/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */ /* * 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/. */ #include #include #include #include #include #include "clang/AST/Attr.h" #include "clang/Basic/Builtins.h" #include "config_clang.h" #include "check.hxx" #include "compat.hxx" #include "functionaddress.hxx" #include "plugin.hxx" namespace { enum FakeBoolKind { FBK_No, FBK_BOOL, FBK_First = FBK_BOOL, FBK_Boolean, FBK_FT_Bool, FBK_FcBool, FBK_GLboolean, FBK_NPBool, FBK_TW_BOOL, FBK_UBool, FBK_boolean, FBK_dbus_bool_t, FBK_gboolean, FBK_hb_boot_t, FBK_jboolean, FBK_my_bool, FBK_sal_Bool, FBK_End }; // matches loplugin::TypeCheck::AnyBoolean (compilerplugins/clang/check.hxx) StringRef getName(FakeBoolKind k) { static constexpr llvm::StringLiteral names[] = { "BOOL", "Boolean", "FT_Bool", "FcBool", "GLboolean", "NPBool", "TW_BOOL", "UBool", "boolean", "dbus_bool_t", "gboolean", "hb_boot_t", "jboolean", "my_bool", "sal_Bool"}; assert(k >= FBK_First && k < FBK_End); return names[k - FBK_First]; } FakeBoolKind isFakeBool(QualType type) { TypedefType const * t = type->getAs(); if (t != nullptr) { auto const name = t->getDecl()->getName(); for (int i = FBK_First; i != FBK_End; ++i) { auto const k = FakeBoolKind(i); if (name == getName(k)) { return k; } } } return FBK_No; } FakeBoolKind isFakeBoolArray(QualType type) { auto t = type->getAsArrayTypeUnsafe(); if (t == nullptr) { return FBK_No; } auto const k = isFakeBool(t->getElementType()); if (k != FBK_No) { return k; } return isFakeBoolArray(t->getElementType()); } // It appears that, given a function declaration, there is no way to determine // the language linkage of the function's type, only of the function's name // (via FunctionDecl::isExternC); however, in a case like // // extern "C" { static void f(); } // // the function's name does not have C language linkage while the function's // type does (as clarified in C++11 [decl.link]); cf. // "Language linkage of function type": bool hasCLanguageLinkageType(FunctionDecl const * decl) { assert(decl != nullptr); if (decl->isExternC()) { return true; } if (decl->isInExternCContext()) { return true; } return false; } enum class OverrideKind { NO, YES, MAYBE }; OverrideKind getOverrideKind(FunctionDecl const * decl) { CXXMethodDecl const * m = dyn_cast(decl); if (m == nullptr) { return OverrideKind::NO; } if (m->size_overridden_methods() != 0 || m->hasAttr()) { return OverrideKind::YES; } if (!dyn_cast(m->getDeclContext())->hasAnyDependentBases()) { return OverrideKind::NO; } return OverrideKind::MAYBE; } enum class BoolOverloadKind { No, Yes, CheckNext }; BoolOverloadKind isBoolOverloadOf( FunctionDecl const * f, FunctionDecl const * decl, bool mustBeDeleted) { if (!mustBeDeleted || f->isDeleted()) { unsigned n = decl->getNumParams(); if (f->getNumParams() == n) { bool hasFB = false; for (unsigned i = 0; i != n; ++i) { QualType t1 { decl->getParamDecl(i)->getType() }; bool isFB = isFakeBool(t1) != FBK_No; bool isFBRef = !isFB && t1->isReferenceType() && isFakeBool(t1.getNonReferenceType()) != FBK_No; QualType t2 { f->getParamDecl(i)->getType() }; if (!