tvl-depot/absl/types/variant.h
Abseil Team bf29470384 Export of internal Abseil changes.
--
bdce7e57e9e886eff1114d0266781b443f7ec639 by Derek Mauro <dmauro@google.com>:

Change {Get|Set}EnvironmentVariable to {Get|Set}EnvironmentVariableA for
compatibility with /DUNICODE.

PiperOrigin-RevId: 239229514

--
2276ed502326a044a84060d34eb19d499e3a3be2 by Derek Mauro <dmauro@google.com>:

Import of CCTZ from GitHub.

PiperOrigin-RevId: 239228622

--
a462efb970ff43b08a362ef2343fb75ac1295a50 by Derek Mauro <dmauro@google.com>:

Adding linking of CoreFoundation to CMakeLists in absl/time.
Import https://github.com/abseil/abseil-cpp/pull/280.

Fix #283

PiperOrigin-RevId: 239220785

--
fc23327b97f940c682aae1956cf7a1bf87f88c06 by Derek Mauro <dmauro@google.com>:

Add hermetic test script that uses Docker to build with a very recent
version of gcc (8.3.0 today) with libstdc++ and bazel.

PiperOrigin-RevId: 239220448

--
418c08a8f6a53e63b84e39473035774417ca3aa7 by Derek Mauro <dmauro@google.com>:

Disable part of the variant exeception safety test on move assignment
when using versions of libstd++ that contain a bug.
https://gcc.gnu.org/bugzilla/show_bug.cgi?id=87431#c7

PiperOrigin-RevId: 239062455

--
799722217aeda79679577843c91d5be62cbcbb42 by Matt Calabrese <calabrese@google.com>:

Add internal-only IsSwappable traits corresponding to std::is_swappable and std::is_nothrow_swappable, which are used with the swap implementations of optional and variant.

PiperOrigin-RevId: 239049448

--
aa46a036038a3de5c68ac5e5d3b4bf76f818d2ea by CJ Johnson <johnsoncj@google.com>:

Make InlinedVectorStorage constructor explicit

PiperOrigin-RevId: 239044361

--
17949715b3aa21c794701f69f2154e91b6acabc3 by CJ Johnson <johnsoncj@google.com>:

Add absl namesapce to internal/inlined_vector.h

PiperOrigin-RevId: 239030789

--
834628325953078cc08ed10d23bb8890e5bec897 by Derek Mauro <dmauro@google.com>:

Add test script that uses Docker to build Abseil with gcc-4.8,
libstdc++, and cmake.

PiperOrigin-RevId: 239028433

--
80fe24149ed73ed2ced995ad1e372fb060c60427 by CJ Johnson <johnsoncj@google.com>:

Factors data members of InlinedVector into an impl type called InlinedVectorStorage so that (in future changes) the contents of a vector can be grouped together with a single pointer.

PiperOrigin-RevId: 239021086

--
585331436d5d4d79f845e45dcf79d918a0dc6169 by Derek Mauro <dmauro@google.com>:

Add -Wno-missing-field-initializers to gcc compiler flags.
gcc-4.x has spurious missing field initializer warnings.
https://gcc.gnu.org/bugzilla/show_bug.cgi?id=36750

PiperOrigin-RevId: 239017217

--
94602fe4e33ee3a552a7f2939c0f57a992f55075 by Abseil Team <absl-team@google.com>:

Formatting fixes.

PiperOrigin-RevId: 238983038

--
a1c1b63c08505574e0a8c491561840cecb2bb93e by Derek Mauro <dmauro@google.com>:

Add hermetic test script that uses Docker to build with a very recent
version of clang with libc++ and bazel.

PiperOrigin-RevId: 238669118

--
e525f8d20bc2f79a0d69336b902f63858f3bff9d by Derek Mauro <dmauro@google.com>:

Disable the test optionalTest.InPlaceTSFINAEBug until libc++ is updated.

PiperOrigin-RevId: 238661703

--
f99a2a0b5ec424a059678f7f226600f137b4c74e by Derek Mauro <dmauro@google.com>:

Correct the check for the FlatHashMap-Any test bug (list conditions
instead of platforms when possible)

PiperOrigin-RevId: 238653344

--
777928035dbcbf39f361eb7d10dc3696822f692f by Jon Cohen <cohenjon@google.com>:

Add install rules for Abseil CMake.

