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

 #include "fp-testing.h"
 #include "testing.h"
 #include "flang/Evaluate/type.h"
 #include "llvm/Support/raw_ostream.h"
 #include <cmath>
 #include <cstdio>
 #include <cstdlib>
 #include <type_traits>

 using namespace Fortran::evaluate;
 using namespace Fortran::common;

 using Real2 = Scalar<Type<TypeCategory::Real, 2>>;
 using Real3 = Scalar<Type<TypeCategory::Real, 3>>;
 using Real4 = Scalar<Type<TypeCategory::Real, 4>>;
 using Real8 = Scalar<Type<TypeCategory::Real, 8>>;
 using Real10 = Scalar<Type<TypeCategory::Real, 10>>;
 using Real16 = Scalar<Type<TypeCategory::Real, 16>>;
 using Integer4 = Scalar<Type<TypeCategory::Integer, 4>>;
 using Integer8 = Scalar<Type<TypeCategory::Integer, 8>>;

 void dumpTest() {
   struct {
     std::uint64_t raw;
     const char *expected;
   } table[] = {
       {0x7f876543, "NaN 0x7f876543"},
       {0x7f800000, "Inf"},
       {0xff800000, "-Inf"},
       {0x00000000, "0.0"},
       {0x80000000, "-0.0"},
       {0x3f800000, "0x1.0p0"},
       {0xbf800000, "-0x1.0p0"},
       {0x40000000, "0x1.0p1"},
       {0x3f000000, "0x1.0p-1"},
       {0x7f7fffff, "0x1.fffffep127"},
       {0x00800000, "0x1.0p-126"},
       {0x00400000, "0x0.8p-127"},
       {0x00000001, "0x0.000002p-127"},
       {0, nullptr},
   };
   for (int j{0}; table[j].expected != nullptr; ++j) {
     TEST(Real4{Integer4{table[j].raw}}.DumpHexadecimal() == table[j].expected)
     ("%d", j);
   }
 }

