src/rt/srcdraw.c

#ifndef lint
static const char       RCSid[] = "$Id: srcdraw.c,v 2.13 2004/09/02 16:02:56 greg Exp $";
#endif
/*
 * Draw small sources into image in case we missed them.
 *
 *  External symbols declared in ray.h
 */

#include "copyright.h"

#include  "ray.h"
#include  "view.h"
#include  "source.h"


#define CLIP_ABOVE      1
#define CLIP_BELOW      2
#define CLIP_RIGHT      3
#define CLIP_LEFT       4

#define MAXVERT         10

typedef struct splist {
        struct splist   *next;                  /* next source in list */
        int     sn;                             /* source number */
        short   nv;                             /* number of vertices */
        RREAL   vl[3][2];                       /* vertex array (last) */
} SPLIST;                               /* source polygon list */

extern VIEW     ourview;                /* our view parameters */
extern int      hres, vres;             /* our image resolution */
static SPLIST   *sphead = NULL;         /* our list of source polys */

static int inregion(RREAL p[2], double cv, int crit);
static void clipregion(RREAL a[2], RREAL b[2], double cv, int crit, RREAL r[2]);
static int hp_clip_poly(RREAL vl[][2], int nv, double cv, int crit,
                RREAL vlo[][2]);
static int box_clip_poly(RREAL vl[MAXVERT][2], int nv,
                double xl, double xr, double yb, double ya, RREAL vlo[MAXVERT][2]);
static double minw2(RREAL vl[][2], int nv, double ar2);
static void convex_center(RREAL vl[][2], int nv, RREAL cv[2]);
static double poly_area(RREAL vl[][2], int nv);
static int convex_hull(RREAL vl[][2], int nv, RREAL vlo[][2]);
static void spinsert(int sn, RREAL vl[][2], int nv);
static int sourcepoly(int sn, RREAL sp[MAXVERT][2]);


static int
inregion(                       /* check if vertex is in region */
        RREAL   p[2],
        double  cv,
        int     crit
)
{
        switch (crit) {
        case CLIP_ABOVE:
                return(p[1] < cv);
        case CLIP_BELOW:
                return(p[1] >= cv);
        case CLIP_RIGHT:
                return(p[0] < cv);
        case CLIP_LEFT:
                return(p[0] >= cv);
        }
        return(-1);
}


static void
clipregion(             /* find intersection with boundary */
        register RREAL  a[2],
        register RREAL  b[2],
        double  cv,
        int     crit,
        RREAL   r[2]    /* return value */
)
{
        switch (crit) {
        case CLIP_ABOVE:
        case CLIP_BELOW:
                r[1] = cv;
                r[0] = a[0] + (cv-a[1])/(b[1]-a[1])*(b[0]-a[0]);
                return;
        case CLIP_RIGHT:
        case CLIP_LEFT:
                r[0] = cv;
                r[1] = a[1] + (cv-a[0])/(b[0]-a[0])*(b[1]-a[1]);
                return;
        }
}


static int
hp_clip_poly(   /* clip polygon to half-plane */
        RREAL   vl[][2],
        int     nv,
        double  cv,
        int     crit,
        RREAL   vlo[][2]        /* return value */
)
{
        RREAL   *s, *p;
        register int    j, nvo;

        s = vl[nv-1];
        nvo = 0;
        for (j = 0; j < nv; j++) {
                p = vl[j];
                if (inregion(p, cv, crit)) {
                        if (!inregion(s, cv, crit))
                                clipregion(s, p, cv, crit, vlo[nvo++]);
                        vlo[nvo][0] = p[0]; vlo[nvo++][1] = p[1];
                } else if (inregion(s, cv, crit))
                        clipregion(s, p, cv, crit, vlo[nvo++]);
                s = p;
        }
        return(nvo);
}


static int
box_clip_poly(  /* clip polygon to box */
        RREAL   vl[MAXVERT][2],
        int     nv,
        double  xl,
        double  xr,
        double  yb,
        double  ya,
        RREAL   vlo[MAXVERT][2] /* return value */
)
{
        RREAL   vlt[MAXVERT][2];
        int     nvt, nvo;

        nvt = hp_clip_poly(vl, nv, yb, CLIP_BELOW, vlt);
        nvo = hp_clip_poly(vlt, nvt, ya, CLIP_ABOVE, vlo);
        nvt = hp_clip_poly(vlo, nvo, xl, CLIP_LEFT, vlt);
        nvo = hp_clip_poly(vlt, nvt, xr, CLIP_RIGHT, vlo);

