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view lib/AsmParser/LLLexer.cpp @ 107:a03ddd01be7e
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author | Kaito Tokumori <e105711@ie.u-ryukyu.ac.jp> |
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date | Sun, 31 Jan 2016 17:34:49 +0900 |
parents | 7d135dc70f03 |
children | 1172e4bd9c6f |
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//===- LLLexer.cpp - Lexer for .ll Files ----------------------------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // Implement the Lexer for .ll files. // //===----------------------------------------------------------------------===// #include "LLLexer.h" #include "llvm/ADT/StringExtras.h" #include "llvm/ADT/Twine.h" #include "llvm/AsmParser/Parser.h" #include "llvm/IR/DerivedTypes.h" #include "llvm/IR/Instruction.h" #include "llvm/IR/LLVMContext.h" #include "llvm/Support/ErrorHandling.h" #include "llvm/Support/MathExtras.h" #include "llvm/Support/MemoryBuffer.h" #include "llvm/Support/SourceMgr.h" #include "llvm/Support/raw_ostream.h" #include <cctype> #include <cstdio> #include <cstdlib> #include <cstring> using namespace llvm; bool LLLexer::Error(LocTy ErrorLoc, const Twine &Msg) const { ErrorInfo = SM.GetMessage(ErrorLoc, SourceMgr::DK_Error, Msg); return true; } void LLLexer::Warning(LocTy WarningLoc, const Twine &Msg) const { SM.PrintMessage(WarningLoc, SourceMgr::DK_Warning, Msg); } //===----------------------------------------------------------------------===// // Helper functions. //===----------------------------------------------------------------------===// // atoull - Convert an ascii string of decimal digits into the unsigned long // long representation... this does not have to do input error checking, // because we know that the input will be matched by a suitable regex... // uint64_t LLLexer::atoull(const char *Buffer, const char *End) { uint64_t Result = 0; for (; Buffer != End; Buffer++) { uint64_t OldRes = Result; Result *= 10; Result += *Buffer-'0'; if (Result < OldRes) { // Uh, oh, overflow detected!!! Error("constant bigger than 64 bits detected!"); return 0; } } return Result; } uint64_t LLLexer::HexIntToVal(const char *Buffer, const char *End) { uint64_t Result = 0; for (; Buffer != End; ++Buffer) { uint64_t OldRes = Result; Result *= 16; Result += hexDigitValue(*Buffer); if (Result < OldRes) { // Uh, oh, overflow detected!!! Error("constant bigger than 64 bits detected!"); return 0; } } return Result; } void LLLexer::HexToIntPair(const char *Buffer, const char *End, uint64_t Pair[2]) { Pair[0] = 0; if (End - Buffer >= 16) { for (int i = 0; i < 16; i++, Buffer++) { assert(Buffer != End); Pair[0] *= 16; Pair[0] += hexDigitValue(*Buffer); } } Pair[1] = 0; for (int i = 0; i < 16 && Buffer != End; i++, Buffer++) { Pair[1] *= 16; Pair[1] += hexDigitValue(*Buffer); } if (Buffer != End) Error("constant bigger than 128 bits detected!"); } /// FP80HexToIntPair - translate an 80 bit FP80 number (20 hexits) into /// { low64, high16 } as usual for an APInt. void LLLexer::FP80HexToIntPair(const char *Buffer, const char *End, uint64_t Pair[2]) { Pair[1] = 0; for (int i=0; i<4 && Buffer != End; i++, Buffer++) { assert(Buffer != End); Pair[1] *= 16; Pair[1] += hexDigitValue(*Buffer); } Pair[0] = 0; for (int i = 0; i < 16 && Buffer != End; i++, Buffer++) { Pair[0] *= 16; Pair[0] += hexDigitValue(*Buffer); } if (Buffer != End) Error("constant bigger than 128 bits detected!"); } // UnEscapeLexed - Run through the specified buffer and change \xx codes to the // appropriate character. static void UnEscapeLexed(std::string &Str) { if (Str.empty()) return; char *Buffer = &Str[0], *EndBuffer = Buffer+Str.size(); char *BOut = Buffer; for (char *BIn = Buffer; BIn != EndBuffer; ) { if (BIn[0] == '\\') { if (BIn < EndBuffer-1 && BIn[1] == '\\') { *BOut++ = '\\'; // Two \ becomes one BIn += 2; } else if (BIn < EndBuffer-2 && isxdigit(static_cast<unsigned char>(BIn[1])) && isxdigit(static_cast<unsigned char>(BIn[2]))) { *BOut = hexDigitValue(BIn[1]) * 16 + hexDigitValue(BIn[2]); BIn += 3; // Skip over handled chars ++BOut; } else { *BOut++ = *BIn++; } } else { *BOut++ = *BIn++; } } Str.resize(BOut-Buffer); } /// isLabelChar - Return true for [-a-zA-Z$._0-9]. static bool isLabelChar(char C) { return isalnum(static_cast<unsigned char>(C)) || C == '-' || C == '$' || C == '.' || C == '_'; } /// isLabelTail - Return true if this pointer points to a valid end of a label. static const char *isLabelTail(const char *CurPtr) { while (1) { if (CurPtr[0] == ':') return CurPtr+1; if (!isLabelChar(CurPtr[0])) return nullptr; ++CurPtr; } } //===----------------------------------------------------------------------===// // Lexer definition. //===----------------------------------------------------------------------===// LLLexer::LLLexer(StringRef StartBuf, SourceMgr &sm, SMDiagnostic &Err, LLVMContext &C) : CurBuf(StartBuf), ErrorInfo(Err), SM(sm), Context(C), APFloatVal(0.0) { CurPtr = CurBuf.begin(); } int LLLexer::getNextChar() { char CurChar = *CurPtr++; switch (CurChar) { default: return (unsigned char)CurChar; case 0: // A nul character in the stream is either the end of the current buffer or // a random nul in the file. Disambiguate that here. if (CurPtr-1 != CurBuf.end()) return 0; // Just whitespace. // Otherwise, return end of file. --CurPtr; // Another call to lex will return EOF again. return EOF; } } lltok::Kind LLLexer::LexToken() { TokStart = CurPtr; int CurChar = getNextChar(); switch (CurChar) { default: // Handle letters: [a-zA-Z_] if (isalpha(static_cast<unsigned char>(CurChar)) || CurChar == '_') return LexIdentifier(); return lltok::Error; case EOF: return lltok::Eof; case 0: case ' ': case '\t': case '\n': case '\r': // Ignore whitespace. return LexToken(); case '+': return LexPositive(); case '@': return LexAt(); case '$': return LexDollar(); case '%': return LexPercent(); case '"': return LexQuote(); case '.': if (const char *Ptr = isLabelTail(CurPtr)) { CurPtr = Ptr; StrVal.assign(TokStart, CurPtr-1); return lltok::LabelStr; } if (CurPtr[0] == '.' && CurPtr[1] == '.') { CurPtr += 2; return lltok::dotdotdot; } return lltok::Error; case ';': SkipLineComment(); return LexToken(); case '!': return LexExclaim(); case '#': return LexHash(); case '0': case '1': case '2': case '3': case '4': case '5': case '6': case '7': case '8': case '9': case '-': return