compiler-rt/lib/builtins/fp_lib.h - llvm-project - Git at Google

 //===-- lib/fp_lib.h - Floating-point utilities -------------------*- 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 is a configuration header for soft-float routines in compiler-rt.
 // This file does not provide any part of the compiler-rt interface, but defines
 // many useful constants and utility routines that are used in the
 // implementation of the soft-float routines in compiler-rt.
 //
 // Assumes that float, double and long double correspond to the IEEE-754
 // binary32, binary64 and binary 128 types, respectively, and that integer
 // endianness matches floating point endianness on the target platform.
 //
 //===----------------------------------------------------------------------===//

 #ifndef FP_LIB_HEADER
 #define FP_LIB_HEADER

 #include "int_lib.h"
 #include "int_math.h"
 #include <limits.h>
 #include <stdbool.h>
 #include <stdint.h>

 // x86_64 FreeBSD prior v9.3 define fixed-width types incorrectly in
 // 32-bit mode.
 #if defined(__FreeBSD__) && defined(__i386__)
 #include <sys/param.h>
 #if __FreeBSD_version < 903000 // v9.3
 #define uint64_t unsigned long long
 #define int64_t long long
 #undef UINT64_C
 #define UINT64_C(c) (c##ULL)
 #endif
 #endif

 #if defined SINGLE_PRECISION

 typedef uint16_t half_rep_t;
 typedef uint32_t rep_t;
 typedef uint64_t twice_rep_t;
 typedef int32_t srep_t;
 typedef float fp_t;
 #define HALF_REP_C UINT16_C
 #define REP_C UINT32_C
 #define significandBits 23

 static __inline int rep_clz(rep_t a) { return clzsi(a); }

 // 32x32 --> 64 bit multiply
 static __inline void wideMultiply(rep_t a, rep_t b, rep_t *hi, rep_t *lo) {
   const uint64_t product = (uint64_t)a * b;
   *hi = product >> 32;
   *lo = product;
 }
 COMPILER_RT_ABI fp_t __addsf3(fp_t a, fp_t b);

 #elif defined DOUBLE_PRECISION

 typedef uint32_t half_rep_t;
 typedef uint64_t rep_t;
 typedef int64_t srep_t;
 typedef double fp_t;
 #define HALF_REP_C UINT32_C
 #define REP_C UINT64_C
 #define significandBits 52

 static __inline int rep_clz(rep_t a) {
 #if defined __LP64__
   return __builtin_clzl(a);
 #else
   if (a & REP_C(0xffffffff00000000))
     return clzsi(a >> 32);
   else
     return 32 + clzsi(a & REP_C(0xffffffff));
 #endif
 }

 #define loWord(a) (a & 0xffffffffU)
 #define hiWord(a) (a >> 32)

 // 64x64 -> 128 wide multiply for platforms that don't have such an operation;
 // many 64-bit platforms have this operation, but they tend to have hardware
 // floating-point, so we don't bother with a special case for them here.
 static __inline void wideMultiply(rep_t a, rep_t b, rep_t *hi, rep_t *lo) {
   // Each of the component 32x32 -> 64 products
   const uint64_t plolo = loWord(a) * loWord(b);
   const uint64_t plohi = loWord(a) * hiWord(b);
   const uint64_t philo = hiWord(a) * loWord(b);
   const uint64_t phihi = hiWord(a) * hiWord(b);
   // Sum terms that contribute to lo in a way that allows us to get the carry
   const uint64_t r0 = loWord(plolo);
   const uint64_t r1 = hiWord(plolo) + loWord(plohi) + loWord(philo);
   *lo = r0 + (r1 << 32);
   // Sum terms contributing to hi with the carry from lo
   *hi = hiWord(plohi) + hiWord(philo) + hiWord(r1) + phihi;
 }
 #undef loWord
 #undef hiWord

 COMPILER_RT_ABI fp_t __adddf3(fp_t a, fp_t b);

