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|
/*=============================================================================
*
* WCSLIB - an implementation of the FITS WCS proposal.
* Copyright (C) 1995-2002, Mark Calabretta
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*
* Correspondence concerning WCSLIB may be directed to:
* Internet email: mcalabre@atnf.csiro.au
* Postal address: Dr. Mark Calabretta,
* Australia Telescope National Facility,
* P.O. Box 76,
* Epping, NSW, 2121,
* AUSTRALIA
*
*=============================================================================
*
* C routines which implement the FITS World Coordinate System (WCS)
* convention.
*
* Summary of routines
* -------------------
* wcsfwd() and wcsrev() are high level driver routines for the WCS linear
* transformation, spherical coordinate transformation, and spherical
* projection routines.
*
* Given either the celestial longitude or latitude plus an element of the
* pixel coordinate a hybrid routine, wcsmix(), iteratively solves for the
* unknown elements.
*
* An initialization routine, wcsset(), computes indices from the ctype
* array but need not be called explicitly - see the explanation of
* wcs.flag below.
*
*
* Initialization routine; wcsset()
* --------------------------------
* Initializes elements of a wcsprm data structure which holds indices into
* the coordinate arrays. Note that this routine need not be called directly;
* it will be invoked by wcsfwd() and wcsrev() if the "flag" structure member
* is anything other than a predefined magic value.
*
* Given:
* naxis const int
* Number of image axes.
* ctype[][9]
* const char
* Coordinate axis types corresponding to the FITS
* CTYPEn header cards.
*
* Returned:
* wcs wcsprm* Indices for the celestial coordinates obtained
* by parsing the ctype[] array (see below).
*
* Function return value:
* int Error status
* 0: Success.
* 1: Inconsistent or unrecognized coordinate axis
* types.
*
*
* Forward transformation; wcsfwd()
* --------------------------------
* Compute the pixel coordinate for given world coordinates.
*
* Given:
* ctype[][9]
* const char
* Coordinate axis types corresponding to the FITS
* CTYPEn header cards.
*
* Given or returned:
* wcs wcsprm* Indices for the celestial coordinates obtained
* by parsing the ctype[] array (see below).
*
* Given:
* world const double[]
* World coordinates. world[wcs->lng] and
* world[wcs->lat] are the celestial longitude and
* latitude, in degrees.
*
* Given:
* crval const double[]
* Coordinate reference values corresponding to the FITS
* CRVALn header cards (see note 2).
*
* Given and returned:
* cel celprm* Spherical coordinate transformation parameters (usage
* is described in the prologue to "cel.c").
*
* Returned:
* phi, double* Longitude and latitude in the native coordinate
* theta system of the projection, in degrees.
*
* Given and returned:
* prj prjprm* Projection parameters (usage is described in the
* prologue to "proj.c").
*
* Returned:
* imgcrd double[] Image coordinate. imgcrd[wcs->lng] and
* imgcrd[wcs->lat] are the projected x-, and
* y-coordinates, in "degrees". For quadcube
* projections with a CUBEFACE axis the face number is
* also returned in imgcrd[wcs->cubeface].
*
* Given and returned:
* lin linprm* Linear transformation parameters (usage is described
* in the prologue to "lin.c").
*
* Returned:
* pixcrd double[] Pixel coordinate.
*
* Function return value:
* int Error status
* 0: Success.
* 1: Invalid coordinate transformation parameters.
* 2: Invalid projection parameters.
* 3: Invalid world coordinate.
* 4: Invalid linear transformation parameters.
*
*
* Reverse transformation; wcsrev()
* --------------------------------
* Compute world coordinates for a given pixel coordinate.
*
* Given:
* ctype[][9]
* const char
* Coordinate axis types corresponding to the FITS
* CTYPEn header cards.
*
* Given or returned:
* wcs wcsprm* Indices for the celestial coordinates obtained
* by parsing the ctype[] array (see below).
*
* Given:
* pixcrd const double[]
* Pixel coordinate.
*
* Given and returned:
* lin linprm* Linear transformation parameters (usage is described
* in the prologue to "lin.c").
*
* Returned:
* imgcrd double[] Image coordinate. imgcrd[wcs->lng] and
* imgcrd[wcs->lat] are the projected x-, and
* y-coordinates, in "degrees".
*
* Given and returned:
* prj prjprm* Projection parameters (usage is described in the
* prologue to "proj.c").
*
* Returned:
* phi, double* Longitude and latitude in the native coordinate
* theta system of the projection, in degrees.
*
* Given:
* crval const double[]
* Coordinate reference values corresponding to the FITS
* CRVALn header cards (see note 2).
*
* Given and returned:
* cel celprm* Spherical coordinate transformation parameters
* (usage is described in the prologue to "cel.c").
*
* Returned:
* world double[] World coordinates. world[wcs->lng] and
* world[wcs->lat] are the celestial longitude and
* latitude, in degrees.
