\trts" in second)) {
mods += Modification(pair[0].index, false, pair[0].value.replace("jsr", "jmp"))
mods += Modification(pair[1].index, true, null)
}
}
return mods
}

745
compiler/src/prog8/compiler/target/c64/codegen/AssignmentAsmGen.kt
View File

@ -1,745 +0,0 @@
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.target.c64.MachineDefinition
import prog8.compiler.toHex
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.STR_S, DataType.ARRAY_UB, DataType.ARRAY_B ->
asmgen.out(" lda $arrayVarName+$indexValue | sta ${MachineDefinition.ESTACK_LO_HEX},x | dex")
DataType.ARRAY_UW, DataType.ARRAY_W ->
asmgen.out(" lda $arrayVarName+$indexValue | sta ${MachineDefinition.ESTACK_LO_HEX},x | lda $arrayVarName+$indexValue+1 | sta ${MachineDefinition.ESTACK_HI_HEX},x | dex")
DataType.ARRAY_F ->
asmgen.out(" lda #<$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()} ${MachineDefinition.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 ${MachineDefinition.ESTACK_LO_HEX},x | sta $targetName")
}
DataType.UWORD, DataType.WORD -> {
asmgen.out("""
inx
lda ${MachineDefinition.ESTACK_LO_HEX},x
sta $targetName
lda ${MachineDefinition.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 ${MachineDefinition.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 ${MachineDefinition.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 ${MachineDefinition.ESTACK_LO_HEX},x | lda $sourceName+1 | sta ${MachineDefinition.ESTACK_HI_HEX},x | dex")
asmgen.translateExpression(index)
asmgen.out(" inx | lda ${MachineDefinition.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 ${MachineDefinition.ESTACK_LO_HEX},x | dex")
asmgen.translateExpression(index)
asmgen.out(" inx | lda ${MachineDefinition.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 ${MachineDefinition.ESTACK_LO_HEX},x
ldy ${MachineDefinition.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 ${MachineDefinition.C64Zeropage.SCRATCH_B1}")
Register.X -> asmgen.out(" stx ${MachineDefinition.C64Zeropage.SCRATCH_B1}")
Register.Y -> asmgen.out(" sty ${MachineDefinition.C64Zeropage.SCRATCH_B1}")
}
when(index.register) {
Register.A -> {}
Register.X -> asmgen.out(" txa")
Register.Y -> asmgen.out(" tya")
}
asmgen.out("""
tay
lda ${MachineDefinition.C64Zeropage.SCRATCH_B1}
sta $targetName,y
""")
}
is IdentifierReference -> {
when(register) {
Register.A -> asmgen.out(" sta ${MachineDefinition.C64Zeropage.SCRATCH_B1}")
Register.X -> asmgen.out(" stx ${MachineDefinition.C64Zeropage.SCRATCH_B1}")
Register.Y -> asmgen.out(" sty ${MachineDefinition.C64Zeropage.SCRATCH_B1}")
}
asmgen.out("""
lda ${asmgen.asmIdentifierName(index)}
tay
lda ${MachineDefinition.C64Zeropage.SCRATCH_B1}
sta $targetName,y
""")
}
else -> {
asmgen.saveRegister(register)
asmgen.translateExpression(index)
asmgen.restoreRegister(register)
when(register) {
Register.A -> asmgen.out(" sta ${MachineDefinition.C64Zeropage.SCRATCH_B1}")
Register.X -> asmgen.out(" stx ${MachineDefinition.C64Zeropage.SCRATCH_B1}")
Register.Y -> asmgen.out(" sty ${MachineDefinition.C64Zeropage.SCRATCH_B1}")
}
asmgen.out("""
inx
lda ${MachineDefinition.ESTACK_LO_HEX},x
tay
lda ${MachineDefinition.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 ${MachineDefinition.C64Zeropage.SCRATCH_W1}
ldy $targetName+1
sty ${MachineDefinition.C64Zeropage.SCRATCH_W1+1}
ldy #0
sta (${MachineDefinition.C64Zeropage.SCRATCH_W1}),y
""")
Register.X -> asmgen.out("""
txa
ldy $targetName
sty ${MachineDefinition.C64Zeropage.SCRATCH_W1}
ldy $targetName+1
sty ${MachineDefinition.C64Zeropage.SCRATCH_W1+1}
ldy #0
sta (${MachineDefinition.C64Zeropage.SCRATCH_W1}),y
""")
Register.Y -> asmgen.out("""
tya
ldy $targetName
sty ${MachineDefinition.C64Zeropage.SCRATCH_W1}
ldy $targetName+1
sty ${MachineDefinition.C64Zeropage.SCRATCH_W1+1}
ldy #0
sta (${MachineDefinition.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 ${MachineDefinition.ESTACK_LO_HEX},x
sta (+) +1
lda ${MachineDefinition.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 ${MachineDefinition.ESTACK_LO_HEX},x
asl a
tay
lda #<${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 ${MachineDefinition.ESTACK_LO_HEX},x
lda #${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() * MachineDefinition.Mflpt5.MemorySize
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 ${MachineDefinition.ESTACK_LO_HEX},x
asl a
asl a
clc
adc ${MachineDefinition.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() * MachineDefinition.Mflpt5.MemorySize
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 ${MachineDefinition.C64Zeropage.SCRATCH_REG}
asl a
asl a
clc
adc ${MachineDefinition.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.STR_S, DataType.ARRAY_UB, DataType.ARRAY_B ->
asmgen.out(" tay | inx | lda ${MachineDefinition.ESTACK_LO_HEX},x | sta $variablename,y")
DataType.ARRAY_UW, DataType.ARRAY_W ->
asmgen.out(" asl a | tay | inx | lda ${MachineDefinition.ESTACK_LO_HEX},x | sta $variablename,y | lda ${MachineDefinition.ESTACK_HI_HEX},x | sta $variablename+1,y")
DataType.ARRAY_F ->
// index * 5 is done in the subroutine that's called
asmgen.out("""
sta ${MachineDefinition.ESTACK_LO_HEX},x
dex
lda #<$variablename
ldy #>$variablename
jsr c64flt.pop_float_to_indexed_var
""")
else ->
throw AssemblyError("weird array type")
}
}
}

814
compiler/src/prog8/compiler/target/c64/codegen/BuiltinFunctionsAsmGen.kt
View File

@ -2,33 +2,24 @@ 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.base.*
import prog8.ast.expressions.*
import prog8.ast.statements.AssignTarget
import prog8.ast.statements.FunctionCallStatement
import prog8.compiler.target.c64.MachineDefinition
import prog8.compiler.target.c64.MachineDefinition.C64Zeropage
import prog8.compiler.target.c64.MachineDefinition.ESTACK_HI_HEX
import prog8.compiler.target.c64.MachineDefinition.ESTACK_HI_PLUS1_HEX
import prog8.compiler.target.c64.MachineDefinition.ESTACK_LO_HEX
import prog8.compiler.target.c64.MachineDefinition.ESTACK_LO_PLUS1_HEX
import prog8.compiler.AssemblyError
import prog8.compiler.toHex
import prog8.functions.FunctionSignature
import prog8.functions.FSignature
internal class BuiltinFunctionsAsmGen(private val program: Program, private val asmgen: AsmGen) {
internal fun translateFunctioncallExpression(fcall: FunctionCall, func: FunctionSignature) {
internal fun translateFunctioncallExpression(fcall: FunctionCall, func: FSignature) {
translateFunctioncall(fcall, func, false)
}
internal fun translateFunctioncallStatement(fcall: FunctionCallStatement, func: FunctionSignature) {
internal fun translateFunctioncallStatement(fcall: FunctionCallStatement, func: FSignature) {
translateFunctioncall(fcall, func, true)
}
private fun translateFunctioncall(fcall: IFunctionCall, func: FunctionSignature, discardResult: Boolean) {
private fun translateFunctioncall(fcall: IFunctionCall, func: FSignature, discardResult: Boolean) {
val functionName = fcall.target.nameInSource.last()
if (discardResult) {
if (func.pure)
@ -38,371 +29,478 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
}
when (functionName) {
"msb" -> {
val arg = fcall.arglist.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.arglist, func)
asmgen.out(" inx | lda $ESTACK_LO_HEX,x | sta $ESTACK_HI_PLUS1_HEX,x")
}
"abs" -> {
translateFunctionArguments(fcall.arglist, func)
val dt = fcall.arglist.single().inferType(program)
when (dt.typeOrElse(DataType.STRUCT)) {
in ByteDatatypes -> asmgen.out(" jsr prog8_lib.abs_b")
in WordDatatypes -> asmgen.out(" jsr prog8_lib.abs_w")
DataType.FLOAT -> asmgen.out(" jsr c64flt.abs_f")
else -> throw AssemblyError("weird type")
}
}
"swap" -> {
val first = fcall.arglist[0]
val second = fcall.arglist[1]
asmgen.translateExpression(first)
asmgen.translateExpression(second)
// pop in reverse order
val firstTarget = AssignTarget.fromExpr(first)
val secondTarget = AssignTarget.fromExpr(second)
asmgen.assignFromEvalResult(firstTarget)
asmgen.assignFromEvalResult(secondTarget)
}
"strlen" -> {
outputPushAddressOfIdentifier(fcall.arglist[0])
asmgen.out(" jsr prog8_lib.func_strlen")
}
"min", "max", "sum" -> {
outputPushAddressAndLenghtOfArray(fcall.arglist[0])
val dt = fcall.arglist.single().inferType(program)
when (dt.typeOrElse(DataType.STRUCT)) {
DataType.ARRAY_UB, DataType.STR_S, DataType.STR -> asmgen.out(" jsr prog8_lib.func_${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 $dt")
}
}
"any", "all" -> {
outputPushAddressAndLenghtOfArray(fcall.arglist[0])
val dt = fcall.arglist.single().inferType(program)
when (dt.typeOrElse(DataType.STRUCT)) {
DataType.ARRAY_B, DataType.ARRAY_UB, DataType.STR_S, DataType.STR -> asmgen.out(" jsr prog8_lib.func_${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.arglist, func)
val dt = fcall.arglist.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 $dt")
}
}
"msb" -> funcMsb(fcall)
"lsb" -> funcLsb(fcall)
"mkword" -> funcMkword(fcall, func)
"abs" -> funcAbs(fcall, func)
"swap" -> funcSwap(fcall)
"strlen" -> funcStrlen(fcall)
"min", "max", "sum" -> funcMinMaxSum(fcall, functionName)
"any", "all" -> funcAnyAll(fcall, functionName)
"sgn" -> funcSgn(fcall, func)
"sin", "cos", "tan", "atan",
"ln", "log2", "sqrt", "rad",
"deg", "round", "floor", "ceil",
"rdnf" -> {
translateFunctionArguments(fcall.arglist, func)
asmgen.out(" jsr c64flt.func_$functionName")
"rdnf" -> funcVariousFloatFuncs(fcall, func, functionName)
"rol" -> funcRol(fcall)
"rol2" -> funcRol2(fcall)
"ror" -> funcRor(fcall)
"ror2" -> funcRor2(fcall)
"sort" -> funcSort(fcall)
"reverse" -> funcReverse(fcall)
"rsave" -> {
// save cpu status flag and all registers A, X, Y.
// see http://6502.org/tutorials/register_preservation.html
asmgen.out(" php | sta P8ZP_SCRATCH_REG | pha | txa | pha | tya | pha | lda P8ZP_SCRATCH_REG")
}
/*
TODO this was the old code for bit rotations:
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)
*/
"lsl" -> {
// in-place
val what = fcall.arglist.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) {
asmgen.out(" asl ${(what.addressExpression as NumericLiteralValue).number.toHex()}")
} else {
TODO("lsl memory byte $what")
}
}
is ArrayIndexedExpression -> {
TODO("lsl byte array $what")
}
else -> throw AssemblyError("weird type")
}
}
in WordDatatypes -> {
when (what) {
is ArrayIndexedExpression -> TODO("lsl sbyte $what")
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.arglist.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) {
asmgen.out(" lsr ${(what.addressExpression as NumericLiteralValue).number.toHex()}")
} else {
TODO("lsr memory byte $what")
}
}
is ArrayIndexedExpression -> {
TODO("lsr byte array $what")
}
else -> throw AssemblyError("weird type")
}
}
DataType.BYTE -> {
when (what) {
is ArrayIndexedExpression -> TODO("lsr sbyte $what")
is DirectMemoryRead -> TODO("lsr sbyte $what")
is RegisterExpr -> TODO("lsr sbyte $what")
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 -> TODO("lsr uword $what")
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 -> TODO("lsr sword $what")
is IdentifierReference -> {
val variable = asmgen.asmIdentifierName(what)
asmgen.out(" lda $variable+1 | asl a | ror $variable+1 | ror $variable")
}
else -> throw AssemblyError("weird type")
}
}
else -> throw AssemblyError("weird type")
}
}
"rol" -> {
// in-place
val what = fcall.arglist.single()
val dt = what.inferType(program)
when (dt.typeOrElse(DataType.STRUCT)) {
DataType.UBYTE -> {
TODO("rol ubyte")
}
DataType.UWORD -> {
TODO("rol uword")
}
else -> throw AssemblyError("weird type")
}
}
"rol2" -> {
// in-place
val what = fcall.arglist.single()
val dt = what.inferType(program)
when (dt.typeOrElse(DataType.STRUCT)) {
DataType.UBYTE -> {
TODO("rol2 ubyte")
}
DataType.UWORD -> {
TODO("rol2 uword")
}
else -> throw AssemblyError("weird type")
}
}
"ror" -> {
// in-place
val what = fcall.arglist.single()
val dt = what.inferType(program)
when (dt.typeOrElse(DataType.STRUCT)) {
DataType.UBYTE -> {
TODO("ror ubyte")
}
DataType.UWORD -> {
TODO("ror uword")
}
else -> throw AssemblyError("weird type")
}
}
"ror2" -> {
// in-place
val what = fcall.arglist.single()
val dt = what.inferType(program)
when (dt.typeOrElse(DataType.STRUCT)) {
DataType.UBYTE -> {
TODO("ror2 ubyte")
}
DataType.UWORD -> {
TODO("ror2 uword")
}
else -> throw AssemblyError("weird type")
}
}
"sort" -> {
val variable = fcall.arglist.single()
if(variable is IdentifierReference) {
val decl = variable.targetVarDecl(program.namespace)!!
val varName = asmgen.asmIdentifierName(variable)
val numElements = decl.arraysize!!.size()
when(decl.datatype) {
DataType.ARRAY_UB, DataType.ARRAY_B -> {
asmgen.out("""
lda #<$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 ${C64Zeropage.SCRATCH_B1}
""")
asmgen.out(if(decl.datatype==DataType.ARRAY_UW) " jsr prog8_lib.sort_uw" else " jsr prog8_lib.sort_w")
}
DataType.ARRAY_F -> TODO("sort floats (consider another solution if possible - this will be very slow, if ever implemented)")
else -> throw AssemblyError("weird type")
}
}
else
throw AssemblyError("weird type")
}
"reverse" -> {
val variable = fcall.arglist.single()
if (variable is IdentifierReference) {
val decl = variable.targetVarDecl(program.namespace)!!
val varName = asmgen.asmIdentifierName(variable)
val numElements = decl.arraysize!!.size()
when (decl.datatype) {
DataType.ARRAY_UB, DataType.ARRAY_B -> {
asmgen.out("""
lda #<$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 -> TODO("reverse floats (consider another solution if possible - this will be quite slow, if ever implemented)")
else -> throw AssemblyError("weird type")
}
}
"rrestore" -> {
// restore all registers and cpu status flag
asmgen.out(" pla | tay | pla | tax | pla | plp")
}
"clear_carry" -> asmgen.out(" clc")
"set_carry" -> asmgen.out(" sec")
"clear_irqd" -> asmgen.out(" cli")
"set_irqd" -> asmgen.out(" sei")
else -> {
translateFunctionArguments(fcall.arglist, func)
translateFunctionArguments(fcall.args, func)
asmgen.out(" jsr prog8_lib.func_$functionName")
}
}
}
private fun funcReverse(fcall: IFunctionCall) {
val variable = fcall.args.single()
if (variable is IdentifierReference) {
val decl = variable.targetVarDecl(program.namespace)!!
val varName = asmgen.asmVariableName(variable)
val numElements = decl.arraysize!!.constIndex()
when (decl.datatype) {
DataType.ARRAY_UB, DataType.ARRAY_B -> {
asmgen.out("""
lda #<$varName
ldy #>$varName
sta P8ZP_SCRATCH_W1
sty P8ZP_SCRATCH_W1+1
lda #$numElements
jsr prog8_lib.reverse_b
""")
}
DataType.ARRAY_UW, DataType.ARRAY_W -> {
asmgen.out("""
lda #<$varName
ldy #>$varName
sta P8ZP_SCRATCH_W1
sty P8ZP_SCRATCH_W1+1
lda #$numElements
jsr prog8_lib.reverse_w
""")
}
DataType.ARRAY_F -> {
asmgen.out("""
lda #<$varName
ldy #>$varName
sta P8ZP_SCRATCH_W1
sty P8ZP_SCRATCH_W1+1
lda #$numElements
jsr prog8_lib.reverse_f
""")
}
else -> throw AssemblyError("weird type")
}
}
}
private fun funcSort(fcall: IFunctionCall) {
val variable = fcall.args.single()
if (variable is IdentifierReference) {
val decl = variable.targetVarDecl(program.namespace)!!
val varName = asmgen.asmVariableName(variable)
val numElements = decl.arraysize!!.constIndex()
when (decl.datatype) {
DataType.ARRAY_UB, DataType.ARRAY_B -> {
asmgen.out("""
lda #<$varName
ldy #>$varName
sta P8ZP_SCRATCH_W1
sty P8ZP_SCRATCH_W1+1
lda #$numElements
sta P8ZP_SCRATCH_B1
""")
asmgen.out(if (decl.datatype == DataType.ARRAY_UB) " jsr prog8_lib.sort_ub" else " jsr prog8_lib.sort_b")
}
DataType.ARRAY_UW, DataType.ARRAY_W -> {
asmgen.out("""
lda #<$varName
ldy #>$varName
sta P8ZP_SCRATCH_W1
sty P8ZP_SCRATCH_W1+1
lda #$numElements
sta P8ZP_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")
}
private fun funcRor2(fcall: IFunctionCall) {
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 IdentifierReference -> {
val variable = asmgen.asmVariableName(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.asmVariableName(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")
}
}
private fun funcRor(fcall: IFunctionCall) {
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 P8ESTACK_LO,x
sta (+) + 1
lda P8ESTACK_HI,x
sta (+) + 2
+ ror ${'$'}ffff ; modified
""")
}
}
is IdentifierReference -> {
val variable = asmgen.asmVariableName(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.asmVariableName(what)
asmgen.out(" ror $variable+1 | ror $variable")
}
else -> throw AssemblyError("weird type")
}
}
else -> throw AssemblyError("weird type")
}
}
private fun funcRol2(fcall: IFunctionCall) {
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 IdentifierReference -> {
val variable = asmgen.asmVariableName(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.asmVariableName(what)
asmgen.out(" asl $variable | rol $variable+1 | bcc + | inc $variable |+ ")
}
else -> throw AssemblyError("weird type")
}
}
else -> throw AssemblyError("weird type")
}
}
private fun funcRol(fcall: IFunctionCall) {
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 P8ESTACK_LO,x
sta (+) + 1
lda P8ESTACK_HI,x
sta (+) + 2
+ rol ${'$'}ffff ; modified
""")
}
}
is IdentifierReference -> {
val variable = asmgen.asmVariableName(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.asmVariableName(what)
asmgen.out(" rol $variable | rol $variable+1")
}
else -> throw AssemblyError("weird type")
}
}
else -> throw AssemblyError("weird type")
}
}
private fun funcVariousFloatFuncs(fcall: IFunctionCall, func: FSignature, functionName: String) {
translateFunctionArguments(fcall.args, func)
asmgen.out(" jsr c64flt.func_$functionName")
}
private fun funcSgn(fcall: IFunctionCall, func: FSignature) {
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 $dt")
}
}
private fun funcAnyAll(fcall: IFunctionCall, functionName: String) {
outputPushAddressAndLenghtOfArray(fcall.args[0])
val dt = fcall.args.single().inferType(program)
when (dt.typeOrElse(DataType.STRUCT)) {
DataType.ARRAY_B, DataType.ARRAY_UB, DataType.STR -> asmgen.out(" jsr prog8_lib.func_${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 $dt")
}
}
private fun funcMinMaxSum(fcall: IFunctionCall, functionName: String) {
outputPushAddressAndLenghtOfArray(fcall.args[0])
val dt = fcall.args.single().inferType(program)
when (dt.typeOrElse(DataType.STRUCT)) {
DataType.ARRAY_UB, DataType.STR -> asmgen.out(" jsr prog8_lib.func_${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 $dt")
}
}
private fun funcStrlen(fcall: IFunctionCall) {
val name = asmgen.asmVariableName(fcall.args[0] as IdentifierReference)
asmgen.out("""
lda #<$name
ldy #>$name
jsr prog8_lib.strlen
sta P8ESTACK_LO,x
dex""")
}
private fun funcSwap(fcall: IFunctionCall) {
val first = fcall.args[0]
val second = fcall.args[1]
if(first is IdentifierReference && second is IdentifierReference) {
val firstName = asmgen.asmVariableName(first)
val secondName = asmgen.asmVariableName(second)
val dt = first.inferType(program)
if(dt.istype(DataType.BYTE) || dt.istype(DataType.UBYTE)) {
asmgen.out(" ldy $firstName | lda $secondName | sta $firstName | tya | sta $secondName")
return
}
if(dt.istype(DataType.WORD) || dt.istype(DataType.UWORD)) {
asmgen.out("""
ldy $firstName
lda $secondName
sta $firstName
sty $secondName
ldy $firstName+1
lda $secondName+1
sta $firstName+1
sty $secondName+1
""")
return
}
if(dt.istype(DataType.FLOAT)) {
asmgen.out("""
lda #<$firstName
sta P8ZP_SCRATCH_W1
lda #>$firstName
sta P8ZP_SCRATCH_W1+1
lda #<$secondName
sta P8ZP_SCRATCH_W2
lda #>$secondName
sta P8ZP_SCRATCH_W2+1
jsr c64flt.swap_floats
""")
return
}
}
// other types of swap() calls should have been replaced by a different statement sequence involving a temp variable
throw AssemblyError("no asm generation for swap funccall $fcall")
}
private fun funcAbs(fcall: IFunctionCall, func: FSignature) {
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")
}
}
private fun funcMkword(fcall: IFunctionCall, func: FSignature) {
// trick: push the args in reverse order (msb first, lsb second) this saves some instructions
asmgen.translateExpression(fcall.args[1])
asmgen.translateExpression(fcall.args[0])
asmgen.out(" inx | lda P8ESTACK_LO,x | sta P8ESTACK_HI+1,x")
}
private fun funcMsb(fcall: IFunctionCall) {
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("msb(const) should have been const-folded away")
if (arg is IdentifierReference) {
val sourceName = asmgen.asmVariableName(arg)
asmgen.out(" lda $sourceName+1 | sta P8ESTACK_LO,x | dex")
} else {
asmgen.translateExpression(arg)
asmgen.out(" lda P8ESTACK_HI+1,x | sta P8ESTACK_LO+1,x")
}
}
private fun funcLsb(fcall: IFunctionCall) {
val arg = fcall.args.single()
if (arg.inferType(program).typeOrElse(DataType.STRUCT) !in WordDatatypes)
throw AssemblyError("lsb required word argument")
if (arg is NumericLiteralValue)
throw AssemblyError("lsb(const) should have been const-folded away")
if (arg is IdentifierReference) {
val sourceName = asmgen.asmVariableName(arg)
asmgen.out(" lda $sourceName | sta P8ESTACK_LO,x | dex")
} else {
asmgen.translateExpression(arg)
// just ignore any high-byte
}
}
private fun outputPushAddressAndLenghtOfArray(arg: Expression) {
arg as IdentifierReference
val identifierName = asmgen.asmIdentifierName(arg)
val size = arg.targetVarDecl(program.namespace)!!.arraysize!!.size()!!
val identifierName = asmgen.asmVariableName(arg)
val size = arg.targetVarDecl(program.namespace)!!.arraysize!!.constIndex()!!
asmgen.out("""
lda #<$identifierName
sta $ESTACK_LO_HEX,x
sta P8ESTACK_LO,x
lda #>$identifierName
sta $ESTACK_HI_HEX,x
sta P8ESTACK_HI,x
dex
lda #$size
sta $ESTACK_LO_HEX,x
sta P8ESTACK_LO,x
dex
""")
}
private fun outputPushAddressOfIdentifier(arg: Expression) {
val identifierName = asmgen.asmIdentifierName(arg as IdentifierReference)
asmgen.out("""
lda #<$identifierName
sta $ESTACK_LO_HEX,x
lda #>$identifierName
sta $ESTACK_HI_HEX,x
dex
""")
}
private fun translateFunctionArguments(args: MutableList<Expression>, signature: FunctionSignature) {
private fun translateFunctionArguments(args: MutableList<Expression>, signature: FSignature) {
args.forEach {
asmgen.translateExpression(it)
}

