src/px/pinterp.c

/* Copyright (c) 1991 Regents of the University of California */

#ifndef lint
static char SCCSid[] = "$SunId$ LBL";
#endif

/*
 * Interpolate and extrapolate pictures with different view parameters.
 *
 *      Greg Ward       09Dec89
 */

#include "standard.h"

#include <ctype.h>

#include "view.h"

#include "color.h"

#include "resolu.h"

#ifndef BSD
#define vfork           fork
#endif

#define pscan(y)        (ourpict+(y)*hresolu)
#define zscan(y)        (ourzbuf+(y)*hresolu)

#define F_FORE          1               /* fill foreground */
#define F_BACK          2               /* fill background */

#define PACKSIZ         256             /* max. calculation packet size */

#define RTCOM           "rtrace -h- -ovl -fff "

#define ABS(x)          ((x)>0?(x):-(x))

struct position {int x,y; float z;};

VIEW    ourview = STDVIEW;              /* desired view */
int     hresolu = 512;                  /* horizontal resolution */
int     vresolu = 512;                  /* vertical resolution */
double  pixaspect = 1.0;                /* pixel aspect ratio */

double  zeps = .02;                     /* allowed z epsilon */

COLR    *ourpict;                       /* output picture */
float   *ourzbuf;                       /* corresponding z-buffer */

char    *progname;

int     fillo = F_FORE|F_BACK;          /* selected fill options */
int     fillsamp = 0;                   /* sample separation (0 == inf) */
extern int      backfill(), rcalfill(); /* fill functions */
int     (*fillfunc)() = backfill;       /* selected fill function */
COLR    backcolr = BLKCOLR;             /* background color */
double  backz = 0.0;                    /* background z value */
int     normdist = 1;                   /* normalized distance? */
double  ourexp = -1;                    /* output picture exposure */

VIEW    theirview = STDVIEW;            /* input view */
int     gotview;                        /* got input view? */
int     wrongformat = 0;                /* input in another format? */
RESOLU  tresolu;                        /* input resolution */
double  theirexp;                       /* input picture exposure */
double  theirs2ours[4][4];              /* transformation matrix */
int     hasmatrix = 0;                  /* has transformation matrix */

int     PDesc[3] = {-1,-1,-1};          /* rtrace process descriptor */
#define childpid        (PDesc[2])
unsigned short  queue[PACKSIZ][2];      /* pending pixels */
int     packsiz;                        /* actual packet size */
int     queuesiz;                       /* number of pixels pending */


main(argc, argv)                        /* interpolate pictures */
int     argc;
char    *argv[];
{
#define  check(ol,al)           if (argv[i][ol] || \
                                badarg(argc-i-1,argv+i+1,al)) \
                                goto badopt
        int     gotvfile = 0;
        char    *zfile = NULL;
        char    *err;
        int     i, rval;

        progname = argv[0];

        for (i = 1; i < argc && argv[i][0] == '-'; i++) {
                rval = getviewopt(&ourview, argc-i, argv+i);
                if (rval >= 0) {
                        i += rval;
                        continue;
                }
                switch (argv[i][1]) {
                case 't':                               /* threshold */
                        check(2,"f");
                        zeps = atof(argv[++i]);
                        break;
                case 'n':                               /* dist. normalized? */
                        check(2,NULL);
                        normdist = !normdist;
                        break;
                case 'f':                               /* fill type */
                        switch (argv[i][2]) {
                        case '0':                               /* none */
                                check(3,NULL);
                                fillo = 0;
                                break;
                        case 'f':                               /* foreground */
                                check(3,NULL);
                                fillo = F_FORE;
                                break;
                        case 'b':                               /* background */
                                check(3,NULL);
                                fillo = F_BACK;
                                break;
                        case 'a':                               /* all */
                                check(3,NULL);
                                fillo = F_FORE|F_BACK;
                                break;
                        case 's':                               /* sample */
                                check(3,"i");
                                fillsamp = atoi(argv[++i]);
                                break;
                        case 'c':                               /* color */
                                check(3,"fff");
                                fillfunc = backfill;
                                setcolr(backcolr, atof(argv[i+1]),
                                        atof(argv[i+2]), atof(argv[i+3]));
                                i += 3;
                                break;
                        case 'z':                               /* z value */
                                check(3,"f");
                                fillfunc = backfill;
                                backz = atof(argv[++i]);
                                break;
                        case 'r':                               /* rtrace */
                                check(3,"s");
                                fillfunc = rcalfill;
                                calstart(RTCOM, argv[++i]);
                                break;
                        default:
                                goto badopt;
                        }
                        break;
                case 'z':                               /* z file */
                        check(2,"s");
                        zfile = argv[++i];
                        break;
                case 'x':                               /* x resolution */
                        check(2,"i");
                        hresolu = atoi(argv[++i]);
                        break;
                case 'y':                               /* y resolution */
                        check(2,"i");
                        vresolu = atoi(argv[++i]);
                        break;
                case 'p':                               /* pixel aspect */
                        if (argv[i][2] != 'a')
                                goto badopt;
                        check(3,"f");
                        pixaspect = atof(argv[++i]);
                        break;
                case 'v':                               /* view file */
                        if (argv[i][2] != 'f')
                                goto badopt;
                        check(3,"s");
                        gotvfile = viewfile(argv[++i], &ourview, 0, 0);
                        if (gotvfile < 0) {
                                perror(argv[i]);
                                exit(1);
                        } else if (gotvfile == 0) {
                                fprintf(stderr, "%s: bad view file\n",
                                                argv[i]);
                                exit(1);
                        }
                        break;
                default:
                badopt:
                        fprintf(stderr, "%s: command line error at '%s'\n",
                                        progname, argv[i]);
                        goto userr;
                }
        }
                                                /* check arguments */
        if ((argc-i)%2)
                goto userr;
        if (fillsamp == 1)
                fillo &= ~F_BACK;
                                                /* set view */
        if (err = setview(&ourview)) {
                fprintf(stderr, "%s: %s\n", progname, err);
                exit(1);
        }
        normaspect(viewaspect(&ourview), &pixaspect, &hresolu, &vresolu);
                                                /* allocate frame */
        ourpict = (COLR *)bmalloc(hresolu*vresolu*sizeof(COLR));
        ourzbuf = (float *)bmalloc(hresolu*vresolu*sizeof(float));
        if (ourpict == NULL || ourzbuf == NULL)
                syserror();
        bzero((char *)ourzbuf, hresolu*vresolu*sizeof(float));
                                                        /* get input */
        for ( ; i < argc; i += 2)
                addpicture(argv[i], argv[i+1]);
                                                        /* fill in spaces */
        if (fillo&F_BACK)
                backpicture(fillfunc, fillsamp);
        else
                fillpicture(fillfunc);
                                                        /* close calculation */
        caldone();
                                                        /* add to header */
        printargs(argc, argv, stdout);
        if (gotvfile) {
                fputs(VIEWSTR, stdout);
                fprintview(&ourview, stdout);
                putc('\n', stdout);
        }
        if (pixaspect < .99 || pixaspect > 1.01)
                fputaspect(pixaspect, stdout);
        if (ourexp > 0 && (ourexp < .995 || ourexp > 1.005))
                fputexpos(ourexp, stdout);
        fputformat(COLRFMT, stdout);
        putc('\n', stdout);
                                                        /* write picture */
        writepicture();
                                                        /* write z file */
        if (zfile != NULL)
                writedistance(zfile);

