Writing Extensions for Python-Markdown
======================================
Overview
--------
Python-Markdown includes an API for extension writers to plug their own
custom functionality and/or syntax into the parser. There are preprocessors
which allow you to alter the source before it is passed to the parser,
inline patterns which allow you to add, remove or override the syntax of
any inline elements, and postprocessors which allow munging of the
output of the parser before it is returned. If you really want to dive in,
there are also blockprocessors which are part of the core BlockParser.
As the parser builds an [ElementTree][] object which is later rendered
as Unicode text, there are also some helpers provided to ease manipulation of
the tree. Each part of the API is discussed in its respective section below.
Additionaly, reading the source of some [[Available Extensions]] may be helpful.
For example, the [[Footnotes]] extension uses most of the features documented
here.
* [Preprocessors][]
* [InlinePatterns][]
* [Treeprocessors][]
* [Postprocessors][]
* [BlockParser][]
* [Working with the ElementTree][]
* [Integrating your code into Markdown][]
* [extendMarkdown][]
* [OrderedDict][]
* [registerExtension][]
* [Config Settings][]
* [makeExtension][]
Preprocessors
Preprocessors munge the source text before it is passed into the Markdown
core. This is an excellent place to clean up bad syntax, extract things the
parser may otherwise choke on and perhaps even store it for later retrieval.
Preprocessors should inherit from ``markdown.Preprocessor`` and implement
a ``run`` method with one argument ``lines``. The ``run`` method of each
Preprocessor will be passed the entire source text as a list of Unicode strings.
Each string will contain one line of text. The ``run`` method should return
either that list, or an altered list of Unicode strings.
A pseudo example:
class MyPreprocessor(markdown.Preprocessor):
def run(self, lines):
new_lines = []
for line in lines:
m = MYREGEX.match(line)
if m:
# do stuff
else:
new_lines.append(line)
return new_lines
Inline Patterns
Inline Patterns implement the inline HTML element syntax for Markdown such as
``*emphasis*`` or ``[links](http://example.com)``. Pattern objects should be
instances of classes that inherit from ``markdown.Pattern`` or one of its
children. Each pattern object uses a single regular expression and must have
the following methods:
* **``getCompiledRegExp()``**:
Returns a compiled regular expression.
* **``handleMatch(m)``**:
Accepts a match object and returns an ElementTree element of a plain
Unicode string.
Note that any regular expression returned by ``getCompiledRegExp`` must capture
the whole block. Therefore, they should all start with ``r'^(.*?)'`` and end
with ``r'(.*?)!'``. When using the default ``getCompiledRegExp()`` method
provided in the ``Pattern`` you can pass in a regular expression without that
and ``getCompiledRegExp`` will wrap your expression for you. This means that
the first group of your match will be ``m.group(2)`` as ``m.group(1)`` will
match everything before the pattern.
For an example, consider this simplified emphasis pattern:
class EmphasisPattern(markdown.Pattern):
def handleMatch(self, m):
el = markdown.etree.Element('em')
el.text = m.group(3)
return el
As discussed in [Integrating Your Code Into Markdown][], an instance of this
class will need to be provided to Markdown. That instance would be created
like so:
# an oversimplified regex
MYPATTERN = r'\*([^*]+)\*'
# pass in pattern and create instance
emphasis = EmphasisPattern(MYPATTERN)
Actually it would not be necessary to create that pattern (and not just because
a more sophisticated emphasis pattern already exists in Markdown). The fact is,
that example pattern is not very DRY. A pattern for `**strong**` text would
be almost identical, with the exception that it would create a 'strong' element.
Therefore, Markdown provides a number of generic pattern classes that can
provide some common functionality. For example, both emphasis and strong are
implemented with separate instances of the ``SimpleTagPettern`` listed below.
Feel free to use or extend any of these Pattern classes.
**Generic Pattern Classes**
* **``SimpleTextPattern(pattern)``**:
Returns simple text of ``group(2)`` of a ``pattern``.
* **``SimpleTagPattern(pattern, tag)``**:
Returns an element of type "`tag`" with a text attribute of ``group(3)``
of a ``pattern``. ``tag`` should be a string of a HTML element (i.e.: 'em').
