# -*- coding: utf-8 -*-
# vim: tabstop=4 shiftwidth=4 softtabstop=4
#
# Copyright (C) 2014-2020 GEM Foundation
#
# OpenQuake is free software: you can redistribute it and/or modify it
# under the terms of the GNU Affero General Public License as published
# by the Free Software Foundation, either version 3 of the License, or
# (at your option) any later version.
#
# OpenQuake is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
# GNU Affero General Public License for more details.
#
# You should have received a copy of the GNU Affero General Public License
# along with OpenQuake. If not, see <http://www.gnu.org/licenses/>.
"""
This module defines a Node class, together with a few conversion
functions which are able to convert NRML files into hierarchical
objects (DOM). That makes it easier to read and write XML from Python
and viceversa. Such features are used in the command-line conversion
tools. The Node class is kept intentionally similar to an
Element class, however it overcomes the limitation of ElementTree: in
particular a node can manage a lazy iterable of subnodes, whereas
ElementTree wants to keep everything in memory. Moreover the Node
class provides a convenient dot notation to access subnodes.
The Node class is instantiated with four arguments:
1. the node tag (a mandatory string)
2. the node attributes (a dictionary)
3. the node value (a string or None)
4. the subnodes (an iterable over nodes)
If a node has subnodes, its value should be None.
For instance, here is an example of instantiating a root node
with two subnodes a and b:
>>> from openquake.baselib.node import Node
>>> a = Node('a', {}, 'A1')
>>> b = Node('b', {'attrb': 'B'}, 'B1')
>>> root = Node('root', nodes=[a, b])
>>> root
<root {} None ...>
Node objects can be converted into nicely indented strings:
>>> print(root.to_str())
root
a 'A1'
b{attrb='B'} 'B1'
<BLANKLINE>
The subnodes can be retrieved with the dot notation:
>>> root.a
<a {} A1 >
The value of a node can be extracted with the `~` operator:
>>> ~root.a
'A1'
If there are multiple subnodes with the same name
>>> root.append(Node('a', {}, 'A2')) # add another 'a' node
the dot notation will retrieve the first node.
It is possible to retrieve the other nodes from the ordinal
index:
>>> root[0], root[1], root[2]
(<a {} A1 >, <b {'attrb': 'B'} B1 >, <a {} A2 >)
The list of all subnodes with a given name can be retrieved
as follows:
>>> list(root.getnodes('a'))
[<a {} A1 >, <a {} A2 >]
It is also possible to delete a node given its index:
>>> del root[2]
A node is an iterable object yielding its subnodes:
>>> list(root)
[<a {} A1 >, <b {'attrb': 'B'} B1 >]
The attributes of a node can be retrieved with the square bracket notation:
>>> root.b['attrb']
'B'
It is possible to add and remove attributes freely:
>>> root.b['attr'] = 'new attr'
>>> del root.b['attr']
Node objects can be easily converted into ElementTree objects:
>>> node_to_elem(root) #doctest: +ELLIPSIS
<Element 'root' at ...>
Then is trivial to generate the XML representation of a node:
>>> from xml.etree import ElementTree
>>> print(ElementTree.tostring(node_to_elem(root)).decode('utf-8'))
<root><a>A1</a><b attrb="B">B1</b></root>
Generating XML files larger than the available memory requires some
care. The trick is to use a node generator, such that it is not
necessary to keep the entire tree in memory. Here is an example:
>>> def gen_many_nodes(N):
... for i in xrange(N):
... yield Node('a', {}, 'Text for node %d' % i)
>>> lazytree = Node('lazytree', {}, nodes=gen_many_nodes(10))
The lazytree object defined here consumes no memory, because the
nodes are not created a instantiation time. They are created as
soon as you start iterating on the lazytree. In particular
list(lazytree) will generated all of them. If your goal is to
store the tree on the filesystem in XML format you should use
a writing routine converting a subnode at the time, without
requiring the full list of them. The routines provided by
ElementTree are no good, however commonlib.writers
provide an StreamingXMLWriter just for that purpose.
Lazy trees should *not* be used unless it is absolutely necessary in
order to save memory; the problem is that if you use a lazy tree the
slice notation will not work (the underlying generator will not accept
it); moreover it will not be possible to iterate twice on the
subnodes, since the generator will be exhausted. Notice that even
accessing a subnode with the dot notation will avance the
generator. Finally, nodes containing lazy nodes will not be pickleable.
