# Crash Course: core functionalities
# Table of Contents
* [Introduction](#introduction)
* [Any as in any type](#any-as-in-any-type)
* [Small buffer optimization](#small-buffer-optimization)
* [Alignment requirement](#alignment-requirement)
* [Compressed pair](#compressed-pair)
* [Enum as bitmask](#enum-as-bitmask)
* [Hashed strings](#hashed-strings)
* [Wide characters](wide-characters)
* [Conflicts](#conflicts)
* [Iterators](#iterators)
* [Input iterator pointer](#input-iterator-pointer)
* [Iota iterator](#iota-iterator)
* [Iterable adaptor](#iterable-adaptor)
* [Memory](#memory)
* [Power of two and fast modulus](#power-of-two-and-fast-modulus)
* [Allocator aware unique pointers](#allocator-aware-unique-pointers)
* [Monostate](#monostate)
* [Type support](#type-support)
* [Built-in RTTI support](#built-in-rtti-support)
* [Type info](#type-info)
* [Almost unique identifiers](#almost-unique-identifiers)
* [Type traits](#type-traits)
* [Size of](#size-of)
* [Is applicable](#is-applicable)
* [Constness as](#constness-as)
* [Member class type](#member-class-type)
* [N-th argument](#n-th-argument)
* [Integral constant](#integral-constant)
* [Tag](#tag)
* [Type list and value list](#type-list-and-value-list)
* [Unique sequential identifiers](#unique-sequential-identifiers)
* [Compile-time generator](#compile-time-generator)
* [Runtime generator](#runtime-generator)
* [Utilities](#utilities)
# Introduction
`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.
# Any as in any type
`EnTT` comes with its own `any` type. It may seem redundant considering that
C++17 introduced `std::any`, but it is not (hopefully).
First of all, the _type_ returned by an `std::any` is a const reference to an
`std::type_info`, an implementation defined class that's not something everyone
wants to see in a software. Furthermore, there is no way to connect it with the
type system of the library and therefore with its integrated RTTI support.
Note that this class is largely used internally by the library itself.
The API is very similar to that of its most famous counterpart, mainly because
this class serves the same purpose of being an opaque container for any type of
value.
Instances of `any` also minimize the number of allocations by relying on a well
known technique called _small buffer optimization_ and a fake vtable.
Creating an object of the `any` type, whether empty or not, is trivial:
```cpp
// an empty container
entt::any empty{};
// a container for an int
entt::any any{0};
// in place construction
entt::any in_place{std::in_place_type, 42};
```
Alternatively, the `make_any` function serves the same purpose but requires to
always be explicit about the type:
```cpp
entt::any any = entt::make_any(42);
```
In both cases, the `any` class takes the burden of destroying the contained
element when required, regardless of the storage strategy used for the specific
object.
Furthermore, an instance of `any` isn't tied to an actual type. Therefore, the
wrapper is reconfigured when it's assigned a new object of a type other than
the one it contains.
There exists also a way to directly assign a value to the variable contained by
an `entt::any`, without necessarily replacing it. This is especially useful when
the object is used in _aliasing mode_, as described below:
```cpp
entt::any any{42};
entt::any value{3};
// assigns by copy
any.assign(value);
// assigns by move
any.assign(std::move(value));
```
The `any` class will also perform a check on the type information and whether or
not the original type was copy or move assignable, as appropriate.
In all cases, the `assign` function returns a boolean value to indicate the
success or failure of the operation.
When in doubt about the type of object contained, the `type` member function of
`any` returns a const reference to the `type_info` associated with its element,
or `type_id()` if the container is empty. The type is also used internally
when comparing two `any` objects:
```cpp
if(any == empty) { /* ... */ }
```
In this case, before proceeding with a comparison, it's verified that the _type_
of the two objects is actually the same.
Refer to the `EnTT` type system documentation for more details about how
`type_info` works and on possible risks of a comparison.
