//===-- llvm/ADT/APSInt.h - Arbitrary Precision Signed Int -----*- C++ -*--===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file implements the APSInt class, which is a simple class that // represents an arbitrary sized integer that knows its signedness. // //===----------------------------------------------------------------------===// #ifndef LLVM_APSINT_H #define LLVM_APSINT_H #include "llvm/ADT/APInt.h" namespace llvm { class APSInt : public APInt { bool IsUnsigned; public: /// Default constructor that creates an uninitialized APInt. explicit APSInt() {} /// 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(const APInt &I, bool isUnsigned = true) : APInt(I), IsUnsigned(isUnsigned) {} APSInt &operator=(const APSInt &RHS) { APInt::operator=(RHS); IsUnsigned = RHS.IsUnsigned; return *this; } APSInt &operator=(const APInt &RHS) { // Retain our current sign. APInt::operator=(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, your should prefer passing in a SmallString instead. std::string toString(unsigned Radix) const { return APInt::toString(Radix, isSigned()); } using APInt::toString; 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) { *this = *this >> 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); } // 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) { *this = *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 And(const APSInt& RHS) const { return this->operator&(RHS); } APSInt operator|(const APSInt& RHS) const { assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!"); return APSInt(static_cast<const APInt&>(*this) | RHS, IsUnsigned); } APSInt Or(const APSInt& RHS) const { return this->operator|(RHS); } APSInt operator^(const APSInt& RHS) const { assert(IsUnsigned == RHS.IsUnsigned && "Signedness mismatch!"); return APSInt(static_cast<const APInt&>(*this) ^ RHS, IsUnsigned); } APSInt Xor(const APSInt& RHS) const { return this->operator^(RHS); } 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); } /// Profile - Used to insert APSInt objects, or objects that contain APSInt /// objects, into FoldingSets. void Profile(FoldingSetNodeID& ID) const; }; inline raw_ostream &operator<<(raw_ostream &OS, const APSInt &I) { I.print(OS, I.isSigned()); return OS; } } // end namespace llvm #endif