umf_triplet.c
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/* ========================================================================== */
/* === UMF_triplet ========================================================== */
/* ========================================================================== */
/* -------------------------------------------------------------------------- */
/* UMFPACK Copyright (c) Timothy A. Davis, CISE, */
/* Univ. of Florida. All Rights Reserved. See ../Doc/License for License. */
/* web: http://www.cise.ufl.edu/research/sparse/umfpack */
/* -------------------------------------------------------------------------- */
/*
Not user callable. Converts triplet input to column-oriented form.
Duplicate entries may exist (they are summed in the output). The columns
of the column-oriented form are in sorted order. The input is not modified.
Returns 1 if OK, 0 if an error occurred.
Compiled into four different routines for each version (di, dl, zi, zl),
for a total of 16 different routines.
*/
#include "umf_internal.h"
#ifdef DO_MAP
#ifdef DO_VALUES
GLOBAL Int UMF_triplet_map_x
#else
GLOBAL Int UMF_triplet_map_nox
#endif
#else
#ifdef DO_VALUES
GLOBAL Int UMF_triplet_nomap_x
#else
GLOBAL Int UMF_triplet_nomap_nox
#endif
#endif
(
Int n_row,
Int n_col,
Int nz,
const Int Ti [ ], /* size nz */
const Int Tj [ ], /* size nz */
Int Ap [ ], /* size n_col + 1 */
Int Ai [ ], /* size nz */
Int Rp [ ], /* size n_row + 1 */
Int Rj [ ], /* size nz */
Int W [ ], /* size max (n_row, n_col) */
Int RowCount [ ] /* size n_row */
#ifdef DO_VALUES
, const double Tx [ ] /* size nz */
, double Ax [ ] /* size nz */
, double Rx [ ] /* size nz */
#ifdef COMPLEX
, const double Tz [ ] /* size nz */
, double Az [ ] /* size nz */
, double Rz [ ] /* size nz */
#endif
#endif
#ifdef DO_MAP
, Int Map [ ] /* size nz */
, Int Map2 [ ] /* size nz */
#endif
)
{
/* ---------------------------------------------------------------------- */
/* local variables */
/* ---------------------------------------------------------------------- */
Int i, j, k, p, cp, p1, p2, pdest, pj ;
#ifdef DO_MAP
Int duplicates ;
#endif
#ifdef DO_VALUES
#ifdef COMPLEX
Int split = SPLIT (Tz) && SPLIT (Az) && SPLIT (Rz) ;
#endif
#endif
/* ---------------------------------------------------------------------- */
/* count the entries in each row (also counting duplicates) */
/* ---------------------------------------------------------------------- */
/* use W as workspace for row counts (including duplicates) */
for (i = 0 ; i < n_row ; i++)
{
W [i] = 0 ;
}
for (k = 0 ; k < nz ; k++)
{
i = Ti [k] ;
j = Tj [k] ;
if (i < 0 || i >= n_row || j < 0 || j >= n_col)
{
return (UMFPACK_ERROR_invalid_matrix) ;
}
W [i]++ ;
#ifndef NDEBUG
DEBUG1 ((ID " triplet: "ID" "ID" ", k, i, j)) ;
#ifdef DO_VALUES
{
Entry tt ;
ASSIGN (tt, Tx, Tz, k, split) ;
EDEBUG2 (tt) ;
DEBUG1 (("\n")) ;
}
#endif
#endif
}
