# entt
**Repository Path**: iceeye001/entt
## Basic Information
- **Project Name**: entt
- **Description**: Gaming meets modern C++ - a fast and reliable entity-component system (ECS) and much more
- **Primary Language**: C/C++
- **License**: MIT
- **Default Branch**: master
- **Homepage**: None
- **GVP Project**: No
## Statistics
- **Stars**: 0
- **Forks**: 0
- **Created**: 2021-04-26
- **Last Updated**: 2021-04-26
## Categories & Tags
**Categories**: Uncategorized
**Tags**: None
## README
[](https://travis-ci.org/skypjack/entt)
[](https://ci.appveyor.com/project/skypjack/entt)
[](https://coveralls.io/github/skypjack/entt?branch=master)
[](https://gitter.im/skypjack/entt)
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# Table of Contents
* [Introduction](#introduction)
* [Build Instructions](#build-instructions)
* [Crash Course: entity-component system](#crash-course-entity-component-system)
* [Design choices](#design-choices)
* [A bitset-free entity-component system](#a-bitset-free-entity-component-system)
* [Pay per use](#pay-per-use)
* [Vademecum](#vademecum)
* [The Registry, the Entity and the Component](#the-registry-the-entity-and-the-component)
* [Single instance components](#single-instance-components)
* [Observe changes](#observe-changes)
* [Who let the tags out?](#who-let-the-tags-out)
* [Runtime components](#runtime-components)
* [A journey through a plugin](#a-journey-through-a-plugin)
* [Sorting: is it possible?](#sorting-is-it-possible)
* [Snapshot: complete vs continuous](#snapshot-complete-vs-continuous)
* [Snapshot loader](#snapshot-loader)
* [Continuous loader](#continuous-loader)
* [Archives](#archives)
* [One example to rule them all](#one-example-to-rule-them-all)
* [Prototype](#prototype)
* [Helpers](#helpers)
* [Dependency function](#dependency-function)
* [Labels](#labels)
* [Null entity](#null-entity)
* [View: to persist or not to persist?](#view-to-persist-or-not-to-persist)
* [Standard View](#standard-view)
* [Single component standard view](#single-component-standard-view)
* [Multi component standard view](#multi-component-standard-view)
* [Persistent View](#persistent-view)
* [Raw View](#raw-view)
* [Runtime View](#runtime-view)
* [Give me everything](#give-me-everything)
* [Iterations: what is allowed and what is not](#iterations-what-is-allowed-and-what-is-not)
* [Multithreading](#multithreading)
* [Crash Course: core functionalities](#crash-course-core-functionalities)
* [Compile-time identifiers](#compile-time-identifiers)
* [Runtime identifiers](#runtime-identifiers)
* [Hashed strings](#hashed-strings)
* [Monostate](#monostate)
* [Crash Course: service locator](#crash-course-service-locator)
* [Crash Course: cooperative scheduler](#crash-course-cooperative-scheduler)
* [The process](#the-process)
* [The scheduler](#the-scheduler)
* [Crash Course: resource management](#crash-course-resource-management)
* [The resource, the loader and the cache](#the-resource-the-loader-and-the-cache)
* [Crash Course: events, signals and everything in between](#crash-course-events-signals-and-everything-in-between)
* [Signals](#signals)
* [Delegate](#delegate)
* [Event dispatcher](#event-dispatcher)
* [Event emitter](#event-emitter)
* [Packaging Tools](#packaging-tools)
* [EnTT in Action](#entt-in-action)
* [License](#license)
* [Support](#support)
* [Donation](#donation)
* [Hire me](#hire-me)
# Introduction
`EnTT` is a header-only, tiny and easy to use entity-component system (and much
more) written in modern C++.
The entity-component-system (also known as _ECS_) is an architectural pattern
used mostly in game development. For further details:
* [Entity Systems Wiki](http://entity-systems.wikidot.com/)
* [Evolve Your Hierarchy](http://cowboyprogramming.com/2007/01/05/evolve-your-heirachy/)
* [ECS on Wikipedia](https://en.wikipedia.org/wiki/Entity%E2%80%93component%E2%80%93system)
A long time ago, the sole entity-component system was part of the project. After
a while the codebase has grown and more and more classes have become part of the
repository.
Here is a brief, yet incomplete list of what it offers today:
* Statically generated integer identifiers for types (assigned either at
compile-time or at runtime).
* A constexpr utility for human readable resource identifiers.
* A minimal configuration system built on top of the monostate pattern.
* An incredibly fast entity-component system based on sparse sets, with its own
views and a _pay for what you use_ policy to adjust performance and memory
usage according to users' requirements.
* Actor class for those who aren't confident with entity-component systems.
* The smallest and most basic implementation of a service locator ever seen.
* A cooperative scheduler for processes of any type.
* All what is needed for resource management (cache, loaders, handles).
* Delegates, signal handlers (with built-in support for collectors) and a tiny
event dispatcher.
* A general purpose event emitter, that is a CRTP idiom based class template.
* An event dispatcher for immediate and delayed events to integrate in loops.
* ...
* Any other business.
Consider it a work in progress. The whole API is also fully documented in-code
for those who are brave enough to read it.
Currently, `EnTT` is tested on Linux, Microsoft Windows and OS X. It has proven
to work also on both Android and iOS.
Most likely it will not be problematic on other systems as well, but has not
been sufficiently tested so far.
## Code Example
```cpp
#include
#include
struct Position {
float x;
float y;
};
struct Velocity {
float dx;
float dy;
};
void update(entt::DefaultRegistry ®istry) {
auto view = registry.view();
for(auto entity: view) {
// gets only the components that are going to be used ...
auto &velocity = view.get(entity);
velocity.dx = 0.;
velocity.dy = 0.;
// ...
}
}
void update(std::uint64_t dt, entt::DefaultRegistry ®istry) {
registry.view().each([dt](auto entity, auto &position, auto &velocity) {
// gets all the components of the view at once ...
position.x += velocity.dx * dt;
position.y += velocity.dy * dt;
// ...
});
}
int main() {
entt::DefaultRegistry registry;
std::uint64_t dt = 16;
for(auto i = 0; i < 10; ++i) {
auto entity = registry.create();
registry.assign(entity, i * 1.f, i * 1.f);
if(i % 2 == 0) { registry.assign(entity, i * .1f, i * .1f); }
}
update(dt, registry);
update(registry);
// ...
}
```
## Motivation
I started working on `EnTT` because of the wrong reason: my goal was to design
an entity-component system that beated another well known open source solution
in terms of performance and used (possibly) less memory in the average
case.
In the end, I did it, but it wasn't much satisfying. Actually it wasn't
satisfying at all. The fastest and nothing more, fairly little indeed. When I
realized it, I tried hard to keep intact the great performance of `EnTT` and to
add all the features I wanted to see in *my own library* at the same time.
Nowadays, `EnTT` is finally what I was looking for: still faster than its
_competitors_, lower memory usage in the average case, a really good API and an
amazing set of features. And even more, of course.
## Performance
As it stands right now, `EnTT` is just fast enough for my requirements if
compared to my first choice (it was already amazingly fast actually).
Below is a comparison between the two (both of them compiled with GCC 7.3.0 on a
Dell XPS 13 out of the mid 2014):
| Benchmark | EntityX (compile-time) | EnTT |
|-----------|-------------|-------------|
| Create 1M entities | 0.0147s | **0.0046s** |
| Destroy 1M entities | 0.0053s | **0.0045s** |
| 1M entities, one component | 0.0012s | **1.9e-07s** |
| 1M entities, two components | 0.0012s | **3.8e-07s** |
| 1M entities, two components
Half of the entities have all the components | 0.0009s | **3.8e-07s** |
| 1M entities, two components
One of the entities has all the components | 0.0008s | **1.0e-06s** |
| 1M entities, five components | 0.0010s | **7.0e-07s** |
| 1M entities, ten components | 0.0011s | **1.2e-06s** |
| 1M entities, ten components
Half of the entities have all the components | 0.0010s | **1.2e-06s** |
| 1M entities, ten components
One of the entities has all the components | 0.0008s | **1.2e-06s** |
| Sort 150k entities, one component
Arrays are in reverse order | - | **0.0036s** |
| Sort 150k entities, enforce permutation
Arrays are in reverse order | - | **0.0005s** |
| Sort 150k entities, one component
Arrays are almost sorted, std::sort | - | **0.0035s** |
| Sort 150k entities, one component
Arrays are almost sorted, insertion sort | - | **0.0007s** |
Note: The default version of `EntityX` (`master` branch) wasn't added to the
comparison because it's already much slower than its compile-time counterpart.
Pretty interesting, aren't them? In fact, these benchmarks are the same used by
`EntityX` to show _how fast it is_. To be honest, they aren't so good and these
results shouldn't be taken much seriously (they are completely unrealistic
indeed).
The proposed entity-component system is incredibly fast to iterate entities,
this is a fact. The compiler can make a lot of optimizations because of how
`EnTT` works, even more when components aren't used at all. This is exactly the
case for these benchmarks. On the other hand and if we consider real world
cases, `EnTT` is in the middle between a bit and much faster than the other
solutions around when users also access the components and not just the
entities, although it is not as fast as reported by these benchmarks.
This is why they are completely wrong and cannot be used to evaluate any of the
entity-component systems.
If you decide to use `EnTT`, choose it because of its API, features and
performance, not because there is a benchmark somewhere that makes it seem the
fastest.
Probably I'll try to get out of `EnTT` more features and even better performance
in the future, mainly for fun.
If you want to contribute and/or have any suggestion, feel free to make a PR or
open an issue to discuss your idea.
# Build Instructions
## Requirements
To be able to use `EnTT`, users must provide a full-featured compiler that
supports at least C++14.
The requirements below are mandatory to compile the tests and to extract the
documentation:
* CMake version 3.2 or later.
* Doxygen version 1.8 or later.
