src/util/dctimestep.c

#ifndef lint
static const char RCSid[] = "$Id: dctimestep.c,v 2.21 2012/10/16 15:53:04 greg Exp $";
#endif
/*
 * Compute time-step result using Daylight Coefficient method.
 *
 *      G. Ward
 */

#include <ctype.h>
#include "standard.h"
#include "platform.h"
#include "paths.h"
#include "color.h"
#include "resolu.h"
#include "bsdf.h"
#include "bsdf_m.h"

char    *progname;                      /* global argv[0] */

/* Data types for file loading */
enum {DTfromHeader, DTascii, DTfloat, DTdouble, DTrgbe, DTxyze};

/* A color coefficient matrix -- vectors have ncols==1 */
typedef struct {
        int     nrows, ncols;
        COLORV  cmem[3];                /* extends struct */
} CMATRIX;

#define COLSPEC (sizeof(COLORV)==sizeof(float) ? "%f %f %f" : "%lf %lf %lf")

#define cm_lval(cm,r,c) ((cm)->cmem + 3*((r)*(cm)->ncols + (c)))

#define cv_lval(cm,i)   ((cm)->cmem + 3*(i))

/* Allocate a color coefficient matrix */
static CMATRIX *
cm_alloc(int nrows, int ncols)
{
        CMATRIX *cm;

        if ((nrows <= 0) | (ncols <= 0))
                error(USER, "attempt to create empty matrix");
        cm = (CMATRIX *)malloc(sizeof(CMATRIX) +
                                3*sizeof(COLORV)*(nrows*ncols - 1));
        if (cm == NULL)
                error(SYSTEM, "out of memory in cm_alloc()");
        cm->nrows = nrows;
        cm->ncols = ncols;
        return(cm);
}

#define cm_free(cm)     free(cm)

/* Resize color coefficient matrix */
static CMATRIX *
cm_resize(CMATRIX *cm, int nrows)
{
        if (nrows == cm->nrows)
                return(cm);
        if (nrows <= 0) {
                cm_free(cm);
                return(NULL);
        }
        cm = (CMATRIX *)realloc(cm, sizeof(CMATRIX) +
                        3*sizeof(COLORV)*(nrows*cm->ncols - 1));
        if (cm == NULL)
                error(SYSTEM, "out of memory in cm_resize()");
        cm->nrows = nrows;
        return(cm);
}

/* Load header to obtain data type */
static int
getDT(char *s, void *p)
{
        char    fmt[32];
        
        if (formatval(fmt, s)) {
                if (!strcmp(fmt, "ascii"))
                        *((int *)p) = DTascii;
                else if (!strcmp(fmt, "float"))
                        *((int *)p) = DTfloat;
                else if (!strcmp(fmt, "double"))
                        *((int *)p) = DTdouble;
                else if (!strcmp(fmt, COLRFMT))
                        *((int *)p) = DTrgbe;
                else if (!strcmp(fmt, CIEFMT))
                        *((int *)p) = DTxyze;
        }
        return(0);
}

static int
getDTfromHeader(FILE *fp)
{
        int     dt = DTfromHeader;
        
        if (getheader(fp, getDT, &dt) < 0)
                error(SYSTEM, "header read error");
        if (dt == DTfromHeader)
                error(USER, "missing data format in header");
        return(dt);
}

/* Allocate and load a matrix from the given file (or stdin if NULL) */
static CMATRIX *
cm_load(const char *fname, int nrows, int ncols, int dtype)
{
        CMATRIX *cm;
        FILE    *fp = stdin;

        if (ncols <= 0)
                error(USER, "Non-positive number of columns");
        if (fname == NULL)
                fname = "<stdin>";
        else if ((fp = fopen(fname, "r")) == NULL) {
                sprintf(errmsg, "cannot open file '%s'", fname);
                error(SYSTEM, errmsg);
        }
        if (dtype != DTascii)
                SET_FILE_BINARY(fp);
        if (dtype == DTfromHeader)
                dtype = getDTfromHeader(fp);
        switch (dtype) {
        case DTascii:
        case DTfloat:
        case DTdouble:
                break;
        default:
                error(USER, "unexpected data type in cm_load()");
        }
        if (nrows <= 0) {                       /* don't know length? */
                int     guessrows = 147;        /* usually big enough */
                if ((dtype != DTascii) & (fp != stdin)) {
                        long    startpos = ftell(fp);
                        if (fseek(fp, 0L, SEEK_END) == 0) {
                                long    endpos = ftell(fp);
                                long    elemsiz = 3*(dtype==DTfloat ?
                                            sizeof(float) : sizeof(double));

                                if ((endpos - startpos) % (ncols*elemsiz)) {
                                        sprintf(errmsg,
                                        "improper length for binary file '%s'",
                                                        fname);
                                        error(USER, errmsg);
                                }
                                guessrows = (endpos - startpos)/(ncols*elemsiz);
                                if (fseek(fp, startpos, SEEK_SET) < 0) {
                                        sprintf(errmsg,
                                                "fseek() error on file '%s'",
                                                        fname);
                                        error(SYSTEM, errmsg);
                                }
                                nrows = guessrows;      /* we're confident */
                        }
                }
                cm = cm_alloc(guessrows, ncols);
        } else
                cm = cm_alloc(nrows, ncols);
        if (cm == NULL)
                return(NULL);
        if (dtype == DTascii) {                         /* read text file */
                int     maxrow = (nrows > 0 ? nrows : 32000);
                int     r, c;
                for (r = 0; r < maxrow; r++) {
                    if (r >= cm->nrows)                 /* need more space? */
                        cm = cm_resize(cm, 2*cm->nrows);
                    for (c = 0; c < ncols; c++) {
                        COLORV  *cv = cm_lval(cm,r,c);
                        if (fscanf(fp, COLSPEC, cv, cv+1, cv+2) != 3)
                                if ((nrows <= 0) & (r > 0) & !c) {
                                        cm = cm_resize(cm, maxrow=r);
                                        break;
                                } else
                                        goto EOFerror;
                    }
                }
                while ((c = getc(fp)) != EOF)
                        if (!isspace(c)) {
                                sprintf(errmsg,
                                "unexpected data at end of ascii file %s",
                                                fname);
                                error(WARNING, errmsg);
                                break;
                        }
        } else {                                        /* read binary file */
                if (sizeof(COLORV) == (dtype==DTfloat ? sizeof(float) :
                                                        sizeof(double))) {
                        int     nread = 0;
                        do {                            /* read all we can */
                                nread += fread(cm->cmem + 3*nread,
                                                3*sizeof(COLORV),
                                                cm->nrows*cm->ncols - nread,
                                                fp);
                                if (nrows <= 0) {       /* unknown length */
                                        if (nread == cm->nrows*cm->ncols)
                                                        /* need more space? */
                                                cm = cm_resize(cm, 2*cm->nrows);
                                        else if (nread && !(nread % cm->ncols))
                                                        /* seem to be  done */
                                                cm = cm_resize(cm, nread/cm->ncols);
                                        else            /* ended mid-row */
                                                goto EOFerror;
                                } else if (nread < cm->nrows*cm->ncols)
                                        goto EOFerror;
                        } while (nread < cm->nrows*cm->ncols);