/* ---------------------------------------------------------------------- */
/* compute the row pointers */
/* ---------------------------------------------------------------------- */
Rp [0] = 0 ;
for (i = 0 ; i < n_row ; i++)
{
Rp [i+1] = Rp [i] + W [i] ;
W [i] = Rp [i] ;
}
/* W is now equal to the row pointers */
/* ---------------------------------------------------------------------- */
/* construct the row form */
/* ---------------------------------------------------------------------- */
for (k = 0 ; k < nz ; k++)
{
p = W [Ti [k]]++ ;
#ifdef DO_MAP
Map [k] = p ;
#endif
Rj [p] = Tj [k] ;
#ifdef DO_VALUES
#ifdef COMPLEX
if (split)
{
Rx [p] = Tx [k] ;
Rz [p] = Tz [k] ;
}
else
{
Rx [2*p ] = Tx [2*k ] ;
Rx [2*p+1] = Tx [2*k+1] ;
}
#else
Rx [p] = Tx [k] ;
#endif
#endif
}
/* Rp stays the same, but W [i] is advanced to the start of row i+1 */
#ifndef NDEBUG
for (i = 0 ; i < n_row ; i++)
{
ASSERT (W [i] == Rp [i+1]) ;
}
#ifdef DO_MAP
for (k = 0 ; k < nz ; k++)
{
/* make sure that kth triplet is mapped correctly */
p = Map [k] ;
DEBUG1 (("First row map: Map ["ID"] = "ID"\n", k, p)) ;
i = Ti [k] ;
j = Tj [k] ;
ASSERT (j == Rj [p]) ;
ASSERT (Rp [i] <= p && p < Rp [i+1]) ;
}
#endif
#endif
/* ---------------------------------------------------------------------- */
/* sum up duplicates */
/* ---------------------------------------------------------------------- */
/* use W [j] to hold position in Ri/Rx/Rz of a_ij, for row i [ */
for (j = 0 ; j < n_col ; j++)
{
W [j] = EMPTY ;
}
#ifdef DO_MAP
duplicates = FALSE ;
#endif
for (i = 0 ; i < n_row ; i++)
{
p1 = Rp [i] ;
p2 = Rp [i+1] ;
pdest = p1 ;
/* At this point, W [j] < p1 holds true for all columns j, */
/* because Ri/Rx/Rz is stored in row oriented order. */
#ifndef NDEBUG
if (UMF_debug >= -2)
{
for (j = 0 ; j < n_col ; j++)
{
ASSERT (W [j] < p1) ;
}
}
#endif
for (p = p1 ; p < p2 ; p++)
{
j = Rj [p] ;
ASSERT (j >= 0 && j < n_col) ;
pj = W [j] ;
if (pj >= p1)
{
/* this column index, j, is already in row i, at position pj */
ASSERT (pj < p) ;
ASSERT (Rj [pj] == j) ;
#ifdef DO_MAP
Map2 [p] = pj ;
duplicates = TRUE ;
#endif
#ifdef DO_VALUES
/* sum the entry */
#ifdef COMPLEX
if (split)
{
Rx [pj] += Rx [p] ;
Rz [pj] += Rz [p] ;
}
else
{
Rx[2*pj ] += Rx[2*p ] ;
Rx[2*pj+1] += Rx[2*p+1] ;
}
#else
Rx [pj] += Rx [p] ;
#endif
#endif
}
else
{
/* keep the entry */
/* also keep track in W[j] of position of a_ij for case above */
W [j] = pdest ;
#ifdef DO_MAP
Map2 [p] = pdest ;
#endif
/* no need to move the entry if pdest is equal to p */
if (pdest != p)
{
Rj [pdest] = j ;
#ifdef DO_VALUES
#ifdef COMPLEX
if (split)
{
Rx [pdest] = Rx [p] ;
Rz [pdest] = Rz [p] ;
}
else
{
Rx [2*pdest ] = Rx [2*p ] ;
Rx [2*pdest+1] = Rx [2*p+1] ;
}
#else
Rx [pdest] = Rx [p] ;
#endif
#endif
}
pdest++ ;
}
}
RowCount [i] = pdest - p1 ;
}
/* done using W for position of a_ij ] */
/* ---------------------------------------------------------------------- */
/* merge Map and Map2 into a single Map */
