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FEA-Bench / testbed /astropy__astropy /cextern /cfitsio /lib /getcolsb.c
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/* This file, getcolsb.c, contains routines that read data elements from */
/* a FITS image or table, with signed char (signed byte) data type. */
/* The FITSIO software was written by William Pence at the High Energy */
/* Astrophysic Science Archive Research Center (HEASARC) at the NASA */
/* Goddard Space Flight Center. */
#include <math.h>
#include <stdlib.h>
#include <limits.h>
#include <string.h>
#include "fitsio2.h"
/*--------------------------------------------------------------------------*/
int ffgpvsb(fitsfile *fptr, /* I - FITS file pointer */
 long group, /* I - group to read (1 = 1st group) */
 LONGLONG firstelem, /* I - first vector element to read (1 = 1st) */
 LONGLONG nelem, /* I - number of values to read */
 signed char nulval, /* I - value for undefined pixels */
 signed char *array, /* O - array of values that are returned */
 int *anynul, /* O - set to 1 if any values are null; else 0 */
 int *status) /* IO - error status */
/*
 Read an array of values from the primary array. Data conversion
 and scaling will be performed if necessary (e.g, if the datatype of
 the FITS array is not the same as the array being read).
 Undefined elements will be set equal to NULVAL, unless NULVAL=0
 in which case no checking for undefined values will be performed.
 ANYNUL is returned with a value of .true. if any pixels are undefined.
*/
{
 long row;
 char cdummy;
 int nullcheck = 1;
 signed char nullvalue;
if (fits_is_compressed_image(fptr, status))
 {
 /* this is a compressed image in a binary table */
 nullvalue = nulval; /* set local variable */
fits_read_compressed_pixels(fptr, TSBYTE, firstelem, nelem,
 nullcheck, &nullvalue, array, NULL, anynul, status);
 return(*status);
 }
 /*
 the primary array is represented as a binary table:
 each group of the primary array is a row in the table,
 where the first column contains the group parameters
 and the second column contains the image itself.
 */
row=maxvalue(1,group);
ffgclsb(fptr, 2, row, firstelem, nelem, 1, 1, nulval,
 array, &cdummy, anynul, status);
 return(*status);
}
/*--------------------------------------------------------------------------*/
int ffgpfsb(fitsfile *fptr, /* I - FITS file pointer */
 long group, /* I - group to read (1 = 1st group) */
 LONGLONG firstelem, /* I - first vector element to read (1 = 1st) */
 LONGLONG nelem, /* I - number of values to read */
 signed char *array, /* O - array of values that are returned */
 char *nularray, /* O - array of null pixel flags */
 int *anynul, /* O - set to 1 if any values are null; else 0 */
 int *status) /* IO - error status */
/*
 Read an array of values from the primary array. Data conversion
 and scaling will be performed if necessary (e.g, if the datatype of
 the FITS array is not the same as the array being read).
 Any undefined pixels in the returned array will be set = 0 and the
corresponding nularray value will be set = 1.
 ANYNUL is returned with a value of .true. if any pixels are undefined.
*/
{
 long row;
 int nullcheck = 2;
if (fits_is_compressed_image(fptr, status))
 {
 /* this is a compressed image in a binary table */
fits_read_compressed_pixels(fptr, TSBYTE, firstelem, nelem,
 nullcheck, NULL, array, nularray, anynul, status);
 return(*status);
 }
/*
 the primary array is represented as a binary table:
 each group of the primary array is a row in the table,
 where the first column contains the group parameters
 and the second column contains the image itself.
 */
row=maxvalue(1,group);
ffgclsb(fptr, 2, row, firstelem, nelem, 1, 2, 0,
 array, nularray, anynul, status);
 return(*status);
}
/*--------------------------------------------------------------------------*/
int ffg2dsb(fitsfile *fptr, /* I - FITS file pointer */
 long group, /* I - group to read (1 = 1st group) */
 signed char nulval, /* set undefined pixels equal to this */
 LONGLONG ncols, /* I - number of pixels in each row of array */
 LONGLONG naxis1, /* I - FITS image NAXIS1 value */
 LONGLONG naxis2, /* I - FITS image NAXIS2 value */
 signed char *array, /* O - array to be filled and returned */
 int *anynul, /* O - set to 1 if any values are null; else 0 */
 int *status) /* IO - error status */
/*
 Read an entire 2-D array of values to the primary array. Data conversion
 and scaling will be performed if necessary (e.g, if the datatype of the
 FITS array is not the same as the array being read). Any null
 values in the array will be set equal to the value of nulval, unless
 nulval = 0 in which case no null checking will be performed.
*/
{
 /* call the 3D reading routine, with the 3rd dimension = 1 */
ffg3dsb(fptr, group, nulval, ncols, naxis2, naxis1, naxis2, 1, array,
anynul, status);
return(*status);
}
/*--------------------------------------------------------------------------*/
int ffg3dsb(fitsfile *fptr, /* I - FITS file pointer */
 long group, /* I - group to read (1 = 1st group) */
 signed char nulval, /* set undefined pixels equal to this */
 LONGLONG ncols, /* I - number of pixels in each row of array */
 LONGLONG nrows, /* I - number of rows in each plane of array */
 LONGLONG naxis1, /* I - FITS image NAXIS1 value */
 LONGLONG naxis2, /* I - FITS image NAXIS2 value */
 LONGLONG naxis3, /* I - FITS image NAXIS3 value */
 signed char *array, /* O - array to be filled and returned */
 int *anynul, /* O - set to 1 if any values are null; else 0 */
 int *status) /* IO - error status */
/*
 Read an entire 3-D array of values to the primary array. Data conversion
 and scaling will be performed if necessary (e.g, if the datatype of the
 FITS array is not the same as the array being read). Any null
 values in the array will be set equal to the value of nulval, unless
 nulval = 0 in which case no null checking will be performed.
*/
{
 long tablerow, ii, jj;
 LONGLONG nfits, narray;
 char cdummy;
 int nullcheck = 1;
 long inc[] = {1,1,1};
 LONGLONG fpixel[] = {1,1,1};
 LONGLONG lpixel[3];
 signed char nullvalue;
if (fits_is_compressed_image(fptr, status))
 {
 /* this is a compressed image in a binary table */
lpixel[0] = ncols;
 lpixel[1] = nrows;
 lpixel[2] = naxis3;
 nullvalue = nulval; /* set local variable */
fits_read_compressed_img(fptr, TSBYTE, fpixel, lpixel, inc,
 nullcheck, &nullvalue, array, NULL, anynul, status);
 return(*status);
 }
/*
 the primary array is represented as a binary table:
 each group of the primary array is a row in the table,
 where the first column contains the group parameters
 and the second column contains the image itself.
 */
 tablerow=maxvalue(1,group);
if (ncols == naxis1 && nrows == naxis2) /* arrays have same size? */
 {
 /* all the image pixels are contiguous, so read all at once */
 ffgclsb(fptr, 2, tablerow, 1, naxis1 * naxis2 * naxis3, 1, 1, nulval,
 array, &cdummy, anynul, status);
 return(*status);
 }
if (ncols < naxis1 || nrows < naxis2)
 return(*status = BAD_DIMEN);
nfits = 1; /* next pixel in FITS image to read */
 narray = 0; /* next pixel in output array to be filled */
/* loop over naxis3 planes in the data cube */
 for (jj = 0; jj < naxis3; jj++)
 {
 /* loop over the naxis2 rows in the FITS image, */
 /* reading naxis1 pixels to each row */
for (ii = 0; ii < naxis2; ii++)
 {
 if (ffgclsb(fptr, 2, tablerow, nfits, naxis1, 1, 1, nulval,
 &array[narray], &cdummy, anynul, status) > 0)
 return(*status);
nfits += naxis1;
 narray += ncols;
 }
 narray += (nrows - naxis2) * ncols;
 }
return(*status);
}
/*--------------------------------------------------------------------------*/
int ffgsvsb(fitsfile *fptr, /* I - FITS file pointer */
 int colnum, /* I - number of the column to read (1 = 1st) */
 int naxis, /* I - number of dimensions in the FITS array */
 long *naxes, /* I - size of each dimension */
 long *blc, /* I - 'bottom left corner' of the subsection */
 long *trc, /* I - 'top right corner' of the subsection */
 long *inc, /* I - increment to be applied in each dimension */
 signed char nulval, /* I - value to set undefined pixels */
 signed char *array, /* O - array to be filled and returned */
 int *anynul, /* O - set to 1 if any values are null; else 0 */
 int *status) /* IO - error status */
/*
 Read a subsection of data values from an image or a table column.
