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/*
* render.c
*
* Render a high dynamic range buffer in some sensible way
*
* (c) 2006-2010 Thomas White <taw@physics.org>
*
* Part of CrystFEL - crystallography with a FEL
*
*/
#ifdef HAVE_CONFIG_H
#include <config.h>
#endif
#include <stdlib.h>
#include <gdk-pixbuf/gdk-pixbuf.h>
#include <math.h>
#include <stdint.h>
#include "hdf5-file.h"
#include "render.h"
#include "peaks.h"
#include "filters.h"
static void *render_bin(int16_t *in, int inw, int inh,
int binning, int16_t *maxp)
{
int16_t *data;
int x, y;
int w, h;
int16_t max;
w = inw / binning;
h = inh / binning; /* Some pixels might get discarded */
data = malloc(w*h*sizeof(int16_t));
max = 0;
for ( x=0; x<w; x++ ) {
for ( y=0; y<h; y++ ) {
/* Big enough to hold large values */
unsigned long long int total;
size_t xb, yb;
total = 0;
for ( xb=0; xb<binning; xb++ ) {
for ( yb=0; yb<binning; yb++ ) {
total += in[binning*x+xb + (binning*y+yb)*(w*binning)];
}
}
data[x+w*y] = total / (binning * binning);
if ( data[x+w*y] > max ) max = data[x+w*y];
}
}
*maxp = max;
return data;
}
int16_t *render_get_image_binned(DisplayWindow *dw, int binning, int16_t *max)
{
struct image *image;
int16_t *data;
if ( (dw->image == NULL) || (dw->image_dirty) ) {
image = malloc(sizeof(struct image));
if ( image == NULL ) return NULL;
image->features = NULL;
image->data = NULL;
hdf5_read(dw->hdfile, image);
dw->image_dirty = 0;
clean_image(image);
/* Deal with the old image, if existing */
if ( dw->image != NULL ) {
image->features = dw->image->features;
if ( dw->image->data != NULL ) free(dw->image->data);
}
dw->image = image;
}
data = render_bin(dw->image->data, hdfile_get_width(dw->hdfile),
hdfile_get_height(dw->hdfile), binning, max);
return data;
}
#define RENDER_RGB \
\
int s; \
float p; \
\
s = val / (max/6); \
p = fmod(val, max/6); \
p /= (max/6); \
\
r = 0; g = 0; b = 0; \
\
if ( (val < 0.0) || (val > max) ) { \
s = 0; \
p = 0.0; \
} \
switch ( s ) { \
case 0 : { /* Black to blue */ \
r = 0; g = 0; b = p*255; \
break; \
} \
case 1 : { /* Blue to green */ \
r = 0; g = 255*p; b = (1-p)*255; \
break; \
} \
case 2 : { /* Green to red */ \
r =p*255; g = (1-p)*255; b = 0; \
break; \
} \
case 3 : { /* Red to Orange */ \
r = 255; g = 127*p; b = 0; \
break; \
} \
case 4 : { /* Orange to Yellow */ \
r = 255; g = 127 + 127*p; b = 0; \
break; \
} \
case 5 : { /* Yellow to White */ \
r = 255; g = 255; b = 255*p; \
break; \
} \
case 6 : { /* Pixel has hit the maximum value */ \
r = 255; g = 255; b = 255; \
break; \
} \
default : { /* Above saturation */ \
r = 255; g = 255; b = 255; \
break; \
} \
}
#define RENDER_MONO \
float p; \
p = (float)val / (float)max; \
if ( val < 0.0 ) p = 0.0; \
if ( val > max ) p = 0.0; \
r = 255.0*p; g = 255.0*p; b = 255.0*p;
/* NB This function is shared between render_get_image() and
* render_get_colour_scale() */
static void render_free_data(guchar *data, gpointer p)
{
free(data);
}
static void show_marked_features(struct image *image, guchar *data,
int w, int h, int binning)
{
int i;
if ( image->features == NULL ) return;
for ( i=0; i<image_feature_count(image->features); i++ ) {
struct imagefeature *f;
int x, y;
double th;
f = image_get_feature(image->features, i);
if ( f == NULL ) continue;
x = f->x; y = f->y;
x /= binning;
y /= binning;
for ( th=0; th<2*M_PI; th+=M_PI/40.0 ) {
int nx, ny;
nx = x + 10.0*cos(th);
ny = y + 10.0*sin(th);
if ( nx < 0 ) continue;
if ( ny < 0 ) continue;
if ( nx >= w ) continue;
if ( ny >= h ) continue;
data[3*( nx+w*(h-1-ny) )+0] = 255;
}
}
}
/* Return a pixbuf containing a rendered version of the image after binning.
* This pixbuf might be scaled later - hopefully mostly in a downward
* direction. */
GdkPixbuf *render_get_image(DisplayWindow *dw)
{
int mw, mh, w, h;
guchar *data;
int16_t *hdr;
size_t x, y;
int16_t max;
mw = hdfile_get_width(dw->hdfile);
mh = hdfile_get_height(dw->hdfile);
w = mw / dw->binning;
h = mh / dw->binning;
/* High dynamic range version */
hdr = render_get_image_binned(dw, dw->binning, &max);
if ( hdr == NULL ) return NULL;
/* Rendered (colourful) version */
data = malloc(3*w*h);
if ( data == NULL ) {
free(hdr);
return NULL;
}
max /= dw->boostint;
if ( max <= 6 ) { max = 10; }
/* These x,y coordinates are measured relative to the bottom-left
* corner */
for ( y=0; y<h; y++ ) {
for ( x=0; x<w; x++ ) {
int val;
guchar r, g, b;
val = hdr[x+w*y];
if ( !dw->monochrome ) {
RENDER_RGB
} else {
RENDER_MONO
}
/* Stuff inside square brackets makes this pixel go to
* the expected location in the pixbuf (which measures
* from the top-left corner */
data[3*( x+w*(h-1-y) )+0] = r;
data[3*( x+w*(h-1-y) )+1] = g;
data[3*( x+w*(h-1-y) )+2] = b;
}
}
show_marked_features(dw->image, data, w, h, dw->binning);
/* Finished with this */
free(hdr);
/* Create the pixbuf from the 8-bit display data */
return gdk_pixbuf_new_from_data(data, GDK_COLORSPACE_RGB, FALSE, 8,
w, h, w*3, render_free_data, NULL);
}
GdkPixbuf *render_get_colour_scale(size_t w, size_t h, int monochrome)
{
guchar *data;
size_t x, y;
int max;
data = malloc(3*w*h);
if ( data == NULL ) return NULL;
max = h;
for ( y=0; y<h; y++ ) {
guchar r, g, b;
int val;
val = y;
if ( !monochrome ) {
RENDER_RGB
} else {
RENDER_MONO
}
data[3*( 0+w*(h-1-y) )+0] = 0;
data[3*( 0+w*(h-1-y) )+1] = 0;
data[3*( 0+w*(h-1-y) )+2] = 0;
for ( x=1; x<w; x++ ) {
data[3*( x+w*(h-1-y) )+0] = r;
data[3*( x+w*(h-1-y) )+1] = g;
data[3*( x+w*(h-1-y) )+2] = b;
}
}
return gdk_pixbuf_new_from_data(data, GDK_COLORSPACE_RGB, FALSE, 8,
w, h, w*3, render_free_data, NULL);
}
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