A particularly interesting feature of this class is that it can also be used as
an opaque container for const and non-const references:
```cpp
int value = 42;
entt::any any{std::in_place_type(value)};
entt::any cany = entt::make_any(value);
entt::any fwd = entt::forward_as_any(value);
any.emplace(value);
```
In other words, whenever `any` is explicitly told to construct an _alias_, it
acts as a pointer to the original instance rather than making a copy of it or
moving it internally. The contained object is never destroyed and users must
ensure that its lifetime exceeds that of the container.
Similarly, it's possible to create non-owning copies of `any` from an existing
object:
```cpp
// aliasing constructor
entt::any ref = other.as_ref();
```
In this case, it doesn't matter if the original container actually holds an
object or acts already as a reference for unmanaged elements, the new instance
thus created won't create copies and will only serve as a reference for the
original item.
This means that, starting from the example above, both `ref` and `other` will
point to the same object, whether it's initially contained in `other` or already
an unmanaged element.
As a side note, it's worth mentioning that, while everything works transparently
when it comes to non-const references, there are some exceptions when it comes
to const references.
In particular, the `data` member function invoked on a non-const instance of
`any` that wraps a const reference will return a null pointer in all cases.
To cast an instance of `any` to a type, the library offers a set of `any_cast`
functions in all respects similar to their most famous counterparts.
The only difference is that, in the case of `EnTT`, these won't raise exceptions
but will only trigger an assert in debug mode, otherwise resulting in undefined
behavior in case of misuse in release mode.
## Small buffer optimization
The `any` class uses a technique called _small buffer optimization_ to reduce
the number of allocations where possible.
The default reserved size for an instance of `any` is `sizeof(double[2])`.
However, this is also configurable if needed. In fact, `any` is defined as an
alias for `basic_any`, where `Len` is the size above.
Users can easily set a custom size or define their own aliases:
```cpp
using my_any = entt::basic_any;
```
This feature, in addition to allowing the choice of a size that best suits the
needs of an application, also offers the possibility of forcing dynamic creation
of objects during construction.
In other terms, if the size is 0, `any` avoids the use of any optimization and
always dynamically allocates objects (except for aliasing cases).
Note that the size of the internal storage as well as the alignment requirements
are directly part of the type and therefore contribute to define different types
that won't be able to interoperate with each other.
## Alignment requirement
The alignment requirement is optional and by default the most stringent (the
largest) for any object whose size is at most equal to the one provided.
The `basic_any` class template inspects the alignment requirements in each case,
even when not provided and may decide not to use the small buffer optimization
in order to meet them.
The alignment requirement is provided as an optional second parameter following
the desired size for the internal storage:
```cpp
using my_any = entt::basic_any;
```
Note that the alignment requirements as well as the size of the internal storage
are directly part of the type and therefore contribute to define different types
that won't be able to interoperate with each other.
# Compressed pair
Primarily designed for internal use and far from being feature complete, the
`compressed_pair` class does exactly what it promises: it tries to reduce the
size of a pair by exploiting _Empty Base Class Optimization_ (or _EBCO_).
This class **is not** a drop-in replacement for `std::pair`. However, it offers
enough functionalities to be a good alternative for when reducing memory usage
is more important than having some cool and probably useless feature.
Although the API is very close to that of `std::pair` (apart from the fact that
the template parameters are inferred from the constructor and therefore there is
no` entt::make_compressed_pair`), the major difference is that `first` and
`second` are functions for implementation needs:
```cpp
entt::compressed_pair pair{0, 3.};
pair.first() = 42;
```
There isn't much to describe then. It's recommended to rely on documentation and
intuition. At the end of the day, it's just a pair and nothing more.
# Enum as bitmask
Sometimes it's useful to be able to use enums as bitmasks. However, enum classes
aren't really suitable for the purpose out of the box. Main problem is that they
don't convert implicitly to their underlying type.
All that remains is to make a choice between using old-fashioned enums (with all
their problems that I don't want to discuss here) or writing _ugly_ code.
Fortunately, there is also a third way: adding enough operators in the global
scope to treat enum classes as bitmask transparently.
