lib/Evaluate/real.cpp - llvm-project/flang - Git at Google

 //===-- lib/Evaluate/real.cpp ---------------------------------------------===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//

 #include "flang/Evaluate/real.h"
 #include "int-power.h"
 #include "flang/Common/idioms.h"
 #include "flang/Decimal/decimal.h"
 #include "flang/Parser/characters.h"
 #include "llvm/Support/raw_ostream.h"
 #include <limits>

 namespace Fortran::evaluate::value {

 template <typename W, int P> Relation Real<W, P>::Compare(const Real &y) const {
   if (IsNotANumber() || y.IsNotANumber()) { // NaN vs x, x vs NaN
     return Relation::Unordered;
   } else if (IsInfinite()) {
     if (y.IsInfinite()) {
       if (IsNegative()) { // -Inf vs +/-Inf
         return y.IsNegative() ? Relation::Equal : Relation::Less;
       } else { // +Inf vs +/-Inf
         return y.IsNegative() ? Relation::Greater : Relation::Equal;
       }
     } else { // +/-Inf vs finite
       return IsNegative() ? Relation::Less : Relation::Greater;
     }
   } else if (y.IsInfinite()) { // finite vs +/-Inf
     return y.IsNegative() ? Relation::Greater : Relation::Less;
   } else { // two finite numbers
     bool isNegative{IsNegative()};
     if (isNegative != y.IsNegative()) {
       if (word_.IOR(y.word_).IBCLR(bits - 1).IsZero()) {
         return Relation::Equal; // +/-0.0 == -/+0.0
       } else {
         return isNegative ? Relation::Less : Relation::Greater;
       }
     } else {
       // same sign
       Ordering order{evaluate::Compare(Exponent(), y.Exponent())};
       if (order == Ordering::Equal) {
         order = GetSignificand().CompareUnsigned(y.GetSignificand());
       }
       if (isNegative) {
         order = Reverse(order);
       }
       return RelationFromOrdering(order);
     }
   }
 }

 template <typename W, int P>
 ValueWithRealFlags<Real<W, P>> Real<W, P>::Add(
     const Real &y, Rounding rounding) const {
   ValueWithRealFlags<Real> result;
   if (IsNotANumber() || y.IsNotANumber()) {
     result.value = NotANumber(); // NaN + x -> NaN
     if (IsSignalingNaN() || y.IsSignalingNaN()) {
       result.flags.set(RealFlag::InvalidArgument);
     }
     return result;
   }
   bool isNegative{IsNegative()};
   bool yIsNegative{y.IsNegative()};
   if (IsInfinite()) {
     if (y.IsInfinite()) {
       if (isNegative == yIsNegative) {
         result.value = *this; // +/-Inf + +/-Inf -> +/-Inf
       } else {
         result.value = NotANumber(); // +/-Inf + -/+Inf -> NaN
         result.flags.set(RealFlag::InvalidArgument);
       }
     } else {
       result.value = *this; // +/-Inf + x -> +/-Inf
     }
     return result;
   }
   if (y.IsInfinite()) {
     result.value = y; // x + +/-Inf -> +/-Inf
     return result;
   }
   int exponent{Exponent()};
   int yExponent{y.Exponent()};
   if (exponent < yExponent) {
     // y is larger in magnitude; simplify by reversing operands
     return y.Add(*this, rounding);
   }
   if (exponent == yExponent && isNegative != yIsNegative) {
     Ordering order{GetSignificand().CompareUnsigned(y.GetSignificand())};
     if (order == Ordering::Less) {
       // Same exponent, opposite signs, and y is larger in magnitude
       return y.Add(*this, rounding);
     }
     if (order == Ordering::Equal) {
       // x + (-x) -> +0.0 unless rounding is directed downwards
       if (rounding.mode == common::RoundingMode::Down) {
         result.value.word_ = result.value.word_.IBSET(bits - 1); // -0.0
       }
       return result;
     }
   }
   // Our exponent is greater than y's, or the exponents match and y is not
   // of the opposite sign and greater magnitude.  So (x+y) will have the
   // same sign as x.
   Fraction fraction{GetFraction()};
   Fraction yFraction{y.GetFraction()};
   int rshift = exponent - yExponent;
   if (exponent > 0 && yExponent == 0) {
     --rshift; // correct overshift when only y is subnormal
   }
   RoundingBits roundingBits{yFraction, rshift};
   yFraction = yFraction.SHIFTR(rshift);
   bool carry{false};
   if (isNegative != yIsNegative) {
     // Opposite signs: subtract via addition of two's complement of y and
     // the rounding bits.
     yFraction = yFraction.NOT();
     carry = roundingBits.Negate();
   }
   auto sum{fraction.AddUnsigned(yFraction, carry)};
   fraction = sum.value;
   if (isNegative == yIsNegative && sum.carry) {
     roundingBits.ShiftRight(sum.value.BTEST(0));
     fraction = fraction.SHIFTR(1).IBSET(fraction.bits - 1);
     ++exponent;
   }
   NormalizeAndRound(
       result, isNegative, exponent, fraction, rounding, roundingBits);
   return result;
 }

