src/common/data.c

#ifndef lint
static const char       RCSid[] = "$Id: data.c,v 2.3 2025/02/28 21:07:18 greg Exp $";
#endif
/*
 *  data.c - routines dealing with interpolated data.
 */

#include "copyright.h"

#include  <time.h>

#include  "platform.h"
#include  "paths.h"
#include  "standard.h"
#include  "color.h"
#include  "view.h"
#include  "data.h"

                                /* picture memory usage before warning */
#ifndef PSIZWARN
#ifdef SMLMEM
#define PSIZWARN        3000000
#else
#define PSIZWARN        50000000
#endif
#endif

#ifndef TABSIZ
#define TABSIZ          997             /* table size (prime) */
#endif

#define hash(s)         (shash(s)%TABSIZ)


static DATARRAY  *dtab[TABSIZ];         /* data array list */

static gethfunc headaspect;


DATARRAY *
getdata(                                /* get data array dname */
        char  *dname
)
{
        char  *dfname;
        FILE  *fp;
        int  asize=0;
        int  i, j;
        DATARRAY  *dp;
                                                /* look for array in list */
        for (dp = dtab[hash(dname)]; dp != NULL; dp = dp->next)
                if (!strcmp(dname, dp->name))
                        return(dp);             /* found! */
        /*
         *      If we haven't loaded the data already, we will look
         *  for it in the directories specified by the library path.
         *
         *      The file has the following format:
         *
         *              N
         *              beg0    end0    n0
         *              beg1    end1    n1
         *              . . .
         *              begN    endN    nN
         *              data, later dimensions changing faster
         *              . . .
         *
         *      For irregularly spaced points, the following can be
         *  substituted for begi endi ni:
         *
         *              0 0 ni p0i p1i .. pni
         */

        if ((dfname = getpath(dname, getrlibpath(), R_OK)) == NULL) {
                sprintf(errmsg, "cannot find data file \"%s\"", dname);
                error(SYSTEM, errmsg);
        }
        if ((fp = fopen(dfname, "r")) == NULL) {
                sprintf(errmsg, "cannot open data file \"%s\"", dfname);
                error(SYSTEM, errmsg);
        }
                                                        /* get dimensions */
        if (fgetval(fp, 'i', &asize) <= 0)
                goto scanerr;
        if ((asize <= 0) | (asize > MAXDDIM)) {
                sprintf(errmsg, "bad number of dimensions for \"%s\"", dname);
                error(USER, errmsg);
        }
        if ((dp = (DATARRAY *)malloc(sizeof(DATARRAY))) == NULL)
                goto memerr;
        dp->name = savestr(dname);
        dp->type = DATATY;
        dp->nd = asize;
        asize = 1;
        for (i = 0; i < dp->nd; i++) {
                if (fgetval(fp, DATATY, &dp->dim[i].org) <= 0)
                        goto scanerr;
                if (fgetval(fp, DATATY, &dp->dim[i].siz) <= 0)
                        goto scanerr;
                if (fgetval(fp, 'i', &dp->dim[i].ne) <= 0)
                        goto scanerr;
                if (dp->dim[i].ne < 2)
                        goto scanerr;
                asize *= dp->dim[i].ne;
                if ((dp->dim[i].siz -= dp->dim[i].org) == 0) {
                        dp->dim[i].p = (DATATYPE *)
                                        malloc(dp->dim[i].ne*sizeof(DATATYPE));
                        if (dp->dim[i].p == NULL)
                                goto memerr;
                        for (j = 0; j < dp->dim[i].ne; j++)
                                if (fgetval(fp, DATATY, &dp->dim[i].p[j]) <= 0)
                                        goto scanerr;
                        for (j = 1; j < dp->dim[i].ne-1; j++)
                                if ((dp->dim[i].p[j-1] < dp->dim[i].p[j]) !=
                                        (dp->dim[i].p[j] < dp->dim[i].p[j+1]))
                                        goto scanerr;
                        dp->dim[i].org = dp->dim[i].p[0];
                        dp->dim[i].siz = dp->dim[i].p[dp->dim[i].ne-1]
                                                - dp->dim[i].p[0];
                } else
                        dp->dim[i].p = NULL;
        }
        if ((dp->arr.d = (DATATYPE *)malloc(asize*sizeof(DATATYPE))) == NULL)
                goto memerr;
        
        for (i = 0; i < asize; i++)
                if (fgetval(fp, DATATY, &dp->arr.d[i]) <= 0)
                        goto scanerr;
        fclose(fp);
        i = hash(dname);
        dp->next = dtab[i];
        return(dtab[i] = dp);
memerr:
        error(SYSTEM, "out of memory in getdata");
scanerr:
        sprintf(errmsg, "%s in data file \"%s\"",
                        feof(fp) ? "unexpected EOF" : "bad format", dfname);
        error(USER, errmsg);
        return NULL;    /* pro forma return */
}


static int
headaspect(                     /* check string for aspect ratio */
        char  *s,
        void  *iap
)
{
        char    fmt[MAXFMTLEN];

        if (isaspect(s))
                *(double*)iap *= aspectval(s);
        else if (formatval(fmt, s) && strcmp(fmt, COLRFMT))
                *(double*)iap = 0.0;
        return(0);
}

