libc/utils/FPUtil/NearestIntegerOperations.h - llvm-project - Git at Google

 //===-- Nearest integer floating-point operations ---------------*- 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
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_LIBC_UTILS_FPUTIL_NEAREST_INTEGER_OPERATIONS_H
 #define LLVM_LIBC_UTILS_FPUTIL_NEAREST_INTEGER_OPERATIONS_H

 #include "FPBits.h"

 #include "utils/CPP/TypeTraits.h"

 namespace __llvm_libc {
 namespace fputil {

 template <typename T,
           cpp::EnableIfType<cpp::IsFloatingPointType<T>::Value, int> = 0>
 static inline T trunc(T x) {
   FPBits<T> bits(x);

   // If x is infinity or NaN, return it.
   // If it is zero also we should return it as is, but the logic
   // later in this function takes care of it. But not doing a zero
   // check, we improve the run time of non-zero values.
   if (bits.isInfOrNaN())
     return x;

   int exponent = bits.getExponent();

   // If the exponent is greater than the most negative mantissa
   // exponent, then x is already an integer.
   if (exponent >= static_cast<int>(MantissaWidth<T>::value))
     return x;

   // If the exponent is such that abs(x) is less than 1, then return 0.
   if (exponent <= -1) {
     if (bits.sign)
       return T(-0.0);
     else
       return T(0.0);
   }

   int trimSize = MantissaWidth<T>::value - exponent;
   bits.mantissa = (bits.mantissa >> trimSize) << trimSize;
   return bits;
 }

 template <typename T,
           cpp::EnableIfType<cpp::IsFloatingPointType<T>::Value, int> = 0>
 static inline T ceil(T x) {
   FPBits<T> bits(x);

   // If x is infinity NaN or zero, return it.
   if (bits.isInfOrNaN() || bits.isZero())
     return x;

   bool isNeg = bits.sign;
   int exponent = bits.getExponent();

   // If the exponent is greater than the most negative mantissa
   // exponent, then x is already an integer.
   if (exponent >= static_cast<int>(MantissaWidth<T>::value))
     return x;

   if (exponent <= -1) {
     if (isNeg)
       return T(-0.0);
     else
       return T(1.0);
   }

   uint32_t trimSize = MantissaWidth<T>::value - exponent;
   bits.mantissa = (bits.mantissa >> trimSize) << trimSize;
   T truncValue = T(bits);

   // If x is already an integer, return it.
   if (truncValue == x)
     return x;

   // If x is negative, the ceil operation is equivalent to the trunc operation.
   if (isNeg)
     return truncValue;

   return truncValue + T(1.0);
 }

 template <typename T,
           cpp::EnableIfType<cpp::IsFloatingPointType<T>::Value, int> = 0>
 static inline T floor(T x) {
   FPBits<T> bits(x);
   if (bits.sign) {
     return -ceil(-x);
   } else {
     return trunc(x);
   }
 }

 template <typename T,
           cpp::EnableIfType<cpp::IsFloatingPointType<T>::Value, int> = 0>
 static inline T round(T x) {
   using UIntType = typename FPBits<T>::UIntType;
   FPBits<T> bits(x);

   // If x is infinity NaN or zero, return it.
   if (bits.isInfOrNaN() || bits.isZero())
     return x;

   bool isNeg = bits.sign;
   int exponent = bits.getExponent();

   // If the exponent is greater than the most negative mantissa
   // exponent, then x is already an integer.
   if (exponent >= static_cast<int>(MantissaWidth<T>::value))
     return x;

   if (exponent == -1) {
     // Absolute value of x is greater than equal to 0.5 but less than 1.
     if (isNeg)
       return T(-1.0);
     else
       return T(1.0);
   }

   if (exponent <= -2) {
     // Absolute value of x is less than 0.5.
     if (isNeg)
       return T(-0.0);
     else
       return T(0.0);
   }

   uint32_t trimSize = MantissaWidth<T>::value - exponent;
   bool halfBitSet = bits.mantissa & (UIntType(1) << (trimSize - 1));
   bits.mantissa = (bits.mantissa >> trimSize) << trimSize;
   T truncValue = T(bits);

   // If x is already an integer, return it.
   if (truncValue == x)
     return x;

   if (!halfBitSet) {
     // Franctional part is less than 0.5 so round value is the
     // same as the trunc value.
     return truncValue;
   } else {
     return isNeg ? truncValue - T(1.0) : truncValue + T(1.0);
   }
 }

