src/rt/pmapdump.c

#ifndef lint
static const char RCSid[] = "$Id: pmapdump.c,v 2.7 2016/05/17 17:39:47 rschregle Exp $";
#endif

/* 
   ======================================================================
   Dump photon maps as RADIANCE scene description to stdout

   Roland Schregle (roland.schregle@{hslu.ch, gmail.com})
   (c) Fraunhofer Institute for Solar Energy Systems,
   (c) Lucerne University of Applied Sciences and Arts,
       supported by the Swiss National Science Foundation (SNSF, #147053)
   ======================================================================
   
   $Id: pmapdump.c,v 2.7 2016/05/17 17:39:47 rschregle Exp $
*/


#include "pmapio.h"
#include "pmapparm.h"
#include "pmaptype.h"
#include "rtio.h"
#include "resolu.h"
#include "random.h"
#include "math.h"

#define PMAPDUMP_REC "$Revision: 2.7 $"   


/* Defaults */
/*    Sphere radius as fraction of avg. intersphere dist */
/*    Relative scale for sphere radius (fudge factor) */
/*    Number of spheres */
#define RADCOEFF 0.05
#define RADSCALE 1.0
#define NSPHERES 10000


/* RADIANCE material and object defs for each photon type */
typedef struct {
   char *mat, *obj;
} RadianceDef;

   
/* Colour code is as follows:    global         = blue
                                 precomp global = cyan
                                 caustic        = red
                                 volume         = green
                                 direct         = magenta 
                                 contrib        = yellow */   
const RadianceDef radDefs [] = {
   {  "void plastic mat.global\n0\n0\n5 0 0 1 0 0\n",
      "mat.global sphere obj.global\n0\n0\n4 %g %g %g %g\n"
   },
   {  "void plastic mat.pglobal\n0\n0\n5 0 1 1 0 0\n",
      "mat.pglobal sphere obj.global\n0\n0\n4 %g %g %g %g\n"
   },
   {  "void plastic mat.caustic\n0\n0\n5 1 0 0 0 0\n",
      "mat.caustic sphere obj.caustic\n0\n0\n4 %g %g %g %g\n"
   },
   {  "void plastic mat.volume\n0\n0\n5 0 1 0 0 0\n",
      "mat.volume sphere obj.volume\n0\n0\n4 %g %g %g %g\n"
   },
   {  "void plastic mat.direct\n0\n0\n5 1 0 1 0 0\n",
      "mat.direct sphere obj.direct\n0\n0\n4 %g %g %g %g\n"
   },
   {  "void plastic mat.contrib\n0\n0\n5 1 1 0 0 0\n",
      "mat.contrib sphere obj.contrib\n0\n0\n4 %g %g %g %g\n"
   }
};


int main (int argc, char** argv)
{
   char           format [128];
   RREAL          rad, radScale = RADSCALE, vol, dumpRatio;
   unsigned       arg, j, ptype;
   long           numSpheres = NSPHERES;
   FILE           *pmapFile;
   PhotonMap      pm;
   PhotonPrimary  pri;
   Photon         p;
#ifdef PMAP_OOC
   char           leafFname [1024];
#endif
   
   if (argc < 2) {
      puts("Dump photon maps as RADIANCE scene description\n");
      printf("Usage: %s [-r radscale1] [-n nspheres1] pmap1 "
             "[-r radscale2] [-n nspheres2] pmap2 ...\n", argv [0]);
      return 1;
   }
   
   for (arg = 1; arg < argc; arg++) {
      /* Parse options */
      if (argv [arg][0] == '-') {
         switch (argv [arg][1]) {
            case 'r':
               if ((radScale = atof(argv [++arg])) <= 0)
                  error(USER, "invalid radius scale");
               break;
               
            case 'n':
               if ((numSpheres = parseMultiplier(argv [++arg])) <= 0)
                  error(USER, "invalid number of spheres");
               break;
               
            default:
               sprintf(errmsg, "unknown option %s", argv [arg]);
               error(USER, errmsg);
               return -1;
         }
         
         continue;
      }
      
      /* Dump photon map */
      if (!(pmapFile = fopen(argv [arg], "rb"))) {
         sprintf(errmsg, "can't open %s", argv [arg]);
         error(SYSTEM, errmsg);
      }
         
