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I ve got two matrices W2 and hiddenLayer and i want to proceed the multiplication of those. W2 size's 12x50 and hiddenLayer size's 50x1. The proper code for the above calculation:

 for(int h=0; h<50; h++){
      for(int k=0; k<12; k++){
        outputLayer += W2[k][h]*HiddenLayer[h];
      }
}

or i ve got to put at first k-for??

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1  
Maybe outputLayer[k] or something like that. Perhaps you should switch the loops around; test both versions and profile. –  Kerrek SB Feb 20 '12 at 22:14
    
Yeah i had to switch for. –  Fere Res Feb 20 '12 at 22:18
    
The implication wasn't that you had to, but rather that one of the two orderings may be much faster than the other. You just have to try. –  Kerrek SB Feb 20 '12 at 22:21

1 Answer 1

up vote 2 down vote accepted

Matrix multiplication is defined as:

C = AB ⇔ Ci,j = Σk=1..n Ai,k Bk,j for i,j = 1...n (in case of square matrices).

Thus outputLayer is a vector. Since HiddenLayer is a vector too, this isn't really a matrix multiplication but a matrix vector multiplication, which simplifies the formula above:

b = Ax ⇔ bi = Σk=1..m Ai,k xk for i = 1...n (A is an n x m matrix).

So all in all your code should be something like

for(int row = 0; row < 12; row++){
    outputLayer[row] = 0;
    for(int column = 0;  column < 50; column++){    
        outputLayer[row] += W2[row][column]*HiddenLayer[column];
      }
}
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Correct. But I'd also add one point. In the most general case multiplication of matrices contains 3 loops (in this case 2 loops, since one of the matrixes is actually a vector). Those 3 loops don't have to be nested in the order you've suggested, actually there are 6 varinats of how to order them. Since the matrix rows are usually consequent in memory, choosing the correct loop ordering utilizes the CPU cache more efficiently. One may multiply matrixes several times faster by reordering those loops. Of course this is relevant for large matrixes. –  valdo Feb 20 '12 at 22:49
    
@valdo: This is true, however I wanted to keep the answer as simple as possible for OP. If you know that a specific matrix is always on the right hand side, you can even transpose the matrix and use C[i][j] += A[i][k] * B[j][k]. There are many ways to speed up matrix-matrix-multiplications, but the asymptotic runtime is always O(n^(2,807)) (using Strassen's algorithm) or O(n^3) (using sequential multiplication and addition). Feel free to edit the answer if you want to :). –  Zeta Feb 20 '12 at 22:59
    
ok got it thank you guys! –  Fere Res Feb 20 '12 at 23:07

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