 } // namespace fputil
 } // namespace __llvm_libc

 #endif // LLVM_LIBC_UTILS_FPUTIL_NEAREST_INTEGER_OPERATIONS_H
	//===-- Nearest integer floating-point operations ---------------- 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
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_LIBC_UTILS_FPUTIL_NEAREST_INTEGER_OPERATIONS_H
	#define LLVM_LIBC_UTILS_FPUTIL_NEAREST_INTEGER_OPERATIONS_H

	#include "FPBits.h"

	#include "utils/CPP/TypeTraits.h"

	namespace __llvm_libc {
	namespace fputil {

	template <typename T,
	cpp::EnableIfType<cpp::IsFloatingPointType<T>::Value, int> = 0>
	static inline T trunc(T x) {
	FPBits<T> bits(x);

	// If x is infinity or NaN, return it.
	// If it is zero also we should return it as is, but the logic
	// later in this function takes care of it. But not doing a zero
	// check, we improve the run time of non-zero values.
	if (bits.isInfOrNaN())
	return x;

	int exponent = bits.getExponent();

	// If the exponent is greater than the most negative mantissa
	// exponent, then x is already an integer.
	if (exponent >= static_cast<int>(MantissaWidth<T>::value))
	return x;

	// If the exponent is such that abs(x) is less than 1, then return 0.
	if (exponent <= -1) {
	if (bits.sign)
	return T(-0.0);
	else
	return T(0.0);
	}

	int trimSize = MantissaWidth<T>::value - exponent;
	bits.mantissa = (bits.mantissa >> trimSize) << trimSize;
	return bits;
	}

	template <typename T,
	cpp::EnableIfType<cpp::IsFloatingPointType<T>::Value, int> = 0>
	static inline T ceil(T x) {
	FPBits<T> bits(x);

	// If x is infinity NaN or zero, return it.
	if (bits.isInfOrNaN() \|\| bits.isZero())
	return x;

	bool isNeg = bits.sign;
	int exponent = bits.getExponent();

	// If the exponent is greater than the most negative mantissa
	// exponent, then x is already an integer.
	if (exponent >= static_cast<int>(MantissaWidth<T>::value))
	return x;

	if (exponent <= -1) {
	if (isNeg)
	return T(-0.0);
	else
	return T(1.0);
	}

	uint32_t trimSize = MantissaWidth<T>::value - exponent;
	bits.mantissa = (bits.mantissa >> trimSize) << trimSize;
	T truncValue = T(bits);

	// If x is already an integer, return it.
	if (truncValue == x)
	return x;

	// If x is negative, the ceil operation is equivalent to the trunc operation.
	if (isNeg)
	return truncValue;

	return truncValue + T(1.0);
	}

	template <typename T,
	cpp::EnableIfType<cpp::IsFloatingPointType<T>::Value, int> = 0>
	static inline T floor(T x) {
	FPBits<T> bits(x);
	if (bits.sign) {
	return -ceil(-x);
	} else {
	return trunc(x);
	}
	}

	template <typename T,
	cpp::EnableIfType<cpp::IsFloatingPointType<T>::Value, int> = 0>
	static inline T round(T x) {
	using UIntType = typename FPBits<T>::UIntType;
	FPBits<T> bits(x);

	// If x is infinity NaN or zero, return it.
	if (bits.isInfOrNaN() \|\| bits.isZero())
	return x;

	bool isNeg = bits.sign;
	int exponent = bits.getExponent();

	// If the exponent is greater than the most negative mantissa
	// exponent, then x is already an integer.
	if (exponent >= static_cast<int>(MantissaWidth<T>::value))
	return x;

	if (exponent == -1) {
	// Absolute value of x is greater than equal to 0.5 but less than 1.
	if (isNeg)
	return T(-1.0);
	else
	return T(1.0);
	}

	if (exponent <= -2) {
	// Absolute value of x is less than 0.5.
	if (isNeg)
	return T(-0.0);
	else
	return T(0.0);
	}

	uint32_t trimSize = MantissaWidth<T>::value - exponent;
	bool halfBitSet = bits.mantissa & (UIntType(1) << (trimSize - 1));
	bits.mantissa = (bits.mantissa >> trimSize) << trimSize;
	T truncValue = T(bits);

	// If x is already an integer, return it.
	if (truncValue == x)
	return x;

	if (!halfBitSet) {
	// Franctional part is less than 0.5 so round value is the
	// same as the trunc value.
	return truncValue;
	} else {
	return isNeg ? truncValue - T(1.0) : truncValue + T(1.0);
	}
	}

	} // namespace fputil
	} // namespace __llvm_libc

	#endif // LLVM_LIBC_UTILS_FPUTIL_NEAREST_INTEGER_OPERATIONS_H