.. _security_chapter:
Security
========
:mod:`repoze.bfg` provides an optional declarative authorization
system that prevents a :term:`view` from being invoked when the user
represented by credentials in the :term:`request` does not have an
appropriate level of access with respect to a specific
:term:`context`.
Authorization is enabled by modifying your :term:`application
registry` (aka ``configure.zcml``).
Enabling an Authorization Policy
--------------------------------
By default, :mod:`repoze.bfg` enables no authorization policy. All
views are accessible by completely anonymous users.
However, if you modify the :term:`application registry` file in your
application's package (usually named ``configure.zcml``), you can
enable an authorization policy.
You must also enable a a :term:`authentication policy` in order to
enable the an authorization policy (this is because authorization, in
general, depends upon authentication).
For example, to enable a policy which compares the value of an "auth
ticket" cookie passed in the request's environment which contains a
reference to a single :term:`principal` against the principals present
in any :term:`ACL` found in model data when attempting to call some
:term:`view`, modify your ``configure.zcml`` to look something like
this:
.. code-block:: xml
:linenos:
"Under the hood", these statements cause an instance of the class
``repoze.bfg.authentication.AuthTktAuthenticationPolicy`` to be
injected as the :term:`authentication policy` used by this application
and an instance of the class
``repoze.bfg.authorization.ACLAuthorizationPolicy`` to be injected as
the :term:`authorization policy` used by this application.
:mod:`repoze.bfg` ships with a few pre-chewed authentication and
authorization policies that should prove useful. See
:ref:`authentication_policies_directives_section` and
:ref:`authorization_policies_directives_section` for more information.
It is also possible to construct your own custom authentication policy
or authorization policy: see :ref:`creating_an_authentication_policy`
and :ref:`creating_an_authorization_policy`.
Protecting Views with Permissions
---------------------------------
You declaratively protect a particular view using a :term:`permission`
name via the ``configure.zcml`` application registry. For example,
the following declaration protects the view named ``add_entry.html``
when invoked against a ``Blog`` context with the ``add`` permission:
.. code-block:: xml
:linenos:
The equivalent view registration including the 'add' permission name
may be performed via the ``bfg_view`` decorator within the "views"
module of your project's package
.. code-block:: python
:linenos:
from repoze.bfg.view import bfg_view
from models import Blog
@bfg_view(for_=Blog, name='add_entry.html', permission='add')
def blog_entry_add_view(context, request):
""" Add blog entry code goes here """
pass
If an authorization policy is in place when this view is found during
normal application operations, the user will need to possess the
``add`` permission against the context to be able to invoke the
``blog_entry_add_view`` view.
Permission names are usually just strings. They hold no special
significance to the system. You can name permissions whatever you
like.
.. _assigning_acls:
Assigning ACLs to your Model Objects
------------------------------------
When :mod:`repoze.bfg` determines whether a user possesses a
particular permission in a :term:`context`, it examines the
:term:`ACL` associated with the context. An ACL is associated with a
context by virtue of the ``__acl__`` attribute of the model object
representing the context. This attribute can be defined on the model
*instance* (if you need instance-level security), or it can be defined
on the model *class* (if you just need type-level security).
For example, an ACL might be attached to model for a blog via its
class:
.. code-block:: python
:linenos:
from repoze.bfg.security import Everyone
from repoze.bfg.security import Allow
class Blog(object):
__acl__ = [
(Allow, Everyone, 'view'),
(Allow, 'group:editors', 'add'),
(Allow, 'group:editors', 'edit'),
]
Or, if your models are persistent, an ACL might be specified via the
``__acl__`` attribute of an *instance* of a model:
.. code-block:: python
:linenos:
from repoze.bfg.security import Everyone
from repoze.bfg.security import Allow
class Blog(object):
pass
blog = Blog()
blog.__acl__ = [
(Allow, Everyone, 'view'),
(Allow, 'group:editors', 'add'),
(Allow, 'group:editors', 'edit'),
]
Whether an ACL is attached to a model's class or an instance of the
model itself, the effect is the same. It is useful to decorate
individual model instances with an ACL (as opposed to just decorating
their class) in applications such as "CMS" systems where fine-grained
access is required on an object-by-object basis.
Elements of an ACL
------------------
Here's an example ACL:
.. code-block:: python
:linenos:
from repoze.bfg.security import Everyone
from repoze.bfg.security import Allow
__acl__ = [
(Allow, Everyone, 'view'),
(Allow, 'group:editors', 'add'),
(Allow, 'group:editors', 'edit'),
]
The example ACL indicates that the ``Everyone`` principal (a special
system-defined principal indicating, literally, everyone) is allowed
to view the blog, the ``group:editors`` principal is allowed to add to
and edit the blog.
