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gimp/plug-ins/common/photocopy.c

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/* GIMP - The GNU Image Manipulation Program
* Copyright (C) 1995 Spencer Kimball and Peter Mattis
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU 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 General Public License for more details.
*
* You should have received a copy of the GNU 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.
*/
/* Photocopy filter for GIMP for BIPS
* -Spencer Kimball
*
* This filter propagates dark values in an image based on
* each pixel's relative darkness to a neighboring average
* and sets the remaining pixels to white.
*/
#include "config.h"
#include <string.h>
#include <libgimp/gimp.h>
#include <libgimp/gimpui.h>
#include "libgimp/stdplugins-intl.h"
/* Some useful macros */
#define PLUG_IN_PROC "plug-in-photocopy"
#define PLUG_IN_BINARY "photocopy"
#define TILE_CACHE_SIZE 48
#define GAMMA 1.0
#define EPSILON 2
typedef struct
{
gdouble mask_radius;
gdouble sharpness;
gdouble threshold;
gdouble pct_black;
gdouble pct_white;
} PhotocopyVals;
/*
* Function prototypes.
*/
static void query (void);
static void run (const gchar *name,
gint nparams,
const GimpParam *param,
gint *nreturn_vals,
GimpParam **return_vals);
static void photocopy (GimpDrawable *drawable,
GimpPreview *preview);
static gboolean photocopy_dialog (GimpDrawable *drawable);
static gdouble compute_ramp (guchar *dest1,
guchar *dest2,
gint length,
gdouble pct_black,
gint under_threshold);
/*
* Gaussian blur helper functions
*/
static void find_constants (gdouble n_p[],
gdouble n_m[],
gdouble d_p[],
gdouble d_m[],
gdouble bd_p[],
gdouble bd_m[],
gdouble std_dev);
static void transfer_pixels (gdouble *src1,
gdouble *src2,
guchar *dest,
gint jump,
gint width);
/***** Local vars *****/
const GimpPlugInInfo PLUG_IN_INFO =
{
NULL, /* init */
NULL, /* quit */
query, /* query */
run, /* run */
};
static PhotocopyVals pvals =
{
8.0, /* mask_radius */
0.8, /* sharpness */
0.75, /* threshold */
0.2, /* pct_black */
0.2 /* pct_white */
};
/***** Functions *****/
MAIN ()
static void
query (void)
{
static const GimpParamDef args[] =
{
{ GIMP_PDB_INT32, "run-mode", "Interactive, non-interactive" },
{ GIMP_PDB_IMAGE, "image", "Input image (unused)" },
{ GIMP_PDB_DRAWABLE, "drawable", "Input drawable" },
{ GIMP_PDB_FLOAT, "mask-radius", "Photocopy mask radius (radius of pixel neighborhood)" },
{ GIMP_PDB_FLOAT, "sharpness", "Sharpness (detail level) (0.0 - 1.0)" },
{ GIMP_PDB_FLOAT, "pct-black", "Percentage of darkened pixels to set to black (0.0 - 1.0)" },
{ GIMP_PDB_FLOAT, "pct-white", "Percentage of non-darkened pixels left white (0.0 - 1.0)" }
};
gchar *help_string =
"Propagates dark values in an image based on "
"each pixel's relative darkness to a neighboring average. The idea behind "
"this filter is to give the look of a photocopied version of the image, "
"with toner transfered based on the relative darkness of a particular "
"region. This is achieved by darkening areas of the image which are "