LexDigitOrNegative(); case '=': return lltok::equal; case '[': return lltok::lsquare; case ']': return lltok::rsquare; case '{': return lltok::lbrace; case '}': return lltok::rbrace; case '<': return lltok::less; case '>': return lltok::greater; case '(': return lltok::lparen; case ')': return lltok::rparen; case ',': return lltok::comma; case '*': return lltok::star; case '|': return lltok::bar; } } void LLLexer::SkipLineComment() { while (1) { if (CurPtr[0] == '\n' || CurPtr[0] == '\r' || getNextChar() == EOF) return; } } /// Lex all tokens that start with an @ character. /// GlobalVar @\"[^\"]*\" /// GlobalVar @[-a-zA-Z$._][-a-zA-Z$._0-9]* /// GlobalVarID @[0-9]+ lltok::Kind LLLexer::LexAt() { return LexVar(lltok::GlobalVar, lltok::GlobalID); } lltok::Kind LLLexer::LexDollar() { if (const char *Ptr = isLabelTail(TokStart)) { CurPtr = Ptr; StrVal.assign(TokStart, CurPtr - 1); return lltok::LabelStr; } // Handle DollarStringConstant: $\"[^\"]*\" if (CurPtr[0] == '"') { ++CurPtr; while (1) { int CurChar = getNextChar(); if (CurChar == EOF) { Error("end of file in COMDAT variable name"); return lltok::Error; } if (CurChar == '"') { StrVal.assign(TokStart + 2, CurPtr - 1); UnEscapeLexed(StrVal); if (StringRef(StrVal).find_first_of(0) != StringRef::npos) { Error("Null bytes are not allowed in names"); return lltok::Error; } return lltok::ComdatVar; } } } // Handle ComdatVarName: $[-a-zA-Z$._][-a-zA-Z$._0-9]* if (ReadVarName()) return lltok::ComdatVar; return lltok::Error; } /// ReadString - Read a string until the closing quote. lltok::Kind LLLexer::ReadString(lltok::Kind kind) { const char *Start = CurPtr; while (1) { int CurChar = getNextChar(); if (CurChar == EOF) { Error("end of file in string constant"); return lltok::Error; } if (CurChar == '"') { StrVal.assign(Start, CurPtr-1); UnEscapeLexed(StrVal); return kind; } } } /// ReadVarName - Read the rest of a token containing a variable name. bool LLLexer::ReadVarName() { const char *NameStart = CurPtr; if (isalpha(static_cast<unsigned char>(CurPtr[0])) || CurPtr[0] == '-' || CurPtr[0] == '$' || CurPtr[0] == '.' || CurPtr[0] == '_') { ++CurPtr; while (isalnum(static_cast<unsigned char>(CurPtr[0])) || CurPtr[0] == '-' || CurPtr[0] == '$' || CurPtr[0] == '.' || CurPtr[0] == '_') ++CurPtr; StrVal.assign(NameStart, CurPtr); return true; } return false; } lltok::Kind LLLexer::LexVar(lltok::Kind Var, lltok::Kind VarID) { // Handle StringConstant: \"[^\"]*\" if (CurPtr[0] == '"') { ++CurPtr; while (1) { int CurChar = getNextChar(); if (CurChar == EOF) { Error("end of file in global variable name"); return lltok::Error; } if (CurChar == '"') { StrVal.assign(TokStart+2, CurPtr-1); UnEscapeLexed(StrVal); if (StringRef(StrVal).find_first_of(0) != StringRef::npos) { Error("Null bytes are not allowed in names"); return lltok::Error; } return Var; } } } // Handle VarName: [-a-zA-Z$._][-a-zA-Z$._0-9]* if (ReadVarName()) return Var; // Handle VarID: [0-9]+ if (isdigit(static_cast<unsigned char>(CurPtr[0]))) { for (++CurPtr; isdigit(static_cast<unsigned char>(CurPtr[0])); ++CurPtr) /*empty*/; uint64_t Val = atoull(TokStart+1, CurPtr); if ((unsigned)Val != Val) Error("invalid value number (too