*
* Function return value:
* int Error status
* 0: Success.
* 1: Invalid coordinate transformation parameters.
* 2: Invalid projection parameters.
* 3: Invalid pixel coordinate.
* 4: Invalid linear transformation parameters.
*
*
* Hybrid transformation; wcsmix()
* -------------------------------
* Given either the celestial longitude or latitude plus an element of the
* pixel coordinate solve for the remaining elements by iterating on the
* unknown celestial coordinate element using wcsfwd().
*
* Given:
* ctype[][9]
* const char
* Coordinate axis types corresponding to the FITS
* CTYPEn header cards.
*
* Given or returned:
* wcs wcsprm* Indices for the celestial coordinates obtained
* by parsing the ctype[] array (see below).
*
* Given:
* mixpix const int
* Which element of the pixel coordinate is given.
* mixcel const int
* Which element of the celestial coordinate is
* given:
* 1: Celestial longitude is given in
* world[wcs->lng], latitude returned in
* world[wcs->lat].
* 2: Celestial latitude is given in
* world[wcs->lat], longitude returned in
* world[wcs->lng].
* vspan[2] const double
* Solution interval for the celestial coordinate, in
* degrees. The ordering of the two limits is
* irrelevant. Longitude ranges may be specified with
* any convenient normalization, for example [-120,+120]
* is the same as [240,480], except that the solution
* will be returned with the same normalization, i.e.
* lie within the interval specified.
* vstep const double
* Step size for solution search, in degrees. If zero,
* a sensible, although perhaps non-optimal default will
* be used.
* viter int
* If a solution is not found then the step size will be
* halved and the search recommenced. viter controls
* how many times the step size is halved. The allowed
* range is 5 - 10.
*
* Given and returned:
* world double[] World coordinates. world[wcs->lng] and
* world[wcs->lat] are the celestial longitude and
* latitude, in degrees. Which is given and which
* returned depends on the value of mixcel. All other
* elements are given.
*
* Given:
* crval const double[]
* Coordinate reference values corresponding to the FITS
* CRVALn header cards (see note 2).
*
* Given and returned:
* cel celprm* Spherical coordinate transformation parameters
* (usage is described in the prologue to "cel.c").
*
* Returned:
* phi, double* Longitude and latitude in the native coordinate
* theta system of the projection, in degrees.
*
* Given and returned:
* prj prjprm* Projection parameters (usage is described in the
* prologue to "proj.c").
*
* Returned:
* imgcrd double[] Image coordinate. imgcrd[wcs->lng] and
* imgcrd[wcs->lat] are the projected x-, and
* y-coordinates, in "degrees".
*
* Given and returned:
* lin linprm* Linear transformation parameters (usage is described
* in the prologue to "lin.c").
*
* Given and returned:
* pixcrd double[] Pixel coordinate. The element indicated by mixpix is
* given and the remaining elements are returned.
*
* Function return value:
* int Error status
* 0: Success.
* 1: Invalid coordinate transformation parameters.
* 2: Invalid projection parameters.
* 3: Coordinate transformation error.
* 4: Invalid linear transformation parameters.
* 5: No solution found in the specified interval.
*
*
* Notes
* -----
* 1) The CTYPEn must in be upper case and there must be 0 or 1 pair of
* matched celestial axis types. The ctype[][9] should be padded with
* blanks on the right and null-terminated.
*
* 2) Elements of the crval[] array which correspond to celestial axes are
* ignored, the reference coordinate values in cel->ref[0] and
* cel->ref[1] are the ones used.
*
* 3) These functions recognize the NCP projection and convert it to the
* equivalent SIN projection.
*
* They also recognize GLS as a synonym for SFL.
*
* 4) The quadcube projections (TSC, CSC, QSC) may be represented in FITS in
* either of two ways:
*
* a) The six faces may be laid out in one plane and numbered as
* follows:
*
* 0
*
* 4 3 2 1 4 3 2
*
* 5
*
* Faces 2, 3 and 4 may appear on one side or the other (or both).
* The forward routines map faces 2, 3 and 4 to the left but the
* inverse routines accept them on either side.
*
* b) The "COBE" convention in which the six faces are stored in a
* three-dimensional structure using a "CUBEFACE" axis indexed from
* 0 to 5 as above.
*
* These routines support both methods; wcsset() determines which is
* being used by the presence or absence of a CUBEFACE axis in ctype[].
* wcsfwd() and wcsrev() translate the CUBEFACE axis representation to
* the single plane representation understood by the lower-level WCSLIB
* projection routines.
*
*
* WCS indexing parameters
* -----------------------
* The wcsprm struct consists of the following:
*
* int flag
* The wcsprm struct contains indexes and other information derived
* from the CTYPEn. Whenever any of the ctype[] are set or changed
* this flag must be set to zero to signal the initialization routine,
* wcsset() to redetermine the indices. The flag is set to 999 if
* there is no celestial axis pair in the CTYPEn.
