src/px/clrtab.c

/* Copyright (c) 1993 Regents of the University of California */

#ifndef lint
static char SCCSid[] = "$SunId$ LBL";
#endif

/*
 * Simple median-cut color quantization based on colortab.c
 */

#include "standard.h"

#include "color.h"
                                /* histogram resolution */
#define NRED            36
#define NGRN            48
#define NBLU            24
#define HMAX            NGRN
                                /* minimum box count for adaptive partition */
#define MINSAMP         7
                                /* color partition */
#define set_branch(p,c) ((c)<<2|(p))
#define part(cn)        ((cn)>>2)
#define prim(cn)        ((cn)&3)
                                /* our color table (global) */
extern BYTE     clrtab[256][3];
                                /* histogram of colors / color assignments */
static unsigned histo[NRED][NGRN][NBLU];
#define cndx(c)         histo[((c)[RED]*NRED)>>8][((c)[GRN]*NGRN)>>8][((c)[BLU]*NBLU)>>8]
                                /* initial color cube boundary */
static int      CLRCUBE[3][2] = {0,NRED,0,NGRN,0,NBLU};
                                /* maximum propagated error during dithering */
#define MAXERR          20
                                /* define CLOSEST to get closest colors */
#ifndef CLOSEST
#ifdef SPEED
#if  SPEED > 8
#define CLOSEST         1       /* this step takes a little longer */
#endif
#endif
#endif


new_histo(n)            /* clear our histogram */
int     n;
{
        bzero((char *)histo, sizeof(histo));
        return(0);
}


cnt_pixel(col)          /* add pixel to our histogram */
register BYTE   col[];
{
        cndx(col)++;
}


cnt_colrs(cs, n)                /* add a scanline to our histogram */
register COLR   *cs;
register int    n;
{
        while (n-- > 0) {
                cndx(cs[0])++;
                cs++;
        }
}


new_clrtab(ncolors)             /* make new color table using ncolors */
int     ncolors;
{
        if (ncolors < 1)
                return(0);
        if (ncolors > 256)
                ncolors = 256;
                                /* partition color space */
        cut(CLRCUBE, 0, ncolors);
#ifdef CLOSEST
        closest(ncolors);       /* ensure colors picked are closest */
#endif
                                /* reset dithering function */
        dith_colrs((BYTE *)NULL, (COLR *)NULL, 0);
                                /* return new color table size */
        return(ncolors);
}


int
map_pixel(col)                  /* get pixel for color */
register BYTE   col[];
{
    return(cndx(col));
}


map_colrs(bs, cs, n)            /* convert a scanline to color index values */
register BYTE   *bs;
register COLR   *cs;
register int    n;
{
        while (n-- > 0) {
                *bs++ = cndx(cs[0]);
                cs++;
        }
}


dith_colrs(bs, cs, n)           /* convert scanline to dithered index values */
register BYTE   *bs;
register COLR   *cs;
int     n;
{
        static short    (*cerr)[3] = NULL;
        static int      N = 0;
        int     err[3], errp[3];
        register int    x, i;

        if (n != N) {           /* get error propogation array */
                if (N) {
                        free((char *)cerr);
                        cerr = NULL;
                }
                if (n)
                        cerr = (short (*)[3])malloc(3*n*sizeof(short));
                if (cerr == NULL) {
                        N = 0;
                        map_colrs(bs, cs, n);
                        return;
                }
                N = n;
                bzero((char *)cerr, 3*N*sizeof(short));
        }
        err[0] = err[1] = err[2] = 0;
        for (x = 0; x < n; x++) {
                for (i = 0; i < 3; i++) {       /* dither value */
                        errp[i] = err[i];
                        err[i] += cerr[x][i];
#ifdef MAXERR
                        if (err[i] > MAXERR) err[i] = MAXERR;
                        else if (err[i] < -MAXERR) err[i] = -MAXERR;
#endif
                        err[i] += cs[x][i];
                        if (err[i] < 0) err[i] = 0;
                        else if (err[i] > 255) err[i] = 255;
                }
                bs[x] = cndx(err);
                for (i = 0; i < 3; i++) {       /* propagate error */
                        err[i] -= clrtab[bs[x]][i];
                        err[i] /= 3;
                        cerr[x][i] = err[i] + errp[i];
                }
        }
}


