//===--- Registry.cpp - Matcher registry -------------------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===------------------------------------------------------------===// /// /// \file /// \brief Registry map populated at static initialization time. /// //===------------------------------------------------------------===// #include "clang/ASTMatchers/Dynamic/Registry.h" #include "Marshallers.h" #include "clang/ASTMatchers/ASTMatchers.h" #include "llvm/ADT/StringMap.h" #include "llvm/ADT/StringRef.h" #include "llvm/Support/ManagedStatic.h" #include #include using namespace clang::ast_type_traits; namespace clang { namespace ast_matchers { namespace dynamic { namespace { using internal::MatcherDescriptor; typedef llvm::StringMap ConstructorMap; class RegistryMaps { public: RegistryMaps(); ~RegistryMaps(); const ConstructorMap &constructors() const { return Constructors; } private: void registerMatcher(StringRef MatcherName, MatcherDescriptor *Callback); ConstructorMap Constructors; }; void RegistryMaps::registerMatcher(StringRef MatcherName, MatcherDescriptor *Callback) { assert(Constructors.find(MatcherName) == Constructors.end()); Constructors[MatcherName] = Callback; } #define REGISTER_MATCHER(name) \ registerMatcher(#name, internal::makeMatcherAutoMarshall( \ ::clang::ast_matchers::name, #name)); #define SPECIFIC_MATCHER_OVERLOAD(name, Id) \ static_cast< ::clang::ast_matchers::name##_Type##Id>( \ ::clang::ast_matchers::name) #define REGISTER_OVERLOADED_2(name) \ do { \ MatcherDescriptor *Callbacks[] = { \ internal::makeMatcherAutoMarshall(SPECIFIC_MATCHER_OVERLOAD(name, 0), \ #name), \ internal::makeMatcherAutoMarshall(SPECIFIC_MATCHER_OVERLOAD(name, 1), \ #name) \ }; \ registerMatcher(#name, \ new internal::OverloadedMatcherDescriptor(Callbacks)); \ } while (0) /// \brief Generate a registry map with all the known matchers. RegistryMaps::RegistryMaps() { // TODO: Here is the list of the missing matchers, grouped by reason. // // Need Variant/Parser fixes: // ofKind // // Polymorphic + argument overload: // findAll // // Other: // equals // equalsNode REGISTER_OVERLOADED_2(callee); REGISTER_OVERLOADED_2(hasPrefix); REGISTER_OVERLOADED_2(hasType); REGISTER_OVERLOADED_2(isDerivedFrom); REGISTER_OVERLOADED_2(isSameOrDerivedFrom); REGISTER_OVERLOADED_2(loc); REGISTER_OVERLOADED_2(pointsTo); REGISTER_OVERLOADED_2(references); REGISTER_OVERLOADED_2(thisPointerType); REGISTER_MATCHER(accessSpecDecl); REGISTER_MATCHER(alignOfExpr); REGISTER_MATCHER(allOf); REGISTER_MATCHER(anyOf); REGISTER_MATCHER(anything); REGISTER_MATCHER(argumentCountIs); REGISTER_MATCHER(arraySubscriptExpr); REGISTER_MATCHER(arrayType); REGISTER_MATCHER(asString); REGISTER_MATCHER(asmStmt); REGISTER_MATCHER(atomicType); REGISTER_MATCHER(autoType); REGISTER_MATCHER(binaryOperator); REGISTER_MATCHER(bindTemporaryExpr); REGISTER_MATCHER(blockPointerType); REGISTER_MATCHER(boolLiteral); REGISTER_MATCHER(breakStmt); REGISTER_MATCHER(builtinType); REGISTER_MATCHER(cStyleCastExpr); REGISTER_MATCHER(callExpr); REGISTER_MATCHER(caseStmt); REGISTER_MATCHER(castExpr); REGISTER_MATCHER(catchStmt); REGISTER_MATCHER(characterLiteral); REGISTER_MATCHER(classTemplateDecl); REGISTER_MATCHER(classTemplateSpecializationDecl); REGISTER_MATCHER(complexType); REGISTER_MATCHER(compoundLiteralExpr); REGISTER_MATCHER(compoundStmt); REGISTER_MATCHER(conditionalOperator); REGISTER_MATCHER(constCastExpr); REGISTER_MATCHER(constantArrayType); REGISTER_MATCHER(constructExpr); REGISTER_MATCHER(constructorDecl); REGISTER_MATCHER(containsDeclaration); REGISTER_MATCHER(continueStmt); REGISTER_MATCHER(ctorInitializer); REGISTER_MATCHER(decl); REGISTER_MATCHER(declCountIs); REGISTER_MATCHER(declRefExpr); REGISTER_MATCHER(declStmt); REGISTER_MATCHER(declaratorDecl); REGISTER_MATCHER(defaultArgExpr); REGISTER_MATCHER(defaultStmt); REGISTER_MATCHER(deleteExpr); REGISTER_MATCHER(dependentSizedArrayType); REGISTER_MATCHER(destructorDecl); REGISTER_MATCHER(doStmt); REGISTER_MATCHER(dynamicCastExpr); REGISTER_MATCHER(eachOf); REGISTER_MATCHER(elaboratedType); REGISTER_MATCHER(enumConstantDecl); REGISTER_MATCHER(enumDecl); REGISTER_MATCHER(equalsBoundNode); REGISTER_MATCHER(explicitCastExpr); REGISTER_MATCHER(expr); REGISTER_MATCHER(exprWithCleanups); REGISTER_MATCHER(fieldDecl); REGISTER_MATCHER(floatLiteral); REGISTER_MATCHER(forEach); REGISTER_MATCHER(forEachConstructorInitializer); REGISTER_MATCHER(forEachDescendant); REGISTER_MATCHER(forEachSwitchCase); REGISTER_MATCHER(forField); REGISTER_MATCHER(forRangeStmt); REGISTER_MATCHER(forStmt); REGISTER_MATCHER(friendDecl); REGISTER_MATCHER(functionDecl); REGISTER_MATCHER(functionTemplateDecl); REGISTER_MATCHER(functionType); REGISTER_MATCHER(functionalCastExpr); REGISTER_MATCHER(gotoStmt); REGISTER_MATCHER(has); REGISTER_MATCHER(hasAncestor); REGISTER_MATCHER(hasAnyArgument); REGISTER_MATCHER(hasAnyConstructorInitializer); REGISTER_MATCHER(hasAnyParameter); REGISTER_MATCHER(hasAnySubstatement); REGISTER_MATCHER(hasAnyTemplateArgument); REGISTER_MATCHER(hasAnyUsingShadowDecl); REGISTER_MATCHER(hasArgument); REGISTER_MATCHER(hasArgumentOfType); REGISTER_MATCHER(hasBase); REGISTER_MATCHER(hasBody); REGISTER_MATCHER(hasCanonicalType); REGISTER_MATCHER(hasCaseConstant); REGISTER_MATCHER(hasCondition); REGISTER_MATCHER(hasConditionVariableStatement); REGISTER_MATCHER(hasDeclContext); REGISTER_MATCHER(hasDeclaration); REGISTER_MATCHER(hasDeducedType); REGISTER_MATCHER(hasDescendant); REGISTER_MATCHER(hasDestinationType); REGISTER_MATCHER(hasEitherOperand); REGISTER_MATCHER(hasElementType); REGISTER_MATCHER(hasFalseExpression); REGISTER_MATCHER(hasGlobalStorage); REGISTER_MATCHER(hasImplicitDestinationType); REGISTER_MATCHER(hasIncrement); REGISTER_MATCHER(hasIndex); REGISTER_MATCHER(hasInitializer); REGISTER_MATCHER(hasLHS); REGISTER_MATCHER(hasLocalQualifiers); REGISTER_MATCHER(hasLocalStorage); REGISTER_MATCHER(hasLoopInit); REGISTER_MATCHER(hasMethod); REGISTER_MATCHER(hasName); REGISTER_MATCHER(hasObjectExpression); REGISTER_MATCHER(hasOperatorName); REGISTER_MATCHER(hasOverloadedOperatorName); REGISTER_MATCHER(hasParameter); REGISTER_MATCHER(hasParent); REGISTER_MATCHER(hasQualifier); REGISTER_MATCHER(hasRHS); REGISTER_MATCHER(hasSingleDecl); REGISTER_MATCHER(hasSize); REGISTER_MATCHER(hasSizeExpr); REGISTER_MATCHER(hasSourceExpression); REGISTER_MATCHER(hasTargetDecl); REGISTER_MATCHER(hasTemplateArgument); REGISTER_MATCHER(hasTrueExpression); REGISTER_MATCHER(hasTypeLoc); REGISTER_MATCHER(hasUnaryOperand); REGISTER_MATCHER(hasValueType); REGISTER_MATCHER(ifStmt); REGISTER_MATCHER(ignoringImpCasts); REGISTER_MATCHER(ignoringParenCasts); REGISTER_MATCHER(ignoringParenImpCasts); REGISTER_MATCHER(implicitCastExpr); REGISTER_MATCHER(incompleteArrayType); REGISTER_MATCHER(initListExpr); REGISTER_MATCHER(innerType); REGISTER_MATCHER(integerLiteral); REGISTER_MATCHER(isArrow); REGISTER_MATCHER(isConst); REGISTER_MATCHER(isConstQualified); REGISTER_MATCHER(isDefinition); REGISTER_MATCHER(isExplicitTemplateSpecialization); REGISTER_MATCHER(isExpr); REGISTER_MATCHER(isExternC); REGISTER_MATCHER(isImplicit); REGISTER_MATCHER(isInteger); REGISTER_MATCHER(isListInitialization); REGISTER_MATCHER(isOverride); REGISTER_MATCHER(isPrivate); REGISTER_MATCHER(isProtected); REGISTER_MATCHER(isPublic); REGISTER_MATCHER(isTemplateInstantiation); REGISTER_MATCHER(isVirtual); REGISTER_MATCHER(isWritten); REGISTER_MATCHER(lValueReferenceType); REGISTER_MATCHER(labelStmt); REGISTER_MATCHER(lambdaExpr); REGISTER_MATCHER(matchesName); REGISTER_MATCHER(materializeTemporaryExpr); REGISTER_MATCHER(member); REGISTER_MATCHER(memberCallExpr); REGISTER_MATCHER(memberExpr); REGISTER_MATCHER(memberPointerType); REGISTER_MATCHER(methodDecl); REGISTER_MATCHER(namedDecl); REGISTER_MATCHER(namesType); REGISTER_MATCHER(namespaceDecl); REGISTER_MATCHER(nestedNameSpecifier); REGISTER_MATCHER(nestedNameSpecifierLoc); REGISTER_MATCHER(newExpr); REGISTER_MATCHER(nullPtrLiteralExpr); REGISTER_MATCHER(nullStmt); REGISTER_MATCHER(ofClass); REGISTER_MATCHER(on); REGISTER_MATCHER(onImplicitObjectArgument); REGISTER_MATCHER(operatorCallExpr); REGISTER_MATCHER(parameterCountIs); REGISTER_MATCHER(parenType); REGISTER_MATCHER(parmVarDecl); REGISTER_MATCHER(pointee); REGISTER_MATCHER(pointerType); REGISTER_MATCHER(qualType); REGISTER_MATCHER(rValueReferenceType); REGISTER_MATCHER(recordDecl); REGISTER_MATCHER(recordType); REGISTER_MATCHER(referenceType); REGISTER_MATCHER(refersToDeclaration); REGISTER_MATCHER(refersToType); REGISTER_MATCHER(reinterpretCastExpr); REGISTER_MATCHER(returnStmt); REGISTER_MATCHER(returns); REGISTER_MATCHER(sizeOfExpr); REGISTER_MATCHER(specifiesNamespace); REGISTER_MATCHER(specifiesType); REGISTER_MATCHER(specifiesTypeLoc); REGISTER_MATCHER(statementCountIs); REGISTER_MATCHER(staticCastExpr); REGISTER_MATCHER(stmt); REGISTER_MATCHER(stringLiteral); REGISTER_MATCHER(switchCase); REGISTER_MATCHER(switchStmt); REGISTER_MATCHER(templateSpecializationType); REGISTER_MATCHER(temporaryObjectExpr); REGISTER_MATCHER(thisExpr); REGISTER_MATCHER(throughUsingDecl); REGISTER_MATCHER(throwExpr); REGISTER_MATCHER(to); REGISTER_MATCHER(tryStmt); REGISTER_MATCHER(type); REGISTER_MATCHER(typeLoc); REGISTER_MATCHER(typedefType); REGISTER_MATCHER(unaryExprOrTypeTraitExpr); REGISTER_MATCHER(unaryOperator); REGISTER_MATCHER(unaryTransformType); REGISTER_MATCHER(unless); REGISTER_MATCHER(unresolvedConstructExpr); REGISTER_MATCHER(unresolvedUsingValueDecl); REGISTER_MATCHER(userDefinedLiteral); REGISTER_MATCHER(usingDecl); REGISTER_MATCHER(varDecl); REGISTER_MATCHER(variableArrayType); REGISTER_MATCHER(whileStmt); REGISTER_MATCHER(withInitializer); } RegistryMaps::~RegistryMaps() { for (ConstructorMap::iterator it = Constructors.begin(), end = Constructors.end(); it != end; ++it) { delete it->second; } } static llvm::ManagedStatic RegistryData; } // anonymous namespace // static llvm::Optional Registry::lookupMatcherCtor(StringRef MatcherName) { ConstructorMap::const_iterator it = RegistryData->constructors().find(MatcherName); return it == RegistryData->constructors().end() ? llvm::Optional() : it->second; } namespace { llvm::raw_ostream &operator<<(llvm::raw_ostream &OS, const std::set &KS) { unsigned Count = 0; for (std::set::const_iterator I = KS.begin(), E = KS.end(); I != E; ++I) { if (I != KS.begin()) OS << "|"; if (Count++ == 3) { OS << "..."; break; } OS << *I; } return OS; } struct ReverseSpecificityThenName { bool operator()(const std::pair &A, const std::pair &B) const { return A.first > B.first || (A.first == B.first && A.second < B.second); } }; } std::vector Registry::getCompletions( ArrayRef > Context) { ASTNodeKind InitialTypes[] = { ASTNodeKind::getFromNodeKind(), ASTNodeKind::getFromNodeKind(), ASTNodeKind::getFromNodeKind(), ASTNodeKind::getFromNodeKind(), ASTNodeKind::getFromNodeKind(), ASTNodeKind::getFromNodeKind(), ASTNodeKind::getFromNodeKind() }; ArrayRef InitialTypesRef(InitialTypes); // Starting with the above seed of acceptable top-level matcher types, compute // the acceptable type set for the argument indicated by each context element. std::set TypeSet(InitialTypesRef.begin(), InitialTypesRef.end()); for (ArrayRef >::iterator CtxI = Context.begin(), CtxE = Context.end(); CtxI != CtxE; ++CtxI) { std::vector NextTypeSet; for (std::set::iterator I = TypeSet.begin(), E = TypeSet.end(); I != E; ++I) { if (CtxI->first->isConvertibleTo(*I) && (CtxI->first->isVariadic() || CtxI->second < CtxI->first->getNumArgs())) CtxI->first->getArgKinds(*I, CtxI->second, NextTypeSet); } TypeSet.clear(); for (std::vector::iterator I = NextTypeSet.begin(), E = NextTypeSet.end(); I != E; ++I) { if (I->getArgKind() == internal::ArgKind::AK_Matcher) TypeSet.insert(I->getMatcherKind()); } } typedef std::map, MatcherCompletion, ReverseSpecificityThenName> CompletionsTy; CompletionsTy Completions; // TypeSet now contains the list of acceptable types for the argument we are // completing. Search the registry for acceptable matchers. for (ConstructorMap::const_iterator I = RegistryData->constructors().begin(), E = RegistryData->constructors().end(); I != E; ++I) { std::set RetKinds; unsigned NumArgs = I->second->isVariadic() ? 