Transforms ========== Many task kinds generate tasks by a process of transforming job descriptions into task definitions. The basic operation is simple, although the sequence of transforms applied for a particular kind may not be! Overview -------- To begin, a kind implementation generates a collection of items; see :doc:`loading`. The items are simply Python dictionaries, and describe "semantically" what the resulting task or tasks should do. The kind also defines a sequence of transformations. These are applied, in order, to each item. Early transforms might apply default values or break items up into smaller items (for example, chunking a test suite). Later transforms rewrite the items entirely, with the final result being a task definition. Transform Functions ................... Each transformation looks like this: .. code-block:: python @transforms.add def transform_an_item(config, items): """This transform ...""" # always a docstring! for item in items: # .. yield item The ``config`` argument is a Python object containing useful configuration for the kind, and is a subclass of :class:`taskgraph.transforms.base.TransformConfig`, which specifies a few of its attributes. Kinds may subclass and add additional attributes if necessary. While most transforms yield one item for each item consumed, this is not always true: items that are not yielded are effectively filtered out. Yielding multiple items for each consumed item implements item duplication; this is how test chunking is accomplished, for example. The ``transforms`` object is an instance of :class:`taskgraph.transforms.base.TransformSequence`, which serves as a simple mechanism to combine a sequence of transforms into one. Schemas ....... The items used in transforms are validated against some simple schemas at various points in the transformation process. These schemas accomplish two things: they provide a place to add comments about the meaning of each field, and they enforce that the fields are actually used in the documented fashion. Keyed By ........ Several fields in the input items can be "keyed by" another value in the item. For example, a test description's chunks may be keyed by ``test-platform``. In the item, this looks like: .. code-block:: yaml chunks: by-test-platform: linux64/debug: 12 linux64/opt: 8 android.*: 14 default: 10 This is a simple but powerful way to encode business rules in the items provided as input to the transforms, rather than expressing those rules in the transforms themselves. If you are implementing a new business rule, prefer this mode where possible. The structure is easily resolved to a single value using :func:`taskgraph.transform.base.resolve_keyed_by`. Exact matches are used immediately. If no exact matches are found, each alternative is treated as a regular expression, matched against the whole value. Thus ``android.*`` would match ``android-api-16/debug``. If nothing matches as a regular expression, but there is a ``default`` alternative, it is used. Otherwise, an exception is raised and graph generation stops. Organization ------------- Task creation operates broadly in a few phases, with the interfaces of those stages defined by schemas. The process begins with the raw data structures parsed from the YAML files in the kind configuration. This data can processed by kind-specific transforms resulting, for test jobs, in a "test description". For non-test jobs, the next step is a "job description". These transformations may also "duplicate" tasks, for example to implement chunking or several variations of the same task. In any case, shared transforms then convert this into a "task description", which the task-generation transforms then convert into a task definition suitable for ``queue.createTask``. Test Descriptions ----------------- Test descriptions specify how to run a unittest or talos run. They aim to describe this abstractly, although in many cases the unique nature of invocation on different platforms leaves a lot of specific behavior in the test description, divided by ``by-test-platform``. Test descriptions are validated to conform to the schema in ``taskcluster/taskgraph/transforms/tests.py``. This schema is extensively documented and is a the primary reference for anyone modifying tests. The output of ``tests.py`` is a task description. Test dependencies are produced in the form of a dictionary mapping dependency name to task label. Job Descriptions ---------------- A job description says what to run in the task. It is a combination of a ``run`` section and all of the fields from a task description. The run section has a ``using`` property that defines how this task should be run; for example, ``mozharness`` to run a mozharness script, or ``mach`` to run a mach command. The remainder of the run section is specific to the run-using implementation. The effect of a job description is to say "run this thing on this worker". The job description must contain enough information about the worker to identify the workerType and the implementation (docker-worker, generic-worker, etc.). Alternatively, job descriptions can specify the ``platforms`` field in conjunction with the ``by-platform`` key to specify multiple workerTypes and implementations. Any other task-description information is passed along verbatim, although it is augmented by the run-using implementation. The run-using implementations are all located in ``taskcluster/taskgraph/transforms/job``, along with the schemas for their implementations. Those well-commented source files are the canonical documentation for what constitutes a job description, and should be considered part of the documentation. following ``run-using`` are available * ``hazard`` * ``mach`` * ``mozharness`` * ``mozharness-test`` * ``run-task`` * ``spidermonkey`` or ``spidermonkey-package`` or ``spidermonkey-mozjs-crate`` or ``spidermonkey-rust-bindings`` * ``debian-package`` * ``toolchain-script`` * ``always-optimized`` * ``fetch-url`` * ``python-test`` Task Descriptions ----------------- Every kind needs to create tasks, and all of those tasks have some things in common. They all run on one of a small set of worker implementations, each with their own idiosyncracies. And they all report to TreeHerder in a similar way. The transforms in ``taskcluster/taskgraph/transforms/task.py`` implement this common functionality. They expect a "task description", and produce a task definition. The schema for a task description is defined at the top of ``task.py``, with copious comments. Go forth and read it now! In general, the task-description transforms handle functionality that is common to all Gecko tasks. While the schema is the definitive reference, the functionality includes: * TreeHerder metadata * Build index routes * Information about the projects on which this task should run * Optimizations * Defaults for ``expires-after`` and and ``deadline-after``, based on project * Worker configuration The parts of the task description that are specific to a worker implementation are isolated in a ``task_description['worker']`` object which has an ``implementation`` property naming the worker implementation. Each worker implementation has its own section of the schema describing the fields it expects. Thus the transforms that produce a task description must be aware of the worker implementation to be used, but need not be aware of the details of its payload format. The ``task.py`` file also contains a dictionary mapping treeherder groups to group names using an internal list of group names. Feel free to add additional groups to this list as necessary. Signing Descriptions -------------------- Signing kinds are passed a single dependent job (from its kind dependency) to act on. The transforms in ``taskcluster/taskgraph/transforms/signing.py`` implement this common functionality. They expect a "signing description", and produce a task definition. The schema for a signing description is defined at the top of ``signing.py``, with copious comments. In particular you define a set of upstream artifact urls (that point at the dependent task) and can optionally provide a dependent name (defaults to build) for use in ``task-reference``/``artifact-reference``. You also need to provide the signing formats to use. More Detail ----------- The source files provide lots of additional detail, both in the code itself and in the comments and docstrings. For the next level of detail beyond this file, consult the transform source under ``taskcluster/taskgraph/transforms``.