# How to speed up matrix code

I have the following simple code which estimates the probability that an h by n binary matrix has a certain property. It runs in exponential time (which is bad to start with) but I am surprised it is so slow even for n = 12 and h = 9.

``````#!/usr/bin/python

import numpy as np
import itertools

n = 12
h = 9

F = np.matrix(list(itertools.product([0,1],repeat = n))).transpose()

count = 0
iters = 100
for i in xrange(iters):
M =  np.random.randint(2, size=(h,n))
product = np.dot(M,F)
setofcols = set()
for column in product.T:
if (len(setofcols)==2**n):
count = count + 1
print count*1.0/iters
``````

I have profiled it using n = 10 and h = 7. The output is rather long but here are the lines that took more time.

``````        23447867 function calls (23038179 primitive calls) in 35.785 seconds

Ordered by: standard name

ncalls  tottime  percall  cumtime  percall filename:lineno(function)
2    0.002    0.001    0.019    0.010 __init__.py:1(<module>)
1    0.001    0.001    0.054    0.054 __init__.py:106(<module>)
1    0.001    0.001    0.022    0.022 __init__.py:15(<module>)
2    0.003    0.002    0.013    0.006 __init__.py:2(<module>)
1    0.001    0.001    0.003    0.003 __init__.py:38(<module>)
1    0.001    0.001    0.001    0.001 __init__.py:4(<module>)
1    0.001    0.001    0.004    0.004 __init__.py:45(<module>)
1    0.001    0.001    0.002    0.002 __init__.py:88(<module>)
307200    0.306    0.000    1.584    0.000 _methods.py:24(_any)
102400    0.026    0.000    0.026    0.000 arrayprint.py:22(product)
102400    1.345    0.000   32.795    0.000 arrayprint.py:225(_array2string)
307200/102400    1.166    0.000   33.350    0.000 arrayprint.py:335(array2string)
716800    0.820    0.000    1.162    0.000 arrayprint.py:448(_extendLine)
204800/102400    1.699    0.000    5.090    0.000 arrayprint.py:456(_formatArray)
307200    0.651    0.000   22.510    0.000 arrayprint.py:524(__init__)
307200   11.783    0.000   21.859    0.000 arrayprint.py:538(fillFormat)
1353748    1.920    0.000    2.537    0.000 arrayprint.py:627(_digits)
102400    0.576    0.000    2.523    0.000 arrayprint.py:636(__init__)
716800    2.159    0.000    2.159    0.000 arrayprint.py:649(__call__)
307200    0.099    0.000    0.099    0.000 arrayprint.py:658(__init__)
102400    0.163    0.000    0.225    0.000 arrayprint.py:686(__init__)
102400    0.307    0.000   13.784    0.000 arrayprint.py:697(__init__)
102400    0.110    0.000    0.110    0.000 arrayprint.py:713(__init__)
102400    0.043    0.000    0.043    0.000 arrayprint.py:741(__init__)
1    0.003    0.003    0.003    0.003 chebyshev.py:87(<module>)
2    0.001    0.000    0.001    0.000 collections.py:284(namedtuple)
1    0.277    0.277   35.786   35.786 counterfeit.py:3(<module>)
205002    0.222    0.000    0.247    0.000 defmatrix.py:279(__array_finalize__)
102500    0.747    0.000    1.077    0.000 defmatrix.py:301(__getitem__)