(isFB ? t2->isBooleanType() : isFBRef ? (t2->isReferenceType() && t2.getNonReferenceType()->isBooleanType()) : t2.getCanonicalType() == t1.getCanonicalType())) { return BoolOverloadKind::CheckNext; } hasFB |= isFB || isFBRef; } return hasFB ? BoolOverloadKind::Yes : BoolOverloadKind::No; // cheaply protect against the case where decl would have no // fake bool parameters at all and would match itself } } return BoolOverloadKind::CheckNext; } //TODO: current implementation is not at all general, just tests what we // encounter in practice: bool hasBoolOverload(FunctionDecl const * decl, bool mustBeDeleted) { auto ctx = decl->getDeclContext(); if (!ctx->isLookupContext()) { return false; } auto res = ctx->lookup(decl->getDeclName()); for (auto d = res.begin(); d != res.end(); ++d) { if (auto f = dyn_cast(*d)) { switch (isBoolOverloadOf(f, decl, mustBeDeleted)) { case BoolOverloadKind::No: return false; case BoolOverloadKind::Yes: return true; case BoolOverloadKind::CheckNext: break; } } else if (auto ftd = dyn_cast(*d)) { for (auto f: ftd->specializations()) { if (f->getTemplateSpecializationKind() == TSK_ExplicitSpecialization) { switch (isBoolOverloadOf(f, decl, mustBeDeleted)) { case BoolOverloadKind::No: return false; case BoolOverloadKind::Yes: return true; case BoolOverloadKind::CheckNext: break; } } } } } return false; } class FakeBool: public loplugin::FunctionAddress> { public: explicit FakeBool(loplugin::InstantiationData const & data): FunctionAddress(data) {} virtual void run() override; bool VisitUnaryOperator(UnaryOperator * op); bool VisitCallExpr(CallExpr * expr); bool VisitCStyleCastExpr(CStyleCastExpr * expr); bool VisitCXXStaticCastExpr(CXXStaticCastExpr * expr); bool VisitCXXFunctionalCastExpr(CXXFunctionalCastExpr * expr); bool VisitImplicitCastExpr(ImplicitCastExpr * expr); bool VisitReturnStmt(ReturnStmt const * stmt); bool WalkUpFromParmVarDecl(ParmVarDecl const * decl); bool VisitParmVarDecl(ParmVarDecl const * decl); bool WalkUpFromVarDecl(VarDecl const * decl); bool VisitVarDecl(VarDecl const * decl); bool WalkUpFromFieldDecl(FieldDecl const * decl); bool VisitFieldDecl(FieldDecl const * decl); bool WalkUpFromFunctionDecl(FunctionDecl const * decl); bool VisitFunctionDecl(FunctionDecl const * decl); bool VisitValueDecl(ValueDecl const * decl); bool TraverseLinkageSpecDecl(LinkageSpecDecl * decl); private: bool isFromCIncludeFile(SourceLocation spellingLocation) const; bool isSharedCAndCppCode(SourceLocation location) const; bool rewrite(SourceLocation location, FakeBoolKind kind); std::map varDecls_; std::map fieldDecls_; std::map parmVarDecls_; std::map functionDecls_; unsigned int externCContexts_ = 0; }; void FakeBool::run() { if (compiler.getLangOpts().CPlusPlus) { TraverseDecl(compiler.getASTContext().getTranslationUnitDecl()); for (auto const & dcl: varDecls_) { auto const decl = dcl.first; auto const fbk = dcl.second; SourceLocation loc { decl->getBeginLoc() }; TypeSourceInfo * tsi = decl->getTypeSourceInfo(); if (tsi != nullptr) { SourceLocation l { compiler.getSourceManager().getExpansionLoc( tsi->getTypeLoc().getBeginLoc()) }; SourceLocation end { compiler.getSourceManager().getExpansionLoc( tsi->getTypeLoc().getEndLoc()) }; assert(l.isFileID() && end.isFileID()); if (l == end || compiler.getSourceManager().isBeforeInTranslationUnit( l, end)) { for (;;) { unsigned n = Lexer::MeasureTokenLength( l, compiler.getSourceManager(), compiler.getLangOpts()); std::string s { compiler.getSourceManager().getCharacterData(l), n }; if (s == getName(fbk)) { loc = l; break; } if (l == end) { break; } l = l.getLocWithOffset(std::max(n, 1)); } } } if (!