//===- BuildTree.cpp ------------------------------------------*- C++ -*-=====// // // 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 // //===----------------------------------------------------------------------===// #include "clang/Tooling/Syntax/BuildTree.h" #include "clang/AST/ASTFwd.h" #include "clang/AST/Decl.h" #include "clang/AST/DeclBase.h" #include "clang/AST/DeclCXX.h" #include "clang/AST/DeclarationName.h" #include "clang/AST/Expr.h" #include "clang/AST/ExprCXX.h" #include "clang/AST/IgnoreExpr.h" #include "clang/AST/OperationKinds.h" #include "clang/AST/RecursiveASTVisitor.h" #include "clang/AST/Stmt.h" #include "clang/AST/TypeLoc.h" #include "clang/AST/TypeLocVisitor.h" #include "clang/Basic/LLVM.h" #include "clang/Basic/SourceLocation.h" #include "clang/Basic/SourceManager.h" #include "clang/Basic/Specifiers.h" #include "clang/Basic/TokenKinds.h" #include "clang/Lex/Lexer.h" #include "clang/Lex/LiteralSupport.h" #include "clang/Tooling/Syntax/Nodes.h" #include "clang/Tooling/Syntax/Tokens.h" #include "clang/Tooling/Syntax/Tree.h" #include "llvm/ADT/ArrayRef.h" #include "llvm/ADT/DenseMap.h" #include "llvm/ADT/PointerUnion.h" #include "llvm/ADT/STLExtras.h" #include "llvm/ADT/ScopeExit.h" #include "llvm/ADT/SmallVector.h" #include "llvm/Support/Allocator.h" #include "llvm/Support/Casting.h" #include "llvm/Support/Compiler.h" #include "llvm/Support/FormatVariadic.h" #include "llvm/Support/MemoryBuffer.h" #include "llvm/Support/raw_ostream.h" #include #include using namespace clang; // Ignores the implicit `CXXConstructExpr` for copy/move constructor calls // generated by the compiler, as well as in implicit conversions like the one // wrapping `1` in `X x = 1;`. static Expr *IgnoreImplicitConstructorSingleStep(Expr *E) { if (auto *C = dyn_cast(E)) { auto NumArgs = C->getNumArgs(); if (NumArgs == 1 || (NumArgs > 1 && isa(C->getArg(1)))) { Expr *A = C->getArg(0); if (C->getParenOrBraceRange().isInvalid()) return A; } } return E; } // In: // struct X { // X(int) // }; // X x = X(1); // Ignores the implicit `CXXFunctionalCastExpr` that wraps // `CXXConstructExpr X(1)`. static Expr *IgnoreCXXFunctionalCastExprWrappingConstructor(Expr *E) { if (auto *F = dyn_cast(E)) { if (F->getCastKind() == CK_ConstructorConversion) return F->getSubExpr(); } return E; } static Expr *IgnoreImplicit(Expr *E) { return IgnoreExprNodes(E, IgnoreImplicitSingleStep, IgnoreImplicitConstructorSingleStep, IgnoreCXXFunctionalCastExprWrappingConstructor); } LLVM_ATTRIBUTE_UNUSED static bool isImplicitExpr(Expr *E) { return IgnoreImplicit(E) != E; } namespace { /// Get start location of the Declarator from the TypeLoc. /// E.g.: /// loc of `(` in `int (a)` /// loc of `*` in `int *(a)` /// loc of the first `(` in `int (*a)(int)` /// loc of the `*` in `int *(a)(int)` /// loc of the first `*` in `const int *const *volatile a;` /// /// It is non-trivial to get the start location because TypeLocs are stored /// inside out. In the example above `*volatile` is the TypeLoc returned /// by `Decl.getTypeSourceInfo()`, and `*const` is what `.getPointeeLoc()` /// returns. struct GetStartLoc : TypeLocVisitor { SourceLocation VisitParenTypeLoc(ParenTypeLoc T) { auto L = Visit(T.getInnerLoc()); if (L.isValid()) return L; return T.getLParenLoc(); } // Types spelled in the prefix part of the declarator. SourceLocation VisitPointerTypeLoc(PointerTypeLoc T) { return HandlePointer(T); } SourceLocation VisitMemberPointerTypeLoc(MemberPointerTypeLoc T) { return HandlePointer(T); } SourceLocation VisitBlockPointerTypeLoc(BlockPointerTypeLoc T) { return HandlePointer(T); } SourceLocation VisitReferenceTypeLoc(ReferenceTypeLoc T) { return HandlePointer(T); } SourceLocation VisitObjCObjectPointerTypeLoc(ObjCObjectPointerTypeLoc T) { return HandlePointer(T); } // All other cases are not important, as they are either part of declaration // specifiers (e.g. inheritors of TypeSpecTypeLoc) or introduce modifiers on // existing declarators (e.g. QualifiedTypeLoc). They cannot start the // declarator themselves, but their underlying type can. SourceLocation VisitTypeLoc(TypeLoc T) { auto N = T.getNextTypeLoc(); if (!N) return SourceLocation(); return Visit(N); } SourceLocation VisitFunctionProtoTypeLoc(FunctionProtoTypeLoc T) { if (T.getTypePtr()->hasTrailingReturn()) return SourceLocation(); // avoid recursing into the suffix of declarator. return VisitTypeLoc(T); } private: template SourceLocation HandlePointer(PtrLoc T) { auto L = Visit(T.getPointeeLoc()); if (L.isValid()) return L; return T.getLocalSourceRange().getBegin(); } }; } // namespace static CallExpr::arg_range dropDefaultArgs(CallExpr::arg_range Args) { auto FirstDefaultArg = std::find_if(Args.begin(), Args.end(), [](auto It) { return isa(It); }); return llvm::make_range(Args.begin(), FirstDefaultArg); } static syntax::NodeKind getOperatorNodeKind(const CXXOperatorCallExpr &E) { switch (E.getOperator()) { // Comparison case OO_EqualEqual: case OO_ExclaimEqual: case OO_Greater: case OO_GreaterEqual: case OO_Less: case OO_LessEqual: case OO_Spaceship: // Assignment case OO_Equal: case OO_SlashEqual: case OO_PercentEqual: case OO_CaretEqual: case OO_PipeEqual: case OO_LessLessEqual: case OO_GreaterGreaterEqual: case OO_PlusEqual: case OO_MinusEqual: case OO_StarEqual: case OO_AmpEqual: // Binary computation case OO_Slash: case OO_Percent: case OO_Caret: case OO_Pipe: case OO_LessLess: case OO_GreaterGreater: case OO_AmpAmp: case OO_PipePipe: case OO_ArrowStar: case OO_Comma: return syntax::NodeKind::BinaryOperatorExpression; case OO_Tilde: case OO_Exclaim: return syntax::NodeKind::PrefixUnaryOperatorExpression; // Prefix/Postfix increment/decrement case OO_PlusPlus: case OO_MinusMinus: switch (E.getNumArgs()) { case 1: return syntax::NodeKind::PrefixUnaryOperatorExpression; case 2: return syntax::NodeKind::PostfixUnaryOperatorExpression; default: llvm_unreachable("Invalid number of arguments for operator"); } // Operators that can be unary or binary case OO_Plus: case OO_Minus: case OO_Star: case OO_Amp: switch (E.getNumArgs()) { case 1: return syntax::NodeKind::PrefixUnaryOperatorExpression; case 2: return syntax::NodeKind::BinaryOperatorExpression; default: llvm_unreachable("Invalid number of arguments for operator"); } return syntax::NodeKind::BinaryOperatorExpression; // Not yet supported by SyntaxTree case OO_New: case OO_Delete: case OO_Array_New: case OO_Array_Delete: case OO_Coawait: case OO_Subscript: case OO_Arrow: return syntax::NodeKind::UnknownExpression; case OO_Call: return syntax::NodeKind::CallExpression; case OO_Conditional: // not overloadable case NUM_OVERLOADED_OPERATORS: case OO_None: llvm_unreachable("Not an overloadable operator"); } llvm_unreachable("Unknown OverloadedOperatorKind enum"); } /// Get the start of the qualified name. In the examples below it gives the /// location of the `^`: /// `int ^a;` /// `int *^a;` /// `int ^a::S::f(){}` static SourceLocation getQualifiedNameStart(NamedDecl *D) { assert((isa(D)) && "only DeclaratorDecl and TypedefNameDecl are supported."); auto DN = D->getDeclName(); bool IsAnonymous = DN.isIdentifier() && !DN.getAsIdentifierInfo(); if (IsAnonymous) return