|
- # -*- coding: utf-8 -*-
- #
- # Copyright (C) 2012-2017 Ben Kurtovic <ben.kurtovic@gmail.com>
- #
- # Permission is hereby granted, free of charge, to any person obtaining a copy
- # of this software and associated documentation files (the "Software"), to deal
- # in the Software without restriction, including without limitation the rights
- # to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
- # copies of the Software, and to permit persons to whom the Software is
- # furnished to do so, subject to the following conditions:
- #
- # The above copyright notice and this permission notice shall be included in
- # all copies or substantial portions of the Software.
- #
- # THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
- # IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
- # FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
- # AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
- # LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
- # OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
- # SOFTWARE.
-
- from __future__ import unicode_literals
- from itertools import chain
- import re
-
- from .compat import bytes, py3k, range, str
- from .nodes import (Argument, Comment, ExternalLink, Heading, HTMLEntity,
- Node, Tag, Template, Text, Wikilink)
- from .string_mixin import StringMixIn
- from .utils import parse_anything
-
- __all__ = ["Wikicode"]
-
- FLAGS = re.IGNORECASE | re.DOTALL | re.UNICODE
-
- class Wikicode(StringMixIn):
- """A ``Wikicode`` is a container for nodes that operates like a string.
-
- Additionally, it contains methods that can be used to extract data from or
- modify the nodes, implemented in an interface similar to a list. For
- example, :meth:`index` can get the index of a node in the list, and
- :meth:`insert` can add a new node at that index. The :meth:`filter()
- <ifilter>` series of functions is very useful for extracting and iterating
- over, for example, all of the templates in the object.
- """
- RECURSE_OTHERS = 2
-
- def __init__(self, nodes):
- super(Wikicode, self).__init__()
- self._nodes = nodes
-
- def __unicode__(self):
- return "".join([str(node) for node in self.nodes])
-
- @staticmethod
- def _get_children(node, contexts=False, restrict=None, parent=None):
- """Iterate over all child :class:`.Node`\ s of a given *node*."""
- yield (parent, node) if contexts else node
- if restrict and isinstance(node, restrict):
- return
- for code in node.__children__():
- for child in code.nodes:
- sub = Wikicode._get_children(child, contexts, restrict, code)
- for result in sub:
- yield result
-
- @staticmethod
- def _slice_replace(code, index, old, new):
- """Replace the string *old* with *new* across *index* in *code*."""
- nodes = [str(node) for node in code.get(index)]
- substring = "".join(nodes).replace(old, new)
- code.nodes[index] = parse_anything(substring).nodes
-
- @staticmethod
- def _build_matcher(matches, flags):
- """Helper for :meth:`_indexed_ifilter` and others.
-
- If *matches* is a function, return it. If it's a regex, return a
- wrapper around it that can be called with a node to do a search. If
- it's ``None``, return a function that always returns ``True``.
- """
- if matches:
- if callable(matches):
- return matches
- return lambda obj: re.search(matches, str(obj), flags)
- return lambda obj: True
-
- def _indexed_ifilter(self, recursive=True, matches=None, flags=FLAGS,
- forcetype=None):
- """Iterate over nodes and their corresponding indices in the node list.
-
- The arguments are interpreted as for :meth:`ifilter`. For each tuple
- ``(i, node)`` yielded by this method, ``self.index(node) == i``. Note
- that if *recursive* is ``True``, ``self.nodes[i]`` might not be the
- node itself, but will still contain it.
- """
- match = self._build_matcher(matches, flags)
- if recursive:
- restrict = forcetype if recursive == self.RECURSE_OTHERS else None
- def getter(i, node):
- for ch in self._get_children(node, restrict=restrict):
- yield (i, ch)
- inodes = chain(*(getter(i, n) for i, n in enumerate(self.nodes)))
- else:
- inodes = enumerate(self.nodes)
- for i, node in inodes:
- if (not forcetype or isinstance(node, forcetype)) and match(node):
- yield (i, node)
-
- def _do_strong_search(self, obj, recursive=True):
- """Search for the specific element *obj* within the node list.
