[ViewVC] Diff of: radiance/ray/src/rt/pmapdump.c

Comparing ray/src/rt/pmapdump.c (file contents):
Revision 2.6 by rschregle, Thu Feb 4 19:39:10 2016 UTC vs.
Revision 2.16 by rschregle, Tue Jul 21 16:10:42 2020 UTC

#	Line 1 \| Line 1
1		#ifndef lint
2		static const char RCSid[] = "$Id$";
3		#endif
4	+
5		/*
6	<	==================================================================
7	<	Dump photon maps as RADIANCE scene description to stdout
6	>	======================================================================
7	>	Dump photon maps as RADIANCE scene description or ASCII point list
8	>	to stdout
9
10		Roland Schregle (roland.schregle@{hslu.ch, gmail.com})
11		(c) Fraunhofer Institute for Solar Energy Systems,
12	+	supported by the German Research Foundation (DFG)
13	+	as part of the FARESYS project
14		(c) Lucerne University of Applied Sciences and Arts,
15	<	supported by the Swiss National Science Foundation (SNSF, #147053)
16	<	==================================================================
15	>	supported by the Swiss National Science Foundation (SNSF, #147053)
16	>	(c) Tokyo University of Science,
17	>	supported by the Japan Society for the Promotion of Science (JSPS)
18	>	under the Grants-in-Aid for Scientific Research Program (KAKENHI),
19	>	grant number JP19KK0115.
20	>	======================================================================
21
22	+	$Id$
23		*/
24
25
26
27	+	#include "pmap.h"
28		#include "pmapio.h"
19	–	#include "pmapparm.h"
20	–	#include "pmaptype.h"
29		#include "rtio.h"
30		#include "resolu.h"
31		#include "random.h"
#	Line 32 \| Line 40 \| static const char RCSid[] = "$Id$";
40		#define RADSCALE 1.0
41		#define NSPHERES 10000
42
43	+	/* Format for optional ASCII output as XYZ RGB points */
44	+	#define POINTFMT "%g\t%g\t%g\t%g\t%g\t%g\n"
45
46		/* RADIANCE material and object defs for each photon type */
47		typedef struct {
48		char mat, obj;
49		} RadianceDef;
50
41	–
42	–	static char header [] = "$Revision$";
43	–
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",
52	>	{ "void glow mat.global\n0\n0\n4 %g %g %g 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"
55	>	{ "void glow mat.pglobal\n0\n0\n4 %g %g %g 0\n",
56	>	"mat.pglobal sphere obj.pglobal\n0\n0\n4 %g %g %g %g\n"
57		},
58	<	{ "void plastic mat.caustic\n0\n0\n5 1 0 0 0 0\n",
58	>	{ "void glow mat.caustic\n0\n0\n4 %g %g %g 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",
61	>	{ "void glow mat.volume\n0\n0\n4 %g %g %g 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",
64	>	{ "void glow mat.direct\n0\n0\n4 %g %g %g 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",
67	>	{ "void glow mat.contrib\n0\n0\n4 %g %g %g 0\n",
68		"mat.contrib sphere obj.contrib\n0\n0\n4 %g %g %g %g\n"
69		}
70		};
71
72
73	+	/* Default colour codes are as follows: global = blue
74	+	precomp global = cyan
75	+	caustic = red
76	+	volume = green
77	+	direct = magenta
78	+	contrib = yellow */
79	+	const COLOR colDefs [] = {
80	+	{0.25, 0.25, 2}, {0.1, 1, 1}, {1, 0.1, 0.1},
81	+	{0.1, 1, 0.1}, {1, 0.1, 1}, {1, 1, 0.1}
82	+	};
83
84	<	int main (int argc, char** argv)
84	>
85	>	static int setBool(char str, unsigned pos, unsigned var)
86		{
87	<	char format [128];
88	<	RREAL rad, radScale = RADSCALE, vol, dumpRatio;
89	<	FVECT minPos, maxPos;
90	<	unsigned arg, j, ptype;
