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================================================
Step 2: Hello World as XML
================================================
We now have a default project named ``lxmlgraph``. It contains a
*package* (also) named ``lxmlgraph``.
In this step we will add an XML document to the *package* as our model
data. We will leverage the following ``repoze.bfg`` machinery:
- Model data with interfaces that define "types"
- ZCML configuration to provide type-specific views
Our application will need to do these things:
- Our model class needs to use lxml to inject itelf into the XML
nodes
- That model class needs to implement the "handshake"
All of the below filenames are relative to the ``lxmlgraph`` *package*
rather than the project.
File ``samplemodel.xml``
-----------------------------------
We're going to add an XML document that will serve as a source for
model data named ``samplemodel.xml``.
.. literalinclude:: step02/myapp/samplemodel.xml
:linenos:
:language: xml
#. Line 2 provides the root of the model as an XML ``<site>`` node.
The element name doesn't have to be ``<site>``.
#. In lines 3-4, the ``<site>`` contains 2 top-level children: a and
b. These are provided as an element name ``<document>``. This,
also, is meaningfless as far as ``repoze.bfg`` is concerned.
However, this is where you compose th information model you are
publishing.
The only special constraint is that a node that wants to be "found" by
``repoze.bfg`` in during traversal *must* have an ``name`` attribute.
(The use of ``@name`` corresponds to ``__name__`` in the
``repoze.bfg`` handshake.) Each hop in the URL tries to grab a child
with an attribute matching the next hop. Also, the value of the
``@name`` should be unique in its containing node.
Module ``models.py``
------------------------------
At a high level, we make write a class that "extends" lxml Element
nodes, create an lxml parser, and register the custom class with the
parser.
.. literalinclude:: step02/myapp/models.py
:linenos:
#. Line 4 imports lxml.
#. Line 9 creates the custom class we are going to use to extend
etree.ElementBase. The lxml website has great documentation on the
various ways to inject custom Python behavior into XML.
#. Just as before, line 12 says that instances of this class support a
certain content type (interface.) In our case, instances will be
XML nodes.
#. ``repoze.bfg`` has a "protocol" where model data should have an
``__name__`` attribute. Lines 14-16 implement this by grabbing the
``@name`` attribute of the current node.
#. URL traversal in ``repoze.bfg`` works via the ``__getitem__``
protocol. Thus, we need a method that implements this. Lines
18-26 use XPath to look for a direct child that has an ``@name``
matching the item name that's being traversed to. If it finds it,
return it. If not, or if more than one is found, raise an error.
#. As before, ``get_root`` is the function that is expected to return
the top of the model. In lines 30-32 we do the lxml magic to get
the custom Python class registered. We then load some XML and
return the top of the tree.
Module ``views.py``
-----------------------------
Our ``views.py`` module does the following:
.. literalinclude:: step02/myapp/views.py
:linenos:
#. Line 5 grabs the element name (tag name) of the ``context``, which
is the current XML node that we're traversing through.
#. Line 6 uses the special property we defined in our custom Python
class to get the ``__name__`` of the context.
Browsing the Model
------------------------
We can use these URLs to browse the model graph and see results::
http://localhost:5432/a
http://localhost:5432/b
http://localhost:5432/c (Not Found)
In this case, each request grabs a node in the XML and uses it as the
data for the view.
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