"measured to be darker than a neighborhood average and setting other "
"pixels to white. In this way, sufficiently large shifts in intensity "
"are darkened to black. The rate at which they are darkened to black is "
"determined by the second pct_black parameter. The mask_radius parameter "
"controls the size of the pixel neighborhood over which the average "
"intensity is computed and then compared to each pixel in the neighborhood "
"to decide whether or not to darken it to black. Large values for "
"mask_radius result in very thick black areas bordering the regions "
"of white and much less detail for black areas everywhere including "
"inside regions of color. Small values result in less toner overall "
"and more detail everywhere. Small values for the pct_black make the "
"blend from the white regions to the black border lines smoother and "
"the toner regions themselves thinner and less noticable; larger values "
"achieve the opposite effect.";
gimp_install_procedure (PLUG_IN_PROC,
N_("Simulate color distortion produced by a copy machine"),
help_string,
"Spencer Kimball",
"Bit Specialists, Inc.",
"2001",
N_("_Photocopy..."),
"RGB*, GRAY*",
GIMP_PLUGIN,
G_N_ELEMENTS (args), 0,
args, NULL);
gimp_plugin_menu_register (PLUG_IN_PROC, "<Image>/Filters/Artistic");
}
static void
run (const gchar *name,
gint nparams,
const GimpParam *param,
gint *nreturn_vals,
GimpParam **return_vals)
{
static GimpParam values[1];
GimpRunMode run_mode;
GimpDrawable *drawable;
GimpPDBStatusType status = GIMP_PDB_SUCCESS;
run_mode = param[0].data.d_int32;
/* Get the specified drawable */
drawable = gimp_drawable_get (param[2].data.d_drawable);
/* set the tile cache size */
gimp_tile_cache_ntiles (TILE_CACHE_SIZE);
*nreturn_vals = 1;
*return_vals = values;
values[0].type = GIMP_PDB_STATUS;
values[0].data.d_status = status;
INIT_I18N();
switch (run_mode)
{
case GIMP_RUN_INTERACTIVE:
/* Possibly retrieve data */
gimp_get_data (PLUG_IN_PROC, &pvals);
/* First acquire information with a dialog */
if (! photocopy_dialog (drawable))
return;
break;
case GIMP_RUN_NONINTERACTIVE:
pvals.mask_radius = param[3].data.d_float;
pvals.sharpness = param[4].data.d_float;
pvals.pct_black = param[5].data.d_float;
pvals.pct_white = param[6].data.d_float;
break;
case GIMP_RUN_WITH_LAST_VALS:
/* Possibly retrieve data */
gimp_get_data (PLUG_IN_PROC, &pvals);
break;
default:
break;
}
if (status == GIMP_PDB_SUCCESS)
{
/* Make sure that the drawable is RGB or GRAY color */
if (gimp_drawable_is_rgb (drawable->drawable_id) ||
gimp_drawable_is_gray (drawable->drawable_id))
{
gimp_progress_init ("Photocopy");
photocopy (drawable, NULL);
if (run_mode != GIMP_RUN_NONINTERACTIVE)
gimp_displays_flush ();
/* Store data */
if (run_mode == GIMP_RUN_INTERACTIVE)
gimp_set_data (PLUG_IN_PROC, &pvals, sizeof (PhotocopyVals));
}
else
{
g_message (_("Cannot operate on indexed color images."));
status = GIMP_PDB_EXECUTION_ERROR;
}
}
values[0].data.d_status = status;
gimp_drawable_detach (drawable);
}
/*
* Photocopy algorithm
* -----------------
* Mask radius = radius of pixel neighborhood for intensity comparison
