//===- Consumed.cpp --------------------------------------------*- C++ --*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // A intra-procedural analysis for checking consumed properties. This is based, // in part, on research on linear types. // //===----------------------------------------------------------------------===// #include "clang/Analysis/Analyses/Consumed.h" #include "clang/AST/ASTContext.h" #include "clang/AST/Attr.h" #include "clang/AST/DeclCXX.h" #include "clang/AST/ExprCXX.h" #include "clang/AST/RecursiveASTVisitor.h" #include "clang/AST/StmtCXX.h" #include "clang/AST/StmtVisitor.h" #include "clang/AST/Type.h" #include "clang/Analysis/Analyses/PostOrderCFGView.h" #include "clang/Analysis/AnalysisContext.h" #include "clang/Analysis/CFG.h" #include "clang/Basic/OperatorKinds.h" #include "clang/Basic/SourceLocation.h" #include "llvm/ADT/DenseMap.h" #include // TODO: Adjust states of args to constructors in the same way that arguments to // function calls are handled. // TODO: Use information from tests in for- and while-loop conditional. // TODO: Add notes about the actual and expected state for // TODO: Correctly identify unreachable blocks when chaining boolean operators. // TODO: Adjust the parser and AttributesList class to support lists of // identifiers. // TODO: Warn about unreachable code. // TODO: Switch to using a bitmap to track unreachable blocks. // TODO: Handle variable definitions, e.g. bool valid = x.isValid(); // if (valid) ...; (Deferred) // TODO: Take notes on state transitions to provide better warning messages. // (Deferred) // TODO: Test nested conditionals: A) Checking the same value multiple times, // and 2) Checking different values. (Deferred) using namespace clang; using namespace consumed; // Key method definition ConsumedWarningsHandlerBase::~ConsumedWarningsHandlerBase() {} static SourceLocation getFirstStmtLoc(const CFGBlock *Block) { // Find the source location of the first statement in the block, if the block // is not empty. for (const auto &B : *Block) if (Optional CS = B.getAs()) return CS->getStmt()->getLocStart(); // Block is empty. // If we have one successor, return the first statement in that block if (Block->succ_size() == 1 && *Block->succ_begin()) return getFirstStmtLoc(*Block->succ_begin()); return SourceLocation(); } static SourceLocation getLastStmtLoc(const CFGBlock *Block) { // Find the source location of the last statement in the block, if the block // is not empty. if (const Stmt *StmtNode = Block->getTerminator()) { return StmtNode->getLocStart(); } else { for (CFGBlock::const_reverse_iterator BI = Block->rbegin(), BE = Block->rend(); BI != BE; ++BI) { if (Optional CS = BI->getAs()) return CS->getStmt()->getLocStart(); } } // If we have one successor, return the first statement in that block SourceLocation Loc; if (Block->succ_size() == 1 && *Block->succ_begin()) Loc = getFirstStmtLoc(*Block->succ_begin()); if (Loc.isValid()) return Loc; // If we have one predecessor, return the last statement in that block if (Block->pred_size() == 1 && *Block->pred_begin()) return getLastStmtLoc(*Block->pred_begin()); return Loc; } static ConsumedState invertConsumedUnconsumed(ConsumedState State) { switch (State) { case CS_Unconsumed: return CS_Consumed; case CS_Consumed: return CS_Unconsumed; case CS_None: return CS_None; case CS_Unknown: return CS_Unknown; } llvm_unreachable("invalid enum"); } static bool isCallableInState(const CallableWhenAttr *CWAttr, ConsumedState State) { for (const auto &S : CWAttr->callableStates()) { ConsumedState MappedAttrState = CS_None; switch (S) { case CallableWhenAttr::Unknown: MappedAttrState = CS_Unknown; break; case CallableWhenAttr::Unconsumed: MappedAttrState = CS_Unconsumed; break; case CallableWhenAttr::Consumed: MappedAttrState = CS_Consumed; break; } if (MappedAttrState == State) return true; } return false; } static bool isConsumableType(const QualType &QT) { if (QT->isPointerType() || QT->isReferenceType()) return false; if (const CXXRecordDecl *RD = QT->getAsCXXRecordDecl()) return RD->hasAttr(); return false; } static bool isAutoCastType(const QualType &QT) { if (QT->isPointerType() || QT->isReferenceType()) return false; if (const CXXRecordDecl *RD = QT->getAsCXXRecordDecl()) return RD->hasAttr(); return false; } static bool isSetOnReadPtrType(const QualType &QT) { if (const CXXRecordDecl *RD = QT->getPointeeCXXRecordDecl()) return RD->hasAttr(); return false; } static bool isKnownState(ConsumedState State) { switch (State) { case CS_Unconsumed: case CS_Consumed: return true; case CS_None: case CS_Unknown: return false; } llvm_unreachable("invalid enum"); } static bool isRValueRef(QualType ParamType) { return ParamType->isRValueReferenceType(); } static bool