 #elif defined QUAD_PRECISION
 #if __LDBL_MANT_DIG__ == 113 && defined(__SIZEOF_INT128__)
 #define CRT_LDBL_128BIT
 typedef uint64_t half_rep_t;
 typedef __uint128_t rep_t;
 typedef __int128_t srep_t;
 typedef long double fp_t;
 #define HALF_REP_C UINT64_C
 #define REP_C (__uint128_t)
 // Note: Since there is no explicit way to tell compiler the constant is a
 // 128-bit integer, we let the constant be casted to 128-bit integer
 #define significandBits 112

 static __inline int rep_clz(rep_t a) {
   const union {
     __uint128_t ll;
 #if _YUGA_BIG_ENDIAN
     struct {
       uint64_t high, low;
     } s;
 #else
     struct {
       uint64_t low, high;
     } s;
 #endif
   } uu = {.ll = a};

   uint64_t word;
   uint64_t add;

   if (uu.s.high) {
     word = uu.s.high;
     add = 0;
   } else {
     word = uu.s.low;
     add = 64;
   }
   return __builtin_clzll(word) + add;
 }

 #define Word_LoMask UINT64_C(0x00000000ffffffff)
 #define Word_HiMask UINT64_C(0xffffffff00000000)
 #define Word_FullMask UINT64_C(0xffffffffffffffff)
 #define Word_1(a) (uint64_t)((a >> 96) & Word_LoMask)
 #define Word_2(a) (uint64_t)((a >> 64) & Word_LoMask)
 #define Word_3(a) (uint64_t)((a >> 32) & Word_LoMask)
 #define Word_4(a) (uint64_t)(a & Word_LoMask)

 // 128x128 -> 256 wide multiply for platforms that don't have such an operation;
 // many 64-bit platforms have this operation, but they tend to have hardware
 // floating-point, so we don't bother with a special case for them here.
 static __inline void wideMultiply(rep_t a, rep_t b, rep_t *hi, rep_t *lo) {

   const uint64_t product11 = Word_1(a) * Word_1(b);
   const uint64_t product12 = Word_1(a) * Word_2(b);
   const uint64_t product13 = Word_1(a) * Word_3(b);
   const uint64_t product14 = Word_1(a) * Word_4(b);
   const uint64_t product21 = Word_2(a) * Word_1(b);
   const uint64_t product22 = Word_2(a) * Word_2(b);
   const uint64_t product23 = Word_2(a) * Word_3(b);
   const uint64_t product24 = Word_2(a) * Word_4(b);
   const uint64_t product31 = Word_3(a) * Word_1(b);
   const uint64_t product32 = Word_3(a) * Word_2(b);
   const uint64_t product33 = Word_3(a) * Word_3(b);
   const uint64_t product34 = Word_3(a) * Word_4(b);
   const uint64_t product41 = Word_4(a) * Word_1(b);
   const uint64_t product42 = Word_4(a) * Word_2(b);
   const uint64_t product43 = Word_4(a) * Word_3(b);
   const uint64_t product44 = Word_4(a) * Word_4(b);

   const __uint128_t sum0 = (__uint128_t)product44;
   const __uint128_t sum1 = (__uint128_t)product34 + (__uint128_t)product43;
   const __uint128_t sum2 =
       (__uint128_t)product24 + (__uint128_t)product33 + (__uint128_t)product42;
   const __uint128_t sum3 = (__uint128_t)product14 + (__uint128_t)product23 +
                            (__uint128_t)product32 + (__uint128_t)product41;
   const __uint128_t sum4 =
       (__uint128_t)product13 + (__uint128_t)product22 + (__uint128_t)product31;
   const __uint128_t sum5 = (__uint128_t)product12 + (__uint128_t)product21;
   const __uint128_t sum6 = (__uint128_t)product11;

   const __uint128_t r0 = (sum0 & Word_FullMask) + ((sum1 & Word_LoMask) << 32);
   const __uint128_t r1 = (sum0 >> 64) + ((sum1 >> 32) & Word_FullMask) +
                          (sum2 & Word_FullMask) + ((sum3 << 32) & Word_HiMask);

   *lo = r0 + (r1 << 64);
   *hi = (r1 >> 64) + (sum1 >> 96) + (sum2 >> 64) + (sum3 >> 32) + sum4 +
         (sum5 << 32) + (sum6 << 64);
 }
 #undef Word_1
 #undef Word_2
 #undef Word_3
 #undef Word_4
 #undef Word_HiMask
 #undef Word_LoMask
 #undef Word_FullMask
 #endif // __LDBL_MANT_DIG__ == 113 && __SIZEOF_INT128__
 #else
 #error SINGLE_PRECISION, DOUBLE_PRECISION or QUAD_PRECISION must be defined.
 #endif