91	<	long numPhotons, numSpheres = NSPHERES;
92	<	FILE *pmapFile;
93	<	Photon p;
87	>	switch ((str) [pos]) {
88	>	case '\0':
89	>	var = !var;
90	>	break;
91	>	case 'y': case 'Y': case 't': case 'T': case '+': case '1':
92	>	*var = 1;
93	>	break;
94	>	case 'n': case 'N': case 'f': case 'F': case '-': case '0':
95	>	*var = 0;
96	>	break;
97	>	default:
98	>	return 0;
99	>	}
100
101	+	return 1;
102	+	}
103	+
104	+
105	+	int main (int argc, char** argv)
106	+	{
107	+	char format [MAXFMTLEN];
108	+	RREAL rad, radScale = RADSCALE, extent, dumpRatio;
109	+	unsigned arg, j, ptype, dim, fluxCol = 0, points = 0;
110	+	long numSpheres = NSPHERES;
111	+	COLOR col = {0, 0, 0};
112	+	FILE *pmapFile;
113	+	PhotonMap pm;
114	+	PhotonPrimary pri;
115	+	Photon p;
116	+	#ifdef PMAP_OOC
117	+	char leafFname [1024];
118	+	#endif
119	+
120		if (argc < 2) {
121	<	puts("Dump photon maps as RADIANCE scene description\n");
122	<	printf("Usage: %s [-r radscale1] [-n nspheres1] pmap1 "
123	<	"[-r radscale2] [-n nspheres2] pmap2 ...\n", argv [0]);
121	>	puts("Dump photon maps as RADIANCE scene description "
122	>	"or ASCII point list\n");
123	>	printf("Usage: %s "
124	>	"[-a] [-r radscale1] [-n num1] "
125	>	"[-f \| -c rcol1 gcol1 bcol1] pmap1 "
126	>	"[-a] [-r radscale2] [-n num2] "
127	>	"[-f \| -c rcol2 gcol2 bcol2] pmap2 "
128	>	"...\n", argv [0]);
129		return 1;
130		}
131
#	Line 92 \| Line 133 \| int main (int argc, char argv)**
133		/* Parse options */
134		if (argv [arg][0] == '-') {
135		switch (argv [arg][1]) {
136	+	case 'a':
137	+	if (!setBool(argv [arg], 2, &points))
138	+	error(USER, "invalid option syntax at -a");
139	+	break;
140		case 'r':
141		if ((radScale = atof(argv [++arg])) <= 0)
142		error(USER, "invalid radius scale");
#	Line 99 \| Line 144 \| int main (int argc, char argv)**
144
145		case 'n':
146		if ((numSpheres = parseMultiplier(argv [++arg])) <= 0)
147	<	error(USER, "invalid number of spheres");
147	>	error(USER, "invalid number of points/spheres");
148		break;
149
150	+	case 'c':
151	+	if (fluxCol)
152	+	error(USER, "-f and -c are mutually exclusive");
153	+
154	+	if (badarg(argc - arg - 1, &argv [arg + 1], "fff"))
155	+	error(USER, "invalid RGB colour");
156	+
157	+	for (j = 0; j < 3; j++)
158	+	col [j] = atof(argv [++arg]);
159	+	break;
160	+
161	+	case 'f':
162	+	if (intens(col) > 0)
163	+	error(USER, "-f and -c are mutually exclusive");
164	+
165	+	if (!setBool(argv [arg], 2, &fluxCol))
166	+	error(USER, "invalid option syntax at -f");
167	+	break;
168	+
169		default:
170		sprintf(errmsg, "unknown option %s", argv [arg]);
171		error(USER, errmsg);
#	Line 110 \| Line 174 \| int main (int argc, char argv)**
174
175		continue;
176		}
177	<
178	<	/* Dump photon map */
177	>
178	>	/* Open next photon map file */
179		if (!(pmapFile = fopen(argv [arg], "rb"))) {
180		sprintf(errmsg, "can't open %s", argv [arg]);
181		error(SYSTEM, errmsg);
182		}
183	<
183	>
184		/* Get format string */
185		strcpy(format, PMAP_FORMAT_GLOB);
186		if (checkheader(pmapFile, format, NULL) != 1) {
#	Line 124 \| Line 188 \| int main (int argc, char argv)**
188		argv [arg], format);
189		error(USER, errmsg);
190		}
191	<
191	>
192		/* Identify photon map type from format string */
193		for (ptype = 0;
194		ptype < NUM_PMAP_TYPES && strcmp(pmapFormat [ptype], format);