 template <typename R> void basicTests(int rm, Rounding rounding) {
   static constexpr int kind{R::bits / 8};
   char desc[64];
   using Word = typename R::Word;
   std::snprintf(desc, sizeof desc, "bits=%d, le=%d, kind=%d", R::bits,
       Word::littleEndian, kind);
   R zero;
   TEST(!zero.IsNegative())(desc);
   TEST(!zero.IsNotANumber())(desc);
   TEST(!zero.IsInfinite())(desc);
   TEST(zero.IsZero())(desc);
   MATCH(0, zero.Exponent())(desc);
   TEST(zero.RawBits().IsZero())(desc);
   MATCH(0, zero.RawBits().ToUInt64())(desc);
   TEST(zero.ABS().RawBits().IsZero())(desc);
   TEST(zero.Negate().RawBits().IEOR(Word::MASKL(1)).IsZero())(desc);
   TEST(zero.Compare(zero) == Relation::Equal)(desc);
   R minusZero{Word{std::uint64_t{1}}.SHIFTL(R::bits - 1)};
   TEST(minusZero.IsNegative())(desc);
   TEST(!minusZero.IsNotANumber())(desc);
   TEST(!minusZero.IsInfinite())(desc);
   TEST(minusZero.IsZero())(desc);
   TEST(minusZero.ABS().RawBits().IsZero())(desc);
   TEST(minusZero.Negate().RawBits().IsZero())(desc);
   MATCH(0, minusZero.Exponent())(desc);
   MATCH(0, minusZero.RawBits().LEADZ())(desc);
   MATCH(1, minusZero.RawBits().POPCNT())(desc);
   TEST(minusZero.Compare(minusZero) == Relation::Equal)(desc);
   TEST(zero.Compare(minusZero) == Relation::Equal)(desc);
   ValueWithRealFlags<R> vr;
   MATCH(0, vr.value.RawBits().ToUInt64())(desc);
   TEST(vr.flags.empty())(desc);
   R nan{Word{std::uint64_t{1}}
             .SHIFTL(R::bits)
             .SubtractSigned(Word{std::uint64_t{1}})
             .value};
   MATCH(R::bits, nan.RawBits().POPCNT())(desc);
   TEST(!nan.IsNegative())(desc);
   TEST(nan.IsNotANumber())(desc);
   TEST(!nan.IsInfinite())(desc);
   TEST(!nan.IsZero())(desc);
   TEST(zero.Compare(nan) == Relation::Unordered)(desc);
   TEST(minusZero.Compare(nan) == Relation::Unordered)(desc);
   TEST(nan.Compare(zero) == Relation::Unordered)(desc);
   TEST(nan.Compare(minusZero) == Relation::Unordered)(desc);
   TEST(nan.Compare(nan) == Relation::Unordered)(desc);
   int significandBits{R::binaryPrecision - R::isImplicitMSB};
   int exponentBits{R::bits - significandBits - 1};
   std::uint64_t maxExponent{(std::uint64_t{1} << exponentBits) - 1};
   MATCH(nan.Exponent(), maxExponent)(desc);
   R inf{Word{maxExponent}.SHIFTL(significandBits)};
   TEST(!inf.IsNegative())(desc);
   TEST(!inf.IsNotANumber())(desc);
   TEST(inf.IsInfinite())(desc);
   TEST(!inf.IsZero())(desc);
   TEST(inf.RawBits().CompareUnsigned(inf.ABS().RawBits()) == Ordering::Equal)
   (desc);
   TEST(zero.Compare(inf) == Relation::Less)(desc);
   TEST(minusZero.Compare(inf) == Relation::Less)(desc);
   TEST(nan.Compare(inf) == Relation::Unordered)(desc);
   TEST(inf.Compare(inf) == Relation::Equal)(desc);
   R negInf{Word{maxExponent}.SHIFTL(significandBits).IOR(Word::MASKL(1))};
   TEST(negInf.IsNegative())(desc);
   TEST(!negInf.IsNotANumber())(desc);
   TEST(negInf.IsInfinite())(desc);
   TEST(!negInf.IsZero())(desc);
   TEST(inf.RawBits().CompareUnsigned(negInf.ABS().RawBits()) == Ordering::Equal)
   (desc);
   TEST(inf.RawBits().CompareUnsigned(negInf.Negate().RawBits()) ==
       Ordering::Equal)
   (desc);
   TEST(inf.Negate().RawBits().CompareUnsigned(negInf.RawBits()) ==
       Ordering::Equal)
   (desc);
   TEST(zero.Compare(negInf) == Relation::Greater)(desc);
   TEST(minusZero.Compare(negInf) == Relation::Greater)(desc);
   TEST(nan.Compare(negInf) == Relation::Unordered)(desc);
   TEST(inf.Compare(negInf) == Relation::Greater)(desc);
   TEST(negInf.Compare(negInf) == Relation::Equal)(desc);
   for (std::uint64_t j{0}; j < 63; ++j) {
     char ldesc[128];
     std::uint64_t x{1};
     x <<= j;
     std::snprintf(ldesc, sizeof ldesc, "%s j=%d x=0x%jx rm=%d", desc,
         static_cast<int>(j), static_cast<std::intmax_t>(x), rm);
     Integer8 ix{x};
     TEST(!ix.IsNegative())(ldesc);
     MATCH(x, ix.ToUInt64())(ldesc);
     vr = R::FromInteger(ix, rounding);
     TEST(!vr.value.IsNegative())(ldesc);
     TEST(!vr.value.IsNotANumber())(ldesc);
     TEST(!vr.value.IsZero())(ldesc);
     auto ivf = vr.value.template ToInteger<Integer8>();
     if (j > (maxExponent / 2)) {
       TEST(vr.flags.test(RealFlag::Overflow))(ldesc);
       TEST(vr.value.IsInfinite())(ldesc);
       TEST(ivf.flags.test(RealFlag::Overflow))(ldesc);
       MATCH(0x7fffffffffffffff, ivf.value.ToUInt64())(ldesc);
     } else {
       TEST(vr.flags.empty())(ldesc);
       TEST(!vr.value.IsInfinite())(ldesc);
       TEST(ivf.flags.empty())(ldesc);
       MATCH(x, ivf.value.ToUInt64())(ldesc);
       if (rounding.mode == RoundingMode::TiesToEven) { // to match stold()
         std::string buf;
         llvm::raw_string_ostream ss{buf};
         vr.value.AsFortran(ss, kind, false /*exact*/);
         std::string decimal{ss.str()};
         const char *p{decimal.data()};
         MATCH(x, static_cast<std::uint64_t>(std::stold(decimal)))
         ("%s %s", ldesc, p);
         auto check{R::Read(p, rounding)};
         auto icheck{check.value.template ToInteger<Integer8>()};
         MATCH(x, icheck.value.ToUInt64())(ldesc);
         TEST(vr.value.Compare(check.value) == Relation::Equal)(ldesc);
       }
     }
     TEST(vr.value.ToWholeNumber().value.Compare(vr.value) == Relation::Equal)
     (ldesc);
     ix = ix.Negate().value;
     TEST(ix.IsNegative())(ldesc);
     x = -x;
     std::int64_t nx = x;
     MATCH(x, ix.ToUInt64())(ldesc);
     MATCH(nx, ix.ToInt64())(ldesc);
     vr = R::FromInteger(ix);
     TEST(vr.value.IsNegative())(ldesc);
     TEST(!vr.value.IsNotANumber())(ldesc);
     TEST(!vr.value.IsZero())(ldesc);
     ivf = vr.value.template ToInteger<Integer8>();
     if (j > (maxExponent / 2)) {
       TEST(vr.flags.test(RealFlag::Overflow))(ldesc);
       TEST(vr.value.IsInfinite())(ldesc);
       TEST(ivf.flags.test(RealFlag::Overflow))(ldesc);
       MATCH(0x8000000000000000, ivf.value.ToUInt64())(ldesc);
     } else {
       TEST(vr.flags.empty())(ldesc);
       TEST(!vr.value.IsInfinite())(ldesc);
       TEST(ivf.flags.empty())(ldesc);
       MATCH(x, ivf.value.ToUInt64())(ldesc);
       MATCH(nx, ivf.value.ToInt64())(ldesc);
     }
     TEST(vr.value.ToWholeNumber().value.Compare(vr.value) == Relation::Equal)
     (ldesc);
   }
 }

 // Takes an integer and distributes its bits across a floating
 // point value.  The LSB is used to complement the result.
 std::uint32_t MakeReal(std::uint32_t n) {
   int shifts[] = {-1, 31, 23, 30, 22, 0, 24, 29, 25, 28, 26, 1, 16, 21, 2, -1};
   std::uint32_t x{0};
   for (int j{1}; shifts[j] >= 0; ++j) {
     x |= ((n >> j) & 1) << shifts[j];
   }
   x ^= -(n & 1);
   return x;
 }

 std::uint64_t MakeReal(std::uint64_t n) {
   int shifts[] = {
       -1, 63, 52, 62, 51, 0, 53, 61, 54, 60, 55, 59, 1, 16, 50, 2, -1};
   std::uint64_t x{0};
   for (int j{1}; shifts[j] >= 0; ++j) {
     x |= ((n >> j) & 1) << shifts[j];
   }
   x ^= -(n & 1);
   return x;
 }

 inline bool IsNaN(std::uint32_t x) {
   return (x & 0x7f800000) == 0x7f800000 && (x & 0x007fffff) != 0;
 }

 inline bool IsNaN(std::uint64_t x) {
   return (x & 0x7ff0000000000000) == 0x7ff0000000000000 &&
       (x & 0x000fffffffffffff) != 0;
 }

 inline bool IsInfinite(std::uint32_t x) {
   return (x & 0x7fffffff) == 0x7f800000;
 }

 inline bool IsInfinite(std::uint64_t x) {
   return (x & 0x7fffffffffffffff) == 0x7ff0000000000000;
 }

 inline bool IsNegative(std::uint32_t x) { return (x & 0x80000000) != 0; }

 inline bool IsNegative(std::uint64_t x) {
   return (x & 0x8000000000000000) != 0;
 }

 inline std::uint32_t NormalizeNaN(std::uint32_t x) {
   if (IsNaN(x)) {
     x = 0x7fe00000;
   }
   return x;
 }

 inline std::uint64_t NormalizeNaN(std::uint64_t x) {
   if (IsNaN(x)) {
     x = 0x7ffc000000000000;
   }
   return x;
 }

 enum FlagBits {
   Overflow = 1,
   DivideByZero = 2,
   InvalidArgument = 4,
   Underflow = 8,
   Inexact = 16,
 };

