static int ReadAtoDArray (TblInfo *tabinfo, int row, TblArray *tabarray) {
extern int status;
int nret; /* number of elements actually read */
/* Find out how many elements there are in the ATOD array,
and allocate space for the array to be read from the table.
*/
c_tbegti (tabinfo->tp, tabinfo->cp_nelem, row, &tabarray->nelem);
if (c_iraferr())
return (status = TABLE_ERROR);
tabarray->atod = (float *) malloc (tabarray->nelem * sizeof(float));
if (tabarray->atod == NULL)
return (status = OUT_OF_MEMORY);
nret = c_tbagtr (tabinfo->tp, tabinfo->cp_atod, row,
tabarray->atod, 1, tabarray->nelem);
if ( (status = c_iraferr()) )
return (status = TABLE_ERROR);
if (nret < tabarray->nelem) {
sprintf (MsgText,
"CORRECTION array in row %d of ATODTAB is too short.",
row);
trlerror (MsgText);
free (tabarray->atod);
return (status = TABLE_ERROR);
}
return (status);
}
static int GetXDisp (char *name, ScatterFunctions *scf) {
/* arguments
char *name; i: name of CDSTAB reference file
ScatterFunctions *scf; o: data structure with scattering functions
*/
IRAFPointer tp;
IRAFPointer cp_optelem, cp_nelem, cp_cdscat;
char opt_elem[STIS_CBUF];
int row, nrows, i;
tp = c_tbtopn (name, IRAF_READ_ONLY, 0);
if (c_iraferr()) {
printf ("ERROR CDSTAB `%s' not found\n", name);
return (OPEN_FAILED);
}
nrows = c_tbpsta (tp, TBL_NROWS);
c_tbcfnd1 (tp, "OPT_ELEM", &cp_optelem);
c_tbcfnd1 (tp, "NELEM", &cp_nelem);
c_tbcfnd1 (tp, "CDSCAT", &cp_cdscat);
if (cp_optelem == 0 || cp_nelem == 0 || cp_cdscat == 0) {
printf( "ERROR Column not found in CDSTAB\n");
c_tbtclo (tp);
return (COLUMN_NOT_FOUND);
}
for (row = 1; row <= nrows ; row++) {
c_tbegtt (tp, cp_optelem, row, opt_elem, STIS_CBUF-1);
if (streq_ic (opt_elem, scf->opt_elem)) {
c_tbegti (tp, cp_nelem, row, &(scf->nxdisp));
scf->xdisp = (float *) calloc (scf->nxdisp, sizeof (float));
if (scf->xdisp == NULL )
return (OUT_OF_MEMORY);
i = c_tbagtr (tp, cp_cdscat, row, scf->xdisp, 1, scf->nxdisp);
if (c_iraferr())
return (TABLE_ERROR);
c_tbtclo (tp);
return (STIS_OK);
}
}
printf( "ERROR Row with %s optical element not found in CDSTAB\n",
opt_elem);
c_tbtclo (tp);
return (ROW_NOT_FOUND);
}
static int GetPSF (char *name, Hdr *phdr, double xsize, double ysize,
ScatterFunctions *scf,
Image *psf1, Image *psf2, Image *psf3) {
/*
char *name; i: name of TELTAB reference file
Hdr *phdr i: primary header
double xsize, ysize; i: aperture size in arcsec
ScatterFunctions *scf; o: data structure with scattering functions
Image *psf1,2,3; o: PSF images, previously initialized
*/
IRAFPointer tp;
IRAFPointer cp_refwave, cp_pscale, cp_psfdim, cp_telepsf;
int row, nrows, psfdim;
double rw, psfscale;
Image ospsf;
Image imtemp, psf;
char keyword[STIS_CBUF];
double xplate, yplate;
double sbox, lbox;
double rstart, rstop;
double frac1, frac2;
float fhold;
double sum;
int i, j, k, kk, ms, ml, ns, nl, s, l;
int ns2, nl2, s1, s2, l1, l2;
int istart, istop;
int status;
int Alloc1DImage (Image *, int);
int Alloc2DImage (Image *, int, int);
void InitImage (Image *);
void FreeImage (Image *);
/* Define plate scale. */
if (streq_ic (scf->opt_elem, "E140M"))
xplate = 0.036;
else if (streq_ic (scf->opt_elem, "E140H"))
xplate = 0.0466;
else if (streq_ic (scf->opt_elem, "E230M"))
xplate = 0.033;
else if (streq_ic (scf->opt_elem, "E230H"))
xplate = 0.0466;
else {
printf ("Non supported grating.\n");
return (ERROR_RETURN);
}
yplate = 0.029;
/* Truncate the aperture size if it extends beyond the borders
of an image.