The ultimate goal is to be able to write code like the following (or maybe
something more meaningful, but this should give a grasp and remain simple at the
same time):
```cpp
enum class my_flag {
unknown = 0x01,
enabled = 0x02,
disabled = 0x04
};
const my_flag flags = my_flag::enabled;
const bool is_enabled = !!(flags & my_flag::enabled);
```
The problem with adding all operators to the global scope is that these will
come into play even when not required, with the risk of introducing errors that
are difficult to deal with.
However, C++ offers enough tools to get around this problem. In particular, the
library requires users to register all enum classes for which bitmask support
should be enabled:
```cpp
template<>
struct entt::enum_as_bitmask
: std::true_type
{};
```
This is handy when dealing with enum classes defined by third party libraries
and over which the users have no control. However, it's also verbose and can be
avoided by adding a specific value to the enum class itself:
```cpp
enum class my_flag {
unknown = 0x01,
enabled = 0x02,
disabled = 0x04,
_entt_enum_as_bitmask
};
```
In this case, there is no need to specialize the `enum_as_bitmask` traits, since
`EnTT` will automatically detect the flag and enable the bitmask support.
Once the enum class has been registered (in one way or the other) all the most
common operators will be available, such as `&`, `|` but also `&=` and `|=`.
Refer to the official documentation for the full list of operators.
# Hashed strings
A hashed string is a zero overhead unique 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 through the `data` member function or converting the instance
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::hashed_string::hash_type resource) {
// uses the numeric representation of the resource to load and return it
}
auto resource = load(entt::hashed_string{"gui/background"});
```
There is also a _user defined literal_ dedicated to hashed strings to make them
more user-friendly:
```cpp
using namespace entt::literals;
constexpr auto str = "text"_hs;
```
To use it, remember that all user defined literals in `EnTT` are enclosed in the
`entt::literals` namespace. Therefore, the entire namespace or selectively the
literal of interest must be explicitly included before each use, a bit like
`std::literals`.
Finally, in case users need to create hashed strings at runtime, this class also
offers the necessary functionalities:
```cpp
std::string orig{"text"};
// create a full-featured hashed string...
entt::hashed_string str{orig.c_str()};
// ... or compute only the unique identifier
const auto hash = entt::hashed_string::value(orig.c_str());
```
This possibility shouldn't be exploited in tight loops, since the computation
takes place at runtime and no longer at compile-time and could therefore impact
performance to some degrees.
## Wide characters
The hashed string has a design that is close to that of an `std::basic_string`.
It means that `hashed_string` is nothing more than an alias for
`basic_hashed_string`. For those who want to use the C++ type for wide
character representation, there exists also the alias `hashed_wstring` for
`basic_hashed_string`.
In this case, the user defined literal to use to create hashed strings on the
fly is `_hws`:
```cpp
constexpr auto str = L"text"_hws;
```
Note that the hash type of the `hashed_wstring` is the same of its counterpart.
## 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 unique 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.
# Iterators
Writing and working with iterators isn't always easy and more often than not
leads to duplicated code.
`EnTT` tries to overcome this problem by offering some utilities designed to
make this hard work easier.
## Input iterator pointer
When writing an input iterator that returns in-place constructed values if
dereferenced, it's not always straightforward to figure out what `value_type` is
and how to make it behave like a full-fledged pointer.
Conversely, it would be very useful to have an `operator->` available on the
iterator itself that always works without too much complexity.
The input iterator pointer is meant for this. It's a small class that wraps the
in-place constructed value and adds some functions on top of it to make it
suitable for use with input iterators:
```cpp
struct iterator_type {
using value_type = std::pair;
using pointer = input_iterator_pointer;
using reference = value_type;
using difference_type = std::ptrdiff_t;
using iterator_category = std::input_iterator_tag;
// ...
}
```
The library makes extensive use of this class internally. In many cases, the
`value_type` of the returned iterators is just an input iterator pointer.
