//===--- IdentifierTable.cpp - Hash table for identifier lookup -----------===// // // The LLVM Compiler Infrastructure // // This file was developed by Chris Lattner and is distributed under // the University of Illinois Open Source License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file implements the IdentifierInfo, IdentifierVisitor, and // IdentifierTable interfaces. // //===----------------------------------------------------------------------===// #include "clang/Basic/IdentifierTable.h" #include "clang/Basic/LangOptions.h" #include "llvm/ADT/FoldingSet.h" #include "llvm/ADT/DenseMap.h" #include "llvm/Bitcode/Serialize.h" #include "llvm/Bitcode/Deserialize.h" using namespace clang; //===----------------------------------------------------------------------===// // IdentifierInfo Implementation //===----------------------------------------------------------------------===// IdentifierInfo::IdentifierInfo() { TokenID = tok::identifier; ObjCID = tok::objc_not_keyword; BuiltinID = 0; HasMacro = false; IsExtension = false; IsPoisoned = false; IsOtherTargetMacro = false; IsCPPOperatorKeyword = false; IsNonPortableBuiltin = false; FETokenInfo = 0; } //===----------------------------------------------------------------------===// // IdentifierTable Implementation //===----------------------------------------------------------------------===// IdentifierTable::IdentifierTable(const LangOptions &LangOpts) // Start with space for 8K identifiers. : HashTable(8192) { // Populate the identifier table with info about keywords for the current // language. AddKeywords(LangOpts); } // This cstor is intended to be used only for serialization. IdentifierTable::IdentifierTable() : HashTable(8192) {} //===----------------------------------------------------------------------===// // Language Keyword Implementation //===----------------------------------------------------------------------===// /// AddKeyword - This method is used to associate a token ID with specific /// identifiers because they are language keywords. This causes the lexer to /// automatically map matching identifiers to specialized token codes. /// /// The C90/C99/CPP/CPP0x flags are set to 0 if the token should be /// enabled in the specified langauge, set to 1 if it is an extension /// in the specified language, and set to 2 if disabled in the /// specified language. static void AddKeyword(const char *Keyword, unsigned KWLen, tok::TokenKind TokenCode, int C90, int C99, int CXX, int CXX0x, int BoolSupport, const LangOptions &LangOpts, IdentifierTable &Table) { int Flags = 0; if (BoolSupport != 0) { Flags = LangOpts.Boolean ? BoolSupport : 2; } else if (LangOpts.CPlusPlus) { Flags = LangOpts.CPlusPlus0x ? CXX0x : CXX; } else if (LangOpts.C99) { Flags = C99; } else { Flags = C90; } // Don't add this keyword if disabled in this language or if an extension // and extensions are disabled. if (Flags + LangOpts.NoExtensions >= 2) return; IdentifierInfo &Info = Table.get(Keyword, Keyword+KWLen); Info.setTokenID(TokenCode); Info.setIsExtensionToken(Flags == 1); } static void AddAlias(const char *Keyword, unsigned KWLen, const char *AliaseeKeyword, unsigned AliaseeKWLen, const LangOptions &LangOpts, IdentifierTable &Table) { IdentifierInfo &AliasInfo = Table.get(Keyword, Keyword+KWLen); IdentifierInfo &AliaseeInfo = Table.get(AliaseeKeyword, AliaseeKeyword+AliaseeKWLen); AliasInfo.setTokenID(AliaseeInfo.getTokenID()); AliasInfo.setIsExtensionToken(AliaseeInfo.isExtensionToken()); } /// AddCXXOperatorKeyword - Register a C++ operator keyword alternative /// representations. static void AddCXXOperatorKeyword(const char *Keyword, unsigned KWLen, tok::TokenKind TokenCode, IdentifierTable &Table) { IdentifierInfo &Info = Table.get(Keyword, Keyword + KWLen); Info.setTokenID(TokenCode); Info.setIsCPlusPlusOperatorKeyword(); } /// AddObjCKeyword - Register an Objective-C @keyword like "class" "selector" or /// "property". static void AddObjCKeyword(tok::ObjCKeywordKind ObjCID, const char *Name, unsigned NameLen, IdentifierTable &Table) { Table.get(Name, Name+NameLen).setObjCKeywordID(ObjCID); } /// AddKeywords - Add all keywords to the symbol table. /// void IdentifierTable::AddKeywords(const LangOptions &LangOpts) { enum { C90Shift = 0, EXTC90 = 1 << C90Shift, NOTC90 = 2 << C90Shift, C99Shift = 2, EXTC99 = 1 << C99Shift, NOTC99 = 2 << C99Shift, CPPShift = 4, EXTCPP = 1 << CPPShift, NOTCPP = 2 << CPPShift, CPP0xShift = 6, EXTCPP0x = 1 << CPP0xShift, NOTCPP0x = 2 << CPP0xShift, BoolShift = 8, BOOLSUPPORT = 1 << BoolShift, Mask = 3 }; // Add keywords and tokens for the current language. #define KEYWORD(NAME, FLAGS) \ AddKeyword(#NAME, strlen(#NAME), tok::kw_ ## NAME, \ ((FLAGS) >> C90Shift) & Mask, \ ((FLAGS) >> C99Shift) & Mask, \ ((FLAGS) >> CPPShift) & Mask, \ ((FLAGS) >> CPP0xShift) & Mask, \ ((FLAGS) >> BoolShift) & Mask, LangOpts, *this); #define ALIAS(NAME, TOK) \ AddAlias(NAME, strlen(NAME), #TOK, strlen(#TOK), LangOpts, *this); #define CXX_KEYWORD_OPERATOR(NAME, ALIAS) \ if (LangOpts.CXXOperatorNames) \ AddCXXOperatorKeyword(#NAME, strlen(#NAME), tok::ALIAS, *this); #define OBJC1_AT_KEYWORD(NAME) \ if (LangOpts.ObjC1) \ AddObjCKeyword(tok::objc_##NAME, #NAME, strlen(#NAME), *this); #define OBJC2_AT_KEYWORD(NAME) \ if (LangOpts.ObjC2) \ AddObjCKeyword(tok::objc_##NAME, #NAME, strlen(#NAME), *this); #include "clang/Basic/TokenKinds.def" } tok::PPKeywordKind IdentifierInfo::getPPKeywordID() const { // We use a perfect hash function here involving the length of the keyword, // the first and third character. For preprocessor ID's there are no // collisions (if there were, the switch below would complain about duplicate // case values). Note that this depends on 'if' being null terminated. #define HASH(LEN, FIRST, THIRD) \ (LEN << 5) + (((FIRST-'a') + (THIRD-'a')) & 31) #define CASE(LEN, FIRST, THIRD, NAME) \ case HASH(LEN, FIRST, THIRD): \ return memcmp(Name, #NAME, LEN) ? tok::pp_not_keyword : tok::pp_ ## NAME unsigned Len = getLength(); if (Len < 2) return tok::pp_not_keyword; const char *Name = getName(); switch (HASH(Len, Name[0], Name[2])) { default: return tok::pp_not_keyword; CASE( 2, 'i', '\0', if); CASE( 4, 'e', 'i', elif); CASE( 4, 'e', 's', else); CASE( 4, 'l', 'n', line); CASE( 4, 's', 'c', sccs); CASE( 5, 'e', 'd', endif); CASE( 5, 'e', 'r', error); CASE( 5, 'i', 'e', ident); CASE( 5, 'i', 'd', ifdef); CASE( 5, 'u', 'd', undef); CASE( 6, 'a', 's', assert); CASE( 6, 'd', 'f', define); CASE( 6, 'i', 'n', ifndef); CASE( 6, 'i', 'p', import); CASE( 6, 'p', 'a', pragma); CASE( 7, 'd', 'f', defined); CASE( 7, 'i', 'c', include); CASE( 