*/
/* See if uniformly illuminated aperture was used. */
if ((status = Get_KeyS (phdr, "SCLAMP", 0, "", keyword, STIS_CBUF)))
return (status);
if (!streq_ic (keyword, "NONE")) {
ml = (int)floor (ysize / yplate);
if (ml % 2) {
status = Alloc1DImage (psf1, ml+1);
status |= Alloc1DImage (psf2, ml+1);
status |= Alloc1DImage (psf3, ml+1);
if (status)
return (status);
for (i = 1; i < ml; i++) {
psf1->pix[i] = 1.0 / ml;
psf2->pix[i] = 1.0 / ml;
psf3->pix[i] = 1.0 / ml;
}
psf1->pix[0] = 0.5 / ml;
psf1->pix[ml] = 0.5 / ml;
psf2->pix[0] = 0.5 / ml;
psf2->pix[ml] = 0.5 / ml;
psf3->pix[0] = 0.5 / ml;
psf3->pix[ml] = 0.5 / ml;
} else {
status = Alloc1DImage (psf1, ml);
status |= Alloc1DImage (psf2, ml);
status |= Alloc1DImage (psf3, ml);
if (status)
return (status);
for (i = 0; i < ml; i++) {
psf1->pix[i] = 1.0 / ml;
psf2->pix[i] = 1.0 / ml;
psf3->pix[i] = 1.0 / ml;
}
}
return (STIS_OK);
}
/* Scan reference file and process each PSF. */
tp = c_tbtopn (name, IRAF_READ_ONLY, 0);
if (c_iraferr()) {
printf ("ERROR TELTAB `%s' not found\n", name);
return (OPEN_FAILED);
}
nrows = c_tbpsta (tp, TBL_NROWS);
c_tbcfnd1 (tp, "PSFWAVE", &cp_refwave);
c_tbcfnd1 (tp, "PSCALE", &cp_pscale);
c_tbcfnd1 (tp, "PSFDIM", &cp_psfdim);
c_tbcfnd1 (tp, "TELEPSF", &cp_telepsf);
if (cp_refwave == 0 || cp_psfdim == 0 ||
cp_pscale == 0 || cp_telepsf == 0) {
printf( "ERROR Column not found in TELTAB\n");
c_tbtclo (tp);
return (COLUMN_NOT_FOUND);
}
kk = 0;
for (row = 1; row <= nrows ; row++) {
c_tbegtd (tp, cp_refwave, row, &rw);
if (c_iraferr())
return (TABLE_ERROR);
/* Matching reference wavelenghts. */
if (rw == scf->psfw[kk]) {
/* Read PSF image and associated data. */
c_tbegtd (tp, cp_pscale, row, &psfscale);
c_tbegti (tp, cp_psfdim, row, &psfdim);
InitImage (&imtemp);
if ((status = Alloc2DImage (&imtemp, psfdim, psfdim)))
return (status);
i = c_tbagtr (tp, cp_telepsf, row, imtemp.pix, 1,
imtemp.npix);
if (c_iraferr())
return (TABLE_ERROR);
/* Find peak. */
ns = imtemp.nx;
nl = imtemp.ny;
fhold = -FLT_MAX;
for (i = 0; i < ns; i++) {
for (j = 0; j < nl; j++) {
if (PIX (imtemp, i, j) > fhold) {
s = i;
l = j;
fhold = PIX (imtemp, i, j);
}
}
}
/* Determine portion of PSF that made it through aperture. */
ns2 = ((int)NINT (xsize / psfscale)) / 2;
nl2 = ((int)NINT (ysize / psfscale)) / 2;