 This routine is set up to handle a maximum of nine dimensions.
*/
{
 long ii, i0, i1, i2, i3, i4, i5, i6, i7, i8, row, rstr, rstp, rinc;
 long str[9], stp[9], incr[9], dir[9];
 long nelem, nultyp, ninc, numcol;
 LONGLONG felem, dsize[10], blcll[9], trcll[9];
 int hdutype, anyf;
 char ldummy, msg[FLEN_ERRMSG];
 int nullcheck = 1;
 signed char nullvalue;
if (naxis < 1 || naxis > 9)
 {
 snprintf(msg, FLEN_ERRMSG,"NAXIS = %d in call to ffgsvsb is out of range", naxis);
 ffpmsg(msg);
 return(*status = BAD_DIMEN);
 }
if (fits_is_compressed_image(fptr, status))
 {
 /* this is a compressed image in a binary table */
for (ii=0; ii < naxis; ii++) {
 blcll[ii] = blc[ii];
 trcll[ii] = trc[ii];
 }
nullvalue = nulval; /* set local variable */
fits_read_compressed_img(fptr, TSBYTE, blcll, trcll, inc,
 nullcheck, &nullvalue, array, NULL, anynul, status);
 return(*status);
 }
/*
 if this is a primary array, then the input COLNUM parameter should
 be interpreted as the row number, and we will alway read the image
 data from column 2 (any group parameters are in column 1).
*/
 if (ffghdt(fptr, &hdutype, status) > 0)
 return(*status);
if (hdutype == IMAGE_HDU)
 {
 /* this is a primary array, or image extension */
 if (colnum == 0)
 {
 rstr = 1;
 rstp = 1;
 }
 else
 {
 rstr = colnum;
 rstp = colnum;
 }
 rinc = 1;
 numcol = 2;
 }
 else
 {
 /* this is a table, so the row info is in the (naxis+1) elements */
 rstr = blc[naxis];
 rstp = trc[naxis];
 rinc = inc[naxis];
 numcol = colnum;
 }
nultyp = 1;
 if (anynul)
 *anynul = FALSE;
i0 = 0;
 for (ii = 0; ii < 9; ii++)
 {
 str[ii] = 1;
 stp[ii] = 1;
 incr[ii] = 1;
 dsize[ii] = 1;
 dir[ii] = 1;
 }
for (ii = 0; ii < naxis; ii++)
 {
 if (trc[ii] < blc[ii])
 {
 if (hdutype == IMAGE_HDU)
 {
 dir[ii] = -1;
 }
 else
 {
 snprintf(msg, FLEN_ERRMSG,"ffgsvsb: illegal range specified for axis %ld", ii + 1);
 ffpmsg(msg);
 return(*status = BAD_PIX_NUM);
 }
 }
str[ii] = blc[ii];
 stp[ii] = trc[ii];
 incr[ii] = inc[ii];
 dsize[ii + 1] = dsize[ii] * naxes[ii];
 dsize[ii] = dsize[ii] * dir[ii];
 }
 dsize[naxis] = dsize[naxis] * dir[naxis];
if (naxis == 1 && naxes[0] == 1)
 {
 /* This is not a vector column, so read all the rows at once */
 nelem = (rstp - rstr) / rinc + 1;
 ninc = rinc;
 rstp = rstr;
 }
 else
 {
 /* have to read each row individually, in all dimensions */
 nelem = (stp[0]*dir[0] - str[0]*dir[0]) / inc[0] + 1;
 ninc = incr[0] * dir[0];
 }
for (row = rstr; row <= rstp; row += rinc)
 {
 for (i8 = str[8]*dir[8]; i8 <= stp[8]*dir[8]; i8 += incr[8])
 {
 for (i7 = str[7]*dir[7]; i7 <= stp[7]*dir[7]; i7 += incr[7])
 {
 for (i6 = str[6]*dir[6]; i6 <= stp[6]*dir[6]; i6 += incr[6])
 {
 for (i5 = str[5]*dir[5]; i5 <= stp[5]*dir[5]; i5 += incr[5])
 {
 for (i4 = str[4]*dir[4]; i4 <= stp[4]*dir[4]; i4 += incr[4])
 {
 for (i3 = str[3]*dir[3]; i3 <= stp[3]*dir[3]; i3 += incr[3])
 {
 for (i2 = str[2]*dir[2]; i2 <= stp[2]*dir[2]; i2 += incr[2])
 {
 for (i1 = str[1]*dir[1]; i1 <= stp[1]*dir[1]; i1 += incr[1])
 {
felem=str[0] + (i1 - dir[1]) * dsize[1] + (i2 - dir[2]) * dsize[2] +
(i3 - dir[3]) * dsize[3] + (i4 - dir[4]) * dsize[4] +
 (i5 - dir[5]) * dsize[5] + (i6 - dir[6]) * dsize[6] +
 (i7 - dir[7]) * dsize[7] + (i8 - dir[8]) * dsize[8];
if ( ffgclsb(fptr, numcol, row, felem, nelem, ninc, nultyp,
 nulval, &array[i0], &ldummy, &anyf, status) > 0)
 return(*status);
if (anyf && anynul)
 *anynul = TRUE;
i0 += nelem;
 }
 }
 }
 }
 }
 }
 }
 }
 }
 return(*status);
}
/*--------------------------------------------------------------------------*/
int ffgsfsb(fitsfile *fptr, /* I - FITS file pointer */
 int colnum, /* I - number of the column to read (1 = 1st) */
 int naxis, /* I - number of dimensions in the FITS array */
 long *naxes, /* I - size of each dimension */
 long *blc, /* I - 'bottom left corner' of the subsection */
 long *trc, /* I - 'top right corner' of the subsection */
 long *inc, /* I - increment to be applied in each dimension */
 signed char *array, /* O - array to be filled and returned */
 char *flagval, /* O - set to 1 if corresponding value is null */
 int *anynul, /* O - set to 1 if any values are null; else 0 */
 int *status) /* IO - error status */
/*
 Read a subsection of data values from an image or a table column.
 This routine is set up to handle a maximum of nine dimensions.
*/
{
 long ii,i0, i1,i2,i3,i4,i5,i6,i7,i8,row,rstr,rstp,rinc;
 long str[9],stp[9],incr[9],dsize[10];
 LONGLONG blcll[9], trcll[9];
 long felem, nelem, nultyp, ninc, numcol;
 int hdutype, anyf;
 signed char nulval = 0;
 char msg[FLEN_ERRMSG];
 int nullcheck = 2;
if (naxis < 1 || naxis > 9)
 {
 snprintf(msg, FLEN_ERRMSG,"NAXIS = %d in call to ffgsvsb is out of range", naxis);
 ffpmsg(msg);
 return(*status = BAD_DIMEN);
 }
if (fits_is_compressed_image(fptr, status))
 {
 /* this is a compressed image in a binary table */
for (ii=0; ii < naxis; ii++) {
 blcll[ii] = blc[ii];
 trcll[ii] = trc[ii];
 }
fits_read_compressed_img(fptr, TSBYTE, blcll, trcll, inc,
 nullcheck, NULL, array, flagval, anynul, status);
 return(*status);
 }
/*
 if this is a primary array, then the input COLNUM parameter should
 be interpreted as the row number, and we will alway read the image
 data from column 2 (any group parameters are in column 1).
