/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4; fill-column: 100 -*- */ /* * This file is part of the LibreOffice project. * * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #ifndef LO_CLANG_SHARED_PLUGINS #include #include #include #include #include #include "clang/Sema/SemaDiagnostic.h" #include "check.hxx" #include "compat.hxx" #include "plugin.hxx" namespace { bool derivesFromTestFixture(CXXRecordDecl const* decl) { static auto const pred = [](CXXBaseSpecifier const& spec) { if (auto const t = spec.getType()->getAs()) { // (may be a template parameter) return derivesFromTestFixture(dyn_cast(t->getDecl())); } return false; }; return loplugin::DeclCheck(decl).Class("TestFixture").Namespace("CppUnit").GlobalNamespace() || std::any_of(decl->bases_begin(), decl->bases_end(), pred) || std::any_of(decl->vbases_begin(), decl->vbases_end(), pred); } bool isInjectedFunction(FunctionDecl const* decl) { for (auto d = decl->redecls_begin(); d != decl->redecls_end(); ++d) { auto const c = d->getLexicalDeclContext(); if (!(c->isFunctionOrMethod() || c->isRecord())) { return false; } } return true; } // Whether type1 mentions type2 (in a way relevant for argument-dependent name lookup): bool mentions(QualType type1, QualType type2) { auto t1 = type1; for (;;) { if (auto const t2 = t1->getAs()) { t1 = t2->getPointeeType(); } else if (auto const t3 = t1->getAs()) { t1 = t3->getPointeeType(); } else if (auto const t4 = t1->getAsArrayTypeUnsafe()) { t1 = t4->getElementType(); } else { break; } } if (t1.getCanonicalType().getTypePtr() == type2.getTypePtr()) { return true; } if (auto const t2 = t1->getAs()) { auto const args = t2->template_arguments(); for (auto a = args.begin(); a != args.end(); ++a) { if (a->getKind() != TemplateArgument::Type) { continue; } if (mentions(a->getAsType(), type2)) { return true; } } auto const t3 = t2->desugar(); if (t3.getTypePtr() == t2) { return false; } return mentions(t3, type2); } if (auto const t2 = t1->getAs()) { if (mentions(t2->getReturnType(), type2)) { return true; } for (auto t3 = t2->param_type_begin(); t3 != t2->param_type_end(); ++t3) { if (mentions(*t3, type2)) { return true; } } return false; } if (auto const t2 = t1->getAs()) { if (t2->getClass()->getUnqualifiedDesugaredType() == type2.getTypePtr()) { return true; } return mentions(t2->getPointeeType(), type2); } return false; } bool hasSalDllpublicExportAttr(Decl const* decl) { if (auto const attr = decl->getAttr()) { return attr->getVisibility() == VisibilityAttr::Default; } return decl->hasAttr(); } class External : public loplugin::FilteringPlugin { public: explicit External(loplugin::InstantiationData const& data) : FilteringPlugin(data) { } void run() override { TraverseDecl(compiler.getASTContext().getTranslationUnitDecl()); } bool VisitTagDecl(TagDecl* decl) { if (isa(decl)) { return true; } if (!decl->isThisDeclarationADefinition()) { return true; } if (isa(decl->getDeclContext())) { return true; } if (!compiler.getLangOpts().CPlusPlus) { return true; } if (auto const d = dyn_cast(decl)) { if (d->getDescribedClassTemplate() != nullptr) { return true; } if (hasSalDllpublicExportAttr(d)) { // If the class definition has explicit default visibility, then assume that it // needs to be present (e.g., a backwards-compatibility stub like in // cppuhelper/source/compat.cxx): return true; } if (derivesFromTestFixture(d)) { // The names of CppUnit tests (that can be specified with CPPUNIT_TEST_NAME) are // tied to the fully-qualified names of classes derived from CppUnit::TestFixture, // so avoid unnamed namespaces in those classes' names: return true; } } return handleDeclaration(decl); } bool VisitFunctionDecl(FunctionDecl* decl) { if (isa(decl)) { return true; } if (decl->getTemplatedKind() != FunctionDecl::TK_NonTemplate) { return true; } if (!decl->isThisDeclarationADefinition()) { return true; } if (decl->isMain() || decl->isMSVCRTEntryPoint()) { return true; } if (loplugin::hasCLanguageLinkageType(decl) && loplugin::DeclCheck(decl).Function("_DllMainCRTStartup").GlobalNamespace()) { return true; } // If the function definition is explicit marked SAL_DLLPUBLIC_EXPORT or similar, then // assume that it needs to be present (e.g., only called via dlopen, or a backwards- // compatibility stub like in sal/osl/all/compat.cxx): if (hasSalDllpublicExportAttr(decl)) { return true; } auto const canon = decl->getCanonicalDecl(); if (loplugin::hasCLanguageLinkageType(canon) && (canon->hasAttr() || canon->hasAttr())) { return true; } if (compiler.getDiagnostics().getDiagnosticLevel(diag::warn_unused_function, decl->getLocation()) < DiagnosticsEngine::Warning) { // Don't warn about e.g. // // G_DEFINE_TYPE (GLOAction, g_lo_action, G_TYPE_OBJECT); // // in vcl/unx/gtk/gloactiongroup.cxx (which expands to non-static g_lo_action_get_type // function definition), which is already wrapped in // // #pragma GCC diagnostic ignored "-Wunused-function" return true; } if (isInjectedFunction(decl)) { return true; } return handleDeclaration(decl); } bool VisitVarDecl(VarDecl* decl) { if (decl->isStaticDataMember()) { return true; } if (isa(decl)) { return true; } if (!decl->isThisDeclarationADefinition()) { return true; } if (loplugin::DeclCheck(decl).Var("_pRawDllMain").GlobalNamespace()) { return true; } return handleDeclaration(decl); } bool VisitClassTemplateDecl(ClassTemplateDecl* decl) { if (!decl->isThisDeclarationADefinition()) { return true; } if (isa(decl->getDeclContext())) { return true; } return handleDeclaration(decl); } bool VisitFunctionTemplateDecl(FunctionTemplateDecl* decl) { if (!decl->isThisDeclarationADefinition()) { return true; } if (isa(decl->getDeclContext())) { return true; } if (isInjectedFunction(decl->getTemplatedDecl())) { return true; } return handleDeclaration(decl); } bool VisitVarTemplateDecl(VarTemplateDecl* decl) { if (!decl->isThisDeclarationADefinition()) { return true; } return handleDeclaration(decl); } private: template void reportSpecializations(T specializations) { for (auto const d : specializations) { auto const k = d->getTemplateSpecializationKind(); if (isTemplateExplicitInstantiationOrSpecialization(k)) { report(DiagnosticsEngine::Note, "explicit %select{instantiation|specialization}0 is here", d->getLocation()) << (k == TSK_ExplicitSpecialization) << d->getSourceRange(); } } } void computeAffectedTypes(Decl const* decl, std::vector* affected) { assert(affected != nullptr); if (auto const d = dyn_cast(decl)) { affected->push_back(compiler.getASTContext().getEnumType(d)); } else { //TODO: Derived types are also affected! CXXRecordDecl const* rec; if (auto const d = dyn_cast(decl)) { rec = d->getTemplatedDecl(); } else { rec = cast(decl); } affected->push_back(compiler.getASTContext().getRecordType(rec)); for (auto d = rec->decls_begin(); d != rec->decls_end(); ++d) { if (*d != (*d)->getCanonicalDecl()) { continue; } if (isa(*d) || isa(*d)) { if (auto const d1 = dyn_cast(*d)) { if (d1->isInjectedClassName()) { continue; } } computeAffectedTypes(*d, affected); } } } } void reportAssociatingFunctions(std::vector const& affected, Decl* decl) { auto c = decl->getDeclContext(); while (isa(c) || c->isInlineNamespace()) { c = c->getParent(); } assert(c->isTranslationUnit() || c->isNamespace()); SmallVector parts; c->collectAllContexts(parts); std::list ctxs; std::copy(parts.begin(), parts.end(), std::back_insert_iterator>(ctxs)); if (auto const d = dyn_cast(decl)) { // To find friend functions declared in the class: ctxs.push_back(d); } std::set fdecls; // to report every function just once for (auto ctx = ctxs.begin(); ctx != ctxs.end(); ++ctx) { for (auto i = (*ctx)->decls_begin(); i != (*ctx)->decls_end(); ++i) { auto d = *i; if (auto const d1 = dyn_cast(d)) { ctxs.push_back(d1); continue; } if (auto const d1 = dyn_cast(d)) { if (d1->isInline()) { ctxs.push_back(d1); } continue; } if (auto const d1 = dyn_cast(d)) { d = d1->getFriendDecl(); if (d == nullptr) // happens for 'friend struct S;' { continue; } } FunctionDecl const* f; if (auto const d1 = dyn_cast(d)) { f = d1->getTemplatedDecl(); } else { f = dyn_cast(d); if (f == nullptr) { continue; } } if (!fdecls.insert(f->getCanonicalDecl()).second) { continue; } if (isa(f)) { continue; } for (auto const& t : affected) { auto const tc = t.getCanonicalType(); for (auto p = f->param_begin(); p != f->param_end(); ++p) { if (mentions((*p)->getType(), tc)) { report(DiagnosticsEngine::Note, "a %select{function|function template|function template " "specialization}0 associating %1 is declared here", f->getLocation()) << (f->isFunctionTemplateSpecialization() ? 2 : f->getDescribedFunctionTemplate() != nullptr ? 