/* ========================================================================== */ /* === MatrixOps/cholmod_submatrix ========================================== */ /* ========================================================================== */ /* ----------------------------------------------------------------------------- * CHOLMOD/MatrixOps Module. Copyright (C) 2005-2006, Timothy A. Davis * The CHOLMOD/MatrixOps Module is licensed under Version 2.0 of the GNU * General Public License. See gpl.txt for a text of the license. * CHOLMOD is also available under other licenses; contact authors for details. * http://www.cise.ufl.edu/research/sparse * -------------------------------------------------------------------------- */ /* C = A (rset,cset), where C becomes length(rset)-by-length(cset) in dimension. * rset and cset can have duplicate entries. A and C must be unsymmetric. C * is packed. If the sorted flag is TRUE on input, or rset is sorted and A is * sorted, then C is sorted; otherwise C is unsorted. * * A NULL rset or cset means "[ ]" in MATLAB notation. * If the length of rset or cset is negative, it denotes ":" in MATLAB notation. * * For permuting a matrix, this routine is an alternative to cholmod_ptranspose * (which permutes and transposes a matrix and can work on symmetric matrices). * * The time taken by this routine is O(A->nrow) if the Common workspace needs * to be initialized, plus O(C->nrow + C->ncol + nnz (A (:,cset))). Thus, if C * is small and the workspace is not initialized, the time can be dominated by * the call to cholmod_allocate_work. However, once the workspace is * allocated, subsequent calls take less time. * * workspace: Iwork (max (A->nrow + length (rset), length (cset))). * allocates temporary copy of C if it is to be returned sorted. * * Future work: A common case occurs where A has sorted columns, and rset is in * the form lo:hi in MATLAB notation. This routine could exploit that case * to run even faster when the matrix is sorted, particularly when lo is small. * * Only pattern and real matrices are supported. Complex and zomplex matrices * are supported only when "values" is FALSE. */ #ifndef NMATRIXOPS #include "cholmod_internal.h" #include "cholmod_matrixops.h" /* ========================================================================== */ /* === check_subset ========================================================= */ /* ========================================================================== */ /* Check the rset or cset, and return TRUE if valid, FALSE if invalid */ static int check_subset (Int *set, Int len, Int n) { Int k ; if (set == NULL) { return (TRUE) ; } for (k = 0 ; k < len ; k++) { if (set [k] < 0 || set [k] >= n) { return (FALSE) ; } } return (TRUE) ; } /* ========================================================================== */ /* === cholmod_submatrix ==================================================== */ /* ========================================================================== */ cholmod_sparse *CHOLMOD(submatrix) ( /* ---- input ---- */ cholmod_sparse *A, /* matrix to subreference */ Int *rset, /* set of row indices, duplicates OK */ UF_long rsize, /* size of rset, or -1 for ":" */ Int *cset, /* set of column indices, duplicates OK */ UF_long csize, /* size of cset, or -1 for ":" */ int values, /* if TRUE compute the numerical values of C */ int sorted, /* if TRUE then return C with sorted columns */ /* --------------- */ cholmod_common *Common ) { double aij = 0 ; double *Ax, *Cx ; Int *Ap, *Ai, *Anz, *Ci, *Cp, *Head, *Rlen, *Rnext, *Iwork ; cholmod_sparse *C ; Int packed, ancol, anrow, cnrow, cncol, nnz, i, j, csorted, ilast, p, pend, pdest, ci, cj, head, nr, nc ; size_t s ; int ok = TRUE ; /* ---------------------------------------------------------------------- */ /* check inputs */ /* ---------------------------------------------------------------------- */ RETURN_IF_NULL_COMMON (NULL) ; RETURN_IF_NULL (A, NULL) ; values = (values && (A->xtype != CHOLMOD_PATTERN)) ; RETURN_IF_XTYPE_INVALID (A, CHOLMOD_PATTERN, values ? CHOLMOD_REAL : CHOLMOD_ZOMPLEX, NULL) ; if (A->stype != 0) { /* A must be unsymmetric */ ERROR (CHOLMOD_INVALID, "symmetric upper or lower case not supported") ; return (NULL) ; } Common->status = CHOLMOD_OK ; ASSERT (CHOLMOD(dump_sparse) (A, "A", Common) >= 0) ; /* ---------------------------------------------------------------------- */ /* allocate workspace */ /* ---------------------------------------------------------------------- */ ancol = A->ncol ; anrow = A->nrow ; nr = rsize ; nc = csize ; if (rset == NULL) { /* nr = 0 denotes rset = [ ], nr < 0 denotes rset = 0:anrow-1 */ nr = (nr < 0) ? (-1) : 0 ; } if (cset == NULL) { /* nr = 0 denotes cset = [ ], nr < 0 denotes cset = 0:ancol-1 */ nc = (nc < 0) ? (-1) : 0 ; } cnrow = (nr < 0) ? anrow : nr ; /* negative rset means rset = 0:anrow-1 */ cncol = (nc < 0) ? ancol : nc ; /* negative cset means cset = 0:ancol-1 */ if (nr < 0 && nc < 0) { /* ------------------------------------------------------------------ */ /* C = A (:,:), use cholmod_copy instead */ /* ------------------------------------------------------------------ */ /* workspace: Iwork (max (C->nrow,C->ncol)) */ PRINT1 (("submatrix C = A (:,:)\n")) ; C = CHOLMOD(copy) (A, 0, values, Common) ; if (Common->status < CHOLMOD_OK) { /* out of memory */ return (NULL) ; } return (C) ; } PRINT1 (("submatrix nr "ID" nc "ID" Cnrow "ID" Cncol "ID"" " Anrow "ID" Ancol "ID"\n", nr, nc, cnrow, cncol, anrow, ancol)) ; /* s = MAX3 (anrow+MAX(0,nr), cncol, cnrow) ; */ s = CHOLMOD(add_size_t) (anrow, MAX (0,nr), &ok) ; if (!ok) { ERROR (CHOLMOD_TOO_LARGE, "problem too large") ; return (NULL) ; } s = MAX3 (s, cncol, cnrow) ; CHOLMOD(allocate_work) (anrow, s, 0, Common) ; if (Common->status < CHOLMOD_OK) { /* out of memory */ return (NULL) ; } ASSERT (CHOLMOD(dump_work) (TRUE, TRUE, 0, Common)) ; /* ---------------------------------------------------------------------- */ /* get inputs */ /* ---------------------------------------------------------------------- */ Ap = A->p ; Anz = A->nz ; Ai = A->i ; Ax = A->x ; packed = A->packed ; /* ---------------------------------------------------------------------- */ /* get workspace */ /* ---------------------------------------------------------------------- */ Head = Common->Head ; /* size anrow */ Iwork = Common->Iwork ; Rlen = Iwork ; /* size anrow (i/i/l) */ Rnext = Iwork + anrow ; /* size nr (i/i/l), not used if nr < 0 */ /* ---------------------------------------------------------------------- */ /* construct inverse of rset and compute nnz (C) */ /* ---------------------------------------------------------------------- */ PRINT1 (("nr "ID" nc "ID"\n", nr, nc)) ; PRINT1 (("anrow "ID" ancol "ID"\n", anrow, ancol)) ; PRINT1 (("cnrow "ID" cncol "ID"\n", cnrow, cncol)) ; DEBUG (for (i = 0 ; i < nr ; i++) PRINT2 (("rset ["ID"] = "ID"\n", i, rset [i]))); DEBUG (for (i = 0 ; i < nc ; i++) PRINT2 (("cset ["ID"] = "ID"\n", i, cset [i]))); /* C is sorted if A and rset are sorted, or if C has one row or less */ csorted = A->sorted || (cnrow <= 1) ; if (!check_subset (rset, nr, anrow)) { ERROR (CHOLMOD_INVALID, "invalid rset") ; return (NULL) ; } if (!check_subset (cset, nc, ancol)) { ERROR (CHOLMOD_INVALID, "invalid cset") ; return (NULL) ; } nnz = 0 ; if (nr < 0) { /* C = A (:,cset) where cset = [ ] or cset is not empty */ ASSERT (IMPLIES (cncol > 0, cset != NULL)) ; for (cj = 0 ; cj < cncol ; cj++) { /* construct column cj of C, which is column j of A */ j = cset [cj] ; nnz += (packed) ? (Ap [j+1] - Ap [j]) : MAX (0, Anz [j]) ; } } else { /* C = A (rset,cset), where rset is not empty but cset might be empty */ /* create link lists in reverse order to preserve natural order */ ilast = anrow ; for (ci = nr-1 ; ci >= 0 ; ci--) { /* row i of A becomes row ci of C; add ci to ith link list */ i = rset [ci] ; head = Head [i] ; Rlen [i] = (head == EMPTY) ? 