7, 'w', 'r', warning); CASE( 8, 'u', 'a', unassert); CASE(12, 'i', 'c', include_next); CASE(13, 'd', 'f', define_target); CASE(19, 'd', 'f', define_other_target); #undef CASE #undef HASH } } //===----------------------------------------------------------------------===// // Stats Implementation //===----------------------------------------------------------------------===// /// PrintStats - Print statistics about how well the identifier table is doing /// at hashing identifiers. void IdentifierTable::PrintStats() const { unsigned NumBuckets = HashTable.getNumBuckets(); unsigned NumIdentifiers = HashTable.getNumItems(); unsigned NumEmptyBuckets = NumBuckets-NumIdentifiers; unsigned AverageIdentifierSize = 0; unsigned MaxIdentifierLength = 0; // TODO: Figure out maximum times an identifier had to probe for -stats. for (llvm::StringMap::const_iterator I = HashTable.begin(), E = HashTable.end(); I != E; ++I) { unsigned IdLen = I->getKeyLength(); AverageIdentifierSize += IdLen; if (MaxIdentifierLength < IdLen) MaxIdentifierLength = IdLen; } fprintf(stderr, "\n*** Identifier Table Stats:\n"); fprintf(stderr, "# Identifiers: %d\n", NumIdentifiers); fprintf(stderr, "# Empty Buckets: %d\n", NumEmptyBuckets); fprintf(stderr, "Hash density (#identifiers per bucket): %f\n", NumIdentifiers/(double)NumBuckets); fprintf(stderr, "Ave identifier length: %f\n", (AverageIdentifierSize/(double)NumIdentifiers)); fprintf(stderr, "Max identifier length: %d\n", MaxIdentifierLength); // Compute statistics about the memory allocated for identifiers. HashTable.getAllocator().PrintStats(); } //===----------------------------------------------------------------------===// // SelectorTable Implementation //===----------------------------------------------------------------------===// unsigned llvm::DenseMapInfo::getHashValue(clang::Selector S) { return DenseMapInfo::getHashValue(S.getAsOpaquePtr()); } /// MultiKeywordSelector - One of these variable length records is kept for each /// selector containing more than one keyword. We use a folding set /// to unique aggregate names (keyword selectors in ObjC parlance). Access to /// this class is provided strictly through Selector. namespace clang { class MultiKeywordSelector : public llvm::FoldingSetNode { friend SelectorTable* SelectorTable::CreateAndRegister(llvm::Deserializer&); MultiKeywordSelector(unsigned nKeys) : NumArgs(nKeys) {} public: unsigned NumArgs; // Constructor for keyword selectors. MultiKeywordSelector(unsigned nKeys, IdentifierInfo **IIV) { assert((nKeys > 1) && "not a multi-keyword selector"); NumArgs = nKeys; // Fill in the trailing keyword array. IdentifierInfo **KeyInfo = reinterpret_cast(this+1); for (unsigned i = 0; i != nKeys; ++i) KeyInfo[i] = IIV[i]; } // getName - Derive the full selector name and return it. std::string getName() const; unsigned getNumArgs() const { return NumArgs; } typedef IdentifierInfo *const *keyword_iterator; keyword_iterator keyword_begin() const { return reinterpret_cast(this+1); } keyword_iterator keyword_end() const { return keyword_begin()+NumArgs; } IdentifierInfo *getIdentifierInfoForSlot(unsigned i) const { assert(i < NumArgs && "getIdentifierInfoForSlot(): illegal index"); return keyword_begin()[i]; } static void Profile(llvm::FoldingSetNodeID &ID, keyword_iterator ArgTys, unsigned NumArgs) { ID.AddInteger(NumArgs); for (unsigned i = 0; i != NumArgs; ++i) ID.AddPointer(ArgTys[i]); } void Profile(llvm::FoldingSetNodeID &ID) { Profile(ID, keyword_begin(), NumArgs); } }; } // end namespace clang. unsigned Selector::getNumArgs() const { unsigned IIF = getIdentifierInfoFlag(); if (IIF == ZeroArg) return 0; if (IIF == OneArg) return 1; // We point to a MultiKeywordSelector (pointer doesn't contain any flags). MultiKeywordSelector *SI = reinterpret_cast(InfoPtr); return SI->getNumArgs(); } IdentifierInfo *Selector::getIdentifierInfoForSlot(unsigned argIndex) const { if (IdentifierInfo *II = getAsIdentifierInfo()) { assert(argIndex == 0 && "illegal keyword index"); return II; } // We point to a MultiKeywordSelector (pointer doesn't contain any flags). MultiKeywordSelector *SI = reinterpret_cast(InfoPtr); return SI->getIdentifierInfoForSlot(argIndex); } std::string MultiKeywordSelector::getName() const { std::string Result; unsigned Length = 0; for (keyword_iterator I = keyword_begin(), E = keyword_end(); I != E; ++I) { if (*I) Length += (*I)->getLength(); ++Length; // : } Result.reserve(Length); for (keyword_iterator I = keyword_begin(), E = keyword_end(); I != E; ++I) { if (*I) Result.insert(Result.end(), (*I)->getName(), (*I)->getName()+(*I)->getLength()); Result.push_back(':'); } return Result; } std::string Selector::getName() const { if (IdentifierInfo *II = getAsIdentifierInfo()) { if (getNumArgs() == 0) return II->getName(); std::string Res = II->getName(); Res += ":"; return Res; } // We have a multiple keyword selector (no embedded flags). return reinterpret_cast(InfoPtr)->getName(); } Selector SelectorTable::getSelector(unsigned nKeys, IdentifierInfo **IIV) { if (nKeys < 2) return Selector(IIV[0], nKeys); llvm::FoldingSet *SelTab; SelTab = static_cast *>(Impl); // Unique selector, to guarantee there is one per name. llvm::FoldingSetNodeID ID; MultiKeywordSelector::Profile(ID, IIV, nKeys); void *InsertPos = 0; if (MultiKeywordSelector *SI = SelTab->FindNodeOrInsertPos(ID, InsertPos)) return Selector(SI); // MultiKeywordSelector objects are not allocated with new because they have a // variable size array (for parameter types) at the end of them. MultiKeywordSelector *SI = (MultiKeywordSelector*)malloc(sizeof(MultiKeywordSelector) + nKeys*sizeof(IdentifierInfo *)); new (SI) MultiKeywordSelector(nKeys, IIV); SelTab->InsertNode(SI, InsertPos); return Selector(SI); } SelectorTable::SelectorTable() { Impl = new llvm::FoldingSet; } SelectorTable::~SelectorTable() { delete static_cast *>(Impl); } //===----------------------------------------------------------------------===// // Serialization for IdentifierInfo and IdentifierTable. //===----------------------------------------------------------------------===// void IdentifierInfo::Emit(llvm::Serializer& S) const { S.EmitInt(getTokenID()); S.EmitInt(getBuiltinID()); S.EmitInt(getObjCKeywordID()); S.EmitBool(hasMacroDefinition()); S.EmitBool(isExtensionToken()); S.EmitBool(isPoisoned()); S.EmitBool(isOtherTargetMacro()); S.EmitBool(isCPlusPlusOperatorKeyword()); S.EmitBool(isNonPortableBuiltin()); // FIXME: FETokenInfo } void