        return(nvo);
}


static double
minw2(                  /* compute square of minimum width */
        RREAL   vl[][2],
        int     nv,
        double  ar2
)
{
        double  d2, w2, w2min, w2max;
        register RREAL  *p0, *p1, *p2;
        int     i, j;
                                /* find minimum for all widths */
        w2min = FHUGE;
        p0 = vl[nv-1];
        for (i = 0; i < nv; i++) {      /* for each edge */
                p1 = vl[i];
                d2 = (p1[0]-p0[0])*(p1[0]-p0[0]) +
                                (p1[1]-p0[1])*(p1[1]-p0[1])*ar2;
                w2max = 0.;             /* find maximum for this side */
                for (j = 1; j < nv-1; j++) {
                        p2 = vl[(i+j)%nv];
                        w2 = (p1[0]-p0[0])*(p2[1]-p0[1]) -
                                        (p1[1]-p0[1])*(p2[0]-p0[0]);
                        w2 = w2*w2*ar2/d2;      /* triangle height squared */
                        if (w2 > w2max)
                                w2max = w2;
                }
                if (w2max < w2min)      /* global min. based on local max.'s */
                        w2min = w2max;
                p0 = p1;
        }
        return(w2min);
}


static void
convex_center(          /* compute center of convex polygon */
        register RREAL  vl[][2],
        int     nv,
        RREAL   cv[2]           /* return value */
)
{
        register int    i;
                                        /* simple average (suboptimal) */
        cv[0] = cv[1] = 0.;
        for (i = 0; i < nv; i++) {
                cv[0] += vl[i][0];
                cv[1] += vl[i][1];
        }
        cv[0] /= (double)nv;
        cv[1] /= (double)nv;
}


static double
poly_area(                      /* compute area of polygon */
        register RREAL  vl[][2],
        int     nv
)
{
        double  a;
        RREAL   v0[2], v1[2];
        register int    i;

        a = 0.;
        v0[0] = vl[1][0] - vl[0][0];
        v0[1] = vl[1][1] - vl[0][1];
        for (i = 2; i < nv; i++) {
                v1[0] = vl[i][0] - vl[0][0];
                v1[1] = vl[i][1] - vl[0][1];
                a += v0[0]*v1[1] - v0[1]*v1[0];
                v0[0] = v1[0]; v0[1] = v1[1];
        }
        return(a * (a >= 0. ? .5 : -.5));
}


static int
convex_hull(            /* compute polygon's convex hull */
        RREAL   vl[][2],
        int     nv,
        RREAL   vlo[][2]        /* return value */
)
{
        int     nvo, nvt;
        RREAL   vlt[MAXVERT][2];
        double  voa, vta;
        register int    i, j;
                                        /* start with original polygon */
        for (i = nvo = nv; i--; ) {
                vlo[i][0] = vl[i][0]; vlo[i][1] = vl[i][1];
        }
        voa = poly_area(vlo, nvo);      /* compute its area */
        for (i = 0; i < nvo; i++) {             /* for each output vertex */
                for (j = 0; j < i; j++) {
                        vlt[j][0] = vlo[j][0]; vlt[j][1] = vlo[j][1];
                }
                nvt = nvo - 1;                  /* make poly w/o vertex */
                for (j = i; j < nvt; j++) {
                        vlt[j][0] = vlo[j+1][0]; vlt[j][1] = vlo[j+1][1];
                }
                vta = poly_area(vlt, nvt);
                if (vta >= voa) {               /* is simpler poly bigger? */
                        voa = vta;                      /* then use it */
                        for (j = nvo = nvt; j--; ) {
                                vlo[j][0] = vlt[j][0]; vlo[j][1] = vlt[j][1];
                        }
                        i--;                            /* next adjust */
                }
        }
        return(nvo);
}


static void
spinsert(                       /* insert new source polygon */
        int     sn,
        RREAL   vl[][2],
        int     nv
)
{
        register SPLIST *spn;
        register int    i;