## Iota iterator
Waiting for C++20, this iterator accepts an integral value and returns all
elements in a certain range:
```cpp
entt::iota_iterator first{0};
entt::iota_iterator last{100};
for(; first != last; ++first) {
int value = *first;
// ...
}
```
In the future, views will replace this class. Meanwhile, the library makes some
interesting uses of it when a range of integral values is to be returned to the
user.
## Iterable adaptor
Typically, a container class provides `begin` and `end` member functions (with
their const counterparts) to be iterated by the user.
However, it can happen that a class offers multiple iteration methods or allows
users to iterate different sets of _elements_.
The iterable adaptor is a utility class that makes it easier to use and access
data in this case.
It accepts a couple of iterators (or an iterator and a sentinel) and offers an
_iterable_ object with all the expected methods like `begin`, `end` and whatnot.
The library uses this class extensively.
Think for example of views, which can be iterated to access entities but also
offer a method of obtaining an iterable object that returns tuples of entities
and components at once.
Another example is the registry class which allows users to iterate its storage
by returning an iterable object for the purpose.
# Memory
There are a handful of tools within `EnTT` to interact with memory in one way or
another.
Some are geared towards simplifying the implementation of (internal or external)
allocator aware containers. Others, on the other hand, are designed to help the
developer with everyday problems.
The former are very specific and for niche problems. These are tools designed to
unwrap fancy or plain pointers (`to_address`) or to help forget the meaning of
acronyms like _POCCA_, _POCMA_ or _POCS_.
I won't describe them here in detail. Instead, I recommend reading the inline
documentation to those interested in the subject.
## Power of two and fast modulus
Finding out if a number is a power of two (`is_power_of_two`) or what the next
power of two is given a random value (`next_power_of_two`) is very useful at
times.
For example, it helps to allocate memory in pages having a size suitable for the
fast modulus:
```cpp
const std::size_t result = entt::fast_mod(value, modulus);
```
Where `modulus` is necessarily a power of two. Perhaps not everyone knows that
this type of operation is far superior in terms of performance to the basic
modulus and for this reason preferred in many areas.
## Allocator aware unique pointers
A nasty thing in C++ (at least up to C++20) is the fact that shared pointers
support allocators while unique pointers don't.
There is a proposal at the moment that also shows among the other things how
this can be implemented without any compiler support.
The `allocate_unique` function follows this proposal, making a virtue out of
necessity:
```cpp
std::unique_ptr> ptr = entt::allocate_unique(allocator, arguments);
```
Although the internal implementation is slightly different from what is proposed
for the standard, this function offers an API that is a drop-in replacement for
the same feature.
# 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{};
```
# Type support
`EnTT` provides some basic information about types of all kinds.
It also offers additional features that are not yet available in the standard
library or that will never be.
## Built-in RTTI support
Runtime type identification support (or RTTI) is one of the most frequently
disabled features in the C++ world, especially in the gaming sector. Regardless
of the reasons for this, it's often a shame not to be able to rely on opaque
type information at runtime.
The library tries to fill this gap by offering a built-in system that doesn't
serve as a replacement but comes very close to being one and offers similar
information to that provided by its counterpart.
Basically, the whole system relies on a handful of classes. In particular:
* The unique sequential identifier associated with a given type:
```cpp
auto index = entt::type_index::value();
```
The returned value isn't guaranteed to be stable across different runs.
However, it can be very useful as index in associative and unordered
associative containers or for positional accesses in a vector or an array.
So as not to conflict with the other tools available, the `family` class isn't
used to generate these indexes. Therefore, the numeric identifiers returned by
the two tools may differ.
On the other hand, this leaves users with full powers over the `family` class
and therefore the generation of custom runtime sequences of indices for their
own purposes, if necessary.
An external generator can also be used if needed. In fact, `type_index` can be
specialized by type and is also _sfinae-friendly_ in order to allow more
refined specializations such as:
```cpp
template
struct entt::type_index> {
static entt::id_type value() noexcept {
return Type::index();
}
};
```
Note that indexes **must** still be generated sequentially in this case.