(suppressWarningAt(loc) || rewrite(loc, fbk))) { report( DiagnosticsEngine::Warning, "VarDecl, use \"bool\" instead of %0", loc) << decl->getType().getLocalUnqualifiedType() << decl->getSourceRange(); } } for (auto const & dcl: fieldDecls_) { auto const decl = dcl.first; auto const fbk = dcl.second; SourceLocation loc { decl->getBeginLoc() }; TypeSourceInfo * tsi = decl->getTypeSourceInfo(); if (tsi != nullptr) { SourceLocation l { compiler.getSourceManager().getExpansionLoc( tsi->getTypeLoc().getBeginLoc()) }; SourceLocation end { compiler.getSourceManager().getExpansionLoc( tsi->getTypeLoc().getEndLoc()) }; assert(l.isFileID() && end.isFileID()); if (l == end || compiler.getSourceManager().isBeforeInTranslationUnit( l, end)) { for (;;) { unsigned n = Lexer::MeasureTokenLength( l, compiler.getSourceManager(), compiler.getLangOpts()); std::string s { compiler.getSourceManager().getCharacterData(l), n }; if (s == getName(fbk)) { loc = l; break; } if (l == end) { break; } l = l.getLocWithOffset(std::max(n, 1)); } } } if (!(suppressWarningAt(loc) || rewrite(loc, fbk))) { report( DiagnosticsEngine::Warning, "FieldDecl, use \"bool\" instead of %0", loc) << decl->getType().getLocalUnqualifiedType() << decl->getSourceRange(); } } auto const ignoredFns = getFunctionsWithAddressTaken(); for (auto const & dcl: parmVarDecls_) { auto const decl = dcl.first; auto const fbk = dcl.second; FunctionDecl const * f = cast(decl->getDeclContext())->getCanonicalDecl(); if (ignoredFns.find(f) != ignoredFns.end()) { continue; } SourceLocation loc { decl->getBeginLoc() }; TypeSourceInfo * tsi = decl->getTypeSourceInfo(); if (tsi != nullptr) { SourceLocation l { compiler.getSourceManager().getExpansionLoc( tsi->getTypeLoc().getBeginLoc()) }; SourceLocation end { compiler.getSourceManager().getExpansionLoc( tsi->getTypeLoc().getEndLoc()) }; assert(l.isFileID() && end.isFileID()); if (l == end || (compiler.getSourceManager() .isBeforeInTranslationUnit(l, end))) { for (;;) { unsigned n = Lexer::MeasureTokenLength( l, compiler.getSourceManager(), compiler.getLangOpts()); std::string s { compiler.getSourceManager().getCharacterData(l), n }; if (s == getName(fbk)) { loc = l; break; } if (l == end) { break; } l = l.getLocWithOffset(std::max(n, 1)); } } } // Only rewrite declarations in include files if a // definition is also seen, to avoid compilation of a // definition (in a main file only processed later) to fail // with a "mismatch" error before the rewriter had a chance // to act upon the definition (but use the heuristic of // assuming pure virtual functions do not have definitions); // also, do not automatically rewrite functions that could // implicitly override depend base functions (and thus stop // doing so after the rewrite; note that this is less // dangerous for return types than for parameter types, // where the function would still implicitly override and // cause a compilation error due to the incompatible return // type): OverrideKind k = getOverrideKind(f); if (!