"""
import io
import sys
import copy
import types
import warnings
import itertools
import pprint as pp
import configparser
from contextlib import contextmanager
from openquake.baselib.python3compat import raise_, decode, encode
from xml.etree import ElementTree
from xml.sax.saxutils import escape, quoteattr
from xml.parsers.expat import ParserCreate, ExpatError, ErrorString
import numpy
zeroset = set(['E', '-', '+', '.', '0'])
[docs]def tostring(node, indent=4, nsmap=None):
"""
Convert a node into an XML string by using the StreamingXMLWriter.
This is useful for testing purposes.
:param node: a node object (typically an ElementTree object)
:param indent: the indentation to use in the XML (default 4 spaces)
"""
out = io.BytesIO()
writer = StreamingXMLWriter(out, indent, nsmap=nsmap)
writer.serialize(node)
return out.getvalue()
[docs]class StreamingXMLWriter(object):
"""
A bynary stream XML writer. The typical usage is something like this::
with StreamingXMLWriter(output_file) as writer:
writer.start_tag('root')
for node in nodegenerator():
writer.serialize(node)
writer.end_tag('root')
"""
def __init__(self, bytestream, indent=4, encoding='utf-8', nsmap=None):
"""
:param bytestream: the stream or file where to write the XML
:param int indent: the indentation to use in the XML (default 4 spaces)
"""
# guard against a common error, one must use io.BytesIO
if isinstance(bytestream, (io.StringIO, io.TextIOWrapper)):
raise TypeError('%r is not a byte stream' % bytestream)
self.stream = bytestream
self.indent = indent
self.encoding = encoding
self.indentlevel = 0
self.nsmap = nsmap
[docs] def shorten(self, tag):
"""
Get the short representation of a fully qualified tag
:param str tag: a (fully qualified or not) XML tag
"""
if tag.startswith('{'):
ns, _tag = tag.rsplit('}')
tag = self.nsmap.get(ns[1:], '') + _tag
return tag
def _write(self, text):
"""Write text by respecting the current indentlevel"""
spaces = ' ' * (self.indent * self.indentlevel)
t = spaces + text.strip() + '\n'
if hasattr(t, 'encode'):
t = t.encode(self.encoding, 'xmlcharrefreplace')
self.stream.write(t) # expected bytes
[docs] def emptyElement(self, name, attrs):
"""Add an empty element (may have attributes)"""
attr = ' '.join('%s=%s' % (n, quoteattr(scientificformat(v)))
for n, v in sorted(attrs.items()))
self._write('<%s %s/>' % (name, attr))
[docs] def start_tag(self, name, attrs=None):
"""Open an XML tag"""
if not attrs:
self._write('<%s>' % name)
else:
self._write('<' + name)
for (name, value) in sorted(attrs.items()):
self._write(
' %s=%s' % (name, quoteattr(scientificformat(value))))
self._write('>')
self.indentlevel += 1
[docs] def end_tag(self, name):
"""Close an XML tag"""
self.indentlevel -= 1
self._write('</%s>' % name)
[docs] def serialize(self, node):
"""Serialize a node object (typically an ElementTree object)"""
if isinstance(node.tag, types.FunctionType):
# this looks like a bug of ElementTree: comments are stored as
# functions!?? see https://hg.python.org/sandbox/python2.7/file/tip/Lib/xml/etree/ElementTree.py#l458
return
if self.nsmap is not None:
tag = self.shorten(node.tag)
else:
tag = node.tag
with warnings.catch_warnings(): # unwanted ElementTree warning
warnings.simplefilter('ignore')
leafnode = not node
# NB: we cannot use len(node) to identify leafs since nodes containing
# an iterator have no length. They are always True, even if empty :-(
if leafnode and node.text is None:
self.emptyElement(tag, node.attrib)
return
self.start_tag(tag, node.attrib)
if node.text is not None:
txt = escape(scientificformat(node.text).strip())
if txt:
self._write(txt)
for subnode in node:
self.serialize(subnode)
self.end_tag(tag)
def __enter__(self):
"""Write the XML declaration"""
self._write('<?xml version="1.0" encoding="%s"?>\n' %
self.encoding)
return self
def __exit__(self, etype, exc, tb):
"""Close the XML document"""
pass
[docs]class SourceLineParser(ElementTree.XMLParser):
"""
A custom parser managing line numbers: works for Python <= 3.3
"""
def _start_list(self, tag, attrib_in):
elem = super()._start_list(tag, attrib_in)
elem.lineno = self.parser.CurrentLineNumber
# there is also CurrentColumnNumber available, if wanted
return elem
[docs]def fromstring(text):
"""Parse an XML string and return a tree"""
return ElementTree.fromstring(text, SourceLineParser())
[docs]def parse(source, remove_comments=True, **kw):
"""Thin wrapper around ElementTree.parse"""
return ElementTree.parse(source, SourceLineParser(), **kw)
[docs]def iterparse(source, events=('end',), remove_comments=True, **kw):
"""Thin wrapper around ElementTree.iterparse"""
return ElementTree.iterparse(source, events, SourceLineParser(), **kw)
# ###################### utilities for the Node class ####################### #
def _displayattrs(attrib, expandattrs):
"""
Helper function to display the attributes of a Node object in lexicographic
order.