isTestingFunction(const FunctionDecl *FunDecl) { return FunDecl->hasAttr(); } static bool isPointerOrRef(QualType ParamType) { return ParamType->isPointerType() || ParamType->isReferenceType(); } static ConsumedState mapConsumableAttrState(const QualType QT) { assert(isConsumableType(QT)); const ConsumableAttr *CAttr = QT->getAsCXXRecordDecl()->getAttr(); switch (CAttr->getDefaultState()) { case ConsumableAttr::Unknown: return CS_Unknown; case ConsumableAttr::Unconsumed: return CS_Unconsumed; case ConsumableAttr::Consumed: return CS_Consumed; } llvm_unreachable("invalid enum"); } static ConsumedState mapParamTypestateAttrState(const ParamTypestateAttr *PTAttr) { switch (PTAttr->getParamState()) { case ParamTypestateAttr::Unknown: return CS_Unknown; case ParamTypestateAttr::Unconsumed: return CS_Unconsumed; case ParamTypestateAttr::Consumed: return CS_Consumed; } llvm_unreachable("invalid_enum"); } static ConsumedState mapReturnTypestateAttrState(const ReturnTypestateAttr *RTSAttr) { switch (RTSAttr->getState()) { case ReturnTypestateAttr::Unknown: return CS_Unknown; case ReturnTypestateAttr::Unconsumed: return CS_Unconsumed; case ReturnTypestateAttr::Consumed: return CS_Consumed; } llvm_unreachable("invalid enum"); } static ConsumedState mapSetTypestateAttrState(const SetTypestateAttr *STAttr) { switch (STAttr->getNewState()) { case SetTypestateAttr::Unknown: return CS_Unknown; case SetTypestateAttr::Unconsumed: return CS_Unconsumed; case SetTypestateAttr::Consumed: return CS_Consumed; } llvm_unreachable("invalid_enum"); } static StringRef stateToString(ConsumedState State) { switch (State) { case consumed::CS_None: return "none"; case consumed::CS_Unknown: return "unknown"; case consumed::CS_Unconsumed: return "unconsumed"; case consumed::CS_Consumed: return "consumed"; } llvm_unreachable("invalid enum"); } static ConsumedState testsFor(const FunctionDecl *FunDecl) { assert(isTestingFunction(FunDecl)); switch (FunDecl->getAttr()->getTestState()) { case TestTypestateAttr::Unconsumed: return CS_Unconsumed; case TestTypestateAttr::Consumed: return CS_Consumed; } llvm_unreachable("invalid enum"); } namespace { struct VarTestResult { const VarDecl *Var; ConsumedState TestsFor; }; } // end anonymous::VarTestResult namespace clang { namespace consumed { enum EffectiveOp { EO_And, EO_Or }; class PropagationInfo { enum { IT_None, IT_State, IT_VarTest, IT_BinTest, IT_Var, IT_Tmp } InfoType; struct BinTestTy { const BinaryOperator *Source; EffectiveOp EOp; VarTestResult LTest; VarTestResult RTest; }; union { ConsumedState State; VarTestResult VarTest; const VarDecl *Var; const CXXBindTemporaryExpr *Tmp; BinTestTy BinTest; }; public: PropagationInfo() : InfoType(IT_None) {} PropagationInfo(const VarTestResult &VarTest) : InfoType(IT_VarTest), VarTest(VarTest) {} PropagationInfo(const VarDecl *Var, ConsumedState TestsFor) : InfoType(IT_VarTest) { VarTest.Var = Var; VarTest.TestsFor = TestsFor; } PropagationInfo(const BinaryOperator *Source, EffectiveOp EOp, const VarTestResult <est, const VarTestResult &RTest) : InfoType(IT_BinTest) { BinTest.Source = Source; BinTest.EOp = EOp; BinTest.LTest = LTest; BinTest.RTest = RTest; } PropagationInfo(const BinaryOperator *Source, EffectiveOp EOp, const VarDecl *LVar, ConsumedState LTestsFor, const VarDecl *RVar, ConsumedState RTestsFor) : InfoType(IT_BinTest) { BinTest.Source = Source; BinTest.EOp = EOp; BinTest.LTest.Var = LVar; BinTest.LTest.TestsFor = LTestsFor; BinTest.RTest.Var = RVar; BinTest.RTest.TestsFor = RTestsFor; } PropagationInfo(ConsumedState State) : InfoType(IT_State), State(State) {} PropagationInfo(const VarDecl *Var) : InfoType(IT_Var), Var(Var) {} PropagationInfo(const CXXBindTemporaryExpr *Tmp) : InfoType(IT_Tmp), Tmp(Tmp) {} const ConsumedState & getState() const { assert(InfoType == IT_State); return State; } const VarTestResult & getVarTest() const { assert(InfoType == IT_VarTest); return VarTest; } const VarTestResult & getLTest() const { assert(InfoType == IT_BinTest); return BinTest.LTest; } const VarTestResult & getRTest() const { assert(InfoType == IT_BinTest); return BinTest.RTest; } const VarDecl * getVar() const { assert(InfoType == IT_Var); return Var; } const CXXBindTemporaryExpr * getTmp() const { assert(InfoType == IT_Tmp); return Tmp; } ConsumedState getAsState(const ConsumedStateMap *StateMap) const { assert(isVar() || isTmp() || isState()); if (isVar()) return StateMap->getState(Var); else if (isTmp()) return StateMap->getState(Tmp); else if (isState()) return State; else return CS_None; } EffectiveOp testEffectiveOp() const { assert(InfoType == IT_BinTest); return BinTest.EOp; } const BinaryOperator * testSourceNode() const { assert(InfoType == IT_BinTest); return BinTest.Source; } inline bool