| //===-- ChangeNamespace.cpp - Change namespace implementation -------------===// |
| // |
| // 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 "ChangeNamespace.h" |
| #include "clang/AST/ASTContext.h" |
| #include "clang/Format/Format.h" |
| #include "clang/Lex/Lexer.h" |
| #include "llvm/Support/Casting.h" |
| #include "llvm/Support/ErrorHandling.h" |
| |
| using namespace clang::ast_matchers; |
| |
| namespace clang { |
| namespace change_namespace { |
| |
| namespace { |
| |
| inline std::string joinNamespaces(ArrayRef<StringRef> Namespaces) { |
| return llvm::join(Namespaces, "::"); |
| } |
| |
| // Given "a::b::c", returns {"a", "b", "c"}. |
| llvm::SmallVector<llvm::StringRef, 4> splitSymbolName(llvm::StringRef Name) { |
| llvm::SmallVector<llvm::StringRef, 4> Splitted; |
| Name.split(Splitted, "::", /*MaxSplit=*/-1, |
| /*KeepEmpty=*/false); |
| return Splitted; |
| } |
| |
| SourceLocation startLocationForType(TypeLoc TLoc) { |
| // For elaborated types (e.g. `struct a::A`) we want the portion after the |
| // `struct` but including the namespace qualifier, `a::`. |
| if (TLoc.getTypeLocClass() == TypeLoc::Elaborated) { |
| NestedNameSpecifierLoc NestedNameSpecifier = |
| TLoc.castAs<ElaboratedTypeLoc>().getQualifierLoc(); |
| if (NestedNameSpecifier.getNestedNameSpecifier()) |
| return NestedNameSpecifier.getBeginLoc(); |
| TLoc = TLoc.getNextTypeLoc(); |
| } |
| return TLoc.getBeginLoc(); |
| } |
| |
| SourceLocation endLocationForType(TypeLoc TLoc) { |
| // Dig past any namespace or keyword qualifications. |
| while (TLoc.getTypeLocClass() == TypeLoc::Elaborated || |
| TLoc.getTypeLocClass() == TypeLoc::Qualified) |
| TLoc = TLoc.getNextTypeLoc(); |
| |
| // The location for template specializations (e.g. Foo<int>) includes the |
| // templated types in its location range. We want to restrict this to just |
| // before the `<` character. |
| if (TLoc.getTypeLocClass() == TypeLoc::TemplateSpecialization) |
| return TLoc.castAs<TemplateSpecializationTypeLoc>() |
| .getLAngleLoc() |
| .getLocWithOffset(-1); |
| return TLoc.getEndLoc(); |
| } |
| |
| // Returns the containing namespace of `InnerNs` by skipping `PartialNsName`. |
| // If the `InnerNs` does not have `PartialNsName` as suffix, or `PartialNsName` |
| // is empty, nullptr is returned. |
| // For example, if `InnerNs` is "a::b::c" and `PartialNsName` is "b::c", then |
| // the NamespaceDecl of namespace "a" will be returned. |
| const NamespaceDecl *getOuterNamespace(const NamespaceDecl *InnerNs, |
| llvm::StringRef PartialNsName) { |
| if (!InnerNs || PartialNsName.empty()) |
| return nullptr; |
| const auto *CurrentContext = llvm::cast<DeclContext>(InnerNs); |
| const auto *CurrentNs = InnerNs; |
| auto PartialNsNameSplitted = splitSymbolName(PartialNsName); |
| while (!PartialNsNameSplitted.empty()) { |
| // Get the inner-most namespace in CurrentContext. |
| while (CurrentContext && !llvm::isa<NamespaceDecl>(CurrentContext)) |
| CurrentContext = CurrentContext->getParent(); |
| if (!CurrentContext) |
| return nullptr; |
| CurrentNs = llvm::cast<NamespaceDecl>(CurrentContext); |
| if (PartialNsNameSplitted.back() != CurrentNs->getNameAsString()) |
| return nullptr; |
| PartialNsNameSplitted.pop_back(); |
| CurrentContext = CurrentContext->getParent(); |
| } |
| return CurrentNs; |
| } |
| |
| static std::unique_ptr<Lexer> |
| getLexerStartingFromLoc(SourceLocation Loc, const SourceManager &SM, |
| const LangOptions &LangOpts) { |
| if (Loc.isMacroID() && |
| !Lexer::isAtEndOfMacroExpansion(Loc, SM, LangOpts, &Loc)) |
| return nullptr; |
| // Break down the source location. |
| std::pair<FileID, unsigned> LocInfo = SM.getDecomposedLoc(Loc); |
| // Try to load the file buffer. |
| bool InvalidTemp = false; |
| llvm::StringRef File = SM.getBufferData(LocInfo.first, &InvalidTemp); |
| if (InvalidTemp) |
| return nullptr; |
| |
| const char *TokBegin = File.data() + LocInfo.second; |
| // Lex from the start of the given location. |
| return std::make_unique<Lexer>(SM.getLocForStartOfFile(LocInfo.first), |
| LangOpts, File.begin(), TokBegin, File.end()); |
| } |
| |
| // FIXME: get rid of this helper function if this is supported in clang-refactor |
| // library. |
| static SourceLocation getStartOfNextLine(SourceLocation Loc, |
| const SourceManager &SM, |
| const LangOptions &LangOpts) { |
| std::unique_ptr<Lexer> Lex = getLexerStartingFromLoc(Loc, SM, LangOpts); |
| if (!Lex.get()) |
| return SourceLocation(); |
| llvm::SmallVector<char, 16> Line; |
| // FIXME: this is a bit hacky to get ReadToEndOfLine work. |
| Lex->setParsingPreprocessorDirective(true); |
| Lex->ReadToEndOfLine(&Line); |
| auto End = Loc.getLocWithOffset(Line.size()); |
| return SM.getLocForEndOfFile(SM.getDecomposedLoc(Loc).first) == End |
| ? End |
| : End.getLocWithOffset(1); |
| } |
| |
| // Returns `R` with new range that refers to code after `Replaces` being |
| // applied. |
| tooling::Replacement |
| getReplacementInChangedCode(const tooling::Replacements &Replaces, |
| const tooling::Replacement &R) { |
| unsigned NewStart = Replaces.getShiftedCodePosition(R.getOffset()); |
| unsigned NewEnd = |
| Replaces.getShiftedCodePosition(R.getOffset() + R.getLength()); |
| return tooling::Replacement(R.getFilePath(), NewStart, NewEnd - NewStart, |
| R.getReplacementText()); |
| } |
| |
| // Adds a replacement `R` into `Replaces` or merges it into `Replaces` by |
| // applying all existing Replaces first if there is conflict. |
| void addOrMergeReplacement(const tooling::Replacement &R, |