                } else if (dtype == DTdouble) {
                        double  dc[3];                  /* load from double */
                        COLORV  *cvp = cm->cmem;
                        int     n = nrows*ncols;

                        if (n <= 0)
                                goto not_handled;
                        while (n--) {
                                if (fread(dc, sizeof(double), 3, fp) != 3)
                                        goto EOFerror;
                                copycolor(cvp, dc);
                                cvp += 3;
                        }
                } else /* dtype == DTfloat */ {
                        float   fc[3];                  /* load from float */
                        COLORV  *cvp = cm->cmem;
                        int     n = nrows*ncols;

                        if (n <= 0)
                                goto not_handled;
                        while (n--) {
                                if (fread(fc, sizeof(float), 3, fp) != 3)
                                        goto EOFerror;
                                copycolor(cvp, fc);
                                cvp += 3;
                        }
                }
                if (getc(fp) != EOF) {
                                sprintf(errmsg,
                                "unexpected data at end of binary file %s",
                                                fname);
                                error(WARNING, errmsg);
                }
        }
        if (fp != stdin)
                fclose(fp);
        return(cm);
EOFerror:
        sprintf(errmsg, "unexpected EOF reading %s",
                        fname);
        error(USER, errmsg);
not_handled:
        error(INTERNAL, "unhandled data size or length in cm_load()");
        return(NULL);   /* gratis return */
}

/* Scale a matrix by a single value */
static CMATRIX *
cm_scale(const CMATRIX *cm1, const COLOR sca)
{
        CMATRIX *cmr;
        int     dr, dc;

        cmr = cm_alloc(cm1->nrows, cm1->ncols);
        if (cmr == NULL)
                return(NULL);
        for (dr = 0; dr < cmr->nrows; dr++)
            for (dc = 0; dc < cmr->ncols; dc++) {
                const COLORV    *sp = cm_lval(cm1,dr,dc);
                COLORV          *dp = cm_lval(cmr,dr,dc);
                dp[0] = sp[0] * sca[0];
                dp[1] = sp[1] * sca[1];
                dp[2] = sp[2] * sca[2];
            }
        return(cmr);
}

/* Multiply two matrices (or a matrix and a vector) and allocate the result */
static CMATRIX *
cm_multiply(const CMATRIX *cm1, const CMATRIX *cm2)
{
        CMATRIX *cmr;
        int     dr, dc, i;

        if ((cm1->ncols <= 0) | (cm1->ncols != cm2->nrows))
                error(INTERNAL, "matrix dimension mismatch in cm_multiply()");
        cmr = cm_alloc(cm1->nrows, cm2->ncols);
        if (cmr == NULL)
                return(NULL);
        for (dr = 0; dr < cmr->nrows; dr++)
            for (dc = 0; dc < cmr->ncols; dc++) {
                COLORV  *dp = cm_lval(cmr,dr,dc);
                dp[0] = dp[1] = dp[2] = 0;
                for (i = 0; i < cm1->ncols; i++) {
                    const COLORV        *cp1 = cm_lval(cm1,dr,i);
                    const COLORV        *cp2 = cm_lval(cm2,i,dc);
                    dp[0] += cp1[0] * cp2[0];
                    dp[1] += cp1[1] * cp2[1];
                    dp[2] += cp1[2] * cp2[2];
                }
            }
        return(cmr);
}

/* print out matrix as ASCII text -- no header */
static void
cm_print(const CMATRIX *cm, FILE *fp)
{
        int             r, c;
        const COLORV    *mp = cm->cmem;
        
        for (r = 0; r < cm->nrows; r++) {
                for (c = 0; c < cm->ncols; c++, mp += 3)
                        fprintf(fp, "\t%.6e %.6e %.6e", mp[0], mp[1], mp[2]);
                fputc('\n', fp);
        }
}

/* Convert a BSDF to our matrix representation */
static CMATRIX *
cm_bsdf(const COLOR bsdfLamb, const COLOR specCol, const SDMat *bsdf)
{
        CMATRIX *cm = cm_alloc(bsdf->nout, bsdf->ninc);
        int     nbadohm = 0;
        int     nneg = 0;
        int     r, c;
                                        /* loop over incident angles */
        for (c = 0; c < cm->ncols; c++) {
                const double    dom = mBSDF_incohm(bsdf,c);
                                        /* projected solid angle */
                nbadohm += (dom <= 0);

                for (r = 0; r < cm->nrows; r++) {
                        float   f = mBSDF_value(bsdf,c,r);
                        COLORV  *mp = cm_lval(cm,r,c);
                                        /* check BSDF value */
                        if ((f <= 0) | (dom <= 0)) {
                                nneg += (f < -FTINY);
                                f = .0f;
                        }
                        copycolor(mp, specCol);
                        scalecolor(mp, f);
                        addcolor(mp, bsdfLamb);
                        scalecolor(mp, dom);
                }
        }
        if (nneg | nbadohm) {
                sprintf(errmsg,
                    "BTDF has %d negatives and %d bad incoming solid angles",
                                nneg, nbadohm);
                error(WARNING, errmsg);
        }
        return(cm);
}

