include/llvm/ADT/APSInt.h - llvm - Git at Google

 //===-- llvm/ADT/APSInt.h - Arbitrary Precision Signed Int -----*- 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 implements the APSInt class, which is a simple class that
 // represents an arbitrary sized integer that knows its signedness.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_ADT_APSINT_H
 #define LLVM_ADT_APSINT_H

 #include "llvm/ADT/APInt.h"

 namespace llvm {

 class LLVM_NODISCARD APSInt : public APInt {
   bool IsUnsigned;

 public:
   /// Default constructor that creates an uninitialized APInt.
   explicit APSInt() : IsUnsigned(false) {}

   /// APSInt ctor - Create an APSInt with the specified width, default to
   /// unsigned.
   explicit APSInt(uint32_t BitWidth, bool isUnsigned = true)
    : APInt(BitWidth, 0), IsUnsigned(isUnsigned) {}

   explicit APSInt(APInt I, bool isUnsigned = true)
    : APInt(std::move(I)), IsUnsigned(isUnsigned) {}

   /// Construct an APSInt from a string representation.
   ///
   /// This constructor interprets the string \p Str using the radix of 10.
   /// The interpretation stops at the end of the string. The bit width of the
   /// constructed APSInt is determined automatically.
   ///
   /// \param Str the string to be interpreted.
   explicit APSInt(StringRef Str);

   APSInt &operator=(APInt RHS) {
     // Retain our current sign.
     APInt::operator=(std::move(RHS));
     return *this;
   }

   APSInt &operator=(uint64_t RHS) {
     // Retain our current sign.
     APInt::operator=(RHS);
     return *this;
   }

   // Query sign information.
   bool isSigned() const { return !IsUnsigned; }
   bool isUnsigned() const { return IsUnsigned; }
   void setIsUnsigned(bool Val) { IsUnsigned = Val; }
   void setIsSigned(bool Val) { IsUnsigned = !Val; }

   /// toString - Append this APSInt to the specified SmallString.
   void toString(SmallVectorImpl<char> &Str, unsigned Radix = 10) const {
     APInt::toString(Str, Radix, isSigned());
   }
   /// toString - Converts an APInt to a std::string.  This is an inefficient
   /// method; you should prefer passing in a SmallString instead.
   std::string toString(unsigned Radix) const {
     return APInt::toString(Radix, isSigned());
   }
   using APInt::toString;

   /// Get the correctly-extended \c int64_t value.
   int64_t getExtValue() const {
     assert(getMinSignedBits() <= 64 && "Too many bits for int64_t");
     return isSigned() ? getSExtValue() : getZExtValue();
   }

   APSInt trunc(uint32_t width) const {
     return APSInt(APInt::trunc(width), IsUnsigned);
   }

   APSInt extend(uint32_t width) const {
     if (IsUnsigned)
       return APSInt(zext(width), IsUnsigned);
     else
       return APSInt(sext(width), IsUnsigned);
   }

   APSInt extOrTrunc(uint32_t width) const {
     if (IsUnsigned)
       return APSInt(zextOrTrunc(width), IsUnsigned);
     else
       return APSInt(sextOrTrunc(width), IsUnsigned);
   }

   const APSInt &operator%=(const APSInt &RHS) {
     assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
     if (IsUnsigned)
       *this = urem(RHS);
     else
       *this = srem(RHS);
     return *this;
   }
   const APSInt &operator/=(const APSInt &RHS) {
     assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
     if (IsUnsigned)
       *this = udiv(RHS);
     else
       *this = sdiv(RHS);
     return *this;
   }
   APSInt operator%(const APSInt &RHS) const {
     assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
     return IsUnsigned ? APSInt(urem(RHS), true) : APSInt(srem(RHS), false);
   }
   APSInt operator/(const APSInt &RHS) const {
     assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
     return IsUnsigned ? APSInt(udiv(RHS), true) : APSInt(sdiv(RHS), false);
   }

   APSInt operator>>(unsigned Amt) const {
     return IsUnsigned ? APSInt(lshr(Amt), true) : APSInt(ashr(Amt), false);
   }
   APSInt& operator>>=(unsigned Amt) {
     if (IsUnsigned)
       lshrInPlace(Amt);
     else
       ashrInPlace(Amt);
     return *this;
   }