static
cut(box, c0, c1)                        /* partition color space */
register int    box[3][2];
int     c0, c1;
{
        register int    branch;
        int     kb[3][2];
        
        if (c1-c0 <= 1) {               /* assign pixel */
                mktabent(c0, box);
                return;
        }
                                        /* split box */
        branch = split(box);
        bcopy((char *)box, (char *)kb, sizeof(kb));
                                                /* do left (lesser) branch */
        kb[prim(branch)][1] = part(branch);
        cut(kb, c0, (c0+c1)>>1);
                                                /* do right branch */
        kb[prim(branch)][0] = part(branch);
        kb[prim(branch)][1] = box[prim(branch)][1];
        cut(kb, (c0+c1)>>1, c1);
}


static int
split(box)                              /* find median cut for box */
register int    box[3][2];
{
#define c0      r
        register int    r, g, b;
        int     pri;
        long    t[HMAX], med;
                                        /* find dominant axis */
        pri = RED;
        if (box[GRN][1]-box[GRN][0] > box[pri][1]-box[pri][0])
                pri = GRN;
        if (box[BLU][1]-box[BLU][0] > box[pri][1]-box[pri][0])
                pri = BLU;
                                        /* sum histogram over box */
        med = 0;
        switch (pri) {
        case RED:
                for (r = box[RED][0]; r < box[RED][1]; r++) {
                        t[r] = 0;
                        for (g = box[GRN][0]; g < box[GRN][1]; g++)
                                for (b = box[BLU][0]; b < box[BLU][1]; b++)
                                        t[r] += histo[r][g][b];
                        med += t[r];
                }
                break;
        case GRN:
                for (g = box[GRN][0]; g < box[GRN][1]; g++) {
                        t[g] = 0;
                        for (b = box[BLU][0]; b < box[BLU][1]; b++)
                                for (r = box[RED][0]; r < box[RED][1]; r++)
                                        t[g] += histo[r][g][b];
                        med += t[g];
                }
                break;
        case BLU:
                for (b = box[BLU][0]; b < box[BLU][1]; b++) {
                        t[b] = 0;
                        for (r = box[RED][0]; r < box[RED][1]; r++)
                                for (g = box[GRN][0]; g < box[GRN][1]; g++)
                                        t[b] += histo[r][g][b];
                        med += t[b];
                }
                break;
        }
        if (med < MINSAMP)              /* if too sparse, split at midpoint */
                return(set_branch(pri,(box[pri][0]+box[pri][1])>>1));
                                        /* find median position */
        med >>= 1;
        for (c0 = box[pri][0]; med > 0; c0++)
                med -= t[c0];
        if (c0 > (box[pri][0]+box[pri][1])>>1)  /* if past the midpoint */
                c0--;                           /* part left of median */
        return(set_branch(pri,c0));
#undef c0
}


static
mktabent(p, box)        /* compute average color for box and assign */
int     p;
register int    box[3][2];
{
        unsigned long   sum[3];
        unsigned        r, g;
        unsigned long   n;
        register unsigned       b, c;
                                                /* sum pixels in box */
        n = 0;
        sum[RED] = sum[GRN] = sum[BLU] = 0;
        for (r = box[RED][0]; r < box[RED][1]; r++)
            for (g = box[GRN][0]; g < box[GRN][1]; g++)
                for (b = box[BLU][0]; b < box[BLU][1]; b++) {
                    if (c = histo[r][g][b]) {
                        n += c;
                        sum[RED] += (long)c*r;
                        sum[GRN] += (long)c*g;
                        sum[BLU] += (long)c*b;
                    }
                    histo[r][g][b] = p;         /* assign pixel */
                }
        if (n >= (1L<<23)/HMAX) {               /* avoid overflow */
                sum[RED] /= n;
                sum[GRN] /= n;
                sum[BLU] /= n;
                n = 1;
        }
        if (n) {                                /* compute average */
                clrtab[p][RED] = sum[RED]*256/NRED/n;
                clrtab[p][GRN] = sum[GRN]*256/NGRN/n;
                clrtab[p][BLU] = sum[BLU]*256/NBLU/n;
        } else {                                /* empty box -- use midpoint */
                clrtab[p][RED] = (box[RED][0]+box[RED][1])*256/NRED/2;
                clrtab[p][GRN] = (box[GRN][0]+box[GRN][1])*256/NGRN/2;
                clrtab[p][BLU] = (box[BLU][0]+box[BLU][1])*256/NBLU/2;
        }
}


