# Converting double to float without relying on the FPU rounding mode

Does anyone have handy the snippets of code to convert an IEEE 754 `double` to the immediately inferior (resp. superior) `float`, without changing or assuming anything about the FPU's current rounding mode?

Note: this constraint probably implies not using the FPU at all. I expect the simplest way to do it in these conditions is to read the bits of the double in a 64-bit long and to work with that.

You can assume the endianness of your choice for simplicity, and that the double in question is available through the `d` field of the union below:

``````union double_bits
{
long i;
double d;
};
``````

I would try to do it myself but I am certain I would introduce hard-to-notice bugs for denormalized or negative numbers.

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on glibc systems you find a header file ieee754.h, which defines unions for the floating point types and a bitfield structure, so you can work with the mantissa and the exponent easier, sorry but I cannot give you real code. –  quinmars Jan 6 '10 at 11:23

I think the following works, but I will state my assumptions first:

• floating-point numbers are stored in IEEE-754 format on your implementation,
• No overflow,
• You have `nextafterf()` available (it's specified in C99).

Also, most likely, this method is not very efficient.

``````#include <stdio.h>
#include <stdlib.h>
#include <math.h>

int main(int argc, char *argv[])
{
/* Change to non-zero for superior, otherwise inferior */
int superior = 0;

/* double value to convert */
double d = 0.1;

float f;
double tmp = d;

if (argc > 1)
d = strtod(argv[1], NULL);

/* First, get an approximation of the double value */
f = d;

/* Now, convert that back to double */
tmp = f;

/* Print the numbers. %a is C99 */
printf("Double: %.20f (%a)\n", d, d);
printf("Float: %.20f (%a)\n", f, f);
printf("tmp: %.20f (%a)\n", tmp, tmp);

if (superior) {
/* If we wanted superior, and got a smaller value,
get the next value */
if (tmp < d)
f = nextafterf(f, INFINITY);
} else {
if (tmp > d)
f = nextafterf(f, -INFINITY);
}
printf("converted: %.20f (%a)\n", f, f);

return 0;
}
``````

On my machine, it prints:

``````Double: 0.10000000000000000555 (0x1.999999999999ap-4)
Float: 0.10000000149011611938 (0x1.99999ap-4)
tmp: 0.10000000149011611938 (0x1.99999ap-4)
converted: 0.09999999403953552246 (0x1.999998p-4)
``````

The idea is that I am converting the `double` value to a `float` value—this could be less than or greater than the double value depending upon the rounding mode. When converted back to `double`, we can check if it is smaller or greater than the original value. Then, if the value of the `float` is not in the right direction, we look at the next `float` number from the converted number in the original number's direction.

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Thank you very much for this code. I was slowly becoming convinced that this was the least error-prone solution. Thanks for pointing out `nextafterf` too, that's much better than in/decrementing the bits of the `float` as if it was an `int`. To alleviate the risk of `f+1` being equal to `f`, may I write `nextafterf(f, INFINITY)` instead? –  Pascal Cuoq Jan 7 '10 at 8:46
I just read the man pages, the C standard draft, and tried it out, and looks like `INFINITY` should work. –  Alok Singhal Jan 7 '10 at 8:54
OK, I have edited my post. Thanks for the comment. –  Alok Singhal Jan 7 '10 at 8:56

I posted code to do this here: Convert IEEE double to IEEE float without native support and copied it below for your convenience.

``````    // d is IEEE double, but double is not natively supported.
static float ConvertDoubleToFloat(void* d)
{
unsigned long long x;
float f; // assumed to be IEEE float
unsigned long long sign ;
unsigned long long exponent;
unsigned long long mantissa;

memcpy(&x,d,8);

// IEEE binary64 format (unsupported)
sign     = (x >> 63) & 1; // 1
exponent = ((x >> 52) & 0x7FF); // 11
mantissa = (x >> 0) & 0x000FFFFFFFFFFFFFULL; // 52
exponent -= 1023;

// IEEE binary32 format (supported)
exponent += 127; // rebase
exponent &= 0xFF;
mantissa >>= (52-23); // left justify

x = mantissa | (exponent << 23) | (sign << 31);
memcpy(&f,&x,4);

return f;
}
``````
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Thanks. The line `exponent &= 0xFF;` means that when it would be appropriate to return `±FLT_MAX` or `±inf`, a `float` with a strange exponent is returned instead (and denormal results are off, too). –  Pascal Cuoq Oct 28 '13 at 21:13

To do this job more accurately than just re-combine mantissa and exponent bit's check this out:

http://www.mathworks.com/matlabcentral/fileexchange/23173

regards

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Thanks. The `doubles2halfp` function there is as complicated as I feared, but at least it already has half the constants right, so it's a good starting point. –  Pascal Cuoq Jan 6 '10 at 10:14
I would use the given code as reference and rewrite a simpler approach, using & >> follwed by or, and then check very small and very large numbers. Take the shift count and bit-position at a glance from babbage.cs.qc.edu/IEEE-754/Decimal.html –  stacker Jan 6 '10 at 10:30