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compare: Apple-2-SW:v7.8
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444 Commits
version7.1 ... v7.8

Author SHA1 Message Date
Irmen de Jong
a3a6812608 version 7.8 2022-02-12 17:40:32 +01:00
Irmen de Jong
2725c4ad4d slight tweaks to zp and allocator 2022-02-12 00:15:52 +01:00
Irmen de Jong
c8cd6e9460 removed old @"screencodes" string encoding syntax (use sc:"hello" instead) 2022-02-11 22:07:14 +01:00
Irmen de Jong
0cd27d6129 fix empty lines in subroutine ast printing 2022-02-11 21:44:38 +01:00
Irmen de Jong
b47fc1c020 renames of some Ast node classes 2022-02-11 00:34:36 +01:00
Irmen de Jong
de6ef7ef5e doc 2022-02-11 00:16:39 +01:00
Irmen de Jong
f95fe8f1da note about removing VarDecls 2022-02-10 23:20:19 +01:00
Irmen de Jong
bd0dee5db5 cleanup 2022-02-10 22:22:50 +01:00
Irmen de Jong
c13b7fd883 report free/occupied Zeropage space at end of compilation 2022-02-10 21:59:44 +01:00
Irmen de Jong
f7e74b3088 naming 2022-02-10 03:18:56 +01:00
Irmen de Jong
343f01d5e1 re-enabled unused variable removal from library modules (+fixed some @shared vars in libraries) 2022-02-10 03:10:47 +01:00
Irmen de Jong
08bacdd090 temp vars are now dynamically added to AST as needed 2022-02-10 02:52:47 +01:00
Irmen de Jong
41b1c80492 label name from memory() no longer interned as string var 2022-02-10 00:45:20 +01:00
Irmen de Jong
e5d7316e5d streamlining non-zpvars asmgen using new mechanism 2022-02-10 00:09:09 +01:00
Irmen de Jong
b043c3a6da streamlining vars asmgen using new mechanism 2022-02-09 21:58:25 +01:00
Irmen de Jong
98b2855b9c cleanups 2022-02-09 16:35:52 +01:00
Irmen de Jong
f3c52c409f variable zp allocation now only done in the allocator 2022-02-08 23:44:21 +01:00
Irmen de Jong
1307bdc612 more cleanups to the allocator 2022-02-08 22:46:49 +01:00
Irmen de Jong
8c2e6971fc start using vars instead of callgraph (2) 2022-02-08 21:09:00 +01:00
Irmen de Jong
1903990f30 start using vars instead of callgraph 2022-02-08 20:40:10 +01:00
Irmen de Jong
7d67005709 more rewrite variable allocation 2022-02-08 20:40:10 +01:00
Irmen de Jong
9acc2f92d1 start to rewrite variable allocation 2022-02-08 20:40:10 +01:00
Irmen de Jong
72dfb0bda3 fix: undefined sys.memcopy when initializing array on cx16 2022-02-08 20:29:47 +01:00
Irmen de Jong
1635612430 tiny tweak in asm optimizer 2022-02-08 02:19:50 +01:00
Irmen de Jong
abda837d2f split program structure codegen out of AsmGen into separate class ProgramGen 2022-02-07 00:12:25 +01:00
Irmen de Jong
101fb0b8aa some naming changes and cleanups 2022-02-06 23:14:44 +01:00
Irmen de Jong
10de7dc1f9 fixed the concurrent modification issue on zeropage when running unit tests in parallel, by not having machine targets be static objects 2022-02-06 21:29:06 +01:00
Irmen de Jong
d2309b8114 introducing IVariableAllocation (WIP) 2022-02-06 18:57:23 +01:00
Irmen de Jong
6bdd81623f cleaning up AsmGen interface 2022-02-06 17:07:03 +01:00
Irmen de Jong
f538c9f0c3 remove bogus double var decl check 2022-02-06 14:04:54 +01:00
Irmen de Jong
8ae3bad6f7 fix rts in empty asmsub 2022-02-06 05:05:58 +01:00
Irmen de Jong
77de99b383 rts-check for non-inlined subroutines + var init adjustment when noreinit, moved out of codegen 2022-02-06 04:03:03 +01:00
Irmen de Jong
312949f336 added experimental codegen backend option 2022-02-05 21:42:03 +01:00
Irmen de Jong
1ab635bd7e small tweak of parse messages 2022-02-05 14:02:24 +01:00
Irmen de Jong
b35abd548c less noisy output about what module files are being imported. 2022-02-05 04:25:34 +01:00
Irmen de Jong
30e1c3307c simplify SourceCode: just read the full text immediately. Also optimized imports. 2022-02-05 03:50:54 +01:00
Irmen de Jong
08e052380a comments 2022-02-05 03:14:26 +01:00
Irmen de Jong
0e824c35cc Merge pull request #73 from akumanatt/master 
Codegen and runtime library optimizations
 2022-02-05 02:21:53 +01:00
Irmen de Jong
548374ac2d fix: do proper sign exension when multiplying signed word and byte vars 2022-02-05 01:52:13 +01:00
Natt Akuma
9ad79fefc9 Merge branch 'master' of https://github.com/irmen/prog8 2022-02-04 22:55:41 +07:00
Natt Akuma
49d37c016e Optimize strcmp_mem 2022-02-04 22:07:03 +07:00
Natt Akuma
7c70c79a84 Optimize in-place word subtraction and negation 2022-02-04 21:21:06 +07:00
Irmen de Jong
6916b8bff7 remove redundant properties 2022-02-03 23:59:24 +01:00
Natt Akuma
73dfb5f443 Optimize sign extension to AY 2022-02-04 00:59:44 +07:00
Irmen de Jong
69b9dfa468 fix invalid recursion warning for code referencing subroutine but not via a call 2022-02-01 23:09:52 +01:00
Irmen de Jong
ab61b8ba0a doc ref 2022-02-01 21:47:53 +01:00
Irmen de Jong
5c8c64242f callgraph: nameInAssemblyCode searches smarter (for unused()) 2022-02-01 00:33:05 +01:00
Irmen de Jong
ddf96943f0 remove Nop ast node. 2022-01-31 22:36:10 +01:00
Irmen de Jong
e773be2f58 remove no longer needed asmSymbol scoping prefixing, now asmSymbolName are identical to asmVarName 2022-01-31 01:47:22 +01:00
Irmen de Jong
f965804e6d fix invalid optimization of returning a parameter variable in a subroutine 2022-01-28 16:44:42 +01:00
Irmen de Jong
ec078eba72 optimize w=msb(w) => w>>=8, w=lsb(w) ==> w&=$00ff 2022-01-28 16:11:52 +01:00
Irmen de Jong
1815cb1bc3 fixed bug in assembly optimizer removing too many instructions 2022-01-28 15:19:08 +01:00
Irmen de Jong
7b3cd71085 fixed improper optimization of word<<8 and word>>8 2022-01-28 13:54:06 +01:00
Irmen de Jong
06128b5d07 optimize word&=$ff00 and word&=$00ff 2022-01-28 13:40:28 +01:00
Irmen de Jong
990c8e1f18 split out 6502 codegen module from various compilertargets module. 2022-01-28 00:32:09 +01:00
Irmen de Jong
a170506356 simplify IdentifierReference equality check back to default (name+pos) 2022-01-27 23:32:55 +01:00
Irmen de Jong
5ecf2a3357 enable more optimizations for typecasted assignments. Fixed missing codegen for assigning bytes to words in certain cases. 2022-01-27 18:05:25 +01:00
Irmen de Jong
fa48746ba9 increase internal buffer for diskio.list_files to be able to list larger directories 2022-01-26 03:17:33 +01:00
Irmen de Jong
e2b8c069d7 check for missing '&' in string + value expressions (can't just add a value to a string) 2022-01-24 23:30:40 +01:00
Irmen de Jong
14407bd1aa fix memory() existing check typo 2022-01-24 23:21:31 +01:00
Irmen de Jong
08db72903c for long containment checks use a subroutine instead of huge cmp-table 2022-01-24 22:40:22 +01:00
Irmen de Jong
46f9fab140 library API change: string.find now returns index of character + carry bit status (instead of substring address) 2022-01-24 21:37:04 +01:00
Irmen de Jong
b7d06f2c0a API change: added alignment parameter to memory() function 2022-01-24 18:58:57 +01:00
Irmen de Jong
118196a0bf library API change: moved cx16.vload() to cx16diskio module 2022-01-24 18:31:18 +01:00
Irmen de Jong
586ce1fc80 tweak return's use of intermediate variable 2022-01-24 01:10:04 +01:00
Irmen de Jong
adb979df38 tweak comment 2022-01-23 22:34:05 +01:00
Irmen de Jong
3401cb5b4a fixed compiler recursion crash when returning certain typecasted value 2022-01-23 19:13:20 +01:00
Irmen de Jong
ebf1f12e97 inferred type for len() is now more precise 2022-01-23 17:24:39 +01:00
Irmen de Jong
5766208207 fix compiler crash when initializing an array var with another array var 2022-01-23 14:23:34 +01:00
Irmen de Jong
4bf4771f08 fix @requirezp in astToSource. Fix sometimes allocating zeropage variables in normal ram. 2022-01-23 13:42:52 +01:00
Irmen de Jong
0e87db9eb7 fix invalid size copied when initializing arrays in Zeropage 2022-01-23 13:00:01 +01:00
Irmen de Jong
1e053783f3 fix invalid size copied when assigning non-byte arrays 2022-01-23 02:42:36 +01:00
Irmen de Jong
7afc96112b now correctly requires using & (address-of) when assigning the address of a label or subroutine, used to generate invalid code when it was omitted 2022-01-23 02:23:30 +01:00
Irmen de Jong
7bb41a30ed fixed compiler crash when assigning number larger than 65535 2022-01-23 01:44:16 +01:00
Irmen de Jong
3d1b0eb843 fixed compiler crash when using cx16.r0H as function call argument 2022-01-23 01:28:16 +01:00
Irmen de Jong
5b9af0b5ae tweaks 2022-01-21 23:38:54 +01:00
Irmen de Jong
9219ec539d allow "goto pointervar" for indirect jumps 2022-01-21 22:55:59 +01:00
Irmen de Jong
c8bd57cd4d fixed signature of mouse_get(): it returns the buttonstatus in A. Added convenience cx16.mouse_pos() routine. 2022-01-21 22:06:17 +01:00
Irmen de Jong
53bf8c09fd fix screencode encoding selection 2022-01-19 21:37:27 +01:00
Irmen de Jong
651c383668 refactor encoder to be the same for all 3 machine targets now 2022-01-19 21:21:33 +01:00
Irmen de Jong
9ed7587e3e document new string encoding syntax 2022-01-19 21:21:33 +01:00
Irmen de Jong
674295e800 improve error reporting from string encoders 2022-01-19 21:21:33 +01:00
Irmen de Jong
6b02f2eea0 implement iso encoding and new string encoding syntax, fixes #38 2022-01-19 21:21:32 +01:00
Irmen de Jong
5237e55326 added txt.iso() to enable iso-charset on cx16 2022-01-18 21:35:29 +01:00
Irmen de Jong
3b59592110 generalize string encoding flag into enum 2022-01-18 21:21:49 +01:00
Irmen de Jong
72640ae058 no longer add nops around breakpoint for vice 2022-01-17 22:12:58 +01:00
Irmen de Jong
d916027e75 labels no longer start with '_' fixes #62 2022-01-17 22:03:53 +01:00
Irmen de Jong
8966d2aa06 comments and prepare new version 7.7 2022-01-16 23:03:00 +01:00
Irmen de Jong
de7ea04f54 when zp option = dontuse, print error for any variable with @requirezp 2022-01-16 18:13:24 +01:00
Irmen de Jong
bf71fabe0e fix codegen mistake for zp allocated loop vars 2022-01-16 18:09:09 +01:00
Irmen de Jong
b3368acb33 todos to fix broken examples 2022-01-16 17:57:47 +01:00
Irmen de Jong
87220c6697 docs for @requirezp 2022-01-16 17:20:36 +01:00
Irmen de Jong
a3b5c2ad71 fix zp address output and adjust vars datastructure 2022-01-16 17:20:36 +01:00
Irmen de Jong
fb4c1473c5 array and string initialization in zeropage 2022-01-16 17:20:36 +01:00
Irmen de Jong
2bb2502d20 added @requirezp to syntax files 2022-01-16 17:20:36 +01:00
Irmen de Jong
fe51698579 tweak how zp varnames are stored 2022-01-16 17:20:36 +01:00
Irmen de Jong
0f0f40bff3 improved ForloopAsmGen loopvar zp allocation 2022-01-16 17:20:36 +01:00
Irmen de Jong
a798fe72d3 cx16 reserved zp vars (virtual registers) 2022-01-16 17:20:36 +01:00
Irmen de Jong
fba98d03a5 improve %zpreserved error messages 2022-01-16 17:20:36 +01:00
Irmen de Jong
7dd2517f67 fix Zp allocation issues 2022-01-16 17:20:36 +01:00
Irmen de Jong
641477d6f6 add @requirezp and allow str/array to be on zp (with warning) 2022-01-16 17:20:32 +01:00
Irmen de Jong
8e56656c8d fix broken code generated for certain ==/!= expressions 2022-01-16 17:10:49 +01:00
Irmen de Jong
564a6a1f62 fix invalid removal of Jump 
that would generate wrong code if occurs at the end of a subroutine
 2022-01-16 14:05:42 +01:00
Irmen de Jong
69f0c80cd7 added pokemon() function 2022-01-15 19:04:04 +01:00
Irmen de Jong
6fcb51cea2 add warning when encoded string contains 0-byte 2022-01-15 17:11:40 +01:00
Irmen de Jong
c58b8a4973 fix ast to source: @shared wasn't printed 
fix grammar: @shared and @zp can occur in any order now in vardecl
 2022-01-13 02:29:55 +01:00
Irmen de Jong
c8f4ab4f06 doc 2022-01-12 22:21:01 +01:00
Irmen de Jong
e425c4cca8 optimizing pipe codegen 2022-01-11 23:17:35 +01:00
Irmen de Jong
056ec986c2 use var initializer assignments in a clearer way 2022-01-11 00:34:44 +01:00
Irmen de Jong
de3b2fb95b slightly optimized certain list iterations into sequences 2022-01-10 23:15:24 +01:00
Irmen de Jong
789e39c719 slightly optimized assembly file handling 2022-01-10 22:48:20 +01:00
Irmen de Jong
b29c3152db Assignment: make its origin explicit 2022-01-10 02:25:02 +01:00
Irmen de Jong
3831679772 VarDecl: make its origin explicit 2022-01-10 01:53:03 +01:00
Irmen de Jong
596f9566d8 todo 2022-01-10 01:00:50 +01:00
Irmen de Jong
124befe9d6 slightly optimized code for assigning boolean expressions such as `b = xx>99` 2022-01-09 18:49:44 +01:00
Irmen de Jong
895534f32b don't remove dead variable assignments if they are a function call 2022-01-09 18:41:01 +01:00
Irmen de Jong
50c16fe6de code size optimization: don't copy floats with inlined copy code but use copy_float routine 2022-01-09 16:18:13 +01:00
Irmen de Jong
b092d1a5d3 fixed code gen issue for uword >= comparison 2022-01-09 13:23:29 +01:00
Irmen de Jong
a9b45630d7 optimized code for variable comparisons to zero 2022-01-09 13:10:01 +01:00
Irmen de Jong
c1a39c269e optimized code for stack eval comparisons with zero 2022-01-09 03:19:49 +01:00
Irmen de Jong
6fa3f0b6cd small refactor 2022-01-08 18:02:38 +01:00
Irmen de Jong
9e5e3d1559 pipe expression not evaluated via stack 2022-01-08 17:51:23 +01:00
Irmen de Jong
7135205299 fix codegen bug for pipe expressions to actually return correct value and not corrupt X register 2022-01-08 17:41:46 +01:00
Irmen de Jong
d99d977d2b fix more typecasting issues 2022-01-08 17:04:25 +01:00
Irmen de Jong
7dd7e562bc pipes also as expressions, cleanup codegen, fix various typecasting issues 2022-01-08 13:45:19 +01:00
Irmen de Jong
75d857027e cleanup of Pipe codegen 2022-01-08 01:33:40 +01:00
Irmen de Jong
17694c1d01 better error handling of invalid number casts 2022-01-07 22:12:13 +01:00
Irmen de Jong
749ad700d8 naming consistency for some expression classes 2022-01-07 21:02:55 +01:00
Irmen de Jong
8f3df3039a added pipe operator `|>` 2022-01-06 22:54:18 +01:00
Irmen de Jong
02c315c194 add missing unit tests and type checking for 'in' expression 2022-01-06 00:01:49 +01:00
Irmen de Jong
b697375573 add note about unspecified order of evaluation of expressions and subroutine call arguments 2022-01-05 23:21:45 +01:00
Irmen de Jong
c57ef7725e preparing v7.6 2022-01-04 20:40:35 +01:00
Irmen de Jong
3ae07503f2 doc css styling: font size slightly bigger for code as well 2022-01-03 23:28:11 +01:00
Irmen de Jong
9a0341adde doc css styling: font size slightly bigger 2022-01-03 23:16:07 +01:00
Irmen de Jong
96225efd96 library doc tweaks 2022-01-03 23:15:34 +01:00
Irmen de Jong
c3bd904f41 todo 2022-01-02 23:46:36 +01:00
Irmen de Jong
74257163b1 fix that memory("name", ...) also allocates a STR variable for the name 2022-01-02 17:07:04 +01:00
Irmen de Jong
7bc75fd220 fix that memory("a b c", ...) produces invalid symbol 2022-01-02 16:11:53 +01:00
Irmen de Jong
a23281afab added experimental -noreinit option 2022-01-01 16:35:36 +01:00
Irmen de Jong
9e90dbdde6 slight optimization of repeat loop (> 256 iters) code generation on 65c02 cpu 2022-01-01 14:42:37 +01:00
Irmen de Jong
1e8d8e40a2 slight optimization of repeat loop (0-256 iters) code generation on 65c02 cpu 2021-12-31 14:06:35 +01:00
Irmen de Jong
583e208c1e remark 2021-12-31 11:34:53 +01:00
Irmen de Jong
9b91c427a1 add porting guide 
sizeof(pointer) is hardcoded as 2 now
 2021-12-31 00:16:23 +01:00
Irmen de Jong
196c5e9c24 v39->r39 2021-12-30 19:05:56 +01:00
Irmen de Jong
d8f7feb672 cleanup code style 2021-12-30 18:47:38 +01:00
Irmen de Jong
7c889f17b9 c128 fixes 2021-12-30 18:33:26 +01:00
Irmen de Jong
c15a75556d Merge branch 'master' into c128target 
# Conflicts:
#	compiler/src/prog8/CompilerMain.kt
#	examples/test.p8
 2021-12-30 18:22:05 +01:00
Irmen de Jong
5275c2e35f todo porting guide 2021-12-30 18:20:09 +01:00
Irmen de Jong
5267e06969 added -asmlist cli option to produce assembler listing output 2021-12-30 14:42:09 +01:00
Irmen de Jong
b62183adcb slightly optimized binexpr evaluation for ==/!= in some cases 2021-12-30 02:00:36 +01:00
Irmen de Jong
5d2dec1803 added missing codegen for augmented ==/!= 2021-12-30 01:34:10 +01:00
Irmen de Jong
4a98dab948 fix compiler warnings 2021-12-30 00:58:33 +01:00
Irmen de Jong
9f8c70b326 fix warning about testing multiple values 2021-12-30 00:49:36 +01:00
Irmen de Jong
a65404e63a doc 2021-12-29 18:24:05 +01:00
Irmen de Jong
05a1ddad05 Merge branch 'master' into c128target 
# Conflicts:
#	examples/test.p8
 2021-12-29 18:14:24 +01:00
Irmen de Jong
4be3d63c0e slight optimization of if-in 2021-12-29 18:13:43 +01:00
Irmen de Jong
de6ce4a46e add "X in [1,2,3]" expression (efficient containment check) 2021-12-29 17:26:00 +01:00
Irmen de Jong
7a9e5afb93 fix: for loop over array literal no longer crashes the compiler 2021-12-28 17:51:38 +01:00
Irmen de Jong
b2876b0a03 add a suggestion to use when statement if it seems appropriate 2021-12-28 16:38:12 +01:00
Irmen de Jong
b66f66fe6a fix renames 2021-12-28 14:32:27 +01:00
Irmen de Jong
30f04962d4 Merge branch 'master' into c128target 
# Conflicts:
#	codeGeneration/src/prog8/codegen/target/C128Target.kt
#	codeGeneration/src/prog8/codegen/target/c128/C128MachineDefinition.kt
#	codeGeneration/src/prog8/codegen/target/c128/C128Zeropage.kt
#	compiler/src/prog8/CompilerMain.kt
#	compiler/src/prog8/compiler/Compiler.kt
 2021-12-28 14:30:11 +01:00
Irmen de Jong
0feeb88024 codegen package rename 2 2021-12-28 14:23:36 +01:00
Irmen de Jong
b799f2e05b codegen package rename 2021-12-28 14:18:04 +01:00
Irmen de Jong
56d21de001 Merge branch 'master' into c128target 
# Conflicts:
#	examples/test.p8
 2021-12-28 13:57:27 +01:00
Irmen de Jong
7b54aa0c7d more consistent naming of the statement classes 2021-12-28 13:56:47 +01:00
Irmen de Jong
6e11b8ada1 GoSub no longer inherits from Jump node, fixes subtle ast/codegen bugs related to jsrs 2021-12-28 01:55:13 +01:00
Irmen de Jong
98d25fc4e9 fix some unneeded open classes 2021-12-28 01:29:08 +01:00
Irmen de Jong
79405f47f6 fix if-gosub 2021-12-28 01:24:31 +01:00
Irmen de Jong
1c7c4fc3b0 optimized if-goto codegeneration 2021-12-28 00:42:00 +01:00
Irmen de Jong
97e84d0977 tweak if statement handling 2021-12-27 15:04:25 +01:00
Irmen de Jong
9906b58818 tweak while desugaring, moved postfixexpr optimizations to VariousCleanups regardless of optimizer setting because asmgen requires these for conditional expressions 2021-12-27 12:41:26 +01:00
Irmen de Jong
371f084884 comment 2021-12-27 02:17:04 +01:00
Irmen de Jong
1c10839c14 moved peek/poke desugaring to other walker 2021-12-27 02:08:47 +01:00
Irmen de Jong
c55fdd9834 removed special code generation for while and util expression (replaced by jumps) 
also added exhaustive parent node checker in validation step
 2021-12-27 02:04:28 +01:00
Irmen de Jong
67b0890a6e remove unneeded var inits when an assignment is already present 2021-12-25 23:31:25 +01:00
Irmen de Jong
4da4f96669 lower code: break -> goto after (simplifies codegen) 2021-12-25 22:30:38 +01:00
Irmen de Jong
60a64c2558 test program for floating point issues on c128 2021-12-25 14:36:10 +01:00
Irmen de Jong
d4153da8b9 setup float routine addresses for c128 2021-12-25 02:34:52 +01:00
Irmen de Jong
fc33ab8905 shuffled some system functions back to c64 block to remain compatible with existing code, added missing float and graphics library stubs 2021-12-24 00:08:32 +01:00
Irmen de Jong
a123c64f59 Merge branch 'master' into c128target 2021-12-23 23:51:42 +01:00
Irmen de Jong
a090fe3834 no compiler optimizer crash on certain missing symbol 2021-12-23 23:51:21 +01:00
Irmen de Jong
8fa84de28e fix c128 clearscreen and bdmusic sound issue 2021-12-22 22:59:36 +01:00
Irmen de Jong
3e3da38de1 correctly disable charset switching 2021-12-22 21:47:41 +01:00
Irmen de Jong
a3be8ccc87 Merge branch 'master' into c128target 2021-12-22 21:25:49 +01:00
Irmen de Jong
cdfef30c22 fixed docs on rsave()/rrestore() builtin functions 2021-12-22 21:24:36 +01:00
Irmen de Jong
cabf1e82e8 some shadow registers added to make uppercase()/lowercase() work 2021-12-22 21:20:34 +01:00
Irmen de Jong
608dc5e284 readme 2021-12-22 00:36:06 +01:00
Irmen de Jong
836d40072f c128 evalstack corrections 2021-12-22 00:07:05 +01:00
Irmen de Jong
431401d90e c128 corrections 2021-12-21 23:37:15 +01:00
Irmen de Jong
6da83e2bd7 first steps to add C128 compiler target 2021-12-21 19:08:33 +01:00
Irmen de Jong
7bccfc0006 proper position in recursion warning 2021-12-17 21:04:41 +01:00
Irmen de Jong
e051e09c1d trim down number of warnings a bit 2021-12-17 20:21:14 +01:00
Irmen de Jong
1462c57d0c no need for intermediary returnvalue var for prefix expressions 2021-12-16 21:00:38 +01:00
Irmen de Jong
77c2b2b326 fix position of @shared in array var declarations so that the order is now type[] @shared 2021-12-16 20:36:05 +01:00
Irmen de Jong
3cf9b9d9a5 code size optimization: subroutine calls with 2 byte arg will pass it via A/Y registers instead of separate param assignments at every call site 2021-12-16 01:48:22 +01:00
Irmen de Jong
629117e594 code size optimization: subroutine calls with 1 int arg will pass it via register instead of separate param assignment at every call site 2021-12-16 00:56:59 +01:00
Irmen de Jong
08f87c321f fixed capitalization of operator sets to be consistent with other sets names 2021-12-15 23:43:14 +01:00
Irmen de Jong
1ff13723fe implicit int to float conversion is now an error if floats are not enabled. 2021-12-15 01:52:28 +01:00
Irmen de Jong
510bda1b28 fix compiler crash when using floats in a comparison expression 2021-12-15 01:24:25 +01:00
Irmen de Jong
890327b381 the returnvalue of the diskio.load() function family now is just the last load address+1 (like kernal's LOAD routine). 
This fixes the inconsistent attempt to calculate a size, just let the caller do this if required.
Added a small helper function in cx16diskio to do this for loads that span multiple banks.
 2021-12-14 23:54:42 +01:00
Irmen de Jong
b21f7411dd fix compiler crash when trying to concatenate string var and string literal. 2021-12-14 23:07:46 +01:00
Irmen de Jong
5df623bd2e doc 2021-12-14 22:40:03 +01:00
Irmen de Jong
1e9d249f71 fixed output of float values in cmp instructions 2021-12-13 00:17:59 +01:00
Irmen de Jong
a7b5949e6a fix compiler crash when using a gosub/subroutinecall in a branch statement 2021-12-11 15:11:16 +01:00
Irmen de Jong
02010170ce fix compiler crash when attempting to call a non-function 2021-12-11 13:20:13 +01:00
Irmen de Jong
35998142fe version 7.5 2021-12-10 20:18:17 +01:00
Irmen de Jong
75ea453bf4 fix asm code optimization problem caused in previous release where asm file is not read back in separate lines anymore 2021-12-10 15:37:53 +01:00
Irmen de Jong
33061aaa0d fix: allow scoped variables such as cx16.rX as loop variable in forloops 2021-12-10 14:59:04 +01:00
Irmen de Jong
e342311bef fix wrong code for inplace modification of a pointervariable's memory value 2021-12-10 14:48:53 +01:00
Irmen de Jong
3d743a1ba1 added more constfolding 2021-12-09 23:32:48 +01:00
Irmen de Jong
abca618008 added more constfolding 2021-12-09 23:12:12 +01:00
Irmen de Jong
0d2c3901a3 added more constfolding 2021-12-09 22:12:31 +01:00
Irmen de Jong
d901a1531f added missing vectors to syslib 2021-12-09 21:38:00 +01:00
Irmen de Jong
d8d56b195f comments 2021-12-09 21:13:13 +01:00
Irmen de Jong
a52699717c Merge remote-tracking branch 'origin/master' 
# Conflicts:
#	compiler/src/prog8/compiler/astprocessing/AstChecker.kt
#	compiler/test/TestSubroutines.kt
#	examples/test.p8
 2021-12-07 23:29:30 +01:00
Irmen de Jong
98315de723 allow using ubyte[] as subroutine parameter type (because it is equivalent to uword pointer var) 2021-12-07 23:28:45 +01:00
Irmen de Jong
68d2f7d4c0 allow using ubyte[] as subroutine parameter type (because it is equivalent to uword pointer var) 2021-12-07 23:21:49 +01:00
Irmen de Jong
c812b5ee09 elaborate pointervar indexing a bit more in the docs 2021-12-07 22:25:14 +01:00
Irmen de Jong
dcf487bdc1 fix: correctly insert return statement if needed to prevent 'fall through' into following subroutine 
this wasn't working correctly anymore when the last statement before the subroutine was a jump/goto
 2021-12-07 21:34:50 +01:00
Irmen de Jong
547b1d3720 comment corrections 2021-12-06 23:33:18 +01:00
Irmen de Jong
84f75f4156 tweaked some more .getOrElse 2021-12-06 21:22:00 +01:00
Irmen de Jong
ff69da3fa2 error when 'else' choice in when statemetn isn't the last one, also generate slightly better code for when statements 2021-12-05 21:54:46 +01:00
Irmen de Jong
edffe92a24 astchecker is smarter in detecting rts in inline assembly 2021-12-05 21:28:31 +01:00
Irmen de Jong
b6fe40ada4 fix: cx16.r0 now properly treated as zeropage var on cx16 so @(cx16.r0) won't copy it to temp var anymore 2021-12-05 21:21:41 +01:00
Irmen de Jong
837804b231 test for string x and u escape sequences 2021-12-05 18:39:34 +01:00
Irmen de Jong
81deed143b fix grammar problem: \x and \u escape sequences didn't work in character literals. 2021-12-05 18:11:40 +01:00
Irmen de Jong
900cdd3fa1 added cx16diskio with load() and load_raw() that are HIMEM bank-aware 2021-12-05 02:20:48 +01:00
Irmen de Jong
0018dc6ce7 refactor machinedefinition 2021-12-04 19:07:19 +01:00
Irmen de Jong
c92f914081 gradle build settings tweak to avoid jdk version conflict 2021-12-04 18:36:47 +01:00
Irmen de Jong
0498444ef2 moved all unit tests into single project to avoid dependency issues 2021-12-04 18:20:22 +01:00
Irmen de Jong
ce3c34e458 tweak in error output for file links, corrected column number off-by-one 2021-12-04 16:52:03 +01:00
Irmen de Jong
20401b99d8 added cx16.getrambank() / getrombank() to retrieve the current ram and rom bank numbers. 2021-12-04 15:27:54 +01:00
Irmen de Jong
397f98513b optimize loading A from pointervar 2021-12-04 05:36:48 +01:00
Irmen de Jong
e545ea9504 fix and optimize storing A into pointervar 2021-12-04 04:43:58 +01:00
Irmen de Jong
b867d8f731 cleanups 2021-12-04 01:03:51 +01:00
Irmen de Jong
9a68864b67 version 7.5-dev 2021-12-04 00:18:44 +01:00
Irmen de Jong
72d7178762 added diskio.load_raw() to load headerless files 2021-12-04 00:07:21 +01:00
Irmen de Jong
fbcd9a0c1d reduce number of similar errors for type problem in assignment 2021-12-02 17:44:52 +01:00
Irmen de Jong
c3144a20db spacing 2021-12-02 00:10:06 +01:00
Irmen de Jong
5b56e0462d also deal with zero args 2021-12-01 22:26:36 +01:00
Irmen de Jong
b7fffbb6df release 7.4.1 - oops, funcion call arg count validation was broken 2021-12-01 21:44:03 +01:00
Irmen de Jong
1f346230e3 release 7.4 2021-11-30 22:50:12 +01:00
Irmen de Jong
a2860a7c8c todo 2021-11-30 22:45:43 +01:00
Irmen de Jong
df997e5d3b don't write the asm file twice 2021-11-30 03:47:57 +01:00
Irmen de Jong
a67a82c921 tweak 2021-11-30 03:05:25 +01:00
Irmen de Jong
ea0fe8d3d2 PrefixExpression doesn't cause clobber risk 2021-11-30 02:32:37 +01:00
Irmen de Jong
2560042ac7 fix compiler crashes on in-place operations on cx16 registers or invalid signed types 2021-11-30 02:27:37 +01:00
Irmen de Jong
3d1d0696b9 refactor compiler arguments passing 2021-11-30 01:40:21 +01:00
Irmen de Jong
83f893f50b doc 2021-11-30 00:54:03 +01:00
Irmen de Jong
9ecf95b075 fix syntaxerror in const processing of ranges if it contained variables 2021-11-29 23:36:41 +01:00
Irmen de Jong
7748c261da rsave/rrestore moved from sys to builtin function to solve the stack related problem when calling it as a regular subroutine 2021-11-29 23:13:04 +01:00
Irmen de Jong
a2db44f80c also consider Y register for clobber check for functioncall arguments 2021-11-29 22:09:05 +01:00
Irmen de Jong
b438d8aec0 fix invalid range size check when stepval is not a positive integer 2021-11-29 02:01:19 +01:00
Irmen de Jong
4ac169b210 formatting 2021-11-29 01:25:21 +01:00
Irmen de Jong
56dc6d7f1e comment 2021-11-29 01:10:11 +01:00
Irmen de Jong
45b8762188 use inc/ina instead of adc 2021-11-29 00:07:15 +01:00
Irmen de Jong
cafab98d10 correction 2021-11-28 18:59:36 +01:00
Irmen de Jong
9256f910f0 rollback binexpr splitting, caused slowdowns 2021-11-28 18:50:05 +01:00
Irmen de Jong
32068a832a split some additional binary expressions to avoid stack-based evaluation 2021-11-28 18:27:28 +01:00
Irmen de Jong
47c2c0376a added some cpu stack related assembly-level optimizations 2021-11-28 17:27:01 +01:00
Irmen de Jong
f0dadc4a43 optimize 1-arg functioncalls 2021-11-28 16:55:10 +01:00
Irmen de Jong
960b60cd2d tweak 2021-11-28 14:06:12 +01:00
Irmen de Jong
d6abd72e55 fix push() of signed values 2021-11-28 13:01:46 +01:00
Irmen de Jong
0a568f2530 fix the check of double-defined subroutine variables 2021-11-28 12:52:32 +01:00
Irmen de Jong
c52aa648c0 use an AnonymousScope to contain GoSub changes instead of adding separate statements 2021-11-28 12:09:13 +01:00
Irmen de Jong
3d23b39f4c moved A to the end of the param list to avoid having to store its value 2021-11-28 04:03:18 +01:00
Irmen de Jong
f3a4048ebf improved setting Carry bit as asmsub parameter 2021-11-28 03:31:32 +01:00
Irmen de Jong
1b07637cc4 better error checking for wrong pop() 2021-11-28 02:49:18 +01:00
Irmen de Jong
68b75fd558 fix: also allow pass-by-reference arguments to builtin functions that accept UWORD (adds implicit type cast) 2021-11-28 02:34:53 +01:00
Irmen de Jong
7c5ec1853d nice error message if pop() argument is wrong 2021-11-28 02:20:35 +01:00
Irmen de Jong
e8f4686430 undid failed attempt of using sys.push/sys.pop for stack args - now using new push(), pushw(), pop(), popw() builtin functions 2021-11-28 01:22:40 +01:00
Irmen de Jong
02348924d0 failed attempt of using sys.push/pop for stack args 2021-11-27 23:52:47 +01:00
Irmen de Jong
69dcb4dbda fix reporting of (not) unused code after GoSub jump 2021-11-27 21:22:34 +01:00
Irmen de Jong
c838821615 refactor fuction arguments codegen a bit 2021-11-27 21:14:21 +01:00
Irmen de Jong
8b4ac7801f fix sys.push() signature for c64 2021-11-27 20:18:41 +01:00
Irmen de Jong
64a411628d doc fixes 2021-11-27 19:58:08 +01:00
Irmen de Jong
e8e25c6fd6 added sys.push() and sys.pop() to put values on cpu stack. Added missing builtin functions to syntax-files. 2021-11-27 18:09:15 +01:00
Irmen de Jong
62485b6851 allow assigns to asmsub parameters (registers), but this is not very useful in practice. 2021-11-27 15:41:44 +01:00
Irmen de Jong
54025d2bf5 small refactor and spelling fixes 2021-11-27 14:49:18 +01:00
Irmen de Jong
f5ebf79e71 make sure X register is also saved if needed when GoSub is used 2021-11-26 22:11:52 +01:00
Irmen de Jong
66d5490702 just added missing FAC2 assign possibility 2021-11-26 21:34:00 +01:00
Irmen de Jong
42fe052f9f got rid of old getScopedSymbolNameForTarget routine 2021-11-26 21:09:29 +01:00
Irmen de Jong
58d9c46a9b got rid of old makeScopedName routine 2021-11-26 20:56:30 +01:00
Irmen de Jong
e4648e2138 proper rounding of builtin functions that return int from float 2021-11-26 20:32:12 +01:00
Irmen de Jong
110e047681 replace subroutine calls (statement) by GoSub 2021-11-26 19:47:01 +01:00
Irmen de Jong
17d403d812 Merge branch 'ref-subroutine-param' into v7.4-dev 
# Conflicts:
#	compilerAst/src/prog8/ast/AstToplevel.kt
 2021-11-26 01:12:14 +01:00
Irmen de Jong
0a53bd4956 fix parameter name conflict 2021-11-26 01:01:59 +01:00
Irmen de Jong
e52d05c7db fix some scoping related symbol lookup issues, clarified scoping rules in docs 2021-11-23 23:43:23 +01:00
Irmen de Jong
b00db4f8a2 no longer report unknown type errors as well for unknown symbols, 
added a bunch more unit tests for symbol scoping rules
 2021-11-23 22:45:57 +01:00
Irmen de Jong
0c2f30fd45 links to 6502 bresenham line algorithms 2021-11-23 21:51:18 +01:00
Irmen de Jong
e08871c637 oops! replace phx/plx 65C02 (cx16) instructions by 6502 (c64) compatible alternative. 
Couldn't assemble code that used some of the routines in conv on c64 before...
 2021-11-22 21:02:43 +01:00
Irmen de Jong
ff715881bc allow scoped identifiers to reference a subroutine parameter directly. 
also for asmsubroutines, but the asm generation for that is not yet done.
 2021-11-21 23:21:39 +01:00
Irmen de Jong
0e2e5ffa52 fix parameter name conflict 2021-11-21 22:12:35 +01:00
Irmen de Jong
8095c4c155 added GoSub node (internal use only later for calling subroutines) 2021-11-21 16:23:48 +01:00
Irmen de Jong
e86246a985 todo 2021-11-21 14:00:19 +01:00
Irmen de Jong
625aaa02eb documented the compiler's command line options in more detail 2021-11-21 13:53:22 +01:00
Irmen de Jong
787e35c9f3 asm optimizer can now also see of a symbol reference if it is in IO space or not (to a certain extent), so that these instructions are no longer optimized away 2021-11-21 13:12:51 +01:00
Irmen de Jong
8887e6af91 fix substituting 0 only if its actually the same variable that's substituted 2021-11-21 12:34:57 +01:00
Irmen de Jong
dde4c751da version 7.4-dev 2021-11-21 03:28:13 +01:00
Irmen de Jong
3c39baf1d6 don't optimize seemingly redundant assembly instructions away that manipulate IO memory space 2021-11-21 03:24:03 +01:00
Irmen de Jong
b292124f3c replaced many short/int values by unsigned types if appropriate 2021-11-21 00:55:56 +01:00
Irmen de Jong
c0035ba1a2 char encodings now use UByte type instead of short 2021-11-21 00:07:17 +01:00
Irmen de Jong
2491509c6a add assignment optimization X=value-X --> X=-X ; X+=value (to avoid need of stack-evaluation) 2021-11-20 23:43:10 +01:00
Irmen de Jong
107935ed31 add some more const folding patterns 2021-11-20 22:47:49 +01:00
Irmen de Jong
31491c62c5 add some more const folding patterns 2021-11-20 22:40:12 +01:00
Irmen de Jong
eacf8b896a fix augmentable check to align with what the asmgen understands 2021-11-20 22:06:51 +01:00
Irmen de Jong
7936fc5bd8 tiny optimization of negating a register 2021-11-20 21:42:55 +01:00
Irmen de Jong
adfaddbcf4 give a nicer error when given a wrong compilation target. 2021-11-20 18:30:55 +01:00
Irmen de Jong
74db5c6be7 fix referencesIdentifier() and better removal of unnecessary assignments 2021-11-20 17:41:41 +01:00
Irmen de Jong
f9399bcce7 r=(q+r)-c and r=q+(r-c) are now both also 'augmentable', and BinExprSplitter doesn't check for associativeOperator anymore 2021-11-20 02:03:32 +01:00
Irmen de Jong
87600b23db fix constvalue parent linkage for prefix and typecast 2021-11-20 00:20:35 +01:00
Irmen de Jong
cedfb17b18 fix too aggressive removal of vars that weren't completely unused 2021-11-19 22:49:35 +01:00
Irmen de Jong
fa4c83df6b added 3 tests for discovered problems 2021-11-18 23:55:20 +01:00
Irmen de Jong
42c8720e8b fix float rounding tests 2021-11-18 22:54:49 +01:00
Irmen de Jong
b334d89715 refactor and fix the way memory addresses are checked to be in IO space or regular ram 2021-11-18 22:47:58 +01:00
Irmen de Jong
4f5d36a84d optimization added: bitwise operations with a negative constant number -> replace the number by its positive 2 complement 2021-11-18 02:51:42 +01:00
Irmen de Jong
8f379e2262 give an error when initializing an integer var with a float value instead of silently rounding 2021-11-18 01:56:11 +01:00
Irmen de Jong
fa11a6e18b removed faulty and too aggressive assembly optimization of double-store 2021-11-18 01:43:22 +01:00
Irmen de Jong
52bedce8f4 added test for assignment.isAugmented 2021-11-18 01:05:16 +01:00
Irmen de Jong
4c82af36e6 fix improperly changed behavior about =0 initializer 2021-11-18 00:17:22 +01:00
Irmen de Jong
dafa0d9138 fix compiler crash bug due to reused ast expression nodes. Now all (relevant) Nodes have a copy() function to make a clone. 2021-11-17 23:05:59 +01:00
Irmen de Jong
2e0450d7ed fix bug where variable=0 initializer was forgotten if vardecl is followed by an augmented assignment 2021-11-17 22:31:43 +01:00
Irmen de Jong
6af3209d4d add more const foldings 2021-11-17 00:57:00 +01:00
Irmen de Jong
5d362047e2 add some more comparison expression optimizations to compare against 0 if possible 2021-11-17 00:04:52 +01:00
Irmen de Jong
f48d6ca9f8 simplified NumericLiteral to always just contain a Double instead of a Number for the value 2021-11-16 23:52:54 +01:00
Irmen de Jong
964e8e0a17 update to Kotlin 1.6.0 2021-11-16 22:36:23 +01:00
Irmen de Jong
1f60a2d8b9 comments 2021-11-15 01:30:12 +01:00
Irmen de Jong
5fd83f2757 version 7.3 2021-11-14 22:55:13 +01:00
Irmen de Jong
c80df4140b until-loop condition now also simplified to avoid stack-eval 2021-11-14 22:51:02 +01:00
Irmen de Jong
53e1729e2f introduce option to use internal scratch variables via prog8_lib definitions (ony for compiler, not for user code!) 2021-11-14 16:01:54 +01:00
Irmen de Jong
ab2d1122a9 conditional expressions are optimized more intelligently (simple ones are not split off in separate assignments) 2021-11-14 12:38:56 +01:00
Irmen de Jong
5190594c8a added several more assembly-level optimizations to remove redundant instructions 2021-11-14 12:23:46 +01:00
Irmen de Jong
c858ceeb58 compiler shouldn't use cx16.r15 as temp var 2021-11-14 02:38:59 +01:00
Irmen de Jong
f0f52b9166 optimize typecasted binary expression to avoid even more estack use. also fix wrong parent crash in removal of unused variable's assignments. 2021-11-13 14:22:37 +01:00
Irmen de Jong
00c6f74481 tweak temp float 2021-11-13 12:56:59 +01:00
Irmen de Jong
2177ba0ed2 added signed versions of the cx16 virtual registers 2021-11-13 02:42:21 +01:00
Irmen de Jong
3483515346 preparing for more optimizations 2021-11-12 23:23:51 +01:00
Irmen de Jong
75a06d2a40 preparing for more optimizations 2021-11-12 02:17:37 +01:00
Irmen de Jong
53ac11983b better unused variable removal 2021-11-11 03:03:21 +01:00
Irmen de Jong
69f4a4d4f8 tweak expr.typecastTo() a bit 2021-11-11 00:15:09 +01:00
Irmen de Jong
222bcb808f optimize load-store-load combo in output asm 2021-11-10 23:47:35 +01:00
Irmen de Jong
686483f51a fixed division of signed byte number by 2. (!) 2021-11-10 00:17:56 +01:00
Irmen de Jong
8df3da11e3 add cosr8, sinr8, cosr16 and sinr16 builtin functions that take a degree 0..179 (= 0..358 in 2 degree steps) 
to more easily scale halves/quarters etc of a circle than possible with the ones that take 0..255 'degrees'.
 2021-11-09 23:39:26 +01:00
Irmen de Jong
84dafda0e4 fix error message for type mismatch on builtin-function parameter 2021-11-09 22:19:07 +01:00
Irmen de Jong
b909facfe5 fix compiler stackoverflow crash on certain typecasted expressions containing floats. 2021-11-09 19:31:19 +01:00
Irmen de Jong
7780d94de1 discovered crash related to float typecasting in asm assignment codegen 2021-11-09 03:45:07 +01:00
Irmen de Jong
f2c440e466 new sin/cos idea 2021-11-09 02:38:43 +01:00
Irmen de Jong
4937e004b5 fix compiler crash where it used wrong datatype in split assignment 
fixes crash for "ubyte bb ;; uword ww ;; bb = not bb or not ww"
 2021-11-09 01:13:23 +01:00
Irmen de Jong
4cb383dccb discovered crash about storage size mismatch 2021-11-08 21:44:06 +01:00
Irmen de Jong
c8a4b6f23c refactor expressionsAsmGen so that it now has just 1 single public function 
this makes replacing it by a non-stack based solution easier in the future.
 2021-11-08 19:21:55 +01:00
Irmen de Jong
857724c7e6 attempt to make if-statement not use stack eval anymore 2021-11-08 19:07:36 +01:00
Irmen de Jong
a9b0400d13 fixed 'not' operator priority: it now has higher priority as or/and/xor. 2021-11-08 18:38:04 +01:00
Irmen de Jong
2d1e5bbc7e remove unimportant empty tests 2021-11-08 17:00:10 +01:00
Irmen de Jong
60627ce756 kotest migration done, fixes #70 2021-11-08 16:19:24 +01:00
Irmen de Jong
7961a09d16 converting compiler module's testcases to kotest assertions 2021-11-08 16:14:22 +01:00
Irmen de Jong
613efcacc7 converting compiler module's testcases to kotest (ongoing) 2021-11-08 15:08:48 +01:00
Irmen de Jong
7e8db16e18 moved to kotest assertions in compilerAst module tests 2021-11-07 21:18:18 +01:00
Irmen de Jong
1fbbed7e23 remove unittest machinery from modules that don't have tests 2021-11-07 17:34:14 +01:00
Irmen de Jong
984272beb4 migrated compilerAst module to KoTest (but not finished with the assertions yet) 2021-11-07 17:25:53 +01:00
Irmen de Jong
b9ce94bb68 migrated codeGeneration module to KoTest 2021-11-07 15:40:05 +01:00
Irmen de Jong
f4c4ee78d9 re-use global returnvalue temp var instead of duplicating it in every subroutine that needs it 2021-11-07 14:19:21 +01:00
Irmen de Jong
793596614e attempt to fix ReadTheDocs build issue 2021-11-07 00:37:31 +01:00
Irmen de Jong
136280100c attempt to fix ReadTheDocs build issue 2021-11-07 00:23:44 +01:00
Irmen de Jong
29f1e4d2c9 attempt to fix ReadTheDocs build issue 2021-11-07 00:18:51 +01:00
Irmen de Jong
72a7e61fd0 version 7.2 2021-11-06 23:42:13 +01:00
Irmen de Jong
381cfca67f Merge branch 'v7.2' 
# Conflicts:
#	compiler/res/version.txt
 2021-11-06 23:41:39 +01:00
Irmen de Jong
f40620aa25 "not x" as a condition (if, while, until) is optimized into "x==0", this avoids calculating the value 2021-11-06 23:25:32 +01:00
Irmen de Jong
57a9fed42b todo 2021-11-06 19:09:33 +01:00
Irmen de Jong
18d820da94 correct assignment type 2021-11-06 18:52:54 +01:00
Irmen de Jong
26e66f046f implement some more missing codegen for inplace Prefix expressions 2021-11-06 18:48:42 +01:00
Irmen de Jong
4270c04856 don't crash but give proper error on "-X" expression where X is not a signed type 2021-11-06 18:06:01 +01:00
Irmen de Jong
74456d1135 optimized prefix-expression in to use stack evaluation less 2021-11-06 17:57:00 +01:00
Irmen de Jong
62dc824bc0 tweaks 2021-11-06 17:14:07 +01:00
Irmen de Jong
1605791f1b float swap() no longer uses evaluation stack but a single temp var instead + FAC1 2021-11-06 03:36:14 +01:00
Irmen de Jong
37a46aa2cf complex memory assignment also tries to avoid estack evaluation (but not done yet) 2021-11-06 00:03:19 +01:00
Irmen de Jong
1d2d217b94 non-optimized typecast assignments now attempt to not use evalstack 2021-11-05 23:25:07 +01:00
Irmen de Jong
23961f695d fixed some parse tree node position end-columns. cleanup some todo's 2021-11-05 22:48:28 +01:00
Irmen de Jong
730b208617 relaxed some type checks on certain word register assignment 
preparing to optimize asmsub arg passing for complex expressions
 2021-11-04 23:57:25 +01:00
Irmen de Jong
f09c04eeac fix invalid asm addressing mode for certain value-to-evalstack transfers 2021-11-04 22:44:31 +01:00
Irmen de Jong
be73739c62 todo 2021-11-03 23:08:11 +01:00
Irmen de Jong
eea3fb48a8 add command line option 'optfloatx' to explicitly re-enable float expr optimization as this can increase code size significantly. 
The output size of the various example programs using floating point, when not using this optimization, has been reduced significantly.
The resulting code runs a (tiny) bit slower though.
 2021-11-03 22:52:08 +01:00
Irmen de Jong
b4fa72c058 fix parent node linkage for reading array parameter 2021-11-03 21:57:31 +01:00
Irmen de Jong
b0a865b0f1 update todo 2021-11-02 23:55:50 +01:00
Irmen de Jong
7f49731618 fix: don't initialize block vars twice, fix: make sure the prog8_init_vars generated routine is correctly called when needed 2021-11-02 23:13:28 +01:00
Irmen de Jong
3410aea788 fix regression: don't add 0 initializer when variable is assigned to anyway (or is loopvar in a for-loop) 2021-11-02 21:23:59 +01:00
Irmen de Jong
bc0a133bb1 doc 2021-11-02 20:24:45 +01:00
Irmen de Jong
7e287a5359 proper parent node linkage in generated const values out of typecast expressions. Fixes crash mentioned in #72 2021-11-02 00:47:01 +01:00
Irmen de Jong
1110bd0851 fix vardecl initialization value to not use stack eval anymore but separate assignment 
(this causes the optimized assignment code gen to be used instead)
but some programs now end up larger in output size
 2021-11-01 00:24:15 +01:00
Irmen de Jong
1b576f826d remove unneeded sibling methods 2021-10-31 16:50:15 +01:00
Irmen de Jong
fe17566370 improved reporting of slow stack based evaluation code 2021-10-31 14:18:49 +01:00
Irmen de Jong
e3c00669c1 fixed improved asm generation for conditions that compare signed word to zero 2021-10-31 02:39:45 +02:00
Irmen de Jong
33d17afc32 improved asm generation for conditions that compare byte/word to zero 2021-10-31 01:58:16 +02:00
Irmen de Jong
2388359a99 improved asm generation for conditions that compare ubyte/uword to zero 2021-10-31 01:39:37 +02:00
Irmen de Jong
2df0c9503c improved asm generation for conditions that compare floats to zero 2021-10-31 01:28:08 +02:00
Irmen de Jong
61fa3bc77c comparisonjump tweak 2021-10-31 00:57:22 +02:00
Irmen de Jong
03ac9b6956 various cleanups, slight update to dbus 2021-10-30 19:30:19 +02:00
Irmen de Jong
dfbef8495d got rid of ParsingFailedError 2021-10-30 17:05:23 +02:00
Irmen de Jong
7b17c49d8f update petscii tables with improvements to box drawing chars. fixes #68 2021-10-30 16:45:23 +02:00
Irmen de Jong
4b3f31c2ee added option to suppress assembler output (and enabled this in unit tests) 2021-10-30 15:26:40 +02:00
Irmen de Jong
9ccc65bf8f more petscii tests 2021-10-30 15:15:11 +02:00
Irmen de Jong
f9e22add03 fix crash when using array as paramater type 2021-10-30 15:15:00 +02:00
Irmen de Jong
846951cda7 kotlin 1.5.31 2021-10-30 12:26:05 +02:00
Irmen de Jong
97836e18b2 simplified gradle config, automatically run installDist task after build 2021-10-30 12:01:52 +02:00
Irmen de Jong
7b69df4db2 todos 2021-10-30 00:38:48 +02:00
Irmen de Jong
3767b4bbe7 'Program' is not an ast Node 2021-10-30 00:25:34 +02:00
Irmen de Jong
d7d2eefa4f implemented CharLiteral.constValue() 2021-10-30 00:05:55 +02:00
Irmen de Jong
6737f28d1e moved unittests of compilerInterfaces into compiler module itself 2021-10-29 23:46:51 +02:00
Irmen de Jong
3da9404c2d removed memsizer arg from all builtin functions 2021-10-29 23:38:31 +02:00
Irmen de Jong
4d5bd0fa32 simplify ZeroPage reserved locations handling a bit 2021-10-29 17:34:42 +02:00
Irmen de Jong
1137da37c3 reshuffle ErrorReporter 2021-10-29 17:02:03 +02:00
Irmen de Jong
495a18805c move asmgen test to codeGeneration module 2021-10-29 16:20:53 +02:00
Irmen de Jong
a226b82d0b cleanup imports 2021-10-29 05:30:12 +02:00
Irmen de Jong
0b5ddcdc9b split out the code generator into own project submodule 2021-10-29 05:00:30 +02:00
Irmen de Jong
82da8f4946 adding tests to the new project's submodules 2021-10-29 03:36:42 +02:00
Irmen de Jong
5ff481ce3c make sure tmp folders exist for unit tests 2021-10-29 03:04:16 +02:00
Irmen de Jong
f21dcaa6fb split out the code optimizers into own project submodule 2021-10-29 02:42:10 +02:00
Irmen de Jong
2c940de598 better name 2021-10-29 01:06:01 +02:00
Irmen de Jong
ce75b776bb refactor loadAsmIncludeFile response 2021-10-29 01:01:24 +02:00
Irmen de Jong
7d22b9b9f9 simplified name conflict check for sub params 2021-10-29 00:20:33 +02:00
Irmen de Jong
6cb8b3b5cd removed unneeded scope param from lookup() 2021-10-29 00:01:28 +02:00
Irmen de Jong
2bf4017f2b fix nested label lookups in anon scopes 
fixed non-global qualified names lookup
 2021-10-28 23:48:01 +02:00
Irmen de Jong
08d2f8568b refactoring symbol lookups 2021-10-27 23:48:12 +02:00
Irmen de Jong
ac5f45d2d4 fix nested label lookups in anon scopes (partly) 2021-10-27 02:41:24 +02:00
Irmen de Jong
3cc7ad7d20 slightly improve error message for unknown module import 2021-10-27 00:38:36 +02:00
Irmen de Jong
d4513364fb fix compiler crash when file on command line doesn't exist 2021-10-27 00:23:54 +02:00
Irmen de Jong
9684f4e42a add unit tests for AnonScope refactoring, cleaned up imports 2021-10-27 00:05:46 +02:00
Irmen de Jong
f4186981fd todo 2021-10-26 23:30:48 +02:00
Irmen de Jong
141689e697 change many uses of .definingScope to just the parent node 2021-10-26 23:25:16 +02:00
Irmen de Jong
743c8b44a2 AnonymousScope refactor: it's no longer a INameScope 
because it doesn't contain scoped variables (these are moved to the subroutine's scope)
 2021-10-26 23:01:51 +02:00
Irmen de Jong
5e1459564a no longer take AddressOf a str-variable that is a subroutine's parameter with str type (it's just an address/uword already) 2021-10-25 23:49:01 +02:00
Irmen de Jong
69a8813a3d first steps to add support for str parameter type 2021-10-24 20:57:10 +02:00
Irmen de Jong
17175df835 more precise error messages checks 2021-10-24 19:14:46 +02:00
Irmen de Jong
6b32535cb6 don't complain about uninitialized str var if it's not a var 2021-10-24 15:13:38 +02:00
Irmen de Jong
2815a14bb5 (7.2) can now test for specific error messages, and specify to omit invoking assembler in tests 2021-10-22 01:25:26 +02:00
Irmen de Jong
f4dfa60790 (7.2) tests for pass by ref parameters 2021-10-22 00:41:34 +02:00
Irmen de Jong
35e88dd529 (7.2) correctly parse datatype of array parameters 2021-10-21 22:06:21 +02:00
Irmen de Jong
4d5094a517 (7.2) cleanup Petscii converter errorhandling, add unit tests for error scenarios 2021-10-20 23:48:20 +02:00
Irmen de Jong
dd5abae721 move testcase to proper location 2021-10-20 23:08:40 +02:00
Irmen de Jong
8f2fb20934 Merge branch 'v7.1' into v7.2 2021-10-20 22:51:14 +02:00
Irmen de Jong
74555a32ed Merge branch 'v7.1' into v7.2 2021-10-20 22:37:43 +02:00
Irmen de Jong
1a111b706e Merge branch 'v7.1' into v7.2 2021-10-19 23:59:31 +02:00
Irmen de Jong
4668932bac todo 2021-10-19 23:38:07 +02:00
Irmen de Jong
e6c41eac93 Merge branch 'v7.1' into v7.2 2021-10-19 23:22:38 +02:00
Irmen de Jong
14aad2358f version 7.2 started 2021-10-16 18:46:08 +02:00
258 changed files with 23685 additions and 12088 deletions
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56
.idea/libraries/io_kotest_runner_junit5_jvm.xml generated Normal file
View File

@ -0,0 +1,56 @@
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<root url="jar://$MAVEN_REPOSITORY$/io/kotest/kotest-framework-concurrency-jvm/4.6.3/kotest-framework-concurrency-jvm-4.6.3.jar!/" />
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17
.idea/libraries/junit_jupiter.xml generated
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@ -1,17 +0,0 @@
<component name="libraryTable">
<library name="junit.jupiter" type="repository">
<properties maven-id="org.junit.jupiter:junit-jupiter:5.7.2" />
<CLASSES>
<root url="jar://$MAVEN_REPOSITORY$/org/junit/jupiter/junit-jupiter/5.7.2/junit-jupiter-5.7.2.jar!/" />
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<root url="jar://$MAVEN_REPOSITORY$/org/apiguardian/apiguardian-api/1.1.0/apiguardian-api-1.1.0.jar!/" />
<root url="jar://$MAVEN_REPOSITORY$/org/opentest4j/opentest4j/1.2.0/opentest4j-1.2.0.jar!/" />
<root url="jar://$MAVEN_REPOSITORY$/org/junit/platform/junit-platform-commons/1.7.2/junit-platform-commons-1.7.2.jar!/" />
<root url="jar://$MAVEN_REPOSITORY$/org/junit/jupiter/junit-jupiter-params/5.7.2/junit-jupiter-params-5.7.2.jar!/" />
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<SOURCES />
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5
.idea/misc.xml generated
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@ -16,7 +16,10 @@
</list>
</option>
</component>
<component name="ProjectRootManager" version="2" languageLevel="JDK_11" project-jdk-name="Kotlin SDK" project-jdk-type="KotlinSDK">
<component name="FrameworkDetectionExcludesConfiguration">
<type id="Python" />
</component>
<component name="ProjectRootManager" version="2" languageLevel="JDK_11" project-jdk-name="11" project-jdk-type="JavaSDK">
<output url="file://$PROJECT_DIR$/out" />
</component>
</project>

5
.idea/modules.xml generated
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@ -2,8 +2,13 @@
<project version="4">
<component name="ProjectModuleManager">
<modules>
<module fileurl="file://$PROJECT_DIR$/codeGenCpu6502/codeGenCpu6502.iml" filepath="$PROJECT_DIR$/codeGenCpu6502/codeGenCpu6502.iml" />
<module fileurl="file://$PROJECT_DIR$/codeGenExperimental6502/codeGenExperimental6502.iml" filepath="$PROJECT_DIR$/codeGenExperimental6502/codeGenExperimental6502.iml" />
<module fileurl="file://$PROJECT_DIR$/codeGenTargets/codeGenTargets.iml" filepath="$PROJECT_DIR$/codeGenTargets/codeGenTargets.iml" />
<module fileurl="file://$PROJECT_DIR$/codeOptimizers/codeOptimizers.iml" filepath="$PROJECT_DIR$/codeOptimizers/codeOptimizers.iml" />
<module fileurl="file://$PROJECT_DIR$/compiler/compiler.iml" filepath="$PROJECT_DIR$/compiler/compiler.iml" />
<module fileurl="file://$PROJECT_DIR$/compilerAst/compilerAst.iml" filepath="$PROJECT_DIR$/compilerAst/compilerAst.iml" />
<module fileurl="file://$PROJECT_DIR$/compilerInterfaces/compilerInterfaces.iml" filepath="$PROJECT_DIR$/compilerInterfaces/compilerInterfaces.iml" />
<module fileurl="file://$PROJECT_DIR$/dbusCompilerService/dbusCompilerService.iml" filepath="$PROJECT_DIR$/dbusCompilerService/dbusCompilerService.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" />

29
.readthedocs.yaml Normal file
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@ -0,0 +1,29 @@
# .readthedocs.yaml
# Read the Docs configuration file
# See https://docs.readthedocs.io/en/stable/config-file/v2.html for details
# Required
version: 2
# Set the version of Python and other tools you might need
build:
os: ubuntu-20.04
tools:
python: "3.9"
# You can also specify other tool versions:
# nodejs: "16"
# rust: "1.55"
# golang: "1.17"
# Build documentation in the docs/ directory with Sphinx
sphinx:
configuration: docs/source/conf.py
# If using Sphinx, optionally build your docs in additional formats such as PDF
formats:
- pdf
# Optionally declare the Python requirements required to build your docs
python:
install:
- requirements: docs/requirements.txt

3
CompilerDevelopment.md
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@ -12,6 +12,9 @@
* The same argument applies to `IMemSizer`, and - not entirely sure about that - `IBuiltinFunctions`.
#### Steps to take, in conceptual (!) order:
(note: all these steps have been implemented, rejected or otherwise solved now.)
1. introduce an abstraction `SourceCode` that encapsulates the origin and actual loading of Prog8 source code
- from the local file system (use case: user programs)
- from resources (prog8lib)

10
README.md
View File

@ -37,7 +37,8 @@ What does Prog8 provide?
- small program boilerplate/compilersupport overhead
- programs can be run multiple times without reloading because of automatic variable (re)initializations.
- conditional branches
- 'when' statement to provide a concise jump table alternative to if/elseif chains
- ``when`` statement to provide a concise jump table alternative to if/elseif chains
- ``in`` expression for concise and efficient multi-value/containment check
- many built-in functions such as ``sin``, ``cos``, ``rnd``, ``abs``, ``min``, ``max``, ``sqrt``, ``msb``, ``rol``, ``ror``, ``swap``, ``sort`` and ``reverse``
- various powerful built-in libraries to do I/O, number conversions, graphics and more
- convenience abstractions for low level aspects such as ZeroPage handling, program startup, explicit memory addresses
@ -52,11 +53,12 @@ What does Prog8 provide?
- 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
*Two supported compiler targets* (contributions to improve these or to add support for other machines are welcome!):
*Multiple supported compiler targets* (contributions to improve these or to add support for other machines are welcome!):
- "c64": Commodore-64 (6510 CPU = almost a 6502)
- "c64": Commodore-64 (6502 like CPU)
- "c128": Commodore-128 (6502 like CPU - the Z80 cpu mode is not supported)
- "cx16": [CommanderX16](https://www.commanderx16.com) (65c02 CPU)
- If you only use standard kernal and prog8 library routines, it is possible to compile the *exact same program* for both machines (just change the compiler target flag)!
- If you only use standard kernal and prog8 library routines, it is possible to compile the *exact same program* for different machines (just change the compiler target flag)

9
build.gradle
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@ -1,3 +1,10 @@
plugins {
id "org.jetbrains.kotlin.jvm" version "1.5.30" apply false
id "org.jetbrains.kotlin.jvm" version "$kotlinVersion" apply false
}
allprojects {
repositories {
mavenLocal()
mavenCentral()
}
}

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codeGenCpu6502/build.gradle Normal file
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@ -0,0 +1,46 @@
plugins {
id 'java'
id 'application'
id "org.jetbrains.kotlin.jvm"
}
java {
toolchain {
languageVersion = JavaLanguageVersion.of(javaVersion)
}
}
compileKotlin {
kotlinOptions {
jvmTarget = javaVersion
}
}
compileTestKotlin {
kotlinOptions {
jvmTarget = javaVersion
}
}
dependencies {
implementation project(':compilerInterfaces')
implementation project(':compilerAst')
implementation "org.jetbrains.kotlin:kotlin-stdlib-jdk8"
// implementation "org.jetbrains.kotlin:kotlin-reflect"
implementation "com.michael-bull.kotlin-result:kotlin-result-jvm:1.1.12"
}
sourceSets {
main {
java {
srcDirs = ["${project.projectDir}/src"]
}
resources {
srcDirs = ["${project.projectDir}/res"]
}
}
}
// note: there are no unit tests in this module!

16
codeGenCpu6502/codeGenCpu6502.iml Normal file
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@ -0,0 +1,16 @@
<?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://$MODULE_DIR$">
<sourceFolder url="file://$MODULE_DIR$/src" isTestSource="false" />
<excludeFolder url="file://$MODULE_DIR$/build" />
</content>
<orderEntry type="inheritedJdk" />
<orderEntry type="sourceFolder" forTests="false" />
<orderEntry type="library" name="KotlinJavaRuntime" level="project" />
<orderEntry type="module" module-name="compilerAst" />
<orderEntry type="module" module-name="compilerInterfaces" />
<orderEntry type="library" name="michael.bull.kotlin.result.jvm" level="project" />
</component>
</module>

2884
codeGenCpu6502/src/prog8/codegen/cpu6502/AsmGen.kt Normal file
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452
codeGenCpu6502/src/prog8/codegen/cpu6502/AsmOptimizer.kt Normal file
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@ -0,0 +1,452 @@
package prog8.codegen.cpu6502
import prog8.ast.Program
import prog8.ast.base.VarDeclType
import prog8.ast.expressions.NumericLiteral
import prog8.ast.statements.VarDecl
import prog8.compilerinterface.IMachineDefinition
// note: see https://wiki.nesdev.org/w/index.php/6502_assembly_optimisations
internal fun optimizeAssembly(lines: MutableList<String>, machine: IMachineDefinition, program: Program): Int {
var numberOfOptimizations = 0
var linesByFour = getLinesBy(lines, 4)
var mods = optimizeUselessStackByteWrites(linesByFour)
if(mods.isNotEmpty()) {
apply(mods, lines)
linesByFour = getLinesBy(lines, 4)
numberOfOptimizations++
}
mods = optimizeIncDec(linesByFour)
if(mods.isNotEmpty()) {
apply(mods, lines)
linesByFour = getLinesBy(lines, 4)
numberOfOptimizations++
}
mods = optimizeCmpSequence(linesByFour)
if(mods.isNotEmpty()) {
apply(mods, lines)
linesByFour = getLinesBy(lines, 4)
numberOfOptimizations++
}
mods = optimizeStoreLoadSame(linesByFour, machine, program)
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)
mods = optimizeSameAssignments(linesByFourteen, machine, program)
if(mods.isNotEmpty()) {
apply(mods, lines)
linesByFourteen = getLinesBy(lines, 14)
numberOfOptimizations++
}
// TODO more assembly optimizations
return numberOfOptimizations
}
private fun String.isBranch() = this.startsWith("b")
private fun String.isStoreReg() = this.startsWith("sta") || this.startsWith("sty") || this.startsWith("stx")
private fun String.isStoreRegOrZero() = this.isStoreReg() || this.startsWith("stz")
private fun String.isLoadReg() = this.startsWith("lda") || this.startsWith("ldy") || this.startsWith("ldx")
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> {
// when statement (on bytes) generates a sequence of:
// lda $ce01,x
// cmp #$20
// beq check_prog8_s72choice_32
// lda $ce01,x
// cmp #$21
// beq check_prog8_s73choice_33
// the repeated lda can be removed
val mods = mutableListOf<Modification>()
for(lines in linesByFour) {
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 P8ESTACK_LO+1,x") {
mods.add(Modification(lines[3].index, true, null)) // remove the second lda
}
}
return mods
}
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 mods = mutableListOf<Modification>()
for(lines in linesByFour) {
if(lines[0].value.trim()=="sta P8ESTACK_LO,x" &&
lines[1].value.trim()=="dex" &&
lines[2].value.trim()=="inx" &&
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 mods
}
private fun optimizeSameAssignments(linesByFourteen: List<List<IndexedValue<String>>>, machine: IMachineDefinition, program: Program): List<Modification> {
// Optimize sequential assignments of the same value to various targets (bytes, words, floats)
// the float one is the one that requires 2*7=14 lines of code to check...
// The better place to do this is in the Compiler instead and never create these types of assembly, but hey
val mods = mutableListOf<Modification>()
for (lines in linesByFourteen) {
val first = lines[0].value.trimStart()
val second = lines[1].value.trimStart()
val third = lines[2].value.trimStart()
val fourth = lines[3].value.trimStart()
val fifth = lines[4].value.trimStart()
val sixth = lines[5].value.trimStart()
val seventh = lines[6].value.trimStart()
val eighth = lines[7].value.trimStart()
if(first.startsWith("lda") && second.startsWith("ldy") && third.startsWith("sta") && fourth.startsWith("sty") &&
fifth.startsWith("lda") && sixth.startsWith("ldy") && seventh.startsWith("sta") && eighth.startsWith("sty")) {
val firstvalue = first.substring(4)
val secondvalue = second.substring(4)
val thirdvalue = fifth.substring(4)
val fourthvalue = sixth.substring(4)
if(firstvalue==thirdvalue && secondvalue==fourthvalue) {
// lda/ldy sta/sty twice the same word --> remove second lda/ldy pair (fifth and sixth lines)
val address1 = getAddressArg(first, program)
val address2 = getAddressArg(second, program)
if(address1==null || address2==null || (!machine.isIOAddress(address1) && !machine.isIOAddress(address2))) {
mods.add(Modification(lines[4].index, true, null))
mods.add(Modification(lines[5].index, true, null))
}
}
}
if(first.startsWith("lda") && second.startsWith("sta") && third.startsWith("lda") && fourth.startsWith("sta")) {
val firstvalue = first.substring(4)
val secondvalue = third.substring(4)
if(firstvalue==secondvalue) {
// lda value / sta ? / lda same-value / sta ? -> remove second lda (third line)
val address = getAddressArg(first, program)
if(address==null || !machine.isIOAddress(address))
mods.add(Modification(lines[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 floats.copy_float") || seventh.startsWith("jsr cx16flt.copy_float"))) {
val nineth = lines[8].value.trimStart()
val tenth = lines[9].value.trimStart()
val eleventh = lines[10].value.trimStart()
val twelveth = lines[11].value.trimStart()
val thirteenth = lines[12].value.trimStart()
val fourteenth = lines[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 floats.copy_float") || fourteenth.startsWith("jsr cx16flt.copy_float"))) {
if(first.substring(4) == eighth.substring(4) && second.substring(4)==nineth.substring(4)) {
// identical float init
mods.add(Modification(lines[7].index, true, null))
mods.add(Modification(lines[8].index, true, null))
mods.add(Modification(lines[9].index, true, null))
mods.add(Modification(lines[10].index, true, null))
}
}
}
var overlappingMods = false
/*
sta prog8_lib.retval_intermX ; remove
sty prog8_lib.retval_intermY ; remove
lda prog8_lib.retval_intermX ; remove
ldy prog8_lib.retval_intermY ; remove
sta A1
sty A2
*/
if(first.isStoreReg() && second.isStoreReg()
&& third.isLoadReg() && fourth.isLoadReg()
&& fifth.isStoreReg() && sixth.isStoreReg()) {
val reg1 = first[2]
val reg2 = second[2]
val reg3 = third[2]
val reg4 = fourth[2]
val reg5 = fifth[2]
val reg6 = sixth[2]
if (reg1 == reg3 && reg1 == reg5 && reg2 == reg4 && reg2 == reg6) {
val firstvalue = first.substring(4)
val secondvalue = second.substring(4)
val thirdvalue = third.substring(4)
val fourthvalue = fourth.substring(4)
if(firstvalue.contains("prog8_lib.retval_interm") && secondvalue.contains("prog8_lib.retval_interm")
&& firstvalue==thirdvalue && secondvalue==fourthvalue) {
mods.add(Modification(lines[0].index, true, null))
mods.add(Modification(lines[1].index, true, null))
mods.add(Modification(lines[2].index, true, null))
mods.add(Modification(lines[3].index, true, null))
overlappingMods = true
}
}
}
/*
sta A1
sty A2
lda A1 ; can be removed
ldy A2 ; can be removed if not followed by a branch instuction
*/
if(!overlappingMods && first.isStoreReg() && second.isStoreReg()
&& third.isLoadReg() && fourth.isLoadReg()) {
val reg1 = first[2]
val reg2 = second[2]
val reg3 = third[2]
val reg4 = fourth[2]
if(reg1==reg3 && reg2==reg4) {
val firstvalue = first.substring(4)
val secondvalue = second.substring(4)
val thirdvalue = third.substring(4)
val fourthvalue = fourth.substring(4)
if(firstvalue==thirdvalue && secondvalue == fourthvalue) {
val address = getAddressArg(first, program)
if(address==null || !machine.isIOAddress(address)) {
overlappingMods = true
mods.add(Modification(lines[2].index, true, null))
if (!fifth.startsWith('b'))
mods.add(Modification(lines[3].index, true, null))
}
}
}
}
/*
sta A1
sty A2 ; ... or stz
lda A1 ; can be removed if not followed by a branch instruction
*/
if(!overlappingMods && first.isStoreReg() && second.isStoreRegOrZero()
&& third.isLoadReg() && !fourth.isBranch()) {
val reg1 = first[2]
val reg3 = third[2]
if(reg1==reg3) {
val firstvalue = first.substring(4)
val thirdvalue = third.substring(4)
if(firstvalue==thirdvalue) {
val address = getAddressArg(first, program)
if(address==null || !machine.isIOAddress(address)) {
overlappingMods = true
mods.add(Modification(lines[2].index, true, null))
}
}
}
}
/*
sta A1
ldy A1 ; make tay
sta A1 ; remove
*/
if(!overlappingMods && first.startsWith("sta") && second.isLoadReg()
&& third.startsWith("sta") && second.length>4) {
val firstvalue = first.substring(4)
val secondvalue = second.substring(4)
val thirdvalue = third.substring(4)
if(firstvalue==secondvalue && firstvalue==thirdvalue) {
val address = getAddressArg(first, program)
if(address==null || !machine.isIOAddress(address)) {
overlappingMods = true
val reg2 = second[2]
mods.add(Modification(lines[1].index, false, " ta$reg2"))
mods.add(Modification(lines[2].index, true, null))
}
}
}
/*
sta A ; or stz double store, remove this first one
sta A ; or stz
*/
if(!overlappingMods && first.isStoreRegOrZero() && second.isStoreRegOrZero()) {
if(first[2]==second[2]) {
val firstvalue = first.substring(4)
val secondvalue = second.substring(4)
if(firstvalue==secondvalue) {
val address = getAddressArg(first, program)
if(address==null || !machine.isIOAddress(address)) {
overlappingMods = true
mods.add(Modification(lines[0].index, true, null))
}
}
}
}
}
return mods
}
private fun optimizeStoreLoadSame(linesByFour: List<List<IndexedValue<String>>>, machine: IMachineDefinition, program: Program): List<Modification> {
// sta X + lda X, sty X + ldy X, stx X + ldx X -> the second instruction can OFTEN be eliminated
val mods = mutableListOf<Modification>()
for (lines in linesByFour) {
val first = lines[1].value.trimStart()
val second = lines[2].value.trimStart()
if ((first.startsWith("sta ") && second.startsWith("lda ")) ||
(first.startsWith("stx ") && second.startsWith("ldx ")) ||
(first.startsWith("sty ") && second.startsWith("ldy ")) ||
(first.startsWith("lda ") && second.startsWith("lda ")) ||
(first.startsWith("ldy ") && second.startsWith("ldy ")) ||
(first.startsWith("ldx ") && second.startsWith("ldx ")) ||
(first.startsWith("sta ") && second.startsWith("lda ")) ||
(first.startsWith("sty ") && second.startsWith("ldy ")) ||
(first.startsWith("stx ") && second.startsWith("ldx "))
) {
val third = lines[3].value.trimStart()
val attemptRemove =
if(third.isBranch()) {
// a branch instruction follows, we can only remove the load instruction if
// another load instruction of the same register precedes the store instruction
// (otherwise wrong cpu flags are used)
val loadinstruction = second.substring(0, 3)
lines[0].value.trimStart().startsWith(loadinstruction)
}
else {
// no branch instruction follows, we can remove the load instruction
val address = getAddressArg(lines[2].value, program)
address==null || !machine.isIOAddress(address)
}
if(attemptRemove) {
val firstLoc = first.substring(4).trimStart()
val secondLoc = second.substring(4).trimStart()
if (firstLoc == secondLoc)
mods.add(Modification(lines[2].index, true, null))
}
}
else if(first=="pha" && second=="pla" ||
first=="phx" && second=="plx" ||
first=="phy" && second=="ply" ||
first=="php" && second=="plp") {
mods.add(Modification(lines[1].index, true, null))
mods.add(Modification(lines[2].index, true, null))
} else if(first=="pha" && second=="plx") {
mods.add(Modification(lines[1].index, true, null))
mods.add(Modification(lines[2].index, false, " tax"))
} else if(first=="pha" && second=="ply") {
mods.add(Modification(lines[1].index, true, null))
mods.add(Modification(lines[2].index, false, " tay"))
} else if(first=="phx" && second=="pla") {
mods.add(Modification(lines[1].index, true, null))
mods.add(Modification(lines[2].index, false, " txa"))
} else if(first=="phx" && second=="ply") {
mods.add(Modification(lines[1].index, true, null))
mods.add(Modification(lines[2].index, false, " txy"))
} else if(first=="phy" && second=="pla") {
mods.add(Modification(lines[1].index, true, null))
mods.add(Modification(lines[2].index, false, " tya"))
} else if(first=="phy" && second=="plx") {
mods.add(Modification(lines[1].index, true, null))
mods.add(Modification(lines[2].index, false, " tyx"))
}
}
return mods
}
private val identifierRegex = Regex("""^([a-zA-Z_$][a-zA-Z\d_\.$]*)""")
private fun getAddressArg(line: String, program: Program): UInt? {
val loadArg = line.trimStart().substring(3).trim()
return when {
loadArg.startsWith('$') -> loadArg.substring(1).toUIntOrNull(16)
loadArg.startsWith('%') -> loadArg.substring(1).toUIntOrNull(2)
loadArg.startsWith('#') -> null
loadArg.startsWith('(') -> null
loadArg[0].isLetter() -> {
val identMatch = identifierRegex.find(loadArg)
if(identMatch!=null) {
val identifier = identMatch.value
val decl = program.toplevelModule.lookup(identifier.split(".")) as? VarDecl
if(decl!=null) {
when(decl.type){
VarDeclType.VAR -> null
VarDeclType.CONST,
VarDeclType.MEMORY -> (decl.value as NumericLiteral).number.toUInt()
}
}
else null
} else null
}
else -> loadArg.substring(1).toUIntOrNull()
}
}
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 mods = mutableListOf<Modification>()
for (lines in linesByFour) {
val first = lines[0].value
val second = lines[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)
|| (" ina" in first || "\tina" in first) && (" dea" in second || "\tdea" in second)
|| (" inc a" in first || "\tinc a" in first) && (" dec a" in second || "\tdec a" 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)
|| (" dea" in first || "\tdea" in first) && (" ina" in second || "\tina" in second)
|| (" dec a" in first || "\tdec a" in first) && (" inc a" in second || "\tinc a" in second)) {
mods.add(Modification(lines[0].index, true, null))
mods.add(Modification(lines[1].index, true, null))
}
}
return mods
}
private fun optimizeJsrRts(linesByFour: List<List<IndexedValue<String>>>): List<Modification> {
// jsr Sub + rts -> jmp Sub
val mods = mutableListOf<Modification>()
for (lines in linesByFour) {
val first = lines[0].value
val second = lines[1].value
if ((" jsr" in first || "\tjsr" in first ) && (" rts" in second || "\trts" in second)) {
mods += Modification(lines[0].index, false, lines[0].value.replace("jsr", "jmp"))
mods += Modification(lines[1].index, true, null)
}
}
return mods
}

