# Multiplying two matrices in Java

I am currently developing a class to represent matrices, it represents any general mxn matrix. I have worked out addition and scalar multiplication but I am struggling to develop the multiplication of two matrices. The data of the matrix is held in a 2D array of doubles.

The method looks a little bit like this:

``````   public Matrix multiply(Matrix A) {
////code
}
``````

It will return the product matrix. This is multiplication on the right. So, if I called A.multiply(B) then it would return the matrix AB, with B on the right.

I don't yet need to worry about checking whether the multiplication is defined on the given matrices, I can assume that I will be given matrices of the correct dimensions.

Does anyone know of an easy algorithm, possibly even in pseudocode to carry out the multiplication process?

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have you tried anything? or have you asked uncle Google? – ogzd Mar 31 '13 at 19:57
I tried Google, but couldn't find anything using things I was familiar with. I'm not concerned with efficiency, just something which is easy to program really. I myself tried using a for loop inside a for loop but had no success. I'm having a little bit of trouble figuring it out really. I think it's tiredness, I'll get there eventually :p But some tips from the net always help. – Jarred Morris Mar 31 '13 at 20:01

Mathematically the Product of Matrices A (l x m) and B (m x n) is defined as a Matrix C (l x n) consisting of the elements:

``````        m
c_i_k = ∑  a_i_k * b_k_i
k=1
``````

So if you're not too much up for speed you might be happy with the straight forward O(n^3) implementation:

``````  for (int i=0; i<l; ++i)
for (int j=0; j<n; ++j)
for (int k=0; k<m; ++k)
c[i][k] += a[i][k] * b[k][j]
``````

If instead you're up for speed you might want to check for ohther alternatives like Strassen algorithm (see: Strassen algorithm).

Nevertheless be warned - especially if you're multiplying small matrices on modern processor archtitectures speed heavily depends on matrix data and multiplication order arranged in a way to make best use of in cache lines.

I strongly doubt there will be any chance to influence this factor from withing a vm, so I'm not sure if this is to be taken into consideration.

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Ah thank you very much :) This works. The efficiency doesn't matter so O(n^3) complexity is just fine. All I need is for the algorithm to carry out the process correctly, it won't matter how long it takes so this is good. Thanks again :) – Jarred Morris Mar 31 '13 at 20:54

Java. Matrix multiplication.

Here is the "code to carry out the multiplication process". Tested with matrices of different size.

``````public class Matrix {

/**
* Matrix multiplication method.
* @param m1 Multiplicand
* @param m2 Multiplier
* @return Product
*/
public static double[][] multiplyByMatrix(double[][] m1, double[][] m2) {
int m1ColLength = m1[0].length; // m1 columns length
int m2RowLength = m2.length;    // m2 rows length
if(m1ColLength != m2RowLength) return null; // matrix multiplication is not possible
int mRRowLength = m1.length;    // m result rows length
int mRColLength = m2[0].length; // m result columns length
double[][] mResult = new double[mRRowLength][mRColLength];
for(int i = 0; i < mRRowLength; i++) {         // rows from m1
for(int j = 0; j < mRColLength; j++) {     // columns from m2
for(int k = 0; k < m1ColLength; k++) { // columns from m1
mResult[i][j] += m1[i][k] * m2[k][j];
}
}
}
return mResult;
}

public static String toString(double[][] m) {
String result = "";
for(int i = 0; i < m.length; i++) {
for(int j = 0; j < m[i].length; j++) {
result += String.format("%11.2f", m[i][j]);
}
result += "\n";
}
return result;
}

public static void main(String[] args) {
// #1
double[][] multiplicand = new double[][] {
{3, -1, 2},
{2,  0, 1},
{1,  2, 1}
};
double[][] multiplier = new double[][] {
{2, -1, 1},
{0, -2, 3},
{3,  0, 1}
};
System.out.println("#1\n" + toString(multiplyByMatrix(multiplicand, multiplier)));
// #2
multiplicand = new double[][] {
{1, 2, 0},
{-1, 3, 1},
{2, -2, 1}
};
multiplier = new double[][] {
{2},
{-1},
{1}
};
System.out.println("#2\n" + toString(multiplyByMatrix(multiplicand, multiplier)));
// #3
multiplicand = new double[][] {
{1, 2, -1},
{0,  1, 0}
};
multiplier = new double[][] {
{1, 1, 0, 0},
{0, 2, 1, 1},
{1, 1, 2, 2}
};
System.out.println("#3\n" + toString(multiplyByMatrix(multiplicand, multiplier)));
}
}
``````

Output:

``````#1
12.00      -1.00       2.00
7.00      -2.00       3.00
5.00      -5.00       8.00

#2
0.00
-4.00
7.00

#3
0.00       4.00       0.00       0.00
0.00       2.00       1.00       1.00
``````
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