Django 1.2 版本发行说明

    欢迎来到 Django 1.2 版本!

    Nearly a year in the making, Django 1.2 packs an impressive list of new features and lots of bug fixes. These release notes cover the new features, as well as important changes you’ll want to be aware of when upgrading from Django 1.1 or older versions.

    Django 1.2 introduces several large, important new features, including:

    These are just the highlights; full details and a complete list of features may be found below.

    参见

    covered the release of Django 1.2 with a series of articles and tutorials that cover some of the new features in depth.

    Wherever possible these features have been introduced in a backwards-compatible manner per our API stability policy policy.

    However, a handful of features have changed in ways that, for some users, will be backwards-incompatible. The big changes are:

    • Support for Python 2.3 has been dropped. See the full notes below.

    • The new CSRF protection framework is not backwards-compatible with the old system. Users of the old system will not be affected until the old system is removed in Django 1.4.

      However, upgrading to the new CSRF protection framework requires a few important backwards-incompatible changes, detailed in , below.

    • Authors of custom Field subclasses should be aware that a number of methods have had a change in prototype, detailed under , below.

    • The internals of template tags have changed somewhat; authors of custom template tags that need to store state (e.g. custom control flow tags) should ensure that their code follows the new rules for stateful template tags

    • The , login_required(), and , decorators from django.contrib.auth only apply to functions and no longer work on methods. There’s a simple one-line fix .

    Again, these are just the big features that will affect the most users. Users upgrading from previous versions of Django are heavily encouraged to consult the complete list of backwards-incompatible changes and the list of .

    While not a new feature, it’s important to note that Django 1.2 introduces the first shift in our Python compatibility policy since Django’s initial public debut. Previous Django releases were tested and supported on 2.x Python versions from 2.3 up; Django 1.2, however, drops official support for Python 2.3. As such, the minimum Python version required for Django is now 2.4, and Django is tested and supported on Python 2.4, 2.5 and 2.6, and will be supported on the as-yet-unreleased Python 2.7.

    This change should affect only a small number of Django users, as most operating-system vendors today are shipping Python 2.4 or newer as their default version. If you’re still using Python 2.3, however, you’ll need to stick to Django 1.1 until you can upgrade; per our support policy, Django 1.1 will continue to receive security support until the release of Django 1.3.

    A roadmap for Django’s overall 2.x Python support, and eventual transition to Python 3.x, is currently being developed, and will be announced prior to the release of Django 1.3.

    Django 1.2 adds the ability to use in your Django project. Queries can be issued at a specific database with the using() method on QuerySet objects. Individual objects can be saved to a specific database by providing a using argument when you call save().

    Model validation

    Model instances now have support for , and both model and form fields now accept configurable lists of validators specifying reusable, encapsulated validation behavior. Note, however, that validation must still be performed explicitly. Simply invoking a model instance’s save() method will not perform any validation of the instance’s data.

    Improved CSRF protection

    Django now has much improved protection against Cross-Site Request Forgery (CSRF) attacks. This type of attack occurs when a malicious website contains a link, a form button or some JavaScript that is intended to perform some action on your website, using the credentials of a logged-in user who visits the malicious site in their browser. A related type of attack, “login CSRF,” where an attacking site tricks a user’s browser into logging into a site with someone else’s credentials, is also covered.

    Messages framework

    Django now includes a robust and configurable messages framework with built-in support for cookie- and session-based messaging, for both anonymous and authenticated clients. The messages framework replaces the deprecated user message API and allows you to temporarily store messages in one request and retrieve them for display in a subsequent request (usually the next one).

    对象级权限

    A foundation for specifying permissions at the per-object level has been added. Although there is no implementation of this in core, a custom authentication backend can provide this implementation and it will be used by django.contrib.auth.models.User. See the for more information.

    Permissions for anonymous users

    If you provide a custom auth backend with supports_anonymous_user set to True, AnonymousUser will check the backend for permissions, just like User already did. This is useful for centralizing permission handling - apps can always delegate the question of whether something is allowed or not to the authorization/authentication backend. See the for more details.

    Relaxed requirements for usernames

    The built-in model’s username field now allows a wider range of characters, including @, +, . and - characters.

