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#include <poincare/print_float.h>
#include <poincare/preferences.h>
#include <poincare/ieee754.h>
extern "C" {
#include <assert.h>
#include <stdlib.h>
#include <string.h>
#include <float.h>
}
#include <cmath>
#include <ion.h>
#include <stdio.h>
namespace Poincare {
void PrintFloat::printBase10IntegerWithDecimalMarker(char * buffer, int bufferLength, Integer i, int decimalMarkerPosition) {
/* The decimal marker position is always preceded by a char, thus, it is never
* in first position. When called by convertFloatToText, the buffer length is
* always > 0 as we asserted a minimal number of available chars. */
assert(bufferLength > 0 && decimalMarkerPosition != 0);
char tempBuffer[PrintFloat::k_maxFloatBufferLength];
int intLength = i.writeTextInBuffer(tempBuffer, PrintFloat::k_maxFloatBufferLength);
int firstDigitChar = tempBuffer[0] == '-' ? 1 : 0;
for (int k = bufferLength-1; k >= firstDigitChar; k--) {
if (k == decimalMarkerPosition) {
buffer[k] = '.';
continue;
}
if (intLength > firstDigitChar) {
buffer[k] = tempBuffer[--intLength];
continue;
}
buffer[k] = '0';
}
if (firstDigitChar == 1) {
buffer[0] = tempBuffer[0];
}
}
template <class T>
int PrintFloat::convertFloatToText(T f, char * buffer, int bufferSize,
int numberOfSignificantDigits, Mode mode) {
assert(numberOfSignificantDigits > 0);
char tempBuffer[PrintFloat::k_maxFloatBufferLength];
int requiredLength = convertFloatToTextPrivate(f, tempBuffer, numberOfSignificantDigits, mode);
/* if the required buffer size overflows the buffer size, we first force the
* display mode to scientific and decrease the number of significant digits to
* fit the buffer size. If the buffer size is still to small, we only write
* the beginning of the float and truncate it (which can result in a non sense
* text) */
if (mode == Mode::Decimal && requiredLength >= bufferSize) {
requiredLength = convertFloatToTextPrivate(f, tempBuffer, numberOfSignificantDigits, Mode::Scientific);
}
if (requiredLength >= bufferSize) {
int adjustedNumberOfSignificantDigits = numberOfSignificantDigits - requiredLength + bufferSize - 1;
adjustedNumberOfSignificantDigits = adjustedNumberOfSignificantDigits < 1 ? 1 : adjustedNumberOfSignificantDigits;
requiredLength = convertFloatToTextPrivate(f, tempBuffer, adjustedNumberOfSignificantDigits, Mode::Scientific);
}
requiredLength = requiredLength < bufferSize ? requiredLength : bufferSize-1;
strlcpy(buffer, tempBuffer, bufferSize);
return requiredLength;
}
template <class T>
int PrintFloat::convertFloatToTextPrivate(T f, char * buffer, int numberOfSignificantDigits, Mode mode) {
assert(numberOfSignificantDigits > 0);
/*if (std::isinf(f)) {
int currentChar = 0;
if (f < 0) {
buffer[currentChar++] = '-';
}
buffer[currentChar++] = 'i';
buffer[currentChar++] = 'n';
buffer[currentChar++] = 'f';
buffer[currentChar] = 0;
return currentChar;
}*/
if (std::isinf(f) || std::isnan(f)) {
int currentChar = 0;
buffer[currentChar++] = 'u';
buffer[currentChar++] = 'n';
buffer[currentChar++] = 'd';
buffer[currentChar++] = 'e';
buffer[currentChar++] = 'f';
buffer[currentChar] = 0;
return currentChar;
}
int exponentInBase10 = IEEE754<T>::exponentBase10(f);
Mode displayMode = mode;
if ((exponentInBase10 >= numberOfSignificantDigits || exponentInBase10 <= -numberOfSignificantDigits) && mode == Mode::Decimal) {
displayMode = Mode::Scientific;
}
// Number of char available for the mantissa
int availableCharsForMantissaWithoutSign = numberOfSignificantDigits + 1;
int availableCharsForMantissaWithSign = f >= 0 ? availableCharsForMantissaWithoutSign : availableCharsForMantissaWithoutSign + 1;
// Compute mantissa
/* The number of digits in an mantissa is capped because the maximal int64_t
* is 2^63 - 1. As our mantissa is an integer built from an int64_t, we assert
* that we stay beyond this threshold during computation. */
assert(availableCharsForMantissaWithoutSign - 1 < std::log10(std::pow(2.0f, 63.0f)));
int numberOfDigitBeforeDecimal = exponentInBase10 >= 0 || displayMode == Mode::Scientific ?
