//===--- ParsePragma.cpp - Language specific pragma parsing ---------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // This file implements the language specific #pragma handlers. // //===----------------------------------------------------------------------===// #include "clang/AST/ASTContext.h" #include "clang/Basic/PragmaKinds.h" #include "clang/Basic/TargetInfo.h" #include "clang/Lex/Preprocessor.h" #include "clang/Lex/Token.h" #include "clang/Parse/LoopHint.h" #include "clang/Parse/ParseDiagnostic.h" #include "clang/Parse/Parser.h" #include "clang/Parse/RAIIObjectsForParser.h" #include "clang/Sema/EnterExpressionEvaluationContext.h" #include "clang/Sema/Scope.h" #include "llvm/ADT/ArrayRef.h" #include "llvm/ADT/StringSwitch.h" #include using namespace clang; namespace { struct PragmaAlignHandler : public PragmaHandler { explicit PragmaAlignHandler() : PragmaHandler("align") {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; }; struct PragmaGCCVisibilityHandler : public PragmaHandler { explicit PragmaGCCVisibilityHandler() : PragmaHandler("visibility") {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; }; struct PragmaOptionsHandler : public PragmaHandler { explicit PragmaOptionsHandler() : PragmaHandler("options") {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; }; struct PragmaPackHandler : public PragmaHandler { explicit PragmaPackHandler() : PragmaHandler("pack") {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; }; struct PragmaClangSectionHandler : public PragmaHandler { explicit PragmaClangSectionHandler(Sema &S) : PragmaHandler("section"), Actions(S) {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; private: Sema &Actions; }; struct PragmaMSStructHandler : public PragmaHandler { explicit PragmaMSStructHandler() : PragmaHandler("ms_struct") {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; }; struct PragmaUnusedHandler : public PragmaHandler { PragmaUnusedHandler() : PragmaHandler("unused") {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; }; struct PragmaWeakHandler : public PragmaHandler { explicit PragmaWeakHandler() : PragmaHandler("weak") {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; }; struct PragmaRedefineExtnameHandler : public PragmaHandler { explicit PragmaRedefineExtnameHandler() : PragmaHandler("redefine_extname") {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; }; struct PragmaOpenCLExtensionHandler : public PragmaHandler { PragmaOpenCLExtensionHandler() : PragmaHandler("EXTENSION") {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; }; struct PragmaFPContractHandler : public PragmaHandler { PragmaFPContractHandler() : PragmaHandler("FP_CONTRACT") {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; }; // Pragma STDC implementations. /// PragmaSTDC_FENV_ACCESSHandler - "\#pragma STDC FENV_ACCESS ...". struct PragmaSTDC_FENV_ACCESSHandler : public PragmaHandler { PragmaSTDC_FENV_ACCESSHandler() : PragmaHandler("FENV_ACCESS") {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &Tok) override { Token PragmaName = Tok; if (!PP.getTargetInfo().hasStrictFP() && !PP.getLangOpts().ExpStrictFP) { PP.Diag(Tok.getLocation(), diag::warn_pragma_fp_ignored) << PragmaName.getIdentifierInfo()->getName(); return; } tok::OnOffSwitch OOS; if (PP.LexOnOffSwitch(OOS)) return; MutableArrayRef Toks(PP.getPreprocessorAllocator().Allocate(1), 1); Toks[0].startToken(); Toks[0].setKind(tok::annot_pragma_fenv_access); Toks[0].setLocation(Tok.getLocation()); Toks[0].setAnnotationEndLoc(Tok.getLocation()); Toks[0].setAnnotationValue(reinterpret_cast( static_cast(OOS))); PP.EnterTokenStream(Toks, /*DisableMacroExpansion=*/true, /*IsReinject=*/false); } }; /// PragmaSTDC_CX_LIMITED_RANGEHandler - "\#pragma STDC CX_LIMITED_RANGE ...". struct PragmaSTDC_CX_LIMITED_RANGEHandler : public PragmaHandler { PragmaSTDC_CX_LIMITED_RANGEHandler() : PragmaHandler("CX_LIMITED_RANGE") {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &Tok) override { tok::OnOffSwitch OOS; if (PP.LexOnOffSwitch(OOS)) return; MutableArrayRef Toks( PP.getPreprocessorAllocator().Allocate(1), 1); Toks[0].startToken(); Toks[0].setKind(tok::annot_pragma_cx_limited_range); Toks[0].setLocation(Tok.getLocation()); Toks[0].setAnnotationEndLoc(Tok.getLocation()); Toks[0].setAnnotationValue( reinterpret_cast(static_cast(OOS))); PP.EnterTokenStream(Toks, /*DisableMacroExpansion=*/true, /*IsReinject=*/false); } }; /// Handler for "\#pragma STDC FENV_ROUND ...". struct PragmaSTDC_FENV_ROUNDHandler : public PragmaHandler { PragmaSTDC_FENV_ROUNDHandler() : PragmaHandler("FENV_ROUND") {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &Tok) override; }; /// PragmaSTDC_UnknownHandler - "\#pragma STDC ...". struct PragmaSTDC_UnknownHandler : public PragmaHandler { PragmaSTDC_UnknownHandler() = default; void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &UnknownTok) override { // C99 6.10.6p2, unknown forms are not allowed. PP.Diag(UnknownTok, diag::ext_stdc_pragma_ignored); } }; struct PragmaFPHandler : public PragmaHandler { PragmaFPHandler() : PragmaHandler("fp") {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; }; // A pragma handler to be the base of the NoOpenMPHandler and NoOpenACCHandler, // which are identical other than the name given to them, and the diagnostic // emitted. template struct PragmaNoSupportHandler : public PragmaHandler { PragmaNoSupportHandler(StringRef Name) : PragmaHandler(Name) {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; }; struct PragmaNoOpenMPHandler : public PragmaNoSupportHandler { PragmaNoOpenMPHandler() : PragmaNoSupportHandler("omp") {} }; struct PragmaNoOpenACCHandler : public PragmaNoSupportHandler { PragmaNoOpenACCHandler() : PragmaNoSupportHandler("acc") {} }; // A pragma handler to be the base for the OpenMPHandler and OpenACCHandler, // which are identical other than the tokens used for the start/end of a pragma // section, and some diagnostics. template struct PragmaSupportHandler : public PragmaHandler { PragmaSupportHandler(StringRef Name) : PragmaHandler(Name) {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; }; struct PragmaOpenMPHandler : public PragmaSupportHandler { PragmaOpenMPHandler() : PragmaSupportHandler("omp") {} }; struct PragmaOpenACCHandler : public PragmaSupportHandler { PragmaOpenACCHandler() : PragmaSupportHandler("acc") {} }; /// PragmaCommentHandler - "\#pragma comment ...". struct PragmaCommentHandler : public PragmaHandler { PragmaCommentHandler(Sema &Actions) : PragmaHandler("comment"), Actions(Actions) {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; private: Sema &Actions; }; struct PragmaDetectMismatchHandler : public PragmaHandler { PragmaDetectMismatchHandler(Sema &Actions) : PragmaHandler("detect_mismatch"), Actions(Actions) {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; private: Sema &Actions; }; struct PragmaFloatControlHandler : public PragmaHandler { PragmaFloatControlHandler(Sema &Actions) : PragmaHandler("float_control") {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; }; struct PragmaMSPointersToMembers : public PragmaHandler { explicit PragmaMSPointersToMembers() : PragmaHandler("pointers_to_members") {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; }; struct PragmaMSVtorDisp : public PragmaHandler { explicit PragmaMSVtorDisp() : PragmaHandler("vtordisp") {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; }; struct PragmaMSPragma : public PragmaHandler { explicit PragmaMSPragma(const char *name) : PragmaHandler(name) {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; }; /// PragmaOptimizeHandler - "\#pragma clang optimize on/off". struct PragmaOptimizeHandler : public PragmaHandler { PragmaOptimizeHandler(Sema &S) : PragmaHandler("optimize"), Actions(S) {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; private: Sema &Actions; }; struct PragmaLoopHintHandler : public PragmaHandler { PragmaLoopHintHandler() : PragmaHandler("loop") {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; }; struct PragmaUnrollHintHandler : public PragmaHandler { PragmaUnrollHintHandler(const char *name) : PragmaHandler(name) {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; }; struct PragmaMSRuntimeChecksHandler : public EmptyPragmaHandler { PragmaMSRuntimeChecksHandler() : EmptyPragmaHandler("runtime_checks") {} }; struct PragmaMSIntrinsicHandler : public PragmaHandler { PragmaMSIntrinsicHandler() : PragmaHandler("intrinsic") {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; }; // "\#pragma fenv_access (on)". struct PragmaMSFenvAccessHandler : public PragmaHandler { PragmaMSFenvAccessHandler() : PragmaHandler("fenv_access") {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override { StringRef PragmaName = FirstToken.getIdentifierInfo()->getName(); if (!PP.getTargetInfo().hasStrictFP() && !PP.getLangOpts().ExpStrictFP) { PP.Diag(FirstToken.getLocation(), diag::warn_pragma_fp_ignored) << PragmaName; return; } Token Tok; PP.Lex(Tok); if (Tok.isNot(tok::l_paren)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_lparen) << PragmaName; return; } PP.Lex(Tok); // Consume the l_paren. if (Tok.isNot(tok::identifier)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_ms_fenv_access); return; } const IdentifierInfo *II = Tok.getIdentifierInfo(); tok::OnOffSwitch OOS; if (II->isStr("on")) { OOS = tok::OOS_ON; PP.Lex(Tok); } else if (II->isStr("off")) { OOS = tok::OOS_OFF; PP.Lex(Tok); } else { PP.Diag(Tok.getLocation(), diag::warn_pragma_ms_fenv_access); return; } if (Tok.isNot(tok::r_paren)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_rparen) << PragmaName; return; } PP.Lex(Tok); // Consume the r_paren. if (Tok.isNot(tok::eod)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_extra_tokens_at_eol) << PragmaName; return; } MutableArrayRef Toks( PP.getPreprocessorAllocator().Allocate(1), 1); Toks[0].startToken(); Toks[0].setKind(tok::annot_pragma_fenv_access_ms); Toks[0].setLocation(FirstToken.getLocation()); Toks[0].setAnnotationEndLoc(Tok.getLocation()); Toks[0].setAnnotationValue( reinterpret_cast(static_cast(OOS))); PP.EnterTokenStream(Toks, /*DisableMacroExpansion=*/true, /*IsReinject=*/false); } }; struct PragmaForceCUDAHostDeviceHandler : public PragmaHandler { PragmaForceCUDAHostDeviceHandler(Sema &Actions) : PragmaHandler("force_cuda_host_device"), Actions(Actions) {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; private: Sema &Actions; }; /// PragmaAttributeHandler - "\#pragma clang attribute ...". struct PragmaAttributeHandler : public PragmaHandler { PragmaAttributeHandler(AttributeFactory &AttrFactory) : PragmaHandler("attribute"), AttributesForPragmaAttribute(AttrFactory) {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; /// A pool of attributes that were parsed in \#pragma clang attribute. ParsedAttributes AttributesForPragmaAttribute; }; struct PragmaMaxTokensHereHandler : public PragmaHandler { PragmaMaxTokensHereHandler() : PragmaHandler("max_tokens_here") {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; }; struct PragmaMaxTokensTotalHandler : public PragmaHandler { PragmaMaxTokensTotalHandler() : PragmaHandler("max_tokens_total") {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; }; struct PragmaRISCVHandler : public PragmaHandler { PragmaRISCVHandler(Sema &Actions) : PragmaHandler("riscv"), Actions(Actions) {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) override; private: Sema &Actions; }; void markAsReinjectedForRelexing(llvm::MutableArrayRef Toks) { for (auto &T : Toks) T.setFlag(clang::Token::IsReinjected); } } // end namespace void Parser::initializePragmaHandlers() { AlignHandler = std::make_unique(); PP.AddPragmaHandler(AlignHandler.get()); GCCVisibilityHandler = std::make_unique(); PP.AddPragmaHandler("GCC", GCCVisibilityHandler.get()); OptionsHandler = std::make_unique(); PP.AddPragmaHandler(OptionsHandler.get()); PackHandler = std::make_unique(); PP.AddPragmaHandler(PackHandler.get()); MSStructHandler = std::make_unique(); PP.AddPragmaHandler(MSStructHandler.get()); UnusedHandler = std::make_unique(); PP.AddPragmaHandler(UnusedHandler.get()); WeakHandler = std::make_unique(); PP.AddPragmaHandler(WeakHandler.get()); RedefineExtnameHandler = std::make_unique(); PP.AddPragmaHandler(RedefineExtnameHandler.get()); FPContractHandler = std::make_unique(); PP.AddPragmaHandler("STDC", FPContractHandler.get()); STDCFenvAccessHandler = std::make_unique(); PP.AddPragmaHandler("STDC", STDCFenvAccessHandler.get()); STDCFenvRoundHandler = std::make_unique(); PP.AddPragmaHandler("STDC", STDCFenvRoundHandler.get()); STDCCXLIMITHandler = std::make_unique(); PP.AddPragmaHandler("STDC", STDCCXLIMITHandler.get()); STDCUnknownHandler = std::make_unique(); PP.AddPragmaHandler("STDC", STDCUnknownHandler.get()); PCSectionHandler = std::make_unique(Actions); PP.AddPragmaHandler("clang", PCSectionHandler.get()); if (getLangOpts().OpenCL) { OpenCLExtensionHandler = std::make_unique(); PP.AddPragmaHandler("OPENCL", OpenCLExtensionHandler.get()); PP.AddPragmaHandler("OPENCL", FPContractHandler.get()); } if (getLangOpts().OpenMP) OpenMPHandler = std::make_unique(); else OpenMPHandler = std::make_unique(); PP.AddPragmaHandler(OpenMPHandler.get()); if (getLangOpts().OpenACC) OpenACCHandler = std::make_unique(); else OpenACCHandler = std::make_unique(); PP.AddPragmaHandler(OpenACCHandler.get()); if (getLangOpts().MicrosoftExt || getTargetInfo().getTriple().isOSBinFormatELF()) { MSCommentHandler = std::make_unique(Actions); PP.AddPragmaHandler(MSCommentHandler.get()); } FloatControlHandler = std::make_unique(Actions); PP.AddPragmaHandler(FloatControlHandler.get()); if (getLangOpts().MicrosoftExt) { MSDetectMismatchHandler = std::make_unique(Actions); PP.AddPragmaHandler(MSDetectMismatchHandler.get()); MSPointersToMembers = std::make_unique(); PP.AddPragmaHandler(MSPointersToMembers.get()); MSVtorDisp = std::make_unique(); PP.AddPragmaHandler(MSVtorDisp.get()); MSInitSeg = std::make_unique("init_seg"); PP.AddPragmaHandler(MSInitSeg.get()); MSDataSeg = std::make_unique("data_seg"); PP.AddPragmaHandler(MSDataSeg.get()); MSBSSSeg = std::make_unique("bss_seg"); PP.AddPragmaHandler(MSBSSSeg.get()); MSConstSeg = std::make_unique("const_seg"); PP.AddPragmaHandler(MSConstSeg.get()); MSCodeSeg = std::make_unique("code_seg"); PP.AddPragmaHandler(MSCodeSeg.get()); MSSection = std::make_unique("section"); PP.AddPragmaHandler(MSSection.get()); MSStrictGuardStackCheck = std::make_unique("strict_gs_check"); PP.AddPragmaHandler(MSStrictGuardStackCheck.get()); MSFunction = std::make_unique("function"); PP.AddPragmaHandler(MSFunction.get()); MSAllocText = std::make_unique("alloc_text"); PP.AddPragmaHandler(MSAllocText.get()); MSOptimize = std::make_unique("optimize"); PP.AddPragmaHandler(MSOptimize.get()); MSRuntimeChecks = std::make_unique(); PP.AddPragmaHandler(MSRuntimeChecks.get()); MSIntrinsic = std::make_unique(); PP.AddPragmaHandler(MSIntrinsic.get()); MSFenvAccess = std::make_unique(); PP.AddPragmaHandler(MSFenvAccess.get()); } if (getLangOpts().CUDA) { CUDAForceHostDeviceHandler = std::make_unique(Actions); PP.AddPragmaHandler("clang", CUDAForceHostDeviceHandler.get()); } OptimizeHandler = std::make_unique(Actions); PP.AddPragmaHandler("clang", OptimizeHandler.get()); LoopHintHandler = std::make_unique(); PP.AddPragmaHandler("clang", LoopHintHandler.get()); UnrollHintHandler = std::make_unique("unroll"); PP.AddPragmaHandler(UnrollHintHandler.get()); PP.AddPragmaHandler("GCC", UnrollHintHandler.get()); NoUnrollHintHandler = std::make_unique("nounroll"); PP.AddPragmaHandler(NoUnrollHintHandler.get()); PP.AddPragmaHandler("GCC", NoUnrollHintHandler.get()); UnrollAndJamHintHandler = std::make_unique("unroll_and_jam"); PP.AddPragmaHandler(UnrollAndJamHintHandler.get()); NoUnrollAndJamHintHandler = std::make_unique("nounroll_and_jam"); PP.AddPragmaHandler(NoUnrollAndJamHintHandler.get()); FPHandler = std::make_unique(); PP.AddPragmaHandler("clang", FPHandler.get()); AttributePragmaHandler = std::make_unique(AttrFactory); PP.AddPragmaHandler("clang", AttributePragmaHandler.get()); MaxTokensHerePragmaHandler = std::make_unique(); PP.AddPragmaHandler("clang", MaxTokensHerePragmaHandler.get()); MaxTokensTotalPragmaHandler = std::make_unique(); PP.AddPragmaHandler("clang", MaxTokensTotalPragmaHandler.get()); if (getTargetInfo().getTriple().isRISCV()) { RISCVPragmaHandler = std::make_unique(Actions); PP.AddPragmaHandler("clang", RISCVPragmaHandler.get()); } } void Parser::resetPragmaHandlers() { // Remove the pragma handlers we installed. PP.RemovePragmaHandler(AlignHandler.get()); AlignHandler.reset(); PP.RemovePragmaHandler("GCC", GCCVisibilityHandler.get()); GCCVisibilityHandler.reset(); PP.RemovePragmaHandler(OptionsHandler.get()); OptionsHandler.reset(); PP.RemovePragmaHandler(PackHandler.get()); PackHandler.reset(); PP.RemovePragmaHandler(MSStructHandler.get()); MSStructHandler.reset(); PP.RemovePragmaHandler(UnusedHandler.get()); UnusedHandler.reset(); PP.RemovePragmaHandler(WeakHandler.get()); WeakHandler.reset(); PP.RemovePragmaHandler(RedefineExtnameHandler.get()); RedefineExtnameHandler.reset(); if (getLangOpts().OpenCL) { PP.RemovePragmaHandler("OPENCL", OpenCLExtensionHandler.get()); OpenCLExtensionHandler.reset(); PP.RemovePragmaHandler("OPENCL", FPContractHandler.get()); } PP.RemovePragmaHandler(OpenMPHandler.get()); OpenMPHandler.reset(); PP.RemovePragmaHandler(OpenACCHandler.get()); OpenACCHandler.reset(); if (getLangOpts().MicrosoftExt || getTargetInfo().getTriple().isOSBinFormatELF()) { PP.RemovePragmaHandler(MSCommentHandler.get()); MSCommentHandler.reset(); } PP.RemovePragmaHandler("clang", PCSectionHandler.get()); PCSectionHandler.reset(); PP.RemovePragmaHandler(FloatControlHandler.get()); FloatControlHandler.reset(); if (getLangOpts().MicrosoftExt) { PP.RemovePragmaHandler(MSDetectMismatchHandler.get()); MSDetectMismatchHandler.reset(); PP.RemovePragmaHandler(MSPointersToMembers.get()); MSPointersToMembers.reset(); PP.RemovePragmaHandler(MSVtorDisp.get()); MSVtorDisp.reset(); PP.RemovePragmaHandler(MSInitSeg.get()); MSInitSeg.reset(); PP.RemovePragmaHandler(MSDataSeg.get()); MSDataSeg.reset(); PP.RemovePragmaHandler(MSBSSSeg.get()); MSBSSSeg.reset(); PP.RemovePragmaHandler(MSConstSeg.get()); MSConstSeg.reset(); PP.RemovePragmaHandler(MSCodeSeg.get()); MSCodeSeg.reset(); PP.RemovePragmaHandler(MSSection.get()); MSSection.reset(); PP.RemovePragmaHandler(MSStrictGuardStackCheck.get()); MSStrictGuardStackCheck.reset(); PP.RemovePragmaHandler(MSFunction.get()); MSFunction.reset(); PP.RemovePragmaHandler(MSAllocText.get()); MSAllocText.reset(); PP.RemovePragmaHandler(MSRuntimeChecks.get()); MSRuntimeChecks.reset(); PP.RemovePragmaHandler(MSIntrinsic.get()); MSIntrinsic.reset(); PP.RemovePragmaHandler(MSOptimize.get()); MSOptimize.reset(); PP.RemovePragmaHandler(MSFenvAccess.get()); MSFenvAccess.reset(); } if (getLangOpts().CUDA) { PP.RemovePragmaHandler("clang", CUDAForceHostDeviceHandler.get()); CUDAForceHostDeviceHandler.reset(); } PP.RemovePragmaHandler("STDC", FPContractHandler.get()); FPContractHandler.reset(); PP.RemovePragmaHandler("STDC", STDCFenvAccessHandler.get()); STDCFenvAccessHandler.reset(); PP.RemovePragmaHandler("STDC", STDCFenvRoundHandler.get()); STDCFenvRoundHandler.reset(); PP.RemovePragmaHandler("STDC", STDCCXLIMITHandler.get()); STDCCXLIMITHandler.reset(); PP.RemovePragmaHandler("STDC", STDCUnknownHandler.get()); STDCUnknownHandler.reset(); PP.RemovePragmaHandler("clang", OptimizeHandler.get()); OptimizeHandler.reset(); PP.RemovePragmaHandler("clang", LoopHintHandler.get()); LoopHintHandler.reset(); PP.RemovePragmaHandler(UnrollHintHandler.get()); PP.RemovePragmaHandler("GCC", UnrollHintHandler.get()); UnrollHintHandler.reset(); PP.RemovePragmaHandler(NoUnrollHintHandler.get()); PP.RemovePragmaHandler("GCC", NoUnrollHintHandler.get()); NoUnrollHintHandler.reset(); PP.RemovePragmaHandler(UnrollAndJamHintHandler.get()); UnrollAndJamHintHandler.reset(); PP.RemovePragmaHandler(NoUnrollAndJamHintHandler.get()); NoUnrollAndJamHintHandler.reset(); PP.RemovePragmaHandler("clang", FPHandler.get()); FPHandler.reset(); PP.RemovePragmaHandler("clang", AttributePragmaHandler.get()); AttributePragmaHandler.reset(); PP.RemovePragmaHandler("clang", MaxTokensHerePragmaHandler.get()); MaxTokensHerePragmaHandler.reset(); PP.RemovePragmaHandler("clang", MaxTokensTotalPragmaHandler.get()); MaxTokensTotalPragmaHandler.reset(); if (getTargetInfo().getTriple().isRISCV()) { PP.RemovePragmaHandler("clang", RISCVPragmaHandler.get()); RISCVPragmaHandler.reset(); } } /// Handle the annotation token produced for #pragma unused(...) /// /// Each annot_pragma_unused is followed by the argument token so e.g. /// "#pragma unused(x,y)" becomes: /// annot_pragma_unused 'x' annot_pragma_unused 'y' void Parser::HandlePragmaUnused() { assert(Tok.is(tok::annot_pragma_unused)); SourceLocation UnusedLoc = ConsumeAnnotationToken(); Actions.ActOnPragmaUnused(Tok, getCurScope(), UnusedLoc); ConsumeToken(); // The argument token. } void Parser::HandlePragmaVisibility() { assert(Tok.is(tok::annot_pragma_vis)); const IdentifierInfo *VisType = static_cast(Tok.getAnnotationValue()); SourceLocation VisLoc = ConsumeAnnotationToken(); Actions.ActOnPragmaVisibility(VisType, VisLoc); } void Parser::HandlePragmaPack() { assert(Tok.is(tok::annot_pragma_pack)); Sema::PragmaPackInfo *Info = static_cast(Tok.getAnnotationValue()); SourceLocation PragmaLoc = Tok.getLocation(); ExprResult Alignment; if (Info->Alignment.is(tok::numeric_constant)) { Alignment = Actions.ActOnNumericConstant(Info->Alignment); if (Alignment.isInvalid()) { ConsumeAnnotationToken(); return; } } Actions.ActOnPragmaPack(PragmaLoc, Info->Action, Info->SlotLabel, Alignment.get()); // Consume the token after processing the pragma to enable pragma-specific // #include warnings. ConsumeAnnotationToken(); } void Parser::HandlePragmaMSStruct() { assert(Tok.is(tok::annot_pragma_msstruct)); PragmaMSStructKind Kind = static_cast( reinterpret_cast(Tok.getAnnotationValue())); Actions.ActOnPragmaMSStruct(Kind); ConsumeAnnotationToken(); } void Parser::HandlePragmaAlign() { assert(Tok.is(tok::annot_pragma_align)); Sema::PragmaOptionsAlignKind Kind = static_cast( reinterpret_cast(Tok.getAnnotationValue())); Actions.ActOnPragmaOptionsAlign(Kind, Tok.getLocation()); // Consume the token after processing the pragma to enable pragma-specific // #include warnings. ConsumeAnnotationToken(); } void Parser::HandlePragmaDump() { assert(Tok.is(tok::annot_pragma_dump)); ConsumeAnnotationToken(); if (Tok.is(tok::eod)) { PP.Diag(Tok, diag::warn_pragma_debug_missing_argument) << "dump"; } else if (NextToken().is(tok::eod)) { if (Tok.isNot(tok::identifier)) { PP.Diag(Tok, diag::warn_pragma_debug_unexpected_argument); ConsumeAnyToken(); ExpectAndConsume(tok::eod); return; } IdentifierInfo *II = Tok.getIdentifierInfo(); Actions.ActOnPragmaDump(getCurScope(), Tok.getLocation(), II); ConsumeToken(); } else { SourceLocation StartLoc = Tok.getLocation(); EnterExpressionEvaluationContext Ctx( Actions, Sema::ExpressionEvaluationContext::Unevaluated); ExprResult E = ParseExpression(); if (!E.isUsable() || E.get()->containsErrors()) { // Diagnostics were emitted during parsing. No action needed. } else if (E.get()->getDependence() != ExprDependence::None) { PP.Diag(StartLoc, diag::warn_pragma_debug_dependent_argument) << E.get()->isTypeDependent() << SourceRange(StartLoc, Tok.getLocation()); } else { Actions.ActOnPragmaDump(E.get()); } SkipUntil(tok::eod, StopBeforeMatch); } ExpectAndConsume(tok::eod); } void Parser::HandlePragmaWeak() { assert(Tok.is(tok::annot_pragma_weak)); SourceLocation PragmaLoc = ConsumeAnnotationToken(); Actions.ActOnPragmaWeakID(Tok.getIdentifierInfo(), PragmaLoc, Tok.getLocation()); ConsumeToken(); // The weak name. } void Parser::HandlePragmaWeakAlias() { assert(Tok.is(tok::annot_pragma_weakalias)); SourceLocation PragmaLoc = ConsumeAnnotationToken(); IdentifierInfo *WeakName = Tok.getIdentifierInfo(); SourceLocation WeakNameLoc = Tok.getLocation(); ConsumeToken(); IdentifierInfo *AliasName = Tok.getIdentifierInfo(); SourceLocation AliasNameLoc = Tok.getLocation(); ConsumeToken(); Actions.ActOnPragmaWeakAlias(WeakName, AliasName, PragmaLoc, WeakNameLoc, AliasNameLoc); } void Parser::HandlePragmaRedefineExtname() { assert(Tok.is(tok::annot_pragma_redefine_extname)); SourceLocation RedefLoc = ConsumeAnnotationToken(); IdentifierInfo *RedefName = Tok.getIdentifierInfo(); SourceLocation RedefNameLoc = Tok.getLocation(); ConsumeToken(); IdentifierInfo *AliasName = Tok.getIdentifierInfo(); SourceLocation AliasNameLoc = Tok.getLocation(); ConsumeToken(); Actions.ActOnPragmaRedefineExtname(RedefName, AliasName, RedefLoc, RedefNameLoc, AliasNameLoc); } void Parser::HandlePragmaFPContract() { assert(Tok.is(tok::annot_pragma_fp_contract)); tok::OnOffSwitch OOS = static_cast( reinterpret_cast(Tok.getAnnotationValue())); LangOptions::FPModeKind FPC; switch (OOS) { case tok::OOS_ON: FPC = LangOptions::FPM_On; break; case tok::OOS_OFF: FPC = LangOptions::FPM_Off; break; case tok::OOS_DEFAULT: FPC = getLangOpts().getDefaultFPContractMode(); break; } SourceLocation PragmaLoc = ConsumeAnnotationToken(); Actions.ActOnPragmaFPContract(PragmaLoc, FPC); } void Parser::HandlePragmaFloatControl() { assert(Tok.is(tok::annot_pragma_float_control)); // The value that is held on the PragmaFloatControlStack encodes // the PragmaFloatControl kind and the MSStackAction kind // into a single 32-bit word. The MsStackAction is the high 16 bits // and the FloatControl is the lower 16 bits. Use shift and bit-and // to decode the parts. uintptr_t Value = reinterpret_cast(Tok.getAnnotationValue()); Sema::PragmaMsStackAction Action = static_cast((Value >> 16) & 0xFFFF); PragmaFloatControlKind Kind = PragmaFloatControlKind(Value & 0xFFFF); SourceLocation PragmaLoc = ConsumeAnnotationToken(); Actions.ActOnPragmaFloatControl(PragmaLoc, Action, Kind); } void Parser::HandlePragmaFEnvAccess() { assert(Tok.is(tok::annot_pragma_fenv_access) || Tok.is(tok::annot_pragma_fenv_access_ms)); tok::OnOffSwitch OOS = static_cast( reinterpret_cast(Tok.getAnnotationValue())); bool IsEnabled; switch (OOS) { case tok::OOS_ON: IsEnabled = true; break; case tok::OOS_OFF: IsEnabled = false; break; case tok::OOS_DEFAULT: // FIXME: Add this cli option when it makes sense. IsEnabled = false; break; } SourceLocation PragmaLoc = ConsumeAnnotationToken(); Actions.ActOnPragmaFEnvAccess(PragmaLoc, IsEnabled); } void Parser::HandlePragmaFEnvRound() { assert(Tok.is(tok::annot_pragma_fenv_round)); auto RM = static_cast( reinterpret_cast(Tok.getAnnotationValue())); SourceLocation PragmaLoc = ConsumeAnnotationToken(); Actions.ActOnPragmaFEnvRound(PragmaLoc, RM); } void Parser::HandlePragmaCXLimitedRange() { assert(Tok.is(tok::annot_pragma_cx_limited_range)); tok::OnOffSwitch OOS = static_cast( reinterpret_cast(Tok.getAnnotationValue())); LangOptions::ComplexRangeKind Range; switch (OOS) { case tok::OOS_ON: Range = LangOptions::CX_Limited; break; case tok::OOS_OFF: Range = LangOptions::CX_Full; break; case tok::OOS_DEFAULT: // According to ISO C99 standard chapter 7.3.4, the default value // for the pragma is ``off'. -fcx-limited-range and -fcx-fortran-rules // control the default value of these pragmas. Range = getLangOpts().getComplexRange(); break; } SourceLocation PragmaLoc = ConsumeAnnotationToken(); Actions.ActOnPragmaCXLimitedRange(PragmaLoc, Range); } StmtResult Parser::HandlePragmaCaptured() { assert(Tok.is(tok::annot_pragma_captured)); ConsumeAnnotationToken(); if (Tok.isNot(tok::l_brace)) { PP.Diag(Tok, diag::err_expected) << tok::l_brace; return StmtError(); } SourceLocation Loc = Tok.getLocation(); ParseScope CapturedRegionScope(this, Scope::FnScope | Scope::DeclScope | Scope::CompoundStmtScope); Actions.ActOnCapturedRegionStart(Loc, getCurScope(), CR_Default, /*NumParams=*/1); StmtResult R = ParseCompoundStatement(); CapturedRegionScope.Exit(); if (R.isInvalid()) { Actions.ActOnCapturedRegionError(); return StmtError(); } return Actions.ActOnCapturedRegionEnd(R.get()); } namespace { enum OpenCLExtState : char { Disable, Enable, Begin, End }; typedef std::pair OpenCLExtData; } void Parser::HandlePragmaOpenCLExtension() { assert(Tok.is(tok::annot_pragma_opencl_extension)); OpenCLExtData *Data = static_cast(Tok.getAnnotationValue()); auto State = Data->second; auto Ident = Data->first; SourceLocation NameLoc = Tok.getLocation(); ConsumeAnnotationToken(); auto &Opt = Actions.getOpenCLOptions(); auto Name = Ident->getName(); // OpenCL 1.1 9.1: "The all variant sets the behavior for all extensions, // overriding all previously issued extension directives, but only if the // behavior is set to disable." if (Name == "all") { if (State == Disable) Opt.disableAll(); else PP.Diag(NameLoc, diag::warn_pragma_expected_predicate) << 1; } else if (State == Begin) { if (!Opt.isKnown(Name) || !Opt.isSupported(Name, getLangOpts())) { Opt.support(Name); // FIXME: Default behavior of the extension pragma is not defined. // Therefore, it should never be added by default. Opt.acceptsPragma(Name); } } else if (State == End) { // There is no behavior for this directive. We only accept this for // backward compatibility. } else if (!Opt.isKnown(Name) || !Opt.isWithPragma(Name)) PP.Diag(NameLoc, diag::warn_pragma_unknown_extension) << Ident; else if (Opt.isSupportedExtension(Name, getLangOpts())) Opt.enable(Name, State == Enable); else if (Opt.isSupportedCoreOrOptionalCore(Name, getLangOpts())) PP.Diag(NameLoc, diag::warn_pragma_extension_is_core) << Ident; else PP.Diag(NameLoc, diag::warn_pragma_unsupported_extension) << Ident; } void Parser::HandlePragmaMSPointersToMembers() { assert(Tok.is(tok::annot_pragma_ms_pointers_to_members)); LangOptions::PragmaMSPointersToMembersKind RepresentationMethod = static_cast( reinterpret_cast(Tok.getAnnotationValue())); SourceLocation PragmaLoc = ConsumeAnnotationToken(); Actions.ActOnPragmaMSPointersToMembers(RepresentationMethod, PragmaLoc); } void Parser::HandlePragmaMSVtorDisp() { assert(Tok.is(tok::annot_pragma_ms_vtordisp)); uintptr_t Value = reinterpret_cast(Tok.getAnnotationValue()); Sema::PragmaMsStackAction Action = static_cast((Value >> 16) & 0xFFFF); MSVtorDispMode Mode = MSVtorDispMode(Value & 0xFFFF); SourceLocation PragmaLoc = ConsumeAnnotationToken(); Actions.ActOnPragmaMSVtorDisp(Action, PragmaLoc, Mode); } void Parser::HandlePragmaMSPragma() { assert(Tok.is(tok::annot_pragma_ms_pragma)); // Grab the tokens out of the annotation and enter them into the stream. auto TheTokens = (std::pair, size_t> *)Tok.getAnnotationValue(); PP.EnterTokenStream(std::move(TheTokens->first), TheTokens->second, true, /*IsReinject=*/true); SourceLocation PragmaLocation = ConsumeAnnotationToken(); assert(Tok.isAnyIdentifier()); StringRef PragmaName = Tok.getIdentifierInfo()->getName(); PP.Lex(Tok); // pragma kind // Figure out which #pragma we're dealing with. The switch has no default // because lex shouldn't emit the annotation token for unrecognized pragmas. typedef bool (Parser::*PragmaHandler)(StringRef, SourceLocation); PragmaHandler Handler = llvm::StringSwitch(PragmaName) .Case("data_seg", &Parser::HandlePragmaMSSegment) .Case("bss_seg", &Parser::HandlePragmaMSSegment) .Case("const_seg", &Parser::HandlePragmaMSSegment) .Case("code_seg", &Parser::HandlePragmaMSSegment) .Case("section", &Parser::HandlePragmaMSSection) .Case("init_seg", &Parser::HandlePragmaMSInitSeg) .Case("strict_gs_check", &Parser::HandlePragmaMSStrictGuardStackCheck) .Case("function", &Parser::HandlePragmaMSFunction) .Case("alloc_text", &Parser::HandlePragmaMSAllocText) .Case("optimize", &Parser::HandlePragmaMSOptimize); if (!