1 : I->second->getNumArgs(); bool IsPolymorphic = I->second->isPolymorphic(); std::vector > ArgsKinds(NumArgs); unsigned MaxSpecificity = 0; for (std::set::iterator TI = TypeSet.begin(), TE = TypeSet.end(); TI != TE; ++TI) { unsigned Specificity; ASTNodeKind LeastDerivedKind; if (I->second->isConvertibleTo(*TI, &Specificity, &LeastDerivedKind)) { if (MaxSpecificity < Specificity) MaxSpecificity = Specificity; RetKinds.insert(LeastDerivedKind); for (unsigned Arg = 0; Arg != NumArgs; ++Arg) I->second->getArgKinds(*TI, Arg, ArgsKinds[Arg]); if (IsPolymorphic) break; } } if (!RetKinds.empty() && MaxSpecificity > 0) { std::string Decl; llvm::raw_string_ostream OS(Decl); if (IsPolymorphic) { OS << "Matcher " << I->first() << "(Matcher"; } else { OS << "Matcher<" << RetKinds << "> " << I->first() << "("; for (std::vector >::iterator KI = ArgsKinds.begin(), KE = ArgsKinds.end(); KI != KE; ++KI) { if (KI != ArgsKinds.begin()) OS << ", "; // This currently assumes that a matcher may not overload a // non-matcher, and all non-matcher overloads have identical // arguments. if ((*KI)[0].getArgKind() == internal::ArgKind::AK_Matcher) { std::set MatcherKinds; std::transform( KI->begin(), KI->end(), std::inserter(MatcherKinds, MatcherKinds.end()), std::mem_fun_ref(&internal::ArgKind::getMatcherKind)); OS << "Matcher<" << MatcherKinds << ">"; } else { OS << (*KI)[0].asString(); } } } if (I->second->isVariadic()) OS << "..."; OS << ")"; std::string TypedText = I->first(); TypedText += "("; if (ArgsKinds.empty()) TypedText += ")"; else if (ArgsKinds[0][0].getArgKind() == internal::ArgKind::AK_String) TypedText += "\""; Completions[std::make_pair(MaxSpecificity, I->first())] = MatcherCompletion(TypedText, OS.str()); } } std::vector RetVal; for (CompletionsTy::iterator I = Completions.begin(), E = Completions.end(); I != E; ++I) RetVal.push_back(I->second); return RetVal; } // static VariantMatcher Registry::constructMatcher(MatcherCtor Ctor, const SourceRange &NameRange, ArrayRef Args, Diagnostics *Error) { return Ctor->create(NameRange, Args, Error); } // static VariantMatcher Registry::constructBoundMatcher(MatcherCtor Ctor, const SourceRange &NameRange, StringRef BindID, ArrayRef Args, Diagnostics *Error) { VariantMatcher Out = constructMatcher(Ctor, NameRange, Args, Error); if (Out.isNull()) return Out; llvm::Optional Result = Out.getSingleMatcher(); if (Result.hasValue()) { llvm::Optional Bound = Result->tryBind(BindID); if (Bound.hasValue()) { return VariantMatcher::SingleMatcher(*Bound); } } Error->addError(NameRange, Error->ET_RegistryNotBindable); return VariantMatcher(); } } // namespace dynamic } // namespace ast_matchers } // namespace clang