# What additional work is done by np.power?

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?

• 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 `power`functions, 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
• 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

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.

• 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
• 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
• True, although`0**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