//== SMTConstraintManager.h -------------------------------------*- C++ -*--==// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // This file defines a SMT generic API, which will be the base class for // every SMT solver specific class. // //===----------------------------------------------------------------------===// #ifndef LLVM_CLANG_STATICANALYZER_CORE_PATHSENSITIVE_SMTCONSTRAINTMANAGER_H #define LLVM_CLANG_STATICANALYZER_CORE_PATHSENSITIVE_SMTCONSTRAINTMANAGER_H #include "clang/Basic/JsonSupport.h" #include "clang/Basic/TargetInfo.h" #include "clang/StaticAnalyzer/Core/PathSensitive/RangedConstraintManager.h" #include "clang/StaticAnalyzer/Core/PathSensitive/SMTConv.h" #include typedef llvm::ImmutableSet< std::pair> ConstraintSMTType; REGISTER_TRAIT_WITH_PROGRAMSTATE(ConstraintSMT, ConstraintSMTType) namespace clang { namespace ento { class SMTConstraintManager : public clang::ento::SimpleConstraintManager { mutable llvm::SMTSolverRef Solver = llvm::CreateZ3Solver(); public: SMTConstraintManager(clang::ento::ExprEngine *EE, clang::ento::SValBuilder &SB) : SimpleConstraintManager(EE, SB) {} virtual ~SMTConstraintManager() = default; //===------------------------------------------------------------------===// // Implementation for interface from SimpleConstraintManager. //===------------------------------------------------------------------===// ProgramStateRef assumeSym(ProgramStateRef State, SymbolRef Sym, bool Assumption) override { ASTContext &Ctx = getBasicVals().getContext(); QualType RetTy; bool hasComparison; llvm::SMTExprRef Exp = SMTConv::getExpr(Solver, Ctx, Sym, &RetTy, &hasComparison); // Create zero comparison for implicit boolean cast, with reversed // assumption if (!hasComparison && !RetTy->isBooleanType()) return assumeExpr( State, Sym, SMTConv::getZeroExpr(Solver, Ctx, Exp, RetTy, !Assumption)); return assumeExpr(State, Sym, Assumption ? Exp : Solver->mkNot(Exp)); } ProgramStateRef assumeSymInclusiveRange(ProgramStateRef State, SymbolRef Sym, const llvm::APSInt &From, const llvm::APSInt &To, bool InRange) override { ASTContext &Ctx = getBasicVals().getContext(); return assumeExpr( State, Sym, SMTConv::getRangeExpr(Solver, Ctx, Sym, From, To, InRange)); } ProgramStateRef assumeSymUnsupported(ProgramStateRef State, SymbolRef Sym, bool Assumption) override { // Skip anything that is unsupported return State; } //===------------------------------------------------------------------===// // Implementation for interface from ConstraintManager. //===------------------------------------------------------------------===// ConditionTruthVal checkNull(ProgramStateRef State, SymbolRef Sym) override { ASTContext &Ctx = getBasicVals().getContext(); QualType RetTy; // The expression may be casted, so we cannot call getZ3DataExpr() directly llvm::SMTExprRef VarExp = SMTConv::getExpr(Solver, Ctx, Sym, &RetTy); llvm::SMTExprRef Exp = SMTConv::getZeroExpr(Solver, Ctx, VarExp, RetTy, /*Assumption=*/true); // Negate the constraint llvm::SMTExprRef NotExp = SMTConv::getZeroExpr(Solver, Ctx, VarExp, RetTy, /*Assumption=*/false); ConditionTruthVal isSat = checkModel(State, Sym, Exp); ConditionTruthVal isNotSat = checkModel(State, Sym, NotExp); // Zero is the only possible solution if (isSat.isConstrainedTrue() && isNotSat.isConstrainedFalse()) return true; // Zero is not a solution if (isSat.isConstrainedFalse() && isNotSat.isConstrainedTrue()) return