DATARRAY *
getpict(                                /* get picture pname */
        char  *pname
)
{
        double  inpaspect;
        char  *pfname;
        FILE  *fp;
        COLR  *scanin;
        int  sl, ns;
        RESOLU  inpres;
        RREAL  loc[2];
        int  y;
        int  x, i;
        DATARRAY  *pp;
                                                /* look for array in list */
        for (pp = dtab[hash(pname)]; pp != NULL; pp = pp->next)
                if (!strcmp(pname, pp->name))
                        return(pp);             /* found! */

        if ((pfname = getpath(pname, getrlibpath(), R_OK)) == NULL) {
                sprintf(errmsg, "cannot find picture file \"%s\"", pname);
                error(SYSTEM, errmsg);
        }
        if ((pp = (DATARRAY *)malloc(3*sizeof(DATARRAY))) == NULL)
                goto memerr;

        pp[0].name = savestr(pname);

        if ((fp = fopen(pfname, "rb")) == NULL) {
                sprintf(errmsg, "cannot open picture file \"%s\"", pfname);
                error(SYSTEM, errmsg);
        }
                                                /* get dimensions */
        inpaspect = 1.0;
        getheader(fp, headaspect, &inpaspect);
        if (inpaspect <= FTINY || !fgetsresolu(&inpres, fp))
                goto readerr;
        pp[0].nd = 2;
        pp[0].dim[0].ne = inpres.yr;
        pp[0].dim[1].ne = inpres.xr;
        pp[0].dim[0].org =
        pp[0].dim[1].org = 0.0;
        if (inpres.xr <= inpres.yr*inpaspect) {
                pp[0].dim[0].siz = inpaspect *
                                        (double)inpres.yr/inpres.xr;
                pp[0].dim[1].siz = 1.0;
        } else {
                pp[0].dim[0].siz = 1.0;
                pp[0].dim[1].siz = (double)inpres.xr/inpres.yr /
                                        inpaspect;
        }
        pp[0].dim[0].p = pp[0].dim[1].p = NULL;
        sl = scanlen(&inpres);                          /* allocate array */
        ns = numscans(&inpres);
        i = ns*sl*sizeof(COLR);
#if PSIZWARN
        if (i > PSIZWARN) {                             /* memory warning */
                sprintf(errmsg, "picture file \"%s\" using %.1f MB of memory",
                                pname, i*(1.0/(1024*1024)));
                error(WARNING, errmsg);
        }
#endif
        if ((pp[0].arr.c = (COLR *)malloc(i)) == NULL)
                goto memerr;
                                                        /* load picture */
        if ((scanin = (COLR *)malloc(sl*sizeof(COLR))) == NULL)
                goto memerr;
        for (y = 0; y < ns; y++) {
                if (freadcolrs(scanin, sl, fp) < 0)
                        goto readerr;
                for (x = 0; x < sl; x++) {
                        pix2loc(loc, &inpres, x, y);
                        i = (int)(loc[1]*inpres.yr)*inpres.xr +
                                        (int)(loc[0]*inpres.xr);
                        copycolr(pp[0].arr.c[i], scanin[x]);
                }
        }
        free(scanin);
        fclose(fp);
        i = hash(pname);
        pp[0].next = dtab[i];           /* link into picture list */
        pp[1] = pp[0];
        pp[2] = pp[0];
        pp[0].type = RED;               /* differentiate RGB records */
        pp[1].type = GRN;
        pp[2].type = BLU;
        return(dtab[i] = pp);
memerr:
        error(SYSTEM, "out of memory in getpict");
readerr:
        sprintf(errmsg, "bad picture file \"%s\"", pfname);
        error(USER, errmsg);
        return NULL;    /* pro forma return */
}


/* header info type for hyperspectral image */
typedef struct {
        float   wlpart[4];      /* wavelength partitions */
        int     nc;             /* number of components */
        double  inpaspect;      /* pixel aspect ratio */
} SPECINFO;

static int
specheadline(                           /* get info for spectral image */
        char  *s,
        void  *cdp
)
{
        SPECINFO        *sip = (SPECINFO *)cdp;
        char            fmt[MAXFMTLEN];

        if (isaspect(s))
                sip->inpaspect *= aspectval(s);
        else if (isncomp(s))
                sip->nc = ncompval(s);
        else if (iswlsplit(s))
                wlsplitval(sip->wlpart, s);
        else if (formatval(fmt, s) && strcmp(fmt, SPECFMT))
                return(-1);
        return(0);
}

DATARRAY *
getspec(                /* load hyperspectral image as data */
        char *sname
)
{
        SPECINFO        si;
        char            *pfname;
        FILE            *fp;
        int             sl, ns;
        int             y, i;
        DATARRAY        *pp;
                                                /* look for array in list */
        for (pp = dtab[hash(sname)]; pp != NULL; pp = pp->next)
                if (!strcmp(sname, pp->name))
                        return(pp);             /* found! */

        if ((pfname = getpath(sname, getrlibpath(), R_OK)) == NULL) {
                sprintf(errmsg, "cannot find hyperspectral image \"%s\"", sname);
                error(SYSTEM, errmsg);
        }
        if ((fp = fopen(pfname, "rb")) == NULL) {
                sprintf(errmsg, "cannot open hyperspectral image \"%s\"", pfname);
                error(SYSTEM, errmsg);
        }
        si.wlpart[3] = 0;
        si.nc = 0;
        si.inpaspect = 1.0;
        if (getheader(fp, specheadline, &si) < 0 ||
                        (si.nc <= 3) | (si.nc > MAXCSAMP) | (si.wlpart[3] < 1) ||
                        !fscnresolu(&sl, &ns, fp))
                goto readerr;