262
compiler/src/prog8/compiler/target/c64/codegen/ExpressionsAsmGen.kt
View File

@ -3,7 +3,9 @@ package prog8.compiler.target.c64.codegen
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.compiler.target.c64.MachineDefinition
import prog8.compiler.AssemblyError
import prog8.compiler.target.CompilationTarget
import prog8.compiler.target.CpuType
import prog8.compiler.toHex
import prog8.functions.BuiltinFunctions
import kotlin.math.absoluteValue
@ -14,16 +16,14 @@ internal class ExpressionsAsmGen(private val program: Program, private val asmge
when(expression) {
is PrefixExpression -> translateExpression(expression)
is BinaryExpression -> translateExpression(expression)
is ArrayIndexedExpression -> translatePushFromArray(expression)
is ArrayIndexedExpression -> translateExpression(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 ArrayLiteralValue, is StringLiteralValue -> throw AssemblyError("no asm gen for string/array literal value assignment - should have been replaced by a variable")
is RangeExpr -> throw AssemblyError("range expression should have been changed into array values")
}
}
@ -34,18 +34,42 @@ internal class ExpressionsAsmGen(private val program: Program, private val asmge
if (builtinFunc != null) {
asmgen.translateFunctioncallExpression(expression, builtinFunc)
} else {
asmgen.translateFunctionCall(expression)
val sub = expression.target.targetSubroutine(program.namespace)!!
asmgen.translateFunctionCall(expression)
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 ${MachineDefinition.ESTACK_LO_HEX},x | dex")
RegisterOrPair.Y -> asmgen.out(" tya | sta ${MachineDefinition.ESTACK_LO_HEX},x | dex")
RegisterOrPair.AY -> asmgen.out(" sta ${MachineDefinition.ESTACK_LO_HEX},x | tya | sta ${MachineDefinition.ESTACK_HI_HEX},x | dex")
RegisterOrPair.X, RegisterOrPair.AX, RegisterOrPair.XY -> throw AssemblyError("can't push X register - use a variable")
RegisterOrPair.A -> asmgen.out(" sta P8ESTACK_LO,x | dex")
RegisterOrPair.Y -> asmgen.out(" tya | sta P8ESTACK_LO,x | dex")
RegisterOrPair.AY -> asmgen.out(" sta P8ESTACK_LO,x | tya | sta P8ESTACK_HI,x | dex")
RegisterOrPair.X -> {
// return value in X register has been discarded, just push a zero
if(CompilationTarget.machine.cpu==CpuType.CPU65c02)
asmgen.out(" stz P8ESTACK_LO,x")
else
asmgen.out(" lda #0 | sta P8ESTACK_LO,x")
asmgen.out(" dex")
}
RegisterOrPair.AX -> {
// return value in X register has been discarded, just push a zero in this place
asmgen.out(" sta P8ESTACK_LO,x")
if(CompilationTarget.machine.cpu==CpuType.CPU65c02)
asmgen.out(" stz P8ESTACK_HI,x")
else
asmgen.out(" lda #0 | sta P8ESTACK_HI,x")
asmgen.out(" dex")
}
RegisterOrPair.XY -> {
// return value in X register has been discarded, just push a zero in this place
if(CompilationTarget.machine.cpu==CpuType.CPU65c02)
asmgen.out(" stz P8ESTACK_LO,x")
else
asmgen.out(" lda #0 | sta P8ESTACK_LO,x")
asmgen.out(" tya | sta P8ESTACK_HI,x | dex")
}
}
}
// return value from a statusregister is not put on the stack, it should be acted on via a conditional branch such as if_cc
@ -60,7 +84,12 @@ internal class ExpressionsAsmGen(private val program: Program, private val asmge
DataType.UBYTE -> {
when(expr.type) {
DataType.UBYTE, DataType.BYTE -> {}
DataType.UWORD, DataType.WORD -> asmgen.out(" lda #0 | sta ${MachineDefinition.ESTACK_HI_PLUS1_HEX},x")
DataType.UWORD, DataType.WORD -> {
if(CompilationTarget.machine.cpu==CpuType.CPU65c02)
asmgen.out(" stz P8ESTACK_HI+1,x")
else
asmgen.out(" lda #0 | sta P8ESTACK_HI+1,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")
@ -69,7 +98,20 @@ internal class ExpressionsAsmGen(private val program: Program, private val asmge
DataType.BYTE -> {
when(expr.type) {
DataType.UBYTE, DataType.BYTE -> {}
DataType.UWORD, DataType.WORD -> asmgen.out(" lda ${MachineDefinition.ESTACK_LO_PLUS1_HEX},x | ${asmgen.signExtendAtoMsb("${MachineDefinition.ESTACK_HI_PLUS1_HEX},x")}")
DataType.UWORD, DataType.WORD -> {
// sign extend
asmgen.out("""
lda P8ESTACK_LO+1,x
ora #$7f
bmi +""")
if(CompilationTarget.machine.cpu==CpuType.CPU65c02)
asmgen.out("""
+ stz P8ESTACK_HI+1,x""")
else
asmgen.out("""
lda #0
+ sta P8ESTACK_HI+1,x""")
}
DataType.FLOAT -> asmgen.out(" jsr c64flt.stack_b2float")
in PassByReferenceDatatypes -> throw AssemblyError("cannot cast to a pass-by-reference datatype")
else -> throw AssemblyError("weird type")
@ -104,80 +146,74 @@ internal class ExpressionsAsmGen(private val program: Program, private val asmge
else -> throw AssemblyError("weird type")
}
}
in PassByReferenceDatatypes -> throw AssemblyError("cannot case a pass-by-reference datatypes into something else")
in PassByReferenceDatatypes -> throw AssemblyError("cannot cast pass-by-reference value into another type")
else -> throw AssemblyError("weird type")
}
}
private fun translateExpression(expr: AddressOf) {
val name = asmgen.asmIdentifierName(expr.identifier)
asmgen.out(" lda #<$name | sta ${MachineDefinition.ESTACK_LO_HEX},x | lda #>$name | sta ${MachineDefinition.ESTACK_HI_HEX},x | dex")
val name = asmgen.asmVariableName(expr.identifier)
asmgen.out(" lda #<$name | sta P8ESTACK_LO,x | lda #>$name | sta P8ESTACK_HI,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 ${MachineDefinition.ESTACK_LO_HEX},x | dex")
asmgen.out(" lda ${address.toHex()} | sta P8ESTACK_LO,x | dex")
}
is IdentifierReference -> {
val sourceName = asmgen.asmIdentifierName(expr.addressExpression as IdentifierReference)
asmgen.out(" lda $sourceName | sta ${MachineDefinition.ESTACK_LO_HEX},x | dex")
// the identifier is a pointer variable, so read the value from the address in it
asmgen.loadByteFromPointerIntoA(expr.addressExpression as IdentifierReference)
asmgen.out(" sta P8ESTACK_LO,x | dex")
}
else -> {
translateExpression(expr.addressExpression)
asmgen.out(" jsr prog8_lib.read_byte_from_address")
asmgen.out(" sta ${MachineDefinition.ESTACK_LO_PLUS1_HEX},x")
asmgen.out(" jsr prog8_lib.read_byte_from_address_on_stack")
asmgen.out(" sta P8ESTACK_LO+1,x")
}
}
}
private fun translateExpression(expr: NumericLiteralValue) {
when(expr.type) {
DataType.UBYTE, DataType.BYTE -> asmgen.out(" lda #${expr.number.toHex()} | sta ${MachineDefinition.ESTACK_LO_HEX},x | dex")
DataType.UBYTE, DataType.BYTE -> asmgen.out(" lda #${expr.number.toHex()} | sta P8ESTACK_LO,x | dex")
DataType.UWORD, DataType.WORD -> asmgen.out("""
lda #<${expr.number.toHex()}
sta ${MachineDefinition.ESTACK_LO_HEX},x
sta P8ESTACK_LO,x
lda #>${expr.number.toHex()}
sta ${MachineDefinition.ESTACK_HI_HEX},x
sta P8ESTACK_HI,x
dex
""")
DataType.FLOAT -> {
val floatConst = asmgen.getFloatConst(expr.number.toDouble())
val floatConst = asmgen.getFloatAsmConst(expr.number.toDouble())
asmgen.out(" lda #<$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 ${MachineDefinition.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 ${MachineDefinition.ESTACK_LO_HEX},x | dex")
}
}
private fun translateExpression(expr: IdentifierReference) {
val varname = asmgen.asmIdentifierName(expr)
val varname = asmgen.asmVariableName(expr)
when(expr.inferType(program).typeOrElse(DataType.STRUCT)) {
DataType.UBYTE, DataType.BYTE -> {
asmgen.out(" lda $varname | sta ${MachineDefinition.ESTACK_LO_HEX},x | dex")
asmgen.out(" lda $varname | sta P8ESTACK_LO,x | dex")
}
DataType.UWORD, DataType.WORD, in ArrayDatatypes, in StringDatatypes -> {
// (for arrays and strings, push their address)
asmgen.out(" lda $varname | sta ${MachineDefinition.ESTACK_LO_HEX},x | lda $varname+1 | sta ${MachineDefinition.ESTACK_HI_HEX},x | dex")
DataType.UWORD, DataType.WORD -> {
asmgen.out(" lda $varname | sta P8ESTACK_LO,x | lda $varname+1 | sta P8ESTACK_HI,x | dex")
}
DataType.FLOAT -> {
asmgen.out(" lda #<$varname | ldy #>$varname| jsr c64flt.push_float")
}
in IterableDatatypes -> {
asmgen.out(" lda #<$varname | sta P8ESTACK_LO,x | lda #>$varname | sta P8ESTACK_HI,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)
@ -190,35 +226,86 @@ internal class ExpressionsAsmGen(private val program: Program, private val asmge
// 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 ${MachineDefinition.ESTACK_LO_PLUS1_HEX},x") }
DataType.BYTE -> repeat(amount) { asmgen.out(" lda ${MachineDefinition.ESTACK_LO_PLUS1_HEX},x | asl a | ror ${MachineDefinition.ESTACK_LO_PLUS1_HEX},x") }
DataType.UWORD -> repeat(amount) { asmgen.out(" lsr ${MachineDefinition.ESTACK_HI_PLUS1_HEX},x | ror ${MachineDefinition.ESTACK_LO_PLUS1_HEX},x") }
DataType.WORD -> repeat(amount) { asmgen.out(" lda ${MachineDefinition.ESTACK_HI_PLUS1_HEX},x | asl a | ror ${MachineDefinition.ESTACK_HI_PLUS1_HEX},x | ror ${MachineDefinition.ESTACK_LO_PLUS1_HEX},x") }
else -> throw AssemblyError("weird type")
val amount = expr.right.constValue(program)?.number?.toInt()
if(amount!=null) {
when (leftDt) {
DataType.UBYTE -> {
if (amount <= 2)
repeat(amount) { asmgen.out(" lsr P8ESTACK_LO+1,x") }
else {
asmgen.out(" lda P8ESTACK_LO+1,x")
repeat(amount) { asmgen.out(" lsr a") }
asmgen.out(" sta P8ESTACK_LO+1,x")
}
}
DataType.BYTE -> {
if (amount <= 2)
repeat(amount) { asmgen.out(" lda P8ESTACK_LO+1,x | asl a | ror P8ESTACK_LO+1,x") }
else {
asmgen.out(" lda P8ESTACK_LO+1,x | sta P8ZP_SCRATCH_B1")
repeat(amount) { asmgen.out(" asl a | ror P8ZP_SCRATCH_B1 | lda P8ZP_SCRATCH_B1") }
asmgen.out(" sta P8ESTACK_LO+1,x")
}
}
DataType.UWORD -> {
var left = amount
while (left >= 7) {
asmgen.out(" jsr math.shift_right_uw_7")
left -= 7
}
if (left in 0..2)
repeat(left) { asmgen.out(" lsr P8ESTACK_HI+1,x | ror P8ESTACK_LO+1,x") }
else
asmgen.out(" jsr math.shift_right_uw_$left")
}
DataType.WORD -> {
var left = amount
while (left >= 7) {
asmgen.out(" jsr math.shift_right_w_7")
left -= 7
}
if (left in 0..2)
repeat(left) { asmgen.out(" lda P8ESTACK_HI+1,x | asl a | ror P8ESTACK_HI+1,x | ror P8ESTACK_LO+1,x") }
else
asmgen.out(" jsr math.shift_right_w_$left")
}
else -> throw AssemblyError("weird type")
}
return
}
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 ${MachineDefinition.ESTACK_LO_PLUS1_HEX},x") }
else
repeat(amount) { asmgen.out(" asl ${MachineDefinition.ESTACK_LO_PLUS1_HEX},x | rol ${MachineDefinition.ESTACK_HI_PLUS1_HEX},x") }
return
val amount = expr.right.constValue(program)?.number?.toInt()
if(amount!=null) {
if (leftDt in ByteDatatypes) {
if (amount <= 2)
repeat(amount) { asmgen.out(" asl P8ESTACK_LO+1,x") }
else {
asmgen.out(" lda P8ESTACK_LO+1,x")
repeat(amount) { asmgen.out(" asl a") }
asmgen.out(" sta P8ESTACK_LO+1,x")
}
} else {
var left = amount
while (left >= 7) {
asmgen.out(" jsr math.shift_left_w_7")
left -= 7
}
if (left in 0..2)
repeat(left) { asmgen.out(" asl P8ESTACK_LO+1,x | rol P8ESTACK_HI+1,x") }
else
asmgen.out(" jsr math.shift_left_w_$left")
}
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) {
@ -268,8 +355,10 @@ internal class ExpressionsAsmGen(private val program: Program, private val asmge
// 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?
if((leftDt in ByteDatatypes && rightDt !in ByteDatatypes)
|| (leftDt in WordDatatypes && rightDt !in WordDatatypes))
throw AssemblyError("binary operator ${expr.operator} left/right dt not identical")
when (leftDt) {
in ByteDatatypes -> translateBinaryOperatorBytes(expr.operator, leftDt)
in WordDatatypes -> translateBinaryOperatorWords(expr.operator, leftDt)
@ -295,9 +384,9 @@ internal class ExpressionsAsmGen(private val program: Program, private val asmge
when(type) {
in ByteDatatypes ->
asmgen.out("""
lda ${MachineDefinition.ESTACK_LO_PLUS1_HEX},x
lda P8ESTACK_LO+1,x
eor #255
sta ${MachineDefinition.ESTACK_LO_PLUS1_HEX},x
sta P8ESTACK_LO+1,x
""")
in WordDatatypes -> asmgen.out(" jsr prog8_lib.inv_word")
else -> throw AssemblyError("weird type")
@ -314,29 +403,47 @@ internal class ExpressionsAsmGen(private val program: Program, private val asmge
}
}
private fun translatePushFromArray(arrayExpr: ArrayIndexedExpression) {
// assume *reading* from an array
private fun translateExpression(arrayExpr: ArrayIndexedExpression) {
val index = arrayExpr.arrayspec.index
val arrayDt = arrayExpr.identifier.targetVarDecl(program.namespace)!!.datatype
val arrayVarName = asmgen.asmIdentifierName(arrayExpr.identifier)
val elementDt = arrayExpr.inferType(program).typeOrElse(DataType.STRUCT)
val arrayVarName = asmgen.asmVariableName(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 ${MachineDefinition.ESTACK_LO_HEX},x | dex")
asmgen.out(" lda $arrayVarName+$indexValue | sta P8ESTACK_LO,x | dex")
}
in WordDatatypes -> {
asmgen.out(" lda $arrayVarName+$indexValue | sta ${MachineDefinition.ESTACK_LO_HEX},x | lda $arrayVarName+$indexValue+1 | sta ${MachineDefinition.ESTACK_HI_HEX},x | dex")
asmgen.out(" lda $arrayVarName+$indexValue | sta P8ESTACK_LO,x | lda $arrayVarName+$indexValue+1 | sta P8ESTACK_HI,x | dex")
}
DataType.FLOAT -> {
asmgen.out(" lda #<$arrayVarName+$indexValue | ldy #>$arrayVarName+$indexValue | jsr c64flt.push_float")
}
else -> throw AssemblyError("weird type")
else -> throw AssemblyError("weird element type")
}
} else {
asmgen.translateArrayIndexIntoA(arrayExpr)
asmgen.readAndPushArrayvalueWithIndexA(arrayDt, arrayExpr.identifier)
when(elementDt) {
in ByteDatatypes -> {
asmgen.loadScaledArrayIndexIntoRegister(arrayExpr, elementDt, CpuRegister.Y)
asmgen.out(" lda $arrayVarName,y | sta P8ESTACK_LO,x | dex")
}
in WordDatatypes -> {
asmgen.loadScaledArrayIndexIntoRegister(arrayExpr, elementDt, CpuRegister.Y)
asmgen.out(" lda $arrayVarName,y | sta P8ESTACK_LO,x | lda $arrayVarName+1,y | sta P8ESTACK_HI,x | dex")
}
DataType.FLOAT -> {
asmgen.loadScaledArrayIndexIntoRegister(arrayExpr, elementDt, CpuRegister.A)
asmgen.out("""
ldy #>$arrayVarName
clc
adc #<$arrayVarName
bcc +
iny
+ jsr c64flt.push_float""")
}
else -> throw AssemblyError("weird dt")
}
}
}
@ -351,20 +458,21 @@ internal class ExpressionsAsmGen(private val program: Program, private val asmge
asmgen.out(" jsr prog8_lib.remainder_ub")
}
"+" -> asmgen.out("""
lda ${MachineDefinition.ESTACK_LO_PLUS2_HEX},x
lda P8ESTACK_LO+2,x
clc
adc ${MachineDefinition.ESTACK_LO_PLUS1_HEX},x
adc P8ESTACK_LO+1,x
inx
sta ${MachineDefinition.ESTACK_LO_PLUS1_HEX},x
sta P8ESTACK_LO+1,x
""")
"-" -> asmgen.out("""
lda ${MachineDefinition.ESTACK_LO_PLUS2_HEX},x
lda P8ESTACK_LO+2,x
sec
sbc ${MachineDefinition.ESTACK_LO_PLUS1_HEX},x
sbc P8ESTACK_LO+1,x
inx
sta ${MachineDefinition.ESTACK_LO_PLUS1_HEX},x
sta P8ESTACK_LO+1,x
""")
"<<", ">>" -> throw AssemblyError("bit-shifts not via stack")
"<<" -> asmgen.out(" jsr prog8_lib.shiftleft_b")
">>" -> asmgen.out(" jsr prog8_lib.shiftright_b")
"<" -> 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")

955
compiler/src/prog8/compiler/target/c64/codegen/ForLoopsAsmGen.kt
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File diff suppressed because it is too large Load Diff