## Library
`EnTT` is a header-only library. This means that including the `entt.hpp` header
is enough to include the library as a whole and use it. For those who are
interested only in the entity-component system, consider to include the sole
`entity/registry.hpp` header instead.
It's a matter of adding the following line to the top of a file:
```cpp
#include
```
Use the line below to include only the entity-component system instead:
```cpp
#include
```
Then pass the proper `-I` argument to the compiler to add the `src` directory to
the include paths.
### Side note: shared libraries
To make sure that an application and a shared library that use both `EnTT` can
interact correctly when symbols are hidden by default, there are some tricks to
follow.
In particular and in order to avoid undefined behaviors, all the instantiation
of the `Family` class template shall be made explicit along with the system-wide
specifier to use to export them.
At the time I'm writing this document, the classes that use internally the above
mentioned class template are `Dispatcher`, `Emitter` and `Registry`. Therefore
and as an example, if you use the `Registry` class template in your shared
library and want to set symbols visibility to _hidden_ by default, the following
lines are required to allow it to function properly with a client that also uses
the `Registry` somehow:
* On GNU/Linux:
```cpp
namespace entt {
template class __attribute__((visibility("default"))) Family;
template class __attribute__((visibility("default"))) Family;
template class __attribute__((visibility("default"))) Family;
}
```
* On Windows:
```cpp
namespace entt {
template class __declspec(dllexport) Family;
template class __declspec(dllexport) Family;
template class __declspec(dllexport) Family;
}
```
Otherwise, the risk is that type identifiers are different between the shared
library and the application and this will prevent the whole thing from
functioning correctly for obvious reasons.
## Documentation
The documentation is based on [doxygen](http://www.stack.nl/~dimitri/doxygen/).
To build it:
$ cd build
$ cmake .. -DBUILD_DOCS=ON
$ make
The API reference will be created in HTML format within the directory
`build/docs/html`. To navigate it with your favorite browser:
$ cd build
$ your_favorite_browser docs/html/index.html
The API reference is also available [online](https://skypjack.github.io/entt/)
for the latest version.
## Tests
To compile and run the tests, `EnTT` requires *googletest*.
`cmake` will download and compile the library before compiling anything else.
In order to build without tests set CMake option `BUILD_TESTING=OFF`.
To build the most basic set of tests:
* `$ cd build`
* `$ cmake ..`
* `$ make`
* `$ make test`
Note that benchmarks are not part of this set.
# Crash Course: entity-component system
## Design choices
### A bitset-free entity-component system
`EnTT` is a _bitset-free_ entity-component system that doesn't require users to
specify the component set at compile-time.
This is why users can instantiate the core class simply like:
```cpp
entt::DefaultRegistry registry;
```
In place of its more annoying and error-prone counterpart:
```cpp
entt::DefaultRegistry registry;
```
### Pay per use
`EnTT` is entirely designed around the principle that users have to pay only for
what they want.
When it comes to using an entity-component system, the tradeoff is usually
between performance and memory usage. The faster it is, the more memory it uses.
However, slightly worse performance along non-critical paths are the right price
to pay to reduce memory usage and I've always wondered why this kind of tools do
not leave me the choice.
`EnTT` follows a completely different approach. It squeezes the best from the
basic data structures and gives users the possibility to pay more for higher
performance where needed.
The disadvantage of this approach is that users need to know the systems they
are working on and the tools they are using. Otherwise, the risk to ruin the
performance along critical paths is high.
So far, this choice has proven to be a good one and I really hope it can be for
many others besides me.
## Vademecum
The `Registry` to store, the views to iterate. That's all.
An entity (the _E_ of an _ECS_) is an opaque identifier that users should just
use as-is and store around if needed. Do not try to inspect an entity
identifier, its format can change in future and a registry offers all the
functionalities to query them out-of-the-box. The underlying type of an entity
(either `std::uint16_t`, `std::uint32_t` or `std::uint64_t`) can be specified
when defining a registry (actually the `DefaultRegistry` is nothing more than a
`Registry` where the type of the entities is `std::uint32_t`).
Components (the _C_ of an _ECS_) should be plain old data structures or more
complex and movable data structures with a proper constructor. Actually, the
sole requirement of a component type is that it must be both move constructible
and move assignable. They are list initialized by using the parameters provided
to construct the component itself. No need to register components or their types
neither with the registry nor with the entity-component system at all.
Systems (the _S_ of an _ECS_) are just plain functions, functors, lambdas or
whatever users want. They can accept a `Registry` or a view of any type and use
them the way they prefer. No need to register systems or their types neither
with the registry nor with the entity-component system at all.
The following sections will explain in short how to use the entity-component
system, the core part of the whole library.
In fact, the project is composed of many other classes in addition to those
describe below. For more details, please refer to the inline documentation.
## The Registry, the Entity and the Component
A registry can store and manage entities, as well as create views to iterate the
underlying data structures.
`Registry` is a class template that lets users decide what's the preferred type
to represent an entity. Because `std::uint32_t` is large enough for almost all
the cases, there exists also an alias named `DefaultRegistry` for
`Registry`.
Entities are represented by _entity identifiers_. An entity identifier is an
opaque type that users should not inspect or modify in any way. It carries
information about the entity itself and its version.
A registry can be used both to construct and destroy entities:
```cpp
// constructs a naked entity with no components and returns its identifier
auto entity = registry.create();
// destroys an entity and all its components
registry.destroy(entity);
```
Entities can also be destroyed _by type_, that is by specifying the types of the
tags or components that identify them:
```cpp
// destroys the entity that owns the given tag, if any
registry.destroy(entt::tag_t{});
// destroys the entities that own the given components, if any
registry.destroy();
```
When an entity is destroyed, the registry can freely reuse it internally with a
slightly different identifier. In particular, the version of an entity is
increased each and every time it's discarded.
In case entity identifiers are stored around, the registry offers all the
functionalities required to test them and get out of the them all the
information they carry:
```cpp
// returns true if the entity is still valid, false otherwise
bool b = registry.valid(entity);
// gets the version contained in the entity identifier
auto version = registry.version(entity);
// gets the actual version for the given entity
auto curr = registry.current(entity);
```
Components can be assigned to or removed from entities at any time with a few
calls to member functions of the registry. As for the entities, the registry
offers also a set of functionalities users can use to work with the components.
The `assign` member function template creates, initializes and assigns to an
entity the given component. It accepts a variable number of arguments to
construct the component itself if present:
```cpp
registry.assign(entity, 0., 0.);
// ...
Velocity &velocity = registry.assign(entity);
velocity.dx = 0.;
velocity.dy = 0.;
```
If an entity already has the given component, the `replace` member function
template can be used to replace it:
```cpp
registry.replace(entity, 0., 0.);
// ...
Velocity &velocity = registry.replace(entity);
velocity.dx = 0.;
velocity.dy = 0.;
```
In case users want to assign a component to an entity, but it's unknown whether
the entity already has it or not, `accommodate` does the work in a single call
(there is a performance penalty to pay for this mainly due to the fact that it
has to check if the entity already has the given component or not):
```cpp
registry.accommodate(entity, 0., 0.);
// ...
Velocity &velocity = registry.accommodate(entity);
velocity.dx = 0.;
velocity.dy = 0.;
```
Note that `accommodate` is a slightly faster alternative for the following
`if/else` statement and nothing more:
```cpp
if(registry.has(entity)) {
registry.replace(entity, arg1, argN);
} else {
registry.assign(entity, arg1, argN);
}
```
As already shown, if in doubt about whether or not an entity has one or more
components, the `has` member function template may be useful:
```cpp
bool b = registry.has(entity);
```
On the other side, if the goal is to delete a single component, the `remove`
member function template is the way to go when it's certain that the entity owns
a copy of the component:
```cpp
registry.remove(entity);
```
Otherwise consider to use the `reset` member function. It behaves similarly to
`remove` but with a strictly defined behavior (and a performance penalty is the
price to pay for this). In particular it removes the component if and only if it
exists, otherwise it returns safely to the caller:
```cpp
registry.reset(entity);
```
There exist also two other _versions_ of the `reset` member function:
* If no entity is passed to it, `reset` will remove the given component from
each entity that has it:
```cpp
registry.reset();
```
* If neither the entity nor the component are specified, all the entities still
in use and their components are destroyed:
```cpp
registry.reset();
```
Finally, references to components can be retrieved simply by doing this:
```cpp
const auto &cregistry = registry;
// const and non-const reference
const Position &position = cregistry.get(entity);
Position &position = registry.get(entity);
// const and non-const references
std::tuple tup = cregistry.get(entity);
std::tuple tup = registry.get(entity);
```
The `get` member function template gives direct access to the component of an
entity stored in the underlying data structures of the registry.
### Single instance components
In those cases where all what is needed is a single instance component, tags are
the right tool to achieve the purpose.
Tags undergo the same requirements of components. They can be either plain old
data structures or more complex and movable data structures with a proper
constructor.
Actually, the same type can be used both as a tag and as a component and the
registry will not complain about it. It is up to users to properly manage their
own types. In some cases, the tag `tag_t` must also be used in order to
disambiguate overloads of member functions.
Attaching tags to entities and removing them is trivial:
```cpp
auto player = registry.create();
auto camera = registry.create();
// attaches a default-initialized tag to an entity
registry.assign(entt::tag_t{}, player);
// attaches a tag to an entity and initializes it
registry.assign(entt::tag_t{}, camera, player);
// removes tags from their owners
registry.remove();
registry.remove();
```
In case a tag already has an owner, its content can be updated by means of the
`replace` member function template and the ownership of the tag can be
transferred to another entity using the `move` member function template:
```
// replaces the content of the given tag
Point &point = registry.replace(entt::tag_t{}, 1.f, 1.f);
// transfers the ownership of the tag to another entity
entity_type prev = registry.move(next);
```
If in doubt about whether or not a tag already has an owner, the `has` member
function template may be useful:
```cpp
bool b = registry.has();
```
References to tags can be retrieved simply by doing this:
```cpp
const auto &cregistry = registry;
// either a non-const reference ...