 #if defined(SINGLE_PRECISION) || defined(DOUBLE_PRECISION) ||                  \
     defined(CRT_LDBL_128BIT)
 #define typeWidth (sizeof(rep_t) * CHAR_BIT)
 #define exponentBits (typeWidth - significandBits - 1)
 #define maxExponent ((1 << exponentBits) - 1)
 #define exponentBias (maxExponent >> 1)

 #define implicitBit (REP_C(1) << significandBits)
 #define significandMask (implicitBit - 1U)
 #define signBit (REP_C(1) << (significandBits + exponentBits))
 #define absMask (signBit - 1U)
 #define exponentMask (absMask ^ significandMask)
 #define oneRep ((rep_t)exponentBias << significandBits)
 #define infRep exponentMask
 #define quietBit (implicitBit >> 1)
 #define qnanRep (exponentMask | quietBit)

 static __inline rep_t toRep(fp_t x) {
   const union {
     fp_t f;
     rep_t i;
   } rep = {.f = x};
   return rep.i;
 }

 static __inline fp_t fromRep(rep_t x) {
   const union {
     fp_t f;
     rep_t i;
   } rep = {.i = x};
   return rep.f;
 }

 static __inline int normalize(rep_t *significand) {
   const int shift = rep_clz(*significand) - rep_clz(implicitBit);
   *significand <<= shift;
   return 1 - shift;
 }

 static __inline void wideLeftShift(rep_t *hi, rep_t *lo, int count) {
   *hi = *hi << count | *lo >> (typeWidth - count);
   *lo = *lo << count;
 }

 static __inline void wideRightShiftWithSticky(rep_t *hi, rep_t *lo,
                                               unsigned int count) {
   if (count < typeWidth) {
     const bool sticky = (*lo << (typeWidth - count)) != 0;
     *lo = *hi << (typeWidth - count) | *lo >> count | sticky;
     *hi = *hi >> count;
   } else if (count < 2 * typeWidth) {
     const bool sticky = *hi << (2 * typeWidth - count) | *lo;
     *lo = *hi >> (count - typeWidth) | sticky;
     *hi = 0;
   } else {
     const bool sticky = *hi | *lo;
     *lo = sticky;
     *hi = 0;
   }
 }

 // Implements logb methods (logb, logbf, logbl) for IEEE-754. This avoids
 // pulling in a libm dependency from compiler-rt, but is not meant to replace
 // it (i.e. code calling logb() should get the one from libm, not this), hence
 // the __compiler_rt prefix.
 static __inline fp_t __compiler_rt_logbX(fp_t x) {
   rep_t rep = toRep(x);
   int exp = (rep & exponentMask) >> significandBits;

   // Abnormal cases:
   // 1) +/- inf returns +inf; NaN returns NaN
   // 2) 0.0 returns -inf
   if (exp == maxExponent) {
     if (((rep & signBit) == 0) || (x != x)) {
       return x; // NaN or +inf: return x
     } else {
       return -x; // -inf: return -x
     }
   } else if (x == 0.0) {
     // 0.0: return -inf
     return fromRep(infRep | signBit);
   }

   if (exp != 0) {
     // Normal number
     return exp - exponentBias; // Unbias exponent
   } else {
     // Subnormal number; normalize and repeat
     rep &= absMask;
     const int shift = 1 - normalize(&rep);
     exp = (rep & exponentMask) >> significandBits;
     return exp - exponentBias - shift; // Unbias exponent
   }
 }

 // Avoid using scalbn from libm. Unlike libc/libm scalbn, this function never
 // sets errno on underflow/overflow.
 static __inline fp_t __compiler_rt_scalbnX(fp_t x, int y) {
   const rep_t rep = toRep(x);
   int exp = (rep & exponentMask) >> significandBits;

   if (x == 0.0 || exp == maxExponent)
     return x; // +/- 0.0, NaN, or inf: return x