        if (nv < 3)
                return;
        if (nv > 3)
                spn = (SPLIST *)malloc(sizeof(SPLIST)+sizeof(RREAL)*2*(nv-3));
        else
                spn = (SPLIST *)malloc(sizeof(SPLIST));
        if (spn == NULL)
                error(SYSTEM, "out of memory in spinsert");
        spn->sn = sn;
        for (i = spn->nv = nv; i--; ) {
                spn->vl[i][0] = vl[i][0]; spn->vl[i][1] = vl[i][1];
        }
        spn->next = sphead;             /* push onto global list */
        sphead = spn;
}


static int
sourcepoly(                     /* compute image polygon for source */
        int     sn,
        RREAL   sp[MAXVERT][2]
)
{
        static short    cubeord[8][6] = {{1,3,2,6,4,5},{0,4,5,7,3,2},
                                         {0,1,3,7,6,4},{0,1,5,7,6,2},
                                         {0,2,6,7,5,1},{0,4,6,7,3,1},
                                         {0,2,3,7,5,4},{1,5,4,6,2,3}};
        register SRCREC *s = source + sn;
        FVECT   ap, ip;
        RREAL   pt[6][2];
        int     dir;
        register int    i, j;

        if (s->sflags & (SDISTANT|SFLAT)) {
                if (s->sflags & SDISTANT) {
                        if (ourview.type == VT_PAR)
                                return(0);      /* all or nothing case */
                        if (s->srad >= 0.05)
                                return(0);      /* should never be a problem */
                }
                if (s->sflags & SFLAT) {
                        for (i = 0; i < 3; i++)
                                ap[i] = s->sloc[i] - ourview.vp[i];
                        if (DOT(ap, s->snorm) >= 0.)
                                return(0);      /* source faces away */
                }
                for (j = 0; j < 4; j++) {       /* four corners */
                        for (i = 0; i < 3; i++) {
                                ap[i] = s->sloc[i];
                                if ((j==1)|(j==2)) ap[i] += s->ss[SU][i];
                                else ap[i] -= s->ss[SU][i];
                                if ((j==2)|(j==3)) ap[i] += s->ss[SV][i];
                                else ap[i] -= s->ss[SV][i];
                                if (s->sflags & SDISTANT) {
                                        ap[i] *= 1. + ourview.vfore;
                                        ap[i] += ourview.vp[i];
                                }
                        }
                        viewloc(ip, &ourview, ap);      /* find image point */
                        if (ip[2] <= 0.)
                                return(0);              /* in front of view */
                        sp[j][0] = ip[0]; sp[j][1] = ip[1];
                }
                return(4);
        }
                                        /* identify furthest corner */
        for (i = 0; i < 3; i++)
                ap[i] = s->sloc[i] - ourview.vp[i];
        dir =   (DOT(ap,s->ss[SU])>0.) |
                (DOT(ap,s->ss[SV])>0.)<<1 |
                (DOT(ap,s->ss[SW])>0.)<<2 ;
                                        /* order vertices based on this */
        for (j = 0; j < 6; j++) {
                for (i = 0; i < 3; i++) {
                        ap[i] = s->sloc[i];
                        if (cubeord[dir][j] & 1) ap[i] += s->ss[SU][i];
                        else ap[i] -= s->ss[SU][i];
                        if (cubeord[dir][j] & 2) ap[i] += s->ss[SV][i];
                        else ap[i] -= s->ss[SV][i];
                        if (cubeord[dir][j] & 4) ap[i] += s->ss[SW][i];
                        else ap[i] -= s->ss[SW][i];
                }
                viewloc(ip, &ourview, ap);      /* find image point */
                if (ip[2] <= 0.)
                        return(0);              /* in front of view */
                pt[j][0] = ip[0]; pt[j][1] = ip[1];
        }
        return(convex_hull(pt, 6, sp));         /* make sure it's convex */
}


