Random picks from permutation generator?

How to randomly pick all the results, one by one (no repeats) from `itertools.permutations(k)`? Or this: how to build a generator of randomized permutations? Something like `shuffle(permutations(k))`. I’m using Python 2.6.

Yeah, `shuffle(r)` could be used if `r = list(permutations(k))`, but such a list will take up too much time and memory when `len(k)` raises above 10.

Thanks.

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The question as presented is a little tricksy. You want to pull all permutations from an iterable, but what are you going to do with it? Often knowing the intent helps to form a more complete and correct solution. Additionally, you want to share some code next time. Lastly, I'm going to point out: you can't do random on random. I suggest emitting all the permutations (perhaps with a loop?) and then randomly choose elements from that newly created array. As you pull a value from the array, remove it from the array. Then always choose a new target value at random from remaining item count. –  jcolebrand Apr 9 '11 at 2:33
My aim is to find the tighest fit of rectangles on a given area. Permutations yield sequences of indexes (Figs positions) to test. Random searches get fair results, but with up to 50% collisions. Permutations() generates too much to test: 3.63M possibilities w/ 10 figs; and len(k) = 11 is already impractical in list(permutations(k)); (2) testing only part of the linearly organized indexes is not efficient, as they are quite similar [0123456789, …98, …879, etc]: results are rarely better than with random searches. Better to pick these randomly, without repeats; this also eliminates collisions. –  Alex Apr 9 '11 at 16:44
My code to measure collisions with shuffle searches: `def colls(list):\ p = permutations(list)\ n = 0\ for i in p: n += 1\ colls = 0\ j = []\ k = list[:]\ j.append(k)\ for i in range(n):\ random.shuffle(list)\ k = list[:]\ if k in j:\ colls += 1\ else:\ j.append(k)\ return "Percentage of collisions: %.2f" % ((float(colls) / n) * 100)` –  Alex Apr 9 '11 at 17:03

this gives the nth permutation of a list

``````def perm_given_index(alist, apermindex):
alist = alist[:]
for i in range(len(alist)-1):
apermindex, j = divmod(apermindex, len(alist)-i)
alist[i], alist[i+j] = alist[i+j], alist[i]
return alist
``````

where `apermindex` is between `0` and `factorial(len(alist))`

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Looks brilliant to me. I can simply randomize the values in range(factorial(len(alist))) and use this sequence linearly. Thanks a lot to all. –  Alex Apr 9 '11 at 16:26

Perhaps that's not so efficient, but it allows to deal with any number of random permutations the given list.

``````import numpy as np
from math import factorial

for i in range(factorial(len(biglist))):
permut = np.random.permutation(biglist).tolist()
...
``````
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There's no way of doing what you have asked for without writing your own version of `permutations`.

Consider this:

• We have a generator object containing the result of `permutations`.
• We have written our own function to tell us the length of the generator.
• We then pick an entries at random between the beginning of the list and the end.

Since I have a generator if the random function picks an entry near the end of the list the only way to get to it will be to go through all the prior entries and either throw them away, which is bad, or store them in a list, which you have pointed out is problematic when you have a lot of options.

Are you going to loop through every permutation or use just a few? If it's the latter it would make more sense to generate each new permutation at random and store then ones you've seen before in a `set`. If you don't use that many the overhead of having to create a new permutation each time you have a collision will be pretty low.

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There are algorithms that can give you permutations. You can find one that works in linear time in this wikipedia article.

Implement it in python using `yield` for efficient sequential generation. Though, if you want random picking with no repetitions, you'll have to generate the list, or use the algorithm posted by Dan and remember numbers you already chose.

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I don't know how python implements its shuffle algorithm, but the following scales in linear time, so I don't see why a length of 10 is such a big deal (unless I misunderstand your question?):