:param attrib: dictionary with the attributes
:param expandattrs: if True also displays the value of the attributes
"""
if not attrib:
return ''
if expandattrs:
alist = ['%s=%r' % item for item in sorted(attrib.items())]
else:
alist = list(attrib)
return '{%s}' % ', '.join(alist)
def _display(node, indent, expandattrs, expandvals, output):
"""Core function to display a Node object"""
attrs = _displayattrs(node.attrib, expandattrs)
if node.text is None or not expandvals:
val = ''
elif isinstance(node.text, str):
val = ' %s' % repr(node.text.strip())
else:
val = ' %s' % repr(node.text) # node.text can be a tuple
output.write(encode(indent + striptag(node.tag) + attrs + val + '\n'))
for sub_node in node:
_display(sub_node, indent + ' ', expandattrs, expandvals, output)
[docs]def node_display(root, expandattrs=False, expandvals=False, output=sys.stdout):
"""
Write an indented representation of the Node object on the output;
this is intended for testing/debugging purposes.
:param root: a Node object
:param bool expandattrs: if True, the values of the attributes are
also printed, not only the names
:param bool expandvals: if True, the values of the tags are also printed,
not only the names.
:param output: stream where to write the string representation of the node
"""
_display(root, '', expandattrs, expandvals, output)
[docs]def striptag(tag):
"""
Get the short representation of a fully qualified tag
:param str tag: a (fully qualified or not) XML tag
"""
if tag.startswith('{'):
return tag.rsplit('}')[1]
return tag
[docs]class Node(object):
"""
A class to make it easy to edit hierarchical structures with attributes,
such as XML files. Node objects must be pickleable and must consume as
little memory as possible. Moreover they must be easily converted from
and to ElementTree objects. The advantage over ElementTree objects
is that subnodes can be lazily generated and that they can be accessed
with the dot notation.
"""
__slots__ = ('tag', 'attrib', 'text', 'nodes', 'lineno')
def __init__(self, fulltag, attrib=None, text=None,
nodes=None, lineno=None):
"""
:param str tag: the Node name
:param dict attrib: the Node attributes
:param str text: the Node text (default None)
:param nodes: an iterable of subnodes (default empty list)
"""
self.tag = fulltag
self.attrib = {} if attrib is None else attrib
self.text = text
self.nodes = [] if nodes is None else nodes
self.lineno = lineno
if self.nodes and self.text is not None:
raise ValueError(
'A branch node cannot have a value, got %r' % self.text)
def __getattr__(self, name):
if name.startswith('_'):
# do the magic only for public names
raise AttributeError(name)
for node in self.nodes:
if striptag(node.tag) == name:
return node
raise AttributeError("No subnode named '%s' found in '%s'" %
(name, striptag(self.tag)))
[docs] def getnodes(self, name):
"Return the direct subnodes with name 'name'"
for node in self.nodes:
if striptag(node.tag) == name:
yield node
[docs] def append(self, node):
"Append a new subnode"
if not isinstance(node, self.__class__):
raise TypeError('Expected Node instance, got %r' % node)
self.nodes.append(node)
[docs] def to_str(self, expandattrs=True, expandvals=True):
"""
Convert the node into a string, intended for testing/debugging purposes
:param expandattrs:
print the values of the attributes if True, else print only the names
:param expandvals:
print the values if True, else print only the tag names
"""
out = io.BytesIO()
node_display(self, expandattrs, expandvals, out)
return decode(out.getvalue())
def __iter__(self):
"""Iterate over subnodes"""
return iter(self.nodes)
def __repr__(self):
"""A condensed representation for debugging purposes"""
return '<%s %s %s %s>' % (striptag(self.tag), self.attrib, self.text,
'' if not self.nodes else '...')
def __getitem__(self, i):
"""
Retrieve a subnode, if i is an integer, or an attribute, if i
is a string.