PlayingCharacter &player = registry.get();
// ... or a const one
const Camera &camera = cregistry.get();
```
The `get` member function template gives direct access to the tag as stored in
the underlying data structures of the registry.
As shown above, in almost all the cases the entity identifier isn't required.
Since a single instance component can have only one associated entity, it
doesn't make much sense to mention it explicitly.
To find out who the owner is, just do the following:
```cpp
auto player = registry.attachee();
```
Note that iterating tags isn't possible for obvious reasons. Tags give direct
access to single entities and nothing more.
### Observe changes
Because of how the registry works internally, it stores a couple of signal
handlers for each pool in order to notify some of its data structures on the
construction and destruction of components.
These signal handlers are also exposed and made available to users. This is the
basic brick to build fancy things like dependencies and reactive systems.
To get a sink to be used to connect and disconnect listeners so as to be
notified on the creation of a component, use the `construction` member function:
```cpp
// connects a free function
registry.construction().connect<&MyFreeFunction>();
// connects a member function
registry.construction().connect(&instance);
// disconnects a free function
registry.construction().disconnect<&MyFreeFunction>();
// disconnects a member function
registry.construction().disconnect(&instance);
```
To be notified when components are destroyed, use the `destruction` member
function instead.
The function type of a listener is the same in both cases:
```cpp
void(Registry &, Entity);
```
In other terms, a listener is provided with the registry that triggered the
notification and the entity affected by the change. Note also that:
* Listeners are invoked **after** components have been assigned to entities.
* Listeners are invoked **before** components have been removed from entities.
* The order of invocation of the listeners isn't guaranteed in any case.
There are also some limitations on what a listener can and cannot do. In
particular:
* Connecting and disconnecting other functions from within the body of a
listener should be avoided. It can lead to undefined behavior in some cases.
* Assigning and removing components and tags from within the body of a listener
that observes the destruction of instances of a given type should be avoided.
It can lead to undefined behavior in some cases. This type of listeners is
intended to provide users with an easy way to perform cleanup and nothing
more.
To a certain extent, these limitations do not apply. However, it is risky to try
to force them and users should respect the limitations unless they know exactly
what they are doing. Subtle bugs are the price to pay in case of errors
otherwise.
In general, events and therefore listeners must not be used as replacements for
systems. They should not contain much logic and interactions with a registry
should be kept to a minimum, if possible. Note also that the greater the number
of listeners, the greater the performance hit when components are created or
destroyed.
#### Who let the tags out?
As an extension, signals are also provided with tags. Although they are not
strictly required internally, it makes sense that a user expects signal support
even when it comes to tags actually.
Signals for tags undergo exactly the same requirements of those introduced for
components. Also the function type for a listener is the same and it's invoked
with the same guarantees discussed above.
To get the sinks for a tag just use tag `tag_t` to disambiguate overloads of
member functions as in the following example:
```cpp
registry.construction(entt::tag_t{}).connect<&MyFreeFunction>();
registry.destruction(entt::tag_t{}).connect(&instance);
```
Listeners for tags and components are managed separately and do not influence
each other in any case. Therefore, note that the greater the number of listeners
for a type, the greater the performance hit when a tag of the given type is
created or destroyed.
### Runtime components
Defining components at runtime is useful to support plugin systems and mods in
general. However, it seems impossible with a tool designed around a bunch of
templates. Indeed it's not that difficult.
Of course, some features cannot be easily exported into a runtime
environment. As an example, sorting a group of components defined at runtime
isn't for free if compared to most of the other operations. However, the basic
functionalities of an entity-component system such as `EnTT` fit the problem
perfectly and can also be used to manage runtime components if required.
All that is necessary to do it is to know the identifiers of the components. An
identifier is nothing more than a number or similar that can be used at runtime
to work with the type system.
In `EnTT`, identifiers are easily accessible:
```cpp
entt::DefaultRegistry registry;
// standard component identifier
auto ctype = registry.type();
// single instance component identifier
auto ttype = registry.type(entt::tag_t{});
```
Once the identifiers are made available, almost everything becomes pretty
simple.
#### A journey through a plugin
`EnTT` comes with an example (actually a test) that shows how to integrate
compile-time and runtime components in a stack based JavaScript environment. It
uses [`Duktape`](https://github.com/svaarala/duktape) under the hood, mainly
because I wanted to learn how it works at the time I was writing the code.
The code is not production-ready and overall performance can be highly improved.
However, I sacrificed optimizations in favor of a more readable piece of code. I
hope I succeeded.
Note also that this isn't neither the only nor (probably) the best way to do it.
In fact, the right way depends on the scripting language and the problem one is
facing in general.
That being said, feel free to use it at your own risk.
The basic idea is that of creating a compile-time component aimed to map all the
runtime components assigned to an entity.
Identifiers come in use to address the right function from a map when invoked
from the runtime environment and to filter entities when iterating.
With a bit of gymnastic, one can narrow views and improve the performance to
some extent but it was not the goal of the example.
### Sorting: is it possible?
It goes without saying that sorting entities and components is possible with
`EnTT`.
In fact, there are two functions that respond to slightly different needs:
* Components can be sorted directly:
```cpp
registry.sort([](const auto &lhs, const auto &rhs) {
return lhs.z < rhs.z;
});
```
There exists also the possibility to use a custom sort function object, as
long as it adheres to the requirements described in the inline
documentation.
This is possible mainly because users can get much more with a custom sort
function object if the pattern of usage is known. As an example, in case of an
almost sorted pool, quick sort could be much, much slower than insertion sort.
* Components can be sorted according to the order imposed by another component:
```cpp
registry.sort();
```
In this case, instances of `Movement` are arranged in memory so that cache
misses are minimized when the two components are iterated together.
### Snapshot: complete vs continuous
The `Registry` class offers basic support to serialization.
It doesn't convert components and tags to bytes directly, there wasn't the need
of another tool for serialization out there. Instead, it accepts an opaque
object with a suitable interface (namely an _archive_) to serialize its internal
data structures and restore them later. The way types and instances are
converted to a bunch of bytes is completely in charge to the archive and thus to
final users.
The goal of the serialization part is to allow users to make both a dump of the
entire registry or a narrower snapshot, that is to select only the components
and the tags in which they are interested.
Intuitively, the use cases are different. As an example, the first approach is
suitable for local save/restore functionalities while the latter is suitable for
creating client-server applications and for transferring somehow parts of the
representation side to side.
To take a snapshot of the registry, use the `snapshot` member function. It
returns a temporary object properly initialized to _save_ the whole registry or
parts of it.
Example of use:
```cpp
OutputArchive output;
registry.snapshot()
.entities(output)
.destroyed(output)
.component(output)
.tag(output);
```
It isn't necessary to invoke all these functions each and every time. What
functions to use in which case mostly depends on the goal and there is not a
golden rule to do that.
The `entities` member function asks the registry to serialize all the entities
that are still in use along with their versions. On the other side, the
`destroyed` member function tells to the registry to serialize the entities that
have been destroyed and are no longer in use.
These two functions can be used to save and restore the whole set of entities
with the versions they had during serialization.
The `component` member function is a function template the aim of which is to
store aside components. The presence of a template parameter list is a
consequence of a couple of design choices from the past and in the present:
* First of all, there is no reason to force a user to serialize all the
components at once and most of the times it isn't desiderable. As an example,
in case the stuff for the HUD in a game is put into the registry for some
reasons, its components can be freely discarded during a serialization step
because probably the software already knows how to reconstruct the HUD
correctly from scratch.
* Furthermore, the registry makes heavy use of _type-erasure_ techniques
internally and doesn't know at any time what types of components it contains.
Therefore being explicit at the call point is mandatory.
There exists also another version of the `component` member function that
accepts a range of entities to serialize. This version is a bit slower than the
other one, mainly because it iterates the range of entities more than once for
internal purposes. However, it can be used to filter out those entities that
shouldn't be serialized for some reasons.
As an example:
```cpp
const auto view = registry.view();
OutputArchive output;
registry.snapshot()
.component(output, view.cbegin(), view.cend());
```
The `tag` member function is similar to the previous one, apart from the fact
that it works with tags and not with components.
Note also that both `component` and `tag` store items along with entities. It
means that they work properly without a call to the `entities` member function.
Once a snapshot is created, there exist mainly two _ways_ to load it: as a whole
and in a kind of _continuous mode_.
The following sections describe both loaders and archives in details.
#### Snapshot loader
A snapshot loader requires that the destination registry be empty and loads all
the data at once while keeping intact the identifiers that the entities
originally had.
To do that, the registry offers a member function named `restore` that returns a
temporary object properly initialized to _restore_ a snapshot.
Example of use:
```cpp
InputArchive input;
registry.restore()
.entities(input)
.destroyed(input)
.component(input)
.tag(input)
.orphans();
```
It isn't necessary to invoke all these functions each and every time. What
functions to use in which case mostly depends on the goal and there is not a
golden rule to do that. For obvious reasons, what is important is that the data
are restored in exactly the same order in which they were serialized.
The `entities` and `destroyed` member functions restore the sets of entities and
the versions that the entities originally had at the source.
The `component` member function restores all and only the components specified
and assigns them to the right entities. Note that the template parameter list
must be exactly the same used during the serialization. The same applies to the
`tag` member function.
The `orphans` member function literally destroys those entities that have
neither components nor tags. It's usually useless if the snapshot is a full dump
of the source. However, in case all the entities are serialized but only few
components and tags are saved, it could happen that some of the entities have
neither components nor tags once restored. The best users can do to deal with
them is to destroy those entities and thus update their versions.