The third argument in an ACE can also be a sequence of permission
names instead of a single permission name. So instead of creating
multiple ACEs representing a number of different permission grants to
a single ``group:editors`` group, we can collapse this into a single
ACE, as below.
.. code-block:: python
:linenos:
from repoze.bfg.security import Everyone
from repoze.bfg.security import Allow
__acl__ = [
(Allow, Everyone, 'view'),
(Allow, 'group:editors', ('add', 'edit')),
]
A principal is usually a user id, however it also may be a group id if
your authentication system provides group information and the
effective :term:`authentication policy` policy is written to respect
group information. For example, the ``RepozeWho1AuthenicationPolicy``
enabled by the ``repozewho1authenticationpolicy`` ZCML directive
respects group information if you configure it with a ``callback``.
See :ref:`authentication_policies_directives_section` for more
information about the ``callback`` attribute.
Each tuple within an ACL structure is known as a :term:`ACE`, which
stands for "access control entry". For example, in the above ACL,
``(Allow, Everyone, 'view')`` is an ACE. Each ACE in an ACL is
processed by an authorization policy *in the order dictated by the
ACL*. So if you have an ACL like this:
.. code-block:: python
:linenos:
from repoze.bfg.security import Everyone
from repoze.bfg.security import Allow
from repoze.bfg.security import Deny
__acl__ = [
(Allow, Everyone, 'view'),
(Deny, Everyone, 'view'),
]
The authorization policy will *allow* everyone the view permission,
even though later in the ACL you have an ACE that denies everyone the
view permission. On the other hand, if you have an ACL like this:
.. code-block:: python
:linenos:
from repoze.bfg.security import Everyone
from repoze.bfg.security import Allow
from repoze.bfg.security import Deny
__acl__ = [
(Deny, Everyone, 'view'),
(Allow, Everyone, 'view'),
]
The authorization policy will deny Everyone the view permission, even
though later in the ACL is an ACE that allows everyone.
Special Principal Names
-----------------------
Special principal names exist in the :mod:`repoze.bfg.security`
module. They can be imported for use in your own code to populate
ACLs, e.g. ``from repoze.bfg.security import Everyone``.
``Everyone``
Literally, everyone, no matter what. This object is actually a
string "under the hood" (``system.Everyone``). Every user "is" the
principal named Everyone during every request, even if a security
policy is not in use.
``Authenticated``
Any user with credentials as determined by the current security
policy. You might think of it as any user that is "logged in".
This object is actually a string "under the hood"
(``system.Authenticated``).
Special Permissions
-------------------
Special permission names exist in the :mod:`repoze.bfg.security`
module. These can be imported for use in ACLs.
.. _all_permissions:
``ALL_PERMISSIONS``
An object representing, literally, *all* permissions. Useful in an
ACL like so: ``(Allow, 'fred', ALL_PERMISSIONS)``. The
``ALL_PERMISSIONS`` object is actually a stand-in object that has a
``__contains__`` method that always returns True, which, for all
known authorization policies, has the effect of indicating that a
given principal "has" any permission asked for by the system.
Special ACEs
------------
A convenience :term:`ACE` is defined within the
:mod:`repoze.bfg.security` module named ``DENY_ALL``. It equals the
following:
.. code-block:: python
(Deny, Everyone, ALL_PERMISSIONS)
This ACE is often used as the *last* ACE of an ACL to explicitly cause
inheriting authorization policies to "stop looking up the traversal
tree" (effectively breaking any inheritance). For example, an ACL
which allows *only* ``fred`` the view permission in a particular
traversal context despite what inherited ACLs may say when the default
authorization policy is in effect might look like so:
.. code-block:: python
:linenos:
from repoze.bfg.security import Allow
from repoze.bfg.security import DENY_ALL
__acl__ = [ (Allow, 'fred', 'view'), DENY_ALL ]
ACL Inheritance
---------------
While the default :term:`authorization policy` is in place, if a model
object does not have an ACL when it is the context, its *parent* is
consulted for an ACL. If that object does not have an ACL, *its*
parent is consulted for an ACL, ad infinitum, until we've reached the
root and there are no more parents left.
Location-Awareness
------------------
In order to allow the security machinery to perform ACL inheritance,
model objects must provide *location-awareness*. Providing
location-awareness means two things: the root object in the graph must
have a ``_name__`` attribute and a ``__parent__`` attribute.
.. code-block:: python
:linenos:
class Blog(object):
__name__ = ''
__parent__ = None
An object with a ``__parent__`` attribute and a ``__name__`` attribute
is said to be *location-aware*. Location-aware objects define an
``__parent__`` attribute which points at their parent object. The
root object's ``__parent__`` is ``None``.
See :ref:`location_module` for documentations of functions which use
location-awareness. See also :ref:`location_aware`.
