Author: | Stefan Behnel |
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This is a tutorial on XML processing with lxml.etree. It briefly overviews the main concepts of the ElementTree API, and some simple enhancements that make your life as a programmer easier.
For a complete reference of the API, see the generated API documentation.
Contents
A common way to import lxml.etree is as follows:
>>> from lxml import etree
If your code only uses the ElementTree API and does not rely on any functionality that is specific to lxml.etree, you can also use (any part of) the following import chain as a fall-back to the original ElementTree:
try: from lxml import etree print("running with lxml.etree") except ImportError: try: # Python 2.5 import xml.etree.cElementTree as etree print("running with cElementTree on Python 2.5+") except ImportError: try: # Python 2.5 import xml.etree.ElementTree as etree print("running with ElementTree on Python 2.5+") except ImportError: try: # normal cElementTree install import cElementTree as etree print("running with cElementTree") except ImportError: try: # normal ElementTree install import elementtree.ElementTree as etree print("running with ElementTree") except ImportError: print("Failed to import ElementTree from any known place")
To aid in writing portable code, this tutorial makes it clear in the examples which part of the presented API is an extension of lxml.etree over the original ElementTree API, as defined by Fredrik Lundh's ElementTree library.
An Element is the main container object for the ElementTree API. Most of the XML tree functionality is accessed through this class. Elements are easily created through the Element factory:
>>> root = etree.Element("root")
The XML tag name of elements is accessed through the tag property:
>>> print(root.tag) root
Elements are organised in an XML tree structure. To create child elements and add them to a parent element, you can use the append() method:
>>> root.append( etree.Element("child1") )
However, this is so common that there is a shorter and much more efficient way to do this: the SubElement factory. It accepts the same arguments as the Element factory, but additionally requires the parent as first argument:
>>> child2 = etree.SubElement(root, "child2") >>> child3 = etree.SubElement(root, "child3")
To see that this is really XML, you can serialise the tree you have created:
>>> print(etree.tostring(root, pretty_print=True)) <root> <child1/> <child2/> <child3/> </root>
To make the access to these subelements as easy and straight forward as possible, elements behave like normal Python lists:
>>> child = root[0] >>> print(child.tag) child1 >>> print(len(root)) 3 >>> root.index(root[1]) # lxml.etree only! 1 >>> children = list(root) >>> for child in root: ... print(child.tag) child1 child2 child3 >>> root.insert(0, etree.Element("child0")) >>> start = root[:1] >>> end = root[-1:] >>> print(start[0].tag) child0 >>> print(end[0].tag) child3 >>> root[0] = root[-1] # this moves the element in lxml.etree! >>> for child in root: ... print(child.tag) child3 child1 child2
Prior to ElementTree 1.3 and lxml 2.0, you could also check the truth value of an Element to see if it has children, i.e. if the list of children is empty. This is no longer supported as people tend to find it surprising that a non-None reference to an existing Element can evaluate to False. Instead, use len(element), which is both more explicit and less error prone.
Note in the examples that the last element was moved to a different position in the last example. This is a difference from the original ElementTree (and from lists), where elements can sit in multiple positions of any number of trees. In lxml.etree, elements can only sit in one position of one tree at a time.