56
compiler/src/prog8/compiler/target/cbm/AssemblyProgram.kt → codeGenCpu6502/src/prog8/codegen/cpu6502/AssemblyProgram.kt
View File

@ -1,40 +1,49 @@
package prog8.compiler.target.cbm
package prog8.codegen.cpu6502
import prog8.compiler.CompilationOptions
import prog8.compiler.OutputType
import prog8.compiler.target.IAssemblyProgram
import prog8.compiler.target.generatedLabelPrefix
import com.github.michaelbull.result.Ok
import com.github.michaelbull.result.Result
import com.github.michaelbull.result.mapError
import prog8.compilerinterface.*
import prog8.parser.SourceCode
import java.io.File
import java.nio.file.Path
import kotlin.io.path.Path
import kotlin.io.path.isRegularFile
internal const val viceMonListPostfix = "vice-mon-list"
class AssemblyProgram(
override val valid: Boolean,
internal class AssemblyProgram(
override val name: String,
outputDir: Path,
private val compTarget: String) : IAssemblyProgram {
private val compTarget: ICompilationTarget) : 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.$viceMonListPostfix")
private val viceMonListFile = outputDir.resolve(viceMonListName(name))
private val listFile = outputDir.resolve("$name.list")
override fun assemble(options: CompilationOptions): Int {
override fun assemble(options: CompilationOptions): Boolean {
// 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",
"--dump-labels", "--vice-labels", "-l", viceMonListFile.toString(), "--no-monitor")
"--dump-labels", "--vice-labels", "--labels=$viceMonListFile", "--no-monitor"
)
if(options.asmQuiet)
command.add("--quiet")
if(options.asmListfile)
command.add("--list=$listFile")
val outFile = when (options.output) {
OutputType.PRG -> {
command.add("--cbm-prg")
println("\nCreating prg for target $compTarget.")
println("\nCreating prg for target ${compTarget.name}.")
prgFile
}
OutputType.RAW -> {
command.add("--nostart")
println("\nCreating raw binary for target $compTarget.")
println("\nCreating raw binary for target ${compTarget.name}.")
binFile
}
}
@ -46,7 +55,7 @@ class AssemblyProgram(
removeGeneratedLabelsFromMonlist()
generateBreakpointList()
}
return result
return result==0
}
private fun removeGeneratedLabelsFromMonlist() {
@ -76,3 +85,18 @@ class AssemblyProgram(
viceMonListFile.toFile().appendText(breakpoints.joinToString("\n") + "\n")
}
}
internal fun loadAsmIncludeFile(filename: String, source: SourceCode): Result<String, NoSuchFileException> {
return if (filename.startsWith(SourceCode.libraryFilePrefix)) {
return com.github.michaelbull.result.runCatching {
SourceCode.Resource("/prog8lib/${filename.substring(SourceCode.libraryFilePrefix.length)}").text
}.mapError { NoSuchFileException(File(filename)) }
} else {
val sib = Path(source.origin).resolveSibling(filename)
if (sib.isRegularFile())
Ok(SourceCode.File(sib).text)
else
Ok(SourceCode.File(Path(filename)).text)
}
}

432
compiler/src/prog8/compiler/target/cpu6502/codegen/BuiltinFunctionsAsmGen.kt → codeGenCpu6502/src/prog8/codegen/cpu6502/BuiltinFunctionsAsmGen.kt
View File

@ -1,4 +1,4 @@
package prog8.compiler.target.cpu6502.codegen
package prog8.codegen.cpu6502
import prog8.ast.IFunctionCall
import prog8.ast.Node
@ -10,16 +10,19 @@ import prog8.ast.statements.DirectMemoryWrite
import prog8.ast.statements.FunctionCallStatement
import prog8.ast.statements.Subroutine
import prog8.ast.toHex
import prog8.compiler.AssemblyError
import prog8.compiler.functions.FSignature
import prog8.compiler.target.CpuType
import prog8.compiler.target.Cx16Target
import prog8.compiler.target.cpu6502.codegen.assignment.*
import prog8.compiler.target.subroutineFloatEvalResultVar2
import prog8.codegen.cpu6502.assignment.*
import prog8.compilerinterface.AssemblyError
import prog8.compilerinterface.BuiltinFunctions
import prog8.compilerinterface.CpuType
import prog8.compilerinterface.FSignature
internal class BuiltinFunctionsAsmGen(private val program: Program, private val asmgen: AsmGen, private val assignAsmGen: AssignmentAsmGen) {
internal fun translateFunctioncallExpression(fcall: FunctionCall, func: FSignature, resultToStack: Boolean, resultRegister: RegisterOrPair?) {
internal class BuiltinFunctionsAsmGen(private val program: Program,
private val asmgen: AsmGen,
private val assignAsmGen: AssignmentAsmGen,
private val allocations: VariableAllocator) {
internal fun translateFunctioncallExpression(fcall: FunctionCallExpression, func: FSignature, resultToStack: Boolean, resultRegister: RegisterOrPair?) {
translateFunctioncall(fcall, func, discardResult = false, resultToStack = resultToStack, resultRegister = resultRegister)
}
@ -27,6 +30,37 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
translateFunctioncall(fcall, func, discardResult = true, resultToStack = false, resultRegister = null)
}
internal fun translateFunctioncall(name: String, args: List<AsmAssignSource>, isStatement: Boolean, scope: Subroutine): DataType {
val func = BuiltinFunctions.getValue(name)
val argExpressions = args.map { src ->
when(src.kind) {
SourceStorageKind.LITERALNUMBER -> src.number!!
SourceStorageKind.EXPRESSION -> src.expression!!
SourceStorageKind.ARRAY -> src.array!!
else -> {
// TODO make it so that we can assign efficiently from something else as an expression....namely: register(s)
// this is useful in pipe expressions for instance, to skip the use of a temporary variable
// but for now, just assign it to a temporary variable and use that as a source
val tempvar = asmgen.getTempVarName(src.datatype)
val assignTempvar = AsmAssignment(
src,
AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, src.datatype, scope, variableAsmName = asmgen.asmVariableName(tempvar)),
false, program.memsizer, Position.DUMMY
)
assignAsmGen.translateNormalAssignment(assignTempvar)
// now use an expression to assign this tempvar
val ident = IdentifierReference(tempvar, Position.DUMMY)
ident.linkParents(scope)
ident
}
}
}.toMutableList()
val fcall = FunctionCallExpression(IdentifierReference(listOf(name), Position.DUMMY), argExpressions, Position.DUMMY)
fcall.linkParents(scope)
translateFunctioncall(fcall, func, discardResult = false, resultToStack = false, null)
return if(isStatement) DataType.UNDEFINED else func.known_returntype!!
}
private fun translateFunctioncall(fcall: IFunctionCall, func: FSignature, discardResult: Boolean, resultToStack: Boolean, resultRegister: RegisterOrPair?) {
if (discardResult && func.pure)
return // can just ignore the whole function call altogether
@ -46,7 +80,9 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
"sum" -> funcSum(fcall, resultToStack, resultRegister, sscope)
"any", "all" -> funcAnyAll(fcall, func, resultToStack, resultRegister, sscope)
"sin8", "sin8u", "sin16", "sin16u",
"cos8", "cos8u", "cos16", "cos16u" -> funcSinCosInt(fcall, func, resultToStack, resultRegister, sscope)
"sinr8", "sinr8u", "sinr16", "sinr16u",
"cos8", "cos8u", "cos16", "cos16u",
"cosr8", "cosr8u", "cosr16", "cosr16u" -> funcSinCosInt(fcall, func, resultToStack, resultRegister, sscope)
"sgn" -> funcSgn(fcall, func, resultToStack, resultRegister, sscope)
"sin", "cos", "tan", "atan",
"ln", "log2", "sqrt", "rad",
@ -64,7 +100,14 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
"peekw" -> funcPeekW(fcall, resultToStack, resultRegister)
"peek" -> throw AssemblyError("peek() should have been replaced by @()")
"pokew" -> funcPokeW(fcall)
"pokemon" -> { /* meme function */ }
"poke" -> throw AssemblyError("poke() should have been replaced by @()")
"push", "pushw" -> funcPush(fcall, func)
"pop", "popw" -> funcPop(fcall, func)
"rsave" -> funcRsave()
"rsavex" -> funcRsaveX()
"rrestore" -> funcRrestore()
"rrestorex" -> funcRrestoreX()
"cmp" -> funcCmp(fcall)
"callfar" -> funcCallFar(fcall)
"callrom" -> funcCallRom(fcall)
@ -72,8 +115,170 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
}
}
private fun funcRsave() {
if (asmgen.isTargetCpu(CpuType.CPU65c02))
asmgen.out("""
php
pha
phy
phx""")
else
// see http://6502.org/tutorials/register_preservation.html
asmgen.out("""
php
sta P8ZP_SCRATCH_REG
pha
txa
pha
tya
pha
lda P8ZP_SCRATCH_REG""")
}
private fun funcRsaveX() {
if (asmgen.isTargetCpu(CpuType.CPU65c02))
asmgen.out(" phx")
else
asmgen.out(" txa | pha")
}
private fun funcRrestore() {
if (asmgen.isTargetCpu(CpuType.CPU65c02))
asmgen.out("""
plx
ply
pla
plp""")
else
asmgen.out("""
pla
tay
pla
tax
pla
plp""")
}
private fun funcRrestoreX() {
if (asmgen.isTargetCpu(CpuType.CPU65c02))
asmgen.out(" plx")
else
asmgen.out(" sta P8ZP_SCRATCH_B1 | pla | tax | lda P8ZP_SCRATCH_B1")
}
private fun funcPop(fcall: IFunctionCall, func: FSignature) {
// note: because A is pushed first so popped last, saving A is often not required here.
require(fcall.args[0] is IdentifierReference) {
"attempt to pop a value into a differently typed variable, or in something else that isn't supported ${(fcall as Node).position}"
}
val target = (fcall.args[0] as IdentifierReference).targetVarDecl(program)!!
val parameter = target.subroutineParameter
if(parameter!=null) {
val sub = parameter.definingSubroutine!!
require(sub.isAsmSubroutine) {
"push/pop arg passing only supported on asmsubs ${(fcall as Node).position}"
}
val shouldKeepA = sub.asmParameterRegisters.any { it.registerOrPair==RegisterOrPair.AX || it.registerOrPair==RegisterOrPair.AY }
val reg = sub.asmParameterRegisters[sub.parameters.indexOf(parameter)]
if(reg.statusflag!=null) {
if(shouldKeepA)
asmgen.out(" sta P8ZP_SCRATCH_REG")
asmgen.out("""
clc
pla
beq +
sec
+""")
if(shouldKeepA)
asmgen.out(" lda P8ZP_SCRATCH_REG")
}
else {
if (func.name == "pop") {
if (asmgen.isTargetCpu(CpuType.CPU65c02)) {
when (reg.registerOrPair) {
RegisterOrPair.A -> asmgen.out(" pla")
RegisterOrPair.X -> asmgen.out(" plx")
RegisterOrPair.Y -> asmgen.out(" ply")
in Cx16VirtualRegisters -> asmgen.out(" pla | sta cx16.${reg.registerOrPair!!.name.lowercase()}")
else -> throw AssemblyError("invalid target register ${reg.registerOrPair}")
}
} else {
when (reg.registerOrPair) {
RegisterOrPair.A -> asmgen.out(" pla")
RegisterOrPair.X -> {
if(shouldKeepA)
asmgen.out(" sta P8ZP_SCRATCH_REG | pla | tax | lda P8ZP_SCRATCH_REG")
else
asmgen.out(" pla | tax")
}
RegisterOrPair.Y -> {
if(shouldKeepA)
asmgen.out(" sta P8ZP_SCRATCH_REG | pla | tay | lda P8ZP_SCRATCH_REG")
else
asmgen.out(" pla | tay")
}
in Cx16VirtualRegisters -> asmgen.out(" pla | sta cx16.${reg.registerOrPair!!.name.lowercase()}")
else -> throw AssemblyError("invalid target register ${reg.registerOrPair}")
}
}
} else {
// word pop
if (asmgen.isTargetCpu(CpuType.CPU65c02))
when (reg.registerOrPair) {
RegisterOrPair.AX -> asmgen.out(" plx | pla")
RegisterOrPair.AY -> asmgen.out(" ply | pla")
RegisterOrPair.XY -> asmgen.out(" ply | plx")
in Cx16VirtualRegisters -> {
val regname = reg.registerOrPair!!.name.lowercase()
asmgen.out(" pla | sta cx16.$regname+1 | pla | sta cx16.$regname")
}
else -> throw AssemblyError("invalid target register ${reg.registerOrPair}")
}
else {
when (reg.registerOrPair) {
RegisterOrPair.AX -> asmgen.out(" pla | tax | pla")
RegisterOrPair.AY -> asmgen.out(" pla | tay | pla")
RegisterOrPair.XY -> asmgen.out(" pla | tay | pla | tax")
in Cx16VirtualRegisters -> {
val regname = reg.registerOrPair!!.name.lowercase()
asmgen.out(" pla | sta cx16.$regname+1 | pla | sta cx16.$regname")
}
else -> throw AssemblyError("invalid target register ${reg.registerOrPair}")
}
}
}
}
} else {
val tgt = AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, target.datatype, (fcall as Node).definingSubroutine, variableAsmName = asmgen.asmVariableName(target.name))
if (func.name == "pop") {
asmgen.out(" pla")
asmgen.assignRegister(RegisterOrPair.A, tgt)
} else {
if (asmgen.isTargetCpu(CpuType.CPU65c02))
asmgen.out(" ply | pla")
else
asmgen.out(" pla | tay | pla")
asmgen.assignRegister(RegisterOrPair.AY, tgt)
}
}
}
private fun funcPush(fcall: IFunctionCall, func: FSignature) {
val signed = fcall.args[0].inferType(program).oneOf(DataType.BYTE, DataType.WORD)
if(func.name=="push") {
asmgen.assignExpressionToRegister(fcall.args[0], RegisterOrPair.A, signed)
asmgen.out(" pha")
} else {
asmgen.assignExpressionToRegister(fcall.args[0], RegisterOrPair.AY, signed)
if (asmgen.isTargetCpu(CpuType.CPU65c02))
asmgen.out(" pha | phy")
else
asmgen.out(" pha | tya | pha")
}
}
private fun funcCallFar(fcall: IFunctionCall) {
if(asmgen.options.compTarget !is Cx16Target)
if(asmgen.options.compTarget.name != "cx16")
throw AssemblyError("callfar only works on cx16 target at this time")
val bank = fcall.args[0].constValue(program)?.number?.toInt()
@ -87,7 +292,7 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
throw AssemblyError("callfar done on bank 0 which is reserved for the kernal")
val argAddrArg = fcall.args[2]
if(argAddrArg.constValue(program)?.number == 0) {
if(argAddrArg.constValue(program)?.number == 0.0) {
asmgen.out("""
jsr cx16.jsrfar
.word ${address.toHex()}
@ -104,7 +309,7 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
.byte ${bank.toHex()}
sta ${asmgen.asmVariableName(argAddrArg.identifier)}""")
}
is NumericLiteralValue -> {
is NumericLiteral -> {
asmgen.out("""
lda ${argAddrArg.number.toHex()}
jsr cx16.jsrfar
@ -118,7 +323,7 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
}
private fun funcCallRom(fcall: IFunctionCall) {
if(asmgen.options.compTarget !is Cx16Target)
if(asmgen.options.compTarget.name != "cx16")
throw AssemblyError("callrom only works on cx16 target at this time")
val bank = fcall.args[0].constValue(program)?.number?.toInt()
@ -132,7 +337,7 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
throw AssemblyError("callrom bank must be <32")
val argAddrArg = fcall.args[2]
if(argAddrArg.constValue(program)?.number == 0) {
if(argAddrArg.constValue(program)?.number == 0.0) {
asmgen.out("""
lda $01
pha
@ -157,7 +362,7 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
pla
sta $01""")
}
is NumericLiteralValue -> {
is NumericLiteral -> {
asmgen.out("""
lda $01
pha
@ -177,8 +382,8 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
private fun funcCmp(fcall: IFunctionCall) {
val arg1 = fcall.args[0]
val arg2 = fcall.args[1]
val dt1 = arg1.inferType(program).getOr(DataType.UNDEFINED)
val dt2 = arg2.inferType(program).getOr(DataType.UNDEFINED)
val dt1 = arg1.inferType(program).getOrElse { throw AssemblyError("unknown dt") }
val dt2 = arg2.inferType(program).getOrElse { throw AssemblyError("unknown dt") }
if(dt1 in ByteDatatypes) {
if(dt2 in ByteDatatypes) {
when (arg2) {
@ -186,12 +391,12 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
asmgen.assignExpressionToRegister(arg1, RegisterOrPair.A)
asmgen.out(" cmp ${asmgen.asmVariableName(arg2)}")
}
is NumericLiteralValue -> {
is NumericLiteral -> {
asmgen.assignExpressionToRegister(arg1, RegisterOrPair.A)
asmgen.out(" cmp #${arg2.number}")
asmgen.out(" cmp #${arg2.number.toInt()}")
}
is DirectMemoryRead -> {
if(arg2.addressExpression is NumericLiteralValue) {
if(arg2.addressExpression is NumericLiteral) {
asmgen.assignExpressionToRegister(arg1, RegisterOrPair.A)
asmgen.out(" cmp ${arg2.addressExpression.constValue(program)!!.number.toHex()}")
} else {
@ -220,12 +425,12 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
cmp ${asmgen.asmVariableName(arg2)}
+""")
}
is NumericLiteralValue -> {
is NumericLiteral -> {
asmgen.assignExpressionToRegister(arg1, RegisterOrPair.AY)
asmgen.out("""
cpy #>${arg2.number}
cpy #>${arg2.number.toInt()}
bne +
cmp #<${arg2.number}
cmp #<${arg2.number.toInt()}
+""")
}
else -> {
@ -244,15 +449,16 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
}
private fun funcMemory(fcall: IFunctionCall, discardResult: Boolean, resultToStack: Boolean, resultRegister: RegisterOrPair?) {
if(discardResult || fcall !is FunctionCall)
if(discardResult || fcall !is FunctionCallExpression)
throw AssemblyError("should not discard result of memory allocation at $fcall")
val nameRef = fcall.args[0] as IdentifierReference
val name = (nameRef.targetVarDecl(program)!!.value as StringLiteralValue).value
val size = (fcall.args[1] as NumericLiteralValue).number.toInt()
val name = (fcall.args[0] as StringLiteral).value
require(name.all { it.isLetterOrDigit() || it=='_' }) {"memory name should be a valid symbol name"}
val size = (fcall.args[1] as NumericLiteral).number.toUInt()
val align = (fcall.args[2] as NumericLiteral).number.toUInt()
val existingSize = asmgen.slabs[name]
if(existingSize!=null && existingSize!=size)
throw AssemblyError("memory slab '$name' already exists with a different size ($size) at ${fcall.position}")
val existing = allocations.getMemorySlab(name)
if(existing!=null && (existing.first!=size || existing.second!=align))
throw AssemblyError("memory slab '$name' already exists with a different size or alignment at ${fcall.position}")
val slabname = IdentifierReference(listOf("prog8_slabs", name), fcall.position)
slabname.linkParents(fcall)
@ -261,10 +467,10 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
if(resultToStack)
AsmAssignTarget(TargetStorageKind.STACK, program, asmgen, DataType.UWORD, null)
else
AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.AY, null, program, asmgen)
AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.AY, false, null, program, asmgen)
val assign = AsmAssignment(src, target, false, program.memsizer, fcall.position)
asmgen.translateNormalAssignment(assign)
asmgen.slabs[name] = size
allocations.allocateMemorySlab(name, size, align)
}
private fun funcSqrt16(fcall: IFunctionCall, func: FSignature, resultToStack: Boolean, resultRegister: RegisterOrPair?, scope: Subroutine?) {
@ -273,7 +479,7 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
asmgen.out(" jsr prog8_lib.func_sqrt16_stack")
else {
asmgen.out(" jsr prog8_lib.func_sqrt16_into_A")
assignAsmGen.assignRegisterByte(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.A, scope, program, asmgen), CpuRegister.A)
assignAsmGen.assignRegisterByte(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.A, false, scope, program, asmgen), CpuRegister.A)
}
}
@ -283,13 +489,13 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
asmgen.out(" jsr prog8_lib.func_${func.name}_stack")
else
when(func.name) {
"sin8", "sin8u", "cos8", "cos8u" -> {
"sin8", "sin8u", "sinr8", "sinr8u", "cos8", "cos8u", "cosr8", "cosr8u" -> {
asmgen.out(" jsr prog8_lib.func_${func.name}_into_A")
assignAsmGen.assignRegisterByte(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.A, scope, program, asmgen), CpuRegister.A)
assignAsmGen.assignRegisterByte(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.A, false, scope, program, asmgen), CpuRegister.A)
}
"sin16", "sin16u", "cos16", "cos16u" -> {
"sin16", "sin16u", "sinr16", "sinr16u", "cos16", "cos16u", "cosr16", "cosr16u" -> {
asmgen.out(" jsr prog8_lib.func_${func.name}_into_AY")
assignAsmGen.assignRegisterpairWord(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.AY, scope, program, asmgen), RegisterOrPair.AY)
assignAsmGen.assignRegisterpairWord(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.AY, false, scope, program, asmgen), RegisterOrPair.AY)
}
}
}
@ -376,8 +582,8 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
asmgen.out(" jsr prog8_lib.ror2_array_ub")
}
is DirectMemoryRead -> {
if (what.addressExpression is NumericLiteralValue) {
val number = (what.addressExpression as NumericLiteralValue).number
if (what.addressExpression is NumericLiteral) {
val number = (what.addressExpression as NumericLiteral).number
asmgen.out(" lda ${number.toHex()} | lsr a | bcc + | ora #\$80 |+ | sta ${number.toHex()}")
} else {
asmgen.assignExpressionToRegister(what.addressExpression, RegisterOrPair.AY)
@ -419,8 +625,8 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
asmgen.out(" jsr prog8_lib.ror_array_ub")
}
is DirectMemoryRead -> {
if (what.addressExpression is NumericLiteralValue) {
val number = (what.addressExpression as NumericLiteralValue).number
if (what.addressExpression is NumericLiteral) {
val number = (what.addressExpression as NumericLiteral).number
asmgen.out(" ror ${number.toHex()}")
} else {
val ptrAndIndex = asmgen.pointerViaIndexRegisterPossible(what.addressExpression)
@ -477,8 +683,8 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
asmgen.out(" jsr prog8_lib.rol2_array_ub")
}
is DirectMemoryRead -> {
if (what.addressExpression is NumericLiteralValue) {
val number = (what.addressExpression as NumericLiteralValue).number
if (what.addressExpression is NumericLiteral) {
val number = (what.addressExpression as NumericLiteral).number
asmgen.out(" lda ${number.toHex()} | cmp #\$80 | rol a | sta ${number.toHex()}")
} else {
asmgen.assignExpressionToRegister(what.addressExpression, RegisterOrPair.AY)
@ -520,8 +726,8 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
asmgen.out(" jsr prog8_lib.rol_array_ub")
}
is DirectMemoryRead -> {
if (what.addressExpression is NumericLiteralValue) {
val number = (what.addressExpression as NumericLiteralValue).number
if (what.addressExpression is NumericLiteral) {
val number = (what.addressExpression as NumericLiteral).number
asmgen.out(" rol ${number.toHex()}")
} else {
val ptrAndIndex = asmgen.pointerViaIndexRegisterPossible(what.addressExpression)
@ -578,7 +784,7 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
asmgen.out(" jsr floats.func_${func.name}_stack")
else {
asmgen.out(" jsr floats.func_${func.name}_fac1")
assignAsmGen.assignFAC1float(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.FAC1, scope, program, asmgen))
assignAsmGen.assignFAC1float(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.FAC1, true, scope, program, asmgen))
}
}
@ -603,7 +809,7 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
DataType.FLOAT -> asmgen.out(" jsr floats.func_sign_f_into_A")
else -> throw AssemblyError("weird type $dt")
}
assignAsmGen.assignRegisterByte(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.A, scope, program, asmgen), CpuRegister.A)
assignAsmGen.assignRegisterByte(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.A, false, scope, program, asmgen), CpuRegister.A)
}
}
@ -624,7 +830,7 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
DataType.ARRAY_F -> asmgen.out(" jsr floats.func_${function.name}_f_into_A")
else -> throw AssemblyError("weird type $dt")
}
assignAsmGen.assignRegisterByte(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.A, scope, program, asmgen), CpuRegister.A)
assignAsmGen.assignRegisterByte(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.A, false, scope, program, asmgen), CpuRegister.A)
}
}
@ -644,23 +850,23 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
when (dt.getOr(DataType.UNDEFINED)) {
DataType.ARRAY_UB, DataType.STR -> {
asmgen.out(" jsr prog8_lib.func_${function.name}_ub_into_A")
assignAsmGen.assignRegisterByte(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.A, scope, program, asmgen), CpuRegister.A)
assignAsmGen.assignRegisterByte(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.A, false, scope, program, asmgen), CpuRegister.A)
}
DataType.ARRAY_B -> {
asmgen.out(" jsr prog8_lib.func_${function.name}_b_into_A")
assignAsmGen.assignRegisterByte(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.A, scope, program, asmgen), CpuRegister.A)
assignAsmGen.assignRegisterByte(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.A, false, scope, program, asmgen), CpuRegister.A)
}
DataType.ARRAY_UW -> {
asmgen.out(" jsr prog8_lib.func_${function.name}_uw_into_AY")
assignAsmGen.assignRegisterpairWord(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.AY, scope, program, asmgen), RegisterOrPair.AY)
assignAsmGen.assignRegisterpairWord(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.AY, false, scope, program, asmgen), RegisterOrPair.AY)
}
DataType.ARRAY_W -> {
asmgen.out(" jsr prog8_lib.func_${function.name}_w_into_AY")
assignAsmGen.assignRegisterpairWord(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.AY, scope, program, asmgen), RegisterOrPair.AY)
assignAsmGen.assignRegisterpairWord(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.AY, false, scope, program, asmgen), RegisterOrPair.AY)
}
DataType.ARRAY_F -> {
asmgen.out(" jsr floats.func_${function.name}_f_fac1")
assignAsmGen.assignFAC1float(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.FAC1, scope, program, asmgen))
assignAsmGen.assignFAC1float(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.FAC1, true, scope, program, asmgen))
}
else -> throw AssemblyError("weird type $dt")
}
@ -683,23 +889,23 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
when (dt.getOr(DataType.UNDEFINED)) {
DataType.ARRAY_UB, DataType.STR -> {
asmgen.out(" jsr prog8_lib.func_sum_ub_into_AY")
assignAsmGen.assignRegisterpairWord(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.AY, scope, program, asmgen), RegisterOrPair.AY)
assignAsmGen.assignRegisterpairWord(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.AY, false, scope, program, asmgen), RegisterOrPair.AY)
}
DataType.ARRAY_B -> {
asmgen.out(" jsr prog8_lib.func_sum_b_into_AY")
assignAsmGen.assignRegisterpairWord(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.AY, scope, program, asmgen), RegisterOrPair.AY)
assignAsmGen.assignRegisterpairWord(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.AY, false, scope, program, asmgen), RegisterOrPair.AY)
}
DataType.ARRAY_UW -> {
asmgen.out(" jsr prog8_lib.func_sum_uw_into_AY")
assignAsmGen.assignRegisterpairWord(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.AY, scope, program, asmgen), RegisterOrPair.AY)
assignAsmGen.assignRegisterpairWord(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.AY, false, scope, program, asmgen), RegisterOrPair.AY)
}
DataType.ARRAY_W -> {
asmgen.out(" jsr prog8_lib.func_sum_w_into_AY")
assignAsmGen.assignRegisterpairWord(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.AY, scope, program, asmgen), RegisterOrPair.AY)
assignAsmGen.assignRegisterpairWord(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.AY, false, scope, program, asmgen), RegisterOrPair.AY)
}
DataType.ARRAY_F -> {
asmgen.out(" jsr floats.func_sum_f_fac1")
assignAsmGen.assignFAC1float(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.FAC1, scope, program, asmgen))
assignAsmGen.assignFAC1float(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.FAC1, true, scope, program, asmgen))
}
else -> throw AssemblyError("weird type $dt")
}
@ -750,8 +956,8 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
// optimized simple case: swap two memory locations
if(first is DirectMemoryRead && second is DirectMemoryRead) {
val addr1 = (first.addressExpression as? NumericLiteralValue)?.number?.toHex()
val addr2 = (second.addressExpression as? NumericLiteralValue)?.number?.toHex()
val addr1 = (first.addressExpression as? NumericLiteral)?.number?.toHex()
val addr2 = (second.addressExpression as? NumericLiteral)?.number?.toHex()
val name1 = if(first.addressExpression is IdentifierReference) asmgen.asmVariableName(first.addressExpression as IdentifierReference) else null
val name2 = if(second.addressExpression is IdentifierReference) asmgen.asmVariableName(second.addressExpression as IdentifierReference) else null
@ -782,11 +988,10 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
if(pointerVariable != null
&& pointerVariable isSameAs secondExpr.left
&& firstExpr.operator == "+" && secondExpr.operator == "+"
&& (firstOffset is NumericLiteralValue || firstOffset is IdentifierReference || firstOffset is TypecastExpression)
&& (secondOffset is NumericLiteralValue || secondOffset is IdentifierReference || secondOffset is TypecastExpression)
&& (firstOffset is NumericLiteral || firstOffset is IdentifierReference || firstOffset is TypecastExpression)
&& (secondOffset is NumericLiteral || secondOffset is IdentifierReference || secondOffset is TypecastExpression)
) {
val pointerVar = firstExpr.left as IdentifierReference
if(firstOffset is NumericLiteralValue && secondOffset is NumericLiteralValue) {
if(firstOffset is NumericLiteral && secondOffset is NumericLiteral) {
if(firstOffset!=secondOffset) {
swapArrayValues(
DataType.UBYTE,
@ -823,13 +1028,11 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
val arrayVarName1 = asmgen.asmVariableName(first.arrayvar)
val arrayVarName2 = asmgen.asmVariableName(second.arrayvar)
val elementIDt = first.inferType(program)
if(!elementIDt.isKnown)
throw AssemblyError("unknown dt")
val elementDt = elementIDt.getOr(DataType.UNDEFINED)
val elementDt = elementIDt.getOrElse { throw AssemblyError("unknown dt") }
val firstNum = first.indexer.indexExpr as? NumericLiteralValue
val firstNum = first.indexer.indexExpr as? NumericLiteral
val firstVar = first.indexer.indexExpr as? IdentifierReference
val secondNum = second.indexer.indexExpr as? NumericLiteralValue
val secondNum = second.indexer.indexExpr as? NumericLiteral
val secondVar = second.indexer.indexExpr as? IdentifierReference
if(firstNum!=null && secondNum!=null) {
@ -876,27 +1079,29 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
asmgen.translateNormalAssignment(assignSecond)
}
DataType.FLOAT -> {
// via evaluation stack
asmgen.translateExpression(first)
asmgen.translateExpression(second)
val assignFirst = AsmAssignment(
AsmAssignSource(SourceStorageKind.STACK, program, asmgen, DataType.FLOAT),
// via temp variable and FAC1
asmgen.assignExpressionTo(first, AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, DataType.FLOAT, first.definingSubroutine, "floats.tempvar_swap_float"))
asmgen.assignExpressionTo(second, AsmAssignTarget(TargetStorageKind.REGISTER, program, asmgen, DataType.FLOAT, null, register=RegisterOrPair.FAC1))
asmgen.translateNormalAssignment(
AsmAssignment(
AsmAssignSource(SourceStorageKind.REGISTER, program, asmgen, datatype, register = RegisterOrPair.FAC1),
targetFromExpr(first, datatype),
false, program.memsizer, first.position
)
val assignSecond = AsmAssignment(
AsmAssignSource(SourceStorageKind.STACK, program, asmgen, DataType.FLOAT),
)
asmgen.translateNormalAssignment(
AsmAssignment(
AsmAssignSource(SourceStorageKind.VARIABLE, program, asmgen, datatype, "floats.tempvar_swap_float"),
targetFromExpr(second, datatype),
false, program.memsizer, second.position
)
asmgen.translateNormalAssignment(assignFirst)
asmgen.translateNormalAssignment(assignSecond)
)
}
else -> throw AssemblyError("weird swap dt")
}
}
private fun swapArrayValues(elementDt: DataType, arrayVarName1: String, indexValue1: NumericLiteralValue, arrayVarName2: String, indexValue2: NumericLiteralValue) {
private fun swapArrayValues(elementDt: DataType, arrayVarName1: String, indexValue1: NumericLiteral, arrayVarName2: String, indexValue2: NumericLiteral) {
val index1 = indexValue1.number.toInt() * program.memsizer.memorySize(elementDt)
val index2 = indexValue2.number.toInt() * program.memsizer.memorySize(elementDt)
when(elementDt) {
@ -1010,7 +1215,7 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
}
}
private fun swapArrayValues(elementDt: DataType, arrayVarName1: String, indexValue1: NumericLiteralValue, arrayVarName2: String, indexName2: IdentifierReference) {
private fun swapArrayValues(elementDt: DataType, arrayVarName1: String, indexValue1: NumericLiteral, arrayVarName2: String, indexName2: IdentifierReference) {
val index1 = indexValue1.number.toInt() * program.memsizer.memorySize(elementDt)
val idxAsmName2 = asmgen.asmVariableName(indexName2)
when(elementDt) {
@ -1068,7 +1273,7 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
}
}
private fun swapArrayValues(elementDt: DataType, arrayVarName1: String, indexName1: IdentifierReference, arrayVarName2: String, indexValue2: NumericLiteralValue) {
private fun swapArrayValues(elementDt: DataType, arrayVarName1: String, indexName1: IdentifierReference, arrayVarName2: String, indexValue2: NumericLiteral) {
val idxAsmName1 = asmgen.asmVariableName(indexName1)
val index2 = indexValue2.number.toInt() * program.memsizer.memorySize(elementDt)
when(elementDt) {
@ -1140,15 +1345,15 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
when (dt) {
in ByteDatatypes -> {
asmgen.out(" jsr prog8_lib.abs_b_into_A")
assignAsmGen.assignRegisterByte(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.A, scope, program, asmgen), CpuRegister.A)
assignAsmGen.assignRegisterByte(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.A, false, scope, program, asmgen), CpuRegister.A)
}
in WordDatatypes -> {
asmgen.out(" jsr prog8_lib.abs_w_into_AY")
assignAsmGen.assignRegisterpairWord(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.AY, scope, program, asmgen), RegisterOrPair.AY)
assignAsmGen.assignRegisterpairWord(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.AY, false, scope, program, asmgen), RegisterOrPair.AY)
}
DataType.FLOAT -> {
asmgen.out(" jsr floats.abs_f_fac1")
assignAsmGen.assignFAC1float(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.FAC1, scope, program, asmgen))
assignAsmGen.assignFAC1float(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.FAC1, true, scope, program, asmgen))
}
else -> throw AssemblyError("weird type")
}
@ -1162,7 +1367,7 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
asmgen.out(" jsr prog8_lib.func_rnd_stack")
else {
asmgen.out(" jsr math.randbyte")
assignAsmGen.assignRegisterByte(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.A, scope, program, asmgen), CpuRegister.A)
assignAsmGen.assignRegisterByte(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.A, false, scope, program, asmgen), CpuRegister.A)
}
}
"rndw" -> {
@ -1170,7 +1375,7 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
asmgen.out(" jsr prog8_lib.func_rndw_stack")
else {
asmgen.out(" jsr math.randword")
assignAsmGen.assignRegisterpairWord(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.AY, scope, program, asmgen), RegisterOrPair.AY)
assignAsmGen.assignRegisterpairWord(AsmAssignTarget.fromRegisters(resultRegister ?: RegisterOrPair.AY, false, scope, program, asmgen), RegisterOrPair.AY)
}
}
else -> throw AssemblyError("wrong func")
@ -1179,7 +1384,7 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
private fun funcPokeW(fcall: IFunctionCall) {
when(val addrExpr = fcall.args[0]) {
is NumericLiteralValue -> {
is NumericLiteral -> {
asmgen.assignExpressionToRegister(fcall.args[1], RegisterOrPair.AY)
val addr = addrExpr.number.toHex()
asmgen.out(" sta $addr | sty ${addr}+1")
@ -1210,13 +1415,13 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
}
}
is BinaryExpression -> {
if(addrExpr.operator=="+" && addrExpr.left is IdentifierReference && addrExpr.right is NumericLiteralValue) {
if(addrExpr.operator=="+" && addrExpr.left is IdentifierReference && addrExpr.right is NumericLiteral) {
val varname = asmgen.asmVariableName(addrExpr.left as IdentifierReference)
if(asmgen.isZpVar(addrExpr.left as IdentifierReference)) {
// pointervar is already in the zero page, no need to copy
asmgen.saveRegisterLocal(CpuRegister.X, (fcall as Node).definingSubroutine!!)
asmgen.assignExpressionToRegister(fcall.args[1], RegisterOrPair.AX)
val index = (addrExpr.right as NumericLiteralValue).number.toHex()
val index = (addrExpr.right as NumericLiteral).number.toHex()
asmgen.out("""
ldy #$index
sta ($varname),y
@ -1228,6 +1433,7 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
}
}
}
else -> throw AssemblyError("wrong pokew arg type")
}
asmgen.assignExpressionToVariable(fcall.args[0], "P8ZP_SCRATCH_W1", DataType.UWORD, null)
@ -1237,7 +1443,7 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
private fun funcPeekW(fcall: IFunctionCall, resultToStack: Boolean, resultRegister: RegisterOrPair?) {
when(val addrExpr = fcall.args[0]) {
is NumericLiteralValue -> {
is NumericLiteral -> {
val addr = addrExpr.number.toHex()
asmgen.out(" lda $addr | ldy ${addr}+1")
}
@ -1267,11 +1473,11 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
}
}
is BinaryExpression -> {
if(addrExpr.operator=="+" && addrExpr.left is IdentifierReference && addrExpr.right is NumericLiteralValue) {
if(addrExpr.operator=="+" && addrExpr.left is IdentifierReference && addrExpr.right is NumericLiteral) {
val varname = asmgen.asmVariableName(addrExpr.left as IdentifierReference)
if(asmgen.isZpVar(addrExpr.left as IdentifierReference)) {
// pointervar is already in the zero page, no need to copy
val index = (addrExpr.right as NumericLiteralValue).number.toHex()
val index = (addrExpr.right as NumericLiteral).number.toHex()
asmgen.out("""
ldy #$index
lda ($varname),y
@ -1318,14 +1524,14 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
asmgen.out(" sta P8ESTACK_LO,x | tya | sta P8ESTACK_HI,x | dex")
} else {
val reg = resultRegister ?: RegisterOrPair.AY
var needAsave = !(fcall.args[0] is DirectMemoryRead || fcall.args[0] is NumericLiteralValue || fcall.args[0] is IdentifierReference)
var needAsave = !(fcall.args[0] is DirectMemoryRead || fcall.args[0] is NumericLiteral || fcall.args[0] is IdentifierReference)
if(!needAsave) {
val mr0 = fcall.args[0] as? DirectMemoryRead
val mr1 = fcall.args[1] as? DirectMemoryRead
if (mr0 != null)
needAsave = mr0.addressExpression !is NumericLiteralValue && mr0.addressExpression !is IdentifierReference
needAsave = mr0.addressExpression !is NumericLiteral && mr0.addressExpression !is IdentifierReference
if (mr1 != null)
needAsave = needAsave or (mr1.addressExpression !is NumericLiteralValue && mr1.addressExpression !is IdentifierReference)
needAsave = needAsave or (mr1.addressExpression !is NumericLiteral && mr1.addressExpression !is IdentifierReference)
}
when(reg) {
RegisterOrPair.AX -> {
@ -1368,7 +1574,7 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
val arg = fcall.args.single()
if (!arg.inferType(program).isWords)
throw AssemblyError("msb required word argument")
if (arg is NumericLiteralValue)
if (arg is NumericLiteral)
throw AssemblyError("msb(const) should have been const-folded away")
if (arg is IdentifierReference) {
val sourceName = asmgen.asmVariableName(arg)
@ -1379,6 +1585,16 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
null, RegisterOrPair.A -> asmgen.out(" lda $sourceName+1")
RegisterOrPair.X -> asmgen.out(" ldx $sourceName+1")
RegisterOrPair.Y -> asmgen.out(" ldy $sourceName+1")
RegisterOrPair.AX -> asmgen.out(" lda $sourceName+1 | ldx #0")
RegisterOrPair.AY -> asmgen.out(" lda $sourceName+1 | ldy #0")
RegisterOrPair.XY -> asmgen.out(" ldx $sourceName+1 | ldy #0")
in Cx16VirtualRegisters -> {
val regname = resultRegister.name.lowercase()
if(asmgen.isTargetCpu(CpuType.CPU65c02))
asmgen.out(" lda $sourceName+1 | sta cx16.$regname | stz cx16.$regname+1")
else
asmgen.out(" lda $sourceName+1 | sta cx16.$regname | lda #0 | sta cx16.$regname+1")
}
else -> throw AssemblyError("invalid reg")
}
}
@ -1412,7 +1628,7 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
val arg = fcall.args.single()
if (!arg.inferType(program).isWords)
throw AssemblyError("lsb required word argument")
if (arg is NumericLiteralValue)
if (arg is NumericLiteral)
throw AssemblyError("lsb(const) should have been const-folded away")
if (arg is IdentifierReference) {
@ -1424,6 +1640,16 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
null, 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")
in Cx16VirtualRegisters -> {
val regname = resultRegister.name.lowercase()
if(asmgen.isTargetCpu(CpuType.CPU65c02))
asmgen.out(" lda $sourceName | sta cx16.$regname | stz cx16.$regname+1")
else
asmgen.out(" lda $sourceName | sta cx16.$regname | lda #0 | sta cx16.$regname+1")
}
else -> throw AssemblyError("invalid reg")
}
}
@ -1474,7 +1700,9 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
}
private fun translateArguments(args: MutableList<Expression>, signature: FSignature, scope: Subroutine?) {
val callConv = signature.callConvention(args.map { it.inferType(program).getOr(DataType.UNDEFINED) })
val callConv = signature.callConvention(args.map {
it.inferType(program).getOrElse { throw AssemblyError("unknown dt")}
})
fun getSourceForFloat(value: Expression): AsmAssignSource {
return when (value) {
@ -1482,14 +1710,14 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
val addr = AddressOf(value, value.position)
AsmAssignSource.fromAstSource(addr, program, asmgen)
}
is NumericLiteralValue -> {
is NumericLiteral -> {
throw AssemblyError("float literals should have been converted into autovar")
}
else -> {
if(scope==null)
throw AssemblyError("cannot use float arguments outside of a subroutine scope")
scope.asmGenInfo.usedFloatEvalResultVar2 = true
allocations.subroutineExtra(scope).usedFloatEvalResultVar2 = true
val variable = IdentifierReference(listOf(subroutineFloatEvalResultVar2), value.position)
val addr = AddressOf(variable, value.position)
addr.linkParents(value)
@ -1533,7 +1761,7 @@ internal class BuiltinFunctionsAsmGen(private val program: Program, private val
AsmAssignSource.fromAstSource(value, program, asmgen)
}
}
val tgt = AsmAssignTarget.fromRegisters(conv.reg, null, program, asmgen)
val tgt = AsmAssignTarget.fromRegisters(conv.reg!!, false, null, program, asmgen)
val assign = AsmAssignment(src, tgt, false, program.memsizer, value.position)
asmgen.translateNormalAssignment(assign)
}

866
codeGenCpu6502/src/prog8/codegen/cpu6502/ExpressionsAsmGen.kt Normal file
View File

@ -0,0 +1,866 @@
package prog8.codegen.cpu6502
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.ast.statements.BuiltinFunctionPlaceholder
import prog8.ast.statements.Subroutine
import prog8.ast.toHex
import prog8.compilerinterface.AssemblyError
import prog8.compilerinterface.BuiltinFunctions
import prog8.compilerinterface.CpuType
import kotlin.math.absoluteValue
internal class ExpressionsAsmGen(private val program: Program,
private val asmgen: AsmGen,
private val allocator: VariableAllocator) {
@Deprecated("avoid calling this as it generates slow evalstack based code")
internal fun translateExpression(expression:Expression) {
if (this.asmgen.options.slowCodegenWarnings) {
asmgen.errors.warn("slow stack evaluation used for expression $expression", expression.position)
}
translateExpressionInternal(expression)
}
// the rest of the methods are all PRIVATE
private fun translateExpressionInternal(expression: Expression) {
when(expression) {
is PrefixExpression -> translateExpression(expression)
is BinaryExpression -> translateExpression(expression)
is ArrayIndexedExpression -> translateExpression(expression)
is TypecastExpression -> translateExpression(expression)
is AddressOf -> translateExpression(expression)
is DirectMemoryRead -> asmgen.translateDirectMemReadExpressionToRegAorStack(expression, true)
is NumericLiteral -> translateExpression(expression)
is IdentifierReference -> translateExpression(expression)
is FunctionCallExpression -> translateFunctionCallResultOntoStack(expression)
is PipeExpression -> asmgen.translatePipeExpression(expression.expressions, expression,false, true)
is ContainmentCheck -> throw AssemblyError("containment check as complex expression value is not supported")
is ArrayLiteral, is StringLiteral -> throw AssemblyError("no asm gen for string/array literal value assignment - should have been replaced by a variable")
is RangeExpression -> throw AssemblyError("range expression should have been changed into array values")
is CharLiteral -> throw AssemblyError("charliteral should have been replaced by ubyte using certain encoding")
else -> TODO("missing expression asmgen for $expression")
}
}
private fun translateFunctionCallResultOntoStack(call: FunctionCallExpression) {
// only for use in nested expression evaluation
val sub = call.target.targetStatement(program)
if(sub is BuiltinFunctionPlaceholder) {
val builtinFunc = BuiltinFunctions.getValue(sub.name)
asmgen.translateBuiltinFunctionCallExpression(call, builtinFunc, true, null)
} else {
sub as Subroutine
asmgen.saveXbeforeCall(call)
asmgen.translateFunctionCall(call, true)
if(sub.regXasResult()) {
// store the return value in X somewhere that we can acces again below
asmgen.out(" stx P8ZP_SCRATCH_REG")
}
asmgen.restoreXafterCall(call)
val returns = sub.returntypes.zip(sub.asmReturnvaluesRegisters)
for ((_, reg) in returns) {
// result value is in cpu or status registers, put it on the stack instead (as we're evaluating an expression tree)
if (reg.registerOrPair != null) {
when (reg.registerOrPair!!) {
RegisterOrPair.A -> asmgen.out(" sta P8ESTACK_LO,x | dex")
RegisterOrPair.Y -> asmgen.out(" tya | sta P8ESTACK_LO,x | dex")
RegisterOrPair.AY -> asmgen.out(" sta P8ESTACK_LO,x | tya | sta P8ESTACK_HI,x | dex")
RegisterOrPair.X -> asmgen.out(" lda P8ZP_SCRATCH_REG | sta P8ESTACK_LO,x | dex")
RegisterOrPair.AX -> asmgen.out(" sta P8ESTACK_LO,x | lda P8ZP_SCRATCH_REG | sta P8ESTACK_HI,x | dex")
RegisterOrPair.XY -> asmgen.out(" tya | sta P8ESTACK_HI,x | lda P8ZP_SCRATCH_REG | sta P8ESTACK_LO,x | dex")
RegisterOrPair.FAC1 -> asmgen.out(" jsr floats.push_fac1")
RegisterOrPair.FAC2 -> asmgen.out(" jsr floats.push_fac2")
RegisterOrPair.R0,
RegisterOrPair.R1,
RegisterOrPair.R2,
RegisterOrPair.R3,
RegisterOrPair.R4,
RegisterOrPair.R5,
RegisterOrPair.R6,
RegisterOrPair.R7,
RegisterOrPair.R8,
RegisterOrPair.R9,
RegisterOrPair.R10,
RegisterOrPair.R11,
RegisterOrPair.R12,
RegisterOrPair.R13,
RegisterOrPair.R14,
RegisterOrPair.R15 -> {
asmgen.out(
"""
lda cx16.${reg.registerOrPair.toString().lowercase()}
sta P8ESTACK_LO,x
lda cx16.${reg.registerOrPair.toString().lowercase()}+1
sta P8ESTACK_HI,x
dex
""")
}
}
} else when(reg.statusflag) {
Statusflag.Pc -> {
asmgen.out("""
lda #0
rol a
sta P8ESTACK_LO,x
dex""")
}
Statusflag.Pz -> {
asmgen.out("""
beq +
lda #0
beq ++
+ lda #1
+ sta P8ESTACK_LO,x
dex""")
}
Statusflag.Pv -> {
asmgen.out("""
bvs +
lda #0
beq ++
+ lda #1
+ sta P8ESTACK_LO,x
dex""")
}
Statusflag.Pn -> {
asmgen.out("""
bmi +
lda #0
beq ++
+ lda #1
+ sta P8ESTACK_LO,x
dex""")
}
null -> {}
}
}
}
}
private fun translateExpression(typecast: TypecastExpression) {
translateExpressionInternal(typecast.expression)
when(typecast.expression.inferType(program).getOr(DataType.UNDEFINED)) {
DataType.UBYTE -> {
when(typecast.type) {
DataType.UBYTE, DataType.BYTE -> {}
DataType.UWORD, DataType.WORD -> {
if(asmgen.isTargetCpu(CpuType.CPU65c02))
asmgen.out(" stz P8ESTACK_HI+1,x")
else
asmgen.out(" lda #0 | sta P8ESTACK_HI+1,x")
}
DataType.FLOAT -> asmgen.out(" jsr floats.stack_ub2float")
in PassByReferenceDatatypes -> throw AssemblyError("cannot cast to a pass-by-reference datatype")
else -> throw AssemblyError("weird type")
}
}
DataType.BYTE -> {
when(typecast.type) {
DataType.UBYTE, DataType.BYTE -> {}
DataType.UWORD, DataType.WORD -> asmgen.signExtendStackLsb(DataType.BYTE)
DataType.FLOAT -> asmgen.out(" jsr floats.stack_b2float")
in PassByReferenceDatatypes -> throw AssemblyError("cannot cast to a pass-by-reference datatype")
else -> throw AssemblyError("weird type")
}
}
DataType.UWORD -> {
when(typecast.type) {
DataType.BYTE, DataType.UBYTE -> {}
DataType.WORD, DataType.UWORD -> {}
DataType.FLOAT -> asmgen.out(" jsr floats.stack_uw2float")
in PassByReferenceDatatypes -> throw AssemblyError("cannot cast to a pass-by-reference datatype")
else -> throw AssemblyError("weird type")
}
}
DataType.WORD -> {
when(typecast.type) {
DataType.BYTE, DataType.UBYTE -> {}
DataType.WORD, DataType.UWORD -> {}
DataType.FLOAT -> asmgen.out(" jsr floats.stack_w2float")
in PassByReferenceDatatypes -> throw AssemblyError("cannot cast to a pass-by-reference datatype")
else -> throw AssemblyError("weird type")
}
}
DataType.FLOAT -> {
when(typecast.type) {
DataType.UBYTE -> asmgen.out(" jsr floats.stack_float2uw")
DataType.BYTE -> asmgen.out(" jsr floats.stack_float2w")
DataType.UWORD -> asmgen.out(" jsr floats.stack_float2uw")
DataType.WORD -> asmgen.out(" jsr floats.stack_float2w")
DataType.FLOAT -> {}
in PassByReferenceDatatypes -> throw AssemblyError("cannot cast to a pass-by-reference datatype")
else -> throw AssemblyError("weird type")
}
}
DataType.STR -> {
if (typecast.type != DataType.UWORD && typecast.type == DataType.STR)
throw AssemblyError("cannot typecast a string into another incompatitble type")
}
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.asmVariableName(expr.identifier)
asmgen.out(" lda #<$name | sta P8ESTACK_LO,x | lda #>$name | sta P8ESTACK_HI,x | dex")
}
private fun translateExpression(expr: NumericLiteral) {
when(expr.type) {
DataType.UBYTE, DataType.BYTE -> asmgen.out(" lda #${expr.number.toHex()} | sta P8ESTACK_LO,x | dex")
DataType.UWORD, DataType.WORD -> asmgen.out("""
lda #<${expr.number.toHex()}
sta P8ESTACK_LO,x
lda #>${expr.number.toHex()}
sta P8ESTACK_HI,x
dex
""")
DataType.FLOAT -> {
val floatConst = allocator.getFloatAsmConst(expr.number)
asmgen.out(" lda #<$floatConst | ldy #>$floatConst | jsr floats.push_float")
}
else -> throw AssemblyError("weird type")
}
}
private fun translateExpression(expr: IdentifierReference) {
val varname = asmgen.asmVariableName(expr)
when(expr.inferType(program).getOr(DataType.UNDEFINED)) {
DataType.UBYTE, DataType.BYTE -> {
asmgen.out(" lda $varname | sta P8ESTACK_LO,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 #>$varname| jsr floats.push_float")
}
in IterableDatatypes -> {
asmgen.out(" lda #<$varname | sta P8ESTACK_LO,x | lda #>$varname | sta P8ESTACK_HI,x | dex")
}
else -> throw AssemblyError("stack push weird variable type $expr")
}
}
private fun translateExpression(expr: BinaryExpression) {
// Uses evalstack to evaluate the given expression.
// TODO we're slowly reducing the number of places where this is called and instead replace that by more efficient assignment-form code (using temp var or register for instance).
val leftIDt = expr.left.inferType(program)
val rightIDt = expr.right.inferType(program)
if(!leftIDt.isKnown || !rightIDt.isKnown)
throw AssemblyError("can't infer type of both expression operands")
val leftDt = leftIDt.getOrElse { throw AssemblyError("unknown dt") }
val rightDt = rightIDt.getOrElse { throw AssemblyError("unknown dt") }
// see if we can apply some optimized routines
when(expr.operator) {
"+" -> {
if(leftDt in IntegerDatatypes && rightDt in IntegerDatatypes) {
val leftVal = expr.left.constValue(program)?.number?.toInt()
val rightVal = expr.right.constValue(program)?.number?.toInt()
if (leftVal!=null && leftVal in -4..4) {
translateExpressionInternal(expr.right)
if(rightDt in ByteDatatypes) {
val incdec = if(leftVal<0) "dec" else "inc"
repeat(leftVal.absoluteValue) {
asmgen.out(" $incdec P8ESTACK_LO+1,x")
}
} else {
// word
if(leftVal<0) {
repeat(leftVal.absoluteValue) {
asmgen.out("""
lda P8ESTACK_LO+1,x
bne +
dec P8ESTACK_HI+1,x
+ dec P8ESTACK_LO+1,x""")
}
} else {
repeat(leftVal) {
asmgen.out("""
inc P8ESTACK_LO+1,x
bne +
inc P8ESTACK_HI+1,x
+""")
}
}
}
return
}
else if (rightVal!=null && rightVal in -4..4)
{
translateExpressionInternal(expr.left)
if(leftDt in ByteDatatypes) {
val incdec = if(rightVal<0) "dec" else "inc"
repeat(rightVal.absoluteValue) {
asmgen.out(" $incdec P8ESTACK_LO+1,x")
}
} else {
// word
if(rightVal<0) {
repeat(rightVal.absoluteValue) {
asmgen.out("""
lda P8ESTACK_LO+1,x
bne +
dec P8ESTACK_HI+1,x
+ dec P8ESTACK_LO+1,x""")
}
} else {
repeat(rightVal) {
asmgen.out("""
inc P8ESTACK_LO+1,x
bne +
inc P8ESTACK_HI+1,x
+""")
}
}
}
return
}
}
}
"-" -> {
if(leftDt in IntegerDatatypes && rightDt in IntegerDatatypes) {
val rightVal = expr.right.constValue(program)?.number?.toInt()
if (rightVal!=null && rightVal in -4..4)
{
translateExpressionInternal(expr.left)
if(leftDt in ByteDatatypes) {
val incdec = if(rightVal<0) "inc" else "dec"
repeat(rightVal.absoluteValue) {
asmgen.out(" $incdec P8ESTACK_LO+1,x")
}
} else {
// word
if(rightVal>0) {
repeat(rightVal.absoluteValue) {
asmgen.out("""
lda P8ESTACK_LO+1,x
bne +
dec P8ESTACK_HI+1,x
+ dec P8ESTACK_LO+1,x""")
}
} else {
repeat(rightVal) {
asmgen.out("""
inc P8ESTACK_LO+1,x
bne +
inc P8ESTACK_HI+1,x
+""")
}
}
}
return
}
}
}
">>" -> {
val amount = expr.right.constValue(program)?.number?.toInt()
if(amount!=null) {
translateExpressionInternal(expr.left)
when (leftDt) {
DataType.UBYTE -> {
if (amount <= 2)
repeat(amount) { asmgen.out(" lsr P8ESTACK_LO+1,x") }
else {
asmgen.out(" lda P8ESTACK_LO+1,x")
repeat(amount) { asmgen.out(" lsr a") }
asmgen.out(" sta P8ESTACK_LO+1,x")
}
}
DataType.BYTE -> {
if (amount <= 2)
repeat(amount) { asmgen.out(" lda P8ESTACK_LO+1,x | asl a | ror P8ESTACK_LO+1,x") }
else {
asmgen.out(" lda P8ESTACK_LO+1,x | sta P8ZP_SCRATCH_B1")
repeat(amount) { asmgen.out(" asl a | ror P8ZP_SCRATCH_B1 | lda P8ZP_SCRATCH_B1") }
asmgen.out(" sta P8ESTACK_LO+1,x")
}
}
DataType.UWORD -> {
if(amount>=16) {
if(asmgen.isTargetCpu(CpuType.CPU65c02))
asmgen.out(" stz P8ESTACK_LO+1,x | stz P8ESTACK_HI+1,x")
else
asmgen.out(" lda #0 | sta P8ESTACK_LO+1,x | sta P8ESTACK_HI+1,x")
return
}
var left = amount
while (left >= 7) {
asmgen.out(" jsr math.shift_right_uw_7")
left -= 7
}
if (left in 0..2)
repeat(left) { asmgen.out(" lsr P8ESTACK_HI+1,x | ror P8ESTACK_LO+1,x") }
else
asmgen.out(" jsr math.shift_right_uw_$left")
}
DataType.WORD -> {
if(amount>=16) {
asmgen.out("""
lda P8ESTACK_HI+1,x
bmi +
lda #0
sta P8ESTACK_LO+1,x
sta P8ESTACK_HI+1,x
beq ++
+ lda #255
sta P8ESTACK_LO+1,x
sta P8ESTACK_HI+1,x
+""")
return
}
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_$left")
}
else -> throw AssemblyError("weird type")
}
return
}
}
"<<" -> {
val amount = expr.right.constValue(program)?.number?.toInt()
if(amount!=null) {
translateExpressionInternal(expr.left)
if (leftDt in ByteDatatypes) {
if (amount <= 2)
repeat(amount) { asmgen.out(" asl P8ESTACK_LO+1,x") }
else {
asmgen.out(" lda P8ESTACK_LO+1,x")
repeat(amount) { asmgen.out(" asl a") }
asmgen.out(" sta P8ESTACK_LO+1,x")
}
} else {
var left = amount
while (left >= 7) {
asmgen.out(" jsr math.shift_left_w_7")
left -= 7
}
if (left in 0..2)
repeat(left) { asmgen.out(" asl P8ESTACK_LO+1,x | rol P8ESTACK_HI+1,x") }
else
asmgen.out(" jsr math.shift_left_w_$left")
}
return
}
}
"*" -> {
if(leftDt in IntegerDatatypes && rightDt in IntegerDatatypes) {
val leftVar = expr.left as? IdentifierReference
val rightVar = expr.right as? IdentifierReference
if(leftVar!=null && rightVar!=null && leftVar==rightVar)
return translateSquared(leftVar, leftDt)
}
val value = expr.right.constValue(program)
if(value!=null) {
if(rightDt in IntegerDatatypes) {
val amount = value.number.toInt()
if(amount==2) {
// optimize x*2 common case
translateExpressionInternal(expr.left)
if(leftDt in ByteDatatypes) {
asmgen.out(" asl P8ESTACK_LO+1,x")
} else {
asmgen.out(" asl P8ESTACK_LO+1,x | rol P8ESTACK_HI+1,x")
}
return
}
when(rightDt) {
DataType.UBYTE -> {
if(amount in asmgen.optimizedByteMultiplications) {
translateExpressionInternal(expr.left)
asmgen.out(" jsr math.stack_mul_byte_$amount")
return
}
}
DataType.BYTE -> {
if(amount in asmgen.optimizedByteMultiplications) {
translateExpressionInternal(expr.left)
asmgen.out(" jsr math.stack_mul_byte_$amount")
return
}
if(amount.absoluteValue in asmgen.optimizedByteMultiplications) {
translateExpressionInternal(expr.left)
asmgen.out(" jsr prog8_lib.neg_b | jsr math.stack_mul_byte_${amount.absoluteValue}")
return
}
}
DataType.UWORD -> {
if(amount in asmgen.optimizedWordMultiplications) {
translateExpressionInternal(expr.left)
asmgen.out(" jsr math.stack_mul_word_$amount")
return
}
}
DataType.WORD -> {
if(amount in asmgen.optimizedWordMultiplications) {
translateExpressionInternal(expr.left)
asmgen.out(" jsr math.stack_mul_word_$amount")
return
}
if(amount.absoluteValue in asmgen.optimizedWordMultiplications) {
translateExpressionInternal(expr.left)
asmgen.out(" jsr prog8_lib.neg_w | jsr math.stack_mul_word_${amount.absoluteValue}")
return
}
}
else -> {}
}
}
}
}
"/" -> {
if(leftDt in IntegerDatatypes && rightDt in IntegerDatatypes) {
val rightVal = expr.right.constValue(program)?.number?.toInt()
if(rightVal!=null && rightVal==2) {
translateExpressionInternal(expr.left)
when(leftDt) {
DataType.UBYTE -> asmgen.out(" lsr P8ESTACK_LO+1,x")
DataType.BYTE -> asmgen.out(" lda P8ESTACK_LO+1,x | asl a | ror P8ESTACK_LO+1,x")
DataType.UWORD -> asmgen.out(" lsr P8ESTACK_HI+1,x | ror P8ESTACK_LO+1,x")
DataType.WORD -> asmgen.out(" lda P8ESTACK_HI+1,x | asl a | ror P8ESTACK_HI+1,x | ror P8ESTACK_LO+1,x")
else -> throw AssemblyError("wrong dt")
}
return
}
}
}
in ComparisonOperators -> {
if(leftDt in NumericDatatypes && rightDt in NumericDatatypes) {
val rightVal = expr.right.constValue(program)?.number?.toInt()
if(rightVal==0)
return translateComparisonWithZero(expr.left, leftDt, expr.operator)
}
}
}
if((leftDt in ByteDatatypes && rightDt !in ByteDatatypes)
|| (leftDt in WordDatatypes && rightDt !in WordDatatypes))
throw AssemblyError("binary operator ${expr.operator} left/right dt not identical")
if(leftDt==DataType.STR && rightDt==DataType.STR && expr.operator in ComparisonOperators) {
translateCompareStrings(expr.left, expr.operator, expr.right)
}
else {
// the general, non-optimized cases TODO optimize more cases.... (or one day just don't use the evalstack at all anymore)
translateExpressionInternal(expr.left)
translateExpressionInternal(expr.right)
when (leftDt) {
in ByteDatatypes -> translateBinaryOperatorBytes(expr.operator, leftDt)
in WordDatatypes -> translateBinaryOperatorWords(expr.operator, leftDt)
DataType.FLOAT -> translateBinaryOperatorFloats(expr.operator)
else -> throw AssemblyError("non-numerical datatype")
}
}
}
private fun translateComparisonWithZero(expr: Expression, dt: DataType, operator: String) {
translateExpressionInternal(expr)
when(operator) {
"==" -> {
when(dt) {
DataType.UBYTE, DataType.BYTE -> asmgen.out(" jsr prog8_lib.equalzero_b")
DataType.UWORD, DataType.WORD -> asmgen.out(" jsr prog8_lib.equalzero_w")
DataType.FLOAT -> asmgen.out(" jsr floats.equal_zero")
else -> throw AssemblyError("wrong dt")
}
}
"!=" -> {
when(dt) {
DataType.UBYTE, DataType.BYTE -> asmgen.out(" jsr prog8_lib.notequalzero_b")
DataType.UWORD, DataType.WORD -> asmgen.out(" jsr prog8_lib.notequalzero_w")
DataType.FLOAT -> asmgen.out(" jsr floats.notequal_zero")
else -> throw AssemblyError("wrong dt")
}
}
"<" -> {
if(dt==DataType.UBYTE || dt==DataType.UWORD)
return translateExpressionInternal(NumericLiteral.fromBoolean(false, expr.position))
when(dt) {
DataType.BYTE -> asmgen.out(" jsr prog8_lib.lesszero_b")
DataType.WORD -> asmgen.out(" jsr prog8_lib.lesszero_w")
DataType.FLOAT -> asmgen.out(" jsr floats.less_zero")
else -> throw AssemblyError("wrong dt")
}
}
">" -> {
when(dt) {
DataType.UBYTE -> asmgen.out(" jsr prog8_lib.greaterzero_ub")
DataType.BYTE -> asmgen.out(" jsr prog8_lib.greaterzero_sb")
DataType.UWORD -> asmgen.out(" jsr prog8_lib.greaterzero_uw")
DataType.WORD -> asmgen.out(" jsr prog8_lib.greaterzero_sw")
DataType.FLOAT -> asmgen.out(" jsr floats.greater_zero")
else -> throw AssemblyError("wrong dt")
}
}
"<=" -> {
when(dt) {
DataType.UBYTE -> asmgen.out(" jsr prog8_lib.equalzero_b")
DataType.BYTE -> asmgen.out(" jsr prog8_lib.lessequalzeros_b")
DataType.UWORD -> asmgen.out(" jsr prog8_lib.equalzero_w")
DataType.WORD -> asmgen.out(" jsr prog8_lib.lessequalzero_sw")
DataType.FLOAT -> asmgen.out(" jsr floats.lessequal_zero")
else -> throw AssemblyError("wrong dt")
}
}
">=" -> {
if(dt==DataType.UBYTE || dt==DataType.UWORD)
return translateExpressionInternal(NumericLiteral.fromBoolean(true, expr.position))
when(dt) {
DataType.BYTE -> asmgen.out(" jsr prog8_lib.greaterequalzero_sb")
DataType.WORD -> asmgen.out(" jsr prog8_lib.greaterequalzero_sw")
DataType.FLOAT -> asmgen.out(" jsr floats.greaterequal_zero")
else -> throw AssemblyError("wrong dt")
}
}
else -> throw AssemblyError("invalid comparison operator")
}
}
private fun translateSquared(variable: IdentifierReference, dt: DataType) {
val asmVar = asmgen.asmVariableName(variable)
when(dt) {
DataType.BYTE, DataType.UBYTE -> {
asmgen.out(" lda $asmVar")
asmgen.signExtendAYlsb(dt)
asmgen.out(" jsr math.square")
}
DataType.UWORD, DataType.WORD -> {
asmgen.out(" lda $asmVar | ldy $asmVar+1 | jsr math.square")
}
else -> throw AssemblyError("require integer dt for square")
}
asmgen.out(" sta P8ESTACK_LO,x | tya | sta P8ESTACK_HI,x | dex")
}
private fun translateExpression(expr: PrefixExpression) {
translateExpressionInternal(expr.expression)
val itype = expr.inferType(program)
val type = itype.getOrElse { throw AssemblyError("unknown dt") }
when(expr.operator) {
"+" -> {}
"-" -> {
when(type) {
in ByteDatatypes -> asmgen.out(" jsr prog8_lib.neg_b")
in WordDatatypes -> asmgen.out(" jsr prog8_lib.neg_w")
DataType.FLOAT -> asmgen.out(" jsr floats.neg_f")
else -> throw AssemblyError("weird type")
}
}
"~" -> {
when(type) {
in ByteDatatypes ->
asmgen.out("""
lda P8ESTACK_LO+1,x
eor #255
sta P8ESTACK_LO+1,x
""")
in WordDatatypes -> asmgen.out(" jsr prog8_lib.inv_word")
else -> throw AssemblyError("weird type")
}
}
"not" -> {
when(type) {
in ByteDatatypes -> asmgen.out(" jsr prog8_lib.not_byte")
in WordDatatypes -> asmgen.out(" jsr prog8_lib.not_word")
else -> throw AssemblyError("weird type")
}
}
else -> throw AssemblyError("invalid prefix operator ${expr.operator}")
}
}
private fun translateExpression(arrayExpr: ArrayIndexedExpression) {
val elementIDt = arrayExpr.inferType(program)
if(!elementIDt.isKnown)
throw AssemblyError("unknown dt")
val elementDt = elementIDt.getOr(DataType.UNDEFINED)
val arrayVarName = asmgen.asmVariableName(arrayExpr.arrayvar)
val constIndexNum = arrayExpr.indexer.constIndex()
if(constIndexNum!=null) {
val indexValue = constIndexNum * program.memsizer.memorySize(elementDt)
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 floats.push_float")
}
else -> throw AssemblyError("weird element type")
}
} else {
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 floats.push_float""")
}
else -> throw AssemblyError("weird dt")
}
}
}
private fun translateBinaryOperatorBytes(operator: String, types: DataType) {
when(operator) {
"**" -> throw AssemblyError("** operator requires floats")
"*" -> asmgen.out(" jsr prog8_lib.mul_byte") // the optimized routines should have been checked earlier
"/" -> asmgen.out(if(types==DataType.UBYTE) " jsr prog8_lib.idiv_ub" else " jsr prog8_lib.idiv_b")
"%" -> {
if(types==DataType.BYTE)
throw AssemblyError("remainder of signed integers is not properly defined/implemented, use unsigned instead")
asmgen.out(" jsr prog8_lib.remainder_ub")
}
"+" -> asmgen.out("""
lda P8ESTACK_LO+2,x
clc
adc P8ESTACK_LO+1,x
inx
sta P8ESTACK_LO+1,x
""")
"-" -> asmgen.out("""
lda P8ESTACK_LO+2,x
sec
sbc P8ESTACK_LO+1,x
inx
sta P8ESTACK_LO+1,x
""")
"<<" -> 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")
">=" -> asmgen.out(if(types==DataType.UBYTE) " jsr prog8_lib.greatereq_ub" else " jsr prog8_lib.greatereq_b")
"==" -> asmgen.out(" jsr prog8_lib.equal_b")
"!=" -> asmgen.out(" jsr prog8_lib.notequal_b")
"&" -> asmgen.out(" jsr prog8_lib.bitand_b")
"^" -> asmgen.out(" jsr prog8_lib.bitxor_b")
"|" -> asmgen.out(" jsr prog8_lib.bitor_b")
"and" -> asmgen.out(" jsr prog8_lib.and_b")
"or" -> asmgen.out(" jsr prog8_lib.or_b")
"xor" -> asmgen.out(" jsr prog8_lib.xor_b")
else -> throw AssemblyError("invalid operator $operator")
}
}
private fun translateBinaryOperatorWords(operator: String, dt: DataType) {
when(operator) {
"**" -> throw AssemblyError("** operator requires floats")
"*" -> asmgen.out(" jsr prog8_lib.mul_word")
"/" -> asmgen.out(if(dt==DataType.UWORD) " jsr prog8_lib.idiv_uw" else " jsr prog8_lib.idiv_w")
"%" -> {
if(dt==DataType.WORD)
throw AssemblyError("remainder of signed integers is not properly defined/implemented, use unsigned instead")
asmgen.out(" jsr prog8_lib.remainder_uw")
}
"+" -> asmgen.out(" jsr prog8_lib.add_w")
"-" -> asmgen.out(" jsr prog8_lib.sub_w")
"<<" -> asmgen.out(" jsr math.shift_left_w")
">>" -> {
if(dt==DataType.UWORD)
asmgen.out(" jsr math.shift_right_uw")
else
asmgen.out(" jsr math.shift_right_w")
}
"<" -> asmgen.out(if(dt==DataType.UWORD) " jsr prog8_lib.less_uw" else " jsr prog8_lib.less_w")
">" -> asmgen.out(if(dt==DataType.UWORD) " jsr prog8_lib.greater_uw" else " jsr prog8_lib.greater_w")
"<=" -> asmgen.out(if(dt==DataType.UWORD) " jsr prog8_lib.lesseq_uw" else " jsr prog8_lib.lesseq_w")
">=" -> asmgen.out(if(dt==DataType.UWORD) " jsr prog8_lib.greatereq_uw" else " jsr prog8_lib.greatereq_w")
"==" -> asmgen.out(" jsr prog8_lib.equal_w")
"!=" -> asmgen.out(" jsr prog8_lib.notequal_w")
"&" -> asmgen.out(" jsr prog8_lib.bitand_w")
"^" -> asmgen.out(" jsr prog8_lib.bitxor_w")
"|" -> asmgen.out(" jsr prog8_lib.bitor_w")
"and" -> asmgen.out(" jsr prog8_lib.and_w")
"or" -> asmgen.out(" jsr prog8_lib.or_w")
"xor" -> asmgen.out(" jsr prog8_lib.xor_w")
else -> throw AssemblyError("invalid operator $operator")
}
}
private fun translateBinaryOperatorFloats(operator: String) {
when(operator) {
"**" -> asmgen.out(" jsr floats.pow_f")
"*" -> asmgen.out(" jsr floats.mul_f")
"/" -> asmgen.out(" jsr floats.div_f")
"+" -> asmgen.out(" jsr floats.add_f")
"-" -> asmgen.out(" jsr floats.sub_f")
"<" -> asmgen.out(" jsr floats.less_f")
">" -> asmgen.out(" jsr floats.greater_f")
"<=" -> asmgen.out(" jsr floats.lesseq_f")
">=" -> asmgen.out(" jsr floats.greatereq_f")
"==" -> asmgen.out(" jsr floats.equal_f")
"!=" -> asmgen.out(" jsr floats.notequal_f")
"%", "<<", ">>", "&", "^", "|", "and", "or", "xor" -> throw AssemblyError("requires integer datatype")
else -> throw AssemblyError("invalid operator $operator")
}
}
private fun translateCompareStrings(s1: Expression, operator: String, s2: Expression) {
asmgen.assignExpressionToVariable(s1, "prog8_lib.strcmp_expression._arg_s1", DataType.UWORD, null)
asmgen.assignExpressionToVariable(s2, "prog8_lib.strcmp_expression._arg_s2", DataType.UWORD, null)
asmgen.out(" jsr prog8_lib.strcmp_expression") // result of compare is in A
when(operator) {
"==" -> asmgen.out(" and #1 | eor #1 | sta P8ESTACK_LO,x")
"!=" -> asmgen.out(" and #1 | sta P8ESTACK_LO,x")
"<=" -> asmgen.out("""
bpl +
lda #1
bne ++
+ lda #0
+ sta P8ESTACK_LO,x""")
">=" -> asmgen.out("""
bmi +
lda #1
bne ++
+ lda #0
+ sta P8ESTACK_LO,x""")
"<" -> asmgen.out("""
bmi +
lda #0
beq ++
+ lda #1
+ sta P8ESTACK_LO,x""")
">" -> asmgen.out("""
bpl +
lda #0
beq ++
+ lda #1
+ sta P8ESTACK_LO,x""")
}
asmgen.out(" dex")
}
}

61
compiler/src/prog8/compiler/target/cpu6502/codegen/ForLoopsAsmGen.kt → codeGenCpu6502/src/prog8/codegen/cpu6502/ForLoopsAsmGen.kt
View File

