lib/All/entt/docs/md/process.md

# Crash Course: cooperative scheduler

# Table of Contents

* [Introduction](#introduction)
* [The process](#the-process)
  * [Adaptor](#adaptor)
* [The scheduler](#the-scheduler)

# Introduction

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 other component
types.<br/>
`EnTT` offers minimal support to this paradigm by introducing a few classes used
to define and execute cooperative processes.

# The process

A typical task inherits from the `process` class template that stays true to the
CRTP idiom. Moreover, derived classes specify what the intended type for elapsed
times is.

A process should expose publicly the following member functions whether needed
(note that it is not required to define a function unless the derived class
wants to _override_ the default behavior):

* `void update(Delta, void *);`

  This is invoked once per tick until a process is explicitly aborted or ends
  either with or without errors. Technically speaking, this member function is 
  not strictly required. However, 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();`

  This is invoked when the process joins the running queue of a scheduler. It
  happens usually when the process is attached to the scheduler if it is a top
  level one, or when it replaces its parent if it is a _continuation_.

* `void succeeded();`

  This is invoked in case of success, immediately after an update and during the
  same tick.

* `void failed();`

  This is invoked in case of errors, immediately after an update and during the
  same tick.

* `void aborted();`

  This is invoked only if a process is explicitly aborted. There is no guarantee
  that it executes in the same tick, it 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.<br/>
All these are protected member functions made available 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;

    my_process(delta_type delay)
        : remaining{delay}
    {}

    void update(delta_type delta, void *) {
        remaining -= std::min(remaining, delta);

        // ...

        if(!remaining) {
            succeed();
        }
    }

private:
    delta_type remaining;
};
```

## Adaptor

Lambdas and functors cannot be used directly with a scheduler because 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 callbacks to
invoke whenever a process terminates 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 should not 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 manage their life
cycles.

Each process is invoked once per tick. If it terminates, it is removed
automatically from the scheduler, and it is never invoked again. Otherwise,
it is 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 is
easy to create a 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::basic_scheduler<std::uint64_t> scheduler;
```

Otherwise, the `scheduler` alias is also available for the most common cases. It
uses `std::uint32_t` as a default type:

```cpp
entt::scheduler scheduler;
```

The class 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::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 is enough to
  indicate its type and submit all the parameters required to construct it to
  the `attach` member function:

  ```cpp
  scheduler.attach<my_process>(1000u);
  ```

* Otherwise, in case of a lambda or a functor, it is enough to provide an
  instance of the class to the `attach` member function:

  ```cpp
  scheduler.attach([](auto...){ /* ... */ });
  ```

In both cases, the scheduler is returned and its `then` member function can be
used 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>(1000u);
```

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 is 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();
```
Initial commit - restart from existing code 2026-02-13 19:15:05 +01:00			`# Crash Course: cooperative scheduler`

			`# Table of Contents`

			`* [Introduction](#introduction)`
			`* [The process](#the-process)`
			`* [Adaptor](#adaptor)`
			`* [The scheduler](#the-scheduler)`

			`# Introduction`

			`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 other component`
			`types.<br/>`
			`EnTT` offers minimal support to this paradigm by introducing a few classes used
			`to define and execute cooperative processes.`

			`# The process`

			A typical task inherits from the `process` class template that stays true to the
			`CRTP idiom. Moreover, derived classes specify what the intended type for elapsed`
			`times is.`

			`A process should expose publicly the following member functions whether needed`
			`(note that it is not required to define a function unless the derived class`
			`wants to _override_ the default behavior):`

			* `void update(Delta, void *);`

			`This is invoked once per tick until a process is explicitly aborted or ends`
			`either with or without errors. Technically speaking, this member function is`
			`not strictly required. However, 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();`

			`This is invoked when the process joins the running queue of a scheduler. It`
			`happens usually when the process is attached to the scheduler if it is a top`
			`level one, or when it replaces its parent if it is a _continuation_.`

			* `void succeeded();`

			`This is invoked in case of success, immediately after an update and during the`
			`same tick.`

			* `void failed();`

			`This is invoked in case of errors, immediately after an update and during the`
			`same tick.`

			* `void aborted();`

			`This is invoked only if a process is explicitly aborted. There is no guarantee`
			`that it executes in the same tick, it 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.<br/>
			`All these are protected member functions made available 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;`

			`my_process(delta_type delay)`
			`: remaining{delay}`
			`{}`

			`void update(delta_type delta, void *) {`
			`remaining -= std::min(remaining, delta);`

			`// ...`

			`if(!remaining) {`
			`succeed();`
			`}`
			`}`

			`private:`
			`delta_type remaining;`
			`};`
			```

			`## Adaptor`

			`Lambdas and functors cannot be used directly with a scheduler because 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 callbacks to`
			`invoke whenever a process terminates 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 should not 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 manage their life`
			`cycles.`

			`Each process is invoked once per tick. If it terminates, it is removed`
			`automatically from the scheduler, and it is never invoked again. Otherwise,`
			`it is 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 is`
			`easy to create a 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::basic_scheduler<std::uint64_t> scheduler;`
			```

			Otherwise, the `scheduler` alias is also available for the most common cases. It
			uses `std::uint32_t` as a default type:

			```cpp
			`entt::scheduler scheduler;`
			```

			`The class 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::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 is enough to
			`indicate its type and submit all the parameters required to construct it to`
			the `attach` member function:

			```cpp
			`scheduler.attach<my_process>(1000u);`
			```

			`* Otherwise, in case of a lambda or a functor, it is enough to provide an`
			instance of the class to the `attach` member function:

			```cpp
			`scheduler.attach([](auto...){ /* ... */ });`
			```

			In both cases, the scheduler is returned and its `then` member function can be
			`used 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>(1000u);`
			```

			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 is 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();`
			```