   // Normalize subnormal input.
   rep_t sig = rep & significandMask;
   if (exp == 0) {
     exp += normalize(&sig);
     sig &= ~implicitBit; // clear the implicit bit again
   }

   if (__builtin_sadd_overflow(exp, y, &exp)) {
     // Saturate the exponent, which will guarantee an underflow/overflow below.
     exp = (y >= 0) ? INT_MAX : INT_MIN;
   }

   // Return this value: [+/-] 1.sig * 2 ** (exp - exponentBias).
   const rep_t sign = rep & signBit;
   if (exp >= maxExponent) {
     // Overflow, which could produce infinity or the largest-magnitude value,
     // depending on the rounding mode.
     return fromRep(sign | ((rep_t)(maxExponent - 1) << significandBits)) * 2.0f;
   } else if (exp <= 0) {
     // Subnormal or underflow. Use floating-point multiply to handle truncation
     // correctly.
     fp_t tmp = fromRep(sign | (REP_C(1) << significandBits) | sig);
     exp += exponentBias - 1;
     if (exp < 1)
       exp = 1;
     tmp *= fromRep((rep_t)exp << significandBits);
     return tmp;
   } else
     return fromRep(sign | ((rep_t)exp << significandBits) | sig);
 }

 // Avoid using fmax from libm.
 static __inline fp_t __compiler_rt_fmaxX(fp_t x, fp_t y) {
   // If either argument is NaN, return the other argument. If both are NaN,
   // arbitrarily return the second one. Otherwise, if both arguments are +/-0,
   // arbitrarily return the first one.
   return (crt_isnan(x) || x < y) ? y : x;
 }

 #endif

 #if defined(SINGLE_PRECISION)

 static __inline fp_t __compiler_rt_logbf(fp_t x) {
   return __compiler_rt_logbX(x);
 }
 static __inline fp_t __compiler_rt_scalbnf(fp_t x, int y) {
   return __compiler_rt_scalbnX(x, y);
 }
 static __inline fp_t __compiler_rt_fmaxf(fp_t x, fp_t y) {
 #if defined(__aarch64__)
   // Use __builtin_fmaxf which turns into an fmaxnm instruction on AArch64.
   return __builtin_fmaxf(x, y);
 #else
   // __builtin_fmaxf frequently turns into a libm call, so inline the function.
   return __compiler_rt_fmaxX(x, y);
 #endif
 }

 #elif defined(DOUBLE_PRECISION)

 static __inline fp_t __compiler_rt_logb(fp_t x) {
   return __compiler_rt_logbX(x);
 }
 static __inline fp_t __compiler_rt_scalbn(fp_t x, int y) {
   return __compiler_rt_scalbnX(x, y);
 }
 static __inline fp_t __compiler_rt_fmax(fp_t x, fp_t y) {
 #if defined(__aarch64__)
   // Use __builtin_fmax which turns into an fmaxnm instruction on AArch64.
   return __builtin_fmax(x, y);
 #else
   // __builtin_fmax frequently turns into a libm call, so inline the function.
   return __compiler_rt_fmaxX(x, y);
 #endif
 }

 #elif defined(QUAD_PRECISION)

 #if defined(CRT_LDBL_128BIT)
 static __inline fp_t __compiler_rt_logbl(fp_t x) {
   return __compiler_rt_logbX(x);
 }
 static __inline fp_t __compiler_rt_scalbnl(fp_t x, int y) {
   return __compiler_rt_scalbnX(x, y);
 }
 static __inline fp_t __compiler_rt_fmaxl(fp_t x, fp_t y) {
   return __compiler_rt_fmaxX(x, y);
 }
 #else
 // The generic implementation only works for ieee754 floating point. For other
 // floating point types, continue to rely on the libm implementation for now.
 static __inline long double __compiler_rt_logbl(long double x) {
   return crt_logbl(x);
 }
 static __inline long double __compiler_rt_scalbnl(long double x, int y) {
   return crt_scalbnl(x, y);
 }
 static __inline long double __compiler_rt_fmaxl(long double x, long double y) {
   return crt_fmaxl(x, y);
 }
 #endif // CRT_LDBL_128BIT