isValid() const { return InfoType != IT_None; } inline bool isState() const { return InfoType == IT_State; } inline bool isVarTest() const { return InfoType == IT_VarTest; } inline bool isBinTest() const { return InfoType == IT_BinTest; } inline bool isVar() const { return InfoType == IT_Var; } inline bool isTmp() const { return InfoType == IT_Tmp; } bool isTest() const { return InfoType == IT_VarTest || InfoType == IT_BinTest; } bool isPointerToValue() const { return InfoType == IT_Var || InfoType == IT_Tmp; } PropagationInfo invertTest() const { assert(InfoType == IT_VarTest || InfoType == IT_BinTest); if (InfoType == IT_VarTest) { return PropagationInfo(VarTest.Var, invertConsumedUnconsumed(VarTest.TestsFor)); } else if (InfoType == IT_BinTest) { return PropagationInfo(BinTest.Source, BinTest.EOp == EO_And ? EO_Or : EO_And, BinTest.LTest.Var, invertConsumedUnconsumed(BinTest.LTest.TestsFor), BinTest.RTest.Var, invertConsumedUnconsumed(BinTest.RTest.TestsFor)); } else { return PropagationInfo(); } } }; static inline void setStateForVarOrTmp(ConsumedStateMap *StateMap, const PropagationInfo &PInfo, ConsumedState State) { assert(PInfo.isVar() || PInfo.isTmp()); if (PInfo.isVar()) StateMap->setState(PInfo.getVar(), State); else StateMap->setState(PInfo.getTmp(), State); } class ConsumedStmtVisitor : public ConstStmtVisitor { typedef llvm::DenseMap MapType; typedef std::pair PairType; typedef MapType::iterator InfoEntry; typedef MapType::const_iterator ConstInfoEntry; AnalysisDeclContext &AC; ConsumedAnalyzer &Analyzer; ConsumedStateMap *StateMap; MapType PropagationMap; InfoEntry findInfo(const Expr *E) { if (auto Cleanups = dyn_cast(E)) if (!Cleanups->cleanupsHaveSideEffects()) E = Cleanups->getSubExpr(); return PropagationMap.find(E->IgnoreParens()); } ConstInfoEntry findInfo(const Expr *E) const { if (auto Cleanups = dyn_cast(E)) if (!Cleanups->cleanupsHaveSideEffects()) E = Cleanups->getSubExpr(); return PropagationMap.find(E->IgnoreParens()); } void insertInfo(const Expr *E, const PropagationInfo &PI) { PropagationMap.insert(PairType(E->IgnoreParens(), PI)); } void forwardInfo(const Expr *From, const Expr *To); void copyInfo(const Expr *From, const Expr *To, ConsumedState CS); ConsumedState getInfo(const Expr *From); void setInfo(const Expr *To, ConsumedState NS); void propagateReturnType(const Expr *Call, const FunctionDecl *Fun); public: void checkCallability(const PropagationInfo &PInfo, const FunctionDecl *FunDecl, SourceLocation BlameLoc); bool handleCall(const CallExpr *Call, const Expr *ObjArg, const FunctionDecl *FunD); void VisitBinaryOperator(const BinaryOperator *BinOp); void VisitCallExpr(const CallExpr *Call); void VisitCastExpr(const CastExpr *Cast); void VisitCXXBindTemporaryExpr(const CXXBindTemporaryExpr *Temp); void VisitCXXConstructExpr(const CXXConstructExpr *Call); void VisitCXXMemberCallExpr(const CXXMemberCallExpr *Call); void VisitCXXOperatorCallExpr(const CXXOperatorCallExpr *Call); void VisitDeclRefExpr(const DeclRefExpr *DeclRef); void VisitDeclStmt(const DeclStmt *DelcS); void VisitMaterializeTemporaryExpr(const MaterializeTemporaryExpr *Temp); void VisitMemberExpr(const MemberExpr *MExpr); void VisitParmVarDecl(const ParmVarDecl *Param); void VisitReturnStmt(const ReturnStmt *Ret); void VisitUnaryOperator(const UnaryOperator *UOp); void VisitVarDecl(const VarDecl *Var); ConsumedStmtVisitor(AnalysisDeclContext &AC, ConsumedAnalyzer &Analyzer, ConsumedStateMap *StateMap) : AC(AC), Analyzer(Analyzer), StateMap(StateMap) {} PropagationInfo getInfo(const Expr *StmtNode) const { ConstInfoEntry Entry = findInfo(StmtNode); if (Entry != PropagationMap.end()) return Entry->second; else return PropagationInfo(); } void reset(ConsumedStateMap *NewStateMap) { StateMap = NewStateMap; } }; void ConsumedStmtVisitor::forwardInfo(const Expr *From, const Expr *To) { InfoEntry Entry = findInfo(From); if (Entry != PropagationMap.end()) insertInfo(To, Entry->second); } // Create a new state for To, which is initialized to the state of From. // If NS is not CS_None, sets the state of From to NS. void ConsumedStmtVisitor::copyInfo(const Expr *From, const Expr *To, ConsumedState NS) { InfoEntry Entry = findInfo(From); if (Entry != PropagationMap.end()) { PropagationInfo& PInfo = Entry->second; ConsumedState CS = PInfo.getAsState(StateMap); if (CS != CS_None) insertInfo(To, PropagationInfo(CS)); if (NS != CS_None && PInfo.isPointerToValue()) setStateForVarOrTmp(StateMap, PInfo, NS); } } // Get the ConsumedState for From ConsumedState ConsumedStmtVisitor::getInfo(const Expr *From) { InfoEntry Entry = findInfo(From); if (Entry != PropagationMap.end()) { PropagationInfo& PInfo = Entry->second; return PInfo.getAsState(StateMap); } return CS_None; } // If we already