Security¶
Pyramid provides an optional, declarative security system. The system determines the identity of the current user (authentication) and whether or not the user has access to certain resources (authorization).
The Pyramid security system can prevent a view from being invoked based on the security policy. Before a view is invoked, the authorization system can use the credentials in the request along with the context resource to determine if access will be allowed. Here's how it works at a high level:
A user may or may not have previously visited the application and supplied authentication credentials, including a userid. If so, the application may have called
pyramid.security.remember()
to remember these.A request is generated when a user visits the application.
Based on the request, a context resource is located through resource location. A context is located differently depending on whether the application uses traversal or URL dispatch, but a context is ultimately found in either case. See the URL Dispatch chapter for more information.
A view callable is located by view lookup using the context as well as other attributes of the request.
If a security policy is in effect and the view configuration associated with the view callable that was found has a permission associated with it, the policy is passed request, the context, and the permission associated with the view; it will allow or deny access.
If the security policy allows access, the view callable is invoked.
If the security policy denies access, the view callable is not invoked. Instead the forbidden view is invoked.
The security system is enabled by modifying your application to include a security policy. Pyramid comes with a variety of helpers to assist in the creation of this policy.
Writing a Security Policy¶
Pyramid does not enable any security policy by default. All views are accessible by completely anonymous users. In order to begin protecting views from execution based on security settings, you need to write a security policy.
Security policies are simple classes implementing
pyramid.interfaces.ISecurityPolicy
.
A simple security policy might look like the following:
1from pyramid.security import Allowed, Denied
2
3class SessionSecurityPolicy:
4 def identity(self, request):
5 """ Return app-specific user object. """
6 userid = request.session.get('userid')
7 if userid is None:
8 return None
9 return load_identity_from_db(request, userid)
10
11 def authenticated_userid(self, request):
12 """ Return a string ID for the user. """
13 identity = self.identity(request)
14 if identity is None:
15 return None
16 return string(identity.id)
17
18 def permits(self, request, context, permission):
19 """ Allow access to everything if signed in. """
20 identity = self.identity(request)
21 if identity is not None:
22 return Allowed('User is signed in.')
23 else:
24 return Denied('User is not signed in.')
25
26 def remember(request, userid, **kw):
27 request.session['userid'] = userid
28 return []
29
30 def forget(request, **kw):
31 del request.session['userid']
32 return []
Use the set_security_policy()
method of
the Configurator
to enforce the security policy on
your application.
参考
For more information on implementing the permits
method, see
Allowing and Denying Access With a Security Policy.
Writing a Security Policy Using Helpers¶
To assist in writing common security policies, Pyramid provides several
helpers. The following authentication helpers assist with implementing
identity
, remember
, and forget
.
Use Case |
Helper |
---|---|
Store the userid with an "auth ticket" cookie. |
|
Retrieve user credentials using HTTP Basic Auth. |
Use |
Retrieve the userid
from |
|
For example, our above security policy can leverage these helpers like so:
1from pyramid.security import Allowed, Denied
2from pyramid.authentication import SessionAuthenticationHelper
3
4class SessionSecurityPolicy:
5 def __init__(self):
6 self.helper = SessionAuthenticationHelper()
7
8 def identity(self, request):
9 """ Return app-specific user object. """
10 userid = self.helper.authenticated_userid(request)
11 if userid is None:
12 return None
13 return load_identity_from_db(request, userid)
14
15 def authenticated_userid(self, request):
16 """ Return a string ID for the user. """
17 identity = self.identity(request)
18 if identity is None:
19 return None
20 return str(identity.id)
21
22 def permits(self, request, context, permission):
23 """ Allow access to everything if signed in. """
24 identity = self.identity(request)
25 if identity is not None:
26 return Allowed('User is signed in.')
27 else:
28 return Denied('User is not signed in.')
29
30 def remember(request, userid, **kw):
31 return self.helper.remember(request, userid, **kw)
32
33 def forget(request, **kw):
34 return self.helper.forget(request, **kw)
Helpers are intended to be used with application-specific code. Notice how the
above code takes the userid from the helper and uses it to load the
identity from the database. authenticated_userid
pulls the
userid from the identity in order to guarantee that the user ID
stored in the session exists in the database ("authenticated").
Protecting Views with Permissions¶
To protect a view callable from invocation based on a user's security settings when a particular type of resource becomes the context, you must pass a permission to view configuration. Permissions are usually just strings, and they have no required composition: you can name permissions whatever you like.
