/usr/lib/x86_64-linux-gnu/scilab-getfem++/src/c/pxop.c is in scilab-getfem++ 4.2.1~beta1~svn4635~dfsg-3+b1.
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**
** Copyright (C) 1993 David E. Steward & Zbigniew Leyk, all rights reserved.
**
** Meschach Library
**
** This Meschach Library is provided "as is" without any express
** or implied warranty of any kind with respect to this software.
** In particular the authors shall not be liable for any direct,
** indirect, special, incidental or consequential damages arising
** in any way from use of the software.
**
** Everyone is granted permission to copy, modify and redistribute this
** Meschach Library, provided:
** 1. All copies contain this copyright notice.
** 2. All modified copies shall carry a notice stating who
** made the last modification and the date of such modification.
** 3. No charge is made for this software or works derived from it.
** This clause shall not be construed as constraining other software
** distributed on the same medium as this software, nor is a
** distribution fee considered a charge.
**
***************************************************************************/
/* pxop.c 1.5 12/03/87 */
#include <stdio.h>
#include "matrix.h"
static char rcsid[] = "$Id: pxop.c 3690 2010-09-02 09:55:19Z lsaavedr $";
/**********************************************************************
Note: A permutation is often interpreted as a matrix
(i.e. a permutation matrix).
A permutation px represents a permutation matrix P where
P[i][j] == 1 if and only if px->pe[i] == j
**********************************************************************/
/* px_inv -- invert permutation -- in situ
-- taken from ACM Collected Algorithms #250 */
PERM *px_inv(px,out)
PERM *px, *out;
{
int i, j, k, n, *p;
out = px_copy(px, out);
n = out->size;
p = (int *)(out->pe);
for ( n--; n>=0; n-- )
{
i = p[n];
if ( i < 0 ) p[n] = -1 - i;
else if ( i != n )
{
k = n;
while (TRUE)
{
if ( i < 0 || i >= out->size )
error(E_BOUNDS,"px_inv");
j = p[i]; p[i] = -1 - k;
if ( j == n )
{ p[n] = i; break; }
k = i; i = j;
}
}
}
return out;
}
/* px_mlt -- permutation multiplication (composition) */
PERM *px_mlt(px1,px2,out)
PERM *px1,*px2,*out;
{
u_int i,size;
if ( px1==(PERM *)NULL || px2==(PERM *)NULL )
error(E_NULL,"px_mlt");
if ( px1->size != px2->size )
error(E_SIZES,"px_mlt");
if ( px1 == out || px2 == out )
error(E_INSITU,"px_mlt");
if ( out==(PERM *)NULL || out->size < px1->size )
out = px_resize(out,px1->size);
size = px1->size;
for ( i=0; i<size; i++ )
if ( px2->pe[i] >= size )
error(E_BOUNDS,"px_mlt");
else
out->pe[i] = px1->pe[px2->pe[i]];
return out;
}
/* px_vec -- permute vector */
VEC *px_vec(px,vector,out)
PERM *px;
VEC *vector,*out;
{
u_int old_i, i, size, start;
Real tmp;
if ( px==(PERM *)NULL || vector==(VEC *)NULL )
error(E_NULL,"px_vec");
if ( px->size > vector->dim )
error(E_SIZES,"px_vec");
if ( out==(VEC *)NULL || out->dim < vector->dim )
out = v_resize(out,vector->dim);
size = px->size;
if ( size == 0 )
return v_copy(vector,out);
if ( out != vector )
{
for ( i=0; i<size; i++ )
if ( px->pe[i] >= size )
error(E_BOUNDS,"px_vec");
else
out->ve[i] = vector->ve[px->pe[i]];
}
else
{ /* in situ algorithm */
start = 0;
while ( start < size )
{
old_i = start;
i = px->pe[old_i];
if ( i >= size )
{
start++;
continue;
}
tmp = vector->ve[start];
while ( TRUE )
{
vector->ve[old_i] = vector->ve[i];
px->pe[old_i] = i+size;
old_i = i;
i = px->pe[old_i];
if ( i >= size )
break;
if ( i == start )
