mirror of
https://github.com/ecency/ecency-mobile.git
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1172 lines
38 KiB
C++
1172 lines
38 KiB
C++
/*
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* Copyright 2017-present Facebook, Inc.
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*
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* Licensed under the Apache License, Version 2.0 (the "License");
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* you may not use this file except in compliance with the License.
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* You may obtain a copy of the License at
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*
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* http://www.apache.org/licenses/LICENSE-2.0
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*
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* Unless required by applicable law or agreed to in writing, software
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* distributed under the License is distributed on an "AS IS" BASIS,
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* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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* See the License for the specific language governing permissions and
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* limitations under the License.
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*/
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// TODO: [x] "cast" from Poly<C&> to Poly<C&&>
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// TODO: [ ] copy/move from Poly<C&>/Poly<C&&> to Poly<C>
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// TODO: [ ] copy-on-write?
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// TODO: [ ] down- and cross-casting? (Possible?)
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// TODO: [ ] shared ownership? (Dubious.)
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// TODO: [ ] can games be played with making the VTable a member of a struct
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// with strange alignment such that the address of the VTable can
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// be used to tell whether the object is stored in-situ or not?
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#pragma once
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#if defined(__GNUC__) && !defined(__clang__) && __GNUC__ < 5
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#error Folly.Poly requires gcc-5 or greater
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#endif
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#include <cassert>
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#include <new>
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#include <type_traits>
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#include <typeinfo>
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#include <utility>
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#include <folly/CPortability.h>
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#include <folly/CppAttributes.h>
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#include <folly/Traits.h>
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#include <folly/detail/TypeList.h>
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#include <folly/lang/Assume.h>
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#if !defined(__cpp_inline_variables)
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#define FOLLY_INLINE_CONSTEXPR constexpr
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#else
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#define FOLLY_INLINE_CONSTEXPR inline constexpr
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#endif
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#include <folly/PolyException.h>
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#include <folly/detail/PolyDetail.h>
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namespace folly {
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template <class I>
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struct Poly;
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/**
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* Within the definition of interface `I`, `PolySelf<Base>` is an alias for
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* the instance of `Poly` that is currently being instantiated. It is
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* one of: `Poly<J>`, `Poly<J&&>`, `Poly<J&>`, or `Poly<J const&>`; where
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* `J` is either `I` or some interface that extends `I`.
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*
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* It can be used within interface definitions to declare members that accept
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* other `Poly` objects of the same type as `*this`.
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*
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* The first parameter may optionally be cv- and/or reference-qualified, in
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* which case, the qualification is applies to the type of the interface in the
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* resulting `Poly<>` instance. The second template parameter controls whether
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* or not the interface is decayed before the cv-ref qualifiers of the first
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* argument are applied. For example, given the following:
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*
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* struct Foo {
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* template <class Base>
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* struct Interface : Base {
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* using A = PolySelf<Base>;
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* using B = PolySelf<Base &>;
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* using C = PolySelf<Base const &>;
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* using X = PolySelf<Base, PolyDecay>;
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* using Y = PolySelf<Base &, PolyDecay>;
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* using Z = PolySelf<Base const &, PolyDecay>;
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* };
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* // ...
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* };
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* struct Bar : PolyExtends<Foo> {
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* // ...
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* };
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*
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* Then for `Poly<Bar>`, the typedefs are aliases for the following types:
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* - `A` is `Poly<Bar>`
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* - `B` is `Poly<Bar &>`
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* - `C` is `Poly<Bar const &>`
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* - `X` is `Poly<Bar>`
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* - `Y` is `Poly<Bar &>`
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* - `Z` is `Poly<Bar const &>`
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*
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* And for `Poly<Bar &>`, the typedefs are aliases for the following types:
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* - `A` is `Poly<Bar &>`
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* - `B` is `Poly<Bar &>`
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* - `C` is `Poly<Bar &>`
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* - `X` is `Poly<Bar>`
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* - `Y` is `Poly<Bar &>`
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* - `Z` is `Poly<Bar const &>`
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*/
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template <
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class Node,
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class Tfx = detail::MetaIdentity,
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class Access = detail::PolyAccess>
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using PolySelf = decltype(Access::template self_<Node, Tfx>());
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/**
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* When used in conjunction with `PolySelf`, controls how to construct `Poly`
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* types related to the one currently being instantiated.
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*
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* \sa PolySelf
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*/
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using PolyDecay = detail::MetaQuote<std::decay_t>;
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#if !defined(__cpp_template_auto)
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/**
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* Use `FOLLY_POLY_MEMBERS(MEMS...)` on pre-C++17 compilers to specify a
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* comma-separated list of member function bindings.
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*
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* For example:
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*
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* struct IFooBar {
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* template <class Base>
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* struct Interface : Base {
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* int foo() const { return folly::poly_call<0>(*this); }
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* void bar() { folly::poly_call<1>(*this); }
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* };
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* template <class T>
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* using Members = FOLLY_POLY_MEMBERS(&T::foo, &T::bar);
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* };
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*/
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#define FOLLY_POLY_MEMBERS(...) \
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typename decltype(::folly::detail::deduceMembers( \
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__VA_ARGS__))::template Members<__VA_ARGS__>
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/**
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* Use `FOLLY_POLY_MEMBER(SIG, MEM)` on pre-C++17 compilers to specify a member
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* function binding that needs to be disambiguated because of overloads. `SIG`
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* should the (possibly const-qualified) signature of the `MEM` member function
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* pointer.
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*
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* For example:
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*
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* struct IFoo {
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* template <class Base> struct Interface : Base {
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* int foo() const { return folly::poly_call<0>(*this); }
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* };
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* template <class T> using Members = FOLLY_POLY_MEMBERS(
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* // This works even if T::foo is overloaded:
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* FOLLY_POLY_MEMBER(int()const, &T::foo)
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* );
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* };
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*/
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#define FOLLY_POLY_MEMBER(SIG, MEM) \
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::folly::detail::MemberDef< \
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::folly::detail::Member<decltype(::folly::sig<SIG>(MEM)), MEM>>::value
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/**
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* A list of member function bindings.
