forked from OSchip/llvm-project
287 lines
9.5 KiB
C++
287 lines
9.5 KiB
C++
//== SimpleConstraintManager.cpp --------------------------------*- C++ -*--==//
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//
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// The LLVM Compiler Infrastructure
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//
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// This file is distributed under the University of Illinois Open Source
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// License. See LICENSE.TXT for details.
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//
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//===----------------------------------------------------------------------===//
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//
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// This file defines SimpleConstraintManager, a class that holds code shared
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// between BasicConstraintManager and RangeConstraintManager.
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//
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//===----------------------------------------------------------------------===//
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#include "SimpleConstraintManager.h"
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#include "clang/StaticAnalyzer/Core/PathSensitive/APSIntType.h"
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#include "clang/StaticAnalyzer/Core/PathSensitive/ExprEngine.h"
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#include "clang/StaticAnalyzer/Core/PathSensitive/ProgramState.h"
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namespace clang {
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namespace ento {
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SimpleConstraintManager::~SimpleConstraintManager() {}
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bool SimpleConstraintManager::canReasonAbout(SVal X) const {
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nonloc::SymbolVal *SymVal = dyn_cast<nonloc::SymbolVal>(&X);
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if (SymVal && SymVal->isExpression()) {
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const SymExpr *SE = SymVal->getSymbol();
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if (const SymIntExpr *SIE = dyn_cast<SymIntExpr>(SE)) {
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switch (SIE->getOpcode()) {
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// We don't reason yet about bitwise-constraints on symbolic values.
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case BO_And:
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case BO_Or:
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case BO_Xor:
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return false;
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// We don't reason yet about these arithmetic constraints on
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// symbolic values.
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case BO_Mul:
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case BO_Div:
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case BO_Rem:
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case BO_Shl:
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case BO_Shr:
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return false;
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// All other cases.
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default:
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return true;
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}
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}
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return false;
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}
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return true;
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}
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ProgramStateRef SimpleConstraintManager::assume(ProgramStateRef state,
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DefinedSVal Cond,
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bool Assumption) {
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if (isa<NonLoc>(Cond))
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return assume(state, cast<NonLoc>(Cond), Assumption);
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else
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return assume(state, cast<Loc>(Cond), Assumption);
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}
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ProgramStateRef SimpleConstraintManager::assume(ProgramStateRef state, Loc cond,
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bool assumption) {
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state = assumeAux(state, cond, assumption);
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return SU.processAssume(state, cond, assumption);
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}
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ProgramStateRef SimpleConstraintManager::assumeAux(ProgramStateRef state,
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Loc Cond, bool Assumption) {
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switch (Cond.getSubKind()) {
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default:
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assert (false && "'Assume' not implemented for this Loc.");
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return state;
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case loc::MemRegionKind: {
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// FIXME: Should this go into the storemanager?
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const MemRegion *R = cast<loc::MemRegionVal>(Cond).getRegion();
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const SubRegion *SubR = dyn_cast<SubRegion>(R);
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while (SubR) {
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// FIXME: now we only find the first symbolic region.
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if (const SymbolicRegion *SymR = dyn_cast<SymbolicRegion>(SubR)) {
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const llvm::APSInt &zero = getBasicVals().getZeroWithPtrWidth();
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if (Assumption)
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return assumeSymNE(state, SymR->getSymbol(), zero, zero);
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else
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return assumeSymEQ(state, SymR->getSymbol(), zero, zero);
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}
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SubR = dyn_cast<SubRegion>(SubR->getSuperRegion());
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}
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// FALL-THROUGH.
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}
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case loc::GotoLabelKind:
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return Assumption ? state : NULL;
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case loc::ConcreteIntKind: {
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bool b = cast<loc::ConcreteInt>(Cond).getValue() != 0;
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bool isFeasible = b ? Assumption : !Assumption;
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return isFeasible ? state : NULL;
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}
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} // end switch
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}
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ProgramStateRef SimpleConstraintManager::assume(ProgramStateRef state,
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NonLoc cond,
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bool assumption) {
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state = assumeAux(state, cond, assumption);
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return SU.processAssume(state, cond, assumption);
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}
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static BinaryOperator::Opcode NegateComparison(BinaryOperator::Opcode op) {
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// FIXME: This should probably be part of BinaryOperator, since this isn't
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// the only place it's used. (This code was copied from SimpleSValBuilder.cpp.)
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switch (op) {
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default:
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llvm_unreachable("Invalid opcode.");
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case BO_LT: return BO_GE;
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case BO_GT: return BO_LE;
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case BO_LE: return BO_GT;
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case BO_GE: return BO_LT;
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case BO_EQ: return BO_NE;
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case BO_NE: return BO_EQ;
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}
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}
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ProgramStateRef
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SimpleConstraintManager::assumeAuxForSymbol(ProgramStateRef State,
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SymbolRef Sym, bool Assumption) {
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BasicValueFactory &BVF = getBasicVals();
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QualType T = Sym->getType(BVF.getContext());
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// None of the constraint solvers currently support non-integer types.
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if (!T->isIntegerType())
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return State;
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const llvm::APSInt &zero = BVF.getValue(0, T);
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if (Assumption)
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return assumeSymNE(State, Sym, zero, zero);
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else
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return assumeSymEQ(State, Sym, zero, zero);
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}
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ProgramStateRef SimpleConstraintManager::assumeAux(ProgramStateRef state,
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NonLoc Cond,
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bool Assumption) {
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// We cannot reason about SymSymExprs, and can only reason about some
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// SymIntExprs.