        exit(0);
userr:
        fprintf(stderr,
        "Usage: %s [view opts][-t eps][-z zout][-fT][-n] pfile zspec ..\n",
                        progname);
        exit(1);
#undef check
}


headline(s)                             /* process header string */
char    *s;
{
        char    fmt[32];

        if (isformat(s)) {
                formatval(fmt, s);
                wrongformat = strcmp(fmt, COLRFMT);
                return;
        }
        putc('\t', stdout);
        fputs(s, stdout);

        if (isexpos(s)) {
                theirexp *= exposval(s);
                return;
        }
        if (isview(s) && sscanview(&theirview, s) > 0)
                gotview++;
}


addpicture(pfile, zspec)                /* add picture to output */
char    *pfile, *zspec;
{
        FILE    *pfp;
        int     zfd;
        char    *err;
        COLR    *scanin;
        float   *zin;
        struct position *plast;
        int     y;
                                        /* open picture file */
        if ((pfp = fopen(pfile, "r")) == NULL) {
                perror(pfile);
                exit(1);
        }
                                        /* get header with exposure and view */
        theirexp = 1.0;
        gotview = 0;
        printf("%s:\n", pfile);
        getheader(pfp, headline, NULL);
        if (wrongformat || !gotview || !fgetsresolu(&tresolu, pfp)) {
                fprintf(stderr, "%s: picture format error\n", pfile);
                exit(1);
        }
        if (ourexp <= 0)
                ourexp = theirexp;
        else if (ABS(theirexp-ourexp) > .01*ourexp)
                fprintf(stderr, "%s: different exposure (warning)\n", pfile);
        if (err = setview(&theirview)) {
                fprintf(stderr, "%s: %s\n", pfile, err);
                exit(1);
        }
                                        /* compute transformation */
        hasmatrix = pixform(theirs2ours, &theirview, &ourview);
                                        /* allocate scanlines */
        scanin = (COLR *)malloc(scanlen(&tresolu)*sizeof(COLR));
        zin = (float *)malloc(scanlen(&tresolu)*sizeof(float));
        plast = (struct position *)calloc(scanlen(&tresolu),
                        sizeof(struct position));
        if (scanin == NULL || zin == NULL || plast == NULL)
                syserror();
                                        /* get z specification or file */
        if ((zfd = open(zspec, O_RDONLY)) == -1) {
                double  zvalue;
                register int    x;
                if (!isfloat(zspec) || (zvalue = atof(zspec)) <= 0.0) {
                        perror(zspec);
                        exit(1);
                }
                for (x = scanlen(&tresolu); x-- > 0; )
                        zin[x] = zvalue;
        }
                                        /* load image */
        for (y = 0; y < numscans(&tresolu); y++) {
                if (freadcolrs(scanin, scanlen(&tresolu), pfp) < 0) {
                        fprintf(stderr, "%s: read error\n", pfile);
                        exit(1);
                }
                if (zfd != -1 && read(zfd,(char *)zin,
                                scanlen(&tresolu)*sizeof(float))
                                < scanlen(&tresolu)*sizeof(float)) {
                        fprintf(stderr, "%s: read error\n", zspec);
                        exit(1);
                }
                addscanline(y, scanin, zin, plast);
        }
                                        /* clean up */
        free((char *)scanin);
        free((char *)zin);
        free((char *)plast);
        fclose(pfp);
        if (zfd != -1)
                close(zfd);
}


pixform(xfmat, vw1, vw2)                /* compute view1 to view2 matrix */
register double xfmat[4][4];
register VIEW   *vw1, *vw2;
{
        double  m4t[4][4];

        if (vw1->type != VT_PER && vw1->type != VT_PAR)
                return(0);
        if (vw2->type != VT_PER && vw2->type != VT_PAR)
                return(0);
        setident4(xfmat);
        xfmat[0][0] = vw1->hvec[0];
        xfmat[0][1] = vw1->hvec[1];
        xfmat[0][2] = vw1->hvec[2];
        xfmat[1][0] = vw1->vvec[0];
        xfmat[1][1] = vw1->vvec[1];
        xfmat[1][2] = vw1->vvec[2];
        xfmat[2][0] = vw1->vdir[0];
        xfmat[2][1] = vw1->vdir[1];
        xfmat[2][2] = vw1->vdir[2];
        xfmat[3][0] = vw1->vp[0];
        xfmat[3][1] = vw1->vp[1];
        xfmat[3][2] = vw1->vp[2];
        setident4(m4t);
        m4t[0][0] = vw2->hvec[0]/vw2->hn2;
        m4t[1][0] = vw2->hvec[1]/vw2->hn2;
        m4t[2][0] = vw2->hvec[2]/vw2->hn2;
        m4t[3][0] = -DOT(vw2->vp,vw2->hvec)/vw2->hn2;
        m4t[0][1] = vw2->vvec[0]/vw2->vn2;
        m4t[1][1] = vw2->vvec[1]/vw2->vn2;
        m4t[2][1] = vw2->vvec[2]/vw2->vn2;
        m4t[3][1] = -DOT(vw2->vp,vw2->vvec)/vw2->vn2;
        m4t[0][2] = vw2->vdir[0];
        m4t[1][2] = vw2->vdir[1];
        m4t[2][2] = vw2->vdir[2];
        m4t[3][2] = -DOT(vw2->vp,vw2->vdir);
        multmat4(xfmat, xfmat, m4t);
        return(1);
}


addscanline(y, pline, zline, lasty)     /* add scanline to output */
int     y;
COLR    *pline;
float   *zline;
struct position *lasty;         /* input/output */
{
        FVECT   pos;
        struct position lastx, newpos;
        register int    x;