SourceLocation(); if (const auto *DD = dyn_cast(D)) { if (DD->getQualifierLoc()) { return DD->getQualifierLoc().getBeginLoc(); } } return D->getLocation(); } /// Gets the range of the initializer inside an init-declarator C++ [dcl.decl]. /// `int a;` -> range of ``, /// `int *a = nullptr` -> range of `= nullptr`. /// `int a{}` -> range of `{}`. /// `int a()` -> range of `()`. static SourceRange getInitializerRange(Decl *D) { if (auto *V = dyn_cast(D)) { auto *I = V->getInit(); // Initializers in range-based-for are not part of the declarator if (I && !V->isCXXForRangeDecl()) return I->getSourceRange(); } return SourceRange(); } /// Gets the range of declarator as defined by the C++ grammar. E.g. /// `int a;` -> range of `a`, /// `int *a;` -> range of `*a`, /// `int a[10];` -> range of `a[10]`, /// `int a[1][2][3];` -> range of `a[1][2][3]`, /// `int *a = nullptr` -> range of `*a = nullptr`. /// `int S::f(){}` -> range of `S::f()`. /// FIXME: \p Name must be a source range. static SourceRange getDeclaratorRange(const SourceManager &SM, TypeLoc T, SourceLocation Name, SourceRange Initializer) { SourceLocation Start = GetStartLoc().Visit(T); SourceLocation End = T.getEndLoc(); if (Name.isValid()) { if (Start.isInvalid()) Start = Name; // End of TypeLoc could be invalid if the type is invalid, fallback to the // NameLoc. if (End.isInvalid() || SM.isBeforeInTranslationUnit(End, Name)) End = Name; } if (Initializer.isValid()) { auto InitializerEnd = Initializer.getEnd(); assert(SM.isBeforeInTranslationUnit(End, InitializerEnd) || End == InitializerEnd); End = InitializerEnd; } return SourceRange(Start, End); } namespace { /// All AST hierarchy roots that can be represented as pointers. using ASTPtr = llvm::PointerUnion; /// Maintains a mapping from AST to syntax tree nodes. This class will get more /// complicated as we support more kinds of AST nodes, e.g. TypeLocs. /// FIXME: expose this as public API. class ASTToSyntaxMapping { public: void add(ASTPtr From, syntax::Tree *To) { assert(To != nullptr); assert(!From.isNull()); bool Added = Nodes.insert({From, To}).second; (void)Added; assert(Added && "mapping added twice"); } void add(NestedNameSpecifierLoc From, syntax::Tree *To) { assert(To != nullptr); assert(From.hasQualifier()); bool Added = NNSNodes.insert({From, To}).second; (void)Added; assert(Added && "mapping added twice"); } syntax::Tree *find(ASTPtr P) const { return Nodes.lookup(P); } syntax::Tree *find(NestedNameSpecifierLoc P) const { return NNSNodes.lookup(P); } private: llvm::DenseMap Nodes; llvm::DenseMap NNSNodes; }; } // namespace /// A helper class for constructing the syntax tree while traversing a clang /// AST. /// /// At each point of the traversal we maintain a list of pending nodes. /// Initially all tokens are added as pending nodes. When processing a clang AST /// node, the clients need to: /// - create a corresponding syntax node, /// - assign roles to all pending child nodes with 'markChild' and /// 'markChildToken', /// - replace the child nodes with the new syntax node in the pending list /// with 'foldNode'. /// /// Note that all children are expected to be processed when building a node. /// /// Call finalize() to finish building the tree and consume the root node. class syntax::TreeBuilder { public: TreeBuilder(syntax::Arena &Arena) : Arena(Arena), Pending(Arena) { for (const auto &T : Arena.getTokenBuffer().expandedTokens()) LocationToToken.insert({T.location(), &T}); } llvm::BumpPtrAllocator &allocator() { return Arena.getAllocator(); } const SourceManager &sourceManager() const { return Arena.getSourceManager(); } /// Populate children for \p New node, assuming it covers tokens from \p /// Range. void foldNode(ArrayRef Range, syntax::Tree *New, ASTPtr From) { assert(New); Pending.foldChildren(Arena, Range, New); if (From) Mapping.add(From, New); } void foldNode(ArrayRef Range, syntax::Tree *New, TypeLoc L) { // FIXME: add mapping for TypeLocs foldNode(Range, New, nullptr); } void foldNode(llvm::ArrayRef Range, syntax::Tree *New, NestedNameSpecifierLoc From) { assert(New); Pending.foldChildren(Arena, Range, New); if (From) Mapping.add(From, New); } /// Populate children for \p New list, assuming it covers tokens from a /// subrange of \p SuperRange. void foldList(ArrayRef SuperRange, syntax::List *New, ASTPtr From) { assert(New); auto ListRange = Pending.shrinkToFitList(SuperRange); Pending.foldChildren(Arena, ListRange, New); if (From) Mapping.add(From, New); } /// Notifies that we should not consume trailing semicolon when computing /// token range of \p D. void noticeDeclWithoutSemicolon(Decl *D); /// Mark the \p Child node with a corresponding \p Role. All marked children /// should be consumed by foldNode. /// When called on expressions (clang::Expr is derived from clang::Stmt), /// wraps expressions into expression statement. void markStmtChild(Stmt *Child, NodeRole Role); /// Should be called for expressions in non-statement position to avoid /// wrapping into expression statement. void markExprChild(Expr *Child, NodeRole Role); /// Set role for a token starting at \p Loc. void markChildToken(SourceLocation Loc, NodeRole R); /// Set role for \p T. void markChildToken(const syntax::Token *T, NodeRole R); /// Set role for \p N. void markChild(syntax::Node *N, NodeRole R); /// Set role for the syntax node matching \p N. void markChild(ASTPtr N, NodeRole R); /// Set role for the syntax node matching \p N. void markChild(NestedNameSpecifierLoc N, NodeRole R); /// Finish building the tree and consume the root node. syntax::TranslationUnit *finalize() && { auto Tokens = Arena.getTokenBuffer().expandedTokens(); assert(!Tokens.empty()); assert(Tokens.back().kind() == tok::eof); // Build the root of the tree, consuming all the children. Pending.foldChildren(Arena, Tokens.drop_back(), new (Arena.getAllocator()) syntax::TranslationUnit); auto *TU = cast(std::move(Pending).finalize()); TU->assertInvariantsRecursive(); return TU; } /// Finds a token starting at \p L. The token must exist if \p L is valid. const syntax::Token *findToken(SourceLocation L) const; /// Finds the syntax tokens corresponding to the \p SourceRange. ArrayRef getRange(SourceRange Range) const { assert(Range.isValid()); return getRange(Range.getBegin(), Range.getEnd()); } /// Finds the syntax tokens corresponding to the passed source locations. /// \p First is the start position of the first token and \p Last is the start /// position of the last token. ArrayRef getRange(SourceLocation First, SourceLocation Last) const { assert(First.isValid()); assert(Last.isValid()); assert(First == Last || Arena.getSourceManager().isBeforeInTranslationUnit(First, Last)); return llvm::makeArrayRef(findToken(First), std::next(findToken(Last))); } ArrayRef getTemplateRange(const ClassTemplateSpecializationDecl *D) const { auto Tokens = getRange(D->getSourceRange()); return maybeAppendSemicolon(Tokens, D); } /// Returns true if \p D is the last declarator in a chain and is thus /// reponsible for creating SimpleDeclaration for the whole chain. bool isResponsibleForCreatingDeclaration(const Decl *D) const { assert((isa(D)) && "only DeclaratorDecl