If you want to copy an element to a different position, consider creating an independent deep copy using the copy module from Python's standard library:
>>> from copy import deepcopy >>> element = etree.Element("neu") >>> element.append( deepcopy(root[1]) ) >>> print(element[0].tag) child1 >>> print([ c.tag for c in root ]) ['child3', 'child1', 'child2']
The way up in the tree is provided through the getparent() method:
>>> root is root[0].getparent() # lxml.etree only! True
The siblings (or neighbours) of an element are accessed as next and previous elements:
>>> root[0] is root[1].getprevious() # lxml.etree only! True >>> root[1] is root[0].getnext() # lxml.etree only! True
XML elements support attributes. You can create them directly in the Element factory:
>>> root = etree.Element("root", interesting="totally") >>> etree.tostring(root) b'<root interesting="totally"/>'
Fast and direct access to these attributes is provided by the set() and get() methods of elements:
>>> print(root.get("interesting")) totally >>> root.set("interesting", "somewhat") >>> print(root.get("interesting")) somewhat
However, a very convenient way of dealing with them is through the dictionary interface of the attrib property:
>>> attributes = root.attrib >>> print(attributes["interesting"]) somewhat >>> print(attributes.get("hello")) None >>> attributes["hello"] = "Guten Tag" >>> print(attributes.get("hello")) Guten Tag >>> print(root.get("hello")) Guten Tag
Elements can contain text:
>>> root = etree.Element("root") >>> root.text = "TEXT" >>> print(root.text) TEXT >>> etree.tostring(root) b'<root>TEXT</root>'
In many XML documents (data-centric documents), this is the only place where text can be found. It is encapsulated by a leaf tag at the very bottom of the tree hierarchy.
However, if XML is used for tagged text documents such as (X)HTML, text can also appear between different elements, right in the middle of the tree:
<html><body>Hello<br/>World</body></html>
Here, the <br/> tag is surrounded by text. This is often referred to as document-style or mixed-content XML. Elements support this through their tail property. It contains the text that directly follows the element, up to the next element in the XML tree:
>>> html = etree.Element("html") >>> body = etree.SubElement(html, "body") >>> body.text = "TEXT" >>> etree.tostring(html) b'<html><body>TEXT</body></html>' >>> br = etree.SubElement(body, "br") >>> etree.tostring(html) b'<html><body>TEXT<br/></body></html>' >>> br.tail = "TAIL" >>> etree.tostring(html) b'<html><body>TEXT<br/>TAIL</body></html>'
The two properties .text and .tail are enough to represent any text content in an XML document. This way, the ElementTree API does not require any special text nodes in addition to the Element class, that tend to get in the way fairly often (as you might know from classic DOM APIs).
However, there are cases where the tail text also gets in the way. For example, when you serialise an Element from within the tree, you do not always want its tail text in the result (although you would still want the tail text of its children). For this purpose, the tostring() function accepts the keyword argument with_tail:
>>> etree.tostring(br) b'<br/>TAIL' >>> etree.tostring(br, with_tail=False) # lxml.etree only! b'<br/>'
If you want to read only the text, i.e. without any intermediate tags, you have to recursively concatenate all text and tail attributes in the correct order. Again, the tostring() function comes to the rescue, this time using the method keyword:
>>> etree.tostring(html, method="text") b'TEXTTAIL'
Another way to extract the text content of a tree is XPath, which also allows you to extract the separate text chunks into a list:
>>> print(html.xpath("string()")) # lxml.etree only! TEXTTAIL >>> print(html.xpath("//text()")) # lxml.etree only! ['TEXT', 'TAIL']
If you want to use this more often, you can wrap it in a function:
>>> build_text_list = etree.XPath("//text()") # lxml.etree only! >>> print(build_text_list(html)) ['TEXT', 'TAIL']
Note that a string result returned by XPath is a special 'smart' object that knows about its origins. You can ask it where it came from through its getparent() method, just as you would with Elements:
>>> texts = build_text_list(html) >>> print(texts[0]) TEXT >>> parent = texts[0].getparent() >>> print(parent.tag) body >>> print(texts[1]) TAIL >>> print(texts[1].getparent().tag) br
You can also find out if it's normal text content or tail text:
>>> print(texts[0].is_text) True >>> print(texts[1].is_text) False >>> print(texts[1].is_tail) True
While this works for the results of the text() function, lxml will not tell you the origin of a string value that was constructed by the XPath functions string() or concat():
>>> stringify = etree.XPath("string()") >>> print(stringify(html)) TEXTTAIL >>> print(stringify(html).getparent()) None
For problems like the above, where you want to recursively traverse the tree and do something with its elements, tree iteration is a very convenient solution. Elements provide a tree iterator for this purpose. It yields elements in document order, i.e. in the order their tags would appear if you serialised the tree to XML:
>>> root = etree.Element("root") >>> etree.SubElement(root, "child").text = "Child 1" >>> etree.SubElement(root, "child").text = "Child 2" >>> etree.SubElement(root, "another").text = "Child 3" >>> print(etree.tostring(root, pretty_print=True)) <root> <child>Child 1</child> <child>Child 2</child> <another>Child 3</another> </root> >>> for element in root.iter(): ... print("%s - %s" % (element.tag, element.text)) root - None child - Child 1 child - Child 2 another - Child 3
If you know you are only interested in a single tag, you can pass its name to iter() to have it filter for you. Starting with lxml 3.0, you can also pass more than one tag to intercept on multiple tags during iteration.