323
compiler/src/prog8/compiler/target/c64/codegen/FunctionCallAsmGen.kt
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@ -4,11 +4,11 @@ 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.target.c64.MachineDefinition
import prog8.compiler.toHex
import prog8.compiler.AssemblyError
import prog8.compiler.target.c64.codegen.assignment.*
internal class FunctionCallAsmGen(private val program: Program, private val asmgen: AsmGen) {
@ -16,218 +16,185 @@ internal class FunctionCallAsmGen(private val program: Program, private val asmg
// 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 saveX = CpuRegister.X in sub.asmClobbers || sub.regXasResult() || sub.regXasParam()
if(saveX)
asmgen.saveRegister(CpuRegister.X) // we only save X for now (required! is the eval stack pointer), screw A and Y...
val subName = asmgen.asmIdentifierName(stmt.target)
if(stmt.arglist.isNotEmpty()) {
for(arg in sub.parameters.withIndex().zip(stmt.arglist)) {
translateFuncArguments(arg.first, arg.second, sub)
val subName = asmgen.asmSymbolName(stmt.target)
if(stmt.args.isNotEmpty()) {
if(sub.asmParameterRegisters.isEmpty()) {
// via variables
for(arg in sub.parameters.withIndex().zip(stmt.args)) {
argumentViaVariable(sub, arg.first, arg.second)
}
} else {
// via registers
if(sub.parameters.size==1) {
// just a single parameter, no risk of clobbering registers
argumentViaRegister(sub, sub.parameters.withIndex().single(), stmt.args[0])
} else {
// multiple register arguments, risk of register clobbering.
// evaluate arguments onto the stack, and load the registers from the evaluated values on the stack.
when {
stmt.args.all {it is AddressOf ||
it is NumericLiteralValue ||
it is StringLiteralValue ||
it is ArrayLiteralValue ||
it is IdentifierReference} -> {
// no risk of clobbering for these simple argument types. Optimize the register loading.
for(arg in sub.parameters.withIndex().zip(stmt.args)) {
argumentViaRegister(sub, arg.first, arg.second)
}
}
else -> {
// Risk of clobbering due to complex expression args. Work via the stack.
registerArgsViaStackEvaluation(stmt, sub)
}
}
}
}
}
asmgen.out(" jsr $subName")
if(Register.X in sub.asmClobbers)
asmgen.out(" ldx c64.SCRATCH_ZPREGX") // restore X again
if(saveX)
asmgen.restoreRegister(CpuRegister.X)
}
private fun translateFuncArguments(parameter: IndexedValue<SubroutineParameter>, value: Expression, sub: Subroutine) {
val sourceIDt = value.inferType(program)
if(!sourceIDt.isKnown)
private fun registerArgsViaStackEvaluation(stmt: IFunctionCall, sub: Subroutine) {
// this is called when one or more of the arguments are 'complex' and
// cannot be assigned to a register easily or risk clobbering other registers.
for (arg in stmt.args.reversed())
asmgen.translateExpression(arg)
for (regparam in sub.asmParameterRegisters) {
when {
regparam.statusflag==Statusflag.Pc -> {
asmgen.out("""
inx
pha
lda P8ESTACK_LO,x
beq +
sec
bcs ++
+ clc
+ pla""")
}
regparam.statusflag!=null -> {
throw AssemblyError("can only use Carry as status flag parameter")
}
regparam.registerOrPair!=null -> {
val tgt = AsmAssignTarget.fromRegisters(regparam.registerOrPair, program, asmgen)
val source = AsmAssignSource(SourceStorageKind.STACK, program, tgt.datatype)
val asgn = AsmAssignment(source, tgt, false, Position.DUMMY)
asmgen.translateNormalAssignment(asgn)
}
else -> {}
}
}
}
private fun argumentViaVariable(sub: Subroutine, parameter: IndexedValue<SubroutineParameter>, value: Expression) {
// pass parameter via a regular variable (not via registers)
val valueIDt = value.inferType(program)
if(!valueIDt.isKnown)
throw AssemblyError("arg type unknown")
val sourceDt = sourceIDt.typeOrElse(DataType.STRUCT)
if(!argumentTypeCompatible(sourceDt, parameter.value.type))
val valueDt = valueIDt.typeOrElse(DataType.STRUCT)
if(!isArgumentTypeCompatible(valueDt, 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) {
val scopedParamVar = (sub.scopedname+"."+parameter.value.name).split(".")
val identifier = IdentifierReference(scopedParamVar, sub.position)
identifier.linkParents(value.parent)
val tgt = AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, parameter.value.type, variable = identifier)
val source = AsmAssignSource.fromAstSource(value, program).adjustDataTypeToTarget(tgt)
val asgn = AsmAssignment(source, tgt, false, Position.DUMMY)
asmgen.translateNormalAssignment(asgn)
}
private fun argumentViaRegister(sub: Subroutine, parameter: IndexedValue<SubroutineParameter>, value: Expression) {
// pass argument via a register parameter
val valueIDt = value.inferType(program)
if(!valueIDt.isKnown)
throw AssemblyError("arg type unknown")
val valueDt = valueIDt.typeOrElse(DataType.STRUCT)
if(!isArgumentTypeCompatible(valueDt, parameter.value.type))
throw AssemblyError("argument type incompatible")
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 address = (value.addressExpression as NumericLiteralValue).number.toInt()
asmgen.assignFromMemoryByte(target, address, null)
val carrySet = value.number.toInt() != 0
asmgen.out(if(carrySet) " sec" else " clc")
}
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("""
val sourceName = asmgen.asmVariableName(value)
asmgen.out("""
pha
lda $sourceName
beq +
sec
bcs ++
+ clc
+
+ pla
""")
}
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 ${MachineDefinition.ESTACK_LO_HEX},x
}
else -> {
asmgen.translateExpression(value)
asmgen.out("""
inx
pha
lda P8ESTACK_LO,x
beq +
sec
bcs ++
+ clc
+
+ pla
""")
}
}
}
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 ${MachineDefinition.ESTACK_LO_HEX},x")
RegisterOrPair.X -> throw AssemblyError("can't pop into X register - use a variable instead")
RegisterOrPair.Y -> asmgen.out(" inx | ldy ${MachineDefinition.ESTACK_LO_HEX},x")
else -> throw AssemblyError("cannot assign to register pair")
}
}
}
}
register!=null && register.name.length==2 -> {
// register pair as a 16-bit value (only possible for subroutine parameters)
when (value) {
is NumericLiteralValue -> {
// optimize when the argument is a constant literal
val hex = value.number.toHex()
when (register) {
RegisterOrPair.AX -> asmgen.out(" lda #<$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 ${MachineDefinition.ESTACK_LO_HEX},x | ldy ${MachineDefinition.ESTACK_HI_HEX},x")
}
}
else throw AssemblyError("can only use Carry as status flag parameter")
}
else -> {
// via register or register pair
val target = AsmAssignTarget.fromRegisters(register!!, program, asmgen)
val src = if(valueDt in PassByReferenceDatatypes) {
val addr = AddressOf(value as IdentifierReference, Position.DUMMY)
AsmAssignSource.fromAstSource(addr, program).adjustDataTypeToTarget(target)
} else {
AsmAssignSource.fromAstSource(value, program).adjustDataTypeToTarget(target)
}
asmgen.translateNormalAssignment(AsmAssignment(src, target, false, Position.DUMMY))
}
}
}
private fun argumentTypeCompatible(argType: DataType, paramType: DataType): Boolean {
private fun isArgumentTypeCompatible(argType: DataType, paramType: DataType): Boolean {
if(argType isAssignableTo paramType)
return true
if(argType in ByteDatatypes && paramType in ByteDatatypes)
return true
if(argType in WordDatatypes && paramType in WordDatatypes)
return true
// we have a special rule for some types.
// strings are assignable to UWORD, for example, and vice versa
if(argType in StringDatatypes && paramType==DataType.UWORD)
if(argType==DataType.STR && paramType==DataType.UWORD)
return true
if(argType==DataType.UWORD && paramType in StringDatatypes)
if(argType==DataType.UWORD && paramType == DataType.STR)
return true
return false

140
compiler/src/prog8/compiler/target/c64/codegen/PostIncrDecrAsmGen.kt
View File

@ -4,39 +4,21 @@ 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.target.c64.MachineDefinition
import prog8.compiler.AssemblyError
import prog8.compiler.toHex
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) {
val what = asmgen.asmVariableName(targetIdent)
when (stmt.target.inferType(program, stmt).typeOrElse(DataType.STRUCT)) {
in ByteDatatypes -> asmgen.out(if (incr) " inc $what" else " dec $what")
in WordDatatypes -> {
if(incr)
@ -57,93 +39,97 @@ internal class PostIncrDecrAsmGen(private val program: Program, private val asmg
}
}
targetMemory!=null -> {
val addressExpr = targetMemory.addressExpression
when (addressExpr) {
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")
val what = asmgen.asmVariableName(addressExpr)
asmgen.out(" lda $what | sta (+) +1 | lda $what+1 | sta (+) +2")
if(incr)
asmgen.out("+\tinc ${'$'}ffff\t; modified")
else
asmgen.out("+\tdec ${'$'}ffff\t; modified")
}
else -> {
asmgen.translateExpression(addressExpr)
asmgen.out("""
inx
lda P8ESTACK_LO,x
sta (+) + 1
lda P8ESTACK_HI,x
sta (+) + 2
""")
if(incr)
asmgen.out("+\tinc ${'$'}ffff\t; modified")
else
asmgen.out("+\tdec ${'$'}ffff\t; modified")
}
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)
val asmArrayvarname = asmgen.asmVariableName(targetArrayIdx.identifier)
val elementDt = targetArrayIdx.inferType(program).typeOrElse(DataType.STRUCT)
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 ByteDatatypes -> asmgen.out(if (incr) " inc $asmArrayvarname+$indexValue" else " dec $asmArrayvarname+$indexValue")
in WordDatatypes -> {
if(incr)
asmgen.out(" inc $what+$indexValue | bne + | inc $what+$indexValue+1 |+")
asmgen.out(" inc $asmArrayvarname+$indexValue | bne + | inc $asmArrayvarname+$indexValue+1 |+")
else
asmgen.out("""
lda $what+$indexValue
lda $asmArrayvarname+$indexValue
bne +
dec $what+$indexValue+1
+ dec $what+$indexValue
dec $asmArrayvarname+$indexValue+1
+ dec $asmArrayvarname+$indexValue
""")
}
DataType.FLOAT -> {
asmgen.out(" lda #<$what+$indexValue | ldy #>$what+$indexValue")
asmgen.out(" lda #<$asmArrayvarname+$indexValue | ldy #>$asmArrayvarname+$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)
asmgen.loadScaledArrayIndexIntoRegister(targetArrayIdx, elementDt, CpuRegister.A)
asmgen.saveRegister(CpuRegister.X)
asmgen.out(" tax")
when(elementDt) {
in ByteDatatypes -> {
asmgen.out(if(incr) " inc $asmArrayvarname,x" else " dec $asmArrayvarname,x")
}
in WordDatatypes -> {
if(incr)
asmgen.out(" inc $asmArrayvarname,x | bne + | inc $asmArrayvarname+1,x |+")
else
asmgen.out("""
lda $asmArrayvarname,x
bne +
dec $asmArrayvarname+1,x
+ dec $asmArrayvarname
""")
}
DataType.FLOAT -> {
asmgen.out("""
ldy #>$asmArrayvarname
clc
adc #<$asmArrayvarname
bcc +
iny
+ jsr c64flt.inc_var_f""")
}
else -> throw AssemblyError("weird array elt dt")
}
asmgen.restoreRegister(CpuRegister.X)
}
}
}
else -> throw AssemblyError("weird target type ${stmt.target}")
}
}
private fun incrDecrArrayvalueWithIndexA(incr: Boolean, arrayDt: DataType, arrayVarName: String) {
asmgen.out(" stx ${MachineDefinition.C64Zeropage.SCRATCH_REG_X} | tax")
when(arrayDt) {
DataType.STR, DataType.STR_S,
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 ${MachineDefinition.C64Zeropage.SCRATCH_REG_X}")
}
}

164
compiler/src/prog8/compiler/target/c64/codegen/assignment/AsmAssignment.kt Normal file
View File

@ -0,0 +1,164 @@
package prog8.compiler.target.c64.codegen.assignment
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.compiler.AssemblyError
import prog8.compiler.target.c64.codegen.AsmGen
internal enum class TargetStorageKind {
VARIABLE,
ARRAY,
MEMORY,
REGISTER,
STACK
}
internal enum class SourceStorageKind {
LITERALNUMBER,
VARIABLE,
ARRAY,
MEMORY,
REGISTER,
STACK, // value is already present on stack
EXPRESSION, // expression in ast-form, still to be evaluated
}
internal class AsmAssignTarget(val kind: TargetStorageKind,
program: Program,
asmgen: AsmGen,
val datatype: DataType,
val variable: IdentifierReference? = null,
val array: ArrayIndexedExpression? = null,
val memory: DirectMemoryWrite? = null,
val register: RegisterOrPair? = null,
val origAstTarget: AssignTarget? = null
)
{
val constMemoryAddress by lazy { memory?.addressExpression?.constValue(program)?.number?.toInt() ?: 0}
val constArrayIndexValue by lazy { array?.arrayspec?.constIndex() }
val vardecl by lazy { variable?.targetVarDecl(program.namespace)!! }
val asmVarname by lazy {
if(variable!=null)
asmgen.asmVariableName(variable)
else
asmgen.asmVariableName(array!!.identifier)
}
lateinit var origAssign: AsmAssignment
init {
if(variable!=null && vardecl.type == VarDeclType.CONST)
throw AssemblyError("can't assign to a constant")
if(register!=null && datatype !in IntegerDatatypes)
throw AssemblyError("register must be integer type")
}
companion object {
fun fromAstAssignment(assign: Assignment, program: Program, asmgen: AsmGen): AsmAssignTarget = with(assign.target) {
val dt = inferType(program, assign).typeOrElse(DataType.STRUCT)
when {
identifier != null -> AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, dt, variable=identifier, origAstTarget = this)
arrayindexed != null -> AsmAssignTarget(TargetStorageKind.ARRAY, program, asmgen, dt, array = arrayindexed, origAstTarget = this)
memoryAddress != null -> AsmAssignTarget(TargetStorageKind.MEMORY, program, asmgen, dt, memory = memoryAddress, origAstTarget = this)
else -> throw AssemblyError("weird target")
}
}
fun fromRegisters(registers: RegisterOrPair, program: Program, asmgen: AsmGen): AsmAssignTarget =
when(registers) {
RegisterOrPair.A,
RegisterOrPair.X,
RegisterOrPair.Y -> AsmAssignTarget(TargetStorageKind.REGISTER, program, asmgen, DataType.UBYTE, register = registers)
RegisterOrPair.AX,
RegisterOrPair.AY,
RegisterOrPair.XY -> AsmAssignTarget(TargetStorageKind.REGISTER, program, asmgen, DataType.UWORD, register = registers)
}
}
}
internal class AsmAssignSource(val kind: SourceStorageKind,
private val program: Program,
val datatype: DataType,
val variable: IdentifierReference? = null,
val array: ArrayIndexedExpression? = null,
val memory: DirectMemoryRead? = null,
val register: CpuRegister? = null,
val number: NumericLiteralValue? = null,
val expression: Expression? = null
)
{
val constMemoryAddress by lazy { memory?.addressExpression?.constValue(program)?.number?.toInt() ?: 0}
val constArrayIndexValue by lazy { array?.arrayspec?.constIndex() }
val vardecl by lazy { variable?.targetVarDecl(program.namespace)!! }
companion object {
fun fromAstSource(value: Expression, program: Program): AsmAssignSource {
val cv = value.constValue(program)
if(cv!=null)
return AsmAssignSource(SourceStorageKind.LITERALNUMBER, program, cv.type, number = cv)
return when(value) {
is NumericLiteralValue -> AsmAssignSource(SourceStorageKind.LITERALNUMBER, program, value.type, number = cv)
is StringLiteralValue -> throw AssemblyError("string literal value should not occur anymore for asm generation")
is ArrayLiteralValue -> throw AssemblyError("array literal value should not occur anymore for asm generation")
is IdentifierReference -> {
val dt = value.inferType(program).typeOrElse(DataType.STRUCT)
AsmAssignSource(SourceStorageKind.VARIABLE, program, dt, variable = value)
}
is DirectMemoryRead -> {
AsmAssignSource(SourceStorageKind.MEMORY, program, DataType.UBYTE, memory = value)
}
is ArrayIndexedExpression -> {
val dt = value.inferType(program).typeOrElse(DataType.STRUCT)
AsmAssignSource(SourceStorageKind.ARRAY, program, dt, array = value)
}
else -> {
val dt = value.inferType(program).typeOrElse(DataType.STRUCT)
AsmAssignSource(SourceStorageKind.EXPRESSION, program, dt, expression = value)
}
}
}
}
fun getAstValue(): Expression = when(kind) {
SourceStorageKind.LITERALNUMBER -> number!!
SourceStorageKind.VARIABLE -> variable!!
SourceStorageKind.ARRAY -> array!!
SourceStorageKind.MEMORY -> memory!!
SourceStorageKind.EXPRESSION -> expression!!
SourceStorageKind.REGISTER -> throw AssemblyError("cannot get a register source as Ast node")
SourceStorageKind.STACK -> throw AssemblyError("cannot get a stack source as Ast node")
}
fun withAdjustedDt(newType: DataType) =
AsmAssignSource(kind, program, newType, variable, array, memory, register, number, expression)
fun adjustDataTypeToTarget(target: AsmAssignTarget): AsmAssignSource {
// allow some signed/unsigned relaxations
if(target.datatype!=datatype) {
if(target.datatype in ByteDatatypes && datatype in ByteDatatypes) {
return withAdjustedDt(target.datatype)
} else if(target.datatype in WordDatatypes && datatype in WordDatatypes) {
return withAdjustedDt(target.datatype)
}
}
return this
}
}
internal class AsmAssignment(val source: AsmAssignSource,
val target: AsmAssignTarget,
val isAugmentable: Boolean,
val position: Position) {
init {
require(source.datatype==target.datatype) {"source and target datatype must be identical"}
}
}

966
compiler/src/prog8/compiler/target/c64/codegen/assignment/AssignmentAsmGen.kt Normal file
View File

