libvips/libsrc/mosaicing/mosaicing_dispatch.c

887 lines
22 KiB
C

/* Function dispatch tables for mosaicing.
*
* J. Cupitt, 23/2/95
*/
/*
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
*/
#ifdef HAVE_CONFIG_H
#include <config.h>
#endif /*HAVE_CONFIG_H*/
#include <vips/intl.h>
#include <stdio.h>
#include <vips/vips.h>
#include <vips/internal.h>
#ifdef WITH_DMALLOC
#include <dmalloc.h>
#endif /*WITH_DMALLOC*/
/* Merge args.
*/
static im_arg_desc merge_args[] = {
IM_INPUT_IMAGE( "ref" ),
IM_INPUT_IMAGE( "sec" ),
IM_OUTPUT_IMAGE( "out" ),
IM_INPUT_INT( "dx" ),
IM_INPUT_INT( "dy" ),
IM_INPUT_INT( "mwidth" )
};
/* Merge1 args.
*/
static im_arg_desc merge1_args[] = {
IM_INPUT_IMAGE( "ref" ),
IM_INPUT_IMAGE( "sec" ),
IM_OUTPUT_IMAGE( "out" ),
IM_INPUT_INT( "xr1" ),
IM_INPUT_INT( "yr1" ),
IM_INPUT_INT( "xs1" ),
IM_INPUT_INT( "ys1" ),
IM_INPUT_INT( "xr2" ),
IM_INPUT_INT( "yr2" ),
IM_INPUT_INT( "xs2" ),
IM_INPUT_INT( "ys2" ),
IM_INPUT_INT( "mwidth" )
};
/* Mosaic args.
*/
static im_arg_desc mosaic_args[] = {
IM_INPUT_IMAGE( "ref" ),
IM_INPUT_IMAGE( "sec" ),
IM_OUTPUT_IMAGE( "out" ),
IM_INPUT_INT( "bandno" ),
IM_INPUT_INT( "xr" ),
IM_INPUT_INT( "yr" ),
IM_INPUT_INT( "xs" ),
IM_INPUT_INT( "ys" ),
IM_INPUT_INT( "halfcorrelation" ),
IM_INPUT_INT( "halfarea" ),
IM_INPUT_INT( "balancetype" ),
IM_INPUT_INT( "mwidth" )
};
/* Mosaic1 args.
*/
static im_arg_desc mosaic1_args[] = {
IM_INPUT_IMAGE( "ref" ),
IM_INPUT_IMAGE( "sec" ),
IM_OUTPUT_IMAGE( "out" ),
IM_INPUT_INT( "bandno" ),
IM_INPUT_INT( "xr1" ),
IM_INPUT_INT( "yr1" ),
IM_INPUT_INT( "xs1" ),
IM_INPUT_INT( "ys1" ),
IM_INPUT_INT( "xr2" ),
IM_INPUT_INT( "yr2" ),
IM_INPUT_INT( "xs2" ),
IM_INPUT_INT( "ys2" ),
IM_INPUT_INT( "halfcorrelation" ),
IM_INPUT_INT( "halfarea" ),
IM_INPUT_INT( "balancetype" ),
IM_INPUT_INT( "mwidth" )
};
/* Call im_lrmosaic via arg vector.
*/
static int
lrmosaic_vec( im_object *argv )
{
int bandno = *((int *) argv[3]);
int xr = *((int *) argv[4]);
int yr = *((int *) argv[5]);
int xs = *((int *) argv[6]);
int ys = *((int *) argv[7]);
int halfcorrelation = *((int *) argv[8]);
int halfarea = *((int *) argv[9]);
int balancetype = *((int *) argv[10]);
int mwidth = *((int *) argv[11]);
return( im_lrmosaic( argv[0], argv[1], argv[2],
bandno,
xr, yr, xs, ys,
halfcorrelation, halfarea,
balancetype, mwidth ) );
}
/* Call im_lrmosaic1 via arg vector.