These are attempted to be limited to in-project installation.  This serves two purposes -- first it's morally the same as using Abseil in-source, except you don't have to rebuild us every time.  Second, the presence of an install rule makes life massively simpler for package manager maintainers.

Currently this doesn't install absl tests or testonly libraries.  This can be added in a follow-up patch.

Fixes #38, Fixes #80, Closes #182

PiperOrigin-RevId: 238645836

--
ded1c6ce697c191b7a6ff14572b3e6d183117b2c by Derek Mauro <dmauro@google.com>:

Add hermetic test script that uses Docker to build with a very recent
version of clang with libstdc++ and bazel.

PiperOrigin-RevId: 238517815
GitOrigin-RevId: bdce7e57e9e886eff1114d0266781b443f7ec639
Change-Id: I6f745869cb8ef63851891ccac05ae9a7dd241c4f
2019-03-19 14:19:10 -04:00

855 lines
33 KiB
C++

// Copyright 2018 The Abseil Authors.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// https://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
//
// -----------------------------------------------------------------------------
// variant.h
// -----------------------------------------------------------------------------
//
// This header file defines an `absl::variant` type for holding a type-safe
// value of some prescribed set of types (noted as alternative types), and
// associated functions for managing variants.
//
// The `absl::variant` type is a form of type-safe union. An `absl::variant`
// should always hold a value of one of its alternative types (except in the
// "valueless by exception state" -- see below). A default-constructed
// `absl::variant` will hold the value of its first alternative type, provided
// it is default-constructable.
//
// In exceptional cases due to error, an `absl::variant` can hold no
// value (known as a "valueless by exception" state), though this is not the
// norm.
//
// As with `absl::optional`, an `absl::variant` -- when it holds a value --
// allocates a value of that type directly within the `variant` itself; it
// cannot hold a reference, array, or the type `void`; it can, however, hold a
// pointer to externally managed memory.
//
// `absl::variant` is a C++11 compatible version of the C++17 `std::variant`
// abstraction and is designed to be a drop-in replacement for code compliant
// with C++17.
#ifndef ABSL_TYPES_VARIANT_H_
#define ABSL_TYPES_VARIANT_H_
#include "absl/base/config.h"
#include "absl/utility/utility.h"
#ifdef ABSL_HAVE_STD_VARIANT
#include <variant> // IWYU pragma: export
namespace absl {
using std::bad_variant_access;
using std::get;
using std::get_if;
using std::holds_alternative;
using std::monostate;
using std::variant;
using std::variant_alternative;
using std::variant_alternative_t;
using std::variant_npos;
using std::variant_size;
using std::variant_size_v;
using std::visit;
} // namespace absl
#else // ABSL_HAVE_STD_VARIANT
#include <functional>
#include <new>
#include <type_traits>
#include <utility>
#include "absl/base/macros.h"
#include "absl/base/port.h"
#include "absl/meta/type_traits.h"
#include "absl/types/internal/variant.h"
namespace absl {
// -----------------------------------------------------------------------------
// absl::variant
// -----------------------------------------------------------------------------
//
// An `absl::variant` type is a form of type-safe union. An `absl::variant` --
// except in exceptional cases -- always holds a value of one of its alternative
// types.
//
// Example:
//
// // Construct a variant that holds either an integer or a std::string and
// // assign it to a std::string.
// absl::variant<int, std::string> v = std::string("abc");
//
// // A default-contructed variant will hold a value-initialized value of
// // the first alternative type.
// auto a = absl::variant<int, std::string>(); // Holds an int of value '0'.
//
// // variants are assignable.
//
// // copy assignment
// auto v1 = absl::variant<int, std::string>("abc");
// auto v2 = absl::variant<int, std::string>(10);
// v2 = v1; // copy assign
//
// // move assignment
// auto v1 = absl::variant<int, std::string>("abc");
// v1 = absl::variant<int, std::string>(10);
//
// // assignment through type conversion
// a = 128; // variant contains int
// a = "128"; // variant contains std::string
//
// An `absl::variant` holding a value of one of its alternative types `T` holds
// an allocation of `T` directly within the variant itself. An `absl::variant`