-
- *obj* can be either a :class:`.Node` or a :class:`.Wikicode` object. If
- found, we return a tuple (*context*, *index*) where *context* is the
- :class:`.Wikicode` that contains *obj* and *index* is its index there,
- as a :class:`slice`. Note that if *recursive* is ``False``, *context*
- will always be ``self`` (since we only look for *obj* among immediate
- descendants), but if *recursive* is ``True``, then it could be any
- :class:`.Wikicode` contained by a node within ``self``. If *obj* is not
- found, :exc:`ValueError` is raised.
- """
- if isinstance(obj, Node):
- mkslice = lambda i: slice(i, i + 1)
- if not recursive:
- return self, mkslice(self.index(obj))
- for i, node in enumerate(self.nodes):
- for context, child in self._get_children(node, contexts=True):
- if obj is child:
- if not context:
- context = self
- return context, mkslice(context.index(child))
- raise ValueError(obj)
-
- context, ind = self._do_strong_search(obj.get(0), recursive)
- for i in range(1, len(obj.nodes)):
- if obj.get(i) is not context.get(ind.start + i):
- raise ValueError(obj)
- return context, slice(ind.start, ind.start + len(obj.nodes))
-
- def _do_weak_search(self, obj, recursive):
- """Search for an element that looks like *obj* within the node list.
-
- This follows the same rules as :meth:`_do_strong_search` with some
- differences. *obj* is treated as a string that might represent any
- :class:`.Node`, :class:`.Wikicode`, or combination of the two present
- in the node list. Thus, matching is weak (using string comparisons)
- rather than strong (using ``is``). Because multiple nodes can match
- *obj*, the result is a list of tuples instead of just one (however,
- :exc:`ValueError` is still raised if nothing is found). Individual
- matches will never overlap.
-
- The tuples contain a new first element, *exact*, which is ``True`` if
- we were able to match *obj* exactly to one or more adjacent nodes, or
- ``False`` if we found *obj* inside a node or incompletely spanning
- multiple nodes.
- """
- obj = parse_anything(obj)
- if not obj or obj not in self:
- raise ValueError(obj)
- results = []
- contexts = [self]
- while contexts:
- context = contexts.pop()
- i = len(context.nodes) - 1
- while i >= 0:
- node = context.get(i)
- if obj.get(-1) == node:
- for j in range(-len(obj.nodes), -1):
- if obj.get(j) != context.get(i + j + 1):
- break
- else:
- i -= len(obj.nodes) - 1
- index = slice(i, i + len(obj.nodes))
- results.append((True, context, index))
- elif recursive and obj in node:
- contexts.extend(node.__children__())
- i -= 1
- if not results:
- if not recursive:
- raise ValueError(obj)
- results.append((False, self, slice(0, len(self.nodes))))
- return results
-
- def _get_tree(self, code, lines, marker, indent):
- """Build a tree to illustrate the way the Wikicode object was parsed.
-
- The method that builds the actual tree is ``__showtree__`` of ``Node``
- objects. *code* is the ``Wikicode`` object to build a tree for. *lines*
- is the list to append the tree to, which is returned at the end of the
- method. *marker* is some object to be used to indicate that the builder
- should continue on from the last line instead of starting a new one; it
- should be any object that can be tested for with ``is``. *indent* is
- the starting indentation.
- """
- def write(*args):
- """Write a new line following the proper indentation rules."""
- if lines and lines[-1] is marker: # Continue from the last line
- lines.pop() # Remove the marker
- last = lines.pop()
- lines.append(last + " ".join(args))
- else:
- lines.append(" " * 6 * indent + " ".join(args))
-
- get = lambda code: self._get_tree(code, lines, marker, indent + 1)
- mark = lambda: lines.append(marker)
- for node in code.nodes:
- node.__showtree__(write, get, mark)
- return lines
-
- @classmethod
- def _build_filter_methods(cls, **meths):
- """Given Node types, build the corresponding i?filter shortcuts.
-
- The should be given as keys storing the method's base name paired with
- values storing the corresponding :class:`.Node` type. For example, the
- dict may contain the pair ``("templates", Template)``, which will
- produce the methods :meth:`ifilter_templates` and
- :meth:`filter_templates`, which are shortcuts for
- :meth:`ifilter(forcetype=Template) <ifilter>` and
- :meth:`filter(forcetype=Template) <filter>`, respectively. These
- shortcuts are added to the class itself, with an appropriate docstring.
- """
- doc = """Iterate over {0}.