#ifdef CLOSEST
#define NBSIZ           32
static
closest(n)                      /* make sure we have the closest colors */
int     n;
{
        BYTE    *neigh[256];
        register int    r, g, b;
#define i r
                                        /* get space for neighbor lists */
        for (i = 0; i < n; i++) {
                if ((neigh[i] = (BYTE *)malloc(NBSIZ)) == NULL) {
                        while (i--)
                                free(neigh[i]);
                        return;                 /* ENOMEM -- abandon effort */
                }
                neigh[i][0] = i;                /* identity is terminator */
        }
                                        /* make neighbor lists */
        for (r = 0; r < NRED; r++)
            for (g = 0; g < NGRN; g++)
                for (b = 0; b < NBLU; b++) {
                    if (r < NRED-1 && histo[r][g][b] != histo[r+1][g][b])
                        addneigh(neigh, histo[r][g][b], histo[r+1][g][b]);
                    if (g < NGRN-1 && histo[r][g][b] != histo[r][g+1][b])
                        addneigh(neigh, histo[r][g][b], histo[r][g+1][b]);
                    if (b < NBLU-1 && histo[r][g][b] != histo[r][g][b+1])
                        addneigh(neigh, histo[r][g][b], histo[r][g][b+1]);
                }
                                        /* assign closest values */
        for (r = 0; r < NRED; r++)
            for (g = 0; g < NGRN; g++)
                for (b = 0; b < NBLU; b++)
                    setclosest(neigh, r, g, b);
                                        /* free neighbor lists */
        for (i = 0; i < n; i++)
                free(neigh[i]);
#undef i
}


static
addneigh(nl, i, j)              /* i and j are neighbors; add them to list */
register BYTE   *nl[];
register int    i;
int     j;
{
        int     nc;
        char    *nnl;
        register int    t;
        
        for (nc = 0; nc < 2; nc++) {            /* do both neighbors */
                for (t = 0; nl[i][t] != i; t++)
                        if (nl[i][t] == j)
                                break;          /* in list already */
                if (nl[i][t] == i) {            /* add to list */
                        nl[i][t++] = j;
                        if (t % NBSIZ == 0) {   /* enlarge list */
                                if ((nnl = realloc(nl[i], t+NBSIZ)) == NULL)
                                        t--;
                                else
                                        nl[i] = (BYTE *)nnl;
                        }
                        nl[i][t] = i;           /* terminator */
                }
                t = i; i = j; j = t;            /* swap and do it again */
        }
}


static unsigned
dist(col, r, g, b)              /* find distance from clrtab entry to r,g,b */
register BYTE   col[3];
int     r, g, b;
{
        register int    tmp;
        register unsigned       sum;
        
        tmp = col[RED]*NRED/256 - r;
        sum = tmp*tmp;
        tmp = col[GRN]*NGRN/256 - g;
        sum += tmp*tmp;
        tmp = col[BLU]*NBLU/256 - b;
        sum += tmp*tmp;
        return(sum);
}