| tooling::Replacements *Replaces) { |
| auto Err = Replaces->add(R); |
| if (Err) { |
| llvm::consumeError(std::move(Err)); |
| auto Replace = getReplacementInChangedCode(*Replaces, R); |
| *Replaces = Replaces->merge(tooling::Replacements(Replace)); |
| } |
| } |
| |
| tooling::Replacement createReplacement(SourceLocation Start, SourceLocation End, |
| llvm::StringRef ReplacementText, |
| const SourceManager &SM) { |
| if (!Start.isValid() || !End.isValid()) { |
| llvm::errs() << "start or end location were invalid\n"; |
| return tooling::Replacement(); |
| } |
| if (SM.getDecomposedLoc(Start).first != SM.getDecomposedLoc(End).first) { |
| llvm::errs() |
| << "start or end location were in different macro expansions\n"; |
| return tooling::Replacement(); |
| } |
| Start = SM.getSpellingLoc(Start); |
| End = SM.getSpellingLoc(End); |
| if (SM.getFileID(Start) != SM.getFileID(End)) { |
| llvm::errs() << "start or end location were in different files\n"; |
| return tooling::Replacement(); |
| } |
| return tooling::Replacement( |
| SM, CharSourceRange::getTokenRange(SM.getSpellingLoc(Start), |
| SM.getSpellingLoc(End)), |
| ReplacementText); |
| } |
| |
| void addReplacementOrDie( |
| SourceLocation Start, SourceLocation End, llvm::StringRef ReplacementText, |
| const SourceManager &SM, |
| std::map<std::string, tooling::Replacements> *FileToReplacements) { |
| const auto R = createReplacement(Start, End, ReplacementText, SM); |
| auto Err = (*FileToReplacements)[std::string(R.getFilePath())].add(R); |
| if (Err) |
| llvm_unreachable(llvm::toString(std::move(Err)).c_str()); |
| } |
| |
| tooling::Replacement createInsertion(SourceLocation Loc, |
| llvm::StringRef InsertText, |
| const SourceManager &SM) { |
| if (Loc.isInvalid()) { |
| llvm::errs() << "insert Location is invalid.\n"; |
| return tooling::Replacement(); |
| } |
| Loc = SM.getSpellingLoc(Loc); |
| return tooling::Replacement(SM, Loc, 0, InsertText); |
| } |
| |
| // Returns the shortest qualified name for declaration `DeclName` in the |
| // namespace `NsName`. For example, if `DeclName` is "a::b::X" and `NsName` |
| // is "a::c::d", then "b::X" will be returned. |
| // Note that if `DeclName` is `::b::X` and `NsName` is `::a::b`, this returns |
| // "::b::X" instead of "b::X" since there will be a name conflict otherwise. |
| // \param DeclName A fully qualified name, "::a::b::X" or "a::b::X". |
| // \param NsName A fully qualified name, "::a::b" or "a::b". Global namespace |
| // will have empty name. |
| std::string getShortestQualifiedNameInNamespace(llvm::StringRef DeclName, |
| llvm::StringRef NsName) { |
| DeclName = DeclName.ltrim(':'); |
| NsName = NsName.ltrim(':'); |
| if (DeclName.find(':') == llvm::StringRef::npos) |
| return std::string(DeclName); |
| |
| auto NsNameSplitted = splitSymbolName(NsName); |
| auto DeclNsSplitted = splitSymbolName(DeclName); |
| llvm::StringRef UnqualifiedDeclName = DeclNsSplitted.pop_back_val(); |
| // If the Decl is in global namespace, there is no need to shorten it. |
| if (DeclNsSplitted.empty()) |
| return std::string(UnqualifiedDeclName); |
| // If NsName is the global namespace, we can simply use the DeclName sans |
| // leading "::". |
| if (NsNameSplitted.empty()) |
| return std::string(DeclName); |
| |
| if (NsNameSplitted.front() != DeclNsSplitted.front()) { |
| // The DeclName must be fully-qualified, but we still need to decide if a |
| // leading "::" is necessary. For example, if `NsName` is "a::b::c" and the |
| // `DeclName` is "b::X", then the reference must be qualified as "::b::X" |
| // to avoid conflict. |
| if (llvm::is_contained(NsNameSplitted, DeclNsSplitted.front())) |
| return ("::" + DeclName).str(); |
| return std::string(DeclName); |
| } |
| // Since there is already an overlap namespace, we know that `DeclName` can be |
| // shortened, so we reduce the longest common prefix. |
| auto DeclI = DeclNsSplitted.begin(); |
| auto DeclE = DeclNsSplitted.end(); |
| auto NsI = NsNameSplitted.begin(); |
| auto NsE = NsNameSplitted.end(); |
| for (; DeclI != DeclE && NsI != NsE && *DeclI == *NsI; ++DeclI, ++NsI) { |
| } |
| return (DeclI == DeclE) |
| ? UnqualifiedDeclName.str() |
| : (llvm::join(DeclI, DeclE, "::") + "::" + UnqualifiedDeclName) |
| .str(); |
| } |
| |
| std::string wrapCodeInNamespace(StringRef NestedNs, std::string Code) { |
| if (Code.back() != '\n') |
| Code += "\n"; |
| auto NsSplitted = splitSymbolName(NestedNs); |
| while (!NsSplitted.empty()) { |
| // FIXME: consider code style for comments. |
| Code = ("namespace " + NsSplitted.back() + " {\n" + Code + |
| "} // namespace " + NsSplitted.back() + "\n") |
| .str(); |
| NsSplitted.pop_back(); |
| } |
| return Code; |
| } |
| |
| // Returns true if \p D is a nested DeclContext in \p Context |
| bool isNestedDeclContext(const DeclContext *D, const DeclContext *Context) { |
| while (D) { |
| if (D == Context) |
| return true; |
| D = D->getParent(); |
| } |
| return false; |
| } |
| |
| // Returns true if \p D is visible at \p Loc with DeclContext \p DeclCtx. |
| bool isDeclVisibleAtLocation(const SourceManager &SM, const Decl *D, |
| const DeclContext *DeclCtx, SourceLocation Loc) { |
| SourceLocation DeclLoc = SM.getSpellingLoc(D->getBeginLoc()); |
| Loc = SM.getSpellingLoc(Loc); |
| return SM.isBeforeInTranslationUnit(DeclLoc, Loc) && |
| (SM.getFileID(DeclLoc) == SM.getFileID(Loc) && |
| isNestedDeclContext(DeclCtx, D->getDeclContext())); |
| } |
| |
| // Given a qualified symbol name, returns true if the symbol will be |
