Concepts

Processing

A configuration file is evaluated in a custom Starlark dialect which provides primitives used by PyOxidizer. This dialect provides some well-defined global variables (defined in UPPERCASE) as well as some types and functions that can be constructed and called. See Global Symbols for a full list of what’s available to the Starlark environment.

Since Starlark is effectively a subset of Python, executing a PyOxidizer configuration file is effectively running a sandboxed Python script. It is conceptually similar to running python setup.py to build a Python package. As functions within the Starlark environment are called, PyOxidizer will perform actions as described by those functions.

Targets

PyOxidizer configuration files are composed of functions registered as named targets. You define a function that does something then register it as a target by calling the register_target() global function provided by our Starlark dialect. e.g.:

def get_python_distribution():
    return default_python_distribution()

register_target("dist", get_python_distribution)

When a configuration file is evaluated, PyOxidizer attempts to resolve an ordered list of targets This list of targets is either specified by the end-user or is derived from the configuration file. The first register_target() target or the last register_target() call passing default=True is the default target.

When evaluated in Rust build script mode (typically via pyoxidizer run-build-script), the default target will be the one specified by the last register_target() call passing default_build_script=True, or the default target if no target defines itself as the default build script target.

PyOxidizer calls the registered target functions in order to resolve the requested set of targets.

Target functions can depend on other targets and dependent target functions will automatically be called and have their return value passed as an argument to the target function depending on it. See register_target() for more.

The value returned by a target function is special. Some types defined by our Starlark dialect have special build or run behavior associated with them. If you run pyoxidizer build or pyoxidizer run against a target that returns one of these types, that behavior will be performed.

For example, if you return a PythonExecutable, the build behavior is to produce that executable file and the run behavior is to run that built executable.

See Types with Target Behavior for the full list of types with registered target behaviors.

Python Distributions Provide Python

The PythonDistribution Starlark type defines a Python distribution. A Python distribution is an entity which contains a Python interpreter, Python standard library, and which PyOxidizer knows how to consume and integrate into a new binary.

PythonDistribution instances are arguably the most important type in configuration files because without them you can’t perform Python packaging actions or construct binaries with Python embedded.

Instances of PythonDistribution are typically constructed from default_python_distribution().

Python Executables Run Python

The PythonExecutable Starlark type defines an executable file embedding Python. Instances of this type are used to build an executable file (and possibly other files needed by it) that contains an embedded Python interpreter and other resources required by it.

Instances of PythonExecutable are derived from a PythonDistribution instance via PythonDistribution.to_python_executable(). There is typically a standalone function/target in config files for doing this.

Python Resources

At run-time, Python interpreters need to consult resources like Python module source and bytecode as well as resource/data files. We refer to all of these as Python Resources.

Configuration files represent Python Resources via the following types:

Specifying Resource Locations

Various functionality relates to the concept of a resource location, or where a resource should be loaded from at run-time. See Managing How Resources are Added for more.

Resource locations are represented as strings in Starlark. The mapping of strings to resource locations is as follows:

in-memory

Load the resource from memory.

filesystem-relative:<prefix>

Install and load the resource from a filesystem relative path to the build binary. e.g. filesystem-relative:lib will place resources in the lib/ directory next to the build binary.