*
* char pcode[4]
* The WCS projection code.
*
* char lngtyp[5], lattyp[5]
* WCS celestial axis types.
*
* int lng,lat
* Indices into the imgcrd[], and world[] arrays as described above.
* These may also serve as indices for the celestial longitude and
* latitude axes in the pixcrd[] array provided that the PC matrix
* does not transpose axes.
*
* int cubeface
* Index into the pixcrd[] array for the CUBEFACE axis. This is
* optionally used for the quadcube projections where each cube face is
* stored on a separate axis.
*
*
* wcsmix() algorithm
* ------------------
* Initially the specified solution interval is checked to see if it's a
* "crossing" interval. If it isn't, a search is made for a crossing
* solution by iterating on the unknown celestial coordinate starting at
* the upper limit of the solution interval and decrementing by the
* specified step size. A crossing is indicated if the trial value of the
* pixel coordinate steps through the value specified. If a crossing
* interval is found then the solution is determined by a modified form of
* "regula falsi" division of the crossing interval. If no crossing
* interval was found within the specified solution interval then a search
* is made for a "non-crossing" solution as may arise from a point of
* tangency. The process is complicated by having to make allowance for
* the discontinuities that occur in all map projections.
*
* Once one solution has been determined others may be found by subsequent
* invokations of wcsmix() with suitably restricted solution intervals.
*
* Note the circumstance which arises when the solution point lies at a
* native pole of a projection in which the pole is represented as a
* finite curve, for example the zenithals and conics. In such cases two
* or more valid solutions may exist but WCSMIX only ever returns one.
*
* Because of its generality wcsmix() is very compute-intensive. For
* compute-limited applications more efficient special-case solvers could
* be written for simple projections, for example non-oblique cylindrical
* projections.
*
* Author: Mark Calabretta, Australia Telescope National Facility
* $Id: wcs.c,v 2.23 2002/04/03 01:25:29 mcalabre Exp $
*===========================================================================*/
#include <stdio.h>
#include <math.h>
#include <string.h>
#include <stdio.h>
#include "wcslib.h"
/* Map error number to error message for each function. */
const char *wcsset_errmsg[] = {
0,
"Inconsistent or unrecognized coordinate axis types"};
const char *wcsfwd_errmsg[] = {
0,
"Invalid coordinate transformation parameters",
"Invalid projection parameters",
"Invalid world coordinate",
"Invalid linear transformation parameters"};
const char *wcsrev_errmsg[] = {
0,
"Invalid coordinate transformation parameters",
"Invalid projection parameters",
"Invalid pixel coordinate",
"Invalid linear transformation parameters"};
const char *wcsmix_errmsg[] = {
0,
"Invalid coordinate transformation parameters",
"Invalid projection parameters",
"Coordinate transformation error",
"Invalid linear transformation parameters",
"No solution found in the specified interval"};
#define signb(X) ((X) < 0.0 ? 1 : 0)
int
wcsset (naxis, ctype, wcs)
const int naxis;
const char ctype[][9];
struct wcsprm *wcs;
{
int nalias = 2;
char aliases [2][4] = {"NCP", "GLS"};
int j, k;
int *ndx = NULL;
char requir[9];
strcpy(wcs->pcode, "");
strcpy(requir, "");
wcs->lng = -1;
wcs->lat = -1;
wcs->cubeface = -1;
for (j = 0; j < naxis; j++) {
if (ctype[j][4] != '-') {
if (strcmp(ctype[j], "CUBEFACE") == 0) {
if (wcs->cubeface == -1) {