| // incorrectly qualified without leading "::". For example, a symbol |
| // "nx::ny::Foo" in namespace "na::nx::ny" without leading "::"; a symbol |
| // "util::X" in namespace "na" can potentially conflict with "na::util" (if this |
| // exists). |
| bool conflictInNamespace(const ASTContext &AST, llvm::StringRef QualifiedSymbol, |
| llvm::StringRef Namespace) { |
| auto SymbolSplitted = splitSymbolName(QualifiedSymbol.trim(":")); |
| assert(!SymbolSplitted.empty()); |
| SymbolSplitted.pop_back(); // We are only interested in namespaces. |
| |
| if (SymbolSplitted.size() >= 1 && !Namespace.empty()) { |
| auto SymbolTopNs = SymbolSplitted.front(); |
| auto NsSplitted = splitSymbolName(Namespace.trim(":")); |
| assert(!NsSplitted.empty()); |
| |
| auto LookupDecl = [&AST](const Decl &Scope, |
| llvm::StringRef Name) -> const NamedDecl * { |
| const auto *DC = llvm::dyn_cast<DeclContext>(&Scope); |
| if (!DC) |
| return nullptr; |
| auto LookupRes = DC->lookup(DeclarationName(&AST.Idents.get(Name))); |
| if (LookupRes.empty()) |
| return nullptr; |
| return LookupRes.front(); |
| }; |
| // We do not check the outermost namespace since it would not be a |
| // conflict if it equals to the symbol's outermost namespace and the |
| // symbol name would have been shortened. |
| const NamedDecl *Scope = |
| LookupDecl(*AST.getTranslationUnitDecl(), NsSplitted.front()); |
| for (auto I = NsSplitted.begin() + 1, E = NsSplitted.end(); I != E; ++I) { |
| if (*I == SymbolTopNs) // Handles "::ny" in "::nx::ny" case. |
| return true; |
| // Handles "::util" and "::nx::util" conflicts. |
| if (Scope) { |
| if (LookupDecl(*Scope, SymbolTopNs)) |
| return true; |
| Scope = LookupDecl(*Scope, *I); |
| } |
| } |
| if (Scope && LookupDecl(*Scope, SymbolTopNs)) |
| return true; |
| } |
| return false; |
| } |
| |
| bool isTemplateParameter(TypeLoc Type) { |
| while (!Type.isNull()) { |
| if (Type.getTypeLocClass() == TypeLoc::SubstTemplateTypeParm) |
| return true; |
| Type = Type.getNextTypeLoc(); |
| } |
| return false; |
| } |
| |
| } // anonymous namespace |
| |
| ChangeNamespaceTool::ChangeNamespaceTool( |
| llvm::StringRef OldNs, llvm::StringRef NewNs, llvm::StringRef FilePattern, |
| llvm::ArrayRef<std::string> AllowedSymbolPatterns, |
| std::map<std::string, tooling::Replacements> *FileToReplacements, |
| llvm::StringRef FallbackStyle) |
| : FallbackStyle(FallbackStyle), FileToReplacements(*FileToReplacements), |
| OldNamespace(OldNs.ltrim(':')), NewNamespace(NewNs.ltrim(':')), |
| FilePattern(FilePattern), FilePatternRE(FilePattern) { |
| FileToReplacements->clear(); |
| auto OldNsSplitted = splitSymbolName(OldNamespace); |
| auto NewNsSplitted = splitSymbolName(NewNamespace); |
| // Calculates `DiffOldNamespace` and `DiffNewNamespace`. |
| while (!OldNsSplitted.empty() && !NewNsSplitted.empty() && |
| OldNsSplitted.front() == NewNsSplitted.front()) { |
| OldNsSplitted.erase(OldNsSplitted.begin()); |
| NewNsSplitted.erase(NewNsSplitted.begin()); |
| } |
| DiffOldNamespace = joinNamespaces(OldNsSplitted); |
| DiffNewNamespace = joinNamespaces(NewNsSplitted); |
| |
| for (const auto &Pattern : AllowedSymbolPatterns) |
| AllowedSymbolRegexes.emplace_back(Pattern); |
| } |
| |
| void ChangeNamespaceTool::registerMatchers(ast_matchers::MatchFinder *Finder) { |
| std::string FullOldNs = "::" + OldNamespace; |
| // Prefix is the outer-most namespace in DiffOldNamespace. For example, if the |
| // OldNamespace is "a::b::c" and DiffOldNamespace is "b::c", then Prefix will |
| // be "a::b". Declarations in this namespace will not be visible in the new |
| // namespace. If DiffOldNamespace is empty, Prefix will be a invalid name "-". |
| llvm::SmallVector<llvm::StringRef, 4> DiffOldNsSplitted; |
| llvm::StringRef(DiffOldNamespace) |
| .split(DiffOldNsSplitted, "::", /*MaxSplit=*/-1, |
| /*KeepEmpty=*/false); |
| std::string Prefix = "-"; |
| if (!DiffOldNsSplitted.empty()) |
| Prefix = (StringRef(FullOldNs).drop_back(DiffOldNamespace.size()) + |
| DiffOldNsSplitted.front()) |
| .str(); |
| auto IsInMovedNs = |
| allOf(hasAncestor(namespaceDecl(hasName(FullOldNs)).bind("ns_decl")), |
| isExpansionInFileMatching(FilePattern)); |
| auto IsVisibleInNewNs = anyOf( |
| IsInMovedNs, unless(hasAncestor(namespaceDecl(hasName(Prefix))))); |
| // Match using declarations. |
| Finder->addMatcher( |
| usingDecl(isExpansionInFileMatching(FilePattern), IsVisibleInNewNs) |
| .bind("using"), |
| this); |
| // Match using namespace declarations. |
| Finder->addMatcher(usingDirectiveDecl(isExpansionInFileMatching(FilePattern), |
| IsVisibleInNewNs) |
| .bind("using_namespace"), |
| this); |
| // Match namespace alias declarations. |
| Finder->addMatcher(namespaceAliasDecl(isExpansionInFileMatching(FilePattern), |
| IsVisibleInNewNs) |
| .bind("namespace_alias"), |
| this); |
| |
| // Match old namespace blocks. |
| Finder->addMatcher( |
| namespaceDecl(hasName(FullOldNs), isExpansionInFileMatching(FilePattern)) |
| .bind("old_ns"), |
| this); |
| |
| // Match class forward-declarations in the old namespace. |
| // Note that forward-declarations in classes are not matched. |
| Finder->addMatcher(cxxRecordDecl(unless(anyOf(isImplicit(), isDefinition())), |
| IsInMovedNs, hasParent(namespaceDecl())) |
| .bind("class_fwd_decl"), |
| this); |
| |
| // Match template class forward-declarations in the old namespace. |
| Finder->addMatcher( |
| classTemplateDecl(unless(hasDescendant(cxxRecordDecl(isDefinition()))), |
| IsInMovedNs, hasParent(namespaceDecl())) |
| .bind("template_class_fwd_decl"), |
| this); |
| |
