Difference between revisions of "Projects/Plugin support improvements (first version)"
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==Directory Structure== |
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==Defaults== |
==Defaults== |
Revision as of 11:59, 22 June 2010
This page contains some notes about improving the plugin infrastructure, but does not make a specific proposal yet.
Some possibly useful ideas at Dr Dobb's. It's rather biased toward C++, and we may disagree with some of the details.
Contents
Motivation
The goal of this project is to create a framework that
- Facilitates simple and clear additions of new plugin interfaces and new implementations of the existing plugins;
- Handles both built-in (static) and dynamic plugins;
- Allows multiple implementation of the same plugin interface;
- Provides uniform way to supply parameters for plugin configuration;
Definitions
- pluggable interface
- an (internal) interface that can be implemented by a third party. These can be one-to-one, or one-to-many. An example of one-to-one is the DAL, and an example of one-to-many is preauth.
- module
- a unit of code that implements a pluggable interface. It can be built in, or it can be dynamically loadable.
- built-in
- a module whose executable code is located within the library shared object or executable program file, or behaves as if it were. (Dependent library shared objects of the calling library can contain "built-in" modules for the calling library.) The distinguishing feature of a built-in module is that, as part of program startup, the operating system automatically maps the executable code of the module into the address space of the process that calls it, without any explicit action by the library or program.
- dynamically loaded
- a module whose executable code is located within a file that is distinct from the library or program that calls it. The plugin support framework uses the runtime linker (or equivalent) to explicitly map the executable code of the module into the process address space.
- discovery
- process of enumerating what modules are available for a pluggable interface. Includes possible filtering of the raw discovered set.
- compiled-in
- directory scan
- explicit inclusion by configuration
- explicit exclusion by configuration
- loading
- the process of making modules available for calling. This can involve dynamically loading a module using the runtime linker, or it can involve registering a vtable provided by an application.
- built-in
- dynamic loading
- application-registered
- selection
- the process of a caller invoking one specific module from the set of loaded modules that implement an interface.
Structure
Participants
- Plugin Manager (PM) - Abstract module that declares interface for operations that manage plugin configuration and registry services;
- Plugin Manager Implementation (PMI) - Implements the operations for plugin configuration and registry services;
- Plugin Loader (PL) - Abstract module that declares an interface for operations that create abstract plugin objects. It knows about:
- Set of available implementations;
- How to create them;
- We might want to have a separate loader function for each pluggable interface, for type safety;
- Plugin Loader Implementation (PLI) - Concrete implementation of PL;
- Plugin Interface (PI) - Abstract module that declares plugin interface. Provides wrap-ups of the interface calls;
- Plugin Interface Implementation (PII) - Concrete implementation of the plugin interface;
- Client - Plugin caller.
Collaboration
- An instance pl_handle of a particular PMI is created as part of krb5_init_context operation at run-time (1). This instance will use methods specific to PMI to configure and register the desired plugin implementations;
- The list of the desired plugin implementations is known to the specific PLI which is aggregated with PMI (2);
- PMI defers acquiring of plugin interfaces to PLI (3);
- The client uses pl_handle to invoke the desired plugin interface (4).
