src/rt/pmapdump.c

#ifndef lint
static const char RCSid[] = "$Id: pmapdump.c,v 2.4 2015/08/18 18:45:55 greg 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)
   ==================================================================
   
*/


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


/* 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;

   
static char header [] = "$Revision: 2.4 $";


/* 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;
   FVECT minPos, maxPos;
   unsigned arg, j, ptype;
   long numPhotons, numSpheres = NSPHERES;
   FILE *pmapFile;
   Photon p;
   
   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; 
           strcmp(pmapFormat [ptype], format) && ptype < NUM_PMAP_TYPES; 
           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 (getint(sizeof(PMAP_FILEVER), 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 (is this sizeof() hack portable?) */
      numPhotons = getint(sizeof(((PhotonMap*)NULL) -> heapSize), 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++) {
         minPos [j] = getflt(pmapFile);
         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 = (maxPos [0] - minPos [0]) * (maxPos [1] - minPos [1]) * 
            (maxPos [2] - minPos [2]);
      rad = radScale * RADCOEFF * pow(vol / numSpheres, 1./3.);
      
      /* Photon dump probability to satisfy target sphere count */
      dumpRatio = numSpheres < numPhotons ? (float)numSpheres / numPhotons
                                          : 1;
      
      while (numPhotons-- > 0) {
         /* Get photon position */            
         for (j = 0; j < 3; j++) 
            p.pos [j] = getflt(pmapFile);

         /* 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);
         }
         
         /* 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);
         
