src/rt/raycalls.c

#ifndef lint
static const char       RCSid[] = "$Id: raycalls.c,v 2.24 2019/04/18 23:58:22 greg Exp $";
#endif
/*
 *  raycalls.c - interface for running Radiance rendering as a library
 *
 *  External symbols declared in ray.h
 */

#include "copyright.h"

/*
 *  These routines are designed to aid the programmer who wishes
 *  to call Radiance as a library.  Unfortunately, the system was
 *  not originally intended to be run this way, and there are some
 *  awkward limitations to contend with.  The most irritating
 *  perhaps is that the global variables and functions do not have
 *  a prefix, and the symbols are a bit generic.  This results in a
 *  serious invasion of the calling application's name-space, and
 *  you may need to rename either some Radiance routines or some
 *  of your routines to avoid conflicts.  Another limitation is
 *  that the global variables are not gathered together into any
 *  sort of context, so it is impossible to simultaneously run
 *  this library on multiple scenes or in multiple threads.
 *  You get one scene and one thread, and if you want more, you
 *  will have to go with the process model defined in raypcalls.c.
 *  Finally, unrecoverable errors result in a call to the application-
 *  defined function quit().  The usual thing to do is to call exit().
 *  You might want to do something else instead, like
 *  call setjmp()/longjmp() to bring you back to the calling
 *  function for recovery.  You may also wish to define your own
 *  wputs(s) and eputs(s) functions to output warning and error
 *  messages, respectively.
 *
 *  With those caveats, we have attempted to make the interface
 *  as simple as we can.  Global variables and their defaults
 *  are defined below, and including "ray.h" declares these
 *  along with all the routines you are likely to need.  First,
 *  assign the global variable progname to your argv[0], then
 *  change the rendering parameters as you like.  If you have a set
 *  of option arguments you are working from, the getrenderopt(ac,av)
 *  call should be very useful.  Before tracing any rays, you
 *  must read in the octree with a call to ray_init(oct).
 *  Passing NULL for the file name causes ray_init() to read
 *  the octree from the standard input -- rarely a good idea.
 *  However, one may read an octree from a program (such as
 *  oconv) by preceding a shell command by a '!' character.
 *
 *  To trace a ray, define a RAY object myRay and assign:
 *
 *      myRay.rorg = ( ray origin point )
 *      myRay.rdir = ( normalized ray direction )
 *      myRay.rmax = ( maximum length, or zero for no limit )
 *
 *  If you are rendering from a VIEW structure, this can be
 *  accomplished with a single call for the ray at (x,y):
 *
 *      myRay.rmax = viewray(myRay.rorg, myRay.rdir, &myView, x, y);
 *
 *  Then, trace the primary ray with:
 *
 *      ray_trace(&myRay);
 *
 *  The resulting contents of myRay should provide you with
 *  more than enough information about what the ray hit,
 *  the computed value, etc.  For further clues of how to
 *  compute irradiance, how to get callbacks on the evaluated
 *  ray tree, etc., see the contents of rtrace.c.  See
 *  also the rpmain.c, rtmain.c, and rvmain.c modules
 *  to learn more how rendering options are processed.
 *
 *  When you are done, you may call ray_done(1) to clean
 *  up memory used by Radiance.  It doesn't free everything,
 *  but it makes a valiant effort.  If you call ray_done(0),
 *  it leaves data that is likely to be reused, including
 *  loaded data files and fonts.  The library may be
 *  restarted at any point by calling ray_init() on a new
 *  octree.
 *
 *  The call ray_save(rp) fills a parameter structure
 *  with the current global parameter settings, which may be
 *  restored at any time with a call to ray_restore(rp).
 *  This buffer contains no linked information, and thus
 *  may be passed between processes using write() and
 *  read() calls, so long as byte order is maintained.
 *  Calling ray_restore(NULL) restores the original
 *  default parameters, which is also retrievable with
 *  the call ray_defaults(rp).  (These  should be the
 *  same as the defaults for rtrace.)
 */

