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ed:main ed:dev ed:Ed94-patch-1 ed:defines_n_macros_upgrades ed:string_distinctings_refactor ed:de_oop ed:broken_changes ed:preprocessor_support ed:parser_context_stack ed:designchanges_to_bettercodetypes
ed:v0.25-Alpha ed:v0.24-Alpha ed:v0.23-Alpha ed:v0.22-Alpha ed:v0.21-Alpha ed:v0.20-Alpha ed:v0.19-Alpha ed:v0.18-Alpha ed:v0.17-Alpha ed:v0.16-Alpha ed:v0.15-Alpha ed:v0.14-Alpha ed:v0.13-Alpha ed:v0.12-Alpha ed:v0.11-Alpha ed:v0.10-Alpha ed:v0.9-Alpha ed:v0.8-Alpha ed:v0.7-Alpha ed:v0.6-Alpha ed:v0.5-alpha ed:v0.4-Alpha ed:V0.3-Alpha ed:V0.1-Alpha ed:V0.2-Alpha
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compare: ed:de_oop
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ed:dev ed:main ed:Ed94-patch-1 ed:defines_n_macros_upgrades ed:string_distinctings_refactor ed:de_oop ed:broken_changes ed:preprocessor_support ed:parser_context_stack ed:designchanges_to_bettercodetypes
ed:v0.25-Alpha ed:v0.24-Alpha ed:v0.23-Alpha ed:v0.22-Alpha ed:v0.21-Alpha ed:v0.20-Alpha ed:v0.19-Alpha ed:v0.18-Alpha ed:v0.17-Alpha ed:v0.16-Alpha ed:v0.15-Alpha ed:v0.14-Alpha ed:v0.13-Alpha ed:v0.12-Alpha ed:v0.11-Alpha ed:v0.10-Alpha ed:v0.9-Alpha ed:v0.8-Alpha ed:v0.7-Alpha ed:v0.6-Alpha ed:v0.5-alpha ed:v0.4-Alpha ed:V0.3-Alpha ed:V0.1-Alpha ed:V0.2-Alpha

319 Commits
designchan ... de_oop

Author SHA1 Message Date
Ed_
0e782cdf99 minor fixees 2024-12-11 14:57:38 -05:00
Ed_
65427bd0f1 Update undef.macros.h 2024-12-11 14:08:34 -05:00
Ed_
cb898595b0 Updates to docs and various changes to project from working on them. 
- CodeParam -> CodeParams
- interfaces array weren't being used in parse_class_struct
- added enum_underlying_sig
 2024-12-11 13:33:35 -05:00
Ed_
9b86d84dd6 typo fix 2024-12-11 12:43:46 -05:00
Ed_
4dfb9031d7 separated _generic macros from base/dependencies/macro.shpp 2024-12-11 08:52:05 -05:00
Ed_
401f85f673 corrections to c_library.cpp, package_release.ps1 working for all zips 2024-12-11 02:04:22 -05:00
Ed_
caec5d8dfc fix clang format for enum_underlying 2024-12-11 00:13:36 -05:00
Ed_
44d0a9cf9d c_library compiles 2024-12-10 23:35:47 -05:00
Ed_
c0aa4fee95 updates on package_release.ps1 and clean.ps1 2024-12-10 22:42:07 -05:00
Ed_
913d9bf26b fixed clean script 2024-12-10 22:27:35 -05:00
Ed_
c8d6c27f07 singleheader compiles again 2024-12-10 22:20:40 -05:00
Ed_
aecc2c59dd segemented builds 2024-12-10 21:59:13 -05:00
Ed_
0e32838da1 base works 2024-12-10 21:35:46 -05:00
Ed_
ef78772278 work on gettings things compiling again after restructuring 2024-12-10 20:45:00 -05:00
Ed_
8891657eb1 Large updates to docs 2024-12-10 19:31:50 -05:00
Ed_
a18b5b97aa typo 2024-12-10 16:58:04 -05:00
Ed_
0ea88a263d third test 2024-12-10 16:56:42 -05:00
Ed_
eea4ebf5c4 another test 2024-12-10 16:55:04 -05:00
Ed_
7351ba6175 testing link embedding 2024-12-10 16:53:07 -05:00
Ed_
8e3e66b3c1 Updates to docs and scripts 2024-12-10 16:38:01 -05:00
Ed_
2c51a2f9c8 WIP: Restructuring project 2024-12-10 16:13:14 -05:00
Ed_
e3b3882443 correctionns to gen_unreal_engine 2024-12-10 13:57:12 -05:00
Ed_
0046c4a223 c_library refacotring works, and compiles with all content from the base project. 
I need to make the refactor step happen before formatting with clang-format in the metaprogram instead of calling it from powershell
 2024-12-10 13:56:56 -05:00
Ed_
5aaef0f1a2 get rid of Test.josnc 
not sure how that got there...
 2024-12-10 10:29:34 -05:00
Ed_
abdad1a436 demacro AST and Code forwards/typedefs 2024-12-10 10:24:48 -05:00
Ed_
a4143b537d builder compiles in c (some issues with filtering out preprocess #if) 2024-12-10 07:24:32 -05:00
Ed_
0ccffe3f80 interface.untyped.cpp impl compiles in gnerated c library 2024-12-09 23:19:19 -05:00
Ed_
cd7548c3d4 parser finally compiles 2024-12-09 22:51:24 -05:00
Ed_
79a1951861 more prep for parser.cpp for c-library gen 2024-12-09 20:01:46 -05:00
Ed_
e786d7c3b6 prepped lexer and parser for c-library generation 2024-12-09 16:45:18 -05:00
Ed_
e6f30c7e1d TokType compiles for c lbirary 2024-12-09 15:23:47 -05:00
Ed_
6147912783 gen.h compiles with interface.upfront.cpp injected 2024-12-09 14:55:02 -05:00
Ed_
ed9f719a07 impl up to interface.cpp compiles (upfront next) 2024-12-09 01:33:37 -05:00
Ed_
500f216da2 ast.cpp compiles (among other things) 2024-12-08 23:10:10 -05:00
Ed_
12e31276eb dependency impl compiles for C11 library (doing components next) 2024-12-08 20:00:16 -05:00
Ed_
65c3fabc52 C-library gen progress: Header files mostly done, starting dep c impl and fixes to generic selection generation 2024-12-08 16:37:04 -05:00
Ed_
c016e245eb still misbehaving (going to try alignas next...) 2024-12-07 20:49:43 -05:00
Ed_
99dbc499fa WIP: code_types.hpp c_library.cpp conversion (issue with C struct padding on asts) 2024-12-07 19:46:19 -05:00
Ed_
1c133bfc8d Massive total progress on c_library generation: (Summary of last 3 WIP commits) 
- No longer using GEN_API_C_* macros as C-library wont need them and if you need C linkage there is no need to use the c++ library.
- GEN_C_LIKE_CPP replaces GEN_SUPPORT_CPP_MEMBER_FEATURES && GEN_SUPPORT_CPP_REFERENCES
  a. If users don't want to use member functions, function overloading, or referencese they can just this one macro to before including the library.
- Enums aren't accomodated in C++ sources, they entirely converted in c_libray.cpp
- ast.hpp now properly generates with C variant
- Fully prepared code_types.hpp for C library gen (not tested yet)
- Generated enums managed by helper.hpp now properly generate for C library.
 2024-12-07 17:58:56 -05:00
Ed_
451b71884c WIP: Broken af 2024-12-07 17:17:02 -05:00
Ed_
4d638a7255 borken : lots of stuff changed, explaining in later commit...v 2024-12-07 00:21:09 -05:00
Ed_
ceea184d5a Update to c_library.cpp (now up to ast.hpp) 2024-12-06 05:29:36 -05:00
Ed_
92e0d3ab8b DId a pass on ast.hpp, types.hpp and helper.hpp for C compatability (unfortuantely clang-format doesn't like my enum macro... 2024-12-06 05:29:17 -05:00
Ed_
9b059dca47 C-library Finished setting up header dependencies ( 2024-12-06 00:33:58 -05:00
Ed_
46562d54e7 parser: added support for enum_underlying macro 2024-12-06 00:33:53 -05:00
Ed_
ec07c70dcf verified the C hashtable has parity with the C++ templated gencpp hashtable. 2024-12-05 23:02:26 -05:00
Ed_
63dd77237a update version (forgot) 2024-12-05 21:37:39 -05:00
Ed_
cf3908c6f0 Added alpha warning message to header_start.hpp files. 2024-12-05 21:37:07 -05:00
Ed_
266163557f Finished draft pass verifying containers.array.hpp is equivalent to container.hpp's array. 
gen_generic_selection_function_macro now works generically
Imprvoed _Generic function overloading examples
 2024-12-05 21:01:04 -05:00
Ed_
8bb2bc7b1b fixes on containers (compiles but still verifying parity with c++ templates 
I'm going to have to change some c++ templates to match the init interfaces as they must not be in the return type
 2024-12-05 17:48:24 -05:00
Ed_
a3407c14d5 First compiling version of operator overloading for C! (on both msvc and clang using -std=c11 flag, using _Generic selection with some helper macros) 
Extremely satsified with how unofuscated the generated code is for _Generic.
Still fixing up the templated container code though in the c-codegen
 2024-12-05 17:04:17 -05:00
Ed_
47b9c37e94 began to setup generation of Array_ssize and StringTable in the c-library 
Still need to confirm if the these old templates require updates compared to the c++ impl
 2024-12-05 03:41:08 -05:00
Ed_
1c3134218e preogress on getting dependencies compilable in C-library 2024-12-05 02:53:14 -05:00
Ed_
a3e7ec4c72 successful compile of c_library for: platform, macros, basic_types, debug, and memory headers (and newly generated c-code) 2024-12-05 00:40:51 -05:00
Ed_
cae1555b11 wip having nasty parser issue (fixed nasty lexer bug) 2024-12-04 15:00:37 -05:00
Ed_
f7709bb64e more progress 2024-12-04 11:30:54 -05:00
Ed_
3a55af9ce4 WIP(broken): Converting base library to use c-linkage symbols only 2024-12-04 11:01:53 -05:00
Ed_
6081834687 bug fix 2024-12-03 20:42:35 -05:00
Ed_
a3548a5bd3 Added support for friend operator definitions 2024-12-03 20:21:08 -05:00
Ed_
d686831a7c Completed initial conversion 2024-12-03 19:31:26 -05:00
Ed_
ba1dd1894a WIP (Broken): Major changes to handling Strings in ast (StringCached defined as StrC) 2024-12-03 18:47:12 -05:00
Ed_
e00b2f8afb Reduced ECode to C compatible vairant 2024-12-03 15:19:39 -05:00
Ed_
72d088c566 reduction done on eoperator 2024-12-03 13:51:29 -05:00
Ed_
c6fba23173 reduce ESpecifier to c-compatiable enum 2024-12-03 13:14:14 -05:00
Ed_
d45908fb32 reduce TokType enum to c-compatiable 2024-12-03 09:50:30 -05:00
Ed_
a7c9dad9fd cpp feature reduction usage in parser 2024-12-03 09:31:27 -05:00
Ed_
63ebd0d094 removed reference type usage in components/lexer.cpp, looking into resolving 'using namespace' usage 2024-12-03 01:44:01 -05:00
Ed_
f28ae57f16 setup upfront interface to have optional vars in structs (for C later) 2024-12-03 00:45:30 -05:00
Ed_
2fe708e4be Began to reduce cpp feature usage in lexer and parser 2024-12-02 22:25:39 -05:00
Ed_
69a9abcd59 Finished AST/Code member inferface usage elimination in base library. 
Now the lexer and parser need to be elimination...
 2024-12-02 20:20:30 -05:00
Ed_
defe42c15c member proc usage reductions on CodeTypes complete (Typedef, Union, Using, Var) 
proceeding to finalize the AST interface reductions...
 2024-12-02 18:58:07 -05:00
Ed_
05e65aa464 Did reductions on Module, NS, Operator, OpCast, Pragma, PreprocessCond, Template, and Type codes 2024-12-02 18:35:34 -05:00
Ed_
8f47f3b30f Comment, Constructor, Destructor, Define, Enum, Exec, Extern, Include, Friend, Fn codes member proc usage reductions 2024-12-02 16:59:13 -05:00
Ed_
0bad61fda6 remove raw member def from code types, reduction on CodeAttributes 2024-12-02 11:20:31 -05:00
Ed_
ea18792373 Progress on member proc usage reduction (CodeParam, CodeSpecifiers) 2024-12-02 10:58:24 -05:00
Ed_
16b8a3a164 began to remove usage of code specific types member procs 2024-12-02 04:12:09 -05:00
Ed_
5b0079fb0c ast interface uage reductions 2024-12-02 03:18:52 -05:00
Ed_
9321a04ebc reduction of Code struct member function usage in base lib 2024-12-02 02:38:55 -05:00
Ed_
9b68791e38 fixes for array when not using member features. 2024-12-02 02:11:49 -05:00
Ed_
2dcc968c39 Preparing for reductions on code_types.hpp 2024-12-02 01:56:49 -05:00
Ed_
c38b077c37 Code::set_global reduction 2024-12-02 00:43:57 -05:00
Ed_
f9b5029e64 Code::is_valid rection 2024-12-02 00:41:41 -05:00
Ed_
2b24511f7d Code::is_equal reduction 2024-12-02 00:34:40 -05:00
Ed_
5cd69e1742 Code::is_body reduction 2024-12-02 00:18:54 -05:00
Ed_
007bfa0cb0 Code::duplicate reduction 2024-12-02 00:16:11 -05:00
Ed_
37c33ffb3e reduction on debug_str 2024-12-02 00:10:24 -05:00
Ed_
937235b776 progress (Code) 2024-12-02 00:03:38 -05:00
Ed_
f9c21ebc04 progress 2024-12-01 23:35:58 -05:00
Ed_
fec709cc76 Progresss 2024-12-01 21:59:43 -05:00
Ed_
80cb3f4eca Significant progress reducing c++ feature usage in the library. 2024-12-01 18:50:37 -05:00
Ed_
9e88cb8724 String::is_equal added (bad last commit) 2024-12-01 13:29:33 -05:00
Ed_
f61c1c560d String::is_equal added 2024-12-01 13:29:16 -05:00
Ed_
8ef982003a Added is_body to AST and Code types 2024-12-01 12:48:58 -05:00
Ed_
31691b1466 Fixed issue with HashTable region detection 2024-12-01 05:37:03 -05:00
Ed_
ed0c0422ad Looking into what the library's convention for enums will be. 
Most likely will just reduce them to C-enums with underlying type.
Otherwise there has to be a mechanism to drop the defs down to them anyways, and eliminate the namespace wraps.
 2024-12-01 05:30:37 -05:00
Ed_
e5acac1d18 String member definitions not longer used in the base project 2024-12-01 03:06:30 -05:00
Ed_
c7b072266f progress on c_library.cpp 2024-12-01 01:40:31 -05:00
Ed_
a96d03eaed brought over the generators of array and hashtable for c-lib gen 
From the old genc repo. Still need to fully check that its code is up to date
 2024-12-01 01:40:14 -05:00
Ed_
0b4ccac8f9 Removed usage of hashtable member procs 2024-12-01 01:39:21 -05:00
Ed_
31a3609b28 some fixes to c's fixed_arena gen 2024-11-30 23:48:14 -05:00
Ed_
fbdb870986 Finished first pass reviewing memory.hpp for C lib generation 2024-11-30 23:38:27 -05:00
Ed_
6d04165b96 Reduce cpp freatures usage of Array container. 
Almost ready to be inter-operable with C
 2024-11-30 18:54:19 -05:00
Ed_
cc245cc263 new files 2024-11-30 17:22:06 -05:00
Ed_
06deb1e836 memory.hpp no longer uses memory mappings by default 2024-11-30 17:18:49 -05:00
Ed_
5527a27f7b prepare c_library meta-program a bit 2024-11-30 16:54:03 -05:00
Ed_
a67fdef20a dir restructuring 
just making it more organized (gen_ prefix for library generation meta-programs)
 2024-11-30 16:50:53 -05:00
Ed_
056a5863b8 for the future... 2024-11-30 14:34:28 -05:00
Ed_
79eb5f1f76 strings done 2024-11-30 14:13:30 -05:00
Ed_
c6cb583518 Hashtable done 2024-11-30 13:31:59 -05:00
Ed_
34eec66f35 Array done 2024-11-30 13:14:47 -05:00
Ed_
4137ebfbd8 pool done (see previous commits for context) 2024-11-30 12:27:54 -05:00
Ed_
5958dd2055 Did arena and fixedarena changes (for reducing usage of member procs) 2024-11-30 12:16:01 -05:00
Ed_
163ad0a511 looking into removing "oop" features from base library 
I want to make member functions an optional addition the user can generate a derivative library with.
The purpose is to simplify the implementation as to make generating a C-variant simpiler.

I also want to use it as a study to see how much simpiler it makes the library without having it.
 2024-11-29 15:18:06 -05:00
Ed_
e3c2a577ba addded String::contains defs 2024-11-29 14:50:54 -05:00
Ed_
81a0376c99 Need cstdlib for systems calls in generator files. update to package_release.ps1 2024-10-27 21:38:02 -04:00
Ed_
1417a68757 updates to test validations 
They don't really work great right now...
 2024-10-27 21:19:25 -04:00
Ed_
1e4d5ce630 touchup to singleheader.cpp 2024-10-27 21:18:58 -04:00
Ed_
0f2763a115 fixes for unreal use 2024-10-27 21:18:41 -04:00
Ed_
420f452d35 More fixes found by self-parsing 2024-10-27 20:22:36 -04:00
Ed_
908c385de5 Fix exp asts having bad union definitions. 
They're not used yet but was causing self-parsing issues.
 2024-10-27 20:22:24 -04:00
Ed_
c1878265c8 Minimizing reformatting of generated library files 2024-10-27 20:01:54 -04:00
Ed_
23742868c4 Delete auxillary/vis_ast 
When I get to making this it will be with SectrPrototype
 2024-10-27 18:59:17 -04:00
Ed_
2e5e31ed3b gencpp : General refactors to dependencies 
Mostly just cleanup and renaming of certain stuff (mostly in dependencies).

* Changed uw and sw to usize and ssize.
* Removed zpl_cast usage throughout dependencies
* No longer using GEN_DEF_INLINE & GEN_IMPL_INLINE
* header_start.hpp renamed to platform.hpp for depdendencies header.
 2024-10-27 18:58:37 -04:00
Ed_
00df336610 fix type on parser namespace in singleheader.cpp 2024-10-26 18:42:23 -04:00
Ed_
d89c9a6072 de-hardcode target_arch.psm1 import 2024-10-25 13:11:21 -04:00
Ed_
6aa99ac1d5 change how path_root is resolved so it works when cloned into another repository 2024-10-25 13:07:39 -04:00
Ed_
3989f5fa83 formatting and removing unused code 2024-10-25 12:54:55 -04:00
Ed_
f90c0a59b6 inital implemention of UE library variant generator completed 2024-10-25 05:01:37 -04:00
Ed_
33f992ef56 Updated generated ast_inlines.hpp so that operator defs have the inline explicit 
* Added support for parsing/serializing specifiers for OpCast roughtly.. Doesn't have constraints on what specifiers beyond whats expected in global nspace scope..
* Minor adjustments to hashtable to avoid UE compile errors
* Make sure scanner.cpp is being made by bootstrap
 2024-10-25 04:08:20 -04:00
Ed_
0542204b35 progress on unreal variant generator 2024-10-25 03:00:07 -04:00
Ed_
e5616c5879 generated code update + reverting some fixes for now... 2024-10-25 02:59:56 -04:00
Ed_
40a256f6c3 initial setup for generating a library compatible for usage as an Unreal thirdyparty module. 2024-10-25 01:04:48 -04:00
Ed_
b8e1aa6eb7 WIP : Fixes and other changes 
* Number literals weren't getting properly lexed
* Fixes for compiler errors with Unreal Engine configuration.
* Support for "post-name" macros in parameters
* Support for variables initializing directly using constructor syntax.
* Explicitly added inline keyword to header inlines for compiling compile library in multiple translation units.
 2024-10-25 01:04:17 -04:00
Ed_
e1592ba410 Bug fixes and updates to package_release.ps1 
- Incrased size of the defines_map_arena to 256KB
- Various fixes for the parser
- Various fixes for code serialization
- Fix for is_equal member func in Code types
- Fixes for hasthable container
- Added are_equal static func to String type for use against StrC
- Added starts_with functions to String type
- package_release.ps1 now packages all docs (forgot to update it with last release)
 2024-05-05 21:53:22 -04:00
Ed_
4a2a93d41b Updated docs 2024-04-17 18:29:30 -04:00
Ed_
36260f6edb Updated gencpp with latest fixes used in other projects. 
This variant can support parsing some Unreal Engine files!!
 2024-04-17 17:40:32 -04:00
Ed_
83d691c65c Pushing latest changes for gencpp 2024-04-17 16:55:22 -04:00
Ed_
626ab703a7 Fixed some compilation errors 2023-11-22 15:41:41 -05:00
Ed_
6b10cd2b3e Updated AST_Types.md doc 2023-11-22 15:03:24 -05:00
Ed_
91a3250d4c Finished current iteration of parser_algo docs and parser.cpp inline comment docs 
Added some todos and prep for upcoming changes
 2023-11-22 14:23:21 -05:00
Ed_
a667eb4afe Progress on parser documentation 2023-11-21 23:36:56 -05:00
Ed_
f67f9547df WIP: Improvements to parser, updated docs 
Trying to get support for typename keyword soon
 2023-11-21 21:27:33 -05:00
Ed_
772db608be Added support for predefining preprocessor defines before parsing strings of code. 
This prevents issues for preprocessor defines not getting treated properly for specific circumstances (such as macro wrappers for specifiers).
 2023-11-21 20:09:14 -05:00
Ed_
be023325a9 Added AST & Code definitions segemnted code defs to separate file 
For upcoming statements & expression types, just beginning to lay things out for the future.
 2023-11-21 20:07:49 -05:00
Ed_
a0ee683f82 Added new csvs for ECode & ETokType to keep track of upcoming additions 2023-11-21 20:06:05 -05:00
Ed_
6ad0ae97bc Added bool type keyword to ETokType, move volatile pos in ESpecifier 
volatile can be applied to a function so I moved it there.
 2023-11-21 20:05:38 -05:00
Ed_
3319bfcaa9 Updates to test and workspace 
Added a more granular test using the original library files. Already helped me identify a bug.
 2023-11-21 20:03:51 -05:00
Ed_
9d27c7d37e Lexer improvement prep, segmentation of lexer and parser. 2023-11-20 21:24:27 -05:00
Ed_
5c73fbee83 WIP : AST serialization improvements 
Code untestd its an initial draft
 2023-11-19 20:35:21 -05:00
Ed_
36ebbfe29b Got refactored raylib working in the vis_ast binary 
Now to make that debugger...
 2023-11-19 00:01:35 -05:00
Ed_
053daaf877 Merge branch 'main' into dev 2023-11-17 19:26:21 -05:00
Ed_
040ec00606 Raylib c refactor scripts complete 2023-11-17 19:25:54 -05:00
Ed_
919166efa1 fix for build script 2023-10-25 23:55:29 -04:00
Ed_
9bd6dac783 Merge pull request #51 from Ed94/dev 2023-10-25 23:47:29 -04:00
Ed_
212d907d73 Fixed bug with inline comments for variables not parsing correctly. 2023-10-25 23:44:25 -04:00
Ed_
c1ab233686 Fix for bug with comma separated declaration list vars 
Known Bug: Inline comments are not printing now
 2023-10-25 21:43:22 -04:00
Ed_
b42b224c0d Forgot to push some parser fixes 2023-10-25 03:33:35 -04:00
Ed_
041671762b Got through parsing raylib.h, started to do some major refactors. 2023-10-25 03:26:25 -04:00
Ed_
d0f3b6187e Added initial support for comma-separated variable declaration lists. 2023-10-25 00:25:35 -04:00
Ed_
b22f589203 Progress on preparing raylib for usage 2023-10-24 12:46:59 -04:00
Ed_
4af85f8612 update gitignore for exes 2023-10-24 06:02:07 -04:00
Ed_
e9c151f85d Deleting a sneaked in binary 2023-10-24 06:01:47 -04:00
Ed_
a900e86b65 Got raylib bootstrapped to compile 
Still need to setup a refactor script among other things before using.
 2023-10-24 06:00:28 -04:00
Ed_
d5a4b77033 Some initial boostrapping of new visual ast aux project 2023-10-24 03:14:20 -04:00
Ed_
eaba60f80b Updated build scripts to latest setup used with HandmadeHero repo 2023-10-24 01:40:21 -04:00
Ed_
912cc6b538 Bugfixes during hiatus 
Found while doing some metaprogramming for day 42 of handmade hero.
 2023-10-22 21:41:36 -04:00
Ed_
3dd5482a46 set ContinuationIndentWidth to 4 for clang format. 2023-10-01 20:19:16 -04:00
Ed_
632fa10027 Updated readme with partial hiatus notice. 2023-10-01 12:37:29 -04:00
Ed_
6498b13658 Fix for non-foreign include content not getting parsed correctly. 2023-10-01 12:16:15 -04:00
Ed_
7f562cd77f Merge branch 'dev' 2023-09-28 20:36:12 -04:00
Ed_
3a0e971ebf Bugfix for parse_variable, const check for prefix specifiers causing infinite loop. 2023-09-28 20:35:20 -04:00
Ed_
4997cb5878 Merge pull request #45 from Ed94/dev 
Dev
 2023-09-25 17:50:16 -04:00
Ed_
729c891cbd Last fixes before handmade hero hiatus 2023-09-25 17:48:16 -04:00
Ed_
754bcfb31e Fixes to get it back to where I was last at with the const specifier issue 2023-09-25 16:42:29 -04:00
Ed_
a8708abf8b WIP : Various changes to project before small hiatus. (Broken) 
I need to manually review these as the changes have various errors that are difficult to diagnose why.

I took a break to do handmade hero and now a bit rusty.
 2023-09-25 12:12:11 -04:00
Ed_
4b48b96a79 WIP : better AST::debug_str() 
Now its more contexually rich to the ast type, however I need to hookup tokens from parsing to the AST. There needs to be a way for the debug string to lookup the token and provide the contexual line.
Can either pass it ( TokArray* toks ) from the parser on failure (or `CodeFile`)..
Technically there is more than enough room for another Token* ptr. I could add another and specifiers would still have at minimum 14 slots before needing to extended to next specs.
**************... yeah
 2023-09-12 02:32:44 -04:00
Ed_
9495fc2985 Updates to documentation 2023-09-11 18:34:37 -04:00
Ed_
378de73a7d Merge branch 'main' of https://github.com/Ed94/gencpp 2023-09-08 15:15:13 -04:00
Ed_
35ac0c1048 Fix compile-error for singleheader found with scanner's scan_file. 2023-09-08 15:14:43 -04:00
Ed_
2c893d5e35 Merge pull request #34 from Ed94/dev 
Dev
 2023-09-07 23:06:02 -04:00
Ed_
6ea40094ee More fixes from clang warnings. Parser::lex prep for changes 
parse_static_assert now properly adds new-line to end of statement.

I'm going to end up making a static_assert ast... that or when the statement ast is made it will handle adding that newline.
 2023-09-07 22:52:51 -04:00
Ed_
0a8d3bfc6a Added fixed arenas (just ergonomics) 2023-09-07 22:29:04 -04:00
Ed_
212b4e6d16 Fixes for compiling with clang 
Clang just had better errors and caught stuff msvc did not.
 2023-09-07 21:11:57 -04:00
Ed_
d606c790ca Added a new AST member NextVar to be used for comma separated variable support. 
Interface adding has been adjusted to use ParentType->Next.

Using the AST_Class->Next was bad since that breaks the linked list a body AST would have used for traversal.
 2023-09-06 03:06:30 -04:00
Ed_
2bfbef1d0c strip_formatting : Remove code thats no longer needed. 
Its everyting related to stripping a function body.
 2023-09-06 02:09:26 -04:00
Ed_
f1fb75cc1c Progress on strip_formatting function, support for multi-dimentional array variables and typenames. 
strip_formatting suffers from some edge failure with what looks to be escaped character literals (not entirely sure).

I've decided to not remove formatting from unvalidated function bodies since I plan to support parsing its content properly.
However expression values for a statement will fail to have their formatting removed with this.

Since I don't plan to parse those anytime soon, I'll have to fix any edge cases for those at least..
 2023-09-06 02:07:09 -04:00
Ed_
2200bcde9a Improved singleheader test 
Need to make the debug_str provided by the AST type aware to provide as much contextual information as possible (finally got to this point with validation).

Singleheader test now directly calls clang-format to cleanup the reconstructed copy of the singleheader. Its needed to remove any sort of formatting discrepancies found by the parser since its sensistive to that for new-lines, etc.
 2023-09-05 13:36:59 -04:00
Ed_
3e249d9bc5 Reorganization of parser, refactor of parse_type( bool* ) and progression of parser docs 
Wanted to make parser implementation easier to sift through, so I emphasized alphabetical order more.

Since I couldn't just strip whitespace from typenames I decided to make the parse_type more aware of the typename's components if it was a function signature.
This ofc lead to the dark & damp hell that is parsing typenames.

Also made initial implementation to support parsing decltype within a typename signature..

The test failure for the singleheader is still a thing, these changes have not addressed that.
 2023-09-05 01:48:11 -04:00
Ed_
3868e1e811 Added cursed typedef 2023-09-04 12:32:31 -04:00
Ed_
543427dfe5 Fixes to parsing for validation 
Removed whitespace stripping from parse_type, prepped for doing some major changes for function signature typenames

Moved template argument parsing to its own helper function since its used in more the one spot.

Latest failure is due to stack overflow when validating parameters. (Shouldn't be hard to debug)
 2023-09-03 23:36:51 -04:00
Ed_
f2d4ec96f0 Dumb fix for name check on parameters 
Its now spitting out actual validation failures.
 2023-09-03 20:34:27 -04:00
Ed_
1076818250 Got whitepace stripping properly working (AFAICT) for parse_define() 
Made debug for viewing whitespace in AST::is_equal with String::visualize_whitespace()

Format stripping code is currently confined within parse_define()

I plan to move it to its own function soon, I just want to make sure its finalized first.

Other unvalidated content will need to have an extra check for preprocessed lines.
Example: Function bodies can have a #define <identifier> <definition>. I cannot strip the last <new line> as it will break the semantic importance to distinguish that line.
So it needs to be:
<content before> <new line>
<preprocessed line> <new line>
<content after>

In the content string that is minimally preserved
 2023-09-03 20:29:49 -04:00
Ed_
c4c308c8ba Fixes for auxilary code + typo fix in ast.cpp 
Needed the intellisense directive ifdef wrap.
 2023-08-29 00:03:08 -04:00
Ed_
a4d9a63d71 Updated single-header based on last cs and also docs 2023-08-28 23:52:44 -04:00
Ed_
0197afd543 Changed how editor intellisense directives are handled for compoenents and dependencies 
Didn't like the way I was processing them in scan_file.
 2023-08-28 23:46:50 -04:00
Ed_
7249a7317d Added space stripping during for content of various ASTs 
* Typedef/Typename
* Function Names
* Pragmas
* Attributes
 2023-08-26 11:55:05 -04:00
Ed_
abf51e4aa9 Adjustment to AST::is_equal based on issues found with last CS. 
Defined check_member_content, will spit out the strings if they aren't equivalent so the user can verify for themselves if its correct.
 2023-08-25 18:57:53 -04:00
Ed_
9b6dc3cbd8 Work on AST::is_equal. 
The NumEntries checks need to be deferred until the end as a final unresolved check on valdiation. As if there really is a discrepancy of entires it should be revealed by the specific entry failing.

Right now the latest failure with the single header check involves a define directive specifically the define does omit whitespace properly and so the check interprets the different cached content to be non-equivalent.

This will happen with all unvalidated aspects of the AST ( expressions, function bodies, etc )

There are two ways to resolve, either make an AST that can tokenize all items (not realistic), or I need to strip non-syntax important whitespace and then cache the string. This would mean removing everything but a single whitespace for all content within a content string. Otherwise, I would have to somehow make sure the content of the string has the exact formatting between both files for the definitions that matter.

AST types with this issue:
* Define Directive
* Pragma Directive
* Comment
* Execution
* Platform Attributes
* Untyped

Comments can technically be left unverified as they do not matter semantically.
When the serialization is first emitted, the content these strings should for the most part be equivalent. However I do see some possible failures for that if a different style of bracket placment is used (between the serialization).

At that point what I could do is just leave those unverified and just emit the content to the user as warning that the ast and the other compared could not be verified.

Those technically can be handled on a per-eye basis, and worst case the tests with the compiler will in the determine if any critical defintions are missing for the user.
 2023-08-25 18:40:13 -04:00
Ed_
9edcbad907 Fixes to parsing marco content, progress on validation test (single-header) 2023-08-23 21:19:31 -04:00
Ed_
a6766cf0b1 Singleheader validation test got through ast reconstruction, failed to validate the reconstructed AST. 2023-08-23 18:16:45 -04:00
Ed_
8635b0fd1b doc update for parampack typename 2023-08-23 13:18:32 -04:00
Ed_
30eec99628 Changes to include usage, starting to attempt singleheader automated verification 2023-08-23 13:17:22 -04:00
Ed_
f9117a2353 Added zpl's ivrtual memory to dependencies (unused for now) 2023-08-23 11:07:43 -04:00
Ed_
c81f4b34ee Cleanup and doc updates 2023-08-23 02:17:47 -04:00
Ed_
c97762ac16 Added support for inline comments 
Also now doing comment serialization on def_comment directly as parse_comment doesn't need it.

Essentially comment ast types serialize the same way s untyped and execution ASTs
 2023-08-23 00:25:14 -04:00
Ed_
5e79e8ba65 Started to setup for codebase validation tests. 
Fleshed out initial version of AST::is_equal( AST* )

Setup the test directory with initial files for each major validation test.
 2023-08-22 16:01:50 -04:00
Ed_
49a2cd7b2c Uncomment formatting comments in build script (forgot to after completing fixes) 2023-08-22 02:17:28 -04:00
Ed_
a6c6574390 More formatting fixes 2023-08-22 02:09:20 -04:00
Ed_
c4846dad26 Formatting fixes 2023-08-22 01:51:59 -04:00
Ed_
a61a28b778 Fixx to bitfield variables 
Related to https://github.com/Ed94/gencpp/issues/25
 2023-08-22 00:40:38 -04:00
Ed_
d0c995893d Lower inital memory allocation amounts. (Lower latency iteration for running generator) 
I need to change it so that they all use one big arena allocation for the initial. This can be done when the global allocator is changed to a growable arena.
 2023-08-21 23:49:23 -04:00
Ed_
a42e241afb Got rid of the temp compoonent files, they are now generated via bootstrapping. 
This isn't the last step though everything in the main project directory that isn't md files needs to be generated only.
Can't do that till testing is robust enough...
 2023-08-21 23:28:39 -04:00
Ed_
6d85dd8fe8 Update vcproj 2023-08-21 23:09:40 -04:00
Ed_
db6e8b33eb got intellisense working for the most part... 
VScode works withs some issues.
VS2022 fails.
10xEditor works fine.
JetBrains Rider fails due to it not supporting <push/pop>_macro pragmas
 2023-08-21 23:07:03 -04:00
Ed_
7be3617083 Runtime fixed 2023-08-21 22:48:05 -04:00
Ed_
5c47777972 compiles agian... 2023-08-21 21:40:23 -04:00
Ed_
4a2ed6de4e another vs code automated edit... 2023-08-21 21:40:05 -04:00
Ed_
9f64760b7a Commenting out includes to diagnose... 2023-08-21 21:20:29 -04:00
Ed_
68f34e6fab gitignore update for vc140.pdb 
will remove after I figure out how its going rogue.
 2023-08-21 21:12:52 -04:00
Ed_
1f9bbddbb7 vs setting update 2023-08-21 21:12:25 -04:00
Ed_
050b00f28a WIP - Broken Compile : Added pragma once and includes to all files + Parser fixes, and String improvements 
Adding the pragma once and includes the files broke compilation, still diagnosing why.

- Some string functions were moved to the cpp, still need to do some more evaluation of it and the containers...
- Added support for forceinline and neverinline to parsing (untested)
- Added support for specifiers in operator cast such as explicit, inline/forceinline/neverinline, etc.
    - Before it only support const.
    - Still need to support volatile.
- Forceinline was not supported at all for tokenization, fixed that.
 2023-08-21 20:30:13 -04:00
Ed_
1241f44fd4 scan_file function can auto skips pragma once and includes 
Needed so that includes could be added to components so that intellisense would not fail since the parser (for most editors) doesn't properly parse the enviornment and cheats on a per-file basis.
 2023-08-21 20:27:00 -04:00
Ed_
7d1c499e7b Build script improvements 
Made sure devshell only loads up the msvc env once.
 2023-08-20 22:39:46 -04:00
Ed_
b3f0c2734f Merge remote-tracking branch 'origin/main' into dev 2023-08-20 18:04:51 -04:00
Ed_
eaeb8acee4 Remove Some vcproj changes, removal of the rogue vc140.pdb 2023-08-20 18:04:35 -04:00
Ed_
12bf878cb3 Merge pull request #23 from Ed94/dev 
dev pull - Build script updates and misc fixes
 2023-08-20 17:55:35 -04:00
Ed_
52ae431ad6 Made clean script remove the gen dir now from test dir. 2023-08-20 15:51:51 -04:00
Ed_
05fa62eced Test building & generation fixed with altest scripts 2023-08-20 15:45:06 -04:00
Ed_
2f7836b191 Fixes to buildscript 2023-08-20 13:18:09 -04:00
Ed_
f574a9ba9a Further improvements to build script 
test is failing to complete properly, need to debug...
 2023-08-20 13:02:50 -04:00
Ed_
a6bf60a51e Simpilication of build script, added initial support for tests 2023-08-20 12:31:28 -04:00
Ed_
37d9782cf2 Singleheader now compiles with new build script on both clang & msvc 2023-08-20 10:17:55 -04:00
Ed_
11679ba8b4 New build script works for clang and msvc! 
Need to update singleheader and test to use it.
 2023-08-19 21:33:01 -04:00
Ed_
8985f0a4d9 MSVC in latest script works 
Clang is having issues.
 2023-08-19 17:08:13 -04:00
Ed_
32a910515e More refactoring, getting rid of meson in favor of just powershell scripts 2023-08-19 12:18:48 -04:00
Ed_
aa928ff446 Scripting updates, some refactors.. 
Made a package release script.

Did refactors based on some design considerations
Still need to make some major decisions...
 2023-08-09 18:47:59 -04:00
Ed_
5aff89262b Fixes (Doc typos, pragma once worng type, non-debug fatal compile fail) 2023-08-09 09:50:12 -04:00
Ed_
b5fa864318 Fixes and improvements to serialization. 
There were multiple issues with comment and newline lexing.

Extended printing functions to support Strings with %S flag (captial 'S').
Allows for length detection. Also made it so that precision for strings is the string length.
 2023-08-08 22:14:58 -04:00
Ed_
bb35444be9 Fix for log_failure macro expansion in helper.hpp: CodeBody gen_ast_inlines() 2023-08-08 15:53:10 -04:00
Ed_
67d02c1f62 Fix for wrong tokens for GNU/MSVC attribute captures (parse_attributes) 
Also a fix for a typo in the readme...
 2023-08-08 15:35:06 -04:00
Ed_
c7647ab00f Updated docs 2023-08-08 11:56:42 -04:00
Ed_
d2fc1d0a56 Converted log_failure and fatal to macros (fixes GEN_PANIC not determining correct line or file) 2023-08-08 09:48:50 -04:00
Ed_
ed3246c6b0 Fixes for typedef serialization of functions.. 
Also fix for HashTable<>::rehash_fast not having finished implemenation...

The typedef fix is a sort of hack (like how parsing the rest of the language feels like tbh...).
I might make a def_typedef_fn to make it clearer how to define function typedefs using the upfront interface.
 2023-08-07 20:16:04 -04:00
Ed_
c4d5637a64 Fixes to single header generation (bad parsing adt/csv injection in wrong place) 2023-08-07 14:52:26 -04:00
Ed_
c2f8c8aeb1 Added constructor and destructor supported (UNTESTED) 
Just compiles and generates...

Also fixed a bug where parsing didn't have a token for virtual specifiers...
 2023-08-07 03:10:45 -04:00
Ed_
c2319b9651 Fixes for test.singleheader_ast.cpp, also added a bench for it. 
On a Ryzen R9 5950 it takes 11 ms to generate AST and 21 ms to serialize to file.
 2023-08-06 17:46:17 -04:00
Ed_
a4f9596d3b Fixes to serialization, reduced Define_CodeType macro 
Now the execution code is generated in bootstrap/singleheader gen.
 2023-08-06 17:19:57 -04:00
Ed_
97750388ad No longer using components/temp/ast_inlines (switched to helper function to avoid macro usage) 
Increased the arg count support of num_args to 100.
 2023-08-06 14:58:43 -04:00
Ed_
00f6c45f15 Fixes for serializations found with last commit's test. 
Should be fine to move on to next major feature....
 2023-08-06 13:28:19 -04:00
Ed_
34f286d218 Library can now construct into AST and serialization itself (singleheader). 
Still need to validate if they match.
 2023-08-04 16:12:13 -04:00
Ed_
d36c3fa847 Single header generates again, some more cleanup. 
Looking into properly dealing with empty lines...

I want to preserve the text's empty lines in the AST for serialization purposes (perserve formatting for gapes between definitions).
Don't want to introduce the possibility of it breaking though, so will have to ignore empty_lines in a general way (if they are in a bad spot).
Attempted to cover that by having TokArray::current() auto-skip empty lines and eat as well if the type doesn't match.
 2023-08-03 23:18:33 -04:00
Ed_
5d7dfaf666 Heavy refactor.. 
Isolating large macros to their own directory (components/temp).
- Plan is to remove them soon with proper generation.

Added additional component files, separating the old data_structures header for a set of ast headers.
Header_end also had its inlines extracted out.
Necessary to complete the macro isolation.

ZPL parser dependencies were removed from the core library along with builder, its now generated in bootstrap as pare of making a gen_builder set of files.

Singleheader will be changed in next few commits to reflect this as well (By making builder deps and components a conditional option).

Tests are most likely all broken for now.
 2023-08-03 11:01:43 -04:00
Ed_
114f678f1b Merge pull request #9 from Ed94/Preprocessor_support 
Preprocessor support
 2023-08-02 16:04:57 -04:00
Ed_
a8a9b681f0 test completes singleheader ast construction and serailizes with corruption 2023-08-02 14:01:56 -04:00
Ed_
b96b0821c1 Fixes towards parsing (getting to line 12575 now of the singleheader. 2023-08-02 12:39:35 -04:00
Ed_
4c8a0f0005 Iterations on serialization improvements. 2023-08-01 20:56:00 -04:00
Ed_
684569750d first serialization of singlehearder without asserts. (Still failing after around 4k lines. 2023-08-01 16:07:47 -04:00
Ed_
0f16d1131e Got past parsing, fixing serialization 2023-08-01 14:02:54 -04:00
Ed_
528ef72a51 More progress on parsing 
Made it to line 2597 of self parsing its singleheader

Complex global or member defintions are now supported.
 2023-08-01 05:17:24 -04:00
Ed_
21a8f3bb39 WIP: It can parse to around ~2k lines. Need to improve its ability to detect when a forward declare of a class/enum/struct/union.. 
This language truly is a mess.
 2023-08-01 00:42:08 -04:00
Ed_
2b63fc27cd Progress toward preprocessor parsing, lexing works, parsing does not. 2023-07-30 18:55:57 -04:00
Ed_
bfbfae466f Naive preprocessor support initial implementation (compiles and runs, not heavily tested) 2023-07-30 01:21:04 -04:00
Ed_
3d7cb85e71 Merge pull request #8 from Ed94/parser_context_stack 
Parser context stack
 2023-07-29 17:16:04 -04:00
Ed_
03df940085 Improved parser scope errors. 
Added the caret for indicating where the error is.
 2023-07-29 17:14:02 -04:00
Ed_
b9064fba9d renamed parsed and upfront dirs to lowercase 2023-07-29 16:27:36 -04:00
Ed_
4e8d6456cb Merge branch 'parser_context_stack' of https://github.com/Ed94/gencpp into parser_context_stack 2023-07-29 16:25:50 -04:00
Ed_
d704f11c81 renamed Docs to lowercase 2023-07-29 16:25:38 -04:00
Ed_
50a10c901f renamed Docs to lowercase 2023-07-29 16:24:07 -04:00
Ed_
0a5885495f got old tests working (test.parsing.cpp and test.upfront.cpp) 2023-07-29 16:00:06 -04:00
Ed_
f09bb99fdf Fixes for test generation (sanity, soa). 2023-07-29 13:15:53 -04:00
Ed_
108b16739f bootstrap and singleheader compile and generate. 2023-07-29 12:25:38 -04:00
Ed_
689646c393 Finished iniital refactor pass. Comples, but has runtime issues. 2023-07-29 06:32:16 -04:00
Ed_
c5afede7b5 Reorganization of files, refactors, doc updates (WIP) 
Removing the gen. namespace from the files for components, dependencies, and file_processors.
They are only necessary if the include directory is transparent, and in my case those are not.

Made a docs directory. I'm offloading information from the main readme to there along with additional informationn I end up elaborating on down the line.
Enum tables were moved to their own directory (project/enums).

Library will not compile for now. Major refactor occuring with parsing related components.
 2023-07-29 05:52:06 -04:00
Ed_
31e1c38c18 Started to implement context stack for parser. 2023-07-28 21:44:31 -04:00
Ed_
3f0b7e7fc6 Update to scripts, readme 
Offloaded todo to the issues on github.
 2023-07-28 03:15:50 -04:00
Ed_
d977c82f37 Fixes from latest refactor of toktype enum. 2023-07-27 17:12:58 -04:00
Ed_
b00c1ae522 ECode, ESpecifier, and ETokType are now all generated. 
There is a redundant pattern for generating all three (as expected).

I'll use it to define a general way of doing this sort of behavior.
 2023-07-27 02:51:36 -04:00
Ed_
cf65638979 Started to generate the enums from csv (ECode, EOperator, ESpecifier). 
- Changed the zpl csv parser to only accept hex values with 0x perfix. it was messing with the add term.
- Small changes to the clang format config.
 2023-07-26 14:21:20 -04:00
Ed_
8232e79aac Adding pragma regions to all dependency components 2023-07-25 23:00:57 -04:00
Ed_
a11117c97c Fixes to the parsing constructors 2023-07-25 19:23:21 -04:00
Ed_
cd9b393790 Fixes to bootstrap and singleheader generation 2023-07-25 17:46:00 -04:00
Ed_
62b0ed2112 Finished initial implmentation bootstrap generation and singleheader implementation. 2023-07-25 15:12:51 -04:00
Ed_
ebe049d3a0 Added refactor.ps1 script, fixed the gencpp.refactor script (missing commas) 2023-07-24 23:47:04 -04:00
Ed_
88d36f5d06 Update readme and scripts 
Both bootstrap and singleheader now name the files the same as the library's default.
Output now directed toward gen directory for the corresponding dir (project, singleheader, or test)
 2023-07-24 23:10:10 -04:00
Ed_
9c81504178 Progress towards bootstrap/singleheader generation 
I will most likely need to refactor some of the components & dependencies files to get the desired gneration implementation the way I want.

Specficially I want to be able to eliminate macros I'm using for enums and common patterns for implmeentation of the data structures.

When it comes to the cpp files, I may leave those alone as the macros largely help ith readability.
Replacing those macros is expensive and most likely not worth it.

The macros under consideration with replacing using the library bootstrap are:

* Define_Types
* Define_Operators
* Define_Specifiers
* GEN_Define_Attribute_Tokens
* Define_CodeType
* Using_Code
* Define_TokType
* def_constant_spec ?
* Helper Macros for def_**_body functions ?
  * AST unallowed types case macros?
(The last three I'm unsure about as they work fine, and neeeding the debugger steps there is a rare scenario...)

The enums could be manually generated and have its fields derived from a CSV (which is what genc is currently doing).
This would allow the user to specify custom attribute macros as well with greater ease.

I may maually inline ProcessModuleFlags, as its not even necessary as any specific symbol with a module flag will only use the export value. Import is only used on modules themselves (from what I can tell).

The Parser::lex function could be offloaded to its own file in case the user wants to swap the entire thing out.
(Most likely may want to for various purposes)

The problem with extracting any definitions out of a component file currently is that will lead to splintering that componnet to multiple other components.
This is necessary as the proper scanner is not implemented yet (only a reduimentary scan_file proc is made so far).
 2023-07-24 22:19:21 -04:00
Ed_
387787b88d Formatting fixes 2023-07-24 20:59:20 -04:00
Ed_
4a87a42db0 Fixes + more setup, added more directories to clean script. 2023-07-24 18:56:15 -04:00
Ed_
b5cad6e8a1 some cleanup of unused macros in test files, preparing bootstrap and single header code + scripts 2023-07-24 18:51:49 -04:00
Ed_
49ef1a2e87 gen.deps.cpp "componentized" 2023-07-24 18:35:16 -04:00
Ed_
5aa334237a gen.dep.hpp "componentization" 2023-07-24 18:19:37 -04:00
Ed_
74ea502de5 "compentiazation" of gen.hpp and gen.cpp 2023-07-24 17:45:27 -04:00
Ed_
fcca15b4b9 Making new files, preparing to offload code to them. 2023-07-24 14:30:57 -04:00
Ed_
88a43cb11f namespace macro unused in gen.dep.cpp, updates to readme. 2023-07-24 14:30:35 -04:00
Ed_
39390535ce Support for interfaces in class/struct. 
Interfaces are assumed to have the public access specifier for their content (if its a class definition)

Started to prepare to segement library code into more files (Less scrolling, need for bootstrapping a tailored version + single header support anyway).
 2023-07-24 13:44:19 -04:00
Ed_
d4c2cdf30e Added varadic parameter support (upfront and parsing) 2023-07-24 11:20:13 -04:00
Ed_
1d3050f157 Update readme todo (remove trailing specifiers task) 2023-07-24 00:28:23 -04:00
Ed_
cee55ad080 Suppeort for trailing specifiers for member functions, operators, and operator type casts (Untested) 2023-07-24 00:27:13 -04:00
Ed_
5df21998ef Should support parsing full definitions within typedef... (need to make tests) 2023-07-23 23:28:21 -04:00
Ed_
80b5c9768d Adding tuning macros for memory usage of the library, fixes. 
Reduced the sanity test case to half its original iterations.
 2023-07-23 23:11:53 -04:00
Ed_
5ce8bfa259 Added macros to make the gen namespace optional. 2023-07-23 22:25:19 -04:00
Ed_
e7374ec328 Support for module and attribute parsing ( untested ) 2023-07-23 22:14:48 -04:00
Ed_
b1de5b1ac7 Fixed swap fn 2023-07-21 01:40:45 -04:00
Ed_
a37c3f63c2 Update to readme, update CodePool_NumBlocks to 64k 2023-07-21 01:12:38 -04:00
Ed_
efd7af9f96 Added ability for a CodeBody to append another 2023-07-20 23:51:56 -04:00
Ed_
8bb0db8145 Moved the indentation for the library over 
The entire project uses the namespace and it felt redundant.

There is a fix for array append_at. Finally got csv parsing working with it.
 2023-07-19 23:42:28 -04:00
Ed_
d1c061769c GlobalAllocator fixes 
- Made a gen script (does full build and test) build just builds gencpp now.
 2023-07-19 00:49:54 -04:00
Ed_
1488aeb188 update todo 2023-07-19 00:24:00 -04:00
Ed_
db584d8fe6 Removed GEN_FEATURE_PARSING macro, fixes to readme 
Parsing constructors are too ergonomic to be a "optional" feature.
 2023-07-19 00:14:15 -04:00
Ed_
4d2f6a6315 Refactor Test gen_time to GEN_TIME 2023-07-19 00:13:12 -04:00
Ed_
231ae5f5d6 Some refactors (see description) 
- Renamed macro gen_time to GEN_TIME
- Moved scanner and editor to their own headers, I'm going to consider them extensions.
- I'm preparing to setup the library to build on multiple compiler platforms: clang, gcc, msvc.
 2023-07-18 23:33:00 -04:00
Ed_
e501941c5c Fix for sanity test... 2023-07-17 23:40:28 -04:00
Ed_
9a784fe92f Preparing to implement ADT for csv functions. 
I'm rewritting it the way I'd like to learn it.
- I want to use csv parsing heavily with the library so I'm just going to add it to the scanner.

- Globaly memory allocator moved to regular gen header/source as its something really just made for the library.
- Some small refactors to macros
- The parser was updated to support tokenizing preprocessor directives.
  - The purpose is based off intuition that it will be required for the scanner.
 2023-07-17 20:17:19 -04:00
Ed_
2a319ed6db Additions and fixes based off genc repo 
Typedef parses enum namespaced types properly (C typedefs of enums to expose to global scope).
 2023-07-16 23:18:00 -04:00
Ed_
41dc0e3fbb Bad ifdef for benchmark in gen_dep. 2023-07-16 18:06:43 -04:00
Ed_
98b776d66e Small correction to test comment. 2023-07-16 18:01:22 -04:00
Ed_
7634aeb34c Fixes to memory mangment, library is much faster now. 2023-07-16 18:00:07 -04:00
Ed_
b544f24015 Moved dependencies back to their own files (gen_dep.hpp/cpp) 
Its easier to manage, I'm sticking with generating the single header so it wont matter, its easy to refactor back if desired.
 2023-07-16 12:08:57 -04:00
Ed_
8879b757ed Readme update 2023-07-16 03:26:07 -04:00
Ed_
1f77e39694 Minor refactor, added optional recursive dups for ast, ... 
- Added support for anonymous structs.
- Gave Token_Fmt::token_map its own static memory.
- Minor natvis fix for CodeBody
- Renamed ESpecifier::Static_Member to just Static (acts as a general use case) specifier option
- Setup the lex token array with a configurable arena allocator.

Two major things left before V0.3-4:
- Attribute and Module parisng support with base case test
- AST serializtaion strings get a dedicated slag allocator.
 2023-07-16 03:19:59 -04:00
164 changed files with 38575 additions and 16916 deletions
Expand all files Collapse all files

44
.gitignore vendored
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@ -1,22 +1,34 @@
.idea
build/*
**/build/*
.vs
**/*.gen.*
**/gen/gen.hpp
**/gen/gen.cpp
**/gen/gen.dep.hpp
**/gen/gen.dep.cpp
**/gen/gen.builder.hpp
**/gen/gen.builder.cpp
**/gen/gen.scanner.hpp
**/gen/gen.scanner.cpp
# Build results
[Dd]ebug/
[Dd]ebugPublic/
[Rr]elease/
[Rr]eleases/
x64/
x86/
[Ww][Ii][Nn]32/
[Aa][Rr][Mm]/
[Aa][Rr][Mm]64/
bld/
[Bb]in/
[Oo]bj/
[Ll]og/
[Ll]ogs/
gencpp.hpp
gencpp.cpp
**/*.lib
**/*.pdb
**/*.exe
**/*.dll
release/**
# Unreal
**/Unreal/*.h
**/Unreal/*.cpp
! **/Unreal/validate.unreal.cpp
project/auxillary/vis_ast/dependencies/temp
test/gen/original
singleheader/gen/scratch.hpp
test/gen/scratch.cpp
gen_c_library/gen

0
singleheader/gen/gen.singleheader.cpp → .vscode/bookmarks.json vendored
View File

62
.vscode/c_cpp_properties.json vendored
View File

@ -1,19 +1,73 @@
{
"configurations": [
{
"name": "Win32",
"name": "Bootstrap",
"includePath": [
"${workspaceFolder}/**"
"${workspaceFolder}/base/**"
],
"defines": [
"_DEBUG",
"UNICODE",
"_UNICODE",
"gen_time"
"GEN_TIME",
"GEN_IMPLEMENTATION",
// "GEN_DONT_USE_NAMESPACE"
"GEN_INTELLISENSE_DIRECTIVES",
"INTELLISENSE_DIRECTIVES"
],
"cStandard": "c11",
"cppStandard": "c++17",
"windowsSdkVersion": "10.0.19041.0",
"compilerPath": "C:/Program Files/Microsoft Visual Studio/2022/Professional/VC/Tools/MSVC/14.29.30133/bin/HostX64/x64/cl.exe",
"intelliSenseMode": "msvc-x64",
"compileCommands": "${workspaceFolder}/.vscode/tasks.json",
"compilerArgs": [
"/EHsc-",
"/GR-",
"/Zc:preprocessor",
"/FC"
]
},
{
"name": "Win32 msvc c_library",
"includePath": [
"${workspaceFolder}/gen_c_library/**"
],
"defines": [
"_DEBUG",
"UNICODE",
"_UNICODE",
"GEN_TIME",
"GEN_IMPLEMENTATION",
// "GEN_DONT_USE_NAMESPACE"
"GEN_INTELLISENSE_DIRECTIVES",
"INTELLISENSE_DIRECTIVES"
],
"cppStandard": "c++17",
"windowsSdkVersion": "10.0.19041.0",
"compilerPath": "C:/Program Files/Microsoft Visual Studio/2022/Professional/VC/Tools/MSVC/14.29.30133/bin/HostX64/x64/cl.exe",
"intelliSenseMode": "msvc-x64",
"compileCommands": "${workspaceFolder}/.vscode/tasks.json"
},
{
"name": "Win32 clang",
"includePath": [
"${workspaceFolder}/base/**"
],
"defines": [
"_DEBUG",
"UNICODE",
"_UNICODE",
"GEN_TIME",
"GEN_IMPLEMENTATION",
// "GEN_DONT_USE_NAMESPACE"
"GEN_INTELLISENSE_DIRECTIVES",
"INTELLISENSE_DIRECTIVES"
],
"windowsSdkVersion": "10.0.19041.0",
"compilerPath": "C:/Users/Ed/scoop/apps/llvm/current/bin/clang++.exe",
"compilerPath": "clang++.exe",
"intelliSenseMode": "windows-clang-x64",
"compileCommands": "${workspaceFolder}/.vscode/tasks.json"
}
],
"version": 4

26
.vscode/launch.json vendored
View File

@ -5,22 +5,30 @@
"version": "0.2.0",
"configurations": [
{
"type": "lldb",
"type": "cppvsdbg",
"request": "launch",
"name": "Debug gentime lldb",
"program": "${workspaceFolder}/test/gen/build/gencpp.exe",
"name": "Debug base vsdbg",
"program": "${workspaceFolder}/base/build/base.exe",
"args": [],
"cwd": "${workspaceFolder}/test/gen/",
"postRunCommands": [
]
"cwd": "${workspaceFolder}/base/",
"visualizerFile": "${workspaceFolder}/scripts/gencpp.natvis"
},
{
"type": "cppvsdbg",
"request": "launch",
"name": "Debug gentime vsdbg",
"program": "${workspaceFolder}/test/gen/build/gencpp.exe",
"name": "Debug singleheader vsdbg",
"program": "${workspaceFolder}/singleheader/build/singleheader.exe",
"args": [],
"cwd": "${workspaceFolder}/test/gen/",
"cwd": "${workspaceFolder}/singleheader/",
"visualizerFile": "${workspaceFolder}/scripts/gencpp.natvis"
},
{
"type": "cppvsdbg",
"request": "launch",
"name": "Debug unreal vsdbg",
"program": "${workspaceFolder}/unreal_engine/build/unreal.exe",
"args": [],
"cwd": "${workspaceFolder}/unreal_engine/",
"visualizerFile": "${workspaceFolder}/scripts/gencpp.natvis"
}
]

57
.vscode/settings.json vendored
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@ -18,10 +18,59 @@
"algorithm": "cpp",
"limits": "cpp",
"concepts": "cpp",
"*.rh": "cpp"
"*.rh": "cpp",
"chrono": "cpp",
"string": "cpp",
"filesystem": "cpp",
"format": "cpp",
"ratio": "cpp",
"xstring": "cpp",
"functional": "cpp",
"vector": "cpp",
"list": "cpp",
"xhash": "cpp",
"glfw3.h": "c",
"stdbool.h": "c",
"objbase.h": "c",
"mmreg.h": "c",
"mmsystem.h": "c",
"propidl.h": "c",
"android_native_app_glue.h": "c",
"raylib.h": "c",
"*.m": "cpp",
"atomic": "cpp",
"gen.h": "c",
"string_ops.hpp": "c",
"assert.h": "c",
"intrin.h": "c",
"bit": "cpp",
"cmath": "cpp",
"cstddef": "cpp",
"cstdint": "cpp",
"cstdio": "cpp",
"cstdlib": "cpp",
"cstring": "cpp",
"ctime": "cpp",
"cwchar": "cpp",
"iosfwd": "cpp",
"new": "cpp",
"typeinfo": "cpp",
"unordered_map": "cpp",
"xstddef": "cpp"
},
"C_Cpp.intelliSenseEngineFallback": "disabled",
"mesonbuild.configureOnOpen": true,
"C_Cpp.errorSquiggles": "enabled",
"godot_tools.scene_file_config": ""
}
"C_Cpp.errorSquiggles": "disabled", // This doesn't work well with how the headers are included.
"godot_tools.scene_file_config": "",
"C_Cpp.default.compilerPath": "cl.exe",
"C_Cpp.exclusionPolicy": "checkFilesAndFolders",
"C_Cpp.files.exclude": {
"**/.vscode": true,
"**/.vs": true,
"**/sanity.gen.hpp": true,
"test/**":true,
},
"autoHide.autoHidePanel": false,
"autoHide.autoHideSideBar": false,
"dimmer.enabled": false
}

144
.vscode/tasks.json vendored Normal file
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@ -0,0 +1,144 @@
{
"version": "2.0.0",
"tasks": [
{
"label": "Build Bootstrap",
"type": "shell",
"command": "C:\\Program Files\\PowerShell\\7\\pwsh.exe",
"args": [
"-ExecutionPolicy",
"Bypass",
"-File",
"${workspaceFolder}/scripts/build.ci.ps1",
"bootstrap",
"msvc"
],
"group": "build",
"problemMatcher": {
"owner": "cpp",
"fileLocation": [
"relative",
"${workspaceFolder}"
],
"pattern": {
"regexp": "^(.*)\\((\\d+)\\)\\s*:\\s*(warning|error)\\s*(\\w+)\\s*:\\s*(.*)$",
"file": 1,
"line": 2,
"severity": 3,
"code": 4,
"message": 5
}
},
"presentation": {
"reveal": "always",
"panel": "shared",
"clear": true
}
},
{
"label": "Build C Library",
"type": "shell",
"command": "C:\\Program Files\\PowerShell\\7\\pwsh.exe",
"args": [
"-ExecutionPolicy",
"Bypass",
"-File",
"${workspaceFolder}/scripts/build.ci.ps1",
"c_library",
"msvc"
],
"group": {
"kind": "build",
"isDefault": true
},
"problemMatcher": {
"owner": "cpp",
"fileLocation": [
"relative",
"${workspaceFolder}"
],
"pattern": {
"regexp": "^(.*)\\((\\d+)\\)\\s*:\\s*(warning|error)\\s*(\\w+)\\s*:\\s*(.*)$",
"file": 1,
"line": 2,
"severity": 3,
"code": 4,
"message": 5
}
},
"presentation": {
"reveal": "always",
"panel": "shared",
"clear": true
}
},
{
"label": "Build Singleheader (MSVC)",
"type": "shell",
"command": "C:\\Program Files\\PowerShell\\7\\pwsh.exe",
"args": [
"-ExecutionPolicy",
"Bypass",
"-File",
"${workspaceFolder}/scripts/build.ci.ps1",
"singleheader",
"msvc",
"debug"
],
"group": "build",
"problemMatcher": {
"owner": "cpp",
"fileLocation": ["relative", "${workspaceFolder}"],
"pattern": [
{
"regexp": "^(.*)\\((\\d+)\\)\\s*:\\s*(error|warning|info|note)\\s+(\\w{1,2}\\d+)\\s*:\\s*(.*)$",
"file": 1,
"line": 2,
"severity": 3,
"code": 4,
"message": 5
}
]
},
"presentation": {
"reveal": "always",
"panel": "shared",
"clear": true
}
},
{
"label": "Build Unreal (MSVC)",
"type": "shell",
"command": "C:\\Program Files\\PowerShell\\7\\pwsh.exe",
"args": [
"-ExecutionPolicy",
"Bypass",
"-File",
"${workspaceFolder}/scripts/build.ci.ps1",
"unreal",
"msvc",
"debug"
],
"group": "build",
"problemMatcher": {
"owner": "cpp",
"fileLocation": ["relative", "${workspaceFolder}"],
"pattern": [
{
"regexp": "^(.*)\\((\\d+)\\)\\s*:\\s*(error|warning|info|note)\\s+(\\w{1,2}\\d+)\\s*:\\s*(.*)$",
"file": 1,
"line": 2,
"severity": 3,
"code": 4,
"message": 5
}
]
},
"presentation": {
"reveal": "always",
"panel": "shared",
"clear": true
}
}
]
}

626
Readme.md
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@ -1,63 +1,53 @@
# gencpp
An attempt at simple staged metaprogramming for c/c++.
An attempt at simple staged metaprogramming for C/C++.
The library API is a compositon of code element constructors.
These build up a code AST to then serialize with a file builder.
The library API is a composition of code element constructors, and a non-standards-compliant single-pass C/C++ parser.
These build up a code AST to then serialize with a file builder, or can be traversed for staged-reflection of C/C++ code.
### TOC
This code base attempts follow the [handmade philosophy](https://handmade.network/manifesto).
Its not meant to be a black box metaprogramming utility, it should be easy to intergrate into a user's project domain.
* [Notes](#notes)
* [Usage](#usage)
* [Building](#notes)
* [Outline](#outline)
* [What is not provided](#what-is-not-provided)
* [The four constructors](#there-are-four-sets-of-interfaces-for-code-ast-generation-the-library-provides)
* [Predefined Codes](#predefined-codes)
* [Code generation and modification](#code-generation-and-modification)
* [On multithreading](#on-multi-threading)
* [Extending the library](#extending-the-library)
* [TODO](#todo)
## Documentation
* [docs - General](./docs/Readme.md): Overview and additional docs
* [AST_Design](./docs/AST_Design.md): Overvie of ASTs
* [AST Types](./docs/AST_Types.md): Listing of all AST types along with their Code type interface.
* [Parsing](./docs/Parsing.md): Overview of the parsing interface.
* [Parser Algo](./docs/Parser_Algo.md): In-depth breakdown of the parser's implementation.
* [base](./base/Readme.md): Essential (base) library.
* [gen_c_library](./gen_c_library/): C11 library variant generation (single header and segmeented).
* [gen_segmented](./gen_segmented/): Segemented C++ (`gen.<hpp/cpp>`, `gen.dep.<hpp/cpp>`) generation
* [gen_singleheader](./gen_singleheader/): Singlehader C++ generation `gen.hpp`
* [gen_unreal_engine](./gen_unreal_engine/): Unreal Engine thirdparty code generation.
## Notes
The project has reached a sort of *alpha* state, all the current functionality works for the test cases but it will most likely break in many other cases.
**On Partial Hiatus: Life has got me tackling other issues..**
I will be passively updating the library with bug fixes and minor improvements as I use it for my personal projects.
There won't be any major reworks or features to this thing for a while.
The project has no external dependencies beyond:
This project is still in development (very much an alpha state), so expect bugs and missing features.
See [issues](https://github.com/Ed94/gencpp/issues) for a list of known bugs or todos.
* `stdarg.h`
* `stddef.h`
* `stdio.h`
* `errno.h`
* `unistd.h` (Linux/Mac)
* `intrin.h` (Windows)
* `windows.h` (Windows)
The library can already be used to generate code just fine, but the parser is where the most work is needed. If your C++ isn't "down to earth" expect issues.
Dependencies for the project are wrapped within `GENCPP_ROLL_OWN_DEPENDENCIES` (Defining it will disable them).
The majority of the dependency's implementation was derived from the [c-zpl library](https://github.com/zpl-c/zpl).
When gencpp is in a stable state, I will make a C variant with the same feature set.
A single-header version will also be generated for both.
A `natvis` and `natstepfilter` are provided in the scripts directory.
***The editor and scanner have not been implemented yet. The scanner will come first, then the editor.***
A `natvis` and `natstepfilter` are provided in the scripts directory (its outdated, I'll update this readme when its not).
## Usage
A metaprogram is built to generate files before the main program is built. We'll term runtime for this program as `gen_time`. The metaprogram's core implementation are within `gen.hpp` and `gen.cpp` in the project directory.
A metaprogram is built to generate files before the main program is built. We'll term runtime for this program as `GEN_TIME`. The metaprogram's core implementation are within `gen.hpp` and `gen.cpp` in the project directory.
`gen.cpp` \`s `main()` is defined as `gen_main()` which the user will have to define once for their program. There they will dictate everything that should be generated.
In order to keep the locality of this code within the same files the following pattern may be used:
In order to keep the locality of this code within the same files the following pattern may be used (although this pattern isn't the best to use):
Within `program.cpp` :
```cpp
#ifdef GEN_TIME
#include "gen.hpp"
#ifdef gen_time
...
u32 gen_main()
@ -66,25 +56,26 @@ u32 gen_main()
}
#endif
// "Stage" agnostic code.
#ifndef gen_time
#ifndef GEN_TIME
#include "program.gen.cpp"
// Regular runtime dependent on the generated code here.
#endif
```
The design uses a constructive builder API for the code to generate.
The user is given `Code` objects that are used to build up the AST.
The user is provided `Code` objects that are used to build up the AST.
Example using each construction interface:
### Upfront
Validation and construction through a functional interface.
```cpp
Code t_uw = def_type( name(uw) );
Code t_uw = def_type( name(usize) );
Code t_allocator = def_type( name(allocator) );
Code t_string_const = def_type( name(char), def_specifiers( args( ESpecifier::Const, ESpecifier::Ptr ) ));
@ -101,12 +92,14 @@ Code header;
### Parse
Validation through ast construction.
```cpp
Code header = parse_struct( code(
struct ArrayHeader
{
uw Num;
uw Capacity;
usize Num;
usize Capacity;
allocator Allocator;
};
));
@ -115,557 +108,38 @@ Code header = parse_struct( code(
### Untyped
No validation, just glorified text injection.
```cpp
Code header = untyped_str( code(
Code header = code_str(
struct ArrayHeader
{
uw Num;
uw Capacity;
usize Num;
usize Capacity;
allocator Allocator;
};
));
);
```
`name` is a helper macro for providing a string literal with its size, intended for the name paraemter of functions.
`name` is a helper macro for providing a string literal with its size, intended for the name parameter of functions.
`code` is a helper macro for providing a string literal with its size, but intended for code string parameters.
`args` is a helper macro for providing the number of arguments to varadic constructors.
`args` is a helper macro for providing the number of arguments to varadic constructors.
`code_str` is a helper macro for writting `untyped_str( code( <content> ))`
All three constrcuton interfaces will generate the following C code:
```cpp
struct ArrayHeader
{
uw Num;
uw Capacity;
usize Num;
usize Capacity;
allocator Allocator;
};
```
**Note: The formatting shown here is not how it will look. For your desired formatting its recommended to run a pass through the files with an auto-formatter.**
**Note: The formatting shown here is not how it will look. For your desired formatting its recommended to run a pass through the files with an auto-formatter.**
*(The library currently uses clang-format for formatting, beware its pretty slow...)*
## Building
An example of building is provided in the test directory.
There are two meson build files the one within test is the program's build specification.
The other one in the gen directory within test is the metaprogram's build specification.
Both of them build the same source file: `test.cpp`. The only differences are that gen needs a different relative path to the include directories and defines the macro definition: `gen_time`.
This method is setup where all the metaprogram's code are the within the same files as the regular program's code.
## Outline
### *WHAT IS NOT PROVIDED*
* Lambdas
* Vendor provided dynamic dispatch (virtuals) : `override` and `final` specifiers complicate the specifier parsing and serialization. (I'll problably end up adding in later)
* RTTI
* Exceptions
* Execution statement validation : Execution expressions are defined using the untyped API.
Keywords kept from "Modern C++":
* constexpr : Great to store compile-time constants.
* consteval : Technically fine, need to make sure to execute in moderation.
* constinit : Better than constexpr at doing its job, however, its only c++ 20.
* export : Useful if c++ modules ever come around to actually being usable.
* import : ^^
* module : ^^
When it comes to expressions:
**There is no support for validating expressions.**
**The reason:** Its difficult to parse without enough benefits.
Most of the time, the critical complex metaprogramming conundrums are producing the frame of abstractions around the expressions (which this library provides constructors to help validate, you can skip that process by using the untyped constructors).
Its not a priority to add such a level of complexity to the library when there isn't a high reward or need for it.
Especially when the priority is to keep this library small and easy to grasp for what it is.
When it comes to templates:
Only trivial template support is provided. the intention is for only simple, non-recursive subsitution.
The parameters of the template are treated like regular parameter AST entries.
This means that the typename entry for the parameter AST would be either:
* `class`
* `typename`
* A fundamental type, function, or pointer type.
Anything beyond this usage is not supported by parse_template for arguments (at least not intentionally).
Use at your own mental peril...
*Concepts and Constraints are not supported, its usage is non-tirival substiution.*
### The Data & Interface
As mentioned in [Usage](#usage), the user is provided Code objects by calling the constructor's functions to generate them or find existing matches.
The AST is managed by the library and provided the user via its interface.
However, the user may specifiy memory configuration.
Data layout of AST struct:
```cpp
union {
struct
{
AST* Attributes; // Class, Enum, Function, Struct, Typedef, Union, Using, Variable
AST* Specs; // Function, Operator, Type symbol, Variable
union {
AST* ParentType; // Class, Struct
AST* ReturnType; // Function, Operator
AST* UnderlyingType; // Enum, Typedef
AST* ValueType; // Parameter, Variable
};
AST* Params; // Function, Operator, Template
union {
AST* ArrExpr; // Type Symbol
AST* Body; // Class, Enum, Function, Namespace, Struct, Union
AST* Declaration; // Friend, Template
AST* Value; // Parameter, Variable
};
};
StringCached Content; // Attributes, Comment, Execution, Include
SpecifierT ArrSpecs[AST::ArrSpecs_Cap]; // Specifiers
};
union {
AST* Prev;
AST* Front; // Used by CodeBody
AST* Last; // Used by CodeParam
};
union {
AST* Next;
AST* Back; // Used by CodeBody
};
AST* Parent;
StringCached Name;
CodeT Type;
ModuleFlag ModuleFlags;
union {
OperatorT Op;
AccessSpec ParentAccess;
s32 NumEntries;
};
```
*`CodeT` is a typedef for `ECode::Type` which has an underlying type of `u32`*
*`OperatorT` is a typedef for `EOperator::Type` which has an underlying type of `u32`*
*`StringCahced` is a typedef for `String const`, to denote it is an interned string*
*`String` is the dynamically allocated string type for the library*
AST widths are setup to be AST_POD_Size.
The width dictates how much the static array can hold before it must give way to using an allocated array:
```cpp
constexpr static
uw ArrSpecs_Cap =
(
AST_POD_Size
- sizeof(AST*) * 3
- sizeof(StringCached)
- sizeof(CodeT)
- sizeof(ModuleFlag)
- sizeof(s32)
)
/ sizeof(SpecifierT) -1; // -1 for 4 extra bytes (Odd num of AST*)
```
*Ex: If the AST_POD_Size is 128 the capacity of the static array is 20.*
Data Notes:
* The allocator definitions used are exposed to the user incase they want to dictate memory usage
* You'll find the memory handling in `init`, `gen_string_allocator`, `get_cached_string`, `make_code`.
* ASTs are wrapped for the user in a Code struct which is a warpper for a AST* type.
* Both AST and Code have member symbols but their data layout is enforced to be POD types.
* This library treats memory failures as fatal.
* Strings are stored in their own set of arenas. AST constructors use cached strings for names, and content.
* `StringArenas`, `StringCache`, `Allocator_StringArena`, and `Allocator_StringTable` are the associated containers or allocators.
* Strings used for seralization and file buffers are not contained by those used for cached strings.
* They are currently using `Memory::GlobalAllocator`, which are tracked array of arenas that grows as needed (adds buckets when one runs out).
* Memory within the buckets is not resused, so its inherently wasteful (most likely will give non-cached strings their own tailored allocator later)
* Linked lists used children nodes on bodies, and parameters.
* Its intended to generate the AST in one go and serialize after. The contructors and serializer are designed to be a "one pass, front to back" setup.
Two generic templated containers are used throughout the library:
* `template< class Type> struct Array`
* `template< class Type> struct HashTable`
Both Code and AST definitions have a `template< class Type> Code/AST cast()`. Its just an alternative way to explictly cast to each other.
Otherwise the library is free of any templates.
The following CodeTypes are used which the user may optionally use strong typeing with if they enable: `GEN_ENFORCE_STRONG_CODE_TYPES`
* CodeBody : Has support for `for-range` iterating across Code objects.
* CodeAttributes
* CodeComment
* CodeClass
* CodeEnum
* CodeExec
* CodeExtern
* CodeInclude
* CodeFriend
* CodeFn
* CodeModule
* CodeNamespace
* CodeOperator
* CodeOpCast
* CodeParam : Has suppor for `for-range` iterating across parameters.
* CodeSpecifier : Has support for `for-range` iterating across specifiers.
* CodeStruct
* CodeTemplate
* CodeType
* CodeTypedef
* CodeUnion
* CodeUsing
* CodeUsingNamespace
* CodeVar
Each Code boy has an assoicated "filtered AST" with the naming convention: `AST_<CodeName>`
Unrelated fields of the AST for that node type are omitted and only necesary padding members are defined otherwise.
Retreiving a raw version of the ast can be done using the `raw()` function defined in each AST.
## There are three sets of interfaces for Code AST generation the library provides
* Upfront
* Parsing
* Untyped
### Upfront Construction
All component ASTs must be previously constructed, and provided on creation of the code AST.
The construction will fail and return Code::Invalid otherwise.
Interface :``
* def_attributes
* *This is preappened right before the function symbol, or placed after the class or struct keyword for any flavor of attributes used.*
* *Its up to the user to use the desired attribute formatting: `[[]]` (standard), `__declspec` (Microsoft), or `__attribute__` (GNU).*
* def_comment
* def_class
* def_enum
* def_execution
* *This is equivalent to untyped_str, except that its intended for use only in execution scopes.*
* def_extern_link
* def_friend
* def_function
* def_include
* def_module
* def_namespace
* def_operator
* def_operator_cast
* def_param
* def_params
* def_specifier
* def_specifiers
* def_struct
* def_template
* def_type
* def_typedef
* def_union
* def_using
* def_using_namespace
* def_variable
Bodies:
* def_body
* def_class_body
* def_enum_body
* def_export_body
* def_extern_link_body
* def_function_body
* *Use this for operator bodies as well*
* def_global_body
* def_namespace_body
* def_struct_body
* def_union_body
Usage:
```cpp
<name> = def_<function type>( ... );
Code <name>
{
...
<name> = def_<function name>( ... );
}
```
When using the body functions, its recommended to use the args macro to auto determine the number of arguments for the varadic:
```cpp
def_global_body( args( ht_entry, array_ht_entry, hashtable ));
// instead of:
def_global_body( 3, ht_entry, array_ht_entry, hashtable );
```
If a more incremental approach is desired for the body ASTs, `Code def_body( CodeT type )` can be used to create an empty body.
When the members have been populated use: `AST::validate_body` to verify that the members are valid entires for that type.
### Parse construction
A string provided to the API is parsed for the intended language construct.
Interface :
* parse_class
* parse_enum
* parse_export_body
* parse_extern_link
* parse_friend
* Purposefully are only support forward declares with this constructor.
* parse_function
* parse_global_body
* parse_namespace
* parse_operator
* parse_operator_cast
* parse_struct
* parse_template
* parse_type
* parse_typedef
* parse_union
* parse_using
* parse_variable
The lexing and parsing takes shortcuts from whats expected in the standard.
* Numeric literals are not check for validity.
* The parse API treats any execution scope definitions with no validation and are turned into untyped Code ASTs.
* *This includes the assignment of variables.*
* Attributes ( `[[]]` (standard), `__declspec` (Microsoft), or `__attribute__` (GNU) )
* Assumed to *come before specifiers* (`const`, `constexpr`, `extern`, `static`, etc) for a function
* Or in the usual spot for class, structs, (*right after the declaration keyword*)
* typedefs have attributes with the type (`parse_type`)
* As a general rule; if its not available from the upfront contructors, its not available in the parsing constructors.
* *Upfront constructors are not necessarily used in the parsing constructors, this is just a good metric to know what can be parsed.*
Usage:
```cpp
Code <name> = parse_<function name>( string with code );
Code <name> = def_<function name>( ..., parse_<function name>(
<string with code>
));
Code <name> = make_<function name>( ... )
{
<name>->add( parse_<function name>(
<string with code>
));
}
```
### Untyped constructions
Code ASTs are constructed using unvalidated strings.
Interface :
* token_fmt_va
* token_fmt
* untyped_str
* untyped_fmt
* untyped_token_fmt
During serialization any untyped Code AST has its string value directly injected inline of whatever context the content existed as an entry within.
Even though these are not validated from somewhat correct c/c++ syntax or components, it doesn't mean that Untyped code can be added as any component of a Code AST:
* Untyped code cannot have children, thus there cannot be recursive injection this way.
* Untyped code can only be a child of a parent of body AST, or for values of an assignment (ex: variable assignment).
These restrictions help prevent abuse of untyped code to some extent.
Usage Conventions:
```cpp
Code <name> = def_varaible( <type>, <name>, untyped_<function name>(
<string with code>
));
```
Template metaprogramming in the traditional sense becomes possible with the use of `token_fmt` and parse constructors:
```cpp
StrC value = txt_StrC("Something");
char const* template_str = txt(
Code with <key> to replace with token_values
...
);
char const* gen_code_str = token_fmt( "key", value, template_str );
Code <name> = parse_<function name>( gen_code_str );
```
## Predefined Codes
The following are provided predefined by the library as they are commonly used:
* `access_public`
* `access_protected`
* `access_private`
* `module_global_fragment`
* `module_private_fragment`
* `pragma_once`
* `spec_const`
* `spec_consteval`
* `spec_constexpr`
* `spec_constinit`
* `spec_extern_linkage` (extern)
* `spec_global` (global macro)
* `spec_inline`
* `spec_internal_linkage` (internal macro)
* `spec_local_persist` (local_persist macro)
* `spec_mutable`
* `spec_ptr`
* `spec_ref`
* `spec_register`
* `spec_rvalue`
* `spec_static_member` (static)
* `spec_thread_local`
* `spec_volatile`
* `spec_type_signed`
* `spec_type_unsigned`
* `spec_type_short`
* `spec_type_long`
* `t_auto`
* `t_void`
* `t_int`
* `t_bool`
* `t_char`
* `t_wchar_t`
* `t_class`
* `t_typename`
Optionally the following may be defined if `GEN_DEFINE_LIBRARY_CODE_CONSTANTS` is defined
* `t_b32`
* `t_s8`
* `t_s16`
* `t_s32`
* `t_s64`
* `t_u8`
* `t_u16`
* `t_u32`
* `t_u64`
* `t_sw`
* `t_uw`
* `t_f32`
* `t_f64`
## Extent of operator overload validation
The AST and constructors will be able to validate that the arguments provided for the operator type match the expected form:
* If return type must match a parameter
* If number of parameters is correct
* If added as a member symbol to a class or struct, that operator matches the requirements for the class (types match up)
The user is responsible for making sure the code types provided are correct
and have the desired specifiers assigned to them beforehand.
## Code generation and modification
There are three provided file interfaces:
* Builder
* Editor
* Scanner
Editor and Scanner are disabled by default, use `GEN_FEATURE_EDITOR` and `GEN_FEATURE_SCANNER` to enable them.
### Builder is a similar object to the jai language's string_builder
* The purpose of it is to generate a file.
* A file is specified and opened for writting using the open( file_path) ) function.
* The code is provided via print( code ) function will be seralized to its buffer.
* When all seralization is finished, use the write() command to write the buffer to the file.
### Editor is for editing a series of files based on a set of requests provided to it
* The purpose is to overrite a specific file, it places its contents in a buffer to scan.
* Requests are populated using the following interface:
* add : Add code.
* remove : Remove code.
* replace: Replace code.
All three have the same parameters with exception to remove which only has SymbolInfo and Policy:
* SymbolInfo:
* File : The file the symbol resides in. Leave null to indicate to search all files. Leave null to indicated all-file search.
* Marker : #define symbol that indicates a location or following signature is valid to manipulate. Leave null to indicate the signature should only be used.
* Signature : Use a Code symbol to find a valid location to manipulate, can be further filtered with the marker. Leave null to indicate the marker should only be used.
* Policy : Additional policy info for completing the request (empty for now)
* Code : Code to inject if adding, or replace existing code with.
Additionally if `GEN_FEATURE_EDITOR_REFACTOR` is defined, refactor( file_path, specification_path ) wil be made available.
Refactor is based of the refactor library and uses its interface.
It will on call add a request to the queue to run the refactor script on the file.
### Scanner allows the user to generate Code ASTs by reading files
* The purpose is to grab definitions to generate metadata or generate new code from these definitions.
* Requests are populated using the add( SymbolInfo, Policy ) function. The symbol info is the same as the one used for the editor. So is the case with Policy.
The file will only be read from, no writting supported.
One great use case is for example: generating the single-header library for gencpp!
### Additional Info (Editor and Scanner)
When all requests have been populated, call process_requests().
It will provide an output of receipt data of the results when it completes.
Files may be added to the Editor and Scanner additionally with add_files( num, files ).
This is intended for when you have requests that are for multiple files.
Request queue in both Editor and Scanner are cleared once process_requests completes.
## On multi-threading
Currently unsupported. The following changes would have to be made:
* Setup static data accesss with fences if more than one thread will generate ASTs ( or keep a different set for each thread)
* Make sure local peristent data of functions are also thread local.
* The builder should be done on a per-thread basis.
* Due to the design of the editor and scanner, it will most likely be best to make each file a job to process request entries on. Receipts should have an an array to store per thread. They can be combined to the final reciepts array when all files have been processed.
## Extending the library
This library is relatively very small, and can be extended without much hassle.
The untyped codes and builder/editor/scanner can be technically be used to circumvent
any sort of constrictions the library has with: modern c++, templates, macros, etc.
Typical use case is for getting define constants an old C/C++ library with the scanner:
Code parse_defines() can emit a custom code AST with Macro_Constant type.
Another would be getting preprocessor or template metaprogramming Codes from Unreal Engine definitions, etc.
The rules for constructing the AST are largely bound the syntax rules for what can be composed with whichever version of C++ your targeting.
The convention you'll see used throughout the API of the library is as follows:
1. Check name or parameters to make sure they are valid for the construction requested
2. Create a code object using `make_code`.
3. Populate immediate fields (Name, Type, ModuleFlags, etc)
4. Populate sub-entires using `add_entry`. If using the default seralization function `to_string`, follow the order at which entires are expected to appear (there is a strong ordering expected).
Names or Content fields are interned strings and thus showed be cached using `get_cached_string` if its desired to preserve that behavior.
`def_operator` is the most sophisitacated constructor as it has multiple permutations of definitions that could be created that are not trivial to determine if valid.
# TODO
* Implement a context stack for the parsing, allows for accurate scope validation for the AST types.
* Make a test suite thats covers some base cases and zpl containers (+ anything else suitable)
* Finish support for module specifiers and standard/platform attributes.
* Generate a single-header library.
* Improve the allocation strategy for strings in `AST::to_string`, `Parser::lex`, and `token_fmt_va`
* May be in need of a better name, I found a few repos with this same one...
See the [scripts directory](scripts/).

