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I have a large, dense matrix A, and I aim to find the solution to the linear system Ax=b using an iterative method (in MATLAB was the plan using its built in GMRES). For more than 10,000 rows, this is too much for my computer to store in memory, but I know that the entries in A are constructed by two known vectors x and y of length N and the entries satisfy: A(i,j) = .5*(x[i]-x[j])^2+([y[i]-y[j])^2 * log(x[i]-x[j])^2+([y[i]-y[j]^2).

MATLAB's GMRES command accepts as input a function call that can compute the matrix vector product A*x, which allows me to handle larger matrices than I can store in memory. To write the matrix-vecotr product function, I first tried this in matlab by going row by row and using some vectorization, but I avoid spawning the entire array A (since it would be too large). This was fairly slow unfortnately in my application for GMRES. My plan was to write a mex file for MATLAB to, which is in C, and ideally should be significantly faster than the matlab code. I'm rather new to C, so this went rather poorly and my naive attempt at writing the code in C was slower than my partially vectorized attempt in Matlab.

#include <math.h>
#include "mex.h"
void Aproduct(double *x, double *ctrs_x, double *ctrs_y, double *b, mwSize n)
    mwSize i;
    mwSize j;
    double val;
    for (i=0; i<n; i++) {
        for (j=0; j<i; j++) {
            val = pow(ctrs_x[i]-ctrs_x[j],2)+pow(ctrs_y[i]-ctrs_y[j],2);

            b[i] = b[i] + .5* val * log(val) * x[j];
        for (j=i+1; j<n; j++) {
            val = pow(ctrs_x[i]-ctrs_x[j],2)+pow(ctrs_y[i]-ctrs_y[j],2);

            b[i] = b[i] + .5* val * log(val) * x[j];

The above is the computational portion of the code for the matlab mex file (which is slightly modified C, if I understand correctly). Please note that I skip the case i=j, since in that case the variable val will be a 0*log(0), which should be interpreted as 0 for me, so I just skip it.

Is there a more efficient or faster way to write this? When I call this C function via the mex file in matlab, it is quite slow, slower even than the matlab method I used. This surprises me since I suspected that C code should be much faster than matlab.

The alternative matlab method which is partially vectorized that I am comparing it with is

function Ax = Aprod(x,ctrs)
n = length(x);
Ax = zeros(n,1);
for j=1:(n-3)
    v = .5*((ctrs(j,1)-ctrs(:,1)).^2+(ctrs(j,2)-ctrs(:,2)).^2).*log((ctrs(j,1)-ctrs(:,1)).^2+(ctrs(j,2)-ctrs(:,2)).^2);

    Ax(j) = dot(v,x(1:n-3);

(the n-3 is because there is actually 3 extra components, but they are dealt with separately,so I excluded that code). This is partly vectorized and only needs one for loop, so it makes some sense that it is faster. However, I was hoping I could go even faster with C+mex file.

Any suggestions or help would be greatly appreciated! Thanks!

EDIT: I should be more clear. I am open to any faster method that can help me use GMRES to invert this matrix that I am interested in, which requires a faster way of doing the matrix vector product without explicitly loading the array into memory. Thanks!

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The reason that your C code is significant slower is because MatLab uses much more elaborate algorithm than your naive one, and because they optimize it to the last bit using their intimate knowledge about CPU cache, SSE instructions and other low level stuff. –  Siyuan Ren Nov 1 '13 at 2:49
I know that the direct computation of Ax would be faster in matlab than anything I could do, but that is not what I am interested in. Since I am unable to load all of A into memory, I cannot directly compute Ax, so I must use some sort of looping mechanism. Any ideas on better ways than how I'm doing it now, for either the C code I attempted or the matlab code I posted? Thanks! –  user35959 Nov 1 '13 at 3:23
I see the challenge you are facing now: Generate the matrix on the fly during A*x computation since you can't keep A in memory. Your MATLAB code seams reasonable, except you should store x(1:n-3) in a variable so you don't have to keep pulling it out. In your C code, I would suggest not using pow for a simple square. pow(x,2.0) is slower than x*x, if I recall correctly. You could also do b[i] += ..., but I'm not sure if that will be any faster. Also, since the purpose of the two j loops is just to avoid j=i you could combine the loops and follow with b[i] -= ..., i=j. –  chappjc Nov 1 '13 at 5:03

1 Answer 1

If you have Parallel Computing Toolbox and MATLAB Distributed Computing Server, you can solve large dense linear systems using backslash directly. (If you don't have a cluster available to you, you might like to use Amazon EC2 machines). Like so: http://www.mathworks.co.uk/help/distcomp/examples/benchmarking-a-b.html

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