 template <typename W, int P>
 ValueWithRealFlags<Real<W, P>> Real<W, P>::Multiply(
     const Real &y, Rounding rounding) const {
   ValueWithRealFlags<Real> result;
   if (IsNotANumber() || y.IsNotANumber()) {
     result.value = NotANumber(); // NaN * x -> NaN
     if (IsSignalingNaN() || y.IsSignalingNaN()) {
       result.flags.set(RealFlag::InvalidArgument);
     }
   } else {
     bool isNegative{IsNegative() != y.IsNegative()};
     if (IsInfinite() || y.IsInfinite()) {
       if (IsZero() || y.IsZero()) {
         result.value = NotANumber(); // 0 * Inf -> NaN
         result.flags.set(RealFlag::InvalidArgument);
       } else {
         result.value = Infinity(isNegative);
       }
     } else {
       auto product{GetFraction().MultiplyUnsigned(y.GetFraction())};
       std::int64_t exponent{CombineExponents(y, false)};
       if (exponent < 1) {
         int rshift = 1 - exponent;
         exponent = 1;
         bool sticky{false};
         if (rshift >= product.upper.bits + product.lower.bits) {
           sticky = !product.lower.IsZero() || !product.upper.IsZero();
         } else if (rshift >= product.lower.bits) {
           sticky = !product.lower.IsZero() ||
               !product.upper
                    .IAND(product.upper.MASKR(rshift - product.lower.bits))
                    .IsZero();
         } else {
           sticky = !product.lower.IAND(product.lower.MASKR(rshift)).IsZero();
         }
         product.lower = product.lower.SHIFTRWithFill(product.upper, rshift);
         product.upper = product.upper.SHIFTR(rshift);
         if (sticky) {
           product.lower = product.lower.IBSET(0);
         }
       }
       int leadz{product.upper.LEADZ()};
       if (leadz >= product.upper.bits) {
         leadz += product.lower.LEADZ();
       }
       int lshift{leadz};
       if (lshift > exponent - 1) {
         lshift = exponent - 1;
       }
       exponent -= lshift;
       product.upper = product.upper.SHIFTLWithFill(product.lower, lshift);
       product.lower = product.lower.SHIFTL(lshift);
       RoundingBits roundingBits{product.lower, product.lower.bits};
       NormalizeAndRound(result, isNegative, exponent, product.upper, rounding,
           roundingBits, true /*multiply*/);
     }
   }
   return result;
 }

 template <typename W, int P>
 ValueWithRealFlags<Real<W, P>> Real<W, P>::Divide(
     const Real &y, Rounding rounding) const {
   ValueWithRealFlags<Real> result;
   if (IsNotANumber() || y.IsNotANumber()) {
     result.value = NotANumber(); // NaN / x -> NaN, x / NaN -> NaN
     if (IsSignalingNaN() || y.IsSignalingNaN()) {
       result.flags.set(RealFlag::InvalidArgument);
     }
   } else {
     bool isNegative{IsNegative() != y.IsNegative()};
     if (IsInfinite()) {
       if (y.IsInfinite()) {
         result.value = NotANumber(); // Inf/Inf -> NaN
         result.flags.set(RealFlag::InvalidArgument);
       } else { // Inf/x -> Inf,  Inf/0 -> Inf
         result.value = Infinity(isNegative);
       }
     } else if (y.IsZero()) {
       if (IsZero()) { // 0/0 -> NaN
         result.value = NotANumber();
         result.flags.set(RealFlag::InvalidArgument);
       } else { // x/0 -> Inf, Inf/0 -> Inf
         result.value = Infinity(isNegative);
         result.flags.set(RealFlag::DivideByZero);
       }
     } else if (IsZero() || y.IsInfinite()) { // 0/x, x/Inf -> 0
       if (isNegative) {
         result.value.word_ = result.value.word_.IBSET(bits - 1);
       }
     } else {
       // dividend and divisor are both finite and nonzero numbers
       Fraction top{GetFraction()}, divisor{y.GetFraction()};
       std::int64_t exponent{CombineExponents(y, true)};
       Fraction quotient;
       bool msb{false};
       if (!top.BTEST(top.bits - 1) || !divisor.BTEST(divisor.bits - 1)) {
         // One or two subnormals
         int topLshift{top.LEADZ()};
         top = top.SHIFTL(topLshift);
         int divisorLshift{divisor.LEADZ()};
         divisor = divisor.SHIFTL(divisorLshift);
         exponent += divisorLshift - topLshift;
       }
       for (int j{1}; j <= quotient.bits; ++j) {
         if (NextQuotientBit(top, msb, divisor)) {
           quotient = quotient.IBSET(quotient.bits - j);
         }
       }
       bool guard{NextQuotientBit(top, msb, divisor)};
       bool round{NextQuotientBit(top, msb, divisor)};
       bool sticky{msb || !top.IsZero()};
       RoundingBits roundingBits{guard, round, sticky};
       if (exponent < 1) {
         std::int64_t rshift{1 - exponent};
         for (; rshift > 0; --rshift) {
           roundingBits.ShiftRight(quotient.BTEST(0));
           quotient = quotient.SHIFTR(1);
         }
         exponent = 1;
       }
       NormalizeAndRound(
           result, isNegative, exponent, quotient, rounding, roundingBits);
     }
   }
   return result;
 }

 template <typename W, int P>
 ValueWithRealFlags<Real<W, P>> Real<W, P>::SQRT(Rounding rounding) const {
   ValueWithRealFlags<Real> result;
   if (IsNotANumber()) {
     result.value = NotANumber();
     if (IsSignalingNaN()) {
       result.flags.set(RealFlag::InvalidArgument);
     }
   } else if (IsNegative()) {
     if (IsZero()) {
       // SQRT(-0) == -0 in IEEE-754.
       result.value.word_ = result.value.word_.IBSET(bits - 1);
     } else {
       result.value = NotANumber();
     }
   } else if (IsInfinite()) {
     // SQRT(+Inf) == +Inf
     result.value = Infinity(false);
   } else {
     // Slow but reliable bit-at-a-time method.  Start with a clear significand
     // and half the unbiased exponent, and then try to set significand bits
     // in descending order of magnitude without exceeding the exact result.
     int expo{UnbiasedExponent()};
     if (IsSubnormal()) {
       expo -= GetFraction().LEADZ();
     }
     expo = expo / 2 + exponentBias;
     result.value.Normalize(false, expo, Fraction::MASKL(1));
     for (int bit{significandBits - 1}; bit >= 0; --bit) {
       Word word{result.value.word_};
       result.value.word_ = word.IBSET(bit);
       auto squared{result.value.Multiply(result.value, rounding)};
       if (squared.flags.test(RealFlag::Overflow) ||
           squared.flags.test(RealFlag::Underflow) ||
           Compare(squared.value) == Relation::Less) {
         result.value.word_ = word;
       }
     }
     // The computed square root, when squared, has a square that's not greater
     // than the original argument.  Check this square against the square of the
     // next Real value, and return that one if its square is closer in magnitude
     // to the original argument.
     Real resultSq{result.value.Multiply(result.value).value};
     Real diff{Subtract(resultSq).value.ABS()};
     if (diff.IsZero()) {
       return result; // exact
     }
     Real ulp;
     ulp.Normalize(false, expo, Fraction::MASKR(1));
     Real nextAfter{result.value.Add(ulp).value};
     auto nextAfterSq{nextAfter.Multiply(nextAfter)};
     if (!nextAfterSq.flags.test(RealFlag::Overflow) &&
         !nextAfterSq.flags.test(RealFlag::Underflow)) {
       Real nextAfterDiff{Subtract(nextAfterSq.value).value.ABS()};
       if (nextAfterDiff.Compare(diff) == Relation::Less) {
         result.value = nextAfter;
         if (nextAfterDiff.IsZero()) {
           return result; // exact
         }
       }
     }
     result.flags.set(RealFlag::Inexact);
   }
   return result;
 }

