14

I am trying to create a generator that returns numbers in a given range that pass a particular test given by a function foo. However I would like the numbers to be tested in a random order. The following code will achieve this:

from random import shuffle

def MyGenerator(foo, num):
    order = list(range(num))
    shuffle(order)
    for i in order:
        if foo(i):
            yield i

The Problem

The problem with this solution is that sometimes the range will be quite large (num might be of the order 10**8 and upwards). This function can become slow, having such a large list in memory. I have tried to avoid this problem, with the following code:

from random import randint    

def MyGenerator(foo, num):
    tried = set()
    while len(tried) <= num - 1:
        i = randint(0, num-1)
        if i in tried:
            continue
        tried.add(i)
        if foo(i):
            yield i

This works well most of the time, since in most cases num will be quite large, foo will pass a reasonable number of numbers and the total number of times the __next__ method will be called will be relatively small (say, a maximum of 200 often much smaller). Therefore its reasonable likely we stumble upon a value that passes the foo test and the size of tried never gets large. (Even if it only passes 10% of the time, we wouldn't expect tried to get larger than about 2000 roughly.)

However, when num is small (close to the number of times that the __next__ method is called, or foo fails most of the time, the above solution becomes very inefficient - randomly guessing numbers until it guesses one that isn't in tried.

My attempted solution...

I was hoping to use some kind of function that maps the numbers 0,1,2,..., n onto themselves in a roughly random way. (This isn't being used for any security purposes and so doesn't matter if it isn't the most 'random' function in the world). The function here (Create a random bijective function which has same domain and range) maps signed 32-bit integers onto themselves, but I am not sure how to adapt the mapping to a smaller range. Given num I don't even need a bijection on 0,1,..num just a value of n larger than and 'close' to num (using whatever definition of close you see fit). Then I can do the following:

def mix_function_factory(num):
    # something here???
    def foo(index):
        # something else here??
    return foo

def MyGenerator(foo, num):
    mix_function = mix_function_factory(num):
    for i in range(num):
        index = mix_function(i)
        if index <= num:
            if foo(index):
                yield index

(so long as the bijection isn't on a set of numbers massively larger than num the number of times index <= num isn't True will be small).

My Question

Can you think of one of the following:

  • A potential solution for mix_function_factory or even a few other potential functions for mix_function that I could attempt to generalise for different values of num?
  • A better way of solving the original problem?

Many thanks in advance....

2
  • maybe you could do either method 1 or 2 depending on the size of num: if small, use shuffle on a pre-computed list, if big use the set approach Apr 21, 2018 at 14:47
  • Something else to consider: how bad is it, really, if the generator repeats a number? If you can get away with an occasional repeated number (possibly with some changes in another part of your code), that opens up a bunch more possibilities, and if num is really large, the chance that happens might be vanishingly small anyway.
    – David Z
    Apr 21, 2018 at 21:29

3 Answers 3

11

The problem is basically generating a random permutation of the integers in the range 0..n-1.

Luckily for us, these numbers have a very useful property: they all have a distinct value modulo n. If we can apply some mathemical operations to these numbers while taking care to keep each number distinct modulo n, it's easy to generate a permutation that appears random. And the best part is that we don't need any memory to keep track of numbers we've already generated, because each number is calculated with a simple formula.


Examples of operations we can perform on every number x in the range include:

  • Addition: We can add any integer c to x.
  • Multiplication: We can multiply x with any number m that shares no prime factors with n.

Applying just these two operations on the range 0..n-1 already gives quite satisfactory results:

>>> n = 7
>>> c = 1
>>> m = 3
>>> [((x+c) * m) % n for x in range(n)]
[3, 6, 2, 5, 1, 4, 0]

Looks random, doesn't it?

If we generate c and m from a random number, it'll actually be random, too. But keep in mind that there is no guarantee that this algorithm will generate all possible permutations, or that each permutation has the same probability of being generated.


Implementation

The difficult part about the implementation is really just generating a suitable random m. I used the prime factorization code from this answer to do so.

import random

# credit for prime factorization code goes
# to https://stackoverflow.com/a/17000452/1222951
def prime_factors(n):
    gaps = [1,2,2,4,2,4,2,4,6,2,6]
    length, cycle = 11, 3
    f, fs, next_ = 2, [], 0
    while f * f <= n:
        while n % f == 0:
            fs.append(f)
            n /= f
        f += gaps[next_]
        next_ += 1
        if next_ == length:
            next_ = cycle
    if n > 1: fs.append(n)
    return fs

def generate_c_and_m(n, seed=None):
    # we need to know n's prime factors to find a suitable multiplier m
    p_factors = set(prime_factors(n))

    def is_valid_multiplier(m):
        # m must not share any prime factors with n
        factors = prime_factors(m)
        return not p_factors.intersection(factors)

    # if no seed was given, generate random values for c and m
    if seed is None:
        c = random.randint(n)
        m = random.randint(1, 2*n)
    else:
        c = seed
        m = seed