#include <string.h>
#include <time.h>

#include  "ray.h"
#include  "source.h"
#include  "bsdf.h"
#include  "ambient.h"
#include  "otypes.h"
#include  "random.h"
#include  "data.h"
#include  "font.h"
#include  "pmapray.h"

char    *progname = "unknown_app";      /* caller sets to argv[0] */

char    *octname;                       /* octree name we are given */

char    *shm_boundary = NULL;           /* boundary of shared memory */

CUBE    thescene;                       /* our scene */
OBJECT  nsceneobjs;                     /* number of objects in our scene */

int     dimlist[MAXDIM];                /* sampling dimensions */
int     ndims = 0;                      /* number of sampling dimensions */
int     samplendx = 0;                  /* index for this sample */

void    (*trace)() = NULL;              /* trace call */

void    (*addobjnotify[8])() = {ambnotify, NULL};

int     do_irrad = 0;                   /* compute irradiance? */

int     rand_samp = 1;                  /* pure Monte Carlo sampling? */

double  dstrsrc = 0.0;                  /* square source distribution */
double  shadthresh = .03;               /* shadow threshold */
double  shadcert = .75;                 /* shadow certainty */
int     directrelay = 2;                /* number of source relays */
int     vspretest = 512;                /* virtual source pretest density */
int     directvis = 1;                  /* sources visible? */
double  srcsizerat = .2;                /* maximum ratio source size/dist. */

COLOR   cextinction = BLKCOLOR;         /* global extinction coefficient */
COLOR   salbedo = BLKCOLOR;             /* global scattering albedo */
double  seccg = 0.;                     /* global scattering eccentricity */
double  ssampdist = 0.;                 /* scatter sampling distance */

double  specthresh = .15;               /* specular sampling threshold */
double  specjitter = 1.;                /* specular sampling jitter */

int     backvis = 1;                    /* back face visibility */

int     maxdepth = -10;                 /* maximum recursion depth */
double  minweight = 2e-3;               /* minimum ray weight */

char    *ambfile = NULL;                /* ambient file name */
COLOR   ambval = BLKCOLOR;              /* ambient value */
int     ambvwt = 0;                     /* initial weight for ambient value */
double  ambacc = 0.1;                   /* ambient accuracy */
int     ambres = 256;                   /* ambient resolution */
int     ambdiv = 1024;                  /* ambient divisions */
int     ambssamp = 512;                 /* ambient super-samples */
int     ambounce = 0;                   /* ambient bounces */
char    *amblist[AMBLLEN+1];            /* ambient include/exclude list */
int     ambincl = -1;                   /* include == 1, exclude == 0 */


static void
reset_random(void)              /* re-initialize random number generator */
{
        if (rand_samp) {
                srandom((long)time(0));
                initurand(0);
        } else {
                srandom(0L);
                initurand(2048);
        }
}


void
ray_init(                       /* initialize ray-tracing calculation */
        char    *otnm
)
{
        if (nobjects > 0)               /* free old scene data */
                ray_done(0);
                                        /* initialize object types */
        if (ofun[OBJ_SPHERE].funp == o_default)
                initotypes();
                                        /* initialize urand */
        reset_random();
                                        /* read scene octree */
        readoct(octname = otnm, ~(IO_FILES|IO_INFO), &thescene, NULL);
        nsceneobjs = nobjects;
                                        /* PMAP: Init & load photon maps */
        ray_init_pmap();
                                        /* find and mark sources */
        marksources();
                                        /* initialize ambient calculation */
        setambient();
                                        /* ready to go... (almost) */
}


void
ray_trace(                      /* trace a primary ray */
        RAY     *r
)
{
        rayorigin(r, PRIMARY, NULL, NULL);
        samplendx++;
        rayvalue(r);            /* assumes origin and direction are set */
}


void
ray_done(               /* free ray-tracing data */
        int     freall
)
{
        retainfonts = 1;
        ambdone();
        ambnotify(OVOID);
        freesources();
        freeobjects(0, nobjects);
        donesets();
        octdone();
        thescene.cutree = EMPTY;
        octname = NULL;
        retainfonts = 0;
        if (freall) {
                freefont(NULL);
                freedata(NULL);
                SDfreeCache(NULL);
                initurand(0);
        }
        if (nobjects > 0) {
                sprintf(errmsg, "%ld objects left after call to ray_done()",
                                (long)nobjects);
                error(WARNING, errmsg);
        }
        
        ray_done_pmap();
}


void
ray_save(                       /* save current parameter settings */
        RAYPARAMS       *rp
)
{
        int     i, ndx;