have info for To then update it, otherwise create a new entry. void ConsumedStmtVisitor::setInfo(const Expr *To, ConsumedState NS) { InfoEntry Entry = findInfo(To); if (Entry != PropagationMap.end()) { PropagationInfo& PInfo = Entry->second; if (PInfo.isPointerToValue()) setStateForVarOrTmp(StateMap, PInfo, NS); } else if (NS != CS_None) { insertInfo(To, PropagationInfo(NS)); } } void ConsumedStmtVisitor::checkCallability(const PropagationInfo &PInfo, const FunctionDecl *FunDecl, SourceLocation BlameLoc) { assert(!PInfo.isTest()); const CallableWhenAttr *CWAttr = FunDecl->getAttr(); if (!CWAttr) return; if (PInfo.isVar()) { ConsumedState VarState = StateMap->getState(PInfo.getVar()); if (VarState == CS_None || isCallableInState(CWAttr, VarState)) return; Analyzer.WarningsHandler.warnUseInInvalidState( FunDecl->getNameAsString(), PInfo.getVar()->getNameAsString(), stateToString(VarState), BlameLoc); } else { ConsumedState TmpState = PInfo.getAsState(StateMap); if (TmpState == CS_None || isCallableInState(CWAttr, TmpState)) return; Analyzer.WarningsHandler.warnUseOfTempInInvalidState( FunDecl->getNameAsString(), stateToString(TmpState), BlameLoc); } } // Factors out common behavior for function, method, and operator calls. // Check parameters and set parameter state if necessary. // Returns true if the state of ObjArg is set, or false otherwise. bool ConsumedStmtVisitor::handleCall(const CallExpr *Call, const Expr *ObjArg, const FunctionDecl *FunD) { unsigned Offset = 0; if (isa(Call) && isa(FunD)) Offset = 1; // first argument is 'this' // check explicit parameters for (unsigned Index = Offset; Index < Call->getNumArgs(); ++Index) { // Skip variable argument lists. if (Index - Offset >= FunD->getNumParams()) break; const ParmVarDecl *Param = FunD->getParamDecl(Index - Offset); QualType ParamType = Param->getType(); InfoEntry Entry = findInfo(Call->getArg(Index)); if (Entry == PropagationMap.end() || Entry->second.isTest()) continue; PropagationInfo PInfo = Entry->second; // Check that the parameter is in the correct state. if (ParamTypestateAttr *PTA = Param->getAttr()) { ConsumedState ParamState = PInfo.getAsState(StateMap); ConsumedState ExpectedState = mapParamTypestateAttrState(PTA); if (ParamState != ExpectedState) Analyzer.WarningsHandler.warnParamTypestateMismatch( Call->getArg(Index)->getExprLoc(), stateToString(ExpectedState), stateToString(ParamState)); } if (!(Entry->second.isVar() || Entry->second.isTmp())) continue; // Adjust state on the caller side. if (isRValueRef(ParamType)) setStateForVarOrTmp(StateMap, PInfo, consumed::CS_Consumed); else if (ReturnTypestateAttr *RT = Param->getAttr()) setStateForVarOrTmp(StateMap, PInfo, mapReturnTypestateAttrState(RT)); else if (isPointerOrRef(ParamType) && (!ParamType->getPointeeType().isConstQualified() || isSetOnReadPtrType(ParamType))) setStateForVarOrTmp(StateMap, PInfo, consumed::CS_Unknown); } if (!ObjArg) return false; // check implicit 'self' parameter, if present InfoEntry Entry = findInfo(ObjArg); if (Entry != PropagationMap.end()) { PropagationInfo PInfo = Entry->second; checkCallability(PInfo, FunD, Call->getExprLoc()); if (SetTypestateAttr *STA = FunD->getAttr()) { if (PInfo.isVar()) { StateMap->setState(PInfo.getVar(), mapSetTypestateAttrState(STA)); return true; } else if (PInfo.isTmp()) { StateMap->setState(PInfo.getTmp(), mapSetTypestateAttrState(STA)); return true; } } else if (isTestingFunction(FunD) && PInfo.isVar()) { PropagationMap.insert(PairType(Call, PropagationInfo(PInfo.getVar(), testsFor(FunD)))); } } return false; } void ConsumedStmtVisitor::propagateReturnType(const Expr *Call, const FunctionDecl *Fun) { QualType RetType = Fun->getCallResultType(); if (RetType->isReferenceType()) RetType = RetType->getPointeeType(); if (isConsumableType(RetType)) { ConsumedState ReturnState; if (ReturnTypestateAttr *RTA = Fun->getAttr()) ReturnState = mapReturnTypestateAttrState(RTA); else ReturnState = mapConsumableAttrState(RetType); PropagationMap.insert(PairType(Call, PropagationInfo(ReturnState))); } } void ConsumedStmtVisitor::VisitBinaryOperator(const BinaryOperator *BinOp) { switch (BinOp->getOpcode()) { case BO_LAnd: case BO_LOr : { InfoEntry LEntry = findInfo(BinOp->getLHS()), REntry = findInfo(BinOp->getRHS()); VarTestResult LTest, RTest; if (LEntry != PropagationMap.end() && LEntry->second.isVarTest()) { LTest = LEntry->second.getVarTest(); } else { LTest.Var = nullptr; LTest.TestsFor = CS_None; } if (REntry != PropagationMap.end() && REntry->second.isVarTest()) { RTest = REntry->second.getVarTest(); } else { RTest.Var = nullptr; RTest.TestsFor = CS_None; } if (!