--- ray/src/cv/bsdf2rad.c 2017/04/12 05:01:45 2.29 +++ ray/src/cv/bsdf2rad.c 2021/02/12 00:53:56 2.37 @@ -1,21 +1,22 @@ #ifndef lint -static const char RCSid[] = "$Id: bsdf2rad.c,v 2.29 2017/04/12 05:01:45 greg Exp $"; +static const char RCSid[] = "$Id: bsdf2rad.c,v 2.37 2021/02/12 00:53:56 greg Exp $"; #endif /* * Plot 3-D BSDF output based on scattering interpolant or XML representation */ -#include -#include #include +#include "rtio.h" #include "paths.h" #include "rtmath.h" -#include "resolu.h" #include "bsdfrep.h" +#ifndef NINCIDENT #define NINCIDENT 37 /* number of samples/hemisphere */ - +#endif +#ifndef GRIDSTEP #define GRIDSTEP 2 /* our grid step size */ +#endif #define SAMPRES (GRIDRES/GRIDSTEP) int front_comp = 0; /* front component flags (SDsamp*) */ @@ -24,7 +25,7 @@ double overall_min = 1./PI; /* overall minimum BSDF v double min_log10; /* smallest log10 value for plotting */ double overall_max = .0; /* overall maximum BSDF value */ -char ourTempDir[TEMPLEN] = ""; /* our temporary directory */ +char ourTempDir[TEMPLEN+1] = ""; /* our temporary directory */ const char frpref[] = "rf"; const char ftpref[] = "tf"; @@ -40,10 +41,9 @@ const double sph_xoffset = 15.; #define bsdf_rad (sph_rad*.25) #define arrow_rad (bsdf_rad*.015) -#define FEQ(a,b) ((a)-(b) <= 1e-7 && (b)-(a) <= 1e-7) +#define set_minlog() overall_min = (overall_min < 1e-5) ? 1e-5 : overall_min; \ + min_log10 = log10(overall_min) - .1 -#define set_minlog() (min_log10 = log10(overall_min + 1e-5) - .1) - char *progname; /* Get Fibonacci sphere vector (0 to NINCIDENT-1) */ @@ -76,7 +76,7 @@ cvt_sposition(FVECT sp, const FVECT iv, int inc_side) static char * tfile_name(const char *prefix, const char *suffix, int i) { - static char buf[128]; + static char buf[256]; if (!ourTempDir[0]) { /* create temporary directory */ mktemp(strcpy(ourTempDir,TEMPLATE)); @@ -274,6 +274,7 @@ put_mirror_arrow(const FVECT origin, const FVECT nrm) { const double arrow_len = 1.2*bsdf_rad; const double tip_len = 0.2*bsdf_rad; + static int cnt = 1; FVECT refl; int i; @@ -281,20 +282,20 @@ put_mirror_arrow(const FVECT origin, const FVECT nrm) refl[1] = 2.*nrm[2]*nrm[1]; refl[2] = 2.*nrm[2]*nrm[2] - 1.; - printf("\n# Mirror arrow\n"); - printf("\nshaft_mat cylinder inc_dir\n0\n0\n7"); + printf("\n# Mirror arrow #%d\n", cnt); + printf("\nshaft_mat cylinder inc_dir%d\n0\n0\n7", cnt); printf("\n\t%f %f %f\n\t%f %f %f\n\t%f\n", origin[0], origin[1], origin[2]+arrow_len, origin[0], origin[1], origin[2], arrow_rad); - printf("\nshaft_mat cylinder mir_dir\n0\n0\n7"); + printf("\nshaft_mat cylinder mir_dir%d\n0\n0\n7", cnt); printf("\n\t%f %f %f\n\t%f %f %f\n\t%f\n", origin[0], origin[1], origin[2], origin[0] + arrow_len*refl[0], origin[1] + arrow_len*refl[1], origin[2] + arrow_len*refl[2], arrow_rad); - printf("\ntip_mat cone mir_tip\n0\n0\n8"); + printf("\ntip_mat cone mir_tip%d\n0\n0\n8", cnt); printf("\n\t%f %f %f\n\t%f %f %f\n\t%f 0\n", origin[0] + (arrow_len-.5*tip_len)*refl[0], origin[1] + (arrow_len-.5*tip_len)*refl[1], @@ -303,6 +304,7 @@ put_mirror_arrow(const FVECT origin, const FVECT nrm) origin[1] + (arrow_len+.5*tip_len)*refl[1], origin[2] + (arrow_len+.5*tip_len)*refl[2], 2.