 #endif // *_PRECISION

 #endif // FP_LIB_HEADER
	//===-- lib/fp_lib.h - Floating-point utilities -------------------- 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 is a configuration header for soft-float routines in compiler-rt.
	// This file does not provide any part of the compiler-rt interface, but defines
	// many useful constants and utility routines that are used in the
	// implementation of the soft-float routines in compiler-rt.
	//
	// Assumes that float, double and long double correspond to the IEEE-754
	// binary32, binary64 and binary 128 types, respectively, and that integer
	// endianness matches floating point endianness on the target platform.
	//
	//===----------------------------------------------------------------------===//

	#ifndef FP_LIB_HEADER
	#define FP_LIB_HEADER

	#include "int_lib.h"
	#include "int_math.h"
	#include <limits.h>
	#include <stdbool.h>
	#include <stdint.h>

	// x86_64 FreeBSD prior v9.3 define fixed-width types incorrectly in
	// 32-bit mode.
	#if defined(__FreeBSD__) && defined(__i386__)
	#include <sys/param.h>
	#if __FreeBSD_version < 903000 // v9.3
	#define uint64_t unsigned long long
	#define int64_t long long
	#undef UINT64_C
	#define UINT64_C(c) (c##ULL)
	#endif
	#endif

	#if defined SINGLE_PRECISION

	typedef uint16_t half_rep_t;
	typedef uint32_t rep_t;
	typedef uint64_t twice_rep_t;
	typedef int32_t srep_t;
	typedef float fp_t;
	#define HALF_REP_C UINT16_C
	#define REP_C UINT32_C
	#define significandBits 23

	static __inline int rep_clz(rep_t a) { return clzsi(a); }

	// 32x32 --> 64 bit multiply
	static __inline void wideMultiply(rep_t a, rep_t b, rep_t hi, rep_t lo) {
	const uint64_t product = (uint64_t)a * b;
	*hi = product >> 32;
	*lo = product;
	}
	COMPILER_RT_ABI fp_t __addsf3(fp_t a, fp_t b);

	#elif defined DOUBLE_PRECISION

	typedef uint32_t half_rep_t;
	typedef uint64_t rep_t;
	typedef int64_t srep_t;
	typedef double fp_t;
	#define HALF_REP_C UINT32_C
	#define REP_C UINT64_C
	#define significandBits 52

	static __inline int rep_clz(rep_t a) {
	#if defined __LP64__
	return __builtin_clzl(a);
	#else
	if (a & REP_C(0xffffffff00000000))
	return clzsi(a >> 32);
	else
	return 32 + clzsi(a & REP_C(0xffffffff));
	#endif
	}

	#define loWord(a) (a & 0xffffffffU)
	#define hiWord(a) (a >> 32)

	// 64x64 -> 128 wide multiply for platforms that don't have such an operation;
	// many 64-bit platforms have this operation, but they tend to have hardware
	// floating-point, so we don't bother with a special case for them here.
	static __inline void wideMultiply(rep_t a, rep_t b, rep_t hi, rep_t lo) {
	// Each of the component 32x32 -> 64 products
	const uint64_t plolo = loWord(a) * loWord(b);
	const uint64_t plohi = loWord(a) * hiWord(b);
	const uint64_t philo = hiWord(a) * loWord(b);
	const uint64_t phihi = hiWord(a) * hiWord(b);
	// Sum terms that contribute to lo in a way that allows us to get the carry
	const uint64_t r0 = loWord(plolo);
	const uint64_t r1 = hiWord(plolo) + loWord(plohi) + loWord(philo);
	*lo = r0 + (r1 << 32);
	// Sum terms contributing to hi with the carry from lo
	*hi = hiWord(plohi) + hiWord(philo) + hiWord(r1) + phihi;
	}
	#undef loWord
	#undef hiWord

	COMPILER_RT_ABI fp_t __adddf3(fp_t a, fp_t b);

