We say that a sequence of numbers x(1),x(2),...,x(k) is zigzag if no three of its consecutive elements create a nonincreasing or nondecreasing sequence. More precisely, for all i=1,2,...,k-2 either

x(i) >( x(i+1),x(i-1) )  


x(i) < ( x(i+1) , x(i-1))

I have two sequences of numbers a(1),a(2),...,a(n) and b(1),b(2),...,b(m). The problem is to compute the length of their longest common zigzag subsequence. In other words, you're going to delete elements from the two sequences so that they are equal, and so that they're a zigzag sequence. If the minimum number of elements required to do this is k then your answer is m+n-2k.

Note. sequences with length two and one are trivially zigzag

Now i tried writing a memoized recursive solution for the same using the below state variables

i= current position of sequence 1.
j= current position of sequence 2.
last= last taken number in the zigzag sequence currently being considered.
direction = current requirement of the number i.e. should it be greater than previous,less or same;  

i call the below function with


Here Integer.MIN_VALUE is used a sentinel value denoting no numbers are taken yet in the sequence. The function is given below:

static int magic(int i, int j, int last, int direction) {

  if (hm.containsKey(i + " " + j + " " + last + " " + direction))
   return hm.get(i + " " + j + " " + last + " " + direction);

  if (i == seq1.length || j == seq2.length) {
   return 0;


  int take_both = 0, leave_both = 0, leave1 = 0, leave2 = 0;
  if (seq1[i] == seq2[j] && last == Integer.MIN_VALUE)
   take_both = 1 + magic(i + 1, j + 1, seq1[i], direction); // this is the first digit  hence direction is 0.
  else if (seq1[i] == seq2[j] && (direction == 0 || direction == 1 && seq1[i] > last || direction == -1 && seq1[i] < last))
   take_both = 1 + magic(i + 1, j + 1, seq1[i], last != seq1[i] ? (last > seq1[i] ? 1 : -1) : 2);

  leave_both = magic(i + 1, j + 1, last, direction);

  leave1 = magic(i + 1, j, last, direction);
  leave2 = magic(i, j + 1, last, direction);
  int ans;

  ans = Math.max(Math.max(Math.max(take_both, leave_both), leave1), leave2);
  hm.put(i + " " + j + " " + last + " " + direction, ans);
  return ans;


Now the above code is working for as much test cases i could make, but the complexity is high. How do i reduce the time complexity,can i eliminate some state variables here? is there a efficient way to do this?

  • Can you give an example of the common sequence? Do you mean common by where they occur or by the values? 1,2,1,2,1,2,1 / 3,2,3,2,3,2... what's the correct result? – Carlos Feb 11 '16 at 10:14

First let's reduce the number of states: Let f(i, j, d) be the length of the longest common zig-zag sequence starting at position i in the first string and position j in the second string and starting with direction d (up or down).

We have the recurrence

f(i, j, up) >= MAX(i' > i, j' > j : f(i', j', up))
if s1[i] = s2[j]:
    f(i, j, up) >= MAX(i' > i, j' > j, s1[i'] > x : f(i', j', down))

an similar for the down direction. Solving this in a straightforward way will lead to a runtime of something like O(n4 · W) where W is the range of integers in the array. W is not polynomially bounded, so we definitely want to get rid of this factor, and ideally a couple of n factors along the way.

To solve the first part, you have to find the maximum f(i', j', up) with i' > i and j' > j. This is a standard standard 2-d orthogonal range maximum query.

For the second case, you need to find the maximum (i', j', down) with i' > i, j' > j and s1[i'] > s1[i]. That is a range maximum query in the rectangle (i, ∞) x (j, ∞) x (s1[i], ∞).

Now having 3 dimensions here looks scary. However, if we process the states in say, decreasing order of i, then we can get rid of one dimension. We thus reduced the problem to a range query in the rectangle (j, ∞) x (s1[i], ∞). Coordinate compression gets the dimension of values down to O(n).

You can use a 2-d data structure such as a range tree or binary-indexed tree to solve both kinds of range queries in O(log2 n). The total runtime will be O(n2 · log2 n).

You can get rid of one log factor using fractional cascading, but that is associated with a high constant factor. The runtime is then only one log-factor short of that for finding the longest common subsequence, which seems like a lower-bound for our problem.

  • Exuse my ignorance but can you explain the recurrence ,more elaboratately ? How did you reduce it to three variables ? – A. Sam Feb 16 '16 at 18:10
  • @Sam The important realization is that if you force the elements i and j to actually be part of the sequences, you know the last value from them, and you don't need to represent it explicitly in the state – Niklas B. Feb 16 '16 at 19:12

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