| // Match references to types that are not defined in the old namespace. |
| // Forward-declarations in the old namespace are also matched since they will |
| // be moved back to the old namespace. |
| auto DeclMatcher = namedDecl( |
| hasAncestor(namespaceDecl()), |
| unless(anyOf( |
| isImplicit(), hasAncestor(namespaceDecl(isAnonymous())), |
| hasAncestor(cxxRecordDecl()), |
| allOf(IsInMovedNs, unless(cxxRecordDecl(unless(isDefinition()))))))); |
| |
| // Using shadow declarations in classes always refers to base class, which |
| // does not need to be qualified since it can be inferred from inheritance. |
| // Note that this does not match using alias declarations. |
| auto UsingShadowDeclInClass = |
| usingDecl(hasAnyUsingShadowDecl(decl()), hasParent(cxxRecordDecl())); |
| |
| // Match TypeLocs on the declaration. Carefully match only the outermost |
| // TypeLoc and template specialization arguments (which are not outermost) |
| // that are directly linked to types matching `DeclMatcher`. Nested name |
| // specifier locs are handled separately below. |
| Finder->addMatcher( |
| typeLoc(IsInMovedNs, |
| loc(qualType(hasDeclaration(DeclMatcher.bind("from_decl")))), |
| unless(anyOf(hasParent(typeLoc(loc(qualType( |
| hasDeclaration(DeclMatcher), |
| unless(templateSpecializationType()))))), |
| hasParent(nestedNameSpecifierLoc()), |
| hasAncestor(decl(isImplicit())), |
| hasAncestor(UsingShadowDeclInClass), |
| hasAncestor(functionDecl(isDefaulted())))), |
| hasAncestor(decl().bind("dc"))) |
| .bind("type"), |
| this); |
| |
| // Types in `UsingShadowDecl` is not matched by `typeLoc` above, so we need to |
| // special case it. |
| // Since using declarations inside classes must have the base class in the |
| // nested name specifier, we leave it to the nested name specifier matcher. |
| Finder->addMatcher(usingDecl(IsInMovedNs, hasAnyUsingShadowDecl(decl()), |
| unless(UsingShadowDeclInClass)) |
| .bind("using_with_shadow"), |
| this); |
| |
| // Handle types in nested name specifier. Specifiers that are in a TypeLoc |
| // matched above are not matched, e.g. "A::" in "A::A" is not matched since |
| // "A::A" would have already been fixed. |
| Finder->addMatcher( |
| nestedNameSpecifierLoc( |
| hasAncestor(decl(IsInMovedNs).bind("dc")), |
| loc(nestedNameSpecifier( |
| specifiesType(hasDeclaration(DeclMatcher.bind("from_decl"))))), |
| unless(anyOf(hasAncestor(decl(isImplicit())), |
| hasAncestor(UsingShadowDeclInClass), |
| hasAncestor(functionDecl(isDefaulted())), |
| hasAncestor(typeLoc(loc(qualType(hasDeclaration( |
| decl(equalsBoundNode("from_decl")))))))))) |
| .bind("nested_specifier_loc"), |
| this); |
| |
| // Matches base class initializers in constructors. TypeLocs of base class |
| // initializers do not need to be fixed. For example, |
| // class X : public a::b::Y { |
| // public: |
| // X() : Y::Y() {} // Y::Y do not need namespace specifier. |
| // }; |
| Finder->addMatcher( |
| cxxCtorInitializer(isBaseInitializer()).bind("base_initializer"), this); |
| |
| // Handle function. |
| // Only handle functions that are defined in a namespace excluding member |
| // function, static methods (qualified by nested specifier), and functions |
| // defined in the global namespace. |
| // Note that the matcher does not exclude calls to out-of-line static method |
| // definitions, so we need to exclude them in the callback handler. |
| auto FuncMatcher = |
| functionDecl(unless(anyOf(cxxMethodDecl(), IsInMovedNs, |
| hasAncestor(namespaceDecl(isAnonymous())), |
| hasAncestor(cxxRecordDecl()))), |
| hasParent(namespaceDecl())); |
| Finder->addMatcher(expr(hasAncestor(decl().bind("dc")), IsInMovedNs, |
| unless(hasAncestor(decl(isImplicit()))), |
| anyOf(callExpr(callee(FuncMatcher)).bind("call"), |
| declRefExpr(to(FuncMatcher.bind("func_decl"))) |
| .bind("func_ref"))), |
| this); |
| |
| auto GlobalVarMatcher = varDecl( |
| hasGlobalStorage(), hasParent(namespaceDecl()), |
| unless(anyOf(IsInMovedNs, hasAncestor(namespaceDecl(isAnonymous()))))); |
| Finder->addMatcher(declRefExpr(IsInMovedNs, hasAncestor(decl().bind("dc")), |
| to(GlobalVarMatcher.bind("var_decl"))) |
| .bind("var_ref"), |
| this); |
| |
| // Handle unscoped enum constant. |
| auto UnscopedEnumMatcher = enumConstantDecl(hasParent(enumDecl( |
| hasParent(namespaceDecl()), |
| unless(anyOf(isScoped(), IsInMovedNs, hasAncestor(cxxRecordDecl()), |
| hasAncestor(namespaceDecl(isAnonymous()))))))); |
| Finder->addMatcher( |
| declRefExpr(IsInMovedNs, hasAncestor(decl().bind("dc")), |
| to(UnscopedEnumMatcher.bind("enum_const_decl"))) |
| .bind("enum_const_ref"), |
| this); |
| } |
| |
| void ChangeNamespaceTool::run( |
| const ast_matchers::MatchFinder::MatchResult &Result) { |
| if (const auto *Using = Result.Nodes.getNodeAs<UsingDecl>("using")) { |
| UsingDecls.insert(Using); |
| } else if (const auto *UsingNamespace = |
| Result.Nodes.getNodeAs<UsingDirectiveDecl>( |
| "using_namespace")) { |
| UsingNamespaceDecls.insert(UsingNamespace); |
| } else if (const auto *NamespaceAlias = |
| Result.Nodes.getNodeAs<NamespaceAliasDecl>( |
| "namespace_alias")) { |
| NamespaceAliasDecls.insert(NamespaceAlias); |
| } else if (const auto *NsDecl = |
| Result.Nodes.getNodeAs<NamespaceDecl>("old_ns")) { |
| moveOldNamespace(Result, NsDecl); |
| } else if (const auto *FwdDecl = |
| Result.Nodes.getNodeAs<CXXRecordDecl>("class_fwd_decl")) { |
| moveClassForwardDeclaration(Result, cast<NamedDecl>(FwdDecl)); |
| } else if (const auto *TemplateFwdDecl = |
| Result.Nodes.getNodeAs<ClassTemplateDecl>( |