	#elif defined QUAD_PRECISION
	#if __LDBL_MANT_DIG__ == 113 && defined(__SIZEOF_INT128__)
	#define CRT_LDBL_128BIT
	typedef uint64_t half_rep_t;
	typedef __uint128_t rep_t;
	typedef __int128_t srep_t;
	typedef long double fp_t;
	#define HALF_REP_C UINT64_C
	#define REP_C (__uint128_t)
	// Note: Since there is no explicit way to tell compiler the constant is a
	// 128-bit integer, we let the constant be casted to 128-bit integer
	#define significandBits 112

	static __inline int rep_clz(rep_t a) {
	const union {
	__uint128_t ll;
	#if _YUGA_BIG_ENDIAN
	struct {
	uint64_t high, low;
	} s;
	#else
	struct {
	uint64_t low, high;
	} s;
	#endif
	} uu = {.ll = a};

	uint64_t word;
	uint64_t add;

	if (uu.s.high) {
	word = uu.s.high;
	add = 0;
	} else {
	word = uu.s.low;
	add = 64;
	}
	return __builtin_clzll(word) + add;
	}

	#define Word_LoMask UINT64_C(0x00000000ffffffff)
	#define Word_HiMask UINT64_C(0xffffffff00000000)
	#define Word_FullMask UINT64_C(0xffffffffffffffff)
	#define Word_1(a) (uint64_t)((a >> 96) & Word_LoMask)
	#define Word_2(a) (uint64_t)((a >> 64) & Word_LoMask)
	#define Word_3(a) (uint64_t)((a >> 32) & Word_LoMask)
	#define Word_4(a) (uint64_t)(a & Word_LoMask)

	// 128x128 -> 256 wide multiply for platforms that don't have such an operation;
	// many 64-bit platforms have this operation, but they tend to have hardware
	// floating-point, so we don't bother with a special case for them here.
	static __inline void wideMultiply(rep_t a, rep_t b, rep_t hi, rep_t lo) {

	const uint64_t product11 = Word_1(a) * Word_1(b);
	const uint64_t product12 = Word_1(a) * Word_2(b);
	const uint64_t product13 = Word_1(a) * Word_3(b);
	const uint64_t product14 = Word_1(a) * Word_4(b);
	const uint64_t product21 = Word_2(a) * Word_1(b);
	const uint64_t product22 = Word_2(a) * Word_2(b);
	const uint64_t product23 = Word_2(a) * Word_3(b);
	const uint64_t product24 = Word_2(a) * Word_4(b);
	const uint64_t product31 = Word_3(a) * Word_1(b);
	const uint64_t product32 = Word_3(a) * Word_2(b);
	const uint64_t product33 = Word_3(a) * Word_3(b);
	const uint64_t product34 = Word_3(a) * Word_4(b);
	const uint64_t product41 = Word_4(a) * Word_1(b);
	const uint64_t product42 = Word_4(a) * Word_2(b);
	const uint64_t product43 = Word_4(a) * Word_3(b);
	const uint64_t product44 = Word_4(a) * Word_4(b);

	const __uint128_t sum0 = (__uint128_t)product44;
	const __uint128_t sum1 = (__uint128_t)product34 + (__uint128_t)product43;
	const __uint128_t sum2 =
	(__uint128_t)product24 + (__uint128_t)product33 + (__uint128_t)product42;
	const __uint128_t sum3 = (__uint128_t)product14 + (__uint128_t)product23 +
	(__uint128_t)product32 + (__uint128_t)product41;
	const __uint128_t sum4 =
	(__uint128_t)product13 + (__uint128_t)product22 + (__uint128_t)product31;
	const __uint128_t sum5 = (__uint128_t)product12 + (__uint128_t)product21;
	const __uint128_t sum6 = (__uint128_t)product11;

	const __uint128_t r0 = (sum0 & Word_FullMask) + ((sum1 & Word_LoMask) << 32);
	const __uint128_t r1 = (sum0 >> 64) + ((sum1 >> 32) & Word_FullMask) +
	(sum2 & Word_FullMask) + ((sum3 << 32) & Word_HiMask);

	*lo = r0 + (r1 << 64);
	*hi = (r1 >> 64) + (sum1 >> 96) + (sum2 >> 64) + (sum3 >> 32) + sum4 +
	(sum5 << 32) + (sum6 << 64);
	}
	#undef Word_1
	#undef Word_2
	#undef Word_3
	#undef Word_4
	#undef Word_HiMask
	#undef Word_LoMask
	#undef Word_FullMask
	#endif // __LDBL_MANT_DIG__ == 113 && __SIZEOF_INT128__
	#else
	#error SINGLE_PRECISION, DOUBLE_PRECISION or QUAD_PRECISION must be defined.
	#endif