Changing the Forbidden View
---------------------------
When :mod:`repoze.bfg` denies a view invocation due to an
authorization denial, the special ``forbidden`` view is invoked. "Out
of the box", this forbidden view is very plain. See
:ref:`changing_the_forbidden_view` within :ref:`hooks_chapter` for
instructions on how to create a custom forbidden view and arrange for
it to be called when view authorization is denied.
.. _debug_authorization_section:
Debugging View Authorization Failures
-------------------------------------
If your application in your judgment is allowing or denying view
access inappropriately, start your application under a shell using the
``BFG_DEBUG_AUTHORIZATION`` environment variable set to ``1``. For
example::
$ BFG_DEBUG_AUTHORIZATION=1 bin/paster serve myproject.ini
When any authorization takes place during a top-level view rendering,
a message will be logged to the console (to stderr) about what ACE in
which ACL permitted or denied the authorization based on
authentication information.
This behavior can also be turned on in the application ``.ini`` file
by setting the ``debug_authorization`` key to ``true`` within the
application's configuration section, e.g.::
[app:main]
use = egg:MyProject#app
debug_authorization = true
With this debug flag turned on, the response sent to the browser will
also contain security debugging information in its body.
Debugging Imperative Authorization Failures
-------------------------------------------
The ``has_permission`` API (see :ref:`security_module`) is used to
check security within view functions imperatively. It returns
instances of objects that are effectively booleans. But these objects
are not raw ``True`` or ``False`` objects, and have information
attached to them about why the permission was allowed or denied. The
object will be one of ``ACLAllowed``, ``ACLDenied``, ``Allowed``, and
``Denied``, documented in :ref:`security_module`. At very minimum
these objects will have a ``msg`` attribute, which is a string
indicating why permission was denied or allowed. Introspecting this
information in the debugger or via print statements when a
``has_permission`` fails is often useful.
.. _authentication_policies_directives_section:
Built-In Authentication Policy Directives
-----------------------------------------
:mod:`repoze.who` ships with a few "pre-chewed" authentication policy
implementations that you can make use of within your application.
``authtktauthenticationpolicy``
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
When this directive is used, authentication information is obtained
from an "auth ticket" cookie value, assumed to be set by a custom
login form.
An example of its usage, with all attributes fully expanded:
.. code-block:: xml
:linenos:
The ``secret`` is a string that will be used to encrypt the data
stored by the cookie. It is required and has no default.
The ``callback`` is a Python dotted name to a function passed the
string representing the userid stored in the cookie and the request as
positional arguments. The callback is expected to return None if the
user represented by the string doesn't exist or a sequence of group
identifiers (possibly empty) if the user does exist. If ``callback``
is None, the userid will be assumed to exist with no groups. It
defaults to ``None``.
The ``cookie_name`` is the name used for the cookie that contains the
user information. It defaults to ``repoze.bfg.auth_tkt``.
``secure`` is a boolean value. If it's set to "true", the cookie will
only be sent back by the browser over a secure (HTTPS) connection.
It defaults to "false".
``include_ip`` is a boolean value. If it's set to true, the
requesting IP address is made part of the authentication data in the
cookie; if the IP encoded in the cookie differs from the IP of the
requesting user agent, the cookie is considered invalid. It defaults
to "false".
``timeout`` is an integer value. It represents the maximum age in
seconds which the auth_tkt ticket will be considered valid. If
``timeout`` is specified, and ``reissue_time`` is also specified,
``reissue_time`` must be a smaller value than ``timeout``. It
defaults to ``None``, meaning that the ticket will be considered valid
forever.
``reissue_time`` is an integer value. If ``reissue_time`` is
specified, when we encounter a cookie that is older than the reissue
time (in seconds), but younger that the ``timeout``, a new cookie will
be issued. It defaults to ``None``, meaning that authentication
cookies are never reissued. A value of ``0`` means reissue a cookie
in the response to every request that requires authentication.
``max_age`` is the maximum age of the auth_tkt *cookie*, in seconds.
This differs from ``timeout`` inasmuch as ``timeout`` represents the
lifetime of the ticket contained in the cookie, while this value
represents the lifetime of the cookie itself. When this value is set,
the cookie's ``Max-Age`` and ``Expires`` settings will be set,
allowing the auth_tkt cookie to last between browser sessions. It is
typically nonsensical to set this to a value that is lower than
``timeout`` or ``reissue_time``, although it is not explicitly
prevented. It defaults to ``None``, meaning (on all major browser
platforms) that auth_tkt cookies will last for the lifetime of the
user's browser session.
``remoteuserauthenticationpolicy``
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
When this directive is used, authentication information is obtained
from a ``REMOTE_USER`` key in the WSGI environment, assumed to
be set by a WSGI server or an upstream middleware component.
