Version 2.x, originally released March, 2022 (see above for current installable version)
PDS Ring-Moon Systems Node, SETI Institute
cspyce
is a Python module that provides an interface to the C-language CSPICE
library produced by the Navigation and Ancillary Information Facility
(NAIF) of NASA's Planetary Data System (PDS).
It implements most functions of CSPICE in a Python-like way, while also
supporting numerous enhancements, including support for Python exceptions,
array inputs, and aliases.
cspyce
may be installed by running pip install cspyce
.
Python versions 3.9 thru 3.12 are currently supported, with pre-built wheels available for Linux, MacOS, and Windows. NumPy 1.x and 2.x are supported.
If you are looking for information on running or distributing this code from
the GitHub sources, look at the file README-developers.md
in this directory.
cspyce
has been designed to replicate the core features of CSPICE for
users who wish to translate a program that already exists. Function names in
cspyce
match their CSPICE names.
However, it is also designed to behave as much as possible like a normal Python module. To that end, it has the following features.
-
The C language requires buffers to be allocated for output and it requires array sizes to be included for both input and output. The
cspyce
module, instead, eliminates all extraneous inputs, and all output arguments are returned as a list (or as a single object if the function only returns one item). -
cspyce
has been fully integrated with Python's exception handling; programmers can still opt to use CSPICE's error handling mechanism if they wish to. -
All
cspyce
functions can handle positional arguments as well as arguments passed by name. -
All
cspyce
functions have informative docstrings, so typinghelp(function)
provides useful information. -
Many
cspyce
functions take sensible default values if input arguments are omitted. -
All
cspyce
functions that take filename arguments now support path-like-arguments. A path-like argument could be a strings, a byte string, or apathlib.Path
. Thepathlib.Path
class provides an object-oriented class for manipulating file-system paths and performing common operations on files.
In addition, the cspyce
module takes advantage of features of the Python
language to provide numerous options about how the functions perform their work.
These options include:
-
Whether to return a CSPICE-style error condition or to raise a Python exception.
-
How to handle CSPICE functions that return a status flag, e.g., "found" or "ok", instead of using the CSPICE toolkit's error handling mechanism.
-
Whether to allow
cspyce
functions to accept arrays of inputs all at once, rather than looping through inputs in Python. -
Whether to automate the translation between SPICE body and frame IDs and their associated names.
-
Whether to allow
cspyce
to support aliases, in which the same body or frame is associated with alternative names or IDs.
In CSPICE, the user can designate what to do in the event of an error condition
using the function erract()
. In CSPICE, the available options are "RETURN",
"REPORT", "IGNORE", "ABORT", and "DEFAULT". The cspyce
version of this
function adds new options "EXCEPTION" and "RUNTIME" to the suite of error
handling options supported by CSPICE.
-
As usual, the user can select the exception handling mechanism to use by calling the function erract(). In
cspyce
, the default is "EXCEPTION". -
When using the "EXCEPTION" option, each CSPICE error condition raises a Python exception rather than setting the
failed()
flag. The exception contains the text of the CSPICE error, in the form (short message + " -- " + long message). The CSPICE error conditions are mapped to standard Python exception types in a sensible way:KeyError
indicates that a SPICE ID or name is unrecognized.ValueError
indicates that one of the inputs to a function had an invalid value.TypeError
indicates that one of the inputs to a function had an invalid type.IndexError
indicates that an integer index is out of range.IOError
indicates errors with reading and writing files, including SPICE kernels. IOError can also indicate that needed information was not in one of the furnished kernels.MemoryError
indicates that adequate memory could not be allocated, or that the defined size of a memory buffer in C is too small.ZeroDivisionError
indicates that a divide-by-zero has occurred.RuntimeError
indicates that an action is incompatible with some aspect of the CSPICE module's internal configuration.
-
When using one of CSPICE's intrinsic error handling methods, no exception will be raised, but a call to
failed()
will reveal whether an error has occurred. A call toreset()
is needed to clear the error. -
Care has been taken to reduce the chances that the "dangerous" options "IGNORE" and "REPORT" will cause a segmentation fault. However, this possibility cannot be entirely ruled out, so caution is advised.
-
Because it would be a highly questionable thing to do, the "ABORT" and "DEFAULT" options are overridden by "EXCEPTION" when the user is running
cspyce
from an interactive shell. However, they resume their standard effects during non-interactive runs. -
When using the "RUNTIME" option, each CSPICE error condition raises a Python
RuntimeError
exception rather than setting thefailed()
flag. This is similar to the "EXCEPTION" option except the type of exception is always the same. -
Certain out-of-memory conditions are beyond the control of the CSPICE library. These will always raise a MemoryError exception, regardless of the exception handling method chosen.