The tool is widely used within `EnTT`. Generating indices not sequentially
would break an assumption and would likely lead to undesired behaviors.
* The hash value associated with a given type:
```cpp
auto hash = entt::type_hash::value();
```
In general, the `value` function exposed by `type_hash` is also `constexpr`
but this isn't guaranteed for all compilers and platforms (although it's valid
with the most well-known and popular ones).
This function **can** use non-standard features of the language for its own
purposes. This makes it possible to provide compile-time identifiers that
remain stable across different runs.
In all cases, users can prevent the library from using these features by means
of the `ENTT_STANDARD_CPP` definition. In this case, there is no guarantee
that identifiers remain stable across executions. Moreover, they are generated
at runtime and are no longer a compile-time thing.
As for `type_index`, also `type_hash` is a _sfinae-friendly_ class that can be
specialized in order to customize its behavior globally or on a per-type or
per-traits basis.
* The name associated with a given type:
```cpp
auto name = entt::type_name::value();
```
The name associated with a type is extracted from some information generally
made available by the compiler in use. Therefore, it may differ depending on
the compiler and may be empty in the event that this information isn't
available.
For example, given the following class:
```cpp
struct my_type { /* ... */ };
```
The name is `my_type` when compiled with GCC or CLang and `struct my_type`
when MSVC is in use.
Most of the time the name is also retrieved at compile-time and is therefore
always returned through an `std::string_view`. Users can easily access it and
modify it as needed, for example by removing the word `struct` to standardize
the result. `EnTT` won't do this for obvious reasons, since it requires
copying and creating a new string potentially at runtime.
This function **can** use non-standard features of the language for its own
purposes. Users can prevent the library from using non-standard features by
means of the `ENTT_STANDARD_CPP` definition. In this case, the name will be
empty by default.
As for `type_index`, also `type_name` is a _sfinae-friendly_ class that can be
specialized in order to customize its behavior globally or on a per-type or
per-traits basis.
These are then combined into utilities that aim to offer an API that is somewhat
similar to that offered by the language.
### Type info
The `type_info` class isn't a drop-in replacement for `std::type_info` but can
provide similar information which are not implementation defined and don't
require to enable RTTI.
Therefore, they can sometimes be even more reliable than those obtained
otherwise.
Its type defines an opaque class that is also copyable and movable.
Objects of this type are generally returned by the `type_id` functions:
```cpp
// by type
auto info = entt::type_id();
// by value
auto other = entt::type_id(42);
```
All elements thus received are nothing more than const references to instances
of `type_info` with static storage duration.
This is convenient for saving the entire object aside for the cost of a pointer.
However, nothing prevents from constructing `type_info` objects directly:
```cpp
entt::type_info info{std::in_place_type};
```
These are the information made available by `type_info`:
* The index associated with a given type:
```cpp
auto idx = entt::type_id().index();
```
This is also an alias for the following:
```cpp
auto idx = entt::type_index>>::value();
```
* The hash value associated with a given type:
```cpp
auto hash = entt::type_id().hash();
```
This is also an alias for the following:
```cpp
auto hash = entt::type_hash>>::value();
```
* The name associated with a given type:
```cpp
auto name = entt::type_id().name();
```
This is also an alias for the following:
```cpp
auto name = entt::type_name>>::value();
```
Where all accessed features are available at compile-time, the `type_info` class
is also fully `constexpr`. However, this cannot be guaranteed in advance and
depends mainly on the compiler in use and any specializations of the classes
described above.
### Almost unique identifiers
Since the default non-standard, compile-time implementation of `type_hash` makes
use of hashed strings, it may happen that two types are assigned the same hash
value.
In fact, although this is quite rare, it's not entirely excluded.
Another case where two types are assigned the same identifier is when classes
from different contexts (for example two or more libraries loaded at runtime)
have the same fully qualified name. In this case, also `type_name` will return
the same value for the two types.