>>> for element in root.iter("child"): ... print("%s - %s" % (element.tag, element.text)) child - Child 1 child - Child 2 >>> for element in root.iter("another", "child"): ... print("%s - %s" % (element.tag, element.text)) child - Child 1 child - Child 2 another - Child 3
By default, iteration yields all nodes in the tree, including ProcessingInstructions, Comments and Entity instances. If you want to make sure only Element objects are returned, you can pass the Element factory as tag parameter:
>>> root.append(etree.Entity("#234")) >>> root.append(etree.Comment("some comment")) >>> for element in root.iter(): ... if isinstance(element.tag, basestring): ... print("%s - %s" % (element.tag, element.text)) ... else: ... print("SPECIAL: %s - %s" % (element, element.text)) root - None child - Child 1 child - Child 2 another - Child 3 SPECIAL: ê - ê SPECIAL: <!--some comment--> - some comment >>> for element in root.iter(tag=etree.Element): ... print("%s - %s" % (element.tag, element.text)) root - None child - Child 1 child - Child 2 another - Child 3 >>> for element in root.iter(tag=etree.Entity): ... print(element.text) ê
Note that passing a wildcard "*" tag name will also yield all Element nodes (and only elements).
In lxml.etree, elements provide further iterators for all directions in the tree: children, parents (or rather ancestors) and siblings.
Serialisation commonly uses the tostring() function that returns a string, or the ElementTree.write() method that writes to a file, a file-like object, or a URL (via FTP PUT or HTTP POST). Both calls accept the same keyword arguments like pretty_print for formatted output or encoding to select a specific output encoding other than plain ASCII:
>>> root = etree.XML('<root><a><b/></a></root>') >>> etree.tostring(root) b'<root><a><b/></a></root>' >>> print(etree.tostring(root, xml_declaration=True)) <?xml version='1.0' encoding='ASCII'?> <root><a><b/></a></root> >>> print(etree.tostring(root, encoding='iso-8859-1')) <?xml version='1.0' encoding='iso-8859-1'?> <root><a><b/></a></root> >>> print(etree.tostring(root, pretty_print=True)) <root> <a> <b/> </a> </root>
Note that pretty printing appends a newline at the end.
In lxml 2.0 and later (as well as ElementTree 1.3), the serialisation functions can do more than XML serialisation. You can serialise to HTML or extract the text content by passing the method keyword:
>>> root = etree.XML( ... '<html><head/><body><p>Hello<br/>World</p></body></html>') >>> etree.tostring(root) # default: method = 'xml' b'<html><head/><body><p>Hello<br/>World</p></body></html>' >>> etree.tostring(root, method='xml') # same as above b'<html><head/><body><p>Hello<br/>World</p></body></html>' >>> etree.tostring(root, method='html') b'<html><head></head><body><p>Hello<br>World</p></body></html>' >>> print(etree.tostring(root, method='html', pretty_print=True)) <html> <head></head> <body><p>Hello<br>World</p></body> </html> >>> etree.tostring(root, method='text') b'HelloWorld'
As for XML serialisation, the default encoding for plain text serialisation is ASCII:
>>> br = root.find('.//br') >>> br.tail = u'W\xf6rld' >>> etree.tostring(root, method='text') # doctest: +ELLIPSIS Traceback (most recent call last): ... UnicodeEncodeError: 'ascii' codec can't encode character u'\xf6' ... >>> etree.tostring(root, method='text', encoding="UTF-8") b'HelloW\xc3\xb6rld'
Here, serialising to a Python unicode string instead of a byte string might become handy. Just pass the unicode type as encoding:
>>> etree.tostring(root, encoding=unicode, method='text') u'HelloW\xf6rld'
The W3C has a good article about the Unicode character set and character encodings.
