3

The input list can be more than 1 million numbers. When I run the following code with smaller 'repeats', its fine;

def sample(x):
    length = 1000000 
    new_array = random.sample((list(x)),length)
    return (new_array)

def repeat_sample(x):    
    i = 0
    repeats = 100
    list_of_samples = []
    for i in range(repeats):
       list_of_samples.append(sample(x))
    return(list_of_samples)

repeat_sample(large_array)

However, using high repeats such as the 100 above, results in MemoryError. Traceback is as follows;

Traceback (most recent call last):
  File "C:\Python31\rnd.py", line 221, in <module>
    STORED_REPEAT_SAMPLE = repeat_sample(STORED_ARRAY)
  File "C:\Python31\rnd.py", line 129, in repeat_sample
    list_of_samples.append(sample(x))
  File "C:\Python31\rnd.py", line 121, in sample
    new_array = random.sample((list(x)),length)
  File "C:\Python31\lib\random.py", line 309, in sample
    result = [None] * k
MemoryError

I am assuming I'm running out of memory. I do not know how to get around this problem.

Thank you for your time!

2
  • Change your algorithm? What are the samples used for? Can't you do that bit by bit, after each sample?
    – TryPyPy
    Jan 16, 2011 at 15:34
  • You might be able to reconfigure your system so you have more virtual memory -- which usually means more free hard disk space.
    – martineau
    Jan 16, 2011 at 22:12

5 Answers 5

5

Expanding on my comment:

Let's say the processing you do to each sample is calculate its mean.

def mean(samplelists):
    means = []
    n = float(len(samplelists[0]))
    for sample in samplelists:
        mean = sum(sample)/n
        means.append(mean)
    return means

calc_means(repeat_sample(large_array))

This is going to make you sweat holding all those lists in memory. You can get it much lighter like this:

def mean(sample, n):
    n = float(n)
    mean = sum(sample)/n
    return mean

def sample(x):
    length = 1000000 
    new_array = random.sample(x, length)
    return new_array

def repeat_means(x):    
    repeats = 100
    list_of_means = []
    for i in range(repeats):
        list_of_means.append(mean(sample(x)))
    return list_of_means    

repeat_means(large_array)

But that's still not good enough... You can do it all with only ever constructing your list of results:

import random

def sampling_mean(population, k, times):
    # Part of this is lifted straight from random.py
    _int = int
    _random = random.random

    n = len(population)
    kf = float(k)
    result = []

    if not 0 <= k <= n:
        raise ValueError, "sample larger than population"

    for t in range(times):
        selected = set()
        sum_ = 0
        selected_add = selected.add

        for i in xrange(k):
            j = _int(_random() * n)
            while j in selected:
                j = _int(_random() * n)
            selected_add(j)
            sum_ += population[j]

        mean = sum_/kf
        result.append(mean)
    return result

sampling_mean(x, 1000000, 100)

Now, can your algorithm be streamlined like this?

1
  • This is perfect. Yes I only was creating it to perform such calculations. Thank you for that!
    – jimy
    Jan 17, 2011 at 3:40
4

Two answers:

  1. Unless you're using an old machine, it's unlikely that you actually run out of memory. You get a MemoryError because you're probably using a 32-bit build of Python and that you can't allocate more than 2GB of memory.

  2. Your approach is wrong. You should use a random sample generator instead of building a list of samples.

1
  • Ahh I see about the 32bit. Cheers.
    – jimy
    Jan 17, 2011 at 3:41
1

A generator version of random.sample() would also help:

from random import random
from math import ceil as _ceil, log as _log

def xsample(population, k):
    """A generator version of random.sample"""
    n = len(population)
    if not 0 <= k <= n:
        raise ValueError("sample larger than population")
    _int = int
    setsize = 21        # size of a small set minus size of an empty list
    if k > 5:
        setsize += 4 ** _ceil(_log(k * 3, 4)) # table size for big sets
    if n <= setsize or hasattr(population, "keys"):
        # An n-length list is smaller than a k-length set, or this is a
        # mapping type so the other algorithm wouldn't work.
        pool = list(population)
        for i in range(k):         # invariant:  non-selected at [0,n-i)
            j = _int(random() * (n-i))
            yield pool[j]
            pool[j] = pool[n-i-1]   # move non-selected item into vacancy
    else:
        try:
            selected = set()
            selected_add = selected.add
            for i in range(k):
                j = _int(random() * n)
                while j in selected:
                    j = _int(random() * n)
                selected_add(j)
                yield population[j]
        except (TypeError, KeyError):   # handle (at least) sets
            if isinstance(population, list):
                raise
            for x in sample(tuple(population), k):
                yield x
0
0

The only improvement you can do is to change your code to:

list_of_samples = [random.sample(x, length) for _ in range(repeats)]

It wouldn't change the fact, however, that you cannot create arbitrary-length list in the real world.

0

You could try to use array object http://docs.python.org/py3k/library/array.html. It should be much more memory effective than list, but probably a little harder to use.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.