@ -1,40 +1,41 @@
package prog8.compiler.target.cpu6502.codegen
package prog8.codegen.cpu6502
import com.github.michaelbull.result.fold
import prog8.ast.Program
import prog8.ast.base.ArrayToElementTypes
import prog8.ast.base.DataType
import prog8.ast.base.RegisterOrPair
import prog8.ast.expressions.IdentifierReference
import prog8.ast.expressions.RangeExpr
import prog8.ast.expressions.RangeExpression
import prog8.ast.statements.ForLoop
import prog8.ast.toHex
import prog8.compiler.AssemblyError
import prog8.compiler.astprocessing.toConstantIntegerRange
import prog8.compilerinterface.AssemblyError
import prog8.compilerinterface.Zeropage
import kotlin.math.absoluteValue
internal class ForLoopsAsmGen(private val program: Program, private val asmgen: AsmGen) {
internal class ForLoopsAsmGen(private val program: Program, private val asmgen: AsmGen, private val zeropage: Zeropage) {
internal fun translate(stmt: ForLoop) {
val iterableDt = stmt.iterable.inferType(program)
if(!iterableDt.isKnown)
throw AssemblyError("unknown dt")
when(stmt.iterable) {
is RangeExpr -> {
val range = (stmt.iterable as RangeExpr).toConstantIntegerRange(asmgen.options.compTarget)
is RangeExpression -> {
val range = (stmt.iterable as RangeExpression).toConstantIntegerRange()
if(range==null) {
translateForOverNonconstRange(stmt, iterableDt.getOr(DataType.UNDEFINED), stmt.iterable as RangeExpr)
translateForOverNonconstRange(stmt, iterableDt.getOrElse { throw AssemblyError("unknown dt") }, stmt.iterable as RangeExpression)
} else {
translateForOverConstRange(stmt, iterableDt.getOr(DataType.UNDEFINED), range)
translateForOverConstRange(stmt, iterableDt.getOrElse { throw AssemblyError("unknown dt") }, range)
}
}
is IdentifierReference -> {
translateForOverIterableVar(stmt, iterableDt.getOr(DataType.UNDEFINED), stmt.iterable as IdentifierReference)
translateForOverIterableVar(stmt, iterableDt.getOrElse { throw AssemblyError("unknown dt") }, stmt.iterable as IdentifierReference)
}
else -> throw AssemblyError("can't iterate over ${stmt.iterable.javaClass} - should have been replaced by a variable")
}
}
private fun translateForOverNonconstRange(stmt: ForLoop, iterableDt: DataType, range: RangeExpr) {
private fun translateForOverNonconstRange(stmt: ForLoop, iterableDt: DataType, range: RangeExpression) {
val loopLabel = asmgen.makeLabel("for_loop")
val endLabel = asmgen.makeLabel("for_end")
val modifiedLabel = asmgen.makeLabel("for_modified")
@ -43,7 +44,7 @@ internal class ForLoopsAsmGen(private val program: Program, private val asmgen:
val stepsize=range.step.constValue(program)!!.number.toInt()
if(stepsize < -1) {
val limit = range.to.constValue(program)?.number?.toDouble()
val limit = range.to.constValue(program)?.number
if(limit==0.0)
throw AssemblyError("for unsigned loop variable it's not possible to count down with step != -1 from a non-const value to exactly zero due to value wrapping")
}
@ -289,13 +290,15 @@ $loopLabel sty $indexVar
bne $loopLabel
beq $endLabel""")
}
if(length>=16 && asmgen.zeropage.hasByteAvailable()) {
// allocate index var on ZP
val zpAddr = asmgen.zeropage.allocate(indexVar, DataType.UBYTE, stmt.position, asmgen.errors)
asmgen.out("""$indexVar = $zpAddr ; auto zp UBYTE""")
if(length>=16) {
// allocate index var on ZP if possible
val result = zeropage.allocate(listOf(indexVar), DataType.UBYTE, stmt.definingScope, null, null, stmt.position, asmgen.errors)
result.fold(
success = { (address,_)-> asmgen.out("""$indexVar = $address ; auto zp UBYTE""") },
failure = { asmgen.out("$indexVar .byte 0") }
)
} else {
asmgen.out("""
$indexVar .byte 0""")
asmgen.out("$indexVar .byte 0")
}
asmgen.out(endLabel)
}
@ -328,13 +331,15 @@ $loopLabel sty $indexVar
bne $loopLabel
beq $endLabel""")
}
if(length>=16 && asmgen.zeropage.hasByteAvailable()) {
// allocate index var on ZP
val zpAddr = asmgen.zeropage.allocate(indexVar, DataType.UBYTE, stmt.position, asmgen.errors)
asmgen.out("""$indexVar = $zpAddr ; auto zp UBYTE""")
if(length>=16) {
// allocate index var on ZP if possible
val result = zeropage.allocate(listOf(indexVar), DataType.UBYTE, stmt.definingScope, null, null, stmt.position, asmgen.errors)
result.fold(
success = { (address,_)-> asmgen.out("""$indexVar = $address ; auto zp UBYTE""") },
failure = { asmgen.out("$indexVar .byte 0") }
)
} else {
asmgen.out("""
$indexVar .byte 0""")
asmgen.out("$indexVar .byte 0")
}
asmgen.out(endLabel)
}
@ -588,6 +593,10 @@ $loopLabel""")
asmgen.loopEndLabels.pop()
}
private fun assignLoopvar(stmt: ForLoop, range: RangeExpr) =
asmgen.assignExpressionToVariable(range.from, asmgen.asmVariableName(stmt.loopVar), stmt.loopVarDt(program).getOr(DataType.UNDEFINED), stmt.definingSubroutine)
private fun assignLoopvar(stmt: ForLoop, range: RangeExpression) =
asmgen.assignExpressionToVariable(
range.from,
asmgen.asmVariableName(stmt.loopVar),
stmt.loopVarDt(program).getOrElse { throw AssemblyError("unknown dt") },
stmt.definingSubroutine)
}

279
compiler/src/prog8/compiler/target/cpu6502/codegen/FunctionCallAsmGen.kt → codeGenCpu6502/src/prog8/codegen/cpu6502/FunctionCallAsmGen.kt
View File

@ -1,27 +1,27 @@
package prog8.compiler.target.cpu6502.codegen
package prog8.codegen.cpu6502
import prog8.ast.IFunctionCall
import prog8.ast.Node
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.ast.statements.InlineAssembly
import prog8.ast.statements.RegisterOrStatusflag
import prog8.ast.statements.Subroutine
import prog8.ast.statements.SubroutineParameter
import prog8.compiler.AssemblyError
import prog8.compiler.target.CpuType
import prog8.compiler.target.cpu6502.codegen.assignment.AsmAssignSource
import prog8.compiler.target.cpu6502.codegen.assignment.AsmAssignTarget
import prog8.compiler.target.cpu6502.codegen.assignment.AsmAssignment
import prog8.compiler.target.cpu6502.codegen.assignment.TargetStorageKind
import prog8.ast.expressions.AddressOf
import prog8.ast.expressions.Expression
import prog8.ast.expressions.IdentifierReference
import prog8.ast.expressions.NumericLiteral
import prog8.ast.statements.*
import prog8.codegen.cpu6502.assignment.AsmAssignSource
import prog8.codegen.cpu6502.assignment.AsmAssignTarget
import prog8.codegen.cpu6502.assignment.AsmAssignment
import prog8.codegen.cpu6502.assignment.TargetStorageKind
import prog8.compilerinterface.AssemblyError
import prog8.compilerinterface.CpuType
internal class FunctionCallAsmGen(private val program: Program, private val asmgen: AsmGen) {
internal fun translateFunctionCallStatement(stmt: IFunctionCall) {
saveXbeforeCall(stmt)
translateFunctionCall(stmt)
translateFunctionCall(stmt, false)
restoreXafterCall(stmt)
// just ignore any result values from the function call.
}
@ -37,6 +37,17 @@ internal class FunctionCallAsmGen(private val program: Program, private val asmg
}
}
internal fun saveXbeforeCall(gosub: GoSub) {
val sub = gosub.identifier?.targetSubroutine(program)
if(sub?.shouldSaveX()==true) {
val regSaveOnStack = sub.asmAddress==null // rom-routines don't require registers to be saved on stack, normal subroutines do because they can contain nested calls
if(regSaveOnStack)
asmgen.saveRegisterStack(CpuRegister.X, sub.shouldKeepA().saveOnEntry)
else
asmgen.saveRegisterLocal(CpuRegister.X, gosub.definingSubroutine!!)
}
}
internal fun restoreXafterCall(stmt: IFunctionCall) {
val sub = stmt.target.targetSubroutine(program) ?: throw AssemblyError("undefined subroutine ${stmt.target}")
if(sub.shouldSaveX()) {
@ -48,101 +59,176 @@ internal class FunctionCallAsmGen(private val program: Program, private val asmg
}
}
internal fun translateFunctionCall(stmt: IFunctionCall) {
internal fun restoreXafterCall(gosub: GoSub) {
val sub = gosub.identifier?.targetSubroutine(program)
if(sub?.shouldSaveX()==true) {
val regSaveOnStack = sub.asmAddress==null // rom-routines don't require registers to be saved on stack, normal subroutines do because they can contain nested calls
if(regSaveOnStack)
asmgen.restoreRegisterStack(CpuRegister.X, sub.shouldKeepA().saveOnReturn)
else
asmgen.restoreRegisterLocal(CpuRegister.X)
}
}
internal fun optimizeIntArgsViaRegisters(sub: Subroutine) =
(sub.parameters.size==1 && sub.parameters[0].type in IntegerDatatypes)
|| (sub.parameters.size==2 && sub.parameters[0].type in ByteDatatypes && sub.parameters[1].type in ByteDatatypes)
internal fun translateFunctionCall(call: IFunctionCall, isExpression: Boolean) {
// Output only the code to set up the parameters and perform the actual call
// NOTE: does NOT output the code to deal with the result values!
// NOTE: does NOT output code to save/restore the X register for this call! Every caller should deal with this in their own way!!
// (you can use subroutine.shouldSaveX() and saveX()/restoreX() routines as a help for this)
val sub = stmt.target.targetSubroutine(program) ?: throw AssemblyError("undefined subroutine ${stmt.target}")
val subName = asmgen.asmSymbolName(stmt.target)
if(stmt.args.isNotEmpty()) {
val sub = call.target.targetSubroutine(program) ?: throw AssemblyError("undefined subroutine ${call.target}")
val subAsmName = asmgen.asmSymbolName(call.target)
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, IndexedValue(0, sub.parameters.single()), stmt.args[0])
} else {
fun isNoClobberRisk(expr: Expression): Boolean {
if(expr is AddressOf ||
expr is NumericLiteralValue ||
expr is StringLiteralValue ||
expr is ArrayLiteralValue ||
expr is IdentifierReference)
return true
if(expr is FunctionCall) {
if(expr.target.nameInSource==listOf("lsb") || expr.target.nameInSource==listOf("msb"))
return isNoClobberRisk(expr.args[0])
if(expr.target.nameInSource==listOf("mkword"))
return isNoClobberRisk(expr.args[0]) && isNoClobberRisk(expr.args[1])
if(!isExpression && !sub.isAsmSubroutine) {
if(!optimizeIntArgsViaRegisters(sub))
throw AssemblyError("functioncall statements to non-asmsub should have been replaced by GoSub $call")
}
return false
}
when {
stmt.args.all {isNoClobberRisk(it)} -> {
// There's no risk of clobbering for these simple argument types. Optimize the register loading directly from these values.
// register assignment order: 1) cx16 virtual word registers, 2) actual CPU registers, 3) CPU Carry status flag.
val argsInfo = sub.parameters.withIndex().zip(stmt.args).zip(sub.asmParameterRegisters)
val (cx16virtualRegs, args2) = argsInfo.partition { it.second.registerOrPair in Cx16VirtualRegisters }
val (cpuRegs, statusRegs) = args2.partition { it.second.registerOrPair!=null }
for(arg in cx16virtualRegs)
argumentViaRegister(sub, arg.first.first, arg.first.second)
for(arg in cpuRegs)
argumentViaRegister(sub, arg.first.first, arg.first.second)
for(arg in statusRegs)
argumentViaRegister(sub, arg.first.first, arg.first.second)
}
else -> {
// Risk of clobbering due to complex expression args. Evaluate first, then assign registers.
registerArgsViaStackEvaluation(stmt, sub)
}
}
}
}
}
if(!sub.inline || !asmgen.options.optimize) {
asmgen.out(" jsr $subName")
} else {
if(sub.isAsmSubroutine) {
argumentsViaRegisters(sub, call)
if (sub.inline && asmgen.options.optimize) {
// inline the subroutine.
// we do this by copying the subroutine's statements at the call site.
// NOTE: *if* there is a return statement, it will be the only one, and the very last statement of the subroutine
// (this condition has been enforced by an ast check earlier)
// note: for now, this is only reliably supported for asmsubs.
if(!sub.isAsmSubroutine)
asmgen.out(" \t; inlined routine follows: ${sub.name}")
sub.statements.forEach { asmgen.translate(it as InlineAssembly) }
asmgen.out(" \t; inlined routine end: ${sub.name}")
} else {
asmgen.out(" jsr $subAsmName")
}
}
else {
if(sub.inline)
throw AssemblyError("can only reliably inline asmsub routines at this time")
asmgen.out(" \t; inlined routine follows: ${sub.name}")
val assembly = sub.statements.single() as InlineAssembly
asmgen.translate(assembly)
asmgen.out(" \t; inlined routine end: ${sub.name}")
if(optimizeIntArgsViaRegisters(sub)) {
if(sub.parameters.size==1) {
val register = if (sub.parameters[0].type in ByteDatatypes) RegisterOrPair.A else RegisterOrPair.AY
argumentViaRegister(sub, IndexedValue(0, sub.parameters[0]), call.args[0], register)
} else {
// 2 byte params, second in Y, first in A
argumentViaRegister(sub, IndexedValue(0, sub.parameters[0]), call.args[0], RegisterOrPair.A)
if(!call.args[1].isSimple)
asmgen.out(" pha")
argumentViaRegister(sub, IndexedValue(1, sub.parameters[1]), call.args[1], RegisterOrPair.Y)
if(!call.args[1].isSimple)
asmgen.out(" pla")
}
} else {
argumentsViaVariables(sub, call)
}
asmgen.out(" jsr $subAsmName")
}
// remember: dealing with the X register and/or dealing with return values is the responsibility of the caller
}
internal fun translateUnaryFunctionCallWithArgSource(target: IdentifierReference, arg: AsmAssignSource, isStatement: Boolean, scope: Subroutine): DataType {
when(val targetStmt = target.targetStatement(program)!!) {
is BuiltinFunctionPlaceholder -> {
return if(isStatement) {
asmgen.translateBuiltinFunctionCallStatement(targetStmt.name, listOf(arg), scope)
DataType.UNDEFINED
} else {
asmgen.translateBuiltinFunctionCallExpression(targetStmt.name, listOf(arg), scope)
}
}
is Subroutine -> {
val argDt = targetStmt.parameters.single().type
if(targetStmt.isAsmSubroutine) {
// argument via registers
val argRegister = targetStmt.asmParameterRegisters.single().registerOrPair!!
val assignArgument = AsmAssignment(
arg,
AsmAssignTarget.fromRegisters(argRegister, argDt in SignedDatatypes, scope, program, asmgen),
false, program.memsizer, target.position
)
asmgen.translateNormalAssignment(assignArgument)
} else {
val assignArgument: AsmAssignment =
if(optimizeIntArgsViaRegisters(targetStmt)) {
// argument goes via registers as optimization
val paramReg: RegisterOrPair = when(argDt) {
in ByteDatatypes -> RegisterOrPair.A
in WordDatatypes -> RegisterOrPair.AY
DataType.FLOAT -> RegisterOrPair.FAC1
else -> throw AssemblyError("invalid dt")
}
AsmAssignment(
arg,
AsmAssignTarget(TargetStorageKind.REGISTER, program, asmgen, argDt, scope, register = paramReg),
false, program.memsizer, target.position
)
} else {
// arg goes via parameter variable
val argVarName = asmgen.asmVariableName(targetStmt.scopedName + targetStmt.parameters.single().name)
AsmAssignment(
arg,
AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, argDt, scope, argVarName),
false, program.memsizer, target.position
)
}
asmgen.translateNormalAssignment(assignArgument)
}
if(targetStmt.shouldSaveX())
asmgen.saveRegisterLocal(CpuRegister.X, scope)
asmgen.out(" jsr ${asmgen.asmSymbolName(target)}")
if(targetStmt.shouldSaveX())
asmgen.restoreRegisterLocal(CpuRegister.X)
return if(isStatement) DataType.UNDEFINED else targetStmt.returntypes.single()
}
else -> throw AssemblyError("invalid call target")
}
}
private fun argumentsViaVariables(sub: Subroutine, call: IFunctionCall) {
for(arg in sub.parameters.withIndex().zip(call.args))
argumentViaVariable(sub, arg.first.value, arg.second)
}
private fun argumentsViaRegisters(sub: Subroutine, call: IFunctionCall) {
if(sub.parameters.size==1) {
argumentViaRegister(sub, IndexedValue(0, sub.parameters.single()), call.args[0])
} else {
if(asmgen.asmsubArgsHaveRegisterClobberRisk(call.args, sub.asmParameterRegisters)) {
registerArgsViaStackEvaluation(call, sub)
} else {
asmgen.asmsubArgsEvalOrder(sub).forEach {
val param = sub.parameters[it]
val arg = call.args[it]
argumentViaRegister(sub, IndexedValue(it, param), arg)
}
}
}
}
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.
// TODO find another way to prepare the arguments, without using the eval stack
if(sub.parameters.isEmpty())
return
// 1. load all arguments reversed onto the stack: first arg goes last (is on top).
for (arg in stmt.args.reversed())
asmgen.translateExpression(arg)
// TODO here's an alternative to the above, but for now generates bigger code due to intermediate register steps:
// for (arg in stmt.args.reversed()) {
// // note this stuff below is needed to (eventually) avoid calling asmgen.translateExpression()
// // TODO also This STILL requires the translateNormalAssignment() to be fixed to avoid stack eval for expressions...
// val dt = arg.inferType(program).getOr(DataType.UNDEFINED)
// asmgen.assignExpressionTo(arg, AsmAssignTarget(TargetStorageKind.STACK, program, asmgen, dt, sub))
// }
var argForCarry: IndexedValue<Pair<Expression, RegisterOrStatusflag>>? = null
var argForXregister: IndexedValue<Pair<Expression, RegisterOrStatusflag>>? = null
var argForAregister: IndexedValue<Pair<Expression, RegisterOrStatusflag>>? = null
@ -209,11 +295,10 @@ internal class FunctionCallAsmGen(private val program: Program, private val asmg
if(argForCarry!=null) {
val plusIdxStr = if(argForCarry.index==0) "" else "+${argForCarry.index}"
asmgen.out("""
clc
lda P8ESTACK_LO$plusIdxStr,x
beq +
sec
bcs ++
+ clc
+ php""") // push the status flags
}
@ -247,29 +332,25 @@ internal class FunctionCallAsmGen(private val program: Program, private val asmg
asmgen.out(" plp") // set the carry flag back to correct value
}
private fun argumentViaVariable(sub: Subroutine, parameter: IndexedValue<SubroutineParameter>, value: Expression) {
private fun argumentViaVariable(sub: Subroutine, parameter: SubroutineParameter, value: Expression) {
// pass parameter via a regular variable (not via registers)
val valueIDt = value.inferType(program)
if(!valueIDt.isKnown)
throw AssemblyError("unknown dt")
val valueDt = valueIDt.getOr(DataType.UNDEFINED)
if(!isArgumentTypeCompatible(valueDt, parameter.value.type))
val valueDt = valueIDt.getOrElse { throw AssemblyError("unknown dt") }
if(!isArgumentTypeCompatible(valueDt, parameter.type))
throw AssemblyError("argument type incompatible")
val varName = asmgen.asmVariableName(sub.scopedname+"."+parameter.value.name)
asmgen.assignExpressionToVariable(value, varName, parameter.value.type, sub)
val varName = asmgen.asmVariableName(sub.scopedName + parameter.name)
asmgen.assignExpressionToVariable(value, varName, parameter.type, sub)
}
private fun argumentViaRegister(sub: Subroutine, parameter: IndexedValue<SubroutineParameter>, value: Expression) {
private fun argumentViaRegister(sub: Subroutine, parameter: IndexedValue<SubroutineParameter>, value: Expression, registerOverride: RegisterOrPair? = null) {
// pass argument via a register parameter
val valueIDt = value.inferType(program)
if(!valueIDt.isKnown)
throw AssemblyError("unknown dt")
val valueDt = valueIDt.getOr(DataType.UNDEFINED)
val valueDt = valueIDt.getOrElse { throw AssemblyError("unknown dt") }
if(!isArgumentTypeCompatible(valueDt, parameter.value.type))
throw AssemblyError("argument type incompatible")
val paramRegister = sub.asmParameterRegisters[parameter.index]
val paramRegister = if(registerOverride==null) sub.asmParameterRegisters[parameter.index] else RegisterOrStatusflag(registerOverride, null)
val statusflag = paramRegister.statusflag
val register = paramRegister.registerOrPair
val requiredDt = parameter.value.type
@ -284,7 +365,7 @@ internal class FunctionCallAsmGen(private val program: Program, private val asmg
// 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 -> {
is NumericLiteral -> {
val carrySet = value.number.toInt() != 0
asmgen.out(if(carrySet) " sec" else " clc")
}
@ -292,13 +373,11 @@ internal class FunctionCallAsmGen(private val program: Program, private val asmg
val sourceName = asmgen.asmVariableName(value)
asmgen.out("""
pha
clc
lda $sourceName
beq +
sec
bcs ++
+ clc
+ pla
""")
+ pla""")
}
else -> {
asmgen.assignExpressionToRegister(value, RegisterOrPair.A)
@ -324,8 +403,10 @@ internal class FunctionCallAsmGen(private val program: Program, private val asmg
val target: AsmAssignTarget =
if(parameter.value.type in ByteDatatypes && (register==RegisterOrPair.AX || register == RegisterOrPair.AY || register==RegisterOrPair.XY || register in Cx16VirtualRegisters))
AsmAssignTarget(TargetStorageKind.REGISTER, program, asmgen, parameter.value.type, sub, register = register)
else
AsmAssignTarget.fromRegisters(register, sub, program, asmgen)
else {
val signed = parameter.value.type == DataType.BYTE || parameter.value.type == DataType.WORD
AsmAssignTarget.fromRegisters(register, signed, sub, program, asmgen)
}
val src = if(valueDt in PassByReferenceDatatypes) {
if(value is IdentifierReference) {
val addr = AddressOf(value, Position.DUMMY)

10
compiler/src/prog8/compiler/target/cpu6502/codegen/PostIncrDecrAsmGen.kt → codeGenCpu6502/src/prog8/codegen/cpu6502/PostIncrDecrAsmGen.kt
View File

@ -1,12 +1,12 @@
package prog8.compiler.target.cpu6502.codegen
package prog8.codegen.cpu6502
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.expressions.IdentifierReference
import prog8.ast.expressions.NumericLiteralValue
import prog8.ast.expressions.NumericLiteral
import prog8.ast.statements.PostIncrDecr
import prog8.ast.toHex
import prog8.compiler.AssemblyError
import prog8.compilerinterface.AssemblyError
internal class PostIncrDecrAsmGen(private val program: Program, private val asmgen: AsmGen) {
@ -41,7 +41,7 @@ internal class PostIncrDecrAsmGen(private val program: Program, private val asmg
}
targetMemory!=null -> {
when (val addressExpr = targetMemory.addressExpression) {
is NumericLiteralValue -> {
is NumericLiteral -> {
val what = addressExpr.number.toHex()
asmgen.out(if(incr) " inc $what" else " dec $what")
}
@ -83,7 +83,7 @@ internal class PostIncrDecrAsmGen(private val program: Program, private val asmg
""")
}
DataType.FLOAT -> {
asmgen.out(" lda #<$asmArrayvarname+$indexValue | ldy #>$asmArrayvarname+$indexValue")
asmgen.out(" lda #<($asmArrayvarname+$indexValue) | ldy #>($asmArrayvarname+$indexValue)")
asmgen.out(if(incr) " jsr floats.inc_var_f" else " jsr floats.dec_var_f")
}
else -> throw AssemblyError("need numeric type")

590
codeGenCpu6502/src/prog8/codegen/cpu6502/ProgramAndVarsGen.kt Normal file
View File

@ -0,0 +1,590 @@
package prog8.codegen.cpu6502
import prog8.ast.INameScope
import prog8.ast.Program
import prog8.ast.antlr.escape
import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.ast.statements.*
import prog8.ast.toHex
import prog8.codegen.cpu6502.assignment.AsmAssignTarget
import prog8.codegen.cpu6502.assignment.TargetStorageKind
import prog8.compilerinterface.*
import java.time.LocalDate
import java.time.LocalDateTime
import kotlin.math.absoluteValue
/**
* Generates the main parts of the program:
* - entry/exit code
* - initialization routines
* - blocks
* - subroutines
* - all variables (note: VarDecl ast nodes are *NOT* used anymore for this! now uses IVariablesAndConsts data tables!)
*/
internal class ProgramAndVarsGen(
val program: Program,
val variables: IVariablesAndConsts,
val options: CompilationOptions,
val errors: IErrorReporter,
private val functioncallAsmGen: FunctionCallAsmGen,
private val asmgen: AsmGen,
private val allocator: VariableAllocator,
private val zeropage: Zeropage
) {
private val compTarget = options.compTarget
private val callGraph = CallGraph(program, true)
private val blockVariableInitializers = program.allBlocks.associateWith { it.statements.filterIsInstance<Assignment>() }
internal fun generate() {
val allInitializers = blockVariableInitializers.asSequence().flatMap { it.value }
require(allInitializers.all { it.origin==AssignmentOrigin.VARINIT }) {"all block-level assignments must be a variable initializer"}
allocator.allocateZeropageVariables()
header()
val allBlocks = program.allBlocks
if(allBlocks.first().name != "main")
throw AssemblyError("first block should be 'main'")
if(errors.noErrors()) {
program.allBlocks.forEach { block2asm(it) }
memorySlabs()
footer()
}
}
private fun header() {
val ourName = this.javaClass.name
val cpu = when(compTarget.machine.cpu) {
CpuType.CPU6502 -> "6502"
CpuType.CPU65c02 -> "w65c02"
else -> "unsupported"
}
asmgen.out("; $cpu assembly code for '${program.name}'")
asmgen.out("; generated by $ourName on ${LocalDateTime.now().withNano(0)}")
asmgen.out("; assembler syntax is for the 64tasm cross-assembler")
asmgen.out("; output options: output=${options.output} launcher=${options.launcher} zp=${options.zeropage}")
asmgen.out("")
asmgen.out(".cpu '$cpu'\n.enc 'none'\n")
program.actualLoadAddress = program.definedLoadAddress
if (program.actualLoadAddress == 0u) // fix load address
program.actualLoadAddress = if (options.launcher == LauncherType.BASIC)
compTarget.machine.BASIC_LOAD_ADDRESS else compTarget.machine.RAW_LOAD_ADDRESS
// the global prog8 variables needed
val zp = zeropage
asmgen.out("P8ZP_SCRATCH_B1 = ${zp.SCRATCH_B1}")
asmgen.out("P8ZP_SCRATCH_REG = ${zp.SCRATCH_REG}")
asmgen.out("P8ZP_SCRATCH_W1 = ${zp.SCRATCH_W1} ; word")
asmgen.out("P8ZP_SCRATCH_W2 = ${zp.SCRATCH_W2} ; word")
asmgen.out("P8ESTACK_LO = ${compTarget.machine.ESTACK_LO.toHex()}")
asmgen.out("P8ESTACK_HI = ${compTarget.machine.ESTACK_HI.toHex()}")
when {
options.launcher == LauncherType.BASIC -> {
if (program.actualLoadAddress != options.compTarget.machine.BASIC_LOAD_ADDRESS)
throw AssemblyError("BASIC output must have correct load address")
asmgen.out("; ---- basic program with sys call ----")
asmgen.out("* = ${program.actualLoadAddress.toHex()}")
val year = LocalDate.now().year
asmgen.out(" .word (+), $year")
asmgen.out(" .null $9e, format(' %d ', prog8_entrypoint), $3a, $8f, ' prog8'")
asmgen.out("+\t.word 0")
asmgen.out("prog8_entrypoint\t; assembly code starts here\n")
if(!options.noSysInit)
asmgen.out(" jsr ${compTarget.name}.init_system")
asmgen.out(" jsr ${compTarget.name}.init_system_phase2")
}
options.output == OutputType.PRG -> {
asmgen.out("; ---- program without basic sys call ----")
asmgen.out("* = ${program.actualLoadAddress.toHex()}\n")
if(!options.noSysInit)
asmgen.out(" jsr ${compTarget.name}.init_system")
asmgen.out(" jsr ${compTarget.name}.init_system_phase2")
}
options.output == OutputType.RAW -> {
asmgen.out("; ---- raw assembler program ----")
asmgen.out("* = ${program.actualLoadAddress.toHex()}\n")
}
}
if(options.zeropage !in arrayOf(ZeropageType.BASICSAFE, ZeropageType.DONTUSE)) {
asmgen.out("""
; zeropage is clobbered so we need to reset the machine at exit
lda #>sys.reset_system
pha
lda #<sys.reset_system
pha""")
}
// make sure that on the cx16 and c64, basic rom is banked in again when we exit the program
when(compTarget.name) {
"cx16" -> {
if(options.floats)
asmgen.out(" lda #4 | sta $01") // to use floats, make sure Basic rom is banked in
asmgen.out(" jsr main.start | lda #4 | sta $01 | rts")
}
"c64" -> asmgen.out(" jsr main.start | lda #31 | sta $01 | rts")
else -> asmgen.jmp("main.start")
}
}
private fun memorySlabs() {
asmgen.out("; memory slabs")
asmgen.out("prog8_slabs\t.block")
for((name, info) in allocator.memorySlabs) {
if(info.second>1u)
asmgen.out("\t.align ${info.second.toHex()}")
asmgen.out("$name\t.fill ${info.first}")
}
asmgen.out("\t.bend")
}
private fun footer() {
// the global list of all floating point constants for the whole program
asmgen.out("; global float constants")
for (flt in allocator.globalFloatConsts) {
val floatFill = compTarget.machine.getFloat(flt.key).makeFloatFillAsm()
val floatvalue = flt.key
asmgen.out("${flt.value}\t.byte $floatFill ; float $floatvalue")
}
// program end
asmgen.out("prog8_program_end\t; end of program label for progend()")
}
private fun block2asm(block: Block) {
asmgen.out("")
asmgen.out("; ---- block: '${block.name}' ----")
if(block.address!=null)
asmgen.out("* = ${block.address!!.toHex()}")
else {
if("align_word" in block.options())
asmgen.out("\t.align 2")
else if("align_page" in block.options())
asmgen.out("\t.align $100")
}
asmgen.out("${block.name}\t" + (if("force_output" in block.options()) ".block\n" else ".proc\n"))
asmgen.outputSourceLine(block)
zeropagevars2asm(block)
memdefsAndConsts2asm(block)
asmsubs2asm(block.statements)
nonZpVariables2asm(block)
asmgen.out("")
asmgen.out("; subroutines in this block")
// First translate regular statements, and then put the subroutines at the end.
// (regular statements = everything except the initialization assignments;
// these will be part of the prog8_init_vars init routine generated below)
val initializers = blockVariableInitializers.getValue(block)
val statements = block.statements.filterNot { it in initializers }
val (subroutine, stmts) = statements.partition { it is Subroutine }
stmts.forEach { asmgen.translate(it) }
subroutine.forEach { asmgen.translate(it) }
if(!options.dontReinitGlobals) {
// generate subroutine to initialize block-level (global) variables
if (initializers.isNotEmpty()) {
asmgen.out("prog8_init_vars\t.proc\n")
initializers.forEach { assign -> asmgen.translate(assign) }
asmgen.out(" rts\n .pend")
}
}
asmgen.out(if("force_output" in block.options()) "\n\t.bend\n" else "\n\t.pend\n")
}
internal fun translateSubroutine(sub: Subroutine) {
var onlyVariables = false
if(sub.inline) {
if(options.optimize) {
if(sub.isAsmSubroutine || callGraph.unused(sub))
return
// from an inlined subroutine only the local variables are generated,
// all other code statements are omitted in the subroutine itself
// (they've been inlined at the call site, remember?)
onlyVariables = true
}
}
asmgen.out("")
if(sub.isAsmSubroutine) {
if(sub.asmAddress!=null)
return // already done at the memvars section
// asmsub with most likely just an inline asm in it
asmgen.out("${sub.name}\t.proc")
sub.statements.forEach { asmgen.translate(it) }
asmgen.out(" .pend\n")
} else {
// regular subroutine
asmgen.out("${sub.name}\t.proc")
zeropagevars2asm(sub)
memdefsAndConsts2asm(sub)
asmsubs2asm(sub.statements)
// the main.start subroutine is the program's entrypoint and should perform some initialization logic
if(sub.name=="start" && sub.definingBlock.name=="main")
entrypointInitialization()
if(functioncallAsmGen.optimizeIntArgsViaRegisters(sub)) {
asmgen.out("; simple int arg(s) passed via register(s)")
if(sub.parameters.size==1) {
val dt = sub.parameters[0].type
val target = AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, dt, sub, variableAsmName = sub.parameters[0].name)
if(dt in ByteDatatypes)
asmgen.assignRegister(RegisterOrPair.A, target)
else
asmgen.assignRegister(RegisterOrPair.AY, target)
} else {
require(sub.parameters.size==2)
// 2 simple byte args, first in A, second in Y
val target1 = AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, sub.parameters[0].type, sub, variableAsmName = sub.parameters[0].name)
val target2 = AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, sub.parameters[1].type, sub, variableAsmName = sub.parameters[1].name)
asmgen.assignRegister(RegisterOrPair.A, target1)
asmgen.assignRegister(RegisterOrPair.Y, target2)
}
}
if(!onlyVariables) {
asmgen.out("; statements")
sub.statements.forEach { asmgen.translate(it) }
}
asmgen.out("; variables")
val asmGenInfo = allocator.subroutineExtra(sub)
for((dt, name, addr) in asmGenInfo.extraVars) {
if(addr!=null)
asmgen.out("$name = $addr")
else when(dt) {
DataType.UBYTE -> asmgen.out("$name .byte 0")
DataType.UWORD -> asmgen.out("$name .word 0")
else -> throw AssemblyError("weird dt")
}
}
if(asmGenInfo.usedRegsaveA) // will probably never occur
asmgen.out("prog8_regsaveA .byte 0")
if(asmGenInfo.usedRegsaveX)
asmgen.out("prog8_regsaveX .byte 0")
if(asmGenInfo.usedRegsaveY)
asmgen.out("prog8_regsaveY .byte 0")
if(asmGenInfo.usedFloatEvalResultVar1)
asmgen.out("$subroutineFloatEvalResultVar1 .byte 0,0,0,0,0")
if(asmGenInfo.usedFloatEvalResultVar2)
asmgen.out("$subroutineFloatEvalResultVar2 .byte 0,0,0,0,0")
nonZpVariables2asm(sub)
asmgen.out(" .pend\n")
}
}
private fun entrypointInitialization() {
asmgen.out("; program startup initialization")
asmgen.out(" cld")
if(!options.dontReinitGlobals) {
blockVariableInitializers.forEach {
if (it.value.isNotEmpty())
asmgen.out(" jsr ${it.key.name}.prog8_init_vars")
}
}
// string and array variables in zeropage that have initializer value, should be initialized
val stringVarsWithInitInZp = allocator.zeropageVars.filter { it.value.dt==DataType.STR && it.value.initialStringValue!=null }
val arrayVarsWithInitInZp = allocator.zeropageVars.filter { it.value.dt in ArrayDatatypes && it.value.initialArrayValue!=null }
if(stringVarsWithInitInZp.isNotEmpty() || arrayVarsWithInitInZp.isNotEmpty()) {
asmgen.out("; zp str and array initializations")
stringVarsWithInitInZp.forEach {
val name = asmgen.asmVariableName(it.key)
asmgen.out("""
lda #<${name}
ldy #>${name}
sta P8ZP_SCRATCH_W1
sty P8ZP_SCRATCH_W1+1
lda #<${name}_init_value
ldy #>${name}_init_value
jsr prog8_lib.strcpy""")
}
arrayVarsWithInitInZp.forEach {
val size = it.value.size
val name = asmgen.asmVariableName(it.key)
asmgen.out("""
lda #<${name}_init_value
ldy #>${name}_init_value
sta cx16.r0L
sty cx16.r0H
lda #<${name}
ldy #>${name}
sta cx16.r1L
sty cx16.r1H
lda #<$size
ldy #>$size
jsr sys.memcopy""")
}
asmgen.out(" jmp +")
}
stringVarsWithInitInZp.forEach {
val varname = asmgen.asmVariableName(it.key)+"_init_value"
val stringvalue = it.value.initialStringValue!!
outputStringvar(varname, it.value.dt, stringvalue.encoding, stringvalue.value)
}
arrayVarsWithInitInZp.forEach {
val varname = asmgen.asmVariableName(it.key)+"_init_value"
arrayVariable2asm(varname, it.value.dt, it.value.initialArrayValue!!, null)
}
asmgen.out("""+ tsx
stx prog8_lib.orig_stackpointer ; required for sys.exit()
ldx #255 ; init estack ptr
clv
clc""")
}
private fun zeropagevars2asm(scope: INameScope) {
val zpVariables = allocator.zeropageVars.filter { it.value.originalScope==scope }
for ((scopedName, zpvar) in zpVariables) {
if (scopedName.size == 2 && scopedName[0] == "cx16" && scopedName[1][0] == 'r' && scopedName[1][1].isDigit())
continue // The 16 virtual registers of the cx16 are not actual variables in zp, they're memory mapped
asmgen.out("${scopedName.last()} \t= ${zpvar.address} \t; zp ${zpvar.dt}")
}
}
private fun nonZpVariables2asm(block: Block) {
val variables = variables.blockVars[block]?.filter { !allocator.isZpVar(it.scopedname) } ?: emptyList()
nonZpVariables2asm(variables)
}
private fun nonZpVariables2asm(sub: Subroutine) {
val variables = variables.subroutineVars[sub]?.filter { !allocator.isZpVar(it.scopedname) } ?: emptyList()
nonZpVariables2asm(variables)
}
private fun nonZpVariables2asm(variables: List<IVariablesAndConsts.StaticVariable>) {
asmgen.out("")
asmgen.out("; non-zeropage variables")
val (stringvars, othervars) = variables.partition { it.type==DataType.STR }
stringvars.forEach {
val stringvalue = it.initialValue as StringLiteral
outputStringvar(it.scopedname.last(), it.type, stringvalue.encoding, stringvalue.value)
}
othervars.sortedBy { it.type }.forEach {
staticVariable2asm(it)
}
}
private fun staticVariable2asm(variable: IVariablesAndConsts.StaticVariable) {
val name = variable.scopedname.last()
val value = variable.initialValue
val staticValue: Number =
if(value!=null) {
if(value is NumericLiteral) {
if(value.type== DataType.FLOAT)
value.number
else
value.number.toInt()
} else {
if(variable.type in NumericDatatypes)
throw AssemblyError("can only deal with constant numeric values for global vars")
else 0
}
} else 0
when (variable.type) {
DataType.UBYTE -> asmgen.out("$name\t.byte ${staticValue.toHex()}")
DataType.BYTE -> asmgen.out("$name\t.char $staticValue")
DataType.UWORD -> asmgen.out("$name\t.word ${staticValue.toHex()}")
DataType.WORD -> asmgen.out("$name\t.sint $staticValue")
DataType.FLOAT -> {
if(staticValue==0) {
asmgen.out("$name\t.byte 0,0,0,0,0 ; float")
} else {
val floatFill = compTarget.machine.getFloat(staticValue).makeFloatFillAsm()
asmgen.out("$name\t.byte $floatFill ; float $staticValue")
}
}
DataType.STR -> {
throw AssemblyError("all string vars should have been interned into prog")
}
in ArrayDatatypes -> arrayVariable2asm(name, variable.type, value as? ArrayLiteral, variable.arraysize)
else -> {
throw AssemblyError("weird dt")
}
}
}
private fun arrayVariable2asm(varname: String, dt: DataType, value: ArrayLiteral?, orNumberOfZeros: Int?) {
when(dt) {
DataType.ARRAY_UB -> {
val data = makeArrayFillDataUnsigned(dt, value, orNumberOfZeros)
if (data.size <= 16)
asmgen.out("$varname\t.byte ${data.joinToString()}")
else {
asmgen.out(varname)
for (chunk in data.chunked(16))
asmgen.out(" .byte " + chunk.joinToString())
}
}
DataType.ARRAY_B -> {
val data = makeArrayFillDataSigned(dt, value, orNumberOfZeros)
if (data.size <= 16)
asmgen.out("$varname\t.char ${data.joinToString()}")
else {
asmgen.out(varname)
for (chunk in data.chunked(16))
asmgen.out(" .char " + chunk.joinToString())
}
}
DataType.ARRAY_UW -> {
val data = makeArrayFillDataUnsigned(dt, value, orNumberOfZeros)
if (data.size <= 16)
asmgen.out("$varname\t.word ${data.joinToString()}")
else {
asmgen.out(varname)
for (chunk in data.chunked(16))
asmgen.out(" .word " + chunk.joinToString())
}
}
DataType.ARRAY_W -> {
val data = makeArrayFillDataSigned(dt, value, orNumberOfZeros)
if (data.size <= 16)
asmgen.out("$varname\t.sint ${data.joinToString()}")
else {
asmgen.out(varname)
for (chunk in data.chunked(16))
asmgen.out(" .sint " + chunk.joinToString())
}
}
DataType.ARRAY_F -> {
val array = value?.value ?:
Array(orNumberOfZeros!!) { defaultZero(ArrayToElementTypes.getValue(dt), Position.DUMMY) }
val floatFills = array.map {
val number = (it as NumericLiteral).number
compTarget.machine.getFloat(number).makeFloatFillAsm()
}
asmgen.out(varname)
for (f in array.zip(floatFills))
asmgen.out(" .byte ${f.second} ; float ${f.first}")
}
else -> throw AssemblyError("require array dt")
}
}
private fun memdefsAndConsts2asm(block: Block) {
val mvs = variables.blockMemvars[block] ?: emptySet()
val consts = variables.blockConsts[block] ?: emptySet()
memdefsAndConsts2asm(mvs, consts)
}
private fun memdefsAndConsts2asm(sub: Subroutine) {
val mvs = variables.subroutineMemvars[sub] ?: emptySet()
val consts = variables.subroutineConsts[sub] ?: emptySet()
memdefsAndConsts2asm(mvs, consts)
}
private fun memdefsAndConsts2asm(
memvars: Set<IVariablesAndConsts.MemoryMappedVariable>,
consts: Set<IVariablesAndConsts.ConstantNumberSymbol>
) {
memvars.forEach {
asmgen.out(" ${it.scopedname.last()} = ${it.address.toHex()}")
}
consts.forEach {
if(it.type==DataType.FLOAT)
asmgen.out(" ${it.scopedname.last()} = ${it.value}")
else
asmgen.out(" ${it.scopedname.last()} = ${it.value.toHex()}")
}
}
private fun asmsubs2asm(statements: List<Statement>) {
statements
.filter { it is Subroutine && it.isAsmSubroutine && it.asmAddress!=null }
.forEach { asmsub ->
asmsub as Subroutine
asmgen.out(" ${asmsub.name} = ${asmsub.asmAddress!!.toHex()}")
}
}
private fun outputStringvar(varname: String, dt: DataType, encoding: Encoding, value: String) {
asmgen.out("$varname\t; $dt $encoding:\"${escape(value).replace("\u0000", "<NULL>")}\"")
val bytes = compTarget.encodeString(value, encoding).plus(0.toUByte())
val outputBytes = bytes.map { "$" + it.toString(16).padStart(2, '0') }
for (chunk in outputBytes.chunked(16))
asmgen.out(" .byte " + chunk.joinToString())
}
private fun makeArrayFillDataUnsigned(dt: DataType, value: ArrayLiteral?, orNumberOfZeros: Int?): List<String> {
val array = value?.value ?:
Array(orNumberOfZeros!!) { defaultZero(ArrayToElementTypes.getValue(dt), Position.DUMMY) }
return when (dt) {
DataType.ARRAY_UB ->
// byte array can never contain pointer-to types, so treat values as all integers
array.map {
val number = (it as NumericLiteral).number.toInt()
"$"+number.toString(16).padStart(2, '0')
}
DataType.ARRAY_UW -> array.map {
when (it) {
is NumericLiteral -> {
"$" + it.number.toInt().toString(16).padStart(4, '0')
}
is AddressOf -> {
asmgen.asmSymbolName(it.identifier)
}
is IdentifierReference -> {
asmgen.asmSymbolName(it)
}
else -> throw AssemblyError("weird array elt dt")
}
}
else -> throw AssemblyError("invalid dt")
}
}
private fun makeArrayFillDataSigned(dt: DataType, value: ArrayLiteral?, orNumberOfZeros: Int?): List<String> {
val array = value?.value ?:
Array(orNumberOfZeros!!) { defaultZero(ArrayToElementTypes.getValue(dt), Position.DUMMY) }
return when (dt) {
DataType.ARRAY_UB ->
// byte array can never contain pointer-to types, so treat values as all integers
array.map {
val number = (it as NumericLiteral).number.toInt()
"$"+number.toString(16).padStart(2, '0')
}
DataType.ARRAY_B ->
// byte array can never contain pointer-to types, so treat values as all integers
array.map {
val number = (it as NumericLiteral).number.toInt()
val hexnum = number.absoluteValue.toString(16).padStart(2, '0')
if(number>=0)
"$$hexnum"
else
"-$$hexnum"
}
DataType.ARRAY_UW -> array.map {
val number = (it as NumericLiteral).number.toInt()
"$" + number.toString(16).padStart(4, '0')
}
DataType.ARRAY_W -> array.map {
val number = (it as NumericLiteral).number.toInt()
val hexnum = number.absoluteValue.toString(16).padStart(4, '0')
if(number>=0)
"$$hexnum"
else
"-$$hexnum"
}
else -> throw AssemblyError("invalid dt")
}
}
}

166
codeGenCpu6502/src/prog8/codegen/cpu6502/VariableAllocator.kt Normal file
View File

@ -0,0 +1,166 @@
package prog8.codegen.cpu6502
import com.github.michaelbull.result.fold
import com.github.michaelbull.result.onSuccess
import prog8.ast.base.ArrayDatatypes
import prog8.ast.base.DataType
import prog8.ast.base.IntegerDatatypes
import prog8.ast.expressions.StringLiteral
import prog8.ast.statements.Subroutine
import prog8.ast.statements.ZeropageWish
import prog8.compilerinterface.*
internal class VariableAllocator(private val vars: IVariablesAndConsts,
private val options: CompilationOptions,
private val errors: IErrorReporter) {
private val zeropage = options.compTarget.machine.zeropage
private val subroutineExtras = mutableMapOf<Subroutine, SubroutineExtraAsmInfo>()
private val memorySlabsInternal = mutableMapOf<String, Pair<UInt, UInt>>()
internal val memorySlabs: Map<String, Pair<UInt, UInt>> = memorySlabsInternal
internal val globalFloatConsts = mutableMapOf<Double, String>() // all float values in the entire program (value -> varname)
internal val zeropageVars: Map<List<String>, Zeropage.ZpAllocation> = zeropage.allocatedVariables
internal fun getMemorySlab(name: String) = memorySlabsInternal[name]
internal fun allocateMemorySlab(name: String, size: UInt, align: UInt) {
memorySlabsInternal[name] = Pair(size, align)
}
/**
* Allocate variables into the Zeropage.
* The result should be retrieved from the current machine's zeropage object!
*/
internal fun allocateZeropageVariables() {
if(options.zeropage== ZeropageType.DONTUSE)
return
val allVariables = (
vars.blockVars.asSequence().flatMap { it.value } +
vars.subroutineVars.asSequence().flatMap { it.value }
).toList()
val numberOfAllocatableVariables = allVariables.size
val varsRequiringZp = allVariables.filter { it.zp == ZeropageWish.REQUIRE_ZEROPAGE }
val varsPreferringZp = allVariables.filter { it.zp == ZeropageWish.PREFER_ZEROPAGE }
val varsDontCare = allVariables.filter { it.zp == ZeropageWish.DONTCARE }
val numberOfExplicitNonZpVariables = allVariables.count { it.zp == ZeropageWish.NOT_IN_ZEROPAGE }
require(varsDontCare.size + varsRequiringZp.size + varsPreferringZp.size + numberOfExplicitNonZpVariables == numberOfAllocatableVariables)
var numVariablesAllocatedInZP: Int = 0
var numberOfNonIntegerVariables: Int = 0
varsRequiringZp.forEach { variable ->
val numElements = numArrayElements(variable)
val result = zeropage.allocate(
variable.scopedname,
variable.type,
variable.scope,
numElements,
variable.initialValue,
variable.position,
errors
)
result.fold(
success = {
numVariablesAllocatedInZP++
},
failure = {
errors.err(it.message!!, variable.position)
}
)
}
if(errors.noErrors()) {
varsPreferringZp.forEach { variable ->
val numElements = numArrayElements(variable)
val result = zeropage.allocate(
variable.scopedname,
variable.type,
variable.scope,
numElements,
variable.initialValue,
variable.position,
errors
)
result.onSuccess { numVariablesAllocatedInZP++ }
// no need to check for allocation error, if there is one, just allocate in normal system ram.
}
// try to allocate any other interger variables into the zeropage until it is full.
// TODO some form of intelligent priorization? most often used variables first? loopcounter vars first? ...?
if(errors.noErrors()) {
for (variable in varsDontCare) {
if(variable.type in IntegerDatatypes) {
if(zeropage.free.isEmpty()) {
break
} else {
val numElements = numArrayElements(variable)
val result = zeropage.allocate(
variable.scopedname,
variable.type,
variable.scope,
numElements,
variable.initialValue,
variable.position,
errors
)
result.onSuccess { numVariablesAllocatedInZP++ }
}
} else
numberOfNonIntegerVariables++
}
}
}
println(" number of allocated vars: $numberOfAllocatableVariables")
println(" put into zeropage: $numVariablesAllocatedInZP, non-zp allocatable: ${numberOfNonIntegerVariables+numberOfExplicitNonZpVariables}")
println(" zeropage free space: ${zeropage.free.size} bytes")
}
internal fun isZpVar(scopedName: List<String>) = scopedName in zeropage.allocatedVariables
private fun numArrayElements(variable: IVariablesAndConsts.StaticVariable) =
when(variable.type) {
DataType.STR -> (variable.initialValue as StringLiteral).value.length
in ArrayDatatypes -> variable.arraysize!!
else -> null
}
internal fun subroutineExtra(sub: Subroutine): SubroutineExtraAsmInfo {
var extra = subroutineExtras[sub]
return if(extra==null) {
extra = SubroutineExtraAsmInfo()
subroutineExtras[sub] = extra
extra
}
else
extra
}
internal fun getFloatAsmConst(number: Double): String {
val asmName = globalFloatConsts[number]
if(asmName!=null)
return asmName
val newName = "prog8_float_const_${globalFloatConsts.size}"
globalFloatConsts[number] = newName
return newName
}
}
/**
* This class contains various attributes that influence the assembly code generator.
* Conceptually it should be part of any INameScope.
* But because the resulting code only creates "real" scopes on a subroutine level,
* it's more consistent to only define these attributes on a Subroutine node.
*/
internal class SubroutineExtraAsmInfo {
var usedRegsaveA = false
var usedRegsaveX = false
var usedRegsaveY = false
var usedFloatEvalResultVar1 = false
var usedFloatEvalResultVar2 = false
val extraVars = mutableListOf<Triple<DataType, String, UInt?>>()
}

83
compiler/src/prog8/compiler/target/cpu6502/codegen/assignment/AsmAssignment.kt → codeGenCpu6502/src/prog8/codegen/cpu6502/assignment/AsmAssignment.kt
View File

@ -1,12 +1,12 @@
package prog8.compiler.target.cpu6502.codegen.assignment
package prog8.codegen.cpu6502.assignment
import prog8.ast.IMemSizer
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.ast.statements.*
import prog8.compiler.AssemblyError
import prog8.compiler.target.cpu6502.codegen.AsmGen
import prog8.codegen.cpu6502.AsmGen
import prog8.compilerinterface.AssemblyError
import prog8.compilerinterface.IMemSizer
internal enum class TargetStorageKind {
@ -39,13 +39,14 @@ internal class AsmAssignTarget(val kind: TargetStorageKind,
val origAstTarget: AssignTarget? = null
)
{
val constMemoryAddress by lazy { memory?.addressExpression?.constValue(program)?.number?.toInt() ?: 0}
val constArrayIndexValue by lazy { array?.indexer?.constIndex() }
val asmVarname: String
get() = if(array==null)
val constMemoryAddress by lazy { memory?.addressExpression?.constValue(program)?.number?.toUInt() ?: 0u}
val constArrayIndexValue by lazy { array?.indexer?.constIndex()?.toUInt() }
val asmVarname: String by lazy {
if (array == null)
variableAsmName!!
else
asmgen.asmVariableName(array.arrayvar)
}
lateinit var origAssign: AsmAssignment
@ -55,27 +56,40 @@ internal class AsmAssignTarget(val kind: TargetStorageKind,
}
companion object {
fun fromAstAssignment(assign: Assignment, program: Program, asmgen: AsmGen): AsmAssignTarget = with(assign.target) {
fun fromAstAssignment(assign: Assignment, program: Program, asmgen: AsmGen): AsmAssignTarget {
with(assign.target) {
val idt = inferType(program)
if(!idt.isKnown)
throw AssemblyError("unknown dt")
val dt = idt.getOr(DataType.UNDEFINED)
val dt = idt.getOrElse { throw AssemblyError("unknown dt") }
when {
identifier != null -> AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, dt, assign.definingSubroutine, variableAsmName = asmgen.asmVariableName(identifier!!), origAstTarget = this)
arrayindexed != null -> AsmAssignTarget(TargetStorageKind.ARRAY, program, asmgen, dt, assign.definingSubroutine, array = arrayindexed, origAstTarget = this)
memoryAddress != null -> AsmAssignTarget(TargetStorageKind.MEMORY, program, asmgen, dt, assign.definingSubroutine, memory = memoryAddress, origAstTarget = this)
identifier != null -> {
val parameter = identifier!!.targetVarDecl(program)?.subroutineParameter
if (parameter!=null) {
val sub = parameter.definingSubroutine!!
if (sub.isAsmSubroutine) {
val reg = sub.asmParameterRegisters[sub.parameters.indexOf(parameter)]
if(reg.statusflag!=null)
throw AssemblyError("can't assign value to processor statusflag directly")
else
return AsmAssignTarget(TargetStorageKind.REGISTER, program, asmgen, dt, assign.definingSubroutine, register=reg.registerOrPair, origAstTarget = this)
}
}
return AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, dt, assign.definingSubroutine, variableAsmName = asmgen.asmVariableName(identifier!!), origAstTarget = this)
}
arrayindexed != null -> return AsmAssignTarget(TargetStorageKind.ARRAY, program, asmgen, dt, assign.definingSubroutine, array = arrayindexed, origAstTarget = this)
memoryAddress != null -> return AsmAssignTarget(TargetStorageKind.MEMORY, program, asmgen, dt, assign.definingSubroutine, memory = memoryAddress, origAstTarget = this)
else -> throw AssemblyError("weird target")
}
}
}
fun fromRegisters(registers: RegisterOrPair, scope: Subroutine?, program: Program, asmgen: AsmGen): AsmAssignTarget =
fun fromRegisters(registers: RegisterOrPair, signed: Boolean, scope: Subroutine?, program: Program, asmgen: AsmGen): AsmAssignTarget =
when(registers) {
RegisterOrPair.A,
RegisterOrPair.X,
RegisterOrPair.Y -> AsmAssignTarget(TargetStorageKind.REGISTER, program, asmgen, DataType.UBYTE, scope, register = registers)
RegisterOrPair.Y -> AsmAssignTarget(TargetStorageKind.REGISTER, program, asmgen, if(signed) DataType.BYTE else DataType.UBYTE, scope, register = registers)
RegisterOrPair.AX,
RegisterOrPair.AY,
RegisterOrPair.XY -> AsmAssignTarget(TargetStorageKind.REGISTER, program, asmgen, DataType.UWORD, scope, register = registers)
RegisterOrPair.XY -> AsmAssignTarget(TargetStorageKind.REGISTER, program, asmgen, if(signed) DataType.WORD else DataType.UWORD, scope, register = registers)
RegisterOrPair.FAC1,
RegisterOrPair.FAC2 -> AsmAssignTarget(TargetStorageKind.REGISTER, program, asmgen, DataType.FLOAT, scope, register = registers)
RegisterOrPair.R0,
@ -93,7 +107,7 @@ internal class AsmAssignTarget(val kind: TargetStorageKind,
RegisterOrPair.R12,
RegisterOrPair.R13,
RegisterOrPair.R14,
RegisterOrPair.R15 -> AsmAssignTarget(TargetStorageKind.REGISTER, program, asmgen, DataType.UWORD, scope, register = registers)
RegisterOrPair.R15 -> AsmAssignTarget(TargetStorageKind.REGISTER, program, asmgen, if(signed) DataType.WORD else DataType.UWORD, scope, register = registers)
}
}
}
@ -106,12 +120,12 @@ internal class AsmAssignSource(val kind: SourceStorageKind,
val array: ArrayIndexedExpression? = null,
val memory: DirectMemoryRead? = null,
val register: RegisterOrPair? = null,
val number: NumericLiteralValue? = null,
val number: NumericLiteral? = null,
val expression: Expression? = null
)
{
val constMemoryAddress by lazy { memory?.addressExpression?.constValue(program)?.number?.toInt() ?: 0}
val constArrayIndexValue by lazy { array?.indexer?.constIndex() }
val constMemoryAddress by lazy { memory?.addressExpression?.constValue(program)?.number?.toUInt() ?: 0u}
val constArrayIndexValue by lazy { array?.indexer?.constIndex()?.toUInt() }
val asmVarname: String
get() = if(array==null)
@ -128,10 +142,13 @@ internal class AsmAssignSource(val kind: SourceStorageKind,
return AsmAssignSource(SourceStorageKind.LITERALNUMBER, program, asmgen, cv.type, number = cv)
return when(value) {
is NumericLiteralValue -> AsmAssignSource(SourceStorageKind.LITERALNUMBER, program, asmgen, 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 NumericLiteral -> throw AssemblyError("should have been constant value")
is StringLiteral -> throw AssemblyError("string literal value should not occur anymore for asm generation")
is ArrayLiteral -> throw AssemblyError("array literal value should not occur anymore for asm generation")
is IdentifierReference -> {
val parameter = value.targetVarDecl(program)?.subroutineParameter
if(parameter!=null && parameter.definingSubroutine!!.isAsmSubroutine)
throw AssemblyError("can't assign from a asmsub register parameter $value ${value.position}")
val dt = value.inferType(program).getOr(DataType.UNDEFINED)
val varName=asmgen.asmVariableName(value)
// special case: "cx16.r[0-15]" are 16-bits virtual registers of the commander X16 system
@ -147,10 +164,10 @@ internal class AsmAssignSource(val kind: SourceStorageKind,
AsmAssignSource(SourceStorageKind.MEMORY, program, asmgen, DataType.UBYTE, memory = value)
}
is ArrayIndexedExpression -> {
val dt = value.inferType(program).getOr(DataType.UNDEFINED)
val dt = value.inferType(program).getOrElse { throw AssemblyError("unknown dt") }
AsmAssignSource(SourceStorageKind.ARRAY, program, asmgen, dt, array = value)
}
is FunctionCall -> {
is FunctionCallExpression -> {
when (val sub = value.target.targetStatement(program)) {
is Subroutine -> {
val returnType = sub.returntypes.zip(sub.asmReturnvaluesRegisters).firstOrNull { rr -> rr.second.registerOrPair != null || rr.second.statusflag!=null }?.first
@ -158,11 +175,9 @@ internal class AsmAssignSource(val kind: SourceStorageKind,
AsmAssignSource(SourceStorageKind.EXPRESSION, program, asmgen, returnType, expression = value)
}
is BuiltinFunctionStatementPlaceholder -> {
is BuiltinFunctionPlaceholder -> {
val returnType = value.inferType(program)
if(!returnType.isKnown)
throw AssemblyError("unknown dt")
AsmAssignSource(SourceStorageKind.EXPRESSION, program, asmgen, returnType.getOr(DataType.UNDEFINED), expression = value)
AsmAssignSource(SourceStorageKind.EXPRESSION, program, asmgen, returnType.getOrElse { throw AssemblyError("unknown dt") }, expression = value)
}
else -> {
throw AssemblyError("weird call")
@ -171,9 +186,7 @@ internal class AsmAssignSource(val kind: SourceStorageKind,
}
else -> {
val dt = value.inferType(program)
if(!dt.isKnown)
throw AssemblyError("unknown dt")
AsmAssignSource(SourceStorageKind.EXPRESSION, program, asmgen, dt.getOr(DataType.UNDEFINED), expression = value)
AsmAssignSource(SourceStorageKind.EXPRESSION, program, asmgen, dt.getOrElse { throw AssemblyError("unknown dt") }, expression = value)
}
}
}
@ -208,7 +221,7 @@ internal class AsmAssignment(val source: AsmAssignSource,
if(target.register !in arrayOf(RegisterOrPair.XY, RegisterOrPair.AX, RegisterOrPair.AY))
require(source.datatype != DataType.UNDEFINED) { "must not be placeholder/undefined datatype" }
require(memsizer.memorySize(source.datatype) <= memsizer.memorySize(target.datatype)) {
"source storage size must be less or equal to target datatype storage size"
"source dt size must be less or equal to target dt size at $position"
}
}
}

564
compiler/src/prog8/compiler/target/cpu6502/codegen/assignment/AssignmentAsmGen.kt → codeGenCpu6502/src/prog8/codegen/cpu6502/assignment/AssignmentAsmGen.kt
View File