/* Convert between input and output indices for reciprocity */
static int
recip_out_from_in(const SDMat *bsdf, int in_recip)
{
        FVECT   v;

        if (!mBSDF_incvec(v, bsdf, in_recip+.5))
                return(in_recip);               /* XXX should be error! */
        v[2] = -v[2];
        return(mBSDF_outndx(bsdf, v));
}

/* Convert between output and input indices for reciprocity */
static int
recip_in_from_out(const SDMat *bsdf, int out_recip)
{
        FVECT   v;

        if (!mBSDF_outvec(v, bsdf, out_recip+.5))
                return(out_recip);              /* XXX should be error! */
        v[2] = -v[2];
        return(mBSDF_incndx(bsdf, v));
}

/* Convert a BSDF to our matrix representation, applying reciprocity */
static CMATRIX *
cm_bsdf_recip(const COLOR bsdfLamb, const COLOR specCol, const SDMat *bsdf)
{
        CMATRIX *cm = cm_alloc(bsdf->ninc, bsdf->nout);
        int     nbadohm = 0;
        int     nneg = 0;
        int     r, c;
                                        /* loop over incident angles */
        for (c = 0; c < cm->ncols; c++) {
                const int       ro = recip_out_from_in(bsdf,c);
                const double    dom = mBSDF_outohm(bsdf,ro);
                                        /* projected solid angle */
                nbadohm += (dom <= 0);

                for (r = 0; r < cm->nrows; r++) {
                        const int       ri = recip_in_from_out(bsdf,r);
                        float           f = mBSDF_value(bsdf,ri,ro);
                        COLORV          *mp = cm_lval(cm,r,c);
                                        /* check BSDF value */
                        if ((f <= 0) | (dom <= 0)) {
                                nneg += (f < -FTINY);
                                f = .0f;
                        }
                        copycolor(mp, specCol);
                        scalecolor(mp, f);
                        addcolor(mp, bsdfLamb);
                        scalecolor(mp, dom);
                }
        }
        if (nneg | nbadohm) {
                sprintf(errmsg,
                    "BTDF has %d negatives and %d bad incoming solid angles",
                                nneg, nbadohm);
                error(WARNING, errmsg);
        }
        return(cm);
}

/* Load and convert a matrix BSDF from the given XML file */
static CMATRIX *
cm_loadBSDF(char *fname, COLOR cLamb)
{
        CMATRIX         *Tmat;
        char            *fpath;
        int             recip;
        SDError         ec;
        SDData          myBSDF;
        SDSpectralDF    *tdf;
        COLOR           bsdfLamb, specCol;
                                        /* find path to BSDF file */
        fpath = getpath(fname, getrlibpath(), R_OK);
        if (fpath == NULL) {
                sprintf(errmsg, "cannot find BSDF file '%s'", fname);
                error(USER, errmsg);
        }
        SDclearBSDF(&myBSDF, fname);    /* load XML and check type */
        ec = SDloadFile(&myBSDF, fpath);
        if (ec)
                error(USER, transSDError(ec));
        ccy2rgb(&myBSDF.tLamb.spec, myBSDF.tLamb.cieY/PI, bsdfLamb);
        recip = (myBSDF.tf == NULL);
        tdf = recip ? myBSDF.tb : myBSDF.tf;
        if (tdf == NULL) {              /* no non-Lambertian transmission? */
                if (cLamb != NULL)
                        copycolor(cLamb, bsdfLamb);
                SDfreeBSDF(&myBSDF);
                return(NULL);
        }
        if (tdf->ncomp != 1 || tdf->comp[0].func != &SDhandleMtx) {
                sprintf(errmsg, "unsupported BSDF '%s'", fpath);
                error(USER, errmsg);
        }
                                        /* convert BTDF to matrix */
        ccy2rgb(&tdf->comp[0].cspec[0], 1., specCol);
        Tmat = recip ? cm_bsdf_recip(bsdfLamb, specCol, (SDMat *)tdf->comp[0].dist)
                        : cm_bsdf(bsdfLamb, specCol, (SDMat *)tdf->comp[0].dist);
        if (cLamb != NULL)              /* Lambertian is included */
                setcolor(cLamb, .0, .0, .0);
                                        /* free BSDF and return */
        SDfreeBSDF(&myBSDF);
        return(Tmat);
}

/* Sum together a set of images and write result to stdout */
static int
sum_images(const char *fspec, const CMATRIX *cv, FILE *fout)
{
        int     myDT = DTfromHeader;
        CMATRIX *pmat;
        COLOR   *scanline;
        int     myXR, myYR;
        int     i, y;

