/* @(#) Returns a circularly symmetric difference of Gaussian mask
* @(#) min_amplitude should be greater than 0.0 and less than 1.0
* @(#) min_amplitude determines the size of the mask; if for instance
* @(#) the value .1 is entered this means that the produced mask is clipped
* @(#) at values less than 10 percent of the minimum negative amplitude.
* @(#) If the value of min_amplitude is too small, then the filter coefficients
* @(#) are calculated for masksize equal to the min of 8 * sigma or 256.
* @(#) The mask can be directly used with the vasari convolution programs,
* @(#) the default offset set is 0
* @(#)
* @(#) DOUBLEMASK *im_log_dmask( filename, sigma, min_amplitude )
* @(#) char *filename;
* @(#) double sigma, min_amplitude;
* @(#)
* @(#) Returns a laplacian of Gaussian square double mask or NULL on error
* @(#)
* @(#) DOUBLEMASK *im_log_imask( filename, sigma, min_amplitude )
* @(#) char *filename;
* @(#) double sigma, min_amplitude;
* @(#)
* @(#) Returns a laplacian of Gaussian square int mask or NULL on error
*/
/* Written on: 30/11/1989
* Updated on: 6/12/1991
* 7/8/96 JC
* - ansified, mem leaks plugged
* 20/11/98 JC
* - mask too large check added
* 26/3/02 JC
* - ahem, was broken since '96, thanks matt
* 16/7/03 JC
* - makes mask out to zero, not out to minimum, thanks again matt
*/
/*
This file is part of VIPS.
VIPS is free software; you can redistribute it and/or modify
it under the terms of the GNU Lesser General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*/
/*
These files are distributed with VIPS - http://www.vips.ecs.soton.ac.uk
*/
/*
#define PIM_RINT 1
*/
#ifdef HAVE_CONFIG_H
#include <config.h>
#endif /*HAVE_CONFIG_H*/
#include <vips/intl.h>
#include <stdio.h>
#include <math.h>
#include <vips/vips.h>
#include <vips/util.h>
#ifdef WITH_DMALLOC
#include <dmalloc.h>
#endif /*WITH_DMALLOC*/
#define IM_MAXMASK 256
DOUBLEMASK *
im_log_dmask( const char *filename, double sigma, double min_ampl )
{
const double sig2 = sigma * sigma;
double last;
int x, y, k;
double *pt1, *pt2, *pt3, *pt4;
int xm, ym;
int xm2, ym2; /* xm2 = xm/2 */
int offset;
double *cf, *cfs, *mc;
DOUBLEMASK *m;
double sum;
/* Stop used-before-set warnings.
*/
last = 0.0;
/* Find the size of the mask depending on the entered data. We want to
* eval the mask out to the flat zero part, ie. beyond the minimum and
* to the point where it comes back up towards zero.
*/
for( x = 0; x < IM_MAXMASK; x++ ) {
const double distance = x * x;
double val;
/* Handbook of Pattern Recognition and image processing
* by Young and Fu AP 1986 pp 220-221
* temp = (1.0 / (2.0 * IM_PI * sig4)) *
(2.0 - (distance / sig2)) *
exp( (-1.0) * distance / (2.0 * sig2) )
.. use 0.5 to normalise
*/
val = 0.5 *
(2.0 - (distance / sig2)) *
exp( -distance / (2.0 * sig2) );
/* Stop when change in temp (ie. difference from the last
* point) and absolute value are both less than the min.
*/
if( x > 0 &&
fabs( val ) < min_ampl &&
fabs( val - last ) < min_ampl )
break;
last = val;
}
if( x == IM_MAXMASK ) {
im_errormsg( "im_log_dmask: mask too large" );
return( NULL );
}
xm2 = x; ym2 = x;
xm = xm2 * 2 + 1; ym = ym2 * 2 + 1;
if( !(cfs = IM_ARRAY( NULL, (xm2 + 1) * (ym2 + 1), double )) )
return( NULL );
/* Make 1/4 of the mask.
*/
for( k = 0, y = 0; y <= ym2; y++ )
for( x = 0; x <= xm2; x++, k++ ) {
const double distance = x * x + y * y;
cfs[k] = 0.5 *
(2.0 - (distance / sig2)) *
exp( -distance / (2.0 * sig2) );
}
#ifdef PIM_RINT
for( k = 0, y = 0; y <= ym2; y++ ) {
for( x = 0; x <= xm2; x++, k++ )
fprintf( stderr, "%3.2f ", cfs[k] );
fprintf( stderr, "\n" );
}
#endif
if( !(m = im_create_dmask( filename, xm, ym )) ) {
im_free( cfs );
return( NULL );
}
/* Copy the 1/4 cfs into the m
*/
cf = cfs;
offset = xm2 * (xm + 1);
mc = m->coeff + offset;
for( y = 0; y <= ym2; y++ ) {
for( x = 0; x <= xm2; x++ ) {
pt1 = mc + (y * xm) + x;
pt2 = mc - (y * xm) + x;
pt3 = mc + (y * xm) - x;
pt4 = mc - (y * xm) - x;
*pt1 = cf[x];
*pt2 = cf[x];
*pt3 = cf[x];
*pt4 = cf[x];
}
cf += (xm2 + 1);
}
im_free( cfs );
sum = 0.0;
for( k = 0, y = 0; y < m->ysize; y++ )
for( x = 0; x < m->xsize; x++, k++ )
sum += m->coeff[k];
m->scale = sum;
m->offset = 0.0;
#ifdef PIM_RINT
im_print_dmask( m );
#endif
return( m );
}
INTMASK *
im_log_imask( const char *filename, double sigma, double min_ampl )
{
DOUBLEMASK *dm;
INTMASK *im;
if( !(dm = im_log_dmask( filename, sigma, min_ampl )) )
return( NULL );
if( !(im = im_scale_dmask( dm, dm->filename )) ) {
im_free_dmask( dm );
return( NULL );
}
im_free_dmask( dm );
return( im ) ;
}