      /* Get format string */
      strcpy(format, PMAP_FORMAT_GLOB);
      if (checkheader(pmapFile, format, NULL) != 1) {
         sprintf(errmsg, "photon map file %s has unknown format %s", 
                 argv [arg], format);
         error(USER, errmsg);
      }
      
      /* Identify photon map type from format string */
      for (ptype = 0; 
           ptype < NUM_PMAP_TYPES && strcmp(pmapFormat [ptype], format);
           ptype++);
      
      if (!validPmapType(ptype)) {
         sprintf(errmsg, "file %s contains an unknown photon map type", 
                argv [arg]);
         error(USER, errmsg);
      }

      /* Get file format version and check for compatibility */
      if (strcmp(getstr(format, pmapFile), PMAP_FILEVER))      
         error(USER, "incompatible photon map file format");
         
      /* Dump command line as comment */
      fputs("# ", stdout);
      printargs(argc, argv, stdout);
      fputc('\n', stdout);
      
      /* Dump material def */   
      fputs(radDefs [ptype].mat, stdout);
      fputc('\n', stdout);
      
      /* Get number of photons */
      pm.numPhotons = getint(sizeof(pm.numPhotons), pmapFile);
      
      /* Skip avg photon flux */ 
      for (j = 0; j < 3; j++) 
         getflt(pmapFile);
      
      /* Get distribution extent (min & max photon positions) */
      for (j = 0; j < 3; j++) {
         pm.minPos [j] = getflt(pmapFile);
         pm.maxPos [j] = getflt(pmapFile);
      }
      
      /* Skip centre of gravity, and avg photon dist to it */
      for (j = 0; j < 4; j++)
         getflt(pmapFile);
      
      /* Sphere radius based on avg intersphere dist 
         (= sphere distrib density ^-1/3) */
      vol = (pm.maxPos [0] - pm.minPos [0]) * (pm.maxPos [1] - pm.minPos [1]) * 
            (pm.maxPos [2] - pm.minPos [2]);
      rad = radScale * RADCOEFF * pow(vol / numSpheres, 1./3.);
      
      /* Photon dump probability to satisfy target sphere count */
      dumpRatio = numSpheres < pm.numPhotons 
                  ? (float)numSpheres / pm.numPhotons : 1;
      
      /* Skip primary rays */
      pm.numPrimary = getint(sizeof(pm.numPrimary), pmapFile);
      while (pm.numPrimary-- > 0) {
         /* Skip source index & incident dir */
         getint(sizeof(pri.srcIdx) + sizeof(pri.dir), pmapFile);
#ifdef PMAP_PRIMARYPOS         
         /* Skip primary hitpoint */
         for (j = 0; j < 3; j++)
            getflt(pmapFile);
#endif
      }

#ifdef PMAP_OOC
      /* Open leaf file with filename derived from pmap, replace pmapFile
       * (which is currently the node file) */
      strncpy(leafFname, argv [arg], 1024);
      strncat(leafFname, PMAP_OOC_LEAFSUFFIX, 1024);
      fclose(pmapFile);
      if (!(pmapFile = fopen(leafFname, "rb"))) {
         sprintf(errmsg, "cannot open leaf file %s", leafFname);
         error(SYSTEM, errmsg);
      }
#endif
            