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*/
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template <class... Ts>
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using PolyMembers = detail::TypeList<Ts...>;
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#else
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#define FOLLY_POLY_MEMBER(SIG, MEM) ::folly::sig<SIG>(MEM)
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#define FOLLY_POLY_MEMBERS(...) ::folly::PolyMembers<__VA_ARGS__>
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template <auto... Ps>
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struct PolyMembers {};
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#endif
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/**
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* Used in the definition of a `Poly` interface to say that the current
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* interface is an extension of a set of zero or more interfaces.
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*
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* Example:
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*
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* struct IFoo {
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* template <class Base> struct Interface : Base {
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* void foo() { folly::poly_call<0>(*this); }
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* };
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* template <class T> using Members = FOLLY_POLY_MEMBERS(&T::foo);
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* }
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* struct IBar : PolyExtends<IFoo> {
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* template <class Base> struct Interface : Base {
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* void bar(int i) { folly::poly_call<0>(*this, i); }
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* };
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* template <class T> using Members = FOLLY_POLY_MEMBERS(&T::bar);
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* }
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*/
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template <class... I>
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struct PolyExtends : virtual I... {
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using Subsumptions = detail::TypeList<I...>;
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template <class Base>
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struct Interface : Base {
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Interface() = default;
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using Base::Base;
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};
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template <class...>
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using Members = PolyMembers<>;
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};
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////////////////////////////////////////////////////////////////////////////////
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/**
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* Call the N-th member of the currently-being-defined interface. When the
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* first parameter is an object of type `PolySelf<Base>` (as opposed to `*this`)
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* you must explicitly specify which interface through which to dispatch.
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* For instance:
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*
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* struct IAddable {
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* template <class Base>
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* struct Interface : Base {
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* friend PolySelf<Base, Decay>
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* operator+(PolySelf<Base> const& a, PolySelf<Base> const& b) {
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* return folly::poly_call<0, IAddable>(a, b);
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* }
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* };
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* template <class T>
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* static auto plus_(T const& a, T const& b) -> decltype(a + b) {
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* return a + b;
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* }
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* template <class T>
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* using Members = FOLLY_POLY_MEMBERS(&plus_<std::decay_t<T>>);
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* };
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*
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* \sa PolySelf
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*/
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template <std::size_t N, typename This, typename... As>
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auto poly_call(This&& _this, As&&... as)
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-> decltype(detail::PolyAccess::call<N>(
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static_cast<This&&>(_this),
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static_cast<As&&>(as)...)) {
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return detail::PolyAccess::call<N>(
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static_cast<This&&>(_this), static_cast<As&&>(as)...);
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}
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/// \overload
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template <std::size_t N, class I, class Tail, typename... As>
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decltype(auto) poly_call(detail::PolyNode<I, Tail>&& _this, As&&... as) {
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using This = detail::InterfaceOf<I, detail::PolyNode<I, Tail>>;
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return detail::PolyAccess::call<N>(
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static_cast<This&&>(_this), static_cast<As&&>(as)...);
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}
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/// \overload
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template <std::size_t N, class I, class Tail, typename... As>
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decltype(auto) poly_call(detail::PolyNode<I, Tail>& _this, As&&... as) {
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using This = detail::InterfaceOf<I, detail::PolyNode<I, Tail>>;
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return detail::PolyAccess::call<N>(
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static_cast<This&>(_this), static_cast<As&&>(as)...);
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}
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/// \overload
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template <std::size_t N, class I, class Tail, typename... As>
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decltype(auto) poly_call(detail::PolyNode<I, Tail> const& _this, As&&... as) {
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using This = detail::InterfaceOf<I, detail::PolyNode<I, Tail>>;
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return detail::PolyAccess::call<N>(
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static_cast<This const&>(_this), static_cast<As&&>(as)...);
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}
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/// \overload
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template <
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std::size_t N,
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class I,
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class Poly,
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typename... As,
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std::enable_if_t<detail::IsPoly<Poly>::value, int> = 0>
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auto poly_call(Poly&& _this, As&&... as) -> decltype(poly_call<N, I>(
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static_cast<Poly&&>(_this).get(),
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static_cast<As&&>(as)...)) {
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return poly_call<N, I>(
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static_cast<Poly&&>(_this).get(), static_cast<As&&>(as)...);
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}
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/// \cond
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/// \overload
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template <std::size_t N, class I, typename... As>
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[[noreturn]] detail::Bottom poly_call(detail::ArchetypeBase const&, As&&...) {
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assume_unreachable();
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}
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/// \endcond
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////////////////////////////////////////////////////////////////////////////////
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/**
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* Try to cast the `Poly` object to the requested type. If the `Poly` stores an
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* object of that type, return a reference to the object; otherwise, throw an
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* exception.
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* \tparam T The (unqualified) type to which to cast the `Poly` object.
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* \tparam Poly The type of the `Poly` object.
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* \param that The `Poly` object to be cast.
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* \return A reference to the `T` object stored in or refered to by `that`.
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* \throw BadPolyAccess if `that` is empty.
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* \throw BadPolyCast if `that` does not store or refer to an object of type
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* `T`.
