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1.1 |
#ifndef lint |
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2.5 |
static const char RCSid[] = "$Id$"; |
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1.1 |
#endif |
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/* |
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* colortab.c - allocate and control dynamic color table. |
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* |
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* We start off with a uniform partition of color space. |
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* As pixels are sent to the frame buffer, a histogram is built. |
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* When a new color table is requested, the histogram is used |
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* to make a pseudo-optimal partition, after which the |
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* histogram is cleared. This algorithm |
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* performs only as well as the next drawing's color |
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* distribution is correlated to the last. |
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2.5 |
* |
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* External symbols declared in drvier.h |
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*/ |
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2.6 |
#include "copyright.h" |
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1.1 |
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1.15 |
#include "standard.h" |
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1.1 |
#include "color.h" |
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/* histogram resolution */ |
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1.3 |
#define NRED 24 |
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1.1 |
#define NGRN 32 |
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1.3 |
#define NBLU 16 |
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1.1 |
#define HMAX NGRN |
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/* minimum box count for adaptive partition */ |
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#define MINSAMP 7 |
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1.3 |
/* maximum distance^2 before color reassign */ |
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1.5 |
#define MAXDST2 12 |
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1.1 |
/* map a color */ |
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1.4 |
#define map_col(c,p) clrmap[p][ colval(c,p)<1. ? \ |
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(int)(colval(c,p)*256.) : 255 ] |
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1.1 |
/* color partition tree */ |
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#define CNODE short |
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2.2 |
#define set_branch(p,c) ((c)<<2|(p)) |
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1.1 |
#define set_pval(pv) ((pv)<<2|3) |
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1.7 |
#define is_branch(cn) (((cn)&3)!=3) |
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1.1 |
#define is_pval(cn) (((cn)&3)==3) |
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#define part(cn) ((cn)>>2) |
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#define prim(cn) ((cn)&3) |
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#define pval(cn) ((cn)>>2) |
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/* our color table */ |
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1.6 |
static struct tabent { |
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1.3 |
long sum[3]; /* sum of colors using this entry */ |
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1.15 |
int n; /* number of colors */ |
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BYTE ent[3]; /* current table value */ |
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1.8 |
} *clrtab = NULL; |
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/* color cube partition */ |
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static CNODE *ctree = NULL; |
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1.1 |
/* our color correction map */ |
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1.4 |
static BYTE clrmap[3][256]; |
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1.1 |
/* histogram of colors used */ |
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1.9 |
static unsigned short histo[NRED][NGRN][NBLU]; |
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1.8 |
/* initial color cube boundary */ |
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2.3 |
static int CLRCUBE[3][2] = {{0,NRED},{0,NGRN},{0,NBLU}}; |
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2.5 |
static int split(); |
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static void cut(); |
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1.1 |
|
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1.3 |
int |
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1.4 |
new_ctab(ncolors) /* start new color table with max ncolors */ |
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1.1 |
int ncolors; |
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{ |
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1.8 |
int treesize; |
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1.6 |
if (ncolors < 1) |
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1.3 |
return(0); |
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1.8 |
/* free old tables */ |
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if (clrtab != NULL) |
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2.5 |
free((void *)clrtab); |
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1.8 |
if (ctree != NULL) |
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2.5 |
free((void *)ctree); |
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1.8 |
/* get new tables */ |
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for (treesize = 1; treesize < ncolors; treesize <<= 1) |
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; |
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treesize <<= 1; |
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clrtab = (struct tabent *)calloc(ncolors, sizeof(struct tabent)); |
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ctree = (CNODE *)malloc(treesize*sizeof(CNODE)); |
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if (clrtab == NULL || ctree == NULL) |
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return(0); |
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1.3 |
/* partition color space */ |
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1.7 |
cut(ctree, 0, CLRCUBE, 0, ncolors); |
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1.1 |
/* clear histogram */ |
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2.7 |
bzero((void *)histo, sizeof(histo)); |
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1.3 |
/* return number of colors used */ |
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return(ncolors); |
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1.1 |
} |
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int |
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1.4 |
get_pixel(col, set_pixel) /* get pixel for color */ |
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1.1 |
COLOR col; |
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2.5 |
void (*set_pixel)(); |
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1.1 |
{ |
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1.3 |
int r, g, b; |
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1.1 |
int cv[3]; |
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1.10 |
register CNODE *tp; |
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1.1 |
register int h; |
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1.3 |
/* map color */ |
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r = map_col(col,RED); |
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g = map_col(col,GRN); |
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b = map_col(col,BLU); |
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/* reduce resolution */ |
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cv[RED] = (r*NRED)>>8; |
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cv[GRN] = (g*NGRN)>>8; |
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cv[BLU] = (b*NBLU)>>8; |
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/* add to histogram */ |
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1.1 |
histo[cv[RED]][cv[GRN]][cv[BLU]]++; |
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1.3 |
/* find pixel in tree */ |
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1.10 |
for (tp = ctree, h = 0; is_branch(*tp); h++) |
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if (cv[prim(*tp)] < part(*tp)) |
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tp += 1<<h; /* left branch */ |
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1.1 |
else |
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1.15 |
tp += 1<<(h+1); /* right branch */ |
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1.10 |
h = pval(*tp); |
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1.3 |
/* add to color table */ |
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1.10 |
clrtab[h].sum[RED] += r; |
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clrtab[h].sum[GRN] += g; |
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clrtab[h].sum[BLU] += b; |
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clrtab[h].n++; |
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1.3 |
/* recompute average */ |
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1.10 |
r = clrtab[h].sum[RED] / clrtab[h].n; |
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g = clrtab[h].sum[GRN] / clrtab[h].n; |