102400    0.322    0.000   34.236    0.000 defmatrix.py:352(__repr__)
102400    0.100    0.000    0.508    0.000 fromnumeric.py:1087(ravel)
307200    0.382    0.000    2.829    0.000 fromnumeric.py:1563(any)
271    0.004    0.000    0.005    0.000 function_base.py:3220(add_newdoc)
1    0.003    0.003    0.003    0.003 hermite.py:59(<module>)
1    0.003    0.003    0.003    0.003 hermite_e.py:59(<module>)
1    0.001    0.001    0.002    0.002 index_tricks.py:1(<module>)
1    0.003    0.003    0.003    0.003 laguerre.py:59(<module>)
1    0.003    0.003    0.003    0.003 legendre.py:83(<module>)
1    0.001    0.001    0.001    0.001 linalg.py:10(<module>)
1    0.001    0.001    0.001    0.001 numeric.py:1(<module>)
102400    0.247    0.000   33.598    0.000 numeric.py:1365(array_repr)
204800    0.321    0.000    1.143    0.000 numeric.py:1437(array_str)
614400    1.199    0.000    2.627    0.000 numeric.py:2178(seterr)
614400    0.837    0.000    0.918    0.000 numeric.py:2274(geterr)
102400    0.081    0.000    0.186    0.000 numeric.py:252(asarray)
307200    0.259    0.000    0.622    0.000 numeric.py:322(asanyarray)
1    0.003    0.003    0.004    0.004 polynomial.py:54(<module>)
513130    0.134    0.000    0.134    0.000 {isinstance}
307229    0.075    0.000    0.075    0.000 {issubclass}
5985327/5985305    0.595    0.000    0.595    0.000 {len}
306988    0.120    0.000    0.120    0.000 {max}
102400    0.061    0.000    0.061    0.000 {method '__array__' of 'numpy.ndarray' objects}
102406    0.027    0.000    0.027    0.000 {method 'add' of 'set' objects}
307200    0.241    0.000    1.824    0.000 {method 'any' of 'numpy.ndarray' objects}
307200    0.482    0.000    0.482    0.000 {method 'compress' of 'numpy.ndarray' objects}
204800    0.035    0.000    0.035    0.000 {method 'item' of 'numpy.ndarray' objects}
102451    0.014    0.000    0.014    0.000 {method 'join' of 'str' objects}
102400    0.222    0.000    0.222    0.000 {method 'ravel' of 'numpy.ndarray' objects}
921176    3.330    0.000    3.330    0.000 {method 'reduce' of 'numpy.ufunc' objects}
102405    0.057    0.000    0.057    0.000 {method 'replace' of 'str' objects}
2992167    0.660    0.000    0.660    0.000 {method 'rstrip' of 'str' objects}
102400    0.041    0.000    0.041    0.000 {method 'splitlines' of 'str' objects}
6    0.003    0.000    0.003    0.001 {method 'sub' of '_sre.SRE_Pattern' objects}
307276    0.090    0.000    0.090    0.000 {min}
100    0.013    0.000    0.013    0.000 {numpy.core._dotblas.dot}
409639    0.473    0.000    0.473    0.000 {numpy.core.multiarray.array}
1228800    0.239    0.000    0.239    0.000 {numpy.core.umath.geterrobj}
614401    0.352    0.000    0.352    0.000 {numpy.core.umath.seterrobj}
102475    0.031    0.000    0.031    0.000 {range}
102400    0.076    0.000    0.102    0.000 {reduce}
204845/102445    0.198    0.000   34.333    0.000 {repr}
``````