s1 = ((s - ns2) >= 0) ? (s - ns2) : 0;
s2 = ((s + ns2) <= (ns - 1)) ? (s + ns2) : (ns - 1);
l1 = ((l - nl2) >= 0) ? (l - nl2) : 0;
l2 = ((l + nl2) <= (nl - 1)) ? (l + nl2) : (nl - 1);
/* Extract sub-image. */
InitImage (&ospsf);
if ((status = Alloc2DImage (&ospsf, s2 - s1 + 1, l2 - l1 + 1)))
return (status);
k = 0;
/* location of braces looks like a typo, but harmless */
for (j = l1; j <= l2; j++)
for (i = s1; i <= s2; i++) {
ospsf.pix[k++] = PIX (imtemp, i, j);
}
FreeImage (&imtemp);
ns = ospsf.nx;
nl = ospsf.ny;
/* # of STIS pixels (ms*ml) illuminated by aperture. */
/* modified on 2013 Nov 13 by PEH
xplate / psfscale and yplate / psfscale are the factors
by which the PSF in the _tel.fits file are oversampled.
*/
ms = (NINT (ns / (xplate / psfscale))) / 2;
ml = (NINT (nl / (yplate / psfscale))) / 2;
ms = 2 * ms + 1;
ml = 2 * ml + 1;
/* Bin oversampled PSF to STIS pixel scale. */
/* Bin columns. */
if ((status = Alloc2DImage (&imtemp, ms, nl)))
return (status);
sbox = ns / (double)ms;
for (i = 0; i < ms; i++) {
rstart = i * sbox;
rstop = (i+1) * sbox;
istart = (int) floor (rstart);
istop = (int) floor (rstop);
istop = (istop < ns) ? istop : ns-1;
frac1 = rstart - istart;
frac2 = 1.0 - (rstop - istop);
for (j = 0; j < nl; j++) {
for (k = istart+1; k < istop;
PIX (imtemp, i, j) += PIX (ospsf, k++, j));
PIX (imtemp, i, j) += PIX (ospsf, istart, j) *
(1.0 - frac1);
PIX (imtemp, i, j) += PIX (ospsf, istop, j) *
(1.0 - frac2);
}
}
FreeImage (&ospsf);
/* Bin rows. */
InitImage (&psf);
if ((status = Alloc2DImage (&psf, ms, ml)))
return (status);
lbox = nl / (double)ml;
for (j = 0; j < ml; j++) {
rstart = j * lbox;
rstop = (j+1) * lbox;
istart = (int) floor (rstart);
istop = (int) floor (rstop);
istop = (istop < nl) ? istop : nl-1;
frac1 = rstart - istart;
frac2 = 1.0 - (rstop - istop);
for (i = 0; i < ms; i++) {
for (k = istart+1; k < istop;
PIX (psf, i, j) += PIX (imtemp, i, k++));
PIX (psf, i, j) += PIX (imtemp, i, istart) *
(1.0 - frac1);
PIX (psf, i, j) += PIX (imtemp, i, istop) *
(1.0 - frac2);
}
}
FreeImage (&imtemp);
/* Normalize PSF to unit area. */
sum = 0.0;
for (i = 0; i < psf.npix; sum += psf.pix[i++]);
for (i = 0; i < psf.npix; psf.pix[i++] /= sum);
/* This awful code is a consequence of the
change in reference file format that took place
after the original code was completed.