 #ifdef __clang__
 // clang support for fenv.h is broken, so tests of flag settings
 // are disabled.
 inline std::uint32_t FlagsToBits(const RealFlags &) { return 0; }
 #else
 inline std::uint32_t FlagsToBits(const RealFlags &flags) {
   std::uint32_t bits{0};
   if (flags.test(RealFlag::Overflow)) {
     bits |= Overflow;
   }
   if (flags.test(RealFlag::DivideByZero)) {
     bits |= DivideByZero;
   }
   if (flags.test(RealFlag::InvalidArgument)) {
     bits |= InvalidArgument;
   }
   if (flags.test(RealFlag::Underflow)) {
     bits |= Underflow;
   }
   if (flags.test(RealFlag::Inexact)) {
     bits |= Inexact;
   }
   return bits;
 }
 #endif // __clang__

 template <typename UINT = std::uint32_t, typename FLT = float, typename REAL>
 void inttest(std::int64_t x, int pass, Rounding rounding) {
   union {
     UINT ui;
     FLT f;
   } u;
   ScopedHostFloatingPointEnvironment fpenv;
   Integer8 ix{x};
   ValueWithRealFlags<REAL> real;
   real = real.value.FromInteger(ix, rounding);
 #ifndef __clang__ // broken and also slow
   fpenv.ClearFlags();
 #endif
   FLT fcheck = x; // TODO unsigned too
   auto actualFlags{FlagsToBits(fpenv.CurrentFlags())};
   u.f = fcheck;
   UINT rcheck{NormalizeNaN(u.ui)};
   UINT check = real.value.RawBits().ToUInt64();
   MATCH(rcheck, check)("%d 0x%llx", pass, x);
   MATCH(actualFlags, FlagsToBits(real.flags))("%d 0x%llx", pass, x);
 }

 template <typename FLT = float> FLT ToIntPower(FLT x, int power) {
   if (power == 0) {
     return x / x;
   }
   bool negative{power < 0};
   if (negative) {
     power = -power;
   }
   FLT result{1};
   while (power > 0) {
     if (power & 1) {
       result *= x;
     }
     x *= x;
     power >>= 1;
   }
   if (negative) {
     result = 1.0 / result;
   }
   return result;
 }

 template <typename FLT, int decimalDigits>
 FLT TimesIntPowerOfTen(FLT x, int power) {
   if (power > decimalDigits || power < -decimalDigits) {
     auto maxExactPowerOfTen{
         TimesIntPowerOfTen<FLT, decimalDigits>(1, decimalDigits)};
     auto big{ToIntPower<FLT>(maxExactPowerOfTen, power / decimalDigits)};
     auto small{
         TimesIntPowerOfTen<FLT, decimalDigits>(1, power % decimalDigits)};
     return (x * big) * small;
   }
   return x * ToIntPower<FLT>(10.0, power);
 }

 template <typename UINT = std::uint32_t, typename FLT = float,
     typename REAL = Real4>
 void subsetTests(int pass, Rounding rounding, std::uint32_t opds) {
   for (int j{0}; j < 63; ++j) {
     std::int64_t x{1};
     x <<= j;
     inttest<UINT, FLT, REAL>(x, pass, rounding);
     inttest<UINT, FLT, REAL>(-x, pass, rounding);
   }
   inttest<UINT, FLT, REAL>(0, pass, rounding);
   inttest<UINT, FLT, REAL>(
       static_cast<std::int64_t>(0x8000000000000000), pass, rounding);

   union {
     UINT ui;
     FLT f;
   } u;
   ScopedHostFloatingPointEnvironment fpenv;

   for (UINT j{0}; j < opds; ++j) {

     UINT rj{MakeReal(j)};
     u.ui = rj;
     FLT fj{u.f};
     REAL x{typename REAL::Word{std::uint64_t{rj}}};

     // unary operations
     {
       ValueWithRealFlags<REAL> aint{x.ToWholeNumber()};
 #ifndef __clang__ // broken and also slow
       fpenv.ClearFlags();
 #endif
       FLT fcheck{std::trunc(fj)};
       auto actualFlags{FlagsToBits(fpenv.CurrentFlags())};
       actualFlags &= ~Inexact; // x86 std::trunc can set Inexact; AINT ain't
       u.f = fcheck;
 #ifndef __clang__
       if (IsNaN(u.ui)) {
         actualFlags |= InvalidArgument; // x86 std::trunc(NaN) workaround
       }
 #endif
       UINT rcheck{NormalizeNaN(u.ui)};
       UINT check = aint.value.RawBits().ToUInt64();
       MATCH(rcheck, check)
       ("%d AINT(0x%jx)", pass, static_cast<std::intmax_t>(rj));
       MATCH(actualFlags, FlagsToBits(aint.flags))
       ("%d AINT(0x%jx)", pass, static_cast<std::intmax_t>(rj));
     }

