API === .. module:: jinja2 :synopsis: public Jinja2 API This document describes the API to Jinja2 and not the template language. It will be most useful as reference to those implementing the template interface to the application and not those who are creating Jinja2 templates. Basics ------ Jinja2 uses a central object called the template :class:`Environment`. Instances of this class are used to store the configuration, global objects and are used to load templates from the file system or other locations. Even if you are creating templates from strings by using the constructor of :class:`Template` class, an environment is created automatically for you, albeit a shared one. Most applications will create one :class:`Environment` object on application initialization and use that to load templates. In some cases it's however useful to have multiple environments side by side, if different configurations are in use. The simplest way to configure Jinja2 to load templates for your application looks roughly like this:: from jinja2 import Environment, PackageLoader env = Environment(loader=PackageLoader('yourapplication', 'templates')) This will create a template environment with the default settings and a loader that looks up the templates in the `templates` folder inside the `yourapplication` python package. Different loaders are available and you can also write your own if you want to load templates from a database or other resources. To load a template from this environment you just have to call the :meth:`get_template` method which then returns the loaded :class:`Template`:: template = env.get_template('mytemplate.html') To render it with some variables, just call the :meth:`render` method:: print template.render(the='variables', go='here') Using a template loader rather then passing strings to :class:`Template` or :meth:`Environment.from_string` has multiple advantages. Besides being a lot easier to use it also enables template inheritance. Unicode ------- Jinja2 is using unicode internally which means that you have to pass unicode objects to the render function or bytestrings that only consist of ASCII characters. Additionally newlines are normalized to one end of line sequence which is per default UNIX style (``\n``). Python 2.x supports two ways of representing string objects. One is the `str` type and the other is the `unicode` type, both of which extend a type called `basestring`. Unfortunately the default is `str` which should not be used to store text based information unless only ASCII characters are used. With Python 2.6 it is possible to make `unicode` the default on a per module level and with Python 3 it will be the default. To explicitly use a unicode string you have to prefix the string literal with a `u`: ``u'Hänsel und Gretel sagen Hallo'``. That way Python will store the string as unicode by decoding the string with the character encoding from the current Python module. If no encoding is specified this defaults to 'ASCII' which means that you can't use any non ASCII identifier. To set a better module encoding add the following comment to the first or second line of the Python module using the unicode literal:: # -*- coding: utf-8 -*- We recommend utf-8 as Encoding for Python modules and templates as it's possible to represent every Unicode character in utf-8 and because it's backwards compatible to ASCII. For Jinja2 the default encoding of templates is assumed to be utf-8. It is not possible to use Jinja2 to process non unicode data. The reason for this is that Jinja2 uses Unicode already on the language level. For example Jinja2 treats the non-breaking space as valid whitespace inside expressions which requires knowledge of the encoding or operating on an unicode string. For more details about unicode in Python have a look at the excellent `Unicode documentation`_. Another important thing is how Jinja2 is handling string literals in templates. A naive implementation would be using unicode strings for all string literals but it turned out in the past that this is problematic as some libraries are typechecking against `str` explicitly. For example `datetime.strftime` does not accept unicode arguments. To not break it completely Jinja2 is returning `str` for strings that fit into ASCII and for everything else `unicode`: >>> m = Template(u"{% set a, b = 'foo', 'föö' %}").module >>> m.a 'foo' >>> m.b u'f\xf6\xf6' .. _Unicode documentation: http://docs.python.org/dev/howto/unicode.html High Level API -------------- The high-level API is the API you will use in the application to load and render Jinja2 templates. The :ref:`low-level-api` on the other side is only useful if you want to dig deeper into Jinja2 or :ref:`develop extensions `. .. autoclass:: Environment([options]) :members: from_string, get_template, join_path, extend, compile_expression .. attribute:: shared If a template was created by using the :class:`Template` constructor an environment is created automatically. These environments are created as shared environments which means that multiple templates may have the same anonymous environment. For all shared environments this attribute is `True`, else `False`. .. attribute:: sandboxed If the environment is sandboxed this attribute is `True`. For the sandbox mode have a look at the documentation for the :class:`~jinja2.sandbox.SandboxedEnvironment`. .. attribute:: filters A dict of filters for this environment. As long as no template was loaded it's safe to add new filters or remove old. For custom filters see :ref:`writing-filters`. For valid