// is not allowed to allocate additional storage, such as dynamic memory, to
// allocate the contained value. The contained value shall be allocated in a
// region of the variant storage suitably aligned for all alternative types.
template <typename... Ts>
class variant;
// swap()
//
// Swaps two `absl::variant` values. This function is equivalent to `v.swap(w)`
// where `v` and `w` are `absl::variant` types.
//
// Note that this function requires all alternative types to be both swappable
// and move-constructible, because any two variants may refer to either the same
// type (in which case, they will be swapped) or to two different types (in
// which case the values will need to be moved).
//
template <
typename... Ts,
absl::enable_if_t<
absl::conjunction<std::is_move_constructible<Ts>...,
type_traits_internal::IsSwappable<Ts>...>::value,
int> = 0>
void swap(variant<Ts...>& v, variant<Ts...>& w) noexcept(noexcept(v.swap(w))) {
v.swap(w);
}
// variant_size
//
// Returns the number of alternative types available for a given `absl::variant`
// type as a compile-time constant expression. As this is a class template, it
// is not generally useful for accessing the number of alternative types of
// any given `absl::variant` instance.
//
// Example:
//
// auto a = absl::variant<int, std::string>;
// constexpr int num_types =
// absl::variant_size<absl::variant<int, std::string>>();
//
// // You can also use the member constant `value`.
// constexpr int num_types =
// absl::variant_size<absl::variant<int, std::string>>::value;
//
// // `absl::variant_size` is more valuable for use in generic code:
// template <typename Variant>
// constexpr bool IsVariantMultivalue() {
// return absl::variant_size<Variant>() > 1;
// }
//
// Note that the set of cv-qualified specializations of `variant_size` are
// provided to ensure that those specializations compile (especially when passed
// within template logic).
template <class T>
struct variant_size;
template <class... Ts>
struct variant_size<variant<Ts...>>
: std::integral_constant<std::size_t, sizeof...(Ts)> {};
// Specialization of `variant_size` for const qualified variants.
template <class T>
struct variant_size<const T> : variant_size<T>::type {};
// Specialization of `variant_size` for volatile qualified variants.
template <class T>
struct variant_size<volatile T> : variant_size<T>::type {};
// Specialization of `variant_size` for const volatile qualified variants.
template <class T>
struct variant_size<const volatile T> : variant_size<T>::type {};
// variant_alternative
//
// Returns the alternative type for a given `absl::variant` at the passed
// index value as a compile-time constant expression. As this is a class
// template resulting in a type, it is not useful for access of the run-time
// value of any given `absl::variant` variable.
//
// Example:
//
// // The type of the 0th alternative is "int".
// using alternative_type_0
// = absl::variant_alternative<0, absl::variant<int, std::string>>::type;
//
// static_assert(std::is_same<alternative_type_0, int>::value, "");
//
// // `absl::variant_alternative` is more valuable for use in generic code:
// template <typename Variant>
// constexpr bool IsFirstElementTrivial() {
// return std::is_trivial_v<variant_alternative<0, Variant>::type>;
// }
//
// Note that the set of cv-qualified specializations of `variant_alternative`
// are provided to ensure that those specializations compile (especially when
// passed within template logic).
template <std::size_t I, class T>
struct variant_alternative;
template <std::size_t I, class... Types>
struct variant_alternative<I, variant<Types...>> {
using type =
variant_internal::VariantAlternativeSfinaeT<I, variant<Types...>>;
};
// Specialization of `variant_alternative` for const qualified variants.
template <std::size_t I, class T>
struct variant_alternative<I, const T> {
using type = const typename variant_alternative<I, T>::type;
};
// Specialization of `variant_alternative` for volatile qualified variants.
template <std::size_t I, class T>
struct variant_alternative<I, volatile T> {
using type = volatile typename variant_alternative<I, T>::type;
};
// Specialization of `variant_alternative` for const volatile qualified
// variants.
template <std::size_t I, class T>
struct variant_alternative<I, const volatile T> {
using type = const volatile typename variant_alternative<I, T>::type;
};
// Template type alias for variant_alternative<I, T>::type.
//
// Example:
//
// using alternative_type_0