 // HYPOT(x,y) = SQRT(x**2 + y**2) by definition, but those squared intermediate
 // values are susceptible to over/underflow when computed naively.
 // Assuming that x>=y, calculate instead:
 //   HYPOT(x,y) = SQRT(x**2 * (1+(y/x)**2))
 //              = ABS(x) * SQRT(1+(y/x)**2)
 template <typename W, int P>
 ValueWithRealFlags<Real<W, P>> Real<W, P>::HYPOT(
     const Real &y, Rounding rounding) const {
   ValueWithRealFlags<Real> result;
   if (IsNotANumber() || y.IsNotANumber()) {
     result.flags.set(RealFlag::InvalidArgument);
     result.value = NotANumber();
   } else if (ABS().Compare(y.ABS()) == Relation::Less) {
     return y.HYPOT(*this);
   } else if (IsZero()) {
     return result; // x==y==0
   } else {
     auto yOverX{y.Divide(*this, rounding)}; // y/x
     bool inexact{yOverX.flags.test(RealFlag::Inexact)};
     auto squared{yOverX.value.Multiply(yOverX.value, rounding)}; // (y/x)**2
     inexact |= squared.flags.test(RealFlag::Inexact);
     Real one;
     one.Normalize(false, exponentBias, Fraction::MASKL(1)); // 1.0
     auto sum{squared.value.Add(one, rounding)}; // 1.0 + (y/x)**2
     inexact |= sum.flags.test(RealFlag::Inexact);
     auto sqrt{sum.value.SQRT()};
     inexact |= sqrt.flags.test(RealFlag::Inexact);
     result = sqrt.value.Multiply(ABS(), rounding);
     if (inexact) {
       result.flags.set(RealFlag::Inexact);
     }
   }
   return result;
 }

 template <typename W, int P>
 ValueWithRealFlags<Real<W, P>> Real<W, P>::ToWholeNumber(
     common::RoundingMode mode) const {
   ValueWithRealFlags<Real> result{*this};
   if (IsNotANumber()) {
     result.flags.set(RealFlag::InvalidArgument);
     result.value = NotANumber();
   } else if (IsInfinite()) {
     result.flags.set(RealFlag::Overflow);
   } else {
     constexpr int noClipExponent{exponentBias + binaryPrecision - 1};
     if (Exponent() < noClipExponent) {
       Real adjust; // ABS(EPSILON(adjust)) == 0.5
       adjust.Normalize(IsSignBitSet(), noClipExponent, Fraction::MASKL(1));
       // Compute ival=(*this + adjust), losing any fractional bits; keep flags
       result = Add(adjust, Rounding{mode});
       result.flags.reset(RealFlag::Inexact); // result *is* exact
       // Return (ival-adjust) with original sign in case we've generated a zero.
       result.value =
           result.value.Subtract(adjust, Rounding{common::RoundingMode::ToZero})
               .value.SIGN(*this);
     }
   }
   return result;
 }

 template <typename W, int P>
 RealFlags Real<W, P>::Normalize(bool negative, int exponent,
     const Fraction &fraction, Rounding rounding, RoundingBits *roundingBits) {
   int lshift{fraction.LEADZ()};
   if (lshift == fraction.bits /* fraction is zero */ &&
       (!roundingBits || roundingBits->empty())) {
     // No fraction, no rounding bits -> +/-0.0
     exponent = lshift = 0;
   } else if (lshift < exponent) {
     exponent -= lshift;
   } else if (exponent > 0) {
     lshift = exponent - 1;
     exponent = 0;
   } else if (lshift == 0) {
     exponent = 1;
   } else {
     lshift = 0;
   }
   if (exponent >= maxExponent) {
     // Infinity or overflow
     if (rounding.mode == common::RoundingMode::TiesToEven ||
         rounding.mode == common::RoundingMode::TiesAwayFromZero ||
         (rounding.mode == common::RoundingMode::Up && !negative) ||
         (rounding.mode == common::RoundingMode::Down && negative)) {
       word_ = Word{maxExponent}.SHIFTL(significandBits); // Inf
     } else {
       // directed rounding: round to largest finite value rather than infinity
       // (x86 does this, not sure whether it's standard behavior)
       word_ = Word{word_.MASKR(word_.bits - 1)}.IBCLR(significandBits);
     }
     if (negative) {
       word_ = word_.IBSET(bits - 1);
     }
     RealFlags flags{RealFlag::Overflow};
     if (!fraction.IsZero()) {
       flags.set(RealFlag::Inexact);
     }
     return flags;
   }
   word_ = Word::ConvertUnsigned(fraction).value;
   if (lshift > 0) {
     word_ = word_.SHIFTL(lshift);
     if (roundingBits) {
       for (; lshift > 0; --lshift) {
         if (roundingBits->ShiftLeft()) {
           word_ = word_.IBSET(lshift - 1);
         }
       }
     }
   }
   if constexpr (isImplicitMSB) {
     word_ = word_.IBCLR(significandBits);
   }
   word_ = word_.IOR(Word{exponent}.SHIFTL(significandBits));
   if (negative) {
     word_ = word_.IBSET(bits - 1);
   }
   return {};
 }