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## Navigation
# base
[Top](../Readme.md)
* [docs](../docs/Readme.md)
The library is fragmented into a series of headers and source files meant to be scanned in and then generated to a standard target format, or a user's desires.
Standard formats:
* **base**: Files are in granular pieces separated into four directories:
* **dependencies**: Originally from the c-zpl library and modified thereafter.
* **components**: The essential definitions of the library.
* **helpers**: Contains helper functionality used by base and other libraries to regenerate or generate the other library formats.
* `base_codegen.hpp`: Helps with self-hosted code generation of enums, and operator overload inlines of the code types.
* `<push/pop>.<name>.inline.<hpp>`: macros that are meant to be injected at specific locations of the library.
* `misc.hpp`: Misc functionality used by the library generation metaprograms.
* `undef.macros.h`: Undefines all macros from library that original were intended to leak into user code.
* **auxillary**: Non-essential tooling:
* `Builder`: Similar conceptually to Jai programming language's *builder*, just opens a file and prepares a string buffer to serialize code into (`builder_print`, `builder_print_fmt`). Then write & close the file when completed (`builder_write`).
* **`Scanner`**: Interface to load up `Code` from files two basic funcctions are currently provided.
* `scan_file`: Used mainly by the library format generators to directly scan files into untyped `Code` (raw string content, pre-formatted no AST parsed).
* `parse_file`: Used to read file and then parsed to populate a `CodeBody` AST.
* CSV parsing via one or two columns simplified.
* **gen_segemetned**: Dependencies go into gen.dep.{hpp/cpp} and components into gen.{hpp/cpp}
* **gen_singleheader**: Everything into a single file: gen.hpp
* **gen_unreal_engine**: Like gen_segemented but the library is modified slightly to compile as a thirdparty library within an Unreal Engine plugin or module.
* **gen_c_library**: The library is heavily modifed into C11 compliant code. A segemented and single-header set of variants are generatd.
Code not making up the core library is located in `auxiliary/<auxiliary_name>.<hpp/cpp>`. These are optional extensions or tools for the library.
## Dependencies
The project has no external dependencies beyond:
* `errno.h`
* `stat.h`
* `stdarg.h`
* `stddef.h`
* `stdio.h`
* `copyfile.h` (Mac)
* `types.h` (Linux)
* `sys/man.h` (Linux)
* `fcntl.h` (POSXIX Filesystem)
* `unistd.h` (Linux/Mac)
* `intrin.h` (Windows)
* `io.h` (Windows with gcc)
* `windows.h` (Windows)
Dependencies for the project are wrapped within `GENCPP_ROLL_OWN_DEPENDENCIES` (Defining it will disable them).
The majority of the dependency's implementation was derived from the [c-zpl library](https://github.com/zpl-c/zpl).
See the following files for any updates:
* [`platform.hpp`](./dependencies/platform.hpp)
* [`src_start.cpp`](./dependencies/src_start.cpp)
* [`filesystem.cpp`](./dependencies/filesystem.cpp)
* [`memory.cpp`](./dependencies/memory.cpp)
## Conventions
This library was written in a subset of C++ where the following are not used at all:
* RAII (Constructors/Destructors), lifetimes are managed using named static or regular functions.
* Language provide dynamic dispatch, RTTI
* Object-Oriented Inheritance
* Exceptions
Polymorphic & Member-functions are used as an ergonomic choice, along with a conserative use of operator overloads.
The base library itself does not use anything but C-like features to allow for generating a derviative compatiable with C.
Member function support or free-functions with reference object passing are wrapped in `! GEN_C_LIKE CPP` preprocess conditionals.
## C++ template usage
There are only 4 template definitions in the entire library (C++ versions). (`Array<Type>`, `Hashtable<Type>`, `swap<Type>`, and `tmpl_cast<CodeT>(CodeT code)`)
Two generic templated containers are used throughout the library:
* `template< class Type> struct Array`
* `template< class Type> struct HashTable`
`tmpl_cast<CodeT>(CodeT code)` is just an alternative way to explicitly cast to code. Its usage is wrapped in a macro called `cast` for the base library (needed for interoperability with C).
`template< class Type> swap( Type& a, Type& b)` is used over a macro.
Otherwise the library is free of any templates.
## Macro usage
Since this is a meta-programming library, it was desired to keep both templates and macros (especially macros) usage very limited.
Most macros are defined within [macros.hpp](./dependencies/macros.hpp).
The most advanced macro usage is `num_args` which is a helper for counting the number of arguments of another macro.
Any large macros used implementing the gen interface or parser are going to be phased out in favor of just forcinlined functions.
*(Unless there is a hot-path that requires them)*
The vast majority of macros should be single-line subsitutions that either add:
* Improvements to searching
* Inteniality of keyword usage
* A feature that only the preprocessor has (ex: function name reflection or stringifying)
* Compatibility of statements or expressions bewteen C & C++ that cannot be parsed by gencpp itself.
* Masking highly verbose syntax (the latter is getting phased out).
[gen_c_library](../gen_c_library/) has the most advanced set of macros for c11's generic selection.
* A significant amount of explicit code geneeration is utilized to keep abuse of the preprocessor to the absolute minimum.
* There is a heavy set of documentation inlined wth them; their naming is also highly verbose and explicit.
* See its documentation for more information.
## On base code generation
There are ***five*** header files which are automatically generated using [base_codegen.hpp](./helpers/base_codegen.hpp) by [base.cpp](./base.cpp). They are all located in [components/gen](./components/gen/).
* [`ecodetypes.hpp`](./components/gen/ecode.hpp): `CodeType` enum definition and related implementaiton. Generation is based off of [`ECodeType.csv](./enums/ECodeTypes.csv).
* [`especifier.hpp`](./components/gen/especifier.hpp): `Specifier` enum definition, etc. Generated using [`ESpecifier.csv`](./enums/ESpecifier.csv).
* [`eoperator.hpp`](./components/gen/eoperator.hpp): `Operator` enum definition, etc. Generated using [`EOperator.hpp`](./enums/EOperator.csv).
* [`etoktype.cpp`](./components/gen/etoktype.cpp): `TokType` enum defininition, etc. Used by the lexer and parser backend. Uses two csvs:
* [`ETokType.csv`](./enums/ETokType.csv): Provides the enum entries and their strinng ids.
* [`AttributeTokens.csv`](./enums/AttributeTokens.csv): Provides tokens entries that should be considered as attributes by the lexer and parser. Sspecfiically macro attributes such as those use for exporting symbols.
* [`ast_inlines.hpp`](./components/gen/ast_inlines.hpp): Member trivial `operator` definitions for C++ code types. Does not use a csv.
[`misc.hpp`](./helpers/misc.hpp): Has shared functions used by the library generation meta-programs throughout this codebase.
## On multi-threading
Currently unsupported. I want the library to be *stable* and *correct*, with the addition of exhausting all basic single-threaded optimizations before I consider multi-threading.
## Extending the library
This library is relatively very small (for parsing C++), and can be extended without much hassle.
The convention you'll see used throughout the upfront interface of the library is as follows:
1. Check name or parameters to make sure they are valid for the construction requested
2. Create a code object using `make_code`.
3. Populate immediate fields (Name, Type, ModuleFlags, etc)
4. Populate sub-entires using `add_entry`. If using the default serialization function `to_string`, follow the order at which entires are expected to appear (there is a strong ordering expected).
Names or Content fields are interned strings and thus showed be cached using `get_cached_string` if its desired to preserve that behavior.
`def_operator` is the most sophisticated upfront constructor as it has multiple permutations of definitions that could be created that are not trivial to determine if valid.
The parser is documented under [`docs/Parsing.md`](../docs/Parsing.md) and [`docs/Parser_Algo.md`](../docs/Parser_Algo.md). Extending it is more serious.
## A note on compilation and runtime generation speed
The library is designed to be fast to compile and generate code at runtime as fast as resonable possible on a debug build.
Its recommended that your metaprogam be compiled using a single translation unit (unity build).

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#ifdef GEN_INTELLISENSE_DIRECTIVES
# include "builder.hpp"
#endif
#pragma region Builder
Builder builder_open( char const* path )
{
Builder result;
FileError error = file_open_mode( & result.File, EFileMode_WRITE, path );
if ( error != EFileError_NONE )
{
log_failure( "gen::File::open - Could not open file: %s", path);
return result;
}
result.Buffer = string_make_reserve( GlobalAllocator, Builder_StrBufferReserve );
// log_fmt("$Builder - Opened file: %s\n", result.File.filename );
return result;
}
void builder_pad_lines( Builder* builder, s32 num )
{
string_append_strc( & builder->Buffer, txt("\n") );
}
void builder_print( Builder* builder, Code code )
{
String str = code_to_string(code);
// const ssize len = str.length();
// log_fmt( "%s - print: %.*s\n", File.filename, len > 80 ? 80 : len, str.Data );
string_append_string( & builder->Buffer, str );
}
void builder_print_fmt_va( Builder* builder, char const* fmt, va_list va )
{
ssize res;
char buf[ GEN_PRINTF_MAXLEN ] = { 0 };
res = str_fmt_va( buf, count_of( buf ) - 1, fmt, va ) - 1;
string_append_c_str_len( (String*) & (builder->Buffer), (char const*)buf, res);
}
void builder_write(Builder* builder)
{
b32 result = file_write( & builder->File, builder->Buffer, string_length(builder->Buffer) );
if ( result == false )
log_failure("gen::File::write - Failed to write to file: %s\n", file_name( & builder->File ) );
log_fmt( "Generated: %s\n", builder->File.filename );
file_close( & builder->File );
string_free(& builder->Buffer);
}
#pragma endregion Builder

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#ifdef GEN_INTELLISENSE_DIRECTIVES
# pragma once
# include "helpers/push_ignores.inline.hpp"
# include "components/header_start.hpp"
# include "components/types.hpp"
# include "components/gen/ecode.hpp"
# include "components/gen/eoperator.hpp"
# include "components/gen/especifier.hpp"
# include "components/ast.hpp"
# include "components/code_types.hpp"
# include "components/ast_types.hpp"
# include "components/interface.hpp"
# include "components/inlines.hpp"
# include "components/gen/ast_inlines.hpp"
# include "components/header_end.hpp"
using namespace gen;
#endif
#pragma region Builder
struct Builder;
typedef struct Builder Builder;
Builder builder_open ( char const* path );
void builder_pad_lines ( Builder* builder, s32 num );
void builder_print ( Builder* builder, Code code );
void builder_print_fmt_va( Builder* builder, char const* fmt, va_list va );
void builder_print_fmt ( Builder* builder, char const* fmt, ... ) {
va_list va;
va_start( va, fmt );
builder_print_fmt_va( builder, fmt, va );
va_end( va );
}
void builder_write( Builder* builder );
struct Builder
{
FileInfo File;
String Buffer;
#if GEN_COMPILER_CPP && ! GEN_C_LIKE_CPP
forceinline static Builder open( char const* path ) { return builder_open(path); }
forceinline void pad_lines( s32 num ) { return builder_pad_lines(this, num); }
forceinline void print( Code code ) { return builder_print(this, code); }
forceinline void print_fmt( char const* fmt, ... ) {
va_list va;
va_start( va, fmt );
builder_print_fmt_va( this, fmt, va );
va_end( va );
}
forceinline void write() { return builder_write(this); }
#endif
};
#if GEN_COMPILER_CPP && ! GEN_C_LIKE_CPP
void builder_pad_lines( Builder& builder, s32 num ) { return builder_pad_lines(& builder, num); }
void builder_print ( Builder& builder, Code code ) { return builder_print(& builder, code); }
void builder_write ( Builder& builder ) { return builder_write(& builder ); }
void builder_print_fmt( Builder& builder, char const* fmt, ...) {
va_list va;
va_start( va, fmt );
builder_print_fmt_va( & builder, fmt, va );
va_end( va );
}
#endif
#pragma endregion Builder

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#ifdef GEN_INTELLISENSE_DIRECTIVES
# pragma once
# include "helpers/push_ignores.inline.hpp"
# include "components/header_start.hpp"
# include "components/types.hpp"
# include "components/gen/ecode.hpp"
# include "components/gen/eoperator.hpp"
# include "components/gen/especifier.hpp"
# include "components/ast.hpp"
# include "components/code_types.hpp"
# include "components/ast_types.hpp"
# include "components/interface.hpp"
# include "components/inlines.hpp"
# include "components/gen/ast_inlines.hpp"
# include "components/header_end.hpp"
#endif
/*
Explicitly generates a resolved definition of a cpp template definition.
TODO(Ed): Needs implementing for the C-library variant.
TODO(Ed): We need a non <token> syntax subst implemtnation for Strings for this to work. It must subst keywords directly based on template parameter names.
This is only meant to be used on relatively trivial templates, where the type or numeric is mostly a 'duck' type.
It cannot parse complex template parameters.
The varadic args should correspond 1:1 with the type of objects the generator expects from the template's parameters.alignas.
*/
CodeOperator gen_operator_template( CodeTemplate template, ... );
CodeFn gen_func_template( CodeTemplate template, ... );
Code gen_class_struct_template( CodeTemplate template, ... );
Code gen_template( CodeTemplate template, ... );
Code gen_template( StrC template, StrC instantiation );

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#ifdef GEN_INTELLISENSE_DIRECTIVES
# include "scanner.hpp"
#endif
#pragma region Scanner
Code scan_file( char const* path )
{
FileInfo file;
FileError error = file_open_mode( & file, EFileMode_READ, path );
if ( error != EFileError_NONE )
{
GEN_FATAL( "scan_file: Could not open: %s", path );
}
ssize fsize = file_size( & file );
if ( fsize <= 0 )
{
GEN_FATAL("scan_file: %s is empty", path );
}
String str = string_make_reserve( GlobalAllocator, fsize );
file_read( & file, str, fsize );
string_get_header(str)->Length = fsize;
// Skip GEN_INTELLISENSE_DIRECTIVES preprocessor blocks
// Its designed so that the directive should be the first thing in the file.
// Anything that comes before it will also be omitted.
{
#define current (*scanner)
#define matched 0
#define move_fwd() do { ++ scanner; -- left; } while (0)
const StrC directive_start = txt( "ifdef" );
const StrC directive_end = txt( "endif" );
const StrC def_intellisense = txt("GEN_INTELLISENSE_DIRECTIVES" );
bool found_directive = false;
char const* scanner = (char const*)str;
s32 left = fsize;
while ( left )
{
// Processing directive.
if ( current == '#' )
{
move_fwd();
while ( left && char_is_space( current ) )
move_fwd();
if ( ! found_directive )
{
if ( left && str_compare_len( scanner, directive_start.Ptr, directive_start.Len ) == matched )
{
scanner += directive_start.Len;
left -= directive_start.Len;
while ( left && char_is_space( current ) )
move_fwd();
if ( left && str_compare_len( scanner, def_intellisense.Ptr, def_intellisense.Len ) == matched )
{
scanner += def_intellisense.Len;
left -= def_intellisense.Len;
found_directive = true;
}
}
// Skip to end of line
while ( left && current != '\r' && current != '\n' )
move_fwd();
move_fwd();
if ( left && current == '\n' )
move_fwd();
continue;
}
if ( left && str_compare_len( scanner, directive_end.Ptr, directive_end.Len ) == matched )
{
scanner += directive_end.Len;
left -= directive_end.Len;
// Skip to end of line
while ( left && current != '\r' && current != '\n' )
move_fwd();
move_fwd();
if ( left && current == '\n' )
move_fwd();
// sptr skip_size = fsize - left;
if ( (scanner + 2) >= ( (char const*) str + fsize ) )
{
mem_move( str, scanner, left );
string_get_header(str)->Length = left;
break;
}
mem_move( str, scanner, left );
string_get_header(str)->Length = left;
break;
}
}
move_fwd();
}
#undef move_fwd
#undef matched
#undef current
}
file_close( & file );
return untyped_str( string_to_strc(str) );
}
CodeBody parse_file( const char* path ) {
FileContents file = file_read_contents( GlobalAllocator, true, path );
StrC content = { file.size, (char const*)file.data };
CodeBody code = parse_global_body( content );
log_fmt("\nParsed: %s\n", path);
return code;
}
CSV_Column parse_csv_one_column(AllocatorInfo allocator, char const* path) {
FileContents content = file_read_contents( allocator, file_zero_terminate, path );
Arena csv_arena = arena_init_from_memory(content.data, content.size);
CSV_Column result;
csv_parse( & result.ADT, rcast(char*, content.data), allocator, false );
result.Content = result.ADT.nodes[0].nodes;
return result;
}
CSV_Columns2 parse_csv_two_columns(AllocatorInfo allocator, char const* path) {
FileContents content = file_read_contents( allocator, file_zero_terminate, path );
Arena csv_arena = arena_init_from_memory(content.data, content.size);
CSV_Columns2 result;
csv_parse( & result.ADT, rcast(char*, content.data), allocator, false );
result.Col_1 = result.ADT.nodes[0].nodes;
result.Col_2 = result.ADT.nodes[1].nodes;
return result;
}
#pragma endregion Scanner

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#ifdef GEN_INTELLISENSE_DIRECTIVES
# pragma once
# include "helpers/push_ignores.inline.hpp"
# include "components/header_start.hpp"
# include "components/types.hpp"
# include "components/gen/ecode.hpp"
# include "components/gen/eoperator.hpp"
# include "components/gen/especifier.hpp"
# include "components/ast.hpp"
# include "components/code_types.hpp"
# include "components/ast_types.hpp"
# include "components/interface.hpp"
# include "components/inlines.hpp"
# include "components/gen/ast_inlines.hpp"
# include "components/header_end.hpp"
#endif
#pragma region Scanner
// This is a simple file reader that reads the entire file into memory.
// It has an extra option to skip the first few lines for undesired includes.
// This is done so that includes can be kept in dependency and component files so that intellisense works.
Code scan_file( char const* path );
CodeBody parse_file( const char* path );
// The follow is basic support for light csv parsing (use it as an example)
// Make something robust if its more serious.
typedef struct CSV_Column CSV_Column;
struct CSV_Column {
CSV_Object ADT;
Array(ADT_Node) Content;
};
typedef struct CSV_Columns2 CSV_Columns2;
struct CSV_Columns2 {
CSV_Object ADT;
Array(ADT_Node) Col_1;
Array(ADT_Node) Col_2;
};
CSV_Column parse_csv_one_column(AllocatorInfo allocator, char const* path);
CSV_Columns2 parse_csv_two_columns(AllocatorInfo allocator, char const* path);
#pragma endregion Scanner

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#define GEN_DEFINE_LIBRARY_CODE_CONSTANTS
#define GEN_ENFORCE_STRONG_CODE_TYPES
#define GEN_EXPOSE_BACKEND
#define GEN_C_LIKE_CPP 1
#include "gen.cpp"
#include "helpers/push_ignores.inline.hpp"
#include <stdlib.h>
GEN_NS_BEGIN
#include "helpers/base_codegen.hpp"
#include "helpers/misc.hpp"
GEN_NS_END
using namespace gen;
constexpr char const* path_format_style = "../scripts/.clang-format";
constexpr char const* scratch_file = "build/scratch.hpp";
Code format( Code code ) {
return code_refactor_and_format(code, scratch_file, nullptr, path_format_style );
}
constexpr char const* generation_notice =
"// This file was generated automatially by gencpp's bootstrap.cpp "
"(See: https://github.com/Ed94/gencpp)\n\n";
int gen_main()
{
gen::init();
CodeBody gen_component_header = def_global_body( args(
def_preprocess_cond( PreprocessCond_IfDef, txt("GEN_INTELLISENSE_DIRECTIVES") ),
pragma_once,
def_include(txt("components/types.hpp")),
preprocess_endif,
fmt_newline,
untyped_str( to_strc_from_c_str(generation_notice) )
));
CodeBody ecode = gen_ecode ( "enums/ECodeTypes.csv" );
CodeBody eoperator = gen_eoperator ( "enums/EOperator.csv" );
CodeBody especifier = gen_especifier( "enums/ESpecifier.csv" );
CodeBody ast_inlines = gen_ast_inlines();
Builder header_ecode = builder_open( "components/gen/ecodetypes.hpp" );
builder_print( & header_ecode, gen_component_header );
builder_print( & header_ecode, format(ecode) );
builder_write( & header_ecode);
Builder header_eoperator = builder_open( "components/gen/eoperator.hpp" );
builder_print( & header_eoperator, gen_component_header );
builder_print( & header_eoperator, format(eoperator) );
builder_write( & header_eoperator );
Builder header_especifier = builder_open( "components/gen/especifier.hpp" );
builder_print( & header_especifier, gen_component_header );
builder_print( & header_especifier, format(especifier) );
builder_write( & header_especifier);
Builder header_ast_inlines = builder_open( "components/gen/ast_inlines.hpp" );
builder_print( & header_ast_inlines, gen_component_header );
builder_print( & header_ast_inlines, format(ast_inlines) );
builder_write( & header_ast_inlines);
gen::deinit();
return 0;
}

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#ifdef GEN_INTELLISENSE_DIRECTIVES
#pragma once
#include "types.hpp"
#include "gen/ecode.hpp"
#include "gen/eoperator.hpp"
#include "gen/especifier.hpp"
#endif
/*
______ ______ ________ __ __ ______ __
/ \ / \| \ | \ | \ / \ | \
| ▓▓▓▓▓▓\ ▓▓▓▓▓▓\\▓▓▓▓▓▓▓▓ | ▓▓\ | ▓▓ | ▓▓▓▓▓▓\ ______ ____| ▓▓ ______
| ▓▓__| ▓▓ ▓▓___\▓▓ | ▓▓ | ▓▓▓\| ▓▓ | ▓▓ \▓▓/ \ / ▓▓/ \
| ▓▓ ▓▓\▓▓ \ | ▓▓ | ▓▓▓▓\ ▓▓ | ▓▓ | ▓▓▓▓▓▓\ ▓▓▓▓▓▓▓ ▓▓▓▓▓▓\
| ▓▓▓▓▓▓▓▓_\▓▓▓▓▓▓\ | ▓▓ | ▓▓\▓▓ ▓▓ | ▓▓ __| ▓▓ | ▓▓ ▓▓ | ▓▓ ▓▓ ▓▓
| ▓▓ | ▓▓ \__| ▓▓ | ▓▓ | ▓▓ \▓▓▓▓ | ▓▓__/ \ ▓▓__/ ▓▓ ▓▓__| ▓▓ ▓▓▓▓▓▓▓▓
| ▓▓ | ▓▓\▓▓ ▓▓ | ▓▓ | ▓▓ \▓▓▓ \▓▓ ▓▓\▓▓ ▓▓\▓▓ ▓▓\▓▓ \
\▓▓ \▓▓ \▓▓▓▓▓▓ \▓▓ \▓▓ \▓▓ \▓▓▓▓▓▓ \▓▓▓▓▓▓ \▓▓▓▓▓▓▓ \▓▓▓▓▓▓▓
*/
struct AST;
struct AST_Body;
struct AST_Attributes;
struct AST_Comment;
struct AST_Constructor;
// struct AST_BaseClass;
struct AST_Class;
struct AST_Define;
struct AST_Destructor;
struct AST_Enum;
struct AST_Exec;
struct AST_Extern;
struct AST_Include;
struct AST_Friend;
struct AST_Fn;
struct AST_Module;
struct AST_NS;
struct AST_Operator;
struct AST_OpCast;
struct AST_Params;
struct AST_Pragma;
struct AST_PreprocessCond;
struct AST_Specifiers;
#if GEN_EXECUTION_EXPRESSION_SUPPORT
struct AST_Expr;
struct AST_Expr_Assign;
struct AST_Expr_Alignof;
struct AST_Expr_Binary;
struct AST_Expr_CStyleCast;
struct AST_Expr_FunctionalCast;
struct AST_Expr_CppCast;
struct AST_Expr_ProcCall;
struct AST_Expr_Decltype;
struct AST_Expr_Comma; // TODO(Ed) : This is a binary op not sure if it needs its own AST...
struct AST_Expr_AMS; // Access Member Symbol
struct AST_Expr_Sizeof;
struct AST_Expr_Subscript;
struct AST_Expr_Ternary;
struct AST_Expr_UnaryPrefix;
struct AST_Expr_UnaryPostfix;
struct AST_Expr_Element;
struct AST_Stmt;
struct AST_Stmt_Break;
struct AST_Stmt_Case;
struct AST_Stmt_Continue;
struct AST_Stmt_Decl;
struct AST_Stmt_Do;
struct AST_Stmt_Expr; // TODO(Ed) : Is this distinction needed? (Should it be a flag instead?)
struct AST_Stmt_Else;
struct AST_Stmt_If;
struct AST_Stmt_For;
struct AST_Stmt_Goto;
struct AST_Stmt_Label;
struct AST_Stmt_Switch;
struct AST_Stmt_While;
#endif
struct AST_Struct;
struct AST_Template;
struct AST_Typename;
struct AST_Typedef;
struct AST_Union;
struct AST_Using;
struct AST_Var;
#if GEN_COMPILER_C
typedef AST* Code;
#else
struct Code;
#endif
#if GEN_COMPILER_C
typedef AST_Body* CodeBody;
typedef AST_Attributes* CodeAttributes;
typedef AST_Comment* CodeComment;
typedef AST_Class* CodeClass;
typedef AST_Constructor* CodeConstructor;
typedef AST_Define* CodeDefine;
typedef AST_Destructor* CodeDestructor;
typedef AST_Enum* CodeEnum;
typedef AST_Exec* CodeExec;
typedef AST_Extern* CodeExtern;
typedef AST_Include* CodeInclude;
typedef AST_Friend* CodeFriend;
typedef AST_Fn* CodeFn;
typedef AST_Module* CodeModule;
typedef AST_NS* CodeNS;
typedef AST_Operator* CodeOperator;
typedef AST_OpCast* CodeOpCast;
typedef AST_Params* CodeParams;
typedef AST_PreprocessCond* CodePreprocessCond;
typedef AST_Pragma* CodePragma;
typedef AST_Specifiers* CodeSpecifiers;
#else
struct CodeBody;
struct CodeAttributes;
struct CodeComment;
struct CodeClass;
struct CodeConstructor;
struct CodeDefine;
struct CodeDestructor;
struct CodeEnum;
struct CodeExec;
struct CodeExtern;
struct CodeInclude;
struct CodeFriend;
struct CodeFn;
struct CodeModule;
struct CodeNS;
struct CodeOperator;
struct CodeOpCast;
struct CodeParams;
struct CodePreprocessCond;
struct CodePragma;
struct CodeSpecifiers;
#endif
#if GEN_EXECUTION_EXPRESSION_SUPPORT
#if GEN_COMPILER_C
typedef AST_Expr* CodeExpr;
typedef AST_Expr_Assign* CodeExpr_Assign;
typedef AST_Expr_Alignof* CodeExpr_Alignof;
typedef AST_Expr_Binary* CodeExpr_Binary;
typedef AST_Expr_CStyleCast* CodeExpr_CStyleCast;
typedef AST_Expr_FunctionalCast* CodeExpr_FunctionalCast;
typedef AST_Expr_CppCast* CodeExpr_CppCast;
typedef AST_Expr_Element* CodeExpr_Element;
typedef AST_Expr_ProcCall* CodeExpr_ProcCall;
typedef AST_Expr_Decltype* CodeExpr_Decltype;
typedef AST_Expr_Comma* CodeExpr_Comma;
typedef AST_Expr_AMS* CodeExpr_AMS; // Access Member Symbol
typedef AST_Expr_Sizeof* CodeExpr_Sizeof;
typedef AST_Expr_Subscript* CodeExpr_Subscript;
typedef AST_Expr_Ternary* CodeExpr_Ternary;
typedef AST_Expr_UnaryPrefix* CodeExpr_UnaryPrefix;
typedef AST_Expr_UnaryPostfix* CodeExpr_UnaryPostfix;
#else
struct CodeExpr;
struct CodeExpr_Assign;
struct CodeExpr_Alignof;
struct CodeExpr_Binary;
struct CodeExpr_CStyleCast;
struct CodeExpr_FunctionalCast;
struct CodeExpr_CppCast;
struct CodeExpr_Element;
struct CodeExpr_ProcCall;
struct CodeExpr_Decltype;
struct CodeExpr_Comma;
struct CodeExpr_AMS; // Access Member Symbol
struct CodeExpr_Sizeof;
struct CodeExpr_Subscript;
struct CodeExpr_Ternary;
struct CodeExpr_UnaryPrefix;
struct CodeExpr_UnaryPostfix;
#endif
#if GEN_COMPILER_C
typedef AST_Stmt* CodeStmt;
typedef AST_Stmt_Break* CodeStmt_Break;
typedef AST_Stmt_Case* CodeStmt_Case;
typedef AST_Stmt_Continue* CodeStmt_Continue;
typedef AST_Stmt_Decl* CodeStmt_Decl;
typedef AST_Stmt_Do* CodeStmt_Do;
typedef AST_Stmt_Expr* CodeStmt_Expr;
typedef AST_Stmt_Else* CodeStmt_Else;
typedef AST_Stmt_If* CodeStmt_If;
typedef AST_Stmt_For* CodeStmt_For;
typedef AST_Stmt_Goto* CodeStmt_Goto;
typedef AST_Stmt_Label* CodeStmt_Label;
typedef AST_Stmt_Switch* CodeStmt_Switch;
typedef AST_Stmt_While* CodeStmt_While;
#else
struct CodeStmt;
struct CodeStmt_Break;
struct CodeStmt_Case;
struct CodeStmt_Continue;
struct CodeStmt_Decl;
struct CodeStmt_Do;
struct CodeStmt_Expr;
struct CodeStmt_Else;
struct CodeStmt_If;
struct CodeStmt_For;
struct CodeStmt_Goto;
struct CodeStmt_Label;
struct CodeStmt_Switch;
struct CodeStmt_While;
#endif
// GEN_EXECUTION_EXPRESSION_SUPPORT
#endif
#if GEN_COMPILER_C
typedef AST_Struct* CodeStruct;
typedef AST_Template* CodeTemplate;
typedef AST_Typename* CodeTypename;
typedef AST_Typedef* CodeTypedef;
typedef AST_Union* CodeUnion;
typedef AST_Using* CodeUsing;
typedef AST_Var* CodeVar;
#else
struct CodeStruct;
struct CodeTemplate;
struct CodeTypename;
struct CodeTypedef;
struct CodeUnion;
struct CodeUsing;
struct CodeVar;
#endif
GEN_NS_PARSER_BEGIN
struct Token;
GEN_NS_PARSER_END
#if GEN_COMPILER_CPP
// Note(Ed): This is to alleviate an edge case with parsing usings or typedefs where I don't really have it setup
// to parse a 'namespace' macro or a type with a macro.
// I have ideas for ways to pack that into the typedef/using ast, but for now just keeping it like this
#define ParserTokenType GEN_NS_PARSER Token
typedef ParserTokenType Token;
#undef ParserTokenType
#endif
#if GEN_COMPILER_CPP
template< class Type> forceinline Type tmpl_cast( Code self ) { return * rcast( Type*, & self ); }
#endif
#pragma region Code C-Interface
void code_append (Code code, Code other );
StrC code_debug_str (Code code);
Code code_duplicate (Code code);
Code* code_entry (Code code, u32 idx );
bool code_has_entries (Code code);
bool code_is_body (Code code);
bool code_is_equal (Code code, Code other);
bool code_is_valid (Code code);
void code_set_global (Code code);
String code_to_string (Code self );
void code_to_string_ptr(Code self, String* result );
StrC code_type_str (Code self );
bool code_validate_body(Code self );
#pragma endregion Code C-Interface
#if GEN_COMPILER_CPP
/*
AST* wrapper
- Not constantly have to append the '*' as this is written often..
- Allows for implicit conversion to any of the ASTs (raw or filtered).
*/
struct Code
{
AST* ast;
# define Using_Code( Typename ) \
forceinline StrC debug_str() { return code_debug_str(* this); } \
forceinline Code duplicate() { return code_duplicate(* this); } \
forceinline bool is_equal( Code other ) { return code_is_equal(* this, other); } \
forceinline bool is_body() { return code_is_body(* this); } \
forceinline bool is_valid() { return code_is_valid(* this); } \
forceinline void set_global() { return code_set_global(* this); }
# define Using_CodeOps( Typename ) \
forceinline Typename& operator = ( Code other ); \
forceinline bool operator ==( Code other ) { return (AST*)ast == other.ast; } \
forceinline bool operator !=( Code other ) { return (AST*)ast != other.ast; } \
forceinline bool operator ==(std::nullptr_t) const { return ast == nullptr; } \
forceinline bool operator !=(std::nullptr_t) const { return ast != nullptr; } \
operator bool();
#if ! GEN_C_LIKE_CPP
Using_Code( Code );
forceinline void append(Code other) { return code_append(* this, other); }
forceinline Code* entry(u32 idx) { return code_entry(* this, idx); }
forceinline bool has_entries() { return code_has_entries(* this); }
forceinline String to_string() { return code_to_string(* this); }
forceinline void to_string(String& result) { return code_to_string_ptr(* this, & result); }
forceinline StrC type_str() { return code_type_str(* this); }
forceinline bool validate_body() { return code_validate_body(*this); }
#endif
Using_CodeOps( Code );
forceinline AST* operator ->() { return ast; }
Code& operator ++();
#ifdef GEN_ENFORCE_STRONG_CODE_TYPES
# define operator explicit operator
#endif
operator CodeBody() const;
operator CodeAttributes() const;
// operator CodeBaseClass() const;
operator CodeComment() const;
operator CodeClass() const;
operator CodeConstructor() const;
operator CodeDefine() const;
operator CodeDestructor() const;
operator CodeExec() const;
operator CodeEnum() const;
operator CodeExtern() const;
operator CodeInclude() const;
operator CodeFriend() const;
operator CodeFn() const;
operator CodeModule() const;
operator CodeNS() const;
operator CodeOperator() const;
operator CodeOpCast() const;
operator CodeParams() const;
operator CodePragma() const;
operator CodePreprocessCond() const;
operator CodeSpecifiers() const;
operator CodeStruct() const;
operator CodeTemplate() const;
operator CodeTypename() const;
operator CodeTypedef() const;
operator CodeUnion() const;
operator CodeUsing() const;
operator CodeVar() const;
#undef operator
};
#endif
#pragma region Statics
// Used to identify ASTs that should always be duplicated. (Global constant ASTs)
extern Code Code_Global;
// Used to identify invalid generated code.
extern Code Code_Invalid;
#pragma endregion Statics
struct Code_POD
{
AST* ast;
};
static_assert( sizeof(Code) == sizeof(Code_POD), "ERROR: Code is not POD" );
// Desired width of the AST data structure.
constexpr int const AST_POD_Size = 128;
constexpr static
int AST_ArrSpecs_Cap =
(
AST_POD_Size
- sizeof(Code)
- sizeof(StringCached)
- sizeof(Code) * 2
- sizeof(Token*)
- sizeof(Code)
- sizeof(CodeType)
- sizeof(ModuleFlag)
- sizeof(u32)
)
/ sizeof(Specifier) - 1;
/*
Simple AST POD with functionality to seralize into C++ syntax.
*/
struct AST
{
union {
struct
{
Code InlineCmt; // Class, Constructor, Destructor, Enum, Friend, Functon, Operator, OpCast, Struct, Typedef, Using, Variable
Code Attributes; // Class, Enum, Function, Struct, Typedef, Union, Using, Variable
Code Specs; // Destructor, Function, Operator, Typename, Variable
union {
Code InitializerList; // Constructor
Code ParentType; // Class, Struct, ParentType->Next has a possible list of interfaces.
Code ReturnType; // Function, Operator, Typename
Code UnderlyingType; // Enum, Typedef
Code ValueType; // Parameter, Variable
};
union {
Code Macro; // Parameter
Code BitfieldSize; // Variable (Class/Struct Data Member)
Code Params; // Constructor, Function, Operator, Template, Typename
Code UnderlyingTypeMacro; // Enum
};
union {
Code ArrExpr; // Typename
Code Body; // Class, Constructor, Destructor, Enum, Friend, Function, Namespace, Struct, Union
Code Declaration; // Friend, Template
Code Value; // Parameter, Variable
};
union {
Code NextVar; // Variable; Possible way to handle comma separated variables declarations. ( , NextVar->Specs NextVar->Name NextVar->ArrExpr = NextVar->Value )
Code SuffixSpecs; // Only used with typenames, to store the function suffix if typename is function signature. ( May not be needed )
Code PostNameMacro; // Only used with parameters for specifically UE_REQUIRES (Thanks Unreal)
};
};
StringCached Content; // Attributes, Comment, Execution, Include
struct {
Specifier ArrSpecs[AST_ArrSpecs_Cap]; // Specifiers
Code NextSpecs; // Specifiers; If ArrSpecs is full, then NextSpecs is used.
};
};
StringCached Name;
union {
Code Prev;
Code Front;
Code Last;
};
union {
Code Next;
Code Back;
};
Token* Token; // Reference to starting token, only avaialble if it was derived from parsing.
Code Parent;
CodeType Type;
// CodeFlag CodeFlags;
ModuleFlag ModuleFlags;
union {
b32 IsFunction; // Used by typedef to not serialize the name field.
struct {
b16 IsParamPack; // Used by typename to know if type should be considered a parameter pack.
ETypenameTag TypeTag; // Used by typename to keep track of explicitly declared tags for the identifier (enum, struct, union)
};
Operator Op;
AccessSpec ParentAccess;
s32 NumEntries;
s32 VarParenthesizedInit; // Used by variables to know that initialization is using a constructor expression instead of an assignment expression.
};
};
static_assert( sizeof(AST) == AST_POD_Size, "ERROR: AST is not size of AST_POD_Size" );
#if GEN_COMPILER_CPP
// Uses an implicitly overloaded cast from the AST to the desired code type.
// Necessary if the user wants GEN_ENFORCE_STRONG_CODE_TYPES
struct InvalidCode_ImplictCaster;
#define InvalidCode (InvalidCode_ImplictCaster{})
#else
#define InvalidCode (void*){ (void*)Code_Invalid }
#endif
#if GEN_COMPILER_CPP
struct NullCode_ImplicitCaster;
// Used when the its desired when omission is allowed in a definition.
#define NullCode (NullCode_ImplicitCaster{})
#else
#define NullCode nullptr
#endif

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# define GEN_AST_BODY_CLASS_UNALLOWED_TYPES \
case CT_PlatformAttributes: \
case CT_Class_Body: \
case CT_Enum_Body: \
case CT_Extern_Linkage: \
case CT_Function_Body: \
case CT_Function_Fwd: \
case CT_Global_Body: \
case CT_Namespace: \
case CT_Namespace_Body: \
case CT_Operator: \
case CT_Operator_Fwd: \
case CT_Parameters: \
case CT_Specifiers: \
case CT_Struct_Body: \
case CT_Typename:
# define GEN_AST_BODY_STRUCT_UNALLOWED_TYPES GEN_AST_BODY_CLASS_UNALLOWED_TYPES
# define GEN_AST_BODY_FUNCTION_UNALLOWED_TYPES \
case CT_Access_Public: \
case CT_Access_Protected: \
case CT_Access_Private: \
case CT_PlatformAttributes: \
case CT_Class_Body: \
case CT_Enum_Body: \
case CT_Extern_Linkage: \
case CT_Friend: \
case CT_Function_Body: \
case CT_Function_Fwd: \
case CT_Global_Body: \
case CT_Namespace: \
case CT_Namespace_Body: \
case CT_Operator: \
case CT_Operator_Fwd: \
case CT_Operator_Member: \
case CT_Operator_Member_Fwd: \
case CT_Parameters: \
case CT_Specifiers: \
case CT_Struct_Body: \
case CT_Typename:
# define GEN_AST_BODY_GLOBAL_UNALLOWED_TYPES \
case CT_Access_Public: \
case CT_Access_Protected: \
case CT_Access_Private: \
case CT_PlatformAttributes: \
case CT_Class_Body: \
case CT_Enum_Body: \
case CT_Execution: \
case CT_Friend: \
case CT_Function_Body: \
case CT_Namespace_Body: \
case CT_Operator_Member: \
case CT_Operator_Member_Fwd: \
case CT_Parameters: \
case CT_Specifiers: \
case CT_Struct_Body: \
case CT_Typename:
# define GEN_AST_BODY_EXPORT_UNALLOWED_TYPES GEN_AST_BODY_GLOBAL_UNALLOWED_TYPES
# define GEN_AST_BODY_EXTERN_LINKAGE_UNALLOWED_TYPES GEN_AST_BODY_GLOBAL_UNALLOWED_TYPES
# define GEN_AST_BODY_NAMESPACE_UNALLOWED_TYPES \
case CT_Access_Public: \
case CT_Access_Protected: \
case CT_Access_Private: \
case CT_PlatformAttributes: \
case CT_Class_Body: \
case CT_Enum_Body: \
case CT_Execution: \
case CT_Friend: \
case CT_Function_Body: \
case CT_Namespace_Body: \
case CT_Operator_Member: \
case CT_Operator_Member_Fwd: \
case CT_Parameters: \
case CT_Specifiers: \
case CT_Struct_Body: \
case CT_Typename:

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#ifdef GEN_INTELLISENSE_DIRECTIVES
#pragma once
#include "components/types.hpp"
#endif
// This file was generated automatially by gencpp's bootstrap.cpp (See: https://github.com/Ed94/gencpp)
#pragma region generated code inline implementation
inline Code& Code::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline Code::operator bool()
{
return ast != nullptr;
}
inline CodeBody& CodeBody::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodeBody::operator bool()
{
return ast != nullptr;
}
inline CodeAttributes& CodeAttributes::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodeAttributes::operator bool()
{
return ast != nullptr;
}
inline CodeAttributes::operator Code()
{
return *rcast( Code*, this );
}
inline AST_Attributes* CodeAttributes::operator->()
{
if ( ast == nullptr )
{
log_failure( "Attempt to dereference a nullptr!" );
return nullptr;
}
return ast;
}
inline CodeComment& CodeComment::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodeComment::operator bool()
{
return ast != nullptr;
}
inline CodeComment::operator Code()
{
return *rcast( Code*, this );
}
inline AST_Comment* CodeComment::operator->()
{
if ( ast == nullptr )
{
log_failure( "Attempt to dereference a nullptr!" );
return nullptr;
}
return ast;
}
inline CodeConstructor& CodeConstructor::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodeConstructor::operator bool()
{
return ast != nullptr;
}
inline CodeConstructor::operator Code()
{
return *rcast( Code*, this );
}
inline AST_Constructor* CodeConstructor::operator->()
{
if ( ast == nullptr )
{
log_failure( "Attempt to dereference a nullptr!" );
return nullptr;
}
return ast;
}
inline CodeClass& CodeClass::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodeClass::operator bool()
{
return ast != nullptr;
}
inline CodeDefine& CodeDefine::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodeDefine::operator bool()
{
return ast != nullptr;
}
inline CodeDefine::operator Code()
{
return *rcast( Code*, this );
}
inline AST_Define* CodeDefine::operator->()
{
if ( ast == nullptr )
{
log_failure( "Attempt to dereference a nullptr!" );
return nullptr;
}
return ast;
}
inline CodeDestructor& CodeDestructor::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodeDestructor::operator bool()
{
return ast != nullptr;
}
inline CodeDestructor::operator Code()
{
return *rcast( Code*, this );
}
inline AST_Destructor* CodeDestructor::operator->()
{
if ( ast == nullptr )
{
log_failure( "Attempt to dereference a nullptr!" );
return nullptr;
}
return ast;
}
inline CodeEnum& CodeEnum::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodeEnum::operator bool()
{
return ast != nullptr;
}
inline CodeEnum::operator Code()
{
return *rcast( Code*, this );
}
inline AST_Enum* CodeEnum::operator->()
{
if ( ast == nullptr )
{
log_failure( "Attempt to dereference a nullptr!" );
return nullptr;
}
return ast;
}
inline CodeExec& CodeExec::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodeExec::operator bool()
{
return ast != nullptr;
}
inline CodeExec::operator Code()
{
return *rcast( Code*, this );
}
inline AST_Exec* CodeExec::operator->()
{
if ( ast == nullptr )
{
log_failure( "Attempt to dereference a nullptr!" );
return nullptr;
}
return ast;
}
inline CodeExtern& CodeExtern::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodeExtern::operator bool()
{
return ast != nullptr;
}
inline CodeExtern::operator Code()
{
return *rcast( Code*, this );
}
inline AST_Extern* CodeExtern::operator->()
{
if ( ast == nullptr )
{
log_failure( "Attempt to dereference a nullptr!" );
return nullptr;
}
return ast;
}
inline CodeFriend& CodeFriend::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodeFriend::operator bool()
{
return ast != nullptr;
}
inline CodeFriend::operator Code()
{
return *rcast( Code*, this );
}
inline AST_Friend* CodeFriend::operator->()
{
if ( ast == nullptr )
{
log_failure( "Attempt to dereference a nullptr!" );
return nullptr;
}
return ast;
}
inline CodeFn& CodeFn::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodeFn::operator bool()
{
return ast != nullptr;
}
inline CodeFn::operator Code()
{
return *rcast( Code*, this );
}
inline AST_Fn* CodeFn::operator->()
{
if ( ast == nullptr )
{
log_failure( "Attempt to dereference a nullptr!" );
return nullptr;
}
return ast;
}
inline CodeInclude& CodeInclude::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodeInclude::operator bool()
{
return ast != nullptr;
}
inline CodeInclude::operator Code()
{
return *rcast( Code*, this );
}
inline AST_Include* CodeInclude::operator->()
{
if ( ast == nullptr )
{
log_failure( "Attempt to dereference a nullptr!" );
return nullptr;
}
return ast;
}
inline CodeModule& CodeModule::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodeModule::operator bool()
{
return ast != nullptr;
}
inline CodeModule::operator Code()
{
return *rcast( Code*, this );
}
inline AST_Module* CodeModule::operator->()
{
if ( ast == nullptr )
{
log_failure( "Attempt to dereference a nullptr!" );
return nullptr;
}
return ast;
}
inline CodeNS& CodeNS::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodeNS::operator bool()
{
return ast != nullptr;
}
inline CodeNS::operator Code()
{
return *rcast( Code*, this );
}
inline AST_NS* CodeNS::operator->()
{
if ( ast == nullptr )
{
log_failure( "Attempt to dereference a nullptr!" );
return nullptr;
}
return ast;
}
inline CodeOperator& CodeOperator::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodeOperator::operator bool()
{
return ast != nullptr;
}
inline CodeOperator::operator Code()
{
return *rcast( Code*, this );
}
inline AST_Operator* CodeOperator::operator->()
{
if ( ast == nullptr )
{
log_failure( "Attempt to dereference a nullptr!" );
return nullptr;
}
return ast;
}
inline CodeOpCast& CodeOpCast::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodeOpCast::operator bool()
{
return ast != nullptr;
}
inline CodeOpCast::operator Code()
{
return *rcast( Code*, this );
}
inline AST_OpCast* CodeOpCast::operator->()
{
if ( ast == nullptr )
{
log_failure( "Attempt to dereference a nullptr!" );
return nullptr;
}
return ast;
}
inline CodeParams& CodeParams::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodeParams::operator bool()
{
return ast != nullptr;
}
inline CodePragma& CodePragma::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodePragma::operator bool()
{
return ast != nullptr;
}
inline CodePragma::operator Code()
{
return *rcast( Code*, this );
}
inline AST_Pragma* CodePragma::operator->()
{
if ( ast == nullptr )
{
log_failure( "Attempt to dereference a nullptr!" );
return nullptr;
}
return ast;
}
inline CodePreprocessCond& CodePreprocessCond::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodePreprocessCond::operator bool()
{
return ast != nullptr;
}
inline CodePreprocessCond::operator Code()
{
return *rcast( Code*, this );
}
inline AST_PreprocessCond* CodePreprocessCond::operator->()
{
if ( ast == nullptr )
{
log_failure( "Attempt to dereference a nullptr!" );
return nullptr;
}
return ast;
}
inline CodeSpecifiers& CodeSpecifiers::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodeSpecifiers::operator bool()
{
return ast != nullptr;
}
inline CodeStruct& CodeStruct::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodeStruct::operator bool()
{
return ast != nullptr;
}
inline CodeTemplate& CodeTemplate::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodeTemplate::operator bool()
{
return ast != nullptr;
}
inline CodeTemplate::operator Code()
{
return *rcast( Code*, this );
}
inline AST_Template* CodeTemplate::operator->()
{
if ( ast == nullptr )
{
log_failure( "Attempt to dereference a nullptr!" );
return nullptr;
}
return ast;
}
inline CodeTypename& CodeTypename::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodeTypename::operator bool()
{
return ast != nullptr;
}
inline CodeTypename::operator Code()
{
return *rcast( Code*, this );
}
inline AST_Typename* CodeTypename::operator->()
{
if ( ast == nullptr )
{
log_failure( "Attempt to dereference a nullptr!" );
return nullptr;
}
return ast;
}
inline CodeTypedef& CodeTypedef::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodeTypedef::operator bool()
{
return ast != nullptr;
}
inline CodeTypedef::operator Code()
{
return *rcast( Code*, this );
}
inline AST_Typedef* CodeTypedef::operator->()
{
if ( ast == nullptr )
{
log_failure( "Attempt to dereference a nullptr!" );
return nullptr;
}
return ast;
}
inline CodeUnion& CodeUnion::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodeUnion::operator bool()
{
return ast != nullptr;
}
inline CodeUnion::operator Code()
{
return *rcast( Code*, this );
}
inline AST_Union* CodeUnion::operator->()
{
if ( ast == nullptr )
{
log_failure( "Attempt to dereference a nullptr!" );
return nullptr;
}
return ast;
}
inline CodeUsing& CodeUsing::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodeUsing::operator bool()
{
return ast != nullptr;
}
inline CodeUsing::operator Code()
{
return *rcast( Code*, this );
}
inline AST_Using* CodeUsing::operator->()
{
if ( ast == nullptr )
{
log_failure( "Attempt to dereference a nullptr!" );
return nullptr;
}
return ast;
}
inline CodeVar& CodeVar::operator=( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype( ast ), code_duplicate( other ).ast );
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return *this;
}
inline CodeVar::operator bool()
{
return ast != nullptr;
}
inline CodeVar::operator Code()
{
return *rcast( Code*, this );
}
inline AST_Var* CodeVar::operator->()
{
if ( ast == nullptr )
{
log_failure( "Attempt to dereference a nullptr!" );
return nullptr;
}
return ast;
}
#pragma endregion generated code inline implementation
#pragma region generated AST/Code cast implementation
GEN_OPTIMIZE_MAPPINGS_BEGIN
forceinline Code::operator CodeBody() const
{
return { (AST_Body*)ast };
}
forceinline Code::operator CodeAttributes() const
{
return { (AST_Attributes*)ast };
}
forceinline Code::operator CodeComment() const
{
return { (AST_Comment*)ast };
}
forceinline Code::operator CodeConstructor() const
{
return { (AST_Constructor*)ast };
}
forceinline Code::operator CodeClass() const
{
return { (AST_Class*)ast };
}
forceinline Code::operator CodeDefine() const
{
return { (AST_Define*)ast };
}
forceinline Code::operator CodeDestructor() const
{
return { (AST_Destructor*)ast };
}
forceinline Code::operator CodeEnum() const
{
return { (AST_Enum*)ast };
}
forceinline Code::operator CodeExec() const
{
return { (AST_Exec*)ast };
}
forceinline Code::operator CodeExtern() const
{
return { (AST_Extern*)ast };
}
forceinline Code::operator CodeFriend() const
{
return { (AST_Friend*)ast };
}
forceinline Code::operator CodeFn() const
{
return { (AST_Fn*)ast };
}
forceinline Code::operator CodeInclude() const
{
return { (AST_Include*)ast };
}
forceinline Code::operator CodeModule() const
{
return { (AST_Module*)ast };
}
forceinline Code::operator CodeNS() const
{
return { (AST_NS*)ast };
}
forceinline Code::operator CodeOperator() const
{
return { (AST_Operator*)ast };
}
forceinline Code::operator CodeOpCast() const
{
return { (AST_OpCast*)ast };
}
forceinline Code::operator CodeParams() const
{
return { (AST_Params*)ast };
}
forceinline Code::operator CodePragma() const
{
return { (AST_Pragma*)ast };
}
forceinline Code::operator CodePreprocessCond() const
{
return { (AST_PreprocessCond*)ast };
}
forceinline Code::operator CodeSpecifiers() const
{
return { (AST_Specifiers*)ast };
}
forceinline Code::operator CodeStruct() const
{
return { (AST_Struct*)ast };
}
forceinline Code::operator CodeTemplate() const
{
return { (AST_Template*)ast };
}
forceinline Code::operator CodeTypename() const
{
return { (AST_Typename*)ast };
}
forceinline Code::operator CodeTypedef() const
{
return { (AST_Typedef*)ast };
}
forceinline Code::operator CodeUnion() const
{
return { (AST_Union*)ast };
}
forceinline Code::operator CodeUsing() const
{
return { (AST_Using*)ast };
}
forceinline Code::operator CodeVar() const
{
return { (AST_Var*)ast };
}
GEN_OPITMIZE_MAPPINGS_END
#pragma endregion generated AST / Code cast implementation

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#ifdef GEN_INTELLISENSE_DIRECTIVES
#pragma once
#include "components/types.hpp"
#endif
// This file was generated automatially by gencpp's bootstrap.cpp (See: https://github.com/Ed94/gencpp)
enum CodeType : u32
{
CT_Invalid,
CT_Untyped,
CT_NewLine,
CT_Comment,
CT_Access_Private,
CT_Access_Protected,
CT_Access_Public,
CT_PlatformAttributes,
CT_Class,
CT_Class_Fwd,
CT_Class_Body,
CT_Constructor,
CT_Constructor_Fwd,
CT_Destructor,
CT_Destructor_Fwd,
CT_Enum,
CT_Enum_Fwd,
CT_Enum_Body,
CT_Enum_Class,
CT_Enum_Class_Fwd,
CT_Execution,
CT_Export_Body,
CT_Extern_Linkage,
CT_Extern_Linkage_Body,
CT_Friend,
CT_Function,
CT_Function_Fwd,
CT_Function_Body,
CT_Global_Body,
CT_Module,
CT_Namespace,
CT_Namespace_Body,
CT_Operator,
CT_Operator_Fwd,
CT_Operator_Member,
CT_Operator_Member_Fwd,
CT_Operator_Cast,
CT_Operator_Cast_Fwd,
CT_Parameters,
CT_Preprocess_Define,
CT_Preprocess_Include,
CT_Preprocess_If,
CT_Preprocess_IfDef,
CT_Preprocess_IfNotDef,
CT_Preprocess_ElIf,
CT_Preprocess_Else,
CT_Preprocess_EndIf,
CT_Preprocess_Pragma,
CT_Specifiers,
CT_Struct,
CT_Struct_Fwd,
CT_Struct_Body,
CT_Template,
CT_Typedef,
CT_Typename,
CT_Union,
CT_Union_Fwd,
CT_Union_Body,
CT_Using,
CT_Using_Namespace,
CT_Variable,
CT_NumTypes,
CT_UnderlyingType = GEN_U32_MAX
};
inline StrC codetype_to_str( CodeType type )
{
local_persist StrC lookup[61] = {
{ sizeof( "Invalid" ), "Invalid" },
{ sizeof( "Untyped" ), "Untyped" },
{ sizeof( "NewLine" ), "NewLine" },
{ sizeof( "Comment" ), "Comment" },
{ sizeof( "Access_Private" ), "Access_Private" },
{ sizeof( "Access_Protected" ), "Access_Protected" },
{ sizeof( "Access_Public" ), "Access_Public" },
{ sizeof( "PlatformAttributes" ), "PlatformAttributes" },
{ sizeof( "Class" ), "Class" },
{ sizeof( "Class_Fwd" ), "Class_Fwd" },
{ sizeof( "Class_Body" ), "Class_Body" },
{ sizeof( "Constructor" ), "Constructor" },
{ sizeof( "Constructor_Fwd" ), "Constructor_Fwd" },
{ sizeof( "Destructor" ), "Destructor" },
{ sizeof( "Destructor_Fwd" ), "Destructor_Fwd" },
{ sizeof( "Enum" ), "Enum" },
{ sizeof( "Enum_Fwd" ), "Enum_Fwd" },
{ sizeof( "Enum_Body" ), "Enum_Body" },
{ sizeof( "Enum_Class" ), "Enum_Class" },
{ sizeof( "Enum_Class_Fwd" ), "Enum_Class_Fwd" },
{ sizeof( "Execution" ), "Execution" },
{ sizeof( "Export_Body" ), "Export_Body" },
{ sizeof( "Extern_Linkage" ), "Extern_Linkage" },
{ sizeof( "Extern_Linkage_Body" ), "Extern_Linkage_Body" },
{ sizeof( "Friend" ), "Friend" },
{ sizeof( "Function" ), "Function" },
{ sizeof( "Function_Fwd" ), "Function_Fwd" },
{ sizeof( "Function_Body" ), "Function_Body" },
{ sizeof( "Global_Body" ), "Global_Body" },
{ sizeof( "Module" ), "Module" },
{ sizeof( "Namespace" ), "Namespace" },
{ sizeof( "Namespace_Body" ), "Namespace_Body" },
{ sizeof( "Operator" ), "Operator" },
{ sizeof( "Operator_Fwd" ), "Operator_Fwd" },
{ sizeof( "Operator_Member" ), "Operator_Member" },
{ sizeof( "Operator_Member_Fwd" ), "Operator_Member_Fwd" },
{ sizeof( "Operator_Cast" ), "Operator_Cast" },
{ sizeof( "Operator_Cast_Fwd" ), "Operator_Cast_Fwd" },
{ sizeof( "Parameters" ), "Parameters" },
{ sizeof( "Preprocess_Define" ), "Preprocess_Define" },
{ sizeof( "Preprocess_Include" ), "Preprocess_Include" },
{ sizeof( "Preprocess_If" ), "Preprocess_If" },
{ sizeof( "Preprocess_IfDef" ), "Preprocess_IfDef" },
{ sizeof( "Preprocess_IfNotDef" ), "Preprocess_IfNotDef" },
{ sizeof( "Preprocess_ElIf" ), "Preprocess_ElIf" },
{ sizeof( "Preprocess_Else" ), "Preprocess_Else" },
{ sizeof( "Preprocess_EndIf" ), "Preprocess_EndIf" },
{ sizeof( "Preprocess_Pragma" ), "Preprocess_Pragma" },
{ sizeof( "Specifiers" ), "Specifiers" },
{ sizeof( "Struct" ), "Struct" },
{ sizeof( "Struct_Fwd" ), "Struct_Fwd" },
{ sizeof( "Struct_Body" ), "Struct_Body" },
{ sizeof( "Template" ), "Template" },
{ sizeof( "Typedef" ), "Typedef" },
{ sizeof( "Typename" ), "Typename" },
{ sizeof( "Union" ), "Union" },
{ sizeof( "Union_Fwd" ), "Union_Fwd" },
{ sizeof( "Union_Body" ), "Union_Body" },
{ sizeof( "Using" ), "Using" },
{ sizeof( "Using_Namespace" ), "Using_Namespace" },
{ sizeof( "Variable" ), "Variable" },
};
return lookup[type];
}
inline StrC codetype_to_keyword_str( CodeType type )
{
local_persist StrC lookup[61] = {
{ sizeof( "__NA__" ) - 1, "__NA__" },
{ sizeof( "__NA__" ) - 1, "__NA__" },
{ sizeof( "__NA__" ) - 1, "__NA__" },
{ sizeof( "//" ) - 1, "//" },
{ sizeof( "private" ) - 1, "private" },
{ sizeof( "protected" ) - 1, "protected" },
{ sizeof( "public" ) - 1, "public" },
{ sizeof( "__NA__" ) - 1, "__NA__" },
{ sizeof( "class" ) - 1, "class" },
{ sizeof( "clsss" ) - 1, "clsss" },
{ sizeof( "__NA__" ) - 1, "__NA__" },
{ sizeof( "__NA__" ) - 1, "__NA__" },
{ sizeof( "__NA__" ) - 1, "__NA__" },
{ sizeof( "__NA__" ) - 1, "__NA__" },
{ sizeof( "__NA__" ) - 1, "__NA__" },
{ sizeof( "enum" ) - 1, "enum" },
{ sizeof( "enum" ) - 1, "enum" },
{ sizeof( "__NA__" ) - 1, "__NA__" },
{ sizeof( "enum class" ) - 1, "enum class" },
{ sizeof( "enum class" ) - 1, "enum class" },
{ sizeof( "__NA__" ) - 1, "__NA__" },
{ sizeof( "__NA__" ) - 1, "__NA__" },
{ sizeof( "extern" ) - 1, "extern" },
{ sizeof( "extern" ) - 1, "extern" },
{ sizeof( "friend" ) - 1, "friend" },
{ sizeof( "__NA__" ) - 1, "__NA__" },
{ sizeof( "__NA__" ) - 1, "__NA__" },
{ sizeof( "__NA__" ) - 1, "__NA__" },
{ sizeof( "__NA__" ) - 1, "__NA__" },
{ sizeof( "module" ) - 1, "module" },
{ sizeof( "namespace" ) - 1, "namespace" },
{ sizeof( "__NA__" ) - 1, "__NA__" },
{ sizeof( "operator" ) - 1, "operator" },
{ sizeof( "operator" ) - 1, "operator" },
{ sizeof( "operator" ) - 1, "operator" },
{ sizeof( "operator" ) - 1, "operator" },
{ sizeof( "operator" ) - 1, "operator" },
{ sizeof( "operator" ) - 1, "operator" },
{ sizeof( "__NA__" ) - 1, "__NA__" },
{ sizeof( "define" ) - 1, "define" },
{ sizeof( "include" ) - 1, "include" },
{ sizeof( "if" ) - 1, "if" },
{ sizeof( "ifdef" ) - 1, "ifdef" },
{ sizeof( "ifndef" ) - 1, "ifndef" },
{ sizeof( "elif" ) - 1, "elif" },
{ sizeof( "else" ) - 1, "else" },
{ sizeof( "endif" ) - 1, "endif" },
{ sizeof( "pragma" ) - 1, "pragma" },
{ sizeof( "__NA__" ) - 1, "__NA__" },
{ sizeof( "struct" ) - 1, "struct" },
{ sizeof( "struct" ) - 1, "struct" },
{ sizeof( "__NA__" ) - 1, "__NA__" },
{ sizeof( "template" ) - 1, "template" },
{ sizeof( "typedef" ) - 1, "typedef" },
{ sizeof( "__NA__" ) - 1, "__NA__" },
{ sizeof( "union" ) - 1, "union" },
{ sizeof( "union" ) - 1, "union" },
{ sizeof( "__NA__" ) - 1, "__NA__" },
{ sizeof( "using" ) - 1, "using" },
{ sizeof( "using namespace" ) - 1, "using namespace" },
{ sizeof( "__NA__" ) - 1, "__NA__" },
};
return lookup[type];
}
forceinline StrC to_str( CodeType type )
{
return codetype_to_str( type );
}
forceinline StrC to_keyword_str( CodeType type )
{
return codetype_to_keyword_str( type );
}

118
base/components/gen/eoperator.hpp Normal file
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#ifdef GEN_INTELLISENSE_DIRECTIVES
#pragma once
#include "components/types.hpp"
#endif
// This file was generated automatially by gencpp's bootstrap.cpp (See: https://github.com/Ed94/gencpp)
enum Operator : u32
{
Op_Invalid,
Op_Assign,
Op_Assign_Add,
Op_Assign_Subtract,
Op_Assign_Multiply,
Op_Assign_Divide,
Op_Assign_Modulo,
Op_Assign_BAnd,
Op_Assign_BOr,
Op_Assign_BXOr,
Op_Assign_LShift,
Op_Assign_RShift,
Op_Increment,
Op_Decrement,
Op_Unary_Plus,
Op_Unary_Minus,
Op_UnaryNot,
Op_Add,
Op_Subtract,
Op_Multiply,
Op_Divide,
Op_Modulo,
Op_BNot,
Op_BAnd,
Op_BOr,
Op_BXOr,
Op_LShift,
Op_RShift,
Op_LAnd,
Op_LOr,
Op_LEqual,
Op_LNot,
Op_Lesser,
Op_Greater,
Op_LesserEqual,
Op_GreaterEqual,
Op_Subscript,
Op_Indirection,
Op_AddressOf,
Op_MemberOfPointer,
Op_PtrToMemOfPtr,
Op_FunctionCall,
Op_Comma,
Op_New,
Op_NewArray,
Op_Delete,
Op_DeleteArray,
Op_NumOps,
Op_UnderlyingType = 0xffffffffu
};
inline StrC operator_to_str( Operator op )
{
local_persist StrC lookup[47] = {
{ sizeof( "INVALID" ), "INVALID" },
{ sizeof( "=" ), "=" },
{ sizeof( "+=" ), "+=" },
{ sizeof( "-=" ), "-=" },
{ sizeof( "*=" ), "*=" },
{ sizeof( "/=" ), "/=" },
{ sizeof( "%=" ), "%=" },
{ sizeof( "&=" ), "&=" },
{ sizeof( "|=" ), "|=" },
{ sizeof( "^=" ), "^=" },
{ sizeof( "<<=" ), "<<=" },
{ sizeof( ">>=" ), ">>=" },
{ sizeof( "++" ), "++" },
{ sizeof( "--" ), "--" },
{ sizeof( "+" ), "+" },
{ sizeof( "-" ), "-" },
{ sizeof( "!" ), "!" },
{ sizeof( "+" ), "+" },
{ sizeof( "-" ), "-" },
{ sizeof( "*" ), "*" },
{ sizeof( "/" ), "/" },
{ sizeof( "%" ), "%" },
{ sizeof( "~" ), "~" },
{ sizeof( "&" ), "&" },
{ sizeof( "|" ), "|" },
{ sizeof( "^" ), "^" },
{ sizeof( "<<" ), "<<" },
{ sizeof( ">>" ), ">>" },
{ sizeof( "&&" ), "&&" },
{ sizeof( "||" ), "||" },
{ sizeof( "==" ), "==" },
{ sizeof( "!=" ), "!=" },
{ sizeof( "<" ), "<" },
{ sizeof( ">" ), ">" },
{ sizeof( "<=" ), "<=" },
{ sizeof( ">=" ), ">=" },
{ sizeof( "[]" ), "[]" },
{ sizeof( "*" ), "*" },
{ sizeof( "&" ), "&" },
{ sizeof( "->" ), "->" },
{ sizeof( "->*" ), "->*" },
{ sizeof( "()" ), "()" },
{ sizeof( "," ), "," },
{ sizeof( "new" ), "new" },
{ sizeof( "new[]" ), "new[]" },
{ sizeof( "delete" ), "delete" },
{ sizeof( "delete[]" ), "delete[]" },
};
return lookup[op];
}
forceinline StrC to_str( Operator op )
{
return operator_to_str( op );
}

108
base/components/gen/especifier.hpp Normal file
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#ifdef GEN_INTELLISENSE_DIRECTIVES
#pragma once
#include "components/types.hpp"
#endif
// This file was generated automatially by gencpp's bootstrap.cpp (See: https://github.com/Ed94/gencpp)
enum Specifier : u32
{
Spec_Invalid,
Spec_Consteval,
Spec_Constexpr,
Spec_Constinit,
Spec_Explicit,
Spec_External_Linkage,
Spec_ForceInline,
Spec_Global,
Spec_Inline,
Spec_Internal_Linkage,
Spec_Local_Persist,
Spec_Mutable,
Spec_NeverInline,
Spec_Ptr,
Spec_Ref,
Spec_Register,
Spec_RValue,
Spec_Static,
Spec_Thread_Local,
Spec_Virtual,
Spec_Const,
Spec_Final,
Spec_NoExceptions,
Spec_Override,
Spec_Pure,
Spec_Volatile,
Spec_NumSpecifiers,
Spec_UnderlyingType = 0xffffffffu
};
inline StrC spec_to_str( Specifier type )
{
local_persist StrC lookup[26] = {
{ sizeof( "INVALID" ), "INVALID" },
{ sizeof( "consteval" ), "consteval" },
{ sizeof( "constexpr" ), "constexpr" },
{ sizeof( "constinit" ), "constinit" },
{ sizeof( "explicit" ), "explicit" },
{ sizeof( "extern" ), "extern" },
{ sizeof( "forceinline" ), "forceinline" },
{ sizeof( "global" ), "global" },
{ sizeof( "inline" ), "inline" },
{ sizeof( "internal" ), "internal" },
{ sizeof( "local_persist" ), "local_persist" },
{ sizeof( "mutable" ), "mutable" },
{ sizeof( "neverinline" ), "neverinline" },
{ sizeof( "*" ), "*" },
{ sizeof( "&" ), "&" },
{ sizeof( "register" ), "register" },
{ sizeof( "&&" ), "&&" },
{ sizeof( "static" ), "static" },
{ sizeof( "thread_local" ), "thread_local" },
{ sizeof( "virtual" ), "virtual" },
{ sizeof( "const" ), "const" },
{ sizeof( "final" ), "final" },
{ sizeof( "noexcept" ), "noexcept" },
{ sizeof( "override" ), "override" },
{ sizeof( "= 0" ), "= 0" },
{ sizeof( "volatile" ), "volatile" },
};
return lookup[type];
}
inline bool spec_is_trailing( Specifier specifier )
{
return specifier > Spec_Virtual;
}
inline Specifier strc_to_specifier( StrC str )
{
local_persist u32 keymap[Spec_NumSpecifiers];
do_once_start for ( u32 index = 0; index < Spec_NumSpecifiers; index++ )
{
StrC enum_str = spec_to_str( (Specifier)index );
keymap[index] = crc32( enum_str.Ptr, enum_str.Len - 1 );
}
do_once_end u32 hash = crc32( str.Ptr, str.Len );
for ( u32 index = 0; index < Spec_NumSpecifiers; index++ )
{
if ( keymap[index] == hash )
return (Specifier)index;
}
return Spec_Invalid;
}
forceinline StrC to_str( Specifier spec )
{
return spec_to_str( spec );
}
forceinline Specifier to_type( StrC str )
{
return strc_to_specifier( str );
}
forceinline bool is_trailing( Specifier specifier )
{
return spec_is_trailing( specifier );
}

235
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#ifdef GEN_INTELLISENSE_DIRECTIVES
#pragma once
#include "components/types.hpp"
#endif
// This file was generated automatially by gencpp's bootstrap.cpp (See: https://github.com/Ed94/gencpp)
GEN_NS_PARSER_BEGIN
#define GEN_DEFINE_ATTRIBUTE_TOKENS Entry( Tok_Attribute_API_Export, "GEN_API_Export_Code" ) Entry( Tok_Attribute_API_Import, "GEN_API_Import_Code" )
enum TokType : u32
{
Tok_Invalid,
Tok_Access_Private,
Tok_Access_Protected,
Tok_Access_Public,
Tok_Access_MemberSymbol,
Tok_Access_StaticSymbol,
Tok_Ampersand,
Tok_Ampersand_DBL,
Tok_Assign_Classifer,
Tok_Attribute_Open,
Tok_Attribute_Close,
Tok_BraceCurly_Open,
Tok_BraceCurly_Close,
Tok_BraceSquare_Open,
Tok_BraceSquare_Close,
Tok_Capture_Start,
Tok_Capture_End,
Tok_Comment,
Tok_Comment_End,
Tok_Comment_Start,
Tok_Char,
Tok_Comma,
Tok_Decl_Class,
Tok_Decl_GNU_Attribute,
Tok_Decl_MSVC_Attribute,
Tok_Decl_Enum,
Tok_Decl_Extern_Linkage,
Tok_Decl_Friend,
Tok_Decl_Module,
Tok_Decl_Namespace,
Tok_Decl_Operator,
Tok_Decl_Struct,
Tok_Decl_Template,
Tok_Decl_Typedef,
Tok_Decl_Using,
Tok_Decl_Union,
Tok_Identifier,
Tok_Module_Import,
Tok_Module_Export,
Tok_NewLine,
Tok_Number,
Tok_Operator,
Tok_Preprocess_Hash,
Tok_Preprocess_Define,
Tok_Preprocess_If,
Tok_Preprocess_IfDef,
Tok_Preprocess_IfNotDef,
Tok_Preprocess_ElIf,
Tok_Preprocess_Else,
Tok_Preprocess_EndIf,
Tok_Preprocess_Include,
Tok_Preprocess_Pragma,
Tok_Preprocess_Content,
Tok_Preprocess_Macro,
Tok_Preprocess_Unsupported,
Tok_Spec_Alignas,
Tok_Spec_Const,
Tok_Spec_Consteval,
Tok_Spec_Constexpr,
Tok_Spec_Constinit,
Tok_Spec_Explicit,
Tok_Spec_Extern,
Tok_Spec_Final,
Tok_Spec_ForceInline,
Tok_Spec_Global,
Tok_Spec_Inline,
Tok_Spec_Internal_Linkage,
Tok_Spec_LocalPersist,
Tok_Spec_Mutable,
Tok_Spec_NeverInline,
Tok_Spec_Override,
Tok_Spec_Static,
Tok_Spec_ThreadLocal,
Tok_Spec_Volatile,
Tok_Spec_Virtual,
Tok_Star,
Tok_Statement_End,
Tok_StaticAssert,
Tok_String,
Tok_Type_Typename,
Tok_Type_Unsigned,
Tok_Type_Signed,
Tok_Type_Short,
Tok_Type_Long,
Tok_Type_bool,
Tok_Type_char,
Tok_Type_int,
Tok_Type_double,
Tok_Type_MS_int8,
Tok_Type_MS_int16,
Tok_Type_MS_int32,
Tok_Type_MS_int64,
Tok_Type_MS_W64,
Tok_Varadic_Argument,
Tok___Attributes_Start,
Tok_Attribute_API_Export,
Tok_Attribute_API_Import,
Tok_NumTokens
};
inline StrC toktype_to_str( TokType type )
{
local_persist StrC lookup[] = {
{ sizeof( "__invalid__" ), "__invalid__" },
{ sizeof( "private" ), "private" },
{ sizeof( "protected" ), "protected" },
{ sizeof( "public" ), "public" },
{ sizeof( "." ), "." },
{ sizeof( "::" ), "::" },
{ sizeof( "&" ), "&" },
{ sizeof( "&&" ), "&&" },
{ sizeof( ":" ), ":" },
{ sizeof( "[[" ), "[[" },
{ sizeof( "]]" ), "]]" },
{ sizeof( "{" ), "{" },
{ sizeof( "}" ), "}" },
{ sizeof( "[" ), "[" },
{ sizeof( "]" ), "]" },
{ sizeof( "(" ), "(" },
{ sizeof( ")" ), ")" },
{ sizeof( "__comment__" ), "__comment__" },
{ sizeof( "__comment_end__" ), "__comment_end__" },
{ sizeof( "__comment_start__" ), "__comment_start__" },
{ sizeof( "__character__" ), "__character__" },
{ sizeof( "," ), "," },
{ sizeof( "class" ), "class" },
{ sizeof( "__attribute__" ), "__attribute__" },
{ sizeof( "__declspec" ), "__declspec" },
{ sizeof( "enum" ), "enum" },
{ sizeof( "extern" ), "extern" },
{ sizeof( "friend" ), "friend" },
{ sizeof( "module" ), "module" },
{ sizeof( "namespace" ), "namespace" },
{ sizeof( "operator" ), "operator" },
{ sizeof( "struct" ), "struct" },
{ sizeof( "template" ), "template" },
{ sizeof( "typedef" ), "typedef" },
{ sizeof( "using" ), "using" },
{ sizeof( "union" ), "union" },
{ sizeof( "__identifier__" ), "__identifier__" },
{ sizeof( "import" ), "import" },
{ sizeof( "export" ), "export" },
{ sizeof( "__new_line__" ), "__new_line__" },
{ sizeof( "__number__" ), "__number__" },
{ sizeof( "__operator__" ), "__operator__" },
{ sizeof( "#" ), "#" },
{ sizeof( "define" ), "define" },
{ sizeof( "if" ), "if" },
{ sizeof( "ifdef" ), "ifdef" },
{ sizeof( "ifndef" ), "ifndef" },
{ sizeof( "elif" ), "elif" },
{ sizeof( "else" ), "else" },
{ sizeof( "endif" ), "endif" },
{ sizeof( "include" ), "include" },
{ sizeof( "pragma" ), "pragma" },
{ sizeof( "__macro_content__" ), "__macro_content__" },
{ sizeof( "__macro__" ), "__macro__" },
{ sizeof( "__unsupported__" ), "__unsupported__" },
{ sizeof( "alignas" ), "alignas" },
{ sizeof( "const" ), "const" },
{ sizeof( "consteval" ), "consteval" },
{ sizeof( "constexpr" ), "constexpr" },
{ sizeof( "constinit" ), "constinit" },
{ sizeof( "explicit" ), "explicit" },
{ sizeof( "extern" ), "extern" },
{ sizeof( "final" ), "final" },
{ sizeof( "forceinline" ), "forceinline" },
{ sizeof( "global" ), "global" },
{ sizeof( "inline" ), "inline" },
{ sizeof( "internal" ), "internal" },
{ sizeof( "local_persist" ), "local_persist" },
{ sizeof( "mutable" ), "mutable" },
{ sizeof( "neverinline" ), "neverinline" },
{ sizeof( "override" ), "override" },
{ sizeof( "static" ), "static" },
{ sizeof( "thread_local" ), "thread_local" },
{ sizeof( "volatile" ), "volatile" },
{ sizeof( "virtual" ), "virtual" },
{ sizeof( "*" ), "*" },
{ sizeof( ";" ), ";" },
{ sizeof( "static_assert" ), "static_assert" },
{ sizeof( "__string__" ), "__string__" },
{ sizeof( "typename" ), "typename" },
{ sizeof( "unsigned" ), "unsigned" },
{ sizeof( "signed" ), "signed" },
{ sizeof( "short" ), "short" },
{ sizeof( "long" ), "long" },
{ sizeof( "bool" ), "bool" },
{ sizeof( "char" ), "char" },
{ sizeof( "int" ), "int" },
{ sizeof( "double" ), "double" },
{ sizeof( "__int8" ), "__int8" },
{ sizeof( "__int16" ), "__int16" },
{ sizeof( "__int32" ), "__int32" },
{ sizeof( "__int64" ), "__int64" },
{ sizeof( "_W64" ), "_W64" },
{ sizeof( "..." ), "..." },
{ sizeof( "__attrib_start__" ), "__attrib_start__" },
{ sizeof( "GEN_API_Export_Code" ), "GEN_API_Export_Code" },
{ sizeof( "GEN_API_Import_Code" ), "GEN_API_Import_Code" },
};
return lookup[type];
}
inline TokType strc_to_toktype( StrC str )
{
local_persist u32 keymap[Tok_NumTokens];
do_once_start for ( u32 index = 0; index < Tok_NumTokens; index++ )
{
StrC enum_str = toktype_to_str( (TokType)index );
keymap[index] = crc32( enum_str.Ptr, enum_str.Len - 1 );
}
do_once_end u32 hash = crc32( str.Ptr, str.Len );
for ( u32 index = 0; index < Tok_NumTokens; index++ )
{
if ( keymap[index] == hash )
return (TokType)index;
}
return Tok_Invalid;
}
GEN_NS_PARSER_END