* Threshold = relative intensity difference which will result in darkening
* Ramp = amount of relative intensity difference before total black
* Blur radius = mask radius / 3.0
*
* Algorithm:
* For each pixel, calculate pixel intensity value to be: avg (blur radius)
* relative diff = pixel intensity / avg (mask radius)
* If relative diff < Threshold
* intensity mult = (Ramp - MIN (Ramp, (Threshold - relative diff))) / Ramp
* pixel intensity *= intensity mult
* Else
* pixel intensity = white
*/
static void
photocopy (GimpDrawable *drawable,
GimpPreview *preview)
{
GimpPixelRgn src_rgn, dest_rgn;
GimpPixelRgn *pr;
gint width, height;
gint bytes;
gboolean has_alpha;
guchar *dest1;
guchar *dest2;
guchar *src1, *sp_p1, *sp_m1;
guchar *src2, *sp_p2, *sp_m2;
gdouble n_p1[5], n_m1[5];
gdouble n_p2[5], n_m2[5];
gdouble d_p1[5], d_m1[5];
gdouble d_p2[5], d_m2[5];
gdouble bd_p1[5], bd_m1[5];
gdouble bd_p2[5], bd_m2[5];
gdouble *val_p1, *val_m1, *vp1, *vm1;
gdouble *val_p2, *val_m2, *vp2, *vm2;
gint x1, y1;
gint i, j;
gint row, col;
gint terms;
gint progress, max_progress;
gint initial_p1[4];
gint initial_p2[4];
gint initial_m1[4];
gint initial_m2[4];
gdouble radius;
gdouble val;
gdouble std_dev1;
gdouble std_dev2;
gdouble ramp_down;
gdouble ramp_up;
if (preview)
{
gimp_preview_get_position (preview, &x1, &y1);
gimp_preview_get_size (preview, &width, &height);
}
else
{
gint x2, y2;
gimp_drawable_mask_bounds (drawable->drawable_id, &x1, &y1, &x2, &y2);
width = x2 - x1;
height = y2 - y1;
}
bytes = drawable->bpp;
has_alpha = gimp_drawable_has_alpha (drawable->drawable_id);
val_p1 = g_new (gdouble, MAX (width, height));
val_p2 = g_new (gdouble, MAX (width, height));
val_m1 = g_new (gdouble, MAX (width, height));
val_m2 = g_new (gdouble, MAX (width, height));
dest1 = g_new0 (guchar, width * height);
dest2 = g_new0 (guchar, width * height);
progress = 0;
max_progress = width * height * 3;
gimp_pixel_rgn_init (&src_rgn, drawable,
x1, y1, width, height, FALSE, FALSE);
for (pr = gimp_pixel_rgns_register (1, &src_rgn);
pr != NULL;
pr = gimp_pixel_rgns_process (pr))
{
guchar *src_ptr = src_rgn.data;
guchar *dest_ptr = dest1 + (src_rgn.y - y1) * width + (src_rgn.x - x1);
for (row = 0; row < src_rgn.h; row++)
{
for (col = 0; col < src_rgn.w; col++)
{
/* desaturate */
if (bytes > 2)
dest_ptr[col] = (guchar) gimp_rgb_to_l_int (src_ptr[col * bytes + 0],
src_ptr[col * bytes + 1],
src_ptr[col * bytes + 2]);
else
dest_ptr[col] = (guchar) src_ptr[col * bytes];
/* compute transfer */
val = pow (dest_ptr[col], (1.0 / GAMMA));
dest_ptr[col] = (guchar) CLAMP (val, 0, 255);
}
src_ptr += src_rgn.rowstride;
dest_ptr += width;
}
if (!preview)
{
progress += src_rgn.w * src_rgn.h;
gimp_progress_update ((gdouble) progress / (gdouble) max_progress);
}
}
/* Calculate the standard deviations */
radius = MAX (1.0, 10 * (1.0 - pvals.sharpness));
radius = fabs (radius) + 1.0;
std_dev1 = sqrt (-(radius * radius) / (2 * log (1.0 / 255.0)));
radius = fabs (pvals.mask_radius) + 1.0;
std_dev2 = sqrt (-(radius * radius) / (2 * log (1.0 / 255.0)));
/* derive the constants for calculating the gaussian from the std dev */
