| 14 |
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#include "rtio.h" |
| 15 |
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#include "resolu.h" |
| 16 |
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#include "bsdfrep.h" |
| 17 |
+ |
/* name and manufacturer if known */ |
| 18 |
+ |
char bsdf_name[256]; |
| 19 |
+ |
char bsdf_manuf[256]; |
| 20 |
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/* active grid resolution */ |
| 21 |
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int grid_res = GRIDRES; |
| 22 |
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|
| 29 |
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int input_orient = 0; |
| 30 |
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int output_orient = 0; |
| 31 |
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|
| 32 |
+ |
/* BSDF histogram */ |
| 33 |
+ |
unsigned long bsdf_hist[HISTLEN]; |
| 34 |
+ |
|
| 35 |
+ |
/* BSDF value for boundary regions */ |
| 36 |
+ |
double bsdf_min = 0; |
| 37 |
+ |
|
| 38 |
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/* processed incident DSF measurements */ |
| 39 |
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RBFNODE *dsf_list = NULL; |
| 40 |
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|
| 91 |
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int |
| 92 |
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use_symmetry(FVECT vec) |
| 93 |
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{ |
| 94 |
< |
double phi = get_phi360(vec); |
| 94 |
> |
const double phi = get_phi360(vec); |
| 95 |
|
|
| 96 |
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switch (inp_coverage) { |
| 97 |
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case INP_QUAD1|INP_QUAD2|INP_QUAD3|INP_QUAD4: |
| 198 |
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int pos[2]; |
| 199 |
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int n; |
| 200 |
|
|
| 201 |
< |
for (n = rbf->nrbf; n-- > 0; ) { |
| 201 |
> |
for (n = ((-.01 > phi) | (phi > .01))*rbf->nrbf; n-- > 0; ) { |
| 202 |
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ovec_from_pos(outvec, rbf->rbfa[n].gx, rbf->rbfa[n].gy); |
| 203 |
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spinvector(outvec, outvec, vnorm, phi); |
| 204 |
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pos_from_vec(pos, outvec); |
| 208 |
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VCOPY(rbf->invec, invec); |
| 209 |
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} |
| 210 |
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|
| 202 |
– |
/* Compute volume associated with Gaussian lobe */ |
| 203 |
– |
double |
| 204 |
– |
rbf_volume(const RBFVAL *rbfp) |
| 205 |
– |
{ |
| 206 |
– |
double rad = R2ANG(rbfp->crad); |
| 207 |
– |
|
| 208 |
– |
return((2.*M_PI) * rbfp->peak * rad*rad); |
| 209 |
– |