*/
switch (kk) {
case 0:
if ((status = Alloc2DImage (psf1, psf.nx, psf.ny)))
return (status);
for (i= 0 ; i < psf1->npix; i++)
psf1->pix[i] = psf.pix[i];
break;
case 1:
if ((status = Alloc2DImage (psf2, psf.nx, psf.ny)))
return (status);
for (i= 0 ; i < psf2->npix; i++)
psf2->pix[i] = psf.pix[i];
break;
case 2:
if ((status = Alloc2DImage (psf3, psf.nx, psf.ny)))
return (status);
for (i= 0 ; i < psf3->npix; i++)
psf3->pix[i] = psf.pix[i];
break;
default:
break;
}
FreeImage (&psf);
kk++;
}
}
if (kk == 0) {
printf ("ERROR No matching rows in TELTAB `%s'\n", name);
return (TABLE_ERROR);
}
c_tbtclo (tp);
return (STIS_OK);
}
static int GetHalo (char *name, ScatterFunctions *scf,
Image *halo1, Image *halo2, Image *halo3) {
/*
char *name; i: name of HALOTAB reference file
ScatterFunctions *scf; o: data structure with scattering functions
Image *halo1,2,3; o: halo images, previously initialized
*/
IRAFPointer tp;
IRAFPointer cp_optelem, cp_refwave, cp_haldim, cp_halo;
char opt_elem[STIS_CBUF];
int row, nrows, i, status, k, haldim;
double rw;
int Alloc2DImage (Image *, int, int);
tp = c_tbtopn (name, IRAF_READ_ONLY, 0);
if (c_iraferr()) {
printf ("ERROR HALOTAB `%s' not found\n", name);
return (OPEN_FAILED);
}
nrows = c_tbpsta (tp, TBL_NROWS);
c_tbcfnd1 (tp, "OPT_ELEM", &cp_optelem);
c_tbcfnd1 (tp, "HALOWAVE", &cp_refwave);
c_tbcfnd1 (tp, "HALDIM", &cp_haldim);
c_tbcfnd1 (tp, "HALO", &cp_halo);
if (cp_optelem == 0 || cp_refwave == 0 ||
cp_haldim == 0 || cp_halo == 0) {
printf( "ERROR Column not found in HALOTAB\n");
c_tbtclo (tp);
return (COLUMN_NOT_FOUND);
}
k = 0;
for (row = 1; row <= nrows ; row++) {
c_tbegtt (tp, cp_optelem, row, opt_elem, STIS_CBUF-1);
c_tbegtd (tp, cp_refwave, row, &rw);
if (c_iraferr())
return (TABLE_ERROR);
if ((rw == scf->kernw[k]) &&
(streq_ic (opt_elem, scf->opt_elem))) {
c_tbegti (tp, cp_haldim, row, &haldim);
/* This awful code is a consequence of the
change in reference file format that took place
after the original code was completed.
*/
switch (k) {
case 0:
if ((status = Alloc2DImage (halo1, haldim, haldim)))
return (status);
i = c_tbagtr (tp, cp_halo, row, halo1->pix, 1, halo1->npix);
if (c_iraferr())
return (TABLE_ERROR);
break;
case 1:
if ((status = Alloc2DImage (halo2, haldim, haldim)))
return (status);
i = c_tbagtr (tp, cp_halo, row, halo2->pix, 1, halo2->npix);
if (c_iraferr())
return (TABLE_ERROR);
break;
case 2:
if ((status = Alloc2DImage (halo3, haldim, haldim)))
return (status);
i = c_tbagtr (tp, cp_halo, row, halo3->pix, 1, halo3->npix);
if (c_iraferr())
return (TABLE_ERROR);
break;
default:
break;
}
k++;
}
}
if (k == 0) {
printf ("ERROR No matching rows in HALOTAB `%s'\n", name);
return (TABLE_ERROR);
}
c_tbtclo (tp);
return (STIS_OK);
}