*/
 if (ffghdt(fptr, &hdutype, status) > 0)
 return(*status);
if (hdutype == IMAGE_HDU)
 {
 /* this is a primary array, or image extension */
 if (colnum == 0)
 {
 rstr = 1;
 rstp = 1;
 }
 else
 {
 rstr = colnum;
 rstp = colnum;
 }
 rinc = 1;
 numcol = 2;
 }
 else
 {
 /* this is a table, so the row info is in the (naxis+1) elements */
 rstr = blc[naxis];
 rstp = trc[naxis];
 rinc = inc[naxis];
 numcol = colnum;
 }
nultyp = 2;
 if (anynul)
 *anynul = FALSE;
i0 = 0;
 for (ii = 0; ii < 9; ii++)
 {
 str[ii] = 1;
 stp[ii] = 1;
 incr[ii] = 1;
 dsize[ii] = 1;
 }
for (ii = 0; ii < naxis; ii++)
 {
 if (trc[ii] < blc[ii])
 {
 snprintf(msg, FLEN_ERRMSG,"ffgsvsb: illegal range specified for axis %ld", ii + 1);
 ffpmsg(msg);
 return(*status = BAD_PIX_NUM);
 }
str[ii] = blc[ii];
 stp[ii] = trc[ii];
 incr[ii] = inc[ii];
 dsize[ii + 1] = dsize[ii] * naxes[ii];
 }
if (naxis == 1 && naxes[0] == 1)
 {
 /* This is not a vector column, so read all the rows at once */
 nelem = (rstp - rstr) / rinc + 1;
 ninc = rinc;
 rstp = rstr;
 }
 else
 {
 /* have to read each row individually, in all dimensions */
 nelem = (stp[0] - str[0]) / inc[0] + 1;
 ninc = incr[0];
 }
for (row = rstr; row <= rstp; row += rinc)
 {
 for (i8 = str[8]; i8 <= stp[8]; i8 += incr[8])
 {
 for (i7 = str[7]; i7 <= stp[7]; i7 += incr[7])
 {
 for (i6 = str[6]; i6 <= stp[6]; i6 += incr[6])
 {
 for (i5 = str[5]; i5 <= stp[5]; i5 += incr[5])
 {
 for (i4 = str[4]; i4 <= stp[4]; i4 += incr[4])
 {
 for (i3 = str[3]; i3 <= stp[3]; i3 += incr[3])
 {
 for (i2 = str[2]; i2 <= stp[2]; i2 += incr[2])
 {
 for (i1 = str[1]; i1 <= stp[1]; i1 += incr[1])
 {
 felem=str[0] + (i1 - 1) * dsize[1] + (i2 - 1) * dsize[2] +
(i3 - 1) * dsize[3] + (i4 - 1) * dsize[4] +
 (i5 - 1) * dsize[5] + (i6 - 1) * dsize[6] +
 (i7 - 1) * dsize[7] + (i8 - 1) * dsize[8];
if ( ffgclsb(fptr, numcol, row, felem, nelem, ninc, nultyp,
 nulval, &array[i0], &flagval[i0], &anyf, status) > 0)
 return(*status);
if (anyf && anynul)
 *anynul = TRUE;
i0 += nelem;
 }
 }
 }
 }
 }
 }
 }
 }
 }
 return(*status);
}
/*--------------------------------------------------------------------------*/
int ffggpsb( fitsfile *fptr, /* I - FITS file pointer */
 long group, /* I - group to read (1 = 1st group) */
 long firstelem, /* I - first vector element to read (1 = 1st) */
 long nelem, /* I - number of values to read */
 signed char *array, /* O - array of values that are returned */
 int *status) /* IO - error status */
/*
 Read an array of group parameters from the primary array. Data conversion
 and scaling will be performed if necessary (e.g, if the datatype of
 the FITS array is not the same as the array being read).
*/
{
 long row;
 int idummy;
 char cdummy;
 /*
 the primary array is represented as a binary table:
 each group of the primary array is a row in the table,
 where the first column contains the group parameters
 and the second column contains the image itself.
 */
row=maxvalue(1,group);
ffgclsb(fptr, 1, row, firstelem, nelem, 1, 1, 0,
 array, &cdummy, &idummy, status);
 return(*status);
}
/*--------------------------------------------------------------------------*/
int ffgcvsb(fitsfile *fptr, /* I - FITS file pointer */
 int colnum, /* I - number of column to read (1 = 1st col) */
 LONGLONG firstrow, /* I - first row to read (1 = 1st row) */
 LONGLONG firstelem, /* I - first vector element to read (1 = 1st) */
 LONGLONG nelem, /* I - number of values to read */
 signed char nulval, /* I - value for null pixels */
 signed char *array, /* O - array of values that are read */
 int *anynul, /* O - set to 1 if any values are null; else 0 */
 int *status) /* IO - error status */
/*
 Read an array of values from a column in the current FITS HDU. Automatic
 datatype conversion will be performed if the datatype of the column does not
 match the datatype of the array parameter. The output values will be scaled
by the FITS TSCALn and TZEROn values if these values have been defined.
 Any undefined pixels will be set equal to the value of 'nulval' unless
 nulval = 0 in which case no checks for undefined pixels will be made.
*/
{
 char cdummy;
ffgclsb(fptr, colnum, firstrow, firstelem, nelem, 1, 1, nulval,
 array, &cdummy, anynul, status);
 return(*status);
}
/*--------------------------------------------------------------------------*/
int ffgcfsb(fitsfile *fptr, /* I - FITS file pointer */
 int colnum, /* I - number of column to read (1 = 1st col) */
 LONGLONG firstrow, /* I - first row to read (1 = 1st row) */
 LONGLONG firstelem, /* I - first vector element to read (1 = 1st) */
 LONGLONG nelem, /* I - number of values to read */
 signed char *array, /* O - array of values that are read */
 char *nularray, /* O - array of flags: 1 if null pixel; else 0 */
 int *anynul, /* O - set to 1 if any values are null; else 0 */
 int *status) /* IO - error status */
/*
 Read an array of values from a column in the current FITS HDU. Automatic
 datatype conversion will be performed if the datatype of the column does not
 match the datatype of the array parameter. The output values will be scaled
by the FITS TSCALn and TZEROn values if these values have been defined.
 Nularray will be set = 1 if the corresponding array pixel is undefined,
otherwise nularray will = 0.
*/
{
 signed char dummy = 0;
ffgclsb(fptr, colnum, firstrow, firstelem, nelem, 1, 2, dummy,
 array, nularray, anynul, status);
 return(*status);
}
/*--------------------------------------------------------------------------*/
int ffgclsb(fitsfile *fptr, /* I - FITS file pointer */
 int colnum, /* I - number of column to read (1 = 1st col) */
 LONGLONG firstrow, /* I - first row to read (1 = 1st row) */
 LONGLONG firstelem, /* I - first vector element to read (1 = 1st) */
 LONGLONG nelem, /* I - number of values to read */
 long elemincre, /* I - pixel increment; e.g., 2 = every other */
 int nultyp, /* I - null value handling code: */
 /* 1: set undefined pixels = nulval */
 /* 2: set nularray=1 for undefined pixels */
 signed char nulval, /* I - value for null pixels if nultyp = 1 */
 signed char *array, /* O - array of values that are read */
 char *nularray, /* O - array of flags = 1 if nultyp = 2 */
 int *anynul, /* O - set to 1 if any values are null; else 0 */
 int *status) /* IO - error status */
/*
 Read an array of values from a column in the current FITS HDU.
 The column number may refer to a real column in an ASCII or binary table,
or it may refer be a virtual column in a 1 or more grouped FITS primary
 array or image extension. FITSIO treats a primary array as a binary table
 with 2 vector columns: the first column contains the group parameters (often
 with length = 0) and the second column contains the array of image pixels.
 Each row of the table represents a group in the case of multigroup FITS
 images.
