/*! @file cpivotgrowth.c

 * \brief Computes the reciprocal pivot growth factor

 *

 * 

 * -- SuperLU routine (version 2.0) --

 * Univ. of California Berkeley, Xerox Palo Alto Research Center,

 * and Lawrence Berkeley National Lab.

 * November 15, 1997

 * 

 */

#include <math.h></math.h>

#include "slu_cdefs.h"

/*! \brief

 *

 * 

 * Purpose

 * =======

 *

 * Compute the reciprocal pivot growth factor of the leading ncols columns

 * of the matrix, using the formula:

 *     min_j ( max_i(abs(A_ij)) / max_i(abs(U_ij)) )

 *

 * Arguments

 * =========

 *

 * ncols    (input) int

 *          The number of columns of matrices A, L and U.

 *

 * A        (input) SuperMatrix*

 *	    Original matrix A, permuted by columns, of dimension

 *          (A->nrow, A->ncol). The type of A can be:

 *          Stype = NC; Dtype = SLU_C; Mtype = GE.

 *

 * L        (output) SuperMatrix*

 *          The factor L from the factorization Pr*A=L*U; use compressed row 

 *          subscripts storage for supernodes, i.e., L has type: 

 *          Stype = SC; Dtype = SLU_C; Mtype = TRLU.

 *

 * U        (output) SuperMatrix*

 *	    The factor U from the factorization Pr*A*Pc=L*U. Use column-wise

 *          storage scheme, i.e., U has types: Stype = NC;

 *          Dtype = SLU_C; Mtype = TRU.

 * 

 */

float

cPivotGrowth(int ncols, SuperMatrix *A, int *perm_c, 

             SuperMatrix *L, SuperMatrix *U)

{

    NCformat *Astore;

    SCformat *Lstore;

    NCformat *Ustore;

    complex  *Aval, *Lval, *Uval;

    int      fsupc, nsupr, luptr, nz_in_U;

    int      i, j, k, oldcol;

    int      *inv_perm_c;

    float   rpg, maxaj, maxuj;

    float   smlnum;

    complex   *luval;

    complex   temp_comp;

    /* Get machine constants. */

    smlnum = slamch_("S");

    rpg = 1. / smlnum;

    Astore = A->Store;

    Lstore = L->Store;

    Ustore = U->Store;

    Aval = Astore->nzval;

    Lval = Lstore->nzval;

    Uval = Ustore->nzval;

    inv_perm_c = (int *) SUPERLU_MALLOC(A->ncol*sizeof(int));

    for (j = 0; j < A->ncol; ++j) inv_perm_c[perm_c[j]] = j;

    for (k = 0; k <= Lstore->nsuper; ++k) {

	fsupc = L_FST_SUPC(k);

	nsupr = L_SUB_START(fsupc+1) - L_SUB_START(fsupc);

	luptr = L_NZ_START(fsupc);

	luval = &Lval[luptr];

	nz_in_U = 1;

	for (j = fsupc; j < L_FST_SUPC(k+1) && j < ncols; ++j) {

	    maxaj = 0.;

            oldcol = inv_perm_c[j];

	    for (i = Astore->colptr[oldcol]; i < Astore->colptr[oldcol+1]; ++i)

		maxaj = SUPERLU_MAX( maxaj, c_abs1( &Aval[i]) );

	    maxuj = 0.;

	    for (i = Ustore->colptr[j]; i < Ustore->colptr[j+1]; i++)

		maxuj = SUPERLU_MAX( maxuj, c_abs1( &Uval[i]) );

	    /* Supernode */

	    for (i = 0; i < nz_in_U; ++i)

		maxuj = SUPERLU_MAX( maxuj, c_abs1( &luval[i]) );

	    ++nz_in_U;

	    luval += nsupr;

	    if ( maxuj == 0. )

		rpg = SUPERLU_MIN( rpg, 1.);

	    else

		rpg = SUPERLU_MIN( rpg, maxaj / maxuj );

	}

	if ( j >= ncols ) break;

    }

    SUPERLU_FREE(inv_perm_c);

    return (rpg);

}