        if (cv->ncols != 1)
                error(INTERNAL, "expected vector in sum_images()");
        for (i = 0; i < cv->nrows; i++) {
                const COLORV    *scv = cv_lval(cv,i);
                char            fname[1024];
                FILE            *fp;
                int             dt, xr, yr;
                COLORV          *psp;
                                                        /* check for zero */
                if ((scv[RED] == 0) & (scv[GRN] == 0) & (scv[BLU] == 0) &&
                                (myDT != DTfromHeader) | (i < cv->nrows-1))
                        continue;
                                                        /* open next picture */
                sprintf(fname, fspec, i);
                if ((fp = fopen(fname, "r")) == NULL) {
                        sprintf(errmsg, "cannot open picture '%s'", fname);
                        error(SYSTEM, errmsg);
                }
                SET_FILE_BINARY(fp);
                dt = getDTfromHeader(fp);
                if ((dt != DTrgbe) & (dt != DTxyze) ||
                                !fscnresolu(&xr, &yr, fp)) {
                        sprintf(errmsg, "file '%s' not a picture", fname);
                        error(USER, errmsg);
                }
                if (myDT == DTfromHeader) {             /* on first one */
                        myDT = dt;
                        myXR = xr; myYR = yr;
                        scanline = (COLOR *)malloc(sizeof(COLOR)*myXR);
                        if (scanline == NULL)
                                error(SYSTEM, "out of memory in sum_images()");
                        pmat = cm_alloc(myYR, myXR);
                        memset(pmat->cmem, 0, sizeof(COLOR)*myXR*myYR);
                                                        /* finish header */
                        fputformat(myDT==DTrgbe ? COLRFMT : CIEFMT, fout);
                        fputc('\n', fout);
                        fprtresolu(myXR, myYR, fout);
                        fflush(fout);
                } else if ((dt != myDT) | (xr != myXR) | (yr != myYR)) {
                        sprintf(errmsg, "picture '%s' format/size mismatch",
                                        fname);
                        error(USER, errmsg);
                }
                psp = pmat->cmem;
                for (y = 0; y < yr; y++) {              /* read it in */
                        int     x;
                        if (freadscan(scanline, xr, fp) < 0) {
                                sprintf(errmsg, "error reading picture '%s'",
                                                fname);
                                error(SYSTEM, errmsg);
                        }
                                                        /* sum in scanline */
                        for (x = 0; x < xr; x++, psp += 3) {
                                multcolor(scanline[x], scv);
                                addcolor(psp, scanline[x]);
                        }
                }
                fclose(fp);                             /* done this picture */
        }
        free(scanline);
                                                        /* write scanlines */
        for (y = 0; y < myYR; y++)
                if (fwritescan((COLOR *)cm_lval(pmat, y, 0), myXR, fout) < 0)
                        return(0);
        cm_free(pmat);                                  /* all done */
        return(fflush(fout) == 0);
}

/* check to see if a string contains a %d or %o specification */
static int
hasNumberFormat(const char *s)
{
        while (*s) {
                while (*s != '%')
                        if (!*s++)
                                return(0);
                if (*++s == '%') {              /* ignore "%%" */
                        ++s;
                        continue;
                }
                while (isdigit(*s))             /* field length */
                        ++s;
                                                /* field we'll use? */
                if ((*s == 'd') | (*s == 'i') | (*s == 'o') |
                                        (*s == 'x') | (*s == 'X'))
                        return(1);
        }
        return(0);                              /* didn't find one */
}

int
main(int argc, char *argv[])
{
        CMATRIX                 *cvec;          /* component vector result */

        progname = argv[0];

        if ((argc < 2) | (argc > 5)) {
                fprintf(stderr, "Usage: %s DCspec [tregvec]\n", progname);
                fprintf(stderr, "   or: %s Vspec Tbsdf.xml Dmat.dat [tregvec]\n",
                                        progname);
                return(1);
        }

        if (argc > 3) {                         /* VTDs expression */
                CMATRIX *svec, *Dmat, *Tmat, *ivec;
                COLOR   tLamb;
                                                /* get sky vector */
                svec = cm_load(argv[4], 0, 1, DTascii);
                                                /* load BSDF */
                Tmat = cm_loadBSDF(argv[2], tLamb);
                                                /* load Daylight matrix */
                Dmat = cm_load(argv[3], Tmat==NULL ? 0 : Tmat->ncols,
                                        svec->nrows, DTfromHeader);
                                                /* multiply vector through */
                ivec = cm_multiply(Dmat, svec);
                cm_free(Dmat); cm_free(svec);
                if (Tmat == NULL) {             /* diffuse only */
                        cvec = cm_scale(ivec, tLamb);
                } else {                        /* else apply BTDF matrix */
                        cvec = cm_multiply(Tmat, ivec);
                        cm_free(Tmat); 
                }
                cm_free(ivec);
        } else {                                /* else just use sky vector */
                cvec = cm_load(argv[2], 0, 1, DTascii);
        }