"""
if isinstance(i, str):
return self.attrib[i]
else: # assume an integer or a slice
return self.nodes[i]
[docs] def get(self, attr, value=None):
"""
Get the given `attr`; if missing, returns `value` or `None`.
"""
return self.attrib.get(attr, value)
def __setitem__(self, i, value):
"""
Update a subnode, if i is an integer, or an attribute, if i
is a string.
"""
if isinstance(i, str):
self.attrib[i] = value
else: # assume an integer or a slice
self.nodes[i] = value
def __delitem__(self, i):
"""
Remove a subnode, if i is an integer, or an attribute, if i
is a string.
"""
if isinstance(i, str):
del self.attrib[i]
else: # assume an integer or a slice
del self.nodes[i]
def __invert__(self):
"""
Return the value of a leaf; raise a TypeError if the node is not a leaf
"""
if self:
raise TypeError('%s is a composite node, not a leaf' % self)
return self.text
def __len__(self):
"""Return the number of subnodes"""
return len(self.nodes)
def __bool__(self):
"""
Return True if there are subnodes; it does not iter on the
subnodes, so for lazy nodes it returns True even if the
generator is empty.
"""
return bool(self.nodes)
def __deepcopy__(self, memo):
new = object.__new__(self.__class__)
new.tag = self.tag
new.attrib = self.attrib.copy()
new.text = copy.copy(self.text)
new.nodes = [copy.deepcopy(n, memo) for n in self.nodes]
new.lineno = self.lineno
return new
def __getstate__(self):
return dict((slot, getattr(self, slot))
for slot in self.__class__.__slots__)
def __setstate__(self, state):
for slot in self.__class__.__slots__:
setattr(self, slot, state[slot])
def __eq__(self, other):
assert other is not None
return all(getattr(self, slot) == getattr(other, slot)
for slot in self.__class__.__slots__)
def __ne__(self, other):
return not self.__eq__(other)
[docs]def to_literal(self):
"""
Convert the node into a literal Python object
"""
if not self.nodes:
return (self.tag, self.attrib, self.text, [])
else:
return (self.tag, self.attrib, self.text,
list(map(to_literal, self.nodes)))
[docs]def pprint(self, stream=None, indent=1, width=80, depth=None):
"""
Pretty print the underlying literal Python object
"""
pp.pprint(to_literal(self), stream, indent, width, depth)
[docs]def node_from_dict(dic, nodefactory=Node):
"""
Convert a (nested) dictionary into a Node object.
"""
[(tag, dic)] = dic.items()
if isinstance(dic, dict):
dic = dic.copy()
text = dic.pop('text', None)
attrib = {n[1:]: dic.pop(n) for n in sorted(dic) if n.startswith('_')}
else:
return nodefactory(tag, {}, dic)
if not dic:
return nodefactory(tag, attrib, text)
[(k, vs)] = dic.items()
if isinstance(vs, list):
nodes = [node_from_dict({k: v}) for v in vs]
else:
nodes = [node_from_dict(dic)]
return nodefactory(tag, attrib, nodes=nodes)
def _group(one_key_dicts):
items = []
for one_key_dict in one_key_dicts:
[(k, v)] = one_key_dict.items()
items.append((k, v))
dic = {}
for k, group in itertools.groupby(items, lambda item: item[0]):
vs = []
for k, v in group:
vs.append(v)
if len(vs) == 1:
dic[k] = vs[0]
else:
dic[k] = vs
return dic
[docs]def node_to_dict(node):
"""
Convert a Node object into a (nested) dictionary
with attributes tag, attrib, text, nodes.
