# Fastest Way to generate 1,000,000+ random numbers in python

I am currently writing an app in python that needs to generate large amount of random numbers, FAST. Currently I have a scheme going that uses numpy to generate all of the numbers in a giant batch (about ~500,000 at a time). While this seems to be faster than python's implementation. I still need it to go faster. Any ideas? I'm open to writing it in C and embedding it in the program or doing w/e it takes.

Constraints on the random numbers:

• A Set of 7 numbers that can all have different bounds:
• eg: [0-X1, 0-X2, 0-X3, 0-X4, 0-X5, 0-X6, 0-X7]
• Currently I am generating a list of 7 numbers with random values from [0-1) then multiplying by [X1..X7]
• A Set of 13 numbers that all add up to 1
• Currently just generating 13 numbers then dividing by their sum

Any ideas? Would pre calculating these numbers and storing them in a file make this faster?

Thanks!

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It's pretty much a guarantee that going to disk I/O will not make it faster, so the file storage approach is probably not what you want. – John Feminella Apr 25 '10 at 20:25
what is the range of numbers? I assume they are floating-point? how much faster do you have to go? how much randomness do you need? can you get by generating N/7 numbers and rotating them?m – Anycorn Apr 25 '10 at 20:26
How important is it that those numbers are randomly generated when you need them? Would it be an option to store maybe 5 times as much previously generated random numbers and just select a random set of those? – poke Apr 25 '10 at 20:28
Could you provide your slow implementation. It takes 12 milliseconds to generate 1000_000 random integers. How much faster do you need? `python -mtimeit -s'import numpy as np' 'np.random.randint(low=0, high=500, size=(1000000,1))'` -> `100 loops, best of 3: 11.9 msec per loop` – J.F. Sebastian Apr 25 '10 at 20:50
[4] * 1000000 should be fastest. However, you may find the xkcd random number generator does not meet your needs as far as randomness goes. Can you say what those needs are? – James K Polk Apr 25 '10 at 21:04

## 5 Answers

You can speed things up a bit from what mtrw posted above just by doing what you initially described (generating a bunch of random numbers and multiplying and dividing accordingly)...

Also, you probably already know this, but be sure to do the operations in-place (*=, /=, +=, etc) when working with large-ish numpy arrays. It makes a huge difference in memory usage with large arrays, and will give a considerable speed increase, too.

``````In [53]: def rand_row_doubles(row_limits, num):
....:     ncols = len(row_limits)
....:     x = np.random.random((num, ncols))
....:     x *= row_limits
....:     return x
....:
In [59]: %timeit rand_row_doubles(np.arange(7) + 1, 1000000)
10 loops, best of 3: 187 ms per loop
``````

As compared to:

``````In [66]: %timeit ManyRandDoubles(np.arange(7) + 1, 1000000)
1 loops, best of 3: 222 ms per loop
``````

It's not a huge difference, but if you're really worried about speed, it's something.

Just to show that it's correct:

``````In [68]: x.max(0)
Out[68]:
array([ 0.99999991,  1.99999971,  2.99999737,  3.99999569,  4.99999836,
5.99999114,  6.99999738])

In [69]: x.min(0)
Out[69]:
array([  4.02099599e-07,   4.41729377e-07,   4.33480302e-08,
7.43497138e-06,   1.28446819e-05,   4.27614385e-07,
1.34106753e-05])
``````

Likewise, for your "rows sum to one" part...

``````In [70]: def rand_rows_sum_to_one(nrows, ncols):
....:     x = np.random.random((ncols, nrows))
....:     y = x.sum(axis=0)
....:     x /= y
....:     return x.T
....:

In [71]: %timeit rand_rows_sum_to_one(1000000, 13)
1 loops, best of 3: 455 ms per loop

In [72]: x = rand_rows_sum_to_one(1000000, 13)

In [73]: x.sum(axis=1)
Out[73]: array([ 1.,  1.,  1., ...,  1.,  1.,  1.])
``````

Honestly, even if you re-implement things in C, I'm not sure you'll be able to beat numpy by much on this one... I could be very wrong, though!

