doc/build/unicode.rst - third_party/mako - Git at Google

 .. _unicode_toplevel:

 ===================
 The Unicode Chapter
 ===================

 The Python language supports two ways of representing what we
 know as "strings", i.e. series of characters. In Python 2, the
 two types are ``string`` and ``unicode``, and in Python 3 they are
 ``bytes`` and ``string``. A key aspect of the Python 2 ``string`` and
 Python 3 ``bytes`` types are that they contain no information
 regarding what **encoding** the data is stored in. For this
 reason they were commonly referred to as **byte strings** on
 Python 2, and Python 3 makes this name more explicit. The
 origins of this come from Python's background of being developed
 before the Unicode standard was even available, back when
 strings were C-style strings and were just that, a series of
 bytes. Strings that had only values below 128 just happened to
 be **ASCII** strings and were printable on the console, whereas
 strings with values above 128 would produce all kinds of
 graphical characters and bells.

 Contrast the "byte-string" type with the "unicode/string" type.
 Objects of this latter type are created whenever you say something like
 ``u"hello world"`` (or in Python 3, just ``"hello world"``). In this
 case, Python represents each character in the string internally
 using multiple bytes per character (something similar to
 UTF-16). What's important is that when using the
 ``unicode``/``string`` type to store strings, Python knows the
 data's encoding; it's in its own internal format. Whereas when
 using the ``string``/``bytes`` type, it does not.

 When Python 2 attempts to treat a byte-string as a string, which
 means it's attempting to compare/parse its characters, to coerce
 it into another encoding, or to decode it to a unicode object,
 it has to guess what the encoding is. In this case, it will
 pretty much always guess the encoding as ``ascii``... and if the
 byte-string contains bytes above value 128, you'll get an error.
 Python 3 eliminates much of this confusion by just raising an
 error unconditionally if a byte-string is used in a
 character-aware context.

 There is one operation that Python *can* do with a non-ASCII
 byte-string, and it's a great source of confusion: it can dump the
 byte-string straight out to a stream or a file, with nary a care
 what the encoding is. To Python, this is pretty much like
 dumping any other kind of binary data (like an image) to a
 stream somewhere. In Python 2, it is common to see programs that
 embed all kinds of international characters and encodings into
 plain byte-strings (i.e. using ``"hello world"`` style literals)
 can fly right through their run, sending reams of strings out to
 wherever they are going, and the programmer, seeing the same
 output as was expressed in the input, is now under the illusion
 that his or her program is Unicode-compliant. In fact, their
 program has no unicode awareness whatsoever, and similarly has
 no ability to interact with libraries that *are* unicode aware.
 Python 3 makes this much less likely by defaulting to unicode as
 the storage format for strings.

 The "pass through encoded data" scheme is what template
 languages like Cheetah and earlier versions of Myghty do by
 default. Mako as of version 0.2 also supports this mode of
 operation when using Python 2, using the ``disable_unicode=True``
 flag. However, when using Mako in its default mode of
 unicode-aware, it requires explicitness when dealing with
 non-ASCII encodings. Additionally, if you ever need to handle
 unicode strings and other kinds of encoding conversions more
 intelligently, the usage of raw byte-strings quickly becomes a
 nightmare, since you are sending the Python interpreter
 collections of bytes for which it can make no intelligent
 decisions with regards to encoding. In Python 3 Mako only allows
 usage of native, unicode strings.

 In normal Mako operation, all parsed template constructs and
 output streams are handled internally as Python ``unicode``
 objects. It's only at the point of :meth:`~.Template.render` that this unicode
 stream may be rendered into whatever the desired output encoding
 is. The implication here is that the template developer must
 :ensure that :ref:`the encoding of all non-ASCII templates is explicit
 <set_template_file_encoding>` (still required in Python 3),
 that :ref:`all non-ASCII-encoded expressions are in one way or another
 converted to unicode <handling_non_ascii_expressions>`
 (not much of a burden in Python 3), and that :ref:`the output stream of the
 template is handled as a unicode stream being encoded to some
 encoding <defining_output_encoding>` (still required in Python 3).

