195 |
|
int |
196 |
|
main(int argc, char *argv[]) |
197 |
|
{ |
198 |
< |
extern int nprocs; |
199 |
< |
int i; |
198 |
> |
extern int nprocs; |
199 |
> |
static const char quadrant_rep[16][16] = { |
200 |
> |
"iso","0-90","90-180","0-180", |
201 |
> |
"180-270","0-90+180-270","90-270", |
202 |
> |
"0-270","270-360","270-90", |
203 |
> |
"90-180+270-360","270-180","180-360", |
204 |
> |
"0-90+180-360","90-360","0-360" |
205 |
> |
}; |
206 |
> |
const char * symmetry = "Unknown"; |
207 |
> |
int i; |
208 |
|
/* start header */ |
209 |
|
SET_FILE_BINARY(stdout); |
210 |
|
newheader("RADIANCE", stdout); |
220 |
|
nprocs = atoi(argv[2]); |
221 |
|
argv++; argc--; |
222 |
|
break; |
223 |
+ |
case 's': |
224 |
+ |
symmetry = argv[2]; |
225 |
+ |
argv++; argc--; |
226 |
+ |
break; |
227 |
|
default: |
228 |
|
goto userr; |
229 |
|
} |
245 |
|
if (!add_pabopto_inp(i)) |
246 |
|
return(1); |
247 |
|
make_rbfrep(); /* process last data set */ |
248 |
+ |
/* check input symmetry */ |
249 |
+ |
switch (toupper(symmetry[0])) { |
250 |
+ |
case 'U': /* unknown symmetry */ |
251 |
+ |
if ((inp_coverage == (INP_QUAD1|INP_QUAD3)) | |
252 |
+ |
(inp_coverage == (INP_QUAD2|INP_QUAD4))) { |
253 |
+ |
fprintf(stderr, |
254 |
+ |
"%s: unsupported bowtie (%s) input symmetry\n", |
255 |
+ |
progname, quadrant_rep[inp_coverage]); |
256 |
+ |
return(1); |
257 |
+ |
} |
258 |
+ |
break; |
259 |
+ |
case 'I': /* isotropic */ |
260 |
+ |
if (inp_coverage) |
261 |
+ |
goto badsymmetry; |
262 |
+ |
break; |
263 |
+ |
case 'Q': /* quadrilateral symmetry */ |
264 |
+ |
if ((inp_coverage != INP_QUAD1) & |
265 |
+ |
(inp_coverage != INP_QUAD2) & |
266 |
+ |
(inp_coverage != INP_QUAD3) & |
267 |
+ |
(inp_coverage != INP_QUAD4)) |
268 |
+ |
goto badsymmetry; |
269 |
+ |
break; |
270 |
+ |
case 'B': /* bilateral symmetry */ |
271 |
+ |
if ((inp_coverage != (INP_QUAD1|INP_QUAD2)) & |
272 |
+ |
(inp_coverage != (INP_QUAD2|INP_QUAD3)) & |
273 |
+ |
(inp_coverage != (INP_QUAD3|INP_QUAD4)) & |
274 |
+ |
(inp_coverage != (INP_QUAD4|INP_QUAD1))) |
275 |
+ |
goto badsymmetry; |
276 |
+ |
break; |
277 |
+ |
case 'A': /* anisotropic */ |
278 |
+ |
if (inp_coverage != (INP_QUAD1|INP_QUAD2|INP_QUAD3|INP_QUAD4)) |
279 |
+ |
goto badsymmetry; |
280 |
+ |
break; |
281 |
+ |
default: |
282 |
+ |
fprintf(stderr, |
283 |
+ |
"%s: -s option must be Isotropic, Quadrilateral, Bilateral, or Anisotropic\n", |
284 |
+ |
progname); |
285 |
+ |
return(1); |
286 |
+ |
} |
287 |
+ |
#ifdef DEBUG |
288 |
+ |
fprintf(stderr, "Input phi coverage: %s\n", quadrant_rep[inp_coverage]); |
289 |
+ |
#endif |
290 |
|
build_mesh(); /* create interpolation */ |
291 |
|
save_bsdf_rep(stdout); /* write it out */ |
292 |
|
return(0); |
293 |
+ |
badsymmetry: |
294 |
+ |
fprintf(stderr, "%s: phi coverage (%s) does not match requested '%s' symmetry\n", |
295 |
+ |
progname, quadrant_rep[inp_coverage], symmetry); |
296 |
|
userr: |
297 |
< |
fprintf(stderr, "Usage: %s [-t][-n nproc] meas1.dat meas2.dat .. > bsdf.sir\n", |
297 |
> |
fprintf(stderr, "Usage: %s [-t][-n nproc][-s symmetry] meas1.dat meas2.dat .. > bsdf.sir\n", |
298 |
|
progname); |
299 |
|
return(1); |
300 |
|
} |