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b = clrtab[h].sum[BLU] / clrtab[h].n; |
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1.3 |
/* check for movement */ |
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1.10 |
if (clrtab[h].n == 1 || |
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(r-clrtab[h].ent[RED])*(r-clrtab[h].ent[RED]) + |
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(g-clrtab[h].ent[GRN])*(g-clrtab[h].ent[GRN]) + |
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(b-clrtab[h].ent[BLU])*(b-clrtab[h].ent[BLU]) > MAXDST2) { |
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clrtab[h].ent[RED] = r; |
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2.2 |
clrtab[h].ent[GRN] = g; /* reassign pixel */ |
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1.10 |
clrtab[h].ent[BLU] = b; |
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1.12 |
#ifdef DEBUG |
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sprintf(errmsg, "pixel %d = (%d,%d,%d) (%d refs)\n", |
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1.10 |
h, r, g, b, clrtab[h].n); |
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1.12 |
eputs(errmsg); |
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1.1 |
#endif |
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1.3 |
(*set_pixel)(h, r, g, b); |
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} |
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return(h); /* return pixel value */ |
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1.1 |
} |
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2.5 |
void |
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1.4 |
make_gmap(gam) /* make gamma correction map */ |
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2.2 |
double gam; |
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1.1 |
{ |
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register int i; |
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1.4 |
for (i = 0; i < 256; i++) |
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clrmap[RED][i] = |
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clrmap[GRN][i] = |
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1.15 |
clrmap[BLU][i] = 256.0 * pow((i+0.5)/256.0, 1.0/gam); |
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1.4 |
} |
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2.5 |
void |
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1.4 |
set_cmap(rmap, gmap, bmap) /* set custom color correction map */ |
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BYTE *rmap, *gmap, *bmap; |
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{ |
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2.7 |
bcopy((void *)rmap, (void *)clrmap[RED], 256); |
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bcopy((void *)gmap, (void *)clrmap[GRN], 256); |
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bcopy((void *)bmap, (void *)clrmap[BLU], 256); |
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1.1 |
} |
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2.5 |
void |
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1.13 |
map_color(rgb, col) /* map a color to a byte triplet */ |
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BYTE rgb[3]; |
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COLOR col; |
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{ |
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rgb[RED] = map_col(col,RED); |
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rgb[GRN] = map_col(col,GRN); |
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rgb[BLU] = map_col(col,BLU); |
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} |
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2.5 |
static void |
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1.7 |
cut(tree, level, box, c0, c1) /* partition color space */ |
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1.1 |
register CNODE *tree; |
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1.7 |
int level; |
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1.1 |
register int box[3][2]; |
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int c0, c1; |
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{ |
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int kb[3][2]; |
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1.3 |
if (c1-c0 <= 1) { /* assign pixel */ |
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1.1 |
*tree = set_pval(c0); |
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return; |
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} |
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/* split box */ |
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*tree = split(box); |
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2.7 |
bcopy((void *)box, (void *)kb, sizeof(kb)); |
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1.3 |
/* do left (lesser) branch */ |
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1.1 |
kb[prim(*tree)][1] = part(*tree); |
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1.7 |
cut(tree+(1<<level), level+1, kb, c0, (c0+c1)>>1); |
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1.3 |
/* do right branch */ |
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1.1 |
kb[prim(*tree)][0] = part(*tree); |
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kb[prim(*tree)][1] = box[prim(*tree)][1]; |
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1.7 |
cut(tree+(1<<(level+1)), level+1, kb, (c0+c1)>>1, c1); |
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1.1 |
} |
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static int |
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split(box) /* find median cut for box */ |
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register int box[3][2]; |
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{ |
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#define c0 r |
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register int r, g, b; |
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int pri; |
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2.4 |
long t[HMAX], med; |
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1.1 |
/* find dominant axis */ |
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pri = RED; |
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if (box[GRN][1]-box[GRN][0] > box[pri][1]-box[pri][0]) |
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pri = GRN; |
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if (box[BLU][1]-box[BLU][0] > box[pri][1]-box[pri][0]) |
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pri = BLU; |
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/* sum histogram over box */ |
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med = 0; |
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switch (pri) { |
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case RED: |
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for (r = box[RED][0]; r < box[RED][1]; r++) { |
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t[r] = 0; |
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for (g = box[GRN][0]; g < box[GRN][1]; g++) |
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for (b = box[BLU][0]; b < box[BLU][1]; b++) |
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t[r] += histo[r][g][b]; |
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med += t[r]; |
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} |
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break; |
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case GRN: |
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for (g = box[GRN][0]; g < box[GRN][1]; g++) { |
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t[g] = 0; |
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for (b = box[BLU][0]; b < box[BLU][1]; b++) |
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for (r = box[RED][0]; r < box[RED][1]; r++) |
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t[g] += histo[r][g][b]; |
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med += t[g]; |
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} |
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break; |
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case BLU: |
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for (b = box[BLU][0]; b < box[BLU][1]; b++) { |
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t[b] = 0; |
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for (r = box[RED][0]; r < box[RED][1]; r++) |
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for (g = box[GRN][0]; g < box[GRN][1]; g++) |
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t[b] += histo[r][g][b]; |
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med += t[b]; |
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} |
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break; |
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} |
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if (med < MINSAMP) /* if too sparse, split at midpoint */ |
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return(set_branch(pri,(box[pri][0]+box[pri][1])>>1)); |
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/* find median position */ |
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med >>= 1; |
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for (c0 = box[pri][0]; med > 0; c0++) |
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med -= t[c0]; |
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if (c0 > (box[pri][0]+box[pri][1])>>1) /* if past the midpoint */ |
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c0--; /* part left of median */ |
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return(set_branch(pri,c0)); |
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#undef c0 |
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} |