(LTest.Var == nullptr && RTest.Var == nullptr)) PropagationMap.insert(PairType(BinOp, PropagationInfo(BinOp, static_cast(BinOp->getOpcode() == BO_LOr), LTest, RTest))); break; } case BO_PtrMemD: case BO_PtrMemI: forwardInfo(BinOp->getLHS(), BinOp); break; default: break; } } void ConsumedStmtVisitor::VisitCallExpr(const CallExpr *Call) { const FunctionDecl *FunDecl = Call->getDirectCallee(); if (!FunDecl) return; // Special case for the std::move function. // TODO: Make this more specific. (Deferred) if (Call->getNumArgs() == 1 && FunDecl->getNameAsString() == "move" && FunDecl->isInStdNamespace()) { copyInfo(Call->getArg(0), Call, CS_Consumed); return; } handleCall(Call, nullptr, FunDecl); propagateReturnType(Call, FunDecl); } void ConsumedStmtVisitor::VisitCastExpr(const CastExpr *Cast) { forwardInfo(Cast->getSubExpr(), Cast); } void ConsumedStmtVisitor::VisitCXXBindTemporaryExpr( const CXXBindTemporaryExpr *Temp) { InfoEntry Entry = findInfo(Temp->getSubExpr()); if (Entry != PropagationMap.end() && !Entry->second.isTest()) { StateMap->setState(Temp, Entry->second.getAsState(StateMap)); PropagationMap.insert(PairType(Temp, PropagationInfo(Temp))); } } void ConsumedStmtVisitor::VisitCXXConstructExpr(const CXXConstructExpr *Call) { CXXConstructorDecl *Constructor = Call->getConstructor(); ASTContext &CurrContext = AC.getASTContext(); QualType ThisType = Constructor->getThisType(CurrContext)->getPointeeType(); if (!isConsumableType(ThisType)) return; // FIXME: What should happen if someone annotates the move constructor? if (ReturnTypestateAttr *RTA = Constructor->getAttr()) { // TODO: Adjust state of args appropriately. ConsumedState RetState = mapReturnTypestateAttrState(RTA); PropagationMap.insert(PairType(Call, PropagationInfo(RetState))); } else if (Constructor->isDefaultConstructor()) { PropagationMap.insert(PairType(Call, PropagationInfo(consumed::CS_Consumed))); } else if (Constructor->isMoveConstructor()) { copyInfo(Call->getArg(0), Call, CS_Consumed); } else if (Constructor->isCopyConstructor()) { // Copy state from arg. If setStateOnRead then set arg to CS_Unknown. ConsumedState NS = isSetOnReadPtrType(Constructor->getThisType(CurrContext)) ? CS_Unknown : CS_None; copyInfo(Call->getArg(0), Call, NS); } else { // TODO: Adjust state of args appropriately. ConsumedState RetState = mapConsumableAttrState(ThisType); PropagationMap.insert(PairType(Call, PropagationInfo(RetState))); } } void ConsumedStmtVisitor::VisitCXXMemberCallExpr( const CXXMemberCallExpr *Call) { CXXMethodDecl* MD = Call->getMethodDecl(); if (!MD) return; handleCall(Call, Call->getImplicitObjectArgument(), MD); propagateReturnType(Call, MD); } void ConsumedStmtVisitor::VisitCXXOperatorCallExpr( const CXXOperatorCallExpr *Call) { const FunctionDecl *FunDecl = dyn_cast_or_null(Call->getDirectCallee()); if (!FunDecl) return; if (Call->getOperator() == OO_Equal) { ConsumedState CS = getInfo(Call->getArg(1)); if (!handleCall(Call, Call->getArg(0), FunDecl)) setInfo(Call->getArg(0), CS); return; } if (const CXXMemberCallExpr *MCall = dyn_cast(Call)) handleCall(MCall, MCall->getImplicitObjectArgument(), FunDecl); else handleCall(Call, Call->getArg(0), FunDecl); propagateReturnType(Call, FunDecl); } void ConsumedStmtVisitor::VisitDeclRefExpr(const DeclRefExpr *DeclRef) { if (const VarDecl *Var = dyn_cast_or_null(DeclRef->getDecl())) if (StateMap->getState(Var) != consumed::CS_None) PropagationMap.insert(PairType(DeclRef, PropagationInfo(Var))); } void ConsumedStmtVisitor::VisitDeclStmt(const DeclStmt *DeclS) { for (const auto *DI : DeclS->decls()) if (isa(DI)) VisitVarDecl(cast(DI)); if (DeclS->isSingleDecl()) if (const VarDecl *Var = dyn_cast_or_null(DeclS->getSingleDecl())) PropagationMap.insert(PairType(DeclS, PropagationInfo(Var))); } void ConsumedStmtVisitor::VisitMaterializeTemporaryExpr( const MaterializeTemporaryExpr *Temp) { forwardInfo(Temp->GetTemporaryExpr(), Temp); } void ConsumedStmtVisitor::VisitMemberExpr(const MemberExpr *MExpr) { forwardInfo(MExpr->getBase(), MExpr); } void ConsumedStmtVisitor::VisitParmVarDecl(const ParmVarDecl *Param) { QualType ParamType = Param->getType(); ConsumedState ParamState = consumed::CS_None; if (const ParamTypestateAttr *PTA = Param->getAttr()) ParamState = mapParamTypestateAttrState(PTA); else if (isConsumableType(ParamType)) ParamState = mapConsumableAttrState(ParamType); else if (isRValueRef(ParamType) && isConsumableType(ParamType->getPointeeType())) ParamState = mapConsumableAttrState(ParamType->getPointeeType()); else if (ParamType->isReferenceType() && isConsumableType(ParamType->getPointeeType())) ParamState = consumed::CS_Unknown; if (ParamState != CS_None) StateMap->setState(Param, ParamState); } void ConsumedStmtVisitor::VisitReturnStmt(const ReturnStmt *Ret) { ConsumedState ExpectedState = Analyzer.getExpectedReturnState(); if (ExpectedState != CS_None) { InfoEntry