(this->*Handler)(PragmaName, PragmaLocation)) { // Pragma handling failed, and has been diagnosed. Slurp up the tokens // until eof (really end of line) to prevent follow-on errors. while (Tok.isNot(tok::eof)) PP.Lex(Tok); PP.Lex(Tok); } } bool Parser::HandlePragmaMSSection(StringRef PragmaName, SourceLocation PragmaLocation) { if (Tok.isNot(tok::l_paren)) { PP.Diag(PragmaLocation, diag::warn_pragma_expected_lparen) << PragmaName; return false; } PP.Lex(Tok); // ( // Parsing code for pragma section if (Tok.isNot(tok::string_literal)) { PP.Diag(PragmaLocation, diag::warn_pragma_expected_section_name) << PragmaName; return false; } ExprResult StringResult = ParseStringLiteralExpression(); if (StringResult.isInvalid()) return false; // Already diagnosed. StringLiteral *SegmentName = cast(StringResult.get()); if (SegmentName->getCharByteWidth() != 1) { PP.Diag(PragmaLocation, diag::warn_pragma_expected_non_wide_string) << PragmaName; return false; } int SectionFlags = ASTContext::PSF_Read; bool SectionFlagsAreDefault = true; while (Tok.is(tok::comma)) { PP.Lex(Tok); // , // Ignore "long" and "short". // They are undocumented, but widely used, section attributes which appear // to do nothing. if (Tok.is(tok::kw_long) || Tok.is(tok::kw_short)) { PP.Lex(Tok); // long/short continue; } if (!Tok.isAnyIdentifier()) { PP.Diag(PragmaLocation, diag::warn_pragma_expected_action_or_r_paren) << PragmaName; return false; } ASTContext::PragmaSectionFlag Flag = llvm::StringSwitch( Tok.getIdentifierInfo()->getName()) .Case("read", ASTContext::PSF_Read) .Case("write", ASTContext::PSF_Write) .Case("execute", ASTContext::PSF_Execute) .Case("shared", ASTContext::PSF_Invalid) .Case("nopage", ASTContext::PSF_Invalid) .Case("nocache", ASTContext::PSF_Invalid) .Case("discard", ASTContext::PSF_Invalid) .Case("remove", ASTContext::PSF_Invalid) .Default(ASTContext::PSF_None); if (Flag == ASTContext::PSF_None || Flag == ASTContext::PSF_Invalid) { PP.Diag(PragmaLocation, Flag == ASTContext::PSF_None ? diag::warn_pragma_invalid_specific_action : diag::warn_pragma_unsupported_action) << PragmaName << Tok.getIdentifierInfo()->getName(); return false; } SectionFlags |= Flag; SectionFlagsAreDefault = false; PP.Lex(Tok); // Identifier } // If no section attributes are specified, the section will be marked as // read/write. if (SectionFlagsAreDefault) SectionFlags |= ASTContext::PSF_Write; if (Tok.isNot(tok::r_paren)) { PP.Diag(PragmaLocation, diag::warn_pragma_expected_rparen) << PragmaName; return false; } PP.Lex(Tok); // ) if (Tok.isNot(tok::eof)) { PP.Diag(PragmaLocation, diag::warn_pragma_extra_tokens_at_eol) << PragmaName; return false; } PP.Lex(Tok); // eof Actions.ActOnPragmaMSSection(PragmaLocation, SectionFlags, SegmentName); return true; } bool Parser::HandlePragmaMSSegment(StringRef PragmaName, SourceLocation PragmaLocation) { if (Tok.isNot(tok::l_paren)) { PP.Diag(PragmaLocation, diag::warn_pragma_expected_lparen) << PragmaName; return false; } PP.Lex(Tok); // ( Sema::PragmaMsStackAction Action = Sema::PSK_Reset; StringRef SlotLabel; if (Tok.isAnyIdentifier()) { StringRef PushPop = Tok.getIdentifierInfo()->getName(); if (PushPop == "push") Action = Sema::PSK_Push; else if (PushPop == "pop") Action = Sema::PSK_Pop; else { PP.Diag(PragmaLocation, diag::warn_pragma_expected_section_push_pop_or_name) << PragmaName; return false; } if (Action != Sema::PSK_Reset) { PP.Lex(Tok); // push | pop if (Tok.is(tok::comma)) { PP.Lex(Tok); // , // If we've got a comma, we either need a label or a string. if (Tok.isAnyIdentifier()) { SlotLabel = Tok.getIdentifierInfo()->getName(); PP.Lex(Tok); // identifier if (Tok.is(tok::comma)) PP.Lex(Tok); else if (Tok.isNot(tok::r_paren)) { PP.Diag(PragmaLocation, diag::warn_pragma_expected_punc) << PragmaName; return false; } } } else if (Tok.isNot(tok::r_paren)) { PP.Diag(PragmaLocation, diag::warn_pragma_expected_punc) << PragmaName; return false; } } } // Grab the string literal for our section name. StringLiteral *SegmentName = nullptr; if (Tok.isNot(tok::r_paren)) { if (Tok.isNot(tok::string_literal)) { unsigned DiagID = Action != Sema::PSK_Reset ? !SlotLabel.empty() ? diag::warn_pragma_expected_section_name : diag::warn_pragma_expected_section_label_or_name : diag::warn_pragma_expected_section_push_pop_or_name; PP.Diag(PragmaLocation, DiagID) << PragmaName; return false; } ExprResult StringResult = ParseStringLiteralExpression(); if (StringResult.isInvalid()) return false; // Already diagnosed. SegmentName = cast(StringResult.get()); if (SegmentName->getCharByteWidth() != 1) { PP.Diag(PragmaLocation, diag::warn_pragma_expected_non_wide_string) << PragmaName; return false; } // Setting section "" has no effect if (SegmentName->getLength()) Action = (Sema::PragmaMsStackAction)(Action | Sema::PSK_Set); } if (Tok.isNot(tok::r_paren)) { PP.Diag(PragmaLocation, diag::warn_pragma_expected_rparen) << PragmaName; return false; } PP.Lex(Tok); // ) if (Tok.isNot(tok::eof)) { PP.Diag(PragmaLocation, diag::warn_pragma_extra_tokens_at_eol) << PragmaName; return false; } PP.Lex(Tok); // eof Actions.ActOnPragmaMSSeg(PragmaLocation, Action, SlotLabel, SegmentName, PragmaName); return true; } // #pragma init_seg({ compiler | lib | user | "section-name" [, func-name]} ) bool Parser::HandlePragmaMSInitSeg(StringRef PragmaName, SourceLocation PragmaLocation) { if (getTargetInfo().getTriple().getEnvironment() != llvm::Triple::MSVC) { PP.Diag(PragmaLocation, diag::warn_pragma_init_seg_unsupported_target); return false; } if (ExpectAndConsume(tok::l_paren, diag::warn_pragma_expected_lparen, PragmaName)) return false; // Parse either the known section names or the string section name. StringLiteral *SegmentName = nullptr; if (Tok.isAnyIdentifier()) { auto *II = Tok.getIdentifierInfo(); StringRef Section = llvm::StringSwitch(II->getName()) .Case("compiler", "\".CRT$XCC\"") .Case("lib", "\".CRT$XCL\"") .Case("user", "\".CRT$XCU\"") .Default(""); if (!Section.empty()) { // Pretend the user wrote the appropriate string literal here. Token Toks[1]; Toks[0].startToken(); Toks[0].setKind(tok::string_literal); Toks[0].setLocation(Tok.getLocation()); Toks[0].setLiteralData(Section.data()); Toks[0].setLength(Section.size()); SegmentName = cast(Actions.ActOnStringLiteral(Toks, nullptr).get()); PP.Lex(Tok); } } else if (Tok.is(tok::string_literal)) { ExprResult StringResult = ParseStringLiteralExpression(); if (StringResult.isInvalid()) return false; SegmentName = cast(StringResult.get()); if (SegmentName->getCharByteWidth() != 1) { PP.Diag(PragmaLocation, diag::warn_pragma_expected_non_wide_string) << PragmaName; return false; } // FIXME: Add support for the '[, func-name]' part of the pragma. } if (!SegmentName) { PP.Diag(PragmaLocation, diag::warn_pragma_expected_init_seg) << PragmaName; return false; } if (ExpectAndConsume(tok::r_paren, diag::warn_pragma_expected_rparen, PragmaName) || ExpectAndConsume(tok::eof, diag::warn_pragma_extra_tokens_at_eol, PragmaName)) return false; Actions.ActOnPragmaMSInitSeg(PragmaLocation, SegmentName); return true; } // #pragma strict_gs_check(pop) // #pragma strict_gs_check(push, "on" | "off") // #pragma strict_gs_check("on" | "off") bool Parser::HandlePragmaMSStrictGuardStackCheck( StringRef PragmaName, SourceLocation PragmaLocation) { if (ExpectAndConsume(tok::l_paren, diag::warn_pragma_expected_lparen, PragmaName)) return false; Sema::PragmaMsStackAction Action = Sema::PSK_Set; if (Tok.is(tok::identifier)) { StringRef PushPop = Tok.getIdentifierInfo()->getName(); if (PushPop == "push") { PP.Lex(Tok); Action = Sema::PSK_Push; if (ExpectAndConsume(tok::comma, diag::warn_pragma_expected_punc, PragmaName)) return false; } else if (PushPop == "pop") { PP.Lex(Tok); Action = Sema::PSK_Pop; } } bool Value = false; if (Action & Sema::PSK_Push || Action & Sema::PSK_Set) { const IdentifierInfo *II = Tok.getIdentifierInfo(); if (II && II->isStr("off")) { PP.Lex(Tok); Value = false; } else if (II && II->isStr("on")) { PP.Lex(Tok); Value = true; } else { PP.Diag(Tok.getLocation(), diag::warn_pragma_invalid_action) << PragmaName; return false; } } // Finish the pragma: ')' $ if (ExpectAndConsume(tok::r_paren, diag::warn_pragma_expected_rparen, PragmaName)) return false; if (ExpectAndConsume(tok::eof, diag::warn_pragma_extra_tokens_at_eol, PragmaName)) return false; Actions.ActOnPragmaMSStrictGuardStackCheck(PragmaLocation, Action, Value); return true; } bool Parser::HandlePragmaMSAllocText(StringRef PragmaName, SourceLocation PragmaLocation) { Token FirstTok = Tok; if (ExpectAndConsume(tok::l_paren, diag::warn_pragma_expected_lparen, PragmaName)) return false; StringRef Section; if (Tok.is(tok::string_literal)) { ExprResult StringResult = ParseStringLiteralExpression(); if (StringResult.isInvalid()) return false; // Already diagnosed. StringLiteral *SegmentName = cast(StringResult.get()); if (SegmentName->getCharByteWidth() != 1) { PP.Diag(PragmaLocation, diag::warn_pragma_expected_non_wide_string) << PragmaName; return false; } Section = SegmentName->getString(); } else if (Tok.is(tok::identifier)) { Section = Tok.getIdentifierInfo()->getName(); PP.Lex(Tok); } else { PP.Diag(PragmaLocation, diag::warn_pragma_expected_section_name) << PragmaName; return false; } if (ExpectAndConsume(tok::comma, diag::warn_pragma_expected_comma, PragmaName)) return false; SmallVector> Functions; while (true) { if (Tok.isNot(tok::identifier)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_identifier) << PragmaName; return false; } IdentifierInfo *II = Tok.getIdentifierInfo(); Functions.emplace_back(II, Tok.getLocation()); PP.Lex(Tok); if (Tok.isNot(tok::comma)) break; PP.Lex(Tok); } if (ExpectAndConsume(tok::r_paren, diag::warn_pragma_expected_rparen, PragmaName) || ExpectAndConsume(tok::eof, diag::warn_pragma_extra_tokens_at_eol, PragmaName)) return false; Actions.ActOnPragmaMSAllocText(FirstTok.getLocation(), Section, Functions); return true; } static std::string PragmaLoopHintString(Token PragmaName, Token Option) { StringRef Str = PragmaName.getIdentifierInfo()->getName(); std::string ClangLoopStr("clang loop "); if (Str == "loop" && Option.getIdentifierInfo()) ClangLoopStr += Option.getIdentifierInfo()->getName(); return std::string(llvm::StringSwitch(Str) .Case("loop", ClangLoopStr) .Case("unroll_and_jam", Str) .Case("unroll", Str) .Default("")); } bool Parser::HandlePragmaLoopHint(LoopHint &Hint) { assert(Tok.is(tok::annot_pragma_loop_hint)); PragmaLoopHintInfo *Info = static_cast(Tok.getAnnotationValue()); IdentifierInfo *PragmaNameInfo = Info->PragmaName.getIdentifierInfo(); Hint.PragmaNameLoc = IdentifierLoc::create( Actions.Context, Info->PragmaName.getLocation(), PragmaNameInfo); // It is possible that the loop hint has no option identifier, such as // #pragma unroll(4). IdentifierInfo *OptionInfo = Info->Option.is(tok::identifier) ? Info->Option.getIdentifierInfo() : nullptr; Hint.OptionLoc = IdentifierLoc::create( Actions.Context, Info->Option.getLocation(), OptionInfo); llvm::ArrayRef Toks = Info->Toks; // Return a valid hint if pragma unroll or nounroll were specified // without an argument. auto IsLoopHint = llvm::StringSwitch(PragmaNameInfo->getName()) .Cases("unroll", "nounroll", "unroll_and_jam", "nounroll_and_jam", true) .Default(false); if (Toks.empty() && IsLoopHint) { ConsumeAnnotationToken(); Hint.Range = Info->PragmaName.getLocation(); return true; } // The constant expression is always followed by an eof token, which increases // the TokSize by 1. assert(!Toks.empty() && "PragmaLoopHintInfo::Toks must contain at least one token."); // If no option is specified the argument is assumed to be a constant expr. bool OptionUnroll = false; bool OptionUnrollAndJam = false; bool OptionDistribute = false; bool OptionPipelineDisabled = false; bool StateOption = false; if (OptionInfo) { // Pragma Unroll does not specify an option. OptionUnroll = OptionInfo->isStr("unroll"); OptionUnrollAndJam = OptionInfo->isStr("unroll_and_jam"); OptionDistribute = OptionInfo->isStr("distribute"); OptionPipelineDisabled = OptionInfo->isStr("pipeline"); StateOption = llvm::StringSwitch(OptionInfo->getName()) .Case("vectorize", true) .Case("interleave", true) .Case("vectorize_predicate", true) .Default(false) || OptionUnroll || OptionUnrollAndJam || OptionDistribute || OptionPipelineDisabled; } bool AssumeSafetyArg = !OptionUnroll && !OptionUnrollAndJam && !OptionDistribute && !OptionPipelineDisabled; // Verify loop hint has an argument. if (Toks[0].is(tok::eof)) { ConsumeAnnotationToken(); Diag(Toks[0].getLocation(), diag::err_pragma_loop_missing_argument) << /*StateArgument=*/StateOption << /*FullKeyword=*/(OptionUnroll || OptionUnrollAndJam) << /*AssumeSafetyKeyword=*/AssumeSafetyArg; return false; } // Validate the argument. if (StateOption) { ConsumeAnnotationToken(); SourceLocation StateLoc = Toks[0].getLocation(); IdentifierInfo *StateInfo = Toks[0].getIdentifierInfo(); bool Valid = StateInfo && llvm::StringSwitch(StateInfo->getName()) .Case("disable", true) .Case("enable", !OptionPipelineDisabled) .Case("full", OptionUnroll || OptionUnrollAndJam) .Case("assume_safety", AssumeSafetyArg) .Default(false); if (!Valid) { if (OptionPipelineDisabled) { Diag(Toks[0].getLocation(), diag::err_pragma_pipeline_invalid_keyword); } else { Diag(Toks[0].getLocation(), diag::err_pragma_invalid_keyword) << /*FullKeyword=*/(OptionUnroll || OptionUnrollAndJam) << /*AssumeSafetyKeyword=*/AssumeSafetyArg; } return false; } if (Toks.size() > 2) Diag(Tok.getLocation(), diag::warn_pragma_extra_tokens_at_eol) << PragmaLoopHintString(Info->PragmaName, Info->Option); Hint.StateLoc = IdentifierLoc::create(Actions.Context, StateLoc, StateInfo); } else if (OptionInfo && OptionInfo->getName() == "vectorize_width") { PP.EnterTokenStream(Toks, /*DisableMacroExpansion=*/false, /*IsReinject=*/false); ConsumeAnnotationToken(); SourceLocation StateLoc = Toks[0].getLocation(); IdentifierInfo *StateInfo = Toks[0].getIdentifierInfo(); StringRef IsScalableStr = StateInfo ? StateInfo->getName() : ""; // Look for vectorize_width(fixed|scalable) if (IsScalableStr == "scalable" || IsScalableStr == "fixed") { PP.Lex(Tok); // Identifier if (Toks.size() > 2) { Diag(Tok.getLocation(), diag::warn_pragma_extra_tokens_at_eol) << PragmaLoopHintString(Info->PragmaName, Info->Option); while (Tok.isNot(tok::eof)) ConsumeAnyToken(); } Hint.StateLoc = IdentifierLoc::create(Actions.Context, StateLoc, StateInfo); ConsumeToken(); // Consume the constant expression eof terminator. } else { // Enter constant expression including eof terminator into token stream. ExprResult R = ParseConstantExpression(); if (R.isInvalid() && !Tok.is(tok::comma)) Diag(Toks[0].getLocation(), diag::note_pragma_loop_invalid_vectorize_option); bool Arg2Error = false; if (Tok.is(tok::comma)) { PP.Lex(Tok); // , StateInfo = Tok.getIdentifierInfo(); IsScalableStr = StateInfo->getName(); if (IsScalableStr != "scalable" && IsScalableStr != "fixed") { Diag(Tok.getLocation(), diag::err_pragma_loop_invalid_vectorize_option); Arg2Error = true; } else Hint.StateLoc = IdentifierLoc::create(Actions.Context, StateLoc, StateInfo); PP.Lex(Tok); // Identifier } // Tokens following an error in an ill-formed constant expression will // remain in the token stream and must be removed. if (Tok.isNot(tok::eof)) { Diag(Tok.getLocation(), diag::warn_pragma_extra_tokens_at_eol) << PragmaLoopHintString(Info->PragmaName, Info->Option); while (Tok.isNot(tok::eof)) ConsumeAnyToken(); } ConsumeToken(); // Consume the constant expression eof terminator. if (Arg2Error || R.isInvalid() || Actions.CheckLoopHintExpr(R.get(), Toks[0].getLocation())) return false; // Argument is a constant expression with an integer type. Hint.ValueExpr = R.get(); } } else { // Enter constant expression including eof terminator into token stream. PP.EnterTokenStream(Toks, /*DisableMacroExpansion=*/false, /*IsReinject=*/false); ConsumeAnnotationToken(); ExprResult R = ParseConstantExpression(); // Tokens following an error in an ill-formed constant expression will // remain in the token stream and must be removed. if (Tok.isNot(tok::eof)) { Diag(Tok.getLocation(), diag::warn_pragma_extra_tokens_at_eol) << PragmaLoopHintString(Info->PragmaName, Info->Option); while (Tok.isNot(tok::eof)) ConsumeAnyToken(); } ConsumeToken(); // Consume the constant expression eof terminator. if (R.isInvalid() || Actions.CheckLoopHintExpr(R.get(), Toks[0].getLocation())) return false; // Argument is a constant expression with an integer type. Hint.ValueExpr = R.get(); } Hint.Range = SourceRange(Info->PragmaName.getLocation(), Info->Toks.back().getLocation()); return true; } namespace { struct PragmaAttributeInfo { enum ActionType { Push, Pop, Attribute }; ParsedAttributes &Attributes; ActionType Action; const IdentifierInfo *Namespace = nullptr; ArrayRef Tokens; PragmaAttributeInfo(ParsedAttributes &Attributes) : Attributes(Attributes) {} }; #include "clang/Parse/AttrSubMatchRulesParserStringSwitches.inc" } // end anonymous namespace static StringRef getIdentifier(const Token &Tok) { if (Tok.is(tok::identifier)) return Tok.getIdentifierInfo()->getName(); const char *S = tok::getKeywordSpelling(Tok.getKind()); if (!S) return ""; return S; } static bool isAbstractAttrMatcherRule(attr::SubjectMatchRule Rule) { using namespace attr; switch (Rule) { #define ATTR_MATCH_RULE(Value, Spelling, IsAbstract) \ case Value: \ return IsAbstract; #include "clang/Basic/AttrSubMatchRulesList.inc" } llvm_unreachable("Invalid attribute subject match rule"); return false; } static void diagnoseExpectedAttributeSubjectSubRule( Parser &PRef, attr::SubjectMatchRule PrimaryRule, StringRef PrimaryRuleName, SourceLocation SubRuleLoc) { auto Diagnostic = PRef.Diag(SubRuleLoc, diag::err_pragma_attribute_expected_subject_sub_identifier) << PrimaryRuleName; if (const char *SubRules = validAttributeSubjectMatchSubRules(PrimaryRule)) Diagnostic << /*SubRulesSupported=*/1 << SubRules; else Diagnostic << /*SubRulesSupported=*/0; } static void diagnoseUnknownAttributeSubjectSubRule( Parser &PRef, attr::SubjectMatchRule PrimaryRule, StringRef PrimaryRuleName, StringRef SubRuleName, SourceLocation SubRuleLoc) { auto Diagnostic = PRef.Diag(SubRuleLoc, diag::err_pragma_attribute_unknown_subject_sub_rule) << SubRuleName << PrimaryRuleName; if (const char *SubRules = validAttributeSubjectMatchSubRules(PrimaryRule)) Diagnostic << /*SubRulesSupported=*/1 << SubRules; else Diagnostic << /*SubRulesSupported=*/0; } bool Parser::ParsePragmaAttributeSubjectMatchRuleSet( attr::ParsedSubjectMatchRuleSet &SubjectMatchRules, SourceLocation &AnyLoc, SourceLocation &LastMatchRuleEndLoc) { bool IsAny = false; BalancedDelimiterTracker AnyParens(*this, tok::l_paren); if (getIdentifier(Tok) == "any") { AnyLoc = ConsumeToken(); IsAny = true; if (AnyParens.expectAndConsume()) return true; } do { // Parse the subject matcher rule. StringRef Name = getIdentifier(Tok); if (Name.empty()) { Diag(Tok, diag::err_pragma_attribute_expected_subject_identifier); return true; } std::pair, std::optional (*)(StringRef, bool)> Rule = isAttributeSubjectMatchRule(Name); if (!Rule.first) { Diag(Tok, diag::err_pragma_attribute_unknown_subject_rule) << Name; return true; } attr::SubjectMatchRule PrimaryRule = *Rule.first; SourceLocation RuleLoc = ConsumeToken(); BalancedDelimiterTracker Parens(*this, tok::l_paren); if (isAbstractAttrMatcherRule(PrimaryRule)) { if (Parens.expectAndConsume()) return true; } else if (Parens.consumeOpen()) { if (!SubjectMatchRules .insert( std::make_pair(PrimaryRule, SourceRange(RuleLoc, RuleLoc))) .second) Diag(RuleLoc, diag::err_pragma_attribute_duplicate_subject) << Name << FixItHint::CreateRemoval(SourceRange( RuleLoc, Tok.is(tok::comma) ? Tok.getLocation() : RuleLoc)); LastMatchRuleEndLoc = RuleLoc; continue; } // Parse the sub-rules. StringRef SubRuleName = getIdentifier(Tok); if (SubRuleName.empty()) { diagnoseExpectedAttributeSubjectSubRule(*this, PrimaryRule, Name, Tok.getLocation()); return true; } attr::SubjectMatchRule SubRule; if (SubRuleName == "unless") { SourceLocation SubRuleLoc = ConsumeToken(); BalancedDelimiterTracker Parens(*this, tok::l_paren); if (Parens.expectAndConsume()) return true; SubRuleName = getIdentifier(Tok); if (SubRuleName.empty()) { diagnoseExpectedAttributeSubjectSubRule(*this, PrimaryRule, Name, SubRuleLoc); return true; } auto SubRuleOrNone = Rule.second(SubRuleName, /*IsUnless=*/true); if (!SubRuleOrNone) { std::string SubRuleUnlessName = "unless(" + SubRuleName.str() + ")"; diagnoseUnknownAttributeSubjectSubRule(*this, PrimaryRule, Name, SubRuleUnlessName, SubRuleLoc); return true; } SubRule = *SubRuleOrNone; ConsumeToken(); if (Parens.consumeClose()) return true; } else { auto SubRuleOrNone = Rule.second(SubRuleName, /*IsUnless=*/false); if (!SubRuleOrNone) { diagnoseUnknownAttributeSubjectSubRule(*this, PrimaryRule, Name, SubRuleName, Tok.getLocation()); return true; } SubRule = *SubRuleOrNone; ConsumeToken(); } SourceLocation RuleEndLoc = Tok.getLocation(); LastMatchRuleEndLoc = RuleEndLoc; if (Parens.consumeClose()) return true; if (!SubjectMatchRules .insert(std::make_pair(SubRule, SourceRange(RuleLoc, RuleEndLoc))) .second) { Diag(RuleLoc, diag::err_pragma_attribute_duplicate_subject) << attr::getSubjectMatchRuleSpelling(SubRule) << FixItHint::CreateRemoval(SourceRange( RuleLoc, Tok.is(tok::comma) ? Tok.getLocation() : RuleEndLoc)); continue; } } while (IsAny && TryConsumeToken(tok::comma)); if (IsAny) if (AnyParens.consumeClose()) return true; return false; } namespace { /// Describes the stage at which attribute subject rule parsing was interrupted. enum class MissingAttributeSubjectRulesRecoveryPoint { Comma, ApplyTo, Equals, Any, None, }; MissingAttributeSubjectRulesRecoveryPoint getAttributeSubjectRulesRecoveryPointForToken(const Token &Tok) { if (const auto *II = Tok.getIdentifierInfo()) { if (II->isStr("apply_to")) return MissingAttributeSubjectRulesRecoveryPoint::ApplyTo; if (II->isStr("any")) return MissingAttributeSubjectRulesRecoveryPoint::Any; } if (Tok.is(tok::equal)) return MissingAttributeSubjectRulesRecoveryPoint::Equals; return MissingAttributeSubjectRulesRecoveryPoint::None; } /// Creates a diagnostic for the attribute subject rule parsing diagnostic that /// suggests the possible attribute subject rules in a fix-it together with /// any other missing tokens. DiagnosticBuilder createExpectedAttributeSubjectRulesTokenDiagnostic( unsigned DiagID, ParsedAttributes &Attrs, MissingAttributeSubjectRulesRecoveryPoint Point, Parser &PRef) { SourceLocation Loc = PRef.getEndOfPreviousToken(); if (Loc.isInvalid()) Loc = PRef.getCurToken().getLocation(); auto Diagnostic = PRef.Diag(Loc, DiagID); std::string FixIt; MissingAttributeSubjectRulesRecoveryPoint EndPoint = getAttributeSubjectRulesRecoveryPointForToken(PRef.getCurToken()); if (Point == MissingAttributeSubjectRulesRecoveryPoint::Comma) FixIt = ", "; if (Point <= MissingAttributeSubjectRulesRecoveryPoint::ApplyTo && EndPoint > MissingAttributeSubjectRulesRecoveryPoint::ApplyTo) FixIt += "apply_to"; if (Point <= MissingAttributeSubjectRulesRecoveryPoint::Equals && EndPoint > MissingAttributeSubjectRulesRecoveryPoint::Equals) FixIt += " = "; SourceRange FixItRange(Loc); if (EndPoint == MissingAttributeSubjectRulesRecoveryPoint::None) { // Gather the subject match rules that are supported by the attribute. // Add all the possible rules initially. llvm::BitVector IsMatchRuleAvailable(attr::SubjectMatchRule_Last + 1, true); // Remove the ones that are not supported by any of the attributes. for (const ParsedAttr &Attribute : Attrs) { SmallVector, 4> MatchRules; Attribute.getMatchRules(PRef.getLangOpts(), MatchRules); llvm::BitVector IsSupported(attr::SubjectMatchRule_Last + 1); for (const auto &Rule : MatchRules) { // Ensure that the missing rule is reported in the fix-it only when it's // supported in the current language mode. if (!Rule.second) continue; IsSupported[Rule.first] = true; } IsMatchRuleAvailable &= IsSupported; } if (IsMatchRuleAvailable.count() == 0) { // FIXME: We can emit a "fix-it" with a subject list placeholder when // placeholders will be supported by the fix-its. return Diagnostic; } FixIt += "any("; bool NeedsComma = false; for (unsigned I = 0; I <= attr::SubjectMatchRule_Last; I++) { if (!IsMatchRuleAvailable[I]) continue; if (NeedsComma) FixIt += ", "; else NeedsComma = true; FixIt += attr::getSubjectMatchRuleSpelling( static_cast(I)); } FixIt += ")"; // Check if we need to remove the range PRef.SkipUntil(tok::eof, Parser::StopBeforeMatch); FixItRange.setEnd(PRef.getCurToken().getLocation()); } if (FixItRange.getBegin() == FixItRange.getEnd()) Diagnostic << FixItHint::CreateInsertion(FixItRange.getBegin(), FixIt); else Diagnostic << FixItHint::CreateReplacement( CharSourceRange::getCharRange(FixItRange), FixIt); return Diagnostic; } } // end anonymous namespace void Parser::HandlePragmaAttribute() { assert(Tok.is(tok::annot_pragma_attribute) && "Expected #pragma attribute annotation token"); SourceLocation PragmaLoc = Tok.getLocation(); auto *Info = static_cast(Tok.getAnnotationValue()); if (Info->Action == PragmaAttributeInfo::Pop) { ConsumeAnnotationToken(); Actions.ActOnPragmaAttributePop(PragmaLoc, Info->Namespace); return; } // Parse the actual attribute with its arguments. assert((Info->Action == PragmaAttributeInfo::Push || Info->Action == PragmaAttributeInfo::Attribute) && "Unexpected #pragma attribute command"); if (Info->Action == PragmaAttributeInfo::Push && Info->Tokens.empty()) { ConsumeAnnotationToken(); Actions.ActOnPragmaAttributeEmptyPush(PragmaLoc, Info->Namespace); return; } PP.EnterTokenStream(Info->Tokens, /*DisableMacroExpansion=*/false, /*IsReinject=*/false); ConsumeAnnotationToken(); ParsedAttributes &Attrs = Info->Attributes; Attrs.clearListOnly(); auto SkipToEnd = [this]() { SkipUntil(tok::eof, StopBeforeMatch); ConsumeToken(); }; if ((Tok.is(tok::l_square) && NextToken().is(tok::l_square)) || Tok.isRegularKeywordAttribute()) { // Parse the CXX11 style attribute. ParseCXX11AttributeSpecifier(Attrs); } else if (Tok.is(tok::kw___attribute)) { ConsumeToken(); if (ExpectAndConsume(tok::l_paren, diag::err_expected_lparen_after, "attribute")) return SkipToEnd(); if (ExpectAndConsume(tok::l_paren, diag::err_expected_lparen_after, "(")) return SkipToEnd(); // FIXME: The practical usefulness of completion here is limited because // we only get here if the line has balanced parens. if (Tok.is(tok::code_completion)) { cutOffParsing(); // FIXME: suppress completion of unsupported attributes? Actions.CodeCompleteAttribute(AttributeCommonInfo::Syntax::AS_GNU); return SkipToEnd(); } // Parse the comma-separated list of attributes. do { if (Tok.isNot(tok::identifier)) { Diag(Tok, diag::err_pragma_attribute_expected_attribute_name); SkipToEnd(); return; } IdentifierInfo *AttrName = Tok.getIdentifierInfo(); SourceLocation AttrNameLoc = ConsumeToken(); if (Tok.isNot(tok::l_paren)) Attrs.addNew(AttrName, AttrNameLoc, nullptr, AttrNameLoc, nullptr, 0, ParsedAttr::Form::GNU()); else ParseGNUAttributeArgs(AttrName, AttrNameLoc, Attrs, /*EndLoc=*/nullptr, /*ScopeName=*/nullptr, /*ScopeLoc=*/SourceLocation(), ParsedAttr::Form::GNU(), /*Declarator=*/nullptr); } while (TryConsumeToken(tok::comma)); if (ExpectAndConsume(tok::r_paren)) return SkipToEnd(); if (ExpectAndConsume(tok::r_paren)) return SkipToEnd(); } else if (Tok.is(tok::kw___declspec)) { ParseMicrosoftDeclSpecs(Attrs); } else { Diag(Tok, diag::err_pragma_attribute_expected_attribute_syntax); if (Tok.getIdentifierInfo()) { // If we suspect that this is an attribute suggest the use of // '__attribute__'. if (ParsedAttr::getParsedKind( Tok.getIdentifierInfo(), /*ScopeName=*/nullptr, ParsedAttr::AS_GNU) != ParsedAttr::UnknownAttribute) { SourceLocation InsertStartLoc = Tok.getLocation(); ConsumeToken(); if (Tok.is(tok::l_paren)) { ConsumeAnyToken(); SkipUntil(tok::r_paren, StopBeforeMatch); if (Tok.isNot(tok::r_paren)) return SkipToEnd(); } Diag(Tok, diag::note_pragma_attribute_use_attribute_kw) << FixItHint::CreateInsertion(InsertStartLoc, "__attribute__((") << FixItHint::CreateInsertion(Tok.getEndLoc(), "))"); } } SkipToEnd(); return; } if (Attrs.empty() || Attrs.begin()->isInvalid()) { SkipToEnd(); return; } for (const ParsedAttr &Attribute : Attrs) { if (!Attribute.isSupportedByPragmaAttribute()) { Diag(PragmaLoc, diag::err_pragma_attribute_unsupported_attribute) << Attribute; SkipToEnd(); return; } } // Parse the subject-list. if (!TryConsumeToken(tok::comma)) { createExpectedAttributeSubjectRulesTokenDiagnostic( diag::err_expected, Attrs, MissingAttributeSubjectRulesRecoveryPoint::Comma, *this) << tok::comma; SkipToEnd(); return; } if (Tok.isNot(tok::identifier)) { createExpectedAttributeSubjectRulesTokenDiagnostic( diag::err_pragma_attribute_invalid_subject_set_specifier, Attrs, MissingAttributeSubjectRulesRecoveryPoint::ApplyTo, *this); SkipToEnd(); return; } const IdentifierInfo *II = Tok.getIdentifierInfo(); if (!II->isStr("apply_to")) { createExpectedAttributeSubjectRulesTokenDiagnostic( diag::err_pragma_attribute_invalid_subject_set_specifier, Attrs, MissingAttributeSubjectRulesRecoveryPoint::ApplyTo, *this); SkipToEnd(); return; } ConsumeToken(); if (!TryConsumeToken(tok::equal)) { createExpectedAttributeSubjectRulesTokenDiagnostic( diag::err_expected, Attrs, MissingAttributeSubjectRulesRecoveryPoint::Equals, *this) << tok::equal; SkipToEnd(); return; } attr::ParsedSubjectMatchRuleSet SubjectMatchRules; SourceLocation AnyLoc, LastMatchRuleEndLoc; if (ParsePragmaAttributeSubjectMatchRuleSet(SubjectMatchRules, AnyLoc, LastMatchRuleEndLoc)) { SkipToEnd(); return; } // Tokens following an ill-formed attribute will remain in the token stream // and must be removed. if (Tok.isNot(tok::eof)) { Diag(Tok, diag::err_pragma_attribute_extra_tokens_after_attribute); SkipToEnd(); return; } // Consume the eof terminator token. ConsumeToken(); // Handle a mixed push/attribute by desurging to a push, then an attribute. if (Info->Action == PragmaAttributeInfo::Push) Actions.ActOnPragmaAttributeEmptyPush(PragmaLoc, Info->Namespace); for (ParsedAttr &Attribute : Attrs) { Actions.ActOnPragmaAttributeAttribute(Attribute, PragmaLoc, SubjectMatchRules); } } // #pragma GCC visibility comes in two variants: // 'push' '(' [visibility] ')' // 'pop' void PragmaGCCVisibilityHandler::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &VisTok) { SourceLocation VisLoc = VisTok.getLocation(); Token Tok; PP.LexUnexpandedToken(Tok); const IdentifierInfo *PushPop = Tok.getIdentifierInfo(); const IdentifierInfo *VisType; if (PushPop && PushPop->isStr("pop")) { VisType = nullptr; } else if (PushPop && PushPop->isStr("push")) { PP.LexUnexpandedToken(Tok); if (Tok.isNot(tok::l_paren)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_lparen) << "visibility"; return; } PP.LexUnexpandedToken(Tok); VisType = Tok.getIdentifierInfo(); if (!VisType) { PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_identifier) << "visibility"; return; } PP.LexUnexpandedToken(Tok); if (Tok.isNot(tok::r_paren)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_rparen) << "visibility"; return; } } else { PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_identifier) << "visibility"; return; } SourceLocation EndLoc = Tok.getLocation(); PP.LexUnexpandedToken(Tok); if (Tok.isNot(tok::eod)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_extra_tokens_at_eol) << "visibility"; return; } auto Toks = std::make_unique(1); Toks[0].startToken(); Toks[0].setKind(tok::annot_pragma_vis); Toks[0].setLocation(VisLoc); Toks[0].setAnnotationEndLoc(EndLoc); Toks[0].setAnnotationValue( const_cast(static_cast(VisType))); PP.EnterTokenStream(std::move(Toks), 1, /*DisableMacroExpansion=*/true, /*IsReinject=*/false); } // #pragma pack(...) comes in the following delicious flavors: // pack '(' [integer] ')' // pack '(' 'show' ')' // pack '(' ('push' | 'pop') [',' identifier] [, integer] ')' void PragmaPackHandler::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &PackTok) { SourceLocation PackLoc = PackTok.getLocation(); Token Tok; PP.Lex(Tok); if (Tok.isNot(tok::l_paren)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_lparen) << "pack"; return; } Sema::PragmaMsStackAction Action = Sema::PSK_Reset; StringRef SlotLabel; Token Alignment; Alignment.startToken(); PP.Lex(Tok); if (Tok.is(tok::numeric_constant)) { Alignment = Tok; PP.Lex(Tok); // In MSVC/gcc, #pragma pack(4) sets the alignment without affecting // the push/pop stack. // In Apple gcc/XL, #pragma pack(4) is equivalent to #pragma pack(push, 4) Action = (PP.getLangOpts().ApplePragmaPack || PP.getLangOpts().XLPragmaPack) ? Sema::PSK_Push_Set : Sema::PSK_Set; } else if (Tok.is(tok::identifier)) { const IdentifierInfo *II = Tok.getIdentifierInfo(); if (II->isStr("show")) { Action = Sema::PSK_Show; PP.Lex(Tok); } else { if (II->isStr("push")) { Action = Sema::PSK_Push; } else if (II->isStr("pop")) { Action = Sema::PSK_Pop; } else { PP.Diag(Tok.getLocation(), diag::warn_pragma_invalid_action) << "pack"; return; } PP.Lex(Tok); if (Tok.is(tok::comma)) { PP.Lex(Tok); if (Tok.is(tok::numeric_constant)) { Action = (Sema::PragmaMsStackAction)(Action | Sema::PSK_Set); Alignment = Tok; PP.Lex(Tok); } else if (Tok.is(tok::identifier)) { SlotLabel = Tok.getIdentifierInfo()->getName(); PP.Lex(Tok); if (Tok.is(tok::comma)) { PP.Lex(Tok); if (Tok.isNot(tok::numeric_constant)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_pack_malformed); return; } Action = (Sema::PragmaMsStackAction)(Action | Sema::PSK_Set); Alignment = Tok; PP.Lex(Tok); } } else { PP.Diag(Tok.getLocation(), diag::warn_pragma_pack_malformed); return; } } } } else if (PP.getLangOpts().ApplePragmaPack || PP.getLangOpts().XLPragmaPack) { // In MSVC/gcc, #pragma pack() resets the alignment without affecting // the push/pop stack. // In Apple gcc and IBM XL, #pragma pack() is equivalent to #pragma // pack(pop). Action = Sema::PSK_Pop; } if (Tok.isNot(tok::r_paren)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_rparen) << "pack"; return; } SourceLocation RParenLoc = Tok.getLocation(); PP.Lex(Tok); if (Tok.isNot(tok::eod)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_extra_tokens_at_eol) << "pack"; return; } Sema::PragmaPackInfo *Info = PP.getPreprocessorAllocator().Allocate(1); Info->Action = Action; Info->SlotLabel = SlotLabel; Info->Alignment = Alignment; MutableArrayRef Toks(PP.getPreprocessorAllocator().Allocate(1), 1); Toks[0].startToken(); Toks[0].setKind(tok::annot_pragma_pack); Toks[0].setLocation(PackLoc); Toks[0].setAnnotationEndLoc(RParenLoc); Toks[0].setAnnotationValue(static_cast(Info)); PP.EnterTokenStream(Toks, /*DisableMacroExpansion=*/true, /*IsReinject=*/false); } // #pragma ms_struct on // #pragma ms_struct off void PragmaMSStructHandler::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &MSStructTok) { PragmaMSStructKind Kind = PMSST_OFF; Token Tok; PP.Lex(Tok); if (Tok.isNot(tok::identifier)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_ms_struct); return; } SourceLocation EndLoc = Tok.getLocation(); const IdentifierInfo *II = Tok.getIdentifierInfo(); if (II->isStr("on")) { Kind = PMSST_ON; PP.Lex(Tok); } else if (II->isStr("off") || II->isStr("reset")) PP.Lex(Tok); else { PP.Diag(Tok.getLocation(), diag::warn_pragma_ms_struct); return; } if (Tok.isNot(tok::eod)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_extra_tokens_at_eol) << "ms_struct"; return; } MutableArrayRef Toks(PP.getPreprocessorAllocator().Allocate(1), 1); Toks[0].startToken(); Toks[0].setKind(tok::annot_pragma_msstruct); Toks[0].setLocation(MSStructTok.getLocation()); Toks[0].setAnnotationEndLoc(EndLoc); Toks[0].setAnnotationValue(reinterpret_cast( static_cast(Kind))); PP.EnterTokenStream(Toks, /*DisableMacroExpansion=*/true, /*IsReinject=*/false); } // #pragma clang section bss="abc" data="" rodata="def" text="" relro="" void PragmaClangSectionHandler::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) { Token Tok; auto SecKind = Sema::PragmaClangSectionKind::PCSK_Invalid; PP.Lex(Tok); // eat 'section' while (Tok.isNot(tok::eod)) { if (Tok.isNot(tok::identifier)) { PP.Diag(Tok.getLocation(), diag::err_pragma_expected_clang_section_name) << "clang section"; return; } const IdentifierInfo *SecType = Tok.getIdentifierInfo(); if (SecType->isStr("bss")) SecKind = Sema::PragmaClangSectionKind::PCSK_BSS; else if (SecType->isStr("data")) SecKind = Sema::PragmaClangSectionKind::PCSK_Data; else if (SecType->isStr("rodata")) SecKind = Sema::PragmaClangSectionKind::PCSK_Rodata; else if (SecType->isStr("relro")) SecKind = Sema::PragmaClangSectionKind::PCSK_Relro; else if (SecType->isStr("text")) SecKind = Sema::PragmaClangSectionKind::PCSK_Text; else { PP.Diag(Tok.getLocation(), diag::err_pragma_expected_clang_section_name) << "clang section"; return; } SourceLocation PragmaLocation = Tok.getLocation(); PP.Lex(Tok); // eat ['bss'|'data'|'rodata'|'text'] if (Tok.isNot(tok::equal)) { PP.Diag(Tok.getLocation(), diag::err_pragma_clang_section_expected_equal) << SecKind; return; } std::string SecName; if (!PP.LexStringLiteral(Tok, SecName, "pragma clang section", false)) return; Actions.ActOnPragmaClangSection( PragmaLocation, (SecName.size() ? Sema::PragmaClangSectionAction::PCSA_Set : Sema::PragmaClangSectionAction::PCSA_Clear), SecKind, SecName); } } // #pragma 'align' '=' {'native','natural','mac68k','power','reset'} // #pragma 'options 'align' '=' {'native','natural','mac68k','power','reset'} // #pragma 'align' '(' {'native','natural','mac68k','power','reset'} ')' static void ParseAlignPragma(Preprocessor &PP, Token &FirstTok, bool IsOptions) { Token Tok; if (IsOptions) { PP.Lex(Tok); if (Tok.isNot(tok::identifier) || !Tok.getIdentifierInfo()->isStr("align")) { PP.Diag(Tok.getLocation(), diag::warn_pragma_options_expected_align); return; } } PP.Lex(Tok); if (PP.getLangOpts().XLPragmaPack) { if (Tok.isNot(tok::l_paren)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_lparen) << "align"; return; } } else if (Tok.isNot(tok::equal)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_align_expected_equal) << IsOptions; return; } PP.Lex(Tok); if (Tok.isNot(tok::identifier)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_identifier) << (IsOptions ? "options" : "align"); return; } Sema::PragmaOptionsAlignKind Kind = Sema::POAK_Natural; const IdentifierInfo *II = Tok.getIdentifierInfo(); if (II->isStr("native")) Kind = Sema::POAK_Native; else if (II->isStr("natural")) Kind = Sema::POAK_Natural; else if (II->isStr("packed")) Kind = Sema::POAK_Packed; else if (II->isStr("power")) Kind = Sema::POAK_Power; else if (II->isStr("mac68k")) Kind = Sema::POAK_Mac68k; else if (II->isStr("reset")) Kind = Sema::POAK_Reset; else { PP.Diag(Tok.getLocation(), diag::warn_pragma_align_invalid_option) << IsOptions; return; } if (PP.getLangOpts().XLPragmaPack) { PP.Lex(Tok); if (Tok.isNot(tok::r_paren)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_rparen) << "align"; return; } } SourceLocation EndLoc = Tok.getLocation(); PP.Lex(Tok); if (Tok.isNot(tok::eod)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_extra_tokens_at_eol) << (IsOptions ? "options" : "align"); return; } MutableArrayRef Toks(PP.getPreprocessorAllocator().Allocate(1), 1); Toks[0].startToken(); Toks[0].setKind(tok::annot_pragma_align); Toks[0].setLocation(FirstTok.getLocation()); Toks[0].setAnnotationEndLoc(EndLoc); Toks[0].setAnnotationValue(reinterpret_cast( static_cast(Kind))); PP.EnterTokenStream(Toks, /*DisableMacroExpansion=*/true, /*IsReinject=*/false); } void PragmaAlignHandler::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &AlignTok) { ParseAlignPragma(PP, AlignTok, /*IsOptions=*/false); } void PragmaOptionsHandler::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &OptionsTok) { ParseAlignPragma(PP, OptionsTok, /*IsOptions=*/true); } // #pragma unused(identifier) void PragmaUnusedHandler::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &UnusedTok) { // FIXME: Should we be expanding macros here? My guess is no. SourceLocation UnusedLoc = UnusedTok.getLocation(); // Lex the left '('. Token Tok; PP.Lex(Tok); if (Tok.isNot(tok::l_paren)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_lparen) << "unused"; return; } // Lex the declaration reference(s). SmallVector Identifiers; SourceLocation RParenLoc; bool LexID = true; while (true) { PP.Lex(Tok); if (LexID) { if (Tok.is(tok::identifier)) { Identifiers.push_back(Tok); LexID = false; continue; } // Illegal token! PP.Diag(Tok.getLocation(), diag::warn_pragma_unused_expected_var); return; } // We are execting a ')' or a ','. if (Tok.is(tok::comma)) { LexID = true; continue; } if (Tok.is(tok::r_paren)) { RParenLoc = Tok.getLocation(); break; } // Illegal token! PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_punc) << "unused"; return; } PP.Lex(Tok); if (Tok.isNot(tok::eod)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_extra_tokens_at_eol) << "unused"; return; } // Verify that we have a location for the right parenthesis. assert(RParenLoc.isValid() && "Valid '#pragma unused' must have ')'"); assert(!Identifiers.empty() && "Valid '#pragma unused' must have arguments"); // For each identifier token, insert into the token stream a // annot_pragma_unused token followed by the identifier token. // This allows us to cache a "#pragma unused" that occurs inside an inline // C++ member function. MutableArrayRef Toks( PP.getPreprocessorAllocator().Allocate(2 * Identifiers.size()), 2 * Identifiers.size()); for (unsigned i=0; i != Identifiers.size(); i++) { Token &pragmaUnusedTok = Toks[2*i], &idTok = Toks[2*i+1]; pragmaUnusedTok.startToken(); pragmaUnusedTok.setKind(tok::annot_pragma_unused); pragmaUnusedTok.setLocation(UnusedLoc); idTok = Identifiers[i]; } PP.EnterTokenStream(Toks, /*DisableMacroExpansion=*/true, /*IsReinject=*/false); } // #pragma weak identifier // #pragma weak identifier '=' identifier void PragmaWeakHandler::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &WeakTok) { SourceLocation WeakLoc = WeakTok.getLocation(); Token Tok; PP.Lex(Tok); if (Tok.isNot(tok::identifier)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_identifier) << "weak"; return; } Token WeakName = Tok; bool HasAlias = false; Token AliasName; PP.Lex(Tok); if (Tok.is(tok::equal)) { HasAlias = true; PP.Lex(Tok); if (Tok.isNot(tok::identifier)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_identifier) << "weak"; return; } AliasName = Tok; PP.Lex(Tok); } if (Tok.isNot(tok::eod)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_extra_tokens_at_eol) << "weak"; return; } if (HasAlias) { MutableArrayRef Toks( PP.getPreprocessorAllocator().Allocate(3), 3); Token &pragmaUnusedTok = Toks[0]; pragmaUnusedTok.startToken(); pragmaUnusedTok.setKind(tok::annot_pragma_weakalias); pragmaUnusedTok.setLocation(WeakLoc); pragmaUnusedTok.setAnnotationEndLoc(AliasName.getLocation()); Toks[1] = WeakName; Toks[2] = AliasName; PP.EnterTokenStream(Toks, /*DisableMacroExpansion=*/true, /*IsReinject=*/false); } else { MutableArrayRef Toks( PP.getPreprocessorAllocator().Allocate(2), 2); Token &pragmaUnusedTok = Toks[0]; pragmaUnusedTok.startToken(); pragmaUnusedTok.setKind(tok::annot_pragma_weak); pragmaUnusedTok.setLocation(WeakLoc); pragmaUnusedTok.setAnnotationEndLoc(WeakLoc); Toks[1] = WeakName; PP.EnterTokenStream(Toks, /*DisableMacroExpansion=*/true, /*IsReinject=*/false); } } // #pragma redefine_extname identifier identifier void PragmaRedefineExtnameHandler::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &RedefToken) { SourceLocation RedefLoc = RedefToken.getLocation(); Token Tok; PP.Lex(Tok); if (Tok.isNot(tok::identifier)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_identifier) << "redefine_extname"; return; } Token