// // Usage // // GSMetaTag() to give commands to the meta layer // // Tag Values // // breakpoint // will cause the meta layer to break in the debugger when it reaches // that point in processing the file // TODO: specify which stage you want it to break at #include #include #include #include #include "..\src\gs_platform.h" #include #include #include #include "gs_meta_lexer.h" struct error_buffer { char* Backbuffer; string* Contents; }; #define ERROR_MAX_LENGTH 256 #define ERROR_BUFFER_SIZE 256 struct errors { error_buffer* Buffers; u32 BuffersCount; u32 Used; }; internal void PushFError (errors* Errors, char* Format, ...) { if (Errors->Used >= (Errors->BuffersCount * ERROR_BUFFER_SIZE)) { Errors->BuffersCount += 1; Errors->Buffers = (error_buffer*)realloc(Errors->Buffers, sizeof(error_buffer*) * Errors->BuffersCount); error_buffer* NewBuffer = Errors->Buffers + (Errors->BuffersCount - 1); NewBuffer->Backbuffer = (char*)malloc(sizeof(char) * ERROR_MAX_LENGTH * ERROR_BUFFER_SIZE); NewBuffer->Contents = (string*)malloc(sizeof(string) * ERROR_BUFFER_SIZE); for (u32 i = 0; i < ERROR_BUFFER_SIZE; i++) { NewBuffer->Contents[i].Memory = NewBuffer->Backbuffer + (i * ERROR_MAX_LENGTH); NewBuffer->Contents[i].Max = ERROR_MAX_LENGTH; NewBuffer->Contents[i].Length = 0; } } u32 NewErrorIndex = Errors->Used++; u32 BufferIndex = NewErrorIndex / ERROR_BUFFER_SIZE; u32 IndexInBuffer = NewErrorIndex % ERROR_BUFFER_SIZE; string* NewError = Errors->Buffers[BufferIndex].Contents + IndexInBuffer; va_list Args; va_start(Args, Format); NewError->Length = PrintFArgsList(NewError->Memory, NewError->Max, Format, Args); va_end(Args); } internal string* TakeError (errors* Errors) { u32 NewErrorIndex = Errors->Used++; u32 BufferIndex = NewErrorIndex / ERROR_BUFFER_SIZE; u32 IndexInBuffer = NewErrorIndex % ERROR_BUFFER_SIZE; string* NewError = Errors->Buffers[BufferIndex].Contents + IndexInBuffer; return NewError; } internal void PrintAllErrors (errors Errors) { for (u32 i = 0; i < Errors.Used; i++) { u32 BufferIndex = i / ERROR_BUFFER_SIZE; u32 IndexInBuffer = i % ERROR_BUFFER_SIZE; string Error = Errors.Buffers[BufferIndex].Contents[IndexInBuffer]; printf("%.*s\n", StringExpand(Error)); } } #include "foldhaus_meta_type_table.h" PLATFORM_ALLOC(StdAlloc) { u8* Result = (u8*)malloc(Size); return Result; } struct source_code_file { string Path; s32 FileSize; string Contents; s32 FirstTokenIndex; s32 LastTokenIndex; }; struct token_iter { gs_bucket* Tokens; token* TokenAt; s32 TokenAtIndex; s32 FirstToken; s32 LastToken; #define TOKEN_ITER_SNAPSHOTS_MAX 64 u32 SnapshotsUsed; u32 Snapshots[TOKEN_ITER_SNAPSHOTS_MAX]; errors* Errors; }; internal token* NextToken (token_iter* Iter) { if (Iter->TokenAtIndex < Iter->LastToken) { Iter->TokenAtIndex++; Iter->TokenAt = Iter->Tokens->GetElementAtIndex(Iter->TokenAtIndex); } return Iter->TokenAt; } internal b32 TokenAtEquals(token_iter* Iter, char* String) { b32 Result = false; if (StringEqualsCharArray(Iter->TokenAt->Text, String)) { Result = true; NextToken(Iter); } return Result; } internal b32 TokenAtEquals(token_iter* Iter, token_type Type) { b32 Result = false; if (Iter->TokenAt->Type == Type) { Result = true; NextToken(Iter); } return Result; } internal b32 TokenAtEquals(token_iter* Iter, token_type Type, token* Token) { b32 Result = false; if (Iter->TokenAt->Type == Type) { Result = true; *Token = *Iter->TokenAt; NextToken(Iter); } return Result; } internal void PushSnapshot (token_iter* Iter) { Iter->Snapshots[Iter->SnapshotsUsed++] = Iter->TokenAtIndex; } internal void PopSnapshot (token_iter* Iter) { if (Iter->SnapshotsUsed > 0) { Iter->SnapshotsUsed -= 1; } } internal void ApplySnapshot (token_iter* Iter) { u32 SnapshotIndex = Iter->SnapshotsUsed; u32 SnapshotPoint = Iter->Snapshots[SnapshotIndex]; Iter->TokenAtIndex = SnapshotPoint; Iter->TokenAt = Iter->Tokens->GetElementAtIndex(SnapshotPoint); } internal void ApplySnapshotIfNotParsedAndPop(b32 ParseSuccess, token_iter* Iter) { PopSnapshot(Iter); if (!ParseSuccess) { ApplySnapshot(Iter); } } internal s32 GetFileSize (char* FileName) { s32 