-
- This is equivalent to :meth:`{1}` with *forcetype* set to
- :class:`~{2.__module__}.{2.__name__}`.
- """
- make_ifilter = lambda ftype: (lambda self, *a, **kw:
- self.ifilter(forcetype=ftype, *a, **kw))
- make_filter = lambda ftype: (lambda self, *a, **kw:
- self.filter(forcetype=ftype, *a, **kw))
- for name, ftype in (meths.items() if py3k else meths.iteritems()):
- ifilter = make_ifilter(ftype)
- filter = make_filter(ftype)
- ifilter.__doc__ = doc.format(name, "ifilter", ftype)
- filter.__doc__ = doc.format(name, "filter", ftype)
- setattr(cls, "ifilter_" + name, ifilter)
- setattr(cls, "filter_" + name, filter)
-
- @property
- def nodes(self):
- """A list of :class:`.Node` objects.
-
- This is the internal data actually stored within a :class:`.Wikicode`
- object.
- """
- return self._nodes
-
- @nodes.setter
- def nodes(self, value):
- if not isinstance(value, list):
- value = parse_anything(value).nodes
- self._nodes = value
-
- def get(self, index):
- """Return the *index*\ th node within the list of nodes."""
- return self.nodes[index]
-
- def set(self, index, value):
- """Set the ``Node`` at *index* to *value*.
-
- Raises :exc:`IndexError` if *index* is out of range, or
- :exc:`ValueError` if *value* cannot be coerced into one :class:`.Node`.
- To insert multiple nodes at an index, use :meth:`get` with either
- :meth:`remove` and :meth:`insert` or :meth:`replace`.
- """
- nodes = parse_anything(value).nodes
- if len(nodes) > 1:
- raise ValueError("Cannot coerce multiple nodes into one index")
- if index >= len(self.nodes) or -1 * index > len(self.nodes):
- raise IndexError("List assignment index out of range")
- if nodes:
- self.nodes[index] = nodes[0]
- else:
- self.nodes.pop(index)
-
- def contains(self, obj):
- """Return whether this Wikicode object contains *obj*.
-
- If *obj* is a :class:`.Node` or :class:`.Wikicode` object, then we
- search for it exactly among all of our children, recursively.
- Otherwise, this method just uses :meth:`.__contains__` on the string.
- """
- if not isinstance(obj, (Node, Wikicode)):
- return obj in self
- try:
- self._do_strong_search(obj, recursive=True)
- except ValueError:
- return False
- return True
-
- def index(self, obj, recursive=False):
- """Return the index of *obj* in the list of nodes.
-
- Raises :exc:`ValueError` if *obj* is not found. If *recursive* is
- ``True``, we will look in all nodes of ours and their descendants, and
- return the index of our direct descendant node within *our* list of
- nodes. Otherwise, the lookup is done only on direct descendants.
- """
- strict = isinstance(obj, Node)
- equivalent = (lambda o, n: o is n) if strict else (lambda o, n: o == n)
- for i, node in enumerate(self.nodes):
- if recursive:
- for child in self._get_children(node):
- if equivalent(obj, child):
- return i
- elif equivalent(obj, node):
- return i
- raise ValueError(obj)
-
- def get_ancestors(self, obj):
- """Return a list of all ancestor nodes of the :class:`.Node` *obj*.
-
- The list is ordered from the most shallow ancestor (greatest great-
- grandparent) to the direct parent. The node itself is not included in
- the list. For example::
-
- >>> text = "{{a|{{b|{{c|{{d}}}}}}}}"
- >>> code = mwparserfromhell.parse(text)
- >>> node = code.filter_templates(matches=lambda n: n == "{{d}}")[0]
- >>> code.get_ancestors(node)
- ['{{a|{{b|{{c|{{d}}}}}}}}', '{{b|{{c|{{d}}}}}}', '{{c|{{d}}}}']
-
- Will return an empty list if *obj* is at the top level of this Wikicode
- object. Will raise :exc:`ValueError` if it wasn't found.
- """
- def _get_ancestors(code, needle):
- for node in code.nodes:
- if node is needle:
- return []
- for code in node.__children__():
- ancestors = _get_ancestors(code, needle)
- if ancestors is not None:
- return [node] + ancestors
-
- if isinstance(obj, Wikicode):
- obj = obj.get(0)
- elif not isinstance(obj, Node):
- raise ValueError(obj)
-
- ancestors = _get_ancestors(self, obj)
- if ancestors is None:
- raise ValueError(obj)
- return ancestors
-
- def get_parent(self, obj):
- """Return the direct parent node of the :class:`.Node` *obj*.