 .. _set_template_file_encoding:

 Specifying the Encoding of a Template File
 ==========================================

 This is the most basic encoding-related setting, and it is
 equivalent to Python's "magic encoding comment", as described in
 `pep-0263 <http://www.python.org/dev/peps/pep-0263/>`_. Any
 template that contains non-ASCII characters requires that this
 comment be present so that Mako can decode to unicode (and also
 make usage of Python's AST parsing services). Mako's lexer will
 use this encoding in order to convert the template source into a
 ``unicode`` object before continuing its parsing:

 .. sourcecode:: mako

     ## -*- coding: utf-8 -*-

     Alors vous imaginez ma surprise, au lever du jour, quand
     une drôle de petite voix m’a réveillé. Elle disait:
      « S’il vous plaît… dessine-moi un mouton! »

 For the picky, the regular expression used is derived from that
 of the above mentioned pep:

 .. sourcecode:: python

     #.*coding[:=]\s*([-\w.]+).*\n

 The lexer will convert to unicode in all cases, so that if any
 characters exist in the template that are outside of the
 specified encoding (or the default of ``ascii``), the error will
 be immediate.

 As an alternative, the template encoding can be specified
 programmatically to either :class:`.Template` or :class:`.TemplateLookup` via
 the ``input_encoding`` parameter:

 .. sourcecode:: python

     t = TemplateLookup(directories=['./'], input_encoding='utf-8')

 The above will assume all located templates specify ``utf-8``
 encoding, unless the template itself contains its own magic
 encoding comment, which takes precedence.

 .. _handling_non_ascii_expressions:

 Handling Expressions
 ====================

 The next area that encoding comes into play is in expression
 constructs. By default, Mako's treatment of an expression like
 this:

 .. sourcecode:: mako

     ${"hello world"}

 looks something like this:

 .. sourcecode:: python

     context.write(unicode("hello world"))

 In Python 3, it's just:

 .. sourcecode:: python

     context.write(str("hello world"))

 That is, **the output of all expressions is run through the
 ``unicode`` built-in**. This is the default setting, and can be
 modified to expect various encodings. The ``unicode`` step serves
 both the purpose of rendering non-string expressions into
 strings (such as integers or objects which contain ``__str()__``
 methods), and to ensure that the final output stream is
 constructed as a unicode object. The main implication of this is
 that **any raw byte-strings that contain an encoding other than
 ASCII must first be decoded to a Python unicode object**. It
 means you can't say this in Python 2:

 .. sourcecode:: mako

     ${"voix m’a réveillé."}  ## error in Python 2!

 You must instead say this:

 .. sourcecode:: mako

     ${u"voix m’a réveillé."}  ## OK !

 Similarly, if you are reading data from a file that is streaming
 bytes, or returning data from some object that is returning a
 Python byte-string containing a non-ASCII encoding, you have to
 explicitly decode to unicode first, such as:

 .. sourcecode:: mako

     ${call_my_object().decode('utf-8')}

 Note that filehandles acquired by ``open()`` in Python 3 default
 to returning "text", that is the decoding is done for you. See
 Python 3's documentation for the ``open()`` built-in for details on
 this.

 If you want a certain encoding applied to *all* expressions,
 override the ``unicode`` builtin with the ``decode`` built-in at the
 :class:`.Template` or :class:`.TemplateLookup` level:

 .. sourcecode:: python

     t = Template(templatetext, default_filters=['decode.utf8'])

 Note that the built-in ``decode`` object is slower than the
 ``unicode`` function, since unlike ``unicode`` it's not a Python
 built-in, and it also checks the type of the incoming data to
 determine if string conversion is needed first.

 The ``default_filters`` argument can be used to entirely customize
 the filtering process of expressions. This argument is described
 in :ref:`filtering_default_filters`.

 .. _defining_output_encoding:

 Defining Output Encoding
 ========================

 Now that we have a template which produces a pure unicode output
 stream, all the hard work is done. We can take the output and do
 anything with it.