An ElementTree is mainly a document wrapper around a tree with a root node. It provides a couple of methods for serialisation and general document handling.
>>> root = etree.XML('''\ ... <?xml version="1.0"?> ... <!DOCTYPE root SYSTEM "test" [ <!ENTITY tasty "parsnips"> ]> ... <root> ... <a>&tasty;</a> ... </root> ... ''') >>> tree = etree.ElementTree(root) >>> print(tree.docinfo.xml_version) 1.0 >>> print(tree.docinfo.doctype) <!DOCTYPE root SYSTEM "test">
An ElementTree is also what you get back when you call the parse() function to parse files or file-like objects (see the parsing section below).
One of the important differences is that the ElementTree class serialises as a complete document, as opposed to a single Element. This includes top-level processing instructions and comments, as well as a DOCTYPE and other DTD content in the document:
>>> print(etree.tostring(tree)) # lxml 1.3.4 and later <!DOCTYPE root SYSTEM "test" [ <!ENTITY tasty "parsnips"> ]> <root> <a>parsnips</a> </root>
In the original xml.etree.ElementTree implementation and in lxml up to 1.3.3, the output looks the same as when serialising only the root Element:
>>> print(etree.tostring(tree.getroot())) <root> <a>parsnips</a> </root>
This serialisation behaviour has changed in lxml 1.3.4. Before, the tree was serialised without DTD content, which made lxml loose DTD information in an input-output cycle.
lxml.etree supports parsing XML in a number of ways and from all important sources, namely strings, files, URLs (http/ftp) and file-like objects. The main parse functions are fromstring() and parse(), both called with the source as first argument. By default, they use the standard parser, but you can always pass a different parser as second argument.
The fromstring() function is the easiest way to parse a string:
>>> some_xml_data = "<root>data</root>" >>> root = etree.fromstring(some_xml_data) >>> print(root.tag) root >>> etree.tostring(root) b'<root>data</root>'
The XML() function behaves like the fromstring() function, but is commonly used to write XML literals right into the source:
>>> root = etree.XML("<root>data</root>") >>> print(root.tag) root >>> etree.tostring(root) b'<root>data</root>'
There is also a corresponding function HTML() for HTML literals.
The parse() function is used to parse from files and file-like objects.
As an example of such a file-like object, the following code uses the StringIO class for reading from a string instead of an external file. That class comes from the StringIO module in Python 2. In Python 2.6 and later, including Python 3.x, you would rather use the BytesIO class from the io module. However, in real life, you would obviously avoid doing this all together and use the string parsing functions above.
>>> some_file_like_object = StringIO("<root>data</root>") >>> tree = etree.parse(some_file_like_object) >>> etree.tostring(tree) b'<root>data</root>'
Note that parse() returns an ElementTree object, not an Element object as the string parser functions:
>>> root = tree.getroot() >>> print(root.tag) root >>> etree.tostring(root) b'<root>data</root>'
The reasoning behind this difference is that parse() returns a complete document from a file, while the string parsing functions are commonly used to parse XML fragments.
