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author | Daniel Baumann <daniel.baumann@progress-linux.org> | 2024-04-08 20:37:50 +0000 |
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committer | Daniel Baumann <daniel.baumann@progress-linux.org> | 2024-04-08 20:37:50 +0000 |
commit | c1f743ab2e4a7046d5500875a47d1f62c8624603 (patch) | |
tree | 709946d52f5f3bbaeb38be9e3f1d56d11f058237 /modules/README.rst | |
parent | Initial commit. (diff) | |
download | knot-resolver-c1f743ab2e4a7046d5500875a47d1f62c8624603.tar.xz knot-resolver-c1f743ab2e4a7046d5500875a47d1f62c8624603.zip |
Adding upstream version 5.7.1.upstream/5.7.1
Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>
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-rw-r--r-- | modules/README.rst | 251 |
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diff --git a/modules/README.rst b/modules/README.rst new file mode 100644 index 0000000..1096c37 --- /dev/null +++ b/modules/README.rst @@ -0,0 +1,251 @@ +.. SPDX-License-Identifier: GPL-3.0-or-later + +.. _modules-api: + +********************* +Modules API reference +********************* + +.. contents:: + :depth: 1 + :local: + +Supported languages +=================== + +Currently modules written in C and Lua(JIT) are supported. + +The anatomy of an extension +=========================== + +A module is a shared object or script defining specific functions/fields; here's an overview. + +.. csv-table:: + :header: "C", "Lua", "Params", "Comment" + + "``X_api()`` [#]_", "", "", "API version" + "``X_init()``", "``X.init()``", "``module``", "Constructor" + "``X_deinit()``", "``X.deinit()``", "``module``", "Destructor" + "``X_config()``", "``X.config()``", "``module, str``", "Configuration" + "``X_layer``", "``X.layer``", "", ":ref:`Module layer <lib-layers>`" + "``X_props``", "", "", "List of properties" + +.. [#] Mandatory symbol; defined by using :c:func:`KR_MODULE_EXPORT`. + +The ``X`` corresponds to the module name; if the module name is ``hints``, the prefix for constructor would be ``hints_init()``. +More details are in docs for the :c:type:`kr_module` and :c:type:`kr_layer_api` structures. + +.. note:: + The modules get ordered -- by default in the same as the order in which they were loaded. The loading command can specify where in the order the module should be positioned. + + +Writing a module in Lua +======================= + +The probably most convenient way of writing modules is Lua since you can use already installed modules +from system and have first-class access to the scripting engine. You can also tap to all the events, that +the C API has access to, but keep in mind that transitioning from the C to Lua function is slower than +the other way round, especially when JIT-compilation is taken into account. + +.. note:: The Lua functions retrieve an additional first parameter compared to the C counterparts - a "state". + Most useful C functions and structures have lua FFI wrappers, sometimes with extra sugar. + +The modules follow the `Lua way <http://lua-users.org/wiki/ModuleDefinition>`_, where the module interface is returned in a named table. + +.. code-block:: lua + + --- @module Count incoming queries + local counter = {} + + function counter.init(module) + counter.total = 0 + counter.last = 0 + counter.failed = 0 + end + + function counter.deinit(module) + print('counted', counter.total, 'queries') + end + + -- @function Run the q/s counter with given interval. + function counter.config(conf) + -- We can use the scripting facilities here + if counter.ev then event.cancel(counter.ev) + event.recurrent(conf.interval, function () + print(counter.total - counter.last, 'q/s') + counter.last = counter.total + end) + end + + return counter + +.. vv Hmm, we do not use these coroutine returns anywhere, so it's unclear whether they still work OK. Splitting work over time is now typically done via the ``event`` timers. + +.. The API functions may return an integer value just like in other languages, but they may also return a coroutine that will be continued asynchronously. A good use case for this approach is is a deferred initialization, e.g. loading a chunks of data or waiting for I/O. + +.. .. code-block:: lua + + function counter.init(module) + counter.total = 0 + counter.last = 0 + counter.failed = 0 + return coroutine.create(function () + for line in io.lines('/etc/hosts') do + load(module, line) + coroutine.yield() + end + end) + end + +The created module can be then loaded just like any other module, except it isn't very useful since it +doesn't provide any layer to capture events. The Lua module can