src/util/glareval.c

/* Copyright (c) 1991 Regents of the University of California */

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

/*
 * Compute pixels for glare calculation
 */

#include "glare.h"
#include <sys/param.h>
                                        /* compute rtrace buffer size */
#ifndef PIPE_BUF
#define PIPE_BUF        512             /* hyperconservative */
#endif
#define MAXPIX          (PIPE_BUF/(6*sizeof(float)) - 1)

#ifndef BSD
#define vfork           fork
#endif

#define NSCANS          64              /* number of scanlines to buffer */

int     rt_pid = -1;            /* process id for rtrace */
int     fd_tort, fd_fromrt;     /* pipe descriptors */

FILE    *pictfp = NULL;         /* picture file pointer */
double  exposure;               /* picture exposure */
int     pxsiz, pysiz;           /* picture dimensions */
int     curpos;                 /* current scanline */
long    *scanpos;               /* scanline positions */
struct {
        long    lused;          /* for LRU replacement */
        int     y;              /* scanline position */
        COLR    *sl;            /* scanline contents */
} scan[NSCANS];         /* buffered scanlines */

static long     ncall = 0L;     /* number of calls to getpictscan */
static long     nread = 0L;     /* number of scanlines read */

extern long     ftell();


COLR *
getpictscan(y)                  /* get picture scanline */
int     y;
{
        int     minused;
        register int    i;
                                        /* first check our buffers */
        ncall++;
        minused = 0;
        for (i = 0; i < NSCANS; i++) {
                if (scan[i].y == y) {
                        scan[i].lused = ncall;
                        return(scan[i].sl);
                }
                if (scan[i].lused < scan[minused].lused)
                        minused = i;
        }
                                        /* not there, read it in */
        if (scanpos[y] < 0) {                   /* need to search */
                for (i = y+1; i < curpos; i++)
                        if (scanpos[i] >= 0) {
                                if (fseek(pictfp, scanpos[i], 0) < 0)
                                        goto seekerr;
                                curpos = i;
                                break;
                        }
                while (curpos >= y) {
                        scanpos[curpos] = ftell(pictfp);
                        if (freadcolrs(scan[minused].sl, pxsiz, pictfp) < 0)
                                goto readerr;
                        nread++;
                        curpos--;
                }
        } else {
                if (curpos != y && fseek(pictfp, scanpos[y], 0) < 0)
                        goto seekerr;
                if (freadcolrs(scan[minused].sl, pxsiz, pictfp) < 0)
                        goto readerr;
                nread++;
                curpos = y-1;
        }
        scan[minused].lused = ncall;
        scan[minused].y = y;
        return(scan[minused].sl);
readerr:
        fprintf(stderr, "%s: picture read error\n", progname);
        exit(1);
seekerr:
        fprintf(stderr, "%s: picture seek error\n", progname);
        exit(1);
}


#ifdef DEBUG
pict_stats()                    /* print out picture read statistics */
{
        static long     lastcall = 0L;  /* ncall at last report */
        static long     lastread = 0L;  /* nread at last report */

        if (ncall == lastcall)
                return;
        fprintf(stderr, "%s: %ld scanlines read in %ld calls\n",
                        progname, nread-lastread, ncall-lastcall);
        lastcall = ncall;
        lastread = nread;
}
#endif


double
pict_val(vd)                    /* find picture value for view direction */
FVECT   vd;
{
        FVECT   pp;
        double  vpx, vpy, vpz;
        COLOR   res;

        if (pictfp == NULL)
                return(-1.0);
        pp[0] = pictview.vp[0] + vd[0];
        pp[1] = pictview.vp[1] + vd[1];
        pp[2] = pictview.vp[2] + vd[2];
        viewpixel(&vpx, &vpy, &vpz, &pictview, pp);
        if (vpz <= FTINY || vpx < 0. || vpx >= 1. || vpy < 0. || vpy >= 1.)
                return(-1.0);
        colr_color(res, getpictscan((int)(vpy*pysiz))[(int)(vpx*pxsiz)]);
        return(luminance(res)/exposure);
}