@ -1,23 +1,22 @@
package prog8.compiler.target.cpu6502.codegen.assignment
package prog8.codegen.cpu6502.assignment
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.ast.statements.*
import prog8.ast.toHex
import prog8.compiler.AssemblyError
import prog8.compiler.functions.BuiltinFunctions
import prog8.compiler.functions.builtinFunctionReturnType
import prog8.compiler.target.CpuType
import prog8.compiler.target.cpu6502.codegen.AsmGen
import prog8.compiler.target.cpu6502.codegen.ExpressionsAsmGen
import prog8.codegen.cpu6502.AsmGen
import prog8.codegen.cpu6502.VariableAllocator
import prog8.compilerinterface.AssemblyError
import prog8.compilerinterface.BuiltinFunctions
import prog8.compilerinterface.CpuType
import prog8.compilerinterface.builtinFunctionReturnType
internal class AssignmentAsmGen(private val program: Program, private val asmgen: AsmGen,
private val exprAsmgen: ExpressionsAsmGen
) {
private val augmentableAsmGen = AugmentableAssignmentAsmGen(program, this, exprAsmgen, asmgen)
internal class AssignmentAsmGen(private val program: Program,
private val asmgen: AsmGen,
private val allocator: VariableAllocator) {
private val augmentableAsmGen = AugmentableAssignmentAsmGen(program, this, asmgen, allocator)
fun translate(assignment: Assignment) {
val target = AsmAssignTarget.fromAstAssignment(assignment, program, asmgen)
@ -32,15 +31,27 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
translateNormalAssignment(assign)
}
internal fun virtualRegsToVariables(origtarget: AsmAssignTarget): AsmAssignTarget {
return if(origtarget.kind==TargetStorageKind.REGISTER && origtarget.register in Cx16VirtualRegisters) {
AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, origtarget.datatype, origtarget.scope,
variableAsmName = "cx16.${origtarget.register!!.name.lowercase()}", origAstTarget = origtarget.origAstTarget)
} else origtarget
}
fun translateNormalAssignment(assign: AsmAssignment) {
if(assign.isAugmentable) {
augmentableAsmGen.translate(assign)
return
}
when(assign.source.kind) {
SourceStorageKind.LITERALNUMBER -> {
// simple case: assign a constant number
val num = assign.source.number!!.number
when (assign.target.datatype) {
DataType.UBYTE, DataType.BYTE -> assignConstantByte(assign.target, num.toShort())
DataType.UBYTE, DataType.BYTE -> assignConstantByte(assign.target, num.toInt())
DataType.UWORD, DataType.WORD -> assignConstantWord(assign.target, num.toInt())
DataType.FLOAT -> assignConstantFloat(assign.target, num.toDouble())
DataType.FLOAT -> assignConstantFloat(assign.target, num)
else -> throw AssemblyError("weird numval type")
}
}
@ -79,7 +90,7 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
assignRegisterpairWord(assign.target, RegisterOrPair.AY)
}
DataType.FLOAT -> {
asmgen.out(" lda #<$arrayVarName+$indexValue | ldy #>$arrayVarName+$indexValue")
asmgen.out(" lda #<($arrayVarName+$indexValue) | ldy #>($arrayVarName+$indexValue)")
assignFloatFromAY(assign.target)
}
else ->
@ -116,17 +127,14 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
SourceStorageKind.MEMORY -> {
fun assignViaExprEval(expression: Expression) {
assignExpressionToVariable(expression, "P8ZP_SCRATCH_W2", DataType.UWORD, assign.target.scope)
if (asmgen.isTargetCpu(CpuType.CPU65c02))
asmgen.out(" lda (P8ZP_SCRATCH_W2)")
else
asmgen.out(" ldy #0 | lda (P8ZP_SCRATCH_W2),y")
asmgen.loadAFromZpPointerVar("P8ZP_SCRATCH_W2")
assignRegisterByte(assign.target, CpuRegister.A)
}
val value = assign.source.memory!!
when (value.addressExpression) {
is NumericLiteralValue -> {
val address = (value.addressExpression as NumericLiteralValue).number.toInt()
is NumericLiteral -> {
val address = (value.addressExpression as NumericLiteral).number.toUInt()
assignMemoryByte(assign.target, address, null)
}
is IdentifierReference -> {
@ -148,16 +156,16 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
val sourceName = asmgen.asmSymbolName(value.identifier)
assignAddressOf(assign.target, sourceName)
}
is NumericLiteralValue -> throw AssemblyError("source kind should have been literalnumber")
is NumericLiteral -> 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 -> assignTypeCastedValue(assign.target, value.type, value.expression, value)
is FunctionCall -> {
is FunctionCallExpression -> {
when (val sub = value.target.targetStatement(program)) {
is Subroutine -> {
asmgen.saveXbeforeCall(value)
asmgen.translateFunctionCall(value)
asmgen.translateFunctionCall(value, true)
val returnValue = sub.returntypes.zip(sub.asmReturnvaluesRegisters).singleOrNull { it.second.registerOrPair!=null } ?:
sub.returntypes.zip(sub.asmReturnvaluesRegisters).single { it.second.statusflag!=null }
when (returnValue.first) {
@ -209,7 +217,7 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
}
}
}
is BuiltinFunctionStatementPlaceholder -> {
is BuiltinFunctionPlaceholder -> {
val signature = BuiltinFunctions.getValue(sub.name)
asmgen.translateBuiltinFunctionCallExpression(value, signature, false, assign.target.register)
if(assign.target.register==null) {
@ -249,34 +257,249 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
}
}
}
is PrefixExpression -> {
// first assign the value to the target then apply the operator in place on the target.
translateNormalAssignment(AsmAssignment(
AsmAssignSource.fromAstSource(value.expression, program, asmgen),
assign.target,
false, program.memsizer, assign.position
))
val target = virtualRegsToVariables(assign.target)
when(value.operator) {
"+" -> {}
"-" -> augmentableAsmGen.inplaceNegate(target, target.datatype)
"~" -> augmentableAsmGen.inplaceInvert(target, target.datatype)
"not" -> augmentableAsmGen.inplaceBooleanNot(target, target.datatype)
else -> throw AssemblyError("invalid prefix operator")
}
}
is ContainmentCheck -> {
containmentCheckIntoA(value)
assignRegisterByte(assign.target, CpuRegister.A)
}
is PipeExpression -> {
asmgen.translatePipeExpression(value.expressions, value, false, false)
val resultDt = value.inferType(program)
val register =
if(resultDt.isBytes) RegisterOrPair.A
else if(resultDt.isWords) RegisterOrPair.AY
else if(resultDt istype DataType.FLOAT) RegisterOrPair.FAC1
else throw AssemblyError("invalid dt")
asmgen.assignRegister(register, assign.target)
}
is BinaryExpression -> {
if(value.operator in ComparisonOperators) {
// TODO real optimized code for comparison expressions that yield a boolean result value
// for now generate code for this: assign-false; if expr { assign-true }
translateNormalAssignment(
AsmAssignment(
AsmAssignSource(SourceStorageKind.LITERALNUMBER, program, asmgen, DataType.UBYTE, number=NumericLiteral.fromBoolean(false, assign.position)),
assign.target, false, program.memsizer, assign.position
)
)
val origTarget = assign.target.origAstTarget
if(origTarget!=null) {
val assignTrue = AnonymousScope(mutableListOf(
Assignment(origTarget, NumericLiteral.fromBoolean(true, assign.position), AssignmentOrigin.ASMGEN, assign.position)
), assign.position)
val assignFalse = AnonymousScope(mutableListOf(), assign.position)
val ifelse = IfElse(value.copy(), assignTrue, assignFalse, assign.position)
ifelse.linkParents(value)
asmgen.translate(ifelse)
}
else {
// no orig ast assign target, can't use the workaround, so fallback to stack eval
fallbackToStackEval(value, assign)
}
} else {
// Everything else just evaluate via the stack.
// (we can't use the assignment helper functions (assignExpressionTo...) to do it via registers here,
// because the code here is the implementation of exactly that...)
fallbackToStackEval(value, assign)
}
}
else -> {
// Everything else just evaluate via the stack.
// (we can't use the assignment helper functions to do it via registers here,
// (we can't use the assignment helper functions (assignExpressionTo...) to do it via registers here,
// because the code here is the implementation of exactly that...)
if (value.parent is Return) {
if (this.asmgen.options.slowCodegenWarnings)
println("warning: slow stack evaluation used for return: $value target=${assign.target.kind} at ${value.position}")
}
exprAsmgen.translateExpression(value)
if (assign.target.datatype in WordDatatypes && assign.source.datatype in ByteDatatypes)
asmgen.signExtendStackLsb(assign.source.datatype)
assignStackValue(assign.target)
fallbackToStackEval(value, assign)
}
}
}
SourceStorageKind.REGISTER -> {
when(assign.source.datatype) {
DataType.UBYTE -> assignRegisterByte(assign.target, assign.source.register!!.asCpuRegister())
DataType.UWORD -> assignRegisterpairWord(assign.target, assign.source.register!!)
else -> throw AssemblyError("invalid register dt")
}
asmgen.assignRegister(assign.source.register!!, assign.target)
}
SourceStorageKind.STACK -> {
if(assign.target.kind!=TargetStorageKind.STACK || assign.target.datatype != assign.source.datatype)
assignStackValue(assign.target)
}
}
}
private fun fallbackToStackEval(value: Expression, assign: AsmAssignment) {
// TODO DON'T STACK-EVAL THIS... by using a temp var? so that it becomes augmentable assignment expression?
asmgen.translateExpression(value)
if (assign.target.datatype in WordDatatypes && assign.source.datatype in ByteDatatypes)
asmgen.signExtendStackLsb(assign.source.datatype)
if (assign.target.kind != TargetStorageKind.STACK || assign.target.datatype != assign.source.datatype)
assignStackValue(assign.target)
}
private fun containmentCheckIntoA(containment: ContainmentCheck) {
val elementDt = containment.element.inferType(program)
val range = containment.iterable as? RangeExpression
if(range!=null) {
val constRange = range.toConstantIntegerRange()
if(constRange!=null)
return containmentCheckIntoA(containment.element, elementDt.getOr(DataType.UNDEFINED), constRange.toList())
TODO("non-const range containment check ${containment.position}")
}
val variable = (containment.iterable as? IdentifierReference)?.targetVarDecl(program)
if(variable!=null) {
if(elementDt istype DataType.FLOAT)
throw AssemblyError("containment check of floats not supported")
if(variable.origin!=VarDeclOrigin.USERCODE) {
when(variable.datatype) {
DataType.STR -> {
require(elementDt.isBytes)
val stringVal = variable.value as StringLiteral
if(stringVal.value.length > ContainmentCheck.max_inlined_string_length) {
// use subroutine
val varname = asmgen.asmVariableName(containment.iterable as IdentifierReference)
assignAddressOf(AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, DataType.UWORD, containment.definingSubroutine, "P8ZP_SCRATCH_W1"), varname)
assignExpressionToRegister(containment.element, RegisterOrPair.A, elementDt istype DataType.BYTE)
asmgen.out(" ldy #${stringVal.value.length}")
asmgen.out(" jsr prog8_lib.containment_bytearray")
return
} else {
// inline cmp table
val encoded = program.encoding.encodeString(stringVal.value, stringVal.encoding)
return containmentCheckIntoA(containment.element, elementDt.getOr(DataType.UNDEFINED), encoded.map { it.toInt() })
}
}
DataType.ARRAY_F -> {
// require(elementDt istype DataType.FLOAT)
throw AssemblyError("containment check of floats not supported")
}
in ArrayDatatypes -> {
require(elementDt.isInteger)
val arrayVal = variable.value as ArrayLiteral
val dt = elementDt.getOr(DataType.UNDEFINED)
if(arrayVal.value.size > ContainmentCheck.max_inlined_string_length) {
// use subroutine
val varname = asmgen.asmVariableName(containment.iterable as IdentifierReference)
when(dt) {
in ByteDatatypes -> {
assignAddressOf(AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, DataType.UWORD, containment.definingSubroutine, "P8ZP_SCRATCH_W1"), varname)
assignExpressionToRegister(containment.element, RegisterOrPair.A, elementDt istype DataType.BYTE)
asmgen.out(" ldy #${arrayVal.value.size}")
asmgen.out(" jsr prog8_lib.containment_bytearray")
}
in WordDatatypes -> {
assignExpressionToVariable(containment.element, "P8ZP_SCRATCH_W1", elementDt.getOr(DataType.UNDEFINED), containment.definingSubroutine)
assignAddressOf(AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, DataType.UWORD, containment.definingSubroutine, "P8ZP_SCRATCH_W2"), varname)
asmgen.out(" ldy #${arrayVal.value.size}")
asmgen.out(" jsr prog8_lib.containment_wordarray")
}
else -> throw AssemblyError("invalid dt")
}
return
} else {
// inline cmp table
val values = arrayVal.value.map { it.constValue(program)!!.number.toInt() }
return containmentCheckIntoA(containment.element, dt, values)
}
}
else -> throw AssemblyError("invalid dt")
}
}
val varname = asmgen.asmVariableName(containment.iterable as IdentifierReference)
when(variable.datatype) {
DataType.STR -> {
// use subroutine
assignAddressOf(AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, DataType.UWORD, containment.definingSubroutine, "P8ZP_SCRATCH_W1"), varname)
assignExpressionToRegister(containment.element, RegisterOrPair.A, elementDt istype DataType.BYTE)
val stringVal = variable.value as StringLiteral
asmgen.out(" ldy #${stringVal.value.length}")
asmgen.out(" jsr prog8_lib.containment_bytearray")
return
}
DataType.ARRAY_F -> throw AssemblyError("containment check of floats not supported")
DataType.ARRAY_B, DataType.ARRAY_UB -> {
val arrayVal = variable.value as ArrayLiteral
assignAddressOf(AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, DataType.UWORD, containment.definingSubroutine, "P8ZP_SCRATCH_W1"), varname)
assignExpressionToRegister(containment.element, RegisterOrPair.A, elementDt istype DataType.BYTE)
asmgen.out(" ldy #${arrayVal.value.size}")
asmgen.out(" jsr prog8_lib.containment_bytearray")
return
}
DataType.ARRAY_W, DataType.ARRAY_UW -> {
val arrayVal = variable.value as ArrayLiteral
assignExpressionToVariable(containment.element, "P8ZP_SCRATCH_W1", elementDt.getOr(DataType.UNDEFINED), containment.definingSubroutine)
assignAddressOf(AsmAssignTarget(TargetStorageKind.VARIABLE, program, asmgen, DataType.UWORD, containment.definingSubroutine, "P8ZP_SCRATCH_W2"), varname)
asmgen.out(" ldy #${arrayVal.value.size}")
asmgen.out(" jsr prog8_lib.containment_wordarray")
return
}
else -> throw AssemblyError("invalid dt")
}
}
val stringVal = containment.iterable as? StringLiteral
if(stringVal!=null) {
require(elementDt.isBytes)
if(stringVal.value.length > ContainmentCheck.max_inlined_string_length)
throw AssemblyError("string should have been inlined in if it was this long")
val encoded = program.encoding.encodeString(stringVal.value, stringVal.encoding)
return containmentCheckIntoA(containment.element, elementDt.getOr(DataType.UNDEFINED), encoded.map { it.toInt() })
}
val arrayVal = containment.iterable as? ArrayLiteral
if(arrayVal!=null) {
require(elementDt.isInteger)
if(arrayVal.value.size > ContainmentCheck.max_inlined_string_length)
throw AssemblyError("array should have been inlined in if it was this long")
val values = arrayVal.value.map { it.constValue(program)!!.number.toInt() }
return containmentCheckIntoA(containment.element, elementDt.getOr(DataType.UNDEFINED), values)
}
throw AssemblyError("invalid containment iterable type")
}
private fun containmentCheckIntoA(element: Expression, dt: DataType, values: List<Number>) {
if(values.size<2)
throw AssemblyError("containment check against 0 or 1 values should have been optimized away")
val containsLabel = asmgen.makeLabel("contains")
when(dt) {
in ByteDatatypes -> {
asmgen.assignExpressionToRegister(element, RegisterOrPair.A, dt==DataType.BYTE)
for (value in values) {
asmgen.out(" cmp #$value | beq +")
}
asmgen.out("""
lda #0
beq ++
+ lda #1
+""")
}
in WordDatatypes -> {
asmgen.assignExpressionToRegister(element, RegisterOrPair.AY, dt==DataType.WORD)
for (value in values) {
asmgen.out("""
cmp #<$value
bne +
cpy #>$value
beq $containsLabel
+""")
}
asmgen.out("""
lda #0
beq +
$containsLabel lda #1
+""")
}
else -> throw AssemblyError("invalid dt")
}
}
private fun assignStatusFlagByte(target: AsmAssignTarget, statusflag: Statusflag) {
when(statusflag) {
Statusflag.Pc -> {
@ -297,9 +520,7 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
private fun assignTypeCastedValue(target: AsmAssignTarget, targetDt: DataType, value: Expression, origTypeCastExpression: TypecastExpression) {
val valueIDt = value.inferType(program)
if(!valueIDt.isKnown)
throw AssemblyError("unknown dt")
val valueDt = valueIDt.getOr(DataType.UNDEFINED)
val valueDt = valueIDt.getOrElse { throw AssemblyError("unknown dt") }
if(valueDt==targetDt)
throw AssemblyError("type cast to identical dt should have been removed")
@ -321,16 +542,13 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
fun assignViaExprEval(addressExpression: Expression) {
asmgen.assignExpressionToVariable(addressExpression, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
if (asmgen.isTargetCpu(CpuType.CPU65c02))
asmgen.out(" lda (P8ZP_SCRATCH_W2)")
else
asmgen.out(" ldy #0 | lda (P8ZP_SCRATCH_W2),y")
asmgen.loadAFromZpPointerVar("P8ZP_SCRATCH_W2")
assignRegisterByte(target, CpuRegister.A)
}
when (value.addressExpression) {
is NumericLiteralValue -> {
val address = (value.addressExpression as NumericLiteralValue).number.toInt()
is NumericLiteral -> {
val address = (value.addressExpression as NumericLiteral).number.toUInt()
assignMemoryByteIntoWord(target, address, null)
return
}
@ -352,7 +570,7 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
}
}
}
is NumericLiteralValue -> throw AssemblyError("a cast of a literal value should have been const-folded away")
is NumericLiteral -> throw AssemblyError("a cast of a literal value should have been const-folded away")
else -> {}
}
@ -364,16 +582,16 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
when (valueDt) {
in ByteDatatypes -> {
assignExpressionToRegister(value, RegisterOrPair.A)
assignExpressionToRegister(value, RegisterOrPair.A, valueDt==DataType.BYTE)
assignTypeCastedRegisters(target.asmVarname, targetDt, RegisterOrPair.A, valueDt)
}
in WordDatatypes -> {
assignExpressionToRegister(value, RegisterOrPair.AY)
assignExpressionToRegister(value, RegisterOrPair.AY, valueDt==DataType.WORD)
assignTypeCastedRegisters(target.asmVarname, targetDt, RegisterOrPair.AY, valueDt)
}
DataType.FLOAT -> {
assignExpressionToRegister(value, RegisterOrPair.FAC1)
assignTypecastedFloatFAC1(target.asmVarname, targetDt)
assignExpressionToRegister(value, RegisterOrPair.FAC1, true)
assignTypeCastedFloatFAC1(target.asmVarname, targetDt)
}
in PassByReferenceDatatypes -> {
// str/array value cast (most likely to UWORD, take address-of)
@ -399,14 +617,14 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
RegisterOrPair.X,
RegisterOrPair.Y -> {
// 'cast' an ubyte value to a byte register; no cast needed at all
return assignExpressionToRegister(value, target.register)
return assignExpressionToRegister(value, target.register, false)
}
RegisterOrPair.AX,
RegisterOrPair.AY,
RegisterOrPair.XY,
in Cx16VirtualRegisters -> {
// cast an ubyte value to a 16 bits register, just assign it and make use of the value extension
return assignExpressionToRegister(value, target.register!!)
return assignExpressionToRegister(value, target.register!!, false)
}
else -> {}
}
@ -424,30 +642,57 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
RegisterOrPair.XY,
in Cx16VirtualRegisters -> {
// 'cast' uword into a 16 bits register, just assign it
return assignExpressionToRegister(value, target.register!!)
return assignExpressionToRegister(value, target.register!!, false)
}
else -> {}
}
}
// give up, do it via eval stack
if(target.kind==TargetStorageKind.REGISTER) {
assignExpressionToRegister(value, target.register!!, targetDt==DataType.BYTE || targetDt==DataType.WORD)
return
}
if(targetDt==DataType.FLOAT && (target.register==RegisterOrPair.FAC1 || target.register==RegisterOrPair.FAC2)) {
when(valueDt) {
DataType.UBYTE -> {
assignExpressionToRegister(value, RegisterOrPair.Y, false)
asmgen.out(" jsr floats.FREADUY")
}
DataType.BYTE -> {
assignExpressionToRegister(value, RegisterOrPair.A, true)
asmgen.out(" jsr floats.FREADSA")
}
DataType.UWORD -> {
assignExpressionToRegister(value, RegisterOrPair.AY, false)
asmgen.out(" jsr floats.GIVUAYFAY")
}
DataType.WORD -> {
assignExpressionToRegister(value, RegisterOrPair.AY, true)
asmgen.out(" jsr floats.GIVAYFAY")
}
else -> throw AssemblyError("invalid dt")
}
if(target.register==RegisterOrPair.FAC2) {
asmgen.out(" jsr floats.MOVEF")
}
} else {
// No more special optmized cases yet. Do the rest via more complex evaluation
// note: cannot use assignTypeCastedValue because that is ourselves :P
// TODO optimize typecasts for more special cases?
if(this.asmgen.options.slowCodegenWarnings)
println("warning: slow stack evaluation used for typecast: $value into $targetDt (target=${target.kind} at ${value.position}")
asmgen.translateExpression(origTypeCastExpression) // this performs the actual type cast in translateExpression(Typecast)
assignStackValue(target)
// NOTE: THIS MAY TURN INTO A STACK OVERFLOW ERROR IF IT CAN'T SIMPLIFY THE TYPECAST..... :-/
asmgen.assignExpressionTo(origTypeCastExpression, target)
}
}
private fun assignCastViaLsbFunc(value: Expression, target: AsmAssignTarget) {
val lsb = FunctionCall(IdentifierReference(listOf("lsb"), value.position), mutableListOf(value), value.position)
val lsb = FunctionCallExpression(IdentifierReference(listOf("lsb"), value.position), mutableListOf(value), value.position)
lsb.linkParents(value.parent)
val src = AsmAssignSource(SourceStorageKind.EXPRESSION, program, asmgen, DataType.UBYTE, expression = lsb)
val assign = AsmAssignment(src, target, false, program.memsizer, value.position)
translateNormalAssignment(assign)
}
private fun assignTypecastedFloatFAC1(targetAsmVarName: String, targetDt: DataType) {
private fun assignTypeCastedFloatFAC1(targetAsmVarName: String, targetDt: DataType) {
if(targetDt==DataType.FLOAT)
throw AssemblyError("typecast to identical type")
@ -768,7 +1013,7 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
}
TargetStorageKind.ARRAY -> {
if(target.constArrayIndexValue!=null) {
val scaledIdx = target.constArrayIndexValue!! * program.memsizer.memorySize(target.datatype)
val scaledIdx = target.constArrayIndexValue!! * program.memsizer.memorySize(target.datatype).toUInt()
when(target.datatype) {
in ByteDatatypes -> {
asmgen.out(" inx | lda P8ESTACK_LO,x | sta ${target.asmVarname}+$scaledIdx")
@ -784,8 +1029,8 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
}
DataType.FLOAT -> {
asmgen.out("""
lda #<${target.asmVarname}+$scaledIdx
ldy #>${target.asmVarname}+$scaledIdx
lda #<(${target.asmVarname}+$scaledIdx)
ldy #>(${target.asmVarname}+$scaledIdx)
jsr floats.pop_float
""")
}
@ -954,7 +1199,8 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
lda #<$sourceName
ldy #>$sourceName+1
sta P8ESTACK_LO,x
sty P8ESTACK_HI,x
tya
sta P8ESTACK_HI,x
dex""")
}
else -> throw AssemblyError("string-assign to weird target")
@ -977,7 +1223,7 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
TargetStorageKind.ARRAY -> {
target.array!!
if(target.constArrayIndexValue!=null) {
val scaledIdx = target.constArrayIndexValue!! * program.memsizer.memorySize(target.datatype)
val scaledIdx = target.constArrayIndexValue!! * program.memsizer.memorySize(target.datatype).toUInt()
when(target.datatype) {
in ByteDatatypes -> {
asmgen.out(" lda $sourceName | sta ${target.asmVarname}+$scaledIdx")
@ -996,8 +1242,8 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
ldy #>$sourceName
sta P8ZP_SCRATCH_W1
sty P8ZP_SCRATCH_W1+1
lda #<${target.asmVarname}+$scaledIdx
ldy #>${target.asmVarname}+$scaledIdx
lda #<(${target.asmVarname}+$scaledIdx)
ldy #>(${target.asmVarname}+$scaledIdx)
jsr floats.copy_float
""")
}
@ -1066,6 +1312,11 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
}
}
internal fun assignFAC2float(target: AsmAssignTarget) {
asmgen.out(" jsr floats.MOVFA") // fac2 -> fac1
assignFAC1float(target)
}
internal fun assignFAC1float(target: AsmAssignTarget) {
when(target.kind) {
TargetStorageKind.VARIABLE -> {
@ -1144,17 +1395,13 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
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 ${target.asmVarname}+4
""")
lda #<$sourceName
ldy #>$sourceName
sta P8ZP_SCRATCH_W1
sty P8ZP_SCRATCH_W1+1
lda #<${target.asmVarname}
ldy #>${target.asmVarname}
jsr floats.copy_float""")
}
TargetStorageKind.ARRAY -> {
asmgen.out("""
@ -1201,7 +1448,7 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
}
TargetStorageKind.ARRAY -> {
if (target.constArrayIndexValue!=null) {
val scaledIdx = target.constArrayIndexValue!! * program.memsizer.memorySize(target.datatype)
val scaledIdx = target.constArrayIndexValue!! * program.memsizer.memorySize(target.datatype).toUInt()
asmgen.out(" lda $sourceName | sta ${target.asmVarname}+$scaledIdx")
}
else {
@ -1254,7 +1501,7 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
}
TargetStorageKind.ARRAY -> {
if (wordtarget.constArrayIndexValue!=null) {
val scaledIdx = wordtarget.constArrayIndexValue!! * 2
val scaledIdx = wordtarget.constArrayIndexValue!! * 2u
asmgen.out(" lda $sourceName")
asmgen.signExtendAYlsb(DataType.BYTE)
asmgen.out(" sta ${wordtarget.asmVarname}+$scaledIdx | sty ${wordtarget.asmVarname}+$scaledIdx+1")
@ -1275,7 +1522,7 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
pha
ora #$7f
bmi +
ldx #0
lda #0
+ tax
pla""")
RegisterOrPair.AY -> asmgen.out("""
@ -1283,7 +1530,7 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
pha
ora #$7f
bmi +
ldy #0
lda #0
+ tay
pla""")
RegisterOrPair.XY -> asmgen.out("""
@ -1291,9 +1538,19 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
tax
ora #$7f
bmi +
ldy #0
lda #0
+ tay""")
else -> throw AssemblyError("only reg pairs are words")
in Cx16VirtualRegisters -> {
val regname = wordtarget.register.name.lowercase()
asmgen.out("""
lda $sourceName
sta cx16.$regname
ora #$7f
bmi +
lda #0
+ sta cx16.$regname+1""")
}
else -> throw AssemblyError("only reg pairs allowed as word target ${wordtarget.register}")
}
}
TargetStorageKind.STACK -> {
@ -1322,7 +1579,7 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
}
TargetStorageKind.ARRAY -> {
if (wordtarget.constArrayIndexValue!=null) {
val scaledIdx = wordtarget.constArrayIndexValue!! * 2
val scaledIdx = wordtarget.constArrayIndexValue!! * 2u
asmgen.out(" lda $sourceName | sta ${wordtarget.asmVarname}+$scaledIdx")
if(asmgen.isTargetCpu(CpuType.CPU65c02))
asmgen.out(" stz ${wordtarget.asmVarname}+$scaledIdx+1")
@ -1344,7 +1601,14 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
RegisterOrPair.AX -> asmgen.out(" ldx #0 | lda $sourceName")
RegisterOrPair.AY -> asmgen.out(" ldy #0 | lda $sourceName")
RegisterOrPair.XY -> asmgen.out(" ldy #0 | ldx $sourceName")
else -> throw AssemblyError("only reg pairs are words")
in Cx16VirtualRegisters -> {
val regname = wordtarget.register.name.lowercase()
if(asmgen.isTargetCpu(CpuType.CPU65c02))
asmgen.out(" lda $sourceName | sta cx16.$regname | stz cx16.$regname+1")
else
asmgen.out(" lda $sourceName | sta cx16.$regname | lda #0 | sta cx16.$regname+1")
}
else -> throw AssemblyError("only reg pairs allowed as word target")
}
}
TargetStorageKind.STACK -> {
@ -1459,7 +1723,7 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
}
internal fun assignRegisterpairWord(target: AsmAssignTarget, regs: RegisterOrPair) {
require(target.datatype in NumericDatatypes)
require(target.datatype in NumericDatatypes || target.datatype in PassByReferenceDatatypes)
if(target.datatype==DataType.FLOAT)
throw AssemblyError("float value should be from FAC1 not from registerpair memory pointer")
@ -1482,7 +1746,7 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
}
TargetStorageKind.ARRAY -> {
if (target.constArrayIndexValue!=null) {
val idx = target.constArrayIndexValue!! * 2
val idx = target.constArrayIndexValue!! * 2u
when (regs) {
RegisterOrPair.AX -> asmgen.out(" sta ${target.asmVarname}+$idx | stx ${target.asmVarname}+$idx+1")
RegisterOrPair.AY -> asmgen.out(" sta ${target.asmVarname}+$idx | sty ${target.asmVarname}+$idx+1")
@ -1586,7 +1850,7 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
}
TargetStorageKind.STACK -> {
when(regs) {
RegisterOrPair.AY -> asmgen.out(" sta P8ESTACK_LO,x | sty P8ESTACK_HI,x | dex")
RegisterOrPair.AY -> asmgen.out(" sta P8ESTACK_LO,x | tya | sta P8ESTACK_HI,x | dex")
RegisterOrPair.AX, RegisterOrPair.XY -> throw AssemblyError("can't use X here")
in Cx16VirtualRegisters -> {
val srcReg = asmgen.asmSymbolName(regs)
@ -1612,7 +1876,7 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
asmgen.out(" stz ${target.asmVarname} | stz ${target.asmVarname}+1")
}
TargetStorageKind.MEMORY -> {
throw AssemblyError("no asm gen for assign word $word to memory ${target.memory}")
throw AssemblyError("memory is bytes not words")
}
TargetStorageKind.ARRAY -> {
asmgen.loadScaledArrayIndexIntoRegister(target.array!!, DataType.UWORD, CpuRegister.Y)
@ -1703,15 +1967,15 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
}
}
private fun assignConstantByte(target: AsmAssignTarget, byte: Short) {
if(byte==0.toShort() && asmgen.isTargetCpu(CpuType.CPU65c02)) {
private fun assignConstantByte(target: AsmAssignTarget, byte: Int) {
if(byte==0 && asmgen.isTargetCpu(CpuType.CPU65c02)) {
// optimize setting zero value for this cpu
when(target.kind) {
TargetStorageKind.VARIABLE -> {
asmgen.out(" stz ${target.asmVarname} ")
}
TargetStorageKind.MEMORY -> {
asmgen.out(" lda #${byte.toHex()}")
asmgen.out(" lda #0")
storeRegisterAInMemoryAddress(target.memory!!)
}
TargetStorageKind.ARRAY -> {
@ -1857,7 +2121,7 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
}
TargetStorageKind.MEMORY -> throw AssemblyError("can't assign float to memory byte")
TargetStorageKind.REGISTER -> {
val floatConst = asmgen.getFloatAsmConst(float)
val floatConst = allocator.getFloatAsmConst(float)
when(target.register!!) {
RegisterOrPair.FAC1 -> asmgen.out(" lda #<$floatConst | ldy #>$floatConst | jsr floats.MOVFM")
RegisterOrPair.FAC2 -> asmgen.out(" lda #<$floatConst | ldy #>$floatConst | jsr floats.CONUPK")
@ -1865,27 +2129,23 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
}
}
TargetStorageKind.STACK -> {
val floatConst = asmgen.getFloatAsmConst(float)
val floatConst = allocator.getFloatAsmConst(float)
asmgen.out(" lda #<$floatConst | ldy #>$floatConst | jsr floats.push_float")
}
}
} else {
// non-zero value
val constFloat = asmgen.getFloatAsmConst(float)
val constFloat = allocator.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 ${target.asmVarname}+4
""")
lda #<$constFloat
ldy #>$constFloat
sta P8ZP_SCRATCH_W1
sty P8ZP_SCRATCH_W1+1
lda #<${target.asmVarname}
ldy #>${target.asmVarname}
jsr floats.copy_float""")
}
TargetStorageKind.ARRAY -> {
val arrayVarName = target.asmVarname
@ -1893,17 +2153,13 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
if (constIndex!=null) {
val indexValue = constIndex * program.memsizer.memorySize(DataType.FLOAT)
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
""")
lda #<$constFloat
ldy #>$constFloat
sta P8ZP_SCRATCH_W1
sty P8ZP_SCRATCH_W1+1
lda #<($arrayVarName+$indexValue)
ldy #>($arrayVarName+$indexValue)
jsr floats.copy_float""")
} else {
val asmvarname = asmgen.asmVariableName(target.array.indexer.indexExpr as IdentifierReference)
asmgen.out("""
@ -1922,7 +2178,7 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
}
TargetStorageKind.MEMORY -> throw AssemblyError("can't assign float to memory byte")
TargetStorageKind.REGISTER -> {
val floatConst = asmgen.getFloatAsmConst(float)
val floatConst = allocator.getFloatAsmConst(float)
when(target.register!!) {
RegisterOrPair.FAC1 -> asmgen.out(" lda #<$floatConst | ldy #>$floatConst | jsr floats.MOVFM")
RegisterOrPair.FAC2 -> asmgen.out(" lda #<$floatConst | ldy #>$floatConst | jsr floats.CONUPK")
@ -1930,14 +2186,14 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
}
}
TargetStorageKind.STACK -> {
val floatConst = asmgen.getFloatAsmConst(float)
val floatConst = allocator.getFloatAsmConst(float)
asmgen.out(" lda #<$floatConst | ldy #>$floatConst | jsr floats.push_float")
}
}
}
}
private fun assignMemoryByte(target: AsmAssignTarget, address: Int?, identifier: IdentifierReference?) {
private fun assignMemoryByte(target: AsmAssignTarget, address: UInt?, identifier: IdentifierReference?) {
if (address != null) {
when(target.kind) {
TargetStorageKind.VARIABLE -> {
@ -2021,7 +2277,7 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
}
}
private fun assignMemoryByteIntoWord(wordtarget: AsmAssignTarget, address: Int?, identifier: IdentifierReference?) {
private fun assignMemoryByteIntoWord(wordtarget: AsmAssignTarget, address: UInt?, identifier: IdentifierReference?) {
if (address != null) {
when(wordtarget.kind) {
TargetStorageKind.VARIABLE -> {
@ -2086,58 +2342,20 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
private fun storeRegisterAInMemoryAddress(memoryAddress: DirectMemoryWrite) {
val addressExpr = memoryAddress.addressExpression
val addressLv = addressExpr as? NumericLiteralValue
val addressLv = addressExpr as? NumericLiteral
fun storeViaExprEval() {
when(addressExpr) {
is NumericLiteralValue, is IdentifierReference -> {
is NumericLiteral, is IdentifierReference -> {
assignExpressionToVariable(addressExpr, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
if (asmgen.isTargetCpu(CpuType.CPU65c02))
asmgen.out(" sta (P8ZP_SCRATCH_W2)")
else
asmgen.out(" ldy #0 | sta (P8ZP_SCRATCH_W2),y")
asmgen.storeAIntoZpPointerVar("P8ZP_SCRATCH_W2")
}
else -> {
// same as above but we need to save the A register
asmgen.out(" pha")
assignExpressionToVariable(addressExpr, "P8ZP_SCRATCH_W2", DataType.UWORD, null)
asmgen.out(" pla")
if (asmgen.isTargetCpu(CpuType.CPU65c02))
asmgen.out(" sta (P8ZP_SCRATCH_W2)")
else
asmgen.out(" ldy #0 | sta (P8ZP_SCRATCH_W2),y")
}
}
}
fun storeAIntoPointerVar(pointervar: IdentifierReference) {
val sourceName = asmgen.asmVariableName(pointervar)
val vardecl = pointervar.targetVarDecl(program)!!
val scopedName = vardecl.makeScopedName(vardecl.name)
if (asmgen.isTargetCpu(CpuType.CPU65c02)) {
if (asmgen.isZpVar(scopedName)) {
// pointervar is already in the zero page, no need to copy
asmgen.out(" sta ($sourceName)")
} else {
asmgen.out("""
ldy $sourceName
sty P8ZP_SCRATCH_W2
ldy $sourceName+1
sty P8ZP_SCRATCH_W2+1
sta (P8ZP_SCRATCH_W2)""")
}
} else {
if (asmgen.isZpVar(scopedName)) {
// pointervar is already in the zero page, no need to copy
asmgen.out(" ldy #0 | sta ($sourceName),y")
} else {
asmgen.out("""
ldy $sourceName
sty P8ZP_SCRATCH_W2
ldy $sourceName+1
sty P8ZP_SCRATCH_W2+1
ldy #0
sta (P8ZP_SCRATCH_W2),y""")
asmgen.storeAIntoZpPointerVar("P8ZP_SCRATCH_W2")
}
}
}
@ -2147,7 +2365,7 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
asmgen.out(" sta ${addressLv.number.toHex()}")
}
addressExpr is IdentifierReference -> {
storeAIntoPointerVar(addressExpr)
asmgen.storeAIntoPointerVar(addressExpr)
}
addressExpr is BinaryExpression -> {
if(!asmgen.tryOptimizedPointerAccessWithA(addressExpr, true))
@ -2157,9 +2375,9 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
}
}
internal fun assignExpressionToRegister(expr: Expression, register: RegisterOrPair) {
internal fun assignExpressionToRegister(expr: Expression, register: RegisterOrPair, signed: Boolean) {
val src = AsmAssignSource.fromAstSource(expr, program, asmgen)
val tgt = AsmAssignTarget.fromRegisters(register, null, program, asmgen)
val tgt = AsmAssignTarget.fromRegisters(register, signed, null, program, asmgen)
val assign = AsmAssignment(src, tgt, false, program.memsizer, expr.position)
translateNormalAssignment(assign)
}
@ -2171,8 +2389,8 @@ internal class AssignmentAsmGen(private val program: Program, private val asmgen
translateNormalAssignment(assign)
}
internal fun assignVariableToRegister(asmVarName: String, register: RegisterOrPair) {
val tgt = AsmAssignTarget.fromRegisters(register, null, program, asmgen)
internal fun assignVariableToRegister(asmVarName: String, register: RegisterOrPair, signed: Boolean) {
val tgt = AsmAssignTarget.fromRegisters(register, signed, null, program, asmgen)
val src = AsmAssignSource(SourceStorageKind.VARIABLE, program, asmgen, tgt.datatype, variableAsmName = asmVarName)
val assign = AsmAssignment(src, tgt, false, program.memsizer, Position.DUMMY)
translateNormalAssignment(assign)

543
compiler/src/prog8/compiler/target/cpu6502/codegen/assignment/AugmentableAssignmentAsmGen.kt → codeGenCpu6502/src/prog8/codegen/cpu6502/assignment/AugmentableAssignmentAsmGen.kt
View File

@ -1,19 +1,20 @@
package prog8.compiler.target.cpu6502.codegen.assignment
package prog8.codegen.cpu6502.assignment
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.ast.statements.Subroutine
import prog8.ast.toHex
import prog8.compiler.AssemblyError
import prog8.compiler.target.CpuType
import prog8.compiler.target.cpu6502.codegen.AsmGen
import prog8.compiler.target.cpu6502.codegen.ExpressionsAsmGen
import prog8.codegen.cpu6502.AsmGen
import prog8.codegen.cpu6502.VariableAllocator
import prog8.compilerinterface.AssemblyError
import prog8.compilerinterface.CpuType
internal class AugmentableAssignmentAsmGen(private val program: Program,
private val assignmentAsmGen: AssignmentAsmGen,
private val exprAsmGen: ExpressionsAsmGen,
private val asmgen: AsmGen
private val asmgen: AsmGen,
private val allocator: VariableAllocator
) {
fun translate(assign: AsmAssignment) {
require(assign.isAugmentable)
@ -22,15 +23,14 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
when (val value = assign.source.expression!!) {
is PrefixExpression -> {
// A = -A , A = +A, A = ~A, A = not A
val target = assignmentAsmGen.virtualRegsToVariables(assign.target)
val itype = value.inferType(program)
if(!itype.isKnown)
throw AssemblyError("unknown dt")
val type = itype.getOr(DataType.UNDEFINED)
val type = itype.getOrElse { throw AssemblyError("unknown dt") }
when (value.operator) {
"+" -> {}
"-" -> inplaceNegate(assign.target, type)
"~" -> inplaceInvert(assign.target, type)
"not" -> inplaceBooleanNot(assign.target, type)
"-" -> inplaceNegate(target, type)
"~" -> inplaceInvert(target, type)
"not" -> inplaceBooleanNot(target, type)
else -> throw AssemblyError("invalid prefix operator")
}
}
@ -47,7 +47,7 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
return inplaceModification(target, binExpr.operator, binExpr.right)
}
if (binExpr.operator in associativeOperators) {
if (binExpr.operator in AssociativeOperators) {
if (binExpr.right isSameAs astTarget) {
// A = 5 <operator> A
return inplaceModification(target, binExpr.operator, binExpr.left)
@ -102,11 +102,67 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
}
}
throw FatalAstException("assignment should be augmentable $binExpr")
val leftBinExpr = binExpr.left as? BinaryExpression
val rightBinExpr = binExpr.right as? BinaryExpression
if(leftBinExpr!=null && rightBinExpr==null) {
if(leftBinExpr.left isSameAs astTarget) {
// X = (X <oper> Right) <oper> Something
inplaceModification(target, leftBinExpr.operator, leftBinExpr.right)
inplaceModification(target, binExpr.operator, binExpr.right)
return
}
if(leftBinExpr.right isSameAs astTarget) {
// X = (Left <oper> X) <oper> Something
if(leftBinExpr.operator in AssociativeOperators) {
inplaceModification(target, leftBinExpr.operator, leftBinExpr.left)
inplaceModification(target, binExpr.operator, binExpr.right)
return
} else {
throw AssemblyError("operands in wrong order for non-associative operator")
}
}
}
if(leftBinExpr==null && rightBinExpr!=null) {
if(rightBinExpr.left isSameAs astTarget) {
// X = Something <oper> (X <oper> Right)
if(binExpr.operator in AssociativeOperators) {
inplaceModification(target, rightBinExpr.operator, rightBinExpr.right)
inplaceModification(target, binExpr.operator, binExpr.left)
return
} else {
throw AssemblyError("operands in wrong order for non-associative operator")
}
}
if(rightBinExpr.right isSameAs astTarget) {
// X = Something <oper> (Left <oper> X)
if(binExpr.operator in AssociativeOperators && rightBinExpr.operator in AssociativeOperators) {
inplaceModification(target, rightBinExpr.operator, rightBinExpr.left)
inplaceModification(target, binExpr.operator, binExpr.left)
return
} else {
throw AssemblyError("operands in wrong order for non-associative operator")
}
}
}
private fun inplaceModification(target: AsmAssignTarget, operator: String, value: Expression) {
val valueLv = (value as? NumericLiteralValue)?.number
throw FatalAstException("assignment should follow augmentable rules $binExpr")
}
private fun inplaceModification(target: AsmAssignTarget, operator: String, origValue: Expression) {
// the asm-gen code can deal with situations where you want to assign a byte into a word.
// it will create the most optimized code to do this (so it type-extends for us).
// But we can't deal with writing a word into a byte - explicit typeconversion is required
val value = if(program.memsizer.memorySize(origValue.inferType(program).getOrElse { throw AssemblyError("unknown dt") }) > program.memsizer.memorySize(target.datatype)) {
val typecast = TypecastExpression(origValue, target.datatype, true, origValue.position)
typecast.linkParents(origValue.parent)
typecast
}
else {
origValue
}
val valueLv = (value as? NumericLiteral)?.number
val ident = value as? IdentifierReference
val memread = value as? DirectMemoryRead
@ -119,7 +175,7 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
ident != null -> inplaceModification_byte_variable_to_variable(target.asmVarname, target.datatype, operator, ident)
memread != null -> inplaceModification_byte_memread_to_variable(target.asmVarname, target.datatype, operator, memread)
value is TypecastExpression -> {
if (tryRemoveRedundantCast(value, target, operator)) return
if (tryInplaceModifyWithRemovedRedundantCast(value, target, operator)) return
inplaceModification_byte_value_to_variable(target.asmVarname, target.datatype, operator, value)
}
else -> inplaceModification_byte_value_to_variable(target.asmVarname, target.datatype, operator, value)
@ -131,7 +187,8 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
ident != null -> inplaceModification_word_variable_to_variable(target.asmVarname, target.datatype, operator, ident)
memread != null -> inplaceModification_word_memread_to_variable(target.asmVarname, target.datatype, operator, memread)
value is TypecastExpression -> {
if (tryRemoveRedundantCast(value, target, operator)) return
if (tryInplaceModifyWithRemovedRedundantCast(value, target, operator))
return
inplaceModification_word_value_to_variable(target.asmVarname, target.datatype, operator, value)
}
else -> inplaceModification_word_value_to_variable(target.asmVarname, target.datatype, operator, value)
@ -142,7 +199,7 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
valueLv != null -> inplaceModification_float_litval_to_variable(target.asmVarname, operator, valueLv.toDouble(), target.scope!!)
ident != null -> inplaceModification_float_variable_to_variable(target.asmVarname, operator, ident, target.scope!!)
value is TypecastExpression -> {
if (tryRemoveRedundantCast(value, target, operator)) return
if (tryInplaceModifyWithRemovedRedundantCast(value, target, operator)) return
inplaceModification_float_value_to_variable(target.asmVarname, operator, value, target.scope!!)
}
else -> inplaceModification_float_value_to_variable(target.asmVarname, operator, value, target.scope!!)
@ -154,15 +211,15 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
TargetStorageKind.MEMORY -> {
val memory = target.memory!!
when (memory.addressExpression) {
is NumericLiteralValue -> {
val addr = (memory.addressExpression as NumericLiteralValue).number.toInt()
is NumericLiteral -> {
val addr = (memory.addressExpression as NumericLiteral).number.toInt()
// re-use code to assign a variable, instead this time, use a direct memory address
when {
valueLv != null -> inplaceModification_byte_litval_to_variable(addr.toHex(), DataType.UBYTE, operator, valueLv.toInt())
ident != null -> inplaceModification_byte_variable_to_variable(addr.toHex(), DataType.UBYTE, operator, ident)
memread != null -> inplaceModification_byte_memread_to_variable(addr.toHex(), DataType.UBYTE, operator, value)
value is TypecastExpression -> {
if (tryRemoveRedundantCast(value, target, operator)) return
if (tryInplaceModifyWithRemovedRedundantCast(value, target, operator)) return
inplaceModification_byte_value_to_variable(addr.toHex(), DataType.UBYTE, operator, value)
}
else -> inplaceModification_byte_value_to_variable(addr.toHex(), DataType.UBYTE, operator, value)
@ -174,21 +231,22 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
valueLv != null -> inplaceModification_byte_litval_to_pointer(pointer, operator, valueLv.toInt())
ident != null -> inplaceModification_byte_variable_to_pointer(pointer, operator, ident)
value is TypecastExpression -> {
if (tryRemoveRedundantCast(value, target, operator)) return
if (tryInplaceModifyWithRemovedRedundantCast(value, target, operator)) return
inplaceModification_byte_value_to_pointer(pointer, operator, value)
}
else -> inplaceModification_byte_value_to_pointer(pointer, operator, value)
}
}
else -> {
asmgen.translateExpression(memory.addressExpression)
// TODO use some other evaluation here; don't use the estack to transfer the address to read/write from
asmgen.assignExpressionTo(memory.addressExpression, AsmAssignTarget(TargetStorageKind.STACK, program, asmgen, DataType.UWORD, memory.definingSubroutine))
asmgen.out(" jsr prog8_lib.read_byte_from_address_on_stack | sta P8ZP_SCRATCH_B1")
when {
valueLv != null -> inplaceModification_byte_litval_to_variable("P8ZP_SCRATCH_B1", DataType.UBYTE, operator, valueLv.toInt())
ident != null -> inplaceModification_byte_variable_to_variable("P8ZP_SCRATCH_B1", DataType.UBYTE, operator, ident)
memread != null -> inplaceModification_byte_memread_to_variable("P8ZP_SCRATCH_B1", DataType.UBYTE, operator, memread)
value is TypecastExpression -> {
if (tryRemoveRedundantCast(value, target, operator)) return
if (tryInplaceModifyWithRemovedRedundantCast(value, target, operator)) return
inplaceModification_byte_value_to_variable("P8ZP_SCRATCH_B1", DataType.UBYTE, operator, value)
}
else -> inplaceModification_byte_value_to_variable("P8ZP_SCRATCH_B1", DataType.UBYTE, operator, value)
@ -199,7 +257,7 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
}
TargetStorageKind.ARRAY -> {
with(target.array!!.indexer) {
val indexNum = indexExpr as? NumericLiteralValue
val indexNum = indexExpr as? NumericLiteral
val indexVar = indexExpr as? IdentifierReference
when {
indexNum!=null -> {
@ -211,7 +269,7 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
ident != null -> inplaceModification_byte_variable_to_variable(targetVarName, target.datatype, operator, ident)
memread != null -> inplaceModification_byte_memread_to_variable(targetVarName, target.datatype, operator, memread)
value is TypecastExpression -> {
if (tryRemoveRedundantCast(value, target, operator)) return
if (tryInplaceModifyWithRemovedRedundantCast(value, target, operator)) return
inplaceModification_byte_value_to_variable(targetVarName, target.datatype, operator, value)
}
else -> inplaceModification_byte_value_to_variable(targetVarName, target.datatype, operator, value)
@ -223,7 +281,7 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
ident != null -> inplaceModification_word_variable_to_variable(targetVarName, target.datatype, operator, ident)
memread != null -> inplaceModification_word_memread_to_variable(targetVarName, target.datatype, operator, memread)
value is TypecastExpression -> {
if (tryRemoveRedundantCast(value, target, operator)) return
if (tryInplaceModifyWithRemovedRedundantCast(value, target, operator)) return
inplaceModification_word_value_to_variable(targetVarName, target.datatype, operator, value)
}
else -> inplaceModification_word_value_to_variable(targetVarName, target.datatype, operator, value)
@ -234,7 +292,7 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
valueLv != null -> inplaceModification_float_litval_to_variable(targetVarName, operator, valueLv.toDouble(), target.scope!!)
ident != null -> inplaceModification_float_variable_to_variable(targetVarName, operator, ident, target.scope!!)
value is TypecastExpression -> {
if (tryRemoveRedundantCast(value, target, operator)) return
if (tryInplaceModifyWithRemovedRedundantCast(value, target, operator)) return
inplaceModification_float_value_to_variable(targetVarName, operator, value, target.scope!!)
}
else -> inplaceModification_float_value_to_variable(targetVarName, operator, value, target.scope!!)
@ -246,19 +304,37 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
indexVar!=null -> {
when (target.datatype) {
in ByteDatatypes -> {
val tgt = AsmAssignTarget.fromRegisters(RegisterOrPair.A, null, program, asmgen)
val tgt =
AsmAssignTarget.fromRegisters(
RegisterOrPair.A,
target.datatype == DataType.BYTE, null,
program,
asmgen
)
val assign = AsmAssignment(target.origAssign.source, tgt, false, program.memsizer, value.position)
assignmentAsmGen.translateNormalAssignment(assign)
assignmentAsmGen.assignRegisterByte(target, CpuRegister.A)
}
in WordDatatypes -> {
val tgt = AsmAssignTarget.fromRegisters(RegisterOrPair.AY, null, program, asmgen)
val tgt =
AsmAssignTarget.fromRegisters(
RegisterOrPair.AY,
target.datatype == DataType.WORD, null,
program,
asmgen
)
val assign = AsmAssignment(target.origAssign.source, tgt, false, program.memsizer, value.position)
assignmentAsmGen.translateNormalAssignment(assign)
assignmentAsmGen.assignRegisterpairWord(target, RegisterOrPair.AY)
}
DataType.FLOAT -> {
val tgt = AsmAssignTarget.fromRegisters(RegisterOrPair.FAC1, null, program, asmgen)
val tgt =
AsmAssignTarget.fromRegisters(
RegisterOrPair.FAC1,
true, null,
program,
asmgen
)
val assign = AsmAssignment(target.origAssign.source, tgt, false, program.memsizer, value.position)
assignmentAsmGen.translateNormalAssignment(assign)
assignmentAsmGen.assignFAC1float(target)
@ -270,17 +346,15 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
}
}
}
TargetStorageKind.REGISTER -> throw AssemblyError("missing codegen for reg in-place modification")
TargetStorageKind.STACK -> throw AssemblyError("missing codegen for stack in-place modification")
TargetStorageKind.REGISTER -> throw AssemblyError("no asm gen for reg in-place modification")
TargetStorageKind.STACK -> throw AssemblyError("no asm gen for stack in-place modification")
}
}
private fun tryRemoveRedundantCast(value: TypecastExpression, target: AsmAssignTarget, operator: String): Boolean {
private fun tryInplaceModifyWithRemovedRedundantCast(value: TypecastExpression, target: AsmAssignTarget, operator: String): Boolean {
if (target.datatype == value.type) {
val childIDt = value.expression.inferType(program)
if(!childIDt.isKnown)
throw AssemblyError("unknown dt")
val childDt = childIDt.getOr(DataType.UNDEFINED)
val childDt = childIDt.getOrElse { throw AssemblyError("unknown dt") }
if (value.type!=DataType.FLOAT && (value.type.equalsSize(childDt) || value.type.largerThan(childDt))) {
// this typecast is redundant here; the rest of the code knows how to deal with the uncasted value.
// (works for integer types, not for float.)
@ -293,13 +367,14 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
private fun inplaceModification_byte_value_to_pointer(pointervar: IdentifierReference, operator: String, value: Expression) {
asmgen.assignExpressionToVariable(value, "P8ZP_SCRATCH_B1", DataType.UBYTE, null)
val sourceName = asmgen.loadByteFromPointerIntoA(pointervar)
when (operator) {
// note: ** (power) operator requires floats.
"+" -> asmgen.out(" clc | adc P8ZP_SCRATCH_B1")
"-" -> asmgen.out(" sec | sbc P8ZP_SCRATCH_B1")
"*" -> asmgen.out(" ldy P8ZP_SCRATCH_B1 | jsr math.multiply_bytes | ldy #0")
"/" -> asmgen.out(" ldy P8ZP_SCRATCH_B1 | jsr math.divmod_ub_asm | tya | ldy #0")
"%" -> asmgen.out(" ldy P8ZP_SCRATCH_B1 | jsr math.divmod_ub_asm | ldy #0")
"*" -> asmgen.out(" ldy P8ZP_SCRATCH_B1 | jsr math.multiply_bytes")
"/" -> asmgen.out(" ldy P8ZP_SCRATCH_B1 | jsr math.divmod_ub_asm | tya")
"%" -> asmgen.out(" ldy P8ZP_SCRATCH_B1 | jsr math.divmod_ub_asm")
"<<" -> {
asmgen.out("""
ldy P8ZP_SCRATCH_B1
@ -323,8 +398,7 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
"^", "xor" -> asmgen.out(" eor P8ZP_SCRATCH_B1")
else -> throw AssemblyError("invalid operator for in-place modification $operator")
}
val sourceName = asmgen.loadByteFromPointerIntoA(pointervar)
asmgen.out(" sta ($sourceName),y")
asmgen.storeAIntoZpPointerVar(sourceName)
}
private fun inplaceModification_byte_variable_to_pointer(pointervar: IdentifierReference, operator: String, value: IdentifierReference) {
@ -335,9 +409,9 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
// note: ** (power) operator requires floats.
"+" -> asmgen.out(" clc | adc $otherName")
"-" -> asmgen.out(" sec | sbc $otherName")
"*" -> asmgen.out(" ldy $otherName | jsr math.multiply_bytes | ldy #0")
"/" -> asmgen.out(" ldy $otherName | jsr math.divmod_ub_asm | tya | ldy #0")
"%" -> asmgen.out(" ldy $otherName | jsr math.divmod_ub_asm | ldy #0")
"*" -> asmgen.out(" ldy $otherName | jsr math.multiply_bytes")
"/" -> asmgen.out(" ldy $otherName | jsr math.divmod_ub_asm | tya")
"%" -> asmgen.out(" ldy $otherName | jsr math.divmod_ub_asm")
"<<" -> {
asmgen.out("""
ldy $otherName
@ -361,7 +435,7 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
"^", "xor" -> asmgen.out(" eor $otherName")
else -> throw AssemblyError("invalid operator for in-place modification $operator")
}
asmgen.out(" sta ($sourceName),y")
asmgen.storeAIntoZpPointerVar(sourceName)
}
private fun inplaceModification_byte_litval_to_pointer(pointervar: IdentifierReference, operator: String, value: Int) {
@ -370,63 +444,63 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
"+" -> {
val sourceName = asmgen.loadByteFromPointerIntoA(pointervar)
asmgen.out(" clc | adc #$value")
asmgen.out(" sta ($sourceName),y")
asmgen.storeAIntoZpPointerVar(sourceName)
}
"-" -> {
val sourceName = asmgen.loadByteFromPointerIntoA(pointervar)
asmgen.out(" sec | sbc #$value")
asmgen.out(" sta ($sourceName),y")
asmgen.storeAIntoZpPointerVar(sourceName)
}
"*" -> {
val sourceName = asmgen.loadByteFromPointerIntoA(pointervar)
if(value in asmgen.optimizedByteMultiplications)
asmgen.out(" jsr math.mul_byte_${value}")
else
asmgen.out(" ldy #$value | jsr math.multiply_bytes | ldy #0")
asmgen.out(" sta ($sourceName),y")
asmgen.out(" ldy #$value | jsr math.multiply_bytes")
asmgen.storeAIntoZpPointerVar(sourceName)
}
"/" -> {
val sourceName = asmgen.loadByteFromPointerIntoA(pointervar)
if(value==0)
throw AssemblyError("division by zero")
asmgen.out(" ldy #$value | jsr math.divmod_ub_asm | tya | ldy #0")
asmgen.out(" sta ($sourceName),y")
asmgen.out(" ldy #$value | jsr math.divmod_ub_asm | tya")
asmgen.storeAIntoZpPointerVar(sourceName)
}
"%" -> {
val sourceName = asmgen.loadByteFromPointerIntoA(pointervar)
if(value==0)
throw AssemblyError("division by zero")
asmgen.out(" ldy #$value | jsr math.divmod_ub_asm | ldy #0")
asmgen.out(" sta ($sourceName),y")
asmgen.out(" ldy #$value | jsr math.divmod_ub_asm")
asmgen.storeAIntoZpPointerVar(sourceName)
}
"<<" -> {
if (value > 0) {
val sourceName = asmgen.loadByteFromPointerIntoA(pointervar)
repeat(value) { asmgen.out(" asl a") }
asmgen.out(" sta ($sourceName),y")
asmgen.storeAIntoZpPointerVar(sourceName)
}
}
">>" -> {
if (value > 0) {
val sourceName = asmgen.loadByteFromPointerIntoA(pointervar)
repeat(value) { asmgen.out(" lsr a") }
asmgen.out(" sta ($sourceName),y")
asmgen.storeAIntoZpPointerVar(sourceName)
}
}
"&", "and" -> {
val sourceName = asmgen.loadByteFromPointerIntoA(pointervar)
asmgen.out(" and #$value")
asmgen.out(" sta ($sourceName),y")
asmgen.storeAIntoZpPointerVar(sourceName)
}
"|", "or" -> {
val sourceName = asmgen.loadByteFromPointerIntoA(pointervar)
asmgen.out(" ora #$value")
asmgen.out(" sta ($sourceName),y")
asmgen.storeAIntoZpPointerVar(sourceName)
}
"^", "xor" -> {
val sourceName = asmgen.loadByteFromPointerIntoA(pointervar)
asmgen.out(" eor #$value")
asmgen.out(" sta ($sourceName),y")
asmgen.storeAIntoZpPointerVar(sourceName)
}
else -> throw AssemblyError("invalid operator for in-place modification $operator")
}
@ -503,6 +577,26 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
asmgen.assignExpressionToRegister(value, RegisterOrPair.A)
asmgen.out(" eor $name | sta $name")
}
"==" -> {
asmgen.assignExpressionToRegister(value, RegisterOrPair.A)
asmgen.out("""
cmp $name
beq +
lda #0
beq ++
+ lda #1
+ sta $name""")
}
"!=" -> {
asmgen.assignExpressionToRegister(value, RegisterOrPair.A)
asmgen.out("""
cmp $name
beq +
lda #1
bne ++
+ lda #0
+ sta $name""")
}
else -> throw AssemblyError("invalid operator for in-place modification $operator")
}
}
@ -560,6 +654,26 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
"&", "and" -> asmgen.out(" lda $name | and $otherName | sta $name")
"|", "or" -> asmgen.out(" lda $name | ora $otherName | sta $name")
"^", "xor" -> asmgen.out(" lda $name | eor $otherName | sta $name")
"==" -> {
asmgen.out("""
lda $otherName
cmp $name
beq +
lda #0
bne ++
+ lda #1
+ sta $name""")
}
"!=" -> {
asmgen.out("""
lda $otherName
cmp $name
beq +
lda #1
bne ++
+ lda #0
+ sta $name""")
}
else -> throw AssemblyError("invalid operator for in-place modification $operator")
}
}
@ -631,6 +745,26 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
"&", "and" -> asmgen.out(" lda $name | and #$value | sta $name")
"|", "or" -> asmgen.out(" lda $name | ora #$value | sta $name")
"^", "xor" -> asmgen.out(" lda $name | eor #$value | sta $name")
"==" -> {
asmgen.out("""
lda $name
cmp #$value
beq +
lda #0
beq ++
+ lda #1
+ sta $name""")
}
"!=" -> {
asmgen.out("""
lda $name
cmp #$value
beq +
lda #1
bne ++
+ lda #0
+ sta $name""")
}
else -> throw AssemblyError("invalid operator for in-place modification $operator")
}
}
@ -638,14 +772,14 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
private fun inplaceModification_byte_memread_to_variable(name: String, dt: DataType, operator: String, memread: DirectMemoryRead) {
when (operator) {
"+" -> {
exprAsmGen.translateDirectMemReadExpression(memread, false)
asmgen.translateDirectMemReadExpressionToRegAorStack(memread, false)
asmgen.out("""
clc
adc $name
sta $name""")
}
"-" -> {
exprAsmGen.translateDirectMemReadExpression(memread, false)
asmgen.translateDirectMemReadExpressionToRegAorStack(memread, false)
asmgen.out("""
sta P8ZP_SCRATCH_B1
lda $name
@ -654,15 +788,15 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
sta $name""")
}
"|", "or" -> {
exprAsmGen.translateDirectMemReadExpression(memread, false)
asmgen.translateDirectMemReadExpressionToRegAorStack(memread, false)
asmgen.out(" ora $name | sta $name")
}
"&", "and" -> {
exprAsmGen.translateDirectMemReadExpression(memread, false)
asmgen.translateDirectMemReadExpressionToRegAorStack(memread, false)
asmgen.out(" and $name | sta $name")
}
"^", "xor" -> {
exprAsmGen.translateDirectMemReadExpression(memread, false)
asmgen.translateDirectMemReadExpressionToRegAorStack(memread, false)
asmgen.out(" eor $name | sta $name")
}
// TODO: tuned code for more operators
@ -675,7 +809,7 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
private fun inplaceModification_word_memread_to_variable(name: String, dt: DataType, operator: String, memread: DirectMemoryRead) {
when (operator) {
"+" -> {
exprAsmGen.translateDirectMemReadExpression(memread, false)
asmgen.translateDirectMemReadExpressionToRegAorStack(memread, false)
asmgen.out("""
clc
adc $name
@ -685,7 +819,7 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
+""")
}
"-" -> {
exprAsmGen.translateDirectMemReadExpression(memread, false)
asmgen.translateDirectMemReadExpressionToRegAorStack(memread, false)
asmgen.out("""
sta P8ZP_SCRATCH_B1
lda $name
@ -697,11 +831,11 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
+""")
}
"|", "or" -> {
exprAsmGen.translateDirectMemReadExpression(memread, false)
asmgen.translateDirectMemReadExpressionToRegAorStack(memread, false)
asmgen.out(" ora $name | sta $name")
}
"&", "and" -> {
exprAsmGen.translateDirectMemReadExpression(memread, false)
asmgen.translateDirectMemReadExpressionToRegAorStack(memread, false)
asmgen.out(" and $name | sta $name")
if(dt in WordDatatypes) {
if(asmgen.isTargetCpu(CpuType.CPU65c02))
@ -711,7 +845,7 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
}
}
"^", "xor" -> {
exprAsmGen.translateDirectMemReadExpression(memread, false)
asmgen.translateDirectMemReadExpressionToRegAorStack(memread, false)
asmgen.out(" eor $name | sta $name")
}
// TODO: tuned code for more operators
@ -935,6 +1069,18 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
else
asmgen.out(" lda #0 | sta $name | sta $name+1")
}
value == 0x00ff -> {
if(asmgen.isTargetCpu(CpuType.CPU65c02))
asmgen.out(" stz $name+1")
else
asmgen.out(" lda #0 | sta $name+1")
}
value == 0xff00 -> {
if(asmgen.isTargetCpu(CpuType.CPU65c02))
asmgen.out(" stz $name")
else
asmgen.out(" lda #0 | sta $name")
}
value and 255 == 0 -> {
if(asmgen.isTargetCpu(CpuType.CPU65c02))
asmgen.out(" stz $name")
@ -1014,25 +1160,30 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
+""")
else
asmgen.out("""
ldy #0
ldy #255
lda $otherName
bpl +
dey ; sign extend
+ sty P8ZP_SCRATCH_B1
lda $name
iny ; sign extend
+ eor #255
sec
sbc $otherName
adc $name
sta $name
lda $name+1
sbc P8ZP_SCRATCH_B1
tya
adc $name+1
sta $name+1""")
}
"*" -> {
if(valueDt==DataType.UBYTE) {
asmgen.out(" lda $otherName | sta P8ZP_SCRATCH_W1")
if(asmgen.isTargetCpu(CpuType.CPU65c02))
asmgen.out(" stz P8ZP_SCRATCH_W1+1")
else
asmgen.out(" lda #0 | sta P8ZP_SCRATCH_W1+1")
} else {
asmgen.out(" lda $otherName")
asmgen.signExtendAYlsb(valueDt)
asmgen.out(" sta P8ZP_SCRATCH_W1 | sty P8ZP_SCRATCH_W1+1")
}
asmgen.out("""
lda $name
ldy $name+1
@ -1084,7 +1235,8 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
sta $name
lda P8ZP_SCRATCH_W2+1
sta $name+1
""") }
""")
}
"<<" -> {
asmgen.out("""
ldy $otherName
@ -1216,9 +1368,7 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
// because the value is evaluated onto the eval stack (=slow).
val valueiDt = value.inferType(program)
if(!valueiDt.isKnown)
throw AssemblyError("unknown dt")
val valueDt = valueiDt.getOr(DataType.UNDEFINED)
val valueDt = valueiDt.getOrElse { throw AssemblyError("unknown dt") }
fun multiplyVarByWordInAY() {
asmgen.out("""
@ -1297,29 +1447,28 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
sta $name+1""")
}
"-" -> {
asmgen.assignExpressionToVariable(value, "P8ZP_SCRATCH_REG", valueDt, null)
asmgen.assignExpressionToVariable(value, "P8ZP_SCRATCH_B1", valueDt, null)
if(valueDt==DataType.UBYTE)
asmgen.out("""
lda $name
sec
sbc P8ZP_SCRATCH_REG
sbc P8ZP_SCRATCH_B1
sta $name
bcs +
dec $name+1
+""")
else
asmgen.out("""
ldy #0
lda P8ZP_SCRATCH_REG
ldy #255
lda P8ZP_SCRATCH_B1
bpl +
dey ; sign extend
+ sty P8ZP_SCRATCH_B1
lda $name
iny ; sign extend
+ eor #255
sec
sbc P8ZP_SCRATCH_REG
adc $name
sta $name
lda $name+1
sbc P8ZP_SCRATCH_B1
tya
adc $name+1
sta $name+1""")
}
"*" -> {
@ -1498,7 +1647,7 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
asmgen.saveRegisterLocal(CpuRegister.X, scope)
when (operator) {
"**" -> {
if(asmgen.haveFPWR()) {
if(asmgen.haveFPWRcall()) {
asmgen.out("""
lda #<$name
ldy #>$name
@ -1571,11 +1720,11 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
}
private fun inplaceModification_float_litval_to_variable(name: String, operator: String, value: Double, scope: Subroutine) {
val constValueName = asmgen.getFloatAsmConst(value)
val constValueName = allocator.getFloatAsmConst(value)
asmgen.saveRegisterLocal(CpuRegister.X, scope)
when (operator) {
"**" -> {
if(asmgen.haveFPWR()) {
if(asmgen.haveFPWRcall()) {
asmgen.out("""
lda #<$name
ldy #>$name
@ -1705,7 +1854,7 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
}
}
private fun inplaceBooleanNot(target: AsmAssignTarget, dt: DataType) {
internal fun inplaceBooleanNot(target: AsmAssignTarget, dt: DataType) {
when (dt) {
DataType.UBYTE -> {
when (target.kind) {
@ -1720,8 +1869,8 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
TargetStorageKind.MEMORY -> {
val mem = target.memory!!
when (mem.addressExpression) {
is NumericLiteralValue -> {
val addr = (mem.addressExpression as NumericLiteralValue).number.toHex()
is NumericLiteral -> {
val addr = (mem.addressExpression as NumericLiteral).number.toHex()
asmgen.out("""
lda $addr
beq +
@ -1735,23 +1884,43 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
beq +
lda #1
+ eor #1""")
asmgen.out(" sta ($sourceName),y")
asmgen.storeAIntoZpPointerVar(sourceName)
}
else -> {
asmgen.assignExpressionToVariable(mem.addressExpression, "P8ZP_SCRATCH_W2", DataType.UWORD, target.scope)
asmgen.loadAFromZpPointerVar("P8ZP_SCRATCH_W2")
asmgen.out("""
ldy #0
lda (P8ZP_SCRATCH_W2),y
beq +
lda #1
+ eor #1""")
asmgen.storeAIntoZpPointerVar("P8ZP_SCRATCH_W2")
}
}
}
TargetStorageKind.REGISTER -> {
when(target.register!!) {
RegisterOrPair.A -> asmgen.out("""
cmp #0
beq +
lda #1
+ eor #1""")
RegisterOrPair.X -> asmgen.out("""
txa
beq +
lda #1
+ eor #1
sta (P8ZP_SCRATCH_W2),y""")
tax""")
RegisterOrPair.Y -> asmgen.out("""
tya
beq +
lda #1
+ eor #1
tay""")
else -> throw AssemblyError("invalid reg dt for byte not")
}
}
}
TargetStorageKind.ARRAY -> throw AssemblyError("missing codegen for in-place not of ubyte array")
TargetStorageKind.REGISTER -> throw AssemblyError("missing codegen for reg not")
TargetStorageKind.STACK -> throw AssemblyError("missing codegen for stack not")
TargetStorageKind.STACK -> TODO("no asm gen for byte stack not")
else -> throw AssemblyError("no asm gen for in-place not of ubyte ${target.kind}")
}
}
DataType.UWORD -> {
@ -1767,17 +1936,55 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
lsr a
sta ${target.asmVarname}+1""")
}
TargetStorageKind.MEMORY -> throw AssemblyError("no asm gen for uword-memory not")
TargetStorageKind.ARRAY -> throw AssemblyError("missing codegen for in-place not of uword array")
TargetStorageKind.REGISTER -> throw AssemblyError("missing codegen for reg not")
TargetStorageKind.STACK -> throw AssemblyError("missing codegen for stack not")
TargetStorageKind.REGISTER -> {
when(target.register!!) {
RegisterOrPair.AX -> {
asmgen.out("""
stx P8ZP_SCRATCH_REG
ora P8ZP_SCRATCH_REG
beq +
lda #0
tax
beq ++
+ lda #1
+""")
}
RegisterOrPair.AY -> {
asmgen.out("""
sty P8ZP_SCRATCH_REG
ora P8ZP_SCRATCH_REG
beq +
lda #0
tay
beq ++
+ lda #1
+""")
}
RegisterOrPair.XY -> {
asmgen.out("""
stx P8ZP_SCRATCH_REG
tya
ora P8ZP_SCRATCH_REG
beq +
ldy #0
ldx #0
beq ++
+ ldx #1
+""")
}
in Cx16VirtualRegisters -> throw AssemblyError("cx16 virtual regs should be variables, not real registers")
else -> throw AssemblyError("invalid reg dt for word not")
}
}
TargetStorageKind.STACK -> TODO("no asm gen for word stack not")
else -> throw AssemblyError("no asm gen for in-place not of uword for ${target.kind}")
}
}
else -> throw AssemblyError("boolean-not of invalid type")
}
}
private fun inplaceInvert(target: AsmAssignTarget, dt: DataType) {
internal fun inplaceInvert(target: AsmAssignTarget, dt: DataType) {
when (dt) {
DataType.UBYTE -> {
when (target.kind) {
@ -1790,8 +1997,8 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
TargetStorageKind.MEMORY -> {
val memory = target.memory!!
when (memory.addressExpression) {
is NumericLiteralValue -> {
val addr = (memory.addressExpression as NumericLiteralValue).number.toHex()
is NumericLiteral -> {
val addr = (memory.addressExpression as NumericLiteral).number.toHex()
asmgen.out("""
lda $addr
eor #255
@ -1807,14 +2014,21 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
asmgen.out("""
ldy #0
lda (P8ZP_SCRATCH_W2),y
eor #255
sta (P8ZP_SCRATCH_W2),y""")
eor #255""")
asmgen.storeAIntoZpPointerVar("P8ZP_SCRATCH_W2")
}
}
}
TargetStorageKind.ARRAY -> throw AssemblyError("missing codegen for in-place invert ubyte array")
TargetStorageKind.REGISTER -> throw AssemblyError("missing codegen for reg invert")
TargetStorageKind.STACK -> throw AssemblyError("missing codegen for stack invert")
TargetStorageKind.REGISTER -> {
when(target.register!!) {
RegisterOrPair.A -> asmgen.out(" eor #255")
RegisterOrPair.X -> asmgen.out(" txa | eor #255 | tax")
RegisterOrPair.Y -> asmgen.out(" tya | eor #255 | tay")
else -> throw AssemblyError("invalid reg dt for byte invert")
}
}
TargetStorageKind.STACK -> TODO("no asm gen for byte stack invert")
else -> throw AssemblyError("no asm gen for in-place invert ubyte for ${target.kind}")
}
}
DataType.UWORD -> {
@ -1828,17 +2042,24 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
eor #255
sta ${target.asmVarname}+1""")
}
TargetStorageKind.MEMORY -> throw AssemblyError("no asm gen for uword-memory invert")
TargetStorageKind.ARRAY -> throw AssemblyError("missing codegen for in-place invert uword array")
TargetStorageKind.REGISTER -> throw AssemblyError("missing codegen for reg invert")
TargetStorageKind.STACK -> throw AssemblyError("missing codegen for stack invert")
TargetStorageKind.REGISTER -> {
when(target.register!!) {
RegisterOrPair.AX -> asmgen.out(" pha | txa | eor #255 | tax | pla | eor #255")
RegisterOrPair.AY -> asmgen.out(" pha | tya | eor #255 | tay | pla | eor #255")
RegisterOrPair.XY -> asmgen.out(" txa | eor #255 | tax | tya | eor #255 | tay")
in Cx16VirtualRegisters -> throw AssemblyError("cx16 virtual regs should be variables, not real registers")
else -> throw AssemblyError("invalid reg dt for word invert")
}
}
TargetStorageKind.STACK -> TODO("no asm gen for word stack invert")
else -> throw AssemblyError("no asm gen for in-place invert uword for ${target.kind}")
}
}
else -> throw AssemblyError("invert of invalid type")
}
}
private fun inplaceNegate(target: AsmAssignTarget, dt: DataType) {
internal fun inplaceNegate(target: AsmAssignTarget, dt: DataType) {
when (dt) {
DataType.BYTE -> {
when (target.kind) {
@ -1849,10 +2070,23 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
sbc ${target.asmVarname}
sta ${target.asmVarname}""")
}
TargetStorageKind.MEMORY -> throw AssemblyError("can't in-place negate memory ubyte")
TargetStorageKind.ARRAY -> throw AssemblyError("missing codegen for in-place negate byte array")
TargetStorageKind.REGISTER -> throw AssemblyError("missing codegen for reg negate")
TargetStorageKind.STACK -> throw AssemblyError("missing codegen for stack negate")
TargetStorageKind.REGISTER -> {
when(target.register!!) {
RegisterOrPair.A -> {
if(asmgen.isTargetCpu(CpuType.CPU65c02))
asmgen.out(" eor #255 | ina")
else
asmgen.out(" eor #255 | clc | adc #1")
}
RegisterOrPair.X -> asmgen.out(" txa | eor #255 | tax | inx")
RegisterOrPair.Y -> asmgen.out(" tya | eor #255 | tay | iny")
else -> throw AssemblyError("invalid reg dt for byte negate")
}
}
TargetStorageKind.MEMORY -> throw AssemblyError("memory is ubyte, can't in-place negate")
TargetStorageKind.STACK -> TODO("no asm gen for byte stack negate")
else -> throw AssemblyError("no asm gen for in-place negate byte")
}
}
DataType.WORD -> {
@ -1867,10 +2101,50 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
sbc ${target.asmVarname}+1
sta ${target.asmVarname}+1""")
}
TargetStorageKind.ARRAY -> throw AssemblyError("missing codegen for in-place negate word array")
TargetStorageKind.MEMORY -> throw AssemblyError("no asm gen for word memory negate")
TargetStorageKind.REGISTER -> throw AssemblyError("missing codegen for reg negate")
TargetStorageKind.STACK -> throw AssemblyError("missing codegen for stack negate")
TargetStorageKind.REGISTER -> {
when(target.register!!) { //P8ZP_SCRATCH_REG
RegisterOrPair.AX -> {
asmgen.out("""
sec
eor #255
adc #0
pha
txa
eor #255
adc #0
tax
pla""")
}
RegisterOrPair.AY -> {
asmgen.out("""
sec
eor #255
adc #0
pha
tya
eor #255
adc #0
tay
pla""")
}
RegisterOrPair.XY -> {
asmgen.out("""
sec
txa
eor #255
adc #0
tax
tya
eor #255
adc #0
tay""")
}
in Cx16VirtualRegisters -> throw AssemblyError("cx16 virtual regs should be variables, not real registers")
else -> throw AssemblyError("invalid reg dt for word neg")
}
}
TargetStorageKind.STACK -> TODO("no asm gen for word stack negate")
else -> throw AssemblyError("no asm gen for in-place negate word")
}
}
DataType.FLOAT -> {
@ -1883,12 +2157,11 @@ internal class AugmentableAssignmentAsmGen(private val program: Program,
sta ${target.asmVarname}+1
""")
}
TargetStorageKind.ARRAY -> throw AssemblyError("missing codegen for in-place negate float array")
TargetStorageKind.STACK -> throw AssemblyError("missing codegen for stack float negate")
else -> throw AssemblyError("weird target kind for float")
TargetStorageKind.STACK -> TODO("no asm gen for float stack negate")
else -> throw AssemblyError("weird target kind for inplace negate float ${target.kind}")
}
}
else -> throw AssemblyError("negate of invalid type")
else -> throw AssemblyError("negate of invalid type $dt")
}
}

46
codeGenExperimental6502/build.gradle Normal file
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@ -0,0 +1,46 @@
plugins {
id 'java'
id 'application'
id "org.jetbrains.kotlin.jvm"
}
java {
toolchain {
languageVersion = JavaLanguageVersion.of(javaVersion)
}
}
compileKotlin {
kotlinOptions {
jvmTarget = javaVersion
}
}
compileTestKotlin {
kotlinOptions {
jvmTarget = javaVersion
}
}
dependencies {
implementation project(':compilerInterfaces')
implementation project(':compilerAst')
implementation "org.jetbrains.kotlin:kotlin-stdlib-jdk8"
// implementation "org.jetbrains.kotlin:kotlin-reflect"
implementation "com.michael-bull.kotlin-result:kotlin-result-jvm:1.1.12"
}
sourceSets {
main {
java {
srcDirs = ["${project.projectDir}/src"]
}
resources {
srcDirs = ["${project.projectDir}/res"]
}
}
}
// note: there are no unit tests in this module!

16
codeGenExperimental6502/codeGenExperimental6502.iml Normal file
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@ -0,0 +1,16 @@
<?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://$MODULE_DIR$">
<sourceFolder url="file://$MODULE_DIR$/src" isTestSource="false" />
<excludeFolder url="file://$MODULE_DIR$/build" />
</content>
<orderEntry type="inheritedJdk" />
<orderEntry type="sourceFolder" forTests="false" />
<orderEntry type="library" name="KotlinJavaRuntime" level="project" />
<orderEntry type="module" module-name="compilerAst" />
<orderEntry type="module" module-name="compilerInterfaces" />
<orderEntry type="library" name="michael.bull.kotlin.result.jvm" level="project" />
</component>
</module>

18
codeGenExperimental6502/src/prog8/codegen/experimental6502/AsmGen.kt Normal file
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@ -0,0 +1,18 @@
package prog8.codegen.experimental6502
import prog8.ast.Program
import prog8.compilerinterface.*
class AsmGen(internal val program: Program,
internal val errors: IErrorReporter,
internal val variables: IVariablesAndConsts,
internal val options: CompilationOptions): IAssemblyGenerator {
override fun compileToAssembly(): IAssemblyProgram? {
println("\n** experimental 65(c)02 code generator **\n")
println("..todo: create assembly code into ${options.outputDir.toAbsolutePath()}..")
return AssemblyProgram("dummy")
}
}

13
codeGenExperimental6502/src/prog8/codegen/experimental6502/AssemblyProgram.kt Normal file
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@ -0,0 +1,13 @@
package prog8.codegen.experimental6502
import prog8.compilerinterface.CompilationOptions
import prog8.compilerinterface.IAssemblyProgram
internal class AssemblyProgram(override val name: String) : IAssemblyProgram
{
override fun assemble(options: CompilationOptions): Boolean {
println("..todo: assemble code into binary..")
return false
}
}

46
codeGenTargets/build.gradle Normal file
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@ -0,0 +1,46 @@
plugins {
id 'java'
id 'application'
id "org.jetbrains.kotlin.jvm"
}
java {
toolchain {
languageVersion = JavaLanguageVersion.of(javaVersion)
}
}
compileKotlin {
kotlinOptions {
jvmTarget = javaVersion
}
}
compileTestKotlin {
kotlinOptions {
jvmTarget = javaVersion
}
}
dependencies {
implementation project(':compilerInterfaces')
implementation project(':compilerAst')
implementation "org.jetbrains.kotlin:kotlin-stdlib-jdk8"
// implementation "org.jetbrains.kotlin:kotlin-reflect"
implementation "com.michael-bull.kotlin-result:kotlin-result-jvm:1.1.12"
}
sourceSets {
main {
java {
srcDirs = ["${project.projectDir}/src"]
}
resources {
srcDirs = ["${project.projectDir}/res"]
}
}
}
// note: there are no unit tests in this module!

16
codeGenTargets/codeGenTargets.iml Normal file
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@ -0,0 +1,16 @@
<?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://$MODULE_DIR$">
<sourceFolder url="file://$MODULE_DIR$/src" isTestSource="false" />
<excludeFolder url="file://$MODULE_DIR$/build" />
</content>
<orderEntry type="inheritedJdk" />
<orderEntry type="sourceFolder" forTests="false" />
<orderEntry type="library" name="KotlinJavaRuntime" level="project" />
<orderEntry type="library" name="michael.bull.kotlin.result.jvm" level="project" />
<orderEntry type="module" module-name="compilerInterfaces" />
<orderEntry type="module" module-name="compilerAst" />
</component>
</module>

2
codeGenTargets/readme-tests.txt Normal file
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@ -0,0 +1,2 @@
Unittests for things in this module are located in the Compiler module instead,
for convenience sake, and to not spread the test cases around too much.

