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Zigzag sequence is a sequence where every element is less or more than it's neighbours.

1 3 2 and 2 1 2 are zigzags, 1 2 3 and 1 2 2 are not.

With two numbers given n, k find out how many sequences of size n can be generated from numbers 1..k

Example: n = 3 k = 3 Answer: 10

121, 212, 131, 313, 232, 323, 132, 231, 312, 213 (no need to generate, just for clarity)


What's the efficient solution? The best I can get is to generate all permutations and test if they are zigzag, but it is O(n!).

I understand that I should use dynamic programming approach, but I don't know how to start.


Thanks to answers I came to this solution. Pleas, tell me if it could be done better.

import sys

ZAG = {}
ZIG = {}

def zag(n, i):
    result = 0

    for j in xrange(1, i):    
        if (n - 1, j) not in ZIG:
            ZIG[(n - 1, j)] = zig(n - 1, j)
        result += ZIG[(n - 1, j)]

    return result    

def zig(n, i):
    result = 0

    for j in xrange(i + 1, MAX_NUMBER + 1):
        if (n - 1, j) not in ZAG:
            ZAG[(n - 1, j)] = zag(n - 1, j)
        result += ZAG[(n - 1, j)]

    return result

def count(n): 
    if n == 1:
        return MAX_NUMBER

    result = 0

    for i in xrange(1, MAX_NUMBER + 1):
        ZIG[(1, i)] = 1
        ZAG[(1, i)] = 1

    for i in xrange(1, MAX_NUMBER + 1):
        result += 2*zag(n, i)

    return result

def main(argv):
    global MAX_NUMBER
    MAX_NUMBER = int(argv[1])
    print count(int(argv[0]))

if __name__ == "__main__":
    main(sys.argv[1:])
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What language are you trying to use? Most of the time you'll get more and more useful responses if you tag a language. –  Sconibulus Oct 8 '12 at 16:45
    
Thanks for hint. Python 2.7.3 –  Sam Davydov Oct 8 '12 at 17:21
    
possible duplicate: stackoverflow.com/questions/6914969/… –  Aman Deep Gautam Oct 17 '12 at 22:21

2 Answers 2

up vote 0 down vote accepted

Orders in whole sequence is given with an ordering of first two elements. There are two types of ordering: up-down-up-... and down-up-down-... There are same number of sequences of both ordering, since sequence of one ordering can be transformed in other order by exchanging each number x with k+1-x.

Let U_k(n) be number of sequences with first up order of length n. Let U_k(n, f) be number of sequences with first up order of length n and with first number f. Similar define D_k(n) and D_k(n, f).

Then number of sequences of length n (for n>1) is:

U_k(n) + D_k(n) = 2*U_k(n) = 2*( sum U_k(n, f) for f in 1 ... k ).

Same argument gives:

U_k(n, f) = sum D_k(n-1, s) for s = f+1 ... k
          = sum U_k(n-1, s) for s = 1 ... k-f
U_k(1, f) = 1

Edit:

Slightly simpler implementation. M(n,k) returns n'th row (from back), and C(n,k) counts number of sequences.

def M(n, k):
    if n == 1: return [1]*k
    m = M(n-1, k)
    return [sum(m[:i]) for i in xrange(k)][::-1]

def C(n, k):
    if n < 1: return 0
    if n == 1: return k
    return 2*sum(M(n,k))
share|improve this answer

If you generate the sequence through recursive calls to a Zig (values less than last number) and Zag (values greater than last number) iterating through the possibilities, it gets a little better, and you can make it better yet (calculation-wise, not memory-wise) by storing solved subproblems in a static table.

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