    邮件后端

    You can now configure the way that Django sends email. Instead of using SMTP to send all email, you can now choose a configurable email backend to send messages. If your hosting provider uses a sandbox or some other non-SMTP technique for sending mail, you can now construct an email backend that will allow Django’s standard to use those facilities.

    This also makes it easier to debug mail sending. Django ships with backend implementations that allow you to send email to a file, to the , or to memory. You can even configure all email to be .

    “Smart” tag

    The if tag has been upgraded to be much more powerful. First, we’ve added support for comparison operators. No longer will you have to type:

    You can now do this:

    1. {% if a != b %}
    2. ...
    3. {% endif %}

    There’s really no reason to use {% ifequal %} or {% ifnotequal %} anymore, unless you’re the nostalgic type.

    The operators supported are ==, !=, <, >, <=, >=, in and not in, all of which work like the Python operators, in addition to and, or and not, which were already supported.

    Also, filters may now be used in the if expression. For example:

    1. <div
    2. {% if user.email|lower == message.recipient|lower %}
    3. class="highlight"
    4. >{{ message }}</div>

    Template caching

    In previous versions of Django, every time you rendered a template, it would be reloaded from disk. In Django 1.2, you can use a cached template loader to load templates once, then cache the result for every subsequent render. This can lead to a significant performance improvement if your templates are broken into lots of smaller subtemplates (using the {% extends %} or {% include %} tags).

    As a side effect, it is now much easier to support non-Django template languages.

    Class-based template loaders

    As part of the changes made to introduce Template caching and following a general trend in Django, the template loaders API has been modified to use template loading mechanisms that are encapsulated in Python classes as opposed to functions, the only method available until Django 1.1.

    All the template loaders have been ported to the new API but they still implement the function-based API and the template core machinery still accepts function-based loaders (builtin or third party) so there is no immediate need to modify your TEMPLATE_LOADERS setting in existing projects, things will keep working if you leave it untouched up to and including the Django 1.3 release.

    If you have developed your own custom template loaders we suggest to consider porting them to a class-based implementation because the code for backwards compatibility with function-based loaders starts its deprecation process in Django 1.2 and will be removed in Django 1.4. There is a description of the API these loader classes must implement in the template API reference and you can also examine the source code of the loaders shipped with Django.

    Natural keys in fixtures

    Fixtures can now refer to remote objects using . This lookup scheme is an alternative to the normal primary-key based object references in a fixture, improving readability and resolving problems referring to objects whose primary key value may not be predictable or known.

    Fast failure for tests

    Both the subcommand of django-admin.py and the runtests.py script used to run Django’s own test suite now support a --failfast option. When specified, this option causes the test runner to exit after encountering a failure instead of continuing with the test run. In addition, the handling of Ctrl-C during a test run has been improved to trigger a graceful exit from the test run that reports details of the tests that were run before the interruption.

    BigIntegerField

    Models can now use a 64-bit type.

    Improved localization

    Django’s has been expanded with locale-aware formatting and form processing. That means, if enabled, dates and numbers on templates will be displayed using the format specified for the current locale. Django will also use localized formats when parsing data in forms. See 本地格式化 for more details.

    has been added to enable non-editable fields in add/change pages for models and inlines. Field and calculated values can be displayed alongside editable fields.

    Customizable syntax highlighting

    You can now use a environment variable to modify or disable the colors used by django-admin.py to provide syntax highlighting.

    Syndication feeds as views

    Syndication feeds can now be used directly as views in your . This means that you can maintain complete control over the URL structure of your feeds. Like any other view, feeds views are passed a request object, so you can do anything you would normally do with a view, like user based access control, or making a feed a named URL.

    GeoDjango

    The most significant new feature for in 1.2 is support for multiple spatial databases. As a result, the following spatial database backends are now included:

    • django.contrib.gis.db.backends.postgis
    • django.contrib.gis.db.backends.mysql
    • django.contrib.gis.db.backends.oracle
    • django.contrib.gis.db.backends.spatialite

    GeoDjango now supports the rich capabilities added in the PostGIS 1.5 release. New features include support for the and enabling of distance queries with non-point geometries on geographic coordinate systems.

    Support for 3D geometry fields was added, and may be enabled by setting the keyword to 3 in your GeometryField. The aggregate and extent3d() GeoQuerySet method were added as a part of this feature.

    The force_rhr(), reverse_geom(), and geohash() GeoQuerySet methods are new.

