libastrometry-dev 0.70+dfsg-1 / usr / include / astrometry / starutil.h

/*
# This file is part of the Astrometry.net suite.
# Licensed under a 3-clause BSD style license - see LICENSE
*/

#ifndef STARUTIL_H
#define STARUTIL_H

#include <math.h>
#include "astrometry/an-bool.h"
#include "astrometry/keywords.h"

#define DIM_STARS 3
#define DIM_XY 2

// upper bound of dimquads value
#define DQMAX 5
// upper bound of dimcodes value
#define DCMAX 6

InlineDeclare int dimquad2dimcode(int dimquad);

typedef unsigned char uchar;

#define ONE_OVER_SIXTY 0.016666666666666666

// pi / 180.
#define RAD_PER_DEG 0.017453292519943295
// pi / (180. * 60.)
#define RAD_PER_ARCMIN 0.00029088820866572158
// pi / (180. * 60. * 60.)
#define RAD_PER_ARCSEC 4.8481368110953598e-06

// 180. / pi
#define DEG_PER_RAD 57.295779513082323
#define DEG_PER_ARCMIN ONE_OVER_SIXTY
// 1./3600.
#define DEG_PER_ARCSEC 0.00027777777777777778

// 60. * 180. / pi
#define ARCMIN_PER_RAD 3437.7467707849396
#define ARCMIN_PER_DEG 60.0
#define ARCMIN_PER_ARCSEC ONE_OVER_SIXTY

// 60. * 60. * 180. / pi
#define ARCSEC_PER_RAD 206264.80624709636
#define ARCSEC_PER_DEG 3600.0
#define ARCSEC_PER_ARCMIN 60.0

InlineDeclare Const double rad2deg(double x);
InlineDeclare Const double rad2arcmin(double x);
InlineDeclare Const double rad2arcsec(double x);

InlineDeclare Const double deg2rad(double x);
InlineDeclare Const double deg2arcmin(double x);
InlineDeclare Const double deg2arcsec(double x);

InlineDeclare Const double arcmin2rad(double x);
InlineDeclare Const double arcmin2deg(double x);
InlineDeclare Const double arcmin2arcsec(double x);

InlineDeclare Const double arcsec2rad(double x);
InlineDeclare Const double arcsec2deg(double x);
InlineDeclare Const double arcsec2arcmin(double x);

#define MJD_JD_OFFSET 2400000.5

InlineDeclare Const double mjdtojd(double mjd);
InlineDeclare Const double jdtomjd(double jd);

// RA,Dec in radians:
#define radec2x(r,d) (cos(d)*cos(r))
#define radec2y(r,d) (cos(d)*sin(r))
#define radec2z(r,d) (sin(d))
InlineDeclare Const double xy2ra(double x, double y);
InlineDeclare Const double z2dec(double z);

double atora(const char* str);
double atodec(const char* str);

double mag2flux(double mag);

/*
 RA,Dec in degrees.  RAs in range [0, 360], Decs in range [-90, 90].
 */
void radecrange2xyzrange(double ralow, double declow, double rahigh, double dechigh,
						 double* xyzlow, double* xyzhigh);

// RA,Dec in radians:
InlineDeclare void radec2xyz(double ra, double dec, double* x, double* y, double* z);
InlineDeclare Flatten void xyz2radec(double x, double y, double z, double *ra, double *dec);
InlineDeclare Flatten void xyzarr2radec(const double* xyz, double *ra, double *dec);
InlineDeclare void xyzarr2radecarr(const double* xyz, double *radec);
InlineDeclare void radec2xyzarr(double ra, double dec, double* p_xyz);
InlineDeclare void radec2xyzarrmany(double *ra, double *dec, double* xyz, int n);

// RA,Dec in degrees:
InlineDeclare void radecdeg2xyz(double ra, double dec, double* x, double* y, double* z);
InlineDeclare Flatten void xyzarr2radecdeg(const double* xyz, double *ra, double *dec);
InlineDeclare Flatten void xyzarr2radecdegarr(double* xyz, double *radec);
InlineDeclare void radecdeg2xyzarr(double ra, double dec, double* p_xyz);
InlineDeclare void radecdegarr2xyzarr(double* radec, double* xyz);
InlineDeclare void radecdeg2xyzarrmany(double *ra, double *dec, double* xyz, int n);