 The output array of values will be converted from the datatype of the column
and will be scaled by the FITS TSCALn and TZEROn values if necessary.
*/
{
 double scale, zero, power = 1., dtemp;
 int tcode, maxelem, hdutype, xcode, decimals;
 long twidth, incre;
 long ii, xwidth, ntodo;
 int nulcheck, readcheck = 0;
 LONGLONG repeat, startpos, elemnum, readptr, tnull;
 LONGLONG rowlen, rownum, remain, next, rowincre;
 char tform[20];
 char message[FLEN_ERRMSG];
 char snull[20]; /* the FITS null value if reading from ASCII table */
double cbuff[DBUFFSIZE / sizeof(double)]; /* align cbuff on word boundary */
 void *buffer;
union u_tag {
 char charval;
 signed char scharval;
 } u;
if (*status > 0 || nelem == 0) /* inherit input status value if > 0 */
 return(*status);
buffer = cbuff;
if (anynul)
 *anynul = 0;
if (nultyp == 2)
memset(nularray, 0, (size_t) nelem); /* initialize nullarray */
/*---------------------------------------------------*/
 /* Check input and get parameters about the column: */
 /*---------------------------------------------------*/
 if (elemincre < 0)
 readcheck = -1; /* don't do range checking in this case */
ffgcprll( fptr, colnum, firstrow, firstelem, nelem, readcheck, &scale, &zero,
 tform, &twidth, &tcode, &maxelem, &startpos, &elemnum, &incre,
 &repeat, &rowlen, &hdutype, &tnull, snull, status);
/* special case: read column of T/F logicals */
 if (tcode == TLOGICAL && elemincre == 1)
 {
 u.scharval = nulval;
 ffgcll(fptr, colnum, firstrow, firstelem, nelem, nultyp,
 u.charval, (char *) array, nularray, anynul, status);
return(*status);
 }
if (strchr(tform,'A') != NULL)
{
 if (*status == BAD_ELEM_NUM)
 {
 /* ignore this error message */
 *status = 0;
 ffcmsg(); /* clear error stack */
 }
/* interpret a 'A' ASCII column as a 'B' byte column ('8A' == '8B') */
 /* This is an undocumented 'feature' in CFITSIO */
/* we have to reset some of the values returned by ffgcpr */
tcode = TBYTE;
 incre = 1; /* each element is 1 byte wide */
 repeat = twidth; /* total no. of chars in the col */
 twidth = 1; /* width of each element */
 scale = 1.0; /* no scaling */
 zero = 0.0;
 tnull = NULL_UNDEFINED; /* don't test for nulls */
 maxelem = DBUFFSIZE;
 }
if (*status > 0)
 return(*status);
incre *= elemincre; /* multiply incre to just get every nth pixel */
if (tcode == TSTRING && hdutype == ASCII_TBL) /* setup for ASCII tables */
 {
 /* get the number of implied decimal places if no explicit decmal point */
 ffasfm(tform, &xcode, &xwidth, &decimals, status);
for(ii = 0; ii < decimals; ii++)
 power *= 10.;
 }
 /*------------------------------------------------------------------*/
 /* Decide whether to check for null values in the input FITS file: */
 /*------------------------------------------------------------------*/
 nulcheck = nultyp; /* by default, check for null values in the FITS file */
if (nultyp == 1 && nulval == 0)
 nulcheck = 0; /* calling routine does not want to check for nulls */
else if (tcode%10 == 1 && /* if reading an integer column, and */
tnull == NULL_UNDEFINED) /* if a null value is not defined, */
 nulcheck = 0; /* then do not check for null values. */
else if (tcode == TSHORT && (tnull > SHRT_MAX || tnull < SHRT_MIN) )
 nulcheck = 0; /* Impossible null value */
else if (tcode == TBYTE && (tnull > 255 || tnull < 0) )
 nulcheck = 0; /* Impossible null value */
else if (tcode == TSTRING && snull[0] == ASCII_NULL_UNDEFINED)
 nulcheck = 0;
/*---------------------------------------------------------------------*/
 /* Now read the pixels from the FITS column. If the column does not */
 /* have the same datatype as the output array, then we have to read */
 /* the raw values into a temporary buffer (of limited size). In */
 /* the case of a vector colum read only 1 vector of values at a time */
 /* then skip to the next row if more values need to be read. */
 /* After reading the raw values, then call the fffXXYY routine to (1) */
 /* test for undefined values, (2) convert the datatype if necessary, */
 /* and (3) scale the values by the FITS TSCALn and TZEROn linear */
 /* scaling parameters. */
 /*---------------------------------------------------------------------*/
 remain = nelem; /* remaining number of values to read */
 next = 0; /* next element in array to be read */
 rownum = 0; /* row number, relative to firstrow */
while (remain)
 {
 /* limit the number of pixels to read at one time to the number that
 will fit in the buffer or to the number of pixels that remain in
 the current vector, which ever is smaller.
 */
 ntodo = (long) minvalue(remain, maxelem);
 if (elemincre >= 0)
 {
 ntodo = (long) minvalue(ntodo, ((repeat - elemnum - 1)/elemincre +1));
 }
 else
 {
 ntodo = (long) minvalue(ntodo, (elemnum/(-elemincre) +1));
 }
readptr = startpos + (rownum * rowlen) + (elemnum * (incre / elemincre));
switch (tcode)
{
 case (TBYTE):
 ffgi1b(fptr, readptr, ntodo, incre, (unsigned char *) &array[next], status);
 fffi1s1((unsigned char *)&array[next], ntodo, scale, zero,
 nulcheck, (unsigned char) tnull, nulval, &nularray[next],
anynul, &array[next], status);
 break;
 case (TSHORT):
 ffgi2b(fptr, readptr, ntodo, incre, (short *) buffer, status);
 fffi2s1((short *) buffer, ntodo, scale, zero, nulcheck,
(short) tnull, nulval, &nularray[next], anynul,
&array[next], status);
 break;
 case (TLONG):
 ffgi4b(fptr, readptr, ntodo, incre, (INT32BIT *) buffer,
 status);
 fffi4s1((INT32BIT *) buffer, ntodo, scale, zero, nulcheck,
(INT32BIT) tnull, nulval, &nularray[next], anynul,
&array[next], status);
 break;
 case (TLONGLONG):
 ffgi8b(fptr, readptr, ntodo, incre, (long *) buffer, status);
 fffi8s1( (LONGLONG *) buffer, ntodo, scale, zero,
nulcheck, tnull, nulval, &nularray[next],
anynul, &array[next], status);
 break;
 case (TFLOAT):
 ffgr4b(fptr, readptr, ntodo, incre, (float *) buffer, status);
 fffr4s1((float *) buffer, ntodo, scale, zero, nulcheck,
nulval, &nularray[next], anynul,
&array[next], status);
 break;
 case (TDOUBLE):
 ffgr8b(fptr, readptr, ntodo, incre, (double *) buffer, status);
 fffr8s1((double *) buffer, ntodo, scale, zero, nulcheck,
nulval, &nularray[next], anynul,
&array[next], status);
 break;
 case (TSTRING):
 ffmbyt(fptr, readptr, REPORT_EOF, status);
if (incre == twidth) /* contiguous bytes */
 ffgbyt(fptr, ntodo * twidth, buffer, status);
 else
 ffgbytoff(fptr, twidth, ntodo, incre - twidth, buffer,
 status);
/* interpret the string as an ASCII formated number */
 fffstrs1((char *) buffer, ntodo, scale, zero, twidth, power,
 nulcheck, snull, nulval, &nularray[next], anynul,
 &array[next], status);
 break;