Result = 0; FILE* ReadFile = fopen(FileName, "r"); if (ReadFile) { fseek(ReadFile, 0, SEEK_END); size_t FileSize = ftell(ReadFile); fseek(ReadFile, 0, SEEK_SET); Result = (s32)FileSize; fclose(ReadFile); } return Result; } internal s32 ReadEntireFileAndNullTerminate (source_code_file* File, errors* Errors) { s32 LengthRead = 0; FILE* ReadFile = fopen(File->Path.Memory, "r"); if (ReadFile) { fseek(ReadFile, 0, SEEK_END); size_t FileSize = ftell(ReadFile); fseek(ReadFile, 0, SEEK_SET); Assert(File->Contents.Memory == 0); File->Contents.Max = (s32)FileSize + 1; File->Contents.Memory = (char*)malloc(File->Contents.Max); size_t ReadSize = fread(File->Contents.Memory, 1, FileSize, ReadFile); File->Contents.Memory[FileSize] = 0; File->Contents.Length = (s32)ReadSize; LengthRead = (s32)ReadSize + 1; fclose(ReadFile); } else { PushFError(Errors, "Could Not Read File: %S", File->Path); } return LengthRead; } internal b32 FileAlreadyInSource(string Path, gs_bucket SourceFiles) { b32 Result = false; for (u32 i = 0; i < SourceFiles.Used; i++) { source_code_file* File = SourceFiles.GetElementAtIndex(i); if (StringsEqual(File->Path, Path)) { Result = true; break; } } return Result; } internal s64 GetWallClock () { LARGE_INTEGER Time; if (!QueryPerformanceCounter(&Time)) { s32 Error = GetLastError(); InvalidCodePath; } return (s64)Time.QuadPart; } internal s64 GetPerformanceFrequency () { LARGE_INTEGER Frequency; if (!QueryPerformanceFrequency(&Frequency)) { s32 Error = GetLastError(); InvalidCodePath; } return (s64)Frequency.QuadPart; } internal r32 GetSecondsElapsed(s64 StartCycles, s64 EndCycles) { s64 Frequency = GetPerformanceFrequency(); r32 SecondsElapsed = (r32)(EndCycles - StartCycles) / (r32)(Frequency); return SecondsElapsed; } internal void AddFileToSource(string RelativePath, gs_bucket* SourceFiles, errors* Errors) { source_code_file File = {0}; File.FirstTokenIndex = -1; File.LastTokenIndex = -1; u32 PathLength = RelativePath.Length + 1; File.Path = MakeString((char*)malloc(sizeof(char) * PathLength), 0, PathLength); CopyStringTo(RelativePath, &File.Path); NullTerminate(&File.Path); File.FileSize = ReadEntireFileAndNullTerminate(&File, Errors); if (File.FileSize > 0) { SourceFiles->PushElementOnBucket(File); } else { PushFError(Errors, "Error: Could not load file %S\n", RelativePath); } } internal void TokenizeFile (source_code_file* File, gs_bucket* Tokens) { tokenizer Tokenizer = {}; Tokenizer.At = File->Contents.Memory; Tokenizer.Memory = File->Contents.Memory; Tokenizer.MemoryLength = File->Contents.Max; token* LastToken = 0; while(AtValidPosition(Tokenizer)) { token NewToken = GetNextToken(&Tokenizer); u32 TokenIndex = Tokens->PushElementOnBucket(NewToken); if (File->FirstTokenIndex < 0) { File->FirstTokenIndex = (s32)TokenIndex; } } File->LastTokenIndex = Tokens->Used - 1; } internal b32 ParseMetaTag(token_iter* Iter, gs_bucket* TagList) { b32 Result = false; PushSnapshot(Iter); if (TokenAtEquals(Iter, "GSMetaTag") && TokenAtEquals(Iter, "(")) { token MetaIdentifier = {0}; if (TokenAtEquals(Iter, Token_Identifier, &MetaIdentifier)) { TagList->PushElementOnBucket(MetaIdentifier); if (StringsEqual(MetaIdentifier.Text, MakeStringLiteral("breakpoint"))) { // NOTE(Peter): This is not a temporary breakpoint. It is // used to be able to break the meta program at specific points // throughout execution __debugbreak(); } if (TokenAtEquals(Iter, ")") && TokenAtEquals(Iter, ";")) { Result = true; } } } ApplySnapshotIfNotParsedAndPop(Result, Iter); return Result; } internal b32 ShortInt (token_iter* Iter, s32* TypeIndexOut, type_table TypeTable) { b32 Result = false; PushSnapshot(Iter); if (TokenAtEquals(Iter, "unsigned") || TokenAtEquals(Iter, "signed")) { } if (TokenAtEquals(Iter, "short")) { Result = true; if (TokenAtEquals(Iter, "int")) { Result = true; } } ApplySnapshotIfNotParsedAndPop(Result, Iter); if (Result) { *TypeIndexOut = GetIndexOfType(MakeStringLiteral("short int"), TypeTable); } return Result; } internal b32 Int (token_iter* Iter, s32* TypeIndexOut, type_table TypeTable) { b32 Result = false; PushSnapshot(Iter); if (TokenAtEquals(Iter, "unsigned") || TokenAtEquals(Iter, "signed")) { } if (TokenAtEquals(Iter, "int")) { Result = true; } ApplySnapshotIfNotParsedAndPop(Result, Iter); if (Result) { *TypeIndexOut = GetIndexOfType(MakeStringLiteral("int"), TypeTable); } return Result; } internal b32 LongInt (token_iter* Iter, s32* TypeIndexOut, type_table TypeTable) { b32 Result = false; PushSnapshot(Iter); if (TokenAtEquals(Iter, "unsigned") || TokenAtEquals(Iter, "signed")) { } if (TokenAtEquals(Iter, "long")) { Result = true; if (TokenAtEquals(Iter, "int")) { Result = true; } } ApplySnapshotIfNotParsedAndPop(Result, Iter); if (Result) { *TypeIndexOut = GetIndexOfType(MakeStringLiteral("long int"), TypeTable); } return Result; } internal b32 LongLongInt (token_iter* Iter, s32* TypeIndexOut, type_table TypeTable) { b32 Result = false; PushSnapshot(Iter); if (TokenAtEquals(Iter, "unsigned") || TokenAtEquals(Iter, "signed")) { } if (TokenAtEquals(Iter, "long")) { if (TokenAtEquals(Iter, "long")) { Result = true; if (TokenAtEquals(Iter, "int")) { Result = true; } } } ApplySnapshotIfNotParsedAndPop(Result, Iter); if (Result) { *TypeIndexOut = GetIndexOfType(MakeStringLiteral("long long int"), TypeTable); } return Result; } internal b32 ParseChar(token_iter* Iter, s32* TypeIndexOut, type_table TypeTable) { b32 Result = false; PushSnapshot(Iter); if (TokenAtEquals(Iter, "unsigned") || TokenAtEquals(Iter, "signed")) { } if (TokenAtEquals(Iter, "char")) { Result = true; } ApplySnapshotIfNotParsedAndPop(Result, Iter); if (Result) { *TypeIndexOut = GetIndexOfType(MakeStringLiteral("char"), TypeTable); } return Result; } internal b32 ParseBool(token_iter* Iter, s32* TypeIndexOut, type_table TypeTable) { b32 Result = false; PushSnapshot(Iter); if (TokenAtEquals(Iter, "bool")) { Result = true; *TypeIndexOut = GetIndexOfType(MakeStringLiteral("bool"), TypeTable); } ApplySnapshotIfNotParsedAndPop(Result, Iter); return Result; } internal b32 ParseFloat(token_iter* Iter, s32* TypeIndexOut, type_table TypeTable) { b32 Result = false; PushSnapshot(Iter); if (TokenAtEquals(Iter, "float")) { Result = true; *TypeIndexOut= GetIndexOfType(MakeStringLiteral("float"), TypeTable); } ApplySnapshotIfNotParsedAndPop(Result, Iter); return Result; } internal b32 ParseDouble(token_iter* Iter, s32* TypeIndexOut, type_table TypeTable) { b32 Result = false; PushSnapshot(Iter); if (TokenAtEquals(Iter, "double")) { Result = true; *TypeIndexOut = GetIndexOfType(MakeStringLiteral("double"), TypeTable); } ApplySnapshotIfNotParsedAndPop(Result, Iter); return Result; } // :UndeclaredType // NOTE(Peter): If TypeIndexOut is -1, you need to call NextToken after this // function to advance past the type identifier. internal b32 ParseType(token_iter* Iter, type_table* TypeTable, s32* TypeIndexOut) { b32 Result = false; *TypeIndexOut = -1; PushSnapshot(Iter); // TODO(Peter): Store signedness, and what makes up a type if (ParseChar(Iter, TypeIndexOut, *TypeTable)) { Result = true; } else if (StringsEqual(Iter->TokenAt->Text, MakeStringLiteral("wchar_t"))) { NextToken(Iter); Result = true; *TypeIndexOut = GetIndexOfType(MakeStringLiteral("wchar_t"), *TypeTable); } else if (ParseBool(Iter, TypeIndexOut, *TypeTable)) { NextToken(Iter); Result = true; } else if (LongLongInt(Iter, TypeIndexOut, *TypeTable)) { Result = true; } else if (LongInt(Iter, TypeIndexOut, *TypeTable)) { Result = true; } else if (ShortInt(Iter, TypeIndexOut, *TypeTable)) { Result = true; } else if (Int(Iter, TypeIndexOut, *TypeTable)) { Result = true; } else if (ParseFloat(Iter, TypeIndexOut, *TypeTable)) { Result = true; } else if (ParseDouble(Iter, TypeIndexOut, *TypeTable)) { Result = true; } else if (StringsEqual(Iter->TokenAt->Text, MakeStringLiteral("void"))) { NextToken(Iter); Result = true; *TypeIndexOut = GetIndexOfType(MakeStringLiteral("void"), *TypeTable); } else { *TypeIndexOut = GetIndexOfType(Iter->TokenAt->Text, *TypeTable); if (*TypeIndexOut >= 0) { Result = true; NextToken(Iter); } else if(Iter->TokenAt->Type == Token_Identifier) { Result = true; // NOTE(Peter): In this case, we believe we are at a type identifier, // however, it hasn't been declared yet. This is due to the fact that we // tokenize files, then parse them, then import the files they include, and // then begin tokenizing, parsing, etc for those files. // In the case that we get an as-of-yet undeclared type, we leave it // up to the calling site to determine what to do with that information // :UndeclaredType *TypeIndexOut = -1; } } ApplySnapshotIfNotParsedAndPop(Result, Iter); return Result; } internal b32 ParsePointer (token_iter* Iter) { b32 Result = false; if (TokenAtEquals(Iter, "*")) { Result = true; } return Result; } internal b32 ParseConstVolatile (token_iter* Iter) { b32 Result = false; PushSnapshot(Iter); if (TokenAtEquals(Iter, "volatile") || TokenAtEquals(Iter, "const")) { Result = true; } ApplySnapshotIfNotParsedAndPop(Result, Iter); return Result; } internal b32 ParseVariableDecl(token_iter* Iter, gs_bucket* TagList, gs_bucket* VariableList, type_table* TypeTable) { b32 Result = false; PushSnapshot(Iter); if (ParseConstVolatile(Iter)) { // NOTE(Peter): we don't do anything with this atm // dont have a reason to just yet // :UnusedConstVolatile } s32 TypeIndex = -1; if (ParseType(Iter, TypeTable, &TypeIndex)) { // :UndeclaredType if (TypeIndex < 0) { TypeIndex = PushUndeclaredType(Iter->TokenAt->Text, TypeTable); NextToken(Iter); } b32 IsPointer = ParsePointer(Iter); if (ParseConstVolatile(Iter)) { // :UnusedConstVolatile } do { token IdentifierToken = {}; if (TokenAtEquals(Iter, Token_Identifier, &IdentifierToken)) { // Array Notationg ie r32 x[2]; // NOTE(Peter): True initially because if there is no array notation, we // are still ok to proceed b32 ArrayParseSuccess = true; u32 ArrayCount = 0; if (TokenAtEquals(Iter, "[")) { // NOTE(Peter): Once we get to this point, we have to complete the entire // array notation before we have successfully parsed, hence setting // ArrayParseSucces to false here. ArrayParseSuccess = false; token NumberToken = {}; if (TokenAtEquals(Iter, Token_Number, &NumberToken)) { parse_result ParseArrayCount = ParseUnsignedInt(StringExpand(NumberToken.Text)); ArrayCount = ParseArrayCount.UnsignedIntValue; if (TokenAtEquals(Iter, "]")) { ArrayParseSuccess = true; } } } if (ArrayParseSuccess) { Result = true; variable_decl* Decl = VariableList->TakeElement(); *Decl = {}; Decl->Identifier = IdentifierToken.Text; Decl->TypeIndex = TypeIndex; Decl->Pointer = IsPointer; Decl->ArrayCount = ArrayCount; CopyMetaTagsAndClear(TagList, &Decl->MetaTags); } } } while (TokenAtEquals(Iter, ",")); } ApplySnapshotIfNotParsedAndPop(Result, Iter); return Result; } internal b32 StructOrUnion(token_iter* Iter, type_definition_type* Type) { b32 Result = false; if (TokenAtEquals(Iter, "struct")) { Result = true; *Type = TypeDef_Struct; } else if (TokenAtEquals(Iter, "union")) { Result = true; *Type = TypeDef_Union; } return Result; } internal b32 ParseStruct(token_iter* Iter, s32* StructTypeIndexOut, gs_bucket* TagList, type_table* TypeTable) { b32 Result = false; *StructTypeIndexOut = -1; PushSnapshot(Iter); type_definition_type DeclType; if (StructOrUnion(Iter, &DeclType)) { token IdentifierToken = {}; if (TokenAtEquals(Iter, Token_Identifier, &IdentifierToken)) {} // TODO(Peter): Handle name coming after the struct if (TokenAtEquals(Iter, "{")) { type_definition StructDecl = {}; StructDecl.Identifier = IdentifierToken.Text; StructDecl.Type = DeclType; CopyMetaTagsAndClear(TagList, &StructDecl.MetaTags); while (!TokenAtEquals(Iter, "}")) { s32 MemberStructTypeIndex = {}; variable_decl MemberDecl = {}; if (ParseMetaTag(Iter, TagList)) { } else if (ParseVariableDecl(Iter, TagList, &StructDecl.Struct.MemberDecls, TypeTable)) { if (!TokenAtEquals(Iter, ";")) { PushFError(Iter->Errors, "No semicolon after struct member variable declaration. %S", StructDecl.Identifier); } } else if (ParseStruct(Iter, &MemberStructTypeIndex, TagList, TypeTable)) { // NOTE(Peter): Pretty sure, since we just parsed the struct, that // MemberStructTypeIndex should never be -1 (unknown