wcs->cubeface = j;
} else {
/* Multiple CUBEFACE axes! */
return 1;
}
}
continue;
}
/* Got an axis qualifier, is it a recognized WCS projection? */
for (k = 0; k < npcode; k++) {
if (strncmp(&ctype[j][5], pcodes[k], 3) == 0) break;
}
if (k == npcode) {
/* Maybe it's a projection alias. */
for (k = 0; k < nalias; k++) {
if (strncmp(&ctype[j][5], aliases[k], 3) == 0) break;
}
/* Not recognized. */
if (k == nalias) {
continue;
}
}
/* Parse the celestial axis type. */
if (strcmp(wcs->pcode, "") == 0) {
sprintf(wcs->pcode, "%.3s", &ctype[j][5]);
if (strncmp(ctype[j], "RA--", 4) == 0) {
wcs->lng = j;
strcpy(wcs->lngtyp, "RA");
strcpy(wcs->lattyp, "DEC");
ndx = &wcs->lat;
sprintf(requir, "DEC--%s", wcs->pcode);
} else if (strncmp(ctype[j], "DEC-", 4) == 0) {
wcs->lat = j;
strcpy(wcs->lngtyp, "RA");
strcpy(wcs->lattyp, "DEC");
ndx = &wcs->lng;
sprintf(requir, "RA---%s", wcs->pcode);
} else if (strncmp(&ctype[j][1], "LON", 3) == 0) {
wcs->lng = j;
sprintf(wcs->lngtyp, "%cLON", ctype[j][0]);
sprintf(wcs->lattyp, "%cLAT", ctype[j][0]);
ndx = &wcs->lat;
sprintf(requir, "%s-%s", wcs->lattyp, wcs->pcode);
} else if (strncmp(&ctype[j][1], "LAT", 3) == 0) {
wcs->lat = j;
sprintf(wcs->lngtyp, "%cLON", ctype[j][0]);
sprintf(wcs->lattyp, "%cLAT", ctype[j][0]);
ndx = &wcs->lng;
sprintf(requir, "%s-%s", wcs->lngtyp, wcs->pcode);
} else if (strncmp(&ctype[j][2], "LN", 2) == 0) {
wcs->lng = j;
sprintf(wcs->lngtyp, "%c%cLN", ctype[j][0], ctype[j][1]);
sprintf(wcs->lattyp, "%c%cLT", ctype[j][0], ctype[j][1]);
ndx = &wcs->lat;
sprintf(requir, "%s-%s", wcs->lattyp, wcs->pcode);
} else if (strncmp(&ctype[j][2], "LT", 2) == 0) {
wcs->lat = j;
sprintf(wcs->lngtyp, "%c%cLN", ctype[j][0], ctype[j][1]);
sprintf(wcs->lattyp, "%c%cLT", ctype[j][0], ctype[j][1]);
ndx = &wcs->lng;
sprintf(requir, "%s-%s", wcs->lngtyp, wcs->pcode);
} else {
/* Unrecognized celestial type. */
return 1;
}
} else {
if (strncmp(ctype[j], requir, 8) != 0) {
/* Inconsistent projection types. */
return 1;
}
if (ndx == NULL)
return 1;
*ndx = j;
strcpy(requir, "");
}
}
if (strcmp(requir, "")) {
/* Unmatched celestial axis. */
return 1;
}
/* Do simple alias translations. */
if (strncmp(wcs->pcode, "GLS", 3) == 0) {
strcpy(wcs->pcode, "SFL");
}
if (strcmp(wcs->pcode, "")) {
wcs->flag = WCSSET;
} else {
/* Signal for no celestial axis pair. */
wcs->flag = 999;
}
return 0;
}
/*--------------------------------------------------------------------------*/
int
wcsfwd(ctype, wcs, world, crval, cel, phi, theta, prj, imgcrd, lin, pixcrd)
const char ctype[][9];
struct wcsprm* wcs;
const double world[];
const double crval[];
struct celprm *cel;
double *phi, *theta;
struct prjprm *prj;
double imgcrd[];
struct linprm *lin;
double pixcrd[];
{
int err, j;
double offset;
/* Initialize if required. */
if (wcs->flag != WCSSET) {
if (wcsset(lin->naxis, ctype, wcs)) return 1;
}
/* Convert to relative physical coordinates. */
for (j = 0; j < lin->naxis; j++) {
if (j == wcs->lng) continue;
if (j == wcs->lat) continue;
imgcrd[j] = world[j] - crval[j];
}
if (wcs->flag != 999) {
/* Compute projected coordinates. */
if (strcmp(wcs->pcode, "NCP") == 0) {
/* Convert NCP to SIN. */
if (cel->ref[1] == 0.0) {
return 2;
}
strcpy(wcs->pcode, "SIN");
prj->p[1] = 0.0;
prj->p[2] = cosdeg (cel->ref[1])/sindeg (cel->ref[1]);
prj->flag = (prj->flag < 0) ? -1 : 0;
}
if ((err = celfwd(wcs->pcode, world[wcs->lng], world[wcs->lat], cel,
phi, theta, prj, &imgcrd[wcs->lng], &imgcrd[wcs->lat]))) {
return err;
}
/* Do we have a CUBEFACE axis? */
if (wcs->cubeface != -1) {
/* Separation between faces. */
if (prj->r0 == 0.0) {