195		ptype++);
196	<
196	>
197		if (!validPmapType(ptype)) {
198		sprintf(errmsg, "file %s contains an unknown photon map type",
199		argv [arg]);
#	Line 137 \| Line 201 \| int main (int argc, char argv)**
201		}
202
203		/* Get file format version and check for compatibility */
204	<	if (getint(sizeof(PMAP_FILEVER), pmapFile) != PMAP_FILEVER)
204	>	if (strcmp(getstr(format, pmapFile), PMAP_FILEVER))
205		error(USER, "incompatible photon map file format");
206	+
207	+	if (!points) {
208	+	/* Dump command line as comment */
209	+	fputs("# ", stdout);
210	+	printargs(argc, argv, stdout);
211	+	fputc('\n', stdout);
212	+	}
213
214	<	/* Dump command line as comment */
215	<	fputs("# ", stdout);
216	<	printargs(argc, argv, stdout);
217	<	fputc('\n', stdout);
214	>	/* Set point/sphere colour if independent of photon flux,
215	>	output RADIANCE material def if required */
216	>	if (!fluxCol) {
217	>	if (intens(col) <= 0)
218	>	copycolor(col, colDefs [ptype]);
219	>	if (!points) {
220	>	printf(radDefs [ptype].mat, col [0], col [1], col [2]);
221	>	fputc('\n', stdout);
222	>	}
223	>	}
224
225	<	/* Dump material def */
226	<	fputs(radDefs [ptype].mat, stdout);
227	<	fputc('\n', stdout);
151	<
152	<	/* Get number of photons (is this sizeof() hack portable?) */
153	<	numPhotons = getint(sizeof(((PhotonMap*)NULL) -> heapSize), pmapFile);
154	<
225	>	/* Get number of photons */
226	>	pm.numPhotons = getint(sizeof(pm.numPhotons), pmapFile);
227	>
228		/* Skip avg photon flux */
229		for (j = 0; j < 3; j++)
230		getflt(pmapFile);
231	<
231	>
232		/* Get distribution extent (min & max photon positions) */
233		for (j = 0; j < 3; j++) {
234	<	minPos [j] = getflt(pmapFile);
235	<	maxPos [j] = getflt(pmapFile);
234	>	pm.minPos [j] = getflt(pmapFile);
235	>	pm.maxPos [j] = getflt(pmapFile);
236		}
237
238		/* Skip centre of gravity, and avg photon dist to it */
239		for (j = 0; j < 4; j++)
240		getflt(pmapFile);
241
242	<	/* Sphere radius based on avg intersphere dist
243	<	(= sphere distrib density ^-1/3) */
244	<	vol = (maxPos [0] - minPos [0]) * (maxPos [1] - minPos [1]) *
245	<	(maxPos [2] - minPos [2]);
246	<	rad = radScale * RADCOEFF * pow(vol / numSpheres, 1./3.);
242	>	/* Sphere radius based on avg intersphere dist depending on
243	>	whether the distribution occupies a 1D line (!), a 2D plane,
244	>	or 3D volume (= sphere distrib density ^-1/d, where d is the
245	>	dimensionality of the distribution) */
246	>	for (j = 0, extent = 1.0, dim = 0; j < 3; j++) {
247	>	rad = pm.maxPos [j] - pm.minPos [j];
248	>
249	>	if (rad > FTINY) {
250	>	dim++;
251	>	extent *= rad;
252	>	}
253	>	}
254	>
255	>	rad = radScale * RADCOEFF * pow(extent / numSpheres, 1./dim);
256
257		/* Photon dump probability to satisfy target sphere count */
258	<	dumpRatio = numSpheres < numPhotons ? (float)numSpheres / numPhotons
177	<	: 1;
258	>	dumpRatio = min(1, (float)numSpheres / pm.numPhotons);
259
260	<	while (numPhotons-- > 0) {
261	<	/* Get photon position */
260	>	/* Skip primary rays */
261	>	pm.numPrimary = getint(sizeof(pm.numPrimary), pmapFile);
262	>	while (pm.numPrimary-- > 0) {
263	>	/* Skip source index & incident dir */
264	>	getint(sizeof(pri.srcIdx), pmapFile);
265	>	#ifdef PMAP_PRIMARYDIR
266	>	/* Skip primary incident dir */
267	>	getint(sizeof(pri.dir), pmapFile);