159
base/components/header_end.hpp Normal file
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#ifdef GEN_INTELLISENSE_DIRECTIVES
#pragma once
#include "inlines.hpp"
#include "gen/ast_inlines.hpp"
#endif
#pragma region Constants
#ifndef GEN_GLOBAL_BUCKET_SIZE
# define GEN_GLOBAL_BUCKET_SIZE megabytes(8)
#endif
#ifndef GEN_CODEPOOL_NUM_BLOCKS
# define GEN_CODEPOOL_NUM_BLOCKS kilobytes(16)
#endif
#ifndef GEN_SIZE_PER_STRING_ARENA
# define GEN_SIZE_PER_STRING_ARENA megabytes(1)
#endif
#ifndef GEN_MAX_COMMENT_LINE_LENGTH
# define GEN_MAX_COMMENT_LINE_LENGTH 1024
#endif
#ifndef GEN_MAX_NAME_LENGTH
# define GEN_MAX_NAME_LENGTH 128
#endif
#ifndef GEN_MAX_UNTYPED_STR_LENGTH
# define GEN_MAX_UNTYPED_STR_LENGTH megabytes(1)
#endif
#ifndef TokenMap_FixedArena
# define TokenMap_FixedArena FixedArena_8KB
#endif
#ifndef GEN_LEX_ALLOCATOR_SIZE
# define GEN_LEX_ALLOCATOR_SIZE megabytes(4)
#endif
#ifndef GEN_BUILDER_STR_BUFFER_RESERVE
# define GEN_BUILDER_STR_BUFFER_RESERVE megabytes(2)
#endif
// These constexprs are used for allocation behavior of data structures
// or string handling while constructing or serializing.
// Change them to suit your needs.
constexpr s32 InitSize_DataArrays = 16;
// NOTE: This limits the maximum size of an allocation
// If you are generating a string larger than this, increase the size of the bucket here.
constexpr usize Global_BucketSize = GEN_GLOBAL_BUCKET_SIZE;
constexpr s32 CodePool_NumBlocks = GEN_CODEPOOL_NUM_BLOCKS;
constexpr s32 SizePer_StringArena = GEN_SIZE_PER_STRING_ARENA;
constexpr s32 MaxCommentLineLength = GEN_MAX_COMMENT_LINE_LENGTH;
constexpr s32 MaxNameLength = GEN_MAX_NAME_LENGTH;
constexpr s32 MaxUntypedStrLength = GEN_MAX_UNTYPED_STR_LENGTH;
// constexpr s32 TokenFmt_TokenMap_MemSize = GEN_TOKEN_FMT_TOKEN_MAP_MEM_SIZE;
constexpr s32 LexAllocator_Size = GEN_LEX_ALLOCATOR_SIZE;
constexpr s32 Builder_StrBufferReserve = GEN_BUILDER_STR_BUFFER_RESERVE;
extern StrC enum_underlying_sig;
extern Code access_public;
extern Code access_protected;
extern Code access_private;
extern CodeAttributes attrib_api_export;
extern CodeAttributes attrib_api_import;
extern Code module_global_fragment;
extern Code module_private_fragment;
extern Code fmt_newline;
extern CodePragma pragma_once;
extern CodeParams param_varadic;
extern CodePreprocessCond preprocess_else;
extern CodePreprocessCond preprocess_endif;
extern CodeSpecifiers spec_const;
extern CodeSpecifiers spec_consteval;
extern CodeSpecifiers spec_constexpr;
extern CodeSpecifiers spec_constinit;
extern CodeSpecifiers spec_extern_linkage;
extern CodeSpecifiers spec_final;
extern CodeSpecifiers spec_forceinline;
extern CodeSpecifiers spec_global;
extern CodeSpecifiers spec_inline;
extern CodeSpecifiers spec_internal_linkage;
extern CodeSpecifiers spec_local_persist;
extern CodeSpecifiers spec_mutable;
extern CodeSpecifiers spec_neverinline;
extern CodeSpecifiers spec_noexcept;
extern CodeSpecifiers spec_override;
extern CodeSpecifiers spec_ptr;
extern CodeSpecifiers spec_pure;
extern CodeSpecifiers spec_ref;
extern CodeSpecifiers spec_register;
extern CodeSpecifiers spec_rvalue;
extern CodeSpecifiers spec_static_member;
extern CodeSpecifiers spec_thread_local;
extern CodeSpecifiers spec_virtual;
extern CodeSpecifiers spec_volatile;
extern CodeTypename t_empty; // Used with varaidc parameters. (Exposing just in case its useful for another circumstance)
extern CodeTypename t_auto;
extern CodeTypename t_void;
extern CodeTypename t_int;
extern CodeTypename t_bool;
extern CodeTypename t_char;
extern CodeTypename t_wchar_t;
extern CodeTypename t_class;
extern CodeTypename t_typename;
#ifdef GEN_DEFINE_LIBRARY_CODE_CONSTANTS
// Predefined typename codes. Are set to readonly and are setup during gen::init()
extern CodeTypename t_b32;
extern CodeTypename t_s8;
extern CodeTypename t_s16;
extern CodeTypename t_s32;
extern CodeTypename t_s64;
extern CodeTypename t_u8;
extern CodeTypename t_u16;
extern CodeTypename t_u32;
extern CodeTypename t_u64;
extern CodeTypename t_ssize;
extern CodeTypename t_usize;
extern CodeTypename t_f32;
extern CodeTypename t_f64;
#endif
#pragma endregion Constants
// Used by the lexer to persistently treat all these identifiers as preprocessor defines.
// Populate with strings via gen::get_cached_string.
// Functional defines must have format: id( ;at minimum to indicate that the define is only valid with arguments.
extern Array(StringCached) PreprocessorDefines;
#ifdef GEN_EXPOSE_BACKEND
// Global allocator used for data with process lifetime.
extern AllocatorInfo GlobalAllocator;
extern Array(Arena) Global_AllocatorBuckets;
extern Array(Pool) CodePools;
extern Array(Arena) StringArenas;
extern StringTable StringCache;
extern Arena LexArena;
extern AllocatorInfo Allocator_DataArrays;
extern AllocatorInfo Allocator_CodePool;
extern AllocatorInfo Allocator_Lexer;
extern AllocatorInfo Allocator_StringArena;
extern AllocatorInfo Allocator_StringTable;
extern AllocatorInfo Allocator_TypeTable;
#endif

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#pragma once
/*
gencpp: An attempt at "simple" staged metaprogramming for c/c++.
See Readme.md for more information from the project repository.
Public Address:
https://github.com/Ed94/gencpp --------------------------------------------------------------.
| _____ _____ _ _ |
| / ____) / ____} | | | |
| | / ___ ___ _ __ ___ _ __ _ __ | {___ | |__ _ _, __ _, ___ __| | |
| | |{_ |/ _ \ '_ \ / __} '_ l| '_ l `\___ \| __/ _` |/ _` |/ _ \/ _` | |
| | l__j | ___/ | | | {__; |+l } |+l | ____) | l| (_| | {_| | ___/ (_| | |
| \_____|\___}_l |_|\___} ,__/| ,__/ (_____/ \__\__/_|\__, |\___}\__,_l |
| | | | | __} | |
| l_l l_l {___/ |
! ----------------------------------------------------------------------- VERSION: v0.20-Alpha |
! ============================================================================================ |
! WARNING: THIS IS AN ALPHA VERSION OF THE LIBRARY, USE AT YOUR OWN DISCRETION |
! NEVER DO CODE GENERATION WITHOUT AT LEAST HAVING CONTENT IN A CODEBASE UNDER VERSION CONTROL |
! ============================================================================================ /
*/
#if ! defined(GEN_DONT_ENFORCE_GEN_TIME_GUARD) && ! defined(GEN_TIME)
# error Gen.hpp : GEN_TIME not defined
#endif
//! If its desired to roll your own dependencies, define GEN_ROLL_OWN_DEPENDENCIES before including this file.
// Dependencies are derived from the c-zpl library: https://github.com/zpl-c/zpl
#ifndef GEN_ROLL_OWN_DEPENDENCIES
# include "gen.dep.hpp"
#endif

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#ifdef GEN_INTELLISENSE_DIRECTIVES
#pragma once
#include "interface.hpp"
#endif
#pragma region Code
inline
void code_append( Code self, Code other )
{
GEN_ASSERT(self);
GEN_ASSERT(other);
GEN_ASSERT_MSG(self != other, "Attempted to recursively append Code AST to itself.");
if ( other->Parent != nullptr )
other = code_duplicate(other);
other->Parent = self;
if ( self->Front == nullptr )
{
self->Front = other;
self->Back = other;
self->NumEntries++;
return;
}
Code
Current = self->Back;
Current->Next = other;
other->Prev = Current;
self->Back = other;
self->NumEntries++;
}
inline
bool code_is_body(Code self)
{
GEN_ASSERT(self);
switch (self->Type)
{
case CT_Enum_Body:
case CT_Class_Body:
case CT_Union_Body:
case CT_Export_Body:
case CT_Global_Body:
case CT_Struct_Body:
case CT_Function_Body:
case CT_Namespace_Body:
case CT_Extern_Linkage_Body:
return true;
}
return false;
}
inline
Code* code_entry( Code self, u32 idx )
{
GEN_ASSERT(self != nullptr);
Code* current = & self->Front;
while ( idx >= 0 && current != nullptr )
{
if ( idx == 0 )
return rcast( Code*, current);
current = & ( * current )->Next;
idx--;
}
return rcast( Code*, current);
}
forceinline
bool code_is_valid(Code self)
{
GEN_ASSERT(self);
return self != nullptr && self->Type != CT_Invalid;
}
forceinline
bool code_has_entries(AST* self)
{
GEN_ASSERT(self);
return self->NumEntries > 0;
}
forceinline
void code_set_global(Code self)
{
if ( self == nullptr )
{
log_failure("Code::set_global: Cannot set code as global, AST is null!");
return;
}
self->Parent = Code_Global;
}
#if GEN_COMPILER_CPP
forceinline
Code& Code::operator ++()
{
if ( ast )
ast = ast->Next.ast;
return * this;
}
#endif
forceinline
StrC code_type_str(Code self)
{
GEN_ASSERT(self != nullptr);
return codetype_to_str( self->Type );
}
#pragma endregion Code
#pragma region CodeBody
inline
void body_append( CodeBody self, Code other )
{
GEN_ASSERT(self);
GEN_ASSERT(other);
if (code_is_body(other)) {
body_append_body( self, cast(CodeBody, other) );
return;
}
code_append( cast(Code, self), other );
}
inline
void body_append_body( CodeBody self, CodeBody body )
{
GEN_ASSERT(self);
GEN_ASSERT(body);
GEN_ASSERT_MSG(self != body, "Attempted to append body to itself.");
for ( Code entry = begin_CodeBody(body); entry != end_CodeBody(body); entry = next_CodeBody(body, entry) ) {
body_append( self, entry );
}
}
inline
Code begin_CodeBody( CodeBody body) {
GEN_ASSERT(body);
if ( body != nullptr )
return body->Front;
return NullCode;
}
forceinline
Code end_CodeBody(CodeBody body ){
GEN_ASSERT(body);
return body->Back->Next;
}
inline
Code next_CodeBody(CodeBody body, Code entry) {
GEN_ASSERT(body);
GEN_ASSERT(entry);
return entry->Next;
}
#pragma endregion CodeBody
#pragma region CodeClass
inline
void class_add_interface( CodeClass self, CodeTypename type )
{
GEN_ASSERT(self);
GEN_ASSERT(type);
CodeTypename possible_slot = self->ParentType;
if ( possible_slot != nullptr )
{
// Were adding an interface to parent type, so we need to make sure the parent type is public.
self->ParentAccess = AccessSpec_Public;
// If your planning on adding a proper parent,
// then you'll need to move this over to ParentType->next and update ParentAccess accordingly.
}
while ( possible_slot != nullptr )
{
possible_slot = cast(CodeTypename, possible_slot->Next);
}
possible_slot = type;
}
#pragma endregion CodeClass
#pragma region CodeParams
inline
void params_append( CodeParams appendee, CodeParams other )
{
GEN_ASSERT(appendee);
GEN_ASSERT(other);
GEN_ASSERT_MSG(appendee != other, "Attempted to append parameter to itself.");
Code self = cast(Code, appendee);
Code entry = cast(Code, other);
if ( entry->Parent != nullptr )
entry = code_duplicate( entry );
entry->Parent = self;
if ( self->Last == nullptr )
{
self->Last = entry;
self->Next = entry;
self->NumEntries++;
return;
}
self->Last->Next = entry;
self->Last = entry;
self->NumEntries++;
}
inline
CodeParams params_get(CodeParams self, s32 idx )
{
GEN_ASSERT(self);
CodeParams param = self;
do
{
if ( ++ param != nullptr )
return NullCode;
param = cast(CodeParams, cast(Code, param)->Next);
}
while ( --idx );
return param;
}
forceinline
bool params_has_entries(CodeParams self)
{
GEN_ASSERT(self);
return self->NumEntries > 0;
}
#if GEN_COMPILER_CPP
forceinline
CodeParams& CodeParams::operator ++()
{
* this = ast->Next;
return * this;
}
#endif
forceinline
CodeParams begin_CodeParams(CodeParams params)
{
if ( params != nullptr )
return params;
return NullCode;
}
forceinline
CodeParams end_CodeParams(CodeParams params)
{
// return { (AST_Params*) rcast( AST*, ast)->Last };
return NullCode;
}
forceinline
CodeParams next_CodeParams(CodeParams params, CodeParams param_iter)
{
GEN_ASSERT(param_iter);
return param_iter->Next;
}
#pragma endregion CodeParams
#pragma region CodeSpecifiers
inline
bool specifiers_append(CodeSpecifiers self, Specifier spec )
{
if ( self == nullptr )
{
log_failure("CodeSpecifiers: Attempted to append to a null specifiers AST!");
return false;
}
if ( self->NumEntries == AST_ArrSpecs_Cap )
{
log_failure("CodeSpecifiers: Attempted to append over %d specifiers to a specifiers AST!", AST_ArrSpecs_Cap );
return false;
}
self->ArrSpecs[ self->NumEntries ] = spec;
self->NumEntries++;
return true;
}
inline
s32 specifiers_has(CodeSpecifiers self, Specifier spec)
{
GEN_ASSERT(self != nullptr);
for ( s32 idx = 0; idx < self->NumEntries; idx++ ) {
if ( self->ArrSpecs[ idx ] == spec )
return idx;
}
return -1;
}
inline
s32 specifiers_remove( CodeSpecifiers self, Specifier to_remove )
{
if ( self == nullptr )
{
log_failure("CodeSpecifiers: Attempted to append to a null specifiers AST!");
return -1;
}
if ( self->NumEntries == AST_ArrSpecs_Cap )
{
log_failure("CodeSpecifiers: Attempted to append over %d specifiers to a specifiers AST!", AST_ArrSpecs_Cap );
return -1;
}
s32 result = -1;
s32 curr = 0;
s32 next = 0;
for(; next < self->NumEntries; ++ curr, ++ next)
{
Specifier spec = self->ArrSpecs[next];
if (spec == to_remove)
{
result = next;
next ++;
if (next >= self->NumEntries)
break;
spec = self->ArrSpecs[next];
}
self->ArrSpecs[ curr ] = spec;
}
if (result > -1) {
self->NumEntries --;
}
return result;
}
forceinline
Specifier* begin_CodeSpecifiers(CodeSpecifiers self)
{
if ( self != nullptr )
return & self->ArrSpecs[0];
return nullptr;
}
forceinline
Specifier* end_CodeSpecifiers(CodeSpecifiers self)
{
return self->ArrSpecs + self->NumEntries;
}
forceinline
Specifier* next_CodeSpecifiers(CodeSpecifiers self, Specifier* spec_iter)
{
return spec_iter + 1;
}
#pragma endregion CodeSpecifiers
#pragma region CodeStruct
inline
void struct_add_interface(CodeStruct self, CodeTypename type )
{
CodeTypename possible_slot = self->ParentType;
if ( possible_slot != nullptr )
{
// Were adding an interface to parent type, so we need to make sure the parent type is public.
self->ParentAccess = AccessSpec_Public;
// If your planning on adding a proper parent,
// then you'll need to move this over to ParentType->next and update ParentAccess accordingly.
}
while ( possible_slot != nullptr )
{
possible_slot = cast(CodeTypename, possible_slot->Next);
}
possible_slot = type;
}
#pragma endregion Code
#pragma region Interface
inline
CodeBody def_body( CodeType type )
{
switch ( type )
{
case CT_Class_Body:
case CT_Enum_Body:
case CT_Export_Body:
case CT_Extern_Linkage:
case CT_Function_Body:
case CT_Global_Body:
case CT_Namespace_Body:
case CT_Struct_Body:
case CT_Union_Body:
break;
default:
log_failure( "def_body: Invalid type %s", codetype_to_str(type).Ptr );
return (CodeBody)Code_Invalid;
}
Code
result = make_code();
result->Type = type;
return (CodeBody)result;
}
inline
StrC token_fmt_impl( ssize num, ... )
{
local_persist thread_local
char buf[GEN_PRINTF_MAXLEN] = { 0 };
mem_set( buf, 0, GEN_PRINTF_MAXLEN );
va_list va;
va_start(va, num );
ssize result = token_fmt_va(buf, GEN_PRINTF_MAXLEN, num, va);
va_end(va);
StrC str = { result, buf };
return str;
}
#pragma endregion Interface

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#ifdef GEN_INTELLISENSE_DIRECTIVES
#pragma once
#include "code_serialization.cpp"
#endif
GEN_NS_PARSER_BEGIN
internal void parser_init();
internal void parser_deinit();
GEN_NS_PARSER_END
internal
void* Global_Allocator_Proc( void* allocator_data, AllocType type, ssize size, ssize alignment, void* old_memory, ssize old_size, u64 flags )
{
Arena* last = array_back(Global_AllocatorBuckets);
switch ( type )
{
case EAllocation_ALLOC:
{
if ( ( last->TotalUsed + size ) > last->TotalSize )
{
Arena bucket = arena_init_from_allocator( heap(), Global_BucketSize );
if ( bucket.PhysicalStart == nullptr )
GEN_FATAL( "Failed to create bucket for Global_AllocatorBuckets");
if ( ! array_append( Global_AllocatorBuckets, bucket ) )
GEN_FATAL( "Failed to append bucket to Global_AllocatorBuckets");
last = array_back(Global_AllocatorBuckets);
}
return alloc_align( arena_allocator_info(last), size, alignment );
}
case EAllocation_FREE:
{
// Doesn't recycle.
}
break;
case EAllocation_FREE_ALL:
{
// Memory::cleanup instead.
}
break;
case EAllocation_RESIZE:
{
if ( last->TotalUsed + size > last->TotalSize )
{
Arena bucket = arena_init_from_allocator( heap(), Global_BucketSize );
if ( bucket.PhysicalStart == nullptr )
GEN_FATAL( "Failed to create bucket for Global_AllocatorBuckets");
if ( ! array_append( Global_AllocatorBuckets, bucket ) )
GEN_FATAL( "Failed to append bucket to Global_AllocatorBuckets");
last = array_back(Global_AllocatorBuckets);
}
void* result = alloc_align( last->Backing, size, alignment );
if ( result != nullptr && old_memory != nullptr )
{
mem_copy( result, old_memory, old_size );
}
return result;
}
}
return nullptr;
}
internal
void define_constants()
{
Code_Global = make_code();
Code_Global->Name = get_cached_string( txt("Global Code") );
Code_Global->Content = Code_Global->Name;
Code_Invalid = make_code();
code_set_global(Code_Invalid);
t_empty = (CodeTypename) make_code();
t_empty->Type = CT_Typename;
t_empty->Name = get_cached_string( txt("") );
code_set_global(cast(Code, t_empty));
access_private = make_code();
access_private->Type = CT_Access_Private;
access_private->Name = get_cached_string( txt("private:\n") );
code_set_global(cast(Code, access_private));
access_protected = make_code();
access_protected->Type = CT_Access_Protected;
access_protected->Name = get_cached_string( txt("protected:\n") );
code_set_global(access_protected);
access_public = make_code();
access_public->Type = CT_Access_Public;
access_public->Name = get_cached_string( txt("public:\n") );
code_set_global(access_public);
StrC api_export_str = code(GEN_API_Export_Code);
attrib_api_export = def_attributes( api_export_str );
code_set_global(cast(Code, attrib_api_export));
StrC api_import_str = code(GEN_API_Import_Code);
attrib_api_import = def_attributes( api_import_str );
code_set_global(cast(Code, attrib_api_import));
module_global_fragment = make_code();
module_global_fragment->Type = CT_Untyped;
module_global_fragment->Name = get_cached_string( txt("module;") );
module_global_fragment->Content = module_global_fragment->Name;
code_set_global(cast(Code, module_global_fragment));
module_private_fragment = make_code();
module_private_fragment->Type = CT_Untyped;
module_private_fragment->Name = get_cached_string( txt("module : private;") );
module_private_fragment->Content = module_private_fragment->Name;
code_set_global(cast(Code, module_private_fragment));
fmt_newline = make_code();
fmt_newline->Type = CT_NewLine;
code_set_global((Code)fmt_newline);
pragma_once = (CodePragma) make_code();
pragma_once->Type = CT_Preprocess_Pragma;
pragma_once->Name = get_cached_string( txt("once") );
pragma_once->Content = pragma_once->Name;
code_set_global((Code)pragma_once);
param_varadic = (CodeParams) make_code();
param_varadic->Type = CT_Parameters;
param_varadic->Name = get_cached_string( txt("...") );
param_varadic->ValueType = t_empty;
code_set_global((Code)param_varadic);
preprocess_else = (CodePreprocessCond) make_code();
preprocess_else->Type = CT_Preprocess_Else;
code_set_global((Code)preprocess_else);
preprocess_endif = (CodePreprocessCond) make_code();
preprocess_endif->Type = CT_Preprocess_EndIf;
code_set_global((Code)preprocess_endif);
# define def_constant_code_type( Type_ ) \
do \
{ \
StrC name_str = name(Type_); \
t_##Type_ = def_type( name_str ); \
code_set_global( cast(Code, t_##Type_)); \
} while(0)
def_constant_code_type( auto );
def_constant_code_type( void );
def_constant_code_type( int );
def_constant_code_type( bool );
def_constant_code_type( char );
def_constant_code_type( wchar_t );
def_constant_code_type( class );
def_constant_code_type( typename );
#ifdef GEN_DEFINE_LIBRARY_CODE_CONSTANTS
t_b32 = def_type( name(b32) );
def_constant_code_type( s8 );
def_constant_code_type( s16 );
def_constant_code_type( s32 );
def_constant_code_type( s64 );
def_constant_code_type( u8 );
def_constant_code_type( u16 );
def_constant_code_type( u32 );
def_constant_code_type( u64 );
def_constant_code_type( ssize );
def_constant_code_type( usize );
def_constant_code_type( f32 );
def_constant_code_type( f64 );
#endif
# undef def_constant_code_type
spec_const = def_specifier( Spec_Const); code_set_global( cast(Code, spec_const ));
spec_consteval = def_specifier( Spec_Consteval); code_set_global( cast(Code, spec_consteval ));;
spec_constexpr = def_specifier( Spec_Constexpr); code_set_global( cast(Code, spec_constexpr ));;
spec_constinit = def_specifier( Spec_Constinit); code_set_global( cast(Code, spec_constinit ));;
spec_extern_linkage = def_specifier( Spec_External_Linkage); code_set_global( cast(Code, spec_extern_linkage ));;
spec_final = def_specifier( Spec_Final); code_set_global( cast(Code, spec_final ));;
spec_forceinline = def_specifier( Spec_ForceInline); code_set_global( cast(Code, spec_forceinline ));;
spec_global = def_specifier( Spec_Global); code_set_global( cast(Code, spec_global ));;
spec_inline = def_specifier( Spec_Inline); code_set_global( cast(Code, spec_inline ));;
spec_internal_linkage = def_specifier( Spec_Internal_Linkage); code_set_global( cast(Code, spec_internal_linkage ));;
spec_local_persist = def_specifier( Spec_Local_Persist); code_set_global( cast(Code, spec_local_persist ));;
spec_mutable = def_specifier( Spec_Mutable); code_set_global( cast(Code, spec_mutable ));;
spec_neverinline = def_specifier( Spec_NeverInline); code_set_global( cast(Code, spec_neverinline ));;
spec_noexcept = def_specifier( Spec_NoExceptions); code_set_global( cast(Code, spec_noexcept ));;
spec_override = def_specifier( Spec_Override); code_set_global( cast(Code, spec_override ));;
spec_ptr = def_specifier( Spec_Ptr); code_set_global( cast(Code, spec_ptr ));;
spec_pure = def_specifier( Spec_Pure); code_set_global( cast(Code, spec_pure ));
spec_ref = def_specifier( Spec_Ref); code_set_global( cast(Code, spec_ref ));;
spec_register = def_specifier( Spec_Register); code_set_global( cast(Code, spec_register ));;
spec_rvalue = def_specifier( Spec_RValue); code_set_global( cast(Code, spec_rvalue ));;
spec_static_member = def_specifier( Spec_Static); code_set_global( cast(Code, spec_static_member ));;
spec_thread_local = def_specifier( Spec_Thread_Local); code_set_global( cast(Code, spec_thread_local ));;
spec_virtual = def_specifier( Spec_Virtual); code_set_global( cast(Code, spec_virtual ));;
spec_volatile = def_specifier( Spec_Volatile); code_set_global( cast(Code, spec_volatile ));
spec_local_persist = def_specifiers( 1, Spec_Local_Persist );
code_set_global(cast(Code, spec_local_persist));
if (enum_underlying_sig.Len == 0) {
enum_underlying_sig = txt("enum_underlying(");
}
array_append(PreprocessorDefines, enum_underlying_sig);
# undef def_constant_spec
}
void init()
{
// Setup global allocator
{
AllocatorInfo becasue_C = { & Global_Allocator_Proc, nullptr };
GlobalAllocator = becasue_C;
Global_AllocatorBuckets = array_init_reserve(Arena, heap(), 128 );
if ( Global_AllocatorBuckets == nullptr )
GEN_FATAL( "Failed to reserve memory for Global_AllocatorBuckets");
Arena bucket = arena_init_from_allocator( heap(), Global_BucketSize );
if ( bucket.PhysicalStart == nullptr )
GEN_FATAL( "Failed to create first bucket for Global_AllocatorBuckets");
array_append( Global_AllocatorBuckets, bucket );
}
if (Allocator_DataArrays.Proc == nullptr) {
Allocator_DataArrays = GlobalAllocator;
}
if (Allocator_CodePool.Proc == nullptr ) {
Allocator_CodePool = GlobalAllocator;
}
if (Allocator_Lexer.Proc == nullptr) {
Allocator_Lexer = GlobalAllocator;
}
if (Allocator_StringArena.Proc == nullptr) {
Allocator_StringArena = GlobalAllocator;
}
if (Allocator_StringTable.Proc == nullptr) {
Allocator_StringTable = GlobalAllocator;
}
if (Allocator_TypeTable.Proc == nullptr) {
Allocator_TypeTable = GlobalAllocator;
}
// Setup the arrays
{
CodePools = array_init_reserve(Pool, Allocator_DataArrays, InitSize_DataArrays );
if ( CodePools == nullptr )
GEN_FATAL( "gen::init: Failed to initialize the CodePools array" );
StringArenas = array_init_reserve(Arena, Allocator_DataArrays, InitSize_DataArrays );
if ( StringArenas == nullptr )
GEN_FATAL( "gen::init: Failed to initialize the StringArenas array" );
}
// Setup the code pool and code entries arena.
{
Pool code_pool = pool_init( Allocator_CodePool, CodePool_NumBlocks, sizeof(AST) );
if ( code_pool.PhysicalStart == nullptr )
GEN_FATAL( "gen::init: Failed to initialize the code pool" );
array_append( CodePools, code_pool );
LexArena = arena_init_from_allocator( Allocator_Lexer, LexAllocator_Size );
Arena string_arena = arena_init_from_allocator( Allocator_StringArena, SizePer_StringArena );
if ( string_arena.PhysicalStart == nullptr )
GEN_FATAL( "gen::init: Failed to initialize the string arena" );
array_append( StringArenas, string_arena );
}
// Setup the hash tables
{
StringCache = hashtable_init(StringCached, Allocator_StringTable);
if ( StringCache.Entries == nullptr )
GEN_FATAL( "gen::init: Failed to initialize the StringCache");
}
// Preprocessor Defines
PreprocessorDefines = array_init_reserve(StringCached, GlobalAllocator, kilobytes(1) );
define_constants();
GEN_NS_PARSER parser_init();
}
void deinit()
{
usize index = 0;
usize left = array_num(CodePools);
do
{
Pool* code_pool = & CodePools[index];
pool_free(code_pool);
index++;
}
while ( left--, left );
index = 0;
left = array_num(StringArenas);
do
{
Arena* string_arena = & StringArenas[index];
arena_free(string_arena);
index++;
}
while ( left--, left );
hashtable_destroy(StringCache);
array_free( CodePools);
array_free( StringArenas);
arena_free(& LexArena);
array_free(PreprocessorDefines);
index = 0;
left = array_num(Global_AllocatorBuckets);
do
{
Arena* bucket = & Global_AllocatorBuckets[ index ];
arena_free(bucket);
index++;
}
while ( left--, left );
array_free(Global_AllocatorBuckets);
GEN_NS_PARSER parser_deinit();
}
void reset()
{
s32 index = 0;
s32 left = array_num(CodePools);
do
{
Pool* code_pool = & CodePools[index];
pool_clear(code_pool);
index++;
}
while ( left--, left );
index = 0;
left = array_num(StringArenas);
do
{
Arena* string_arena = & StringArenas[index];
string_arena->TotalUsed = 0;;
index++;
}
while ( left--, left );
hashtable_clear(StringCache);
define_constants();
}
AllocatorInfo get_string_allocator( s32 str_length )
{
Arena* last = array_back(StringArenas);
usize size_req = str_length + sizeof(StringHeader) + sizeof(char*);
if ( last->TotalUsed + scast(ssize, size_req) > last->TotalSize )
{
Arena new_arena = arena_init_from_allocator( Allocator_StringArena, SizePer_StringArena );
if ( ! array_append( StringArenas, new_arena ) )
GEN_FATAL( "gen::get_string_allocator: Failed to allocate a new string arena" );
last = array_back(StringArenas);
}
return arena_allocator_info(last);
}
// Will either make or retrive a code string.
StringCached get_cached_string( StrC str )
{
s32 hash_length = str.Len > kilobytes(1) ? kilobytes(1) : str.Len;
u64 key = crc32( str.Ptr, hash_length );
{
StringCached* result = hashtable_get(StringCache, key );
if ( result )
return * result;
}
StrC result = string_to_strc( string_make_strc( get_string_allocator( str.Len ), str ));
hashtable_set(StringCache, key, result );
return result;
}
// Used internally to retireve a Code object form the CodePool.
Code make_code()
{
Pool* allocator = array_back( CodePools);
if ( allocator->FreeList == nullptr )
{
Pool code_pool = pool_init( Allocator_CodePool, CodePool_NumBlocks, sizeof(AST) );
if ( code_pool.PhysicalStart == nullptr )
GEN_FATAL( "gen::make_code: Failed to allocate a new code pool - CodePool allcoator returned nullptr." );
if ( ! array_append( CodePools, code_pool ) )
GEN_FATAL( "gen::make_code: Failed to allocate a new code pool - CodePools failed to append new pool." );
allocator = array_back( CodePools);
}
Code result = { rcast( AST*, alloc( pool_allocator_info(allocator), sizeof(AST) )) };
mem_set( rcast(void*, cast(AST*, result)), 0, sizeof(AST) );
return result;
}
void set_allocator_data_arrays( AllocatorInfo allocator )
{
Allocator_DataArrays = allocator;
}
void set_allocator_code_pool( AllocatorInfo allocator )
{
Allocator_CodePool = allocator;
}
void set_allocator_lexer( AllocatorInfo allocator )
{
Allocator_Lexer = allocator;
}
void set_allocator_string_arena( AllocatorInfo allocator )
{
Allocator_StringArena = allocator;
}
void set_allocator_string_table( AllocatorInfo allocator )
{
Allocator_StringArena = allocator;
}

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#ifdef GEN_INTELLISENSE_DIRECTIVES
#pragma once
#include "ast_types.hpp"
#endif
#pragma region Gen Interface
/*
/ \ | \ | \ / \
| ▓▓▓▓▓▓\ ______ _______ \▓▓▓▓▓▓_______ _| ▓▓_ ______ ______ | ▓▓▓▓▓▓\ ______ _______ ______
| ▓▓ __\▓▓/ \| \ | ▓▓ | \| ▓▓ \ / \ / \| ▓▓_ \▓▓| \ / \/ \
| ▓▓| \ ▓▓▓▓▓▓\ ▓▓▓▓▓▓▓\ | ▓▓ | ▓▓▓▓▓▓▓\\▓▓▓▓▓▓ | ▓▓▓▓▓▓\ ▓▓▓▓▓▓\ ▓▓ \ \▓▓▓▓▓▓\ ▓▓▓▓▓▓▓ ▓▓▓▓▓▓\
| ▓▓ \▓▓▓▓ ▓▓ ▓▓ ▓▓ | ▓▓ | ▓▓ | ▓▓ | ▓▓ | ▓▓ __| ▓▓ ▓▓ ▓▓ \▓▓ ▓▓▓▓ / ▓▓ ▓▓ | ▓▓ ▓▓
| ▓▓__| ▓▓ ▓▓▓▓▓▓▓▓ ▓▓ | ▓▓ _| ▓▓_| ▓▓ | ▓▓ | ▓▓| \ ▓▓▓▓▓▓▓▓ ▓▓ | ▓▓ | ▓▓▓▓▓▓▓ ▓▓_____| ▓▓▓▓▓▓▓▓
\▓▓ ▓▓\▓▓ \ ▓▓ | ▓▓ | ▓▓ \ ▓▓ | ▓▓ \▓▓ ▓▓\▓▓ \ ▓▓ | ▓▓ \▓▓ ▓▓\▓▓ \\▓▓ \
\▓▓▓▓▓▓ \▓▓▓▓▓▓▓\▓▓ \▓▓ \▓▓▓▓▓▓\▓▓ \▓▓ \▓▓▓▓ \▓▓▓▓▓▓▓\▓▓ \▓▓ \▓▓▓▓▓▓▓ \▓▓▓▓▓▓▓ \▓▓▓▓▓▓▓
*/
// Initialize the library.
void init();
// Currently manually free's the arenas, code for checking for leaks.
// However on Windows at least, it doesn't need to occur as the OS will clean up after the process.
void deinit();
// Clears the allocations, but doesn't return to the heap, the calls init() again.
// Ease of use.
void reset();
// Used internally to retrive or make string allocations.
// Strings are stored in a series of string arenas of fixed size (SizePer_StringArena)
StringCached get_cached_string( StrC str );
/*
This provides a fresh Code AST.
The gen interface use this as their method from getting a new AST object from the CodePool.
Use this if you want to make your own API for formatting the supported Code Types.
*/
Code make_code();
// Set these before calling gen's init() procedure.
void set_allocator_data_arrays ( AllocatorInfo data_array_allocator );
void set_allocator_code_pool ( AllocatorInfo pool_allocator );
void set_allocator_lexer ( AllocatorInfo lex_allocator );
void set_allocator_string_arena( AllocatorInfo string_allocator );
void set_allocator_string_table( AllocatorInfo string_allocator );
void set_allocator_type_table ( AllocatorInfo type_reg_allocator );
#pragma region Upfront
CodeAttributes def_attributes( StrC content );
CodeComment def_comment ( StrC content );
struct Opts_def_struct {
CodeBody body;
CodeTypename parent;
AccessSpec parent_access;
CodeAttributes attributes;
CodeTypename* interfaces;
s32 num_interfaces;
ModuleFlag mflags;
};
CodeClass def_class( StrC name, Opts_def_struct opts GEN_PARAM_DEFAULT );
struct Opts_def_constructor {
CodeParams params;
Code initializer_list;
Code body;
};
CodeConstructor def_constructor( Opts_def_constructor opts GEN_PARAM_DEFAULT );
struct Opts_def_define {
b32 dont_append_preprocess_defines;
};
CodeDefine def_define( StrC name, StrC content, Opts_def_define opts GEN_PARAM_DEFAULT );
struct Opts_def_destructor {
Code body;
CodeSpecifiers specifiers;
};
CodeDestructor def_destructor( Opts_def_destructor opts GEN_PARAM_DEFAULT );
struct Opts_def_enum {
CodeBody body;
CodeTypename type;
EnumT specifier;
CodeAttributes attributes;
ModuleFlag mflags;
Code type_macro;
};
CodeEnum def_enum( StrC name, Opts_def_enum opts GEN_PARAM_DEFAULT );
CodeExec def_execution ( StrC content );
CodeExtern def_extern_link( StrC name, CodeBody body );
CodeFriend def_friend ( Code symbol );
struct Opts_def_function {
CodeParams params;
CodeTypename ret_type;
CodeBody body;
CodeSpecifiers specs;
CodeAttributes attrs;
ModuleFlag mflags;
};
CodeFn def_function( StrC name, Opts_def_function opts GEN_PARAM_DEFAULT );
struct Opts_def_include { b32 foreign; };
struct Opts_def_module { ModuleFlag mflags; };
struct Opts_def_namespace { ModuleFlag mflags; };
CodeInclude def_include ( StrC content, Opts_def_include opts GEN_PARAM_DEFAULT );
CodeModule def_module ( StrC name, Opts_def_module opts GEN_PARAM_DEFAULT );
CodeNS def_namespace( StrC name, CodeBody body, Opts_def_namespace opts GEN_PARAM_DEFAULT );
struct Opts_def_operator {
CodeParams params;
CodeTypename ret_type;
CodeBody body;
CodeSpecifiers specifiers;
CodeAttributes attributes;
ModuleFlag mflags;
};
CodeOperator def_operator( Operator op, StrC nspace, Opts_def_operator opts GEN_PARAM_DEFAULT );
struct Opts_def_operator_cast {
CodeBody body;
CodeSpecifiers specs;
};
CodeOpCast def_operator_cast( CodeTypename type, Opts_def_operator_cast opts GEN_PARAM_DEFAULT );
struct Opts_def_param { Code value; };
CodeParams def_param ( CodeTypename type, StrC name, Opts_def_param opts GEN_PARAM_DEFAULT );
CodePragma def_pragma( StrC directive );
CodePreprocessCond def_preprocess_cond( EPreprocessCond type, StrC content );
CodeSpecifiers def_specifier( Specifier specifier );
CodeStruct def_struct( StrC name, Opts_def_struct opts GEN_PARAM_DEFAULT );
struct Opts_def_template { ModuleFlag mflags; };
CodeTemplate def_template( CodeParams params, Code definition, Opts_def_template opts GEN_PARAM_DEFAULT );
struct Opts_def_type {
ETypenameTag type_tag;
Code arrayexpr;
CodeSpecifiers specifiers;
CodeAttributes attributes;
};
CodeTypename def_type( StrC name, Opts_def_type opts GEN_PARAM_DEFAULT );
struct Opts_def_typedef {
CodeAttributes attributes;
ModuleFlag mflags;
};
CodeTypedef def_typedef( StrC name, Code type, Opts_def_typedef opts GEN_PARAM_DEFAULT );
struct Opts_def_union {
CodeAttributes attributes;
ModuleFlag mflags;
};
CodeUnion def_union( StrC name, CodeBody body, Opts_def_union opts GEN_PARAM_DEFAULT );
struct Opts_def_using {
CodeAttributes attributes;
ModuleFlag mflags;
};
CodeUsing def_using( StrC name, CodeTypename type, Opts_def_using opts GEN_PARAM_DEFAULT );
CodeUsing def_using_namespace( StrC name );
struct Opts_def_variable
{
Code value;
CodeSpecifiers specifiers;
CodeAttributes attributes;
ModuleFlag mflags;
};
CodeVar def_variable( CodeTypename type, StrC name, Opts_def_variable opts GEN_PARAM_DEFAULT );
// Constructs an empty body. Use AST::validate_body() to check if the body is was has valid entries.
CodeBody def_body( CodeType type );
// There are two options for defining a struct body, either varadically provided with the args macro to auto-deduce the arg num,
/// or provide as an array of Code objects.
CodeBody def_class_body ( s32 num, ... );
CodeBody def_class_body ( s32 num, Code* codes );
CodeBody def_enum_body ( s32 num, ... );
CodeBody def_enum_body ( s32 num, Code* codes );
CodeBody def_export_body ( s32 num, ... );
CodeBody def_export_body ( s32 num, Code* codes);
CodeBody def_extern_link_body( s32 num, ... );
CodeBody def_extern_link_body( s32 num, Code* codes );
CodeBody def_function_body ( s32 num, ... );
CodeBody def_function_body ( s32 num, Code* codes );
CodeBody def_global_body ( s32 num, ... );
CodeBody def_global_body ( s32 num, Code* codes );
CodeBody def_namespace_body ( s32 num, ... );
CodeBody def_namespace_body ( s32 num, Code* codes );
CodeParams def_params ( s32 num, ... );
CodeParams def_params ( s32 num, CodeParams* params );
CodeSpecifiers def_specifiers ( s32 num, ... );
CodeSpecifiers def_specifiers ( s32 num, Specifier* specs );
CodeBody def_struct_body ( s32 num, ... );
CodeBody def_struct_body ( s32 num, Code* codes );
CodeBody def_union_body ( s32 num, ... );
CodeBody def_union_body ( s32 num, Code* codes );
#pragma endregion Upfront
#pragma region Parsing
// TODO(Ed) : Implmeent the new parser API design.
#if 0
GEN_NS_PARSER_BEGIN
struct StackNode
{
StackNode* Prev;
Token Start;
Token Name; // The name of the AST node (if parsed)
StrC FailedProc; // The name of the procedure that failed
};
// Stack nodes are allocated the error's allocator
struct Error
{
String message;
StackNode* context_stack;
};
GEN_NS_PARSER_END
struct ParseInfo
{
Arena FileMem;
Arena TokMem;
Arena CodeMem;
FileContents FileContent;
Array<Token> Tokens;
Array<Error> Errors;
// Errors are allocated to a dedicated general arena.
};
CodeBody parse_file( StrC path );
#endif
CodeClass parse_class ( StrC class_def );
CodeConstructor parse_constructor ( StrC constructor_def );
CodeDestructor parse_destructor ( StrC destructor_def );
CodeEnum parse_enum ( StrC enum_def );
CodeBody parse_export_body ( StrC export_def );
CodeExtern parse_extern_link ( StrC exten_link_def );
CodeFriend parse_friend ( StrC friend_def );
CodeFn parse_function ( StrC fn_def );
CodeBody parse_global_body ( StrC body_def );
CodeNS parse_namespace ( StrC namespace_def );
CodeOperator parse_operator ( StrC operator_def );
CodeOpCast parse_operator_cast( StrC operator_def );
CodeStruct parse_struct ( StrC struct_def );
CodeTemplate parse_template ( StrC template_def );
CodeTypename parse_type ( StrC type_def );
CodeTypedef parse_typedef ( StrC typedef_def );
CodeUnion parse_union ( StrC union_def );
CodeUsing parse_using ( StrC using_def );
CodeVar parse_variable ( StrC var_def );
#pragma endregion Parsing
#pragma region Untyped text
ssize token_fmt_va( char* buf, usize buf_size, s32 num_tokens, va_list va );
//! Do not use directly. Use the token_fmt macro instead.
StrC token_fmt_impl( ssize, ... );
Code untyped_str ( StrC content);
Code untyped_fmt ( char const* fmt, ... );
Code untyped_token_fmt( s32 num_tokens, char const* fmt, ... );
#pragma endregion Untyped text
#pragma region Macros
#ifndef gen_main
#define gen_main main
#endif
#ifndef name
// Convienence for defining any name used with the gen api.
// Lets you provide the length and string literal to the functions without the need for the DSL.
#define name( Id_ ) { sizeof(stringize( Id_ )) - 1, stringize(Id_) }
#endif
#ifndef code
// Same as name just used to indicate intention of literal for code instead of names.
#define code( ... ) { sizeof(stringize(__VA_ARGS__)) - 1, stringize( __VA_ARGS__ ) }
#endif
#ifndef args
// Provides the number of arguments while passing args inplace.
#define args( ... ) num_args( __VA_ARGS__ ), __VA_ARGS__
#endif
#ifndef code_str
// Just wrappers over common untyped code definition constructions.
#define code_str( ... ) GEN_NS untyped_str( code( __VA_ARGS__ ) )
#endif
#ifndef code_fmt
#define code_fmt( ... ) GEN_NS untyped_str( token_fmt( __VA_ARGS__ ) )
#endif
#ifndef parse_fmt
#define parse_fmt( type, ... ) GEN_NS parse_##type( token_fmt( __VA_ARGS__ ) )
#endif
#ifndef token_fmt
/*
Takes a format string (char const*) and a list of tokens (StrC) and returns a StrC of the formatted string.
Tokens are provided in '<'identifier'>' format where '<' '>' are just angle brackets (you can change it in token_fmt_va)
---------------------------------------------------------
Example - A string with:
typedef <type> <name> <name>;
Will have a token_fmt arguments populated with:
"type", strc_for_type,
"name", strc_for_name,
and:
stringize( typedef <type> <name> <name>; )
-----------------------------------------------------------
So the full call for this example would be:
token_fmt(
"type", strc_for_type
, "name", strc_for_name
, stringize(
typedef <type> <name> <name>
));
!----------------------------------------------------------
! Note: token_fmt_va is whitespace sensitive for the tokens.
! This can be alleviated by skipping whitespace between brackets but it was choosen to not have that implementation by default.
*/
#define token_fmt( ... ) GEN_NS token_fmt_impl( (num_args( __VA_ARGS__ ) + 1) / 2, __VA_ARGS__ )
#endif
#pragma endregion Macros
#pragma endregion Gen Interface

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#ifdef GEN_INTELLISENSE_DIRECTIVES
#pragma once
#include "gen/etoktype.cpp"
#include "interface.upfront.cpp"
#include "lexer.cpp"
#include "parser.cpp"
#endif
// Publically Exposed Interface
CodeClass parse_class( StrC def )
{
GEN_USING_NS_PARSER;
check_parse_args( def );
TokArray toks = lex( def );
if ( toks.Arr == nullptr )
return InvalidCode;
Context.Tokens = toks;
push_scope();
CodeClass result = (CodeClass) parse_class_struct( Tok_Decl_Class, parser_not_inplace_def );
parser_pop(& Context);
return result;
}
CodeConstructor parse_constructor( StrC def )
{
GEN_USING_NS_PARSER;
check_parse_args( def );
TokArray toks = lex( def );
if ( toks.Arr == nullptr )
return InvalidCode;
// TODO(Ed): Constructors can have prefix attributes
CodeSpecifiers specifiers = NullCode;
Specifier specs_found[ 16 ] = { Spec_NumSpecifiers };
s32 NumSpecifiers = 0;
while ( left && tok_is_specifier(currtok) )
{
Specifier spec = strc_to_specifier( tok_to_str(currtok) );
b32 ignore_spec = false;
switch ( spec )
{
case Spec_Constexpr :
case Spec_Explicit:
case Spec_Inline :
case Spec_ForceInline :
case Spec_NeverInline :
break;
case Spec_Const :
ignore_spec = true;
break;
default :
log_failure( "Invalid specifier %s for variable\n%s", spec_to_str( spec ), parser_to_string(Context) );
parser_pop(& Context);
return InvalidCode;
}
// Every specifier after would be considered part of the type type signature
if (ignore_spec)
break;
specs_found[ NumSpecifiers ] = spec;
NumSpecifiers++;
eat( currtok.Type );
}
if ( NumSpecifiers )
{
specifiers = def_specifiers( NumSpecifiers, specs_found );
// <specifiers> ...
}
Context.Tokens = toks;
CodeConstructor result = parser_parse_constructor( specifiers );
return result;
}
CodeDestructor parse_destructor( StrC def )
{
GEN_USING_NS_PARSER;
check_parse_args( def );
TokArray toks = lex( def );
if ( toks.Arr == nullptr )
return InvalidCode;
// TODO(Ed): Destructors can have prefix attributes
// TODO(Ed): Destructors can have virtual
Context.Tokens = toks;
CodeDestructor result = parser_parse_destructor(NullCode);
return result;
}
CodeEnum parse_enum( StrC def )
{
GEN_USING_NS_PARSER;
check_parse_args( def );
TokArray toks = lex( def );
if ( toks.Arr == nullptr )
{
parser_pop(& Context);
return InvalidCode;
}
Context.Tokens = toks;
return parser_parse_enum( parser_not_inplace_def);
}
CodeBody parse_export_body( StrC def )
{
GEN_USING_NS_PARSER;
check_parse_args( def );
TokArray toks = lex( def );
if ( toks.Arr == nullptr )
return InvalidCode;
Context.Tokens = toks;
return parser_parse_export_body();
}
CodeExtern parse_extern_link( StrC def )
{
GEN_USING_NS_PARSER;
check_parse_args( def );
TokArray toks = lex( def );
if ( toks.Arr == nullptr )
return InvalidCode;
Context.Tokens = toks;
return parser_parse_extern_link();
}
CodeFriend parse_friend( StrC def )
{
GEN_USING_NS_PARSER;
check_parse_args( def );
TokArray toks = lex( def );
if ( toks.Arr == nullptr )
return InvalidCode;
Context.Tokens = toks;
return parser_parse_friend();
}
CodeFn parse_function( StrC def )
{
GEN_USING_NS_PARSER;
check_parse_args( def );
TokArray toks = lex( def );
if ( toks.Arr == nullptr )
return InvalidCode;
Context.Tokens = toks;
return (CodeFn) parser_parse_function();
}
CodeBody parse_global_body( StrC def )
{
GEN_USING_NS_PARSER;
check_parse_args( def );
TokArray toks = lex( def );
if ( toks.Arr == nullptr )
return InvalidCode;
Context.Tokens = toks;
push_scope();
CodeBody result = parse_global_nspace( CT_Global_Body );
parser_pop(& Context);
return result;
}
CodeNS parse_namespace( StrC def )
{
GEN_USING_NS_PARSER;
check_parse_args( def );
TokArray toks = lex( def );
if ( toks.Arr == nullptr )
return InvalidCode;
Context.Tokens = toks;
return parser_parse_namespace();
}
CodeOperator parse_operator( StrC def )
{
GEN_USING_NS_PARSER;
check_parse_args( def );
TokArray toks = lex( def );
if ( toks.Arr == nullptr )
return InvalidCode;
Context.Tokens = toks;
return (CodeOperator) parser_parse_operator();
}
CodeOpCast parse_operator_cast( StrC def )
{
GEN_USING_NS_PARSER;
check_parse_args( def );
TokArray toks = lex( def );
if ( toks.Arr == nullptr )
return InvalidCode;
Context.Tokens = toks;
return parser_parse_operator_cast(NullCode);
}
CodeStruct parse_struct( StrC def )
{
GEN_USING_NS_PARSER;
check_parse_args( def );
TokArray toks = lex( def );
if ( toks.Arr == nullptr )
return InvalidCode;
Context.Tokens = toks;
push_scope();
CodeStruct result = (CodeStruct) parse_class_struct( Tok_Decl_Struct, parser_not_inplace_def );
parser_pop(& Context);
return result;
}
CodeTemplate parse_template( StrC def )
{
GEN_USING_NS_PARSER;
check_parse_args( def );
TokArray toks = lex( def );
if ( toks.Arr == nullptr )
return InvalidCode;
Context.Tokens = toks;
return parser_parse_template();
}
CodeTypename parse_type( StrC def )
{
GEN_USING_NS_PARSER;
check_parse_args( def );
TokArray toks = lex( def );
if ( toks.Arr == nullptr )
return InvalidCode;
Context.Tokens = toks;
return parser_parse_type( parser_not_from_template, nullptr);
}
CodeTypedef parse_typedef( StrC def )
{
GEN_USING_NS_PARSER;
check_parse_args( def );
TokArray toks = lex( def );
if ( toks.Arr == nullptr )
return InvalidCode;
Context.Tokens = toks;
return parser_parse_typedef();
}
CodeUnion parse_union( StrC def )
{
GEN_USING_NS_PARSER;
check_parse_args( def );
TokArray toks = lex( def );
if ( toks.Arr == nullptr )
return InvalidCode;
Context.Tokens = toks;
return parser_parse_union( parser_not_inplace_def);
}
CodeUsing parse_using( StrC def )
{
GEN_USING_NS_PARSER;
check_parse_args( def );
TokArray toks = lex( def );
if ( toks.Arr == nullptr )
return InvalidCode;
Context.Tokens = toks;
return parser_parse_using();
}
CodeVar parse_variable( StrC def )
{
GEN_USING_NS_PARSER;
check_parse_args( def );
TokArray toks = lex( def );
if ( toks.Arr == nullptr )
return InvalidCode;
Context.Tokens = toks;
return parser_parse_variable();
}
// Undef helper macros
#undef check_parse_args
#undef currtok_noskip
#undef currtok
#undef peektok
#undef prevtok
#undef nexttok
#undef nexttok_noskip
#undef eat
#undef left
#undef check
#undef push_scope
#undef def_assign
// Here for C Variant
#undef lex_dont_skip_formatting
#undef lex_skip_formatting
#undef parser_inplace_def
#undef parser_not_inplace_def
#undef parser_dont_consume_braces
#undef parser_consume_braces
#undef parser_not_from_template
#undef parser_use_parenthesis
#undef parser_strip_formatting_dont_preserve_newlines

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#ifdef GEN_INTELLISENSE_DIRECTIVES
#pragma once
#include "interface.parsing.cpp"
#endif
ssize token_fmt_va( char* buf, usize buf_size, s32 num_tokens, va_list va )
{
char const* buf_begin = buf;
ssize remaining = buf_size;
local_persist
TokenMap_FixedArena tok_map_arena;
fixed_arena_init( & tok_map_arena);
local_persist
StringTable tok_map;
{
tok_map = hashtable_init(StrC, fixed_arena_allocator_info(& tok_map_arena) );
s32 left = num_tokens - 1;
while ( left-- )
{
char const* token = va_arg( va, char const* );
StrC value = va_arg( va, StrC );
u32 key = crc32( token, str_len(token) );
hashtable_set( tok_map, key, value );
}
}
char const* fmt = va_arg( va, char const* );
char current = *fmt;
while ( current )
{
ssize len = 0;
while ( current && current != '<' && remaining )
{
* buf = * fmt;
buf++;
fmt++;
remaining--;
current = * fmt;
}
if ( current == '<' )
{
char const* scanner = fmt + 1;
s32 tok_len = 0;
while ( *scanner != '>' )
{
tok_len++;
scanner++;
}
char const* token = fmt + 1;
u32 key = crc32( token, tok_len );
StrC* value = hashtable_get(tok_map, key );
if ( value )
{
ssize left = value->Len;
char const* str = value->Ptr;
while ( left-- )
{
* buf = * str;
buf++;
str++;
remaining--;
}
scanner++;
fmt = scanner;
current = * fmt;
continue;
}
* buf = * fmt;
buf++;
fmt++;
remaining--;
current = * fmt;
}
}
hashtable_clear(tok_map);
fixed_arena_free(& tok_map_arena);
ssize result = buf_size - remaining;
return result;
}
Code untyped_str( StrC content )
{
if ( content.Len == 0 )
{
log_failure( "untyped_str: empty string" );
return InvalidCode;
}
Code
result = make_code();
result->Name = get_cached_string( content );
result->Type = CT_Untyped;
result->Content = result->Name;
if ( result->Name.Len == 0 )
{
log_failure( "untyped_str: could not cache string" );
return InvalidCode;
}
return result;
}
Code untyped_fmt( char const* fmt, ...)
{
if ( fmt == nullptr )
{
log_failure( "untyped_fmt: null format string" );
return InvalidCode;
}
local_persist thread_local
char buf[GEN_PRINTF_MAXLEN] = { 0 };
va_list va;
va_start(va, fmt);
ssize length = str_fmt_va(buf, GEN_PRINTF_MAXLEN, fmt, va);
va_end(va);
StrC buf_str = { str_len_capped(fmt, MaxNameLength), fmt };
StrC uncapped_str = { length, buf };
Code
result = make_code();
result->Name = get_cached_string( buf_str );
result->Type = CT_Untyped;
result->Content = get_cached_string( uncapped_str );
if ( result->Name.Len == 0 )
{
log_failure( "untyped_fmt: could not cache string" );
return InvalidCode;
}
return result;
}
Code untyped_token_fmt( s32 num_tokens, char const* fmt, ... )
{
if ( num_tokens == 0 )
{
log_failure( "untyped_token_fmt: zero tokens" );
return InvalidCode;
}
local_persist thread_local
char buf[GEN_PRINTF_MAXLEN] = { 0 };
va_list va;
va_start(va, fmt);
ssize length = token_fmt_va(buf, GEN_PRINTF_MAXLEN, num_tokens, va);
va_end(va);
StrC buf_str = { length, buf };
Code
result = make_code();
result->Name = get_cached_string( buf_str );
result->Type = CT_Untyped;
result->Content = result->Name;
if ( result->Name.Len == 0 )
{
log_failure( "untyped_fmt: could not cache string" );
return InvalidCode;
}
return result;
}

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#if ! defined(GEN_DONT_ENFORCE_GEN_TIME_GUARD) && ! defined(GEN_TIME)
# error Gen.hpp : GEN_TIME not defined
#endif
#include "gen.hpp"
//! If its desired to roll your own dependencies, define GEN_ROLL_OWN_DEPENDENCIES before including this file.
//! Dependencies are derived from the c-zpl library: https://github.com/zpl-c/zpl
#ifndef GEN_ROLL_OWN_DEPENDENCIES
# include "gen.dep.cpp"
#endif

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#ifdef GEN_INTELLISENSE_DIRECTIVES
#pragma once
#include "../gen.hpp"
#endif
#pragma region StaticData
// TODO : Convert global allocation strategy to use a slab allocation strategy.
global AllocatorInfo GlobalAllocator;
global Array( Arena ) Global_AllocatorBuckets;
// TODO(Ed) : Make the code pool a dynamic arena
global Array( Pool ) CodePools = { nullptr };
global Array( Arena ) StringArenas = { nullptr };
global StringTable StringCache;
global Arena LexArena;
global AllocatorInfo Allocator_DataArrays = {0};
global AllocatorInfo Allocator_CodePool = {0};
global AllocatorInfo Allocator_Lexer = {0};
global AllocatorInfo Allocator_StringArena = {0};
global AllocatorInfo Allocator_StringTable = {0};
global AllocatorInfo Allocator_TypeTable = {0};
#pragma endregion StaticData
#pragma region Constants
global StrC enum_underlying_sig;
global Code access_public;
global Code access_protected;
global Code access_private;
global CodeAttributes attrib_api_export;
global CodeAttributes attrib_api_import;
global Code module_global_fragment;
global Code module_private_fragment;
global Code fmt_newline;
global CodeParams param_varadic;
global CodePragma pragma_once;
global CodePreprocessCond preprocess_else;
global CodePreprocessCond preprocess_endif;
global CodeSpecifiers spec_const;
global CodeSpecifiers spec_consteval;
global CodeSpecifiers spec_constexpr;
global CodeSpecifiers spec_constinit;
global CodeSpecifiers spec_extern_linkage;
global CodeSpecifiers spec_final;
global CodeSpecifiers spec_forceinline;
global CodeSpecifiers spec_global;
global CodeSpecifiers spec_inline;
global CodeSpecifiers spec_internal_linkage;
global CodeSpecifiers spec_local_persist;
global CodeSpecifiers spec_mutable;
global CodeSpecifiers spec_noexcept;
global CodeSpecifiers spec_neverinline;
global CodeSpecifiers spec_override;
global CodeSpecifiers spec_ptr;
global CodeSpecifiers spec_pure;
global CodeSpecifiers spec_ref;
global CodeSpecifiers spec_register;
global CodeSpecifiers spec_rvalue;
global CodeSpecifiers spec_static_member;
global CodeSpecifiers spec_thread_local;
global CodeSpecifiers spec_virtual;
global CodeSpecifiers spec_volatile;
global CodeTypename t_empty;
global CodeTypename t_auto;
global CodeTypename t_void;
global CodeTypename t_int;
global CodeTypename t_bool;
global CodeTypename t_char;
global CodeTypename t_wchar_t;
global CodeTypename t_class;
global CodeTypename t_typename;
global Array(StringCached) PreprocessorDefines;
#ifdef GEN_DEFINE_LIBRARY_CODE_CONSTANTS
global CodeTypename t_b32;
global CodeTypename t_s8;
global CodeTypename t_s16;
global CodeTypename t_s32;
global CodeTypename t_s64;
global CodeTypename t_u8;
global CodeTypename t_u16;
global CodeTypename t_u32;
global CodeTypename t_u64;
global CodeTypename t_ssize;
global CodeTypename t_usize;
global CodeTypename t_f32;
global CodeTypename t_f64;
#endif
#pragma endregion Constants

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#ifdef GEN_INTELLISENSE_DIRECTIVES
#pragma once
#include "header_start.hpp"
#endif
/*
________ __ __ ________
| \ | \ | \ | \
| ▓▓▓▓▓▓▓▓_______ __ __ ______ ____ _______ | ▓▓\ | ▓▓ \▓▓▓▓▓▓▓▓__ __ ______ ______ _______
| ▓▓__ | \| \ | \ \ \ / \ | ▓▓▓\| ▓▓ | ▓▓ | \ | \/ \ / \ / \
| ▓▓ \ | ▓▓▓▓▓▓▓\ ▓▓ | ▓▓ ▓▓▓▓▓▓\▓▓▓▓\ ▓▓▓▓▓▓▓ | ▓▓▓▓\ ▓▓ | ▓▓ | ▓▓ | ▓▓ ▓▓▓▓▓▓\ ▓▓▓▓▓▓\ ▓▓▓▓▓▓▓
| ▓▓▓▓▓ | ▓▓ | ▓▓ ▓▓ | ▓▓ ▓▓ | ▓▓ | ▓▓\▓▓ \ | ▓▓\▓▓ ▓▓ | ▓▓ | ▓▓ | ▓▓ ▓▓ | ▓▓ ▓▓ ▓▓\▓▓ \
| ▓▓_____| ▓▓ | ▓▓ ▓▓__/ ▓▓ ▓▓ | ▓▓ | ▓▓_\▓▓▓▓▓▓\ | ▓▓ \▓▓▓▓ | ▓▓ | ▓▓__/ ▓▓ ▓▓__/ ▓▓ ▓▓▓▓▓▓▓▓_\▓▓▓▓▓▓\
| ▓▓ \ ▓▓ | ▓▓\▓▓ ▓▓ ▓▓ | ▓▓ | ▓▓ ▓▓ | ▓▓ \▓▓▓ | ▓▓ \▓▓ ▓▓ ▓▓ ▓▓\▓▓ \ ▓▓
\▓▓▓▓▓▓▓▓\▓▓ \▓▓ \▓▓▓▓▓▓ \▓▓ \▓▓ \▓▓\▓▓▓▓▓▓▓ \▓▓ \▓▓ \▓▓ _\▓▓▓▓▓▓▓ ▓▓▓▓▓▓▓ \▓▓▓▓▓▓▓\▓▓▓▓▓▓▓
| \__| ▓▓ ▓▓
\▓▓ ▓▓ ▓▓
\▓▓▓▓▓▓ \▓▓
*/
using LogFailType = ssize(*)(char const*, ...);
// By default this library will either crash or exit if an error is detected while generating codes.
// Even if set to not use GEN_FATAL, GEN_FATAL will still be used for memory failures as the library is unusable when they occur.
#ifdef GEN_DONT_USE_FATAL
#define log_failure log_fmt
#else
#define log_failure GEN_FATAL
#endif
enum AccessSpec : u32
{
AccessSpec_Default,
AccessSpec_Private,
AccessSpec_Protected,
AccessSpec_Public,
AccessSpec_Num_AccessSpec,
AccessSpec_Invalid,
AccessSpec_SizeDef = GEN_U32_MAX,
};
static_assert( size_of(AccessSpec) == size_of(u32), "AccessSpec not u32 size" );
inline
StrC access_spec_to_str( AccessSpec type )
{
local_persist
StrC lookup[ (u32)AccessSpec_Num_AccessSpec ] = {
{ sizeof("") - 1, "" },
{ sizeof("prviate") - 1, "private" },
{ sizeof("protected") - 1, "private" },
{ sizeof("public") - 1, "public" },
};
StrC invalid = { sizeof("Invalid") - 1, "Invalid" };
if ( type > AccessSpec_Public )
return invalid;
return lookup[ (u32)type ];
}
enum CodeFlag : u32
{
CodeFlag_None = 0,
CodeFlag_FunctionType = bit(0),
CodeFlag_ParamPack = bit(1),
CodeFlag_Module_Export = bit(2),
CodeFlag_Module_Import = bit(3),
CodeFlag_SizeDef = GEN_U32_MAX,
};
static_assert( size_of(CodeFlag) == size_of(u32), "CodeFlag not u32 size" );
// Used to indicate if enum definitoin is an enum class or regular enum.
enum EnumDecl : u8
{
EnumDecl_Regular,
EnumDecl_Class,
EnumT_SizeDef = GEN_U8_MAX,
};
typedef u8 EnumT;
enum ModuleFlag : u32
{
ModuleFlag_None = 0,
ModuleFlag_Export = bit(0),
ModuleFlag_Import = bit(1),
Num_ModuleFlags,
ModuleFlag_Invalid,
ModuleFlag_SizeDef = GEN_U32_MAX,
};
static_assert( size_of(ModuleFlag) == size_of(u32), "ModuleFlag not u32 size" );
inline
StrC module_flag_to_str( ModuleFlag flag )
{
local_persist
StrC lookup[ (u32)Num_ModuleFlags ] = {
{ sizeof("__none__"), "__none__" },
{ sizeof("export"), "export" },
{ sizeof("import"), "import" },
};
local_persist
StrC invalid_flag = { sizeof("invalid"), "invalid" };
if ( flag > ModuleFlag_Import )
return invalid_flag;
return lookup[ (u32)flag ];
}
enum EPreprocessCond : u32
{
PreprocessCond_If,
PreprocessCond_IfDef,
PreprocessCond_IfNotDef,
PreprocessCond_ElIf,
EPreprocessCond_SizeDef = GEN_U32_MAX,
};
static_assert( size_of(EPreprocessCond) == size_of(u32), "EPreprocessCond not u32 size" );
enum ETypenameTag : u16
{
Tag_None,
Tag_Class,
Tag_Enum,
Tag_Struct,
Tag_Union,
Tag_UnderlyingType = GEN_U16_MAX,
};
static_assert( size_of(ETypenameTag) == size_of(u16), "ETypenameTag is not u16 size");

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#ifdef GEN_INTELLISENSE_DIRECTIVES
# pragma once
# include "macros.hpp"
#endif
#pragma region Basic Types
#define GEN_U8_MIN 0u
#define GEN_U8_MAX 0xffu
#define GEN_I8_MIN ( -0x7f - 1 )
#define GEN_I8_MAX 0x7f
#define GEN_U16_MIN 0u
#define GEN_U16_MAX 0xffffu
#define GEN_I16_MIN ( -0x7fff - 1 )
#define GEN_I16_MAX 0x7fff
#define GEN_U32_MIN 0u
#define GEN_U32_MAX 0xffffffffu
#define GEN_I32_MIN ( -0x7fffffff - 1 )
#define GEN_I32_MAX 0x7fffffff
#define GEN_U64_MIN 0ull
#define GEN_U64_MAX 0xffffffffffffffffull
#define GEN_I64_MIN ( -0x7fffffffffffffffll - 1 )
#define GEN_I64_MAX 0x7fffffffffffffffll
#if defined( GEN_ARCH_32_BIT )
# define GEN_USIZE_MIN GEN_U32_MIN
# define GEN_USIZE_MAX GEN_U32_MAX
# define GEN_ISIZE_MIN GEN_S32_MIN
# define GEN_ISIZE_MAX GEN_S32_MAX
#elif defined( GEN_ARCH_64_BIT )
# define GEN_USIZE_MIN GEN_U64_MIN
# define GEN_USIZE_MAX GEN_U64_MAX
# define GEN_ISIZE_MIN GEN_I64_MIN
# define GEN_ISIZE_MAX GEN_I64_MAX
#else
# error Unknown architecture size. This library only supports 32 bit and 64 bit architectures.
#endif
#define GEN_F32_MIN 1.17549435e-38f
#define GEN_F32_MAX 3.40282347e+38f
#define GEN_F64_MIN 2.2250738585072014e-308
#define GEN_F64_MAX 1.7976931348623157e+308
#if defined( GEN_COMPILER_MSVC )
# if _MSC_VER < 1300
typedef unsigned char u8;
typedef signed char s8;
typedef unsigned short u16;
typedef signed short s16;
typedef unsigned int u32;
typedef signed int s32;
# else
typedef unsigned __int8 u8;
typedef signed __int8 s8;
typedef unsigned __int16 u16;
typedef signed __int16 s16;
typedef unsigned __int32 u32;
typedef signed __int32 s32;
# endif
typedef unsigned __int64 u64;
typedef signed __int64 s64;
#else
# include <stdint.h>
typedef uint8_t u8;
typedef int8_t s8;
typedef uint16_t u16;
typedef int16_t s16;
typedef uint32_t u32;
typedef int32_t s32;
typedef uint64_t u64;
typedef int64_t s64;
#endif
static_assert( sizeof( u8 ) == sizeof( s8 ), "sizeof(u8) != sizeof(s8)" );
static_assert( sizeof( u16 ) == sizeof( s16 ), "sizeof(u16) != sizeof(s16)" );
static_assert( sizeof( u32 ) == sizeof( s32 ), "sizeof(u32) != sizeof(s32)" );
static_assert( sizeof( u64 ) == sizeof( s64 ), "sizeof(u64) != sizeof(s64)" );
static_assert( sizeof( u8 ) == 1, "sizeof(u8) != 1" );
static_assert( sizeof( u16 ) == 2, "sizeof(u16) != 2" );
static_assert( sizeof( u32 ) == 4, "sizeof(u32) != 4" );
static_assert( sizeof( u64 ) == 8, "sizeof(u64) != 8" );
typedef size_t usize;
typedef ptrdiff_t ssize;
static_assert( sizeof( usize ) == sizeof( ssize ), "sizeof(usize) != sizeof(ssize)" );
// NOTE: (u)zpl_intptr is only here for semantic reasons really as this library will only support 32/64 bit OSes.
#if defined( _WIN64 )
typedef signed __int64 sptr;
typedef unsigned __int64 uptr;
#elif defined( _WIN32 )
// NOTE; To mark types changing their size, e.g. zpl_intptr
# ifndef _W64
# if ! defined( __midl ) && ( defined( _X86_ ) || defined( _M_IX86 ) ) && _MSC_VER >= 1300
# define _W64 __w64
# else
# define _W64
# endif
# endif
typedef _W64 signed int sptr;
typedef _W64 unsigned int uptr;
#else
typedef uintptr_t uptr;
typedef intptr_t sptr;
#endif
static_assert( sizeof( uptr ) == sizeof( sptr ), "sizeof(uptr) != sizeof(sptr)" );
typedef float f32;
typedef double f64;
static_assert( sizeof( f32 ) == 4, "sizeof(f32) != 4" );
static_assert( sizeof( f64 ) == 8, "sizeof(f64) != 8" );
typedef s8 b8;
typedef s16 b16;
typedef s32 b32;
typedef void* mem_ptr;
typedef void const* mem_ptr_const ;
#if GEN_COMPILER_CPP
template<typename Type> uptr to_uptr( Type* ptr ) { return (uptr)ptr; }
template<typename Type> sptr to_sptr( Type* ptr ) { return (sptr)ptr; }
template<typename Type> mem_ptr to_mem_ptr ( Type ptr ) { return (mem_ptr) ptr; }
template<typename Type> mem_ptr_const to_mem_ptr_const( Type ptr ) { return (mem_ptr_const)ptr; }
#else
#define to_uptr( ptr ) ((uptr)(ptr))
#define to_sptr( ptr ) ((sptr)(ptr))
#define to_mem_ptr( ptr) ((mem_ptr)ptr)
#define to_mem_ptr_const( ptr) ((mem_ptr)ptr)
#endif
#pragma endregion Basic Types