        if (hasNumberFormat(argv[1])) {         /* generating image */
                SET_FILE_BINARY(stdout);
                newheader("RADIANCE", stdout);
                printargs(argc, argv, stdout);
                fputnow(stdout);
                if (!sum_images(argv[1], cvec, stdout))
                        return(1);
        } else {                                /* generating vector */
                CMATRIX *Vmat = cm_load(argv[1], 0, cvec->nrows, DTfromHeader);
                CMATRIX *rvec = cm_multiply(Vmat, cvec);
                cm_free(Vmat);
                cm_print(rvec, stdout);
                cm_free(rvec);
        }
        cm_free(cvec);                          /* final clean-up */
        return(0);
}
Revision:	2.22
Committed:	Tue Oct 23 22:24:09 2012 UTC (13 years ago) by greg
Content type:	text/plain
Branch:	MAIN
Changes since 2.21:	+70 -4 lines
Log Message:	Fixed reciprocity calculation
#	User	Rev	Content
1	greg	2.1	#ifndef lint
2	greg	2.22	static const char RCSid[] = "$Id: dctimestep.c,v 2.21 2012/10/16 15:53:04 greg Exp $";
3	greg	2.1	#endif
4			/*
5			* Compute time-step result using Daylight Coefficient method.
6			*
7			* G. Ward
8			*/
9
10			#include <ctype.h>
11			#include "standard.h"
12			#include "platform.h"
13	greg	2.15	#include "paths.h"
14	greg	2.1	#include "color.h"
15			#include "resolu.h"
16			#include "bsdf.h"
17	greg	2.15	#include "bsdf_m.h"
18	greg	2.1
19			char progname; / global argv[0] */
20
21	greg	2.2	/* Data types for file loading */
22	greg	2.1	enum {DTfromHeader, DTascii, DTfloat, DTdouble, DTrgbe, DTxyze};
23
24			/* A color coefficient matrix -- vectors have ncols==1 */
25			typedef struct {
26			int nrows, ncols;
27			COLORV cmem[3]; /* extends struct */
28			} CMATRIX;
29
30			#define COLSPEC (sizeof(COLORV)==sizeof(float) ? "%f %f %f" : "%lf %lf %lf")
31
32			#define cm_lval(cm,r,c) ((cm)->cmem + 3((r)(cm)->ncols + (c)))
33
34			#define cv_lval(cm,i) ((cm)->cmem + 3*(i))
35
36			/* Allocate a color coefficient matrix */
37			static CMATRIX *
38			cm_alloc(int nrows, int ncols)
39			{
40			CMATRIX *cm;
41
42			if ((nrows <= 0) \| (ncols <= 0))
43	greg	2.10	error(USER, "attempt to create empty matrix");
44	greg	2.1	cm = (CMATRIX *)malloc(sizeof(CMATRIX) +
45			3sizeof(COLORV)(nrows*ncols - 1));
46			if (cm == NULL)
47			error(SYSTEM, "out of memory in cm_alloc()");
48			cm->nrows = nrows;
49			cm->ncols = ncols;
50			return(cm);
51			}
52
53			#define cm_free(cm) free(cm)
54
55			/* Resize color coefficient matrix */
56			static CMATRIX *
57			cm_resize(CMATRIX *cm, int nrows)
58			{
59			if (nrows == cm->nrows)
60			return(cm);
61			if (nrows <= 0) {
62			cm_free(cm);
63			return(NULL);
64			}
65			cm = (CMATRIX *)realloc(cm, sizeof(CMATRIX) +
66			3sizeof(COLORV)(nrows*cm->ncols - 1));
67			if (cm == NULL)
68			error(SYSTEM, "out of memory in cm_resize()");
69			cm->nrows = nrows;
70			return(cm);
71			}
72
73			/* Load header to obtain data type */
74			static int
75			getDT(char s, void p)
76			{
77			char fmt[32];
78
79			if (formatval(fmt, s)) {
80			if (!strcmp(fmt, "ascii"))
81			((int )p) = DTascii;
82			else if (!strcmp(fmt, "float"))
83			((int )p) = DTfloat;
84			else if (!strcmp(fmt, "double"))
85			((int )p) = DTdouble;
86			else if (!strcmp(fmt, COLRFMT))
87			((int )p) = DTrgbe;
88			else if (!strcmp(fmt, CIEFMT))
89			((int )p) = DTxyze;
90			}
91			return(0);
92			}
93
94			static int
95			getDTfromHeader(FILE *fp)
96			{
97			int dt = DTfromHeader;
98
99			if (getheader(fp, getDT, &dt) < 0)
100			error(SYSTEM, "header read error");
101			if (dt == DTfromHeader)
102			error(USER, "missing data format in header");
103			return(dt);
104			}
105
106			/* Allocate and load a matrix from the given file (or stdin if NULL) */
107			static CMATRIX *
108			cm_load(const char *fname, int nrows, int ncols, int dtype)
109			{
110			CMATRIX *cm;
111			FILE *fp = stdin;
112
113	greg	2.12	if (ncols <= 0)
114			error(USER, "Non-positive number of columns");
115	greg	2.1	if (fname == NULL)
116			fname = "<stdin>";
117			else if ((fp = fopen(fname, "r")) == NULL) {
118			sprintf(errmsg, "cannot open file '%s'", fname);
119			error(SYSTEM, errmsg);
120			}
121			if (dtype != DTascii)
122			SET_FILE_BINARY(fp);
123			if (dtype == DTfromHeader)
124			dtype = getDTfromHeader(fp);
125			switch (dtype) {
126			case DTascii:
127			case DTfloat:
128			case DTdouble:
129			break;
130			default:
131			error(USER, "unexpected data type in cm_load()");
132			}
133			if (nrows <= 0) { /* don't know length? */
134			int guessrows = 147; /* usually big enough */
135			if ((dtype != DTascii) & (fp != stdin)) {
136			long startpos = ftell(fp);
137			if (fseek(fp, 0L, SEEK_END) == 0) {
138			long endpos = ftell(fp);
139			long elemsiz = 3*(dtype==DTfloat ?
140			sizeof(float) : sizeof(double));
141	greg	2.2
142			if ((endpos - startpos) % (ncols*elemsiz)) {