static
setclosest(nl, r, g, b)         /* find index closest to color and assign */
BYTE    *nl[];
int     r, g, b;
{
        int     ident;
        unsigned        min;
        register unsigned       d;
        register BYTE   *p;
                                        /* get starting value */
        min = dist(clrtab[ident=histo[r][g][b]], r, g, b);
                                        /* find minimum */
        for (p = nl[ident]; *p != ident; p++)
                if ((d = dist(clrtab[*p], r, g, b)) < min) {
                        min = d;
                        histo[r][g][b] = *p;
                }
}
#endif
Revision:	2.10
Committed:	Fri Jun 10 12:51:16 1994 UTC (31 years, 4 months ago) by greg
Content type:	text/plain
Branch:	MAIN
Changes since 2.9:	+4 -2 lines
Log Message:	added Anthony Dekker's neural net color quantization code
#	Content
1	/* Copyright (c) 1993 Regents of the University of California */
2
3	#ifndef lint
4	static char SCCSid[] = "$SunId$ LBL";
5	#endif
6
7	/*
8	* Simple median-cut color quantization based on colortab.c
9	*/
10
11	#include "standard.h"
12
13	#include "color.h"
14	/* histogram resolution */
15	#define NRED 36
16	#define NGRN 48
17	#define NBLU 24
18	#define HMAX NGRN
19	/* minimum box count for adaptive partition */
20	#define MINSAMP 7
21	/* color partition */
22	#define set_branch(p,c) ((c)<<2\|(p))
23	#define part(cn) ((cn)>>2)
24	#define prim(cn) ((cn)&3)
25	/* our color table (global) */
26	extern BYTE clrtab[256][3];
27	/* histogram of colors / color assignments */
28	static unsigned histo[NRED][NGRN][NBLU];
29	#define cndx(c) histo[((c)[RED]NRED)>>8][((c)[GRN]NGRN)>>8][((c)[BLU]*NBLU)>>8]
30	/* initial color cube boundary */
31	static int CLRCUBE[3][2] = {0,NRED,0,NGRN,0,NBLU};
32	/* maximum propagated error during dithering */
33	#define MAXERR 20
34	/* define CLOSEST to get closest colors */
35	#ifndef CLOSEST
36	#ifdef SPEED
37	#if SPEED > 8
38	#define CLOSEST 1 /* this step takes a little longer */
39	#endif
40	#endif
41	#endif
42
43
44	new_histo(n) /* clear our histogram */
45	int n;
46	{
47	bzero((char *)histo, sizeof(histo));
48	return(0);
49	}
50
51
52	cnt_pixel(col) /* add pixel to our histogram */
53	register BYTE col[];
54	{
55	cndx(col)++;
56	}
57
58
59	cnt_colrs(cs, n) /* add a scanline to our histogram */
60	register COLR *cs;
61	register int n;
62	{
63	while (n-- > 0) {
64	cndx(cs[0])++;
65	cs++;
66	}
67	}
68
69
70	new_clrtab(ncolors) /* make new color table using ncolors */
71	int ncolors;
72	{
73	if (ncolors < 1)
74	return(0);
75	if (ncolors > 256)
76	ncolors = 256;
77	/* partition color space */
78	cut(CLRCUBE, 0, ncolors);
79	#ifdef CLOSEST
80	closest(ncolors); /* ensure colors picked are closest */
81	#endif
82	/* reset dithering function */
83	dith_colrs((BYTE )NULL, (COLR )NULL, 0);
84	/* return new color table size */
85	return(ncolors);
86	}
87
88
89	int
90	map_pixel(col) /* get pixel for color */
91	register BYTE col[];
92	{
93	return(cndx(col));
94	}
95
96
97	map_colrs(bs, cs, n) /* convert a scanline to color index values */
98	register BYTE *bs;
99	register COLR *cs;
100	register int n;
101	{
102	while (n-- > 0) {
103	*bs++ = cndx(cs[0]);
104	cs++;
105	}
106	}
107
108
109	dith_colrs(bs, cs, n) /* convert scanline to dithered index values */
110	register BYTE *bs;
111	register COLR *cs;
112	int n;
113	{
114	static short (*cerr)[3] = NULL;
115	static int N = 0;
116	int err[3], errp[3];
