Provided by: gyoto-bin_1.4.4-7build1_amd64 
NAME
Gyoto - the General relativitY Orbit Tracer of Observatoire de Paris
SYNOPSIS
gyoto [--silent|--quiet|--verbose[=N]|--debug]
[--no-sigfpe]
[--help[=class]] [--version] [--list]
[--ispec=i0:i1:di] [--jspec=j0:j1:dj]
([--imin=i0] [--imax=i1] [--di=di])
([--jmin=j0] [--jmax=j1] [--dj=dj])
[--time=tobs] [--tmin=tmin]
[--fov=angle] [--resolution=npix] [--distance=dist]
[--paln=Omega] [--inclination=i] [--argument=theta]
[--nthreads=nth] [--nprocesses=nworkers]
[--plugins=pluglist]
[--impact-coords[=fname.fits]]
[--unit[=unit]]
[--parameter=Path::Name[=value]]
[--xmlwrite=output.xml]
[--] input.xml output.fits
gyoto mk-video [options]
DESCRIPTION
Gyoto is a framework for computing geodesics in curved space-times. The gyoto utility program uses this
framework to compute images of astronomical objects in the vicinity of compact objects (e.g. black-
holes). Such images are distorted by strong gravitational lensing.
In the first form, gyoto takes a scenery description in XML format (input.xml), computes this scenery
using relativistic ray-tracing, and saves the result in FITS format.
In the second form, gyoto produces a movie. See gyoto mk-video --help for details. In particular, it can
read a Scenery in XML format and a trajectory also in XML format (for instance produced with gyotoy(1),
see below) and produce a movie as would be seen by an observer following this trajectory. The Gyoto plug-
in python and the Python module OpenCV-Python must be installed.
A companion program, gyotoy(1), can be used to interactively visualize a single geodesic in any Gyoto
metric (the trajectory of a single photon or massive particle).
Ray-tracing can be very time consuming. It is possible to interrupt the process at any time by hitting
^C, which will save the already-computed part of the image before exiting the program. You can then
compute the rest of the image later using the --jmin option.
OPTIONS
The gyoto program accepts many options. Most have a long name (e.g. --parameter) and a short name (e.g.
-E). When an option takes an argument, this argument must follow immediately the short option (e.g.
-EPath::Name) and be separated from the long option by exactly the character "=" (e.g.
--parameter=Path::Name). Long options can be abbreviated as long as the abbreviation is unambiguous (e.g.
--par=Path::Name). Most options can appear several times and are processed in the order they appear in
the command line. The two positional parameters (input.xml and output.fits) can appear anywhere in the
command line, except if they start with a minus character (-) in which case they must appear last, after
the option --.
Getting help
--help[=class]
-h[class]
Without argument class, print help summary. Although not as verbose as this manual page, the
output of gyoto -h may be more complete and up to date. If class is specified, list and document
the properties of class (e.g. "Screen", "Astrobj::Star"). Then exit the program, unless --list
below has only been specified.
--list
-l Print list of currently registered Astrobj, Metric etc., then exit the program. This occurs after
loading input.xml (if provided), so that any plug-in specified in the input file have already been
loaded.
--version
-V Print the Gyoto version, ABI compatibility version, copyright information and exit.
Setting the verbosity level
Those options are processed separately from the other and take effect early in the program execution.
--silent
-s No output.
--quiet
-q Minimal output.
--verbose[=N]
-v[N] Verbose mode. Verbosity level N may be specified.
--debug
-d Insanely verbose.
--no-sigfpe
Do not try to raise SIGFPE upon arithmetic exceptions. This option is meaningful only if fenv.h
support is built in. Else this option is a no-op as SIGFPE is never raised.
Loading plug-ins
--plugins[=[nofail:]plug1[,[nofail:]plug2][...]]
-p[[nofail:]plug1[,[nofail:]plug2][...]]
Comma-separated list of Gyoto plugins to load. Overrides GYOTO_PLUGINS environment variable below.
Only the last occurrence matters.
Selecting a region
It is possible to ray-trace only part of the scenery by providing the pixel coordinates of the bottom-
left (i0, j0) and top-right (i1, j1) corners of the region. The bottom-left pixel of the complete image
has coordinates i=1 and j=1. The step in each direction (di, dj) can also be specified.