Entry = findInfo(Ret->getRetValue()); if (Entry != PropagationMap.end()) { ConsumedState RetState = Entry->second.getAsState(StateMap); if (RetState != ExpectedState) Analyzer.WarningsHandler.warnReturnTypestateMismatch( Ret->getReturnLoc(), stateToString(ExpectedState), stateToString(RetState)); } } StateMap->checkParamsForReturnTypestate(Ret->getLocStart(), Analyzer.WarningsHandler); } void ConsumedStmtVisitor::VisitUnaryOperator(const UnaryOperator *UOp) { InfoEntry Entry = findInfo(UOp->getSubExpr()); if (Entry == PropagationMap.end()) return; switch (UOp->getOpcode()) { case UO_AddrOf: PropagationMap.insert(PairType(UOp, Entry->second)); break; case UO_LNot: if (Entry->second.isTest()) PropagationMap.insert(PairType(UOp, Entry->second.invertTest())); break; default: break; } } // TODO: See if I need to check for reference types here. void ConsumedStmtVisitor::VisitVarDecl(const VarDecl *Var) { if (isConsumableType(Var->getType())) { if (Var->hasInit()) { MapType::iterator VIT = findInfo(Var->getInit()->IgnoreImplicit()); if (VIT != PropagationMap.end()) { PropagationInfo PInfo = VIT->second; ConsumedState St = PInfo.getAsState(StateMap); if (St != consumed::CS_None) { StateMap->setState(Var, St); return; } } } // Otherwise StateMap->setState(Var, consumed::CS_Unknown); } } }} // end clang::consumed::ConsumedStmtVisitor namespace clang { namespace consumed { static void splitVarStateForIf(const IfStmt *IfNode, const VarTestResult &Test, ConsumedStateMap *ThenStates, ConsumedStateMap *ElseStates) { ConsumedState VarState = ThenStates->getState(Test.Var); if (VarState == CS_Unknown) { ThenStates->setState(Test.Var, Test.TestsFor); ElseStates->setState(Test.Var, invertConsumedUnconsumed(Test.TestsFor)); } else if (VarState == invertConsumedUnconsumed(Test.TestsFor)) { ThenStates->markUnreachable(); } else if (VarState == Test.TestsFor) { ElseStates->markUnreachable(); } } static void splitVarStateForIfBinOp(const PropagationInfo &PInfo, ConsumedStateMap *ThenStates, ConsumedStateMap *ElseStates) { const VarTestResult <est = PInfo.getLTest(), &RTest = PInfo.getRTest(); ConsumedState LState = LTest.Var ? ThenStates->getState(LTest.Var) : CS_None, RState = RTest.Var ? ThenStates->getState(RTest.Var) : CS_None; if (LTest.Var) { if (PInfo.testEffectiveOp() == EO_And) { if (LState == CS_Unknown) { ThenStates->setState(LTest.Var, LTest.TestsFor); } else if (LState == invertConsumedUnconsumed(LTest.TestsFor)) { ThenStates->markUnreachable(); } else if (LState == LTest.TestsFor && isKnownState(RState)) { if (RState == RTest.TestsFor) ElseStates->markUnreachable(); else ThenStates->markUnreachable(); } } else { if (LState == CS_Unknown) { ElseStates->setState(LTest.Var, invertConsumedUnconsumed(LTest.TestsFor)); } else if (LState == LTest.TestsFor) { ElseStates->markUnreachable(); } else if (LState == invertConsumedUnconsumed(LTest.TestsFor) && isKnownState(RState)) { if (RState == RTest.TestsFor) ElseStates->markUnreachable(); else ThenStates->markUnreachable(); } } } if (RTest.Var) { if (PInfo.testEffectiveOp() == EO_And) { if (RState == CS_Unknown) ThenStates->setState(RTest.Var, RTest.TestsFor); else if (RState == invertConsumedUnconsumed(RTest.TestsFor)) ThenStates->markUnreachable(); } else { if (RState == CS_Unknown) ElseStates->setState(RTest.Var, invertConsumedUnconsumed(RTest.TestsFor)); else if (RState == RTest.TestsFor) ElseStates->markUnreachable(); } } } bool ConsumedBlockInfo::allBackEdgesVisited(const CFGBlock *CurrBlock, const CFGBlock *TargetBlock) { assert(CurrBlock && "Block pointer must not be NULL"); assert(TargetBlock && "TargetBlock pointer must not be NULL"); unsigned int CurrBlockOrder = VisitOrder[CurrBlock->getBlockID()]; for (CFGBlock::const_pred_iterator PI = TargetBlock->pred_begin(), PE = TargetBlock->pred_end(); PI != PE; ++PI) { if (*PI && CurrBlockOrder < VisitOrder[(*PI)->getBlockID()] ) return false; } return true; } void ConsumedBlockInfo::addInfo( const CFGBlock *Block, ConsumedStateMap *StateMap, std::unique_ptr &OwnedStateMap) { assert(Block && "Block pointer must not be NULL"); auto &Entry = StateMapsArray[Block->getBlockID()]; if (Entry) { Entry->intersect(*StateMap); } else if (OwnedStateMap) Entry = std::move(OwnedStateMap); else Entry = llvm::make_unique(*StateMap); } void ConsumedBlockInfo::addInfo(const CFGBlock *Block, std::unique_ptr StateMap) { assert(Block && "Block pointer must not be NULL"); auto &Entry = StateMapsArray[Block->getBlockID()]; if (Entry) { Entry->intersect(*StateMap); } else { Entry = std::move(StateMap); } } ConsumedStateMap* ConsumedBlockInfo::borrowInfo(const CFGBlock *Block) { assert(Block && "Block pointer must not be NULL"); assert(StateMapsArray[Block->getBlockID()] && "Block has no block