 template <typename W, int P>
 RealFlags Real<W, P>::Round(
     Rounding rounding, const RoundingBits &bits, bool multiply) {
   int origExponent{Exponent()};
   RealFlags flags;
   bool inexact{!bits.empty()};
   if (inexact) {
     flags.set(RealFlag::Inexact);
   }
   if (origExponent < maxExponent &&
       bits.MustRound(rounding, IsNegative(), word_.BTEST(0) /* is odd */)) {
     typename Fraction::ValueWithCarry sum{
         GetFraction().AddUnsigned(Fraction{}, true)};
     int newExponent{origExponent};
     if (sum.carry) {
       // The fraction was all ones before rounding; sum.value is now zero
       sum.value = sum.value.IBSET(binaryPrecision - 1);
       if (++newExponent >= maxExponent) {
         flags.set(RealFlag::Overflow); // rounded away to an infinity
       }
     }
     flags |= Normalize(IsNegative(), newExponent, sum.value);
   }
   if (inexact && origExponent == 0) {
     // inexact subnormal input: signal Underflow unless in an x86-specific
     // edge case
     if (rounding.x86CompatibleBehavior && Exponent() != 0 && multiply &&
         bits.sticky() &&
         (bits.guard() ||
             (rounding.mode != common::RoundingMode::Up &&
                 rounding.mode != common::RoundingMode::Down))) {
       // x86 edge case in which Underflow fails to signal when a subnormal
       // inexact multiplication product rounds to a normal result when
       // the guard bit is set or we're not using directed rounding
     } else {
       flags.set(RealFlag::Underflow);
     }
   }
   return flags;
 }

 template <typename W, int P>
 void Real<W, P>::NormalizeAndRound(ValueWithRealFlags<Real> &result,
     bool isNegative, int exponent, const Fraction &fraction, Rounding rounding,
     RoundingBits roundingBits, bool multiply) {
   result.flags |= result.value.Normalize(
       isNegative, exponent, fraction, rounding, &roundingBits);
   result.flags |= result.value.Round(rounding, roundingBits, multiply);
 }

 inline enum decimal::FortranRounding MapRoundingMode(
     common::RoundingMode rounding) {
   switch (rounding) {
   case common::RoundingMode::TiesToEven:
     break;
   case common::RoundingMode::ToZero:
     return decimal::RoundToZero;
   case common::RoundingMode::Down:
     return decimal::RoundDown;
   case common::RoundingMode::Up:
     return decimal::RoundUp;
   case common::RoundingMode::TiesAwayFromZero:
     return decimal::RoundCompatible;
   }
   return decimal::RoundNearest; // dodge gcc warning about lack of result
 }

 inline RealFlags MapFlags(decimal::ConversionResultFlags flags) {
   RealFlags result;
   if (flags & decimal::Overflow) {
     result.set(RealFlag::Overflow);
   }
   if (flags & decimal::Inexact) {
     result.set(RealFlag::Inexact);
   }
   if (flags & decimal::Invalid) {
     result.set(RealFlag::InvalidArgument);
   }
   return result;
 }

 template <typename W, int P>
 ValueWithRealFlags<Real<W, P>> Real<W, P>::Read(
     const char *&p, Rounding rounding) {
   auto converted{
       decimal::ConvertToBinary<P>(p, MapRoundingMode(rounding.mode))};
   const auto *value{reinterpret_cast<Real<W, P> *>(&converted.binary)};
   return {*value, MapFlags(converted.flags)};
 }

 template <typename W, int P> std::string Real<W, P>::DumpHexadecimal() const {
   if (IsNotANumber()) {
     return "NaN0x"s + word_.Hexadecimal();
   } else if (IsNegative()) {
     return "-"s + Negate().DumpHexadecimal();
   } else if (IsInfinite()) {
     return "Inf"s;
   } else if (IsZero()) {
     return "0.0"s;
   } else {
     Fraction frac{GetFraction()};
     std::string result{"0x"};
     char intPart = '0' + frac.BTEST(frac.bits - 1);
     result += intPart;
     result += '.';
     int trailz{frac.TRAILZ()};
     if (trailz >= frac.bits - 1) {
       result += '0';
     } else {
       int remainingBits{frac.bits - 1 - trailz};
       int wholeNybbles{remainingBits / 4};
       int lostBits{remainingBits - 4 * wholeNybbles};
       if (wholeNybbles > 0) {
         std::string fracHex{frac.SHIFTR(trailz + lostBits)
                                 .IAND(frac.MASKR(4 * wholeNybbles))
                                 .Hexadecimal()};
         std::size_t field = wholeNybbles;
         if (fracHex.size() < field) {
           result += std::string(field - fracHex.size(), '0');
         }
         result += fracHex;
       }
       if (lostBits > 0) {
         result += frac.SHIFTR(trailz)
                       .IAND(frac.MASKR(lostBits))
                       .SHIFTL(4 - lostBits)
                       .Hexadecimal();
       }
     }
     result += 'p';
     int exponent = Exponent() - exponentBias;
     result += Integer<32>{exponent}.SignedDecimal();
     return result;
   }
 }

 template <typename W, int P>
 llvm::raw_ostream &Real<W, P>::AsFortran(
     llvm::raw_ostream &o, int kind, bool minimal) const {
   if (IsNotANumber()) {
     o << "(0._" << kind << "/0.)";
   } else if (IsInfinite()) {
     if (IsNegative()) {
       o << "(-1._" << kind << "/0.)";
     } else {
       o << "(1._" << kind << "/0.)";
     }
   } else {
     using B = decimal::BinaryFloatingPointNumber<P>;
     B value{word_.template ToUInt<typename B::RawType>()};
     char buffer[common::MaxDecimalConversionDigits(P) +
         EXTRA_DECIMAL_CONVERSION_SPACE];
     decimal::DecimalConversionFlags flags{}; // default: exact representation
     if (minimal) {
       flags = decimal::Minimize;
     }
     auto result{decimal::ConvertToDecimal<P>(buffer, sizeof buffer, flags,
         static_cast<int>(sizeof buffer), decimal::RoundNearest, value)};
     const char *p{result.str};
     if (DEREF(p) == '-' || *p == '+') {
       o << *p++;
     }
     int expo{result.decimalExponent};
     if (*p != '0') {
       --expo;
     }
     o << *p << '.' << (p + 1);
     if (expo != 0) {
       o << 'e' << expo;
     }
     o << '_' << kind;
   }
   return o;
 }

 template class Real<Integer<16>, 11>;
 template class Real<Integer<16>, 8>;
 template class Real<Integer<32>, 24>;
 template class Real<Integer<64>, 53>;
 template class Real<Integer<80>, 64>;
 template class Real<Integer<128>, 113>;
 } // namespace Fortran::evaluate::value
	//===-- lib/Evaluate/real.cpp ---------------------------------------------===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//