143			sprintf(errmsg,
144			"improper length for binary file '%s'",
145			fname);
146			error(USER, errmsg);
147			}
148			guessrows = (endpos - startpos)/(ncols*elemsiz);
149	greg	2.1	if (fseek(fp, startpos, SEEK_SET) < 0) {
150			sprintf(errmsg,
151			"fseek() error on file '%s'",
152			fname);
153			error(SYSTEM, errmsg);
154			}
155	greg	2.2	nrows = guessrows; /* we're confident */
156	greg	2.1	}
157			}
158			cm = cm_alloc(guessrows, ncols);
159			} else
160			cm = cm_alloc(nrows, ncols);
161			if (cm == NULL)
162			return(NULL);
163			if (dtype == DTascii) { /* read text file */
164			int maxrow = (nrows > 0 ? nrows : 32000);
165			int r, c;
166			for (r = 0; r < maxrow; r++) {
167	greg	2.6	if (r >= cm->nrows) /* need more space? */
168	greg	2.1	cm = cm_resize(cm, 2*cm->nrows);
169			for (c = 0; c < ncols; c++) {
170			COLORV *cv = cm_lval(cm,r,c);
171			if (fscanf(fp, COLSPEC, cv, cv+1, cv+2) != 3)
172	greg	2.6	if ((nrows <= 0) & (r > 0) & !c) {
173	greg	2.1	cm = cm_resize(cm, maxrow=r);
174			break;
175			} else
176			goto EOFerror;
177			}
178			}
179			while ((c = getc(fp)) != EOF)
180			if (!isspace(c)) {
181			sprintf(errmsg,
182			"unexpected data at end of ascii file %s",
183			fname);
184			error(WARNING, errmsg);
185			break;
186			}
187			} else { /* read binary file */
188			if (sizeof(COLORV) == (dtype==DTfloat ? sizeof(float) :
189			sizeof(double))) {
190			int nread = 0;
191			do { /* read all we can */
192			nread += fread(cm->cmem + 3*nread,
193			3*sizeof(COLORV),
194			cm->nrows*cm->ncols - nread,
195			fp);
196			if (nrows <= 0) { /* unknown length */
197			if (nread == cm->nrows*cm->ncols)
198			/* need more space? */
199			cm = cm_resize(cm, 2*cm->nrows);
200	greg	2.6	else if (nread && !(nread % cm->ncols))
201	greg	2.1	/* seem to be done */
202			cm = cm_resize(cm, nread/cm->ncols);
203			else /* ended mid-row */
204			goto EOFerror;
205			} else if (nread < cm->nrows*cm->ncols)
206			goto EOFerror;
207			} while (nread < cm->nrows*cm->ncols);
208
209			} else if (dtype == DTdouble) {
210			double dc[3]; /* load from double */
211			COLORV *cvp = cm->cmem;
212			int n = nrows*ncols;
213
214			if (n <= 0)
215			goto not_handled;
216			while (n--) {
217			if (fread(dc, sizeof(double), 3, fp) != 3)
218			goto EOFerror;
219			copycolor(cvp, dc);
220			cvp += 3;
221			}
222			} else /* dtype == DTfloat */ {
223			float fc[3]; /* load from float */
224			COLORV *cvp = cm->cmem;
225			int n = nrows*ncols;
226
227			if (n <= 0)
228			goto not_handled;
229			while (n--) {
230			if (fread(fc, sizeof(float), 3, fp) != 3)
231			goto EOFerror;
232			copycolor(cvp, fc);
233			cvp += 3;
234			}
235			}
236			if (getc(fp) != EOF) {
237			sprintf(errmsg,
238			"unexpected data at end of binary file %s",
239			fname);
240			error(WARNING, errmsg);
241			}
242			}
243			if (fp != stdin)
244			fclose(fp);
245			return(cm);
246			EOFerror:
247			sprintf(errmsg, "unexpected EOF reading %s",
248			fname);
249			error(USER, errmsg);
250			not_handled:
251			error(INTERNAL, "unhandled data size or length in cm_load()");
252			return(NULL); /* gratis return */
253			}
254
255	greg	2.20	/* Scale a matrix by a single value */
256			static CMATRIX *
257			cm_scale(const CMATRIX *cm1, const COLOR sca)
258			{
259			CMATRIX *cmr;
260			int dr, dc;
261
262			cmr = cm_alloc(cm1->nrows, cm1->ncols);
263			if (cmr == NULL)
264			return(NULL);
265			for (dr = 0; dr < cmr->nrows; dr++)
266			for (dc = 0; dc < cmr->ncols; dc++) {
267			const COLORV *sp = cm_lval(cm1,dr,dc);
268			COLORV *dp = cm_lval(cmr,dr,dc);
269			dp[0] = sp[0] * sca[0];
270			dp[1] = sp[1] * sca[1];
271			dp[2] = sp[2] * sca[2];
272			}
273			return(cmr);
274			}
275
276			/* Multiply two matrices (or a matrix and a vector) and allocate the result */
277	greg	2.1	static CMATRIX *
278			cm_multiply(const CMATRIX cm1, const CMATRIX cm2)
279			{
280			CMATRIX *cmr;
281			int dr, dc, i;
282
283			if ((cm1->ncols <= 0) \| (cm1->ncols != cm2->nrows))
284			error(INTERNAL, "matrix dimension mismatch in cm_multiply()");
285			cmr = cm_alloc(cm1->nrows, cm2->ncols);
286			if (cmr == NULL)
287			return(NULL);
288			for (dr = 0; dr < cmr->nrows; dr++)
289			for (dc = 0; dc < cmr->ncols; dc++) {
290			COLORV *dp = cm_lval(cmr,dr,dc);
291			dp[0] = dp[1] = dp[2] = 0;
292			for (i = 0; i < cm1->ncols; i++) {
293			const COLORV *cp1 = cm_lval(cm1,dr,i);
294			const COLORV *cp2 = cm_lval(cm2,i,dc);
295			dp[0] += cp1[0] * cp2[0];
296			dp[1] += cp1[1] * cp2[1];
297			dp[2] += cp1[2] * cp2[2];
298			}
299			}
300			return(cmr);
301			}
302
303			/* print out matrix as ASCII text -- no header */
304			static void
305			cm_print(const CMATRIX cm, FILE fp)
306			{
307			int r, c;
308			const COLORV *mp = cm->cmem;
309
310			for (r = 0; r < cm->nrows; r++) {
311			for (c = 0; c < cm->ncols; c++, mp += 3)
312			fprintf(fp, "\t%.6e %.6e %.6e", mp[0], mp[1], mp[2]);