// = absl::variant_alternative_t<0, absl::variant<int, std::string>>;
// static_assert(std::is_same<alternative_type_0, int>::value, "");
template <std::size_t I, class T>
using variant_alternative_t = typename variant_alternative<I, T>::type;
// holds_alternative()
//
// Checks whether the given variant currently holds a given alternative type,
// returning `true` if so.
//
// Example:
//
// absl::variant<int, std::string> foo = 42;
// if (absl::holds_alternative<int>(foo)) {
// std::cout << "The variant holds an integer";
// }
template <class T, class... Types>
constexpr bool holds_alternative(const variant<Types...>& v) noexcept {
static_assert(
variant_internal::UnambiguousIndexOfImpl<variant<Types...>, T,
0>::value != sizeof...(Types),
"The type T must occur exactly once in Types...");
return v.index() ==
variant_internal::UnambiguousIndexOf<variant<Types...>, T>::value;
}
// get()
//
// Returns a reference to the value currently within a given variant, using
// either a unique alternative type amongst the variant's set of alternative
// types, or the variant's index value. Attempting to get a variant's value
// using a type that is not unique within the variant's set of alternative types
// is a compile-time error. If the index of the alternative being specified is
// different from the index of the alternative that is currently stored, throws
// `absl::bad_variant_access`.
//
// Example:
//
// auto a = absl::variant<int, std::string>;
//
// // Get the value by type (if unique).
// int i = absl::get<int>(a);
//
// auto b = absl::variant<int, int>;
//
// // Getting the value by a type that is not unique is ill-formed.
// int j = absl::get<int>(b); // Compile Error!
//
// // Getting value by index not ambiguous and allowed.
// int k = absl::get<1>(b);
// Overload for getting a variant's lvalue by type.
template <class T, class... Types>
constexpr T& get(variant<Types...>& v) { // NOLINT
return variant_internal::VariantCoreAccess::CheckedAccess<
variant_internal::IndexOf<T, Types...>::value>(v);
}
// Overload for getting a variant's rvalue by type.
// Note: `absl::move()` is required to allow use of constexpr in C++11.
template <class T, class... Types>
constexpr T&& get(variant<Types...>&& v) {
return variant_internal::VariantCoreAccess::CheckedAccess<
variant_internal::IndexOf<T, Types...>::value>(absl::move(v));
}
// Overload for getting a variant's const lvalue by type.
template <class T, class... Types>
constexpr const T& get(const variant<Types...>& v) {
return variant_internal::VariantCoreAccess::CheckedAccess<
variant_internal::IndexOf<T, Types...>::value>(v);
}
// Overload for getting a variant's const rvalue by type.
// Note: `absl::move()` is required to allow use of constexpr in C++11.
template <class T, class... Types>
constexpr const T&& get(const variant<Types...>&& v) {
return variant_internal::VariantCoreAccess::CheckedAccess<
variant_internal::IndexOf<T, Types...>::value>(absl::move(v));
}
// Overload for getting a variant's lvalue by index.
template <std::size_t I, class... Types>
constexpr variant_alternative_t<I, variant<Types...>>& get(
variant<Types...>& v) { // NOLINT
return variant_internal::VariantCoreAccess::CheckedAccess<I>(v);
}
// Overload for getting a variant's rvalue by index.
// Note: `absl::move()` is required to allow use of constexpr in C++11.
template <std::size_t I, class... Types>
constexpr variant_alternative_t<I, variant<Types...>>&& get(
variant<Types...>&& v) {
return variant_internal::VariantCoreAccess::CheckedAccess<I>(absl::move(v));
}
// Overload for getting a variant's const lvalue by index.
template <std::size_t I, class... Types>
constexpr const variant_alternative_t<I, variant<Types...>>& get(
const variant<Types...>& v) {
return variant_internal::VariantCoreAccess::CheckedAccess<I>(v);
}
// Overload for getting a variant's const rvalue by index.
// Note: `absl::move()` is required to allow use of constexpr in C++11.
template <std::size_t I, class... Types>
constexpr const variant_alternative_t<I, variant<Types...>>&& get(
const variant<Types...>&& v) {
return variant_internal::VariantCoreAccess::CheckedAccess<I>(absl::move(v));
}
// get_if()
//
// Returns a pointer to the value currently stored within a given variant, if
// present, using either a unique alternative type amongst the variant's set of
// alternative types, or the variant's index value. If such a value does not
// exist, returns `nullptr`.
//
// As with `get`, attempting to get a variant's value using a type that is not