#### Continuous loader
A continuous loader is designed to load data from a source registry to a
(possibly) non-empty destination. The loader can accommodate in a registry more
than one snapshot in a sort of _continuous loading_ that updates the
destination one step at a time.
Identifiers that entities originally had are not transferred to the target.
Instead, the loader maps remote identifiers to local ones while restoring a
snapshot. Because of that, this kind of loader offers a way to update
automatically identifiers that are part of components or tags (as an example, as
data members or gathered in a container).
Another difference with the snapshot loader is that the continuous loader does
not need to work with the private data structures of a registry. Furthermore, it
has an internal state that must persist over time. Therefore, there is no reason
to create it by means of a registry, or to limit its lifetime to that of a
temporary object.
Example of use:
```cpp
entt::ContinuousLoader loader{registry};
InputArchive input;
loader.entities(input)
.destroyed(input)
.component(input, &DirtyComponent::parent, &DirtyComponent::child)
.tag(input, &DirtyTag::container)
.orphans()
.shrink();
```
It isn't necessary to invoke all these functions each and every time. What
functions to use in which case mostly depends on the goal and there is not a
golden rule to do that. For obvious reasons, what is important is that the data
are restored in exactly the same order in which they were serialized.
The `entities` and `destroyed` member functions restore groups of entities and
map each entity to a local counterpart when required. In other terms, for each
remote entity identifier not yet registered by the loader, the latter creates a
local identifier so that it can keep the local entity in sync with the remote
one.
The `component` and `tag` member functions restore all and only the components
and the tags specified and assign them to the right entities.
In case the component or the tag contains entities itself (either as data
members of type `entity_type` or as containers of entities), the loader can
update them automatically. To do that, it's enough to specify the data members
to update as shown in the example.
The `orphans` member function literally destroys those entities that have
neither components nor tags after a restore. It has exactly the same purpose
described in the previous section and works the same way.
Finally, `shrink` helps to purge local entities that no longer have a remote
conterpart. Users should invoke this member function after restoring each
snapshot, unless they know exactly what they are doing.
#### Archives
Archives must publicly expose a predefined set of member functions. The API is
straightforward and consists only of a group of function call operators that
are invoked by the snapshot class and the loaders.
In particular:
* An output archive, the one used when creating a snapshot, must expose a
function call operator with the following signature to store entities:
```cpp
void operator()(Entity);
```
Where `Entity` is the type of the entities used by the registry. Note that all
the member functions of the snapshot class make also an initial call to this
endpoint to save the _size_ of the set they are going to store.
In addition, an archive must accept a pair of entity and either component or
tag for each type to be serialized. Therefore, given a type `T`, the archive
must contain a function call operator with the following signature:
```cpp
void operator()(Entity, const T &);
```
The output archive can freely decide how to serialize the data. The register
is not affected at all by the decision.
* An input archive, the one used when restoring a snapshot, must expose a
function call operator with the following signature to load entities:
```cpp
void operator()(Entity &);
```
Where `Entity` is the type of the entities used by the registry. Each time the
function is invoked, the archive must read the next element from the
underlying storage and copy it in the given variable. Note that all the member
functions of a loader class make also an initial call to this endpoint to read
the _size_ of the set they are going to load.
In addition, the archive must accept a pair of entity and either component or
tag for each type to be restored. Therefore, given a type `T`, the archive
must contain a function call operator with the following signature:
```cpp
void operator()(Entity &, T &);
```
Every time such an operator is invoked, the archive must read the next
elements from the underlying storage and copy them in the given variables.
#### One example to rule them all
`EnTT` comes with some examples (actually some tests) that show how to integrate
a well known library for serialization as an archive. It uses
[`Cereal C++`](https://uscilab.github.io/cereal/) under the hood, mainly
because I wanted to learn how it works at the time I was writing the code.
The code is not production-ready and it isn't neither the only nor (probably)
the best way to do it. However, feel free to use it at your own risk.
The basic idea is to store everything in a group of queues in memory, then bring
everything back to the registry with different loaders.
### Prototype
A prototype defines a type of an application in terms of its parts. They can be
used to assign components to entities of a registry at once.
Roughly speaking, in most cases prototypes can be considered just as templates
to use to initialize entities according to _concepts_. In fact, users can create
how many prototypes they want, each one initialized differently from the others.
The following is an example of use of a prototype:
```cpp
entt::DefaultRegistry registry;
entt::DefaultPrototype prototype{registry};
prototype.set(100.f, 100.f);
prototype.set(0.f, 0.f);
// ...
const auto entity = prototype();
```
To assign and remove components from a prototype, it offers two dedicated member
functions named `set` and `unset`. The `has` member function can be used to know
if a given prototype contains one or more components and the `get` member
function can be used to retrieve the components.
Creating an entity from a prototype is straightforward:
* To create a new entity from scratch and assign it a prototype, this is the way
to go:
```cpp
const auto entity = prototype();
```
It is equivalent to the following invokation:
```cpp
const auto entity = prototype.create();
```
* In case we want to initialize an already existing entity, we can provide the
`operator()` directly with the entity identifier:
```cpp
prototype(entity);
```
It is equivalent to the following invokation:
```cpp
prototype.assign(entity);
```
Note that existing components aren't overwritten in this case. Only those
components that the entity doesn't own yet are copied over. All the other
components remain unchanged.
* Finally, to assign or replace all the components for an entity, thus
overwriting existing ones:
```cpp
prototype.accommodate(entity);
```
In the examples above, the prototype uses its underlying registry to create
entities and components both for its purposes and when it's cloned. To use a
different repository to clone a prototype, all the member functions accept also
a reference to a valid registry as a first argument.
Prototypes are a very useful tool that can save a lot of typing sometimes.
Furthermore, the codebase may be easier to maintain, since updating a prototype
is much less error prone than jumping around in the codebase to update all the
snippets copied and pasted around to initialize entities and components.
### Helpers
The so called _helpers_ are small classes and functions mainly designed to offer
built-in support for the most basic functionalities.
The list of helpers will grow longer as time passes and new ideas come out.
#### Dependency function
A _dependency function_ is a predefined listener, actually a function template
to use to automatically assign components to an entity when a type has a
dependency on some other types.
The following adds components `AType` and `AnotherType` whenever `MyType` is
assigned to an entity:
```cpp
entt::connnect(registry.construction());
```
A component is assigned to an entity and thus default initialized only in case
the entity itself hasn't it yet. It means that already existent components won't
be overriden.
A dependency can easily be broken by means of the following function template:
```cpp
entt::disconnect(registry.construction());
```
#### Labels
There's nothing magical about the way labels can be assigned to entities while
avoiding a performance hit at runtime. Nonetheless, the syntax can be annoying
and that's why a more user-friendly shortcut is provided to do it.
This shortcut is the alias template `entt::label`.
If used in combination with hashed strings, it helps to use labels where types
would be required otherwise. As an example:
```cpp
registry.assign>(entity);
```
### Null entity
In `EnTT`, there exists a sort of _null entity_ made available to users that is
accessible via the `entt::null` variable.
The library guarantees that the following expression always returns false:
```cpp
registry.valid(entt::null);
```
In other terms, a registry will reject the null entity in all cases because it
isn't considered valid. It means that the null entity cannot own components or
tags for obvious reasons.
The type of the null entity is internal and should not be used for any purpose
other than defining the null entity itself. However, there exist implicit
conversions from the null entity to identifiers of any allowed type:
```cpp
typename entt::DefaultRegistry::entity_type null = entt::null;
```
Similarly, the null entity can be compared to any other identifier:
```cpp
const auto entity = registry.create();
const bool null = (entity == entt::null);
```
## View: to persist or not to persist?
First of all, it is worth answering an obvious question: why views?
Roughly speaking, they are a good tool to enforce single responsibility. A
system that has access to a registry can create and destroy entities, as well as
assign and remove components. On the other side, a system that has access to a
view can only iterate entities and their components, then read or update the
data members of the latter.
It is a subtle difference that can help designing a better software sometimes.
There are mainly four kinds of views: standard (also known as `View`),
persistent (also known as `PersistentView`), raw (also known as `RawView`) and
runtime (also known as `RuntimeView`).
All of them have pros and cons to take in consideration. In particular:
* Standard views:
Pros:
* They work out-of-the-box and don't require any dedicated data structure.
* Creating and destroying them isn't expensive at all because they don't have
any type of initialization.
* They are the best tool for iterating entities for a single component.
* They are the best tool for iterating entities for multiple components when
one of the components is assigned to a significantly low number of entities.
* They don't affect any other operations of the registry.
Cons:
* Their performance tend to degenerate when the number of components to
iterate grows up and the most of the entities have all of them.
* Persistent views:
Pros:
* Once prepared, creating and destroying them isn't expensive at all because
they don't have any type of initialization.
* They are the best tool for iterating entities for multiple components when
most entities have them all.
Cons:
* They have dedicated data structures and thus affect the memory usage to a
minimal extent.
* If not previously prepared, the first time they are used they go through an
initialization step that could take a while.
* They affect to a minimum the creation and destruction of entities and
components. In other terms: the more persistent views there will be, the
less performing will be creating and destroying entities and components.
* Raw views:
Pros:
* They work out-of-the-box and don't require any dedicated data structure.
* Creating and destroying them isn't expensive at all because they don't have
any type of initialization.
* They are the best tool for iterating components when it is not necessary to
know which entities they belong to.
* They don't affect any other operations of the registry.
Cons:
* They can be used to iterate only one type of component at a time.
* They don't return the entity to which a component belongs to the caller.
* Runtime views:
Pros:
* Their lists of components are defined at runtime and not at compile-time.
* Creating and destroying them isn't expensive at all because they don't have
any type of initialization.
* They are the best tool for things like plugin systems and mods in general.
* They don't affect any other operations of the registry.
Cons:
* Their performances are definitely lower than those of all the other views,
although they are still usable and sufficient for most of the purposes.
To sum up and as a rule of thumb:
* Use a raw view to iterate components only (no entities) for a given type.