double
getviewpix(vh, vv)              /* compute single view pixel */
int     vh, vv;
{
        FVECT   dir;
        float   rt_buf[6];
        double  res;

        if (compdir(dir, vh, vv) < 0)
                return(-1.0);
        npixinvw++;
        if ((res = pict_val(dir)) >= 0.0)
                return(res);
        if (rt_pid == -1) {
                npixmiss++;
                return(-1.0);
        }
        rt_buf[0] = ourview.vp[0];
        rt_buf[1] = ourview.vp[1];
        rt_buf[2] = ourview.vp[2];
        rt_buf[3] = dir[0];
        rt_buf[4] = dir[1];
        rt_buf[5] = dir[2];
        rt_compute(rt_buf, 1);
        return(luminance(rt_buf));
}


getviewspan(vv, vb)             /* compute a span of view pixels */
int     vv;
float   *vb;
{
        float   rt_buf[6*MAXPIX];       /* rtrace send/receive buffer */
        register int    n;              /* number of pixels in buffer */
        short   buf_vh[MAXPIX];         /* pixel positions */
        FVECT   dir;
        register int    vh;

#ifdef DEBUG
        if (verbose)
                fprintf(stderr, "%s: computing view span at %d...\n",
                                progname, vv);
#endif
        n = 0;
        for (vh = -hsize; vh <= hsize; vh++) {
                if (compdir(dir, vh, vv) < 0) { /* off viewable region */
                        vb[vh+hsize] = -1.0;
                        continue;
                }
                npixinvw++;
                if ((vb[vh+hsize] = pict_val(dir)) >= 0.0)
                        continue;
                if (rt_pid == -1) {             /* missing information */
                        npixmiss++;
                        continue;
                }
                                                /* send to rtrace */
                if (n >= MAXPIX) {                      /* flush */
                        rt_compute(rt_buf, n);
                        while (n-- > 0)
                                vb[buf_vh[n]+hsize] = luminance(rt_buf+3*n);
                }
                rt_buf[6*n] = ourview.vp[0];
                rt_buf[6*n+1] = ourview.vp[1];
                rt_buf[6*n+2] = ourview.vp[2];
                rt_buf[6*n+3] = dir[0];
                rt_buf[6*n+4] = dir[1];
                rt_buf[6*n+5] = dir[2];
                buf_vh[n++] = vh;
        }
#ifdef DEBUG
        if (verbose)
                pict_stats();
#endif
        if (n > 0) {                            /* process pending buffer */
                rt_compute(rt_buf, n);
                while (n-- > 0)
                        vb[buf_vh[n]+hsize] = luminance(rt_buf+3*n);
        }
}


rt_compute(pb, np)              /* process buffer through rtrace */
float   *pb;
int     np;
{
        static float    nbuf[6] = {0.,0.,0.,0.,0.,0.};

#ifdef DEBUG
        if (verbose && np > 1)
                fprintf(stderr, "%s: sending %d samples to rtrace...\n",
                                progname, np);
#endif
        if (writebuf(fd_tort,(char *)pb,6*sizeof(float)*np) < 6*sizeof(float)*np
                || writebuf(fd_tort,(char *)nbuf,sizeof(nbuf)) < sizeof(nbuf)) {
                fprintf(stderr, "%s: error writing to rtrace process\n",
                                progname);
                exit(1);
        }
        if (readbuf(fd_fromrt, (char *)pb, 3*sizeof(float)*np)
                        < 3*sizeof(float)*np) {
                fprintf(stderr, "%s: error reading from rtrace process\n",
                                progname);
                exit(1);
        }
}


getexpos(s)                     /* get exposure from header line */
char    *s;
{
        if (isexpos(s))
                exposure *= exposval(s);
}


open_pict(fn)                   /* open picture file */
char    *fn;
{
        register int    i;