default: /* error trap for invalid column format */
 snprintf(message, FLEN_ERRMSG,
 "Cannot read bytes from column %d which has format %s",
 colnum, tform);
 ffpmsg(message);
 if (hdutype == ASCII_TBL)
 return(*status = BAD_ATABLE_FORMAT);
 else
 return(*status = BAD_BTABLE_FORMAT);
} /* End of switch block */
/*-------------------------*/
 /* Check for fatal error */
 /*-------------------------*/
 if (*status > 0) /* test for error during previous read operation */
 {
 dtemp = (double) next;
 if (hdutype > 0)
 snprintf(message,FLEN_ERRMSG,
 "Error reading elements %.0f thru %.0f from column %d (ffgclsb).",
 dtemp+1., dtemp+ntodo, colnum);
 else
 snprintf(message,FLEN_ERRMSG,
 "Error reading elements %.0f thru %.0f from image (ffgclsb).",
 dtemp+1., dtemp+ntodo);
ffpmsg(message);
 return(*status);
 }
/*--------------------------------------------*/
 /* increment the counters for the next loop */
 /*--------------------------------------------*/
 remain -= ntodo;
 if (remain)
 {
 next += ntodo;
 elemnum = elemnum + (ntodo * elemincre);
if (elemnum >= repeat) /* completed a row; start on later row */
 {
 rowincre = elemnum / repeat;
 rownum += rowincre;
 elemnum = elemnum - (rowincre * repeat);
 }
 else if (elemnum < 0) /* completed a row; start on a previous row */
 {
 rowincre = (-elemnum - 1) / repeat + 1;
 rownum -= rowincre;
 elemnum = (rowincre * repeat) + elemnum;
 }
 }
 } /* End of main while Loop */
/*--------------------------------*/
 /* check for numerical overflow */
 /*--------------------------------*/
 if (*status == OVERFLOW_ERR)
 {
 ffpmsg(
 "Numerical overflow during type conversion while reading FITS data.");
 *status = NUM_OVERFLOW;
 }
return(*status);
}
/*--------------------------------------------------------------------------*/
int fffi1s1(unsigned char *input, /* I - array of values to be converted */
 long ntodo, /* I - number of elements in the array */
 double scale, /* I - FITS TSCALn or BSCALE value */
 double zero, /* I - FITS TZEROn or BZERO value */
 int nullcheck, /* I - null checking code; 0 = don't check */
 /* 1:set null pixels = nullval */
 /* 2: if null pixel, set nullarray = 1 */
 unsigned char tnull, /* I - value of FITS TNULLn keyword if any */
 signed char nullval, /* I - set null pixels, if nullcheck = 1 */
 char *nullarray, /* I - bad pixel array, if nullcheck = 2 */
 int *anynull, /* O - set to 1 if any pixels are null */
 signed char *output, /* O - array of converted pixels */
 int *status) /* IO - error status */
/*
 Copy input to output following reading of the input from a FITS file.
 Check for null values and do datatype conversion and scaling if required.
 The nullcheck code value determines how any null values in the input array
 are treated. A null value is an input pixel that is equal to tnull. If
nullcheck = 0, then no checking for nulls is performed and any null values
 will be transformed just like any other pixel. If nullcheck = 1, then the
 output pixel will be set = nullval if the corresponding input pixel is null.
 If nullcheck = 2, then if the pixel is null then the corresponding value of
 nullarray will be set to 1; the value of nullarray for non-null pixels
will = 0. The anynull parameter will be set = 1 if any of the returned
 pixels are null, otherwise anynull will be returned with a value = 0;
*/
{
 long ii;
 double dvalue;
if (nullcheck == 0) /* no null checking required */
 {
 if (scale == 1. && zero == -128.)
 {
 /* Instead of subtracting 128, it is more efficient */
 /* to just flip the sign bit with the XOR operator */
for (ii = 0; ii < ntodo; ii++)
 output[ii] = ( *(signed char *) &input[ii] ) ^ 0x80;
 }
 else if (scale == 1. && zero == 0.) /* no scaling */
 {
for (ii = 0; ii < ntodo; ii++)
 {
 if (input[ii] > 127)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 output[ii] = (signed char) input[ii]; /* copy input */
 }
 }
 else /* must scale the data */
 {
for (ii = 0; ii < ntodo; ii++)
 {
 dvalue = input[ii] * scale + zero;
if (dvalue < DSCHAR_MIN)
 {
 *status = OVERFLOW_ERR;
 output[ii] = -128;
 }
 else if (dvalue > DSCHAR_MAX)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 output[ii] = (signed char) dvalue;
 }
 }
 }
 else /* must check for null values */
 {
 if (scale == 1. && zero == -128.)
 {
 /* Instead of subtracting 128, it is more efficient */
 /* to just flip the sign bit with the XOR operator */
for (ii = 0; ii < ntodo; ii++)
 {
 if (input[ii] == tnull)
 {
 *anynull = 1;
 if (nullcheck == 1)
 output[ii] = nullval;
 else
 nullarray[ii] = 1;
 }
 else
 output[ii] = ( *(signed char *) &input[ii] ) ^ 0x80;
 }
 }
 else if (scale == 1. && zero == 0.) /* no scaling */
 {
for (ii = 0; ii < ntodo; ii++)
 {
 if (input[ii] == tnull)
 {
 *anynull = 1;
 if (nullcheck == 1)
 output[ii] = nullval;
 else
 nullarray[ii] = 1;
 }
 else
 output[ii] = (signed char) input[ii];
 }
 }
 else /* must scale the data */
 {
 for (ii = 0; ii < ntodo; ii++)
 {
 if (input[ii] == tnull)
 {
 *anynull = 1;
 if (nullcheck == 1)
 output[ii] = nullval;
 else
 nullarray[ii] = 1;
 }
 else
 {
 dvalue = input[ii] * scale + zero;
if (dvalue < DSCHAR_MIN)
 {
 *status = OVERFLOW_ERR;
 output[ii] = -128;
 }
 else if (dvalue > DSCHAR_MAX)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 output[ii] = (signed char) dvalue;
 }
 }
 }
 }
 return(*status);
}
/*--------------------------------------------------------------------------*/
int fffi2s1(short *input, /* I - array of values to be converted */
 long ntodo, /* I - number of elements in the array */
 double scale, /* I - FITS TSCALn or BSCALE value */
 double zero, /* I - FITS TZEROn or BZERO value */
 int nullcheck, /* I - null checking code; 0 = don't check */
 /* 1:set null pixels = nullval */
 /* 2: if null pixel, set nullarray = 1 */
 short tnull, /* I - value of FITS TNULLn keyword if any */
 signed char nullval, /* I - set null pixels, if nullcheck = 1 */
 char *nullarray, /* I - bad pixel array, if nullcheck = 2 */
 int *anynull, /* O - set to 1 if any pixels are null */
 signed char *output, /* O - array of converted pixels */
 int *status) /* IO - error status */
/*
 Copy input to output following reading of the input from a FITS file.
 Check for null values and do datatype conversion and scaling if required.
 The nullcheck code value determines how any null values in the input array
 are treated. A null value is an input pixel that is equal to tnull. If
nullcheck = 0, then no checking for nulls is performed and any null values
 will be transformed just like any other pixel. If nullcheck = 1, then the
 output pixel will be set = nullval if the corresponding input pixel is null.
