Short answer: Don't use Boost's `LAPACK`

bindings, these were designed for dense matrices,
not sparse matrices, use `UMFPACK`

instead.

Long answer: `UMFPACK`

is one of the best libraries for solving Ax=b when A is large and sparse.

Below is sample code (based on `umfpack_simple.c`

) that generates a simple `A`

and `b`

and solves `Ax = b`

.

```
#include <stdlib.h>
#include <stdio.h>
#include "umfpack.h"
int *Ap;
int *Ai;
double *Ax;
double *b;
double *x;
/* Generates a sparse matrix problem:
A is n x n tridiagonal matrix
A(i,i-1) = -1;
A(i,i) = 3;
A(i,i+1) = -1;
*/
void generate_sparse_matrix_problem(int n){
int i; /* row index */
int nz; /* nonzero index */
int nnz = 2 + 3*(n-2) + 2; /* number of nonzeros*/
int *Ti; /* row indices */
int *Tj; /* col indices */
double *Tx; /* values */
/* Allocate memory for triplet form */
Ti = malloc(sizeof(int)*nnz);
Tj = malloc(sizeof(int)*nnz);
Tx = malloc(sizeof(double)*nnz);
/* Allocate memory for compressed sparse column form */
Ap = malloc(sizeof(int)*(n+1));
Ai = malloc(sizeof(int)*nnz);
Ax = malloc(sizeof(double)*nnz);
/* Allocate memory for rhs and solution vector */
x = malloc(sizeof(double)*n);
b = malloc(sizeof(double)*n);
/* Construct the matrix A*/
nz = 0;
for (i = 0; i < n; i++){
if (i > 0){
Ti[nz] = i;
Tj[nz] = i-1;
Tx[nz] = -1;
nz++;
}
Ti[nz] = i;
Tj[nz] = i;
Tx[nz] = 3;
nz++;
if (i < n-1){
Ti[nz] = i;
Tj[nz] = i+1;
Tx[nz] = -1;
nz++;
}
b[i] = 0;
}
b[0] = 21; b[1] = 1; b[2] = 17;
/* Convert Triplet to Compressed Sparse Column format */
(void) umfpack_di_triplet_to_col(n,n,nnz,Ti,Tj,Tx,Ap,Ai,Ax,NULL);
/* free triplet format */
free(Ti); free(Tj); free(Tx);
}
int main (void)
{
double *null = (double *) NULL ;
int i, n;
void *Symbolic, *Numeric ;
n = 500000;
generate_sparse_matrix_problem(n);
(void) umfpack_di_symbolic (n, n, Ap, Ai, Ax, &Symbolic, null, null);
(void) umfpack_di_numeric (Ap, Ai, Ax, Symbolic, &Numeric, null, null);
umfpack_di_free_symbolic (&Symbolic);
(void) umfpack_di_solve (UMFPACK_A, Ap, Ai, Ax, x, b, Numeric, null, null);
umfpack_di_free_numeric (&Numeric);
for (i = 0 ; i < 10 ; i++) printf ("x [%d] = %g\n", i, x [i]);
free(b); free(x); free(Ax); free(Ai); free(Ap);
return (0);
}
```

The function `generate_sparse_matrix_problem`

creates the matrix `A`

and the
right-hand side `b`

. The matrix is first constructed in triplet form. The
vectors Ti, Tj, and Tx fully describe A. Triplet form is easy to create but
efficient sparse matrix methods require Compressed Sparse Column format. Conversion
is performed with `umfpack_di_triplet_to_col`

.

A symbolic factorization is performed with `umfpack_di_symbolic`

. A sparse
LU decomposition of `A`

is performed with `umfpack_di_numeric`

.
The lower and upper triangular solves are performed with `umfpack_di_solve`

.

With `n`

as 500,000, on my machine, the entire program takes about a second to run.
Valgrind reports that 369,239,649 bytes (just a little over 352 MB) were allocated.

Note this page discusses Boost's support for sparse matrices in Triplet (Coordinate)
and Compressed format. If you like, you can write routines to convert these boost objects
to the simple arrays `UMFPACK`

requires as input.