however provide a processing layer, just +:ref:`like its C counterpart <lib-layers>`. + +.. code-block:: lua + + -- Notice it isn't a function, but a table of functions + counter.layer = { + begin = function (state, data) + counter.total = counter.total + 1 + return state + end, + finish = function (state, req, answer) + if state == kres.FAIL then + counter.failed = counter.failed + 1 + end + return state + end + } + +There is currently an additional "feature" in comparison to C layer functions: +some functions do not get called at all if ``state == kres.FAIL``; +see docs for details: :c:type:`kr_layer_api`. + +Since the modules are like any other Lua modules, you can interact with them through the CLI and and any interface. + +.. tip:: Module discovery: ``kres_modules.`` is prepended to the module name and lua search path is used on that. + + +Writing a module in C +===================== + +As almost all the functions are optional, the minimal module looks like this: + +.. code-block:: c + + #include "lib/module.h" + /* Convenience macro to declare module ABI. */ + KR_MODULE_EXPORT(mymodule) + +.. TODO it's probably not a good idea to start C module tutorial by pthread_create() + +Let's define an observer thread for the module as well. It's going to be stub for the sake of brevity, +but you can for example create a condition, and notify the thread from query processing by declaring +module layer (see the :ref:`Writing layers <lib-layers>`). + +.. code-block:: c + + static void* observe(void *arg) + { + /* ... do some observing ... */ + } + + int mymodule_init(struct kr_module *module) + { + /* Create a thread and start it in the background. */ + pthread_t thr_id; + int ret = pthread_create(&thr_id, NULL, &observe, NULL); + if (ret != 0) { + return kr_error(errno); + } + + /* Keep it in the thread */ + module->data = thr_id; + return kr_ok(); + } + + int mymodule_deinit(struct kr_module *module) + { + /* ... signalize cancellation ... */ + void *res = NULL; + pthread_t thr_id = (pthread_t) module->data; + int ret = pthread_join(thr_id, res); + if (ret != 0) { + return kr_error(errno); + } + + return kr_ok(); + } + +This example shows how a module can run in the background, this enables you to, for example, observe +and publish data about query resolution. + +Configuring modules +=================== + +There is a callback ``X_config()`` that you can implement, see hints module. + +.. _mod-properties: + +Exposing C module properties +============================ + +A module can offer NULL-terminated list of *properties*, each property is essentially a callable with free-form JSON input/output. +JSON was chosen as an interchangeable format that doesn't require any schema beforehand, so you can do two things - query the module properties +from external applications or between modules (e.g. `statistics` module can query `cache` module for memory usage). +JSON was chosen not because it's the most efficient protocol, but because it's easy to read and write and interface to outside world. + +.. note:: The ``void *env`` is a generic module interface. Since we're implementing daemon modules, the pointer can be cast to ``struct engine*``. + This is guaranteed by the implemented API version (see `Writing a module in C`_). + +Here's an example how a module can expose its property: + +.. code-block:: c + + char* get_size(void *env, struct kr_module *m, + const char *args) + { + /* Get cache from engine. */ + struct engine *engine = env; + struct kr_cache *cache = &engine->resolver.cache; + /* Read item count */ + int count = (cache->api)->count(cache->db); + char *result = NULL; + asprintf(&result, "{ \"result\": %d }", count); + + return result; + } + + struct kr_prop *cache_props(void) + { + static struct kr_prop prop_list[] = { + /* Callback, Name, Description */ + {&get_size, "get_size", "Return number of records."}, + {NULL, NULL, NULL} + }; + return prop_list; + } + + KR_MODULE_EXPORT(cache) + +Once you load the module, you can call the module property from the interactive console. +*Note:* the JSON output will be transparently converted to Lua tables. + +.. code-block:: bash + + $ kresd + ... + [system] started in interactive mode, type 'help()' + > modules.load('cached') + > cached.get_size() + [size] => 53 + +.. No idea what this talks about, but kept for now: +.. *Note:* this relies on function pointers, so the same ``static inline`` trick as for the ``Layer()`` is required for C. + +Special properties +------------------ + +If the module declares properties ``get`` or ``set``, they can be used in the Lua interpreter as +regular tables. + |