I realised that np.power(a, b) is slower than np.exp(b * np.log(a)):

import numpy as np
a, b = np.random.random((2, 100000))
%timeit np.power(a, b) # best of 3: 4.16 ms per loop
%timeit np.exp(b * np.log(a)) # best of 3: 1.74 ms per loop

The results are the same (with a few numerical errors of order 1e-16).

What additional work is done in np.power? Furthermore, how can I find an answer to these kind of questions myself?

  • 6
    The entire source code is available at github.com/numpy/numpy, I found several power functions there and can't be sure which is which (I don't invest time in looking through it) but you could try there, just search with quotes "def power" as a start – Ofer Sadan Aug 7 '17 at 10:08
  • @OferSadan Can you tell me a little bit more, where you found these powerfunctions, can't find them myself (turns put NumPy is really big...) – Jürg Merlin Spaak Aug 7 '17 at 10:28
  • At the top of the github page there is a search field. Typing "def power" finds 3 hits. – unutbu Aug 7 '17 at 10:31
  • Exactly what @unutbu said – Ofer Sadan Aug 7 '17 at 10:33
  • 1
    Side note: %timeit a**b gives the same time as %timeit np.power(a,b) for me. – Michael H. Aug 7 '17 at 10:41
up vote 32 down vote accepted

Under the hood both expressions call the respective C functions pow or exp and log and running a profiling on those in C++, without any numpy code, gives:

pow      : 286 ms
exp(log) :  93 ms

This is consistent with the numpy timings. It thus seems like the primary difference is that the C function pow is slower than exp(log).

Why? It seems that part of the reson is that the expressions are not equivalent for all input. For example, with negative a and integer b, power works while exp(log) fails:

>>> np.power(-2, 2)
4
>>> np.exp(2 * np.log(-2))
nan

Another example is 0 ** 0:

>>> np.power(0, 0)
1
>>> np.exp(0 * np.log(0))
nan

Hence, the exp(log) trick only works on a subset of inputs, while power works on all (valid) inputs.

In addition to this, power is guaranteed to give full precision according to the IEEE 754 standard, while exp(log) may suffer from rounding errors.

  • 2
    And as for OP's question about finding answer yourself - I checked debugger for type of: np.power, np.log, np.exp - it was ufunc and in the documentation of numpy I found that these are defined in generate_umath.py as: pow, log and npy_ObjectPower. The last one is actually C function found in this file and returns PyNumber_Power and this is actually Python's pow according to docs – pierscin Aug 7 '17 at 10:55
  • 3
    Moreover, pow() always gives you the full accuracy of double precision floating point numbers, even in cases where the combination of exp() and log() loses a few digits. – Sven Marnach Aug 7 '17 at 10:56
  • You can actually do the "log trick" with negatives if you assign a = a.astype(complex) and pull the real part, but you lose the speed advantage – Daniel F Aug 7 '17 at 11:30
  • Sure, but you also need to handle a = b = 0! – Jonas Adler Aug 7 '17 at 11:33
  • 1
    True, although0**0=1 is more convention than identity, and technically 0**0=nan is also correct. It's just not very useful! – Daniel F Aug 7 '17 at 11:50

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