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You may have heard about the well-known problem of finding the longest increasing subsequence. The optimal algorithm has O(n*log(n)) complexity.

I was thinking about problem of finding all increasing subsequences in given sequence. I have found solution for a problem where we need to find a number of increasing subsequences of length k, which has O(n*k*log(n)) complexity (where n is a length of a sequence).

Of course, this algorithm can be used for my problem, but then solution has O(n*k*log(n)*n) = O(n^2*k*log(n)) complexity, I suppose. I think, that there must be a better (I mean - faster) solution, but I don't know such yet.

If you know how to solve the problem of finding all increasing subsequences in given sequence in optimal time/complexity (in this case, optimal = better than O(n^2*k*log(n))), please let me know about that.

In the end: this problem is not a homework. There was mentioned on my lecture a problem of the longest increasing subsequence and I have started thinking about general idea of all increasing subsequences in given sequence.

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You should give an example. –  Colonel Panic Jun 10 at 14:03

4 Answers 4

I don't know if this is optimal - probably not, but here's a DP solution in O(n^2).

Let dp[i] = number of increasing subsequences with i as the last element

for i = 1 to n do
    dp[i] = 1
    for j = 1 to i - 1 do
        if input[j] < input[i] then
            dp[i] = dp[i] + dp[j] // we can just append input[i] to every subsequence ending with j

Then it's just a matter of summing all the entries in dp

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1  
Here's your code in Python: codepad.org/fbEyb8Mb –  J.F. Sebastian Jan 8 '11 at 23:33
    
@J.F. Sebastian - looks like it works for easily-verified input then! :). I was thinking of a formula based on the number of equal elements and inversions in the given array, but I haven't gotten far. That might be able to get it down to O(n log n). Perhaps more advanced data structures can get it down to that complexity too. –  IVlad Jan 8 '11 at 23:43
    
Elegant solution, thanks! –  Raj Jun 4 '11 at 16:32

You can compute the number of increasing subsequences in O(n log n) time as follows.

Recall the algorithm for the length of the longest increasing subsequence:

For each element, compute the predecessor element among previous elements, and add one to that length.

This algorithm runs naively in O(n^2) time, and runs in O(n log n) (or even better, in the case of integers), if you compute the predecessor using a data structure like a balanced binary search tree (BST) (or something more advanced like a van Emde Boas tree for integers).

To amend this algorithm for computing the number of sequences, store in the BST in each node the number of sequences ending at that element. When processing the next element in the list, you simply search for the predecessor, count the number of sequences ending at an element that is less than the element currently being processed (in O(log n) time), and store the result in the BST along with the current element. Finally, you sum the results for every element in the tree to get the result.

As a caveat, note that the number of increasing sequences could be very large, so that the arithmetic no longer takes O(1) time per operation. This needs to be taken into consideration.

Psuedocode:

ret = 0
T = empty_augmented_bst() // with an integer field in addition to the key
for x int X:

  // sum of auxiliary fields of keys less than x
  // computed in O(log n) time using augmented BSTs
  count = 1 + T.sum_less(x)

  T.insert(x, 1 + count) // sets x's auxiliary field to 1 + count
  ret += count // keep track of return value

return ret
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Wouldn't this only count longest increasing subsequences? In the O(n log n) algorithm for the LIS problem that you're describing, one can remove the inner loop of the classical algorithm with a query in a BST for a maximum value. If you sum these like you say, for each node / element you will only sum the number of longest increasing subsequences ending at that element. For example, for 1 2 3, you would only count 1, 1 2, 1 2 3. If this is somehow not the case, can you post an implementation or at least some pseudocode please? –  IVlad Jan 9 '11 at 0:26
    
@IVlad: 1: {1=>1}, 2: {1=>1, 2=>2}, 3: {1=>1, 2=>2, 3=>4}. For example, when encountering 3, there are two entry keys less than it (1 and 2), and the value for 3 is the values of these keys plus one (i.e. 1->3, 1->2->3, 2->3, 3). For us to do this efficiently we would also store at each node the sum of values under the subtree. –  Nabb Jan 9 '11 at 1:58
    
@Vlad: As long as you include in the count for each node, the singleton sequence consisting element itself, and sum over all of the elements at the end, it will work. The invariant we use is that each element stores the count of all subsequences, not necessarily maximal, that end at that node, which is just 1 + the number of sequences that end in a smaller number. The second operand of this sum is computed using augmented binary search trees to sum the auxiliary fields of the BST from elements that are smaller than the current element. I'll post some pseudocode shortly. –  jonderry Jan 10 '11 at 20:36
    
@jonderry do you know how to modify this algorithm to get only number of longest increasing sequences? –  Wojciech Kulik Apr 7 at 13:53
    
Yes, I think this should be possible if for each element you store the number of longest sequences ending in it. To compute this value for element i+1 given values for 0 through i, you need to binary search to find the length of the longest sequence ending in element i+1, and then perform another search in an augmented BST that stores the elements that terminate increasing sequences of that length, less 1 (the BST nodes are augmented with the number of increasing sequences of that length, and we use augmentation to facilitate computing the prefix sum in O(lg n) time). Hope this makes sense. –  jonderry Apr 9 at 19:43

I'm assuming without loss of generalization the input A[0..(n-1)] consists of all integers in {0, 1, ..., n-1}.

Let DP[i] = number of increasing subsequences ending in A[i].

We have the recurrence:

DP[i] = 1 + \sum_{j < i, A[j] < A[i]} DP[j]

To compute DP[i], we only need to compute DP[j] for all j where A[j] < A[i]. Therefore, we can compute the DP array in the ascending order of values of A. This leaves DP[k] = 0 for all k where A[k] > A[i].

The problem boils down to computing the sum DP[0] to DP[i-1]. Supposing we have already calculated DP[0] to DP[i-1], we can calculate DP[i] in O(log n) using a Fenwick tree.

The final answer is then DP[0] + DP[1] + ... DP[n-1]. The algorithm runs in O(n log n).

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Even though I am the editor, I am still not sure how to deal with the case where a value appear twice in the array... –  nhahtdh Jun 9 at 22:53

Java version as an example:

    int[] A = {1, 2, 0, 0, 0, 4};
    int[] dp = new int[A.length];

    for (int i = 0; i < A.length; i++) {
        dp[i] = 1;

        for (int j = 0; j <= i - 1; j++) {
            if (A[j] < A[i]) {
                dp[i] = dp[i] + dp[j];
            }
        }
    }
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