//===--- UnnecessaryValueParamCheck.cpp - clang-tidy-----------------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #include "UnnecessaryValueParamCheck.h" #include "../utils/DeclRefExprUtils.h" #include "../utils/FixItHintUtils.h" #include "../utils/Matchers.h" #include "../utils/OptionsUtils.h" #include "../utils/TypeTraits.h" #include "clang/Frontend/CompilerInstance.h" #include "clang/Lex/Lexer.h" #include "clang/Lex/Preprocessor.h" using namespace clang::ast_matchers; namespace clang { namespace tidy { namespace performance { namespace { std::string paramNameOrIndex(StringRef Name, size_t Index) { return (Name.empty() ? llvm::Twine('#') + llvm::Twine(Index + 1) : llvm::Twine('\'') + Name + llvm::Twine('\'')) .str(); } bool isReferencedOutsideOfCallExpr(const FunctionDecl &Function, ASTContext &Context) { auto Matches = match(declRefExpr(to(functionDecl(equalsNode(&Function))), unless(hasAncestor(callExpr()))), Context); return !Matches.empty(); } bool hasLoopStmtAncestor(const DeclRefExpr &DeclRef, const Decl &Decl, ASTContext &Context) { auto Matches = match(decl(forEachDescendant(declRefExpr( equalsNode(&DeclRef), unless(hasAncestor(stmt(anyOf(forStmt(), cxxForRangeStmt(), whileStmt(), doStmt()))))))), Decl, Context); return Matches.empty(); } bool isExplicitTemplateSpecialization(const FunctionDecl &Function) { if (const auto *SpecializationInfo = Function.getTemplateSpecializationInfo()) if (SpecializationInfo->getTemplateSpecializationKind() == TSK_ExplicitSpecialization) return true; if (const auto *Method = llvm::dyn_cast(&Function)) if (Method->getTemplatedKind() == FunctionDecl::TK_MemberSpecialization && Method->getMemberSpecializationInfo()->isExplicitSpecialization()) return true; return false; } } // namespace UnnecessaryValueParamCheck::UnnecessaryValueParamCheck( StringRef Name, ClangTidyContext *Context) : ClangTidyCheck(Name, Context), IncludeStyle(utils::IncludeSorter::parseIncludeStyle( Options.getLocalOrGlobal("IncludeStyle", "llvm"))), AllowedTypes( utils::options::parseStringList(Options.get("AllowedTypes", ""))) {} void UnnecessaryValueParamCheck::registerMatchers(MatchFinder *Finder) { // This check is specific to C++ and doesn't apply to languages like // Objective-C. if (!getLangOpts().CPlusPlus) return; const auto ExpensiveValueParamDecl = parmVarDecl( hasType(qualType(allOf( hasCanonicalType(matchers::isExpensiveToCopy()), unless(anyOf(hasCanonicalType(referenceType()), hasDeclaration(namedDecl( matchers::matchesAnyListedName(AllowedTypes)))))))), decl().bind("param")); Finder->addMatcher( functionDecl(hasBody(stmt()), isDefinition(), unless(isImplicit()), unless(cxxMethodDecl(anyOf(isOverride(), isFinal()))), has(typeLoc(forEach(ExpensiveValueParamDecl))), unless(isInstantiated()), decl().bind("functionDecl")), this); } void UnnecessaryValueParamCheck::check(const MatchFinder::MatchResult &Result) { const auto *Param = Result.Nodes.getNodeAs("param"); const auto *Function = Result.Nodes.getNodeAs("functionDecl"); FunctionParmMutationAnalyzer &Analyzer = MutationAnalyzers.try_emplace(Function, *Function, *Result.Context) .first->second; if (Analyzer.isMutated(Param)) return; const bool IsConstQualified = Param->getType().getCanonicalType().isConstQualified(); // If the parameter is non-const, check if it has a move constructor and is // only referenced once to copy-construct another object or whether it has a // move assignment operator and is only referenced once when copy-assigned. // In this case wrap DeclRefExpr with std::move() to avoid the unnecessary // copy. if (!IsConstQualified) { auto AllDeclRefExprs = utils::decl_ref_expr::allDeclRefExprs( *Param, *Function, *Result.Context); if (AllDeclRefExprs.size() == 