        if ((pictfp = fopen(fn, "r")) == NULL) {
                fprintf("%s: cannot open\n", fn);
                exit(1);
        }
        exposure = 1.0;
        getheader(pictfp, getexpos);
        if (fgetresolu(&pxsiz, &pysiz, pictfp) != (YMAJOR|YDECR)) {
                fprintf("%s: bad picture resolution\n", fn);
                exit(1);
        }
        scanpos = (long *)malloc(pysiz*sizeof(long));
        if (scanpos == NULL)
                memerr("scanline positions");
        for (i = pysiz-1; i >= 0; i--)
                scanpos[i] = -1L;
        curpos = pysiz-1;
        for (i = 0; i < NSCANS; i++) {
                scan[i].lused = -1;
                scan[i].y = -1;
                scan[i].sl = (COLR *)malloc(pxsiz*sizeof(COLR));
                if (scan[i].sl == NULL)
                        memerr("scanline buffers");
        }
}


close_pict()                    /* done with picture */
{
        register int    i;

        if (pictfp == NULL)
                return;
        fclose(pictfp);
        free((char *)scanpos);
        for (i = 0; i < NSCANS; i++)
                free((char *)scan[i].sl);
        pictfp = NULL;
}


fork_rtrace(av)                 /* open pipe and start rtrace */
char    *av[];
{
        int     p0[2], p1[2];

        if (pipe(p0) < 0 || pipe(p1) < 0) {
                perror(progname);
                exit(1);
        }
        if ((rt_pid = vfork()) == 0) {          /* if child */
                close(p0[1]);
                close(p1[0]);
                if (p0[0] != 0) {       /* connect p0 to stdin */
                        dup2(p0[0], 0);
                        close(p0[0]);
                }
                if (p1[1] != 0) {       /* connect p1 to stdout */
                        dup2(p1[1], 1);
                        close(p1[1]);
                }
                execvp(av[0], av);
                perror(av[0]);
                _exit(127);
        }
        if (rt_pid == -1) {
                perror(progname);
                exit(1);
        }
        close(p0[0]);
        close(p1[1]);
        fd_tort = p0[1];
        fd_fromrt = p1[0];
}


done_rtrace()                   /* wait for rtrace to finish */
{
        int     pid, status;

        if (rt_pid == -1)
                return;
        close(fd_tort);
        close(fd_fromrt);
        while ((pid = wait(&status)) != -1 && pid != rt_pid)
                ;
        if (pid == rt_pid && status != 0) {
                fprintf(stderr, "%s: bad status (%d) from rtrace\n",
                                progname, status);
                exit(1);
        }
        rt_pid = -1;
}


int
readbuf(fd, bpos, siz)
int     fd;
char    *bpos;
int     siz;
{
        register int    cc, nrem = siz;

        while (nrem > 0 && (cc = read(fd, bpos, nrem)) > 0) {
                bpos += cc;
                nrem -= cc;
        }
        if (cc < 0)
                return(cc);
        return(siz-nrem);
}


int
writebuf(fd, bpos, siz)
char    *bpos;
int     siz;
{
        register int    cc, nrem = siz;