*/
static int
lrmosaic1_vec( im_object *argv )
{
int bandno = *((int *) argv[3]);
int xr1 = *((int *) argv[4]);
int yr1 = *((int *) argv[5]);
int xs1 = *((int *) argv[6]);
int ys1 = *((int *) argv[7]);
int xr2 = *((int *) argv[8]);
int yr2 = *((int *) argv[9]);
int xs2 = *((int *) argv[10]);
int ys2 = *((int *) argv[11]);
int halfcorrelation = *((int *) argv[12]);
int halfarea = *((int *) argv[13]);
int balancetype = *((int *) argv[14]);
int mwidth = *((int *) argv[15]);
return( im_lrmosaic1( argv[0], argv[1], argv[2],
bandno,
xr1, yr1, xs1, ys1,
xr2, yr2, xs2, ys2,
halfcorrelation, halfarea,
balancetype, mwidth ) );
}
/* Description of im_lrmosaic.
*/
static im_function lrmosaic_desc = {
"im_lrmosaic", /* Name */
"left-right mosaic of ref and sec",/* Description */
IM_FN_TRANSFORM | IM_FN_PIO, /* Flags */
lrmosaic_vec, /* Dispatch function */
IM_NUMBER( mosaic_args ), /* Size of arg list */
mosaic_args /* Arg list */
};
static im_arg_desc find_overlap_args[] = {
IM_INPUT_IMAGE( "ref" ),
IM_INPUT_IMAGE( "sec" ),
IM_INPUT_INT( "bandno" ),
IM_INPUT_INT( "xr" ),
IM_INPUT_INT( "yr" ),
IM_INPUT_INT( "xs" ),
IM_INPUT_INT( "ys" ),
IM_INPUT_INT( "halfcorrelation" ),
IM_INPUT_INT( "halfarea" ),
IM_OUTPUT_INT( "dx0" ),
IM_OUTPUT_INT( "dy0" ),
IM_OUTPUT_DOUBLE( "scale1" ),
IM_OUTPUT_DOUBLE( "angle1" ),
IM_OUTPUT_DOUBLE( "dx1" ),
IM_OUTPUT_DOUBLE( "dy1" )
};
/* Call im__find_lroverlap via arg vector.
*/
static int
find_lroverlap_vec( im_object *argv )
{
int bandno = *((int *) argv[2]);
int xr = *((int *) argv[3]);
int yr = *((int *) argv[4]);
int xs = *((int *) argv[5]);
int ys = *((int *) argv[6]);
int halfcorrelation = *((int *) argv[7]);
int halfarea = *((int *) argv[8]);
int *dx0 = (int *) argv[9];
int *dy0 = (int *) argv[10];
double *scale1 = (double *) argv[11];
double *angle1 = (double *) argv[12];
double *dx1 = (double *) argv[13];
double *dy1 = (double *) argv[14];
IMAGE *t;
int result;
if( !(t = im_open( "find_lroverlap_vec", "p" )) )
return( -1 );
result = im__find_lroverlap( argv[0], argv[1], t,
bandno,
xr, yr, xs, ys,
halfcorrelation, halfarea,
dx0, dy0, scale1, angle1, dx1, dy1 );
im_close( t );
return( result );
}
/* Description of im__find_lroverlap.
*/
static im_function find_lroverlap_desc = {
"im__find_lroverlap", /* Name */
"search for left-right overlap of ref and sec",/* Description */
IM_FN_TRANSFORM | IM_FN_PIO, /* Flags */
find_lroverlap_vec, /* Dispatch function */
IM_NUMBER( find_overlap_args ), /* Size of arg list */
find_overlap_args /* Arg list */
};
/* Description of im_lrmosaic1.
*/
static im_function lrmosaic1_desc = {
"im_lrmosaic1", /* Name */
"first-order left-right mosaic of ref and sec",/* Description */
IM_FN_TRANSFORM | IM_FN_PIO, /* Flags */
lrmosaic1_vec, /* Dispatch function */
IM_NUMBER( mosaic1_args ), /* Size of arg list */
mosaic1_args /* Arg list */
};
/* Call im_tbmosaic via arg vector.