	#include "flang/Evaluate/real.h"
	#include "int-power.h"
	#include "flang/Common/idioms.h"
	#include "flang/Decimal/decimal.h"
	#include "flang/Parser/characters.h"
	#include "llvm/Support/raw_ostream.h"
	#include <limits>

	namespace Fortran::evaluate::value {

	template <typename W, int P> Relation Real<W, P>::Compare(const Real &y) const {
	if (IsNotANumber() \|\| y.IsNotANumber()) { // NaN vs x, x vs NaN
	return Relation::Unordered;
	} else if (IsInfinite()) {
	if (y.IsInfinite()) {
	if (IsNegative()) { // -Inf vs +/-Inf
	return y.IsNegative() ? Relation::Equal : Relation::Less;
	} else { // +Inf vs +/-Inf
	return y.IsNegative() ? Relation::Greater : Relation::Equal;
	}
	} else { // +/-Inf vs finite
	return IsNegative() ? Relation::Less : Relation::Greater;
	}
	} else if (y.IsInfinite()) { // finite vs +/-Inf
	return y.IsNegative() ? Relation::Greater : Relation::Less;
	} else { // two finite numbers
	bool isNegative{IsNegative()};
	if (isNegative != y.IsNegative()) {
	if (word_.IOR(y.word_).IBCLR(bits - 1).IsZero()) {
	return Relation::Equal; // +/-0.0 == -/+0.0
	} else {
	return isNegative ? Relation::Less : Relation::Greater;
	}
	} else {
	// same sign
	Ordering order{evaluate::Compare(Exponent(), y.Exponent())};
	if (order == Ordering::Equal) {
	order = GetSignificand().CompareUnsigned(y.GetSignificand());
	}
	if (isNegative) {
	order = Reverse(order);
	}
	return RelationFromOrdering(order);
	}
	}
	}

	template <typename W, int P>
	ValueWithRealFlags<Real<W, P>> Real<W, P>::Add(
	const Real &y, Rounding rounding) const {
	ValueWithRealFlags<Real> result;
	if (IsNotANumber() \|\| y.IsNotANumber()) {
	result.value = NotANumber(); // NaN + x -> NaN
	if (IsSignalingNaN() \|\| y.IsSignalingNaN()) {
	result.flags.set(RealFlag::InvalidArgument);
	}
	return result;
	}
	bool isNegative{IsNegative()};
	bool yIsNegative{y.IsNegative()};
	if (IsInfinite()) {
	if (y.IsInfinite()) {
	if (isNegative == yIsNegative) {
	result.value = *this; // +/-Inf + +/-Inf -> +/-Inf
	} else {
	result.value = NotANumber(); // +/-Inf + -/+Inf -> NaN
	result.flags.set(RealFlag::InvalidArgument);
	}
	} else {
	result.value = *this; // +/-Inf + x -> +/-Inf
	}
	return result;
	}
	if (y.IsInfinite()) {
	result.value = y; // x + +/-Inf -> +/-Inf
	return result;
	}
	int exponent{Exponent()};
	int yExponent{y.Exponent()};
	if (exponent < yExponent) {
	// y is larger in magnitude; simplify by reversing operands
	return y.Add(*this, rounding);
	}
	if (exponent == yExponent && isNegative != yIsNegative) {
	Ordering order{GetSignificand().CompareUnsigned(y.GetSignificand())};
	if (order == Ordering::Less) {
	// Same exponent, opposite signs, and y is larger in magnitude
	return y.Add(*this, rounding);
	}
	if (order == Ordering::Equal) {
	// x + (-x) -> +0.0 unless rounding is directed downwards
	if (rounding.mode == common::RoundingMode::Down) {
	result.value.word_ = result.value.word_.IBSET(bits - 1); // -0.0
	}
	return result;
	}
	}
	// Our exponent is greater than y's, or the exponents match and y is not
	// of the opposite sign and greater magnitude. So (x+y) will have the
	// same sign as x.
	Fraction fraction{GetFraction()};
	Fraction yFraction{y.GetFraction()};
	int rshift = exponent - yExponent;
	if (exponent > 0 && yExponent == 0) {
	--rshift; // correct overshift when only y is subnormal
	}
	RoundingBits roundingBits{yFraction, rshift};
	yFraction = yFraction.SHIFTR(rshift);
	bool carry{false};
	if (isNegative != yIsNegative) {
	// Opposite signs: subtract via addition of two's complement of y and
	// the rounding bits.
	yFraction = yFraction.NOT();
	carry = roundingBits.Negate();
	}
	auto sum{fraction.AddUnsigned(yFraction, carry)};
	fraction = sum.value;
	if (isNegative == yIsNegative && sum.carry) {
	roundingBits.ShiftRight(sum.value.BTEST(0));
	fraction = fraction.SHIFTR(1).IBSET(fraction.bits - 1);
	++exponent;
	}
	NormalizeAndRound(
	result, isNegative, exponent, fraction, rounding, roundingBits);
	return result;
	}

	template <typename W, int P>
	ValueWithRealFlags<Real<W, P>> Real<W, P>::Multiply(
	const Real &y, Rounding rounding) const {
	ValueWithRealFlags<Real> result;
	if (IsNotANumber() \|\| y.IsNotANumber()) {
	result.value = NotANumber(); // NaN * x -> NaN
	if (IsSignalingNaN() \|\| y.IsSignalingNaN()) {
	result.flags.set(RealFlag::InvalidArgument);
	}
	} else {
	bool isNegative{IsNegative() != y.IsNegative()};
	if (IsInfinite() \|\| y.IsInfinite()) {
	if (IsZero() \|\| y.IsZero()) {
	result.value = NotANumber(); // 0 * Inf -> NaN
	result.flags.set(RealFlag::InvalidArgument);
	} else {
	result.value = Infinity(isNegative);
	}
	} else {
	auto product{GetFraction().MultiplyUnsigned(y.GetFraction())};
	std::int64_t exponent{CombineExponents(y, false)};
	if (exponent < 1) {
	int rshift = 1 - exponent;
	exponent = 1;
	bool sticky{false};
	if (rshift >= product.upper.bits + product.lower.bits) {
	sticky = !product.lower.IsZero() \|\| !product.upper.IsZero();
	} else if (rshift >= product.lower.bits) {
	sticky = !product.lower.IsZero() \|\|
	!product.upper
	.IAND(product.upper.MASKR(rshift - product.lower.bits))
	.IsZero();
	} else {
	sticky = !product.lower.IAND(product.lower.MASKR(rshift)).IsZero();
	}
	product.lower = product.lower.SHIFTRWithFill(product.upper, rshift);
	product.upper = product.upper.SHIFTR(rshift);
	if (sticky) {
	product.lower = product.lower.IBSET(0);
	}
	}
	int leadz{product.upper.LEADZ()};
	if (leadz >= product.upper.bits) {
	leadz += product.lower.LEADZ();
	}
	int lshift{leadz};
	if (lshift > exponent - 1) {
	lshift = exponent - 1;
	}
	exponent -= lshift;
	product.upper = product.upper.SHIFTLWithFill(product.lower, lshift);
	product.lower = product.lower.SHIFTL(lshift);
	RoundingBits roundingBits{product.lower, product.lower.bits};
	NormalizeAndRound(result, isNegative, exponent, product.upper, rounding,
	roundingBits, true /multiply/);
	}
	}
	return result;
	}