find_constants (n_p1, n_m1, d_p1, d_m1, bd_p1, bd_m1, std_dev1);
find_constants (n_p2, n_m2, d_p2, d_m2, bd_p2, bd_m2, std_dev2);
/* First the vertical pass */
for (col = 0; col < width; col++)
{
memset (val_p1, 0, height * sizeof (gdouble));
memset (val_p2, 0, height * sizeof (gdouble));
memset (val_m1, 0, height * sizeof (gdouble));
memset (val_m2, 0, height * sizeof (gdouble));
src1 = dest1 + col;
sp_p1 = src1;
sp_m1 = src1 + (height - 1) * width;
vp1 = val_p1;
vp2 = val_p2;
vm1 = val_m1 + (height - 1);
vm2 = val_m2 + (height - 1);
/* Set up the first vals */
initial_p1[0] = sp_p1[0];
initial_m1[0] = sp_m1[0];
for (row = 0; row < height; row++)
{
gdouble *vpptr1, *vmptr1;
gdouble *vpptr2, *vmptr2;
terms = (row < 4) ? row : 4;
vpptr1 = vp1; vmptr1 = vm1;
vpptr2 = vp2; vmptr2 = vm2;
for (i = 0; i <= terms; i++)
{
*vpptr1 += n_p1[i] * sp_p1[-i * width] - d_p1[i] * vp1[-i];
*vmptr1 += n_m1[i] * sp_m1[i * width] - d_m1[i] * vm1[i];
*vpptr2 += n_p2[i] * sp_p1[-i * width] - d_p2[i] * vp2[-i];
*vmptr2 += n_m2[i] * sp_m1[i * width] - d_m2[i] * vm2[i];
}
for (j = i; j <= 4; j++)
{
*vpptr1 += (n_p1[j] - bd_p1[j]) * initial_p1[0];
*vmptr1 += (n_m1[j] - bd_m1[j]) * initial_m1[0];
*vpptr2 += (n_p2[j] - bd_p2[j]) * initial_p1[0];
*vmptr2 += (n_m2[j] - bd_m2[j]) * initial_m1[0];
}
sp_p1 += width;
sp_m1 -= width;
vp1 += 1;
vp2 += 1;
vm1 -= 1;
vm2 -= 1;
}
transfer_pixels (val_p1, val_m1, dest1 + col, width, height);
transfer_pixels (val_p2, val_m2, dest2 + col, width, height);
if (!preview)
{
progress += height;
if ((col % 5) == 0)
gimp_progress_update ((gdouble) progress / (gdouble) max_progress);
}
}
for (row = 0; row < height; row++)
{
memset (val_p1, 0, width * sizeof (gdouble));
memset (val_p2, 0, width * sizeof (gdouble));
memset (val_m1, 0, width * sizeof (gdouble));
memset (val_m2, 0, width * sizeof (gdouble));
src1 = dest1 + row * width;
src2 = dest2 + row * width;
sp_p1 = src1;
sp_p2 = src2;
sp_m1 = src1 + width - 1;
sp_m2 = src2 + width - 1;
vp1 = val_p1;
vp2 = val_p2;
vm1 = val_m1 + width - 1;
vm2 = val_m2 + width - 1;
/* Set up the first vals */
initial_p1[0] = sp_p1[0];
initial_p2[0] = sp_p2[0];
initial_m1[0] = sp_m1[0];
initial_m2[0] = sp_m2[0];
for (col = 0; col < width; col++)
{
gdouble *vpptr1, *vmptr1;
gdouble *vpptr2, *vmptr2;
terms = (col < 4) ? col : 4;
vpptr1 = vp1; vmptr1 = vm1;
vpptr2 = vp2; vmptr2 = vm2;
for (i = 0; i <= terms; i++)
{
*vpptr1 += n_p1[i] * sp_p1[-i] - d_p1[i] * vp1[-i];
*vmptr1 += n_m1[i] * sp_m1[i] - d_m1[i] * vm1[i];
*vpptr2 += n_p2[i] * sp_p2[-i] - d_p2[i] * vp2[-i];
*vmptr2 += n_m2[i] * sp_m2[i] - d_m2[i] * vm2[i];
}
for (j = i; j <= 4; j++)
{
*vpptr1 += (n_p1[j] - bd_p1[j]) * initial_p1[0];
*vmptr1 += (n_m1[j] - bd_m1[j]) * initial_m1[0];
*vpptr2 += (n_p2[j] - bd_p2[j]) * initial_p2[0];
*vmptr2 += (n_m2[j] - bd_m2[j]) * initial_m2[0];
}
sp_p1 ++;
sp_p2 ++;
sp_m1 --;
sp_m2 --;
vp1 ++;
vp2 ++;
vm1 --;
vm2 --;
}
transfer_pixels (val_p1, val_m1, dest1 + row * width, 1, width);
transfer_pixels (val_p2, val_m2, dest2 + row * width, 1, width);
if (!preview)
{
progress += width;
if ((row % 5) == 0)