*/
static int
tbmosaic_vec( im_object *argv )
{
int bandno = *((int *) argv[3]);
int x1 = *((int *) argv[4]);
int y1 = *((int *) argv[5]);
int x2 = *((int *) argv[6]);
int y2 = *((int *) argv[7]);
int halfcorrelation = *((int *) argv[8]);
int halfarea = *((int *) argv[9]);
int balancetype = *((int *) argv[10]);
int mwidth = *((int *) argv[11]);
return( im_tbmosaic( argv[0], argv[1], argv[2],
bandno,
x1, y1, x2, y2,
halfcorrelation, halfarea,
balancetype, mwidth ) );
}
/* Call im_tbmosaic1 via arg vector.
*/
static int
tbmosaic1_vec( im_object *argv )
{
int bandno = *((int *) argv[3]);
int xr1 = *((int *) argv[4]);
int yr1 = *((int *) argv[5]);
int xs1 = *((int *) argv[6]);
int ys1 = *((int *) argv[7]);
int xr2 = *((int *) argv[8]);
int yr2 = *((int *) argv[9]);
int xs2 = *((int *) argv[10]);
int ys2 = *((int *) argv[11]);
int halfcorrelation = *((int *) argv[12]);
int halfarea = *((int *) argv[13]);
int balancetype = *((int *) argv[14]);
int mwidth = *((int *) argv[15]);
return( im_tbmosaic1( argv[0], argv[1], argv[2],
bandno,
xr1, yr1, xs1, ys1,
xr2, yr2, xs2, ys2,
halfcorrelation, halfarea,
balancetype, mwidth ) );
}
/* Call im__find_tboverlap via arg vector.
*/
static int
find_tboverlap_vec( im_object *argv )
{
int bandno = *((int *) argv[2]);
int xr = *((int *) argv[3]);
int yr = *((int *) argv[4]);
int xs = *((int *) argv[5]);
int ys = *((int *) argv[6]);
int halfcorrelation = *((int *) argv[7]);
int halfarea = *((int *) argv[8]);
int *dx0 = (int *) argv[9];
int *dy0 = (int *) argv[10];
double *scale1 = (double *) argv[11];
double *angle1 = (double *) argv[12];
double *dx1 = (double *) argv[13];
double *dy1 = (double *) argv[14];
IMAGE *t;
int result;
if( !(t = im_open( "find_tboverlap_vec", "p" )) )
return( -1 );
result = im__find_tboverlap( argv[0], argv[1], t,
bandno,
xr, yr, xs, ys,
halfcorrelation, halfarea,
dx0, dy0, scale1, angle1, dx1, dy1 );
im_close( t );
return( result );
}
/* Description of im__find_tboverlap.
*/
static im_function find_tboverlap_desc = {
"im__find_tboverlap", /* Name */
"search for top-bottom overlap of ref and sec",/* Description */
IM_FN_TRANSFORM | IM_FN_PIO, /* Flags */
find_tboverlap_vec, /* Dispatch function */
IM_NUMBER( find_overlap_args ), /* Size of arg list */
find_overlap_args /* Arg list */
};
/* Description of im_tbmosaic.
*/
static im_function tbmosaic_desc = {
"im_tbmosaic", /* Name */
"top-bottom mosaic of in1 and in2",/* Description */
IM_FN_TRANSFORM | IM_FN_PIO, /* Flags */
tbmosaic_vec, /* Dispatch function */
IM_NUMBER( mosaic_args ), /* Size of arg list */
mosaic_args /* Arg list */
};
/* Description of im_tbmosaic1.
*/
static im_function tbmosaic1_desc = {
"im_tbmosaic1", /* Name */
"first-order top-bottom mosaic of ref and sec",/* Description */
IM_FN_TRANSFORM | IM_FN_PIO, /* Flags */
tbmosaic1_vec, /* Dispatch function */
IM_NUMBER( mosaic1_args ), /* Size of arg list */
mosaic1_args /* Arg list */
};
/* Call im_lrmerge via arg vector.
*/
static int
lrmerge_vec( im_object *argv )
{
int dx = *((int *) argv[3]);
int dy = *((int *) argv[4]);
int mwidth = *((int *) argv[5]);
return( im_lrmerge( argv[0], argv[1], argv[2], dx, dy, mwidth ) );
}
/* Call im_lrmerge1 via arg vector.