	#if defined(SINGLE_PRECISION) \|\| defined(DOUBLE_PRECISION) \|\| \
	defined(CRT_LDBL_128BIT)
	#define typeWidth (sizeof(rep_t) * CHAR_BIT)
	#define exponentBits (typeWidth - significandBits - 1)
	#define maxExponent ((1 << exponentBits) - 1)
	#define exponentBias (maxExponent >> 1)

	#define implicitBit (REP_C(1) << significandBits)
	#define significandMask (implicitBit - 1U)
	#define signBit (REP_C(1) << (significandBits + exponentBits))
	#define absMask (signBit - 1U)
	#define exponentMask (absMask ^ significandMask)
	#define oneRep ((rep_t)exponentBias << significandBits)
	#define infRep exponentMask
	#define quietBit (implicitBit >> 1)
	#define qnanRep (exponentMask \| quietBit)

	static __inline rep_t toRep(fp_t x) {
	const union {
	fp_t f;
	rep_t i;
	} rep = {.f = x};
	return rep.i;
	}

	static __inline fp_t fromRep(rep_t x) {
	const union {
	fp_t f;
	rep_t i;
	} rep = {.i = x};
	return rep.f;
	}

	static __inline int normalize(rep_t *significand) {
	const int shift = rep_clz(*significand) - rep_clz(implicitBit);
	*significand <<= shift;
	return 1 - shift;
	}

	static __inline void wideLeftShift(rep_t hi, rep_t lo, int count) {
	hi = hi << count \| *lo >> (typeWidth - count);
	lo = lo << count;
	}

	static __inline void wideRightShiftWithSticky(rep_t hi, rep_t lo,
	unsigned int count) {
	if (count < typeWidth) {
	const bool sticky = (*lo << (typeWidth - count)) != 0;
	lo = hi << (typeWidth - count) \| *lo >> count \| sticky;
	hi = hi >> count;
	} else if (count < 2 * typeWidth) {
	const bool sticky = hi << (2 typeWidth - count) \| *lo;
	lo = hi >> (count - typeWidth) \| sticky;
	*hi = 0;
	} else {
	const bool sticky = hi \| lo;
	*lo = sticky;
	*hi = 0;
	}
	}

	// Implements logb methods (logb, logbf, logbl) for IEEE-754. This avoids
	// pulling in a libm dependency from compiler-rt, but is not meant to replace
	// it (i.e. code calling logb() should get the one from libm, not this), hence
	// the __compiler_rt prefix.
	static __inline fp_t __compiler_rt_logbX(fp_t x) {
	rep_t rep = toRep(x);
	int exp = (rep & exponentMask) >> significandBits;

	// Abnormal cases:
	// 1) +/- inf returns +inf; NaN returns NaN
	// 2) 0.0 returns -inf
	if (exp == maxExponent) {
	if (((rep & signBit) == 0) \|\| (x != x)) {
	return x; // NaN or +inf: return x
	} else {
	return -x; // -inf: return -x
	}
	} else if (x == 0.0) {
	// 0.0: return -inf
	return fromRep(infRep \| signBit);
	}

	if (exp != 0) {
	// Normal number
	return exp - exponentBias; // Unbias exponent
	} else {
	// Subnormal number; normalize and repeat
	rep &= absMask;
	const int shift = 1 - normalize(&rep);
	exp = (rep & exponentMask) >> significandBits;
	return exp - exponentBias - shift; // Unbias exponent
	}
	}

	// Avoid using scalbn from libm. Unlike libc/libm scalbn, this function never
	// sets errno on underflow/overflow.
	static __inline fp_t __compiler_rt_scalbnX(fp_t x, int y) {
	const rep_t rep = toRep(x);
	int exp = (rep & exponentMask) >> significandBits;

	if (x == 0.0 \|\| exp == maxExponent)
	return x; // +/- 0.0, NaN, or inf: return x