@ -0,0 +1,966 @@
package prog8.compiler.target.c64.codegen.assignment
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.ast.statements.*
import prog8.compiler.AssemblyError
import prog8.compiler.target.CompilationTarget
import prog8.compiler.target.CpuType
import prog8.compiler.target.c64.codegen.AsmGen
import prog8.compiler.toHex
internal class AssignmentAsmGen(private val program: Program, private val asmgen: AsmGen) {
private val augmentableAsmGen = AugmentableAssignmentAsmGen(program, this, asmgen)
fun translate(assignment: Assignment) {
val target = AsmAssignTarget.fromAstAssignment(assignment, program, asmgen)
val source = AsmAssignSource.fromAstSource(assignment.value, program).adjustDataTypeToTarget(target)
val assign = AsmAssignment(source, target, assignment.isAugmentable, assignment.position)
target.origAssign = assign
if(assign.isAugmentable)
augmentableAsmGen.translate(assign)
else
translateNormalAssignment(assign)
}
fun translateNormalAssignment(assign: AsmAssignment) {
when(assign.source.kind) {
SourceStorageKind.LITERALNUMBER -> {
// simple case: assign a constant number
val num = assign.source.number!!.number
when (assign.source.datatype) {
DataType.UBYTE, DataType.BYTE -> assignConstantByte(assign.target, num.toShort())
DataType.UWORD, DataType.WORD -> assignConstantWord(assign.target, num.toInt())
DataType.FLOAT -> assignConstantFloat(assign.target, num.toDouble())
else -> throw AssemblyError("weird numval type")
}
}
SourceStorageKind.VARIABLE -> {
// simple case: assign from another variable
val variable = assign.source.variable!!
when (assign.source.datatype) {
DataType.UBYTE, DataType.BYTE -> assignVariableByte(assign.target, variable)
DataType.UWORD, DataType.WORD -> assignVariableWord(assign.target, variable)
DataType.FLOAT -> assignVariableFloat(assign.target, variable)
in PassByReferenceDatatypes -> assignAddressOf(assign.target, variable)
else -> throw AssemblyError("unsupported assignment target type ${assign.target.datatype}")
}
}
SourceStorageKind.ARRAY -> {
val value = assign.source.array!!
val elementDt = assign.source.datatype
val index = value.arrayspec.index
val arrayVarName = asmgen.asmVariableName(value.identifier)
if (index is NumericLiteralValue) {
// constant array index value
val indexValue = index.number.toInt() * elementDt.memorySize()
when (elementDt) {
in ByteDatatypes ->
asmgen.out(" lda $arrayVarName+$indexValue | sta P8ESTACK_LO,x | dex")
in WordDatatypes ->
asmgen.out(" lda $arrayVarName+$indexValue | sta P8ESTACK_LO,x | lda $arrayVarName+$indexValue+1 | sta P8ESTACK_HI,x | dex")
DataType.FLOAT ->
asmgen.out(" lda #<$arrayVarName+$indexValue | ldy #>$arrayVarName+$indexValue | jsr c64flt.push_float")
else ->
throw AssemblyError("weird array type")
}
} else {
when (elementDt) {
in ByteDatatypes -> {
asmgen.loadScaledArrayIndexIntoRegister(value, elementDt, CpuRegister.Y)
asmgen.out(" lda $arrayVarName,y | sta P8ESTACK_LO,x | dex")
}
in WordDatatypes -> {
asmgen.loadScaledArrayIndexIntoRegister(value, elementDt, CpuRegister.Y)
asmgen.out(" lda $arrayVarName,y | sta P8ESTACK_LO,x | lda $arrayVarName+1,y | sta P8ESTACK_HI,x | dex")
}
DataType.FLOAT -> {
asmgen.loadScaledArrayIndexIntoRegister(value, elementDt, CpuRegister.A)
asmgen.out("""
ldy #>$arrayVarName
clc
adc #<$arrayVarName
bcc +
iny
+ jsr c64flt.push_float""")
}
else ->
throw AssemblyError("weird array elt type")
}
}
assignStackValue(assign.target)
}
SourceStorageKind.MEMORY -> {
val value = assign.source.memory!!
when (value.addressExpression) {
is NumericLiteralValue -> {
val address = (value.addressExpression as NumericLiteralValue).number.toInt()
assignMemoryByte(assign.target, address, null)
}
is IdentifierReference -> {
assignMemoryByte(assign.target, null, value.addressExpression as IdentifierReference)
}
else -> {
asmgen.translateExpression(value.addressExpression)
asmgen.out(" jsr prog8_lib.read_byte_from_address_on_stack | inx")
assignRegisterByte(assign.target, CpuRegister.A)
}
}
}
SourceStorageKind.EXPRESSION -> {
val value = assign.source.expression!!
when(value) {
is AddressOf -> assignAddressOf(assign.target, value.identifier)
is NumericLiteralValue -> throw AssemblyError("source kind should have been literalnumber")
is IdentifierReference -> throw AssemblyError("source kind should have been variable")
is ArrayIndexedExpression -> throw AssemblyError("source kind should have been array")
is DirectMemoryRead -> throw AssemblyError("source kind should have been memory")
// is TypecastExpression -> {
// if(assign.target.kind == TargetStorageKind.STACK) {
// asmgen.translateExpression(value)
// assignStackValue(assign.target)
// } else {
// println("!!!!TYPECAST to ${assign.target.kind} $value")
// // TODO maybe we can do the typecast on the target directly instead of on the stack?
// asmgen.translateExpression(value)
// assignStackValue(assign.target)
// }
// }
// is FunctionCall -> {
// if (assign.target.kind == TargetStorageKind.STACK) {
// asmgen.translateExpression(value)
// assignStackValue(assign.target)
// } else {
// val functionName = value.target.nameInSource.last()
// val builtinFunc = BuiltinFunctions[functionName]
// if (builtinFunc != null) {
// println("!!!!BUILTIN-FUNCCALL target=${assign.target.kind} $value") // TODO optimize certain functions?
// }
// asmgen.translateExpression(value)
// assignStackValue(assign.target)
// }
// }
else -> {
// everything else just evaluate via the stack.
asmgen.translateExpression(value)
assignStackValue(assign.target)
}
}
}
SourceStorageKind.REGISTER -> {
assignRegisterByte(assign.target, assign.source.register!!)
}
SourceStorageKind.STACK -> {
assignStackValue(assign.target)
}
}
}
private fun assignStackValue(target: AsmAssignTarget) {
when(target.kind) {
TargetStorageKind.VARIABLE -> {
when (target.datatype) {
DataType.UBYTE, DataType.BYTE -> {
asmgen.out(" inx | lda P8ESTACK_LO,x | sta ${target.asmVarname}")
}
DataType.UWORD, DataType.WORD -> {
asmgen.out("""
inx
lda P8ESTACK_LO,x
sta ${target.asmVarname}
lda P8ESTACK_HI,x
sta ${target.asmVarname}+1
""")
}
DataType.FLOAT -> {
asmgen.out("""
lda #<${target.asmVarname}
ldy #>${target.asmVarname}
jsr c64flt.pop_float
""")
}
else -> throw AssemblyError("weird target variable type ${target.datatype}")
}
}
TargetStorageKind.MEMORY -> {
asmgen.out(" inx")
storeByteViaRegisterAInMemoryAddress("P8ESTACK_LO,x", target.memory!!)
}
TargetStorageKind.ARRAY -> {
val index = target.array!!.arrayspec.index
when {
target.constArrayIndexValue!=null -> {
val scaledIdx = target.constArrayIndexValue!! * target.datatype.memorySize()
when(target.datatype) {
in ByteDatatypes -> {
asmgen.out(" inx | lda P8ESTACK_LO,x | sta ${target.asmVarname}+$scaledIdx")
}
in WordDatatypes -> {
asmgen.out("""
inx
lda P8ESTACK_LO,x
sta ${target.asmVarname}+$scaledIdx
lda P8ESTACK_HI,x
sta ${target.asmVarname}+$scaledIdx+1
""")
}
DataType.FLOAT -> {
asmgen.out("""
lda #<${target.asmVarname}+$scaledIdx
ldy #>${target.asmVarname}+$scaledIdx
jsr c64flt.pop_float
""")
}
else -> throw AssemblyError("weird target variable type ${target.datatype}")
}
}
index is IdentifierReference -> {
when(target.datatype) {
DataType.UBYTE, DataType.BYTE -> {
asmgen.loadScaledArrayIndexIntoRegister(target.array, target.datatype, CpuRegister.Y)
asmgen.out(" inx | lda P8ESTACK_LO,x | sta ${target.asmVarname},y")
}
DataType.UWORD, DataType.WORD -> {
asmgen.loadScaledArrayIndexIntoRegister(target.array, target.datatype, CpuRegister.Y)
asmgen.out("""
inx
lda P8ESTACK_LO,x
sta ${target.asmVarname},y
lda P8ESTACK_HI,x
sta ${target.asmVarname}+1,y
""")
}
DataType.FLOAT -> {
asmgen.loadScaledArrayIndexIntoRegister(target.array, target.datatype, CpuRegister.A)
asmgen.out("""
ldy #>${target.asmVarname}
clc
adc #<${target.asmVarname}
bcc +
iny
+ jsr c64flt.pop_float""")
}
else -> throw AssemblyError("weird dt")
}
}
else -> {
asmgen.translateExpression(index)
asmgen.out(" inx | lda P8ESTACK_LO,x")
popAndWriteArrayvalueWithUnscaledIndexA(target.datatype, target.asmVarname)
}
}
}
TargetStorageKind.REGISTER -> {
when (target.datatype) {
DataType.UBYTE, DataType.BYTE -> {
when(target.register!!) {
RegisterOrPair.A -> asmgen.out(" inx | lda P8ESTACK_LO,x")
RegisterOrPair.X -> throw AssemblyError("can't use X here")
RegisterOrPair.Y -> asmgen.out(" inx | ldy P8ESTACK_LO,x")
else -> throw AssemblyError("can't assign byte to register pair word")
}
}
DataType.UWORD, DataType.WORD, in PassByReferenceDatatypes -> {
when(target.register!!) {
RegisterOrPair.AX -> throw AssemblyError("can't use X here")
RegisterOrPair.AY-> asmgen.out(" inx | lda P8ESTACK_LO,x | ldy P8ESTACK_HI,x")
RegisterOrPair.XY-> throw AssemblyError("can't use X here")
else -> throw AssemblyError("can't assign word to single byte register")
}
}
else -> throw AssemblyError("weird dt")
}
}
TargetStorageKind.STACK -> {}
}
}
private fun assignAddressOf(target: AsmAssignTarget, name: IdentifierReference) {
val struct = name.memberOfStruct(program.namespace)
val sourceName = if (struct != null) {
// take the address of the first struct member instead
val decl = name.targetVarDecl(program.namespace)!!
val firstStructMember = struct.nameOfFirstMember()
// find the flattened var that belongs to this first struct member
val firstVarName = listOf(decl.name, firstStructMember)
val firstVar = name.definingScope().lookup(firstVarName, name) as VarDecl
firstVar.name
} else {
asmgen.fixNameSymbols(name.nameInSource.joinToString("."))
}
when(target.kind) {
TargetStorageKind.VARIABLE -> {
asmgen.out("""
lda #<$sourceName
ldy #>$sourceName
sta ${target.asmVarname}
sty ${target.asmVarname}+1
""")
}
TargetStorageKind.MEMORY -> {
throw AssemblyError("no asm gen for assign address $sourceName to memory word $target")
}
TargetStorageKind.ARRAY -> {
throw AssemblyError("no asm gen for assign address $sourceName to array ${target.asmVarname}")
}
TargetStorageKind.REGISTER -> {
when(target.register!!) {
RegisterOrPair.AX -> asmgen.out(" lda #<$sourceName | ldx #>$sourceName")
RegisterOrPair.AY -> asmgen.out(" lda #<$sourceName | ldy #>$sourceName")
RegisterOrPair.XY -> asmgen.out(" ldx #<$sourceName | ldy #>$sourceName")
else -> throw AssemblyError("can't load address in a single 8-bit register")
}
}
TargetStorageKind.STACK -> {
val srcname = asmgen.asmVariableName(name)
asmgen.out("""
lda #<$srcname
sta P8ESTACK_LO,x
lda #>$srcname
sta P8ESTACK_HI,x
dex""")
}
}
}
private fun assignVariableWord(target: AsmAssignTarget, variable: IdentifierReference) {
val sourceName = asmgen.asmVariableName(variable)
when(target.kind) {
TargetStorageKind.VARIABLE -> {
asmgen.out("""
lda $sourceName
ldy $sourceName+1
sta ${target.asmVarname}
sty ${target.asmVarname}+1
""")
}
TargetStorageKind.MEMORY -> {
throw AssemblyError("no asm gen for assign wordvar $sourceName to memory ${target.memory}")
}
TargetStorageKind.ARRAY -> {
val index = target.array!!.arrayspec.index
when {
target.constArrayIndexValue!=null -> {
val scaledIdx = target.constArrayIndexValue!! * target.datatype.memorySize()
when(target.datatype) {
in ByteDatatypes -> {
asmgen.out(" lda $sourceName | sta ${target.asmVarname}+$scaledIdx")
}
in WordDatatypes -> {
asmgen.out("""
lda $sourceName
sta ${target.asmVarname}+$scaledIdx
lda $sourceName+1
sta ${target.asmVarname}+$scaledIdx+1
""")
}
DataType.FLOAT -> {
asmgen.out("""
lda #<$sourceName
ldy #>$sourceName
sta P8ZP_SCRATCH_W1
sty P8ZP_SCRATCH_W1+1
lda #<${target.asmVarname}+$scaledIdx
ldy #>${target.asmVarname}+$scaledIdx
jsr c64flt.copy_float
""")
}
else -> throw AssemblyError("weird target variable type ${target.datatype}")
}
}
index is IdentifierReference -> {
when(target.datatype) {
DataType.UBYTE, DataType.BYTE -> {
asmgen.loadScaledArrayIndexIntoRegister(target.array, target.datatype, CpuRegister.Y)
asmgen.out(" lda $sourceName | sta ${target.asmVarname},y")
}
DataType.UWORD, DataType.WORD -> {
asmgen.loadScaledArrayIndexIntoRegister(target.array, target.datatype, CpuRegister.Y)
asmgen.out("""
lda $sourceName
sta ${target.asmVarname},y
lda $sourceName+1
sta ${target.asmVarname}+1,y
""")
}
DataType.FLOAT -> {
asmgen.loadScaledArrayIndexIntoRegister(target.array, target.datatype, CpuRegister.A)
asmgen.out("""
ldy #<$sourceName
sty P8ZP_SCRATCH_W1
ldy #>$sourceName
sty P8ZP_SCRATCH_W1+1
ldy #>${target.asmVarname}
clc
adc #<${target.asmVarname}
bcc +
iny
+ jsr c64flt.copy_float""")
}
else -> throw AssemblyError("weird dt")
}
}
else -> {
asmgen.out(" lda $sourceName | sta P8ESTACK_LO,x | lda $sourceName+1 | sta P8ESTACK_HI,x | dex")
asmgen.translateExpression(index)
asmgen.out(" inx | lda P8ESTACK_LO,x")
popAndWriteArrayvalueWithUnscaledIndexA(target.datatype, target.asmVarname)
}
}
}
TargetStorageKind.REGISTER -> {
when(target.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 $sourceName+1")
else -> throw AssemblyError("can't load word in a single 8-bit register")
}
}
TargetStorageKind.STACK -> {
asmgen.out("""
lda #$sourceName
sta P8ESTACK_LO,x
lda #$sourceName+1
sta P8ESTACK_HI,x
dex""")
}
}
}
private fun assignVariableFloat(target: AsmAssignTarget, variable: IdentifierReference) {
val sourceName = asmgen.asmVariableName(variable)
when(target.kind) {
TargetStorageKind.VARIABLE -> {
asmgen.out("""
lda $sourceName
sta ${target.asmVarname}
lda $sourceName+1
sta ${target.asmVarname}+1
lda $sourceName+2
sta ${target.asmVarname}+2
lda $sourceName+3
sta ${target.asmVarname}+3
lda $sourceName+4
sta ${target.asmVarname}+4
""")
}
TargetStorageKind.ARRAY -> {
// TODO optimize this, but the situation doesn't occur very often
// if(target.constArrayIndexValue!=null) {
// TODO("const index ${target.constArrayIndexValue}")
// } else if(target.array!!.arrayspec.index is IdentifierReference) {
// TODO("array[var] ${target.constArrayIndexValue}")
// }
val index = target.array!!.arrayspec.index
asmgen.out(" lda #<$sourceName | ldy #>$sourceName | jsr c64flt.push_float")
asmgen.translateExpression(index)
asmgen.out(" lda #<${target.asmVarname} | ldy #>${target.asmVarname} | jsr c64flt.pop_float_to_indexed_var")
}
TargetStorageKind.MEMORY -> throw AssemblyError("can't assign float to mem byte")
TargetStorageKind.REGISTER -> throw AssemblyError("can't assign float to register")
TargetStorageKind.STACK -> asmgen.out(" lda #<$sourceName | ldy #>$sourceName | jsr c64flt.push_float")
}
}
private fun assignVariableByte(target: AsmAssignTarget, variable: IdentifierReference) {
val sourceName = asmgen.asmVariableName(variable)
when(target.kind) {
TargetStorageKind.VARIABLE -> {
asmgen.out("""
lda $sourceName
sta ${target.asmVarname}
""")
}
TargetStorageKind.MEMORY -> {
storeByteViaRegisterAInMemoryAddress(sourceName, target.memory!!)
}
TargetStorageKind.ARRAY -> {
val index = target.array!!.arrayspec.index
when {
target.constArrayIndexValue!=null -> {
val scaledIdx = target.constArrayIndexValue!! * target.datatype.memorySize()
asmgen.out(" lda $sourceName | sta ${target.asmVarname}+$scaledIdx")
}
index is IdentifierReference -> {
asmgen.loadScaledArrayIndexIntoRegister(target.array, target.datatype, CpuRegister.Y)
asmgen.out(" lda $sourceName | sta ${target.asmVarname},y")
}
else -> {
asmgen.out(" lda $sourceName | sta P8ESTACK_LO,x | dex")
asmgen.translateExpression(index)
asmgen.out(" inx | lda P8ESTACK_LO,x")
popAndWriteArrayvalueWithUnscaledIndexA(target.datatype, target.asmVarname)
}
}
}
TargetStorageKind.REGISTER -> {
when(target.register!!) {
RegisterOrPair.A -> asmgen.out(" lda $sourceName")
RegisterOrPair.X -> asmgen.out(" ldx $sourceName")
RegisterOrPair.Y -> asmgen.out(" ldy $sourceName")
RegisterOrPair.AX -> asmgen.out(" lda $sourceName | ldx #0")
RegisterOrPair.AY -> asmgen.out(" lda $sourceName | ldy #0")
RegisterOrPair.XY -> asmgen.out(" ldx $sourceName | ldy #0")
}
}
TargetStorageKind.STACK -> {
asmgen.out("""
lda #$sourceName
sta P8ESTACK_LO,x
dex""")
}
}
}
private fun assignRegisterByte(target: AsmAssignTarget, register: CpuRegister) {
require(target.datatype in ByteDatatypes)
when(target.kind) {
TargetStorageKind.VARIABLE -> {
asmgen.out(" st${register.name.toLowerCase()} ${target.asmVarname}")
}
TargetStorageKind.MEMORY -> {
storeRegisterInMemoryAddress(register, target.memory!!)
}
TargetStorageKind.ARRAY -> {
val index = target.array!!.arrayspec.index
when (index) {
is NumericLiteralValue -> {
val memindex = index.number.toInt()
when (register) {
CpuRegister.A -> asmgen.out(" sta ${target.asmVarname}+$memindex")
CpuRegister.X -> asmgen.out(" stx ${target.asmVarname}+$memindex")
CpuRegister.Y -> asmgen.out(" sty ${target.asmVarname}+$memindex")
}
}
is IdentifierReference -> {
when (register) {
CpuRegister.A -> {}
CpuRegister.X -> asmgen.out(" txa")
CpuRegister.Y -> asmgen.out(" tya")
}
asmgen.out(" ldy ${asmgen.asmVariableName(index)} | sta ${target.asmVarname},y")
}
else -> {
asmgen.saveRegister(register)
asmgen.translateExpression(index)
asmgen.restoreRegister(register)
when (register) {
CpuRegister.A -> asmgen.out(" sta P8ZP_SCRATCH_B1")
CpuRegister.X -> asmgen.out(" stx P8ZP_SCRATCH_B1")
CpuRegister.Y -> asmgen.out(" sty P8ZP_SCRATCH_B1")
}
asmgen.out("""
inx
lda P8ESTACK_LO,x
tay
lda P8ZP_SCRATCH_B1
sta ${target.asmVarname},y
""")
}
}
}
TargetStorageKind.REGISTER -> {
when(register) {
CpuRegister.A -> when(target.register!!) {
RegisterOrPair.A -> {}
RegisterOrPair.X -> { asmgen.out(" tax") }
RegisterOrPair.Y -> { asmgen.out(" tay") }
else -> throw AssemblyError("attempt to assign byte to register pair word")
}
CpuRegister.X -> when(target.register!!) {
RegisterOrPair.A -> { asmgen.out(" txa") }
RegisterOrPair.X -> { }
RegisterOrPair.Y -> { asmgen.out(" txy") }
else -> throw AssemblyError("attempt to assign byte to register pair word")
}
CpuRegister.Y -> when(target.register!!) {
RegisterOrPair.A -> { asmgen.out(" tya") }
RegisterOrPair.X -> { asmgen.out(" tyx") }
RegisterOrPair.Y -> { }
else -> throw AssemblyError("attempt to assign byte to register pair word")
}
}
}
TargetStorageKind.STACK -> {
when(register) {
CpuRegister.A -> asmgen.out(" sta P8ESTACK_LO,x | dex")
CpuRegister.X -> throw AssemblyError("can't use X here")
CpuRegister.Y -> asmgen.out(" tya | sta P8ESTACK_LO,x | dex")
}
}
}
}
private fun assignConstantWord(target: AsmAssignTarget, word: Int) {
when(target.kind) {
TargetStorageKind.VARIABLE -> {
if (word ushr 8 == word and 255) {
// lsb=msb
asmgen.out("""
lda #${(word and 255).toHex()}
sta ${target.asmVarname}
sta ${target.asmVarname}+1
""")
} else {
asmgen.out("""
lda #<${word.toHex()}
ldy #>${word.toHex()}
sta ${target.asmVarname}
sty ${target.asmVarname}+1
""")
}
}
TargetStorageKind.MEMORY -> {
throw AssemblyError("no asm gen for assign word $word to memory ${target.memory}")
}
TargetStorageKind.ARRAY -> {
// TODO optimize this, but the situation doesn't occur very often
// if(target.constArrayIndexValue!=null) {
// TODO("const index ${target.constArrayIndexValue}")
// } else if(target.array!!.arrayspec.index is IdentifierReference) {
// TODO("array[var] ${target.constArrayIndexValue}")
// }
val index = target.array!!.arrayspec.index
asmgen.translateExpression(index)
asmgen.out("""
inx
lda P8ESTACK_LO,x
asl a
tay
lda #<${word.toHex()}
sta ${target.asmVarname},y
lda #>${word.toHex()}
sta ${target.asmVarname}+1,y
""")
}
TargetStorageKind.REGISTER -> {
when(target.register!!) {
RegisterOrPair.AX -> asmgen.out(" lda #<${word.toHex()} | ldx #>${word.toHex()}")
RegisterOrPair.AY -> asmgen.out(" lda #<${word.toHex()} | ldy #>${word.toHex()}")
RegisterOrPair.XY -> asmgen.out(" ldx #<${word.toHex()} | ldy #>${word.toHex()}")
else -> throw AssemblyError("can't assign word to single byte register")
}
}
TargetStorageKind.STACK -> {
asmgen.out("""
lda #<${word.toHex()}
sta P8ESTACK_LO,x
lda #>${word.toHex()}
sta P8ESTACK_HI,x
dex""")
}
}
}
private fun assignConstantByte(target: AsmAssignTarget, byte: Short) {
when(target.kind) {
TargetStorageKind.VARIABLE -> {
asmgen.out(" lda #${byte.toHex()} | sta ${target.asmVarname} ")
}
TargetStorageKind.MEMORY -> {
storeByteViaRegisterAInMemoryAddress("#${byte.toHex()}", target.memory!!)
}
TargetStorageKind.ARRAY -> {
val index = target.array!!.arrayspec.index
when {
target.constArrayIndexValue!=null -> {
val indexValue = target.constArrayIndexValue!!
asmgen.out(" lda #${byte.toHex()} | sta ${target.asmVarname}+$indexValue")
}
index is IdentifierReference -> {
asmgen.loadScaledArrayIndexIntoRegister(target.array, DataType.UBYTE, CpuRegister.Y)
asmgen.out(" lda #<${byte.toHex()} | sta ${target.asmVarname},y")
}
else -> {
asmgen.translateExpression(index)
asmgen.out("""
inx
ldy P8ESTACK_LO,x
lda #${byte.toHex()}
sta ${target.asmVarname},y
""")
}
}
}
TargetStorageKind.REGISTER -> when(target.register!!) {
RegisterOrPair.A -> asmgen.out(" lda #${byte.toHex()}")
RegisterOrPair.X -> asmgen.out(" ldx #${byte.toHex()}")
RegisterOrPair.Y -> asmgen.out(" ldy #${byte.toHex()}")
else -> throw AssemblyError("can't assign byte to word register apir")
}
TargetStorageKind.STACK -> {
asmgen.out("""
lda #${byte.toHex()}
sta P8ESTACK_LO,x
dex""")
}
}
}
private fun assignConstantFloat(target: AsmAssignTarget, float: Double) {
if (float == 0.0) {
// optimized case for float zero
when(target.kind) {
TargetStorageKind.VARIABLE -> {
if(CompilationTarget.machine.cpu == CpuType.CPU65c02)
asmgen.out("""
stz ${target.asmVarname}
stz ${target.asmVarname}+1
stz ${target.asmVarname}+2
stz ${target.asmVarname}+3
stz ${target.asmVarname}+4
""")
else
asmgen.out("""
lda #0
sta ${target.asmVarname}
sta ${target.asmVarname}+1
sta ${target.asmVarname}+2
sta ${target.asmVarname}+3
sta ${target.asmVarname}+4
""")
}
TargetStorageKind.ARRAY -> {
// TODO optimize this, but the situation doesn't occur very often
// if(target.constArrayIndexValue!=null) {
// TODO("const index ${target.constArrayIndexValue}")
// } else if(target.array!!.arrayspec.index is IdentifierReference) {
// TODO("array[var] ${target.constArrayIndexValue}")
// }
val index = target.array!!.arrayspec.index
if (index is NumericLiteralValue) {
val indexValue = index.number.toInt() * DataType.FLOAT.memorySize()
asmgen.out("""
lda #0
sta ${target.asmVarname}+$indexValue
sta ${target.asmVarname}+$indexValue+1
sta ${target.asmVarname}+$indexValue+2
sta ${target.asmVarname}+$indexValue+3
sta ${target.asmVarname}+$indexValue+4
""")
} else {
asmgen.translateExpression(index)
asmgen.out("""
lda #<${target.asmVarname}
sta P8ZP_SCRATCH_W1
lda #>${target.asmVarname}
sta P8ZP_SCRATCH_W1+1
jsr c64flt.set_0_array_float
""")
}
}
TargetStorageKind.MEMORY -> throw AssemblyError("can't assign float to memory byte")
TargetStorageKind.REGISTER -> throw AssemblyError("can't assign float to register")
TargetStorageKind.STACK -> {
val floatConst = asmgen.getFloatAsmConst(float)
asmgen.out(" lda #<$floatConst | ldy #>$floatConst | jsr c64flt.push_float")
}
}
} else {
// non-zero value
val constFloat = asmgen.getFloatAsmConst(float)
when(target.kind) {
TargetStorageKind.VARIABLE -> {
asmgen.out("""
lda $constFloat
sta ${target.asmVarname}
lda $constFloat+1
sta ${target.asmVarname}+1
lda $constFloat+2
sta ${target.asmVarname}+2
lda $constFloat+3
sta ${target.asmVarname}+3
lda $constFloat+4
sta ${target.asmVarname}+4
""")
}
TargetStorageKind.ARRAY -> {
// TODO optimize this, but the situation doesn't occur very often
// if(target.constArrayIndexValue!=null) {
// TODO("const index ${target.constArrayIndexValue}")
// } else if(target.array!!.arrayspec.index is IdentifierReference) {
// TODO("array[var] ${target.constArrayIndexValue}")
// }
val index = target.array!!.arrayspec.index
val arrayVarName = target.asmVarname
if (index is NumericLiteralValue) {
val indexValue = index.number.toInt() * DataType.FLOAT.memorySize()
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.translateExpression(index)
asmgen.out("""
lda #<${constFloat}
sta P8ZP_SCRATCH_W1
lda #>${constFloat}
sta P8ZP_SCRATCH_W1+1
lda #<${arrayVarName}
sta P8ZP_SCRATCH_W2
lda #>${arrayVarName}
sta P8ZP_SCRATCH_W2+1
jsr c64flt.set_array_float
""")
}
}
TargetStorageKind.MEMORY -> throw AssemblyError("can't assign float to memory byte")
TargetStorageKind.REGISTER -> throw AssemblyError("can't assign float to register")
TargetStorageKind.STACK -> {
val floatConst = asmgen.getFloatAsmConst(float)
asmgen.out(" lda #<$floatConst | ldy #>$floatConst | jsr c64flt.push_float")
}
}
}
}
private fun assignMemoryByte(target: AsmAssignTarget, address: Int?, identifier: IdentifierReference?) {
if (address != null) {
when(target.kind) {
TargetStorageKind.VARIABLE -> {
asmgen.out("""
lda ${address.toHex()}
sta ${target.asmVarname}
""")
}
TargetStorageKind.MEMORY -> {
storeByteViaRegisterAInMemoryAddress(address.toHex(), target.memory!!)
}
TargetStorageKind.ARRAY -> {
throw AssemblyError("no asm gen for assign memory byte at $address to array ${target.asmVarname}")
}
TargetStorageKind.REGISTER -> when(target.register!!) {
RegisterOrPair.A -> asmgen.out(" lda ${address.toHex()}")
RegisterOrPair.X -> asmgen.out(" ldx ${address.toHex()}")
RegisterOrPair.Y -> asmgen.out(" ldy ${address.toHex()}")
else -> throw AssemblyError("can't assign byte to word register apir")
}
TargetStorageKind.STACK -> {
asmgen.out("""
lda ${address.toHex()}
sta P8ESTACK_LO,x
dex""")
}
}
} else if (identifier != null) {
when(target.kind) {
TargetStorageKind.VARIABLE -> {
asmgen.loadByteFromPointerIntoA(identifier)
asmgen.out(" sta ${target.asmVarname}")
}
TargetStorageKind.MEMORY -> {
val sourceName = asmgen.asmVariableName(identifier)
storeByteViaRegisterAInMemoryAddress(sourceName, target.memory!!)
}
TargetStorageKind.ARRAY -> {
throw AssemblyError("no asm gen for assign memory byte $identifier to array ${target.asmVarname} ")
}
TargetStorageKind.REGISTER -> {
asmgen.loadByteFromPointerIntoA(identifier)
when(target.register!!) {
RegisterOrPair.A -> {}
RegisterOrPair.X -> asmgen.out(" tax")
RegisterOrPair.Y -> asmgen.out(" tay")
else -> throw AssemblyError("can't assign byte to word register apir")
}
}
TargetStorageKind.STACK -> {
asmgen.loadByteFromPointerIntoA(identifier)
asmgen.out(" sta P8ESTACK_LO,x | dex")
}
}
}
}
private fun storeByteViaRegisterAInMemoryAddress(ldaInstructionArg: String, memoryAddress: DirectMemoryWrite) {
val addressExpr = memoryAddress.addressExpression
val addressLv = addressExpr as? NumericLiteralValue
when {
addressLv != null -> {
asmgen.out(" lda $ldaInstructionArg | sta ${addressLv.number.toHex()}")
}
addressExpr is IdentifierReference -> {
asmgen.storeByteIntoPointer(addressExpr, ldaInstructionArg)
}
else -> {
asmgen.translateExpression(addressExpr)
asmgen.out("""
inx
lda P8ESTACK_LO,x
sta P8ZP_SCRATCH_W2
lda P8ESTACK_HI,x
sta P8ZP_SCRATCH_W2+1
lda $ldaInstructionArg
ldy #0
sta (P8ZP_SCRATCH_W2),y""")
}
}
}
private fun storeRegisterInMemoryAddress(register: CpuRegister, memoryAddress: DirectMemoryWrite) {
// this is optimized for register A.
val addressExpr = memoryAddress.addressExpression
val addressLv = addressExpr as? NumericLiteralValue
val registerName = register.name.toLowerCase()
when {
addressLv != null -> {
asmgen.out(" st$registerName ${addressLv.number.toHex()}")
}
addressExpr is IdentifierReference -> {
when (register) {
CpuRegister.A -> {}
CpuRegister.X -> asmgen.out(" txa")
CpuRegister.Y -> asmgen.out(" tya")
}
asmgen.storeByteIntoPointer(addressExpr, null)
}
else -> {
asmgen.saveRegister(register)
asmgen.translateExpression(addressExpr)
asmgen.restoreRegister(CpuRegister.A)
asmgen.out("""
inx
ldy P8ESTACK_LO,x
sty P8ZP_SCRATCH_W2
ldy P8ESTACK_HI,x
sty P8ZP_SCRATCH_W2+1
ldy #0
sta (P8ZP_SCRATCH_W2),y""")
}
}
}
private fun popAndWriteArrayvalueWithUnscaledIndexA(elementDt: DataType, asmArrayvarname: String) {
when (elementDt) {
in ByteDatatypes ->
asmgen.out(" tay | inx | lda P8ESTACK_LO,x | sta $asmArrayvarname,y")
in WordDatatypes ->
asmgen.out(" asl a | tay | inx | lda P8ESTACK_LO,x | sta $asmArrayvarname,y | lda P8ESTACK_HI,x | sta $asmArrayvarname+1,y")
DataType.FLOAT ->
// scaling * 5 is done in the subroutine that's called
asmgen.out("""
sta P8ESTACK_LO,x
dex
lda #<$asmArrayvarname
ldy #>$asmArrayvarname
jsr c64flt.pop_float_to_indexed_var
""")
else ->
throw AssemblyError("weird array type")
}
}
}