        if ((pp = (DATARRAY *)malloc(sizeof(DATARRAY))) == NULL)
                goto memerr;

        pp->name = savestr(sname);
        pp->type = SPECTY;
        pp->nd = 3;
        pp->dim[0].ne = ns;
        pp->dim[1].ne = sl;
        pp->dim[0].org =
        pp->dim[1].org = 0.0;
        if (sl <= ns*si.inpaspect) {
                pp->dim[0].siz = si.inpaspect * (double)ns/sl;
                pp->dim[1].siz = 1.0;
        } else {
                pp->dim[0].siz = 1.0;
                pp->dim[1].siz = (double)sl/ns / si.inpaspect;
        }
        pp->dim[2].ne = si.nc;
        pp->dim[2].siz = si.wlpart[3] - si.wlpart[0];
        pp->dim[2].org = si.wlpart[0] + 0.5*pp->dim[2].siz/si.nc;
        pp->dim[2].siz *= (si.nc - 1.0)/si.nc;
        pp->dim[0].p = pp->dim[1].p = pp->dim[2].p = NULL;
        i = ns*sl*(si.nc+1);
#if PSIZWARN
        if (i > PSIZWARN) {                     /* memory warning */
                sprintf(errmsg, "hyperspectral image \"%s\" using %.1f MB of memory",
                                sname, i*(1.0/(1024*1024)));
                error(WARNING, errmsg);
        }
#endif
        if ((pp->arr.s = (uby8 *)malloc(i)) == NULL)
                goto memerr;
        for (y = ns; y-- > 0; )                 /* read each scanline */
                if (freadscolrs(pp->arr.s + y*sl*(si.nc+1), si.nc, sl, fp) < 0)
                        goto readerr;
        fclose(fp);
        i = hash(sname);                        /* insert in hash table */
        pp->next = dtab[i];
        return(dtab[i] = pp);
memerr:
        error(SYSTEM, "out of memory in getspec");
readerr:
        sprintf(errmsg, "bad hyperspectral image \"%s\"", pfname);
        error(USER, errmsg);
        return NULL;    /* pro forma return */
}


void
freedata(                       /* release data array reference */
        DATARRAY  *dta
)
{
        DATARRAY  head;
        int  hval, nents;
        DATARRAY  *dpl, *dp;
        int  i;

        if (dta == NULL) {                      /* free all if NULL */
                hval = 0; nents = TABSIZ;
        } else {
                if (dta->next == dta) {
                        free(dta);              /* unlisted temp array */
                        return;
                }
                hval = hash(dta->name); nents = 1;
                if (!*dta->name) {              /* not a data file? */
                        dta->next = dtab[hval];
                        dtab[hval] = dta;       /* ...fake position */
                }
        }
        while (nents--) {
                head.next = dtab[hval];
                dpl = &head;
                while ((dp = dpl->next) != NULL)
                        if ((dta == NULL) | (dta == dp)) {
                                dpl->next = dp->next;
                                free(dp->arr.p);
                                for (i = 0; i < dp->nd; i++)
                                        if (dp->dim[i].p != NULL)
                                                free(dp->dim[i].p);
                                freestr(dp->name);
                                free(dp);
                        } else
                                dpl = dp;
                dtab[hval++] = head.next;
        }
}


/* internal call to interpolate data value or vector */
static double
data_interp(DATARRAY *dp, double *pt, double coef, DATATYPE *rvec)
{
        DATARRAY        sd;
        int             stride, i;
        double          x, c0, c1, y0, y1;
                                        /* unlikely, but may as well check */
        if ((-FTINY <= coef) & (coef <= FTINY))
                return(0.);
                                        /* set up dimensions for recursion */
        if (dp->nd > 1) {
                sd.name = dp->name;
                sd.type = dp->type;
                sd.nd = dp->nd - 1;
                memcpy(sd.dim, dp->dim+1, sd.nd*sizeof(struct dadim));
                stride = sd.dim[i = sd.nd-1].ne + (sd.type==SPECTY);
                while (i-- > 0)
                        stride *= sd.dim[i].ne;
        }
                                        /* get independent variable */
        if (dp->dim[0].p == NULL) {             /* evenly spaced points */
                x = (pt[0] - dp->dim[0].org)/dp->dim[0].siz;
                x *= (double)(dp->dim[0].ne - 1);
                i = x;
                if (i < 0)
                        i = 0;
                else if (i > dp->dim[0].ne - 2)
                        i = dp->dim[0].ne - 2;
        } else {                                /* unevenly spaced points */
                int     lower, upper;
                if (dp->dim[0].siz > 0.) {
                        lower = 0;
                        upper = dp->dim[0].ne;
                } else {
                        lower = dp->dim[0].ne;
                        upper = 0;
                }
                do {
                        i = (lower + upper) >> 1;
                        if (pt[0] >= dp->dim[0].p[i])
                                lower = i;
                        else
                                upper = i;
                } while (i != (lower + upper) >> 1);

                if (i > dp->dim[0].ne - 2)
                        i = dp->dim[0].ne - 2;

