The sigmoid function is defined as
I found that using the C built-in function exp()
to calculate the value of f(x)
is slow. Is there any faster algorithm to calculate the value of f(x)
?
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The sigmoid function is defined as
I found that using the C built-in function exp()
to calculate the value of f(x)
is slow. Is there any faster algorithm to calculate the value of f(x)
?
you don't have to use the actual, exact sigmoid function in a neural network algorithm but can replace it with an approximated version that has similar properties but is faster the compute.
For example, you can use the "fast sigmoid" function
f(x) = x / (1 + abs(x))
Using first terms of the series expansion for exp(x) won't help too much if the arguments to f(x) are not near zero, and you have the same problem with a series expansion of the sigmoid function if the arguments are "large".
An alternative is to use table lookup. That is, you precalculate the values of the sigmoid function for a given number of data points, and then do fast (linear) interpolation between them if you want.
f(x) = 0.5 * (x / (1 + abs(x)) + 1)
to approximate the questioner's sigmoid function f(x) = 1 / (1 + exp(-x))
?
– Samuel
Sep 11 '20 at 10:16
It's best to measure on your hardware first. Just a quick benchmark script shows, that on my machine 1/(1+|x|)
is the fastest, and tanh(x)
is the close second. Error function erf
is pretty fast too.
% gcc -Wall -O2 -lm -o sigmoid-bench{,.c} -std=c99 && ./sigmoid-bench
atan(pi*x/2)*2/pi 24.1 ns
atan(x) 23.0 ns
1/(1+exp(-x)) 20.4 ns
1/sqrt(1+x^2) 13.4 ns
erf(sqrt(pi)*x/2) 6.7 ns
tanh(x) 5.5 ns
x/(1+|x|) 5.5 ns
I expect that the results may vary depending on architecture and the compiler used, but erf(x)
(since C99), tanh(x)
and x/(1.0+fabs(x))
are likely to be the fast performers.
People here are mostly concerned about how fast one function is relative to another and create micro benchmark to see whether f1(x)
runs 0.0001 ms faster than f2(x)
. The big problem is that this is mostly irrelevant, because what matters is how fast your network learns with your activation function trying to minimize your cost function.
As of current theory, rectifier function and softplus
compared to sigmoid function or similar activation functions, allow for faster and effective training of deep neural architectures on large and complex datasets.
So I suggest to throw away micro-optimization, and take a look at which function allows faster learning (also taking looking at various other cost function).
This answer probably isn't relevant for most cases, but just wanted to throw out there that for CUDA computing I've found x/sqrt(1+x^2)
to be the fastest function by far.
For example, done with single precision float intrinsics:
__device__ void fooCudaKernel(/* some arguments */) {
float foo, sigmoid;
// some code defining foo
sigmoid = __fmul_rz(rsqrtf(__fmaf_rz(foo,foo,1)),foo);
}
To do the NN more flexible usually used some alpha rate to change the angle of graph around 0.
The sigmoid function looks like:
f(x) = 1 / ( 1+exp(-x*alpha))
The nearly equivalent, (but more faster function) is:
f(x) = 0.5 * (x * alpha / (1 + abs(x*alpha))) + 0.5
You can check the graphs here
When I using abs function the network become faster 100+ times.