 If nullcheck = 2, then if the pixel is null then the corresponding value of
 nullarray will be set to 1; the value of nullarray for non-null pixels
will = 0. The anynull parameter will be set = 1 if any of the returned
 pixels are null, otherwise anynull will be returned with a value = 0;
*/
{
 long ii;
 double dvalue;
if (nullcheck == 0) /* no null checking required */
 {
 if (scale == 1. && zero == 0.) /* no scaling */
 {
for (ii = 0; ii < ntodo; ii++)
 {
 if (input[ii] < -128)
 {
 *status = OVERFLOW_ERR;
 output[ii] = -128;
 }
 else if (input[ii] > 127)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 output[ii] = (signed char) input[ii];
 }
 }
 else /* must scale the data */
 {
 for (ii = 0; ii < ntodo; ii++)
 {
 dvalue = input[ii] * scale + zero;
if (dvalue < DSCHAR_MIN)
 {
 *status = OVERFLOW_ERR;
 output[ii] = -128;
 }
 else if (dvalue > DSCHAR_MAX)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 output[ii] = (signed char) dvalue;
 }
 }
 }
 else /* must check for null values */
 {
 if (scale == 1. && zero == 0.) /* no scaling */
 {
for (ii = 0; ii < ntodo; ii++)
 {
 if (input[ii] == tnull)
 {
 *anynull = 1;
 if (nullcheck == 1)
 output[ii] = nullval;
 else
 nullarray[ii] = 1;
 }
else
 {
 if (input[ii] < -128)
 {
 *status = OVERFLOW_ERR;
 output[ii] = -128;
 }
 else if (input[ii] > 127)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 output[ii] = (signed char) input[ii];
 }
 }
 }
 else /* must scale the data */
 {
 for (ii = 0; ii < ntodo; ii++)
 {
 if (input[ii] == tnull)
 {
 *anynull = 1;
 if (nullcheck == 1)
 output[ii] = nullval;
 else
 nullarray[ii] = 1;
 }
 else
 {
 dvalue = input[ii] * scale + zero;
if (dvalue < DSCHAR_MIN)
 {
 *status = OVERFLOW_ERR;
 output[ii] = -128;
 }
 else if (dvalue > DSCHAR_MAX)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 output[ii] = (signed char) dvalue;
 }
 }
 }
 }
 return(*status);
}
/*--------------------------------------------------------------------------*/
int fffi4s1(INT32BIT *input, /* I - array of values to be converted */
 long ntodo, /* I - number of elements in the array */
 double scale, /* I - FITS TSCALn or BSCALE value */
 double zero, /* I - FITS TZEROn or BZERO value */
 int nullcheck, /* I - null checking code; 0 = don't check */
 /* 1:set null pixels = nullval */
 /* 2: if null pixel, set nullarray = 1 */
 INT32BIT tnull, /* I - value of FITS TNULLn keyword if any */
 signed char nullval, /* I - set null pixels, if nullcheck = 1 */
 char *nullarray, /* I - bad pixel array, if nullcheck = 2 */
 int *anynull, /* O - set to 1 if any pixels are null */
 signed char *output, /* O - array of converted pixels */
 int *status) /* IO - error status */
/*
 Copy input to output following reading of the input from a FITS file.
 Check for null values and do datatype conversion and scaling if required.
 The nullcheck code value determines how any null values in the input array
 are treated. A null value is an input pixel that is equal to tnull. If
nullcheck = 0, then no checking for nulls is performed and any null values
 will be transformed just like any other pixel. If nullcheck = 1, then the
 output pixel will be set = nullval if the corresponding input pixel is null.
 If nullcheck = 2, then if the pixel is null then the corresponding value of
 nullarray will be set to 1; the value of nullarray for non-null pixels
will = 0. The anynull parameter will be set = 1 if any of the returned
 pixels are null, otherwise anynull will be returned with a value = 0;
*/
{
 long ii;
 double dvalue;
if (nullcheck == 0) /* no null checking required */
 {
 if (scale == 1. && zero == 0.) /* no scaling */
 {
for (ii = 0; ii < ntodo; ii++)
 {
 if (input[ii] < -128)
 {
 *status = OVERFLOW_ERR;
 output[ii] = -128;
 }
 else if (input[ii] > 127)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 output[ii] = (signed char) input[ii];
 }
 }
 else /* must scale the data */
 {
 for (ii = 0; ii < ntodo; ii++)
 {
 dvalue = input[ii] * scale + zero;
if (dvalue < DSCHAR_MIN)
 {
 *status = OVERFLOW_ERR;
 output[ii] = -128;
 }
 else if (dvalue > DSCHAR_MAX)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 output[ii] = (signed char) dvalue;
 }
 }
 }
 else /* must check for null values */
 {
 if (scale == 1. && zero == 0.) /* no scaling */
 {
for (ii = 0; ii < ntodo; ii++)
 {
 if (input[ii] == tnull)
 {
 *anynull = 1;
 if (nullcheck == 1)
 output[ii] = nullval;
 else
 nullarray[ii] = 1;
 }
 else
 {
 if (input[ii] < -128)
 {
 *status = OVERFLOW_ERR;
 output[ii] = -128;
 }
 else if (input[ii] > 127)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 output[ii] = (signed char) input[ii];
 }
 }
 }
 else /* must scale the data */
 {
 for (ii = 0; ii < ntodo; ii++)
 {
 if (input[ii] == tnull)
 {
 *anynull = 1;
 if (nullcheck == 1)
 output[ii] = nullval;
 else
 nullarray[ii] = 1;
 }
 else
 {
 dvalue = input[ii] * scale + zero;
if (dvalue < DSCHAR_MIN)
 {
 *status = OVERFLOW_ERR;
 output[ii] = -128;
 }
 else if (dvalue > DSCHAR_MAX)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 output[ii] = (signed char) dvalue;
 }
 }
 }
 }
 return(*status);
}
/*--------------------------------------------------------------------------*/
int fffi8s1(LONGLONG *input, /* I - array of values to be converted */
 long ntodo, /* I - number of elements in the array */
 double scale, /* I - FITS TSCALn or BSCALE value */
 double zero, /* I - FITS TZEROn or BZERO value */
 int nullcheck, /* I - null checking code; 0 = don't check */
 /* 1:set null pixels = nullval */
 /* 2: if null pixel, set nullarray = 1 */
 LONGLONG tnull, /* I - value of FITS TNULLn keyword if any */
 signed char nullval, /* I - set null pixels, if nullcheck = 1 */
 char *nullarray, /* I - bad pixel array, if nullcheck = 2 */
 int *anynull, /* O - set to 1 if any pixels are null */
 signed char *output, /* O - array of converted pixels */
 int *status) /* IO - error status */
/*
 Copy input to output following reading of the input from a FITS file.
 Check for null values and do datatype conversion and scaling if required.
 The nullcheck code value determines how any null values in the input array
 are treated. A null value is an input pixel that is equal to tnull. If
nullcheck = 0, then no checking for nulls is performed and any null values
 will be transformed just like any other pixel. If nullcheck = 1, then the
 output pixel will be set = nullval if the corresponding input pixel is null.
 If nullcheck = 2, then if the pixel is null then the corresponding value of
 nullarray will be set to 1; the value of nullarray for non-null pixels
will = 0. The anynull parameter will be set = 1 if any of the returned
 pixels are null, otherwise anynull will be returned with a value = 0;
*/
{
 long ii;
 double dvalue;
 ULONGLONG ulltemp;
if (nullcheck == 0) /* no null checking required */
 {
 if (scale == 1. && zero == 9223372036854775808.)
 {
/* The column we read contains unsigned long long values. */
 /* Instead of adding 9223372036854775808, it is more efficient */
 /* and more precise to just flip the sign bit with the XOR operator */
for (ii = 0; ii < ntodo; ii++) {
ulltemp = (ULONGLONG) (((LONGLONG) input[ii]) ^ 0x8000000000000000);
if (ulltemp > 127)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 {
 output[ii] = (short) ulltemp;
 }
 }
 }
 else if (scale == 1. && zero == 0.) /* no scaling */
 {
for (ii = 0; ii < ntodo; ii++)
 {
 if (input[ii] < -128)
 {
 *status = OVERFLOW_ERR;
 output[ii] = -128;
 }
 else if (input[ii] > 127)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 output[ii] = (signed char) input[ii];
 }
 }
 else /* must scale the data */
 {
 for (ii = 0; ii < ntodo; ii++)
 {
 dvalue = input[ii] * scale + zero;
if (dvalue < DSCHAR_MIN)
 {
 *status = OVERFLOW_ERR;
 output[ii] = -128;
 }
 else if (dvalue > DSCHAR_MAX)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 output[ii] = (signed char) dvalue;
 }
 }
 }
 else /* must check for null values */
 {
 if (scale == 1. && zero == 9223372036854775808.)