/* ---------------------------------------------------------------------- */
#ifdef DO_MAP
if (duplicates)
{
for (k = 0 ; k < nz ; k++)
{
Map [k] = Map2 [Map [k]] ;
}
}
#ifndef NDEBUG
else
{
/* no duplicates, so no need to recompute Map */
for (k = 0 ; k < nz ; k++)
{
ASSERT (Map2 [k] == k) ;
}
}
for (k = 0 ; k < nz ; k++)
{
/* make sure that kth triplet is mapped correctly */
p = Map [k] ;
DEBUG1 (("Second row map: Map ["ID"] = "ID"\n", k, p)) ;
i = Ti [k] ;
j = Tj [k] ;
ASSERT (j == Rj [p]) ;
ASSERT (Rp [i] <= p && p < Rp [i+1]) ;
}
#endif
#endif
/* now the kth triplet maps to p = Map [k], and thus to Rj/Rx [p] */
/* ---------------------------------------------------------------------- */
/* count the entries in each column */
/* ---------------------------------------------------------------------- */
/* [ use W as work space for column counts of A */
for (j = 0 ; j < n_col ; j++)
{
W [j] = 0 ;
}
for (i = 0 ; i < n_row ; i++)
{
for (p = Rp [i] ; p < Rp [i] + RowCount [i] ; p++)
{
j = Rj [p] ;
ASSERT (j >= 0 && j < n_col) ;
W [j]++ ;
}
}
/* ---------------------------------------------------------------------- */
/* create the column pointers */
/* ---------------------------------------------------------------------- */
Ap [0] = 0 ;
for (j = 0 ; j < n_col ; j++)
{
Ap [j+1] = Ap [j] + W [j] ;
}
/* done using W as workspace for column counts of A ] */
for (j = 0 ; j < n_col ; j++)
{
W [j] = Ap [j] ;
}
/* ---------------------------------------------------------------------- */
/* construct the column form */
/* ---------------------------------------------------------------------- */
for (i = 0 ; i < n_row ; i++)
{
for (p = Rp [i] ; p < Rp [i] + RowCount [i] ; p++)
{
cp = W [Rj [p]]++ ;
#ifdef DO_MAP
Map2 [p] = cp ;
#endif
Ai [cp] = i ;
#ifdef DO_VALUES
#ifdef COMPLEX
if (split)
{
Ax [cp] = Rx [p] ;
Az [cp] = Rz [p] ;
}
else
{
Ax [2*cp ] = Rx [2*p ] ;
Ax [2*cp+1] = Rx [2*p+1] ;
}
#else
Ax [cp] = Rx [p] ;
#endif
#endif
}
}
/* ---------------------------------------------------------------------- */
/* merge Map and Map2 into a single Map */
/* ---------------------------------------------------------------------- */
#ifdef DO_MAP
for (k = 0 ; k < nz ; k++)
{
Map [k] = Map2 [Map [k]] ;
}
#endif
/* now the kth triplet maps to p = Map [k], and thus to Ai/Ax [p] */
#ifndef NDEBUG
for (j = 0 ; j < n_col ; j++)
{
ASSERT (W [j] == Ap [j+1]) ;
}
UMF_dump_col_matrix (
#ifdef DO_VALUES
Ax,
#ifdef COMPLEX
Az,
#endif
#else
(double *) NULL,
#ifdef COMPLEX
(double *) NULL,
#endif
#endif
Ai, Ap, n_row, n_col, nz) ;
#ifdef DO_MAP
for (k = 0 ; k < nz ; k++)
{
/* make sure that kth triplet is mapped correctly */
p = Map [k] ;
DEBUG1 (("Col map: Map ["ID"] = "ID"\t", k, p)) ;
i = Ti [k] ;
j = Tj [k] ;
ASSERT (i == Ai [p]) ;
DEBUG1 ((" i "ID" j "ID" Ap[j] "ID" p "ID" Ap[j+1] "ID"\n",
i, j, Ap [j], p, Ap [j+1])) ;
ASSERT (Ap [j] <= p && p < Ap [j+1]) ;
}
#endif
#endif
return (UMFPACK_OK) ;
}