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#ifdef GEN_INTELLISENSE_DIRECTIVES
# pragma once
# include "printing.hpp"
#endif
#pragma region Containers
template<class TType> struct RemoveConst { typedef TType Type; };
template<class TType> struct RemoveConst<const TType> { typedef TType Type; };
template<class TType> struct RemoveConst<const TType[]> { typedef TType Type[]; };
template<class TType, usize Size> struct RemoveConst<const TType[Size]> { typedef TType Type[Size]; };
template<class TType> using TRemoveConst = typename RemoveConst<TType>::Type;
template <class TType> struct RemovePtr { typedef TType Type; };
template <class TType> struct RemovePtr<TType*> { typedef TType Type; };
template <class TType> using TRemovePtr = typename RemovePtr<TType>::Type;
#pragma region Array
#define Array(Type) Array<Type>
// #define array_init(Type, ...) array_init <Type>(__VA_ARGS__)
// #define array_init_reserve(Type, ...) array_init_reserve<Type>(__VA_ARGS__)
struct ArrayHeader;
#if GEN_COMPILER_CPP
template<class Type> struct Array;
# define get_array_underlying_type(array) typename TRemovePtr<typeof(array)>:: DataType
#endif
usize array_grow_formula(ssize value);
template<class Type> Array<Type> array_init (AllocatorInfo allocator);
template<class Type> Array<Type> array_init_reserve (AllocatorInfo allocator, ssize capacity);
template<class Type> bool array_append_array (Array<Type>* array, Array<Type> other);
template<class Type> bool array_append (Array<Type>* array, Type value);
template<class Type> bool array_append_items (Array<Type>* array, Type* items, usize item_num);
template<class Type> bool array_append_at (Array<Type>* array, Type item, usize idx);
template<class Type> bool array_append_items_at(Array<Type>* array, Type* items, usize item_num, usize idx);
template<class Type> Type* array_back (Array<Type> array);
template<class Type> void array_clear (Array<Type> array);
template<class Type> bool array_fill (Array<Type> array, usize begin, usize end, Type value);
template<class Type> void array_free (Array<Type>* array);
template<class Type> bool arary_grow (Array<Type>* array, usize min_capacity);
template<class Type> usize array_num (Array<Type> array);
template<class Type> void arary_pop (Array<Type> array);
template<class Type> void arary_remove_at (Array<Type> array, usize idx);
template<class Type> bool arary_reserve (Array<Type>* array, usize new_capacity);
template<class Type> bool arary_resize (Array<Type>* array, usize num);
template<class Type> bool arary_set_capacity (Array<Type>* array, usize new_capacity);
template<class Type> ArrayHeader* arary_get_header (Array<Type> array);
struct ArrayHeader {
AllocatorInfo Allocator;
usize Capacity;
usize Num;
};
#if GEN_COMPILER_CPP
template<class Type>
struct Array
{
Type* Data;
#pragma region Member Mapping
forceinline static Array init(AllocatorInfo allocator) { return array_init<Type>(allocator); }
forceinline static Array init_reserve(AllocatorInfo allocator, ssize capacity) { return array_init_reserve<Type>(allocator, capacity); }
forceinline static usize grow_formula(ssize value) { return array_grow_formula<Type>(value); }
forceinline bool append(Array other) { return array_append_array<Type>(this, other); }
forceinline bool append(Type value) { return array_append<Type>(this, value); }
forceinline bool append(Type* items, usize item_num) { return array_append_items<Type>(this, items, item_num); }
forceinline bool append_at(Type item, usize idx) { return array_append_at<Type>(this, item, idx); }
forceinline bool append_at(Type* items, usize item_num, usize idx) { return array_append_items_at<Type>(this, items, item_num, idx); }
forceinline Type* back() { return array_back<Type>(* this); }
forceinline void clear() { array_clear<Type>(* this); }
forceinline bool fill(usize begin, usize end, Type value) { return array_fill<Type>(* this, begin, end, value); }
forceinline void free() { array_free<Type>(this); }
forceinline ArrayHeader* get_header() { return array_get_header<Type>(* this); }
forceinline bool grow(usize min_capacity) { return array_grow<Type>(this, min_capacity); }
forceinline usize num() { return array_num<Type>(*this); }
forceinline void pop() { array_pop<Type>(* this); }
forceinline void remove_at(usize idx) { array_remove_at<Type>(* this, idx); }
forceinline bool reserve(usize new_capacity) { return array_reserve<Type>(this, new_capacity); }
forceinline bool resize(usize num) { return array_resize<Type>(this, num); }
forceinline bool set_capacity(usize new_capacity) { return array_set_capacity<Type>(this, new_capacity); }
#pragma endregion Member Mapping
forceinline operator Type*() { return Data; }
forceinline operator Type const*() const { return Data; }
forceinline Type* begin() { return Data; }
forceinline Type* end() { return Data + get_header()->Num; }
forceinline Type& operator[](ssize index) { return Data[index]; }
forceinline Type const& operator[](ssize index) const { return Data[index]; }
using DataType = Type;
};
#endif
#if GEN_COMPILER_CPP && 0
template<class Type> bool append(Array<Type>& array, Array<Type> other) { return append( & array, other ); }
template<class Type> bool append(Array<Type>& array, Type value) { return append( & array, value ); }
template<class Type> bool append(Array<Type>& array, Type* items, usize item_num) { return append( & array, items, item_num ); }
template<class Type> bool append_at(Array<Type>& array, Type item, usize idx) { return append_at( & array, item, idx ); }
template<class Type> bool append_at(Array<Type>& array, Type* items, usize item_num, usize idx) { return append_at( & array, items, item_num, idx ); }
template<class Type> void free(Array<Type>& array) { return free( & array ); }
template<class Type> bool grow(Array<Type>& array, usize min_capacity) { return grow( & array, min_capacity); }
template<class Type> bool reserve(Array<Type>& array, usize new_capacity) { return reserve( & array, new_capacity); }
template<class Type> bool resize(Array<Type>& array, usize num) { return resize( & array, num); }
template<class Type> bool set_capacity(Array<Type>& array, usize new_capacity) { return set_capacity( & array, new_capacity); }
template<class Type> forceinline Type* begin(Array<Type>& array) { return array; }
template<class Type> forceinline Type* end(Array<Type>& array) { return array + array_get_header(array)->Num; }
template<class Type> forceinline Type* next(Array<Type>& array, Type* entry) { return entry + 1; }
#endif
template<class Type> forceinline Type* array_begin(Array<Type> array) { return array; }
template<class Type> forceinline Type* array_end(Array<Type> array) { return array + array_get_header(array)->Num; }
template<class Type> forceinline Type* array_next(Array<Type> array, Type* entry) { return ++ entry; }
template<class Type> inline
Array<Type> array_init(AllocatorInfo allocator) {
return array_init_reserve<Type>(allocator, array_grow_formula(0));
}
template<class Type> inline
Array<Type> array_init_reserve(AllocatorInfo allocator, ssize capacity)
{
GEN_ASSERT(capacity > 0);
ArrayHeader* header = rcast(ArrayHeader*, alloc(allocator, sizeof(ArrayHeader) + sizeof(Type) * capacity));
if (header == nullptr)
return {nullptr};
header->Allocator = allocator;
header->Capacity = capacity;
header->Num = 0;
return {rcast(Type*, header + 1)};
}
usize array_grow_formula(ssize value) {
return 2 * value + 8;
}
template<class Type> inline
bool array_append_array(Array<Type>* array, Array<Type> other) {
return array_append_items(array, (Type*)other, num(other));
}
template<class Type> inline
bool array_append(Array<Type>* array, Type value)
{
GEN_ASSERT( array != nullptr);
GEN_ASSERT(* array != nullptr);
ArrayHeader* header = array_get_header(* array);
if (header->Num == header->Capacity)
{
if ( ! array_grow(array, header->Capacity))
return false;
header = array_get_header(* array);
}
(*array)[ header->Num] = value;
header->Num++;
return true;
}
template<class Type> inline
bool array_append_items(Array<Type>* array, Type* items, usize item_num)
{
GEN_ASSERT( array != nullptr);
GEN_ASSERT(* array != nullptr);
GEN_ASSERT(items != nullptr);
GEN_ASSERT(item_num > 0);
ArrayHeader* header = array_get_header(array);
if (header->Num + item_num > header->Capacity)
{
if ( ! grow(array, header->Capacity + item_num))
return false;
header = array_get_header(array);
}
mem_copy((Type*)array + header->Num, items, item_num * sizeof(Type));
header->Num += item_num;
return true;
}
template<class Type> inline
bool array_append_at(Array<Type>* array, Type item, usize idx)
{
GEN_ASSERT( array != nullptr);
GEN_ASSERT(* array != nullptr);
ArrayHeader* header = array_get_header(* array);
ssize slot = idx;
if (slot >= header->Num)
slot = header->Num - 1;
if (slot < 0)
slot = 0;
if (header->Capacity < header->Num + 1)
{
if ( ! array_grow(array, header->Capacity + 1))
return false;
header = array_get_header(* array);
}
Type* target = &(*array)[slot];
mem_move(target + 1, target, (header->Num - slot) * sizeof(Type));
header->Num++;
return true;
}
template<class Type> inline
bool array_append_items_at(Array<Type>* array, Type* items, usize item_num, usize idx)
{
GEN_ASSERT( array != nullptr);
GEN_ASSERT(* array != nullptr);
ArrayHeader* header = get_header(array);
if (idx >= header->Num)
{
return array_append_items(array, items, item_num);
}
if (item_num > header->Capacity)
{
if (! grow(array, header->Capacity + item_num))
return false;
header = get_header(array);
}
Type* target = array.Data + idx + item_num;
Type* src = array.Data + idx;
mem_move(target, src, (header->Num - idx) * sizeof(Type));
mem_copy(src, items, item_num * sizeof(Type));
header->Num += item_num;
return true;
}
template<class Type> inline
Type* array_back(Array<Type> array)
{
GEN_ASSERT(array != nullptr);
ArrayHeader* header = array_get_header(array);
if (header->Num <= 0)
return nullptr;
return & (array)[header->Num - 1];
}
template<class Type> inline
void array_clear(Array<Type> array) {
GEN_ASSERT(array != nullptr);
ArrayHeader* header = array_get_header(array);
header->Num = 0;
}
template<class Type> inline
bool array_fill(Array<Type> array, usize begin, usize end, Type value)
{
GEN_ASSERT(array != nullptr);
GEN_ASSERT(begin <= end);
ArrayHeader* header = array_get_header(array);
if (begin < 0 || end > header->Num)
return false;
for (ssize idx = ssize(begin); idx < ssize(end); idx++)
{
array[idx] = value;
}
return true;
}
template<class Type> forceinline
void array_free(Array<Type>* array) {
GEN_ASSERT( array != nullptr);
GEN_ASSERT(* array != nullptr);
ArrayHeader* header = array_get_header(* array);
allocator_free(header->Allocator, header);
Type** Data = (Type**)array;
*Data = nullptr;
}
template<class Type> forceinline
ArrayHeader* array_get_header(Array<Type> array) {
GEN_ASSERT(array != nullptr);
Type* Data = array;
using NonConstType = TRemoveConst<Type>;
return rcast(ArrayHeader*, const_cast<NonConstType*>(Data)) - 1;
}
template<class Type> forceinline
bool array_grow(Array<Type>* array, usize min_capacity)
{
GEN_ASSERT( array != nullptr);
GEN_ASSERT(* array != nullptr);
GEN_ASSERT( min_capacity > 0 );
ArrayHeader* header = array_get_header(* array);
usize new_capacity = array_grow_formula(header->Capacity);
if (new_capacity < min_capacity)
new_capacity = min_capacity;
return array_set_capacity(array, new_capacity);
}
template<class Type> forceinline
usize array_num(Array<Type> array) {
GEN_ASSERT(array != nullptr);
return array_get_header(array)->Num;
}
template<class Type> forceinline
void array_pop(Array<Type> array) {
GEN_ASSERT(array != nullptr);
ArrayHeader* header = array_get_header(array);
GEN_ASSERT(header->Num > 0);
header->Num--;
}
template<class Type> inline
void array_remove_at(Array<Type> array, usize idx)
{
GEN_ASSERT(array != nullptr);
ArrayHeader* header = array_get_header(array);
GEN_ASSERT(idx < header->Num);
mem_move(array + idx, array + idx + 1, sizeof(Type) * (header->Num - idx - 1));
header->Num--;
}
template<class Type> inline
bool array_reserve(Array<Type>* array, usize new_capacity)
{
GEN_ASSERT( array != nullptr);
GEN_ASSERT(* array != nullptr);
GEN_ASSERT(num > 0)
ArrayHeader* header = array_get_header(array);
if (header->Capacity < new_capacity)
return set_capacity(array, new_capacity);
return true;
}
template<class Type> inline
bool array_resize(Array<Type>* array, usize num)
{
GEN_ASSERT( array != nullptr);
GEN_ASSERT(* array != nullptr);
ArrayHeader* header = array_get_header(* array);
if (header->Capacity < num) {
if (! array_grow( array, num))
return false;
header = array_get_header(* array);
}
header->Num = num;
return true;
}
template<class Type> inline
bool array_set_capacity(Array<Type>* array, usize new_capacity)
{
GEN_ASSERT( array != nullptr);
GEN_ASSERT(* array != nullptr);
ArrayHeader* header = array_get_header(* array);
if (new_capacity == header->Capacity)
return true;
if (new_capacity < header->Num)
{
header->Num = new_capacity;
return true;
}
ssize size = sizeof(ArrayHeader) + sizeof(Type) * new_capacity;
ArrayHeader* new_header = rcast(ArrayHeader*, alloc(header->Allocator, size));
if (new_header == nullptr)
return false;
mem_move(new_header, header, sizeof(ArrayHeader) + sizeof(Type) * header->Num);
new_header->Capacity = new_capacity;
allocator_free(header->Allocator, header);
Type** Data = (Type**)array;
* Data = rcast(Type*, new_header + 1);
return true;
}
// These are intended for use in the base library of gencpp and the C-variant of the library
// It provides a interoperability between the C++ and C implementation of arrays. (not letting these do any crazy substiution though)
// They are undefined in gen.hpp and gen.cpp at the end of the files.
// We cpp library expects the user to use the regular calls as they can resolve the type fine.
#define array_init(type, allocator) array_init <type> (allocator )
#define array_init_reserve(type, allocator, cap) array_init_reserve <type> (allocator, cap)
#define array_append_array(array, other) array_append_array < get_array_underlying_type(array) > (& array, other )
#define array_append(array, value) array_append < get_array_underlying_type(array) > (& array, value )
#define array_append_items(array, items, item_num) array_append_items < get_array_underlying_type(array) > (& array, items, item_num )
#define array_append_at(array, item, idx ) array_append_at < get_array_underlying_type(array) > (& array, item, idx )
#define array_append_at_items(array, items, item_num, idx) array_append_at_items< get_array_underlying_type(array) > (& items, item_num, idx )
#define array_back(array) array_back < get_array_underlying_type(array) > (array )
#define array_clear(array) array_clear < get_array_underlying_type(array) > (array )
#define array_fill(array, begin, end, value) array_fill < get_array_underlying_type(array) > (array, begin, end, value )
#define array_free(array) array_free < get_array_underlying_type(array) > (& array )
#define arary_grow(array, min_capacity) arary_grow < get_array_underlying_type(array) > (& array, min_capacity)
#define array_num(array) array_num < get_array_underlying_type(array) > (array )
#define arary_pop(array) arary_pop < get_array_underlying_type(array) > (array )
#define arary_remove_at(array, idx) arary_remove_at < get_array_underlying_type(array) > (idx)
#define arary_reserve(array, new_capacity) arary_reserve < get_array_underlying_type(array) > (& array, new_capacity )
#define arary_resize(array, num) arary_resize < get_array_underlying_type(array) > (& array, num)
#define arary_set_capacity(new_capacity) arary_set_capacity < get_array_underlying_type(array) > (& array, new_capacity )
#define arary_get_header(array) arary_get_header < get_array_underlying_type(array) > (array )
#pragma endregion Array
#pragma region HashTable
#define HashTable(Type) HashTable<Type>
template<class Type> struct HashTable;
#ifndef get_hashtable_underlying_type
#define get_hashtable_underlying_type(table) typename TRemovePtr<typeof(table)>:: DataType
#endif
struct HashTableFindResult {
ssize HashIndex;
ssize PrevIndex;
ssize EntryIndex;
};
template<class Type>
struct HashTableEntry {
u64 Key;
ssize Next;
Type Value;
};
#define HashTableEntry(Type) HashTableEntry<Type>
template<class Type> HashTable<Type> hashtable_init (AllocatorInfo allocator);
template<class Type> HashTable<Type> hashtable_init_reserve(AllocatorInfo allocator, usize num);
template<class Type> void hashtable_clear (HashTable<Type> table);
template<class Type> void hashtable_destroy (HashTable<Type>* table);
template<class Type> Type* hashtable_get (HashTable<Type> table, u64 key);
template<class Type> void hashtable_grow (HashTable<Type>* table);
template<class Type> void hashtable_rehash (HashTable<Type>* table, ssize new_num);
template<class Type> void hashtable_rehash_fast (HashTable<Type> table);
template<class Type> void hashtable_remove (HashTable<Type> table, u64 key);
template<class Type> void hashtable_remove_entry(HashTable<Type> table, ssize idx);
template<class Type> void hashtable_set (HashTable<Type>* table, u64 key, Type value);
template<class Type> ssize hashtable_slot (HashTable<Type> table, u64 key);
template<class Type> void hashtable_map (HashTable<Type> table, void (*map_proc)(u64 key, Type value));
template<class Type> void hashtable_map_mut (HashTable<Type> table, void (*map_proc)(u64 key, Type* value));
template<class Type> ssize hashtable__add_entry (HashTable<Type>* table, u64 key);
template<class Type> HashTableFindResult hashtable__find (HashTable<Type> table, u64 key);
template<class Type> bool hashtable__full (HashTable<Type> table);
static constexpr f32 HashTable_CriticalLoadScale = 0.7f;
template<typename Type>
struct HashTable
{
Array<ssize> Hashes;
Array<HashTableEntry<Type>> Entries;
#if ! GEN_C_LIKE_CPP
#pragma region Member Mapping
forceinline static HashTable init(AllocatorInfo allocator) { return hashtable_init<Type>(allocator); }
forceinline static HashTable init_reserve(AllocatorInfo allocator, usize num) { return hashtable_init_reserve<Type>(allocator, num); }
forceinline void clear() { clear<Type>(*this); }
forceinline void destroy() { destroy<Type>(*this); }
forceinline Type* get(u64 key) { return get<Type>(*this, key); }
forceinline void grow() { grow<Type>(*this); }
forceinline void rehash(ssize new_num) { rehash<Type>(*this, new_num); }
forceinline void rehash_fast() { rehash_fast<Type>(*this); }
forceinline void remove(u64 key) { remove<Type>(*this, key); }
forceinline void remove_entry(ssize idx) { remove_entry<Type>(*this, idx); }
forceinline void set(u64 key, Type value) { set<Type>(*this, key, value); }
forceinline ssize slot(u64 key) { return slot<Type>(*this, key); }
forceinline void map(void (*proc)(u64, Type)) { map<Type>(*this, proc); }
forceinline void map_mut(void (*proc)(u64, Type*)) { map_mut<Type>(*this, proc); }
#pragma endregion Member Mapping
#endif
using DataType = Type;
};
#if GEN_SUPPORT_CPP_REFERENCES
template<class Type> void destroy (HashTable<Type>& table) { destroy(& table); }
template<class Type> void grow (HashTable<Type>& table) { grow(& table); }
template<class Type> void rehash (HashTable<Type>& table, ssize new_num) { rehash(& table, new_num); }
template<class Type> void set (HashTable<Type>& table, u64 key, Type value) { set(& table, key, value); }
template<class Type> ssize add_entry(HashTable<Type>& table, u64 key) { add_entry(& table, key); }
#endif
template<typename Type> inline
HashTable<Type> hashtable_init(AllocatorInfo allocator) {
HashTable<Type> result = hashtable_init_reserve<Type>(allocator, 8);
return result;
}
template<typename Type> inline
HashTable<Type> hashtable_init_reserve(AllocatorInfo allocator, usize num)
{
HashTable<Type> result = { { nullptr }, { nullptr } };
result.Hashes = array_init_reserve<ssize>(allocator, num);
array_get_header(result.Hashes)->Num = num;
array_resize(& result.Hashes, num);
array_fill(result.Hashes, 0, num, (ssize)-1);
result.Entries = array_init_reserve<HashTableEntry<Type>>(allocator, num);
return result;
}
template<typename Type> forceinline
void hashtable_clear(HashTable<Type> table) {
GEN_ASSERT_NOT_NULL(table.Hashes);
GEN_ASSERT_NOT_NULL(table.Entries);
array_clear(table.Entries);
array_fill(table.Hashes, 0, array_num(table.Hashes), (ssize)-1);
}
template<typename Type> forceinline
void hashtable_destroy(HashTable<Type>* table) {
GEN_ASSERT_NOT_NULL(table->Hashes);
GEN_ASSERT_NOT_NULL(table->Entries);
if (table->Hashes && array_get_header(table->Hashes)->Capacity) {
array_free(table->Hashes);
array_free(table->Entries);
}
}
template<typename Type> forceinline
Type* hashtable_get(HashTable<Type> table, u64 key) {
GEN_ASSERT_NOT_NULL(table.Hashes);
GEN_ASSERT_NOT_NULL(table.Entries);
ssize idx = hashtable__find(table, key).EntryIndex;
if (idx >= 0)
return & table.Entries[idx].Value;
return nullptr;
}
template<typename Type> forceinline
void hashtable_map(HashTable<Type> table, void (*map_proc)(u64 key, Type value)) {
GEN_ASSERT_NOT_NULL(table.Hashes);
GEN_ASSERT_NOT_NULL(table.Entries);
GEN_ASSERT_NOT_NULL(map_proc);
for (ssize idx = 0; idx < ssize(num(table.Entries)); ++idx) {
map_proc(table.Entries[idx].Key, table.Entries[idx].Value);
}
}
template<typename Type> forceinline
void hashtable_map_mut(HashTable<Type> table, void (*map_proc)(u64 key, Type* value)) {
GEN_ASSERT_NOT_NULL(table.Hashes);
GEN_ASSERT_NOT_NULL(table.Entries);
GEN_ASSERT_NOT_NULL(map_proc);
for (ssize idx = 0; idx < ssize(num(table.Entries)); ++idx) {
map_proc(table.Entries[idx].Key, & table.Entries[idx].Value);
}
}
template<typename Type> forceinline
void hashtable_grow(HashTable<Type>* table) {
GEN_ASSERT_NOT_NULL(table);
GEN_ASSERT_NOT_NULL(table->Hashes);
GEN_ASSERT_NOT_NULL(table->Entries);
ssize new_num = array_grow_formula( array_num(table->Entries));
hashtable_rehash(table, new_num);
}
template<typename Type> inline
void hashtable_rehash(HashTable<Type>* table, ssize new_num)
{
GEN_ASSERT_NOT_NULL(table);
GEN_ASSERT_NOT_NULL(table->Hashes);
GEN_ASSERT_NOT_NULL(table->Entries);
ssize last_added_index;
HashTable<Type> new_ht = hashtable_init_reserve<Type>( array_get_header(table->Hashes)->Allocator, new_num);
for (ssize idx = 0; idx < ssize( array_num(table->Entries)); ++idx)
{
HashTableFindResult find_result;
HashTableEntry<Type>& entry = table->Entries[idx];
find_result = hashtable__find(new_ht, entry.Key);
last_added_index = hashtable__add_entry(& new_ht, entry.Key);
if (find_result.PrevIndex < 0)
new_ht.Hashes[find_result.HashIndex] = last_added_index;
else
new_ht.Entries[find_result.PrevIndex].Next = last_added_index;
new_ht.Entries[last_added_index].Next = find_result.EntryIndex;
new_ht.Entries[last_added_index].Value = entry.Value;
}
hashtable_destroy(table);
* table = new_ht;
}
template<typename Type> inline
void hashtable_rehash_fast(HashTable<Type> table)
{
GEN_ASSERT_NOT_NULL(table.Hashes);
GEN_ASSERT_NOT_NULL(table.Entries);
ssize idx;
for (idx = 0; idx < ssize(num(table.Entries)); idx++)
table.Entries[idx].Next = -1;
for (idx = 0; idx < ssize(num(table.Hashes)); idx++)
table.Hashes[idx] = -1;
for (idx = 0; idx < ssize(num(table.Entries)); idx++)
{
HashTableEntry<Type>* entry;
HashTableFindResult find_result;
entry = &table.Entries[idx];
find_result = find(table, entry->Key);
if (find_result.PrevIndex < 0)
table.Hashes[find_result.HashIndex] = idx;
else
table.Entries[find_result.PrevIndex].Next = idx;
}
}
template<typename Type> forceinline
void hashtable_remove(HashTable<Type> table, u64 key) {
GEN_ASSERT_NOT_NULL(table.Hashes);
GEN_ASSERT_NOT_NULL(table.Entries);
HashTableFindResult find_result = find(table, key);
if (find_result.EntryIndex >= 0) {
remove_at(table.Entries, find_result.EntryIndex);
rehash_fast(table);
}
}
template<typename Type> forceinline
void hashtable_remove_entry(HashTable<Type> table, ssize idx) {
GEN_ASSERT_NOT_NULL(table.Hashes);
GEN_ASSERT_NOT_NULL(table.Entries);
remove_at(table.Entries, idx);
}
template<typename Type> inline
void hashtable_set(HashTable<Type>* table, u64 key, Type value)
{
GEN_ASSERT_NOT_NULL(table);
GEN_ASSERT_NOT_NULL(table->Hashes);
GEN_ASSERT_NOT_NULL(table->Entries);
ssize idx;
HashTableFindResult find_result;
if (hashtable_full(* table))
hashtable_grow(table);
find_result = hashtable__find(* table, key);
if (find_result.EntryIndex >= 0) {
idx = find_result.EntryIndex;
}
else
{
idx = hashtable__add_entry(table, key);
if (find_result.PrevIndex >= 0) {
table->Entries[find_result.PrevIndex].Next = idx;
}
else {
table->Hashes[find_result.HashIndex] = idx;
}
}
table->Entries[idx].Value = value;
if (hashtable_full(* table))
hashtable_grow(table);
}
template<typename Type> forceinline
ssize hashtable_slot(HashTable<Type> table, u64 key) {
GEN_ASSERT_NOT_NULL(table.Hashes);
GEN_ASSERT_NOT_NULL(table.Entries);
for (ssize idx = 0; idx < ssize(num(table.Hashes)); ++idx)
if (table.Hashes[idx] == key)
return idx;
return -1;
}
template<typename Type> forceinline
ssize hashtable__add_entry(HashTable<Type>* table, u64 key) {
GEN_ASSERT_NOT_NULL(table);
GEN_ASSERT_NOT_NULL(table->Hashes);
GEN_ASSERT_NOT_NULL(table->Entries);
ssize idx;
HashTableEntry<Type> entry = { key, -1 };
idx = array_num(table->Entries);
array_append( table->Entries, entry);
return idx;
}
template<typename Type> inline
HashTableFindResult hashtable__find(HashTable<Type> table, u64 key)
{
GEN_ASSERT_NOT_NULL(table.Hashes);
GEN_ASSERT_NOT_NULL(table.Entries);
HashTableFindResult result = { -1, -1, -1 };
if (array_num(table.Hashes) > 0)
{
result.HashIndex = key % array_num(table.Hashes);
result.EntryIndex = table.Hashes[result.HashIndex];
while (result.EntryIndex >= 0)
{
if (table.Entries[result.EntryIndex].Key == key)
break;
result.PrevIndex = result.EntryIndex;
result.EntryIndex = table.Entries[result.EntryIndex].Next;
}
}
return result;
}
template<typename Type> forceinline
bool hashtable_full(HashTable<Type> table) {
GEN_ASSERT_NOT_NULL(table.Hashes);
GEN_ASSERT_NOT_NULL(table.Entries);
usize critical_load = usize(HashTable_CriticalLoadScale * f32(array_num(table.Hashes)));
b32 result = array_num(table.Entries) > critical_load;
return result;
}
#define hashtable_init(type, allocator) hashtable_init <type >(allocator)
#define hashtable_init_reserve(type, allocator, num) hashtable_init_reserve<type >(allocator, num)
#define hashtable_clear(table) hashtable_clear < get_hashtable_underlying_type(table) >(table)
#define hashtable_destroy(table) hashtable_destroy < get_hashtable_underlying_type(table) >(& table)
#define hashtable_get(table, key) hashtable_get < get_hashtable_underlying_type(table) >(table, key)
#define hashtable_grow(table) hashtable_grow < get_hashtable_underlying_type(table) >(& table)
#define hashtable_rehash(table, new_num) hashtable_rehash < get_hashtable_underlying_type(table) >(& table, new_num)
#define hashtable_rehash_fast(table) hashtable_rehash_fast < get_hashtable_underlying_type(table) >(table)
#define hashtable_remove(table, key) hashtable_remove < get_hashtable_underlying_type(table) >(table, key)
#define hashtable_remove_entry(table, idx) hashtable_remove_entry< get_hashtable_underlying_type(table) >(table, idx)
#define hashtable_set(table, key, value) hashtable_set < get_hashtable_underlying_type(table) >(& table, key, value)
#define hashtable_slot(table, key) hashtable_slot < get_hashtable_underlying_type(table) >(table, key)
#define hashtable_map(table, map_proc) hashtable_map < get_hashtable_underlying_type(table) >(table, map_proc)
#define hashtable_map_mut(table, map_proc) hashtable_map_mut < get_hashtable_underlying_type(table) >(table, map_proc)
//#define hashtable_add_entry(table, key) hashtable_add_entry < get_hashtable_underlying_type(table) >(& table, key)
//#define hashtable_find(table, key) hashtable_find < get_hashtable_underlying_type(table) >(table, key)
//#define hashtable_full(table) hashtable_full < get_hashtable_underlying_type(table) >(table)
#pragma endregion HashTable
#pragma endregion Containers

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#ifdef GEN_INTELLISENSE_DIRECTIVES
# pragma once
# include "src_start.cpp"
#endif
#pragma region Debug
void assert_handler( char const* condition, char const* file, char const* function, s32 line, char const* msg, ... )
{
_printf_err( "%s - %s:(%d): Assert Failure: ", file, function, line );
if ( condition )
_printf_err( "`%s` \n", condition );
if ( msg )
{
va_list va;
va_start( va, msg );
_printf_err_va( msg, va );
va_end( va );
}
_printf_err( "%s", "\n" );
}
s32 assert_crash( char const* condition )
{
GEN_PANIC( condition );
return 0;
}
#if defined( GEN_SYSTEM_WINDOWS )
void process_exit( u32 code )
{
ExitProcess( code );
}
#else
# include <stdlib.h>
void process_exit( u32 code )
{
exit( code );
}
#endif
#pragma endregion Debug

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#ifdef GEN_INTELLISENSE_DIRECTIVES
# pragma once
# include "dependencies/platform.hpp"
# include "dependencies/macros.hpp"
# include "basic_types.hpp"
# include "macros.hpp"
#endif
#pragma region Debug
#if defined( _MSC_VER )
# if _MSC_VER < 1300
# define GEN_DEBUG_TRAP() __asm int 3 /* Trap to debugger! */
# else
# define GEN_DEBUG_TRAP() __debugbreak()
# endif
#elif defined( GEN_COMPILER_TINYC )
# define GEN_DEBUG_TRAP() process_exit( 1 )
#else
# define GEN_DEBUG_TRAP() __builtin_trap()
#endif
#define GEN_ASSERT( cond ) GEN_ASSERT_MSG( cond, NULL )
#define GEN_ASSERT_MSG( cond, msg, ... ) \
do \
{ \
if ( ! ( cond ) ) \
{ \
assert_handler( #cond, __FILE__, __func__, scast( s64, __LINE__ ), msg, ##__VA_ARGS__ ); \
GEN_DEBUG_TRAP(); \
} \
} while ( 0 )
#define GEN_ASSERT_NOT_NULL( ptr ) GEN_ASSERT_MSG( ( ptr ) != NULL, #ptr " must not be NULL" )
// NOTE: Things that shouldn't happen with a message!
#define GEN_PANIC( msg, ... ) GEN_ASSERT_MSG( 0, msg, ##__VA_ARGS__ )
#if Build_Debug
#define GEN_FATAL( ... ) \
do \
{ \
local_persist thread_local \
char buf[GEN_PRINTF_MAXLEN] = { 0 }; \
\
str_fmt(buf, GEN_PRINTF_MAXLEN, __VA_ARGS__); \
GEN_PANIC(buf); \
} \
while (0)
#else
# define GEN_FATAL( ... ) \
do \
{ \
str_fmt_out_err( __VA_ARGS__ ); \
process_exit(1); \
} \
while (0)
#endif
void assert_handler( char const* condition, char const* file, char const* function, s32 line, char const* msg, ... );
s32 assert_crash( char const* condition );
void process_exit( u32 code );
#pragma endregion Debug

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#ifdef GEN_INTELLISENSE_DIRECTIVES
# pragma once
# include "strings.cpp"
#endif
#pragma region File Handling
#if defined( GEN_SYSTEM_WINDOWS ) || defined( GEN_SYSTEM_CYGWIN )
internal
wchar_t* _alloc_utf8_to_ucs2( AllocatorInfo a, char const* text, ssize* w_len_ )
{
wchar_t* w_text = NULL;
ssize len = 0, w_len = 0, w_len1 = 0;
if ( text == NULL )
{
if ( w_len_ )
*w_len_ = w_len;
return NULL;
}
len = str_len( text );
if ( len == 0 )
{
if ( w_len_ )
*w_len_ = w_len;
return NULL;
}
w_len = MultiByteToWideChar( CP_UTF8, MB_ERR_INVALID_CHARS, text, scast( int, len), NULL, 0 );
if ( w_len == 0 )
{
if ( w_len_ )
*w_len_ = w_len;
return NULL;
}
w_text = alloc_array( a, wchar_t, w_len + 1 );
w_len1 = MultiByteToWideChar( CP_UTF8, MB_ERR_INVALID_CHARS, text, scast( int, len), w_text, scast( int, w_len) );
if ( w_len1 == 0 )
{
allocator_free( a, w_text );
if ( w_len_ )
*w_len_ = 0;
return NULL;
}
w_text[ w_len ] = 0;
if ( w_len_ )
*w_len_ = w_len;
return w_text;
}
internal
GEN_FILE_SEEK_PROC( _win32_file_seek )
{
LARGE_INTEGER li_offset;
li_offset.QuadPart = offset;
if ( ! SetFilePointerEx( fd.p, li_offset, &li_offset, whence ) )
{
return false;
}
if ( new_offset )
*new_offset = li_offset.QuadPart;
return true;
}
internal
GEN_FILE_READ_AT_PROC( _win32_file_read )
{
// unused( stop_at_newline );
b32 result = false;
_win32_file_seek( fd, offset, ESeekWhence_BEGIN, NULL );
DWORD size_ = scast( DWORD, ( size > GEN_I32_MAX ? GEN_I32_MAX : size ));
DWORD bytes_read_;
if ( ReadFile( fd.p, buffer, size_, &bytes_read_, NULL ) )
{
if ( bytes_read )
*bytes_read = bytes_read_;
result = true;
}
return result;
}
internal
GEN_FILE_WRITE_AT_PROC( _win32_file_write )
{
DWORD size_ = scast( DWORD, ( size > GEN_I32_MAX ? GEN_I32_MAX : size ));
DWORD bytes_written_;
_win32_file_seek( fd, offset, ESeekWhence_BEGIN, NULL );
if ( WriteFile( fd.p, buffer, size_, &bytes_written_, NULL ) )
{
if ( bytes_written )
*bytes_written = bytes_written_;
return true;
}
return false;
}
internal
GEN_FILE_CLOSE_PROC( _win32_file_close )
{
CloseHandle( fd.p );
}
FileOperations const default_file_operations = { _win32_file_read, _win32_file_write, _win32_file_seek, _win32_file_close };
neverinline
GEN_FILE_OPEN_PROC( _win32_file_open )
{
DWORD desired_access;
DWORD creation_disposition;
void* handle;
wchar_t* w_text;
switch ( mode & GEN_FILE_MODES )
{
case EFileMode_READ :
desired_access = GENERIC_READ;
creation_disposition = OPEN_EXISTING;
break;
case EFileMode_WRITE :
desired_access = GENERIC_WRITE;
creation_disposition = CREATE_ALWAYS;
break;
case EFileMode_APPEND :
desired_access = GENERIC_WRITE;
creation_disposition = OPEN_ALWAYS;
break;
case EFileMode_READ | EFileMode_RW :
desired_access = GENERIC_READ | GENERIC_WRITE;
creation_disposition = OPEN_EXISTING;
break;
case EFileMode_WRITE | EFileMode_RW :
desired_access = GENERIC_READ | GENERIC_WRITE;
creation_disposition = CREATE_ALWAYS;
break;
case EFileMode_APPEND | EFileMode_RW :
desired_access = GENERIC_READ | GENERIC_WRITE;
creation_disposition = OPEN_ALWAYS;
break;
default :
GEN_PANIC( "Invalid file mode" );
return EFileError_INVALID;
}
w_text = _alloc_utf8_to_ucs2( heap(), filename, NULL );
handle = CreateFileW( w_text, desired_access, FILE_SHARE_READ | FILE_SHARE_DELETE, NULL, creation_disposition, FILE_ATTRIBUTE_NORMAL, NULL );
allocator_free( heap(), w_text );
if ( handle == INVALID_HANDLE_VALUE )
{
DWORD err = GetLastError();
switch ( err )
{
case ERROR_FILE_NOT_FOUND :
return EFileError_NOT_EXISTS;
case ERROR_FILE_EXISTS :
return EFileError_EXISTS;
case ERROR_ALREADY_EXISTS :
return EFileError_EXISTS;
case ERROR_ACCESS_DENIED :
return EFileError_PERMISSION;
}
return EFileError_INVALID;
}
if ( mode & EFileMode_APPEND )
{
LARGE_INTEGER offset = { { 0 } };
if ( ! SetFilePointerEx( handle, offset, NULL, ESeekWhence_END ) )
{
CloseHandle( handle );
return EFileError_INVALID;
}
}
fd->p = handle;
*ops = default_file_operations;
return EFileError_NONE;
}
#else // POSIX
# include <fcntl.h>
internal
GEN_FILE_SEEK_PROC( _posix_file_seek )
{
# if defined( GEN_SYSTEM_OSX )
s64 res = lseek( fd.i, offset, whence );
# else // TODO(ZaKlaus): @fixme lseek64
s64 res = lseek( fd.i, offset, whence );
# endif
if ( res < 0 )
return false;
if ( new_offset )
*new_offset = res;
return true;
}
internal
GEN_FILE_READ_AT_PROC( _posix_file_read )
{
unused( stop_at_newline );
ssize res = pread( fd.i, buffer, size, offset );
if ( res < 0 )
return false;
if ( bytes_read )
*bytes_read = res;
return true;
}
internal
GEN_FILE_WRITE_AT_PROC( _posix_file_write )
{
ssize res;
s64 curr_offset = 0;
_posix_file_seek( fd, 0, ESeekWhence_CURRENT, &curr_offset );
if ( curr_offset == offset )
{
// NOTE: Writing to stdout et al. doesn't like pwrite for numerous reasons
res = write( scast( int, fd.i), buffer, size );
}
else
{
res = pwrite( scast( int, fd.i), buffer, size, offset );
}
if ( res < 0 )
return false;
if ( bytes_written )
*bytes_written = res;
return true;
}
internal
GEN_FILE_CLOSE_PROC( _posix_file_close )
{
close( fd.i );
}
FileOperations const default_file_operations = { _posix_file_read, _posix_file_write, _posix_file_seek, _posix_file_close };
neverinline
GEN_FILE_OPEN_PROC( _posix_file_open )
{
s32 os_mode;
switch ( mode & GEN_FILE_MODES )
{
case EFileMode_READ :
os_mode = O_RDONLY;
break;
case EFileMode_WRITE :
os_mode = O_WRONLY | O_CREAT | O_TRUNC;
break;
case EFileMode_APPEND :
os_mode = O_WRONLY | O_APPEND | O_CREAT;
break;
case EFileMode_READ | EFileMode_RW :
os_mode = O_RDWR;
break;
case EFileMode_WRITE | EFileMode_RW :
os_mode = O_RDWR | O_CREAT | O_TRUNC;
break;
case EFileMode_APPEND | EFileMode_RW :
os_mode = O_RDWR | O_APPEND | O_CREAT;
break;
default :
GEN_PANIC( "Invalid file mode" );
return EFileError_INVALID;
}
fd->i = open( filename, os_mode, S_IRUSR | S_IWUSR | S_IRGRP | S_IWGRP | S_IROTH | S_IWOTH );
if ( fd->i < 0 )
{
// TODO : More file errors
return EFileError_INVALID;
}
*ops = default_file_operations;
return EFileError_NONE;
}
// POSIX
#endif
internal void _dirinfo_free_entry( DirEntry* entry );
// TODO : Is this a bad idea?
global b32 _std_file_set = false;
global FileInfo _std_files[ EFileStandard_COUNT ] = {
{
{ nullptr, nullptr, nullptr, nullptr },
{ nullptr },
0,
nullptr,
0,
nullptr
} };
#if defined( GEN_SYSTEM_WINDOWS ) || defined( GEN_SYSTEM_CYGWIN )
FileInfo* file_get_standard( FileStandardType std )
{
if ( ! _std_file_set )
{
# define GEN__SET_STD_FILE( type, v ) \
_std_files[ type ].fd.p = v; \
_std_files[ type ].ops = default_file_operations
GEN__SET_STD_FILE( EFileStandard_INPUT, GetStdHandle( STD_INPUT_HANDLE ) );
GEN__SET_STD_FILE( EFileStandard_OUTPUT, GetStdHandle( STD_OUTPUT_HANDLE ) );
GEN__SET_STD_FILE( EFileStandard_ERROR, GetStdHandle( STD_ERROR_HANDLE ) );
# undef GEN__SET_STD_FILE
_std_file_set = true;
}
return &_std_files[ std ];
}
#else // POSIX
FileInfo* file_get_standard( FileStandardType std )
{
if ( ! _std_file_set )
{
# define GEN__SET_STD_FILE( type, v ) \
_std_files[ type ].fd.i = v; \
_std_files[ type ].ops = default_file_operations
GEN__SET_STD_FILE( EFileStandard_INPUT, 0 );
GEN__SET_STD_FILE( EFileStandard_OUTPUT, 1 );
GEN__SET_STD_FILE( EFileStandard_ERROR, 2 );
# undef GEN__SET_STD_FILE
_std_file_set = true;
}
return &_std_files[ std ];
}
#endif
FileError file_close( FileInfo* f )
{
if ( ! f )
return EFileError_INVALID;
if ( f->filename )
allocator_free( heap(), ccast( char*, f->filename ));
#if defined( GEN_SYSTEM_WINDOWS )
if ( f->fd.p == INVALID_HANDLE_VALUE )
return EFileError_INVALID;
#else
if ( f->fd.i < 0 )
return EFileError_INVALID;
#endif
if ( f->is_temp )
{
f->ops.close( f->fd );
return EFileError_NONE;
}
if ( ! f->ops.read_at )
f->ops = default_file_operations;
f->ops.close( f->fd );
#if 0
if ( f->Dir )
{
_dirinfo_free_entry( f->Dir );
mfree( f->Dir );
f->Dir = NULL;
}
#endif
return EFileError_NONE;
}
FileError file_new( FileInfo* f, FileDescriptor fd, FileOperations ops, char const* filename )
{
FileError err = EFileError_NONE;
ssize len = str_len( filename );
f->ops = ops;
f->fd = fd;
f->dir = nullptr;
f->last_write_time = 0;
f->filename = alloc_array( heap(), char, len + 1 );
mem_copy( ccast( char*, f->filename), ccast( char*, filename), len + 1 );
return err;
}
FileError file_open( FileInfo* f, char const* filename )
{
return file_open_mode( f, EFileMode_READ, filename );
}
FileError file_open_mode( FileInfo* f, FileMode mode, char const* filename )
{
FileInfo file_ =
{
{ nullptr, nullptr, nullptr, nullptr },
{ nullptr },
0,
nullptr,
0,
nullptr
};
*f = file_;
FileError err;
#if defined( GEN_SYSTEM_WINDOWS ) || defined( GEN_SYSTEM_CYGWIN )
err = _win32_file_open( &f->fd, &f->ops, mode, filename );
#else
err = _posix_file_open( &f->fd, &f->ops, mode, filename );
#endif
if ( err == EFileError_NONE )
return file_new( f, f->fd, f->ops, filename );
return err;
}
s64 file_size( FileInfo* f )
{
s64 size = 0;
s64 prev_offset = file_tell( f );
file_seek_to_end( f );
size = file_tell( f );
file_seek( f, prev_offset );
return size;
}
FileContents file_read_contents( AllocatorInfo a, b32 zero_terminate, char const* filepath )
{
FileContents result;
FileInfo file ;
result.allocator = a;
if ( file_open( &file, filepath ) == EFileError_NONE )
{
ssize fsize = scast( ssize , file_size( &file ));
if ( fsize > 0 )
{
result.data = alloc( a, zero_terminate ? fsize + 1 : fsize );
result.size = fsize;
file_read_at( &file, result.data, result.size, 0 );
if ( zero_terminate )
{
u8* str = rcast( u8*, result.data);
str[ fsize ] = '\0';
}
}
file_close( &file );
}
return result;
}
typedef struct _memory_fd _memory_fd;
struct _memory_fd
{
u8 magic;
u8* buf; //< zpl_array OR plain buffer if we can't write
ssize cursor;
AllocatorInfo allocator;
FileStreamFlags flags;
ssize cap;
};
#define GEN__FILE_STREAM_FD_MAGIC 37
FileDescriptor _file_stream_fd_make( _memory_fd* d );
_memory_fd* _file_stream_from_fd( FileDescriptor fd );
inline
FileDescriptor _file_stream_fd_make( _memory_fd* d )
{
FileDescriptor fd = { 0 };
fd.p = ( void* )d;
return fd;
}
inline
_memory_fd* _file_stream_from_fd( FileDescriptor fd )
{
_memory_fd* d = ( _memory_fd* )fd.p;
GEN_ASSERT( d->magic == GEN__FILE_STREAM_FD_MAGIC );
return d;
}
b8 file_stream_new( FileInfo* file, AllocatorInfo allocator )
{
GEN_ASSERT_NOT_NULL( file );
_memory_fd* d = ( _memory_fd* )alloc( allocator, size_of( _memory_fd ) );
if ( ! d )
return false;
zero_item( file );
d->magic = GEN__FILE_STREAM_FD_MAGIC;
d->allocator = allocator;
d->flags = EFileStream_CLONE_WRITABLE;
d->cap = 0;
d->buf = array_init( u8, allocator );
if ( ! d->buf )
return false;
file->ops = memory_file_operations;
file->fd = _file_stream_fd_make( d );
file->dir = NULL;
file->last_write_time = 0;
file->filename = NULL;
file->is_temp = true;
return true;
}
b8 file_stream_open( FileInfo* file, AllocatorInfo allocator, u8* buffer, ssize size, FileStreamFlags flags )
{
GEN_ASSERT_NOT_NULL( file );
_memory_fd* d = ( _memory_fd* )alloc( allocator, size_of( _memory_fd ) );
if ( ! d )
return false;
zero_item( file );
d->magic = GEN__FILE_STREAM_FD_MAGIC;
d->allocator = allocator;
d->flags = flags;
if ( d->flags & EFileStream_CLONE_WRITABLE )
{
Array(u8) arr = array_init_reserve(u8, allocator, size );
d->buf = arr;
if ( ! d->buf )
return false;
mem_copy( d->buf, buffer, size );
d->cap = size;
array_get_header(arr)->Num = size;
}
else
{
d->buf = buffer;
d->cap = size;
}
file->ops = memory_file_operations;
file->fd = _file_stream_fd_make( d );
file->dir = NULL;
file->last_write_time = 0;
file->filename = NULL;
file->is_temp = true;
return true;
}
u8* file_stream_buf( FileInfo* file, ssize* size )
{
GEN_ASSERT_NOT_NULL( file );
_memory_fd* d = _file_stream_from_fd( file->fd );
if ( size )
*size = d->cap;
return d->buf;
}
internal
GEN_FILE_SEEK_PROC( _memory_file_seek )
{
_memory_fd* d = _file_stream_from_fd( fd );
ssize buflen = d->cap;
if ( whence == ESeekWhence_BEGIN )
d->cursor = 0;
else if ( whence == ESeekWhence_END )
d->cursor = buflen;
d->cursor = max( 0, clamp( d->cursor + offset, 0, buflen ) );
if ( new_offset )
*new_offset = d->cursor;
return true;
}
internal
GEN_FILE_READ_AT_PROC( _memory_file_read )
{
// unused( stop_at_newline );
_memory_fd* d = _file_stream_from_fd( fd );
mem_copy( buffer, d->buf + offset, size );
if ( bytes_read )
*bytes_read = size;
return true;
}
internal
GEN_FILE_WRITE_AT_PROC( _memory_file_write )
{
_memory_fd* d = _file_stream_from_fd( fd );
if ( ! ( d->flags & ( EFileStream_CLONE_WRITABLE | EFileStream_WRITABLE ) ) )
return false;
ssize buflen = d->cap;
ssize extralen = max( 0, size - ( buflen - offset ) );
ssize rwlen = size - extralen;
ssize new_cap = buflen + extralen;
if ( d->flags & EFileStream_CLONE_WRITABLE )
{
Array(u8) arr = { d->buf };
if ( array_get_header(arr)->Capacity < scast(usize, new_cap) )
{
if ( ! array_grow( & arr, ( s64 )( new_cap ) ) )
return false;
d->buf = arr;
}
}
mem_copy( d->buf + offset, buffer, rwlen );
if ( ( d->flags & EFileStream_CLONE_WRITABLE ) && extralen > 0 )
{
Array(u8) arr = { d->buf };
mem_copy( d->buf + offset + rwlen, pointer_add_const( buffer, rwlen ), extralen );
d->cap = new_cap;
array_get_header(arr)->Capacity = new_cap;
}
else
{
extralen = 0;
}
if ( bytes_written )
*bytes_written = ( rwlen + extralen );
return true;
}
internal
GEN_FILE_CLOSE_PROC( _memory_file_close )
{
_memory_fd* d = _file_stream_from_fd( fd );
AllocatorInfo allocator = d->allocator;
if ( d->flags & EFileStream_CLONE_WRITABLE )
{
Array(u8) arr = { d->buf };
array_free(arr);
}
allocator_free( allocator, d );
}
FileOperations const memory_file_operations = { _memory_file_read, _memory_file_write, _memory_file_seek, _memory_file_close };
#pragma endregion File Handling

386
base/dependencies/filesystem.hpp Normal file
View File

@ -0,0 +1,386 @@
#ifdef GEN_INTELLISENSE_DIRECTIVES
# pragma once
# include "strings.hpp"
#endif
#pragma region File Handling
enum FileModeFlag
{
EFileMode_READ = bit( 0 ),
EFileMode_WRITE = bit( 1 ),
EFileMode_APPEND = bit( 2 ),
EFileMode_RW = bit( 3 ),
GEN_FILE_MODES = EFileMode_READ | EFileMode_WRITE | EFileMode_APPEND | EFileMode_RW,
};
// NOTE: Only used internally and for the file operations
enum SeekWhenceType
{
ESeekWhence_BEGIN = 0,
ESeekWhence_CURRENT = 1,
ESeekWhence_END = 2,
};
enum FileError
{
EFileError_NONE,
EFileError_INVALID,
EFileError_INVALID_FILENAME,
EFileError_EXISTS,
EFileError_NOT_EXISTS,
EFileError_PERMISSION,
EFileError_TRUNCATION_FAILURE,
EFileError_NOT_EMPTY,
EFileError_NAME_TOO_LONG,
EFileError_UNKNOWN,
};
union FileDescriptor
{
void* p;
sptr i;
uptr u;
};
typedef u32 FileMode;
typedef struct FileOperations FileOperations;
#define GEN_FILE_OPEN_PROC( name ) FileError name( FileDescriptor* fd, FileOperations* ops, FileMode mode, char const* filename )
#define GEN_FILE_READ_AT_PROC( name ) b32 name( FileDescriptor fd, void* buffer, ssize size, s64 offset, ssize* bytes_read, b32 stop_at_newline )
#define GEN_FILE_WRITE_AT_PROC( name ) b32 name( FileDescriptor fd, mem_ptr_const buffer, ssize size, s64 offset, ssize* bytes_written )
#define GEN_FILE_SEEK_PROC( name ) b32 name( FileDescriptor fd, s64 offset, SeekWhenceType whence, s64* new_offset )
#define GEN_FILE_CLOSE_PROC( name ) void name( FileDescriptor fd )
typedef GEN_FILE_OPEN_PROC( file_open_proc );
typedef GEN_FILE_READ_AT_PROC( FileReadProc );
typedef GEN_FILE_WRITE_AT_PROC( FileWriteProc );
typedef GEN_FILE_SEEK_PROC( FileSeekProc );
typedef GEN_FILE_CLOSE_PROC( FileCloseProc );
struct FileOperations
{
FileReadProc* read_at;
FileWriteProc* write_at;
FileSeekProc* seek;
FileCloseProc* close;
};
extern FileOperations const default_file_operations;
typedef u64 FileTime;
enum DirType
{
GEN_DIR_TYPE_FILE,
GEN_DIR_TYPE_FOLDER,
GEN_DIR_TYPE_UNKNOWN,
};
struct DirInfo;
struct DirEntry
{
char const* filename;
DirInfo* dir_info;
u8 type;
};
struct DirInfo
{
char const* fullpath;
DirEntry* entries; // zpl_array
// Internals
char** filenames; // zpl_array
String buf;
};
struct FileInfo
{
FileOperations ops;
FileDescriptor fd;
b32 is_temp;
char const* filename;
FileTime last_write_time;
DirEntry* dir;
};
enum FileStandardType
{
EFileStandard_INPUT,
EFileStandard_OUTPUT,
EFileStandard_ERROR,
EFileStandard_COUNT,
};
/**
* Get standard file I/O.
* @param std Check zpl_file_standard_type
* @return File handle to standard I/O
*/
FileInfo* file_get_standard( FileStandardType std );
/**
* Closes the file
* @param file
*/
FileError file_close( FileInfo* file );
/**
* Returns the currently opened file's name
* @param file
*/
inline
char const* file_name( FileInfo* file )
{
return file->filename ? file->filename : "";
}
/**
* Opens a file
* @param file
* @param filename
*/
FileError file_open( FileInfo* file, char const* filename );
/**
* Opens a file using a specified mode
* @param file
* @param mode Access mode to use
* @param filename
*/
FileError file_open_mode( FileInfo* file, FileMode mode, char const* filename );
/**
* Reads from a file
* @param file
* @param buffer Buffer to read to
* @param size Size to read
*/
b32 file_read( FileInfo* file, void* buffer, ssize size );
/**
* Reads file at a specific offset
* @param file
* @param buffer Buffer to read to
* @param size Size to read
* @param offset Offset to read from
* @param bytes_read How much data we've actually read
*/
b32 file_read_at( FileInfo* file, void* buffer, ssize size, s64 offset );
/**
* Reads file safely
* @param file
* @param buffer Buffer to read to
* @param size Size to read
* @param offset Offset to read from
* @param bytes_read How much data we've actually read
*/
b32 file_read_at_check( FileInfo* file, void* buffer, ssize size, s64 offset, ssize* bytes_read );
typedef struct FileContents FileContents;
struct FileContents
{
AllocatorInfo allocator;
void* data;
ssize size;
};
constexpr b32 file_zero_terminate = true;
constexpr b32 file_no_zero_terminate = false;
/**
* Reads the whole file contents
* @param a Allocator to use
* @param zero_terminate End the read data with null terminator
* @param filepath Path to the file
* @return File contents data
*/
FileContents file_read_contents( AllocatorInfo a, b32 zero_terminate, char const* filepath );
/**
* Returns a size of the file
* @param file
* @return File size
*/
s64 file_size( FileInfo* file );
/**
* Seeks the file cursor from the beginning of file to a specific position
* @param file
* @param offset Offset to seek to
*/
s64 file_seek( FileInfo* file, s64 offset );
/**
* Seeks the file cursor to the end of the file
* @param file
*/
s64 file_seek_to_end( FileInfo* file );
/**
* Returns the length from the beginning of the file we've read so far
* @param file
* @return Our current position in file
*/
s64 file_tell( FileInfo* file );
/**
* Writes to a file
* @param file
* @param buffer Buffer to read from
* @param size Size to read
*/
b32 file_write( FileInfo* file, void const* buffer, ssize size );
/**
* Writes to file at a specific offset
* @param file
* @param buffer Buffer to read from
* @param size Size to write
* @param offset Offset to write to
* @param bytes_written How much data we've actually written
*/
b32 file_write_at( FileInfo* file, void const* buffer, ssize size, s64 offset );
/**
* Writes to file safely
* @param file
* @param buffer Buffer to read from
* @param size Size to write
* @param offset Offset to write to
* @param bytes_written How much data we've actually written
*/
b32 file_write_at_check( FileInfo* file, void const* buffer, ssize size, s64 offset, ssize* bytes_written );
enum FileStreamFlags : u32
{
/* Allows us to write to the buffer directly. Beware: you can not append a new data! */
EFileStream_WRITABLE = bit( 0 ),
/* Clones the input buffer so you can write (zpl_file_write*) data into it. */
/* Since we work with a clone, the buffer size can dynamically grow as well. */
EFileStream_CLONE_WRITABLE = bit( 1 ),
EFileStream_UNDERLYING = GEN_U32_MAX,
};
/**
* Opens a new memory stream
* @param file
* @param allocator
*/
b8 file_stream_new( FileInfo* file, AllocatorInfo allocator );
/**
* Opens a memory stream over an existing buffer
* @param file
* @param allocator
* @param buffer Memory to create stream from
* @param size Buffer's size
* @param flags
*/
b8 file_stream_open( FileInfo* file, AllocatorInfo allocator, u8* buffer, ssize size, FileStreamFlags flags );
/**
* Retrieves the stream's underlying buffer and buffer size.
* @param file memory stream
* @param size (Optional) buffer size
*/
u8* file_stream_buf( FileInfo* file, ssize* size );
extern FileOperations const memory_file_operations;
inline
s64 file_seek( FileInfo* f, s64 offset )
{
s64 new_offset = 0;
if ( ! f->ops.read_at )
f->ops = default_file_operations;
f->ops.seek( f->fd, offset, ESeekWhence_BEGIN, &new_offset );
return new_offset;
}
inline
s64 file_seek_to_end( FileInfo* f )
{
s64 new_offset = 0;
if ( ! f->ops.read_at )
f->ops = default_file_operations;
f->ops.seek( f->fd, 0, ESeekWhence_END, &new_offset );
return new_offset;
}
inline
s64 file_tell( FileInfo* f )
{
s64 new_offset = 0;
if ( ! f->ops.read_at )
f->ops = default_file_operations;
f->ops.seek( f->fd, 0, ESeekWhence_CURRENT, &new_offset );
return new_offset;
}
inline
b32 file_read( FileInfo* f, void* buffer, ssize size )
{
s64 cur_offset = file_tell( f );
b32 result = file_read_at( f, buffer, size, file_tell( f ) );
file_seek( f, cur_offset + size );
return result;
}
inline
b32 file_read_at( FileInfo* f, void* buffer, ssize size, s64 offset )
{
return file_read_at_check( f, buffer, size, offset, NULL );
}
inline
b32 file_read_at_check( FileInfo* f, void* buffer, ssize size, s64 offset, ssize* bytes_read )
{
if ( ! f->ops.read_at )
f->ops = default_file_operations;
return f->ops.read_at( f->fd, buffer, size, offset, bytes_read, false );
}
inline
b32 file_write( FileInfo* f, void const* buffer, ssize size )
{
s64 cur_offset = file_tell( f );
b32 result = file_write_at( f, buffer, size, file_tell( f ) );
file_seek( f, cur_offset + size );
return result;
}
inline
b32 file_write_at( FileInfo* f, void const* buffer, ssize size, s64 offset )
{
return file_write_at_check( f, buffer, size, offset, NULL );
}
inline
b32 file_write_at_check( FileInfo* f, void const* buffer, ssize size, s64 offset, ssize* bytes_written )
{
if ( ! f->ops.read_at )
f->ops = default_file_operations;
return f->ops.write_at( f->fd, buffer, size, offset, bytes_written );
}
#pragma endregion File Handling

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base/dependencies/hashing.cpp Normal file
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#ifdef GEN_INTELLISENSE_DIRECTIVES
# pragma once
# include "memory.cpp"
#endif
#pragma region Hashing
global u32 const _crc32_table[ 256 ] = {
0x00000000, 0x77073096, 0xee0e612c, 0x990951ba, 0x076dc419, 0x706af48f, 0xe963a535, 0x9e6495a3, 0x0edb8832, 0x79dcb8a4, 0xe0d5e91e, 0x97d2d988, 0x09b64c2b, 0x7eb17cbd,
0xe7b82d07, 0x90bf1d91, 0x1db71064, 0x6ab020f2, 0xf3b97148, 0x84be41de, 0x1adad47d, 0x6ddde4eb, 0xf4d4b551, 0x83d385c7, 0x136c9856, 0x646ba8c0, 0xfd62f97a, 0x8a65c9ec,
0x14015c4f, 0x63066cd9, 0xfa0f3d63, 0x8d080df5, 0x3b6e20c8, 0x4c69105e, 0xd56041e4, 0xa2677172, 0x3c03e4d1, 0x4b04d447, 0xd20d85fd, 0xa50ab56b, 0x35b5a8fa, 0x42b2986c,
0xdbbbc9d6, 0xacbcf940, 0x32d86ce3, 0x45df5c75, 0xdcd60dcf, 0xabd13d59, 0x26d930ac, 0x51de003a, 0xc8d75180, 0xbfd06116, 0x21b4f4b5, 0x56b3c423, 0xcfba9599, 0xb8bda50f,
0x2802b89e, 0x5f058808, 0xc60cd9b2, 0xb10be924, 0x2f6f7c87, 0x58684c11, 0xc1611dab, 0xb6662d3d, 0x76dc4190, 0x01db7106, 0x98d220bc, 0xefd5102a, 0x71b18589, 0x06b6b51f,
0x9fbfe4a5, 0xe8b8d433, 0x7807c9a2, 0x0f00f934, 0x9609a88e, 0xe10e9818, 0x7f6a0dbb, 0x086d3d2d, 0x91646c97, 0xe6635c01, 0x6b6b51f4, 0x1c6c6162, 0x856530d8, 0xf262004e,
0x6c0695ed, 0x1b01a57b, 0x8208f4c1, 0xf50fc457, 0x65b0d9c6, 0x12b7e950, 0x8bbeb8ea, 0xfcb9887c, 0x62dd1ddf, 0x15da2d49, 0x8cd37cf3, 0xfbd44c65, 0x4db26158, 0x3ab551ce,
0xa3bc0074, 0xd4bb30e2, 0x4adfa541, 0x3dd895d7, 0xa4d1c46d, 0xd3d6f4fb, 0x4369e96a, 0x346ed9fc, 0xad678846, 0xda60b8d0, 0x44042d73, 0x33031de5, 0xaa0a4c5f, 0xdd0d7cc9,
0x5005713c, 0x270241aa, 0xbe0b1010, 0xc90c2086, 0x5768b525, 0x206f85b3, 0xb966d409, 0xce61e49f, 0x5edef90e, 0x29d9c998, 0xb0d09822, 0xc7d7a8b4, 0x59b33d17, 0x2eb40d81,
0xb7bd5c3b, 0xc0ba6cad, 0xedb88320, 0x9abfb3b6, 0x03b6e20c, 0x74b1d29a, 0xead54739, 0x9dd277af, 0x04db2615, 0x73dc1683, 0xe3630b12, 0x94643b84, 0x0d6d6a3e, 0x7a6a5aa8,
0xe40ecf0b, 0x9309ff9d, 0x0a00ae27, 0x7d079eb1, 0xf00f9344, 0x8708a3d2, 0x1e01f268, 0x6906c2fe, 0xf762575d, 0x806567cb, 0x196c3671, 0x6e6b06e7, 0xfed41b76, 0x89d32be0,
0x10da7a5a, 0x67dd4acc, 0xf9b9df6f, 0x8ebeeff9, 0x17b7be43, 0x60b08ed5, 0xd6d6a3e8, 0xa1d1937e, 0x38d8c2c4, 0x4fdff252, 0xd1bb67f1, 0xa6bc5767, 0x3fb506dd, 0x48b2364b,
0xd80d2bda, 0xaf0a1b4c, 0x36034af6, 0x41047a60, 0xdf60efc3, 0xa867df55, 0x316e8eef, 0x4669be79, 0xcb61b38c, 0xbc66831a, 0x256fd2a0, 0x5268e236, 0xcc0c7795, 0xbb0b4703,
0x220216b9, 0x5505262f, 0xc5ba3bbe, 0xb2bd0b28, 0x2bb45a92, 0x5cb36a04, 0xc2d7ffa7, 0xb5d0cf31, 0x2cd99e8b, 0x5bdeae1d, 0x9b64c2b0, 0xec63f226, 0x756aa39c, 0x026d930a,
0x9c0906a9, 0xeb0e363f, 0x72076785, 0x05005713, 0x95bf4a82, 0xe2b87a14, 0x7bb12bae, 0x0cb61b38, 0x92d28e9b, 0xe5d5be0d, 0x7cdcefb7, 0x0bdbdf21, 0x86d3d2d4, 0xf1d4e242,
0x68ddb3f8, 0x1fda836e, 0x81be16cd, 0xf6b9265b, 0x6fb077e1, 0x18b74777, 0x88085ae6, 0xff0f6a70, 0x66063bca, 0x11010b5c, 0x8f659eff, 0xf862ae69, 0x616bffd3, 0x166ccf45,
0xa00ae278, 0xd70dd2ee, 0x4e048354, 0x3903b3c2, 0xa7672661, 0xd06016f7, 0x4969474d, 0x3e6e77db, 0xaed16a4a, 0xd9d65adc, 0x40df0b66, 0x37d83bf0, 0xa9bcae53, 0xdebb9ec5,
0x47b2cf7f, 0x30b5ffe9, 0xbdbdf21c, 0xcabac28a, 0x53b39330, 0x24b4a3a6, 0xbad03605, 0xcdd70693, 0x54de5729, 0x23d967bf, 0xb3667a2e, 0xc4614ab8, 0x5d681b02, 0x2a6f2b94,
0xb40bbe37, 0xc30c8ea1, 0x5a05df1b, 0x2d02ef8d,
};
u32 crc32( void const* data, ssize len )
{
ssize remaining;
u32 result = ~( scast( u32, 0) );
u8 const* c = rcast( u8 const*, data);
for ( remaining = len; remaining--; c++ )
result = ( result >> 8 ) ^ ( _crc32_table[ ( result ^ *c ) & 0xff ] );
return ~result;
}
global u64 const _crc64_table[ 256 ] = {
0x0000000000000000ull, 0x7ad870c830358979ull, 0xf5b0e190606b12f2ull, 0x8f689158505e9b8bull, 0xc038e5739841b68full, 0xbae095bba8743ff6ull, 0x358804e3f82aa47dull,
0x4f50742bc81f2d04ull, 0xab28ecb46814fe75ull, 0xd1f09c7c5821770cull, 0x5e980d24087fec87ull, 0x24407dec384a65feull, 0x6b1009c7f05548faull, 0x11c8790fc060c183ull,
0x9ea0e857903e5a08ull, 0xe478989fa00bd371ull, 0x7d08ff3b88be6f81ull, 0x07d08ff3b88be6f8ull, 0x88b81eabe8d57d73ull, 0xf2606e63d8e0f40aull, 0xbd301a4810ffd90eull,
0xc7e86a8020ca5077ull, 0x4880fbd87094cbfcull, 0x32588b1040a14285ull, 0xd620138fe0aa91f4ull, 0xacf86347d09f188dull, 0x2390f21f80c18306ull, 0x594882d7b0f40a7full,
0x1618f6fc78eb277bull, 0x6cc0863448deae02ull, 0xe3a8176c18803589ull, 0x997067a428b5bcf0ull, 0xfa11fe77117cdf02ull, 0x80c98ebf2149567bull, 0x0fa11fe77117cdf0ull,
0x75796f2f41224489ull, 0x3a291b04893d698dull, 0x40f16bccb908e0f4ull, 0xcf99fa94e9567b7full, 0xb5418a5cd963f206ull, 0x513912c379682177ull, 0x2be1620b495da80eull,
0xa489f35319033385ull, 0xde51839b2936bafcull, 0x9101f7b0e12997f8ull, 0xebd98778d11c1e81ull, 0x64b116208142850aull, 0x1e6966e8b1770c73ull, 0x8719014c99c2b083ull,
0xfdc17184a9f739faull, 0x72a9e0dcf9a9a271ull, 0x08719014c99c2b08ull, 0x4721e43f0183060cull, 0x3df994f731b68f75ull, 0xb29105af61e814feull, 0xc849756751dd9d87ull,
0x2c31edf8f1d64ef6ull, 0x56e99d30c1e3c78full, 0xd9810c6891bd5c04ull, 0xa3597ca0a188d57dull, 0xec09088b6997f879ull, 0x96d1784359a27100ull, 0x19b9e91b09fcea8bull,
0x636199d339c963f2ull, 0xdf7adabd7a6e2d6full, 0xa5a2aa754a5ba416ull, 0x2aca3b2d1a053f9dull, 0x50124be52a30b6e4ull, 0x1f423fcee22f9be0ull, 0x659a4f06d21a1299ull,
0xeaf2de5e82448912ull, 0x902aae96b271006bull, 0x74523609127ad31aull, 0x0e8a46c1224f5a63ull, 0x81e2d7997211c1e8ull, 0xfb3aa75142244891ull, 0xb46ad37a8a3b6595ull,
0xceb2a3b2ba0eececull, 0x41da32eaea507767ull, 0x3b024222da65fe1eull, 0xa2722586f2d042eeull, 0xd8aa554ec2e5cb97ull, 0x57c2c41692bb501cull, 0x2d1ab4dea28ed965ull,
0x624ac0f56a91f461ull, 0x1892b03d5aa47d18ull, 0x97fa21650afae693ull, 0xed2251ad3acf6feaull, 0x095ac9329ac4bc9bull, 0x7382b9faaaf135e2ull, 0xfcea28a2faafae69ull,
0x8632586aca9a2710ull, 0xc9622c4102850a14ull, 0xb3ba5c8932b0836dull, 0x3cd2cdd162ee18e6ull, 0x460abd1952db919full, 0x256b24ca6b12f26dull, 0x5fb354025b277b14ull,
0xd0dbc55a0b79e09full, 0xaa03b5923b4c69e6ull, 0xe553c1b9f35344e2ull, 0x9f8bb171c366cd9bull, 0x10e3202993385610ull, 0x6a3b50e1a30ddf69ull, 0x8e43c87e03060c18ull,
0xf49bb8b633338561ull, 0x7bf329ee636d1eeaull, 0x012b592653589793ull, 0x4e7b2d0d9b47ba97ull, 0x34a35dc5ab7233eeull, 0xbbcbcc9dfb2ca865ull, 0xc113bc55cb19211cull,
0x5863dbf1e3ac9decull, 0x22bbab39d3991495ull, 0xadd33a6183c78f1eull, 0xd70b4aa9b3f20667ull, 0x985b3e827bed2b63ull, 0xe2834e4a4bd8a21aull, 0x6debdf121b863991ull,
0x1733afda2bb3b0e8ull, 0xf34b37458bb86399ull, 0x8993478dbb8deae0ull, 0x06fbd6d5ebd3716bull, 0x7c23a61ddbe6f812ull, 0x3373d23613f9d516ull, 0x49aba2fe23cc5c6full,
0xc6c333a67392c7e4ull, 0xbc1b436e43a74e9dull, 0x95ac9329ac4bc9b5ull, 0xef74e3e19c7e40ccull, 0x601c72b9cc20db47ull, 0x1ac40271fc15523eull, 0x5594765a340a7f3aull,
0x2f4c0692043ff643ull, 0xa02497ca54616dc8ull, 0xdafce7026454e4b1ull, 0x3e847f9dc45f37c0ull, 0x445c0f55f46abeb9ull, 0xcb349e0da4342532ull, 0xb1eceec59401ac4bull,
0xfebc9aee5c1e814full, 0x8464ea266c2b0836ull, 0x0b0c7b7e3c7593bdull, 0x71d40bb60c401ac4ull, 0xe8a46c1224f5a634ull, 0x927c1cda14c02f4dull, 0x1d148d82449eb4c6ull,
0x67ccfd4a74ab3dbfull, 0x289c8961bcb410bbull, 0x5244f9a98c8199c2ull, 0xdd2c68f1dcdf0249ull, 0xa7f41839ecea8b30ull, 0x438c80a64ce15841ull, 0x3954f06e7cd4d138ull,
0xb63c61362c8a4ab3ull, 0xcce411fe1cbfc3caull, 0x83b465d5d4a0eeceull, 0xf96c151de49567b7ull, 0x76048445b4cbfc3cull, 0x0cdcf48d84fe7545ull, 0x6fbd6d5ebd3716b7ull,
0x15651d968d029fceull, 0x9a0d8ccedd5c0445ull, 0xe0d5fc06ed698d3cull, 0xaf85882d2576a038ull, 0xd55df8e515432941ull, 0x5a3569bd451db2caull, 0x20ed197575283bb3ull,
0xc49581ead523e8c2ull, 0xbe4df122e51661bbull, 0x3125607ab548fa30ull, 0x4bfd10b2857d7349ull, 0x04ad64994d625e4dull, 0x7e7514517d57d734ull, 0xf11d85092d094cbfull,
0x8bc5f5c11d3cc5c6ull, 0x12b5926535897936ull, 0x686de2ad05bcf04full, 0xe70573f555e26bc4ull, 0x9ddd033d65d7e2bdull, 0xd28d7716adc8cfb9ull, 0xa85507de9dfd46c0ull,
0x273d9686cda3dd4bull, 0x5de5e64efd965432ull, 0xb99d7ed15d9d8743ull, 0xc3450e196da80e3aull, 0x4c2d9f413df695b1ull, 0x36f5ef890dc31cc8ull, 0x79a59ba2c5dc31ccull,
0x037deb6af5e9b8b5ull, 0x8c157a32a5b7233eull, 0xf6cd0afa9582aa47ull, 0x4ad64994d625e4daull, 0x300e395ce6106da3ull, 0xbf66a804b64ef628ull, 0xc5bed8cc867b7f51ull,
0x8aeeace74e645255ull, 0xf036dc2f7e51db2cull, 0x7f5e4d772e0f40a7ull, 0x05863dbf1e3ac9deull, 0xe1fea520be311aafull, 0x9b26d5e88e0493d6ull, 0x144e44b0de5a085dull,
0x6e963478ee6f8124ull, 0x21c640532670ac20ull, 0x5b1e309b16452559ull, 0xd476a1c3461bbed2ull, 0xaeaed10b762e37abull, 0x37deb6af5e9b8b5bull, 0x4d06c6676eae0222ull,
0xc26e573f3ef099a9ull, 0xb8b627f70ec510d0ull, 0xf7e653dcc6da3dd4ull, 0x8d3e2314f6efb4adull, 0x0256b24ca6b12f26ull, 0x788ec2849684a65full, 0x9cf65a1b368f752eull,
0xe62e2ad306bafc57ull, 0x6946bb8b56e467dcull, 0x139ecb4366d1eea5ull, 0x5ccebf68aecec3a1ull, 0x2616cfa09efb4ad8ull, 0xa97e5ef8cea5d153ull, 0xd3a62e30fe90582aull,
0xb0c7b7e3c7593bd8ull, 0xca1fc72bf76cb2a1ull, 0x45775673a732292aull, 0x3faf26bb9707a053ull, 0x70ff52905f188d57ull, 0x0a2722586f2d042eull, 0x854fb3003f739fa5ull,
0xff97c3c80f4616dcull, 0x1bef5b57af4dc5adull, 0x61372b9f9f784cd4ull, 0xee5fbac7cf26d75full, 0x9487ca0fff135e26ull, 0xdbd7be24370c7322ull, 0xa10fceec0739fa5bull,
0x2e675fb4576761d0ull, 0x54bf2f7c6752e8a9ull, 0xcdcf48d84fe75459ull, 0xb71738107fd2dd20ull, 0x387fa9482f8c46abull, 0x42a7d9801fb9cfd2ull, 0x0df7adabd7a6e2d6ull,
0x772fdd63e7936bafull, 0xf8474c3bb7cdf024ull, 0x829f3cf387f8795dull, 0x66e7a46c27f3aa2cull, 0x1c3fd4a417c62355ull, 0x935745fc4798b8deull, 0xe98f353477ad31a7ull,
0xa6df411fbfb21ca3ull, 0xdc0731d78f8795daull, 0x536fa08fdfd90e51ull, 0x29b7d047efec8728ull,
};
u64 crc64( void const* data, ssize len )
{
ssize remaining;
u64 result = ( scast( u64, 0) );
u8 const* c = rcast( u8 const*, data);
for ( remaining = len; remaining--; c++ )
result = ( result >> 8 ) ^ ( _crc64_table[ ( result ^ *c ) & 0xff ] );
return result;
}
#pragma endregion Hashing

11
base/dependencies/hashing.hpp Normal file
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#ifdef GEN_INTELLISENSE_DIRECTIVES
#pragma once
#include "containers.hpp"
#endif
#pragma region Hashing
u32 crc32( void const* data, ssize len );
u64 crc64( void const* data, ssize len );
#pragma endregion Hashing

287
base/dependencies/macros.hpp Normal file
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#ifdef GEN_INTELLISENSE_DIRECTIVES
# pragma once
# include "platform.hpp"
#endif
#pragma region Macros
#ifndef global
#define global static // Global variables
#endif
#ifndef internal
#define internal static // Internal linkage
#endif
#ifndef local_persist
#define local_persist static // Local Persisting variables
#endif
#ifndef bit
#define bit( Value ) ( 1 << Value )
#define bitfield_is_equal( Type, Field, Mask ) ( (scast(Type, Mask) & scast(Type, Field)) == scast(Type, Mask) )
#endif
// Mainly intended for forcing the base library to utilize only C-valid constructs or type coercion
#ifndef GEN_C_LIKE_CPP
#define GEN_C_LIKE_CPP 0
#endif
#if GEN_COMPILER_CPP
# ifndef cast
# define cast( type, value ) (tmpl_cast<type>( value ))
# endif
#else
# ifndef cast
# define cast( type, value ) ( (type)(value) )
# endif
#endif
#if GEN_COMPILER_CPP
# ifndef ccast
# define ccast( type, value ) ( const_cast< type >( (value) ) )
# endif
# ifndef pcast
# define pcast( type, value ) ( * reinterpret_cast< type* >( & ( value ) ) )
# endif
# ifndef rcast
# define rcast( type, value ) reinterpret_cast< type >( value )
# endif
# ifndef scast
# define scast( type, value ) static_cast< type >( value )
# endif
#else
# ifndef ccast
# define ccast( type, value ) ( (type)(value) )
# endif
# ifndef pcast
# define pcast( type, value ) ( * (type*)(& value) )
# endif
# ifndef rcast
# define rcast( type, value ) ( (type)(value) )
# endif
# ifndef scast
# define scast( type, value ) ( (type)(value) )
# endif
#endif
#ifndef stringize
#define stringize_va( ... ) #__VA_ARGS__
#define stringize( ... ) stringize_va( __VA_ARGS__ )
#endif
#ifndef do_once
#define do_once( statement ) for ( local_persist b32 once = true; once; once = false, (statement) )
#define do_once_start \
do \
{ \
local_persist \
bool done = false; \
if ( done ) \
break; \
done = true;
#define do_once_end \
} \
while(0);
#endif
#ifndef labeled_scope_start
#define labeled_scope_start if ( false ) {
#define labeled_scope_end }
#endif
#ifndef compiler_decorated_func_name
# ifdef COMPILER_CLANG
# define compiler_decorated_func_name __PRETTY_NAME__
# elif defined(COMPILER_MSVC)
# define compiler_decorated_func_name __FUNCDNAME__
# endif
#endif
#ifndef num_args_impl
// This is essentially an arg couneter version of GEN_SELECT_ARG macros
// See section : _Generic function overloading for that usage (explains this heavier case)
#define num_args_impl( _0, \
_1, _2, _3, _4, _5, _6, _7, _8, _9, _10, \
_11, _12, _13, _14, _15, _16, _17, _18, _19, _20, \
_21, _22, _23, _24, _25, _26, _27, _28, _29, _30, \
_31, _32, _33, _34, _35, _36, _37, _38, _39, _40, \
_41, _42, _43, _44, _45, _46, _47, _48, _49, _50, \
_51, _52, _53, _54, _55, _56, _57, _58, _59, _60, \
_61, _62, _63, _64, _65, _66, _67, _68, _69, _70, \
_71, _72, _73, _74, _75, _76, _77, _78, _79, _80, \
_81, _82, _83, _84, _85, _86, _87, _88, _89, _90, \
_91, _92, _93, _94, _95, _96, _97, _98, _99, _100, \
N, ... \
) N
// ## deletes preceding comma if _VA_ARGS__ is empty (GCC, Clang)
#define num_args(...) \
num_args_impl(_, ## __VA_ARGS__, \
100, 99, 98, 97, 96, 95, 94, 93, 92, 91, \
90, 89, 88, 87, 86, 85, 84, 83, 82, 81, \
80, 79, 78, 77, 76, 75, 74, 73, 72, 71, \
70, 69, 68, 67, 66, 65, 64, 63, 62, 61, \
60, 59, 58, 57, 56, 55, 54, 53, 52, 51, \
50, 49, 48, 47, 46, 45, 44, 43, 42, 41, \
40, 39, 38, 37, 36, 35, 34, 33, 32, 31, \
30, 29, 28, 27, 26, 25, 24, 23, 22, 21, \
20, 19, 18, 17, 16, 15, 14, 13, 12, 11, \
10, 9, 8, 7, 6, 5, 4, 3, 2, 1, \
0 \
)
#endif
#ifndef clamp
#define clamp( x, lower, upper ) min( max( ( x ), ( lower ) ), ( upper ) )
#endif
#ifndef count_of
#define count_of( x ) ( ( size_of( x ) / size_of( 0 [ x ] ) ) / ( ( ssize )( ! ( size_of( x ) % size_of( 0 [ x ] ) ) ) ) )
#endif
#ifndef is_between
#define is_between( x, lower, upper ) ( ( ( lower ) <= ( x ) ) && ( ( x ) <= ( upper ) ) )
#endif
#ifndef size_of
#define size_of( x ) ( ssize )( sizeof( x ) )
#endif
#ifndef max
#define max( a, b ) ( (a > b) ? (a) : (b) )
#endif
#ifndef min
#define min( a, b ) ( (a < b) ? (a) : (b) )
#endif
#if GEN_COMPILER_MSVC || GEN_COMPILER_TINYC
# define offset_of( Type, element ) ( ( GEN_NS( ssize ) ) & ( ( ( Type* )0 )->element ) )
#else
# define offset_of( Type, element ) __builtin_offsetof( Type, element )
#endif
#ifndef forceinline
# if GEN_COMPILER_MSVC
# define forceinline __forceinline
# define neverinline __declspec( noinline )
# elif GEN_COMPILER_GCC
# define forceinline inline __attribute__((__always_inline__))
# define neverinline __attribute__( ( __noinline__ ) )
# elif GEN_COMPILER_CLANG
# if __has_attribute(__always_inline__)
# define forceinline inline __attribute__((__always_inline__))
# define neverinline __attribute__( ( __noinline__ ) )
# else
# define forceinline
# define neverinline
# endif
# else
# define forceinline
# define neverinline
# endif
#endif
#ifndef neverinline
# if GEN_COMPILER_MSVC
# define neverinline __declspec( noinline )
# elif GEN_COMPILER_GCC
# define neverinline __attribute__( ( __noinline__ ) )
# elif GEN_COMPILER_CLANG
# if __has_attribute(__always_inline__)
# define neverinline __attribute__( ( __noinline__ ) )
# else
# define neverinline
# endif
# else
# define neverinline
# endif
#endif
#if GEN_COMPILER_C
#ifndef static_assert
#undef static_assert
#if GEN_COMPILER_C && __STDC_VERSION__ >= 201112L
#define static_assert(condition, message) _Static_assert(condition, message)
#else
#define static_assert(condition, message) typedef char static_assertion_##__LINE__[(condition)?1:-1]
#endif
#endif
#endif
#if GEN_COMPILER_CPP
// Already Defined
#elif GEN_COMPILER_C && __STDC_VERSION__ >= 201112L
# define thread_local _Thread_local
#elif GEN_COMPILER_MSVC
# define thread_local __declspec(thread)
#elif GEN_COMPILER_CLANG
# define thread_local __thread
#else
# error "No thread local support"
#endif
#if ! defined(typeof) && (!GEN_COMPILER_C || __STDC_VERSION__ < 202311L)
# if ! GEN_COMPILER_C
# define typeof decltype
# elif defined(_MSC_VER)
# define typeof(x) __typeof__(x)
# elif defined(__GNUC__) || defined(__clang__)
# define typeof(x) __typeof__(x)
# else
# error "Compiler not supported"
# endif
#endif
#ifndef GEN_API_C_BEGIN
# if GEN_COMPILER_C
# define GEN_API_C_BEGIN
# define GEN_API_C_END
# else
# define GEN_API_C_BEGIN extern "C" {
# define GEN_API_C_END }
# endif
#endif
#if GEN_COMPILER_C
# if __STDC_VERSION__ >= 202311L
# define enum_underlying(type) : type
# else
# define enum_underlying(type)
# endif
#else
# define enum_underlying(type) : type
#endif
#if GEN_COMPILER_C
# ifndef nullptr
# define nullptr NULL
# endif
# ifndef GEN_REMOVE_PTR
# define GEN_REMOVE_PTR(type) typeof(* ( (type) NULL) )
# endif
#endif
#if ! defined(GEN_PARAM_DEFAULT) && GEN_COMPILER_CPP
# define GEN_PARAM_DEFAULT = {}
#else
# define GEN_PARAM_DEFAULT
#endif
#if GEN_COMPILER_CPP
#define struct_init(type, value) {value}
#else
#define struct_init(type, value) {value}
#endif
#if 0
#ifndef GEN_OPTIMIZE_MAPPINGS_BEGIN
# define GEN_OPTIMIZE_MAPPINGS_BEGIN _pragma(optimize("gt", on))
# define GEN_OPITMIZE_MAPPINGS_END _pragma(optimize("", on))
#endif
#else
# define GEN_OPTIMIZE_MAPPINGS_BEGIN
# define GEN_OPITMIZE_MAPPINGS_END
#endif
#pragma endregion Macros

