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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?

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    Try the same test with larger arrays (e.g. near 32768). Oct 17, 2014 at 18:02
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    @WarrenWeckesser - There's now a massive increase in performance when I pad it to a power of two (i.e., 32768). SO I'm guessing there's a cutoff where the performance increase starts to show.
    – Kitchi
    Oct 17, 2014 at 18:21
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    For small arrays, the overhead (extra copying, other?) swamps the performance gain of using a power of 2. The amount of overhead from using n=1024 is surprising, but I haven't looked into the code to find the cause. Oct 17, 2014 at 18:42

2 Answers 2

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FFT algorithms like NumPy's are fast for array sizes that factorize into a product of small primes, not just powers of two. If you increase the array size by padding the computational work increases. The speed of FFT algorithms is also critically dependent on the cache use. If you pad to an array size that creates less efficient cache use the efficiency slows down. The really fast FFT algorithms, like FFTW and Intel MKL, will actually generate plans for the array size factorization to get the most efficient computation. This includes both heuristics and actual measurements. So no, padding to the nearest power of two is only beneficial in introductory textbooks and not neccesarily in practice. As a rule of thumb you usually benefit from padding if the array size factorizes to one or more very large prime.

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You're using np.arange when you want to be using np.linspace

In [2]: x     = np.arange(-4.*np.pi, 4.*np.pi, 1000)

In [3]: x
Out[3]: array([-12.56637061])

np.arange takes arguments (start, stop, step), whereas np.linspace is (start, stop, number_of_pts). When you calculate with the data I suspect you think you're using, you get the expected behavior:

In [4]: x = np.linspace(-4.*np.pi, 4.*np.pi, 1000)

In [5]: dat1 = np.sin(x)

In [6]: %timeit np.fft.fft(dat1)
1 loops, best of 3: 28.1 µs per loop

In [7]: %timeit np.fft.fft(dat1, n=1024)
10000 loops, best of 3: 26.7 µs per loop

In [8]: x = np.linspace(-4.*np.pi, 4.*np.pi, 1009)

In [9]: dat2 = np.sin(x)

In [10]: %timeit np.fft.fft(dat2)
10000 loops, best of 3: 53 µs per loop

In [11]: %timeit np.fft.fft(dat2, n=1024)
10000 loops, best of 3: 26.8 µs per loop
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  • Ah, damn. I shouldn't be making "intelligent" observations this far past bedtime. Thanks for pointing out the stupidity!
    – Kitchi
    Oct 17, 2014 at 17:53
  • I just tried it with linspace and I'm finding something similar to the original post. I've edited it to reflect that.
    – Kitchi
    Oct 17, 2014 at 17:58

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