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By default, MATLAB's sort function deals with ties/repeated elements by preserving the order of the elements, that is

>> [srt,idx] = sort([1 0 1])

srt =

    0     1     1


idx =

    2     1     3

Note that the two elements with value 1 in the input arbitrarily get assigned index 2 and 3, respectively. idx = [3 1 2], however, would be an equally valid sort.

I would like a function [srt,all_idx] = sort_ties(in) that explicitly returns all possible values for idx that are consistent with the sorted output. Of course this would only happen in the case of ties or repeated elements, and all_idx would be dimension nPossibleSorts x length(in).

I got started on a recursive algorithm for doing this, but quickly realized that things were getting out of hand and someone must have solved this before! Any suggestions?

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up vote 2 down vote accepted

I had a similar idea to what R. M. suggested. However, this solution is generalized to handle any number of repeated elements in the input vector. The code first sorts the input (using the function SORT), then loops over each unique value to generate all the permutations of the indices for that value (using the function PERMS), storing the results in a cell array. Then these index permutations for each individual value are combined into the total number of permutations for the sorted index by replicating them appropriately with the functions KRON and REPMAT:

function [srt,all_idx] = sort_ties(in,varargin)

  [srt,idx] = sort(in,varargin{:});
  uniqueValues = srt(logical([1 diff(srt)]));
  nValues = numel(uniqueValues);
  if nValues == numel(srt)
    all_idx = idx;
    return
  end

  permCell = cell(1,nValues);
  for iValue = 1:nValues
    valueIndex = idx(srt == uniqueValues(iValue));
    if numel(valueIndex) == 1
      permCell{iValue} = valueIndex;
    else
      permCell{iValue} = perms(valueIndex);
    end
  end
  nPerms = cellfun('size',permCell,1);

  for iValue = 1:nValues
    N = prod(nPerms(1:iValue-1));
    M = prod(nPerms(iValue+1:end));
    permCell{iValue} = repmat(kron(permCell{iValue},ones(N,1)),M,1);
  end
  all_idx = [permCell{:}];

end

And here are some sample results:

>> [srt,all_idx] = sort_ties([0 2 1 2 2 1])

srt =

     0     1     1     2     2     2

all_idx =

     1     6     3     5     4     2
     1     3     6     5     4     2
     1     6     3     5     2     4
     1     3     6     5     2     4
     1     6     3     4     5     2
     1     3     6     4     5     2
     1     6     3     4     2     5
     1     3     6     4     2     5
     1     6     3     2     4     5
     1     3     6     2     4     5
     1     6     3     2     5     4
     1     3     6     2     5     4
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1  
nice, it took me a moment to figure out how kron and repmat did the right thing here, but it's a satisfying solution. for maximum generality it would be nice to have 'ascend' and 'descend' options (not specified in the question but a freebie in my solution :-)) – Matt Mizumi Mar 21 '11 at 17:03
    
@Matt: You're right, the extra sorting options would be nice. I've updated my answer accordingly. – gnovice Mar 21 '11 at 17:39

Consider the example A=[1,2,3,2,5,6,2]. You want to find the indices where 2 occurs, and get all possible permutations of those indices.

For the first step, use unique in combination with histc to find the repeated element and the indices where it occurs.

uniqA=unique(A);
B=histc(A,uniqA);

You get B=[1 3 1 1 1]. Now you know which value in uniqA is repeated and how many times. To get the indices,

repeatIndices=find(A==uniqA(B==max(B))); 

which gives the indices as [2, 4, 7]. Lastly, for all possible permutations of these indices, use the perms function.

perms(repeatIndices)
ans =

 7     4     2
 7     2     4
 4     7     2
 4     2     7
 2     4     7
 2     7     4

I believe this does what you wanted. You can write a wrapper function around all this so that you have something compact like out=sort_ties(in). You probably should include a conditional around the repeatIndices line, so that if B is all ones, you don't proceed any further (i.e., there are no ties).

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1  
Thanks for the ideas! It seems this approach leaves you with some work to do though: the possible permutations still need to be incorporated in the complete indices (with the non-repeated elements), and additionally, there could be a case with multiple duplicate elements (e.g. [5 2 2 1 1]). On the plus side, this approach doesn't generate duplicates before removing them later, like my solution. – Matt Mizumi Mar 20 '11 at 17:04
1  
Incorporating this into the complete index is trivial. From the example, you know that the repeated indices [2, 4, 7]. The original index is simply indxOriginal=1:7; in this case (or if you use sort, the index returned by sort). So the multiple options can be simply accessed by doing indexOriginal(repeatIndices)=tiePerms(i,:), where tiePerms is the output of perms from above and i is the permutation that you want. Extending this to sets of duplicates is also straightforward, by checking to see how many elements in B are greater than 1. sum(B>1) should tell you how many sets. – abcd Mar 20 '11 at 20:23

Here is a possible solution I believe to be correct, but it's somewhat inefficient because of the duplicates it generates initially. It's pretty neat otherwise, but I still suspect it can be done better.

function [srt,idx] = tie_sort(in,order)

L = length(in);
[srt,idx] = sort(in,order);

for j = 1:L-1 % for each position in sorted array, look for repeats following it

  for k = j+1:L

    % if repeat found, add possible permutations to the list of possible sorts
    if srt(j) == srt(k)

       swapped = 1:L; swapped(j) = k; swapped(k) = j;
       add_idx = idx(:,swapped);

       idx = cat(1,idx,add_idx);
       idx = unique(idx,'rows'); % remove identical copies

    else % because already sorted, know don't have to keep looking

       break;

    end

  end

end
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