    The GEOS interface was updated to use thread-safe C library functions when available on the platform.

    The GDAL interface now allows the user to set a spatial_filter on the features returned when iterating over a .

    Finally, GeoDjango’s documentation is now included with Django’s and is no longer hosted separately at geodjango.org.

    If a user has JavaScript enabled in their browser, the interface for inline objects in the admin now allows inline objects to be dynamically added and removed. Users without JavaScript-enabled browsers will see no change in the behavior of inline objects.

    New now template tag format specifier characters: c and u

    These are also available in others parts like the and time template filters, the humanize template tag library and the new framework.

    Wherever possible the new features above have been introduced in a backwards-compatible manner per our API stability policy policy. This means that practically all existing code which worked with Django 1.1 will continue to work with Django 1.2; such code will, however, begin issuing warnings (see below for details).

    However, a handful of features have changed in ways that, for some users, will be immediately backwards-incompatible. Those changes are detailed below.

    CSRF Protection

    We’ve made large changes to the way CSRF protection works, detailed in the CSRF documentation. Here are the major changes you should be aware of:

    • CsrfResponseMiddleware and CsrfMiddleware have been deprecated and will be removed completely in Django 1.4, in favor of a template tag that should be inserted into forms.

    • All contrib apps use a csrf_protect decorator to protect the view. This requires the use of the csrf_token template tag in the template. If you have used custom templates for contrib views, you MUST READ THE UPGRADE INSTRUCTIONS to fix those templates.

      Documentation removed

      The upgrade notes have been removed in current Django docs. Please refer to the docs for Django 1.3 or older to find these instructions.

    • CsrfViewMiddleware is included in MIDDLEWARE_CLASSES by default. This turns on CSRF protection by default, so views that accept POST requests need to be written to work with the middleware. Instructions on how to do this are found in the CSRF docs.

    • All of the CSRF has moved from contrib to core (with backwards compatible imports in the old locations, which are deprecated and will cease to be supported in Django 1.4).

    get_db_prep_*() methods on Field

    Prior to Django 1.2, a custom Field had the option of defining several functions to support conversion of Python values into database-compatible values. A custom field might look something like:

    1. class CustomModelField(models.Field):
    2. # ...
    3. def db_type(self):
    4. # ...
    5. def get_db_prep_save(self, value):
    6. # ...
    7. def get_db_prep_value(self, value):
    8. # ...
    9. def get_db_prep_lookup(self, lookup_type, value):
    10. # ...

    In 1.2, these three methods have undergone a change in prototype, and two extra methods have been introduced:

    1. class CustomModelField(models.Field):
    2. # ...
    3. def db_type(self, connection):
    4. # ...
    5. def get_prep_value(self, value):
    6. # ...
    7. def get_prep_lookup(self, lookup_type, value):
    8. # ...
    9. def get_db_prep_save(self, value, connection):
    10. # ...
    11. def get_db_prep_value(self, value, connection, prepared=False):
    12. # ...
    13. def get_db_prep_lookup(self, lookup_type, value, connection, prepared=False):
    14. # ...

    These changes are required to support multiple databases — db_type and get_db_prep_* can no longer make any assumptions regarding the database for which it is preparing. The connection argument now provides the preparation methods with the specific connection for which the value is being prepared.

    The two new methods exist to differentiate general data-preparation requirements from requirements that are database-specific. The prepared argument is used to indicate to the database-preparation methods whether generic value preparation has been performed. If an unprepared (i.e., prepared=False) value is provided to the get_db_prep_*() calls, they should invoke the corresponding get_prep_*() calls to perform generic data preparation.

    We’ve provided conversion functions that will transparently convert functions adhering to the old prototype into functions compatible with the new prototype. However, these conversion functions will be removed in Django 1.4, so you should upgrade your Field definitions to use the new prototype as soon as possible.

    If your get_db_prep_*() methods made no use of the database connection, you should be able to upgrade by renaming get_db_prep_value() to and get_db_prep_lookup() to get_prep_lookup(). If you require database specific conversions, then you will need to provide an implementation get_db_prep_* that uses the connection argument to resolve database-specific values.

    Stateful template tags

    Template tags that store rendering state on their Node subclass have always been vulnerable to thread-safety and other issues; as of Django 1.2, however, they may also cause problems when used with the new .