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*/
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template <class T, class I>
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detail::AddCvrefOf<T, I>&& poly_cast(detail::PolyRoot<I>&& that) {
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return detail::PolyAccess::cast<T>(std::move(that));
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}
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/// \overload
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template <class T, class I>
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detail::AddCvrefOf<T, I>& poly_cast(detail::PolyRoot<I>& that) {
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return detail::PolyAccess::cast<T>(that);
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}
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/// \overload
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template <class T, class I>
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detail::AddCvrefOf<T, I> const& poly_cast(detail::PolyRoot<I> const& that) {
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return detail::PolyAccess::cast<T>(that);
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}
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/// \cond
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/// \overload
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template <class T, class I>
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[[noreturn]] detail::AddCvrefOf<T, I>&& poly_cast(detail::ArchetypeRoot<I>&&) {
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assume_unreachable();
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}
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/// \overload
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template <class T, class I>
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[[noreturn]] detail::AddCvrefOf<T, I>& poly_cast(detail::ArchetypeRoot<I>&) {
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assume_unreachable();
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}
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/// \overload
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template <class T, class I>
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[[noreturn]] detail::AddCvrefOf<T, I> const& poly_cast(
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detail::ArchetypeRoot<I> const&) {
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assume_unreachable();
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}
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/// \endcond
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/// \overload
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template <
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class T,
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class Poly,
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std::enable_if_t<detail::IsPoly<Poly>::value, int> = 0>
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constexpr auto poly_cast(Poly&& that)
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-> decltype(poly_cast<T>(std::declval<Poly>().get())) {
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return poly_cast<T>(static_cast<Poly&&>(that).get());
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}
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////////////////////////////////////////////////////////////////////////////////
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/**
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* Returns a reference to the `std::type_info` object corresponding to the
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* object currently stored in `that`. If `that` is empty, returns
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* `typeid(void)`.
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*/
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template <class I>
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std::type_info const& poly_type(detail::PolyRoot<I> const& that) noexcept {
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return detail::PolyAccess::type(that);
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}
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/// \cond
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/// \overload
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[[noreturn]] inline std::type_info const& poly_type(
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detail::ArchetypeBase const&) noexcept {
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assume_unreachable();
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}
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/// \endcond
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/// \overload
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template <class Poly, std::enable_if_t<detail::IsPoly<Poly>::value, int> = 0>
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constexpr auto poly_type(Poly const& that) noexcept
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-> decltype(poly_type(that.get())) {
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return poly_type(that.get());
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}
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////////////////////////////////////////////////////////////////////////////////
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/**
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* Returns `true` if `that` is not currently storing an object; `false`,
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* otherwise.
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*/
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template <class I>
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bool poly_empty(detail::PolyRoot<I> const& that) noexcept {
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return detail::State::eEmpty == detail::PolyAccess::vtable(that)->state_;
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}
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/// \overload
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template <class I>
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constexpr bool poly_empty(detail::PolyRoot<I&&> const&) noexcept {
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return false;
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}
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/// \overload
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template <class I>
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constexpr bool poly_empty(detail::PolyRoot<I&> const&) noexcept {
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return false;
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}
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/// \overload
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template <class I>
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constexpr bool poly_empty(Poly<I&&> const&) noexcept {
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return false;
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}
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/// \overload
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template <class I>
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constexpr bool poly_empty(Poly<I&> const&) noexcept {
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return false;
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}
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/// \cond
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[[noreturn]] inline bool poly_empty(detail::ArchetypeBase const&) noexcept {
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assume_unreachable();
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}
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/// \endcond
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////////////////////////////////////////////////////////////////////////////////
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/**
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* Given a `Poly<I&>`, return a `Poly<I&&>`. Otherwise, when `I` is not a
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* reference type, returns a `Poly<I>&&` when given a `Poly<I>&`, like
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* `std::move`.
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*/
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template <
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class I,
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std::enable_if_t<detail::Not<std::is_reference<I>>::value, int> = 0>
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constexpr Poly<I>&& poly_move(detail::PolyRoot<I>& that) noexcept {
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return static_cast<Poly<I>&&>(static_cast<Poly<I>&>(that));
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}
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/// \overload
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template <
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class I,
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std::enable_if_t<detail::Not<std::is_const<I>>::value, int> = 0>
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Poly<I&&> poly_move(detail::PolyRoot<I&> const& that) noexcept {
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return detail::PolyAccess::move(that);
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}
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/// \overload
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template <class I>
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Poly<I const&> poly_move(detail::PolyRoot<I const&> const& that) noexcept {
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return detail::PolyAccess::move(that);
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}
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/// \cond
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/// \overload
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[[noreturn]] inline detail::ArchetypeBase poly_move(
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detail::ArchetypeBase const&) noexcept {
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assume_unreachable();
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}
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/// \endcond
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/// \overload
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template <class Poly, std::enable_if_t<detail::IsPoly<Poly>::value, int> = 0>
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constexpr auto poly_move(Poly& that) noexcept
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-> decltype(poly_move(that.get())) {
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return poly_move(that.get());
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}
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/// \cond
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namespace detail {
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/**
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* The implementation for `Poly` for when the interface type is not
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* reference-like qualified, as in `Poly<SemiRegular>`.
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*/
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template <class I>
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struct PolyVal : PolyImpl<I> {
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private:
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friend PolyAccess;
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struct NoneSuch {};
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using Copyable = std::is_copy_constructible<PolyImpl<I>>;
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using PolyOrNonesuch = If<Copyable::value, PolyVal, NoneSuch>;
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using PolyRoot<I>::vptr_;
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PolyRoot<I>& _polyRoot_() noexcept {
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return *this;
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}
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PolyRoot<I> const& _polyRoot_() const noexcept {
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return *this;
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}
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Data* _data_() noexcept {
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return PolyAccess::data(*this);
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}
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Data const* _data_() const noexcept {
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return PolyAccess::data(*this);
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}
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public:
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/**
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* Default constructor.
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* \post `poly_empty(*this) == true`
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*/
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PolyVal() = default;
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/**
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* Move constructor.