large)!"); UIntVal = unsigned(Val); return VarID; } return lltok::Error; } /// Lex all tokens that start with a % character. /// LocalVar ::= %\"[^\"]*\" /// LocalVar ::= %[-a-zA-Z$._][-a-zA-Z$._0-9]* /// LocalVarID ::= %[0-9]+ lltok::Kind LLLexer::LexPercent() { return LexVar(lltok::LocalVar, lltok::LocalVarID); } /// Lex all tokens that start with a " character. /// QuoteLabel "[^"]+": /// StringConstant "[^"]*" lltok::Kind LLLexer::LexQuote() { lltok::Kind kind = ReadString(lltok::StringConstant); if (kind == lltok::Error || kind == lltok::Eof) return kind; if (CurPtr[0] == ':') { ++CurPtr; if (StringRef(StrVal).find_first_of(0) != StringRef::npos) { Error("Null bytes are not allowed in names"); kind = lltok::Error; } else { kind = lltok::LabelStr; } } return kind; } /// Lex all tokens that start with a ! character. /// !foo /// ! lltok::Kind LLLexer::LexExclaim() { // Lex a metadata name as a MetadataVar. if (isalpha(static_cast<unsigned char>(CurPtr[0])) || CurPtr[0] == '-' || CurPtr[0] == '$' || CurPtr[0] == '.' || CurPtr[0] == '_' || CurPtr[0] == '\\') { ++CurPtr; while (isalnum(static_cast<unsigned char>(CurPtr[0])) || CurPtr[0] == '-' || CurPtr[0] == '$' || CurPtr[0] == '.' || CurPtr[0] == '_' || CurPtr[0] == '\\') ++CurPtr; StrVal.assign(TokStart+1, CurPtr); // Skip ! UnEscapeLexed(StrVal); return lltok::MetadataVar; } return lltok::exclaim; } /// Lex all tokens that start with a # character. /// AttrGrpID ::= #[0-9]+ lltok::Kind LLLexer::LexHash() { // Handle AttrGrpID: #[0-9]+ if (isdigit(static_cast<unsigned char>(CurPtr[0]))) { for (++CurPtr; isdigit(static_cast<unsigned char>(CurPtr[0])); ++CurPtr) /*empty*/; uint64_t Val = atoull(TokStart+1, CurPtr); if ((unsigned)Val != Val) Error("invalid value number (too large)!"); UIntVal = unsigned(Val); return lltok::AttrGrpID; } return lltok::Error; } /// Lex a label, integer type, keyword, or hexadecimal integer constant. /// Label [-a-zA-Z$._0-9]+: /// IntegerType i[0-9]+ /// Keyword sdiv, float, ... /// HexIntConstant [us]0x[0-9A-Fa-f]+ lltok::Kind LLLexer::LexIdentifier() { const char *StartChar = CurPtr; const char *IntEnd = CurPtr[-1] == 'i' ? nullptr : StartChar; const char *KeywordEnd = nullptr; for (; isLabelChar(*CurPtr); ++CurPtr) { // If we decide this is an integer, remember the end of the sequence. if (!IntEnd && !isdigit(static_cast<unsigned char>(*CurPtr))) IntEnd = CurPtr; if (!KeywordEnd && !isalnum(static_cast<unsigned char>(*CurPtr)) && *CurPtr != '_') KeywordEnd = CurPtr; } // If we stopped due to a colon, this really is a label. if (*CurPtr == ':') { StrVal.assign(StartChar-1, CurPtr++); return lltok::LabelStr; } // Otherwise, this wasn't a label. If this was valid as an integer type, // return it. if (!IntEnd) IntEnd = CurPtr; if (IntEnd != StartChar) { CurPtr = IntEnd; uint64_t NumBits = atoull(StartChar, CurPtr); if (NumBits < IntegerType::MIN_INT_BITS || NumBits > IntegerType::MAX_INT_BITS) { Error("bitwidth for integer type out of range!"); return lltok::Error; } TyVal = IntegerType::get(Context, NumBits); return lltok::Type; } // Otherwise, this was a letter sequence. See which keyword this is. if (!KeywordEnd) KeywordEnd = CurPtr; CurPtr = KeywordEnd; --StartChar; StringRef Keyword(StartChar, CurPtr - StartChar); #define KEYWORD(STR) \ do { \ if (Keyword == #STR) \ return lltok::kw_##STR; \ } while (0) KEYWORD(true); KEYWORD(false); KEYWORD(declare); KEYWORD(define); KEYWORD(global); KEYWORD(constant); KEYWORD(private); KEYWORD(internal); KEYWORD(available_externally); KEYWORD(linkonce); KEYWORD(linkonce_odr); KEYWORD(weak); // Use as a linkage, and a modifier for "cmpxchg". KEYWORD(weak_odr); KEYWORD(appending); KEYWORD(dllimport); KEYWORD(dllexport); KEYWORD(common); KEYWORD(default); KEYWORD(hidden); KEYWORD(protected); KEYWORD(unnamed_addr); KEYWORD(externally_initialized); KEYWORD(extern_weak); KEYWORD(external); KEYWORD(thread_local); KEYWORD(localdynamic); KEYWORD(initialexec); KEYWORD(localexec); KEYWORD(zeroinitializer); KEYWORD(undef); KEYWORD(null); KEYWORD(none); KEYWORD(to); KEYWORD(caller); KEYWORD(within); KEYWORD(from); KEYWORD(tail); KEYWORD(musttail); KEYWORD(notail); KEYWORD(target); KEYWORD(triple); KEYWORD(unwind); KEYWORD(deplibs); // FIXME: Remove in 4.0. KEYWORD(datalayout); KEYWORD(volatile); KEYWORD(atomic); KEYWORD(unordered); KEYWORD(monotonic); KEYWORD(acquire); KEYWORD(release); KEYWORD(acq_rel); KEYWORD(seq_cst); KEYWORD(singlethread); KEYWORD(nnan); KEYWORD(ninf); KEYWORD(nsz); KEYWORD(arcp); KEYWORD(fast); KEYWORD(nuw); KEYWORD(nsw); KEYWORD(exact); KEYWORD(inbounds); KEYWORD(align); KEYWORD(addrspace); KEYWORD(section); KEYWORD(alias); KEYWORD(module); KEYWORD(asm); KEYWORD(sideeffect); KEYWORD(alignstack); KEYWORD(inteldialect); KEYWORD(gc); KEYWORD(prefix); KEYWORD(prologue); KEYWORD(ccc); KEYWORD(fastcc); KEYWORD(coldcc); KEYWORD(x86_stdcallcc); KEYWORD(x86_fastcallcc); KEYWORD(x86_thiscallcc); KEYWORD(x86_vectorcallcc); KEYWORD(arm_apcscc); KEYWORD(arm_aapcscc); KEYWORD(arm_aapcs_vfpcc); KEYWORD(msp430_intrcc); KEYWORD(ptx_kernel); KEYWORD(ptx_device); KEYWORD(spir_kernel); KEYWORD(spir_func); KEYWORD(intel_ocl_bicc); KEYWORD(x86_64_sysvcc); KEYWORD(x86_64_win64cc); KEYWORD(webkit_jscc); KEYWORD(anyregcc); KEYWORD(preserve_mostcc); KEYWORD(preserve_allcc); KEYWORD(ghccc); KEYWORD(x86_intrcc); KEYWORD(hhvmcc); KEYWORD(hhvm_ccc); KEYWORD(cxx_fast_tlscc); KEYWORD(cc); KEYWORD(c); KEYWORD(attributes); KEYWORD(alwaysinline); KEYWORD(argmemonly); KEYWORD(builtin); KEYWORD(byval); KEYWORD(inalloca); KEYWORD(cold); KEYWORD(convergent); KEYWORD(dereferenceable); KEYWORD(dereferenceable_or_null); KEYWORD(inaccessiblememonly); KEYWORD(inaccessiblemem_or_argmemonly); KEYWORD(inlinehint); KEYWORD(inreg); KEYWORD(jumptable); KEYWORD(minsize); KEYWORD(naked); KEYWORD(nest); KEYWORD(noalias); KEYWORD(nobuiltin); KEYWORD(nocapture); KEYWORD(noduplicate); KEYWORD(noimplicitfloat); KEYWORD(noinline); KEYWORD(norecurse); KEYWORD(nonlazybind); KEYWORD(nonnull); KEYWORD(noredzone); KEYWORD(noreturn); KEYWORD(nounwind); KEYWORD(optnone); KEYWORD(optsize); KEYWORD(readnone); KEYWORD(readonly); KEYWORD(returned); KEYWORD(returns_twice); KEYWORD(signext); KEYWORD(sret); KEYWORD(ssp); KEYWORD(sspreq); KEYWORD(sspstrong); KEYWORD(safestack); KEYWORD(sanitize_address); KEYWORD(sanitize_thread); KEYWORD(sanitize_memory); KEYWORD(uwtable); KEYWORD(zeroext); KEYWORD(type); KEYWORD(opaque); KEYWORD(comdat); // Comdat