offset = 90.0;
} else {
offset = prj->r0*PI/2.0;
}
/* Stack faces in a cube. */
if (imgcrd[wcs->lat] < -0.5*offset) {
imgcrd[wcs->lat] += offset;
imgcrd[wcs->cubeface] = 5.0;
} else if (imgcrd[wcs->lat] > 0.5*offset) {
imgcrd[wcs->lat] -= offset;
imgcrd[wcs->cubeface] = 0.0;
} else if (imgcrd[wcs->lng] > 2.5*offset) {
imgcrd[wcs->lng] -= 3.0*offset;
imgcrd[wcs->cubeface] = 4.0;
} else if (imgcrd[wcs->lng] > 1.5*offset) {
imgcrd[wcs->lng] -= 2.0*offset;
imgcrd[wcs->cubeface] = 3.0;
} else if (imgcrd[wcs->lng] > 0.5*offset) {
imgcrd[wcs->lng] -= offset;
imgcrd[wcs->cubeface] = 2.0;
} else {
imgcrd[wcs->cubeface] = 1.0;
}
}
}
/* Apply forward linear transformation. */
if (linfwd(imgcrd, lin, pixcrd)) {
return 4;
}
return 0;
}
/*--------------------------------------------------------------------------*/
int
wcsrev(ctype, wcs, pixcrd, lin, imgcrd, prj, phi, theta, crval, cel, world)
const char ctype[][9];
struct wcsprm *wcs;
const double pixcrd[];
struct linprm *lin;
double imgcrd[];
struct prjprm *prj;
double *phi, *theta;
const double crval[];
struct celprm *cel;
double world[];
{
int err, face, j;
double offset;
/* Initialize if required. */
if (wcs->flag != WCSSET) {
if (wcsset(lin->naxis, ctype, wcs)) return 1;
}
/* Apply reverse linear transformation. */
if (linrev(pixcrd, lin, imgcrd)) {
return 4;
}
/* Convert to world coordinates. */
for (j = 0; j < lin->naxis; j++) {
if (j == wcs->lng) continue;
if (j == wcs->lat) continue;
world[j] = imgcrd[j] + crval[j];
}
if (wcs->flag != 999) {
/* Do we have a CUBEFACE axis? */
if (wcs->cubeface != -1) {
face = (int)(imgcrd[wcs->cubeface] + 0.5);
if (fabs(imgcrd[wcs->cubeface]-face) > 1e-10) {
return 3;
}
/* Separation between faces. */
if (prj->r0 == 0.0) {
offset = 90.0;
} else {
offset = prj->r0*PI/2.0;
}
/* Lay out faces in a plane. */
switch (face) {
case 0:
imgcrd[wcs->lat] += offset;
break;
case 1:
break;
case 2:
imgcrd[wcs->lng] += offset;
break;
case 3:
imgcrd[wcs->lng] += offset*2;
break;
case 4:
imgcrd[wcs->lng] += offset*3;
break;
case 5:
imgcrd[wcs->lat] -= offset;
break;
default:
return 3;
}
}
/* Compute celestial coordinates. */
if (strcmp(wcs->pcode, "NCP") == 0) {
/* Convert NCP to SIN. */
if (cel->ref[1] == 0.0) {
return 2;
}
strcpy(wcs->pcode, "SIN");
prj->p[1] = 0.0;
prj->p[2] = cosdeg (cel->ref[1])/sindeg (cel->ref[1]);
prj->flag = (prj->flag < 0) ? -1 : 0;
}
if ((err = celrev(wcs->pcode, imgcrd[wcs->lng], imgcrd[wcs->lat], prj,
phi, theta, cel, &world[wcs->lng], &world[wcs->lat]))) {
return err;
}
}
return 0;
}
/*--------------------------------------------------------------------------*/
int
wcsmix(ctype, wcs, mixpix, mixcel, vspan, vstep, viter, world, crval, cel,
phi, theta, prj, imgcrd, lin, pixcrd)
const char ctype[][9];
struct wcsprm *wcs;
const int mixpix, mixcel;
const double vspan[2], vstep;
int viter;
double world[];
const double crval[];
struct celprm *cel;
double *phi, *theta;
struct prjprm *prj;
double imgcrd[];
struct linprm *lin;
double pixcrd[];
{
const int niter = 60;
int crossed, err, istep, iter, j, k, nstep, retry;
const double tol = 1.0e-10;
const double tol2 = 100.0*tol;
double lambda, span[2], step;
double pixmix;
double dlng, lng, lng0, lng0m, lng1, lng1m;
double dlat, lat, lat0, lat0m, lat1, lat1m;
double d, d0, d0m, d1, d1m;
double dx = 0.0;
double dabs, dmin, lmin;
double dphi, phi0, phi1;
struct celprm cel0;
/* Initialize if required. */
if (wcs->flag != WCSSET) {
if (wcsset(lin->naxis, ctype, wcs)) return 1;
}
/* Check vspan. */
if (vspan[0] <= vspan[1]) {
span[0] = vspan[0];
span[1] = vspan[1];
} else {
/* Swap them. */
span[0] = vspan[1];