      /* Load photons */      
      while (pm.numPhotons-- > 0) {
#ifdef PMAP_OOC
         /* Get entire photon record 
            !!! OOC PMAP FILES CURRENTLY DON'T USE PORTABLE I/O !!! */
         if (!fread(&p, sizeof(p), 1, pmapFile)) {
            sprintf(errmsg, "error reading OOC leaf file %s", leafFname);
            error(SYSTEM, errmsg);
         }
#else         
         /* Get photon position */            
         for (j = 0; j < 3; j++) 
            p.pos [j] = getflt(pmapFile);
#endif
         /* Dump photon probabilistically acc. to target sphere count */
         if (frandom() <= dumpRatio) {
            printf(radDefs [ptype].obj, p.pos [0], p.pos [1], p.pos [2], rad);
            fputc('\n', stdout);
         }
         
#ifndef PMAP_OOC
         /* Skip photon normal and flux */
         for (j = 0; j < 3; j++) 
            getint(sizeof(p.norm [j]), pmapFile);
            
#ifdef PMAP_FLOAT_FLUX
         for (j = 0; j < 3; j++) 
            getflt(pmapFile);
#else      
         for (j = 0; j < 4; j++) 
            getint(1, pmapFile);
#endif

         /* Skip primary ray index */
         getint(sizeof(p.primary), pmapFile);

         /* Skip flags */
         getint(sizeof(p.flags), pmapFile);
#endif
         
         if (ferror(pmapFile) || feof(pmapFile)) {
            sprintf(errmsg, "error reading %s", argv [arg]);
            error(USER, errmsg);
         }
      }
      
      fclose(pmapFile);
      
      /* Reset defaults for next dump */
      radScale = RADSCALE;
      numSpheres = NSPHERES;
   }
   