1 : (Rlen [i] + 1) ; Rnext [ci] = head ; Head [i] = ci ; if (i > ilast) { /* row indices in columns of C will not be sorted */ csorted = FALSE ; } ilast = i ; } #ifndef NDEBUG for (i = 0 ; i < anrow ; i++) { Int k = 0 ; Int rlen = (Head [i] != EMPTY) ? Rlen [i] : -1 ; PRINT1 (("Row "ID" Rlen "ID": ", i, rlen)) ; for (ci = Head [i] ; ci != EMPTY ; ci = Rnext [ci]) { k++ ; PRINT2 ((""ID" ", ci)) ; } PRINT1 (("\n")) ; ASSERT (IMPLIES (Head [i] != EMPTY, k == Rlen [i])) ; } #endif /* count nonzeros in C */ for (cj = 0 ; cj < cncol ; cj++) { /* count rows in column cj of C, which is column j of A */ j = (nc < 0) ? cj : (cset [cj]) ; p = Ap [j] ; pend = (packed) ? (Ap [j+1]) : (p + Anz [j]) ; for ( ; p < pend ; p++) { /* row i of A becomes multiple rows (ci) of C */ i = Ai [p] ; ASSERT (i >= 0 && i < anrow) ; if (Head [i] != EMPTY) { nnz += Rlen [i] ; } } } } PRINT1 (("nnz (C) "ID"\n", nnz)) ; /* rset and cset are now valid */ DEBUG (CHOLMOD(dump_subset) (rset, rsize, anrow, "rset", Common)) ; DEBUG (CHOLMOD(dump_subset) (cset, csize, ancol, "cset", Common)) ; /* ---------------------------------------------------------------------- */ /* allocate C */ /* ---------------------------------------------------------------------- */ C = CHOLMOD(allocate_sparse) (cnrow, cncol, nnz, csorted, TRUE, 0, values ? A->xtype : CHOLMOD_PATTERN, Common) ; if (Common->status < CHOLMOD_OK) { /* out of memory */ for (i = 0 ; i < anrow ; i++) { Head [i] = EMPTY ; } ASSERT (CHOLMOD(dump_work) (TRUE, TRUE, 0, Common)) ; return (NULL) ; } Cp = C->p ; Ci = C->i ; Cx = C->x ; /* ---------------------------------------------------------------------- */ /* C = A (rset,cset) */ /* ---------------------------------------------------------------------- */ pdest = 0 ; if (nnz == 0) { /* C has no nonzeros */ for (cj = 0 ; cj <= cncol ; cj++) { Cp [cj] = 0 ; } } else if (nr < 0) { /* C = A (:,cset), where cset is not empty */ for (cj = 0 ; cj < cncol ; cj++) { /* construct column cj of C, which is column j of A */ PRINT1 (("construct cj = j = "ID"\n", cj)) ; j = cset [cj] ; Cp [cj] = pdest ; p = Ap [j] ; pend = (packed) ? (Ap [j+1]) : (p + Anz [j]) ; for ( ; p < pend ; p++) { Ci [pdest] = Ai [p] ; if (values) { Cx [pdest] = Ax [p] ; } pdest++ ; ASSERT (pdest <= nnz) ; } } } else { /* C = A (rset,cset), where rset is not empty but cset might be empty */ for (cj = 0 ; cj < cncol ; cj++) { /* construct column cj of C, which is column j of A */ PRINT1 (("construct cj = "ID"\n", cj)) ; j = (nc < 0) ? cj : (cset [cj]) ; PRINT1 (("cj = "ID"\n", j)) ; Cp [cj] = pdest ; p = Ap [j] ; pend = (packed) ? (Ap [j+1]) : (p + Anz [j]) ; for ( ; p < pend ; p++) { /* row (Ai [p]) of A becomes multiple rows (ci) of C */ PRINT2 (("i: "ID" becomes: ", Ai [p])) ; if (values) { aij = Ax [p] ; } for (ci = Head [Ai [p]] ; ci != EMPTY ; ci = Rnext [ci]) { PRINT3 ((""ID" ", ci)) ; Ci [pdest] = ci ; if (values) { Cx [pdest] = aij ; } pdest++ ; ASSERT (pdest <= nnz) ; } PRINT2 (("\n")) ; } } } Cp [cncol] = pdest ; ASSERT (nnz == pdest) ; /* ---------------------------------------------------------------------- */ /* clear workspace */ /* ---------------------------------------------------------------------- */ for (ci = 0 ; ci < nr ; ci++) { Head [rset [ci]] = EMPTY ; } ASSERT (CHOLMOD(dump_work) (TRUE, TRUE, 0, Common)) ; /* ---------------------------------------------------------------------- */ /* sort C, if requested */ /* ---------------------------------------------------------------------- */ ASSERT (CHOLMOD(dump_sparse) (C , "C before sort", Common) >= 0) ; if (sorted && !csorted) { /* workspace: Iwork (max (C->nrow,C->ncol)) */ if (!CHOLMOD(sort) (C, Common)) { /* out of memory */ CHOLMOD(free_sparse) (&C, Common) ; ASSERT (CHOLMOD(dump_work) (TRUE, TRUE, 0, Common)) ; return (NULL) ; } } /* ---------------------------------------------------------------------- */ /* return result */ /* ---------------------------------------------------------------------- */ ASSERT (CHOLMOD(dump_sparse) (C , "Final C", Common) >= 0) ; ASSERT (CHOLMOD(dump_work) (TRUE, TRUE, 0, Common)) ; return (C) ; } #endif