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I have a set of items, from which I want to select DISSIMILAR tuples (more on the definition of dissimilar touples later). The set could contain potentially several thousand items, although typically, it would contain only a few hundreds.

I am trying to write a generic algorithm that will allow me to select N items to form an N-tuple, from the original set. The new set of selected N-tuples should be DISSIMILAR.

A N-tuple A is said to be DISSIMILAR to another N-tuple B if and only if:

  • Every pair (2-tuple) that occurs in A DOES NOT appear in B

Note: For this algorithm, A 2-tuple (pair) is considered SIMILAR/IDENTICAL if it contains the same elements, i.e. (x,y) is considered the same as (y,x).

This is a (possible variation on the) classic Urn Problem. A trivial (pseudocode) implementation of this algorithm would be something along the lines of

def fetch_unique_tuples(original_set, tuple_size):
    while True:
        # randomly select [tuple_size] items from the set to create first set
        # create a key or hash from the N elements and store in a set
        # store selected N-tuple in a container
        if end_condition_met:
            break

I don't think this is the most efficient way of doing this - and though I am no algorithm theorist, I suspect that the time for this algorithm to run is NOT O(n) - in fact, its probably more likely to be O(n!). I am wondering if there is a more efficient way of implementing such an algo, and preferably, reducing the time to O(n).

Actually, as Mark Byers pointed out there is a second variable m, which is the size of the number of elements being selected. This (i.e. m) will typically be between 2 and 5.

Regarding examples, here would be a typical (albeit shortened) example:

original_list = ['CAGG', 'CTTC', 'ACCT', 'TGCA', 'CCTG', 'CAAA', 'TGCC', 'ACTT', 'TAAT', 'CTTG', 'CGGC', 'GGCC', 'TCCT', 'ATCC', 'ACAG', 'TGAA', 'TTTG', 'ACAA', 'TGTC', 'TGGA', 'CTGC', 'GCTC', 'AGGA', 'TGCT', 'GCGC', 'GCGG', 'AAAG', 'GCTG', 'GCCG', 'ACCA', 'CTCC', 'CACG', 'CATA', 'GGGA', 'CGAG', 'CCCC', 'GGTG', 'AAGT', 'CCAC', 'AACA', 'AATA', 'CGAC', 'GGAA', 'TACC', 'AGTT', 'GTGG', 'CGCA', 'GGGG', 'GAGA', 'AGCC', 'ACCG', 'CCAT', 'AGAC', 'GGGT', 'CAGC', 'GATG', 'TTCG']


# Select 3-tuples from the original list should produce a list (or set) similar to:

    [('CAGG', 'CTTC', 'ACCT')
     ('CAGG', 'TGCA', 'CCTG')
     ('CAGG', 'CAAA', 'TGCC')
     ('CAGG', 'ACTT', 'ACCT')
     ('CAGG', 'CTTG', 'CGGC')
     ....
     ('CTTC', 'TGCA', 'CAAA')
    ]

[[Edit]]

Actually, in constructing the example output, I have realized that the earlier definition I gave for UNIQUENESS was incorrect. I have updated my definition and have introduced a new metric of DISSIMILARITY instead, as a result of this finding.

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Could you provide an example? –  Rik Poggi Apr 6 '12 at 10:44
    
You have defined one variable n but here are two variables here: the number of elements in the set, and the number of unique tuples you wish to find. The algorithm's performance may depend on both of these variables. –  Mark Byers Apr 6 '12 at 10:47
    
@MarkByers: Thanks for pointing that out. There is indeed another dimension m - the number of variables. m is typically in the range of between two and five - so perhaps, not too much a factor considering the potential size of n. –  Homunculus Reticulli Apr 6 '12 at 10:50
    
Is it a requirement that the result be a random selection? –  Vaughn Cato Apr 6 '12 at 13:20
    
@VaughnCato: No, the requirement is that the result consists of DISSIMILAR N-tuples (assuming we selecting N elements at a time). I have provided the definition for DISSIMILARITY (a boolean metric) above. –  Homunculus Reticulli Apr 6 '12 at 16:53

3 Answers 3

up vote 1 down vote accepted

I tried another approach--combinations of combinations. It seems to work pretty swiftly:

def fetch_unique_tuples(original_set, tuple_size):
    from itertools import combinations

    good = []
    used = []
    for i in combinations(original_set,tuple_size):
        lst = list([tuple(sorted(j)) for j in combinations(i,2)])
        if not any(l in used for l in lst):
            used.extend(lst)
            good.append(tuple(sorted(i)))
    return sorted(good)

elements = ['CAGG', 'CTTC', 'ACCT', 'TGCA', 'CCTG', 'CAAA', 'TGCC', 'ACTT', 'TAAT', 'CTTG', 'CGGC', 'GGCC', 'TCCT', 'ATCC', 'ACAG', 'TGAA', 'TTTG', 'ACAA', 'TGTC', 'TGGA', 'CTGC', 'GCTC', 'AGGA', 'TGCT', 'GCGC', 'GCGG', 'AAAG', 'GCTG', 'GCCG', 'ACCA', 'CTCC', 'CACG', 'CATA', 'GGGA', 'CGAG', 'CCCC', 'GGTG', 'AAGT', 'CCAC', 'AACA', 'AATA', 'CGAC', 'GGAA', 'TACC', 'AGTT', 'GTGG', 'CGCA', 'GGGG', 'GAGA', 'AGCC', 'ACCG', 'CCAT', 'AGAC', 'GGGT', 'CAGC', 'GATG', 'TTCG']
uniques = fetch_unique_tuples(elements, 3)
print len(uniques)