 As stated in the :doc:`"Usage" chapter <usage>`, both :class:`.Template` and
 :class:`.TemplateLookup` accept ``output_encoding`` and ``encoding_errors``
 parameters which can be used to encode the output in any Python
 supported codec:

 .. sourcecode:: python

     from mako.template import Template
     from mako.lookup import TemplateLookup

     mylookup = TemplateLookup(directories=['/docs'], output_encoding='utf-8', encoding_errors='replace')

     mytemplate = mylookup.get_template("foo.txt")
     print(mytemplate.render())

 :meth:`~.Template.render` will return a ``bytes`` object in Python 3 if an output
 encoding is specified. By default it performs no encoding and
 returns a native string.

 :meth:`~.Template.render_unicode` will return the template output as a Python
 ``unicode`` object (or ``string`` in Python 3):

 .. sourcecode:: python

     print(mytemplate.render_unicode())

 The above method disgards the output encoding keyword argument;
 you can encode yourself by saying:

 .. sourcecode:: python

     print(mytemplate.render_unicode().encode('utf-8', 'replace'))

 Buffer Selection
 ----------------

 Mako does play some games with the style of buffering used
 internally, to maximize performance. Since the buffer is by far
 the most heavily used object in a render operation, it's
 important!

 When calling :meth:`~.Template.render` on a template that does not specify any
 output encoding (i.e. it's ``ascii``), Python's ``cStringIO`` module,
 which cannot handle encoding of non-ASCII ``unicode`` objects
 (even though it can send raw byte-strings through), is used for
 buffering. Otherwise, a custom Mako class called
 ``FastEncodingBuffer`` is used, which essentially is a super
 dumbed-down version of ``StringIO`` that gathers all strings into
 a list and uses ``u''.join(elements)`` to produce the final output
 -- it's markedly faster than ``StringIO``.

 .. _unicode_disabled:

 Saying to Heck with It: Disabling the Usage of Unicode Entirely
 ===============================================================

 Some segments of Mako's userbase choose to make no usage of
 Unicode whatsoever, and instead would prefer the "pass through"
 approach; all string expressions in their templates return
 encoded byte-strings, and they would like these strings to pass
 right through. The only advantage to this approach is that
 templates need not use ``u""`` for literal strings; there's an
 arguable speed improvement as well since raw byte-strings
 generally perform slightly faster than unicode objects in
 Python. For these users, assuming they're sticking with Python
 2, they can hit the ``disable_unicode=True`` flag as so:

 .. sourcecode:: python

     # -*- coding:utf-8 -*-
     from mako.template import Template

     t = Template("drôle de petite voix m’a réveillé.", disable_unicode=True, input_encoding='utf-8')
     print(t.code)

 The ``disable_unicode`` mode is strictly a Python 2 thing. It is
 not supported at all in Python 3.

 The generated module source code will contain elements like
 these:

 .. sourcecode:: python

     # -*- coding:utf-8 -*-
     #  ...more generated code ...

     def render_body(context,**pageargs):
         context.caller_stack.push_frame()
         try:
             __M_locals = dict(pageargs=pageargs)
             # SOURCE LINE 1
             context.write('dr\xc3\xb4le de petite voix m\xe2\x80\x99a r\xc3\xa9veill\xc3\xa9.')
             return ''
         finally:
             context.caller_stack.pop_frame()

 Where above that the string literal used within :meth:`.Context.write`
 is a regular byte-string.

 When ``disable_unicode=True`` is turned on, the ``default_filters``
 argument which normally defaults to ``["unicode"]`` now defaults
 to ``["str"]`` instead. Setting ``default_filters`` to the empty list
 ``[]`` can remove the overhead of the ``str`` call. Also, in this
 mode you **cannot** safely call :meth:`~.Template.render_unicode` -- you'll get
 unicode/decode errors.

 The ``h`` filter (HTML escape) uses a less performant pure Python
 escape function in non-unicode mode. This because
 MarkupSafe only supports Python unicode objects for non-ASCII
 strings.

 .. versionchanged:: 0.3.4
    In prior versions, it used ``cgi.escape()``, which has been replaced
    with a function that also escapes single quotes.