 {
/* The column we read contains unsigned long long values. */
 /* Instead of subtracting 9223372036854775808, it is more efficient */
 /* and more precise to just flip the sign bit with the XOR operator */
for (ii = 0; ii < ntodo; ii++) {
if (input[ii] == tnull)
 {
 *anynull = 1;
 if (nullcheck == 1)
 output[ii] = nullval;
 else
 nullarray[ii] = 1;
 }
 else
 {
 ulltemp = (ULONGLONG) (((LONGLONG) input[ii]) ^ 0x8000000000000000);
if (ulltemp > 127)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 {
 output[ii] = (short) ulltemp;
 }
 }
 }
 }
 else if (scale == 1. && zero == 0.) /* no scaling */
 {
for (ii = 0; ii < ntodo; ii++)
 {
 if (input[ii] == tnull)
 {
 *anynull = 1;
 if (nullcheck == 1)
 output[ii] = nullval;
 else
 nullarray[ii] = 1;
 }
 else
 {
 if (input[ii] < -128)
 {
 *status = OVERFLOW_ERR;
 output[ii] = -128;
 }
 else if (input[ii] > 127)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 output[ii] = (signed char) input[ii];
 }
 }
 }
 else /* must scale the data */
 {
 for (ii = 0; ii < ntodo; ii++)
 {
 if (input[ii] == tnull)
 {
 *anynull = 1;
 if (nullcheck == 1)
 output[ii] = nullval;
 else
 nullarray[ii] = 1;
 }
 else
 {
 dvalue = input[ii] * scale + zero;
if (dvalue < DSCHAR_MIN)
 {
 *status = OVERFLOW_ERR;
 output[ii] = -128;
 }
 else if (dvalue > DSCHAR_MAX)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 output[ii] = (signed char) dvalue;
 }
 }
 }
 }
 return(*status);
}
/*--------------------------------------------------------------------------*/
int fffr4s1(float *input, /* I - array of values to be converted */
 long ntodo, /* I - number of elements in the array */
 double scale, /* I - FITS TSCALn or BSCALE value */
 double zero, /* I - FITS TZEROn or BZERO value */
 int nullcheck, /* I - null checking code; 0 = don't check */
 /* 1:set null pixels = nullval */
 /* 2: if null pixel, set nullarray = 1 */
 signed char nullval, /* I - set null pixels, if nullcheck = 1 */
 char *nullarray, /* I - bad pixel array, if nullcheck = 2 */
 int *anynull, /* O - set to 1 if any pixels are null */
 signed char *output, /* O - array of converted pixels */
 int *status) /* IO - error status */
/*
 Copy input to output following reading of the input from a FITS file.
 Check for null values and do datatype conversion and scaling if required.
 The nullcheck code value determines how any null values in the input array
 are treated. A null value is an input pixel that is equal to NaN. If
nullcheck = 0, then no checking for nulls is performed and any null values
 will be transformed just like any other pixel. If nullcheck = 1, then the
 output pixel will be set = nullval if the corresponding input pixel is null.
 If nullcheck = 2, then if the pixel is null then the corresponding value of
 nullarray will be set to 1; the value of nullarray for non-null pixels
will = 0. The anynull parameter will be set = 1 if any of the returned
 pixels are null, otherwise anynull will be returned with a value = 0;
*/
{
 long ii;
 double dvalue;
 short *sptr, iret;
if (nullcheck == 0) /* no null checking required */
 {
 if (scale == 1. && zero == 0.) /* no scaling */
 {
for (ii = 0; ii < ntodo; ii++)
 {
 if (input[ii] < DSCHAR_MIN)
 {
 *status = OVERFLOW_ERR;
 output[ii] = -128;
 }
 else if (input[ii] > DSCHAR_MAX)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 output[ii] = (signed char) input[ii];
 }
 }
 else /* must scale the data */
 {
 for (ii = 0; ii < ntodo; ii++)
 {
 dvalue = input[ii] * scale + zero;
if (dvalue < DSCHAR_MIN)
 {
 *status = OVERFLOW_ERR;
 output[ii] = -128;
 }
 else if (dvalue > DSCHAR_MAX)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 output[ii] = (signed char) dvalue;
 }
 }
 }
 else /* must check for null values */
 {
 sptr = (short *) input;
#if BYTESWAPPED && MACHINE != VAXVMS && MACHINE != ALPHAVMS
 sptr++; /* point to MSBs */
#endif
 if (scale == 1. && zero == 0.) /* no scaling */
 {
for (ii = 0; ii < ntodo; ii++, sptr += 2)
 {
 /* use redundant boolean logic in following statement */
 /* to suppress irritating Borland compiler warning message */
 if (0 != (iret = fnan(*sptr) ) ) /* test for NaN or underflow */
 {
 if (iret == 1) /* is it a NaN? */
 {
 *anynull = 1;
 if (nullcheck == 1)
 output[ii] = nullval;
 else
 nullarray[ii] = 1;
 }
 else /* it's an underflow */
 output[ii] = 0;
 }
 else
 {
 if (input[ii] < DSCHAR_MIN)
 {
 *status = OVERFLOW_ERR;
 output[ii] = -128;
 }
 else if (input[ii] > DSCHAR_MAX)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 output[ii] = (signed char) input[ii];
 }
 }
 }
 else /* must scale the data */
 {
 for (ii = 0; ii < ntodo; ii++, sptr += 2)
 {
 if (0 != (iret = fnan(*sptr) ) ) /* test for NaN or underflow */
 {
 if (iret == 1) /* is it a NaN? */
 {
*anynull = 1;
 if (nullcheck == 1)
 output[ii] = nullval;
 else
 nullarray[ii] = 1;
 }
 else /* it's an underflow */
 {
 if (zero < DSCHAR_MIN)
 {
 *status = OVERFLOW_ERR;
 output[ii] = -128;
 }
 else if (zero > DSCHAR_MAX)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 output[ii] = (signed char) zero;
 }
 }
 else
 {
 dvalue = input[ii] * scale + zero;
if (dvalue < DSCHAR_MIN)
 {
 *status = OVERFLOW_ERR;
 output[ii] = -128;
 }
 else if (dvalue > DSCHAR_MAX)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 output[ii] = (signed char) dvalue;
 }
 }
 }
 }
 return(*status);
}
/*--------------------------------------------------------------------------*/
int fffr8s1(double *input, /* I - array of values to be converted */
 long ntodo, /* I - number of elements in the array */
 double scale, /* I - FITS TSCALn or BSCALE value */
 double zero, /* I - FITS TZEROn or BZERO value */
 int nullcheck, /* I - null checking code; 0 = don't check */
 /* 1:set null pixels = nullval */
 /* 2: if null pixel, set nullarray = 1 */
 signed char nullval, /* I - set null pixels, if nullcheck = 1 */
 char *nullarray, /* I - bad pixel array, if nullcheck = 2 */
 int *anynull, /* O - set to 1 if any pixels are null */
 signed char *output, /* O - array of converted pixels */
 int *status) /* IO - error status */
/*
 Copy input to output following reading of the input from a FITS file.
 Check for null values and do datatype conversion and scaling if required.
 The nullcheck code value determines how any null values in the input array
 are treated. A null value is an input pixel that is equal to NaN. If
nullcheck = 0, then no checking for nulls is performed and any null values
 will be transformed just like any other pixel. If nullcheck = 1, then the
 output pixel will be set = nullval if the corresponding input pixel is null.
