I came up with this algorithm for matrix multiplication. I read somewhere that matrix multiplication has a time complexity of o(n^2). But I think my this algorithm will give o(n^3). I don't know how to calculate time complexity of nested loops. So please correct me.

for i=1 to n
   for j=1 to n    
     for k=1 to n
         c[i][j] = c[i][j]+a[i][k]*b[k][j]
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    That b[i][k] looks wrong. I suspect you want something like c[i][j] + a[i][k] * b[k][j] on the RHS of the last line. – Mark Dickinson Dec 17 '11 at 18:04
  • no its correct. Here c[i][j] is the result matrix – zedai Dec 17 '11 at 18:06
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    Well, in that case you're definitely not doing matrix multiplication! Notice that for a given i, you're computing the same result in c[i][j] for each j, so in your output matrix c all the columns will be identical. You need to replace b[i][k] with b[k][j] in the last line. – Mark Dickinson Dec 17 '11 at 18:18

The naive algorithm, which is what you've got once you correct it as noted in comments, is O(n^3).

There do exist algorithms that reduce this somewhat, but you're not likely to find an O(n^2) implementation. I believe the question of the most efficient implementation is still open.

See this wikipedia article on Matrix Multiplication for more information.

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    It's actually proven that O(n^2) is not possible to achieve. – downhand Jul 4 '18 at 16:04
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    @downhand citation please? I've not encountered that result previously. I'd like to read the proof. – Ken Goss Dec 20 '18 at 16:16
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    @downhand I realize this post is from nearly a year ago, but I am very interested in seeing a proof. – Jordan Singer Apr 5 '19 at 18:45
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    The closest I could find is in the introduction of arxiv.org/abs/1204.1111 – Mr. White Apr 27 '19 at 12:28
  • What is n here ? – Arun Joshla May 12 '19 at 19:49

Using linear algebra, there exist algorithms that achieve better complexity than the naive O(n3). Solvay Strassen algorithm achieves a complexity of O(n2.807) by reducing the number of multiplications required for each 2x2 sub-matrix from 8 to 7.

The fastest known matrix multiplication algorithm is Coppersmith-Winograd algorithm with a complexity of O(n2.3737). Unless the matrix is huge, these algorithms do not result in a vast difference in computation time. In practice, it is easier and faster to use parallel algorithms for matrix multiplication.

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    According to Wikipedia, there's a matrix multiplication algorithm from 2014 that achieved O(n^2.3729) while the Coppersmith-Winograd algorithm was the fastest until 2010. – Garrett Oct 24 '14 at 5:23

The standard way of multiplying an m-by-n matrix by an n-by-p matrix has complexity O(mnp). If all of those are "n" to you, it's O(n^3), not O(n^2). EDIT: it will not be O(n^2) in the general case. But there are faster algorithms for particular types of matrices -- if you know more you may be able to do better.

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    This is false. There are speedups in the general case. – jwg Jun 8 '14 at 22:35
  • Strassen's algorithm? Sure. The OP asked for O(n^2) and that is not possible in general. That's really what I was getting at. – Sean Owen Jun 9 '14 at 11:38

In matrix multiplication there are 3 for loop, we are using since execution of each for loop requires time complexity O(n). So for three loops it becomes O(n^3)

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