        lastx.z = 0;
        for (x = scanlen(&tresolu); x-- > 0; ) {
                pix2loc(pos, &tresolu, x, y);
                pos[2] = zline[x];
                if (movepixel(pos) < 0) {
                        lasty[x].z = lastx.z = 0;       /* mark invalid */
                        continue;
                }
                newpos.x = pos[0] * hresolu;
                newpos.y = pos[1] * vresolu;
                newpos.z = zline[x];
                                        /* add pixel to our image */
                if (pos[0] >= 0 && newpos.x < hresolu
                                && pos[1] >= 0 && newpos.y < vresolu) {
                        addpixel(&newpos, &lastx, &lasty[x], pline[x], pos[2]);
                        lasty[x].x = lastx.x = newpos.x;
                        lasty[x].y = lastx.y = newpos.y;
                        lasty[x].z = lastx.z = newpos.z;
                } else
                        lasty[x].z = lastx.z = 0;       /* mark invalid */
        }
}


addpixel(p0, p1, p2, pix, z)            /* fill in pixel parallelogram */
struct position *p0, *p1, *p2;
COLR    pix;
double  z;
{
        double  zt = 2.*zeps*p0->z;             /* threshold */
        int     s1x, s1y, s2x, s2y;             /* step sizes */
        int     l1, l2, c1, c2;                 /* side lengths and counters */
        int     p1isy;                          /* p0p1 along y? */
        int     x1, y1;                         /* p1 position */
        register int    x, y;                   /* final position */

                                        /* compute vector p0p1 */
        if (fillo&F_FORE && ABS(p1->z-p0->z) <= zt) {
                s1x = p1->x - p0->x;
                s1y = p1->y - p0->y;
                l1 = ABS(s1x);
                if (p1isy = (ABS(s1y) > l1))
                        l1 = ABS(s1y);
        } else {
                l1 = s1x = s1y = 1;
                p1isy = -1;
        }
                                        /* compute vector p0p2 */
        if (fillo&F_FORE && ABS(p2->z-p0->z) <= zt) {
                s2x = p2->x - p0->x;
                s2y = p2->y - p0->y;
                if (p1isy == 1)
                        l2 = ABS(s2x);
                else {
                        l2 = ABS(s2y);
                        if (p1isy != 0 && ABS(s2x) > l2)
                                l2 = ABS(s2x);
                }
        } else
                l2 = s2x = s2y = 1;
                                        /* fill the parallelogram */
        for (c1 = l1; c1-- > 0; ) {
                x1 = p0->x + c1*s1x/l1;
                y1 = p0->y + c1*s1y/l1;
                for (c2 = l2; c2-- > 0; ) {
                        x = x1 + c2*s2x/l2;
                        if (x < 0 || x >= hresolu)
                                continue;
                        y = y1 + c2*s2y/l2;
                        if (y < 0 || y >= vresolu)
                                continue;
                        if (zscan(y)[x] <= 0 || zscan(y)[x]-z
                                                > zeps*zscan(y)[x]) {
                                zscan(y)[x] = z;
                                copycolr(pscan(y)[x], pix);
                        }
                }
        }
}


movepixel(pos)                          /* reposition image point */
FVECT   pos;
{
        FVECT   pt, direc;
        
        if (pos[2] <= 0)                /* empty pixel */
                return(-1);
        if (hasmatrix) {
                pos[0] += theirview.hoff - .5;
                pos[1] += theirview.voff - .5;
                if (theirview.type == VT_PER) {
                        if (normdist)   /* adjust for eye-ray distance */
                                pos[2] /= sqrt( 1.
                                        + pos[0]*pos[0]*theirview.hn2
                                        + pos[1]*pos[1]*theirview.vn2 );
                        pos[0] *= pos[2];
                        pos[1] *= pos[2];
                }
                multp3(pos, pos, theirs2ours);
                if (pos[2] <= 0)
                        return(-1);
                if (ourview.type == VT_PER) {
                        pos[0] /= pos[2];
                        pos[1] /= pos[2];
                }
                pos[0] += .5 - ourview.hoff;
                pos[1] += .5 - ourview.voff;
                return(0);
        }
        if (viewray(pt, direc, &theirview, pos[0], pos[1]) < 0)
                return(-1);
        pt[0] += direc[0]*pos[2];
        pt[1] += direc[1]*pos[2];
        pt[2] += direc[2]*pos[2];
        viewloc(pos, &ourview, pt);
        if (pos[2] <= 0)
                return(-1);
        return(0);
}


backpicture(fill, samp)                 /* background fill algorithm */
int     (*fill)();
int     samp;
{
        int     *yback, xback;
        int     y;
        register int    x, i;
                                                        /* get back buffer */
        yback = (int *)malloc(hresolu*sizeof(int));
        if (yback == NULL)
                syserror();
        for (x = 0; x < hresolu; x++)
                yback[x] = -2;
        /*
         * Xback and yback are the pixel locations of suitable
         * background values in each direction.
         * A value of -2 means unassigned, and -1 means
         * that there is no suitable background in this direction.
         */
                                                        /* fill image */
        for (y = 0; y < vresolu; y++) {
                xback = -2;
                for (x = 0; x < hresolu; x++)
                        if (zscan(y)[x] <= 0) {         /* empty pixel */
                                /*
                                 * First, find background from above or below.
                                 * (farthest assigned pixel)
                                 */
                                if (yback[x] == -2) {
                                        for (i = y+1; i < vresolu; i++)
                                                if (zscan(i)[x] > 0)
                                                        break;
                                        if (i < vresolu
                                && (y <= 0 || zscan(y-1)[x] < zscan(i)[x]))
                                                yback[x] = i;
                                        else
                                                yback[x] = y-1;
                                }
                                /*
                                 * Next, find background from left or right.
                                 */
                                if (xback == -2) {
                                        for (i = x+1; i < hresolu; i++)
                                                if (zscan(y)[i] > 0)
                                                        break;
                                        if (i < hresolu
                                && (x <= 0 || zscan(y)[x-1] < zscan(y)[i]))
                                                xback = i;
                                        else
                                                xback = x-1;
                                }
                                /*
                                 * If we have no background for this pixel,
                                 * use the given fill function.
                                 */
                                if (xback < 0 && yback[x] < 0)
                                        goto fillit;
                                /*
                                 * Compare, and use the background that is
                                 * farther, unless one of them is next to us.
                                 * If the background is too distant, call
                                 * the fill function.
                                 */
                                if ( yback[x] < 0
                                        || (xback >= 0 && ABS(x-xback) <= 1)
                                        || ( ABS(y-yback[x]) > 1
                                                && zscan(yback[x])[x]
                                                < zscan(y)[xback] ) ) {
                                        if (samp > 0 && ABS(x-xback) >= samp)
                                                goto fillit;
                                        copycolr(pscan(y)[x],pscan(y)[xback]);
                                        zscan(y)[x] = zscan(y)[xback];
                                } else {
                                        if (samp > 0 && ABS(y-yback[x]) > samp)
                                                goto fillit;
                                        copycolr(pscan(y)[x],pscan(yback[x])[x]);
                                        zscan(y)[x] = zscan(yback[x])[x];
                                }
                                continue;
                        fillit:
                                (*fill)(x,y);
                                if (fill == rcalfill) {         /* use it */
                                        clearqueue();
                                        xback = x;
                                        yback[x] = y;
                                }
                        } else {                                /* full pixel */
                                yback[x] = -2;
                                xback = -2;
                        }
        }
        free((char *)yback);
}