Many CSPICE functions bypass the library's own error handling mechanism; instead
they return a status flag, sometimes called "found" or "ok", or perhaps an empty
response to indicate failure. The cspyce
module provides alternative options
for these functions.
Within cspyce
, functions that return error flags have an alternative
implementation with a suffix of "_error", which uses the CSPICE/cspyce
error
handling mechanism detailed above instead.
Note that most _error
versions of functions have fewer return values than the
associated non-error versions. The user should be certain which version is being
used before interpreting the returned value(s).
The cspyce
module provides several ways to control which version of the
function to use:
-
The function
use_flags()
takes a function name or list of names and designates the original version of each function as the default. If the input argument is missing, original versions are selected universally. -
The function
use_errors()
takes a function name or list of names and designates the_error
version of each function as the default. If the input argument is missing,_error
versions are selected universally.
To provide a more consistent Python interface, the _error
versions of all
cspyce
functions are selected by default. You can also choose between the
"flag" and "error" versions of a function using cspyce
function attributes,
as discussed below.
Nearly every function that takes floating-point input (be it a
scalar, 1-D array, or 2-D array) has a vectorized version that allows you to
pass a vector of these items in place of a single value. The CSPICE function is
called for each of the provided inputs, the results are collected, and the
cspyce
function returns a vector of results.
-
Vectorized versions have the same name but with
_vector
appended. -
In a vectorized function, you can replace any or all floating-point input parameters with an array having one extra leading dimension. Integer, boolean, and string inputs cannot be replaced by arrays.
-
If no inputs have an extra dimension, then the result is the same as calling the original, un-vectorized function.
-
Otherwise, all returned quantities are replaced by arrays having the size of the largest leading axis.
-
Note that it is permissible to pass arrays with different leading axis sizes to the function. The vectorized function cycles through the elements of each array repeatedly if necessary. It may make sense to do this if each leading axis is an integer fraction of the largest axis size. For example, if the first input array has size 100 and the second has size 25, then the returned arrays(s) will have 100 elements and the values of the second will each be used four times. However, caution is advised when using this capability.
-
Some functions are not vectorized. These include:
- Functions that have no floating-point inputs.
- Functions that include strings among the returned quantities.
- Functions that already return arrays where the leading axis could be variable in size.
-
In the two cases (
ckgp
andckgpav
) where a function can be both vectorized and either raise an error or return a flag, the_vector
suffix comes before_error
.
An optional import allows the cspyce
module to support multidimensional
arrays:
import cspyce
import cspyce.arrays
The latter import creates a new function in which the suffix _array
replaces
_vector
for every vectorized function. Whereas _vector
functions support
only a single extra dimension, _array
functions follow all the standard rules
of shape broadcasting as defined in NumPy. For example, if one input has leading
dimension (10,4) and another has dimension (4,), then the two shapes will be
broadcasted together and returned quantities will be arrays with shape (10,4).
You can choose between the scalar, vector, and array versions of a function by
using their explicit names, or by using cspyce
function attributes, as discussed
below.
Aliases allow the user to associate multiple names or SPICE codes with the same CSPICE body or frame. Aliases can be used for a variety of purposes.
- You can use names and codes interchangeably as input arguments to any
cspyce
function. - You can use a body name or code in place of a frame name or code, and the primary frame associated with that identified body will be used.
- Strings that represent integers are equivalent to the integers themselves.
Most importantly, you can allow multiple names or codes to refer to the same
CSPICE body or frame. For bodies and frames that have multiple names or codes,
calls to a cspyce
function will try each option in sequence until it finds one
that works. Options are always tried in the order in which they were defined, so
higher-priority names and codes are tried first.
Example 1: Jupiter's moon Dia uses code 553, but it previously used code
55076. With 55076 defined as an alias for 553, a cspyce
call will return
information about Dia under either of its codes.
Example 2: The Earth's rotation is, by default, modeled by frame "IAU_EARTH".
However, "ITRF93" is the name of a much more precise description of Earth's
rotation. If you define "IAU_EARTH" as an alias for "ITRF93", then the cspyce
toolkit will use ITRF93 if it is available, and otherwise IAU_EARTH.
