src/utils/SkFloatToDecimal.cpp - platform/external/skia - Gitiles

 /*
  * Copyright 2017 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "src/utils/SkFloatToDecimal.h"

 #include <cfloat>
 #include <climits>
 #include <cmath>

 #include "include/core/SkTypes.h"

 // returns `value * pow(base, e)`, assuming `e` is positive.
 static double pow_by_squaring(double value, double base, int e) {
     // https://en.wikipedia.org/wiki/Exponentiation_by_squaring
     SkASSERT(e > 0);
     while (true) {
         if (e & 1) {
             value *= base;
         }
         e >>= 1;
         if (0 == e) {
             return value;
         }
         base *= base;
     }
 }

 // Return pow(10.0, e), optimized for common cases.
 static double pow10(int e) {
     switch (e) {
         case 0:  return 1.0;  // common cases
         case 1:  return 10.0;
         case 2:  return 100.0;
         case 3:  return 1e+03;
         case 4:  return 1e+04;
         case 5:  return 1e+05;
         case 6:  return 1e+06;
         case 7:  return 1e+07;
         case 8:  return 1e+08;
         case 9:  return 1e+09;
         case 10: return 1e+10;
         case 11: return 1e+11;
         case 12: return 1e+12;
         case 13: return 1e+13;
         case 14: return 1e+14;
         case 15: return 1e+15;
         default:
             if (e > 15) {
                 return pow_by_squaring(1e+15, 10.0, e - 15);
             } else {
                 SkASSERT(e < 0);
                 return pow_by_squaring(1.0, 0.1, -e);
             }
     }
 }

 /** Write a string into output, including a terminating '\0' (for
     unit testing).  Return strlen(output) (for SkWStream::write) The
     resulting string will be in the form /[-]?([0-9]*.)?[0-9]+/ and
     sscanf(output, "%f", &x) will return the original value iff the
     value is finite. This function accepts all possible input values.

     Motivation: "PDF does not support [numbers] in exponential format
     (such as 6.02e23)."  Otherwise, this function would rely on a
     sprintf-type function from the standard library. */
 unsigned SkFloatToDecimal(float value, char output[kMaximumSkFloatToDecimalLength]) {
     /* The longest result is -FLT_MIN.
        We serialize it as "-.0000000000000000000000000000000000000117549435"
        which has 48 characters plus a terminating '\0'. */

     static_assert(kMaximumSkFloatToDecimalLength == 49, "");
     // 3 = '-', '.', and '\0' characters.
     // 9 = number of significant digits
     // abs(FLT_MIN_10_EXP) = number of zeros in FLT_MIN
     static_assert(kMaximumSkFloatToDecimalLength == 3 + 9 - FLT_MIN_10_EXP, "");

     /* section C.1 of the PDF1.4 spec (http://goo.gl/0SCswJ) says that
        most PDF rasterizers will use fixed-point scalars that lack the
        dynamic range of floats.  Even if this is the case, I want to
        serialize these (uncommon) very small and very large scalar
        values with enough precision to allow a floating-point
        rasterizer to read them in with perfect accuracy.
        Experimentally, rasterizers such as pdfium do seem to benefit
        from this.  Rasterizers that rely on fixed-point scalars should
        gracefully ignore these values that they can not parse. */
     char* output_ptr = &output[0];
     const char* const end = &output[kMaximumSkFloatToDecimalLength - 1];
     // subtract one to leave space for '\0'.

     /* This function is written to accept any possible input value,
        including non-finite values such as INF and NAN.  In that case,
        we ignore value-correctness and output a syntacticly-valid
        number. */
     if (value == INFINITY) {
         value = FLT_MAX;  // nearest finite float.
     }
     if (value == -INFINITY) {
         value = -FLT_MAX;  // nearest finite float.
     }
     if (!std::isfinite(value) || value == 0.0f) {
         // NAN is unsupported in PDF.  Always output a valid number.
         // Also catch zero here, as a special case.
         *output_ptr++ = '0';
         *output_ptr = '\0';
         return static_cast<unsigned>(output_ptr - output);
     }
     if (value < 0.0) {
         *output_ptr++ = '-';
         value = -value;
     }
     SkASSERT(value >= 0.0f);