fillpicture(fill)               /* paint in empty pixels using fill */
int     (*fill)();
{
        register int    x, y;

        for (y = 0; y < vresolu; y++)
                for (x = 0; x < hresolu; x++)
                        if (zscan(y)[x] <= 0)
                                (*fill)(x,y);
}


writepicture()                          /* write out picture */
{
        int     y;

        fprtresolu(hresolu, vresolu, stdout);
        for (y = vresolu-1; y >= 0; y--)
                if (fwritecolrs(pscan(y), hresolu, stdout) < 0)
                        syserror();
}


writedistance(fname)                    /* write out z file */
char    *fname;
{
        int     donorm = normdist && ourview.type == VT_PER;
        int     fd;
        int     y;
        float   *zout;

        if ((fd = open(fname, O_WRONLY|O_CREAT|O_TRUNC, 0666)) == -1) {
                perror(fname);
                exit(1);
        }
        if (donorm
        && (zout = (float *)malloc(hresolu*sizeof(float))) == NULL)
                syserror();
        for (y = vresolu-1; y >= 0; y--) {
                if (donorm) {
                        double  vx, yzn2;
                        register int    x;
                        yzn2 = (y+.5)/vresolu + ourview.voff - .5;
                        yzn2 = 1. + yzn2*yzn2*ourview.vn2;
                        for (x = 0; x < hresolu; x++) {
                                vx = (x+.5)/hresolu + ourview.hoff - .5;
                                zout[x] = zscan(y)[x]
                                        * sqrt(vx*vx*ourview.hn2 + yzn2);
                        }
                } else
                        zout = zscan(y);
                if (write(fd, (char *)zout, hresolu*sizeof(float))
                                < hresolu*sizeof(float)) {
                        perror(fname);
                        exit(1);
                }
        }
        if (donorm)
                free((char *)zout);
        close(fd);
}


isfloat(s)                              /* see if string is floating number */
register char   *s;
{
        for ( ; *s; s++)
                if ((*s < '0' || *s > '9') && *s != '.' && *s != '-'
                                && *s != 'e' && *s != 'E' && *s != '+')
                        return(0);
        return(1);
}


backfill(x, y)                          /* fill pixel with background */
int     x, y;
{
        register BYTE   *dest = pscan(y)[x];

        copycolr(dest, backcolr);
        zscan(y)[x] = backz;
}


calstart(prog, args)                    /* start fill calculation */
char    *prog, *args;
{
        char    combuf[512];
        char    *argv[64];
        int     rval;
        register char   **wp, *cp;

        if (childpid != -1) {
                fprintf(stderr, "%s: too many calculations\n", progname);
                exit(1);
        }
        strcpy(combuf, prog);
        strcat(combuf, args);
        cp = combuf;
        wp = argv;
        for ( ; ; ) {
                while (isspace(*cp)) cp++;
                if (!*cp) break;
                *wp++ = cp;
                while (!isspace(*cp))
                        if (!*cp++) goto done;
                *cp++ = '\0';
        }
done:
        *wp = NULL;
                                                /* start process */
        if ((rval = open_process(PDesc, argv)) < 0)
                syserror();
        if (rval == 0) {
                fprintf(stderr, "%s: command not found\n", argv[0]);
                exit(1);
        }
        packsiz = rval/(6*sizeof(float)) - 1;
        if (packsiz > PACKSIZ)
                packsiz = PACKSIZ;
        queuesiz = 0;
}


caldone()                               /* done with calculation */
{
        if (childpid == -1)
                return;
        clearqueue();
        close_process(PDesc);
        childpid = -1;
}


rcalfill(x, y)                          /* fill with ray-calculated pixel */
int     x, y;
{
        if (queuesiz >= packsiz)        /* flush queue if needed */
                clearqueue();
                                        /* add position to queue */
        queue[queuesiz][0] = x;
        queue[queuesiz][1] = y;
        queuesiz++;
}


clearqueue()                            /* process queue */
{
        FVECT   orig, dir;
        float   fbuf[6*(PACKSIZ+1)];
        register float  *fbp;
        register int    i;

        fbp = fbuf;
        for (i = 0; i < queuesiz; i++) {
                viewray(orig, dir, &ourview,
                                (queue[i][0]+.5)/hresolu,
                                (queue[i][1]+.5)/vresolu);
                *fbp++ = orig[0]; *fbp++ = orig[1]; *fbp++ = orig[2];
                *fbp++ = dir[0]; *fbp++ = dir[1]; *fbp++ = dir[2];
        }
                                        /* mark end and get results */
        bzero((char *)fbp, 6*sizeof(float));
        if (process(PDesc, fbuf, fbuf, 4*sizeof(float)*queuesiz,
                        6*sizeof(float)*(queuesiz+1)) !=
                        4*sizeof(float)*queuesiz) {
                fprintf(stderr, "%s: error reading from rtrace process\n",
                                progname);
                exit(1);
        }
        fbp = fbuf;
        for (i = 0; i < queuesiz; i++) {
                if (ourexp > 0 && ourexp != 1.0) {
                        fbp[0] *= ourexp;
                        fbp[1] *= ourexp;
                        fbp[2] *= ourexp;
                }
                setcolr(pscan(queue[i][1])[queue[i][0]],
                                fbp[0], fbp[1], fbp[2]);
                zscan(queue[i][1])[queue[i][0]] = fbp[3];
                fbp += 4;
        }
        queuesiz = 0;
}


