//=-- ExprEngineCallAndReturn.cpp - Support for call/return -----*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file defines ExprEngine's support for calls and returns. // //===----------------------------------------------------------------------===// #include "clang/StaticAnalyzer/Core/PathSensitive/ExprEngine.h" #include "PrettyStackTraceLocationContext.h" #include "clang/AST/CXXInheritance.h" #include "clang/AST/DeclCXX.h" #include "clang/AST/ParentMap.h" #include "clang/Analysis/Analyses/LiveVariables.h" #include "clang/StaticAnalyzer/Core/CheckerManager.h" #include "clang/StaticAnalyzer/Core/PathSensitive/CallEvent.h" #include "llvm/ADT/SmallSet.h" #include "llvm/ADT/Statistic.h" #include "llvm/Support/SaveAndRestore.h" using namespace clang; using namespace ento; #define DEBUG_TYPE "ExprEngine" STATISTIC(NumOfDynamicDispatchPathSplits, "The # of times we split the path due to imprecise dynamic dispatch info"); STATISTIC(NumInlinedCalls, "The # of times we inlined a call"); STATISTIC(NumReachedInlineCountMax, "The # of times we reached inline count maximum"); void ExprEngine::processCallEnter(CallEnter CE, ExplodedNode *Pred) { // Get the entry block in the CFG of the callee. const StackFrameContext *calleeCtx = CE.getCalleeContext(); PrettyStackTraceLocationContext CrashInfo(calleeCtx); const CFG *CalleeCFG = calleeCtx->getCFG(); const CFGBlock *Entry = &(CalleeCFG->getEntry()); // Validate the CFG. assert(Entry->empty()); assert(Entry->succ_size() == 1); // Get the solitary successor. const CFGBlock *Succ = *(Entry->succ_begin()); // Construct an edge representing the starting location in the callee. BlockEdge Loc(Entry, Succ, calleeCtx); ProgramStateRef state = Pred->getState(); // Construct a new node and add it to the worklist. bool isNew; ExplodedNode *Node = G.getNode(Loc, state, false, &isNew); Node->addPredecessor(Pred, G); if (isNew) Engine.getWorkList()->enqueue(Node); } // Find the last statement on the path to the exploded node and the // corresponding Block. static std::pair getLastStmt(const ExplodedNode *Node) { const Stmt *S = nullptr; const CFGBlock *Blk = nullptr; const StackFrameContext *SF = Node->getLocation().getLocationContext()->getCurrentStackFrame(); // Back up through the ExplodedGraph until we reach a statement node in this // stack frame. while (Node) { const ProgramPoint &PP = Node->getLocation(); if (PP.getLocationContext()->getCurrentStackFrame() == SF) { if (Optional SP = PP.getAs()) { S = SP->getStmt(); break; } else if (Optional CEE = PP.getAs()) { S = CEE->getCalleeContext()->getCallSite(); if (S) break; // If there is no statement, this is an implicitly-generated call. // We'll walk backwards over it and then continue the loop to find // an actual statement. Optional CE; do { Node = Node->getFirstPred(); CE = Node->getLocationAs(); } while (!CE || CE->getCalleeContext() != CEE->getCalleeContext()); // Continue searching the graph. } else if (Optional BE = PP.getAs()) { Blk = BE->getSrc(); } } else if (Optional CE = PP.getAs()) { // If we reached the CallEnter for this function, it has no statements. if (CE->getCalleeContext() == SF) break; } if (Node->pred_empty()) return std::make_pair(nullptr, nullptr); Node = *Node->pred_begin(); } return std::make_pair(S, Blk); } /// Adjusts a return value when the called function's return type does not /// match the caller's expression type. This can happen when a dynamic call /// is devirtualized, and the overridding method has a covariant (more specific) /// return type than the parent's method. For C++ objects, this means we need /// to add base casts. static SVal adjustReturnValue(SVal V, QualType ExpectedTy, QualType ActualTy, StoreManager &StoreMgr) { // For now, the only adjustments we handle apply only to locations. if (!V.getAs()) return V; // If the types already match, don't do any unnecessary work. ExpectedTy = ExpectedTy.getCanonicalType(); ActualTy = ActualTy.getCanonicalType(); if (ExpectedTy == ActualTy) return V; // No adjustment is needed between