Sign up ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

I'm trying to solve a problem on TopCoder. Basically what I need is algorithms for the following:

Let S = [1, 2, ..., n] be a sequence. Let m be less than n.

1) Find all subsequences of S of size m (which is easy - n^m).

2) Find all subsequences of S of size m where the elements are in nondecreasing order.

3) Find all subsequences of S of size m where the elements are not allowed to be repeated (which is also easy - (n!)/((n-m)!).

4) Find all subsequences of S of size m where the elements are in nondecreasing order and are not allowed to be repeated.

Still trying to find formula for parts 2 and 4. A little bit of help will be appreciated.

Thanks in advance.


Original problem:

share|improve this question
I'm confused about the use of the term "set" here. Sets tend to be unordered and to contain individual elements at most once, so I don't understand what question 2, 3 and 4 even mean. –  Gian Mar 21 '13 at 10:07
hmmm, my fault "set" in this problem is considered by the following properties: 1) [1, 2, 3] and [2, 1, 3] are different "sets" 2) [1, 1, 1] is a "set". bonus for the proper name of "set" :) –  Kudayar Pirimbaev Mar 21 '13 at 10:11
if you get 2) you get 4) by the intersection of 2) and 3) –  Tony Morris Mar 21 '13 at 10:12
Oh. Those are probably just sequences, in that case. –  Gian Mar 21 '13 at 10:12
Your example suggest that S contains all the integers from 1..n for some n. Is that intentional or accidental ? –  High Performance Mark Mar 21 '13 at 10:14

1 Answer 1

to solve 4), note that w/o repetitions 'non-decreasing' means 'increasing'. partition the set of all sequences of length m built from S without repeating elements into equivalence classes defined by the set of elements occurring in the subsequence. within each equivalence class, there is exactly one increasing sequence (elements ordered by <). the size of each equivalence class is the number of permutations of the elements. the number of 4)-sequences therefore is (n!)/((n-m)! * m!) = n \choose m.

ad 2), model the sequence as a sequence of occurrence counts (including 0 for non-inclusion) for all elements in S. this can be written as a sequence of pairs (s_i, k_i), i=1..n; s_i \in S, k_i \in IN, \foreach p,q in {1..n}, p!=q: s_p != s_q of length exactly n. 'non-decreasing' implies a unique permissible ordering of the sequence given by arranging the elements according to increasing s_i. thus the only degree of freedom is the occurrence count which must obey the constraint of summing to m: sum_{i=1..n} k_i = m.

this problem is equivalent to partitions with (particular) restrictions and counting lattice paths. i don't think there is a closed formula for the number of n-tuples from IN^n meeting this condition.

however, there is a standard algorithm to enumerate all possibilities, eg. here

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.