The parse() function supports any of the following sources:
Note that passing a filename or URL is usually faster than passing an open file or file-like object. However, the HTTP/FTP client in libxml2 is rather simple, so things like HTTP authentication require a dedicated URL request library, e.g. urllib2 or request. These libraries usually provide a file-like object for the result that you can parse from while the response is streaming in.
By default, lxml.etree uses a standard parser with a default setup. If you want to configure the parser, you can create a you instance:
>>> parser = etree.XMLParser(remove_blank_text=True) # lxml.etree only!
This creates a parser that removes empty text between tags while parsing, which can reduce the size of the tree and avoid dangling tail text if you know that whitespace-only content is not meaningful for your data. An example:
>>> root = etree.XML("<root> <a/> <b> </b> </root>", parser) >>> etree.tostring(root) b'<root><a/><b> </b></root>'
Note that the whitespace content inside the <b> tag was not removed, as content at leaf elements tends to be data content (even if blank). You can easily remove it in an additional step by traversing the tree:
>>> for element in root.iter("*"): ... if element.text is not None and not element.text.strip(): ... element.text = None >>> etree.tostring(root) b'<root><a/><b/></root>'
See help(etree.XMLParser) to find out about the available parser options.
lxml.etree provides two ways for incremental step-by-step parsing. One is through file-like objects, where it calls the read() method repeatedly. This is best used where the data arrives from a source like urllib or any other file-like object that can provide data on request. Note that the parser will block and wait until data becomes available in this case:
>>> class DataSource: ... data = [ b"<roo", b"t><", b"a/", b"><", b"/root>" ] ... def read(self, requested_size): ... try: ... return self.data.pop(0) ... except IndexError: ... return b'' >>> tree = etree.parse(DataSource()) >>> etree.tostring(tree) b'<root><a/></root>'
The second way is through a feed parser interface, given by the feed(data) and close() methods:
>>> parser = etree.XMLParser() >>> parser.feed("<roo") >>> parser.feed("t><") >>> parser.feed("a/") >>> parser.feed("><") >>> parser.feed("/root>") >>> root = parser.close() >>> etree.tostring(root) b'<root><a/></root>'
Here, you can interrupt the parsing process at any time and continue it later on with another call to the feed() method. This comes in handy if you want to avoid blocking calls to the parser, e.g. in frameworks like Twisted, or whenever data comes in slowly or in chunks and you want to do other things while waiting for the next chunk.
After calling the close() method (or when an exception was raised by the parser), you can reuse the parser by calling its feed() method again:
>>> parser.feed("<root/>") >>> root = parser.close() >>> etree.tostring(root) b'<root/>'
Sometimes, all you need from a document is a small fraction somewhere deep inside the tree, so parsing the whole tree into memory, traversing it and dropping it can be too much overhead. lxml.etree supports this use case with two event-driven parser interfaces, one that generates parser events while building the tree (iterparse), and one that does not build the tree at all, and instead calls feedback methods on a target object in a SAX-like fashion.
Here is a simple iterparse() example:
>>> some_file_like = StringIO("<root><a>data</a></root>") >>> for event, element in etree.iterparse(some_file_like): ... print("%s, %4s, %s" % (event, element.tag, element.text)) end, a, data end, root, None
By default, iterparse() only generates events when it is done parsing an element, but you can control this through the events keyword argument:
>>> some_file_like = StringIO("<root><a>data</a></root>") >>> for event, element in etree.iterparse(some_file_like, ... events=("start", "end")): ... print("%5s, %4s, %s" % (event, element.tag, element.text)) start, root, None start, a, data end, a, data end, root, None
Note that the text, tail and children of an Element are not necessarily there yet when receiving the start event. Only the end event guarantees that the Element has been parsed completely.
