// Copyright 2022 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. // // Implementation details for `absl::AnyInvocable` #ifndef ABSL_FUNCTIONAL_INTERNAL_ANY_INVOCABLE_H_ #define ABSL_FUNCTIONAL_INTERNAL_ANY_INVOCABLE_H_ //////////////////////////////////////////////////////////////////////////////// // // // This implementation chooses between local storage and remote storage for // // the contained target object based on the target object's size, alignment // // requirements, and whether or not it has a nothrow move constructor. // // Additional optimizations are performed when the object is a trivially // // copyable type [basic.types]. // // // // There are three datamembers per `AnyInvocable` instance // // // // 1) A union containing either // // - A pointer to the target object referred to via a void*, or // // - the target object, emplaced into a raw char buffer // // // // 2) A function pointer to a "manager" function operation that takes a // // discriminator and logically branches to either perform a move operation // // or destroy operation based on that discriminator. // // // // 3) A function pointer to an "invoker" function operation that invokes the // // target object, directly returning the result. // // // // When in the logically empty state, the manager function is an empty // // function and the invoker function is one that would be undefined behavior // // to call. // // // // An additional optimization is performed when converting from one // // AnyInvocable to another where only the noexcept specification and/or the // // cv/ref qualifiers of the function type differ. In these cases, the // // conversion works by "moving the guts", similar to if they were the same // // exact type, as opposed to having to perform an additional layer of // // wrapping through remote storage. // // // //////////////////////////////////////////////////////////////////////////////// // IWYU pragma: private, include "absl/functional/any_invocable.h" #include #include #include #include #include #include #include #include #include #include "absl/base/attributes.h" #include "absl/base/config.h" #include "absl/base/internal/invoke.h" #include "absl/base/macros.h" #include "absl/base/optimization.h" #include "absl/meta/type_traits.h" #include "absl/utility/utility.h" namespace absl { ABSL_NAMESPACE_BEGIN // Helper macro used to prevent spelling `noexcept` in language versions older // than C++17, where it is not part of the type system, in order to avoid // compilation failures and internal compiler errors. #if ABSL_INTERNAL_CPLUSPLUS_LANG >= 201703L #define ABSL_INTERNAL_NOEXCEPT_SPEC(noex) noexcept(noex) #else #define ABSL_INTERNAL_NOEXCEPT_SPEC(noex) #endif // Defined in functional/any_invocable.h template class AnyInvocable; namespace internal_any_invocable { // Constants relating to the small-object-storage for AnyInvocable enum StorageProperty : std::size_t { kAlignment = alignof(std::max_align_t), // The alignment of the storage kStorageSize = sizeof(void*) * 2 // The size of the storage }; //////////////////////////////////////////////////////////////////////////////// // // A metafunction for checking if a type is an AnyInvocable instantiation. // This is used during conversion operations. template struct IsAnyInvocable : std::false_type {}; template struct IsAnyInvocable> : std::true_type {}; // //////////////////////////////////////////////////////////////////////////////// // A type trait that tells us whether or not a target function type should be // stored locally in the small object optimization storage template using IsStoredLocally = std::integral_constant< bool, sizeof(T) <= kStorageSize && alignof(T) <= kAlignment && kAlignment % alignof(T) == 0 && std::is_nothrow_move_constructible::value>; // An implementation of std::remove_cvref_t of C++20. template using RemoveCVRef = typename std::remove_cv::type>::type; //////////////////////////////////////////////////////////////////////////////// // // An implementation of the C++ standard INVOKE pseudo-macro, operation is // equivalent to std::invoke except that it forces an implicit conversion to the // specified return type. If "R" is void, the function is executed and the // return value is simply ignored. template ::value>> void InvokeR(F&& f, P&&... args) { absl::base_internal::invoke(std::forward(f), std::forward

(args)...); } template ::value, int> = 0> ReturnType InvokeR(F&& f, P&&... args) { // GCC 12 has a false-positive -Wmaybe-uninitialized warning here. #if ABSL_INTERNAL_HAVE_MIN_GNUC_VERSION(12, 0) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif return absl::base_internal::invoke(std::forward(f), std::forward