        while (nrem > 0 && (cc = write(fd, bpos, nrem)) > 0) {
                bpos += cc;
                nrem -= cc;
        }
        if (cc < 0)
                return(cc);
        return(siz-nrem);
}
Revision:	1.7
Committed:	Tue Apr 2 14:29:17 1991 UTC (34 years, 7 months ago) by greg
Content type:	text/plain
Branch:	MAIN
Changes since 1.6:	+8 -2 lines
Log Message:	added test for insufficient data
#	Content
1	/* Copyright (c) 1991 Regents of the University of California */
2
3	#ifndef lint
4	static char SCCSid[] = "$SunId$ LBL";
5	#endif
6
7	/*
8	* Compute pixels for glare calculation
9	*/
10
11	#include "glare.h"
12	#include <sys/param.h>
13	/* compute rtrace buffer size */
14	#ifndef PIPE_BUF
15	#define PIPE_BUF 512 /* hyperconservative */
16	#endif
17	#define MAXPIX (PIPE_BUF/(6*sizeof(float)) - 1)
18
19	#ifndef BSD
20	#define vfork fork
21	#endif
22
23	#define NSCANS 64 /* number of scanlines to buffer */
24
25	int rt_pid = -1; /* process id for rtrace */
26	int fd_tort, fd_fromrt; /* pipe descriptors */
27
28	FILE pictfp = NULL; / picture file pointer */
29	double exposure; /* picture exposure */
30	int pxsiz, pysiz; /* picture dimensions */
31	int curpos; /* current scanline */
32	long scanpos; / scanline positions */
33	struct {
34	long lused; /* for LRU replacement */
35	int y; /* scanline position */
36	COLR sl; / scanline contents */
37	} scan[NSCANS]; /* buffered scanlines */
38
39	static long ncall = 0L; /* number of calls to getpictscan */
40	static long nread = 0L; /* number of scanlines read */
41
42	extern long ftell();
43
44
45	COLR *
46	getpictscan(y) /* get picture scanline */
47	int y;
48	{
49	int minused;
50	register int i;
51	/* first check our buffers */
52	ncall++;
53	minused = 0;
54	for (i = 0; i < NSCANS; i++) {
55	if (scan[i].y == y) {
56	scan[i].lused = ncall;
57	return(scan[i].sl);
58	}
59	if (scan[i].lused < scan[minused].lused)
60	minused = i;
61	}
62	/* not there, read it in */
63	if (scanpos[y] < 0) { /* need to search */
64	for (i = y+1; i < curpos; i++)
65	if (scanpos[i] >= 0) {
66	if (fseek(pictfp, scanpos[i], 0) < 0)
67	goto seekerr;
68	curpos = i;
69	break;
70	}
71	while (curpos >= y) {
72	scanpos[curpos] = ftell(pictfp);
73	if (freadcolrs(scan[minused].sl, pxsiz, pictfp) < 0)
74	goto readerr;
75	nread++;
76	curpos--;
77	}
78	} else {
79	if (curpos != y && fseek(pictfp, scanpos[y], 0) < 0)
80	goto seekerr;
81	if (freadcolrs(scan[minused].sl, pxsiz, pictfp) < 0)
82	goto readerr;
83	nread++;
84	curpos = y-1;
85	}
86	scan[minused].lused = ncall;
87	scan[minused].y = y;
88	return(scan[minused].sl);
89	readerr:
90	fprintf(stderr, "%s: picture read error\n", progname);
91	exit(1);
92	seekerr:
93	fprintf(stderr, "%s: picture seek error\n", progname);
94	exit(1);
95	}
96
97
98	#ifdef DEBUG
99	pict_stats() /* print out picture read statistics */
100	{
101	static long lastcall = 0L; /* ncall at last report */
102	static long lastread = 0L; /* nread at last report */
103
104	if (ncall == lastcall)
105	return;
106	fprintf(stderr, "%s: %ld scanlines read in %ld calls\n",
