|
|
- # Crash Course: cooperative scheduler
-
- <!--
- @cond TURN_OFF_DOXYGEN
- -->
- # Table of Contents
-
- * [Introduction](#introduction)
- * [The process](#the-process)
- * [Adaptor](#adaptor)
- * [The scheduler](#the-scheduler)
- <!--
- @endcond TURN_OFF_DOXYGEN
- -->
-
- # Introduction
-
- Sometimes processes are a useful tool to work around the strict definition of a
- system and introduce logic in a different way, usually without resorting to the
- introduction of other components.
-
- `EnTT` offers a minimal support to this paradigm by introducing a few classes
- that users can use to define and execute cooperative processes.
-
- # The process
-
- A typical process must inherit from the `process` class template that stays true
- to the CRTP idiom. Moreover, derived classes must specify what's the intended
- type for elapsed times.
-
- A process should expose publicly the following member functions whether
- required (note that it isn't required to define a function unless the derived
- class wants to _override_ the default behavior):
-
- * `void update(Delta, void *);`
-
- It's invoked once per tick until a process is explicitly aborted or it
- terminates either with or without errors. Even though it's not mandatory to
- declare this member function, as a rule of thumb each process should at
- least define it to work properly. The `void *` parameter is an opaque pointer
- to user data (if any) forwarded directly to the process during an update.
-
- * `void init();`
-
- It's invoked when the process joins the running queue of a scheduler. This
- happens as soon as it's attached to the scheduler if the process is a top
- level one, otherwise when it replaces its parent if the process is a
- continuation.
-
- * `void succeeded();`
-
- It's invoked in case of success, immediately after an update and during the
- same tick.
-
- * `void failed();`
-
- It's invoked in case of errors, immediately after an update and during the
- same tick.
-
- * `void aborted();`
-
- It's invoked only if a process is explicitly aborted. There is no guarantee
- that it executes in the same tick, this depends solely on whether the
- process is aborted immediately or not.
-
- Derived classes can also change the internal state of a process by invoking
- `succeed` and `fail`, as well as `pause` and `unpause` the process itself. All
- these are protected member functions made available to be able to manage the
- life cycle of a process from a derived class.
-
- Here is a minimal example for the sake of curiosity:
-
- ```cpp
- struct my_process: entt::process<my_process, std::uint32_t> {
- using delta_type = std::uint32_t;
-
- void update(delta_type delta, void *) {
- remaining -= std::min(remaining, delta);
-
- // ...
-
- if(!remaining) {
- succeed();
- }
- }
-
- private:
- delta_type remaining{1000u};
- };
- ```
-
- ## Adaptor
-
- Lambdas and functors can't be used directly with a scheduler for they are not
- properly defined processes with managed life cycles.<br/>
- This class helps in filling the gap and turning lambdas and functors into
- full featured processes usable by a scheduler.
-
- The function call operator has a signature similar to the one of the `update`
- function of a process but for the fact that it receives two extra arguments to
- call whenever a process is terminated with success or with an error:
-
- ```cpp
- void(Delta delta, void *data, auto succeed, auto fail);
- ```
-
- Parameters have the following meaning:
-
- * `delta` is the elapsed time.
- * `data` is an opaque pointer to user data if any, `nullptr` otherwise.
- * `succeed` is a function to call when a process terminates with success.
- * `fail` is a function to call when a process terminates with errors.
-
- Both `succeed` and `fail` accept no parameters at all.
-
- Note that usually users shouldn't worry about creating adaptors at all. A
- scheduler creates them internally each and every time a lambda or a functor is
- used as a process.
-
- # The scheduler
-
- A cooperative scheduler runs different processes and helps managing their life
- cycles.
-
- Each process is invoked once per tick. If it terminates, it's removed
- automatically from the scheduler and it's never invoked again. Otherwise it's
- a good candidate to run one more time the next tick.<br/>
- A process can also have a child. In this case, the parent process is replaced
- with its child when it terminates and only if it returns with success. In case
- of errors, both the parent process and its child are discarded. This way, it's
- easy to create chain of processes to run sequentially.
-
- Using a scheduler is straightforward. To create it, users must provide only the
- type for the elapsed times and no arguments at all:
-
- ```cpp
- entt::scheduler<std::uint32_t> scheduler;
- ```
-
- It has member functions to query its internal data structures, like `empty` or
- `size`, as well as a `clear` utility to reset it to a clean state:
-
- ```cpp
- // checks if there are processes still running
- const auto empty = scheduler.empty();
-
- // gets the number of processes still running
- entt::scheduler<std::uint32_t>::size_type size = scheduler.size();
-
- // resets the scheduler to its initial state and discards all the processes
- scheduler.clear();
- ```
-
- To attach a process to a scheduler there are mainly two ways:
-
- * If the process inherits from the `process` class template, it's enough to
- indicate its type and submit all the parameters required to construct it to
- the `attach` member function:
-
- ```cpp
- scheduler.attach<my_process>("foobar");
- ```
-
- * Otherwise, in case of a lambda or a functor, it's enough to provide an
- instance of the class to the `attach` member function:
-
- ```cpp
- scheduler.attach([](auto...){ /* ... */ });
- ```
-
- In both cases, the return value is an opaque object that offers a `then` member
- function to use to create chains of processes to run sequentially.<br/>
- As a minimal example of use:
-
- ```cpp
- // schedules a task in the form of a lambda function
- scheduler.attach([](auto delta, void *, auto succeed, auto fail) {
- // ...
- })
- // appends a child in the form of another lambda function
- .then([](auto delta, void *, auto succeed, auto fail) {
- // ...
- })
- // appends a child in the form of a process class
- .then<my_process>();
- ```
-
- To update a scheduler and therefore all its processes, the `update` member
- function is the way to go:
-
- ```cpp
- // updates all the processes, no user data are provided
- scheduler.update(delta);
-
- // updates all the processes and provides them with custom data
- scheduler.update(delta, &data);
- ```
-
- In addition to these functions, the scheduler offers an `abort` member function
- that can be used to discard all the running processes at once:
-
- ```cpp
- // aborts all the processes abruptly ...
- scheduler.abort(true);
-
- // ... or gracefully during the next tick
- scheduler.abort();
- ```
|