and TypedefNameDecl are supported."); const Decl *Next = D->getNextDeclInContext(); // There's no next sibling, this one is responsible. if (Next == nullptr) { return true; } // Next sibling is not the same type, this one is responsible. if (D->getKind() != Next->getKind()) { return true; } // Next sibling doesn't begin at the same loc, it must be a different // declaration, so this declarator is responsible. if (Next->getBeginLoc() != D->getBeginLoc()) { return true; } // NextT is a member of the same declaration, and we need the last member to // create declaration. This one is not responsible. return false; } ArrayRef getDeclarationRange(Decl *D) { ArrayRef Tokens; // We want to drop the template parameters for specializations. if (const auto *S = dyn_cast(D)) Tokens = getRange(S->TypeDecl::getBeginLoc(), S->getEndLoc()); else Tokens = getRange(D->getSourceRange()); return maybeAppendSemicolon(Tokens, D); } ArrayRef getExprRange(const Expr *E) const { return getRange(E->getSourceRange()); } /// Find the adjusted range for the statement, consuming the trailing /// semicolon when needed. ArrayRef getStmtRange(const Stmt *S) const { auto Tokens = getRange(S->getSourceRange()); if (isa(S)) return Tokens; // Some statements miss a trailing semicolon, e.g. 'return', 'continue' and // all statements that end with those. Consume this semicolon here. if (Tokens.back().kind() == tok::semi) return Tokens; return withTrailingSemicolon(Tokens); } private: ArrayRef maybeAppendSemicolon(ArrayRef Tokens, const Decl *D) const { if (isa(D)) return Tokens; if (DeclsWithoutSemicolons.count(D)) return Tokens; // FIXME: do not consume trailing semicolon on function definitions. // Most declarations own a semicolon in syntax trees, but not in clang AST. return withTrailingSemicolon(Tokens); } ArrayRef withTrailingSemicolon(ArrayRef Tokens) const { assert(!Tokens.empty()); assert(Tokens.back().kind() != tok::eof); // We never consume 'eof', so looking at the next token is ok. if (Tokens.back().kind() != tok::semi && Tokens.end()->kind() == tok::semi) return llvm::makeArrayRef(Tokens.begin(), Tokens.end() + 1); return Tokens; } void setRole(syntax::Node *N, NodeRole R) { assert(N->getRole() == NodeRole::Detached); N->setRole(R); } /// A collection of trees covering the input tokens. /// When created, each tree corresponds to a single token in the file. /// Clients call 'foldChildren' to attach one or more subtrees to a parent /// node and update the list of trees accordingly. /// /// Ensures that added nodes properly nest and cover the whole token stream. struct Forest { Forest(syntax::Arena &A) { assert(!A.getTokenBuffer().expandedTokens().empty()); assert(A.getTokenBuffer().expandedTokens().back().kind() == tok::eof); // Create all leaf nodes. // Note that we do not have 'eof' in the tree. for (const auto &T : A.getTokenBuffer().expandedTokens().drop_back()) { auto *L = new (A.getAllocator()) syntax::Leaf(&T); L->Original = true; L->CanModify = A.getTokenBuffer().spelledForExpanded(T).hasValue(); Trees.insert(Trees.end(), {&T, L}); } } void assignRole(ArrayRef Range, syntax::NodeRole Role) { assert(!Range.empty()); auto It = Trees.lower_bound(Range.begin()); assert(It != Trees.end() && "no node found"); assert(It->first == Range.begin() && "no child with the specified range"); assert((std::next(It) == Trees.end() || std::next(It)->first == Range.end()) && "no child with the specified range"); assert(It->second->getRole() == NodeRole::Detached && "re-assigning role for a child"); It->second->setRole(Role); } /// Shrink \p Range to a subrange that only contains tokens of a list. /// List elements and delimiters should already have correct roles. ArrayRef shrinkToFitList(ArrayRef Range) { auto BeginChildren = Trees.lower_bound(Range.begin()); assert((BeginChildren == Trees.end() || BeginChildren->first == Range.begin()) && "Range crosses boundaries of existing subtrees"); auto EndChildren = Trees.lower_bound(Range.end()); assert( (EndChildren == Trees.end() || EndChildren->first == Range.end()) && "Range crosses boundaries of existing subtrees"); auto BelongsToList = [](decltype(Trees)::value_type KV) { auto Role = KV.second->getRole(); return Role == syntax::NodeRole::ListElement || Role == syntax::NodeRole::ListDelimiter; }; auto BeginListChildren = std::find_if(BeginChildren, EndChildren, BelongsToList); auto EndListChildren = std::find_if_not(BeginListChildren, EndChildren, BelongsToList); return ArrayRef(BeginListChildren->first, EndListChildren->first); } /// Add \p Node to the forest and attach child nodes based on \p Tokens. void foldChildren(const syntax::Arena &A, ArrayRef Tokens, syntax::Tree *Node) { // Attach children to `Node`. assert(Node->getFirstChild() == nullptr && "node already has children"); auto *FirstToken = Tokens.begin(); auto BeginChildren = Trees.lower_bound(FirstToken); assert((BeginChildren == Trees.end() || BeginChildren->first == FirstToken) && "fold crosses boundaries of existing subtrees"); auto EndChildren = Trees.lower_bound(Tokens.end()); assert( (EndChildren == Trees.end() || EndChildren->first == Tokens.end()) && "fold crosses boundaries of existing subtrees"); for (auto It = BeginChildren; It != EndChildren; ++It) { auto *C = It->second; if (C->getRole() == NodeRole::Detached) C->setRole(NodeRole::Unknown); Node->appendChildLowLevel(C); } // Mark that this node came from the AST and is backed by the source code. Node->Original = true; Node->CanModify = A.getTokenBuffer().spelledForExpanded(Tokens).hasValue(); Trees.erase(BeginChildren, EndChildren); Trees.insert({FirstToken, Node}); } // EXPECTS: all tokens were consumed and are owned by a single root node. syntax::Node *finalize() && { assert(Trees.size() == 1); auto *Root = Trees.begin()->second; Trees = {}; return Root; } std::string str(const syntax::Arena &A) const { std::string R; for (auto It = Trees.begin(); It != Trees.end(); ++It) { unsigned CoveredTokens = It != Trees.end() ? (std::next(It)->first - It->first) : A.getTokenBuffer().expandedTokens().end() - It->first; R += std::string( formatv("- '{0}' covers '{1}'+{2} tokens\n", It->second->getKind(), It->first->text(A.getSourceManager()), CoveredTokens)); R += It->second->dump(A.getSourceManager()); } return R; } private: /// Maps from the start token to a subtree starting at that token. /// Keys in the map are pointers into the array of expanded tokens, so /// pointer order corresponds to the order of preprocessor tokens. std::map Trees; }; /// For debugging purposes. std::string str() { return Pending.str(Arena); } syntax::Arena &Arena; /// To quickly find tokens by their start location. llvm::DenseMap LocationToToken; Forest Pending; llvm::DenseSet DeclsWithoutSemicolons; ASTToSyntaxMapping Mapping; }; namespace { class BuildTreeVisitor : public RecursiveASTVisitor { public: explicit BuildTreeVisitor(ASTContext &Context, syntax::TreeBuilder &Builder) : Builder(Builder), Context(Context) {} bool shouldTraversePostOrder() const { return true; } bool WalkUpFromDeclaratorDecl(DeclaratorDecl *DD) { return processDeclaratorAndDeclaration(DD); } bool WalkUpFromTypedefNameDecl(TypedefNameDecl *TD) { return