--ispec=[i0]:[i1]:[di]
-i[i0]:[i1]:[di]
--jspec=[j0]:[j1]:[dj]
-j[j0]:[j1]:[dj]
Default values: x0: 1; x1: npix (see option --resolution below); dx: 1.
--ispec=N
-iN
--jspec=N
-jN Set both x0 and x1 to N.
Alternate region-selection options:
Those options are still supported for backward compatibility. They are deprecated in favour of --ispec
and --jspec above:
--imin=i0
Default value: 1.
--imax=i1
Default value: npix (see option --resolution below).
--di=di
Default value:1.
--jmin=j0
Default value: 1.
--jmax=j1
Default value: npix (see option --resolution below).
--dj=dj
Default value:1.
Setting the camera position
The following parameters are normally provided in the Screen section of input.xml but can be overridden
on the command line for instance to make a movie (by calling gyoto for each movie frame, changing only
the option --time).
--time=tobs
The observing time in geometrical units.
--fov=angle
The field-of-view of the camera, in radians.
--resolution=npix
-rnpix Number of rows and columns in the output image.
--distance=dist
(Coordinate) distance from the observer to the center of the coordinate system, in geometrical
units.
--paln=Omega
Position angle of the line of nodes, in radians, East of North. The is the angle between the North
direction and the line of nodes (see below).
--inclination=i
Angle between the plane of the sky and the equator of the coordinate system. The intersection of
those two planes is the line of nodes.
--argument=theta
Angle in the equatorial plane between the line of nodes and one of the main axes of the coordinate
system.
Miscellaneous
Unsorted option(s):
-- Ends option processing, in case either input.xml or output.fits starts with "-".
--nthreads=nth
-Tnth Number of parallel threads to use. For instance, on a dual-core machine, --nthreads=2 should yield
the fastest computation. This option is silently ignored if Gyoto was compiled without POSIX
threads support. Note that the metric and object are replicated for each thread which can lead to
a decrease in performance if either is memory-intensive. Setting this option to 0 is equivalent to
setting it to 1.
--nprocesses=nworkers
-Pnworkers
Number of MPI processes to spawn for parallel ray-tracing, in addition to the main gyoto process
which remains for managing the computation. Ignored if gyoto was compiled without MPI support.
nworkers is the number of workers spawned. The total number of processes is nprocs=nworkers+1.
-P0 disables MPI multi-processing, while -P1 uses two processes: the manager and one worker. If
nworkers is >0, --nthreads is ignored. Note that the MPI environment usually needs to be set-up
using some variant of mpirun(1). If mpirun starts several instances of gyoto, nworkers must be
>0, but its exact value is ignored as the set of processes used is exactly that launched by
mpirun. In other words, Gyoto can be called in a number of ways that should be functionally
equivalent:
• let mpirun launch nprocs instances of the gyoto executable:
mpirun -np -Pnprocs gyoto -P1 input.xml output.fits
• let mpirun launch 1 instance of the gyoto executable, and Gyoto spawn nworkers worker
processes:
mpirun -np 1 gyoto -Pworkers input.xml output.fits
• let mpirun launch 1 instance of the gyoto executable, and nworkers worker processes:
mpirun -np 1 gyoto -P1 input.xml output.fits : \
-np nworkers gyoto-mpi-worker.version
where version is the ABI compatibility version of gyoto (see gyoto --version).
--impact-coords[=impactcoords.fits]
In some circumstances, you may want to perform several computations in which the computed
geodesics end up being exactly identical. This is the case for instance if you want to experiment
changing the spectrum of a star or when making a movie of a rotating, optically thick disk. This
option provides a mechanism to not recompute the geodesics in the most simple case:
• the Screen is always at the same position;
• the Metric is always exactly the same;
• the Astrobj is optically thick (no radiative transfer processing is necessary);
• the location and shape of the Astrobj is always the same.
If --impact-coords is passed without specifying impactcoords.fits, the 8-coordinate vectors of the
object and photon at impact point are saved for each point of the Screen. Missing data (no impact)
are set to DBL_MAX. These data are saved as a supplementary image HDU in the FITS file which is
identified by its EXTNAME: "Gyoto Impact Coordinates". The FITS keyword "HIERARCH Gyoto Observing
Date" of this HDU holds the observing date (in geometrical unit).