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* \post `poly_empty(that) == true`
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*/
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PolyVal(PolyVal&& that) noexcept;
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|
/**
|
|
* A copy constructor if `I` is copyable; otherwise, a useless constructor
|
|
* from a private, incomplete type.
|
|
*/
|
|
/* implicit */ PolyVal(PolyOrNonesuch const& that);
|
|
|
|
~PolyVal();
|
|
|
|
/**
|
|
* Inherit any constructors defined by any of the interfaces.
|
|
*/
|
|
using PolyImpl<I>::PolyImpl;
|
|
|
|
/**
|
|
* Copy assignment, destroys the object currently held (if any) and makes
|
|
* `*this` equal to `that` by stealing its guts.
|
|
*/
|
|
Poly<I>& operator=(PolyVal that) noexcept;
|
|
|
|
/**
|
|
* Construct a Poly<I> from a concrete type that satisfies the I concept
|
|
*/
|
|
template <class T, std::enable_if_t<ModelsInterface<T, I>::value, int> = 0>
|
|
/* implicit */ PolyVal(T&& t);
|
|
|
|
/**
|
|
* Construct a `Poly` from a compatible `Poly`. "Compatible" here means: the
|
|
* other interface extends this one either directly or indirectly.
|
|
*/
|
|
template <class I2, std::enable_if_t<ValueCompatible<I, I2>::value, int> = 0>
|
|
/* implicit */ PolyVal(Poly<I2> that);
|
|
|
|
/**
|
|
* Assign to this `Poly<I>` from a concrete type that satisfies the `I`
|
|
* concept.
|
|
*/
|
|
template <class T, std::enable_if_t<ModelsInterface<T, I>::value, int> = 0>
|
|
Poly<I>& operator=(T&& t);
|
|
|
|
/**
|
|
* Assign a compatible `Poly` to `*this`. "Compatible" here means: the
|
|
* other interface extends this one either directly or indirectly.
|
|
*/
|
|
template <class I2, std::enable_if_t<ValueCompatible<I, I2>::value, int> = 0>
|
|
Poly<I>& operator=(Poly<I2> that);
|
|
|
|
/**
|
|
* Swaps the values of two `Poly` objects.
|
|
*/
|
|
void swap(Poly<I>& that) noexcept;
|
|
};
|
|
|
|
////////////////////////////////////////////////////////////////////////////////
|
|
/**
|
|
* The implementation of `Poly` for when the interface type is
|
|
* reference-quelified, like `Poly<SemuRegular &>`.
|
|
*/
|
|
template <class I>
|
|
struct PolyRef : private PolyImpl<I> {
|
|
private:
|
|
friend PolyAccess;
|
|
|
|
AddCvrefOf<PolyRoot<I>, I>& _polyRoot_() const noexcept;
|
|
|
|
Data* _data_() noexcept {
|
|
return PolyAccess::data(*this);
|
|
}
|
|
Data const* _data_() const noexcept {
|
|
return PolyAccess::data(*this);
|
|
}
|
|
|
|
static constexpr RefType refType() noexcept;
|
|
|
|
protected:
|
|
template <class That, class I2>
|
|
PolyRef(That&& that, Type<I2>);
|
|
|
|
public:
|
|
/**
|
|
* Copy constructor
|
|
* \post `&poly_cast<T>(*this) == &poly_cast<T>(that)`, where `T` is the
|
|
* type of the object held by `that`.
|
|
*/
|
|
PolyRef(PolyRef const& that) noexcept;
|
|
|
|
/**
|
|
* Copy assignment
|
|
* \post `&poly_cast<T>(*this) == &poly_cast<T>(that)`, where `T` is the
|
|
* type of the object held by `that`.
|
|
*/
|
|
Poly<I>& operator=(PolyRef const& that) noexcept;
|
|
|
|
/**
|
|
* Construct a `Poly<I>` from a concrete type that satisfies concept `I`.
|
|
* \post `!poly_empty(*this)`
|
|
*/
|
|
template <class T, std::enable_if_t<ModelsInterface<T, I>::value, int> = 0>
|
|
/* implicit */ PolyRef(T&& t) noexcept;
|
|
|
|
/**
|
|
* Construct a `Poly<I>` from a compatible `Poly<I2>`.
|
|
*/
|
|
template <
|
|
class I2,
|
|
std::enable_if_t<ReferenceCompatible<I, I2, I2&&>::value, int> = 0>
|
|
/* implicit */ PolyRef(Poly<I2>&& that) noexcept(
|
|
std::is_reference<I2>::value);
|
|
|
|
template <
|
|
class I2,
|
|
std::enable_if_t<ReferenceCompatible<I, I2, I2&>::value, int> = 0>
|
|
/* implicit */ PolyRef(Poly<I2>& that) noexcept(std::is_reference<I2>::value)
|
|
: PolyRef{that, Type<I2>{}} {}
|
|
|
|
template <
|
|
class I2,
|
|
std::enable_if_t<ReferenceCompatible<I, I2, I2 const&>::value, int> = 0>
|
|
/* implicit */ PolyRef(Poly<I2> const& that) noexcept(
|
|
std::is_reference<I2>::value)
|
|
: PolyRef{that, Type<I2>{}} {}
|
|
|
|
/**
|
|
* Assign to a `Poly<I>` from a concrete type that satisfies concept `I`.
|
|
* \post `!poly_empty(*this)`
|
|
*/
|
|
template <class T, std::enable_if_t<ModelsInterface<T, I>::value, int> = 0>
|
|
Poly<I>& operator=(T&& t) noexcept;
|
|
|
|
/**
|
|
* Assign to `*this` from another compatible `Poly`.
|
|
*/
|
|
template <
|
|
class I2,
|
|
std::enable_if_t<ReferenceCompatible<I, I2, I2&&>::value, int> = 0>
|
|
Poly<I>& operator=(Poly<I2>&& that) noexcept(std::is_reference<I2>::value);
|
|
|
|
/**
|
|
* \overload
|
|
*/
|
|
template <
|
|
class I2,
|
|
std::enable_if_t<ReferenceCompatible<I, I2, I2&>::value, int> = 0>
|
|
Poly<I>& operator=(Poly<I2>& that) noexcept(std::is_reference<I2>::value);
|
|
|
|
/**
|
|
* \overload
|
|
*/
|
|
template <
|
|
class I2,
|
|
std::enable_if_t<ReferenceCompatible<I, I2, I2 const&>::value, int> = 0>
|
|
Poly<I>& operator=(Poly<I2> const& that) noexcept(
|
|
std::is_reference<I2>::value);
|
|
|
|
/**
|
|
* Swap which object this `Poly` references ("shallow" swap).