	template <typename W, int P>
	ValueWithRealFlags<Real<W, P>> Real<W, P>::Divide(
	const Real &y, Rounding rounding) const {
	ValueWithRealFlags<Real> result;
	if (IsNotANumber() \|\| y.IsNotANumber()) {
	result.value = NotANumber(); // NaN / x -> NaN, x / NaN -> NaN
	if (IsSignalingNaN() \|\| y.IsSignalingNaN()) {
	result.flags.set(RealFlag::InvalidArgument);
	}
	} else {
	bool isNegative{IsNegative() != y.IsNegative()};
	if (IsInfinite()) {
	if (y.IsInfinite()) {
	result.value = NotANumber(); // Inf/Inf -> NaN
	result.flags.set(RealFlag::InvalidArgument);
	} else { // Inf/x -> Inf, Inf/0 -> Inf
	result.value = Infinity(isNegative);
	}
	} else if (y.IsZero()) {
	if (IsZero()) { // 0/0 -> NaN
	result.value = NotANumber();
	result.flags.set(RealFlag::InvalidArgument);
	} else { // x/0 -> Inf, Inf/0 -> Inf
	result.value = Infinity(isNegative);
	result.flags.set(RealFlag::DivideByZero);
	}
	} else if (IsZero() \|\| y.IsInfinite()) { // 0/x, x/Inf -> 0
	if (isNegative) {
	result.value.word_ = result.value.word_.IBSET(bits - 1);
	}
	} else {
	// dividend and divisor are both finite and nonzero numbers
	Fraction top{GetFraction()}, divisor{y.GetFraction()};
	std::int64_t exponent{CombineExponents(y, true)};
	Fraction quotient;
	bool msb{false};
	if (!top.BTEST(top.bits - 1) \|\| !divisor.BTEST(divisor.bits - 1)) {
	// One or two subnormals
	int topLshift{top.LEADZ()};
	top = top.SHIFTL(topLshift);
	int divisorLshift{divisor.LEADZ()};
	divisor = divisor.SHIFTL(divisorLshift);
	exponent += divisorLshift - topLshift;
	}
	for (int j{1}; j <= quotient.bits; ++j) {
	if (NextQuotientBit(top, msb, divisor)) {
	quotient = quotient.IBSET(quotient.bits - j);
	}
	}
	bool guard{NextQuotientBit(top, msb, divisor)};
	bool round{NextQuotientBit(top, msb, divisor)};
	bool sticky{msb \|\| !top.IsZero()};
	RoundingBits roundingBits{guard, round, sticky};
	if (exponent < 1) {
	std::int64_t rshift{1 - exponent};
	for (; rshift > 0; --rshift) {
	roundingBits.ShiftRight(quotient.BTEST(0));
	quotient = quotient.SHIFTR(1);
	}
	exponent = 1;
	}
	NormalizeAndRound(
	result, isNegative, exponent, quotient, rounding, roundingBits);
	}
	}
	return result;
	}

	template <typename W, int P>
	ValueWithRealFlags<Real<W, P>> Real<W, P>::SQRT(Rounding rounding) const {
	ValueWithRealFlags<Real> result;
	if (IsNotANumber()) {
	result.value = NotANumber();
	if (IsSignalingNaN()) {
	result.flags.set(RealFlag::InvalidArgument);
	}
	} else if (IsNegative()) {
	if (IsZero()) {
	// SQRT(-0) == -0 in IEEE-754.
	result.value.word_ = result.value.word_.IBSET(bits - 1);
	} else {
	result.value = NotANumber();
	}
	} else if (IsInfinite()) {
	// SQRT(+Inf) == +Inf
	result.value = Infinity(false);
	} else {
	// Slow but reliable bit-at-a-time method. Start with a clear significand
	// and half the unbiased exponent, and then try to set significand bits
	// in descending order of magnitude without exceeding the exact result.
	int expo{UnbiasedExponent()};
	if (IsSubnormal()) {
	expo -= GetFraction().LEADZ();
	}
	expo = expo / 2 + exponentBias;
	result.value.Normalize(false, expo, Fraction::MASKL(1));
	for (int bit{significandBits - 1}; bit >= 0; --bit) {
	Word word{result.value.word_};
	result.value.word_ = word.IBSET(bit);
	auto squared{result.value.Multiply(result.value, rounding)};
	if (squared.flags.test(RealFlag::Overflow) \|\|
	squared.flags.test(RealFlag::Underflow) \|\|
	Compare(squared.value) == Relation::Less) {
	result.value.word_ = word;
	}
	}
	// The computed square root, when squared, has a square that's not greater
	// than the original argument. Check this square against the square of the
	// next Real value, and return that one if its square is closer in magnitude
	// to the original argument.
	Real resultSq{result.value.Multiply(result.value).value};
	Real diff{Subtract(resultSq).value.ABS()};
	if (diff.IsZero()) {
	return result; // exact
	}
	Real ulp;
	ulp.Normalize(false, expo, Fraction::MASKR(1));
	Real nextAfter{result.value.Add(ulp).value};
	auto nextAfterSq{nextAfter.Multiply(nextAfter)};
	if (!nextAfterSq.flags.test(RealFlag::Overflow) &&
	!nextAfterSq.flags.test(RealFlag::Underflow)) {
	Real nextAfterDiff{Subtract(nextAfterSq.value).value.ABS()};
	if (nextAfterDiff.Compare(diff) == Relation::Less) {
	result.value = nextAfter;
	if (nextAfterDiff.IsZero()) {
	return result; // exact
	}
	}
	}
	result.flags.set(RealFlag::Inexact);
	}
	return result;
	}