                        /* initialize by finding sources smaller than rad */
extern void
init_drawsources(
        int     rad                             /* source sample size */
)
{
        RREAL   spoly[MAXVERT][2];
        int     nsv;
        register SPLIST *sp;
        register int    i;
                                        /* free old source list if one */
        for (sp = sphead; sp != NULL; sp = sphead) {
                sphead = sp->next;
                free((void *)sp);
        }
                                        /* loop through all sources */
        for (i = nsources; i--; ) {
                                        /* compute image polygon for source */
                if (!(nsv = sourcepoly(i, spoly)))
                        continue;
                                        /* clip to image boundaries */
                if (!(nsv = box_clip_poly(spoly, nsv, 0., 1., 0., 1., spoly)))
                        continue;
                                        /* big enough for standard sampling? */
                if (minw2(spoly, nsv, ourview.vn2/ourview.hn2) >
                                (double)rad*rad/hres/hres)
                        continue;
                                        /* OK, add to our list */
                spinsert(i, spoly, nsv);
        }
}

extern void                     /* add sources smaller than rad to computed subimage */
drawsources(
        COLOR   *pic[],                         /* subimage pixel value array */
        float   *zbf[],                         /* subimage distance array (opt.) */
        int     x0,                             /* origin and size of subimage */
        int     xsiz,
        int     y0,
        int     ysiz
)
{
        RREAL   spoly[MAXVERT][2], ppoly[MAXVERT][2];
        int     nsv, npv;
        int     xmin, xmax, ymin, ymax, x, y;
        RREAL   cxy[2];
        double  w;
        RAY     sr;
        register SPLIST *sp;
        register int    i;
                                        /* check each source in our list */
        for (sp = sphead; sp != NULL; sp = sp->next) {
                                        /* clip source poly to subimage */
                nsv = box_clip_poly(sp->vl, sp->nv,
                                (double)x0/hres, (double)(x0+xsiz)/hres,
                                (double)y0/vres, (double)(y0+ysiz)/vres, spoly);
                if (!nsv)
                        continue;
                                        /* find common subimage (BBox) */
                xmin = x0 + xsiz; xmax = x0;
                ymin = y0 + ysiz; ymax = y0;
                for (i = 0; i < nsv; i++) {
                        if ((double)xmin/hres > spoly[i][0])
                                xmin = spoly[i][0]*hres + FTINY;
                        if ((double)xmax/hres < spoly[i][0])
                                xmax = spoly[i][0]*hres - FTINY;
                        if ((double)ymin/vres > spoly[i][1])
                                ymin = spoly[i][1]*vres + FTINY;
                        if ((double)ymax/vres < spoly[i][1])
                                ymax = spoly[i][1]*vres - FTINY;
                }
                                        /* evaluate each pixel in BBox */
                for (y = ymin; y <= ymax; y++)
                        for (x = xmin; x <= xmax; x++) {
                                                        /* subarea for pixel */
                                npv = box_clip_poly(spoly, nsv,
                                                (double)x/hres, (x+1.)/hres,