 If nullcheck = 2, then if the pixel is null then the corresponding value of
 nullarray will be set to 1; the value of nullarray for non-null pixels
will = 0. The anynull parameter will be set = 1 if any of the returned
 pixels are null, otherwise anynull will be returned with a value = 0;
*/
{
 long ii;
 double dvalue;
 short *sptr, iret;
if (nullcheck == 0) /* no null checking required */
 {
 if (scale == 1. && zero == 0.) /* no scaling */
 {
for (ii = 0; ii < ntodo; ii++)
 {
 if (input[ii] < DSCHAR_MIN)
 {
 *status = OVERFLOW_ERR;
 output[ii] = -128;
 }
 else if (input[ii] > DSCHAR_MAX)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 output[ii] = (signed char) input[ii];
 }
 }
 else /* must scale the data */
 {
 for (ii = 0; ii < ntodo; ii++)
 {
 dvalue = input[ii] * scale + zero;
if (dvalue < DSCHAR_MIN)
 {
 *status = OVERFLOW_ERR;
 output[ii] = -128;
 }
 else if (dvalue > DSCHAR_MAX)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 output[ii] = (signed char) dvalue;
 }
 }
 }
 else /* must check for null values */
 {
 sptr = (short *) input;
#if BYTESWAPPED && MACHINE != VAXVMS && MACHINE != ALPHAVMS
 sptr += 3; /* point to MSBs */
#endif
 if (scale == 1. && zero == 0.) /* no scaling */
 {
for (ii = 0; ii < ntodo; ii++, sptr += 4)
 {
 if (0 != (iret = dnan(*sptr)) ) /* test for NaN or underflow */
 {
 if (iret == 1) /* is it a NaN? */
 {
 *anynull = 1;
 if (nullcheck == 1)
 output[ii] = nullval;
 else
 nullarray[ii] = 1;
 }
 else /* it's an underflow */
 output[ii] = 0;
 }
 else
 {
 if (input[ii] < DSCHAR_MIN)
 {
 *status = OVERFLOW_ERR;
 output[ii] = -128;
 }
 else if (input[ii] > DSCHAR_MAX)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 output[ii] = (signed char) input[ii];
 }
 }
 }
 else /* must scale the data */
 {
 for (ii = 0; ii < ntodo; ii++, sptr += 4)
 {
 if (0 != (iret = dnan(*sptr)) ) /* test for NaN or underflow */
 {
 if (iret == 1) /* is it a NaN? */
 {
*anynull = 1;
 if (nullcheck == 1)
 output[ii] = nullval;
 else
 nullarray[ii] = 1;
 }
 else /* it's an underflow */
 {
 if (zero < DSCHAR_MIN)
 {
 *status = OVERFLOW_ERR;
 output[ii] = -128;
 }
 else if (zero > DSCHAR_MAX)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 output[ii] = (signed char) zero;
 }
 }
 else
 {
 dvalue = input[ii] * scale + zero;
if (dvalue < DSCHAR_MIN)
 {
 *status = OVERFLOW_ERR;
 output[ii] = -128;
 }
 else if (dvalue > DSCHAR_MAX)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 output[ii] = (signed char) dvalue;
 }
 }
 }
 }
 return(*status);
}
/*--------------------------------------------------------------------------*/
int fffstrs1(char *input, /* I - array of values to be converted */
 long ntodo, /* I - number of elements in the array */
 double scale, /* I - FITS TSCALn or BSCALE value */
 double zero, /* I - FITS TZEROn or BZERO value */
 long twidth, /* I - width of each substring of chars */
 double implipower, /* I - power of 10 of implied decimal */
 int nullcheck, /* I - null checking code; 0 = don't check */
 /* 1:set null pixels = nullval */
 /* 2: if null pixel, set nullarray = 1 */
 char *snull, /* I - value of FITS null string, if any */
 signed char nullval, /* I - set null pixels, if nullcheck = 1 */
 char *nullarray, /* I - bad pixel array, if nullcheck = 2 */
 int *anynull, /* O - set to 1 if any pixels are null */
 signed char *output, /* O - array of converted pixels */
 int *status) /* IO - error status */
/*
 Copy input to output following reading of the input from a FITS file. Check
 for null values and do scaling if required. The nullcheck code value
 determines how any null values in the input array are treated. A null
 value is an input pixel that is equal to snull. If nullcheck= 0, then
 no special checking for nulls is performed. If nullcheck = 1, then the
 output pixel will be set = nullval if the corresponding input pixel is null.
 If nullcheck = 2, then if the pixel is null then the corresponding value of
 nullarray will be set to 1; the value of nullarray for non-null pixels
will = 0. The anynull parameter will be set = 1 if any of the returned
 pixels are null, otherwise anynull will be returned with a value = 0;
*/
{
 int nullen;
 long ii;
 double dvalue;
 char *cstring, message[FLEN_ERRMSG];
 char *cptr, *tpos;
 char tempstore, chrzero = '0';
 double val, power;
 int exponent, sign, esign, decpt;
nullen = strlen(snull);
 cptr = input; /* pointer to start of input string */
 for (ii = 0; ii < ntodo; ii++)
 {
 cstring = cptr;
 /* temporarily insert a null terminator at end of the string */
 tpos = cptr + twidth;
 tempstore = *tpos;
 *tpos = 0;
/* check if null value is defined, and if the */
 /* column string is identical to the null string */
 if (snull[0] != ASCII_NULL_UNDEFINED &&
!strncmp(snull, cptr, nullen) )
 {
 if (nullcheck)
{
 *anynull = 1;
if (nullcheck == 1)
 output[ii] = nullval;
 else
 nullarray[ii] = 1;
 }
 cptr += twidth;
 }
 else
 {
 /* value is not the null value, so decode it */
 /* remove any embedded blank characters from the string */
decpt = 0;
 sign = 1;
 val = 0.;
 power = 1.;
 exponent = 0;
 esign = 1;
while (*cptr == ' ') /* skip leading blanks */
 cptr++;
if (*cptr == '-' || *cptr == '+') /* check for leading sign */
 {
 if (*cptr == '-')
 sign = -1;
cptr++;
while (*cptr == ' ') /* skip blanks between sign and value */
 cptr++;
 }
while (*cptr >= '0' && *cptr <= '9')
 {
 val = val * 10. + *cptr - chrzero; /* accumulate the value */
 cptr++;
while (*cptr == ' ') /* skip embedded blanks in the value */
 cptr++;
 }
if (*cptr == '.' || *cptr == ',') /* check for decimal point */
 {
 decpt = 1;
 cptr++;
 while (*cptr == ' ') /* skip any blanks */
 cptr++;
while (*cptr >= '0' && *cptr <= '9')
 {
 val = val * 10. + *cptr - chrzero; /* accumulate the value */
 power = power * 10.;
 cptr++;
while (*cptr == ' ') /* skip embedded blanks in the value */
 cptr++;
 }
 }
if (*cptr == 'E' || *cptr == 'D') /* check for exponent */
 {
 cptr++;
 while (*cptr == ' ') /* skip blanks */
 cptr++;
if (*cptr == '-' || *cptr == '+') /* check for exponent sign */
 {
 if (*cptr == '-')
 esign = -1;
cptr++;
while (*cptr == ' ') /* skip blanks between sign and exp */
 cptr++;
 }
while (*cptr >= '0' && *cptr <= '9')
 {
 exponent = exponent * 10 + *cptr - chrzero; /* accumulate exp */
 cptr++;
while (*cptr == ' ') /* skip embedded blanks */
 cptr++;
 }
 }
if (*cptr != 0) /* should end up at the null terminator */
 {
 snprintf(message, FLEN_ERRMSG,"Cannot read number from ASCII table");
 ffpmsg(message);
 snprintf(message, FLEN_ERRMSG,"Column field = %s.", cstring);
 ffpmsg(message);
 /* restore the char that was overwritten by the null */
 *tpos = tempstore;
 return(*status = BAD_C2D);
 }
if (!decpt) /* if no explicit decimal, use implied */
 power = implipower;
dvalue = (sign * val / power) * pow(10., (double) (esign * exponent));
dvalue = dvalue * scale + zero; /* apply the scaling */
if (dvalue < DSCHAR_MIN)
 {
 *status = OVERFLOW_ERR;
 output[ii] = -128;
 }
 else if (dvalue > DSCHAR_MAX)
 {
 *status = OVERFLOW_ERR;
 output[ii] = 127;
 }
 else
 output[ii] = (signed char) dvalue;
 }
 /* restore the char that was overwritten by the null */
 *tpos = tempstore;
 }
 return(*status);
}