117	register int x, i;
118
119	if (n != N) { /* get error propogation array */
120	if (N) {
121	free((char *)cerr);
122	cerr = NULL;
123	}
124	if (n)
125	cerr = (short ()[3])malloc(3n*sizeof(short));
126	if (cerr == NULL) {
127	N = 0;
128	map_colrs(bs, cs, n);
129	return;
130	}
131	N = n;
132	bzero((char )cerr, 3N*sizeof(short));
133	}
134	err[0] = err[1] = err[2] = 0;
135	for (x = 0; x < n; x++) {
136	for (i = 0; i < 3; i++) { /* dither value */
137	errp[i] = err[i];
138	err[i] += cerr[x][i];
139	#ifdef MAXERR
140	if (err[i] > MAXERR) err[i] = MAXERR;
141	else if (err[i] < -MAXERR) err[i] = -MAXERR;
142	#endif
143	err[i] += cs[x][i];
144	if (err[i] < 0) err[i] = 0;
145	else if (err[i] > 255) err[i] = 255;
146	}
147	bs[x] = cndx(err);
148	for (i = 0; i < 3; i++) { /* propagate error */
149	err[i] -= clrtab[bs[x]][i];
150	err[i] /= 3;
151	cerr[x][i] = err[i] + errp[i];
152	}
153	}
154	}
155
156
157	static
158	cut(box, c0, c1) /* partition color space */
159	register int box[3][2];
160	int c0, c1;
161	{
162	register int branch;
163	int kb[3][2];
164
165	if (c1-c0 <= 1) { /* assign pixel */
166	mktabent(c0, box);
167	return;
168	}
169	/* split box */
170	branch = split(box);
171	bcopy((char )box, (char )kb, sizeof(kb));
172	/* do left (lesser) branch */
173	kb[prim(branch)][1] = part(branch);
174	cut(kb, c0, (c0+c1)>>1);
175	/* do right branch */
176	kb[prim(branch)][0] = part(branch);
177	kb[prim(branch)][1] = box[prim(branch)][1];
178	cut(kb, (c0+c1)>>1, c1);
179	}
180
181
182	static int
183	split(box) /* find median cut for box */
184	register int box[3][2];
185	{
186	#define c0 r
187	register int r, g, b;
188	int pri;
189	long t[HMAX], med;
190	/* find dominant axis */
191	pri = RED;
192	if (box[GRN][1]-box[GRN][0] > box[pri][1]-box[pri][0])
193	pri = GRN;
194	if (box[BLU][1]-box[BLU][0] > box[pri][1]-box[pri][0])
195	pri = BLU;
196	/* sum histogram over box */
197	med = 0;
198	switch (pri) {
199	case RED:
200	for (r = box[RED][0]; r < box[RED][1]; r++) {
201	t[r] = 0;
202	for (g = box[GRN][0]; g < box[GRN][1]; g++)
203	for (b = box[BLU][0]; b < box[BLU][1]; b++)
204	t[r] += histo[r][g][b];
205	med += t[r];
206	}
207	break;
208	case GRN:
209	for (g = box[GRN][0]; g < box[GRN][1]; g++) {
210	t[g] = 0;
211	for (b = box[BLU][0]; b < box[BLU][1]; b++)
212	for (r = box[RED][0]; r < box[RED][1]; r++)
213	t[g] += histo[r][g][b];
214	med += t[g];
215	}
216	break;
217	case BLU:
218	for (b = box[BLU][0]; b < box[BLU][1]; b++) {
219	t[b] = 0;
220	for (r = box[RED][0]; r < box[RED][1]; r++)
221	for (g = box[GRN][0]; g < box[GRN][1]; g++)
222	t[b] += histo[r][g][b];
223	med += t[b];
224	}
225	break;
226	}
227	if (med < MINSAMP) /* if too sparse, split at midpoint */
228	return(set_branch(pri,(box[pri][0]+box[pri][1])>>1));
229	/* find median position */
230	med >>= 1;
231	for (c0 = box[pri][0]; med > 0; c0++)
232	med -= t[c0];
233	if (c0 > (box[pri][0]+box[pri][1])>>1) /* if past the midpoint */
234	c0--; /* part left of median */
235	return(set_branch(pri,c0));
236	#undef c0
237	}
238
239
240	static
241	mktabent(p, box) /* compute average color for box and assign */
242	int p;
243	register int box[3][2];
244	{
245	unsigned long sum[3];
246	unsigned r, g;
247	unsigned long n;
248	register unsigned b, c;
249	/* sum pixels in box */
250	n = 0;
251	sum[RED] = sum[GRN] = sum[BLU] = 0;
252	for (r = box[RED][0]; r < box[RED][1]; r++)
253	for (g = box[GRN][0]; g < box[GRN][1]; g++)