* Use a standard view to iterate entities and components for a single type.
* Use a standard view to iterate entities and components for multiple types when
the number of types is low. Standard views are really optimized and persistent
views won't add much in this case.
* Use a standard view to iterate entities and components for multiple types when
a significantly low number of entities have one of the components.
* Use a standard view in all those cases where a persistent view would give a
boost to performance but the iteration isn't performed frequently.
* Prepare and use a persistent view when you want to iterate only entities for
multiple components.
* Prepare and use a persistent view when you want to iterate entities for
multiple components and each component is assigned to a great number of
entities but the intersection between the sets of entities is small.
* Prepare and use a persistent view in all the cases where a standard view
wouldn't fit well otherwise.
* Finally, in case you don't know at compile-time what are the components to
use, choose a runtime view and set them during execution.
To easily iterate entities and components, all the views offer the common
`begin` and `end` member functions that allow users to use a view in a typical
range-for loop. Almost all the views offer also a *more functional* `each`
member function that accepts a callback for convenience.
Continue reading for more details or refer to the inline documentation.
### Standard View
A standard view behaves differently if it's constructed for a single component
or if it has been requested to iterate multiple components. Even the API is
different in the two cases.
All that they share is the way they are created by means of a registry:
```cpp
// single component standard view
auto single = registry.view();
// multi component standard view
auto multi = registry.view();
```
For all that remains, it's worth discussing them separately.
#### Single component standard view
Single component standard views are specialized in order to give a boost in
terms of performance in all the situation. This kind of views can access the
underlying data structures directly and avoid superfluous checks.
They offer a bunch of functionalities to get the number of entities they are
going to return and a raw access to the entity list as well as to the component
list. It's also possible to ask a view if it contains a given entity.
Refer to the inline documentation for all the details.
There is no need to store views around for they are extremely cheap to
construct, even though they can be copied without problems and reused freely. In
fact, they return newly created and correctly initialized iterators whenever
`begin` or `end` are invoked.
To iterate a single component standard view, either use it in a range-for loop:
```cpp
auto view = registry.view();
for(auto entity: view) {
Renderable &renderable = view.get(entity);
// ...
}
```
Or rely on the `each` member function to iterate entities and get all their
components at once:
```cpp
registry.view().each([](auto entity, auto &renderable) {
// ...
});
```
The `each` member function is highly optimized. Unless users want to iterate
only entities, using `each` should be the preferred approach.
**Note**: prefer the `get` member function of a view instead of the `get` member
function template of a registry during iterations, if possible. However, keep in
mind that it works only with the components of the view itself.
#### Multi component standard view
Multi component standard views iterate entities that have at least all the given
components in their bags. During construction, these views look at the number of
entities available for each component and pick up a reference to the smallest
set of candidates in order to speed up iterations.
They offer fewer functionalities than their companion views for single
component. In particular, a multi component standard view exposes utility
functions to get the estimated number of entities it is going to return and to
know whether it's empty or not. It's also possible to ask a view if it contains
a given entity.
Refer to the inline documentation for all the details.
There is no need to store views around for they are extremely cheap to
construct, even though they can be copied without problems and reused freely. In
fact, they return newly created and correctly initialized iterators whenever
`begin` or `end` are invoked.
To iterate a multi component standard view, either use it in a range-for loop:
```cpp
auto view = registry.view();
for(auto entity: view) {
// a component at a time ...
Position &position = view.get(entity);
Velocity &velocity = view.get(entity);
// ... or multiple components at once
std::tuple tup = view.get(entity);
// ...
}
```
Or rely on the `each` member function to iterate entities and get all their
components at once:
```cpp
registry.view().each([](auto entity, auto &position, auto &velocity) {
// ...
});
```
The `each` member function is highly optimized. Unless users want to iterate
only entities or get only some of the components, using `each` should be the
preferred approach.
**Note**: prefer the `get` member function of a view instead of the `get` member
function template of a registry during iterations, if possible. However, keep in
mind that it works only with the components of the view itself.
### Persistent View
A persistent view returns all the entities and only the entities that have at
least the given components. Moreover, it's guaranteed that the entity list is
tightly packed in memory for fast iterations.
In general, persistent views don't stay true to the order of any set of
components unless users explicitly sort them.
Persistent views can be used only to iterate multiple components. To create this
kind of views, the tag `persistent_t` must also be used in order to disambiguate
overloads of the `view` member function:
```cpp
auto view = registry.view(entt::persistent_t{});
```
There is no need to store views around for they are extremely cheap to
construct, even though they can be copied without problems and reused freely. In
fact, they return newly created and correctly initialized iterators whenever
`begin` or `end` are invoked.
That being said, persistent views perform an initialization step the very first
time they are constructed and this could be quite costly. To avoid it, consider
asking to the registry to _prepare_ them when no entities have been created yet:
```cpp
registry.prepare();
```
If the registry is empty, preparation is extremely fast. Moreover the `prepare`
member function template is idempotent. Feel free to invoke it even more than
once: if the view has been already prepared before, the function returns
immediately and does nothing.
A persistent view offers a bunch of functionalities to get the number of
entities it's going to return, a raw access to the entity list and the
possibility to sort the underlying data structures according to the order of one
of the components for which it has been constructed. It's also possible to ask a
view if it contains a given entity.
Refer to the inline documentation for all the details.
To iterate a persistent view, either use it in a range-for loop:
```cpp
auto view = registry.view(entt::persistent_t{});
for(auto entity: view) {
// a component at a time ...
Position &position = view.get(entity);
Velocity &velocity = view.get(entity);
// ... or multiple components at once
std::tuple tup = view.get(entity);
// ...
}
```
Or rely on the `each` member function to iterate entities and get all their
components at once:
```cpp
registry.view(entt::persistent_t{}).each([](auto entity, auto &position, auto &velocity) {
// ...
});
```
Performance are more or less the same. The best approach depends mainly on
whether all the components have to be accessed or not.
**Note**: prefer the `get` member function of a view instead of the `get` member
function template of a registry during iterations, if possible. However, keep in
mind that it works only with the components of the view itself.
### Raw View
Raw views return all the components of a given type. This kind of views can
access components directly and avoid extra indirections like when components are
accessed via an entity identifier.
They offer a bunch of functionalities to get the number of instances they are
going to return and a raw access to the entity list as well as to the component
list.
Refer to the inline documentation for all the details.
Raw views can be used only to iterate components for a single type. To create
this kind of views, the tag `raw_t` must also be used in order to disambiguate
overloads of the `view` member function:
```cpp
auto view = registry.view(entt::raw_t{});
```
There is no need to store views around for they are extremely cheap to
construct, even though they can be copied without problems and reused freely. In
fact, they return newly created and correctly initialized iterators whenever
`begin` or `end` are invoked.
To iterate a raw view, use it in a range-for loop:
```cpp
auto view = registry.view(entt::raw_t{});
for(auto &&component: raw) {
// ...
}
```
Or rely on the `each` member function:
```cpp
registry.view(entt::raw_t{}).each([](auto &renderable) {
// ...
});
```
Performance are exactly the same in both cases.
**Note**: raw views don't have a `get` member function for obvious reasons.
### Runtime View
Runtime views iterate entities that have at least all the given components in
their bags. During construction, these views look at the number of entities
available for each component and pick up a reference to the smallest
set of candidates in order to speed up iterations.
They offer more or less the same functionalities of a multi component standard
view. However, they don't expose a `get` member function and users should refer
to the registry that generated the view to access components. In particular, a
runtime view exposes utility functions to get the estimated number of entities
it is going to return and to know whether it's empty or not. It's also possible
to ask a view if it contains a given entity.
Refer to the inline documentation for all the details.
Runtime view are extremely cheap to construct and should not be stored around in
any case. They should be used immediately after creation and then they should be
thrown away. The reasons for this go far beyond the scope of this document.
To iterate a runtime view, either use it in a range-for loop:
```cpp
using component_type = typename decltype(registry)::component_type;
component_type types[] = { registry.type(), registry.type() };
auto view = registry.view(std::cbegin(types), std::cend(types));
for(auto entity: view) {
// a component at a time ...
Position &position = registry.get(entity);
Velocity &velocity = registry.get(entity);
// ... or multiple components at once
std::tuple tup = view.get(entity);
// ...
}
```
Or rely on the `each` member function to iterate entities:
```cpp
using component_type = typename decltype(registry)::component_type;
component_type types[] = { registry.type(), registry.type() };
auto view = registry.view(std::cbegin(types), std::cend(types)).each([](auto entity) {
// ...
});
```
Performance are exactly the same in both cases.
**Note**: runtime views are meant for all those cases where users don't know at
compile-time what components to use to iterate entities. This is particularly
well suited to plugin systems and mods in general. Where possible, don't use
runtime views, as their performance are slightly inferior to those of the other
views.
### Give me everything
Views are narrow windows on the entire list of entities. They work by filtering
entities according to their components.
In some cases there may be the need to iterate all the entities still in use
regardless of their components. The registry offers a specific member function
to do that:
```cpp
registry.each([](auto entity) {
// ...
});
```
It returns to the caller all the entities that are still in use by means of the
given function.
As a rule of thumb, consider using a view if the goal is to iterate entities
that have a determinate set of components. A view is usually much faster than
combining this function with a bunch of custom tests.
In all the other cases, this is the way to go.
There exists also another member function to use to retrieve orphans. An orphan
is an entity that is still in use and has neither assigned components nor
tags.
The signature of the function is the same of `each`:
```cpp
registry.orphans([](auto entity) {
// ...
});
```
To test the _orphanity_ of a single entity, use the member function `orphan`
instead. It accepts a valid entity identifer as an argument and returns true in
case the entity is an orphan, false otherwise.
In general, all these functions can result in poor performance.