        if (rp == NULL)
                return;
        rp->do_irrad = do_irrad;
        rp->rand_samp = rand_samp;
        rp->dstrsrc = dstrsrc;
        rp->shadthresh = shadthresh;
        rp->shadcert = shadcert;
        rp->directrelay = directrelay;
        rp->vspretest = vspretest;
        rp->directvis = directvis;
        rp->srcsizerat = srcsizerat;
        copycolor(rp->cextinction, cextinction);
        copycolor(rp->salbedo, salbedo);
        rp->seccg = seccg;
        rp->ssampdist = ssampdist;
        rp->specthresh = specthresh;
        rp->specjitter = specjitter;
        rp->backvis = backvis;
        rp->maxdepth = maxdepth;
        rp->minweight = minweight;
        if (ambfile != NULL)
                strncpy(rp->ambfile, ambfile, sizeof(rp->ambfile)-1);
        else
                memset(rp->ambfile, '\0', sizeof(rp->ambfile));
        copycolor(rp->ambval, ambval);
        rp->ambvwt = ambvwt;
        rp->ambacc = ambacc;
        rp->ambres = ambres;
        rp->ambdiv = ambdiv;
        rp->ambssamp = ambssamp;
        rp->ambounce = ambounce;
        rp->ambincl = ambincl;
        memset(rp->amblval, '\0', sizeof(rp->amblval));
        ndx = 0;
        for (i = 0; i < AMBLLEN && amblist[i] != NULL; i++) {
                int     len = strlen(amblist[i]);
                if (ndx+len >= sizeof(rp->amblval))
                        break;
                strcpy(rp->amblval+ndx, amblist[i]);
                rp->amblndx[i] = ndx;
                ndx += len+1;
        }
        while (i <= AMBLLEN)
                rp->amblndx[i++] = -1;
                
        /* PMAP: save photon mapping params */
        ray_save_pmap(rp);
}


void
ray_restore(                    /* restore parameter settings */
        RAYPARAMS       *rp
)
{
        int     i;

        if (rp == NULL) {               /* restore defaults */
                RAYPARAMS       dflt;
                ray_defaults(&dflt);
                ray_restore(&dflt);
                return;
        }
                                        /* restore saved settings */
        do_irrad = rp->do_irrad;
        if (!rand_samp != !rp->rand_samp) {
                rand_samp = rp->rand_samp;
                reset_random();
        }
        dstrsrc = rp->dstrsrc;
        shadthresh = rp->shadthresh;
        shadcert = rp->shadcert;
        directrelay = rp->directrelay;
        vspretest = rp->vspretest;
        directvis = rp->directvis;
        srcsizerat = rp->srcsizerat;
        copycolor(cextinction, rp->cextinction);
        copycolor(salbedo, rp->salbedo);
        seccg = rp->seccg;
        ssampdist = rp->ssampdist;
        specthresh = rp->specthresh;
        specjitter = rp->specjitter;
        backvis = rp->backvis;
        maxdepth = rp->maxdepth;
        minweight = rp->minweight;
        copycolor(ambval, rp->ambval);
        ambvwt = rp->ambvwt;
        ambdiv = rp->ambdiv;
        ambssamp = rp->ambssamp;
        ambounce = rp->ambounce;
                                        /* a bit dangerous if not static */
        for (i = 0; rp->amblndx[i] >= 0; i++)
                amblist[i] = rp->amblval + rp->amblndx[i];
        while (i <= AMBLLEN)
                amblist[i++] = NULL;
        ambincl = rp->ambincl;
                                        /* update ambient calculation */
        ambnotify(OVOID);
        if (thescene.cutree != EMPTY) {
                int     newamb = (ambfile == NULL) ?  rp->ambfile[0] :
                                        strcmp(ambfile, rp->ambfile) ;

                if (amblist[0] != NULL)
                        for (i = 0; i < nobjects; i++)
                                ambnotify(i);

                ambfile = (rp->ambfile[0]) ? rp->ambfile : (char *)NULL;
                if (newamb) {
                        ambres = rp->ambres;
                        ambacc = rp->ambacc;
                        setambient();
                } else {
                        setambres(rp->ambres);
                        setambacc(rp->ambacc);
                }
        } else {
                ambfile = (rp->ambfile[0]) ? rp->ambfile : (char *)NULL;
                ambres = rp->ambres;
                ambacc = rp->ambacc;
        }
        
