//===--- UseUsingCheck.cpp - clang-tidy------------------------------------===// // // 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 "UseUsingCheck.h" #include "clang/AST/ASTContext.h" #include "clang/Lex/Lexer.h" using namespace clang::ast_matchers; namespace clang { namespace tidy { namespace modernize { static constexpr llvm::StringLiteral ParentDeclName = "parent-decl"; static constexpr llvm::StringLiteral TagDeclName = "tag-decl"; static constexpr llvm::StringLiteral TypedefName = "typedef"; UseUsingCheck::UseUsingCheck(StringRef Name, ClangTidyContext *Context) : ClangTidyCheck(Name, Context), IgnoreMacros(Options.getLocalOrGlobal("IgnoreMacros", true)) {} void UseUsingCheck::storeOptions(ClangTidyOptions::OptionMap &Opts) { Options.store(Opts, "IgnoreMacros", IgnoreMacros); } void UseUsingCheck::registerMatchers(MatchFinder *Finder) { Finder->addMatcher(typedefDecl(unless(isInstantiated()), hasParent(decl().bind(ParentDeclName))) .bind(TypedefName), this); // This matcher is used to find tag declarations in source code within // typedefs. They appear in the AST just *prior* to the typedefs. Finder->addMatcher( tagDecl( anyOf(allOf(unless(anyOf(isImplicit(), classTemplateSpecializationDecl())), hasParent(decl().bind(ParentDeclName))), // We want the parent of the ClassTemplateDecl, not the parent // of the specialization. classTemplateSpecializationDecl(hasAncestor(classTemplateDecl( hasParent(decl().bind(ParentDeclName))))))) .bind(TagDeclName), this); } void UseUsingCheck::check(const MatchFinder::MatchResult &Result) { const auto *ParentDecl = Result.Nodes.getNodeAs(ParentDeclName); if (!ParentDecl) return; // Match CXXRecordDecl only to store the range of the last non-implicit full // declaration, to later check whether it's within the typdef itself. const auto *MatchedTagDecl = Result.Nodes.getNodeAs(TagDeclName); if (MatchedTagDecl) { // It is not sufficient to just track the last TagDecl that we've seen, // because if one struct or union is nested inside another, the last TagDecl // before the typedef will be the nested one (PR#50990). Therefore, we also // keep track of the parent declaration, so that we can look up the last // TagDecl that is a sibling of the typedef in the AST. LastTagDeclRanges[ParentDecl] = MatchedTagDecl->getSourceRange(); return; } const auto *MatchedDecl = Result.Nodes.getNodeAs(TypedefName); if (MatchedDecl->getLocation().isInvalid()) return; SourceLocation StartLoc = MatchedDecl->getBeginLoc(); if (StartLoc.isMacroID() && IgnoreMacros) return; static const char *UseUsingWarning = "use 'using' instead of 'typedef'"; // Warn at StartLoc but do not fix if there is macro or array. if (MatchedDecl->getUnderlyingType()->isArrayType() || StartLoc.isMacroID()) { diag(StartLoc, UseUsingWarning); return; } PrintingPolicy PrintPolicy(getLangOpts()); PrintPolicy.SuppressScope = true; PrintPolicy.ConstantArraySizeAsWritten = true; PrintPolicy.UseVoidForZeroParams = false; PrintPolicy.PrintInjectedClassNameWithArguments = false; std::string Type = MatchedDecl->getUnderlyingType().getAsString(PrintPolicy); std::string Name = MatchedDecl->getNameAsString(); SourceRange ReplaceRange = MatchedDecl->getSourceRange(); // typedefs with multiple comma-separated definitions produce multiple // consecutive TypedefDecl nodes whose SourceRanges overlap. Each range starts // at the "typedef" and then continues *across* previous definitions through // the end of the current TypedefDecl definition. // But also we need to check that the ranges belong to the same file because // different files may contain overlapping ranges. std::string Using = "using "; if (ReplaceRange.getBegin().isMacroID() || (Result.SourceManager->getFileID(ReplaceRange.getBegin()) != Result.SourceManager->getFileID(LastReplacementEnd)) || (ReplaceRange.getBegin() >= LastReplacementEnd)) { // This is the first (and possibly the only) TypedefDecl in a typedef. Save // Type and Name in case we find subsequent TypedefDecl's in this typedef. FirstTypedefType = Type; FirstTypedefName = Name; } else { // This is additional TypedefDecl in a comma-separated typedef declaration. // Start replacement *after* prior replacement and separate with semicolon. ReplaceRange.setBegin(LastReplacementEnd); Using = ";\nusing "; // If this additional TypedefDecl's Type starts with the first TypedefDecl's // type, make this using statement refer back to the first type, e.g. make // "typedef int Foo, *Foo_p;" -> "using Foo = int;\nusing Foo_p = Foo*;" if (Type.size() > FirstTypedefType.size() && Type.substr(0, FirstTypedefType.size()) == FirstTypedefType) Type = FirstTypedefName + Type.substr(FirstTypedefType.size() + 1); } if (!ReplaceRange.getEnd().isMacroID()) LastReplacementEnd = ReplaceRange.getEnd().getLocWithOffset(Name.size()); auto Diag = diag(ReplaceRange.getBegin(), UseUsingWarning); // If typedef contains a full tag declaration, extract its full text. auto LastTagDeclRange = LastTagDeclRanges.find(ParentDecl); if (LastTagDeclRange != LastTagDeclRanges.end() && LastTagDeclRange->second.isValid() && ReplaceRange.fullyContains(LastTagDeclRange->second)) { Type = std::string(Lexer::getSourceText( CharSourceRange::getTokenRange(LastTagDeclRange->second), *Result.SourceManager, getLangOpts())); if (Type.empty()) return; } std::string Replacement = Using + Name + " = " + Type; Diag << FixItHint::CreateReplacement(ReplaceRange, Replacement); } } // namespace modernize } // namespace tidy } // namespace clang