syserror()                      /* report error and exit */
{
        perror(progname);
        exit(1);
}
Revision:	2.9
Committed:	Fri Oct 2 16:24:22 1992 UTC (31 years, 7 months ago) by greg
Content type:	text/plain
Branch:	MAIN
Changes since 2.8:	+0 -2 lines
Log Message:	Removed problematic math function declarations
#	Content
1	/* Copyright (c) 1991 Regents of the University of California */
2
3	#ifndef lint
4	static char SCCSid[] = "$SunId$ LBL";
5	#endif
6
7	/*
8	* Interpolate and extrapolate pictures with different view parameters.
9	*
10	* Greg Ward 09Dec89
11	*/
12
13	#include "standard.h"
14
15	#include <ctype.h>
16
17	#include "view.h"
18
19	#include "color.h"
20
21	#include "resolu.h"
22
23	#ifndef BSD
24	#define vfork fork
25	#endif
26
27	#define pscan(y) (ourpict+(y)*hresolu)
28	#define zscan(y) (ourzbuf+(y)*hresolu)
29
30	#define F_FORE 1 /* fill foreground */
31	#define F_BACK 2 /* fill background */
32
33	#define PACKSIZ 256 /* max. calculation packet size */
34
35	#define RTCOM "rtrace -h- -ovl -fff "
36
37	#define ABS(x) ((x)>0?(x):-(x))
38
39	struct position {int x,y; float z;};
40
41	VIEW ourview = STDVIEW; /* desired view */
42	int hresolu = 512; /* horizontal resolution */
43	int vresolu = 512; /* vertical resolution */
44	double pixaspect = 1.0; /* pixel aspect ratio */
45
46	double zeps = .02; /* allowed z epsilon */
47
48	COLR ourpict; / output picture */
49	float ourzbuf; / corresponding z-buffer */
50
51	char *progname;
52
53	int fillo = F_FORE\|F_BACK; /* selected fill options */
54	int fillsamp = 0; /* sample separation (0 == inf) */
55	extern int backfill(), rcalfill(); /* fill functions */
56	int (fillfunc)() = backfill; / selected fill function */
57	COLR backcolr = BLKCOLR; /* background color */
58	double backz = 0.0; /* background z value */
59	int normdist = 1; /* normalized distance? */
60	double ourexp = -1; /* output picture exposure */
61
62	VIEW theirview = STDVIEW; /* input view */
63	int gotview; /* got input view? */
64	int wrongformat = 0; /* input in another format? */
65	RESOLU tresolu; /* input resolution */
66	double theirexp; /* input picture exposure */
67	double theirs2ours[4][4]; /* transformation matrix */
68	int hasmatrix = 0; /* has transformation matrix */
69
70	int PDesc[3] = {-1,-1,-1}; /* rtrace process descriptor */
71	#define childpid (PDesc[2])
72	unsigned short queue[PACKSIZ][2]; /* pending pixels */
73	int packsiz; /* actual packet size */
74	int queuesiz; /* number of pixels pending */
75
76
77	main(argc, argv) /* interpolate pictures */
78	int argc;
79	char *argv[];
80	{
81	#define check(ol,al) if (argv[i][ol] \|\| \
82	badarg(argc-i-1,argv+i+1,al)) \
83	goto badopt
84	int gotvfile = 0;
85	char *zfile = NULL;
86	char *err;
87	int i, rval;
88
89	progname = argv[0];
90
91	for (i = 1; i < argc && argv[i][0] == '-'; i++) {
92	rval = getviewopt(&ourview, argc-i, argv+i);
93	if (rval >= 0) {
94	i += rval;
95	continue;
96	}
97	switch (argv[i][1]) {
98	case 't': /* threshold */
99	check(2,"f");
100	zeps = atof(argv[++i]);
101	break;
102	case 'n': /* dist. normalized? */
103	check(2,NULL);
104	normdist = !normdist;
105	break;
106	case 'f': /* fill type */
107	switch (argv[i][2]) {
108	case '0': /* none */
109	check(3,NULL);
110	fillo = 0;
111	break;
112	case 'f': /* foreground */
113	check(3,NULL);
114	fillo = F_FORE;
115	break;
116	case 'b': /* background */
117	check(3,NULL);
118	fillo = F_BACK;
119	break;
120	case 'a': /* all */
121	check(3,NULL);
122	fillo = F_FORE\|F_BACK;
123	break;
124	case 's': /* sample */
125	check(3,"i");
126	fillsamp = atoi(argv[++i]);
127	break;
128	case 'c': /* color */
129	check(3,"fff");
130	fillfunc = backfill;
131	setcolr(backcolr, atof(argv[i+1]),
132	atof(argv[i+2]), atof(argv[i+3]));
133	i += 3;
134	break;
135	case 'z': /* z value */
136	check(3,"f");
137	fillfunc = backfill;
138	backz = atof(argv[++i]);
139	break;
140	case 'r': /* rtrace */
141	check(3,"s");
142	fillfunc = rcalfill;
143	calstart(RTCOM, argv[++i]);
144	break;
145	default:
146	goto badopt;
147	}
148	break;
149	case 'z': /* z file */
150	check(2,"s");
151	zfile = argv[++i];
152	break;
153	case 'x': /* x resolution */
154	check(2,"i");
155	hresolu = atoi(argv[++i]);
156	break;
157	case 'y': /* y resolution */
158	check(2,"i");
159	vresolu = atoi(argv[++i]);
160	break;
161	case 'p': /* pixel aspect */
162	if (argv[i][2] != 'a')
163	goto badopt;
164	check(3,"f");
165	pixaspect = atof(argv[++i]);
166	break;
167	case 'v': /* view file */
168	if (argv[i][2] != 'f')
169	goto badopt;
170	check(3,"s");
171	gotvfile = viewfile(argv[++i], &ourview, 0, 0);
172	if (gotvfile < 0) {
173	perror(argv[i]);
174	exit(1);
175	} else if (gotvfile == 0) {
176	fprintf(stderr, "%s: bad view file\n",
177	argv[i]);
178	exit(1);
179	}
180	break;
181	default:
182	badopt:
183	fprintf(stderr, "%s: command line error at '%s'\n",
184	progname, argv[i]);
185	goto userr;
186	}
187	}
188	/* check arguments */
189	if ((argc-i)%2)
190	goto userr;
191	if (fillsamp == 1)
192	fillo &= ~F_BACK;