type). // Putting this Assert here for now, but remove if there's a valid // reason that you might not be able to find a struct just parsed at // this point. Assert(MemberStructTypeIndex >= 0); MemberDecl.TypeIndex = MemberStructTypeIndex; StructDecl.Struct.MemberDecls.PushElementOnBucket(MemberDecl); } else { // NOTE(Peter): One of the things that falls through here is // cpp template stuff. Eventually, we should be able to use // this meta layer to get rid of them all together, and then // we can just disallow CPP templates NextToken(Iter); } } if (TokenAtEquals(Iter, ";")) { Result = true; *StructTypeIndexOut = PushTypeDefOnTypeTable(StructDecl, TypeTable); } } } ApplySnapshotIfNotParsedAndPop(Result, Iter); return Result; } // ( type *? identifier, ... ) internal b32 ParseFunctionParameterList (token_iter* Iter, type_definition* FunctionPtrDecl, gs_bucket* TagList, type_table* TypeTable) { b32 Result = false; PushSnapshot(Iter); if (TokenAtEquals(Iter, "(")) { Result = true; while(!StringsEqual(Iter->TokenAt->Text, MakeStringLiteral(")"))) { if (ParseVariableDecl(Iter, TagList, &FunctionPtrDecl->FunctionPtr.Parameters, TypeTable)) { if (TokenAtEquals(Iter, Token_Comma)) { } else if (!StringsEqual(Iter->TokenAt->Text, MakeStringLiteral(")"))) { Result = false; break; } } } if (TokenAtEquals(Iter, ")")) { Result = true; } } ApplySnapshotIfNotParsedAndPop(Result, Iter); return Result; } internal b32 ParseFunctionDeclaration (token_iter* Iter, token* Identifier, gs_bucket* TagList, type_table* TypeTable) { b32 Result = false; PushSnapshot(Iter); s32 ReturnTypeIndex = -1; if (ParseType(Iter, TypeTable, &ReturnTypeIndex)) { if (ReturnTypeIndex < 0) { ReturnTypeIndex = PushUndeclaredType(Iter->TokenAt->Text, TypeTable); NextToken(Iter); } b32 IsPointer = ParsePointer(Iter); if (TokenAtEquals(Iter, Token_Identifier, Identifier)) { type_definition FunctionPtr = {}; FunctionPtr.Identifier = Identifier->Text; FunctionPtr.Size = sizeof(void*); CopyMetaTagsAndClear(TagList, &FunctionPtr.MetaTags); FunctionPtr.Type = TypeDef_FunctionPointer; FunctionPtr.Pointer = true; FunctionPtr.FunctionPtr = {}; FunctionPtr.FunctionPtr.ReturnTypeIndex = ReturnTypeIndex; if (ParseFunctionParameterList(Iter, &FunctionPtr, TagList, TypeTable)) { if (TokenAtEquals(Iter, ";")) { Result = true; PushTypeDefOnTypeTable(FunctionPtr, TypeTable); } } } } ApplySnapshotIfNotParsedAndPop(Result, Iter); if (!Result) { *Identifier = {0}; } return Result; } internal b32 ParseTypedef(token_iter* Iter, gs_bucket* TagList, type_table* TypeTable) { b32 Result = false; PushSnapshot(Iter); if (TokenAtEquals(Iter, "typedef")) { token TypeToken = {0}; s32 TypeIndex = -1; if (TokenAtEquals(Iter, "struct") && ParseStruct(Iter, &TypeIndex, TagList, TypeTable)) { Result = true; } else if (ParseFunctionDeclaration(Iter, &TypeToken, TagList, TypeTable)) { Result = true; } else if (ParseType(Iter, TypeTable, &TypeIndex)) { if (TypeIndex < 0) { TypeIndex = PushUndeclaredType(Iter->TokenAt->Text, TypeTable); NextToken(Iter); } b32 IsPointer = ParsePointer(Iter); type_definition* BasisType = TypeTable->Types.GetElementAtIndex(TypeIndex); type_definition NewType = {}; NewType.Size = BasisType->Size; CopyMetaTagsAndClear(TagList, &NewType.MetaTags); NewType.Type = BasisType->Type; if (NewType.Type == TypeDef_Struct || NewType.Type == TypeDef_Union) { NewType.Struct = BasisType->Struct; } NewType.Pointer = BasisType->Pointer || IsPointer; token IdentifierToken = {}; if (TokenAtEquals(Iter, Token_Identifier, &IdentifierToken)) { NewType.Identifier = IdentifierToken.Text; PushTypeDefOnTypeTable(NewType, TypeTable); Result = true; } } else { string* Error = TakeError(Iter->Errors); PrintF(Error, "unhandled typedef "); while (!TokenAtEquals(Iter, ";")) { PrintF(Error, "%S ", Iter->TokenAt->Text); NextToken(Iter); } PrintF(Error, "\n"); } } ApplySnapshotIfNotParsedAndPop(Result, Iter); return Result; } internal b32 ParseEnum (token_iter* Iter, gs_bucket* TagList, type_table* TypeTable) { b32 Result = false; PushSnapshot(Iter); if (TokenAtEquals(Iter, "enum")) { token