span[1] = vspan[0];
}
/* Check vstep. */
step = fabs(vstep);
if (step == 0.0) {
step = (span[1] - span[0])/10.0;
if (step > 1.0 || step == 0.0) step = 1.0;
}
/* Check viter. */
nstep = viter;
if (nstep < 5) {
nstep = 5;
} else if (nstep > 10) {
nstep = 10;
}
/* Given pixel element. */
pixmix = pixcrd[mixpix];
/* Iterate on the step size. */
for (istep = 0; istep <= nstep; istep++) {
if (istep) step /= 2.0;
/* Iterate on the sky coordinate between the specified range. */
if (mixcel == 1) {
/* Celestial longitude is given. */
/* Check whether the solution interval is a crossing interval. */
lat0 = span[0];
world[wcs->lat] = lat0;
if ((err = wcsfwd(ctype, wcs, world, crval, cel, phi, theta, prj,
imgcrd, lin, pixcrd))) {
return err;
}
d0 = pixcrd[mixpix] - pixmix;
dabs = fabs(d0);
if (dabs < tol) return 0;
lat1 = span[1];
world[wcs->lat] = lat1;
if ((err = wcsfwd(ctype, wcs, world, crval, cel, phi, theta, prj,
imgcrd, lin, pixcrd))) {
return err;
}
d1 = pixcrd[mixpix] - pixmix;
dabs = fabs(d1);
if (dabs < tol) return 0;
lmin = lat1;
dmin = dabs;
/* Check for a crossing point. */
if (signb(d0) != signb(d1)) {
crossed = 1;
dx = d1;
} else {
crossed = 0;
lat0 = span[1];
}
for (retry = 0; retry < 4; retry++) {
/* Refine the solution interval. */
while (lat0 > span[0]) {
lat0 -= step;
if (lat0 < span[0]) lat0 = span[0];
world[wcs->lat] = lat0;
if ((err = wcsfwd(ctype, wcs, world, crval, cel, phi, theta,
prj, imgcrd, lin, pixcrd))) {
return err;
}
d0 = pixcrd[mixpix] - pixmix;
/* Check for a solution. */
dabs = fabs(d0);
if (dabs < tol) return 0;
/* Record the point of closest approach. */
if (dabs < dmin) {
lmin = lat0;
dmin = dabs;
}
/* Check for a crossing point. */
if (signb(d0) != signb(d1)) {
crossed = 2;
dx = d0;
break;
}
/* Advance to the next subinterval. */
lat1 = lat0;
d1 = d0;
}
if (crossed) {
/* A crossing point was found. */
for (iter = 0; iter < niter; iter++) {
/* Use regula falsi division of the interval. */
lambda = d0/(d0-d1);
if (lambda < 0.1) {
lambda = 0.1;
} else if (lambda > 0.9) {
lambda = 0.9;
}
dlat = lat1 - lat0;
lat = lat0 + lambda*dlat;
world[wcs->lat] = lat;
if ((err = wcsfwd(ctype, wcs, world, crval, cel, phi, theta,
prj, imgcrd, lin, pixcrd))) {
return err;
}
/* Check for a solution. */
d = pixcrd[mixpix] - pixmix;
dabs = fabs(d);
if (dabs < tol) return 0;
if (dlat < tol) {
/* An artifact of numerical imprecision. */
if (dabs < tol2) return 0;
/* Must be a discontinuity. */
break;
}
/* Record the point of closest approach. */
if (dabs < dmin) {
lmin = lat;
dmin = dabs;
}
if (signb(d0) == signb(d)) {
lat0 = lat;
d0 = d;
} else {
lat1 = lat;
d1 = d;
}
}
/* No convergence, must have been a discontinuity. */
if (crossed == 1) lat0 = span[1];
lat1 = lat0;
d1 = dx;
crossed = 0;
} else {
/* No crossing point; look for a tangent point. */
if (lmin == span[0]) break;
if (lmin == span[1]) break;
lat = lmin;
lat0 = lat - step;
if (lat0 < span[0]) lat0 = span[0];
lat1 = lat + step;
if (lat1 > span[1]) lat1 = span[1];
world[wcs->lat] = lat0;
if ((err = wcsfwd(ctype, wcs, world, crval, cel, phi, theta,
prj, imgcrd, lin, pixcrd))) {
return err;
}
d0 = fabs(pixcrd[mixpix] - pixmix);
d = dmin;
world[wcs->lat] = lat1;
if ((err = wcsfwd(ctype, wcs, world, crval, cel, phi, theta,
prj, imgcrd, lin, pixcrd))) {
return err;
}
d1 = fabs(pixcrd[mixpix] - pixmix);
for (iter = 0; iter < niter; iter++) {
lat0m = (lat0 + lat)/2.0;
world[wcs->lat] = lat0m;
if ((err = wcsfwd(ctype, wcs, world, crval, cel, phi, theta,
prj, imgcrd, lin, pixcrd))) {
return err;
}
d0m = fabs(pixcrd[mixpix] - pixmix);
if (d0m < tol) return 0;