     {
       MATCH(IsNaN(rj), x.IsNotANumber())
       ("%d IsNaN(0x%jx)", pass, static_cast<std::intmax_t>(rj));
       MATCH(IsInfinite(rj), x.IsInfinite())
       ("%d IsInfinite(0x%jx)", pass, static_cast<std::intmax_t>(rj));

       static constexpr int kind{REAL::bits / 8};
       std::string ssBuf, cssBuf;
       llvm::raw_string_ostream ss{ssBuf};
       llvm::raw_string_ostream css{cssBuf};
       x.AsFortran(ss, kind, false /*exact*/);
       std::string s{ss.str()};
       if (IsNaN(rj)) {
         css << "(0._" << kind << "/0.)";
         MATCH(css.str(), s)
         ("%d invalid(0x%jx)", pass, static_cast<std::intmax_t>(rj));
       } else if (IsInfinite(rj)) {
         css << '(';
         if (IsNegative(rj)) {
           css << '-';
         }
         css << "1._" << kind << "/0.)";
         MATCH(css.str(), s)
         ("%d overflow(0x%jx)", pass, static_cast<std::intmax_t>(rj));
       } else {
         const char *p = s.data();
         if (*p == '(') {
           ++p;
         }
         auto readBack{REAL::Read(p, rounding)};
         MATCH(rj, readBack.value.RawBits().ToUInt64())
         ("%d Read(AsFortran()) 0x%jx %s %g", pass,
             static_cast<std::intmax_t>(rj), s.data(), static_cast<double>(fj));
         MATCH('_', *p)
         ("%d Read(AsFortran()) 0x%jx %s %d", pass,
             static_cast<std::intmax_t>(rj), s.data(),
             static_cast<int>(p - s.data()));
       }
     }

     // dyadic operations
     for (UINT k{0}; k < opds; ++k) {
       UINT rk{MakeReal(k)};
       u.ui = rk;
       FLT fk{u.f};
       REAL y{typename REAL::Word{std::uint64_t{rk}}};
       {
         ValueWithRealFlags<REAL> sum{x.Add(y, rounding)};
 #ifndef __clang__ // broken and also slow
         fpenv.ClearFlags();
 #endif
         FLT fcheck{fj + fk};
         auto actualFlags{FlagsToBits(fpenv.CurrentFlags())};
         u.f = fcheck;
         UINT rcheck{NormalizeNaN(u.ui)};
         UINT check = sum.value.RawBits().ToUInt64();
         MATCH(rcheck, check)
         ("%d 0x%jx + 0x%jx", pass, static_cast<std::intmax_t>(rj),
             static_cast<std::intmax_t>(rk));
         MATCH(actualFlags, FlagsToBits(sum.flags))
         ("%d 0x%jx + 0x%jx", pass, static_cast<std::intmax_t>(rj),
             static_cast<std::intmax_t>(rk));
       }
       {
         ValueWithRealFlags<REAL> diff{x.Subtract(y, rounding)};
 #ifndef __clang__ // broken and also slow
         fpenv.ClearFlags();
 #endif
         FLT fcheck{fj - fk};
         auto actualFlags{FlagsToBits(fpenv.CurrentFlags())};
         u.f = fcheck;
         UINT rcheck{NormalizeNaN(u.ui)};
         UINT check = diff.value.RawBits().ToUInt64();
         MATCH(rcheck, check)
         ("%d 0x%jx - 0x%jx", pass, static_cast<std::intmax_t>(rj),
             static_cast<std::intmax_t>(rk));
         MATCH(actualFlags, FlagsToBits(diff.flags))
         ("%d 0x%jx - 0x%jx", pass, static_cast<std::intmax_t>(rj),
             static_cast<std::intmax_t>(rk));
       }
       {
         ValueWithRealFlags<REAL> prod{x.Multiply(y, rounding)};
 #ifndef __clang__ // broken and also slow
         fpenv.ClearFlags();
 #endif
         FLT fcheck{fj * fk};
         auto actualFlags{FlagsToBits(fpenv.CurrentFlags())};
         u.f = fcheck;
         UINT rcheck{NormalizeNaN(u.ui)};
         UINT check = prod.value.RawBits().ToUInt64();
         MATCH(rcheck, check)
         ("%d 0x%jx * 0x%jx", pass, static_cast<std::intmax_t>(rj),
             static_cast<std::intmax_t>(rk));
         MATCH(actualFlags, FlagsToBits(prod.flags))
         ("%d 0x%jx * 0x%jx", pass, static_cast<std::intmax_t>(rj),
             static_cast<std::intmax_t>(rk));
       }
       {
         ValueWithRealFlags<REAL> quot{x.Divide(y, rounding)};
 #ifndef __clang__ // broken and also slow
         fpenv.ClearFlags();
 #endif
         FLT fcheck{fj / fk};
         auto actualFlags{FlagsToBits(fpenv.CurrentFlags())};
         u.f = fcheck;
         UINT rcheck{NormalizeNaN(u.ui)};
         UINT check = quot.value.RawBits().ToUInt64();
         MATCH(rcheck, check)
         ("%d 0x%jx / 0x%jx", pass, static_cast<std::intmax_t>(rj),
             static_cast<std::intmax_t>(rk));
         MATCH(actualFlags, FlagsToBits(quot.flags))
         ("%d 0x%jx / 0x%jx", pass, static_cast<std::intmax_t>(rj),
             static_cast<std::intmax_t>(rk));
       }
     }
   }
 }

 void roundTest(int rm, Rounding rounding, std::uint32_t opds) {
   basicTests<Real2>(rm, rounding);
   basicTests<Real3>(rm, rounding);
   basicTests<Real4>(rm, rounding);
   basicTests<Real8>(rm, rounding);
   basicTests<Real10>(rm, rounding);
   basicTests<Real16>(rm, rounding);
   ScopedHostFloatingPointEnvironment::SetRounding(rounding);
   subsetTests<std::uint32_t, float, Real4>(rm, rounding, opds);
   subsetTests<std::uint64_t, double, Real8>(rm, rounding, opds);
 }

 int main() {
   dumpTest();
   std::uint32_t opds{512}; // for quick testing by default
   if (const char *p{std::getenv("REAL_TEST_OPERANDS")}) {
     // Use 8192 or 16384 for more exhaustive testing.
     opds = std::atol(p);
   }
   roundTest(0, Rounding{RoundingMode::TiesToEven}, opds);
   roundTest(1, Rounding{RoundingMode::ToZero}, opds);
   roundTest(2, Rounding{RoundingMode::Up}, opds);
   roundTest(3, Rounding{RoundingMode::Down}, opds);
   // TODO: how to test Rounding::TiesAwayFromZero on x86?
   return testing::Complete();
 }
	#include "fp-testing.h"
	#include "testing.h"
	#include "flang/Evaluate/type.h"
	#include "llvm/Support/raw_ostream.h"
	#include <cmath>
	#include <cstdio>
	#include <cstdlib>
	#include <type_traits>