It also allows to .clear() or modify the content of an Element to save memory. So if you parse a large tree and you want to keep memory usage small, you should clean up parts of the tree that you no longer need:
>>> some_file_like = StringIO( ... "<root><a><b>data</b></a><a><b/></a></root>") >>> for event, element in etree.iterparse(some_file_like): ... if element.tag == 'b': ... print(element.text) ... elif element.tag == 'a': ... print("** cleaning up the subtree") ... element.clear() data ** cleaning up the subtree None ** cleaning up the subtree
A very important use cases for iterparse() is parsing large generated XML files, e.g. database dumps. Most often, these XML formats only have one main data item element that hangs directly below the root node and that is repeated thousands of times. In this case, it is best practice to let lxml.etree do the tree building and to only intercept exactly on this one Element, using the normal tree API for data extraction.
>>> xml_file = StringIO('''\ ... <root> ... <a><b>ABC</b><c>abc</c></a> ... <a><b>MORE DATA</b><c>more data</c></a> ... <a><b>XYZ</b><c>xyz</c></a> ... </root>''') >>> for _, element in etree.iterparse(xml_file, tag='a'): ... print('%s -- %s' % (element.findtext('b'), element[1].text)) ... element.clear() ABC -- abc MORE DATA -- more data XYZ -- xyz
If, for some reason, building the tree is not desired at all, the target parser interface of lxml.etree can be used. It creates SAX-like events by calling the methods of a target object. By implementing some or all of these methods, you can control which events are generated:
>>> class ParserTarget: ... events = [] ... close_count = 0 ... def start(self, tag, attrib): ... self.events.append(("start", tag, attrib)) ... def close(self): ... events, self.events = self.events, [] ... self.close_count += 1 ... return events >>> parser_target = ParserTarget() >>> parser = etree.XMLParser(target=parser_target) >>> events = etree.fromstring('<root test="true"/>', parser) >>> print(parser_target.close_count) 1 >>> for event in events: ... print('event: %s - tag: %s' % (event[0], event[1])) ... for attr, value in event[2].items(): ... print(' * %s = %s' % (attr, value)) event: start - tag: root * test = true
You can reuse the parser and its target as often as you like, so you should take care that the .close() methods really resets the target to a usable state (also in the case of an error!).
>>> events = etree.fromstring('<root test="true"/>', parser) >>> print(parser_target.close_count) 2 >>> events = etree.fromstring('<root test="true"/>', parser) >>> print(parser_target.close_count) 3 >>> events = etree.fromstring('<root test="true"/>', parser) >>> print(parser_target.close_count) 4 >>> for event in events: ... print('event: %s - tag: %s' % (event[0], event[1])) ... for attr, value in event[2].items(): ... print(' * %s = %s' % (attr, value)) event: start - tag: root * test = true
The ElementTree API avoids namespace prefixes wherever possible and deploys the real namespaces (the URI) instead:
>>> xhtml = etree.Element("{http://www.w3.org/1999/xhtml}html") >>> body = etree.SubElement(xhtml, "{http://www.w3.org/1999/xhtml}body") >>> body.text = "Hello World" >>> print(etree.tostring(xhtml, pretty_print=True)) <html:html xmlns:html="http://www.w3.org/1999/xhtml"> <html:body>Hello World</html:body> </html:html>
The notation that ElementTree uses was originally brought up by James Clark. It has the major advantage of providing a universally qualified name for a tag, regardless of any prefixes that may or may not have been used or defined in a document. By moving the indirection of prefixes out of the way, it makes namespace aware code much clearer and easier to get right.