If impactcoords.fits is specified, the above mentioned data are read back from this file. The ray-
tracing is not performed, but the Gyoto::Astrobj::Generic::processHitQuantities() method is called
directly, yielding the same result if the four conditions above are met. The observing date stored
in the FITS keyword "HIERARCH Gyoto Observing Date" is compared to the date specified in the
screen or using the --time option and the impact coordinates are shifted in time accordingly.
It is also possible to set the two versions of this option at the same time:
--impact-coords=impactcoords.fits --impact-coords
In this case, the impact coordinates are read from impactcoords.fits, shifted in time, and saved
in output.fits.
--unit[=unit]
-u[unit]
Specify unit to use for allowing instances of --parameter, until next instance of --unit.
--parameter=Path::Name[=value]
-EPath::Name[=value]
Set arbitrary parameter by name. Parameters can be set in the Astrobj, Metric etc. using the Path
componenent. For instance,
For instance, assuming the Astrobj in star.xml has a property named "Radius" that can be set in
unit "km", and a property named "Spectrum" which has a property named "Temperature", we can set
the radius, temperature and the quantities to compute (a property in the Scenery itself) with:
gyoto -EQuantities=Spectrum \
-ukm -EAstrobj::Radius=3 \
-u -EAstrobj::Spectrum::Temperature=1000 \
star.xml star.fits
gyoto --parameter=Quantities=Spectrum \
--unit=km --parameter=Astrobj::Radius=3 \
--unit="" --param=Astrobj::Spectrum::Temperature=1000 \
star.xml star.fits
--xmlwrite=output.xml
-Xoutput.xml
Write back scenery to an XML file. The new file will contain additional default parameters and
reflect the effect of --(astrobj|metric|scenery|screen|spectrometer)-parameter that appear before
--xmlwrite. Can appear several times, e.g. to generate several XML files with different settings.
FILES
input.xml
A gyoto input file in XML format. Several examples are provided in the source doc/examples
directory. Depending on how you installed gyoto, they may be installed on your system in a place
such as /usr/share/doc/libgyoto/examples/. It goes beyond the scope of this manpage to document
the XML file format supported by Gyoto, please refer to the library documentation which may be
distributed by your package manager, can be compiled from the Gyoto source, and can be consulted
online at http://gyoto.obspm.fr/.
output.fits
The output image in FITS format. gyoto will not overwrite output.fits unless it is prefixed with
an (escaped) "!": "gyoto in.xml \!out.fits". This file may actually consist in a stack of images
depending on the Gyoto Quantities and on the Spectrometer specified in input.xml. For further
information on the FITS format, see http://fits.gsfc.nasa.gov/.
ENVIRONMENT
GYOTO_PLUGINS
Gyoto astronomical objects and metrics are implemented in plug-ins. To use more (or less!) than
the standard plug-ins, you may set the environment variable GYOTO_PLUGINS to a comma-separated
list of plug-ins. gyoto will exit with an error status if unable to load a specified plug-in,
unless it is prefixed with "nofail:" in GYOTO_PLUGINS. This environment variable is overridden by
he --plugins command-line parameter. Default value: "stdplug,nofail:lorene". Gyoto attempts to
find plug-ins first by relying on the system's dynamic linker (so paths in e.g. LD_LIBRARY_PATH
and ld.so.conf are searched first). If that fails, it looks in PREFIX/lib/gyoto/ and finally in
PREFIX/lib/gyoto/SOVERS/ where PREFIX and SOVERS are two compile-time options. PREFIX usually is
/usr/local or /usr. At the time of writing, SOVERS is 0.0.0.
EXIT STATUS
gyoto returns 0 upon success, 1 if unable to parse the command line or to interpret input.xml, and a
CFITSIO error code if an error occurs when trying to open, write to, or close output.fits. Refer to the
CFITSIO documentation for more details.
AUTHOR
Thibaut Paumard <thibaut.paumard@obspm.fr> wrote this manual.
SEE ALSO
gyotoy(1)
Science JULY 2019 GYOTO(1)