I wound up understanding the supernodal representation from a nice comment in the supernodal-to-simplicial helper function in t_cholmod_change_factor.c
. I paraphrase the comment and add some details below:
A supernodal Cholesky factorisation is represented as a collection of supernodal blocks. The entries of a supernodal block are arranged in column-major order like this 6x4 supernode:
t - - - (row s[pi[snode+0]])
t t - - (row s[pi[snode+1]])
t t t - (row s[pi[snode+2]])
t t t t (row s[pi[snode+3]])
r r r r (row s[pi[snode+4]])
r r r r (row s[pi[snode+5]])
- There are unused entries (indicated by the hyphens) in order to make the matrix rectangular.
- The column indices are consecutive.
- The first
ncols
row indices are those same consecutive column indices. Later row indices can refer to any row below the t
triangle.
- The
super
member has one entry for each supernode; it refers to the first column represented by the supernode.
- The
pi
member has one entry for each supernode; it refers to the first index in the s
member where you can look up the row numbers.
- The
px
member has one entry for each supernode; it refers to the first index in the x
member where the entries are stored. Again, this is not packed storage.
The following code for multiplication by a cholmod_factor *L
appears to work (I only care about int
indices and double-precision real entries):
cholmod_dense *mul_L(cholmod_factor *L, cholmod_dense *d) {
int rows = d->nrow, cols = d->ncol;
cholmod_dense *ans = cholmod_allocate_dense(rows, cols, rows,
CHOLMOD_REAL, &comm);
memset(ans->x, 0, 8 * rows * cols);
FOR(i, L->nsuper) {
int *sup = (int *)L->super;
int *pi = (int *)L->pi;
int *px = (int *)L->px;
double *x = (double *)L->x;
int *ss = (int *)L->s;
int r0 = pi[i], r1 = pi[i+1], nrow = r1 - r0;
int c0 = sup[i], c1 = sup[i+1], ncol = c1 - c0;
int px0 = px[i];
/* TODO: Use BLAS instead. */
for (int j = 0; j < ncol; j++) {
for (int k = j; k < nrow; k++) {
for (int l = 0; l < cols; l++) {
((double *)ans->x)[l * rows + ss[r0 + k]] +=
x[px0 + k + j * nrow] * ((double *)d->x)[l*rows+c0 + j];
}
}
}
}
return ans;
}