// unique within the variant's set of alternative types is a compile-time error.
// Overload for getting a pointer to the value stored in the given variant by
// index.
template <std::size_t I, class... Types>
constexpr absl::add_pointer_t<variant_alternative_t<I, variant<Types...>>>
get_if(variant<Types...>* v) noexcept {
return (v != nullptr && v->index() == I)
? std::addressof(
variant_internal::VariantCoreAccess::Access<I>(*v))
: nullptr;
}
// Overload for getting a pointer to the const value stored in the given
// variant by index.
template <std::size_t I, class... Types>
constexpr absl::add_pointer_t<const variant_alternative_t<I, variant<Types...>>>
get_if(const variant<Types...>* v) noexcept {
return (v != nullptr && v->index() == I)
? std::addressof(
variant_internal::VariantCoreAccess::Access<I>(*v))
: nullptr;
}
// Overload for getting a pointer to the value stored in the given variant by
// type.
template <class T, class... Types>
constexpr absl::add_pointer_t<T> get_if(variant<Types...>* v) noexcept {
return absl::get_if<variant_internal::IndexOf<T, Types...>::value>(v);
}
// Overload for getting a pointer to the const value stored in the given variant
// by type.
template <class T, class... Types>
constexpr absl::add_pointer_t<const T> get_if(
const variant<Types...>* v) noexcept {
return absl::get_if<variant_internal::IndexOf<T, Types...>::value>(v);
}
// visit()
//
// Calls a provided functor on a given set of variants. `absl::visit()` is
// commonly used to conditionally inspect the state of a given variant (or set
// of variants).
//
// The functor must return the same type when called with any of the variants'
// alternatives.
//
// Example:
//
// // Define a visitor functor
// struct GetVariant {
// template<typename T>
// void operator()(const T& i) const {
// std::cout << "The variant's value is: " << i;
// }
// };
//
// // Declare our variant, and call `absl::visit()` on it.
// // Note that `GetVariant()` returns void in either case.
// absl::variant<int, std::string> foo = std::string("foo");
// GetVariant visitor;
// absl::visit(visitor, foo); // Prints `The variant's value is: foo'
template <typename Visitor, typename... Variants>
variant_internal::VisitResult<Visitor, Variants...> visit(Visitor&& vis,
Variants&&... vars) {
return variant_internal::
VisitIndices<variant_size<absl::decay_t<Variants> >::value...>::Run(
variant_internal::PerformVisitation<Visitor, Variants...>{
std::forward_as_tuple(absl::forward<Variants>(vars)...),
absl::forward<Visitor>(vis)},
vars.index()...);
}
// monostate
//
// The monostate class serves as a first alternative type for a variant for
// which the first variant type is otherwise not default-constructible.
struct monostate {};
// `absl::monostate` Relational Operators
constexpr bool operator<(monostate, monostate) noexcept { return false; }
constexpr bool operator>(monostate, monostate) noexcept { return false; }
constexpr bool operator<=(monostate, monostate) noexcept { return true; }
constexpr bool operator>=(monostate, monostate) noexcept { return true; }
constexpr bool operator==(monostate, monostate) noexcept { return true; }
constexpr bool operator!=(monostate, monostate) noexcept { return false; }
//------------------------------------------------------------------------------
// `absl::variant` Template Definition
//------------------------------------------------------------------------------
template <typename T0, typename... Tn>
class variant<T0, Tn...> : private variant_internal::VariantBase<T0, Tn...> {
static_assert(absl::conjunction<std::is_object<T0>,
std::is_object<Tn>...>::value,
"Attempted to instantiate a variant containing a non-object "
"type.");
// Intentionally not qualifying `negation` with `absl::` to work around a bug
// in MSVC 2015 with inline namespace and variadic template.
static_assert(absl::conjunction<negation<std::is_array<T0> >,
negation<std::is_array<Tn> >...>::value,
"Attempted to instantiate a variant containing an array type.");
static_assert(absl::conjunction<std::is_nothrow_destructible<T0>,
std::is_nothrow_destructible<Tn>...>::value,
"Attempted to instantiate a variant containing a non-nothrow "
"destructible type.");
friend struct variant_internal::VariantCoreAccess;
private:
using Base = variant_internal::VariantBase<T0, Tn...>;
public:
// Constructors
// Constructs a variant holding a default-initialized value of the first
// alternative type.
constexpr variant() /*noexcept(see 111above)*/ = default;