gimp_progress_update ((gdouble) progress / (gdouble) max_progress);
}
}
/* Compute the ramp value which sets 'pct_black' % of the darkened pixels black */
ramp_down = compute_ramp (dest1, dest2, width * height, pvals.pct_black, 1);
ramp_up = compute_ramp (dest1, dest2, width * height, 1.0 - pvals.pct_white, 0);
/* Initialize the pixel regions. */
gimp_pixel_rgn_init (&src_rgn, drawable, x1, y1, width, height, FALSE, FALSE);
gimp_pixel_rgn_init (&dest_rgn, drawable, x1, y1, width, height,
(preview == NULL), TRUE);
pr = gimp_pixel_rgns_register (2, &src_rgn, &dest_rgn);
while (pr)
{
guchar *src_ptr = src_rgn.data;
guchar *dest_ptr = dest_rgn.data;
guchar *blur_ptr = dest1 + (src_rgn.y - y1) * width + (src_rgn.x - x1);
guchar *avg_ptr = dest2 + (src_rgn.y - y1) * width + (src_rgn.x - x1);
gdouble diff, mult;
gdouble lightness = 0.0;
for (row = 0; row < src_rgn.h; row++)
{
for (col = 0; col < src_rgn.w; col++)
{
if (avg_ptr[col] > EPSILON)
{
diff = (gdouble) blur_ptr[col] / (gdouble) avg_ptr[col];
if (diff < pvals.threshold)
{
if (ramp_down == 0.0)
mult = 0.0;
else
mult = (ramp_down - MIN (ramp_down,
(pvals.threshold - diff))) / ramp_down;
lightness = CLAMP (blur_ptr[col] * mult, 0, 255);
}
else
{
if (ramp_up == 0.0)
mult = 1.0;
else
mult = MIN (ramp_up,
(diff - pvals.threshold)) / ramp_up;
lightness = 255 - (1.0 - mult) * (255 - blur_ptr[col]);
lightness = CLAMP (lightness, 0, 255);
}
}
else
{
lightness = 0;
}
if (bytes < 3)
{
dest_ptr[col * bytes] = (guchar) lightness;
if (has_alpha)
dest_ptr[col * bytes + 1] = src_ptr[col * src_rgn.bpp + 1];
}
else
{
dest_ptr[col * bytes + 0] = lightness;
dest_ptr[col * bytes + 1] = lightness;
dest_ptr[col * bytes + 2] = lightness;
if (has_alpha)
dest_ptr[col * bytes + 3] = src_ptr[col * src_rgn.bpp + 3];
}
}
src_ptr += src_rgn.rowstride;
dest_ptr += dest_rgn.rowstride;
blur_ptr += width;
avg_ptr += width;
}
if (preview)
{
gimp_drawable_preview_draw_region (GIMP_DRAWABLE_PREVIEW (preview),
&dest_rgn);
}
else
{
progress += src_rgn.w * src_rgn.h;
gimp_progress_update ((gdouble) progress / (gdouble) max_progress);
}
pr = gimp_pixel_rgns_process (pr);
}
if (! preview)
{
/* merge the shadow, update the drawable */
gimp_drawable_flush (drawable);
gimp_drawable_merge_shadow (drawable->drawable_id, TRUE);
gimp_drawable_update (drawable->drawable_id, x1, y1, width, height);
}
/* free up buffers */
g_free (val_p1);
g_free (val_p2);
g_free (val_m1);
g_free (val_m2);
g_free (dest1);
g_free (dest2);
}
static gdouble
compute_ramp (guchar *dest1,
guchar *dest2,
gint length,
gdouble pct,
gint under_threshold)
{
gint hist[2000];
gdouble diff;
gint count;
gint i;
gint sum;
memset (hist, 0, sizeof (int) * 2000);
count = 0;
for (i = 0; i < length; i++)
{
if (*dest2 != 0)
{
diff = (gdouble) *dest1 / (gdouble) *dest2;
if (under_threshold)
{
if (diff < pvals.threshold)
{
hist[(int) (diff * 1000)] += 1;
count += 1;
}
}
else
{
if (diff >= pvals.threshold && diff < 2.0)
{
hist[(int) (diff * 1000)] += 1;
count += 1;
}
}
}
dest1++;
dest2++;
}
if (pct == 0.0 || count == 0)
return (under_threshold ? 1.0 : 0.0);
sum = 0;
for (i = 0; i < 2000; i++)
{
sum += hist[i];