27
codeGenTargets/src/prog8/codegen/target/C128Target.kt Normal file
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@ -0,0 +1,27 @@
package prog8.codegen.target
import prog8.ast.expressions.Expression
import prog8.ast.statements.RegisterOrStatusflag
import prog8.ast.statements.Subroutine
import prog8.codegen.target.c128.C128MachineDefinition
import prog8.codegen.target.cbm.CbmMemorySizer
import prog8.codegen.target.cbm.asmsub6502ArgsEvalOrder
import prog8.codegen.target.cbm.asmsub6502ArgsHaveRegisterClobberRisk
import prog8.compilerinterface.ICompilationTarget
import prog8.compilerinterface.IMemSizer
import prog8.compilerinterface.IStringEncoding
class C128Target: ICompilationTarget, IStringEncoding by Encoder, IMemSizer by CbmMemorySizer {
override val name = NAME
override val machine = C128MachineDefinition()
companion object {
const val NAME = "c128"
}
override fun asmsubArgsEvalOrder(sub: Subroutine): List<Int> =
asmsub6502ArgsEvalOrder(sub)
override fun asmsubArgsHaveRegisterClobberRisk(args: List<Expression>, paramRegisters: List<RegisterOrStatusflag>) =
asmsub6502ArgsHaveRegisterClobberRisk(args, paramRegisters)
}

27
codeGenTargets/src/prog8/codegen/target/C64Target.kt Normal file
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@ -0,0 +1,27 @@
package prog8.codegen.target
import prog8.ast.expressions.Expression
import prog8.ast.statements.RegisterOrStatusflag
import prog8.ast.statements.Subroutine
import prog8.codegen.target.c64.C64MachineDefinition
import prog8.codegen.target.cbm.CbmMemorySizer
import prog8.codegen.target.cbm.asmsub6502ArgsEvalOrder
import prog8.codegen.target.cbm.asmsub6502ArgsHaveRegisterClobberRisk
import prog8.compilerinterface.ICompilationTarget
import prog8.compilerinterface.IMemSizer
import prog8.compilerinterface.IStringEncoding
class C64Target: ICompilationTarget, IStringEncoding by Encoder, IMemSizer by CbmMemorySizer {
override val name = NAME
override val machine = C64MachineDefinition()
companion object {
const val NAME = "c64"
}
override fun asmsubArgsEvalOrder(sub: Subroutine): List<Int> =
asmsub6502ArgsEvalOrder(sub)
override fun asmsubArgsHaveRegisterClobberRisk(args: List<Expression>, paramRegisters: List<RegisterOrStatusflag>) =
asmsub6502ArgsHaveRegisterClobberRisk(args, paramRegisters)
}

27
codeGenTargets/src/prog8/codegen/target/Cx16Target.kt Normal file
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@ -0,0 +1,27 @@
package prog8.codegen.target
import prog8.ast.expressions.Expression
import prog8.ast.statements.RegisterOrStatusflag
import prog8.ast.statements.Subroutine
import prog8.codegen.target.cbm.CbmMemorySizer
import prog8.codegen.target.cbm.asmsub6502ArgsEvalOrder
import prog8.codegen.target.cbm.asmsub6502ArgsHaveRegisterClobberRisk
import prog8.codegen.target.cx16.CX16MachineDefinition
import prog8.compilerinterface.ICompilationTarget
import prog8.compilerinterface.IMemSizer
import prog8.compilerinterface.IStringEncoding
class Cx16Target: ICompilationTarget, IStringEncoding by Encoder, IMemSizer by CbmMemorySizer {
override val name = NAME
override val machine = CX16MachineDefinition()
companion object {
const val NAME = "cx16"
}
override fun asmsubArgsEvalOrder(sub: Subroutine): List<Int> =
asmsub6502ArgsEvalOrder(sub)
override fun asmsubArgsHaveRegisterClobberRisk(args: List<Expression>, paramRegisters: List<RegisterOrStatusflag>) =
asmsub6502ArgsHaveRegisterClobberRisk(args, paramRegisters)
}

35
codeGenTargets/src/prog8/codegen/target/Encoder.kt Normal file
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@ -0,0 +1,35 @@
package prog8.codegen.target
import com.github.michaelbull.result.fold
import prog8.ast.base.FatalAstException
import prog8.codegen.target.cbm.IsoEncoding
import prog8.codegen.target.cbm.PetsciiEncoding
import prog8.compilerinterface.Encoding
import prog8.compilerinterface.IStringEncoding
internal object Encoder: IStringEncoding {
override fun encodeString(str: String, encoding: Encoding): List<UByte> { // TODO use Result
val coded = when(encoding) {
Encoding.PETSCII -> PetsciiEncoding.encodePetscii(str, true)
Encoding.SCREENCODES -> PetsciiEncoding.encodeScreencode(str, true)
Encoding.ISO -> IsoEncoding.encode(str)
else -> throw FatalAstException("unsupported encoding $encoding")
}
return coded.fold(
failure = { throw it },
success = { it }
)
}
override fun decodeString(bytes: List<UByte>, encoding: Encoding): String { // TODO use Result
val decoded = when(encoding) {
Encoding.PETSCII -> PetsciiEncoding.decodePetscii(bytes, true)
Encoding.SCREENCODES -> PetsciiEncoding.decodeScreencode(bytes, true)
Encoding.ISO -> IsoEncoding.decode(bytes)
else -> throw FatalAstException("unsupported encoding $encoding")
}
return decoded.fold(
failure = { throw it },
success = { it }
)
}
}

65
codeGenTargets/src/prog8/codegen/target/c128/C128MachineDefinition.kt Normal file
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@ -0,0 +1,65 @@
package prog8.codegen.target.c128
import prog8.codegen.target.c64.normal6502instructions
import prog8.codegen.target.cbm.Mflpt5
import prog8.compilerinterface.*
import java.io.IOException
import java.nio.file.Path
class C128MachineDefinition: IMachineDefinition {
override val cpu = CpuType.CPU6502
override val FLOAT_MAX_POSITIVE = Mflpt5.FLOAT_MAX_POSITIVE
override val FLOAT_MAX_NEGATIVE = Mflpt5.FLOAT_MAX_NEGATIVE
override val FLOAT_MEM_SIZE = Mflpt5.FLOAT_MEM_SIZE
override val BASIC_LOAD_ADDRESS = 0x1c01u
override val RAW_LOAD_ADDRESS = 0x1300u
// the 2*256 byte evaluation stack (on which bytes, words, and even floats are stored during calculations)
override val ESTACK_LO = 0x1a00u // $1a00-$1aff inclusive
override val ESTACK_HI = 0x1b00u // $1b00-$1bff inclusive
override lateinit var zeropage: Zeropage
override fun getFloat(num: Number) = Mflpt5.fromNumber(num)
override fun importLibs(compilerOptions: CompilationOptions, compilationTargetName: String): List<String> {
return if (compilerOptions.launcher == LauncherType.BASIC || compilerOptions.output == OutputType.PRG)
listOf("syslib")
else
emptyList()
}
override fun launchEmulator(selectedEmulator: Int, programNameWithPath: Path) {
if(selectedEmulator!=1) {
System.err.println("The c128 target only supports the main emulator (Vice).")
return
}
for(emulator in listOf("x128")) {
println("\nStarting C-128 emulator $emulator...")
val viceMonlist = viceMonListName(programNameWithPath.toString())
val cmdline = listOf(emulator, "-silent", "-moncommands", viceMonlist,
"-autostartprgmode", "1", "-autostart-warp", "-autostart", "${programNameWithPath}.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 isIOAddress(address: UInt): Boolean = address==0u || address==1u || address in 0xd000u..0xdfffu
override fun initializeZeropage(compilerOptions: CompilationOptions) {
zeropage = C128Zeropage(compilerOptions)
}
override val opcodeNames = normal6502instructions
}

42
codeGenTargets/src/prog8/codegen/target/c128/C128Zeropage.kt Normal file
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@ -0,0 +1,42 @@
package prog8.codegen.target.c128
import prog8.compilerinterface.CompilationOptions
import prog8.compilerinterface.InternalCompilerException
import prog8.compilerinterface.Zeropage
import prog8.compilerinterface.ZeropageType
class C128Zeropage(options: CompilationOptions) : Zeropage(options) {
override val SCRATCH_B1 = 0x9bu // temp storage for a single byte
override val SCRATCH_REG = 0x9cu // temp storage for a register, must be B1+1
override val SCRATCH_W1 = 0xfbu // temp storage 1 for a word $fb+$fc
override val SCRATCH_W2 = 0xfdu // temp storage 2 for a word $fd+$fe
init {
if (options.floats && options.zeropage !in arrayOf(
ZeropageType.FLOATSAFE,
ZeropageType.BASICSAFE,
ZeropageType.DONTUSE
))
throw InternalCompilerException("when floats are enabled, zero page type should be 'floatsafe' or 'basicsafe' or 'dontuse'")
when (options.zeropage) {
ZeropageType.FULL -> {
// TODO all c128 usable zero page locations, except the ones used by the system's IRQ routine
free.addAll(0x0au..0xffu) // TODO c128 what about $02-$09?
// TODO c128 free.removeAll(setOf(0xa0u, 0xa1u, 0xa2u, 0x91u, 0xc0u, 0xc5u, 0xcbu, 0xf5u, 0xf6u)) // these are updated by IRQ
}
ZeropageType.KERNALSAFE,
ZeropageType.FLOATSAFE,
ZeropageType.BASICSAFE -> {
free.clear() // TODO c128 usable zero page addresses
}
ZeropageType.DONTUSE -> {
free.clear() // don't use zeropage at all
}
}
removeReservedFromFreePool()
}
}

77
codeGenTargets/src/prog8/codegen/target/c64/C64MachineDefinition.kt Normal file
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@ -0,0 +1,77 @@
package prog8.codegen.target.c64
import prog8.codegen.target.cbm.Mflpt5
import prog8.compilerinterface.*
import java.io.IOException
import java.nio.file.Path
class C64MachineDefinition: IMachineDefinition {
override val cpu = CpuType.CPU6502
override val FLOAT_MAX_POSITIVE = Mflpt5.FLOAT_MAX_POSITIVE
override val FLOAT_MAX_NEGATIVE = Mflpt5.FLOAT_MAX_NEGATIVE
override val FLOAT_MEM_SIZE = Mflpt5.FLOAT_MEM_SIZE
override val BASIC_LOAD_ADDRESS = 0x0801u
override val RAW_LOAD_ADDRESS = 0xc000u
// the 2*256 byte evaluation stack (on which bytes, words, and even floats are stored during calculations)
override val ESTACK_LO = 0xce00u // $ce00-$ceff inclusive
override val ESTACK_HI = 0xcf00u // $ce00-$ceff inclusive
override lateinit var zeropage: Zeropage
override fun getFloat(num: Number) = Mflpt5.fromNumber(num)
override fun importLibs(compilerOptions: CompilationOptions, compilationTargetName: String): List<String> {
return if (compilerOptions.launcher == LauncherType.BASIC || compilerOptions.output == OutputType.PRG)
listOf("syslib")
else
emptyList()
}
override fun launchEmulator(selectedEmulator: Int, programNameWithPath: Path) {
if(selectedEmulator!=1) {
System.err.println("The c64 target only supports the main emulator (Vice).")
return
}
for(emulator in listOf("x64sc", "x64")) {
println("\nStarting C-64 emulator $emulator...")
val viceMonlist = viceMonListName(programNameWithPath.toString())
val cmdline = listOf(emulator, "-silent", "-moncommands", viceMonlist,
"-autostartprgmode", "1", "-autostart-warp", "-autostart", "${programNameWithPath}.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 isIOAddress(address: UInt): Boolean = address==0u || address==1u || address in 0xd000u..0xdfffu
override fun initializeZeropage(compilerOptions: CompilationOptions) {
zeropage = C64Zeropage(compilerOptions)
}
override val opcodeNames = normal6502instructions
}
// 6502 opcodes (including aliases and illegal opcodes), these cannot be used as variable or label names
internal val normal6502instructions = setOf(
"adc", "ahx", "alr", "anc", "and", "ane", "arr", "asl", "asr", "axs", "bcc", "bcs",
"beq", "bge", "bit", "blt", "bmi", "bne", "bpl", "brk", "bvc", "bvs", "clc",
"cld", "cli", "clv", "cmp", "cpx", "cpy", "dcm", "dcp", "dec", "dex", "dey",
"eor", "gcc", "gcs", "geq", "gge", "glt", "gmi", "gne", "gpl", "gvc", "gvs",
"inc", "ins", "inx", "iny", "isb", "isc", "jam", "jmp", "jsr", "lae", "las",
"lax", "lda", "lds", "ldx", "ldy", "lsr", "lxa", "nop", "ora", "pha", "php",
"pla", "plp", "rla", "rol", "ror", "rra", "rti", "rts", "sax", "sbc", "sbx",
"sec", "sed", "sei", "sha", "shl", "shr", "shs", "shx", "shy", "slo", "sre",
"sta", "stx", "sty", "tas", "tax", "tay", "tsx", "txa", "txs", "tya", "xaa")

73
codeGenTargets/src/prog8/codegen/target/c64/C64Zeropage.kt Normal file
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@ -0,0 +1,73 @@
package prog8.codegen.target.c64
import prog8.compilerinterface.CompilationOptions
import prog8.compilerinterface.InternalCompilerException
import prog8.compilerinterface.Zeropage
import prog8.compilerinterface.ZeropageType
class C64Zeropage(options: CompilationOptions) : Zeropage(options) {
override val SCRATCH_B1 = 0x02u // temp storage for a single byte
override val SCRATCH_REG = 0x03u // temp storage for a register, must be B1+1
override val SCRATCH_W1 = 0xfbu // temp storage 1 for a word $fb+$fc
override val SCRATCH_W2 = 0xfdu // temp storage 2 for a word $fd+$fe
init {
if (options.floats && options.zeropage !in arrayOf(
ZeropageType.FLOATSAFE,
ZeropageType.BASICSAFE,
ZeropageType.DONTUSE
))
throw InternalCompilerException("when floats are enabled, zero page type should be 'floatsafe' or 'basicsafe' or 'dontuse'")
if (options.zeropage == ZeropageType.FULL) {
free.addAll(0x02u..0xffu)
free.removeAll(setOf(SCRATCH_B1, SCRATCH_REG, SCRATCH_W1, SCRATCH_W1+1u, SCRATCH_W2, SCRATCH_W2+1u))
free.removeAll(setOf(0xa0u, 0xa1u, 0xa2u, 0x91u, 0xc0u, 0xc5u, 0xcbu, 0xf5u, 0xf6u)) // 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,
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 'kernal work storage area'
).map{it.toUInt()})
}
if (options.zeropage == ZeropageType.FLOATSAFE) {
// remove the zeropage locations used for floating point operations from the free list
free.removeAll(listOf(
0x22, 0x23, 0x24, 0x25,
0x10, 0x11, 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, 0xff
).map{it.toUInt()})
}
if(options.zeropage!= ZeropageType.DONTUSE) {
// add the free Zp addresses
// these are valid for the C-64 but allow BASIC to keep running fully *as long as you don't use tape I/O*
free.addAll(listOf(0x04, 0x05, 0x06, 0x0a, 0x0e,
0x92, 0x96, 0x9b, 0x9c, 0x9e, 0x9f, 0xa5, 0xa6,
0xb0, 0xb1, 0xbe, 0xbf, 0xf9).map{it.toUInt()})
} else {
// don't use the zeropage at all
free.clear()
}
}
removeReservedFromFreePool()
}
}

61
codeGenTargets/src/prog8/codegen/target/cbm/AsmsubHelpers.kt Normal file
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@ -0,0 +1,61 @@
package prog8.codegen.target.cbm
import prog8.ast.base.Cx16VirtualRegisters
import prog8.ast.base.RegisterOrPair
import prog8.ast.expressions.ArrayIndexedExpression
import prog8.ast.expressions.Expression
import prog8.ast.expressions.FunctionCallExpression
import prog8.ast.statements.RegisterOrStatusflag
import prog8.ast.statements.Subroutine
internal fun asmsub6502ArgsEvalOrder(sub: Subroutine): List<Int> {
val order = mutableListOf<Int>()
// order is:
// 1) cx16 virtual word registers,
// 2) paired CPU registers,
// 3) single CPU registers (X last), except A,
// 4) CPU Carry status flag
// 5) the A register itself last (so everything before it can use the accumulator without having to save its value)
val args = sub.parameters.zip(sub.asmParameterRegisters).withIndex()
val (cx16regs, args2) = args.partition { it.value.second.registerOrPair in Cx16VirtualRegisters }
val pairedRegisters = arrayOf(RegisterOrPair.AX, RegisterOrPair.AY, RegisterOrPair.XY)
val (pairedRegs , args3) = args2.partition { it.value.second.registerOrPair in pairedRegisters }
val (regsWithoutA, args4) = args3.partition { it.value.second.registerOrPair != RegisterOrPair.A }
val (regA, rest) = args4.partition { it.value.second.registerOrPair != null }
cx16regs.forEach { order += it.index }
pairedRegs.forEach { order += it.index }
regsWithoutA.forEach {
if(it.value.second.registerOrPair != RegisterOrPair.X)
order += it.index
}
regsWithoutA.firstOrNull { it.value.second.registerOrPair==RegisterOrPair.X } ?.let { order += it.index}
rest.forEach { order += it.index }
regA.forEach { order += it.index }
require(order.size==sub.parameters.size)
return order
}
internal fun asmsub6502ArgsHaveRegisterClobberRisk(args: List<Expression>,
paramRegisters: List<RegisterOrStatusflag>): Boolean {
fun isClobberRisk(expr: Expression): Boolean {
when (expr) {
is ArrayIndexedExpression -> {
return paramRegisters.any {
it.registerOrPair in listOf(RegisterOrPair.Y, RegisterOrPair.AY, RegisterOrPair.XY)
}
}
is FunctionCallExpression -> {
if (expr.target.nameInSource == listOf("lsb") || expr.target.nameInSource == listOf("msb"))
return isClobberRisk(expr.args[0])
if (expr.target.nameInSource == listOf("mkword"))
return isClobberRisk(expr.args[0]) && isClobberRisk(expr.args[1])
return !expr.isSimple
}
else -> return !expr.isSimple
}
}
return args.size>1 && args.any { isClobberRisk(it) }
}

31
codeGenTargets/src/prog8/codegen/target/cbm/CbmMemorySizer.kt Normal file
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@ -0,0 +1,31 @@
package prog8.codegen.target.cbm
import prog8.ast.base.*
import prog8.ast.expressions.StringLiteral
import prog8.ast.statements.VarDecl
import prog8.compilerinterface.IMemSizer
internal object CbmMemorySizer: IMemSizer {
override fun memorySize(dt: DataType): Int {
return when(dt) {
in ByteDatatypes -> 1
in WordDatatypes, in PassByReferenceDatatypes -> 2
DataType.FLOAT -> Mflpt5.FLOAT_MEM_SIZE
else -> Int.MIN_VALUE
}
}
override fun memorySize(decl: VarDecl): Int {
return when(decl.type) {
VarDeclType.CONST -> 0
VarDeclType.VAR, VarDeclType.MEMORY -> {
when(val dt = decl.datatype) {
in NumericDatatypes -> return memorySize(dt)
in ArrayDatatypes -> decl.arraysize!!.constIndex()!! * memorySize(ArrayToElementTypes.getValue(dt))
DataType.STR -> (decl.value as StringLiteral).value.length + 1
else -> 0
}
}
}
}
}

27
codeGenTargets/src/prog8/codegen/target/cbm/IsoEncoding.kt Normal file
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@ -0,0 +1,27 @@
package prog8.codegen.target.cbm
import com.github.michaelbull.result.Err
import com.github.michaelbull.result.Ok
import com.github.michaelbull.result.Result
import java.io.CharConversionException
import java.nio.charset.Charset
object IsoEncoding {
val charset: Charset = Charset.forName("ISO-8859-15")
fun encode(str: String): Result<List<UByte>, CharConversionException> {
return try {
Ok(str.toByteArray(charset).map { it.toUByte() })
} catch (ce: CharConversionException) {
Err(ce)
}
}
fun decode(bytes: List<UByte>): Result<String, CharConversionException> {
return try {
Ok(String(bytes.map { it.toByte() }.toByteArray(), charset))
} catch (ce: CharConversionException) {
Err(ce)
}
}
}

78
codeGenTargets/src/prog8/codegen/target/cbm/Mflpt5.kt Normal file
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@ -0,0 +1,78 @@
package prog8.codegen.target.cbm
import prog8.compilerinterface.IMachineFloat
import prog8.compilerinterface.InternalCompilerException
import kotlin.math.absoluteValue
import kotlin.math.pow
data class Mflpt5(val b0: UByte, val b1: UByte, val b2: UByte, val b3: UByte, val b4: UByte): IMachineFloat {
companion object {
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 FLOAT_MEM_SIZE = 5
val zero = Mflpt5(0u, 0u, 0u, 0u, 0u)
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 InternalCompilerException("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 InternalCompilerException("floating point overflow: $this")
exponent == 0 -> zero
else -> {
val mantLong = mantissa.toLong()
Mflpt5(
exponent.toUByte(),
(mantLong.and(0x7f000000L) ushr 24).or(sign).toUByte(),
(mantLong.and(0x00ff0000L) ushr 16).toUByte(),
(mantLong.and(0x0000ff00L) ushr 8).toUByte(),
(mantLong.and(0x000000ffL)).toUByte()
)
}
}
}
}
override fun toDouble(): Double {
if (this == zero) return 0.0
val exp = b0.toInt() - 128
val sign = (b1.toInt() and 0x80) > 0
val number = 0x80000000L.or(b1.toLong() shl 24).or(b2.toLong() shl 16).or(b3.toLong() shl 8).or(b4.toLong())
val result = number.toDouble() * (2.0).pow(exp) / 0x100000000
return if (sign) -result else result
}
override fun makeFloatFillAsm(): String {
val b0 = "$" + 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"
}
}

175
compiler/src/prog8/compiler/target/cbm/Petscii.kt → codeGenTargets/src/prog8/codegen/target/cbm/PetsciiEncoding.kt
View File

@ -1,4 +1,4 @@
package prog8.compiler.target.cbm
package prog8.codegen.target.cbm
import com.github.michaelbull.result.Err
import com.github.michaelbull.result.Ok
@ -6,12 +6,12 @@ import com.github.michaelbull.result.Result
import prog8.ast.antlr.escape
import java.io.CharConversionException
object Petscii {
object PetsciiEncoding {
// decoding: from Petscii/Screencodes (0-255) to unicode
// character tables used from https://github.com/dj51d/cbmcodecs
// character tables used from https://github.com/irmen/cbmcodecs2
private val decodingPetsciiLowercase = arrayOf(
private val decodingPetsciiLowercase = charArrayOf(
'\u0000', // 0x00 -> \u0000
'\ufffe', // 0x01 -> UNDEFINED
'\ufffe', // 0x02 -> UNDEFINED
@ -270,7 +270,7 @@ object Petscii {
'\u2592' // ▒ 0xFF -> MEDIUM SHADE
)
private val decodingPetsciiUppercase = arrayOf(
private val decodingPetsciiUppercase = charArrayOf(
'\u0000', // 0x00 -> \u0000
'\ufffe', // 0x01 -> UNDEFINED
'\ufffe', // 0x02 -> UNDEFINED
@ -369,13 +369,13 @@ object Petscii {
'\u2190', // ← 0x5F -> LEFTWARDS ARROW
'\u2500', // ─ 0x60 -> BOX DRAWINGS LIGHT HORIZONTAL
'\u2660', // ♠ 0x61 -> BLACK SPADE SUIT
'\u2502', // │ 0x62 -> BOX DRAWINGS LIGHT VERTICAL
'\u2500', // ─ 0x63 -> BOX DRAWINGS LIGHT HORIZONTAL
'\uf122', //  0x64 -> BOX DRAWINGS LIGHT HORIZONTAL ONE QUARTER UP (CUS)
'\uf123', //  0x65 -> BOX DRAWINGS LIGHT HORIZONTAL TWO QUARTERS UP (CUS)
'\uf124', //  0x66 -> BOX DRAWINGS LIGHT HORIZONTAL ONE QUARTER DOWN (CUS)
'\uf126', //  0x67 -> BOX DRAWINGS LIGHT VERTICAL ONE QUARTER LEFT (CUS)
'\uf128', //  0x68 -> BOX DRAWINGS LIGHT VERTICAL ONE QUARTER RIGHT (CUS)
'\uf13c', // │ 0x62 -> BOX DRAWINGS LIGHT VERTICAL ONE EIGHTH LEFT (CUS)
'\uf13b', // ─ 0x63 -> BOX DRAWINGS LIGHT HORIZONTAL ONE EIGHTH UP (CUS)
'\uf122', //  0x64 -> BOX DRAWINGS LIGHT HORIZONTAL TWO EIGHTHS UP (CUS)
'\uf123', //  0x65 -> BOX DRAWINGS LIGHT HORIZONTAL THREE EIGHTHS UP (CUS)
'\uf124', //  0x66 -> BOX DRAWINGS LIGHT HORIZONTAL ONE EIGHTH DOWN (CUS)
'\uf126', //  0x67 -> BOX DRAWINGS LIGHT VERTICAL TWO EIGHTHS LEFT (CUS)
'\uf128', //  0x68 -> BOX DRAWINGS LIGHT VERTICAL ONE EIGHTH RIGHT (CUS)
'\u256e', // ╮ 0x69 -> BOX DRAWINGS LIGHT ARC DOWN AND LEFT
'\u2570', // ╰ 0x6A -> BOX DRAWINGS LIGHT ARC UP AND RIGHT
'\u256f', // ╯ 0x6B -> BOX DRAWINGS LIGHT ARC UP AND LEFT
@ -385,14 +385,14 @@ object Petscii {
'\uf12b', //  0x6F -> ONE EIGHTH BLOCK DOWN AND RIGHT (CUS)
'\uf12c', //  0x70 -> ONE EIGHTH BLOCK DOWN AND LEFT (CUS)
'\u25cf', // ● 0x71 -> BLACK CIRCLE
'\uf125', //  0x72 -> BOX DRAWINGS LIGHT HORIZONTAL TWO QUARTERS DOWN (CUS)
'\uf125', //  0x72 -> BOX DRAWINGS LIGHT HORIZONTAL TWO EIGHTHS DOWN (CUS)
'\u2665', // ♥ 0x73 -> BLACK HEART SUIT
'\uf127', //  0x74 -> BOX DRAWINGS LIGHT VERTICAL TWO QUARTERS LEFT (CUS)
'\uf127', //  0x74 -> BOX DRAWINGS LIGHT VERTICAL THREE EIGHTHS LEFT (CUS)
'\u256d', // ╭ 0x75 -> BOX DRAWINGS LIGHT ARC DOWN AND RIGHT
'\u2573', // 0x76 -> BOX DRAWINGS LIGHT DIAGONAL CROSS
'\u25cb', // ○ 0x77 -> WHITE CIRCLE
'\u2663', // ♣ 0x78 -> BLACK CLUB SUIT
'\uf129', //  0x79 -> BOX DRAWINGS LIGHT VERTICAL TWO QUARTERS RIGHT (CUS)
'\uf129', //  0x79 -> BOX DRAWINGS LIGHT VERTICAL TWO EIGHTS RIGHT (CUS)
'\u2666', // ♦ 0x7A -> BLACK DIAMOND SUIT
'\u253c', // ┼ 0x7B -> BOX DRAWINGS LIGHT VERTICAL AND HORIZONTAL
'\uf12e', //  0x7C -> LEFT HALF BLOCK MEDIUM SHADE (CUS)
@ -465,13 +465,13 @@ object Petscii {
'\u259a', // ▚ 0xBF -> QUADRANT UPPER LEFT AND LOWER RIGHT
'\u2500', // ─ 0xC0 -> BOX DRAWINGS LIGHT HORIZONTAL
'\u2660', // ♠ 0xC1 -> BLACK SPADE SUIT
'\u2502', // │ 0xC2 -> BOX DRAWINGS LIGHT VERTICAL
'\u2500', // ─ 0xC3 -> BOX DRAWINGS LIGHT HORIZONTAL
'\uf122', //  0xC4 -> BOX DRAWINGS LIGHT HORIZONTAL ONE QUARTER UP (CUS)
'\uf123', //  0xC5 -> BOX DRAWINGS LIGHT HORIZONTAL TWO QUARTERS UP (CUS)
'\uf124', //  0xC6 -> BOX DRAWINGS LIGHT HORIZONTAL ONE QUARTER DOWN (CUS)
'\uf126', //  0xC7 -> BOX DRAWINGS LIGHT VERTICAL ONE QUARTER LEFT (CUS)
'\uf128', //  0xC8 -> BOX DRAWINGS LIGHT VERTICAL ONE QUARTER RIGHT (CUS)
'\uf13c', // │ 0xC2 -> BOX DRAWINGS LIGHT VERTICAL ONE EIGHTH LEFT (CUS)
'\uf13b', // ─ 0xC3 -> BOX DRAWINGS LIGHT HORIZONTAL ONE EIGHTH UP (CUS)
'\uf122', //  0xC4 -> BOX DRAWINGS LIGHT HORIZONTAL TWO EIGHTHS UP (CUS)
'\uf123', //  0xC5 -> BOX DRAWINGS LIGHT HORIZONTAL THREE EIGHTHS UP (CUS)
'\uf124', //  0xC6 -> BOX DRAWINGS LIGHT HORIZONTAL ONE EIGHTH DOWN (CUS)
'\uf126', //  0xC7 -> BOX DRAWINGS LIGHT VERTICAL TWO EIGHTHS LEFT (CUS)
'\uf128', //  0xC8 -> BOX DRAWINGS LIGHT VERTICAL ONE EIGHTH RIGHT (CUS)
'\u256e', // ╮ 0xC9 -> BOX DRAWINGS LIGHT ARC DOWN AND LEFT
'\u2570', // ╰ 0xCA -> BOX DRAWINGS LIGHT ARC UP AND RIGHT
'\u256f', // ╯ 0xCB -> BOX DRAWINGS LIGHT ARC UP AND LEFT
@ -481,14 +481,14 @@ object Petscii {
'\uf12b', //  0xCF -> ONE EIGHTH BLOCK DOWN AND RIGHT (CUS)
'\uf12c', //  0xD0 -> ONE EIGHTH BLOCK DOWN AND LEFT (CUS)
'\u25cf', // ● 0xD1 -> BLACK CIRCLE
'\uf125', //  0xD2 -> BOX DRAWINGS LIGHT HORIZONTAL TWO QUARTERS DOWN (CUS)
'\uf125', //  0xD2 -> BOX DRAWINGS LIGHT HORIZONTAL TWO EIGHTS DOWN (CUS)
'\u2665', // ♥ 0xD3 -> BLACK HEART SUIT
'\uf127', //  0xD4 -> BOX DRAWINGS LIGHT VERTICAL TWO QUARTERS LEFT (CUS)
'\uf127', //  0xD4 -> BOX DRAWINGS LIGHT VERTICAL THREE EIGHTS LEFT (CUS)
'\u256d', // ╭ 0xD5 -> BOX DRAWINGS LIGHT ARC DOWN AND LEFT
'\u2573', // 0xD6 -> BOX DRAWINGS LIGHT DIAGONAL CROSS
'\u25cb', // ○ 0xD7 -> WHITE CIRCLE
'\u2663', // ♣ 0xD8 -> BLACK CLUB SUIT
'\uf129', //  0xD9 -> BOX DRAWINGS LIGHT VERTICAL TWO QUARTERS RIGHT (CUS)
'\uf129', //  0xD9 -> BOX DRAWINGS LIGHT VERTICAL TWO EIGHTS RIGHT (CUS)
'\u2666', // ♦ 0xDA -> BLACK DIAMOND SUIT
'\u253c', // ┼ 0xDB -> BOX DRAWINGS LIGHT VERTICAL AND HORIZONTAL
'\uf12e', //  0xDC -> LEFT HALF BLOCK MEDIUM SHADE (CUS)
@ -529,7 +529,7 @@ object Petscii {
'\u03c0' // π 0xFF -> GREEK SMALL LETTER PI
)
private val decodingScreencodeLowercase = arrayOf(
private val decodingScreencodeLowercase = charArrayOf(
'@' , // @ 0x00 -> COMMERCIAL AT
'a' , // a 0x01 -> LATIN SMALL LETTER A
'b' , // b 0x02 -> LATIN SMALL LETTER B
@ -788,7 +788,7 @@ object Petscii {
'\ufffe' // 0xFF -> UNDEFINED
)
private val decodingScreencodeUppercase = arrayOf(
private val decodingScreencodeUppercase = charArrayOf(
'@' , // @ 0x00 -> COMMERCIAL AT
'A' , // A 0x01 -> LATIN CAPITAL LETTER A
'B' , // B 0x02 -> LATIN CAPITAL LETTER B
@ -855,13 +855,13 @@ object Petscii {
'?' , // ? 0x3F -> QUESTION MARK
'\u2500', // ─ 0x40 -> BOX DRAWINGS LIGHT HORIZONTAL
'\u2660', // ♠ 0x41 -> BLACK SPADE SUIT
'\u2502', // │ 0x42 -> BOX DRAWINGS LIGHT VERTICAL
'\u2500', // ─ 0x43 -> BOX DRAWINGS LIGHT HORIZONTAL
'\uf122', //  0x44 -> BOX DRAWINGS LIGHT HORIZONTAL ONE QUARTER UP (CUS)
'\uf123', //  0x45 -> BOX DRAWINGS LIGHT HORIZONTAL TWO QUARTERS UP (CUS)
'\uf124', //  0x46 -> BOX DRAWINGS LIGHT HORIZONTAL ONE QUARTER DOWN (CUS)
'\uf126', //  0x47 -> BOX DRAWINGS LIGHT VERTICAL ONE QUARTER LEFT (CUS)
'\uf128', //  0x48 -> BOX DRAWINGS LIGHT VERTICAL ONE QUARTER RIGHT (CUS)
'\uf13c', // │ 0x42 -> BOX DRAWINGS LIGHT VERTICAL ONE EIGHTH LEFT (CUS)
'\uf13b', // ─ 0x43 -> BOX DRAWINGS LIGHT HORIZONTAL ONE EIGHTH UP (CUS)
'\uf122', //  0x44 -> BOX DRAWINGS LIGHT HORIZONTAL TWO EIGHTHS UP (CUS)
'\uf123', //  0x45 -> BOX DRAWINGS LIGHT HORIZONTAL THREE EIGHTHS UP (CUS
'\uf124', //  0x46 -> BOX DRAWINGS LIGHT HORIZONTAL ONE EIGHTH DOWN (CUS)
'\uf126', //  0x47 -> BOX DRAWINGS LIGHT VERTICAL TWO EIGHTHS LEFT (CUS)
'\uf128', //  0x48 -> BOX DRAWINGS LIGHT VERTICAL ONE EIGHTH RIGHT (CUS)
'\u256e', // ╮ 0x49 -> BOX DRAWINGS LIGHT ARC DOWN AND LEFT
'\u2570', // ╰ 0x4A -> BOX DRAWINGS LIGHT ARC UP AND RIGHT
'\u256f', // ╯ 0x4B -> BOX DRAWINGS LIGHT ARC UP AND LEFT
@ -871,14 +871,14 @@ object Petscii {
'\uf12b', //  0x4F -> ONE EIGHTH BLOCK DOWN AND RIGHT (CUS)
'\uf12c', //  0x50 -> ONE EIGHTH BLOCK DOWN AND LEFT (CUS)
'\u25cf', // ● 0x51 -> BLACK CIRCLE
'\uf125', //  0x52 -> BOX DRAWINGS LIGHT HORIZONTAL TWO QUARTERS DOWN (CUS)
'\uf125', //  0x52 -> BOX DRAWINGS LIGHT HORIZONTAL TWO EIGHTS DOWN (CUS)
'\u2665', // ♥ 0x53 -> BLACK HEART SUIT
'\uf127', //  0x54 -> BOX DRAWINGS LIGHT VERTICAL TWO QUARTERS LEFT (CUS)
'\uf127', //  0x54 -> BOX DRAWINGS LIGHT VERTICAL THREE EIGHTS LEFT (CUS)
'\u256d', // ╭ 0x55 -> BOX DRAWINGS LIGHT ARC DOWN AND RIGHT
'\u2573', // 0x56 -> BOX DRAWINGS LIGHT DIAGONAL CROSS
'\u25cb', // ○ 0x57 -> WHITE CIRCLE
'\u2663', // ♣ 0x58 -> BLACK CLUB SUIT
'\uf129', //  0x59 -> BOX DRAWINGS LIGHT VERTICAL TWO QUARTERS RIGHT (CUS)
'\uf129', //  0x59 -> BOX DRAWINGS LIGHT VERTICAL TWO EIGHTS RIGHT (CUS)
'\u2666', // ♦ 0x5A -> BLACK DIAMOND SUIT
'\u253c', // ┼ 0x5B -> BOX DRAWINGS LIGHT VERTICAL AND HORIZONTAL
'\uf12e', //  0x5C -> LEFT HALF BLOCK MEDIUM SHADE (CUS)
@ -1065,15 +1065,15 @@ object Petscii {
else -> chr
}
fun encodePetscii(text: String, lowercase: Boolean = false): Result<List<Short>, CharConversionException> {
fun encodeChar(chr3: Char, lowercase: Boolean): Short {
fun encodePetscii(text: String, lowercase: Boolean = false): Result<List<UByte>, CharConversionException> {
fun encodeChar(chr3: Char, lowercase: Boolean): UByte {
val chr = replaceSpecial(chr3)
val screencode = if(lowercase) encodingPetsciiLowercase[chr] else encodingPetsciiUppercase[chr]
return screencode?.toShort() ?: when (chr) {
'\u0000' -> 0.toShort()
return screencode?.toUByte() ?: when (chr) {
'\u0000' -> 0u
in '\u8000'..'\u80ff' -> {
// special case: take the lower 8 bit hex value directly
(chr.code - 0x8000).toShort()
(chr.code - 0x8000).toUByte()
}
else -> {
val case = if (lowercase) "lower" else "upper"
@ -1095,27 +1095,28 @@ object Petscii {
}
}
fun decodePetscii(petscii: Iterable<Short>, lowercase: Boolean = false): String {
return petscii.map {
fun decodePetscii(petscii: Iterable<UByte>, lowercase: Boolean = false): Result<String, CharConversionException> {
return try {
Ok(petscii.map {
val code = it.toInt()
try {
if(code<0 || code>= decodingPetsciiLowercase.size)
throw CharConversionException("petscii $code out of range 0..${decodingPetsciiLowercase.size-1}")
if(lowercase) decodingPetsciiLowercase[code] else decodingPetsciiUppercase[code]
} catch(x: CharConversionException) {
// TODO this CharConversionException can never occur?? also clean up ICompilationTarget.decodeString?
if(lowercase) decodingPetsciiUppercase[code] else decodingPetsciiLowercase[code]
}.joinToString(""))
} catch(ce: CharConversionException) {
return Err(ce)
}
}.joinToString("")
}
fun encodeScreencode(text: String, lowercase: Boolean = false): Result<List<Short>, CharConversionException> {
fun encodeChar(chr3: Char, lowercase: Boolean): Short {
fun encodeScreencode(text: String, lowercase: Boolean = false): Result<List<UByte>, CharConversionException> {
fun encodeChar(chr3: Char, lowercase: Boolean): UByte {
val chr = replaceSpecial(chr3)
val screencode = if(lowercase) encodingScreencodeLowercase[chr] else encodingScreencodeUppercase[chr]
return screencode?.toShort() ?: when (chr) {
'\u0000' -> 0.toShort()
return screencode?.toUByte() ?: when (chr) {
'\u0000' -> 0u
in '\u8000'..'\u80ff' -> {
// special case: take the lower 8 bit hex value directly
(chr.code - 0x8000).toShort()
(chr.code - 0x8000).toUByte()
}
else -> {
val case = if (lowercase) "lower" else "upper"
@ -1137,48 +1138,50 @@ object Petscii {
}
}
fun decodeScreencode(screencode: Iterable<Short>, lowercase: Boolean = false): String {
return screencode.map {
fun decodeScreencode(screencode: Iterable<UByte>, lowercase: Boolean = false): Result<String, CharConversionException> {
return try {
Ok(screencode.map {
val code = it.toInt()
try {
if(code<0 || code>= decodingScreencodeLowercase.size)
throw CharConversionException("screencode $code out of range 0..${decodingScreencodeLowercase.size-1}")
if (lowercase) decodingScreencodeLowercase[code] else decodingScreencodeUppercase[code]
} catch (x: CharConversionException) {
// TODO this CharConversionException can never occur?? also clean up ICompilationTarget.decodeString?
if (lowercase) decodingScreencodeUppercase[code] else decodingScreencodeLowercase[code]
}.joinToString(""))
} catch(ce: CharConversionException) {
Err(ce)
}
}.joinToString("")
}
fun petscii2scr(petscii_code: Short, inverseVideo: Boolean): Result<Short, CharConversionException> {
val code = when {
petscii_code <= 0x1f -> petscii_code + 128
petscii_code <= 0x3f -> petscii_code.toInt()
petscii_code <= 0x5f -> petscii_code - 64
petscii_code <= 0x7f -> petscii_code - 32
petscii_code <= 0x9f -> petscii_code + 64
petscii_code <= 0xbf -> petscii_code - 64
petscii_code <= 0xfe -> petscii_code - 128
petscii_code == 255.toShort() -> 95
fun petscii2scr(petscii_code: UByte, inverseVideo: Boolean): Result<UByte, CharConversionException> {
val code: UInt = when {
petscii_code <= 0x1fu -> petscii_code + 128u
petscii_code <= 0x3fu -> petscii_code.toUInt()
petscii_code <= 0x5fu -> petscii_code - 64u
petscii_code <= 0x7fu -> petscii_code - 32u
petscii_code <= 0x9fu -> petscii_code + 64u
petscii_code <= 0xbfu -> petscii_code - 64u
petscii_code <= 0xfeu -> petscii_code - 128u
petscii_code == 255.toUByte() -> 95u
else -> return Err(CharConversionException("petscii code out of range"))
}
if(inverseVideo)
return Ok((code or 0x80).toShort())
return Ok(code.toShort())
if(inverseVideo) {
return Ok((code or 0x80u).toUByte())
}
return Ok(code.toUByte())
}
fun scr2petscii(screencode: Short): Result<Short, CharConversionException> {
val petscii = when {
screencode <= 0x1f -> screencode + 64
screencode <= 0x3f -> screencode.toInt()
screencode <= 0x5d -> screencode +123
screencode == 0x5e.toShort() -> 255
screencode == 0x5f.toShort() -> 223
screencode <= 0x7f -> screencode + 64
screencode <= 0xbf -> screencode - 128
screencode <= 0xfe -> screencode - 64
screencode == 255.toShort() -> 191
fun scr2petscii(screencode: UByte): Result<UByte, CharConversionException> {
val petscii: UInt = when {
screencode <= 0x1fu -> screencode + 64u
screencode <= 0x3fu -> screencode.toUInt()
screencode <= 0x5du -> screencode +123u
screencode == 0x5e.toUByte() -> 255u
screencode == 0x5f.toUByte() -> 223u
screencode <= 0x7fu -> screencode + 64u
screencode <= 0xbfu -> screencode - 128u
screencode <= 0xfeu -> screencode - 64u
screencode == 255.toUByte() -> 191u
else -> return Err(CharConversionException("screencode out of range"))
}
return Ok(petscii.toShort())
return Ok(petscii.toUByte())
}
}

87
codeGenTargets/src/prog8/codegen/target/cx16/CX16MachineDefinition.kt Normal file
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@ -0,0 +1,87 @@
package prog8.codegen.target.cx16
import prog8.codegen.target.cbm.Mflpt5
import prog8.compilerinterface.*
import java.io.IOException
import java.nio.file.Path
class CX16MachineDefinition: IMachineDefinition {
override val cpu = CpuType.CPU65c02
override val FLOAT_MAX_POSITIVE = Mflpt5.FLOAT_MAX_POSITIVE
override val FLOAT_MAX_NEGATIVE = Mflpt5.FLOAT_MAX_NEGATIVE
override val FLOAT_MEM_SIZE = Mflpt5.FLOAT_MEM_SIZE
override val BASIC_LOAD_ADDRESS = 0x0801u
override val RAW_LOAD_ADDRESS = 0x8000u
// the 2*256 byte evaluation stack (on which bytes, words, and even floats are stored during calculations)
override val ESTACK_LO = 0x0400u // $0400-$04ff inclusive
override val ESTACK_HI = 0x0500u // $0500-$05ff inclusive
override lateinit var zeropage: Zeropage
override fun getFloat(num: Number) = Mflpt5.fromNumber(num)
override fun importLibs(compilerOptions: CompilationOptions, compilationTargetName: String): List<String> {
return if (compilerOptions.launcher == LauncherType.BASIC || compilerOptions.output == OutputType.PRG)
listOf("syslib")
else
emptyList()
}
override fun launchEmulator(selectedEmulator: Int, programNameWithPath: Path) {
val emulatorName: String
val extraArgs: List<String>
when(selectedEmulator) {
1 -> {
emulatorName = "x16emu"
extraArgs = emptyList()
}
2 -> {
emulatorName = "box16"
extraArgs = listOf("-sym", viceMonListName(programNameWithPath.toString()))
}
else -> {
System.err.println("Cx16 target only supports x16emu and box16 emulators.")
return
}
}
for(emulator in listOf(emulatorName)) {
println("\nStarting Commander X16 emulator $emulator...")
val cmdline = listOf(emulator, "-scale", "2", "-run", "-prg", "${programNameWithPath}.prg") + extraArgs
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 isIOAddress(address: UInt): Boolean = address==0u || address==1u || address in 0x9f00u..0x9fffu
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")
}

57
codeGenTargets/src/prog8/codegen/target/cx16/CX16Zeropage.kt Normal file
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@ -0,0 +1,57 @@
package prog8.codegen.target.cx16
import prog8.ast.GlobalNamespace
import prog8.ast.base.DataType
import prog8.compilerinterface.CompilationOptions
import prog8.compilerinterface.InternalCompilerException
import prog8.compilerinterface.Zeropage
import prog8.compilerinterface.ZeropageType
class CX16Zeropage(options: CompilationOptions) : Zeropage(options) {
override val SCRATCH_B1 = 0x7au // temp storage for a single byte
override val SCRATCH_REG = 0x7bu // temp storage for a register, must be B1+1
override val SCRATCH_W1 = 0x7cu // temp storage 1 for a word $7c+$7d
override val SCRATCH_W2 = 0x7eu // temp storage 2 for a word $7e+$7f
init {
if (options.floats && options.zeropage !in arrayOf(ZeropageType.BASICSAFE, ZeropageType.DONTUSE))
throw InternalCompilerException("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.
synchronized(this) {
when (options.zeropage) {
ZeropageType.FULL -> {
free.addAll(0x22u..0xffu)
}
ZeropageType.KERNALSAFE -> {
free.addAll(0x22u..0x7fu)
free.addAll(0xa9u..0xffu)
}
ZeropageType.BASICSAFE -> {
free.addAll(0x22u..0x7fu)
}
ZeropageType.DONTUSE -> {
free.clear() // don't use zeropage at all
}
else -> throw InternalCompilerException("for this machine target, zero page type 'floatsafe' is not available. ${options.zeropage}")
}
removeReservedFromFreePool()
// note: the 16 virtual registers R0-R15 are not regular allocated variables, they're *memory mapped* elsewhere to fixed addresses.
// however, to be able for the compiler to "see" them as zero page variables, we have to register them here as well.
val dummyscope = GlobalNamespace(emptyList())
for(reg in 0..15) {
allocatedVariables[listOf("cx16", "r${reg}")] = ZpAllocation((2+reg*2).toUInt(), DataType.UWORD, 2, dummyscope, null, null) // cx16.r0 .. cx16.r15
allocatedVariables[listOf("cx16", "r${reg}s")] = ZpAllocation((2+reg*2).toUInt(), DataType.WORD, 2, dummyscope, null, null) // cx16.r0s .. cx16.r15s
allocatedVariables[listOf("cx16", "r${reg}L")] = ZpAllocation((2+reg*2).toUInt(), DataType.UBYTE, 1, dummyscope, null, null) // cx16.r0L .. cx16.r15L
allocatedVariables[listOf("cx16", "r${reg}H")] = ZpAllocation((3+reg*2).toUInt(), DataType.UBYTE, 1, dummyscope, null, null) // cx16.r0H .. cx16.r15H
allocatedVariables[listOf("cx16", "r${reg}sL")] = ZpAllocation((2+reg*2).toUInt(), DataType.BYTE, 1, dummyscope, null, null) // cx16.r0sL .. cx16.r15sL
allocatedVariables[listOf("cx16", "r${reg}sH")] = ZpAllocation((3+reg*2).toUInt(), DataType.BYTE, 1, dummyscope, null, null) // cx16.r0sH .. cx16.r15sH
}
}
}
}

44
codeOptimizers/build.gradle Normal file
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@ -0,0 +1,44 @@
plugins {
id 'java'
id 'application'
id "org.jetbrains.kotlin.jvm"
}
java {
toolchain {
languageVersion = JavaLanguageVersion.of(javaVersion)
}
}
compileKotlin {
kotlinOptions {
jvmTarget = javaVersion
}
}
compileTestKotlin {
kotlinOptions {
jvmTarget = javaVersion
}
}
dependencies {
implementation project(':compilerInterfaces')
implementation project(':compilerAst')
implementation "org.jetbrains.kotlin:kotlin-stdlib-jdk8"
// implementation "org.jetbrains.kotlin:kotlin-reflect"
}
sourceSets {
main {
java {
srcDirs = ["${project.projectDir}/src"]
}
resources {
srcDirs = ["${project.projectDir}/res"]
}
}
}
// note: there are no unit tests in this module!

15
codeOptimizers/codeOptimizers.iml Normal file
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@ -0,0 +1,15 @@
<?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://$MODULE_DIR$">
<sourceFolder url="file://$MODULE_DIR$/src" isTestSource="false" />
<excludeFolder url="file://$MODULE_DIR$/build" />
</content>
<orderEntry type="inheritedJdk" />
<orderEntry type="sourceFolder" forTests="false" />
<orderEntry type="library" name="KotlinJavaRuntime" level="project" />
<orderEntry type="module" module-name="compilerInterfaces" />
<orderEntry type="module" module-name="compilerAst" />
</component>
</module>

2
codeOptimizers/readme-tests.txt Normal file
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@ -0,0 +1,2 @@
Unittests for things in this module are located in the Compiler module instead,
for convenience sake, and to not spread the test cases around too much.

122
codeOptimizers/src/prog8/optimizer/BinExprSplitter.kt Normal file
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@ -0,0 +1,122 @@
package prog8.optimizer
import prog8.ast.IStatementContainer
import prog8.ast.Node
import prog8.ast.Program
import prog8.ast.base.DataType
import prog8.ast.expressions.AugmentAssignmentOperators
import prog8.ast.expressions.BinaryExpression
import prog8.ast.expressions.IdentifierReference
import prog8.ast.expressions.TypecastExpression
import prog8.ast.getTempVar
import prog8.ast.statements.AssignTarget
import prog8.ast.statements.Assignment
import prog8.ast.statements.AssignmentOrigin
import prog8.ast.walk.AstWalker
import prog8.ast.walk.IAstModification
import prog8.compilerinterface.CompilationOptions
import prog8.compilerinterface.ICompilationTarget
import prog8.compilerinterface.isIOAddress
class BinExprSplitter(private val program: Program, private val options: CompilationOptions, private val compTarget: ICompilationTarget) : AstWalker() {
override fun after(assignment: Assignment, parent: Node): Iterable<IAstModification> {
if(assignment.value.inferType(program) istype DataType.FLOAT && !options.optimizeFloatExpressions)
return noModifications
val binExpr = assignment.value as? BinaryExpression
if (binExpr != null) {
/*
Reduce the complexity of a (binary) expression that has to be evaluated on the eval stack,
by attempting to splitting it up into individual simple steps.
We only consider a binary expression *one* level deep (so the operands must not be a combined expression)
X = BinExpr X = LeftExpr
<operator> followed by
/ \ IF 'X' not used X = BinExpr
/ \ IN expression ==> <operator>
/ \ / \
LeftExpr. RightExpr. / \
X RightExpr.
*/
if(binExpr.operator in AugmentAssignmentOperators && isSimpleTarget(assignment.target)) {
if(assignment.target isSameAs binExpr.right)
return noModifications
if(assignment.target isSameAs binExpr.left) {
if(binExpr.right.isSimple)
return noModifications
val leftBx = binExpr.left as? BinaryExpression
if(leftBx!=null && (!leftBx.left.isSimple || !leftBx.right.isSimple))
return noModifications
val rightBx = binExpr.right as? BinaryExpression
if(rightBx!=null && (!rightBx.left.isSimple || !rightBx.right.isSimple))
return noModifications
// TODO below attempts to remove stack-based evaluated expressions, but often the resulting code is BIGGER, and SLOWER.
// val dt = assignment.target.inferType(program)
// if(!dt.isInteger)
// return noModifications
// val tempVar = IdentifierReference(getTempVarName(dt), binExpr.right.position)
// val assignTempVar = Assignment(
// AssignTarget(tempVar, null, null, binExpr.right.position),
// binExpr.right, binExpr.right.position
// )
// return listOf(
// IAstModification.InsertBefore(assignment, assignTempVar, assignment.parent as IStatementContainer),
// IAstModification.ReplaceNode(binExpr.right, tempVar.copy(), binExpr)
// )
}
if(binExpr.right.isSimple) {
val firstAssign = Assignment(assignment.target.copy(), binExpr.left, AssignmentOrigin.OPTIMIZER, binExpr.left.position)
val targetExpr = assignment.target.toExpression()
val augExpr = BinaryExpression(targetExpr, binExpr.operator, binExpr.right, binExpr.right.position)
return listOf(
IAstModification.ReplaceNode(binExpr, augExpr, assignment),
IAstModification.InsertBefore(assignment, firstAssign, assignment.parent as IStatementContainer)
)
}
}
// TODO further unraveling of binary expression trees into flat statements.
// however this should probably be done in a more generic way to also work on
// the expressiontrees that are not used in an assignment statement...
}
val typecast = assignment.value as? TypecastExpression
if(typecast!=null) {
val origExpr = typecast.expression as? BinaryExpression
if(origExpr!=null) {
// it's a typecast of a binary expression.
// we can see if we can unwrap the binary expression by working on a new temporary variable
// (that has the type of the expression), and then finally doing the typecast.
// Once it's outside the typecast, the regular splitting can commence.
val tempVar = program.getTempVar(origExpr.inferType(program).getOr(DataType.UNDEFINED))
val assignTempVar = Assignment(
AssignTarget(IdentifierReference(tempVar, typecast.position), null, null, typecast.position),
typecast.expression, AssignmentOrigin.OPTIMIZER, typecast.position
)
return listOf(
IAstModification.InsertBefore(assignment, assignTempVar, parent as IStatementContainer),
IAstModification.ReplaceNode(typecast.expression, IdentifierReference(tempVar, typecast.position), typecast)
)
}
}
return noModifications
}
private fun isSimpleTarget(target: AssignTarget) =
if (target.identifier!=null || target.memoryAddress!=null)
!target.isIOAddress(compTarget.machine)
else
false
}

278
codeOptimizers/src/prog8/optimizer/ConstExprEvaluator.kt Normal file
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package prog8.optimizer
import prog8.ast.base.*
import prog8.ast.expressions.Expression
import prog8.ast.expressions.NumericLiteral
import kotlin.math.pow
class ConstExprEvaluator {
fun evaluate(left: NumericLiteral, operator: String, right: NumericLiteral): Expression {
try {
return when(operator) {
"+" -> plus(left, right)
"-" -> minus(left, right)
"*" -> multiply(left, right)
"/" -> divide(left, right)
"%" -> remainder(left, right)
"**" -> power(left, right)
"&" -> bitwiseand(left, right)
"|" -> bitwiseor(left, right)
"^" -> bitwisexor(left, right)
"and" -> logicaland(left, right)
"or" -> logicalor(left, right)
"xor" -> logicalxor(left, right)
"<" -> NumericLiteral.fromBoolean(left < right, left.position)
">" -> NumericLiteral.fromBoolean(left > right, left.position)
"<=" -> NumericLiteral.fromBoolean(left <= right, left.position)
">=" -> NumericLiteral.fromBoolean(left >= right, left.position)
"==" -> NumericLiteral.fromBoolean(left == right, left.position)
"!=" -> NumericLiteral.fromBoolean(left != right, left.position)
"<<" -> shiftedleft(left, right)
">>" -> shiftedright(left, right)
else -> throw FatalAstException("const evaluation for invalid operator $operator")
}
} catch (ax: FatalAstException) {
throw ExpressionError(ax.message, left.position)
}
}
private fun shiftedright(left: NumericLiteral, amount: NumericLiteral): Expression {
if(left.type !in IntegerDatatypes || amount.type !in IntegerDatatypes)
throw ExpressionError("cannot compute $left >> $amount", left.position)
val result =
if(left.type== DataType.UBYTE || left.type== DataType.UWORD)
left.number.toInt().ushr(amount.number.toInt())
else
left.number.toInt().shr(amount.number.toInt())
return NumericLiteral(left.type, result.toDouble(), left.position)
}
private fun shiftedleft(left: NumericLiteral, amount: NumericLiteral): Expression {
if(left.type !in IntegerDatatypes || amount.type !in IntegerDatatypes)
throw ExpressionError("cannot compute $left << $amount", left.position)
val result = left.number.toInt().shl(amount.number.toInt())
return NumericLiteral(left.type, result.toDouble(), left.position)
}
private fun logicalxor(left: NumericLiteral, right: NumericLiteral): NumericLiteral {
val error = "cannot compute $left locical-bitxor $right"
return when (left.type) {
in IntegerDatatypes -> when (right.type) {
in IntegerDatatypes -> NumericLiteral.fromBoolean((left.number.toInt() != 0) xor (right.number.toInt() != 0), left.position)
DataType.FLOAT -> NumericLiteral.fromBoolean((left.number.toInt() != 0) xor (right.number != 0.0), left.position)
else -> throw ExpressionError(error, left.position)
}
DataType.FLOAT -> when (right.type) {
in IntegerDatatypes -> NumericLiteral.fromBoolean((left.number != 0.0) xor (right.number.toInt() != 0), left.position)
DataType.FLOAT -> NumericLiteral.fromBoolean((left.number != 0.0) xor (right.number != 0.0), left.position)
else -> throw ExpressionError(error, left.position)
}
else -> throw ExpressionError(error, left.position)
}
}
private fun logicalor(left: NumericLiteral, right: NumericLiteral): NumericLiteral {
val error = "cannot compute $left locical-or $right"
return when (left.type) {
in IntegerDatatypes -> when (right.type) {
in IntegerDatatypes -> NumericLiteral.fromBoolean(left.number.toInt() != 0 || right.number.toInt() != 0, left.position)
DataType.FLOAT -> NumericLiteral.fromBoolean(left.number.toInt() != 0 || right.number != 0.0, left.position)
else -> throw ExpressionError(error, left.position)
}
DataType.FLOAT -> when (right.type) {
in IntegerDatatypes -> NumericLiteral.fromBoolean(left.number != 0.0 || right.number.toInt() != 0, left.position)
DataType.FLOAT -> NumericLiteral.fromBoolean(left.number != 0.0 || right.number != 0.0, left.position)
else -> throw ExpressionError(error, left.position)
}
else -> throw ExpressionError(error, left.position)
}
}
private fun logicaland(left: NumericLiteral, right: NumericLiteral): NumericLiteral {
val error = "cannot compute $left locical-and $right"
return when (left.type) {
in IntegerDatatypes -> when (right.type) {
in IntegerDatatypes -> NumericLiteral.fromBoolean(left.number.toInt() != 0 && right.number.toInt() != 0, left.position)
DataType.FLOAT -> NumericLiteral.fromBoolean(left.number.toInt() != 0 && right.number != 0.0, left.position)
else -> throw ExpressionError(error, left.position)
}
DataType.FLOAT -> when (right.type) {
in IntegerDatatypes -> NumericLiteral.fromBoolean(left.number != 0.0 && right.number.toInt() != 0, left.position)
DataType.FLOAT -> NumericLiteral.fromBoolean(left.number != 0.0 && right.number != 0.0, left.position)
else -> throw ExpressionError(error, left.position)
}
else -> throw ExpressionError(error, left.position)
}
}
private fun bitwisexor(left: NumericLiteral, right: NumericLiteral): NumericLiteral {
if(left.type== DataType.UBYTE) {
if(right.type in IntegerDatatypes) {
return NumericLiteral(DataType.UBYTE, (left.number.toInt() xor (right.number.toInt() and 255)).toDouble(), left.position)
}
} else if(left.type== DataType.UWORD) {
if(right.type in IntegerDatatypes) {
return NumericLiteral(DataType.UWORD, (left.number.toInt() xor right.number.toInt()).toDouble(), left.position)
}
}
throw ExpressionError("cannot calculate $left ^ $right", left.position)
}
private fun bitwiseor(left: NumericLiteral, right: NumericLiteral): NumericLiteral {
if(left.type== DataType.UBYTE) {
if(right.type in IntegerDatatypes) {
return NumericLiteral(DataType.UBYTE, (left.number.toInt() or (right.number.toInt() and 255)).toDouble(), left.position)
}
} else if(left.type== DataType.UWORD) {
if(right.type in IntegerDatatypes) {
return NumericLiteral(DataType.UWORD, (left.number.toInt() or right.number.toInt()).toDouble(), left.position)
}
}
throw ExpressionError("cannot calculate $left | $right", left.position)
}
private fun bitwiseand(left: NumericLiteral, right: NumericLiteral): NumericLiteral {
if(left.type== DataType.UBYTE) {
if(right.type in IntegerDatatypes) {
return NumericLiteral(DataType.UBYTE, (left.number.toInt() and (right.number.toInt() and 255)).toDouble(), left.position)
}
} else if(left.type== DataType.UWORD) {
if(right.type in IntegerDatatypes) {
return NumericLiteral(DataType.UWORD, (left.number.toInt() and right.number.toInt()).toDouble(), left.position)
}
}
throw ExpressionError("cannot calculate $left & $right", left.position)
}
private fun power(left: NumericLiteral, right: NumericLiteral): NumericLiteral {
val error = "cannot calculate $left ** $right"
return when (left.type) {
in IntegerDatatypes -> when (right.type) {
in IntegerDatatypes -> NumericLiteral.optimalNumeric(left.number.toInt().toDouble().pow(right.number.toInt()), left.position)
DataType.FLOAT -> NumericLiteral(DataType.FLOAT, left.number.toInt().toDouble().pow(right.number), left.position)
else -> throw ExpressionError(error, left.position)
}
DataType.FLOAT -> when (right.type) {
in IntegerDatatypes -> NumericLiteral(DataType.FLOAT, left.number.pow(right.number.toInt()), left.position)
DataType.FLOAT -> NumericLiteral(DataType.FLOAT, left.number.pow(right.number), left.position)
else -> throw ExpressionError(error, left.position)
}
else -> throw ExpressionError(error, left.position)
}
}
private fun plus(left: NumericLiteral, right: NumericLiteral): NumericLiteral {
val error = "cannot add $left and $right"
return when (left.type) {
in IntegerDatatypes -> when (right.type) {
in IntegerDatatypes -> NumericLiteral.optimalInteger(left.number.toInt() + right.number.toInt(), left.position)
DataType.FLOAT -> NumericLiteral(DataType.FLOAT, left.number.toInt() + right.number, left.position)
else -> throw ExpressionError(error, left.position)
}
DataType.FLOAT -> when (right.type) {
in IntegerDatatypes -> NumericLiteral(DataType.FLOAT, left.number + right.number.toInt(), left.position)
DataType.FLOAT -> NumericLiteral(DataType.FLOAT, left.number + right.number, left.position)
else -> throw ExpressionError(error, left.position)
}
else -> throw ExpressionError(error, left.position)
}
}
private fun minus(left: NumericLiteral, right: NumericLiteral): NumericLiteral {
val error = "cannot subtract $left and $right"
return when (left.type) {
in IntegerDatatypes -> when (right.type) {
in IntegerDatatypes -> NumericLiteral.optimalInteger(left.number.toInt() - right.number.toInt(), left.position)
DataType.FLOAT -> NumericLiteral(DataType.FLOAT, left.number.toInt() - right.number, left.position)
else -> throw ExpressionError(error, left.position)
}
DataType.FLOAT -> when (right.type) {
in IntegerDatatypes -> NumericLiteral(DataType.FLOAT, left.number - right.number.toInt(), left.position)
DataType.FLOAT -> NumericLiteral(DataType.FLOAT, left.number - right.number, left.position)
else -> throw ExpressionError(error, left.position)
}
else -> throw ExpressionError(error, left.position)
}
}
private fun multiply(left: NumericLiteral, right: NumericLiteral): NumericLiteral {
val error = "cannot multiply ${left.type} and ${right.type}"
return when (left.type) {
in IntegerDatatypes -> when (right.type) {
in IntegerDatatypes -> NumericLiteral.optimalInteger(left.number.toInt() * right.number.toInt(), left.position)
DataType.FLOAT -> NumericLiteral(DataType.FLOAT, left.number.toInt() * right.number, left.position)
else -> throw ExpressionError(error, left.position)
}
DataType.FLOAT -> when (right.type) {
in IntegerDatatypes -> NumericLiteral(DataType.FLOAT, left.number * right.number.toInt(), left.position)
DataType.FLOAT -> NumericLiteral(DataType.FLOAT, left.number * right.number, left.position)
else -> throw ExpressionError(error, left.position)
}
else -> throw ExpressionError(error, left.position)
}
}
private fun divideByZeroError(pos: Position): Unit =
throw ExpressionError("division by zero", pos)
private fun divide(left: NumericLiteral, right: NumericLiteral): NumericLiteral {
val error = "cannot divide $left by $right"
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()
NumericLiteral.optimalInteger(result, left.position)
}
DataType.FLOAT -> {
if(right.number==0.0) divideByZeroError(right.position)
NumericLiteral(DataType.FLOAT, left.number.toInt() / right.number, left.position)
}
else -> throw ExpressionError(error, left.position)
}
DataType.FLOAT -> when (right.type) {
in IntegerDatatypes -> {
if(right.number.toInt()==0) divideByZeroError(right.position)
NumericLiteral(DataType.FLOAT, left.number / right.number.toInt(), left.position)
}
DataType.FLOAT -> {
if(right.number ==0.0) divideByZeroError(right.position)
NumericLiteral(DataType.FLOAT, left.number / right.number, left.position)
}
else -> throw ExpressionError(error, left.position)
}
else -> throw ExpressionError(error, left.position)
}
}
private fun remainder(left: NumericLiteral, right: NumericLiteral): NumericLiteral {
val error = "cannot compute remainder of $left by $right"
return when (left.type) {
in IntegerDatatypes -> when (right.type) {
in IntegerDatatypes -> {
if(right.number.toInt()==0) divideByZeroError(right.position)
NumericLiteral.optimalNumeric(left.number.toInt().toDouble() % right.number.toInt().toDouble(), left.position)
}
DataType.FLOAT -> {
if(right.number ==0.0) divideByZeroError(right.position)
NumericLiteral(DataType.FLOAT, left.number.toInt() % right.number, left.position)
}
else -> throw ExpressionError(error, left.position)
}
DataType.FLOAT -> when (right.type) {
in IntegerDatatypes -> {
if(right.number.toInt()==0) divideByZeroError(right.position)
NumericLiteral(DataType.FLOAT, left.number % right.number.toInt(), left.position)
}
DataType.FLOAT -> {
if(right.number ==0.0) divideByZeroError(right.position)
NumericLiteral(DataType.FLOAT, left.number % right.number, left.position)
}
else -> throw ExpressionError(error, left.position)
}
else -> throw ExpressionError(error, left.position)
}
}
}

173
compiler/src/prog8/optimizer/ConstantFoldingOptimizer.kt → codeOptimizers/src/prog8/optimizer/ConstantFoldingOptimizer.kt
View File

@ -12,7 +12,7 @@ import prog8.ast.walk.IAstModification
import kotlin.math.pow
internal class ConstantFoldingOptimizer(private val program: Program) : AstWalker() {
class ConstantFoldingOptimizer(private val program: Program) : AstWalker() {
override fun before(memread: DirectMemoryRead, parent: Node): Iterable<IAstModification> {
// @( &thing ) --> thing
@ -23,24 +23,31 @@ internal class ConstantFoldingOptimizer(private val program: Program) : AstWalke
noModifications
}
override fun after(containment: ContainmentCheck, parent: Node): Iterable<IAstModification> {
val result = containment.constValue(program)
if(result!=null)
return listOf(IAstModification.ReplaceNode(containment, result, parent))
return 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) {
if (subexpr is NumericLiteral) {
// 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),
NumericLiteral.optimalInteger(-subexpr.number.toInt(), subexpr.position),
parent))
}
DataType.FLOAT -> {
listOf(IAstModification.ReplaceNode(expr,
NumericLiteralValue(DataType.FLOAT, -subexpr.number.toDouble(), subexpr.position),
NumericLiteral(DataType.FLOAT, -subexpr.number, subexpr.position),
parent))
}
else -> throw ExpressionError("can only take negative of int or float", subexpr.position)
@ -48,29 +55,29 @@ internal class ConstantFoldingOptimizer(private val program: Program) : AstWalke
"~" -> when (subexpr.type) {
DataType.BYTE -> {
listOf(IAstModification.ReplaceNode(expr,
NumericLiteralValue(DataType.BYTE, subexpr.number.toInt().inv(), subexpr.position),
NumericLiteral(DataType.BYTE, subexpr.number.toInt().inv().toDouble(), subexpr.position),
parent))
}
DataType.UBYTE -> {
listOf(IAstModification.ReplaceNode(expr,
NumericLiteralValue(DataType.UBYTE, subexpr.number.toInt().inv() and 255, subexpr.position),
NumericLiteral(DataType.UBYTE, (subexpr.number.toInt().inv() and 255).toDouble(), subexpr.position),
parent))
}
DataType.WORD -> {
listOf(IAstModification.ReplaceNode(expr,
NumericLiteralValue(DataType.WORD, subexpr.number.toInt().inv(), subexpr.position),
NumericLiteral(DataType.WORD, subexpr.number.toInt().inv().toDouble(), subexpr.position),
parent))
}
DataType.UWORD -> {
listOf(IAstModification.ReplaceNode(expr,
NumericLiteralValue(DataType.UWORD, subexpr.number.toInt().inv() and 65535, subexpr.position),
NumericLiteral(DataType.UWORD, (subexpr.number.toInt().inv() and 65535).toDouble(), 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),
NumericLiteral.fromBoolean(subexpr.number == 0.0, subexpr.position),
parent))
}
else -> throw ExpressionError(expr.operator, subexpr.position)
@ -79,7 +86,7 @@ internal class ConstantFoldingOptimizer(private val program: Program) : AstWalke
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.
@ -101,23 +108,50 @@ internal class ConstantFoldingOptimizer(private val program: Program) : AstWalke
val rightconst = expr.right.constValue(program)
val modifications = mutableListOf<IAstModification>()
if(expr.operator=="==" && rightconst!=null) {
val leftExpr = expr.left as? BinaryExpression
if(leftExpr!=null) {
val leftRightConst = leftExpr.right.constValue(program)
if(leftRightConst!=null) {
when (leftExpr.operator) {
"+" -> {
// X + С1 == C2 --> X == C2 - C1
val newRightConst = NumericLiteral(rightconst.type, rightconst.number - leftRightConst.number, rightconst.position)
return listOf(
IAstModification.ReplaceNode(leftExpr, leftExpr.left, expr),
IAstModification.ReplaceNode(expr.right, newRightConst, expr)
)
}
"-" -> {
// X - С1 == C2 --> X == C2 + C1
val newRightConst = NumericLiteral(rightconst.type, rightconst.number + leftRightConst.number, rightconst.position)
return listOf(
IAstModification.ReplaceNode(leftExpr, leftExpr.left, expr),
IAstModification.ReplaceNode(expr.right, newRightConst, expr)
)
}
}
}
}
}
if(expr.operator == "**" && leftconst!=null) {
// optimize various simple cases of ** :
// optimize away 1 ** x into just 1 and 0 ** x into just 0
// optimize 2 ** x into (1<<x) if both operands are integer.
val leftDt = leftconst.inferType(program).getOr(DataType.UNDEFINED)
when (leftconst.number.toDouble()) {
when (leftconst.number) {
0.0 -> {
val value = NumericLiteralValue(leftDt, 0, expr.position)
val value = NumericLiteral(leftDt, 0.0, expr.position)
modifications += IAstModification.ReplaceNode(expr, value, parent)
}
1.0 -> {
val value = NumericLiteralValue(leftDt, 1, expr.position)
val value = NumericLiteral(leftDt, 1.0, expr.position)
modifications += IAstModification.ReplaceNode(expr, value, parent)
}
2.0 -> {
if(rightconst!=null) {
val value = NumericLiteralValue(leftDt, 2.0.pow(rightconst.number.toDouble()), expr.position)
val value = NumericLiteral(leftDt, 2.0.pow(rightconst.number), expr.position)
modifications += IAstModification.ReplaceNode(expr, value, parent)
} else {
val rightDt = expr.right.inferType(program).getOr(DataType.UNDEFINED)
@ -128,7 +162,7 @@ internal class ConstantFoldingOptimizer(private val program: Program) : AstWalke
is VarDecl -> parent.datatype
else -> leftDt
}
val one = NumericLiteralValue(targetDt, 1, expr.position)
val one = NumericLiteral(targetDt, 1.0, expr.position)
val shift = BinaryExpression(one, "<<", expr.right, expr.position)
modifications += IAstModification.ReplaceNode(expr, shift, parent)
}
@ -159,17 +193,98 @@ internal class ConstantFoldingOptimizer(private val program: Program) : AstWalke
}
}
val evaluator = ConstExprEvaluator()
// const fold when both operands are a const
if(leftconst != null && rightconst != null) {
val evaluator = ConstExprEvaluator()
val result = evaluator.evaluate(leftconst, expr.operator, rightconst)
modifications += IAstModification.ReplaceNode(expr, result, parent)
}
val leftBinExpr = expr.left as? BinaryExpression
val rightBinExpr = expr.right as? BinaryExpression
if(leftBinExpr!=null && rightconst!=null) {
if(expr.operator=="+" || expr.operator=="-") {
if(leftBinExpr.operator in listOf("+", "-")) {
val c2 = leftBinExpr.right.constValue(program)
if(c2!=null) {
// (X + C2) +/- rightConst --> X + (C2 +/- rightConst)
// (X - C2) +/- rightConst --> X - (C2 +/- rightConst) mind the flipped right operator
val operator = if(leftBinExpr.operator=="+") expr.operator else if(expr.operator=="-") "+" else "-"
val constants = BinaryExpression(c2, operator, rightconst, c2.position)
val newExpr = BinaryExpression(leftBinExpr.left, leftBinExpr.operator, constants, expr.position)
return listOf(IAstModification.ReplaceNode(expr, newExpr, parent))
}
}
}
else if(expr.operator=="*") {
val c2 = leftBinExpr.right.constValue(program)
if(c2!=null) {
if(leftBinExpr.operator=="*") {
// (X * C2) * rightConst --> X * (rightConst*C2)
val constants = BinaryExpression(rightconst, "*", c2, c2.position)
val newExpr = BinaryExpression(leftBinExpr.left, "*", constants, expr.position)
return listOf(IAstModification.ReplaceNode(expr, newExpr, parent))
} else if (leftBinExpr.operator=="/") {
// (X / C2) * rightConst --> X * (rightConst/C2)
val constants = BinaryExpression(rightconst, "/", c2, c2.position)
val newExpr = BinaryExpression(leftBinExpr.left, "*", constants, expr.position)
return listOf(IAstModification.ReplaceNode(expr, newExpr, parent))
}
}
}
else if(expr.operator=="/") {
val c2 = leftBinExpr.right.constValue(program)
if(c2!=null && leftBinExpr.operator=="/") {
// (X / C1) / C2 --> X / (C1*C2)
// NOTE: do not optimize (X * C1) / C2 --> X * (C1/C2) because this causes precision loss on integers
val constants = BinaryExpression(c2, "*", rightconst, c2.position)
val newExpr = BinaryExpression(leftBinExpr.left, "/", constants, expr.position)
return listOf(IAstModification.ReplaceNode(expr, newExpr, parent))
}
}
}
if(expr.operator=="+" || expr.operator=="-") {
if(leftBinExpr!=null && rightBinExpr!=null) {
val c1 = leftBinExpr.right.constValue(program)
val c2 = rightBinExpr.right.constValue(program)
if(leftBinExpr.operator=="+" && rightBinExpr.operator=="+") {
if (c1 != null && c2 != null) {
// (X + C1) <plusmin> (Y + C2) => (X <plusmin> Y) + (C1 <plusmin> C2)
val c3 = evaluator.evaluate(c1, expr.operator, c2)
val xwithy = BinaryExpression(leftBinExpr.left, expr.operator, rightBinExpr.left, expr.position)
val newExpr = BinaryExpression(xwithy, "+", c3, expr.position)
modifications += IAstModification.ReplaceNode(expr, newExpr, parent)
}
}
else if(leftBinExpr.operator=="-" && rightBinExpr.operator=="-") {
if (c1 != null && c2 != null) {
// (X - C1) <plusmin> (Y - C2) => (X <plusmin> Y) - (C1 <plusmin> C2)
val c3 = evaluator.evaluate(c1, expr.operator, c2)
val xwithy = BinaryExpression(leftBinExpr.left, expr.operator, rightBinExpr.left, expr.position)
val newExpr = BinaryExpression(xwithy, "-", c3, expr.position)
modifications += IAstModification.ReplaceNode(expr, newExpr, parent)
}
}
else if(leftBinExpr.operator=="*" && rightBinExpr.operator=="*"){
if (c1 != null && c2 != null && c1==c2) {
//(X * C) <plusmin> (Y * C) => (X <plusmin> Y) * C
val xwithy = BinaryExpression(leftBinExpr.left, expr.operator, rightBinExpr.left, expr.position)
val newExpr = BinaryExpression(xwithy, "*", c1, expr.position)
modifications += IAstModification.ReplaceNode(expr, newExpr, parent)
}
}
}
}
return modifications
}
override fun after(array: ArrayLiteralValue, parent: Node): Iterable<IAstModification> {
override fun after(array: ArrayLiteral, 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.
@ -195,17 +310,17 @@ internal class ConstantFoldingOptimizer(private val program: Program) : AstWalke
return noModifications
}
override fun after(functionCall: FunctionCall, parent: Node): Iterable<IAstModification> {
override fun after(functionCallExpr: FunctionCallExpression, parent: Node): Iterable<IAstModification> {
// the args of a fuction are constfolded via recursion already.
val constvalue = functionCall.constValue(program)
val constvalue = functionCallExpr.constValue(program)
return if(constvalue!=null)
listOf(IAstModification.ReplaceNode(functionCall, constvalue, parent))
listOf(IAstModification.ReplaceNode(functionCallExpr, 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? {
fun adjustRangeDt(rangeFrom: NumericLiteral, targetDt: DataType, rangeTo: NumericLiteral, stepLiteral: NumericLiteral?, range: RangeExpression): RangeExpression? {
val fromCast = rangeFrom.cast(targetDt)
val toCast = rangeTo.cast(targetDt)
if(!fromCast.isValid || !toCast.isValid)
@ -222,18 +337,18 @@ internal class ConstantFoldingOptimizer(private val program: Program) : AstWalke
range.step
}
return RangeExpr(fromCast.valueOrZero(), toCast.valueOrZero(), newStep, range.position)
return RangeExpression(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
val iterableRange = forLoop.iterable as? RangeExpression ?: return noModifications
val rangeFrom = iterableRange.from as? NumericLiteral
val rangeTo = iterableRange.to as? NumericLiteral
if(rangeFrom==null || rangeTo==null) return noModifications
val loopvar = forLoop.loopVar.targetVarDecl(program) ?: throw UndefinedSymbolError(forLoop.loopVar)
val stepLiteral = iterableRange.step as? NumericLiteralValue
val stepLiteral = iterableRange.step as? NumericLiteral
when(loopvar.datatype) {
DataType.UBYTE -> {
if(rangeFrom.type!= DataType.UBYTE) {
@ -274,7 +389,7 @@ internal class ConstantFoldingOptimizer(private val program: Program) : AstWalke
}
override fun after(decl: VarDecl, parent: Node): Iterable<IAstModification> {
val numval = decl.value as? NumericLiteralValue
val numval = decl.value as? NumericLiteral
if(decl.type== VarDeclType.CONST && numval!=null) {
val valueDt = numval.inferType(program)
if(valueDt isnot decl.datatype) {
@ -312,12 +427,12 @@ internal class ConstantFoldingOptimizer(private val program: Program) : AstWalke
{
// NOTE: THIS IS ONLY VALID ON FLOATING POINT CONSTANTS
// todo: this implements only a small set of possible reorderings at this time
// todo: this implements only a small set of possible reorderings at this time, we could think of more
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) {
if(expr.operator in AssociativeOperators) {
return if(leftIsConst) {
if(subleftIsConst)
ShuffleOperands(expr, null, subExpr, subExpr.right, null, null, expr.left)

105
compiler/src/prog8/optimizer/ConstantIdentifierReplacer.kt → codeOptimizers/src/prog8/optimizer/ConstantIdentifierReplacer.kt
View File

@ -1,6 +1,5 @@
package prog8.optimizer
import prog8.ast.INameScope
import prog8.ast.Node
import prog8.ast.Program
import prog8.ast.base.*
@ -8,58 +7,43 @@ import prog8.ast.expressions.*
import prog8.ast.statements.*
import prog8.ast.walk.AstWalker
import prog8.ast.walk.IAstModification
import prog8.compiler.IErrorReporter
import prog8.compiler.astprocessing.size
import prog8.compiler.astprocessing.toConstantIntegerRange
import prog8.compiler.target.ICompilationTarget
import prog8.compilerinterface.ICompilationTarget
import prog8.compilerinterface.IErrorReporter
// Fix up the literal value's type to match that of the vardecl
// (also check range literal operands types before they get expanded into arrays for instance)
internal class VarConstantValueTypeAdjuster(private val program: Program, private val errors: IErrorReporter) : AstWalker() {
class VarConstantValueTypeAdjuster(private val program: Program, private val errors: IErrorReporter) : AstWalker() {
override fun after(decl: VarDecl, parent: Node): Iterable<IAstModification> {
if(decl.parent is AnonymousScope)
throw FatalAstException("vardecl may no longer occur in anonymousscope")
try {
val declConstValue = decl.value?.constValue(program)
if(declConstValue!=null && (decl.type==VarDeclType.VAR || decl.type==VarDeclType.CONST)
&& declConstValue.inferType(program) isnot decl.datatype) {
&& declConstValue.type != decl.datatype) {
// avoid silent float roundings
if(decl.datatype in IntegerDatatypes && declConstValue.type==DataType.FLOAT) {
errors.err("refused rounding of float to avoid loss of precision", decl.value!!.position)
} else {
// cast the numeric literal to the appropriate datatype of the variable
val cast = declConstValue.cast(decl.datatype)
if (cast.isValid)
return listOf(IAstModification.ReplaceNode(decl.value!!, cast.valueOrZero(), decl))
}
}
} catch (x: UndefinedSymbolError) {
errors.err(x.message, x.position)
}
// move vardecl to the containing subroutine and add initialization assignment in its place if needed
if(decl.type == VarDeclType.VAR && decl.datatype in NumericDatatypes) {
val subroutine = decl.definingSubroutine as? INameScope
if(subroutine!=null && subroutine!==parent) {
val declValue = decl.value
decl.value = null
decl.allowInitializeWithZero = false
return if (declValue == null) {
listOf(
IAstModification.Remove(decl, parent as INameScope),
IAstModification.InsertFirst(decl, subroutine)
)
} else {
val target = AssignTarget(IdentifierReference(listOf(decl.name), decl.position), null, null, decl.position)
val assign = Assignment(target, declValue, decl.position)
listOf(
IAstModification.ReplaceNode(decl, assign, parent),
IAstModification.InsertFirst(decl, subroutine)
)
}
}
}
return noModifications
}
override fun after(range: RangeExpr, parent: Node): Iterable<IAstModification> {
val from = range.from.constValue(program)?.number?.toDouble()
val to = range.to.constValue(program)?.number?.toDouble()
val step = range.step.constValue(program)?.number?.toDouble()
override fun after(range: RangeExpression, parent: Node): Iterable<IAstModification> {
val from = range.from.constValue(program)?.number
val to = range.to.constValue(program)?.number
val step = range.step.constValue(program)?.number
if(from==null) {
if(!range.from.inferType(program).isInteger)
@ -109,7 +93,7 @@ internal class ConstantIdentifierReplacer(private val program: Program, private
in NumericDatatypes -> listOf(
IAstModification.ReplaceNode(
identifier,
NumericLiteralValue(cval.type, cval.number, identifier.position),
NumericLiteral(cval.type, cval.number, identifier.position),
identifier.parent
)
)
@ -124,8 +108,7 @@ internal class ConstantIdentifierReplacer(private val program: Program, private
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?.referencesIdentifier(decl.name) == true || decl.arraysize?.indexExpr?.referencesIdentifier(decl.name) == true) {
if(decl.value?.referencesIdentifier(listOf(decl.name)) == true || decl.arraysize?.indexExpr?.referencesIdentifier(listOf(decl.name)) == true) {
errors.err("recursive var declaration", decl.position)
return noModifications
}
@ -135,11 +118,11 @@ internal class ConstantIdentifierReplacer(private val program: Program, private
val arraysize = decl.arraysize
if(arraysize==null) {
// for arrays that have no size specifier attempt to deduce the size
val arrayval = decl.value as? ArrayLiteralValue
val arrayval = decl.value as? ArrayLiteral
if(arrayval!=null) {
return listOf(IAstModification.SetExpression(
{ decl.arraysize = ArrayIndex(it, decl.position) },
NumericLiteralValue.optimalInteger(arrayval.value.size, decl.position),
NumericLiteral.optimalInteger(arrayval.value.size, decl.position),
decl
))
}
@ -149,35 +132,35 @@ internal class ConstantIdentifierReplacer(private val program: Program, private
when(decl.datatype) {
DataType.FLOAT -> {
// vardecl: for scalar float vars, promote constant integer initialization values to floats
val litval = decl.value as? NumericLiteralValue
val litval = decl.value as? NumericLiteral
if (litval!=null && litval.type in IntegerDatatypes) {
val newValue = NumericLiteralValue(DataType.FLOAT, litval.number.toDouble(), litval.position)
val newValue = NumericLiteral(DataType.FLOAT, litval.number, litval.position)
return listOf(IAstModification.ReplaceNode(decl.value!!, newValue, decl))
}
}
DataType.ARRAY_UB, DataType.ARRAY_B, DataType.ARRAY_UW, DataType.ARRAY_W -> {
val rangeExpr = decl.value as? RangeExpr
val rangeExpr = decl.value as? RangeExpression
if(rangeExpr!=null) {
// convert the initializer range expression to an actual array
val declArraySize = decl.arraysize?.constIndex()
if(declArraySize!=null && declArraySize!=rangeExpr.size(compTarget))
errors.err("range expression size doesn't match declared array size", decl.value?.position!!)
val constRange = rangeExpr.toConstantIntegerRange(compTarget)
if(declArraySize!=null && declArraySize!=rangeExpr.size())
errors.err("range expression size (${rangeExpr.size()}) doesn't match declared array size ($declArraySize)", decl.value?.position!!)
val constRange = rangeExpr.toConstantIntegerRange()
if(constRange!=null) {
val eltType = rangeExpr.inferType(program).getOr(DataType.UBYTE)
val newValue = if(eltType in ByteDatatypes) {
ArrayLiteralValue(InferredTypes.InferredType.known(decl.datatype),
constRange.map { NumericLiteralValue(eltType, it.toShort(), decl.value!!.position) }.toTypedArray(),
ArrayLiteral(InferredTypes.InferredType.known(decl.datatype),
constRange.map { NumericLiteral(eltType, it.toDouble(), decl.value!!.position) }.toTypedArray(),
position = decl.value!!.position)
} else {
ArrayLiteralValue(InferredTypes.InferredType.known(decl.datatype),
constRange.map { NumericLiteralValue(eltType, it, decl.value!!.position) }.toTypedArray(),
ArrayLiteral(InferredTypes.InferredType.known(decl.datatype),
constRange.map { NumericLiteral(eltType, it.toDouble(), decl.value!!.position) }.toTypedArray(),
position = decl.value!!.position)
}
return listOf(IAstModification.ReplaceNode(decl.value!!, newValue, decl))
}
}
val numericLv = decl.value as? NumericLiteralValue
val numericLv = decl.value as? NumericLiteral
if(numericLv!=null && numericLv.type== DataType.FLOAT)
errors.err("arraysize requires only integers here", numericLv.position)
val size = decl.arraysize?.constIndex() ?: return noModifications
@ -204,38 +187,38 @@ internal class ConstantIdentifierReplacer(private val program: Program, private
else -> {}
}
// create the array itself, filled with the fillvalue.
val array = Array(size) {fillvalue}.map { NumericLiteralValue(ArrayToElementTypes.getValue(decl.datatype), it, numericLv.position) }.toTypedArray<Expression>()
val refValue = ArrayLiteralValue(InferredTypes.InferredType.known(decl.datatype), array, position = numericLv.position)
val array = Array(size) {fillvalue}.map { NumericLiteral(ArrayToElementTypes.getValue(decl.datatype), it.toDouble(), numericLv.position) }.toTypedArray<Expression>()
val refValue = ArrayLiteral(InferredTypes.InferredType.known(decl.datatype), array, position = numericLv.position)
return listOf(IAstModification.ReplaceNode(decl.value!!, refValue, decl))
}
}
DataType.ARRAY_F -> {
val rangeExpr = decl.value as? RangeExpr
val rangeExpr = decl.value as? RangeExpression
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(compTarget))
errors.err("range expression size (${rangeExpr.size(compTarget)}) doesn't match declared array size ($declArraySize)", decl.value?.position!!)
val constRange = rangeExpr.toConstantIntegerRange(compTarget)
if(declArraySize!=null && declArraySize!=rangeExpr.size())
errors.err("range expression size (${rangeExpr.size()}) doesn't match declared array size ($declArraySize)", 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(),
val newValue = ArrayLiteral(InferredTypes.InferredType.known(DataType.ARRAY_F),
constRange.map { NumericLiteral(DataType.FLOAT, it.toDouble(), decl.value!!.position) }.toTypedArray(),
position = decl.value!!.position)
return listOf(IAstModification.ReplaceNode(decl.value!!, newValue, decl))
}
}
val numericLv = decl.value as? NumericLiteralValue
val numericLv = decl.value as? NumericLiteral
val size = decl.arraysize?.constIndex() ?: return noModifications
if(rangeExpr==null && numericLv!=null) {
// arraysize initializer is a single int, and we know the size.
val fillvalue = numericLv.number.toDouble()
val fillvalue = numericLv.number
if (fillvalue < compTarget.machine.FLOAT_MAX_NEGATIVE || fillvalue > compTarget.machine.FLOAT_MAX_POSITIVE)
errors.err("float value overflow", numericLv.position)
else {
// create the array itself, filled with the fillvalue.
val array = Array(size) {fillvalue}.map { NumericLiteralValue(DataType.FLOAT, it, numericLv.position) }.toTypedArray<Expression>()
val refValue = ArrayLiteralValue(InferredTypes.InferredType.known(DataType.ARRAY_F), array, position = numericLv.position)
val array = Array(size) {fillvalue}.map { NumericLiteral(DataType.FLOAT, it, numericLv.position) }.toTypedArray<Expression>()
val refValue = ArrayLiteral(InferredTypes.InferredType.known(DataType.ARRAY_F), array, position = numericLv.position)
return listOf(IAstModification.ReplaceNode(decl.value!!, refValue, decl))
}
}