        /* PMAP: restore photon mapping params */
        ray_restore_pmap(rp);
}


void
ray_defaults(           /* get default parameter values */
        RAYPARAMS       *rp
)
{
        int     i;

        if (rp == NULL)
                return;

        rp->do_irrad = 0;
        rp->rand_samp = 1;
        rp->dstrsrc = 0.0;
        rp->shadthresh = .03;
        rp->shadcert = .75;
        rp->directrelay = 2;
        rp->vspretest = 512;
        rp->directvis = 1;
        rp->srcsizerat = .2;
        setcolor(rp->cextinction, 0., 0., 0.);
        setcolor(rp->salbedo, 0., 0., 0.);
        rp->seccg = 0.;
        rp->ssampdist = 0.;
        rp->specthresh = .15;
        rp->specjitter = 1.;
        rp->backvis = 1;
        rp->maxdepth = -10;
        rp->minweight = 2e-3;
        memset(rp->ambfile, '\0', sizeof(rp->ambfile));
        setcolor(rp->ambval, 0., 0., 0.);
        rp->ambvwt = 0;
        rp->ambres = 256;
        rp->ambacc = 0.15;
        rp->ambdiv = 1024;
        rp->ambssamp = 512;
        rp->ambounce = 0;
        rp->ambincl = -1;
        memset(rp->amblval, '\0', sizeof(rp->amblval));
        for (i = AMBLLEN+1; i--; )
                rp->amblndx[i] = -1;
        