As you can see from the example, prefixes only become important when you serialise the result. However, the above code looks somewhat verbose due to the lengthy namespace names. And retyping or copying a string over and over again is error prone. It is therefore common practice to store a namespace URI in a global variable. To adapt the namespace prefixes for serialisation, you can also pass a mapping to the Element factory function, e.g. to define the default namespace:
>>> XHTML_NAMESPACE = "http://www.w3.org/1999/xhtml" >>> XHTML = "{%s}" % XHTML_NAMESPACE >>> NSMAP = {None : XHTML_NAMESPACE} # the default namespace (no prefix) >>> xhtml = etree.Element(XHTML + "html", nsmap=NSMAP) # lxml only! >>> body = etree.SubElement(xhtml, XHTML + "body") >>> body.text = "Hello World" >>> print(etree.tostring(xhtml, pretty_print=True)) <html xmlns="http://www.w3.org/1999/xhtml"> <body>Hello World</body> </html>
You can also use the QName helper class to build or split qualified tag names:
>>> tag = etree.QName('http://www.w3.org/1999/xhtml', 'html') >>> print(tag.localname) html >>> print(tag.namespace) http://www.w3.org/1999/xhtml >>> print(tag.text) {http://www.w3.org/1999/xhtml}html >>> tag = etree.QName('{http://www.w3.org/1999/xhtml}html') >>> print(tag.localname) html >>> print(tag.namespace) http://www.w3.org/1999/xhtml >>> root = etree.Element('{http://www.w3.org/1999/xhtml}html') >>> tag = etree.QName(root) >>> print(tag.localname) html >>> tag = etree.QName(root, 'script') >>> print(tag.text) {http://www.w3.org/1999/xhtml}script >>> tag = etree.QName('{http://www.w3.org/1999/xhtml}html', 'script') >>> print(tag.text) {http://www.w3.org/1999/xhtml}script
lxml.etree allows you to look up the current namespaces defined for a node through the .nsmap property:
>>> xhtml.nsmap {None: 'http://www.w3.org/1999/xhtml'}
Note, however, that this includes all prefixes known in the context of an Element, not only those that it defines itself.
>>> root = etree.Element('root', nsmap={'a': 'http://a.b/c'}) >>> child = etree.SubElement(root, 'child', ... nsmap={'b': 'http://b.c/d'}) >>> len(root.nsmap) 1 >>> len(child.nsmap) 2 >>> child.nsmap['a'] 'http://a.b/c' >>> child.nsmap['b'] 'http://b.c/d'
Therefore, modifying the returned dict cannot have any meaningful impact on the Element. Any changes to it are ignored.
Namespaces on attributes work alike, but as of version 2.3, lxml.etree will make sure that the attribute uses a prefixed namespace declaration. This is because unprefixed attribute names are not considered being in a namespace by the XML namespace specification (section 6.2), so they may end up loosing their namespace on a serialise-parse roundtrip, even if they appear in a namespaced element.
>>> body.set(XHTML + "bgcolor", "#CCFFAA") >>> print(etree.tostring(xhtml, pretty_print=True)) <html xmlns="http://www.w3.org/1999/xhtml"> <body xmlns:html="http://www.w3.org/1999/xhtml" html:bgcolor="#CCFFAA">Hello World</body> </html> >>> print(body.get("bgcolor")) None >>> body.get(XHTML + "bgcolor") '#CCFFAA'
You can also use XPath with fully qualified names:
>>> find_xhtml_body = etree.ETXPath( # lxml only ! ... "//{%s}body" % XHTML_NAMESPACE) >>> results = find_xhtml_body(xhtml) >>> print(results[0].tag) {http://www.w3.org/1999/xhtml}body
For convenience, you can use "*" wildcards in all iterators of lxml.etree, both for tag names and namespaces:
>>> for el in xhtml.iter('*'): print(el.tag) # any element {http://www.w3.org/1999/xhtml}html {http://www.w3.org/1999/xhtml}body >>> for el in xhtml.iter('{http://www.w3.org/1999/xhtml}*'): print(el.tag) {http://www.w3.org/1999/xhtml}html {http://www.w3.org/1999/xhtml}body >>> for el in xhtml.iter('{*}body'): print(el.tag) {http://www.w3.org/1999/xhtml}body