:param node: a Node-compatible object
"""
tag = striptag(node.tag)
dic = {}
if node.attrib:
for nam, val in node.attrib.items():
dic['_' + nam] = (float(val)
if isinstance(val, numpy.float64) else val)
if isinstance(node.text, str) and node.text.strip() == '':
pass
elif node.text is not None:
if 'attrib' in dic:
dic['text'] = node.text
else:
dic = node.text
if node.nodes:
dic.update(_group([node_to_dict(n) for n in node]))
return {tag: dic}
[docs]def node_from_elem(elem, nodefactory=Node, lazy=()):
"""
Convert (recursively) an ElementTree object into a Node object.
"""
children = list(elem)
lineno = getattr(elem, 'lineno', None)
if not children:
return nodefactory(elem.tag, dict(elem.attrib), elem.text,
lineno=lineno)
if striptag(elem.tag) in lazy:
nodes = (node_from_elem(ch, nodefactory, lazy) for ch in children)
else:
nodes = [node_from_elem(ch, nodefactory, lazy) for ch in children]
return nodefactory(elem.tag, dict(elem.attrib), nodes=nodes, lineno=lineno)
# taken from https://gist.github.com/651801, which comes for the effbot
[docs]def node_to_elem(root):
"""
Convert (recursively) a Node object into an ElementTree object.
"""
def generate_elem(append, node, level):
var = "e" + str(level)
arg = repr(node.tag)
if node.attrib:
arg += ", **%r" % node.attrib
if level == 1:
append("e1 = Element(%s)" % arg)
else:
append("%s = SubElement(e%d, %s)" % (var, level - 1, arg))
if not node.nodes:
append("%s.text = %r" % (var, node.text))
for x in node:
generate_elem(append, x, level + 1)
# generate code to create a tree
output = []
generate_elem(output.append, root, 1) # print "\n".join(output)
namespace = {"Element": ElementTree.Element,
"SubElement": ElementTree.SubElement}
exec("\n".join(output), globals(), namespace)
return namespace["e1"]
[docs]def read_nodes(fname, filter_elem, nodefactory=Node, remove_comments=True):
"""
Convert an XML file into a lazy iterator over Node objects
satifying the given specification, i.e. a function element -> boolean.
:param fname: file name of file object
:param filter_elem: element specification
In case of errors, add the file name to the error message.
"""
try:
for _, el in iterparse(fname, remove_comments=remove_comments):
if filter_elem(el):
yield node_from_elem(el, nodefactory)
el.clear() # save memory
except Exception:
etype, exc, tb = sys.exc_info()
msg = str(exc)
if not str(fname) in msg:
msg = '%s in %s' % (msg, fname)
raise_(etype, msg, tb)
[docs]def node_from_xml(xmlfile, nodefactory=Node):
"""
Convert a .xml file into a Node object.
:param xmlfile: a file name or file object open for reading
"""
root = parse(xmlfile).getroot()
return node_from_elem(root, nodefactory)
[docs]def node_to_xml(node, output=sys.stdout, nsmap=None):
"""
Convert a Node object into a pretty .xml file without keeping
everything in memory. If you just want the string representation
use tostring(node).
:param node: a Node-compatible object (ElementTree nodes are fine)
:param nsmap: if given, shorten the tags with aliases
"""
if nsmap:
for ns, prefix in nsmap.items():
if prefix:
node['xmlns:' + prefix[:-1]] = ns
else:
node['xmlns'] = ns
with StreamingXMLWriter(output, nsmap=nsmap) as w:
w.serialize(node)
[docs]def node_from_ini(ini_file, nodefactory=Node, root_name='ini'):
"""
Convert a .ini file into a Node object.
:param ini_file: a filename or a file like object in read mode
"""
fileobj = open(ini_file) if isinstance(ini_file, str) else ini_file
cfp = configparser.RawConfigParser()
cfp.read_file(fileobj)
root = nodefactory(root_name)
sections = cfp.sections()
for section in sections:
params = dict(cfp.items(section))
root.append(Node(section, params))
return root
[docs]def node_to_ini(node, output=sys.stdout):
"""
Convert a Node object with the right structure into a .ini file.