*arrow_rad); + ++cnt; } /* Put out transmitted direction arrow for the given incident vector */ @@ -311,19 +313,21 @@ put_trans_arrow(const FVECT origin) { const double arrow_len = 1.2*bsdf_rad; const double tip_len = 0.2*bsdf_rad; + static int cnt = 1; int i; - printf("\n# Transmission arrow\n"); - printf("\nshaft_mat cylinder trans_dir\n0\n0\n7"); + printf("\n# Transmission arrow #%d\n", cnt); + printf("\nshaft_mat cylinder trans_dir%d\n0\n0\n7", cnt); printf("\n\t%f %f %f\n\t%f %f %f\n\t%f\n", origin[0], origin[1], origin[2], origin[0], origin[1], origin[2]-arrow_len, arrow_rad); - printf("\ntip_mat cone trans_tip\n0\n0\n8"); + printf("\ntip_mat cone trans_tip%d\n0\n0\n8", cnt); printf("\n\t%f %f %f\n\t%f %f %f\n\t%f 0\n", origin[0], origin[1], origin[2]-arrow_len+.5*tip_len, origin[0], origin[1], origin[2]-arrow_len-.5*tip_len, - 2.*arrow_rad); + 2.*arrow_rad); + ++cnt; } /* Compute rotation (x,y,z) => (xp,yp,zp) */ @@ -342,19 +346,19 @@ addrot(char *xf, const FVECT xp, const FVECT yp, const return(4); } theta = atan2(yp[2], zp[2]); - if (!FEQ(theta,0.0)) { + if (!FABSEQ(theta,0.0)) { sprintf(xf, " -rx %f", theta*(180./PI)); while (*xf) ++xf; n += 2; } theta = Asin(-xp[2]); - if (!FEQ(theta,0.0)) { + if (!FABSEQ(theta,0.0)) { sprintf(xf, " -ry %f", theta*(180./PI)); while (*xf) ++xf; n += 2; } theta = atan2(xp[1], xp[0]); - if (!FEQ(theta,0.0)) { + if (!FABSEQ(theta,0.0)) { sprintf(xf, " -rz %f", theta*(180./PI)); /* while (*xf) ++xf; */ n += 2; @@ -512,7 +516,7 @@ put_hemispheres(void) if (front_comp) { printf( "\n!genrev %s Front \"R*sin(A*t)\" \"R*cos(A*t)\" %d -e \"R:%g;A:%f\" -s | xform -t %g 0 0\n", - sph_fmat, nsegs, sph_rad, 0.495*PI, sph_xoffset); + sph_fmat, nsegs, sph_rad, 0.5*PI, sph_xoffset); printf("\nvoid brighttext front_text\n3 helvet.fnt . FRONT\n0\n"); printf("12\n\t%f %f 0\n\t%f 0 0\n\t0 %f 0\n\t.01 1 -.1\n", -.22*sph_rad + sph_xoffset, -1.4*sph_rad, @@ -528,7 +532,7 @@ put_hemispheres(void) if (back_comp) { printf( "\n!genrev %s Back \"R*cos(A*t)\" \"R*sin(A*t)\" %d -e \"R:%g;A:%f\" -s | xform -t %g 0 0\n", - sph_bmat, nsegs, sph_rad, 0.495*PI, -sph_xoffset); + sph_bmat, nsegs, sph_rad, 0.5*PI, -sph_xoffset); printf("\nvoid brighttext back_text\n3 helvet.fnt . BACK\n0\n"); printf("12\n\t%f %f 0\n\t%f 0 0\n\t0 %f 0\n\t.01 1 -.1\n", -.22*sph_rad - sph_xoffset, -1.4*sph_rad, @@ -668,7 +672,7 @@ convert_mgf(const char *mgfdata) static int rbf_headline(char *s, void *p) { - char fmt[64]; + char fmt[MAXFMTLEN]; if (formatval(fmt, s)) { if (strcmp(fmt, BSDFREP_FMT)) @@ -702,27 +706,35 @@ int main(int argc, char *argv[]) { int inpXML = -1; + double myLim[2]; SDData myBSDF; - int n; + int a, n; /* check arguments */ progname = argv[0]; - if (argc > 1 && (n = strlen(argv[1])-4) > 0) { - if (!strcasecmp(argv[1]+n, ".xml")) + a = 1; + myLim[0] = -1; myLim[1] = -2; /* specified BSDF range? */ + if (argc > a+3 && argv[a][0] == '-' && argv[a][1] == 'r') { + myLim[0] = atof(argv[++a]); + myLim[1] = atof(argv[++a]); + ++a; + } + if (argc > a && (n = strlen(argv[a])-4) > 0) { + if (!strcasecmp(argv[a]+n, ".xml")) inpXML = 1; - else if (!strcasecmp(argv[1]+n, ".sir")) + else if (!strcasecmp(argv[a]+n, ".sir")) inpXML = 0; } - if (inpXML < 0 || inpXML & (argc > 2)) { - fprintf(stderr, "Usage: %s bsdf.xml > output.rad\n", progname); - fprintf(stderr, " Or: %s hemi1.sir hemi2.sir .. > output.rad\n", progname); + if (inpXML < 0 || inpXML & (argc > a+1)) { + fprintf(stderr, "Usage: %s [-r min max] bsdf.xml > output.rad\n", progname); + fprintf(stderr, " Or: %s [-r min max] hemi1.sir hemi2.sir .. > output.rad\n", progname); return(1); } fputs("# ", stdout); /* copy our command */ printargs(argc, argv, stdout); /* evaluate BSDF */ if (inpXML) { - SDclearBSDF(&myBSDF, argv[1]); - if (SDreportError(SDloadFile(&myBSDF, argv[1]), stderr)) + SDclearBSDF(&myBSDF, argv[a]); + if (SDreportError(SDloadFile(&myBSDF, argv[a]), stderr)) return(1); if (myBSDF.rf != NULL) front_comp |= SDsampR; if (myBSDF.tf != NULL) front_comp |= SDsampT; @@ -730,16 +742,20 @@ main(int argc, char *argv[]) if (myBSDF.tb != NULL) back_comp |= SDsampT; if (!front_comp & !back_comp) { fprintf(stderr, "%s: nothing to plot in '%s'\n", - progname, argv[1]); + progname, argv[a]); return(1); } - if (front_comp & SDsampR && myBSDF.rLambFront.cieY < overall_min*PI) - overall_min = myBSDF.rLambFront.cieY/PI; - if (back_comp & SDsampR && myBSDF.rLambBack.cieY < overall_min*PI) - overall_min = myBSDF.rLambBack.cieY/PI; - if ((front_comp|back_comp) & SDsampT && - myBSDF.tLamb.cieY < overall_min*PI) - overall_min = myBSDF.tLamb.cieY/PI; + if (myLim[0] >= 0) + overall_min = myLim[0]; + else { + if (front_comp & SDsampR && myBSDF.rLambFront.cieY < overall_min*PI) + overall_min = myBSDF.rLambFront.cieY/PI; + if (back_comp & SDsampR && myBSDF.rLambBack.cieY < overall_min*PI) + overall_min = myBSDF.rLambBack.cieY/PI; + if ((front_comp|back_comp) & SDsampT && + myBSDF.tLamb.cieY < overall_min*PI) + overall_min = myBSDF.tLamb.cieY/PI; + } set_minlog(); if (!build_wBSDF(&myBSDF)) return(1); @@ -748,41 +764,45 @@ main(int argc, char *argv[]) else strcpy(bsdf_name, myBSDF.name); strcpy(bsdf_manuf, myBSDF.makr); - put_matBSDF(argv[1]); + put_matBSDF(argv[a]); } else { FILE *fp[4]; - if (argc > 5) { + if (argc > a+4) { fprintf(stderr, "%s: more than 4 hemispheres!\n", progname); return(1); } - for (n = 1; n < argc; n++) { - fp[n-1] = fopen(argv[n], "rb"); - if (fp[n-1] == NULL) { + for (n = a; n < argc; n++) { + fp[n-a] = fopen(argv[n], "rb"); + if (fp[n-a] == NULL) { fprintf(stderr, "%s: cannot open BSDF interpolant '%s'\n", progname, argv[n]); return(1); } - if (getheader(fp[n-1], rbf_headline, NULL) < 0) { + if (getheader(fp[n-a], rbf_headline, NULL) < 0) { fprintf(stderr, "%s: bad BSDF interpolant '%s'\n", progname, argv[n]); return(1); } } + if (myLim[0] >= 0) + overall_min = myLim[0]; set_minlog(); - for (n = 1; n < argc; n++) { - if (fseek(fp[n-1], 0L, SEEK_SET) < 0) { + for (n = a; n < argc; n++) { + if (fseek(fp[n-a], 0L, SEEK_SET) < 0) { fprintf(stderr, "%s: cannot seek on '%s'\n", progname, argv[n]); return(1); } - if (!load_bsdf_rep(fp[n-1])) + if (!load_bsdf_rep(fp[n-a])) return(1); - fclose(fp[n-1]); + fclose(fp[n-a]); if (!build_wRBF()) return(1); } put_matBSDF(NULL); } + if (myLim[1] > myLim[0]) /* override maximum BSDF? */ + overall_max = myLim[1]; put_source(); /* before hemispheres & labels */ put_hemispheres(); put_scale();