filter names have a look at :ref:`identifier-naming`. .. attribute:: tests A dict of test functions for this environment. As long as no template was loaded it's safe to modify this dict. For custom tests see :ref:`writing-tests`. For valid test names have a look at :ref:`identifier-naming`. .. attribute:: globals A dict of global variables. These variables are always available in a template. As long as no template was loaded it's safe to modify this dict. For more details see :ref:`global-namespace`. For valid object names have a look at :ref:`identifier-naming`. .. automethod:: overlay([options]) .. method:: undefined([hint, obj, name, exc]) Creates a new :class:`Undefined` object for `name`. This is useful for filters or functions that may return undefined objects for some operations. All parameters except of `hint` should be provided as keyword parameters for better readability. The `hint` is used as error message for the exception if provided, otherwise the error message will be generated from `obj` and `name` automatically. The exception provided as `exc` is raised if something with the generated undefined object is done that the undefined object does not allow. The default exception is :exc:`UndefinedError`. If a `hint` is provided the `name` may be ommited. The most common way to create an undefined object is by providing a name only:: return environment.undefined(name='some_name') This means that the name `some_name` is not defined. If the name was from an attribute of an object it makes sense to tell the undefined object the holder object to improve the error message:: if not hasattr(obj, 'attr'): return environment.undefined(obj=obj, name='attr') For a more complex example you can provide a hint. For example the :func:`first` filter creates an undefined object that way:: return environment.undefined('no first item, sequence was empty') If it the `name` or `obj` is known (for example because an attribute was accessed) it shold be passed to the undefined object, even if a custom `hint` is provided. This gives undefined objects the possibility to enhance the error message. .. autoclass:: Template :members: module, make_module .. attribute:: globals The dict with the globals of that template. It's unsafe to modify this dict as it may be shared with other templates or the environment that loaded the template. .. attribute:: name The loading name of the template. If the template was loaded from a string this is `None`. .. attribute:: filename The filename of the template on the file system if it was loaded from there. Otherwise this is `None`. .. automethod:: render([context]) .. automethod:: generate([context]) .. automethod:: stream([context]) .. autoclass:: jinja2.environment.TemplateStream() :members: disable_buffering, enable_buffering, dump .. _identifier-naming: Notes on Identifiers -------------------- Jinja2 uses the regular Python 2.x naming rules. Valid identifiers have to match ``[a-zA-Z_][a-zA-Z0-9_]*``. As a matter of fact non ASCII characters are currently not allowed. This limitation will probably go away as soon as unicode identifiers are fully specified for Python 3. Filters and tests are looked up in separate namespaces and have slightly modified identifier syntax. Filters and tests may contain dots to group filters and tests by topic. For example it's perfectly valid to add a function into the filter dict and call it `to.unicode`. The regular expression for filter and test identifiers is ``[a-zA-Z_][a-zA-Z0-9_]*(\.[a-zA-Z_][a-zA-Z0-9_]*)*```. Undefined Types --------------- These classes can be used as undefined types. The :class:`Environment` constructor takes an `undefined` parameter that can be one of those classes or a custom subclass of :class:`Undefined`. Whenever the template engine is unable to look up a name or access an attribute one of those objects is created and returned. Some operations on undefined values are then allowed, others fail. The closest to regular Python behavior is the `StrictUndefined` which disallows all operations beside testing if it's an undefined object. .. autoclass:: jinja2.Undefined() .. attribute:: _undefined_hint Either `None` or an unicode string with the error message for the undefined object. .. attribute:: _undefined_obj Either `None` or the owner object that caused the undefined object to be created (for example because an attribute does not exist). .. attribute:: _undefined_name The name for the undefined variable / attribute or just `None` if no such information exists. .. attribute:: _undefined_exception The exception that the undefined object wants to raise. This is usually one of :exc:`UndefinedError` or :exc:`SecurityError`. .. method:: _fail_with_undefined_error(\*args, \**kwargs) When called with any arguments this method raises :attr:`_undefined_exception` with an error message generated from the undefined hints stored on the undefined object. .. autoclass:: jinja2.DebugUndefined() .. autoclass:: jinja2.StrictUndefined() Undefined objects are created by calling :attr:`undefined`. .. admonition:: Implementation :class:`Undefined` objects are implemented by overriding the special `__underscore__` methods. For example the default :class:`Undefined` class implements `__unicode__` in a way that it returns an empty string, however `__int__` and others still fail with an exception. To allow conversion to int by returning ``0`` you can implement your own:: class NullUndefined(Undefined): def __int__(self): return 0 def __float__(self): return 0.0 To disallow a method, just override it and raise :attr:`~Undefined._undefined_exception`. Because this is a very common idom in undefined objects there is the helper method :meth:`~Undefined._fail_with_undefined_error` that does the error raising automatically. Here a class that works like the regular :class:`Undefined` but chokes on iteration:: class NonIterableUndefined(Undefined): __iter__ = Undefined._fail_with_undefined_error The Context ----------- .. autoclass:: jinja2.runtime.Context() :members: resolve, get_exported, get_all .. attribute:: parent A dict of read only, global variables the template looks up. These can either come from another :class:`Context`, from the :attr:`Environment.globals` or :attr:`Template.globals` or points to a dict created by combining the globals with the variables passed to the render function. It must not be altered. .. attribute:: vars The template local variables. This list contains environment and context functions from the :attr:`parent` scope as well as local modifications and exported variables from the template. The template will modify this dict during template evaluation but filters and context functions are not allowed to modify it. .. attribute:: environment The environment that loaded the template. .. attribute:: exported_vars This set contains all the names the template exports. The values for the names are in the :attr:`vars` dict. In order to get a copy of the exported variables as dict, :meth:`get_exported` can be used. .. attribute:: name The load name of the template owning this context. .. attribute:: blocks A dict with the current mapping of blocks in the template. The keys in this dict are the names of the blocks, and the values a list of blocks registered. The last item in each list is the current active block (latest in the inheritance chain). .. automethod:: jinja2.runtime.Context.call(callable, \*args, \**kwargs) .. admonition:: Implementation Context is immutable for the same reason Python's frame locals are immutable inside functions. Both Jinja2 and Python are not using the context / frame locals as data storage for variables but only as primary data source. When a template accesses a variable the template does not define, Jinja2 looks up the variable in the context, after that the variable is treated as if it was defined in the template. .. _loaders: Loaders ------- Loaders are responsible for loading templates from a resource such as the file system. The environment will keep the compiled modules in memory like Python's `sys.modules`. Unlike `sys.modules` however this cache is limited in size by default and templates are automatically reloaded. All loaders are subclasses of :class:`BaseLoader`. If you want to create your own loader, subclass :class:`BaseLoader` and override `get_source`. .. autoclass:: jinja2.BaseLoader :members: get_source, load Here a list of the builtin loaders Jinja2 provides: .. autoclass:: jinja2.FileSystemLoader .. autoclass:: jinja2.PackageLoader .. autoclass:: jinja2.DictLoader .. autoclass:: jinja2.FunctionLoader .. autoclass:: jinja2.PrefixLoader .. autoclass:: jinja2.ChoiceLoader .. _bytecode-cache: Bytecode Cache -------------- Jinja 2.1 and higher support external bytecode caching. Bytecode caches make it possible to store the generated bytecode on the file system or a different location to avoid parsing the templates on first use. This is especially useful if you have a web application that is initialized on the first request and Jinja compiles many templates at once which slows down the application. To use a bytecode cache, instanciate it and pass it to the :class:`Environment`. .. autoclass:: jinja2.BytecodeCache :members: load_bytecode, dump_bytecode, clear .. autoclass:: jinja2.bccache.Bucket :members: write_bytecode, load_bytecode, bytecode_from_string, bytecode_to_string, reset .. attribute:: environment The :class:`Environment` that created the bucket. .. attribute:: key The unique cache key for this bucket .. attribute:: code The bytecode if it's loaded, otherwise `None`. Builtin bytecode caches: .. autoclass:: jinja2.FileSystemBytecodeCache .. autoclass:: jinja2.MemcachedBytecodeCache Utilities --------- These helper functions and classes are useful if you add custom filters or functions to a Jinja2 environment. .. autofunction:: jinja2.environmentfilter .. autofunction:: jinja2.contextfilter .. autofunction:: jinja2.environmentfunction .. autofunction:: jinja2.contextfunction .. function:: escape(s) Convert the characters ``&``, ``<``, ``>``, ``'``, and ``"`` in string `s` to HTML-safe sequences. Use this if you need to display text that might contain such characters in HTML. This function will not escaped objects that do have an HTML representation such as already escaped data. The return value is a :class:`Markup` string. .. autofunction:: jinja2.clear_caches .. autofunction:: jinja2.is_undefined .. autoclass:: jinja2.Markup([string]) :members: escape, unescape, striptags .. admonition:: Note The Jinja2 :class:`Markup` class is compatible with at least Pylons and Genshi. It's expected that more template engines and framework will pick up the `__html__` concept soon. Exceptions ---------- .. autoexception:: jinja2.TemplateError .. autoexception:: jinja2.UndefinedError .. autoexception:: jinja2.TemplateNotFound .. autoexception:: jinja2.TemplateSyntaxError .. attribute:: message The error message as utf-8 bytestring. .. attribute:: lineno The line number where the error occurred .. attribute:: name The load name for the template as unicode string. .. attribute:: filename The filename that loaded the template as