data | ||
docs/reference/swe-glib | ||
examples | ||
po | ||
src | ||
tests | ||
.gitignore | ||
.travis.yml | ||
autogen.sh | ||
configure.ac | ||
Makefile.am | ||
README.md | ||
swe-glib.mk |
SWE-GLib
SWE-GLib is a GLib style wrapper library around Astrodienst's Swiss Ephemeris library.
The source tree contains Astrodienst's ephemeride files, as requested by Alois Treindl of Astrodienst in a mail written to me on 24 July, 2013.
GTK-Doc
The project utilizes GTK-Doc, requiring version 1.19 or later. Although the generated documentation is a bit messy (not everything is documented, and there are some unresolved variables, like [SERVER] on the generated index page.
Still, the documentation generates well, and at least gives a clue about object usage.
Bindings
SWE-GLib utilizes GObject Introspection, which means it is available for many languages. Check out the examples directory for some sample code!
Usage
Many functions return non-opaque C structs; their documentation can be found inline, and in the generated GTK-Doc. Unless otherwise stated, the returned values should never be freed.
Creating the required objects
Then you need to create a GsweTimestamp
object:
GsweTimestamp *timestamp = gswe_timestamp_new_from_gregorian_full(1983, 3, 7, 11, 54, 45, 0, 1.0);
The GsweTimetamp
object is used to convert dates between the Gregorian calendar dates and Julian Day values (not to be confused with Julian calendar dates).
Next, you have to create a GsweMoment
object:
GsweMoment *moment = gswe_moment_new_full(timestamp, 19.081599, 47.462485, 300.0, GSWE_HOUSE_PLACIDUS);
The GsweMoment
object holds information of a given moment at a given place on earth. gswe_moment_new_full()
requires a GsweTimestamp
object, some geographical coordinates (in degrees) together with altitude above sea level (in meters), and a house system to use.
Adding planets
After that you have to add some planets you want to do calculations on.
gswe_moment_add_planet(moment, GSWE_PLANET_SUN);
Alternatively, you can add every planets known by SWE-GLib with
gswe_moment_add_all_planets(moment);
Getting planet positions and such
Then, you can get the planet data with
GswePlanetData *sun_data = gswe_moment_get_planet(moment, GSWE_PLANET_SUN);
Getting aspects and antiscia
SWE-GLib is also able to calculate aspects and antiscia. This functionality does not exist in the Swiss Ephemeris library, though. For this, of course, you have to add multiple planets (at least two) to your GsweMoment
. After that, you can call gswe_moment_get_planet_aspects()
and gswe_moment_get_planet_antiscia()
.
GList *sun_aspects = gswe_moment_get_planet_aspects(moment, GSWE_PLANET_SUN);
GList *sun_antiscia = gswe_moment_get_planet_antiscia(moment, GSWE_PLANET_SUN);
The returned GList objects hold zero or more GsweAspectData
or
GsweAntiscionData
objects, respectively.
Getting the Moon phase
Last, but not least, SWE-GLib can calculate Moon's phase at the given
moment. For that, you have to call gswe_moment_get_moon_phase()
:
GsweMoonPhaseData *moon_phase = gswe_moment_get_moon_phase(moment);
About altitude
The Swiss Ephemeris library requires the altitude value to be specified for several calculations. It also notifies how important it is:
the altitude above sea must be in meters. Neglecting the altitude can result in an error of about 2 arc seconds with the moon and at an altitude 3000m.
2 arc seconds is about 0.000555 degrees of error, which is, well, kind of small. Of course, if you need very precise horoscopes or need planetary positions for a totally different thing, you should really provide a (close to) exact value; otherwise, it is safe to pass any value (well, which seems logical: the average level of all dry lands is about 840 meters; the average level of the whole planet Earth (including oceans and seas) is around 280 meters. Providing a value of ~400 should be OK most of the time).
API stability
The project is currently transitioning to 2.0. master is a bit fragile
at the moment, 1.x versions are considered to be stable (although see
commit 8f52aba
about a huge typo-bug).
Limitations
Topocentric calculations only
Although the original Swiss Ephemeris library supports it, SWE-GLib can't do Heliocentric, nor Geocentric (as seen from the center of Earth) calculations, only Topocentric (as seen from a given point on Earth’s surface) calculations yet.
Database size
The size of all data files provided by Astrodienst is around 40MB. Although it should not be a problem with today's home hardware, it can be a hard requirement on embedded systems. For basic calculations, keeping the following files under $(datadir)/swe-glib is usually enough:
seas_18.se1
semo_18.se1
sepl_18.se1
Fixed stars are not known yet
Although Swiss Ephemeris has the functionality to calculate the position of fixed stars, SWE-GLib doesn't provide such functionality. This, however, is a planned feature for the close future.
Licencing
As the underlying Swiss Ephemeris is published under GPL (or a commercial license I can not afford), SWE-GLib is also uses that. This means that you can currently use SWE-GLib in software published under the GNU GPL v3 (or, at your option, any later version).