	using namespace Fortran::evaluate;
	using namespace Fortran::common;

	using Real2 = Scalar<Type<TypeCategory::Real, 2>>;
	using Real3 = Scalar<Type<TypeCategory::Real, 3>>;
	using Real4 = Scalar<Type<TypeCategory::Real, 4>>;
	using Real8 = Scalar<Type<TypeCategory::Real, 8>>;
	using Real10 = Scalar<Type<TypeCategory::Real, 10>>;
	using Real16 = Scalar<Type<TypeCategory::Real, 16>>;
	using Integer4 = Scalar<Type<TypeCategory::Integer, 4>>;
	using Integer8 = Scalar<Type<TypeCategory::Integer, 8>>;

	void dumpTest() {
	struct {
	std::uint64_t raw;
	const char *expected;
	} table[] = {
	{0x7f876543, "NaN 0x7f876543"},
	{0x7f800000, "Inf"},
	{0xff800000, "-Inf"},
	{0x00000000, "0.0"},
	{0x80000000, "-0.0"},
	{0x3f800000, "0x1.0p0"},
	{0xbf800000, "-0x1.0p0"},
	{0x40000000, "0x1.0p1"},
	{0x3f000000, "0x1.0p-1"},
	{0x7f7fffff, "0x1.fffffep127"},
	{0x00800000, "0x1.0p-126"},
	{0x00400000, "0x0.8p-127"},
	{0x00000001, "0x0.000002p-127"},
	{0, nullptr},
	};
	for (int j{0}; table[j].expected != nullptr; ++j) {
	TEST(Real4{Integer4{table[j].raw}}.DumpHexadecimal() == table[j].expected)
	("%d", j);
	}
	}