// Copy constructor, standard semantics
variant(const variant& other) = default;
// Move constructor, standard semantics
variant(variant&& other) /*noexcept(see above)*/ = default;
// Constructs a variant of an alternative type specified by overload
// resolution of the provided forwarding arguments through
// direct-initialization.
//
// Note: If the selected constructor is a constexpr constructor, this
// constructor shall be a constexpr constructor.
//
// NOTE: http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2018/p0608r1.html
// has been voted passed the design phase in the C++ standard meeting in Mar
// 2018. It will be implemented and integrated into `absl::variant`.
template <
class T,
std::size_t I = std::enable_if<
variant_internal::IsNeitherSelfNorInPlace<variant,
absl::decay_t<T>>::value,
variant_internal::IndexOfConstructedType<variant, T>>::type::value,
class Tj = absl::variant_alternative_t<I, variant>,
absl::enable_if_t<std::is_constructible<Tj, T>::value>* =
nullptr>
constexpr variant(T&& t) noexcept(std::is_nothrow_constructible<Tj, T>::value)
: Base(variant_internal::EmplaceTag<I>(), absl::forward<T>(t)) {}
// Constructs a variant of an alternative type from the arguments through
// direct-initialization.
//
// Note: If the selected constructor is a constexpr constructor, this
// constructor shall be a constexpr constructor.
template <class T, class... Args,
typename std::enable_if<std::is_constructible<
variant_internal::UnambiguousTypeOfT<variant, T>,
Args...>::value>::type* = nullptr>
constexpr explicit variant(in_place_type_t<T>, Args&&... args)
: Base(variant_internal::EmplaceTag<
variant_internal::UnambiguousIndexOf<variant, T>::value>(),
absl::forward<Args>(args)...) {}
// Constructs a variant of an alternative type from an initializer list
// and other arguments through direct-initialization.
//
// Note: If the selected constructor is a constexpr constructor, this
// constructor shall be a constexpr constructor.
template <class T, class U, class... Args,
typename std::enable_if<std::is_constructible<
variant_internal::UnambiguousTypeOfT<variant, T>,
std::initializer_list<U>&, Args...>::value>::type* = nullptr>
constexpr explicit variant(in_place_type_t<T>, std::initializer_list<U> il,
Args&&... args)
: Base(variant_internal::EmplaceTag<
variant_internal::UnambiguousIndexOf<variant, T>::value>(),
il, absl::forward<Args>(args)...) {}
// Constructs a variant of an alternative type from a provided index,
// through value-initialization using the provided forwarded arguments.
template <std::size_t I, class... Args,
typename std::enable_if<std::is_constructible<
variant_internal::VariantAlternativeSfinaeT<I, variant>,
Args...>::value>::type* = nullptr>
constexpr explicit variant(in_place_index_t<I>, Args&&... args)
: Base(variant_internal::EmplaceTag<I>(), absl::forward<Args>(args)...) {}
// Constructs a variant of an alternative type from a provided index,
// through value-initialization of an initializer list and the provided
// forwarded arguments.
template <std::size_t I, class U, class... Args,
typename std::enable_if<std::is_constructible<
variant_internal::VariantAlternativeSfinaeT<I, variant>,
std::initializer_list<U>&, Args...>::value>::type* = nullptr>
constexpr explicit variant(in_place_index_t<I>, std::initializer_list<U> il,
Args&&... args)
: Base(variant_internal::EmplaceTag<I>(), il,
absl::forward<Args>(args)...) {}
// Destructors
// Destroys the variant's currently contained value, provided that
// `absl::valueless_by_exception()` is false.
~variant() = default;
// Assignment Operators
// Copy assignment operator
variant& operator=(const variant& other) = default;
// Move assignment operator
variant& operator=(variant&& other) /*noexcept(see above)*/ = default;
// Converting assignment operator
//
// NOTE: http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2018/p0608r1.html
// has been voted passed the design phase in the C++ standard meeting in Mar
// 2018. It will be implemented and integrated into `absl::variant`.
template <
class T,
std::size_t I = std::enable_if<
!std::is_same<absl::decay_t<T>, variant>::value,
variant_internal::IndexOfConstructedType<variant, T>>::type::value,
class Tj = absl::variant_alternative_t<I, variant>,
typename std::enable_if<std::is_assignable<Tj&, T>::value &&
std::is_constructible<Tj, T>::value>::type* =
nullptr>
variant& operator=(T&& t) noexcept(
std::is_nothrow_assignable<Tj&, T>::value&&