1540
compiler/src/prog8/compiler/target/c64/codegen/assignment/AugmentableAssignmentAsmGen.kt Normal file
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126
compiler/src/prog8/compiler/target/cx16/CX16MachineDefinition.kt Normal file
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@ -0,0 +1,126 @@
package prog8.compiler.target.cx16
import prog8.ast.Program
import prog8.compiler.*
import prog8.compiler.target.CpuType
import prog8.compiler.target.IMachineDefinition
import prog8.compiler.target.c64.C64MachineDefinition
import prog8.parser.ModuleImporter
import java.io.IOException
internal object CX16MachineDefinition: IMachineDefinition {
override val cpu = CpuType.CPU65c02
// 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
override val POINTER_MEM_SIZE = 2
override val BASIC_LOAD_ADDRESS = 0x0801
override val RAW_LOAD_ADDRESS = 0x8000
// 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
override val ESTACK_LO = 0x0400 // $0400-$04ff inclusive
override val ESTACK_HI = 0x0500 // $0500-$05ff inclusive
override lateinit var zeropage: Zeropage
override val initSystemProcname = "cx16.init_system"
override fun getFloat(num: Number) = C64MachineDefinition.Mflpt5.fromNumber(num)
override fun getFloatRomConst(number: Double): String? = null // Cx16 has no pulblic ROM float locations
override fun importLibs(compilerOptions: CompilationOptions, importer: ModuleImporter, program: Program) {
if (compilerOptions.launcher == LauncherType.BASIC || compilerOptions.output == OutputType.PRG)
importer.importLibraryModule(program, "cx16lib")
}
override fun launchEmulator(programName: String) {
for(emulator in listOf("x16emu")) {
println("\nStarting Commander X16 emulator $emulator...")
val cmdline = listOf(emulator, "-rom", "/usr/share/x16-rom/rom.bin", "-scale", "2",
"-run", "-prg", 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
}
}
override fun initializeZeropage(compilerOptions: CompilationOptions) {
zeropage = CX16Zeropage(compilerOptions)
}
// 6502 opcodes (including aliases and illegal opcodes), these cannot be used as variable or label names
override val opcodeNames = setOf("adc", "and", "asl", "bcc", "bcs",
"beq", "bge", "bit", "blt", "bmi", "bne", "bpl", "brk", "bvc", "bvs", "clc",
"cld", "cli", "clv", "cmp", "cpx", "cpy", "dec", "dex", "dey",
"eor", "gcc", "gcs", "geq", "gge", "glt", "gmi", "gne", "gpl", "gvc", "gvs",
"inc", "inx", "iny", "jmp", "jsr",
"lda", "ldx", "ldy", "lsr", "nop", "ora", "pha", "php",
"pla", "plp", "rol", "ror", "rti", "rts", "sbc",
"sec", "sed", "sei",
"sta", "stx", "sty", "tax", "tay", "tsx", "txa", "txs", "tya",
"bra", "phx", "phy", "plx", "ply", "stz", "trb", "tsb", "bbr", "bbs",
"rmb", "smb", "stp", "wai")
internal class CX16Zeropage(options: CompilationOptions) : Zeropage(options) {
override val SCRATCH_B1 = 0x79 // temp storage for a single byte
override val SCRATCH_REG = 0x7a // temp storage for a register
override val SCRATCH_REG_X = 0x7b // temp storage for register X (the evaluation stack pointer)
override val SCRATCH_W1 = 0x7c // temp storage 1 for a word $7c+$7d
override val SCRATCH_W2 = 0x7e // temp storage 2 for a word $7e+$7f
override val exitProgramStrategy: ExitProgramStrategy = when (options.zeropage) {
ZeropageType.BASICSAFE, ZeropageType.DONTUSE -> ExitProgramStrategy.CLEAN_EXIT
ZeropageType.KERNALSAFE, ZeropageType.FULL -> ExitProgramStrategy.SYSTEM_RESET
else -> ExitProgramStrategy.SYSTEM_RESET
}
init {
if (options.floats && options.zeropage !in setOf(ZeropageType.BASICSAFE, ZeropageType.DONTUSE ))
throw CompilerException("when floats are enabled, zero page type should be 'basicsafe' or 'dontuse'")
// the addresses 0x02 to 0x21 (inclusive) are taken for sixteen virtual 16-bit api registers.
when (options.zeropage) {
ZeropageType.FULL -> {
free.addAll(0x22..0xff)
free.removeAll(listOf(SCRATCH_B1, SCRATCH_REG, SCRATCH_REG_X, SCRATCH_W1, SCRATCH_W1 + 1, SCRATCH_W2, SCRATCH_W2 + 1))
}
ZeropageType.KERNALSAFE -> {
free.addAll(0x22..0x7f)
free.addAll(0xa9..0xff)
free.removeAll(listOf(SCRATCH_B1, SCRATCH_REG, SCRATCH_REG_X, SCRATCH_W1, SCRATCH_W1 + 1, SCRATCH_W2, SCRATCH_W2 + 1))
}
ZeropageType.BASICSAFE -> {
free.addAll(0x22..0x7f)
free.removeAll(listOf(SCRATCH_B1, SCRATCH_REG, SCRATCH_REG_X, SCRATCH_W1, SCRATCH_W1 + 1, SCRATCH_W2, SCRATCH_W2 + 1))
}
ZeropageType.DONTUSE -> {
free.clear() // don't use zeropage at all
}
else -> throw CompilerException("for this machine target, zero page type 'floatsafe' is not available. ${options.zeropage}")
}
require(SCRATCH_B1 !in free)
require(SCRATCH_REG !in free)
require(SCRATCH_REG_X !in free)
require(SCRATCH_W1 !in free)
require(SCRATCH_W2 !in free)
for (reserved in options.zpReserved)
reserve(reserved)
}
}
}