                x = i + (pt[0] - dp->dim[0].p[i]) /
                                (dp->dim[0].p[i+1] - dp->dim[0].p[i]);
        }
        /*
         * Compute interpolation coefficients:
         * extrapolate as far as one division, then
         * taper off harmonically to zero.
         */
        if (x > i+2) {
                c0 = 1./(i-1 - x);
                c1 = -2.*c0;
        } else if (x < i-1) {
                c1 = 1./(x - i);
                c0 = -2.*c1;
        } else {
                c0 = i+1 - x;
                c1 = x - i;
        }
        c0 *= coef;
        c1 *= coef;
                                        /* check if vector interp */
        if ((dp->nd == 2) & (rvec != NULL)) {
                if (dp->type == DATATY) {
                        sd.arr.d = dp->arr.d + i*stride;
                        for (i = sd.dim[0].ne; i--; )
                                rvec[i] += c0*sd.arr.d[i]
                                        + c1*sd.arr.d[i+stride];
                } else if (dp->type == SPECTY) {
                        double  f;
                        sd.arr.s = dp->arr.s + i*stride;
                        if ((sd.arr.s[sd.dim[0].ne] > 0) & ((-FTINY>c0)|(c0>FTINY))) {
                                f = c0 * cxponent[sd.arr.s[sd.dim[0].ne]];
                                for (i = sd.dim[0].ne; i--; )
                                        rvec[i] += f*(sd.arr.s[i] + .5);
                        }
                        sd.arr.s += stride;
                        if ((sd.arr.s[sd.dim[0].ne] > 0) & ((-FTINY>c1)|(c1>FTINY))) {
                                f = c1 * cxponent[sd.arr.s[sd.dim[0].ne]];
                                for (i = sd.dim[0].ne; i--; )
                                        rvec[i] += f*(sd.arr.s[i] + .5);
                        }
                } else {
                        sd.arr.c = dp->arr.c + i*stride;
                        for (i = sd.dim[0].ne; i--; )
                                rvec[i] += c0*colrval(sd.arr.c[i],sd.type)
                                        + c1*colrval(sd.arr.c[i+stride],sd.type);
                }
                return(0.);             /* return value ignored */
        }
                                        /* get dependent variable */
        if (dp->nd > 1) {
                if (dp->type == DATATY) {
                        sd.arr.d = dp->arr.d + i*stride;
                        y0 = data_interp(&sd, pt+1, c0, rvec);
                        sd.arr.d += stride;
                } else if (dp->type == SPECTY) {
                        sd.arr.s = dp->arr.s + i*stride;
                        y0 = data_interp(&sd, pt+1, c0, rvec);
                        sd.arr.s += stride;
                } else {
                        sd.arr.c = dp->arr.c + i*stride;
                        y0 = data_interp(&sd, pt+1, c0, rvec);
                        sd.arr.c += stride;
                }
                y1 = data_interp(&sd, pt+1, c1, rvec);
        } else {                        /* end of recursion */
                if (dp->type == DATATY) {
                        y0 = dp->arr.d[i];
                        y1 = dp->arr.d[i+1];
                } else if (dp->type == SPECTY) {
                        double  f = cxponent[dp->arr.s[dp->dim[0].ne]];
                        y0 = f*(dp->arr.s[i] + 0.5);
                        y1 = f*(dp->arr.s[i+1] + 0.5);
                } else {
                        y0 = colrval(dp->arr.c[i],dp->type);
                        y1 = colrval(dp->arr.c[i+1],dp->type);
                }
                y0 *= c0;
                y1 *= c1;
        }
        return(y0 + y1);        /* coefficients already applied */
}


double
datavalue(              /* interpolate data value at a point */
        DATARRAY  *dp,
        double  *pt
)
{
        return(data_interp(dp, pt, 1., NULL));
}


/* Interpolate final vector corresponding to last dimension in data array */
DATARRAY *
datavector(DATARRAY *dp, double *pt)
{
        DATARRAY        *newdp;

        if (dp->nd < 2)
                error(INTERNAL, "datavector() called with 1-D array");
                                        /* create vector array */
        newdp = (DATARRAY *)malloc(sizeof(DATARRAY) -
                                (MAXDDIM-1)*sizeof(struct dadim) +
                                sizeof(DATATYPE)*dp->dim[dp->nd-1].ne);
        if (newdp == NULL)
                error(SYSTEM, "out of memory in datavector");
        newdp->next = newdp;            /* flags us as temp vector */
        newdp->name = dp->name;
        newdp->type = DATATY;
        newdp->nd = 1;                  /* vector data goes here */
        newdp->dim[0] = dp->dim[dp->nd-1];
        newdp->arr.d = (DATATYPE *)(newdp->dim + 1);
        memset(newdp->arr.d, 0, sizeof(DATATYPE)*newdp->dim[0].ne);

        (void)data_interp(dp, pt, 1., newdp->arr.d);