std::is_nothrow_constructible<Tj, T>::value) {
variant_internal::VisitIndices<sizeof...(Tn) + 1>::Run(
variant_internal::VariantCoreAccess::MakeConversionAssignVisitor(
this, absl::forward<T>(t)),
index());
return *this;
}
// emplace() Functions
// Constructs a value of the given alternative type T within the variant.
//
// Example:
//
// absl::variant<std::vector<int>, int, std::string> v;
// v.emplace<int>(99);
// v.emplace<std::string>("abc");
template <
class T, class... Args,
typename std::enable_if<std::is_constructible<
absl::variant_alternative_t<
variant_internal::UnambiguousIndexOf<variant, T>::value, variant>,
Args...>::value>::type* = nullptr>
T& emplace(Args&&... args) {
return variant_internal::VariantCoreAccess::Replace<
variant_internal::UnambiguousIndexOf<variant, T>::value>(
this, absl::forward<Args>(args)...);
}
// Constructs a value of the given alternative type T within the variant using
// an initializer list.
//
// Example:
//
// absl::variant<std::vector<int>, int, std::string> v;
// v.emplace<std::vector<int>>({0, 1, 2});
template <
class T, class U, class... Args,
typename std::enable_if<std::is_constructible<
absl::variant_alternative_t<
variant_internal::UnambiguousIndexOf<variant, T>::value, variant>,
std::initializer_list<U>&, Args...>::value>::type* = nullptr>
T& emplace(std::initializer_list<U> il, Args&&... args) {
return variant_internal::VariantCoreAccess::Replace<
variant_internal::UnambiguousIndexOf<variant, T>::value>(
this, il, absl::forward<Args>(args)...);
}
// Destroys the current value of the variant (provided that
// `absl::valueless_by_exception()` is false, and constructs a new value at
// the given index.
//
// Example:
//
// absl::variant<std::vector<int>, int, int> v;
// v.emplace<1>(99);
// v.emplace<2>(98);
// v.emplace<int>(99); // Won't compile. 'int' isn't a unique type.
template <std::size_t I, class... Args,
typename std::enable_if<
std::is_constructible<absl::variant_alternative_t<I, variant>,
Args...>::value>::type* = nullptr>
absl::variant_alternative_t<I, variant>& emplace(Args&&... args) {
return variant_internal::VariantCoreAccess::Replace<I>(
this, absl::forward<Args>(args)...);
}
// Destroys the current value of the variant (provided that
// `absl::valueless_by_exception()` is false, and constructs a new value at
// the given index using an initializer list and the provided arguments.
//
// Example:
//
// absl::variant<std::vector<int>, int, int> v;
// v.emplace<0>({0, 1, 2});
template <std::size_t I, class U, class... Args,
typename std::enable_if<std::is_constructible<
absl::variant_alternative_t<I, variant>,
std::initializer_list<U>&, Args...>::value>::type* = nullptr>
absl::variant_alternative_t<I, variant>& emplace(std::initializer_list<U> il,
Args&&... args) {
return variant_internal::VariantCoreAccess::Replace<I>(
this, il, absl::forward<Args>(args)...);
}
// variant::valueless_by_exception()
//
// Returns false if and only if the variant currently holds a valid value.
constexpr bool valueless_by_exception() const noexcept {
return this->index_ == absl::variant_npos;
}
// variant::index()
//
// Returns the index value of the variant's currently selected alternative
// type.
constexpr std::size_t index() const noexcept { return this->index_; }
// variant::swap()
//
// Swaps the values of two variant objects.
//
void swap(variant& rhs) noexcept(
absl::conjunction<
std::is_nothrow_move_constructible<T0>,
std::is_nothrow_move_constructible<Tn>...,
type_traits_internal::IsNothrowSwappable<T0>,
type_traits_internal::IsNothrowSwappable<Tn>...>::value) {
return variant_internal::VisitIndices<sizeof...(Tn) + 1>::Run(
variant_internal::Swap<T0, Tn...>{this, &rhs}, rhs.index());
}
};
// We need a valid declaration of variant<> for SFINAE and overload resolution
// to work properly above, but we don't need a full declaration since this type
// will never be constructed. This declaration, though incomplete, suffices.
template <>
class variant<>;
//------------------------------------------------------------------------------
// Relational Operators
//------------------------------------------------------------------------------
//
// If neither operand is in the `variant::valueless_by_exception` state:
//
// * If the index of both variants is the same, the relational operator
// returns the result of the corresponding relational operator for the
// corresponding alternative type.
// * If the index of both variants is not the same, the relational operator