Implementation
- k5-int.h
- plugin_manager *pl_handle is added to _krb5_context
Implementation must be MT safe
Sample Code
How to call plugins
The following is an example of invoking password quality plugin:
/* plugin_manager *pl_handle; */ plhandle plugin_handle; plugin_handle = plugin_manager_get_service(pl_handle, "plugin_pwd_qlty", PWD_QLTY_KRB); plugin_pwd_qlty_check(plugin_handle, srv_handle, password, use_policy, pol, principal);
How to construct plugin interface (PI)
The following is an example of plugin interface called "password quality":
typedef struct { int version; int plugin_id; kadm5_ret_t (*pwd_qlty_init)(kadm5_server_handle_t); void (*pwd_qlty_cleanup)(); kadm5_ret_t (*pwd_qlty_check)(kadm5_server_handle_t, char*, int, kadm5_policy_ent_t, krb5_principal); } plugin_pwd_qlty; kadm5_ret_t plugin_pwd_qlty_check( plhandle handle, kadm5_server_handle_t srv_handle, char *password, int use_policy, kadm5_policy_ent_t pol, krb5_principal principal) { plugin_pwd_qlty* api = (plugin_pwd_qlty*) handle.api; api->pwd_qlty_check(srv_handle, password, use_policy, pol, principal); } kadm5_ret_t plugin_pwd_qlty_init(plhandle, kadm5_server_handle_t){...} void plugin_pwd_qlty_cleanup(plhandle) {...}
How to construct plugin interface implementation (PII)
Every PII should have only one public create function. For PII called "password quality krb" it would be plhandle plugin_pwd_qlty_krb_create().The following is an example of the this PII:
plhandle plugin_pwd_qlty_krb_create() { plhandle handle; plugin_pwd_qlty* api = malloc(sizeof(plugin_pwd_qlty)); api->version = 1; api->plugin_id = PWD_QLTY_KRB; api->pwd_qlty_init = _plugin_pwd_qlty_init; api->pwd_qlty_check = _plugin_pwd_qlty_check; api->pwd_qlty_cleanup = _plugin_pwd_qlty_clean; handle.api = api; return handle; } static kadm5_ret_t _plugin_pwd_qlty_check(kadm5_server_handle_t srv_handle, char *password, int use_policy, kadm5_policy_ent_t pol, krb5_principal principal) { /* do some quality verification */ } static kadm5_ret_t _plugin_pwd_qlty_init(kadm5_server_handle_t handle) { /* do some initialization */ } static kadm5_ret_t _plugin_pwd_qlty_cleanup() { /* do some cleanup */ }
Static Plugins
- Examples
- PreAuth, AuthData, Password Quality (see Current plugins section for details)
- Invoking multiple implementations of the same plugin
- This is achieved by using the aimed plugin_id's in plugin_manager_get_service calls
Dynamic Plugins
(..)
Configuration
Configuration file attributes
- plugin list - list of the desired plugins;
- plugin_api - name of the plugin interface;
- plugin_name - concrete plugin implementation;
- plugin_id - the id that plugin implementation is associated with. Used by the client;
- plugin_loader_name - name of the loader the particular implementation is associated with;
- plugin_loader_type - defines the plugin type: built-in (i.e. static) or dynamic;
Example of the plugin section in krb5.conf
[plugins] plugin_list = PQ1 PQ1 = { plugin_api = plugin_pwd_qlty plugin_loader_name = plugin_default_factory plugin_loader_type = static plugin_name = plugin_pwd_qlty_krb plugin_id = 1 }
Choices
The choice of plugin configuration format is a matter of taste. It may be presented in XML, YAML, JSON etc. One needs only an appropriate parser.
Configuration change at run-time
(...)
Directory Structure
- src/plugin_core
- plugin_manager.[ch], plugin_loader.[ch], impl/plugin_XXX_manager.[ch], impl/plugin_XXX_loader.[ch]
- src/plugins
- pluginA/plugin_A.[ch], pluginA/plugin_A_implN/plugin_A_implN.[ch]
Defaults
(...)
Build process
- Options
- DEBUG_PLUGINS - output more info for debugging
Current plugins
We currently have the following plugin frameworks:
- Preauth: All shared objects from profile-specified or installation directory are loaded. Two vtables are read from the shared objects, one for libkrb5 and one for the KDC. The preauth framework iterates over the module list invoking functions to generate or handle preauth data. Preauth vtable functions receive a callback function and data object which allow it to request information such as the expected enctype or FAST armor key for the request.
- Authdata: Very similar to the preauth framework.
- KDB: The profile specifies a database library name for each realm. Shared objects matching the library name are loaded from a profile-specified and installation directory; the first matching object with an appropriately-named vtable data object is used, and the rest are ignored. libkdb5 contains wrappers which invoke functions in the library's vtable, or (for some optional functions) default implementations if the vtable left the function pointer as NULL.
- KDC location: All shared objects from an installation directory are located. A vtable is read from the shared objects. The KDC location framework iterates over each vtable and invokes a lookup function; modules can return success with a location, an error (which halts the location process), or a distinguished error code which passes control along to the next module or the built-in location mechanisms.
