# is this python benchmark useful?

I recently tried to run an Project Euler problem in python. It was my belief that it would do something like 100^5 steps.

After seeing that my solution wat taking too long (it is supposed to run in under a minute) I asked myself if any python program that ran this many steps would be viable (under a minute)

so, I designed a foolish little test

``````def fun():
l=range(1,100)
for x in l:
for y in l:
for k in l:
for n in l:
for h in l:
s=1

>>> t.timeit(1)
1202.484529018402
>>>
``````

does is make sense ? Does it prove that any program with this many steps (in this case, I guess there are 2*(100^5)) always demands some 20 minutes ?

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For python it's probably a good estimate. Using numpy or C++ extensions might speed up your Project Euler code, but remember all problems on Project Euler are designed to be solvable in <1 min. It's very unlikely you are required to run 100^5 operations in order to arrive at the correct solution. I'd try to approach the problem from a different angle if I were you.

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In C, it ran just under a minute. Then, looking at the answers, I saw a small modification that seems to make things aprox 100x faster. I'll look further into it. Thanks, though –  josinalvo Jul 22 '12 at 22:32
No problem! Glad I could help. –  Madison May Jul 23 '12 at 22:26

Project Euler problems are not supposed to run in under a minute because your programming language is fast enough, but because there exists a solution that's cleverer than just brute force.

But in your case, yes, you'll get a function that loops `99^5` times (not `100^5` because `range(1,100)` is `1, 2, ..., 99`)...

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It is a reasonable assumption, though I am not sure it is doing what you want. In real life this might be closer:

``````for i in xrange(100 ** 5): pass
``````
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Does it prove that any program with this many steps always demands some 20 minutes ?

Depends on your definition of "step". Here is code that requires about 99^5 floating point operations, but runs in about 1 second:

``````import numpy as np
a = np.zeros(shape=(1681, 1681), dtype=np.float32) # 1681 x 1681 matrix
b = np.dot(a, a) # matrix product
``````
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Try `pass` instead of `s=1` in the inner loop.

Also, use `numpy.nditer` with "external_loop" option, or write the loops in Cython if loops turn out to be your bottleneck.

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