        return(newdp);                  /* will be free'd using free() */
}
Revision:	2.4
Committed:	Sun Mar 9 19:11:51 2025 UTC (7 weeks, 4 days ago) by greg
Content type:	text/plain
Branch:	MAIN
CVS Tags:	HEAD
Changes since 2.3:	+6 -12 lines
Log Message:	perf: Eliminated calls to ldexp() in favor of exponent multiplier table
#	Content
1	#ifndef lint
2	static const char RCSid[] = "$Id: data.c,v 2.3 2025/02/28 21:07:18 greg Exp $";
3	#endif
4	/*
5	* data.c - routines dealing with interpolated data.
6	*/
7
8	#include "copyright.h"
9
10	#include <time.h>
11
12	#include "platform.h"
13	#include "paths.h"
14	#include "standard.h"
15	#include "color.h"
16	#include "view.h"
17	#include "data.h"
18
19	/* picture memory usage before warning */
20	#ifndef PSIZWARN
21	#ifdef SMLMEM
22	#define PSIZWARN 3000000
23	#else
24	#define PSIZWARN 50000000
25	#endif
26	#endif
27
28	#ifndef TABSIZ
29	#define TABSIZ 997 /* table size (prime) */
30	#endif
31
32	#define hash(s) (shash(s)%TABSIZ)
33
34
35	static DATARRAY dtab[TABSIZ]; / data array list */
36
37	static gethfunc headaspect;
38
39
40	DATARRAY *
41	getdata( /* get data array dname */
42	char *dname
43	)
44	{
45	char *dfname;
46	FILE *fp;
47	int asize=0;
48	int i, j;
49	DATARRAY *dp;
50	/* look for array in list */
51	for (dp = dtab[hash(dname)]; dp != NULL; dp = dp->next)
52	if (!strcmp(dname, dp->name))
53	return(dp); /* found! */
54	/*
55	* If we haven't loaded the data already, we will look
56	* for it in the directories specified by the library path.
57	*
58	* The file has the following format:
59	*
60	* N
61	* beg0 end0 n0
62	* beg1 end1 n1
63	* . . .
64	* begN endN nN
65	* data, later dimensions changing faster
66	* . . .
67	*
68	* For irregularly spaced points, the following can be
69	* substituted for begi endi ni:
70	*
71	* 0 0 ni p0i p1i .. pni
72	*/
73
74	if ((dfname = getpath(dname, getrlibpath(), R_OK)) == NULL) {
75	sprintf(errmsg, "cannot find data file \"%s\"", dname);
76	error(SYSTEM, errmsg);
77	}
78	if ((fp = fopen(dfname, "r")) == NULL) {
79	sprintf(errmsg, "cannot open data file \"%s\"", dfname);
80	error(SYSTEM, errmsg);
81	}
82	/* get dimensions */
83	if (fgetval(fp, 'i', &asize) <= 0)
84	goto scanerr;
85	if ((asize <= 0) \| (asize > MAXDDIM)) {
86	sprintf(errmsg, "bad number of dimensions for \"%s\"", dname);
87	error(USER, errmsg);
88	}
89	if ((dp = (DATARRAY *)malloc(sizeof(DATARRAY))) == NULL)
90	goto memerr;
91	dp->name = savestr(dname);
92	dp->type = DATATY;
93	dp->nd = asize;
94	asize = 1;
95	for (i = 0; i < dp->nd; i++) {
96	if (fgetval(fp, DATATY, &dp->dim[i].org) <= 0)
97	goto scanerr;
98	if (fgetval(fp, DATATY, &dp->dim[i].siz) <= 0)
99	goto scanerr;
100	if (fgetval(fp, 'i', &dp->dim[i].ne) <= 0)
101	goto scanerr;
102	if (dp->dim[i].ne < 2)
103	goto scanerr;
104	asize *= dp->dim[i].ne;
105	if ((dp->dim[i].siz -= dp->dim[i].org) == 0) {
106	dp->dim[i].p = (DATATYPE *)
107	malloc(dp->dim[i].ne*sizeof(DATATYPE));
108	if (dp->dim[i].p == NULL)
109	goto memerr;
110	for (j = 0; j < dp->dim[i].ne; j++)
111	if (fgetval(fp, DATATY, &dp->dim[i].p[j]) <= 0)
112	goto scanerr;
113	for (j = 1; j < dp->dim[i].ne-1; j++)
114	if ((dp->dim[i].p[j-1] < dp->dim[i].p[j]) !=
115	(dp->dim[i].p[j] < dp->dim[i].p[j+1]))
116	goto scanerr;
117	dp->dim[i].org = dp->dim[i].p[0];
118	dp->dim[i].siz = dp->dim[i].p[dp->dim[i].ne-1]
119	- dp->dim[i].p[0];
120	} else
121	dp->dim[i].p = NULL;
122	}
123	if ((dp->arr.d = (DATATYPE )malloc(asizesizeof(DATATYPE))) == NULL)
124	goto memerr;
125
126	for (i = 0; i < asize; i++)
127	if (fgetval(fp, DATATY, &dp->arr.d[i]) <= 0)
128	goto scanerr;
129	fclose(fp);
130	i = hash(dname);
131	dp->next = dtab[i];
132	return(dtab[i] = dp);
133	memerr:
134	error(SYSTEM, "out of memory in getdata");
135	scanerr:
136	sprintf(errmsg, "%s in data file \"%s\"",
137	feof(fp) ? "unexpected EOF" : "bad format", dfname);
138	error(USER, errmsg);