    All of the built-in Django template tags are safe to use with the cached loader, but if you’re using custom template tags that come from third party packages, or from your own code, you should ensure that the Node implementation for each tag is thread-safe. For more information, see template tag thread safety considerations.

    You may also need to update your templates if you were relying on the implementation of Django’s template tags not being thread safe. The tag is the most likely to be affected in this way, especially when used in conjunction with the include tag. Consider the following template fragment:

    1. {% for object in object_list %}
    2. {% include "subtemplate.html" %}
    3. {% endfor %}

    with a subtemplate.html that reads:

    1. {% cycle 'even' 'odd' %}

    Using the non-thread-safe, pre-Django 1.2 renderer, this would output:

    1. even odd even odd ...

    Using the thread-safe Django 1.2 renderer, you will instead get:

    1. even even even even ...

    This is because each rendering of the tag is an independent rendering. When the cycle tag was not thread safe, the state of the tag would leak between multiple renderings of the same include. Now that the tag is thread safe, this leakage no longer occurs.

    user_passes_test, login_required and permission_required

    django.contrib.auth.decorators provides the decorators login_required, permission_required and user_passes_test. Previously it was possible to use these decorators both on functions (where the first argument is ‘request’) and on methods (where the first argument is ‘self’, and the second argument is ‘request’). Unfortunately, flaws were discovered in the code supporting this: it only works in limited circumstances, and produces errors that are very difficult to debug when it does not work.

    For this reason, the ‘auto adapt’ behavior has been removed, and if you are using these decorators on methods, you will need to manually apply to convert the decorator to one that works with methods. For example, you would change code from this:

    1. class MyClass(object):
    2. @login_required
    3. def my_view(self, request):
    4. pass

    改成这个:

    1. from django.utils.decorators import method_decorator
    2. class MyClass(object):
    3. @method_decorator(login_required)
    4. def my_view(self, request):
    5. pass

    或者:

    For those of you who’ve been following the development trunk, this change also applies to other decorators introduced since 1.1, including csrf_protect, cache_control and anything created using decorator_from_middleware.

    tag changes

    Due to new features in the if template tag, it no longer accepts ‘and’, ‘or’ and ‘not’ as valid variable names. Previously, these strings could be used as variable names. Now, the keyword status is always enforced, and template code such as {% if not %} or {% if and %} will throw a TemplateSyntaxError. Also, in is a new keyword and so is not a valid variable name in this tag.

    LazyObject

    LazyObject is an undocumented-but-often-used utility class used for lazily wrapping other objects of unknown type.

    In Django 1.1 and earlier, it handled introspection in a non-standard way, depending on wrapped objects implementing a public method named get_all_members(). Since this could easily lead to name clashes, it has been changed to use the standard Python introspection method, involving __members__ and __dir__().

    If you used LazyObject in your own code and implemented the get_all_members() method for wrapped objects, you’ll need to make a couple of changes:

    First, if your class does not have special requirements for introspection (i.e., you have not implemented __getattr__() or other methods that allow for attributes not discoverable by normal mechanisms), you can simply remove the get_all_members() method. The default implementation on LazyObject will do the right thing.

    If you have more complex requirements for introspection, first rename the get_all_members() method to __dir__(). This is the standard introspection method for Python 2.6 and above. If you require support for Python versions earlier than 2.6, add the following code to the class:

    1. __members__ = property(lambda self: self.__dir__())

    __dict__ on model instances

    Historically, the __dict__ attribute of a model instance has only contained attributes corresponding to the fields on a model.

    In order to support multiple database configurations, Django 1.2 has added a _state attribute to object instances. This attribute will appear in __dict__ for a model instance. If your code relies on iterating over __dict__ to obtain a list of fields, you must now be prepared to handle or filter out the _state attribute.

    Test runner exit status code

    The exit status code of the test runners (tests/runtests.py and python manage.py test) no longer represents the number of failed tests, because a failure of 256 or more tests resulted in a wrong exit status code. The exit status code for the test runner is now 0 for success (no failing tests) and 1 for any number of test failures. If needed, the number of test failures can be found at the end of the test runner’s output.

    To fix bugs with cookies in Internet Explorer, Safari, and possibly other browsers, our encoding of cookie values was changed so that the comma and semicolon are treated as non-safe characters, and are therefore encoded as \054 and \073 respectively. This could produce backwards incompatibilities, especially if you are storing comma or semi-colon in cookies and have JavaScript code that parses and manipulates cookie values client-side.