An example of its usage, with all attributes fully expanded:
.. code-block:: xml
:linenos:
The ``environ_key`` is the name that will be used to obtain the remote
user value from the WSGI environment. It defaults to ``REMOTE_USER``.
The ``callback`` is a Python dotted name to a function passed the
string representing the remote user and the request as positional
arguments. The callback is expected to return None if the user
represented by the string doesn't exist or a sequence of group
identifiers (possibly empty) if the user does exist. If ``callback``
is None, the userid will be assumed to exist with no groups. It
defaults to ``None``.
``repozewho1authenticationpolicy``
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
When this directive is used, authentication information is obtained
from a ``repoze.who.identity`` key in the WSGI environment, assumed to
be set by :term:`repoze.who` middleware.
An example of its usage, with all attributes fully expanded:
.. code-block:: xml
:linenos:
The ``identifier_name`` controls the name used to look up the
:term:`repoze.who` "identifier" plugin within
``request.environ['repoze.who.plugins']`` which is used by this policy to
"remember" and "forget" credentials. It defaults to ``auth_tkt``.
The ``callback`` is a Python dotted name to a function passed the
repoze.who identity and the request as positional arguments. The
callback is expected to return None if the user represented by the
identity doesn't exist or a sequence of group identifiers (possibly
empty) if the user does exist. If ``callback`` is None, the userid
will be assumed to exist with no groups. It defaults to ``None``.
.. _authorization_policies_directives_section:
Built-In Authorization Policy Directives
----------------------------------------
``aclauthorizationpolicy``
When this directive is used, authorization information is obtained
from :term:`ACL` objects attached to model instances.
An example of its usage, with all attributes fully expanded:
.. code-block:: xml
:linenos:
In other words, it has no configuration attributes; its existence in a
``configure.zcml`` file enables it.
.. _creating_an_authentication_policy:
Creating Your Own Authentication Policy
---------------------------------------
:mod:`repoze.bfg` ships with a number of useful out-of-the-box
security policies (see
:ref:`authentication_policies_directives_section`). However, creating
your own authentication policy is often necessary when you want to
control the "horizontal and vertical" of how your users authenticate.
Doing so is matter of creating an instance of something that
implements the following interface:
.. code-block:: python
class AuthenticationPolicy(object):
""" An object representing a BFG authentication policy. """
def authenticated_userid(self, request):
""" Return the authenticated userid or ``None`` if no
authenticated userid can be found. """
def effective_principals(self, request):
""" Return a sequence representing the effective principals
including the userid and any groups belonged to by the current
user, including 'system' groups such as Everyone and
Authenticated. """
def remember(self, request, principal, **kw):
""" Return a set of headers suitable for 'remembering' the
principal named ``principal`` when set in a response. An
individual authentication policy and its consumers can decide
on the composition and meaning of **kw. """
def forget(self, request):
""" Return a set of headers suitable for 'forgetting' the
current user on subsequent requests. """
You will then need to create a ZCML directive which allows you to use
the authentication policy within a ZCML file. See the
``repoze.bfg.zcml`` module in the :mod:`repoze.bfg` source code for
examples of how to create a directive. Authorization policy ZCML
directives should use the ZCML discriminator value
"authentication_policy" in their actions to allow for conflict
detection.
.. _creating_an_authorization_policy:
Creating Your Own Authorization Policy
--------------------------------------
An authentication policy the policy that allows or denies access after
a user has been authenticated. By default, :mod:`repoze.bfg` will use
the ``repoze.bfg.authorization.ACLAuthorizationPolicy`` if an
authentication policy is activated and an authorization policy isn't
otherwise specified. In some cases, it's useful to be able to use a
different authentication policy than the
``repoze.bfg.authorization.ACLAuthorizationPolicy``. For example, it
might be desirable to construct an alternate authorization policy
which allows the application to use an authorization mechanism that
does not involve :term:`ACL` objects.
:mod:`repoze.bfg` ships with only its single default
``ACLAuthorizationPolicy``, so you'll need to create your own if you'd
like to use a different one. Creating and using your own
authorization policy is a matter of creating an instance of an object
that implements the following interface:
.. code-block:: python
class IAuthorizationPolicy(object):
""" A adapter on context """
def permits(self, context, principals, permission):
""" Return True if any of the principals is allowed the
permission in the current context, else return False """
def principals_allowed_by_permission(self, context, permission):
""" Return a set of principal identifiers allowed by the
permission """
You will then need to create a ZCML directive which allows you to use
the authorization policy within a ZCML file. See the
``repoze.bfg.zcml`` module in the :mod:`repoze.bfg` source for
examples of how to create a directive. Authorization policy ZCML
directives should use the ZCML discriminator value
"authorization_policy" in their actions to allow for conflict
detection.