lat1m = (lat1 + lat)/2.0;
world[wcs->lat] = lat1m;
if ((err = wcsfwd(ctype, wcs, world, crval, cel, phi, theta,
prj, imgcrd, lin, pixcrd))) {
return err;
}
d1m = fabs(pixcrd[mixpix] - pixmix);
if (d1m < tol) return 0;
if (d0m < d && d0m <= d1m) {
lat1 = lat;
d1 = d;
lat = lat0m;
d = d0m;
} else if (d1m < d) {
lat0 = lat;
d0 = d;
lat = lat1m;
d = d1m;
} else {
lat0 = lat0m;
d0 = d0m;
lat1 = lat1m;
d1 = d1m;
}
}
}
}
} else {
/* Celestial latitude is given. */
/* Check whether the solution interval is a crossing interval. */
lng0 = span[0];
world[wcs->lng] = lng0;
if ((err = wcsfwd(ctype, wcs, world, crval, cel, phi, theta, prj,
imgcrd, lin, pixcrd))) {
return err;
}
d0 = pixcrd[mixpix] - pixmix;
dabs = fabs(d0);
if (dabs < tol) return 0;
lng1 = span[1];
world[wcs->lng] = lng1;
if ((err = wcsfwd(ctype, wcs, world, crval, cel, phi, theta, prj,
imgcrd, lin, pixcrd))) {
return err;
}
d1 = pixcrd[mixpix] - pixmix;
dabs = fabs(d1);
if (dabs < tol) return 0;
lmin = lng1;
dmin = dabs;
/* Check for a crossing point. */
if (signb(d0) != signb(d1)) {
crossed = 1;
dx = d1;
} else {
crossed = 0;
lng0 = span[1];
}
for (retry = 0; retry < 4; retry++) {
/* Refine the solution interval. */
while (lng0 > span[0]) {
lng0 -= step;
if (lng0 < span[0]) lng0 = span[0];
world[wcs->lng] = lng0;
if ((err = wcsfwd(ctype, wcs, world, crval, cel, phi, theta,
prj, imgcrd, lin, pixcrd))) {
return err;
}
d0 = pixcrd[mixpix] - pixmix;
/* Check for a solution. */
dabs = fabs(d0);
if (dabs < tol) return 0;
/* Record the point of closest approach. */
if (dabs < dmin) {
lmin = lng0;
dmin = dabs;
}
/* Check for a crossing point. */
if (signb(d0) != signb(d1)) {
crossed = 2;
dx = d0;
break;
}
/* Advance to the next subinterval. */
lng1 = lng0;
d1 = d0;
}
if (crossed) {
/* A crossing point was found. */
for (iter = 0; iter < niter; iter++) {
/* Use regula falsi division of the interval. */
lambda = d0/(d0-d1);
if (lambda < 0.1) {
lambda = 0.1;
} else if (lambda > 0.9) {
lambda = 0.9;
}
dlng = lng1 - lng0;
lng = lng0 + lambda*dlng;
world[wcs->lng] = lng;
if ((err = wcsfwd(ctype, wcs, world, crval, cel, phi, theta,
prj, imgcrd, lin, pixcrd))) {
return err;
}
/* Check for a solution. */
d = pixcrd[mixpix] - pixmix;
dabs = fabs(d);
if (dabs < tol) return 0;
if (dlng < tol) {
/* An artifact of numerical imprecision. */
if (dabs < tol2) return 0;
/* Must be a discontinuity. */
break;
}
/* Record the point of closest approach. */
if (dabs < dmin) {
lmin = lng;
dmin = dabs;
}
if (signb(d0) == signb(d)) {
lng0 = lng;
d0 = d;
} else {
lng1 = lng;
d1 = d;
}
}
/* No convergence, must have been a discontinuity. */
if (crossed == 1) lng0 = span[1];
lng1 = lng0;
d1 = dx;
crossed = 0;
} else {
/* No crossing point; look for a tangent point. */
if (lmin == span[0]) break;
if (lmin == span[1]) break;
lng = lmin;
lng0 = lng - step;
if (lng0 < span[0]) lng0 = span[0];
lng1 = lng + step;
if (lng1 > span[1]) lng1 = span[1];
world[wcs->lng] = lng0;
if ((err = wcsfwd(ctype, wcs, world, crval, cel, phi, theta,
prj, imgcrd, lin, pixcrd))) {
return err;
}
d0 = fabs(pixcrd[mixpix] - pixmix);
d = dmin;
world[wcs->lng] = lng1;
if ((err = wcsfwd(ctype, wcs, world, crval, cel, phi, theta,
prj, imgcrd, lin, pixcrd))) {
return err;
}
d1 = fabs(pixcrd[mixpix] - pixmix);
for (iter = 0; iter < niter; iter++) {
lng0m = (lng0 + lng)/2.0;
world[wcs->lng] = lng0m;
if ((err = wcsfwd(ctype, wcs, world, crval, cel, phi, theta,
prj, imgcrd, lin, pixcrd))) {
return err;
}
d0m = fabs(pixcrd[mixpix] - pixmix);
if (d0m < tol) return 0;
lng1m = (lng1 + lng)/2.0;
world[wcs->lng] = lng1m;
