I had writted a script using NumPy's fft
function, where I was padding my input array to the nearest power of 2 to get a faster FFT.
After profiling the code, I found that the FFT call was taking the longest time, so I fiddled around with the parameters and found that if I didn't pad the input array, the FFT ran several times faster.
Here's a minimal example to illustrate what I'm talking about (I ran this in IPython and used the %timeit
magic to time the execution).
x = np.arange(-4.*np.pi, 4.*np.pi, 1000)
dat1 = np.sin(x)
The timing results:
%timeit np.fft.fft(dat1)
100000 loops, best of 3: 12.3 µs per loop
%timeit np.fft.fft(dat1, n=1024)
10000 loops, best of 3: 61.5 µs per loop
Padding the array to a power of 2 leads to a very drastic slowdown.
Even if I create an array with a prime number of elements (hence the theoretically slowest FFT)
x2 = np.arange(-4.*np.pi, 4.*np.pi, 1009)
dat2 = np.sin(x2)
The time it takes to run still doesn't change so drastically!
%timeit np.fft.fft(dat2)
100000 loops, best of 3: 12.2 µs per loop
I would have thought that padding the array will be a one time operation, and then calculating the FFT should be quicker. Am I missing anything?
EDIT: I was supposed to use np.linspace
rather than np.arange
. Below are the timing results using linspace
In [2]: import numpy as np
In [3]: x = np.linspace(-4*np.pi, 4*np.pi, 1000)
In [4]: x2 = np.linspace(-4*np.pi, 4*np.pi, 1024)
In [5]: dat1 = np.sin(x)
In [6]: dat2 = np.sin(x2)
In [7]: %timeit np.fft.fft(dat1)
10000 loops, best of 3: 55.1 µs per loop
In [8]: %timeit np.fft.fft(dat2)
10000 loops, best of 3: 49.4 µs per loop
In [9]: %timeit np.fft.fft(dat1, n=1024)
10000 loops, best of 3: 64.9 µs per loop
Padding still causes a slowdown. Could this be a local issue? i.e., due to some quirk in my NumPy setup it's acting this way?
n=1024
is surprising, but I haven't looked into the code to find the cause.