processDeclaratorAndDeclaration(TD); } bool VisitDecl(Decl *D) { assert(!D->isImplicit()); Builder.foldNode(Builder.getDeclarationRange(D), new (allocator()) syntax::UnknownDeclaration(), D); return true; } // RAV does not call WalkUpFrom* on explicit instantiations, so we have to // override Traverse. // FIXME: make RAV call WalkUpFrom* instead. bool TraverseClassTemplateSpecializationDecl(ClassTemplateSpecializationDecl *C) { if (!RecursiveASTVisitor::TraverseClassTemplateSpecializationDecl(C)) return false; if (C->isExplicitSpecialization()) return true; // we are only interested in explicit instantiations. auto *Declaration = cast(handleFreeStandingTagDecl(C)); foldExplicitTemplateInstantiation( Builder.getTemplateRange(C), Builder.findToken(C->getExternLoc()), Builder.findToken(C->getTemplateKeywordLoc()), Declaration, C); return true; } bool WalkUpFromTemplateDecl(TemplateDecl *S) { foldTemplateDeclaration( Builder.getDeclarationRange(S), Builder.findToken(S->getTemplateParameters()->getTemplateLoc()), Builder.getDeclarationRange(S->getTemplatedDecl()), S); return true; } bool WalkUpFromTagDecl(TagDecl *C) { // FIXME: build the ClassSpecifier node. if (!C->isFreeStanding()) { assert(C->getNumTemplateParameterLists() == 0); return true; } handleFreeStandingTagDecl(C); return true; } syntax::Declaration *handleFreeStandingTagDecl(TagDecl *C) { assert(C->isFreeStanding()); // Class is a declaration specifier and needs a spanning declaration node. auto DeclarationRange = Builder.getDeclarationRange(C); syntax::Declaration *Result = new (allocator()) syntax::SimpleDeclaration; Builder.foldNode(DeclarationRange, Result, nullptr); // Build TemplateDeclaration nodes if we had template parameters. auto ConsumeTemplateParameters = [&](const TemplateParameterList &L) { const auto *TemplateKW = Builder.findToken(L.getTemplateLoc()); auto R = llvm::makeArrayRef(TemplateKW, DeclarationRange.end()); Result = foldTemplateDeclaration(R, TemplateKW, DeclarationRange, nullptr); DeclarationRange = R; }; if (auto *S = dyn_cast(C)) ConsumeTemplateParameters(*S->getTemplateParameters()); for (unsigned I = C->getNumTemplateParameterLists(); 0 < I; --I) ConsumeTemplateParameters(*C->getTemplateParameterList(I - 1)); return Result; } bool WalkUpFromTranslationUnitDecl(TranslationUnitDecl *TU) { // We do not want to call VisitDecl(), the declaration for translation // unit is built by finalize(). return true; } bool WalkUpFromCompoundStmt(CompoundStmt *S) { using NodeRole = syntax::NodeRole; Builder.markChildToken(S->getLBracLoc(), NodeRole::OpenParen); for (auto *Child : S->body()) Builder.markStmtChild(Child, NodeRole::Statement); Builder.markChildToken(S->getRBracLoc(), NodeRole::CloseParen); Builder.foldNode(Builder.getStmtRange(S), new (allocator()) syntax::CompoundStatement, S); return true; } // Some statements are not yet handled by syntax trees. bool WalkUpFromStmt(Stmt *S) { Builder.foldNode(Builder.getStmtRange(S), new (allocator()) syntax::UnknownStatement, S); return true; } bool TraverseIfStmt(IfStmt *S) { bool Result = [&, this]() { if (S->getInit() && !TraverseStmt(S->getInit())) { return false; } // In cases where the condition is an initialized declaration in a // statement, we want to preserve the declaration and ignore the // implicit condition expression in the syntax tree. if (S->hasVarStorage()) { if (!TraverseStmt(S->getConditionVariableDeclStmt())) return false; } else if (S->getCond() && !TraverseStmt(S->getCond())) return false; if (S->getThen() && !TraverseStmt(S->getThen())) return false; if (S->getElse() && !TraverseStmt(S->getElse())) return false; return true; }(); WalkUpFromIfStmt(S); return Result; } bool TraverseCXXForRangeStmt(CXXForRangeStmt *S) { // We override to traverse range initializer as VarDecl. // RAV traverses it as a statement, we produce invalid node kinds in that // case. // FIXME: should do this in RAV instead? bool Result = [&, this]() { if (S->getInit() && !TraverseStmt(S->getInit())) return false; if (S->getLoopVariable() && !TraverseDecl(S->getLoopVariable())) return false; if (S->getRangeInit() && !TraverseStmt(S->getRangeInit())) return false; if (S->getBody() && !TraverseStmt(S->getBody())) return false; return true; }(); WalkUpFromCXXForRangeStmt(S); return Result; } bool TraverseStmt(Stmt *S) { if (auto *DS = dyn_cast_or_null(S)) { // We want to consume the semicolon, make sure SimpleDeclaration does not. for (auto *D : DS->decls()) Builder.noticeDeclWithoutSemicolon(D); } else if (auto *E = dyn_cast_or_null(S)) { return RecursiveASTVisitor::TraverseStmt(IgnoreImplicit(E)); } return RecursiveASTVisitor::TraverseStmt(S); } bool TraverseOpaqueValueExpr(OpaqueValueExpr *VE) { // OpaqueValue doesn't correspond to concrete syntax, ignore it. return true; } // Some expressions are not yet handled by syntax trees. bool WalkUpFromExpr(Expr *E) { assert(!isImplicitExpr(E) && "should be handled by TraverseStmt"); Builder.foldNode(Builder.getExprRange(E), new (allocator()) syntax::UnknownExpression, E); return true; } bool TraverseUserDefinedLiteral(UserDefinedLiteral *S) { // The semantic AST node `UserDefinedLiteral` (UDL) may have one child node // referencing the location of the UDL suffix (`_w` in `1.2_w`). The // UDL suffix location does not point to the beginning of a token, so we // can't represent the UDL suffix as a separate syntax tree node. return WalkUpFromUserDefinedLiteral(S); } syntax::UserDefinedLiteralExpression * buildUserDefinedLiteral(UserDefinedLiteral *S) { switch (S->getLiteralOperatorKind()) { case UserDefinedLiteral::LOK_Integer: return new (allocator()) syntax::IntegerUserDefinedLiteralExpression; case UserDefinedLiteral::LOK_Floating: return new (allocator()) syntax::FloatUserDefinedLiteralExpression; case UserDefinedLiteral::LOK_Character: return new (allocator()) syntax::CharUserDefinedLiteralExpression; case UserDefinedLiteral::LOK_String: return new (allocator()) syntax::StringUserDefinedLiteralExpression; case UserDefinedLiteral::LOK_Raw: case UserDefinedLiteral::LOK_Template: // For raw literal operator and numeric literal operator template we // cannot get the type of the operand in the semantic AST. We get this // information from the token. As integer and floating point have the same // token kind, we run `NumericLiteralParser` again to distinguish them. auto TokLoc = S->getBeginLoc(); auto TokSpelling = Builder.findToken(TokLoc)->text(Context.getSourceManager()); auto Literal = NumericLiteralParser(TokSpelling, TokLoc, Context.getSourceManager(), Context.getLangOpts(), Context.getTargetInfo(), Context.getDiagnostics()); if (Literal.isIntegerLiteral()) return new (allocator()) syntax::IntegerUserDefinedLiteralExpression; else { assert(Literal.isFloatingLiteral()); return new (allocator()) syntax::FloatUserDefinedLiteralExpression; } } llvm_unreachable("Unknown literal operator kind."); } bool WalkUpFromUserDefinedLiteral(UserDefinedLiteral *S) { Builder.markChildToken(S->getBeginLoc(), syntax::NodeRole::LiteralToken); Builder.foldNode(Builder.getExprRange(S), buildUserDefinedLiteral(S), S); return true; } // FIXME: Fix `NestedNameSpecifierLoc::getLocalSourceRange` for