RedefName = Tok; PP.Lex(Tok); if (Tok.isNot(tok::identifier)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_identifier) << "redefine_extname"; return; } Token AliasName = Tok; PP.Lex(Tok); if (Tok.isNot(tok::eod)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_extra_tokens_at_eol) << "redefine_extname"; return; } MutableArrayRef Toks(PP.getPreprocessorAllocator().Allocate(3), 3); Token &pragmaRedefTok = Toks[0]; pragmaRedefTok.startToken(); pragmaRedefTok.setKind(tok::annot_pragma_redefine_extname); pragmaRedefTok.setLocation(RedefLoc); pragmaRedefTok.setAnnotationEndLoc(AliasName.getLocation()); Toks[1] = RedefName; Toks[2] = AliasName; PP.EnterTokenStream(Toks, /*DisableMacroExpansion=*/true, /*IsReinject=*/false); } void PragmaFPContractHandler::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &Tok) { tok::OnOffSwitch OOS; if (PP.LexOnOffSwitch(OOS)) return; MutableArrayRef Toks(PP.getPreprocessorAllocator().Allocate(1), 1); Toks[0].startToken(); Toks[0].setKind(tok::annot_pragma_fp_contract); Toks[0].setLocation(Tok.getLocation()); Toks[0].setAnnotationEndLoc(Tok.getLocation()); Toks[0].setAnnotationValue(reinterpret_cast( static_cast(OOS))); PP.EnterTokenStream(Toks, /*DisableMacroExpansion=*/true, /*IsReinject=*/false); } void PragmaOpenCLExtensionHandler::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &Tok) { PP.LexUnexpandedToken(Tok); if (Tok.isNot(tok::identifier)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_identifier) << "OPENCL"; return; } IdentifierInfo *Ext = Tok.getIdentifierInfo(); SourceLocation NameLoc = Tok.getLocation(); PP.Lex(Tok); if (Tok.isNot(tok::colon)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_colon) << Ext; return; } PP.Lex(Tok); if (Tok.isNot(tok::identifier)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_predicate) << 0; return; } IdentifierInfo *Pred = Tok.getIdentifierInfo(); OpenCLExtState State; if (Pred->isStr("enable")) { State = Enable; } else if (Pred->isStr("disable")) { State = Disable; } else if (Pred->isStr("begin")) State = Begin; else if (Pred->isStr("end")) State = End; else { PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_predicate) << Ext->isStr("all"); return; } SourceLocation StateLoc = Tok.getLocation(); PP.Lex(Tok); if (Tok.isNot(tok::eod)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_extra_tokens_at_eol) << "OPENCL EXTENSION"; return; } auto Info = PP.getPreprocessorAllocator().Allocate(1); Info->first = Ext; Info->second = State; MutableArrayRef Toks(PP.getPreprocessorAllocator().Allocate(1), 1); Toks[0].startToken(); Toks[0].setKind(tok::annot_pragma_opencl_extension); Toks[0].setLocation(NameLoc); Toks[0].setAnnotationValue(static_cast(Info)); Toks[0].setAnnotationEndLoc(StateLoc); PP.EnterTokenStream(Toks, /*DisableMacroExpansion=*/true, /*IsReinject=*/false); if (PP.getPPCallbacks()) PP.getPPCallbacks()->PragmaOpenCLExtension(NameLoc, Ext, StateLoc, State); } /// Handle '#pragma omp ...' when OpenMP is disabled and '#pragma acc ...' when /// OpenACC is disabled. template void PragmaNoSupportHandler::HandlePragma( Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstTok) { if (!PP.getDiagnostics().isIgnored(IgnoredDiag, FirstTok.getLocation())) { PP.Diag(FirstTok, IgnoredDiag); PP.getDiagnostics().setSeverity(IgnoredDiag, diag::Severity::Ignored, SourceLocation()); } PP.DiscardUntilEndOfDirective(); } /// Handle '#pragma omp ...' when OpenMP is enabled, and handle '#pragma acc...' /// when OpenACC is enabled. template void PragmaSupportHandler::HandlePragma( Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstTok) { SmallVector Pragma; Token Tok; Tok.startToken(); Tok.setKind(StartTok); Tok.setLocation(Introducer.Loc); while (Tok.isNot(tok::eod) && Tok.isNot(tok::eof)) { Pragma.push_back(Tok); PP.Lex(Tok); if (Tok.is(StartTok)) { PP.Diag(Tok, UnexpectedDiag) << 0; unsigned InnerPragmaCnt = 1; while (InnerPragmaCnt != 0) { PP.Lex(Tok); if (Tok.is(StartTok)) ++InnerPragmaCnt; else if (Tok.is(EndTok)) --InnerPragmaCnt; } PP.Lex(Tok); } } SourceLocation EodLoc = Tok.getLocation(); Tok.startToken(); Tok.setKind(EndTok); Tok.setLocation(EodLoc); Pragma.push_back(Tok); auto Toks = std::make_unique(Pragma.size()); std::copy(Pragma.begin(), Pragma.end(), Toks.get()); PP.EnterTokenStream(std::move(Toks), Pragma.size(), /*DisableMacroExpansion=*/false, /*IsReinject=*/false); } /// Handle '#pragma pointers_to_members' // The grammar for this pragma is as follows: // // ::= ('single' | 'multiple' | 'virtual') '_inheritance' // // #pragma pointers_to_members '(' 'best_case' ')' // #pragma pointers_to_members '(' 'full_generality' [',' inheritance-model] ')' // #pragma pointers_to_members '(' inheritance-model ')' void PragmaMSPointersToMembers::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &Tok) { SourceLocation PointersToMembersLoc = Tok.getLocation(); PP.Lex(Tok); if (Tok.isNot(tok::l_paren)) { PP.Diag(PointersToMembersLoc, diag::warn_pragma_expected_lparen) << "pointers_to_members"; return; } PP.Lex(Tok); const IdentifierInfo *Arg = Tok.getIdentifierInfo(); if (!Arg) { PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_identifier) << "pointers_to_members"; return; } PP.Lex(Tok); LangOptions::PragmaMSPointersToMembersKind RepresentationMethod; if (Arg->isStr("best_case")) { RepresentationMethod = LangOptions::PPTMK_BestCase; } else { if (Arg->isStr("full_generality")) { if (Tok.is(tok::comma)) { PP.Lex(Tok); Arg = Tok.getIdentifierInfo(); if (!Arg) { PP.Diag(Tok.getLocation(), diag::err_pragma_pointers_to_members_unknown_kind) << Tok.getKind() << /*OnlyInheritanceModels*/ 0; return; } PP.Lex(Tok); } else if (Tok.is(tok::r_paren)) { // #pragma pointers_to_members(full_generality) implicitly specifies // virtual_inheritance. Arg = nullptr; RepresentationMethod = LangOptions::PPTMK_FullGeneralityVirtualInheritance; } else { PP.Diag(Tok.getLocation(), diag::err_expected_punc) << "full_generality"; return; } } if (Arg) { if (Arg->isStr("single_inheritance")) { RepresentationMethod = LangOptions::PPTMK_FullGeneralitySingleInheritance; } else if (Arg->isStr("multiple_inheritance")) { RepresentationMethod = LangOptions::PPTMK_FullGeneralityMultipleInheritance; } else if (Arg->isStr("virtual_inheritance")) { RepresentationMethod = LangOptions::PPTMK_FullGeneralityVirtualInheritance; } else { PP.Diag(Tok.getLocation(), diag::err_pragma_pointers_to_members_unknown_kind) << Arg << /*HasPointerDeclaration*/ 1; return; } } } if (Tok.isNot(tok::r_paren)) { PP.Diag(Tok.getLocation(), diag::err_expected_rparen_after) << (Arg ? Arg->getName() : "full_generality"); return; } SourceLocation EndLoc = Tok.getLocation(); PP.Lex(Tok); if (Tok.isNot(tok::eod)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_extra_tokens_at_eol) << "pointers_to_members"; return; } Token AnnotTok; AnnotTok.startToken(); AnnotTok.setKind(tok::annot_pragma_ms_pointers_to_members); AnnotTok.setLocation(PointersToMembersLoc); AnnotTok.setAnnotationEndLoc(EndLoc); AnnotTok.setAnnotationValue( reinterpret_cast(static_cast(RepresentationMethod))); PP.EnterToken(AnnotTok, /*IsReinject=*/true); } /// Handle '#pragma vtordisp' // The grammar for this pragma is as follows: // // ::= ('off' | 'on' | '0' | '1' | '2' ) // // #pragma vtordisp '(' ['push' ','] vtordisp-mode ')' // #pragma vtordisp '(' 'pop' ')' // #pragma vtordisp '(' ')' void PragmaMSVtorDisp::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &Tok) { SourceLocation VtorDispLoc = Tok.getLocation(); PP.Lex(Tok); if (Tok.isNot(tok::l_paren)) { PP.Diag(VtorDispLoc, diag::warn_pragma_expected_lparen) << "vtordisp"; return; } PP.Lex(Tok); Sema::PragmaMsStackAction Action = Sema::PSK_Set; const IdentifierInfo *II = Tok.getIdentifierInfo(); if (II) { if (II->isStr("push")) { // #pragma vtordisp(push, mode) PP.Lex(Tok); if (Tok.isNot(tok::comma)) { PP.Diag(VtorDispLoc, diag::warn_pragma_expected_punc) << "vtordisp"; return; } PP.Lex(Tok); Action = Sema::PSK_Push_Set; // not push, could be on/off } else if (II->isStr("pop")) { // #pragma vtordisp(pop) PP.Lex(Tok); Action = Sema::PSK_Pop; } // not push or pop, could be on/off } else { if (Tok.is(tok::r_paren)) { // #pragma vtordisp() Action = Sema::PSK_Reset; } } uint64_t Value = 0; if (Action & Sema::PSK_Push || Action & Sema::PSK_Set) { const IdentifierInfo *II = Tok.getIdentifierInfo(); if (II && II->isStr("off")) { PP.Lex(Tok); Value = 0; } else if (II && II->isStr("on")) { PP.Lex(Tok); Value = 1; } else if (Tok.is(tok::numeric_constant) && PP.parseSimpleIntegerLiteral(Tok, Value)) { if (Value > 2) { PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_integer) << 0 << 2 << "vtordisp"; return; } } else { PP.Diag(Tok.getLocation(), diag::warn_pragma_invalid_action) << "vtordisp"; return; } } // Finish the pragma: ')' $ if (Tok.isNot(tok::r_paren)) { PP.Diag(VtorDispLoc, diag::warn_pragma_expected_rparen) << "vtordisp"; return; } SourceLocation EndLoc = Tok.getLocation(); PP.Lex(Tok); if (Tok.isNot(tok::eod)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_extra_tokens_at_eol) << "vtordisp"; return; } // Enter the annotation. Token AnnotTok; AnnotTok.startToken(); AnnotTok.setKind(tok::annot_pragma_ms_vtordisp); AnnotTok.setLocation(VtorDispLoc); AnnotTok.setAnnotationEndLoc(EndLoc); AnnotTok.setAnnotationValue(reinterpret_cast( static_cast((Action << 16) | (Value & 0xFFFF)))); PP.EnterToken(AnnotTok, /*IsReinject=*/false); } /// Handle all MS pragmas. Simply forwards the tokens after inserting /// an annotation token. void PragmaMSPragma::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &Tok) { Token EoF, AnnotTok; EoF.startToken(); EoF.setKind(tok::eof); AnnotTok.startToken(); AnnotTok.setKind(tok::annot_pragma_ms_pragma); AnnotTok.setLocation(Tok.getLocation()); AnnotTok.setAnnotationEndLoc(Tok.getLocation()); SmallVector TokenVector; // Suck up all of the tokens before the eod. for (; Tok.isNot(tok::eod); PP.Lex(Tok)) { TokenVector.push_back(Tok); AnnotTok.setAnnotationEndLoc(Tok.getLocation()); } // Add a sentinel EoF token to the end of the list. TokenVector.push_back(EoF); // We must allocate this array with new because EnterTokenStream is going to // delete it later. markAsReinjectedForRelexing(TokenVector); auto TokenArray = std::make_unique(TokenVector.size()); std::copy(TokenVector.begin(), TokenVector.end(), TokenArray.get()); auto Value = new (PP.getPreprocessorAllocator()) std::pair, size_t>(std::move(TokenArray), TokenVector.size()); AnnotTok.setAnnotationValue(Value); PP.EnterToken(AnnotTok, /*IsReinject*/ false); } /// Handle the \#pragma float_control extension. /// /// The syntax is: /// \code /// #pragma float_control(keyword[, setting] [,push]) /// \endcode /// Where 'keyword' and 'setting' are identifiers. // 'keyword' can be: precise, except, push, pop // 'setting' can be: on, off /// The optional arguments 'setting' and 'push' are supported only /// when the keyword is 'precise' or 'except'. void PragmaFloatControlHandler::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &Tok) { Sema::PragmaMsStackAction Action = Sema::PSK_Set; SourceLocation FloatControlLoc = Tok.getLocation(); Token PragmaName = Tok; if (!PP.getTargetInfo().hasStrictFP() && !PP.getLangOpts().ExpStrictFP) { PP.Diag(Tok.getLocation(), diag::warn_pragma_fp_ignored) << PragmaName.getIdentifierInfo()->getName(); return; } PP.Lex(Tok); if (Tok.isNot(tok::l_paren)) { PP.Diag(FloatControlLoc, diag::err_expected) << tok::l_paren; return; } // Read the identifier. PP.Lex(Tok); if (Tok.isNot(tok::identifier)) { PP.Diag(Tok.getLocation(), diag::err_pragma_float_control_malformed); return; } // Verify that this is one of the float control options. IdentifierInfo *II = Tok.getIdentifierInfo(); PragmaFloatControlKind Kind = llvm::StringSwitch(II->getName()) .Case("precise", PFC_Precise) .Case("except", PFC_Except) .Case("push", PFC_Push) .Case("pop", PFC_Pop) .Default(PFC_Unknown); PP.Lex(Tok); // the identifier if (Kind == PFC_Unknown) { PP.Diag(Tok.getLocation(), diag::err_pragma_float_control_malformed); return; } else if (Kind == PFC_Push || Kind == PFC_Pop) { if (Tok.isNot(tok::r_paren)) { PP.Diag(Tok.getLocation(), diag::err_pragma_float_control_malformed); return; } PP.Lex(Tok); // Eat the r_paren Action = (Kind == PFC_Pop) ? Sema::PSK_Pop : Sema::PSK_Push; } else { if (Tok.is(tok::r_paren)) // Selecting Precise or Except PP.Lex(Tok); // the r_paren else if (Tok.isNot(tok::comma)) { PP.Diag(Tok.getLocation(), diag::err_pragma_float_control_malformed); return; } else { PP.Lex(Tok); // , if (!Tok.isAnyIdentifier()) { PP.Diag(Tok.getLocation(), diag::err_pragma_float_control_malformed); return; } StringRef PushOnOff = Tok.getIdentifierInfo()->getName(); if (PushOnOff == "on") // Kind is set correctly ; else if (PushOnOff == "off") { if (Kind == PFC_Precise) Kind = PFC_NoPrecise; if (Kind == PFC_Except) Kind = PFC_NoExcept; } else if (PushOnOff == "push") { Action = Sema::PSK_Push_Set; } else { PP.Diag(Tok.getLocation(), diag::err_pragma_float_control_malformed); return; } PP.Lex(Tok); // the identifier if (Tok.is(tok::comma)) { PP.Lex(Tok); // , if (!Tok.isAnyIdentifier()) { PP.Diag(Tok.getLocation(), diag::err_pragma_float_control_malformed); return; } StringRef ExpectedPush = Tok.getIdentifierInfo()->getName(); if (ExpectedPush == "push") { Action = Sema::PSK_Push_Set; } else { PP.Diag(Tok.getLocation(), diag::err_pragma_float_control_malformed); return; } PP.Lex(Tok); // the push identifier } if (Tok.isNot(tok::r_paren)) { PP.Diag(Tok.getLocation(), diag::err_pragma_float_control_malformed); return; } PP.Lex(Tok); // the r_paren } } SourceLocation EndLoc = Tok.getLocation(); if (Tok.isNot(tok::eod)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_extra_tokens_at_eol) << "float_control"; return; } // Note: there is no accomodation for PP callback for this pragma. // Enter the annotation. auto TokenArray = std::make_unique(1); TokenArray[0].startToken(); TokenArray[0].setKind(tok::annot_pragma_float_control); TokenArray[0].setLocation(FloatControlLoc); TokenArray[0].setAnnotationEndLoc(EndLoc); // Create an encoding of Action and Value by shifting the Action into // the high 16 bits then union with the Kind. TokenArray[0].setAnnotationValue(reinterpret_cast( static_cast((Action << 16) | (Kind & 0xFFFF)))); PP.EnterTokenStream(std::move(TokenArray), 1, /*DisableMacroExpansion=*/false, /*IsReinject=*/false); } /// Handle the Microsoft \#pragma detect_mismatch extension. /// /// The syntax is: /// \code /// #pragma detect_mismatch("name", "value") /// \endcode /// Where 'name' and 'value' are quoted strings. The values are embedded in /// the object file and passed along to the linker. If the linker detects a /// mismatch in the object file's values for the given name, a LNK2038 error /// is emitted. See MSDN for more details. void PragmaDetectMismatchHandler::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &Tok) { SourceLocation DetectMismatchLoc = Tok.getLocation(); PP.Lex(Tok); if (Tok.isNot(tok::l_paren)) { PP.Diag(DetectMismatchLoc, diag::err_expected) << tok::l_paren; return; } // Read