if (((gdouble) sum / (gdouble) count) > pct)
{
if (under_threshold)
return (pvals.threshold - (gdouble) i / 1000.0);
else
return ((gdouble) i / 1000.0 - pvals.threshold);
}
}
return (under_threshold ? 0.0 : 1.0);
}
/*
* Gaussian blur helper functions
*/
static void
transfer_pixels (gdouble *src1,
gdouble *src2,
guchar *dest,
gint jump,
gint width)
{
gint i;
gdouble sum;
for(i = 0; i < width; i++)
{
sum = src1[i] + src2[i];
if (sum > 255) sum = 255;
else if(sum < 0) sum = 0;
*dest = (guchar) sum;
dest += jump;
}
}
static void
find_constants (gdouble n_p[],
gdouble n_m[],
gdouble d_p[],
gdouble d_m[],
gdouble bd_p[],
gdouble bd_m[],
gdouble std_dev)
{
gint i;
gdouble constants [8];
gdouble div;
/* The constants used in the implemenation of a casual sequence
* using a 4th order approximation of the gaussian operator
*/
div = sqrt (2 * G_PI) * std_dev;
constants [0] = -1.783 / std_dev;
constants [1] = -1.723 / std_dev;
constants [2] = 0.6318 / std_dev;
constants [3] = 1.997 / std_dev;
constants [4] = 1.6803 / div;
constants [5] = 3.735 / div;
constants [6] = -0.6803 / div;
constants [7] = -0.2598 / div;
n_p [0] = constants[4] + constants[6];
n_p [1] = exp (constants[1]) *
(constants[7] * sin (constants[3]) -
(constants[6] + 2 * constants[4]) * cos (constants[3])) +
exp (constants[0]) *
(constants[5] * sin (constants[2]) -
(2 * constants[6] + constants[4]) * cos (constants[2]));
n_p [2] = 2 * exp (constants[0] + constants[1]) *
((constants[4] + constants[6]) * cos (constants[3]) * cos (constants[2]) -
constants[5] * cos (constants[3]) * sin (constants[2]) -
constants[7] * cos (constants[2]) * sin (constants[3])) +
constants[6] * exp (2 * constants[0]) +
constants[4] * exp (2 * constants[1]);
n_p [3] = exp (constants[1] + 2 * constants[0]) *
(constants[7] * sin (constants[3]) - constants[6] * cos (constants[3])) +
exp (constants[0] + 2 * constants[1]) *
(constants[5] * sin (constants[2]) - constants[4] * cos (constants[2]));
n_p [4] = 0.0;
d_p [0] = 0.0;
d_p [1] = -2 * exp (constants[1]) * cos (constants[3]) -
2 * exp (constants[0]) * cos (constants[2]);
d_p [2] = 4 * cos (constants[3]) * cos (constants[2]) * exp (constants[0] + constants[1]) +
exp (2 * constants[1]) + exp (2 * constants[0]);
d_p [3] = -2 * cos (constants[2]) * exp (constants[0] + 2 * constants[1]) -
2 * cos (constants[3]) * exp (constants[1] + 2 * constants[0]);
d_p [4] = exp (2 * constants[0] + 2 * constants[1]);
#ifndef ORIGINAL_READABLE_CODE
memcpy(d_m, d_p, 5 * sizeof(gdouble));
#else
for (i = 0; i <= 4; i++)
d_m [i] = d_p [i];
#endif
n_m[0] = 0.0;
for (i = 1; i <= 4; i++)
n_m [i] = n_p[i] - d_p[i] * n_p[0];
{
gdouble sum_n_p, sum_n_m, sum_d;
gdouble a, b;
sum_n_p = 0.0;
sum_n_m = 0.0;
sum_d = 0.0;
for (i = 0; i <= 4; i++)
{
sum_n_p += n_p[i];
sum_n_m += n_m[i];
sum_d += d_p[i];
}
#ifndef ORIGINAL_READABLE_CODE
sum_d++;
a = sum_n_p / sum_d;
b = sum_n_m / sum_d;
#else
a = sum_n_p / (1 + sum_d);
b = sum_n_m / (1 + sum_d);
#endif
for (i = 0; i <= 4; i++)
{
bd_p[i] = d_p[i] * a;
bd_m[i] = d_m[i] * b;
}
}
}
/*******************************************************/
/* Dialog */