IdentifierInfo::Read(llvm::Deserializer& D) { setTokenID((tok::TokenKind) D.ReadInt()); setBuiltinID(D.ReadInt()); setObjCKeywordID((tok::ObjCKeywordKind) D.ReadInt()); setHasMacroDefinition(D.ReadBool()); setIsExtensionToken(D.ReadBool()); setIsPoisoned(D.ReadBool()); setIsOtherTargetMacro(D.ReadBool()); setIsCPlusPlusOperatorKeyword(D.ReadBool()); setNonPortableBuiltin(D.ReadBool()); // FIXME: FETokenInfo } void IdentifierTable::Emit(llvm::Serializer& S) const { S.EnterBlock(); S.EmitPtr(this); for (iterator I=begin(), E=end(); I != E; ++I) { const char* Key = I->getKeyData(); const IdentifierInfo* Info = &I->getValue(); bool KeyRegistered = S.isRegistered(Key); bool InfoRegistered = S.isRegistered(Info); if (KeyRegistered || InfoRegistered) { // These acrobatics are so that we don't incur the cost of registering // a pointer with the backpatcher during deserialization if nobody // references the object. S.EmitPtr(InfoRegistered ? Info : NULL); S.EmitPtr(KeyRegistered ? Key : NULL); S.EmitCStr(Key); S.Emit(*Info); } } S.ExitBlock(); } IdentifierTable* IdentifierTable::CreateAndRegister(llvm::Deserializer& D) { llvm::Deserializer::Location BLoc = D.getCurrentBlockLocation(); std::vector buff; buff.reserve(200); IdentifierTable* t = new IdentifierTable(); D.RegisterPtr(t); while (!D.FinishedBlock(BLoc)) { llvm::SerializedPtrID InfoPtrID = D.ReadPtrID(); llvm::SerializedPtrID KeyPtrID = D.ReadPtrID(); D.ReadCStr(buff); llvm::StringMapEntry& Entry = t->HashTable.GetOrCreateValue(&buff[0],&buff[0]+buff.size()); D.Read(Entry.getValue()); if (InfoPtrID) D.RegisterRef(InfoPtrID,Entry.getValue()); if (KeyPtrID) D.RegisterPtr(KeyPtrID,Entry.getKeyData()); } return t; } //===----------------------------------------------------------------------===// // Serialization for Selector and SelectorTable. //===----------------------------------------------------------------------===// void Selector::Emit(llvm::Serializer& S) const { S.EmitInt(getIdentifierInfoFlag()); S.EmitPtr(reinterpret_cast(InfoPtr & ~ArgFlags)); } Selector Selector::ReadVal(llvm::Deserializer& D) { unsigned flag = D.ReadInt(); uintptr_t ptr; D.ReadUIntPtr(ptr,false); // No backpatching. return Selector(ptr | flag); } void SelectorTable::Emit(llvm::Serializer& S) const { typedef llvm::FoldingSet::iterator iterator; llvm::FoldingSet *SelTab; SelTab = static_cast *>(Impl); S.EnterBlock(); S.EmitPtr(this); for (iterator I=SelTab->begin(), E=SelTab->end(); I != E; ++I) { if (!S.isRegistered(&*I)) continue; S.FlushRecord(); // Start a new record. S.EmitPtr(&*I); S.EmitInt(I->getNumArgs()); for (MultiKeywordSelector::keyword_iterator KI = I->keyword_begin(), KE = I->keyword_end(); KI != KE; ++KI) S.EmitPtr(*KI); } S.ExitBlock(); } SelectorTable* SelectorTable::CreateAndRegister(llvm::Deserializer& D) { llvm::Deserializer::Location BLoc = D.getCurrentBlockLocation(); SelectorTable* t = new SelectorTable(); D.RegisterPtr(t); llvm::FoldingSet& SelTab = *static_cast*>(t->Impl); while (!D.FinishedBlock(BLoc)) { llvm::SerializedPtrID PtrID = D.ReadPtrID(); unsigned nKeys = D.ReadInt(); MultiKeywordSelector *SI = (MultiKeywordSelector*)malloc(sizeof(MultiKeywordSelector) + nKeys*sizeof(IdentifierInfo *)); new (SI) MultiKeywordSelector(nKeys); D.RegisterPtr(PtrID,SI); IdentifierInfo **KeyInfo = reinterpret_cast(SI+1); for (unsigned i = 0; i != nKeys; ++i) D.ReadPtr(KeyInfo[i],false); SelTab.GetOrInsertNode(SI); } return t; }