I need to calculate the LZ-complexity of a binary string. The LZ-complexity is the number of differencet substrings encountered as the stream is viewed from begining to the end. As an example:

s = 1001111011000010

Marking in the different substrings the sequence complexity c(s) = 6: s = 1 / 0 / 01 / 1110 / 1100 / 0010 /

can someone guide me to find a simple solution for that? I am sure there should be some very straight-forward implementations for this well-known problem, but I have difficulty finding them. Can it be done simply done with constructing a suffix tree or something similar. If yes, exactly how? and what should I do?

anyone knows of any c/c++ source code to accomplish the task?

thanks in advance.

to clarify the construction of the tree suggested in the answers. Does the tree looks like this?

       /   \
      o     o
     / \   / \
    o   o o   o
       /     /
      o     o

Below is a quick example of how to compute LZ-Complexity using a tree. For convenience - mine; not yours - this code implements a fixed-sized pre-allocated tree, and is a prime example of why void* pointers are ugly to use and difficult to maintain. Hand this code in as is, and your lecturer is likely to shoot you in the face :)

#include <stdlib.h>
#include <stdio.h>

int LZComplexity(char *p_binarySequence, int p_maxTreeNodes)
 void **patternTree;
 void **currentNode;
 void **nextFreeNode;
 int nodeCount;
 int sequenceIndex;
 int currentDigit;

 nodeCount = 0;
 patternTree = malloc(sizeof(void*) * (p_maxTreeNodes << 1));
 currentNode = patternTree;
 nextFreeNode = patternTree + (sizeof(void*) << 1);
 currentNode[0] = NULL;
 currentNode[1] = NULL;
 sequenceIndex = 0;

 while (p_binarySequence[sequenceIndex])
  currentDigit = p_binarySequence[sequenceIndex] - 48;
  if (NULL == currentNode[currentDigit])
   currentNode[currentDigit] = nextFreeNode;
   nextFreeNode[0] = NULL;
   nextFreeNode[1] = NULL;
   nextFreeNode += (sizeof(void*) << 1);
   currentNode = patternTree;
   currentNode = currentNode[currentDigit];

 return nodeCount;

int main(int argc, char *argv[])
 printf("%u\n", LZComplexity("10100101001011101011", 1000));
 return 0;
  • Thanks Taliadon for taking the time to write the code, well I personally have no problem with void pointers! ;) to me your code looks quite ok! :D but was just wondering that for example I wrote should I get the LZ-complexity as 6 or 8?! your code and a manual construction of the tree suggests 8 but I have read that it should be 6, any comments on that? – Arash Mar 1 '11 at 15:06
  • if you have compilation errors just make two simple type casts form (void*) to (void **) and that should work! – Arash Mar 1 '11 at 15:14

1 0 01 11 10 110 00 010
Complexity of sequence is 8 because the partitions are 8 not 6 - 1/0/01/11/10/110/00/010

  • well the LZ complexity of the string is not really calculated as you pointed out. It's different and for the above example it's 6 not 8 :-) – Arash Oct 6 '11 at 18:58
  • below is slightly modified code for catering open sequence i.e. sequences with not distinct last LZ pattern... it solved my problem to calculate LZ complexity according to paper On Lempel-Ziv Complexity of Sequences Ali Do˘ganaksoy1,2,4 and Faruk G¨olo˘glu2,3 – Sanchit Gupta Oct 16 '11 at 6:56
  • int flag; while (p_binarySequence[sequenceIndex]) { currentDigit = p_binarySequence[sequenceIndex] - 48; if (NULL == currentNode[currentDigit]) { currentNode[currentDigit] = nextFreeNode; nextFreeNode[0] = NULL; nextFreeNode[1] = NULL; nextFreeNode += (sizeof(void*) << 1); currentNode = patternTree; nodeCount++; flag=0; } else { currentNode = currentNode[currentDigit]; flag=1; } sequenceIndex++; } free(patternTree); if(flag==0) return nodeCount; else return nodeCount+1; } – Sanchit Gupta Oct 16 '11 at 6:57
  • @Arash I read this paper and got LZ complexity 8 :) "On Lempel-Ziv Complexity of Sequences" Ali Do˘ganaksoy1,2,4 and Faruk G¨olo˘glu2,3 – Sanchit Gupta Oct 16 '11 at 6:59

@Arash and @Sanchit Gupta: You might've got confused between LZ76 complexity and LZ78 complexity. The one Arash is refering to is LZ76 complexity and the other one is LZ78 complexity. You can refer to section-3 of the paper "Estimating the Entropy Rate of Spike Trains via Lempel-Ziv Complexity".

Create a binary tree where left is 0 and right is 1. For each bit, try to find the sequence in the tree. If it's there, concatenate the next bit, rinse, repeat. If it's not there, add it to the tree and continue. LZ Complexity is the total number of paths in the tree (not just # leaf nodes).

By the way, is this homework?

  • Thanks Justin for your clarification. I am still not sure if I got it right or not, but for the example I have mention in the question, if I construct the tree I end up with 8 paths ( total number of nodes in the tree minus one, the root) Is it right? I was expecting to get 6 as the answer, as I have just read (am not sure) that the LZ-Complexity should be 6 in this example! Still not clear for me how they have calculated that! – Arash Mar 1 '11 at 14:54
  • 1
    and btw, this is not my homework! ;) I need this for a very strange purpose, to be more specific, I want this to find the regularity of the patterns in the data communication between two cooperating functions in an application!!! pretty weird na? :) – Arash Mar 1 '11 at 14:57

This should do the trick in Python (from: Kaspar, F. Schuster, H. Easily calculable measure for the complexity of spatiotemporal patterns. Physical Review A, vol 36, n. 2, p 842.)


def lz_complexity(s):
    i, k, l = 0, 1, 1
    k_max = 1
    n = len(s) - 1
    c = 1
    while True:
        if s[i + k - 1] == s[l + k - 1]:
            k = k + 1
            if l + k >= n - 1:
                c = c + 1
            if k > k_max:
               k_max = k
            i = i + 1
            if i == l:
                c = c + 1
                l = l + k_max
                if l + 1 > n:
                    i = 0
                    k = 1
                    k_max = 1
                k = 1
    return c

def main():
    lz = lz_complexity('1001111011000010')
    assert lz == 6 
    print lz

if __name__ == '__main__':


This may be relevant for you. It is parallel implementation of an algorithm LZMP that computes the LZ-complexity in CUDA and runs on nVidia GPU.


  • 1
    could add as comment – jjj Mar 21 '17 at 8:31

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