//===-- DeclContextInternals.h - DeclContext Representation -----*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file defines the data structures used in the implementation // of DeclContext. // //===----------------------------------------------------------------------===// #ifndef LLVM_CLANG_AST_DECLCONTEXTINTERNALS_H #define LLVM_CLANG_AST_DECLCONTEXTINTERNALS_H #include "clang/AST/Decl.h" #include "clang/AST/DeclCXX.h" #include "clang/AST/DeclarationName.h" #include "llvm/ADT/DenseMap.h" #include "llvm/ADT/PointerIntPair.h" #include "llvm/ADT/PointerUnion.h" #include "llvm/ADT/SmallVector.h" #include namespace clang { class DependentDiagnostic; /// \brief An array of decls optimized for the common case of only containing /// one entry. struct StoredDeclsList { /// \brief When in vector form, this is what the Data pointer points to. typedef SmallVector DeclsTy; /// \brief A collection of declarations, with a flag to indicate if we have /// further external declarations. typedef llvm::PointerIntPair DeclsAndHasExternalTy; /// \brief The stored data, which will be either a pointer to a NamedDecl, /// or a pointer to a vector with a flag to indicate if there are further /// external declarations. llvm::PointerUnion Data; public: StoredDeclsList() {} StoredDeclsList(StoredDeclsList &&RHS) : Data(RHS.Data) { RHS.Data = (NamedDecl *)nullptr; } ~StoredDeclsList() { // If this is a vector-form, free the vector. if (DeclsTy *Vector = getAsVector()) delete Vector; } StoredDeclsList &operator=(StoredDeclsList &&RHS) { if (DeclsTy *Vector = getAsVector()) delete Vector; Data = RHS.Data; RHS.Data = (NamedDecl *)nullptr; return *this; } bool isNull() const { return Data.isNull(); } NamedDecl *getAsDecl() const { return Data.dyn_cast(); } DeclsAndHasExternalTy getAsVectorAndHasExternal() const { return Data.dyn_cast(); } DeclsTy *getAsVector() const { return getAsVectorAndHasExternal().getPointer(); } bool hasExternalDecls() const { return getAsVectorAndHasExternal().getInt(); } void setHasExternalDecls() { if (DeclsTy *Vec = getAsVector()) Data = DeclsAndHasExternalTy(Vec, true); else { DeclsTy *VT = new DeclsTy(); if (NamedDecl *OldD = getAsDecl()) VT->push_back(OldD); Data = DeclsAndHasExternalTy(VT, true); } } void setOnlyValue(NamedDecl *ND) { assert(!getAsVector() && "Not inline"); Data = ND; // Make sure that Data is a plain NamedDecl* so we can use its address // at getLookupResult. assert(*(NamedDecl **)&Data == ND && "PointerUnion mangles the NamedDecl pointer!"); } void remove(NamedDecl *D) { assert(!isNull() && "removing from empty list"); if (NamedDecl *Singleton = getAsDecl()) { assert(Singleton == D && "list is different singleton"); (void)Singleton; Data = (NamedDecl *)nullptr; return; } DeclsTy &Vec = *getAsVector(); DeclsTy::iterator I = std::find(Vec.begin(), Vec.end(), D); assert(I != Vec.end() && "list does not contain decl"); Vec.erase(I); assert(std::find(Vec.begin(), Vec.end(), D) == Vec.end() && "list still contains decl"); } /// \brief Remove any declarations which were imported from an external /// AST source. void removeExternalDecls() { if (isNull()) { // Nothing to do. } else if (NamedDecl *Singleton = getAsDecl()) { if (Singleton->isFromASTFile()) *this = StoredDeclsList(); } else { DeclsTy &Vec = *getAsVector(); Vec.erase(std::remove_if(Vec.begin(), Vec.end(), std::mem_fun(&Decl::isFromASTFile)), Vec.end()); // Don't have any external decls any more. Data = DeclsAndHasExternalTy(&Vec, false); } } /// getLookupResult - Return an array of all the decls that this list /// represents. DeclContext::lookup_result getLookupResult() { if (isNull()) return DeclContext::lookup_result(); // If we have a single NamedDecl, return it. if (NamedDecl *ND = getAsDecl()) { assert(!isNull() && "Empty list isn't allowed"); // Data is a raw pointer to a NamedDecl*, return it. return DeclContext::lookup_result(ND); } assert(getAsVector() && "Must have a vector at this point"); DeclsTy &Vector = *getAsVector(); // Otherwise, we have a range result. return DeclContext::lookup_result(Vector); } /// HandleRedeclaration - If this is a redeclaration of an existing decl, /// replace the old one with D and return true. Otherwise return false. bool HandleRedeclaration(NamedDecl *D, bool IsKnownNewer) { // Most decls only have one entry in their list, special case it. if (NamedDecl *OldD = getAsDecl()) { if (!D->declarationReplaces(OldD, IsKnownNewer)) return false; setOnlyValue(D); return true; } // Determine if this declaration is actually a redeclaration. DeclsTy &Vec = *getAsVector(); for (DeclsTy::iterator OD = Vec.begin(), ODEnd = Vec.end(); OD != ODEnd; ++OD) { NamedDecl *OldD = *OD; if (D->declarationReplaces(OldD, IsKnownNewer)) { *OD = D; return true; } } return false; } /// AddSubsequentDecl - This is called on the second and later decl when it is /// not a redeclaration to merge it into the appropriate place in our list. /// void AddSubsequentDecl(NamedDecl *D) { assert(!isNull() && "don't AddSubsequentDecl when we have no decls"); // If this is the second decl added to the list, convert this to vector // form. if (NamedDecl *OldD = getAsDecl()) { DeclsTy *VT = new DeclsTy(); VT->push_back(OldD); Data = DeclsAndHasExternalTy(VT, false); } DeclsTy &Vec = *getAsVector(); // Using directives end up in a special entry which contains only // other using directives, so all this logic is wasted for them. // But avoiding the logic wastes time in the far-more-common case // that we're *not* adding a new using directive. // Tag declarations always go at the end of the list so that an // iterator which points at the first tag will start a span of // decls that only contains tags. if (D->hasTagIdentifierNamespace()) Vec.push_back(D); // Resolved using declarations go at the front of the list so that // they won't show up in other lookup results. Unresolved using // declarations (which are always in IDNS_Using | IDNS_Ordinary) // follow that so that the using declarations will be contiguous. else if (D->getIdentifierNamespace() & Decl::IDNS_Using) { DeclsTy::iterator I = Vec.begin(); if (D->getIdentifierNamespace() != Decl::IDNS_Using) { while (I != Vec.end() && (*I)->getIdentifierNamespace() == Decl::IDNS_Using) ++I; } Vec.insert(I, D); // All other declarations go at the end of the list, but before any // tag declarations. But we can be clever about tag declarations // because there can only ever be one in a scope. } else if (!Vec.empty() && Vec.back()->hasTagIdentifierNamespace()) { NamedDecl *TagD = Vec.back(); Vec.back() = D; Vec.push_back(TagD); } else Vec.push_back(D); } }; class StoredDeclsMap : public llvm::SmallDenseMap { public: static void DestroyAll(StoredDeclsMap *Map, bool Dependent); private: friend class ASTContext; // walks the chain deleting these friend class DeclContext; llvm::PointerIntPair Previous; }; class DependentStoredDeclsMap : public StoredDeclsMap { public: DependentStoredDeclsMap() : FirstDiagnostic(nullptr) {} private: friend class DependentDiagnostic; friend class DeclContext; // iterates over diagnostics DependentDiagnostic *FirstDiagnostic; }; } // end namespace clang #endif