| "template_class_fwd_decl")) { |
| moveClassForwardDeclaration(Result, cast<NamedDecl>(TemplateFwdDecl)); |
| } else if (const auto *UsingWithShadow = |
| Result.Nodes.getNodeAs<UsingDecl>("using_with_shadow")) { |
| fixUsingShadowDecl(Result, UsingWithShadow); |
| } else if (const auto *Specifier = |
| Result.Nodes.getNodeAs<NestedNameSpecifierLoc>( |
| "nested_specifier_loc")) { |
| SourceLocation Start = Specifier->getBeginLoc(); |
| SourceLocation End = endLocationForType(Specifier->getTypeLoc()); |
| fixTypeLoc(Result, Start, End, Specifier->getTypeLoc()); |
| } else if (const auto *BaseInitializer = |
| Result.Nodes.getNodeAs<CXXCtorInitializer>( |
| "base_initializer")) { |
| BaseCtorInitializerTypeLocs.push_back( |
| BaseInitializer->getTypeSourceInfo()->getTypeLoc()); |
| } else if (const auto *TLoc = Result.Nodes.getNodeAs<TypeLoc>("type")) { |
| // This avoids fixing types with record types as qualifier, which is not |
| // filtered by matchers in some cases, e.g. the type is templated. We should |
| // handle the record type qualifier instead. |
| TypeLoc Loc = *TLoc; |
| while (Loc.getTypeLocClass() == TypeLoc::Qualified) |
| Loc = Loc.getNextTypeLoc(); |
| if (Loc.getTypeLocClass() == TypeLoc::Elaborated) { |
| NestedNameSpecifierLoc NestedNameSpecifier = |
| Loc.castAs<ElaboratedTypeLoc>().getQualifierLoc(); |
| // This happens for friend declaration of a base class with injected class |
| // name. |
| if (!NestedNameSpecifier.getNestedNameSpecifier()) |
| return; |
| const Type *SpecifierType = |
| NestedNameSpecifier.getNestedNameSpecifier()->getAsType(); |
| if (SpecifierType && SpecifierType->isRecordType()) |
| return; |
| } |
| fixTypeLoc(Result, startLocationForType(Loc), endLocationForType(Loc), Loc); |
| } else if (const auto *VarRef = |
| Result.Nodes.getNodeAs<DeclRefExpr>("var_ref")) { |
| const auto *Var = Result.Nodes.getNodeAs<VarDecl>("var_decl"); |
| assert(Var); |
| if (Var->getCanonicalDecl()->isStaticDataMember()) |
| return; |
| const auto *Context = Result.Nodes.getNodeAs<Decl>("dc"); |
| assert(Context && "Empty decl context."); |
| fixDeclRefExpr(Result, Context->getDeclContext(), |
| llvm::cast<NamedDecl>(Var), VarRef); |
| } else if (const auto *EnumConstRef = |
| Result.Nodes.getNodeAs<DeclRefExpr>("enum_const_ref")) { |
| // Do not rename the reference if it is already scoped by the EnumDecl name. |
| if (EnumConstRef->hasQualifier() && |
| EnumConstRef->getQualifier()->getKind() == |
| NestedNameSpecifier::SpecifierKind::TypeSpec && |
| EnumConstRef->getQualifier()->getAsType()->isEnumeralType()) |
| return; |
| const auto *EnumConstDecl = |
| Result.Nodes.getNodeAs<EnumConstantDecl>("enum_const_decl"); |
| assert(EnumConstDecl); |
| const auto *Context = Result.Nodes.getNodeAs<Decl>("dc"); |
| assert(Context && "Empty decl context."); |
| // FIXME: this would qualify "ns::VALUE" as "ns::EnumValue::VALUE". Fix it |
| // if it turns out to be an issue. |
| fixDeclRefExpr(Result, Context->getDeclContext(), |
| llvm::cast<NamedDecl>(EnumConstDecl), EnumConstRef); |
| } else if (const auto *FuncRef = |
| Result.Nodes.getNodeAs<DeclRefExpr>("func_ref")) { |
| // If this reference has been processed as a function call, we do not |
| // process it again. |
| if (ProcessedFuncRefs.count(FuncRef)) |
| return; |
| ProcessedFuncRefs.insert(FuncRef); |
| const auto *Func = Result.Nodes.getNodeAs<FunctionDecl>("func_decl"); |
| assert(Func); |
| const auto *Context = Result.Nodes.getNodeAs<Decl>("dc"); |
| assert(Context && "Empty decl context."); |
| fixDeclRefExpr(Result, Context->getDeclContext(), |
| llvm::cast<NamedDecl>(Func), FuncRef); |
| } else { |
| const auto *Call = Result.Nodes.getNodeAs<CallExpr>("call"); |
| assert(Call != nullptr && "Expecting callback for CallExpr."); |
| const auto *CalleeFuncRef = |
| llvm::cast<DeclRefExpr>(Call->getCallee()->IgnoreImplicit()); |
| ProcessedFuncRefs.insert(CalleeFuncRef); |
| const FunctionDecl *Func = Call->getDirectCallee(); |
| assert(Func != nullptr); |
| // FIXME: ignore overloaded operators. This would miss cases where operators |
| // are called by qualified names (i.e. "ns::operator <"). Ignore such |
| // cases for now. |
| if (Func->isOverloadedOperator()) |
| return; |
| // Ignore out-of-line static methods since they will be handled by nested |
| // name specifiers. |
| if (Func->getCanonicalDecl()->getStorageClass() == |
| StorageClass::SC_Static && |
| Func->isOutOfLine()) |
| return; |
| const auto *Context = Result.Nodes.getNodeAs<Decl>("dc"); |
| assert(Context && "Empty decl context."); |
| SourceRange CalleeRange = Call->getCallee()->getSourceRange(); |
| replaceQualifiedSymbolInDeclContext( |
| Result, Context->getDeclContext(), CalleeRange.getBegin(), |
| CalleeRange.getEnd(), llvm::cast<NamedDecl>(Func)); |
| } |
| } |
| |
| static SourceLocation getLocAfterNamespaceLBrace(const NamespaceDecl *NsDecl, |
| const SourceManager &SM, |
| const LangOptions &LangOpts) { |
| std::unique_ptr<Lexer> Lex = |
| getLexerStartingFromLoc(NsDecl->getBeginLoc(), SM, LangOpts); |
| assert(Lex.get() && |
| "Failed to create lexer from the beginning of namespace."); |
| if (!Lex.get()) |
| return SourceLocation(); |
| Token Tok; |
| while (!Lex->LexFromRawLexer(Tok) && Tok.isNot(tok::TokenKind::l_brace)) { |
| } |
| return Tok.isNot(tok::TokenKind::l_brace) |
| ? SourceLocation() |
| : Tok.getEndLoc().getLocWithOffset(1); |
| } |
| |
| // Stores information about a moved namespace in `MoveNamespaces` and leaves |