types KEYWORD(any); KEYWORD(exactmatch); KEYWORD(largest); KEYWORD(noduplicates); KEYWORD(samesize); KEYWORD(eq); KEYWORD(ne); KEYWORD(slt); KEYWORD(sgt); KEYWORD(sle); KEYWORD(sge); KEYWORD(ult); KEYWORD(ugt); KEYWORD(ule); KEYWORD(uge); KEYWORD(oeq); KEYWORD(one); KEYWORD(olt); KEYWORD(ogt); KEYWORD(ole); KEYWORD(oge); KEYWORD(ord); KEYWORD(uno); KEYWORD(ueq); KEYWORD(une); KEYWORD(xchg); KEYWORD(nand); KEYWORD(max); KEYWORD(min); KEYWORD(umax); KEYWORD(umin); KEYWORD(x); KEYWORD(blockaddress); // Metadata types. KEYWORD(distinct); // Use-list order directives. KEYWORD(uselistorder); KEYWORD(uselistorder_bb); KEYWORD(personality); KEYWORD(cleanup); KEYWORD(catch); KEYWORD(filter); #undef KEYWORD // Keywords for types. #define TYPEKEYWORD(STR, LLVMTY) \ do { \ if (Keyword == STR) { \ TyVal = LLVMTY; \ return lltok::Type; \ } \ } while (false) TYPEKEYWORD("void", Type::getVoidTy(Context)); TYPEKEYWORD("half", Type::getHalfTy(Context)); TYPEKEYWORD("float", Type::getFloatTy(Context)); TYPEKEYWORD("double", Type::getDoubleTy(Context)); TYPEKEYWORD("x86_fp80", Type::getX86_FP80Ty(Context)); TYPEKEYWORD("fp128", Type::getFP128Ty(Context)); TYPEKEYWORD("ppc_fp128", Type::getPPC_FP128Ty(Context)); TYPEKEYWORD("label", Type::getLabelTy(Context)); TYPEKEYWORD("metadata", Type::getMetadataTy(Context)); TYPEKEYWORD("x86_mmx", Type::getX86_MMXTy(Context)); TYPEKEYWORD("token", Type::getTokenTy(Context)); #undef TYPEKEYWORD // Keywords for instructions. #define INSTKEYWORD(STR, Enum) \ do { \ if (Keyword == #STR) { \ UIntVal = Instruction::Enum; \ return lltok::kw_##STR; \ } \ } while (false) INSTKEYWORD(add, Add); INSTKEYWORD(fadd, FAdd); INSTKEYWORD(sub, Sub); INSTKEYWORD(fsub, FSub); INSTKEYWORD(mul, Mul); INSTKEYWORD(fmul, FMul); INSTKEYWORD(udiv, UDiv); INSTKEYWORD(sdiv, SDiv); INSTKEYWORD(fdiv, FDiv); INSTKEYWORD(urem, URem); INSTKEYWORD(srem, SRem); INSTKEYWORD(frem, FRem); INSTKEYWORD(shl, Shl); INSTKEYWORD(lshr, LShr); INSTKEYWORD(ashr, AShr); INSTKEYWORD(and, And); INSTKEYWORD(or, Or); INSTKEYWORD(xor, Xor); INSTKEYWORD(icmp, ICmp); INSTKEYWORD(fcmp, FCmp); INSTKEYWORD(phi, PHI); INSTKEYWORD(call, Call); INSTKEYWORD(trunc, Trunc); INSTKEYWORD(zext, ZExt); INSTKEYWORD(sext, SExt); INSTKEYWORD(fptrunc, FPTrunc); INSTKEYWORD(fpext, FPExt); INSTKEYWORD(uitofp, UIToFP); INSTKEYWORD(sitofp, SIToFP); INSTKEYWORD(fptoui, FPToUI); INSTKEYWORD(fptosi, FPToSI); INSTKEYWORD(inttoptr, IntToPtr); INSTKEYWORD(ptrtoint, PtrToInt); INSTKEYWORD(bitcast, BitCast); INSTKEYWORD(addrspacecast, AddrSpaceCast); INSTKEYWORD(select, Select); INSTKEYWORD(va_arg, VAArg); INSTKEYWORD(ret, Ret); INSTKEYWORD(br, Br); INSTKEYWORD(switch, Switch); INSTKEYWORD(indirectbr, IndirectBr); INSTKEYWORD(invoke, Invoke); INSTKEYWORD(resume, Resume); INSTKEYWORD(unreachable, Unreachable); INSTKEYWORD(alloca, Alloca); INSTKEYWORD(load, Load); INSTKEYWORD(store, Store); INSTKEYWORD(cmpxchg, AtomicCmpXchg); INSTKEYWORD(atomicrmw, AtomicRMW); INSTKEYWORD(fence, Fence); INSTKEYWORD(getelementptr, GetElementPtr); INSTKEYWORD(extractelement, ExtractElement); INSTKEYWORD(insertelement, InsertElement); INSTKEYWORD(shufflevector, ShuffleVector); INSTKEYWORD(extractvalue, ExtractValue); INSTKEYWORD(insertvalue, InsertValue); INSTKEYWORD(landingpad, LandingPad); INSTKEYWORD(cleanupret, CleanupRet); INSTKEYWORD(catchret, CatchRet); INSTKEYWORD(catchswitch, CatchSwitch); INSTKEYWORD(catchpad, CatchPad); INSTKEYWORD(cleanuppad, CleanupPad); #undef