408
compiler/src/prog8/optimizer/ExpressionSimplifier.kt → codeOptimizers/src/prog8/optimizer/ExpressionSimplifier.kt
View File

@ -1,5 +1,6 @@
package prog8.optimizer
import prog8.ast.IStatementContainer
import prog8.ast.Node
import prog8.ast.Program
import prog8.ast.base.DataType
@ -7,22 +8,23 @@ import prog8.ast.base.FatalAstException
import prog8.ast.base.IntegerDatatypes
import prog8.ast.base.NumericDatatypes
import prog8.ast.expressions.*
import prog8.ast.statements.Assignment
import prog8.ast.statements.*
import prog8.ast.walk.AstWalker
import prog8.ast.walk.IAstModification
import prog8.compilerinterface.IErrorReporter
import kotlin.math.abs
import kotlin.math.log2
import kotlin.math.pow
/*
todo add more expression optimizations
todo add more peephole expression optimizations
Investigate what optimizations binaryen has, also see https://egorbo.com/peephole-optimizations.html
*/
internal class ExpressionSimplifier(private val program: Program) : AstWalker() {
class ExpressionSimplifier(private val program: Program, private val errors: IErrorReporter) : AstWalker() {
private val powersOfTwo = (1..16).map { (2.0).pow(it) }.toSet()
private val negativePowersOfTwo = powersOfTwo.map { -it }.toSet()
@ -30,7 +32,7 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
val mods = mutableListOf<IAstModification>()
// try to statically convert a literal value into one of the desired type
val literal = typecast.expression as? NumericLiteralValue
val literal = typecast.expression as? NumericLiteral
if (literal != null) {
val newLiteral = literal.cast(typecast.type)
if (newLiteral.isValid && newLiteral.valueOrZero() !== literal)
@ -54,35 +56,26 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
return mods
}
override fun before(expr: PrefixExpression, parent: Node): Iterable<IAstModification> {
if (expr.operator == "+") {
// +X --> X
return listOf(IAstModification.ReplaceNode(expr, expr.expression, parent))
} else if (expr.operator == "not") {
when(expr.expression) {
is PrefixExpression -> {
// NOT(NOT(...)) -> ...
val pe = expr.expression as PrefixExpression
if(pe.operator == "not")
return listOf(IAstModification.ReplaceNode(expr, pe.expression, parent))
override fun after(ifElse: IfElse, parent: Node): Iterable<IAstModification> {
val truepart = ifElse.truepart
val elsepart = ifElse.elsepart
if(truepart.isNotEmpty() && elsepart.isNotEmpty()) {
if(truepart.statements.singleOrNull() is Jump) {
return listOf(
IAstModification.InsertAfter(ifElse, elsepart, parent as IStatementContainer),
IAstModification.ReplaceNode(elsepart, AnonymousScope(mutableListOf(), elsepart.position), ifElse)
)
}
is BinaryExpression -> {
// NOT (xxxx) -> invert the xxxx
val be = expr.expression as BinaryExpression
val newExpr = when (be.operator) {
"<" -> BinaryExpression(be.left, ">=", be.right, be.position)
">" -> BinaryExpression(be.left, "<=", be.right, be.position)
"<=" -> BinaryExpression(be.left, ">", be.right, be.position)
">=" -> BinaryExpression(be.left, "<", be.right, be.position)
"==" -> BinaryExpression(be.left, "!=", be.right, be.position)
"!=" -> BinaryExpression(be.left, "==", be.right, be.position)
else -> null
if(elsepart.statements.singleOrNull() is Jump) {
val invertedCondition = invertCondition(ifElse.condition)
if(invertedCondition!=null) {
return listOf(
IAstModification.ReplaceNode(ifElse.condition, invertedCondition, ifElse),
IAstModification.InsertAfter(ifElse, truepart, parent as IStatementContainer),
IAstModification.ReplaceNode(elsepart, AnonymousScope(mutableListOf(), elsepart.position), ifElse),
IAstModification.ReplaceNode(truepart, elsepart, ifElse)
)
}
if (newExpr != null)
return listOf(IAstModification.ReplaceNode(expr, newExpr, parent))
}
else -> return noModifications
}
}
return noModifications
@ -98,11 +91,11 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
throw FatalAstException("can't determine datatype of both expression operands $expr")
// ConstValue <associativeoperator> X --> X <associativeoperator> ConstValue
if (leftVal != null && expr.operator in associativeOperators && rightVal == null)
if (leftVal != null && expr.operator in AssociativeOperators && rightVal == null)
return listOf(IAstModification.SwapOperands(expr))
// NonBinaryExpression <associativeoperator> BinaryExpression --> BinaryExpression <associativeoperator> NonBinaryExpression
if (expr.operator in associativeOperators && expr.left !is BinaryExpression && expr.right is BinaryExpression) {
if (expr.operator in AssociativeOperators && expr.left !is BinaryExpression && expr.right is BinaryExpression) {
if(parent !is Assignment || !(expr.left isSameAs parent.target))
return listOf(IAstModification.SwapOperands(expr))
}
@ -149,7 +142,7 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
val x = expr.right
val y = determineY(x, leftBinExpr)
if (y != null) {
val yPlus1 = BinaryExpression(y, "+", NumericLiteralValue(leftDt, 1, y.position), y.position)
val yPlus1 = BinaryExpression(y, "+", NumericLiteral(leftDt, 1.0, y.position), y.position)
val newExpr = BinaryExpression(x, "*", yPlus1, x.position)
return listOf(IAstModification.ReplaceNode(expr, newExpr, parent))
}
@ -159,7 +152,7 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
val x = expr.right
val y = determineY(x, leftBinExpr)
if (y != null) {
val yMinus1 = BinaryExpression(y, "-", NumericLiteralValue(leftDt, 1, y.position), y.position)
val yMinus1 = BinaryExpression(y, "-", NumericLiteral(leftDt, 1.0, y.position), y.position)
val newExpr = BinaryExpression(x, "*", yMinus1, x.position)
return listOf(IAstModification.ReplaceNode(expr, newExpr, parent))
}
@ -171,7 +164,7 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
val x = expr.left
val y = determineY(x, rightBinExpr)
if (y != null) {
val yPlus1 = BinaryExpression(y, "+", NumericLiteralValue.optimalInteger(1, y.position), y.position)
val yPlus1 = BinaryExpression(y, "+", NumericLiteral.optimalInteger(1, y.position), y.position)
val newExpr = BinaryExpression(x, "*", yPlus1, x.position)
return listOf(IAstModification.ReplaceNode(expr, newExpr, parent))
}
@ -179,93 +172,93 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
}
}
if(expr.operator == ">=" && rightVal?.number == 0) {
if(leftDt!=DataType.FLOAT && expr.operator == ">=" && rightVal?.number == 1.0) {
// for integers: x >= 1 --> x > 0
expr.operator = ">"
return listOf(IAstModification.ReplaceNode(expr.right, NumericLiteral.optimalInteger(0, expr.right.position), expr))
}
if(expr.operator == ">=" && rightVal?.number == 0.0) {
if (leftDt == DataType.UBYTE || leftDt == DataType.UWORD) {
// unsigned >= 0 --> true
return listOf(IAstModification.ReplaceNode(expr, NumericLiteralValue.fromBoolean(true, expr.position), parent))
return listOf(IAstModification.ReplaceNode(expr, NumericLiteral.fromBoolean(true, expr.position), parent))
}
}
if(expr.operator == "<" && rightVal?.number == 0) {
if(leftDt!=DataType.FLOAT && expr.operator == "<" && rightVal?.number == 1.0) {
// for integers: x < 1 --> x <= 0
expr.operator = "<="
return listOf(IAstModification.ReplaceNode(expr.right, NumericLiteral.optimalInteger(0, expr.right.position), expr))
}
if(expr.operator == "<" && rightVal?.number == 0.0) {
if (leftDt == DataType.UBYTE || leftDt == DataType.UWORD) {
// unsigned < 0 --> false
return listOf(IAstModification.ReplaceNode(expr, NumericLiteralValue.fromBoolean(false, expr.position), parent))
}
when(leftDt) {
DataType.BYTE -> {
// signed < 0 --> signed & $80
return listOf(IAstModification.ReplaceNode(
expr,
BinaryExpression(expr.left, "&", NumericLiteralValue.optimalInteger(0x80, expr.position), expr.position),
parent
))
}
DataType.WORD -> {
// signedw < 0 --> msb(signedw) & $80
return listOf(IAstModification.ReplaceNode(
expr,
BinaryExpression(FunctionCall(IdentifierReference(listOf("msb"), expr.position),
mutableListOf(expr.left),
expr.position
), "&", NumericLiteralValue.optimalInteger(0x80, expr.position), expr.position),
parent
))
}
else -> {}
return listOf(IAstModification.ReplaceNode(expr, NumericLiteral.fromBoolean(false, expr.position), parent))
}
}
// simplify when a term is constant and directly determines the outcome
val constTrue = NumericLiteralValue.fromBoolean(true, expr.position)
val constFalse = NumericLiteralValue.fromBoolean(false, expr.position)
val constTrue = NumericLiteral.fromBoolean(true, expr.position)
val constFalse = NumericLiteral.fromBoolean(false, expr.position)
val newExpr: Expression? = when (expr.operator) {
"or" -> {
if ((leftVal != null && leftVal.asBooleanValue) || (rightVal != null && rightVal.asBooleanValue))
constTrue
else if (leftVal != null && !leftVal.asBooleanValue)
expr.right
else if (rightVal != null && !rightVal.asBooleanValue)
expr.left
else
null
when {
leftVal != null && leftVal.asBooleanValue || rightVal != null && rightVal.asBooleanValue -> constTrue
leftVal != null && !leftVal.asBooleanValue -> expr.right
rightVal != null && !rightVal.asBooleanValue -> expr.left
else -> null
}
}
"and" -> {
if ((leftVal != null && !leftVal.asBooleanValue) || (rightVal != null && !rightVal.asBooleanValue))
constFalse
else if (leftVal != null && leftVal.asBooleanValue)
expr.right
else if (rightVal != null && rightVal.asBooleanValue)
expr.left
else
null
when {
leftVal != null && !leftVal.asBooleanValue || rightVal != null && !rightVal.asBooleanValue -> constFalse
leftVal != null && leftVal.asBooleanValue -> expr.right
rightVal != null && rightVal.asBooleanValue -> expr.left
else -> null
}
}
"xor" -> {
if (leftVal != null && !leftVal.asBooleanValue)
expr.right
else if (rightVal != null && !rightVal.asBooleanValue)
expr.left
else if (leftVal != null && leftVal.asBooleanValue)
PrefixExpression("not", expr.right, expr.right.position)
else if (rightVal != null && rightVal.asBooleanValue)
PrefixExpression("not", expr.left, expr.left.position)
else
null
when {
leftVal != null && !leftVal.asBooleanValue -> expr.right
rightVal != null && !rightVal.asBooleanValue -> expr.left
leftVal != null && leftVal.asBooleanValue -> PrefixExpression("not", expr.right, expr.right.position)
rightVal != null && rightVal.asBooleanValue -> PrefixExpression("not", expr.left, expr.left.position)
else -> null
}
}
"|" -> {
when {
leftVal?.number==0.0 -> expr.right
rightVal?.number==0.0 -> expr.left
rightIDt.isBytes && rightVal?.number==255.0 -> NumericLiteral(DataType.UBYTE, 255.0, rightVal.position)
rightIDt.isWords && rightVal?.number==65535.0 -> NumericLiteral(DataType.UWORD, 65535.0, rightVal.position)
leftIDt.isBytes && leftVal?.number==255.0 -> NumericLiteral(DataType.UBYTE, 255.0, leftVal.position)
leftIDt.isWords && leftVal?.number==65535.0 -> NumericLiteral(DataType.UWORD, 65535.0, leftVal.position)
else -> null
}
}
"^" -> {
when {
leftVal?.number==0.0 -> expr.right
rightVal?.number==0.0 -> expr.left
rightIDt.isBytes && rightVal?.number==255.0 -> PrefixExpression("~", expr.left, expr.left.position)
rightIDt.isWords && rightVal?.number==65535.0 -> PrefixExpression("~", expr.left, expr.left.position)
leftIDt.isBytes && leftVal?.number==255.0 -> PrefixExpression("~", expr.right, expr.right.position)
leftIDt.isWords && leftVal?.number==65535.0 -> PrefixExpression("~", expr.right, expr.right.position)
else -> null
}
"|", "^" -> {
if (leftVal != null && !leftVal.asBooleanValue)
expr.right
else if (rightVal != null && !rightVal.asBooleanValue)
expr.left
else
null
}
"&" -> {
if (leftVal != null && !leftVal.asBooleanValue)
constFalse
else if (rightVal != null && !rightVal.asBooleanValue)
constFalse
else
null
when {
leftVal?.number==0.0 -> constFalse
rightVal?.number==0.0 -> constFalse
rightIDt.isBytes && rightVal?.number==255.0 -> expr.left
rightIDt.isWords && rightVal?.number==65535.0 -> expr.left
leftIDt.isBytes && leftVal?.number==255.0 -> expr.right
leftIDt.isWords && leftVal?.number==65535.0 -> expr.right
else -> null
}
}
"*" -> optimizeMultiplication(expr, leftVal, rightVal)
"/" -> optimizeDivision(expr, leftVal, rightVal)
@ -284,32 +277,32 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
return noModifications
}
override fun after(functionCall: FunctionCall, parent: Node): Iterable<IAstModification> {
if(functionCall.target.nameInSource == listOf("lsb")) {
val arg = functionCall.args[0]
override fun after(functionCallExpr: FunctionCallExpression, parent: Node): Iterable<IAstModification> {
if(functionCallExpr.target.nameInSource == listOf("lsb")) {
val arg = functionCallExpr.args[0]
if(arg is TypecastExpression) {
val valueDt = arg.expression.inferType(program)
if (valueDt istype DataType.BYTE || valueDt istype DataType.UBYTE) {
// useless lsb() of byte value that was typecasted to word
return listOf(IAstModification.ReplaceNode(functionCall, arg.expression, parent))
return listOf(IAstModification.ReplaceNode(functionCallExpr, arg.expression, parent))
}
} else {
val argDt = arg.inferType(program)
if (argDt istype DataType.BYTE || argDt istype DataType.UBYTE) {
// useless lsb() of byte value
return listOf(IAstModification.ReplaceNode(functionCall, arg, parent))
return listOf(IAstModification.ReplaceNode(functionCallExpr, arg, parent))
}
}
}
else if(functionCall.target.nameInSource == listOf("msb")) {
val arg = functionCall.args[0]
else if(functionCallExpr.target.nameInSource == listOf("msb")) {
val arg = functionCallExpr.args[0]
if(arg is TypecastExpression) {
val valueDt = arg.expression.inferType(program)
if (valueDt istype DataType.BYTE || valueDt istype DataType.UBYTE) {
// useless msb() of byte value that was typecasted to word, replace with 0
return listOf(IAstModification.ReplaceNode(
functionCall,
NumericLiteralValue(valueDt.getOr(DataType.UBYTE), 0, arg.expression.position),
functionCallExpr,
NumericLiteral(valueDt.getOr(DataType.UBYTE), 0.0, arg.expression.position),
parent))
}
} else {
@ -317,8 +310,8 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
if (argDt istype DataType.BYTE || argDt istype DataType.UBYTE) {
// useless msb() of byte value, replace with 0
return listOf(IAstModification.ReplaceNode(
functionCall,
NumericLiteralValue(argDt.getOr(DataType.UBYTE), 0, arg.position),
functionCallExpr,
NumericLiteral(argDt.getOr(DataType.UBYTE), 0.0, arg.position),
parent))
}
}
@ -327,6 +320,63 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
return noModifications
}
override fun after(containment: ContainmentCheck, parent: Node): Iterable<IAstModification> {
val range = containment.iterable as? RangeExpression
if(range!=null && range.step.constValue(program)?.number==1.0) {
val from = range.from.constValue(program)
val to = range.to.constValue(program)
val value = containment.element
if(from!=null && to!=null && value.isSimple) {
if(to.number-from.number>6.0) {
// replace containment test with X>=from and X<=to
val left = BinaryExpression(value, ">=", from, containment.position)
val right = BinaryExpression(value.copy(), "<=", to, containment.position)
val comparison = BinaryExpression(left, "and", right, containment.position)
return listOf(IAstModification.ReplaceNode(containment, comparison, parent))
}
}
}
return noModifications
}
override fun after(pipeExpr: PipeExpression, parent: Node): Iterable<IAstModification> {
val expressions = pipeExpr.expressions
val firstValue = expressions.first()
if(firstValue.isSimple) {
val funcname = expressions[1] as IdentifierReference
val first = FunctionCallExpression(funcname.copy(), mutableListOf(firstValue), firstValue.position)
val newExprs = mutableListOf<Expression>(first)
newExprs.addAll(expressions.drop(2))
return listOf(IAstModification.ReplaceNode(pipeExpr, PipeExpression(newExprs, pipeExpr.position), parent))
}
val singleExpr = expressions.singleOrNull()
if(singleExpr!=null) {
val callExpr = singleExpr as FunctionCallExpression
val call = FunctionCallExpression(callExpr.target, callExpr.args, callExpr.position)
return listOf(IAstModification.ReplaceNode(pipeExpr, call, parent))
}
return noModifications
}
override fun after(pipe: Pipe, parent: Node): Iterable<IAstModification> {
val expressions = pipe.expressions
val firstValue = expressions.first()
if(firstValue.isSimple) {
val funcname = expressions[1] as IdentifierReference
val first = FunctionCallExpression(funcname.copy(), mutableListOf(firstValue), firstValue.position)
val newExprs = mutableListOf<Expression>(first)
newExprs.addAll(expressions.drop(2))
return listOf(IAstModification.ReplaceNode(pipe, Pipe(newExprs, pipe.position), parent))
}
val singleExpr = expressions.singleOrNull()
if(singleExpr!=null) {
val callExpr = singleExpr as FunctionCallExpression
val call = FunctionCallStatement(callExpr.target, callExpr.args, true, callExpr.position)
return listOf(IAstModification.ReplaceNode(pipe, call, parent))
}
return noModifications
}
private fun determineY(x: Expression, subBinExpr: BinaryExpression): Expression? {
return when {
subBinExpr.left isSameAs x -> subBinExpr.right
@ -335,11 +385,11 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
}
}
private fun optimizeAdd(expr: BinaryExpression, leftVal: NumericLiteralValue?, rightVal: NumericLiteralValue?): Expression? {
private fun optimizeAdd(expr: BinaryExpression, leftVal: NumericLiteral?, rightVal: NumericLiteral?): Expression? {
if(expr.left.isSameAs(expr.right)) {
// optimize X+X into X *2
expr.operator = "*"
expr.right = NumericLiteralValue.optimalInteger(2, expr.right.position)
expr.right = NumericLiteral.optimalInteger(2, expr.right.position)
expr.right.linkParents(expr)
return expr
}
@ -350,8 +400,8 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
val (expr2, _, rightVal2) = reorderAssociativeWithConstant(expr, leftVal)
if (rightVal2 != null) {
// right value is a constant, see if we can optimize
val rightConst: NumericLiteralValue = rightVal2
when (rightConst.number.toDouble()) {
val rightConst: NumericLiteral = rightVal2
when (rightConst.number) {
0.0 -> {
// left
return expr2.left
@ -360,20 +410,20 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
}
// no need to check for left val constant (because of associativity)
val rnum = rightVal?.number?.toDouble()
val rnum = rightVal?.number
if(rnum!=null && rnum<0.0) {
expr.operator = "-"
expr.right = NumericLiteralValue(rightVal.type, -rnum, rightVal.position)
expr.right = NumericLiteral(rightVal.type, -rnum, rightVal.position)
return expr
}
return null
}
private fun optimizeSub(expr: BinaryExpression, leftVal: NumericLiteralValue?, rightVal: NumericLiteralValue?): Expression? {
private fun optimizeSub(expr: BinaryExpression, leftVal: NumericLiteral?, rightVal: NumericLiteral?): Expression? {
if(expr.left.isSameAs(expr.right)) {
// optimize X-X into 0
return NumericLiteralValue.optimalInteger(0, expr.position)
return NumericLiteral.optimalInteger(0, expr.position)
}
if (leftVal == null && rightVal == null)
@ -381,7 +431,7 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
if (rightVal != null) {
// right value is a constant, see if we can optimize
val rnum = rightVal.number.toDouble()
val rnum = rightVal.number
if (rnum == 0.0) {
// left
return expr.left
@ -389,13 +439,13 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
if(rnum<0.0) {
expr.operator = "+"
expr.right = NumericLiteralValue(rightVal.type, -rnum, rightVal.position)
expr.right = NumericLiteral(rightVal.type, -rnum, rightVal.position)
return expr
}
}
if (leftVal != null) {
// left value is a constant, see if we can optimize
when (leftVal.number.toDouble()) {
when (leftVal.number) {
0.0 -> {
// -right
return PrefixExpression("-", expr.right, expr.position)
@ -407,38 +457,38 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
return null
}
private fun optimizePower(expr: BinaryExpression, leftVal: NumericLiteralValue?, rightVal: NumericLiteralValue?): Expression? {
private fun optimizePower(expr: BinaryExpression, leftVal: NumericLiteral?, rightVal: NumericLiteral?): Expression? {
if (leftVal == null && rightVal == null)
return null
if (rightVal != null) {
// right value is a constant, see if we can optimize
val rightConst: NumericLiteralValue = rightVal
when (rightConst.number.toDouble()) {
val rightConst: NumericLiteral = rightVal
when (rightConst.number) {
-3.0 -> {
// -1/(left*left*left)
return BinaryExpression(NumericLiteralValue(DataType.FLOAT, -1.0, expr.position), "/",
return BinaryExpression(NumericLiteral(DataType.FLOAT, -1.0, expr.position), "/",
BinaryExpression(expr.left, "*", BinaryExpression(expr.left, "*", expr.left, expr.position), expr.position),
expr.position)
}
-2.0 -> {
// -1/(left*left)
return BinaryExpression(NumericLiteralValue(DataType.FLOAT, -1.0, expr.position), "/",
return BinaryExpression(NumericLiteral(DataType.FLOAT, -1.0, expr.position), "/",
BinaryExpression(expr.left, "*", expr.left, expr.position),
expr.position)
}
-1.0 -> {
// -1/left
return BinaryExpression(NumericLiteralValue(DataType.FLOAT, -1.0, expr.position), "/",
return BinaryExpression(NumericLiteral(DataType.FLOAT, -1.0, expr.position), "/",
expr.left, expr.position)
}
0.0 -> {
// 1
return NumericLiteralValue(rightConst.type, 1, expr.position)
return NumericLiteral(rightConst.type, 1.0, expr.position)
}
0.5 -> {
// sqrt(left)
return FunctionCall(IdentifierReference(listOf("sqrt"), expr.position), mutableListOf(expr.left), expr.position)
return FunctionCallExpression(IdentifierReference(listOf("sqrt"), expr.position), mutableListOf(expr.left), expr.position)
}
1.0 -> {
// left
@ -456,18 +506,18 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
}
if (leftVal != null) {
// left value is a constant, see if we can optimize
when (leftVal.number.toDouble()) {
when (leftVal.number) {
-1.0 -> {
// -1
return NumericLiteralValue(DataType.FLOAT, -1.0, expr.position)
return NumericLiteral(DataType.FLOAT, -1.0, expr.position)
}
0.0 -> {
// 0
return NumericLiteralValue(leftVal.type, 0, expr.position)
return NumericLiteral(leftVal.type, 0.0, expr.position)
}
1.0 -> {
//1
return NumericLiteralValue(leftVal.type, 1, expr.position)
return NumericLiteral(leftVal.type, 1.0, expr.position)
}
}
@ -476,7 +526,7 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
return null
}
private fun optimizeRemainder(expr: BinaryExpression, leftVal: NumericLiteralValue?, rightVal: NumericLiteralValue?): Expression? {
private fun optimizeRemainder(expr: BinaryExpression, leftVal: NumericLiteral?, rightVal: NumericLiteral?): Expression? {
if (leftVal == null && rightVal == null)
return null
@ -489,10 +539,10 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
val idt = expr.inferType(program)
if(!idt.isKnown)
throw FatalAstException("unknown dt")
return NumericLiteralValue(idt.getOr(DataType.UNDEFINED), 0, expr.position)
return NumericLiteral(idt.getOr(DataType.UNDEFINED), 0.0, expr.position)
} else if (cv in powersOfTwo) {
expr.operator = "&"
expr.right = NumericLiteralValue.optimalInteger(cv!!.toInt()-1, expr.position)
expr.right = NumericLiteral.optimalInteger(cv!!.toInt()-1, expr.position)
return null
}
}
@ -501,15 +551,15 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
}
private fun optimizeDivision(expr: BinaryExpression, leftVal: NumericLiteralValue?, rightVal: NumericLiteralValue?): Expression? {
private fun optimizeDivision(expr: BinaryExpression, leftVal: NumericLiteral?, rightVal: NumericLiteral?): Expression? {
if (leftVal == null && rightVal == null)
return null
// cannot shuffle assiciativity with division!
if (rightVal != null) {
// right value is a constant, see if we can optimize
val rightConst: NumericLiteralValue = rightVal
val cv = rightConst.number.toDouble()
val rightConst: NumericLiteral = rightVal
val cv = rightConst.number
val leftIDt = expr.left.inferType(program)
if (!leftIDt.isKnown)
return null
@ -531,35 +581,35 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
if (leftDt in IntegerDatatypes) {
// divided by a power of two => shift right
val numshifts = log2(cv).toInt()
return BinaryExpression(expr.left, ">>", NumericLiteralValue.optimalInteger(numshifts, expr.position), expr.position)
return BinaryExpression(expr.left, ">>", NumericLiteral.optimalInteger(numshifts, expr.position), expr.position)
}
}
in negativePowersOfTwo -> {
if (leftDt in IntegerDatatypes) {
// divided by a negative power of two => negate, then shift right
val numshifts = log2(-cv).toInt()
return BinaryExpression(PrefixExpression("-", expr.left, expr.position), ">>", NumericLiteralValue.optimalInteger(numshifts, expr.position), expr.position)
return BinaryExpression(PrefixExpression("-", expr.left, expr.position), ">>", NumericLiteral.optimalInteger(numshifts, expr.position), expr.position)
}
}
}
if (leftDt == DataType.UBYTE) {
if (abs(rightConst.number.toDouble()) >= 256.0) {
return NumericLiteralValue(DataType.UBYTE, 0, expr.position)
if (abs(rightConst.number) >= 256.0) {
return NumericLiteral(DataType.UBYTE, 0.0, expr.position)
}
} else if (leftDt == DataType.UWORD) {
if (abs(rightConst.number.toDouble()) >= 65536.0) {
return NumericLiteralValue(DataType.UBYTE, 0, expr.position)
if (abs(rightConst.number) >= 65536.0) {
return NumericLiteral(DataType.UBYTE, 0.0, expr.position)
}
}
}
if (leftVal != null) {
// left value is a constant, see if we can optimize
when (leftVal.number.toDouble()) {
when (leftVal.number) {
0.0 -> {
// 0
return NumericLiteralValue(leftVal.type, 0, expr.position)
return NumericLiteral(leftVal.type, 0.0, expr.position)
}
}
}
@ -567,7 +617,7 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
return null
}
private fun optimizeMultiplication(expr: BinaryExpression, leftVal: NumericLiteralValue?, rightVal: NumericLiteralValue?): Expression? {
private fun optimizeMultiplication(expr: BinaryExpression, leftVal: NumericLiteral?, rightVal: NumericLiteral?): Expression? {
if (leftVal == null && rightVal == null)
return null
@ -575,15 +625,15 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
if (rightVal2 != null) {
// right value is a constant, see if we can optimize
val leftValue: Expression = expr2.left
val rightConst: NumericLiteralValue = rightVal2
when (val cv = rightConst.number.toDouble()) {
val rightConst: NumericLiteral = rightVal2
when (val cv = rightConst.number) {
-1.0 -> {
// -left
return PrefixExpression("-", leftValue, expr.position)
}
0.0 -> {
// 0
return NumericLiteralValue(rightConst.type, 0, expr.position)
return NumericLiteral(rightConst.type, 0.0, expr.position)
}
1.0 -> {
// left
@ -593,14 +643,14 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
if (leftValue.inferType(program).isInteger) {
// times a power of two => shift left
val numshifts = log2(cv).toInt()
return BinaryExpression(expr2.left, "<<", NumericLiteralValue.optimalInteger(numshifts, expr.position), expr.position)
return BinaryExpression(expr2.left, "<<", NumericLiteral.optimalInteger(numshifts, expr.position), expr.position)
}
}
in negativePowersOfTwo -> {
if (leftValue.inferType(program).isInteger) {
// times a negative power of two => negate, then shift left
val numshifts = log2(-cv).toInt()
return BinaryExpression(PrefixExpression("-", expr2.left, expr.position), "<<", NumericLiteralValue.optimalInteger(numshifts, expr.position), expr.position)
return BinaryExpression(PrefixExpression("-", expr2.left, expr.position), "<<", NumericLiteral.optimalInteger(numshifts, expr.position), expr.position)
}
}
}
@ -610,7 +660,7 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
return null
}
private fun optimizeShiftLeft(expr: BinaryExpression, amountLv: NumericLiteralValue?): Expression? {
private fun optimizeShiftLeft(expr: BinaryExpression, amountLv: NumericLiteral?): Expression? {
if (amountLv == null)
return null
@ -624,19 +674,16 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
when (val targetDt = targetIDt.getOr(DataType.UNDEFINED)) {
DataType.UBYTE, DataType.BYTE -> {
if (amount >= 8) {
return NumericLiteralValue(targetDt, 0, expr.position)
return NumericLiteral(targetDt, 0.0, expr.position)
}
}
DataType.UWORD, DataType.WORD -> {
if (amount >= 16) {
return NumericLiteralValue(targetDt, 0, expr.position)
} else if (amount >= 8) {
val lsb = FunctionCall(IdentifierReference(listOf("lsb"), expr.position), mutableListOf(expr.left), expr.position)
if (amount == 8) {
return FunctionCall(IdentifierReference(listOf("mkword"), expr.position), mutableListOf(lsb, NumericLiteralValue.optimalInteger(0, expr.position)), expr.position)
}
val shifted = BinaryExpression(lsb, "<<", NumericLiteralValue.optimalInteger(amount - 8, expr.position), expr.position)
return FunctionCall(IdentifierReference(listOf("mkword"), expr.position), mutableListOf(shifted, NumericLiteralValue.optimalInteger(0, expr.position)), expr.position)
return NumericLiteral(targetDt, 0.0, expr.position)
} else if (amount > 8) {
val lsb = FunctionCallExpression(IdentifierReference(listOf("lsb"), expr.position), mutableListOf(expr.left), expr.position)
val shifted = BinaryExpression(lsb, "<<", NumericLiteral.optimalInteger(amount - 8, expr.position), expr.position)
return FunctionCallExpression(IdentifierReference(listOf("mkword"), expr.position), mutableListOf(shifted, NumericLiteral.optimalInteger(0, expr.position)), expr.position)
}
}
else -> {
@ -645,7 +692,7 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
return null
}
private fun optimizeShiftRight(expr: BinaryExpression, amountLv: NumericLiteralValue?): Expression? {
private fun optimizeShiftRight(expr: BinaryExpression, amountLv: NumericLiteral?): Expression? {
if (amountLv == null)
return null
@ -659,32 +706,27 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
when (idt.getOr(DataType.UNDEFINED)) {
DataType.UBYTE -> {
if (amount >= 8) {
return NumericLiteralValue.optimalInteger(0, expr.position)
return NumericLiteral.optimalInteger(0, expr.position)
}
}
DataType.BYTE -> {
if (amount > 8) {
expr.right = NumericLiteralValue.optimalInteger(8, expr.right.position)
expr.right = NumericLiteral.optimalInteger(8, expr.right.position)
return null
}
}
DataType.UWORD -> {
if (amount >= 16) {
return NumericLiteralValue.optimalInteger(0, expr.position)
return NumericLiteral.optimalInteger(0, expr.position)
}
else if (amount >= 8) {
val msb = FunctionCall(IdentifierReference(listOf("msb"), expr.position), mutableListOf(expr.left), expr.position)
if (amount == 8) {
// mkword(0, msb(v))
val zero = NumericLiteralValue(DataType.UBYTE, 0, expr.position)
return FunctionCall(IdentifierReference(listOf("mkword"), expr.position), mutableListOf(zero, msb), expr.position)
}
return TypecastExpression(BinaryExpression(msb, ">>", NumericLiteralValue.optimalInteger(amount - 8, expr.position), expr.position), DataType.UWORD, true, expr.position)
else if (amount > 8) {
val msb = FunctionCallExpression(IdentifierReference(listOf("msb"), expr.position), mutableListOf(expr.left), expr.position)
return TypecastExpression(BinaryExpression(msb, ">>", NumericLiteral.optimalInteger(amount - 8, expr.position), expr.position), DataType.UWORD, true, expr.position)
}
}
DataType.WORD -> {
if (amount > 16) {
expr.right = NumericLiteralValue.optimalInteger(16, expr.right.position)
expr.right = NumericLiteral.optimalInteger(16, expr.right.position)
return null
}
}
@ -694,8 +736,8 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
return null
}
private fun reorderAssociativeWithConstant(expr: BinaryExpression, leftVal: NumericLiteralValue?): BinExprWithConstants {
if (expr.operator in associativeOperators && leftVal != null) {
private fun reorderAssociativeWithConstant(expr: BinaryExpression, leftVal: NumericLiteral?): BinExprWithConstants {
if (expr.operator in AssociativeOperators && leftVal != null) {
// swap left and right so that right is always the constant
val tmp = expr.left
expr.left = expr.right
@ -705,6 +747,6 @@ internal class ExpressionSimplifier(private val program: Program) : AstWalker()
return BinExprWithConstants(expr, leftVal, expr.right.constValue(program))
}
private data class BinExprWithConstants(val expr: BinaryExpression, val leftVal: NumericLiteralValue?, val rightVal: NumericLiteralValue?)
private data class BinExprWithConstants(val expr: BinaryExpression, val leftVal: NumericLiteral?, val rightVal: NumericLiteral?)
}

35
compiler/src/prog8/optimizer/Extensions.kt → codeOptimizers/src/prog8/optimizer/Extensions.kt
View File

@ -2,11 +2,15 @@ package prog8.optimizer
import prog8.ast.IBuiltinFunctions
import prog8.ast.Program
import prog8.compiler.IErrorReporter
import prog8.compiler.target.ICompilationTarget
import prog8.ast.base.DataType
import prog8.ast.base.FatalAstException
import prog8.ast.expressions.InferredTypes
import prog8.compilerinterface.CompilationOptions
import prog8.compilerinterface.ICompilationTarget
import prog8.compilerinterface.IErrorReporter
internal fun Program.constantFold(errors: IErrorReporter, compTarget: ICompilationTarget) {
fun Program.constantFold(errors: IErrorReporter, compTarget: ICompilationTarget) {
val valuetypefixer = VarConstantValueTypeAdjuster(this, errors)
valuetypefixer.visit(this)
if(errors.noErrors()) {
@ -40,9 +44,10 @@ internal fun Program.constantFold(errors: IErrorReporter, compTarget: ICompilati
}
internal fun Program.optimizeStatements(errors: IErrorReporter,
fun Program.optimizeStatements(errors: IErrorReporter,
functions: IBuiltinFunctions,
compTarget: ICompilationTarget): Int {
compTarget: ICompilationTarget
): Int {
val optimizer = StatementOptimizer(this, errors, functions, compTarget)
optimizer.visit(this)
val optimizationCount = optimizer.applyModifications()
@ -52,14 +57,26 @@ internal fun Program.optimizeStatements(errors: IErrorReporter,
return optimizationCount
}
internal fun Program.simplifyExpressions() : Int {
val opti = ExpressionSimplifier(this)
fun Program.simplifyExpressions(errors: IErrorReporter) : Int {
val opti = ExpressionSimplifier(this, errors)
opti.visit(this)
return opti.applyModifications()
}
internal fun Program.splitBinaryExpressions(compTarget: ICompilationTarget) : Int {
val opti = BinExprSplitter(this, compTarget)
fun Program.splitBinaryExpressions(options: CompilationOptions, compTarget: ICompilationTarget) : Int {
val opti = BinExprSplitter(this, options, compTarget)
opti.visit(this)
return opti.applyModifications()
}
fun getTempRegisterName(dt: InferredTypes.InferredType): List<String> {
return when {
// TODO assume (hope) cx16.r9 isn't used for anything else during the use of this temporary variable...
dt istype DataType.UBYTE -> listOf("cx16", "r9L")
dt istype DataType.BYTE -> listOf("cx16", "r9sL")
dt istype DataType.UWORD -> listOf("cx16", "r9")
dt istype DataType.WORD -> listOf("cx16", "r9s")
dt.isPassByReference -> listOf("cx16", "r9")
else -> throw FatalAstException("invalid dt $dt")
}
}

366
compiler/src/prog8/optimizer/StatementOptimizer.kt → codeOptimizers/src/prog8/optimizer/StatementOptimizer.kt
View File

@ -1,85 +1,71 @@
package prog8.optimizer
import prog8.ast.IBuiltinFunctions
import prog8.ast.INameScope
import prog8.ast.Node
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.*
import prog8.ast.base.ArrayDatatypes
import prog8.ast.base.DataType
import prog8.ast.base.IntegerDatatypes
import prog8.ast.base.VarDeclType
import prog8.ast.expressions.*
import prog8.ast.statements.*
import prog8.ast.walk.AstWalker
import prog8.ast.walk.IAstModification
import prog8.ast.walk.IAstVisitor
import prog8.compiler.IErrorReporter
import prog8.compiler.astprocessing.size
import prog8.compiler.target.ICompilationTarget
import prog8.compilerinterface.ICompilationTarget
import prog8.compilerinterface.IErrorReporter
import kotlin.math.floor
internal const val retvarName = "prog8_retval"
internal class StatementOptimizer(private val program: Program,
class StatementOptimizer(private val program: Program,
private val errors: IErrorReporter,
private val functions: IBuiltinFunctions,
private val compTarget: ICompilationTarget) : AstWalker() {
private val compTarget: ICompilationTarget
) : AstWalker() {
private val subsThatNeedReturnVariable = mutableSetOf<Triple<INameScope, DataType, Position>>()
override fun after(subroutine: Subroutine, parent: Node): Iterable<IAstModification> {
for(returnvar in subsThatNeedReturnVariable) {
val decl = VarDecl(VarDeclType.VAR, returnvar.second, ZeropageWish.DONTCARE, null, retvarName, null,
isArray = false,
autogeneratedDontRemove = true,
sharedWithAsm = false,
position = returnvar.third
)
returnvar.first.statements.add(0, decl)
}
subsThatNeedReturnVariable.clear()
return noModifications
}
override fun before(functionCall: FunctionCall, parent: Node): Iterable<IAstModification> {
// if the first instruction in the called subroutine is a return statement with a simple value,
override fun before(functionCallExpr: FunctionCallExpression, parent: Node): Iterable<IAstModification> {
// if the first instruction in the called subroutine is a return statement with a simple value (NOT being a parameter),
// remove the jump altogeter and inline the returnvalue directly.
val subroutine = functionCall.target.targetSubroutine(program)
fun scopePrefix(variable: IdentifierReference): IdentifierReference {
val target = variable.targetStatement(program) as INamedStatement
return IdentifierReference(target.scopedName, variable.position)
}
val subroutine = functionCallExpr.target.targetSubroutine(program)
if(subroutine!=null) {
val first = subroutine.statements.asSequence().filterNot { it is VarDecl || it is Directive }.firstOrNull()
if(first is Return && first.value?.isSimple==true) {
val copy = when(val orig = first.value!!) {
is AddressOf -> {
val scoped = scopePrefix(orig.identifier, subroutine)
val scoped = scopePrefix(orig.identifier)
AddressOf(scoped, orig.position)
}
is DirectMemoryRead -> {
when(val expr = orig.addressExpression) {
is NumericLiteralValue -> DirectMemoryRead(expr.copy(), orig.position)
is NumericLiteral -> DirectMemoryRead(expr.copy(), orig.position)
else -> return noModifications
}
}
is IdentifierReference -> scopePrefix(orig, subroutine)
is NumericLiteralValue -> orig.copy()
is StringLiteralValue -> orig.copy()
is IdentifierReference -> {
if(orig.targetVarDecl(program)?.origin == VarDeclOrigin.SUBROUTINEPARAM)
return noModifications
else
scopePrefix(orig)
}
is NumericLiteral -> orig.copy()
is StringLiteral -> orig.copy()
else -> return noModifications
}
return listOf(IAstModification.ReplaceNode(functionCall, copy, parent))
return listOf(IAstModification.ReplaceNode(functionCallExpr, copy, parent))
}
}
return noModifications
}
private fun scopePrefix(variable: IdentifierReference, subroutine: Subroutine): IdentifierReference {
val scoped = subroutine.makeScopedName(variable.nameInSource.last())
return IdentifierReference(scoped.split('.'), variable.position)
}
override fun after(functionCallStatement: FunctionCallStatement, parent: Node): Iterable<IAstModification> {
if(functionCallStatement.target.nameInSource.size==1 && functionCallStatement.target.nameInSource[0] in functions.names) {
if(functionCallStatement.target.targetStatement(program) is BuiltinFunctionPlaceholder) {
val functionName = functionCallStatement.target.nameInSource[0]
if (functionName in functions.purefunctionNames) {
errors.warn("statement has no effect (function return value is discarded)", functionCallStatement.position)
return listOf(IAstModification.Remove(functionCallStatement, functionCallStatement.definingScope))
return listOf(IAstModification.Remove(functionCallStatement, parent as IStatementContainer))
}
}
@ -93,32 +79,38 @@ internal class StatementOptimizer(private val program: Program,
arg as? IdentifierReference
}
if(stringVar!=null && stringVar.wasStringLiteral(program)) {
val string = stringVar.targetVarDecl(program)?.value as? StringLiteralValue
val string = stringVar.targetVarDecl(program)?.value as? StringLiteral
if(string!=null) {
val pos = functionCallStatement.position
if (string.value.length == 1) {
val firstCharEncoded = compTarget.encodeString(string.value, string.altEncoding)[0]
val firstCharEncoded = compTarget.encodeString(string.value, string.encoding)[0]
val chrout = FunctionCallStatement(
IdentifierReference(listOf("txt", "chrout"), pos),
mutableListOf(NumericLiteralValue(DataType.UBYTE, firstCharEncoded.toInt(), pos)),
mutableListOf(NumericLiteral(DataType.UBYTE, firstCharEncoded.toDouble(), pos)),
functionCallStatement.void, pos
)
return listOf(IAstModification.ReplaceNode(functionCallStatement, chrout, parent))
val stringDecl = string.parent as VarDecl
return listOf(
IAstModification.ReplaceNode(functionCallStatement, chrout, parent),
IAstModification.Remove(stringDecl, stringDecl.parent as IStatementContainer)
)
} else if (string.value.length == 2) {
val firstTwoCharsEncoded = compTarget.encodeString(string.value.take(2), string.altEncoding)
val firstTwoCharsEncoded = compTarget.encodeString(string.value.take(2), string.encoding)
val chrout1 = FunctionCallStatement(
IdentifierReference(listOf("txt", "chrout"), pos),
mutableListOf(NumericLiteralValue(DataType.UBYTE, firstTwoCharsEncoded[0].toInt(), pos)),
mutableListOf(NumericLiteral(DataType.UBYTE, firstTwoCharsEncoded[0].toDouble(), pos)),
functionCallStatement.void, pos
)
val chrout2 = FunctionCallStatement(
IdentifierReference(listOf("txt", "chrout"), pos),
mutableListOf(NumericLiteralValue(DataType.UBYTE, firstTwoCharsEncoded[1].toInt(), pos)),
mutableListOf(NumericLiteral(DataType.UBYTE, firstTwoCharsEncoded[1].toDouble(), pos)),
functionCallStatement.void, pos
)
val stringDecl = string.parent as VarDecl
return listOf(
IAstModification.InsertBefore(functionCallStatement, chrout1, parent as INameScope),
IAstModification.ReplaceNode(functionCallStatement, chrout2, parent)
IAstModification.InsertBefore(functionCallStatement, chrout1, parent as IStatementContainer),
IAstModification.ReplaceNode(functionCallStatement, chrout2, parent),
IAstModification.Remove(stringDecl, stringDecl.parent as IStatementContainer)
)
}
}
@ -130,53 +122,55 @@ internal class StatementOptimizer(private val program: Program,
if(subroutine!=null) {
val first = subroutine.statements.asSequence().filterNot { it is VarDecl || it is Directive }.firstOrNull()
if(first is Return)
return listOf(IAstModification.Remove(functionCallStatement, functionCallStatement.definingScope))
return listOf(IAstModification.Remove(functionCallStatement, parent as IStatementContainer))
}
// see if we can optimize any complex arguments
// TODO for now, only works for single-argument functions because we use just 1 temp var: R9
if(functionCallStatement.target.nameInSource !in listOf(listOf("pop"), listOf("popw")) && functionCallStatement.args.size==1) {
val arg = functionCallStatement.args[0]
if(!arg.isSimple && arg !is TypecastExpression && arg !is IFunctionCall) {
val name = getTempRegisterName(arg.inferType(program))
val tempvar = IdentifierReference(name, functionCallStatement.position)
val assignTempvar = Assignment(AssignTarget(tempvar.copy(), null, null, functionCallStatement.position), arg, AssignmentOrigin.OPTIMIZER, functionCallStatement.position)
return listOf(
IAstModification.InsertBefore(functionCallStatement, assignTempvar, parent as IStatementContainer),
IAstModification.ReplaceNode(arg, tempvar, functionCallStatement)
)
}
}
return noModifications
}
// override fun before(functionCall: FunctionCall, parent: Node): Iterable<IAstModification> {
// // if the first instruction in the called subroutine is a return statement with constant value, replace with the constant value
// val subroutine = functionCall.target.targetSubroutine(program)
// if(subroutine!=null) {
// val first = subroutine.statements.asSequence().filterNot { it is VarDecl || it is Directive }.firstOrNull()
// if(first is Return && first.value!=null) {
// val constval = first.value?.constValue(program)
// if(constval!=null)
// return listOf(IAstModification.ReplaceNode(functionCall, constval, parent))
// }
// }
// return noModifications
// }
override fun after(ifStatement: IfStatement, parent: Node): Iterable<IAstModification> {
override fun after(ifElse: IfElse, parent: Node): Iterable<IAstModification> {
// remove empty if statements
if(ifStatement.truepart.containsNoCodeNorVars && ifStatement.elsepart.containsNoCodeNorVars)
return listOf(IAstModification.Remove(ifStatement, ifStatement.definingScope))
if(ifElse.truepart.isEmpty() && ifElse.elsepart.isEmpty())
return listOf(IAstModification.Remove(ifElse, parent as IStatementContainer))
// empty true part? switch with the else part
if(ifStatement.truepart.containsNoCodeNorVars && ifStatement.elsepart.containsCodeOrVars) {
val invertedCondition = PrefixExpression("not", ifStatement.condition, ifStatement.condition.position)
val emptyscope = AnonymousScope(mutableListOf(), ifStatement.elsepart.position)
val truepart = AnonymousScope(ifStatement.elsepart.statements, ifStatement.truepart.position)
if(ifElse.truepart.isEmpty() && ifElse.elsepart.isNotEmpty()) {
val invertedCondition = PrefixExpression("not", ifElse.condition, ifElse.condition.position)
val emptyscope = AnonymousScope(mutableListOf(), ifElse.elsepart.position)
val truepart = AnonymousScope(ifElse.elsepart.statements, ifElse.truepart.position)
return listOf(
IAstModification.ReplaceNode(ifStatement.condition, invertedCondition, ifStatement),
IAstModification.ReplaceNode(ifStatement.truepart, truepart, ifStatement),
IAstModification.ReplaceNode(ifStatement.elsepart, emptyscope, ifStatement)
IAstModification.ReplaceNode(ifElse.condition, invertedCondition, ifElse),
IAstModification.ReplaceNode(ifElse.truepart, truepart, ifElse),
IAstModification.ReplaceNode(ifElse.elsepart, emptyscope, ifElse)
)
}
val constvalue = ifStatement.condition.constValue(program)
val constvalue = ifElse.condition.constValue(program)
if(constvalue!=null) {
return if(constvalue.asBooleanValue){
// always true -> keep only if-part
errors.warn("condition is always true", ifStatement.position)
listOf(IAstModification.ReplaceNode(ifStatement, ifStatement.truepart, parent))
errors.warn("condition is always true", ifElse.condition.position)
listOf(IAstModification.ReplaceNode(ifElse, ifElse.truepart, parent))
} else {
// always false -> keep only else-part
errors.warn("condition is always false", ifStatement.position)
listOf(IAstModification.ReplaceNode(ifStatement, ifStatement.elsepart, parent))
errors.warn("condition is always false", ifElse.condition.position)
listOf(IAstModification.ReplaceNode(ifElse, ifElse.elsepart, parent))
}
}
@ -184,24 +178,24 @@ internal class StatementOptimizer(private val program: Program,
}
override fun after(forLoop: ForLoop, parent: Node): Iterable<IAstModification> {
if(forLoop.body.containsNoCodeNorVars) {
if(forLoop.body.isEmpty()) {
errors.warn("removing empty for loop", forLoop.position)
return listOf(IAstModification.Remove(forLoop, forLoop.definingScope))
return listOf(IAstModification.Remove(forLoop, parent as IStatementContainer))
} else if(forLoop.body.statements.size==1) {
val loopvar = forLoop.body.statements[0] as? VarDecl
if(loopvar!=null && loopvar.name==forLoop.loopVar.nameInSource.singleOrNull()) {
// remove empty for loop (only loopvar decl in it)
return listOf(IAstModification.Remove(forLoop, forLoop.definingScope))
return listOf(IAstModification.Remove(forLoop, parent as IStatementContainer))
}
}
val range = forLoop.iterable as? RangeExpr
val range = forLoop.iterable as? RangeExpression
if(range!=null) {
if (range.size(compTarget) == 1) {
if (range.size() == 1) {
// for loop over a (constant) range of just a single value-- optimize the loop away
// loopvar/reg = range value , follow by block
val scope = AnonymousScope(mutableListOf(), forLoop.position)
scope.statements.add(Assignment(AssignTarget(forLoop.loopVar, null, null, forLoop.position), range.from, forLoop.position))
scope.statements.add(Assignment(AssignTarget(forLoop.loopVar, null, null, forLoop.position), range.from, AssignmentOrigin.OPTIMIZER, forLoop.position))
scope.statements.addAll(forLoop.body.statements)
return listOf(IAstModification.ReplaceNode(forLoop, scope, parent))
}
@ -209,14 +203,14 @@ internal class StatementOptimizer(private val program: Program,
val iterable = (forLoop.iterable as? IdentifierReference)?.targetVarDecl(program)
if(iterable!=null) {
if(iterable.datatype==DataType.STR) {
val sv = iterable.value as StringLiteralValue
val sv = iterable.value as StringLiteral
val size = sv.value.length
if(size==1) {
// loop over string of length 1 -> just assign the single character
val character = compTarget.encodeString(sv.value, sv.altEncoding)[0]
val byte = NumericLiteralValue(DataType.UBYTE, character, iterable.position)
val character = compTarget.encodeString(sv.value, sv.encoding)[0]
val byte = NumericLiteral(DataType.UBYTE, character.toDouble(), iterable.position)
val scope = AnonymousScope(mutableListOf(), forLoop.position)
scope.statements.add(Assignment(AssignTarget(forLoop.loopVar, null, null, forLoop.position), byte, forLoop.position))
scope.statements.add(Assignment(AssignTarget(forLoop.loopVar, null, null, forLoop.position), byte, AssignmentOrigin.OPTIMIZER, forLoop.position))
scope.statements.addAll(forLoop.body.statements)
return listOf(IAstModification.ReplaceNode(forLoop, scope, parent))
}
@ -225,12 +219,12 @@ internal class StatementOptimizer(private val program: Program,
val size = iterable.arraysize!!.constIndex()
if(size==1) {
// loop over array of length 1 -> just assign the single value
val av = (iterable.value as ArrayLiteralValue).value[0].constValue(program)?.number
val av = (iterable.value as ArrayLiteral).value[0].constValue(program)?.number
if(av!=null) {
val scope = AnonymousScope(mutableListOf(), forLoop.position)
scope.statements.add(Assignment(
AssignTarget(forLoop.loopVar, null, null, forLoop.position), NumericLiteralValue.optimalInteger(av.toInt(), iterable.position),
forLoop.position))
AssignTarget(forLoop.loopVar, null, null, forLoop.position), NumericLiteral.optimalInteger(av.toInt(), iterable.position),
AssignmentOrigin.OPTIMIZER, forLoop.position))
scope.statements.addAll(forLoop.body.statements)
return listOf(IAstModification.ReplaceNode(forLoop, scope, parent))
}
@ -244,15 +238,14 @@ internal class StatementOptimizer(private val program: Program,
override fun before(untilLoop: UntilLoop, parent: Node): Iterable<IAstModification> {
val constvalue = untilLoop.condition.constValue(program)
if(constvalue!=null) {
if(constvalue.asBooleanValue) {
// always true -> keep only the statement block (if there are no break statements)
return if(constvalue.asBooleanValue) {
// always true -> keep only the statement block
errors.warn("condition is always true", untilLoop.condition.position)
if(!hasBreak(untilLoop.body))
return listOf(IAstModification.ReplaceNode(untilLoop, untilLoop.body, parent))
listOf(IAstModification.ReplaceNode(untilLoop, untilLoop.body, parent))
} else {
// always false
val forever = RepeatLoop(null, untilLoop.body, untilLoop.position)
return listOf(IAstModification.ReplaceNode(untilLoop, forever, parent))
listOf(IAstModification.ReplaceNode(untilLoop, forever, parent))
}
}
return noModifications
@ -268,7 +261,7 @@ internal class StatementOptimizer(private val program: Program,
} else {
// always false -> remove the while statement altogether
errors.warn("condition is always false", whileLoop.condition.position)
listOf(IAstModification.Remove(whileLoop, whileLoop.definingScope))
listOf(IAstModification.Remove(whileLoop, parent as IStatementContainer))
}
}
return noModifications
@ -277,14 +270,14 @@ internal class StatementOptimizer(private val program: Program,
override fun after(repeatLoop: RepeatLoop, parent: Node): Iterable<IAstModification> {
val iter = repeatLoop.iterations
if(iter!=null) {
if(repeatLoop.body.containsNoCodeNorVars) {
if(repeatLoop.body.isEmpty()) {
errors.warn("empty loop removed", repeatLoop.position)
return listOf(IAstModification.Remove(repeatLoop, repeatLoop.definingScope))
return listOf(IAstModification.Remove(repeatLoop, parent as IStatementContainer))
}
val iterations = iter.constValue(program)?.number?.toInt()
if (iterations == 0) {
errors.warn("iterations is always 0, removed loop", iter.position)
return listOf(IAstModification.Remove(repeatLoop, repeatLoop.definingScope))
return listOf(IAstModification.Remove(repeatLoop, parent as IStatementContainer))
}
if (iterations == 1) {
errors.warn("iterations is always 1", iter.position)
@ -294,13 +287,22 @@ internal class StatementOptimizer(private val program: Program,
return noModifications
}
override fun after(jump: Jump, parent: Node): Iterable<IAstModification> {
// if the jump is to the next statement, remove the jump
val scope = jump.definingScope
val label = jump.identifier?.targetStatement(program)
if(label!=null && scope.statements.indexOf(label) == scope.statements.indexOf(jump)+1)
return listOf(IAstModification.Remove(jump, jump.definingScope))
// NOTE: do NOT remove a jump to the next statement, because this will lead to wrong code when this occurs at the end of a subroutine
// if we want to optimize this away, it can be done later at code generation time.
override fun after(gosub: GoSub, parent: Node): Iterable<IAstModification> {
// if the next statement is return with no returnvalue, change into a regular jump if there are no parameters as well.
val subroutineParams = gosub.identifier?.targetSubroutine(program)?.parameters
if(subroutineParams!=null && subroutineParams.isEmpty()) {
val returnstmt = gosub.nextSibling() as? Return
if(returnstmt!=null && returnstmt.value==null) {
return listOf(
IAstModification.Remove(returnstmt, parent as IStatementContainer),
IAstModification.ReplaceNode(gosub, Jump(gosub.address, gosub.identifier, gosub.generatedLabel, gosub.position), parent)
)
}
}
return noModifications
}
@ -314,43 +316,43 @@ internal class StatementOptimizer(private val program: Program,
val op1 = binExpr.operator
val op2 = rExpr.operator
if(rExpr.left is NumericLiteralValue && op2 in associativeOperators) {
if(rExpr.left is NumericLiteral && op2 in AssociativeOperators) {
// associative operator, make sure the constant numeric value is second (right)
return listOf(IAstModification.SwapOperands(rExpr))
}
val rNum = (rExpr.right as? NumericLiteralValue)?.number
val rNum = (rExpr.right as? NumericLiteral)?.number
if(rNum!=null) {
if (op1 == "+" || op1 == "-") {
if (op2 == "+") {
// A = A +/- B + N
// A = A +/- B + N ---> A = A +/- B ; A = A + N
val expr2 = BinaryExpression(binExpr.left, binExpr.operator, rExpr.left, binExpr.position)
val addConstant = Assignment(
assignment.target,
BinaryExpression(binExpr.left, "+", rExpr.right, rExpr.position),
assignment.position
assignment.target.copy(),
BinaryExpression(binExpr.left.copy(), "+", rExpr.right, rExpr.position),
AssignmentOrigin.OPTIMIZER, assignment.position
)
return listOf(
IAstModification.ReplaceNode(binExpr, expr2, binExpr.parent),
IAstModification.InsertAfter(assignment, addConstant, assignment.definingScope))
IAstModification.InsertAfter(assignment, addConstant, parent as IStatementContainer))
} else if (op2 == "-") {
// A = A +/- B - N
// A = A +/- B - N ---> A = A +/- B ; A = A - N
val expr2 = BinaryExpression(binExpr.left, binExpr.operator, rExpr.left, binExpr.position)
val subConstant = Assignment(
assignment.target,
BinaryExpression(binExpr.left, "-", rExpr.right, rExpr.position),
assignment.position
assignment.target.copy(),
BinaryExpression(binExpr.left.copy(), "-", rExpr.right, rExpr.position),
AssignmentOrigin.OPTIMIZER, assignment.position
)
return listOf(
IAstModification.ReplaceNode(binExpr, expr2, binExpr.parent),
IAstModification.InsertAfter(assignment, subConstant, assignment.definingScope))
IAstModification.InsertAfter(assignment, subConstant, parent as IStatementContainer))
}
}
}
}
}
if(binExpr.operator in associativeOperators && binExpr.right isSameAs assignment.target) {
if(binExpr.operator in AssociativeOperators && binExpr.right isSameAs assignment.target) {
// associative operator, swap the operands so that the assignment target is first (left)
// unless the other operand is the same in which case we don't swap (endless loop!)
if (!(binExpr.left isSameAs binExpr.right))
@ -365,27 +367,39 @@ internal class StatementOptimizer(private val program: Program,
override fun after(assignment: Assignment, parent: Node): Iterable<IAstModification> {
if(assignment.target isSameAs assignment.value) {
// remove assignment to self
return listOf(IAstModification.Remove(assignment, assignment.definingScope))
return listOf(IAstModification.Remove(assignment, parent as IStatementContainer))
}
val targetIDt = assignment.target.inferType(program)
if(!targetIDt.isKnown)
throw FatalAstException("can't infer type of assignment target")
return noModifications
// optimize binary expressions a bit
val targetDt = targetIDt.getOr(DataType.UNDEFINED)
val bexpr=assignment.value as? BinaryExpression
if(bexpr!=null) {
val rightCv = bexpr.right.constValue(program)?.number?.toDouble()
val rightCv = bexpr.right.constValue(program)?.number
if(bexpr.operator=="-" && rightCv==null) {
if(bexpr.right isSameAs assignment.target) {
// X = value - X --> X = -X ; X += value (to avoid need of stack-evaluation)
val negation = PrefixExpression("-", bexpr.right.copy(), bexpr.position)
val addValue = Assignment(assignment.target.copy(), BinaryExpression(bexpr.right, "+", bexpr.left, bexpr.position), AssignmentOrigin.OPTIMIZER, assignment.position)
return listOf(
IAstModification.ReplaceNode(bexpr, negation, assignment),
IAstModification.InsertAfter(assignment, addValue, parent as IStatementContainer)
)
}
}
if (rightCv != null && assignment.target isSameAs bexpr.left) {
// assignments of the form: X = X <operator> <expr>
// remove assignments that have no effect (such as X=X+0)
// optimize/rewrite some other expressions
val targetDt = targetIDt.getOr(DataType.UNDEFINED)
val vardeclDt = (assignment.target.identifier?.targetVarDecl(program))?.type
when (bexpr.operator) {
"+" -> {
if (rightCv == 0.0) {
return listOf(IAstModification.Remove(assignment, assignment.definingScope))
return listOf(IAstModification.Remove(assignment, parent as IStatementContainer))
} else if (targetDt in IntegerDatatypes && floor(rightCv) == rightCv) {
if (vardeclDt != VarDeclType.MEMORY && rightCv in 1.0..4.0) {
// replace by several INCs if it's not a memory address (inc on a memory mapped register doesn't work very well)
@ -393,13 +407,13 @@ internal class StatementOptimizer(private val program: Program,
repeat(rightCv.toInt()) {
incs.statements.add(PostIncrDecr(assignment.target.copy(), "++", assignment.position))
}
return listOf(IAstModification.ReplaceNode(assignment, incs, parent))
listOf(IAstModification.ReplaceNode(assignment, if(incs.statements.size==1) incs.statements[0] else incs, parent))
}
}
}
"-" -> {
if (rightCv == 0.0) {
return listOf(IAstModification.Remove(assignment, assignment.definingScope))
return listOf(IAstModification.Remove(assignment, parent as IStatementContainer))
} else if (targetDt in IntegerDatatypes && floor(rightCv) == rightCv) {
if (vardeclDt != VarDeclType.MEMORY && rightCv in 1.0..4.0) {
// replace by several DECs if it's not a memory address (dec on a memory mapped register doesn't work very well)
@ -411,24 +425,46 @@ internal class StatementOptimizer(private val program: Program,
}
}
}
"*" -> if (rightCv == 1.0) return listOf(IAstModification.Remove(assignment, assignment.definingScope))
"/" -> if (rightCv == 1.0) return listOf(IAstModification.Remove(assignment, assignment.definingScope))
"**" -> if (rightCv == 1.0) return listOf(IAstModification.Remove(assignment, assignment.definingScope))
"|" -> if (rightCv == 0.0) return listOf(IAstModification.Remove(assignment, assignment.definingScope))
"^" -> if (rightCv == 0.0) return listOf(IAstModification.Remove(assignment, assignment.definingScope))
"*" -> if (rightCv == 1.0) return listOf(IAstModification.Remove(assignment, parent as IStatementContainer))
"/" -> if (rightCv == 1.0) return listOf(IAstModification.Remove(assignment, parent as IStatementContainer))
"**" -> if (rightCv == 1.0) return listOf(IAstModification.Remove(assignment, parent as IStatementContainer))
"|" -> if (rightCv == 0.0) return listOf(IAstModification.Remove(assignment, parent as IStatementContainer))
"^" -> if (rightCv == 0.0) return listOf(IAstModification.Remove(assignment, parent as IStatementContainer))
"<<" -> {
if (rightCv == 0.0)
return listOf(IAstModification.Remove(assignment, assignment.definingScope))
return listOf(IAstModification.Remove(assignment, parent as IStatementContainer))
}
">>" -> {
if (rightCv == 0.0)
return listOf(IAstModification.Remove(assignment, assignment.definingScope))
return listOf(IAstModification.Remove(assignment, parent as IStatementContainer))
}
}
}
}
// word = msb(word) , word=lsb(word)
if(assignment.target.inferType(program).isWords) {
var fcall = assignment.value as? FunctionCallExpression
if (fcall == null)
fcall = (assignment.value as? TypecastExpression)?.expression as? FunctionCallExpression
if (fcall != null && (fcall.target.nameInSource == listOf("lsb") || fcall.target.nameInSource == listOf("msb"))) {
if (fcall.args.single() isSameAs assignment.target) {
return if (fcall.target.nameInSource == listOf("lsb")) {
// optimize word=lsb(word) ==> word &= $00ff
val and255 = BinaryExpression(fcall.args[0], "&", NumericLiteral(DataType.UWORD, 255.0, fcall.position), fcall.position)
val newAssign = Assignment(assignment.target, and255, AssignmentOrigin.OPTIMIZER, fcall.position)
listOf(IAstModification.ReplaceNode(assignment, newAssign, parent))
} else {
// optimize word=msb(word) ==> word >>= 8
val shift8 = BinaryExpression(fcall.args[0], ">>", NumericLiteral(DataType.UBYTE, 8.0, fcall.position), fcall.position)
val newAssign = Assignment(assignment.target, shift8, AssignmentOrigin.OPTIMIZER, fcall.position)
listOf(IAstModification.ReplaceNode(assignment, newAssign, parent))
}
}
}
}
return noModifications
}
@ -438,55 +474,29 @@ internal class StatementOptimizer(private val program: Program,
val returnDt = subr.returntypes.single()
if (returnDt in IntegerDatatypes) {
// first assign to intermediary variable, then return that
subsThatNeedReturnVariable.add(Triple(subr, returnDt, returnStmt.position))
val returnValueIntermediary1 = IdentifierReference(listOf(retvarName), returnStmt.position)
val returnValueIntermediary2 = IdentifierReference(listOf(retvarName), returnStmt.position)
val tgt = AssignTarget(returnValueIntermediary1, null, null, returnStmt.position)
val assign = Assignment(tgt, value, returnStmt.position)
val returnReplacement = Return(returnValueIntermediary2, returnStmt.position)
val returnVarName = program.getTempVar(returnDt)
val returnValueIntermediary = IdentifierReference(returnVarName, returnStmt.position)
val tgt = AssignTarget(returnValueIntermediary, null, null, returnStmt.position)
val assign = Assignment(tgt, value, AssignmentOrigin.OPTIMIZER, returnStmt.position)
val returnReplacement = Return(returnValueIntermediary.copy(), returnStmt.position)
return listOf(
IAstModification.InsertBefore(returnStmt, assign, parent as INameScope),
IAstModification.InsertBefore(returnStmt, assign, parent as IStatementContainer),
IAstModification.ReplaceNode(returnStmt, returnReplacement, parent)
)
}
return null
}
when(returnStmt.value) {
is PrefixExpression -> {
val mod = returnViaIntermediaryVar(returnStmt.value!!)
// TODO decision when to use intermediary variable to calculate returnvalue seems a bit arbitrary...
val returnvalue = returnStmt.value
if (returnvalue!=null) {
if (returnvalue is BinaryExpression || (returnvalue is TypecastExpression && !returnvalue.expression.isSimple)) {
val mod = returnViaIntermediaryVar(returnvalue)
if(mod!=null)
return mod
}
is BinaryExpression -> {
val mod = returnViaIntermediaryVar(returnStmt.value!!)
if(mod!=null)
return mod
}
else -> {}
}
return super.after(returnStmt, parent)
}
private fun hasBreak(scope: INameScope): Boolean {
class Searcher: IAstVisitor
{
var count=0
override fun visit(breakStmt: Break) {
count++
return noModifications
}
}
val s=Searcher()
for(stmt in scope.statements) {
stmt.accept(s)
if(s.count>0)
return true
}
return s.count > 0
}
}

254
codeOptimizers/src/prog8/optimizer/UnusedCodeRemover.kt Normal file
View File

@ -0,0 +1,254 @@
package prog8.optimizer
import prog8.ast.*
import prog8.ast.base.DataType
import prog8.ast.base.VarDeclType
import prog8.ast.base.defaultZero
import prog8.ast.expressions.*
import prog8.ast.statements.*
import prog8.ast.walk.AstWalker
import prog8.ast.walk.IAstModification
import prog8.compilerinterface.CallGraph
import prog8.compilerinterface.ICompilationTarget
import prog8.compilerinterface.IErrorReporter
import prog8.compilerinterface.isIOAddress
class UnusedCodeRemover(private val program: Program,
private val errors: IErrorReporter,
private val compTarget: ICompilationTarget
): AstWalker() {
private val callgraph = CallGraph(program)
override fun before(module: Module, parent: Node): Iterable<IAstModification> {
return if (!module.isLibrary && (module.containsNoCodeNorVars || callgraph.unused(module)))
listOf(IAstModification.Remove(module, parent as IStatementContainer))
else
noModifications
}
override fun before(breakStmt: Break, parent: Node): Iterable<IAstModification> {
reportUnreachable(breakStmt)
return emptyList()
}
override fun before(jump: Jump, parent: Node): Iterable<IAstModification> {
reportUnreachable(jump)
return emptyList()
}
override fun before(returnStmt: Return, parent: Node): Iterable<IAstModification> {
reportUnreachable(returnStmt)
return emptyList()
}
override fun before(functionCallStatement: FunctionCallStatement, parent: Node): Iterable<IAstModification> {
if(functionCallStatement.target.nameInSource.last() == "exit")
reportUnreachable(functionCallStatement)
return emptyList()
}
private fun reportUnreachable(stmt: Statement) {
when(val next = stmt.nextSibling()) {
null, is Label, is Directive, is VarDecl, is InlineAssembly, is Subroutine -> {}
else -> errors.warn("unreachable code", next.position)
}
}
override fun after(scope: AnonymousScope, parent: Node): Iterable<IAstModification> {
return deduplicateAssignments(scope.statements, scope)
}
override fun after(block: Block, parent: Node): Iterable<IAstModification> {
if("force_output" !in block.options()) {
if (block.containsNoCodeNorVars) {
if(block.name != internedStringsModuleName)
errors.warn("removing unused block '${block.name}'", block.position)
return listOf(IAstModification.Remove(block, parent as IStatementContainer))
}
if(callgraph.unused(block)) {
if(block.statements.any{ it !is VarDecl || it.type==VarDeclType.VAR})
errors.warn("removing unused block '${block.name}'", block.position)
program.removeInternedStringsFromRemovedBlock(block)
return listOf(IAstModification.Remove(block, parent as IStatementContainer))
}
}
return deduplicateAssignments(block.statements, block)
}
override fun after(subroutine: Subroutine, parent: Node): Iterable<IAstModification> {
val forceOutput = "force_output" in subroutine.definingBlock.options()
if (subroutine !== program.entrypoint && !forceOutput && !subroutine.inline && !subroutine.isAsmSubroutine) {
if(callgraph.unused(subroutine)) {
if(subroutine.containsNoCodeNorVars) {
if(!subroutine.definingModule.isLibrary)
errors.warn("removing empty subroutine '${subroutine.name}'", subroutine.position)
val removals = mutableListOf(IAstModification.Remove(subroutine, parent as IStatementContainer))
callgraph.calledBy[subroutine]?.let {
for(node in it)
removals.add(IAstModification.Remove(node, node.parent as IStatementContainer))
}
return removals
}
if(!subroutine.definingModule.isLibrary)
errors.warn("removing unused subroutine '${subroutine.name}'", subroutine.position)
program.removeInternedStringsFromRemovedSubroutine(subroutine)
return listOf(IAstModification.Remove(subroutine, parent as IStatementContainer))
}
}
return deduplicateAssignments(subroutine.statements, subroutine)
}
override fun after(decl: VarDecl, parent: Node): Iterable<IAstModification> {
if(decl.type==VarDeclType.VAR) {
val block = decl.definingBlock
val forceOutput = "force_output" in block.options()
if (!forceOutput && decl.origin==VarDeclOrigin.USERCODE && !decl.sharedWithAsm) {
val usages = callgraph.usages(decl)
if (usages.isEmpty()) {
// if(!decl.definingModule.isLibrary)
errors.warn("removing unused variable '${decl.name}'", decl.position)
return listOf(IAstModification.Remove(decl, parent as IStatementContainer))
}
else {
if(usages.size==1) {
val singleUse = usages[0].parent
if(singleUse is AssignTarget) {
val assignment = singleUse.parent as Assignment
if(assignment.origin==AssignmentOrigin.VARINIT) {
if(!decl.definingModule.isLibrary)
errors.warn("removing unused variable '${decl.name}'", decl.position)
return listOf(
IAstModification.Remove(decl, parent as IStatementContainer),
IAstModification.Remove(assignment, assignment.parent as IStatementContainer)
)
}
}
}
}
}
}
return noModifications
}
private fun deduplicateAssignments(statements: List<Statement>, scope: IStatementContainer): List<IAstModification> {
// removes 'duplicate' assignments that assign the same target directly after another, unless it is a function call
val linesToRemove = mutableListOf<Assignment>()
val modifications = mutableListOf<IAstModification>()
fun substituteZeroInBinexpr(expr: BinaryExpression, zero: NumericLiteral, assign1: Assignment, assign2: Assignment) {
if(expr.left isSameAs assign2.target) {
// X = X <oper> Right
linesToRemove.add(assign1)
modifications.add(IAstModification.ReplaceNode(
expr.left, zero, expr
))
}
if(expr.right isSameAs assign2.target) {
// X = Left <oper> X
linesToRemove.add(assign1)
modifications.add(IAstModification.ReplaceNode(
expr.right, zero, expr
))
}
val leftBinExpr = expr.left as? BinaryExpression
val rightBinExpr = expr.right as? BinaryExpression
if(leftBinExpr!=null && rightBinExpr==null) {
if(leftBinExpr.left isSameAs assign2.target) {
// X = (X <oper> Right) <oper> Something
linesToRemove.add(assign1)
modifications.add(IAstModification.ReplaceNode(
leftBinExpr.left, zero, leftBinExpr
))
}
if(leftBinExpr.right isSameAs assign2.target) {
// X = (Left <oper> X) <oper> Something
linesToRemove.add(assign1)
modifications.add(IAstModification.ReplaceNode(
leftBinExpr.right, zero, leftBinExpr
))
}
}
if(leftBinExpr==null && rightBinExpr!=null) {
if(rightBinExpr.left isSameAs assign2.target) {
// X = Something <oper> (X <oper> Right)
linesToRemove.add(assign1)
modifications.add(IAstModification.ReplaceNode(
rightBinExpr.left, zero, rightBinExpr
))
}
if(rightBinExpr.right isSameAs assign2.target) {
// X = Something <oper> (Left <oper> X)
linesToRemove.add(assign1)
modifications.add(IAstModification.ReplaceNode(
rightBinExpr.right, zero, rightBinExpr
))
}
}
}
fun substituteZeroInPrefixexpr(expr: PrefixExpression, zero: NumericLiteral, assign1: Assignment, assign2: Assignment) {
if(expr.expression isSameAs assign2.target) {
linesToRemove.add(assign1)
modifications.add(IAstModification.ReplaceNode(
expr.expression, zero, expr
))
}
}
fun substituteZeroInTypecast(expr: TypecastExpression, zero: NumericLiteral, assign1: Assignment, assign2: Assignment) {
if(expr.expression isSameAs assign2.target) {
linesToRemove.add(assign1)
modifications.add(IAstModification.ReplaceNode(
expr.expression, zero, expr
))
}
val subCast = expr.expression as? TypecastExpression
if(subCast!=null && subCast.expression isSameAs assign2.target) {
linesToRemove.add(assign1)
modifications.add(IAstModification.ReplaceNode(
subCast.expression, zero, subCast
))
}
}
for (stmtPairs in statements.windowed(2, step = 1)) {
val assign1 = stmtPairs[0] as? Assignment
val assign2 = stmtPairs[1] as? Assignment
if (assign1 != null && assign2 != null) {
val cvalue1 = assign1.value.constValue(program)
if(cvalue1!=null && cvalue1.number==0.0 && assign2.target.isSameAs(assign1.target, program) && assign2.isAugmentable) {
val value2 = assign2.value
val zero = defaultZero(value2.inferType(program).getOr(DataType.UNDEFINED), value2.position)
when(value2) {
is BinaryExpression -> substituteZeroInBinexpr(value2, zero, assign1, assign2)
is PrefixExpression -> substituteZeroInPrefixexpr(value2, zero, assign1, assign2)
is TypecastExpression -> substituteZeroInTypecast(value2, zero, assign1, assign2)
else -> {}
}
} else {
if (assign1.target.isSameAs(assign2.target, program) && !assign1.target.isIOAddress(compTarget.machine)) {
if(assign2.target.identifier==null || !assign2.value.referencesIdentifier(assign2.target.identifier!!.nameInSource))
// only remove the second assignment if its value is a simple expression!
when(assign2.value) {
is PrefixExpression,
is BinaryExpression,
is TypecastExpression,
is FunctionCallExpression -> { /* don't remove */ }
else -> {
if(assign1.value !is IFunctionCall)
linesToRemove.add(assign1)
}
}
}
}
}
}
return modifications + linesToRemove.map { IAstModification.Remove(it, scope) }
}
}