The multiplication of the matrices seems to take a tiny fraction of the time. Is it possible to speed up the rest?

Results

There are now three answers but one seems to have a bug currently. I have tested the remaining two with n=18, h=11 and iters=10 .

• bubble - 21 seconds, 185MB of RAM . 16 seconds on "sort".
• hpaulj - 7.5 seconds, 130MB of RAM . 3 seconds on "tolist". 1.5 seconds on "numpy.core.multiarray.array", 1.5 seconds on "genexpr" (the 'set' line).

Interestingly, the time for multiplying the matrices is still a tiny fraction of the overall time taken.

-
obviously it is possible to speed it up incredulously. if you see arrayprint, which part do you think is the slow part ;). –  seberg Dec 12 '13 at 11:55
You should read the link stackoverflow.com/questions/16970982/… I mentioned in your previous question for much more efficient method of uniques count. `arrapyprint.fillFormat` is what called in `repr(column)` part of your code, so it's the slowest part. –  alko Dec 12 '13 at 12:56
The set approach might be very good. But if you know the dtype/row is safe (including contiguity and byte order), you could just use `arr.tostring()`. –  seberg Dec 12 '13 at 14:07
Most of the time is in `arrayprint`, which is called by `repr`. What's the purpose of converting the numbers to strings? `numpy` is designed to work rapidly with arrays of numbers. When dealing with strings it uses regular Python methods. –  hpaulj Dec 12 '13 at 19:45
@hpaulj The conversion is just so you can tell how many columns are unique. –  marshall Dec 12 '13 at 19:46

Try replacing `repr(col)` with

``````setofcols.add(tuple(column.A1.tolist()))
``````

`set` accepts a `tuple`. `column.A1` is the matrix converted to a 1d array. The tuple is then something like `(0, 1, 0)`, which `set` can easily compare.

Just replacing the expensive `repr` formatting lops off a lot of time (25x speedup).

EDIT

By creating and filling the `set` in one statement I get a further 10x speed up. In my tests it is 2x faster than `bubble's` vectorization.

``````count = 0
for i in xrange(iters):
M =  np.random.randint(2, size=(h,n))
product = np.dot(M,F)
setofcols = set(tuple(x) for x in product.T.tolist())
# or {tuple(x) for x in product.T.tolist()} if new enough Python
if (len(setofcols)==2**n):
count += 1
# print M # to see the unique M
print count*1.0/iters
``````

EDIT

Here's something even faster - transform each column of 9 integers into 1, using `dot([1,10,100,...],column)`. Then apply `np.unique` (or `set`) to the list of integers. It's a 2-3x further speedup.

``````count = 0
X = 10**np.arange(h)
for i in xrange(iters):
M =  np.random.randint(2, size=(h,n))
product = np.dot(M,F)
setofcols = np.unique(np.dot(X,product).A1)
if (setofcols.size==2**n):
count += 1
print count*1.0/iters
``````

With this the top calls are

``````  200    0.201    0.001    0.204    0.001 {numpy.core._dotblas.dot}
100    0.026    0.000    0.026    0.000 {method 'sort' of 'numpy.ndarray' objects}
100    0.007    0.000    0.035    0.000 arraysetops.py:93(unique)
``````
-
Thanks. It still spends a small percentage of the time multiplying the matrices. I get for different parameters of n and h and iters=2, "39 6.465 0.166 6.465 0.166 {numpy.core.multiarray.array}", "2 3.803 1.902 3.803 1.902 {method 'tolist' of 'numpy.ndarray' objects}", "2 1.072 0.536 1.072 0.536 {numpy.core._dotblas.dot}" –  marshall Dec 13 '13 at 10:41
`np.dot` usng BLAS is one the most efficient (time wise) operations in `numpy`. So I'm not surprised that `tolist` takes longer. I suspect the numerous `array` calls remain even if you remove the `set` operations. –  hpaulj Dec 13 '13 at 16:41
Profiling in IPython shows that `multiarray.array` is being called while generating `F`, not during the `iters` loop. –  hpaulj Dec 13 '13 at 17:05
I've gotten further speedup by compressing each column down to one integer (by multiplying by `[1,10,100,...]`). Still have to do `unique` or `set` column by column. –  hpaulj Dec 13 '13 at 22:00