| // the actual movement to `onEndOfTranslationUnit()`. |
| void ChangeNamespaceTool::moveOldNamespace( |
| const ast_matchers::MatchFinder::MatchResult &Result, |
| const NamespaceDecl *NsDecl) { |
| // If the namespace is empty, do nothing. |
| if (Decl::castToDeclContext(NsDecl)->decls_empty()) |
| return; |
| |
| const SourceManager &SM = *Result.SourceManager; |
| // Get the range of the code in the old namespace. |
| SourceLocation Start = |
| getLocAfterNamespaceLBrace(NsDecl, SM, Result.Context->getLangOpts()); |
| assert(Start.isValid() && "Can't find l_brace for namespace."); |
| MoveNamespace MoveNs; |
| MoveNs.Offset = SM.getFileOffset(Start); |
| // The range of the moved namespace is from the location just past the left |
| // brace to the location right before the right brace. |
| MoveNs.Length = SM.getFileOffset(NsDecl->getRBraceLoc()) - MoveNs.Offset; |
| |
| // Insert the new namespace after `DiffOldNamespace`. For example, if |
| // `OldNamespace` is "a::b::c" and `NewNamespace` is `a::x::y`, then |
| // "x::y" will be inserted inside the existing namespace "a" and after "a::b". |
| // `OuterNs` is the first namespace in `DiffOldNamespace`, e.g. "namespace b" |
| // in the above example. |
| // If there is no outer namespace (i.e. DiffOldNamespace is empty), the new |
| // namespace will be a nested namespace in the old namespace. |
| const NamespaceDecl *OuterNs = getOuterNamespace(NsDecl, DiffOldNamespace); |
| SourceLocation InsertionLoc = Start; |
| if (OuterNs) { |
| SourceLocation LocAfterNs = getStartOfNextLine( |
| OuterNs->getRBraceLoc(), SM, Result.Context->getLangOpts()); |
| assert(LocAfterNs.isValid() && |
| "Failed to get location after DiffOldNamespace"); |
| InsertionLoc = LocAfterNs; |
| } |
| MoveNs.InsertionOffset = SM.getFileOffset(SM.getSpellingLoc(InsertionLoc)); |
| MoveNs.FID = SM.getFileID(Start); |
| MoveNs.SourceMgr = Result.SourceManager; |
| MoveNamespaces[std::string(SM.getFilename(Start))].push_back(MoveNs); |
| } |
| |
| // Removes a class forward declaration from the code in the moved namespace and |
| // creates an `InsertForwardDeclaration` to insert the forward declaration back |
| // into the old namespace after moving code from the old namespace to the new |
| // namespace. |
| // For example, changing "a" to "x": |
| // Old code: |
| // namespace a { |
| // class FWD; |
| // class A { FWD *fwd; } |
| // } // a |
| // New code: |
| // namespace a { |
| // class FWD; |
| // } // a |
| // namespace x { |
| // class A { a::FWD *fwd; } |
| // } // x |
| void ChangeNamespaceTool::moveClassForwardDeclaration( |
| const ast_matchers::MatchFinder::MatchResult &Result, |
| const NamedDecl *FwdDecl) { |
| SourceLocation Start = FwdDecl->getBeginLoc(); |
| SourceLocation End = FwdDecl->getEndLoc(); |
| const SourceManager &SM = *Result.SourceManager; |
| SourceLocation AfterSemi = Lexer::findLocationAfterToken( |
| End, tok::semi, SM, Result.Context->getLangOpts(), |
| /*SkipTrailingWhitespaceAndNewLine=*/true); |
| if (AfterSemi.isValid()) |
| End = AfterSemi.getLocWithOffset(-1); |
| // Delete the forward declaration from the code to be moved. |
| addReplacementOrDie(Start, End, "", SM, &FileToReplacements); |
| llvm::StringRef Code = Lexer::getSourceText( |
| CharSourceRange::getTokenRange(SM.getSpellingLoc(Start), |
| SM.getSpellingLoc(End)), |
| SM, Result.Context->getLangOpts()); |
| // Insert the forward declaration back into the old namespace after moving the |
| // code from old namespace to new namespace. |
| // Insertion information is stored in `InsertFwdDecls` and actual |
| // insertion will be performed in `onEndOfTranslationUnit`. |
| // Get the (old) namespace that contains the forward declaration. |
| const auto *NsDecl = Result.Nodes.getNodeAs<NamespaceDecl>("ns_decl"); |
| // The namespace contains the forward declaration, so it must not be empty. |
| assert(!NsDecl->decls_empty()); |
| const auto Insertion = createInsertion( |
| getLocAfterNamespaceLBrace(NsDecl, SM, Result.Context->getLangOpts()), |
| Code, SM); |
| InsertForwardDeclaration InsertFwd; |
| InsertFwd.InsertionOffset = Insertion.getOffset(); |
| InsertFwd.ForwardDeclText = Insertion.getReplacementText().str(); |
| InsertFwdDecls[std::string(Insertion.getFilePath())].push_back(InsertFwd); |
| } |
| |
| // Replaces a qualified symbol (in \p DeclCtx) that refers to a declaration \p |
| // FromDecl with the shortest qualified name possible when the reference is in |
| // `NewNamespace`. |
| void ChangeNamespaceTool::replaceQualifiedSymbolInDeclContext( |
| const ast_matchers::MatchFinder::MatchResult &Result, |
| const DeclContext *DeclCtx, SourceLocation Start, SourceLocation End, |
| const NamedDecl *FromDecl) { |
| const auto *NsDeclContext = DeclCtx->getEnclosingNamespaceContext(); |
| if (llvm::isa<TranslationUnitDecl>(NsDeclContext)) { |
| // This should not happen in usual unless the TypeLoc is in function type |
| // parameters, e.g `std::function<void(T)>`. In this case, DeclContext of |
| // `T` will be the translation unit. We simply use fully-qualified name |
| // here. |
| // Note that `FromDecl` must not be defined in the old namespace (according |
| // to `DeclMatcher`), so its fully-qualified name will not change after |
| // changing the namespace. |
| addReplacementOrDie(Start, End, FromDecl->getQualifiedNameAsString(), |
| *Result.SourceManager, &FileToReplacements); |
| return; |
| } |
| const auto *NsDecl = llvm::cast<NamespaceDecl>(NsDeclContext); |
| // Calculate the name of the `NsDecl` after it is moved to new namespace. |