56
compiler/build.gradle
View File

@ -3,31 +3,43 @@ plugins {
id 'application'
id "org.jetbrains.kotlin.jvm"
id 'com.github.johnrengelman.shadow' version '7.1.0'
id "io.kotest" version "0.3.8"
}
targetCompatibility = 11
sourceCompatibility = 11
java {
toolchain {
languageVersion = JavaLanguageVersion.of(javaVersion)
}
}
compileKotlin {
kotlinOptions {
jvmTarget = javaVersion
}
}
repositories {
mavenLocal()
mavenCentral()
maven { url "https://kotlin.bintray.com/kotlinx" }
compileTestKotlin {
kotlinOptions {
jvmTarget = javaVersion
}
}
def prog8version = rootProject.file('compiler/res/version.txt').text.trim()
dependencies {
implementation project(':compilerInterfaces')
implementation project(':codeOptimizers')
implementation project(':compilerAst')
implementation project(':codeGenTargets')
implementation project(':codeGenCpu6502')
implementation project(':codeGenExperimental6502')
implementation 'org.antlr:antlr4-runtime:4.9.2'
implementation "org.jetbrains.kotlin:kotlin-stdlib-jdk8"
// implementation "org.jetbrains.kotlin:kotlin-reflect"
implementation 'org.jetbrains.kotlinx:kotlinx-cli:0.3.3'
implementation "com.michael-bull.kotlin-result:kotlin-result-jvm:1.1.12"
testImplementation "org.jetbrains.kotlin:kotlin-test-junit5"
testImplementation 'org.junit.jupiter:junit-jupiter-api:5.7.2'
testImplementation 'org.hamcrest:hamcrest:2.2'
testRuntimeOnly 'org.junit.jupiter:junit-jupiter-engine:5.7.2'
testImplementation 'io.kotest:kotest-runner-junit5-jvm:4.6.3'
}
configurations.all {
@ -43,23 +55,6 @@ configurations {
}
}
compileKotlin {
kotlinOptions {
jvmTarget = "11"
useIR = true
// verbose = true
// freeCompilerArgs += "-XXLanguage:+NewInference"
}
}
compileTestKotlin {
kotlinOptions {
jvmTarget = "11"
useIR = true
}
}
sourceSets {
main {
java {
@ -84,11 +79,6 @@ application {
applicationName = 'p8compile'
}
artifacts {
archives shadowJar
}
shadowJar {
archiveBaseName = 'prog8compiler'
archiveVersion = prog8version
@ -108,3 +98,5 @@ test {
events "skipped", "failed"
}
}
build.finalizedBy installDist, installShadowDist

18
compiler/compiler.iml
View File

@ -1,10 +1,5 @@
<?xml version="1.0" encoding="UTF-8"?>
<module type="JAVA_MODULE" version="4">
<component name="FacetManager">
<facet type="Python" name="Python">
<configuration sdkName="Python 3.9" />
</facet>
</component>
<component name="NewModuleRootManager" inherit-compiler-output="true">
<exclude-output />
<content url="file://$MODULE_DIR$">
@ -13,14 +8,19 @@
<sourceFolder url="file://$MODULE_DIR$/test" isTestSource="true" />
<excludeFolder url="file://$MODULE_DIR$/build" />
</content>
<orderEntry type="jdk" jdkName="openjdk-11" jdkType="JavaSDK" />
<orderEntry type="inheritedJdk" />
<orderEntry type="sourceFolder" forTests="false" />
<orderEntry type="library" name="KotlinJavaRuntime" level="project" />
<orderEntry type="module" module-name="compilerAst" />
<orderEntry type="library" name="Python 3.9 interpreter library" level="application" />
<orderEntry type="library" name="hamcrest" level="project" />
<orderEntry type="library" name="jetbrains.kotlinx.cli.jvm" level="project" />
<orderEntry type="library" name="junit.jupiter" level="project" />
<orderEntry type="library" name="michael.bull.kotlin.result.jvm" level="project" />
<orderEntry type="module" module-name="codeOptimizers" />
<orderEntry type="module" module-name="compilerInterfaces" />
<orderEntry type="module" module-name="codeGenTargets" />
<orderEntry type="library" name="io.kotest.assertions.core.jvm" level="project" />
<orderEntry type="library" name="io.kotest.runner.junit5.jvm" level="project" />
<orderEntry type="library" name="antlr.antlr4" level="project" />
<orderEntry type="module" module-name="codeGenCpu6502" />
<orderEntry type="module" module-name="codeGenExperimental6502" />
</component>
</module>

683
compiler/res/prog8lib/c128/floats.asm Normal file
View File

@ -0,0 +1,683 @@
; --- low level floating point assembly routines for the C128
; these are almost all identical to the C64 except for a few details
; so we have to have a separate library file for the C128 unfortunately.
FL_ONE_const .byte 129 ; 1.0
FL_ZERO_const .byte 0,0,0,0,0 ; 0.0
FL_LOG2_const .byte $80, $31, $72, $17, $f8 ; log(2)
floats_store_reg .byte 0 ; temp storage
ub2float .proc
; -- convert ubyte in SCRATCH_ZPB1 to float at address A/Y
; clobbers A, Y
stx P8ZP_SCRATCH_REG
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
rts
.pend
b2float .proc
; -- convert byte in SCRATCH_ZPB1 to float at address A/Y
; clobbers A, Y
stx P8ZP_SCRATCH_REG
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
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
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
cast_from_uw .proc
; -- uword in A/Y into float var at (P8ZP_SCRATCH_W2)
stx P8ZP_SCRATCH_REG
jsr GIVUAYFAY
jmp ub2float._fac_to_mem
.pend
cast_from_w .proc
; -- word in A/Y into float var at (P8ZP_SCRATCH_W2)
stx P8ZP_SCRATCH_REG
jsr GIVAYFAY
jmp ub2float._fac_to_mem
.pend
cast_from_ub .proc
; -- ubyte in Y into float var at (P8ZP_SCRATCH_W2)
stx P8ZP_SCRATCH_REG
jsr FREADUY
jmp ub2float._fac_to_mem
.pend
cast_from_b .proc
; -- byte in A into float var at (P8ZP_SCRATCH_W2)
stx P8ZP_SCRATCH_REG
jsr FREADSA
jmp ub2float._fac_to_mem
.pend
cast_as_uw_into_ya .proc ; also used for float 2 ub
; -- cast float at A/Y to uword into Y/A
jsr MOVFM
jmp cast_FAC1_as_uw_into_ya
.pend
cast_as_w_into_ay .proc ; also used for float 2 b
; -- cast float at A/Y to word into A/Y
jsr MOVFM
jmp cast_FAC1_as_w_into_ay
.pend
cast_FAC1_as_uw_into_ya .proc ; also used for float 2 ub
; -- cast fac1 to uword into Y/A
stx P8ZP_SCRATCH_REG
jsr GETADR ; into Y/A
ldx P8ZP_SCRATCH_REG
rts
.pend
cast_FAC1_as_w_into_ay .proc ; also used for float 2 b
; -- cast fac1 to word into A/Y
stx P8ZP_SCRATCH_REG
jsr AYINT
ldy $66
lda $67
ldx P8ZP_SCRATCH_REG
rts
.pend
stack_b2float .proc
; -- b2float operating on the stack
inx
lda P8ESTACK_LO,x
stx P8ZP_SCRATCH_REG
jsr FREADSA
jmp push_fac1._internal
.pend
stack_w2float .proc
; -- w2float operating on the stack
inx
ldy P8ESTACK_LO,x
lda P8ESTACK_HI,x
stx P8ZP_SCRATCH_REG
jsr GIVAYF
jmp push_fac1._internal
.pend
stack_ub2float .proc
; -- ub2float operating on the stack
inx
lda P8ESTACK_LO,x
stx P8ZP_SCRATCH_REG
tay
lda #0
jsr GIVAYF
jmp push_fac1._internal
.pend
stack_uw2float .proc
; -- uw2float operating on the stack
inx
lda P8ESTACK_LO,x
ldy P8ESTACK_HI,x
stx P8ZP_SCRATCH_REG
jsr GIVUAYFAY
jmp push_fac1._internal
.pend
stack_float2w .proc ; also used for float2b
jsr pop_float_fac1
stx P8ZP_SCRATCH_REG
jsr AYINT
ldx P8ZP_SCRATCH_REG
lda $66
sta P8ESTACK_HI,x
lda $67
sta P8ESTACK_LO,x
dex
rts
.pend
stack_float2uw .proc ; also used for float2ub
jsr pop_float_fac1
stx P8ZP_SCRATCH_REG
jsr GETADR
ldx P8ZP_SCRATCH_REG
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
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
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
jsr MOVFM
lda #<FL_ONE_const
ldy #>FL_ONE_const
jsr FADD
ldx P8ZP_SCRATCH_W1
ldy P8ZP_SCRATCH_W1+1
jsr MOVMF
ldx P8ZP_SCRATCH_REG
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
lda #<FL_ONE_const
ldy #>FL_ONE_const
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
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 .proc
; -- push the float in FAC1 onto the stack
stx P8ZP_SCRATCH_REG
_internal ldx #<fmath_float1
ldy #>fmath_float1
jsr MOVMF
lda #<fmath_float1
ldy #>fmath_float1
ldx P8ZP_SCRATCH_REG
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
lda #<fmath_float1
ldy #>fmath_float1
jsr ROMUPK ; fac2 = float1
lda #<fmath_float2
ldy #>fmath_float2
jsr FPWR
jmp push_fac1._internal
.pend
div_f .proc
; -- push f1/f2 on stack
jsr pop_2_floats_f2_in_fac1
stx P8ZP_SCRATCH_REG
lda #<fmath_float1
ldy #>fmath_float1
jsr FDIV
jmp push_fac1._internal
.pend
add_f .proc
; -- push f1+f2 on stack
jsr pop_2_floats_f2_in_fac1
stx P8ZP_SCRATCH_REG
lda #<fmath_float1
ldy #>fmath_float1
jsr FADD
jmp push_fac1._internal
.pend
sub_f .proc
; -- push f1-f2 on stack
jsr pop_2_floats_f2_in_fac1
stx P8ZP_SCRATCH_REG
lda #<fmath_float1
ldy #>fmath_float1
jsr FSUB
jmp push_fac1._internal
.pend
mul_f .proc
; -- push f1*f2 on stack
jsr pop_2_floats_f2_in_fac1
stx P8ZP_SCRATCH_REG
lda #<fmath_float1
ldy #>fmath_float1
jsr FMULT
jmp push_fac1._internal
.pend
neg_f .proc
; -- toggle the sign bit on the stack
lda P8ESTACK_HI+3,x
eor #$80
sta P8ESTACK_HI+3,x
rts
.pend
var_fac1_less_f .proc
; -- is the float in FAC1 < the variable AY?
stx P8ZP_SCRATCH_REG
jsr FCOMP
ldx P8ZP_SCRATCH_REG
cmp #255
beq +
lda #0
rts
+ lda #1
rts
.pend
var_fac1_lesseq_f .proc
; -- is the float in FAC1 <= the variable AY?
stx P8ZP_SCRATCH_REG
jsr FCOMP
ldx P8ZP_SCRATCH_REG
cmp #0
beq +
cmp #255
beq +
lda #0
rts
+ lda #1
rts
.pend
var_fac1_greater_f .proc
; -- is the float in FAC1 > the variable AY?
stx P8ZP_SCRATCH_REG
jsr FCOMP
ldx P8ZP_SCRATCH_REG
cmp #1
beq +
lda #0
rts
+ lda #1
rts
.pend
var_fac1_greatereq_f .proc
; -- is the float in FAC1 >= the variable AY?
stx P8ZP_SCRATCH_REG
jsr FCOMP
ldx P8ZP_SCRATCH_REG
cmp #0
beq +
cmp #1
beq +
lda #0
rts
+ lda #1
rts
.pend
var_fac1_notequal_f .proc
; -- are the floats numbers in FAC1 and the variable AY *not* identical?
stx P8ZP_SCRATCH_REG
jsr FCOMP
ldx P8ZP_SCRATCH_REG
and #1
rts
.pend
vars_equal_f .proc
; -- are the mflpt5 numbers in P8ZP_SCRATCH_W1 and AY identical?
sta P8ZP_SCRATCH_W2
sty P8ZP_SCRATCH_W2+1
ldy #0
lda (P8ZP_SCRATCH_W1),y
cmp (P8ZP_SCRATCH_W2),y
bne _false
iny
lda (P8ZP_SCRATCH_W1),y
cmp (P8ZP_SCRATCH_W2),y
bne _false
iny
lda (P8ZP_SCRATCH_W1),y
cmp (P8ZP_SCRATCH_W2),y
bne _false
iny
lda (P8ZP_SCRATCH_W1),y
cmp (P8ZP_SCRATCH_W2),y
bne _false
iny
lda (P8ZP_SCRATCH_W1),y
cmp (P8ZP_SCRATCH_W2),y
bne _false
lda #1
rts
_false lda #0
rts
.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
vars_less_f .proc
; -- is float in AY < float in P8ZP_SCRATCH_W2 ?
jsr MOVFM
lda P8ZP_SCRATCH_W2
ldy P8ZP_SCRATCH_W2+1
stx P8ZP_SCRATCH_REG
jsr FCOMP
ldx P8ZP_SCRATCH_REG
cmp #255
bne +
lda #1
rts
+ lda #0
rts
.pend
vars_lesseq_f .proc
; -- is float in AY <= float in P8ZP_SCRATCH_W2 ?
jsr MOVFM
lda P8ZP_SCRATCH_W2
ldy P8ZP_SCRATCH_W2+1
stx P8ZP_SCRATCH_REG
jsr FCOMP
ldx P8ZP_SCRATCH_REG
cmp #255
bne +
- lda #1
rts
+ cmp #0
beq -
lda #0
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
set_array_float_from_fac1 .proc
; -- set the float in FAC1 in the array (index in A, array in P8ZP_SCRATCH_W1)
sta P8ZP_SCRATCH_B1
asl a
asl a
clc
adc P8ZP_SCRATCH_B1
ldy P8ZP_SCRATCH_W1+1
clc
adc P8ZP_SCRATCH_W1
bcc +
iny
+ stx floats_store_reg
tax
jsr MOVMF
ldx floats_store_reg
rts
.pend
set_0_array_float .proc
; -- set a float in an array to zero (index in A, array in P8ZP_SCRATCH_W1)
sta P8ZP_SCRATCH_B1
asl a
asl a
clc
adc P8ZP_SCRATCH_B1
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 in A, float in P8ZP_SCRATCH_W1, array in P8ZP_SCRATCH_W2)
sta P8ZP_SCRATCH_B1
asl a
asl a
clc
adc P8ZP_SCRATCH_B1
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

157
compiler/res/prog8lib/c128/floats.p8 Normal file
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; Prog8 definitions for floating point handling on the Commodore 128
;
; Written by Irmen de Jong (irmen@razorvine.net) - license: GNU GPL 3.0
%option enable_floats
floats {
; ---- this block contains C-128 compatible floating point related functions ----
const float PI = 3.141592653589793
const float TWOPI = 6.283185307179586
; ---- 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 $af00 = AYINT() clobbers(A,X,Y) ; fac1-> signed word in 102-103 ($66-$67) MSB FIRST. (might throw ILLEGAL QUANTITY)
; GIVAYF: signed word in Y/A (note different lsb/msb order) -> float in fac1
; there is also floats.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 $af03 = GIVAYF(ubyte lo @ Y, ubyte hi @ A) clobbers(A,X,Y)
romsub $af09 = VAL(ubyte length @ A) clobbers(A,X,Y) ; str -> fac1, $24/25 must point to string in bank1, A=string length Don't call this from bank0
; fac1 -> unsigned word in Y/A (might throw ILLEGAL QUANTITY) (result also in $16/17)
; (tip: use GETADRAY to get A/Y output; lo/hi switched to normal little endian order)
romsub $af0c = GETADR() clobbers(X) -> ubyte @ Y, ubyte @ A
romsub $af12 = FSUB(uword mflpt @ AY) clobbers(A,X,Y) ; fac1 = mflpt from A/Y - fac1
romsub $af15 = FSUBT() clobbers(A,X,Y) ; fac1 = fac2-fac1 mind the order of the operands
romsub $af18 = FADD(uword mflpt @ AY) clobbers(A,X,Y) ; fac1 += mflpt value from A/Y in bank 1
romsub $af1b = FADDT() clobbers(A,X,Y) ; fac1 += fac2
romsub $af2a = LOG() clobbers(A,X,Y) ; fac1 = LN(fac1) (natural log)
romsub $af1e = FMULT(uword mflpt @ AY) clobbers(A,X,Y) ; fac1 *= mflpt value from A/Y
romsub $af21 = FMULTT() clobbers(A,X,Y) ; fac1 *= fac2
romsub $af5a = CONUPK(uword mflpt @ AY) clobbers(A,X,Y) ; load mflpt value from memory bank 1 in A/Y into fac2
romsub $af5d = ROMUPK(uword mflpt @ AY) clobbers(A,X,Y) ; load mflpt value from memory in current bank in A/Y into fac2
romsub $af24 = FDIV(uword mflpt @ AY) clobbers(A,X,Y) ; fac1 = mflpt in A/Y / fac1 (remainder in fac2)
romsub $af27 = FDIVT() clobbers(A,X,Y) ; fac1 = fac2/fac1 (remainder in fac2) mind the order of the operands
romsub $af63 = MOVFM(uword mflpt @ AY) clobbers(A,X,Y) ; load mflpt value from memory in A/Y into fac1
romsub $af60 = MOVFRM() clobbers(A,X,Y) ; load mflpt value from memory in $24/$25 into fac2
romsub $af66 = MOVMF(uword mflpt @ XY) clobbers(A,X,Y) ; store fac1 to memory X/Y as 5-byte mflpt
romsub $af69 = MOVFA() clobbers(A,X) ; copy fac2 to fac1
romsub $af6c = MOVAF() clobbers(A,X) ; copy fac1 to fac2
romsub $af6c = MOVEF() clobbers(A,X) ; copy fac1 to fac2
romsub $af51 = SIGN() clobbers(X,Y) -> ubyte @ A ; SIGN(fac1) to A, $ff, $0, $1 for negative, zero, positive
romsub $af4e = ABS() clobbers(A,X,Y) ; fac1 = ABS(fac1)
romsub $af54 = FCOMP(uword mflpt @ AY) clobbers(X,Y) -> ubyte @ A ; A = compare fac1 to mflpt in A/Y, 0=equal 1=fac1 is greater, 255=fac1 is less than
romsub $af2d = INT() clobbers(A,X,Y) ; INT() truncates, use FADDH first to round instead of trunc
romsub $af06 = FOUT() clobbers(X) -> uword @ AY ; fac1 -> string, address returned in AY ($0100)
romsub $af30 = SQR() clobbers(A,X,Y) ; fac1 = SQRT(fac1)
romsub $af36 = FPWR(uword mflpt @ AY) clobbers(A,X,Y) ; fac1 = fac2 ** mflpt from A/Y
romsub $af39 = FPWRT() clobbers(A,X,Y) ; fac1 = fac2 ** fac1
romsub $af33 = NEGOP() clobbers(A) ; switch the sign of fac1 (fac1 = -fac1)
romsub $af3c = EXP() clobbers(A,X,Y) ; fac1 = EXP(fac1) (e ** fac1)
romsub $af57 = RND() clobbers(A,X,Y) ; fac1 = RND(fac1) float random number generator
romsub $af3f = COS() clobbers(A,X,Y) ; fac1 = COS(fac1)
romsub $af42 = SIN() clobbers(A,X,Y) ; fac1 = SIN(fac1)
romsub $af45 = TAN() clobbers(A,X,Y) ; fac1 = TAN(fac1)
romsub $af48 = ATN() clobbers(A,X,Y) ; fac1 = ATN(fac1)
asmsub FREADSA (byte value @A) clobbers(A,X,Y) {
; ---- 8 bit signed A -> float in fac1
%asm {{
tay
bpl +
lda #$ff
jmp GIVAYF
+ lda #0
jmp GIVAYF
}}
}
asmsub GIVUAYFAY (uword value @ AY) clobbers(A,X,Y) {
; ---- unsigned 16 bit word in A/Y (lo/hi) to fac1
%asm {{
stx P8ZP_SCRATCH_REG
sta _tmp
sty P8ZP_SCRATCH_B1
tya
ldy _tmp
jsr GIVAYF ; load it as signed... correct afterwards
lda P8ZP_SCRATCH_B1
bpl +
lda #<_flt65536
ldy #>_flt65536
jsr ROMUPK
jsr FADDT
+ ldx P8ZP_SCRATCH_REG
rts
_tmp .byte 0
_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_B1
tya
ldy P8ZP_SCRATCH_B1
jmp GIVAYF ; this uses the inverse order, Y/A
}}
}
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
}}
}
asmsub FREADUY (ubyte value @Y) {
; -- 8 bit unsigned Y -> float in fac1
%asm {{
lda #0
jmp GIVAYF
}}
}
sub print_f (float value) {
; ---- prints the floating point value (without a newline).
%asm {{
stx P8ZP_SCRATCH_REG
lda #<value
ldy #>value
jsr MOVFM ; load float into fac1
jsr FOUT ; fac1 to string in A/Y
sta P8ZP_SCRATCH_W1
sty P8ZP_SCRATCH_W1+1
ldy #0
- lda (P8ZP_SCRATCH_W1),y
beq +
jsr c64.CHROUT
iny
bne -
+ ldx P8ZP_SCRATCH_REG
rts
}}
}
%asminclude "library:c128/floats.asm"
%asminclude "library:c64/floats_funcs.asm"
}

60
compiler/res/prog8lib/c128/graphics.p8 Normal file
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%import syslib
%import textio
; Bitmap pixel graphics module for the Commodore 128
; TODO c128 actually implement the graphics routines. Ideally a way to 'borrow' the code form the C64 version without just copy-pasting that here?
graphics {
const uword WIDTH = 320
const ubyte HEIGHT = 200
sub enable_bitmap_mode() {
; enable bitmap screen, erase it and set colors to black/white.
; TODO
}
sub disable_bitmap_mode() {
; enables text mode, erase the text screen, color white
; TODO
}
sub clear_screen(ubyte pixelcolor, ubyte bgcolor) {
; TODO
}
sub line(uword @zp x1, ubyte @zp y1, uword @zp x2, ubyte @zp y2) {
; TODO
}
sub fillrect(uword x, uword y, uword width, uword height) {
; TODO
}
sub rect(uword x, uword y, uword width, uword height) {
; TODO
}
sub horizontal_line(uword x, uword y, uword length) {
; TODO
}
sub vertical_line(uword x, uword y, uword height) {
; TODO
}
sub circle(uword xcenter, ubyte ycenter, ubyte radius) {
; TODO
}
sub disc(uword xcenter, ubyte ycenter, ubyte radius) {
; TODO
}
inline asmsub plot(uword plotx @R0, uword ploty @R1) clobbers(A, X, Y) {
%asm {{
nop ; TODO
}}
}
}

797
compiler/res/prog8lib/c128/syslib.p8 Normal file
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; Prog8 definitions for the Commodore-128
; Including memory registers, I/O registers, Basic and Kernal subroutines.
;
; Written by Irmen de Jong (irmen@razorvine.net) - license: GNU GPL 3.0
;
c64 {
&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 STATUS = $90 ; kernal status variable for I/O
&ubyte STKEY = $91 ; various keyboard statuses (updated by IRQ)
;;&ubyte SFDX = $cb ; current key pressed (matrix value) (updated by IRQ) // TODO c128 ??
&ubyte COLOR = $00f1 ; cursor color
;;&ubyte HIBASE = $0288 ; screen base address / 256 (hi-byte of screen memory address) // TODO c128 ??
&uword CINV = $0314 ; IRQ vector (in ram)
&uword CBINV = $0316 ; BRK vector (in ram)
&uword NMINV = $0318 ; NMI vector (in ram)
&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.
; ---- 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 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
; ---- 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 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
; ---- end of SID registers ----
; ---- kernal routines, these are the same as on the Commodore-64 (hence the same block name) ----
; STROUT --> use txt.print
; CLEARSCR -> use txt.clear_screen
; HOMECRSR -> use txt.home or txt.plot
romsub $FA65 = IRQDFRT() clobbers(A,X,Y) ; default IRQ routine
romsub $FF33 = IRQDFEND() clobbers(A,X,Y) ; default IRQ end/cleanup
; TODO c128 a bunch of kernal routines are missing here that are specific to the c128
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 secondary @ Y) ; set logical file parameters
romsub $FFBD = SETNAM(ubyte namelen @ A, str filename @ XY) ; set filename parameters
romsub $FFC0 = OPEN() clobbers(X,Y) -> ubyte @Pc, ubyte @A ; (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) -> ubyte @Pc ; (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(X, 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, uword @ XY ; (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 (A=lo,X=mid,Y=high)
romsub $FFE1 = STOP() clobbers(X) -> ubyte @ Pz, ubyte @ A ; (via 808 ($328)) check the STOP key (and some others in A)
romsub $FFE4 = GETIN() clobbers(X,Y) -> ubyte @Pc, 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 txt.plot for a 'safe' wrapper that preserves X.
romsub $FFF3 = IOBASE() -> uword @ XY ; read base address of I/O devices
; ---- end of C64 compatible ROM kernal routines ----
; ---- utilities -----
asmsub STOP2() -> ubyte @A {
; -- check if STOP key was pressed, returns true if so. More convenient to use than STOP() because that only sets the carry status flag.
%asm {{
txa
pha
jsr c64.STOP
beq +
pla
tax
lda #0
rts
+ pla
tax
lda #1
rts
}}
}
asmsub RDTIM16() -> uword @AY {
; -- like RDTIM() but only returning the lower 16 bits in AY for convenience
%asm {{
stx P8ZP_SCRATCH_REG
jsr c64.RDTIM
pha
txa
tay
pla
ldx P8ZP_SCRATCH_REG
rts
}}
}
; ---- system utility routines that are essentially the same as on the C64: -----
asmsub disable_runstop_and_charsetswitch() clobbers(A) {
%asm {{
lda #$80
sta 247 ; disable charset switching
lda #112
sta 808 ; disable run/stop key
rts
}}
}
asmsub set_irq(uword handler @AY, ubyte useKernal @Pc) clobbers(A) {
%asm {{
sta _modified+1
sty _modified+2
lda #0
adc #0
sta _use_kernal
sei
lda #<_irq_handler
sta c64.CINV
lda #>_irq_handler
sta c64.CINV+1
cli
rts
_irq_handler jsr _irq_handler_init
_modified jsr $ffff ; modified
jsr _irq_handler_end
lda _use_kernal
bne +
lda #$ff
sta c64.VICIRQ ; acknowledge raster irq
lda c64.CIA1ICR ; acknowledge CIA1 interrupt
; end irq processing - don't use kernal's irq handling
pla
tay
pla
tax
pla
rti
+ jmp c64.IRQDFRT ; continue with normal kernal irq routine
_use_kernal .byte 0
_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_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_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_ZPWORD1 .word 0
IRQ_SCRATCH_ZPWORD2 .word 0
}}
}
asmsub restore_irq() clobbers(A) {
%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 handler @AY, uword rasterpos @R0, ubyte useKernal @Pc) clobbers(A) {
%asm {{
sta _modified+1
sty _modified+2
lda #0
adc #0
sta set_irq._use_kernal
lda cx16.r0
ldy cx16.r0+1
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_irq._irq_handler_init
_modified jsr $ffff ; modified
jsr set_irq._irq_handler_end
lda #$ff
sta c64.VICIRQ ; acknowledge raster irq
lda set_irq._use_kernal
bne +
; end irq processing - don't use kernal's irq handling
pla
tay
pla
tax
pla
rti
+ jmp c64.IRQDFRT ; continue with kernal irq routine
_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
}}
}
}
c128 {
; ---- C128 specific registers ----
&ubyte VM1 = $0A2C ; shadow for VUC $d018 in text mode
&ubyte VM2 = $0A2D ; shadow for VIC $d018 in bitmap screen mode
&ubyte VM3 = $0A2E ; starting page for VDC screen mem
&ubyte VM4 = $0A2F ; starting page for VDC attribute mem
; ---- C128 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 ; TODO c128 ram and rom bank selection how?
;;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
jsr c64.disable_runstop_and_charsetswitch
clc
clv
cli
rts
}}
}
asmsub init_system_phase2() {
%asm {{
rts ; no phase 2 steps on the C128
}}
}
asmsub disable_basic() clobbers(A) {
%asm {{
lda $0a04 ; disable BASIC shadow registers
and #$fe
sta $0a04
lda #$01 ; disable BASIC IRQ service routine
sta $12fd
lda #$ff ; disable screen editor IRQ setup
sta $d8
lda #$b7 ; skip programmable function key check
sta $033c
lda #$0e ; bank out BASIC ROM
sta $ff00
rts
}}
}
; ---- end of C128 specific system utility routines ----
}
sys {
; ------- lowlevel system routines --------
const ubyte target = 128 ; compilation target specifier. 64 = C64, 128 = C128, 16 = CommanderX16.
asmsub reset_system() {
; Soft-reset the system back to initial power-on Basic prompt.
%asm {{
sei
;lda #14
;sta $01 ; bank the kernal in TODO c128 how to do this?
jmp (c64.RESET_VEC)
}}
}
sub wait(uword jiffies) {
; --- wait approximately the given number of jiffies (1/60th seconds)
; note: the system irq handler has to be active for this to work as it depends on the system jiffy clock
repeat jiffies {
ubyte jiff = lsb(c64.RDTIM16())
while jiff==lsb(c64.RDTIM16()) {
; wait until 1 jiffy has passed
}
}
}
asmsub waitvsync() clobbers(A) {
; --- busy wait till the next vsync has occurred (approximately), without depending on custom irq handling.
; note: a more accurate way to wait for vsync is to set up a vsync irq handler instead.
%asm {{
- bit c64.SCROLY
bpl -
- bit c64.SCROLY
bmi -
rts
}}
}
inline asmsub waitrastborder() {
; --- busy wait till the raster position has reached the bottom screen border (approximately)
; note: a more accurate way to do this is by using a raster irq handler instead.
%asm {{
- bit c64.SCROLY
bpl -
}}
}
asmsub memcopy(uword source @R0, uword target @R1, uword count @AY) clobbers(A,X,Y) {
; note: can't be inlined because is called from asm as well
%asm {{
ldx cx16.r0
stx P8ZP_SCRATCH_W1 ; source in ZP
ldx cx16.r0+1
stx P8ZP_SCRATCH_W1+1
ldx cx16.r1
stx P8ZP_SCRATCH_W2 ; target in ZP
ldx cx16.r1+1
stx P8ZP_SCRATCH_W2+1
cpy #0
bne _longcopy
; copy <= 255 bytes
tay
bne _copyshort
rts ; nothing to copy
_copyshort
; decrease source and target pointers so we can simply index by Y
lda P8ZP_SCRATCH_W1
bne +
dec P8ZP_SCRATCH_W1+1
+ dec P8ZP_SCRATCH_W1
lda P8ZP_SCRATCH_W2
bne +
dec P8ZP_SCRATCH_W2+1
+ dec P8ZP_SCRATCH_W2
- lda (P8ZP_SCRATCH_W1),y
sta (P8ZP_SCRATCH_W2),y
dey
bne -
rts
_longcopy
sta P8ZP_SCRATCH_B1 ; lsb(count) = remainder in last page
tya
tax ; x = num pages (1+)
ldy #0
- lda (P8ZP_SCRATCH_W1),y
sta (P8ZP_SCRATCH_W2),y
iny
bne -
inc P8ZP_SCRATCH_W1+1
inc P8ZP_SCRATCH_W2+1
dex
bne -
ldy P8ZP_SCRATCH_B1
bne _copyshort
rts
}}
}
asmsub memset(uword mem @R0, uword numbytes @R1, ubyte value @A) clobbers(A,X,Y) {
%asm {{
ldy cx16.r0
sty P8ZP_SCRATCH_W1
ldy cx16.r0+1
sty P8ZP_SCRATCH_W1+1
ldx cx16.r1
ldy cx16.r1+1
jmp prog8_lib.memset
}}
}
asmsub memsetw(uword mem @R0, uword numwords @R1, uword value @AY) clobbers(A,X,Y) {
%asm {{
ldx cx16.r0
stx P8ZP_SCRATCH_W1
ldx cx16.r0+1
stx P8ZP_SCRATCH_W1+1
ldx cx16.r1
stx P8ZP_SCRATCH_W2
ldx cx16.r1+1
stx P8ZP_SCRATCH_W2+1
jmp prog8_lib.memsetw
}}
}
inline asmsub read_flags() -> ubyte @A {
%asm {{
php
pla
}}
}
inline asmsub clear_carry() {
%asm {{
clc
}}
}
inline asmsub set_carry() {
%asm {{
sec
}}
}
inline asmsub clear_irqd() {
%asm {{
cli
}}
}
inline asmsub set_irqd() {
%asm {{
sei
}}
}
inline asmsub exit(ubyte returnvalue @A) {
; -- immediately exit the program with a return code in the A register
%asm {{
jsr c64.CLRCHN ; reset i/o channels
ldx prog8_lib.orig_stackpointer
txs
rts ; return to original caller
}}
}
inline asmsub progend() -> uword @AY {
%asm {{
lda #<prog8_program_end
ldy #>prog8_program_end
}}
}
}
cx16 {
; the sixteen virtual 16-bit registers that the CX16 has defined in the zeropage
; they are simulated on the C128 as well but their location in memory is different
; (because there's no room for them in the zeropage)
; $1300-$1bff is unused RAM on C128. We'll use $1a00-$1bff as the lo/hi evalstack.
; the virtual registers are allocated at the bottom of the eval-stack (should be ample space unless
; you're doing insane nesting of expressions...)
&uword r0 = $1b00
&uword r1 = $1b02
&uword r2 = $1b04
&uword r3 = $1b06
&uword r4 = $1b08
&uword r5 = $1b0a
&uword r6 = $1b0c
&uword r7 = $1b0e
&uword r8 = $1b10
&uword r9 = $1b12
&uword r10 = $1b14
&uword r11 = $1b16
&uword r12 = $1b18
&uword r13 = $1b1a
&uword r14 = $1b1c
&uword r15 = $1b1e
&word r0s = $1b00
&word r1s = $1b02
&word r2s = $1b04
&word r3s = $1b06
&word r4s = $1b08
&word r5s = $1b0a
&word r6s = $1b0c
&word r7s = $1b0e
&word r8s = $1b10
&word r9s = $1b12
&word r10s = $1b14
&word r11s = $1b16
&word r12s = $1b18
&word r13s = $1b1a
&word r14s = $1b1c
&word r15s = $1b1e
&ubyte r0L = $1b00
&ubyte r1L = $1b02
&ubyte r2L = $1b04
&ubyte r3L = $1b06
&ubyte r4L = $1b08
&ubyte r5L = $1b0a
&ubyte r6L = $1b0c
&ubyte r7L = $1b0e
&ubyte r8L = $1b10
&ubyte r9L = $1b12
&ubyte r10L = $1b14
&ubyte r11L = $1b16
&ubyte r12L = $1b18
&ubyte r13L = $1b1a
&ubyte r14L = $1b1c
&ubyte r15L = $1b1e
&ubyte r0H = $1b01
&ubyte r1H = $1b03
&ubyte r2H = $1b05
&ubyte r3H = $1b07
&ubyte r4H = $1b09
&ubyte r5H = $1b0b
&ubyte r6H = $1b0d
&ubyte r7H = $1b0f
&ubyte r8H = $1b11
&ubyte r9H = $1b13
&ubyte r10H = $1b15
&ubyte r11H = $1b17
&ubyte r12H = $1b19
&ubyte r13H = $1b1b
&ubyte r14H = $1b1d
&ubyte r15H = $1b1f
&byte r0sL = $1b00
&byte r1sL = $1b02
&byte r2sL = $1b04
&byte r3sL = $1b06
&byte r4sL = $1b08
&byte r5sL = $1b0a
&byte r6sL = $1b0c
&byte r7sL = $1b0e
&byte r8sL = $1b10
&byte r9sL = $1b12
&byte r10sL = $1b14
&byte r11sL = $1b16
&byte r12sL = $1b18
&byte r13sL = $1b1a
&byte r14sL = $1b1c
&byte r15sL = $1b1e
&byte r0sH = $1b01
&byte r1sH = $1b03
&byte r2sH = $1b05
&byte r3sH = $1b07
&byte r4sH = $1b09
&byte r5sH = $1b0b
&byte r6sH = $1b0d
&byte r7sH = $1b0f
&byte r8sH = $1b11
&byte r9sH = $1b13
&byte r10sH = $1b15
&byte r11sH = $1b17
&byte r12sH = $1b19
&byte r13sH = $1b1b
&byte r14sH = $1b1d
&byte r15sH = $1b1f
}

619
compiler/res/prog8lib/c128/textio.p8 Normal file
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@ -0,0 +1,619 @@
; 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 syslib
%import conv
txt {
const ubyte DEFAULT_WIDTH = 40
const ubyte DEFAULT_HEIGHT = 25
sub clear_screen() {
txt.chrout(147)
}
sub home() {
txt.chrout(19)
}
sub nl() {
txt.chrout('\n')
}
sub spc() {
txt.chrout(' ')
}
asmsub column(ubyte col @A) clobbers(A, X, Y) {
; ---- set the cursor on the given column (starting with 0) on the current line
%asm {{
sec
jsr c64.PLOT
tay
clc
jmp c64.PLOT
}}
}
asmsub fill_screen (ubyte char @ A, ubyte color @ 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 #250
- sta c64.Screen+250*0-1,y
sta c64.Screen+250*1-1,y
sta c64.Screen+250*2-1,y
sta c64.Screen+250*3-1,y
dey
bne -
rts
}}
}
asmsub clear_screencolors (ubyte color @ A) clobbers(Y) {
; ---- clear the character screen colors with the given color (leaves characters).
; (assumes color matrix is at the default address)
%asm {{
ldy #250
- sta c64.Colors+250*0-1,y
sta c64.Colors+250*1-1,y
sta c64.Colors+250*2-1,y
sta c64.Colors+250*3-1,y
dey
bne -
rts
}}
}
sub color (ubyte txtcol) {
c64.COLOR = txtcol
}
sub lowercase() {
c64.VMCSB |= 2
c128.VM1 |= 2
}
sub uppercase() {
c64.VMCSB &= ~2
c128.VM1 &= ~2
}
asmsub scroll_left (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
bcc _scroll_screen
+ ; scroll the screen and the color memory
ldx #0
ldy #38
-
.for row=0, row<=24, row+=1
lda c64.Screen + 40*row + 1,x
sta c64.Screen + 40*row + 0,x
lda c64.Colors + 40*row + 1,x
sta c64.Colors + 40*row + 0,x
.next
inx
dey
bpl -
rts
_scroll_screen ; scroll only 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 + 0,x
.next
inx
dey
bpl -
ldx P8ZP_SCRATCH_REG
rts
}}
}
asmsub scroll_right (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
bcc _scroll_screen
+ ; scroll the screen and the color memory
ldx #38
-
.for row=0, row<=24, row+=1
lda c64.Screen + 40*row + 0,x
sta c64.Screen + 40*row + 1,x
lda c64.Colors + 40*row + 0,x
sta c64.Colors + 40*row + 1,x
.next
dex
bpl -
rts
_scroll_screen ; scroll only 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
rts
}}
}
asmsub scroll_up (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
bcc _scroll_screen
+ ; scroll the screen and the color memory
ldx #39
-
.for row=1, row<=24, row+=1
lda c64.Screen + 40*row,x
sta c64.Screen + 40*(row-1),x
lda c64.Colors + 40*row,x
sta c64.Colors + 40*(row-1),x
.next
dex
bpl -
rts
_scroll_screen ; scroll only 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
rts
}}
}
asmsub scroll_down (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
bcc _scroll_screen
+ ; scroll the screen and 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
lda c64.Screen + 40*row,x
sta c64.Screen + 40*(row+1),x
.next
dex
bpl -
rts
_scroll_screen ; scroll only 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
rts
}}
}
romsub $FFD2 = chrout(ubyte char @ A) ; for consistency. You can also use c64.CHROUT directly ofcourse.
asmsub print (str text @ AY) clobbers(A,Y) {
; ---- print null terminated string from A/Y
; note: the compiler contains an optimization that will replace
; a call to this subroutine with a string argument of just one char,
; by just one call to c64.CHROUT of that single char.
%asm {{
sta P8ZP_SCRATCH_B1
sty P8ZP_SCRATCH_REG
ldy #0
- lda (P8ZP_SCRATCH_B1),y
beq +
jsr c64.CHROUT
iny
bne -
+ rts
}}
}
asmsub print_ub0 (ubyte value @ A) clobbers(A,Y) {
; ---- print the ubyte in A in decimal form, with left padding 0s (3 positions total)
%asm {{
stx P8ZP_SCRATCH_REG
jsr conv.ubyte2decimal
pha
tya
jsr c64.CHROUT
pla
jsr c64.CHROUT
txa
jsr c64.CHROUT
ldx P8ZP_SCRATCH_REG
rts
}}
}
asmsub print_ub (ubyte value @ A) clobbers(A,Y) {
; ---- print the ubyte in A in decimal form, without left padding 0s
%asm {{
stx P8ZP_SCRATCH_REG
jsr conv.ubyte2decimal
_print_byte_digits
pha
cpy #'0'
beq +
tya
jsr c64.CHROUT
pla
jsr c64.CHROUT
jmp _ones
+ pla
cmp #'0'
beq _ones
jsr c64.CHROUT
_ones txa
jsr c64.CHROUT
ldx P8ZP_SCRATCH_REG
rts
}}
}
asmsub print_b (byte value @ A) clobbers(A,Y) {
; ---- print the byte in A in decimal form, without left padding 0s
%asm {{
stx P8ZP_SCRATCH_REG
pha
cmp #0
bpl +
lda #'-'
jsr c64.CHROUT
+ pla
jsr conv.byte2decimal
jmp print_ub._print_byte_digits
}}
}
asmsub print_ubhex (ubyte value @ A, ubyte prefix @ Pc) clobbers(A,Y) {
; ---- print the ubyte in A in hex form (if Carry is set, a radix prefix '$' is printed as well)
%asm {{
stx P8ZP_SCRATCH_REG
bcc +
pha
lda #'$'
jsr c64.CHROUT
pla
+ jsr conv.ubyte2hex
jsr c64.CHROUT
tya
jsr c64.CHROUT
ldx P8ZP_SCRATCH_REG
rts
}}
}
asmsub print_ubbin (ubyte value @ A, ubyte prefix @ Pc) clobbers(A,Y) {
; ---- print the ubyte in A in binary form (if Carry is set, a radix prefix '%' is printed as well)
%asm {{
stx P8ZP_SCRATCH_REG
sta P8ZP_SCRATCH_B1
bcc +
lda #'%'
jsr c64.CHROUT
+ ldy #8
- lda #'0'
asl P8ZP_SCRATCH_B1
bcc +
lda #'1'
+ jsr c64.CHROUT
dey
bne -
ldx P8ZP_SCRATCH_REG
rts
}}
}
asmsub print_uwbin (uword value @ AY, ubyte prefix @ Pc) clobbers(A,Y) {
; ---- print the uword in A/Y in binary form (if Carry is set, a radix prefix '%' is printed as well)
%asm {{
pha
tya
jsr print_ubbin
pla
clc
jmp print_ubbin
}}
}
asmsub print_uwhex (uword value @ AY, ubyte prefix @ Pc) clobbers(A,Y) {
; ---- print the uword in A/Y in hexadecimal form (4 digits)
; (if Carry is set, a radix prefix '$' 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
jsr conv.uword2decimal
ldy #0
- lda conv.uword2decimal.decTenThousands,y
beq +
jsr c64.CHROUT
iny
bne -
+ ldx P8ZP_SCRATCH_REG
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
jsr conv.uword2decimal
ldx P8ZP_SCRATCH_REG
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 @X, ubyte row @Y, ubyte character @A) clobbers(A, Y) {
; ---- sets the character in the screen matrix at the given position
%asm {{
pha
tya
asl a
tay
lda _screenrows+1,y
sta _mod+2
txa
clc
adc _screenrows,y
sta _mod+1
bcc +
inc _mod+2
+ pla
_mod sta $ffff ; modified
rts
_screenrows .word $0400 + range(0, 1000, 40)
}}
}
asmsub getchr (ubyte col @A, ubyte row @Y) clobbers(Y) -> ubyte @ A {
; ---- get the character in the screen matrix at the given location
%asm {{
pha
tya
asl a
tay
lda setchr._screenrows+1,y
sta _mod+2
pla
clc
adc setchr._screenrows,y
sta _mod+1
bcc _mod
inc _mod+2
_mod lda $ffff ; modified
rts
}}
}
asmsub setclr (ubyte col @X, ubyte row @Y, ubyte color @A) clobbers(A, Y) {
; ---- set the color in A on the screen matrix at the given position
%asm {{
pha
tya
asl a
tay
lda _colorrows+1,y
sta _mod+2
txa
clc
adc _colorrows,y
sta _mod+1
bcc +
inc _mod+2
+ pla
_mod sta $ffff ; modified
rts
_colorrows .word $d800 + range(0, 1000, 40)
}}
}
asmsub getclr (ubyte col @A, ubyte row @Y) clobbers(Y) -> ubyte @ A {
; ---- get the color in the screen color matrix at the given location
%asm {{
pha
tya
asl a
tay
lda setclr._colorrows+1,y
sta _mod+2
pla
clc
adc setclr._colorrows,y
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 kernal routine, to save the X register.
%asm {{
stx P8ZP_SCRATCH_REG
tax
clc
jsr c64.PLOT
ldx P8ZP_SCRATCH_REG
rts
}}
}
asmsub width() clobbers(X,Y) -> ubyte @A {
; -- returns the text screen width (number of columns)
%asm {{
jsr c64.SCREEN
txa
rts
}}
}
asmsub height() clobbers(X, Y) -> ubyte @A {
; -- returns the text screen height (number of rows)
%asm {{
jsr c64.SCREEN
tya
rts
}}
}
}

77
compiler/res/prog8lib/c64/floats.asm
View File

@ -248,15 +248,25 @@ pop_float_fac1 .proc
.pend
copy_float .proc
; -- copies the 5 bytes of the mflt value pointed to by SCRATCH_ZPWORD1,
; -- copies the 5 bytes of the mflt value pointed to by P8ZP_SCRATCH_W1,
; 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
sta P8ZP_SCRATCH_W2
sty P8ZP_SCRATCH_W2+1
ldy #0
lda (P8ZP_SCRATCH_W1),y
sta (P8ZP_SCRATCH_W2),y
iny
lda (P8ZP_SCRATCH_W1),y
sta (P8ZP_SCRATCH_W2),y
iny
lda (P8ZP_SCRATCH_W1),y
sta (P8ZP_SCRATCH_W2),y
iny
lda (P8ZP_SCRATCH_W1),y
sta (P8ZP_SCRATCH_W2),y
iny
lda (P8ZP_SCRATCH_W1),y
sta (P8ZP_SCRATCH_W2),y
rts
.pend
@ -678,3 +688,54 @@ set_array_float .proc
.pend
equal_zero .proc
jsr floats.pop_float_fac1
jsr floats.SIGN
beq _true
bne _false
_true lda #1
sta P8ESTACK_LO,x
dex
rts
_false lda #0
sta P8ESTACK_LO,x
dex
rts
.pend
notequal_zero .proc
jsr floats.pop_float_fac1
jsr floats.SIGN
bne equal_zero._true
beq equal_zero._false
.pend
greater_zero .proc
jsr floats.pop_float_fac1
jsr floats.SIGN
beq equal_zero._false
bpl equal_zero._true
jmp equal_zero._false
.pend
less_zero .proc
jsr floats.pop_float_fac1
jsr floats.SIGN
bmi equal_zero._true
jmp equal_zero._false
.pend
greaterequal_zero .proc
jsr floats.pop_float_fac1
jsr floats.SIGN
bpl equal_zero._true
jmp equal_zero._false
.pend
lessequal_zero .proc
jsr floats.pop_float_fac1
jsr floats.SIGN
beq equal_zero._true
bmi equal_zero._true
jmp equal_zero._false
.pend

1
compiler/res/prog8lib/c64/floats.p8
View File

@ -12,6 +12,7 @@ floats {
const float PI = 3.141592653589793
const float TWOPI = 6.283185307179586
float tempvar_swap_float ; used for some swap() operations
; ---- C64 basic and kernal ROM float constants and functions ----

15
compiler/res/prog8lib/c64/graphics.p8
View File

@ -33,6 +33,9 @@ graphics {
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 implement this as optimized assembly, for instance https://github.com/EgonOlsen71/bresenham/blob/main/src/asm/graphics.asm ??
; or from here https://retro64.altervista.org/blog/an-introduction-to-vector-based-graphics-the-commodore-64-rotating-simple-3d-objects/
if y1>y2 {
; make sure dy is always positive to have only 4 instead of 8 special cases
swap(x1, x2)
@ -160,7 +163,7 @@ graphics {
lda addr+1
sta P8ZP_SCRATCH_W1+1
ldy separate_pixels
lda _filled_right,y
lda hline_filled_right,y
eor #255
ldy #0
ora (P8ZP_SCRATCH_W1),y
@ -204,18 +207,18 @@ _modified stx $ffff ; modified
_zero ldx P8ZP_SCRATCH_REG
ldy separate_pixels
beq _zero2
beq hline_zero2
lda _modified+1
sta P8ZP_SCRATCH_W1
lda _modified+2
sta P8ZP_SCRATCH_W1+1
lda _filled_right,y
lda hline_filled_right,y
ldy #0
ora (P8ZP_SCRATCH_W1),y
sta (P8ZP_SCRATCH_W1),y
jmp _zero2
_filled_right .byte 0, %10000000, %11000000, %11100000, %11110000, %11111000, %11111100, %11111110
_zero2
jmp hline_zero2
hline_filled_right .byte 0, %10000000, %11000000, %11100000, %11110000, %11111000, %11111100, %11111110
hline_zero2
}}
}
}

86
compiler/res/prog8lib/c64/syslib.p8
View File

@ -15,7 +15,9 @@ c64 {
&ubyte COLOR = $0286 ; cursor color
&ubyte HIBASE = $0288 ; screen base address / 256 (hi-byte of screen memory address)
&uword CINV = $0314 ; IRQ vector
&uword CINV = $0314 ; IRQ vector (in ram)
&uword CBINV = $0316 ; BRK vector (in ram)
&uword NMINV = $0318 ; NMI vector (in ram)
&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
@ -472,7 +474,7 @@ _setup_raster_irq
sys {
; ------- lowlevel system routines --------
const ubyte target = 64 ; compilation target specifier. 64 = C64, 16 = CommanderX16.
const ubyte target = 64 ; compilation target specifier. 64 = C64, 128 = C128, 16 = CommanderX16.
asmsub reset_system() {
@ -518,6 +520,7 @@ sys {
}
asmsub memcopy(uword source @R0, uword target @R1, uword count @AY) clobbers(A,X,Y) {
; note: can't be inlined because is called from asm as well
%asm {{
ldx cx16.r0
stx P8ZP_SCRATCH_W1 ; source in ZP
@ -597,34 +600,6 @@ _longcopy
}}
}
inline asmsub rsave() {
; save cpu status flag and all registers A, X, Y.
; see http://6502.org/tutorials/register_preservation.html
%asm {{
php
sta P8ZP_SCRATCH_REG
pha
txa
pha
tya
pha
lda P8ZP_SCRATCH_REG
}}
}
inline asmsub rrestore() {
; restore all registers and cpu status flag
%asm {{
pla
tay
pla
tax
pla
plp
}}
}
inline asmsub read_flags() -> ubyte @A {
%asm {{
php
@ -699,6 +674,23 @@ cx16 {
&uword r14 = $cf1c
&uword r15 = $cf1e
&word r0s = $cf00
&word r1s = $cf02
&word r2s = $cf04
&word r3s = $cf06
&word r4s = $cf08
&word r5s = $cf0a
&word r6s = $cf0c
&word r7s = $cf0e
&word r8s = $cf10
&word r9s = $cf12
&word r10s = $cf14
&word r11s = $cf16
&word r12s = $cf18
&word r13s = $cf1a
&word r14s = $cf1c
&word r15s = $cf1e
&ubyte r0L = $cf00
&ubyte r1L = $cf02
&ubyte r2L = $cf04
@ -732,4 +724,38 @@ cx16 {
&ubyte r13H = $cf1b
&ubyte r14H = $cf1d
&ubyte r15H = $cf1f
&byte r0sL = $cf00
&byte r1sL = $cf02
&byte r2sL = $cf04
&byte r3sL = $cf06
&byte r4sL = $cf08
&byte r5sL = $cf0a
&byte r6sL = $cf0c
&byte r7sL = $cf0e
&byte r8sL = $cf10
&byte r9sL = $cf12
&byte r10sL = $cf14
&byte r11sL = $cf16
&byte r12sL = $cf18
&byte r13sL = $cf1a
&byte r14sL = $cf1c
&byte r15sL = $cf1e
&byte r0sH = $cf01
&byte r1sH = $cf03
&byte r2sH = $cf05
&byte r3sH = $cf07
&byte r4sH = $cf09
&byte r5sH = $cf0b
&byte r6sH = $cf0d
&byte r7sH = $cf0f
&byte r8sH = $cf11
&byte r9sH = $cf13
&byte r10sH = $cf15
&byte r11sH = $cf17
&byte r12sH = $cf19
&byte r13sH = $cf1b
&byte r14sH = $cf1d
&byte r15sH = $cf1f
}

24
compiler/res/prog8lib/conv.p8
View File

@ -7,19 +7,19 @@ conv {
; ----- number conversions to decimal strings ----
str string_out = "????????????????" ; result buffer for the string conversion routines
str @shared string_out = "????????????????" ; result buffer for the string conversion routines
asmsub str_ub0 (ubyte value @ A) clobbers(A,Y) {
; ---- convert the ubyte in A in decimal string form, with left padding 0s (3 positions total)
%asm {{
phx
stx P8ZP_SCRATCH_REG
jsr conv.ubyte2decimal
sty string_out
sta string_out+1
stx string_out+2
lda #0
sta string_out+3
plx
ldx P8ZP_SCRATCH_REG
rts
}}
}
@ -27,7 +27,7 @@ asmsub str_ub0 (ubyte value @ A) clobbers(A,Y) {
asmsub str_ub (ubyte value @ A) clobbers(A,Y) {
; ---- convert the ubyte in A in decimal string form, without left padding 0s
%asm {{
phx
stx P8ZP_SCRATCH_REG
ldy #0
sty P8ZP_SCRATCH_B1
jsr conv.ubyte2decimal
@ -53,7 +53,7 @@ _output_byte_digits
iny
lda #0
sta string_out,y
plx
ldx P8ZP_SCRATCH_REG
rts
}}
}
@ -61,7 +61,7 @@ _output_byte_digits
asmsub str_b (byte value @ A) clobbers(A,Y) {
; ---- convert the byte in A in decimal string form, without left padding 0s
%asm {{
phx
stx P8ZP_SCRATCH_REG
ldy #0
sty P8ZP_SCRATCH_B1
cmp #0
@ -149,7 +149,7 @@ asmsub str_uwhex (uword value @ AY) clobbers(A,Y) {
asmsub str_uw0 (uword value @ AY) clobbers(A,Y) {
; ---- convert the uword in A/Y in decimal string form, with left padding 0s (5 positions total)
%asm {{
phx
stx P8ZP_SCRATCH_REG
jsr conv.uword2decimal
ldy #0
- lda conv.uword2decimal.decTenThousands,y
@ -157,7 +157,7 @@ asmsub str_uw0 (uword value @ AY) clobbers(A,Y) {
beq +
iny
bne -
+ plx
+ ldx P8ZP_SCRATCH_REG
rts
}}
}
@ -165,7 +165,7 @@ asmsub str_uw0 (uword value @ AY) clobbers(A,Y) {
asmsub str_uw (uword value @ AY) clobbers(A,Y) {
; ---- convert the uword in A/Y in decimal string form, without left padding 0s
%asm {{
phx
stx P8ZP_SCRATCH_REG
jsr conv.uword2decimal
ldx #0
_output_digits
@ -183,7 +183,7 @@ _gotdigit sta string_out,x
bne _gotdigit
_end lda #0
sta string_out,x
plx
ldx P8ZP_SCRATCH_REG
rts
_allzero lda #'0'
@ -198,7 +198,7 @@ asmsub str_w (word value @ AY) clobbers(A,Y) {
%asm {{
cpy #0
bpl str_uw
phx
stx P8ZP_SCRATCH_REG
pha
lda #'-'
sta string_out
@ -516,7 +516,7 @@ asmsub uword2decimal (uword value @AY) -> ubyte @Y, ubyte @A, ubyte @X {
;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
; routine from https://forums.nesdev.org/viewtopic.php?f=2&t=11341&start=15
;HexToDec99
; start in A

75
compiler/res/prog8lib/cx16/cx16diskio.p8 Normal file
View File

@ -0,0 +1,75 @@
; Cx16 specific disk drive I/O routines.
;
; Written by Irmen de Jong (irmen@razorvine.net) - license: GNU GPL 3.0
%import diskio
cx16diskio {
; Use kernal LOAD routine to load the given program file in memory.
; This is similar to Basic's LOAD "filename",drive / LOAD "filename",drive,1
; If you don't give an address_override, the location in memory is taken from the 2-byte file header.
; If you specify a custom address_override, the first 2 bytes in the file are ignored
; and the rest is loaded at the given location in memory.
; Returns the end load address+1 if successful or 0 if a load error occurred.
; You can use the load_size() function to calcuate the size of the file that was loaded.
sub load(ubyte drivenumber, uword filenameptr, ubyte bank, uword address_override) -> uword {
cx16.rambank(bank)
return diskio.load(drivenumber, filenameptr, address_override)
}
; Use kernal LOAD routine to load the given file in memory.
; INCLUDING the first 2 bytes in the file: no program header is assumed in the file.
; This is different from Basic's LOAD instruction which always skips the first two bytes.
; The load address is mandatory. Returns the number of bytes loaded.
; Returns the end load address+1 if successful or 0 if a load error occurred.
; You can use the load_size() function to calcuate the size of the file that was loaded.
sub load_raw(ubyte drivenumber, uword filenameptr, ubyte bank, uword address) -> uword {
cx16.rambank(bank)
return diskio.load_raw(drivenumber, filenameptr, address)
}
; For use directly after a load or load_raw call (don't mess with the ram bank yet):
; Calculates the number of bytes loaded (files > 64Kb ar truncated to 16 bits)
sub load_size(ubyte startbank, uword startaddress, uword endaddress) -> uword {
return $2000 * (cx16.getrambank() - startbank) + endaddress - startaddress
}
asmsub vload(str name @R0, ubyte device @Y, ubyte bank @A, uword address @R1) -> ubyte @A {
; -- like the basic command VLOAD "filename",device,bank,address
; loads a file into Vera's video memory in the given bank:address, returns success in A
%asm {{
; -- load a file into video ram
phx
pha
tya
tax
lda #1
ldy #0
jsr c64.SETLFS
lda cx16.r0
ldy cx16.r0+1
jsr prog8_lib.strlen
tya
ldx cx16.r0
ldy cx16.r0+1
jsr c64.SETNAM
pla
clc
adc #2
ldx cx16.r1
ldy cx16.r1+1
stz P8ZP_SCRATCH_B1
jsr c64.LOAD
bcs +
inc P8ZP_SCRATCH_B1
+ jsr c64.CLRCHN
lda #1
jsr c64.CLOSE
plx
lda P8ZP_SCRATCH_B1
rts
}}
}
}

1
compiler/res/prog8lib/cx16/floats.p8
View File

@ -10,7 +10,6 @@ floats {
; ---- this block contains C-64 compatible floating point related functions ----
; the addresses are from cx16 V39 emulator and roms! they won't work on older versions.
const float PI = 3.141592653589793
const float TWOPI = 6.283185307179586

21
compiler/res/prog8lib/cx16/gfx2.p8
View File

@ -369,7 +369,7 @@ _done
set_both_strides(13) ; 160 increment = 1 line in 640 px 4c mode
color &= 3
color <<= gfx2.plot.shift4c[lsb(x) & 3]
ubyte mask = gfx2.plot.mask4c[lsb(x) & 3]
ubyte @shared mask = gfx2.plot.mask4c[lsb(x) & 3]
repeat height {
%asm {{
lda cx16.VERA_DATA0
@ -545,9 +545,9 @@ _done
}
sub plot(uword @zp x, uword y, ubyte color) {
ubyte[8] bits = [128, 64, 32, 16, 8, 4, 2, 1]
ubyte[4] mask4c = [%00111111, %11001111, %11110011, %11111100]
ubyte[4] shift4c = [6,4,2,0]
ubyte[8] @shared bits = [128, 64, 32, 16, 8, 4, 2, 1]
ubyte[4] @shared mask4c = [%00111111, %11001111, %11110011, %11111100]
ubyte[4] @shared shift4c = [6,4,2,0]
when active_mode {
1 -> {
@ -775,6 +775,7 @@ _done
; -- Write some text at the given pixel position. The text string must be in screencode encoding (not petscii!).
; You must also have called text_charset() first to select and prepare the character set to use.
; NOTE: in monochrome (1bpp) screen modes, x position is currently constrained to multiples of 8 ! TODO allow per-pixel horizontal positioning
; TODO draw whole horizontal spans using vera auto increment if possible, instead of per-character columns
uword chardataptr
when active_mode {
1, 5 -> {
@ -808,11 +809,8 @@ _done
sta cx16.VERA_ADDR_L
bcc +
inc cx16.VERA_ADDR_M
+ lda x
clc
adc #1
sta x
bcc +
+ inc x
bne +
inc x+1
+ dey
bne -
@ -826,7 +824,6 @@ _done
chardataptr = charset_addr + (@(sctextptr) as uword)*8
cx16.vaddr(charset_bank, chardataptr, 1, 1)
repeat 8 {
; TODO rewrite this inner loop fully in assembly
position(x,y)
y++
%asm {{
@ -855,7 +852,9 @@ _done
while @(sctextptr) {
chardataptr = charset_addr + (@(sctextptr) as uword)*8
repeat 8 {
; TODO rewrite this inner loop fully in assembly
; TODO rewrite this inner loop partly in assembly
; requires expanding the charbits to 2-bits per pixel (based on color)
; also it's way more efficient to draw whole horizontal spans instead of per-character
ubyte charbits = cx16.vpeek(charset_bank, chardataptr)
repeat 8 {
charbits <<= 1

158
compiler/res/prog8lib/cx16/syslib.p8
View File

@ -11,7 +11,7 @@ c64 {
; STROUT --> use txt.print
; CLEARSCR -> use txt.clear_screen
; HOMECRSR -> use txt.plot
; HOMECRSR -> use txt.home or txt.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)
@ -90,12 +90,14 @@ cx16 {
; irq and hardware vectors:
&uword CINV = $0314 ; IRQ vector (in ram)
&uword CBINV = $0316 ; BRK vector (in ram)
&uword NMINV = $0318 ; NMI vector (in ram)
&uword NMI_VEC = $FFFA ; 65c02 nmi vector, determined by the kernal if banked in
&uword RESET_VEC = $FFFC ; 65c02 reset vector, determined by the kernal if banked in
&uword IRQ_VEC = $FFFE ; 65c02 interrupt vector, determined by the kernal if banked in
; the sixteen virtual 16-bit registers
; the sixteen virtual 16-bit registers in both normal unsigned mode and signed mode (s)
&uword r0 = $0002
&uword r1 = $0004
&uword r2 = $0006
@ -113,6 +115,23 @@ cx16 {
&uword r14 = $001e
&uword r15 = $0020
&word r0s = $0002
&word r1s = $0004
&word r2s = $0006
&word r3s = $0008
&word r4s = $000a
&word r5s = $000c
&word r6s = $000e
&word r7s = $0010
&word r8s = $0012
&word r9s = $0014
&word r10s = $0016
&word r11s = $0018
&word r12s = $001a
&word r13s = $001c
&word r14s = $001e
&word r15s = $0020
&ubyte r0L = $0002
&ubyte r1L = $0004
&ubyte r2L = $0006
@ -147,6 +166,39 @@ cx16 {
&ubyte r14H = $001f
&ubyte r15H = $0021
&byte r0sL = $0002
&byte r1sL = $0004
&byte r2sL = $0006
&byte r3sL = $0008
&byte r4sL = $000a
&byte r5sL = $000c
&byte r6sL = $000e
&byte r7sL = $0010
&byte r8sL = $0012
&byte r9sL = $0014
&byte r10sL = $0016
&byte r11sL = $0018
&byte r12sL = $001a
&byte r13sL = $001c
&byte r14sL = $001e
&byte r15sL = $0020
&byte r0sH = $0003
&byte r1sH = $0005
&byte r2sH = $0007
&byte r3sH = $0009
&byte r4sH = $000b
&byte r5sH = $000d
&byte r6sH = $000f
&byte r7sH = $0011
&byte r8sH = $0013
&byte r9sH = $0015
&byte r10sH = $0017
&byte r11sH = $0019
&byte r12sH = $001b
&byte r13sH = $001d
&byte r14sH = $001f
&byte r15sH = $0021
; VERA registers
@ -255,14 +307,27 @@ romsub $ff7d = primm()
romsub $ff44 = macptr() clobbers(A,X,Y)
romsub $ff47 = enter_basic(ubyte cold_or_warm @Pc) clobbers(A,X,Y)
romsub $ff68 = mouse_config(ubyte shape @A, ubyte scale @X) clobbers (A, X, Y)
romsub $ff6b = mouse_get(ubyte zpdataptr @X) clobbers(A)
romsub $ff6b = mouse_get(ubyte zpdataptr @X) -> ubyte @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(uword yearmonth @R0, uword dayhours @R1, uword minsecs @R2, ubyte jiffies @R3) clobbers(A, X, Y)
romsub $ff50 = clock_get_date_time() clobbers(A, X, Y) -> uword @R0, uword @R1, uword @R2, ubyte @R3 ; result registers see clock_set_date_time()
; TODO specify the correct clobbers for alle these functions below, we now assume all 3 regs are clobbered
asmsub mouse_pos() -> ubyte @A {
; -- short wrapper around mouse_get() kernal routine:
; -- gets the position of the mouse cursor in cx16.r0 and cx16.r1 (x/y coordinate), returns mouse button status.
%asm {{
phx
ldx #cx16.r0
jsr cx16.mouse_get
plx
rts
}}
}
; It's not documented what registers are clobbered, so we assume the worst for all following kernal routines...:
; high level graphics & fonts
romsub $ff20 = GRAPH_init(uword vectors @R0) clobbers(A,X,Y)
@ -317,20 +382,34 @@ romsub $fecc = monitor() clobbers(A,X,Y)
; ---- utilities -----
inline asmsub rombank(ubyte rombank @A) {
inline asmsub rombank(ubyte bank @A) {
; -- set the rom banks
%asm {{
sta $01 ; rom bank register (v39+, used to be cx16.d1prb $9f60 in v38)
}}
}
inline asmsub rambank(ubyte rambank @A) {
inline asmsub rambank(ubyte bank @A) {
; -- set the ram bank
%asm {{
sta $00 ; ram bank register (v39+, used to be cx16.d1pra $9f61 in v38)
}}
}
inline asmsub getrombank() -> ubyte @A {
; -- get the current rom bank
%asm {{
lda $01 ; rom bank register (v39+, used to be cx16.d1prb $9f60 in v38)
}}
}
inline asmsub getrambank() -> ubyte @A {
; -- get the current ram bank
%asm {{
lda $00 ; ram bank register (v39+, used to be cx16.d1pra $9f61 in v38)
}}
}
asmsub numbanks() -> ubyte @A {
; -- uses MEMTOP's cx16 extension to query the number of available RAM banks. (each is 8 Kb)
%asm {{
@ -454,45 +533,6 @@ asmsub vpoke_xor(ubyte bank @A, uword address @R0, ubyte value @Y) clobbers (A)
}}
}
asmsub vload(str name @R0, ubyte device @Y, ubyte bank @A, uword address @R1) -> ubyte @A {
; -- like the basic command VLOAD "filename",device,bank,address
; loads a file into video memory in the given bank:address, returns success in A
; !! NOTE !! the V38 ROMs contain a bug in the LOAD code that makes the load address not work correctly,
; it works fine when loading from local filesystem
%asm {{
; -- load a file into video ram
phx
pha
tya
tax
lda #1
ldy #0
jsr c64.SETLFS
lda cx16.r0
ldy cx16.r0+1
jsr prog8_lib.strlen
tya
ldx cx16.r0
ldy cx16.r0+1
jsr c64.SETNAM
pla
clc
adc #2
ldx cx16.r1
ldy cx16.r1+1
stz P8ZP_SCRATCH_B1
jsr c64.LOAD
bcs +
inc P8ZP_SCRATCH_B1
+ jsr c64.CLRCHN
lda #1
jsr c64.CLOSE
plx
lda P8ZP_SCRATCH_B1
rts
}}
}
inline asmsub joystick_get2(ubyte joynr @A) clobbers(Y) -> uword @AX {
; convenience routine to get the joystick state without requiring inline assembly that deals with the multiple return values.
; Also disables interrupts to avoid the IRQ race condition mentioned here: https://github.com/commanderx16/x16-rom/issues/203
@ -744,7 +784,7 @@ asmsub set_rasterline(uword line @AY) {
sys {
; ------- lowlevel system routines --------
const ubyte target = 16 ; compilation target specifier. 64 = C64, 16 = CommanderX16.
const ubyte target = 16 ; compilation target specifier. 64 = C64, 128 = C128, 16 = CommanderX16.
asmsub reset_system() {
@ -781,11 +821,12 @@ sys {
}}
}
inline asmsub memcopy(uword source @R0, uword target @R1, uword count @AY) clobbers(A,X,Y) {
asmsub memcopy(uword source @R0, uword target @R1, uword count @AY) clobbers(A,X,Y) {
; note: can't be inlined because is called from asm as well
%asm {{
sta cx16.r2
sty cx16.r2+1
jsr cx16.memory_copy
jmp cx16.memory_copy
}}
}
@ -809,27 +850,6 @@ sys {
}}
}
inline asmsub rsave() {
; save cpu status flag and all registers A, X, Y.
; see http://6502.org/tutorials/register_preservation.html
%asm {{
php
pha
phy
phx
}}
}
inline asmsub rrestore() {
; restore all registers and cpu status flag
%asm {{
plx
ply
pla
plp
}}
}
inline asmsub read_flags() -> ubyte @A {
%asm {{
php

22
compiler/res/prog8lib/cx16/textio.p8
View File

@ -169,13 +169,26 @@ sub color2 (ubyte txtcol, ubyte bgcol) {
}
sub lowercase() {
cx16.screen_set_charset(3, 0) ; lowercase charset
c64.CHROUT($0e)
; this is not 100% compatible: cx16.screen_set_charset(3, 0) ; lowercase petscii charset
}
sub uppercase() {
cx16.screen_set_charset(2, 0) ; uppercase charset
c64.CHROUT($8e)
; this is not 100% compatible: cx16.screen_set_charset(2, 0) ; uppercase petscii charset
}
sub iso() {
c64.CHROUT($0f)
; This doesn't enable it completely: cx16.screen_set_charset(1, 0) ; iso charset
}
sub iso_off() {
; -- you have to call this first when switching back from iso charset to regular charset.
c64.CHROUT($8f)
}
asmsub scroll_left() 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
@ -565,9 +578,8 @@ asmsub print_w (word value @ AY) clobbers(A,Y) {
tay
pla
eor #255
clc
adc #1
bcc +
ina
bne +
iny
+ bra print_uw
}}

12
compiler/res/prog8lib/cx16logo.p8
View File

@ -20,12 +20,12 @@ cx16logo {
}
str[] logo_lines = [
"\uf10d\uf11a\uf139\uf11b \uf11a\uf13a\uf11b\n",
"\uf10b\uf11a▎\uf139\uf11b \uf11a\uf13a\uf130\uf11b\n",
"\uf10f\uf11a▌ \uf139\uf11b \uf11a\uf13a \uf11b▌\n",
"\uf102 \uf132\uf11a▖\uf11b \uf11a▗\uf11b\uf132\n",
"\uf10e ▂\uf11a▘\uf11b \uf11a▝\uf11b▂\n",
"\uf104 \uf11a \uf11b\uf13a\uf11b \uf139\uf11a \uf11b\n",
"\uf10d\uf11a\uf139\uf11b \uf11a\uf13a\uf11b",
"\uf10b\uf11a▎\uf139\uf11b \uf11a\uf13a\uf130\uf11b",
"\uf10f\uf11a▌ \uf139\uf11b \uf11a\uf13a \uf11b▌",
"\uf102 \uf132\uf11a▖\uf11b \uf11a▗\uf11b\uf132",
"\uf10e ▂\uf11a▘\uf11b \uf11a▝\uf11b▂",
"\uf104 \uf11a \uf11b\uf13a\uf11b \uf139\uf11a \uf11b",
"\uf101\uf130\uf13a \uf139▎\uf100"
]
}

62
compiler/res/prog8lib/diskio.p8
View File

@ -76,7 +76,8 @@ io_error:
sub list_files(ubyte drivenumber, uword pattern_ptr, uword name_ptrs, ubyte max_names) -> ubyte {
; -- fill the array 'name_ptrs' with (pointers to) the names of the files requested.
uword names_buffer = memory("filenames", 512)
const uword names_buf_size = 800
uword names_buffer = memory("filenames", names_buf_size, 0)
uword buffer_start = names_buffer
ubyte files_found = 0
if lf_start_list(drivenumber, pattern_ptr) {
@ -87,7 +88,7 @@ io_error:
name_ptrs++
names_buffer += string.copy(diskio.list_filename, names_buffer) + 1
files_found++
if names_buffer - buffer_start > 512-18
if names_buffer - buffer_start > names_buf_size-18
break
if files_found == max_names
break
@ -242,18 +243,18 @@ close_end:
void c64.CHKIN(11) ; use #11 as input channel again
%asm {{
lda bufferpointer
sta _in_buffer+1
sta m_in_buffer+1
lda bufferpointer+1
sta _in_buffer+2
sta m_in_buffer+2
}}
repeat num_bytes {
%asm {{
jsr c64.CHRIN
sta cx16.r5
_in_buffer sta $ffff
inc _in_buffer+1
m_in_buffer sta $ffff
inc m_in_buffer+1
bne +
inc _in_buffer+2
inc m_in_buffer+2
+ inc list_blocks
bne +
inc list_blocks+1
@ -406,7 +407,7 @@ io_error:
sub save(ubyte drivenumber, uword filenameptr, uword address, uword size) -> ubyte {
c64.SETNAM(string.length(filenameptr), filenameptr)
c64.SETLFS(1, drivenumber, 0)
uword end_address = address + size
uword @shared end_address = address + size
first_byte = 0 ; result var reuse
%asm {{
@ -433,10 +434,20 @@ io_error:
return first_byte
}
; Use kernal LOAD routine to load the given program file in memory.
; This is similar to Basic's LOAD "filename",drive / LOAD "filename",drive,1
; If you don't give an address_override, the location in memory is taken from the 2-byte file header.
; If you specify a custom address_override, the first 2 bytes in the file are ignored
; and the rest is loaded at the given location in memory.
; Returns the end load address+1 if successful or 0 if a load error occurred.
; NOTE: when the load is larger than 64Kb and/or spans multiple RAM banks
; (which is possible on the Commander X16), the returned size is not correct,
; because it doesn't take the number of ram banks into account.
; Consider using cx16diskio.load() instead.
sub load(ubyte drivenumber, uword filenameptr, uword address_override) -> uword {
c64.SETNAM(string.length(filenameptr), filenameptr)
ubyte secondary = 1
uword end_of_load = 0
cx16.r1 = 0
if address_override
secondary = 0
c64.SETLFS(1, drivenumber, secondary)
@ -447,22 +458,35 @@ io_error:
ldy address_override+1
jsr c64.LOAD
bcs +
stx end_of_load
sty end_of_load+1
stx cx16.r1
sty cx16.r1+1
+ ldx P8ZP_SCRATCH_REG
}}
c64.CLRCHN()
c64.CLOSE(1)
if end_of_load
return end_of_load - address_override
return 0
return cx16.r1
}
str filename = "0:??????????????????????????????????????"
; Use kernal LOAD routine to load the given file in memory.
; INCLUDING the first 2 bytes in the file: no program header is assumed in the file.
; This is different from Basic's LOAD instruction which always skips the first two bytes.
; The load address is mandatory.
; Returns the end load address+1 if successful or 0 if a load error occurred.
; NOTE: when the load is larger than 64Kb and/or spans multiple RAM banks
; (which is possible on the Commander X16), the returned size is not correct,
; because it doesn't take the number of ram banks into account.
; Consider using cx16diskio.load_raw() instead.
sub load_raw(ubyte drivenumber, uword filenameptr, uword address) -> uword {
if not f_open(drivenumber, filenameptr)
return 0
cx16.r1 = f_read(address, 2)
f_close()
if cx16.r1!=2
return 0
address += 2
return load(drivenumber, filenameptr, address)
}
sub delete(ubyte drivenumber, uword filenameptr) {
; -- delete a file on the drive
@ -489,4 +513,6 @@ io_error:
c64.CLRCHN()
c64.CLOSE(1)
}
str filename = "0:??????????????????????????????????????"
}