522
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#ifdef GEN_INTELLISENSE_DIRECTIVES
# pragma once
# include "printing.cpp"
#endif
#pragma region Memory
void* mem_copy( void* dest, void const* source, ssize n )
{
if ( dest == nullptr )
{
return nullptr;
}
return memcpy( dest, source, n );
}
void const* mem_find( void const* data, u8 c, ssize n )
{
u8 const* s = rcast( u8 const*, data);
while ( ( rcast( uptr, s) & ( sizeof( usize ) - 1 ) ) && n && *s != c )
{
s++;
n--;
}
if ( n && *s != c )
{
ssize const* w;
ssize k = GEN__ONES * c;
w = rcast( ssize const*, s);
while ( n >= size_of( ssize ) && ! GEN__HAS_ZERO( *w ^ k ) )
{
w++;
n -= size_of( ssize );
}
s = rcast( u8 const*, w);
while ( n && *s != c )
{
s++;
n--;
}
}
return n ? rcast( void const*, s ) : NULL;
}
#define GEN_HEAP_STATS_MAGIC 0xDEADC0DE
typedef struct _heap_stats _heap_stats;
struct _heap_stats
{
u32 magic;
ssize used_memory;
ssize alloc_count;
};
global _heap_stats _heap_stats_info;
void heap_stats_init( void )
{
zero_item( &_heap_stats_info );
_heap_stats_info.magic = GEN_HEAP_STATS_MAGIC;
}
ssize heap_stats_used_memory( void )
{
GEN_ASSERT_MSG( _heap_stats_info.magic == GEN_HEAP_STATS_MAGIC, "heap_stats is not initialised yet, call heap_stats_init first!" );
return _heap_stats_info.used_memory;
}
ssize heap_stats_alloc_count( void )
{
GEN_ASSERT_MSG( _heap_stats_info.magic == GEN_HEAP_STATS_MAGIC, "heap_stats is not initialised yet, call heap_stats_init first!" );
return _heap_stats_info.alloc_count;
}
void heap_stats_check( void )
{
GEN_ASSERT_MSG( _heap_stats_info.magic == GEN_HEAP_STATS_MAGIC, "heap_stats is not initialised yet, call heap_stats_init first!" );
GEN_ASSERT( _heap_stats_info.used_memory == 0 );
GEN_ASSERT( _heap_stats_info.alloc_count == 0 );
}
typedef struct _heap_alloc_info _heap_alloc_info;
struct _heap_alloc_info
{
ssize size;
void* physical_start;
};
void* heap_allocator_proc( void* allocator_data, AllocType type, ssize size, ssize alignment, void* old_memory, ssize old_size, u64 flags )
{
void* ptr = NULL;
// unused( allocator_data );
// unused( old_size );
if ( ! alignment )
alignment = GEN_DEFAULT_MEMORY_ALIGNMENT;
#ifdef GEN_HEAP_ANALYSIS
ssize alloc_info_size = size_of( _heap_alloc_info );
ssize alloc_info_remainder = ( alloc_info_size % alignment );
ssize track_size = max( alloc_info_size, alignment ) + alloc_info_remainder;
switch ( type )
{
case EAllocation_FREE :
{
if ( ! old_memory )
break;
_heap_alloc_info* alloc_info = rcast( _heap_alloc_info*, old_memory) - 1;
_heap_stats_info.used_memory -= alloc_info->size;
_heap_stats_info.alloc_count--;
old_memory = alloc_info->physical_start;
}
break;
case EAllocation_ALLOC :
{
size += track_size;
}
break;
default :
break;
}
#endif
switch ( type )
{
#if defined( GEN_COMPILER_MSVC ) || ( defined( GEN_COMPILER_GCC ) && defined( GEN_SYSTEM_WINDOWS ) ) || ( defined( GEN_COMPILER_TINYC ) && defined( GEN_SYSTEM_WINDOWS ) )
case EAllocation_ALLOC :
ptr = _aligned_malloc( size, alignment );
if ( flags & ALLOCATOR_FLAG_CLEAR_TO_ZERO )
zero_size( ptr, size );
break;
case EAllocation_FREE :
_aligned_free( old_memory );
break;
case EAllocation_RESIZE :
{
AllocatorInfo a = heap();
ptr = default_resize_align( a, old_memory, old_size, size, alignment );
}
break;
#elif defined( GEN_SYSTEM_LINUX ) && ! defined( GEN_CPU_ARM ) && ! defined( GEN_COMPILER_TINYC )
case EAllocation_ALLOC :
{
ptr = aligned_alloc( alignment, ( size + alignment - 1 ) & ~( alignment - 1 ) );
if ( flags & GEN_ALLOCATOR_FLAG_CLEAR_TO_ZERO )
{
zero_size( ptr, size );
}
}
break;
case EAllocation_FREE :
{
free( old_memory );
}
break;
case EAllocation_RESIZE :
{
AllocatorInfo a = heap();
ptr = default_resize_align( a, old_memory, old_size, size, alignment );
}
break;
#else
case EAllocation_ALLOC :
{
posix_memalign( &ptr, alignment, size );
if ( flags & GEN_ALLOCATOR_FLAG_CLEAR_TO_ZERO )
{
zero_size( ptr, size );
}
}
break;
case EAllocation_FREE :
{
free( old_memory );
}
break;
case EAllocation_RESIZE :
{
AllocatorInfo a = heap();
ptr = default_resize_align( a, old_memory, old_size, size, alignment );
}
break;
#endif
case EAllocation_FREE_ALL :
break;
}
#ifdef GEN_HEAP_ANALYSIS
if ( type == EAllocation_ALLOC )
{
_heap_alloc_info* alloc_info = rcast( _heap_alloc_info*, rcast( char*, ptr) + alloc_info_remainder );
zero_item( alloc_info );
alloc_info->size = size - track_size;
alloc_info->physical_start = ptr;
ptr = rcast( void*, alloc_info + 1 );
_heap_stats_info.used_memory += alloc_info->size;
_heap_stats_info.alloc_count++;
}
#endif
return ptr;
}
#pragma region VirtualMemory
VirtualMemory vm_from_memory( void* data, ssize size )
{
VirtualMemory vm;
vm.data = data;
vm.size = size;
return vm;
}
#if defined( GEN_SYSTEM_WINDOWS )
VirtualMemory vm_alloc( void* addr, ssize size )
{
VirtualMemory vm;
GEN_ASSERT( size > 0 );
vm.data = VirtualAlloc( addr, size, MEM_COMMIT | MEM_RESERVE, PAGE_READWRITE );
vm.size = size;
return vm;
}
b32 vm_free( VirtualMemory vm )
{
MEMORY_BASIC_INFORMATION info;
while ( vm.size > 0 )
{
if ( VirtualQuery( vm.data, &info, size_of( info ) ) == 0 )
return false;
if ( info.BaseAddress != vm.data || info.AllocationBase != vm.data || info.State != MEM_COMMIT || info.RegionSize > scast( usize, vm.size) )
{
return false;
}
if ( VirtualFree( vm.data, 0, MEM_RELEASE ) == 0 )
return false;
vm.data = pointer_add( vm.data, info.RegionSize );
vm.size -= info.RegionSize;
}
return true;
}
VirtualMemory vm_trim( VirtualMemory vm, ssize lead_size, ssize size )
{
VirtualMemory new_vm = { 0 };
void* ptr;
GEN_ASSERT( vm.size >= lead_size + size );
ptr = pointer_add( vm.data, lead_size );
vm_free( vm );
new_vm = vm_alloc( ptr, size );
if ( new_vm.data == ptr )
return new_vm;
if ( new_vm.data )
vm_free( new_vm );
return new_vm;
}
b32 vm_purge( VirtualMemory vm )
{
VirtualAlloc( vm.data, vm.size, MEM_RESET, PAGE_READWRITE );
// NOTE: Can this really fail?
return true;
}
ssize virtual_memory_page_size( ssize* alignment_out )
{
SYSTEM_INFO info;
GetSystemInfo( &info );
if ( alignment_out )
*alignment_out = info.dwAllocationGranularity;
return info.dwPageSize;
}
#else
# include <sys/mman.h>
# ifndef MAP_ANONYMOUS
# define MAP_ANONYMOUS MAP_ANON
# endif
VirtualMemory vm_alloc( void* addr, ssize size )
{
VirtualMemory vm;
GEN_ASSERT( size > 0 );
vm.data = mmap( addr, size, PROT_READ | PROT_WRITE, MAP_ANONYMOUS | MAP_PRIVATE, -1, 0 );
vm.size = size;
return vm;
}
b32 vm_free( VirtualMemory vm )
{
munmap( vm.data, vm.size );
return true;
}
VirtualMemory vm_trim( VirtualMemory vm, ssize lead_size, ssize size )
{
void* ptr;
ssize trail_size;
GEN_ASSERT( vm.size >= lead_size + size );
ptr = pointer_add( vm.data, lead_size );
trail_size = vm.size - lead_size - size;
if ( lead_size != 0 )
vm_free( vm_from_memory(( vm.data, lead_size ) );
if ( trail_size != 0 )
vm_free( vm_from_memory( ptr, trail_size ) );
return vm_from_memory( ptr, size );
}
b32 vm_purge( VirtualMemory vm )
{
int err = madvise( vm.data, vm.size, MADV_DONTNEED );
return err != 0;
}
ssize virtual_memory_page_size( ssize* alignment_out )
{
// TODO: Is this always true?
ssize result = scast( ssize, sysconf( _SC_PAGE_SIZE ));
if ( alignment_out )
*alignment_out = result;
return result;
}
#endif
#pragma endregion VirtualMemory
void* arena_allocator_proc( void* allocator_data, AllocType type, ssize size, ssize alignment, void* old_memory, ssize old_size, u64 flags )
{
Arena* arena = rcast(Arena*, allocator_data);
void* ptr = NULL;
// unused( old_size );
switch ( type )
{
case EAllocation_ALLOC :
{
void* end = pointer_add( arena->PhysicalStart, arena->TotalUsed );
ssize total_size = align_forward_s64( size, alignment );
// NOTE: Out of memory
if ( arena->TotalUsed + total_size > (ssize) arena->TotalSize )
{
// zpl__printf_err("%s", "Arena out of memory\n");
GEN_FATAL("Arena out of memory! (Possibly could not fit for the largest size Arena!!)");
return nullptr;
}
ptr = align_forward( end, alignment );
arena->TotalUsed += total_size;
if ( flags & ALLOCATOR_FLAG_CLEAR_TO_ZERO )
zero_size( ptr, size );
}
break;
case EAllocation_FREE :
// NOTE: Free all at once
// Use Temp_Arena_Memory if you want to free a block
break;
case EAllocation_FREE_ALL :
arena->TotalUsed = 0;
break;
case EAllocation_RESIZE :
{
// TODO : Check if ptr is on top of stack and just extend
AllocatorInfo a = arena->Backing;
ptr = default_resize_align( a, old_memory, old_size, size, alignment );
}
break;
}
return ptr;
}
void* pool_allocator_proc( void* allocator_data, AllocType type, ssize size, ssize alignment, void* old_memory, ssize old_size, u64 flags )
{
Pool* pool = rcast( Pool*, allocator_data);
void* ptr = NULL;
// unused( old_size );
switch ( type )
{
case EAllocation_ALLOC :
{
uptr next_free;
GEN_ASSERT( size == pool->BlockSize );
GEN_ASSERT( alignment == pool->BlockAlign );
GEN_ASSERT( pool->FreeList != NULL );
next_free = * rcast( uptr*, pool->FreeList);
ptr = pool->FreeList;
pool->FreeList = rcast( void*, next_free);
pool->TotalSize += pool->BlockSize;
if ( flags & ALLOCATOR_FLAG_CLEAR_TO_ZERO )
zero_size( ptr, size );
}
break;
case EAllocation_FREE :
{
uptr* next;
if ( old_memory == NULL )
return NULL;
next = rcast( uptr*, old_memory);
*next = rcast( uptr, pool->FreeList);
pool->FreeList = old_memory;
pool->TotalSize -= pool->BlockSize;
}
break;
case EAllocation_FREE_ALL :
{
ssize actual_block_size, block_index;
void* curr;
uptr* end;
actual_block_size = pool->BlockSize + pool->BlockAlign;
pool->TotalSize = 0;
// NOTE: Init intrusive freelist
curr = pool->PhysicalStart;
for ( block_index = 0; block_index < pool->NumBlocks - 1; block_index++ )
{
uptr* next = rcast( uptr*, curr);
* next = rcast( uptr, curr) + actual_block_size;
curr = pointer_add( curr, actual_block_size );
}
end = rcast( uptr*, curr);
* end = scast( uptr, NULL);
pool->FreeList = pool->PhysicalStart;
}
break;
case EAllocation_RESIZE :
// NOTE: Cannot resize
GEN_PANIC( "You cannot resize something allocated by with a pool." );
break;
}
return ptr;
}
Pool pool_init_align( AllocatorInfo backing, ssize num_blocks, ssize block_size, ssize block_align )
{
Pool pool = {};
ssize actual_block_size, pool_size, block_index;
void *data, *curr;
uptr* end;
zero_item( &pool );
pool.Backing = backing;
pool.BlockSize = block_size;
pool.BlockAlign = block_align;
pool.NumBlocks = num_blocks;
actual_block_size = block_size + block_align;
pool_size = num_blocks * actual_block_size;
data = alloc_align( backing, pool_size, block_align );
// NOTE: Init intrusive freelist
curr = data;
for ( block_index = 0; block_index < num_blocks - 1; block_index++ )
{
uptr* next = ( uptr* ) curr;
*next = ( uptr ) curr + actual_block_size;
curr = pointer_add( curr, actual_block_size );
}
end = ( uptr* ) curr;
*end = ( uptr ) NULL;
pool.PhysicalStart = data;
pool.FreeList = data;
return pool;
}
void pool_clear(Pool* pool)
{
ssize actual_block_size, block_index;
void* curr;
uptr* end;
actual_block_size = pool->BlockSize + pool->BlockAlign;
curr = pool->PhysicalStart;
for ( block_index = 0; block_index < pool->NumBlocks - 1; block_index++ )
{
uptr* next = ( uptr* ) curr;
*next = ( uptr ) curr + actual_block_size;
curr = pointer_add( curr, actual_block_size );
}
end = ( uptr* ) curr;
*end = ( uptr ) NULL;
pool->FreeList = pool->PhysicalStart;
}
#pragma endregion Memory

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#ifdef GEN_INTELLISENSE_DIRECTIVES
# pragma once
# include "debug.hpp"
#endif
#pragma region Memory
#define kilobytes( x ) ( ( x ) * ( s64 )( 1024 ) )
#define megabytes( x ) ( kilobytes( x ) * ( s64 )( 1024 ) )
#define gigabytes( x ) ( megabytes( x ) * ( s64 )( 1024 ) )
#define terabytes( x ) ( gigabytes( x ) * ( s64 )( 1024 ) )
#define GEN__ONES ( scast( GEN_NS usize, - 1) / GEN_U8_MAX )
#define GEN__HIGHS ( GEN__ONES * ( GEN_U8_MAX / 2 + 1 ) )
#define GEN__HAS_ZERO( x ) ( ( ( x ) - GEN__ONES ) & ~( x ) & GEN__HIGHS )
template< class Type >
void swap( Type& a, Type& b )
{
Type tmp = a;
a = b;
b = tmp;
}
//! Checks if value is power of 2.
b32 is_power_of_two( ssize x );
//! Aligns address to specified alignment.
void* align_forward( void* ptr, ssize alignment );
//! Aligns value to a specified alignment.
s64 align_forward_by_value( s64 value, ssize alignment );
//! Moves pointer forward by bytes.
void* pointer_add( void* ptr, ssize bytes );
//! Moves pointer forward by bytes.
void const* pointer_add_const( void const* ptr, ssize bytes );
//! Calculates difference between two addresses.
ssize pointer_diff( void const* begin, void const* end );
//! Copy non-overlapping memory from source to destination.
void* mem_copy( void* dest, void const* source, ssize size );
//! Search for a constant value within the size limit at memory location.
void const* mem_find( void const* data, u8 byte_value, ssize size );
//! Copy memory from source to destination.
void* mem_move( void* dest, void const* source, ssize size );
//! Set constant value at memory location with specified size.
void* mem_set( void* data, u8 byte_value, ssize size );
//! @param ptr Memory location to clear up.
//! @param size The size to clear up with.
void zero_size( void* ptr, ssize size );
//! Clears up an item.
#define zero_item( t ) zero_size( ( t ), size_of( *( t ) ) ) // NOTE: Pass pointer of struct
//! Clears up an array.
#define zero_array( a, count ) zero_size( ( a ), size_of( *( a ) ) * count )
enum AllocType : u8
{
EAllocation_ALLOC,
EAllocation_FREE,
EAllocation_FREE_ALL,
EAllocation_RESIZE,
};
typedef void*(AllocatorProc)( void* allocator_data, AllocType type, ssize size, ssize alignment, void* old_memory, ssize old_size, u64 flags );
struct AllocatorInfo
{
AllocatorProc* Proc;
void* Data;
};
enum AllocFlag
{
ALLOCATOR_FLAG_CLEAR_TO_ZERO = bit( 0 ),
};
#ifndef GEN_DEFAULT_MEMORY_ALIGNMENT
# define GEN_DEFAULT_MEMORY_ALIGNMENT ( 2 * size_of( void* ) )
#endif
#ifndef GEN_DEFAULT_ALLOCATOR_FLAGS
# define GEN_DEFAULT_ALLOCATOR_FLAGS ( ALLOCATOR_FLAG_CLEAR_TO_ZERO )
#endif
//! Allocate memory with default alignment.
void* alloc( AllocatorInfo a, ssize size );
//! Allocate memory with specified alignment.
void* alloc_align( AllocatorInfo a, ssize size, ssize alignment );
//! Free allocated memory.
void allocator_free( AllocatorInfo a, void* ptr );
//! Free all memory allocated by an allocator.
void free_all( AllocatorInfo a );
//! Resize an allocated memory.
void* resize( AllocatorInfo a, void* ptr, ssize old_size, ssize new_size );
//! Resize an allocated memory with specified alignment.
void* resize_align( AllocatorInfo a, void* ptr, ssize old_size, ssize new_size, ssize alignment );
//! Allocate memory for an item.
#define alloc_item( allocator_, Type ) ( Type* )alloc( allocator_, size_of( Type ) )
//! Allocate memory for an array of items.
#define alloc_array( allocator_, Type, count ) ( Type* )alloc( allocator_, size_of( Type ) * ( count ) )
/* heap memory analysis tools */
/* define GEN_HEAP_ANALYSIS to enable this feature */
/* call zpl_heap_stats_init at the beginning of the entry point */
/* you can call zpl_heap_stats_check near the end of the execution to validate any possible leaks */
void heap_stats_init( void );
ssize heap_stats_used_memory( void );
ssize heap_stats_alloc_count( void );
void heap_stats_check( void );
//! Allocate/Resize memory using default options.
//! Use this if you don't need a "fancy" resize allocation
void* default_resize_align( AllocatorInfo a, void* ptr, ssize old_size, ssize new_size, ssize alignment );
void* heap_allocator_proc( void* allocator_data, AllocType type, ssize size, ssize alignment, void* old_memory, ssize old_size, u64 flags );
//! The heap allocator backed by operating system's memory manager.
constexpr AllocatorInfo heap( void ) { AllocatorInfo allocator = { heap_allocator_proc, nullptr }; return allocator; }
//! Helper to allocate memory using heap allocator.
#define malloc( sz ) alloc( heap(), sz )
//! Helper to free memory allocated by heap allocator.
#define mfree( ptr ) free( heap(), ptr )
struct VirtualMemory
{
void* data;
ssize size;
};
//! Initialize virtual memory from existing data.
VirtualMemory vm_from_memory( void* data, ssize size );
//! Allocate virtual memory at address with size.
//! @param addr The starting address of the region to reserve. If NULL, it lets operating system to decide where to allocate it.
//! @param size The size to serve.
VirtualMemory vm_alloc( void* addr, ssize size );
//! Release the virtual memory.
b32 vm_free( VirtualMemory vm );
//! Trim virtual memory.
VirtualMemory vm_trim( VirtualMemory vm, ssize lead_size, ssize size );
//! Purge virtual memory.
b32 vm_purge( VirtualMemory vm );
//! Retrieve VM's page size and alignment.
ssize virtual_memory_page_size( ssize* alignment_out );
#pragma region Arena
struct Arena;
AllocatorInfo arena_allocator_info( Arena* arena );
// Remove static keyword and rename allocator_proc
void* arena_allocator_proc(void* allocator_data, AllocType type, ssize size, ssize alignment, void* old_memory, ssize old_size, u64 flags);
// Add these declarations after the Arena struct
Arena arena_init_from_allocator(AllocatorInfo backing, ssize size);
Arena arena_init_from_memory ( void* start, ssize size );
Arena arena_init_sub (Arena* parent, ssize size);
ssize arena_alignment_of (Arena* arena, ssize alignment);
void arena_check (Arena* arena);
void arena_free (Arena* arena);
ssize arena_size_remaining(Arena* arena, ssize alignment);
struct Arena
{
AllocatorInfo Backing;
void* PhysicalStart;
ssize TotalSize;
ssize TotalUsed;
ssize TempCount;
#if GEN_COMPILER_CPP && ! GEN_C_LIKE_CPP
#pragma region Member Mapping
forceinline operator AllocatorInfo() { return arena_allocator_info(this); }
forceinline static void* allocator_proc( void* allocator_data, AllocType type, ssize size, ssize alignment, void* old_memory, ssize old_size, u64 flags ) { return arena_allocator_proc( allocator_data, type, size, alignment, old_memory, old_size, flags ); }
forceinline static Arena init_from_memory( void* start, ssize size ) { return arena_init_from_memory( start, size ); }
forceinline static Arena init_from_allocator( AllocatorInfo backing, ssize size ) { return arena_init_from_allocator( backing, size ); }
forceinline static Arena init_sub( Arena& parent, ssize size ) { return arena_init_from_allocator( parent.Backing, size ); }
forceinline ssize alignment_of( ssize alignment ) { return arena_alignment_of(this, alignment); }
forceinline void free() { return arena_free(this); }
forceinline ssize size_remaining( ssize alignment ) { return arena_size_remaining(this, alignment); }
// This id is defined by Unreal for asserts
#pragma push_macro("check")
#undef check
forceinline void check() { arena_check(this); }
#pragma pop_macro("check")
#pragma endregion Member Mapping
#endif
};
#if GEN_COMPILER_CPP && ! GEN_C_LIKE_CPP
forceinline AllocatorInfo allocator_info(Arena& arena ) { return arena_allocator_info(& arena); }
forceinline Arena init_sub (Arena& parent, ssize size) { return arena_init_sub( & parent, size); }
forceinline ssize alignment_of (Arena& arena, ssize alignment) { return arena_alignment_of( & arena, alignment); }
forceinline void free (Arena& arena) { return arena_free(& arena); }
forceinline ssize size_remaining(Arena& arena, ssize alignment) { return arena_size_remaining(& arena, alignment); }
// This id is defined by Unreal for asserts
#pragma push_macro("check")
#undef check
forceinline void check(Arena& arena) { return arena_check(& arena); };
#pragma pop_macro("check")
#endif
inline
AllocatorInfo arena_allocator_info( Arena* arena ) {
GEN_ASSERT(arena != nullptr);
AllocatorInfo info = { arena_allocator_proc, arena };
return info;
}
inline
Arena arena_init_from_memory( void* start, ssize size )
{
Arena arena = {
{ nullptr, nullptr },
start,
size,
0,
0
};
return arena;
}
inline
Arena arena_init_from_allocator(AllocatorInfo backing, ssize size) {
Arena result = {
backing,
alloc(backing, size),
size,
0,
0
};
return result;
}
inline
Arena arena_init_sub(Arena* parent, ssize size) {
GEN_ASSERT(parent != nullptr);
return arena_init_from_allocator(parent->Backing, size);
}
inline
ssize arena_alignment_of(Arena* arena, ssize alignment)
{
GEN_ASSERT(arena != nullptr);
ssize alignment_offset, result_pointer, mask;
GEN_ASSERT(is_power_of_two(alignment));
alignment_offset = 0;
result_pointer = (ssize)arena->PhysicalStart + arena->TotalUsed;
mask = alignment - 1;
if (result_pointer & mask)
alignment_offset = alignment - (result_pointer & mask);
return alignment_offset;
}
inline
void arena_check(Arena* arena)
{
GEN_ASSERT(arena != nullptr );
GEN_ASSERT(arena->TempCount == 0);
}
inline
void arena_free(Arena* arena)
{
GEN_ASSERT(arena != nullptr);
if (arena->Backing.Proc)
{
allocator_free(arena->Backing, arena->PhysicalStart);
arena->PhysicalStart = nullptr;
}
}
inline
ssize arena_size_remaining(Arena* arena, ssize alignment)
{
GEN_ASSERT(arena != nullptr);
ssize result = arena->TotalSize - (arena->TotalUsed + arena_alignment_of(arena, alignment));
return result;
}
#pragma endregion Arena
#pragma region FixedArena
template<s32 Size>
struct FixedArena;
template<s32 Size> FixedArena<Size> fixed_arena_init();
template<s32 Size> AllocatorInfo fixed_arena_allocator_info(FixedArena<Size>* fixed_arena );
template<s32 Size> ssize fixed_arena_size_remaining(FixedArena<Size>* fixed_arena, ssize alignment);
template<s32 Size> void fixed_arena_free(FixedArena<Size>* fixed_arena);
#if GEN_COMPILER_CPP && ! GEN_C_LIKE_CPP
template<s32 Size> AllocatorInfo allocator_info( FixedArena<Size>& fixed_arena ) { return allocator_info(& fixed_arena); }
template<s32 Size> ssize size_remaining(FixedArena<Size>& fixed_arena, ssize alignment) { return size_remaining( & fixed_arena, alignment); }
#endif
// Just a wrapper around using an arena with memory associated with its scope instead of from an allocator.
// Used for static segment or stack allocations.
template< s32 Size >
struct FixedArena
{
char memory[Size];
Arena arena;
#if GEN_COMPILER_CPP && ! GEN_C_LIKE_CPP
#pragma region Member Mapping
forceinline operator AllocatorInfo() { return fixed_arena_allocator_info(this); }
forceinline static FixedArena init() { FixedArena result; fixed_arena_init<Size>(result); return result; }
forceinline ssize size_remaining(ssize alignment) { fixed_arena_size_remaining(this, alignment); }
#pragma endregion Member Mapping
#endif
};
template<s32 Size> inline
AllocatorInfo fixed_arena_allocator_info( FixedArena<Size>* fixed_arena ) {
GEN_ASSERT(fixed_arena);
return { arena_allocator_proc, & fixed_arena->arena };
}
template<s32 Size> inline
void fixed_arena_init(FixedArena<Size>* result) {
zero_size(& result->memory[0], Size);
result->arena = arena_init_from_memory(& result->memory[0], Size);
}
template<s32 Size> inline
void fixed_arena_free(FixedArena<Size>* fixed_arena) {
arena_free( & fixed_arena->arena);
}
template<s32 Size> inline
ssize fixed_arena_size_remaining(FixedArena<Size>* fixed_arena, ssize alignment) {
return size_remaining(fixed_arena->arena, alignment);
}
using FixedArena_1KB = FixedArena< kilobytes( 1 ) >;
using FixedArena_4KB = FixedArena< kilobytes( 4 ) >;
using FixedArena_8KB = FixedArena< kilobytes( 8 ) >;
using FixedArena_16KB = FixedArena< kilobytes( 16 ) >;
using FixedArena_32KB = FixedArena< kilobytes( 32 ) >;
using FixedArena_64KB = FixedArena< kilobytes( 64 ) >;
using FixedArena_128KB = FixedArena< kilobytes( 128 ) >;
using FixedArena_256KB = FixedArena< kilobytes( 256 ) >;
using FixedArena_512KB = FixedArena< kilobytes( 512 ) >;
using FixedArena_1MB = FixedArena< megabytes( 1 ) >;
using FixedArena_2MB = FixedArena< megabytes( 2 ) >;
using FixedArena_4MB = FixedArena< megabytes( 4 ) >;
#pragma endregion FixedArena
#pragma region Pool
struct Pool;
void* pool_allocator_proc(void* allocator_data, AllocType type, ssize size, ssize alignment, void* old_memory, ssize old_size, u64 flags);
Pool pool_init(AllocatorInfo backing, ssize num_blocks, ssize block_size);
Pool pool_init_align(AllocatorInfo backing, ssize num_blocks, ssize block_size, ssize block_align);
AllocatorInfo pool_allocator_info(Pool* pool);
void pool_clear(Pool* pool);
void pool_free(Pool* pool);
#if GEN_COMPILER_CPP && ! GEN_C_LIKE_CPP
AllocatorInfo allocator_info(Pool& pool) { return pool_allocator_info(& pool); }
void clear(Pool& pool) { return pool_clear(& pool); }
void free(Pool& pool) { return pool_free(& pool); }
#endif
struct Pool
{
AllocatorInfo Backing;
void* PhysicalStart;
void* FreeList;
ssize BlockSize;
ssize BlockAlign;
ssize TotalSize;
ssize NumBlocks;
#if GEN_COMPILER_CPP && ! GEN_C_LIKE_CPP
#pragma region Member Mapping
forceinline operator AllocatorInfo() { return pool_allocator_info(this); }
forceinline static void* allocator_proc(void* allocator_data, AllocType type, ssize size, ssize alignment, void* old_memory, ssize old_size, u64 flags) { return pool_allocator_proc(allocator_data, type, size, alignment, old_memory, old_size, flags); }
forceinline static Pool init(AllocatorInfo backing, ssize num_blocks, ssize block_size) { return pool_init(backing, num_blocks, block_size); }
forceinline static Pool init_align(AllocatorInfo backing, ssize num_blocks, ssize block_size, ssize block_align) { return pool_init_align(backing, num_blocks, block_size, block_align); }
forceinline void clear() { pool_clear( this); }
forceinline void free() { pool_free( this); }
#pragma endregion
#endif
};
inline
AllocatorInfo pool_allocator_info(Pool* pool) {
AllocatorInfo info = { pool_allocator_proc, pool };
return info;
}
inline
Pool pool_init(AllocatorInfo backing, ssize num_blocks, ssize block_size) {
return pool_init_align(backing, num_blocks, block_size, GEN_DEFAULT_MEMORY_ALIGNMENT);
}
inline
void pool_free(Pool* pool) {
if(pool->Backing.Proc) {
allocator_free(pool->Backing, pool->PhysicalStart);
}
}
#pragma endregion Pool
inline
b32 is_power_of_two( ssize x ) {
if ( x <= 0 )
return false;
return ! ( x & ( x - 1 ) );
}
inline
mem_ptr align_forward( void* ptr, ssize alignment )
{
GEN_ASSERT( is_power_of_two( alignment ) );
uptr p = to_uptr(ptr);
uptr forward = (p + ( alignment - 1 ) ) & ~( alignment - 1 );
return to_mem_ptr(forward);
}
inline s64 align_forward_s64( s64 value, ssize alignment ) { return value + ( alignment - value % alignment ) % alignment; }
inline void* pointer_add ( void* ptr, ssize bytes ) { return rcast(void*, rcast( u8*, ptr) + bytes ); }
inline void const* pointer_add_const( void const* ptr, ssize bytes ) { return rcast(void const*, rcast( u8 const*, ptr) + bytes ); }
inline sptr pointer_diff( mem_ptr_const begin, mem_ptr_const end ) {
return scast( ssize, rcast( u8 const*, end) - rcast(u8 const*, begin) );
}
inline
void* mem_move( void* destination, void const* source, ssize byte_count )
{
if ( destination == NULL )
{
return NULL;
}
u8* dest_ptr = rcast( u8*, destination);
u8 const* src_ptr = rcast( u8 const*, source);
if ( dest_ptr == src_ptr )
return dest_ptr;
if ( src_ptr + byte_count <= dest_ptr || dest_ptr + byte_count <= src_ptr ) // NOTE: Non-overlapping
return mem_copy( dest_ptr, src_ptr, byte_count );
if ( dest_ptr < src_ptr )
{
if ( to_uptr(src_ptr) % size_of( ssize ) == to_uptr(dest_ptr) % size_of( ssize ) )
{
while ( pcast( uptr, dest_ptr) % size_of( ssize ) )
{
if ( ! byte_count-- )
return destination;
*dest_ptr++ = *src_ptr++;
}
while ( byte_count >= size_of( ssize ) )
{
* rcast(ssize*, dest_ptr) = * rcast(ssize const*, src_ptr);
byte_count -= size_of( ssize );
dest_ptr += size_of( ssize );
src_ptr += size_of( ssize );
}
}
for ( ; byte_count; byte_count-- )
*dest_ptr++ = *src_ptr++;
}
else
{
if ( ( to_uptr(src_ptr) % size_of( ssize ) ) == ( to_uptr(dest_ptr) % size_of( ssize ) ) )
{
while ( to_uptr( dest_ptr + byte_count ) % size_of( ssize ) )
{
if ( ! byte_count-- )
return destination;
dest_ptr[ byte_count ] = src_ptr[ byte_count ];
}
while ( byte_count >= size_of( ssize ) )
{
byte_count -= size_of( ssize );
* rcast(ssize*, dest_ptr + byte_count ) = * rcast( ssize const*, src_ptr + byte_count );
}
}
while ( byte_count )
byte_count--, dest_ptr[ byte_count ] = src_ptr[ byte_count ];
}
return destination;
}
inline
void* mem_set( void* destination, u8 fill_byte, ssize byte_count )
{
if ( destination == NULL )
{
return NULL;
}
ssize align_offset;
u8* dest_ptr = rcast( u8*, destination);
u32 fill_word = ( ( u32 )-1 ) / 255 * fill_byte;
if ( byte_count == 0 )
return destination;
dest_ptr[ 0 ] = dest_ptr[ byte_count - 1 ] = fill_byte;
if ( byte_count < 3 )
return destination;
dest_ptr[ 1 ] = dest_ptr[ byte_count - 2 ] = fill_byte;
dest_ptr[ 2 ] = dest_ptr[ byte_count - 3 ] = fill_byte;
if ( byte_count < 7 )
return destination;
dest_ptr[ 3 ] = dest_ptr[ byte_count - 4 ] = fill_byte;
if ( byte_count < 9 )
return destination;
align_offset = -to_sptr( dest_ptr ) & 3;
dest_ptr += align_offset;
byte_count -= align_offset;
byte_count &= -4;
* rcast( u32*, ( dest_ptr + 0 ) ) = fill_word;
* rcast( u32*, ( dest_ptr + byte_count - 4 ) ) = fill_word;
if ( byte_count < 9 )
return destination;
* rcast( u32*, dest_ptr + 4 ) = fill_word;
* rcast( u32*, dest_ptr + 8 ) = fill_word;
* rcast( u32*, dest_ptr + byte_count - 12 ) = fill_word;
* rcast( u32*, dest_ptr + byte_count - 8 ) = fill_word;
if ( byte_count < 25 )
return destination;
* rcast( u32*, dest_ptr + 12 ) = fill_word;
* rcast( u32*, dest_ptr + 16 ) = fill_word;
* rcast( u32*, dest_ptr + 20 ) = fill_word;
* rcast( u32*, dest_ptr + 24 ) = fill_word;
* rcast( u32*, dest_ptr + byte_count - 28 ) = fill_word;
* rcast( u32*, dest_ptr + byte_count - 24 ) = fill_word;
* rcast( u32*, dest_ptr + byte_count - 20 ) = fill_word;
* rcast( u32*, dest_ptr + byte_count - 16 ) = fill_word;
align_offset = 24 + to_uptr( dest_ptr ) & 4;
dest_ptr += align_offset;
byte_count -= align_offset;
{
u64 fill_doubleword = ( scast( u64, fill_word) << 32 ) | fill_word;
while ( byte_count > 31 )
{
* rcast( u64*, dest_ptr + 0 ) = fill_doubleword;
* rcast( u64*, dest_ptr + 8 ) = fill_doubleword;
* rcast( u64*, dest_ptr + 16 ) = fill_doubleword;
* rcast( u64*, dest_ptr + 24 ) = fill_doubleword;
byte_count -= 32;
dest_ptr += 32;
}
}
return destination;
}
inline
void* alloc_align( AllocatorInfo a, ssize size, ssize alignment ) {
return a.Proc( a.Data, EAllocation_ALLOC, size, alignment, nullptr, 0, GEN_DEFAULT_ALLOCATOR_FLAGS );
}
inline
void* alloc( AllocatorInfo a, ssize size ) {
return alloc_align( a, size, GEN_DEFAULT_MEMORY_ALIGNMENT );
}
inline
void allocator_free( AllocatorInfo a, void* ptr ) {
if ( ptr != nullptr )
a.Proc( a.Data, EAllocation_FREE, 0, 0, ptr, 0, GEN_DEFAULT_ALLOCATOR_FLAGS );
}
inline
void free_all( AllocatorInfo a ) {
a.Proc( a.Data, EAllocation_FREE_ALL, 0, 0, nullptr, 0, GEN_DEFAULT_ALLOCATOR_FLAGS );
}
inline
void* resize( AllocatorInfo a, void* ptr, ssize old_size, ssize new_size ) {
return resize_align( a, ptr, old_size, new_size, GEN_DEFAULT_MEMORY_ALIGNMENT );
}
inline
void* resize_align( AllocatorInfo a, void* ptr, ssize old_size, ssize new_size, ssize alignment ) {
return a.Proc( a.Data, EAllocation_RESIZE, new_size, alignment, ptr, old_size, GEN_DEFAULT_ALLOCATOR_FLAGS );
}
inline
void* default_resize_align( AllocatorInfo a, void* old_memory, ssize old_size, ssize new_size, ssize alignment )
{
if ( ! old_memory )
return alloc_align( a, new_size, alignment );
if ( new_size == 0 )
{
allocator_free( a, old_memory );
return nullptr;
}
if ( new_size < old_size )
new_size = old_size;
if ( old_size == new_size )
{
return old_memory;
}
else
{
void* new_memory = alloc_align( a, new_size, alignment );
if ( ! new_memory )
return nullptr;
mem_move( new_memory, old_memory, min( new_size, old_size ) );
allocator_free( a, old_memory );
return new_memory;
}
}
inline
void zero_size( void* ptr, ssize size ) {
mem_set( ptr, 0, size );
}
#pragma endregion Memory

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#ifdef GEN_INTELLISENSE_DIRECTIVES
# pragma once
# include "timing.hpp"
#endif
#pragma region ADT
enum ADT_Type : u32
{
EADT_TYPE_UNINITIALISED, /* node was not initialised, this is a programming error! */
EADT_TYPE_ARRAY,
EADT_TYPE_OBJECT,
EADT_TYPE_STRING,
EADT_TYPE_MULTISTRING,
EADT_TYPE_INTEGER,
EADT_TYPE_REAL,
};
enum ADT_Props : u32
{
EADT_PROPS_NONE,
EADT_PROPS_NAN,
EADT_PROPS_NAN_NEG,
EADT_PROPS_INFINITY,
EADT_PROPS_INFINITY_NEG,
EADT_PROPS_FALSE,
EADT_PROPS_TRUE,
EADT_PROPS_NULL,
EADT_PROPS_IS_EXP,
EADT_PROPS_IS_HEX,
// Used internally so that people can fill in real numbers they plan to write.
EADT_PROPS_IS_PARSED_REAL,
};
enum ADT_NamingStyle : u32
{
EADT_NAME_STYLE_DOUBLE_QUOTE,
EADT_NAME_STYLE_SINGLE_QUOTE,
EADT_NAME_STYLE_NO_QUOTES,
};
enum ADT_AssignStyle : u32
{
EADT_ASSIGN_STYLE_COLON,
EADT_ASSIGN_STYLE_EQUALS,
EADT_ASSIGN_STYLE_LINE,
};
enum ADT_DelimStyle : u32
{
EADT_DELIM_STYLE_COMMA,
EADT_DELIM_STYLE_LINE,
EADT_DELIM_STYLE_NEWLINE,
};
enum ADT_Error : u32
{
EADT_ERROR_NONE,
EADT_ERROR_INTERNAL,
EADT_ERROR_ALREADY_CONVERTED,
EADT_ERROR_INVALID_TYPE,
EADT_ERROR_OUT_OF_MEMORY,
};
struct ADT_Node
{
char const* name;
struct ADT_Node* parent;
/* properties */
ADT_Type type : 4;
u8 props : 4;
#ifndef GEN_PARSER_DISABLE_ANALYSIS
u8 cfg_mode : 1;
u8 name_style : 2;
u8 assign_style : 2;
u8 delim_style : 2;
u8 delim_line_width : 4;
u8 assign_line_width : 4;
#endif
/* adt data */
union
{
char const* string;
Array(ADT_Node) nodes; ///< zpl_array
struct
{
union
{
f64 real;
s64 integer;
};
#ifndef GEN_PARSER_DISABLE_ANALYSIS
/* number analysis */
s32 base;
s32 base2;
u8 base2_offset : 4;
s8 exp : 4;
u8 neg_zero : 1;
u8 lead_digit : 1;
#endif
};
};
};
/* ADT NODE LIMITS
* delimiter and assignment segment width is limited to 128 whitespace symbols each.
* real number limits decimal position to 128 places.
* real number exponent is limited to 64 digits.
*/
/**
* @brief Initialise an ADT object or array
*
* @param node
* @param backing Memory allocator used for descendants
* @param name Node's name
* @param is_array
* @return error code
*/
u8 adt_make_branch( ADT_Node* node, AllocatorInfo backing, char const* name, b32 is_array );
/**
* @brief Destroy an ADT branch and its descendants
*
* @param node
* @return error code
*/
u8 adt_destroy_branch( ADT_Node* node );
/**
* @brief Initialise an ADT leaf
*
* @param node
* @param name Node's name
* @param type Node's type (use zpl_adt_make_branch for container nodes)
* @return error code
*/
u8 adt_make_leaf( ADT_Node* node, char const* name, ADT_Type type );
/**
* @brief Fetch a node using provided URI string.
*
* This method uses a basic syntax to fetch a node from the ADT. The following features are available
* to retrieve the data:
*
* - "a/b/c" navigates through objects "a" and "b" to get to "c"
* - "arr/[foo=123]/bar" iterates over "arr" to find any object with param "foo" that matches the value "123", then gets its field called "bar"
* - "arr/3" retrieves the 4th element in "arr"
* - "arr/[apple]" retrieves the first element of value "apple" in "arr"
*
* @param node ADT node
* @param uri Locator string as described above
* @return zpl_adt_node*
*
* @see code/apps/examples/json_get.c
*/
ADT_Node* adt_query( ADT_Node* node, char const* uri );
/**
* @brief Find a field node within an object by the given name.
*
* @param node
* @param name
* @param deep_search Perform search recursively
* @return zpl_adt_node * node
*/
ADT_Node* adt_find( ADT_Node* node, char const* name, b32 deep_search );
/**
* @brief Allocate an unitialised node within a container at a specified index.
*
* @param parent
* @param index
* @return zpl_adt_node * node
*/
ADT_Node* adt_alloc_at( ADT_Node* parent, ssize index );
/**
* @brief Allocate an unitialised node within a container.
*
* @param parent
* @return zpl_adt_node * node
*/
ADT_Node* adt_alloc( ADT_Node* parent );
/**
* @brief Move an existing node to a new container at a specified index.
*
* @param node
* @param new_parent
* @param index
* @return zpl_adt_node * node
*/
ADT_Node* adt_move_node_at( ADT_Node* node, ADT_Node* new_parent, ssize index );
/**
* @brief Move an existing node to a new container.
*
* @param node
* @param new_parent
* @return zpl_adt_node * node
*/
ADT_Node* adt_move_node( ADT_Node* node, ADT_Node* new_parent );
/**
* @brief Swap two nodes.
*
* @param node
* @param other_node
* @return
*/
void adt_swap_nodes( ADT_Node* node, ADT_Node* other_node );
/**
* @brief Remove node from container.
*
* @param node
* @return
*/
void adt_remove_node( ADT_Node* node );
/**
* @brief Initialise a node as an object
*
* @param obj
* @param name
* @param backing
* @return
*/
b8 adt_set_obj( ADT_Node* obj, char const* name, AllocatorInfo backing );
/**
* @brief Initialise a node as an array
*
* @param obj
* @param name
* @param backing
* @return
*/
b8 adt_set_arr( ADT_Node* obj, char const* name, AllocatorInfo backing );
/**
* @brief Initialise a node as a string
*
* @param obj
* @param name
* @param value
* @return
*/
b8 adt_set_str( ADT_Node* obj, char const* name, char const* value );
/**
* @brief Initialise a node as a float
*
* @param obj
* @param name
* @param value
* @return
*/
b8 adt_set_flt( ADT_Node* obj, char const* name, f64 value );
/**
* @brief Initialise a node as a signed integer
*
* @param obj
* @param name
* @param value
* @return
*/
b8 adt_set_int( ADT_Node* obj, char const* name, s64 value );
/**
* @brief Append a new node to a container as an object
*
* @param parent
* @param name
* @return*
*/
ADT_Node* adt_append_obj( ADT_Node* parent, char const* name );
/**
* @brief Append a new node to a container as an array
*
* @param parent
* @param name
* @return*
*/
ADT_Node* adt_append_arr( ADT_Node* parent, char const* name );
/**
* @brief Append a new node to a container as a string
*
* @param parent
* @param name
* @param value
* @return*
*/
ADT_Node* adt_append_str( ADT_Node* parent, char const* name, char const* value );
/**
* @brief Append a new node to a container as a float
*
* @param parent
* @param name
* @param value
* @return*
*/
ADT_Node* adt_append_flt( ADT_Node* parent, char const* name, f64 value );
/**
* @brief Append a new node to a container as a signed integer
*
* @param parent
* @param name
* @param value
* @return*
*/
ADT_Node* adt_append_int( ADT_Node* parent, char const* name, s64 value );
/* parser helpers */
/**
* @brief Parses a text and stores the result into an unitialised node.
*
* @param node
* @param base
* @return*
*/
char* adt_parse_number( ADT_Node* node, char* base );
/**
* @brief Parses a text and stores the result into an unitialised node.
* This function expects the entire input to be a number.
*
* @param node
* @param base
* @return*
*/
char* adt_parse_number_strict( ADT_Node* node, char* base_str );
/**
* @brief Parses and converts an existing string node into a number.
*
* @param node
* @return
*/
ADT_Error adt_str_to_number( ADT_Node* node );
/**
* @brief Parses and converts an existing string node into a number.
* This function expects the entire input to be a number.
*
* @param node
* @return
*/
ADT_Error adt_str_to_number_strict( ADT_Node* node );
/**
* @brief Prints a number into a file stream.
*
* The provided file handle can also be a memory mapped stream.
*
* @see zpl_file_stream_new
* @param file
* @param node
* @return
*/
ADT_Error adt_print_number( FileInfo* file, ADT_Node* node );
/**
* @brief Prints a string into a file stream.
*
* The provided file handle can also be a memory mapped stream.
*
* @see zpl_file_stream_new
* @param file
* @param node
* @param escaped_chars
* @param escape_symbol
* @return
*/
ADT_Error adt_print_string( FileInfo* file, ADT_Node* node, char const* escaped_chars, char const* escape_symbol );
#pragma endregion ADT
#pragma region CSV
enum CSV_Error : u32
{
ECSV_Error__NONE,
ECSV_Error__INTERNAL,
ECSV_Error__UNEXPECTED_END_OF_INPUT,
ECSV_Error__MISMATCHED_ROWS,
};
typedef ADT_Node CSV_Object;
u8 csv_parse( CSV_Object* root, char* text, AllocatorInfo allocator, b32 has_header );
u8 csv_parse_delimiter( CSV_Object* root, char* text, AllocatorInfo allocator, b32 has_header, char delim );
void csv_free( CSV_Object* obj );
void csv_write( FileInfo* file, CSV_Object* obj );
String csv_write_string( AllocatorInfo a, CSV_Object* obj );
void csv_write_delimiter( FileInfo* file, CSV_Object* obj, char delim );
String csv_write_string_delimiter( AllocatorInfo a, CSV_Object* obj, char delim );
/* inline */
inline
u8 csv_parse( CSV_Object* root, char* text, AllocatorInfo allocator, b32 has_header )
{
return csv_parse_delimiter( root, text, allocator, has_header, ',' );
}
inline
void csv_write( FileInfo* file, CSV_Object* obj )
{
csv_write_delimiter( file, obj, ',' );
}
inline
String csv_write_string( AllocatorInfo a, CSV_Object* obj )
{
return csv_write_string_delimiter( a, obj, ',' );
}
#pragma endregion CSV

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#ifdef GEN_INTELLISENSE_DIRECTIVES
# pragma once
#endif
#pragma region Platform Detection
/* Platform architecture */
#if defined( _WIN64 ) || defined( __x86_64__ ) || defined( _M_X64 ) || defined( __64BIT__ ) || defined( __powerpc64__ ) || defined( __ppc64__ ) || defined( __aarch64__ )
# ifndef GEN_ARCH_64_BIT
# define GEN_ARCH_64_BIT 1
# endif
#else
# ifndef GEN_ARCH_32_BItxt_StrCaT
# define GEN_ARCH_32_BIT 1
# endif
#endif
/* Platform OS */
#if defined( _WIN32 ) || defined( _WIN64 )
# ifndef GEN_SYSTEM_WINDOWS
# define GEN_SYSTEM_WINDOWS 1
# endif
#elif defined( __APPLE__ ) && defined( __MACH__ )
# ifndef GEN_SYSTEM_OSX
# define GEN_SYSTEM_OSX 1
# endif
# ifndef GEN_SYSTEM_MACOS
# define GEN_SYSTEM_MACOS 1
# endif
#elif defined( __unix__ )
# ifndef GEN_SYSTEM_UNIX
# define GEN_SYSTEM_UNIX 1
# endif
# if defined( ANDROID ) || defined( __ANDROID__ )
# ifndef GEN_SYSTEM_ANDROID
# define GEN_SYSTEM_ANDROID 1
# endif
# ifndef GEN_SYSTEM_LINUX
# define GEN_SYSTEM_LINUX 1
# endif
# elif defined( __linux__ )
# ifndef GEN_SYSTEM_LINUX
# define GEN_SYSTEM_LINUX 1
# endif
# elif defined( __FreeBSD__ ) || defined( __FreeBSD_kernel__ )
# ifndef GEN_SYSTEM_FREEBSD
# define GEN_SYSTEM_FREEBSD 1
# endif
# elif defined( __OpenBSD__ )
# ifndef GEN_SYSTEM_OPENBSD
# define GEN_SYSTEM_OPENBSD 1
# endif
# elif defined( __EMSCRIPTEN__ )
# ifndef GEN_SYSTEM_EMSCRIPTEN
# define GEN_SYSTEM_EMSCRIPTEN 1
# endif
# elif defined( __CYGWIN__ )
# ifndef GEN_SYSTEM_CYGWIN
# define GEN_SYSTEM_CYGWIN 1
# endif
# else
# error This UNIX operating system is not supported
# endif
#else
# error This operating system is not supported
#endif
/* Platform compiler */
#if defined( _MSC_VER )
# pragma message("Detected MSVC")
// # define GEN_COMPILER_CLANG 0
# define GEN_COMPILER_MSVC 1
// # define GEN_COMPILER_GCC 0
#elif defined( __GNUC__ )
# pragma message("Detected GCC")
// # define GEN_COMPILER_CLANG 0
// # define GEN_COMPILER_MSVC 0
# define GEN_COMPILER_GCC 1
#elif defined( __clang__ )
# pragma message("Detected CLANG")
# define GEN_COMPILER_CLANG 1
// # define GEN_COMPILER_MSVC 0
// # define GEN_COMPILER_GCC 0
#else
# error Unknown compiler
#endif
#if defined( __has_attribute )
# define GEN_HAS_ATTRIBUTE( attribute ) __has_attribute( attribute )
#else
# define GEN_HAS_ATTRIBUTE( attribute ) ( 0 )
#endif
#if defined(GEN_GCC_VERSION_CHECK)
# undef GEN_GCC_VERSION_CHECK
#endif
#if defined(GEN_GCC_VERSION)
# define GEN_GCC_VERSION_CHECK(major,minor,patch) (GEN_GCC_VERSION >= GEN_VERSION_ENCODE(major, minor, patch))
#else
# define GEN_GCC_VERSION_CHECK(major,minor,patch) (0)
#endif
#if !defined(GEN_COMPILER_C)
# ifdef __cplusplus
# define GEN_COMPILER_C 0
# define GEN_COMPILER_CPP 1
# else
# if defined(__STDC__)
# define GEN_COMPILER_C 1
# define GEN_COMPILER_CPP 0
# else
// Fallback for very old C compilers
# define GEN_COMPILER_C 1
# define GEN_COMPILER_CPP 0
# endif
# endif
#endif
#if GEN_COMPILER_C
#pragma message("GENCPP: Detected C")
#endif
#pragma endregion Platform Detection
#pragma region Mandatory Includes
# include <stdarg.h>
# include <stddef.h>
# if defined( GEN_SYSTEM_WINDOWS )
# include <intrin.h>
# endif
#if GEN_COMPILER_C
#include <assert.h>
#include <stdbool.h>
#endif
#pragma endregion Mandatory Includes
#if GEN_DONT_USE_NAMESPACE || GEN_COMPILER_C
# if GEN_COMPILER_C
# define GEN_NS_PARSER_BEGIN
# define GEN_NS_PARSER_END
# define GEN_USING_NS_PARSER
# define GEN_NS_PARSER
# define GEN_NS
# define GEN_NS_BEGIN
# define GEN_NS_END
# else
# define GEN_NS_PARSER_BEGIN namespace parser {
# define GEN_NS_PARSER_END }
# define GEN_USING_NS_PARSER using namespace parser
# define GEN_NS_PARSER parser::
# define GEN_NS ::
# define GEN_NS_BEGIN
# define GEN_NS_END
# endif
#else
# define GEN_NS_PARSER_BEGIN namespace parser {
# define GEN_NS_PARSER_END }
# define GEN_NS_PARSER parser::
# define GEN_USING_NS_PARSER using namespace parser
# define GEN_NS gen::
# define GEN_NS_BEGIN namespace gen {
# define GEN_NS_END }
#endif

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#ifdef GEN_INTELLISENSE_DIRECTIVES
# pragma once
# include "string_ops.cpp"
#endif
#pragma region Printing
enum
{
GEN_FMT_MINUS = bit( 0 ),
GEN_FMT_PLUS = bit( 1 ),
GEN_FMT_ALT = bit( 2 ),
GEN_FMT_SPACE = bit( 3 ),
GEN_FMT_ZERO = bit( 4 ),
GEN_FMT_CHAR = bit( 5 ),
GEN_FMT_SHORT = bit( 6 ),
GEN_FMT_INT = bit( 7 ),
GEN_FMT_LONG = bit( 8 ),
GEN_FMT_LLONG = bit( 9 ),
GEN_FMT_SIZE = bit( 10 ),
GEN_FMT_INTPTR = bit( 11 ),
GEN_FMT_UNSIGNED = bit( 12 ),
GEN_FMT_LOWER = bit( 13 ),
GEN_FMT_UPPER = bit( 14 ),
GEN_FMT_WIDTH = bit( 15 ),
GEN_FMT_DONE = bit( 30 ),
GEN_FMT_INTS = GEN_FMT_CHAR | GEN_FMT_SHORT | GEN_FMT_INT | GEN_FMT_LONG | GEN_FMT_LLONG | GEN_FMT_SIZE | GEN_FMT_INTPTR
};
typedef struct _format_info _format_info;
struct _format_info
{
s32 base;
s32 flags;
s32 width;
s32 precision;
};
internal ssize _print_string( char* text, ssize max_len, _format_info* info, char const* str )
{
ssize res = 0, len = 0;
ssize remaining = max_len;
char* begin = text;
if ( str == NULL && max_len >= 6 )
{
res += str_copy_nulpad( text, "(null)", 6 );
return res;
}
if ( info && info->precision >= 0 )
// Made the design decision for this library that precision is the length of the string.
len = info->precision;
else
len = str_len( str );
if ( info && ( info->width == 0 && info->flags & GEN_FMT_WIDTH ) )
{
return res;
}
if ( info && ( info->width == 0 || info->flags & GEN_FMT_MINUS ) )
{
if ( info->precision > 0 )
len = info->precision < len ? info->precision : len;
if ( res + len > max_len )
return res;
res += str_copy_nulpad( text, str, len );
text += res;
if ( info->width > res )
{
ssize padding = info->width - len;
char pad = ( info->flags & GEN_FMT_ZERO ) ? '0' : ' ';
while ( padding-- > 0 && remaining-- > 0 )
*text++ = pad, res++;
}
}
else
{
if ( info && ( info->width > res ) )
{
ssize padding = info->width - len;
char pad = ( info->flags & GEN_FMT_ZERO ) ? '0' : ' ';
while ( padding-- > 0 && remaining-- > 0 )
*text++ = pad, res++;
}
if ( res + len > max_len )
return res;
res += str_copy_nulpad( text, str, len );
}
if ( info )
{
if ( info->flags & GEN_FMT_UPPER )
str_to_upper( begin );
else if ( info->flags & GEN_FMT_LOWER )
str_to_lower( begin );
}
return res;
}
internal ssize _print_char( char* text, ssize max_len, _format_info* info, char arg )
{
char str[ 2 ] = "";
str[ 0 ] = arg;
return _print_string( text, max_len, info, str );
}
internal ssize _print_repeated_char( char* text, ssize max_len, _format_info* info, char arg )
{
ssize res = 0;
s32 rem = ( info ) ? ( info->width > 0 ) ? info->width : 1 : 1;
res = rem;
while ( rem-- > 0 )
*text++ = arg;
return res;
}
internal ssize _print_i64( char* text, ssize max_len, _format_info* info, s64 value )
{
char num[ 130 ];
i64_to_str( value, num, info ? info->base : 10 );
return _print_string( text, max_len, info, num );
}
internal ssize _print_u64( char* text, ssize max_len, _format_info* info, u64 value )
{
char num[ 130 ];
u64_to_str( value, num, info ? info->base : 10 );
return _print_string( text, max_len, info, num );
}
internal ssize _print_f64( char* text, ssize max_len, _format_info* info, b32 is_hexadecimal, f64 arg )
{
// TODO: Handle exponent notation
ssize width, len, remaining = max_len;
char* text_begin = text;
if ( arg )
{
u64 value;
if ( arg < 0 )
{
if ( remaining > 1 )
*text = '-', remaining--;
text++;
arg = -arg;
}
else if ( info->flags & GEN_FMT_MINUS )
{
if ( remaining > 1 )
*text = '+', remaining--;
text++;
}
value = scast( u64, arg);
len = _print_u64( text, remaining, NULL, value );
text += len;
if ( len >= remaining )
remaining = min( remaining, 1 );
else
remaining -= len;
arg -= value;
if ( info->precision < 0 )
info->precision = 6;
if ( ( info->flags & GEN_FMT_ALT ) || info->precision > 0 )
{
s64 mult = 10;
if ( remaining > 1 )
*text = '.', remaining--;
text++;
while ( info->precision-- > 0 )
{
value = scast( u64, arg * mult );
len = _print_u64( text, remaining, NULL, value );
text += len;
if ( len >= remaining )
remaining = min( remaining, 1 );
else
remaining -= len;
arg -= scast( f64, value / mult);
mult *= 10;
}
}
}
else
{
if ( remaining > 1 )
*text = '0', remaining--;
text++;
if ( info->flags & GEN_FMT_ALT )
{
if ( remaining > 1 )
*text = '.', remaining--;
text++;
}
}
width = info->width - ( text - text_begin );
if ( width > 0 )
{
char fill = ( info->flags & GEN_FMT_ZERO ) ? '0' : ' ';
char* end = text + remaining - 1;
len = ( text - text_begin );
for ( len = ( text - text_begin ); len--; )
{
if ( ( text_begin + len + width ) < end )
*( text_begin + len + width ) = *( text_begin + len );
}
len = width;
text += len;
if ( len >= remaining )
remaining = min( remaining, 1 );
else
remaining -= len;
while ( len-- )
{
if ( text_begin + len < end )
text_begin[ len ] = fill;
}
}
return ( text - text_begin );
}
neverinline ssize str_fmt_va( char* text, ssize max_len, char const* fmt, va_list va )
{
char const* text_begin = text;
ssize remaining = max_len, res;
while ( *fmt )
{
_format_info info = { 0 };
ssize len = 0;
info.precision = -1;
while ( *fmt && *fmt != '%' && remaining )
*text++ = *fmt++;
if ( *fmt == '%' )
{
do
{
switch ( *++fmt )
{
case '-' :
{
info.flags |= GEN_FMT_MINUS;
break;
}
case '+' :
{
info.flags |= GEN_FMT_PLUS;
break;
}
case '#' :
{
info.flags |= GEN_FMT_ALT;
break;
}
case ' ' :
{
info.flags |= GEN_FMT_SPACE;
break;
}
case '0' :
{
info.flags |= ( GEN_FMT_ZERO | GEN_FMT_WIDTH );
break;
}
default :
{
info.flags |= GEN_FMT_DONE;
break;
}
}
} while ( ! ( info.flags & GEN_FMT_DONE ) );
}
// NOTE: Optional Width
if ( *fmt == '*' )
{
int width = va_arg( va, int );
if ( width < 0 )
{
info.flags |= GEN_FMT_MINUS;
info.width = -width;
}
else
{
info.width = width;
}
info.flags |= GEN_FMT_WIDTH;
fmt++;
}
else
{
info.width = scast( s32, str_to_i64( fmt, ccast( char**, & fmt), 10 ));
if ( info.width != 0 )
{
info.flags |= GEN_FMT_WIDTH;
}
}
// NOTE: Optional Precision
if ( *fmt == '.' )
{
fmt++;
if ( *fmt == '*' )
{
info.precision = va_arg( va, int );
fmt++;
}
else
{
info.precision = scast( s32, str_to_i64( fmt, ccast( char**, & fmt), 10 ));
}
info.flags &= ~GEN_FMT_ZERO;
}
switch ( *fmt++ )
{
case 'h' :
if ( *fmt == 'h' )
{ // hh => char
info.flags |= GEN_FMT_CHAR;
fmt++;
}
else
{ // h => short
info.flags |= GEN_FMT_SHORT;
}
break;
case 'l' :
if ( *fmt == 'l' )
{ // ll => long long
info.flags |= GEN_FMT_LLONG;
fmt++;
}
else
{ // l => long
info.flags |= GEN_FMT_LONG;
}
break;
break;
case 'z' : // NOTE: zpl_usize
info.flags |= GEN_FMT_UNSIGNED;
// fallthrough
case 't' : // NOTE: zpl_isize
info.flags |= GEN_FMT_SIZE;
break;
default :
fmt--;
break;
}
switch ( *fmt )
{
case 'u' :
info.flags |= GEN_FMT_UNSIGNED;
// fallthrough
case 'd' :
case 'i' :
info.base = 10;
break;
case 'o' :
info.base = 8;
break;
case 'x' :
info.base = 16;
info.flags |= ( GEN_FMT_UNSIGNED | GEN_FMT_LOWER );
break;
case 'X' :
info.base = 16;
info.flags |= ( GEN_FMT_UNSIGNED | GEN_FMT_UPPER );
break;
case 'f' :
case 'F' :
case 'g' :
case 'G' :
len = _print_f64( text, remaining, &info, 0, va_arg( va, f64 ) );
break;
case 'a' :
case 'A' :
len = _print_f64( text, remaining, &info, 1, va_arg( va, f64 ) );
break;
case 'c' :
len = _print_char( text, remaining, &info, scast( char, va_arg( va, int ) ));
break;
case 's' :
len = _print_string( text, remaining, &info, va_arg( va, char* ) );
break;
case 'S':
{
if ( *(fmt + 1) == 'C' )
{
++ fmt;
StrC gen_str = va_arg( va, StrC);
info.precision = gen_str.Len;
len = _print_string( text, remaining, &info, gen_str.Ptr );
break;
}
String gen_str = { va_arg( va, char*) };
info.precision = string_length(gen_str);
len = _print_string( text, remaining, &info, gen_str );
}
break;
case 'r' :
len = _print_repeated_char( text, remaining, &info, va_arg( va, int ) );
break;
case 'p' :
info.base = 16;
info.flags |= ( GEN_FMT_LOWER | GEN_FMT_UNSIGNED | GEN_FMT_ALT | GEN_FMT_INTPTR );
break;
case '%' :
len = _print_char( text, remaining, &info, '%' );
break;
default :
fmt--;
break;
}
fmt++;
if ( info.base != 0 )
{
if ( info.flags & GEN_FMT_UNSIGNED )
{
u64 value = 0;
switch ( info.flags & GEN_FMT_INTS )
{
case GEN_FMT_CHAR :
value = scast( u64, scast( u8, va_arg( va, int )));
break;
case GEN_FMT_SHORT :
value = scast( u64, scast( u16, va_arg( va, int )));
break;
case GEN_FMT_LONG:
value = scast( u64, va_arg( va, unsigned long ));
break;
case GEN_FMT_LLONG :
value = scast( u64, va_arg( va, unsigned long long ));
break;
case GEN_FMT_SIZE :
value = scast( u64, va_arg( va, usize ));
break;
case GEN_FMT_INTPTR :
value = scast( u64, va_arg( va, uptr ));
break;
default :
value = scast( u64, va_arg( va, unsigned int ));
break;
}
len = _print_u64( text, remaining, &info, value );
}
else
{
s64 value = 0;
switch ( info.flags & GEN_FMT_INTS )
{
case GEN_FMT_CHAR :
value = scast( s64, scast( s8, va_arg( va, int )));
break;
case GEN_FMT_SHORT :
value = scast( s64, scast( s16, va_arg( va, int )));
break;
case GEN_FMT_LONG :
value = scast( s64, va_arg( va, long ));
break;
case GEN_FMT_LLONG :
value = scast( s64, va_arg( va, long long ));
break;
case GEN_FMT_SIZE :
value = scast( s64, va_arg( va, usize ));
break;
case GEN_FMT_INTPTR :
value = scast( s64, va_arg( va, uptr ));
break;
default :
value = scast( s64, va_arg( va, int ));
break;
}
len = _print_i64( text, remaining, &info, value );
}
}
text += len;
if ( len >= remaining )
remaining = min( remaining, 1 );
else
remaining -= len;
}
*text++ = '\0';
res = ( text - text_begin );
return ( res >= max_len || res < 0 ) ? -1 : res;
}
char* str_fmt_buf_va( char const* fmt, va_list va )
{
local_persist thread_local char buffer[ GEN_PRINTF_MAXLEN ];
str_fmt_va( buffer, size_of( buffer ), fmt, va );
return buffer;
}
char* str_fmt_buf( char const* fmt, ... )
{
va_list va;
char* str;
va_start( va, fmt );
str = str_fmt_buf_va( fmt, va );
va_end( va );
return str;
}
ssize str_fmt_file_va( FileInfo* f, char const* fmt, va_list va )
{
local_persist thread_local char buf[ GEN_PRINTF_MAXLEN ];
ssize len = str_fmt_va( buf, size_of( buf ), fmt, va );
b32 res = file_write( f, buf, len - 1 ); // NOTE: prevent extra whitespace
return res ? len : -1;
}
ssize str_fmt_file( FileInfo* f, char const* fmt, ... )
{
ssize res;
va_list va;
va_start( va, fmt );
res = str_fmt_file_va( f, fmt, va );
va_end( va );
return res;
}
ssize str_fmt( char* str, ssize n, char const* fmt, ... )
{
ssize res;
va_list va;
va_start( va, fmt );
res = str_fmt_va( str, n, fmt, va );
va_end( va );
return res;
}
ssize str_fmt_out_va( char const* fmt, va_list va )
{
return str_fmt_file_va( file_get_standard( EFileStandard_OUTPUT ), fmt, va );
}
ssize str_fmt_out_err_va( char const* fmt, va_list va )
{
return str_fmt_file_va( file_get_standard( EFileStandard_ERROR ), fmt, va );
}
ssize str_fmt_out_err( char const* fmt, ... )
{
ssize res;
va_list va;
va_start( va, fmt );
res = str_fmt_out_err_va( fmt, va );
va_end( va );
return res;
}
#pragma endregion Printing

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#ifdef GEN_INTELLISENSE_DIRECTIVES
# pragma once
# include "string_ops.hpp"
#endif
#pragma region Printing
typedef struct FileInfo FileInfo;
#ifndef GEN_PRINTF_MAXLEN
# define GEN_PRINTF_MAXLEN kilobytes(128)
#endif
typedef char PrintF_Buffer[GEN_PRINTF_MAXLEN];
// NOTE: A locally persisting buffer is used internally
char* str_fmt_buf ( char const* fmt, ... );
char* str_fmt_buf_va ( char const* fmt, va_list va );
ssize str_fmt ( char* str, ssize n, char const* fmt, ... );
ssize str_fmt_va ( char* str, ssize n, char const* fmt, va_list va );
ssize str_fmt_out_va ( char const* fmt, va_list va );
ssize str_fmt_out_err ( char const* fmt, ... );
ssize str_fmt_out_err_va( char const* fmt, va_list va );
ssize str_fmt_file ( FileInfo* f, char const* fmt, ... );
ssize str_fmt_file_va ( FileInfo* f, char const* fmt, va_list va );
constexpr
char const* Msg_Invalid_Value = "INVALID VALUE PROVIDED";
inline
ssize log_fmt(char const* fmt, ...)
{
ssize res;
va_list va;
va_start(va, fmt);
res = str_fmt_out_va(fmt, va);
va_end(va);
return res;
}
#pragma endregion Printing

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#ifdef GEN_INTELLISENSE_DIRECTIVES
# pragma once
# include "header_start.hpp"
#endif
#pragma region Macros and Includes
# include <stdio.h>
// NOTE: Ensure we use standard methods for these calls if we use GEN_PICO
# if ! defined( GEN_PICO_CUSTOM_ROUTINES )
# if ! defined( GEN_MODULE_CORE )
# define _strlen strlen
# define _printf_err( fmt, ... ) fprintf( stderr, fmt, __VA_ARGS__ )
# define _printf_err_va( fmt, va ) vfprintf( stderr, fmt, va )
# else
# define _strlen str_len
# define _printf_err( fmt, ... ) str_fmt_out_err( fmt, __VA_ARGS__ )
# define _printf_err_va( fmt, va ) str_fmt_out_err_va( fmt, va )
# endif
# endif
#
# include <errno.h>
#
# if defined( GEN_SYSTEM_UNIX ) || defined( GEN_SYSTEM_MACOS )
# include <unistd.h>
# elif defined( GEN_SYSTEM_WINDOWS )
# if ! defined( GEN_NO_WINDOWS_H )
# ifndef WIN32_LEAN_AND_MEAN
# ifndef NOMINMAX
# define NOMINMAX
# endif
#
# define WIN32_LEAN_AND_MEAN
# define WIN32_MEAN_AND_LEAN
# define VC_EXTRALEAN
# endif
# include <windows.h>
# undef NOMINMAX
# undef WIN32_LEAN_AND_MEAN
# undef WIN32_MEAN_AND_LEAN
# undef VC_EXTRALEAN
# endif
# endif
#include <sys/stat.h>
#ifdef GEN_SYSTEM_MACOS
# include <copyfile.h>
#endif
#ifdef GEN_SYSTEM_CYGWIN
# include <windows.h>
#endif
#if defined( GEN_SYSTEM_WINDOWS ) && ! defined( GEN_COMPILER_GCC )
# include <io.h>
#endif
#if defined( GEN_SYSTEM_LINUX )
# include <sys/types.h>
#endif
#ifdef GEN_BENCHMARK
// Timing includes
#if defined( GEN_SYSTEM_MACOS ) || GEN_SYSTEM_UNIX
# include <time.h>
# include <sys/time.h>
#endif
#if defined( GEN_SYSTEM_MACOS )
# include <mach/mach.h>
# include <mach/mach_time.h>
# include <mach/clock.h>
#endif
#if defined( GEN_SYSTEM_EMSCRIPTEN )
# include <emscripten.h>
#endif
#if defined( GEN_SYSTEM_WINDOWS )
# include <timezoneapi.h>
#endif
#endif
#pragma endregion Macros and Includes

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#ifdef GEN_INTELLISENSE_DIRECTIVES
# pragma once
# include "debug.cpp"
#endif
#pragma region String Ops
internal
ssize _scan_zpl_i64( const char* text, s32 base, s64* value )
{
const char* text_begin = text;
s64 result = 0;
b32 negative = false;
if ( *text == '-' )
{
negative = true;
text++;
}
if ( base == 16 && str_compare_len( text, "0x", 2 ) == 0 )
text += 2;
for ( ;; )
{
s64 v;
if ( char_is_digit( *text ) )
v = *text - '0';
else if ( base == 16 && char_is_hex_digit( *text ) )
v = hex_digit_to_int( *text );
else
break;
result *= base;
result += v;
text++;
}
if ( value )
{
if ( negative )
result = -result;
*value = result;
}
return ( text - text_begin );
}
// TODO : Are these good enough for characters?
global const char _num_to_char_table[] =
"0123456789"
"ABCDEFGHIJKLMNOPQRSTUVWXYZ"
"abcdefghijklmnopqrstuvwxyz"
"@$";
s64 str_to_i64( const char* str, char** end_ptr, s32 base )
{
ssize len;
s64 value;
if ( ! base )
{
if ( ( str_len( str ) > 2 ) && ( str_compare_len( str, "0x", 2 ) == 0 ) )
base = 16;
else
base = 10;
}
len = _scan_zpl_i64( str, base, &value );
if ( end_ptr )
*end_ptr = ( char* )str + len;
return value;
}
void i64_to_str( s64 value, char* string, s32 base )
{
char* buf = string;
b32 negative = false;
u64 v;
if ( value < 0 )
{
negative = true;
value = -value;
}
v = scast( u64, value);
if ( v != 0 )
{
while ( v > 0 )
{
*buf++ = _num_to_char_table[ v % base ];
v /= base;
}
}
else
{
*buf++ = '0';
}
if ( negative )
*buf++ = '-';
*buf = '\0';
str_reverse( string );
}
void u64_to_str( u64 value, char* string, s32 base )
{
char* buf = string;
if ( value )
{
while ( value > 0 )
{
*buf++ = _num_to_char_table[ value % base ];
value /= base;
}
}
else
{
*buf++ = '0';
}
*buf = '\0';
str_reverse( string );
}
f64 str_to_f64( const char* str, char** end_ptr )
{
f64 result, value, sign, scale;
s32 frac;
while ( char_is_space( *str ) )
{
str++;
}
sign = 1.0;
if ( *str == '-' )
{
sign = -1.0;
str++;
}
else if ( *str == '+' )
{
str++;
}
for ( value = 0.0; char_is_digit( *str ); str++ )
{
value = value * 10.0 + ( *str - '0' );
}
if ( *str == '.' )
{
f64 pow10 = 10.0;
str++;
while ( char_is_digit( *str ) )
{
value += ( *str - '0' ) / pow10;
pow10 *= 10.0;
str++;
}
}
frac = 0;
scale = 1.0;
if ( ( *str == 'e' ) || ( *str == 'E' ) )
{
u32 exp;
str++;
if ( *str == '-' )
{
frac = 1;
str++;
}
else if ( *str == '+' )
{
str++;
}
for ( exp = 0; char_is_digit( *str ); str++ )
{
exp = exp * 10 + ( *str - '0' );
}
if ( exp > 308 )
exp = 308;
while ( exp >= 50 )
{
scale *= 1e50;
exp -= 50;
}
while ( exp >= 8 )
{
scale *= 1e8;
exp -= 8;
}
while ( exp > 0 )
{
scale *= 10.0;
exp -= 1;
}
}
result = sign * ( frac ? ( value / scale ) : ( value * scale ) );
if ( end_ptr )
* end_ptr = rcast( char*, ccast(char*, str) );
return result;
}
#pragma endregion String Ops

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#ifdef GEN_INTELLISENSE_DIRECTIVES
# pragma once
# include "memory.hpp"
#endif
#pragma region String Ops
const char* char_first_occurence( const char* str, char c );
b32 char_is_alpha( char c );
b32 char_is_alphanumeric( char c );
b32 char_is_digit( char c );
b32 char_is_hex_digit( char c );
b32 char_is_space( char c );
char char_to_lower( char c );
char char_to_upper( char c );
s32 digit_to_int( char c );
s32 hex_digit_to_int( char c );
s32 str_compare( const char* s1, const char* s2 );
s32 str_compare_len( const char* s1, const char* s2, ssize len );
char* str_copy( char* dest, const char* source, ssize len );
ssize str_copy_nulpad( char* dest, const char* source, ssize len );
ssize str_len( const char* str );
ssize str_len_capped( const char* str, ssize max_len );
char* str_reverse( char* str ); // NOTE: ASCII only
char const* str_skip( char const* str, char c );
char const* str_skip_any( char const* str, char const* char_list );
char const* str_trim( char const* str, b32 catch_newline );
// NOTE: ASCII only
void str_to_lower( char* str );
void str_to_upper( char* str );
s64 str_to_i64( const char* str, char** end_ptr, s32 base );
void i64_to_str( s64 value, char* string, s32 base );
void u64_to_str( u64 value, char* string, s32 base );
f64 str_to_f64( const char* str, char** end_ptr );
inline
const char* char_first_occurence( const char* s, char c )
{
char ch = c;
for ( ; *s != ch; s++ )
{
if ( *s == '\0' )
return NULL;
}
return s;
}
inline
b32 char_is_alpha( char c )
{
if ( ( c >= 'A' && c <= 'Z' ) || ( c >= 'a' && c <= 'z' ) )
return true;
return false;
}
inline
b32 char_is_alphanumeric( char c )
{
return char_is_alpha( c ) || char_is_digit( c );
}
inline
b32 char_is_digit( char c )
{
if ( c >= '0' && c <= '9' )
return true;
return false;
}
inline
b32 char_is_hex_digit( char c )
{
if ( char_is_digit( c ) || ( c >= 'a' && c <= 'f' ) || ( c >= 'A' && c <= 'F' ) )
return true;
return false;
}
inline
b32 char_is_space( char c )
{
if ( c == ' ' || c == '\t' || c == '\n' || c == '\r' || c == '\f' || c == '\v' )
return true;
return false;
}
inline
char char_to_lower( char c )
{
if ( c >= 'A' && c <= 'Z' )
return 'a' + ( c - 'A' );
return c;
}
inline char char_to_upper( char c )
{
if ( c >= 'a' && c <= 'z' )
return 'A' + ( c - 'a' );
return c;
}
inline
s32 digit_to_int( char c )
{
return char_is_digit( c ) ? c - '0' : c - 'W';
}
inline
s32 hex_digit_to_int( char c )
{
if ( char_is_digit( c ) )
return digit_to_int( c );
else if ( is_between( c, 'a', 'f' ) )
return c - 'a' + 10;
else if ( is_between( c, 'A', 'F' ) )
return c - 'A' + 10;
return -1;
}
inline
s32 str_compare( const char* s1, const char* s2 )
{
while ( *s1 && ( *s1 == *s2 ) )
{
s1++, s2++;
}
return *( u8* )s1 - *( u8* )s2;
}
inline
s32 str_compare_len( const char* s1, const char* s2, ssize len )
{
for ( ; len > 0; s1++, s2++, len-- )
{
if ( *s1 != *s2 )
return ( ( s1 < s2 ) ? -1 : +1 );
else if ( *s1 == '\0' )
return 0;
}
return 0;
}
inline
char* str_copy( char* dest, const char* source, ssize len )
{
GEN_ASSERT_NOT_NULL( dest );
if ( source )
{
char* str = dest;
while ( len > 0 && *source )
{
*str++ = *source++;
len--;
}
while ( len > 0 )
{
*str++ = '\0';
len--;
}
}
return dest;
}
inline
ssize str_copy_nulpad( char* dest, const char* source, ssize len )
{
ssize result = 0;
GEN_ASSERT_NOT_NULL( dest );
if ( source )
{
const char* source_start = source;
char* str = dest;
while ( len > 0 && *source )
{
*str++ = *source++;
len--;
}
while ( len > 0 )
{
*str++ = '\0';
len--;
}
result = source - source_start;
}
return result;
}
inline
ssize str_len( const char* str )
{
if ( str == NULL )
{
return 0;
}
const char* p = str;
while ( *str )
str++;
return str - p;
}
inline
ssize str_len_capped( const char* str, ssize max_len )
{
const char* end = rcast(const char*, mem_find( str, 0, max_len ));
if ( end )
return end - str;
return max_len;
}
inline
char* str_reverse( char* str )
{
ssize len = str_len( str );
char* a = str + 0;
char* b = str + len - 1;
len /= 2;
while ( len-- )
{
swap( *a, *b );
a++, b--;
}
return str;
}
inline
char const* str_skip( char const* str, char c )
{
while ( *str && *str != c )
{
++str;
}
return str;
}
inline
char const* str_skip_any( char const* str, char const* char_list )
{
char const* closest_ptr = rcast( char const*, pointer_add_const( rcast(mem_ptr_const, str), str_len( str ) ));
ssize char_list_count = str_len( char_list );
for ( ssize i = 0; i < char_list_count; i++ )
{
char const* p = str_skip( str, char_list[ i ] );
closest_ptr = min( closest_ptr, p );
}
return closest_ptr;
}
inline
char const* str_trim( char const* str, b32 catch_newline )
{
while ( *str && char_is_space( *str ) && ( ! catch_newline || ( catch_newline && *str != '\n' ) ) )
{
++str;
}
return str;
}
inline
void str_to_lower( char* str )
{
if ( ! str )
return;
while ( *str )
{
*str = char_to_lower( *str );
str++;
}
}
inline
void str_to_upper( char* str )
{
if ( ! str )
return;
while ( *str )
{
*str = char_to_upper( *str );
str++;
}
}
#pragma endregion String Ops

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#ifdef GEN_INTELLISENSE_DIRECTIVES
# pragma once
# include "hashing.cpp"
#endif
#pragma region String
String string_make_length( AllocatorInfo allocator, char const* str, ssize length )
{
ssize const header_size = sizeof( StringHeader );
s32 alloc_size = header_size + length + 1;
void* allocation = alloc( allocator, alloc_size );
if ( allocation == nullptr ) {
String null_string = {nullptr};
return null_string;
}
StringHeader*
header = rcast(StringHeader*, allocation);
header->Allocator = allocator;
header->Capacity = length;
header->Length = length;
String result = { rcast( char*, allocation) + header_size };
if ( length && str )
mem_copy( result, str, length );
else
mem_set( result, 0, alloc_size - header_size );
result[ length ] = '\0';
return result;
}
String string_make_reserve( AllocatorInfo allocator, ssize capacity )
{
ssize const header_size = sizeof( StringHeader );
s32 alloc_size = header_size + capacity + 1;
void* allocation = alloc( allocator, alloc_size );
if ( allocation == nullptr ) {
String null_string = {nullptr};
return null_string;
}
mem_set( allocation, 0, alloc_size );
StringHeader*
header = rcast(StringHeader*, allocation);
header->Allocator = allocator;
header->Capacity = capacity;
header->Length = 0;
String result = { rcast(char*, allocation) + header_size };
return result;
}
#pragma endregion String