Immediately after a cspyce
call involving aliases, you can find out what value
or values were actually used by looking at attributes of the function. For
example, the first input to the cspyce
function spkez
is called targ
and
it identifies the code of a target being observed. After a call to
cspyce.spkez(553, ...)
the value of cspyce.spkez.targ
will be the code actually used, in this case
either 553 or 55076.
To enable aliases, you must import an additional module
import cspyce
import cspyce.aliases
(Note that cspyce.aliases
and cspyce.arrays
can both be imported, and in
either order. Note also that these are unconventional modules, in that they
introduce new functionality into the cspyce
namespace rather than creating
new namespaces called cspyce.aliases
and cspyce.arrays
.)
With this import, a new function is defined for every cspyce
function that takes
a frame or body as input. The new function has the same name as the pre-existing
cspyce
function, but with _alias
inserted immediately after the original
cspyce
name (and before any other suffix such as _vector
or _error
).
You can make alias support the default for individual cspyce
functions or for
the entire cspyce
module by calling cspyce.use_aliases()
. These versions
can subsequently be disabled as the default by calling cspyce.use_noaliases()
(see more detailed discussion below).
To define a body alias or frame alias, call
cspyce.define_body_aliases(name_or_code, name_or_code, ...)
cspyce.define_frame_aliases(name_or_code, name_or_code, ...)
where the arguments are an arbitrary list of codes and names.
To determine the aliases associated with a name or code, call
cspyce.get_body_aliases(name_or_code)
cspyce.get_frame_aliases(name_or_code)
where the argument is either a name or a code.
You can also select between the alias-supporting and alias-nonsupporting versions of a function using function attributes as discussed below.
A cspyce
function can accumulate several suffixes, based on the particular
behavior, as so:
basename[_alias][_vector|_array][_error]
Only functions that are truly distinct are defined. For example, if a function
does not have a vector option, then no function will exist containing the
_vector
suffix.
You can use these functions to set defaults:
cspyce.use_flags()
cspyce.use_errors()
cspyce.use_scalars()
cspyce.use_vectors()
cspyce.use_arrays()
cspyce.use_aliases()
cspyce.use_noaliases()
Each function can take one or more arguments referencing specific cspyce
functions, in which case the defaults only apply to those functions. If no
arguments are specified, the default applies to all functions. For example,
to use "flags" as the default for all functions except ckgp
, you could use:
cspyce.use_flags()
cspyce.use_errors(cspyce.ckgp)
Function attributes provide a simpler mechanism for choosing the needed
version of a function, without needing to remember the suffix rules. Every
cspyce
function has these attributes, each of which identifies another
(or possibly the same) cspyce
function:
Attribute | Meaning |
---|---|
func.flag |
the equivalent function without the _error suffix, if any. |
func.error |
the equivalent function with the _error suffix, if any. |
func.scalar |
the equivalent function without _array or _vector suffixes. |
func.vector |
the equivalent function with the _vector suffix, if any. |
func.array |
the equivalent function with the _array suffix, if any. |
func.alias |
the equivalent function with the _alias suffix, if any. |
func.noalias |
the equivalent function without the _alias suffix, if any. |
These attributes are always defined, even if the particular option is not supported by that function. This saves the programmer the effort of remembering, for example, which functions support aliases or which functions support flags.
Thus, if the programmer wishes to be sure they are using the error version of
function bodn2c
, and wants the vector version if it exists (but it doesn't!),
they can call
cspyce.bodn2c.error.vector(args, ...)
cspyce
provides an enhanced version of SpiceCell
to make it simpler to use for
both CSPICE and in Python.
In the documentation that follows, active elements refer to those elements in the
SpiceCell
whose index
is such that 0 ≤ index < spice_cell.card
.
To create a SpiceCell
:
from cspyce import SpiceCell, SPICE_CELL_INT, SPICE_CELL_DOUBLE
spice_cell = SpiceCell(typeno=SPICE_CELL_INT, size=20)
spice_cell = SpiceCell(typeno=SPICE_CELL_DOUBLE, size=10)
With these constructors, spice_cell.card
will be set to 0 and there will initially be
no active elements.
If you already have data that you want to convert to a spice cell, you can use a simpler interface:
spice_cell = SpiceCell([1, 2, 3, 4, 5])
spice_cell = SpiceCell(np.arange(1.0, 10.0))
spice_cell = SpiceCell(np.arange(1.0, 10.0), size=40) # set size explicitly
If you use these constructions, Python will create a SpiceCell
whose size is a little
bigger than the length of the given data. The passed first argument will be the active
elements.
