Analysis/ValueManager.cpp - platform/external/clang - Gitiles

 // ValueManager.h - Low-level value management for Value Tracking -*- C++ -*--==
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 //  This files defines ValueManager, a class that manages the lifetime of APSInt
 //  objects and symbolic constraints used by GRExprEngine and related classes.
 //
 //===----------------------------------------------------------------------===//

 #include "clang/Analysis/PathSensitive/ValueManager.h"

 using namespace clang;

 ValueManager::~ValueManager() {
   // Note that the dstor for the contents of APSIntSet will never be called,
   // so we iterate over the set and invoke the dstor for each APSInt.  This
   // frees an aux. memory allocated to represent very large constants.
   for (APSIntSetTy::iterator I=APSIntSet.begin(), E=APSIntSet.end(); I!=E; ++I)
     I->getValue().~APSInt();
 }

 const llvm::APSInt& ValueManager::getValue(const llvm::APSInt& X) {
   llvm::FoldingSetNodeID ID;
   void* InsertPos;
   typedef llvm::FoldingSetNodeWrapper<llvm::APSInt> FoldNodeTy;

   X.Profile(ID);
   FoldNodeTy* P = APSIntSet.FindNodeOrInsertPos(ID, InsertPos);

   if (!P) {
     P = (FoldNodeTy*) BPAlloc.Allocate<FoldNodeTy>();
     new (P) FoldNodeTy(X);
     APSIntSet.InsertNode(P, InsertPos);
   }

   return *P;
 }

 const llvm::APSInt& ValueManager::getValue(uint64_t X, unsigned BitWidth,
                                            bool isUnsigned) {
   llvm::APSInt V(BitWidth, isUnsigned);
   V = X;
   return getValue(V);
 }

 const llvm::APSInt& ValueManager::getValue(uint64_t X, QualType T,
                                            SourceLocation Loc) {

   unsigned bits = Ctx.getTypeSize(T, Loc);
   llvm::APSInt V(bits, T->isUnsignedIntegerType());
   V = X;
   return getValue(V);
 }

 const SymIntConstraint&
 ValueManager::getConstraint(SymbolID sym, BinaryOperator::Opcode Op,
                             const llvm::APSInt& V) {

   llvm::FoldingSetNodeID ID;
   SymIntConstraint::Profile(ID, sym, Op, V);
   void* InsertPos;

   SymIntConstraint* C = SymIntCSet.FindNodeOrInsertPos(ID, InsertPos);

   if (!C) {
     C = (SymIntConstraint*) BPAlloc.Allocate<SymIntConstraint>();
     new (C) SymIntConstraint(sym, Op, V);
     SymIntCSet.InsertNode(C, InsertPos);
   }

   return *C;
 }

 const llvm::APSInt*
 ValueManager::EvaluateAPSInt(BinaryOperator::Opcode Op,
                              const llvm::APSInt& V1, const llvm::APSInt& V2) {

   switch (Op) {
     default:
       assert (false && "Invalid Opcode.");

     case BinaryOperator::Mul:
       return &getValue( V1 * V2 );

     case BinaryOperator::Div:
       return &getValue( V1 / V2 );

     case BinaryOperator::Rem:
       return &getValue( V1 % V2 );

     case BinaryOperator::Add:
       return &getValue( V1 + V2 );

     case BinaryOperator::Sub:
       return &getValue( V1 - V2 );

     case BinaryOperator::Shl: {

       // FIXME: This logic should probably go higher up, where we can
       // test these conditions symbolically.

       // FIXME: Expand these checks to include all undefined behavior.

       if (V2.isSigned() && V2.isNegative())
         return NULL;

       uint64_t Amt = V2.getZExtValue();

       if (Amt > V1.getBitWidth())
         return NULL;

       return &getValue( V1.operator<<( (unsigned) Amt ));
     }

     case BinaryOperator::Shr: {

       // FIXME: This logic should probably go higher up, where we can
       // test these conditions symbolically.

       // FIXME: Expand these checks to include all undefined behavior.

       if (V2.isSigned() && V2.isNegative())
         return NULL;

       uint64_t Amt = V2.getZExtValue();

       if (Amt > V1.getBitWidth())
         return NULL;

       return &getValue( V1.operator>>( (unsigned) Amt ));
     }

     case BinaryOperator::LT:
       return &getTruthValue( V1 < V2 );

     case BinaryOperator::GT:
       return &getTruthValue( V1 > V2 );

     case BinaryOperator::LE:
       return &getTruthValue( V1 <= V2 );

     case BinaryOperator::GE:
       return &getTruthValue( V1 >= V2 );

     case BinaryOperator::EQ:
       return &getTruthValue( V1 == V2 );

     case BinaryOperator::NE:
       return &getTruthValue( V1 != V2 );

       // Note: LAnd, LOr, Comma are handled specially by higher-level logic.

