// // Copyright (c) 2002-2010 The ANGLE Project Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. // // // Symbol table for parsing. Most functionaliy and main ideas // are documented in the header file. // #if defined(_MSC_VER) #pragma warning(disable: 4718) #endif #include "compiler/SymbolTable.h" #include #include // // TType helper function needs a place to live. // // // Recursively generate mangled names. // void TType::buildMangledName(TString& mangledName) { if (isMatrix()) mangledName += 'm'; else if (isVector()) mangledName += 'v'; switch (type) { case EbtFloat: mangledName += 'f'; break; case EbtInt: mangledName += 'i'; break; case EbtBool: mangledName += 'b'; break; case EbtSampler2D: mangledName += "s2"; break; case EbtSamplerCube: mangledName += "sC"; break; case EbtStruct: mangledName += "struct-"; if (typeName) mangledName += *typeName; {// support MSVC++6.0 for (unsigned int i = 0; i < structure->size(); ++i) { mangledName += '-'; (*structure)[i].type->buildMangledName(mangledName); } } default: break; } mangledName += static_cast('0' + getNominalSize()); if (isArray()) { char buf[20]; sprintf(buf, "%d", arraySize); mangledName += '['; mangledName += buf; mangledName += ']'; } } int TType::getStructSize() const { if (!getStruct()) { assert(false && "Not a struct"); return 0; } if (structureSize == 0) for (TTypeList::const_iterator tl = getStruct()->begin(); tl != getStruct()->end(); tl++) structureSize += ((*tl).type)->getObjectSize(); return structureSize; } void TType::computeDeepestStructNesting() { if (!getStruct()) { return; } int maxNesting = 0; for (TTypeList::const_iterator tl = getStruct()->begin(); tl != getStruct()->end(); ++tl) { maxNesting = std::max(maxNesting, ((*tl).type)->getDeepestStructNesting()); } deepestStructNesting = 1 + maxNesting; } // // Dump functions. // void TVariable::dump(TInfoSink& infoSink) const { infoSink.debug << getName().c_str() << ": " << type.getQualifierString() << " " << type.getPrecisionString() << " " << type.getBasicString(); if (type.isArray()) { infoSink.debug << "[0]"; } infoSink.debug << "\n"; } void TFunction::dump(TInfoSink &infoSink) const { infoSink.debug << getName().c_str() << ": " << returnType.getBasicString() << " " << getMangledName().c_str() << "\n"; } void TSymbolTableLevel::dump(TInfoSink &infoSink) const { tLevel::const_iterator it; for (it = level.begin(); it != level.end(); ++it) (*it).second->dump(infoSink); } void TSymbolTable::dump(TInfoSink &infoSink) const { for (int level = currentLevel(); level >= 0; --level) { infoSink.debug << "LEVEL " << level << "\n"; table[level]->dump(infoSink); } } // // Functions have buried pointers to delete. // TFunction::~TFunction() { for (TParamList::iterator i = parameters.begin(); i != parameters.end(); ++i) delete (*i).type; } // // Symbol table levels are a map of pointers to symbols that have to be deleted. // TSymbolTableLevel::~TSymbolTableLevel() { for (tLevel::iterator it = level.begin(); it != level.end(); ++it) delete (*it).second; } // // Change all function entries in the table with the non-mangled name // to be related to the provided built-in operation. This is a low // performance operation, and only intended for symbol tables that // live across a large number of compiles. // void TSymbolTableLevel::relateToOperator(const char* name, TOperator op) { tLevel::iterator it; for (it = level.begin(); it != level.end(); ++it) { if ((*it).second->isFunction()) { TFunction* function = static_cast((*it).second); if (function->getName() == name) function->relateToOperator(op); } } } // // Change all function entries in the table with the non-mangled name // to be related to the provided built-in extension. This is a low // performance operation, and only intended for symbol tables that // live across a large number of compiles. // void TSymbolTableLevel::relateToExtension(const char* name, const TString& ext) { for (tLevel::iterator it = level.begin(); it != level.end(); ++it) { if (it->second->isFunction()) { TFunction* function = static_cast(it->second); if (function->getName() == name) function->relateToExtension(ext); } } } TSymbol::TSymbol(const TSymbol& copyOf) { name = NewPoolTString(copyOf.name->c_str()); uniqueId = copyOf.uniqueId; } TVariable::TVariable(const TVariable& copyOf, TStructureMap& remapper) : TSymbol(copyOf) { type.copyType(copyOf.type, remapper); userType = copyOf.userType; // for builtIn symbol table level, unionArray and arrayInformation pointers should be NULL assert(copyOf.arrayInformationType == 0); arrayInformationType = 0; if (copyOf.unionArray) { assert(!copyOf.type.getStruct()); assert(copyOf.type.getObjectSize() == 1); unionArray = new ConstantUnion[1]; unionArray[0] = copyOf.unionArray[0]; } else unionArray = 0; } TVariable* TVariable::clone(TStructureMap& remapper) { TVariable *variable = new TVariable(*this, remapper); return variable; } TFunction::TFunction(const TFunction& copyOf, TStructureMap& remapper) : TSymbol(copyOf) { for (unsigned int i = 0; i < copyOf.parameters.size(); ++i) { TParameter param; parameters.push_back(param); parameters.back().copyParam(copyOf.parameters[i], remapper); } returnType.copyType(copyOf.returnType, remapper); mangledName = copyOf.mangledName; op = copyOf.op; defined = copyOf.defined; } TFunction* TFunction::clone(TStructureMap& remapper) { TFunction *function = new TFunction(*this, remapper); return function; } TSymbolTableLevel* TSymbolTableLevel::clone(TStructureMap& remapper) { TSymbolTableLevel *symTableLevel = new TSymbolTableLevel(); tLevel::iterator iter; for (iter = level.begin(); iter != level.end(); ++iter) { symTableLevel->insert(*iter->second->clone(remapper)); } return symTableLevel; } void TSymbolTable::copyTable(const TSymbolTable& copyOf) { TStructureMap remapper; uniqueId = copyOf.uniqueId; for (unsigned int i = 0; i < copyOf.table.size(); ++i) { table.push_back(copyOf.table[i]->clone(remapper)); } for( unsigned int i = 0; i < copyOf.precisionStack.size(); i++) { precisionStack.push_back( copyOf.precisionStack[i] ); } }