Objective-C pointer types. if (ExpectedTy->isObjCObjectPointerType() && ActualTy->isObjCObjectPointerType()) return V; // C++ object pointers may need "derived-to-base" casts. const CXXRecordDecl *ExpectedClass = ExpectedTy->getPointeeCXXRecordDecl(); const CXXRecordDecl *ActualClass = ActualTy->getPointeeCXXRecordDecl(); if (ExpectedClass && ActualClass) { CXXBasePaths Paths(/*FindAmbiguities=*/true, /*RecordPaths=*/true, /*DetectVirtual=*/false); if (ActualClass->isDerivedFrom(ExpectedClass, Paths) && !Paths.isAmbiguous(ActualTy->getCanonicalTypeUnqualified())) { return StoreMgr.evalDerivedToBase(V, Paths.front()); } } // Unfortunately, Objective-C does not enforce that overridden methods have // covariant return types, so we can't assert that that never happens. // Be safe and return UnknownVal(). return UnknownVal(); } void ExprEngine::removeDeadOnEndOfFunction(NodeBuilderContext& BC, ExplodedNode *Pred, ExplodedNodeSet &Dst) { // Find the last statement in the function and the corresponding basic block. const Stmt *LastSt = nullptr; const CFGBlock *Blk = nullptr; std::tie(LastSt, Blk) = getLastStmt(Pred); if (!Blk || !LastSt) { Dst.Add(Pred); return; } // Here, we destroy the current location context. We use the current // function's entire body as a diagnostic statement, with which the program // point will be associated. However, we only want to use LastStmt as a // reference for what to clean up if it's a ReturnStmt; otherwise, everything // is dead. SaveAndRestore NodeContextRAII(currBldrCtx, &BC); const LocationContext *LCtx = Pred->getLocationContext(); removeDead(Pred, Dst, dyn_cast(LastSt), LCtx, LCtx->getAnalysisDeclContext()->getBody(), ProgramPoint::PostStmtPurgeDeadSymbolsKind); } static bool wasDifferentDeclUsedForInlining(CallEventRef<> Call, const StackFrameContext *calleeCtx) { const Decl *RuntimeCallee = calleeCtx->getDecl(); const Decl *StaticDecl = Call->getDecl(); assert(RuntimeCallee); if (!StaticDecl) return true; return RuntimeCallee->getCanonicalDecl() != StaticDecl->getCanonicalDecl(); } /// Returns true if the CXXConstructExpr \p E was intended to construct a /// prvalue for the region in \p V. /// /// Note that we can't just test for rvalue vs. glvalue because /// CXXConstructExprs embedded in DeclStmts and initializers are considered /// rvalues by the AST, and the analyzer would like to treat them as lvalues. static bool isTemporaryPRValue(const CXXConstructExpr *E, SVal V) { if (E->isGLValue()) return false; const MemRegion *MR = V.getAsRegion(); if (!MR) return false; return isa(MR); } /// The call exit is simulated with a sequence of nodes, which occur between /// CallExitBegin and CallExitEnd. The following operations occur between the /// two program points: /// 1. CallExitBegin (triggers the start of call exit sequence) /// 2. Bind the return value /// 3. Run Remove dead bindings to clean up the dead symbols from the callee. /// 4. CallExitEnd (switch to the caller context) /// 5. PostStmt void ExprEngine::processCallExit(ExplodedNode *CEBNode) { // Step 1 CEBNode was generated before the call. PrettyStackTraceLocationContext CrashInfo(CEBNode->getLocationContext()); const StackFrameContext *calleeCtx = CEBNode->getLocationContext()->getCurrentStackFrame(); // The parent context might not be a stack frame, so make sure we // look up the first enclosing stack frame. const StackFrameContext *callerCtx = calleeCtx->getParent()->getCurrentStackFrame(); const Stmt *CE = calleeCtx->getCallSite(); ProgramStateRef state = CEBNode->getState(); // Find the last statement in the function and the corresponding basic block. const Stmt *LastSt = nullptr; const CFGBlock *Blk = nullptr; std::tie(LastSt, Blk) = getLastStmt(CEBNode); // Generate a CallEvent /before/ cleaning the state, so that we can get the // correct value for 'this' (if necessary). CallEventManager &CEMgr = getStateManager().getCallEventManager(); CallEventRef<> Call = CEMgr.getCaller(calleeCtx, state); // Step 2: generate node with bound return value: CEBNode -> BindedRetNode. // If the callee returns an expression, bind its value to CallExpr. if (CE) { if (const ReturnStmt *RS = dyn_cast_or_null(LastSt)) { const LocationContext *LCtx = CEBNode->getLocationContext(); SVal V = state->getSVal(RS, LCtx); // Ensure that the return type matches the type of the returned Expr. if (wasDifferentDeclUsedForInlining(Call, calleeCtx)) { QualType ReturnedTy = CallEvent::getDeclaredResultType(calleeCtx->getDecl()); if (!ReturnedTy.isNull()) { if (const Expr *Ex = dyn_cast(CE)) { V = adjustReturnValue(V, Ex->getType(), ReturnedTy, getStoreManager()); } } } state = state->BindExpr(CE, callerCtx, V); } // Bind the constructed object value to CXXConstructExpr. if (const CXXConstructExpr *CCE = dyn_cast(CE)) { loc::MemRegionVal This = svalBuilder.getCXXThis(CCE->getConstructor()->getParent(), calleeCtx); SVal ThisV = state->getSVal(This); // If the constructed object is a temporary prvalue, get its bindings. if (isTemporaryPRValue(CCE, ThisV)) ThisV = state->getSVal(ThisV.castAs()); state = state->BindExpr(CCE, callerCtx, ThisV); } } // Step 3: BindedRetNode -> CleanedNodes // If we can find a statement and a block in the inlined function, run remove // dead bindings before returning from the call. This is important to ensure // that we report the issues such as leaks in the stack contexts in which // they occurred. ExplodedNodeSet CleanedNodes; if (LastSt && Blk && AMgr.options.AnalysisPurgeOpt != PurgeNone) { static SimpleProgramPointTag retValBind("ExprEngine", "Bind Return Value"); PostStmt Loc(LastSt, calleeCtx, &retValBind); bool isNew; ExplodedNode *BindedRetNode = G.getNode(Loc, state, false, &isNew); BindedRetNode->addPredecessor(CEBNode, G); if (!isNew) return; NodeBuilderContext Ctx(getCoreEngine(), Blk, BindedRetNode); currBldrCtx = &Ctx; // Here, we call the Symbol Reaper with 0 statement and callee location // context, telling it to clean up everything in the callee's context // (and its children). We use the callee's function body as a diagnostic // statement, with which the program point will be associated. removeDead(BindedRetNode, CleanedNodes, nullptr, calleeCtx, calleeCtx->getAnalysisDeclContext()->getBody(), ProgramPoint::PostStmtPurgeDeadSymbolsKind); currBldrCtx = nullptr; } else { CleanedNodes.Add(CEBNode); } for (ExplodedNodeSet::iterator I = CleanedNodes.begin(), E = CleanedNodes.end(); I != E; ++I) { // Step 4: Generate the CallExit and leave the callee's context. // CleanedNodes -> CEENode CallExitEnd Loc(calleeCtx, callerCtx); bool isNew; ProgramStateRef CEEState = (*I == CEBNode) ? state : (*I)->getState(); ExplodedNode *CEENode = G.getNode(Loc, CEEState, false, &isNew); CEENode->addPredecessor(*I, G); if (!isNew) return; // Step 5: Perform the post-condition check of the CallExpr and enqueue the // result onto the work list. // CEENode -> Dst -> WorkList NodeBuilderContext Ctx(Engine, calleeCtx->getCallSiteBlock(), CEENode); SaveAndRestore NBCSave(currBldrCtx, &Ctx); SaveAndRestore CBISave(currStmtIdx, calleeCtx->getIndex()); CallEventRef<> UpdatedCall = Call.cloneWithState(CEEState); ExplodedNodeSet DstPostCall; getCheckerManager().runCheckersForPostCall(DstPostCall, CEENode, *UpdatedCall, *this, /*WasInlined=*/true); ExplodedNodeSet Dst; if (const ObjCMethodCall *Msg = dyn_cast(Call)) { getCheckerManager().runCheckersForPostObjCMessage(Dst, DstPostCall, *Msg, *this, /*WasInlined=*/true); } else if (CE) { getCheckerManager().runCheckersForPostStmt(Dst, DstPostCall, CE, *this, /*WasInlined=*/true); } else { Dst.insert(DstPostCall); } // Enqueue the next element in the block. for (ExplodedNodeSet::iterator PSI = Dst.begin(), PSE = Dst.end(); PSI != PSE; ++PSI) { Engine.getWorkList()->enqueue(*PSI, calleeCtx->getCallSiteBlock(), calleeCtx->getIndex()+1); } } } void ExprEngine::examineStackFrames(const Decl *D, const LocationContext *LCtx, bool &IsRecursive, unsigned &StackDepth) { IsRecursive = false; StackDepth = 0; while (LCtx) { if (const StackFrameContext *SFC = dyn_cast(LCtx)) { const Decl *DI = SFC->getDecl(); // Mark recursive (and mutually recursive) functions and always count // them when measuring the stack depth. if (DI == D) { IsRecursive = true; ++StackDepth; LCtx = LCtx->getParent(); continue; } // Do not count the small functions when determining the stack depth. AnalysisDeclContext *CalleeADC = AMgr.getAnalysisDeclContext(DI); const CFG *CalleeCFG = CalleeADC->getCFG(); if (CalleeCFG->getNumBlockIDs() > AMgr.options.getAlwaysInlineSize()) ++StackDepth; } LCtx = LCtx->getParent(); } } static bool IsInStdNamespace(const FunctionDecl *FD) { const DeclContext *DC = FD->getEnclosingNamespaceContext(); const NamespaceDecl *ND = dyn_cast(DC); if (!ND) return false; while (const DeclContext *Parent = ND->getParent()) { if (!isa(Parent)) break; ND = cast(Parent); } return ND->isStdNamespace(); } // The GDM component containing the dynamic dispatch bifurcation info. When // the exact type of the receiver is not known, we want to explore both paths - // one on which we do inline it and the other one on which we don't. This is // done to ensure we do not drop coverage. // This is the map from the receiver region to a bool, specifying either we // consider this region's information precise or not along the given path. namespace { enum DynamicDispatchMode { DynamicDispatchModeInlined = 1, DynamicDispatchModeConservative }; } REGISTER_TRAIT_WITH_PROGRAMSTATE(DynamicDispatchBifurcationMap, CLANG_ENTO_PROGRAMSTATE_MAP(const MemRegion *, unsigned)) bool ExprEngine::inlineCall(const CallEvent &Call, const Decl *D, NodeBuilder &Bldr, ExplodedNode *Pred, ProgramStateRef State) { assert(D); const LocationContext *CurLC = Pred->getLocationContext(); const StackFrameContext *CallerSFC = CurLC->getCurrentStackFrame(); const LocationContext *ParentOfCallee = CallerSFC; if (Call.getKind() == CE_Block) { const BlockDataRegion *BR = cast(Call).getBlockRegion(); assert(BR && "If we have the block definition we should have its region"); AnalysisDeclContext *BlockCtx = AMgr.getAnalysisDeclContext(D); ParentOfCallee = BlockCtx->getBlockInvocationContext(CallerSFC, cast(D), BR); } // This may be NULL, but that's fine. const Expr *CallE = Call.getOriginExpr(); // Construct a new stack frame for the callee. AnalysisDeclContext *CalleeADC = AMgr.getAnalysisDeclContext(D); const StackFrameContext *CalleeSFC = CalleeADC->getStackFrame(ParentOfCallee, CallE, currBldrCtx->getBlock(), currStmtIdx); CallEnter Loc(CallE, CalleeSFC, CurLC); // Construct a new state which contains the mapping from actual to // formal arguments. State = State->enterStackFrame(Call, CalleeSFC); bool isNew; if (ExplodedNode *N = G.getNode(Loc, State, false, &isNew)) { N->addPredecessor(Pred, G); if (isNew) Engine.getWorkList()->enqueue(N); } // If we decided to inline the call, the successor has been manually // added onto the work list so remove it from the node builder. Bldr.takeNodes(Pred); NumInlinedCalls++; // Mark the decl as visited. if (VisitedCallees) VisitedCallees->insert(D); return true; } static ProgramStateRef getInlineFailedState(ProgramStateRef State, const Stmt *CallE) { const void *ReplayState = State->get(); if (!ReplayState) return nullptr; assert(ReplayState == CallE && "Backtracked to the wrong call."); (void)CallE; return State->remove(); } void ExprEngine::VisitCallExpr(const CallExpr *CE, ExplodedNode *Pred, ExplodedNodeSet &dst) { // Perform the previsit of the CallExpr. ExplodedNodeSet dstPreVisit; getCheckerManager().runCheckersForPreStmt(dstPreVisit, Pred, CE, *this); // Get the call in its initial state. We use this as a template to perform // all the checks. CallEventManager &CEMgr = getStateManager().getCallEventManager(); CallEventRef<> CallTemplate = CEMgr.getSimpleCall(CE, Pred->getState(), Pred->getLocationContext()); // Evaluate the function call. We try each of the checkers // to see if the can evaluate the function call. ExplodedNodeSet dstCallEvaluated; for (ExplodedNodeSet::iterator I = dstPreVisit.begin(), E = dstPreVisit.end(); I != E; ++I) { evalCall(dstCallEvaluated, *I, *CallTemplate); } // Finally, perform the post-condition check of the CallExpr and store // the created nodes in 'Dst'. // Note that if the call was inlined, dstCallEvaluated will be empty. // The post-CallExpr check will occur in processCallExit. getCheckerManager().runCheckersForPostStmt(dst, dstCallEvaluated, CE, *this); } void ExprEngine::evalCall(ExplodedNodeSet &Dst, ExplodedNode *Pred, const CallEvent &Call) { // WARNING: At this time, the state attached to 'Call' may be older than the // state in 'Pred'. This is a minor optimization since CheckerManager will // use an updated CallEvent instance when calling checkers, but if 'Call' is // ever used directly in this function all callers should be updated to pass // the most recent state. (It is probably not worth doing the work here since // for some callers this will not be necessary.) // Run any pre-call checks using the generic call interface. ExplodedNodeSet dstPreVisit; getCheckerManager().runCheckersForPreCall(dstPreVisit, Pred, Call, *this); // Actually evaluate the function call. We try each of the checkers // to see if the can evaluate the function call, and get a callback at // defaultEvalCall if all of them fail. ExplodedNodeSet dstCallEvaluated; getCheckerManager().runCheckersForEvalCall(dstCallEvaluated, dstPreVisit, Call, *this); // Finally, run any post-call checks. getCheckerManager().runCheckersForPostCall(Dst, dstCallEvaluated, Call, *this); } ProgramStateRef ExprEngine::bindReturnValue(const CallEvent &Call, const LocationContext *LCtx, ProgramStateRef State) { const Expr *E = Call.getOriginExpr(); if (!E) return State; // Some method families have known return values. if (const ObjCMethodCall *Msg = dyn_cast(&Call)) { switch (Msg->getMethodFamily()) { default: break; case OMF_autorelease: case OMF_retain: case OMF_self: { // These methods return their receivers. return State->BindExpr(E, LCtx, Msg->getReceiverSVal()); } } } else if (const CXXConstructorCall *C = dyn_cast(&Call)){ SVal ThisV = C->getCXXThisVal(); // If the constructed object is a temporary prvalue, get its bindings. if (isTemporaryPRValue(cast(E), ThisV)) ThisV = State->getSVal(ThisV.castAs()); return State->BindExpr(E, LCtx, ThisV); } // Conjure a symbol if the return value is unknown. QualType ResultTy = Call.getResultType(); SValBuilder &SVB = getSValBuilder(); unsigned Count = currBldrCtx->blockCount(); SVal R = SVB.conjureSymbolVal(nullptr, E, LCtx, ResultTy, Count); return State->BindExpr(E, LCtx, R); } // Conservatively evaluate call by invalidating regions and binding // a conjured return value. void ExprEngine::conservativeEvalCall(const CallEvent &Call, NodeBuilder &Bldr, ExplodedNode *Pred, ProgramStateRef State) { State = Call.invalidateRegions(currBldrCtx->blockCount(), State); State = bindReturnValue(Call, Pred->getLocationContext(), State); // And make the result node. Bldr.generateNode(Call.getProgramPoint(), State, Pred); } enum CallInlinePolicy { CIP_Allowed, CIP_DisallowedOnce, CIP_DisallowedAlways }; static CallInlinePolicy mayInlineCallKind(const CallEvent &Call, const ExplodedNode *Pred, AnalyzerOptions &Opts) { const LocationContext *CurLC = Pred->getLocationContext(); const StackFrameContext *CallerSFC = CurLC->getCurrentStackFrame(); switch (Call.getKind()) { case CE_Function: case CE_Block: break; case CE_CXXMember: case CE_CXXMemberOperator: if (!Opts.mayInlineCXXMemberFunction(CIMK_MemberFunctions)) return CIP_DisallowedAlways; break; case CE_CXXConstructor: { if (!Opts.mayInlineCXXMemberFunction(CIMK_Constructors)) return CIP_DisallowedAlways; const CXXConstructorCall &Ctor = cast(Call); // FIXME: We don't handle constructors or destructors for arrays properly. // Even once we do, we still need to be careful about implicitly-generated // initializers for array fields in default move/copy constructors. const MemRegion *Target = Ctor.getCXXThisVal().getAsRegion(); if (Target && isa(Target)) return CIP_DisallowedOnce; // FIXME: This is a hack. We don't use the correct region