	template <typename R> void basicTests(int rm, Rounding rounding) {
	static constexpr int kind{R::bits / 8};
	char desc[64];
	using Word = typename R::Word;
	std::snprintf(desc, sizeof desc, "bits=%d, le=%d, kind=%d", R::bits,
	Word::littleEndian, kind);
	R zero;
	TEST(!zero.IsNegative())(desc);
	TEST(!zero.IsNotANumber())(desc);
	TEST(!zero.IsInfinite())(desc);
	TEST(zero.IsZero())(desc);
	MATCH(0, zero.Exponent())(desc);
	TEST(zero.RawBits().IsZero())(desc);
	MATCH(0, zero.RawBits().ToUInt64())(desc);
	TEST(zero.ABS().RawBits().IsZero())(desc);
	TEST(zero.Negate().RawBits().IEOR(Word::MASKL(1)).IsZero())(desc);
	TEST(zero.Compare(zero) == Relation::Equal)(desc);
	R minusZero{Word{std::uint64_t{1}}.SHIFTL(R::bits - 1)};
	TEST(minusZero.IsNegative())(desc);
	TEST(!minusZero.IsNotANumber())(desc);
	TEST(!minusZero.IsInfinite())(desc);
	TEST(minusZero.IsZero())(desc);
	TEST(minusZero.ABS().RawBits().IsZero())(desc);
	TEST(minusZero.Negate().RawBits().IsZero())(desc);
	MATCH(0, minusZero.Exponent())(desc);
	MATCH(0, minusZero.RawBits().LEADZ())(desc);
	MATCH(1, minusZero.RawBits().POPCNT())(desc);
	TEST(minusZero.Compare(minusZero) == Relation::Equal)(desc);
	TEST(zero.Compare(minusZero) == Relation::Equal)(desc);
	ValueWithRealFlags<R> vr;
	MATCH(0, vr.value.RawBits().ToUInt64())(desc);
	TEST(vr.flags.empty())(desc);
	R nan{Word{std::uint64_t{1}}
	.SHIFTL(R::bits)
	.SubtractSigned(Word{std::uint64_t{1}})
	.value};
	MATCH(R::bits, nan.RawBits().POPCNT())(desc);
	TEST(!nan.IsNegative())(desc);
	TEST(nan.IsNotANumber())(desc);
	TEST(!nan.IsInfinite())(desc);
	TEST(!nan.IsZero())(desc);
	TEST(zero.Compare(nan) == Relation::Unordered)(desc);
	TEST(minusZero.Compare(nan) == Relation::Unordered)(desc);
	TEST(nan.Compare(zero) == Relation::Unordered)(desc);
	TEST(nan.Compare(minusZero) == Relation::Unordered)(desc);
	TEST(nan.Compare(nan) == Relation::Unordered)(desc);
	int significandBits{R::binaryPrecision - R::isImplicitMSB};
	int exponentBits{R::bits - significandBits - 1};
	std::uint64_t maxExponent{(std::uint64_t{1} << exponentBits) - 1};
	MATCH(nan.Exponent(), maxExponent)(desc);
	R inf{Word{maxExponent}.SHIFTL(significandBits)};
	TEST(!inf.IsNegative())(desc);
	TEST(!inf.IsNotANumber())(desc);
	TEST(inf.IsInfinite())(desc);
	TEST(!inf.IsZero())(desc);
	TEST(inf.RawBits().CompareUnsigned(inf.ABS().RawBits()) == Ordering::Equal)
	(desc);
	TEST(zero.Compare(inf) == Relation::Less)(desc);
	TEST(minusZero.Compare(inf) == Relation::Less)(desc);
	TEST(nan.Compare(inf) == Relation::Unordered)(desc);
	TEST(inf.Compare(inf) == Relation::Equal)(desc);
	R negInf{Word{maxExponent}.SHIFTL(significandBits).IOR(Word::MASKL(1))};
	TEST(negInf.IsNegative())(desc);
	TEST(!negInf.IsNotANumber())(desc);
	TEST(negInf.IsInfinite())(desc);
	TEST(!negInf.IsZero())(desc);
	TEST(inf.RawBits().CompareUnsigned(negInf.ABS().RawBits()) == Ordering::Equal)
	(desc);
	TEST(inf.RawBits().CompareUnsigned(negInf.Negate().RawBits()) ==
	Ordering::Equal)
	(desc);
	TEST(inf.Negate().RawBits().CompareUnsigned(negInf.RawBits()) ==
	Ordering::Equal)
	(desc);
	TEST(zero.Compare(negInf) == Relation::Greater)(desc);
	TEST(minusZero.Compare(negInf) == Relation::Greater)(desc);
	TEST(nan.Compare(negInf) == Relation::Unordered)(desc);
	TEST(inf.Compare(negInf) == Relation::Greater)(desc);
	TEST(negInf.Compare(negInf) == Relation::Equal)(desc);
	for (std::uint64_t j{0}; j < 63; ++j) {
	char ldesc[128];
	std::uint64_t x{1};
	x <<= j;
	std::snprintf(ldesc, sizeof ldesc, "%s j=%d x=0x%jx rm=%d", desc,
	static_cast<int>(j), static_cast<std::intmax_t>(x), rm);
	Integer8 ix{x};
	TEST(!ix.IsNegative())(ldesc);
	MATCH(x, ix.ToUInt64())(ldesc);
	vr = R::FromInteger(ix, rounding);
	TEST(!vr.value.IsNegative())(ldesc);
	TEST(!vr.value.IsNotANumber())(ldesc);
	TEST(!vr.value.IsZero())(ldesc);
	auto ivf = vr.value.template ToInteger<Integer8>();
	if (j > (maxExponent / 2)) {
	TEST(vr.flags.test(RealFlag::Overflow))(ldesc);
	TEST(vr.value.IsInfinite())(ldesc);
	TEST(ivf.flags.test(RealFlag::Overflow))(ldesc);
	MATCH(0x7fffffffffffffff, ivf.value.ToUInt64())(ldesc);
	} else {
	TEST(vr.flags.empty())(ldesc);
	TEST(!vr.value.IsInfinite())(ldesc);
	TEST(ivf.flags.empty())(ldesc);
	MATCH(x, ivf.value.ToUInt64())(ldesc);
	if (rounding.mode == RoundingMode::TiesToEven) { // to match stold()
	std::string buf;
	llvm::raw_string_ostream ss{buf};
	vr.value.AsFortran(ss, kind, false /exact/);
	std::string decimal{ss.str()};
	const char *p{decimal.data()};
	MATCH(x, static_cast<std::uint64_t>(std::stold(decimal)))
	("%s %s", ldesc, p);
	auto check{R::Read(p, rounding)};
	auto icheck{check.value.template ToInteger<Integer8>()};
	MATCH(x, icheck.value.ToUInt64())(ldesc);
	TEST(vr.value.Compare(check.value) == Relation::Equal)(ldesc);
	}
	}
	TEST(vr.value.ToWholeNumber().value.Compare(vr.value) == Relation::Equal)
	(ldesc);
	ix = ix.Negate().value;
	TEST(ix.IsNegative())(ldesc);
	x = -x;
	std::int64_t nx = x;
	MATCH(x, ix.ToUInt64())(ldesc);
	MATCH(nx, ix.ToInt64())(ldesc);
	vr = R::FromInteger(ix);
	TEST(vr.value.IsNegative())(ldesc);
	TEST(!vr.value.IsNotANumber())(ldesc);
	TEST(!vr.value.IsZero())(ldesc);
	ivf = vr.value.template ToInteger<Integer8>();
	if (j > (maxExponent / 2)) {
	TEST(vr.flags.test(RealFlag::Overflow))(ldesc);
	TEST(vr.value.IsInfinite())(ldesc);
	TEST(ivf.flags.test(RealFlag::Overflow))(ldesc);
	MATCH(0x8000000000000000, ivf.value.ToUInt64())(ldesc);
	} else {
	TEST(vr.flags.empty())(ldesc);
	TEST(!vr.value.IsInfinite())(ldesc);
	TEST(ivf.flags.empty())(ldesc);
	MATCH(x, ivf.value.ToUInt64())(ldesc);
	MATCH(nx, ivf.value.ToInt64())(ldesc);
	}
	TEST(vr.value.ToWholeNumber().value.Compare(vr.value) == Relation::Equal)
	(ldesc);
	}
	}

	// Takes an integer and distributes its bits across a floating
	// point value. The LSB is used to complement the result.
	std::uint32_t MakeReal(std::uint32_t n) {
	int shifts[] = {-1, 31, 23, 30, 22, 0, 24, 29, 25, 28, 26, 1, 16, 21, 2, -1};
	std::uint32_t x{0};
	for (int j{1}; shifts[j] >= 0; ++j) {
	x \|= ((n >> j) & 1) << shifts[j];
	}
	x ^= -(n & 1);
	return x;
	}

	std::uint64_t MakeReal(std::uint64_t n) {
	int shifts[] = {
	-1, 63, 52, 62, 51, 0, 53, 61, 54, 60, 55, 59, 1, 16, 50, 2, -1};
	std::uint64_t x{0};
	for (int j{1}; shifts[j] >= 0; ++j) {
	x \|= ((n >> j) & 1) << shifts[j];
	}
	x ^= -(n & 1);
	return x;
	}

	inline bool IsNaN(std::uint32_t x) {
	return (x & 0x7f800000) == 0x7f800000 && (x & 0x007fffff) != 0;
	}

	inline bool IsNaN(std::uint64_t x) {
	return (x & 0x7ff0000000000000) == 0x7ff0000000000000 &&
	(x & 0x000fffffffffffff) != 0;
	}

	inline bool IsInfinite(std::uint32_t x) {
	return (x & 0x7fffffff) == 0x7f800000;
	}

	inline bool IsInfinite(std::uint64_t x) {
	return (x & 0x7fffffffffffffff) == 0x7ff0000000000000;
	}

	inline bool IsNegative(std::uint32_t x) { return (x & 0x80000000) != 0; }

	inline bool IsNegative(std::uint64_t x) {
	return (x & 0x8000000000000000) != 0;
	}

	inline std::uint32_t NormalizeNaN(std::uint32_t x) {
	if (IsNaN(x)) {
	x = 0x7fe00000;
	}
	return x;
	}

	inline std::uint64_t NormalizeNaN(std::uint64_t x) {
	if (IsNaN(x)) {
	x = 0x7ffc000000000000;
	}
	return x;
	}

	enum FlagBits {
	Overflow = 1,
	DivideByZero = 2,
	InvalidArgument = 4,
	Underflow = 8,
	Inexact = 16,
	};