193	/* set view */
194	if (err = setview(&ourview)) {
195	fprintf(stderr, "%s: %s\n", progname, err);
196	exit(1);
197	}
198	normaspect(viewaspect(&ourview), &pixaspect, &hresolu, &vresolu);
199	/* allocate frame */
200	ourpict = (COLR )bmalloc(hresoluvresolu*sizeof(COLR));
201	ourzbuf = (float )bmalloc(hresoluvresolu*sizeof(float));
202	if (ourpict == NULL \|\| ourzbuf == NULL)
203	syserror();
204	bzero((char )ourzbuf, hresoluvresolu*sizeof(float));
205	/* get input */
206	for ( ; i < argc; i += 2)
207	addpicture(argv[i], argv[i+1]);
208	/* fill in spaces */
209	if (fillo&F_BACK)
210	backpicture(fillfunc, fillsamp);
211	else
212	fillpicture(fillfunc);
213	/* close calculation */
214	caldone();
215	/* add to header */
216	printargs(argc, argv, stdout);
217	if (gotvfile) {
218	fputs(VIEWSTR, stdout);
219	fprintview(&ourview, stdout);
220	putc('\n', stdout);
221	}
222	if (pixaspect < .99 \|\| pixaspect > 1.01)
223	fputaspect(pixaspect, stdout);
224	if (ourexp > 0 && (ourexp < .995 \|\| ourexp > 1.005))
225	fputexpos(ourexp, stdout);
226	fputformat(COLRFMT, stdout);
227	putc('\n', stdout);
228	/* write picture */
229	writepicture();
230	/* write z file */
231	if (zfile != NULL)
232	writedistance(zfile);
233
234	exit(0);
235	userr:
236	fprintf(stderr,
237	"Usage: %s [view opts][-t eps][-z zout][-fT][-n] pfile zspec ..\n",
238	progname);
239	exit(1);
240	#undef check
241	}
242
243
244	headline(s) /* process header string */
245	char *s;
246	{
247	char fmt[32];
248
249	if (isformat(s)) {
250	formatval(fmt, s);
251	wrongformat = strcmp(fmt, COLRFMT);
252	return;
253	}
254	putc('\t', stdout);
255	fputs(s, stdout);
256
257	if (isexpos(s)) {
258	theirexp *= exposval(s);
259	return;
260	}
261	if (isview(s) && sscanview(&theirview, s) > 0)
262	gotview++;
263	}
264
265
266	addpicture(pfile, zspec) /* add picture to output */
267	char pfile, zspec;
268	{
269	FILE *pfp;
270	int zfd;
271	char *err;
272	COLR *scanin;
273	float *zin;
274	struct position *plast;
275	int y;
276	/* open picture file */
277	if ((pfp = fopen(pfile, "r")) == NULL) {
278	perror(pfile);
279	exit(1);
280	}
281	/* get header with exposure and view */
282	theirexp = 1.0;
283	gotview = 0;
284	printf("%s:\n", pfile);
285	getheader(pfp, headline, NULL);
286	if (wrongformat \|\| !gotview \|\| !fgetsresolu(&tresolu, pfp)) {
287	fprintf(stderr, "%s: picture format error\n", pfile);
288	exit(1);
289	}
290	if (ourexp <= 0)
291	ourexp = theirexp;
292	else if (ABS(theirexp-ourexp) > .01*ourexp)
293	fprintf(stderr, "%s: different exposure (warning)\n", pfile);
294	if (err = setview(&theirview)) {
295	fprintf(stderr, "%s: %s\n", pfile, err);
296	exit(1);
297	}
298	/* compute transformation */
299	hasmatrix = pixform(theirs2ours, &theirview, &ourview);
300	/* allocate scanlines */
301	scanin = (COLR )malloc(scanlen(&tresolu)sizeof(COLR));
302	zin = (float )malloc(scanlen(&tresolu)sizeof(float));
303	plast = (struct position *)calloc(scanlen(&tresolu),
304	sizeof(struct position));
305	if (scanin == NULL \|\| zin == NULL \|\| plast == NULL)
306	syserror();
307	/* get z specification or file */
308	if ((zfd = open(zspec, O_RDONLY)) == -1) {
309	double zvalue;
310	register int x;
311	if (!isfloat(zspec) \|\| (zvalue = atof(zspec)) <= 0.0) {
312	perror(zspec);
313	exit(1);
314	}
315	for (x = scanlen(&tresolu); x-- > 0; )
316	zin[x] = zvalue;
317	}
318	/* load image */
319	for (y = 0; y < numscans(&tresolu); y++) {
320	if (freadcolrs(scanin, scanlen(&tresolu), pfp) < 0) {
321	fprintf(stderr, "%s: read error\n", pfile);
322	exit(1);
323	}
324	if (zfd != -1 && read(zfd,(char *)zin,
325	scanlen(&tresolu)*sizeof(float))
326	< scanlen(&tresolu)*sizeof(float)) {
327	fprintf(stderr, "%s: read error\n", zspec);
328	exit(1);
329	}
330	addscanline(y, scanin, zin, plast);
331	}
332	/* clean up */
333	free((char *)scanin);
334	free((char *)zin);
335	free((char *)plast);
336	fclose(pfp);
337	if (zfd != -1)
338	close(zfd);
339	}
340
341
342	pixform(xfmat, vw1, vw2) /* compute view1 to view2 matrix */
343	register double xfmat[4][4];
344	register VIEW vw1, vw2;
345	{
346	double m4t[4][4];
347
348	if (vw1->type != VT_PER && vw1->type != VT_PAR)
349	return(0);
350	if (vw2->type != VT_PER && vw2->type != VT_PAR)
351	return(0);
352	setident4(xfmat);
353	xfmat[0][0] = vw1->hvec[0];
354	xfmat[0][1] = vw1->hvec[1];
355	xfmat[0][2] = vw1->hvec[2];
356	xfmat[1][0] = vw1->vvec[0];
357	xfmat[1][1] = vw1->vvec[1];
358	xfmat[1][2] = vw1->vvec[2];
359	xfmat[2][0] = vw1->vdir[0];
360	xfmat[2][1] = vw1->vdir[1];
361	xfmat[2][2] = vw1->vdir[2];
362	xfmat[3][0] = vw1->vp[0];
363	xfmat[3][1] = vw1->vp[1];
364	xfmat[3][2] = vw1->vp[2];
365	setident4(m4t);
366	m4t[0][0] = vw2->hvec[0]/vw2->hn2;
367	m4t[1][0] = vw2->hvec[1]/vw2->hn2;
368	m4t[2][0] = vw2->hvec[2]/vw2->hn2;
369	m4t[3][0] = -DOT(vw2->vp,vw2->hvec)/vw2->hn2;
370	m4t[0][1] = vw2->vvec[0]/vw2->vn2;
371	m4t[1][1] = vw2->vvec[1]/vw2->vn2;
372	m4t[2][1] = vw2->vvec[2]/vw2->vn2;
373	m4t[3][1] = -DOT(vw2->vp,vw2->vvec)/vw2->vn2;
374	m4t[0][2] = vw2->vdir[0];