for a new // expression, so if we inline the constructor its result will just be // thrown away. This short-term hack is tracked in // and the longer-term possible fix is discussed in PR12014. const CXXConstructExpr *CtorExpr = Ctor.getOriginExpr(); if (const Stmt *Parent = CurLC->getParentMap().getParent(CtorExpr)) if (isa(Parent)) return CIP_DisallowedOnce; // Inlining constructors requires including initializers in the CFG. const AnalysisDeclContext *ADC = CallerSFC->getAnalysisDeclContext(); assert(ADC->getCFGBuildOptions().AddInitializers && "No CFG initializers"); (void)ADC; // If the destructor is trivial, it's always safe to inline the constructor. if (Ctor.getDecl()->getParent()->hasTrivialDestructor()) break; // For other types, only inline constructors if destructor inlining is // also enabled. if (!Opts.mayInlineCXXMemberFunction(CIMK_Destructors)) return CIP_DisallowedAlways; // FIXME: This is a hack. We don't handle temporary destructors // right now, so we shouldn't inline their constructors. if (CtorExpr->getConstructionKind() == CXXConstructExpr::CK_Complete) if (!Target || !isa(Target)) return CIP_DisallowedOnce; break; } case CE_CXXDestructor: { if (!Opts.mayInlineCXXMemberFunction(CIMK_Destructors)) return CIP_DisallowedAlways; // Inlining destructors requires building the CFG correctly. const AnalysisDeclContext *ADC = CallerSFC->getAnalysisDeclContext(); assert(ADC->getCFGBuildOptions().AddImplicitDtors && "No CFG destructors"); (void)ADC; const CXXDestructorCall &Dtor = cast(Call); // FIXME: We don't handle constructors or destructors for arrays properly. const MemRegion *Target = Dtor.getCXXThisVal().getAsRegion(); if (Target && isa(Target)) return CIP_DisallowedOnce; break; } case CE_CXXAllocator: if (Opts.mayInlineCXXAllocator()) break; // Do not inline allocators until we model deallocators. // This is unfortunate, but basically necessary for smart pointers and such. return CIP_DisallowedAlways; case CE_ObjCMessage: if (!Opts.mayInlineObjCMethod()) return CIP_DisallowedAlways; if (!(Opts.getIPAMode() == IPAK_DynamicDispatch || Opts.getIPAMode() == IPAK_DynamicDispatchBifurcate)) return CIP_DisallowedAlways; break; } return CIP_Allowed; } /// Returns true if the given C++ class contains a member with the given name. static bool hasMember(const ASTContext &Ctx, const CXXRecordDecl *RD, StringRef Name) { const IdentifierInfo &II = Ctx.Idents.get(Name); DeclarationName DeclName = Ctx.DeclarationNames.getIdentifier(&II); if (!RD->lookup(DeclName).empty()) return true; CXXBasePaths Paths(false, false, false); if (RD->lookupInBases(&CXXRecordDecl::FindOrdinaryMember, DeclName.getAsOpaquePtr(), Paths)) return true; return false; } /// Returns true if the given C++ class is a container or iterator. /// /// Our heuristic for this is whether it contains a method named 'begin()' or a /// nested type named 'iterator' or 'iterator_category'. static bool isContainerClass(const ASTContext &Ctx, const CXXRecordDecl *RD) { return hasMember(Ctx, RD, "begin") || hasMember(Ctx, RD, "iterator") || hasMember(Ctx, RD, "iterator_category"); } /// Returns true if the given function refers to a method of a C++ container /// or iterator. /// /// We generally do a poor job modeling most containers right now, and might /// prefer not to inline their methods. static bool isContainerMethod(const ASTContext &Ctx, const FunctionDecl *FD) { if (const CXXMethodDecl *MD = dyn_cast(FD)) return isContainerClass(Ctx, MD->getParent()); return false; } /// Returns true if the given function is the destructor of a class named /// "shared_ptr". static bool isCXXSharedPtrDtor(const FunctionDecl *FD) { const CXXDestructorDecl *Dtor = dyn_cast(FD); if (!Dtor) return false; const CXXRecordDecl *RD = Dtor->getParent(); if (const IdentifierInfo *II = RD->getDeclName().getAsIdentifierInfo()) if (II->isStr("shared_ptr")) return true; return false; } /// Returns true if the function in \p CalleeADC may be inlined in general. /// /// This checks static properties of the function, such