	// Normalize subnormal input.
	rep_t sig = rep & significandMask;
	if (exp == 0) {
	exp += normalize(&sig);
	sig &= ~implicitBit; // clear the implicit bit again
	}

	if (__builtin_sadd_overflow(exp, y, &exp)) {
	// Saturate the exponent, which will guarantee an underflow/overflow below.
	exp = (y >= 0) ? INT_MAX : INT_MIN;
	}

	// Return this value: [+/-] 1.sig * 2 ** (exp - exponentBias).
	const rep_t sign = rep & signBit;
	if (exp >= maxExponent) {
	// Overflow, which could produce infinity or the largest-magnitude value,
	// depending on the rounding mode.
	return fromRep(sign \| ((rep_t)(maxExponent - 1) << significandBits)) * 2.0f;
	} else if (exp <= 0) {
	// Subnormal or underflow. Use floating-point multiply to handle truncation
	// correctly.
	fp_t tmp = fromRep(sign \| (REP_C(1) << significandBits) \| sig);
	exp += exponentBias - 1;
	if (exp < 1)
	exp = 1;
	tmp *= fromRep((rep_t)exp << significandBits);
	return tmp;
	} else
	return fromRep(sign \| ((rep_t)exp << significandBits) \| sig);
	}

	// Avoid using fmax from libm.
	static __inline fp_t __compiler_rt_fmaxX(fp_t x, fp_t y) {
	// If either argument is NaN, return the other argument. If both are NaN,
	// arbitrarily return the second one. Otherwise, if both arguments are +/-0,
	// arbitrarily return the first one.
	return (crt_isnan(x) \|\| x < y) ? y : x;
	}

	#endif

	#if defined(SINGLE_PRECISION)

	static __inline fp_t __compiler_rt_logbf(fp_t x) {
	return __compiler_rt_logbX(x);
	}
	static __inline fp_t __compiler_rt_scalbnf(fp_t x, int y) {
	return __compiler_rt_scalbnX(x, y);
	}
	static __inline fp_t __compiler_rt_fmaxf(fp_t x, fp_t y) {
	#if defined(__aarch64__)
	// Use __builtin_fmaxf which turns into an fmaxnm instruction on AArch64.
	return __builtin_fmaxf(x, y);
	#else
	// __builtin_fmaxf frequently turns into a libm call, so inline the function.
	return __compiler_rt_fmaxX(x, y);
	#endif
	}

	#elif defined(DOUBLE_PRECISION)

	static __inline fp_t __compiler_rt_logb(fp_t x) {
	return __compiler_rt_logbX(x);
	}
	static __inline fp_t __compiler_rt_scalbn(fp_t x, int y) {
	return __compiler_rt_scalbnX(x, y);
	}
	static __inline fp_t __compiler_rt_fmax(fp_t x, fp_t y) {
	#if defined(__aarch64__)
	// Use __builtin_fmax which turns into an fmaxnm instruction on AArch64.
	return __builtin_fmax(x, y);
	#else
	// __builtin_fmax frequently turns into a libm call, so inline the function.
	return __compiler_rt_fmaxX(x, y);
	#endif
	}

	#elif defined(QUAD_PRECISION)

	#if defined(CRT_LDBL_128BIT)
	static __inline fp_t __compiler_rt_logbl(fp_t x) {
	return __compiler_rt_logbX(x);
	}
	static __inline fp_t __compiler_rt_scalbnl(fp_t x, int y) {
	return __compiler_rt_scalbnX(x, y);
	}
	static __inline fp_t __compiler_rt_fmaxl(fp_t x, fp_t y) {
	return __compiler_rt_fmaxX(x, y);
	}
	#else
	// The generic implementation only works for ieee754 floating point. For other
	// floating point types, continue to rely on the libm implementation for now.
	static __inline long double __compiler_rt_logbl(long double x) {
	return crt_logbl(x);
	}
	static __inline long double __compiler_rt_scalbnl(long double x, int y) {
	return crt_scalbnl(x, y);
	}
	static __inline long double __compiler_rt_fmaxl(long double x, long double y) {
	return crt_fmaxl(x, y);
	}
	#endif // CRT_LDBL_128BIT

	#endif // *_PRECISION

	#endif // FP_LIB_HEADER