path: root/include/clang/Analysis/PathSensitive/SVals.h

//== SVals.h - Abstract Values for Static Analysis ---------*- 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 SVal, Loc, and NonLoc, classes that represent
//  abstract r-values for use with path-sensitive value tracking.
//
//===----------------------------------------------------------------------===//

#ifndef LLVM_CLANG_ANALYSIS_RVALUE_H
#define LLVM_CLANG_ANALYSIS_RVALUE_H

#include "clang/Analysis/PathSensitive/SymbolManager.h"
#include "llvm/Support/Casting.h"
#include "llvm/ADT/ImmutableList.h"

namespace llvm {
  class raw_ostream;
}

//==------------------------------------------------------------------------==//
//  Base SVal types.
//==------------------------------------------------------------------------==//

namespace clang {

class CompoundValData;
class LazyCompoundValData;
class GRState;
class BasicValueFactory;
class MemRegion;
class TypedRegion;
class MemRegionManager;
class GRStateManager;
class ValueManager;

class SVal {
public:
  enum BaseKind { UndefinedKind, UnknownKind, LocKind, NonLocKind };
  enum { BaseBits = 2, BaseMask = 0x3 };

protected:
  void* Data;
  unsigned Kind;

protected:
  SVal(const void* d, bool isLoc, unsigned ValKind)
  : Data(const_cast<void*>(d)),
    Kind((isLoc ? LocKind : NonLocKind) | (ValKind << BaseBits)) {}

  explicit SVal(BaseKind k, void* D = NULL)
    : Data(D), Kind(k) {}

public:
  SVal() : Data(0), Kind(0) {}
  ~SVal() {}

  /// BufferTy - A temporary buffer to hold a set of SVals.
  typedef llvm::SmallVector<SVal,5> BufferTy;

  inline unsigned getRawKind() const { return Kind; }
  inline BaseKind getBaseKind() const { return (BaseKind) (Kind & BaseMask); }
  inline unsigned getSubKind() const { return (Kind & ~BaseMask) >> BaseBits; }

  inline void Profile(llvm::FoldingSetNodeID& ID) const {
    ID.AddInteger((unsigned) getRawKind());
    ID.AddPointer(reinterpret_cast<void*>(Data));
  }

  inline bool operator==(const SVal& R) const {
    return getRawKind() == R.getRawKind() && Data == R.Data;
  }

  inline bool operator!=(const SVal& R) const {
    return !(*this == R);
  }

  inline bool isUnknown() const {
    return getRawKind() == UnknownKind;
  }

  inline bool isUndef() const {
    return getRawKind() == UndefinedKind;
  }

  inline bool isUnknownOrUndef() const {
    return getRawKind() <= UnknownKind;
  }

  inline bool isValid() const {
    return getRawKind() > UnknownKind;
  }

  bool isConstant() const;

  bool isZeroConstant() const;

  /// hasConjuredSymbol - If this SVal wraps a conjured symbol, return true;
  bool hasConjuredSymbol() const;

  /// getAsFunctionDecl - If this SVal is a MemRegionVal and wraps a
  /// CodeTextRegion wrapping a FunctionDecl, return that FunctionDecl.
  /// Otherwise return 0.
  const FunctionDecl* getAsFunctionDecl() const;

  /// getAsLocSymbol - If this SVal is a location (subclasses Loc) and
  ///  wraps a symbol, return that SymbolRef.  Otherwise return a SymbolData*
  SymbolRef getAsLocSymbol() const;

  /// getAsSymbol - If this Sval wraps a symbol return that SymbolRef.
  ///  Otherwise return a SymbolRef where 'isValid()' returns false.
  SymbolRef getAsSymbol() const;

  /// getAsSymbolicExpression - If this Sval wraps a symbolic expression then
  ///  return that expression.  Otherwise return NULL.
  const SymExpr *getAsSymbolicExpression() const;

  const MemRegion *getAsRegion() const;

  void dumpToStream(llvm::raw_ostream& OS) const;
  void dump() const;

  // Iterators.
  class symbol_iterator {
    llvm::SmallVector<const SymExpr*, 5> itr;
    void expand();
  public:
    symbol_iterator() {}
    symbol_iterator(const SymExpr* SE);

    symbol_iterator& operator++();
    SymbolRef operator*();

    bool operator==(const symbol_iterator& X) const;
    bool operator!=(const symbol_iterator& X) const;
  };

  symbol_iterator symbol_begin() const {
    const SymExpr *SE = getAsSymbolicExpression();
    if (SE)
      return symbol_iterator(SE);
    else
      return symbol_iterator();
  }

  symbol_iterator symbol_end() const { return symbol_iterator(); }

  // Implement isa<T> support.
  static inline bool classof(const SVal*) { return true; }
};


class UndefinedVal : public SVal {
public:
  UndefinedVal() : SVal(UndefinedKind) {}
  UndefinedVal(void* D) : SVal(UndefinedKind, D) {}

  static inline bool classof(const SVal* V) {
    return V->getBaseKind() == UndefinedKind;
  }