     int binaryExponent;
     (void)std::frexp(value, &binaryExponent);
     static const double kLog2 = 0.3010299956639812;  // log10(2.0);
     int decimalExponent = static_cast<int>(std::floor(kLog2 * binaryExponent));
     int decimalShift = decimalExponent - 8;
     double power = pow10(-decimalShift);
     SkASSERT(value * power <= (double)INT_MAX);
     int d = static_cast<int>(value * power + 0.5);
     // SkASSERT(value == (float)(d * pow(10.0, decimalShift)));
     SkASSERT(d <= 999999999);
     if (d > 167772159) {  // floor(pow(10,1+log10(1<<24)))
        // need one fewer decimal digits for 24-bit precision.
        decimalShift = decimalExponent - 7;
        // SkASSERT(power * 0.1 = pow10(-decimalShift));
        // recalculate to get rounding right.
        d = static_cast<int>(value * (power * 0.1) + 0.5);
        SkASSERT(d <= 99999999);
     }
     while (d % 10 == 0) {
         d /= 10;
         ++decimalShift;
     }
     SkASSERT(d > 0);
     // SkASSERT(value == (float)(d * pow(10.0, decimalShift)));
     unsigned char buffer[9]; // decimal value buffer.
     int bufferIndex = 0;
     do {
         buffer[bufferIndex++] = d % 10;
         d /= 10;
     } while (d != 0);
     SkASSERT(bufferIndex <= (int)sizeof(buffer) && bufferIndex > 0);
     if (decimalShift >= 0) {
         do {
             --bufferIndex;
             *output_ptr++ = '0' + buffer[bufferIndex];
         } while (bufferIndex);
         for (int i = 0; i < decimalShift; ++i) {
             *output_ptr++ = '0';
         }
     } else {
         int placesBeforeDecimal = bufferIndex + decimalShift;
         if (placesBeforeDecimal > 0) {
             while (placesBeforeDecimal-- > 0) {
                 --bufferIndex;
                 *output_ptr++ = '0' + buffer[bufferIndex];
             }
             *output_ptr++ = '.';
         } else {
             *output_ptr++ = '.';
             int placesAfterDecimal = -placesBeforeDecimal;
             while (placesAfterDecimal-- > 0) {
                 *output_ptr++ = '0';
             }
         }
         while (bufferIndex > 0) {
             --bufferIndex;
             *output_ptr++ = '0' + buffer[bufferIndex];
             if (output_ptr == end) {
                 break;  // denormalized: don't need extra precision.
                 // Note: denormalized numbers will not have the same number of
                 // significantDigits, but do not need them to round-trip.
             }
         }
     }
     SkASSERT(output_ptr <= end);
     *output_ptr = '\0';
     return static_cast<unsigned>(output_ptr - output);
 }
	/*
	* Copyright 2017 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "src/utils/SkFloatToDecimal.h"

	#include <cfloat>
	#include <climits>
	#include <cmath>

	#include "include/core/SkTypes.h"

	// returns `value * pow(base, e)`, assuming `e` is positive.
	static double pow_by_squaring(double value, double base, int e) {
	// https://en.wikipedia.org/wiki/Exponentiation_by_squaring
	SkASSERT(e > 0);
	while (true) {
	if (e & 1) {
	value *= base;
	}
	e >>= 1;
	if (0 == e) {
	return value;
	}
	base *= base;
	}
	}

	// Return pow(10.0, e), optimized for common cases.
	static double pow10(int e) {
	switch (e) {
	case 0: return 1.0; // common cases
	case 1: return 10.0;
	case 2: return 100.0;
	case 3: return 1e+03;
	case 4: return 1e+04;
	case 5: return 1e+05;
	case 6: return 1e+06;
	case 7: return 1e+07;
	case 8: return 1e+08;
	case 9: return 1e+09;
	case 10: return 1e+10;
	case 11: return 1e+11;
	case 12: return 1e+12;
	case 13: return 1e+13;
	case 14: return 1e+14;
	case 15: return 1e+15;
	default:
	if (e > 15) {
	return pow_by_squaring(1e+15, 10.0, e - 15);
	} else {
	SkASSERT(e < 0);
	return pow_by_squaring(1.0, 0.1, -e);
	}
	}
	}

	/** Write a string into output, including a terminating '\0' (for
	unit testing). Return strlen(output) (for SkWStream::write) The
	resulting string will be in the form /[-]?([0-9]*.)?[0-9]+/ and
	sscanf(output, "%f", &x) will return the original value iff the
	value is finite. This function accepts all possible input values.