   return 0;
}
Revision:	2.8
Committed:	Mon Aug 14 21:12:10 2017 UTC (6 years, 8 months ago) by rschregle
Content type:	text/plain
Branch:	MAIN
CVS Tags:	rad5R1
Changes since 2.7:	+7 -3 lines
Log Message:	Updated photon map code for Windows; no multproc or ooC for now
#	Content
1	#ifndef lint
2	static const char RCSid[] = "$Id: pmapdump.c,v 2.7 2016/05/17 17:39:47 rschregle Exp $";
3	#endif
4
5	/*
6	======================================================================
7	Dump photon maps as RADIANCE scene description to stdout
8
9	Roland Schregle (roland.schregle@{hslu.ch, gmail.com})
10	(c) Fraunhofer Institute for Solar Energy Systems,
11	(c) Lucerne University of Applied Sciences and Arts,
12	supported by the Swiss National Science Foundation (SNSF, #147053)
13	======================================================================
14
15	$Id: pmapdump.c,v 2.7 2016/05/17 17:39:47 rschregle Exp $
16	*/
17
18
19
20	#include "pmapio.h"
21	#include "pmapparm.h"
22	#include "pmaptype.h"
23	#include "rtio.h"
24	#include "resolu.h"
25	#include "random.h"
26	#include "math.h"
27
28	#define PMAPDUMP_REC "$Revision: 2.7 $"
29
30
31	/* Defaults */
32	/* Sphere radius as fraction of avg. intersphere dist */
33	/* Relative scale for sphere radius (fudge factor) */
34	/* Number of spheres */
35	#define RADCOEFF 0.05
36	#define RADSCALE 1.0
37	#define NSPHERES 10000
38
39
40	/* RADIANCE material and object defs for each photon type */
41	typedef struct {
42	char mat, obj;
43	} RadianceDef;
44
45
46
47	/* Colour code is as follows: global = blue
48	precomp global = cyan
49	caustic = red
50	volume = green
51	direct = magenta
52	contrib = yellow */
53	const RadianceDef radDefs [] = {
54	{ "void plastic mat.global\n0\n0\n5 0 0 1 0 0\n",
55	"mat.global sphere obj.global\n0\n0\n4 %g %g %g %g\n"
56	},
57	{ "void plastic mat.pglobal\n0\n0\n5 0 1 1 0 0\n",
58	"mat.pglobal sphere obj.global\n0\n0\n4 %g %g %g %g\n"
59	},
60	{ "void plastic mat.caustic\n0\n0\n5 1 0 0 0 0\n",
61	"mat.caustic sphere obj.caustic\n0\n0\n4 %g %g %g %g\n"
62	},
63	{ "void plastic mat.volume\n0\n0\n5 0 1 0 0 0\n",
64	"mat.volume sphere obj.volume\n0\n0\n4 %g %g %g %g\n"
65	},
66	{ "void plastic mat.direct\n0\n0\n5 1 0 1 0 0\n",
67	"mat.direct sphere obj.direct\n0\n0\n4 %g %g %g %g\n"
68	},
69	{ "void plastic mat.contrib\n0\n0\n5 1 1 0 0 0\n",
70	"mat.contrib sphere obj.contrib\n0\n0\n4 %g %g %g %g\n"
71	}
72	};
73
74
75
76	int main (int argc, char** argv)
77	{
78	char format [128];
79	RREAL rad, radScale = RADSCALE, vol, dumpRatio;
80	unsigned arg, j, ptype;
81	long numSpheres = NSPHERES;
82	FILE *pmapFile;
83	PhotonMap pm;
84	PhotonPrimary pri;
85	Photon p;
86	#ifdef PMAP_OOC
87	char leafFname [1024];
88	#endif
89
90	if (argc < 2) {
91	puts("Dump photon maps as RADIANCE scene description\n");
92	printf("Usage: %s [-r radscale1] [-n nspheres1] pmap1 "
93	"[-r radscale2] [-n nspheres2] pmap2 ...\n", argv [0]);
94	return 1;
95	}
96
97	for (arg = 1; arg < argc; arg++) {
98	/* Parse options */
99	if (argv [arg][0] == '-') {
100	switch (argv [arg][1]) {
101	case 'r':
102	if ((radScale = atof(argv [++arg])) <= 0)
103	error(USER, "invalid radius scale");
104	break;
105
106	case 'n':
107	if ((numSpheres = parseMultiplier(argv [++arg])) <= 0)
108	error(USER, "invalid number of spheres");
109	break;
110
111	default:
112	sprintf(errmsg, "unknown option %s", argv [arg]);
113	error(USER, errmsg);
114	return -1;
115	}
116
117	continue;
118	}
119
120	/* Dump photon map */
121	if (!(pmapFile = fopen(argv [arg], "rb"))) {
122	sprintf(errmsg, "can't open %s", argv [arg]);
123	error(SYSTEM, errmsg);
124	}
125
126	/* Get format string */
127	strcpy(format, PMAP_FORMAT_GLOB);
128	if (checkheader(pmapFile, format, NULL) != 1) {
129	sprintf(errmsg, "photon map file %s has unknown format %s",