For example, the following view declaration protects the view named
add_entry.html
when the context resource is of type Blog
with the
add
permission using the pyramid.config.Configurator.add_view()
API:
1# config is an instance of pyramid.config.Configurator
2
3config.add_view('mypackage.views.blog_entry_add_view',
4 name='add_entry.html',
5 context='mypackage.resources.Blog',
6 permission='add')
The equivalent view registration including the add
permission name may be
performed via the @view_config
decorator:
1from pyramid.view import view_config
2from resources import Blog
3
4@view_config(context=Blog, name='add_entry.html', permission='add')
5def blog_entry_add_view(request):
6 """ Add blog entry code goes here """
7 pass
As a result of any of these various view configuration statements, if an
security policy is in place when the view callable is found during normal
application operations, the security policy will be queried to see if the
requesting user is allowed the add
permission within the current
context. If the policy allows access, blog_entry_add_view
will be
invoked. If not, the Forbidden view will be invoked.
Allowing and Denying Access With a Security Policy¶
To determine whether access is allowed to a view with an attached permission,
Pyramid calls the permits
method of the security policy. permits
should return an instance of pyramid.security.Allowed
or
pyramid.security.Denied
. Both classes accept a string as an argument,
which should detail why access was allowed or denied.
A simple permits
implementation that grants access based on a user role
might look like so:
1from pyramid.security import Allowed, Denied
2
3class SecurityPolicy:
4 def permits(self, request, context, permission):
5 identity = self.identity(request)
6
7 if identity is None:
8 return Denied('User is not signed in.')
9 if identity.role == 'admin':
10 allowed = ['read', 'write', 'delete']
11 elif identity.role == 'editor':
12 allowed = ['read', 'write']
13 else:
14 allowed = ['read']
15
16 if permission in allowed:
17 return Allowed(
18 'Access granted for user %s with role %s.',
19 identity,
20 identity.role,
21 )
22 else:
23 return Denied(
24 'Access denied for user %s with role %s.',
25 identity,
26 identity.role,
27 )
Setting a Default Permission¶
If a permission is not supplied to a view configuration, the registered view will always be executable by entirely anonymous users: any security policy in effect is ignored.
In support of making it easier to configure applications which are "secure by
default", Pyramid allows you to configure a default permission. If
supplied, the default permission is used as the permission string to all view
registrations which don't otherwise name a permission
argument.
The pyramid.config.Configurator.set_default_permission()
method supports
configuring a default permission for an application.
When a default permission is registered:
If a view configuration names an explicit
permission
, the default permission is ignored for that view registration, and the view-configuration-named permission is used.If a view configuration names the permission
pyramid.security.NO_PERMISSION_REQUIRED
, the default permission is ignored, and the view is registered without a permission (making it available to all callers regardless of their credentials).
警告
When you register a default permission, all views (even exception
view views) are protected by a permission. For all views which are truly
meant to be anonymously accessible, you will need to associate the view's
configuration with the pyramid.security.NO_PERMISSION_REQUIRED
permission.
Elements of an ACL¶
Here's an example ACL:
1from pyramid.authorization import Allow
2from pyramid.authorization import Everyone
3
4__acl__ = [
5 (Allow, Everyone, 'view'),
6 (Allow, 'group:editors', 'add'),
7 (Allow, 'group:editors', 'edit'),
8]
The example ACL indicates that the pyramid.authorization.Everyone
principal—a special system-defined principal indicating, literally, everyone—is
allowed to view the blog, and the group:editors
principal is allowed to add
to and edit the blog.
Each element of an ACL is an ACE, or access control entry. For example,
in the above code block, there are three ACEs: (Allow, Everyone, 'view')
,
(Allow, 'group:editors', 'add')
, and (Allow, 'group:editors', 'edit')
.
The first element of any ACE is either pyramid.authorization.Allow
, or
pyramid.authorization.Deny
, representing the action to take when the ACE
matches. The second element is a principal. The third argument is a
permission or sequence of permission names.
A principal is usually a user id, however it also may be a group id if your authentication system provides group information.
Each ACE in an ACL is processed by the ACL helper in the order dictated by the ACL. So if you have an ACL like this:
1from pyramid.authorization import Allow
2from pyramid.authorization import Deny
3from pyramid.authorization import Everyone
4
5__acl__ = [
6 (Allow, Everyone, 'view'),
7 (Deny, Everyone, 'view'),
8]
The ACL helper 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:
1from pyramid.authorization import Everyone
2from pyramid.authorization import Allow
3from pyramid.authorization import Deny
4
5__acl__ = [
6 (Deny, Everyone, 'view'),
7 (Allow, Everyone, 'view'),
8]
The ACL helper will deny everyone the view permission, even though later in the ACL, there is an ACE that allows everyone.