301
compiler/src/prog8/functions/BuiltinFunctions.kt
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@ -3,122 +3,110 @@ package prog8.functions
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.ast.statements.StructDecl
import prog8.ast.statements.VarDecl
import prog8.compiler.CompilerException
import kotlin.math.*
class BuiltinFunctionParam(val name: String, val possibleDatatypes: Set<DataType>)
class FParam(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: ConstExpressionCaller? = null)
class FSignature(val pure: Boolean, // does it have side effects?
val parameters: List<FParam>,
val returntype: DataType?,
val constExpressionFunc: ConstExpressionCaller? = null)
val BuiltinFunctions = mapOf(
// this set of function have no return value and operate in-place:
"rol" to FunctionSignature(false, listOf(BuiltinFunctionParam("item", setOf(DataType.UBYTE, DataType.UWORD))), null),
"ror" to FunctionSignature(false, listOf(BuiltinFunctionParam("item", setOf(DataType.UBYTE, DataType.UWORD))), null),
"rol2" to FunctionSignature(false, listOf(BuiltinFunctionParam("item", setOf(DataType.UBYTE, DataType.UWORD))), null),
"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),
"rol" to FSignature(false, listOf(FParam("item", setOf(DataType.UBYTE, DataType.UWORD))), null),
"ror" to FSignature(false, listOf(FParam("item", setOf(DataType.UBYTE, DataType.UWORD))), null),
"rol2" to FSignature(false, listOf(FParam("item", setOf(DataType.UBYTE, DataType.UWORD))), null),
"ror2" to FSignature(false, listOf(FParam("item", setOf(DataType.UBYTE, DataType.UWORD))), null),
"sort" to FSignature(false, listOf(FParam("array", ArrayDatatypes)), null),
"reverse" to FSignature(false, listOf(FParam("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 -> 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
"max" to FSignature(true, listOf(FParam("values", ArrayDatatypes)), null) { a, p, prg -> collectionArg(a, p, prg, ::builtinMax) }, // type depends on args
"min" to FSignature(true, listOf(FParam("values", ArrayDatatypes)), null) { a, p, prg -> collectionArg(a, p, prg, ::builtinMin) }, // type depends on args
"sum" to FSignature(true, listOf(FParam("values", ArrayDatatypes)), null) { a, p, prg -> collectionArg(a, p, prg, ::builtinSum) }, // type depends on args
"abs" to FSignature(true, listOf(FParam("value", NumericDatatypes)), null, ::builtinAbs), // type depends on argument
"len" to FSignature(true, listOf(FParam("values", IterableDatatypes)), null, ::builtinLen), // type is UBYTE or UWORD depending on actual length
"sizeof" to FSignature(true, listOf(FParam("object", DataType.values().toSet())), DataType.UBYTE, ::builtinSizeof),
// 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 ),
"sin16" to FunctionSignature(true, listOf(BuiltinFunctionParam("angle8", setOf(DataType.UBYTE))), DataType.WORD, ::builtinSin16 ),
"sin16u" to FunctionSignature(true, listOf(BuiltinFunctionParam("angle8", setOf(DataType.UBYTE))), DataType.UWORD, ::builtinSin16u ),
"cos" to FunctionSignature(true, listOf(BuiltinFunctionParam("rads", setOf(DataType.FLOAT))), DataType.FLOAT) { a, p, prg -> oneDoubleArg(a, p, prg, Math::cos) },
"cos8" to FunctionSignature(true, listOf(BuiltinFunctionParam("angle8", setOf(DataType.UBYTE))), DataType.BYTE, ::builtinCos8 ),
"cos8u" to FunctionSignature(true, listOf(BuiltinFunctionParam("angle8", setOf(DataType.UBYTE))), DataType.UBYTE, ::builtinCos8u ),
"cos16" to FunctionSignature(true, listOf(BuiltinFunctionParam("angle8", setOf(DataType.UBYTE))), DataType.WORD, ::builtinCos16 ),
"cos16u" to FunctionSignature(true, listOf(BuiltinFunctionParam("angle8", setOf(DataType.UBYTE))), DataType.UWORD, ::builtinCos16u ),
"tan" to FunctionSignature(true, listOf(BuiltinFunctionParam("rads", setOf(DataType.FLOAT))), DataType.FLOAT) { a, p, prg -> oneDoubleArg(a, p, prg, Math::tan) },
"atan" to FunctionSignature(true, listOf(BuiltinFunctionParam("rads", setOf(DataType.FLOAT))), DataType.FLOAT) { a, p, prg -> oneDoubleArg(a, p, prg, Math::atan) },
"ln" to FunctionSignature(true, listOf(BuiltinFunctionParam("value", setOf(DataType.FLOAT))), DataType.FLOAT) { a, p, prg -> oneDoubleArg(a, p, prg, Math::log) },
"log2" to FunctionSignature(true, listOf(BuiltinFunctionParam("value", setOf(DataType.FLOAT))), DataType.FLOAT) { a, p, prg -> oneDoubleArg(a, p, prg, ::log2) },
"sqrt16" to FunctionSignature(true, listOf(BuiltinFunctionParam("value", setOf(DataType.UWORD))), DataType.UBYTE) { a, p, prg -> oneIntArgOutputInt(a, p, prg) { sqrt(it.toDouble()).toInt() } },
"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) },
"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 -> 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(
BuiltinFunctionParam("lsb", setOf(DataType.UBYTE)),
BuiltinFunctionParam("msb", setOf(DataType.UBYTE))), DataType.UWORD, ::builtinMkword),
"rnd" to FunctionSignature(true, emptyList(), DataType.UBYTE),
"rndw" to FunctionSignature(true, emptyList(), DataType.UWORD),
"rndf" to FunctionSignature(true, emptyList(), DataType.FLOAT),
"rsave" to FunctionSignature(false, emptyList(), null),
"rrestore" to FunctionSignature(false, emptyList(), null),
"set_carry" to FunctionSignature(false, emptyList(), null),
"clear_carry" to FunctionSignature(false, emptyList(), null),
"set_irqd" to FunctionSignature(false, emptyList(), null),
"clear_irqd" to FunctionSignature(false, emptyList(), null),
"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 + DataType.UWORD),
BuiltinFunctionParam("to", IterableDatatypes + DataType.UWORD),
BuiltinFunctionParam("numbytes", setOf(DataType.UBYTE))), null),
"memset" to FunctionSignature(false, listOf(
BuiltinFunctionParam("address", IterableDatatypes + DataType.UWORD),
BuiltinFunctionParam("numbytes", setOf(DataType.UWORD)),
BuiltinFunctionParam("bytevalue", ByteDatatypes)), null),
"memsetw" to FunctionSignature(false, listOf(
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),
// TODO clean up these vm-specific functions
"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)
"sgn" to FSignature(true, listOf(FParam("value", NumericDatatypes)), DataType.BYTE, ::builtinSgn ),
"sin" to FSignature(true, listOf(FParam("rads", setOf(DataType.FLOAT))), DataType.FLOAT) { a, p, prg -> oneDoubleArg(a, p, prg, Math::sin) },
"sin8" to FSignature(true, listOf(FParam("angle8", setOf(DataType.UBYTE))), DataType.BYTE, ::builtinSin8 ),
"sin8u" to FSignature(true, listOf(FParam("angle8", setOf(DataType.UBYTE))), DataType.UBYTE, ::builtinSin8u ),
"sin16" to FSignature(true, listOf(FParam("angle8", setOf(DataType.UBYTE))), DataType.WORD, ::builtinSin16 ),
"sin16u" to FSignature(true, listOf(FParam("angle8", setOf(DataType.UBYTE))), DataType.UWORD, ::builtinSin16u ),
"cos" to FSignature(true, listOf(FParam("rads", setOf(DataType.FLOAT))), DataType.FLOAT) { a, p, prg -> oneDoubleArg(a, p, prg, Math::cos) },
"cos8" to FSignature(true, listOf(FParam("angle8", setOf(DataType.UBYTE))), DataType.BYTE, ::builtinCos8 ),
"cos8u" to FSignature(true, listOf(FParam("angle8", setOf(DataType.UBYTE))), DataType.UBYTE, ::builtinCos8u ),
"cos16" to FSignature(true, listOf(FParam("angle8", setOf(DataType.UBYTE))), DataType.WORD, ::builtinCos16 ),
"cos16u" to FSignature(true, listOf(FParam("angle8", setOf(DataType.UBYTE))), DataType.UWORD, ::builtinCos16u ),
"tan" to FSignature(true, listOf(FParam("rads", setOf(DataType.FLOAT))), DataType.FLOAT) { a, p, prg -> oneDoubleArg(a, p, prg, Math::tan) },
"atan" to FSignature(true, listOf(FParam("rads", setOf(DataType.FLOAT))), DataType.FLOAT) { a, p, prg -> oneDoubleArg(a, p, prg, Math::atan) },
"ln" to FSignature(true, listOf(FParam("value", setOf(DataType.FLOAT))), DataType.FLOAT) { a, p, prg -> oneDoubleArg(a, p, prg, Math::log) },
"log2" to FSignature(true, listOf(FParam("value", setOf(DataType.FLOAT))), DataType.FLOAT) { a, p, prg -> oneDoubleArg(a, p, prg, ::log2) },
"sqrt16" to FSignature(true, listOf(FParam("value", setOf(DataType.UWORD))), DataType.UBYTE) { a, p, prg -> oneIntArgOutputInt(a, p, prg) { sqrt(it.toDouble()).toInt() } },
"sqrt" to FSignature(true, listOf(FParam("value", setOf(DataType.FLOAT))), DataType.FLOAT) { a, p, prg -> oneDoubleArg(a, p, prg, Math::sqrt) },
"rad" to FSignature(true, listOf(FParam("value", setOf(DataType.FLOAT))), DataType.FLOAT) { a, p, prg -> oneDoubleArg(a, p, prg, Math::toRadians) },
"deg" to FSignature(true, listOf(FParam("value", setOf(DataType.FLOAT))), DataType.FLOAT) { a, p, prg -> oneDoubleArg(a, p, prg, Math::toDegrees) },
"round" to FSignature(true, listOf(FParam("value", setOf(DataType.FLOAT))), DataType.FLOAT) { a, p, prg -> oneDoubleArgOutputWord(a, p, prg, Math::round) },
"floor" to FSignature(true, listOf(FParam("value", setOf(DataType.FLOAT))), DataType.FLOAT) { a, p, prg -> oneDoubleArgOutputWord(a, p, prg, Math::floor) },
"ceil" to FSignature(true, listOf(FParam("value", setOf(DataType.FLOAT))), DataType.FLOAT) { a, p, prg -> oneDoubleArgOutputWord(a, p, prg, Math::ceil) },
"any" to FSignature(true, listOf(FParam("values", ArrayDatatypes)), DataType.UBYTE) { a, p, prg -> collectionArg(a, p, prg, ::builtinAny) },
"all" to FSignature(true, listOf(FParam("values", ArrayDatatypes)), DataType.UBYTE) { a, p, prg -> collectionArg(a, p, prg, ::builtinAll) },
"lsb" to FSignature(true, listOf(FParam("value", setOf(DataType.UWORD, DataType.WORD))), DataType.UBYTE) { a, p, prg -> oneIntArgOutputInt(a, p, prg) { x: Int -> x and 255 }},
"msb" to FSignature(true, listOf(FParam("value", setOf(DataType.UWORD, DataType.WORD))), DataType.UBYTE) { a, p, prg -> oneIntArgOutputInt(a, p, prg) { x: Int -> x ushr 8 and 255}},
"mkword" to FSignature(true, listOf(FParam("msb", setOf(DataType.UBYTE)), FParam("lsb", setOf(DataType.UBYTE))), DataType.UWORD, ::builtinMkword),
"rnd" to FSignature(true, emptyList(), DataType.UBYTE),
"rndw" to FSignature(true, emptyList(), DataType.UWORD),
"rndf" to FSignature(true, emptyList(), DataType.FLOAT),
"exit" to FSignature(false, listOf(FParam("returnvalue", setOf(DataType.UBYTE))), null),
"rsave" to FSignature(false, emptyList(), null),
"rrestore" to FSignature(false, emptyList(), null),
"set_carry" to FSignature(false, emptyList(), null),
"clear_carry" to FSignature(false, emptyList(), null),
"set_irqd" to FSignature(false, emptyList(), null),
"clear_irqd" to FSignature(false, emptyList(), null),
"read_flags" to FSignature(false, emptyList(), DataType.UBYTE),
"swap" to FSignature(false, listOf(FParam("first", NumericDatatypes), FParam("second", NumericDatatypes)), null),
"memcopy" to FSignature(false, listOf(
FParam("from", IterableDatatypes + DataType.UWORD),
FParam("to", IterableDatatypes + DataType.UWORD),
FParam("numbytes", setOf(DataType.UBYTE))), null),
"memset" to FSignature(false, listOf(
FParam("address", IterableDatatypes + DataType.UWORD),
FParam("numbytes", setOf(DataType.UWORD)),
FParam("bytevalue", ByteDatatypes)), null),
"memsetw" to FSignature(false, listOf(
FParam("address", IterableDatatypes + DataType.UWORD),
FParam("numwords", setOf(DataType.UWORD)),
FParam("wordvalue", setOf(DataType.UWORD, DataType.WORD))), null),
"strlen" to FSignature(true, listOf(FParam("string", setOf(DataType.STR))), DataType.UBYTE, ::builtinStrlen),
"substr" to FSignature(false, listOf(
FParam("source", IterableDatatypes + DataType.UWORD),
FParam("target", IterableDatatypes + DataType.UWORD),
FParam("start", setOf(DataType.UBYTE)),
FParam("length", setOf(DataType.UBYTE))), null),
"leftstr" to FSignature(false, listOf(
FParam("source", IterableDatatypes + DataType.UWORD),
FParam("target", IterableDatatypes + DataType.UWORD),
FParam("length", setOf(DataType.UBYTE))), null),
"rightstr" to FSignature(false, listOf(
FParam("source", IterableDatatypes + DataType.UWORD),
FParam("target", IterableDatatypes + DataType.UWORD),
FParam("length", setOf(DataType.UBYTE))), null)
)
fun builtinMax(array: List<Number>): Number = array.maxBy { it.toDouble() }!!
fun builtinMax(array: List<Number>): Number = array.maxByOrNull { it.toDouble() }!!
fun builtinMin(array: List<Number>): Number = array.minBy { it.toDouble() }!!
fun builtinMin(array: List<Number>): Number = array.minByOrNull { it.toDouble() }!!
fun builtinSum(array: List<Number>): Number = array.sumByDouble { it.toDouble() }
@ -145,10 +133,8 @@ fun builtinFunctionReturnType(function: String, args: List<Expression>, program:
val idt = arglist.inferType(program)
if(!idt.isKnown)
throw FatalAstException("couldn't determine type of iterable $arglist")
val dt = idt.typeOrElse(DataType.STRUCT)
return when(dt) {
in NumericDatatypes -> dt
in StringDatatypes -> dt
return when(val dt = idt.typeOrElse(DataType.STRUCT)) {
DataType.STR, in NumericDatatypes -> dt
in ArrayDatatypes -> ArrayElementTypes.getValue(dt)
else -> throw FatalAstException("function '$function' requires one argument which is an iterable")
}
@ -171,8 +157,8 @@ fun builtinFunctionReturnType(function: String, args: List<Expression>, program:
}
"max", "min" -> {
when(val dt = datatypeFromIterableArg(args.single())) {
DataType.STR -> InferredTypes.knownFor(DataType.UBYTE)
in NumericDatatypes -> InferredTypes.knownFor(dt)
in StringDatatypes -> InferredTypes.knownFor(DataType.UBYTE)
in ArrayDatatypes -> InferredTypes.knownFor(ArrayElementTypes.getValue(dt))
else -> InferredTypes.unknown()
}
@ -185,7 +171,7 @@ fun builtinFunctionReturnType(function: String, args: List<Expression>, program:
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)
in StringDatatypes -> InferredTypes.knownFor(DataType.UWORD)
DataType.STR -> InferredTypes.knownFor(DataType.UWORD)
else -> InferredTypes.unknown()
}
}
@ -199,7 +185,8 @@ fun builtinFunctionReturnType(function: String, args: List<Expression>, program:
}
class NotConstArgumentException: AstException("not a const argument to a built-in function") // TODO: ugly, remove throwing exceptions for control flow
class NotConstArgumentException: AstException("not a const argument to a built-in function")
class CannotEvaluateException(func:String, msg: String): FatalAstException("cannot evaluate built-in function $func: $msg")
private fun oneDoubleArg(args: List<Expression>, position: Position, program: Program, function: (arg: Double)->Number): NumericLiteralValue {
@ -254,54 +241,88 @@ private fun builtinAbs(args: List<Expression>, position: Position, program: Prog
}
}
private fun builtinSizeof(args: List<Expression>, position: Position, program: Program): NumericLiteralValue {
// 1 arg, type = anything, result type = ubyte
if(args.size!=1)
throw SyntaxError("sizeof requires one argument", position)
if(args[0] !is IdentifierReference)
throw SyntaxError("sizeof argument should be an identifier", position)
val dt = args[0].inferType(program)
if(dt.isKnown) {
val target = (args[0] as IdentifierReference).targetStatement(program.namespace)
?: throw CannotEvaluateException("sizeof", "no target")
fun structSize(target: StructDecl) =
NumericLiteralValue(DataType.UBYTE, target.statements.map { (it as VarDecl).datatype.memorySize() }.sum(), position)
return when {
dt.typeOrElse(DataType.STRUCT) in ArrayDatatypes -> {
val length = (target as VarDecl).arraysize!!.constIndex() ?: throw CannotEvaluateException("sizeof", "unknown array size")
val elementDt = ArrayElementTypes.getValue(dt.typeOrElse(DataType.STRUCT))
numericLiteral(elementDt.memorySize() * length, position)
}
dt.istype(DataType.STRUCT) -> {
when (target) {
is VarDecl -> structSize(target.struct!!)
is StructDecl -> structSize(target)
else -> throw CompilerException("weird struct type $target")
}
}
dt.istype(DataType.STR) -> throw SyntaxError("sizeof str is undefined, did you mean len?", position)
else -> NumericLiteralValue(DataType.UBYTE, dt.typeOrElse(DataType.STRUCT).memorySize(), position)
}
} else {
throw SyntaxError("sizeof invalid argument type", position)
}
}
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)
throw SyntaxError("strlen must have string argument", position)
throw NotConstArgumentException() // this function is not considering the string argument a constant
val argument=args[0]
if(argument is StringLiteralValue)
return NumericLiteralValue.optimalInteger(argument.value.length, argument.position)
val vardecl = (argument as IdentifierReference).targetVarDecl(program.namespace)
if(vardecl!=null) {
if(vardecl.datatype!=DataType.STR)
throw SyntaxError("strlen must have string argument", position)
if(vardecl.autogeneratedDontRemove) {
return NumericLiteralValue.optimalInteger((vardecl.value as StringLiteralValue).value.length, argument.position)
}
}
throw NotConstArgumentException()
}
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)
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()
var arraySize = directMemVar?.arraysize?.constIndex()
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)!!
throw SyntaxError("len argument should be an identifier", position)
val target = (args[0] as IdentifierReference).targetVarDecl(program.namespace)
?: throw CannotEvaluateException("len", "no target vardecl")
return when(target.datatype) {
DataType.ARRAY_UB, DataType.ARRAY_B, DataType.ARRAY_UW, DataType.ARRAY_W -> {
arraySize = target.arraysize!!.size()!!
if(arraySize>256)
throw CompilerException("array length exceeds byte limit ${target.position}")
DataType.ARRAY_UB, DataType.ARRAY_B, DataType.ARRAY_UW, DataType.ARRAY_W, DataType.ARRAY_F -> {
arraySize = target.arraysize?.constIndex()
if(arraySize==null)
throw CannotEvaluateException("len", "arraysize unknown")
NumericLiteralValue.optimalInteger(arraySize, args[0].position)
}
DataType.ARRAY_F -> {
arraySize = target.arraysize!!.size()!!
if(arraySize>256)
throw CompilerException("array length exceeds byte limit ${target.position}")
NumericLiteralValue.optimalInteger(arraySize, args[0].position)
}
in StringDatatypes -> {
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)
DataType.STRUCT -> throw SyntaxError("cannot use len on struct, did you mean sizeof?", args[0].position)
in NumericDatatypes -> throw SyntaxError("cannot use len on numeric value, did you mean sizeof?", args[0].position)
else -> throw CompilerException("weird datatype")
}
}
@ -309,9 +330,9 @@ private fun builtinLen(args: List<Expression>, position: Position, program: Prog
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()
throw SyntaxError("mkword requires msb and lsb arguments", position)
val constMsb = args[0].constValue(program) ?: throw NotConstArgumentException()
val constLsb = args[1].constValue(program) ?: throw NotConstArgumentException()
val result = (constMsb.number.toInt() shl 8) or constLsb.number.toInt()
return NumericLiteralValue(DataType.UWORD, result, position)
}
@ -321,7 +342,7 @@ private fun builtinSin8(args: List<Expression>, position: Position, program: Pro
throw SyntaxError("sin8 requires one argument", position)
val constval = args[0].constValue(program) ?: throw NotConstArgumentException()
val rad = constval.number.toDouble() /256.0 * 2.0 * PI
return NumericLiteralValue(DataType.BYTE, (127.0 * sin(rad)).toShort(), position)
return NumericLiteralValue(DataType.BYTE, (127.0 * sin(rad)).toInt().toShort(), position)
}
private fun builtinSin8u(args: List<Expression>, position: Position, program: Program): NumericLiteralValue {
@ -329,7 +350,7 @@ private fun builtinSin8u(args: List<Expression>, position: Position, program: Pr
throw SyntaxError("sin8u requires one argument", position)
val constval = args[0].constValue(program) ?: throw NotConstArgumentException()
val rad = constval.number.toDouble() /256.0 * 2.0 * PI
return NumericLiteralValue(DataType.UBYTE, (128.0 + 127.5 * sin(rad)).toShort(), position)
return NumericLiteralValue(DataType.UBYTE, (128.0 + 127.5 * sin(rad)).toInt().toShort(), position)
}
private fun builtinCos8(args: List<Expression>, position: Position, program: Program): NumericLiteralValue {
@ -337,7 +358,7 @@ private fun builtinCos8(args: List<Expression>, position: Position, program: Pro
throw SyntaxError("cos8 requires one argument", position)
val constval = args[0].constValue(program) ?: throw NotConstArgumentException()
val rad = constval.number.toDouble() /256.0 * 2.0 * PI
return NumericLiteralValue(DataType.BYTE, (127.0 * cos(rad)).toShort(), position)
return NumericLiteralValue(DataType.BYTE, (127.0 * cos(rad)).toInt().toShort(), position)
}
private fun builtinCos8u(args: List<Expression>, position: Position, program: Program): NumericLiteralValue {
@ -345,7 +366,7 @@ private fun builtinCos8u(args: List<Expression>, position: Position, program: Pr
throw SyntaxError("cos8u requires one argument", position)
val constval = args[0].constValue(program) ?: throw NotConstArgumentException()
val rad = constval.number.toDouble() /256.0 * 2.0 * PI
return NumericLiteralValue(DataType.UBYTE, (128.0 + 127.5 * cos(rad)).toShort(), position)
return NumericLiteralValue(DataType.UBYTE, (128.0 + 127.5 * cos(rad)).toInt().toShort(), position)
}
private fun builtinSin16(args: List<Expression>, position: Position, program: Program): NumericLiteralValue {
@ -384,7 +405,7 @@ private fun builtinSgn(args: List<Expression>, position: Position, program: Prog
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)
return NumericLiteralValue(DataType.BYTE, constval.number.toDouble().sign.toInt().toShort(), position)
}
private fun numericLiteral(value: Number, position: Position): NumericLiteralValue {
@ -396,8 +417,8 @@ private fun numericLiteral(value: Number, position: Position): NumericLiteralVal
floatNum
return when(tweakedValue) {
is Int -> NumericLiteralValue.optimalNumeric(value.toInt(), position)
is Short -> NumericLiteralValue.optimalNumeric(value.toInt(), position)
is Int -> NumericLiteralValue.optimalInteger(value.toInt(), position)
is Short -> NumericLiteralValue.optimalInteger(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)

114
compiler/src/prog8/optimizer/CallGraph.kt
View File

@ -6,22 +6,29 @@ 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
import prog8.ast.expressions.FunctionCall
import prog8.ast.expressions.IdentifierReference
import prog8.ast.processing.IAstVisitor
import prog8.ast.statements.*
import prog8.compiler.loadAsmIncludeFile
private val alwaysKeepSubroutines = setOf(
Pair("main", "start"),
Pair("irq", "irq")
)
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)
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() }
// TODO add dataflow graph: what statements use what variables
class CallGraph(private val program: Program) : IAstVisitor {
val imports = mutableMapOf<Module, List<Module>>().withDefault { mutableListOf() }
val importedBy = mutableMapOf<Module, List<Module>>().withDefault { mutableListOf() }
val calls = mutableMapOf<INameScope, List<Subroutine>>().withDefault { mutableListOf() }
val calledBy = mutableMapOf<Subroutine, List<Node>>().withDefault { mutableListOf() }
// TODO add dataflow graph: what statements use what variables - can be used to eliminate unused vars
val usedSymbols = mutableSetOf<Statement>()
init {
@ -31,9 +38,9 @@ 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)
}
}
@ -47,17 +54,8 @@ class CallGraph(private val program: Program): IAstVisitor {
it.importedBy.clear()
it.imports.clear()
it.importedBy.addAll(modulesImportedBy.getValue(it))
it.imports.addAll(modulesImporting.getValue(it))
forAllSubroutines(it) { sub ->
sub.calledBy.clear()
sub.calls.clear()
sub.calledBy.addAll(subroutinesCalledBy.getValue(sub))
sub.calls.addAll(subroutinesCalling.getValue(sub))
}
it.importedBy.addAll(importedBy.getValue(it))
it.imports.addAll(imports.getValue(it))
}
val rootmodule = program.modules.first()
@ -65,7 +63,7 @@ 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)
}
@ -75,11 +73,11 @@ 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 }
modulesImporting[thisModule] = modulesImporting.getValue(thisModule).plus(importedModule)
modulesImportedBy[importedModule] = modulesImportedBy.getValue(importedModule).plus(thisModule)
} else if (directive.directive=="%asminclude") {
if (directive.directive == "%import") {
val importedModule: Module = program.modules.single { it.name == directive.args[0].name }
imports[thisModule] = imports.getValue(thisModule).plus(importedModule)
importedBy[importedModule] = importedBy.getValue(importedModule).plus(thisModule)
} else if (directive.directive == "%asminclude") {
val asm = loadAsmIncludeFile(directive.args[0].str!!, thisModule.source)
val scope = directive.definingScope()
scanAssemblyCode(asm, directive, scope)
@ -91,7 +89,7 @@ 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)
@ -99,24 +97,18 @@ class CallGraph(private val program: Program): IAstVisitor {
private fun addNodeAndParentScopes(stmt: Statement) {
usedSymbols.add(stmt)
var node: Node=stmt
var node: Node = stmt
do {
if(node is INameScope && node is Statement) {
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) {
val alwaysKeepSubroutines = setOf(
Pair("main", "start"),
Pair("irq", "irq"),
Pair("prog8_lib", "init_system")
)
if(Pair(subroutine.definingScope().name, subroutine.name) in alwaysKeepSubroutines
|| subroutine.name== initvarsSubName || subroutine.definingModule().isLibraryModule) {
if (Pair(subroutine.definingScope().name, subroutine.name) in alwaysKeepSubroutines
|| subroutine.definingModule().isLibraryModule) {
// make sure the entrypoint is mentioned in the used symbols
addNodeAndParentScopes(subroutine)
}
@ -124,12 +116,12 @@ class CallGraph(private val program: Program): IAstVisitor {
}
override fun visit(decl: VarDecl) {
if(decl.autogeneratedDontRemove || (decl.definingModule().isLibraryModule && decl.type!=VarDeclType.VAR)) {
// make sure autogenerated vardecls are in the used symbols
if (decl.autogeneratedDontRemove || decl.definingModule().isLibraryModule) {
// make sure autogenerated vardecls are in the used symbols and are never removed as 'unused'
addNodeAndParentScopes(decl)
}
if(decl.datatype==DataType.STRUCT)
if (decl.datatype == DataType.STRUCT)
addNodeAndParentScopes(decl)
super.visit(decl)
@ -137,10 +129,10 @@ class CallGraph(private val program: Program): IAstVisitor {
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)
calls[thisSub] = calls.getValue(thisSub).plus(otherSub)
calledBy[otherSub] = calledBy.getValue(otherSub).plus(functionCall)
}
}
super.visit(functionCall)
@ -148,10 +140,10 @@ 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)
calls[thisSub] = calls.getValue(thisSub).plus(otherSub)
calledBy[otherSub] = calledBy.getValue(otherSub).plus(functionCallStatement)
}
}
super.visit(functionCallStatement)
@ -159,10 +151,10 @@ 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)
calls[thisSub] = calls.getValue(thisSub).plus(otherSub)
calledBy[otherSub] = calledBy.getValue(otherSub).plus(jump)
}
}
super.visit(jump)
@ -181,8 +173,6 @@ class CallGraph(private val program: Program): IAstVisitor {
}
private fun scanAssemblyCode(asm: String, context: Statement, 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)
asm.lines().forEach { line ->
val matches = asmJumpRx.matchEntire(line)
if (matches != null) {
@ -190,27 +180,27 @@ class CallGraph(private val program: Program): IAstVisitor {
if (jumptarget != null && (jumptarget[0].isLetter() || jumptarget[0] == '_')) {
val node = program.namespace.lookup(jumptarget.split('.'), context)
if (node is Subroutine) {
subroutinesCalling[scope] = subroutinesCalling.getValue(scope).plus(node)
subroutinesCalledBy[node] = subroutinesCalledBy.getValue(node).plus(context)
} else if(jumptarget.contains('.')) {
calls[scope] = calls.getValue(scope).plus(node)
calledBy[node] = calledBy.getValue(node).plus(context)
} 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) {
subroutinesCalling[scope] = subroutinesCalling.getValue(scope).plus(node2)
subroutinesCalledBy[node2] = subroutinesCalledBy.getValue(node2).plus(context)
calls[scope] = calls.getValue(scope).plus(node2)
calledBy[node2] = calledBy.getValue(node2).plus(context)
}
}
}
} 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] == '_')) {
if(target.contains('.')) {
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)
calls[scope] = calls.getValue(scope).plus(node)
calledBy[node] = calledBy.getValue(node).plus(context)
}
}
}