    Much of the validation work for ModelForms has been moved down to the model level. As a result, the first time you call ModelForm.is_valid(), access ModelForm.errors or otherwise trigger form validation, your model will be cleaned in-place. This conversion used to happen when the model was saved. If you need an unmodified instance of your model, you should pass a copy to the ModelForm constructor.

    BooleanField on MySQL

    In previous versions of Django, a model’s BooleanField under MySQL would return its value as either 1 or 0, instead of True or False; for most people this wasn’t a problem because bool is a subclass of int in Python. In Django 1.2, however, BooleanField on MySQL correctly returns a real bool. The only time this should ever be an issue is if you were expecting the repr of a BooleanField to print 1 or 0.

    Changes to the interpretation of max_num in FormSets

    As part of enhancements made to the handling of FormSets, the default value and interpretation of the max_num parameter to the and django.forms.models.modelformset_factory() functions has changed slightly. This change also affects the way the argument is used for inline admin objects.

    Previously, the default value for max_num was 0 (zero). FormSets then used the boolean value of max_num to determine if a limit was to be imposed on the number of generated forms. The default value of 0 meant that there was no default limit on the number of forms in a FormSet.

    Starting with 1.2, the default value for max_num has been changed to None, and FormSets will differentiate between a value of None and a value of 0. A value of None indicates that no limit on the number of forms is to be imposed; a value of 0 indicates that a maximum of 0 forms should be imposed. This doesn’t necessarily mean that no forms will be displayed — see the ModelFormSet documentation for more details.

    If you were manually specifying a value of 0 for max_num, you will need to update your FormSet and/or admin definitions.

    参见

    email_re

    An undocumented regular expression for validating email addresses has been moved from django.form.fields to django.core.validators. You will need to update your imports if you are using it.

    Finally, Django 1.2 deprecates some features from earlier releases. These features are still supported, but will be gradually phased out over the next few release cycles.

    Code taking advantage of any of the features below will raise a PendingDeprecationWarning in Django 1.2. This warning will be silent by default, but may be turned on using Python’s module, or by running Python with a -Wd or -Wall flag.

    In Django 1.3, these warnings will become a DeprecationWarning, which is not silent. In Django 1.4 support for these features will be removed entirely.

    参见

    For more details, see the documentation Django’s release process and our .`

    Specifying databases

    Any existing Django settings file will continue to work as expected until Django 1.4. Until then, old-style database settings will be automatically translated to the new-style format.

    In the old-style (pre 1.2) format, you had a number of DATABASE_ settings in your settings file. For example:

    1. DATABASE_NAME = 'test_db'
    2. DATABASE_ENGINE = 'postgresql_psycopg2'
    3. DATABASE_USER = 'myusername'
    4. DATABASE_PASSWORD = 's3krit'

    These settings are now in a dictionary named . Each item in the dictionary corresponds to a single database connection, with the name 'default' describing the default database connection. The setting names have also been shortened. The previous sample settings would now look like this:

    1. DATABASES = {
    2. 'default': {
    3. 'NAME': 'test_db',
    4. 'ENGINE': 'django.db.backends.postgresql_psycopg2',
    5. 'USER': 'myusername',
    6. 'PASSWORD': 's3krit',
    7. }

    This affects the following settings:

    These changes are also required if you have manually created a database connection using DatabaseWrapper() from your database backend of choice.

    In addition to the change in structure, Django 1.2 removes the special handling for the built-in database backends. All database backends must now be specified by a fully qualified module name (i.e., django.db.backends.postgresql_psycopg2, rather than just postgresql_psycopg2).

    postgresql database backend

    The psycopg1 library has not been updated since October 2005. As a result, the postgresql database backend, which uses this library, has been deprecated.

    If you are currently using the postgresql backend, you should migrate to using the postgresql_psycopg2 backend. To update your code, install the psycopg2 library and change the setting to use django.db.backends.postgresql_psycopg2.

    CSRF response-rewriting middleware

    CsrfResponseMiddleware, the middleware that automatically inserted CSRF tokens into POST forms in outgoing pages, has been deprecated in favor of a template tag method (see above), and will be removed completely in Django 1.4. CsrfMiddleware, which includes the functionality of and CsrfViewMiddleware, has likewise been deprecated.