INSTKEYWORD #define DWKEYWORD(TYPE, TOKEN) \ do { \ if (Keyword.startswith("DW_" #TYPE "_")) { \ StrVal.assign(Keyword.begin(), Keyword.end()); \ return lltok::TOKEN; \ } \ } while (false) DWKEYWORD(TAG, DwarfTag); DWKEYWORD(ATE, DwarfAttEncoding); DWKEYWORD(VIRTUALITY, DwarfVirtuality); DWKEYWORD(LANG, DwarfLang); DWKEYWORD(OP, DwarfOp); DWKEYWORD(MACINFO, DwarfMacinfo); #undef DWKEYWORD if (Keyword.startswith("DIFlag")) { StrVal.assign(Keyword.begin(), Keyword.end()); return lltok::DIFlag; } // Check for [us]0x[0-9A-Fa-f]+ which are Hexadecimal constant generated by // the CFE to avoid forcing it to deal with 64-bit numbers. if ((TokStart[0] == 'u' || TokStart[0] == 's') && TokStart[1] == '0' && TokStart[2] == 'x' && isxdigit(static_cast<unsigned char>(TokStart[3]))) { int len = CurPtr-TokStart-3; uint32_t bits = len * 4; StringRef HexStr(TokStart + 3, len); if (!std::all_of(HexStr.begin(), HexStr.end(), isxdigit)) { // Bad token, return it as an error. CurPtr = TokStart+3; return lltok::Error; } APInt Tmp(bits, HexStr, 16); uint32_t activeBits = Tmp.getActiveBits(); if (activeBits > 0 && activeBits < bits) Tmp = Tmp.trunc(activeBits); APSIntVal = APSInt(Tmp, TokStart[0] == 'u'); return lltok::APSInt; } // If this is "cc1234", return this as just "cc". if (TokStart[0] == 'c' && TokStart[1] == 'c') { CurPtr = TokStart+2; return lltok::kw_cc; } // Finally, if this isn't known, return an error. CurPtr = TokStart+1; return lltok::Error; } /// Lex all tokens that start with a 0x prefix, knowing they match and are not /// labels. /// HexFPConstant 0x[0-9A-Fa-f]+ /// HexFP80Constant 0xK[0-9A-Fa-f]+ /// HexFP128Constant 0xL[0-9A-Fa-f]+ /// HexPPC128Constant 0xM[0-9A-Fa-f]+ /// HexHalfConstant 0xH[0-9A-Fa-f]+ lltok::Kind LLLexer::Lex0x() { CurPtr = TokStart + 2; char Kind; if ((CurPtr[0] >= 'K' && CurPtr[0] <= 'M') || CurPtr[0] == 'H') { Kind = *CurPtr++; } else { Kind = 'J'; } if (!isxdigit(static_cast<unsigned char>(CurPtr[0]))) { // Bad token, return it as an error. CurPtr = TokStart+1; return lltok::Error; } while (isxdigit(static_cast<unsigned char>(CurPtr[0]))) ++CurPtr; if (Kind == 'J') { // HexFPConstant - Floating point constant represented in IEEE format as a // hexadecimal number for when exponential notation is not precise enough. // Half, Float, and double only. APFloatVal = APFloat(BitsToDouble(HexIntToVal(TokStart+2, CurPtr))); return lltok::APFloat; } uint64_t Pair[2]; switch (Kind) { default: llvm_unreachable("Unknown kind!"); case 'K': // F80HexFPConstant - x87 long double in hexadecimal format (10 bytes) FP80HexToIntPair(TokStart+3, CurPtr, Pair); APFloatVal = APFloat(APFloat::x87DoubleExtended, APInt(80, Pair)); return lltok::APFloat; case 'L': // F128HexFPConstant - IEEE 128-bit in hexadecimal format (16 bytes) HexToIntPair(TokStart+3, CurPtr, Pair); APFloatVal = APFloat(APFloat::IEEEquad, APInt(128, Pair)); return