* **``SubstituteTagPattern(pattern, tag)``**:
Returns an element of type "`tag`" with no children or text (i.e.: 'br').
There may be other Pattern classes in the Markdown source that you could extend
or use as well. Read through the source and see if there is anything you can
use. You might even get a few ideas for different approaches to your specific
situation.
Treeprocessors
Treeprocessors manipulate an ElemenTree object after it has passed through the
core BlockParser. This is where additional manipulation of the tree takes
place. Additionaly, the InlineProcessor is a Treeprocessor which steps through
the tree and runs the InlinePatterns on the text of each Element in the tree.
An Treeprocessor should inherit from ``markdown.Treeprocessor``,
over-ride the ``run`` method which takes one argument ``root`` (an Elementree
object) and returns either that root element or a modified root element.
A pseudo example:
class MyTreeprocessor(markdown.Treeprocessor):
def run(self, root):
#do stufff
return my_modified_root
For specifics on manipulating the ElementTree, see
[Working with the ElementTree][] below.
Postprocessors
Postprocessors manipulate the document after the ElementTree has been
serialized into a string. Postprocessors should be used to work with the
text just before output.
A Postprocessor should inherit from ``markdown.Postprocessor`` and
over-ride the ``run`` method which takes one argument ``text`` and returns a
Unicode string.
Postprocessors are run after the ElementTree has been serialized back into
Unicode text. For example, this may be an appropriate place to add a table of
contents to a document:
class TocPostprocessor(markdown.Postprocessor):
def run(self, text):
return MYMARKERRE.sub(MyToc, text)
BlockParser
Sometimes, pre/tree/postprocessors and Inline Patterns aren't going to do what
you need. Perhaps you want a new type of block type that needs to be integrated
into the core parsing. In such a situation, you can add/change/remove
functionality of the core ``BlockParser``. The BlockParser is composed of a
number of Blockproccessors. The BlockParser steps through each block of text
(split by blank lines) and passes each block to the appropriate Blockprocessor.
That Blockprocessor parses the block and adds it to the ElementTree. The
[[Definition Lists]] extension would be a good example of an extension that
adds/modifies Blockprocessors.
A Blockprocessor should inherit from ``markdown.BlockProcessor`` and implement
both the ``test`` and ``run`` methods.
The ``test`` method is used by BlockParser to identify the type of block.
Therefore the ``test`` method must return a boolean value. If the test returns
``True``, then the BlockParser will call that Blockprocessor's ``run`` method.
If it returns ``False``, the BlockParser will move on to the next
BlockProcessor.
The **``test``** method takes two arguments:
* **``parent``**: The parent etree Element of the block. This can be useful as
the block may need to be treated differently if it is inside a list, for
example.
* **``block``**: A string of the current block of text. The test may be a
simple string method (such as ``block.startswith(some_text)``) or a complex
regular expression.
The **``run``** method takes two arguments:
* **``parent``**: A pointer to the parent etree Element of the block. The run
method will most likely attach additional nodes to this parent. Note that
nothing is returned by the method. The Elementree object is altered in place.
* **``blocks``**: A list of all remaining blocks of the document. Your run
method must remove (pop) the first block from the list (which it altered in
place - not returned) and parse that block. You may find that a block of text
legitimately contains multiple block types. Therefore, after processing the
first type, you processor can insert the remaining text into the beginning
of the ``blocks`` list for future parsing.
Please be aware that a single block can span multiple text blocks. For example,
The official Markdown syntax rules state that a blank line does not end a
Code Block. If the next block of text is also indented, then it is part of
the previous block. Therefore, the BlockParser was specifically designed to
address these types of situations. If you notice the ``CodeBlockProcessor``,
in the core, you will note that it checks the last child of the ``parent``.
If the last child is a code block (``...
``), then it
appends that block to the previous code block rather than creating a new
code block.
Each BlockProcessor has the following utility methods available:
* **``lastChild(parent)``**:
Returns the last child of the given etree Element or ``None`` if it had no
children.
* **``detab(text)``**:
Removes one level of indent (four spaces by default) from the front of each
line of the given text string.
