How to implement “ char * ftoa(float num) ” without sprintf() library function in C, C++ and JAVA?

Today I appeared for an interview, and the question was writing my own "char * ftoa(float num) " in C, C++ and Java.

Yes, I know float numbers follow IEEE standard while allocating their memory, but I don't know float to char conversion by using Mantissa and Exponent in C.

I don't have any idea to solve the above problem in C++ and JAVA.

I/P to the ftoa(): 1.23

O/P from the ftoa(): 1.23 (char format).

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C has float to char conversion like `sprintf(a, "%d", f)` –  Hans W Feb 20 '10 at 17:23
@Hans: You mean `%f`, right? –  GManNickG Feb 20 '10 at 17:32
One solution: edaboard.com/ftopic41714.html#160029 –  tur1ng Feb 20 '10 at 17:51
GMan: Yes, of course. –  Hans W Feb 20 '10 at 19:53

When you're dealing with fp numbers, it can get very compex but the algorithm is simplistic and similar to edgar holleis's answer; kudos! Its complex because when you're dealing with floating point numbers, the calculations will be a little off depending on the precision you've chosen. That's why its not good programming practice to compare a float to a zero.

But there is an answer and this is my attempt at implementing it. Here I've used a tolerance value so you don't end up calculating too many decimal places resulting in an infinite loop. I'm sure there might be better solutions out there but this should help give you a good understanding of how to do it.

``````char fstr[80];
float num = 2.55f;
int m = log10(num);
int digit;
float tolerance = .0001f;

while (num > 0 + precision)
{
float weight = pow(10.0f, m);
digit = floor(num / weight);
num -= (digit*weight);
*(fstr++)= '0' + digit;
if (m == 0)
*(fstr++) = '.';
m--;
}
*(fstr) = '\0';
``````
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@Pal, Good answer. thanks –  SIVA Feb 21 '10 at 16:38
"tolerance" is unused. –  Janus Troelsen Nov 10 '11 at 14:58
There's a problem with this. If num is smaller than 1 you will calculate the string wrong. You need to change the 3rd line to be floor(log10(num)) –  Andi Jay Jul 3 '12 at 21:17
Another issue is if you try to convert a number that has a 0 in the ones place. For example 230.0. You will only get 23 in this case the way it is written now. You have to change the condition in the while loop to ((num > 0 + precision)||(m >= 0)) –  Andi Jay Jul 5 '12 at 21:18
Just to note that this implementation, and androider's improvement, is good. Hpwever, with a high precision (eg: 9 dp) the repeated pow() can make this rather slow. Not great if this is part of other actions providing user feedback I've found. –  Toby Jul 23 at 9:14

Based on Sophy Pal's answer, this is a slightly more complete solution that takes into account the number zero, NaN, infinite, negative numbers, and scientific notation. Albeit sprintf still provides a more accurate string representation.

``````/*
Double to ASCII Conversion without sprintf.
Roughly equivalent to: sprintf(s, "%.14g", n);
*/

#include <math.h>
#include <string.h>
// For printf
#include <stdio.h>

static double PRECISION = 0.00000000000001;
static int MAX_NUMBER_STRING_SIZE = 32;

/**
* Double to ASCII
*/
char * dtoa(char *s, double n) {
// handle special cases
if (isnan(n)) {
strcpy(s, "nan");
} else if (isinf(n)) {
strcpy(s, "inf");
} else if (n == 0.0) {
strcpy(s, "0");
} else {
int digit, m, m1;
char *c = s;
int neg = (n < 0);
if (neg)
n = -n;
// calculate magnitude
m = log10(n);
int useExp = (m >= 14 || (neg && m >= 9) || m <= -9);
if (neg)
*(c++) = '-';
// set up for scientific notation
if (useExp) {
if (m < 0)
m -= 1.0;
n = n / pow(10.0, m);
m1 = m;
m = 0;
}
if (m < 1.0) {
m = 0;
}
// convert the number
while (n > PRECISION || m >= 0) {
double weight = pow(10.0, m);
if (weight > 0 && !isinf(weight)) {
digit = floor(n / weight);
n -= (digit * weight);
*(c++) = '0' + digit;
}
if (m == 0 && n > 0)
*(c++) = '.';
m--;
}
if (useExp) {
// convert the exponent
int i, j;
*(c++) = 'e';
if (m1 > 0) {
*(c++) = '+';
} else {
*(c++) = '-';
m1 = -m1;
}
m = 0;
while (m1 > 0) {
*(c++) = '0' + m1 % 10;
m1 /= 10;
m++;
}
c -= m;
for (i = 0, j = m-1; i<j; i++, j--) {
// swap without temporary
c[i] ^= c[j];
c[j] ^= c[i];
c[i] ^= c[j];
}
c += m;
}
*(c) = '\0';
}
return s;
}

int main(int argc, char** argv) {

int i;
char s[MAX_NUMBER_STRING_SIZE];
double d[] = {
0.0,
42.0,
1234567.89012345,
0.000000000000018,
555555.55555555555555555,
-888888888888888.8888888,
111111111111111111111111.2222222222
};
for (i = 0; i < 7; i++) {
printf("%d: printf: %.14g, dtoa: %s\n", i+1, d[i], dtoa(s, d[i]));
}
}
``````

Outputs:

1. printf: 0, dtoa: 0
2. printf: 42, dtoa: 42
3. printf: 1234567.8901234, dtoa: 1234567.89012344996444
4. printf: 1.8e-14, dtoa: 1.79999999999999e-14
5. printf: 555555.55555556, dtoa: 555555.55555555550381
6. printf: -8.8888888888889e+14, dtoa: -8.88888888888888e+14
7. printf: 1.1111111111111e+23, dtoa: 1.11111111111111e+23
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1. Use the `log`-function to find out the magnitude `m` of your number. If the magnitude is negative print `"0."` and an appropriate amount of zeros.
2. Consecutively divide by `10^m` and cast the result to int to get the decimal digits. m-- for the next digit.
3. If you came accross `m==0`, don't forget to print the decimal point `"."`.
4. Break off after a couple of digits. If `m>0` when you break of, don't forget to print `"E"` and `itoa(m)`.