|
|
*/
|
|
void swap(Poly<I>& that) noexcept;
|
|
|
|
/**
|
|
* Get a reference to the interface, with correct `const`-ness applied.
|
|
*/
|
|
AddCvrefOf<PolyImpl<I>, I>& get() const noexcept;
|
|
|
|
/**
|
|
* Get a reference to the interface, with correct `const`-ness applied.
|
|
*/
|
|
AddCvrefOf<PolyImpl<I>, I>& operator*() const noexcept {
|
|
return get();
|
|
}
|
|
|
|
/**
|
|
* Get a pointer to the interface, with correct `const`-ness applied.
|
|
*/
|
|
auto operator-> () const noexcept {
|
|
return &get();
|
|
}
|
|
};
|
|
|
|
template <class I>
|
|
using PolyValOrRef = If<std::is_reference<I>::value, PolyRef<I>, PolyVal<I>>;
|
|
} // namespace detail
|
|
/// \endcond
|
|
|
|
/**
|
|
* `Poly` is a class template that makes it relatively easy to define a
|
|
* type-erasing polymorphic object wrapper.
|
|
*
|
|
* \par Type-erasure
|
|
*
|
|
* \par
|
|
* `std::function` is one example of a type-erasing polymorphic object wrapper;
|
|
* `folly::exception_wrapper` is another. Type-erasure is often used as an
|
|
* alternative to dynamic polymorphism via inheritance-based virtual dispatch.
|
|
* The distinguishing characteristic of type-erasing wrappers are:
|
|
* \li **Duck typing:** Types do not need to inherit from an abstract base
|
|
* class in order to be assignable to a type-erasing wrapper; they merely
|
|
* need to satisfy a particular interface.
|
|
* \li **Value semantics:** Type-erasing wrappers are objects that can be
|
|
* passed around _by value_. This is in contrast to abstract base classes
|
|
* which must be passed by reference or by pointer or else suffer from
|
|
* _slicing_, which causes them to lose their polymorphic behaviors.
|
|
* Reference semantics make it difficult to reason locally about code.
|
|
* \li **Automatic memory management:** When dealing with inheritance-based
|
|
* dynamic polymorphism, it is often necessary to allocate and manage
|
|
* objects on the heap. This leads to a proliferation of `shared_ptr`s and
|
|
* `unique_ptr`s in APIs, complicating their point-of-use. APIs that take
|
|
* type-erasing wrappers, on the other hand, can often store small objects
|
|
* in-situ, with no dynamic allocation. The memory management, if any, is
|
|
* handled for you, and leads to cleaner APIs: consumers of your API don't
|
|
* need to pass `shared_ptr<AbstractBase>`; they can simply pass any object
|
|
* that satisfies the interface you require. (`std::function` is a
|
|
* particularly compelling example of this benefit. Far worse would be an
|
|
* inheritance-based callable solution like
|
|
* `shared_ptr<ICallable<void(int)>>`. )
|
|
*
|
|
* \par Example: Defining a type-erasing function wrapper with `folly::Poly`
|
|
*
|
|
* \par
|
|
* Defining a polymorphic wrapper with `Poly` is a matter of defining two
|
|
* things:
|
|
* \li An *interface*, consisting of public member functions, and
|
|
* \li A *mapping* from a concrete type to a set of member function bindings.
|
|
*
|
|
* Below is a (heavily commented) example of a simple implementation of a
|
|
* `std::function`-like polymorphic wrapper. Its interface has only a simgle
|
|
* member function: `operator()`
|
|
*
|
|
* // An interface for a callable object of a particular signature, Fun
|
|
* // (most interfaces don't need to be templates, FWIW).
|
|
* template <class Fun>
|
|
* struct IFunction;
|
|
*
|
|
* template <class R, class... As>
|
|
* struct IFunction<R(As...)> {
|
|
* // An interface is defined as a nested class template called
|
|
* // Interface that takes a single template parameter, Base, from
|
|
* // which it inherits.
|
|
* template <class Base>
|
|
* struct Interface : Base {
|
|
* // The Interface has public member functions. These become the
|
|
* // public interface of the resulting Poly instantiation.
|
|
* // (Implementation note: Poly<IFunction<Sig>> will publicly
|
|
* // inherit from this struct, which is what gives it the right
|
|
* // member functions.)
|
|
* R operator()(As... as) const {
|
|
* // The definition of each member function in your interface will
|
|
* // always consist of a single line dispatching to
|
|
* // folly::poly_call<N>. The "N" corresponds to the N-th member
|
|
* // function in the list of member function bindings, Members,
|
|
* // defined below. The first argument will always be *this, and the
|
|
* // rest of the arguments should simply forward (if necessary) the
|
|
* // member function's arguments.
|
|
* return static_cast<R>(
|
|
* folly::poly_call<0>(*this, std::forward<As>(as)...));
|
|
* }
|
|
* };
|
|
*
|
|
* // The "Members" alias template is a comma-separated list of bound
|
|
* // member functions for a given concrete type "T". The
|
|
* // "FOLLY_POLY_MEMBERS" macro accepts a comma-separated list, and the
|
|
* // (optional) "FOLLY_POLY_MEMBER" macro lets you disambiguate overloads
|
|
* // by explicitly specifying the function signature the target member
|
|
* // function should have. In this case, we require "T" to have a
|
|
* // function call operator with the signature `R(As...) const`.