To look for elements that do not have a namespace, either use the plain tag name or provide the empty namespace explicitly:
>>> [ el.tag for el in xhtml.iter('{http://www.w3.org/1999/xhtml}body') ] ['{http://www.w3.org/1999/xhtml}body'] >>> [ el.tag for el in xhtml.iter('body') ] [] >>> [ el.tag for el in xhtml.iter('{}body') ] [] >>> [ el.tag for el in xhtml.iter('{}*') ] []
The E-factory provides a simple and compact syntax for generating XML and HTML:
>>> from lxml.builder import E >>> def CLASS(*args): # class is a reserved word in Python ... return {"class":' '.join(args)} >>> html = page = ( ... E.html( # create an Element called "html" ... E.head( ... E.title("This is a sample document") ... ), ... E.body( ... E.h1("Hello!", CLASS("title")), ... E.p("This is a paragraph with ", E.b("bold"), " text in it!"), ... E.p("This is another paragraph, with a", "\n ", ... E.a("link", href="http://www.python.org"), "."), ... E.p("Here are some reservered characters: <spam&egg>."), ... etree.XML("<p>And finally an embedded XHTML fragment.</p>"), ... ) ... ) ... ) >>> print(etree.tostring(page, pretty_print=True)) <html> <head> <title>This is a sample document</title> </head> <body> <h1 class="title">Hello!</h1> <p>This is a paragraph with <b>bold</b> text in it!</p> <p>This is another paragraph, with a <a href="http://www.python.org">link</a>.</p> <p>Here are some reservered characters: <spam&egg>.</p> <p>And finally an embedded XHTML fragment.</p> </body> </html>
The Element creation based on attribute access makes it easy to build up a simple vocabulary for an XML language:
>>> from lxml.builder import ElementMaker # lxml only ! >>> E = ElementMaker(namespace="http://my.de/fault/namespace", ... nsmap={'p' : "http://my.de/fault/namespace"}) >>> DOC = E.doc >>> TITLE = E.title >>> SECTION = E.section >>> PAR = E.par >>> my_doc = DOC( ... TITLE("The dog and the hog"), ... SECTION( ... TITLE("The dog"), ... PAR("Once upon a time, ..."), ... PAR("And then ...") ... ), ... SECTION( ... TITLE("The hog"), ... PAR("Sooner or later ...") ... ) ... ) >>> print(etree.tostring(my_doc, pretty_print=True)) <p:doc xmlns:p="http://my.de/fault/namespace"> <p:title>The dog and the hog</p:title> <p:section> <p:title>The dog</p:title> <p:par>Once upon a time, ...</p:par> <p:par>And then ...</p:par> </p:section> <p:section> <p:title>The hog</p:title> <p:par>Sooner or later ...</p:par> </p:section> </p:doc>
One such example is the module lxml.html.builder, which provides a vocabulary for HTML.
When dealing with multiple namespaces, it is good practice to define one ElementMaker for each namespace URI. Again, note how the above example predefines the tag builders in named constants. That makes it easy to put all tag declarations of a namespace into one Python module and to import/use the tag name constants from there. This avoids pitfalls like typos or accidentally missing namespaces.
The ElementTree library comes with a simple XPath-like path language called ElementPath. The main difference is that you can use the {namespace}tag notation in ElementPath expressions. However, advanced features like value comparison and functions are not available.
In addition to a full XPath implementation, lxml.etree supports the ElementPath language in the same way ElementTree does, even using (almost) the same implementation. The API provides four methods here that you can find on Elements and ElementTrees:
Here are some examples:
>>> root = etree.XML("<root><a x='123'>aText<b/><c/><b/></a></root>")
Find a child of an Element:
>>> print(root.find("b")) None >>> print(root.find("a").tag) a
Find an Element anywhere in the tree:
>>> print(root.find(".//b").tag) b >>> [ b.tag for b in root.iterfind(".//b") ] ['b', 'b']
Find Elements with a certain attribute:
>>> print(root.findall(".//a[@x]")[0].tag) a >>> print(root.findall(".//a[@y]")) []