Easily converted into a generator if you're willing to lose the capability of len().

edit: added additional sorted() to make all tuples and ultimate list alpha.

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+1 for the code snippet. I'm amazed at the difference in speed. Trying to understand where the speed improvement is coming from (not very familiar with itertools) –  Homunculus Reticulli Apr 6 '12 at 21:05
    
Read my latest comment on luke's solution; its probably less the tools than sheer count of iterations. –  hexparrot Apr 6 '12 at 22:32

This is a trivial implementation of the algorithm. I'm not a theorist either but I love algorithms. I think this simple implementation is O(n^m) where m is the dimensions + something for the combinations, which should be less than O(n!).

def combine(elements,n=3):
    from itertools import combinations,product,ifilter

    hashes=[]
    combs=[]
    for p in combinations(elements,n):
        if len(set(p)) == 3 and not any(i in hashes for i in [sorted(i) for i in combinations(p,2)]):
            combs.append(p)
            hashes.extend([sorted(i) for i in combinations(p,2)])
    return combs

elements = ['CAGG', 'CTTC', 'ACCT', 'TGCA', 'CCTG', 'CAAA', 'TGCC', 'ACTT', 'TAAT', 'CTTG', 'CGGC', 'GGCC', 'TCCT', 'ATCC', 'ACAG', 'TGAA', 'TTTG', 'ACAA', 'TGTC', 'TGGA', 'CTGC', 'GCTC', 'AGGA', 'TGCT', 'GCGC', 'GCGG', 'AAAG', 'GCTG', 'GCCG', 'ACCA', 'CTCC', 'CACG', 'CATA', 'GGGA', 'CGAG', 'CCCC', 'GGTG', 'AAGT', 'CCAC', 'AACA', 'AATA', 'CGAC', 'GGAA', 'TACC', 'AGTT', 'GTGG', 'CGCA', 'GGGG', 'GAGA', 'AGCC', 'ACCG', 'CCAT', 'AGAC', 'GGGT', 'CAGC', 'GATG', 'TTCG']
print combine(elements)
share|improve this answer
    
Thanks for giving it a go. However, the solution you propose is not quite right. If you recall, the definition of DISSIMILAR was that NO 2-tuple (pair) should be identical between two selected N-tuples [remember (x,y) <=> (y,x)]. The code above selects tuples like [('CAGG', 'CTTC', 'ACCT'), ('CAGG', 'CTTC', 'TGCA'), ... ]. These are not DISSIMILAR because the pair ('CAGG', 'CTTC') is common to more than one of the selected 3-tuples. –  Homunculus Reticulli Apr 6 '12 at 16:50
    
oh ok, I didn't get it. I'll think about it and come back with a new solution. –  luke14free Apr 6 '12 at 16:55
    
it's pretty slow but it should work now –  luke14free Apr 6 '12 at 17:18
    
+1 for the effort. Yes, it is a bit slow - but at least, it seems to be working. I'll worry about 'optimizing' later. Need to run a few checks to make sure its working as expected. –  Homunculus Reticulli Apr 6 '12 at 21:00
    
run it on pypy to make it go a bit faster. –  luke14free Apr 6 '12 at 21:03

Assuming you mean that the set of M N-tuples must be pairwise dissimilar, it seems like using a graph to keep track of 'forbidden' pairs is the way to go.

import random
def select_tuples(original, N, M):
  used = {}
  first = random.sample(original, N)
  updateUsed(used, first)
  answer = [first]
  for i in xrange(M):
    notFound = True
    while notFound:
      remaining = set(original)
      thisTuple = []
      for j in xrange(N):
        if not remaining:
          break
        candidate = random.choice(remaining)
        remaining.remove(candidate)
        for adjacent in used[candidate]:
          remaining.remove(adjacent)
      else:
        notFound = False
    answer.append(thisTuple)
    updateUsed(used, thisTuple)
  return answer

def updateUsed(used, selected):
  for x in selected:
    if x not in used:
      used[x] = []
    for y in selected:
      if y != x:
        used[x].append(y)

This is something like O(MN^2) I think. I doubt you'll be able to do much better than that as for each of the M tuples you're introducing N*(N-1)/2 forbidden pairs which you can't use any more.

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