`each` is fairly slow because of some checks it performs on each and every
entity. For similar reasons, `orphans` can be even slower. Both functions should
not be used frequently to avoid the risk of a performance hit.
## Iterations: what is allowed and what is not
Most of the _ECS_ available out there have some annoying limitations (at least
from my point of view): entities and components cannot be created nor destroyed
during iterations.
`EnTT` partially solves the problem with a few limitations:
* Creating entities and components is allowed during iterations.
* Deleting an entity or removing its components is allowed during iterations if
it's the one currently returned by the view. For all the other entities,
destroying them or removing their components isn't allowed and it can result
in undefined behavior.
Iterators are invalidated and the behavior is undefined if an entity is modified
or destroyed and it's not the one currently returned by the view nor a newly
created one.
To work around it, possible approaches are:
* Store aside the entities and the components to be removed and perform the
operations at the end of the iteration.
* Mark entities and components with a proper tag component that indicates they
must be purged, then perform a second iteration to clean them up one by one.
A notable side effect of this feature is that the number of required allocations
is further reduced in most of the cases.
## Multithreading
In general, the entire registry isn't thread safe as it is. Thread safety isn't
something that users should want out of the box for several reasons. Just to
mention one of them: performance.
Views and consequently the approach adopted by `EnTT` are the great exception to
the rule. It's true that views and thus their iterators aren't thread safe by
themselves. Because of this users shouldn't try to iterate a set of components
and modify the same set concurrently. However:
* As long as a thread iterates the entities that have the component `X` or
assign and removes that component from a set of entities, another thread can
safely do the same with components `Y` and `Z` and everything will work like a
charm. As a trivial example, users can freely execute the rendering system and
iterate the renderable entities while updating a physic component concurrently
on a separate thread.
* Similarly, a single set of components can be iterated by multiple threads as
long as the components are neither assigned nor removed in the meantime. In
other words, a hypothetical movement system can start multiple threads, each
of which will access the components that carry information about velocity and
position for its entities.
This kind of entity-component systems can be used in single threaded
applications as well as along with async stuff or multiple threads. Moreover,
typical thread based models for _ECS_ don't require a fully thread safe registry
to work. Actually, users can reach the goal with the registry as it is while
working with most of the common models.
Because of the few reasons mentioned above and many others not mentioned, users
are completely responsible for synchronization whether required. On the other
hand, they could get away with it without having to resort to particular
expedients.
# Crash Course: core functionalities
`EnTT` comes with a bunch of core functionalities mostly used by the other parts
of the library itself.
Hardly users will include these features in their code, but it's worth
describing what `EnTT` offers so as not to reinvent the wheel in case of need.
## Compile-time identifiers
Sometimes it's useful to be able to give unique identifiers to types at
compile-time.
There are plenty of different solutions out there and I could have used one of
them. However, I decided to spend my time to define a compact and versatile tool
that fully embraces what the modern C++ has to offer.
The _result of my efforts_ is the `Identifier` class template:
```cpp
#include
// defines the identifiers for the given types
using ID = entt::Identifier;
// ...
switch(aTypeIdentifier) {
case ID::get():
// ...
break;
case ID::get():
// ...
break;
default:
// ...
}
```
This is all what the class template has to offer: a static `get` member function
that returns a numerical identifier for the given type. It can be used in any
context where constant expressions are required.
As long as the list remains unchanged, identifiers are also guaranteed to be the
same for every run. In case they have been used in a production environment and
a type has to be removed, one can just use a placeholder to left the other
identifiers unchanged:
```cpp
template struct IgnoreType {};
using ID = entt::Identifier<
ATypeStillValid,
IgnoreType,
AnotherTypeStillValid
>;
```
A bit ugly to see, but it works at least.
## Runtime identifiers
Sometimes it's useful to be able to give unique identifiers to types at
runtime.
There are plenty of different solutions out there and I could have used one of
them. In fact, I adapted the most common one to my requirements and used it
extensively within the entire library.
It's the `Family` class. Here is an example of use directly from the
entity-component system:
```cpp
using component_family = entt::Family;
// ...
template
component_type component() const noexcept {
return component_family::type();
}
```
This is all what a _family_ has to offer: a `type` member function that returns
a numerical identifier for the given type.
Please, note that identifiers aren't guaranteed to be the same for every run.
Indeed it mostly depends on the flow of execution.
## Hashed strings
A hashed string is a zero overhead resource identifier. Users can use
human-readable identifiers in the codebase while using their numeric
counterparts at runtime, thus without affecting performance.
The class has an implicit `constexpr` constructor that chews a bunch of
characters. Once created, all what one can do with it is getting back the
original string or converting it into a number.
The good part is that a hashed string can be used wherever a constant expression
is required and no _string-to-number_ conversion will take place at runtime if
used carefully.
Example of use:
```cpp
auto load(entt::HashedString::hash_type resource) {
// uses the numeric representation of the resource to load and return it
}
auto resource = load(entt::HashedString{"gui/background"});
```
There is also a _user defined literal_ dedicated to hashed strings to make them
more user-friendly:
```cpp
constexpr auto str = "text"_hs;
```
### Conflicts
The hashed string class uses internally FNV-1a to compute the numeric
counterpart of a string. Because of the _pigeonhole principle_, conflicts are
possible. This is a fact.
There is no silver bullet to solve the problem of conflicts when dealing with
hashing functions. In this case, the best solution seemed to be to give up.
That's all.
After all, human-readable resource identifiers aren't something strictly defined
and over which users have not the control. Choosing a slightly different
identifier is probably the best solution to make the conflict disappear in this
case.
## Monostate
The monostate pattern is often presented as an alternative to a singleton based
configuration system. This is exactly its purpose in `EnTT`. Moreover, this
implementation is thread safe by design (hopefully).
Keys are represented by hashed strings, values are basic types like `int`s or
`bool`s. Values of different types can be associated to each key, even more than
one at a time. Because of this, users must pay attention to use the same type
both during an assignment and when they try to read back their data. Otherwise,
they will probably incur in unexpected results.
Example of use:
```cpp
entt::Monostate{} = true;
entt::Monostate<"mykey"_hs>{} = 42;
// ...
const bool b = entt::Monostate<"mykey"_hs>{};
const int i = entt::Monostate{};
```
# Crash Course: service locator
Usually service locators are tightly bound to the services they expose and it's
hard to define a general purpose solution. This template based implementation
tries to fill the gap and to get rid of the burden of defining a different
specific locator for each application.
This class is tiny, partially unsafe and thus risky to use. Moreover it doesn't
fit probably most of the scenarios in which a service locator is required. Look
at it as a small tool that can sometimes be useful if the user knows how to
handle it.
The API is straightforward. The basic idea is that services are implemented by
means of interfaces and rely on polymorphism.
The locator is instantiated with the base type of the service if any and a
concrete implementation is provided along with all the parameters required to
initialize it. As an example:
```cpp
// the service has no base type, a locator is used to treat it as a kind of singleton
entt::ServiceLocator::set(params...);
// sets up an opaque service
entt::ServiceLocator::set(params...);
// resets (destroys) the service
entt::ServiceLocator::reset();
```
The locator can also be queried to know if an active service is currently set
and to retrieve it if necessary (either as a pointer or as a reference):
```cpp
// no service currently set
auto empty = entt::ServiceLocator::empty();
// gets a (possibly empty) shared pointer to the service ...
std::shared_ptr ptr = entt::ServiceLocator::get();
// ... or a reference, but it's undefined behaviour if the service isn't set yet
AudioInterface &ref = entt::ServiceLocator::ref();
```
A common use is to wrap the different locators in a container class, creating
aliases for the various services:
```cpp
struct Locator {
using Camera = entt::ServiceLocator;
using Audio = entt::ServiceLocator;
// ...
};
// ...
void init() {
Locator::Camera::set();
Locator::Audio::set(params...);
// ...
}
```
# Crash Course: cooperative scheduler
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(void *);`
It's invoked at the first tick, immediately before an update. The `void *`
parameter is an opaque pointer to user data (if any) forwarded directly to the
process during an update.
* `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 MyProcess: entt::Process {
using delta_type = std::uint32_t;
void update(delta_type delta, void *) {
remaining = delta > remaining ? delta_type{] : (remaining - delta);
// ...
if(!remaining) {
succeed();
}
}
void init(void *data) {
remaining = *static_cast(data);
}
private:
delta_type remaining;
};
```
### Adaptor
Lambdas and functors can't be used directly with a scheduler for they are not
properly defined processes with managed life cycles.
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 once more the next tick.
A process can also have a child. In this case, the process is replaced with
its child when it terminates if it returns with success. In case of errors,
both the 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
Scheduler 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
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's enough to
indicate its type and submit all the parameters required to construct it to
the `attach` member function:
```cpp
scheduler.attach("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.
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();
```
To update a scheduler and thus 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();
```
# Crash Course: resource management
Resource management is usually one of the most critical part of a software like
a game. Solutions are often tuned to the particular application. There exist
several approaches and all of them are perfectly fine as long as they fit the
requirements of the piece of software in which they are used.
Examples are loading everything on start, loading on request, predictive
loading, and so on.
`EnTT` doesn't pretend to offer a _one-fits-all_ solution for the different
cases. Instead, it offers a minimal and perhaps trivial cache that can be useful
most of the time during prototyping and sometimes even in a production
environment.
For those interested in the subject, the plan is to improve it considerably over
time in terms of performance, memory usage and functionalities. Hoping to make
it, of course, one step at a time.
## The resource, the loader and the cache
There are three main actors in the model: the resource, the loader and the
cache.
The _resource_ is whatever the user wants it to be. An image, a video, an audio,
whatever. There are no limits.
As a minimal example:
```cpp
struct MyResource { const int value; };
```
A _loader_ is a class the aim of which is to load a specific resource. It has to
inherit directly from the dedicated base class as in the following example:
```cpp
struct MyLoader final: entt::ResourceLoader {
// ...