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#ifdef GEN_INTELLISENSE_DIRECTIVES
# pragma once
# include "hashing.hpp"
#endif
#pragma region Strings
struct StrC;
StrC to_strc_from_c_str (char const* bad_string);
bool strc_are_equal (StrC lhs, StrC rhs);
char const* strc_back (StrC str);
bool strc_contains (StrC str, StrC substring);
StrC strc_duplicate (StrC str, AllocatorInfo allocator);
b32 strc_starts_with (StrC str, StrC substring);
StrC strc_visualize_whitespace(StrC str, AllocatorInfo allocator);
// Constant string with length.
struct StrC
{
ssize Len;
char const* Ptr;
#if GEN_COMPILER_CPP
forceinline operator char const* () const { return Ptr; }
forceinline char const& operator[]( ssize index ) const { return Ptr[index]; }
#if ! GEN_C_LIKE_CPP
forceinline bool is_equal (StrC rhs) const { return strc_are_equal(* this, rhs); }
forceinline char const* back () const { return strc_back(* this); }
forceinline bool contains (StrC substring) const { return strc_contains(* this, substring); }
forceinline StrC duplicate (AllocatorInfo allocator) const { return strc_duplicate(* this, allocator); }
forceinline b32 starts_with (StrC substring) const { return strc_starts_with(* this, substring); }
forceinline StrC visualize_whitespace(AllocatorInfo allocator) const { return strc_visualize_whitespace(* this, allocator); }
#endif
#endif
};
#define cast_to_strc( str ) * rcast( StrC*, (str) - sizeof(ssize) )
#ifndef txt
# if GEN_COMPILER_CPP
# define txt( text ) StrC { sizeof( text ) - 1, ( text ) }
# else
# define txt( text ) (StrC){ sizeof( text ) - 1, ( text ) }
# endif
#endif
GEN_API_C_BEGIN
forceinline char const* strc_begin(StrC str) { return str.Ptr; }
forceinline char const* strc_end (StrC str) { return str.Ptr + str.Len; }
forceinline char const* strc_next (StrC str, char const* iter) { return iter + 1; }
GEN_API_C_END
#if GEN_COMPILER_CPP
forceinline char const* begin(StrC str) { return str.Ptr; }
forceinline char const* end (StrC str) { return str.Ptr + str.Len; }
forceinline char const* next (StrC str, char const* iter) { return iter + 1; }
#endif
inline
bool strc_are_equal(StrC lhs, StrC rhs)
{
if (lhs.Len != rhs.Len)
return false;
for (ssize idx = 0; idx < lhs.Len; ++idx)
if (lhs.Ptr[idx] != rhs.Ptr[idx])
return false;
return true;
}
inline
char const* strc_back(StrC str) {
return & str.Ptr[str.Len - 1];
}
inline
bool strc_contains(StrC str, StrC substring)
{
if (substring.Len > str.Len)
return false;
ssize main_len = str.Len;
ssize sub_len = substring.Len;
for (ssize idx = 0; idx <= main_len - sub_len; ++idx)
{
if (str_compare_len(str.Ptr + idx, substring.Ptr, sub_len) == 0)
return true;
}
return false;
}
inline
b32 strc_starts_with(StrC str, StrC substring) {
if (substring.Len > str.Len)
return false;
b32 result = str_compare_len(str.Ptr, substring.Ptr, substring.Len) == 0;
return result;
}
inline
StrC to_strc_from_c_str( char const* bad_str ) {
StrC result = { str_len( bad_str ), bad_str };
return result;
}
// Dynamic String
// This is directly based off the ZPL string api.
// They used a header pattern
// I kept it for simplicty of porting but its not necessary to keep it that way.
#pragma region String
struct StringHeader;
#if GEN_COMPILER_C
typedef char* String;
#else
struct String;
#endif
forceinline usize string_grow_formula(usize value);
String string_make_c_str (AllocatorInfo allocator, char const* str);
String string_make_strc (AllocatorInfo allocator, StrC str);
String string_make_reserve (AllocatorInfo allocator, ssize capacity);
String string_make_length (AllocatorInfo allocator, char const* str, ssize length);
String string_fmt (AllocatorInfo allocator, char* buf, ssize buf_size, char const* fmt, ...);
String string_fmt_buf (AllocatorInfo allocator, char const* fmt, ...);
String string_join (AllocatorInfo allocator, char const** parts, ssize num_parts, char const* glue);
bool string_are_equal (String const lhs, String const rhs);
bool string_are_equal_strc (String const lhs, StrC rhs);
bool string_make_space_for (String* str, char const* to_append, ssize add_len);
bool string_append_char (String* str, char c);
bool string_append_c_str (String* str, char const* str_to_append);
bool string_append_c_str_len (String* str, char const* str_to_append, ssize length);
bool string_append_strc (String* str, StrC str_to_append);
bool string_append_string (String* str, String const other);
bool string_append_fmt (String* str, char const* fmt, ...);
ssize string_avail_space (String const str);
char* string_back (String str);
bool string_contains_strc (String const str, StrC substring);
bool string_contains_string (String const str, String const substring);
ssize string_capacity (String const str);
void string_clear (String str);
String string_duplicate (String const str, AllocatorInfo allocator);
void string_free (String* str);
StringHeader* string_get_header (String str);
ssize string_length (String const str);
b32 string_starts_with_strc (String const str, StrC substring);
b32 string_starts_with_string (String const str, String substring);
void string_skip_line (String str);
void string_strip_space (String str);
StrC string_to_strc (String str);
void string_trim (String str, char const* cut_set);
void string_trim_space (String str);
String string_visualize_whitespace(String const str);
struct StringHeader {
AllocatorInfo Allocator;
ssize Capacity;
ssize Length;
};
#if GEN_COMPILER_CPP
struct String
{
char* Data;
forceinline operator char*() { return Data; }
forceinline operator char const*() const { return Data; }
forceinline operator StrC() const { return { string_length(* this), Data }; }
String const& operator=(String const& other) const {
if (this == &other)
return *this;
String* this_ = ccast(String*, this);
this_->Data = other.Data;
return *this;
}
forceinline char& operator[](ssize index) { return Data[index]; }
forceinline char const& operator[](ssize index) const { return Data[index]; }
forceinline bool operator==(std::nullptr_t) const { return Data == nullptr; }
forceinline bool operator!=(std::nullptr_t) const { return Data != nullptr; }
friend forceinline bool operator==(std::nullptr_t, const String str) { return str.Data == nullptr; }
friend forceinline bool operator!=(std::nullptr_t, const String str) { return str.Data != nullptr; }
#if ! GEN_C_LIKE_CPP
forceinline char* begin() const { return Data; }
forceinline char* end() const { return Data + string_length(* this); }
#pragma region Member Mapping
forceinline static String make(AllocatorInfo allocator, char const* str) { return string_make_c_str(allocator, str); }
forceinline static String make(AllocatorInfo allocator, StrC str) { return string_make_strc(allocator, str); }
forceinline static String make_reserve(AllocatorInfo allocator, ssize cap) { return string_make_reserve(allocator, cap); }
forceinline static String make_length(AllocatorInfo a, char const* s, ssize l) { return string_make_length(a, s, l); }
forceinline static String join(AllocatorInfo a, char const** p, ssize n, char const* g) { return string_join(a, p, n, g); }
forceinline static usize grow_formula(usize value) { return string_grow_formula(value); }
static
String fmt(AllocatorInfo allocator, char* buf, ssize buf_size, char const* fmt, ...) {
va_list va;
va_start(va, fmt);
ssize res = str_fmt_va(buf, buf_size, fmt, va) - 1;
va_end(va);
return string_make_length(allocator, buf, res);
}
static
String fmt_buf(AllocatorInfo allocator, char const* fmt, ...) {
local_persist thread_local
char buf[GEN_PRINTF_MAXLEN] = { 0 };
va_list va;
va_start(va, fmt);
ssize res = str_fmt_va(buf, GEN_PRINTF_MAXLEN, fmt, va) - 1;
va_end(va);
return string_make_length(allocator, buf, res);
}
forceinline bool make_space_for(char const* str, ssize add_len) { return string_make_space_for(this, str, add_len); }
forceinline bool append(char c) { return string_append_char(this, c); }
forceinline bool append(char const* str) { return string_append_c_str(this, str); }
forceinline bool append(char const* str, ssize length) { return string_append_c_str_len(this, str, length); }
forceinline bool append(StrC str) { return string_append_strc(this, str); }
forceinline bool append(const String other) { return string_append_string(this, other); }
forceinline ssize avail_space() const { return string_avail_space(* this); }
forceinline char* back() { return string_back(* this); }
forceinline bool contains(StrC substring) const { return string_contains_strc(* this, substring); }
forceinline bool contains(String const& substring) const { return string_contains_string(* this, substring); }
forceinline ssize capacity() const { return string_capacity(* this); }
forceinline void clear() { string_clear(* this); }
forceinline String duplicate(AllocatorInfo allocator) const { return string_duplicate(* this, allocator); }
forceinline void free() { string_free(this); }
forceinline bool is_equal(String const& other) const { return string_are_equal(* this, other); }
forceinline bool is_equal(StrC other) const { return string_are_equal_strc(* this, other); }
forceinline ssize length() const { return string_length(* this); }
forceinline b32 starts_with(StrC substring) const { return string_starts_with_strc(* this, substring); }
forceinline b32 starts_with(String substring) const { return string_starts_with_string(* this, substring); }
forceinline void skip_line() { string_skip_line(* this); }
forceinline void strip_space() { string_strip_space(* this); }
forceinline StrC to_strc() { return { string_length(*this), Data}; }
forceinline void trim(char const* cut_set) { string_trim(* this, cut_set); }
forceinline void trim_space() { string_trim_space(* this); }
forceinline String visualize_whitespace() const { return string_visualize_whitespace(* this); }
forceinline StringHeader& get_header() { return * string_get_header(* this); }
bool append_fmt(char const* fmt, ...) {
ssize res;
char buf[GEN_PRINTF_MAXLEN] = { 0 };
va_list va;
va_start(va, fmt);
res = str_fmt_va(buf, count_of(buf) - 1, fmt, va) - 1;
va_end(va);
return string_append_c_str_len(this, buf, res);
}
#pragma endregion Member Mapping
#endif
};
#endif
forceinline char* string_begin(String str) { return ((char*) str); }
forceinline char* string_end (String str) { return ((char*) str + string_length(str)); }
forceinline char* string_next (String str, char const* iter) { return ((char*) iter + 1); }
#if GEN_COMPILER_CPP && ! GEN_C_LIKE_CPP
forceinline char* begin(String str) { return ((char*) str); }
forceinline char* end (String str) { return ((char*) str + string_length(str)); }
forceinline char* next (String str, char* iter) { return ((char*) iter + 1); }
#endif
#if GEN_COMPILER_CPP && ! GEN_C_LIKE_CPP
forceinline bool make_space_for(String& str, char const* to_append, ssize add_len);
forceinline bool append(String& str, char c);
forceinline bool append(String& str, char const* str_to_append);
forceinline bool append(String& str, char const* str_to_append, ssize length);
forceinline bool append(String& str, StrC str_to_append);
forceinline bool append(String& str, const String other);
forceinline bool append_fmt(String& str, char const* fmt, ...);
forceinline char& back(String& str);
forceinline void clear(String& str);
forceinline void free(String& str);
#endif
forceinline
usize string_grow_formula(usize value) {
// Using a very aggressive growth formula to reduce time mem_copying with recursive calls to append in this library.
return 4 * value + 8;
}
forceinline
String string_make_c_str(AllocatorInfo allocator, char const* str) {
ssize length = str ? str_len(str) : 0;
return string_make_length(allocator, str, length);
}
forceinline
String string_make_strc(AllocatorInfo allocator, StrC str) {
return string_make_length(allocator, str.Ptr, str.Len);
}
inline
String string_fmt(AllocatorInfo allocator, char* buf, ssize buf_size, char const* fmt, ...) {
va_list va;
va_start(va, fmt);
ssize res = str_fmt_va(buf, buf_size, fmt, va) - 1;
va_end(va);
return string_make_length(allocator, buf, res);
}
inline
String string_fmt_buf(AllocatorInfo allocator, char const* fmt, ...)
{
local_persist thread_local
PrintF_Buffer buf = struct_init(PrintF_Buffer, {0});
va_list va;
va_start(va, fmt);
ssize res = str_fmt_va(buf, GEN_PRINTF_MAXLEN, fmt, va) -1;
va_end(va);
return string_make_length(allocator, buf, res);
}
inline
String string_join(AllocatorInfo allocator, char const** parts, ssize num_parts, char const* glue)
{
String result = string_make_c_str(allocator, "");
for (ssize idx = 0; idx < num_parts; ++idx)
{
string_append_c_str(& result, parts[idx]);
if (idx < num_parts - 1)
string_append_c_str(& result, glue);
}
return result;
}
forceinline
bool string_append_char(String* str, char c) {
GEN_ASSERT(str != nullptr);
return string_append_c_str_len( str, (char const*)& c, (ssize)1);
}
forceinline
bool string_append_c_str(String* str, char const* str_to_append) {
GEN_ASSERT(str != nullptr);
return string_append_c_str_len(str, str_to_append, str_len(str_to_append));
}
inline
bool string_append_c_str_len(String* str, char const* str_to_append, ssize append_length)
{
GEN_ASSERT(str != nullptr);
if ( rcast(sptr, str_to_append) > 0)
{
ssize curr_len = string_length(* str);
if ( ! string_make_space_for(str, str_to_append, append_length))
return false;
StringHeader* header = string_get_header(* str);
char* Data = * str;
mem_copy( Data + curr_len, str_to_append, append_length);
Data[curr_len + append_length] = '\0';
header->Length = curr_len + append_length;
}
return str_to_append != nullptr;
}
forceinline
bool string_append_strc(String* str, StrC str_to_append) {
GEN_ASSERT(str != nullptr);
return string_append_c_str_len(str, str_to_append.Ptr, str_to_append.Len);
}
forceinline
bool string_append_string(String* str, String const other) {
GEN_ASSERT(str != nullptr);
return string_append_c_str_len(str, (char const*)other, string_length(other));
}
bool string_append_fmt(String* str, char const* fmt, ...) {
GEN_ASSERT(str != nullptr);
ssize res;
char buf[GEN_PRINTF_MAXLEN] = { 0 };
va_list va;
va_start(va, fmt);
res = str_fmt_va(buf, count_of(buf) - 1, fmt, va) - 1;
va_end(va);
return string_append_c_str_len(str, (char const*)buf, res);
}
inline
bool string_are_equal_string(String const lhs, String const rhs)
{
if (string_length(lhs) != string_length(rhs))
return false;
for (ssize idx = 0; idx < string_length(lhs); ++idx)
if (lhs[idx] != rhs[idx])
return false;
return true;
}
inline
bool string_are_equal_strc(String const lhs, StrC rhs)
{
if (string_length(lhs) != (rhs.Len))
return false;
for (ssize idx = 0; idx < string_length(lhs); ++idx)
if (lhs[idx] != rhs.Ptr[idx])
return false;
return true;
}
forceinline
ssize string_avail_space(String const str) {
StringHeader const* header = rcast(StringHeader const*, scast(char const*, str) - sizeof(StringHeader));
return header->Capacity - header->Length;
}
forceinline
char* string_back(String str) {
return & (str)[string_length(str) - 1];
}
inline
bool string_contains_StrC(String const str, StrC substring)
{
StringHeader const* header = rcast(StringHeader const*, scast(char const*, str) - sizeof(StringHeader));
if (substring.Len > header->Length)
return false;
ssize main_len = header->Length;
ssize sub_len = substring.Len;
for (ssize idx = 0; idx <= main_len - sub_len; ++idx)
{
if (str_compare_len(str + idx, substring.Ptr, sub_len) == 0)
return true;
}
return false;
}
inline
bool string_contains_string(String const str, String const substring)
{
StringHeader const* header = rcast(StringHeader const*, scast(char const*, str) - sizeof(StringHeader));
if (string_length(substring) > header->Length)
return false;
ssize main_len = header->Length;
ssize sub_len = string_length(substring);
for (ssize idx = 0; idx <= main_len - sub_len; ++idx)
{
if (str_compare_len(str + idx, substring, sub_len) == 0)
return true;
}
return false;
}
forceinline
ssize string_capacity(String const str) {
StringHeader const* header = rcast(StringHeader const*, scast(char const*, str) - sizeof(StringHeader));
return header->Capacity;
}
forceinline
void string_clear(String str) {
string_get_header(str)->Length = 0;
}
forceinline
String string_duplicate(String const str, AllocatorInfo allocator) {
return string_make_length(allocator, str, string_length(str));
}
forceinline
void string_free(String* str) {
GEN_ASSERT(str != nullptr);
if (! (* str))
return;
StringHeader* header = string_get_header(* str);
allocator_free(header->Allocator, header);
}
forceinline
StringHeader* string_get_header(String str) {
return (StringHeader*)(scast(char*, str) - sizeof(StringHeader));
}
forceinline
ssize string_length(String const str)
{
StringHeader const* header = rcast(StringHeader const*, scast(char const*, str) - sizeof(StringHeader));
return header->Length;
}
inline
bool string_make_space_for(String* str, char const* to_append, ssize add_len)
{
ssize available = string_avail_space(* str);
if (available >= add_len) {
return true;
}
else
{
ssize new_len, old_size, new_size;
void* ptr;
void* new_ptr;
AllocatorInfo allocator = string_get_header(* str)->Allocator;
StringHeader* header = nullptr;
new_len = string_grow_formula(string_length(* str) + add_len);
ptr = string_get_header(* str);
old_size = size_of(StringHeader) + string_length(* str) + 1;
new_size = size_of(StringHeader) + new_len + 1;
new_ptr = resize(allocator, ptr, old_size, new_size);
if (new_ptr == nullptr)
return false;
header = rcast(StringHeader*, new_ptr);
header->Allocator = allocator;
header->Capacity = new_len;
char** Data = rcast(char**, str);
* Data = rcast(char*, header + 1);
return true;
}
}
forceinline
b32 string_starts_with_strc(String const str, StrC substring) {
if (substring.Len > string_length(str))
return false;
b32 result = str_compare_len(str, substring.Ptr, substring.Len) == 0;
return result;
}
forceinline
b32 string_starts_with_string(String const str, String substring) {
if (string_length(substring) > string_length(str))
return false;
b32 result = str_compare_len(str, substring, string_length(substring) - 1) == 0;
return result;
}
inline
void string_skip_line(String str)
{
#define current (*scanner)
char* scanner = str;
while (current != '\r' && current != '\n') {
++scanner;
}
s32 new_length = scanner - str;
if (current == '\r') {
new_length += 1;
}
mem_move((char*)str, scanner, new_length);
StringHeader* header = string_get_header(str);
header->Length = new_length;
#undef current
}
inline
void strip_space(String str)
{
char* write_pos = str;
char* read_pos = str;
while (* read_pos)
{
if (! char_is_space(* read_pos))
{
* write_pos = * read_pos;
write_pos++;
}
read_pos++;
}
write_pos[0] = '\0'; // Null-terminate the modified string
// Update the length if needed
string_get_header(str)->Length = write_pos - str;
}
forceinline
StrC string_to_strc(String str) {
StrC result = { string_length(str), (char const*)str };
return result;
}
inline
void string_trim(String str, char const* cut_set)
{
ssize len = 0;
char* start_pos = str;
char* end_pos = scast(char*, str) + string_length(str) - 1;
while (start_pos <= end_pos && char_first_occurence(cut_set, *start_pos))
start_pos++;
while (end_pos > start_pos && char_first_occurence(cut_set, *end_pos))
end_pos--;
len = scast(ssize, (start_pos > end_pos) ? 0 : ((end_pos - start_pos) + 1));
if (str != start_pos)
mem_move(str, start_pos, len);
str[len] = '\0';
string_get_header(str)->Length = len;
}
forceinline
void string_trim_space(String str) {
string_trim(str, " \t\r\n\v\f");
}
inline
String string_visualize_whitespace(String const str)
{
StringHeader* header = (StringHeader*)(scast(char const*, str) - sizeof(StringHeader));
String result = string_make_reserve(header->Allocator, string_length(str) * 2); // Assume worst case for space requirements.
for (char const* c = string_begin(str); c != string_end(str); c = string_next(str, c))
switch ( * c )
{
case ' ':
string_append_strc(& result, txt("·"));
break;
case '\t':
string_append_strc(& result, txt(""));
break;
case '\n':
string_append_strc(& result, txt(""));
break;
case '\r':
string_append_strc(& result, txt(""));
break;
case '\v':
string_append_strc(& result, txt(""));
break;
case '\f':
string_append_strc(& result, txt(""));
break;
default:
string_append_char(& result, * c);
break;
}
return result;
}
#pragma endregion String
#if GEN_COMPILER_CPP
struct String_POD {
char* Data;
};
static_assert( sizeof( String_POD ) == sizeof( String ), "String is not a POD" );
#endif
forceinline
StrC strc_duplicate(StrC str, AllocatorInfo allocator) {
StrC result = string_to_strc( string_make_length(allocator, str.Ptr, str.Len));
return result;
}
inline
StrC strc_visualize_whitespace(StrC str, AllocatorInfo allocator)
{
String result = string_make_reserve(allocator, str.Len * 2); // Assume worst case for space requirements.
for (char const* c = strc_begin(str); c != strc_end(str); c = strc_next(str, c))
switch ( * c )
{
case ' ':
string_append_strc(& result, txt("·"));
break;
case '\t':
string_append_strc(& result, txt(""));
break;
case '\n':
string_append_strc(& result, txt(""));
break;
case '\r':
string_append_strc(& result, txt(""));
break;
case '\v':
string_append_strc(& result, txt(""));
break;
case '\f':
string_append_strc(& result, txt(""));
break;
default:
string_append_char(& result, * c);
break;
}
return string_to_strc(result);
}
// Represents strings cached with the string table.
// Should never be modified, if changed string is desired, cache_string( str ) another.
typedef StrC StringCached;
// Implements basic string interning. Data structure is based off the ZPL Hashtable.
typedef HashTable(StringCached) StringTable;
#pragma endregion Strings

167
base/dependencies/timing.cpp Normal file
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#ifdef GEN_INTELLISENSE_DIRECTIVES
# pragma once
# include "filesystem.cpp"
#endif
#pragma region Timing
#ifdef GEN_BENCHMARK
#if defined( GEN_COMPILER_MSVC ) && ! defined( __clang__ )
u64 read_cpu_time_stamp_counter( void )
{
return __rdtsc();
}
#elif defined( __i386__ )
u64 read_cpu_time_stamp_counter( void )
{
u64 x;
__asm__ volatile( ".byte 0x0f, 0x31" : "=A"( x ) );
return x;
}
#elif defined( __x86_64__ )
u64 read_cpu_time_stamp_counter( void )
{
u32 hi, lo;
__asm__ __volatile__( "rdtsc" : "=a"( lo ), "=d"( hi ) );
return scast( u64, lo ) | ( scast( u64, hi ) << 32 );
}
#elif defined( __powerpc__ )
u64 read_cpu_time_stamp_counter( void )
{
u64 result = 0;
u32 upper, lower, tmp;
__asm__ volatile(
"0: \n"
"\tmftbu %0 \n"
"\tmftb %1 \n"
"\tmftbu %2 \n"
"\tcmpw %2,%0 \n"
"\tbne 0b \n"
: "=r"( upper ), "=r"( lower ), "=r"( tmp )
);
result = upper;
result = result << 32;
result = result | lower;
return result;
}
#elif defined( GEN_SYSTEM_EMSCRIPTEN )
u64 read_cpu_time_stamp_counter( void )
{
return ( u64 )( emscripten_get_now() * 1e+6 );
}
#elif defined( GEN_CPU_ARM ) && ! defined( GEN_COMPILER_TINYC )
u64 read_cpu_time_stamp_counter( void )
{
# if defined( __aarch64__ )
int64_t r = 0;
asm volatile( "mrs %0, cntvct_el0" : "=r"( r ) );
# elif ( __ARM_ARCH >= 6 )
uint32_t r = 0;
uint32_t pmccntr;
uint32_t pmuseren;
uint32_t pmcntenset;
// Read the user mode perf monitor counter access permissions.
asm volatile( "mrc p15, 0, %0, c9, c14, 0" : "=r"( pmuseren ) );
if ( pmuseren & 1 )
{ // Allows reading perfmon counters for user mode code.
asm volatile( "mrc p15, 0, %0, c9, c12, 1" : "=r"( pmcntenset ) );
if ( pmcntenset & 0x80000000ul )
{ // Is it counting?
asm volatile( "mrc p15, 0, %0, c9, c13, 0" : "=r"( pmccntr ) );
// The counter is set up to count every 64th cycle
return ( ( int64_t )pmccntr ) * 64; // Should optimize to << 6
}
}
# else
# error "No suitable method for read_cpu_time_stamp_counter for this cpu type"
# endif
return r;
}
#else
u64 read_cpu_time_stamp_counter( void )
{
GEN_PANIC( "read_cpu_time_stamp_counter is not supported on this particular setup" );
return -0;
}
#endif
#if defined( GEN_SYSTEM_WINDOWS ) || defined( GEN_SYSTEM_CYGWIN )
u64 time_rel_ms( void )
{
local_persist LARGE_INTEGER win32_perf_count_freq = {};
u64 result;
LARGE_INTEGER counter;
local_persist LARGE_INTEGER win32_perf_counter = {};
if ( ! win32_perf_count_freq.QuadPart )
{
QueryPerformanceFrequency( &win32_perf_count_freq );
GEN_ASSERT( win32_perf_count_freq.QuadPart != 0 );
QueryPerformanceCounter( &win32_perf_counter );
}
QueryPerformanceCounter( &counter );
result = ( counter.QuadPart - win32_perf_counter.QuadPart ) * 1000 / ( win32_perf_count_freq.QuadPart );
return result;
}
#else
# if defined( GEN_SYSTEM_LINUX ) || defined( GEN_SYSTEM_FREEBSD ) || defined( GEN_SYSTEM_OPENBSD ) || defined( GEN_SYSTEM_EMSCRIPTEN )
u64 _unix_gettime( void )
{
struct timespec t;
u64 result;
clock_gettime( 1 /*CLOCK_MONOTONIC*/, &t );
result = 1000 * t.tv_sec + 1.0e-6 * t.tv_nsec;
return result;
}
# endif
u64 time_rel_ms( void )
{
# if defined( GEN_SYSTEM_OSX )
u64 result;
local_persist u64 timebase = 0;
local_persist u64 timestart = 0;
if ( ! timestart )
{
mach_timebase_info_data_t tb = { 0 };
mach_timebase_info( &tb );
timebase = tb.numer;
timebase /= tb.denom;
timestart = mach_absolute_time();
}
// NOTE: mach_absolute_time() returns things in nanoseconds
result = 1.0e-6 * ( mach_absolute_time() - timestart ) * timebase;
return result;
# else
local_persist u64 unix_timestart = 0.0;
if ( ! unix_timestart )
{
unix_timestart = _unix_gettime();
}
u64 now = _unix_gettime();
return ( now - unix_timestart );
# endif
}
#endif
f64 time_rel( void )
{
return ( f64 )( time_rel_ms() * 1e-3 );
}
#endif
#pragma endregion Timing

19
base/dependencies/timing.hpp Normal file
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#ifdef GEN_INTELLISENSE_DIRECTIVES
# pragma once
# include "filesystem.hpp"
#endif
#pragma region Timing
#ifdef GEN_BENCHMARK
//! Return CPU timestamp.
u64 read_cpu_time_stamp_counter( void );
//! Return relative time (in seconds) since the application start.
f64 time_rel( void );
//! Return relative time since the application start.
u64 time_rel_ms( void );
#endif
#pragma endregion Timing

2
base/enums/AttributeTokens.csv Normal file
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@ -0,0 +1,2 @@
API_Export, GEN_API_Export_Code
API_Import, GEN_API_Import_Code
1 API_Export GEN_API_Export_Code
2 API_Import GEN_API_Import_Code

144
base/enums/ECodeType_ExecutionSupport.csv Normal file
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Invalid
Untyped
NewLine
Comment
Access_Private
Access_Protected
Access_Public
PlatformAttributes
Class
Class_Fwd
Class_Body
Constructor
Constructor_Fwd
Destructor
Destructor_Fwd
Enum
Enum_Fwd
Enum_Body
Enum_Class
Enum_Class_Fwd
Execution
Expression
Expr_Identifier
Expr_NumericLiteral
Expr_StringLiteral
Expr_Alignof
Expr_ProcCall
Expr_Assign_Add
Expr_Assign_Subtract
Expr_Assign_Multiply
Expr_Assign_Divide
Expr_Assign_Modulo
Expr_Assign_Bitwise_And
Expr_Assign_Bitwise_Or
Expr_Assign_Bitwise_XOr
Expr_Assign_LeftShift
Expr_Assign_RightShift
Expr_CStyleCast
Expr_FunctionalCast
Expr_ConstCast
Expr_DynamicCast
Expr_ReinterpretCast
Expr_StaticCast
Expr_Unary_Add
Expr_Unary_Minus
Expr_Unary_Not
Expr_Unary_Increment
Expr_Unary_Decrement
Expr_Indirection
Expr_AddressOf,
Expr_UnaryPost_Increment
Expr_UnaryPost_Decrement
Expr_Subscript
Expr_Binary_Add
Expr_Binary_Subtract
Expr_Binary_Multiply
Expr_Binary_Divide
Expr_Binary_Modulo
Expr_Binary_Bitwise_And
Expr_Binary_Bitwise_Or
Expr_Binary_Bitwise_XOr
Expr_Binary_Bitwise_LeftShift
Expr_Binary_Bitwise_RightShift
Expr_Binary_Logical_Not
Expr_Binary_Logical_And
Expr_Binary_Logical_Or
Expr_Binary_Equal
Expr_Binary_NotEqual
Expr_Binary_Lesser
Expr_Binary_Greater
Expr_Binary_LesserEqual
Expr_Binary_GreaterEqual
Expr_MemberOfObject,
Expr_MemberOfPointer,
Expr_PointerToMemberOfObject,
Expr_PointerToMemberOfPointer,
Expr_Comma,
Expr_Tenary,
Export_Body
Extern_Linkage
Extern_Linkage_Body
Friend
Function
Function_Fwd
Function_Body
Global_Body
Module
Namespace
Namespace_Body
Operator
Operator_Fwd
Operator_Member
Operator_Member_Fwd
Operator_Cast
Operator_Cast_Fwd
Parameters
Preprocess_Define
Preprocess_Include
Preprocess_If
Preprocess_IfDef
Preprocess_IfNotDef
Preprocess_ElIf
Preprocess_Else
Preprocess_EndIf
Preprocess_Pragma
Specifiers
Statement
Stmt_Break
Stmt_Case
Stmt_Continue
Stmt_Declaration
Stmt_Do
Stmt_Expr
Stmt_Else
Stmt_If
Stmt_For
Stmt_Goto
Stmt_Label
Stmt_Switch
Stmt_Switch
Stmt_While
Struct
Struct_Fwd
Struct_Body
Template
Typedef
Typename
Union
Union_Body
Using
Using_Namespace
Variable
Can't render this file because it has a wrong number of fields in line 56.

61
base/enums/ECodeTypes.csv Normal file
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Invalid, "__NA__"
Untyped, "__NA__"
NewLine, "__NA__"
Comment, "//"
Access_Private, "private"
Access_Protected, "protected"
Access_Public, "public"
PlatformAttributes, "__NA__"
Class, "class"
Class_Fwd, "clsss"
Class_Body, "__NA__"
Constructor, "__NA__"
Constructor_Fwd, "__NA__"
Destructor, "__NA__"
Destructor_Fwd, "__NA__"
Enum, "enum"
Enum_Fwd, "enum"
Enum_Body, "__NA__"
Enum_Class, "enum class"
Enum_Class_Fwd, "enum class"
Execution, "__NA__"
Export_Body, "__NA__"
Extern_Linkage, "extern"
Extern_Linkage_Body, "extern"
Friend, "friend"
Function, "__NA__"
Function_Fwd, "__NA__"
Function_Body, "__NA__"
Global_Body, "__NA__"
Module, "module"
Namespace, "namespace"
Namespace_Body, "__NA__"
Operator, "operator"
Operator_Fwd, "operator"
Operator_Member, "operator"
Operator_Member_Fwd, "operator"
Operator_Cast, "operator"
Operator_Cast_Fwd, "operator"
Parameters, "__NA__"
Preprocess_Define, "define"
Preprocess_Include, "include"
Preprocess_If, "if"
Preprocess_IfDef, "ifdef"
Preprocess_IfNotDef, "ifndef"
Preprocess_ElIf, "elif"
Preprocess_Else, "else"
Preprocess_EndIf, "endif"
Preprocess_Pragma, "pragma"
Specifiers, "__NA__"
Struct, "struct"
Struct_Fwd, "struct"
Struct_Body, "__NA__"
Template, "template"
Typedef, "typedef"
Typename, "__NA__"
Union, "union"
Union_Fwd, "union"
Union_Body, "__NA__"
Using, "using"
Using_Namespace, "using namespace"
Variable, "__NA__"
1 Invalid __NA__
2 Untyped __NA__
3 NewLine __NA__
4 Comment //
5 Access_Private private
6 Access_Protected protected
7 Access_Public public
8 PlatformAttributes __NA__
9 Class class
10 Class_Fwd clsss
11 Class_Body __NA__
12 Constructor __NA__
13 Constructor_Fwd __NA__
14 Destructor __NA__
15 Destructor_Fwd __NA__
16 Enum enum
17 Enum_Fwd enum
18 Enum_Body __NA__
19 Enum_Class enum class
20 Enum_Class_Fwd enum class
21 Execution __NA__
22 Export_Body __NA__
23 Extern_Linkage extern
24 Extern_Linkage_Body extern
25 Friend friend
26 Function __NA__
27 Function_Fwd __NA__
28 Function_Body __NA__
29 Global_Body __NA__
30 Module module
31 Namespace namespace
32 Namespace_Body __NA__
33 Operator operator
34 Operator_Fwd operator
35 Operator_Member operator
36 Operator_Member_Fwd operator
37 Operator_Cast operator
38 Operator_Cast_Fwd operator
39 Parameters __NA__
40 Preprocess_Define define
41 Preprocess_Include include
42 Preprocess_If if
43 Preprocess_IfDef ifdef
44 Preprocess_IfNotDef ifndef
45 Preprocess_ElIf elif
46 Preprocess_Else else
47 Preprocess_EndIf endif
48 Preprocess_Pragma pragma
49 Specifiers __NA__
50 Struct struct
51 Struct_Fwd struct
52 Struct_Body __NA__
53 Template template
54 Typedef typedef
55 Typename __NA__
56 Union union
57 Union_Fwd union
58 Union_Body __NA__
59 Using using
60 Using_Namespace using namespace
61 Variable __NA__

47
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Invalid, INVALID
Assign, "="
Assign_Add, "+="
Assign_Subtract, "-="
Assign_Multiply, "*="
Assign_Divide, "/="
Assign_Modulo, "%="
Assign_BAnd, "&="
Assign_BOr, "|="
Assign_BXOr, "^="
Assign_LShift, "<<="
Assign_RShift, ">>="
Increment, "++"
Decrement, "--"
Unary_Plus, "+"
Unary_Minus, "-"
UnaryNot, "!"
Add, "+"
Subtract, "-"
Multiply, "*"
Divide, "/"
Modulo, "%"
BNot, "~"
BAnd, "&"
BOr, "|"
BXOr, "^"
LShift, "<<"
RShift, ">>"
LAnd, "&&"
LOr, "||"
LEqual, "=="
LNot, "!="
Lesser, "<"
Greater, ">"
LesserEqual, "<="
GreaterEqual, ">="
Subscript, "[]"
Indirection, "*"
AddressOf, "&"
MemberOfPointer, "->"
PtrToMemOfPtr, "->*"
FunctionCall, "()"
Comma, ","
New, "new"
NewArray, "new[]"
Delete, "delete"
DeleteArray, "delete[]"
1 Invalid INVALID
2 Assign =
3 Assign_Add +=
4 Assign_Subtract -=
5 Assign_Multiply *=
6 Assign_Divide /=
7 Assign_Modulo %=
8 Assign_BAnd &=
9 Assign_BOr |=
10 Assign_BXOr ^=
11 Assign_LShift <<=
12 Assign_RShift >>=
13 Increment ++
14 Decrement --
15 Unary_Plus +
16 Unary_Minus -
17 UnaryNot !
18 Add +
19 Subtract -
20 Multiply *
21 Divide /
22 Modulo %
23 BNot ~
24 BAnd &
25 BOr |
26 BXOr ^
27 LShift <<
28 RShift >>
29 LAnd &&
30 LOr ||
31 LEqual ==
32 LNot !=
33 Lesser <
34 Greater >
35 LesserEqual <=
36 GreaterEqual >=
37 Subscript []
38 Indirection *
39 AddressOf &
40 MemberOfPointer ->
41 PtrToMemOfPtr ->*
42 FunctionCall ()
43 Comma ,
44 New new
45 NewArray new[]
46 Delete delete
47 DeleteArray delete[]

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Invalid, INVALID
Consteval, consteval
Constexpr, constexpr
Constinit, constinit
Explicit, explicit
External_Linkage, extern
ForceInline, forceinline
Global, global
Inline, inline
Internal_Linkage, internal
Local_Persist, local_persist
Mutable, mutable
NeverInline, neverinline
Ptr, *
Ref, &
Register, register
RValue, &&
Static, static
Thread_Local, thread_local
Virtual, virtual
Const, const
Final, final
NoExceptions, noexcept
Override, override
Pure, = 0
Volatile, volatile
1 Invalid INVALID
2 Consteval consteval
3 Constexpr constexpr
4 Constinit constinit
5 Explicit explicit
6 External_Linkage extern
7 ForceInline forceinline
8 Global global
9 Inline inline
10 Internal_Linkage internal
11 Local_Persist local_persist
12 Mutable mutable
13 NeverInline neverinline
14 Ptr *
15 Ref &
16 Register register
17 RValue &&
18 Static static
19 Thread_Local thread_local
20 Virtual virtual
21 Const const
22 Final final
23 NoExceptions noexcept
24 Override override
25 Pure = 0
26 Volatile volatile

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Invalid, "__invalid__"
Access_Private, "private"
Access_Protected, "protected"
Access_Public, "public"
Access_MemberSymbol, "."
Access_StaticSymbol, "::"
Ampersand, "&"
Ampersand_DBL, "&&"
Assign_Classifer, ":"
Attribute_Open, "[["
Attribute_Close, "]]"
BraceCurly_Open, "{"
BraceCurly_Close, "}"
BraceSquare_Open, "["
BraceSquare_Close, "]"
Capture_Start, "("
Capture_End, ")"
Comment, "__comment__"
Comment_End, "__comment_end__"
Comment_Start, "__comment_start__"
Char, "__character__"
Comma, ","
Decl_Class, "class"
Decl_GNU_Attribute, "__attribute__"
Decl_MSVC_Attribute, "__declspec"
Decl_Enum, "enum"
Decl_Extern_Linkage, "extern"
Decl_Friend, "friend"
Decl_Module, "module"
Decl_Namespace, "namespace"
Decl_Operator, "operator"
Decl_Struct, "struct"
Decl_Template, "template"
Decl_Typedef, "typedef"
Decl_Using, "using"
Decl_Union, "union"
Identifier, "__identifier__"
Module_Import, "import"
Module_Export, "export"
NewLine, "__new_line__"
Number, "__number__"
Operator, "__operator__"
Preprocess_Hash, "#"
Preprocess_Define, "define"
Preprocess_If, "if"
Preprocess_IfDef, "ifdef"
Preprocess_IfNotDef, "ifndef"
Preprocess_ElIf, "elif"
Preprocess_Else, "else"
Preprocess_EndIf, "endif"
Preprocess_Include, "include"
Preprocess_Pragma, "pragma"
Preprocess_Content, "__macro_content__"
Preprocess_Macro, "__macro__"
Preprocess_Unsupported, "__unsupported__"
Spec_Alignas, "alignas"
Spec_Const, "const"
Spec_Consteval, "consteval"
Spec_Constexpr, "constexpr"
Spec_Constinit, "constinit"
Spec_Explicit, "explicit"
Spec_Extern, "extern"
Spec_Final, "final"
Spec_ForceInline, "forceinline"
Spec_Global, "global"
Spec_Inline, "inline"
Spec_Internal_Linkage, "internal"
Spec_LocalPersist, "local_persist"
Spec_Mutable, "mutable"
Spec_NeverInline, "neverinline"
Spec_Override, "override"
Spec_Static, "static"
Spec_ThreadLocal, "thread_local"
Spec_Volatile, "volatile"
Spec_Virtual, "virtual"
Star, "*"
Statement_End, ";"
StaticAssert, "static_assert"
String, "__string__"
Type_Typename, "typename"
Type_Unsigned, "unsigned"
Type_Signed, "signed"
Type_Short, "short"
Type_Long, "long"
Type_bool, "bool"
Type_char, "char"
Type_int, "int"
Type_double, "double"
Type_MS_int8, "__int8"
Type_MS_int16, "__int16"
Type_MS_int32, "__int32"
Type_MS_int64, "__int64"
Type_MS_W64, "_W64"
Varadic_Argument, "..."
__Attributes_Start, "__attrib_start__"
1 Invalid __invalid__
2 Access_Private private
3 Access_Protected protected
4 Access_Public public
5 Access_MemberSymbol .
6 Access_StaticSymbol ::
7 Ampersand &
8 Ampersand_DBL &&
9 Assign_Classifer :
10 Attribute_Open [[
11 Attribute_Close ]]
12 BraceCurly_Open {
13 BraceCurly_Close }
14 BraceSquare_Open [
15 BraceSquare_Close ]
16 Capture_Start (
17 Capture_End )
18 Comment __comment__
19 Comment_End __comment_end__
20 Comment_Start __comment_start__
21 Char __character__
22 Comma ,
23 Decl_Class class
24 Decl_GNU_Attribute __attribute__
25 Decl_MSVC_Attribute __declspec
26 Decl_Enum enum
27 Decl_Extern_Linkage extern
28 Decl_Friend friend
29 Decl_Module module
30 Decl_Namespace namespace
31 Decl_Operator operator
32 Decl_Struct struct
33 Decl_Template template
34 Decl_Typedef typedef
35 Decl_Using using
36 Decl_Union union
37 Identifier __identifier__
38 Module_Import import
39 Module_Export export
40 NewLine __new_line__
41 Number __number__
42 Operator __operator__
43 Preprocess_Hash #
44 Preprocess_Define define
45 Preprocess_If if
46 Preprocess_IfDef ifdef
47 Preprocess_IfNotDef ifndef
48 Preprocess_ElIf elif
49 Preprocess_Else else
50 Preprocess_EndIf endif
51 Preprocess_Include include
52 Preprocess_Pragma pragma
53 Preprocess_Content __macro_content__
54 Preprocess_Macro __macro__
55 Preprocess_Unsupported __unsupported__
56 Spec_Alignas alignas
57 Spec_Const const
58 Spec_Consteval consteval
59 Spec_Constexpr constexpr
60 Spec_Constinit constinit
61 Spec_Explicit explicit
62 Spec_Extern extern
63 Spec_Final final
64 Spec_ForceInline forceinline
65 Spec_Global global
66 Spec_Inline inline
67 Spec_Internal_Linkage internal
68 Spec_LocalPersist local_persist
69 Spec_Mutable mutable
70 Spec_NeverInline neverinline
71 Spec_Override override
72 Spec_Static static
73 Spec_ThreadLocal thread_local
74 Spec_Volatile volatile
75 Spec_Virtual virtual
76 Star *
77 Statement_End ;
78 StaticAssert static_assert
79 String __string__
80 Type_Typename typename
81 Type_Unsigned unsigned
82 Type_Signed signed
83 Type_Short short
84 Type_Long long
85 Type_bool bool
86 Type_char char
87 Type_int int
88 Type_double double
89 Type_MS_int8 __int8
90 Type_MS_int16 __int16
91 Type_MS_int32 __int32
92 Type_MS_int64 __int64
93 Type_MS_W64 _W64
94 Varadic_Argument ...
95 __Attributes_Start __attrib_start__

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Invalid, "__invalid__"
Access_Private, "private"
Access_Protected, "protected"
Access_Public, "public"
Access_MemberSymbol, "."
Access_StaticSymbol, "::"
Ampersand, "&"
Ampersand_DBL, "&&"
Assign_Classifer, ":"
Attribute_Open, "[["
Attribute_Close, "]]"
BraceCurly_Open, "{"
BraceCurly_Close, "}"
BraceSquare_Open, "["
BraceSquare_Close, "]"
Capture_Start, "("
Capture_End, ")"
Comment, "__comment__"
Comment_End, "__comment_end__"
Comment_Start, "__comment_start__"
Char, "__character__"
Comma, ","
Decl_Class, "class"
Decl_Default "default"
Decl_GNU_Attribute, "__attribute__"
Decl_MSVC_Attribute, "__declspec"
Decl_Enum, "enum"
Decl_Extern_Linkage, "extern"
Decl_Friend, "friend"
Decl_Module, "module"
Decl_Namespace, "namespace"
Decl_Operator, "operator"
Decl_Struct, "struct"
Decl_Template, "template"
Decl_Type, "decltype"
Decl_Typedef, "typedef"
Decl_Using, "using"
Decl_Union, "union"
Expr_AlignOf, "alignof"
Identifier, "__identifier__"
Module_Import, "import"
Module_Export, "export"
NewLine, "__new_line__"
Number, "__number__"
Operator, "__operator__"
Op_Assign, "="
Op_Assign_Add, "+="
Op_Assign_Subtract, "-="
Op_Assign_Multiply, "*="
Op_Assign_Divide, "/="
Op_Assign_Modulo, "%="
Op_Assign_Bitwise_And, "&="
Op_Assign_Bitwise_Or, "|="
Op_Assign_Bitwise_XOr, "^="
Op_Assign_Bitwise_LeftShift, "<<="
Op_Assign_Bitwise_RightShift, ">>="
Op_Increment, "++"
Op_Decrement, "--"
Op_Add, "+"
Op_Subtract, "-"
Op_Multiply, "*"
Op_Divide, "/"
Op_Modulo, "%"
Op_Bitwise_And, "&"
Op_Bitwise_Or, "|"
Op_Bitwise_XOr, "^"
Op_Bitwise_LeftShitf, "<<"
Op_Bitwise_RightShift, ">>"
Op_UnaryAdd, "+"
Op_UnaryMinus, "-"
Op_UnaryNot, "~"
Op_Logical_Not, "!"
Op_Logical_And, "&&"
Op_Logical_Or, "||"
Op_Equal, "=="
Op_NotEqual, "!="
Op_Lesser, "<"
Op_Greater, ">"
Op_LesserEqual, "<="
Op_GreaterEqual", ">=
Op_Subscript, "[]"
Op_Indirection, "*"
Op_AddressOf, "&"
Op_MemberOfObject, "."
Op_MemberOfPointer", "->"
Op_PointerToMemberOfObject, ".*"
Op_PointerToMemberOfPointer, "->*"
Op_Comma, ","
Op_Ternary, "?"
Preprocess_Hash, "#"
Preprocess_Define, "define"
Preprocess_If, "if"
Preprocess_IfDef, "ifdef"
Preprocess_IfNotDef, "ifndef"
Preprocess_ElIf, "elif"
Preprocess_Else, "else"
Preprocess_EndIf, "endif"
Preprocess_Include, "include"
Preprocess_Pragma, "pragma"
Preprocess_Content, "__macro_content__"
Preprocess_Macro, "__macro__"
Preprocess_Generic, "_Generic"
Preprocess_Unsupported, "__unsupported__"
Spec_Alignof, "alignof"
Spec_Const, "const"
Spec_Consteval, "consteval"
Spec_Constexpr, "constexpr"
Spec_Constinit, "constinit"
Spec_Explicit, "explicit"
Spec_Extern, "extern"
Spec_Final, "final"
Spec_ForceInline, "forceinline"
Spec_Global, "global"
Spec_Inline, "inline"
Spec_Internal_Linkage, "internal"
Spec_LocalPersist, "local_persist"
Spec_Mutable, "mutable"
Spec_NeverInline, "neverinline"
Spec_Override, "override"
Spec_Static, "static"
Spec_ThreadLocal, "thread_local"
Spec_Volatile, "volatile"
Spec_Virtual, "virtual"
Star, "*"
Stmt_Break, "break"
Stmt_Case, "case"
Stmt_Continue, "continue"
Stmt_Default, "default"
Stmt_Do, "do"
Stmt_Else, "else"
Stmt_End, ";"
Stmt_If, "if"
Stmt_For, "for"
Stmt_Goto, "goto"
Stmt_Return, "return"
Stmt_Switch, "switch"
Stmt_While, "while"
StaticAssert, "static_assert"
String, "__string__"
Type_Auto, "auto"
Type_Unsigned, "unsigned"
Type_Signed, "signed"
Type_Short, "short"
Type_Long, "long"
Type_bool, "bool"
Type_char, "char"
Type_int, "int"
Type_float, "float"
Type_double, "double"
Type_MS_int8, "__int8"
Type_MS_int16, "__int16"
Type_MS_int32, "__int32"
Type_MS_int64, "__int64"
Type_MS_W64, "_W64"
Varadic_Argument, "..."
__Attributes_Start, "__attrib_start__"
Can't render this file because it contains an unexpected character in line 25 and column 25.

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#include "helpers/push_ignores.inline.hpp"
// ReSharper disable CppClangTidyClangDiagnosticSwitchEnum
#if ! defined(GEN_DONT_ENFORCE_GEN_TIME_GUARD) && ! defined(GEN_TIME)
# error Gen.hpp : GEN_TIME not defined
#endif
#include "gen.hpp"
// These are intended for use in the base library of gencpp and the C-variant of the library
// It provides a interoperability between the C++ and C interfacing for containers. (not letting these do any crazy substiution though)
// They are undefined in gen.hpp and gen.cpp at the end of the files.
// We cpp library expects the user to use the regular calls as they can resolve the type fine.
#include "helpers/push_container_defines.inline.hpp"
//! If its desired to roll your own dependencies, define GEN_ROLL_OWN_DEPENDENCIES before including this file.
//! Dependencies are derived from the c-zpl library: https://github.com/zpl-c/zpl
#ifndef GEN_ROLL_OWN_DEPENDENCIES
# include "gen.dep.cpp"
#endif
GEN_NS_BEGIN
#include "components/static_data.cpp"
#include "components/ast_case_macros.cpp"
#include "components/ast.cpp"
#include "components/code_serialization.cpp"
#include "components/interface.cpp"
#include "components/interface.upfront.cpp"
#include "components/gen/etoktype.cpp"
#include "components/lexer.cpp"
#include "components/parser.cpp"
#include "components/interface.parsing.cpp"
#include "components/interface.untyped.cpp"
#include "auxillary/builder.cpp"
#include "auxillary/scanner.cpp"
GEN_NS_END
#include "helpers/pop_container_defines.inline.hpp"
#include "helpers/pop_ignores.inline.hpp"

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// This file is intended to be included within gen.cpp (There is no pragma diagnostic ignores)
#include "gen.dep.hpp"
#include "dependencies/src_start.cpp"
GEN_NS_BEGIN
#include "dependencies/debug.cpp"
#include "dependencies/string_ops.cpp"
#include "dependencies/printing.cpp"
#include "dependencies/memory.cpp"
#include "dependencies/hashing.cpp"
#include "dependencies/strings.cpp"
#include "dependencies/filesystem.cpp"
#include "dependencies/timing.cpp"
#include "dependencies/parsing.cpp"
GEN_NS_END

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// This file is intended to be included within gen.hpp (There is no pragma diagnostic ignores)
#pragma once
#include "dependencies/platform.hpp"
GEN_NS_BEGIN
#include "dependencies/macros.hpp"
#include "dependencies/basic_types.hpp"
#include "dependencies/debug.hpp"
#include "dependencies/memory.hpp"
#include "dependencies/string_ops.hpp"
#include "dependencies/printing.hpp"
#include "dependencies/containers.hpp"
#include "dependencies/hashing.hpp"
#include "dependencies/strings.hpp"
#include "dependencies/filesystem.hpp"
#include "dependencies/timing.hpp"
#include "dependencies/parsing.hpp"
GEN_NS_END

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/*
gencpp: An attempt at "simple" staged metaprogramming for c/c++.
See Readme.md for more information from the project repository.
Public Address:
https://github.com/Ed94/gencpp
*/
#pragma once
#include "helpers/push_ignores.inline.hpp"
#include "components/header_start.hpp"
// Has container defines pushed
#include "gen.dep.hpp"
GEN_NS_BEGIN
#include "components/types.hpp"
#include "components/gen/ecodetypes.hpp"
#include "components/gen/eoperator.hpp"
#include "components/gen/especifier.hpp"
#include "components/ast.hpp"
#include "components/code_types.hpp"
#include "components/ast_types.hpp"
#include "components/interface.hpp"
#include "components/inlines.hpp"
#include "components/gen/ast_inlines.hpp"
#include "components/header_end.hpp"
#include "auxillary/builder.hpp"
#include "auxillary/scanner.hpp"
GEN_NS_END
#include "helpers/pop_container_defines.inline.hpp"
#include "helpers/pop_ignores.inline.hpp"

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__VERSION 1
// This is a example template to be used with the refactor program
// Use it to refactor the naming convention of this library to your own.
// Can be used as an aid to help use use your project's implementation if it fullfills the dependencies of this project.
// Example: Most likely have a memory and string library already, just rename the functions and make sure the args are the same.
// Program: https://github.com/Ed94/refactor
// NOTE: Due to the current limitations of the program, not every symbol in the library can be renamed.
// This is due to the program not actually parsing C/C++.
// not : Ignore
// include : #includes
// word : Alphanumeric or underscore
// namespace : Prefix search and replace (c-namspaces).
// regex : Unavailable in __VERSION 1.
// Precedence (highest to lowest):
// word, namespace, regex
// TODO(ED): THIS IS VERY OUTDATED
// Gen Macro namespace
// namespace GEN_, new_namespace_
// ---------- Dependency Macros
// Platform
// word GEN_ARCH_64_BIT, new_name
// word GEN_ARCH_32_BIT, new_name
// word GEN_SYSTEM_ANDROID, new_name
// word GEN_SYSTEM_CYGWIN, new_name
// word GEN_SYSTEM_EMSCRIPTEN, new_name
// word GEN_SYSTEM_FREEBSD, new_name
// word GEN_SYSTEM_IOS, new_name
// word GEN_SYSTEM_LINUX, new_name
// word GEN_SYSTEM_MACOS, new_name
// word GEN_SYSTEM_OPENBSD, new_name
// word GEN_SYSTEM_OSX, new_name
// word GEN_SYSTEM_UNIX, new_name
// word GEN_SYSTEM_WINDOWS, new_name
// word GEN_COMPILER_CLANG, new_name
// word GEN_COMPILER_GCC, new_name
// word GEN_COMPILER_MINGW, new_name
// word GEN_COMPILER_MSVC, new_name
// word global, new_name
// word internal, new_name
// word local_persist, new_name
// word forceinline, new_name
// word neverinline, new_name
// word bit, new_name
// word bitfield_is_equal, new_name
// word ccast, new_name
// word pcast, new_name
// word rcast, new_name
// word scast, new_name
// word num_args, new_name
// word num_args_impl, new_name
// word stringize, new_name
// word stringize_va, new_name
// word do_once, new_name
// word do_once_start, new_name
// word do_once_end, new_name
// word label_scope_start, new_name
// word label_scope_end, new_name
// word count_of, new_name
// word is_between, new_name
// word min, new_name
// word size_of, new_name
// word offset_of, new_name
// word swap, new_name
// Basic Types
// word GEN_U8_MIN, new_name
// word GEN_U8_MAX, new_name
// word GEN_I8_MIN, new_name
// word GEN_I8_MAX, new_name
// word GEN_U16_MIN, new_name
// word GEN_U16_MAX, new_name
// word GEN_I16_MIN, new_name
// word GEN_I16_MAX, new_name
// word GEN_U32_MIN, new_name
// word GEN_U32_MAX, new_name
// word GEN_I32_MIN, new_name
// word GEN_I32_MAX, new_name
// word GEN_U64_MIN, new_name
// word GEN_U64_MAX, new_name
// word GEN_I64_MIN, new_name
// word GEN_I64_MAX, new_name
// word GEN_USIZE_MIN, new_name
// word GEN_USIZE_MAX, new_name
// word GEN_ISIZE_MIN, new_name
// word GEN_ISIZE_MAX, new_name
// word GEN_F32_MIN, new_name
// word GEN_F32_MAX, new_name
// word GEN_F64_MIN, new_name
// word GEN_F64_MAX, new_name
// Debug
// word GEN_DEBUG_TRAP, new_name
// word GEN_ASSERT, new_name
// word GEN_ASSERT_MSG, new_name
// word GEN_ASSERT_NOT_NULL, new_name
// word GEN_PANIC, new_name
// word GEN_FATAL, new_name
// Memory
// word kilobytes, new_name
// word megabytes, new_name
// word gigabytes, new_name
// word terabytes, new_name
// word zero_item, new_name
// word zero_array, new_name
// word alloc_item, new_name
// word alloc_array, new_name
// word malloc, new_name
// word mfree, new_name
// Strings
// word txt, new_name
// word cast_to_strc, new_name
// ---------- Dependency Types
// word b8, new_name
// word b16, new_name
// word b32, new_name
// word s8, new_name
// word s16, new_name
// word s32, new_name
// word s64, new_name
// word u8, new_name
// word u16, new_name
// word u32, new_name
// word u64, new_name
// word usize, new_name
// word ssize, new_name
// word sptr, new_name
// word uptr, new_name
// word f32, new_name
// word f64, new_name
// namespace EAllocator_, new_namespace_
// namespace EFileMode_, new_namespace_
// namespace EFileError_, new_namespace_
// word AllocatorInfo, new_name
// word AllocatorProc, new_name
// word AllocFlag, new_name
// word AllocType, new_name
// word ArrayHeader, new_name
// word DirEntry, new_name
// word DirInfo, new_name
// word DirType, new_name
// word FileDescriptor, new_name
// word FileError, new_name
// word FileInfo, new_name
// word FileTime, new_name
// word FileModeFlag, new_name
// word FileOperations, new_name
// word FileStandardType, new_name
// word SeekWhenceType, new_name
// ---------- Dependency Data
// word default_file_operations, new_name
// ---------- Dependency Procedures
// word align_forward, new_name
// word align_fordward_i64, new_name
// word alloc, new_name
// word alloc_align, new_name
// word assert_handler, new_name
// word assert_crash, new_name
// word char_first_occurence, new_name
// word char_is_alpha, new_name
// word char_is_alphanumeric, new_name
// word char_is_digit, new_name
// word char_is_hex_digit, new_name
// word char_is_space, new_name
// word char_to_lower, new_name
// word char_to_upper, new_name
// word crc32, new_name
// word default_resize_align, new_name
// word digit_to_int, new_name
// word file_close, new_name
// word file_get_standard, new_name
// word file_name, new_name
// word file_open, new_name
// word file_open_mode, new_name
// word file_seek, new_name
// word file_tell, new_name
// word file_write, new_name
// word file_write_at, new_name
// word file_write_at_check, new_name
// word free, new_name
// word free_all, new_name
// word heap, new_name
// word heap_allocator_proc, new_name
// word heap_stats_check, new_name
// word heap_stats_alloc_count, new_name
// word heap_stats_init, new_name
// word heap_stats_used_memory, new_name
// word hex_digit_to_int, new_name
// word i64_to_str, new_name
// word is_power_of_two, new_name
// word log_fmt, new_name
// word mem_copy, new_name
// word mem_move, new_name
// word mem_set, new_name
// word pointer_add, new_name
// word mem_copy, new_name
// word mem_find, new_name
// word mem_move, new_name
// word mem_set, new_name
// word resize, new_name
// word resize_align, new_name
// word process_exit, new_name
// word str_compare, new_name
// word str_copy, new_name
// word str_copy_nulpad, new_name
// word str_fmt_buf, new_name
// word str_fmt_buf_va, new_name
// word str_fmt_file_va, new_name
// word str_fmt_out_va, new_name
// word str_fmt_out_err, new_name
// word str_fmt_out_err_va, new_name
// word str_fmt_va, new_name
// word str_len, new_name
// word str_reverse, new_name
// word str_to_i64, new_name
// word str_to_lower, new_name
// word str_to_upper, new_name
// word u64_to_str, new_name
// word zero_size, new_name
// ---------- gencpp Macros
// word log_failure, new_name
// word NullCode, new_name
// word CodeInvalid, new_name
// ------------ gencpp common
// word Arena, new_name
// word Array, new_name
// word HashTable, new_name
// word Pool, new_name
// word StrC, new_name
// word String, new_name
// word to_str, new_name
// word to_str, new_name
// word to_type, new_name
// ------------ gencpp Types & Constants
// word LogFailType, new_name
// word AccessSpec, new_name
// word ECode, new_name
// word EnumClass, new_name
// word EnumRegular, new_name
// word EnumT, new_name
// word EOperator, new_name
// word ESpecifier, new_name
// word OperatorT, new_name
// word ModuleFlag, new_name
// word SpecifierT, new_name
// word StringCached, new_name
// word StringTable, new_name
// word UsingRegular, new_name
// word UsingNamespace, new_name
// ------------ gencpp Data
// word API_Export, new_name
// word API_Import, new_name
// word AST_POD_Size, new_name
// word AST, new_name
// word AST_POD, new_name
// word Code, new_name
// word Code_POD, new_name
// word Keyword, new_name
// ------------ gencpp API
// word init, new_name
// word deinit, new_name
// word get_cached_string, new_name
// word make_code, new_name
// word make_code_entries, new_name
// word set_allocator_data_arrays, new_name
// word set_allocator_code_pool, new_name
// word set_allocator_code_entries_arena, new_name
// word set_allocator_string_arena, new_name
// word set_allocator_string_table, new_name
// word set_allocator_type_table, new_name
// ------------ upfront constructor namespace
// namespace def_ new_namespace_
// ------------ upfront constructor individual
// word def_attributes, new_name
// word def_comment, new_name
// word def_class, new_name
// word def_constructor, new_name
// word def_destructor, new_name
// word def_define, new_name
// word def_enum, new_name
// word def_execution, new_name
// word def_extern_link, new_name
// word def_friend, new_name
// word def_function, new_name
// word def_include, new_name
// word def_module, new_name
// word def_namespace, new_name
// word def_operator, new_name
// word def_operator_cast, new_name
// word def_param, new_name
// word def_pargma, new_name
// word def_preprocess_cond, new_name
// word def_specifier, new_name
// word def_struct, new_name
// word def_template, new_name
// word def_type, new_name
// word def_typedef, new_name
// word def_union, new_name
// word def_using, new_name
// word def_using_namespace, new_name
// word def_variable, new_name
// word def_body, new_name
// word def_class_body, new_name
// word def_enum_body, new_name
// word def_export_body, new_name
// word def_extern_link_body, new_name
// word def_function_body, new_name
// word def_global_body, new_name
// word def_namespace_body, new_name
// word def_params, new_name
// word def_specifiers, new_name
// word def_struct_body, new_name
// word def_union_body, new_name
// ------------ parse constructor namespace
// namespace parse_, new_namespace_
// ------------ parse constructor individual
// word parse_class, new_name
// word parse_enum, new_name
// word parse_export_body, new_name
// word parse_extern_link, new_name
// word parse_friend, new_name
// word parse_function, new_name
// word parse_global_body, new_name
// word parse_namespace, new_name
// word parse_operator, new_name
// word parse_struct, new_name
// word parse_template, new_name
// word parse_type, new_name
// word parse_typedef, new_name
// word parse_union, new_name
// word parse_using, new_name
// word parse_variable, new_name
// ------------ untyped constructor namespace
// namespace untyped_, new_namespace_
// ------------ untyped constructor individual
// word token_fmt_impl, new_name
// word token_fmt_va, new_name
// word untyped_str, new_name
// word untyped_fmt, new_name
// word untyped_token_fmt, new_name
// ------------ File Ops
// word Builder, new_name
// word Editor, new_name
// word Scanner, new_name
// ------------ gencpp user macros
// word gen_main, new_name
// word GEN_TIME, new_name
// word __, new_name
// word name, new_name
// word code, new_name
// word args, new_name
// word code_str, new_name
// word code_fmt, new_name
// word token_fmt, new_name
// ------------ Type AST namespace
// namespace t_, new_namespace_
// ------------ Specifier AST namespace
// namespace spec_, new_namespace_

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#pragma once
#if GEN_INTELLISENSE_DIRECTIVES
# include "../gen.hpp"
# include "misc.hpp"
using namespace gen;
#endif
CodeBody gen_ecode( char const* path, bool use_c_definition = false )
{
FixedArena_32KB scratch; fixed_arena_init(& scratch);
AllocatorInfo scratch_info = fixed_arena_allocator_info(& scratch);
CSV_Columns2 csv_enum = parse_csv_two_columns( scratch_info, path );
String enum_entries = string_make_reserve( GlobalAllocator, kilobytes(1) );
String to_str_entries = string_make_reserve( GlobalAllocator, kilobytes(1) );
String to_keyword_str_entries = string_make_reserve( GlobalAllocator, kilobytes(1) );
for ( ssize idx = 0; idx < array_num(csv_enum.Col_1); ++ idx ) {
char const* code = csv_enum.Col_1[idx].string;
char const* keyword = csv_enum.Col_2[idx].string;
// TODO(Ed): to_str_entries and the others in here didn't have proper sizing of the StrC slice.
string_append_fmt( & enum_entries, "CT_%s,\n", code );
string_append_fmt( & to_str_entries, "{ sizeof(\"%s\"), \"%s\" },\n", code, code );
string_append_fmt( & to_keyword_str_entries, "{ sizeof(\"%s\") - 1, \"%s\" },\n", keyword, keyword );
}
CodeEnum enum_code;
if (use_c_definition) {
enum_code = parse_enum(token_fmt_impl((3 + 1) / 2, "entries", string_to_strc(enum_entries),
"enum CodeType enum_underlying(u32) { <entries> CT_NumTypes, CT_UnderlyingType = GEN_U32_MAX };"
));
}
else {
enum_code = parse_enum(token_fmt_impl((3 + 1) / 2, "entries", string_to_strc(enum_entries),
"enum CodeType : u32 { <entries> CT_NumTypes, CT_UnderlyingType = GEN_U32_MAX };"
));
}
#pragma push_macro("local_persist")
#undef local_persist
StrC lookup_size = string_to_strc(string_fmt_buf(GlobalAllocator, "%d", array_num(csv_enum.Col_1) ));
CodeBody to_str_fns = parse_global_body( token_fmt(
"entries", string_to_strc(to_str_entries)
, "keywords", string_to_strc(to_keyword_str_entries)
, "num", lookup_size
, stringize(
inline
StrC codetype_to_str( CodeType type )
{
local_persist
StrC lookup[<num>] = {
<entries>
};
return lookup[ type ];
}
inline
StrC codetype_to_keyword_str( CodeType type )
{
local_persist
StrC lookup[ <num> ] = {
<keywords>
};
return lookup[ type ];
}
)));
#pragma pop_macro("local_persist")
CodeBody result = def_body(CT_Global_Body);
body_append(result, enum_code);
if (use_c_definition) {
CodeTypedef code_t = parse_typedef(code(typedef enum CodeType CodeType; ));
body_append(result, code_t);
}
body_append(result, to_str_fns);
if (! use_c_definition) {
#pragma push_macro("forceinline")
#undef forceinline
CodeBody alias_mappings = parse_global_body(code(
forceinline StrC to_str (CodeType type) { return codetype_to_str(type); }
forceinline StrC to_keyword_str(CodeType type) { return codetype_to_keyword_str(type); }
));
#pragma pop_macro("forceinline")
body_append(result, alias_mappings);
}
return result;
}
CodeBody gen_eoperator( char const* path, bool use_c_definition = false )
{
FixedArena_16KB scratch; fixed_arena_init(& scratch);
AllocatorInfo scratch_info = fixed_arena_allocator_info(& scratch);
CSV_Columns2 csv_enum = parse_csv_two_columns( scratch_info, path );
String enum_entries = string_make_reserve( GlobalAllocator, 32 );
String to_str_entries = string_make_reserve( GlobalAllocator, 32 );
for (usize idx = 0; idx < array_num(csv_enum.Col_1); idx++) {
char const* enum_str = csv_enum.Col_1[idx].string;
char const* entry_to_str = csv_enum.Col_2[idx].string;
string_append_fmt( & enum_entries, "Op_%s,\n", enum_str );
string_append_fmt( & to_str_entries, "{ sizeof(\"%s\"), \"%s\" },\n", entry_to_str, entry_to_str);
}
CodeEnum enum_code;
if (use_c_definition)
{
#pragma push_macro("enum_underlying")
#undef enum_underlying
enum_code = parse_enum(token_fmt("entries", string_to_strc(enum_entries), stringize(
enum Operator enum_underlying(u32)
{
<entries>
Op_NumOps,
Op_UnderlyingType = GEN_U32_MAX
};
)));
#pragma pop_macro("enum_underlying")
}
else
{
enum_code = parse_enum(token_fmt("entries", string_to_strc(enum_entries), stringize(
enum Operator : u32
{
<entries>
Op_NumOps,
Op_UnderlyingType = GEN_U32_MAX
};
)));
}
#pragma push_macro("local_persist")
#undef local_persist
StrC lookup_size = string_to_strc(string_fmt_buf(GlobalAllocator, "%d", array_num(csv_enum.Col_1) ));
CodeFn to_str = parse_function(token_fmt(
"entries", string_to_strc(to_str_entries)
, "num", lookup_size
, stringize(
inline
StrC operator_to_str( Operator op )
{
local_persist
StrC lookup[<num>] = {
<entries>
};
return lookup[ op ];
}
)));
#pragma pop_macro("local_persist")
CodeBody result = def_body(CT_Global_Body);
body_append(result, enum_code);
if ( use_c_definition ) {
CodeTypedef operator_t = parse_typedef(code( typedef enum Operator Operator; ));
body_append(result, operator_t);
}
body_append(result, to_str);
if (! use_c_definition)
{
#pragma push_macro("forceinline")
#undef forceinline
CodeBody alias_mappings = parse_global_body(code(
forceinline StrC to_str(Operator op) { return operator_to_str(op); }
));
#pragma pop_macro("forceinline")
body_append(result, alias_mappings);
}
return result;
}
CodeBody gen_especifier( char const* path, bool use_c_definition = false )
{
FixedArena_16KB scratch; fixed_arena_init(& scratch);
AllocatorInfo scratch_info = fixed_arena_allocator_info(& scratch);
CSV_Columns2 csv_enum = parse_csv_two_columns( scratch_info, path );
String enum_entries = string_make_reserve( scratch_info, kilobytes(1) );
String to_str_entries = string_make_reserve( scratch_info, kilobytes(1) );
for (usize idx = 0; idx < array_num(csv_enum.Col_1); idx++)
{
char const* enum_str = csv_enum.Col_1[idx].string;
char const* entry_to_str = csv_enum.Col_2[idx].string;
string_append_fmt( & enum_entries, "Spec_%s,\n", enum_str );
string_append_fmt( & to_str_entries, "{ sizeof(\"%s\"), \"%s\" },\n", entry_to_str, entry_to_str);
}
CodeEnum enum_code;
if (use_c_definition)
{
#pragma push_macro("enum_underlying")
#undef enum_underlying
enum_code = parse_enum(token_fmt("entries", string_to_strc(enum_entries), stringize(
enum Specifier enum_underlying(u32)
{
<entries>
Spec_NumSpecifiers,
Spec_UnderlyingType = GEN_U32_MAX
};
)));
#pragma pop_macro("enum_underlying")
}
else
{
enum_code = parse_enum(token_fmt("entries", string_to_strc(enum_entries), stringize(
enum Specifier : u32
{
<entries>
Spec_NumSpecifiers,
Spec_UnderlyingType = GEN_U32_MAX
};
)));
}
CodeFn is_trailing = parse_function(token_fmt("specifier", string_to_strc(to_str_entries), stringize(
inline
bool spec_is_trailing( Specifier specifier )
{
return specifier > Spec_Virtual;
}
)));
#pragma push_macro("local_persist")
#pragma push_macro("do_once_start")
#pragma push_macro("do_once_end")
#pragma push_macro("forceinline")
#pragma push_macro("neverinline")
#undef local_persist
#undef do_once_start
#undef do_once_end
#undef forceinline
#undef neverinline
StrC lookup_size = string_to_strc(string_fmt_buf(GlobalAllocator, "%d", array_num(csv_enum.Col_1) ));
CodeFn to_str = parse_function(token_fmt(
"entries", string_to_strc(to_str_entries)
, "num", lookup_size
, stringize(
inline
StrC spec_to_str( Specifier type )
{
local_persist
StrC lookup[<num>] = {
<entries>
};
return lookup[ type ];
}
)));
CodeFn to_type = parse_function( token_fmt( "entries", string_to_strc(to_str_entries), stringize(
inline
Specifier strc_to_specifier( StrC str )
{
local_persist
u32 keymap[ Spec_NumSpecifiers ];
do_once_start
for ( u32 index = 0; index < Spec_NumSpecifiers; index++ )
{
StrC enum_str = spec_to_str( (Specifier)index );
// We subtract 1 to remove the null terminator
// This is because the tokens lexed are not null terminated.
keymap[index] = crc32( enum_str.Ptr, enum_str.Len - 1);
}
do_once_end
u32 hash = crc32( str.Ptr, str.Len );
for ( u32 index = 0; index < Spec_NumSpecifiers; index++ )
{
if ( keymap[index] == hash )
return (Specifier)index;
}
return Spec_Invalid;
}
)));
#pragma pop_macro("local_persist")
#pragma pop_macro("do_once_start")
#pragma pop_macro("do_once_end")
#pragma pop_macro("forceinline")
#pragma pop_macro("neverinline")
CodeBody result = def_body(CT_Global_Body);
body_append(result, enum_code);
if (use_c_definition)
{
CodeTypedef specifier_t = parse_typedef( code(typedef u32 Specifier; ));
body_append(result, specifier_t);
}
body_append(result, to_str);
body_append(result, is_trailing);
body_append(result, to_type);
if (! use_c_definition)
{
#pragma push_macro("forceinline")
#undef forceinline
CodeBody alias_mappings = parse_global_body(code(
forceinline StrC to_str (Specifier spec) { return spec_to_str(spec); }
forceinline Specifier to_type( StrC str ) { return strc_to_specifier(str); }
forceinline bool is_trailing( Specifier specifier ) { return spec_is_trailing(specifier); }
));
#pragma pop_macro("forceinline")
body_append(result, alias_mappings);
}
return result;
}
CodeBody gen_etoktype( char const* etok_path, char const* attr_path, bool use_c_definition = false )
{
FixedArena_64KB scratch; fixed_arena_init(& scratch);
AllocatorInfo scratch_info = fixed_arena_allocator_info(& scratch);
FileContents enum_content = file_read_contents( scratch_info, file_zero_terminate, etok_path );
CSV_Object csv_enum_nodes;
csv_parse( &csv_enum_nodes, rcast(char*, enum_content.data), scratch_info, false );
FileContents attrib_content = file_read_contents( scratch_info, file_zero_terminate, attr_path );
CSV_Object csv_attr_nodes;
csv_parse( &csv_attr_nodes, rcast(char*, attrib_content.data), scratch_info, false );
Array<ADT_Node> enum_strs = csv_enum_nodes.nodes[0].nodes;
Array<ADT_Node> enum_str_strs = csv_enum_nodes.nodes[1].nodes;
Array<ADT_Node> attribute_strs = csv_attr_nodes.nodes[0].nodes;
Array<ADT_Node> attribute_str_strs = csv_attr_nodes.nodes[1].nodes;
String enum_entries = string_make_reserve( scratch_info, kilobytes(2) );
String to_str_entries = string_make_reserve( scratch_info, kilobytes(4) );
String attribute_entries = string_make_reserve( scratch_info, kilobytes(2) );
String to_str_attributes = string_make_reserve( scratch_info, kilobytes(4) );
String attribute_define_entries = string_make_reserve( scratch_info, kilobytes(4) );
for (usize idx = 0; idx < array_num(enum_strs); idx++)
{
char const* enum_str = enum_strs[idx].string;
char const* entry_to_str = enum_str_strs [idx].string;
string_append_fmt( & enum_entries, "Tok_%s,\n", enum_str );
string_append_fmt( & to_str_entries, "{ sizeof(\"%s\"), \"%s\" },\n", entry_to_str, entry_to_str);
}
for ( usize idx = 0; idx < array_num(attribute_strs); idx++ )
{
char const* attribute_str = attribute_strs[idx].string;
char const* entry_to_str = attribute_str_strs [idx].string;
string_append_fmt( & attribute_entries, "Tok_Attribute_%s,\n", attribute_str );
string_append_fmt( & to_str_attributes, "{ sizeof(\"%s\"), \"%s\" },\n", entry_to_str, entry_to_str);
string_append_fmt( & attribute_define_entries, "Entry( Tok_Attribute_%s, \"%s\" )", attribute_str, entry_to_str );
if ( idx < array_num(attribute_strs) - 1 )
string_append_strc( & attribute_define_entries, txt(" \\\n"));
else
string_append_strc( & attribute_define_entries, txt("\n"));
}
#pragma push_macro("GEN_DEFINE_ATTRIBUTE_TOKENS")
#undef GEN_DEFINE_ATTRIBUTE_TOKENS
CodeDefine attribute_entires_def = def_define( name(GEN_DEFINE_ATTRIBUTE_TOKENS), string_to_strc(attribute_define_entries) );
#pragma pop_macro("GEN_DEFINE_ATTRIBUTE_TOKENS")
// We cannot parse this enum, it has Attribute names as enums
CodeEnum enum_code;
if (use_c_definition)
{
enum_code = parse_enum(token_fmt("entries", string_to_strc(enum_entries), "attribute_toks", string_to_strc(attribute_entries), stringize(
enum TokType
{
<entries>
<attribute_toks>
Tok_NumTokens,
Tok_UnderlyingType = GEN_U32_MAX
};
)));
}
else
{
enum_code = parse_enum(token_fmt("entries", string_to_strc(enum_entries), "attribute_toks", string_to_strc(attribute_entries), stringize(
enum TokType : u32
{
<entries>
<attribute_toks>
Tok_NumTokens
};
)));
}
#pragma push_macro("local_persist")
#pragma push_macro("do_once_start")
#pragma push_macro("do_once_end")
#undef local_persist
#undef do_once_start
#undef do_once_end
CodeFn to_str = parse_function(token_fmt("entries", string_to_strc(to_str_entries), "attribute_toks", string_to_strc(to_str_attributes), stringize(
inline
StrC toktype_to_str( TokType type )
{
local_persist
StrC lookup[] = {
<entries>
<attribute_toks>
};
return lookup[ type ];
}
)));
CodeFn to_type = parse_function( token_fmt( "entries", string_to_strc(to_str_entries), stringize(
inline
TokType strc_to_toktype( StrC str )
{
local_persist
u32 keymap[ Tok_NumTokens ];
do_once_start
for ( u32 index = 0; index < Tok_NumTokens; index++ )
{
StrC enum_str = toktype_to_str( (TokType)index );
// We subtract 1 to remove the null terminator
// This is because the tokens lexed are not null terminated.
keymap[index] = crc32( enum_str.Ptr, enum_str.Len - 1);
}
do_once_end
u32 hash = crc32( str.Ptr, str.Len );
for ( u32 index = 0; index < Tok_NumTokens; index++ )
{
if ( keymap[index] == hash )
return (TokType)index;
}
return Tok_Invalid;
}
)));
#pragma pop_macro("local_persist")
#pragma pop_macro("do_once_start")
#pragma pop_macro("do_once_end")
CodeBody result = def_body(CT_Global_Body);
body_append(result, untyped_str(txt("GEN_NS_PARSER_BEGIN\n\n")));
body_append(result, attribute_entires_def);
body_append(result, enum_code);
if (use_c_definition)
{
CodeTypedef td_toktype = parse_typedef( code( typedef enum TokType TokType; ));
body_append(result, td_toktype);
}
body_append(result, to_str);
body_append(result, to_type);
body_append(result, untyped_str(txt("\nGEN_NS_PARSER_END\n\n")));
return result;
}
CodeBody gen_ast_inlines()
{
#pragma push_macro("GEN_NS")
#pragma push_macro("rcast")
#pragma push_macro("log_failure")
#pragma push_macro("CodeInvalid")
#undef GEN_NS
#undef rcast
#undef log_failure
#undef CodeInvalid
char const* code_impl_tmpl = stringize(
\n
inline
<typename>& <typename>::operator =( Code other )
{
if ( other.ast != nullptr && other->Parent != nullptr )
{
ast = rcast( decltype(ast), code_duplicate(other).ast);
ast->Parent = { nullptr };
}
ast = rcast( decltype( ast ), other.ast );
return * this;
}
inline
<typename>::operator bool()
{
return ast != nullptr;
}
);
char const* codetype_impl_tmpl = stringize(
inline
Code<typename>::operator Code()
{
return *rcast( Code*, this );
}
inline
AST_<typename>* Code<typename>::operator->()
{
if ( ast == nullptr )
{
log_failure( "Attempt to dereference a nullptr!" );
return nullptr;
}
return ast;
}
\n
);
#pragma pop_macro("GEN_NS")
#pragma pop_macro("CodeInvalid")
CodeBody impl_code = parse_global_body( token_fmt( "typename", StrC name(Code), code_impl_tmpl ));
CodeBody impl_code_body = parse_global_body( token_fmt( "typename", StrC name(CodeBody), code_impl_tmpl ));
CodeBody impl_code_attr = parse_global_body( token_fmt( "typename", StrC name(CodeAttributes), code_impl_tmpl ));
CodeBody impl_code_cmt = parse_global_body( token_fmt( "typename", StrC name(CodeComment), code_impl_tmpl ));
CodeBody impl_code_constr = parse_global_body( token_fmt( "typename", StrC name(CodeConstructor), code_impl_tmpl ));
CodeBody impl_code_class = parse_global_body( token_fmt( "typename", StrC name(CodeClass), code_impl_tmpl ));
CodeBody impl_code_define = parse_global_body( token_fmt( "typename", StrC name(CodeDefine), code_impl_tmpl ));
CodeBody impl_code_destruct = parse_global_body( token_fmt( "typename", StrC name(CodeDestructor), code_impl_tmpl ));
CodeBody impl_code_enum = parse_global_body( token_fmt( "typename", StrC name(CodeEnum), code_impl_tmpl ));
CodeBody impl_code_exec = parse_global_body( token_fmt( "typename", StrC name(CodeExec), code_impl_tmpl ));
CodeBody impl_code_extern = parse_global_body( token_fmt( "typename", StrC name(CodeExtern), code_impl_tmpl ));
CodeBody impl_code_include = parse_global_body( token_fmt( "typename", StrC name(CodeInclude), code_impl_tmpl ));
CodeBody impl_code_friend = parse_global_body( token_fmt( "typename", StrC name(CodeFriend), code_impl_tmpl ));
CodeBody impl_code_fn = parse_global_body( token_fmt( "typename", StrC name(CodeFn), code_impl_tmpl ));
CodeBody impl_code_module = parse_global_body( token_fmt( "typename", StrC name(CodeModule), code_impl_tmpl ));
CodeBody impl_code_ns = parse_global_body( token_fmt( "typename", StrC name(CodeNS), code_impl_tmpl ));
CodeBody impl_code_op = parse_global_body( token_fmt( "typename", StrC name(CodeOperator), code_impl_tmpl ));
CodeBody impl_code_opcast = parse_global_body( token_fmt( "typename", StrC name(CodeOpCast), code_impl_tmpl ));
CodeBody impl_code_params = parse_global_body( token_fmt( "typename", StrC name(CodeParams), code_impl_tmpl ));
CodeBody impl_code_pragma = parse_global_body( token_fmt( "typename", StrC name(CodePragma), code_impl_tmpl ));
CodeBody impl_code_precond = parse_global_body( token_fmt( "typename", StrC name(CodePreprocessCond), code_impl_tmpl ));
CodeBody impl_code_specs = parse_global_body( token_fmt( "typename", StrC name(CodeSpecifiers), code_impl_tmpl ));
CodeBody impl_code_struct = parse_global_body( token_fmt( "typename", StrC name(CodeStruct), code_impl_tmpl ));
CodeBody impl_code_tmpl = parse_global_body( token_fmt( "typename", StrC name(CodeTemplate), code_impl_tmpl ));
CodeBody impl_code_type = parse_global_body( token_fmt( "typename", StrC name(CodeTypename), code_impl_tmpl ));
CodeBody impl_code_typedef = parse_global_body( token_fmt( "typename", StrC name(CodeTypedef), code_impl_tmpl ));
CodeBody impl_code_union = parse_global_body( token_fmt( "typename", StrC name(CodeUnion), code_impl_tmpl ));
CodeBody impl_code_using = parse_global_body( token_fmt( "typename", StrC name(CodeUsing), code_impl_tmpl ));
CodeBody impl_code_var = parse_global_body( token_fmt( "typename", StrC name(CodeVar), code_impl_tmpl ));
body_append(impl_code_attr, parse_global_body( token_fmt( "typename", StrC name(Attributes), codetype_impl_tmpl )));
body_append(impl_code_cmt, parse_global_body( token_fmt( "typename", StrC name(Comment), codetype_impl_tmpl )));
body_append(impl_code_constr, parse_global_body( token_fmt( "typename", StrC name(Constructor), codetype_impl_tmpl )));
body_append(impl_code_define, parse_global_body( token_fmt( "typename", StrC name(Define), codetype_impl_tmpl )));
body_append(impl_code_destruct, parse_global_body( token_fmt( "typename", StrC name(Destructor), codetype_impl_tmpl )));
body_append(impl_code_enum, parse_global_body( token_fmt( "typename", StrC name(Enum), codetype_impl_tmpl )));
body_append(impl_code_exec, parse_global_body( token_fmt( "typename", StrC name(Exec), codetype_impl_tmpl )));
body_append(impl_code_extern, parse_global_body( token_fmt( "typename", StrC name(Extern), codetype_impl_tmpl )));
body_append(impl_code_include, parse_global_body( token_fmt( "typename", StrC name(Include), codetype_impl_tmpl )));
body_append(impl_code_friend, parse_global_body( token_fmt( "typename", StrC name(Friend), codetype_impl_tmpl )));
body_append(impl_code_fn, parse_global_body( token_fmt( "typename", StrC name(Fn), codetype_impl_tmpl )));
body_append(impl_code_module, parse_global_body( token_fmt( "typename", StrC name(Module), codetype_impl_tmpl )));
body_append(impl_code_ns, parse_global_body( token_fmt( "typename", StrC name(NS), codetype_impl_tmpl )));
body_append(impl_code_op, parse_global_body( token_fmt( "typename", StrC name(Operator), codetype_impl_tmpl )));
body_append(impl_code_opcast, parse_global_body( token_fmt( "typename", StrC name(OpCast), codetype_impl_tmpl )));
body_append(impl_code_pragma, parse_global_body( token_fmt( "typename", StrC name(Pragma), codetype_impl_tmpl )));
body_append(impl_code_precond, parse_global_body( token_fmt( "typename", StrC name(PreprocessCond), codetype_impl_tmpl )));
body_append(impl_code_tmpl, parse_global_body( token_fmt( "typename", StrC name(Template), codetype_impl_tmpl )));
body_append(impl_code_type, parse_global_body( token_fmt( "typename", StrC name(Typename), codetype_impl_tmpl )));
body_append(impl_code_typedef, parse_global_body( token_fmt( "typename", StrC name(Typedef), codetype_impl_tmpl )));
body_append(impl_code_union, parse_global_body( token_fmt( "typename", StrC name(Union), codetype_impl_tmpl )));
body_append(impl_code_using, parse_global_body( token_fmt( "typename", StrC name(Using), codetype_impl_tmpl )));
body_append(impl_code_var, parse_global_body( token_fmt( "typename", StrC name(Var), codetype_impl_tmpl )));
#pragma push_macro("forceinline")
#undef forceinline
char const* cast_tmpl = stringize(
forceinline Code::operator Code<typename>() const
{
return { (AST_<typename>*) ast };
}
);
#pragma pop_macro("forceinline")
CodeBody impl_cast_body = parse_global_body( token_fmt( "typename", StrC name(Body), cast_tmpl ));
CodeBody impl_cast_attribute = parse_global_body( token_fmt( "typename", StrC name(Attributes), cast_tmpl ));
CodeBody impl_cast_cmt = parse_global_body( token_fmt( "typename", StrC name(Comment), cast_tmpl ));
CodeBody impl_cast_constr = parse_global_body( token_fmt( "typename", StrC name(Constructor), cast_tmpl ));
CodeBody impl_cast_class = parse_global_body( token_fmt( "typename", StrC name(Class), cast_tmpl ));
CodeBody impl_cast_define = parse_global_body( token_fmt( "typename", StrC name(Define), cast_tmpl ));
CodeBody impl_cast_destruct = parse_global_body( token_fmt( "typename", StrC name(Destructor), cast_tmpl ));
CodeBody impl_cast_enum = parse_global_body( token_fmt( "typename", StrC name(Enum), cast_tmpl ));
CodeBody impl_cast_exec = parse_global_body( token_fmt( "typename", StrC name(Exec), cast_tmpl ));
CodeBody impl_cast_extern = parse_global_body( token_fmt( "typename", StrC name(Extern), cast_tmpl ));
CodeBody impl_cast_friend = parse_global_body( token_fmt( "typename", StrC name(Friend), cast_tmpl ));
CodeBody impl_cast_fn = parse_global_body( token_fmt( "typename", StrC name(Fn), cast_tmpl ));
CodeBody impl_cast_include = parse_global_body( token_fmt( "typename", StrC name(Include), cast_tmpl ));
CodeBody impl_cast_module = parse_global_body( token_fmt( "typename", StrC name(Module), cast_tmpl ));
CodeBody impl_cast_ns = parse_global_body( token_fmt( "typename", StrC name(NS), cast_tmpl ));
CodeBody impl_cast_op = parse_global_body( token_fmt( "typename", StrC name(Operator), cast_tmpl ));
CodeBody impl_cast_opcast = parse_global_body( token_fmt( "typename", StrC name(OpCast), cast_tmpl ));
CodeBody impl_cast_params = parse_global_body( token_fmt( "typename", StrC name(Params), cast_tmpl ));
CodeBody impl_cast_pragma = parse_global_body( token_fmt( "typename", StrC name(Pragma), cast_tmpl ));
CodeBody impl_cast_precond = parse_global_body( token_fmt( "typename", StrC name(PreprocessCond), cast_tmpl ));
CodeBody impl_cast_specs = parse_global_body( token_fmt( "typename", StrC name(Specifiers), cast_tmpl ));
CodeBody impl_cast_struct = parse_global_body( token_fmt( "typename", StrC name(Struct), cast_tmpl ));
CodeBody impl_cast_tmpl = parse_global_body( token_fmt( "typename", StrC name(Template), cast_tmpl ));
CodeBody impl_cast_type = parse_global_body( token_fmt( "typename", StrC name(Typename), cast_tmpl ));
CodeBody impl_cast_typedef = parse_global_body( token_fmt( "typename", StrC name(Typedef), cast_tmpl ));
CodeBody impl_cast_union = parse_global_body( token_fmt( "typename", StrC name(Union), cast_tmpl ));
CodeBody impl_cast_using = parse_global_body( token_fmt( "typename", StrC name(Using), cast_tmpl ));
CodeBody impl_cast_var = parse_global_body( token_fmt( "typename", StrC name(Var), cast_tmpl ));
CodeBody result = def_global_body( args(
def_pragma( txt("region generated code inline implementation")),
fmt_newline,
impl_code,
impl_code_body,
impl_code_attr,
impl_code_cmt,
impl_code_constr,
impl_code_class,
impl_code_define,
impl_code_destruct,
impl_code_enum,
impl_code_exec,
impl_code_extern,
impl_code_friend,
impl_code_fn,
impl_code_include,
impl_code_module,
impl_code_ns,
impl_code_op,
impl_code_opcast,
impl_code_params,
impl_code_pragma,
impl_code_precond,
impl_code_specs,
impl_code_struct,
impl_code_tmpl,
impl_code_type,
impl_code_typedef,
impl_code_union,
impl_code_using,
impl_code_var,
fmt_newline,
def_pragma( txt("endregion generated code inline implementation")),
fmt_newline,
def_pragma( txt("region generated AST/Code cast implementation")),
untyped_str(txt("GEN_OPTIMIZE_MAPPINGS_BEGIN\n")),
fmt_newline,
impl_cast_body,
impl_cast_attribute,
impl_cast_cmt,
impl_cast_constr,
impl_cast_class,
impl_cast_define,
impl_cast_destruct,
impl_cast_enum,
impl_cast_exec,
impl_cast_extern,
impl_cast_friend,
impl_cast_fn,
impl_cast_include,
impl_cast_module,
impl_cast_ns,
impl_cast_op,
impl_cast_opcast,
impl_cast_params,
impl_cast_pragma,
impl_cast_precond,
impl_cast_specs,
impl_cast_struct,
impl_cast_tmpl,
impl_cast_type,
impl_cast_typedef,
impl_cast_union,
impl_cast_using,
impl_cast_var,
fmt_newline,
untyped_str(txt("GEN_OPITMIZE_MAPPINGS_END\n")),
def_pragma( txt("endregion generated AST/Code cast implementation")),
fmt_newline
));
return result;
#pragma pop_macro("rcast")
#pragma pop_macro("log_failure")
}