132
compiler/src/prog8/optimizer/ConstExprEvaluator.kt
View File

@ -54,15 +54,15 @@ class ConstExprEvaluator {
private fun logicalxor(left: NumericLiteralValue, right: NumericLiteralValue): NumericLiteralValue {
val error = "cannot compute $left locical-bitxor $right"
return when {
left.type in IntegerDatatypes -> when {
right.type in IntegerDatatypes -> NumericLiteralValue.fromBoolean((left.number.toInt() != 0) xor (right.number.toInt() != 0), left.position)
right.type == DataType.FLOAT -> NumericLiteralValue.fromBoolean((left.number.toInt() != 0) xor (right.number.toDouble() != 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.type == DataType.FLOAT -> when {
right.type in IntegerDatatypes -> NumericLiteralValue.fromBoolean((left.number.toDouble() != 0.0) xor (right.number.toInt() != 0), left.position)
right.type == DataType.FLOAT -> NumericLiteralValue.fromBoolean((left.number.toDouble() != 0.0) xor (right.number.toDouble() != 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)
@ -71,15 +71,15 @@ class ConstExprEvaluator {
private fun logicalor(left: NumericLiteralValue, right: NumericLiteralValue): NumericLiteralValue {
val error = "cannot compute $left locical-or $right"
return when {
left.type in IntegerDatatypes -> when {
right.type in IntegerDatatypes -> NumericLiteralValue.fromBoolean(left.number.toInt() != 0 || right.number.toInt() != 0, left.position)
right.type == DataType.FLOAT -> NumericLiteralValue.fromBoolean(left.number.toInt() != 0 || right.number.toDouble() != 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.type == DataType.FLOAT -> when {
right.type in IntegerDatatypes -> NumericLiteralValue.fromBoolean(left.number.toDouble() != 0.0 || right.number.toInt() != 0, left.position)
right.type == DataType.FLOAT -> NumericLiteralValue.fromBoolean(left.number.toDouble() != 0.0 || right.number.toDouble() != 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)
@ -88,15 +88,15 @@ class ConstExprEvaluator {
private fun logicaland(left: NumericLiteralValue, right: NumericLiteralValue): NumericLiteralValue {
val error = "cannot compute $left locical-and $right"
return when {
left.type in IntegerDatatypes -> when {
right.type in IntegerDatatypes -> NumericLiteralValue.fromBoolean(left.number.toInt() != 0 && right.number.toInt() != 0, left.position)
right.type == DataType.FLOAT -> NumericLiteralValue.fromBoolean(left.number.toInt() != 0 && right.number.toDouble() != 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.type == DataType.FLOAT -> when {
right.type in IntegerDatatypes -> NumericLiteralValue.fromBoolean(left.number.toDouble() != 0.0 && right.number.toInt() != 0, left.position)
right.type == DataType.FLOAT -> NumericLiteralValue.fromBoolean(left.number.toDouble() != 0.0 && right.number.toDouble() != 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)
@ -132,11 +132,11 @@ class ConstExprEvaluator {
private fun bitwiseand(left: NumericLiteralValue, right: NumericLiteralValue): NumericLiteralValue {
if(left.type== DataType.UBYTE) {
if(right.type in IntegerDatatypes) {
return NumericLiteralValue(DataType.UBYTE, (left.number.toInt() or (right.number.toInt() and 255)).toShort(), left.position)
return NumericLiteralValue(DataType.UBYTE, (left.number.toInt() and (right.number.toInt() and 255)).toShort(), left.position)
}
} else if(left.type== DataType.UWORD) {
if(right.type in IntegerDatatypes) {
return NumericLiteralValue(DataType.UWORD, left.number.toInt() or right.number.toInt(), left.position)
return NumericLiteralValue(DataType.UWORD, left.number.toInt() and right.number.toInt(), left.position)
}
}
throw ExpressionError("cannot calculate $left & $right", left.position)
@ -144,15 +144,15 @@ class ConstExprEvaluator {
private fun power(left: NumericLiteralValue, right: NumericLiteralValue): NumericLiteralValue {
val error = "cannot calculate $left ** $right"
return when {
left.type in IntegerDatatypes -> when {
right.type in IntegerDatatypes -> NumericLiteralValue.optimalNumeric(left.number.toInt().toDouble().pow(right.number.toInt()), left.position)
right.type == DataType.FLOAT -> NumericLiteralValue(DataType.FLOAT, left.number.toInt().toDouble().pow(right.number.toDouble()), 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.type == DataType.FLOAT -> when {
right.type in IntegerDatatypes -> NumericLiteralValue(DataType.FLOAT, left.number.toDouble().pow(right.number.toInt()), left.position)
right.type == DataType.FLOAT -> NumericLiteralValue(DataType.FLOAT, left.number.toDouble().pow(right.number.toDouble()), 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)
@ -161,15 +161,15 @@ class ConstExprEvaluator {
private fun plus(left: NumericLiteralValue, right: NumericLiteralValue): NumericLiteralValue {
val error = "cannot add $left and $right"
return when {
left.type in IntegerDatatypes -> when {
right.type in IntegerDatatypes -> NumericLiteralValue.optimalNumeric(left.number.toInt() + right.number.toInt(), left.position)
right.type == DataType.FLOAT -> NumericLiteralValue(DataType.FLOAT, left.number.toInt() + right.number.toDouble(), left.position)
return when (left.type) {
in IntegerDatatypes -> when (right.type) {
in IntegerDatatypes -> NumericLiteralValue.optimalInteger(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.type == DataType.FLOAT -> when {
right.type in IntegerDatatypes -> NumericLiteralValue(DataType.FLOAT, left.number.toDouble() + right.number.toInt(), left.position)
right.type == DataType.FLOAT -> NumericLiteralValue(DataType.FLOAT, left.number.toDouble() + right.number.toDouble(), 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)
@ -178,15 +178,15 @@ class ConstExprEvaluator {
private fun minus(left: NumericLiteralValue, right: NumericLiteralValue): NumericLiteralValue {
val error = "cannot subtract $left and $right"
return when {
left.type in IntegerDatatypes -> when {
right.type in IntegerDatatypes -> NumericLiteralValue.optimalNumeric(left.number.toInt() - right.number.toInt(), left.position)
right.type == DataType.FLOAT -> NumericLiteralValue(DataType.FLOAT, left.number.toInt() - right.number.toDouble(), left.position)
return when (left.type) {
in IntegerDatatypes -> when (right.type) {
in IntegerDatatypes -> NumericLiteralValue.optimalInteger(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.type == DataType.FLOAT -> when {
right.type in IntegerDatatypes -> NumericLiteralValue(DataType.FLOAT, left.number.toDouble() - right.number.toInt(), left.position)
right.type == DataType.FLOAT -> NumericLiteralValue(DataType.FLOAT, left.number.toDouble() - right.number.toDouble(), 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)
@ -195,15 +195,15 @@ class ConstExprEvaluator {
private fun multiply(left: NumericLiteralValue, right: NumericLiteralValue): NumericLiteralValue {
val error = "cannot multiply ${left.type} and ${right.type}"
return when {
left.type in IntegerDatatypes -> when {
right.type in IntegerDatatypes -> NumericLiteralValue.optimalNumeric(left.number.toInt() * right.number.toInt(), left.position)
right.type == DataType.FLOAT -> NumericLiteralValue(DataType.FLOAT, left.number.toInt() * right.number.toDouble(), left.position)
return when (left.type) {
in IntegerDatatypes -> when (right.type) {
in IntegerDatatypes -> NumericLiteralValue.optimalInteger(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.type == DataType.FLOAT -> when {
right.type in IntegerDatatypes -> NumericLiteralValue(DataType.FLOAT, left.number.toDouble() * right.number.toInt(), left.position)
right.type == DataType.FLOAT -> NumericLiteralValue(DataType.FLOAT, left.number.toDouble() * right.number.toDouble(), 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)
@ -215,25 +215,25 @@ class ConstExprEvaluator {
private fun divide(left: NumericLiteralValue, right: NumericLiteralValue): NumericLiteralValue {
val error = "cannot divide $left by $right"
return when {
left.type in IntegerDatatypes -> when {
right.type in IntegerDatatypes -> {
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)
NumericLiteralValue.optimalInteger(result, left.position)
}
right.type == DataType.FLOAT -> {
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.type == DataType.FLOAT -> when {
right.type in IntegerDatatypes -> {
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.type == DataType.FLOAT -> {
DataType.FLOAT -> {
if(right.number.toDouble()==0.0) divideByZeroError(right.position)
NumericLiteralValue(DataType.FLOAT, left.number.toDouble() / right.number.toDouble(), left.position)
}
@ -245,24 +245,24 @@ class ConstExprEvaluator {
private fun remainder(left: NumericLiteralValue, right: NumericLiteralValue): NumericLiteralValue {
val error = "cannot compute remainder of $left by $right"
return when {
left.type in IntegerDatatypes -> when {
right.type in IntegerDatatypes -> {
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.type == DataType.FLOAT -> {
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.type == DataType.FLOAT -> when {
right.type in IntegerDatatypes -> {
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.type == DataType.FLOAT -> {
DataType.FLOAT -> {
if(right.number.toDouble()==0.0) divideByZeroError(right.position)
NumericLiteralValue(DataType.FLOAT, left.number.toDouble() % right.number.toDouble(), left.position)
}

693
compiler/src/prog8/optimizer/ConstantFolding.kt
View File

@ -1,693 +0,0 @@
package prog8.optimizer
import prog8.ast.IFunctionCall
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.ast.processing.IAstModifyingVisitor
import prog8.ast.processing.fixupArrayDatatype
import prog8.ast.statements.*
import prog8.compiler.target.c64.MachineDefinition.FLOAT_MAX_NEGATIVE
import prog8.compiler.target.c64.MachineDefinition.FLOAT_MAX_POSITIVE
import prog8.compiler.target.c64.codegen.AssemblyError
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) {
// check that we don't add the isSameAs error more than once
if(x.toString() !in reportedErrorMessages) {
reportedErrorMessages.add(x.toString())
errors.add(x)
}
}
override fun visit(decl: VarDecl): Statement {
// the initializer value can't refer to the variable itself (recursive definition)
// 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) {
if(decl.isArray){
if(decl.arraysize==null) {
// 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(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 NumericLiteralValue) {
decl.arraysize = ArrayIndex(size, decl.position)
optimizationsDone++
}
}
}
when(decl.datatype) {
DataType.FLOAT -> {
// vardecl: for scalar float vars, promote constant integer initialization values to floats
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 super.visit(decl)
}
}
in StringDatatypes -> {
// nothing to do for strings
}
DataType.STRUCT -> {
// struct defintions don't have anything else in them
}
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
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).typeOrElse(DataType.UBYTE)
if(eltType in ByteDatatypes) {
decl.value = ArrayLiteralValue(decl.datatype,
constRange.map { NumericLiteralValue(eltType, it.toShort(), decl.value!!.position) }.toTypedArray(),
position = decl.value!!.position)
} else {
decl.value = ArrayLiteralValue(decl.datatype,
constRange.map { NumericLiteralValue(eltType, it, decl.value!!.position) }.toTypedArray(),
position = decl.value!!.position)
}
decl.value!!.linkParents(decl)
optimizationsDone++
return super.visit(decl)
}
}
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 (rangeExpr==null && numericLv!=null) {
// arraysize initializer is empty or a single int, and we know the size; create the arraysize.
val fillvalue = numericLv.number.toInt()
when(decl.datatype){
DataType.ARRAY_UB -> {
if(fillvalue !in 0..255)
errors.add(ExpressionError("ubyte value overflow", numericLv.position))
}
DataType.ARRAY_B -> {
if(fillvalue !in -128..127)
errors.add(ExpressionError("byte value overflow", numericLv.position))
}
DataType.ARRAY_UW -> {
if(fillvalue !in 0..65535)
errors.add(ExpressionError("uword value overflow", numericLv.position))
}
DataType.ARRAY_W -> {
if(fillvalue !in -32768..32767)
errors.add(ExpressionError("word value overflow", numericLv.position))
}
else -> {}
}
// 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(decl.datatype, array, position = numericLv.position)
refValue.addToHeap(program.heap)
decl.value = refValue
refValue.parent=decl
optimizationsDone++
return super.visit(decl)
}
}
DataType.ARRAY_F -> {
val size = decl.arraysize?.size() ?: return decl
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 < FLOAT_MAX_NEGATIVE || fillvalue > FLOAT_MAX_POSITIVE)
errors.add(ExpressionError("float value overflow", litval.position))
else {
// 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(DataType.ARRAY_F, array, position = litval.position)
refValue.addToHeap(program.heap)
decl.value = refValue
refValue.parent=decl
optimizationsDone++
return super.visit(decl)
}
}
}
else -> {
// nothing to do for this type
}
}
}
return super.visit(decl)
}
/**
* replace identifiers that refer to const value, with the value itself (if it's a simple type)
*/
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 when {
cval.type in NumericDatatypes -> {
val copy = NumericLiteralValue(cval.type, cval.number, identifier.position)
copy.parent = identifier.parent
copy
}
cval.type in PassByReferenceDatatypes -> throw AssemblyError("pass-by-reference type should not be considered a constant")
else -> identifier
}
} catch (ax: AstException) {
addError(ax)
identifier
}
}
override fun visit(functionCall: FunctionCall): Expression {
super.visit(functionCall)
typeCastConstArguments(functionCall)
return try {
functionCall.constValue(program) ?: functionCall
} catch (ax: AstException) {
addError(ax)
functionCall
}
}
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.arglist.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.arglist[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)) {
val expectedDt = arg.second.type
val argConst = arg.first.value.constValue(program)
if(argConst!=null && argConst.type!=expectedDt) {
val convertedValue = argConst.cast(expectedDt)
functionCall.arglist[arg.first.index] = convertedValue
optimizationsDone++
}
}
}
}
override fun visit(memread: DirectMemoryRead): Expression {
// @( &thing ) --> thing
val addrOf = memread.addressExpression as? AddressOf
if(addrOf!=null)
return super.visit(addrOf.identifier)
return super.visit(memread)
}
/**
* Try to accept a unary prefix expression.
* 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): Expression {
return try {
val prefixExpr=super.visit(expr)
if(prefixExpr !is PrefixExpression)
return prefixExpr
val subexpr = prefixExpr.expression
if (subexpr is NumericLiteralValue) {
// accept prefixed literal values (such as -3, not true)
return when {
prefixExpr.operator == "+" -> subexpr
prefixExpr.operator == "-" -> when {
subexpr.type in IntegerDatatypes -> {
optimizationsDone++
NumericLiteralValue.optimalNumeric(-subexpr.number.toInt(), subexpr.position)
}
subexpr.type == DataType.FLOAT -> {
optimizationsDone++
NumericLiteralValue(DataType.FLOAT, -subexpr.number.toDouble(), subexpr.position)
}
else -> throw ExpressionError("can only take negative of int or float", subexpr.position)
}
prefixExpr.operator == "~" -> when {
subexpr.type in IntegerDatatypes -> {
optimizationsDone++
NumericLiteralValue.optimalNumeric(subexpr.number.toInt().inv(), subexpr.position)
}
else -> throw ExpressionError("can only take bitwise inversion of int", subexpr.position)
}
prefixExpr.operator == "not" -> {
optimizationsDone++
NumericLiteralValue.fromBoolean(subexpr.number.toDouble() == 0.0, subexpr.position)
}
else -> throw ExpressionError(prefixExpr.operator, subexpr.position)
}
}
return prefixExpr
} catch (ax: AstException) {
addError(ax)
expr
}
}
/**
* Try to accept a binary expression.
* Compile-time constant sub expressions will be evaluated on the spot.
* For instance, "9 * (4 + 2)" will be optimized into the integer literal 54.
*
* More complex stuff: reordering to group constants:
* If one of our operands is a Constant,
* and the other operand is a Binary expression,
* and one of ITS operands is a Constant,
* and ITS other operand is NOT a Constant,
* ...it may be possible to rewrite the expression to group the two Constants together,
* to allow them to be const-folded away.
*
* examples include:
* (X / c1) * c2 -> X / (c2/c1)
* (X + c1) - c2 -> X + (c1-c2)
*/
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)
val subExpr: BinaryExpression? = when {
leftconst!=null -> expr.right as? BinaryExpression
rightconst!=null -> expr.left as? BinaryExpression
else -> null
}
if(subExpr!=null) {
val subleftconst = subExpr.left.constValue(program)
val subrightconst = subExpr.right.constValue(program)
if ((subleftconst != null && subrightconst == null) || (subleftconst==null && subrightconst!=null)) {
// try reordering.
return groupTwoConstsTogether(expr, subExpr,
leftconst != null, rightconst != null,
subleftconst != null, subrightconst != null)
}
}
// const fold when both operands are a const
return when {
leftconst != null && rightconst != null -> {
optimizationsDone++
val evaluator = ConstExprEvaluator()
evaluator.evaluate(leftconst, expr.operator, rightconst)
}
else -> expr
}
} catch (ax: AstException) {
addError(ax)
expr
}
}
private fun groupTwoConstsTogether(expr: BinaryExpression,
subExpr: BinaryExpression,
leftIsConst: Boolean,
rightIsConst: Boolean,
subleftIsConst: Boolean,
subrightIsConst: Boolean): Expression
{
// 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.
if(expr.operator=="+" || expr.operator=="*") {
if(leftIsConst) {
if(subleftIsConst)
expr.left = subExpr.right.also { subExpr.right = expr.left }
else
expr.left = subExpr.left.also { subExpr.left = expr.left }
} else {
if(subleftIsConst)
expr.right = subExpr.right.also {subExpr.right = expr.right }
else
expr.right = subExpr.left.also { subExpr.left = expr.right }
}
optimizationsDone++
return expr
}
// If - or /, we simetimes must reorder more, and flip operators (- -> +, / -> *)
if(expr.operator=="-" || expr.operator=="/") {
optimizationsDone++
if(leftIsConst) {
return if(subleftIsConst) {
val tmp = subExpr.right
subExpr.right = subExpr.left
subExpr.left = expr.left
expr.left = tmp
expr.operator = if(expr.operator=="-") "+" else "*"
expr
} else
BinaryExpression(
BinaryExpression(expr.left, if (expr.operator == "-") "+" else "*", subExpr.right, subExpr.position),
expr.operator, subExpr.left, expr.position)
} else {
return if(subleftIsConst) {
expr.right = subExpr.right.also { subExpr.right = expr.right }
expr
} else
BinaryExpression(
subExpr.left, expr.operator,
BinaryExpression(expr.right, if (expr.operator == "-") "+" else "*", subExpr.right, subExpr.position),
expr.position)
}
}
return expr
}
else
{
if(expr.operator=="/" && subExpr.operator=="*") {
optimizationsDone++
if(leftIsConst) {
return if(subleftIsConst) {
// C1/(C2*V) -> (C1/C2)/V
BinaryExpression(
BinaryExpression(expr.left, "/", subExpr.left, subExpr.position),
"/",
subExpr.right, expr.position)
} else {
// C1/(V*C2) -> (C1/C2)/V
BinaryExpression(
BinaryExpression(expr.left, "/", subExpr.right, subExpr.position),
"/",
subExpr.left, expr.position)
}
} else {
return if(subleftIsConst) {
// (C1*V)/C2 -> (C1/C2)*V
BinaryExpression(
BinaryExpression(subExpr.left, "/", expr.right, subExpr.position),
"*",
subExpr.right, expr.position)
} else {
// (V*C1)/C2 -> (C1/C2)*V
BinaryExpression(
BinaryExpression(subExpr.right, "/", expr.right, subExpr.position),
"*",
subExpr.left, expr.position)
}
}
}
else if(expr.operator=="*" && subExpr.operator=="/") {
optimizationsDone++
if(leftIsConst) {
return if(subleftIsConst) {
// C1*(C2/V) -> (C1*C2)/V
BinaryExpression(
BinaryExpression(expr.left, "*", subExpr.left, subExpr.position),
"/",
subExpr.right, expr.position)
} else {
// C1*(V/C2) -> (C1/C2)*V
BinaryExpression(
BinaryExpression(expr.left, "/", subExpr.right, subExpr.position),
"*",
subExpr.left, expr.position)
}
} else {
return if(subleftIsConst) {
// (C1/V)*C2 -> (C1*C2)/V
BinaryExpression(
BinaryExpression(subExpr.left, "*", expr.right, subExpr.position),
"/",
subExpr.right, expr.position)
} else {
// (V/C1)*C2 -> (C1/C2)*V
BinaryExpression(
BinaryExpression(expr.right, "/", subExpr.right, subExpr.position),
"*",
subExpr.left, expr.position)
}
}
}
else if(expr.operator=="+" && subExpr.operator=="-") {
optimizationsDone++
if(leftIsConst){
return if(subleftIsConst){
// c1+(c2-v) -> (c1+c2)-v
BinaryExpression(
BinaryExpression(expr.left, "+", subExpr.left, subExpr.position),
"-",
subExpr.right, expr.position)
} else {
// c1+(v-c2) -> v+(c1-c2)
BinaryExpression(
BinaryExpression(expr.left, "-", subExpr.right, subExpr.position),
"+",
subExpr.left, expr.position)
}
} else {
return if(subleftIsConst) {
// (c1-v)+c2 -> (c1+c2)-v
BinaryExpression(
BinaryExpression(subExpr.left, "+", expr.right, subExpr.position),
"-",
subExpr.right, expr.position)
} else {
// (v-c1)+c2 -> v+(c2-c1)
BinaryExpression(
BinaryExpression(expr.right, "-", subExpr.right, subExpr.position),
"+",
subExpr.left, expr.position)
}
}
}
else if(expr.operator=="-" && subExpr.operator=="+") {
optimizationsDone++
if(leftIsConst) {
return if(subleftIsConst) {
// c1-(c2+v) -> (c1-c2)-v
BinaryExpression(
BinaryExpression(expr.left, "-", subExpr.left, subExpr.position),
"-",
subExpr.right, expr.position)
} else {
// c1-(v+c2) -> (c1-c2)-v
BinaryExpression(
BinaryExpression(expr.left, "-", subExpr.right, subExpr.position),
"-",
subExpr.left, expr.position)
}
} else {
return if(subleftIsConst) {
// (c1+v)-c2 -> v+(c1-c2)
BinaryExpression(
BinaryExpression(subExpr.left, "-", expr.right, subExpr.position),
"+",
subExpr.right, expr.position)
} else {
// (v+c1)-c2 -> v+(c1-c2)
BinaryExpression(
BinaryExpression(subExpr.right, "-", expr.right, subExpr.position),
"+",
subExpr.left, expr.position)
}
}
}
return expr
}
}
override fun visit(forLoop: ForLoop): Statement {
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 = stepLiteral?.cast(targetDt) ?: range.step
return RangeExpr(newFrom, newTo, newStep, range.position)
}
// 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? NumericLiteralValue
val rangeTo = iterableRange.to as? NumericLiteralValue
if(rangeFrom==null || rangeTo==null) return resultStmt
val loopvar = resultStmt.loopVar?.targetVarDecl(program.namespace)
if(loopvar!=null) {
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)
}
}
DataType.BYTE -> {
if(rangeFrom.type!= DataType.BYTE) {
// attempt to translate the iterable into byte values
resultStmt.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)
}
}
DataType.WORD -> {
if(rangeFrom.type!= DataType.WORD) {
// attempt to translate the iterable into word values
resultStmt.iterable = adjustRangeDt(rangeFrom, loopvar.datatype, rangeTo, stepLiteral, iterableRange)
}
}
else -> throw FatalAstException("invalid loopvar datatype $loopvar")
}
}
return resultStmt
}
override fun visit(arrayLiteral: ArrayLiteralValue): Expression {
val array = super.visit(arrayLiteral)
if(array is ArrayLiteralValue) {
if(array.heapId==null)
array.addToHeap(program.heap)
val vardecl = array.parent as? VarDecl
return if (vardecl!=null) {
fixupArrayDatatype(array, vardecl, program)
} else {
// it's not an array associated with a vardecl, attempt to guess the data type from the array values
fixupArrayDatatype(array, program)
}
}
return array
}
override fun visit(assignment: Assignment): Statement {
super.visit(assignment)
val lv = assignment.value as? NumericLiteralValue
if(lv!=null) {
// see if we can promote/convert a literal value to the required datatype
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 = 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.number.toDouble()
if(floor(d)==d && d>=0 && d<=65535)
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.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.number.toDouble()
if(floor(d)==d && d >=0 && d<=255)
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.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.number.toDouble()
if(floor(d)==d && d>=0 && d<=127)
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 = 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.number.toDouble()
if(floor(d)==d && d>=-32768 && d<=32767)
assignment.value = NumericLiteralValue(DataType.BYTE, floor(d).toShort(), lv.position)
}
}
DataType.FLOAT -> {
assignment.value = NumericLiteralValue(DataType.FLOAT, lv.number.toDouble(), lv.position)
}
else -> {}
}
}
return assignment
}
}