-
- This function is equivalent to calling :meth:`.get_ancestors` and
- taking the last element of the resulting list. Will return None if
- the node exists but does not have a parent; i.e., it is at the top
- level of the Wikicode object.
- """
- ancestors = self.get_ancestors(obj)
- return ancestors[-1] if ancestors else None
-
- def insert(self, index, value):
- """Insert *value* at *index* in the list of nodes.
-
- *value* can be anything parsable by :func:`.parse_anything`, which
- includes strings or other :class:`.Wikicode` or :class:`.Node` objects.
- """
- nodes = parse_anything(value).nodes
- for node in reversed(nodes):
- self.nodes.insert(index, node)
-
- def insert_before(self, obj, value, recursive=True):
- """Insert *value* immediately before *obj*.
-
- *obj* can be either a string, a :class:`.Node`, or another
- :class:`.Wikicode` object (as created by :meth:`get_sections`, for
- example). If *obj* is a string, we will operate on all instances of
- that string within the code, otherwise only on the specific instance
- given. *value* can be anything parsable by :func:`.parse_anything`. If
- *recursive* is ``True``, we will try to find *obj* within our child
- nodes even if it is not a direct descendant of this :class:`.Wikicode`
- object. If *obj* is not found, :exc:`ValueError` is raised.
- """
- if isinstance(obj, (Node, Wikicode)):
- context, index = self._do_strong_search(obj, recursive)
- context.insert(index.start, value)
- else:
- for exact, context, index in self._do_weak_search(obj, recursive):
- if exact:
- context.insert(index.start, value)
- else:
- obj = str(obj)
- self._slice_replace(context, index, obj, str(value) + obj)
-
- def insert_after(self, obj, value, recursive=True):
- """Insert *value* immediately after *obj*.
-
- *obj* can be either a string, a :class:`.Node`, or another
- :class:`.Wikicode` object (as created by :meth:`get_sections`, for
- example). If *obj* is a string, we will operate on all instances of
- that string within the code, otherwise only on the specific instance
- given. *value* can be anything parsable by :func:`.parse_anything`. If
- *recursive* is ``True``, we will try to find *obj* within our child
- nodes even if it is not a direct descendant of this :class:`.Wikicode`
- object. If *obj* is not found, :exc:`ValueError` is raised.
- """
- if isinstance(obj, (Node, Wikicode)):
- context, index = self._do_strong_search(obj, recursive)
- context.insert(index.stop, value)
- else:
- for exact, context, index in self._do_weak_search(obj, recursive):
- if exact:
- context.insert(index.stop, value)
- else:
- obj = str(obj)
- self._slice_replace(context, index, obj, obj + str(value))
-
- def replace(self, obj, value, recursive=True):
- """Replace *obj* with *value*.
-
- *obj* can be either a string, a :class:`.Node`, or another
- :class:`.Wikicode` object (as created by :meth:`get_sections`, for
- example). If *obj* is a string, we will operate on all instances of
- that string within the code, otherwise only on the specific instance
- given. *value* can be anything parsable by :func:`.parse_anything`.
- If *recursive* is ``True``, we will try to find *obj* within our child
- nodes even if it is not a direct descendant of this :class:`.Wikicode`
- object. If *obj* is not found, :exc:`ValueError` is raised.
- """
- if isinstance(obj, (Node, Wikicode)):
- context, index = self._do_strong_search(obj, recursive)
- for i in range(index.start, index.stop):
- context.nodes.pop(index.start)
- context.insert(index.start, value)
- else:
- for exact, context, index in self._do_weak_search(obj, recursive):
- if exact:
- for i in range(index.start, index.stop):
- context.nodes.pop(index.start)
- context.insert(index.start, value)
- else:
- self._slice_replace(context, index, str(obj), str(value))
-
- def append(self, value):
- """Insert *value* at the end of the list of nodes.
-
- *value* can be anything parsable by :func:`.parse_anything`.
- """
- nodes = parse_anything(value).nodes
- for node in nodes:
- self.nodes.append(node)
-
- def remove(self, obj, recursive=True):
- """Remove *obj* from the list of nodes.