IdentifierToken = {}; if (TokenAtEquals(Iter, Token_Identifier, &IdentifierToken)) { type_definition EnumDecl = {}; EnumDecl.Identifier = IdentifierToken.Text; EnumDecl.Size = sizeof(u32); CopyMetaTagsAndClear(TagList, &EnumDecl.MetaTags); EnumDecl.Type = TypeDef_Enum; if (TokenAtEquals(Iter, "{")) { u32 EnumAcc = 0; while (!StringsEqual(Iter->TokenAt->Text, MakeStringLiteral("}"))) { token EnumIdentifierToken = {}; if (TokenAtEquals(Iter, Token_Identifier, &EnumIdentifierToken)) { if (TokenAtEquals(Iter, "=")) { // TODO(Peter): TempValue is just here until we handle all // const expr that could define an enum value. Its there so // that if the first token of an expression is a number, // we can avoid using anything from the expression. u32 TempValue = EnumAcc; token NumberToken = {}; if (TokenAtEquals(Iter, Token_Number, &NumberToken)) { parse_result ParsedExpr = ParseSignedInt(StringExpand(NumberToken.Text)); TempValue = ParsedExpr.SignedIntValue; } // TODO(Peter): Handle setting enums equal to other kinds // of const exprs. // We're skipping a whole bunch of stuff now while (!(StringsEqual(Iter->TokenAt->Text, MakeStringLiteral(",")) || StringsEqual(Iter->TokenAt->Text, MakeStringLiteral("}")))) { TempValue = EnumAcc; NextToken(Iter); } EnumAcc = TempValue; } s32 EnumValue = EnumAcc++; if (TokenAtEquals(Iter, ",") || StringsEqual(Iter->TokenAt->Text, MakeStringLiteral("}"))) { EnumDecl.Enum.Identifiers.PushElementOnBucket(EnumIdentifierToken.Text); EnumDecl.Enum.Values.PushElementOnBucket(EnumValue); } else if (!StringsEqual(Iter->TokenAt->Text, MakeStringLiteral("}"))) { Result = false; break; } } } if (TokenAtEquals(Iter, "}") && TokenAtEquals(Iter, ";")) { PushTypeDefOnTypeTable(EnumDecl, TypeTable); Result = true; } } } } ApplySnapshotIfNotParsedAndPop(Result, Iter); return Result; } internal void PrintIndent (u32 Indent) { for (u32 i = 0; i < Indent; i++) { printf(" "); } } internal void PrintStructDecl (type_definition* StructDecl, type_table TypeTable, u32 Indent); internal void PrintVariableDecl (variable_decl Member, type_table TypeTable, u32 Indent = 0) { type_definition* MemberTypeDef = TypeTable.Types.GetElementAtIndex(Member.TypeIndex); if ((MemberTypeDef->Type == TypeDef_Struct || MemberTypeDef->Type == TypeDef_Union) && MemberTypeDef->Identifier.Length == 0) { PrintStructDecl(MemberTypeDef, TypeTable, Indent); } else { PrintIndent(Indent); if (Member.TypeIndex == -1) { printf("???? "); } printf("%.*s ", StringExpand(MemberTypeDef->Identifier)); } if (Member.Pointer) { printf("* "); } printf("%.*s", StringExpand(Member.Identifier)); if (Member.ArrayCount > 0) { printf("[%d]", Member.ArrayCount); } } internal void PrintStructDecl (type_definition* StructDecl, type_table TypeTable, u32 Indent = 0) { Assert(StructDecl->Type == TypeDef_Struct || StructDecl->Type == TypeDef_Union); PrintIndent(Indent); if (StructDecl->Type == TypeDef_Struct) { printf("struct "); } else if (StructDecl->Type == TypeDef_Union) { printf("union "); } else { InvalidCodePath; } if (StructDecl->Identifier.Length > 0) { printf("%.*s ", StringExpand(StructDecl->Identifier)); } printf("{\n"); for (u32 MemberIndex = 0; MemberIndex < StructDecl->Struct.MemberDecls.Used; MemberIndex++) { variable_decl* Member = StructDecl->Struct.MemberDecls.GetElementAtIndex(MemberIndex); PrintVariableDecl(*Member, TypeTable, Indent + 1); printf(";\n"); } PrintIndent(Indent); printf("} ( size = %d ) ", StructDecl->Size); } internal void PrintFunctionPtrDecl (type_definition* FnPtrDecl, type_table TypeTable) { type_definition* ReturnType = TypeTable.Types.GetElementAtIndex(FnPtrDecl->FunctionPtr.ReturnTypeIndex); printf("%.*s ", StringExpand(ReturnType->Identifier)); if (FnPtrDecl->Identifier.Length > 0) { printf("%.