exponentInBase10 + 1 : 1;
T unroundedMantissa = f * std::pow((T)10.0, (T)(availableCharsForMantissaWithoutSign - 1 - numberOfDigitBeforeDecimal));
T mantissa = std::round(unroundedMantissa);
/* if availableCharsForMantissaWithoutSign - 1 - numberOfDigitBeforeDecimal
* is too big (or too small), mantissa is now inf. We handle this case by
* using logarithm function. */
if (std::isnan(mantissa) || std::isinf(mantissa)) {
mantissa = std::round(std::pow(10, std::log10(std::fabs(f))+(T)(availableCharsForMantissaWithoutSign - 1 - numberOfDigitBeforeDecimal)));
mantissa = std::copysign(mantissa, f);
}
/* We update the exponent in base 10 (if 0.99999999 was rounded to 1 for
* instance)
* NB: the following if-condition would rather be:
* "exponentBase10(unroundedMantissa) != exponentBase10(mantissa)",
* however, unroundedMantissa can have a different exponent than expected
* (ex: f = 1E13, unroundedMantissa = 99999999.99 and mantissa = 1000000000) */
if (f != 0 && IEEE754<T>::exponentBase10(mantissa)-exponentInBase10 != availableCharsForMantissaWithoutSign - 1 - numberOfDigitBeforeDecimal) {
exponentInBase10++;
}
// Update the display mode if the exponent changed
if ((exponentInBase10 >= numberOfSignificantDigits || exponentInBase10 <= -numberOfSignificantDigits) && mode == Mode::Decimal) {
displayMode = Mode::Scientific;
}
int decimalMarkerPosition = exponentInBase10 < 0 || displayMode == Mode::Scientific ?
1 : exponentInBase10+1;
decimalMarkerPosition = f < 0 ? decimalMarkerPosition+1 : decimalMarkerPosition;
// Correct the number of digits in mantissa after rounding
int mantissaExponentInBase10 = exponentInBase10 > 0 || displayMode == Mode::Scientific ? availableCharsForMantissaWithoutSign - 1 : availableCharsForMantissaWithoutSign + exponentInBase10;
if (IEEE754<T>::exponentBase10(mantissa) >= mantissaExponentInBase10) {
mantissa = mantissa/10;
}
int numberOfCharExponent = exponentInBase10 != 0 ? std::log10(std::fabs((T)exponentInBase10)) + 1 : 1;
if (exponentInBase10 < 0){
// If the exponent is < 0, we need a additional char for the sign
numberOfCharExponent++;
}
// Supress the 0 on the right side of the mantissa
Integer dividend = Integer((int64_t)std::fabs(mantissa));
Integer quotient = Integer::Division(dividend, Integer(10)).quotient;
Integer digit = Integer::Subtraction(dividend, Integer::Multiplication(quotient, Integer(10)));
int minimumNumberOfCharsInMantissa = 1;
while (digit.isZero() && availableCharsForMantissaWithoutSign > minimumNumberOfCharsInMantissa &&
(availableCharsForMantissaWithoutSign > exponentInBase10+2 || displayMode == Mode::Scientific)) {
mantissa = mantissa/10;
availableCharsForMantissaWithoutSign--;
availableCharsForMantissaWithSign--;
dividend = quotient;
quotient = Integer::Division(dividend, Integer(10)).quotient;
digit = Integer::Subtraction(dividend, Integer::Multiplication(quotient, Integer(10)));
}
// Suppress the decimal marker if no fractional part
if ((displayMode == Mode::Decimal && availableCharsForMantissaWithoutSign == exponentInBase10+2)
|| (displayMode == Mode::Scientific && availableCharsForMantissaWithoutSign == 2)) {
availableCharsForMantissaWithSign--;
}
// Print mantissa
assert(availableCharsForMantissaWithSign < PrintFloat::k_maxFloatBufferLength);
PrintFloat::printBase10IntegerWithDecimalMarker(buffer, availableCharsForMantissaWithSign, Integer((int64_t)mantissa), decimalMarkerPosition);
if (displayMode == Mode::Decimal || exponentInBase10 == 0) {
buffer[availableCharsForMantissaWithSign] = 0;
return availableCharsForMantissaWithSign;
}
// Print exponent
assert(availableCharsForMantissaWithSign < PrintFloat::k_maxFloatBufferLength);
buffer[availableCharsForMantissaWithSign] = Ion::Charset::Exponent;
assert(numberOfCharExponent+availableCharsForMantissaWithSign+1 < PrintFloat::k_maxFloatBufferLength);
PrintFloat::printBase10IntegerWithDecimalMarker(buffer+availableCharsForMantissaWithSign+1, numberOfCharExponent, Integer(exponentInBase10), -1);
buffer[availableCharsForMantissaWithSign+1+numberOfCharExponent] = 0;
return (availableCharsForMantissaWithSign+1+numberOfCharExponent);
}
template int PrintFloat::convertFloatToText<float>(float, char*, int, int, PrintFloat::Mode);
template int PrintFloat::convertFloatToText<double>(double, char*, int, int, PrintFloat::Mode);
}
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