Any CSPICE function that expects a SpiceCell
as an input can also be passed an array,
a tuple, or anything that can reasonably be converted into an appropriately typed
SpiceCell
:
Any CSPICE function that returns a SpiceCell
as a result takes an optional final
argument.
- If this argument is omitted, a
SpiceCell
with a function-specific default capacity will be created, and the output will be placed into it. - If this argument is a
SpiceCell
, it will be used as the output argument. - If this argument is an integer, a
SpiceCell
with that capacity will be created and used as the output.
In all cases, the SpiceCell
output will also be a return value.
>>> import cspyce
>>> cspyce.wninsd(2.0, 4.9, (1.0, 3.0, 5.0, 7.0, 9.0, 11.0))
<SpiceCell double 6/12 [ 1. 4.9 5. 7. 9. 11. ]>
SpiceCell
offers the following methods so that they behave like Python sequences.
spice_cell[index]
, spice_cell[index] = value
: Gets or sets the index
-th element of the SpiceCell
.
Must have -len(spice_cell) ≤ index < spice_cell.size
. As in Python, we allow
negative indices, but -1, -2, etc count backwards from the last active elements.
len(spice_cell)
: Returns the number of active elements of spice_cell
.
spice_cell.append(value)
: If value
is a float or integer, it is added to the SpiceCell
's active cells.
If value
is an array, all of its elements are added to the SpiceCell
's active cells.
The cell's maximum size is grown if necessary.
spice_cell.extend(values)
: Appends each value in values
to the end of the SpiceCell
's active cells.
Each element of values
can be a float, an integer, or an array.
The SpiceCell
's maximum size is grown if necessary.
spice_cell += values
: Synonym for spice_cell.extend(values)
spice_cell.clear()
: Make all elements inactive. Same as spice_cell.card = 0
.
iter(spice_cell)
: Iterates through the active elements of spice_cell
.
Because of this iterator, list(spice_cell)
, set(spice_cell)
, and tuple(spice_cell)
work as expected.
You can also write a for loop for item in spice_cell: ...
to iterate through
the active elements.
bool(spice_cell)
: If a spice_cell
is used in a boolean context, its value is False
if all elements
are inactive (spice.cell.card == 0
), and True
otherwise.
SpiceCell
also has the following methods and properties specific to a SpiceCell
.
spice_cell.size
: Gets the current maximum size of the SpiceCell
.
spice_cell.size = value
: Grows or shrinks the maximum size of the SpiceCell
.
If the number of active elements is greater than value
, it is reduced to value
.
This operation is a cspyce
enhancement that does not exist in CSPICE.
spice_cell.card
: Same as len(spice_cell)
. (Also known as the "cardinality", hence the name).
spice_cell.card = value
: Changes the number of active elements in the SpiceCell
.
Must have 0 ≤ value < spice_cell.size
.
spice_cell.as_array()
: Returns a view of the active contents of the array as a numpy array
spice_cell.as_intervals()
: Returns a view of the active contents of the array as a 2-dimensional card/2
x 2 array.
Many SpiceCell
s are used to represent intervals in which each
pair of numbers represents the lower and upper bounds.
Although cspyce
's SpiceCell
s can grow and shrink, CSPICE is not aware of this
capability. Its functions will still raise a WINDOWOVERFLOW if SpiceCell.size
is
not large enough to hold the results. The user must increase SpiceCell.size
and try
again.
Although internally, a SpiceCell
is a flat array of integers or floats,
some CSPICE routines treat the contents of a SpiceCell
as if it were a 2-dimensional array.
For example, some CSPICE routines expect the SpiceCell
to contain pairs of values
where each pair represents the limits of an interval.
To simplify dealing with this use case, the methods append
and extend
have been enhanced.
You can pass an array or an array-like object to append
, and all elements of the
array will be added to the SpiceCell
.
Likewise you can pass extend
a sequence of array-like objects, and all of them will
be added to the SpiceCell
.
So, for example, you could write:
spice_cell.append([10, 20])
spice_cell.extend([[35, 50], [90, 100], [120, 140]])
to add intervals to your SpiceCell.
To view a SpiceCell
containing intervals, you can use spice_cell.as_intervals()
as described above.
This is just a shortcut for spice_cell.as_array().reshape(-1, 2)
, where
-1 is a special marker to reshape
saying "figure out this value from the size of the
array and the other dimensions".
The expression spice_cell.as_array().reshape(-1, 3)
would give an array of triples.
self.as_array().reshape(-1, 4, 4)
gives an array of 4x4 matrices.