# Cholesky decomposition of large sparse matrices in Java

I want to do Cholesky decomposition of large sparse matrices in Java. Currently I'm using the Parallel Colt library class SparseDoubleCholeskyDecomposition but it's much slower than using my code I wrote in C for dense matrices which I use in java with JNI.

For example for 5570x5570 matrices with a non-zero density of 0.25% with SparseDoubleCholeskyDecomposition takes 26.6 seconds to factor and my own code for the same matrix using dense storage only takes 1.12 seconds. However, if I set the density to 0.025% then the colt library only takes 0.13 seconds.

I have also written my own sparse matrix Cholesky decomposition in C using compressed row storage and OpenMP and it's quite a bit faster than SparseDoubleCholeskyDecomposition as well but still slower than my algorithm using dense storage. I could probably optimize it further but in any case the Cholesky factors are dense so it neither solves the speed nor the storage problem.

But I want times in the milliseconds and I eventually need to scale to over 10000x10000 matrices so even my own dense code for dense matrices will become too slow and use too much memory.

I have reason to believe the Cholesky decomposition of sparse matrices can be done much faster and use less memory. Maybe I need a better Java BLAS library? Is there a library for Java which does Cholesky decomposition for sparse matrices efficiently? Maybe I'm not using Parallel Colt optimally?

``````import cern.colt.matrix.tdouble.algo.decomposition.SparseDoubleCholeskyDecomposition;
import cern.colt.matrix.tdouble.impl.*;
import java.util.Random;

public class Cholesky {
static SparseRCDoubleMatrix2D create_sparse(double[] a, int n, double r) {
SparseRCDoubleMatrix2D result = new SparseRCDoubleMatrix2D(n, n);
Random rand = new Random();
for(int i=0; i<n; i++) {
for(int j=i; j<n; j++) {
double c = rand.nextDouble();
double element = c<r ? rand.nextDouble() : 0;
a[i*n+j] = element;
a[j*n+i] = element;
if (element != 0) {
result.setQuick(i, j, element);
result.setQuick(j, i, element);
}
}
}
for(int i=0; i<n; i++) {
a[i * n + i] += n;
result.setQuick(i,i, result.getQuick(i,i) + n);
}
return result;
}

public static void main(String[] args) {
int n = 5570;
//int n = 2048;
double[] a = new double[n*n];
SparseRCDoubleMatrix2D sparseMatrix = create_sparse(a, n, 0.0025);

long startTime, endTime, duration;

startTime = System.nanoTime();
SparseDoubleCholeskyDecomposition sparseDoubleCholeskyDecomposition = new SparseDoubleCholeskyDecomposition(sparseMatrix, 0);
endTime = System.nanoTime();
duration = (endTime - startTime);
System.out.printf("colt time construct %.2f s\n", 1E-9*duration);
}
}
``````