as its signature and /// CFG, to determine whether the analyzer should ever consider inlining it, /// in any context. static bool mayInlineDecl(AnalysisDeclContext *CalleeADC, AnalyzerOptions &Opts) { // FIXME: Do not inline variadic calls. if (CallEvent::isVariadic(CalleeADC->getDecl())) return false; // Check certain C++-related inlining policies. ASTContext &Ctx = CalleeADC->getASTContext(); if (Ctx.getLangOpts().CPlusPlus) { if (const FunctionDecl *FD = dyn_cast(CalleeADC->getDecl())) { // Conditionally control the inlining of template functions. if (!Opts.mayInlineTemplateFunctions()) if (FD->getTemplatedKind() != FunctionDecl::TK_NonTemplate) return false; // Conditionally control the inlining of C++ standard library functions. if (!Opts.mayInlineCXXStandardLibrary()) if (Ctx.getSourceManager().isInSystemHeader(FD->getLocation())) if (IsInStdNamespace(FD)) return false; // Conditionally control the inlining of methods on objects that look // like C++ containers. if (!Opts.mayInlineCXXContainerMethods()) if (!Ctx.getSourceManager().isInMainFile(FD->getLocation())) if (isContainerMethod(Ctx, FD)) return false; // Conditionally control the inlining of the destructor of C++ shared_ptr. // We don't currently do a good job modeling shared_ptr because we can't // see the reference count, so treating as opaque is probably the best // idea. if (!Opts.mayInlineCXXSharedPtrDtor()) if (isCXXSharedPtrDtor(FD)) return false; } } // It is possible that the CFG cannot be constructed. // Be safe, and check if the CalleeCFG is valid. const CFG *CalleeCFG = CalleeADC->getCFG(); if (!CalleeCFG) return false; // Do not inline large functions. if (CalleeCFG->getNumBlockIDs() > Opts.getMaxInlinableSize()) return false; // It is possible that the live variables analysis cannot be // run. If so, bail out. if (!CalleeADC->getAnalysis()) return false; return true; } bool ExprEngine::shouldInlineCall(const CallEvent &Call, const Decl *D, const ExplodedNode *Pred) { if (!D) return false; AnalysisManager &AMgr = getAnalysisManager(); AnalyzerOptions &Opts = AMgr.options; AnalysisDeclContextManager &ADCMgr = AMgr.getAnalysisDeclContextManager(); AnalysisDeclContext *CalleeADC = ADCMgr.getContext(D); // Temporary object destructor processing is currently broken, so we never // inline them. // FIXME: Remove this once temp destructors are working. if (isa(Call)) { if ((*currBldrCtx->getBlock())[currStmtIdx].getAs()) return false; } // The auto-synthesized bodies are essential to inline as they are // usually small and commonly used. Note: we should do this check early on to // ensure we always inline these calls. if (CalleeADC->isBodyAutosynthesized()) return true; if (!AMgr.shouldInlineCall()) return false; // Check if this function has been marked as non-inlinable. Optional MayInline = Engine.FunctionSummaries->mayInline(D); if (MayInline.hasValue()) { if (!MayInline.getValue()) return false; } else { // We haven't actually checked the static properties of this function yet. // Do that now, and record our decision in the function summaries. if (mayInlineDecl(CalleeADC, Opts)) { Engine.FunctionSummaries->markMayInline(D); } else { Engine.FunctionSummaries->markShouldNotInline(D); return false; } } // Check if we should inline a call based on its kind. // FIXME: this checks both static and dynamic properties of the call, which // means we're redoing a bit of work that could be cached in the function // summary. CallInlinePolicy CIP = mayInlineCallKind(Call, Pred, Opts); if (CIP != CIP_Allowed) { if (CIP == CIP_DisallowedAlways) { assert(!MayInline.hasValue() || MayInline.getValue()); Engine.FunctionSummaries->markShouldNotInline(D); } return false; } const CFG *CalleeCFG = CalleeADC->getCFG(); // Do not inline if recursive or we've reached max stack frame count. bool IsRecursive = false; unsigned StackDepth = 0; examineStackFrames(D, Pred->getLocationContext(), IsRecursive, StackDepth); if ((StackDepth >= Opts.InlineMaxStackDepth) && ((CalleeCFG->getNumBlockIDs() > Opts.getAlwaysInlineSize()) || IsRecursive)) return