     case BinaryOperator::And:
       return &getValue( V1 & V2 );

     case BinaryOperator::Or:
       return &getValue( V1 | V2 );

     case BinaryOperator::Xor:
       return &getValue( V1 ^ V2 );
   }
 }
	// ValueManager.h - Low-level value management for Value Tracking -- C++ ---==
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This files defines ValueManager, a class that manages the lifetime of APSInt
	// objects and symbolic constraints used by GRExprEngine and related classes.
	//
	//===----------------------------------------------------------------------===//

	#include "clang/Analysis/PathSensitive/ValueManager.h"

	using namespace clang;

	ValueManager::~ValueManager() {
	// Note that the dstor for the contents of APSIntSet will never be called,
	// so we iterate over the set and invoke the dstor for each APSInt. This
	// frees an aux. memory allocated to represent very large constants.
	for (APSIntSetTy::iterator I=APSIntSet.begin(), E=APSIntSet.end(); I!=E; ++I)
	I->getValue().~APSInt();
	}

	const llvm::APSInt& ValueManager::getValue(const llvm::APSInt& X) {
	llvm::FoldingSetNodeID ID;
	void* InsertPos;
	typedef llvm::FoldingSetNodeWrapper<llvm::APSInt> FoldNodeTy;

	X.Profile(ID);
	FoldNodeTy* P = APSIntSet.FindNodeOrInsertPos(ID, InsertPos);

	if (!P) {
	P = (FoldNodeTy*) BPAlloc.Allocate<FoldNodeTy>();
	new (P) FoldNodeTy(X);
	APSIntSet.InsertNode(P, InsertPos);
	}

	return *P;
	}

	const llvm::APSInt& ValueManager::getValue(uint64_t X, unsigned BitWidth,
	bool isUnsigned) {
	llvm::APSInt V(BitWidth, isUnsigned);
	V = X;
	return getValue(V);
	}

	const llvm::APSInt& ValueManager::getValue(uint64_t X, QualType T,
	SourceLocation Loc) {

	unsigned bits = Ctx.getTypeSize(T, Loc);
	llvm::APSInt V(bits, T->isUnsignedIntegerType());
	V = X;
	return getValue(V);
	}

	const SymIntConstraint&
	ValueManager::getConstraint(SymbolID sym, BinaryOperator::Opcode Op,
	const llvm::APSInt& V) {

	llvm::FoldingSetNodeID ID;
	SymIntConstraint::Profile(ID, sym, Op, V);
	void* InsertPos;

	SymIntConstraint* C = SymIntCSet.FindNodeOrInsertPos(ID, InsertPos);

	if (!C) {
	C = (SymIntConstraint*) BPAlloc.Allocate<SymIntConstraint>();
	new (C) SymIntConstraint(sym, Op, V);
	SymIntCSet.InsertNode(C, InsertPos);
	}

	return *C;
	}

	const llvm::APSInt*
	ValueManager::EvaluateAPSInt(BinaryOperator::Opcode Op,
	const llvm::APSInt& V1, const llvm::APSInt& V2) {

	switch (Op) {
	default:
	assert (false && "Invalid Opcode.");

	case BinaryOperator::Mul:
	return &getValue( V1 * V2 );

	case BinaryOperator::Div:
	return &getValue( V1 / V2 );

	case BinaryOperator::Rem:
	return &getValue( V1 % V2 );

	case BinaryOperator::Add:
	return &getValue( V1 + V2 );

	case BinaryOperator::Sub:
	return &getValue( V1 - V2 );

	case BinaryOperator::Shl: {

	// FIXME: This logic should probably go higher up, where we can
	// test these conditions symbolically.

	// FIXME: Expand these checks to include all undefined behavior.

	if (V2.isSigned() && V2.isNegative())
	return NULL;

	uint64_t Amt = V2.getZExtValue();

	if (Amt > V1.getBitWidth())
	return NULL;

	return &getValue( V1.operator<<( (unsigned) Amt ));
	}

	case BinaryOperator::Shr: {

	// FIXME: This logic should probably go higher up, where we can
	// test these conditions symbolically.

	// FIXME: Expand these checks to include all undefined behavior.

	if (V2.isSigned() && V2.isNegative())
	return NULL;

	uint64_t Amt = V2.getZExtValue();

	if (Amt > V1.getBitWidth())
	return NULL;

	return &getValue( V1.operator>>( (unsigned) Amt ));
	}

	case BinaryOperator::LT:
	return &getTruthValue( V1 < V2 );

	case BinaryOperator::GT:
	return &getTruthValue( V1 > V2 );

	case BinaryOperator::LE:
	return &getTruthValue( V1 <= V2 );

	case BinaryOperator::GE:
	return &getTruthValue( V1 >= V2 );

	case BinaryOperator::EQ:
	return &getTruthValue( V1 == V2 );

	case BinaryOperator::NE:
	return &getTruthValue( V1 != V2 );

	// Note: LAnd, LOr, Comma are handled specially by higher-level logic.

	case BinaryOperator::And:
	return &getValue( V1 & V2 );

	case BinaryOperator::Or:
	return &getValue( V1 \| V2 );

	case BinaryOperator::Xor:
	return &getValue( V1 ^ V2 );
	}
	}