*/
static int
lrmerge1_vec( im_object *argv )
{
int xr1 = *((int *) argv[3]);
int yr1 = *((int *) argv[4]);
int xs1 = *((int *) argv[5]);
int ys1 = *((int *) argv[6]);
int xr2 = *((int *) argv[7]);
int yr2 = *((int *) argv[8]);
int xs2 = *((int *) argv[9]);
int ys2 = *((int *) argv[10]);
int mwidth = *((int *) argv[11]);
return( im_lrmerge1( argv[0], argv[1], argv[2],
xr1, yr1, xs1, ys1,
xr2, yr2, xs2, ys2, mwidth ) );
}
/* Description of im_lrmerge.
*/
static im_function lrmerge_desc = {
"im_lrmerge", /* Name */
"left-right merge of in1 and in2",/* Description */
IM_FN_TRANSFORM | IM_FN_PIO, /* Flags */
lrmerge_vec, /* Dispatch function */
IM_NUMBER( merge_args ), /* Size of arg list */
merge_args /* Arg list */
};
/* Description of im_lrmerge1.
*/
static im_function lrmerge1_desc = {
"im_lrmerge1", /* Name */
"first-order left-right merge of ref and sec",/* Description */
IM_FN_TRANSFORM | IM_FN_PIO, /* Flags */
lrmerge1_vec, /* Dispatch function */
IM_NUMBER( merge1_args ), /* Size of arg list */
merge1_args /* Arg list */
};
/* Call im_tbmerge via arg vector.
*/
static int
tbmerge_vec( im_object *argv )
{
int dx = *((int *) argv[3]);
int dy = *((int *) argv[4]);
int mwidth = *((int *) argv[5]);
return( im_tbmerge( argv[0], argv[1], argv[2], dx, dy, mwidth ) );
}
/* Call im_tbmerge1 via arg vector.
*/
static int
tbmerge1_vec( im_object *argv )
{
int xr1 = *((int *) argv[3]);
int yr1 = *((int *) argv[4]);
int xs1 = *((int *) argv[5]);
int ys1 = *((int *) argv[6]);
int xr2 = *((int *) argv[7]);
int yr2 = *((int *) argv[8]);
int xs2 = *((int *) argv[9]);
int ys2 = *((int *) argv[10]);
int mwidth = *((int *) argv[11]);
return( im_tbmerge1( argv[0], argv[1], argv[2],
xr1, yr1, xs1, ys1,
xr2, yr2, xs2, ys2, mwidth ) );
}
/* Description of im_tbmerge.
*/
static im_function tbmerge_desc = {
"im_tbmerge", /* Name */
"top-bottom merge of in1 and in2",/* Description */
IM_FN_TRANSFORM | IM_FN_PIO, /* Flags */
tbmerge_vec, /* Dispatch function */
IM_NUMBER( merge_args ), /* Size of arg list */
merge_args /* Arg list */
};
/* Description of im_tbmerge1.
*/
static im_function tbmerge1_desc = {
"im_tbmerge1", /* Name */
"first-order top-bottom merge of in1 and in2",/* Description */
IM_FN_TRANSFORM | IM_FN_PIO, /* Flags */
tbmerge1_vec, /* Dispatch function */
IM_NUMBER( merge1_args ), /* Size of arg list */
merge1_args /* Arg list */
};
/* affine args
*/
static im_arg_desc affine_args[] = {
IM_INPUT_IMAGE( "in" ),
IM_OUTPUT_IMAGE( "out" ),
IM_INPUT_DOUBLE( "a" ),
IM_INPUT_DOUBLE( "b" ),
IM_INPUT_DOUBLE( "c" ),
IM_INPUT_DOUBLE( "d" ),
IM_INPUT_DOUBLE( "dx" ),
IM_INPUT_DOUBLE( "dy" ),
IM_INPUT_INT( "x" ),
IM_INPUT_INT( "y" ),
IM_INPUT_INT( "w" ),
IM_INPUT_INT( "h" )
};
/* Call im_affine via arg vector.
*/
static int
affine_vec( im_object *argv )
{
double a = *((double *) argv[2]);
double b = *((double *) argv[3]);
double c = *((double *) argv[4]);
double d = *((double *) argv[5]);
double dx = *((double *) argv[6]);
double dy = *((double *) argv[7]);
int x = *((int *) argv[8]);
int y = *((int *) argv[9]);
int w = *((int *) argv[10]);
int h = *((int *) argv[11]);
return( im_affine( argv[0], argv[1], a, b, c, d, dx, dy, x, y, w, h ) );
}
/* Description of im_affine.