254	for (b = box[BLU][0]; b < box[BLU][1]; b++) {
255	if (c = histo[r][g][b]) {
256	n += c;
257	sum[RED] += (long)c*r;
258	sum[GRN] += (long)c*g;
259	sum[BLU] += (long)c*b;
260	}
261	histo[r][g][b] = p; /* assign pixel */
262	}
263	if (n >= (1L<<23)/HMAX) { /* avoid overflow */
264	sum[RED] /= n;
265	sum[GRN] /= n;
266	sum[BLU] /= n;
267	n = 1;
268	}
269	if (n) { /* compute average */
270	clrtab[p][RED] = sum[RED]*256/NRED/n;
271	clrtab[p][GRN] = sum[GRN]*256/NGRN/n;
272	clrtab[p][BLU] = sum[BLU]*256/NBLU/n;
273	} else { /* empty box -- use midpoint */
274	clrtab[p][RED] = (box[RED][0]+box[RED][1])*256/NRED/2;
275	clrtab[p][GRN] = (box[GRN][0]+box[GRN][1])*256/NGRN/2;
276	clrtab[p][BLU] = (box[BLU][0]+box[BLU][1])*256/NBLU/2;
277	}
278	}
279
280
281	#ifdef CLOSEST
282	#define NBSIZ 32
283	static
284	closest(n) /* make sure we have the closest colors */
285	int n;
286	{
287	BYTE *neigh[256];
288	register int r, g, b;
289	#define i r
290	/* get space for neighbor lists */
291	for (i = 0; i < n; i++) {
292	if ((neigh[i] = (BYTE *)malloc(NBSIZ)) == NULL) {
293	while (i--)
294	free(neigh[i]);
295	return; /* ENOMEM -- abandon effort */
296	}
297	neigh[i][0] = i; /* identity is terminator */
298	}
299	/* make neighbor lists */
300	for (r = 0; r < NRED; r++)
301	for (g = 0; g < NGRN; g++)
302	for (b = 0; b < NBLU; b++) {
303	if (r < NRED-1 && histo[r][g][b] != histo[r+1][g][b])
304	addneigh(neigh, histo[r][g][b], histo[r+1][g][b]);
305	if (g < NGRN-1 && histo[r][g][b] != histo[r][g+1][b])
306	addneigh(neigh, histo[r][g][b], histo[r][g+1][b]);
307	if (b < NBLU-1 && histo[r][g][b] != histo[r][g][b+1])
308	addneigh(neigh, histo[r][g][b], histo[r][g][b+1]);
309	}
310	/* assign closest values */
311	for (r = 0; r < NRED; r++)
312	for (g = 0; g < NGRN; g++)
313	for (b = 0; b < NBLU; b++)
314	setclosest(neigh, r, g, b);
315	/* free neighbor lists */
316	for (i = 0; i < n; i++)
317	free(neigh[i]);
318	#undef i
319	}
320
321
322	static
323	addneigh(nl, i, j) /* i and j are neighbors; add them to list */
324	register BYTE *nl[];
325	register int i;
326	int j;
327	{
328	int nc;
329	char *nnl;
330	register int t;
331
332	for (nc = 0; nc < 2; nc++) { /* do both neighbors */
333	for (t = 0; nl[i][t] != i; t++)
334	if (nl[i][t] == j)
335	break; /* in list already */
336	if (nl[i][t] == i) { /* add to list */
337	nl[i][t++] = j;
338	if (t % NBSIZ == 0) { /* enlarge list */
339	if ((nnl = realloc(nl[i], t+NBSIZ)) == NULL)
340	t--;
341	else
342	nl[i] = (BYTE *)nnl;
343	}
344	nl[i][t] = i; /* terminator */
345	}
346	t = i; i = j; j = t; /* swap and do it again */
347	}
348	}
349
350
351	static unsigned
352	dist(col, r, g, b) /* find distance from clrtab entry to r,g,b */
353	register BYTE col[3];
354	int r, g, b;
355	{
356	register int tmp;
357	register unsigned sum;
358
359	tmp = col[RED]*NRED/256 - r;
360	sum = tmp*tmp;
361	tmp = col[GRN]*NGRN/256 - g;
362	sum += tmp*tmp;
363	tmp = col[BLU]*NBLU/256 - b;
364	sum += tmp*tmp;
365	return(sum);
366	}
367
368
369	static
370	setclosest(nl, r, g, b) /* find index closest to color and assign */
371	BYTE *nl[];
372	int r, g, b;
373	{
374	int ident;
375	unsigned min;
376	register unsigned d;
377	register BYTE *p;
378	/* get starting value */
379	min = dist(clrtab[ident=histo[r][g][b]], r, g, b);
380	/* find minimum */
381	for (p = nl[ident]; *p != ident; p++)
382	if ((d = dist(clrtab[*p], r, g, b)) < min) {
383	min = d;
384	histo[r][g][b] = *p;
385	}
386	}
387	#endif