* **``looseDetab(text)``**:
Removes one level if indent from the front of each line of the given text
string. However, this methods allows secondary lines to not be indented as
does some parts of the Markdown syntax.
Each BlockProcessor also has a pointer to the containing BlockParser instance at
``self.parser``, which can be used to check or alter the state of the parser.
The BlockParser tracks it's state in a stack at ``parser.state``. The state
stack is an instance of the ``State`` class.
**``State``** is a subclass of ``list`` and has the additional methods:
* **``set(state)``**:
Set a new state to string ``state``. The new state is appended to the end
of the stack.
* **``reset()``**:
Step back one step in the stack. The last state at the end is removed from
the stack.
* **``isstate(state)``**:
Test that the top (current) level of the stack is of the given string
``state``.
Note that to ensure that the state stack doesn't become corrupted, each time a
state is set for a block, that state *must* be reset when the parser finishes
parsing that block.
An instance of the **``BlockParser``** is found at ``Markdown.parser``.
``BlockParser`` has the following methods:
* **``parseDocument(lines)``**:
Given a list of lines, an ElementTree object is returned. This should be
passed an entire document and is the only method the ``Markdown`` class
calls directly.
* **``parseChunk(parent, text)``**:
Parses a chunk of markdown text composed of multiple blocks and attaches
those blocks to the ``parent`` Element. The ``parent`` is altered in place
and nothing is returned. Extensions would most likely use this method for
block parsing.
* **``parseBlocks(parent, blocks)``**:
Parses a list of blocks of text and attaches those blocks to the ``parent``
Element. The ``parent`` is altered in place and nothing is returned. This
method will generally only be used internally to recursively parse nested
blocks of text.
While is is not recommended, an extension could subclass or completely replace
the ``BlockParser``. The new class would have to provide the same public API.
However, be aware that other extensions may expect the core parser provided
and will not work with such a drastically different parser.
Working with the ElementTree
As mentioned, the Markdown parser converts a source document to an
[ElementTree][] object before serializing that back to Unicode text.
Markdown has provided some helpers to ease that manipulation within the context
of the Markdown module.
First, to get access to the ElementTree module import ElementTree from
``markdown`` rather than importing it directly. This will ensure you are using
the same version of ElementTree as markdown. The module is named ``etree``
within Markdown.
from markdown import etree
``markdown.etree`` tries to import ElementTree from any known location, first
as a standard library module (from ``xml.etree`` in Python 2.5), then as a third
party package (``Elementree``). In each instance, ``cElementTree`` is tried
first, then ``ElementTree`` if the faster C implementation is not available on
your system.
Sometimes you may want text inserted into an element to be parsed by
[InlinePatterns][]. In such a situation, simply insert the text as you normally
would and the text will be automatically run through the InlinePatterns.
However, if you do *not* want some text to be parsed by InlinePatterns,
then insert the text as an ``AtomicString``.
some_element.text = markdown.AtomicString(some_text)
Here's a basic example which creates an HTML table (note that the contents of
the second cell (``td2``) will be run through InlinePatterns latter):
table = etree.Element("table")
table.set("cellpadding", "2") # Set cellpadding to 2
tr = etree.SubElement(table, "tr") # Add child tr to table
td1 = etree.SubElement(tr, "td") # Add child td1 to tr
td1.text = markdown.AtomicString("Cell content") # Add plain text content
td2 = etree.SubElement(tr, "td") # Add second td to tr
td2.text = "*text* with **inline** formatting." # Add markup text
table.tail = "Text after table" # Add text after table
You can also manipulate an existing tree. Consider the following example which
adds a ``class`` attribute to ```` elements:
def set_link_class(self, element):
for child in element:
if child.tag == "a":
child.set("class", "myclass") #set the class attribute
set_link_class(child) # run recursively on children
For more information about working with ElementTree see the ElementTree
[Documentation](http://effbot.org/zone/element-index.htm)
([Python Docs](http://docs.python.org/lib/module-xml.etree.ElementTree.html)).
Integrating Your Code Into Markdown
Once you have the various pieces of your extension built, you need to tell
Markdown about them and ensure that they are run in the proper sequence.