-
- *obj* can be either a string, a :class:`.Node`, or another
- :class:`.Wikicode` object (as created by :meth:`get_sections`, for
- example). If *obj* is a string, we will operate on all instances of
- that string within the code, otherwise only on the specific instance
- given. If *recursive* is ``True``, we will try to find *obj* within our
- child nodes even if it is not a direct descendant of this
- :class:`.Wikicode` object. If *obj* is not found, :exc:`ValueError` is
- raised.
- """
- if isinstance(obj, (Node, Wikicode)):
- context, index = self._do_strong_search(obj, recursive)
- for i in range(index.start, index.stop):
- context.nodes.pop(index.start)
- else:
- for exact, context, index in self._do_weak_search(obj, recursive):
- if exact:
- for i in range(index.start, index.stop):
- context.nodes.pop(index.start)
- else:
- self._slice_replace(context, index, str(obj), "")
-
- def matches(self, other):
- """Do a loose equivalency test suitable for comparing page names.
-
- *other* can be any string-like object, including :class:`.Wikicode`, or
- an iterable of these. This operation is symmetric; both sides are
- adjusted. Specifically, whitespace and markup is stripped and the first
- letter's case is normalized. Typical usage is
- ``if template.name.matches("stub"): ...``.
- """
- cmp = lambda a, b: (a[0].upper() + a[1:] == b[0].upper() + b[1:]
- if a and b else a == b)
- this = self.strip_code().strip()
- if isinstance(other, (str, bytes, Wikicode, Node)):
- that = parse_anything(other).strip_code().strip()
- return cmp(this, that)
-
- for obj in other:
- that = parse_anything(obj).strip_code().strip()
- if cmp(this, that):
- return True
- return False
-
- def ifilter(self, recursive=True, matches=None, flags=FLAGS,
- forcetype=None):
- """Iterate over nodes in our list matching certain conditions.
-
- If *forcetype* is given, only nodes that are instances of this type (or
- tuple of types) are yielded. Setting *recursive* to ``True`` will
- iterate over all children and their descendants. ``RECURSE_OTHERS``
- will only iterate over children that are not the instances of
- *forcetype*. ``False`` will only iterate over immediate children.
-
- ``RECURSE_OTHERS`` can be used to iterate over all un-nested templates,
- even if they are inside of HTML tags, like so:
-
- >>> code = mwparserfromhell.parse("{{foo}}<b>{{foo|{{bar}}}}</b>")
- >>> code.filter_templates(code.RECURSE_OTHERS)
- ["{{foo}}", "{{foo|{{bar}}}}"]
-
- *matches* can be used to further restrict the nodes, either as a
- function (taking a single :class:`.Node` and returning a boolean) or a
- regular expression (matched against the node's string representation
- with :func:`re.search`). If *matches* is a regex, the flags passed to
- :func:`re.search` are :const:`re.IGNORECASE`, :const:`re.DOTALL`, and
- :const:`re.UNICODE`, but custom flags can be specified by passing
- *flags*.
- """
- gen = self._indexed_ifilter(recursive, matches, flags, forcetype)
- return (node for i, node in gen)
-
- def filter(self, *args, **kwargs):
- """Return a list of nodes within our list matching certain conditions.
-
- This is equivalent to calling :func:`list` on :meth:`ifilter`.
- """
- return list(self.ifilter(*args, **kwargs))
-
- def get_sections(self, levels=None, matches=None, flags=FLAGS, flat=False,
- include_lead=None, include_headings=True):
- """Return a list of sections within the page.
-
- Sections are returned as :class:`.Wikicode` objects with a shared node
- list (implemented using :class:`.SmartList`) so that changes to
- sections are reflected in the parent Wikicode object.
-
- Each section contains all of its subsections, unless *flat* is
- ``True``. If *levels* is given, it should be a iterable of integers;
- only sections whose heading levels are within it will be returned. If
- *matches* is given, it should be either a function or a regex; only
- sections whose headings match it (without the surrounding equal signs)
- will be included. *flags* can be used to override the default regex
- flags (see :meth:`ifilter`) if a regex *matches* is used.