                                                (double)y/vres, (y+1.)/vres,
                                                ppoly);
                                if (!npv)
                                        continue;       /* no overlap */
                                convex_center(ppoly, npv, cxy);
                                if ((sr.rmax = viewray(sr.rorg,sr.rdir,&ourview,
                                                cxy[0],cxy[1])) < -FTINY)
                                        continue;       /* not in view */
                                if (source[sp->sn].sflags & SSPOT &&
                                                spotout(&sr, source[sp->sn].sl.s))
                                        continue;       /* outside spot */
                                rayorigin(&sr, NULL, PRIMARY, 1.0);
                                rayvalue(&sr);          /* compute value */
                                if (bright(sr.rcol) <= FTINY)
                                        continue;       /* missed/blocked */
                                                        /* modify pixel */
                                w = poly_area(ppoly, npv) * hres * vres;
                                if (zbf[y-y0] != NULL &&
                                                sr.rt < 0.99*zbf[y-y0][x-x0]) {
                                        zbf[y-y0][x-x0] = sr.rt;
                                } else if (!bigdiff(sr.rcol, pic[y-y0][x-x0],
                                                0.01)) { /* source sample */
                                        scalecolor(pic[y-y0][x-x0], w);
                                        continue;
                                }
                                scalecolor(sr.rcol, w);
                                scalecolor(pic[y-y0][x-x0], 1.-w);
                                addcolor(pic[y-y0][x-x0], sr.rcol);
                        }
        }
}
Revision:	2.14
Committed:	Wed Oct 20 18:19:22 2004 UTC (19 years, 6 months ago) by greg
Content type:	text/plain
Branch:	MAIN
CVS Tags:	rad3R6
Changes since 2.13:	+3 -7 lines
Log Message:	Changed source drawing routines so edges of illum's are not drawn
#	Content
1	#ifndef lint
2	static const char RCSid[] = "$Id: srcdraw.c,v 2.13 2004/09/02 16:02:56 greg Exp $";
3	#endif
4	/*
5	* Draw small sources into image in case we missed them.
6	*
7	* External symbols declared in ray.h
8	*/
9
10	#include "copyright.h"
11
12	#include "ray.h"
13	#include "view.h"
14	#include "source.h"
15
16
17	#define CLIP_ABOVE 1
18	#define CLIP_BELOW 2
19	#define CLIP_RIGHT 3
20	#define CLIP_LEFT 4
21
22	#define MAXVERT 10
23
24	typedef struct splist {
25	struct splist next; / next source in list */
26	int sn; /* source number */
27	short nv; /* number of vertices */
28	RREAL vl[3][2]; /* vertex array (last) */
29	} SPLIST; /* source polygon list */
30
31	extern VIEW ourview; /* our view parameters */
32	extern int hres, vres; /* our image resolution */
33	static SPLIST sphead = NULL; / our list of source polys */
34
35	static int inregion(RREAL p[2], double cv, int crit);
36	static void clipregion(RREAL a[2], RREAL b[2], double cv, int crit, RREAL r[2]);
37	static int hp_clip_poly(RREAL vl[][2], int nv, double cv, int crit,
38	RREAL vlo[][2]);
39	static int box_clip_poly(RREAL vl[MAXVERT][2], int nv,
40	double xl, double xr, double yb, double ya, RREAL vlo[MAXVERT][2]);
41	static double minw2(RREAL vl[][2], int nv, double ar2);
42	static void convex_center(RREAL vl[][2], int nv, RREAL cv[2]);
43	static double poly_area(RREAL vl[][2], int nv);