the name to embed, which must be a string literal. std::string NameString; if (!PP.LexStringLiteral(Tok, NameString, "pragma detect_mismatch", /*AllowMacroExpansion=*/true)) return; // Read the comma followed by a second string literal. std::string ValueString; if (Tok.isNot(tok::comma)) { PP.Diag(Tok.getLocation(), diag::err_pragma_detect_mismatch_malformed); return; } if (!PP.LexStringLiteral(Tok, ValueString, "pragma detect_mismatch", /*AllowMacroExpansion=*/true)) return; if (Tok.isNot(tok::r_paren)) { PP.Diag(Tok.getLocation(), diag::err_expected) << tok::r_paren; return; } PP.Lex(Tok); // Eat the r_paren. if (Tok.isNot(tok::eod)) { PP.Diag(Tok.getLocation(), diag::err_pragma_detect_mismatch_malformed); return; } // If the pragma is lexically sound, notify any interested PPCallbacks. if (PP.getPPCallbacks()) PP.getPPCallbacks()->PragmaDetectMismatch(DetectMismatchLoc, NameString, ValueString); Actions.ActOnPragmaDetectMismatch(DetectMismatchLoc, NameString, ValueString); } /// Handle the microsoft \#pragma comment extension. /// /// The syntax is: /// \code /// #pragma comment(linker, "foo") /// \endcode /// 'linker' is one of five identifiers: compiler, exestr, lib, linker, user. /// "foo" is a string, which is fully macro expanded, and permits string /// concatenation, embedded escape characters etc. See MSDN for more details. void PragmaCommentHandler::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &Tok) { SourceLocation CommentLoc = Tok.getLocation(); PP.Lex(Tok); if (Tok.isNot(tok::l_paren)) { PP.Diag(CommentLoc, diag::err_pragma_comment_malformed); return; } // Read the identifier. PP.Lex(Tok); if (Tok.isNot(tok::identifier)) { PP.Diag(CommentLoc, diag::err_pragma_comment_malformed); return; } // Verify that this is one of the 5 explicitly listed options. IdentifierInfo *II = Tok.getIdentifierInfo(); PragmaMSCommentKind Kind = llvm::StringSwitch(II->getName()) .Case("linker", PCK_Linker) .Case("lib", PCK_Lib) .Case("compiler", PCK_Compiler) .Case("exestr", PCK_ExeStr) .Case("user", PCK_User) .Default(PCK_Unknown); if (Kind == PCK_Unknown) { PP.Diag(Tok.getLocation(), diag::err_pragma_comment_unknown_kind); return; } if (PP.getTargetInfo().getTriple().isOSBinFormatELF() && Kind != PCK_Lib) { PP.Diag(Tok.getLocation(), diag::warn_pragma_comment_ignored) << II->getName(); return; } // Read the optional string if present. PP.Lex(Tok); std::string ArgumentString; if (Tok.is(tok::comma) && !PP.LexStringLiteral(Tok, ArgumentString, "pragma comment", /*AllowMacroExpansion=*/true)) return; // FIXME: warn that 'exestr' is deprecated. // FIXME: If the kind is "compiler" warn if the string is present (it is // ignored). // The MSDN docs say that "lib" and "linker" require a string and have a short // list of linker options they support, but in practice MSVC doesn't // issue a diagnostic. Therefore neither does clang. if (Tok.isNot(tok::r_paren)) { PP.Diag(Tok.getLocation(), diag::err_pragma_comment_malformed); return; } PP.Lex(Tok); // eat the r_paren. if (Tok.isNot(tok::eod)) { PP.Diag(Tok.getLocation(), diag::err_pragma_comment_malformed); return; } // If the pragma is lexically sound, notify any interested PPCallbacks. if (PP.getPPCallbacks()) PP.getPPCallbacks()->PragmaComment(CommentLoc, II, ArgumentString); Actions.ActOnPragmaMSComment(CommentLoc, Kind, ArgumentString); } // #pragma clang optimize off // #pragma clang optimize on void PragmaOptimizeHandler::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) { Token Tok; PP.Lex(Tok); if (Tok.is(tok::eod)) { PP.Diag(Tok.getLocation(), diag::err_pragma_missing_argument) << "clang optimize" << /*Expected=*/true << "'on' or 'off'"; return; } if (Tok.isNot(tok::identifier)) { PP.Diag(Tok.getLocation(), diag::err_pragma_optimize_invalid_argument) << PP.getSpelling(Tok); return; } const IdentifierInfo *II = Tok.getIdentifierInfo(); // The only accepted values are 'on' or 'off'. bool IsOn = false; if (II->isStr("on")) { IsOn = true; } else if (!II->isStr("off")) { PP.Diag(Tok.getLocation(), diag::err_pragma_optimize_invalid_argument) << PP.getSpelling(Tok); return; } PP.Lex(Tok); if (Tok.isNot(tok::eod)) { PP.Diag(Tok.getLocation(), diag::err_pragma_optimize_extra_argument) << PP.getSpelling(Tok); return; } Actions.ActOnPragmaOptimize(IsOn, FirstToken.getLocation()); } namespace { /// Used as the annotation value for tok::annot_pragma_fp. struct TokFPAnnotValue { enum FlagValues { On, Off, Fast }; std::optional ContractValue; std::optional ReassociateValue; std::optional ReciprocalValue; std::optional ExceptionsValue; std::optional EvalMethodValue; }; } // end anonymous namespace void PragmaFPHandler::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &Tok) { // fp Token PragmaName = Tok; SmallVector TokenList; PP.Lex(Tok); if (Tok.isNot(tok::identifier)) { PP.Diag(Tok.getLocation(), diag::err_pragma_fp_invalid_option) << /*MissingOption=*/true << ""; return; } auto *AnnotValue = new (PP.getPreprocessorAllocator()) TokFPAnnotValue; while (Tok.is(tok::identifier)) { IdentifierInfo *OptionInfo = Tok.getIdentifierInfo(); auto FlagKind = llvm::StringSwitch>(OptionInfo->getName()) .Case("contract", PFK_Contract) .Case("reassociate", PFK_Reassociate) .Case("exceptions", PFK_Exceptions) .Case("eval_method", PFK_EvalMethod) .Case("reciprocal", PFK_Reciprocal) .Default(std::nullopt); if (!FlagKind) { PP.Diag(Tok.getLocation(), diag::err_pragma_fp_invalid_option) << /*MissingOption=*/false << OptionInfo; return; } PP.Lex(Tok); // Read '(' if (Tok.isNot(tok::l_paren)) { PP.Diag(Tok.getLocation(), diag::err_expected) << tok::l_paren; return; } PP.Lex(Tok); bool isEvalMethodDouble = Tok.is(tok::kw_double) && FlagKind == PFK_EvalMethod; // Don't diagnose if we have an eval_metod pragma with "double" kind. if (Tok.isNot(tok::identifier) && !isEvalMethodDouble) { PP.Diag(Tok.getLocation(), diag::err_pragma_fp_invalid_argument) << PP.getSpelling(Tok) << OptionInfo->getName() << static_cast(*FlagKind); return; } const IdentifierInfo *II = Tok.getIdentifierInfo(); if (FlagKind == PFK_Contract) { AnnotValue->ContractValue = llvm::StringSwitch>( II->getName()) .Case("on", LangOptions::FPModeKind::FPM_On) .Case("off", LangOptions::FPModeKind::FPM_Off) .Case("fast", LangOptions::FPModeKind::FPM_Fast) .Default(std::nullopt); if (!AnnotValue->ContractValue) { PP.Diag(Tok.getLocation(), diag::err_pragma_fp_invalid_argument) << PP.getSpelling(Tok) << OptionInfo->getName() << *FlagKind; return; } } else if (FlagKind == PFK_Reassociate || FlagKind == PFK_Reciprocal) { auto &Value = FlagKind == PFK_Reassociate ? AnnotValue->ReassociateValue : AnnotValue->ReciprocalValue; Value = llvm::StringSwitch>( II->getName()) .Case("on", LangOptions::FPModeKind::FPM_On) .Case("off", LangOptions::FPModeKind::FPM_Off) .Default(std::nullopt); if (!Value) { PP.Diag(Tok.getLocation(), diag::err_pragma_fp_invalid_argument) << PP.getSpelling(Tok) << OptionInfo->getName() << *FlagKind; return; } } else if (FlagKind == PFK_Exceptions) { AnnotValue->ExceptionsValue = llvm::StringSwitch>( II->getName()) .Case("ignore", LangOptions::FPE_Ignore) .Case("maytrap", LangOptions::FPE_MayTrap) .Case("strict", LangOptions::FPE_Strict) .Default(std::nullopt); if (!AnnotValue->ExceptionsValue) { PP.Diag(Tok.getLocation(), diag::err_pragma_fp_invalid_argument) << PP.getSpelling(Tok) << OptionInfo->getName() << *FlagKind; return; } } else if (FlagKind == PFK_EvalMethod) { AnnotValue->EvalMethodValue = llvm::StringSwitch>( II->getName()) .Case("source", LangOptions::FPEvalMethodKind::FEM_Source) .Case("double", LangOptions::FPEvalMethodKind::FEM_Double) .Case("extended", LangOptions::FPEvalMethodKind::FEM_Extended) .Default(std::nullopt); if (!AnnotValue->EvalMethodValue) { PP.Diag(Tok.getLocation(), diag::err_pragma_fp_invalid_argument) << PP.getSpelling(Tok) << OptionInfo->getName() << *FlagKind; return; } } PP.Lex(Tok); // Read ')' if (Tok.isNot(tok::r_paren)) { PP.Diag(Tok.getLocation(), diag::err_expected) << tok::r_paren; return; } PP.Lex(Tok); } if (Tok.isNot(tok::eod)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_extra_tokens_at_eol) << "clang fp"; return; } Token FPTok; FPTok.startToken(); FPTok.setKind(tok::annot_pragma_fp); FPTok.setLocation(PragmaName.getLocation()); FPTok.setAnnotationEndLoc(PragmaName.getLocation()); FPTok.setAnnotationValue(reinterpret_cast(AnnotValue)); TokenList.push_back(FPTok); auto TokenArray = std::make_unique(TokenList.size()); std::copy(TokenList.begin(), TokenList.end(), TokenArray.get()); PP.EnterTokenStream(std::move(TokenArray), TokenList.size(), /*DisableMacroExpansion=*/false, /*IsReinject=*/false); } void PragmaSTDC_FENV_ROUNDHandler::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &Tok) { Token PragmaName = Tok; SmallVector TokenList; if (!PP.getTargetInfo().hasStrictFP() && !PP.getLangOpts().ExpStrictFP) { PP.Diag(Tok.getLocation(), diag::warn_pragma_fp_ignored) << PragmaName.getIdentifierInfo()->getName(); return; } PP.Lex(Tok); if (Tok.isNot(tok::identifier)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_identifier) << PragmaName.getIdentifierInfo()->getName(); return; } IdentifierInfo *II = Tok.getIdentifierInfo(); auto RM = llvm::StringSwitch(II->getName()) .Case("FE_TOWARDZERO", llvm::RoundingMode::TowardZero) .Case("FE_TONEAREST", llvm::RoundingMode::NearestTiesToEven) .Case("FE_UPWARD", llvm::RoundingMode::TowardPositive) .Case("FE_DOWNWARD", llvm::RoundingMode::TowardNegative) .Case("FE_TONEARESTFROMZERO", llvm::RoundingMode::NearestTiesToAway) .Case("FE_DYNAMIC", llvm::RoundingMode::Dynamic) .Default(llvm::RoundingMode::Invalid); if (RM == llvm::RoundingMode::Invalid) { PP.Diag(Tok.getLocation(), diag::warn_stdc_unknown_rounding_mode); return; } PP.Lex(Tok); if (Tok.isNot(tok::eod)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_extra_tokens_at_eol) << "STDC FENV_ROUND"; return; } // Until the pragma is fully implemented, issue a warning. PP.Diag(Tok.getLocation(), diag::warn_stdc_fenv_round_not_supported); MutableArrayRef Toks(PP.getPreprocessorAllocator().Allocate(1), 1); Toks[0].startToken(); Toks[0].setKind(tok::annot_pragma_fenv_round); Toks[0].setLocation(Tok.getLocation()); Toks[0].setAnnotationEndLoc(Tok.getLocation()); Toks[0].setAnnotationValue( reinterpret_cast(static_cast(RM))); PP.EnterTokenStream(Toks, /*DisableMacroExpansion=*/true, /*IsReinject=*/false); } void Parser::HandlePragmaFP() { assert(Tok.is(tok::annot_pragma_fp)); auto *AnnotValue = reinterpret_cast(Tok.getAnnotationValue()); if (AnnotValue->ReassociateValue) Actions.ActOnPragmaFPValueChangingOption( Tok.getLocation(), PFK_Reassociate, *AnnotValue->ReassociateValue == LangOptions::FPModeKind::FPM_On); if (AnnotValue->ReciprocalValue) Actions.ActOnPragmaFPValueChangingOption( Tok.getLocation(), PFK_Reciprocal, *AnnotValue->ReciprocalValue == LangOptions::FPModeKind::FPM_On); if (AnnotValue->ContractValue) Actions.ActOnPragmaFPContract(Tok.getLocation(), *AnnotValue->ContractValue); if (AnnotValue->ExceptionsValue) Actions.ActOnPragmaFPExceptions(Tok.getLocation(), *AnnotValue->ExceptionsValue); if (AnnotValue->EvalMethodValue) Actions.ActOnPragmaFPEvalMethod(Tok.getLocation(), *AnnotValue->EvalMethodValue); ConsumeAnnotationToken(); } /// Parses loop or unroll pragma hint value and fills in Info. static bool ParseLoopHintValue(Preprocessor &PP, Token &Tok, Token PragmaName, Token Option, bool ValueInParens, PragmaLoopHintInfo &Info) { SmallVector ValueList; int OpenParens = ValueInParens ? 1 : 0; // Read constant expression. while (Tok.isNot(tok::eod)) { if (Tok.is(tok::l_paren)) OpenParens++; else if (Tok.is(tok::r_paren)) { OpenParens--; if (OpenParens == 0 && ValueInParens) break; } ValueList.push_back(Tok); PP.Lex(Tok); } if (ValueInParens) { // Read ')' if (Tok.isNot(tok::r_paren)) { PP.Diag(Tok.getLocation(), diag::err_expected) << tok::r_paren; return true; } PP.Lex(Tok); } Token EOFTok; EOFTok.startToken(); EOFTok.setKind(tok::eof); EOFTok.setLocation(Tok.getLocation()); ValueList.push_back(EOFTok); // Terminates expression for parsing. markAsReinjectedForRelexing(ValueList); Info.Toks = llvm::ArrayRef(ValueList).copy(PP.getPreprocessorAllocator()); Info.PragmaName = PragmaName; Info.Option = Option; return false; } /// Handle the \#pragma clang loop directive. /// #pragma clang 'loop' loop-hints /// /// loop-hints: /// loop-hint loop-hints[opt] /// /// loop-hint: /// 'vectorize' '(' loop-hint-keyword ')' /// 'interleave' '(' loop-hint-keyword ')' /// 'unroll' '(' unroll-hint-keyword ')' /// 'vectorize_predicate' '(' loop-hint-keyword ')' /// 'vectorize_width' '(' loop-hint-value ')' /// 'interleave_count' '(' loop-hint-value ')' /// 'unroll_count' '(' loop-hint-value ')' /// 'pipeline' '(' disable ')' /// 'pipeline_initiation_interval' '(' loop-hint-value ')' /// /// loop-hint-keyword: /// 'enable' /// 'disable' /// 'assume_safety' /// /// unroll-hint-keyword: /// 'enable' /// 'disable' /// 'full' /// /// loop-hint-value: /// constant-expression /// /// Specifying vectorize(enable) or vectorize_width(_value_) instructs llvm to /// try vectorizing the instructions of the loop it precedes. Specifying /// interleave(enable) or interleave_count(_value_) instructs llvm to try /// interleaving multiple iterations of the loop it precedes. The width of the /// vector instructions is specified by vectorize_width() and the number of /// interleaved loop iterations is specified by interleave_count(). Specifying a /// value of 1 effectively disables vectorization/interleaving, even if it is /// possible and profitable, and 0 is invalid. The loop vectorizer currently /// only works on inner loops. /// /// The unroll and unroll_count directives control the concatenation /// unroller. Specifying unroll(enable) instructs llvm to unroll the loop /// completely if the trip count is known at compile time and unroll partially /// if the trip count is not known. Specifying unroll(full) is similar to /// unroll(enable) but will unroll the loop only if the trip count is known at /// compile time. Specifying unroll(disable) disables unrolling for the /// loop. Specifying unroll_count(_value_) instructs llvm to try to unroll the /// loop the number of times indicated by the value. void PragmaLoopHintHandler::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &Tok) { // Incoming token is "loop" from "#pragma clang loop". Token PragmaName = Tok; SmallVector TokenList; // Lex the optimization option and verify it is an identifier. PP.Lex(Tok); if (Tok.isNot(tok::identifier)) { PP.Diag(Tok.getLocation(), diag::err_pragma_loop_invalid_option) << /*MissingOption=*/true << ""; return; } while (Tok.is(tok::identifier)) { Token Option = Tok; IdentifierInfo *OptionInfo = Tok.getIdentifierInfo(); bool OptionValid = llvm::StringSwitch(OptionInfo->getName()) .Case("vectorize", true) .Case("interleave", true) .Case("unroll", true) .Case("distribute", true) .Case("vectorize_predicate", true) .Case("vectorize_width", true) .Case("interleave_count", true) .Case("unroll_count", true) .Case("pipeline", true) .Case("pipeline_initiation_interval", true) .Default(false); if (!OptionValid) { PP.Diag(Tok.getLocation(), diag::err_pragma_loop_invalid_option) << /*MissingOption=*/false << OptionInfo; return; } PP.Lex(Tok); // Read '(' if (Tok.isNot(tok::l_paren)) { PP.Diag(Tok.getLocation(), diag::err_expected) << tok::l_paren; return; } PP.Lex(Tok); auto *Info = new (PP.getPreprocessorAllocator()) PragmaLoopHintInfo; if (ParseLoopHintValue(PP, Tok, PragmaName, Option, /*ValueInParens=*/true, *Info)) return; // Generate the loop hint token. Token LoopHintTok; LoopHintTok.startToken(); LoopHintTok.setKind(tok::annot_pragma_loop_hint); LoopHintTok.setLocation(Introducer.Loc); LoopHintTok.setAnnotationEndLoc(PragmaName.getLocation()); LoopHintTok.setAnnotationValue(static_cast(Info)); TokenList.push_back(LoopHintTok); } if (Tok.isNot(tok::eod)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_extra_tokens_at_eol) << "clang loop"; return; } auto TokenArray = std::make_unique(TokenList.size()); std::copy(TokenList.begin(), TokenList.end(), TokenArray.get()); PP.EnterTokenStream(std::move(TokenArray), TokenList.size(), /*DisableMacroExpansion=*/false, /*IsReinject=*/false); } /// Handle the loop unroll optimization pragmas. /// #pragma unroll /// #pragma unroll unroll-hint-value /// #pragma unroll '(' unroll-hint-value ')' /// #pragma nounroll /// #pragma unroll_and_jam /// #pragma unroll_and_jam unroll-hint-value /// #pragma unroll_and_jam '(' unroll-hint-value ')' /// #pragma nounroll_and_jam /// /// unroll-hint-value: /// constant-expression /// /// Loop unrolling hints can be specified with '#pragma unroll' or /// '#pragma nounroll'. '#pragma unroll' can take a numeric argument optionally /// contained in parentheses. With no argument the directive instructs llvm to /// try to unroll the loop completely. A positive integer argument can be /// specified to indicate the number of times the loop should be unrolled. To /// maximize compatibility with other compilers the unroll count argument can be /// specified with or without parentheses. Specifying, '#pragma nounroll' /// disables unrolling of the loop. void PragmaUnrollHintHandler::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &Tok) { // Incoming token is "unroll" for "#pragma unroll", or "nounroll" for // "#pragma nounroll". Token PragmaName = Tok; PP.Lex(Tok); auto *Info = new (PP.getPreprocessorAllocator()) PragmaLoopHintInfo; if (Tok.is(tok::eod)) { // nounroll or unroll pragma without an argument. Info->PragmaName = PragmaName; Info->Option.startToken(); } else if (PragmaName.getIdentifierInfo()->getName() == "nounroll" || PragmaName.getIdentifierInfo()->getName() == "nounroll_and_jam") { PP.Diag(Tok.getLocation(), diag::warn_pragma_extra_tokens_at_eol) << PragmaName.getIdentifierInfo()->getName(); return; } else { // Unroll pragma with an argument: "#pragma unroll N" or // "#pragma unroll(N)". // Read '(' if it exists. bool ValueInParens = Tok.is(tok::l_paren); if (ValueInParens) PP.Lex(Tok); Token Option; Option.startToken(); if (ParseLoopHintValue(PP, Tok, PragmaName, Option, ValueInParens, *Info)) return; // In CUDA, the argument to '#pragma unroll' should not be contained in // parentheses. if (PP.getLangOpts().CUDA && ValueInParens) PP.Diag(Info->Toks[0].getLocation(), diag::warn_pragma_unroll_cuda_value_in_parens); if (Tok.isNot(tok::eod)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_extra_tokens_at_eol) << "unroll"; return; } } // Generate the hint token. auto TokenArray = std::make_unique(1); TokenArray[0].startToken(); TokenArray[0].setKind(tok::annot_pragma_loop_hint); TokenArray[0].setLocation(Introducer.Loc); TokenArray[0].setAnnotationEndLoc(PragmaName.getLocation()); TokenArray[0].setAnnotationValue(static_cast(Info)); PP.EnterTokenStream(std::move(TokenArray), 1, /*DisableMacroExpansion=*/false, /*IsReinject=*/false); } /// Handle the Microsoft \#pragma intrinsic extension. /// /// The syntax is: /// \code /// #pragma intrinsic(memset) /// #pragma intrinsic(strlen, memcpy) /// \endcode /// /// Pragma intrisic tells the compiler to use a builtin version of the /// function. Clang does it anyway, so the pragma doesn't really do anything. /// Anyway, we emit a warning if the function specified in \#pragma intrinsic /// isn't an intrinsic in clang and suggest to include intrin.h. void PragmaMSIntrinsicHandler::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &Tok) { PP.Lex(Tok); if (Tok.isNot(tok::l_paren)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_lparen) << "intrinsic"; return; } PP.Lex(Tok); bool SuggestIntrinH = !PP.isMacroDefined("__INTRIN_H"); while (Tok.is(tok::identifier)) { IdentifierInfo *II = Tok.getIdentifierInfo(); if (!II->getBuiltinID()) PP.Diag(Tok.getLocation(), diag::warn_pragma_intrinsic_builtin) << II << SuggestIntrinH; PP.Lex(Tok); if (Tok.isNot(tok::comma)) break; PP.Lex(Tok); } if (Tok.isNot(tok::r_paren)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_expected_rparen) << "intrinsic"; return; } PP.Lex(Tok); if (Tok.isNot(tok::eod)) PP.Diag(Tok.getLocation(), diag::warn_pragma_extra_tokens_at_eol) << "intrinsic"; } bool Parser::HandlePragmaMSFunction(StringRef PragmaName, SourceLocation PragmaLocation) { Token FirstTok = Tok; if (ExpectAndConsume(tok::l_paren, diag::warn_pragma_expected_lparen, PragmaName)) return false; bool SuggestIntrinH = !PP.isMacroDefined("__INTRIN_H"); llvm::SmallVector NoBuiltins; while (Tok.is(tok::identifier)) { IdentifierInfo *II = Tok.getIdentifierInfo(); if (!II->getBuiltinID()) PP.Diag(Tok.getLocation(), diag::warn_pragma_intrinsic_builtin) << II << SuggestIntrinH; else NoBuiltins.emplace_back(II->getName()); PP.Lex(Tok); if (Tok.isNot(tok::comma)) break; PP.Lex(Tok); // , } if (ExpectAndConsume(tok::r_paren, diag::warn_pragma_expected_rparen, PragmaName) || ExpectAndConsume(tok::eof, diag::warn_pragma_extra_tokens_at_eol, PragmaName)) return false; Actions.ActOnPragmaMSFunction(FirstTok.getLocation(), NoBuiltins); return true; } // #pragma optimize("gsty", on|off) bool Parser::HandlePragmaMSOptimize(StringRef PragmaName, SourceLocation PragmaLocation) { Token FirstTok = Tok; if (ExpectAndConsume(tok::l_paren, diag::warn_pragma_expected_lparen, PragmaName)) return false; if (Tok.isNot(tok::string_literal)) { PP.Diag(PragmaLocation, diag::warn_pragma_expected_string) << PragmaName; return false; } ExprResult StringResult = ParseStringLiteralExpression(); if (StringResult.isInvalid()) return false; // Already diagnosed. StringLiteral *OptimizationList = cast(StringResult.get()); if (OptimizationList->getCharByteWidth() != 1) { PP.Diag(PragmaLocation, diag::warn_pragma_expected_non_wide_string) << PragmaName; return false; } if (ExpectAndConsume(tok::comma, diag::warn_pragma_expected_comma, PragmaName)) return false; if (Tok.is(tok::eof) || Tok.is(tok::r_paren)) { PP.Diag(PragmaLocation, diag::warn_pragma_missing_argument) << PragmaName << /*Expected=*/true << "'on' or 'off'"; return false; } IdentifierInfo *II = Tok.getIdentifierInfo(); if (!II || (!II->isStr("on") && !II->isStr("off"))) { PP.Diag(PragmaLocation, diag::warn_pragma_invalid_argument) << PP.getSpelling(Tok) << PragmaName << /*Expected=*/true << "'on' or 'off'"; return false; } bool IsOn = II->isStr("on"); PP.Lex(Tok); if (ExpectAndConsume(tok::r_paren, diag::warn_pragma_expected_rparen, PragmaName)) return false; // TODO: Add support for "sgty" if (!OptimizationList->getString().empty()) { PP.Diag(PragmaLocation, diag::warn_pragma_invalid_argument) << OptimizationList->getString() << PragmaName << /*Expected=*/true << "\"\""; return false; } if (ExpectAndConsume(tok::eof, diag::warn_pragma_extra_tokens_at_eol, PragmaName)) return false; Actions.ActOnPragmaMSOptimize(FirstTok.getLocation(), IsOn); return true; } void PragmaForceCUDAHostDeviceHandler::HandlePragma( Preprocessor &PP, PragmaIntroducer Introducer, Token &Tok) { Token FirstTok = Tok; PP.Lex(Tok); IdentifierInfo *Info = Tok.getIdentifierInfo(); if (!Info || (!Info->isStr("begin") && !Info->isStr("end"))) { PP.Diag(FirstTok.getLocation(), diag::warn_pragma_force_cuda_host_device_bad_arg); return; } if (Info->isStr("begin")) Actions.PushForceCUDAHostDevice(); else if (!Actions.PopForceCUDAHostDevice()) PP.Diag(FirstTok.getLocation(), diag::err_pragma_cannot_end_force_cuda_host_device); PP.Lex(Tok); if (!Tok.is(tok::eod)) PP.Diag(FirstTok.getLocation(), diag::warn_pragma_force_cuda_host_device_bad_arg); } /// Handle the #pragma clang attribute directive. /// /// The syntax is: /// \code /// #pragma clang attribute push (attribute, subject-set) /// #pragma clang attribute push /// #pragma clang attribute (attribute, subject-set) /// #pragma clang attribute pop /// \endcode /// /// There are also 'namespace' variants of push and pop directives. The bare /// '#pragma clang attribute (attribute, subject-set)' version doesn't require a /// namespace, since it always applies attributes to the most recently pushed /// group, regardless of namespace. /// \code /// #pragma clang attribute namespace.push (attribute, subject-set) /// #pragma clang attribute namespace.push /// #pragma clang attribute namespace.pop /// \endcode /// /// The subject-set clause defines the set of declarations which receive the /// attribute. Its exact syntax is described in the LanguageExtensions document /// in Clang's documentation. /// /// This directive instructs the compiler to begin/finish applying the specified /// attribute to the set of attribute-specific declarations in the active range /// of the pragma. void PragmaAttributeHandler::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) { Token Tok; PP.Lex(Tok); auto *Info = new (PP.getPreprocessorAllocator()) PragmaAttributeInfo(AttributesForPragmaAttribute); // Parse the optional namespace followed by a period. if (Tok.is(tok::identifier)) { IdentifierInfo *II = Tok.getIdentifierInfo(); if (!II->isStr("push") && !II->isStr("pop")) { Info->Namespace = II; PP.Lex(Tok); if (!Tok.is(tok::period)) { PP.Diag(Tok.getLocation(), diag::err_pragma_attribute_expected_period) << II; return; } PP.Lex(Tok); } } if (!Tok.isOneOf(tok::identifier, tok::l_paren)) { PP.Diag(Tok.getLocation(), diag::err_pragma_attribute_expected_push_pop_paren); return; } // Determine what action this pragma clang attribute represents. if (Tok.is(tok::l_paren)) { if (Info->Namespace) { PP.Diag(Tok.getLocation(), diag::err_pragma_attribute_namespace_on_attribute); PP.Diag(Tok.getLocation(), diag::note_pragma_attribute_namespace_on_attribute); return; } Info->Action = PragmaAttributeInfo::Attribute; } else { const IdentifierInfo *II = Tok.getIdentifierInfo(); if (II->isStr("push")) Info->Action = PragmaAttributeInfo::Push; else if (II->isStr("pop")) Info->Action = PragmaAttributeInfo::Pop; else { PP.Diag(Tok.getLocation(), diag::err_pragma_attribute_invalid_argument) << PP.getSpelling(Tok); return; } PP.Lex(Tok); } // Parse the actual attribute. if ((Info->Action == PragmaAttributeInfo::Push && Tok.isNot(tok::eod)) || Info->Action == PragmaAttributeInfo::Attribute) { if (Tok.isNot(tok::l_paren)) { PP.Diag(Tok.getLocation(), diag::err_expected) << tok::l_paren; return; } PP.Lex(Tok); // Lex the attribute tokens. SmallVector AttributeTokens; int OpenParens = 1; while (Tok.isNot(tok::eod)) { if (Tok.is(tok::l_paren)) OpenParens++; else if (Tok.is(tok::r_paren)) { OpenParens--; if (OpenParens == 0) break; } AttributeTokens.push_back(Tok); PP.Lex(Tok); } if (AttributeTokens.empty()) { PP.Diag(Tok.getLocation(), diag::err_pragma_attribute_expected_attribute); return; } if (Tok.isNot(tok::r_paren)) { PP.Diag(Tok.getLocation(), diag::err_expected) << tok::r_paren; return; } SourceLocation EndLoc = Tok.getLocation(); PP.Lex(Tok); // Terminate the attribute for parsing. Token EOFTok; EOFTok.startToken(); EOFTok.setKind(tok::eof); EOFTok.setLocation(EndLoc); AttributeTokens.push_back(EOFTok); markAsReinjectedForRelexing(AttributeTokens); Info->Tokens = llvm::ArrayRef(AttributeTokens).copy(PP.getPreprocessorAllocator()); } if (Tok.isNot(tok::eod)) PP.Diag(Tok.getLocation(), diag::warn_pragma_extra_tokens_at_eol) << "clang attribute"; // Generate the annotated pragma token. auto TokenArray = std::make_unique(1); TokenArray[0].startToken(); TokenArray[0].setKind(tok::annot_pragma_attribute); TokenArray[0].setLocation(FirstToken.getLocation()); TokenArray[0].setAnnotationEndLoc(FirstToken.getLocation()); TokenArray[0].setAnnotationValue(static_cast(Info)); PP.EnterTokenStream(std::move(TokenArray), 1, /*DisableMacroExpansion=*/false, /*IsReinject=*/false); } // Handle '#pragma clang max_tokens 12345'. void PragmaMaxTokensHereHandler::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &Tok) { PP.Lex(Tok); if (Tok.is(tok::eod)) { PP.Diag(Tok.getLocation(), diag::err_pragma_missing_argument) << "clang max_tokens_here" << /*Expected=*/true << "integer"; return; } SourceLocation Loc = Tok.getLocation(); uint64_t MaxTokens; if (Tok.isNot(tok::numeric_constant) || !PP.parseSimpleIntegerLiteral(Tok, MaxTokens)) { PP.Diag(Tok.getLocation(), diag::err_pragma_expected_integer) << "clang max_tokens_here"; return; } if (Tok.isNot(tok::eod)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_extra_tokens_at_eol) << "clang max_tokens_here"; return; } if (PP.getTokenCount() > MaxTokens) { PP.Diag(Loc, diag::warn_max_tokens) << PP.getTokenCount() << (unsigned)MaxTokens; } } // Handle '#pragma clang max_tokens_total 12345'. void PragmaMaxTokensTotalHandler::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &Tok) { PP.Lex(Tok); if (Tok.is(tok::eod)) { PP.Diag(Tok.getLocation(), diag::err_pragma_missing_argument) << "clang max_tokens_total" << /*Expected=*/true << "integer"; return; } SourceLocation Loc = Tok.getLocation(); uint64_t MaxTokens; if (Tok.isNot(tok::numeric_constant) || !PP.parseSimpleIntegerLiteral(Tok, MaxTokens)) { PP.Diag(Tok.getLocation(), diag::err_pragma_expected_integer) << "clang max_tokens_total"; return; } if (Tok.isNot(tok::eod)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_extra_tokens_at_eol) << "clang max_tokens_total"; return; } PP.overrideMaxTokens(MaxTokens, Loc); } // Handle '#pragma clang riscv intrinsic vector'. // '#pragma clang riscv intrinsic sifive_vector'. void PragmaRISCVHandler::HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &FirstToken) { Token Tok; PP.Lex(Tok); IdentifierInfo *II = Tok.getIdentifierInfo(); if (!II || !II->isStr("intrinsic")) { PP.Diag(Tok.getLocation(), diag::warn_pragma_invalid_argument) << PP.getSpelling(Tok) << "riscv" << /*Expected=*/true << "'intrinsic'"; return; } PP.Lex(Tok); II = Tok.getIdentifierInfo(); if (!II || !(II->isStr("vector") || II->isStr("sifive_vector"))) { PP.Diag(Tok.getLocation(), diag::warn_pragma_invalid_argument) << PP.getSpelling(Tok) << "riscv" << /*Expected=*/true << "'vector' or 'sifive_vector'"; return; } PP.Lex(Tok); if (Tok.isNot(tok::eod)) { PP.Diag(Tok.getLocation(), diag::warn_pragma_extra_tokens_at_eol) << "clang riscv intrinsic"; return; } if (II->isStr("vector")) Actions.DeclareRISCVVBuiltins = true; else if (II->isStr("sifive_vector")) Actions.DeclareRISCVSiFiveVectorBuiltins = true; }