/* This file creating by running f2c linpack. this version dated 08/14/78 cleve moler, university of new mexico, argonne national lab. Computes the inverse of a matrix given its factors and pivots calculated by PetscLINPACKgefa(). Performed in-place for an n by n dense matrix. Used by the sparse factorization routines in src/mat/impls/baij/seq */ #include PetscErrorCode PetscLINPACKgedi(MatScalar *a, PetscInt n, PetscInt *ipvt, MatScalar *work) { PetscInt i__2, kb, kp1, nm1, i, j, k, l, ll, kn, knp1, jn1; MatScalar *aa, *ax, *ay, tmp; MatScalar t; PetscFunctionBegin; --work; --ipvt; a -= n + 1; /* compute inverse(u) */ for (k = 1; k <= n; ++k) { kn = k * n; knp1 = kn + k; a[knp1] = 1.0 / a[knp1]; t = -a[knp1]; i__2 = k - 1; aa = &a[1 + kn]; for (ll = 0; ll < i__2; ll++) aa[ll] *= t; kp1 = k + 1; if (n < kp1) continue; ax = aa; for (j = kp1; j <= n; ++j) { jn1 = j * n; t = a[k + jn1]; a[k + jn1] = 0.; ay = &a[1 + jn1]; for (ll = 0; ll < k; ll++) ay[ll] += t * ax[ll]; } } /* form inverse(u)*inverse(l) */ nm1 = n - 1; if (nm1 < 1) PetscFunctionReturn(PETSC_SUCCESS); for (kb = 1; kb <= nm1; ++kb) { k = n - kb; kn = k * n; kp1 = k + 1; aa = a + kn; for (i = kp1; i <= n; ++i) { work[i] = aa[i]; aa[i] = 0.; } for (j = kp1; j <= n; ++j) { t = work[j]; ax = &a[j * n + 1]; ay = &a[kn + 1]; for (ll = 0; ll < n; ll++) ay[ll] += t * ax[ll]; } l = ipvt[k]; if (l != k) { ax = &a[kn + 1]; ay = &a[l * n + 1]; for (ll = 0; ll < n; ll++) { tmp = ax[ll]; ax[ll] = ay[ll]; ay[ll] = tmp; } } } PetscFunctionReturn(PETSC_SUCCESS); }