To speed up the code above you should avoid loops.

``````import numpy as np
import itertools

def unique_rows(a):
a = np.ascontiguousarray(a)
unique_a = np.unique(a.view([('', a.dtype)]*a.shape[1]))
return unique_a.view(a.dtype).reshape((unique_a.shape[0], a.shape[1]))

n = 12
h = 9
iters=100
F = np.matrix(list(itertools.product([0,1],repeat = n))).transpose()
M =  np.random.randint(2, size=(h*iters,n))
product = np.dot(M,F)
counts = map(lambda x: len(unique_rows(x.T))==2**n, np.split(product,iters,axis=0))
prob=float(sum(counts))/iters

#All unique submatrices M (hxn) with the sophisticated property...
[np.split(M,iters,axis=0)[j] for j in range(len(counts)) if counts[j]==True]
``````
-
the bottleneck in code is slow unique_rows implementation. –  alko Dec 12 '13 at 12:53
These solutions are slow? stackoverflow.com/questions/16970982/… –  bubble Dec 12 '13 at 12:56
Nope, those links I refer to too, but your answer do not contain them in any way, so it adds no value to OP question –  alko Dec 12 '13 at 12:58
If you care to elaborate your answer to working code, I guess it gonna be accepted. –  alko Dec 12 '13 at 12:59
@Bubble Thanks! This is much faster. Avoiding loops has two problems though. The first is that it now uses a lot of RAM. The second is that I can't now print M when the number of distinct columns is 2**n. Is there an easy way to modify your code to fix this? –  marshall Dec 12 '13 at 13:17

As alko and seberg pointed out, you are loosing a lot of time converting your arrays to large strings to store them in your set of columns.

If I understood your code correctly, you are trying to find if the number of different columns in your `product` matrix is equal to the length of this matrix. You can do that easily by sorting it and looking at differences from one column to the next:

``````D = (np.diff(np.sort(product.T, axis=0), axis=0) == 0)
``````

This will give you a matrix of booleans `D`. You can then see whether at least one element changes from one column to the next:

``````C = (1 - np.prod(D, axis=1)) # i.e. 'not all(D[i,:]) for all i'
``````

You then simply have to take see whether `all` the values are different:

``````hasproperty = np.all(C)
``````

Which gives you the complete code:

``````def f(n, h, iters):
F = np.array(list(itertools.product([0,1], repeat=n))).T
counts = []
for _ in xrange(iters):
M = np.random.randint(2, size=(h,n))
product = M.dot(F)
D = (np.diff(np.sort(product.T, axis=1), axis=0) == 0)
C =  (1 - np.prod(D, axis=1))
hasproperty = np.all(C)
counts.append(1. if hasproperty else 0.)
return np.mean(counts)
``````

Which takes roughly 8s for `f(12, 9, 100)`.

If you prefer comically compact expressions:

``````def g(n, h, iters):
F = np.array(list(itertools.product([0,1], repeat=n))).T
return np.mean([np.all(1 - np.prod(np.diff(np.sort(np.random.randint(2,size=(h,n)).dot(F).T, axis=1), axis=0)==0, axis=1)) for _ in xrange(iters)])
``````

Timing it gives:

``````>>> setup = """import numpy as np
def g(n, h, iters):
F = np.array(list(itertools.product([0,1], repeat=n))).T
return np.mean([np.all(1 - np.prod(np.diff(np.sort(np.random.randint(2,size=(h,n)).dot(F).T, axis=1), axis=0)==0, axis=1)) for _ in xrange(iters)])
"""
>>> timeit.timeit('g(10, 7, 100)', setup=setup, number=10)
17.358669997900734
>>> timeit.timeit('g(10, 7, 100)', setup=setup, number=50)
83.06966196163967
``````

Or approximatively 1.7s per call to `g(10,7,100)`.

-
Thanks but I think there is something slightly wrong with f at least. When you do f(12,8,100) you get 0.0. But using @bubble's code you don't. –  marshall Dec 12 '13 at 18:35
Indeed, there was a bug: `product.T` had to be sorted along `axis=1`. This is corrected, thank's for your feedback :) –  val Dec 13 '13 at 10:28
I am afraid there is still a bug. Try n =5, h = 4 and iters = 100. The output should be roughly 0.07. –  marshall Dec 13 '13 at 11:01