130	argv [arg], format);
131	error(USER, errmsg);
132	}
133
134	/* Identify photon map type from format string */
135	for (ptype = 0;
136	ptype < NUM_PMAP_TYPES && strcmp(pmapFormat [ptype], format);
137	ptype++);
138
139	if (!validPmapType(ptype)) {
140	sprintf(errmsg, "file %s contains an unknown photon map type",
141	argv [arg]);
142	error(USER, errmsg);
143	}
144
145	/* Get file format version and check for compatibility */
146	if (strcmp(getstr(format, pmapFile), PMAP_FILEVER))
147	error(USER, "incompatible photon map file format");
148
149	/* Dump command line as comment */
150	fputs("# ", stdout);
151	printargs(argc, argv, stdout);
152	fputc('\n', stdout);
153
154	/* Dump material def */
155	fputs(radDefs [ptype].mat, stdout);
156	fputc('\n', stdout);
157
158	/* Get number of photons */
159	pm.numPhotons = getint(sizeof(pm.numPhotons), pmapFile);
160
161	/* Skip avg photon flux */
162	for (j = 0; j < 3; j++)
163	getflt(pmapFile);
164
165	/* Get distribution extent (min & max photon positions) */
166	for (j = 0; j < 3; j++) {
167	pm.minPos [j] = getflt(pmapFile);
168	pm.maxPos [j] = getflt(pmapFile);
169	}
170
171	/* Skip centre of gravity, and avg photon dist to it */
172	for (j = 0; j < 4; j++)
173	getflt(pmapFile);
174
175	/* Sphere radius based on avg intersphere dist
176	(= sphere distrib density ^-1/3) */
177	vol = (pm.maxPos [0] - pm.minPos [0]) * (pm.maxPos [1] - pm.minPos [1]) *
178	(pm.maxPos [2] - pm.minPos [2]);
179	rad = radScale * RADCOEFF * pow(vol / numSpheres, 1./3.);
180
181	/* Photon dump probability to satisfy target sphere count */
182	dumpRatio = numSpheres < pm.numPhotons
183	? (float)numSpheres / pm.numPhotons : 1;
184
185	/* Skip primary rays */
186	pm.numPrimary = getint(sizeof(pm.numPrimary), pmapFile);
187	while (pm.numPrimary-- > 0) {
188	/* Skip source index & incident dir */
189	getint(sizeof(pri.srcIdx) + sizeof(pri.dir), pmapFile);
190	#ifdef PMAP_PRIMARYPOS
191	/* Skip primary hitpoint */
192	for (j = 0; j < 3; j++)
193	getflt(pmapFile);
194	#endif
195	}
196
197	#ifdef PMAP_OOC
198	/* Open leaf file with filename derived from pmap, replace pmapFile
199	* (which is currently the node file) */
200	strncpy(leafFname, argv [arg], 1024);
201	strncat(leafFname, PMAP_OOC_LEAFSUFFIX, 1024);
202	fclose(pmapFile);
203	if (!(pmapFile = fopen(leafFname, "rb"))) {
204	sprintf(errmsg, "cannot open leaf file %s", leafFname);
205	error(SYSTEM, errmsg);
206	}
207	#endif
208
209	/* Load photons */
210	while (pm.numPhotons-- > 0) {
211	#ifdef PMAP_OOC
212	/* Get entire photon record
213	!!! OOC PMAP FILES CURRENTLY DON'T USE PORTABLE I/O !!! */
214	if (!fread(&p, sizeof(p), 1, pmapFile)) {
215	sprintf(errmsg, "error reading OOC leaf file %s", leafFname);
216	error(SYSTEM, errmsg);
217	}
218	#else
219	/* Get photon position */
220	for (j = 0; j < 3; j++)
221	p.pos [j] = getflt(pmapFile);
222	#endif
223	/* Dump photon probabilistically acc. to target sphere count */
224	if (frandom() <= dumpRatio) {
225	printf(radDefs [ptype].obj, p.pos [0], p.pos [1], p.pos [2], rad);
226	fputc('\n', stdout);
227	}
228
229	#ifndef PMAP_OOC
230	/* Skip photon normal and flux */
231	for (j = 0; j < 3; j++)
232	getint(sizeof(p.norm [j]), pmapFile);
233
234	#ifdef PMAP_FLOAT_FLUX
235	for (j = 0; j < 3; j++)
236	getflt(pmapFile);
237	#else
238	for (j = 0; j < 4; j++)
239	getint(1, pmapFile);
240	#endif
241
242	/* Skip primary ray index */
243	getint(sizeof(p.primary), pmapFile);
244
245	/* Skip flags */
246	getint(sizeof(p.flags), pmapFile);
247	#endif
248
249	if (ferror(pmapFile) \|\| feof(pmapFile)) {
250	sprintf(errmsg, "error reading %s", argv [arg]);
251	error(USER, errmsg);
252	}
253	}
254
255	fclose(pmapFile);
256
257	/* Reset defaults for next dump */
258	radScale = RADSCALE;
259	numSpheres = NSPHERES;
260	}
261
262	return 0;
263	}