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.
1from pyramid.authorization import Allow
2from pyramid.authorization import Everyone
3
4__acl__ = [
5 (Allow, Everyone, 'view'),
6 (Allow, 'group:editors', ('add', 'edit')),
7]
Special Principal Names¶
Special principal names exist in the pyramid.authorization
module. They can
be imported for use in your own code to populate ACLs, e.g.,
pyramid.authorization.Everyone
.
pyramid.authorization.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.
pyramid.authorization.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 pyramid.authorization
module. These
can be imported for use in ACLs.
pyramid.authorization.ALL_PERMISSIONS
An object representing, literally, all permissions. Useful in an ACL like so:
(Allow, 'fred', ALL_PERMISSIONS)
. TheALL_PERMISSIONS
object is actually a stand-in object that has a__contains__
method that always returnsTrue
, 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 ACE is defined representing a deny to everyone of all
permissions in pyramid.authorization.DENY_ALL
. 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 for a
particular resource, despite what inherited ACLs may say, might look like so:
1from pyramid.authorization import Allow
2from pyramid.authorization import DENY_ALL
3
4__acl__ = [ (Allow, 'fred', 'view'), DENY_ALL ]
Under the hood, the pyramid.authorization.DENY_ALL
ACE equals the
following:
1from pyramid.authorization import ALL_PERMISSIONS
2__acl__ = [ (Deny, Everyone, ALL_PERMISSIONS) ]
ACL Inheritance and Location-Awareness¶
While the ACL helper is in place, if a resource 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.
In order to allow the security machinery to perform ACL inheritance, resource
objects must provide location-awareness. Providing location-awareness
means two things: the root object in the resource tree must have a __name__
attribute and a __parent__
attribute.
1class Blog(object):
2 __name__ = ''
3 __parent__ = None
An object with a __parent__
attribute and a __name__
attribute is said
to be location-aware. Location-aware objects define a __parent__
attribute which points at their parent object. The root object's
__parent__
is None
.
参考
See also pyramid.location for documentations of functions which use location-awareness.
参考
See also Location-Aware Resources.
Changing the Forbidden View¶
When Pyramid 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 Changing the Forbidden View within
Using Hooks for instructions on how to create a custom forbidden view
and arrange for it to be called when view authorization is denied.
Admonishment Against Secret-Sharing¶
A "secret" is required by various components of Pyramid. For example, the
helper below might be used for a security policy and uses a secret value
seekrit
:
helper = AuthTktCookieHelper('seekrit')
A session factory also requires a secret:
my_session_factory = SignedCookieSessionFactory('itsaseekreet')
It is tempting to use the same secret for multiple Pyramid subsystems. For
example, you might be tempted to use the value seekrit
as the secret for
both the helper and the session factory defined above. This is a bad idea,
because in both cases, these secrets are used to sign the payload of the data.
If you use the same secret for two different parts of your application for signing purposes, it may allow an attacker to get his chosen plaintext signed, which would allow the attacker to control the content of the payload. Re-using a secret across two different subsystems might drop the security of signing to zero. Keys should not be re-used across different contexts where an attacker has the possibility of providing a chosen plaintext.
Preventing Cross-Site Request Forgery Attacks¶
Cross-site request forgery attacks are a phenomenon whereby a user who is logged in to your website might inadvertently load a URL because it is linked from, or embedded in, an attacker's website. If the URL is one that may modify or delete data, the consequences can be dire.
You can avoid most of these attacks by issuing a unique token to the browser and then requiring that it be present in all potentially unsafe requests. Pyramid provides facilities to create and check CSRF tokens.
By default Pyramid comes with a session-based CSRF implementation
pyramid.csrf.SessionCSRFStoragePolicy
. To use it, you must first enable
a session factory as described in
Using the Default Session Factory or
Using Alternate Session Factories. Alternatively, you can use
a cookie-based implementation pyramid.csrf.CookieCSRFStoragePolicy
which gives
some additional flexibility as it does not require a session for each user.
You can also define your own implementation of
pyramid.interfaces.ICSRFStoragePolicy
and register it with the
pyramid.config.Configurator.set_csrf_storage_policy()
directive.