*s ", StringExpand(FnPtrDecl->Identifier)); } printf("("); for (u32 MemberIndex = 0; MemberIndex < FnPtrDecl->FunctionPtr.Parameters.Used; MemberIndex++) { variable_decl* Param = FnPtrDecl->FunctionPtr.Parameters.GetElementAtIndex(MemberIndex); PrintVariableDecl(*Param, TypeTable, 0); printf(", "); } printf(");"); } struct typeinfo_generator { string_builder TypeList; string_builder StructMembers; string_builder TypeDefinitions; u32 GeneratedInfoTypesCount; u32 TypesMax; b8* TypesGeneratedMask; }; internal typeinfo_generator InitTypeInfoGenerator(type_table TypeTable) { typeinfo_generator Result = {}; Result.TypesMax = TypeTable.Types.Used; Result.TypesGeneratedMask = (b8*)malloc(sizeof(b8) * Result.TypesMax); GSZeroMemory((u8*)Result.TypesGeneratedMask, Result.TypesMax); WriteF(&Result.TypeList, "enum gsm_struct_type\n{\n"); WriteF(&Result.TypeDefinitions, "static gsm_struct_type_info StructTypes[] = {\n"); return Result; } internal void FinishGeneratingTypes(typeinfo_generator* Generator) { WriteF(&Generator->TypeList, "gsm_StructTypeCount,\n};\n\n"); WriteF(&Generator->StructMembers, "\n"); WriteF(&Generator->TypeDefinitions, "};\n"); WriteF(&Generator->TypeDefinitions, "gsm_u32 StructTypesCount = %d;\n", Generator->GeneratedInfoTypesCount); } internal void GenerateMetaTagInfo (gs_bucket Tags, string_builder* Builder) { WriteF(Builder, "{"); for (u32 t = 0; t < Tags.Used; t++) { meta_tag* Tag = Tags.GetElementAtIndex(t); WriteF(Builder, "{ \"%S\", %d }", Tag->Identifier, Tag->Identifier.Length); if ((t + 1) < Tags.Used) { WriteF(Builder, ", "); } } WriteF(Builder, "}, %d", Tags.Used); } internal void GenerateStructMemberInfo (variable_decl* Member, string StructIdentifier, type_table TypeTable, typeinfo_generator* Gen) { WriteF(&Gen->StructMembers, "{ \"%S\", %d, ", Member->Identifier, Member->Identifier.Length); WriteF(&Gen->StructMembers, "(u64)&((%S*)0)->%S ", StructIdentifier, Member->Identifier); WriteF(&Gen->StructMembers, "},\n"); } internal void GenerateTypeInfo (type_definition* Type, u32 TypeIndex, type_table TypeTable, typeinfo_generator* Generator) { Generator->TypesGeneratedMask[TypeIndex] = true; Generator->GeneratedInfoTypesCount++; { // NOTE(Peter): This block MUST come before generating // type info for any member types. If it doesn't, it will screw // up array ordering // Lookup Enum WriteF(&Generator->TypeList, "gsm_StructType_%S,\n", Type->Identifier); // Type Info WriteF(&Generator->TypeDefinitions, "{ gsm_StructType_%S, \"%S\", %d, %d, 0, 0, ", Type->Identifier, Type->Identifier, Type->Identifier.Length, Type->Size // TODO(Peter): include Meta Tags somehow ); if ((Type->Type == TypeDef_Struct || Type->Type == TypeDef_Union) && Type->Struct.MemberDecls.Used > 0) { WriteF(&Generator->TypeDefinitions, "StructMembers_%S, %d },\n", Type->Identifier, Type->Struct.MemberDecls.Used); } else { WriteF(&Generator->TypeDefinitions, "0, 0 },\n"); } } if (Type->Type == TypeDef_Struct || Type->Type == TypeDef_Union) { for (u32 m = 0; m < Type->Struct.MemberDecls.Used; m++) { variable_decl* Member = Type->Struct.MemberDecls.GetElementAtIndex(m); type_definition* MemberType = TypeTable.Types.GetElementAtIndex(Member->TypeIndex); if (MemberType->Identifier.Length == 0) { continue; } // Don't gen info for anonymous struct and union members if (Generator->TypesGeneratedMask[Member->TypeIndex]) { continue; } GenerateTypeInfo(MemberType, Member->TypeIndex, TypeTable, Generator); } // WriteF(&Generator->StructMembers, "static gsm_struct_member_type_info StructMembers_%S[] = {\n", Type->Identifier); for (u32 m = 0; m < Type->Struct.MemberDecls.Used; m++) { variable_decl* Member = Type->Struct.MemberDecls.GetElementAtIndex(m); type_definition* MemberType = TypeTable.Types.GetElementAtIndex(Member->TypeIndex); if (MemberType->Identifier.Length > 0) { GenerateStructMemberInfo(Member, Type->Identifier, TypeTable, Generator); } else if (MemberType->Type == TypeDef_Struct || MemberType->Type == TypeDef_Union) { // Anonymous Members for (u32 a = 0; a < MemberType->Struct.MemberDecls.Used; a++) { variable_decl* AnonMember = MemberType->Struct.MemberDecls.GetElementAtIndex(a); GenerateStructMemberInfo(AnonMember, Type->Identifier, TypeTable, Generator); } } } WriteF(&Generator->StructMembers, "};\n", Type->Struct.MemberDecls.Used); } } internal void GenerateFilteredTypeInfo (string MetaTagFilter, type_table TypeTable, typeinfo_generator* Generator) { for (u32 i = 0; i < TypeTable.Types.Used; i++) { if (Generator->TypesGeneratedMask[i]) { continue; } type_definition* Type = TypeTable.Types.GetElementAtIndex(i); if (HasTag(MetaTagFilter, Type->MetaTags)) { GenerateTypeInfo(Type, i, TypeTable, Generator); } } } int main(int ArgCount, char** ArgV) { s64 TotalStart = GetWallClock(); if (ArgCount <= 1) { printf("Please supply at least one source directory to analyze.