80
base/helpers/misc.hpp Normal file
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#pragma once
#ifdef GEN_INTELLISENSE_DIRECTIVES
# define GEN_DEFINE_LIBRARY_CODE_CONSTANTS
# define GEN_ENFORCE_STRONG_CODE_TYPES
# define GEN_EXPOSE_BACKEND
# include "gen.hpp"
# include "helpers/push_ignores.inline.hpp"
# include "helpers/helper.hpp"
# include "auxillary/builder.hpp"
# include "auxillary/builder.cpp"
# include "auxillary/scanner.hpp"
#include <stdlib.h>
using namespace gen;
#endif
// Will format a file with the given style at the provided path.
// Assumes clang-format is defined in an user-exposed or system enviornment PATH.
void clang_format_file( char const* path, char const* style_path )
{
GEN_ASSERT_NOT_NULL(path);
String resolved_path = string_make_strc(GlobalAllocator, to_strc_from_c_str(path));
String style_arg;
if (style_path) {
style_arg = string_make_strc(GlobalAllocator, txt("-style=file:"));
string_append_fmt( & style_arg, "%s ", style_path );
}
StrC clang_format = txt("clang-format ");
StrC cf_format_inplace = txt("-i ");
StrC cf_verbose = txt("-verbose ");
String command = string_make_strc( GlobalAllocator, clang_format );
string_append_strc( & command, cf_format_inplace );
string_append_strc( & command, cf_verbose );
string_append_string( & command, style_arg );
string_append_string( & command, resolved_path );
system( command );
}
// Will refactor a file with the given script at the provided path.
// Assumes refactor is defined in an user-exposed or system enviornment PATH.
// (See: ./gencpp/scripts/build.ci.ps1 for how)
void refactor_file( char const* path, char const* refactor_script )
{
GEN_ASSERT_NOT_NULL(path);
GEN_ASSERT_NOT_NULL(refactor_script);
String command = string_make_strc(GlobalAllocator, txt("refactor "));
// string_append_strc( & command, txt("-debug ") );
string_append_strc( & command, txt("-num=1 ") );
string_append_fmt( & command, "-src=%s ", path );
string_append_fmt( & command,"-spec=%s ", refactor_script );
system(command);
log_fmt("\n");
}
// Does either of the above or both to the provided code.
// Code returned will be untyped content (its be serialized)
Code code_refactor_and_format( Code code, char const* scratch_path, char const* refactor_script, char const* clang_format_sytle_path )
{
GEN_ASSERT(code);
GEN_ASSERT_NOT_NULL(scratch_path);
Builder scratch_file = builder_open( scratch_path );
builder_print( & scratch_file, code);
builder_write(& scratch_file);
if (refactor_script) {
refactor_file(scratch_path, refactor_script);
}
if ( clang_format_sytle_path ) {
clang_format_file(scratch_path, clang_format_sytle_path);
}
Code result = scan_file( scratch_path );
::remove(scratch_path);
return result;
}

39
base/helpers/pop_container_defines.inline.hpp Normal file
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@ -0,0 +1,39 @@
#undef array_init
#undef array_init_reserve
#undef array_append_array
#undef array_append
#undef array_append_items
#undef array_append_at
#undef array_append_items_at
#undef array_back
#undef array_clear
#undef array_fill
#undef array_free
#undef arary_grow
#undef array_num
#undef arary_pop
#undef arary_remove_at
#undef arary_reserve
#undef arary_resize
#undef arary_set_capacity
#undef arary_get_header
#undef hashtable_init
#undef hashtable_init_reserve
#undef hashtable_clear
#undef hashtable_destroy
#undef hashtable_get
#undef hashtable_grow
#undef hashtable_rehash
#undef hashtable_rehash_fast
#undef hashtable_remove
#undef hashtable_remove_entry
#undef hashtable_set
#undef hashtable_slot
#undef hashtable_map
#undef hashtable_map_mut
//#undef hashtable_add_entry
//#undef hashtable_find
//#undef hashtable_full

7
base/helpers/pop_ignores.inline.hpp Normal file
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#ifdef __clang__
# pragma clang diagnostic pop
#endif
#ifdef __GNUC__
# pragma GCC diagnostic pop
#endif

39
base/helpers/push_container_defines.inline.hpp Normal file
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#define array_init(type, allocator) array_init <type> (allocator )
#define array_init_reserve(type, allocator, cap) array_init_reserve <type> (allocator, cap)
#define array_append_array(array, other) array_append_array < get_array_underlying_type(array) > (& array, other )
#define array_append(array, value) array_append < get_array_underlying_type(array) > (& array, value )
#define array_append_items(array, items, item_num) array_append_items < get_array_underlying_type(array) > (& array, items, item_num )
#define array_append_at(array, item, idx ) array_append_at < get_array_underlying_type(array) > (& array, item, idx )
#define array_append_at_items(array, items, item_num, idx) array_append_at_items< get_array_underlying_type(array) > (& items, item_num, idx )
#define array_back(array) array_back < get_array_underlying_type(array) > (array )
#define array_clear(array) array_clear < get_array_underlying_type(array) > (array )
#define array_fill(array, begin, end, value) array_fill < get_array_underlying_type(array) > (array, begin, end, value )
#define array_free(array) array_free < get_array_underlying_type(array) > (& array )
#define arary_grow(array, min_capacity) arary_grow < get_array_underlying_type(array) > (& array, min_capacity)
#define array_num(array) array_num < get_array_underlying_type(array) > (array )
#define arary_pop(array) arary_pop < get_array_underlying_type(array) > (array )
#define arary_remove_at(array, idx) arary_remove_at < get_array_underlying_type(array) > (idx)
#define arary_reserve(array, new_capacity) arary_reserve < get_array_underlying_type(array) > (& array, new_capacity )
#define arary_resize(array, num) arary_resize < get_array_underlying_type(array) > (& array, num)
#define arary_set_capacity(new_capacity) arary_set_capacity < get_array_underlying_type(array) > (& array, new_capacity )
#define arary_get_header(array) arary_get_header < get_array_underlying_type(array) > (array )
#define hashtable_init(type, allocator) hashtable_init <type >(allocator)
#define hashtable_init_reserve(type, allocator, num) hashtable_init_reserve<type >(allocator, num)
#define hashtable_clear(table) hashtable_clear < get_hashtable_underlying_type(table) >(table)
#define hashtable_destroy(table) hashtable_destroy < get_hashtable_underlying_type(table) >(& table)
#define hashtable_get(table, key) hashtable_get < get_hashtable_underlying_type(table) >(table, key)
#define hashtable_grow(table) hashtable_grow < get_hashtable_underlying_type(table) >(& table)
#define hashtable_rehash(table, new_num) hashtable_rehash < get_hashtable_underlying_type(table) >(& table, new_num)
#define hashtable_rehash_fast(table) hashtable_rehash_fast < get_hashtable_underlying_type(table) >(table)
#define hashtable_remove(table, key) hashtable_remove < get_hashtable_underlying_type(table) >(table, key)
#define hashtable_remove_entry(table, idx) hashtable_remove_entry< get_hashtable_underlying_type(table) >(table, idx)
#define hashtable_set(table, key, value) hashtable_set < get_hashtable_underlying_type(table) >(& table, key, value)
#define hashtable_slot(table, key) hashtable_slot < get_hashtable_underlying_type(table) >(table, key)
#define hashtable_map(table, map_proc) hashtable_map < get_hashtable_underlying_type(table) >(table, map_proc)
#define hashtable_map_mut(table, map_proc) hashtable_map_mut < get_hashtable_underlying_type(table) >(table, map_proc)
//#define hashtable_add_entry(table, key) hashtable_add_entry < get_hashtable_underlying_type(table) >(& table, key)
//#define hashtable_find(table, key) hashtable_find < get_hashtable_underlying_type(table) >(table, key)
//#define hashtable_full(table) hashtable_full < get_hashtable_underlying_type(table) >(table)

21
base/helpers/push_ignores.inline.hpp Normal file
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#ifdef __clang__
# pragma clang diagnostic push
# pragma clang diagnostic ignored "-Wunused-const-variable"
# pragma clang diagnostic ignored "-Wunused-but-set-variable"
# pragma clang diagnostic ignored "-Wswitch"
# pragma clang diagnostic ignored "-Wunused-variable"
# pragma clang diagnostic ignored "-Wunknown-pragmas"
# pragma clang diagnostic ignored "-Wvarargs"
# pragma clang diagnostic ignored "-Wunused-function"
# pragma clang diagnostic ignored "-Wbraced-scalar-init"
# pragma clang diagnostic ignored "-W#pragma-messages"
# pragma clang diagnostic ignored "-Wstatic-in-inline"
#endif
#ifdef __GNUC__
# pragma GCC diagnostic push
# pragma GCC diagnostic ignored "-Wunknown-pragmas"
# pragma GCC diagnostic ignored "-Wcomment"
# pragma GCC diagnostic ignored "-Wswitch"
# pragma GCC diagnostic ignored "-Wunused-variable"
#endif

203
base/helpers/undef.macros.h Normal file
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// This undefines the macros used by the gen library
#undef GEN_TIME
#undef GEN_ARCH_64_BIT
#undef GEN_ARCH_32_BIT
#undef GEN_SYSTEM_ANDROID
#undef GEN_SYSTEM_CYGWIN
#undef GEN_SYSTEM_EMSCRIPTEN
#undef GEN_SYSTEM_FREEBSD
#undef GEN_SYSTEM_IOS
#undef GEN_SYSTEM_LINUX
#undef GEN_SYSTEM_MACOS
#undef GEN_SYSTEM_OPENBSD
#undef GEN_SYSTEM_OSX
#undef GEN_SYSTEM_UNIX
#undef GEN_SYSTEM_WINDOWS
#undef GEN_COMPILER_CLANG
#undef GEN_COMPILER_GCC
#undef GEN_COMPILER_MSVC
#undef GEN_HAS_ATTRIBUTE
#undef GEN_COMPILER_C
#undef GEN_COMPILER_CPP
#undef GEN_DONT_USE_NAMESPACE
#undef GEN_NS_PARSER_BEGIN
#undef GEN_NS_PARSER_END
#undef GEN_USING_NS_PARSER
#undef GEN_NS_PARSER
#undef GEN_NS
#undef GEN_NS_BEGIN
#undef GEN_NS_END
#undef GEN_C_LIKE_CPP
#undef global
#undef internal
#undef local_persist
#undef bit
#undef bitfield_is_equal
#undef cast
#undef ccast
#undef scast
#undef rcast
#undef pcast
#undef stringize
#undef do_once
#undef do_once_start
#undef do_once_end
#undef labeled_scope_start
#undef labeled_scope_end
#undef compiler_decorated_func_name
#undef num_args_impl
#undef num_args
#undef clamp
#undef count_of
#undef is_between
#undef size_of
#undef max
#undef min
#undef offset_of
#undef forceinline
#undef neverinline
#undef static_assert
#undef thread_local
#undef typeof
#undef GEN_API_C_BEGIN
#undef GEN_API_C_END
#undef enum_underlying
#undef nullptr
#undef GEN_PARAM_DEFAULT
#undef struct_init
#undef GEN_OPTIMIZE_MAPPINGS_BEGIN
#undef GEN_OPITMIZE_MAPPINGS_END
#undef GEN_U8_MIN
#undef GEN_U8_MAX
#undef GEN_I8_MIN
#undef GEN_I8_MAX
#undef GEN_U16_MIN
#undef GEN_U16_MAX
#undef GEN_I16_MIN
#undef GEN_I16_MAX
#undef GEN_U32_MIN
#undef GEN_U32_MAX
#undef GEN_I32_MIN
#undef GEN_I32_MAX
#undef GEN_U64_MIN
#undef GEN_U64_MAX
#undef GEN_I64_MIN
#undef GEN_I64_MAX
#undef GEN_USIZE_MIN
#undef GEN_USIZE_MAX
#undef GEN_ISIZE_MIN
#undef GEN_ISIZE_MAX
#undef GEN_USIZE_MIN
#undef GEN_USIZE_MAX
#undef GEN_ISIZE_MIN
#undef GEN_ISIZE_MAX
#undef GEN_F32_MIN
#undef GEN_F32_MAX
#undef GEN_F64_MIN
#undef GEN_F64_MAX
#undef to_uptr
#undef to_sptr
#undef to_mem_ptr
#undef to_mem_ptr_const
#undef kilobytes
#undef megabytes
#undef gigabytes
#undef terabytes
#undef GEN__ONES
#undef GEN__HIGHS
#undef GEN__HAS_ZERO
#undef GEN_DEFAULT_MEMORY_ALIGNMENT
#undef GEN_DEFAULT_ALLOCATOR_FLAGS
#undef zero_item
#undef zero_array
#undef alloc_item
#undef alloc_array
#undef malloc
#undef mfree
#undef GEN_DEBUG_TRAP
#undef GEN_ASSERT
#undef GEN_ASSERT_MSG
#undef GEN_ASSERT_NOT_NULL
#undef GEN_PANIC
#undef GEN_FATAL
#undef GEN_FILE_OPEN_PROC
#undef GEN_FILE_READ_AT_PROC
#undef GEN_FILE_WRITE_AT_PROC
#undef GEN_FILE_SEEK_PROC
#undef GEN_FILE_CLOSE_PROC
#undef GEN_PRINTF_MAXLEN
#undef _strlen
#undef _printf_err
#undef _printf_err_va
#undef _strlen
#undef _printf_err
#undef _printf_err_va
#undef Array
#undef get_array_underlying_type
#undef HashTable
#undef get_hashtable_underlying_type
#undef txt
#undef NOMINMAX
#undef VC_EXTRALEAN
#undef WIN32_LEAN_AND_MEAN
#undef WIN32_MEAN_AND_LEAN
#undef GEN_DEFINE_ATTRIBUTE_TOKENS
#undef GEN_AST_BODY_CLASS_UNALLOWED_TYPES
#undef GEN_AST_BODY_FUNCTION_UNALLOWED_TYPES
#undef GEN_AST_BODY_GLOBAL_UNALLOWED_TYPES
#undef GEN_AST_BODY_EXPORT_UNALLOWED_TYPES
#undef GEN_AST_BODY_EXTERN_LINKAGE_UNALLOWED_TYPES
#undef GEN_AST_BODY_NAMESPACE_UNALLOWED_TYPES
#undef GEN_GLOBAL_BUCKET_SIZE
#undef GEN_CODEPOOL_NUM_BLOCKS
#undef GEN_SIZE_PER_STRING_ARENA
#undef GEN_MAX_COMMENT_LINE_LENGTH
#undef GEN_MAX_NAME_LENGTH
#undef GEN_MAX_UNTYPED_STR_LENGTH
#undef TokenMap_FixedArena
#undef GEN_LEX_ALLOCATOR_SIZE
#undef GEN_BUILDER_STR_BUFFER_RESERVE
#undef log_failure
#undef gen_main
#undef name
#undef code
#undef args
#undef code_str
#undef code_fmt
#undef token_fmt
#undef parse_fmt
#undef token_fmt

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## Navigation
[Top](../Readme.md)
<- [docs - General](Readme.md)
## Current Design
`AST` is the actual managed node object for the library.
Its raw and really not meant to be used directly.
All user interaction must be with its pointer so the type they deal with is `AST*`.
In order to abstract away constant use of `AST*` its wrapped in a Code type which can be either:
When its the [C generated variant of the library](../gen_c_library/)
```c
typedef AST* Code;
tyepdef AST_<name>* Code<name>;
...
```
**or**
For C++:
```cpp
struct Code {
AST* ast;
};
struct Code<name> {
...
AST_<name>* ast;
};
```
The full definitions of all asts are within:
* [`ast.hpp`](../base/components/ast.hpp)
* [`ast_types.hpp`](../base/components/ast_types.hpp)
* [`code_types.hpp`](../base/components/ast_types.hpp)
The C/C++ interface procedures are located with `ast.hpp` (for the Code type), and `code_types.hpp` for all others.
## Serialization
All code types can either serialize using a function of the pattern:
```c
String <prefix>_to_string(Code code);
// or
<prefix>_to_string(Code code, String& result);
```
Where the first generates strings allocated using Allocator_StringArena and the other appends an existing strings with their backed allocator.
Serialization of for the AST is defined for `Code` in [`ast.chpp`](../base/components/ast.cpp) with `code_to_string_ptr` & `code_to_string`.
Serializtion for the rest of the code types is within [`code_serialization.cpp`](../base/components/code_serialization.cpp).
Gencpp's serialization does not provide coherent formatting of the code. The user should use a formatter after serializing.

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## Navigation
[Top](../Readme.md)
<- [docs - General](Readme.md)
# AST Types Documentation
While the Readme for docs covers the data layout per AST, this will focus on the AST types avaialble, and their nuances.
## Body
These are containers representing a scope body of a definition that can be of the following `CodeType` type:
* Class_Body
* Enum_Body
* Export_Body
* Extern_Linkage_Body
* Function_Body
* Global_Body
* Namespace_Body
* Struct_Body
* Union_Body
Fields:
```cpp
StringCached Name;
Code Front;
Code Back;
Token* Tok;
Code Parent;
CodeT Type;
s32 NumEntries;
```
The `Front` member represents the start of the link list and `Back` the end.
NumEntries is the number of entries in the body.
Parent should have a compatible CodeType type for the type of defintion used.
Serialization:
Will output only the entries, the braces are handled by the parent.
```cpp
<Front>
...
<Back>
```
## Attributes
Represent standard or vendor specific C/C++ attributes.
Fields:
```cpp
StringCached Content;
StringCached Name;
Code Prev;
Code Next;
Token* Tok;
Code Parent;
CodeT Type;
```
Serialization:
```cpp
<Content>
```
While the parser supports the `__declspec` and `__attribute__` syntax, the upfront constructor ( def_attributes ) must have the user specify the entire attribute, including the `[[]]`, `__declspec` or `__attribute__` parts.
## Comment
Stores a comment.
Fields:
```cpp
StringCached Content;
StringCached Name;
Code Prev;
Code Next;
Token* Tok;
Code Parent;
CodeT Type;
```
Serialization:
```cpp
<Content>
```
The parser will perserve comments found if residing with a body or in accepted inline-to-definition locations.
Otherwise they will be skipped by the TokArray::__eat and TokArray::current( skip foramtting enabled ) functions.
The upfront constructor: `def_comment` expects to recieve a comment without the `//` or `/* */` parts. It will add them during construction.
## Class & Struct
Fields:
```cpp
CodeComment InlineCmt; // Only supported by forward declarations
CodeAttributes Attributes;
CodeType ParentType;
CodeBody Body;
StringCached Name;
CodeType Prev;
CodeType Next;
Token* Tok;
Code Parent;
CodeT Type;
ModuleFlag ModuleFlags;
AccessSpec ParentAccess;
```
Serialization:
```cpp
// Class_Fwd
<ModuleFlags> <class/struct> <Name>; <InlineCmt>
// Class
<ModuleFlags> <class/struct> <Attributes> <Name> : <ParentAccess> <ParentType>, public <ParentType->Next>, ... <InlineCmt>
{
<Body>
};
```
You'll notice that only one parent type is supported only with parent access. This library only supports single inheritance, the rest are assumed to be interfaces and are given public acess specifiers.
## Constructor
Fields:
```cpp
CodeComment InlineCmt; // Only supported by forward declarations
Code InitializerList;
CodeParams Params;
Code Body;
StringCached Name;
Code Prev;
Code Next;
Token* Tok;
Code Parent;
CodeT Type;
```
Serialization:
```cpp
// Constructor_Fwd
<Specs> <Parent->Name>( <Params> ); <InlineCmt>
// Constructor
<Specs> <Parent->Name>( <Params> ) <InlineCmt>
: <InitializerList>
{
<Body>
}
// Constructor Source Implementation
<Specs> <Parent>::~<Parent->Name>( <Params> ) <Specs>
{
<Body>
}
```
## Define
Represents a preprocessor define
Fields:
```cpp
StringCached Content;
StringCached Name;
Code Prev;
Code Next;
Token* Tok;
Code Parent;
CodeT Type;
```
Serialization:
```cpp
#define <Name> <Content>
```
## Destructor
Fields:
```cpp
CodeComment InlineCmt;
CodeSpecifiers Specs;
Code Body;
StringCached Name;
Code Prev;
Code Next;
Token* Tok;
Code Parent;
CodeT Type;
```
Serialization:
```cpp
// Destructor_Fwd
<Specs> ~<Parent->Name>( <Params> ) <Specs>; <InlineCmt>
// Destructor
<Specs> ~<Parent->Name>( <Params> ) <Specs>
{
<Body>
}
// Destructor Source Implementation
<Specs> <Parent>::~<Parent->Name>( <Params> ) <Specs>
{
<Body>
}
```
## Enum
Fields:
```cpp
CodeComment InlineCmt;
CodeAttributes Attributes;
CodeType UnderlyingType;
Code UnderlyingTypeMacro;
CodeBody Body;
Code Prev;
Code Next;
Token* Tok;
Code Parent;
StringCached Name;
CodeT Type;
ModuleFlag ModuleFlags;
```
UnderlyingTypeMacro is a macro the library natively supports: `enum_underlying(type)` that is meant to behave as a wrapper for underlying type assignment.
The `enum_underlying_sig` is a `StrC` global var that can be set which will be defined within `PreprocessorDefines` and used in `parser_parse_enum` to identify a valid macro.
Serialization:
```cpp
// Enum_Fwd
<ModuleFlags> enum class <Name> : <UnderlyingType> or <UnderlyingTypeMacro> ; <InlineCmt>
// Enum
<ModuleFlags> <enum or enum class> <Name> : <UnderlyingType> or <UnderlyingTypeMacro>
{
<Body>
};
```
## Execution
Just represents an execution body. Equivalent to an untyped body.
Will be obsolute when function body parsing is implemented.
Fields:
```cpp
StringCached Content;
StringCached Name;
Code Prev;
Code Next;
Token* Tok;
Code Parent;
CodeT Type;
```
Serialization:
```cpp
<Content>
```
## External Linkage
Fields:
```cpp
CodeBody Body;
StringCached Name;
Code Prev;
Code Next;
Token* Tok;
Code Parent;
CodeT Type;
```
Serialization:
```cpp
extern "<Name>"
{
<Body>
}
```
## Include
Fields:
```cpp
StringCached Content;
StringCached Name;
Code Prev;
Code Next;
Code Parent;
Token* Tok;
CodeT Type;
```
Serialization:
```cpp
#include <Content>
```
## Friend
This library (until its necessary become some third-party library to do otherwise) does not support friend declarations with in-statment function definitions.
Fields:
```cpp
CodeComment InlineCmt;
Code Declaration;
StringCached Name;
Code Prev;
Code Next;
Token* Tok;
Code Parent;
CodeT Type;
```
Serialization:
```cpp
friend <Declaration>; <InlineCmt>
```
## Function
Fields:
```cpp
CodeComment InlineCmt;
CodeAttributes Attributes;
CodeSpecifiers Specs;
CodeType ReturnType;
CodeParams Params;
CodeBody Body;
StringCached Name;
Code Prev;
Code Next;
Token* Tok;
Code Parent;
CodeT Type;
ModuleFlag ModuleFlags;
```
Serialization:
```cpp
// Function_Fwd
<ModuleFlags> <Attributes> <Specs> <ReturnType> <Name>( <Params> ) <Specs>; <InlineCmt>
// Function
<ModuleFlags> <Attributes> <Specs> <ReturnType> <Name>( <Params> ) <Specs>
{
<Body>
}
```
## Module
Fields:
```cpp
StringCached Name;
Code Prev;
Code Next;
Token* Tok;
Code Parent;
CodeT Type;
ModuleFlag ModuleFlags;
```
Serialization:
```cpp
<ModuleFlags> module <Name>;
```
## Namespace
Fields:
```cpp
CodeBody Body;
StringCached Name;
Code Prev;
Code Next;
Token* Tok;
Code Parent;
CodeT Type;
ModuleFlag ModuleFlags;
```
Serialization:
```cpp
<ModuleFlags> namespace <Name>
{
<Body>
}
```
## Operator Overload (Operator)
Fields:
```cpp
CodeComment InlineCmt;
CodeAttributes Attributes;
CodeSpecifiers Specs;
CodeType ReturnType;
CodeParams Params;
CodeBody Body;
StringCached Name;
Code Prev;
Code Next;
Token* Tok;
Code Parent;
CodeT Type;
ModuleFlag ModuleFlags;
OperatorT Op;
```
Serialization:
```cpp
// Operator_Fwd
<ModuleFlags> <Attributes> <Specs> <ReturnType> operator <Op>( <Params> ) <Specs>; <InlineCmt>
// Operator
<ModuleFlags> <Attributes> <Specs> <ReturnType> <Name>operator <Op>( <Params> ) <Specs>
{
<Body>
}
```
## Operator Cast Overload ( User-Defined Type Conversion, OpCast )
Fields:
```cpp
CodeComment InlineCmt;
CodeSpecifiers Specs;
CodeType ValueType;
CodeBody Body;
StringCached Name;
Code Prev;
Code Next;
Token* Tok;
Code Parent;
CodeT Type;
```
Serialization:
```cpp
// Operator_Cast_Fwd
<Specs> operator <ValueType>() <Specs>; <InlineCmt>
// Operator_Cast
<Specs> <Name>operator <ValueType>() <Specs>
{
<Body>
}
```
## Parameters (AST_Params)
Fields:
```cpp
CodeType ValueType;
Code Macro;
Code Value;
Code PostNameMacro;
StringCached Name;
CodeParams Last;
CodeParams Next;
Token* Tok;
Code Parent;
CodeT Type;
s32 NumEntries;
```
Serialization:
```cpp
<Macro>, <Next> ... <Last>
<Macro> <ValueType> <Name> <PostNameMacro> = <Value>, <Next>... <Last>
```
## Pragma
Fields:
```cpp
StringCached Content;
StringCached Name;
Code Prev;
Code Next;
Token* Tok;
Code Parent;
CodeT Type;
```
Serialization:
```cpp
#pragma <Content>
```
## Preprocessor Conditional
Fields:
```cpp
StringCached Content;
StringCached Name;
Code Prev;
Code Next;
Token* Tok;
Code Parent;
CodeT Type;
```
Serialization:
```cpp
#<based off Type> <Content>
```
## Specifiers
Fields:
```cpp
SpecifierT ArrSpecs[ AST_ArrSpecs_Cap ];
CodeSpecifiers NextSpecs;
StringCached Name;
Code Prev;
Code Next;
Token* Tok;
Code Parent;
CodeT Type;
s32 NumEntries;
```
Serialization:
```cpp
<Spec>, ...
```
## Template
Fields:
```cpp
CodeParams Params;
Code Declaration;
StringCached Name;
Code Prev;
Code Next;
Token* Tok;
Code Parent;
CodeT Type;
ModuleFlag ModuleFlags;
```
Serialization:
```cpp
<ModuleFlags>
template< <Params> >
<Declaration>
```
## Typename
Typenames represent the type "symbol".
Fields:
```cpp
CodeAttributes Attributes;
CodeSpecifiers Specs;
CodeReturnType ReturnType;
CodeParams Params;
Code ArrExpr;
Code Prev;
Code Next;
Token* Tok;
Code Parent;
StringCached Name;
CodeT Type;
b32 IsParamPack;
ETypenameTag TypeTag;
```
Serialization:
```cpp
<Attributes> <TypeTag> <Name> <Specs> <IsParamPack ?: ...>
// Function
<Attributes> <ReturnType> <Name> <Params> <Specs>
```
`<Name>` currently has the full serialization of anything with
*Note: ArrExpr is not used in serialization by `typename_to_string_ref` its instead handled by a parent AST's serailization (variable, typedef, using).*
## Typedef
Behave as usual except function or macro typedefs.
Those (macros) don't use the underlying type field as everything was serialized under the Name field.
Fields:
```cpp
CodeComment InlineCmt;
Code UnderlyingType;
StringCached Name;
Code Prev;
Code Next;
Token* Tok
Code Parent;
CodeT Type;
ModuleFlag ModuleFlags;
b32 IsFunction;
```
Serialization:
```cpp
// Regular
<ModuleFlags> typedef <UnderlyingType> <Name> <UnderlyingType-ArrExpr>; <InlineCmt>
// Functions
// Currently:
<ModuleFlags> typedef <UnderlyingType (Serialized expression)>; <InlineCmt>
// Desired: Not handled yet
<ModuleFlags> typedef <UnderlyingType->ReturnType> UnderlyingType->Name> <UnderlyingType-ArrExpr> ( <UnderlyingType->Parameters> ); <InlineCmt>
<ModuleFlags> typedef <UnderlyingType->ReturnType> ( <Name->Namespace> for<Specs->has(Spec_Ptr) ?: *> <UnderlyingType->Name> <UnderlyingType-ArrExpr> ) ( <UnderlyingType->Parameters> ); <InlineCmt>
```
## Union
Fields:
```cpp
CodeAttributes Attributes;
CodeBody Body;
StringCached Name;
Code Prev;
Code Next;
Token* Tok;
Code Parent;
CodeT Type;
ModuleFlag ModuleFlags;
```
Serialization:
```cpp
<ModuleFlags> union <Attributes> <Name>
{
<Body>
}
```
## Using
Fields:
```cpp
CodeComment InlineCmt;
CodeAttributes Attributes;
CodeType UnderlyingType;
StringCached Name;
Code Prev;
Code Next;
Token* Tok;
Code Parent;
CodeT Type;
ModuleFlag ModuleFlags;
```
Serialization:
```cpp
// Regular
<ModuleFlags> using <Attributes> <Name> = <UnderlyingType>; <InlineCmt>
// Namespace
<ModuleFlags> using namespace <Name>; <InlineCmt>
```
## Variable
[Algo](./Parser_Algo.md:)
Fields:
```cpp
CodeComment InlineCmt;
CodeAttributes Attributes;
CodeSpecifiers Specs;
CodeType ValueType;
Code BitfieldSize;
Code Value;
StringCached Name;
CodeVar NextVar;
Code Prev;
Code Next;
Token* Tok;
Code Parent;
CodeT Type;
ModuleFlag ModuleFlags;
s32 VarParenthesizedInit;
```
Serialization:
```cpp
// Regular
<ModuleFlags> <Attributes> <Specs> <ValueType> <Name> = <Value>, NextVar ...; <InlineCmt>
// Bitfield
<ModuleFlags> <Attributes> <Specs> <ValueType> <Name> : <BitfieldSize> = <Value>, NextVar ...; <InlineCmt>
// VarParenthesizedInit
<Attributes> <Specs> <ValueType> <Name>( <Value>, NextVar ... ); <InlineCmt>
```

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## Navigation
[Top](../Readme.md)
<- [docs - General](Readme.md)
# Parser's Algorithim
gencpp uses a hand-written recursive descent parser. Both the lexer and parser currently handle a full C/C++ file in a single pass.
## Notable implementation background
### Lexer
The lex procedure does the lexical pass of content provided as a `StrC` type.
The tokens are stored (for now) in `gen::parser::Lexer_Tokens`.
Fields:
```cpp
Array<Token> Arr;
s32 Idx;
```
What token types are supported can be found in [ETokType.csv](../base/enums/ETokType.csv) you can also find the token types in [ETokType.h](../base/components/gen/etoktype.cpp) , which is the generated enum from the csv file.
Tokens are defined with the struct `gen::parser::Token`:
Fields:
```cpp
char const* Text;
sptr Length;
TokType Type;
s32 Line;
s32 Column;
u32 Flags;
```
Flags is a bitfield made up of TokFlags (Token Flags):
* `TF_Operator` : Any operator token used in expressions
* `TF_Assign`
* Using statment assignment
* Parameter argument default value assignment
* Variable declaration initialization assignment
* `TF_Preprocess` : Related to a preprocessing directive
* `TF_Preprocess_Cond` : A preprocess conditional
* `TF_Attribute` : An attribute token
* `TF_AccessSpecifier` : An accesor operation token
* `TF_Specifier` : One of the specifier tokens
* `TF_EndDefinition` : Can be interpreted as an end definition for a scope.
* `TF_Formatting` : Considered a part of the formatting
* `TF_Literal` : Anything considered a literal by C++.
I plan to replace IsAssign with a general flags field and properly keep track of all operator types instead of abstracting it away to `ETokType::Operator`.
Traversing the tokens is done with the following interface macros:
| Macro | Description |
| --- | --- |
| `currtok_noskip` | Get the current token without skipping whitespace |
| `currtok` | Get the current token, skip any whitespace tokens |
| `prevtok` | Get the previous token (does not skip whitespace) |
| `nexttok` | Get the next token (does not skip whitespace) |
| `eat( Token Type )` | Check to see if the current token is of the given type, if so, advance Token's index to the next token |
| `left` | Get the number of tokens left in the token array |
| `check_noskip` | Check to see if the current token is of the given type, without skipping whitespace |
| `check` | Check to see if the current token is of the given type, skip any whitespace tokens |
### Parser
The parser has a limited user interface, only specific types of definitions or statements are expected to be provided by the user directly when using to construct an AST dynamically (See SOA for example). It however does attempt to provide capability to parse a full C/C++ from production codebases.
Each public user interface procedure has the following format:
```cpp
<code type> parse_<definition type>( StrC def )
{
check_parse_args( def );
using namespace Parser;
TokArray toks = lex( def );
if ( toks.Arr == nullptr )
return CodeInvalid;
// Parse the tokens and return a constructed AST using internal procedures
...
}
```
The most top-level parsing procedure used for C/C++ file parsing is `parse_global_body`:
It uses a helper procedure called `parse_global_nspace`.
Each internal procedure will have the following format:
```cpp
internal
<code type> parse_<definition_type>( <empty or contextual params> )
{
push_scope();
...
<code type> result = (<code type>) make_code();
...
Context.pop();
return result;
}
```
Below is an outline of the general alogirithim used for these internal procedures. The intention is to provide a basic briefing to aid the user in traversing the actual code definitions. These appear in the same order as they are in the `parser.cpp` file
***NOTE: This is still heavily in an alpha state. A large swaph of this can change, make sure these docs are up to date before considering them 1:1 with the repo commit your considering.***
## `parse_array_decl`
1. Check if its an array declaration with no expression.
1. Consume and return empty array declaration
2. Opening square bracket
3. Consume expression
4. Closing square bracket
5. If adjacent opening bracket
1. Repeat array declaration parse until no brackets remain
## `parse_assignment_expression`
1. Eat the assignment operator
2. Make sure there is content or at least an end statement after.
3. Flatten the assignment expression to an untyped Code string.
## `parse_attributes`
1. Check for standard attribute
2. Check for GNU attribute
3. Check for MSVC attribute
4. Check for a token registered as an attribute
a. Check and grab the arguments of a token registered of an attribute if it has any.
5. Repeat for chained attributes. Flatten them to a single attribute AST node.
## `parse_class_struct`
1. Check for export module specifier
2. class or struct keyword
3. `parse_attributes`
4. If identifier : `parse_identifier`
5. Parse inherited parent or interfaces
6. If opening curly brace : `parse_class_struct_body`
7. If not an inplace definition
1. End statement
2. Check for inline comment
## `parse_class_struct_body`
1. Opening curly brace
2. Parse the body (Possible options):
1. Ignore dangling end statements
2. Newline : ast constant
3. Comment : `parse_comment`
4. Access_Public : ast constant
5. Access_Protected : ast constant
6. Access_Private : ast constant
7. Decl_Class : `parse_complicated_definition`
8. Decl_Enum : `parse_complicated_definition`
9. Decl_Friend : `parse_friend`
10. Decl_Operator : `parse_operator_cast`
11. Decl_Struct : `parse_complicated_definition`
12. Decl_Template : `parse_template`
13. Decl_Typedef : `parse_typedef`
14. Decl_Union : `parse_complicated_definition`
15. Decl_Using : `parse_using`
16. Operator == '~'
1. `parse_destructor`
17. Preprocess_Define : `parse_define`
18. Preprocess_Include : `parse_include`
19. Preprocess_Conditional (if, ifdef, ifndef, elif, else, endif) : `parse_preprocess_cond` or else/endif ast constant
20. Preprocess_Macro : `parse_simple_preprocess`
21. Preprocess_Pragma : `parse_pragma`
22. Preprocess_Unsupported : `parse_simple_preprocess`
23. StaticAssert : `parse_static_assert`
24. The following compound into a resolved definition or declaration:
1. Attributes (Standard, GNU, MSVC) : `parse_attributes`
2. Specifiers (consteval, constexpr, constinit, explicit, forceinline, inline, mutable, neverinline, static, volatile, virtual)
3. Possible Destructor : `parse_destructor`
4. Possible User defined operator cast : `parse_operator_cast`
5. Possible Constructor : `parse_constructor`
6. Something that has the following: (identifier, const, unsigned, signed, short, long, bool, char, int, double)
1. Possible Constructor `parse_constructor`
2. Possible Operator, Function, or varaible : `parse_operator_function_or_variable`
25. Something completely unknown (will just make untyped...) : `parse_untyped`
## `parse_comment`
1. Just wrap the token into a cached string ( the lexer did the processing )
## `parse_compilcated_definition`
This is a helper function used by the following functions to help resolve a declaration or definition:
* `parse_class_struct_body`
* `parse_global_nspace`
* `parse_union`
A portion of the code in `parse_typedef` is very similar to this as both have to resolve a similar issue.
1. Look ahead to the termination token (End statement)
2. Check to see if it fits the pattern for a forward declare
3. If the previous token was an identifier ( `token[-1]` ):
1. Look back one more token : `[-2]`
2. If the token has a closing brace its an inplace definition
3. If the `token[-2]` is an identifier & `token[-3]` is the declaration type, its a variable using a namespaced type.
4. If the `token[-2]` is an indirection, then its a variable using a namespaced/forwarded type.
5. If the `token[-2]` is an assign classifier, and the starting tokens were the which type with possible `class` token after, its an enum forward declaration.
6. If any of the above is the case, `parse_operator_function_or_variable`
4. If the `token[2]` is a vendor fundamental type (builtin) then it is an enum forward declaration.
5. If the previous token was a closing curly brace, its a definition : `parse_forward_or_definition`
6. If the previous token was a closing square brace, its an array definition : `parse_operator_function_or_variable`
## `parse_define`
1. Define directive
2. Get identifier
3. Get Content (Optional)
## `parse_forward_or_definition`
* Parse any of the following for either a forward declaration or definition:
1. Decl_Class : `parse_class`
2. Decl_Enum : `parse_enum`
3. Decl_Struct : `parse_struct`
4. Decl_Union : `parse_union`
## `parse_function_after_name`
This is needed as a function defintion is not easily resolvable early on, as such this function handles resolving a function
after its been made ceratin that the type of declaration or definition is indeed for a function signature.
By the point this function is called the following are known : export module flag, attributes, specifiers, return type, & name
1. `parse_parameters`
2. parse postfix specifiers (we do not check if the specifier here is correct or not to be here... yet)
3. If there is a body : `parse_body`
4. Otherwise :
1. Statment end
2. Check for inline comment
## `parse_function_body`
Currently there is no actual parsing of the function body. Any content with the braces is shoved into an execution AST node.
In the future statements and expressions will be parsed.
1. Open curly brace
2. Grab all tokens between the brace and the closing brace, shove them in a execution AST node.
3. Closing curly brace
## `parse_global_nspace`
1. Make sure this is being called for a valid type (namespace, global body, export body, linkage body)
2. If its not a global body, consume the opening curly brace
3. Parse the body (Possible options):
1. Ignore dangling end statements
2. NewLine : ast constant
3. Comment : `parse_comment`
4. Decl_Cass : `parse_complicated_definition`
5. Decl_Enum : `parse_complicated_definition`
6. Decl_Extern_Linkage : `parse_extern_link`
7. Decl_Namespace : `parse_namespace`
8. Decl_Struct : `parse_complicated_definition`
9. Decl_Template : `parse_template`
10. Decl_Typedef : `parse_typedef`
11. Decl_Union : `parse_complicated_definition`
12. Decl_Using : `parse_using`
13. Preprocess_Define : `parse_define`
14. Preprocess_Include : `parse_include`
15. Preprocess_If, IfDef, IfNotDef, Elif : `parse_preprocess_cond`
16. Preprocess_Else : ast constant
17. Preprocess_Endif : ast constant
18. Preprocess_Macro : `parse_simple_preprocess`
19. Preprocess_Pragma : `parse_pragma`
20. Preprocess_Unsupported : `parse_simple_preprocess`
21. StaticAssert : `parse_static_assert`
22. Module_Export : `parse_export_body`
23. Module_Import : NOT_IMPLEMENTED
24. The following compound into a resolved definition or declaration:
1. Attributes ( Standard, GNU, MSVC, Macro ) : `parse_attributes`
2. Specifiers ( consteval, constexpr, constinit, extern, forceinline, global, inline, internal_linkage, neverinline, static )
3. Is either ( identifier, const specifier, long, short, signed, unsigned, bool, char, double, int)
1. Attempt to parse as constrcutor or destructor : `parse_global_nspace_constructor_destructor`
2. If its an operator cast (definition outside class) : `parse_operator_cast`
3. Its an operator, function, or varaible : `parse_operator_function_or_varaible`
4. If its not a global body, consume the closing curly brace
## `parse_global_nspace_constructor_destructor`
1. Look ahead for the start of the arguments for a possible constructor/destructor
2. Go back past the identifier
3. Check to see if its a destructor by checking for the `~`
4. Continue the next token should be a `::`
5. Determine if the next valid identifier (ignoring possible template parameters) is the same as the first identifier of the function.
6. If it is we have either a constructor or destructor so parse using their respective functions (`parse_constructor`, `parse_destructor`).
## `parse_identifier`
This is going to get heavily changed down the line to have a more broken down "identifier expression" so that the qualifier, template args, etc, can be distinguished between the targeted identifier.
The function can parse all of them, however the AST node compresses them all into a string.
1. Consume first identifier
2. `parse_template_args`
3. While there is a static symbol accessor ( `::` )
1. Consume `::`
2. Consume member identifier
3. `parse_template args` (for member identifier)
4. If a `~` is encounted and the scope is for a destructor's identifier, do not consume it and return with what parsed.
## `parse_include`
1. Consume include directive
2. Consume the path
## `parse_operator_after_ret_type`
This is needed as a operator defintion is not easily resolvable early on, as such this function handles resolving a operator after its been made ceratin that the type of declaration or definition is indeed for a operator signature.
By the point this function is called the following are known : export module flag, attributes, specifiers, return type
1. If there is any qualifiers for the operator, parse them
2. Consume operator keyword
3. Determine the operator type (This will be offloaded to the lexer moreso than how it is now) & consume
4. `parse_params`
5. If there is no parameters this is operator is a member of pointer if its symbols is a *.
6. Parse postfix specifiers
7. If there is a opening curly brace, `parse function_body`
8. Otherwise: consume end statement, check for inline comment.
## `parse_operator_function_or_variable`
When this function is called, attribute and specifiers may have been resolved, however what comes next can still be either an operator, function, or varaible.
1. Check for preprocessor macro, if there is one : `parse_simple_preprocess`
2. `parse_type` (Does the bulk of the work)
3. Begin lookahead to see if we get qualifiers or we eventually find the operator declaration
4. If we find an operator keyword : `parse_operator_after_ret_type`
5. otherwise :
1. `parse_identifier`
2. If we se a opening parenthesis (capture start), its a function : `parse_function_after_name`
3. Its a variable : `parse_variable_after_name`
## `parse_pragma`
1. Consume pragma directive
2. Process the token content into cached string
## `parse_params`
1. Consume either a `(` or `<` based on `use_template_capture` arg
2. If the we immdiately find a closing token, consume it and finish.
3. If we encounter a varadic argument, consume it and return a `param_varadic` ast constant
4. `parse_type`
5. If we have a macro, parse it (Unreal has macros as tags to parameters and or as entire arguments).
6. So long as next token isn't a comma
a. If we have an identifier
1. Consume it
2. Check for assignment:
a. Consume assign operator
b. Parse the expression
7. While we continue to encounter commas
a. Consume them
b. Repeat steps 3 to 6.2.b
8. Consume the closing token
## `parse_preprocess_cond`
1. Parse conditional directive
2. Process directive's content expression
## `parse_simple_preprocess`
There is still decent room for improvement in this setup. Right now the entire macro's relevant tokens are shoved into an untyped AST. It would be better to store it instead in an `AST_Macro` node instead down the line.
1. Consume the macro token
2. Check for an opening curly brace
1. Consume opening curly brace
2. Until the closing curly is encountered consume all tokens.
3. If the parent context is a typedef
1. Check for end stement
1. Consume it
2. Consume potential inline comment
3. Otherwise do steps 3 to 3.1.2
4. Shove it all in an untyped string
## `parse_static_assert`
1. Consume static assert and opening curly brace
2. Consume all tokens until the the closing brace is reached.
3. Consume curly brace and end statement
4. Place all tokens within braces into a content for the assert.
## `parse_template_args`
This will get changed heavily once we have better support for typename expressions
1. Consume opening angle bracket
2. Consume all tokens until closing angle bracket
3. Consme closing angle bracket
4. Return the currtok with the ammended length.
## `parse_variable_after_name`
This is needed as a variable defintion is not easily resolvable early on, it takes a long evaluation period before its known that the declaration or definition is a variable. As such this function handles resolving a variable.
By the point this function is called the following are known : export module flag, attributes, specifiers, value type, name
1. If its an assignment, parse the assignment expression (currently to an untyped string)
2. If its an opening curly brace, parse the expression within (currnelty to an untyped stirng).
1. Consume the closing curly brace
3. If its a `:`, we're dealing with bitfield definition:
1. Consume the assign classifier
2. Consume the expression (currently to an untyped string)
4. If a comma is encountered : `parse_variable declaration_list`
5. Consume statement end
6. Check for inline comment
## `parse_variable_declaration_list`
1. Consume the comma
2. Parse specifiers
3. `parse_variable_after_name`
## `parse_class`
1. `parse_class_struct`
## `parse_constructor`
This currently doesn't support postfix specifiers (planning to in the future)
1. `parse_identifier`
2. `parse_parameters`
3. If currtok is a `:`
1. Consume `:`
2. Parse the initializer list
3. `parse_function_body`
4. If currtok is an opening curly brace
1. `parse_function_body`
5. Otherwise:
1. Consume statement end
2. Check for inline comment
## `parse_destructor`
1. Check for and consume virtual specifier
2. Check for the `~` operator
3. `parse_identifier`
4. Consume opening and closing parenthesis
5. Check for assignment operator:
1. Consume assignment op
2. Consume pure specifier `0`
6. If not pure virtual & currtok is opening curly brace:
1. `parse_function_body`
7. Otherwise:
1. Consume end statement
2. If currtok is comment : `parse_comment`
## `parse_enum`
1. Consume enum token
2. Check for and consume class token
3. `parse_attributes`
4. If there is an identifier consume it
5. Check for a `:`
1. Consume `:`
2. `parse_type`
6. If there is a body parse it (Consume `{`):
1. Newline : ast constant
2. Comment : `parse_comment`
3. Preprocess_Define : `parse_define`
4. Preprocess_Conditional (if, ifdef, ifndef, elif ) : `parse_preprocess_cond`
5. Preprocess_Else : ast constant
6. Preprocess_Endif : ast constant
7. Preprocess_Macro : `parse_simple_preprocess`
8. Preprocess_Pragma : `parse_pragma`
9. Preprocess_Unsupported : `parse_smple_preprocess`
10. An actual enum entry
1. Consume identifier
2. If there is an assignment operator:
1. Consume operator
2. Consume the expression (assigned to untyped string for now)
3. If a macro is encountered consume it (Unreal UMETA macro support)
3. If there is a comma, consume it
## `parse_export_body`
1. `parse_global_nspace`
## `parse_extern_link_body`
1. `parse_global_nspace`
## `parse_extern_link`
1. Consume Decl_Extern_Linkage
2. Consume the linkage identifier
3. `parse_extern_link_body`
## `parse_friend`
1. Consume `friend`
2. `parse_type`
3. If the currok is an identifier its a function declaration or definition
1. `parse_function_after_name`
4. Consume end statement so long as its not a function definion
5. Check for inline comment, `parse_comment` if exists
## `parse_function`
1. Check and parse for `export`
2. `parse_attributes`
3. Parse specifiers
4. `parse_type`
5. `parse_identifier`
6. `parse_function_after_name`
## `parse_namespace`
1. Consume namespace declaration
2. Parse identifier
3. `parse_global_namespace`
## `parse_operator`
1. Check for and parse export declaration
2. `parse_attributes`
3. Parse specifiers
4. `parse_type`
5. `parse_operator_after_ret_type`
## `parse_operator_cast`
1. Look for and parse a qualifier namespace for the cast (in-case this is defined outside the class's scope)
2. Consume operator declaration
3. `parse_type`
4. Consume opening and closing parethesis
5. Check for a const qualifiying specifier
6. Check to see if this is a definition (`{`)
1. Consume `{`
2. Parse body to untyped string (parsing statement and expressions not supported yet)
3. Consume `}`
7. Otherwise:
1. Consume end statement
2. Check for and consume comment : `parse_comment`
## `parse_struct`
1. `parse_class_struct`
## `parse_template`
Note: This currently doesn't support templated operator casts (going to need to add support for it)
1. Check for and parse export declaration
2. Consume template declaration
3. `parse_params`
4. Parse for any of the following:
1. Decl_Class : `parse_class`
2. Decl_Struct : `parse_struct`
3. Decl_Union : `parse_union`
4. Decl_Using : `parse_using`
5. The following compound into a resolved definition or declaration:
1. `parse_attributes`
2. Parse specifiers
3. Attempt to parse as constructor or destructor: `parse_global_nspace_constructor_destructor`
4. Otherwise: `parse_operator_function_or_variable`
## `parse_type`
This function's implementation is awful and not done correctly. It will most likely be overhauled in the future as I plan to segement the AST_Type into several AST varaints along with sub-types to help produce robust type expressions.
Hopefully I won't need to make authentic type expressions as I was hopeing to avoid that...
### Current Algorithim
Anything that is in the qualifier capture of the function typename is treated as an expression abstracted as an untyped string
1. `parse_attributes`
2. Parse specifiers
3. If the `parse_type` was called from a template parse, check to see if class was used instead of typname and consume as name.
4. This is where things get ugly for each of these depend on what the next token is.
1. If its an in-place definition of a class, enum, struct, or union:
2. If its a decltype (Not supported yet but draft impl there)
3. If its a compound native type expression (unsigned, char, short, long, int, float, dobule, etc )
4. Ends up being a regular type alias of an identifier
5. Parse specifiers (postfix)
6. We need to now look ahead to see If we're dealing with a function typename
7. If wer're dealing with a function typename:
1. Shove the specifiers, and identifier code we have so far into a return type typename's Name (untyped string)
1. Reset the specifiers code for the top-level typeanme
2. Check to see if the next token is an identifier:
1. `parse_identifier`
3. Check to see if the next token is capture start and is not the last capture ("qualifier capture"):
1. Consume `(`
2. Consume expresssion between capture
3. Consume `)`
4. `parse_params`
5. Parse postfix specifiers
8. Check for varaidic argument (param pack) token:
1. Consume varadic argument token
### WIP - Alternative Algorithim
Currently wrapped up via macro: `GEN_USE_NEW_TYPENAME_PARSING`
Anything that is in the qualifier capture of the function typename is treated as an expression abstracted as an untyped string
1. `parse_attributes`
2. Parse specifiers (prefix)
3. This is where things get ugly for each of these depend on what the next token is.
1. If its an in-place definition of a class, enum, struct, or union:
2. If its a decltype (Not supported yet but draft impl there)
3. If its a compound native type expression (unsigned, char, short, long, int, float, dobule, etc )
4. Ends up being a regular type alias of an identifier
4. Parse specifiers (postfix)
1. If any specifiers are found populate specifiers code with them.
5. We need to now look ahead to see If we're dealing with a function typename
6. If wer're dealing with a function typename:
1. Shove the specifiers, and identifier code we have so far into a return type typename's Name (untyped string)
1. Reset the specifiers code for the top-level typename
2. Check to see if the next token is an identifier:
1. `parse_identifier`
3. Check to see if the next token is capture start and is not the last capture ("qualifier capture"):
1. Consume `(`
2. Parse binding specifiers
3. `parse_identifier`
4. `parse_parameters` -> params_nested
5. Consume `)`
6. Construct a nested function typename definition for the qualifier `Name`
4. `parse_params` - > params
5. Parse postfix specifiers
7. Check for varaidic argument (param pack) token:
1. Consume varadic argument token
### **Later: Algorithim based on typename expressions**
## `parse_typedef`
1. Check for export module specifier
2. typedef keyword
3. If its a preprocess macro: Get the macro name
4. Else:
1. Check to see if its a complicated definition (in-place enum, class, struct, union)
2. If its a complicated definition:
1. Perform the look ahead similar to `parse_complicated_definition`'s implementation
2. Check to see if its a forward declaration : `parse_forward_declaration`
3. If end[-1] is an identifier:
1. Its either an in-place, varaible type qualified identifier, or indirection type:
1. `parse_foward_or_definition`
4. else if end[-1] is a closing curly brace
1. Its a definition: `parse_forward_or_definition`
5. else if end[-1] is a closing square brace
2. Its an array definition: `parse_type`
3. Else : `parse-type`
4. Check for identifier : Consume the token
5. `parse_array_decl`
5. Consume end statement
6. Check for inline comment : `parse_comment`
## `parse_union`
1. Check for export module specifier
2. union keyword
3. `parse_attributes`
4. Check for identifier
5. Parse the body (Possible options):
1. Newline
2. Comment
3. Decl_Class
4. Decl_Enum
5. Decl_Struct
6. Decl_Union
7. Preprocess_Define
8. Preprocess_Conditional (if, ifdef, ifndef, elif, else, endif)
9. Preprocess_Macro
10. Preprocess_Pragma
11. Unsupported preprocess directive
12. Variable
6. If its not an inplace definiton: End Statement
## `parse_using`
1. Check for export module specifier
2. using keyword
3. Check to see if its a using namespace
4. Get the identifier
5. If its a regular using declaration:
1. `parse_attributes`
2. `parse_type`
3. `parse_array_decl`
6. End statement
7. Check for inline comment
## `parse_variable`
1. Check for export module specifier
2. `parse_attributes`
3. `parse specifiers`
4. `parse_type`
5. `parse_identifier`
6. `parse_variable_after_name`

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## Navigation
[Top](../Readme.md)
<- [docs - General](Readme.md)
# Parsing
The library features a naive single-pass parser tailored for only what the library needs to construct the supported syntax of C++ into its AST for *"front-end"* meta-programming purposes.
This parser does not, and should not do the compiler's job. By only supporting this minimal set of features, the parser is kept (so far) around ~7000 loc. I hope to keep it under 10k loc worst case.
You can think of this parser as *frontend parser* vs a *semantic parser*. Its intuitively similar to WYSIWYG. What you ***precerive*** as the syntax from the user-side before the compiler gets a hold of it, is what you get.
User exposed interface:
```cpp
CodeClass parse_class ( StrC class_def );
CodeConstructor parse_constructor ( StrC constructor_def );
CodeDestructor parse_destructor ( StrC destructor_def );
CodeEnum parse_enum ( StrC enum_def );
CodeBody parse_export_body ( StrC export_def );
CodeExtern parse_extern_link ( StrC exten_link_def );
CodeFriend parse_friend ( StrC friend_def );
CodeFn parse_function ( StrC fn_def );
CodeBody parse_global_body ( StrC body_def );
CodeNS parse_namespace ( StrC namespace_def );
CodeOperator parse_operator ( StrC operator_def );
CodeOpCast parse_operator_cast( StrC operator_def );
CodeStruct parse_struct ( StrC struct_def );
CodeTemplate parse_template ( StrC template_def );
CodeType parse_type ( StrC type_def );
CodeTypedef parse_typedef ( StrC typedef_def );
CodeUnion parse_union ( StrC union_def );
CodeUsing parse_using ( StrC using_def );
CodeVar parse_variable ( StrC var_def );
```
To parse file buffers, use the `parse_global_body` function.
***Parsing will aggregate any tokens within a function body or expression statement to an untyped Code AST.***
Everything is done in one pass for both the preprocessor directives and the rest of the language.
The parser performs no macro expansion as the scope of gencpp feature-set is to only support the preprocessor for the goal of having rudimentary awareness of preprocessor ***conditionals***, ***defines***, ***includes***, and ***pragmas***.
The keywords supported for the preprocessor are:
* include
* define
* if
* ifdef
* elif
* endif
* pragma
Each directive `#` line is considered one preproecessor unit, and will be treated as one Preprocessor AST.
If a directive is used with an unsupported keyword its will be processed as an untyped AST.
The preprocessor lines are stored as members of their associated scope they are parsed within. ( Global, Namespace, Class/Struct )
***Again (Its not standard): These ASTs will be considered members or entries of braced scope they reside within***
Any preprocessor definition abuse that changes the syntax of the core language is unsupported and will fail to parse if not kept within an execution scope (function body, or expression assignment).
Exceptions:
* function signatures are allowed for a preprocessed macro: `neverinline MACRO() { ... }`
* Disable with: `#define GEN_PARSER_DISABLE_MACRO_FUNCTION_SIGNATURES`
* typedefs allow for a preprocessed macro: `typedef MACRO();`
* Disable with: `#define GEN_PARSER_DISABLE_MACRO_TYPEDEF`
* Macros can behave as typenames
* There is some macro support in paramters for functions or templates *(Specifically added to support parsing Unreal Engine source)*.
*(Exceptions are added on an on-demand basis)*
*(See functions `parse_operator_function_or_variable` and `parse_typedef` )*
Adding your own exceptions is possible by simply modifying the parser to allow for the syntax you need.
*Note: You could interpret this strictness as a feature. This would allow the user to see if their codebase or a third-party's codebase some some egregious preprocessor abuse.*
If a macro is not defined withint e scope of parsing a set of files, it can be defined beforehand by:
* Appending the [`PreprocessorDefines`](https://github.com/Ed94/gencpp/blob/a18b5b97aa5cfd20242065cbf53462a623cd18fa/base/components/header_end.hpp#L137) array.
* For functional macros a "(" just needs to be added after the name like: `<name>(` so that it will tokenize its arguments as part of the token during lexing.
* Defining a CodeDefine using `def_define`. The definition will be processed by the interface for user into `PreprocessorDefines`.
* This can be prevented by setting the optional prameter `dont_append_preprocess_defines`.
The lexing and parsing takes shortcuts from whats expected in the standard.
* Numeric literals are not checked for validity.
* The parse API treats any execution scope definitions with no validation and are turned into untyped Code ASTs. (There is a [todo](https://github.com/Ed94/gencpp/issues/49) to add support)
* *This includes the assignment of variables.*
* Attributes ( `[[]]` (standard), `__declspec` (Microsoft), or `__attribute__` (GNU) )
* Assumed to *come before specifiers* (`const`, `constexpr`, `extern`, `static`, etc) for a function or right afterthe return type.
* Or in the usual spot for class, structs, (*right after the declaration keyword*)
* typedefs have attributes with the type (`parse_type`)
* Parsing attributes can be extended to support user defined macros by defining `GEN_DEFINE_ATTRIBUTE_TOKENS` (see `gen.hpp` for the formatting)
* This is useful for example: parsing Unreal `Module_API` macros.
Empty lines used throughout the file are preserved for formatting purposes during ast serialization.

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# General Docs
[Top](../Readme.md)
Contains:
* [AST_Design](./AST_Design.md): Overvie of ASTs
* [AST Types](./AST_Types.md): Listing of all AST types along with their Code type interface.
* [Parsing](./Parsing.md): Overview of the parsing interface.
* [Parser Algo](./Parser_Algo.md): In-depth breakdown of the parser's implementation.
### *CURRENTLY UNSUPPORTED*
**There is no support for validating expressions.**
Its a [todo](https://github.com/Ed94/gencpp/issues/49)
**Only trivial template support is provided.**
The intention is for only simple, non-recursive substitution.
The parameters of the template are treated like regular parameter AST entries.
This means that the typename entry for the parameter AST would be either:
* `class`
* `typename`
* A fundamental type, function, or pointer type.
***Concepts and Constraints are not supported***
Its a [todo](https://github.com/Ed94/gencpp/issues/21)
### Feature Macros:
* `GEN_DEFINE_ATTRIBUTE_TOKENS` : Allows user to define their own attribute macros for use in parsing.
* This can be generated using base.cpp.
* `GEN_DEFINE_LIBRARY_CORE_CONSTANTS` : Optional typename codes as they are non-standard to C/C++ and not necessary to library usage
* `GEN_DONT_ENFORCE_GEN_TIME_GUARD` : By default, the library ( gen.hpp/ gen.cpp ) expects the macro `GEN_TIME` to be defined, this disables that.
* `GEN_ENFORCE_STRONG_CODE_TYPES` : Enforces casts to filtered code types.
* `GEN_EXPOSE_BACKEND` : Will expose symbols meant for internal use only.
* `GEN_ROLL_OWN_DEPENDENCIES` : Optional override so that user may define the dependencies themselves.
* `GEN_DONT_ALLOW_INVALID_CODE` (Not implemented yet) : Will fail when an invalid code is constructed, parsed, or serialized.
* `GEN_C_LIKE_PP` : Setting to `<true or 1>` Will prevent usage of function defnitions using references and structs with member functions. Structs will still have user-defined operator conversions, for-range support, and other operator overloads
### The Data & Interface
As mentioned in root readme, the user is provided Code objects by calling the constructor's functions to generate them or find existing matches.
The AST is managed by the library and provided to the user via its interface.
However, the user may specifiy memory configuration.
[Data layout of AST struct (Subject to heavily change with upcoming todos)](../base/components/ast.hpp#L396-461)
https://github.com/Ed94/gencpp/blob/eea4ebf5c40d5d87baa465abfb1be30845b2377e/base/components/ast.hpp#L396-L461
*`CodeType` is enum taggin the type of code. Has an underlying type of `u32`*
*`OperatorT` is a typedef for `EOperator::Type` which has an underlying type of `u32`*
*`StringCahced` is a typedef for `String const`, to denote it is an interned string*
*`String` is the dynamically allocated string type for the library*
AST widths are setup to be AST_POD_Size.
The width dictates how much the static array can hold before it must give way to using an allocated array:
```cpp
constexpr static
int AST_ArrSpecs_Cap =
(
AST_POD_Size
- sizeof(Code)
- sizeof(StringCached)
- sizeof(Code) * 2
- sizeof(Token*)
- sizeof(Code)
- sizeof(CodeType)
- sizeof(ModuleFlag)
- sizeof(u32)
)
/ sizeof(Specifier) - 1;
```
*Ex: If the AST_POD_Size is 128 the capacity of the static array is 20.*
Data Notes:
* The allocator definitions used are exposed to the user incase they want to dictate memory usage
* You'll find the memory handling in `init`, `deinit`, `reset`, `gen_string_allocator`, `get_cached_string`, `make_code`.
* Allocators are defined with the `AllocatorInfo` structure found in [`memory.hpp`](../base/dependencies/memory.hpp)
* Most of the work is just defining the allocation procedure:
```cpp
void* ( void* allocator_data, AllocType type, ssize size, ssize alignment, void* old_memory, ssize old_size, u64 flags );
```
* ASTs are wrapped for the user in a Code struct which is a wrapper for a AST* type.
* Code types have member symbols but their data layout is enforced to be POD types.
* This library treats memory failures as fatal.
* Cached Strings are stored in their own set of arenas. AST constructors use cached strings for names, and content.
* `StringArenas`, `StringCache`, `Allocator_StringArena`, and `Allocator_StringTable` are the associated containers or allocators.
* Strings used for serialization and file buffers are not contained by those used for cached strings.
* They are currently using `GlobalAllocator`, which are tracked array of arenas that grows as needed (adds buckets when one runs out).
* Memory within the buckets is not reused, so its inherently wasteful.
* I will be augmenting the default allocator with virtual memory & a slab allocator in the [future](https://github.com/Ed94/gencpp/issues/12)
* Intrusive linked lists used children nodes on bodies, and parameters.
* Its intended to generate the AST in one go and serialize after. The constructors and serializer are designed to be a "one pass, front to back" setup.
* Allocations can be tuned by defining the folloiwng macros (will be moved to runtime configuration in the future):
* `GEN_GLOBAL_BUCKET_SIZE` : Size of each bucket area for the global allocator
* `GEN_CODEPOOL_NUM_BLOCKS` : Number of blocks per code pool in the code allocator
* `GEN_SIZE_PER_STRING_ARENA` : Size per arena used with string caching.
* `GEN_MAX_COMMENT_LINE_LENGTH` : Longest length a comment can have per line.
* `GEN_MAX_NAME_LENGTH` : Max length of any identifier.
* `GEN_MAX_UNTYPED_STR_LENGTH` : Max content length for any untyped code.
* `TokenMap_FixedArena` : token_fmt_va uses local_persit memory of this arena type for the hashtable.
* `GEN_LEX_ALLOCATOR_SIZE`
* `GEN_BUILDER_STR_BUFFER_RESERVE`
The following CodeTypes are used which the user may optionally use strong typing with if they enable: `GEN_ENFORCE_STRONG_CODE_TYPES`
* CodeBody : Has support for `for : range` iterating across Code objects.
* CodeAttributes
* CodeComment
* CodeClass
* CodeConstructor
* CodeDefine
* CodeDestructor
* CodeEnum
* CodeExec
* CodeExtern
* CodeInclude
* CodeFriend
* CodeFn
* CodeModule
* CodeNS
* CodeOperator
* CodeOpCast
* CodeParams : Has support for `for : range` iterating across parameters.
* CodePreprocessCond
* CodePragma
* CodeSpecifiers : Has support for `for : range` iterating across specifiers.
* CodeStruct
* CodeTemplate
* CodeTypename
* CodeTypedef
* CodeUnion
* CodeUsing
* CodeVar
Each Code boy has an associated "filtered AST" with the naming convention: `AST_<CodeName>`
Unrelated fields of the AST for that node type are omitted and only necessary padding members are defined otherwise.
Retrieving a raw version of the ast can be done using the `raw()` function defined in each AST.
## There are three sets of interfaces for Code AST generation the library provides
* Upfront
* Parsing
* Untyped
### Upfront Construction
All component ASTs must be previously constructed, and provided on creation of the code AST.
The construction will fail and return CodeInvalid otherwise.
Interface :``
* def_attributes
* *This is pre-appended right before the function symbol, or placed after the class or struct keyword for any flavor of attributes used.*
* *Its up to the user to use the desired attribute formatting: `[[]]` (standard), `__declspec` (Microsoft), or `__attribute__` (GNU).*
* def_comment
* def_class
* def_constructor
* def_define
* def_destructor
* def_enum
* def_execution
* *This is equivalent to untyped_str, except that its intended for use only in execution scopes.*
* def_extern_link
* def_friend
* def_function
* def_include
* def_module
* def_namespace
* def_operator
* def_operator_cast
* def_param
* def_params
* def_pragma
* def_preprocess_cond
* def_specifier
* def_specifiers
* def_struct
* def_template
* def_type
* def_typedef
* def_union
* def_using
* def_using_namespace
* def_variable
Bodies:
* def_body
* def_class_body
* def_enum_body
* def_export_body
* def_extern_link_body
* def_function_body
* *Use this for operator bodies as well*
* def_global_body
* def_namespace_body
* def_struct_body
* def_union_body
Usage:
```cpp
<name> = def_<function type>( ... );
Code <name>
{
...
<name> = def_<function name>( ... );
}
```
When using the body functions, its recommended to use the args macro to auto determine the number of arguments for the varadic:
```cpp
def_global_body( args( ht_entry, array_ht_entry, hashtable ));
// instead of:
def_global_body( 3, ht_entry, array_ht_entry, hashtable );
```
If a more incremental approach is desired for the body ASTs, `Code def_body( CodeT type )` can be used to create an empty body.
When the members have been populated use: `AST::validate_body` to verify that the members are valid entires for that type.
### Parse construction
A string provided to the API is parsed for the intended language construct.
Interface :
* parse_class
* parse_constructor
* parse_destructor
* parse_enum
* parse_export_body
* parse_extern_link
* parse_friend
* Purposefully are only support forward declares with this constructor.
* parse_function
* parse_global_body
* parse_namespace
* parse_operator
* parse_operator_cast
* parse_struct
* parse_template
* parse_type
* parse_typedef
* parse_union
* parse_using
* parse_variable
Usage:
```cpp
Code <name> = parse_<function name>( string with code );
Code <name> = def_<function name>( ..., parse_<function name>(
<string with code>
));
```
### Untyped constructions
Code ASTs are constructed using unvalidated strings.
Interface :
* token_fmt_va
* token_fmt
* untyped_str
* untyped_fmt
* untyped_token_fmt
During serialization any untyped Code AST has its string value directly injected inline of whatever context the content existed as an entry within.
Even though these are not validated from somewhat correct c/c++ syntax or components, it doesn't mean that Untyped code can be added as any component of a Code AST:
* Untyped code cannot have children, thus there cannot be recursive injection this way.
* Untyped code can only be a child of a parent of body AST, or for values of an assignment (ex: variable assignment).
These restrictions help prevent abuse of untyped code to some extent.
Usage Conventions:
```cpp
Code <name> = def_variable( <type>, <name>, untyped_<function name>(
<string with code>
));
Code <name> = untyped_str( code(
<some code without "" quotes>
));
```
Optionally, `code_str`, and `code_fmt` macros can be used so that the code macro doesn't have to be used:
```cpp
Code <name> = code_str( <some code without "" quotes > )
```
Template metaprogramming in the traditional sense becomes possible with the use of `token_fmt` and parse constructors:
```cpp
StrC value = txt("Something");
char const* template_str = txt(
Code with <key> to replace with token_values
...
);
char const* gen_code_str = token_fmt( "key", value, template_str );
Code <name> = parse_<function name>( gen_code_str );
```
## Predefined Codes
The following are provided predefined by the library as they are commonly used:
* `access_public`
* `access_protected`
* `access_private`
* `attrib_api_export`
* `attrib_api_import`
* `module_global_fragment`
* `module_private_fragment`
* `fmt_newline`
* `pragma_once`
* `param_varaidc` (Used for varadic definitions)
* `preprocess_else`
* `preprocess_endif`
* `spec_const`
* `spec_consteval`
* `spec_constexpr`
* `spec_constinit`
* `spec_extern_linkage` (extern)
* `spec_final`
* `spec_forceinline`
* `spec_global` (global macro)
* `spec_inline`
* `spec_internal_linkage` (internal macro)
* `spec_local_persist` (local_persist macro)
* `spec_mutable`
* `spec_neverinline`
* `spec_noexcept`
* `spec_override`
* `spec_ptr`
* `spec_pure`
* `spec_ref`
* `spec_register`
* `spec_rvalue`
* `spec_static_member` (static)
* `spec_thread_local`
* `spec_virtual`
* `spec_volatile`
* `t_empty` (Used for varaidc macros)
* `t_auto`
* `t_void`
* `t_int`
* `t_bool`
* `t_char`
* `t_wchar_t`
* `t_class`
* `t_typename`
Optionally the following may be defined if `GEN_DEFINE_LIBRARY_CODE_CONSTANTS` is defined
* `t_b32`
* `t_s8`
* `t_s16`
* `t_s32`
* `t_s64`
* `t_u8`
* `t_u16`
* `t_u32`
* `t_u64`
* `t_ssize` (ssize_t)
* `t_usize` (size_t)
* `t_f32`
* `t_f64`
## Extent of operator overload validation
The AST and constructors will be able to validate that the arguments provided for the operator type match the expected form:
* If return type must match a parameter
* If number of parameters is correct
* If added as a member symbol to a class or struct, that operator matches the requirements for the class (types match up)
* There is no support for validating new & delete operations (yet)
The user is responsible for making sure the code types provided are correct
and have the desired specifiers assigned to them beforehand.
## Code generation and modification
There are two provided auxillary interfaces:
* Builder
* Scanner
### Builder is a similar object to the jai language's string_builder
* The purpose of it is to generate a file.
* A file is specified and opened for writing using the open( file_path) function.
* The code is provided via print( code ) function will be serialized to its buffer.
* When all serialization is finished, use the write() command to write the buffer to the file.
### Scanner Auxillary Interface
* The purpose is to scan or parse files
* Some with two basic functions to convert a fil to code: `scan_file` and `parse_file`
* `scan_file`: Merely grabs the file and stores it in an untyped Code.
* `parse_file`: Will parse the file using `parse_global_body` and return a `CodeBody`.
* Two basic functions for grabbing columns from a CSV: `parse_csv_one_column` and `parse_csv_two_columns`

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[*.c]
indent_style = tab
indent_size = 4
[*.cpp]
indent_style = tab
indent_size = 2

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## Navigation
# base
[Top](../Readme.md)
* [docs](../docs/Readme.md)
# C Library Generation
`c_library.cpp` generates both *segemnted* and *singleheader* variants of the library compliant with C11.
The output will be in the `gen_segmented/gen` directory (if the directory does not exist, it will create it).
If using the library's provided build scripts:
```ps1
.\build.ps1 <compiler> <debug or omit> c_library
```
All free from tag identifiers will be prefixed with `gen_` or `GEN_` as the namespace. This can either be changed after generation with a `.refactor` script (or your preferred subst method), OR by modifying c_library.refactor.
**If c_library.refactor is modified you may need to modify c_library.cpp and its [components](./components/). As some of the container generation relies on that prefix.**