44	static int convex_hull(RREAL vl[][2], int nv, RREAL vlo[][2]);
45	static void spinsert(int sn, RREAL vl[][2], int nv);
46	static int sourcepoly(int sn, RREAL sp[MAXVERT][2]);
47
48
49	static int
50	inregion( /* check if vertex is in region */
51	RREAL p[2],
52	double cv,
53	int crit
54	)
55	{
56	switch (crit) {
57	case CLIP_ABOVE:
58	return(p[1] < cv);
59	case CLIP_BELOW:
60	return(p[1] >= cv);
61	case CLIP_RIGHT:
62	return(p[0] < cv);
63	case CLIP_LEFT:
64	return(p[0] >= cv);
65	}
66	return(-1);
67	}
68
69
70	static void
71	clipregion( /* find intersection with boundary */
72	register RREAL a[2],
73	register RREAL b[2],
74	double cv,
75	int crit,
76	RREAL r[2] /* return value */
77	)
78	{
79	switch (crit) {
80	case CLIP_ABOVE:
81	case CLIP_BELOW:
82	r[1] = cv;
83	r[0] = a[0] + (cv-a[1])/(b[1]-a[1])*(b[0]-a[0]);
84	return;
85	case CLIP_RIGHT:
86	case CLIP_LEFT:
87	r[0] = cv;
88	r[1] = a[1] + (cv-a[0])/(b[0]-a[0])*(b[1]-a[1]);
89	return;
90	}
91	}
92
93
94	static int
95	hp_clip_poly( /* clip polygon to half-plane */
96	RREAL vl[][2],
97	int nv,
98	double cv,
99	int crit,
100	RREAL vlo[][2] /* return value */
101	)
102	{
103	RREAL s, p;
104	register int j, nvo;
105
106	s = vl[nv-1];
107	nvo = 0;
108	for (j = 0; j < nv; j++) {
109	p = vl[j];
110	if (inregion(p, cv, crit)) {
111	if (!inregion(s, cv, crit))
112	clipregion(s, p, cv, crit, vlo[nvo++]);
113	vlo[nvo][0] = p[0]; vlo[nvo++][1] = p[1];
114	} else if (inregion(s, cv, crit))
115	clipregion(s, p, cv, crit, vlo[nvo++]);
116	s = p;
117	}
118	return(nvo);
119	}
120
121
122	static int
123	box_clip_poly( /* clip polygon to box */
124	RREAL vl[MAXVERT][2],
125	int nv,
126	double xl,
127	double xr,
128	double yb,
129	double ya,
130	RREAL vlo[MAXVERT][2] /* return value */
131	)
132	{
133	RREAL vlt[MAXVERT][2];
134	int nvt, nvo;
135
136	nvt = hp_clip_poly(vl, nv, yb, CLIP_BELOW, vlt);
137	nvo = hp_clip_poly(vlt, nvt, ya, CLIP_ABOVE, vlo);
138	nvt = hp_clip_poly(vlo, nvo, xl, CLIP_LEFT, vlt);
139	nvo = hp_clip_poly(vlt, nvt, xr, CLIP_RIGHT, vlo);
140
141	return(nvo);
142	}
143
144
145	static double
146	minw2( /* compute square of minimum width */
147	RREAL vl[][2],
148	int nv,
149	double ar2
150	)
151	{
152	double d2, w2, w2min, w2max;
153	register RREAL p0, p1, *p2;
154	int i, j;
155	/* find minimum for all widths */
156	w2min = FHUGE;
157	p0 = vl[nv-1];
158	for (i = 0; i < nv; i++) { /* for each edge */
159	p1 = vl[i];
160	d2 = (p1[0]-p0[0])*(p1[0]-p0[0]) +
161	(p1[1]-p0[1])(p1[1]-p0[1])ar2;
162	w2max = 0.; /* find maximum for this side */
163	for (j = 1; j < nv-1; j++) {
164	p2 = vl[(i+j)%nv];
165	w2 = (p1[0]-p0[0])*(p2[1]-p0[1]) -
166	(p1[1]-p0[1])*(p2[0]-p0[0]);
167	w2 = w2w2ar2/d2; /* triangle height squared */
168	if (w2 > w2max)
169	w2max = w2;
170	}
171	if (w2max < w2min) /* global min. based on local max.'s */
172	w2min = w2max;
173	p0 = p1;
174	}
175	return(w2min);
176	}
177
178
179	static void
180	convex_center( /* compute center of convex polygon */
181	register RREAL vl[][2],
182	int nv,
183	RREAL cv[2] /* return value */
184	)
185	{
186	register int i;
187	/* simple average (suboptimal) */
188	cv[0] = cv[1] = 0.;
189	for (i = 0; i < nv; i++) {
190	cv[0] += vl[i][0];
191	cv[1] += vl[i][1];
192	}
193	cv[0] /= (double)nv;
194	cv[1] /= (double)nv;
195	}
196
197
198	static double
199	poly_area( /* compute area of polygon */
200	register RREAL vl[][2],
201	int nv
202	)
203	{
204	double a;
205	RREAL v0[2], v1[2];
206	register int i;
207
208	a = 0.;
209	v0[0] = vl[1][0] - vl[0][0];
210	v0[1] = vl[1][1] - vl[0][1];
211	for (i = 2; i < nv; i++) {
