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* Start working on colour reduction with a constrained palette. 

git-svn-id: file:///srv/caca.zoy.org/var/lib/svn/libpipi/trunk@2726 92316355-f0b4-4df1-b90c-862c8a59935f
remotes/tiles
sam 16 years ago
parent
e50ce5c67a
commit
13bbfb8b27
1 changed files with 130 additions and 10 deletions
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  1. +130
    -10
      examples/img2rubik.c

+ 130
- 10
examples/img2rubik.c View File

@@ -4,26 +4,146 @@
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <math.h>

#include <pipi.h>

#define Y(x) (0.299*(x)[0] + 0.587*(x)[1] + 0.114*(x)[2])

#define STEPS 16
#define EPSILON (0.000001)

int main(int argc, char *argv[])
{
char *srcname = NULL, *dstname = NULL;
pipi_image_t *img;
double palette[][3] =
{
{ 1.0, 0.0, 0.0 }, /* red */
{ 0.0, 1.0, 0.0 }, /* green */
{ 0.0, 0.0, 1.0 }, /* blue */
{ 1.0, 1.0, 1.0 }, /* white */
{ 1.0, 1.0, 0.0 }, /* yellow */
{ 1.0, 0.5, 0.0 }, /* orange */
};
#define NCOLORS ((int)(sizeof(palette)/sizeof(*palette)))

if(argc < 3)
double tmp;
int i, j;

/*
* 1. Find the darkest and lightest colours
*/
double *dark = NULL, *light = NULL;
double min = 1.0, max = 0.0;
for(i = 0; i < NCOLORS; i++)
{
fprintf(stderr, "%s: too few arguments\n", argv[0]);
return EXIT_FAILURE;
double p = Y(palette[i]);
if(p < min)
{
dark = palette[i];
min = p;
}
if(p > max)
{
light = palette[i];
max = p;
}
}
printf("lightest (%g,%g,%g)\n", light[0], light[1], light[2]);
printf("darkest (%g,%g,%g)\n", dark[0], dark[1], dark[2]);

/*
* 2. Find two base vectors for the chrominance planes
* FIXME: this doesn't work in all cases because u can be null
*/
double y[3], u[3], v[3];
double ylen;

y[0] = light[0] - dark[0];
y[1] = light[1] - dark[1];
y[2] = light[2] - dark[2];
ylen = sqrt(y[0] * y[0] + y[1] * y[1] + y[2] * y[2]);

u[0] = y[1];
u[1] = -y[0];
u[2] = 0;
tmp = sqrt(u[0] * u[0] + u[1] * u[1] + u[2] * u[2]);
u[0] /= tmp; u[1] /= tmp; u[2] /= tmp;

v[0] = y[1] * u[2] - y[2] * u[1];
v[1] = y[2] * u[0] - y[0] * u[2];
v[2] = y[0] * u[1] - y[1] * u[0];
tmp = sqrt(v[0] * v[0] + v[1] * v[1] + v[2] * v[2]);
v[0] /= tmp; v[1] /= tmp; v[2] /= tmp;

printf("gray axis (%g,%g,%g) - length %g\n", y[0], y[1], y[2], ylen);
printf("u (%g,%g,%g)\n", u[0], u[1], u[2]);
printf("v (%g,%g,%g)\n", v[0], v[1], v[2]);

/*
* 3. Browse the grey axis and do stuff
*/
double t;
for(t = 0.; t <= 1.0; t += 1. / STEPS)
{
double pts[NCOLORS*NCOLORS/2][3];
double p0[3];
int npts = 0;

p0[0] = dark[0] + t * y[0];
p0[1] = dark[1] + t * y[1];
p0[2] = dark[2] + t * y[2];
printf("%g,%g,%g\n", p0[0], p0[1], p0[2]);

/*
* 3.1. Find all edges that intersect the t.y + (u,v) plane
*/
for(i = 0; i < NCOLORS; i++)
{
double k1[3];
k1[0] = palette[i][0] - dark[0];
k1[1] = palette[i][1] - dark[1];
k1[2] = palette[i][2] - dark[2];
tmp = sqrt(k1[0] * k1[0] + k1[1] * k1[1] + k1[2] * k1[2]);

/* If k1.y > t.y.y, we don't want this point */
double yk1 = y[0] * k1[0] + y[1] * k1[1] + y[2] * k1[2];
if(yk1 > t * ylen * ylen + EPSILON)
continue;

for(j = 0; j < NCOLORS; j++)
{
if(i == j)
continue;

srcname = argv[1];
dstname = argv[2];
double k2[3];
k2[0] = palette[j][0] - dark[0];
k2[1] = palette[j][1] - dark[1];
k2[2] = palette[j][2] - dark[2];
tmp = sqrt(k2[0] * k2[0] + k2[1] * k2[1] + k2[2] * k2[2]);

img = pipi_load(srcname);
pipi_save(img, dstname);
pipi_free(img);
/* If k2.y < t.y.y, we don't want this point */
double yk2 = y[0] * k2[0] + y[1] * k2[1] + y[2] * k2[2];
if(yk2 < t * ylen * ylen - EPSILON)
continue;

if(yk2 < yk1)
continue;

double s = yk1 == yk2 ?
0.5 : (t * ylen * ylen - yk1) / (yk2 - yk1);

pts[npts][0] = dark[0] + k1[0] + s * (k2[0] - k1[0]);
pts[npts][1] = dark[1] + k1[1] + s * (k2[1] - k1[1]);
pts[npts][2] = dark[2] + k1[2] + s * (k2[2] - k1[2]);
printf(" %i,%i: s = (%g,%g,%g)\n", i, j, pts[npts][0], pts[npts][1], pts[npts][2]);
npts++;
}
}

/*
* 3.2. Find the barycentre of these points' convex hull. (TODO)
*/
}

return 0;
}


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