375	m4t[1][2] = vw2->vdir[1];
376	m4t[2][2] = vw2->vdir[2];
377	m4t[3][2] = -DOT(vw2->vp,vw2->vdir);
378	multmat4(xfmat, xfmat, m4t);
379	return(1);
380	}
381
382
383	addscanline(y, pline, zline, lasty) /* add scanline to output */
384	int y;
385	COLR *pline;
386	float *zline;
387	struct position lasty; / input/output */
388	{
389	FVECT pos;
390	struct position lastx, newpos;
391	register int x;
392
393	lastx.z = 0;
394	for (x = scanlen(&tresolu); x-- > 0; ) {
395	pix2loc(pos, &tresolu, x, y);
396	pos[2] = zline[x];
397	if (movepixel(pos) < 0) {
398	lasty[x].z = lastx.z = 0; /* mark invalid */
399	continue;
400	}
401	newpos.x = pos[0] * hresolu;
402	newpos.y = pos[1] * vresolu;
403	newpos.z = zline[x];
404	/* add pixel to our image */
405	if (pos[0] >= 0 && newpos.x < hresolu
406	&& pos[1] >= 0 && newpos.y < vresolu) {
407	addpixel(&newpos, &lastx, &lasty[x], pline[x], pos[2]);
408	lasty[x].x = lastx.x = newpos.x;
409	lasty[x].y = lastx.y = newpos.y;
410	lasty[x].z = lastx.z = newpos.z;
411	} else
412	lasty[x].z = lastx.z = 0; /* mark invalid */
413	}
414	}
415
416
417	addpixel(p0, p1, p2, pix, z) /* fill in pixel parallelogram */
418	struct position p0, p1, *p2;
419	COLR pix;
420	double z;
421	{
422	double zt = 2.zepsp0->z; /* threshold */
423	int s1x, s1y, s2x, s2y; /* step sizes */
424	int l1, l2, c1, c2; /* side lengths and counters */
425	int p1isy; /* p0p1 along y? */
426	int x1, y1; /* p1 position */
427	register int x, y; /* final position */
428
429	/* compute vector p0p1 */
430	if (fillo&F_FORE && ABS(p1->z-p0->z) <= zt) {
431	s1x = p1->x - p0->x;
432	s1y = p1->y - p0->y;
433	l1 = ABS(s1x);
434	if (p1isy = (ABS(s1y) > l1))
435	l1 = ABS(s1y);
436	} else {
437	l1 = s1x = s1y = 1;
438	p1isy = -1;
439	}
440	/* compute vector p0p2 */
441	if (fillo&F_FORE && ABS(p2->z-p0->z) <= zt) {
442	s2x = p2->x - p0->x;
443	s2y = p2->y - p0->y;
444	if (p1isy == 1)
445	l2 = ABS(s2x);
446	else {
447	l2 = ABS(s2y);
448	if (p1isy != 0 && ABS(s2x) > l2)
449	l2 = ABS(s2x);
450	}
451	} else
452	l2 = s2x = s2y = 1;
453	/* fill the parallelogram */
454	for (c1 = l1; c1-- > 0; ) {
455	x1 = p0->x + c1*s1x/l1;
456	y1 = p0->y + c1*s1y/l1;
457	for (c2 = l2; c2-- > 0; ) {
458	x = x1 + c2*s2x/l2;
459	if (x < 0 \|\| x >= hresolu)
460	continue;
461	y = y1 + c2*s2y/l2;
462	if (y < 0 \|\| y >= vresolu)
463	continue;
464	if (zscan(y)[x] <= 0 \|\| zscan(y)[x]-z
465	> zeps*zscan(y)[x]) {
466	zscan(y)[x] = z;
467	copycolr(pscan(y)[x], pix);
468	}
469	}
470	}
471	}
472
473
474	movepixel(pos) /* reposition image point */
475	FVECT pos;
476	{
477	FVECT pt, direc;
478
479	if (pos[2] <= 0) /* empty pixel */
480	return(-1);
481	if (hasmatrix) {
482	pos[0] += theirview.hoff - .5;
483	pos[1] += theirview.voff - .5;
484	if (theirview.type == VT_PER) {
485	if (normdist) /* adjust for eye-ray distance */
486	pos[2] /= sqrt( 1.
487	+ pos[0]pos[0]theirview.hn2
488	+ pos[1]pos[1]theirview.vn2 );
489	pos[0] *= pos[2];
490	pos[1] *= pos[2];
491	}
492	multp3(pos, pos, theirs2ours);
493	if (pos[2] <= 0)
494	return(-1);
495	if (ourview.type == VT_PER) {
496	pos[0] /= pos[2];
497	pos[1] /= pos[2];
498	}
499	pos[0] += .5 - ourview.hoff;
500	pos[1] += .5 - ourview.voff;
501	return(0);
502	}
503	if (viewray(pt, direc, &theirview, pos[0], pos[1]) < 0)
504	return(-1);
505	pt[0] += direc[0]*pos[2];
506	pt[1] += direc[1]*pos[2];
507	pt[2] += direc[2]*pos[2];
508	viewloc(pos, &ourview, pt);
509	if (pos[2] <= 0)
510	return(-1);
511	return(0);
512	}
513
514
515	backpicture(fill, samp) /* background fill algorithm */
516	int (*fill)();
517	int samp;
518	{
519	int *yback, xback;
520	int y;
521	register int x, i;
522	/* get back buffer */
523	yback = (int )malloc(hresolusizeof(int));
524	if (yback == NULL)
525	syserror();
526	for (x = 0; x < hresolu; x++)
527	yback[x] = -2;
528	/*
529	* Xback and yback are the pixel locations of suitable
530	* background values in each direction.
531	* A value of -2 means unassigned, and -1 means
532	* that there is no suitable background in this direction.
533	*/
534	/* fill image */
535	for (y = 0; y < vresolu; y++) {
536	xback = -2;
537	for (x = 0; x < hresolu; x++)
538	if (zscan(y)[x] <= 0) { /* empty pixel */
539	/*
540	* First, find background from above or below.
541	* (farthest assigned pixel)
542	*/
543	if (yback[x] == -2) {
544	for (i = y+1; i < vresolu; i++)
545	if (zscan(i)[x] > 0)
546	break;
547	if (i < vresolu
548	&& (y <= 0 \|\| zscan(y-1)[x] < zscan(i)[x]))
549	yback[x] = i;
550	else
551	yback[x] = y-1;
552	}
553	/*
554	* Next, find background from left or right.
555	*/
556	if (xback == -2) {
557	for (i = x+1; i < hresolu; i++)
558	if (zscan(y)[i] > 0)
559	break;
560	if (i < hresolu
561	&& (x <= 0 \|\| zscan(y)[x-1] < zscan(y)[i]))
562	xback = i;
563	else
564	xback = x-1;
565	}
566	/*
567	* If we have no background for this pixel,
568	* use the given fill function.
569	*/
570	if (xback < 0 && yback[x] < 0)
571	goto fillit;
572	/*
573	* Compare, and use the background that is
574	* farther, unless one of them is next to us.