Instead of the `log`-function you can also directly extract the exponent by bitshifting and correcting for the exponent's offset (see IEEE 754). Java has a double-to-bits function to get at the binary representation.

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`````` /*
* Program to convert float number to string without using sprintf
*/

#include "iostream"
#include "string"
#include "math.h"

# define PRECISION 5

using namespace std;

char*  floatToString(float num)
{
int whole_part = num;
int digit = 0, reminder =0;
int log_value = log10(num), index = log_value;
long wt =0;

// String containg result
char* str = new char[20];

//Initilise stirng to zero
memset(str, 0 ,20);

//Extract the whole part from float num
for(int  i = 1 ; i < log_value + 2 ; i++)
{
wt  =  pow(10.0,i);
reminder = whole_part  %  wt;
digit = (reminder - digit) / (wt/10);

//Store digit in string
str[index--] = digit + 48;              // ASCII value of digit  = digit + 48
if (index == -1)
break;
}

index = log_value + 1;
str[index] = '.';

float fraction_part  = num - whole_part;
float tmp1 = fraction_part,  tmp =0;

//Extract the fraction part from  num
for( int i= 1; i < PRECISION; i++)
{
wt =10;
tmp  = tmp1 * wt;
digit = tmp;

//Store digit in string
str[++index] = digit +48;           // ASCII value of digit  = digit + 48
tmp1 = tmp - digit;
}

return str;
}

//Main program
void main()
{
int i;
float f = 123456.789;
char* str =  floatToString(f);
cout  << endl <<  str;
cin >> i;
delete [] str;
}
``````
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worked like a charm for me. –  dmsherazi Jun 30 at 7:29

You have two major problems:

1. Converting the bit representation into a string of characters
2. Allocating enough memory to store the characters.

The simplest way to solve the second part is to allocate a big enough chunk for every possible answer. Start with that. Later you'll want to be more clever, but don't bother until you've solved the numeric part of the problem.

You have two sets of tools available for dealing with the numeric part of the problem: direct bit manipulation (masking, shifting, etc) and arithmetic operation (*,+,/, plus possibly math functions link `log()`).

In principle you could tackle the bitwise representation directly, but that would not be portable in the event that floating point representation formats change in the future. The method suggested by edgar.holleis should be portable.

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Here http://www.edaboard.com/ftopic41714.html You have implementation of ftoa. BTW: Strange question for interview :| Writing such function might not be obvious even for someone profession programmers.

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Just found realy good implementation at https://code.google.com/p/stringencoders/

``````size_t modp_dtoa(double value, char* str, int prec)
{
/* Hacky test for NaN
* under -fast-math this won't work, but then you also won't
* have correct nan values anyways.  The alternative is
*/
if (! (value == value)) {
str[0] = 'n'; str[1] = 'a'; str[2] = 'n'; str[3] = '\0';
return (size_t)3;
}
/* if input is larger than thres_max, revert to exponential */
const double thres_max = (double)(0x7FFFFFFF);

double diff = 0.0;
char* wstr = str;

if (prec < 0) {
prec = 0;
} else if (prec > 9) {
/* precision of >= 10 can lead to overflow errors */
prec = 9;
}

/* we'll work in positive values and deal with the
negative sign issue later */
int neg = 0;
if (value < 0) {
neg = 1;
value = -value;
}

int whole = (int) value;
double tmp = (value - whole) * powers_of_10[prec];
uint32_t frac = (uint32_t)(tmp);
diff = tmp - frac;

if (diff > 0.5) {
++frac;
/* handle rollover, e.g.  case 0.99 with prec 1 is 1.0  */
if (frac >= powers_of_10[prec]) {
frac = 0;
++whole;
}
} else if (diff == 0.5 && ((frac == 0) || (frac & 1))) {
/* if halfway, round up if odd, OR
if last digit is 0.  That last part is strange */
++frac;
}

/* for very large numbers switch back to native sprintf for exponentials.
anyone want to write code to replace this? */
/*
normal printf behavior is to print EVERY whole number digit
*/
if (value > thres_max) {
sprintf(str, "%e", neg ? -value : value);
return strlen(str);
}

if (prec == 0) {
diff = value - whole;
if (diff > 0.5) {
/* greater than 0.5, round up, e.g. 1.6 -> 2 */
++whole;
} else if (diff == 0.5 && (whole & 1)) {
/* exactly 0.5 and ODD, then round up */
/* 1.5 -> 2, but 2.5 -> 2 */
++whole;
}
} else {
int count = prec;
// now do fractional part, as an unsigned number
do {
--count;
*wstr++ = (char)(48 + (frac % 10));
} while (frac /= 10);
while (count-- > 0) *wstr++ = '0';
*wstr++ = '.';
}

// do whole part
// Take care of sign
// Conversion. Number is reversed.
do *wstr++ = (char)(48 + (whole % 10)); while (whole /= 10);
if (neg) {
*wstr++ = '-';
}
*wstr='\0';
strreverse(str, wstr-1);
return (size_t)(wstr - str);
}
``````
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This gist might help : https://gist.github.com/psych0der/6319244 Basic idea is split the whole part and decimal part and then concatenate both of them with decimal in between.

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