Also you might use rough version of sigmoid (it differences not greater than 0.2% from original):
inline float RoughSigmoid(float value)
{
float x = ::abs(value);
float x2 = x*x;
float e = 1.0f + x + x2*0.555f + x2*x2*0.143f;
return 1.0f / (1.0f + (value > 0 ? 1.0f / e : e));
}
void RoughSigmoid(const float * src, size_t size, const float * slope, float * dst)
{
float s = slope[0];
for (size_t i = 0; i < size; ++i)
dst[i] = RoughSigmoid(src[i] * s);
}
Optimization of RoughSigmoid function with using SSE:
#include <xmmintrin.h>
void RoughSigmoid(const float * src, size_t size, const float * slope, float * dst)
{
size_t alignedSize = size/4*4;
__m128 _slope = _mm_set1_ps(*slope);
__m128 _0 = _mm_set1_ps(-0.0f);
__m128 _1 = _mm_set1_ps(1.0f);
__m128 _0555 = _mm_set1_ps(0.555f);
__m128 _0143 = _mm_set1_ps(0.143f);
size_t i = 0;
for (; i < alignedSize; i += 4)
{
__m128 _src = _mm_loadu_ps(src + i);
__m128 x = _mm_andnot_ps(_0, _mm_mul_ps(_src, _slope));
__m128 x2 = _mm_mul_ps(x, x);
__m128 x4 = _mm_mul_ps(x2, x2);
__m128 series = _mm_add_ps(_mm_add_ps(_1, x), _mm_add_ps(_mm_mul_ps(x2, _0555), _mm_mul_ps(x4, _0143)));
__m128 mask = _mm_cmpgt_ps(_src, _0);
__m128 exp = _mm_or_ps(_mm_and_ps(_mm_rcp_ps(series), mask), _mm_andnot_ps(mask, series));
__m128 sigmoid = _mm_rcp_ps(_mm_add_ps(_1, exp));
_mm_storeu_ps(dst + i, sigmoid);
}
for (; i < size; ++i)
dst[i] = RoughSigmoid(src[i] * slope[0]);
}
Optimization of RoughSigmoid function with using AVX:
#include <immintrin.h>
void RoughSigmoid(const float * src, size_t size, const float * slope, float * dst)
{
size_t alignedSize = size/8*8;
__m256 _slope = _mm256_set1_ps(*slope);
__m256 _0 = _mm256_set1_ps(-0.0f);
__m256 _1 = _mm256_set1_ps(1.0f);
__m256 _0555 = _mm256_set1_ps(0.555f);
__m256 _0143 = _mm256_set1_ps(0.143f);
size_t i = 0;
for (; i < alignedSize; i += 8)
{
__m256 _src = _mm256_loadu_ps(src + i);
__m256 x = _mm256_andnot_ps(_0, _mm256_mul_ps(_src, _slope));
__m256 x2 = _mm256_mul_ps(x, x);
__m256 x4 = _mm256_mul_ps(x2, x2);
__m256 series = _mm256_add_ps(_mm256_add_ps(_1, x), _mm256_add_ps(_mm256_mul_ps(x2, _0555), _mm256_mul_ps(x4, _0143)));
__m256 mask = _mm256_cmp_ps(_src, _0, _CMP_GT_OS);
__m256 exp = _mm256_or_ps(_mm256_and_ps(_mm256_rcp_ps(series), mask), _mm256_andnot_ps(mask, series));
__m256 sigmoid = _mm256_rcp_ps(_mm256_add_ps(_1, exp));
_mm256_storeu_ps(dst + i, sigmoid);
}
for (; i < size; ++i)
dst[i] = RoughSigmoid(src[i] * slope[0]);
}
You can use a simple but effective method by using two formulas:
if x < 0 then f(x) = 1 / (0.5/(1+(x^2)))
if x > 0 then f(x) = 1 / (-0.5/(1+(x^2)))+1
This will look like this:
Two graphs for a sigmoid {Blue: (0.5/(1+(x^2))), Yellow: (-0.5/(1+(x^2)))+1}
Using Eureqa to search for approximations to sigmoid I found 1/(1 + 0.3678749025^x)
approximates it. It's pretty close, just gets rid of one operation with the negation of x.
Some of the other functions shown here are interesting, but is the power operation really that slow? I tested it and it actually did faster than addition, but that could just be a fluke. If so it should be just as fast or faster as all the others.
EDIT:0.5 + 0.5*tanh(0.5*x)
and less accurate, 0.5 + 0.5*tanh(n)
also works. And you could just get rid of the constants if you don't care about getting it between the range [0,1] like sigmoid. But it assumes that tanh is faster.
The tanh function may be optimized in some languages, making it faster than a custom defined x/(1+abs(x)), such is the case in Julia.
You can also use this:
y=x / (2 * ((x<0.0)*-x+(x>=0.0)*x) + 2) + 0.5;
y'=y(1-y);
acts like a sigmoid now because y(1-y)=y' is more let say round than 1/(2 (1 + abs(x))^2) acts more like to fast sigmoid;
I don't think you can do better than the built-in exp() but if you want another approach, you can use series expansion. WolframAlpha can compute it for you.