 Rules for using ``disable_unicode=True``
 ----------------------------------------

 * Don't use this mode unless you really, really want to and you
   absolutely understand what you're doing.
 * Don't use this option just because you don't want to learn to
   use Unicode properly; we aren't supporting user issues in this
   mode of operation. We will however offer generous help for the
   vast majority of users who stick to the Unicode program.
 * Python 3 is unicode by default, and the flag is not available
   when running on Python 3.
	.. _unicode_toplevel:

	===================
	The Unicode Chapter
	===================

	The Python language supports two ways of representing what we
	know as "strings", i.e. series of characters. In Python 2, the
	two types are ``string`` and ``unicode``, and in Python 3 they are
	``bytes`` and ``string``. A key aspect of the Python 2 ``string`` and
	Python 3 ``bytes`` types are that they contain no information
	regarding what encoding the data is stored in. For this
	reason they were commonly referred to as byte strings on
	Python 2, and Python 3 makes this name more explicit. The
	origins of this come from Python's background of being developed
	before the Unicode standard was even available, back when
	strings were C-style strings and were just that, a series of
	bytes. Strings that had only values below 128 just happened to
	be ASCII strings and were printable on the console, whereas
	strings with values above 128 would produce all kinds of
	graphical characters and bells.

	Contrast the "byte-string" type with the "unicode/string" type.
	Objects of this latter type are created whenever you say something like
	``u"hello world"`` (or in Python 3, just ``"hello world"``). In this
	case, Python represents each character in the string internally
	using multiple bytes per character (something similar to
	UTF-16). What's important is that when using the
	``unicode``/``string`` type to store strings, Python knows the
	data's encoding; it's in its own internal format. Whereas when
	using the ``string``/``bytes`` type, it does not.

	When Python 2 attempts to treat a byte-string as a string, which
	means it's attempting to compare/parse its characters, to coerce
	it into another encoding, or to decode it to a unicode object,
	it has to guess what the encoding is. In this case, it will
	pretty much always guess the encoding as ``ascii``... and if the
	byte-string contains bytes above value 128, you'll get an error.
	Python 3 eliminates much of this confusion by just raising an
	error unconditionally if a byte-string is used in a
	character-aware context.

	There is one operation that Python can do with a non-ASCII
	byte-string, and it's a great source of confusion: it can dump the
	byte-string straight out to a stream or a file, with nary a care
	what the encoding is. To Python, this is pretty much like
	dumping any other kind of binary data (like an image) to a
	stream somewhere. In Python 2, it is common to see programs that
	embed all kinds of international characters and encodings into
	plain byte-strings (i.e. using ``"hello world"`` style literals)
	can fly right through their run, sending reams of strings out to
	wherever they are going, and the programmer, seeing the same
	output as was expressed in the input, is now under the illusion
	that his or her program is Unicode-compliant. In fact, their
	program has no unicode awareness whatsoever, and similarly has
	no ability to interact with libraries that are unicode aware.
	Python 3 makes this much less likely by defaulting to unicode as
	the storage format for strings.

	The "pass through encoded data" scheme is what template
	languages like Cheetah and earlier versions of Myghty do by
	default. Mako as of version 0.2 also supports this mode of
	operation when using Python 2, using the ``disable_unicode=True``
	flag. However, when using Mako in its default mode of
	unicode-aware, it requires explicitness when dealing with
	non-ASCII encodings. Additionally, if you ever need to handle
	unicode strings and other kinds of encoding conversions more
	intelligently, the usage of raw byte-strings quickly becomes a
	nightmare, since you are sending the Python interpreter
	collections of bytes for which it can make no intelligent
	decisions with regards to encoding. In Python 3 Mako only allows
	usage of native, unicode strings.

	In normal Mako operation, all parsed template constructs and
	output streams are handled internally as Python ``unicode``
	objects. It's only at the point of :meth:`~.Template.render` that this unicode
	stream may be rendered into whatever the desired output encoding
	is. The implication here is that the template developer must
	:ensure that :ref:`the encoding of all non-ASCII templates is explicit
	<set_template_file_encoding>` (still required in Python 3),
	that :ref:`all non-ASCII-encoded expressions are in one way or another
	converted to unicode <handling_non_ascii_expressions>`
	(not much of a burden in Python 3), and that :ref:`the output stream of the
	template is handled as a unicode stream being encoded to some
	encoding <defining_output_encoding>` (still required in Python 3).