   inline bool operator<(const APSInt& RHS) const {
     assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
     return IsUnsigned ? ult(RHS) : slt(RHS);
   }
   inline bool operator>(const APSInt& RHS) const {
     assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
     return IsUnsigned ? ugt(RHS) : sgt(RHS);
   }
   inline bool operator<=(const APSInt& RHS) const {
     assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
     return IsUnsigned ? ule(RHS) : sle(RHS);
   }
   inline bool operator>=(const APSInt& RHS) const {
     assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
     return IsUnsigned ? uge(RHS) : sge(RHS);
   }
   inline bool operator==(const APSInt& RHS) const {
     assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
     return eq(RHS);
   }
   inline bool operator!=(const APSInt& RHS) const {
     return !((*this) == RHS);
   }

   bool operator==(int64_t RHS) const {
     return compareValues(*this, get(RHS)) == 0;
   }
   bool operator!=(int64_t RHS) const {
     return compareValues(*this, get(RHS)) != 0;
   }
   bool operator<=(int64_t RHS) const {
     return compareValues(*this, get(RHS)) <= 0;
   }
   bool operator>=(int64_t RHS) const {
     return compareValues(*this, get(RHS)) >= 0;
   }
   bool operator<(int64_t RHS) const {
     return compareValues(*this, get(RHS)) < 0;
   }
   bool operator>(int64_t RHS) const {
     return compareValues(*this, get(RHS)) > 0;
   }

   // The remaining operators just wrap the logic of APInt, but retain the
   // signedness information.

   APSInt operator<<(unsigned Bits) const {
     return APSInt(static_cast<const APInt&>(*this) << Bits, IsUnsigned);
   }
   APSInt& operator<<=(unsigned Amt) {
     static_cast<APInt&>(*this) <<= Amt;
     return *this;
   }

   APSInt& operator++() {
     ++(static_cast<APInt&>(*this));
     return *this;
   }
   APSInt& operator--() {
     --(static_cast<APInt&>(*this));
     return *this;
   }
   APSInt operator++(int) {
     return APSInt(++static_cast<APInt&>(*this), IsUnsigned);
   }
   APSInt operator--(int) {
     return APSInt(--static_cast<APInt&>(*this), IsUnsigned);
   }
   APSInt operator-() const {
     return APSInt(-static_cast<const APInt&>(*this), IsUnsigned);
   }
   APSInt& operator+=(const APSInt& RHS) {
     assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
     static_cast<APInt&>(*this) += RHS;
     return *this;
   }
   APSInt& operator-=(const APSInt& RHS) {
     assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
     static_cast<APInt&>(*this) -= RHS;
     return *this;
   }
   APSInt& operator*=(const APSInt& RHS) {
     assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
     static_cast<APInt&>(*this) *= RHS;
     return *this;
   }
   APSInt& operator&=(const APSInt& RHS) {
     assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
     static_cast<APInt&>(*this) &= RHS;
     return *this;
   }
   APSInt& operator|=(const APSInt& RHS) {
     assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
     static_cast<APInt&>(*this) |= RHS;
     return *this;
   }
   APSInt& operator^=(const APSInt& RHS) {
     assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
     static_cast<APInt&>(*this) ^= RHS;
     return *this;
   }

   APSInt operator&(const APSInt& RHS) const {
     assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
     return APSInt(static_cast<const APInt&>(*this) & RHS, IsUnsigned);
   }

   APSInt operator|(const APSInt& RHS) const {
     assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
     return APSInt(static_cast<const APInt&>(*this) | RHS, IsUnsigned);
   }

   APSInt operator^(const APSInt &RHS) const {
     assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
     return APSInt(static_cast<const APInt&>(*this) ^ RHS, IsUnsigned);
   }

   APSInt operator*(const APSInt& RHS) const {
     assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
     return APSInt(static_cast<const APInt&>(*this) * RHS, IsUnsigned);
   }
   APSInt operator+(const APSInt& RHS) const {
     assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
     return APSInt(static_cast<const APInt&>(*this) + RHS, IsUnsigned);
   }
   APSInt operator-(const APSInt& RHS) const {
     assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
     return APSInt(static_cast<const APInt&>(*this) - RHS, IsUnsigned);
   }
   APSInt operator~() const {
     return APSInt(~static_cast<const APInt&>(*this), IsUnsigned);
   }

   /// getMaxValue - Return the APSInt representing the maximum integer value
   ///  with the given bit width and signedness.
   static APSInt getMaxValue(uint32_t numBits, bool Unsigned) {
     return APSInt(Unsigned ? APInt::getMaxValue(numBits)
                            : APInt::getSignedMaxValue(numBits), Unsigned);
   }

   /// getMinValue - Return the APSInt representing the minimum integer value
   ///  with the given bit width and signedness.
   static APSInt getMinValue(uint32_t numBits, bool Unsigned) {
     return APSInt(Unsigned ? APInt::getMinValue(numBits)
                            : APInt::getSignedMinValue(numBits), Unsigned);
   }