	// HYPOT(x,y) = SQRT(x2 + y2) by definition, but those squared intermediate
	// values are susceptible to over/underflow when computed naively.
	// Assuming that x>=y, calculate instead:
	// HYPOT(x,y) = SQRT(x*2 (1+(y/x)**2))
	// = ABS(x) * SQRT(1+(y/x)**2)
	template <typename W, int P>
	ValueWithRealFlags<Real<W, P>> Real<W, P>::HYPOT(
	const Real &y, Rounding rounding) const {
	ValueWithRealFlags<Real> result;
	if (IsNotANumber() \|\| y.IsNotANumber()) {
	result.flags.set(RealFlag::InvalidArgument);
	result.value = NotANumber();
	} else if (ABS().Compare(y.ABS()) == Relation::Less) {
	return y.HYPOT(*this);
	} else if (IsZero()) {
	return result; // x==y==0
	} else {
	auto yOverX{y.Divide(*this, rounding)}; // y/x
	bool inexact{yOverX.flags.test(RealFlag::Inexact)};
	auto squared{yOverX.value.Multiply(yOverX.value, rounding)}; // (y/x)**2
	inexact \|= squared.flags.test(RealFlag::Inexact);
	Real one;
	one.Normalize(false, exponentBias, Fraction::MASKL(1)); // 1.0
	auto sum{squared.value.Add(one, rounding)}; // 1.0 + (y/x)**2
	inexact \|= sum.flags.test(RealFlag::Inexact);
	auto sqrt{sum.value.SQRT()};
	inexact \|= sqrt.flags.test(RealFlag::Inexact);
	result = sqrt.value.Multiply(ABS(), rounding);
	if (inexact) {
	result.flags.set(RealFlag::Inexact);
	}
	}
	return result;
	}

	template <typename W, int P>
	ValueWithRealFlags<Real<W, P>> Real<W, P>::ToWholeNumber(
	common::RoundingMode mode) const {
	ValueWithRealFlags<Real> result{*this};
	if (IsNotANumber()) {
	result.flags.set(RealFlag::InvalidArgument);
	result.value = NotANumber();
	} else if (IsInfinite()) {
	result.flags.set(RealFlag::Overflow);
	} else {
	constexpr int noClipExponent{exponentBias + binaryPrecision - 1};
	if (Exponent() < noClipExponent) {
	Real adjust; // ABS(EPSILON(adjust)) == 0.5
	adjust.Normalize(IsSignBitSet(), noClipExponent, Fraction::MASKL(1));
	// Compute ival=(*this + adjust), losing any fractional bits; keep flags
	result = Add(adjust, Rounding{mode});
	result.flags.reset(RealFlag::Inexact); // result is exact
	// Return (ival-adjust) with original sign in case we've generated a zero.
	result.value =
	result.value.Subtract(adjust, Rounding{common::RoundingMode::ToZero})
	.value.SIGN(*this);
	}
	}
	return result;
	}

	template <typename W, int P>
	RealFlags Real<W, P>::Normalize(bool negative, int exponent,
	const Fraction &fraction, Rounding rounding, RoundingBits *roundingBits) {
	int lshift{fraction.LEADZ()};
	if (lshift == fraction.bits /* fraction is zero */ &&
	(!roundingBits \|\| roundingBits->empty())) {
	// No fraction, no rounding bits -> +/-0.0
	exponent = lshift = 0;
	} else if (lshift < exponent) {
	exponent -= lshift;
	} else if (exponent > 0) {
	lshift = exponent - 1;
	exponent = 0;
	} else if (lshift == 0) {
	exponent = 1;
	} else {
	lshift = 0;
	}
	if (exponent >= maxExponent) {
	// Infinity or overflow
	if (rounding.mode == common::RoundingMode::TiesToEven \|\|
	rounding.mode == common::RoundingMode::TiesAwayFromZero \|\|
	(rounding.mode == common::RoundingMode::Up && !negative) \|\|
	(rounding.mode == common::RoundingMode::Down && negative)) {
	word_ = Word{maxExponent}.SHIFTL(significandBits); // Inf
	} else {
	// directed rounding: round to largest finite value rather than infinity
	// (x86 does this, not sure whether it's standard behavior)
	word_ = Word{word_.MASKR(word_.bits - 1)}.IBCLR(significandBits);
	}
	if (negative) {
	word_ = word_.IBSET(bits - 1);
	}
	RealFlags flags{RealFlag::Overflow};
	if (!fraction.IsZero()) {
	flags.set(RealFlag::Inexact);
	}
	return flags;
	}
	word_ = Word::ConvertUnsigned(fraction).value;
	if (lshift > 0) {
	word_ = word_.SHIFTL(lshift);
	if (roundingBits) {
	for (; lshift > 0; --lshift) {
	if (roundingBits->ShiftLeft()) {
	word_ = word_.IBSET(lshift - 1);
	}
	}
	}
	}
	if constexpr (isImplicitMSB) {
	word_ = word_.IBCLR(significandBits);
	}
	word_ = word_.IOR(Word{exponent}.SHIFTL(significandBits));
	if (negative) {
	word_ = word_.IBSET(bits - 1);
	}
	return {};
	}