*/
static im_function affine_desc = {
"im_affine", /* Name */
"affine transform",
IM_FN_TRANSFORM | IM_FN_PIO, /* Flags */
affine_vec, /* Dispatch function */
IM_NUMBER( affine_args ), /* Size of arg list */
affine_args /* Arg list */
};
/* similarity args
*/
static im_arg_desc similarity_args[] = {
IM_INPUT_IMAGE( "in" ),
IM_OUTPUT_IMAGE( "out" ),
IM_INPUT_DOUBLE( "a" ),
IM_INPUT_DOUBLE( "b" ),
IM_INPUT_DOUBLE( "dx" ),
IM_INPUT_DOUBLE( "dy" )
};
/* Call im_similarity via arg vector.
*/
static int
similarity_vec( im_object *argv )
{
double a = *((double *) argv[2]);
double b = *((double *) argv[3]);
double dx = *((double *) argv[4]);
double dy = *((double *) argv[5]);
return( im_similarity( argv[0], argv[1], a, b, dx, dy ) );
}
/* Description of im_similarity.
*/
static im_function similarity_desc = {
"im_similarity", /* Name */
"similarity transformation",
IM_FN_TRANSFORM | IM_FN_PIO, /* Flags */
similarity_vec, /* Dispatch function */
IM_NUMBER( similarity_args ), /* Size of arg list */
similarity_args /* Arg list */
};
/* match_linear args
*/
static im_arg_desc match_linear_args[] = {
IM_INPUT_IMAGE( "ref" ),
IM_INPUT_IMAGE( "sec" ),
IM_OUTPUT_IMAGE( "out" ),
IM_INPUT_INT( "xref1" ),
IM_INPUT_INT( "yref1" ),
IM_INPUT_INT( "xsec1" ),
IM_INPUT_INT( "ysec1" ),
IM_INPUT_INT( "xref2" ),
IM_INPUT_INT( "yref2" ),
IM_INPUT_INT( "xsec2" ),
IM_INPUT_INT( "ysec2" )
};
/* Call im_match_linear via arg vector.
*/
static int
match_linear_vec( im_object *argv )
{
int xref1 = *((int *) argv[3]);
int yref1 = *((int *) argv[4]);
int xsec1 = *((int *) argv[5]);
int ysec1 = *((int *) argv[6]);
int xref2 = *((int *) argv[7]);
int yref2 = *((int *) argv[8]);
int xsec2 = *((int *) argv[9]);
int ysec2 = *((int *) argv[10]);
return( im_match_linear( argv[0], argv[1], argv[2],
xref1, yref1, xsec1, ysec1,
xref2, yref2, xsec2, ysec2 ) );
}
/* Description of im_match_linear.
*/
static im_function match_linear_desc = {
"im_match_linear", /* Name */
"resample ref so that tie-points match",
IM_FN_PIO, /* Flags */
match_linear_vec, /* Dispatch function */
IM_NUMBER( match_linear_args ), /* Size of arg list */
match_linear_args /* Arg list */
};
/* match_linear_search args
*/
static im_arg_desc match_linear_search_args[] = {
IM_INPUT_IMAGE( "ref" ),
IM_INPUT_IMAGE( "sec" ),
IM_OUTPUT_IMAGE( "out" ),
IM_INPUT_INT( "xref1" ),
IM_INPUT_INT( "yref1" ),
IM_INPUT_INT( "xsec1" ),
IM_INPUT_INT( "ysec1" ),
IM_INPUT_INT( "xref2" ),
IM_INPUT_INT( "yref2" ),
IM_INPUT_INT( "xsec2" ),
IM_INPUT_INT( "ysec2" ),
IM_INPUT_INT( "hwindowsize" ),
IM_INPUT_INT( "hsearchsize" )
};
/* Call im_match_linear_search via arg vector.
