A Permission represents the ability to perform an action or access a resource. A Permission is the most
granular, or atomic, unit in a system's security policy and is the cornerstone upon which fine-grained security
models are built.
It is important to understand a Permission instance only represents functionality or access - it does not grant it.
Granting access to an application functionality or a particular resource is done by the application's security
configuration, typically by assigning Permissions to users, roles and/or groups.
Most typical systems are what the Shiro team calls role-based
in nature, where a role represents
common behavior for certain user types. For example, a system might have an Administrator
But if you have a dynamic security model, where roles can be created and deleted at runtime, you can't hard-code
role names in your code. In this environment, roles themselves aren't very useful. What matters is what
are assigned to these roles.
Under this paradigm, permissions are immutable and reflect an application's raw functionality
(opening files, accessing a web URL, creating users, etc). This is what allows a system's security policy
to be dynamic: because Permissions represent raw functionality and only change when the application's
source code changes, they are immutable at runtime - they represent 'what' the system can do. Roles, users, and
groups are the 'who' of the application. Determining 'who' can do 'what' then becomes a simple exercise of
associating Permissions to roles, users, and groups in some way.
Most applications do this by associating a named role with permissions (i.e. a role 'has a' collection of
Permissions) and then associate users with roles (i.e. a user 'has a' collection of roles) so that by transitive
association, the user 'has' the permissions in their roles. There are numerous variations on this theme
(permissions assigned directly to users, or assigned to groups, and users added to groups and these groups in turn
have roles, etc, etc). When employing a permission-based security model instead of a role-based one, users, roles,
and groups can all be created, configured and/or deleted at runtime. This enables an extremely powerful security
A benefit to Shiro is that, although it assumes most systems are based on these types of static role or
dynamic role w/ permission schemes, it does not require a system to model their security data this way - all
Permission checks are relegated to
implementations, and only those
implementations really determine how a user 'has' a permission or not. The Realm could use the semantics described
here, or it could utilize some other mechanism entirely - it is always up to the application developer.
Shiro provides a very powerful default implementation of this interface in the form of the
. We highly recommend that you
investigate this class before trying to implement your own