1 : 0) << t << f->getSourceRange(); for (auto f1 = f->redecls_begin(); f1 != f->redecls_end(); ++f1) { if (*f1 == f) { continue; } report(DiagnosticsEngine::Note, "another declaration is here", f1->getLocation()) << f1->getSourceRange(); } break; } } } } } } void reportAssociatingFunctions(Decl* decl) { std::vector affected; // enum/class/class template + recursively affected members computeAffectedTypes(decl, &affected); reportAssociatingFunctions(affected, decl); } bool handleDeclaration(NamedDecl* decl) { if (ignoreLocation(decl)) { return true; } if (decl->getLinkageInternal() < compat::Linkage::Module) { return true; } // In some cases getLinkageInternal() arguably wrongly reports ExternalLinkage, see the // commit message of "DR1113: anonymous namespaces formally give // their contents internal linkage": // // "We still deviate from the standard in one regard here: extern "C" declarations // in anonymous namespaces are still granted external linkage. Changing those does // not appear to have been an intentional consequence of the standard change in // DR1113." // // Do not warn about such "wrongly external" declarations here: if (decl->isInAnonymousNamespace()) { return true; } for (Decl const* d = decl; d != nullptr; d = d->getPreviousDecl()) { if (!compiler.getSourceManager().isInMainFile(d->getLocation())) { return true; } } if (compiler.getSourceManager().isMacroBodyExpansion(decl->getLocation())) { if (Lexer::getImmediateMacroName(decl->getLocation(), compiler.getSourceManager(), compiler.getLangOpts()) == "MDDS_MTV_DEFINE_ELEMENT_CALLBACKS") { // Even wrapping in an unnamed namespace or sneaking "static" into the macro // wouldn't help, as then some of the functions it defines would be flagged as // unused: return true; } } else if (compiler.getSourceManager().isMacroArgExpansion(decl->getLocation())) { if (Lexer::getImmediateMacroName(decl->getLocation(), compiler.getSourceManager(), compiler.getLangOpts()) == "DEFINE_GUID") { // Windows, guiddef.h: return true; } } TypedefNameDecl const* typedefed = nullptr; if (auto const d = dyn_cast(decl)) { typedefed = d->getTypedefNameForAnonDecl(); } bool canStatic; if (auto const d = dyn_cast(decl)) { canStatic = d->isUnion() && d->isAnonymousStructOrUnion(); } else { canStatic = isa(decl) || isa(decl) || isa(decl) || isa(decl); } // In general, moving functions into an unnamed namespace can: break ADL like in // // struct S1 { int f() { return 1; } }; // int f(S1 s) { return s.f(); } // namespace N { // struct S2: S1 { int f() { return 0; } }; // int f(S2 s) { return s.f(); } // [*] // } // int main() { return f(N::S2()); } // // changing from returning 0 to returning 1 when [*] is moved into an unnamed namespace; can // conflict with function declarations in the moved function like in // // int f(int) { return 0; } // namespace { int f(int) { return 1; } } // int g() { // [*] // int f(int); // return f(0); // } // int main() { return g(); } // // changing from returning 0 to returning 1 when [*] is moved into an unnamed namespace; and // can conflict with overload resolution in general like in // // int f(int) { return 0; } // namespace { int f(...) { return 1; } } // int g() { return f(0); } // [*] // int main() { return g(); } // // changing from returning 0 to returning 1 when [*] is moved into an unnamed namespace: auto const canUnnamed = compiler.getLangOpts().CPlusPlus && !(isa(decl) || isa(decl)); assert(canStatic || canUnnamed); report( DiagnosticsEngine::Warning, ("externally available%select{| typedef'ed}0 entity %1 is not previously declared in an" " included file (if it is only used in this translation unit," " %select{|make it static}2%select{| or }3%select{|put it in an unnamed namespace}4;" " otherwise, provide a declaration of it in an included file)"), decl->getLocation()) << (typedefed != nullptr) << (typedefed == nullptr ? decl : typedefed) << canStatic << (canStatic && canUnnamed) << canUnnamed << decl->getSourceRange(); for (auto d = decl->redecls_begin(); d != decl->redecls_end(); ++d) { if (*d == decl) { continue; } report(DiagnosticsEngine::Note, "another declaration is here", d->getLocation()) << d->getSourceRange(); } //TODO: Class template specializations can be in the enclosing namespace, so no need to // list them here (as they won't need to be put into the unnamed namespace too, unlike for // specializations of function and variable templates); and explicit function template // specializations cannot have storage-class specifiers, so as we only suggest to make // function templates static (but not to move them into an unnamed namespace), no need to // list function template specializations here, either: if (auto const d = dyn_cast(decl)) { reportSpecializations(d->specializations()); } if (isa(decl) || isa(decl)) { reportAssociatingFunctions(decl); } return true; } }; loplugin::Plugin::Registration external("external"); } // namespace #endif // LO_CLANG_SHARED_PLUGINS /* vim:set shiftwidth=4 softtabstop=4 expandtab cinoptions=b1,g0,N-s cinkeys+=0=break: */