Maybe I'm doing something odd, but maybe found a surprising performance loss when using numpy, seems consistent regardless of the power used. For instance when x is a random 100x100 array

```
x = numpy.power(x,3)
```

is about 60x slower than

```
x = x*x*x
```

A plot of the speed up for various array sizes reveals a sweet spot with arrays around size 10k and a consistent 5-10x speed up for other sizes.

Code to test below on your own machine (a little messy):

```
import numpy as np
from matplotlib import pyplot as plt
from time import time
ratios = []
sizes = []
for n in np.logspace(1,3,20).astype(int):
a = np.random.randn(n,n)
inline_times = []
for i in range(100):
t = time()
b = a*a*a
inline_times.append(time()-t)
inline_time = np.mean(inline_times)
pow_times = []
for i in range(100):
t = time()
b = np.power(a,3)
pow_times.append(time()-t)
pow_time = np.mean(pow_times)
sizes.append(a.size)
ratios.append(pow_time/inline_time)
plt.plot(sizes,ratios)
plt.title('Performance of inline vs numpy.power')
plt.ylabel('Nx speed-up using inline')
plt.xlabel('Array size')
plt.xscale('log')
plt.show()
```

Anyone have an explanation?

`time`

for timing code. The docs for`time`

even tell you this. On some platforms, in some circumstances, it may be good enough… but it's still better to use`timeit`

. – abarnert Aug 12 '14 at 0:46`x*x*x`

however can be expressed very easily using opcodes, which themselves can be easily translated into actual machine code. – poke Aug 12 '14 at 0:49`timeit`

is how you profile your code; it's actually easier to use than`time`

, as well as more likely to be right. (Even more so if you use IPython and its magic`%timeit`

.) – abarnert Aug 12 '14 at 1:24`power`

that unrolls small integers, and just put my name instead of whoever's that was? If so, then yeah, you may be right. – abarnert Aug 12 '14 at 1:25