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__VERSION 1
// not : Ignore
// include : #includes
// word : Alphanumeric or underscore
// namespace : Prefix search and replace (c-namspaces).
// regex : Unavailable in __VERSION 1.
// Precedence (highest to lowest):
// word, namespace, regex
// Gen Macro namespace
// namespace GEN_, new_namespace_
// c_library.refactor
// Used to prefix all exposed identifiers with the gen_namespace by c_library.cpp using ./gencpp/scripts/helpers/refactor.exe
// Macros
word global, gen_global
word internal, gen_internal
word local_persist, gen_local_persist
word bit, gen_bit
word bitfield_is_equal, gen_bitfield_is_equal
word cast, gen_cast
word ccast, gen_ccast
word pcast, gen_pcast
word rcast, gen_rcast
word scast, gen_scast
word stringize_va, gen_stringize_va
word stringize, gen_stringize
word do_once, gen_do_once
word do_once_start, gen_do_once_start
word do_once_end, gen_do_once_end
word labeled_scope_start, gen_labeled_scope_start
word labeled_scope_end, gen_labeled_scope_end
word compiler_decorated_func_name, gen_compiler_decorated_func_name
word num_args_impl, gen_num_args_impl
word num_args, gen_num_args
word clamp, gen_clamp
word count_of, gen_count_of
word is_between, gen_is_between
word size_of, gen_size_of
word max, gen_max
word min, gen_min
word offset_of, gen_offset_of
word forceinline, gen_forceinline
word neverinline, gen_neverinline
word static_assert, gen_static_assert
word thread_local, gen_thread_local
word typeof, gen_typeof
word enum_underlying, gen_enum_underlying
word nullptr, gen_nullptr
word struct_init, gen_struct_init
word hash, gen_hash
// Basic Types
word u8, gen_u8
word s8, gen_s8
word u16, gen_u16
word s16, gen_s16
word u32, gen_u32
word s32, gen_s32
word u64, gen_u64
word s64, gen_s64
word usize, gen_usize
word ssize, gen_ssize
word sptr, gen_sptr
word uptr, gen_uptr
word f32, gen_f32
word f64, gen_f64
word b8, gen_b8
word b16, gen_b16
word b32, gen_b32
word mem_ptr, gen_mem_ptr
word mem_ptr_const, gen_mem_ptr_const
word to_uptr, gen_to_uptr
word to_sptr, gen_to_sptr
word to_mem_ptr, gen_to_mem_ptr
word to_mem_ptr_const, gen_to_mem_ptr_const
// Debug
word assert_handler, gen_assert_handler
word assert_crash, gen_assert_crash
word process_exit, gen_process_exit
// Memory
word kilobytes, gen_kilobytes
word megabytes, gen_megabytes
word gigabytes, gen_gigabytes
word terabytes, gen_terabytes
word swap, gen_swap
word is_power_of_two, gen_is_power_of_two
word align_forward, gen_align_forward
word align_forward_by_value, gen_align_forward_by_value
word pointer_add, gen_pointer_add
word pointer_add_const, gen_pointer_add_const
word pointer_diff, gen_pointer_diff
word mem_copy, gen_mem_copy
word mem_find, gen_mem_find
word mem_move, gen_mem_move
word mem_set, gen_mem_set
word zero_size, gen_zero_size
word zero_item, gen_zero_item
word zero_array, gen_zero_array
word AllocType, gen_AllocType
word AllocatorProc, gen_AllocatorProc
word AllocatorInfo, gen_AllocatorInfo
word AllocFlag, gen_AllocFlag
word alloc, gen_alloc
word alloc_align, gen_alloc_align
word allocator_free, gen_allocator_free
word free_all, gen_free_all
word resize, gen_resize
word resize_align, gen_resize_align
word alloc_item, gen_alloc_item
word alloc_array, gen_alloc_array
word heap_stats_init, gen_heap_stats_init
word heap_stats_used_memory, gen_heap_stats_used_memory
word heap_stats_alloc_count, gen_heap_stats_alloc_count
word heap_stats_check, gen_heap_stats_check
word default_resize_align, gen_default_resize_align
word heap_allocator_proc, gen_heap_allocator_proc
word heap, gen_heap
word malloc, gen_malloc
word mfree, gen_mfree
word VirtualMemory, gen_VirtualMemory
word vm_from_memory, gen_vm_from_memory
word vm_alloc, gen_vm_alloc
word vm_free, gen_vm_free
word vm_trim, gen_vm_trim
word vm_purge, gen_vm_purge
word virtual_memory_page_size, gen_virtual_memory_page_size
// Memory: Arena
word Arena, gen_Arena
namespace arena_, gen_arena_
// word arena_allocator_info
// word arena_init_from_memory
// word arena_init_from_allocator
// word arena_init_sub
// word arena_alignment_of
// word arena_check
// word arena_size_remaining
// Memory: FixedArena
namespace FixedArena_, gen_FixedArena_
namespace fixed_arena_, gen_fixed_arena_
// Memory: Pool
word Pool, gen_Pool
namespace pool_, gen_pool_
// Printing
namespace str_, gen_str_
word PrintF_Buffer, gen_PrintF_Buffer
word Msg_Invalid_Value, gen_Msg_Invalid_Value
word log_fmt, gen_log_fmt
// String Ops
namespace char_, gen_char_
word digit_to_int, gen_digit_to_int
word hex_digit_to_init, gen_hex_digit_to_init
word i64_to_str, gen_i64_to_str
word u64_to_str, gen_u64_to_str
// Containers
namespace GENERIC_SLOT_, GEN_GENERIC_SLOT_
word Array, gen_Array
word Array_ssize, gen_Array_gen_ssize
word ArrayHeader, gen_ArrayHeader
namespace Array_, gen_Array_
namespace array_, gen_array_
word HashTable, gen_HashTable
namespace HashTable_, gen_HashTable_
namespace hashtable_, gen_hashtable_
namespace HT_, gen_HT_
namespace HTE_, gen_HTE_
namespace arr_hte_, gen_arr_hte_
namespace Arr_HTE_, gen_Arr_HTE_
// Hashing
word crc32, gen_crc32
word crc64, gen_crc64
// Strings
word StrC, gen_StrC
word to_strc_from_c_str, gen_to_strc_from_c_str
namespace strc_, gen_strc_
word cast_to_strc, gen_cast_to_strc
word StringHeader, gen_StringHeader
word String, gen_String
namespace string_, gen_string_
word StringCached, gen_StringCached
word StringTable, gen_StringTable
namespace StringTable_, gen_StringTable_
// File Handling
word FileModeFlag, gen_FileModeFlag
word SeekWhenceType, gen_SeekWhenceType
word FileError, gen_FileError
word FileDescriptor, gen_FileDescriptor
word FileMode, gen_FileMode
word FileOperations, gen_FileOperations
word FileOperations, gen_FileOperations
default_file_operations
word FileTime, word FileTime
word DirType, gen_DirType
word DirInfo, gen_DirInfo
word DirEntry, gen_DirEntry
word DirInfo, gen_DirInfo
word FileInfo, gen_FileInfo
word FileStandardType, gen_FileStandardType
namespace file_, gen_file_
word gen_FileContents, gen_FileContents
// Timing
word read_cpu_time_stamp_counter, gen_read_cpu_time_stamp_counter
word time_rel, gen_time_rel
word time_rel_ms, gen_time_rel_ms
// Parsing
// Parsing: ADT
word ADT_Node, gen_ADT_Node
word ADT_Type, gen_ADT_Type
word ADT_Props, gen_ADT_Props
word ADT_NamingStyle, gen_ADT_NamingStyle
word ADT_AssignStyle, gen_ADT_AssignStyle
word ADT_DelimStyle, gen_ADT_DelimStyle
word ADT_Error, gen_ADT_Error
word ADT_Node, gen_ADT_Node
namespace adt_, gen_adt_
word CSV_Error, gen_CSV_Error
word CSV_Object, gen_CSV_Object
namespace csv_, gen_csv_
// Types.hpp
word log_failure, gen_log_failure
word AccessSpec, gen_AccessSpec
word access_spec_to_str, gen_access_spec_to_str
word CodeFlag, gen_CodeFlag
word EnumDecl, gen_EnumDecl
word ModuleFlag, gen_ModuleFlag
word module_flag_to_str, gen_module_flag_to_str
word EPreprocessCond, gen_EPreprocessCOnd
word ETypenameTag, gen_ETypenameTag
word CodeType, gen_CodeType
word codetype_to_str, gen_codetype_to_str
word codetype_to_keyword_str, gen_codetype_to_keyword_str
word Operator, gen_Operator
word operator_to_str, gen_operator_to_str
word Specifier, gen_Specifier
word spec_to_str, gen_spec_to_str
word spec_is_trailing, gen_spec_is_trailing
// word strc_to_specifier, gen_strc_to_specifier
// AST
word AST, gen_AST
namespace AST_, gen_AST_
word Code, gen_Code
word Token, gen_Token
word CodeBody, gen_CodeBody
word CodeAttributes, gen_CodeAttributes
word CodeComment, gen_CodeComment
word CodeClass, gen_CodeClass
word CodeConstructor, gen_CodeConstructor
word CodeDefine, gen_CodeDefine
word CodeDestructor, gen_CodeDestructor
word CodeEnum, gen_CodeEnum
word CodeExec, gen_CodeExec
word CodeExtern, gen_CodeExtern
word CodeInclude, gen_CodeInclude
word CodeFriend, gen_CodeFriend
word CodeFn, gen_CodeFn
word CodeModule, gen_CodeModule
word CodeNS, gen_CodeNS
word CodeOperator, gen_CodeOperator
word CodeOpCast, gen_CodeOpCast
word CodePragma, gen_CodePragma
word CodeParams, gen_CodeParams
word CodePreprocessCond, gen_CodePreprocessCond
word CodeSpecifiers, gen_CodeSpecifiers
word CodeTemplate, gen_CodeTemplate
word CodeTypename, gen_CodeTypename
word CodeTypedef, gen_CodeTypedef
word CodeUnion, gen_CodeUnion
word CodeUsing, gen_CodeUsing
word CodeVar, gen_CodeVar
// Code Interface
namespace code_, gen_code_
word Code_Global, gen_Code_Global
word Code_Invalid, gen_Code_Invalid
word Code_POD, gen_Code_POD
word AST_POD_Size, gen_AST_POD_Size
word AST_ArrSpecs_Cap, gen_AST_ArrSpecs_Cap
word InvalidCode, gen_InvalidCode
word NullCode, gen_NullCode
namespace begin_, gen_begin_
namespace end_, gen_end_
namespace next_, gen_next_
namespace body_, gen_body_
namespace class_, gen_class_
namespace params_, gen_params_
namespace specifiers_, gen_specifiers_
namespace struct_, gen_struct_
namespace attributes_, gen_attributes_
namespace comment_, gen_comment_
namespace constructor, gen_constructor_
namespace define_, gen_define_
namespace destructor, gen_destructor_
namespace enum_, gen_enum_
namespace exec_, gen_exec_
namespace extern_, gen_extern_
namespace include_, gen_include_
namespace friend_, gen_friend_
namespace fn_, gen_fn_
namespace module_, gen_module_
namespace code_op, gen_code_op_
namespace opcast_, gen_opcast_
namespace pragma_, gen_pragma_
namespace preprocess_, gen_preprocess_
namespace template_, gen_template_
namespace typename_, gen_typename_
namespace typedef_, gen_typedef_
namesapce union_, gen_union_
namespace using_, gen_using_
namespace var_, gen_var_
// Gen Interface
word init, gen_init
word deinit, gen_deinit
word reset, gen_reset
word get_cached_string, gen_get_cached_string
word make_code, gen_make_code
namespace set_allocator_, gen_set_allocator_
namespace def_, gen_def_
namespace parse_, gen_parse_
namespace token_, gen_token_
namespace untyped_, gen_untyped_
// Constants
word TokenMap_FixedArena, gen_TokenMap_FixedArena
word InitSize_DataArrays, gen_InitSize_DataArrays
word Global_BucketSize, gen_Global_BucketSize
word CodePool_NumBlocks, gen_CodePool_NumBlocks
word SizePer_StringArena, gen_SizePer_StringArena
word MaxCommentLineLength, gen_MaxCommentLineLength
word MaxNameLength, gen_MaxNameLength
word MaxUntypedStrLength, gen_MaxUntypedStrLength
word LexAllocator_Size, gen_LexAllocator_Size
word Builder_StrBufferReserve, gen_Builder_StrBufferReserve
word access_public, gen_access_public
word access_protected, gen_access_protected
word access_private, gen_access_private
word attrib_api_export, gen_attrib_api_export
word attrib_api_import, gen_attrib_api_import
word module_global_fragment, gen_module_global_fragment
word module_private_fragment, gen_module_private_fragment
word fmt_newline, gen_fmt_newline
word pragma_once, gen_pragma_once
word param_varadic, gen_param_varadic
word preprocess_else, gen_preprocess_else
namespace spec_, gen_spec_
namespace t_, gen_t_
word PreprocessorDefines, gen_PreprocessorDefines
// Backend
word GlobalAllocator, gen_GlobalAllocator
word Global_AllocatorBuckets, gen_Global_AllocatorBuckets
word CodePools, gen_CodePools
word StringArenas, gen_StringArenas
word StringCache, gen_StringCache
word LexArena, gen_LexArena
word Allocator_DataArrays, gen_Allocator_DataArrays
word Allocator_CodePool, gen_Allocator_CodePool
word Allocator_Lexer, gen_Allocator_Lexer
word Allocator_StringArena, gen_Allocator_StringArena
word Allocator_StringTable, gen_Allocator_StringTable
word Allocator_TypeTable, gen_Allocator_TypeTable
// Builder
word Builder, gen_Builder
namespace builder_, gen_builder_
// Implementation (prviate)
word _format_info, gen__format_info
namespace _print_, gen__print_
word _heap_stats, gen__heap_stats
word _heap_alloc_info, gen__heap_alloc_info
word _crc32_table, gen__crc32_table
word _crc64_table, gen__crc64_table
word _alloc_utf8_to_ucs2, gen__alloc_utf8_to_ucs2
word _win32_file_seek, gen__win32_file_seek
word _win32_file_read, gen__win32_file_read
word _win32_file_write, gen__win32_file_write
word _win32_file_close, gen__win32_file_close
word _win32_file_open, gen__win32_file_open
word _posix_file_seek, gen__posix_file_seek
word _posix_file_read, gen__posix_file_read
word _posix_file_write, gen__posix_file_write
word _posix_file_close, gen__posix_file_close
word _posix_file_open, gen__posix_file_open
word _dirinfo_free_entry, gen__dirinfo_free_entry
word _std_file_set, gen__std_file_set
word _memory_fd, gen__memory_fd
word _file_stream_fd_make, gen__file_stream_fd_make
word _file_stream_from_fd, gen__file_stream_from_fd
word _memory_file_seek, gen__memory_file_seek
word _memory_file_read, gen__memory_file_read
word _memory_file_write, gen__memory_file_write
word _memory_file_close, gen__memory_file_close
word _unix_gettime, gen__unix_gettime
word _adt_fprintf, gen__adt_fprintf
word _adt_get_value, gen__adt_get_value
word _adt_get_field, gen__adt_get_field
word _csv_write_record, gen__csv_write_record
word _csv_write_header, gen__csv_write_header
word Global_Allocator_Proc, gen_Global_Allocator_Proc
word define_constants, gen_define_constants
word operator__validate, gen_operator__validate
word parser_init, gen_parser_init
word parser_deinit, gen_parser_deinit
word TokType, gen_TokType
word toktype_to_str, gen_toktype_to_str
// word strc_to_toktype, gen_strc_to_toktype
word NullToken, gen_NullToken
namespace tok_, gen_tok_
word TokArray, gen_TokArray
namespace lex_, gen_lex_
namespace Lexer_, gen_Lexer_
word LexContext, gen_LexContext
word lex, gen_lex
word StackNode, gen_StackNode
word ParseContext, gen_ParseContext
// namespace parse_, gen_parse_
namespace parser_, gen_parser_

434
gen_c_library/components/containers.array.hpp Normal file
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#pragma once
#include "gen.hpp"
using namespace gen;
// Used to know what slot the array will be for generic selection
global s32 Array_DefinitionCounter = 0;
CodeBody gen_array_base()
{
CodeTypedef td_header = parse_typedef( code( typedef struct ArrayHeader ArrayHeader; ));
CodeStruct header = parse_struct( code(
struct ArrayHeader
{
AllocatorInfo Allocator;
usize Capacity;
usize Num;
};
));
Code grow_formula = untyped_str( txt( "#define array_grow_formula( value ) ( 2 * value + 8 )\n" ));
Code get_header = untyped_str( txt( "#define array_get_header( self ) ( (ArrayHeader*)( self ) - 1)\n" ));
Code type_define = untyped_str( txt( "#define Array(Type) gen_Array_##Type\n"));
Code array_begin = def_define(txt("array_begin(array)"), code( (array) ));
Code array_end = def_define(txt("array_end(array)"), code( (array + array_get_header(array)->Num ) ));
Code array_next = def_define(txt("array_next(array, entry)"), code( (entry + 1) ));
return def_global_body( args(
fmt_newline,
td_header,
header,
type_define,
grow_formula,
get_header,
array_begin,
array_end,
array_next,
fmt_newline
));
};
CodeBody gen_array( StrC type, StrC array_name )
{
String array_type = String::fmt_buf( GlobalAllocator, "%.*s", array_name.Len, array_name.Ptr );
String fn = String::fmt_buf( GlobalAllocator, "%.*s", array_name.Len, array_name.Ptr );
// str_to_lower(fn.Data);
#pragma push_macro( "GEN_ASSERT" )
#pragma push_macro( "rcast" )
#pragma push_macro( "cast" )
#pragma push_macro( "typeof" )
#pragma push_macro( "forceinline" )
#undef GEN_ASSERT
#undef rcast
#undef cast
#undef typeof
#undef forceinline
CodeBody result = parse_global_body( token_fmt( "array_type", (StrC)array_type, "fn", (StrC)fn, "type", (StrC)type
, stringize(
typedef <type>* <array_type>;
<array_type> <fn>_init ( AllocatorInfo allocator );
<array_type> <fn>_init_reserve ( AllocatorInfo allocator, usize capacity );
bool <fn>_append_array ( <array_type>* self, <array_type> other );
bool <fn>_append ( <array_type>* self, <type> value );
bool <fn>_append_items ( <array_type>* self, <type>* items, usize item_num );
bool <fn>_append_at ( <array_type>* self, <type> item, usize idx );
bool <fn>_append_items_at( <array_type>* self, <type>* items, usize item_num, usize idx );
<type>* <fn>_back ( <array_type> self );
void <fn>_clear ( <array_type> self );
bool <fn>_fill ( <array_type> self, usize begin, usize end, <type> value );
void <fn>_free ( <array_type>* self );
bool <fn>_grow ( <array_type>* self, usize min_capacity );
usize <fn>_num ( <array_type> self );
<type> <fn>_pop ( <array_type> self );
void <fn>_remove_at ( <array_type> self, usize idx );
bool <fn>_reserve ( <array_type>* self, usize new_capacity );
bool <fn>_resize ( <array_type>* self, usize num );
bool <fn>_set_capacity ( <array_type>* self, usize new_capacity );
forceinline
<array_type> <fn>_init( AllocatorInfo allocator )
{
size_t initial_size = array_grow_formula(0);
return array_init_reserve( <type>, allocator, initial_size );
}
inline
<array_type> <fn>_init_reserve( AllocatorInfo allocator, usize capacity )
{
GEN_ASSERT(capacity > 0);
ArrayHeader* header = rcast(ArrayHeader*, alloc(allocator, sizeof(ArrayHeader) + sizeof(<type>) * capacity));
if (header == nullptr)
return nullptr;
header->Allocator = allocator;
header->Capacity = capacity;
header->Num = 0;
return rcast(<type>*, header + 1);
}
forceinline
bool <fn>_append_array( <array_type>* self, <array_type> other )
{
return array_append_items( * self, (<array_type>)other, <fn>_num(other));
}
inline
bool <fn>_append( <array_type>* self, <type> value )
{
GEN_ASSERT( self != nullptr);
GEN_ASSERT(* self != nullptr);
ArrayHeader* header = array_get_header( * self );
if ( header->Num == header->Capacity )
{
if ( ! array_grow( self, header->Capacity))
return false;
header = array_get_header( * self );
}
(* self)[ header->Num ] = value;
header->Num++;
return true;
}
inline
bool <fn>_append_items( <array_type>* self, <type>* items, usize item_num )
{
GEN_ASSERT( self != nullptr);
GEN_ASSERT(* self != nullptr);
GEN_ASSERT(items != nullptr);
GEN_ASSERT(item_num > 0);
ArrayHeader* header = array_get_header( * self );
if ( header->Num + item_num > header->Capacity )
{
if ( ! array_grow( self, header->Capacity + item_num ))
return false;
header = array_get_header( * self );
}
mem_copy( (* self) + header->Num, items, sizeof(<type>) * item_num );
header->Num += item_num;
return true;
}
inline
bool <fn>_append_at( <array_type>* self, <type> item, usize idx )
{
GEN_ASSERT( self != nullptr);
GEN_ASSERT(* self != nullptr);
ArrayHeader* header = array_get_header( * self );
if ( idx >= header->Num )
idx = header->Num - 1;
if ( idx < 0 )
idx = 0;
if ( header->Capacity < header->Num + 1 )
{
if ( ! array_grow( self, header->Capacity + 1 ) )
return false;
header = array_get_header( * self );
}
<array_type> target = (* self) + idx;
mem_move( target + 1, target, (header->Num - idx) * sizeof(<type>) );
header->Num++;
return true;
}
inline
bool <fn>_append_items_at( <array_type>* self, <type>* items, usize item_num, usize idx )
{
GEN_ASSERT( self != nullptr);
GEN_ASSERT(* self != nullptr);
ArrayHeader* header = array_get_header( * self );
if ( idx >= header->Num )
{
return array_append_items( * self, items, item_num );
}
if ( item_num > header->Capacity )
{
if ( ! array_grow( self, item_num + header->Capacity ) )
return false;
header = array_get_header( * self );
}
<type>* target = (* self) + idx + item_num;
<type>* src = (* self) + idx;
mem_move( target, src, (header->Num - idx) * sizeof(<type>) );
mem_copy( src, items, item_num * sizeof(<type>) );
header->Num += item_num;
return true;
}
inline
<type>* <fn>_back( <array_type> self )
{
GEN_ASSERT(self != nullptr);
ArrayHeader* header = array_get_header( self );
if ( header->Num == 0 )
return NULL;
return self + header->Num - 1;
}
inline
void <fn>_clear( <array_type> self )
{
GEN_ASSERT(self != nullptr);
ArrayHeader* header = array_get_header( self );
header->Num = 0;
}
inline
bool <fn>_fill( <array_type> self, usize begin, usize end, <type> value )
{
GEN_ASSERT(self != nullptr);
GEN_ASSERT(begin <= end);
ArrayHeader* header = array_get_header( self );
if ( begin < 0 || end >= header->Num )
return false;
for ( ssize idx = begin; idx < end; idx ++ )
self[ idx ] = value;
return true;
}
inline
void <fn>_free( <array_type>* self )
{
GEN_ASSERT( self != nullptr);
GEN_ASSERT(* self != nullptr);
ArrayHeader* header = array_get_header( * self );
allocator_free( header->Allocator, header );
self = NULL;
}
inline
bool <fn>_grow( <array_type>* self, usize min_capacity )
{
GEN_ASSERT( self != nullptr);
GEN_ASSERT(* self != nullptr);
GEN_ASSERT( min_capacity > 0 );
ArrayHeader* header = array_get_header( *self );
usize new_capacity = array_grow_formula( header->Capacity );
if ( new_capacity < min_capacity )
new_capacity = min_capacity;
return array_set_capacity( self, new_capacity );
}
forceinline
usize <fn>_num( <array_type> self )
{
GEN_ASSERT( self != nullptr);
return array_get_header(self)->Num;
}
inline
<type> <fn>_pop( <array_type> self )
{
GEN_ASSERT( self != nullptr);
ArrayHeader* header = array_get_header( self );
GEN_ASSERT( header->Num > 0 );
<type> result = self[ header->Num - 1 ];
header->Num--;
return result;
}
forceinline
void <fn>_remove_at( <array_type> self, usize idx )
{
GEN_ASSERT( self != nullptr);
ArrayHeader* header = array_get_header( self );
GEN_ASSERT( idx < header->Num );
mem_move( self + idx, self + idx + 1, sizeof( <type> ) * ( header->Num - idx - 1 ) );
header->Num--;
}
inline
bool <fn>_reserve( <array_type>* self, usize new_capacity )
{
GEN_ASSERT( self != nullptr);
GEN_ASSERT(* self != nullptr);
GEN_ASSERT(new_capacity > 0);
ArrayHeader* header = array_get_header( * self );
if ( header->Capacity < new_capacity )
return array_set_capacity( self, new_capacity );
return true;
}
inline
bool <fn>_resize( <array_type>* self, usize num )
{
GEN_ASSERT( self != nullptr);
GEN_ASSERT(* self != nullptr);
GEN_ASSERT(num > 0);
ArrayHeader* header = array_get_header( * self );
if ( header->Capacity < num )
{
if ( ! array_grow( self, num ) )
return false;
header = array_get_header( * self );
}
header->Num = num;
return true;
}
inline
bool <fn>_set_capacity( <array_type>* self, usize new_capacity )
{
GEN_ASSERT( self != nullptr);
GEN_ASSERT(* self != nullptr);
GEN_ASSERT( new_capacity > 0 );
ArrayHeader* header = array_get_header( * self );
if ( new_capacity == header->Capacity )
return true;
if ( new_capacity < header->Num )
{
header->Num = new_capacity;
return true;
}
usize size = sizeof( ArrayHeader ) + sizeof( <type> ) * new_capacity;
ArrayHeader* new_header = cast( ArrayHeader*, alloc( header->Allocator, size ));
if ( new_header == NULL )
return false;
mem_move( new_header, header, sizeof( ArrayHeader ) + sizeof( <type> ) * header->Num );
new_header->Capacity = new_capacity;
allocator_free( header->Allocator, & header );
* self = cast( <type>*, new_header + 1 );
return true;
}
)));
#pragma pop_macro( "GEN_ASSERT" )
#pragma pop_macro( "rcast" )
#pragma pop_macro( "cast" )
#pragma pop_macro( "typeof" )
#pragma pop_macro( "forceinline" )
++ Array_DefinitionCounter;
StrC slot_str = String::fmt_buf(GlobalAllocator, "%d", Array_DefinitionCounter).to_strc();
Code generic_interface_slot = untyped_str(token_fmt( "type", type, "array_type", (StrC)array_type, "slot", (StrC)slot_str,
R"(#define GENERIC_SLOT_<slot>__array_init <type>, <array_type>_init
#define GENERIC_SLOT_<slot>__array_init_reserve <type>, <array_type>_init_reserve
#define GENERIC_SLOT_<slot>__array_append <array_type>, <array_type>_append
#define GENERIC_SLOT_<slot>__array_append_items <array_type>, <array_type>_append_items
#define GENERIC_SLOT_<slot>__array_append_at <array_type>, <array_type>_append_at
#define GENERIC_SLOT_<slot>__array_append_items_at <array_type>, <array_type>_append_items_at
#define GENERIC_SLOT_<slot>__array_back <array_type>, <array_type>_back
#define GENERIC_SLOT_<slot>__array_clear <array_type>, <array_type>_clear
#define GENERIC_SLOT_<slot>__array_fill <array_type>, <array_type>_fill
#define GENERIC_SLOT_<slot>__array_free <array_type>, <array_type>_free
#define GENERIC_SLOT_<slot>__array_grow <array_type>*, <array_type>_grow
#define GENERIC_SLOT_<slot>__array_num <array_type>, <array_type>_num
#define GENERIC_SLOT_<slot>__array_pop <array_type>, <array_type>_pop
#define GENERIC_SLOT_<slot>__array_remove_at <array_type>, <array_type>_remove_at
#define GENERIC_SLOT_<slot>__array_reserve <array_type>, <array_type>_reserve
#define GENERIC_SLOT_<slot>__array_resize <array_type>, <array_type>_resize
#define GENERIC_SLOT_<slot>__array_set_capacity <array_type>*, <array_type>_set_capacity
)"
));
return def_global_body( args(
def_pragma( string_to_strc( string_fmt_buf( GlobalAllocator, "region %S", array_type ))),
fmt_newline,
generic_interface_slot,
fmt_newline,
result,
fmt_newline,
def_pragma( string_to_strc(string_fmt_buf( GlobalAllocator, "endregion %S", array_type ))),
fmt_newline
));
};
CodeBody gen_array_generic_selection_interface()
{
CodeBody interface_defines = def_body(CT_Global_Body);
interface_defines.append( gen_generic_selection_function_macro( Array_DefinitionCounter, txt("array_init"), GenericSel_Direct_Type ));
interface_defines.append( gen_generic_selection_function_macro( Array_DefinitionCounter, txt("array_init_reserve"), GenericSel_Direct_Type ));
interface_defines.append( gen_generic_selection_function_macro( Array_DefinitionCounter, txt("array_append"), GenericSel_By_Ref ));
interface_defines.append( gen_generic_selection_function_macro( Array_DefinitionCounter, txt("array_append_at"), GenericSel_By_Ref ));
interface_defines.append( gen_generic_selection_function_macro( Array_DefinitionCounter, txt("array_append_items"), GenericSel_By_Ref ));
interface_defines.append( gen_generic_selection_function_macro( Array_DefinitionCounter, txt("array_append_items_at"), GenericSel_By_Ref ));
interface_defines.append( gen_generic_selection_function_macro( Array_DefinitionCounter, txt("array_back"), GenericSel_Default, GenericSel_One_Arg ));
interface_defines.append( gen_generic_selection_function_macro( Array_DefinitionCounter, txt("array_clear"), GenericSel_Default, GenericSel_One_Arg ));
interface_defines.append( gen_generic_selection_function_macro( Array_DefinitionCounter, txt("array_fill")) );
interface_defines.append( gen_generic_selection_function_macro( Array_DefinitionCounter, txt("array_free"), GenericSel_By_Ref, GenericSel_One_Arg ) );
interface_defines.append( gen_generic_selection_function_macro( Array_DefinitionCounter, txt("array_grow")) );
interface_defines.append( gen_generic_selection_function_macro( Array_DefinitionCounter, txt("array_num"), GenericSel_Default, GenericSel_One_Arg ));
interface_defines.append( gen_generic_selection_function_macro( Array_DefinitionCounter, txt("array_pop"), GenericSel_Default, GenericSel_One_Arg ));
interface_defines.append( gen_generic_selection_function_macro( Array_DefinitionCounter, txt("array_remove_at")) );
interface_defines.append( gen_generic_selection_function_macro( Array_DefinitionCounter, txt("array_reserve"), GenericSel_By_Ref) );
interface_defines.append( gen_generic_selection_function_macro( Array_DefinitionCounter, txt("array_resize"), GenericSel_By_Ref) );
interface_defines.append( gen_generic_selection_function_macro( Array_DefinitionCounter, txt("array_set_capacity")) );
return interface_defines;
}

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gen_c_library/components/containers.hashtable.hpp Normal file
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#pragma once
#include "gen.hpp"
#include "containers.array.hpp"
using namespace gen;
global s32 HashTable_DefinitionCounter = 0;
CodeBody gen_hashtable_base()
{
CodeBody struct_def = parse_global_body( code(
typedef struct HT_FindResult_Def HT_FindResult;
struct HT_FindResult_Def
{
ssize HashIndex;
ssize PrevIndex;
ssize EntryIndex;
};
));
Code define_type = untyped_str(txt(
R"(#define HashTable(_type) struct _type
)"
));
Code define_critical_load_scale = untyped_str(txt("#define HashTable_CriticalLoadScale 0.7f\n"));
return def_global_body(args(struct_def, define_type, define_critical_load_scale));
}
CodeBody gen_hashtable( StrC type, StrC hashtable_name )
{
String tbl_type = {(char*) hashtable_name.duplicate(GlobalAllocator).Ptr};
String fn = tbl_type.duplicate(GlobalAllocator);
// str_to_lower(fn.Data);
String name_lower = String::make( GlobalAllocator, hashtable_name );
// str_to_lower( name_lower.Data );
String hashtable_entry = String::fmt_buf( GlobalAllocator, "HTE_%.*s", hashtable_name.Len, hashtable_name.Ptr );
String entry_array_name = String::fmt_buf( GlobalAllocator, "Arr_HTE_%.*s", hashtable_name.Len, hashtable_name.Ptr );
String entry_array_fn_ns = String::fmt_buf( GlobalAllocator, "arr_hte_%.*s", name_lower.length(), name_lower.Data );
CodeBody hashtable_types = parse_global_body( token_fmt(
"type", (StrC) type,
"tbl_name", (StrC) hashtable_name,
"tbl_type", (StrC) tbl_type,
stringize(
typedef struct HashTable_<type> <tbl_type>;
typedef struct HTE_<tbl_name> HTE_<tbl_name>;
struct HTE_<tbl_name> {
u64 Key;
ssize Next;
<type> Value;
};
typedef void (* <tbl_type>_MapProc) ( <tbl_type> self, u64 key, <type> value );
typedef void (* <tbl_type>_MapMutProc) ( <tbl_type> self, u64 key, <type>* value );
)));
CodeBody entry_array = gen_array( hashtable_entry, entry_array_name );
#pragma push_macro( "GEN_ASSERT" )
#pragma push_macro( "GEN_ASSERT_NOT_NULL" )
#pragma push_macro( "rcast" )
#pragma push_macro( "cast" )
#pragma push_macro( "typeof" )
#pragma push_macro( "forceinline" )
#undef GEN_ASSERT
#undef GEN_ASSERT_NOT_NULL
#undef GEN_ASSERT
#undef rcast
#undef cast
#undef typeof
#undef forceinline
CodeBody hashtable_def = parse_global_body( token_fmt(
"type", (StrC) type,
"tbl_name", (StrC) hashtable_name,
"tbl_type", (StrC) tbl_type,
"fn", (StrC) fn,
"entry_type", (StrC) hashtable_entry,
"array_entry", (StrC) entry_array_name,
"fn_array", (StrC) entry_array_fn_ns,
stringize(
struct HashTable_<type> {
Array_ssize Hashes;
<array_entry> Entries;
};
<tbl_type> <fn>_init ( AllocatorInfo allocator );
<tbl_type> <fn>_init_reserve( AllocatorInfo allocator, ssize num );
void <fn>_clear ( <tbl_type> self );
void <fn>_destroy ( <tbl_type>* self );
<type>* <fn>_get ( <tbl_type> self, u64 key );
void <fn>_map ( <tbl_type> self, <tbl_type>_MapProc map_proc );
void <fn>_map_mut ( <tbl_type> self, <tbl_type>_MapMutProc map_proc );
void <fn>_grow ( <tbl_type>* self );
void <fn>_rehash ( <tbl_type>* self, ssize new_num );
void <fn>_rehash_fast ( <tbl_type> self );
void <fn>_remove ( <tbl_type> self, u64 key );
void <fn>_remove_entry( <tbl_type> self, ssize idx );
void <fn>_set ( <tbl_type>* self, u64 key, <type> value );
ssize <fn>_slot ( <tbl_type> self, u64 key );
ssize <fn>__add_entry( <tbl_type>* self, u64 key );
HT_FindResult <fn>__find ( <tbl_type> self, u64 key );
b32 <fn>__full ( <tbl_type> self );
<tbl_type> <fn>_init( AllocatorInfo allocator )
{
<tbl_type> result = hashtable_init_reserve(<type>, allocator, 8);
return result;
}
<tbl_type> <fn>_init_reserve( AllocatorInfo allocator, ssize num )
{
<tbl_type> result = { NULL, NULL };
result.Hashes = array_init_reserve(ssize, allocator, num );
array_get_header(result.Hashes)->Num = num;
array_resize(result.Hashes, num);
array_fill(result.Hashes, 0, num, -1);
result.Entries = array_init_reserve(<entry_type>, allocator, num );
return result;
}
void <fn>_clear( <tbl_type> self )
{
GEN_ASSERT_NOT_NULL(self.Hashes);
GEN_ASSERT_NOT_NULL(self.Entries);
array_clear( self.Entries );
s32 what = array_num(self.Hashes);
array_fill( self.Hashes, 0, what, (ssize)-1 );
}
void <fn>_destroy( <tbl_type>* self )
{
GEN_ASSERT_NOT_NULL(self);
GEN_ASSERT_NOT_NULL(self->Hashes);
GEN_ASSERT_NOT_NULL(self->Entries);
if ( self->Hashes && array_get_header(self->Hashes)->Capacity) {
array_free( self->Hashes );
array_free( self->Entries );
}
}
<type>* <fn>_get( <tbl_type> self, u64 key )
{
GEN_ASSERT_NOT_NULL(self.Hashes);
GEN_ASSERT_NOT_NULL(self.Entries);
ssize idx = <fn>__find( self, key ).EntryIndex;
if ( idx > 0 )
return & self.Entries[idx].Value;
return nullptr;
}
void <fn>_map( <tbl_type> self, <tbl_type>_MapProc map_proc )
{
GEN_ASSERT_NOT_NULL(self.Hashes);
GEN_ASSERT_NOT_NULL(self.Entries);
GEN_ASSERT_NOT_NULL( map_proc );
for ( ssize idx = 0; idx < array_get_header( self.Entries )->Num; idx++ ) {
map_proc( self, self.Entries[idx].Key, self.Entries[idx].Value );
}
}
void <fn>_map_mut( <tbl_type> self, <tbl_type>_MapMutProc map_proc )
{
GEN_ASSERT_NOT_NULL(self.Hashes);
GEN_ASSERT_NOT_NULL(self.Entries);
GEN_ASSERT_NOT_NULL( map_proc );
for ( ssize idx = 0; idx < array_get_header( self.Entries )->Num; idx++ ) {
map_proc( self, self.Entries[idx].Key, & self.Entries[idx].Value );
}
}
void <fn>_grow( <tbl_type>* self )
{
GEN_ASSERT_NOT_NULL(self);
GEN_ASSERT_NOT_NULL(self->Hashes);
GEN_ASSERT_NOT_NULL(self->Entries);
ssize new_num = array_grow_formula( array_get_header( self->Entries )->Num );
hashtable_rehash( self, new_num );
}
void <fn>_rehash( <tbl_type>* self, ssize new_num )
{
GEN_ASSERT_NOT_NULL(self);
GEN_ASSERT_NOT_NULL(self->Hashes);
GEN_ASSERT_NOT_NULL(self->Entries);
GEN_ASSERT( new_num > 0 );
ssize idx;
ssize last_added_index;
ArrayHeader* old_hash_header = array_get_header( self->Hashes );
ArrayHeader* old_entries_header = array_get_header( self->Entries );
<tbl_type> new_tbl = hashtable_init_reserve( <type>, old_hash_header->Allocator, old_hash_header->Num );
ArrayHeader* new_hash_header = array_get_header( new_tbl.Hashes );
for (ssize idx = 0; idx < cast(ssize, old_hash_header->Num); ++idx)
{
<entry_type>* entry = & self->Entries[idx];
HT_FindResult find_result;
find_result = <fn>__find( new_tbl, entry->Key);
last_added_index = <fn>__add_entry( & new_tbl, entry->Key);
if (find_result.PrevIndex < 0)
new_tbl.Hashes[find_result.HashIndex] = last_added_index;
else
new_tbl.Entries[find_result.PrevIndex].Next = last_added_index;
new_tbl.Entries[last_added_index].Next = find_result.EntryIndex;
new_tbl.Entries[last_added_index].Value = entry->Value;
}
<fn>_destroy( self );
* self = new_tbl;
}
void <fn>_rehash_fast( <tbl_type> self )
{
GEN_ASSERT_NOT_NULL(self.Hashes);
GEN_ASSERT_NOT_NULL(self.Entries);
ssize idx;
for ( idx = 0; idx < array_get_header( self.Entries )->Num; idx++ )
self.Entries[ idx ].Next = -1;
for ( idx = 0; idx < array_get_header( self.Hashes )->Num; idx++ )
self.Hashes[ idx ] = -1;
for ( idx = 0; idx < array_get_header( self.Entries )->Num; idx++ )
{
<entry_type>* entry;
HT_FindResult find_result;
entry = & self.Entries[ idx ];
find_result = <fn>__find( self, entry->Key );
if ( find_result.PrevIndex < 0 )
self.Hashes[ find_result.HashIndex ] = idx;
else
self.Entries[ find_result.PrevIndex ].Next = idx;
}
}
void <fn>_remove( <tbl_type> self, u64 key )
{
GEN_ASSERT_NOT_NULL(self.Hashes);
GEN_ASSERT_NOT_NULL(self.Entries);
HT_FindResult find_result = <fn>__find( self, key );
if ( find_result.EntryIndex >= 0 ) {
array_remove_at( self.Entries, find_result.EntryIndex );
hashtable_rehash_fast( self );
}
}
void <fn>_remove_entry( <tbl_type> self, ssize idx )
{
GEN_ASSERT_NOT_NULL(self.Hashes);
GEN_ASSERT_NOT_NULL(self.Entries);
array_remove_at( self.Entries, idx );
}
void <fn>_set( <tbl_type>* self, u64 key, <type> value )
{
GEN_ASSERT_NOT_NULL(self);
GEN_ASSERT_NOT_NULL(self->Hashes);
GEN_ASSERT_NOT_NULL(self->Entries);
ssize idx;
HT_FindResult find_result;
if ( array_get_header( self->Hashes )->Num == 0 )
hashtable_grow( self );
find_result = <fn>__find( * self, key );
if ( find_result.EntryIndex >= 0 ) {
idx = find_result.EntryIndex;
}
else
{
idx = <fn>__add_entry( self, key );
if ( find_result.PrevIndex >= 0 ) {
self->Entries[ find_result.PrevIndex ].Next = idx;
}
else {
self->Hashes[ find_result.HashIndex ] = idx;
}
}
self->Entries[ idx ].Value = value;
if ( <fn>__full( * self ) )
hashtable_grow( self );
}
ssize <fn>_slot( <tbl_type> self, u64 key )
{
GEN_ASSERT_NOT_NULL(self.Hashes);
GEN_ASSERT_NOT_NULL(self.Entries);
for ( ssize idx = 0; idx < array_get_header( self.Hashes )->Num; ++idx )
if ( self.Hashes[ idx ] == key )
return idx;
return -1;
}
ssize <fn>__add_entry( <tbl_type>* self, u64 key )
{
GEN_ASSERT_NOT_NULL(self);
GEN_ASSERT_NOT_NULL(self->Hashes);
GEN_ASSERT_NOT_NULL(self->Entries);
ssize idx;
<entry_type> entry = { key, -1 };
idx = array_get_header( self->Entries )->Num;
array_append( self->Entries, entry );
return idx;
}
HT_FindResult <fn>__find( <tbl_type> self, u64 key )
{
GEN_ASSERT_NOT_NULL(self.Hashes);
GEN_ASSERT_NOT_NULL(self.Entries);
HT_FindResult result = { -1, -1, -1 };
ArrayHeader* hash_header = array_get_header( self.Hashes );
if ( hash_header->Num > 0 )
{
result.HashIndex = key % hash_header->Num;
result.EntryIndex = self.Hashes[ result.HashIndex ];
while ( result.EntryIndex >= 0 )
{
if ( self.Entries[ result.EntryIndex ].Key == key )
break;
result.PrevIndex = result.EntryIndex;
result.EntryIndex = self.Entries[ result.EntryIndex ].Next;
}
}
return result;
}
b32 <fn>__full( <tbl_type> self )
{
GEN_ASSERT_NOT_NULL(self.Hashes);
GEN_ASSERT_NOT_NULL(self.Entries);
ArrayHeader* hash_header = array_get_header( self.Hashes );
ArrayHeader* entries_header = array_get_header( self.Entries );
usize critical_load = cast(usize, HashTable_CriticalLoadScale * cast(f32, hash_header->Num));
b32 result = entries_header->Num > critical_load;
return result;
}
)));
#pragma pop_macro( "GEN_ASSERT" )
#pragma pop_macro( "GEN_ASSERT_NOT_NULL" )
#pragma pop_macro( "rcast" )
#pragma pop_macro( "cast" )
#pragma pop_macro( "typeof" )
#pragma pop_macro( "forceinline" )
++ HashTable_DefinitionCounter;
StrC slot_str = String::fmt_buf(GlobalAllocator, "%d", HashTable_DefinitionCounter).to_strc();
Code generic_interface_slot = untyped_str(token_fmt( "type", type, "tbl_type", (StrC)tbl_type, "slot", (StrC)slot_str,
R"(#define GENERIC_SLOT_<slot>__hashtable_init <type>, <tbl_type>_init
#define GENERIC_SLOT_<slot>__hashtable_init_reserve <type>, <tbl_type>_init_reserve
#define GENERIC_SLOT_<slot>__hashtable_clear <tbl_type>, <tbl_type>_clear
#define GENERIC_SLOT_<slot>__hashtable_destroy <tbl_type>, <tbl_type>_destroy
#define GENERIC_SLOT_<slot>__hashtable_get <tbl_type>, <tbl_type>_get
#define GENERIC_SLOT_<slot>__hashtable_map <tbl_type>, <tbl_type>_map
#define GENERIC_SLOT_<slot>__hashtable_map_mut <tbl_type>, <tbl_type>_map_mut
#define GENERIC_SLOT_<slot>__hashtable_grow <tbl_type>*, <tbl_type>_grow
#define GENERIC_SLOT_<slot>__hashtable_rehash <tbl_type>*, <tbl_type>_rehash
#define GENERIC_SLOT_<slot>__hashtable_rehash_fast <tbl_type>, <tbl_type>_rehash_fast
#define GENERIC_SLOT_<slot>__hashtable_remove_entry <tbl_type>, <tbl_type>_remove_entry
#define GENERIC_SLOT_<slot>__hashtable_set <tbl_type>, <tbl_type>_set
#define GENERIC_SLOT_<slot>__hashtable_slot <tbl_type>, <tbl_type>_slot
#define GENERIC_SLOT_<slot>__hashtable__add_entry <tbl_type>*, <tbl_type>__add_entry
#define GENERIC_SLOT_<slot>__hashtable__find <tbl_type>, <tbl_type>__find
#define GENERIC_SLOT_<slot>__hashtable__full <tbl_type>, <tbl_type>__full
)"
));
char const* cmt_str = str_fmt_buf( "Name: %.*s Type: %.*s"
, tbl_type.length(), tbl_type.Data
, type.Len, type.Ptr );
return def_global_body(args(
def_pragma( string_to_strc( string_fmt_buf( GlobalAllocator, "region %S", tbl_type ))),
fmt_newline,
generic_interface_slot,
fmt_newline,
hashtable_types,
fmt_newline,
entry_array,
hashtable_def,
fmt_newline,
def_pragma( string_to_strc( string_fmt_buf( GlobalAllocator, "endregion %S", tbl_type ))),
fmt_newline
));
}
CodeBody gen_hashtable_generic_selection_interface()
{
CodeBody interface_defines = def_body(CT_Global_Body);
interface_defines.append( gen_generic_selection_function_macro( HashTable_DefinitionCounter, txt("hashtable_init"), GenericSel_Direct_Type ));
interface_defines.append( gen_generic_selection_function_macro( HashTable_DefinitionCounter, txt("hashtable_init_reserve"), GenericSel_Direct_Type ));
interface_defines.append( gen_generic_selection_function_macro( HashTable_DefinitionCounter, txt("hashtable_clear"), GenericSel_Default, GenericSel_One_Arg ));
interface_defines.append( gen_generic_selection_function_macro( HashTable_DefinitionCounter, txt("hashtable_destroy"), GenericSel_By_Ref, GenericSel_One_Arg ) );
interface_defines.append( gen_generic_selection_function_macro( HashTable_DefinitionCounter, txt("hashtable_get") ));
interface_defines.append( gen_generic_selection_function_macro( HashTable_DefinitionCounter, txt("hashtable_grow"), GenericSel_Default, GenericSel_One_Arg ));
interface_defines.append( gen_generic_selection_function_macro( HashTable_DefinitionCounter, txt("hashtable_rehash") ));
interface_defines.append( gen_generic_selection_function_macro( HashTable_DefinitionCounter, txt("hashtable_rehash_fast"), GenericSel_Default, GenericSel_One_Arg ));
interface_defines.append( gen_generic_selection_function_macro( HashTable_DefinitionCounter, txt("hashtable_remove") ));
interface_defines.append( gen_generic_selection_function_macro( HashTable_DefinitionCounter, txt("hashtable_remove_entry") ));
interface_defines.append( gen_generic_selection_function_macro( HashTable_DefinitionCounter, txt("hashtable_set"), GenericSel_By_Ref ));
interface_defines.append( gen_generic_selection_function_macro( HashTable_DefinitionCounter, txt("hashtable_slot") ));
return interface_defines;
}

115
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#pragma region _Generic Macros
// ____ _ ______ _ _ ____ _ __ _
// / ___} (_) | ____} | | (_) / __ \ | | | |(_)
// | | ___ ___ _ __ ___ _ __ _ ___ | |__ _ _ _ __ ___| |_ _ ___ _ __ | | | |_ _____ _ __ | | ___ __ _ __| | _ _ __ __ _
// | |{__ |/ _ \ '_ \ / _ \ '__} |/ __| | __} | | | '_ \ / __} __} |/ _ \| '_ \ | | | \ \ / / _ \ '_ \| |/ _ \ / _` |/ _` || | '_ \ / _` |
// | |__j | __/ | | | __/ | | | (__ | | | |_| | | | | (__| l_| | (_) | | | | | l__| |\ V / __/ | | | | (_) | (_| | (_| || | | | | (_| |
// \____/ \___}_l l_l\___}_l l_l\___| l_l \__,_l_l l_l\___}\__}_l\___/l_l l_l \____/ \_/ \___}_l l_l_l\___/ \__,_l\__,_l|_|_| |_|\__, |
// This implemnents macros for utilizing "The Naive Extendible _Generic Macro" explained in: __| |
// https://github.com/JacksonAllan/CC/blob/main/articles/Better_C_Generics_Part_1_The_Extendible_Generic.md {___/
// Since gencpp is used to generate the c-library, it was choosen over the more novel implementations to keep the macros as easy to understand and unobfuscated as possible.
#define GEN_COMMA_OPERATOR , // The comma operator is used by preprocessor macros to delimit arguments, so we have to represent it via a macro to prevent parsing incorrectly.
// Helper macros for argument selection
#define GEN_SELECT_ARG_1( _1, ... ) _1 // <-- Of all th args passed pick _1.
#define GEN_SELECT_ARG_2( _1, _2, ... ) _2 // <-- Of all the args passed pick _2.
#define GEN_SELECT_ARG_3( _1, _2, _3, ... ) _3 // etc..
#define GEN_GENERIC_SEL_ENTRY_TYPE GEN_SELECT_ARG_1 // Use the arg expansion macro to select arg 1 which should have the type.
#define GEN_GENERIC_SEL_ENTRY_FUNCTION GEN_SELECT_ARG_2 // Use the arg expansion macro to select arg 2 which should have the function.
#define GEN_GENERIC_SEL_ENTRY_COMMA_DELIMITER GEN_SELECT_ARG_3 // Use the arg expansion macro to select arg 3 which should have the comma delimiter ','.
#define GEN_RESOLVED_FUNCTION_CALL // Just used to indicate where the call "occurs"
// ----------------------------------------------------------------------------------------------------------------------------------
// GEN_IF_MACRO_DEFINED_INCLUDE_THIS_SLOT( macro ) includes a _Generic slot only if the specified macro is defined (as type, function_name).
// It takes advantage of the fact that if the macro is defined, then the expanded text will contain a comma.
// Expands to ',' if it can find (type): (function) <comma_operator: ',' >
// Where GEN_GENERIC_SEL_ENTRY_COMMA_DELIMITER is specifically looking for that <comma> ,
#define GEN_IF_MACRO_DEFINED_INCLUDE_THIS_SLOT( slot_exp ) GEN_GENERIC_SEL_ENTRY_COMMA_DELIMITER( slot_exp, GEN_GENERIC_SEL_ENTRY_TYPE( slot_exp, ): GEN_GENERIC_SEL_ENTRY_FUNCTION( slot_exp, ) GEN_COMMA_OPERATOR, , )
// ^ Selects the comma ^ is the type ^ is the function ^ Insert a comma
// The slot won't exist if that comma is not found. |
// For the occastion where an expression didn't resolve to a selection option the "default: <value>" will be set to:
typedef struct GENCPP_NO_RESOLVED_GENERIC_SELECTION GENCPP_NO_RESOLVED_GENERIC_SELECTION;
struct GENCPP_NO_RESOLVED_GENERIC_SELECTION {
void* _THE_VOID_SLOT_;
};
GENCPP_NO_RESOLVED_GENERIC_SELECTION const gen_generic_selection_fail = {0};
// Which will provide the message: error: called object type 'struct NO_RESOLVED_GENERIC_SELECTION' is not a function or function pointer
// ----------------------------------------------------------------------------------------------------------------------------------
// Below are generated on demand for an overlaod depdendent on a type:
// ----------------------------------------------------------------------------------------------------------------------------------
#define GEN_FUNCTION_GENERIC_EXAMPLE( selector_arg ) _Generic( \
(selector_arg), /* Select Via Expression*/ \
/* Extendibility slots: */ \
GEN_IF_MACRO_DEFINED_INCLUDE_THIS_SLOT( FunctionID__ARGS_SIG_1 ) \
GEN_IF_MACRO_DEFINED_INCLUDE_THIS_SLOT( FunctionID__ARGS_SIG_1 ) \
default: gen_generic_selection_fail \
) GEN_RESOLVED_FUNCTION_CALL( selector_arg )
// ----------------------------------------------------------------------------------------------------------------------------------
// Then each definiton of a function has an associated define:
#// #define GENERIC_SLOT_<#>_<generic identifier> <typename>, <function_to_resolve>
// Then somehwere later on
// <etc> <return_type> <function_id> ( <arguments> ) { <implementation> }
// Concrete example:
// To add support for long:
#define GENERIC_SLOT_1_gen_example_hash long, gen_example_hash__P_long
size_t gen_example_hash__P_long( long val ) { return val * 2654435761ull; }
// To add support for long long:
#define GENERIC_SLOT_2_gen_example_hash long long, gen_example_hash__P_long_long
size_t gen_example_hash__P_long_long( long long val ) { return val * 2654435761ull; }
// If using an Editor with support for syntax hightlighting macros: HASH__ARGS_SIG_1 and HASH_ARGS_SIG_2 should show color highlighting indicating the slot is enabled,
// or, "defined" for usage during the compilation pass that handles the _Generic instrinsic.
#define gen_hash_example( function_arguments ) _Generic( \
(function_arguments), /* Select Via Expression*/ \
/* Extendibility slots: */ \
GEN_IF_MACRO_DEFINED_INCLUDE_THIS_SLOT( HASH__ARGS_SIG_1 ) \
GEN_IF_MACRO_DEFINED_INCLUDE_THIS_SLOT( HASH__ARGS_SIG_2 ) \
GEN_IF_MACRO_DEFINED_INCLUDE_THIS_SLOT( HASH__ARGS_SIG_3 ) \
GEN_IF_MACRO_DEFINED_INCLUDE_THIS_SLOT( HASH__ARGS_SIG_4 ) \
GEN_IF_MACRO_DEFINED_INCLUDE_THIS_SLOT( HASH__ARGS_SIG_5 ) \
GEN_IF_MACRO_DEFINED_INCLUDE_THIS_SLOT( HASH__ARGS_SIG_6 ) \
GEN_IF_MACRO_DEFINED_INCLUDE_THIS_SLOT( HASH__ARGS_SIG_7 ) \
GEN_IF_MACRO_DEFINED_INCLUDE_THIS_SLOT( HASH__ARGS_SIG_8 ) \
default: gen_generic_selection_fail \
) GEN_RESOLVED_FUNCTION_CALL( function_arguments )
// Additional Variations:
// If the function takes more than one argument the following is used:
#define GEN_FUNCTION_GENERIC_EXAMPLE_VARADIC( selector_arg, ... ) _Generic( \
(selector_arg), \
GEN_IF_MACRO_DEFINED_INCLUDE_THIS_SLOT( FunctionID__ARGS_SIG_1 ) \
GEN_IF_MACRO_DEFINED_INCLUDE_THIS_SLOT( FunctionID__ARGS_SIG_2 ) \
/* ... */ \
GEN_IF_MACRO_DEFINED_INCLUDE_THIS_SLOT(FunctionID__ARGS_SIG_N ) \
default: gen_generic_selection_fail \
) GEN_RESOLVED_FUNCTION_CALL( selector_arg, __VA_ARG__ )
// If the function does not take the arugment as a parameter:
#define GEN_FUNCTION_GENERIC_EXAMPLE_DIRECT_TYPE( selector_arg ) _Generic( \
( GEN_TYPE_TO_EXP(selector_arg) ), \
GEN_IF_MACRO_DEFINED_INCLUDE_THIS_SLOT( FunctionID__ARGS_SIG_1 ) \
GEN_IF_MACRO_DEFINED_INCLUDE_THIS_SLOT( FunctionID__ARGS_SIG_2 ) \
/* ... */ \
GEN_IF_MACRO_DEFINED_INCLUDE_THIS_SLOT(FunctionID__ARGS_SIG_N ) \
default: gen_generic_selection_fail \
) GEN_RESOLVED_FUNCTION_CALL()
// Used to keep the _Generic keyword happy as bare types are not considered "expressions"
#define GEN_TYPE_TO_EXP(type) (* (type*)NULL)
// Instead of using this macro, you'll see it directly expanded by the code generation.
// typedef void* GEN_GenericExampleType;
// GEN_FUNCTION_GENERIC_EXAMPLE_DIRECT_TYPE( GEN_GenericExampleType );
#pragma endregion _Generic Macros

9
gen_c_library/components/header_seg_includes.h Normal file
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#if ! defined(GEN_DONT_ENFORCE_GEN_TIME_GUARD) && ! defined(GEN_TIME)
# error Gen.h : GEN_TIME not defined
#endif
//! If its desired to roll your own dependencies, define GEN_ROLL_OWN_DEPENDENCIES before including this file.
// Dependencies are derived from the c-zpl library: https://github.com/zpl-c/zpl
#ifndef GEN_ROLL_OWN_DEPENDENCIES
# include "gen.dep.h"
#endif

24
gen_c_library/components/header_start.hpp Normal file
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/*
gencpp: An attempt at "simple" staged metaprogramming for c/c++.
See Readme.md for more information from the project repository.
Public Address:
https://github.com/Ed94/gencpp ---------------------------------------------------------------.
| _____ _____ _ _ ___ __ __ |
| / ____) / ____} | | | / ,__} / | / | |
| | / ___ ___ _ __ ___ _ __ _ __ | {___ | l_ __ _ __ _, ___ __| | | | '-l | '-l | |
| | |{_ \/ __\ '_ \ / __} '_ l| '_ l \___ \| __/ _` |/ _` |/ __\/ _` | | | | | | | |
| | l__j | ___/ | | | {__; ;_l } ;_l } ____} | l| (_} | {_| | ___j {_; | | l___ _J l_ _J l_ |
| \_____|\___}_l |_|\___} .__/| .__/ {_____/ \__\__/_l\__. |\___/\__,_l \____}{_____}{_____} |
| | | | | __} | |
| l_l l_l {___/ |
! ----------------------------------------------------------------------- VERSION: v0.20-Alpha |
! ============================================================================================= |
! WARNING: THIS IS AN ALPHA VERSION OF THE LIBRARY, USE AT YOUR OWN DISCRETION |
! NEVER DO CODE GENERATION WITHOUT AT LEAST HAVING CONTENT IN A CODEBASE UNDER VERSION CONTROL |
! ============================================================================================= /
*/
#if ! defined(GEN_DONT_ENFORCE_GEN_TIME_GUARD) && ! defined(GEN_TIME)
# error Gen.hpp : GEN_TIME not defined
#endif

151
gen_c_library/components/memory.fixed_arena.hpp Normal file
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#pragma once
#include "gen.hpp"
using namespace gen;
CodeBody gen_fixed_arenas()
{
CodeBody result = def_body(CT_Global_Body);
result.append(def_pragma(txt("region FixedArena")));
char const* template_struct = stringize(
struct FixedArena_<Name>
{
char memory[<Size>];
Arena arena;
};
typedef struct FixedArena_<Name> FixedArena_<Name>;
);
char const* template_interface = stringize(
inline
void fixed_arena_init_<Name>(FixedArena_<Name>* result)
{
result->arena = arena_init_from_memory(& result->memory[0], <Size>);
}
inline
ssize fixed_arena_size_remaining_<Name>(FixedArena_<Name>* fixed_arena, ssize alignment)
{
return arena_size_remaining( & fixed_arena->arena, alignment);
}
inline
void fixed_arena_free_<Name>(FixedArena_<Name>* fixed_arena) {
arena_free( & fixed_arena->arena);
}
);
CodeBody arena_struct_1kb = parse_global_body( token_fmt_impl( 3, "Name", txt("1KB"), "Size", txt("kilobytes(1)"), template_struct ));
CodeBody arena_struct_4kb = parse_global_body( token_fmt_impl( 3, "Name", txt("4KB"), "Size", txt("kilobytes(4)"), template_struct ));
CodeBody arena_struct_8kb = parse_global_body( token_fmt_impl( 3, "Name", txt("8KB"), "Size", txt("kilobytes(8)"), template_struct ));
CodeBody arena_struct_16kb = parse_global_body( token_fmt_impl( 3, "Name", txt("16KB"), "Size", txt("kilobytes(16)"), template_struct ));
CodeBody arena_struct_32kb = parse_global_body( token_fmt_impl( 3, "Name", txt("32KB"), "Size", txt("kilobytes(32)"), template_struct ));
CodeBody arena_struct_64kb = parse_global_body( token_fmt_impl( 3, "Name", txt("64KB"), "Size", txt("kilobytes(64)"), template_struct ));
CodeBody arena_struct_128kb = parse_global_body( token_fmt_impl( 3, "Name", txt("128KB"), "Size", txt("kilobytes(128)"), template_struct ));
CodeBody arena_struct_256kb = parse_global_body( token_fmt_impl( 3, "Name", txt("256KB"), "Size", txt("kilobytes(256)"), template_struct ));
CodeBody arena_struct_512kb = parse_global_body( token_fmt_impl( 3, "Name", txt("512KB"), "Size", txt("kilobytes(512)"), template_struct ));
CodeBody arena_struct_1mb = parse_global_body( token_fmt_impl( 3, "Name", txt("1MB"), "Size", txt("megabytes(1)"), template_struct ));
CodeBody arena_struct_2mb = parse_global_body( token_fmt_impl( 3, "Name", txt("2MB"), "Size", txt("megabytes(2)"), template_struct ));
CodeBody arena_struct_4mb = parse_global_body( token_fmt_impl( 3, "Name", txt("4MB"), "Size", txt("megabytes(4)"), template_struct ));
CodeBody arena_interface_1kb = parse_global_body( token_fmt_impl( 3, "Name", txt("1KB"), "Size", txt("kilobytes(1)"), template_interface ));
CodeBody arena_interface_4kb = parse_global_body( token_fmt_impl( 3, "Name", txt("4KB"), "Size", txt("kilobytes(4)"), template_interface ));
CodeBody arena_interface_8kb = parse_global_body( token_fmt_impl( 3, "Name", txt("8KB"), "Size", txt("kilobytes(8)"), template_interface ));
CodeBody arena_interface_16kb = parse_global_body( token_fmt_impl( 3, "Name", txt("16KB"), "Size", txt("kilobytes(16)"), template_interface ));
CodeBody arena_interface_32kb = parse_global_body( token_fmt_impl( 3, "Name", txt("32KB"), "Size", txt("kilobytes(32)"), template_interface ));
CodeBody arena_interface_64kb = parse_global_body( token_fmt_impl( 3, "Name", txt("64KB"), "Size", txt("kilobytes(64)"), template_interface ));
CodeBody arena_interface_128kb = parse_global_body( token_fmt_impl( 3, "Name", txt("128KB"), "Size", txt("kilobytes(128)"), template_interface ));
CodeBody arena_interface_256kb = parse_global_body( token_fmt_impl( 3, "Name", txt("256KB"), "Size", txt("kilobytes(256)"), template_interface ));
CodeBody arena_interface_512kb = parse_global_body( token_fmt_impl( 3, "Name", txt("512KB"), "Size", txt("kilobytes(512)"), template_interface ));
CodeBody arena_interface_1mb = parse_global_body( token_fmt_impl( 3, "Name", txt("1MB"), "Size", txt("megabytes(1)"), template_interface ));
CodeBody arena_interface_2mb = parse_global_body( token_fmt_impl( 3, "Name", txt("2MB"), "Size", txt("megabytes(2)"), template_interface ));
CodeBody arena_interface_4mb = parse_global_body( token_fmt_impl( 3, "Name", txt("4MB"), "Size", txt("megabytes(4)"), template_interface ));
result.append(arena_struct_1kb);
result.append(arena_struct_4kb);
result.append(arena_struct_8kb);
result.append(arena_struct_16kb);
result.append(arena_struct_32kb);
result.append(arena_struct_64kb);
result.append(arena_struct_128kb);
result.append(arena_struct_256kb);
result.append(arena_struct_512kb);
result.append(arena_struct_1mb);
result.append(arena_struct_2mb);
result.append(arena_struct_4mb);
result.append(arena_interface_1kb);
result.append(arena_interface_4kb);
result.append(arena_interface_8kb);
result.append(arena_interface_16kb);
result.append(arena_interface_32kb);
result.append(arena_interface_64kb);
result.append(arena_interface_128kb);
result.append(arena_interface_256kb);
result.append(arena_interface_512kb);
result.append(arena_interface_1mb);
result.append(arena_interface_2mb);
result.append(arena_interface_4mb);
CodeDefine def = def_define(txt("fixed_arena_allocator_info(fixed_arena)"), txt("( (AllocatorInfo) { arena_allocator_proc, & (fixed_arena)->arena } )"));
result.append(def);
result.append(fmt_newline);
result.append(parse_global_body(txt(R"(
#define fixed_arena_init(expr) _Generic((expr), \
FixedArena_1KB* : fixed_arena_init_1KB, \
FixedArena_4KB* : fixed_arena_init_4KB, \
FixedArena_8KB* : fixed_arena_init_8KB, \
FixedArena_16KB* : fixed_arena_init_16KB, \
FixedArena_32KB* : fixed_arena_init_32KB, \
FixedArena_64KB* : fixed_arena_init_64KB, \
FixedArena_128KB* : fixed_arena_init_128KB, \
FixedArena_256KB* : fixed_arena_init_256KB, \
FixedArena_512KB* : fixed_arena_init_512KB, \
FixedArena_1MB* : fixed_arena_init_1MB, \
FixedArena_2MB* : fixed_arena_init_2MB, \
FixedArena_4MB* : fixed_arena_init_4MB, \
default : gen_generic_selection_fail \
) GEN_RESOLVED_FUNCTION_CALL(expr)
#define fixed_arena_free(expr) _Generic((expr), \
FixedArena_1KB* : fixed_arena_free_1KB, \
FixedArena_4KB* : fixed_arena_free_4KB, \
FixedArena_8KB* : fixed_arena_free_8KB, \
FixedArena_16KB* : fixed_arena_free_16KB, \
FixedArena_32KB* : fixed_arena_free_32KB, \
FixedArena_64KB* : fixed_arena_free_64KB, \
FixedArena_128KB* : fixed_arena_free_128KB, \
FixedArena_256KB* : fixed_arena_free_256KB, \
FixedArena_512KB* : fixed_arena_free_512KB, \
FixedArena_1MB* : fixed_arena_free_1MB, \
FixedArena_2MB* : fixed_arena_free_2MB, \
FixedArena_4MB* : fixed_arena_free_4MB, \
default : gen_generic_selection_fail \
) GEN_RESOLVED_FUNCTION_CALL(expr)
#define fixed_arena_size_remaining(expr, alignment) _Generic((expr), \
FixedArena_1KB* : fixed_arena_size_remaining_1KB, \
FixedArena_4KB* : fixed_arena_size_remaining_4KB, \
FixedArena_8KB* : fixed_arena_size_remaining_8KB, \
FixedArena_16KB* : fixed_arena_size_remaining_16KB, \
FixedArena_32KB* : fixed_arena_size_remaining_32KB, \
FixedArena_64KB* : fixed_arena_size_remaining_64KB, \
FixedArena_128KB* : fixed_arena_size_remaining_128KB, \
FixedArena_256KB* : fixed_arena_size_remaining_256KB, \
FixedArena_512KB* : fixed_arena_size_remaining_512KB, \
FixedArena_1MB* : fixed_arena_size_remaining_1MB, \
FixedArena_2MB* : fixed_arena_size_remaining_2MB, \
FixedArena_4MB* : fixed_arena_size_remaining_4MB, \
default : gen_generic_selection_fail \
) GEN_RESOLVED_FUNCTION_CALL(expr, alignment)
)"
)));
result.append(fmt_newline);
result.append(def_pragma(txt("endregion FixedArena")));
return result;
}

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#pragma once
#include "gen.hpp"
using namespace gen;
void convert_cpp_enum_to_c( CodeEnum to_convert, CodeBody to_append )
{
#pragma push_macro("enum_underlying")
#undef enum_underlying
if (to_convert->UnderlyingType)
{
to_convert->UnderlyingTypeMacro = untyped_str(token_fmt("type", to_convert->UnderlyingType->Name, stringize(enum_underlying(<type>))));
to_convert->UnderlyingType = CodeTypename{nullptr};
}
CodeTypedef tdef = parse_typedef(token_fmt("name", to_convert->Name, stringize( typedef enum <name> <name>; )));
to_append.append(to_convert);
to_append.append(tdef);
#pragma pop_macro("enum_underlying")
}
b32 ignore_preprocess_cond_block( StrC cond_sig, Code& entry_iter, CodeBody& parsed_body, CodeBody& body )
{
b32 found = false;
CodePreprocessCond cond = cast(CodePreprocessCond, entry_iter);
if ( cond->Content.is_equal(cond_sig) )
{
//log_fmt("Preprocess cond found: %SC\n", cond->Content);
found = true;
s32 depth = 1;
++ entry_iter;
for(b32 continue_for = true; continue_for && entry_iter != parsed_body.end(); ) switch
(entry_iter->Type) {
case CT_Preprocess_If:
case CT_Preprocess_IfDef:
case CT_Preprocess_IfNotDef:
++ depth;
++ entry_iter;
break;
case CT_Preprocess_Else:
++ entry_iter;
for(; continue_for && entry_iter != parsed_body.end(); ++ entry_iter)
{
if (entry_iter->Type == CT_Preprocess_EndIf)
{
continue_for = false;
break;
}
body.append(entry_iter);
}
break;
case CT_Preprocess_EndIf:
{
depth --;
if (depth == 0) {
continue_for = false;
break;
}
++ entry_iter;
}
break;
default:
++ entry_iter;
break;
}
}
return found;
}
constexpr bool GenericSel_One_Arg = true;
enum GenericSelectionOpts : u32 { GenericSel_Default, GenericSel_By_Ref, GenericSel_Direct_Type };
Code gen_generic_selection_function_macro( s32 num_slots, StrC macro_name, GenericSelectionOpts opts = GenericSel_Default, bool one_arg = false )
{
/* Implements:
#define GEN_FUNCTION_GENERIC_EXAMPLE( selector_arg, ... ) _Generic( \
(selector_arg), \
GEN_IF_MACRO_DEFINED_INCLUDE_THIS_SLOT( FunctionID__ARGS_SIG_1 ) \
GEN_IF_MACRO_DEFINED_INCLUDE_THIS_SLOT( FunctionID__ARGS_SIG_2 ) \
... \
GEN_IF_MACRO_DEFINED_INCLUDE_THIS_SLOT_LAST(FunctionID__ARGS_SIG_N ) \
) GEN_RESOLVED_FUNCTION_CALL( selector_arg )
*/
local_persist
String define_builder = String::make_reserve(GlobalAllocator, kilobytes(64));
define_builder.clear();
StrC macro_begin;
if (opts == GenericSel_Direct_Type) {
macro_begin = token_fmt( "macro_name", (StrC)macro_name,
R"(#define <macro_name>(selector_arg, ...) _Generic( (*(selector_arg*)NULL ), \
)"
);
}
else {
macro_begin = token_fmt( "macro_name", (StrC)macro_name,
R"(#define <macro_name>(selector_arg, ...) _Generic( (selector_arg), \
)"
);
}
define_builder.append(macro_begin);
for ( s32 slot = 1; slot <= num_slots; ++ slot )
{
StrC slot_str = String::fmt_buf(GlobalAllocator, "%d", slot).to_strc();
if (slot == num_slots && false)
{
define_builder.append( token_fmt( "macro_name", macro_name, "slot", slot_str,
R"( GEN_IF_MACRO_DEFINED_INCLUDE_THIS_SLOT_LAST( GENERIC_SLOT_<slot>__<macro_name> ) \
)"
));
// if ( one_arg )
// define_builder.append(token_fmt( "macro_name", macro_name, stringize(
// default: static_assert(false, "<macro_name>: Failed to select correct function signature (Did you pass the type?)")
// )));
// else
// define_builder.append(token_fmt( "macro_name", macro_name, stringize(
// default: static_assert(false, "<macro_name>: Failed to select correct function signature")
// )));
continue;
}
define_builder.append( token_fmt( "macro_name", macro_name, "slot", slot_str,
R"( GEN_IF_MACRO_DEFINED_INCLUDE_THIS_SLOT( GENERIC_SLOT_<slot>__<macro_name> ) \
)"
));
}
define_builder.append( txt("default: gen_generic_selection_fail") );
if ( ! one_arg )
{
if (opts == GenericSel_By_Ref)
define_builder.append(txt("\t)\tGEN_RESOLVED_FUNCTION_CALL( & selector_arg, __VA_ARGS__ )"));
else if (opts == GenericSel_Direct_Type)
define_builder.append(txt("\t)\tGEN_RESOLVED_FUNCTION_CALL( __VA_ARGS__ )"));
else
define_builder.append(txt("\t)\tGEN_RESOLVED_FUNCTION_CALL( selector_arg, __VA_ARGS__ )"));
}
else
{
if (opts == GenericSel_By_Ref)
define_builder.append(txt("\t)\tGEN_RESOLVED_FUNCTION_CALL( & selector_arg )"));
else if (opts == GenericSel_Direct_Type)
define_builder.append(txt("\t)\tGEN_RESOLVED_FUNCTION_CALL()"));
else
define_builder.append(txt("\t)\tGEN_RESOLVED_FUNCTION_CALL( selector_arg )"));
}
// Add gap for next definition
define_builder.append(txt("\n\n"));
Code macro = untyped_str(define_builder.to_strc());
return macro;
}
CodeFn rename_function_to_unique_symbol(CodeFn fn, StrC optional_prefix = txt(""))
{
// Get basic components for the name
StrC old_name = fn->Name;
String new_name;
// Add prefix if provided
if (optional_prefix.Len)
new_name = string_fmt_buf(GlobalAllocator, "%SC_%SC_", optional_prefix, old_name);
else
new_name = string_fmt_buf(GlobalAllocator, "%SC_", old_name);
// Add return type to the signature
if (fn->ReturnType)
new_name.append_fmt("_%SC", fn->ReturnType->Name);
// Add parameter types to create a unique signature
bool first_param = true;
for (CodeParams param = fn->Params; param.ast; param = param->Next)
{
if (param->ValueType)
{
// Add separator for readability
if (first_param)
{
new_name.append("_P_");
first_param = false;
}
else
new_name.append("_");
// Add parameter type, handle any specifiers
if (param->ValueType->Specs && param->ValueType->Specs->NumEntries > 0)
{
// Add specifiers (const, volatile, etc)
for (Specifier spec : param->ValueType->Specs)
{
if (spec == Spec_Ptr) {
new_name.append("ptr_");
continue;
}
new_name.append_fmt("%SC_", spec_to_str(spec));
}
}
new_name.append_fmt("%SC", param->ValueType->Name);
}
}
// Handle function specifiers if present
if (fn->Specs && fn->Specs->NumEntries > 0)
{
new_name.append("_S_");
for (Specifier* spec = begin(fn->Specs);
spec != end(fn->Specs);
++spec)
{
new_name.append_fmt("%SC_", spec_to_str(*spec));
}
}
fn->Name = new_name;
return fn;
}
using SwapContentProc = CodeBody(void);
bool swap_pragma_region_implementation( StrC region_name, SwapContentProc* swap_content, Code& entry_iter, CodeBody& body )
{
bool found = false;
CodePragma possible_region = cast(CodePragma, entry_iter);
String region_sig = string_fmt_buf(GlobalAllocator, "region %s", region_name.Ptr);
String endregion_sig = string_fmt_buf(GlobalAllocator, "endregion %s", region_name.Ptr);
if ( possible_region->Content.contains(region_sig))
{
found = true;
// body.append(possible_region);
body.append(swap_content());
++ entry_iter;
for(b32 continue_for = true; continue_for; ++entry_iter) switch
(entry_iter->Type) {
case CT_Preprocess_Pragma:
{
CodePragma possible_end_region = cast(CodePragma, entry_iter);
if ( possible_end_region->Content.contains(endregion_sig) ) {
// body.append(possible_end_region);
continue_for = false;
}
}
break;
}
body.append(entry_iter);
}
return found;
}

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#if ! defined(GEN_DONT_ENFORCE_GEN_TIME_GUARD) && ! defined(GEN_TIME)
# error Gen.hpp : GEN_TIME not defined
#endif
#include "gen.h"
//! If its desired to roll your own dependencies, define GEN_ROLL_OWN_DEPENDENCIES before including this file.
//! Dependencies are derived from the c-zpl library: https://github.com/zpl-c/zpl
#ifndef GEN_ROLL_OWN_DEPENDENCIES
# include "gen.dep.c"
#endif

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#define GEN_IMPLEMENTATION
#include "gen/gen.c"
int main()
{
// init();
__debugbreak();
}

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## Navigation
# base
[Top](../Readme.md)
* [docs](../docs/Readme.md)
# Segemented Library Generation
The principal (user) files are `gen.hpp` and `gen.cpp`.
They contain includes for its various components: `components/<component_name>.<hpp/cpp>`
Dependencies are bundled into `gen.dep.<hpp/cpp>`. They are included in `gen.<hpp/cpp>` before component includes.
Just like the `gen.<hpp/cpp>` they include their components: `dependencies/<dependency_name>.<hpp/cpp>`
If using the library's provided build scripts:
```ps1
.\build.ps1 <compiler> <debug or omit> segmented
```

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// Includes are exposed to base directory
#define GEN_DEFINE_LIBRARY_CODE_CONSTANTS
#define GEN_ENFORCE_STRONG_CODE_TYPES
#define GEN_EXPOSE_BACKEND
#define GEN_C_LIKE_CPP 1
#include "gen.cpp"
#include "helpers/push_ignores.inline.hpp"
#include <stdlib.h>
GEN_NS_BEGIN
#include "helpers/base_codegen.hpp"
#include "helpers/misc.hpp"
GEN_NS_END
using namespace gen;
constexpr char const* generation_notice =
"// This file was generated automatially by gencpp's bootstrap.cpp "
"(See: https://github.com/Ed94/gencpp)\n\n";
#include <cstdlib> // for system()
#define path_format_style "../scripts/.clang-format "
#define scratch_file "gen/scratch.hpp"
#define path_base "../base/"
Code format( Code code ) {
return code_refactor_and_format(code, scratch_file, nullptr, path_format_style );
}
int gen_main()
{
gen::init();
Code push_ignores = scan_file( (path_base "helpers/push_ignores.inline.hpp") );
Code pop_ignores = scan_file( (path_base "helpers/pop_ignores.inline.hpp") );
// gen_dep.hpp
{
Code platform = scan_file( path_base "dependencies/platform.hpp" );
Code macros = scan_file( path_base "dependencies/macros.hpp" );
Code basic_types = scan_file( path_base "dependencies/basic_types.hpp" );
Code debug = scan_file( path_base "dependencies/debug.hpp" );
Code memory = scan_file( path_base "dependencies/memory.hpp" );
Code string_ops = scan_file( path_base "dependencies/string_ops.hpp" );
Code printing = scan_file( path_base "dependencies/printing.hpp" );
Code containers = scan_file( path_base "dependencies/containers.hpp" );
Code hashing = scan_file( path_base "dependencies/hashing.hpp" );
Code strings = scan_file( path_base "dependencies/strings.hpp" );
Code filesystem = scan_file( path_base "dependencies/filesystem.hpp" );
Code timing = scan_file( path_base "dependencies/timing.hpp" );
Code parsing = scan_file( path_base "dependencies/parsing.hpp" );
Builder _header = builder_open( "gen/gen.dep.hpp");
Builder* header = & _header;
builder_print_fmt( header, generation_notice );
builder_print_fmt( header, "// This file is intended to be included within gen.hpp (There is no pragma diagnostic ignores)\n" );
builder_print( header, platform );
builder_print_fmt( header, "\nGEN_NS_BEGIN\n" );
builder_print( header, macros );
builder_print( header, basic_types );
builder_print( header, debug );
builder_print( header, memory );
builder_print( header, string_ops );
builder_print( header, printing );
builder_print( header, containers );
builder_print( header, hashing );
builder_print( header, strings );
builder_print( header, filesystem );
builder_print( header, timing );
builder_print( header, parsing );
builder_print_fmt( header, "\nGEN_NS_END\n" );
builder_write(header);
}
// gen_dep.cpp
{
Code src_start = scan_file( path_base "dependencies/src_start.cpp" );
Code debug = scan_file( path_base "dependencies/debug.cpp" );
Code string_ops = scan_file( path_base "dependencies/string_ops.cpp" );
Code printing = scan_file( path_base "dependencies/printing.cpp" );
Code memory = scan_file( path_base "dependencies/memory.cpp" );
Code hashing = scan_file( path_base "dependencies/hashing.cpp" );
Code strings = scan_file( path_base "dependencies/strings.cpp" );
Code filesystem = scan_file( path_base "dependencies/filesystem.cpp" );
Code timing = scan_file( path_base "dependencies/timing.cpp" );
Code parsing = scan_file( path_base "dependencies/parsing.cpp" );
Builder _src = builder_open( "gen/gen.dep.cpp" );
Builder* src = & _src;
builder_print_fmt(src, generation_notice );
builder_print_fmt( src, "// This file is intended to be included within gen.cpp (There is no pragma diagnostic ignores)\n" );
builder_print( src, src_start );
builder_print_fmt( src, "\nGEN_NS_BEGIN\n" );
builder_print( src, debug );
builder_print( src, string_ops );
builder_print( src, printing );
builder_print( src, hashing );
builder_print( src, memory );
builder_print( src, strings );
builder_print( src, filesystem );
builder_print( src, timing );
builder_print( src, parsing );
builder_print_fmt( src, "\nGEN_NS_END\n" );
builder_write(src);
}
CodeBody gen_component_header = def_global_body( args(
def_preprocess_cond( PreprocessCond_IfDef, txt("GEN_INTELLISENSE_DIRECTIVES") ),
pragma_once,
def_include(txt("components/types.hpp")),
preprocess_endif,
fmt_newline,
untyped_str( to_strc_from_c_str(generation_notice) )
));
// gen.hpp
{
Code header_start = scan_file( path_base "components/header_start.hpp" );
Code types = scan_file( path_base "components/types.hpp" );
Code ast = scan_file( path_base "components/ast.hpp" );
Code ast_types = scan_file( path_base "components/ast_types.hpp" );
Code code_types = scan_file( path_base "components/code_types.hpp" );
Code interface = scan_file( path_base "components/interface.hpp" );
Code inlines = scan_file( path_base "components/inlines.hpp" );
Code header_end = scan_file( path_base "components/header_end.hpp" );
CodeBody ecode = gen_ecode ( path_base "enums/ECodeTypes.csv" );
CodeBody eoperator = gen_eoperator ( path_base "enums/EOperator.csv" );
CodeBody especifier = gen_especifier( path_base "enums/ESpecifier.csv" );
CodeBody ast_inlines = gen_ast_inlines();
Builder _header = builder_open( "gen/gen.hpp" );
Builder* header = & _header;
builder_print_fmt( header, generation_notice );
builder_print_fmt( header, "#pragma once\n\n" );
builder_print( header, push_ignores );
builder_print( header, header_start );
builder_print_fmt( header, "\nGEN_NS_BEGIN\n\n" );
builder_print_fmt(header, "#pragma region Types\n" );
builder_print( header, types );
builder_print( header, fmt_newline);
builder_print( header, format(ecode) );
builder_print( header, fmt_newline);
builder_print( header, format(eoperator) );
builder_print( header, fmt_newline);
builder_print( header, format(especifier) );
builder_print( header, fmt_newline);
builder_print_fmt( header, "#pragma endregion Types\n\n" );
builder_print_fmt( header, "#pragma region AST\n" );
builder_print( header, ast );
builder_print( header, code_types );
builder_print( header, ast_types );
builder_print_fmt( header, "\n#pragma endregion AST\n" );
builder_print( header, interface );
builder_print_fmt( header, "\n#pragma region Inlines\n" );
builder_print( header, inlines );
builder_print( header, fmt_newline );
builder_print( header, format(ast_inlines) );
builder_print( header, fmt_newline );
builder_print_fmt( header, "#pragma endregion Inlines\n" );
builder_print( header, header_end );
builder_print_fmt( header, "GEN_NS_END\n\n" );
builder_print( header, pop_ignores );
builder_write(header);
}
// gen.cpp
{
Code src_start = scan_file( path_base "components/src_start.cpp" );
Code static_data = scan_file( path_base "components/static_data.cpp" );
Code ast_case_macros = scan_file( path_base "components/ast_case_macros.cpp" );
Code ast = scan_file( path_base "components/ast.cpp" );
Code code_serialization = scan_file( path_base "components/code_serialization.cpp" );
Code interface = scan_file( path_base "components/interface.cpp" );
Code upfront = scan_file( path_base "components/interface.upfront.cpp" );
Code lexer = scan_file( path_base "components/lexer.cpp" );
Code parser = scan_file( path_base "components/parser.cpp" );
Code parsing_interface = scan_file( path_base "components/interface.parsing.cpp" );
Code untyped = scan_file( path_base "components/interface.untyped.cpp" );
CodeBody etoktype = gen_etoktype( path_base "enums/ETokType.csv", path_base "enums/AttributeTokens.csv" );
CodeBody nspaced_etoktype = def_global_body( args(
etoktype
));
Code formatted_toktype = format(nspaced_etoktype);
Builder _src = builder_open( "gen/gen.cpp" );
Builder* src = & _src;
builder_print_fmt( src, generation_notice );
builder_print( src, push_ignores );
builder_print( src, src_start );
builder_print_fmt( src, "\nGEN_NS_BEGIN\n");
builder_print( src, static_data );
builder_print_fmt( src, "\n#pragma region AST\n\n" );
builder_print( src, ast_case_macros );
builder_print( src, ast );
builder_print( src, code_serialization );
builder_print_fmt( src, "\n#pragma endregion AST\n" );
builder_print_fmt( src, "\n#pragma region Interface\n" );
builder_print( src, interface );
builder_print( src, upfront );
builder_print_fmt( src, "\n#pragma region Parsing\n\n" );
builder_print( src, formatted_toktype );
builder_print( src, lexer );
builder_print( src, parser );
builder_print( src, parsing_interface );
builder_print_fmt( src, "\n#pragma endregion Parsing\n\n" );
builder_print( src, untyped );
builder_print_fmt( src, "#pragma endregion Interface\n\n" );
builder_print_fmt( src, "GEN_NS_END\n\n");
builder_print( src, pop_ignores );
builder_write(src);
}
// gen_builder.hpp
{
Code builder = scan_file( path_base "auxillary/builder.hpp" );
Builder header = builder_open( "gen/gen.builder.hpp" );
builder_print_fmt( & header, generation_notice );
builder_print_fmt( & header, "#pragma once\n\n" );
builder_print( & header, def_include( txt("gen.hpp") ));
builder_print_fmt( & header, "\nGEN_NS_BEGIN\n" );
builder_print( & header, builder );
builder_print_fmt( & header, "GEN_NS_END\n" );
builder_write( & header);
}
// gen_builder.cpp
{
Code builder = scan_file( path_base "auxillary/builder.cpp" );
Builder src = builder_open( "gen/gen.builder.cpp" );
builder_print_fmt( & src, generation_notice );
builder_print( & src, def_include( txt("gen.builder.hpp") ) );
builder_print_fmt( & src, "\nGEN_NS_BEGIN\n" );
builder_print( & src, builder );
builder_print_fmt( & src, "\nGEN_NS_END\n" );
builder_write( & src);
}
// gen_scanner.hpp
{
Code scanner = scan_file( path_base "auxillary/scanner.hpp" );
Builder header = builder_open( "gen/gen.scanner.hpp" );
builder_print_fmt( & header, generation_notice );
builder_print_fmt( & header, "#pragma once\n\n" );
builder_print( & header, def_include( txt("gen.hpp") ) );
builder_print_fmt( & header, "\nGEN_NS_BEGIN\n" );
builder_print( & header, scanner );
builder_print_fmt( & header, "\nGEN_NS_END\n" );
builder_write(& header);
}
// gen_scanner.cpp
{
Code scanner = scan_file( path_base "auxillary/scanner.cpp" );
Builder src = builder_open( "gen/gen.scanner.cpp" );
builder_print_fmt( & src, generation_notice );
builder_print( & src, def_include( txt("gen.scanner.hpp") ) );
builder_print_fmt( & src, "\nGEN_NS_BEGIN\n" );
builder_print( & src, scanner );
builder_print_fmt( & src, "GEN_NS_END\n" );
builder_write( & src);
}
gen::deinit();
return 0;
}

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