lltok::APFloat; case 'M': // PPC128HexFPConstant - PowerPC 128-bit in hexadecimal format (16 bytes) HexToIntPair(TokStart+3, CurPtr, Pair); APFloatVal = APFloat(APFloat::PPCDoubleDouble, APInt(128, Pair)); return lltok::APFloat; case 'H': APFloatVal = APFloat(APFloat::IEEEhalf, APInt(16,HexIntToVal(TokStart+3, CurPtr))); return lltok::APFloat; } } /// Lex tokens for a label or a numeric constant, possibly starting with -. /// Label [-a-zA-Z$._0-9]+: /// NInteger -[0-9]+ /// FPConstant [-+]?[0-9]+[.][0-9]*([eE][-+]?[0-9]+)? /// PInteger [0-9]+ /// HexFPConstant 0x[0-9A-Fa-f]+ /// HexFP80Constant 0xK[0-9A-Fa-f]+ /// HexFP128Constant 0xL[0-9A-Fa-f]+ /// HexPPC128Constant 0xM[0-9A-Fa-f]+ lltok::Kind LLLexer::LexDigitOrNegative() { // If the letter after the negative is not a number, this is probably a label. if (!isdigit(static_cast<unsigned char>(TokStart[0])) && !isdigit(static_cast<unsigned char>(CurPtr[0]))) { // Okay, this is not a number after the -, it's probably a label. if (const char *End = isLabelTail(CurPtr)) { StrVal.assign(TokStart, End-1); CurPtr = End; return lltok::LabelStr; } return lltok::Error; } // At this point, it is either a label, int or fp constant. // Skip digits, we have at least one. for (; isdigit(static_cast<unsigned char>(CurPtr[0])); ++CurPtr) /*empty*/; // Check to see if this really is a label afterall, e.g. "-1:". if (isLabelChar(CurPtr[0]) || CurPtr[0] == ':') { if (const char *End = isLabelTail(CurPtr)) { StrVal.assign(TokStart, End-1); CurPtr = End; return lltok::LabelStr; } } // If the next character is a '.', then it is a fp value, otherwise its // integer. if (CurPtr[0] != '.') { if (TokStart[0] == '0' && TokStart[1] == 'x') return Lex0x(); APSIntVal = APSInt(StringRef(TokStart, CurPtr - TokStart)); return lltok::APSInt; } ++CurPtr; // Skip over [0-9]*([eE][-+]?[0-9]+)? while (isdigit(static_cast<unsigned char>(CurPtr[0]))) ++CurPtr; if (CurPtr[0] == 'e' || CurPtr[0] == 'E') { if (isdigit(static_cast<unsigned char>(CurPtr[1])) || ((CurPtr[1] == '-' || CurPtr[1] == '+') && isdigit(static_cast<unsigned char>(CurPtr[2])))) { CurPtr += 2; while (isdigit(static_cast<unsigned char>(CurPtr[0]))) ++CurPtr; } } APFloatVal = APFloat(std::atof(TokStart)); return lltok::APFloat; } /// Lex a floating point constant starting with +. /// FPConstant [-+]?[0-9]+[.][0-9]*([eE][-+]?[0-9]+)? lltok::Kind LLLexer::LexPositive() { // If the letter after the negative is a number, this is probably not a // label. if (!isdigit(static_cast<unsigned char>(CurPtr[0]))) return lltok::Error; // Skip digits. for (++CurPtr; isdigit(static_cast<unsigned char>(CurPtr[0])); ++CurPtr) /*empty*/; // At this point, we need a '.'. if (CurPtr[0] != '.') { CurPtr = TokStart+1; return lltok::Error; } ++CurPtr; // Skip over [0-9]*([eE][-+]?[0-9]+)? while (isdigit(static_cast<unsigned char>(CurPtr[0]))) ++CurPtr; if (CurPtr[0] == 'e' || CurPtr[0] == 'E') { if (isdigit(static_cast<unsigned char>(CurPtr[1])) || ((CurPtr[1] == '-' || CurPtr[1] == '+') && isdigit(static_cast<unsigned char>(CurPtr[2])))) { CurPtr += 2; while (isdigit(static_cast<unsigned char>(CurPtr[0]))) ++CurPtr; } } APFloatVal = APFloat(std::atof(TokStart)); return lltok::APFloat; }