For example:
from pyramid.config import Configurator
config = Configurator()
config.set_csrf_storage_policy(MyCustomCSRFPolicy())
Using the csrf.get_csrf_token
Method¶
To get the current CSRF token, use the
pyramid.csrf.get_csrf_token
method.
from pyramid.csrf import get_csrf_token
token = get_csrf_token(request)
The get_csrf_token()
method accepts a single argument: the request. It
returns a CSRF token string. If get_csrf_token()
or new_csrf_token()
was invoked previously for this user, then the existing token will be returned.
If no CSRF token previously existed for this user, then a new token will be set
into the session and returned. The newly created token will be opaque and
randomized.
Using the get_csrf_token
global in templates¶
Templates have a get_csrf_token()
method inserted into their globals, which
allows you to get the current token without modifying the view code. This
method takes no arguments and returns a CSRF token string. You can use the
returned token as the value of a hidden field in a form that posts to a method
that requires elevated privileges, or supply it as a request header in AJAX
requests.
For example, include the CSRF token as a hidden field:
<form method="post" action="/myview">
<input type="hidden" name="csrf_token" value="${get_csrf_token()}">
<input type="submit" value="Delete Everything">
</form>
Or include it as a header in a jQuery AJAX request:
var csrfToken = "${get_csrf_token()}";
$.ajax({
type: "POST",
url: "/myview",
headers: { 'X-CSRF-Token': csrfToken }
}).done(function() {
alert("Deleted");
});
The handler for the URL that receives the request should then require that the correct CSRF token is supplied.
Using the csrf.new_csrf_token
Method¶
To explicitly create a new CSRF token, use the csrf.new_csrf_token()
method. This differs only from csrf.get_csrf_token()
inasmuch as it
clears any existing CSRF token, creates a new CSRF token, sets the token into
the user, and returns the token.
from pyramid.csrf import new_csrf_token
token = new_csrf_token(request)
注釈
It is not possible to force a new CSRF token from a template. If you want to regenerate your CSRF token then do it in the view code and return the new token as part of the context.
Checking CSRF Tokens Manually¶
In request handling code, you can check the presence and validity of a CSRF
token with pyramid.csrf.check_csrf_token()
. If the token is valid, it
will return True
, otherwise it will raise HTTPBadRequest
. Optionally,
you can specify raises=False
to have the check return False
instead of
raising an exception.
By default, it checks for a POST parameter named csrf_token
or a header
named X-CSRF-Token
.
from pyramid.csrf import check_csrf_token
def myview(request):
# Require CSRF Token
check_csrf_token(request)
# ...
Checking CSRF Tokens Automatically¶
バージョン 1.7 で追加.
Pyramid supports automatically checking CSRF tokens on requests with an
unsafe method as defined by RFC2616. Any other request may be checked manually.
This feature can be turned on globally for an application using the
pyramid.config.Configurator.set_default_csrf_options()
directive.
For example:
from pyramid.config import Configurator
config = Configurator()
config.set_default_csrf_options(require_csrf=True)
CSRF checking may be explicitly enabled or disabled on a per-view basis using
the require_csrf
view option. A value of True
or False
will
override the default set by set_default_csrf_options
. For example:
@view_config(route_name='hello', require_csrf=False)
def myview(request):
# ...
When CSRF checking is active, the token and header used to find the
supplied CSRF token will be csrf_token
and X-CSRF-Token
, respectively,
unless otherwise overridden by set_default_csrf_options
. The token is
checked against the value in request.POST
which is the submitted form body.
If this value is not present, then the header will be checked.
In addition to token based CSRF checks, if the request is using HTTPS then the
automatic CSRF checking will also check the referrer of the request to ensure
that it matches one of the trusted origins. By default the only trusted origin
is the current host, however additional origins may be configured by setting
pyramid.csrf_trusted_origins
to a list of domain names (and ports if they
are non-standard). If a host in the list of domains starts with a .
then
that will allow all subdomains as well as the domain without the .
. If no
Referer
or Origin
header is present in an HTTPS request, the CSRF check
will fail unless allow_no_origin
is set. The special Origin: null
can
be allowed by adding null
to the pyramid.csrf_trusted_origins
list.
It is possible to opt out of checking the origin by passing
check_origin=False
. This is useful if the CSRF storage policy is
known to be secure such that the token cannot be easily used by an attacker.
If CSRF checks fail then a pyramid.exceptions.BadCSRFToken
or
pyramid.exceptions.BadCSRFOrigin
exception will be raised. This
exception may be caught and handled by an exception view but, by
default, will result in a 400 Bad Request
response being sent to the
client.