        /* PMAP: restore photon mapping defaults */
        ray_defaults_pmap(rp);
}
Revision:	2.25
Committed:	Fri Apr 19 16:29:10 2019 UTC (5 years ago) by greg
Content type:	text/plain
Branch:	MAIN
CVS Tags:	rad5R3
Changes since 2.24:	+22 -10 lines
Log Message:	Added reset of random sampling
#	Content
1	#ifndef lint
2	static const char RCSid[] = "$Id: raycalls.c,v 2.24 2019/04/18 23:58:22 greg Exp $";
3	#endif
4	/*
5	* raycalls.c - interface for running Radiance rendering as a library
6	*
7	* External symbols declared in ray.h
8	*/
9
10	#include "copyright.h"
11
12	/*
13	* These routines are designed to aid the programmer who wishes
14	* to call Radiance as a library. Unfortunately, the system was
15	* not originally intended to be run this way, and there are some
16	* awkward limitations to contend with. The most irritating
17	* perhaps is that the global variables and functions do not have
18	* a prefix, and the symbols are a bit generic. This results in a
19	* serious invasion of the calling application's name-space, and
20	* you may need to rename either some Radiance routines or some
21	* of your routines to avoid conflicts. Another limitation is
22	* that the global variables are not gathered together into any
23	* sort of context, so it is impossible to simultaneously run
24	* this library on multiple scenes or in multiple threads.
25	* You get one scene and one thread, and if you want more, you
26	* will have to go with the process model defined in raypcalls.c.
27	* Finally, unrecoverable errors result in a call to the application-
28	* defined function quit(). The usual thing to do is to call exit().
29	* You might want to do something else instead, like
30	* call setjmp()/longjmp() to bring you back to the calling
31	* function for recovery. You may also wish to define your own
32	* wputs(s) and eputs(s) functions to output warning and error
33	* messages, respectively.
34	*
35	* With those caveats, we have attempted to make the interface
36	* as simple as we can. Global variables and their defaults
37	* are defined below, and including "ray.h" declares these
38	* along with all the routines you are likely to need. First,
39	* assign the global variable progname to your argv[0], then
40	* change the rendering parameters as you like. If you have a set
41	* of option arguments you are working from, the getrenderopt(ac,av)
42	* call should be very useful. Before tracing any rays, you
43	* must read in the octree with a call to ray_init(oct).
44	* Passing NULL for the file name causes ray_init() to read
45	* the octree from the standard input -- rarely a good idea.
46	* However, one may read an octree from a program (such as
47	* oconv) by preceding a shell command by a '!' character.
48	*
49	* To trace a ray, define a RAY object myRay and assign:
50	*
51	* myRay.rorg = ( ray origin point )
52	* myRay.rdir = ( normalized ray direction )
53	* myRay.rmax = ( maximum length, or zero for no limit )
54	*
55	* If you are rendering from a VIEW structure, this can be
56	* accomplished with a single call for the ray at (x,y):
57	*
58	* myRay.rmax = viewray(myRay.rorg, myRay.rdir, &myView, x, y);
59	*
60	* Then, trace the primary ray with:
61	*
62	* ray_trace(&myRay);
63	*
64	* The resulting contents of myRay should provide you with
65	* more than enough information about what the ray hit,
66	* the computed value, etc. For further clues of how to
67	* compute irradiance, how to get callbacks on the evaluated
68	* ray tree, etc., see the contents of rtrace.c. See
69	* also the rpmain.c, rtmain.c, and rvmain.c modules
70	* to learn more how rendering options are processed.
71	*
72	* When you are done, you may call ray_done(1) to clean
73	* up memory used by Radiance. It doesn't free everything,
74	* but it makes a valiant effort. If you call ray_done(0),
75	* it leaves data that is likely to be reused, including
76	* loaded data files and fonts. The library may be
77	* restarted at any point by calling ray_init() on a new
78	* octree.
79	*
80	* The call ray_save(rp) fills a parameter structure
81	* with the current global parameter settings, which may be
82	* restored at any time with a call to ray_restore(rp).
83	* This buffer contains no linked information, and thus
84	* may be passed between processes using write() and
85	* read() calls, so long as byte order is maintained.