	.. _set_template_file_encoding:

	Specifying the Encoding of a Template File
	==========================================

	This is the most basic encoding-related setting, and it is
	equivalent to Python's "magic encoding comment", as described in
	`pep-0263 <http://www.python.org/dev/peps/pep-0263/>`_. Any
	template that contains non-ASCII characters requires that this
	comment be present so that Mako can decode to unicode (and also
	make usage of Python's AST parsing services). Mako's lexer will
	use this encoding in order to convert the template source into a
	``unicode`` object before continuing its parsing:

	.. sourcecode:: mako

	## -- coding: utf-8 --

	Alors vous imaginez ma surprise, au lever du jour, quand
	une drôle de petite voix m’a réveillé. Elle disait:
	« S’il vous plaît… dessine-moi un mouton! »

	For the picky, the regular expression used is derived from that
	of the above mentioned pep:

	.. sourcecode:: python

	#.coding[:=]\s([-\w.]+).*\n

	The lexer will convert to unicode in all cases, so that if any
	characters exist in the template that are outside of the
	specified encoding (or the default of ``ascii``), the error will
	be immediate.

	As an alternative, the template encoding can be specified
	programmatically to either :class:`.Template` or :class:`.TemplateLookup` via
	the ``input_encoding`` parameter:

	.. sourcecode:: python

	t = TemplateLookup(directories=['./'], input_encoding='utf-8')

	The above will assume all located templates specify ``utf-8``
	encoding, unless the template itself contains its own magic
	encoding comment, which takes precedence.

	.. _handling_non_ascii_expressions:

	Handling Expressions
	====================

	The next area that encoding comes into play is in expression
	constructs. By default, Mako's treatment of an expression like
	this:

	.. sourcecode:: mako

	${"hello world"}

	looks something like this:

	.. sourcecode:: python

	context.write(unicode("hello world"))

	In Python 3, it's just:

	.. sourcecode:: python

	context.write(str("hello world"))

	That is, **the output of all expressions is run through the
	``unicode`` built-in**. This is the default setting, and can be
	modified to expect various encodings. The ``unicode`` step serves
	both the purpose of rendering non-string expressions into
	strings (such as integers or objects which contain ``__str()__``
	methods), and to ensure that the final output stream is
	constructed as a unicode object. The main implication of this is
	that **any raw byte-strings that contain an encoding other than
	ASCII must first be decoded to a Python unicode object**. It
	means you can't say this in Python 2:

	.. sourcecode:: mako

	${"voix m’a réveillé."} ## error in Python 2!

	You must instead say this:

	.. sourcecode:: mako

	${u"voix m’a réveillé."} ## OK !

	Similarly, if you are reading data from a file that is streaming
	bytes, or returning data from some object that is returning a
	Python byte-string containing a non-ASCII encoding, you have to
	explicitly decode to unicode first, such as:

	.. sourcecode:: mako

	${call_my_object().decode('utf-8')}

	Note that filehandles acquired by ``open()`` in Python 3 default
	to returning "text", that is the decoding is done for you. See
	Python 3's documentation for the ``open()`` built-in for details on
	this.

	If you want a certain encoding applied to all expressions,
	override the ``unicode`` builtin with the ``decode`` built-in at the
	:class:`.Template` or :class:`.TemplateLookup` level:

	.. sourcecode:: python

	t = Template(templatetext, default_filters=['decode.utf8'])

	Note that the built-in ``decode`` object is slower than the
	``unicode`` function, since unlike ``unicode`` it's not a Python
	built-in, and it also checks the type of the incoming data to
	determine if string conversion is needed first.

	The ``default_filters`` argument can be used to entirely customize
	the filtering process of expressions. This argument is described
	in :ref:`filtering_default_filters`.

	.. _defining_output_encoding:

	Defining Output Encoding
	========================

	Now that we have a template which produces a pure unicode output
	stream, all the hard work is done. We can take the output and do
	anything with it.

	As stated in the :doc:`"Usage" chapter <usage>`, both :class:`.Template` and
	:class:`.TemplateLookup` accept ``output_encoding`` and ``encoding_errors``
	parameters which can be used to encode the output in any Python
	supported codec:

	.. sourcecode:: python

	from mako.template import Template
	from mako.lookup import TemplateLookup

	mylookup = TemplateLookup(directories=['/docs'], output_encoding='utf-8', encoding_errors='replace')

	mytemplate = mylookup.get_template("foo.txt")
	print(mytemplate.render())

	:meth:`~.Template.render` will return a ``bytes`` object in Python 3 if an output
	encoding is specified. By default it performs no encoding and
	returns a native string.