bytestring in the encoding of the file system (most likely utf-8 or mbcs on Windows systems). The reason why the filename and error message are bytestrings and not unicode strings is that Python 2.x is not using unicode for exceptions and tracebacks as well as the compiler. This will change with Python 3. .. autoexception:: jinja2.TemplateAssertionError .. _writing-filters: Custom Filters -------------- Custom filters are just regular Python functions that take the left side of the filter as first argument and the the arguments passed to the filter as extra arguments or keyword arguments. For example in the filter ``{{ 42|myfilter(23) }}`` the function would be called with ``myfilter(42, 23)``. Here for example a simple filter that can be applied to datetime objects to format them:: def datetimeformat(value, format='%H:%M / %d-%m-%Y'): return value.strftime(format) You can register it on the template environment by updating the :attr:`~Environment.filters` dict on the environment:: environment.filters['datetimeformat'] = datetimeformat Inside the template it can then be used as follows: .. sourcecode:: jinja written on: {{ article.pub_date|datetimeformat }} publication date: {{ article.pub_date|datetimeformat('%d-%m-%Y') }} Filters can also be passed the current template context or environment. This is useful if a filter wants to return an undefined value or check the current :attr:`~Environment.autoescape` setting. For this purpose two decorators exist: :func:`environmentfilter` and :func:`contextfilter`. Here a small example filter that breaks a text into HTML line breaks and paragraphs and marks the return value as safe HTML string if autoescaping is enabled:: import re from jinja2 import environmentfilter, Markup, escape _paragraph_re = re.compile(r'(?:\r\n|\r|\n){2,}') @environmentfilter def nl2br(environment, value): result = u'\n\n'.join(u'

%s

' % p.replace('\n', '
\n') for p in _paragraph_re.split(escape(value))) if environment.autoescape: result = Markup(result) return result Context filters work the same just that the first argument is the current active :class:`Context` rather then the environment. .. _writing-tests: Custom Tests ------------ Tests work like filters just that there is no way for a test to get access to the environment or context and that they can't be chained. The return value of a test should be `True` or `False`. The purpose of a test is to give the template designers the possibility to perform type and conformability checks. Here a simple test that checks if a variable is a prime number:: import math def is_prime(n): if n == 2: return True for i in xrange(2, int(math.ceil(math.sqrt(n))) + 1): if n % i == 0: return False return True You can register it on the template environment by updating the :attr:`~Environment.tests` dict on the environment:: environment.tests['prime'] = is_prime A template designer can then use the test like this: .. sourcecode:: jinja {% if 42 is prime %} 42 is a prime number {% else %} 42 is not a prime number {% endif %} .. _global-namespace: The Global Namespace -------------------- Variables stored in the :attr:`Environment.globals` dict are special as they are available for imported templates too, even if they are imported without context. This is the place where you can put variables and functions that should be available all the time. Additionally :attr:`Template.globals` exist that are variables available to a specific template that are available to all :meth:`~Template.render` calls. .. _low-level-api: Low Level API ------------- The low level API exposes functionality that can be useful to understand some implementation details, debugging purposes or advanced :ref:`extension ` techniques. Unless you know exactly what you are doing we don't recommend using any of those. .. automethod:: Environment.lex .. automethod:: Environment.parse .. automethod:: Environment.preprocess .. automethod:: Template.new_context .. method:: Template.root_render_func(context) This is the low level render function. It's passed a :class:`Context` that has to be created by :meth:`new_context` of the same template or a compatible template. This render function is generated by the compiler from the template code and returns a generator that yields unicode strings. If an exception in the template code happens the template engine will not rewrite the exception but pass through the original one. As a matter of fact this function should only be called from within a :meth:`render` / :meth:`generate` / :meth:`stream` call. .. attribute:: Template.blocks A dict of block render functions. Each of these functions works exactly like the :meth:`root_render_func` with the same limitations. .. attribute:: Template.is_up_to_date This attribute is `False` if there is a newer version of the template available, otherwise `True`. .. admonition:: Note The low-level API is fragile. Future Jinja2 versions will try not to change it in a backwards incompatible way but modifications in the Jinja2 core may shine through. For example if Jinja2 introduces a new AST node in later versions that may be returned by :meth:`~Environment.parse`. The Meta API ------------ .. versionadded:: 2.2 The meta API returns some information about abstract syntax trees that could help applications to implement more advanced template concepts. All the functions of the meta API operate on an abstract syntax tree as returned by the :meth:`Environment.parse` method. .. autofunction:: jinja2.meta.find_undeclared_variables .. autofunction:: jinja2.meta.find_referenced_templates