|
|
* //
|
|
* // If you are using a C++17-compatible compiler, you can do away with
|
|
* // the macros and write this as:
|
|
* //
|
|
* // template <class T>
|
|
* // using Members = folly::PolyMembers<
|
|
* // folly::sig<R(As...) const>(&T::operator())>;
|
|
* //
|
|
* // And since `folly::sig` is only needed for disambiguation in case of
|
|
* // overloads, if you are not concerned about objects with overloaded
|
|
* // function call operators, it could be further simplified to:
|
|
* //
|
|
* // template <class T>
|
|
* // using Members = folly::PolyMembers<&T::operator()>;
|
|
* //
|
|
* template <class T>
|
|
* using Members = FOLLY_POLY_MEMBERS(
|
|
* FOLLY_POLY_MEMBER(R(As...) const, &T::operator()));
|
|
* };
|
|
*
|
|
* // Now that we have defined the interface, we can pass it to Poly to
|
|
* // create our type-erasing wrapper:
|
|
* template <class Fun>
|
|
* using Function = Poly<IFunction<Fun>>;
|
|
*
|
|
* \par
|
|
* Given the above definition of `Function`, users can now initialize instances
|
|
* of (say) `Function<int(int, int)>` with function objects like
|
|
* `std::plus<int>` and `std::multiplies<int>`, as below:
|
|
*
|
|
* Function<int(int, int)> fun = std::plus<int>{};
|
|
* assert(5 == fun(2, 3));
|
|
* fun = std::multiplies<int>{};
|
|
* assert(6 = fun(2, 3));
|
|
*
|
|
* \par Defining an interface with C++17
|
|
*
|
|
* \par
|
|
* With C++17, defining an interface to be used with `Poly` is fairly
|
|
* straightforward. As in the `Function` example above, there is a struct with
|
|
* a nested `Interface` class template and a nested `Members` alias template.
|
|
* No macros are needed with C++17.
|
|
* \par
|
|
* Imagine we were defining something like a Java-style iterator. If we are
|
|
* using a C++17 compiler, our interface would look something like this:
|
|
*
|
|
* template <class Value>
|
|
* struct IJavaIterator {
|
|
* template <class Base>
|
|
* struct Interface : Base {
|
|
* bool Done() const { return folly::poly_call<0>(*this); }
|
|
* Value Current() const { return folly::poly_call<1>(*this); }
|
|
* void Next() { folly::poly_call<2>(*this); }
|
|
* };
|
|
* // NOTE: This works in C++17 only:
|
|
* template <class T>
|
|
* using Members = folly::PolyMembers<&T::Done, &T::Current, &T::Next>;
|
|
* };
|
|
*
|
|
* template <class Value>
|
|
* using JavaIterator = Poly<IJavaIterator>;
|
|
*
|
|
* \par
|
|
* Given the above definition, `JavaIterator<int>` can be used to hold instances
|
|
* of any type that has `Done`, `Current`, and `Next` member functions with the
|
|
* correct (or compatible) signatures.
|
|
*
|
|
* \par
|
|
* The presence of overloaded member functions complicates this picture. Often,
|
|
* property members are faked in C++ with `const` and non-`const` member
|
|
* function overloads, like in the interface specified below:
|
|
*
|
|
* struct IIntProperty {
|
|
* template <class Base>
|
|
* struct Interface : Base {
|
|
* int Value() const { return folly::poly_call<0>(*this); }
|
|
* void Value(int i) { folly::poly_call<1>(*this, i); }
|
|
* };
|
|
* // NOTE: This works in C++17 only:
|
|
* template <class T>
|
|
* using Members = folly::PolyMembers<
|
|
* folly::sig<int() const>(&T::Value),
|
|
* folly::sig<void(int)>(&T::Value)>;
|
|
* };
|
|
*
|
|
* using IntProperty = Poly<IIntProperty>;
|
|
*
|
|
* \par
|
|
* Now, any object that has `Value` members of compatible signatures can be
|
|
* assigned to instances of `IntProperty` object. Note how `folly::sig` is used
|
|
* to disambiguate the overloads of `&T::Value`.
|
|
*
|
|
* \par Defining an interface with C++14
|
|
*
|
|
* \par
|
|
* In C++14, the nice syntax above doesn't work, so we have to resort to macros.
|
|
* The two examples above would look like this:
|
|
*
|
|
* template <class Value>
|
|
* struct IJavaIterator {
|
|
* template <class Base>
|
|
* struct Interface : Base {
|
|
* bool Done() const { return folly::poly_call<0>(*this); }
|
|
* Value Current() const { return folly::poly_call<1>(*this); }
|
|
* void Next() { folly::poly_call<2>(*this); }
|
|
* };
|
|
* // NOTE: This works in C++14 and C++17:
|
|
* template <class T>
|
|
* using Members = FOLLY_POLY_MEMBERS(&T::Done, &T::Current, &T::Next);
|
|
* };
|
|
*
|
|
* template <class Value>
|
|
* using JavaIterator = Poly<IJavaIterator>;
|
|
*
|
|
* \par
|
|
* and
|
|
*
|
|
* struct IIntProperty {
|
|
* template <class Base>
|
|
* struct Interface : Base {
|
|
* int Value() const { return folly::poly_call<0>(*this); }
|
|
* void Value(int i) { return folly::poly_call<1>(*this, i); }
|
|
* };
|
|
* // NOTE: This works in C++14 and C++17:
|
|
* template <class T>
|
|
* using Members = FOLLY_POLY_MEMBERS(
|
|
* FOLLY_POLY_MEMBER(int() const, &T::Value),
|
|
* FOLLY_POLY_MEMBER(void(int), &T::Value));
|
|
* };
|
|
*
|
|
* using IntProperty = Poly<IIntProperty>;
|
|
*
|
|
* \par Extending interfaces
|
|
*
|
|
* \par
|
|
* One typical advantage of inheritance-based solutions to runtime polymorphism
|
|
* is that one polymorphic interface could extend another through inheritance.