139	return NULL; /* pro forma return */
140	}
141
142
143	static int
144	headaspect( /* check string for aspect ratio */
145	char *s,
146	void *iap
147	)
148	{
149	char fmt[MAXFMTLEN];
150
151	if (isaspect(s))
152	(double)iap *= aspectval(s);
153	else if (formatval(fmt, s) && strcmp(fmt, COLRFMT))
154	(double)iap = 0.0;
155	return(0);
156	}
157
158	DATARRAY *
159	getpict( /* get picture pname */
160	char *pname
161	)
162	{
163	double inpaspect;
164	char *pfname;
165	FILE *fp;
166	COLR *scanin;
167	int sl, ns;
168	RESOLU inpres;
169	RREAL loc[2];
170	int y;
171	int x, i;
172	DATARRAY *pp;
173	/* look for array in list */
174	for (pp = dtab[hash(pname)]; pp != NULL; pp = pp->next)
175	if (!strcmp(pname, pp->name))
176	return(pp); /* found! */
177
178	if ((pfname = getpath(pname, getrlibpath(), R_OK)) == NULL) {
179	sprintf(errmsg, "cannot find picture file \"%s\"", pname);
180	error(SYSTEM, errmsg);
181	}
182	if ((pp = (DATARRAY )malloc(3sizeof(DATARRAY))) == NULL)
183	goto memerr;
184
185	pp[0].name = savestr(pname);
186
187	if ((fp = fopen(pfname, "rb")) == NULL) {
188	sprintf(errmsg, "cannot open picture file \"%s\"", pfname);
189	error(SYSTEM, errmsg);
190	}
191	/* get dimensions */
192	inpaspect = 1.0;
193	getheader(fp, headaspect, &inpaspect);
194	if (inpaspect <= FTINY \|\| !fgetsresolu(&inpres, fp))
195	goto readerr;
196	pp[0].nd = 2;
197	pp[0].dim[0].ne = inpres.yr;
198	pp[0].dim[1].ne = inpres.xr;
199	pp[0].dim[0].org =
200	pp[0].dim[1].org = 0.0;
201	if (inpres.xr <= inpres.yr*inpaspect) {
202	pp[0].dim[0].siz = inpaspect *
203	(double)inpres.yr/inpres.xr;
204	pp[0].dim[1].siz = 1.0;
205	} else {
206	pp[0].dim[0].siz = 1.0;
207	pp[0].dim[1].siz = (double)inpres.xr/inpres.yr /
208	inpaspect;
209	}
210	pp[0].dim[0].p = pp[0].dim[1].p = NULL;
211	sl = scanlen(&inpres); /* allocate array */
212	ns = numscans(&inpres);
213	i = nsslsizeof(COLR);
214	#if PSIZWARN
215	if (i > PSIZWARN) { /* memory warning */
216	sprintf(errmsg, "picture file \"%s\" using %.1f MB of memory",
217	pname, i(1.0/(10241024)));
218	error(WARNING, errmsg);
219	}
220	#endif
221	if ((pp[0].arr.c = (COLR *)malloc(i)) == NULL)
222	goto memerr;
223	/* load picture */
224	if ((scanin = (COLR )malloc(slsizeof(COLR))) == NULL)
225	goto memerr;
226	for (y = 0; y < ns; y++) {
227	if (freadcolrs(scanin, sl, fp) < 0)
228	goto readerr;
229	for (x = 0; x < sl; x++) {
230	pix2loc(loc, &inpres, x, y);
231	i = (int)(loc[1]inpres.yr)inpres.xr +
232	(int)(loc[0]*inpres.xr);
233	copycolr(pp[0].arr.c[i], scanin[x]);
234	}
235	}
236	free(scanin);
237	fclose(fp);
238	i = hash(pname);
239	pp[0].next = dtab[i]; /* link into picture list */
240	pp[1] = pp[0];
241	pp[2] = pp[0];
242	pp[0].type = RED; /* differentiate RGB records */
243	pp[1].type = GRN;
244	pp[2].type = BLU;
245	return(dtab[i] = pp);
246	memerr:
247	error(SYSTEM, "out of memory in getpict");
248	readerr:
249	sprintf(errmsg, "bad picture file \"%s\"", pfname);
250	error(USER, errmsg);
251	return NULL; /* pro forma return */
252	}
253
254
255	/* header info type for hyperspectral image */
256	typedef struct {
257	float wlpart[4]; /* wavelength partitions */
258	int nc; /* number of components */
259	double inpaspect; /* pixel aspect ratio */
260	} SPECINFO;
261
262	static int
263	specheadline( /* get info for spectral image */
264	char *s,
265	void *cdp
266	)
267	{
268	SPECINFO sip = (SPECINFO )cdp;
269	char fmt[MAXFMTLEN];
270
271	if (isaspect(s))
272	sip->inpaspect *= aspectval(s);
273	else if (isncomp(s))
274	sip->nc = ncompval(s);
275	else if (iswlsplit(s))
276	wlsplitval(sip->wlpart, s);
277	else if (formatval(fmt, s) && strcmp(fmt, SPECFMT))
278	return(-1);
279	return(0);
280	}
281
282	DATARRAY *
283	getspec( /* load hyperspectral image as data */
284	char *sname
285	)
286	{
287	SPECINFO si;
288	char *pfname;
289	FILE *fp;
290	int sl, ns;
291	int y, i;
292	DATARRAY *pp;
293	/* look for array in list */