if ((err = wcsfwd(ctype, wcs, world, crval, cel, phi, theta,
prj, imgcrd, lin, pixcrd))) {
return err;
}
d1m = fabs(pixcrd[mixpix] - pixmix);
if (d1m < tol) return 0;
if (d0m < d && d0m <= d1m) {
lng1 = lng;
d1 = d;
lng = lng0m;
d = d0m;
} else if (d1m < d) {
lng0 = lng;
d0 = d;
lng = lng1m;
d = d1m;
} else {
lng0 = lng0m;
d0 = d0m;
lng1 = lng1m;
d1 = d1m;
}
}
}
}
}
}
/* Set cel0 to the unity transformation. */
cel0.flag = CELSET;
cel0.ref[0] = cel->ref[0];
cel0.ref[1] = cel->ref[1];
cel0.ref[2] = cel->ref[2];
cel0.ref[3] = cel->ref[3];
cel0.euler[0] = -90.0;
cel0.euler[1] = 0.0;
cel0.euler[2] = 90.0;
cel0.euler[3] = 1.0;
cel0.euler[4] = 0.0;
/* No convergence, check for aberrant behaviour at a native pole. */
*theta = -90.0;
for (j = 1; j <= 2; j++) {
/* Could the celestial coordinate element map to a native pole? */
*theta = -*theta;
err = sphrev(0.0, *theta, cel->euler, &lng, &lat);
if (mixcel == 1) {
if (fabs(fmod(world[wcs->lng]-lng,360.0)) > tol) continue;
if (lat < span[0]) continue;
if (lat > span[1]) continue;
world[wcs->lat] = lat;
} else {
if (fabs(world[wcs->lat]-lat) > tol) continue;
if (lng < span[0]) lng += 360.0;
if (lng > span[1]) lng -= 360.0;
if (lng < span[0]) continue;
if (lng > span[1]) continue;
world[wcs->lng] = lng;
}
/* Is there a solution for the given pixel coordinate element? */
lng = world[wcs->lng];
lat = world[wcs->lat];
/* Feed native coordinates to wcsfwd() with cel0 set to unity. */
world[wcs->lng] = -180.0;
world[wcs->lat] = *theta;
if ((err = wcsfwd(ctype, wcs, world, crval, &cel0, phi, theta, prj,
imgcrd, lin, pixcrd))) {
return err;
}
d0 = pixcrd[mixpix] - pixmix;
/* Check for a solution. */
if (fabs(d0) < tol) {
/* Recall saved world coordinates. */
world[wcs->lng] = lng;
world[wcs->lat] = lat;
return 0;
}
/* Search for a crossing interval. */
phi0 = -180.0;
for (k = -179; k <= 180; k++) {
phi1 = (double) k;
world[wcs->lng] = phi1;
if ((err = wcsfwd(ctype, wcs, world, crval, &cel0, phi, theta, prj,
imgcrd, lin, pixcrd))) {
return err;
}
d1 = pixcrd[mixpix] - pixmix;
/* Check for a solution. */
dabs = fabs(d1);
if (dabs < tol) {
/* Recall saved world coordinates. */
world[wcs->lng] = lng;
world[wcs->lat] = lat;
return 0;
}
/* Is it a crossing interval? */
if (signb(d0) != signb(d1)) break;
phi0 = phi1;
d0 = d1;
}
for (iter = 1; iter <= niter; iter++) {
/* Use regula falsi division of the interval. */
lambda = d0/(d0-d1);
if (lambda < 0.1) {
lambda = 0.1;
} else if (lambda > 0.9) {
lambda = 0.9;
}
dphi = phi1 - phi0;
world[wcs->lng] = phi0 + lambda*dphi;
if ((err = wcsfwd(ctype, wcs, world, crval, &cel0, phi, theta, prj,
imgcrd, lin, pixcrd))) {
return err;
}
/* Check for a solution. */
d = pixcrd[mixpix] - pixmix;
dabs = fabs(d);
if (dabs < tol || (dphi < tol && dabs < tol2)) {
/* Recall saved world coordinates. */
world[wcs->lng] = lng;
world[wcs->lat] = lat;
return 0;
}
if (signb(d0) == signb(d)) {
phi0 = world[wcs->lng];
d0 = d;
} else {
phi1 = world[wcs->lng];
d1 = d;
}
}
}
/* No solution. */
return 5;
}
/* Dec 20 1999 Doug Mink - Change signbit() to signb() and always define it
* Dec 20 1999 Doug Mink - Include wcslib.h, which includes wcs.h, wcstrig.h
*
* Mar 20 2001 Doug Mink - Include stdio.h for sprintf()
* Mar 20 2001 Doug Mink - Add () around err assignments in if statements
* Sep 19 2001 Doug Mink - Add above changes to WCSLIB-2.7 version
*
* Mar 15 2002 Doug Mink - Add above changes to WCSLIB-2.8.2
* Apr 3 2002 Mark Calabretta - Fix bug in code checking section
*
* Jun 20 2006 Doug Mink - Initialized uninitialized variables
*/
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