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compiler/src/prog8/optimizer/ConstantFoldingOptimizer.kt Normal file
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package prog8.optimizer
import prog8.ast.Node
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.ast.processing.AstWalker
import prog8.ast.processing.IAstModification
import prog8.ast.statements.*
import prog8.compiler.target.CompilationTarget
// First thing to do is replace all constant identifiers with their actual value,
// and the array var initializer values and sizes.
// This is needed because further constant optimizations depend on those.
internal class ConstantIdentifierReplacer(private val program: Program, private val errors: ErrorReporter) : AstWalker() {
private val noModifications = emptyList<IAstModification>()
override fun after(identifier: IdentifierReference, parent: Node): Iterable<IAstModification> {
// replace identifiers that refer to const value, with the value itself
// if it's a simple type and if it's not a left hand side variable
if(identifier.parent is AssignTarget)
return noModifications
var forloop = identifier.parent as? ForLoop
if(forloop==null)
forloop = identifier.parent.parent as? ForLoop
if(forloop!=null && identifier===forloop.loopVar)
return noModifications
val cval = identifier.constValue(program) ?: return noModifications
return when (cval.type) {
in NumericDatatypes -> listOf(IAstModification.ReplaceNode(identifier, NumericLiteralValue(cval.type, cval.number, identifier.position), identifier.parent))
in PassByReferenceDatatypes -> throw FatalAstException("pass-by-reference type should not be considered a constant")
else -> noModifications
}
}
override fun before(decl: VarDecl, parent: Node): Iterable<IAstModification> {
// the initializer value can't refer to the variable itself (recursive definition)
// TODO: use call graph for this?
if(decl.value?.referencesIdentifiers(decl.name) == true || decl.arraysize?.index?.referencesIdentifiers(decl.name) == true) {
errors.err("recursive var declaration", decl.position)
return noModifications
}
if(decl.type==VarDeclType.CONST || decl.type==VarDeclType.VAR) {
if(decl.isArray){
if(decl.arraysize==null) {
// 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) {
return listOf(IAstModification.SetExpression(
{ decl.arraysize = ArrayIndex(it, decl.position) },
NumericLiteralValue.optimalInteger(arrayval.value.size, decl.position),
decl
))
}
}
else if(decl.arraysize?.constIndex()==null) {
val size = decl.arraysize!!.index.constValue(program)
if(size!=null) {
return listOf(IAstModification.SetExpression(
{ decl.arraysize = ArrayIndex(it, decl.position) },
size, decl
))
}
}
}
when(decl.datatype) {
DataType.FLOAT -> {
// vardecl: for scalar float vars, promote constant integer initialization values to floats
val litval = decl.value as? NumericLiteralValue
if (litval!=null && litval.type in IntegerDatatypes) {
val newValue = NumericLiteralValue(DataType.FLOAT, litval.number.toDouble(), litval.position)
return listOf(IAstModification.ReplaceNode(decl.value!!, newValue, 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
val declArraySize = decl.arraysize?.constIndex()
if(declArraySize!=null && declArraySize!=rangeExpr.size())
errors.err("range expression size doesn't match declared array size", decl.value?.position!!)
val constRange = rangeExpr.toConstantIntegerRange()
if(constRange!=null) {
val eltType = rangeExpr.inferType(program).typeOrElse(DataType.UBYTE)
val newValue = if(eltType in ByteDatatypes) {
ArrayLiteralValue(InferredTypes.InferredType.known(decl.datatype),
constRange.map { NumericLiteralValue(eltType, it.toShort(), decl.value!!.position) }.toTypedArray(),
position = decl.value!!.position)
} else {
ArrayLiteralValue(InferredTypes.InferredType.known(decl.datatype),
constRange.map { NumericLiteralValue(eltType, it, decl.value!!.position) }.toTypedArray(),
position = decl.value!!.position)
}
return listOf(IAstModification.ReplaceNode(decl.value!!, newValue, decl))
}
}
if(numericLv!=null && numericLv.type==DataType.FLOAT)
errors.err("arraysize requires only integers here", numericLv.position)
val size = decl.arraysize?.constIndex() ?: return noModifications
if (rangeExpr==null && numericLv!=null) {
// arraysize initializer is empty or a single int, and we know the size; create the arraysize.
val fillvalue = numericLv.number.toInt()
when(decl.datatype){
DataType.ARRAY_UB -> {
if(fillvalue !in 0..255)
errors.err("ubyte value overflow", numericLv.position)
}
DataType.ARRAY_B -> {
if(fillvalue !in -128..127)
errors.err("byte value overflow", numericLv.position)
}
DataType.ARRAY_UW -> {
if(fillvalue !in 0..65535)
errors.err("uword value overflow", numericLv.position)
}
DataType.ARRAY_W -> {
if(fillvalue !in -32768..32767)
errors.err("word value overflow", numericLv.position)
}
else -> {}
}
// create the array itself, filled with the fillvalue.
val array = Array(size) {fillvalue}.map { NumericLiteralValue(ArrayElementTypes.getValue(decl.datatype), it, numericLv.position) }.toTypedArray<Expression>()
val refValue = ArrayLiteralValue(InferredTypes.InferredType.known(decl.datatype), array, position = numericLv.position)
return listOf(IAstModification.ReplaceNode(decl.value!!, refValue, decl))
}
}
DataType.ARRAY_F -> {
val size = decl.arraysize?.constIndex() ?: return noModifications
val litval = decl.value as? NumericLiteralValue
val rangeExpr = decl.value as? RangeExpr
if(rangeExpr!=null) {
// convert the initializer range expression to an actual array of floats
val declArraySize = decl.arraysize?.constIndex()
if(declArraySize!=null && declArraySize!=rangeExpr.size())
errors.err("range expression size doesn't match declared array size", decl.value?.position!!)
val constRange = rangeExpr.toConstantIntegerRange()
if(constRange!=null) {
val newValue = ArrayLiteralValue(InferredTypes.InferredType.known(DataType.ARRAY_F),
constRange.map { NumericLiteralValue(DataType.FLOAT, it.toDouble(), decl.value!!.position) }.toTypedArray(),
position = decl.value!!.position)
return listOf(IAstModification.ReplaceNode(decl.value!!, newValue, decl))
}
}
if(rangeExpr==null && litval!=null) {
// 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.err("float value overflow", litval.position)
else {
// create the array itself, filled with the fillvalue.
val array = Array(size) {fillvalue}.map { NumericLiteralValue(DataType.FLOAT, it, litval.position) }.toTypedArray<Expression>()
val refValue = ArrayLiteralValue(InferredTypes.InferredType.known(DataType.ARRAY_F), array, position = litval.position)
return listOf(IAstModification.ReplaceNode(decl.value!!, refValue, decl))
}
}
}
else -> {
// nothing to do for this type
// this includes strings and structs
}
}
}
val declValue = decl.value
if(declValue!=null && decl.type==VarDeclType.VAR
&& declValue is NumericLiteralValue && !declValue.inferType(program).istype(decl.datatype)) {
// cast the numeric literal to the appropriate datatype of the variable
val cast = declValue.cast(decl.datatype)
if(cast.isValid)
return listOf(IAstModification.ReplaceNode(decl.value!!, cast.valueOrZero(), decl))
}
return noModifications
}
}
internal class ConstantFoldingOptimizer(private val program: Program) : AstWalker() {
private val noModifications = emptyList<IAstModification>()
override fun before(memread: DirectMemoryRead, parent: Node): Iterable<IAstModification> {
// @( &thing ) --> thing
val addrOf = memread.addressExpression as? AddressOf
return if(addrOf!=null)
listOf(IAstModification.ReplaceNode(memread, addrOf.identifier, parent))
else
noModifications
}
override fun after(expr: PrefixExpression, parent: Node): Iterable<IAstModification> {
// Try to turn a unary prefix expression into a single constant value.
// 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
val subexpr = expr.expression
if (subexpr is NumericLiteralValue) {
// accept prefixed literal values (such as -3, not true)
return when (expr.operator) {
"+" -> listOf(IAstModification.ReplaceNode(expr, subexpr, parent))
"-" -> when (subexpr.type) {
in IntegerDatatypes -> {
listOf(IAstModification.ReplaceNode(expr,
NumericLiteralValue.optimalInteger(-subexpr.number.toInt(), subexpr.position),
parent))
}
DataType.FLOAT -> {
listOf(IAstModification.ReplaceNode(expr,
NumericLiteralValue(DataType.FLOAT, -subexpr.number.toDouble(), subexpr.position),
parent))
}
else -> throw ExpressionError("can only take negative of int or float", subexpr.position)
}
"~" -> when (subexpr.type) {
in IntegerDatatypes -> {
listOf(IAstModification.ReplaceNode(expr,
NumericLiteralValue.optimalInteger(subexpr.number.toInt().inv(), subexpr.position),
parent))
}
else -> throw ExpressionError("can only take bitwise inversion of int", subexpr.position)
}
"not" -> {
listOf(IAstModification.ReplaceNode(expr,
NumericLiteralValue.fromBoolean(subexpr.number.toDouble() == 0.0, subexpr.position),
parent))
}
else -> throw ExpressionError(expr.operator, subexpr.position)
}
}
return noModifications
}
/**
* Try to constfold a binary expression.
* Compile-time constant sub expressions will be evaluated on the spot.
* For instance, "9 * (4 + 2)" will be optimized into the integer literal 54.
*
* More complex stuff: reordering to group constants:
* If one of our operands is a Constant,
* and the other operand is a Binary expression,
* and one of ITS operands is a Constant,
* and ITS other operand is NOT a Constant,
* ...it may be possible to rewrite the expression to group the two Constants together,
* to allow them to be const-folded away.
*
* examples include:
* (X / c1) * c2 -> X / (c2/c1)
* (X + c1) - c2 -> X + (c1-c2)
*/
override fun after(expr: BinaryExpression, parent: Node): Iterable<IAstModification> {
val leftconst = expr.left.constValue(program)
val rightconst = expr.right.constValue(program)
val subExpr: BinaryExpression? = when {
leftconst!=null -> expr.right as? BinaryExpression
rightconst!=null -> expr.left as? BinaryExpression
else -> null
}
if(subExpr!=null) {
val subleftconst = subExpr.left.constValue(program)
val subrightconst = subExpr.right.constValue(program)
if ((subleftconst != null && subrightconst == null) || (subleftconst==null && subrightconst!=null)) {
// try reordering.
val change = groupTwoConstsTogether(expr, subExpr,
leftconst != null, rightconst != null,
subleftconst != null, subrightconst != null)
return change?.let { listOf(it) } ?: noModifications
}
}
// const fold when both operands are a const
if(leftconst != null && rightconst != null) {
val evaluator = ConstExprEvaluator()
val result = evaluator.evaluate(leftconst, expr.operator, rightconst)
return listOf(IAstModification.ReplaceNode(expr, result, parent))
}
return noModifications
}
override fun after(array: ArrayLiteralValue, parent: Node): Iterable<IAstModification> {
// 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.
if(array.type.isKnown)
return noModifications
// if the array literalvalue is inside an array vardecl, take the type from that
// otherwise infer it from the elements of the array
val vardeclType = (array.parent as? VarDecl)?.datatype
if(vardeclType!=null) {
val newArray = array.cast(vardeclType)
if (newArray != null && newArray != array)
return listOf(IAstModification.ReplaceNode(array, newArray, parent))
} else {
val arrayDt = array.guessDatatype(program)
if (arrayDt.isKnown) {
val newArray = array.cast(arrayDt.typeOrElse(DataType.STRUCT))
if (newArray != null && newArray != array)
return listOf(IAstModification.ReplaceNode(array, newArray, parent))
}
}
return noModifications
}
override fun after(functionCall: FunctionCall, parent: Node): Iterable<IAstModification> {
// the args of a fuction are constfolded via recursion already.
val constvalue = functionCall.constValue(program)
return if(constvalue!=null)
listOf(IAstModification.ReplaceNode(functionCall, constvalue, parent))
else
noModifications
}
override fun after(forLoop: ForLoop, parent: Node): Iterable<IAstModification> {
fun adjustRangeDt(rangeFrom: NumericLiteralValue, targetDt: DataType, rangeTo: NumericLiteralValue, stepLiteral: NumericLiteralValue?, range: RangeExpr): RangeExpr? {
val fromCast = rangeFrom.cast(targetDt)
val toCast = rangeTo.cast(targetDt)
if(!fromCast.isValid || !toCast.isValid)
return null
val newStep =
if(stepLiteral!=null) {
val stepCast = stepLiteral.cast(targetDt)
if(stepCast.isValid)
stepCast.valueOrZero()
else
range.step
} else {
range.step
}
return RangeExpr(fromCast.valueOrZero(), toCast.valueOrZero(), newStep, range.position)
}
// adjust the datatype of a range expression in for loops to the loop variable.
val iterableRange = forLoop.iterable as? RangeExpr ?: return noModifications
val rangeFrom = iterableRange.from as? NumericLiteralValue
val rangeTo = iterableRange.to as? NumericLiteralValue
if(rangeFrom==null || rangeTo==null) return noModifications
val loopvar = forLoop.loopVar.targetVarDecl(program.namespace)!!
val stepLiteral = iterableRange.step as? NumericLiteralValue
when(loopvar.datatype) {
DataType.UBYTE -> {
if(rangeFrom.type!= DataType.UBYTE) {
// attempt to translate the iterable into ubyte values
val newIter = adjustRangeDt(rangeFrom, loopvar.datatype, rangeTo, stepLiteral, iterableRange)
if(newIter!=null)
return listOf(IAstModification.ReplaceNode(forLoop.iterable, newIter, forLoop))
}
}
DataType.BYTE -> {
if(rangeFrom.type!= DataType.BYTE) {
// attempt to translate the iterable into byte values
val newIter = adjustRangeDt(rangeFrom, loopvar.datatype, rangeTo, stepLiteral, iterableRange)
if(newIter!=null)
return listOf(IAstModification.ReplaceNode(forLoop.iterable, newIter, forLoop))
}
}
DataType.UWORD -> {
if(rangeFrom.type!= DataType.UWORD) {
// attempt to translate the iterable into uword values
val newIter = adjustRangeDt(rangeFrom, loopvar.datatype, rangeTo, stepLiteral, iterableRange)
if(newIter!=null)
return listOf(IAstModification.ReplaceNode(forLoop.iterable, newIter, forLoop))
}
}
DataType.WORD -> {
if(rangeFrom.type!= DataType.WORD) {
// attempt to translate the iterable into word values
val newIter = adjustRangeDt(rangeFrom, loopvar.datatype, rangeTo, stepLiteral, iterableRange)
if(newIter!=null)
return listOf(IAstModification.ReplaceNode(forLoop.iterable, newIter, forLoop))
}
}
else -> throw FatalAstException("invalid loopvar datatype $loopvar")
}
return noModifications
}
override fun after(decl: VarDecl, parent: Node): Iterable<IAstModification> {
val numval = decl.value as? NumericLiteralValue
if(decl.type== VarDeclType.CONST && numval!=null) {
val valueDt = numval.inferType(program)
if(!valueDt.istype(decl.datatype)) {
val cast = numval.cast(decl.datatype)
if(cast.isValid)
return listOf(IAstModification.ReplaceNode(numval, cast.valueOrZero(), decl))
}
}
return noModifications
}
private class ShuffleOperands(val expr: BinaryExpression,
val exprOperator: String?,
val subExpr: BinaryExpression,
val newExprLeft: Expression?,
val newExprRight: Expression?,
val newSubexprLeft: Expression?,
val newSubexprRight: Expression?
): IAstModification {
override fun perform() {
if(exprOperator!=null) expr.operator = exprOperator
if(newExprLeft!=null) expr.left = newExprLeft
if(newExprRight!=null) expr.right = newExprRight
if(newSubexprLeft!=null) subExpr.left = newSubexprLeft
if(newSubexprRight!=null) subExpr.right = newSubexprRight
}
}
private fun groupTwoConstsTogether(expr: BinaryExpression,
subExpr: BinaryExpression,
leftIsConst: Boolean,
rightIsConst: Boolean,
subleftIsConst: Boolean,
subrightIsConst: Boolean): IAstModification?
{
// todo: this implements only a small set of possible reorderings at this time
if(expr.operator==subExpr.operator) {
// both operators are the same.
// If associative, we can simply shuffle the const operands around to optimize.
if(expr.operator in associativeOperators) {
return if(leftIsConst) {
if(subleftIsConst)
ShuffleOperands(expr, null, subExpr, subExpr.right, null, null, expr.left)
else
ShuffleOperands(expr, null, subExpr, subExpr.left, null, expr.left, null)
} else {
if(subleftIsConst)
ShuffleOperands(expr, null, subExpr, null, subExpr.right, null, expr.right)
else
ShuffleOperands(expr, null, subExpr, null, subExpr.left, expr.right, null)
}
}
// If - or /, we simetimes must reorder more, and flip operators (- -> +, / -> *)
if(expr.operator=="-" || expr.operator=="/") {
if(leftIsConst) {
return if (subleftIsConst) {
ShuffleOperands(expr, if (expr.operator == "-") "+" else "*", subExpr, subExpr.right, null, expr.left, subExpr.left)
} else {
IAstModification.ReplaceNode(expr,
BinaryExpression(
BinaryExpression(expr.left, if (expr.operator == "-") "+" else "*", subExpr.right, subExpr.position),
expr.operator, subExpr.left, expr.position),
expr.parent)
}
} else {
return if(subleftIsConst) {
return ShuffleOperands(expr, null, subExpr, null, subExpr.right, null, expr.right)
} else {
IAstModification.ReplaceNode(expr,
BinaryExpression(
subExpr.left, expr.operator,
BinaryExpression(expr.right, if (expr.operator == "-") "+" else "*", subExpr.right, subExpr.position),
expr.position),
expr.parent)
}
}
}
return null
}
else
{
if(expr.operator=="/" && subExpr.operator=="*") {
if(leftIsConst) {
val change = if(subleftIsConst) {
// C1/(C2*V) -> (C1/C2)/V
BinaryExpression(
BinaryExpression(expr.left, "/", subExpr.left, subExpr.position),
"/",
subExpr.right, expr.position)
} else {
// C1/(V*C2) -> (C1/C2)/V
BinaryExpression(
BinaryExpression(expr.left, "/", subExpr.right, subExpr.position),
"/",
subExpr.left, expr.position)
}
return IAstModification.ReplaceNode(expr, change, expr.parent)
} else {
val change = if(subleftIsConst) {
// (C1*V)/C2 -> (C1/C2)*V
BinaryExpression(
BinaryExpression(subExpr.left, "/", expr.right, subExpr.position),
"*",
subExpr.right, expr.position)
} else {
// (V*C1)/C2 -> (C1/C2)*V
BinaryExpression(
BinaryExpression(subExpr.right, "/", expr.right, subExpr.position),
"*",
subExpr.left, expr.position)
}
return IAstModification.ReplaceNode(expr, change, expr.parent)
}
}
else if(expr.operator=="*" && subExpr.operator=="/") {
if(leftIsConst) {
val change = if(subleftIsConst) {
// C1*(C2/V) -> (C1*C2)/V
BinaryExpression(
BinaryExpression(expr.left, "*", subExpr.left, subExpr.position),
"/",
subExpr.right, expr.position)
} else {
// C1*(V/C2) -> (C1/C2)*V
BinaryExpression(
BinaryExpression(expr.left, "/", subExpr.right, subExpr.position),
"*",
subExpr.left, expr.position)
}
return IAstModification.ReplaceNode(expr, change, expr.parent)
} else {
val change = if(subleftIsConst) {
// (C1/V)*C2 -> (C1*C2)/V
BinaryExpression(
BinaryExpression(subExpr.left, "*", expr.right, subExpr.position),
"/",
subExpr.right, expr.position)
} else {
// (V/C1)*C2 -> (C1/C2)*V
BinaryExpression(
BinaryExpression(expr.right, "/", subExpr.right, subExpr.position),
"*",
subExpr.left, expr.position)
}
return IAstModification.ReplaceNode(expr, change, expr.parent)
}
}
else if(expr.operator=="+" && subExpr.operator=="-") {
if(leftIsConst){
val change = if(subleftIsConst){
// c1+(c2-v) -> (c1+c2)-v
BinaryExpression(
BinaryExpression(expr.left, "+", subExpr.left, subExpr.position),
"-",
subExpr.right, expr.position)
} else {
// c1+(v-c2) -> v+(c1-c2)
BinaryExpression(
BinaryExpression(expr.left, "-", subExpr.right, subExpr.position),
"+",
subExpr.left, expr.position)
}
return IAstModification.ReplaceNode(expr, change, expr.parent)
} else {
val change = if(subleftIsConst) {
// (c1-v)+c2 -> (c1+c2)-v
BinaryExpression(
BinaryExpression(subExpr.left, "+", expr.right, subExpr.position),
"-",
subExpr.right, expr.position)
} else {
// (v-c1)+c2 -> v+(c2-c1)
BinaryExpression(
BinaryExpression(expr.right, "-", subExpr.right, subExpr.position),
"+",
subExpr.left, expr.position)
}
return IAstModification.ReplaceNode(expr, change, expr.parent)
}
}
else if(expr.operator=="-" && subExpr.operator=="+") {
if(leftIsConst) {
val change = if(subleftIsConst) {
// c1-(c2+v) -> (c1-c2)-v
BinaryExpression(
BinaryExpression(expr.left, "-", subExpr.left, subExpr.position),
"-",
subExpr.right, expr.position)
} else {
// c1-(v+c2) -> (c1-c2)-v
BinaryExpression(
BinaryExpression(expr.left, "-", subExpr.right, subExpr.position),
"-",
subExpr.left, expr.position)
}
return IAstModification.ReplaceNode(expr, change, expr.parent)
} else {
val change = if(subleftIsConst) {
// (c1+v)-c2 -> v+(c1-c2)
BinaryExpression(
BinaryExpression(subExpr.left, "-", expr.right, subExpr.position),
"+",
subExpr.right, expr.position)
} else {
// (v+c1)-c2 -> v+(c1-c2)
BinaryExpression(
BinaryExpression(subExpr.right, "-", expr.right, subExpr.position),
"+",
subExpr.left, expr.position)
}
return IAstModification.ReplaceNode(expr, change, expr.parent)
}
}
return null
}
}
}

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