| std::string OldNs = NsDecl->getQualifiedNameAsString(); |
| llvm::StringRef Postfix = OldNs; |
| bool Consumed = Postfix.consume_front(OldNamespace); |
| assert(Consumed && "Expect OldNS to start with OldNamespace."); |
| (void)Consumed; |
| const std::string NewNs = (NewNamespace + Postfix).str(); |
| |
| llvm::StringRef NestedName = Lexer::getSourceText( |
| CharSourceRange::getTokenRange( |
| Result.SourceManager->getSpellingLoc(Start), |
| Result.SourceManager->getSpellingLoc(End)), |
| *Result.SourceManager, Result.Context->getLangOpts()); |
| std::string FromDeclName = FromDecl->getQualifiedNameAsString(); |
| for (llvm::Regex &RE : AllowedSymbolRegexes) |
| if (RE.match(FromDeclName)) |
| return; |
| std::string ReplaceName = |
| getShortestQualifiedNameInNamespace(FromDeclName, NewNs); |
| // Checks if there is any using namespace declarations that can shorten the |
| // qualified name. |
| for (const auto *UsingNamespace : UsingNamespaceDecls) { |
| if (!isDeclVisibleAtLocation(*Result.SourceManager, UsingNamespace, DeclCtx, |
| Start)) |
| continue; |
| StringRef FromDeclNameRef = FromDeclName; |
| if (FromDeclNameRef.consume_front(UsingNamespace->getNominatedNamespace() |
| ->getQualifiedNameAsString())) { |
| FromDeclNameRef = FromDeclNameRef.drop_front(2); |
| if (FromDeclNameRef.size() < ReplaceName.size()) |
| ReplaceName = std::string(FromDeclNameRef); |
| } |
| } |
| // Checks if there is any namespace alias declarations that can shorten the |
| // qualified name. |
| for (const auto *NamespaceAlias : NamespaceAliasDecls) { |
| if (!isDeclVisibleAtLocation(*Result.SourceManager, NamespaceAlias, DeclCtx, |
| Start)) |
| continue; |
| StringRef FromDeclNameRef = FromDeclName; |
| if (FromDeclNameRef.consume_front( |
| NamespaceAlias->getNamespace()->getQualifiedNameAsString() + |
| "::")) { |
| std::string AliasName = NamespaceAlias->getNameAsString(); |
| std::string AliasQualifiedName = |
| NamespaceAlias->getQualifiedNameAsString(); |
| // We only consider namespace aliases define in the global namespace or |
| // in namespaces that are directly visible from the reference, i.e. |
| // ancestor of the `OldNs`. Note that declarations in ancestor namespaces |
| // but not visible in the new namespace is filtered out by |
| // "IsVisibleInNewNs" matcher. |
| if (AliasQualifiedName != AliasName) { |
| // The alias is defined in some namespace. |
| assert(StringRef(AliasQualifiedName).endswith("::" + AliasName)); |
| llvm::StringRef AliasNs = |
| StringRef(AliasQualifiedName).drop_back(AliasName.size() + 2); |
| if (!llvm::StringRef(OldNs).startswith(AliasNs)) |
| continue; |
| } |
| std::string NameWithAliasNamespace = |
| (AliasName + "::" + FromDeclNameRef).str(); |
| if (NameWithAliasNamespace.size() < ReplaceName.size()) |
| ReplaceName = NameWithAliasNamespace; |
| } |
| } |
| // Checks if there is any using shadow declarations that can shorten the |
| // qualified name. |
| bool Matched = false; |
| for (const UsingDecl *Using : UsingDecls) { |
| if (Matched) |
| break; |
| if (isDeclVisibleAtLocation(*Result.SourceManager, Using, DeclCtx, Start)) { |
| for (const auto *UsingShadow : Using->shadows()) { |
| const auto *TargetDecl = UsingShadow->getTargetDecl(); |
| if (TargetDecl->getQualifiedNameAsString() == |
| FromDecl->getQualifiedNameAsString()) { |
| ReplaceName = FromDecl->getNameAsString(); |
| Matched = true; |
| break; |
| } |
| } |
| } |
| } |
| bool Conflict = conflictInNamespace(DeclCtx->getParentASTContext(), |
| ReplaceName, NewNamespace); |
| // If the new nested name in the new namespace is the same as it was in the |
| // old namespace, we don't create replacement unless there can be ambiguity. |
| if ((NestedName == ReplaceName && !Conflict) || |
| (NestedName.startswith("::") && NestedName.drop_front(2) == ReplaceName)) |
| return; |
| // If the reference need to be fully-qualified, add a leading "::" unless |
| // NewNamespace is the global namespace. |
| if (ReplaceName == FromDeclName && !NewNamespace.empty() && Conflict) |
| ReplaceName = "::" + ReplaceName; |
| addReplacementOrDie(Start, End, ReplaceName, *Result.SourceManager, |
| &FileToReplacements); |
| } |
| |
| // Replace the [Start, End] of `Type` with the shortest qualified name when the |
| // `Type` is in `NewNamespace`. |
| void ChangeNamespaceTool::fixTypeLoc( |
| const ast_matchers::MatchFinder::MatchResult &Result, SourceLocation Start, |
| SourceLocation End, TypeLoc Type) { |
| // FIXME: do not rename template parameter. |
| if (Start.isInvalid() || End.isInvalid()) |
| return; |
| // Types of CXXCtorInitializers do not need to be fixed. |
| if (llvm::is_contained(BaseCtorInitializerTypeLocs, Type)) |
| return; |
| if (isTemplateParameter(Type)) |
| return; |
| // The declaration which this TypeLoc refers to. |
| const auto *FromDecl = Result.Nodes.getNodeAs<NamedDecl>("from_decl"); |
| // `hasDeclaration` gives underlying declaration, but if the type is |
| // a typedef type, we need to use the typedef type instead. |
| auto IsInMovedNs = [&](const NamedDecl *D) { |
| if (!llvm::StringRef(D->getQualifiedNameAsString()) |
| .startswith(OldNamespace + "::")) |
| return false; |
| auto ExpansionLoc = Result.SourceManager->getExpansionLoc(D->getBeginLoc()); |
| if (ExpansionLoc.isInvalid()) |
| return false; |
| llvm::StringRef Filename = Result.SourceManager->getFilename(ExpansionLoc); |
| return FilePatternRE.match(Filename); |
| }; |
| // Make `FromDecl` the immediate declaration that `Type` refers to, i.e. if |
