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What is an efficient way to do the following in python?
Given N symbols, iterate through all L length sequences of N symbols, that include all N symbols.

The order does not matter, as long as all sequences are covered, and each only once.

Let's call this iterator seq(symbols,L). Then, for example,
list(seq([1,2,3],3))=[(1, 2, 3), (1, 3, 2), (2, 1, 3), (2, 3, 1), (3, 1, 2), (3, 2, 1)]
list(seq([1,2,3],4))=[(1, 1, 2, 3), (1, 1, 3, 2), (1, 2, 1, 3), ...

Here's an intuitive, yet slow implementation:

import itertools

def seq(symbols,L):
  for x in itertools.product(symbols,repeat=L):
    if all(s in x for s in symbols):
      yield x

When N is large and L is close to N, there is a lot of wasted effort. For example, when L==N, it would be much better to use itertools.permutations(). Since every sequence needs to have all N symbols, it seems like a better solution would somehow start with the permuted solution, then add in the extra repeated symbols somehow, but I can't figure out how to do this without double counting (and without resorting to saving all previous output to check for a repeat).

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Is this what you want? en.wikipedia.org/wiki/… –  Tarzan Jan 28 '14 at 4:26

2 Answers 2

up vote 2 down vote accepted

An idea:

import itertools
def solve(size, symbols, todo = None):
  if todo is None: todo = frozenset(symbols)
  if size < len(todo): return
  if size == len(todo):
    yield from itertools.permutations(todo)  # use sorted(todo) here 
                                             # for lexicographical order
  for s in symbols:
    for xs in solve(size - 1, symbols, todo - frozenset((s,))):
      yield (s,) + xs

for x in solve(5, (1,2,3)):

Will print all sequences of size 5 that contain each of 1,2,3 and 2 more arbitrary elements. You can use bitmasks instead of a set if you aim for efficiency, but I guess you're not since you are using Python :) The complexity is optimal in the sense that it is linear in the output size.

Some "proof":

 $ python3 test.py | wc -l                               # number of output lines
 $ python3 test.py | sort | uniq | wc -l                 # unique output lines
 $ python3 test.py | grep "1"|grep "2"|grep "3"| wc -l   # lines with 1,2,3
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Thanks for the hint on the bitmasks, as I'll probably be writing this up in C at some point (I like playing with algorithms in python, as it is easier to think about there). I'm not convinced about the complexity comment though, as this is still "checking" a lot of sequences only to toss them out. For example it will try starting with (1,1,1,1) then realizes that won't work, then it rejects (1,1,1,2,1) and then (1,1,1,2,2), etc. So it does prune better than my initial slow solution, but it still feels like there should be a solution taking advantage of itertools.permutations(symbols). –  EdBrown Jan 28 '14 at 4:53
@EdBrown: Granted, it does a single recursion that is invalid, only to prune immediately in the if size < len(todo): return line. That's still O(1) per transition though ;) –  Niklas B. Jan 28 '14 at 4:56
Not quite O(1), since building that set might be more expensive. –  user2357112 Jan 28 '14 at 4:57
@user2357112: Yeah sure, but you can use bitmasks instead for O(1) set operations at least for reasonable symbol set sizes (I'm assuming here that the symbols set will be small enough for the algorithm to finish in some reasonable amount of time). The tuple prefix is never actually built, though –  Niklas B. Jan 28 '14 at 4:58
Maybe I'm not understanding. Let's say we're at size=1 and todo=(3,). This will try all N symbols to discover that only 3 works. That doesn't sound like an O(1) to me. That sounds like O(N). I would therefore put the complexity at O(N^N), similar to my example solution. Sorry if I'm slow to understand, what am I missing? –  EdBrown Jan 28 '14 at 5:05

You can do this by breaking the problem into two parts:

  1. Find every possible multiset of size L of N symbols which includes every symbol at least once.

  2. For each multiset, find all unique permutations.

For simplicity, let's suppose the N symbols are the integers in range(N). Then we can represent a multiset as a vector of length N whose values are non-negative integers summing to L. To restrict the multiset to include every symbol at least once, we require that the values in the vector all be strictly positive.

def msets(L, N):
  if L == N:
    yield (1,) * L
  elif N == 1:
    yield (L,)
  elif N > 0:
    for i in range(L - N + 1):
      for m in msets(L - i - 1, N - 1):
        yield (i + 1,) + m

Unfortunately, itertools.permutations does not produce unique iterations of lists with repeating elements. If we were writing this in C++, we could use std::next_permutation, which does produce unique iterations. There is a sample implementation (in C++, but it's straightforward to convert it to Python) on the linked page.

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I might be missing something, but why is len(list(msets(5,3))) = 6? –  Niklas B. Jan 28 '14 at 5:32
@Niklas: What would you expect it to be? There are six possible multisets of length 5 of the elements (0,1,2) which contain each element at least once. –  rici Jan 28 '14 at 5:34
Ah, I thought you're producing the permutations as well. Nevermind :) –  Niklas B. Jan 28 '14 at 5:35
@NiklasB.:it's a bit late here; I think the C++ code is sufficiently clear for an algorithm question, but I could write the python equivalent in the morning. –  rici Jan 28 '14 at 5:36
BTW, your function is essentially (tuple(xrange(N)) + y for y in itertools.combinations_with_replacement(xrange(N), L - N)) –  Niklas B. Jan 28 '14 at 5:47

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