false; // Do not inline large functions too many times. if ((Engine.FunctionSummaries->getNumTimesInlined(D) > Opts.getMaxTimesInlineLarge()) && CalleeCFG->getNumBlockIDs() > 13) { NumReachedInlineCountMax++; return false; } if (HowToInline == Inline_Minimal && (CalleeCFG->getNumBlockIDs() > Opts.getAlwaysInlineSize() || IsRecursive)) return false; Engine.FunctionSummaries->bumpNumTimesInlined(D); return true; } static bool isTrivialObjectAssignment(const CallEvent &Call) { const CXXInstanceCall *ICall = dyn_cast(&Call); if (!ICall) return false; const CXXMethodDecl *MD = dyn_cast_or_null(ICall->getDecl()); if (!MD) return false; if (!(MD->isCopyAssignmentOperator() || MD->isMoveAssignmentOperator())) return false; return MD->isTrivial(); } void ExprEngine::defaultEvalCall(NodeBuilder &Bldr, ExplodedNode *Pred, const CallEvent &CallTemplate) { // Make sure we have the most recent state attached to the call. ProgramStateRef State = Pred->getState(); CallEventRef<> Call = CallTemplate.cloneWithState(State); // Special-case trivial assignment operators. if (isTrivialObjectAssignment(*Call)) { performTrivialCopy(Bldr, Pred, *Call); return; } // Try to inline the call. // The origin expression here is just used as a kind of checksum; // this should still be safe even for CallEvents that don't come from exprs. const Expr *E = Call->getOriginExpr(); ProgramStateRef InlinedFailedState = getInlineFailedState(State, E); if (InlinedFailedState) { // If we already tried once and failed, make sure we don't retry later. State = InlinedFailedState; } else { RuntimeDefinition RD = Call->getRuntimeDefinition(); const Decl *D = RD.getDecl(); if (shouldInlineCall(*Call, D, Pred)) { if (RD.mayHaveOtherDefinitions()) { AnalyzerOptions &Options = getAnalysisManager().options; // Explore with and without inlining the call. if (Options.getIPAMode() == IPAK_DynamicDispatchBifurcate) { BifurcateCall(RD.getDispatchRegion(), *Call, D, Bldr, Pred); return; } // Don't inline if we're not in any dynamic dispatch mode. if (Options.getIPAMode() != IPAK_DynamicDispatch) { conservativeEvalCall(*Call, Bldr, Pred, State); return; } } // We are not bifurcating and we do have a Decl, so just inline. if (inlineCall(*Call, D, Bldr, Pred, State)) return; } } // If we can't inline it, handle the return value and invalidate the regions. conservativeEvalCall(*Call, Bldr, Pred, State); } void ExprEngine::BifurcateCall(const MemRegion *BifurReg, const CallEvent &Call, const Decl *D, NodeBuilder &Bldr, ExplodedNode *Pred) { assert(BifurReg); BifurReg = BifurReg->StripCasts(); // Check if we've performed the split already - note, we only want // to split the path once per memory region. ProgramStateRef State = Pred->getState(); const unsigned *BState = State->get(BifurReg); if (BState) { // If we are on "inline path", keep inlining if possible. if (*BState == DynamicDispatchModeInlined) if (inlineCall(Call, D, Bldr, Pred, State)) return; // If inline failed, or we are on the path where we assume we // don't have enough info about the receiver to inline, conjure the // return value and invalidate the regions. conservativeEvalCall(Call, Bldr, Pred, State); return; } // If we got here, this is the first time we process a message to this // region, so split the path. ProgramStateRef IState = State->set(BifurReg, DynamicDispatchModeInlined); inlineCall(Call, D, Bldr, Pred, IState); ProgramStateRef NoIState = State->set(BifurReg, DynamicDispatchModeConservative); conservativeEvalCall(Call, Bldr, Pred, NoIState); NumOfDynamicDispatchPathSplits++; return; } void ExprEngine::VisitReturnStmt(const ReturnStmt *RS, ExplodedNode *Pred, ExplodedNodeSet &Dst) { ExplodedNodeSet dstPreVisit; getCheckerManager().runCheckersForPreStmt(dstPreVisit, Pred, RS, *this); StmtNodeBuilder B(dstPreVisit, Dst, *currBldrCtx); if (RS->getRetValue()) { for (ExplodedNodeSet::iterator it = dstPreVisit.begin(), ei = dstPreVisit.end(); it != ei; ++it) { B.generateNode(RS, *it, (*it)->getState()); } } }