|
|
* The same can be accomplished with type-erasing polymorphic wrappers. In
|
|
* the `Poly` library, you can use `folly::PolyExtends` to say that one
|
|
* interface extends another.
|
|
*
|
|
* struct IFoo {
|
|
* template <class Base>
|
|
* struct Interface : Base {
|
|
* void Foo() const { return folly::poly_call<0>(*this); }
|
|
* };
|
|
* template <class T>
|
|
* using Members = FOLLY_POLY_MEMBERS(&T::Foo);
|
|
* };
|
|
*
|
|
* // The IFooBar interface extends the IFoo interface
|
|
* struct IFooBar : PolyExtends<IFoo> {
|
|
* template <class Base>
|
|
* struct Interface : Base {
|
|
* void Bar() const { return folly::poly_call<0>(*this); }
|
|
* };
|
|
* template <class T>
|
|
* using Members = FOLLY_POLY_MEMBERS(&T::Bar);
|
|
* };
|
|
*
|
|
* using FooBar = Poly<IFooBar>;
|
|
*
|
|
* \par
|
|
* Given the above defintion, instances of type `FooBar` have both `Foo()` and
|
|
* `Bar()` member functions.
|
|
*
|
|
* \par
|
|
* The sensible conversions exist between a wrapped derived type and a wrapped
|
|
* base type. For instance, assuming `IDerived` extends `IBase` with
|
|
* `PolyExtends`:
|
|
*
|
|
* Poly<IDerived> derived = ...;
|
|
* Poly<IBase> base = derived; // This conversion is OK.
|
|
*
|
|
* \par
|
|
* As you would expect, there is no conversion in the other direction, and at
|
|
* present there is no `Poly` equivalent to `dynamic_cast`.
|
|
*
|
|
* \par Type-erasing polymorphic reference wrappers
|
|
*
|
|
* \par
|
|
* Sometimes you don't need to own a copy of an object; a reference will do. For
|
|
* that you can use `Poly` to capture a _reference_ to an object satisfying an
|
|
* interface rather than the whole object itself. The syntax is intuitive.
|
|
*
|
|
* int i = 42;
|
|
* // Capture a mutable reference to an object of any IRegular type:
|
|
* Poly<IRegular &> intRef = i;
|
|
* assert(42 == folly::poly_cast<int>(intRef));
|
|
* // Assert that we captured the address of "i":
|
|
* assert(&i == &folly::poly_cast<int>(intRef));
|
|
*
|
|
* \par
|
|
* A reference-like `Poly` has a different interface than a value-like `Poly`.
|
|
* Rather than calling member functions with the `obj.fun()` syntax, you would
|
|
* use the `obj->fun()` syntax. This is for the sake of `const`-correctness.
|
|
* For example, consider the code below:
|
|
*
|
|
* struct IFoo {
|
|
* template <class Base>
|
|
* struct Interface {
|
|
* void Foo() { folly::poly_call<0>(*this); }
|
|
* };
|
|
* template <class T>
|
|
* using Members = folly::PolyMembers<&T::Foo>;
|
|
* };
|
|
*
|
|
* struct SomeFoo {
|
|
* void Foo() { std::printf("SomeFoo::Foo\n"); }
|
|
* };
|
|
*
|
|
* SomeFoo foo;
|
|
* Poly<IFoo &> const anyFoo = foo;
|
|
* anyFoo->Foo(); // prints "SomeFoo::Foo"
|
|
*
|
|
* \par
|
|
* Notice in the above code that the `Foo` member function is non-`const`.
|
|
* Notice also that the `anyFoo` object is `const`. However, since it has
|
|
* captured a non-`const` reference to the `foo` object, it should still be
|
|
* possible to dispatch to the non-`const` `Foo` member function. When
|
|
* instantiated with a reference type, `Poly` has an overloaded `operator->`
|
|
* member that returns a pointer to the `IFoo` interface with the correct
|
|
* `const`-ness, which makes this work.
|
|
*
|
|
* \par
|
|
* The same mechanism also prevents users from calling non-`const` member
|
|
* functions on `Poly` objects that have captured `const` references, which
|
|
* would violate `const`-correctness.
|
|
*
|
|
* \par
|
|
* Sensible conversions exist between non-reference and reference `Poly`s. For
|
|
* instance:
|
|
*
|
|
* Poly<IRegular> value = 42;
|
|
* Poly<IRegular &> mutable_ref = value;
|
|
* Poly<IRegular const &> const_ref = mutable_ref;
|
|
*
|
|
* assert(&poly_cast<int>(value) == &poly_cast<int>(mutable_ref));
|
|
* assert(&poly_cast<int>(value) == &poly_cast<int>(const_ref));
|
|
*
|
|
* \par Non-member functions (C++17)
|
|
*
|
|
* \par
|
|
* If you wanted to write the interface `ILogicallyNegatable`, which captures
|
|
* all types that can be negated with unary `operator!`, you could do it
|
|
* as we've shown above, by binding `&T::operator!` in the nested `Members`
|
|
* alias template, but that has the problem that it won't work for types that
|
|
* have defined unary `operator!` as a free function. To handle this case,
|
|
* the `Poly` library lets you use a free function instead of a member function
|
|
* when creating a binding.
|
|
*
|
|
* \par
|
|
* With C++17 you may use a lambda to create a binding, as shown in the example
|
|
* below:
|
|
*
|
|
* struct ILogicallyNegatable {
|
|
* template <class Base>
|
|
* struct Interface : Base {
|
|
* bool operator!() const { return folly::poly_call<0>(*this); }
|
|
* };
|
|
* template <class T>
|
|
* using Members = folly::PolyMembers<
|
|
* +[](T const& t) -> decltype(!t) { return !t; }>;
|
|
* };
|
|
*
|
|
* \par
|
|
* This requires some explanation. The unary `operator+` in front of the lambda
|
|
* is necessary! It causes the lambda to decay to a C-style function pointer,
|
|
* which is one of the types that `folly::PolyMembers` accepts. The `decltype`
|
|
* in the lambda return type is also necessary. Through the magic of SFINAE, it
|
|
* will cause `Poly<ILogicallyNegatable>` to reject any types that don't support
|
|
* unary `operator!`.