  void* getData() const { return Data; }
};

class DefinedOrUnknownSVal : public SVal {
private:
  // Do not implement.  We want calling these methods to be a compiler
  // error since they are tautologically false.
  bool isUndef() const;
  bool isValid() const;
  
protected:
  explicit DefinedOrUnknownSVal(const void* d, bool isLoc, unsigned ValKind)
    : SVal(d, isLoc, ValKind) {}
  
  explicit DefinedOrUnknownSVal(BaseKind k, void *D = NULL)
    : SVal(k, D) {}
  
public:
    // Implement isa<T> support.
  static inline bool classof(const SVal *V) {
    return !V->isUndef();
  }
};
  
class UnknownVal : public DefinedOrUnknownSVal {
public:
  UnknownVal() : DefinedOrUnknownSVal(UnknownKind) {}
  
  static inline bool classof(const SVal *V) {
    return V->getBaseKind() == UnknownKind;
  }
};
  
class DefinedSVal : public DefinedOrUnknownSVal {
private:
  // Do not implement.  We want calling these methods to be a compiler
  // error since they are tautologically true/false.
  bool isUnknown() const;
  bool isUnknownOrUndef() const;
  bool isValid() const;  
protected:
  DefinedSVal(const void* d, bool isLoc, unsigned ValKind)
    : DefinedOrUnknownSVal(d, isLoc, ValKind) {}
public:
  // Implement isa<T> support.
  static inline bool classof(const SVal *V) {
    return !V->isUnknownOrUndef();
  }
};

class NonLoc : public DefinedSVal {
protected:
  NonLoc(unsigned SubKind, const void* d) : DefinedSVal(d, false, SubKind) {}

public:
  void dumpToStream(llvm::raw_ostream& Out) const;

  // Implement isa<T> support.
  static inline bool classof(const SVal* V) {
    return V->getBaseKind() == NonLocKind;
  }
};

class Loc : public DefinedSVal {
protected:
  Loc(unsigned SubKind, const void* D)
  : DefinedSVal(const_cast<void*>(D), true, SubKind) {}

public:
  void dumpToStream(llvm::raw_ostream& Out) const;

  Loc(const Loc& X) : DefinedSVal(X.Data, true, X.getSubKind()) {}
  Loc& operator=(const Loc& X) { memcpy(this, &X, sizeof(Loc)); return *this; }

  // Implement isa<T> support.
  static inline bool classof(const SVal* V) {
    return V->getBaseKind() == LocKind;
  }

  static inline bool IsLocType(QualType T) {
    return T->isAnyPointerType() || T->isBlockPointerType() || 
           T->isReferenceType();
  }
};

//==------------------------------------------------------------------------==//
//  Subclasses of NonLoc.
//==------------------------------------------------------------------------==//

namespace nonloc {

enum Kind { ConcreteIntKind, SymbolValKind, SymExprValKind,
            LocAsIntegerKind, CompoundValKind, LazyCompoundValKind };

class SymbolVal : public NonLoc {
public:
  SymbolVal(SymbolRef sym) : NonLoc(SymbolValKind, sym) {}

  SymbolRef getSymbol() const {
    return (const SymbolData*) Data;
  }

  static inline bool classof(const SVal* V) {
    return V->getBaseKind() == NonLocKind &&
           V->getSubKind() == SymbolValKind;
  }

  static inline bool classof(const NonLoc* V) {
    return V->getSubKind() == SymbolValKind;
  }
};

class SymExprVal : public NonLoc {
public:
  SymExprVal(const SymExpr *SE)
    : NonLoc(SymExprValKind, reinterpret_cast<const void*>(SE)) {}

  const SymExpr *getSymbolicExpression() const {
    return reinterpret_cast<SymExpr*>(Data);
  }

  static inline bool classof(const SVal* V) {
    return V->getBaseKind() == NonLocKind &&
           V->getSubKind() == SymExprValKind;
  }

  static inline bool classof(const NonLoc* V) {
    return V->getSubKind() == SymExprValKind;
  }
};

class ConcreteInt : public NonLoc {
public:
  ConcreteInt(const llvm::APSInt& V) : NonLoc(ConcreteIntKind, &V) {}

  const llvm::APSInt& getValue() const {
    return *static_cast<llvm::APSInt*>(Data);
  }

  // Transfer functions for binary/unary operations on ConcreteInts.
  SVal evalBinOp(ValueManager &ValMgr, BinaryOperator::Opcode Op,
                 const ConcreteInt& R) const;

  ConcreteInt evalComplement(ValueManager &ValMgr) const;

  ConcreteInt evalMinus(ValueManager &ValMgr) const;

  // Implement isa<T> support.
  static inline bool classof(const SVal* V) {
    return V->getBaseKind() == NonLocKind &&
           V->getSubKind() == ConcreteIntKind;
  }

  static inline bool classof(const NonLoc* V) {
    return V->getSubKind() == ConcreteIntKind;
  }
};

class LocAsInteger : public NonLoc {
  friend class clang::ValueManager;

