src/base/SkFloatingPoint.cpp - skia - Git at Google

 /*
  * Copyright 2023 Google LLC
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "include/private/base/SkFloatingPoint.h"

 #include "include/private/base/SkAssert.h"

 #include <cmath>

 static inline int64_t double_to_twos_complement_bits(double x) {
     // Convert a double to its bit pattern
     int64_t bits = 0;
     static_assert(sizeof(x) == sizeof(bits));
     std::memcpy(&bits, &x, sizeof(bits));
     // Convert a sign-bit int (i.e. double interpreted as int) into a 2s complement
     // int. This also converts -0 (0x8000000000000000) to 0. Doing this to a double allows
     // it to be compared using normal C operators (<, <=, etc.)
     if (bits < 0) {
         bits &= 0x7FFFFFFFFFFFFFFF;
         bits = -bits;
     }
     return bits;
 }

 // Arbitrarily chosen.
 constexpr static double sk_double_epsilon = 0.0000000001;

 bool sk_doubles_nearly_equal_ulps(double a, double b, uint8_t max_ulps_diff) {
     // If both of these are zero (or very close), then using Units of Least Precision
     // will not be accurate and we should use sk_double_nearly_zero instead.
     SkASSERT(!(fabs(a) < sk_double_epsilon && fabs(b) < sk_double_epsilon));
     // This algorithm does not work if both inputs are NaN.
     SkASSERT(!(std::isnan(a) && std::isnan(b)));
     // If both inputs are infinity (or actually equal), this catches it.
     if (a == b) {
         return true;
     }
     int64_t aBits = double_to_twos_complement_bits(a);
     int64_t bBits = double_to_twos_complement_bits(b);

     // Find the difference in Units of Least Precision (ULPs).
     return aBits < bBits + max_ulps_diff && bBits < aBits + max_ulps_diff;
 }

 bool sk_double_nearly_zero(double a) {
     return a == 0 || fabs(a) < sk_double_epsilon;
 }
	/*
	* Copyright 2023 Google LLC
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "include/private/base/SkFloatingPoint.h"

	#include "include/private/base/SkAssert.h"

	#include <cmath>

	static inline int64_t double_to_twos_complement_bits(double x) {
	// Convert a double to its bit pattern
	int64_t bits = 0;
	static_assert(sizeof(x) == sizeof(bits));
	std::memcpy(&bits, &x, sizeof(bits));
	// Convert a sign-bit int (i.e. double interpreted as int) into a 2s complement
	// int. This also converts -0 (0x8000000000000000) to 0. Doing this to a double allows
	// it to be compared using normal C operators (<, <=, etc.)
	if (bits < 0) {
	bits &= 0x7FFFFFFFFFFFFFFF;
	bits = -bits;
	}
	return bits;
	}

	// Arbitrarily chosen.
	constexpr static double sk_double_epsilon = 0.0000000001;

	bool sk_doubles_nearly_equal_ulps(double a, double b, uint8_t max_ulps_diff) {
	// If both of these are zero (or very close), then using Units of Least Precision
	// will not be accurate and we should use sk_double_nearly_zero instead.
	SkASSERT(!(fabs(a) < sk_double_epsilon && fabs(b) < sk_double_epsilon));
	// This algorithm does not work if both inputs are NaN.
	SkASSERT(!(std::isnan(a) && std::isnan(b)));
	// If both inputs are infinity (or actually equal), this catches it.
	if (a == b) {
	return true;
	}
	int64_t aBits = double_to_twos_complement_bits(a);
	int64_t bBits = double_to_twos_complement_bits(b);

	// Find the difference in Units of Least Precision (ULPs).
	return aBits < bBits + max_ulps_diff && bBits < aBits + max_ulps_diff;
	}

	bool sk_double_nearly_zero(double a) {
	return a == 0 \|\| fabs(a) < sk_double_epsilon;
	}