{
vector->ve[old_i] = tmp;
px->pe[old_i] = i+size;
break;
}
}
start++;
}
for ( i = 0; i < size; i++ )
if ( px->pe[i] < size )
error(E_BOUNDS,"px_vec");
else
px->pe[i] = px->pe[i]-size;
}
return out;
}
/* pxinv_vec -- apply the inverse of px to x, returning the result in out */
VEC *pxinv_vec(px,x,out)
PERM *px;
VEC *x, *out;
{
u_int i, size;
if ( ! px || ! x )
error(E_NULL,"pxinv_vec");
if ( px->size > x->dim )
error(E_SIZES,"pxinv_vec");
/* if ( x == out )
error(E_INSITU,"pxinv_vec"); */
if ( ! out || out->dim < x->dim )
out = v_resize(out,x->dim);
size = px->size;
if ( size == 0 )
return v_copy(x,out);
if ( out != x )
{
for ( i=0; i<size; i++ )
if ( px->pe[i] >= size )
error(E_BOUNDS,"pxinv_vec");
else
out->ve[px->pe[i]] = x->ve[i];
}
else
{ /* in situ algorithm --- cheat's way out */
px_inv(px,px);
px_vec(px,x,out);
px_inv(px,px);
}
return out;
}
/* px_transp -- transpose elements of permutation
-- Really multiplying a permutation by a transposition */
PERM *px_transp(px,i1,i2)
PERM *px; /* permutation to transpose */
u_int i1,i2; /* elements to transpose */
{
u_int temp;
if ( px==(PERM *)NULL )
error(E_NULL,"px_transp");
if ( i1 < px->size && i2 < px->size )
{
temp = px->pe[i1];
px->pe[i1] = px->pe[i2];
px->pe[i2] = temp;
}
return px;
}
/* myqsort -- a cheap implementation of Quicksort on integers
-- returns number of swaps */
static int myqsort(a,num)
int *a, num;
{
int i, j, tmp, v;
int numswaps;
numswaps = 0;
if ( num <= 1 )
return 0;
i = 0; j = num; v = a[0];
for ( ; ; )
{
while ( a[++i] < v )
;
while ( a[--j] > v )
;
if ( i >= j ) break;
tmp = a[i];
a[i] = a[j];
a[j] = tmp;
numswaps++;
}
tmp = a[0];
a[0] = a[j];
a[j] = tmp;
if ( j != 0 )
numswaps++;
numswaps += myqsort(&a[0],j);
numswaps += myqsort(&a[j+1],num-(j+1));
return numswaps;
}
/* px_sign -- compute the ``sign'' of a permutation = +/-1 where
px is the product of an even/odd # transpositions */
int px_sign(px)
PERM *px;
{
int numtransp;
PERM *px2;
if ( px==(PERM *)NULL )
error(E_NULL,"px_sign");
px2 = px_copy(px,PNULL);
numtransp = myqsort(px2->pe,px2->size);
px_free(px2);
return ( numtransp % 2 ) ? -1 : 1;
}
/* px_cols -- permute columns of matrix A; out = A.px'
-- May NOT be in situ */
MAT *px_cols(px,A,out)
PERM *px;
MAT *A, *out;
{
int i, j, m, n, px_j;
Real **A_me, **out_me;
#ifdef ANSI_C
MAT *m_get(int, int);
#else
extern MAT *m_get();
#endif
if ( ! A || ! px )
error(E_NULL,"px_cols");
if ( px->size != A->n )
error(E_SIZES,"px_cols");
if ( A == out )
error(E_INSITU,"px_cols");
m = A->m; n = A->n;
if ( ! out || out->m != m || out->n != n )
out = m_get(m,n);
A_me = A->me; out_me = out->me;
for ( j = 0; j < n; j++ )
{
px_j = px->pe[j];
if ( px_j >= n )
error(E_BOUNDS,"px_cols");
for ( i = 0; i < m; i++ )
out_me[i][px_j] = A_me[i][j];
}
return out;
}
/* px_rows -- permute columns of matrix A; out = px.A
-- May NOT be in situ */
MAT *px_rows(px,A,out)
PERM *px;
MAT *A, *out;
{
int i, j, m, n, px_i;
Real **A_me, **out_me;
#ifdef ANSI_C
MAT *m_get(int, int);
#else
extern MAT *m_get();
#endif
if ( ! A || ! px )
error(E_NULL,"px_rows");
if ( px->size != A->m )
error(E_SIZES,"px_rows");
if ( A == out )
error(E_INSITU,"px_rows");
m = A->m; n = A->n;
if ( ! out || out->m != m || out->n != n )
out = m_get(m,n);
A_me = A->me; out_me = out->me;
for ( i = 0; i < m; i++ )
{
px_i = px->pe[i];
if ( px_i >= m )
error(E_BOUNDS,"px_rows");
for ( j = 0; j < n; j++ )
out_me[i][j] = A_me[px_i][j];
}
return out;
}
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