212	v1[0] = vl[i][0] - vl[0][0];
213	v1[1] = vl[i][1] - vl[0][1];
214	a += v0[0]v1[1] - v0[1]v1[0];
215	v0[0] = v1[0]; v0[1] = v1[1];
216	}
217	return(a * (a >= 0. ? .5 : -.5));
218	}
219
220
221	static int
222	convex_hull( /* compute polygon's convex hull */
223	RREAL vl[][2],
224	int nv,
225	RREAL vlo[][2] /* return value */
226	)
227	{
228	int nvo, nvt;
229	RREAL vlt[MAXVERT][2];
230	double voa, vta;
231	register int i, j;
232	/* start with original polygon */
233	for (i = nvo = nv; i--; ) {
234	vlo[i][0] = vl[i][0]; vlo[i][1] = vl[i][1];
235	}
236	voa = poly_area(vlo, nvo); /* compute its area */
237	for (i = 0; i < nvo; i++) { /* for each output vertex */
238	for (j = 0; j < i; j++) {
239	vlt[j][0] = vlo[j][0]; vlt[j][1] = vlo[j][1];
240	}
241	nvt = nvo - 1; /* make poly w/o vertex */
242	for (j = i; j < nvt; j++) {
243	vlt[j][0] = vlo[j+1][0]; vlt[j][1] = vlo[j+1][1];
244	}
245	vta = poly_area(vlt, nvt);
246	if (vta >= voa) { /* is simpler poly bigger? */
247	voa = vta; /* then use it */
248	for (j = nvo = nvt; j--; ) {
249	vlo[j][0] = vlt[j][0]; vlo[j][1] = vlt[j][1];
250	}
251	i--; /* next adjust */
252	}
253	}
254	return(nvo);
255	}
256
257
258	static void
259	spinsert( /* insert new source polygon */
260	int sn,
261	RREAL vl[][2],
262	int nv
263	)
264	{
265	register SPLIST *spn;
266	register int i;
267
268	if (nv < 3)
269	return;
270	if (nv > 3)
271	spn = (SPLIST )malloc(sizeof(SPLIST)+sizeof(RREAL)2*(nv-3));
272	else
273	spn = (SPLIST *)malloc(sizeof(SPLIST));
274	if (spn == NULL)
275	error(SYSTEM, "out of memory in spinsert");
276	spn->sn = sn;
277	for (i = spn->nv = nv; i--; ) {
278	spn->vl[i][0] = vl[i][0]; spn->vl[i][1] = vl[i][1];
279	}
280	spn->next = sphead; /* push onto global list */
281	sphead = spn;
282	}
283
284
285	static int
286	sourcepoly( /* compute image polygon for source */
287	int sn,
288	RREAL sp[MAXVERT][2]
289	)
290	{
291	static short cubeord[8][6] = {{1,3,2,6,4,5},{0,4,5,7,3,2},
292	{0,1,3,7,6,4},{0,1,5,7,6,2},
293	{0,2,6,7,5,1},{0,4,6,7,3,1},
294	{0,2,3,7,5,4},{1,5,4,6,2,3}};
295	register SRCREC *s = source + sn;
296	FVECT ap, ip;
297	RREAL pt[6][2];
298	int dir;
299	register int i, j;
300
301	if (s->sflags & (SDISTANT\|SFLAT)) {
302	if (s->sflags & SDISTANT) {
303	if (ourview.type == VT_PAR)
304	return(0); /* all or nothing case */
305	if (s->srad >= 0.05)
306	return(0); /* should never be a problem */
307	}
308	if (s->sflags & SFLAT) {
309	for (i = 0; i < 3; i++)
310	ap[i] = s->sloc[i] - ourview.vp[i];
311	if (DOT(ap, s->snorm) >= 0.)
312	return(0); /* source faces away */
313	}
314	for (j = 0; j < 4; j++) { /* four corners */
315	for (i = 0; i < 3; i++) {
316	ap[i] = s->sloc[i];
317	if ((j==1)\|(j==2)) ap[i] += s->ss[SU][i];
318	else ap[i] -= s->ss[SU][i];
319	if ((j==2)\|(j==3)) ap[i] += s->ss[SV][i];
320	else ap[i] -= s->ss[SV][i];
321	if (s->sflags & SDISTANT) {
322	ap[i] *= 1. + ourview.vfore;
323	ap[i] += ourview.vp[i];
324	}
325	}
326	viewloc(ip, &ourview, ap); /* find image point */
327	if (ip[2] <= 0.)
328	return(0); /* in front of view */
329	sp[j][0] = ip[0]; sp[j][1] = ip[1];
330	}
331	return(4);
332	}
333	/* identify furthest corner */
334	for (i = 0; i < 3; i++)
335	ap[i] = s->sloc[i] - ourview.vp[i];
336	dir = (DOT(ap,s->ss[SU])>0.) \|
337	(DOT(ap,s->ss[SV])>0.)<<1 \|
338	(DOT(ap,s->ss[SW])>0.)<<2 ;
339	/* order vertices based on this */
340	for (j = 0; j < 6; j++) {
341	for (i = 0; i < 3; i++) {
342	ap[i] = s->sloc[i];
343	if (cubeord[dir][j] & 1) ap[i] += s->ss[SU][i];
344	else ap[i] -= s->ss[SU][i];
345	if (cubeord[dir][j] & 2) ap[i] += s->ss[SV][i];