294	for (pp = dtab[hash(sname)]; pp != NULL; pp = pp->next)
295	if (!strcmp(sname, pp->name))
296	return(pp); /* found! */
297
298	if ((pfname = getpath(sname, getrlibpath(), R_OK)) == NULL) {
299	sprintf(errmsg, "cannot find hyperspectral image \"%s\"", sname);
300	error(SYSTEM, errmsg);
301	}
302	if ((fp = fopen(pfname, "rb")) == NULL) {
303	sprintf(errmsg, "cannot open hyperspectral image \"%s\"", pfname);
304	error(SYSTEM, errmsg);
305	}
306	si.wlpart[3] = 0;
307	si.nc = 0;
308	si.inpaspect = 1.0;
309	if (getheader(fp, specheadline, &si) < 0 \|\|
310	(si.nc <= 3) \| (si.nc > MAXCSAMP) \| (si.wlpart[3] < 1) \|\|
311	!fscnresolu(&sl, &ns, fp))
312	goto readerr;
313
314	if ((pp = (DATARRAY *)malloc(sizeof(DATARRAY))) == NULL)
315	goto memerr;
316
317	pp->name = savestr(sname);
318	pp->type = SPECTY;
319	pp->nd = 3;
320	pp->dim[0].ne = ns;
321	pp->dim[1].ne = sl;
322	pp->dim[0].org =
323	pp->dim[1].org = 0.0;
324	if (sl <= ns*si.inpaspect) {
325	pp->dim[0].siz = si.inpaspect * (double)ns/sl;
326	pp->dim[1].siz = 1.0;
327	} else {
328	pp->dim[0].siz = 1.0;
329	pp->dim[1].siz = (double)sl/ns / si.inpaspect;
330	}
331	pp->dim[2].ne = si.nc;
332	pp->dim[2].siz = si.wlpart[3] - si.wlpart[0];
333	pp->dim[2].org = si.wlpart[0] + 0.5*pp->dim[2].siz/si.nc;
334	pp->dim[2].siz *= (si.nc - 1.0)/si.nc;
335	pp->dim[0].p = pp->dim[1].p = pp->dim[2].p = NULL;
336	i = nssl(si.nc+1);
337	#if PSIZWARN
338	if (i > PSIZWARN) { /* memory warning */
339	sprintf(errmsg, "hyperspectral image \"%s\" using %.1f MB of memory",
340	sname, i(1.0/(10241024)));
341	error(WARNING, errmsg);
342	}
343	#endif
344	if ((pp->arr.s = (uby8 *)malloc(i)) == NULL)
345	goto memerr;
346	for (y = ns; y-- > 0; ) /* read each scanline */
347	if (freadscolrs(pp->arr.s + ysl(si.nc+1), si.nc, sl, fp) < 0)
348	goto readerr;
349	fclose(fp);
350	i = hash(sname); /* insert in hash table */
351	pp->next = dtab[i];
352	return(dtab[i] = pp);
353	memerr:
354	error(SYSTEM, "out of memory in getspec");
355	readerr:
356	sprintf(errmsg, "bad hyperspectral image \"%s\"", pfname);
357	error(USER, errmsg);
358	return NULL; /* pro forma return */
359	}
360
361
362	void
363	freedata( /* release data array reference */
364	DATARRAY *dta
365	)
366	{
367	DATARRAY head;
368	int hval, nents;
369	DATARRAY dpl, dp;
370	int i;
371
372	if (dta == NULL) { /* free all if NULL */
373	hval = 0; nents = TABSIZ;
374	} else {
375	if (dta->next == dta) {
376	free(dta); /* unlisted temp array */
377	return;
378	}
379	hval = hash(dta->name); nents = 1;
380	if (!dta->name) { / not a data file? */
381	dta->next = dtab[hval];
382	dtab[hval] = dta; /* ...fake position */
383	}
384	}
385	while (nents--) {
386	head.next = dtab[hval];
387	dpl = &head;
388	while ((dp = dpl->next) != NULL)
389	if ((dta == NULL) \| (dta == dp)) {
390	dpl->next = dp->next;
391	free(dp->arr.p);
392	for (i = 0; i < dp->nd; i++)
393	if (dp->dim[i].p != NULL)
394	free(dp->dim[i].p);
395	freestr(dp->name);
396	free(dp);
397	} else
398	dpl = dp;
399	dtab[hval++] = head.next;
400	}
401	}
402
403
404	/* internal call to interpolate data value or vector */
405	static double
406	data_interp(DATARRAY dp, double pt, double coef, DATATYPE *rvec)
407	{
408	DATARRAY sd;
409	int stride, i;
410	double x, c0, c1, y0, y1;
411	/* unlikely, but may as well check */
412	if ((-FTINY <= coef) & (coef <= FTINY))
413	return(0.);
414	/* set up dimensions for recursion */
415	if (dp->nd > 1) {
416	sd.name = dp->name;
417	sd.type = dp->type;
418	sd.nd = dp->nd - 1;
419	memcpy(sd.dim, dp->dim+1, sd.nd*sizeof(struct dadim));
420	stride = sd.dim[i = sd.nd-1].ne + (sd.type==SPECTY);
421	while (i-- > 0)
422	stride *= sd.dim[i].ne;
423	}
424	/* get independent variable */
425	if (dp->dim[0].p == NULL) { /* evenly spaced points */
426	x = (pt[0] - dp->dim[0].org)/dp->dim[0].siz;
427	x *= (double)(dp->dim[0].ne - 1);
428	i = x;
429	if (i < 0)
430	i = 0;
431	else if (i > dp->dim[0].ne - 2)