the // `DependentTemplateSpecializationType` case. /// Given a nested-name-specifier return the range for the last name /// specifier. /// /// e.g. `std::T::template X::` => `template X::` SourceRange getLocalSourceRange(const NestedNameSpecifierLoc &NNSLoc) { auto SR = NNSLoc.getLocalSourceRange(); // The method `NestedNameSpecifierLoc::getLocalSourceRange` *should* // return the desired `SourceRange`, but there is a corner case. For a // `DependentTemplateSpecializationType` this method returns its // qualifiers as well, in other words in the example above this method // returns `T::template X::` instead of only `template X::` if (auto TL = NNSLoc.getTypeLoc()) { if (auto DependentTL = TL.getAs()) { // The 'template' keyword is always present in dependent template // specializations. Except in the case of incorrect code // TODO: Treat the case of incorrect code. SR.setBegin(DependentTL.getTemplateKeywordLoc()); } } return SR; } syntax::NodeKind getNameSpecifierKind(const NestedNameSpecifier &NNS) { switch (NNS.getKind()) { case NestedNameSpecifier::Global: return syntax::NodeKind::GlobalNameSpecifier; case NestedNameSpecifier::Namespace: case NestedNameSpecifier::NamespaceAlias: case NestedNameSpecifier::Identifier: return syntax::NodeKind::IdentifierNameSpecifier; case NestedNameSpecifier::TypeSpecWithTemplate: return syntax::NodeKind::SimpleTemplateNameSpecifier; case NestedNameSpecifier::TypeSpec: { const auto *NNSType = NNS.getAsType(); assert(NNSType); if (isa(NNSType)) return syntax::NodeKind::DecltypeNameSpecifier; if (isa( NNSType)) return syntax::NodeKind::SimpleTemplateNameSpecifier; return syntax::NodeKind::IdentifierNameSpecifier; } default: // FIXME: Support Microsoft's __super llvm::report_fatal_error("We don't yet support the __super specifier", true); } } syntax::NameSpecifier * buildNameSpecifier(const NestedNameSpecifierLoc &NNSLoc) { assert(NNSLoc.hasQualifier()); auto NameSpecifierTokens = Builder.getRange(getLocalSourceRange(NNSLoc)).drop_back(); switch (getNameSpecifierKind(*NNSLoc.getNestedNameSpecifier())) { case syntax::NodeKind::GlobalNameSpecifier: return new (allocator()) syntax::GlobalNameSpecifier; case syntax::NodeKind::IdentifierNameSpecifier: { assert(NameSpecifierTokens.size() == 1); Builder.markChildToken(NameSpecifierTokens.begin(), syntax::NodeRole::Unknown); auto *NS = new (allocator()) syntax::IdentifierNameSpecifier; Builder.foldNode(NameSpecifierTokens, NS, nullptr); return NS; } case syntax::NodeKind::SimpleTemplateNameSpecifier: { // TODO: Build `SimpleTemplateNameSpecifier` children and implement // accessors to them. // Be aware, we cannot do that simply by calling `TraverseTypeLoc`, // some `TypeLoc`s have inside them the previous name specifier and // we want to treat them independently. auto *NS = new (allocator()) syntax::SimpleTemplateNameSpecifier; Builder.foldNode(NameSpecifierTokens, NS, nullptr); return NS; } case syntax::NodeKind::DecltypeNameSpecifier: { const auto TL = NNSLoc.getTypeLoc().castAs(); if (!RecursiveASTVisitor::TraverseDecltypeTypeLoc(TL)) return nullptr; auto *NS = new (allocator()) syntax::DecltypeNameSpecifier; // TODO: Implement accessor to `DecltypeNameSpecifier` inner // `DecltypeTypeLoc`. // For that add mapping from `TypeLoc` to `syntax::Node*` then: // Builder.markChild(TypeLoc, syntax::NodeRole); Builder.foldNode(NameSpecifierTokens, NS, nullptr); return NS; } default: llvm_unreachable("getChildKind() does not return this value"); } } // To build syntax tree nodes for NestedNameSpecifierLoc we override // Traverse instead of WalkUpFrom because we want to traverse the children // ourselves and build a list instead of a nested tree of name specifier // prefixes. bool TraverseNestedNameSpecifierLoc(NestedNameSpecifierLoc QualifierLoc) { if (!QualifierLoc) return true; for (auto It = QualifierLoc; It; It = It.getPrefix()) { auto *NS = buildNameSpecifier(It); if (!NS) return false; Builder.markChild(NS, syntax::NodeRole::ListElement); Builder.markChildToken(It.getEndLoc(), syntax::NodeRole::ListDelimiter); } Builder.foldNode(Builder.getRange(QualifierLoc.getSourceRange()), new (allocator()) syntax::NestedNameSpecifier, QualifierLoc); return true; } syntax::IdExpression *buildIdExpression(NestedNameSpecifierLoc QualifierLoc, SourceLocation TemplateKeywordLoc, SourceRange UnqualifiedIdLoc, ASTPtr From) { if (QualifierLoc) { Builder.markChild(QualifierLoc, syntax::NodeRole::Qualifier); if (TemplateKeywordLoc.isValid()) Builder.markChildToken(TemplateKeywordLoc, syntax::NodeRole::TemplateKeyword); } auto *TheUnqualifiedId = new (allocator()) syntax::UnqualifiedId; Builder.foldNode(Builder.getRange(UnqualifiedIdLoc), TheUnqualifiedId, nullptr); Builder.markChild(TheUnqualifiedId, syntax::NodeRole::UnqualifiedId); auto IdExpressionBeginLoc = QualifierLoc ? QualifierLoc.getBeginLoc() : UnqualifiedIdLoc.getBegin(); auto *TheIdExpression = new (allocator()) syntax::IdExpression; Builder.foldNode( Builder.getRange(IdExpressionBeginLoc, UnqualifiedIdLoc.getEnd()), TheIdExpression, From); return TheIdExpression; } bool WalkUpFromMemberExpr(MemberExpr *S) { // For `MemberExpr` with implicit `this->` we generate a simple // `id-expression` syntax node, beacuse an implicit `member-expression` is // syntactically undistinguishable from an `id-expression` if (S->isImplicitAccess()) { buildIdExpression(S->getQualifierLoc(), S->getTemplateKeywordLoc(), SourceRange(S->getMemberLoc(), S->getEndLoc()), S); return true; } auto *TheIdExpression = buildIdExpression( S->getQualifierLoc(), S->getTemplateKeywordLoc(), SourceRange(S->getMemberLoc(), S->getEndLoc()), nullptr); Builder.markChild(TheIdExpression, syntax::NodeRole::Member); Builder.markExprChild(S->getBase(), syntax::NodeRole::Object); Builder.markChildToken(S->getOperatorLoc(), syntax::NodeRole::AccessToken); Builder.foldNode(Builder.getExprRange(S), new (allocator()) syntax::MemberExpression, S); return true; } bool WalkUpFromDeclRefExpr(DeclRefExpr *S) { buildIdExpression(S->getQualifierLoc(), S->getTemplateKeywordLoc(), SourceRange(S->getLocation(), S->getEndLoc()), S); return true; } // Same logic as DeclRefExpr. bool WalkUpFromDependentScopeDeclRefExpr(DependentScopeDeclRefExpr *S) { buildIdExpression(S->getQualifierLoc(), S->getTemplateKeywordLoc(), SourceRange(S->getLocation(), S->getEndLoc()), S); return true; } bool WalkUpFromCXXThisExpr(CXXThisExpr *S) { if (!S->isImplicit()) { Builder.markChildToken(S->getLocation(), syntax::NodeRole::IntroducerKeyword); Builder.foldNode(Builder.getExprRange(S), new (allocator()) syntax::ThisExpression, S); } return true; } bool WalkUpFromParenExpr(ParenExpr *S) { Builder.markChildToken(S->getLParen(), syntax::NodeRole::OpenParen); Builder.markExprChild(S->getSubExpr(), syntax::NodeRole::SubExpression); Builder.markChildToken(S->getRParen(), syntax::NodeRole::CloseParen); Builder.foldNode(Builder.getExprRange(S), new (allocator()) syntax::ParenExpression, S); return true; } bool WalkUpFromIntegerLiteral(IntegerLiteral *S) { Builder.markChildToken(S->getLocation(), syntax::NodeRole::LiteralToken); Builder.foldNode(Builder.getExprRange(S), new (allocator()) syntax::IntegerLiteralExpression, S); return true; } bool WalkUpFromCharacterLiteral(CharacterLiteral *S) { Builder.markChildToken(S->getLocation(), syntax::NodeRole::LiteralToken); Builder.foldNode(Builder.getExprRange(S), new (allocator()) syntax::CharacterLiteralExpression, S); return true; } bool WalkUpFromFloatingLiteral(FloatingLiteral *S) { Builder.markChildToken(S->getLocation(), syntax::NodeRole::LiteralToken); Builder.foldNode(Builder.getExprRange(S), new (allocator()) syntax::FloatingLiteralExpression, S); return true; } bool WalkUpFromStringLiteral(StringLiteral *S) { Builder.markChildToken(S->getBeginLoc(), syntax::NodeRole::LiteralToken); Builder.foldNode(Builder.getExprRange(S), new (allocator()) syntax::StringLiteralExpression, S); return true; } bool WalkUpFromCXXBoolLiteralExpr(CXXBoolLiteralExpr *S) { Builder.markChildToken(S->getLocation(), syntax::NodeRole::LiteralToken); Builder.foldNode(Builder.getExprRange(S), new (allocator()) syntax::BoolLiteralExpression, S); return true; } bool WalkUpFromCXXNullPtrLiteralExpr(CXXNullPtrLiteralExpr *S) { Builder.markChildToken(S->getLocation(), syntax::NodeRole::LiteralToken); Builder.foldNode(Builder.getExprRange(S), new (allocator()) syntax::CxxNullPtrExpression, S); return true; } bool WalkUpFromUnaryOperator(UnaryOperator *S) { Builder.markChildToken(S->getOperatorLoc(), syntax::NodeRole::OperatorToken); Builder.markExprChild(S->getSubExpr(), syntax::NodeRole::Operand); if (S->isPostfix()) Builder.foldNode(Builder.getExprRange(S), new (allocator()) syntax::PostfixUnaryOperatorExpression, S); else Builder.foldNode(Builder.getExprRange(S), new (allocator()) syntax::PrefixUnaryOperatorExpression, S); return true; } bool WalkUpFromBinaryOperator(BinaryOperator *S) { Builder.markExprChild(S->getLHS(), syntax::NodeRole::LeftHandSide); Builder.markChildToken(S->getOperatorLoc(), syntax::NodeRole::OperatorToken); Builder.markExprChild(S->getRHS(), syntax::NodeRole::RightHandSide); Builder.foldNode(Builder.getExprRange(S), new (allocator()) syntax::BinaryOperatorExpression, S); return true; } /// Builds `CallArguments` syntax node from arguments that appear in source /// code, i.e. not default arguments. syntax::CallArguments * buildCallArguments(CallExpr::arg_range ArgsAndDefaultArgs) { auto Args = dropDefaultArgs(ArgsAndDefaultArgs); for (auto *Arg : Args) { Builder.markExprChild(Arg, syntax::NodeRole::ListElement); const auto *DelimiterToken = std::next(Builder.findToken(Arg->getEndLoc())); if (DelimiterToken->kind() == clang::tok::TokenKind::comma) Builder.markChildToken(DelimiterToken, syntax::NodeRole::ListDelimiter); } auto *Arguments = new (allocator()) syntax::CallArguments; if (!Args.empty()) Builder.foldNode(Builder.getRange((*Args.begin())->getBeginLoc(), (*(Args.end() - 1))->getEndLoc()), Arguments, nullptr); return Arguments; } bool WalkUpFromCallExpr(CallExpr *S) { Builder.markExprChild(S->getCallee(), syntax::NodeRole::Callee); const auto *LParenToken = std::next(Builder.findToken(S->getCallee()->getEndLoc())); // FIXME: Assert that `LParenToken` is indeed a `l_paren` once we have fixed // the test on decltype desctructors. if (LParenToken->kind() == clang::tok::l_paren) Builder.markChildToken(LParenToken, syntax::NodeRole::OpenParen); Builder.markChild(buildCallArguments(S->arguments()), syntax::NodeRole::Arguments); Builder.markChildToken(S->getRParenLoc(), syntax::NodeRole::CloseParen); Builder.foldNode(Builder.getRange(S->getSourceRange()), new (allocator()) syntax::CallExpression, S); return true; } bool WalkUpFromCXXConstructExpr(CXXConstructExpr *S) { // Ignore the implicit calls to default constructors. if ((S->getNumArgs() == 0 || isa(S->getArg(0))) && S->getParenOrBraceRange().isInvalid()) return true; return RecursiveASTVisitor::WalkUpFromCXXConstructExpr(S); } bool TraverseCXXOperatorCallExpr(CXXOperatorCallExpr *S) { // To construct a syntax tree of the same shape for calls to built-in and // user-defined operators, ignore the `DeclRefExpr` that refers to the // operator and treat it as a simple token. Do that by traversing // arguments instead of children. for (auto *child : S->arguments()) { // A postfix unary operator is declared as taking two operands. The // second operand is used to distinguish from its prefix counterpart. In // the semantic AST this "phantom" operand is represented as a // `IntegerLiteral` with invalid `SourceLocation`. We skip visiting this // operand because it does not correspond to anything written in source // code. if (child->getSourceRange().isInvalid()) { assert(getOperatorNodeKind(*S) == syntax::NodeKind::PostfixUnaryOperatorExpression); continue; } if (!TraverseStmt(child)) return false; } return WalkUpFromCXXOperatorCallExpr(S); } bool WalkUpFromCXXOperatorCallExpr(CXXOperatorCallExpr *S) { switch (getOperatorNodeKind(*S)) { case syntax::NodeKind::BinaryOperatorExpression: Builder.markExprChild(S->getArg(0), syntax::NodeRole::LeftHandSide); Builder.markChildToken(S->getOperatorLoc(), syntax::NodeRole::OperatorToken); Builder.markExprChild(S->getArg(1), syntax::NodeRole::RightHandSide); Builder.foldNode(Builder.getExprRange(S), new (allocator()) syntax::BinaryOperatorExpression, S); return true; case syntax::NodeKind::PrefixUnaryOperatorExpression: Builder.markChildToken(S->getOperatorLoc(), syntax::NodeRole::OperatorToken); Builder.markExprChild(S->getArg(0), syntax::NodeRole::Operand); Builder.foldNode(Builder.getExprRange(S), new (allocator()) syntax::PrefixUnaryOperatorExpression, S); return true; case syntax::NodeKind::PostfixUnaryOperatorExpression: Builder.markChildToken(S->getOperatorLoc(), syntax::NodeRole::OperatorToken); Builder.markExprChild(S->getArg(0), syntax::NodeRole::Operand); Builder.foldNode(Builder.getExprRange(S), new (allocator()) syntax::PostfixUnaryOperatorExpression, S); return true; case syntax::NodeKind::CallExpression: { Builder.markExprChild(S->getArg(0), syntax::NodeRole::Callee); const auto *LParenToken = std::next(Builder.findToken(S->getArg(0)->getEndLoc())); // FIXME: Assert that `LParenToken` is indeed a `l_paren` once we have // fixed the test on decltype desctructors. if (LParenToken->kind() == clang::tok::l_paren) Builder.markChildToken(LParenToken, syntax::NodeRole::OpenParen); Builder.markChild(buildCallArguments(CallExpr::arg_range( S->arg_begin() + 1, S->arg_end())), syntax::NodeRole::Arguments); Builder.markChildToken(S->getRParenLoc(), syntax::NodeRole::CloseParen); Builder.foldNode(Builder.getRange(S->getSourceRange()), new (allocator()) syntax::CallExpression, S); return true; } case syntax::NodeKind::UnknownExpression: return WalkUpFromExpr(S); default: llvm_unreachable("getOperatorNodeKind() does not return this value"); } } bool WalkUpFromCXXDefaultArgExpr(CXXDefaultArgExpr *S) { return true; } bool WalkUpFromNamespaceDecl(NamespaceDecl *S) { auto Tokens = Builder.getDeclarationRange(S); if (Tokens.front().kind() == tok::coloncolon) { // Handle nested namespace definitions. Those start at '::' token, e.g. // namespace a^::b {} // FIXME: build corresponding nodes for the name of this namespace. return true; } Builder.foldNode(Tokens, new (allocator()) syntax::NamespaceDefinition, S); return