313			fputc('\n', fp);
314			}
315			}
316
317	greg	2.15	/* Convert a BSDF to our matrix representation */
318	greg	2.1	static CMATRIX *
319	greg	2.15	cm_bsdf(const COLOR bsdfLamb, const COLOR specCol, const SDMat *bsdf)
320	greg	2.1	{
321	greg	2.16	CMATRIX *cm = cm_alloc(bsdf->nout, bsdf->ninc);
322	greg	2.3	int nbadohm = 0;
323			int nneg = 0;
324	greg	2.1	int r, c;
325	greg	2.22	/* loop over incident angles */
326	greg	2.16	for (c = 0; c < cm->ncols; c++) {
327	greg	2.17	const double dom = mBSDF_incohm(bsdf,c);
328			/* projected solid angle */
329	greg	2.16	nbadohm += (dom <= 0);
330
331			for (r = 0; r < cm->nrows; r++) {
332			float f = mBSDF_value(bsdf,c,r);
333			COLORV *mp = cm_lval(cm,r,c);
334			/* check BSDF value */
335			if ((f <= 0) \| (dom <= 0)) {
336			nneg += (f < -FTINY);
337			f = .0f;
338	greg	2.3	}
339	greg	2.16	copycolor(mp, specCol);
340			scalecolor(mp, f);
341			addcolor(mp, bsdfLamb);
342			scalecolor(mp, dom);
343	greg	2.3	}
344	greg	2.7	}
345	greg	2.15	if (nneg \| nbadohm) {
346	greg	2.3	sprintf(errmsg,
347	greg	2.4	"BTDF has %d negatives and %d bad incoming solid angles",
348			nneg, nbadohm);
349	greg	2.3	error(WARNING, errmsg);
350			}
351	greg	2.1	return(cm);
352			}
353
354	greg	2.22	/* Convert between input and output indices for reciprocity */
355			static int
356			recip_out_from_in(const SDMat *bsdf, int in_recip)
357			{
358			FVECT v;
359
360			if (!mBSDF_incvec(v, bsdf, in_recip+.5))
361			return(in_recip); /* XXX should be error! */
362			v[2] = -v[2];
363			return(mBSDF_outndx(bsdf, v));
364			}
365
366			/* Convert between output and input indices for reciprocity */
367			static int
368			recip_in_from_out(const SDMat *bsdf, int out_recip)
369			{
370			FVECT v;
371
372			if (!mBSDF_outvec(v, bsdf, out_recip+.5))
373			return(out_recip); /* XXX should be error! */
374			v[2] = -v[2];
375			return(mBSDF_incndx(bsdf, v));
376			}
377
378			/* Convert a BSDF to our matrix representation, applying reciprocity */
379			static CMATRIX *
380			cm_bsdf_recip(const COLOR bsdfLamb, const COLOR specCol, const SDMat *bsdf)
381			{
382			CMATRIX *cm = cm_alloc(bsdf->ninc, bsdf->nout);
383			int nbadohm = 0;
384			int nneg = 0;
385			int r, c;
386			/* loop over incident angles */
387			for (c = 0; c < cm->ncols; c++) {
388			const int ro = recip_out_from_in(bsdf,c);
389			const double dom = mBSDF_outohm(bsdf,ro);
390			/* projected solid angle */
391			nbadohm += (dom <= 0);
392
393			for (r = 0; r < cm->nrows; r++) {
394			const int ri = recip_in_from_out(bsdf,r);
395			float f = mBSDF_value(bsdf,ri,ro);
396			COLORV *mp = cm_lval(cm,r,c);
397			/* check BSDF value */
398			if ((f <= 0) \| (dom <= 0)) {
399			nneg += (f < -FTINY);
400			f = .0f;
401			}
402			copycolor(mp, specCol);
403			scalecolor(mp, f);
404			addcolor(mp, bsdfLamb);
405			scalecolor(mp, dom);
406			}
407			}
408			if (nneg \| nbadohm) {
409			sprintf(errmsg,
410			"BTDF has %d negatives and %d bad incoming solid angles",
411			nneg, nbadohm);
412			error(WARNING, errmsg);
413			}
414			return(cm);
415			}
416
417	greg	2.15	/* Load and convert a matrix BSDF from the given XML file */
418			static CMATRIX *
419	greg	2.20	cm_loadBSDF(char *fname, COLOR cLamb)
420	greg	2.15	{
421	greg	2.21	CMATRIX *Tmat;
422			char *fpath;
423	greg	2.22	int recip;
424	greg	2.21	SDError ec;
425			SDData myBSDF;
426			SDSpectralDF *tdf;
427			COLOR bsdfLamb, specCol;
428	greg	2.15	/* find path to BSDF file */
429			fpath = getpath(fname, getrlibpath(), R_OK);
430			if (fpath == NULL) {
431			sprintf(errmsg, "cannot find BSDF file '%s'", fname);
432			error(USER, errmsg);
433			}
434	greg	2.16	SDclearBSDF(&myBSDF, fname); /* load XML and check type */
435	greg	2.15	ec = SDloadFile(&myBSDF, fpath);
436			if (ec)
437			error(USER, transSDError(ec));
438	greg	2.20	ccy2rgb(&myBSDF.tLamb.spec, myBSDF.tLamb.cieY/PI, bsdfLamb);
439	greg	2.22	recip = (myBSDF.tf == NULL);
440			tdf = recip ? myBSDF.tb : myBSDF.tf;
441	greg	2.21	if (tdf == NULL) { /* no non-Lambertian transmission? */
442	greg	2.20	if (cLamb != NULL)
443			copycolor(cLamb, bsdfLamb);
444			SDfreeBSDF(&myBSDF);
445			return(NULL);
446			}
447	greg	2.21	if (tdf->ncomp != 1 \|\| tdf->comp[0].func != &SDhandleMtx) {
448	greg	2.15	sprintf(errmsg, "unsupported BSDF '%s'", fpath);
449			error(USER, errmsg);
450			}
451			/* convert BTDF to matrix */
452	greg	2.21	ccy2rgb(&tdf->comp[0].cspec[0], 1., specCol);
453	greg	2.22	Tmat = recip ? cm_bsdf_recip(bsdfLamb, specCol, (SDMat *)tdf->comp[0].dist)
454			: cm_bsdf(bsdfLamb, specCol, (SDMat *)tdf->comp[0].dist);
455	greg	2.20	if (cLamb != NULL) /* Lambertian is included */
456			setcolor(cLamb, .0, .0, .0);
457	greg	2.15	/* free BSDF and return */
458			SDfreeBSDF(&myBSDF);
459			return(Tmat);
460			}
461
462	greg	2.1	/* Sum together a set of images and write result to stdout */
463			static int