| // `Type` is an alias type, we make `FromDecl` the type alias declaration. |
| // Also, don't fix the \p Type if it refers to a type alias decl in the moved |
| // namespace since the alias decl will be moved along with the type reference. |
| if (auto *Typedef = Type.getType()->getAs<TypedefType>()) { |
| FromDecl = Typedef->getDecl(); |
| if (IsInMovedNs(FromDecl)) |
| return; |
| } else if (auto *TemplateType = |
| Type.getType()->getAs<TemplateSpecializationType>()) { |
| if (TemplateType->isTypeAlias()) { |
| FromDecl = TemplateType->getTemplateName().getAsTemplateDecl(); |
| if (IsInMovedNs(FromDecl)) |
| return; |
| } |
| } |
| const auto *DeclCtx = Result.Nodes.getNodeAs<Decl>("dc"); |
| assert(DeclCtx && "Empty decl context."); |
| replaceQualifiedSymbolInDeclContext(Result, DeclCtx->getDeclContext(), Start, |
| End, FromDecl); |
| } |
| |
| void ChangeNamespaceTool::fixUsingShadowDecl( |
| const ast_matchers::MatchFinder::MatchResult &Result, |
| const UsingDecl *UsingDeclaration) { |
| SourceLocation Start = UsingDeclaration->getBeginLoc(); |
| SourceLocation End = UsingDeclaration->getEndLoc(); |
| if (Start.isInvalid() || End.isInvalid()) |
| return; |
| |
| assert(UsingDeclaration->shadow_size() > 0); |
| // FIXME: it might not be always accurate to use the first using-decl. |
| const NamedDecl *TargetDecl = |
| UsingDeclaration->shadow_begin()->getTargetDecl(); |
| std::string TargetDeclName = TargetDecl->getQualifiedNameAsString(); |
| // FIXME: check if target_decl_name is in moved ns, which doesn't make much |
| // sense. If this happens, we need to use name with the new namespace. |
| // Use fully qualified name in UsingDecl for now. |
| addReplacementOrDie(Start, End, "using ::" + TargetDeclName, |
| *Result.SourceManager, &FileToReplacements); |
| } |
| |
| void ChangeNamespaceTool::fixDeclRefExpr( |
| const ast_matchers::MatchFinder::MatchResult &Result, |
| const DeclContext *UseContext, const NamedDecl *From, |
| const DeclRefExpr *Ref) { |
| SourceRange RefRange = Ref->getSourceRange(); |
| replaceQualifiedSymbolInDeclContext(Result, UseContext, RefRange.getBegin(), |
| RefRange.getEnd(), From); |
| } |
| |
| void ChangeNamespaceTool::onEndOfTranslationUnit() { |
| // Move namespace blocks and insert forward declaration to old namespace. |
| for (const auto &FileAndNsMoves : MoveNamespaces) { |
| auto &NsMoves = FileAndNsMoves.second; |
| if (NsMoves.empty()) |
| continue; |
| const std::string &FilePath = FileAndNsMoves.first; |
| auto &Replaces = FileToReplacements[FilePath]; |
| auto &SM = *NsMoves.begin()->SourceMgr; |
| llvm::StringRef Code = SM.getBufferData(NsMoves.begin()->FID); |
| auto ChangedCode = tooling::applyAllReplacements(Code, Replaces); |
| if (!ChangedCode) { |
| llvm::errs() << llvm::toString(ChangedCode.takeError()) << "\n"; |
| continue; |
| } |
| // Replacements on the changed code for moving namespaces and inserting |
| // forward declarations to old namespaces. |
| tooling::Replacements NewReplacements; |
| // Cut the changed code from the old namespace and paste the code in the new |
| // namespace. |
| for (const auto &NsMove : NsMoves) { |
| // Calculate the range of the old namespace block in the changed |
| // code. |
| const unsigned NewOffset = Replaces.getShiftedCodePosition(NsMove.Offset); |
| const unsigned NewLength = |
| Replaces.getShiftedCodePosition(NsMove.Offset + NsMove.Length) - |
| NewOffset; |
| tooling::Replacement Deletion(FilePath, NewOffset, NewLength, ""); |
| std::string MovedCode = ChangedCode->substr(NewOffset, NewLength); |
| std::string MovedCodeWrappedInNewNs = |
| wrapCodeInNamespace(DiffNewNamespace, MovedCode); |
| // Calculate the new offset at which the code will be inserted in the |
| // changed code. |
| unsigned NewInsertionOffset = |
| Replaces.getShiftedCodePosition(NsMove.InsertionOffset); |
| tooling::Replacement Insertion(FilePath, NewInsertionOffset, 0, |
| MovedCodeWrappedInNewNs); |
| addOrMergeReplacement(Deletion, &NewReplacements); |
| addOrMergeReplacement(Insertion, &NewReplacements); |
| } |
| // After moving namespaces, insert forward declarations back to old |
| // namespaces. |
| const auto &FwdDeclInsertions = InsertFwdDecls[FilePath]; |
| for (const auto &FwdDeclInsertion : FwdDeclInsertions) { |
| unsigned NewInsertionOffset = |
| Replaces.getShiftedCodePosition(FwdDeclInsertion.InsertionOffset); |
| tooling::Replacement Insertion(FilePath, NewInsertionOffset, 0, |
| FwdDeclInsertion.ForwardDeclText); |
| addOrMergeReplacement(Insertion, &NewReplacements); |
| } |
| // Add replacements referring to the changed code to existing replacements, |
| // which refers to the original code. |
| Replaces = Replaces.merge(NewReplacements); |
| auto Style = |
| format::getStyle(format::DefaultFormatStyle, FilePath, FallbackStyle); |
| if (!Style) { |
| llvm::errs() << llvm::toString(Style.takeError()) << "\n"; |
| continue; |
| } |
| // Clean up old namespaces if there is nothing in it after moving. |
| auto CleanReplacements = |
| format::cleanupAroundReplacements(Code, Replaces, *Style); |
| if (!CleanReplacements) { |
| llvm::errs() << llvm::toString(CleanReplacements.takeError()) << "\n"; |
| continue; |
| } |
| FileToReplacements[FilePath] = *CleanReplacements; |
| } |
| |
| // Make sure we don't generate replacements for files that do not match |
| // FilePattern. |
| for (auto &Entry : FileToReplacements) |
| if (!FilePatternRE.match(Entry.first)) |
| Entry.second.clear(); |
| } |
| |
| } // namespace change_namespace |
| } // namespace clang |