107	progname, nread-lastread, ncall-lastcall);
108	lastcall = ncall;
109	lastread = nread;
110	}
111	#endif
112
113
114	double
115	pict_val(vd) /* find picture value for view direction */
116	FVECT vd;
117	{
118	FVECT pp;
119	double vpx, vpy, vpz;
120	COLOR res;
121
122	if (pictfp == NULL)
123	return(-1.0);
124	pp[0] = pictview.vp[0] + vd[0];
125	pp[1] = pictview.vp[1] + vd[1];
126	pp[2] = pictview.vp[2] + vd[2];
127	viewpixel(&vpx, &vpy, &vpz, &pictview, pp);
128	if (vpz <= FTINY \|\| vpx < 0. \|\| vpx >= 1. \|\| vpy < 0. \|\| vpy >= 1.)
129	return(-1.0);
130	colr_color(res, getpictscan((int)(vpypysiz))[(int)(vpxpxsiz)]);
131	return(luminance(res)/exposure);
132	}
133
134
135	double
136	getviewpix(vh, vv) /* compute single view pixel */
137	int vh, vv;
138	{
139	FVECT dir;
140	float rt_buf[6];
141	double res;
142
143	if (compdir(dir, vh, vv) < 0)
144	return(-1.0);
145	npixinvw++;
146	if ((res = pict_val(dir)) >= 0.0)
147	return(res);
148	if (rt_pid == -1) {
149	npixmiss++;
150	return(-1.0);
151	}
152	rt_buf[0] = ourview.vp[0];
153	rt_buf[1] = ourview.vp[1];
154	rt_buf[2] = ourview.vp[2];
155	rt_buf[3] = dir[0];
156	rt_buf[4] = dir[1];
157	rt_buf[5] = dir[2];
158	rt_compute(rt_buf, 1);
159	return(luminance(rt_buf));
160	}
161
162
163	getviewspan(vv, vb) /* compute a span of view pixels */
164	int vv;
165	float *vb;
166	{
167	float rt_buf[6MAXPIX]; / rtrace send/receive buffer */
168	register int n; /* number of pixels in buffer */
169	short buf_vh[MAXPIX]; /* pixel positions */
170	FVECT dir;
171	register int vh;
172
173	#ifdef DEBUG
174	if (verbose)
175	fprintf(stderr, "%s: computing view span at %d...\n",
176	progname, vv);
177	#endif
178	n = 0;
179	for (vh = -hsize; vh <= hsize; vh++) {
180	if (compdir(dir, vh, vv) < 0) { /* off viewable region */
181	vb[vh+hsize] = -1.0;
182	continue;
183	}
184	npixinvw++;
185	if ((vb[vh+hsize] = pict_val(dir)) >= 0.0)
186	continue;
187	if (rt_pid == -1) { /* missing information */
188	npixmiss++;
189	continue;
190	}
191	/* send to rtrace */
192	if (n >= MAXPIX) { /* flush */
193	rt_compute(rt_buf, n);
194	while (n-- > 0)
195	vb[buf_vh[n]+hsize] = luminance(rt_buf+3*n);
196	}
197	rt_buf[6*n] = ourview.vp[0];
198	rt_buf[6*n+1] = ourview.vp[1];
199	rt_buf[6*n+2] = ourview.vp[2];
200	rt_buf[6*n+3] = dir[0];
201	rt_buf[6*n+4] = dir[1];
202	rt_buf[6*n+5] = dir[2];
203	buf_vh[n++] = vh;
204	}
205	#ifdef DEBUG
206	if (verbose)
207	pict_stats();
208	#endif
209	if (n > 0) { /* process pending buffer */
210	rt_compute(rt_buf, n);
211	while (n-- > 0)
212	vb[buf_vh[n]+hsize] = luminance(rt_buf+3*n);
213	}
214	}
215
216
217	rt_compute(pb, np) /* process buffer through rtrace */
218	float *pb;
219	int np;
220	{
221	static float nbuf[6] = {0.,0.,0.,0.,0.,0.};
222
223	#ifdef DEBUG
224	if (verbose && np > 1)
225	fprintf(stderr, "%s: sending %d samples to rtrace...\n",
226	progname, np);
227	#endif
228	if (writebuf(fd_tort,(char )pb,6sizeof(float)np) < 6sizeof(float)*np
229	\|\| writebuf(fd_tort,(char *)nbuf,sizeof(nbuf)) < sizeof(nbuf)) {