	:meth:`~.Template.render_unicode` will return the template output as a Python
	``unicode`` object (or ``string`` in Python 3):

	.. sourcecode:: python

	print(mytemplate.render_unicode())

	The above method disgards the output encoding keyword argument;
	you can encode yourself by saying:

	.. sourcecode:: python

	print(mytemplate.render_unicode().encode('utf-8', 'replace'))

	Buffer Selection
	----------------

	Mako does play some games with the style of buffering used
	internally, to maximize performance. Since the buffer is by far
	the most heavily used object in a render operation, it's
	important!

	When calling :meth:`~.Template.render` on a template that does not specify any
	output encoding (i.e. it's ``ascii``), Python's ``cStringIO`` module,
	which cannot handle encoding of non-ASCII ``unicode`` objects
	(even though it can send raw byte-strings through), is used for
	buffering. Otherwise, a custom Mako class called
	``FastEncodingBuffer`` is used, which essentially is a super
	dumbed-down version of ``StringIO`` that gathers all strings into
	a list and uses ``u''.join(elements)`` to produce the final output
	-- it's markedly faster than ``StringIO``.

	.. _unicode_disabled:

	Saying to Heck with It: Disabling the Usage of Unicode Entirely
	===============================================================

	Some segments of Mako's userbase choose to make no usage of
	Unicode whatsoever, and instead would prefer the "pass through"
	approach; all string expressions in their templates return
	encoded byte-strings, and they would like these strings to pass
	right through. The only advantage to this approach is that
	templates need not use ``u""`` for literal strings; there's an
	arguable speed improvement as well since raw byte-strings
	generally perform slightly faster than unicode objects in
	Python. For these users, assuming they're sticking with Python
	2, they can hit the ``disable_unicode=True`` flag as so:

	.. sourcecode:: python

	# -- coding:utf-8 --
	from mako.template import Template

	t = Template("drôle de petite voix m’a réveillé.", disable_unicode=True, input_encoding='utf-8')
	print(t.code)

	The ``disable_unicode`` mode is strictly a Python 2 thing. It is
	not supported at all in Python 3.

	The generated module source code will contain elements like
	these:

	.. sourcecode:: python

	# -- coding:utf-8 --
	# ...more generated code ...

	def render_body(context,**pageargs):
	context.caller_stack.push_frame()
	try:
	__M_locals = dict(pageargs=pageargs)
	# SOURCE LINE 1
	context.write('dr\xc3\xb4le de petite voix m\xe2\x80\x99a r\xc3\xa9veill\xc3\xa9.')
	return ''
	finally:
	context.caller_stack.pop_frame()

	Where above that the string literal used within :meth:`.Context.write`
	is a regular byte-string.

	When ``disable_unicode=True`` is turned on, the ``default_filters``
	argument which normally defaults to ``["unicode"]`` now defaults
	to ``["str"]`` instead. Setting ``default_filters`` to the empty list
	``[]`` can remove the overhead of the ``str`` call. Also, in this
	mode you cannot safely call :meth:`~.Template.render_unicode` -- you'll get
	unicode/decode errors.

	The ``h`` filter (HTML escape) uses a less performant pure Python
	escape function in non-unicode mode. This because
	MarkupSafe only supports Python unicode objects for non-ASCII
	strings.

	.. versionchanged:: 0.3.4
	In prior versions, it used ``cgi.escape()``, which has been replaced
	with a function that also escapes single quotes.

	Rules for using ``disable_unicode=True``
	----------------------------------------

	* Don't use this mode unless you really, really want to and you
	absolutely understand what you're doing.
	* Don't use this option just because you don't want to learn to
	use Unicode properly; we aren't supporting user issues in this
	mode of operation. We will however offer generous help for the
	vast majority of users who stick to the Unicode program.
	* Python 3 is unicode by default, and the flag is not available
	when running on Python 3.