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A string is called a square string if it can be obtained by concatenating two copies of the same string. For example, "abab", "aa" are square strings, while "aaa", "abba" are not. Given a string, how many subsequences of the string are square strings? A subsequence of a string can be obtained by deleting zero or more characters from it, and maintaining the relative order of the remaining characters.The subsequence need not be unique.

eg string 'aaa' will have 3 square subsequences

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9  
What's your question? Other than, "please do my homework for me"? –  Greg Hewgill Apr 3 '12 at 19:46
1  
If this is a homework question, please label it as homework and say what you've done so far to approach the problem. (If this is not a homework question, I apologize.) Thanks! –  ninjagecko Apr 3 '12 at 19:47
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I came across this question in one of those programming challenges...i found it interesting but was unable to solve it.. –  Avinash Apr 3 '12 at 20:16
    
This problem was originally stated on interviewstreet.com with more examples –  Colonel Panic Jul 2 '12 at 10:45
    
Importantly, the original challenge asks for an efficient solution 'the string S may have as many as 200 characters' –  Colonel Panic Jul 2 '12 at 10:53

3 Answers 3

up vote 6 down vote accepted

Observation 1: The length of a square string is always even.

Observation 2: Every square subsequence of length 2n (n>1) is a combination of two shorter subsequences: one of length 2(n-1) and one of length 2.

First, find the subsequences of length two, i.e. the characters that occur twice or more in the string. We'll call these pairs. For each subsequence of length 2 (1 pair), remember the position of the first and last character in the sequence.

Now, suppose we have all subsequences of length 2(n-1), and we know for each where in the string the first and second part begins and ends. We can find sequences of length 2n by using observation 2:

Go through all the subsequences of length 2(n-1), and find all pairs where the first item in the pair lies between the last position of the first part and the first position of the second part, and the second item lies after the last position of the second part. Every time such a pair is found, combine it with the current subsequence of length 2(n-2) into a new subsequence of length 2n.

Repeat the last step until no more new square subsequences are found.

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It seems like your method might work...the second observation really seems to simplyfy the problem...thanks a lot man –  Avinash Apr 6 '12 at 18:40
    
For others' information, this technique - where you solve a problem by combining solutions to smaller cases of the same problem - is called dynamic programming. It's like recursion run in reverse. –  Colonel Panic Jul 4 '12 at 19:22
    
Sorry..Could you please explain "for each subsequence of length 1"? Is that each char in the string? Thx. –  Louis_PIG Aug 6 '12 at 0:15
    
Seems you have updated "of length 1" to "of length 2(1 pair)". Thanks. –  Louis_PIG Aug 15 '12 at 6:09

Psuedocode:

total_square_substrings <- 0

# Find every substring
for i in 1:length_of_string {

    # Odd strings are not square, continue
    if((length_of_string-i) % 2 == 1)
        continue;

    for j in 1:length_of_string {
        # Remove i characters from the string, starting at character j
        substring <- substr(string,0,j) + substr(string,j+1,length_of_string);

        # Test all ways of splitting the substring into even, whole parts (e.g. if string is of length 15, this splits by 3 and 5)
        SubstringTest: for(k in 2:(length_of_substring/2))
        {           
            if(length_of_substring % k > 0)
                continue;

            first_partition <- substring[1:partition_size];

            # Test every partition against the first for equality, if all pass, we have a square substring
            for(m in 2:k)
            {           
                if(first_partition != substring[(k-1)*partition_size:k*partition_size])
                    continue SubstringTest;
            }

            # We have a square substring, move on to next substring
            total_square_substrings++;
            break SubstringTest;
        }
    }
}
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A subsequence need to be continuous. 'abacb' contains the square subsequence 'abab'. Your algorithm would miss that. –  Jeffrey Sax Apr 5 '12 at 23:28
    
we are looking for square sunsequence....your algorithm seems to be searching for substrings and why did you assume a substring can have only one square subsequence –  Avinash Apr 6 '12 at 18:56

Here's a solution using LINQ:

IEnumerable<string> input = new[] {"a","a","a"};

// The next line assumes the existence of a "PowerSet" method for IEnumerable<T>.
// I'll provide my implementation of the method later.
IEnumerable<IEnumerable<string>> powerSet = input.PowerSet();

// Once you have the power set of all subsequences, select only those that are "square".
IEnumerable<IEnumerable<string>> squares = powerSet.Where(x => x.Take(x.Count()/2).SequenceEqual(x.Skip(x.Count()/2)));

Console.WriteLine(squares);

And here is my PowerSet extension method, along with a "Choose" extension method that is required by PowerSet:

public static class CombinatorialExtensionMethods
{
    public static IEnumerable<IEnumerable<T>> Choose<T>(this IEnumerable<T> seq, int k)
    {
        // Use "Select With Index" to create IEnumerable<anonymous type containing sequence values with indexes>
        var indexedSeq = seq.Select((Value, Index) => new {Value, Index});

        // Create k copies of the sequence to join
        var sequences = Enumerable.Repeat(indexedSeq,k);

        // Create IEnumerable<TypeOf(indexedSeq)> containing one empty sequence
        /// To create an empty sequence of the same anonymous type as indexedSeq, allow the compiler to infer the type from a query expression
        var emptySequence =
            from item in indexedSeq
            where false
            select item;
        var emptyProduct = Enumerable.Repeat(emptySequence,1);

        // Select "Choose" permutations, using Index to order the items
        var indexChoose = sequences.Aggregate( 
            emptyProduct,
            (accumulator, sequence) =>  
            from accseq in accumulator  
            from item in sequence
            where accseq.All(accitem => accitem.Index < item.Index)
            select accseq.Concat(new[] { item }));

        // Select just the Value from each permutation
        IEnumerable<IEnumerable<T>> result = 
            from item in indexChoose
            select item.Select((x) => x.Value);

        return result;
    }

    public static IEnumerable<IEnumerable<T>> PowerSet<T>(this IEnumerable<T> seq)
    {
        IEnumerable<IEnumerable<T>> result = new[] { Enumerable.Empty<T>() };
        for (int i=1; i<=seq.Count(); i++)
        {
            result = result.Concat(seq.Choose<T>(i));
        }
        return result;
    }
}
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