   /// Determine if two APSInts have the same value, zero- or
   /// sign-extending as needed.
   static bool isSameValue(const APSInt &I1, const APSInt &I2) {
     return !compareValues(I1, I2);
   }

   /// Compare underlying values of two numbers.
   static int compareValues(const APSInt &I1, const APSInt &I2) {
     if (I1.getBitWidth() == I2.getBitWidth() && I1.isSigned() == I2.isSigned())
       return I1.IsUnsigned ? I1.compare(I2) : I1.compareSigned(I2);

     // Check for a bit-width mismatch.
     if (I1.getBitWidth() > I2.getBitWidth())
       return compareValues(I1, I2.extend(I1.getBitWidth()));
     if (I2.getBitWidth() > I1.getBitWidth())
       return compareValues(I1.extend(I2.getBitWidth()), I2);

     // We have a signedness mismatch. Check for negative values and do an
     // unsigned compare if both are positive.
     if (I1.isSigned()) {
       assert(!I2.isSigned() && "Expected signed mismatch");
       if (I1.isNegative())
         return -1;
     } else {
       assert(I2.isSigned() && "Expected signed mismatch");
       if (I2.isNegative())
         return 1;
     }

     return I1.compare(I2);
   }

   static APSInt get(int64_t X) { return APSInt(APInt(64, X), false); }
   static APSInt getUnsigned(uint64_t X) { return APSInt(APInt(64, X), true); }

   /// Profile - Used to insert APSInt objects, or objects that contain APSInt
   ///  objects, into FoldingSets.
   void Profile(FoldingSetNodeID& ID) const;
 };

 inline bool operator==(int64_t V1, const APSInt &V2) { return V2 == V1; }
 inline bool operator!=(int64_t V1, const APSInt &V2) { return V2 != V1; }
 inline bool operator<=(int64_t V1, const APSInt &V2) { return V2 >= V1; }
 inline bool operator>=(int64_t V1, const APSInt &V2) { return V2 <= V1; }
 inline bool operator<(int64_t V1, const APSInt &V2) { return V2 > V1; }
 inline bool operator>(int64_t V1, const APSInt &V2) { return V2 < V1; }

 inline raw_ostream &operator<<(raw_ostream &OS, const APSInt &I) {
   I.print(OS, I.isSigned());
   return OS;
 }

 } // end namespace llvm

 #endif
	//===-- llvm/ADT/APSInt.h - Arbitrary Precision Signed Int ------ 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 implements the APSInt class, which is a simple class that
	// represents an arbitrary sized integer that knows its signedness.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_ADT_APSINT_H
	#define LLVM_ADT_APSINT_H

	#include "llvm/ADT/APInt.h"

	namespace llvm {

	class LLVM_NODISCARD APSInt : public APInt {
	bool IsUnsigned;

	public:
	/// Default constructor that creates an uninitialized APInt.
	explicit APSInt() : IsUnsigned(false) {}

	/// APSInt ctor - Create an APSInt with the specified width, default to
	/// unsigned.
	explicit APSInt(uint32_t BitWidth, bool isUnsigned = true)
	: APInt(BitWidth, 0), IsUnsigned(isUnsigned) {}

	explicit APSInt(APInt I, bool isUnsigned = true)
	: APInt(std::move(I)), IsUnsigned(isUnsigned) {}

	/// Construct an APSInt from a string representation.
	///
	/// This constructor interprets the string \p Str using the radix of 10.
	/// The interpretation stops at the end of the string. The bit width of the
	/// constructed APSInt is determined automatically.
	///
	/// \param Str the string to be interpreted.
	explicit APSInt(StringRef Str);

	APSInt &operator=(APInt RHS) {
	// Retain our current sign.
	APInt::operator=(std::move(RHS));
	return *this;
	}

	APSInt &operator=(uint64_t RHS) {
	// Retain our current sign.
	APInt::operator=(RHS);
	return *this;
	}

	// Query sign information.
	bool isSigned() const { return !IsUnsigned; }
	bool isUnsigned() const { return IsUnsigned; }
	void setIsUnsigned(bool Val) { IsUnsigned = Val; }
	void setIsSigned(bool Val) { IsUnsigned = !Val; }

	/// toString - Append this APSInt to the specified SmallString.
	void toString(SmallVectorImpl<char> &Str, unsigned Radix = 10) const {
	APInt::toString(Str, Radix, isSigned());
	}
	/// toString - Converts an APInt to a std::string. This is an inefficient
	/// method; you should prefer passing in a SmallString instead.
	std::string toString(unsigned Radix) const {
	return APInt::toString(Radix, isSigned());
	}
	using APInt::toString;