	#ifdef __clang__
	// clang support for fenv.h is broken, so tests of flag settings
	// are disabled.
	inline std::uint32_t FlagsToBits(const RealFlags &) { return 0; }
	#else
	inline std::uint32_t FlagsToBits(const RealFlags &flags) {
	std::uint32_t bits{0};
	if (flags.test(RealFlag::Overflow)) {
	bits \|= Overflow;
	}
	if (flags.test(RealFlag::DivideByZero)) {
	bits \|= DivideByZero;
	}
	if (flags.test(RealFlag::InvalidArgument)) {
	bits \|= InvalidArgument;
	}
	if (flags.test(RealFlag::Underflow)) {
	bits \|= Underflow;
	}
	if (flags.test(RealFlag::Inexact)) {
	bits \|= Inexact;
	}
	return bits;
	}
	#endif // __clang__

	template <typename UINT = std::uint32_t, typename FLT = float, typename REAL>
	void inttest(std::int64_t x, int pass, Rounding rounding) {
	union {
	UINT ui;
	FLT f;
	} u;
	ScopedHostFloatingPointEnvironment fpenv;
	Integer8 ix{x};
	ValueWithRealFlags<REAL> real;
	real = real.value.FromInteger(ix, rounding);
	#ifndef __clang__ // broken and also slow
	fpenv.ClearFlags();
	#endif
	FLT fcheck = x; // TODO unsigned too
	auto actualFlags{FlagsToBits(fpenv.CurrentFlags())};
	u.f = fcheck;
	UINT rcheck{NormalizeNaN(u.ui)};
	UINT check = real.value.RawBits().ToUInt64();
	MATCH(rcheck, check)("%d 0x%llx", pass, x);
	MATCH(actualFlags, FlagsToBits(real.flags))("%d 0x%llx", pass, x);
	}

	template <typename FLT = float> FLT ToIntPower(FLT x, int power) {
	if (power == 0) {
	return x / x;
	}
	bool negative{power < 0};
	if (negative) {
	power = -power;
	}
	FLT result{1};
	while (power > 0) {
	if (power & 1) {
	result *= x;
	}
	x *= x;
	power >>= 1;
	}
	if (negative) {
	result = 1.0 / result;
	}
	return result;
	}

	template <typename FLT, int decimalDigits>
	FLT TimesIntPowerOfTen(FLT x, int power) {
	if (power > decimalDigits \|\| power < -decimalDigits) {
	auto maxExactPowerOfTen{
	TimesIntPowerOfTen<FLT, decimalDigits>(1, decimalDigits)};
	auto big{ToIntPower<FLT>(maxExactPowerOfTen, power / decimalDigits)};
	auto small{
	TimesIntPowerOfTen<FLT, decimalDigits>(1, power % decimalDigits)};
	return (x * big) * small;
	}
	return x * ToIntPower<FLT>(10.0, power);
	}

	template <typename UINT = std::uint32_t, typename FLT = float,
	typename REAL = Real4>
	void subsetTests(int pass, Rounding rounding, std::uint32_t opds) {
	for (int j{0}; j < 63; ++j) {
	std::int64_t x{1};
	x <<= j;
	inttest<UINT, FLT, REAL>(x, pass, rounding);
	inttest<UINT, FLT, REAL>(-x, pass, rounding);
	}
	inttest<UINT, FLT, REAL>(0, pass, rounding);
	inttest<UINT, FLT, REAL>(
	static_cast<std::int64_t>(0x8000000000000000), pass, rounding);

	union {
	UINT ui;
	FLT f;
	} u;
	ScopedHostFloatingPointEnvironment fpenv;

	for (UINT j{0}; j < opds; ++j) {

	UINT rj{MakeReal(j)};
	u.ui = rj;
	FLT fj{u.f};
	REAL x{typename REAL::Word{std::uint64_t{rj}}};

	// unary operations
	{
	ValueWithRealFlags<REAL> aint{x.ToWholeNumber()};
	#ifndef __clang__ // broken and also slow
	fpenv.ClearFlags();
	#endif
	FLT fcheck{std::trunc(fj)};
	auto actualFlags{FlagsToBits(fpenv.CurrentFlags())};
	actualFlags &= ~Inexact; // x86 std::trunc can set Inexact; AINT ain't
	u.f = fcheck;
	#ifndef __clang__
	if (IsNaN(u.ui)) {
	actualFlags \|= InvalidArgument; // x86 std::trunc(NaN) workaround
	}
	#endif
	UINT rcheck{NormalizeNaN(u.ui)};
	UINT check = aint.value.RawBits().ToUInt64();
	MATCH(rcheck, check)
	("%d AINT(0x%jx)", pass, static_cast<std::intmax_t>(rj));
	MATCH(actualFlags, FlagsToBits(aint.flags))
	("%d AINT(0x%jx)", pass, static_cast<std::intmax_t>(rj));
	}