false; // Zero may be a solution return ConditionTruthVal(); } const llvm::APSInt *getSymVal(ProgramStateRef State, SymbolRef Sym) const override { BasicValueFactory &BVF = getBasicVals(); ASTContext &Ctx = BVF.getContext(); if (const SymbolData *SD = dyn_cast(Sym)) { QualType Ty = Sym->getType(); assert(!Ty->isRealFloatingType()); llvm::APSInt Value(Ctx.getTypeSize(Ty), !Ty->isSignedIntegerOrEnumerationType()); // TODO: this should call checkModel so we can use the cache, however, // this method tries to get the interpretation (the actual value) from // the solver, which is currently not cached. llvm::SMTExprRef Exp = SMTConv::fromData(Solver, Ctx, SD); Solver->reset(); addStateConstraints(State); // Constraints are unsatisfiable std::optional isSat = Solver->check(); if (!isSat || !*isSat) return nullptr; // Model does not assign interpretation if (!Solver->getInterpretation(Exp, Value)) return nullptr; // A value has been obtained, check if it is the only value llvm::SMTExprRef NotExp = SMTConv::fromBinOp( Solver, Exp, BO_NE, Ty->isBooleanType() ? Solver->mkBoolean(Value.getBoolValue()) : Solver->mkBitvector(Value, Value.getBitWidth()), /*isSigned=*/false); Solver->addConstraint(NotExp); std::optional isNotSat = Solver->check(); if (!isNotSat || *isNotSat) return nullptr; // This is the only solution, store it return &BVF.getValue(Value); } if (const SymbolCast *SC = dyn_cast(Sym)) { SymbolRef CastSym = SC->getOperand(); QualType CastTy = SC->getType(); // Skip the void type if (CastTy->isVoidType()) return nullptr; const llvm::APSInt *Value; if (!(Value = getSymVal(State, CastSym))) return nullptr; return &BVF.Convert(SC->getType(), *Value); } if (const BinarySymExpr *BSE = dyn_cast(Sym)) { const llvm::APSInt *LHS, *RHS; if (const SymIntExpr *SIE = dyn_cast(BSE)) { LHS = getSymVal(State, SIE->getLHS()); RHS = &SIE->getRHS(); } else if (const IntSymExpr *ISE = dyn_cast(BSE)) { LHS = &ISE->getLHS(); RHS = getSymVal(State, ISE->getRHS()); } else if (const SymSymExpr *SSM = dyn_cast(BSE)) { // Early termination to avoid expensive call LHS = getSymVal(State, SSM->getLHS()); RHS = LHS ? getSymVal(State, SSM->getRHS()) : nullptr; } else { llvm_unreachable("Unsupported binary expression to get symbol value!"); } if (!LHS || !RHS) return nullptr; llvm::APSInt ConvertedLHS, ConvertedRHS; QualType LTy, RTy; std::tie(ConvertedLHS, LTy) = SMTConv::fixAPSInt(Ctx, *LHS); std::tie(ConvertedRHS, RTy) = SMTConv::fixAPSInt(Ctx, *RHS); SMTConv::doIntTypeConversion( Solver, Ctx, ConvertedLHS, LTy, ConvertedRHS, RTy); return BVF.evalAPSInt(BSE->getOpcode(), ConvertedLHS, ConvertedRHS); } llvm_unreachable("Unsupported expression to get symbol value!"); } ProgramStateRef removeDeadBindings(ProgramStateRef State, SymbolReaper &SymReaper) override { auto CZ = State->get(); auto &CZFactory = State->get_context(); for (const auto &Entry : CZ) { if (SymReaper.isDead(Entry.first)) CZ = CZFactory.remove(CZ, Entry); } return State->set(CZ); } void printJson(raw_ostream &Out, ProgramStateRef State, const char *NL = "\n", unsigned int Space = 0, bool IsDot = false) const override { ConstraintSMTType Constraints = State->get(); Indent(Out, Space, IsDot) << "\"constraints\": "; if (Constraints.isEmpty()) { Out << "null," << NL; return; } ++Space; Out << '[' << NL; for (ConstraintSMTType::iterator I = Constraints.begin(); I != Constraints.end(); ++I) { Indent(Out, Space, IsDot) << "{ \"symbol\": \"" << I->first << "\", \"range\": \""; I->second->print(Out); Out << "\" }"; if (std::next(I) != Constraints.end()) Out << ','; Out << NL; } --Space; Indent(Out, Space, IsDot) << "],"; } bool haveEqualConstraints(ProgramStateRef S1, ProgramStateRef S2) const override { return S1->get() == S2->get(); } bool canReasonAbout(SVal X) const override { const TargetInfo &TI = getBasicVals().getContext().getTargetInfo(); std::optional SymVal = X.getAs(); if (!SymVal) return true; const SymExpr *Sym = SymVal->getSymbol(); QualType Ty = Sym->getType(); // Complex types are not modeled if (Ty->isComplexType() || Ty->isComplexIntegerType()) return false; // Non-IEEE 754 floating-point types are not modeled if ((Ty->isSpecificBuiltinType(BuiltinType::LongDouble) && (&TI.getLongDoubleFormat() == &llvm::APFloat::x87DoubleExtended() || &TI.getLongDoubleFormat() == &llvm::APFloat::PPCDoubleDouble()))) return false; if (Ty->isRealFloatingType()) return Solver->isFPSupported(); if (isa(Sym)) return true; SValBuilder &SVB = getSValBuilder(); if (const SymbolCast *SC = dyn_cast(Sym)) return canReasonAbout(SVB.makeSymbolVal(SC->getOperand())); if (const BinarySymExpr *BSE = dyn_cast(Sym)) { if (const SymIntExpr *SIE = dyn_cast(BSE)) return canReasonAbout(SVB.makeSymbolVal(SIE->getLHS())); if (const IntSymExpr *ISE = dyn_cast(BSE)) return canReasonAbout(SVB.makeSymbolVal(ISE->getRHS())); if (const SymSymExpr *SSE = dyn_cast(BSE)) return canReasonAbout(SVB.makeSymbolVal(SSE->getLHS())) && canReasonAbout(SVB.makeSymbolVal(SSE->getRHS())); } llvm_unreachable("Unsupported expression to reason about!"); } /// Dumps SMT formula LLVM_DUMP_METHOD void dump() const { Solver->dump(); } protected: // Check whether a new model is satisfiable, and update the program state. virtual ProgramStateRef assumeExpr(ProgramStateRef State, SymbolRef Sym, const llvm::SMTExprRef &Exp) { // Check the model, avoid simplifying AST to save time if (checkModel(State, Sym, Exp).isConstrainedTrue()) return State->add(std::make_pair(Sym, Exp)); return nullptr; } /// Given a program state, construct the logical conjunction and add it to /// the solver virtual void addStateConstraints(ProgramStateRef State) const { // TODO: Don't add all the constraints, only the relevant ones auto CZ = State->get(); auto I = CZ.begin(), IE = CZ.end(); // Construct the logical AND of all the constraints if (I != IE) { std::vector ASTs; llvm::SMTExprRef Constraint = I++->second; while (I != IE) { Constraint = Solver->mkAnd(Constraint, I++->second); } Solver->addConstraint(Constraint); } } // Generate and check a Z3 model, using the given constraint. ConditionTruthVal checkModel(ProgramStateRef State, SymbolRef Sym, const llvm::SMTExprRef &Exp) const { ProgramStateRef NewState = State->add(std::make_pair(Sym, Exp)); llvm::FoldingSetNodeID ID; NewState->get().Profile(ID); unsigned hash = ID.ComputeHash(); auto I = Cached.find(hash); if (I != Cached.end()) return I->second; Solver->reset(); addStateConstraints(NewState); std::optional res = Solver->check(); if (!res) Cached[hash] = ConditionTruthVal(); else Cached[hash] = ConditionTruthVal(*res); return Cached[hash]; } // Cache the result of an SMT query (true, false, unknown). The key is the // hash of the constraints in a state mutable llvm::DenseMap Cached; }; // end class SMTConstraintManager } // namespace ento } // namespace clang #endif