# Make efficient - A symmetric matrix multiplication with two vectors in c#

As per following the inital thread make efficient the copy of symmetric matrix in c-sharp from cMinor.

I would be quite interesting with some inputs in how to build a symmetric square matrix multiplication with one line vector and one column vector by using an array implementation of the matrix, instead of the classical

``````long s = 0;
List<double> columnVector = new List<double>(N);
List<double> lineVector = new List<double>(N);
//- init. vectors and symmetric square matrix m

for (int i=0; i < N; i++)
{
for(int j=0; j < N; j++){
s += lineVector[i] * columnVector[j] * m[i,j];
}
}
``````

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The line vector times symmetric matrix equals to the transpose of the matrix times the column vector. So only the column vector case needs to be considered.

Originally the `i`-th element of `y=A*x` is defined as

``````y[i] = SUM( A[i,j]*x[j], j=0..N-1 )
``````

but since `A` is symmetric, the sum be split into sums, one below the diagonal and the other above

``````y[i] = SUM( A[i,j]*x[j], j=0..i-1) + SUM( A[i,j]*x[j], j=i..N-1 )
``````

From the other posting the matrix index is

``````A[i,j] = A[i*N-i*(i+1)/2+j]  // j>=i
A[i,j] = A[j*N-j*(j+1)/2+i]  // j< i
``````

For a `N×N` symmetric matrix `A = new double[N*(N+1)/2];`

In `C#` code the above is:

``````int k;
for(int i=0; i<N; i++)
{
// start sum with zero
y[i]=0;
// below diagonal
k=i;
for(int j=0; j<=i-1; j++)
{
y[i]+=A[k]*x[j];
k+=N-j-1;
}
// above diagonal
k=i*N-i*(i+1)/2+i;
for(int j=i; j<=N-1; j++)
{
y[i]+=A[k]*x[j];
k++;
}
}
``````

Example for you to try:

``````| -7  -6  -5  -4  -3 | | -2 |   | 10 |
| -6  -2  -1   0   1 | | -1 |   | 16 |
| -5  -1   2   3   4 | |  0 | = | 22 |
| -4   0   3   5   6 | |  1 |   | 25 |
| -3   1   4   6   7 | |  7 |   | 25 |
``````

To get the quadratic form do a dot product with the multiplication result vector `x·A·y = Dot(x,A*y)`

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Thanks for this pretty detailed answer and for providing the code, I have learned a lot in few lines. – Sebastien Thuilliez May 24 '12 at 9:46
Just a small confirmation on my understanding. In this particular case using a square symmetric matrix we can consider both vector as column vectors (that we can name x & x'). Meaning that if I want to have multiplication result for both vectors, I can do it in one go by using for "below diagonal" code as y[i]+=A[k]*x[j]*x'[j]; and so on for "above diagonal". Am I correct ?! – Sebastien Thuilliez May 24 '12 at 9:55
Well you wouldn't consider both `x` and `x'` in the same operation. So the statement `y[i]+=A[k]*x[j]*x'[j]` is not valid. Maybe you need to include an example in the original posting on what you are trying to do. Typically you do something like `scalar = x'*A*x`. – ja72 May 24 '12 at 15:50
Consider also that the product of two symmetric matrices is not symmetric. – ja72 May 24 '12 at 18:28
Thanks for the update – Sebastien Thuilliez May 25 '12 at 6:59

You could make matrix multiplication pretty fast with unsafe code. I have blogged about it.

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Correct. If the goal is speed, unsafe is the way to go. If the object is reduced size, then the reduced element approach referenced in OP is the way to go. – ja72 May 23 '12 at 16:57
+1 for the unsafe approach and for the blog link. Thanks. – Sebastien Thuilliez May 24 '12 at 9:46

Making matrix multiplication as fast as possible is easy: Use a well-known library. Insane amounts of performance work has gone into such libraries. You cannot compete with that.

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