/*******************************************************/
static gboolean
photocopy_dialog (GimpDrawable *drawable)
{
GtkWidget *dialog;
GtkWidget *main_vbox;
GtkWidget *preview;
GtkWidget *table;
GtkObject *scale_data;
gboolean run;
gimp_ui_init (PLUG_IN_BINARY, FALSE);
dialog = gimp_dialog_new (_("Photocopy"), PLUG_IN_BINARY,
NULL, 0,
gimp_standard_help_func, PLUG_IN_PROC,
GTK_STOCK_CANCEL, GTK_RESPONSE_CANCEL,
GTK_STOCK_OK, GTK_RESPONSE_OK,
NULL);
gtk_dialog_set_alternative_button_order (GTK_DIALOG (dialog),
GTK_RESPONSE_OK,
GTK_RESPONSE_CANCEL,
-1);
gimp_window_set_transient (GTK_WINDOW (dialog));
main_vbox = gtk_vbox_new (FALSE, 12);
gtk_container_set_border_width (GTK_CONTAINER (main_vbox), 12);
gtk_container_add (GTK_CONTAINER (GTK_DIALOG (dialog)->vbox), main_vbox);
gtk_widget_show (main_vbox);
preview = gimp_drawable_preview_new (drawable, NULL);
gtk_box_pack_start (GTK_BOX (main_vbox), preview, TRUE, TRUE, 0);
gtk_widget_show (preview);
g_signal_connect_swapped (preview, "invalidated",
G_CALLBACK (photocopy),
drawable);
table = gtk_table_new (4, 3, FALSE);
gtk_table_set_col_spacings (GTK_TABLE (table), 6);
gtk_table_set_row_spacings (GTK_TABLE (table), 6);
gtk_box_pack_start (GTK_BOX (main_vbox), table, FALSE, FALSE, 0);
gtk_widget_show (table);
/* Label, scale, entry for pvals.amount */
scale_data = gimp_scale_entry_new (GTK_TABLE (table), 0, 0,
_("_Mask radius:"), 100, 5,
pvals.mask_radius, 3.0, 50.0, 1, 5.0, 2,
TRUE, 0, 0,
NULL, NULL);
g_signal_connect (scale_data, "value-changed",
G_CALLBACK (gimp_double_adjustment_update),
&pvals.mask_radius);
g_signal_connect_swapped (scale_data, "value-changed",
G_CALLBACK (gimp_preview_invalidate),
preview);
/* Label, scale, entry for pvals.amount */
scale_data = gimp_scale_entry_new (GTK_TABLE (table), 0, 1,
_("_Sharpness:"), 50, 5,
pvals.sharpness, 0.0, 1.0, 0.01, 0.1, 3,
TRUE, 0, 0,
NULL, NULL);
g_signal_connect (scale_data, "value-changed",
G_CALLBACK (gimp_double_adjustment_update),
&pvals.sharpness);
g_signal_connect_swapped (scale_data, "value-changed",
G_CALLBACK (gimp_preview_invalidate),
preview);
/* Label, scale, entry for pvals.amount */
scale_data = gimp_scale_entry_new (GTK_TABLE (table), 0, 2,
_("Percent _black:"), 50, 5,
pvals.pct_black, 0.0, 1.0, 0.01, 0.1, 3,
TRUE, 0, 0,
NULL, NULL);
g_signal_connect (scale_data, "value-changed",
G_CALLBACK (gimp_double_adjustment_update),
&pvals.pct_black);
g_signal_connect_swapped (scale_data, "value-changed",
G_CALLBACK (gimp_preview_invalidate),
preview);
/* Label, scale, entry for pvals.amount */
scale_data = gimp_scale_entry_new (GTK_TABLE (table), 0, 3,
_("Percent _white:"), 50, 5,
pvals.pct_white, 0.0, 1.0, 0.01, 0.1, 3,
TRUE, 0, 0,
NULL, NULL);
g_signal_connect (scale_data, "value-changed",
G_CALLBACK (gimp_double_adjustment_update),
&pvals.pct_white);
g_signal_connect_swapped (scale_data, "value-changed",
G_CALLBACK (gimp_preview_invalidate),
preview);
gtk_widget_show (dialog);
run = (gimp_dialog_run (GIMP_DIALOG (dialog)) == GTK_RESPONSE_OK);
gtk_widget_destroy (dialog);
return run;
}
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