true; } // FIXME: Deleting the `TraverseParenTypeLoc` override doesn't change test // results. Find test coverage or remove it. bool TraverseParenTypeLoc(ParenTypeLoc L) { // We reverse order of traversal to get the proper syntax structure. if (!WalkUpFromParenTypeLoc(L)) return false; return TraverseTypeLoc(L.getInnerLoc()); } bool WalkUpFromParenTypeLoc(ParenTypeLoc L) { Builder.markChildToken(L.getLParenLoc(), syntax::NodeRole::OpenParen); Builder.markChildToken(L.getRParenLoc(), syntax::NodeRole::CloseParen); Builder.foldNode(Builder.getRange(L.getLParenLoc(), L.getRParenLoc()), new (allocator()) syntax::ParenDeclarator, L); return true; } // Declarator chunks, they are produced by type locs and some clang::Decls. bool WalkUpFromArrayTypeLoc(ArrayTypeLoc L) { Builder.markChildToken(L.getLBracketLoc(), syntax::NodeRole::OpenParen); Builder.markExprChild(L.getSizeExpr(), syntax::NodeRole::Size); Builder.markChildToken(L.getRBracketLoc(), syntax::NodeRole::CloseParen); Builder.foldNode(Builder.getRange(L.getLBracketLoc(), L.getRBracketLoc()), new (allocator()) syntax::ArraySubscript, L); return true; } syntax::ParameterDeclarationList * buildParameterDeclarationList(ArrayRef Params) { for (auto *P : Params) { Builder.markChild(P, syntax::NodeRole::ListElement); const auto *DelimiterToken = std::next(Builder.findToken(P->getEndLoc())); if (DelimiterToken->kind() == clang::tok::TokenKind::comma) Builder.markChildToken(DelimiterToken, syntax::NodeRole::ListDelimiter); } auto *Parameters = new (allocator()) syntax::ParameterDeclarationList; if (!Params.empty()) Builder.foldNode(Builder.getRange(Params.front()->getBeginLoc(), Params.back()->getEndLoc()), Parameters, nullptr); return Parameters; } bool WalkUpFromFunctionTypeLoc(FunctionTypeLoc L) { Builder.markChildToken(L.getLParenLoc(), syntax::NodeRole::OpenParen); Builder.markChild(buildParameterDeclarationList(L.getParams()), syntax::NodeRole::Parameters); Builder.markChildToken(L.getRParenLoc(), syntax::NodeRole::CloseParen); Builder.foldNode(Builder.getRange(L.getLParenLoc(), L.getEndLoc()), new (allocator()) syntax::ParametersAndQualifiers, L); return true; } bool WalkUpFromFunctionProtoTypeLoc(FunctionProtoTypeLoc L) { if (!L.getTypePtr()->hasTrailingReturn()) return WalkUpFromFunctionTypeLoc(L); auto *TrailingReturnTokens = buildTrailingReturn(L); // Finish building the node for parameters. Builder.markChild(TrailingReturnTokens, syntax::NodeRole::TrailingReturn); return WalkUpFromFunctionTypeLoc(L); } bool TraverseMemberPointerTypeLoc(MemberPointerTypeLoc L) { // In the source code "void (Y::*mp)()" `MemberPointerTypeLoc` corresponds // to "Y::*" but it points to a `ParenTypeLoc` that corresponds to // "(Y::*mp)" We thus reverse the order of traversal to get the proper // syntax structure. if (!WalkUpFromMemberPointerTypeLoc(L)) return false; return TraverseTypeLoc(L.getPointeeLoc()); } bool WalkUpFromMemberPointerTypeLoc(MemberPointerTypeLoc L) { auto SR = L.getLocalSourceRange(); Builder.foldNode(Builder.getRange(SR), new (allocator()) syntax::MemberPointer, L); return true; } // The code below is very regular, it could even be generated with some // preprocessor magic. We merely assign roles to the corresponding children // and fold resulting nodes. bool WalkUpFromDeclStmt(DeclStmt *S) { Builder.foldNode(Builder.getStmtRange(S), new (allocator()) syntax::DeclarationStatement, S); return true; } bool WalkUpFromNullStmt(NullStmt *S) { Builder.foldNode(Builder.getStmtRange(S), new (allocator()) syntax::EmptyStatement, S); return true; } bool WalkUpFromSwitchStmt(SwitchStmt *S) { Builder.markChildToken(S->getSwitchLoc(), syntax::NodeRole::IntroducerKeyword); Builder.markStmtChild(S->getBody(), syntax::NodeRole::BodyStatement); Builder.foldNode(Builder.getStmtRange(S), new (allocator()) syntax::SwitchStatement, S); return true; } bool WalkUpFromCaseStmt(CaseStmt *S) { Builder.markChildToken(S->getKeywordLoc(), syntax::NodeRole::IntroducerKeyword); Builder.markExprChild(S->getLHS(), syntax::NodeRole::CaseValue); Builder.markStmtChild(S->getSubStmt(), syntax::NodeRole::BodyStatement); Builder.foldNode(Builder.getStmtRange(S), new (allocator()) syntax::CaseStatement, S); return true; } bool WalkUpFromDefaultStmt(DefaultStmt *S) { Builder.markChildToken(S->getKeywordLoc(), syntax::NodeRole::IntroducerKeyword); Builder.markStmtChild(S->getSubStmt(), syntax::NodeRole::BodyStatement); Builder.foldNode(Builder.getStmtRange(S), new (allocator()) syntax::DefaultStatement, S); return true; } bool WalkUpFromIfStmt(IfStmt *S) { Builder.markChildToken(S->getIfLoc(), syntax::NodeRole::IntroducerKeyword); Stmt *ConditionStatement = S->getCond(); if (S->hasVarStorage()) ConditionStatement = S->getConditionVariableDeclStmt(); Builder.markStmtChild(ConditionStatement, syntax::NodeRole::Condition); Builder.markStmtChild(S->getThen(), syntax::NodeRole::ThenStatement); Builder.markChildToken(S->getElseLoc(), syntax::NodeRole::ElseKeyword); Builder.markStmtChild(S->getElse(), syntax::NodeRole::ElseStatement); Builder.foldNode(Builder.getStmtRange(S), new (allocator()) syntax::IfStatement, S); return true; } bool WalkUpFromForStmt(ForStmt *S) { Builder.markChildToken(S->getForLoc(), syntax::NodeRole::IntroducerKeyword); Builder.markStmtChild(S->getBody(), syntax::NodeRole::BodyStatement); Builder.foldNode(Builder.getStmtRange(S), new (allocator()) syntax::ForStatement, S); return true; } bool WalkUpFromWhileStmt(WhileStmt *S) { Builder.markChildToken(S->getWhileLoc(), syntax::NodeRole::IntroducerKeyword); Builder.markStmtChild(S->getBody(), syntax::NodeRole::BodyStatement); Builder.foldNode(Builder.getStmtRange(S), new (allocator()) syntax::WhileStatement, S); return true; } bool WalkUpFromContinueStmt(ContinueStmt *S) { Builder.markChildToken(S->getContinueLoc(), syntax::NodeRole::IntroducerKeyword); Builder.foldNode(Builder.getStmtRange(S), new (allocator()) syntax::ContinueStatement, S); return true; } bool WalkUpFromBreakStmt(BreakStmt *S) { Builder.markChildToken(S->getBreakLoc(), syntax::NodeRole::IntroducerKeyword); Builder.foldNode(Builder.getStmtRange(S), new (allocator()) syntax::BreakStatement, S); return true; } bool WalkUpFromReturnStmt(ReturnStmt *S) { Builder.markChildToken(S->getReturnLoc(), syntax::NodeRole::IntroducerKeyword); Builder.markExprChild(S->getRetValue(), syntax::NodeRole::ReturnValue); Builder.foldNode(Builder.getStmtRange(S), new (allocator()) syntax::ReturnStatement, S); return true; } bool WalkUpFromCXXForRangeStmt(CXXForRangeStmt *S) { Builder.markChildToken(S->getForLoc(), syntax::NodeRole::IntroducerKeyword); Builder.markStmtChild(S->getBody(), syntax::NodeRole::BodyStatement); Builder.foldNode(Builder.getStmtRange(S), new (allocator()) syntax::RangeBasedForStatement, S); return true; } bool WalkUpFromEmptyDecl(EmptyDecl *S) { Builder.foldNode(Builder.getDeclarationRange(S), new (allocator()) syntax::EmptyDeclaration, S); return true; } bool WalkUpFromStaticAssertDecl(StaticAssertDecl *S) { Builder.markExprChild(S->getAssertExpr(), syntax::NodeRole::Condition); Builder.markExprChild(S->getMessage(), syntax::NodeRole::Message); Builder.foldNode(Builder.getDeclarationRange(S), new (allocator()) syntax::StaticAssertDeclaration, S); return true; } bool WalkUpFromLinkageSpecDecl(LinkageSpecDecl *S) { Builder.foldNode(Builder.getDeclarationRange(S), new (allocator()) syntax::LinkageSpecificationDeclaration, S); return true; } bool WalkUpFromNamespaceAliasDecl(NamespaceAliasDecl *S) { Builder.foldNode(Builder.getDeclarationRange(S), new (allocator()) syntax::NamespaceAliasDefinition, S); return true; } bool WalkUpFromUsingDirectiveDecl(UsingDirectiveDecl *S) { Builder.foldNode(Builder.getDeclarationRange(S), new (allocator()) syntax::UsingNamespaceDirective, S); return true; } bool WalkUpFromUsingDecl(UsingDecl *S) { Builder.foldNode(Builder.getDeclarationRange(S), new (allocator()) syntax::UsingDeclaration, S); return true; } bool WalkUpFromUnresolvedUsingValueDecl(UnresolvedUsingValueDecl *S) { Builder.foldNode(Builder.getDeclarationRange(S), new (allocator()) syntax::UsingDeclaration, S); return true; } bool WalkUpFromUnresolvedUsingTypenameDecl(UnresolvedUsingTypenameDecl *S) { Builder.foldNode(Builder.getDeclarationRange(S), new (allocator()) syntax::UsingDeclaration, S); return true; } bool WalkUpFromTypeAliasDecl(TypeAliasDecl *S) { Builder.foldNode(Builder.getDeclarationRange(S), new (allocator()) syntax::TypeAliasDeclaration, S); return true; } private: /// Folds SimpleDeclarator node (if present) and in case this is the last /// declarator in the chain it also folds SimpleDeclaration node. template bool processDeclaratorAndDeclaration(T *D) { auto Range = getDeclaratorRange( Builder.sourceManager(), D->getTypeSourceInfo()->getTypeLoc(), getQualifiedNameStart(D), getInitializerRange(D)); // There doesn't have to be a declarator (e.g. `void foo(int)` only has // declaration, but no declarator). if (!Range.getBegin().isValid()) { Builder.markChild(new (allocator()) syntax::DeclaratorList, syntax::NodeRole::Declarators); Builder.foldNode(Builder.getDeclarationRange(D), new (allocator()) syntax::SimpleDeclaration, D); return true; } auto *N = new (allocator()) syntax::SimpleDeclarator; Builder.foldNode(Builder.getRange(Range), N, nullptr); Builder.markChild(N, syntax::NodeRole::ListElement); if (!Builder.isResponsibleForCreatingDeclaration(D)) { // If this is not the last declarator in the declaration we expect a // delimiter after it. const auto *DelimiterToken = std::next(Builder.findToken(Range.getEnd())); if (DelimiterToken->kind() == clang::tok::TokenKind::comma) Builder.markChildToken(DelimiterToken, syntax::NodeRole::ListDelimiter); } else { auto *DL = new (allocator()) syntax::DeclaratorList; auto DeclarationRange = Builder.getDeclarationRange(D); Builder.foldList(DeclarationRange, DL, nullptr); Builder.markChild(DL, syntax::NodeRole::Declarators); Builder.foldNode(DeclarationRange, new (allocator()) syntax::SimpleDeclaration, D); } return true; } /// Returns the range of the built node. syntax::TrailingReturnType *buildTrailingReturn(FunctionProtoTypeLoc L) { assert(L.getTypePtr()->hasTrailingReturn()); auto ReturnedType = L.getReturnLoc(); // Build node for the declarator, if any. auto ReturnDeclaratorRange = SourceRange(GetStartLoc().Visit(ReturnedType), ReturnedType.getEndLoc()); syntax::SimpleDeclarator *ReturnDeclarator = nullptr; if (ReturnDeclaratorRange.isValid()) { ReturnDeclarator = new (allocator()) syntax::SimpleDeclarator; Builder.foldNode(Builder.getRange(ReturnDeclaratorRange), ReturnDeclarator, nullptr); } // Build node for trailing return type. auto Return = Builder.getRange(ReturnedType.getSourceRange()); const auto *Arrow = Return.begin() - 1; assert(Arrow->kind() == tok::arrow); auto Tokens = llvm::makeArrayRef(Arrow, Return.end()); Builder.markChildToken(Arrow, syntax::NodeRole::ArrowToken); if (ReturnDeclarator) Builder.markChild(ReturnDeclarator, syntax::NodeRole::Declarator); auto *R = new (allocator()) syntax::TrailingReturnType; Builder.foldNode(Tokens, R, L); return R; } void foldExplicitTemplateInstantiation( ArrayRef Range, const syntax::Token *ExternKW, const syntax::Token *TemplateKW, syntax::SimpleDeclaration *InnerDeclaration, Decl *From) { assert(!ExternKW || ExternKW->kind() == tok::kw_extern); assert(TemplateKW && TemplateKW->kind() == tok::kw_template); Builder.markChildToken(ExternKW, syntax::NodeRole::ExternKeyword); Builder.markChildToken(TemplateKW, syntax::NodeRole::IntroducerKeyword); Builder.markChild(InnerDeclaration, syntax::NodeRole::Declaration); Builder.foldNode( Range, new (allocator()) syntax::ExplicitTemplateInstantiation, From); } syntax::TemplateDeclaration *foldTemplateDeclaration( ArrayRef Range, const syntax::Token *TemplateKW, ArrayRef TemplatedDeclaration, Decl *From) { assert(TemplateKW && TemplateKW->kind() == tok::kw_template); Builder.markChildToken(TemplateKW, syntax::NodeRole::IntroducerKeyword); auto *N = new (allocator()) syntax::TemplateDeclaration; Builder.foldNode(Range, N, From); Builder.markChild(N, syntax::NodeRole::Declaration); return N; } /// A small helper to save some typing. llvm::BumpPtrAllocator &allocator() { return Builder.allocator(); } syntax::TreeBuilder &Builder; const ASTContext &Context; }; } // namespace void syntax::TreeBuilder::noticeDeclWithoutSemicolon(Decl *D) { DeclsWithoutSemicolons.insert(D); } void syntax::TreeBuilder::markChildToken(SourceLocation Loc, NodeRole Role) { if (Loc.isInvalid()) return; Pending.assignRole(*findToken(Loc), Role); } void syntax::TreeBuilder::markChildToken(const syntax::Token *T, NodeRole R) { if (!T) return; Pending.assignRole(*T, R); } void syntax::TreeBuilder::markChild(syntax::Node *N, NodeRole R) { assert(N); setRole(N, R); } void syntax::TreeBuilder::markChild(ASTPtr N, NodeRole R) { auto *SN = Mapping.find(N); assert(SN != nullptr); setRole(SN, R); } void syntax::TreeBuilder::markChild(NestedNameSpecifierLoc NNSLoc, NodeRole R) { auto *SN = Mapping.find(NNSLoc); assert(SN != nullptr); setRole(SN, R); } void syntax::TreeBuilder::markStmtChild(Stmt *Child, NodeRole Role) { if (!Child) return; syntax::Tree *ChildNode; if (Expr *ChildExpr = dyn_cast(Child)) { // This is an expression in a statement position, consume the trailing // semicolon and form an 'ExpressionStatement' node. markExprChild(ChildExpr, NodeRole::Expression); ChildNode = new (allocator()) syntax::ExpressionStatement; // (!) 'getStmtRange()' ensures this covers a trailing semicolon. Pending.foldChildren(Arena, getStmtRange(Child), ChildNode); } else { ChildNode = Mapping.find(Child); } assert(ChildNode != nullptr); setRole(ChildNode, Role); } void syntax::TreeBuilder::markExprChild(Expr *Child, NodeRole Role) { if (!Child) return; Child = IgnoreImplicit(Child); syntax::Tree *ChildNode = Mapping.find(Child); assert(ChildNode != nullptr); setRole(ChildNode, Role); } const syntax::Token *syntax::TreeBuilder::findToken(SourceLocation L) const { if (L.isInvalid()) return nullptr; auto It = LocationToToken.find(L); assert(It != LocationToToken.end()); return It->second; } syntax::TranslationUnit *syntax::buildSyntaxTree(Arena &A, ASTContext &Context) { TreeBuilder Builder(A); BuildTreeVisitor(Context, Builder).TraverseAST(Context); return std::move(Builder).finalize(); }