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I have written programs in C++, Python and Java for matrix multiplication and tested their speed for multiplying two 2000 x 2000 matrices (see post). The standard ikj-implentation - which is in enter image description here - took:

  • C++: 15 seconds (Source)
  • Python: 6 minutes 13 seconds (Source)

Now I have implemented the Strassen algorithm for matrix multiplication - which is in enter image description here - in Python and C++ as it was on wikipedia. These are the times I've got:

  • C++: 45 minutes (Source)
  • Python: Killed after 10 hours (Source)

Why is Strassen matrix multiplication so much slower than standard matrix multiplication?


Ideas:

  • Some cache effects
  • Implementation:
    • error (the resulting 2000 x 2000 matrix is correct)
    • null-multiplication (shouldn't be that important for 2000 x 2000 -> 2048 x 2048)

This is especially astonishing, as it seems to contradict the experiences of others:


edit: The reason why Strassen matrix multiplication was slower in my case, were:

  • I made it fully recursive (see tam)
  • I had two functions strassen and strassenRecursive. The first one resized the matrix to a power of two, if required and called the second one. But strassenRecursive didn't recursively call itself, but strassen.
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3  
Haven't checked it, but there are a lot of new vectors being allocated. I imagine the memory allocation times are what is killing it. –  Vaughn Cato Jul 15 '12 at 21:33
    
Voo's answer basically covers the memory allocation issue as well, since stopping the recursion sooner will reduce the number of allocations. BTW: On my computer I found a good value to be around 250 for the cutoff. –  Vaughn Cato Jul 15 '12 at 22:07
    
By the way, your posted source can't be experimented with by anybody, because you don't post the data file. This means that nobody can do anything except speculate. –  Puppy Jul 15 '12 at 22:13
1  
@DeadMG: actually the data file is there, just up a couple of levels in the Testing directory. –  Vaughn Cato Jul 15 '12 at 23:02

3 Answers 3

up vote 12 down vote accepted

The basic problem is that you're recursing down to a leaf size of 1 with your strassen implementaiton. Strassen's algorithm has a better Big O complexity, but constants do matter in reality, which means in reality you're better off with a standard n^3 matrix multiplication for smaller problem sizes.

So to greatly improve your program instead of doing:

if (tam == 1) {
        C[0][0] = A[0][0] * B[0][0];
        return;
    }

use if (tam == LEAF_SIZE) // iterative solution here. LEAF_SIZE should be a constant that you have to experimentally determine for your given architecture. Depending on the architecture it may be larger or smaller - there are architectures where the constant factors for strassen are so large that it's basically always worse than a simpler n^3 implementation for sensible matrix sizes. It all depends.

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+1 Beat me just as I was about to starting writing it up. –  Mysticial Jul 15 '12 at 21:31
    
@Mysticial Ah it's better so, your time is better spent answering questions that mere humans will find hard to answer ;) –  Voo Jul 16 '12 at 1:14
    
You were right. I've added LEAF_SIZE in this script: github.com/MartinThoma/matrix-multiplication/blob/master/… . For Leaf size 10 the time dropped to 66.50 seconds, for 20 to 29.96 seconds and for 50 to 18.80 seconds. How can I better (more structured, automatically) test for good values of LEAF_SIZE than changing the value in the code, recompiling, testing and trying other ones? Do you know an easy possibility to graph it? (Should I ask another question, as this seems to go in another direction than my previous one?) –  moose Jul 16 '12 at 12:20
    
@moose Well make the program take the leaf size as an input parameter. Personally I do the following then: For every leaf size run the program ten times (more is better, but 10 is somewhat accurate) and store all values in a text file (64.txt, 128.txtetc) - that's a shell script job obviously. Afterwards use a simple script (I like python) that takes the runtimes, throws away the 2 fastest/slowest and computes the average of the rest and outputs that data as CSV. And a CSV has the great advantage that excel/openoffice and co can all read it and generate nice graphs with two clicks. –  Voo Jul 16 '12 at 12:30
2  
Thanks for your help. I've just plotted the results: cloud.github.com/downloads/MartinThoma/matrix-multiplication/… –  moose Jul 16 '12 at 15:01

Well, "arithmetic operations" are not the only things that count. It's not like everything else is free.

My naive guess would be that all this memory-allocating and copying beats the gain from having fewer arithmetic operations...

Memory access, in particular, can be quite expensive when it gets out of the cache, In comparison, arihmetic operations could be considered free :-)

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1  
..and, in case of C++, an optimization could probably be using placement new on a sufficiently large block of memory allocated beforehand. –  Desmond Hume Jul 15 '12 at 21:45
1  
Agree, I think that all of the memory mechanics going on here are a big source of slowdown. –  Puppy Jul 15 '12 at 22:15

Although the Strassen algorithm has a smaller Big O notation, in order to take advantage of this you would need to multiply to matrcies that are too big to solve on most standard machines and even super computers.

Think of it this way

one problem is x^3 , the other is X^1.6734 + 8x^(1/2) +x .....

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Not really. You generally get a cutoff value in the hundreds on modern machines for Strassen. And really, 600x600 matrizes are small in this day and age. Heck problems with 50k x 50k matrizes aren't noteworthy today (9gb of memory? there are desktops with 16gb+ around) –  Voo Jul 15 '12 at 22:02
    
You may be referring to the Coppersmith-Winograd algorithm: en.wikipedia.org/wiki/Coppersmith%E2%80%93Winograd_algorithm –  ysap Nov 1 '12 at 23:46

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