//===--- Types.cpp - Driver input & temporary type information ------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #include "clang/Driver/Types.h" #include "llvm/ADT/STLExtras.h" #include "llvm/ADT/StringSwitch.h" #include #include using namespace clang::driver; using namespace clang::driver::types; struct TypeInfo { const char *Name; const char *Flags; const char *TempSuffix; ID PreprocessedType; }; static const TypeInfo TypeInfos[] = { #define TYPE(NAME, ID, PP_TYPE, TEMP_SUFFIX, FLAGS) \ { NAME, FLAGS, TEMP_SUFFIX, TY_##PP_TYPE, }, #include "clang/Driver/Types.def" #undef TYPE }; static const unsigned numTypes = llvm::array_lengthof(TypeInfos); static const TypeInfo &getInfo(unsigned id) { assert(id > 0 && id - 1 < numTypes && "Invalid Type ID."); return TypeInfos[id - 1]; } const char *types::getTypeName(ID Id) { return getInfo(Id).Name; } types::ID types::getPreprocessedType(ID Id) { return getInfo(Id).PreprocessedType; } const char *types::getTypeTempSuffix(ID Id, bool CLMode) { if (Id == TY_Object && CLMode) return "obj"; if (Id == TY_Image && CLMode) return "exe"; if (Id == TY_PP_Asm && CLMode) return "asm"; return getInfo(Id).TempSuffix; } bool types::onlyAssembleType(ID Id) { return strchr(getInfo(Id).Flags, 'a'); } bool types::onlyPrecompileType(ID Id) { return strchr(getInfo(Id).Flags, 'p'); } bool types::canTypeBeUserSpecified(ID Id) { return strchr(getInfo(Id).Flags, 'u'); } bool types::appendSuffixForType(ID Id) { return strchr(getInfo(Id).Flags, 'A'); } bool types::canLipoType(ID Id) { return (Id == TY_Nothing || Id == TY_Image || Id == TY_Object || Id == TY_LTO_BC); } bool types::isAcceptedByClang(ID Id) { switch (Id) { default: return false; case TY_Asm: case TY_C: case TY_PP_C: case TY_CL: case TY_CUDA: case TY_PP_CUDA: case TY_CUDA_DEVICE: case TY_ObjC: case TY_PP_ObjC: case TY_PP_ObjC_Alias: case TY_CXX: case TY_PP_CXX: case TY_ObjCXX: case TY_PP_ObjCXX: case TY_PP_ObjCXX_Alias: case TY_CHeader: case TY_PP_CHeader: case TY_CLHeader: case TY_ObjCHeader: case TY_PP_ObjCHeader: case TY_CXXHeader: case TY_PP_CXXHeader: case TY_ObjCXXHeader: case TY_PP_ObjCXXHeader: case TY_AST: case TY_ModuleFile: case TY_LLVM_IR: case TY_LLVM_BC: return true; } } bool types::isObjC(ID Id) { switch (Id) { default: return false; case TY_ObjC: case TY_PP_ObjC: case TY_PP_ObjC_Alias: case TY_ObjCXX: case TY_PP_ObjCXX: case TY_ObjCHeader: case TY_PP_ObjCHeader: case TY_ObjCXXHeader: case TY_PP_ObjCXXHeader: case TY_PP_ObjCXX_Alias: return true; } } bool types::isCXX(ID Id) { switch (Id) { default: return false; case TY_CXX: case TY_PP_CXX: case TY_ObjCXX: case TY_PP_ObjCXX: case TY_PP_ObjCXX_Alias: case TY_CXXHeader: case TY_PP_CXXHeader: case TY_ObjCXXHeader: case TY_PP_ObjCXXHeader: case TY_CUDA: case TY_PP_CUDA: case TY_CUDA_DEVICE: return true; } } bool types::isLLVMIR(ID Id) { switch (Id) { default: return false; case TY_LLVM_IR: case TY_LLVM_BC: case TY_LTO_IR: case TY_LTO_BC: return true; } } bool types::isCuda(ID Id) { switch (Id) { default: return false; case TY_CUDA: case TY_PP_CUDA: case TY_CUDA_DEVICE: return true; } } types::ID types::lookupTypeForExtension(const char *Ext) { return llvm::StringSwitch(Ext) .Case("c", TY_C) .Case("i", TY_PP_C) .Case("m", TY_ObjC) .Case("M", TY_ObjCXX) .Case("h", TY_CHeader) .Case("C", TY_CXX) .Case("H", TY_CXXHeader) .Case("f", TY_PP_Fortran) .Case("F", TY_Fortran) .Case("s", TY_PP_Asm) .Case("asm", TY_PP_Asm) .Case("S", TY_Asm) .Case("o", TY_Object) .Case("obj", TY_Object) .Case("lib", TY_Object) .Case("ii", TY_PP_CXX) .Case("mi", TY_PP_ObjC) .Case("mm", TY_ObjCXX) .Case("bc", TY_LLVM_BC) .Case("cc", TY_CXX) .Case("CC", TY_CXX) .Case("cl", TY_CL) .Case("cp", TY_CXX) .Case("cu", TY_CUDA) .Case("cui", TY_PP_CUDA) .Case("hh", TY_CXXHeader) .Case("ll", TY_LLVM_IR) .Case("hpp", TY_CXXHeader) .Case("ads", TY_Ada) .Case("adb", TY_Ada) .Case("ast", TY_AST) .Case("c++", TY_CXX) .Case("C++", TY_CXX) .Case("cxx", TY_CXX) .Case("cpp", TY_CXX) .Case("CPP", TY_CXX) .Case("CXX", TY_CXX) .Case("for", TY_PP_Fortran) .Case("FOR", TY_PP_Fortran) .Case("fpp", TY_Fortran) .Case("FPP", TY_Fortran) .Case("f90", TY_PP_Fortran) .Case("f95", TY_PP_Fortran) .Case("F90", TY_Fortran) .Case("F95", TY_Fortran) .Case("mii", TY_PP_ObjCXX) .Case("pcm", TY_ModuleFile) .Case("pch", TY_PCH) .Case("gch", TY_PCH) .Case("rs", TY_RenderScript) .Default(TY_INVALID); } types::ID types::lookupTypeForTypeSpecifier(const char *Name) { for (unsigned i=0; i &P) { if (Id != TY_Object) { if (getPreprocessedType(Id) != TY_INVALID) { P.push_back(phases::Preprocess); } if (onlyPrecompileType(Id)) { P.push_back(phases::Precompile); } else { if (!onlyAssembleType(Id)) { P.push_back(phases::Compile); P.push_back(phases::Backend); } P.push_back(phases::Assemble); } } if (!onlyPrecompileType(Id) && Id != TY_CUDA_DEVICE) { P.push_back(phases::Link); } assert(0 < P.size() && "Not enough phases in list"); assert(P.size() <= phases::MaxNumberOfPhases && "Too many phases in list"); } ID types::lookupCXXTypeForCType(ID Id) { switch (Id) { default: return Id; case types::TY_C: return types::TY_CXX; case types::TY_PP_C: return types::TY_PP_CXX; case types::TY_CHeader: return types::TY_CXXHeader; case types::TY_PP_CHeader: return types::TY_PP_CXXHeader; } }