info"); return StateMapsArray[Block->getBlockID()].get(); } void ConsumedBlockInfo::discardInfo(const CFGBlock *Block) { StateMapsArray[Block->getBlockID()] = nullptr; } std::unique_ptr ConsumedBlockInfo::getInfo(const CFGBlock *Block) { assert(Block && "Block pointer must not be NULL"); auto &Entry = StateMapsArray[Block->getBlockID()]; return isBackEdgeTarget(Block) ? llvm::make_unique(*Entry) : std::move(Entry); } bool ConsumedBlockInfo::isBackEdge(const CFGBlock *From, const CFGBlock *To) { assert(From && "From block must not be NULL"); assert(To && "From block must not be NULL"); return VisitOrder[From->getBlockID()] > VisitOrder[To->getBlockID()]; } bool ConsumedBlockInfo::isBackEdgeTarget(const CFGBlock *Block) { assert(Block && "Block pointer must not be NULL"); // Anything with less than two predecessors can't be the target of a back // edge. if (Block->pred_size() < 2) return false; unsigned int BlockVisitOrder = VisitOrder[Block->getBlockID()]; for (CFGBlock::const_pred_iterator PI = Block->pred_begin(), PE = Block->pred_end(); PI != PE; ++PI) { if (*PI && BlockVisitOrder < VisitOrder[(*PI)->getBlockID()]) return true; } return false; } void ConsumedStateMap::checkParamsForReturnTypestate(SourceLocation BlameLoc, ConsumedWarningsHandlerBase &WarningsHandler) const { for (const auto &DM : VarMap) { if (isa(DM.first)) { const ParmVarDecl *Param = cast(DM.first); const ReturnTypestateAttr *RTA = Param->getAttr(); if (!RTA) continue; ConsumedState ExpectedState = mapReturnTypestateAttrState(RTA); if (DM.second != ExpectedState) WarningsHandler.warnParamReturnTypestateMismatch(BlameLoc, Param->getNameAsString(), stateToString(ExpectedState), stateToString(DM.second)); } } } void ConsumedStateMap::clearTemporaries() { TmpMap.clear(); } ConsumedState ConsumedStateMap::getState(const VarDecl *Var) const { VarMapType::const_iterator Entry = VarMap.find(Var); if (Entry != VarMap.end()) return Entry->second; return CS_None; } ConsumedState ConsumedStateMap::getState(const CXXBindTemporaryExpr *Tmp) const { TmpMapType::const_iterator Entry = TmpMap.find(Tmp); if (Entry != TmpMap.end()) return Entry->second; return CS_None; } void ConsumedStateMap::intersect(const ConsumedStateMap &Other) { ConsumedState LocalState; if (this->From && this->From == Other.From && !Other.Reachable) { this->markUnreachable(); return; } for (const auto &DM : Other.VarMap) { LocalState = this->getState(DM.first); if (LocalState == CS_None) continue; if (LocalState != DM.second) VarMap[DM.first] = CS_Unknown; } } void ConsumedStateMap::intersectAtLoopHead(const CFGBlock *LoopHead, const CFGBlock *LoopBack, const ConsumedStateMap *LoopBackStates, ConsumedWarningsHandlerBase &WarningsHandler) { ConsumedState LocalState; SourceLocation BlameLoc = getLastStmtLoc(LoopBack); for (const auto &DM : LoopBackStates->VarMap) { LocalState = this->getState(DM.first); if (LocalState == CS_None) continue; if (LocalState != DM.second) { VarMap[DM.first] = CS_Unknown; WarningsHandler.warnLoopStateMismatch(BlameLoc, DM.first->getNameAsString()); } } } void ConsumedStateMap::markUnreachable() { this->Reachable = false; VarMap.clear(); TmpMap.clear(); } void ConsumedStateMap::setState(const VarDecl *Var, ConsumedState State) { VarMap[Var] = State; } void ConsumedStateMap::setState(const CXXBindTemporaryExpr *Tmp, ConsumedState State) { TmpMap[Tmp] = State; } void ConsumedStateMap::remove(const CXXBindTemporaryExpr *Tmp) { TmpMap.erase(Tmp); } bool ConsumedStateMap::operator!=(const ConsumedStateMap *Other) const { for (const auto &DM : Other->VarMap) if (this->getState(DM.first) != DM.second) return true; return false; } void ConsumedAnalyzer::determineExpectedReturnState(AnalysisDeclContext &AC, const FunctionDecl *D) { QualType ReturnType; if (const CXXConstructorDecl *Constructor = dyn_cast(D)) { ASTContext &CurrContext = AC.getASTContext(); ReturnType = Constructor->getThisType(CurrContext)->getPointeeType(); } else ReturnType = D->getCallResultType(); if (const ReturnTypestateAttr *RTSAttr = D->getAttr()) { const CXXRecordDecl *RD = ReturnType->getAsCXXRecordDecl(); if (!RD || !RD->hasAttr()) { // FIXME: This should be removed when template instantiation propagates // attributes at template specialization definition, not // declaration. When it is removed the test needs to be enabled // in SemaDeclAttr.cpp. WarningsHandler.warnReturnTypestateForUnconsumableType( RTSAttr->getLocation(), ReturnType.getAsString()); ExpectedReturnState = CS_None; } else ExpectedReturnState = mapReturnTypestateAttrState(RTSAttr); } else if (isConsumableType(ReturnType)) { if (isAutoCastType(ReturnType)) // We can auto-cast the state to the ExpectedReturnState = CS_None; // expected state. else ExpectedReturnState = mapConsumableAttrState(ReturnType); } else ExpectedReturnState = CS_None; } bool ConsumedAnalyzer::splitState(const CFGBlock *CurrBlock, const ConsumedStmtVisitor &Visitor) { std::unique_ptr FalseStates( new ConsumedStateMap(*CurrStates)); PropagationInfo PInfo; if (const IfStmt *IfNode = dyn_cast_or_null(CurrBlock->getTerminator().getStmt())) { const Expr *Cond = IfNode->getCond(); PInfo = Visitor.getInfo(Cond); if (!PInfo.isValid() && isa(Cond)) PInfo = Visitor.getInfo(cast(Cond)->getRHS()); if (PInfo.isVarTest()) { CurrStates->setSource(Cond); FalseStates->setSource(Cond); splitVarStateForIf(IfNode, PInfo.getVarTest(), CurrStates.get(), FalseStates.get()); } else if (PInfo.isBinTest()) { CurrStates->setSource(PInfo.testSourceNode()); FalseStates->setSource(PInfo.testSourceNode()); splitVarStateForIfBinOp(PInfo, CurrStates.get(), FalseStates.get()); } else { return false; } } else if (const BinaryOperator *BinOp = dyn_cast_or_null(CurrBlock->getTerminator().getStmt())) { PInfo = Visitor.getInfo(BinOp->getLHS()); if (!PInfo.isVarTest()) { if ((BinOp = dyn_cast_or_null(BinOp->getLHS()))) { PInfo = Visitor.getInfo(BinOp->getRHS()); if (!PInfo.isVarTest()) return false; } else { return false; } } CurrStates->setSource(BinOp); FalseStates->setSource(BinOp); const VarTestResult &Test = PInfo.getVarTest(); ConsumedState VarState = CurrStates->getState(Test.Var); if (BinOp->getOpcode() == BO_LAnd) { if (VarState == CS_Unknown) CurrStates->setState(Test.Var, Test.TestsFor); else if (VarState == invertConsumedUnconsumed(Test.TestsFor)) CurrStates->markUnreachable(); } else if (BinOp->getOpcode() == BO_LOr) { if (VarState == CS_Unknown) FalseStates->setState(Test.Var, invertConsumedUnconsumed(Test.TestsFor)); else if (VarState == Test.TestsFor) FalseStates->markUnreachable(); } } else { return false; } CFGBlock::const_succ_iterator SI = CurrBlock->succ_begin(); if (*SI) BlockInfo.addInfo(*SI, std::move(CurrStates)); else CurrStates = nullptr; if (*++SI) BlockInfo.addInfo(*SI, std::move(FalseStates)); return true; } void ConsumedAnalyzer::run(AnalysisDeclContext &AC) { const FunctionDecl *D = dyn_cast_or_null(AC.getDecl()); if (!D) return; CFG *CFGraph = AC.getCFG(); if (!CFGraph) return; determineExpectedReturnState(AC, D); PostOrderCFGView *SortedGraph = AC.getAnalysis(); // AC.getCFG()->viewCFG(LangOptions()); BlockInfo = ConsumedBlockInfo(CFGraph->getNumBlockIDs(), SortedGraph); CurrStates = llvm::make_unique(); ConsumedStmtVisitor Visitor(AC, *this, CurrStates.get()); // Add all trackable parameters to the state map. for (const auto *PI : D->parameters()) Visitor.VisitParmVarDecl(PI); // Visit all of the function's basic blocks. for (const auto *CurrBlock : *SortedGraph) { if (!CurrStates) CurrStates = BlockInfo.getInfo(CurrBlock); if (!CurrStates) { continue; } else if (!CurrStates->isReachable()) { CurrStates = nullptr; continue; } Visitor.reset(CurrStates.get()); // Visit all of the basic block's statements. for (const auto &B : *CurrBlock) { switch (B.getKind()) { case CFGElement::Statement: Visitor.Visit(B.castAs().getStmt()); break; case CFGElement::TemporaryDtor: { const CFGTemporaryDtor &DTor = B.castAs(); const CXXBindTemporaryExpr *BTE = DTor.getBindTemporaryExpr(); Visitor.checkCallability(PropagationInfo(BTE), DTor.getDestructorDecl(AC.getASTContext()), BTE->getExprLoc()); CurrStates->remove(BTE); break; } case CFGElement::AutomaticObjectDtor: { const CFGAutomaticObjDtor &DTor = B.castAs(); SourceLocation Loc = DTor.getTriggerStmt()->getLocEnd(); const VarDecl *Var = DTor.getVarDecl(); Visitor.checkCallability(PropagationInfo(Var), DTor.getDestructorDecl(AC.getASTContext()), Loc); break; } default: break; } } // TODO: Handle other forms of branching with precision, including while- // and for-loops. (Deferred) if (!splitState(CurrBlock, Visitor)) { CurrStates->setSource(nullptr); if (CurrBlock->succ_size() > 1 || (CurrBlock->succ_size() == 1 && (*CurrBlock->succ_begin())->pred_size() > 1)) { auto *RawState = CurrStates.get(); for (CFGBlock::const_succ_iterator SI = CurrBlock->succ_begin(), SE = CurrBlock->succ_end(); SI != SE; ++SI) { if (*SI == nullptr) continue; if (BlockInfo.isBackEdge(CurrBlock, *SI)) { BlockInfo.borrowInfo(*SI)->intersectAtLoopHead( *SI, CurrBlock, RawState, WarningsHandler); if (BlockInfo.allBackEdgesVisited(CurrBlock, *SI)) BlockInfo.discardInfo(*SI); } else { BlockInfo.addInfo(*SI, RawState, CurrStates); } } CurrStates = nullptr; } } if (CurrBlock == &AC.getCFG()->getExit() && D->getCallResultType()->isVoidType()) CurrStates->checkParamsForReturnTypestate(D->getLocation(), WarningsHandler); } // End of block iterator. // Delete the last existing state map. CurrStates = nullptr; WarningsHandler.emitDiagnostics(); } }} // end namespace clang::consumed