// returns the result of that operation applied to the value of the left
// operand's index and the value of the right operand's index.
// * If at least one operand is in the valueless_by_exception state:
// - A variant in the valueless_by_exception state is only considered equal
// to another variant in the valueless_by_exception state.
// - If exactly one operand is in the valueless_by_exception state, the
// variant in the valueless_by_exception state is less than the variant
// that is not in the valueless_by_exception state.
//
// Note: The value 1 is added to each index in the relational comparisons such
// that the index corresponding to the valueless_by_exception state wraps around
// to 0 (the lowest value for the index type), and the remaining indices stay in
// the same relative order.
// Equal-to operator
template <typename... Types>
constexpr variant_internal::RequireAllHaveEqualT<Types...> operator==(
const variant<Types...>& a, const variant<Types...>& b) {
return (a.index() == b.index()) &&
variant_internal::VisitIndices<sizeof...(Types)>::Run(
variant_internal::EqualsOp<Types...>{&a, &b}, a.index());
}
// Not equal operator
template <typename... Types>
constexpr variant_internal::RequireAllHaveNotEqualT<Types...> operator!=(
const variant<Types...>& a, const variant<Types...>& b) {
return (a.index() != b.index()) ||
variant_internal::VisitIndices<sizeof...(Types)>::Run(
variant_internal::NotEqualsOp<Types...>{&a, &b}, a.index());
}
// Less-than operator
template <typename... Types>
constexpr variant_internal::RequireAllHaveLessThanT<Types...> operator<(
const variant<Types...>& a, const variant<Types...>& b) {
return (a.index() != b.index())
? (a.index() + 1) < (b.index() + 1)
: variant_internal::VisitIndices<sizeof...(Types)>::Run(
variant_internal::LessThanOp<Types...>{&a, &b}, a.index());
}
// Greater-than operator
template <typename... Types>
constexpr variant_internal::RequireAllHaveGreaterThanT<Types...> operator>(
const variant<Types...>& a, const variant<Types...>& b) {
return (a.index() != b.index())
? (a.index() + 1) > (b.index() + 1)
: variant_internal::VisitIndices<sizeof...(Types)>::Run(
variant_internal::GreaterThanOp<Types...>{&a, &b},
a.index());
}
// Less-than or equal-to operator
template <typename... Types>
constexpr variant_internal::RequireAllHaveLessThanOrEqualT<Types...> operator<=(
const variant<Types...>& a, const variant<Types...>& b) {
return (a.index() != b.index())
? (a.index() + 1) < (b.index() + 1)
: variant_internal::VisitIndices<sizeof...(Types)>::Run(
variant_internal::LessThanOrEqualsOp<Types...>{&a, &b},
a.index());
}
// Greater-than or equal-to operator
template <typename... Types>
constexpr variant_internal::RequireAllHaveGreaterThanOrEqualT<Types...>
operator>=(const variant<Types...>& a, const variant<Types...>& b) {
return (a.index() != b.index())
? (a.index() + 1) > (b.index() + 1)
: variant_internal::VisitIndices<sizeof...(Types)>::Run(
variant_internal::GreaterThanOrEqualsOp<Types...>{&a, &b},
a.index());
}
} // namespace absl
namespace std {
// hash()
template <> // NOLINT
struct hash<absl::monostate> {
std::size_t operator()(absl::monostate) const { return 0; }
};
template <class... T> // NOLINT
struct hash<absl::variant<T...>>
: absl::variant_internal::VariantHashBase<absl::variant<T...>, void,
absl::remove_const_t<T>...> {};
} // namespace std
#endif // ABSL_HAVE_STD_VARIANT
namespace absl {
namespace variant_internal {
// Helper visitor for converting a variant<Ts...>` into another type (mostly
// variant) that can be constructed from any type.
template <typename To>
struct ConversionVisitor {
template <typename T>
To operator()(T&& v) const {
return To(std::forward<T>(v));
}
};
} // namespace variant_internal
// ConvertVariantTo()
//
// Helper functions to convert an `absl::variant` to a variant of another set of
// types, provided that the alternative type of the new variant type can be
// converted from any type in the source variant.
//
// Example:
//
// absl::variant<name1, name2, float> InternalReq(const Req&);
//
// // name1 and name2 are convertible to name
// absl::variant<name, float> ExternalReq(const Req& req) {
// return absl::ConvertVariantTo<absl::variant<name, float>>(
// InternalReq(req));
// }
template <typename To, typename Variant>
To ConvertVariantTo(Variant&& variant) {
return absl::visit(variant_internal::ConversionVisitor<To>{},
std::forward<Variant>(variant));
}
} // namespace absl
#endif // ABSL_TYPES_VARIANT_H_