Markdown accepts a ``Extension`` instance for each extension. Therefore, you
will need to define a class that extends ``markdown.Extension`` and over-rides
the ``extendMarkdown`` method. Within this class you will manage configuration
options for your extension and attach the various processors and patterns to
the Markdown instance.
It is important to note that the order of the various processors and patterns
matters. For example, if we replace ``http://...`` links with elements, and
*then* try to deal with inline html, we will end up with a mess. Therefore,
the various types of processors and patterns are stored within an instance of
the Markdown class in [OrderedDict][]s. Your ``Extension`` class will need to
manipulate those OrderedDicts appropriately. You may insert instances of your
processors and patterns into the appropriate location in an OrderedDict, remove
a built-in instance, or replace a built-in instance with your own.
extendMarkdown
The ``extendMarkdown`` method of a ``markdown.Extension`` class accepts two
arguments:
* **``md``**:
A pointer to the instance of the Markdown class. You should use this to
access the [OrderedDict][]s of processors and patterns. They are found
under the following attributes:
* ``md.preprocessors``
* ``md.inlinePatterns``
* ``md.parser.blockprocessors``
* ``md.treepreprocessors``
* ``md.postprocessors``
Some other things you may want to access in the markdown instance are:
* ``md.htmlStash``
* ``md.output_formats``
* ``md.set_output_format()``
* ``md.registerExtension()``
* **``md_globals``**:
Contains all the various global variables within the markdown module.
Of course, with access to those items, theoretically you have the option to
changing anything through various [monkey_patching][] techniques. However, you
should be aware that the various undocumented or private parts of markdown
may change without notice and your monkey_patches may break with a new release.
Therefore, what you really should be doing is inserting processors and patterns
into the markdown pipeline. Consider yourself warned.
[monkey_patching]: http://en.wikipedia.org/wiki/Monkey_patch
A simple example:
class MyExtension(makrdown.Extension):
def extendMarkdown(self, md, md_globals):
# Insert instance of 'mypattern' before 'references' pattern
md.inlinePatterns.add('mypattern', MyPattern(md), 'OrderedDict
An OrderedDict is a dictionary like object that retains the order of it's
items. The items are ordered in the order in which they were appended to
the OrderedDict. However, an item can also be inserted into the OrderedDict
in a specific location in relation to the existing items.
Think of OrderedDict as a combination of a list and a dictionary as it has
methods common to both. For example, you can get and set items using the
``od[key] = value`` syntax and the methods ``keys()``, ``values()``, and
``items()`` work as expected with the keys, values and items returned in the
proper order. At the same time, you can use ``insert()``, ``append()``, and
``index()`` as you would with a list.
Generally speaking, within Markdown extensions you will be using the special
helper method ``add()`` to add additional items to an existing OrderedDict.
The ``add()`` method accepts three arguments:
* **``key``**: A string. The key is used for later reference to the item.
* **``value``**: The object instance stored in this item.
* **``location``**: Optional. The items location in relation to other items.
Note that the location can consist of a few different values:
* The special strings ``"_begin"`` and ``"_end"`` insert that item at the
beginning or end of the OrderedDict respectively.
* A less-than sign (``<``) followed by an existing key (i.e.:
``"``) followed by an existing key (i.e.:
``">somekey"``) inserts that item after the existing key.
Consider the following example:
>>> import markdown
>>> od = markdown.OrderedDict()
>>> od['one'] = 1 # The same as: od.add('one', 1, '_begin')
>>> od['three'] = 3 # The same as: od.add('three', 3, '>one')
>>> od['four'] = 4 # The same as: od.add('four', 4, '_end')
>>> od.items()
[("one", 1), ("three", 3), ("four", 4)]
Note that when building an OrderedDict in order, the extra features of the
``add`` method offer no real value and are not necessary. However, when
manipulating an existing OrderedDict, ``add`` can be very helpful. So let's
insert another item into the OrderedDict.
>>> od.add('two', 2, '>one') # Insert after 'one'
>>> od.values()
[1, 2, 3, 4]
Now let's insert another item.