464	greg	2.13	sum_images(const char fspec, const CMATRIX cv, FILE *fout)
465	greg	2.1	{
466			int myDT = DTfromHeader;
467			CMATRIX *pmat;
468			COLOR *scanline;
469			int myXR, myYR;
470			int i, y;
471
472			if (cv->ncols != 1)
473			error(INTERNAL, "expected vector in sum_images()");
474			for (i = 0; i < cv->nrows; i++) {
475			const COLORV *scv = cv_lval(cv,i);
476			char fname[1024];
477			FILE *fp;
478			int dt, xr, yr;
479			COLORV *psp;
480	greg	2.14	/* check for zero */
481	greg	2.19	if ((scv[RED] == 0) & (scv[GRN] == 0) & (scv[BLU] == 0) &&
482			(myDT != DTfromHeader) \| (i < cv->nrows-1))
483	greg	2.14	continue;
484	greg	2.1	/* open next picture */
485			sprintf(fname, fspec, i);
486			if ((fp = fopen(fname, "r")) == NULL) {
487			sprintf(errmsg, "cannot open picture '%s'", fname);
488			error(SYSTEM, errmsg);
489			}
490			SET_FILE_BINARY(fp);
491			dt = getDTfromHeader(fp);
492			if ((dt != DTrgbe) & (dt != DTxyze) \|\|
493			!fscnresolu(&xr, &yr, fp)) {
494			sprintf(errmsg, "file '%s' not a picture", fname);
495			error(USER, errmsg);
496			}
497			if (myDT == DTfromHeader) { /* on first one */
498			myDT = dt;
499			myXR = xr; myYR = yr;
500			scanline = (COLOR )malloc(sizeof(COLOR)myXR);
501			if (scanline == NULL)
502			error(SYSTEM, "out of memory in sum_images()");
503			pmat = cm_alloc(myYR, myXR);
504			memset(pmat->cmem, 0, sizeof(COLOR)myXRmyYR);
505	greg	2.2	/* finish header */
506	greg	2.13	fputformat(myDT==DTrgbe ? COLRFMT : CIEFMT, fout);
507			fputc('\n', fout);
508			fprtresolu(myXR, myYR, fout);
509			fflush(fout);
510	greg	2.1	} else if ((dt != myDT) \| (xr != myXR) \| (yr != myYR)) {
511			sprintf(errmsg, "picture '%s' format/size mismatch",
512			fname);
513			error(USER, errmsg);
514			}
515			psp = pmat->cmem;
516			for (y = 0; y < yr; y++) { /* read it in */
517			int x;
518			if (freadscan(scanline, xr, fp) < 0) {
519			sprintf(errmsg, "error reading picture '%s'",
520			fname);
521			error(SYSTEM, errmsg);
522			}
523			/* sum in scanline */
524			for (x = 0; x < xr; x++, psp += 3) {
525			multcolor(scanline[x], scv);
526			addcolor(psp, scanline[x]);
527			}
528			}
529			fclose(fp); /* done this picture */
530			}
531			free(scanline);
532			/* write scanlines */
533			for (y = 0; y < myYR; y++)
534	greg	2.13	if (fwritescan((COLOR *)cm_lval(pmat, y, 0), myXR, fout) < 0)
535	greg	2.1	return(0);
536			cm_free(pmat); /* all done */
537	greg	2.13	return(fflush(fout) == 0);
538	greg	2.1	}
539
540	greg	2.11	/* check to see if a string contains a %d or %o specification */
541			static int
542			hasNumberFormat(const char *s)
543	greg	2.1	{
544	greg	2.18	while (*s) {
545			while (*s != '%')
546			if (!*s++)
547			return(0);
548			if (++s == '%') { / ignore "%%" */
549			++s;
550			continue;
551			}
552			while (isdigit(s)) / field length */
553			++s;
554			/* field we'll use? */
555			if ((s == 'd') \| (s == 'i') \| (*s == 'o') \|
556			(s == 'x') \| (s == 'X'))
557			return(1);
558			}
559			return(0); /* didn't find one */
560	greg	2.1	}
561
562			int
563			main(int argc, char *argv[])
564			{
565	greg	2.20	CMATRIX cvec; / component vector result */
566	greg	2.1
567			progname = argv[0];
568
569	greg	2.12	if ((argc < 2) \| (argc > 5)) {
570			fprintf(stderr, "Usage: %s DCspec [tregvec]\n", progname);
571			fprintf(stderr, " or: %s Vspec Tbsdf.xml Dmat.dat [tregvec]\n",
572			progname);
573	greg	2.1	return(1);
574			}
575	greg	2.12
576	greg	2.13	if (argc > 3) { /* VTDs expression */
577	greg	2.12	CMATRIX svec, Dmat, Tmat, ivec;
578	greg	2.20	COLOR tLamb;
579	greg	2.12	/* get sky vector */
580			svec = cm_load(argv[4], 0, 1, DTascii);
581			/* load BSDF */
582	greg	2.20	Tmat = cm_loadBSDF(argv[2], tLamb);
583	greg	2.5	/* load Daylight matrix */
584	greg	2.20	Dmat = cm_load(argv[3], Tmat==NULL ? 0 : Tmat->ncols,
585			svec->nrows, DTfromHeader);
586	greg	2.1	/* multiply vector through */
587	greg	2.12	ivec = cm_multiply(Dmat, svec);
588			cm_free(Dmat); cm_free(svec);
589	greg	2.20	if (Tmat == NULL) { /* diffuse only */
590			cvec = cm_scale(ivec, tLamb);
591			} else { /* else apply BTDF matrix */
592			cvec = cm_multiply(Tmat, ivec);
593			cm_free(Tmat);
594			}
595			cm_free(ivec);
596	greg	2.12	} else { /* else just use sky vector */
597			cvec = cm_load(argv[2], 0, 1, DTascii);
598			}
599
600	greg	2.11	if (hasNumberFormat(argv[1])) { /* generating image */
601	greg	2.1	SET_FILE_BINARY(stdout);
602			newheader("RADIANCE", stdout);
603			printargs(argc, argv, stdout);
604			fputnow(stdout);
605	greg	2.12	if (!sum_images(argv[1], cvec, stdout))
606	greg	2.1	return(1);
607			} else { /* generating vector */
608			CMATRIX *Vmat = cm_load(argv[1], 0, cvec->nrows, DTfromHeader);
609			CMATRIX *rvec = cm_multiply(Vmat, cvec);
610			cm_free(Vmat);
611			cm_print(rvec, stdout);
612			cm_free(rvec);
613			}
614			cm_free(cvec); /* final clean-up */
615			return(0);
616			}