230	fprintf(stderr, "%s: error writing to rtrace process\n",
231	progname);
232	exit(1);
233	}
234	if (readbuf(fd_fromrt, (char )pb, 3sizeof(float)*np)
235	< 3sizeof(float)np) {
236	fprintf(stderr, "%s: error reading from rtrace process\n",
237	progname);
238	exit(1);
239	}
240	}
241
242
243	getexpos(s) /* get exposure from header line */
244	char *s;
245	{
246	if (isexpos(s))
247	exposure *= exposval(s);
248	}
249
250
251	open_pict(fn) /* open picture file */
252	char *fn;
253	{
254	register int i;
255
256	if ((pictfp = fopen(fn, "r")) == NULL) {
257	fprintf("%s: cannot open\n", fn);
258	exit(1);
259	}
260	exposure = 1.0;
261	getheader(pictfp, getexpos);
262	if (fgetresolu(&pxsiz, &pysiz, pictfp) != (YMAJOR\|YDECR)) {
263	fprintf("%s: bad picture resolution\n", fn);
264	exit(1);
265	}
266	scanpos = (long )malloc(pysizsizeof(long));
267	if (scanpos == NULL)
268	memerr("scanline positions");
269	for (i = pysiz-1; i >= 0; i--)
270	scanpos[i] = -1L;
271	curpos = pysiz-1;
272	for (i = 0; i < NSCANS; i++) {
273	scan[i].lused = -1;
274	scan[i].y = -1;
275	scan[i].sl = (COLR )malloc(pxsizsizeof(COLR));
276	if (scan[i].sl == NULL)
277	memerr("scanline buffers");
278	}
279	}
280
281
282	close_pict() /* done with picture */
283	{
284	register int i;
285
286	if (pictfp == NULL)
287	return;
288	fclose(pictfp);
289	free((char *)scanpos);
290	for (i = 0; i < NSCANS; i++)
291	free((char *)scan[i].sl);
292	pictfp = NULL;
293	}
294
295
296	fork_rtrace(av) /* open pipe and start rtrace */
297	char *av[];
298	{
299	int p0[2], p1[2];
300
301	if (pipe(p0) < 0 \|\| pipe(p1) < 0) {
302	perror(progname);
303	exit(1);
304	}
305	if ((rt_pid = vfork()) == 0) { /* if child */
306	close(p0[1]);
307	close(p1[0]);
308	if (p0[0] != 0) { /* connect p0 to stdin */
309	dup2(p0[0], 0);
310	close(p0[0]);
311	}
312	if (p1[1] != 0) { /* connect p1 to stdout */
313	dup2(p1[1], 1);
314	close(p1[1]);
315	}
316	execvp(av[0], av);
317	perror(av[0]);
318	_exit(127);
319	}
320	if (rt_pid == -1) {
321	perror(progname);
322	exit(1);
323	}
324	close(p0[0]);
325	close(p1[1]);
326	fd_tort = p0[1];
327	fd_fromrt = p1[0];
328	}
329
330
331	done_rtrace() /* wait for rtrace to finish */
332	{
333	int pid, status;
334
335	if (rt_pid == -1)
336	return;
337	close(fd_tort);
338	close(fd_fromrt);
339	while ((pid = wait(&status)) != -1 && pid != rt_pid)
340	;
341	if (pid == rt_pid && status != 0) {
342	fprintf(stderr, "%s: bad status (%d) from rtrace\n",
343	progname, status);
344	exit(1);
345	}
346	rt_pid = -1;
347	}
348
349
350	int
351	readbuf(fd, bpos, siz)
352	int fd;
353	char *bpos;
354	int siz;
355	{
356	register int cc, nrem = siz;
357
358	while (nrem > 0 && (cc = read(fd, bpos, nrem)) > 0) {
359	bpos += cc;
360	nrem -= cc;
361	}
362	if (cc < 0)
363	return(cc);
364	return(siz-nrem);
365	}
366
367
368	int
369	writebuf(fd, bpos, siz)
370	char *bpos;
371	int siz;
372	{
373	register int cc, nrem = siz;
374
375	while (nrem > 0 && (cc = write(fd, bpos, nrem)) > 0) {
376	bpos += cc;
377	nrem -= cc;
378	}
379	if (cc < 0)
380	return(cc);
381	return(siz-nrem);
382	}