:params node: a Node object
:params output: a file-like object opened in write mode
"""
for subnode in node:
output.write(u'\n[%s]\n' % subnode.tag)
for name, value in sorted(subnode.attrib.items()):
output.write(u'%s=%s\n' % (name, value))
output.flush()
[docs]def node_copy(node, nodefactory=Node):
"""Make a deep copy of the node"""
return nodefactory(node.tag, node.attrib.copy(), node.text,
[node_copy(n, nodefactory) for n in node])
[docs]@contextmanager
def context(fname, node):
"""
Context manager managing exceptions and adding line number of the
current node and name of the current file to the error message.
:param fname: the current file being processed
:param node: the current node being processed
"""
try:
yield node
except Exception:
etype, exc, tb = sys.exc_info()
msg = 'node %s: %s, line %s of %s' % (
striptag(node.tag), exc, getattr(node, 'lineno', '?'), fname)
raise_(etype, msg, tb)
[docs]class ValidatingXmlParser(object):
"""
Validating XML Parser based on Expat. It has two methods `.parse_file`
and `.parse_bytes` returning a validated :class:`Node` object.
:param validators: a dictionary of validation functions
:param stop: the tag where to stop the parsing (if any)
"""
[docs] class Exit(Exception):
"""Raised when the parsing is stopped before the end on purpose"""
def __init__(self, validators, stop=None):
self.validators = validators
self.stop = stop
@contextmanager
def _context(self):
self.p = ParserCreate(namespace_separator='}')
self.p.StartElementHandler = self._start_element
self.p.EndElementHandler = self._end_element
self.p.CharacterDataHandler = self._char_data
self._ancestors = []
self._root = None
try:
yield
except ExpatError as err:
msg = '%s: %s: %s' % (self.filename, err.lineno,
ErrorString(err.code))
e = ExpatError(msg)
e.lineno = err.lineno
e.offset = err.offset
e.filename = self.filename
raise e
except ValueError as err:
err.lineno = self.p.CurrentLineNumber
err.offset = self.p.CurrentColumnNumber
err.filename = self.filename
raise err
except self.Exit:
pass
[docs] def parse_bytes(self, bytestr, isfinal=True):
"""
Parse a byte string. If the string is very large, split it in chuncks
and parse each chunk with isfinal=False, then parse an empty chunk
with isfinal=True.
"""
with self._context():
self.filename = None
self.p.Parse(bytestr, isfinal)
return self._root
[docs] def parse_file(self, file_or_fname):
"""
Parse a file or a filename
"""
with self._context():
if hasattr(file_or_fname, 'read'):
self.filename = getattr(
file_or_fname, 'name', file_or_fname.__class__.__name__)
self.p.ParseFile(file_or_fname)
else:
self.filename = file_or_fname
with open(file_or_fname, 'rb') as f:
self.p.ParseFile(f)
return self._root
def _start_element(self, longname, attrs):
try:
xmlns, name = longname.split('}')
except ValueError: # no namespace in the longname
name = tag = longname
else: # fix the tag with an opening brace
tag = '{' + longname
self._ancestors.append(
Node(tag, attrs, lineno=self.p.CurrentLineNumber))
if self.stop and name == self.stop:
for anc in reversed(self._ancestors):
self._end_element(anc.tag)
raise self.Exit
def _end_element(self, name):
node = self._ancestors[-1]
with context(self.filename, node):
self._root = self._literalnode(node)
del self._ancestors[-1]
if self._ancestors:
self._ancestors[-1].append(self._root)
def _char_data(self, data):
if data:
parent = self._ancestors[-1]
if parent.text is None:
parent.text = data
else:
parent.text += data
def _set_text(self, node, text, tag):
if text is None:
return
try:
val = self.validators[tag]
except KeyError:
return
try:
node.text = val(decode(text.strip()))
except Exception as exc:
raise ValueError('Could not convert %s->%s: %s' %
(tag, val.__name__, exc))
def _set_attrib(self, node, n, tn, v):
val = self.validators[tn]
try:
node.attrib[n] = val(decode(v))
except Exception as exc:
raise ValueError(
'Could not convert %s->%s: %s, line %s' %
(tn, val.__name__, exc, node.lineno))
def _literalnode(self, node):
tag = striptag(node.tag)
# cast the text
self._set_text(node, node.text, tag)
# cast the attributes
for n, v in node.attrib.items():
tn = '%s.%s' % (tag, n)
if tn in self.validators:
self._set_attrib(node, n, tn, v)
elif n in self.validators:
self._set_attrib(node, n, n, v)
return node