- GSSAPI: The file /etc/gss/mechs can specify a list of mechanism OIDs and shared object filenames; filenames are taken as relative to an installation directory. Shared objects implementing mechanisms can export either a function returning a vtable, or can export each GSSAPI interface individually.
The following areas of functionality are virtualized but have no exposed plugin framework:
- Serialization: Serialization table entries can be registered with krb5_register_serializer. Data objects are matched to table entries by magic number. The registration function is exported by libkrb5 and is named with the krb5_ prefix, but it and its associated structure are declared in k5-int.h rather than krb5.h. It is not used outside of libkrb5.
- ccache: Very similar to serialization, except that ccache implementations are selected using a URL-style prefix in the ccache name.
- keytab: Very similar to ccache, except that the keytab registration function is used outside of libkrb5 to register a "KDB keytab", which is used by kadmind to serve GSSRPC without requiring a keytab file containing the kadmin keys.
- Replay cache: Very similar to ccache, except that the replay cache registration function is not used anywhere (even inside libkrb5).
Plugin frameworks which are "not exposed" may still be productively used by vendor forks of the krb5 tree.
Future plugins
The following areas are candidates for future plugin support:
- PRNG
- profile / configuration
- DNS / host-realm mapping
- password quality policy
- lockout
- audit
- password synchronization
Current support infrastructure
In libkrb5support, we have functions to facilitate loading plugins from shared objects. There is a set of functions to load individual plugins from named files and mechglue; these are currently used by the HDB bridge and GSS mechglue:
- krb5int_open_plugin - Create a plugin handle from a filename
- krb5int_close_plugin - Close a plugin handle
- krb5int_get_plugin_data - Retrieve a data object from a plugin handle by symbol name
- krb5int_get_plugin_func - Retrieve a function object from a plugin handle by symbol name
There is another set of functions to scan a list of directories for plugins:
- krb5int_open_plugin_dirs - Create a plugin dir handle from a list of directories and (optionally) filebases
- krb5int_close_plugin_dirs - Close a plugin dir handle
- krb5int_get_plugin_dir_data - Retrieve a list of data objects from a plugin dir handle by symbol name
- krb5int_get_plugin_dir_func - Retrieve a list of function objects from a plugin dir handle by symbol name
- krb5int_free_plugin_dir_data - Free a list of data objects returned by krb5int_get_plugin_dir_data
- krb5int_free_plugin_dir_func - Free a list of function objects returned by krb5int_get_plugin_dir_func
Problem areas
- Every caller of krb5int_open_plugin_dirs specifies either no filebases (e.g. preauth plugins) or a single filebase (KDB plugins). Accepting and processing a list of filebases is probably needless complexity.
- Callers of krb5int_open_plugin_dirs have to know what directories to supply, which means they need to know the krb5 install root as well as the magic plugin area for OS X, and they need logic for reading a profile variable to determine the alternate plugin directory for the test suite (currently only implemented for KDB and preauth plugins).
- In most uses of plugins, we read a data object containing a list of function pointers. This makes it mostly impossible to supply a plugin which works with multiple versions of krb5. If we instead read a function object which we invoked with a version number to retrieve the vtable, it would be possible (though perhaps awkward) to create a shared object which works with multiple versions.
- We are somewhat schizophrenic about how plugins can access krb5 library functionality, and in particular internal symbols. Sometimes we call functions directly, sometimes we make use of a vtable passed into the plugin (e.g. the preauth_get_client_data_proc function), sometimes we use the accessor to invoke internal functions, and sometimes we call APIs or internal functions directly. Ideally we should have a consistent policy with a sound justification.
- When measuring code coverage with gcov, we cannot use shared libraries; this means we need to link in-tree plugins statically into the libraries or programs which load them. We have an ad-hoc method to do this with KDB plugins, but not with other plugin types.
- Administrators have an easier time writing scripts than creating linkable shared objects. In some cases it might yield a better administrator experience to create plugin interfaces via subprocesses than loading shared objects, although in many cases this might not be feasible.
- In some scenarios such as embedded environments, it may be more useful to allow applications to supply plugin vtables via an API (as we do for keytabs and ccaches, though those APIs are not public) than to load them from shared objects in the filesystem.