>>> od.add('twohalf', 2.5, '>> od.keys()
["one", "two", "twohalf", "three", "four"]
Note that we also could have set the location of "twohalf" to be 'after two'
(i.e.: ``'>two'``). However, it's unlikely that you will have control over the
order in which extensions will be loaded, and this could affect the final
sorted order of an OrderedDict. For example, suppose a extension adding
'twohalf' in the above examples was loaded before a separate extension which
adds 'two'. You may need to take this into consideration when adding your
extension components to the various markdown OrderedDicts.
Once an OrderedDict is created, the items are available via key:
MyNode = od['somekey']
Therefore, to delete an existing item:
del od['somekey']
To change the value of an existing item (leaving location unchanged):
od['somekey'] = MyNewObject()
To change the location of an existing item:
t.link('somekey', 'registerExtension
Some extensions may need to have their state reset between multiple runs of the
Markdown class. For example, consider the following use of the [[Footnotes]]
extension:
md = markdown.Markdown(extensions=['footnotes'])
html1 = md.convert(text_with_footnote)
md.reset()
html2 = md.convert(text_without_footnote)
Without calling ``reset``, the footnote definitions from the first document will
be inserted into the second document as they are still stored within the class
instance. Therefore the ``Extension`` class needs to define a ``reset`` method
that will reset the state of the extension (i.e.: ``self.footnotes = {}``).
However, as many extensions do not have a need for ``reset``, ``reset`` is only
called on extensions that are registered.
To register an extension, call ``md.registerExtension`` from within your
``extendMarkdown`` method:
def extendMarkdown(self, md, md_globals):
md.registerExtension(self)
# insert processors and patterns here
Then, each time ``reset`` is called on the Markdown instance, the ``reset``
method of each registered extension will be called as well. You should also
note that ``reset`` will be called on each registered extension after it is
initialized the first time. Keep that in mind when over-riding the extension's
``reset`` method.
Config Settings
If an extension uses any parameters that the user may want to change,
those parameters should be stored in ``self.config`` of your
``markdown.Extension`` class in the following format:
self.config = {parameter_1_name : [value1, description1],
parameter_2_name : [value2, description2] }
When stored this way the config parameters can be over-ridden from the
command line or at the time Markdown is initiated:
markdown.py -x myextension(SOME_PARAM=2) inputfile.txt > output.txt
Note that parameters should always be assumed to be set to string
values, and should be converted at run time. For example:
i = int(self.getConfig("SOME_PARAM"))
makeExtension
Each extension should ideally be placed in its own module starting
with the ``mdx_`` prefix (e.g. ``mdx_footnotes.py``). The module must
provide a module-level function called ``makeExtension`` that takes
an optional parameter consisting of a dictionary of configuration over-rides
and returns an instance of the extension. An example from the footnote
extension:
def makeExtension(configs=None) :
return FootnoteExtension(configs=configs)
By following the above example, when Markdown is passed the name of your
extension as a string (i.e.: ``'footnotes'``), it will automatically import
the module and call the ``makeExtension`` function initiating your extension.
You may have noted that the extensions packaged with Python-Markdown do not
use the ``mdx_`` prefix in their module names. This is because they are all
part of the ``markdown_extensions`` package. Markdown will first try to import
from ``markdown_extensions.extname`` and upon failure, ``mdx_extname``. If both
fail, Markdown will continue without the extension.
However, Markdown will also accept an already existing instance of an extension.
For example:
import markdown
import myextension
configs = {...}
myext = myextension.MyExtension(configs=configs)
md = markdown.Markdown(extensions=[myext])
This is useful if you need to implement a large number of extensions with more
than one residing in a module.
[Preprocessors]: #preprocessors
[InlinePatterns]: #inlinepatterns
[Treeprocessors]: #treeprocessors
[Postprocessors]: #postprocessors
[BlockParser]: #blockparser
[Working with the ElementTree]: #working_with_et
[Integrating your code into Markdown]: #integrating_into_markdown
[extendMarkdown]: #extendmarkdown
[OrderedDict]: #ordereddict
[registerExtension]: #registerextension
[Config Settings]: #configsettings
[makeExtension]: #makeextension
[ElementTree]: http://effbot.org/zone/element-index.htm