Fortunately, there are several easy ways to deal with this:
* The most trivial one is to define the `ENTT_STANDARD_CPP` macro. Runtime
identifiers don't suffer from the same problem in fact. However, this solution
doesn't work well with a plugin system, where the libraries aren't linked.
* Another possibility is to specialize the `type_name` class for one of the
conflicting types, in order to assign it a custom identifier. This is probably
the easiest solution that also preserves the feature of the tool.
* A fully customized identifier generation policy (based for example on enum
classes or preprocessing steps) may represent yet another option.
These are just some examples of possible approaches to the problem but there are
many others. As already mentioned above, since users have full control over
their types, this problem is in any case easy to solve and should not worry too
much.
In all likelihood, it will never happen to run into a conflict anyway.
## Type traits
A handful of utilities and traits not present in the standard template library
but which can be useful in everyday life.
This list **is not** exhaustive and contains only some of the most useful
classes. Refer to the inline documentation for more information on the features
offered by this module.
### Size of
The standard operator `sizeof` complains when users provide it for example with
function or incomplete types. On the other hand, it's guaranteed that its result
is always nonzero, even if applied to an empty class type.
This small class combines the two and offers an alternative to `sizeof` that
works under all circumstances, returning zero if the type isn't supported:
```cpp
const auto size = entt::size_of_v;
```
### Is applicable
The standard library offers the great `std::is_invocable` trait in several
forms. This takes a function type and a series of arguments and returns true if
the condition is satisfied.
Moreover, users are also provided with `std::apply`, a tool for combining
invocable elements and tuples of arguments.
It would therefore be a good idea to have a variant of `std::is_invocable` that
also accepts its arguments in the form of a tuple-like type, so as to complete
the offer:
```cpp
constexpr bool result = entt::is_applicable>;
```
This trait is built on top of `std::is_invocable` and does nothing but unpack a
tuple-like type and simplify the code at the call site.
### Constness as
A utility to easily transfer the constness of a type to another type:
```cpp
// type is const dst_type because of the constness of src_type
using type = entt::constness_as_t;
```
The trait is subject to the rules of the language. Therefore, for example,
transferring constness between references won't give the desired effect.
### Member class type
The `auto` template parameter introduced with C++17 made it possible to simplify
many class templates and template functions but also made the class type opaque
when members are passed as template arguments.
The purpose of this utility is to extract the class type in a few lines of code:
```cpp
template
using clazz = entt::member_class_t;
```
### N-th argument
A utility to quickly find the n-th argument of a function, member function or
data member (for blind operations on opaque types):
```cpp
using type = entt::nt_argument_t<1u, &clazz::member>;
```
Disambiguation of overloaded functions is the responsibility of the user, should
it be needed.
### Integral constant
Since `std::integral_constant` may be annoying because of its form that requires
to specify both a type and a value of that type, there is a more user-friendly
shortcut for the creation of integral constants.
This shortcut is the alias template `entt::integral_constant`:
```cpp
constexpr auto constant = entt::integral_constant<42>;
```
Among the other uses, when combined with a hashed string it helps to define tags
as human-readable _names_ where actual types would be required otherwise:
```cpp
constexpr auto enemy_tag = entt::integral_constant<"enemy"_hs>;
registry.emplace(entity);
```
### Tag
Since `id_type` is very important and widely used in `EnTT`, there is a more
user-friendly shortcut for the creation of integral constants based on it.
This shortcut is the alias template `entt::tag`.
If used in combination with hashed strings, it helps to use human-readable names
where types would be required otherwise. As an example:
```cpp
registry.emplace>(entity);
```
However, this isn't the only permitted use. Literally any value convertible to
`id_type` is a good candidate, such as the named constants of an unscoped enum.
### Type list and value list
There is no respectable library where the much desired _type list_ can be
missing.
`EnTT` is no exception and provides (making extensive use of it internally) the
`type_list` type, in addition to its `value_list` counterpart dedicated to
non-type template parameters.
Here is a (possibly incomplete) list of the functionalities that come with a
type list:
* `type_list_element[_t]` to get the N-th element of a type list.