// RA,Dec in degrees.
// Puts the xyz unit vector pointing in positive-RA direction in "dra",
// Puts the xyz unit vector pointing in the positive-Dec direction in "ddec".
void radec_derivatives(double ra, double dec, double* dra, double* ddec);

// Returns the distance-squared between two (RA,Dec)s in degrees.
double distsq_between_radecdeg(double ra1, double dec1, double ra2, double dec2);

// Returns the arcseconds between two (RA,Dec)s in degrees.
double arcsec_between_radecdeg(double ra1, double dec1, double ra2, double dec2);

// Returns the degrees between two (RA,Dec)s in degrees.
double deg_between_radecdeg(double ra1, double dec1, double ra2, double dec2);

// RA in degrees to Mercator X coordinate [0, 1).
double ra2mercx(double ra);
// Dec in degrees to Mercator Y coordinate [0, 1).
double dec2mercy(double dec);

// RA in degrees to H:M:S
void ra2hms(double ra, int* h, int* m, double* s);
// Dec in degrees to D:M:S
void dec2dms(double dec, int* sign, int* d, int* m, double* s);

double hms2ra(int h, int m, double s);
double dms2dec(int sgn, int d, int m, double s);

void ra2hmsstring(double ra, char* str);
void dec2dmsstring(double dec, char* str);

void project_hammer_aitoff_x(double x, double y, double z, double* projx, double* projy);

void project_equal_area(double x, double y, double z, double* projx, double* projy);

// Converts a distance-squared between two points on the
// surface of the unit sphere into the angle between the
// rays from the center of the sphere to the points, in
// radians.
InlineDeclare Flatten Const double distsq2arc(double dist2);

// Distance^2 on the unit sphere to radians.
// (alias of distsq2arc)
InlineDeclare Flatten Const double distsq2rad(double dist2);

InlineDeclare Flatten Const double distsq2deg(double dist2);

// Distance on the unit sphere to radians.
InlineDeclare Flatten Const double dist2rad(double dist);

// Distance^2 on the unit sphere to arcseconds.
InlineDeclare Flatten Const double distsq2arcsec(double dist2);

// Distance on the unit sphere to arcseconds
InlineDeclare Flatten Const double dist2arcsec(double dist);

// Radians to distance^2 on the unit sphere.
// (alias of arc2distsq)
InlineDeclare Const double rad2distsq(double arcInRadians);

// Radians to distance on the unit sphere.
InlineDeclare Flatten Const double rad2dist(double arcInRadians);

// Converts an angle (in arcseconds) into the distance-squared
// between two points on the unit sphere separated by that angle.
InlineDeclare Flatten Const double arcsec2distsq(double arcInArcSec);

// Arcseconds to distance on the unit sphere.
InlineDeclare Flatten Const double arcsec2dist(double arcInArcSec);

// Degrees to distance on the unit sphere.
InlineDeclare Flatten Const double deg2dist(double arcInDegrees);

InlineDeclare Flatten Const double deg2distsq(double d);

InlineDeclare Flatten Const double arcmin2dist(double arcmin);

InlineDeclare Flatten Const double arcmin2distsq(double arcmin);

// Distance on the unit sphere to degrees.
InlineDeclare Flatten Const double dist2deg(double dist);

#define HELP_ERR -101
#define OPT_ERR -201

void make_rand_star(double* star, double ramin, double ramax,
					double decmin, double decmax);

/* 
 Computes the 2D coordinates (x,y) (in units of a celestial sphere of
 radius 1) that star s would have in a TANGENTIAL PROJECTION defined
 by (centred at) star r.  s and r are both given in xyz coordinates,
 the parameters are pointers to arrays of size 3.

 If "tangent" is true, the projection is the WCS TAN projection; if
 not, it is the WCS SIN projection.

 The resulting x,y coordinates are intermediate world coordinates in
 degrees.  The "x" direction should be positive for increasing RA, "y"
 is increasing Dec.

 WARNING -- this code assumes s and r are UNIT vectors (ie normalized
 to have length 1).
*/
WarnUnusedResult InlineDeclare
anbool star_coords(const double *s, const double *r, 
				 anbool tangent, double *x, double *y);

InlineDeclare void star_midpoint(double* mid, const double* A, const double* B);

#ifdef INCLUDE_INLINE_SOURCE
#define InlineDefine InlineDefineH
#include "astrometry/starutil.inc"
#undef InlineDefine
#endif

#endif