346	else ap[i] -= s->ss[SV][i];
347	if (cubeord[dir][j] & 4) ap[i] += s->ss[SW][i];
348	else ap[i] -= s->ss[SW][i];
349	}
350	viewloc(ip, &ourview, ap); /* find image point */
351	if (ip[2] <= 0.)
352	return(0); /* in front of view */
353	pt[j][0] = ip[0]; pt[j][1] = ip[1];
354	}
355	return(convex_hull(pt, 6, sp)); /* make sure it's convex */
356	}
357
358
359	/* initialize by finding sources smaller than rad */
360	extern void
361	init_drawsources(
362	int rad /* source sample size */
363	)
364	{
365	RREAL spoly[MAXVERT][2];
366	int nsv;
367	register SPLIST *sp;
368	register int i;
369	/* free old source list if one */
370	for (sp = sphead; sp != NULL; sp = sphead) {
371	sphead = sp->next;
372	free((void *)sp);
373	}
374	/* loop through all sources */
375	for (i = nsources; i--; ) {
376	/* compute image polygon for source */
377	if (!(nsv = sourcepoly(i, spoly)))
378	continue;
379	/* clip to image boundaries */
380	if (!(nsv = box_clip_poly(spoly, nsv, 0., 1., 0., 1., spoly)))
381	continue;
382	/* big enough for standard sampling? */
383	if (minw2(spoly, nsv, ourview.vn2/ourview.hn2) >
384	(double)rad*rad/hres/hres)
385	continue;
386	/* OK, add to our list */
387	spinsert(i, spoly, nsv);
388	}
389	}
390
391	extern void /* add sources smaller than rad to computed subimage */
392	drawsources(
393	COLOR pic[], / subimage pixel value array */
394	float zbf[], / subimage distance array (opt.) */
395	int x0, /* origin and size of subimage */
396	int xsiz,
397	int y0,
398	int ysiz
399	)
400	{
401	RREAL spoly[MAXVERT][2], ppoly[MAXVERT][2];
402	int nsv, npv;
403	int xmin, xmax, ymin, ymax, x, y;
404	RREAL cxy[2];
405	double w;
406	RAY sr;
407	register SPLIST *sp;
408	register int i;
409	/* check each source in our list */
410	for (sp = sphead; sp != NULL; sp = sp->next) {
411	/* clip source poly to subimage */
412	nsv = box_clip_poly(sp->vl, sp->nv,
413	(double)x0/hres, (double)(x0+xsiz)/hres,
414	(double)y0/vres, (double)(y0+ysiz)/vres, spoly);
415	if (!nsv)
416	continue;
417	/* find common subimage (BBox) */
418	xmin = x0 + xsiz; xmax = x0;
419	ymin = y0 + ysiz; ymax = y0;
420	for (i = 0; i < nsv; i++) {
421	if ((double)xmin/hres > spoly[i][0])
422	xmin = spoly[i][0]*hres + FTINY;
423	if ((double)xmax/hres < spoly[i][0])
424	xmax = spoly[i][0]*hres - FTINY;
425	if ((double)ymin/vres > spoly[i][1])
426	ymin = spoly[i][1]*vres + FTINY;
427	if ((double)ymax/vres < spoly[i][1])
428	ymax = spoly[i][1]*vres - FTINY;
429	}
430	/* evaluate each pixel in BBox */
431	for (y = ymin; y <= ymax; y++)
432	for (x = xmin; x <= xmax; x++) {
433	/* subarea for pixel */
434	npv = box_clip_poly(spoly, nsv,
435	(double)x/hres, (x+1.)/hres,
436	(double)y/vres, (y+1.)/vres,
437	ppoly);
438	if (!npv)
439	continue; /* no overlap */
440	convex_center(ppoly, npv, cxy);
441	if ((sr.rmax = viewray(sr.rorg,sr.rdir,&ourview,
442	cxy[0],cxy[1])) < -FTINY)
443	continue; /* not in view */
444	if (source[sp->sn].sflags & SSPOT &&
445	spotout(&sr, source[sp->sn].sl.s))
446	continue; /* outside spot */
447	rayorigin(&sr, NULL, PRIMARY, 1.0);
448	rayvalue(&sr); /* compute value */
449	if (bright(sr.rcol) <= FTINY)
450	continue; /* missed/blocked */
451	/* modify pixel */
452	w = poly_area(ppoly, npv) * hres * vres;
453	if (zbf[y-y0] != NULL &&
454	sr.rt < 0.99*zbf[y-y0][x-x0]) {
455	zbf[y-y0][x-x0] = sr.rt;
456	} else if (!bigdiff(sr.rcol, pic[y-y0][x-x0],
457	0.01)) { /* source sample */
458	scalecolor(pic[y-y0][x-x0], w);
459	continue;
460	}
461	scalecolor(sr.rcol, w);
462	scalecolor(pic[y-y0][x-x0], 1.-w);
463	addcolor(pic[y-y0][x-x0], sr.rcol);
464	}
465	}
466	}