* `type_list_index[_v]` to get the index of a given element of a type list.
* `type_list_cat[_t]` and a handy `operator+` to concatenate type lists.
* `type_list_unique[_t]` to remove duplicate types from a type list.
* `type_list_contains[_v]` to know if a type list contains a given type.
* `type_list_diff[_t]` to remove types from type lists.
* `type_list_transform[_t]` to _transform_ a range and create another type list.
I'm also pretty sure that more and more utilities will be added over time as
needs become apparent.
Many of these functionalities also exist in their version dedicated to value
lists. We therefore have `value_list_element[_v]` as well as
`value_list_cat[_t]`and so on.
# Unique sequential identifiers
Sometimes it's useful to be able to give unique, sequential numeric identifiers
to types either at compile-time or runtime.
There are plenty of different solutions for this out there and I could have used
one of them. However, I decided to spend my time to define a couple of tools
that fully embraces what the modern C++ has to offer.
## Compile-time generator
To generate sequential numeric identifiers at compile-time, `EnTT` offers the
`ident` class template:
```cpp
// defines the identifiers for the given types
using id = entt::ident;
// ...
switch(a_type_identifier) {
case id::value:
// ...
break;
case id::value:
// ...
break;
default:
// ...
}
```
This is what this class template has to offer: a `value` inline variable that
contains a numeric 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
stable across different runs. In case they have been used in a production
environment and a type has to be removed, one can just use a placeholder to
leave the other identifiers unchanged:
```cpp
template struct ignore_type {};
using id = entt::ident<
a_type_still_valid,
ignore_type,
another_type_still_valid
>;
```
Perhaps a bit ugly to see in a codebase but it gets the job done at least.
## Runtime generator
To generate sequential numeric identifiers at runtime, `EnTT` offers the
`family` class template:
```cpp
// defines a custom generator
using id = entt::family;
// ...
const auto a_type_id = id::value;
const auto another_type_id = id::value;
```
This is what a _family_ has to offer: a `value` inline variable that contains a
numeric identifier for the given type.
The generator is customizable, so as to get different _sequences_ for different
purposes if needed.
Please, note that identifiers aren't guaranteed to be stable across different
runs. Indeed it mostly depends on the flow of execution.
# Utilities
It's not possible to escape the temptation to add utilities of some kind to a
library. In fact, `EnTT` also provides a handful of tools to simplify the
life of developers:
* `entt::identity`: the identity function object that will be available with
C++20. It returns its argument unchanged and nothing more. It's useful as a
sort of _do nothing_ function in template programming.
* `entt::overload`: a tool to disambiguate different overloads from their
function type. It works with both free and member functions.
Consider the following definition:
```cpp
struct clazz {
void bar(int) {}
void bar() {}
};
```
This utility can be used to get the _right_ overload as:
```cpp
auto *member = entt::overload(&clazz::bar);
```
The line above is literally equivalent to:
```cpp
auto *member = static_cast(&clazz::bar);
```
Just easier to read and shorter to type.
* `entt::overloaded`: a small class template used to create a new type with an
overloaded `operator()` from a bunch of lambdas or functors.
As an example:
```cpp
entt::overloaded func{
[](int value) { /* ... */ },
[](char value) { /* ... */ }
};
func(42);
func('c');
```
Rather useful when doing metaprogramming and having to pass to a function a
callable object that supports multiple types at once.
* `entt::y_combinator`: this is a C++ implementation of **the** _y-combinator_.
If it's not clear what it is, there is probably no need for this utility.
Below is a small example to show its use:
```cpp
entt::y_combinator gauss([](const auto &self, auto value) -> unsigned int {
return value ? (value + self(value-1u)) : 0;
});
const auto result = gauss(3u);
```
Maybe convoluted at a first glance but certainly effective. Unfortunately,
the language doesn't make it possible to do much better.
This is a rundown of the (actually few) utilities made available by `EnTT`. The
list will probably grow over time but the size of each will remain rather small,
as has been the case so far.