	{
	MATCH(IsNaN(rj), x.IsNotANumber())
	("%d IsNaN(0x%jx)", pass, static_cast<std::intmax_t>(rj));
	MATCH(IsInfinite(rj), x.IsInfinite())
	("%d IsInfinite(0x%jx)", pass, static_cast<std::intmax_t>(rj));

	static constexpr int kind{REAL::bits / 8};
	std::string ssBuf, cssBuf;
	llvm::raw_string_ostream ss{ssBuf};
	llvm::raw_string_ostream css{cssBuf};
	x.AsFortran(ss, kind, false /exact/);
	std::string s{ss.str()};
	if (IsNaN(rj)) {
	css << "(0._" << kind << "/0.)";
	MATCH(css.str(), s)
	("%d invalid(0x%jx)", pass, static_cast<std::intmax_t>(rj));
	} else if (IsInfinite(rj)) {
	css << '(';
	if (IsNegative(rj)) {
	css << '-';
	}
	css << "1._" << kind << "/0.)";
	MATCH(css.str(), s)
	("%d overflow(0x%jx)", pass, static_cast<std::intmax_t>(rj));
	} else {
	const char *p = s.data();
	if (*p == '(') {
	++p;
	}
	auto readBack{REAL::Read(p, rounding)};
	MATCH(rj, readBack.value.RawBits().ToUInt64())
	("%d Read(AsFortran()) 0x%jx %s %g", pass,
	static_cast<std::intmax_t>(rj), s.data(), static_cast<double>(fj));
	MATCH('_', *p)
	("%d Read(AsFortran()) 0x%jx %s %d", pass,
	static_cast<std::intmax_t>(rj), s.data(),
	static_cast<int>(p - s.data()));
	}
	}

	// dyadic operations
	for (UINT k{0}; k < opds; ++k) {
	UINT rk{MakeReal(k)};
	u.ui = rk;
	FLT fk{u.f};
	REAL y{typename REAL::Word{std::uint64_t{rk}}};
	{
	ValueWithRealFlags<REAL> sum{x.Add(y, rounding)};
	#ifndef __clang__ // broken and also slow
	fpenv.ClearFlags();
	#endif
	FLT fcheck{fj + fk};
	auto actualFlags{FlagsToBits(fpenv.CurrentFlags())};
	u.f = fcheck;
	UINT rcheck{NormalizeNaN(u.ui)};
	UINT check = sum.value.RawBits().ToUInt64();
	MATCH(rcheck, check)
	("%d 0x%jx + 0x%jx", pass, static_cast<std::intmax_t>(rj),
	static_cast<std::intmax_t>(rk));
	MATCH(actualFlags, FlagsToBits(sum.flags))
	("%d 0x%jx + 0x%jx", pass, static_cast<std::intmax_t>(rj),
	static_cast<std::intmax_t>(rk));
	}
	{
	ValueWithRealFlags<REAL> diff{x.Subtract(y, rounding)};
	#ifndef __clang__ // broken and also slow
	fpenv.ClearFlags();
	#endif
	FLT fcheck{fj - fk};
	auto actualFlags{FlagsToBits(fpenv.CurrentFlags())};
	u.f = fcheck;
	UINT rcheck{NormalizeNaN(u.ui)};
	UINT check = diff.value.RawBits().ToUInt64();
	MATCH(rcheck, check)
	("%d 0x%jx - 0x%jx", pass, static_cast<std::intmax_t>(rj),
	static_cast<std::intmax_t>(rk));
	MATCH(actualFlags, FlagsToBits(diff.flags))
	("%d 0x%jx - 0x%jx", pass, static_cast<std::intmax_t>(rj),
	static_cast<std::intmax_t>(rk));
	}
	{
	ValueWithRealFlags<REAL> prod{x.Multiply(y, rounding)};
	#ifndef __clang__ // broken and also slow
	fpenv.ClearFlags();
	#endif
	FLT fcheck{fj * fk};
	auto actualFlags{FlagsToBits(fpenv.CurrentFlags())};
	u.f = fcheck;
	UINT rcheck{NormalizeNaN(u.ui)};
	UINT check = prod.value.RawBits().ToUInt64();
	MATCH(rcheck, check)
	("%d 0x%jx * 0x%jx", pass, static_cast<std::intmax_t>(rj),
	static_cast<std::intmax_t>(rk));
	MATCH(actualFlags, FlagsToBits(prod.flags))
	("%d 0x%jx * 0x%jx", pass, static_cast<std::intmax_t>(rj),
	static_cast<std::intmax_t>(rk));
	}
	{
	ValueWithRealFlags<REAL> quot{x.Divide(y, rounding)};
	#ifndef __clang__ // broken and also slow
	fpenv.ClearFlags();
	#endif
	FLT fcheck{fj / fk};
	auto actualFlags{FlagsToBits(fpenv.CurrentFlags())};
	u.f = fcheck;
	UINT rcheck{NormalizeNaN(u.ui)};
	UINT check = quot.value.RawBits().ToUInt64();
	MATCH(rcheck, check)
	("%d 0x%jx / 0x%jx", pass, static_cast<std::intmax_t>(rj),
	static_cast<std::intmax_t>(rk));
	MATCH(actualFlags, FlagsToBits(quot.flags))
	("%d 0x%jx / 0x%jx", pass, static_cast<std::intmax_t>(rj),
	static_cast<std::intmax_t>(rk));
	}
	}
	}
	}

	void roundTest(int rm, Rounding rounding, std::uint32_t opds) {
	basicTests<Real2>(rm, rounding);
	basicTests<Real3>(rm, rounding);
	basicTests<Real4>(rm, rounding);
	basicTests<Real8>(rm, rounding);
	basicTests<Real10>(rm, rounding);
	basicTests<Real16>(rm, rounding);
	ScopedHostFloatingPointEnvironment::SetRounding(rounding);
	subsetTests<std::uint32_t, float, Real4>(rm, rounding, opds);
	subsetTests<std::uint64_t, double, Real8>(rm, rounding, opds);
	}

	int main() {
	dumpTest();
	std::uint32_t opds{512}; // for quick testing by default
	if (const char *p{std::getenv("REAL_TEST_OPERANDS")}) {
	// Use 8192 or 16384 for more exhaustive testing.
	opds = std::atol(p);
	}
	roundTest(0, Rounding{RoundingMode::TiesToEven}, opds);
	roundTest(1, Rounding{RoundingMode::ToZero}, opds);
	roundTest(2, Rounding{RoundingMode::Up}, opds);
	roundTest(3, Rounding{RoundingMode::Down}, opds);
	// TODO: how to test Rounding::TiesAwayFromZero on x86?
	return testing::Complete();
	}