1) { auto CanonicalType = Param->getType().getCanonicalType(); const auto &DeclRefExpr = **AllDeclRefExprs.begin(); if (!hasLoopStmtAncestor(DeclRefExpr, *Function, *Result.Context) && ((utils::type_traits::hasNonTrivialMoveConstructor(CanonicalType) && utils::decl_ref_expr::isCopyConstructorArgument( DeclRefExpr, *Function, *Result.Context)) || (utils::type_traits::hasNonTrivialMoveAssignment(CanonicalType) && utils::decl_ref_expr::isCopyAssignmentArgument( DeclRefExpr, *Function, *Result.Context)))) { handleMoveFix(*Param, DeclRefExpr, *Result.Context); return; } } } const size_t Index = std::find(Function->parameters().begin(), Function->parameters().end(), Param) - Function->parameters().begin(); auto Diag = diag(Param->getLocation(), IsConstQualified ? "the const qualified parameter %0 is " "copied for each invocation; consider " "making it a reference" : "the parameter %0 is copied for each " "invocation but only used as a const reference; " "consider making it a const reference") << paramNameOrIndex(Param->getName(), Index); // Do not propose fixes when: // 1. the ParmVarDecl is in a macro, since we cannot place them correctly // 2. the function is virtual as it might break overrides // 3. the function is referenced outside of a call expression within the // compilation unit as the signature change could introduce build errors. // 4. the function is an explicit template specialization. const auto *Method = llvm::dyn_cast(Function); if (Param->getBeginLoc().isMacroID() || (Method && Method->isVirtual()) || isReferencedOutsideOfCallExpr(*Function, *Result.Context) || isExplicitTemplateSpecialization(*Function)) return; for (const auto *FunctionDecl = Function; FunctionDecl != nullptr; FunctionDecl = FunctionDecl->getPreviousDecl()) { const auto &CurrentParam = *FunctionDecl->getParamDecl(Index); Diag << utils::fixit::changeVarDeclToReference(CurrentParam, *Result.Context); // The parameter of each declaration needs to be checked individually as to // whether it is const or not as constness can differ between definition and // declaration. if (!CurrentParam.getType().getCanonicalType().isConstQualified()) Diag << utils::fixit::changeVarDeclToConst(CurrentParam); } } void UnnecessaryValueParamCheck::registerPPCallbacks( CompilerInstance &Compiler) { Inserter.reset(new utils::IncludeInserter( Compiler.getSourceManager(), Compiler.getLangOpts(), IncludeStyle)); Compiler.getPreprocessor().addPPCallbacks(Inserter->CreatePPCallbacks()); } void UnnecessaryValueParamCheck::storeOptions( ClangTidyOptions::OptionMap &Opts) { Options.store(Opts, "IncludeStyle", utils::IncludeSorter::toString(IncludeStyle)); Options.store(Opts, "AllowedTypes", utils::options::serializeStringList(AllowedTypes)); } void UnnecessaryValueParamCheck::onEndOfTranslationUnit() { MutationAnalyzers.clear(); } void UnnecessaryValueParamCheck::handleMoveFix(const ParmVarDecl &Var, const DeclRefExpr &CopyArgument, const ASTContext &Context) { auto Diag = diag(CopyArgument.getBeginLoc(), "parameter %0 is passed by value and only copied once; " "consider moving it to avoid unnecessary copies") << &Var; // Do not propose fixes in macros since we cannot place them correctly. if (CopyArgument.getBeginLoc().isMacroID()) return; const auto &SM = Context.getSourceManager(); auto EndLoc = Lexer::getLocForEndOfToken(CopyArgument.getLocation(), 0, SM, Context.getLangOpts()); Diag << FixItHint::CreateInsertion(CopyArgument.getBeginLoc(), "std::move(") << FixItHint::CreateInsertion(EndLoc, ")"); if (auto IncludeFixit = Inserter->CreateIncludeInsertion( SM.getFileID(CopyArgument.getBeginLoc()), "utility", /*IsAngled=*/true)) Diag << *IncludeFixit; } } // namespace performance } // namespace tidy } // namespace clang