	Motivation: "PDF does not support [numbers] in exponential format
	(such as 6.02e23)." Otherwise, this function would rely on a
	sprintf-type function from the standard library. */
	unsigned SkFloatToDecimal(float value, char output[kMaximumSkFloatToDecimalLength]) {
	/* The longest result is -FLT_MIN.
	We serialize it as "-.0000000000000000000000000000000000000117549435"
	which has 48 characters plus a terminating '\0'. */

	static_assert(kMaximumSkFloatToDecimalLength == 49, "");
	// 3 = '-', '.', and '\0' characters.
	// 9 = number of significant digits
	// abs(FLT_MIN_10_EXP) = number of zeros in FLT_MIN
	static_assert(kMaximumSkFloatToDecimalLength == 3 + 9 - FLT_MIN_10_EXP, "");

	/* section C.1 of the PDF1.4 spec (http://goo.gl/0SCswJ) says that
	most PDF rasterizers will use fixed-point scalars that lack the
	dynamic range of floats. Even if this is the case, I want to
	serialize these (uncommon) very small and very large scalar
	values with enough precision to allow a floating-point
	rasterizer to read them in with perfect accuracy.
	Experimentally, rasterizers such as pdfium do seem to benefit
	from this. Rasterizers that rely on fixed-point scalars should
	gracefully ignore these values that they can not parse. */
	char* output_ptr = &output[0];
	const char* const end = &output[kMaximumSkFloatToDecimalLength - 1];
	// subtract one to leave space for '\0'.

	/* This function is written to accept any possible input value,
	including non-finite values such as INF and NAN. In that case,
	we ignore value-correctness and output a syntacticly-valid
	number. */
	if (value == INFINITY) {
	value = FLT_MAX; // nearest finite float.
	}
	if (value == -INFINITY) {
	value = -FLT_MAX; // nearest finite float.
	}
	if (!std::isfinite(value) \|\| value == 0.0f) {
	// NAN is unsupported in PDF. Always output a valid number.
	// Also catch zero here, as a special case.
	*output_ptr++ = '0';
	*output_ptr = '\0';
	return static_cast<unsigned>(output_ptr - output);
	}
	if (value < 0.0) {
	*output_ptr++ = '-';
	value = -value;
	}
	SkASSERT(value >= 0.0f);

	int binaryExponent;
	(void)std::frexp(value, &binaryExponent);
	static const double kLog2 = 0.3010299956639812; // log10(2.0);
	int decimalExponent = static_cast<int>(std::floor(kLog2 * binaryExponent));
	int decimalShift = decimalExponent - 8;
	double power = pow10(-decimalShift);
	SkASSERT(value * power <= (double)INT_MAX);
	int d = static_cast<int>(value * power + 0.5);
	// SkASSERT(value == (float)(d * pow(10.0, decimalShift)));
	SkASSERT(d <= 999999999);
	if (d > 167772159) { // floor(pow(10,1+log10(1<<24)))
	// need one fewer decimal digits for 24-bit precision.
	decimalShift = decimalExponent - 7;
	// SkASSERT(power * 0.1 = pow10(-decimalShift));
	// recalculate to get rounding right.
	d = static_cast<int>(value * (power * 0.1) + 0.5);
	SkASSERT(d <= 99999999);
	}
	while (d % 10 == 0) {
	d /= 10;
	++decimalShift;
	}
	SkASSERT(d > 0);
	// SkASSERT(value == (float)(d * pow(10.0, decimalShift)));
	unsigned char buffer[9]; // decimal value buffer.
	int bufferIndex = 0;
	do {
	buffer[bufferIndex++] = d % 10;
	d /= 10;
	} while (d != 0);
	SkASSERT(bufferIndex <= (int)sizeof(buffer) && bufferIndex > 0);
	if (decimalShift >= 0) {
	do {
	--bufferIndex;
	*output_ptr++ = '0' + buffer[bufferIndex];
	} while (bufferIndex);
	for (int i = 0; i < decimalShift; ++i) {
	*output_ptr++ = '0';
	}
	} else {
	int placesBeforeDecimal = bufferIndex + decimalShift;
	if (placesBeforeDecimal > 0) {
	while (placesBeforeDecimal-- > 0) {
	--bufferIndex;
	*output_ptr++ = '0' + buffer[bufferIndex];
	}
	*output_ptr++ = '.';
	} else {
	*output_ptr++ = '.';
	int placesAfterDecimal = -placesBeforeDecimal;
	while (placesAfterDecimal-- > 0) {
	*output_ptr++ = '0';
	}
	}
	while (bufferIndex > 0) {
	--bufferIndex;
	*output_ptr++ = '0' + buffer[bufferIndex];
	if (output_ptr == end) {
	break; // denormalized: don't need extra precision.
	// Note: denormalized numbers will not have the same number of
	// significantDigits, but do not need them to round-trip.
	}
	}
	}
	SkASSERT(output_ptr <= end);
	*output_ptr = '\0';
	return static_cast<unsigned>(output_ptr - output);
	}