};
```
Where `MyResource` is the type of resources it creates.
A resource loader must also expose a public const member function named `load`
that accepts a variable number of arguments and returns a shared pointer to a
resource.
As an example:
```cpp
struct MyLoader: entt::ResourceLoader {
std::shared_ptr load(int value) const {
// ...
return std::shared_ptr(new MyResource{ value });
}
};
```
In general, resource loaders should not have a state or retain data of any type.
They should let the cache manage their resources instead.
As a side note, base class and CRTP idiom aren't strictly required with the
current implementation. One could argue that a cache can easily work with
loaders of any type. However, future changes won't be breaking ones by forcing
the use of a base class today and that's why the model is already in its place.
Finally, a cache is a specialization of a class template tailored to a specific
resource:
```cpp
using MyResourceCache = entt::ResourceCache;
// ...
MyResourceCache cache{};
```
The idea is to create different caches for different types of resources and to
manage each one independently and in the most appropriate way.
As a (very) trivial example, audio tracks can survive in most of the scenes of
an application while meshes can be associated with a single scene and then
discarded when the user leaves it.
A cache offers a set of basic functionalities to query its internal state and to
_organize_ it:
```cpp
// gets the number of resources managed by a cache
const auto size = cache.size();
// checks if a cache contains at least a valid resource
const auto empty = cache.empty();
// clears a cache and discards its content
cache.clear();
```
Besides these member functions, it contains what is needed to load, use and
discard resources of the given type.
Before to explore this part of the interface, it makes sense to mention how
resources are identified. The type of the identifiers to use is defined as:
```cpp
entt::ResourceCache::resource_type
```
Where `resource_type` is an alias for `entt::HashedString`. Therefore, resource
identifiers are created explicitly as in the following example:
```cpp
constexpr auto identifier = entt::ResourceCache::resource_type{"my/resource/identifier"};
// this is equivalent to the following
constexpr auto hs = entt::HashedString{"my/resource/identifier"};
```
The class `HashedString` is described in a dedicated section, so I won't do in
details here.
Resources are loaded and thus stored in a cache through the `load` member
function. It accepts the loader to use as a template parameter, the resource
identifier and the parameters used to construct the resource as arguments:
```cpp
// uses the identifier declared above
cache.load(identifier, 0);
// uses a const char * directly as an identifier
cache.load("another/identifier", 42);
```
The return value can be used to know if the resource has been loaded correctly.
In case the loader returns an invalid pointer or the resource already exists in
the cache, a false value is returned:
```cpp
if(!cache.load("another/identifier", 42)) {
// ...
}
```
Unfortunately, in this case there is no way to know what was the problem
exactly. However, before trying to load a resource or after an error, one can
use the `contains` member function to know if a cache already contains a
specific resource:
```cpp
auto exists = cache.contains("my/identifier");
```
There exists also a member function to use to force a reload of an already
existing resource if needed:
```cpp
auto result = cache.reload("another/identifier", 42);
```
As above, the function returns true in case of success, false otherwise. The
sole difference in this case is that an error necessarily means that the loader
has failed for some reasons to load the resource.
Note that the `reload` member function is a kind of alias of the following
snippet:
```cpp
cache.discard(identifier);
cache.load(identifier, 42);
```
Where the `discard` member function is used to get rid of a resource if loaded.
In case the cache doesn't contain a resource for the given identifier, the
function does nothing and returns immediately.
So far, so good. Resources are finally loaded and stored within the cache.
They are returned to users in the form of handles. To get one of them:
```cpp
auto handle = cache.handle("my/identifier");
```
The idea behind a handle is the same of the flyweight pattern. In other terms,
resources aren't copied around. Instead, instances are shared between handles.
Users of a resource owns a handle and it guarantees that a resource isn't
destroyed until all the handles are destroyed, even if the resource itself is
removed from the cache.
Handles are tiny objects both movable and copyable. They returns the contained
resource as a const reference on request:
* By means of the `get` member function:
```cpp
const auto &resource = handle.get();
```
* Using the proper cast operator:
```cpp
const auto &resource = handle;
```
* Through the dereference operator:
```cpp
const auto &resource = *handle;
```
The resource can also be accessed directly using the arrow operator if required:
```cpp
auto value = handle->value;
```
To test if a handle is still valid, the cast operator to `bool` allows users to
use it in a guard:
```cpp
if(handle) {
// ...
}
```
Finally, in case there is the need to load a resource and thus to get a handle
without storing the resource itself in the cache, users can rely on the `temp`
member function template.
The declaration is similar to the one of `load` but for the fact that it doesn't
return a boolean value. Instead, it returns a (possibly invalid) handle for the
resource:
```cpp
auto handle = cache.temp("another/identifier", 42);
```
Do not forget to test the handle for validity. Otherwise, getting the reference
to the resource it points may result in undefined behavior.
# Crash Course: events, signals and everything in between
Signals are usually a core part of games and software architectures in
general.
Roughly speaking, they help to decouple the various parts of a system while
allowing them to communicate with each other somehow.
The so called _modern C++_ comes with a tool that can be useful in these terms,
the `std::function`. As an example, it can be used to create delegates.
However, there is no guarantee that an `std::function` does not perform
allocations under the hood and this could be problematic sometimes. Furthermore,
it solves a problem but may not adapt well to other requirements that may arise
from time to time.
In case that the flexibility and potential of an `std::function` are not
required or where you are looking for something different, `EnTT` offers a full
set of classes to solve completely different problems.
## Signals
Signal handlers work with naked pointers, function pointers and pointers to
member functions. Listeners can be any kind of objects and the user is in charge
of connecting and disconnecting them from a signal to avoid crashes due to
different lifetimes. On the other side, performance shouldn't be affected that
much by the presence of such a signal handler.
A signal handler can be used as a private data member without exposing any
_publish_ functionality to the clients of a class. The basic idea is to impose a
clear separation between the signal itself and its _sink_ class, that is a tool
to be used to connect and disconnect listeners on the fly.
The API of a signal handler is straightforward. The most important thing is that
it comes in two forms: with and without a collector. In case a signal is
associated with a collector, all the values returned by the listeners can be
literally _collected_ and used later by the caller. Otherwise it works just like
a plain signal that emits events from time to time.
**Note**: collectors are allowed only in case of function types whose the return
type isn't `void` for obvious reasons.
To create instances of signal handlers there exist mainly two ways:
```cpp
// no collector type
entt::SigH signal;
// explicit collector type
entt::SigH> collector;
```
As expected, they offer all the basic functionalities required to know how many
listeners they contain (`size`) or if they contain at least a listener (`empty`)
and even to swap two signal handlers (`swap`).
Besides them, there are member functions to use both to connect and disconnect
listeners in all their forms by means of a sink:
```cpp
void foo(int, char) { /* ... */ }
struct S {
void bar(int, char) { /* ... */ }
};
// ...
S instance;
signal.sink().connect<&foo>();
signal.sink().connect(&instance);
// ...
// disconnects a free function
signal.sink().disconnect<&foo>();
// disconnect a specific member function of an instance ...
signal.sink().disconnect(&instance);
// ... or an instance as a whole
signal.sink().disconnect(&instance);
// discards all the listeners at once
signal.sink().disconnect();
```
Once listeners are attached (or even if there are no listeners at all), events
and data in general can be published through a signal by means of the `publish`
member function:
```cpp
signal.publish(42, 'c');
```
To collect data, the `collect` member function should be used instead. Below is
a minimal example to show how to use it:
```cpp
struct MyCollector {
std::vector vec{};
bool operator()(int v) noexcept {
vec.push_back(v);
return true;
}
};
int f() { return 0; }
int g() { return 1; }
// ...
entt::SigH> signal;
signal.sink().connect<&f>();
signal.sink().connect<&g>();
MyCollector collector = signal.collect();
assert(collector.vec[0] == 0);
assert(collector.vec[1] == 1);
```
As shown above, a collector must expose a function operator that accepts as an
argument a type to which the return type of the listeners can be converted.
Moreover, it has to return a boolean value that is false to stop collecting
data, true otherwise. This way one can avoid calling all the listeners in case
it isn't necessary.
## Delegate
A delegate can be used as general purpose invoker with no memory overhead for
free functions and member functions provided along with an instance on which
to invoke them.
It does not claim to be a drop-in replacement for an `std::function`, so do not
expect to use it whenever an `std::function` fits well. However, it can be used
to send opaque delegates around to be used to invoke functions as needed.
The interface is trivial. It offers a default constructor to create empty
delegates:
```cpp
entt::Delegate delegate{};
```
All what is needed to create an instance is to specify the type of the function
the delegate will _contain_, that is the signature of the free function or the
member function one wants to assign to it.
Attempting to use an empty delegate by invoking its function call operator
results in undefined behavior, most likely a crash actually. Before to use a
delegate, it must be initialized.
There exist two functions to do that, both named `connect`:
```cpp
int f(int i) { return i; }
struct MyStruct {
int f(int i) { return i }
};
// bind a free function to the delegate
delegate.connect<&f>();
// bind a member function to the delegate
MyStruct instance;
delegate.connect(&instance);
```
It hasn't a `disconnect` counterpart. Instead, there exists a `reset` member
function to clear it.
The `empty` member function can be used to know if a delegate is empty:
```cpp
const auto empty = delegate.empty();
```
Finally, to invoke a delegate, the function call operator is the way to go as
usual:
```cpp
auto ret = delegate(42);
```
Probably too much small and pretty poor of functionalities, but the delegate
class can help in a lot of cases and it has shown that it is worth keeping it
within the library.
## Event dispatcher
The event dispatcher class is designed so as to be used in a loop. It allows
users both to trigger immediate events or to queue events to be published all
together once per tick.
This class shares part of its API with the one of the signal handler, but it
doesn't require that all the types of events are specified when declared:
```cpp
// define a general purpose dispatcher that works with naked pointers
entt::Dispatcher dispatcher{};
```
In order to register an instance of a class to a dispatcher, its type must
expose one or more member functions of which the return types are `void` and the
argument lists are `const E &`, for each type of event `E`.