    Also, the CSRF module has moved from contrib to core, and the old imports are deprecated, as described in the upgrading notes.

    Documentation removed

    The upgrade notes have been removed in current Django docs. Please refer to the docs for Django 1.3 or older to find these instructions.

    SMTPConnection

    The SMTPConnection class has been deprecated in favor of a generic email backend API. Old code that explicitly instantiated an instance of an SMTPConnection:

    1. from django.core.mail import SMTPConnection
    2. connection = SMTPConnection()
    3. messages = get_notification_email()
    4. connection.send_messages(messages)

    …should now call get_connection() to instantiate a generic email connection:

    1. from django.core.mail import get_connection
    2. connection = get_connection()
    3. messages = get_notification_email()
    4. connection.send_messages(messages)

    Depending on the value of the setting, this may not return an SMTP connection. If you explicitly require an SMTP connection with which to send email, you can explicitly request an SMTP connection:

    1. from django.core.mail import get_connection
    2. connection = get_connection('django.core.mail.backends.smtp.EmailBackend')
    3. messages = get_notification_email()
    4. connection.send_messages(messages)

    If your call to construct an instance of SMTPConnection required additional arguments, those arguments can be passed to the get_connection() call:

    1. connection = get_connection('django.core.mail.backends.smtp.EmailBackend', hostname='localhost', port=1234)

    User Messages API

    The API for storing messages in the user Message model (via user.message_set.create) is now deprecated and will be removed in Django 1.4 according to the standard release process.

    To upgrade your code, you need to replace any instances of this:

    1. user.message_set.create('a message')

    …with the following:

    1. from django.contrib import messages
    2. messages.add_message(request, messages.INFO, 'a message')

    Additionally, if you make use of the method, you need to replace the following:

    1. for message in user.get_and_delete_messages():
    2. ...

    …with:

    For more information, see the full . You should begin to update your code to use the new API immediately.

    Date format helper functions

    django.utils.translation.get_date_formats() and django.utils.translation.get_partial_date_formats() have been deprecated in favor of the appropriate calls to django.utils.formats.get_format(), which is locale-aware when USE_L10N is set to True, and falls back to default settings if set to False.

    To get the different date formats, instead of writing this:

    1. from django.utils.translation import get_date_formats
    2. date_format, datetime_format, time_format = get_date_formats()

    …use:

    1. from django.utils import formats
    2. date_format = formats.get_format('DATE_FORMAT')
    3. datetime_format = formats.get_format('DATETIME_FORMAT')
    4. time_format = formats.get_format('TIME_FORMAT')

    Or, when directly formatting a date value:

    1. from django.utils import formats
    2. value_formatted = formats.date_format(value, 'DATETIME_FORMAT')

    The same applies to the globals found in django.forms.fields:

    • DEFAULT_DATE_INPUT_FORMATS
    • DEFAULT_TIME_INPUT_FORMATS
    • DEFAULT_DATETIME_INPUT_FORMATS

    Use django.utils.formats.get_format() to get the appropriate formats.

    Function-based test runners

    Django 1.2 changes the test runner tools to use a class-based approach. Old style function-based test runners will still work, but should be updated to use the new class-based runners.

    Feed in django.contrib.syndication.feeds

    The django.contrib.syndication.feeds.Feed class has been replaced by the django.contrib.syndication.views.Feed class. The old feeds.Feed class is deprecated, and will be removed in Django 1.4.

    The new class has an almost identical API, but allows instances to be used as views. For example, consider the use of the old framework in the following :

    1. from django.conf.urls.defaults import *
    2. from myproject.feeds import LatestEntries, LatestEntriesByCategory
    3. feeds = {
    4. 'latest': LatestEntries,
    5. 'categories': LatestEntriesByCategory,
    6. }
    7. urlpatterns = patterns('',
    8. # ...
    9. (r'^feeds/(?P<url>.*)/$', 'django.contrib.syndication.views.feed',
    10. {'feed_dict': feeds}),
    11. # ...
    12. )

    Using the new Feed class, these feeds can be deployed directly as views:

    1. from django.conf.urls.defaults import *
    2. from myproject.feeds import LatestEntries, LatestEntriesByCategory
    3. urlpatterns = patterns('',
    4. # ...
    5. (r'^feeds/latest/$', LatestEntries()),
    6. (r'^feeds/categories/(?P<category_id>\d+)/$', LatestEntriesByCategory()),
    7. # ...
    8. )

    If you currently use the feed() view, the LatestEntries class would often not need to be modified apart from subclassing the new Feed class. The exception is if Django was automatically working out the name of the template to use to render the feed’s description and title elements (if you were not specifying the title_template and description_template attributes). You should ensure that you always specify title_template and description_template attributes, or provide item_title() and item_description() methods.