} |
| 210 |
– |
|
| 211 |
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/* Compute outgoing vector from grid position */ |
| 212 |
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void |
| 213 |
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ovec_from_pos(FVECT vec, int xpos, int ypos) |
| 237 |
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pos[1] = (int)(sq[1]*grid_res); |
| 238 |
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} |
| 239 |
|
|
| 240 |
+ |
/* Compute volume associated with Gaussian lobe */ |
| 241 |
+ |
double |
| 242 |
+ |
rbf_volume(const RBFVAL *rbfp) |
| 243 |
+ |
{ |
| 244 |
+ |
double rad = R2ANG(rbfp->crad); |
| 245 |
+ |
FVECT odir; |
| 246 |
+ |
double elev, integ; |
| 247 |
+ |
/* infinite integral approximation */ |
| 248 |
+ |
integ = (2.*M_PI) * rbfp->peak * rad*rad; |
| 249 |
+ |
/* check if we're near horizon */ |
| 250 |
+ |
ovec_from_pos(odir, rbfp->gx, rbfp->gy); |
| 251 |
+ |
elev = output_orient*odir[2]; |
| 252 |
+ |
/* apply cut-off correction if > 1% */ |
| 253 |
+ |
if (elev < 2.8*rad) { |
| 254 |
+ |
/* elev = asin(elev); /* this is so crude, anyway... */ |
| 255 |
+ |
integ *= 1. - .5*exp(-.5*elev*elev/(rad*rad)); |
| 256 |
+ |
} |
| 257 |
+ |
return(integ); |
| 258 |
+ |
} |
| 259 |
+ |
|
| 260 |
|
/* Evaluate RBF for DSF at the given normalized outgoing direction */ |
| 261 |
|
double |
| 262 |
|
eval_rbfrep(const RBFNODE *rp, const FVECT outvec) |
| 263 |
|
{ |
| 264 |
+ |
const double rfact2 = (38./M_PI/M_PI)*(grid_res*grid_res); |
| 265 |
+ |
double minval = bsdf_min*output_orient*outvec[2]; |
| 266 |
+ |
int pos[2]; |
| 267 |
|
double res = 0; |
| 268 |
|
const RBFVAL *rbfp; |
| 269 |
|
FVECT odir; |
| 270 |
< |
double sig2; |
| 270 |
> |
double rad2; |
| 271 |
|
int n; |
| 272 |
< |
|
| 273 |
< |
if (rp == NULL) |
| 272 |
> |
/* check for wrong side */ |
| 273 |
> |
if (outvec[2] > 0 ^ output_orient > 0) |
| 274 |
|
return(.0); |
| 275 |
+ |
/* use minimum if no information avail. */ |
| 276 |
+ |
if (rp == NULL) |
| 277 |
+ |
return(minval); |
| 278 |
+ |
/* optimization for fast lobe culling */ |
| 279 |
+ |
pos_from_vec(pos, outvec); |
| 280 |
+ |
/* sum radial basis function */ |
| 281 |
|
rbfp = rp->rbfa; |
| 282 |
|
for (n = rp->nrbf; n--; rbfp++) { |
| 283 |
+ |
int d2 = (pos[0]-rbfp->gx)*(pos[0]-rbfp->gx) + |
| 284 |
+ |
(pos[1]-rbfp->gy)*(pos[1]-rbfp->gy); |
| 285 |
+ |
rad2 = R2ANG(rbfp->crad); |
| 286 |
+ |
rad2 *= rad2; |
| 287 |
+ |
if (d2 > rad2*rfact2) |
| 288 |
+ |
continue; |
| 289 |
|
ovec_from_pos(odir, rbfp->gx, rbfp->gy); |
| 290 |
< |
sig2 = R2ANG(rbfp->crad); |
| 256 |
< |
sig2 = (DOT(odir,outvec) - 1.) / (sig2*sig2); |
| 257 |
< |
if (sig2 > -19.) |
| 258 |
< |
res += rbfp->peak * exp(sig2); |
| 290 |
> |
res += rbfp->peak * exp((DOT(odir,outvec) - 1.) / rad2); |
| 291 |
|
} |
| 292 |
+ |
if (res < minval) /* never return less than minval */ |