268	>	#endif
269	>	#ifdef PMAP_PRIMARYPOS
270	>	/* Skip primary hitpoint */
271	>	for (j = 0; j < 3; j++)
272	>	getflt(pmapFile);
273	>	#endif
274	>	}
275	>
276	>	#ifdef PMAP_OOC
277	>	/* Open leaf file with filename derived from pmap, replace pmapFile
278	>	* (which is currently the node file) */
279	>	strncpy(leafFname, argv [arg], sizeof(leafFname) - 1);
280	>	strncat(leafFname, PMAP_OOC_LEAFSUFFIX, sizeof(leafFname) - 1);
281	>	fclose(pmapFile);
282	>	if (!(pmapFile = fopen(leafFname, "rb"))) {
283	>	sprintf(errmsg, "cannot open leaf file %s", leafFname);
284	>	error(SYSTEM, errmsg);
285	>	}
286	>	#endif
287	>
288	>	/* Read photons */
289	>	while (pm.numPhotons-- > 0) {
290	>	#ifdef PMAP_OOC
291	>	/* Get entire photon record from ooC octree leaf file
292	>	!!! OOC PMAP FILES CURRENTLY DON'T USE PORTABLE I/O !!! */
293	>	if (!fread(&p, sizeof(p), 1, pmapFile)) {
294	>	sprintf(errmsg, "error reading OOC leaf file %s", leafFname);
295	>	error(SYSTEM, errmsg);
296	>	}
297	>	#else /* kd-tree */
298	>	/* Get photon position */
299		for (j = 0; j < 3; j++)
300		p.pos [j] = getflt(pmapFile);
301
302	<	/* 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 */
302	>	/* Get photon normal (currently not used) */
303		for (j = 0; j < 3; j++)
304	<	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
304	>	p.norm [j] = getint(1, pmapFile);
305
306	+	/* Get photon flux */
307	+	#ifdef PMAP_FLOAT_FLUX
308	+	for (j = 0; j < 3; j++)
309	+	p.flux [j] = getflt(pmapFile);
310	+	#else
311	+	for (j = 0; j < 4; j++)
312	+	p.flux [j] = getint(1, pmapFile);
313	+	#endif
314	+
315	+
316	+
317		/* Skip primary ray index */
318		getint(sizeof(p.primary), pmapFile);
319
320		/* Skip flags */
321		getint(sizeof(p.flags), pmapFile);
322	+	#endif
323	+
324	+	/* Dump photon probabilistically acc. to target sphere count */
325	+	if (frandom() <= dumpRatio) {
326	+	if (fluxCol) {
327	+	/* Get photon flux */
328	+	getPhotonFlux(&p, col);
329	+	/* Scale by dumpRatio for energy conservation */
330	+	scalecolor(col, 1.0 / dumpRatio);
331	+	}
332	+
333	+	if (!points) {
334	+	if (fluxCol) {
335	+	/* Dump material def if variable (depends on flux) */
336	+	printf(radDefs [ptype].mat, col [0], col [1], col [2]);
337	+	fputc('\n', stdout);
338	+	}
339	+	printf(radDefs [ptype].obj, p.pos [0], p.pos [1], p.pos [2],
340	+	rad);
341	+	fputc('\n', stdout);
342	+	}
343	+	else /* Dump as XYZ RGB point */
344	+	printf(POINTFMT, p.pos [0], p.pos [1], p.pos [2],
345	+	col [0], col [1] ,col [2]);
346	+	}
347
348	<	if (feof(pmapFile)) {
348	>	if (ferror(pmapFile) \|\| feof(pmapFile)) {
349		sprintf(errmsg, "error reading %s", argv [arg]);
350		error(USER, errmsg);
351		}
#	Line 216 \| Line 356 \| int main (int argc, char argv)**
356		/* Reset defaults for next dump */
357		radScale = RADSCALE;
358		numSpheres = NSPHERES;
359	+	col [0] = col [1] = col [2] = 0;
360	+	fluxCol = points = 0;
361		}
362
363		return 0;

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Comparing ray/src/rt/pmapdump.c (file contents): Revision 2.6 by rschregle, Thu Feb 4 19:39:10 2016 UTC vs. Revision 2.16 by rschregle, Tue Jul 21 16:10:42 2020 UTC

Diff Legend

Comparing ray/src/rt/pmapdump.c (file contents):
Revision 2.6 by rschregle, Thu Feb 4 19:39:10 2016 UTC vs.
Revision 2.16 by rschregle, Tue Jul 21 16:10:42 2020 UTC