    However, LatestEntriesByCategory uses the get_object() method with the bits argument to specify a specific category to show. In the new class, get_object() method takes a request and arguments from the URL, so it would look like this:

    1. from django.contrib.syndication.views import Feed
    2. from django.shortcuts import get_object_or_404
    3. from myproject.models import Category
    4. class LatestEntriesByCategory(Feed):
    5. def get_object(self, request, category_id):
    6. return get_object_or_404(Category, id=category_id)
    7. # ...

    Additionally, the get_feed() method on Feed classes now take different arguments, which may impact you if you use the Feed classes directly. Instead of just taking an optional url argument, it now takes two arguments: the object returned by its own get_object() method, and the current request object.

    To take into account Feed classes not being initialized for each request, the __init__() method now takes no arguments by default. Previously it would have taken the slug from the URL and the request object.

    In accordance with RSS best practices, RSS feeds will now include an atom:link element. You may need to update your tests to take this into account.

    For more information, see the full .

    Technical message IDs

    Up to version 1.1 Django used technical message IDs to provide localizers the possibility to translate date and time formats. They were translatable that could be recognized because they were all upper case (for example DATETIME_FORMAT, , TIME_FORMAT). They have been deprecated in favor of the new infrastructure that allows localizers to specify that information in a formats.py file in the corresponding django/conf/locale/<locale name>/ directory.

    GeoDjango

    To allow support for multiple databases, the GeoDjango database internals were changed substantially. The largest backwards-incompatible change is that the module django.contrib.gis.db.backend was renamed to , where the full-fledged spatial database backends now exist. The following sections provide information on the most-popular APIs that were affected by these changes.

    SpatialBackend

    Prior to the creation of the separate spatial backends, the django.contrib.gis.db.backend.SpatialBackend object was provided as an abstraction to introspect on the capabilities of the spatial database. All of the attributes and routines provided by SpatialBackend are now a part of the ops attribute of the database backend.

    The old module django.contrib.gis.db.backend is still provided for backwards-compatibility access to a SpatialBackend object, which is just an alias to the ops module of the default spatial database connection.

    Users that were relying on undocumented modules and objects within django.contrib.gis.db.backend, rather the abstractions provided by SpatialBackend, are required to modify their code. For example, the following import which would work in 1.1 and below:

    1. from django.contrib.gis.db.backend.postgis import PostGISAdaptor

    Would need to be changed:

    1. from django.db import connection
    2. PostGISAdaptor = connection.ops.Adapter

    SpatialRefSys and GeometryColumns models

    In previous versions of GeoDjango, had SpatialRefSys and GeometryColumns models for querying the OGC spatial metadata tables spatial_ref_sys and geometry_columns, respectively.

    While these aliases are still provided, they are only for the default database connection and exist only if the default connection is using a supported spatial database backend.

    注解

    Because the table structure of the OGC spatial metadata tables differs across spatial databases, the SpatialRefSys and GeometryColumns models can no longer be associated with the gis application name. Thus, no models will be returned when using the get_models method in the following example:

    1. >>> from django.db.models import get_app, get_models
    2. >>> get_models(get_app('gis'))
    3. []

    To get the correct SpatialRefSys and GeometryColumns for your spatial database use the methods provided by the spatial backend:

    1. >>> from django.db import connections
    2. >>> SpatialRefSys = connections['my_spatialite'].ops.spatial_ref_sys()
    3. >>> GeometryColumns = connections['my_postgis'].ops.geometry_columns()

    注解

    When using the models returned from the spatial_ref_sys() and geometry_columns() method, you’ll still need to use the correct database alias when querying on the non-default connection. In other words, to ensure that the models in the example above use the correct database:

    Language code no

    The currently used language code for Norwegian Bokmål is being replaced by the more common language code nb.