432	i = dp->dim[0].ne - 2;
433	} else { /* unevenly spaced points */
434	int lower, upper;
435	if (dp->dim[0].siz > 0.) {
436	lower = 0;
437	upper = dp->dim[0].ne;
438	} else {
439	lower = dp->dim[0].ne;
440	upper = 0;
441	}
442	do {
443	i = (lower + upper) >> 1;
444	if (pt[0] >= dp->dim[0].p[i])
445	lower = i;
446	else
447	upper = i;
448	} while (i != (lower + upper) >> 1);
449
450	if (i > dp->dim[0].ne - 2)
451	i = dp->dim[0].ne - 2;
452
453	x = i + (pt[0] - dp->dim[0].p[i]) /
454	(dp->dim[0].p[i+1] - dp->dim[0].p[i]);
455	}
456	/*
457	* Compute interpolation coefficients:
458	* extrapolate as far as one division, then
459	* taper off harmonically to zero.
460	*/
461	if (x > i+2) {
462	c0 = 1./(i-1 - x);
463	c1 = -2.*c0;
464	} else if (x < i-1) {
465	c1 = 1./(x - i);
466	c0 = -2.*c1;
467	} else {
468	c0 = i+1 - x;
469	c1 = x - i;
470	}
471	c0 *= coef;
472	c1 *= coef;
473	/* check if vector interp */
474	if ((dp->nd == 2) & (rvec != NULL)) {
475	if (dp->type == DATATY) {
476	sd.arr.d = dp->arr.d + i*stride;
477	for (i = sd.dim[0].ne; i--; )
478	rvec[i] += c0*sd.arr.d[i]
479	+ c1*sd.arr.d[i+stride];
480	} else if (dp->type == SPECTY) {
481	double f;
482	sd.arr.s = dp->arr.s + i*stride;
483	if ((sd.arr.s[sd.dim[0].ne] > 0) & ((-FTINY>c0)\|(c0>FTINY))) {
484	f = c0 * cxponent[sd.arr.s[sd.dim[0].ne]];
485	for (i = sd.dim[0].ne; i--; )
486	rvec[i] += f*(sd.arr.s[i] + .5);
487	}
488	sd.arr.s += stride;
489	if ((sd.arr.s[sd.dim[0].ne] > 0) & ((-FTINY>c1)\|(c1>FTINY))) {
490	f = c1 * cxponent[sd.arr.s[sd.dim[0].ne]];
491	for (i = sd.dim[0].ne; i--; )
492	rvec[i] += f*(sd.arr.s[i] + .5);
493	}
494	} else {
495	sd.arr.c = dp->arr.c + i*stride;
496	for (i = sd.dim[0].ne; i--; )
497	rvec[i] += c0*colrval(sd.arr.c[i],sd.type)
498	+ c1*colrval(sd.arr.c[i+stride],sd.type);
499	}
500	return(0.); /* return value ignored */
501	}
502	/* get dependent variable */
503	if (dp->nd > 1) {
504	if (dp->type == DATATY) {
505	sd.arr.d = dp->arr.d + i*stride;
506	y0 = data_interp(&sd, pt+1, c0, rvec);
507	sd.arr.d += stride;
508	} else if (dp->type == SPECTY) {
509	sd.arr.s = dp->arr.s + i*stride;
510	y0 = data_interp(&sd, pt+1, c0, rvec);
511	sd.arr.s += stride;
512	} else {
513	sd.arr.c = dp->arr.c + i*stride;
514	y0 = data_interp(&sd, pt+1, c0, rvec);
515	sd.arr.c += stride;
516	}
517	y1 = data_interp(&sd, pt+1, c1, rvec);
518	} else { /* end of recursion */
519	if (dp->type == DATATY) {
520	y0 = dp->arr.d[i];
521	y1 = dp->arr.d[i+1];
522	} else if (dp->type == SPECTY) {
523	double f = cxponent[dp->arr.s[dp->dim[0].ne]];
524	y0 = f*(dp->arr.s[i] + 0.5);
525	y1 = f*(dp->arr.s[i+1] + 0.5);
526	} else {
527	y0 = colrval(dp->arr.c[i],dp->type);
528	y1 = colrval(dp->arr.c[i+1],dp->type);
529	}
530	y0 *= c0;
531	y1 *= c1;
532	}
533	return(y0 + y1); /* coefficients already applied */
534	}
535
536
537	double
538	datavalue( /* interpolate data value at a point */
539	DATARRAY *dp,
540	double *pt
541	)
542	{
543	return(data_interp(dp, pt, 1., NULL));
544	}
545
546
547	/* Interpolate final vector corresponding to last dimension in data array */
548	DATARRAY *
549	datavector(DATARRAY dp, double pt)
550	{
551	DATARRAY *newdp;
552
553	if (dp->nd < 2)
554	error(INTERNAL, "datavector() called with 1-D array");
555	/* create vector array */
556	newdp = (DATARRAY *)malloc(sizeof(DATARRAY) -
557	(MAXDDIM-1)*sizeof(struct dadim) +
558	sizeof(DATATYPE)*dp->dim[dp->nd-1].ne);
559	if (newdp == NULL)
560	error(SYSTEM, "out of memory in datavector");
561	newdp->next = newdp; /* flags us as temp vector */
562	newdp->name = dp->name;
563	newdp->type = DATATY;
564	newdp->nd = 1; /* vector data goes here */
565	newdp->dim[0] = dp->dim[dp->nd-1];
566	newdp->arr.d = (DATATYPE *)(newdp->dim + 1);
567	memset(newdp->arr.d, 0, sizeof(DATATYPE)*newdp->dim[0].ne);
568
569	(void)data_interp(dp, pt, 1., newdp->arr.d);
570
571	return(newdp); /* will be free'd using free() */
572	}