\n"); return 0; } errors Errors = {0}; gs_bucket SourceFiles; string CurrentWorkingDirectory = MakeString((char*)malloc(1024), 0, 1024); if (ArgCount > 1) { string RootFile = MakeString(ArgV[1]); AddFileToSource(RootFile, &SourceFiles, &Errors); s32 LastSlash = ReverseSearchForCharInSet(RootFile, "\\/"); Assert(LastSlash > 0); string RootPath = Substring(RootFile, 0, LastSlash + 1); CopyStringTo(RootPath, &CurrentWorkingDirectory); } // NOTE(Peter): this is a temporary list of GSMetaTags. It gets copied and cleared // after use gs_bucket Tokens; gs_bucket TagList; type_table TypeTable = {0}; PopulateTableWithDefaultCPPTypes(&TypeTable); s32 NodeProcCount = 0; for (u32 SourceFileIdx = 0; SourceFileIdx < SourceFiles.Used; SourceFileIdx++) { source_code_file* File = SourceFiles.GetElementAtIndex(SourceFileIdx); TokenizeFile(File, &Tokens); token_iter Iter = {}; Iter.Tokens = &Tokens; Iter.FirstToken = File->FirstTokenIndex; Iter.LastToken = File->LastTokenIndex; Iter.TokenAtIndex = Iter.FirstToken; Iter.TokenAt = Tokens.GetElementAtIndex(Iter.TokenAtIndex); Iter.Errors = &Errors; while (Iter.TokenAtIndex < Iter.LastToken) { b32 ParseSuccess = false; s32 TypeIndex = -1; if (TokenAtEquals(&Iter, "#include")) { token* IncludeFile = Iter.TokenAt; // NOTE(Peter): For now we aren't going in and preprocessing the header files // we include from the system // Token_Operator is used to check if the include is of the form '#include ' // and skip it. // TODO(Peter): This is only a rough approximation of ignoring system headers // TODO(Peter): We should actually see what parsing system headers would entail if (IncludeFile->Type != Token_Operator) { string TempFilePath = IncludeFile->Text; // NOTE(Peter): if the path is NOT absolute ie "C:\etc if (!(IsAlpha(TempFilePath.Memory[0]) && TempFilePath.Memory[1] == ':' && TempFilePath.Memory[2] == '\\')) { TempFilePath = CurrentWorkingDirectory; ConcatString(IncludeFile->Text, &TempFilePath); NullTerminate(&TempFilePath); } ParseSuccess = true; if (!FileAlreadyInSource(TempFilePath, SourceFiles)) { AddFileToSource(TempFilePath, &SourceFiles, &Errors); } } } else if(ParseMetaTag(&Iter, &TagList)) { ParseSuccess = true; } else if (ParseEnum(&Iter, &TagList, &TypeTable)) { ParseSuccess = true; } else if (ParseStruct(&Iter, &TypeIndex, &TagList, &TypeTable)) { ParseSuccess = true; } else if (ParseTypedef(&Iter, &TagList, &TypeTable)) { ParseSuccess = true; } if (!ParseSuccess) { NextToken(&Iter); } } } // Type Table Fixup for (u32 i = 0; i < TypeTable.Types.Used; i++) { type_definition* TypeDef = TypeTable.Types.GetElementAtIndex(i); if (TypeDef->Type == TypeDef_Struct) { FixUpStructSize(i, TypeTable, &Errors); } else if (TypeDef->Type == TypeDef_Union) { FixUpUnionSize(i, TypeTable, &Errors); } } s64 Cycles_Preprocess = GetWallClock(); PrintAllErrors(Errors); typeinfo_generator TypeGenerator = InitTypeInfoGenerator(TypeTable); GenerateFilteredTypeInfo(MakeStringLiteral("node_struct"), TypeTable, &TypeGenerator); GenerateFilteredTypeInfo(MakeStringLiteral("gen_type_info"), TypeTable, &TypeGenerator); FinishGeneratingTypes(&TypeGenerator); FILE* TypeInfoH = fopen("C:\\projects\\foldhaus\\src\\generated\\gs_meta_generated_typeinfo.h", "w"); if (TypeInfoH) { WriteStringBuilderToFile(TypeGenerator.TypeList, TypeInfoH); WriteStringBuilderToFile(TypeGenerator.StructMembers, TypeInfoH); WriteStringBuilderToFile(TypeGenerator.TypeDefinitions, TypeInfoH); fclose(TypeInfoH); } s64 TotalEnd = GetWallClock(); r32 TotalTime = GetSecondsElapsed(TotalStart, TotalEnd); printf("Metaprogram Preproc Time: %.*f sec\n", 6, TotalTime); //__debugbreak(); return 0; }