((compiler.getSourceManager().isInMainFile( compiler.getSourceManager().getSpellingLoc( dyn_cast( decl->getDeclContext()) ->getNameInfo().getLoc())) || f->isDefined() || compat::isPureVirtual(f)) && k != OverrideKind::MAYBE && rewrite(loc, fbk))) { report( DiagnosticsEngine::Warning, ("ParmVarDecl, use \"bool\" instead of" " %0%1"), loc) << decl->getType().getNonReferenceType().getLocalUnqualifiedType() << (k == OverrideKind::MAYBE ? (" (unless this member function overrides a" " dependent base member function, even" " though it is not marked 'override')") : "") << decl->getSourceRange(); } } for (auto const & dcl: functionDecls_) { auto const decl = dcl.first; auto const fbk = dcl.second; FunctionDecl const * f = decl->getCanonicalDecl(); if (ignoredFns.find(f) != ignoredFns.end()) { continue; } SourceLocation loc { decl->getBeginLoc() }; SourceLocation l { compiler.getSourceManager().getExpansionLoc( loc) }; SourceLocation end { compiler.getSourceManager().getExpansionLoc( decl->getNameInfo().getLoc()) }; assert(l.isFileID() && end.isFileID()); if (compiler.getSourceManager().isBeforeInTranslationUnit(l, end)) { while (l != end) { unsigned n = Lexer::MeasureTokenLength( l, compiler.getSourceManager(), compiler.getLangOpts()); std::string s { compiler.getSourceManager().getCharacterData(l), n }; if (s == getName(fbk)) { loc = l; break; } l = l.getLocWithOffset(std::max(n, 1)); } } // Only rewrite declarations in include files if a definition is // also seen, to avoid compilation of a definition (in a main file // only processed later) to fail with a "mismatch" error before the // rewriter had a chance to act upon the definition (but use the // heuristic of assuming pure virtual functions do not have // definitions): if (!((compiler.getSourceManager().isInMainFile( compiler.getSourceManager().getSpellingLoc( decl->getNameInfo().getLoc())) || f->isDefined() || compat::isPureVirtual(f)) && rewrite(loc, fbk))) { report( DiagnosticsEngine::Warning, "use \"bool\" instead of %0 as return type%1", loc) << decl->getReturnType().getNonReferenceType().getLocalUnqualifiedType() << (getOverrideKind(f) == OverrideKind::MAYBE ? (" (unless this member function overrides a dependent" " base member function, even though it is not marked" " 'override')") : "") << decl->getSourceRange(); } } } } bool FakeBool::VisitUnaryOperator(UnaryOperator * op) { if (op->getOpcode() != UO_AddrOf) { return FunctionAddress::VisitUnaryOperator(op); } FunctionAddress::VisitUnaryOperator(op); Expr const * e1 = op->getSubExpr()->IgnoreParenCasts(); if (isFakeBool(e1->getType()) != FBK_No) { if (DeclRefExpr const * e2 = dyn_cast(e1)) { if (auto const d = dyn_cast(e2->getDecl())) { varDecls_.erase(d); } else if (auto const d = dyn_cast(e2->getDecl())) { fieldDecls_.erase(d); } } else if (auto const e3 = dyn_cast(e1)) { if (auto const d = dyn_cast(e3->getMemberDecl())) { fieldDecls_.erase(d); } } } return true; } bool FakeBool::VisitCallExpr(CallExpr * expr) { Decl const * d = expr->getCalleeDecl(); FunctionProtoType const * ft = nullptr; if (d != nullptr) { FunctionDecl const * fd = dyn_cast(d); if (fd != nullptr) { if (!hasBoolOverload(fd, false)) { clang::PointerType const * pt = fd->getType() ->getAs(); QualType t2( pt == nullptr ? fd->getType() : pt->getPointeeType()); ft = t2->getAs(); assert( ft != nullptr || !compiler.getLangOpts().CPlusPlus || (fd->getBuiltinID() != Builtin::NotBuiltin && isa(t2))); // __builtin_*s have no proto type? } } else { VarDecl const * vd = dyn_cast(d); if (vd != nullptr) { clang::PointerType const * pt = vd->getType() ->getAs(); ft = (pt == nullptr ? vd->getType() : pt->getPointeeType()) ->getAs(); } } } if (ft != nullptr) { for (unsigned i = 0; i != ft->getNumParams(); ++i) { QualType t(ft->getParamType(i)); bool b = false; if (t->isLValueReferenceType()) { t = t.getNonReferenceType(); b = !t.isConstQualified() && isFakeBool(t) != FBK_No; } else