	/// Get the correctly-extended \c int64_t value.
	int64_t getExtValue() const {
	assert(getMinSignedBits() <= 64 && "Too many bits for int64_t");
	return isSigned() ? getSExtValue() : getZExtValue();
	}

	APSInt trunc(uint32_t width) const {
	return APSInt(APInt::trunc(width), IsUnsigned);
	}

	APSInt extend(uint32_t width) const {
	if (IsUnsigned)
	return APSInt(zext(width), IsUnsigned);
	else
	return APSInt(sext(width), IsUnsigned);
	}

	APSInt extOrTrunc(uint32_t width) const {
	if (IsUnsigned)
	return APSInt(zextOrTrunc(width), IsUnsigned);
	else
	return APSInt(sextOrTrunc(width), IsUnsigned);
	}

	const APSInt &operator%=(const APSInt &RHS) {
	assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
	if (IsUnsigned)
	*this = urem(RHS);
	else
	*this = srem(RHS);
	return *this;
	}
	const APSInt &operator/=(const APSInt &RHS) {
	assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
	if (IsUnsigned)
	*this = udiv(RHS);
	else
	*this = sdiv(RHS);
	return *this;
	}
	APSInt operator%(const APSInt &RHS) const {
	assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
	return IsUnsigned ? APSInt(urem(RHS), true) : APSInt(srem(RHS), false);
	}
	APSInt operator/(const APSInt &RHS) const {
	assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
	return IsUnsigned ? APSInt(udiv(RHS), true) : APSInt(sdiv(RHS), false);
	}

	APSInt operator>>(unsigned Amt) const {
	return IsUnsigned ? APSInt(lshr(Amt), true) : APSInt(ashr(Amt), false);
	}
	APSInt& operator>>=(unsigned Amt) {
	if (IsUnsigned)
	lshrInPlace(Amt);
	else
	ashrInPlace(Amt);
	return *this;
	}

	inline bool operator<(const APSInt& RHS) const {
	assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
	return IsUnsigned ? ult(RHS) : slt(RHS);
	}
	inline bool operator>(const APSInt& RHS) const {
	assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
	return IsUnsigned ? ugt(RHS) : sgt(RHS);
	}
	inline bool operator<=(const APSInt& RHS) const {
	assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
	return IsUnsigned ? ule(RHS) : sle(RHS);
	}
	inline bool operator>=(const APSInt& RHS) const {
	assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
	return IsUnsigned ? uge(RHS) : sge(RHS);
	}
	inline bool operator==(const APSInt& RHS) const {
	assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
	return eq(RHS);
	}
	inline bool operator!=(const APSInt& RHS) const {
	return !((*this) == RHS);
	}

	bool operator==(int64_t RHS) const {
	return compareValues(*this, get(RHS)) == 0;
	}
	bool operator!=(int64_t RHS) const {
	return compareValues(*this, get(RHS)) != 0;
	}
	bool operator<=(int64_t RHS) const {
	return compareValues(*this, get(RHS)) <= 0;
	}
	bool operator>=(int64_t RHS) const {
	return compareValues(*this, get(RHS)) >= 0;
	}
	bool operator<(int64_t RHS) const {
	return compareValues(*this, get(RHS)) < 0;
	}
	bool operator>(int64_t RHS) const {
	return compareValues(*this, get(RHS)) > 0;
	}

	// The remaining operators just wrap the logic of APInt, but retain the
	// signedness information.

	APSInt operator<<(unsigned Bits) const {
	return APSInt(static_cast<const APInt&>(*this) << Bits, IsUnsigned);
	}
	APSInt& operator<<=(unsigned Amt) {
	static_cast<APInt&>(*this) <<= Amt;
	return *this;
	}

	APSInt& operator++() {
	++(static_cast<APInt&>(*this));
	return *this;
	}
	APSInt& operator--() {
	--(static_cast<APInt&>(*this));
	return *this;
	}
	APSInt operator++(int) {
	return APSInt(++static_cast<APInt&>(*this), IsUnsigned);
	}
	APSInt operator--(int) {
	return APSInt(--static_cast<APInt&>(*this), IsUnsigned);
	}
	APSInt operator-() const {
	return APSInt(-static_cast<const APInt&>(*this), IsUnsigned);
	}
	APSInt& operator+=(const APSInt& RHS) {
	assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
	static_cast<APInt&>(*this) += RHS;
	return *this;
	}
	APSInt& operator-=(const APSInt& RHS) {
	assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
	static_cast<APInt&>(*this) -= RHS;
	return *this;
	}
	APSInt& operator*=(const APSInt& RHS) {
	assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
	static_cast<APInt&>(this) = RHS;
	return *this;
	}
	APSInt& operator&=(const APSInt& RHS) {
	assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
	static_cast<APInt&>(*this) &= RHS;
	return *this;
	}
	APSInt& operator\|=(const APSInt& RHS) {
	assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
	static_cast<APInt&>(*this) \|= RHS;
	return *this;
	}
	APSInt& operator^=(const APSInt& RHS) {
	assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
	static_cast<APInt&>(*this) ^= RHS;
	return *this;
	}

