# Efficient exponentials with small base

I need to perform a softmax operation. That is, given a sequence of n real values ranging from -inf to +inf, I turn them into probabilities by exponentianting each value and dividing for the sum of exponentials:

for (i = 0; i < n; i++)
p_x[i] = exp(x[i]) / sum_exp(x, n)


(don't take the code literally, I'm not summing up all exp's every iteration!)

I'm having overflow problems when values go above 700 in some extreme cases (using 8-bytes doubles). I know I could use another base instead of e, however, I'm afraid calling pow will be much slower than exp (speed is critical for me).

What is the fastest way to solve this?

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Don't be afraid of pow being slower. Benchmark it! If you can't measure, you can't improve. –  paxdiablo Oct 16 '12 at 3:54
If you're afraid of pow, how about exp2? It performs 2^x instead of e^x. –  Gabe Oct 16 '12 at 4:04
I benchmarked pow, exp and exp2 (which I didn't know). exp seems to be 40~50 times faster than pow and 6~7 than exp2. Well, that's already something. –  erickrf Oct 16 '12 at 4:10
700 doesn't seem extreme compared to +Inf. Can you restrict your domain further? –  starblue Oct 16 '12 at 19:25
In fact, I found it easier and more efficient to subtract a constant value from every exponent. This way, the result is left unchanged. I only noticed later that using different bases will yield different probabilities. –  erickrf Oct 16 '12 at 19:31

Use each number as the 52-bit mantissa in a 64-bit floating point number. This is simply a matter of masking then casting.

#include <stdio.h>

int main(int argc, char *argv[])
{
long long val = 1234567890;
long long mval = val & ~0xfff0000000000000ULL;
float fval = *((float*)&mval);
printf("%f", fval);
}

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b^x = e^(x * ln b)


So using a smaller base b is equivalent to multiplying your values by ln b before applying exp, and dividing again at the end.

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