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@Joe - I tried your method for the limited numbers and found it to be slower on my machine. I'm curious if you could try mine and compare? I also stole your method for the sum-to-1 numbers; it was way faster than what I was trying before. Thanks! – mtrw Apr 25 '10 at 23:05
@mtrw- Your updated functions are faster than mine by a fair bit, now. (166ms vs 184ms) Yours don't require that the entire chunk of memory be contiguous, just the memory for each column, which I think is what's mostly causing the difference. The downside is in accessing the data after it's created. You'll have to use list comprehensions (or similar) for yours, whereas mine returns a single 2D numpy array (slightly faster and much more flexible indexing). It doesn't matter much if you just need to access one row at a time, though. Cheers! – Joe Kington Apr 26 '10 at 0:41
Thanks for the hard work! Trying to piece the code together now... – Sandro Apr 26 '10 at 0:44

EDIT Created functions that return the full set of numbers, not just one row at a time. EDIT 2 Make the functions more pythonic (and faster), add solution for second question

For the first set of numbers, you might consider `numpy.random.randint` or `numpy.random.uniform`, which take `low` and `high` parameters. Generating an array of 7 x 1,000,000 numbers in a specified range seems to take < 0.7 second on my 2 GHz machine:

``````def LimitedRandInts(XLim, N):
rowlen = (1,N)
return [np.random.randint(low=0,high=lim,size=rowlen) for lim in XLim]

def LimitedRandDoubles(XLim, N):
rowlen = (1,N)
return [np.random.uniform(low=0,high=lim,size=rowlen) for lim in XLim]

>>> import numpy as np
>>> N = 1000000 #number of randoms in each range
>>> xLim = [x*500 for x in range(1,8)] #convenient limit generation
>>> fLim = [x/7.0 for x in range(1,8)]
>>> aa = LimitedRandInts(xLim, N)
>>> ff = LimitedRandDoubles(fLim, N)
``````

This returns integers in [0,xLim-1] or floats in [0,fLim). The integer version took ~0.3 seconds, the double ~0.66, on my 2 GHz single-core machine.

For the second set, I used @Joe Kingston's suggestion.

``````def SumToOneRands(NumToSum, N):
aa = np.random.uniform(low=0,high=1.0,size=(NumToSum,N)) #13 rows by 1000000 columns, for instance
s = np.reciprocal(aa.sum(0))
aa *= s
return aa.T #get back to column major order, so aa[k] is the kth set of 13 numbers

>>> ll = SumToOneRands(13, N)
``````

This takes ~1.6 seconds.

In all cases, `result[k]` gives you the kth set of data.

-
you may win few cycles if you multiply by inverse instead of dividing in floating-point performance. – Anycorn Apr 25 '10 at 20:40
I'll have to give that a whack. Do you know the performance of stacking arrays horizontally (not sure how to word this) to combine the arrays? – Sandro Apr 25 '10 at 20:46
@aaa - Thanks, I pulled your suggestion into the answer. @Sandro - I think stack is not great. You might be able to preallocate the array. I'll see if I can make that work and update the answer. – mtrw Apr 25 '10 at 20:52
your code generating 100_000 not 1000_000 random integers. – J.F. Sebastian Apr 25 '10 at 20:54
other thing you can do is generate random N/13 numbers and rotate them clockwise or counter clockwise. this will generate random sets (but not random members in general). Really need to know where bottleneck is – Anycorn Apr 25 '10 at 21:01

Making your code run in parallel certainly couldn't hurt. Try adapting it for SMP with Parallel Python

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Actually due to the large memory required, copy the memory or sending it over a pipe is quiet expensive and so far has actually been slowing me down. – Sandro Apr 25 '10 at 21:09

Try `r = 1664525*r + 1013904223`
from "an even quicker generator" in "Numerical Recipes in C" 2nd edition, Press et al., isbn 0521431085, p. 284.
np.random is certainly "more random"; see Linear congruential generator .

In python, use `np.uint32` like this:

``````python -mtimeit -s '
import numpy as np
r = 1
r = np.array([r], np.uint32)[0]  # 316 py -> 16 us np
# python longs can be arbitrarily long, so slow
' '
r = r*1664525 + 1013904223  # NR2 p. 284
'
``````
-

As others have already pointed out, `numpy` is a very good start, fast and easy to use.

If you need random numbers on a massive scale, consider eas-ecb or rc4. Both can be parallelised, you should reach performance in several GB/s.

achievable numbers posted here

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I don't think your answer adds new information? – nemo Oct 8 '13 at 18:55
added a link... – qarma Oct 8 '13 at 20:34