143
compiler/res/prog8lib/prog8_funcs.asm
View File

@ -91,6 +91,13 @@ func_sin8_into_A .proc
_sinecos8 .char trunc(127.0 * sin(range(256+64) * rad(360.0/256.0)))
.pend
func_sinr8_into_A .proc
tay
lda _sinecosR8,y
rts
_sinecosR8 .char trunc(127.0 * sin(range(180+45) * rad(360.0/180.0)))
.pend
func_sin8u_into_A .proc
tay
lda _sinecos8u,y
@ -98,6 +105,13 @@ func_sin8u_into_A .proc
_sinecos8u .byte trunc(128.0 + 127.5 * sin(range(256+64) * rad(360.0/256.0)))
.pend
func_sinr8u_into_A .proc
tay
lda _sinecosR8u,y
rts
_sinecosR8u .byte trunc(128.0 + 127.5 * sin(range(180+45) * rad(360.0/180.0)))
.pend
func_sin8_stack .proc
tay
lda func_sin8_into_A._sinecos8,y
@ -106,6 +120,14 @@ func_sin8_stack .proc
rts
.pend
func_sinr8_stack .proc
tay
lda func_sinr8_into_A._sinecosR8,y
sta P8ESTACK_LO,x
dex
rts
.pend
func_sin8u_stack .proc
tay
lda func_sin8u_into_A._sinecos8u,y
@ -114,18 +136,38 @@ func_sin8u_stack .proc
rts
.pend
func_sinr8u_stack .proc
tay
lda func_sinr8u_into_A._sinecosR8u,y
sta P8ESTACK_LO,x
dex
rts
.pend
func_cos8_into_A .proc
tay
lda func_sin8_into_A._sinecos8+64,y
rts
.pend
func_cosr8_into_A .proc
tay
lda func_sinr8_into_A._sinecosR8+45,y
rts
.pend
func_cos8u_into_A .proc
tay
lda func_sin8u_into_A._sinecos8u+64,y
rts
.pend
func_cosr8u_into_A .proc
tay
lda func_sinr8u_into_A._sinecosR8u+45,y
rts
.pend
func_cos8_stack .proc
tay
lda func_sin8_into_A._sinecos8+64,y
@ -134,6 +176,14 @@ func_cos8_stack .proc
rts
.pend
func_cosr8_stack .proc
tay
lda func_sinr8_into_A._sinecosR8+45,y
sta P8ESTACK_LO,x
dex
rts
.pend
func_cos8u_stack .proc
tay
lda func_sin8u_into_A._sinecos8u+64,y
@ -142,6 +192,14 @@ func_cos8u_stack .proc
rts
.pend
func_cosr8u_stack .proc
tay
lda func_sinr8u_into_A._sinecosR8u+45,y
sta P8ESTACK_LO,x
dex
rts
.pend
func_sin16_into_AY .proc
tay
lda _sinecos8lo,y
@ -155,6 +213,19 @@ _sinecos8lo .byte <_
_sinecos8hi .byte >_
.pend
func_sinr16_into_AY .proc
tay
lda _sinecosR8lo,y
pha
lda _sinecosR8hi,y
tay
pla
rts
_ := trunc(32767.0 * sin(range(180+45) * rad(360.0/180.0)))
_sinecosR8lo .byte <_
_sinecosR8hi .byte >_
.pend
func_sin16u_into_AY .proc
tay
lda _sinecos8ulo,y
@ -168,6 +239,18 @@ _sinecos8ulo .byte <_
_sinecos8uhi .byte >_
.pend
func_sinr16u_into_AY .proc
tay
lda _sinecosR8ulo,y
pha
lda _sinecosR8uhi,y
tay
pla
rts
_ := trunc(32768.0 + 32767.5 * sin(range(180+45) * rad(360.0/180.0)))
_sinecosR8ulo .byte <_
_sinecosR8uhi .byte >_
.pend
func_sin16_stack .proc
tay
@ -179,6 +262,16 @@ func_sin16_stack .proc
rts
.pend
func_sinr16_stack .proc
tay
lda func_sinr16_into_AY._sinecosR8lo,y
sta P8ESTACK_LO,x
lda func_sinr16_into_AY._sinecosR8hi,y
sta P8ESTACK_HI,x
dex
rts
.pend
func_sin16u_stack .proc
tay
lda func_sin16u_into_AY._sinecos8ulo,y
@ -189,6 +282,16 @@ func_sin16u_stack .proc
rts
.pend
func_sinr16u_stack .proc
tay
lda func_sinr16u_into_AY._sinecosR8ulo,y
sta P8ESTACK_LO,x
lda func_sinr16u_into_AY._sinecosR8uhi,y
sta P8ESTACK_HI,x
dex
rts
.pend
func_cos16_into_AY .proc
tay
lda func_sin16_into_AY._sinecos8lo+64,y
@ -199,6 +302,16 @@ func_cos16_into_AY .proc
rts
.pend
func_cosr16_into_AY .proc
tay
lda func_sinr16_into_AY._sinecosR8lo+45,y
pha
lda func_sinr16_into_AY._sinecosR8hi+45,y
tay
pla
rts
.pend
func_cos16u_into_AY .proc
tay
lda func_sin16u_into_AY._sinecos8ulo+64,y
@ -209,6 +322,16 @@ func_cos16u_into_AY .proc
rts
.pend
func_cosr16u_into_AY .proc
tay
lda func_sinr16u_into_AY._sinecosR8ulo+45,y
pha
lda func_sinr16u_into_AY._sinecosR8uhi+45,y
tay
pla
rts
.pend
func_cos16_stack .proc
tay
lda func_sin16_into_AY._sinecos8lo+64,y
@ -219,6 +342,16 @@ func_cos16_stack .proc
rts
.pend
func_cosr16_stack .proc
tay
lda func_sinr16_into_AY._sinecosR8lo+45,y
sta P8ESTACK_LO,x
lda func_sinr16_into_AY._sinecosR8hi+45,y
sta P8ESTACK_HI,x
dex
rts
.pend
func_cos16u_stack .proc
tay
lda func_sin16u_into_AY._sinecos8ulo+64,y
@ -229,6 +362,16 @@ func_cos16u_stack .proc
rts
.pend
func_cosr16u_stack .proc
tay
lda func_sinr16u_into_AY._sinecosR8ulo+45,y
sta P8ESTACK_LO,x
lda func_sinr16u_into_AY._sinecosR8uhi+45,y
sta P8ESTACK_HI,x
dex
rts
.pend
abs_b_stack .proc
; -- push abs(A) on stack (as byte)
jsr abs_b_into_A

170
compiler/res/prog8lib/prog8_lib.asm
View File

@ -4,6 +4,8 @@
; Written by Irmen de Jong (irmen@razorvine.net) - license: GNU GPL 3.0
orig_stackpointer .byte 0 ; stores the Stack pointer register at program start
read_byte_from_address_on_stack .proc
; -- read the byte from the memory address on the top of the stack, return in A (stack remains unchanged)
lda P8ESTACK_LO+1,x
@ -683,8 +685,106 @@ shiftright_b .proc
.pend
orig_stackpointer .byte 0 ; stores the Stack pointer register at program start
equalzero_b .proc
lda P8ESTACK_LO+1,x
beq _true
bne _false
_true lda #1
sta P8ESTACK_LO+1,x
rts
_false lda #0
sta P8ESTACK_LO+1,x
rts
.pend
equalzero_w .proc
lda P8ESTACK_LO+1,x
ora P8ESTACK_HI+1,x
beq equalzero_b._true
bne equalzero_b._false
.pend
notequalzero_b .proc
lda P8ESTACK_LO+1,x
beq equalzero_b._false
bne equalzero_b._true
.pend
notequalzero_w .proc
lda P8ESTACK_LO+1,x
ora P8ESTACK_HI+1,x
beq equalzero_b._false
bne equalzero_b._true
.pend
lesszero_b .proc
lda P8ESTACK_LO+1,x
bmi equalzero_b._true
jmp equalzero_b._false
.pend
lesszero_w .proc
lda P8ESTACK_HI+1,x
bmi equalzero_b._true
jmp equalzero_b._false
.pend
greaterzero_ub .proc
lda P8ESTACK_LO+1,x
bne equalzero_b._true
beq equalzero_b._false
.pend
greaterzero_sb .proc
lda P8ESTACK_LO+1,x
beq equalzero_b._false
bpl equalzero_b._true
bmi equalzero_b._false
.pend
greaterzero_uw .proc
lda P8ESTACK_LO+1,x
ora P8ESTACK_HI+1,x
bne equalzero_b._true
beq equalzero_b._false
.pend
greaterzero_sw .proc
lda P8ESTACK_HI+1,x
bmi equalzero_b._false
ora P8ESTACK_LO+1,x
beq equalzero_b._false
bne equalzero_b._true
.pend
lessequalzero_sb .proc
lda P8ESTACK_LO+1,x
bmi equalzero_b._true
beq equalzero_b._true
bne equalzero_b._false
.pend
lessequalzero_sw .proc
lda P8ESTACK_HI+1,x
bmi equalzero_b._true
ora P8ESTACK_LO+1,x
beq equalzero_b._true
bne equalzero_b._false
.pend
greaterequalzero_sb .proc
lda P8ESTACK_LO+1,x
bpl equalzero_b._true
bmi equalzero_b._false
.pend
greaterequalzero_sw .proc
lda P8ESTACK_HI+1,x
bmi equalzero_b._false
ora P8ESTACK_LO+1,x
beq equalzero_b._true
bne equalzero_b._false
.pend
memcopy16_up .proc
@ -1021,17 +1121,15 @@ strcmp_mem .proc
; Returns -1,0,1 in A, depeding on the ordering. Clobbers Y.
sta P8ZP_SCRATCH_W1
sty P8ZP_SCRATCH_W1+1
_loop ldy #0
lda (P8ZP_SCRATCH_W1),y
ldy #0
_loop lda (P8ZP_SCRATCH_W1),y
bne +
lda (P8ZP_SCRATCH_W2),y
bne _return_minusone
beq _return
+ lda (P8ZP_SCRATCH_W2),y
sec
sbc (P8ZP_SCRATCH_W1),y
bmi _return_one
bne _return_minusone
+ cmp (P8ZP_SCRATCH_W2),y
bcc _return_minusone
bne _return_one
inc P8ZP_SCRATCH_W1
bne +
inc P8ZP_SCRATCH_W1+1
@ -1058,20 +1156,6 @@ sign_extend_stack_byte .proc
rts
.pend
sign_extend_AY_byte .proc
; -- sign extend the (signed) byte in AY to full 16 bits
pha
and #$80
beq +
ldy #$ff
pla
rts
+ ldy #0
pla
rts
.pend
strlen .proc
; -- returns the number of bytes in the string in AY, in Y.
sta P8ZP_SCRATCH_W1
@ -1083,3 +1167,45 @@ strlen .proc
bne -
+ rts
.pend
containment_bytearray .proc
; -- check if a value exists in a byte array.
; parameters: P8ZP_SCRATCH_W1: address of the byte array, A = byte to check, Y = length of array (>=1).
; returns boolean 0/1 in A.
dey
- cmp (P8ZP_SCRATCH_W1),y
beq +
dey
cpy #255
bne -
lda #0
rts
+ lda #1
rts
.pend
containment_wordarray .proc
; -- check if a value exists in a word array.
; parameters: P8ZP_SCRATCH_W1: value to check, P8ZP_SCRATCH_W2: address of the word array, Y = length of array (>=1).
; returns boolean 0/1 in A.
dey
tya
asl a
tay
- lda P8ZP_SCRATCH_W1
cmp (P8ZP_SCRATCH_W2),y
bne +
lda P8ZP_SCRATCH_W1+1
iny
cmp (P8ZP_SCRATCH_W2),y
beq _found
+ dey
dey
cpy #254
bne -
lda #0
rts
_found lda #1
rts
.pend

4
compiler/res/prog8lib/prog8_lib.p8
View File

@ -6,10 +6,6 @@ prog8_lib {
%asminclude "library:prog8_lib.asm"
%asminclude "library:prog8_funcs.asm"
uword @zp retval_interm_uw ; to store intermediary expression results for return values (hopefully allocated on ZP to reduce code size)
word @zp retval_interm_w ; to store intermediary expression results for return values (hopefully allocated on ZP to reduce code size)
ubyte @zp retval_interm_ub ; to store intermediary expression results for return values (hopefully allocated on ZP to reduce code size)
byte @zp retval_interm_b ; to store intermediary expression results for return values (hopefully allocated on ZP to reduce code size)
asmsub pattern_match(str string @AY, str pattern @R0) clobbers(Y) -> ubyte @A {
%asm {{

21
compiler/res/prog8lib/string.p8
View File

@ -130,11 +130,11 @@ _startloop dey
}}
}
asmsub find(uword string @R0, ubyte character @A) -> uword @AY {
asmsub find(uword string @R0, ubyte character @A) -> ubyte @A, ubyte @Pc {
; Locates the first position of the given character in the string,
; returns the string starting with this character or $0000 if the character is not found.
; returns Carry set if found + index in A, or Carry clear if not found.
%asm {{
; need to copy the the cx16 virtual registers to zeropage to be compatible with C64...
; need to copy the the cx16 virtual registers to zeropage to make this run on C64...
sta P8ZP_SCRATCH_B1
lda cx16.r0
ldy cx16.r0+1
@ -147,18 +147,11 @@ _startloop dey
beq _found
iny
bne -
_notfound lda #0
ldy #0
_notfound clc
rts
_found tya
sec
rts
_found sty P8ZP_SCRATCH_B1
ldy P8ZP_SCRATCH_W1+1
lda P8ZP_SCRATCH_W1
clc
adc P8ZP_SCRATCH_B1
bcc +
iny
+ rts
}}
}

2
compiler/res/version.txt
View File

@ -1 +1 @@
7.1
7.8

55
compiler/src/prog8/CompilerMain.kt
View File

@ -2,11 +2,12 @@ package prog8
import kotlinx.cli.*
import prog8.ast.base.AstException
import prog8.codegen.target.C128Target
import prog8.codegen.target.C64Target
import prog8.codegen.target.Cx16Target
import prog8.compiler.CompilationResult
import prog8.compiler.CompilerArguments
import prog8.compiler.compileProgram
import prog8.compiler.target.C64Target
import prog8.compiler.target.Cx16Target
import prog8.parser.ParsingFailedError
import java.io.File
import java.nio.file.FileSystems
import java.nio.file.Path
@ -36,10 +37,15 @@ private fun compileMain(args: Array<String>): Boolean {
val outputDir by cli.option(ArgType.String, fullName = "out", description = "directory for output files instead of current directory").default(".")
val dontWriteAssembly by cli.option(ArgType.Boolean, fullName = "noasm", description="don't create assembly code")
val dontOptimize by cli.option(ArgType.Boolean, fullName = "noopt", description = "don't perform any optimizations")
val dontReinitGlobals by cli.option(ArgType.Boolean, fullName = "noreinit", description = "don't create code to reinitialize globals on multiple runs of the program (experimental!)")
val optimizeFloatExpressions by cli.option(ArgType.Boolean, fullName = "optfloatx", description = "optimize float expressions (warning: can increase program size)")
val watchMode by cli.option(ArgType.Boolean, fullName = "watch", description = "continuous compilation mode (watches for file changes), greatly increases compilation speed")
val slowCodegenWarnings by cli.option(ArgType.Boolean, fullName = "slowwarn", description="show debug warnings about slow/problematic assembly code generation")
val compilationTarget by cli.option(ArgType.String, fullName = "target", description = "target output of the compiler, currently '${C64Target.name}' and '${Cx16Target.name}' available").default(C64Target.name)
val sourceDirs by cli.option(ArgType.String, fullName="srcdirs", description = "list of extra paths to search in for imported modules").multiple().delimiter(File.pathSeparator)
val quietAssembler by cli.option(ArgType.Boolean, fullName = "quietasm", description = "don't print assembler output results")
val asmListfile by cli.option(ArgType.Boolean, fullName = "asmlist", description = "make the assembler produce a listing file as well")
val experimentalCodegen by cli.option(ArgType.Boolean, fullName = "expericodegen", description = "use experimental codegen")
val compilationTarget by cli.option(ArgType.String, fullName = "target", description = "target output of the compiler (one of '${C64Target.NAME}', '${C128Target.NAME}', '${Cx16Target.NAME}')").default(C64Target.NAME)
val sourceDirs by cli.option(ArgType.String, fullName="srcdirs", description = "list of extra paths, separated with ${File.pathSeparator}, to search in for imported modules").multiple().delimiter(File.pathSeparator)
val moduleFiles by cli.argument(ArgType.String, fullName = "modules", description = "main module file(s) to compile").multiple(999)
try {
@ -65,6 +71,11 @@ private fun compileMain(args: Array<String>): Boolean {
if(srcdirs.firstOrNull()!=".")
srcdirs.add(0, ".")
if (compilationTarget !in setOf(C64Target.NAME, C128Target.NAME, Cx16Target.NAME)) {
System.err.println("Invalid compilation target: $compilationTarget")
return false
}
if(watchMode==true) {
val watchservice = FileSystems.getDefault().newWatchService()
val allImportedFiles = mutableSetOf<Path>()
@ -74,7 +85,21 @@ private fun compileMain(args: Array<String>): Boolean {
val results = mutableListOf<CompilationResult>()
for(filepathRaw in moduleFiles) {
val filepath = pathFrom(filepathRaw).normalize()
val compilationResult = compileProgram(filepath, dontOptimize!=true, dontWriteAssembly!=true, slowCodegenWarnings==true, compilationTarget, srcdirs, outputPath)
val compilerArgs = CompilerArguments(
filepath,
dontOptimize != true,
optimizeFloatExpressions == true,
dontReinitGlobals == true,
dontWriteAssembly != true,
slowCodegenWarnings == true,
quietAssembler == true,
asmListfile == true,
experimentalCodegen == true,
compilationTarget,
srcdirs,
outputPath
)
val compilationResult = compileProgram(compilerArgs)
results.add(compilationResult)
}
@ -111,11 +136,23 @@ private fun compileMain(args: Array<String>): Boolean {
val filepath = pathFrom(filepathRaw).normalize()
val compilationResult: CompilationResult
try {
compilationResult = compileProgram(filepath, dontOptimize!=true, dontWriteAssembly!=true, slowCodegenWarnings==true, compilationTarget, srcdirs, outputPath)
val compilerArgs = CompilerArguments(
filepath,
dontOptimize != true,
optimizeFloatExpressions == true,
dontReinitGlobals == true,
dontWriteAssembly != true,
slowCodegenWarnings == true,
quietAssembler == true,
asmListfile == true,
experimentalCodegen == true,
compilationTarget,
srcdirs,
outputPath
)
compilationResult = compileProgram(compilerArgs)
if (!compilationResult.success)
return false
} catch (x: ParsingFailedError) {
return false
} catch (x: AstException) {
return false
}

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

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

355
compiler/src/prog8/compiler/BeforeAsmGenerationAstChanger.kt
View File

@ -1,355 +0,0 @@
package prog8.compiler
import prog8.ast.IFunctionCall
import prog8.ast.Node
import prog8.ast.Program
import prog8.ast.base.*
import prog8.ast.expressions.*
import prog8.ast.statements.*
import prog8.ast.walk.AstWalker
import prog8.ast.walk.IAstModification
import prog8.ast.walk.IAstVisitor
import prog8.compiler.astprocessing.isInRegularRAMof
import prog8.compiler.target.ICompilationTarget
internal class BeforeAsmGenerationAstChanger(val program: Program, val errors: IErrorReporter, private val compTarget: ICompilationTarget) : AstWalker() {
override fun after(decl: VarDecl, parent: Node): Iterable<IAstModification> {
subroutineVariables.add(decl.name to decl)
if (decl.value == null && !decl.autogeneratedDontRemove && decl.type == VarDeclType.VAR && decl.datatype in NumericDatatypes) {
// A numeric vardecl without an initial value is initialized with zero,
// unless there's already an assignment below, that initializes the value.
// This allows you to restart the program and have the same starting values of the variables
if(decl.allowInitializeWithZero)
{
val nextAssign = decl.definingScope.nextSibling(decl) as? Assignment
if (nextAssign != null && nextAssign.target isSameAs IdentifierReference(listOf(decl.name), Position.DUMMY))
decl.value = null
else {
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.
// But it can only be done if the target variable IS NOT OCCURRING AS AN OPERAND ITSELF.
if(!assignment.isAugmentable
&& assignment.target.identifier != null
&& assignment.target.isInRegularRAMof(compTarget.machine)) {
val binExpr = assignment.value as? BinaryExpression
if (binExpr != null && binExpr.operator !in comparisonOperators) {
if (binExpr.left !is BinaryExpression) {
if (binExpr.right.referencesIdentifier(*assignment.target.identifier!!.nameInSource.toTypedArray())) {
// the right part of the expression contains the target variable itself.
// we can't 'split' it trivially because the variable will be changed halfway through.
if(binExpr.operator in associativeOperators) {
// A = <something-without-A> <associativeoperator> <otherthing-with-A>
// use the other part of the expression to split.
val assignRight = Assignment(assignment.target, binExpr.right, assignment.position)
return listOf(
IAstModification.InsertBefore(assignment, assignRight, assignment.definingScope),
IAstModification.ReplaceNode(binExpr.right, binExpr.left, binExpr),
IAstModification.ReplaceNode(binExpr.left, assignment.target.toExpression(), binExpr))
}
} else {
val assignLeft = Assignment(assignment.target, binExpr.left, assignment.position)
return listOf(
IAstModification.InsertBefore(assignment, assignLeft, assignment.definingScope),
IAstModification.ReplaceNode(binExpr.left, assignment.target.toExpression(), binExpr))
}
}
}
}
return noModifications
}
private val subroutineVariables = mutableListOf<Pair<String, VarDecl>>()
private val addedIfConditionVars = mutableSetOf<Pair<Subroutine, String>>()
override fun before(subroutine: Subroutine, parent: Node): Iterable<IAstModification> {
subroutineVariables.clear()
addedIfConditionVars.clear()
return noModifications
}
override fun after(scope: AnonymousScope, parent: Node): Iterable<IAstModification> {
val decls = scope.statements.filterIsInstance<VarDecl>().filter { it.type == VarDeclType.VAR }
subroutineVariables.addAll(decls.map { it.name to it })
val sub = scope.definingSubroutine
if (sub != null) {
// move any remaining vardecls of the scope into the upper scope. Make sure the position remains the same!
val replacements = mutableListOf<IAstModification>()
val movements = mutableListOf<IAstModification.InsertFirst>()
for(decl in decls) {
if(decl.value!=null && decl.datatype in NumericDatatypes) {
val target = AssignTarget(IdentifierReference(listOf(decl.name), decl.position), null, null, decl.position)
val assign = Assignment(target, decl.value!!, decl.position)
replacements.add(IAstModification.ReplaceNode(decl, assign, scope))
decl.value = null
decl.allowInitializeWithZero = false
} else {
replacements.add(IAstModification.Remove(decl, scope))
}
movements.add(IAstModification.InsertFirst(decl, sub))
}
return replacements + movements
}
return noModifications
}
override fun after(subroutine: Subroutine, parent: Node): Iterable<IAstModification> {
val firstDeclarations = mutableMapOf<String, VarDecl>()
for(decl in subroutineVariables) {
val existing = firstDeclarations[decl.first]
if(existing!=null && existing !== decl.second) {
errors.err("variable ${decl.first} already defined in subroutine ${subroutine.name} at ${existing.position}", decl.second.position)
} else {
firstDeclarations[decl.first] = decl.second
}
}
// add the implicit return statement at the end (if it's not there yet), but only if it's not a kernal 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.inline) {
if(subroutine.statements.isEmpty() ||
(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)
}
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).getOr(DataType.UNDEFINED)
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.
// The only place for now where we can do this is for:
// asmsub register pair parameter.
if(sourceDt in PassByReferenceDatatypes) {
if(typecast.type==DataType.UWORD) {
if(typecast.expression is IdentifierReference) {
return listOf(IAstModification.ReplaceNode(
typecast,
AddressOf(typecast.expression as IdentifierReference, typecast.position),
parent
))
} else if(typecast.expression is IFunctionCall) {
return listOf(IAstModification.ReplaceNode(
typecast,
typecast.expression,
parent
))
}
} else {
errors.err("cannot cast pass-by-reference value to type ${typecast.type} (only to UWORD)", typecast.position)
}
}
return noModifications
}
override fun after(ifStatement: IfStatement, parent: Node): Iterable<IAstModification> {
val binExpr = ifStatement.condition as? BinaryExpression
if(binExpr==null || binExpr.operator !in comparisonOperators) {
// if x -> if x!=0, if x+5 -> if x+5 != 0
val booleanExpr = BinaryExpression(ifStatement.condition, "!=", NumericLiteralValue.optimalInteger(0, ifStatement.condition.position), ifStatement.condition.position)
return listOf(IAstModification.ReplaceNode(ifStatement.condition, booleanExpr, ifStatement))
}
if((binExpr.operator=="==" || binExpr.operator=="!=") &&
(binExpr.left as? NumericLiteralValue)?.number==0 &&
(binExpr.right as? NumericLiteralValue)?.number!=0)
throw CompilerException("if 0==X should have been swapped to if X==0")
// split the conditional expression into separate variables if the operand(s) is not simple.
// DISABLED FOR NOW AS IT GENEREATES LARGER CODE IN THE SIMPLE CASES LIKE IF X {...} or IF NOT X {...}
// val modifications = mutableListOf<IAstModification>()
// if(!binExpr.left.isSimple) {
// val sub = binExpr.definingSubroutine()!!
// val (variable, isNew, assignment) = addIfOperandVar(sub, "left", binExpr.left)
// if(isNew)
// modifications.add(IAstModification.InsertFirst(variable, sub))
// modifications.add(IAstModification.InsertBefore(ifStatement, assignment, parent as INameScope))
// modifications.add(IAstModification.ReplaceNode(binExpr.left, IdentifierReference(listOf(variable.name), binExpr.position), binExpr))
// addedIfConditionVars.add(Pair(sub, variable.name))
// }
// if(!binExpr.right.isSimple) {
// val sub = binExpr.definingSubroutine()!!
// val (variable, isNew, assignment) = addIfOperandVar(sub, "right", binExpr.right)
// if(isNew)
// modifications.add(IAstModification.InsertFirst(variable, sub))
// modifications.add(IAstModification.InsertBefore(ifStatement, assignment, parent as INameScope))
// modifications.add(IAstModification.ReplaceNode(binExpr.right, IdentifierReference(listOf(variable.name), binExpr.position), binExpr))
// addedIfConditionVars.add(Pair(sub, variable.name))
// }
// return modifications
return noModifications
}
// private fun addIfOperandVar(sub: Subroutine, side: String, operand: Expression): Triple<VarDecl, Boolean, Assignment> {
// val dt = operand.inferType(program).typeOrElse(DataType.UNDEFINED)
// val varname = "prog8_ifvar_${side}_${dt.name.toLowerCase()}"
// val tgt = AssignTarget(IdentifierReference(listOf(varname), operand.position), null, null, operand.position)
// val assign = Assignment(tgt, operand, operand.position)
// if(Pair(sub, varname) in addedIfConditionVars) {
// val vardecl = VarDecl(VarDeclType.VAR, dt, ZeropageWish.DONTCARE, null, varname, null, null, false, true, operand.position)
// return Triple(vardecl, false, assign)
// }
// val existing = sub.statements.firstOrNull { it is VarDecl && it.name == varname} as VarDecl?
// return if (existing == null) {
// val vardecl = VarDecl(VarDeclType.VAR, dt, ZeropageWish.DONTCARE, null, varname, null, null, false, true, operand.position)
// Triple(vardecl, true, assign)
// } else {
// Triple(existing, false, assign)
// }
// }
override fun after(untilLoop: UntilLoop, parent: Node): Iterable<IAstModification> {
val binExpr = untilLoop.condition as? BinaryExpression
if(binExpr==null || binExpr.operator !in comparisonOperators) {
// until x -> until x!=0, until x+5 -> until x+5 != 0
val booleanExpr = BinaryExpression(untilLoop.condition, "!=", NumericLiteralValue.optimalInteger(0, untilLoop.condition.position), untilLoop.condition.position)
return listOf(IAstModification.ReplaceNode(untilLoop.condition, booleanExpr, untilLoop))
}
return noModifications
}
override fun after(whileLoop: WhileLoop, parent: Node): Iterable<IAstModification> {
val binExpr = whileLoop.condition as? BinaryExpression
if(binExpr==null || binExpr.operator !in comparisonOperators) {
// while x -> while x!=0, while x+5 -> while x+5 != 0
val booleanExpr = BinaryExpression(whileLoop.condition, "!=", NumericLiteralValue.optimalInteger(0, whileLoop.condition.position), whileLoop.condition.position)
return listOf(IAstModification.ReplaceNode(whileLoop.condition, booleanExpr, whileLoop))
}
return noModifications
}
override fun after(functionCallStatement: FunctionCallStatement, parent: Node): Iterable<IAstModification> {
if(functionCallStatement.target.nameInSource==listOf("cmp")) {
// if the datatype of the arguments of cmp() are different, cast the byte one to word.
val arg1 = functionCallStatement.args[0]
val arg2 = functionCallStatement.args[1]
val dt1 = arg1.inferType(program).getOr(DataType.UNDEFINED)
val dt2 = arg2.inferType(program).getOr(DataType.UNDEFINED)
if(dt1 in ByteDatatypes) {
if(dt2 in ByteDatatypes)
return noModifications
val cast1 = TypecastExpression(arg1, if(dt1==DataType.UBYTE) DataType.UWORD else DataType.WORD, true, functionCallStatement.position)
return listOf(IAstModification.ReplaceNode(arg1, cast1, functionCallStatement))
} else {
if(dt2 in WordDatatypes)
return noModifications
val cast2 = TypecastExpression(arg2, if(dt2==DataType.UBYTE) DataType.UWORD else DataType.WORD, true, functionCallStatement.position)
return listOf(IAstModification.ReplaceNode(arg2, cast2, functionCallStatement))
}
}
return noModifications
}
override fun after(arrayIndexedExpression: ArrayIndexedExpression, parent: Node): Iterable<IAstModification> {
val containingStatement = getContainingStatement(arrayIndexedExpression)
if(getComplexArrayIndexedExpressions(containingStatement).size > 1) {
errors.err("it's not possible to use more than one complex array indexing expression in a single statement; break it up via a temporary variable for instance", containingStatement.position)
return noModifications
}
val index = arrayIndexedExpression.indexer.indexExpr
if(index !is NumericLiteralValue && index !is IdentifierReference) {
// replace complex indexing expression with a temp variable to hold the computed index first
return getAutoIndexerVarFor(arrayIndexedExpression)
}
return noModifications
}
private fun getComplexArrayIndexedExpressions(stmt: Statement): List<ArrayIndexedExpression> {
class Searcher : IAstVisitor {
val complexArrayIndexedExpressions = mutableListOf<ArrayIndexedExpression>()
override fun visit(arrayIndexedExpression: ArrayIndexedExpression) {
val ix = arrayIndexedExpression.indexer.indexExpr
if(ix !is NumericLiteralValue && ix !is IdentifierReference)
complexArrayIndexedExpressions.add(arrayIndexedExpression)
}
override fun visit(branchStatement: BranchStatement) {}
override fun visit(forLoop: ForLoop) {}
override fun visit(ifStatement: IfStatement) {
ifStatement.condition.accept(this)
}
override fun visit(untilLoop: UntilLoop) {
untilLoop.condition.accept(this)
}
}
val searcher = Searcher()
stmt.accept(searcher)
return searcher.complexArrayIndexedExpressions
}
private fun getContainingStatement(expression: Expression): Statement {
var node: Node = expression
while(node !is Statement)
node = node.parent
return node
}
private fun getAutoIndexerVarFor(expr: ArrayIndexedExpression): MutableList<IAstModification> {
val modifications = mutableListOf<IAstModification>()
val statement = expr.containingStatement
val dt = expr.indexer.indexExpr.inferType(program)
val register = if(dt istype DataType.UBYTE || dt istype DataType.BYTE ) "r9L" else "r9"
// replace the indexer with just the variable (simply use a cx16 virtual register r9, that we HOPE is not used for other things in the expression...)
// assign the indexing expression to the helper variable, but only if that hasn't been done already
val target = AssignTarget(IdentifierReference(listOf("cx16", register), expr.indexer.position), null, null, expr.indexer.position)
val assign = Assignment(target, expr.indexer.indexExpr, expr.indexer.position)
modifications.add(IAstModification.InsertBefore(statement, assign, statement.definingScope))
modifications.add(IAstModification.ReplaceNode(expr.indexer.indexExpr, target.identifier!!.copy(), expr.indexer))
return modifications
}
}

343
compiler/src/prog8/compiler/Compiler.kt
View File

@ -1,154 +1,152 @@
package prog8.compiler
import com.github.michaelbull.result.*
import prog8.ast.AstToSourceCode
import com.github.michaelbull.result.onFailure
import prog8.ast.AstToSourceTextConverter
import prog8.ast.IBuiltinFunctions
import prog8.ast.IMemSizer
import prog8.ast.IStatementContainer
import prog8.ast.Program
import prog8.ast.base.AstException
import prog8.ast.base.Position
import prog8.ast.expressions.Expression
import prog8.ast.expressions.NumericLiteralValue
import prog8.ast.expressions.NumericLiteral
import prog8.ast.statements.Directive
import prog8.ast.statements.VarDecl
import prog8.ast.walk.IAstVisitor
import prog8.codegen.target.C128Target
import prog8.codegen.target.C64Target
import prog8.codegen.target.Cx16Target
import prog8.compiler.astprocessing.*
import prog8.compiler.functions.*
import prog8.compiler.target.C64Target
import prog8.compiler.target.Cx16Target
import prog8.compiler.target.ICompilationTarget
import prog8.compiler.target.asmGeneratorFor
import prog8.compilerinterface.*
import prog8.optimizer.*
import prog8.parser.ParseError
import prog8.parser.ParsingFailedError
import prog8.parser.SourceCode
import prog8.parser.SourceCode.Companion.libraryFilePrefix
import java.io.File
import java.nio.file.Path
import kotlin.io.path.Path
import kotlin.io.path.nameWithoutExtension
import kotlin.math.round
import kotlin.system.measureTimeMillis
enum class OutputType {
RAW,
PRG
}
enum class LauncherType {
BASIC,
NONE
}
enum class ZeropageType {
BASICSAFE,
FLOATSAFE,
KERNALSAFE,
FULL,
DONTUSE
}
data class CompilationOptions(val output: OutputType,
val launcher: LauncherType,
val zeropage: ZeropageType,
val zpReserved: List<IntRange>,
val floats: Boolean,
val noSysInit: Boolean,
val compTarget: ICompilationTarget) {
var slowCodegenWarnings = false
var optimize = false
}
class CompilerException(message: String?) : Exception(message)
class CompilationResult(val success: Boolean,
val programAst: Program,
val program: Program,
val programName: String,
val compTarget: ICompilationTarget,
val importedFiles: List<Path>)
class CompilerArguments(val filepath: Path,
val optimize: Boolean,
val optimizeFloatExpressions: Boolean,
val dontReinitGlobals: Boolean,
val writeAssembly: Boolean,
val slowCodegenWarnings: Boolean,
val quietAssembler: Boolean,
val asmListfile: Boolean,
val experimentalCodegen: Boolean,
val compilationTarget: String,
val sourceDirs: List<String> = emptyList(),
val outputDir: Path = Path(""),
val errors: IErrorReporter = ErrorReporter())
fun compileProgram(filepath: Path,
optimize: Boolean,
writeAssembly: Boolean,
slowCodegenWarnings: Boolean,
compilationTarget: String,
sourceDirs: List<String>,
outputDir: Path): CompilationResult {
fun compileProgram(args: CompilerArguments): CompilationResult {
var programName = ""
lateinit var programAst: Program
lateinit var program: Program
lateinit var importedFiles: List<Path>
val errors = ErrorReporter()
val optimizeFloatExpr = if(args.optimize) args.optimizeFloatExpressions else false
val compTarget =
when(compilationTarget) {
C64Target.name -> C64Target
Cx16Target.name -> Cx16Target
when(args.compilationTarget) {
C64Target.NAME -> C64Target()
C128Target.NAME -> C128Target()
Cx16Target.NAME -> Cx16Target()
else -> throw IllegalArgumentException("invalid compilation target")
}
try {
val totalTime = measureTimeMillis {
// import main module and everything it needs
val (ast, compilationOptions, imported) = parseImports(filepath, errors, compTarget, sourceDirs)
compilationOptions.slowCodegenWarnings = slowCodegenWarnings
compilationOptions.optimize = optimize
programAst = ast
val (programresult, compilationOptions, imported) = parseImports(args.filepath, args.errors, compTarget, args.sourceDirs)
print("Parsed ${args.filepath}")
ModuleImporter.ansiEraseRestOfLine(true)
with(compilationOptions) {
slowCodegenWarnings = args.slowCodegenWarnings
optimize = args.optimize
optimizeFloatExpressions = optimizeFloatExpr
dontReinitGlobals = args.dontReinitGlobals
asmQuiet = args.quietAssembler
asmListfile = args.asmListfile
experimentalCodegen = args.experimentalCodegen
outputDir = args.outputDir.normalize()
}
program = programresult
importedFiles = imported
processAst(programAst, errors, compilationOptions)
if (compilationOptions.optimize)
processAst(program, args.errors, compilationOptions)
if (compilationOptions.optimize) {
// println("*********** AST RIGHT BEFORE OPTIMIZING *************")
// printProgram(program)
optimizeAst(
programAst,
errors,
program,
compilationOptions,
args.errors,
BuiltinFunctionsFacade(BuiltinFunctions),
compTarget,
compilationOptions
compTarget
)
postprocessAst(programAst, errors, compilationOptions)
}
postprocessAst(program, args.errors, compilationOptions)
// printAst(programAst)
// println("*********** AST BEFORE ASSEMBLYGEN *************")
// printProgram(program)
if (writeAssembly) {
val result = writeAssembly(programAst, errors, outputDir, compilationOptions)
when (result) {
if (args.writeAssembly) {
when (val result = writeAssembly(program, args.errors, compilationOptions)) {
is WriteAssemblyResult.Ok -> programName = result.filename
is WriteAssemblyResult.Fail -> {
System.err.println(result.error)
return CompilationResult(false, programAst, programName, compTarget, importedFiles)
return CompilationResult(false, program, programName, compTarget, importedFiles)
}
}
}
}
System.out.flush()
System.err.flush()
println("\nTotal compilation+assemble time: ${totalTime / 1000.0} sec.")
return CompilationResult(true, programAst, programName, compTarget, importedFiles)
val seconds = totalTime/1000.0
println("\nTotal compilation+assemble time: ${round(seconds*100.0)/100.0} sec.")
return CompilationResult(true, program, programName, compTarget, importedFiles)
} catch (px: ParseError) {
System.err.print("\u001b[91m") // bright red
System.err.print("\n\u001b[91m") // bright red
System.err.println("${px.position.toClickableStr()} parse error: ${px.message}".trim())
System.err.print("\u001b[0m") // reset
} catch (pfx: ParsingFailedError) {
System.err.print("\u001b[91m") // bright red
System.err.println(pfx.message)
} catch (ac: AbortCompilation) {
if(!ac.message.isNullOrEmpty()) {
System.err.print("\n\u001b[91m") // bright red
System.err.println(ac.message)
System.err.print("\u001b[0m") // reset
}
} catch (nsf: NoSuchFileException) {
System.err.print("\n\u001b[91m") // bright red
System.err.println("File not found: ${nsf.message}")
System.err.print("\u001b[0m") // reset
} catch (ax: AstException) {
System.err.print("\u001b[91m") // bright red
System.err.print("\n\u001b[91m") // bright red
System.err.println(ax.toString())
System.err.print("\u001b[0m") // reset
} catch (x: Exception) {
print("\u001b[91m") // bright red
print("\n\u001b[91m") // bright red
println("\n* internal error *")
print("\u001b[0m") // reset
System.out.flush()
throw x
} catch (x: NotImplementedError) {
print("\u001b[91m") // bright red
print("\n\u001b[91m") // bright red
println("\n* internal error: missing feature/code *")
print("\u001b[0m") // reset
System.out.flush()
throw x
}
val failedProgram = Program("failed", BuiltinFunctionsFacade(BuiltinFunctions), compTarget)
val failedProgram = Program("failed", BuiltinFunctionsFacade(BuiltinFunctions), compTarget, compTarget)
return CompilationResult(false, failedProgram, programName, compTarget, emptyList())
}
@ -158,13 +156,13 @@ private class BuiltinFunctionsFacade(functions: Map<String, FSignature>): IBuilt
override val names = functions.keys
override val purefunctionNames = functions.filter { it.value.pure }.map { it.key }.toSet()
override fun constValue(name: String, args: List<Expression>, position: Position, memsizer: IMemSizer): NumericLiteralValue? {
override fun constValue(name: String, args: List<Expression>, position: Position): NumericLiteral? {
val func = BuiltinFunctions[name]
if(func!=null) {
val exprfunc = func.constExpressionFunc
if(exprfunc!=null) {
return try {
exprfunc(args, position, program, memsizer)
exprfunc(args, position, program)
} catch(x: NotConstArgumentException) {
// const-evaluating the builtin function call failed.
null
@ -186,23 +184,20 @@ fun parseImports(filepath: Path,
errors: IErrorReporter,
compTarget: ICompilationTarget,
sourceDirs: List<String>): Triple<Program, CompilationOptions, List<Path>> {
println("Compiler target: ${compTarget.name}. Parsing...")
println("Compiler target: ${compTarget.name}")
val bf = BuiltinFunctionsFacade(BuiltinFunctions)
val programAst = Program(filepath.nameWithoutExtension, bf, compTarget)
bf.program = programAst
val program = Program(filepath.nameWithoutExtension, bf, compTarget, compTarget)
bf.program = program
val importer = ModuleImporter(programAst, compTarget.name, errors, sourceDirs)
val importer = ModuleImporter(program, compTarget.name, errors, sourceDirs)
val importedModuleResult = importer.importModule(filepath)
importedModuleResult.onFailure { throw it }
errors.report()
val importedFiles = programAst.modules.map { it.source }
val importedFiles = program.modules.map { it.source }
.filter { it.isFromFilesystem }
.map { Path(it.origin) }
val compilerOptions = determineCompilationOptions(programAst, compTarget)
if (compilerOptions.launcher == LauncherType.BASIC && compilerOptions.output != OutputType.PRG)
throw ParsingFailedError("${programAst.modules.first().position} BASIC launcher requires output type PRG.")
val compilerOptions = determineCompilationOptions(program, compTarget)
// depending on the machine and compiler options we may have to include some libraries
for(lib in compTarget.machine.importLibs(compilerOptions, compTarget.name))
importer.importLibraryModule(lib)
@ -210,8 +205,12 @@ fun parseImports(filepath: Path,
// always import prog8_lib and math
importer.importLibraryModule("math")
importer.importLibraryModule("prog8_lib")
if (compilerOptions.launcher == LauncherType.BASIC && compilerOptions.output != OutputType.PRG)
errors.err("BASIC launcher requires output type PRG", program.toplevelModule.position)
errors.report()
return Triple(programAst, compilerOptions, importedFiles)
return Triple(program, compilerOptions, importedFiles)
}
fun determineCompilationOptions(program: Program, compTarget: ICompilationTarget): CompilationOptions {
@ -237,7 +236,7 @@ fun determineCompilationOptions(program: Program, compTarget: ICompilationTarget
// error will be printed by the astchecker
}
if (zpType == ZeropageType.FLOATSAFE && compTarget.name == Cx16Target.name) {
if (zpType == ZeropageType.FLOATSAFE && compTarget.name == Cx16Target.NAME) {
System.err.println("Warning: zp option floatsafe changed to basicsafe for cx16 target")
zpType = ZeropageType.BASICSAFE
}
@ -246,6 +245,7 @@ fun determineCompilationOptions(program: Program, compTarget: ICompilationTarget
.asSequence()
.filter { it is Directive && it.directive == "%zpreserved" }
.map { (it as Directive).args }
.filter { it.size==2 && it[0].int!=null && it[1].int!=null }
.map { it[0].int!!..it[1].int!! }
.toList()
@ -274,63 +274,66 @@ fun determineCompilationOptions(program: Program, compTarget: ICompilationTarget
)
}
private fun processAst(programAst: Program, errors: IErrorReporter, compilerOptions: CompilationOptions) {
private fun processAst(program: Program, errors: IErrorReporter, compilerOptions: CompilationOptions) {
// perform initial syntax checks and processings
println("Processing for target ${compilerOptions.compTarget.name}...")
programAst.checkIdentifiers(errors, compilerOptions)
println("Analyzing code...")
program.preprocessAst(errors)
program.checkIdentifiers(errors, compilerOptions)
errors.report()
// TODO: turning char literals into UBYTEs via an encoding should really happen in code gen - but for that we'd need DataType.CHAR
// NOTE: we will then lose the opportunity to do constant-folding on any expression containing a char literal, but how often will those occur?
// Also they might be optimized away eventually in codegen or by the assembler even
programAst.charLiteralsToUByteLiterals(errors, compilerOptions.compTarget)
// ...but what do we gain from this? We can leave it as it is now: where a char literal is no more than syntactic sugar for an UBYTE value.
// By introduction a CHAR dt, we will also lose the opportunity to do constant-folding on any expression containing a char literal.
// Yes this is different from strings that are only encoded in the code gen phase.
program.charLiteralsToUByteLiterals(compilerOptions.compTarget)
program.constantFold(errors, compilerOptions.compTarget)
errors.report()
programAst.constantFold(errors, compilerOptions.compTarget)
program.desugaring(errors)
errors.report()
programAst.reorderStatements(errors)
program.reorderStatements(errors, compilerOptions)
errors.report()
programAst.addTypecasts(errors)
program.addTypecasts(errors, compilerOptions)
errors.report()
programAst.variousCleanups(programAst, errors)
program.variousCleanups(errors, compilerOptions)
errors.report()
programAst.checkValid(compilerOptions, errors, compilerOptions.compTarget)
program.checkValid(errors, compilerOptions)
errors.report()
programAst.checkIdentifiers(errors, compilerOptions)
program.checkIdentifiers(errors, compilerOptions)
errors.report()
}
private fun optimizeAst(programAst: Program, errors: IErrorReporter, functions: IBuiltinFunctions, compTarget: ICompilationTarget, options: CompilationOptions) {
private fun optimizeAst(program: Program, compilerOptions: CompilationOptions, errors: IErrorReporter, functions: IBuiltinFunctions, compTarget: ICompilationTarget) {
// optimize the parse tree
println("Optimizing...")
val remover = UnusedCodeRemover(programAst, errors, compTarget)
remover.visit(programAst)
val remover = UnusedCodeRemover(program, errors, compTarget)
remover.visit(program)
remover.applyModifications()
while (true) {
// keep optimizing expressions and statements until no more steps remain
val optsDone1 = programAst.simplifyExpressions()
val optsDone2 = programAst.splitBinaryExpressions(compTarget)
val optsDone3 = programAst.optimizeStatements(errors, functions, compTarget)
programAst.constantFold(errors, compTarget) // because simplified statements and expressions can result in more constants that can be folded away
val optsDone1 = program.simplifyExpressions(errors)
val optsDone2 = program.splitBinaryExpressions(compilerOptions, compTarget)
val optsDone3 = program.optimizeStatements(errors, functions, compTarget)
program.constantFold(errors, compTarget) // because simplified statements and expressions can result in more constants that can be folded away
errors.report()
if (optsDone1 + optsDone2 + optsDone3 == 0)
break
}
errors.report()
}
private fun postprocessAst(programAst: Program, errors: IErrorReporter, compilerOptions: CompilationOptions) {
programAst.addTypecasts(errors)
private fun postprocessAst(program: Program, errors: IErrorReporter, compilerOptions: CompilationOptions) {
program.desugaring(errors)
program.addTypecasts(errors, compilerOptions)
errors.report()
programAst.variousCleanups(programAst, errors)
programAst.checkValid(compilerOptions, errors, compilerOptions.compTarget) // check if final tree is still valid
errors.report()
val callGraph = CallGraph(programAst)
program.variousCleanups(errors, compilerOptions)
val callGraph = CallGraph(program)
callGraph.checkRecursiveCalls(errors)
errors.report()
programAst.verifyFunctionArgTypes()
programAst.moveMainAndStartToFirst()
program.verifyFunctionArgTypes()
program.moveMainAndStartToFirst()
program.checkValid(errors, compilerOptions) // check if final tree is still valid
errors.report()
}
private sealed class WriteAssemblyResult {
@ -338,58 +341,74 @@ private sealed class WriteAssemblyResult {
class Fail(val error: String): WriteAssemblyResult()
}
private fun writeAssembly(programAst: Program,
private fun writeAssembly(program: Program,
errors: IErrorReporter,
outputDir: Path,
compilerOptions: CompilationOptions): WriteAssemblyResult {
compilerOptions: CompilationOptions
): WriteAssemblyResult {
// asm generation directly from the Ast
programAst.processAstBeforeAsmGeneration(errors, compilerOptions.compTarget)
errors.report()
// printAst(programAst)
compilerOptions.compTarget.machine.initializeZeropage(compilerOptions)
val assembly = asmGeneratorFor(compilerOptions.compTarget,
programAst,
errors,
compilerOptions.compTarget.machine.zeropage,
compilerOptions,
outputDir).compileToAssembly()
val variables = VariableExtractor().extractVars(program)
program.processAstBeforeAsmGeneration(compilerOptions, variables, errors)
errors.report()
return if(assembly.valid && errors.noErrors()) {
val assemblerReturnStatus = assembly.assemble(compilerOptions)
if(assemblerReturnStatus!=0)
WriteAssemblyResult.Fail("assembler step failed with return code $assemblerReturnStatus")
else {
// TODO make removing all VarDecls work, but this needs inferType to be able to get its information from somewhere else as the VarDecl nodes in the Ast,
// or don't use inferType at all anymore and "bake the type information" into the Ast somehow.
// Note: we don't actually *need* to remove the VarDecl nodes, but it is nice as a temporary measure
// to help clean up the code that still depends on them.
// removeAllVardeclsFromAst(program)
// println("*********** AST RIGHT BEFORE ASM GENERATION *************")
// printProgram(program)
val assembly = asmGeneratorFor(program, errors, variables, compilerOptions).compileToAssembly()
errors.report()
return if(assembly!=null && errors.noErrors()) {
if(assembly.assemble(compilerOptions)) {
WriteAssemblyResult.Ok(assembly.name)
}
} else
WriteAssemblyResult.Fail("assembler step failed")
} else {
errors.report()
WriteAssemblyResult.Fail("compiler failed with errors")
}
}
fun printAst(programAst: Program) {
private fun removeAllVardeclsFromAst(program: Program) {
// remove all VarDecl nodes from the AST.
// code generation doesn't require them anymore, it operates only on the 'variables' collection.
class SearchAndRemove: IAstVisitor {
private val allVars = mutableListOf<VarDecl>()
init {
visit(program)
for (it in allVars) {
require((it.parent as IStatementContainer).statements.remove(it))
}
}
override fun visit(decl: VarDecl) {
allVars.add(decl)
}
}
SearchAndRemove()
}
fun printProgram(program: Program) {
println()
val printer = AstToSourceCode(::print, programAst)
printer.visit(programAst)
val printer = AstToSourceTextConverter(::print, program)
printer.visit(program)
println()
}
internal fun loadAsmIncludeFile(filename: String, source: SourceCode): Result<String, NoSuchFileException> {
return if (filename.startsWith(libraryFilePrefix)) {
return runCatching {
val stream = object {}.javaClass.getResourceAsStream("/prog8lib/${filename.substring(libraryFilePrefix.length)}") // TODO handle via SourceCode
stream!!.bufferedReader().use { r -> r.readText() }
}.mapError { NoSuchFileException(File(filename)) }
internal fun asmGeneratorFor(program: Program, errors: IErrorReporter, variables: IVariablesAndConsts, options: CompilationOptions): IAssemblyGenerator
{
if(options.experimentalCodegen) {
if (options.compTarget.machine.cpu in arrayOf(CpuType.CPU6502, CpuType.CPU65c02))
return prog8.codegen.experimental6502.AsmGen(program, errors, variables, options)
} else {
// first try in the isSameAs folder as where the containing file was imported from
val sib = Path(source.origin).resolveSibling(filename)
if (options.compTarget.machine.cpu in arrayOf(CpuType.CPU6502, CpuType.CPU65c02))
return prog8.codegen.cpu6502.AsmGen(program, errors, variables, options)
}
if (sib.toFile().isFile)
Ok(sib.toFile().readText())
else
Ok(File(filename).readText())
}
throw NotImplementedError("no asm generator for cpu ${options.compTarget.machine.cpu}")
}

32
compiler/src/prog8/compiler/ErrorReporting.kt → compiler/src/prog8/compiler/ErrorReporter.kt
View File

@ -1,16 +1,7 @@
package prog8.compiler
import prog8.ast.base.Position
import prog8.parser.ParsingFailedError
interface IErrorReporter {
fun err(msg: String, position: Position)
fun warn(msg: String, position: Position)
fun noErrors(): Boolean
fun report()
}
import prog8.compilerinterface.IErrorReporter
internal class ErrorReporter: IErrorReporter {
private enum class MessageSeverity {
@ -33,24 +24,29 @@ internal class ErrorReporter: IErrorReporter {
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 printer = when(it.severity) {
MessageSeverity.WARNING -> System.out
MessageSeverity.ERROR -> System.err
}
val msg = "${it.position.toClickableStr()} ${it.severity} ${it.message}".trim()
when(it.severity) {
MessageSeverity.ERROR -> printer.print("\u001b[91m") // bright red
MessageSeverity.WARNING -> printer.print("\u001b[93m") // bright yellow
}
val msg = "${it.severity} ${it.position.toClickableStr()} ${it.message}".trim()
if(msg !in alreadyReportedMessages) {
System.err.println(msg)
printer.println(msg)
alreadyReportedMessages.add(msg)
when(it.severity) {
MessageSeverity.WARNING -> numWarnings++
MessageSeverity.ERROR -> numErrors++
}
}
System.err.print("\u001b[0m") // reset color
printer.print("\u001b[0m") // reset color
}
System.out.flush()
System.err.flush()
messages.clear()
if(numErrors>0)
throw ParsingFailedError("There are $numErrors errors and $numWarnings warnings.")
finalizeNumErrors(numErrors, numWarnings)
}
override fun noErrors() = messages.none { it.severity==MessageSeverity.ERROR }

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

@ -1,6 +0,0 @@
package prog8.compiler
interface IStringEncoding {
fun encodeString(str: String, altEncoding: Boolean): List<Short>
fun decodeString(bytes: List<Short>, altEncoding: Boolean): String
}

40
compiler/src/prog8/compiler/ModuleImporter.kt
View File

@ -7,6 +7,7 @@ import prog8.ast.base.Position
import prog8.ast.base.SyntaxError
import prog8.ast.statements.Directive
import prog8.ast.statements.DirectiveArg
import prog8.compilerinterface.IErrorReporter
import prog8.parser.Prog8Parser
import prog8.parser.SourceCode
import java.io.File
@ -33,29 +34,24 @@ class ModuleImporter(private val program: Program,
val srcPath = when (candidates.size) {
0 -> return Err(NoSuchFileException(
file = filePath.normalize().toFile(),
reason = "searched in $searchIn"))
reason = "Searched in $searchIn"))
1 -> candidates.first()
else -> candidates.first() // when more candiates, pick the one from the first location
}
val logMsg = "importing '${filePath.nameWithoutExtension}' (from file $srcPath)"
println(logMsg)
val module = importModule(SourceCode.File(srcPath))
return if(module==null)
Err(NoSuchFileException(srcPath.toFile()))
else
Ok(module)
val source = SourceCode.File(srcPath)
return Ok(importModule(source))
}
fun importLibraryModule(name: String): Module? {
val import = Directive("%import", listOf(
DirectiveArg("", name, 42, position = Position("<<<implicit-import>>>", 0, 0, 0))
DirectiveArg("", name, 42u, position = Position("<<<implicit-import>>>", 0, 0, 0))
), Position("<<<implicit-import>>>", 0, 0, 0))
return executeImportDirective(import, null)
}
private fun importModule(src: SourceCode) : Module? {
private fun importModule(src: SourceCode) : Module {
printImportingMessage(src.name, src.origin)
val moduleAst = Prog8Parser.parseModule(src)
program.addModule(moduleAst)
@ -93,7 +89,6 @@ class ModuleImporter(private val program: Program,
val importedModule =
moduleResourceSrc.fold(
success = {
println("importing '$moduleName' (from internal ${it.origin})")
importModule(it)
},
failure = {
@ -101,18 +96,16 @@ class ModuleImporter(private val program: Program,
val moduleSrc = getModuleFromFile(moduleName, importingModule)
moduleSrc.fold(
success = {
println("importing '$moduleName' (from file ${it.origin})")
importModule(it)
},
failure = {
errors.err("no module found with name $moduleName", import.position)
errors.err("no module found with name $moduleName. Searched in: $sourcePaths (and internal libraries)", import.position)
return null
}
)
}
)
if(importedModule!=null)
removeDirectivesFromImportedModule(importedModule)
return importedModule
}
@ -142,7 +135,6 @@ class ModuleImporter(private val program: Program,
} else {
val dropCurDir = if(sourcePaths.isNotEmpty() && sourcePaths[0].name == ".") 1 else 0
sourcePaths.drop(dropCurDir) +
// TODO: won't work until Prog8Parser is fixed s.t. it fully initializes the modules it returns. // hm, what won't work?)
listOf(Path(importingModule.position.file).parent ?: Path("")) +
listOf(Path(".", "prog8lib"))
}
@ -150,10 +142,24 @@ class ModuleImporter(private val program: Program,
locations.forEach {
try {
return Ok(SourceCode.File(it.resolve(fileName)))
} catch (e: NoSuchFileException) {
} catch (_: NoSuchFileException) {
}
}
return Err(NoSuchFileException(File("name")))
}
fun printImportingMessage(module: String, origin: String) {
print(" importing '$module' (from ${origin})")
ansiEraseRestOfLine(false)
print("\r")
}
companion object {
fun ansiEraseRestOfLine(newline: Boolean) {
print("\u001b[0K")
if(newline)
println()
}
}
}

95
compiler/src/prog8/compiler/Zeropage.kt
View File

@ -1,95 +0,0 @@
package prog8.compiler
import prog8.ast.base.*
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_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.
val allowedDatatypes = NumericDatatypes
fun availableBytes() = if(options.zeropage==ZeropageType.DONTUSE) 0 else free.size
fun hasByteAvailable() = if(options.zeropage==ZeropageType.DONTUSE) false else free.isNotEmpty()
fun availableWords(): Int {
if(options.zeropage==ZeropageType.DONTUSE)
return 0
val words = free.windowed(2).filter { it[0] == it[1]-1 }
var nonOverlappingWordsCount = 0
var prevMsbLoc = -1
for(w in words) {
if(w[0]!=prevMsbLoc) {
nonOverlappingWordsCount++
prevMsbLoc = w[1]
}
}
return nonOverlappingWordsCount
}
fun hasWordAvailable(): Boolean {
if(options.zeropage==ZeropageType.DONTUSE)
return false
return free.windowed(2).any { it[0] == it[1] - 1 }
}
fun allocate(scopedname: String, datatype: DataType, position: Position?, errors: IErrorReporter): 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")
val size =
when (datatype) {
in ByteDatatypes -> 1
in WordDatatypes -> 2
DataType.FLOAT -> {
if (options.floats) {
if(position!=null)
errors.warn("allocated a large value (float) in zeropage", position)
else
errors.warn("$scopedname: allocated a large value (float) in zeropage", position ?: Position.DUMMY)
5
} else throw CompilerException("floating point option not enabled")
}
else -> throw CompilerException("cannot put datatype $datatype in zeropage")
}
if(free.size > 0) {
if(size==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.minOrNull()!! .. free.maxOrNull()!!+1) {
if (sequentialFree(candidate, size))
return makeAllocation(candidate, size, datatype, scopedname)
}
}
throw ZeropageDepletedError("ERROR: no free space in ZP to allocate $size sequential bytes")
}
protected fun reserve(range: IntRange) = free.removeAll(range)
private fun makeAllocation(address: Int, size: Int, datatype: DataType, name: String?): Int {
free.removeAll(address until address+size)
allocations[address] = (name ?: "<unnamed>") to datatype
return address
}
private fun loneByte(address: Int) = address in free && address-1 !in free && address+1 !in free
private fun sequentialFree(address: Int, size: Int) = free.containsAll((address until address+size).toList())
}

571
compiler/src/prog8/compiler/astprocessing/AstChecker.kt
View File

File diff suppressed because it is too large Load Diff

160
compiler/src/prog8/compiler/astprocessing/AstExtensions.kt
View File

@ -3,82 +3,42 @@ package prog8.compiler.astprocessing
import prog8.ast.Node
import prog8.ast.Program
import prog8.ast.base.DataType
import prog8.ast.base.VarDeclType
import prog8.ast.expressions.*
import prog8.ast.statements.AssignTarget
import prog8.ast.expressions.CharLiteral
import prog8.ast.expressions.IdentifierReference
import prog8.ast.expressions.NumericLiteral
import prog8.ast.statements.Directive
import prog8.ast.statements.VarDeclOrigin
import prog8.ast.walk.AstWalker
import prog8.ast.walk.IAstModification
import prog8.compiler.BeforeAsmGenerationAstChanger
import prog8.compiler.CompilationOptions
import prog8.compiler.IErrorReporter
import prog8.compiler.IStringEncoding
import prog8.compiler.target.ICompilationTarget
import prog8.compiler.target.IMachineDefinition
import kotlin.math.abs
import prog8.compilerinterface.CompilationOptions
import prog8.compilerinterface.IErrorReporter
import prog8.compilerinterface.IStringEncoding
import prog8.compilerinterface.IVariablesAndConsts
fun RangeExpr.size(encoding: IStringEncoding): Int? {
val fromLv = (from as? NumericLiteralValue)
val toLv = (to as? NumericLiteralValue)
if(fromLv==null || toLv==null)
return null
return toConstantIntegerRange(encoding)?.count()
}
fun RangeExpr.toConstantIntegerRange(encoding: IStringEncoding): IntProgression? {
val fromVal: Int
val toVal: Int
val fromString = from as? StringLiteralValue
val toString = to as? StringLiteralValue
if(fromString!=null && toString!=null ) {
// string range -> int range over character values
fromVal = encoding.encodeString(fromString.value, fromString.altEncoding)[0].toInt()
toVal = encoding.encodeString(toString.value, fromString.altEncoding)[0].toInt()
} else {
val fromLv = from as? NumericLiteralValue
val toLv = to as? NumericLiteralValue
if(fromLv==null || toLv==null)
return null // non-constant range
// integer range
fromVal = fromLv.number.toInt()
toVal = toLv.number.toInt()
}
val stepVal = (step as? NumericLiteralValue)?.number?.toInt() ?: 1
return makeRange(fromVal, toVal, stepVal)
}
private fun makeRange(fromVal: Int, toVal: Int, stepVal: Int): IntProgression {
return when {
fromVal <= toVal -> when {
stepVal <= 0 -> IntRange.EMPTY
stepVal == 1 -> fromVal..toVal
else -> fromVal..toVal step stepVal
}
else -> when {
stepVal >= 0 -> IntRange.EMPTY
stepVal == -1 -> fromVal downTo toVal
else -> fromVal downTo toVal step abs(stepVal)
}
}
}
internal fun Program.checkValid(compilerOptions: CompilationOptions, errors: IErrorReporter, compTarget: ICompilationTarget) {
val checker = AstChecker(this, compilerOptions, errors, compTarget)
internal fun Program.checkValid(errors: IErrorReporter, compilerOptions: CompilationOptions) {
// semantic analysis to see if the program is valid.
val parentChecker = ParentNodeChecker()
parentChecker.visit(this)
val checker = AstChecker(this, errors, compilerOptions)
checker.visit(this)
}
internal fun Program.processAstBeforeAsmGeneration(errors: IErrorReporter, compTarget: ICompilationTarget) {
val fixer = BeforeAsmGenerationAstChanger(this, errors, compTarget)
internal fun Program.processAstBeforeAsmGeneration(compilerOptions: CompilationOptions, variables: IVariablesAndConsts, errors: IErrorReporter) {
val fixer = BeforeAsmAstChanger(this, compilerOptions, variables, errors)
fixer.visit(this)
while(errors.noErrors() && fixer.applyModifications()>0) {
fixer.visit(this)
}
val cleaner = BeforeAsmTypecastCleaner(this, errors)
cleaner.visit(this)
while(errors.noErrors() && cleaner.applyModifications()>0) {
cleaner.visit(this)
}
}
internal fun Program.reorderStatements(errors: IErrorReporter) {
val reorder = StatementReorderer(this, errors)
internal fun Program.reorderStatements(errors: IErrorReporter, options: CompilationOptions) {
val reorder = StatementReorderer(this, errors, options)
reorder.visit(this)
if(errors.noErrors()) {
reorder.applyModifications()
@ -88,12 +48,12 @@ internal fun Program.reorderStatements(errors: IErrorReporter) {
}
}
internal fun Program.charLiteralsToUByteLiterals(errors: IErrorReporter, enc: IStringEncoding) {
internal fun Program.charLiteralsToUByteLiterals(enc: IStringEncoding) {
val walker = object : AstWalker() {
override fun after(char: CharLiteral, parent: Node): Iterable<IAstModification> {
return listOf(IAstModification.ReplaceNode(
char,
NumericLiteralValue(DataType.UBYTE, enc.encodeString(char.value.toString(), char.altEncoding)[0].toInt(), char.position),
NumericLiteral(DataType.UBYTE, enc.encodeString(char.value.toString(), char.encoding)[0].toDouble(), char.position),
parent
))
}
@ -102,20 +62,34 @@ internal fun Program.charLiteralsToUByteLiterals(errors: IErrorReporter, enc: IS
walker.applyModifications()
}
internal fun Program.addTypecasts(errors: IErrorReporter) {
val caster = TypecastsAdder(this, errors)
internal fun Program.addTypecasts(errors: IErrorReporter, options: CompilationOptions) {
val caster = TypecastsAdder(this, options, errors)
caster.visit(this)
caster.applyModifications()
}
fun Program.desugaring(errors: IErrorReporter): Int {
val desugar = CodeDesugarer(this, errors)
desugar.visit(this)
return desugar.applyModifications()
}
internal fun Program.verifyFunctionArgTypes() {
val fixer = VerifyFunctionArgTypes(this)
fixer.visit(this)
}
internal fun Program.preprocessAst(errors: IErrorReporter) {
val transforms = AstPreprocessor(this, errors)
transforms.visit(this)
var mods = transforms.applyModifications()
while(mods>0)
mods = transforms.applyModifications()
}
internal fun Program.checkIdentifiers(errors: IErrorReporter, options: CompilationOptions) {
val checker2 = AstIdentifiersChecker(this, errors, options.compTarget)
val checker2 = AstIdentifiersChecker(errors, this, options.compTarget)
checker2.visit(this)
if(errors.noErrors()) {
@ -124,18 +98,18 @@ internal fun Program.checkIdentifiers(errors: IErrorReporter, options: Compilati
transforms.applyModifications()
val lit2decl = LiteralsToAutoVars(this)
lit2decl.visit(this)
if(errors.noErrors())
lit2decl.applyModifications()
}
}
internal fun Program.variousCleanups(program: Program, errors: IErrorReporter) {
val process = VariousCleanups(program, errors)
internal fun Program.variousCleanups(errors: IErrorReporter, options: CompilationOptions) {
val process = VariousCleanups(this, errors, options)
process.visit(this)
if(errors.noErrors())
process.applyModifications()
}
internal fun Program.moveMainAndStartToFirst() {
// the module containing the program entrypoint is moved to the first in the sequence.
// the "main" block containing the entrypoint is moved to the top in there,
@ -166,46 +140,10 @@ internal fun Program.moveMainAndStartToFirst() {
}
}
internal fun AssignTarget.isInRegularRAMof(machine: IMachineDefinition): Boolean {
val memAddr = memoryAddress
val arrayIdx = arrayindexed
val ident = identifier
when {
memAddr != null -> {
return when (memAddr.addressExpression) {
is NumericLiteralValue -> {
machine.isRegularRAMaddress((memAddr.addressExpression as NumericLiteralValue).number.toInt())
}
is IdentifierReference -> {
val program = definingModule.program
val decl = (memAddr.addressExpression as IdentifierReference).targetVarDecl(program)
if ((decl?.type == VarDeclType.VAR || decl?.type == VarDeclType.CONST) && decl.value is NumericLiteralValue)
machine.isRegularRAMaddress((decl.value as NumericLiteralValue).number.toInt())
else
false
}
else -> false
}
}
arrayIdx != null -> {
val program = definingModule.program
val targetStmt = arrayIdx.arrayvar.targetVarDecl(program)
return if (targetStmt?.type == VarDeclType.MEMORY) {
val addr = targetStmt.value as? NumericLiteralValue
if (addr != null)
machine.isRegularRAMaddress(addr.number.toInt())
else
false
} else true
}
ident != null -> {
val program = definingModule.program
val decl = ident.targetVarDecl(program)!!
return if (decl.type == VarDeclType.MEMORY && decl.value is NumericLiteralValue)
machine.isRegularRAMaddress((decl.value as NumericLiteralValue).number.toInt())
else
true
}
else -> return true
internal fun IdentifierReference.isSubroutineParameter(program: Program): Boolean {
val vardecl = this.targetVarDecl(program)
if(vardecl!=null && vardecl.origin==VarDeclOrigin.SUBROUTINEPARAM) {
return vardecl.definingSubroutine?.parameters?.any { it.name==vardecl.name } == true
}
return false
}

75
compiler/src/prog8/compiler/astprocessing/AstIdentifiersChecker.kt
View File

@ -1,15 +1,21 @@
package prog8.compiler.astprocessing
import prog8.ast.IFunctionCall
import prog8.ast.Node
import prog8.ast.Program
import prog8.ast.base.Position
import prog8.ast.expressions.StringLiteralValue
import prog8.ast.expressions.FunctionCallExpression
import prog8.ast.expressions.StringLiteral
import prog8.ast.statements.*
import prog8.ast.walk.IAstVisitor
import prog8.compiler.IErrorReporter
import prog8.compiler.functions.BuiltinFunctions
import prog8.compiler.target.ICompilationTarget
import prog8.compilerinterface.BuiltinFunctions
import prog8.compilerinterface.Encoding
import prog8.compilerinterface.ICompilationTarget
import prog8.compilerinterface.IErrorReporter
internal class AstIdentifiersChecker(private val program: Program, private val errors: IErrorReporter, private val compTarget: ICompilationTarget) : IAstVisitor {
internal class AstIdentifiersChecker(private val errors: IErrorReporter,
private val program: Program,
private val compTarget: ICompilationTarget) : IAstVisitor {
private var blocks = mutableMapOf<String, Block>()
private fun nameError(name: String, position: Position, existing: Statement) {
@ -42,7 +48,7 @@ internal class AstIdentifiersChecker(private val program: Program, private val e
if(decl.name in compTarget.machine.opcodeNames)
errors.err("can't use a cpu opcode name as a symbol: '${decl.name}'", decl.position)
val existing = program.namespace.lookup(listOf(decl.name), decl)
val existing = decl.definingScope.lookup(listOf(decl.name))
if (existing != null && existing !== decl)
nameError(decl.name, decl.position, existing)
@ -65,22 +71,19 @@ internal class AstIdentifiersChecker(private val program: Program, private val e
// if (subroutine.parameters.any { it.name in BuiltinFunctions })
// checkResult.add(NameError("builtin function name cannot be used as parameter", subroutine.position))
val existing = program.namespace.lookup(listOf(subroutine.name), subroutine)
val existing = subroutine.lookup(listOf(subroutine.name))
if (existing != null && existing !== subroutine)
nameError(subroutine.name, subroutine.position, existing)
// check that there are no local variables, labels, or other subs that redefine the subroutine's parameters. Blocks are okay.
// check that there are no local symbols (variables, labels, subs) that redefine the subroutine's parameters.
val symbolsInSub = subroutine.allDefinedSymbols
val namesInSub = symbolsInSub.map{ it.first }.toSet()
val paramNames = subroutine.parameters.map { it.name }.toSet()
val paramsToCheck = paramNames.intersect(namesInSub)
for(name in paramsToCheck) {
val labelOrVar = subroutine.getLabelOrVariable(name)
if(labelOrVar!=null && labelOrVar.position != subroutine.position)
nameError(name, labelOrVar.position, subroutine)
val sub = subroutine.statements.firstOrNull { it is Subroutine && it.name==name}
if(sub!=null)
nameError(name, subroutine.position, sub)
val symbol = subroutine.searchSymbol(name)
if(symbol!=null && (symbol as? VarDecl)?.subroutineParameter==null)
nameError(name, symbol.position, subroutine)
}
if(subroutine.isAsmSubroutine && subroutine.statements.any{it !is InlineAssembly}) {
@ -119,10 +122,52 @@ internal class AstIdentifiersChecker(private val program: Program, private val e
super.visit(label)
}
override fun visit(string: StringLiteralValue) {
override fun visit(string: StringLiteral) {
if (string.value.length > 255)
errors.err("string literal length max is 255", string.position)
super.visit(string)
}
override fun visit(functionCallExpr: FunctionCallExpression) = visitFunctionCall(functionCallExpr)
override fun visit(functionCallStatement: FunctionCallStatement) = visitFunctionCall(functionCallStatement)
private fun visitFunctionCall(call: IFunctionCall) {
when (val target = call.target.targetStatement(program)) {
is Subroutine -> {
if(call.args.size != target.parameters.size) {
val pos = (if(call.args.any()) call.args[0] else (call as Node)).position
errors.err("invalid number of arguments", pos)
}
}
is BuiltinFunctionPlaceholder -> {
val func = BuiltinFunctions.getValue(target.name)
if(call.args.size != func.parameters.size) {
val pos = (if(call.args.any()) call.args[0] else (call as Node)).position
errors.err("invalid number of arguments", pos)
}
if(func.name=="memory") {
val name = call.args[0] as? StringLiteral
if(name!=null) {
val processed = name.value.map {
if(it.isLetterOrDigit())
it
else
'_'
}.joinToString("")
call.args[0] = StringLiteral(processed, Encoding.PETSCII, name.position)
call.args[0].linkParents(call as Node)
}
}
}
is Label -> {
if(call.args.isNotEmpty()) {
val pos = (if(call.args.any()) call.args[0] else (call as Node)).position
errors.err("cannot use arguments when calling a label", pos)
}
}
null -> {}
else -> errors.err("cannot call this as a subroutine or function", call.target.position)
}
}
}

102
compiler/src/prog8/compiler/astprocessing/AstPreprocessor.kt Normal file
View File

@ -0,0 +1,102 @@
package prog8.compiler.astprocessing
import prog8.ast.Node
import prog8.ast.Program
import prog8.ast.base.NumericDatatypes
import prog8.ast.base.SyntaxError
import prog8.ast.base.VarDeclType
import prog8.ast.expressions.*
import prog8.ast.statements.*
import prog8.ast.walk.AstWalker
import prog8.ast.walk.IAstModification
import prog8.compilerinterface.IErrorReporter
class AstPreprocessor(val program: Program, val errors: IErrorReporter) : AstWalker() {
override fun after(range: RangeExpression, parent: Node): Iterable<IAstModification> {
// has to be done before the constant folding, otherwise certain checks there will fail on invalid range sizes
val modifications = mutableListOf<IAstModification>()
if(range.from !is NumericLiteral) {
try {
val constval = range.from.constValue(program)
if (constval != null)
modifications += IAstModification.ReplaceNode(range.from, constval, range)
} catch (x: SyntaxError) {
// syntax errors will be reported later
}
}
if(range.to !is NumericLiteral) {
try {
val constval = range.to.constValue(program)
if(constval!=null)
modifications += IAstModification.ReplaceNode(range.to, constval, range)
} catch (x: SyntaxError) {
// syntax errors will be reported later
}
}
if(range.step !is NumericLiteral) {
try {
val constval = range.step.constValue(program)
if(constval!=null)
modifications += IAstModification.ReplaceNode(range.step, constval, range)
} catch (x: SyntaxError) {
// syntax errors will be reported later
}
}
return modifications
}
override fun before(scope: AnonymousScope, parent: Node): Iterable<IAstModification> {
// move vardecls in Anonymous scope up to the containing subroutine
// and add initialization assignment in its place if needed
val vars = scope.statements.asSequence().filterIsInstance<VarDecl>()
val parentscope = scope.definingScope
if(vars.any() && parentscope !== parent) {
val movements = mutableListOf<IAstModification>()
val replacements = mutableListOf<IAstModification>()
for(decl in vars) {
if(decl.type != VarDeclType.VAR) {
movements.add(IAstModification.InsertFirst(decl, parentscope))
replacements.add(IAstModification.Remove(decl, scope))
} else {
if(decl.value!=null && decl.datatype in NumericDatatypes) {
val target = AssignTarget(IdentifierReference(listOf(decl.name), decl.position), null, null, decl.position)
val assign = Assignment(target, decl.value!!, AssignmentOrigin.VARINIT, decl.position)
replacements.add(IAstModification.ReplaceNode(decl, assign, scope))
decl.value = null
decl.allowInitializeWithZero = false
} else {
replacements.add(IAstModification.Remove(decl, scope))
}
movements.add(IAstModification.InsertFirst(decl, parentscope))
}
}
return movements + replacements
}
return noModifications
}
override fun after(expr: BinaryExpression, parent: Node): Iterable<IAstModification> {
// this has to be done here becuse otherwise the string / range literal values will have been replaced by variables
if(expr.operator=="in") {
val containment = ContainmentCheck(expr.left, expr.right, expr.position)
return listOf(IAstModification.ReplaceNode(expr, containment, parent))
}
return noModifications
}
override fun after(decl: VarDecl, parent: Node): Iterable<IAstModification> {
val nextAssignment = decl.nextSibling() as? Assignment
if(nextAssignment!=null && nextAssignment.origin!=AssignmentOrigin.VARINIT) {
// check if it's a proper initializer assignment for the variable
if(decl.value==null && nextAssignment.target.identifier?.targetVarDecl(program)===decl) {
if(!nextAssignment.value.referencesIdentifier(nextAssignment.target.identifier!!.nameInSource))
nextAssignment.origin = AssignmentOrigin.VARINIT
}
}
return noModifications
}
}

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