| 293 |
+ |
return(minval); |
| 294 |
|
return(res); |
| 295 |
|
} |
| 296 |
|
|
| 407 |
|
dsf_list = rbf->next; |
| 408 |
|
free(rbf); |
| 409 |
|
} |
| 410 |
+ |
bsdf_name[0] = '\0'; |
| 411 |
+ |
bsdf_manuf[0] = '\0'; |
| 412 |
|
inp_coverage = 0; |
| 413 |
|
single_plane_incident = -1; |
| 414 |
|
input_orient = output_orient = 0; |
| 423 |
|
MIGRATION *mig; |
| 424 |
|
int i, n; |
| 425 |
|
/* finish header */ |
| 426 |
+ |
if (bsdf_name[0]) |
| 427 |
+ |
fprintf(ofp, "NAME=%s\n", bsdf_name); |
| 428 |
+ |
if (bsdf_manuf[0]) |
| 429 |
+ |
fprintf(ofp, "MANUFACT=%s\n", bsdf_manuf); |
| 430 |
|
fprintf(ofp, "SYMMETRY=%d\n", !single_plane_incident * inp_coverage); |
| 431 |
|
fprintf(ofp, "IO_SIDES= %d %d\n", input_orient, output_orient); |
| 432 |
|
fprintf(ofp, "GRIDRES=%d\n", grid_res); |
| 433 |
+ |
fprintf(ofp, "BSDFMIN=%g\n", bsdf_min); |
| 434 |
|
fputformat(BSDFREP_FMT, ofp); |
| 435 |
|
fputc('\n', ofp); |
| 436 |
|
/* write each DSF */ |
| 483 |
|
{ |
| 484 |
|
char fmt[32]; |
| 485 |
|
|
| 486 |
+ |
if (!strncmp(s, "NAME=", 5)) { |
| 487 |
+ |
strcpy(bsdf_name, s+5); |
| 488 |
+ |
bsdf_name[strlen(bsdf_name)-1] = '\0'; |
| 489 |
+ |
} |
| 490 |
+ |
if (!strncmp(s, "MANUFACT=", 9)) { |
| 491 |
+ |
strcpy(bsdf_manuf, s+9); |
| 492 |
+ |
bsdf_manuf[strlen(bsdf_manuf)-1] = '\0'; |
| 493 |
+ |
} |
| 494 |
|
if (!strncmp(s, "SYMMETRY=", 9)) { |
| 495 |
|
inp_coverage = atoi(s+9); |
| 496 |
|
single_plane_incident = !inp_coverage; |
| 504 |
|
sscanf(s+8, "%d", &grid_res); |
| 505 |
|
return(0); |
| 506 |
|
} |
| 507 |
+ |
if (!strncmp(s, "BSDFMIN=", 8)) { |
| 508 |
+ |
sscanf(s+8, "%lf", &bsdf_min); |
| 509 |
+ |
return(0); |
| 510 |
+ |
} |
| 511 |
|
if (formatval(fmt, s) && strcmp(fmt, BSDFREP_FMT)) |
| 512 |
|
return(-1); |
| 513 |
|
return(0); |
| 530 |
|
progname); |
| 531 |
|
return(0); |
| 532 |
|
} |
| 533 |
< |
rbfh.next = NULL; /* read each DSF */ |
| 481 |
< |
rbfh.ejl = NULL; |
| 533 |
> |
memset(&rbfh, 0, sizeof(rbfh)); /* read each DSF */ |
| 534 |
|
while ((rbfh.ord = getint(4, ifp)) >= 0) { |
| 535 |
|
RBFNODE *newrbf; |
| 536 |
|
|
| 537 |
|
rbfh.invec[0] = getflt(ifp); |
| 538 |
|
rbfh.invec[1] = getflt(ifp); |
| 539 |
|
rbfh.invec[2] = getflt(ifp); |
| 540 |
+ |
if (normalize(rbfh.invec) == 0) { |
| 541 |
+ |
fprintf(stderr, "%s: zero incident vector\n", progname); |
| 542 |
+ |
return(0); |
| 543 |
+ |
} |
| 544 |
|
rbfh.vtotal = getflt(ifp); |
| 545 |
|
rbfh.nrbf = getint(4, ifp); |
| 546 |
|
newrbf = (RBFNODE *)malloc(sizeof(RBFNODE) + |
| 547 |
|
sizeof(RBFVAL)*(rbfh.nrbf-1)); |
| 548 |
|
if (newrbf == NULL) |
| 549 |
|
goto memerr; |
| 550 |
< |
memcpy(newrbf, &rbfh, sizeof(RBFNODE)-sizeof(RBFVAL)); |
| 550 |
> |
*newrbf = rbfh; |
| 551 |
|
for (i = 0; i < rbfh.nrbf; i++) { |
| 552 |
|
newrbf->rbfa[i].peak = getflt(ifp); |
| 553 |
|
newrbf->rbfa[i].crad = getint(2, ifp) & 0xffff; |