  LocAsInteger(const std::pair<SVal, uintptr_t>& data) :
    NonLoc(LocAsIntegerKind, &data) {
      assert (isa<Loc>(data.first));
    }

public:

  Loc getLoc() const {
    return cast<Loc>(((std::pair<SVal, uintptr_t>*) Data)->first);
  }

  const Loc& getPersistentLoc() const {
    const SVal& V = ((std::pair<SVal, uintptr_t>*) Data)->first;
    return cast<Loc>(V);
  }

  unsigned getNumBits() const {
    return ((std::pair<SVal, unsigned>*) Data)->second;
  }

  // Implement isa<T> support.
  static inline bool classof(const SVal* V) {
    return V->getBaseKind() == NonLocKind &&
           V->getSubKind() == LocAsIntegerKind;
  }

  static inline bool classof(const NonLoc* V) {
    return V->getSubKind() == LocAsIntegerKind;
  }
};

class CompoundVal : public NonLoc {
  friend class clang::ValueManager;

  CompoundVal(const CompoundValData* D) : NonLoc(CompoundValKind, D) {}

public:
  const CompoundValData* getValue() const {
    return static_cast<CompoundValData*>(Data);
  }

  typedef llvm::ImmutableList<SVal>::iterator iterator;
  iterator begin() const;
  iterator end() const;

  static bool classof(const SVal* V) {
    return V->getBaseKind() == NonLocKind && V->getSubKind() == CompoundValKind;
  }

  static bool classof(const NonLoc* V) {
    return V->getSubKind() == CompoundValKind;
  }
};

class LazyCompoundVal : public NonLoc {
  friend class clang::ValueManager;

  LazyCompoundVal(const LazyCompoundValData *D)
    : NonLoc(LazyCompoundValKind, D) {}
public:
  const LazyCompoundValData *getCVData() const {
    return static_cast<const LazyCompoundValData*>(Data);
  }
  const GRState *getState() const;
  const TypedRegion *getRegion() const;

  static bool classof(const SVal *V) {
    return V->getBaseKind() == NonLocKind &&
           V->getSubKind() == LazyCompoundValKind;
  }
  static bool classof(const NonLoc *V) {
    return V->getSubKind() == LazyCompoundValKind;
  }
};

} // end namespace clang::nonloc

//==------------------------------------------------------------------------==//
//  Subclasses of Loc.
//==------------------------------------------------------------------------==//

namespace loc {

enum Kind { GotoLabelKind, MemRegionKind, ConcreteIntKind };

class GotoLabel : public Loc {
public:
  GotoLabel(LabelStmt* Label) : Loc(GotoLabelKind, Label) {}

  LabelStmt* getLabel() const {
    return static_cast<LabelStmt*>(Data);
  }

  static inline bool classof(const SVal* V) {
    return V->getBaseKind() == LocKind &&
           V->getSubKind() == GotoLabelKind;
  }

  static inline bool classof(const Loc* V) {
    return V->getSubKind() == GotoLabelKind;
  }
};


class MemRegionVal : public Loc {
public:
  MemRegionVal(const MemRegion* r) : Loc(MemRegionKind, r) {}

  const MemRegion* getRegion() const {
    return static_cast<MemRegion*>(Data);
  }

  const MemRegion* StripCasts() const;

  template <typename REGION>
  const REGION* getRegionAs() const {
    return llvm::dyn_cast<REGION>(getRegion());
  }

  inline bool operator==(const MemRegionVal& R) const {
    return getRegion() == R.getRegion();
  }

  inline bool operator!=(const MemRegionVal& R) const {
    return getRegion() != R.getRegion();
  }

  // Implement isa<T> support.
  static inline bool classof(const SVal* V) {
    return V->getBaseKind() == LocKind &&
           V->getSubKind() == MemRegionKind;
  }

  static inline bool classof(const Loc* V) {
    return V->getSubKind() == MemRegionKind;
  }
};

class ConcreteInt : public Loc {
public:
  ConcreteInt(const llvm::APSInt& V) : Loc(ConcreteIntKind, &V) {}

  const llvm::APSInt& getValue() const {
    return *static_cast<llvm::APSInt*>(Data);
  }

  // Transfer functions for binary/unary operations on ConcreteInts.
  SVal EvalBinOp(BasicValueFactory& BasicVals, BinaryOperator::Opcode Op,
                 const ConcreteInt& R) const;

  // Implement isa<T> support.
  static inline bool classof(const SVal* V) {
    return V->getBaseKind() == LocKind &&
           V->getSubKind() == ConcreteIntKind;
  }

  static inline bool classof(const Loc* V) {
    return V->getSubKind() == ConcreteIntKind;
  }
};

} // end clang::loc namespace
} // end clang namespace

namespace llvm {
static inline llvm::raw_ostream& operator<<(llvm::raw_ostream& os,
                                            clang::SVal V) {
  V.dumpToStream(os);
  return os;
}
} // end llvm namespace
#endif