    # make sure m is valid
    while not is_valid_multiplier(m):
        m += 1

    return c, m

Now that we can generate suitable values for c and m, creating the permutation is trivial:

def random_range(n, seed=None):
    c, m = generate_c_and_m(n, seed)

    for x in range(n):
        yield ((x + c) * m) % n

And your generator function can be implemented as

def MyGenerator(foo, num):
    for x in random_range(num):
        if foo(x):
            yield x
3
  • 5
    @Tim: This answer is effectively using a Linear Congruential Generator. IIRC, with m and n relatively prime or some similar condition, you do get all integers in the range exactly once, but it's not a very strong PRNG by modern standards. If it's good enough for your purposes, then great, but be aware that it's potentially weak, especially with some choices of m and n and maybe c. Apr 21, 2018 at 19:27
  • 5
    @PeterCordes: Unfortunately, it's not even a LCG. It's even weaker than that. I made the same mistake you did, but this answer is actually just stepping by multiples of m, because it increments x instead of using the previous output as the next x. This is really weak. Apr 21, 2018 at 21:21
  • Thankyou both. Having read the linked article, this can easily be adapted to be a genuine LCG, and since we already have the prime factors, we can choose a value of m that will ensure it is a genuine permutation. I had thought this would be good enough for my purposes, however for my actual use case, (which perhaps I should have originally stated) these numbers are a parametrisation of points in a finite n-dimensional space, and I can see how points might collect on certain planes, which I don’t want. Any suggestions? Apr 21, 2018 at 23:01
3

That may be a case where the best algorithm depends on the value of num, so why not using 2 selectable algorithms wrapped in one generator ?

you could mix your shuffle and set solutions with a threshold on the value of num. That's basically assembling your 2 first solutions in one generator:

from random import shuffle,randint

def MyGenerator(foo, num):
    if num < 100000 # has to be adjusted by experiments
      order = list(range(num))
      shuffle(order)
      for i in order:
          if foo(i):
              yield i
    else:   # big values, few collisions with random generator 
      tried = set()
      while len(tried) < num:
        i = randint(0, num-1)
        if i in tried:
           continue
        tried.add(i)
        if foo(i):
           yield i

The randint solution (for big values of num) works well because there aren't so many repeats in the random generator.

4
  • haha, I thought of this just after posting. Thankyou though :) It's what I think i'll go with for the time being, I'm still seems less than ideal though. I'll accept the answer if no-one can figure out a 'bijection factory' that'll work. I think it might be a case of over-optimizing too early on my part as well... Apr 21, 2018 at 15:27
  • Also, I have changed the original post from <= num to <= num - 1 (otherwise it will keep looping). I tried to edit your answer as well, but was unable to because it wasn't more than 6 characters, perhaps you won't have this restriction? Apr 21, 2018 at 16:25
  • ok, edited. Your both approaches are all right I doubt there's a generic solution. Well, we'll see. Nice question anyway. Apr 21, 2018 at 17:26
  • Cheers :) @aran-fey's solution seems to shuffle the numbers quite nicely. Although I suspect your idea of using a different algorithm depending upon the value of num, will improve the efficiency of his answer. I'll need to test with some actual values to find out Apr 21, 2018 at 17:34
1

Getting the best performance in Python is much trickier than in lower-level languages. For example, in C, you can often save a little bit in hot inner loops by replacing a multiplication by a shift. The overhead of python bytecode-orientation erases this. Of course, this changes again when you consider which variant of "python" you're targetting (pypy? numpy? cython?)- you really have to write your code based on which one you're using.

But even more important is arranging operations to avoid serialized dependencies, since all CPUs are superscalar these days. Of course, real compilers know about this, but it still matters when choosing an algorithm.


One of the easiest ways to gain a little bit over existing answers would be by by generating numbers in chunks using numpy.arange() and applying the ((x + c) * m) % n to the numpy ndarray directly. Every python-level loop that can be avoided helps.

If the function can be applied directly to numpy ndarrays, that might even better. Of course, a sufficiently-small function in python will be dominated by function-call overhead anyway.


The best fast random-number-generator today is PCG. I wrote a pure-python port here but concentrated on flexibility and ease-of-understanding rather than speed.

Xoroshiro128+ is second-best-quality and faster, but less informative to study.

Python's (and many others') default choice of Mersenne Twister is among the worst.

(there's also something called splitmix64 which I don't know enough about to place - some people say it's better than xoroshiro128+, but it has a period problem - of course, you might want that here)

Both default-PCG and xoroshiro128+ use a 2N-bit state to generate N-bit numbers. This is generally desirable, but means numbers will be repeated. PCG has alternate modes that avoid this, however.

Of course, much of this depends on whether num is (close to) a power of 2. In theory, PCG variants can be created for any bit width, but currently only various word sizes are implemented since you'd need explicit masking. I'm not sure exactly how to generate the parameters for new bit sizes (perhaps it's in the paper?), but they can be tested simply by doing a period/2 jump and verifying that the value is different.

Of course, if you're only making 200 calls to the RNG, you probably don't actually need to avoid duplicates on the math side.


Alternatively, you could use an LFSR, which does exist for every bit size (though note that it never generates the all-zeros value (or equivalently, the all-ones value)). LFSRs are serial and (AFAIK) not jumpable, and thus can't be easily split across multiple tasks. Edit: I figured out that this is untrue, simply represent the advance step as a matrix, and exponentiate it to jump.

Note that LFSRs do have the same obvious biases as simply generating numbers in sequential order based on a random start point - for example, if rng_outputs[a:b] all fail your foo function, then rng_outputs[b] will be much more likely as a first output regardless of starting point. PCG's "stream" parameter avoids this by not generating numbers in the same order.

Edit2: I have completed what I thought was a "brief project" implementing LFSRs in python, including jumping, fully tested.

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