         if (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:	2.5
Committed:	Tue Sep 1 16:27:52 2015 UTC (10 years, 1 month ago) by greg
Content type:	text/plain
Branch:	MAIN
CVS Tags:	rad5R0
Changes since 2.4:	+2 -3 lines
Log Message:	Removed redundant $Id: in file
#	User	Rev	Content
1	greg	2.4	#ifndef lint
2	greg	2.5	static const char RCSid[] = "$Id: pmapdump.c,v 2.4 2015/08/18 18:45:55 greg Exp $";
3	greg	2.4	#endif
4	greg	2.1	/*
5	rschregle	2.3	==================================================================
6	greg	2.1	Dump photon maps as RADIANCE scene description to stdout
7
8			Roland Schregle (roland.schregle@{hslu.ch, gmail.com})
9			(c) Fraunhofer Institute for Solar Energy Systems,
10	rschregle	2.3	(c) Lucerne University of Applied Sciences and Arts,
11			supported by the Swiss National Science Foundation (SNSF, #147053)
12	greg	2.1	==================================================================
13
14			*/
15
16
17
18			#include "pmapio.h"
19			#include "pmapparm.h"
20			#include "pmaptype.h"
21			#include "rtio.h"
22			#include "resolu.h"
23			#include "random.h"
24	greg	2.2	#include "math.h"
25	greg	2.1
26
27			/* Defaults */
28			/* Sphere radius as fraction of avg. intersphere dist */
29			/* Relative scale for sphere radius (fudge factor) */
30			/* Number of spheres */
31			#define RADCOEFF 0.05
32			#define RADSCALE 1.0
33			#define NSPHERES 10000
34
35
36			/* RADIANCE material and object defs for each photon type */
37			typedef struct {
38			char mat, obj;
39			} RadianceDef;
40
41
42	greg	2.5	static char header [] = "$Revision: 2.4 $";
43	greg	2.1
44
45			/* Colour code is as follows: global = blue
46			precomp global = cyan
47			caustic = red
48			volume = green
49			direct = magenta
50			contrib = yellow */
51			const RadianceDef radDefs [] = {
52			{ "void plastic mat.global\n0\n0\n5 0 0 1 0 0\n",
53			"mat.global sphere obj.global\n0\n0\n4 %g %g %g %g\n"
54			},
55			{ "void plastic mat.pglobal\n0\n0\n5 0 1 1 0 0\n",
56			"mat.pglobal sphere obj.global\n0\n0\n4 %g %g %g %g\n"
57			},
58			{ "void plastic mat.caustic\n0\n0\n5 1 0 0 0 0\n",
59			"mat.caustic sphere obj.caustic\n0\n0\n4 %g %g %g %g\n"
60			},
61			{ "void plastic mat.volume\n0\n0\n5 0 1 0 0 0\n",
62			"mat.volume sphere obj.volume\n0\n0\n4 %g %g %g %g\n"
63			},
64			{ "void plastic mat.direct\n0\n0\n5 1 0 1 0 0\n",
65			"mat.direct sphere obj.direct\n0\n0\n4 %g %g %g %g\n"
66			},
67			{ "void plastic mat.contrib\n0\n0\n5 1 1 0 0 0\n",
68			"mat.contrib sphere obj.contrib\n0\n0\n4 %g %g %g %g\n"
69			}
70			};
71
72
73
74			int main (int argc, char** argv)
75			{
76			char format [128];
77			RREAL rad, radScale = RADSCALE, vol, dumpRatio;
78			FVECT minPos, maxPos;
79			unsigned arg, j, ptype;
80			long numPhotons, numSpheres = NSPHERES;
81			FILE *pmapFile;
82			Photon p;
83
84			if (argc < 2) {
85			puts("Dump photon maps as RADIANCE scene description\n");
86			printf("Usage: %s [-r radscale1] [-n nspheres1] pmap1 "
87			"[-r radscale2] [-n nspheres2] pmap2 ...\n", argv [0]);
88			return 1;
89			}
90
91			for (arg = 1; arg < argc; arg++) {
92			/* Parse options */
93			if (argv [arg][0] == '-') {
94			switch (argv [arg][1]) {
95			case 'r':
96			if ((radScale = atof(argv [++arg])) <= 0)
97			error(USER, "invalid radius scale");
98			break;
99
100			case 'n':
101			if ((numSpheres = parseMultiplier(argv [++arg])) <= 0)
102			error(USER, "invalid number of spheres");
103			break;
104
105			default:
106			sprintf(errmsg, "unknown option %s", argv [arg]);
107			error(USER, errmsg);
108			return -1;
109			}
110
111			continue;
112			}
113
114			/* Dump photon map */
115			if (!(pmapFile = fopen(argv [arg], "rb"))) {
116			sprintf(errmsg, "can't open %s", argv [arg]);
117			error(SYSTEM, errmsg);
118			}
119
120			/* Get format string */
121			strcpy(format, PMAP_FORMAT_GLOB);
122			if (checkheader(pmapFile, format, NULL) != 1) {
123			sprintf(errmsg, "photon map file %s has unknown format %s",
124			argv [arg], format);
125			error(USER, errmsg);
126			}
127
128			/* Identify photon map type from format string */
129			for (ptype = 0;
130			strcmp(pmapFormat [ptype], format) && ptype < NUM_PMAP_TYPES;
131			ptype++);
132
133			if (!validPmapType(ptype)) {
134			sprintf(errmsg, "file %s contains an unknown photon map type",
135			argv [arg]);
136			error(USER, errmsg);
137			}
138
139			/* Get file format version and check for compatibility */
140			if (getint(sizeof(PMAP_FILEVER), pmapFile) != PMAP_FILEVER)
141			error(USER, "incompatible photon map file format");
142
143			/* Dump command line as comment */
144			fputs("# ", stdout);
145			printargs(argc, argv, stdout);
146			fputc('\n', stdout);
147
148			/* Dump material def */
149			fputs(radDefs [ptype].mat, stdout);
150			fputc('\n', stdout);
151
152			/* Get number of photons (is this sizeof() hack portable?) */
153			numPhotons = getint(sizeof(((PhotonMap*)NULL) -> heapSize), pmapFile);
154
155			/* Skip avg photon flux */
156			for (j = 0; j < 3; j++)
157			getflt(pmapFile);
158
159			/* Get distribution extent (min & max photon positions) */
160			for (j = 0; j < 3; j++) {
161			minPos [j] = getflt(pmapFile);
162			maxPos [j] = getflt(pmapFile);
163			}
164
165			/* Skip centre of gravity, and avg photon dist to it */
166			for (j = 0; j < 4; j++)
167			getflt(pmapFile);
168
169			/* Sphere radius based on avg intersphere dist
170			(= sphere distrib density ^-1/3) */
171			vol = (maxPos [0] - minPos [0]) * (maxPos [1] - minPos [1]) *
172			(maxPos [2] - minPos [2]);
173	greg	2.2	rad = radScale * RADCOEFF * pow(vol / numSpheres, 1./3.);
174	greg	2.1
175			/* Photon dump probability to satisfy target sphere count */
176			dumpRatio = numSpheres < numPhotons ? (float)numSpheres / numPhotons
177			: 1;
178
179			while (numPhotons-- > 0) {
180			/* Get photon position */
181			for (j = 0; j < 3; j++)
182			p.pos [j] = getflt(pmapFile);
183
184			/* Dump photon probabilistically acc. to target sphere count */
185			if (frandom() <= dumpRatio) {
186			printf(radDefs [ptype].obj, p.pos [0], p.pos [1], p.pos [2], rad);
187			fputc('\n', stdout);
188			}
189
190			/* Skip photon normal and flux */
191			for (j = 0; j < 3; j++)
192			getint(sizeof(p.norm [j]), pmapFile);
193
194			#ifdef PMAP_FLOAT_FLUX
195			for (j = 0; j < 3; j++)
196			getflt(pmapFile);
197			#else
198			for (j = 0; j < 4; j++)
199			getint(1, pmapFile);
200			#endif
201
202			/* Skip primary ray index */
203			getint(sizeof(p.primary), pmapFile);
204
205			/* Skip flags */
206			getint(sizeof(p.flags), pmapFile);
207
208			if (feof(pmapFile)) {
209			sprintf(errmsg, "error reading %s", argv [arg]);
210			error(USER, errmsg);
211			}
212			}
213
214			fclose(pmapFile);
215
216			/* Reset defaults for next dump */
217			radScale = RADSCALE;
218			numSpheres = NSPHERES;
219			}
220
221			return 0;
222			}