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if (!canReasonAbout(Cond)) {
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// Just add the constraint to the expression without trying to simplify.
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SymbolRef sym = Cond.getAsSymExpr();
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return assumeAuxForSymbol(state, sym, Assumption);
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}
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BasicValueFactory &BasicVals = getBasicVals();
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switch (Cond.getSubKind()) {
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default:
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llvm_unreachable("'Assume' not implemented for this NonLoc");
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case nonloc::SymbolValKind: {
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nonloc::SymbolVal& SV = cast<nonloc::SymbolVal>(Cond);
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SymbolRef sym = SV.getSymbol();
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assert(sym);
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// Handle SymbolData.
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if (!SV.isExpression()) {
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return assumeAuxForSymbol(state, sym, Assumption);
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// Handle symbolic expression.
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} else {
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// We can only simplify expressions whose RHS is an integer.
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const SymIntExpr *SE = dyn_cast<SymIntExpr>(sym);
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if (!SE)
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return assumeAuxForSymbol(state, sym, Assumption);
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BinaryOperator::Opcode op = SE->getOpcode();
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// Implicitly compare non-comparison expressions to 0.
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if (!BinaryOperator::isComparisonOp(op)) {
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QualType T = SE->getType(BasicVals.getContext());
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const llvm::APSInt &zero = BasicVals.getValue(0, T);
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op = (Assumption ? BO_NE : BO_EQ);
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return assumeSymRel(state, SE, op, zero);
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}
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// From here on out, op is the real comparison we'll be testing.
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if (!Assumption)
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op = NegateComparison(op);
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return assumeSymRel(state, SE->getLHS(), op, SE->getRHS());
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}
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}
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case nonloc::ConcreteIntKind: {
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bool b = cast<nonloc::ConcreteInt>(Cond).getValue() != 0;
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bool isFeasible = b ? Assumption : !Assumption;
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return isFeasible ? state : NULL;
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}
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case nonloc::LocAsIntegerKind:
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return assumeAux(state, cast<nonloc::LocAsInteger>(Cond).getLoc(),
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Assumption);
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} // end switch
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}
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static void computeAdjustment(SymbolRef &Sym, llvm::APSInt &Adjustment) {
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// Is it a "($sym+constant1)" expression?
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if (const SymIntExpr *SE = dyn_cast<SymIntExpr>(Sym)) {
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BinaryOperator::Opcode Op = SE->getOpcode();
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if (Op == BO_Add || Op == BO_Sub) {
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Sym = SE->getLHS();
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Adjustment = APSIntType(Adjustment).convert(SE->getRHS());
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// Don't forget to negate the adjustment if it's being subtracted.
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// This should happen /after/ promotion, in case the value being
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// subtracted is, say, CHAR_MIN, and the promoted type is 'int'.
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if (Op == BO_Sub)
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Adjustment = -Adjustment;
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}
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}
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}
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ProgramStateRef SimpleConstraintManager::assumeSymRel(ProgramStateRef state,
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const SymExpr *LHS,
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BinaryOperator::Opcode op,
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const llvm::APSInt& Int) {
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assert(BinaryOperator::isComparisonOp(op) &&
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"Non-comparison ops should be rewritten as comparisons to zero.");
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BasicValueFactory &BVF = getBasicVals();
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ASTContext &Ctx = BVF.getContext();
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// Get the type used for calculating wraparound.
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APSIntType WraparoundType = BVF.getAPSIntType(LHS->getType(Ctx));
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// We only handle simple comparisons of the form "$sym == constant"
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// or "($sym+constant1) == constant2".
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// The adjustment is "constant1" in the above expression. It's used to
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// "slide" the solution range around for modular arithmetic. For example,
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// x < 4 has the solution [0, 3]. x+2 < 4 has the solution [0-2, 3-2], which
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// in modular arithmetic is [0, 1] U [UINT_MAX-1, UINT_MAX]. It's up to
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// the subclasses of SimpleConstraintManager to handle the adjustment.
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SymbolRef Sym = LHS;
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llvm::APSInt Adjustment = WraparoundType.getZeroValue();
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computeAdjustment(Sym, Adjustment);
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// Convert the right-hand side integer as necessary.
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APSIntType ComparisonType = std::max(WraparoundType, APSIntType(Int));
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llvm::APSInt ConvertedInt = ComparisonType.convert(Int);
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switch (op) {
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default:
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// No logic yet for other operators. assume the constraint is feasible.
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return state;
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case BO_EQ:
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return assumeSymEQ(state, Sym, ConvertedInt, Adjustment);
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case BO_NE:
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return assumeSymNE(state, Sym, ConvertedInt, Adjustment);
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case BO_GT:
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return assumeSymGT(state, Sym, ConvertedInt, Adjustment);
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case BO_GE:
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return assumeSymGE(state, Sym, ConvertedInt, Adjustment);
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case BO_LT:
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return assumeSymLT(state, Sym, ConvertedInt, Adjustment);
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case BO_LE:
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return assumeSymLE(state, Sym, ConvertedInt, Adjustment);
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} // end switch
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}
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} // end of namespace ento
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} // end of namespace clang
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