*/
static int
match_linear_search_vec( im_object *argv )
{
int xref1 = *((int *) argv[3]);
int yref1 = *((int *) argv[4]);
int xsec1 = *((int *) argv[5]);
int ysec1 = *((int *) argv[6]);
int xref2 = *((int *) argv[7]);
int yref2 = *((int *) argv[8]);
int xsec2 = *((int *) argv[9]);
int ysec2 = *((int *) argv[10]);
int hwin = *((int *) argv[11]);
int hsrch = *((int *) argv[12]);
return( im_match_linear_search( argv[0], argv[1], argv[2],
xref1, yref1, xsec1, ysec1,
xref2, yref2, xsec2, ysec2,
hwin, hsrch ) );
}
/* Description of im_match_linear_search.
*/
static im_function match_linear_search_desc = {
"im_match_linear_search", /* Name */
"search sec, then resample so that tie-points match",
IM_FN_PIO, /* Flags */
match_linear_search_vec, /* Dispatch function */
IM_NUMBER( match_linear_search_args ),/* Size of arg list */
match_linear_search_args /* Arg list */
};
/* correl args
*/
static im_arg_desc correl_args[] = {
IM_INPUT_IMAGE( "ref" ),
IM_INPUT_IMAGE( "sec" ),
IM_INPUT_INT( "xref" ),
IM_INPUT_INT( "yref" ),
IM_INPUT_INT( "xsec" ),
IM_INPUT_INT( "ysec" ),
IM_INPUT_INT( "hwindowsize" ),
IM_INPUT_INT( "hsearchsize" ),
IM_OUTPUT_DOUBLE( "correlation" ),
IM_OUTPUT_INT( "x" ),
IM_OUTPUT_INT( "y" )
};
/* Call im_correl via arg vector.
*/
static int
correl_vec( im_object *argv )
{
int xref = *((int *) argv[2]);
int yref = *((int *) argv[3]);
int xsec = *((int *) argv[4]);
int ysec = *((int *) argv[5]);
int cor = *((int *) argv[6]);
int area = *((int *) argv[7]);
int *x = (int *) argv[8];
int *y = (int *) argv[9];
double *correlation = (double *) argv[10];
return( im_correl( argv[0], argv[1],
xref, yref, xsec, ysec, cor, area, correlation, x, y ) );
}
/* Description of im_correl.
*/
static im_function correl_desc = {
"im_correl", /* Name */
"search area around sec for match for area around ref",
IM_FN_PIO, /* Flags */
correl_vec, /* Dispatch function */
IM_NUMBER( correl_args ), /* Size of arg list */
correl_args /* Arg list */
};
/* similarity_area args
*/
static im_arg_desc similarity_area_args[] = {
IM_INPUT_IMAGE( "in" ),
IM_OUTPUT_IMAGE( "out" ),
IM_INPUT_DOUBLE( "a" ),
IM_INPUT_DOUBLE( "b" ),
IM_INPUT_DOUBLE( "dx" ),
IM_INPUT_DOUBLE( "dy" ),
IM_INPUT_INT( "x" ),
IM_INPUT_INT( "y" ),
IM_INPUT_INT( "w" ),
IM_INPUT_INT( "h" )
};
/* Call im_similarity_area via arg vector.
*/
static int
similarity_area_vec( im_object *argv )
{
double a = *((double *) argv[2]);
double b = *((double *) argv[3]);
double dx = *((double *) argv[4]);
double dy = *((double *) argv[5]);
int x = *((int *) argv[6]);
int y = *((int *) argv[7]);
int w = *((int *) argv[8]);
int h = *((int *) argv[9]);
return( im_similarity_area( argv[0], argv[1], a, b, dx, dy,
x, y, w, h ) );
}
/* Description of im_similarity_area.
*/
static im_function similarity_area_desc = {
"im_similarity_area", /* Name */
"output area xywh of similarity transformation",
IM_FN_TRANSFORM | IM_FN_PIO, /* Flags */
similarity_area_vec, /* Dispatch function */
IM_NUMBER( similarity_area_args ), /* Size of arg list */
similarity_area_args /* Arg list */
};
/* global_balance args
*/
static im_arg_desc global_balance_args[] = {
IM_INPUT_IMAGE( "in" ),
IM_OUTPUT_IMAGE( "out" ),
IM_INPUT_DOUBLE( "gamma" )
};
/* Call im_global_balance via arg vector.
