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Configuring Bazaar
==================
A configuration option has:
- a name: a valid python identifier (even if it's not used as an
identifier in python itself)
- a value: a unicode string
Sections
--------
Options are grouped into sections which share some properties with the well
known dict objects:
- the key is the name,
- you can get, set and remove an option,
- the value is a unicode string.
MutableSection is needed to set or remove an option, ReadOnlySection should
be used otherwise.
Stores
------
Options can be persistent in which case they are saved into Stores.
``config.Store`` defines the abstract interface that all stores should
implement.
This object doesn't provide direct access to the options, it only provides
access to Sections. This is deliberate to ensure that sections can be
properly shared by reusing the same underlying objects. Accessing options
should be done via the ``Section`` objects.
A ``Store`` can contain one or more sections, each section is uniquely
identified by a unicode string.
``config.ConfigObjStore`` is an implementation that use ``ConfigObj``.
Depending on the object it is associated with (or not) a ``Store`` also needs
to implement a locking mechanism. ``LockableConfigObjStore`` implements such a
mechanism for ``ConfigObj`` based stores.
Classes are provided for the usual Bazaar configuration files and could be
used as examples to define new ones if needed. The associated tests provides a
basis for new classes which only need to register themselves in the right
places to inherit from the existing basic tests and add their own specific
ones.
Filtering sections
------------------
For some contexts, only some sections from a given store will apply. Defining
which is what the ``SectionMatcher`` are about.
The main constraint here is that a ``SectionMatcher`` should delay the loading
of the associated store as long as possible. The constructor should collect
all data needed for the selection and uses it while processing the sections in
``get_sections``.
Only ``ReadOnlySection`` objects are manipulated here but a ``SectionMatcher``
can return dedicated ``Section`` to provide additional context (the
``LocationSection`` add an ``extra_path`` attribute to implement the
``appendpath`` policy for example).
.. FIXME: Replace the appendpath example if/when it's deprecated ;)
Stacks
------
An option can take different values depending on the context it is used. Such
a context can involve configuration files, options from the command line,
default values in bzrlib and then some.
Such a context is implemented by creating a list of ``Section`` stacked upon
each other. A ``Stack`` can then be asked for an option value and returns the
first definition found.
This provides a great flexibility to decide priorities between sections when
the stack is defined without to worry about them in the code itself.
A stack also defines a mutable section (which can be None) to handle
modifications.
Many sections (or even stores) are aimed at providing default values for an
option but these sections shouldn't be modified lightly as modifying an option
used for different contexts will indeed be seen by all these contexts.
Default values in configuration files are defined by users. Developers
shouldn't have to modify them, as such, no mechanism nor heuristics are used
to find which section (or sections) should be modified.
A ``Stack`` defines a mutable section when there is no ambiguity. If there
is one, then the *user* should be able to decide and in this case a new
``Stack`` can be created cheaply.
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