# Precisly convert float 32 to unsigned short or unsigned char

First of all sorry if this is a duplicate, I couldn't find any subject answering my question.

I'm coding a little program that will be used to convert 32-bit floating point values to short int (16 bit) and unsigned char( 8 bits) values. This is for HDR images purpose.

From here I could get the following function (without clamping) :

``````static inline uint8_t u8fromfloat(float x)
{
return (int)(x * 255.0f);
}
``````

I suppose that in the same way we could get short int by multiplying by `(pow( 2,16 ) -1)`

But then I ended up thinking about ordered dithering and especially to Bayer dithering. To convert to uint8_t I suppose I could use a 4x4 matrix and a 8*8 matrix for unsigned short.

I also thought of a Look-up table to speed-up the process, this way :

``````uint16_t LUT[0x10000] // 2^16 values contained
``````

and store 2^16 unsigned short values corresponding to a float. This same table could be then used for uint8_t as well because of the implicit cast between unsigned short <--> unsigned int

But wouldn't a look-up table like this be huge in memory? Also how would one fill a table like this?!

Now I'm confused, what would be best according to you? Thanks for any help !

EDIT after uwind answer: Let's say now that I also want to do basic color space conversion at the same time, that is before converting to U8/U16 , do a color space conversion (in float), and then shrink it to U8/U16. Wouldn't in that case use a lut be more efficient? And yeah I would still have the problem to index the lut..

.

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I've assumed this is a C question. –  Jodrell Jan 8 '13 at 11:09
yes, I forgot to precise that, it is C/ C++ –  Lex Jan 8 '13 at 11:12

The way I see it, the look-up table won't help since in order to index into it, you need to convert the float into some integer type. Catch 22.

The table would require 0x10000 * sizeof (uint16_t) bytes, which is 128 KB. Not a lot by modern standards, but on the other hand cache is precious. But, as I said, the table doesn't add much to the solution since you need to convert float to integer in order to index.

You could do a table indexed by the raw bits of the float re-interpreted as integer, but that would have to be 32 bits which becomes very large (8 GB or so).

Go for the straight-forward runtime conversion you outlined.

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Thanks unwind for your input . Let's say now that I also want to do basic color space conversion at the same time, that is before converting to U8/U16 , do a color space conversion (in float), and then shrink it to U8/U16. Wouldn't in that case use a lut be more efficient? And yeah I would still have the problem to index the lut... –  Lex Jan 8 '13 at 11:17

Just stay with the multiplication - it'll work fine.

Practically all modern CPU have vector instructions (SSE, AVX, ...) adapted to this stuff, so you might look at programming for that. Or use a compiler that automatically vectorizes your code, if possible (Intel C, also GCC). Even in cases where table-lookup is a possible solution, this can often be faster because you don't suffer from memory latency.

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First, float have 24 bits of precision, which can no way fit into a 16-bit int or even 8 bit. Second, float have much larger range, which can't be stored in any int or long long int

So your question is not correct, no way to precisely convert any float to short or char. It may be more correctly express as converting 32-bit float pixel value to 8 bit or 16 bit.

For the code you use above, the value 255 will less likely to be returned because it needs exactly 1.0 input, otherwise values such as 254.99999 will ended up truncated as 254. You should use some kind or rounding

``````return (int)(x * 255.0f + .5f);
``````

or better, use the code provided in your link for more balanced distribution

``````static inline uint8_t u8fromfloat_trick(float x)
{
union { float f; uint32_t i; } u;
u.f = 32768.0f + x * (255.0f / 256.0f);
return (uint8_t)u.i;
}
``````

Using LUT wouldn't be any faster because a table for 16-bit value is too large for fitting in cache, and in fact may reduce your performance greatly. The codes above need only 2 floating-point instructions, or with FMA only 1 instruction is enough. And SIMD will improve performance 4-8x further, so LUT method would be easily outperformed as you can't parallelize table lookups

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