*/
static int
global_balance_vec( im_object *argv )
{
double gamma = *((double *) argv[2]);
return( im_global_balance( argv[0], argv[1], gamma ) );
}
/* Description of im_global_balance.
*/
static im_function global_balance_desc = {
"im_global_balance", /* Name */
"automatically rebuild mosaic with balancing",
IM_FN_TRANSFORM | IM_FN_PIO, /* Flags */
global_balance_vec, /* Dispatch function */
IM_NUMBER( global_balance_args ), /* Size of arg list */
global_balance_args /* Arg list */
};
/* Call im_global_balancef via arg vector.
*/
static int
global_balancef_vec( im_object *argv )
{
double gamma = *((double *) argv[2]);
return( im_global_balancef( argv[0], argv[1], gamma ) );
}
/* Description of im_global_balancef.
*/
static im_function global_balancef_desc = {
"im_global_balancef", /* Name */
"automatically rebuild mosaic with balancing, float output",
IM_FN_TRANSFORM | IM_FN_PIO, /* Flags */
global_balancef_vec, /* Dispatch function */
IM_NUMBER( global_balance_args ), /* Size of arg list */
global_balance_args /* Arg list */
};
/* remosaic args
*/
static im_arg_desc remosaic_args[] = {
IM_INPUT_IMAGE( "in" ),
IM_OUTPUT_IMAGE( "out" ),
IM_INPUT_STRING( "old_str" ),
IM_INPUT_STRING( "new_str" )
};
/* Call im_remosaic via arg vector.
*/
static int
remosaic_vec( im_object *argv )
{
return( im_remosaic( argv[0], argv[1], argv[2], argv[3] ) );
}
/* Description of im_remosaic.
*/
static im_function remosaic_desc = {
"im_remosaic", /* Name */
"automatically rebuild mosaic with new files",
IM_FN_TRANSFORM | IM_FN_PIO, /* Flags */
remosaic_vec, /* Dispatch function */
IM_NUMBER( remosaic_args ),/* Size of arg list */
remosaic_args /* Arg list */
};
static int align_bands_vec( im_object *argv ){
return im_align_bands( (IMAGE*)argv[0], (IMAGE*)argv[1] );
}
static im_arg_desc align_bands_arg_types[]= {
IM_INPUT_IMAGE( "in" ),
IM_OUTPUT_IMAGE( "out" )
};
static im_function align_bands_desc= {
"im_align_bands",
"align the bands of an image",
0,
align_bands_vec,
IM_NUMBER( align_bands_arg_types ),
align_bands_arg_types
};
static int maxpos_subpel_vec( im_object *argv ){
return im_maxpos_subpel( (IMAGE*)argv[0], (double*)argv[1], (double*)argv[2] );
}
static im_arg_desc maxpos_subpel_arg_types[]= {
IM_INPUT_IMAGE( "im" ),
IM_OUTPUT_DOUBLE( "x" ),
IM_OUTPUT_DOUBLE( "y" )
};
static im_function maxpos_subpel_desc= {
"im_maxpos_subpel",
"subpixel position of maximum of (phase correlation) image",
IM_FN_PIO,
maxpos_subpel_vec,
IM_NUMBER( maxpos_subpel_arg_types ),
maxpos_subpel_arg_types
};
/* Package up all these functions.
*/
static im_function *mos_list[] = {
&affine_desc,
&align_bands_desc,
&correl_desc,
&find_lroverlap_desc,
&find_tboverlap_desc,
&global_balance_desc,
&global_balancef_desc,
&lrmerge_desc,
&lrmerge1_desc,
&lrmosaic_desc,
&lrmosaic1_desc,
&match_linear_desc,
&match_linear_search_desc,
&maxpos_subpel_desc,
&remosaic_desc,
&similarity_area_desc,
&similarity_desc,
&tbmerge_desc,
&tbmerge1_desc,
&tbmosaic_desc,
&tbmosaic1_desc
};
/* Package of functions.
*/
im_package im__mosaicing = {
"mosaicing",
IM_NUMBER( mos_list ),
mos_list
};