if (t->isPointerType()) { for (;;) { auto t2 = t->getAs(); if (t2 == nullptr) { break; } t = t2->getPointeeType(); } b = isFakeBool(t) != FBK_No; } if (b && i < expr->getNumArgs()) { auto const e1 = expr->getArg(i)->IgnoreParenImpCasts(); if (DeclRefExpr * ref = dyn_cast(e1)) { VarDecl const * d = dyn_cast(ref->getDecl()); if (d != nullptr) { varDecls_.erase(d); } } else if (auto const e2 = dyn_cast(e1)) { if (auto const d = dyn_cast(e2->getMemberDecl())) { fieldDecls_.erase(d); } } } } } return true; } bool FakeBool::VisitCStyleCastExpr(CStyleCastExpr * expr) { if (ignoreLocation(expr)) { return true; } auto const k = isFakeBool(expr->getType()); if (k != FBK_No) { SourceLocation loc { expr->getBeginLoc() }; while (compiler.getSourceManager().isMacroArgExpansion(loc)) { loc = compiler.getSourceManager().getImmediateMacroCallerLoc(loc); } if (compiler.getSourceManager().isMacroBodyExpansion(loc)) { StringRef name { Lexer::getImmediateMacroName( loc, compiler.getSourceManager(), compiler.getLangOpts()) }; if (k == FBK_sal_Bool && (name == "sal_False" || name == "sal_True")) { auto callLoc = compiler.getSourceManager() .getImmediateMacroCallerLoc(loc); if (!isSharedCAndCppCode(callLoc)) { SourceLocation argLoc; if (compiler.getSourceManager().isMacroArgExpansion( expr->getBeginLoc(), &argLoc) //TODO: check it's the complete (first) arg to the macro && (Lexer::getImmediateMacroName( argLoc, compiler.getSourceManager(), compiler.getLangOpts()) == "CPPUNIT_ASSERT_EQUAL")) { // Ignore sal_False/True that are directly used as // arguments to CPPUNIT_ASSERT_EQUAL: return true; } if (suppressWarningAt(callLoc)) { return true; } bool b = k == FBK_sal_Bool && name == "sal_True"; if (rewriter != nullptr) { auto callSpellLoc = compiler.getSourceManager() .getSpellingLoc(callLoc); unsigned n = Lexer::MeasureTokenLength( callSpellLoc, compiler.getSourceManager(), compiler.getLangOpts()); if (StringRef( compiler.getSourceManager().getCharacterData( callSpellLoc), n) == name) { return replaceText( callSpellLoc, n, b ? "true" : "false"); } } report( DiagnosticsEngine::Warning, "use '%select{false|true}0' instead of '%1'", callLoc) << b << name << expr->getSourceRange(); } return true; } if (isSharedCAndCppCode(loc)) { return true; } } report( DiagnosticsEngine::Warning, "CStyleCastExpr, suspicious cast from %0 to %1", expr->getBeginLoc()) << expr->getSubExpr()->IgnoreParenImpCasts()->getType() << expr->getType() << expr->getSourceRange(); } return true; } bool FakeBool::VisitCXXStaticCastExpr(CXXStaticCastExpr * expr) { if (ignoreLocation(expr)) { return true; } if (isFakeBool(expr->getType()) == FBK_No) { return true; } if (suppressWarningAt(expr->getBeginLoc())) { return true; } report( DiagnosticsEngine::Warning, "CXXStaticCastExpr, suspicious cast from %0 to %1", expr->getBeginLoc()) << expr->getSubExpr()->IgnoreParenImpCasts()->getType() << expr->getType() << expr->getSourceRange(); return true; } bool FakeBool::VisitCXXFunctionalCastExpr(CXXFunctionalCastExpr * expr) { if (ignoreLocation(expr)) { return true; } if (isFakeBool(expr->getType()) != FBK_No) { report( DiagnosticsEngine::Warning, "CXXFunctionalCastExpr, suspicious cast from %0 to %1", expr->getBeginLoc()) << expr->getSubExpr()->IgnoreParenImpCasts()->getType() << expr->getType() << expr->getSourceRange(); } return true; } bool FakeBool::VisitImplicitCastExpr(ImplicitCastExpr * expr) { FunctionAddress::VisitImplicitCastExpr(expr); if (ignoreLocation(expr)) { return true; } if (isFakeBool(expr->getType()) == FBK_No) { return true; } auto l = expr->getBeginLoc(); while (compiler.getSourceManager().isMacroArgExpansion(l)) { l = compiler.getSourceManager().getImmediateMacroCallerLoc(l); } if (compiler.getSourceManager().isMacroBodyExpansion(l) && isSharedCAndCppCode(l)) { return true; } auto e1 = expr->getSubExprAsWritten(); auto t = e1->getType(); if (!t->isFundamentalType() || loplugin::TypeCheck(t).AnyBoolean()) { return true; } auto e2 = dyn_cast(e1); if (e2 != nullptr) { auto ic1 = dyn_cast( e2->getTrueExpr()->IgnoreParens()); auto ic2 = dyn_cast( e2->getFalseExpr()->IgnoreParens()); if (ic1 != nullptr && ic2 != nullptr && ic1->getType()->isSpecificBuiltinType(BuiltinType::Int) && (loplugin::TypeCheck(ic1->getSubExprAsWritten()->getType()) .AnyBoolean()) && ic2->getType()->isSpecificBuiltinType(BuiltinType::Int) && (loplugin::TypeCheck(ic2->getSubExprAsWritten()->getType()) .AnyBoolean())) { return true; } } report( DiagnosticsEngine::Warning, "conversion from %0 to %1", expr->getBeginLoc()) << t << expr->getType() << expr->getSourceRange(); return true; } bool FakeBool::VisitReturnStmt(ReturnStmt const * stmt) { // Just enough to avoid warnings in rtl_getUriCharClass (sal/rtl/uri.cxx), // which has // // static sal_Bool const aCharClass[][nCharClassSize] = ...; // // and // // return aCharClass[eCharClass]; // if (ignoreLocation(stmt)) { return true; } auto e = stmt->getRetValue(); if (e == nullptr) { return true; } auto t = e->getType(); if (!t->isPointerType()) { return true; } for (;;) { auto t2 = t->getAs(); if (t2 == nullptr) { break; } t = t2->getPointeeType(); } if (isFakeBool(t) != FBK_sal_Bool) { return true; } auto e2 = dyn_cast(e->IgnoreParenImpCasts()); if (e2 == nullptr) { return true; } auto e3 = dyn_cast(e2->getBase()->IgnoreParenImpCasts()); if (e3 == nullptr) { return true; } auto d = dyn_cast(e3->getDecl()); if (d == nullptr) { return true; } varDecls_.erase(d); return true; } bool FakeBool::WalkUpFromParmVarDecl(ParmVarDecl const * decl) { return VisitParmVarDecl(decl); } bool FakeBool::VisitParmVarDecl(ParmVarDecl const * decl) { if (ignoreLocation(decl)) { return true; } auto const fbk = isFakeBool(decl->getType().getNonReferenceType()); if (fbk != FBK_No) { FunctionDecl const * f = dyn_cast(decl->getDeclContext()); if (f != nullptr) { // e.g.: typedef sal_Bool (* FuncPtr )( sal_Bool ); f = f->getCanonicalDecl(); if (handler.isAllRelevantCodeDefined(f) && !(hasCLanguageLinkageType(f) || (fbk == FBK_sal_Bool && isInUnoIncludeFile(f) && (!f->isInlined() || f->hasAttr() || decl->getType()->isReferenceType() || hasBoolOverload(f, false))) || f->isDeleted() || hasBoolOverload(f, true))) { OverrideKind k = getOverrideKind(f); if (k != OverrideKind::YES) { parmVarDecls_.insert({decl, fbk}); } } } } return true; } bool FakeBool::WalkUpFromVarDecl(VarDecl const * decl) { return VisitVarDecl(decl); } bool FakeBool::VisitVarDecl(VarDecl const * decl) { if (ignoreLocation(decl)) { return true; } if (decl->isExternC()) { return true; } auto k = isFakeBool(decl->getType()); if (k == FBK_No) { k = isFakeBoolArray(decl->getType()); } if (k == FBK_No) { return true; } auto l = decl->getBeginLoc(); while (compiler.getSourceManager().isMacroArgExpansion(l)) { l = compiler.getSourceManager().getImmediateMacroCallerLoc(l); } if (compiler.getSourceManager().isMacroBodyExpansion(l) && isSharedCAndCppCode(l)) { return true; } varDecls_.insert({decl, k}); return true; } bool FakeBool::WalkUpFromFieldDecl(FieldDecl const * decl) { return VisitFieldDecl(decl); } bool FakeBool::VisitFieldDecl(FieldDecl const * decl) { if (ignoreLocation(decl)) { return true; } auto k = isFakeBool(decl->getType()); if (k == FBK_No) { k = isFakeBoolArray(decl->getType()); } if (k == FBK_No) { return true; } if (!handler.isAllRelevantCodeDefined(decl)) { return true; } TagDecl const * td = dyn_cast(decl->getDeclContext()); if (td == nullptr) { //TODO: ObjCInterface return true; } if (!(((td->isStruct() || td->isUnion()) && td->isExternCContext()) || isInUnoIncludeFile( compiler.getSourceManager().getSpellingLoc( decl->getLocation())))) { fieldDecls_.insert({decl, k}); } return true; } bool FakeBool::WalkUpFromFunctionDecl(FunctionDecl const * decl) { return VisitFunctionDecl(decl); } bool FakeBool::VisitFunctionDecl(FunctionDecl const * decl) { if (ignoreLocation(decl)) { return true; } auto const fbk = isFakeBool(decl->getReturnType().getNonReferenceType()); if (fbk != FBK_No && !(decl->isDeletedAsWritten() && isa(decl)) && handler.isAllRelevantCodeDefined(decl)) { FunctionDecl const * f = decl->getCanonicalDecl(); OverrideKind k = getOverrideKind(f); if (k != OverrideKind::YES && !(hasCLanguageLinkageType(f) || (isInUnoIncludeFile(f) && (!f->isInlined() || f->hasAttr())))) { functionDecls_.insert({decl, fbk}); } } return true; } bool FakeBool::VisitValueDecl(ValueDecl const * decl) { if (ignoreLocation(decl)) { return true; } auto const k = isFakeBool(decl->getType()); if (k != FBK_No && !rewrite(decl->getBeginLoc(), k)) { report( DiagnosticsEngine::Warning, "ValueDecl, use \"bool\" instead of %0", decl->getBeginLoc()) << decl->getType() << decl->getSourceRange(); } return true; } bool FakeBool::TraverseLinkageSpecDecl(LinkageSpecDecl * decl) { assert(externCContexts_ != std::numeric_limits::max()); //TODO ++externCContexts_; bool ret = RecursiveASTVisitor::TraverseLinkageSpecDecl(decl); assert(externCContexts_ != 0); --externCContexts_; return ret; } bool FakeBool::isFromCIncludeFile(SourceLocation spellingLocation) const { return !compiler.getSourceManager().isInMainFile(spellingLocation) && compat::ends_with( StringRef(compiler.getSourceManager().getPresumedLoc(spellingLocation).getFilename()), ".h"); } bool FakeBool::isSharedCAndCppCode(SourceLocation location) const { // Assume that code is intended to be shared between C and C++ if it comes // from an include file ending in .h, and is either in an extern "C" context // or the body of a macro definition: return isFromCIncludeFile(compiler.getSourceManager().getSpellingLoc(location)) && (externCContexts_ != 0 || compiler.getSourceManager().isMacroBodyExpansion(location)); } bool FakeBool::rewrite(SourceLocation location, FakeBoolKind kind) { if (rewriter != nullptr) { //TODO: "::sal_Bool" -> "bool", not "::bool" SourceLocation loc { compiler.getSourceManager().getExpansionLoc( location) }; unsigned n = Lexer::MeasureTokenLength( loc, compiler.getSourceManager(), compiler.getLangOpts()); if (std::string(compiler.getSourceManager().getCharacterData(loc), n) == getName(kind)) { return replaceText(loc, n, "bool"); } } return false; } loplugin::Plugin::Registration X("fakebool", true); } /* vim:set shiftwidth=4 softtabstop=4 expandtab: */