-
- If *include_lead* is ``True``, the first, lead section (without a
- heading) will be included in the list; ``False`` will not include it;
- the default will include it only if no specific *levels* were given. If
- *include_headings* is ``True``, the section's beginning
- :class:`.Heading` object will be included; otherwise, this is skipped.
- """
- title_matcher = self._build_matcher(matches, flags)
- matcher = lambda heading: (title_matcher(heading.title) and
- (not levels or heading.level in levels))
- iheadings = self._indexed_ifilter(recursive=False, forcetype=Heading)
- sections = [] # Tuples of (index_of_first_node, section)
- open_headings = [] # Tuples of (index, heading), where index and
- # heading.level are both monotonically increasing
-
- # Add the lead section if appropriate:
- if include_lead or not (include_lead is not None or matches or levels):
- itr = self._indexed_ifilter(recursive=False, forcetype=Heading)
- try:
- first = next(itr)[0]
- sections.append((0, Wikicode(self.nodes[:first])))
- except StopIteration: # No headings in page
- sections.append((0, Wikicode(self.nodes[:])))
-
- # Iterate over headings, adding sections to the list as they end:
- for i, heading in iheadings:
- if flat: # With flat, all sections close at the next heading
- newly_closed, open_headings = open_headings, []
- else: # Otherwise, figure out which sections have closed, if any
- closed_start_index = len(open_headings)
- for j, (start, last_heading) in enumerate(open_headings):
- if heading.level <= last_heading.level:
- closed_start_index = j
- break
- newly_closed = open_headings[closed_start_index:]
- del open_headings[closed_start_index:]
- for start, closed_heading in newly_closed:
- if matcher(closed_heading):
- sections.append((start, Wikicode(self.nodes[start:i])))
- start = i if include_headings else (i + 1)
- open_headings.append((start, heading))
-
- # Add any remaining open headings to the list of sections:
- for start, heading in open_headings:
- if matcher(heading):
- sections.append((start, Wikicode(self.nodes[start:])))
-
- # Ensure that earlier sections are earlier in the returned list:
- return [section for i, section in sorted(sections)]
-
- def strip_code(self, normalize=True, collapse=True,
- keep_template_params=False):
- """Return a rendered string without unprintable code such as templates.
-
- The way a node is stripped is handled by the
- :meth:`~.Node.__strip__` method of :class:`.Node` objects, which
- generally return a subset of their nodes or ``None``. For example,
- templates and tags are removed completely, links are stripped to just
- their display part, headings are stripped to just their title.
-
- If *normalize* is ``True``, various things may be done to strip code
- further, such as converting HTML entities like ``Σ``, ``Σ``,
- and ``Σ`` to ``Σ``. If *collapse* is ``True``, we will try to
- remove excess whitespace as well (three or more newlines are converted
- to two, for example). If *keep_template_params* is ``True``, then
- template parameters will be preserved in the output (normally, they are
- removed completely).
- """
- kwargs = {
- "normalize": normalize,
- "collapse": collapse,
- "keep_template_params": keep_template_params
- }
-
- nodes = []
- for node in self.nodes:
- stripped = node.__strip__(**kwargs)
- if stripped:
- nodes.append(str(stripped))
-
- if collapse:
- stripped = "".join(nodes).strip("\n")
- while "\n\n\n" in stripped:
- stripped = stripped.replace("\n\n\n", "\n\n")
- return stripped
- else:
- return "".join(nodes)
-
- def get_tree(self):
- """Return a hierarchical tree representation of the object.
-
- The representation is a string makes the most sense printed. It is
- built by calling :meth:`_get_tree` on the :class:`.Wikicode` object and
- its children recursively. The end result may look something like the
- following::
-
- >>> text = "Lorem ipsum {{foo|bar|{{baz}}|spam=eggs}}"
- >>> print(mwparserfromhell.parse(text).get_tree())
- Lorem ipsum
- {{
- foo
- | 1
- = bar
- | 2
- = {{
- baz
- }}
- | spam
- = eggs
- }}
- """
- marker = object() # Random object we can find with certainty in a list
- return "\n".join(self._get_tree(self, [], marker, 0))
-
- Wikicode._build_filter_methods(
- arguments=Argument, comments=Comment, external_links=ExternalLink,
- headings=Heading, html_entities=HTMLEntity, tags=Tag, templates=Template,
- text=Text, wikilinks=Wikilink)
|