	APSInt operator&(const APSInt& RHS) const {
	assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
	return APSInt(static_cast<const APInt&>(*this) & RHS, IsUnsigned);
	}

	APSInt operator\|(const APSInt& RHS) const {
	assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
	return APSInt(static_cast<const APInt&>(*this) \| RHS, IsUnsigned);
	}

	APSInt operator^(const APSInt &RHS) const {
	assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
	return APSInt(static_cast<const APInt&>(*this) ^ RHS, IsUnsigned);
	}

	APSInt operator*(const APSInt& RHS) const {
	assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
	return APSInt(static_cast<const APInt&>(this) RHS, IsUnsigned);
	}
	APSInt operator+(const APSInt& RHS) const {
	assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
	return APSInt(static_cast<const APInt&>(*this) + RHS, IsUnsigned);
	}
	APSInt operator-(const APSInt& RHS) const {
	assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!");
	return APSInt(static_cast<const APInt&>(*this) - RHS, IsUnsigned);
	}
	APSInt operator~() const {
	return APSInt(~static_cast<const APInt&>(*this), IsUnsigned);
	}

	/// getMaxValue - Return the APSInt representing the maximum integer value
	/// with the given bit width and signedness.
	static APSInt getMaxValue(uint32_t numBits, bool Unsigned) {
	return APSInt(Unsigned ? APInt::getMaxValue(numBits)
	: APInt::getSignedMaxValue(numBits), Unsigned);
	}

	/// getMinValue - Return the APSInt representing the minimum integer value
	/// with the given bit width and signedness.
	static APSInt getMinValue(uint32_t numBits, bool Unsigned) {
	return APSInt(Unsigned ? APInt::getMinValue(numBits)
	: APInt::getSignedMinValue(numBits), Unsigned);
	}

	/// Determine if two APSInts have the same value, zero- or
	/// sign-extending as needed.
	static bool isSameValue(const APSInt &I1, const APSInt &I2) {
	return !compareValues(I1, I2);
	}

	/// Compare underlying values of two numbers.
	static int compareValues(const APSInt &I1, const APSInt &I2) {
	if (I1.getBitWidth() == I2.getBitWidth() && I1.isSigned() == I2.isSigned())
	return I1.IsUnsigned ? I1.compare(I2) : I1.compareSigned(I2);

	// Check for a bit-width mismatch.
	if (I1.getBitWidth() > I2.getBitWidth())
	return compareValues(I1, I2.extend(I1.getBitWidth()));
	if (I2.getBitWidth() > I1.getBitWidth())
	return compareValues(I1.extend(I2.getBitWidth()), I2);

	// We have a signedness mismatch. Check for negative values and do an
	// unsigned compare if both are positive.
	if (I1.isSigned()) {
	assert(!I2.isSigned() && "Expected signed mismatch");
	if (I1.isNegative())
	return -1;
	} else {
	assert(I2.isSigned() && "Expected signed mismatch");
	if (I2.isNegative())
	return 1;
	}

	return I1.compare(I2);
	}

	static APSInt get(int64_t X) { return APSInt(APInt(64, X), false); }
	static APSInt getUnsigned(uint64_t X) { return APSInt(APInt(64, X), true); }

	/// Profile - Used to insert APSInt objects, or objects that contain APSInt
	/// objects, into FoldingSets.
	void Profile(FoldingSetNodeID& ID) const;
	};

	inline bool operator==(int64_t V1, const APSInt &V2) { return V2 == V1; }
	inline bool operator!=(int64_t V1, const APSInt &V2) { return V2 != V1; }
	inline bool operator<=(int64_t V1, const APSInt &V2) { return V2 >= V1; }
	inline bool operator>=(int64_t V1, const APSInt &V2) { return V2 <= V1; }
	inline bool operator<(int64_t V1, const APSInt &V2) { return V2 > V1; }
	inline bool operator>(int64_t V1, const APSInt &V2) { return V2 < V1; }

	inline raw_ostream &operator<<(raw_ostream &OS, const APSInt &I) {
	I.print(OS, I.isSigned());
	return OS;
	}

	} // end namespace llvm

	#endif