575	* If the background is too distant, call
576	* the fill function.
577	*/
578	if ( yback[x] < 0
579	\|\| (xback >= 0 && ABS(x-xback) <= 1)
580	\|\| ( ABS(y-yback[x]) > 1
581	&& zscan(yback[x])[x]
582	< zscan(y)[xback] ) ) {
583	if (samp > 0 && ABS(x-xback) >= samp)
584	goto fillit;
585	copycolr(pscan(y)[x],pscan(y)[xback]);
586	zscan(y)[x] = zscan(y)[xback];
587	} else {
588	if (samp > 0 && ABS(y-yback[x]) > samp)
589	goto fillit;
590	copycolr(pscan(y)[x],pscan(yback[x])[x]);
591	zscan(y)[x] = zscan(yback[x])[x];
592	}
593	continue;
594	fillit:
595	(*fill)(x,y);
596	if (fill == rcalfill) { /* use it */
597	clearqueue();
598	xback = x;
599	yback[x] = y;
600	}
601	} else { /* full pixel */
602	yback[x] = -2;
603	xback = -2;
604	}
605	}
606	free((char *)yback);
607	}
608
609
610	fillpicture(fill) /* paint in empty pixels using fill */
611	int (*fill)();
612	{
613	register int x, y;
614
615	for (y = 0; y < vresolu; y++)
616	for (x = 0; x < hresolu; x++)
617	if (zscan(y)[x] <= 0)
618	(*fill)(x,y);
619	}
620
621
622	writepicture() /* write out picture */
623	{
624	int y;
625
626	fprtresolu(hresolu, vresolu, stdout);
627	for (y = vresolu-1; y >= 0; y--)
628	if (fwritecolrs(pscan(y), hresolu, stdout) < 0)
629	syserror();
630	}
631
632
633	writedistance(fname) /* write out z file */
634	char *fname;
635	{
636	int donorm = normdist && ourview.type == VT_PER;
637	int fd;
638	int y;
639	float *zout;
640
641	if ((fd = open(fname, O_WRONLY\|O_CREAT\|O_TRUNC, 0666)) == -1) {
642	perror(fname);
643	exit(1);
644	}
645	if (donorm
646	&& (zout = (float )malloc(hresolusizeof(float))) == NULL)
647	syserror();
648	for (y = vresolu-1; y >= 0; y--) {
649	if (donorm) {
650	double vx, yzn2;
651	register int x;
652	yzn2 = (y+.5)/vresolu + ourview.voff - .5;
653	yzn2 = 1. + yzn2yzn2ourview.vn2;
654	for (x = 0; x < hresolu; x++) {
655	vx = (x+.5)/hresolu + ourview.hoff - .5;
656	zout[x] = zscan(y)[x]
657	* sqrt(vxvxourview.hn2 + yzn2);
658	}
659	} else
660	zout = zscan(y);
661	if (write(fd, (char )zout, hresolusizeof(float))
662	< hresolu*sizeof(float)) {
663	perror(fname);
664	exit(1);
665	}
666	}
667	if (donorm)
668	free((char *)zout);
669	close(fd);
670	}
671
672
673	isfloat(s) /* see if string is floating number */
674	register char *s;
675	{
676	for ( ; *s; s++)
677	if ((s < '0' \|\| s > '9') && s != '.' && s != '-'
678	&& s != 'e' && s != 'E' && *s != '+')
679	return(0);
680	return(1);
681	}
682
683
684	backfill(x, y) /* fill pixel with background */
685	int x, y;
686	{
687	register BYTE *dest = pscan(y)[x];
688
689	copycolr(dest, backcolr);
690	zscan(y)[x] = backz;
691	}
692
693
694	calstart(prog, args) /* start fill calculation */
695	char prog, args;
696	{
697	char combuf[512];
698	char *argv[64];
699	int rval;
700	register char *wp, cp;
701
702	if (childpid != -1) {
703	fprintf(stderr, "%s: too many calculations\n", progname);
704	exit(1);
705	}
706	strcpy(combuf, prog);
707	strcat(combuf, args);
708	cp = combuf;
709	wp = argv;
710	for ( ; ; ) {
711	while (isspace(*cp)) cp++;
712	if (!*cp) break;
713	*wp++ = cp;
714	while (!isspace(*cp))
715	if (!*cp++) goto done;
716	*cp++ = '\0';
717	}
718	done:
719	*wp = NULL;
720	/* start process */
721	if ((rval = open_process(PDesc, argv)) < 0)
722	syserror();
723	if (rval == 0) {
724	fprintf(stderr, "%s: command not found\n", argv[0]);
725	exit(1);
726	}
727	packsiz = rval/(6*sizeof(float)) - 1;
728	if (packsiz > PACKSIZ)
729	packsiz = PACKSIZ;
730	queuesiz = 0;
731	}
732
733
734	caldone() /* done with calculation */
735	{
736	if (childpid == -1)
737	return;
738	clearqueue();
739	close_process(PDesc);
740	childpid = -1;
741	}
742
743
744	rcalfill(x, y) /* fill with ray-calculated pixel */
745	int x, y;
746	{
747	if (queuesiz >= packsiz) /* flush queue if needed */
748	clearqueue();
749	/* add position to queue */
750	queue[queuesiz][0] = x;
751	queue[queuesiz][1] = y;
752	queuesiz++;
753	}
754
755
756	clearqueue() /* process queue */
757	{
758	FVECT orig, dir;
759	float fbuf[6*(PACKSIZ+1)];
760	register float *fbp;
761	register int i;
762
763	fbp = fbuf;
764	for (i = 0; i < queuesiz; i++) {
765	viewray(orig, dir, &ourview,
766	(queue[i][0]+.5)/hresolu,
767	(queue[i][1]+.5)/vresolu);
768	fbp++ = orig[0]; fbp++ = orig[1]; *fbp++ = orig[2];
769	fbp++ = dir[0]; fbp++ = dir[1]; *fbp++ = dir[2];
770	}
771	/* mark end and get results */
772	bzero((char )fbp, 6sizeof(float));
773	if (process(PDesc, fbuf, fbuf, 4sizeof(float)queuesiz,
774	6sizeof(float)(queuesiz+1)) !=
775	4sizeof(float)queuesiz) {
776	fprintf(stderr, "%s: error reading from rtrace process\n",
777	progname);
778	exit(1);
779	}
780	fbp = fbuf;
781	for (i = 0; i < queuesiz; i++) {
782	if (ourexp > 0 && ourexp != 1.0) {
783	fbp[0] *= ourexp;
784	fbp[1] *= ourexp;
785	fbp[2] *= ourexp;
786	}
787	setcolr(pscan(queue[i][1])[queue[i][0]],
788	fbp[0], fbp[1], fbp[2]);
789	zscan(queue[i][1])[queue[i][0]] = fbp[3];
790	fbp += 4;
791	}
792	queuesiz = 0;
793	}
794
795
796	syserror() /* report error and exit */
797	{
798	perror(progname);
799	exit(1);
800	}