86	* Calling ray_restore(NULL) restores the original
87	* default parameters, which is also retrievable with
88	* the call ray_defaults(rp). (These should be the
89	* same as the defaults for rtrace.)
90	*/
91
92	#include <string.h>
93	#include <time.h>
94
95	#include "ray.h"
96	#include "source.h"
97	#include "bsdf.h"
98	#include "ambient.h"
99	#include "otypes.h"
100	#include "random.h"
101	#include "data.h"
102	#include "font.h"
103	#include "pmapray.h"
104
105	char progname = "unknown_app"; / caller sets to argv[0] */
106
107	char octname; / octree name we are given */
108
109	char shm_boundary = NULL; / boundary of shared memory */
110
111	CUBE thescene; /* our scene */
112	OBJECT nsceneobjs; /* number of objects in our scene */
113
114	int dimlist[MAXDIM]; /* sampling dimensions */
115	int ndims = 0; /* number of sampling dimensions */
116	int samplendx = 0; /* index for this sample */
117
118	void (trace)() = NULL; / trace call */
119
120	void (*addobjnotify[8])() = {ambnotify, NULL};
121
122	int do_irrad = 0; /* compute irradiance? */
123
124	int rand_samp = 1; /* pure Monte Carlo sampling? */
125
126	double dstrsrc = 0.0; /* square source distribution */
127	double shadthresh = .03; /* shadow threshold */
128	double shadcert = .75; /* shadow certainty */
129	int directrelay = 2; /* number of source relays */
130	int vspretest = 512; /* virtual source pretest density */
131	int directvis = 1; /* sources visible? */
132	double srcsizerat = .2; /* maximum ratio source size/dist. */
133
134	COLOR cextinction = BLKCOLOR; /* global extinction coefficient */
135	COLOR salbedo = BLKCOLOR; /* global scattering albedo */
136	double seccg = 0.; /* global scattering eccentricity */
137	double ssampdist = 0.; /* scatter sampling distance */
138
139	double specthresh = .15; /* specular sampling threshold */
140	double specjitter = 1.; /* specular sampling jitter */
141
142	int backvis = 1; /* back face visibility */
143
144	int maxdepth = -10; /* maximum recursion depth */
145	double minweight = 2e-3; /* minimum ray weight */
146
147	char ambfile = NULL; / ambient file name */
148	COLOR ambval = BLKCOLOR; /* ambient value */
149	int ambvwt = 0; /* initial weight for ambient value */
150	double ambacc = 0.1; /* ambient accuracy */
151	int ambres = 256; /* ambient resolution */
152	int ambdiv = 1024; /* ambient divisions */
153	int ambssamp = 512; /* ambient super-samples */
154	int ambounce = 0; /* ambient bounces */
155	char amblist[AMBLLEN+1]; / ambient include/exclude list */
156	int ambincl = -1; /* include == 1, exclude == 0 */
157
158
159	static void
160	reset_random(void) /* re-initialize random number generator */
161	{
162	if (rand_samp) {
163	srandom((long)time(0));
164	initurand(0);
165	} else {
166	srandom(0L);
167	initurand(2048);
168	}
169	}
170
171
172	void
173	ray_init( /* initialize ray-tracing calculation */
174	char *otnm
175	)
176	{
177	if (nobjects > 0) /* free old scene data */
178	ray_done(0);
179	/* initialize object types */
180	if (ofun[OBJ_SPHERE].funp == o_default)
181	initotypes();
182	/* initialize urand */
183	reset_random();
184	/* read scene octree */
185	readoct(octname = otnm, ~(IO_FILES\|IO_INFO), &thescene, NULL);
186	nsceneobjs = nobjects;
187	/* PMAP: Init & load photon maps */
188	ray_init_pmap();
189	/* find and mark sources */
190	marksources();
191	/* initialize ambient calculation */
192	setambient();
193	/* ready to go... (almost) */
194	}
195
196
197	void
198	ray_trace( /* trace a primary ray */
199	RAY *r
200	)
201	{
202	rayorigin(r, PRIMARY, NULL, NULL);
203	samplendx++;
204	rayvalue(r); /* assumes origin and direction are set */
205	}
206
207
208	void
209	ray_done( /* free ray-tracing data */
210	int freall
211	)
212	{
213	retainfonts = 1;
214	ambdone();
215	ambnotify(OVOID);
216	freesources();
217	freeobjects(0, nobjects);
218	donesets();
219	octdone();
220	thescene.cutree = EMPTY;
221	octname = NULL;
222	retainfonts = 0;
223	if (freall) {
224	freefont(NULL);
225	freedata(NULL);
226	SDfreeCache(NULL);
227	initurand(0);
228	}
229	if (nobjects > 0) {
230	sprintf(errmsg, "%ld objects left after call to ray_done()",
231	(long)nobjects);
232	error(WARNING, errmsg);
233	}
234
235	ray_done_pmap();
236	}
237
238
239	void
240	ray_save( /* save current parameter settings */
241	RAYPARAMS *rp
242	)
243	{
244	int i, ndx;
245
246	if (rp == NULL)
247	return;