|
|
*
|
|
* \par
|
|
* If you are using a free function to create a binding, the first parameter is
|
|
* implicitly the `this` parameter. It will receive the type-erased object.
|
|
*
|
|
* \par Non-member functions (C++14)
|
|
*
|
|
* \par
|
|
* If you are using a C++14 compiler, the defintion of `ILogicallyNegatable`
|
|
* above will fail because lambdas are not `constexpr`. We can get the same
|
|
* effect by writing the lambda as a named free function, as show below:
|
|
*
|
|
* struct ILogicallyNegatable {
|
|
* template <class Base>
|
|
* struct Interface : Base {
|
|
* bool operator!() const { return folly::poly_call<0>(*this); }
|
|
* };
|
|
*
|
|
* template <class T>
|
|
* static auto negate(T const& t) -> decltype(!t) { return !t; }
|
|
*
|
|
* template <class T>
|
|
* using Members = FOLLY_POLY_MEMBERS(&negate<T>);
|
|
* };
|
|
*
|
|
* \par
|
|
* As with the example that uses the lambda in the preceding section, the first
|
|
* parameter is implicitly the `this` parameter. It will receive the type-erased
|
|
* object.
|
|
*
|
|
* \par Multi-dispatch
|
|
*
|
|
* \par
|
|
* What if you want to create an `IAddable` interface for things that can be
|
|
* added? Adding requires _two_ objects, both of which are type-erased. This
|
|
* interface requires dispatching on both objects, doing the addition only
|
|
* if the types are the same. For this we make use of the `PolySelf` template
|
|
* alias to define an interface that takes more than one object of the the
|
|
* erased type.
|
|
*
|
|
* struct IAddable {
|
|
* template <class Base>
|
|
* struct Interface : Base {
|
|
* friend PolySelf<Base, Decay>
|
|
* operator+(PolySelf<Base> const& a, PolySelf<Base> const& b) {
|
|
* return folly::poly_call<0, IAddable>(a, b);
|
|
* }
|
|
* };
|
|
*
|
|
* template <class T>
|
|
* using Members = folly::PolyMembers<
|
|
* +[](T const& a, T const& b) -> decltype(a + b) { return a + b; }>;
|
|
* };
|
|
*
|
|
* \par
|
|
* Given the above defintion of `IAddable` we would be able to do the following:
|
|
*
|
|
* Poly<IAddable> a = 2, b = 3;
|
|
* Poly<IAddable> c = a + b;
|
|
* assert(poly_cast<int>(c) == 5);
|
|
*
|
|
* \par
|
|
* If `a` and `b` stored objects of different types, a `BadPolyCast` exception
|
|
* would be thrown.
|
|
*
|
|
* \par Move-only types
|
|
*
|
|
* \par
|
|
* If you want to store move-only types, then your interface should extend the
|
|
* `IMoveOnly` interface.
|
|
*
|
|
* \par Implementation notes
|
|
* \par
|
|
* `Poly` will store "small" objects in an internal buffer, avoiding the cost of
|
|
* of dynamic allocations. At present, this size is not configurable; it is
|
|
* pegged at the size of two `double`s.
|
|
*
|
|
* \par
|
|
* `Poly` objects are always nothrow movable. If you store an object in one that
|
|
* has a potentially throwing move contructor, the object will be stored on the
|
|
* heap, even if it could fit in the internal storage of the `Poly` object.
|
|
* (So be sure to give your objects nothrow move constructors!)
|
|
*
|
|
* \par
|
|
* `Poly` implements type-erasure in a manner very similar to how the compiler
|
|
* accomplishes virtual dispatch. Every `Poly` object contains a pointer to a
|
|
* table of function pointers. Member function calls involve a double-
|
|
* indirection: once through the v-pointer, and other indirect function call
|
|
* through the function pointer.
|
|
*/
|
|
template <class I>
|
|
struct Poly final : detail::PolyValOrRef<I> {
|
|
friend detail::PolyAccess;
|
|
Poly() = default;
|
|
using detail::PolyValOrRef<I>::PolyValOrRef;
|
|
using detail::PolyValOrRef<I>::operator=;
|
|
};
|
|
|
|
/**
|
|
* Swap two `Poly<I>` instances.
|
|
*/
|
|
template <class I>
|
|
void swap(Poly<I>& left, Poly<I>& right) noexcept {
|
|
left.swap(right);
|
|
}
|
|
|
|
/**
|
|
* Pseudo-function template handy for disambiguating function overloads.
|
|
*
|
|
* For example, given:
|
|
* struct S {
|
|
* int property() const;
|
|
* void property(int);
|
|
* };
|
|
*
|
|
* You can get a member function pointer to the first overload with:
|
|
* folly::sig<int()const>(&S::property);
|
|
*
|
|
* This is arguably a nicer syntax that using the built-in `static_cast`:
|
|
* static_cast<int (S::*)() const>(&S::property);
|
|
*
|
|
* `sig` is also more permissive than `static_cast` about `const`. For instance,
|
|
* the following also works:
|
|
* folly::sig<int()>(&S::property);
|
|
*
|
|
* The above is permitted
|
|
*/
|
|
template <class Sig>
|
|
FOLLY_INLINE_CONSTEXPR detail::Sig<Sig> const sig = {};
|
|
|
|
} // namespace folly
|
|
|
|
#include <folly/Poly-inl.h>
|
|
|
|
#undef FOLLY_INLINE_CONSTEXPR
|