	template <typename W, int P>
	RealFlags Real<W, P>::Round(
	Rounding rounding, const RoundingBits &bits, bool multiply) {
	int origExponent{Exponent()};
	RealFlags flags;
	bool inexact{!bits.empty()};
	if (inexact) {
	flags.set(RealFlag::Inexact);
	}
	if (origExponent < maxExponent &&
	bits.MustRound(rounding, IsNegative(), word_.BTEST(0) /* is odd */)) {
	typename Fraction::ValueWithCarry sum{
	GetFraction().AddUnsigned(Fraction{}, true)};
	int newExponent{origExponent};
	if (sum.carry) {
	// The fraction was all ones before rounding; sum.value is now zero
	sum.value = sum.value.IBSET(binaryPrecision - 1);
	if (++newExponent >= maxExponent) {
	flags.set(RealFlag::Overflow); // rounded away to an infinity
	}
	}
	flags \|= Normalize(IsNegative(), newExponent, sum.value);
	}
	if (inexact && origExponent == 0) {
	// inexact subnormal input: signal Underflow unless in an x86-specific
	// edge case
	if (rounding.x86CompatibleBehavior && Exponent() != 0 && multiply &&
	bits.sticky() &&
	(bits.guard() \|\|
	(rounding.mode != common::RoundingMode::Up &&
	rounding.mode != common::RoundingMode::Down))) {
	// x86 edge case in which Underflow fails to signal when a subnormal
	// inexact multiplication product rounds to a normal result when
	// the guard bit is set or we're not using directed rounding
	} else {
	flags.set(RealFlag::Underflow);
	}
	}
	return flags;
	}

	template <typename W, int P>
	void Real<W, P>::NormalizeAndRound(ValueWithRealFlags<Real> &result,
	bool isNegative, int exponent, const Fraction &fraction, Rounding rounding,
	RoundingBits roundingBits, bool multiply) {
	result.flags \|= result.value.Normalize(
	isNegative, exponent, fraction, rounding, &roundingBits);
	result.flags \|= result.value.Round(rounding, roundingBits, multiply);
	}

	inline enum decimal::FortranRounding MapRoundingMode(
	common::RoundingMode rounding) {
	switch (rounding) {
	case common::RoundingMode::TiesToEven:
	break;
	case common::RoundingMode::ToZero:
	return decimal::RoundToZero;
	case common::RoundingMode::Down:
	return decimal::RoundDown;
	case common::RoundingMode::Up:
	return decimal::RoundUp;
	case common::RoundingMode::TiesAwayFromZero:
	return decimal::RoundCompatible;
	}
	return decimal::RoundNearest; // dodge gcc warning about lack of result
	}

	inline RealFlags MapFlags(decimal::ConversionResultFlags flags) {
	RealFlags result;
	if (flags & decimal::Overflow) {
	result.set(RealFlag::Overflow);
	}
	if (flags & decimal::Inexact) {
	result.set(RealFlag::Inexact);
	}
	if (flags & decimal::Invalid) {
	result.set(RealFlag::InvalidArgument);
	}
	return result;
	}

	template <typename W, int P>
	ValueWithRealFlags<Real<W, P>> Real<W, P>::Read(
	const char *&p, Rounding rounding) {
	auto converted{
	decimal::ConvertToBinary<P>(p, MapRoundingMode(rounding.mode))};
	const auto value{reinterpret_cast<Real<W, P> >(&converted.binary)};
	return {*value, MapFlags(converted.flags)};
	}

	template <typename W, int P> std::string Real<W, P>::DumpHexadecimal() const {
	if (IsNotANumber()) {
	return "NaN0x"s + word_.Hexadecimal();
	} else if (IsNegative()) {
	return "-"s + Negate().DumpHexadecimal();
	} else if (IsInfinite()) {
	return "Inf"s;
	} else if (IsZero()) {
	return "0.0"s;
	} else {
	Fraction frac{GetFraction()};
	std::string result{"0x"};
	char intPart = '0' + frac.BTEST(frac.bits - 1);
	result += intPart;
	result += '.';
	int trailz{frac.TRAILZ()};
	if (trailz >= frac.bits - 1) {
	result += '0';
	} else {
	int remainingBits{frac.bits - 1 - trailz};
	int wholeNybbles{remainingBits / 4};
	int lostBits{remainingBits - 4 * wholeNybbles};
	if (wholeNybbles > 0) {
	std::string fracHex{frac.SHIFTR(trailz + lostBits)
	.IAND(frac.MASKR(4 * wholeNybbles))
	.Hexadecimal()};
	std::size_t field = wholeNybbles;
	if (fracHex.size() < field) {
	result += std::string(field - fracHex.size(), '0');
	}
	result += fracHex;
	}
	if (lostBits > 0) {
	result += frac.SHIFTR(trailz)
	.IAND(frac.MASKR(lostBits))
	.SHIFTL(4 - lostBits)
	.Hexadecimal();
	}
	}
	result += 'p';
	int exponent = Exponent() - exponentBias;
	result += Integer<32>{exponent}.SignedDecimal();
	return result;
	}
	}

	template <typename W, int P>
	llvm::raw_ostream &Real<W, P>::AsFortran(
	llvm::raw_ostream &o, int kind, bool minimal) const {
	if (IsNotANumber()) {
	o << "(0._" << kind << "/0.)";
	} else if (IsInfinite()) {
	if (IsNegative()) {
	o << "(-1._" << kind << "/0.)";
	} else {
	o << "(1._" << kind << "/0.)";
	}
	} else {
	using B = decimal::BinaryFloatingPointNumber<P>;
	B value{word_.template ToUInt<typename B::RawType>()};
	char buffer[common::MaxDecimalConversionDigits(P) +
	EXTRA_DECIMAL_CONVERSION_SPACE];
	decimal::DecimalConversionFlags flags{}; // default: exact representation
	if (minimal) {
	flags = decimal::Minimize;
	}
	auto result{decimal::ConvertToDecimal<P>(buffer, sizeof buffer, flags,
	static_cast<int>(sizeof buffer), decimal::RoundNearest, value)};
	const char *p{result.str};
	if (DEREF(p) == '-' \|\| *p == '+') {
	o << *p++;
	}
	int expo{result.decimalExponent};
	if (*p != '0') {
	--expo;
	}
	o << *p << '.' << (p + 1);
	if (expo != 0) {
	o << 'e' << expo;
	}
	o << '_' << kind;
	}
	return o;
	}

	template class Real<Integer<16>, 11>;
	template class Real<Integer<16>, 8>;
	template class Real<Integer<32>, 24>;
	template class Real<Integer<64>, 53>;
	template class Real<Integer<80>, 64>;
	template class Real<Integer<128>, 113>;
	} // namespace Fortran::evaluate::value