248	rp->do_irrad = do_irrad;
249	rp->rand_samp = rand_samp;
250	rp->dstrsrc = dstrsrc;
251	rp->shadthresh = shadthresh;
252	rp->shadcert = shadcert;
253	rp->directrelay = directrelay;
254	rp->vspretest = vspretest;
255	rp->directvis = directvis;
256	rp->srcsizerat = srcsizerat;
257	copycolor(rp->cextinction, cextinction);
258	copycolor(rp->salbedo, salbedo);
259	rp->seccg = seccg;
260	rp->ssampdist = ssampdist;
261	rp->specthresh = specthresh;
262	rp->specjitter = specjitter;
263	rp->backvis = backvis;
264	rp->maxdepth = maxdepth;
265	rp->minweight = minweight;
266	if (ambfile != NULL)
267	strncpy(rp->ambfile, ambfile, sizeof(rp->ambfile)-1);
268	else
269	memset(rp->ambfile, '\0', sizeof(rp->ambfile));
270	copycolor(rp->ambval, ambval);
271	rp->ambvwt = ambvwt;
272	rp->ambacc = ambacc;
273	rp->ambres = ambres;
274	rp->ambdiv = ambdiv;
275	rp->ambssamp = ambssamp;
276	rp->ambounce = ambounce;
277	rp->ambincl = ambincl;
278	memset(rp->amblval, '\0', sizeof(rp->amblval));
279	ndx = 0;
280	for (i = 0; i < AMBLLEN && amblist[i] != NULL; i++) {
281	int len = strlen(amblist[i]);
282	if (ndx+len >= sizeof(rp->amblval))
283	break;
284	strcpy(rp->amblval+ndx, amblist[i]);
285	rp->amblndx[i] = ndx;
286	ndx += len+1;
287	}
288	while (i <= AMBLLEN)
289	rp->amblndx[i++] = -1;
290
291	/* PMAP: save photon mapping params */
292	ray_save_pmap(rp);
293	}
294
295
296	void
297	ray_restore( /* restore parameter settings */
298	RAYPARAMS *rp
299	)
300	{
301	int i;
302
303	if (rp == NULL) { /* restore defaults */
304	RAYPARAMS dflt;
305	ray_defaults(&dflt);
306	ray_restore(&dflt);
307	return;
308	}
309	/* restore saved settings */
310	do_irrad = rp->do_irrad;
311	if (!rand_samp != !rp->rand_samp) {
312	rand_samp = rp->rand_samp;
313	reset_random();
314	}
315	dstrsrc = rp->dstrsrc;
316	shadthresh = rp->shadthresh;
317	shadcert = rp->shadcert;
318	directrelay = rp->directrelay;
319	vspretest = rp->vspretest;
320	directvis = rp->directvis;
321	srcsizerat = rp->srcsizerat;
322	copycolor(cextinction, rp->cextinction);
323	copycolor(salbedo, rp->salbedo);
324	seccg = rp->seccg;
325	ssampdist = rp->ssampdist;
326	specthresh = rp->specthresh;
327	specjitter = rp->specjitter;
328	backvis = rp->backvis;
329	maxdepth = rp->maxdepth;
330	minweight = rp->minweight;
331	copycolor(ambval, rp->ambval);
332	ambvwt = rp->ambvwt;
333	ambdiv = rp->ambdiv;
334	ambssamp = rp->ambssamp;
335	ambounce = rp->ambounce;
336	/* a bit dangerous if not static */
337	for (i = 0; rp->amblndx[i] >= 0; i++)
338	amblist[i] = rp->amblval + rp->amblndx[i];
339	while (i <= AMBLLEN)
340	amblist[i++] = NULL;
341	ambincl = rp->ambincl;
342	/* update ambient calculation */
343	ambnotify(OVOID);
344	if (thescene.cutree != EMPTY) {
345	int newamb = (ambfile == NULL) ? rp->ambfile[0] :
346	strcmp(ambfile, rp->ambfile) ;
347
348	if (amblist[0] != NULL)
349	for (i = 0; i < nobjects; i++)
350	ambnotify(i);
351
352	ambfile = (rp->ambfile[0]) ? rp->ambfile : (char *)NULL;
353	if (newamb) {
354	ambres = rp->ambres;
355	ambacc = rp->ambacc;
356	setambient();
357	} else {
358	setambres(rp->ambres);
359	setambacc(rp->ambacc);
360	}
361	} else {
362	ambfile = (rp->ambfile[0]) ? rp->ambfile : (char *)NULL;
363	ambres = rp->ambres;
364	ambacc = rp->ambacc;
365	}
366
367	/* PMAP: restore photon mapping params */
368	ray_restore_pmap(rp);
369	}
370
371
372	void
373	ray_defaults( /* get default parameter values */
374	RAYPARAMS *rp
375	)
376	{
377	int i;
378
379	if (rp == NULL)
380	return;
381
382	rp->do_irrad = 0;
383	rp->rand_samp = 1;
384	rp->dstrsrc = 0.0;
385	rp->shadthresh = .03;
386	rp->shadcert = .75;
387	rp->directrelay = 2;
388	rp->vspretest = 512;
389	rp->directvis = 1;
390	rp->srcsizerat = .2;
391	setcolor(rp->cextinction, 0., 0., 0.);
392	setcolor(rp->salbedo, 0., 0., 0.);
393	rp->seccg = 0.;
394	rp->ssampdist = 0.;
395	rp->specthresh = .15;
396	rp->specjitter = 1.;
397	rp->backvis = 1;
398	rp->maxdepth = -10;
399	rp->minweight = 2e-3;
400	memset(rp->ambfile, '\0', sizeof(rp->ambfile));
401	setcolor(rp->ambval, 0., 0., 0.);
402	rp->ambvwt = 0;
403	rp->ambres = 256;
404	rp->ambacc = 0.15;
405	rp->ambdiv = 1024;
406	rp->ambssamp = 512;
407	rp->ambounce = 0;
408	rp->ambincl = -1;
409	memset(rp->amblval, '\0', sizeof(rp->amblval));
410	for (i = AMBLLEN+1; i--; )
411	rp->amblndx[i] = -1;
412
413	/* PMAP: restore photon mapping defaults */
414	ray_defaults_pmap(rp);
415	}