To ease the development, member functions that are named `receive` are
automatically detected and have not to be explicitly specified when registered.
In all the other cases, the name of the member function aimed to receive the
event must be provided to the `connect` member function of the sink bound to the
specific event:
```cpp
struct AnEvent { int value; };
struct AnotherEvent {};
struct Listener
{
void receive(const AnEvent &) { /* ... */ }
void method(const AnotherEvent &) { /* ... */ }
};
// ...
Listener listener;
dispatcher.sink().connect(&listener);
dispatcher.sink().connect(&listener);
```
The `disconnect` member function follows the same pattern and can be used to
selectively remove listeners:
```cpp
dispatcher.sink().disconnect(&listener);
dispatcher.sink().disconnect(&listener);
```
The `trigger` member function serves the purpose of sending an immediate event
to all the listeners registered so far. It offers a convenient approach that
relieves the user from having to create the event itself. Instead, it's enough
to specify the type of event and provide all the parameters required to
construct it.
As an example:
```cpp
dispatcher.trigger(42);
dispatcher.trigger();
```
Listeners are invoked immediately, order of execution isn't guaranteed. This
method can be used to push around urgent messages like an _is terminating_
notification on a mobile app.
On the other hand, the `enqueue` member function queues messages together and
allows to maintain control over the moment they are sent to listeners. The
signature of this method is more or less the same of `trigger`:
```cpp
dispatcher.enqueue(42);
dispatcher.enqueue();
```
Events are stored aside until the `update` member function is invoked, then all
the messages that are still pending are sent to the listeners at once:
```cpp
// emits all the events of the given type at once
dispatcher.update();
// emits all the events queued so far at once
dispatcher.update();
```
This way users can embed the dispatcher in a loop and literally dispatch events
once per tick to their systems.
## Event emitter
A general purpose event emitter thought mainly for those cases where it comes to
working with asynchronous stuff.
Originally designed to fit the requirements of
[`uvw`](https://github.com/skypjack/uvw) (a wrapper for `libuv` written in
modern C++), it was adapted later to be included in this library.
To create a custom emitter type, derived classes must inherit directly from the
base class as:
```cpp
struct MyEmitter: Emitter {
// ...
}
```
The full list of accepted types of events isn't required. Handlers are created
internally on the fly and thus each type of event is accepted by default.
Whenever an event is published, an emitter provides the listeners with a
reference to itself along with a const reference to the event. Therefore
listeners have an handy way to work with it without incurring in the need of
capturing a reference to the emitter itself.
In addition, an opaque object is returned each time a connection is established
between an emitter and a listener, allowing the caller to disconnect them at a
later time.
The opaque object used to handle connections is both movable and copyable. On
the other side, an event emitter is movable but not copyable by default.
To create new instances of an emitter, no arguments are required:
```cpp
MyEmitter emitter{};
```
Listeners must be movable and callable objects (free functions, lambdas,
functors, `std::function`s, whatever) whose function type is:
```cpp
void(const Event &, MyEmitter &)
```
Where `Event` is the type of event they want to listen.
There are two ways to attach a listener to an event emitter that differ
slightly from each other:
* To register a long-lived listener, use the `on` member function. It is meant
to register a listener designed to be invoked more than once for the given
event type.
As an example:
```cpp
auto conn = emitter.on([](const MyEvent &event, MyEmitter &emitter) {
// ...
});
```
The connection object can be freely discarded. Otherwise, it can be used later
to disconnect the listener if required.
* To register a short-lived listener, use the `once` member function. It is
meant to register a listener designed to be invoked only once for the given
event type. The listener is automatically disconnected after the first
invocation.
As an example:
```cpp
auto conn = emitter.once([](const MyEvent &event, MyEmitter &emitter) {
// ...
});
```
The connection object can be freely discarded. Otherwise, it can be used later
to disconnect the listener if required.
In both cases, the connection object can be used with the `erase` member
function:
```cpp
emitter.erase(conn);
```
There are also two member functions to use either to disconnect all the
listeners for a given type of event or to clear the emitter:
```cpp
// removes all the listener for the specific event
emitter.clear();
// removes all the listeners registered so far
emitter.clear();
```
To send an event to all the listeners that are interested in it, the `publish`
member function offers a convenient approach that relieves the user from having
to create the event:
```cpp
struct MyEvent { int i; };
// ...
emitter.publish(42);
```
Finally, the `empty` member function tests if there exists at least either a
listener registered with the event emitter or to a given type of event:
```cpp
bool empty;
// checks if there is any listener registered for the specific event
empty = emitter.empty();
// checks it there are listeners registered with the event emitter
empty = emitter.empty();
```
In general, the event emitter is a handy tool when the derived classes _wrap_
asynchronous operations, because it introduces a _nice-to-have_ model based on
events and listeners that kindly hides the complexity behind the scenes. However
it is not limited to such uses.
# Packaging Tools
`EnTT` is available for some of the most known packaging tools. In particular:
* [`vcpkg`](https://github.com/Microsoft/vcpkg/tree/master/ports/entt),
Microsoft VC++ Packaging Tool.
* [`Homebrew`](https://github.com/skypjack/homebrew-entt), the missing package
manager for macOS.
Available as a homebrew formula. Just type the following to install it:
```
brew install skypjack/entt/entt
```
Consider this list a work in progress and help me to make it longer.
# EnTT in Action
`EnTT` is widely used in private and commercial applications. I cannot even
mention most of them because of some signatures I put on some documents time
ago.
Fortunately, there are also people who took the time to implement open source
projects based on EnTT and did not hold back when it came to documenting them.
Below an incomplete list of projects and articles:
* [Minecraft](https://minecraft.net/en-us/attribution/): of course, **that**
Minecraft, by Mojang (see the open source attributions page).
* [Face Smash](https://play.google.com/store/apps/details?id=com.gamee.facesmash):
the emojis dominate the world, destroy them all with your facial expressions.
* [shiva](https://github.com/Milerius/shiva): modern C++ Engine with modularity.
* [Classic Tower Defence](https://github.com/kerndog73/Classic-Tower-Defence):
a tiny little tower defence game featuring a homemade font.
[Check it out](https://indi-kernick.itch.io/classic-tower-defence).
* [The Machine](https://github.com/Kerndog73/The-Machine): a box pushing puzzler
with logic gates and other cool stuff.
[Check it out](https://indi-kernick.itch.io/the-machine-web-version).
* [EnttPong](https://github.com/reworks/EnttPong): example game with `EnTT`.
* [Space Battle: Huge edition](http://victor.madtriangles.com/code%20experiment/2018/06/11/post-ecs-battle-huge.html):
huge space battle built entirely from scratch.
* [Space Battle](https://github.com/vblanco20-1/ECS_SpaceBattle): huge space
battle built on `UE4`.
* [Experimenting with ECS in UE4](http://victor.madtriangles.com/code%20experiment/2018/03/25/post-ue4-ecs-battle.html):
interesting article about `UE4` and `EnTT`.
* [Implementing ECS architecture in UE4](https://forums.unrealengine.com/development-discussion/c-gameplay-programming/1449913-implementing-ecs-architecture-in-ue4-giant-space-battle):
giant space battle.
* [MatchOneEntt](https://github.com/mhaemmerle/MatchOneEntt): port of
[Match One](https://github.com/sschmid/Match-One) for `Entitas-CSharp`.
* [Randballs](https://github.com/gale93/randballs): simple `SFML` and `EnTT`
playground.
* ...
If you know of other resources out there that are about `EnTT`, feel free to
open an issue or a PR and I'll be glad to add them to the list.
# Contributors
`EnTT` was written initially as a faster alternative to other well known and
open source entity-component systems. Nowadays this library is moving its first
steps. Much more will come in the future and hopefully I'm going to work on it
for a long time.
Requests for features, PR, suggestions ad feedback are highly appreciated.
If you find you can help me and want to contribute to the project with your
experience or you do want to get part of the project for some other reasons,
feel free to contact me directly (you can find the mail in the
[profile](https://github.com/skypjack)).
I can't promise that each and every contribution will be accepted, but I can
assure that I'll do my best to take them all seriously.
If you decide to participate, please see the guidelines for
[contributing](docs/CONTRIBUTING.md) before to create issues or pull requests.
Take also a look at the
[contributors list](https://github.com/skypjack/entt/blob/master/AUTHORS) to
know who has participated so far.
# License
Code and documentation Copyright (c) 2017-2018 Michele Caini.
Logo Copyright (c) 2018 Richard Caseres.
Code released under
[the MIT license](https://github.com/skypjack/entt/blob/master/LICENSE).
Documentation released under
[CC BY 4.0](https://creativecommons.org/licenses/by/4.0/).
Logo released under
[CC BY-SA 4.0](https://creativecommons.org/licenses/by-sa/4.0/).
# Support
## Donation
Developing and maintaining `EnTT` takes some time and lots of coffee. I'd like
to add more and more functionalities in future and turn it in a full-featured
solution.
If you want to support this project, you can offer me an espresso. I'm from
Italy, we're used to turning the best coffee ever in code. If you find that
it's not enough, feel free to support me the way you prefer.
Take a look at the donation button at the top of the page for more details or
just click [here](https://www.paypal.com/cgi-bin/webscr?cmd=_donations&business=W2HF9FESD5LJY&lc=IT&item_name=Michele%20Caini¤cy_code=EUR&bn=PP%2dDonationsBF%3abtn_donateCC_LG%2egif%3aNonHosted).
## Hire me
If you start using `EnTT` and need help, if you want a new feature and want me
to give it the highest priority, if you have any other reason to contact me:
do not hesitate. I'm available for hiring.
Feel free to take a look at my [profile](https://github.com/skypjack) and
contact me by mail.