(args)...); #if ABSL_INTERNAL_HAVE_MIN_GNUC_VERSION(12, 0) #pragma GCC diagnostic pop #endif } // //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// /// // A metafunction that takes a "T" corresponding to a parameter type of the // user's specified function type, and yields the parameter type to use for the // type-erased invoker. In order to prevent observable moves, this must be // either a reference or, if the type is trivial, the original parameter type // itself. Since the parameter type may be incomplete at the point that this // metafunction is used, we can only do this optimization for scalar types // rather than for any trivial type. template T ForwardImpl(std::true_type); template T&& ForwardImpl(std::false_type); // NOTE: We deliberately use an intermediate struct instead of a direct alias, // as a workaround for b/206991861 on MSVC versions < 1924. template struct ForwardedParameter { using type = decltype(( ForwardImpl)(std::integral_constant::value>())); }; template using ForwardedParameterType = typename ForwardedParameter::type; // //////////////////////////////////////////////////////////////////////////////// // A discriminator when calling the "manager" function that describes operation // type-erased operation should be invoked. // // "relocate_from_to" specifies that the manager should perform a move. // // "dispose" specifies that the manager should perform a destroy. enum class FunctionToCall : bool { relocate_from_to, dispose }; // The portion of `AnyInvocable` state that contains either a pointer to the // target object or the object itself in local storage union TypeErasedState { struct { // A pointer to the type-erased object when remotely stored void* target; // The size of the object for `RemoteManagerTrivial` std::size_t size; } remote; // Local-storage for the type-erased object when small and trivial enough alignas(kAlignment) char storage[kStorageSize]; }; // A typed accessor for the object in `TypeErasedState` storage template T& ObjectInLocalStorage(TypeErasedState* const state) { // We launder here because the storage may be reused with the same type. #if defined(__cpp_lib_launder) && __cpp_lib_launder >= 201606L return *std::launder(reinterpret_cast(&state->storage)); #elif ABSL_HAVE_BUILTIN(__builtin_launder) return *__builtin_launder(reinterpret_cast(&state->storage)); #else // When `std::launder` or equivalent are not available, we rely on undefined // behavior, which works as intended on Abseil's officially supported // platforms as of Q2 2022. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wstrict-aliasing" #endif return *reinterpret_cast(&state->storage); #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif #endif } // The type for functions issuing lifetime-related operations: move and dispose // A pointer to such a function is contained in each `AnyInvocable` instance. // NOTE: When specifying `FunctionToCall::`dispose, the same state must be // passed as both "from" and "to". using ManagerType = void(FunctionToCall /*operation*/, TypeErasedState* /*from*/, TypeErasedState* /*to*/) ABSL_INTERNAL_NOEXCEPT_SPEC(true); // The type for functions issuing the actual invocation of the object // A pointer to such a function is contained in each AnyInvocable instance. template using InvokerType = ReturnType(TypeErasedState*, ForwardedParameterType

...) ABSL_INTERNAL_NOEXCEPT_SPEC(SigIsNoexcept); // The manager that is used when AnyInvocable is empty inline void EmptyManager(FunctionToCall /*operation*/, TypeErasedState* /*from*/, TypeErasedState* /*to*/) noexcept {} // The manager that is used when a target function is in local storage and is // a trivially copyable type. inline void LocalManagerTrivial(FunctionToCall /*operation*/, TypeErasedState* const from, TypeErasedState* const to) noexcept { // This single statement without branching handles both possible operations. // // For FunctionToCall::dispose, "from" and "to" point to the same state, and // so this assignment logically would do nothing. // // Note: Correctness here relies on http://wg21.link/p0593, which has only // become standard in C++20, though implementations do not break it in // practice for earlier versions of C++. // // The correct way to do this without that paper is to first placement-new a // default-constructed T in "to->storage" prior to the memmove, but doing so // requires a different function to be created for each T that is stored // locally, which can cause unnecessary bloat and be less cache friendly. *to = *from; // Note: Because the type is trivially copyable, the destructor does not need // to be called ("trivially copyable" requires a trivial destructor). } // The manager that is used when a target function is in local storage and is // not a trivially copyable type. template void LocalManagerNontrivial(FunctionToCall operation, TypeErasedState* const from, TypeErasedState* const to) noexcept { static_assert(IsStoredLocally::value, "Local storage must only be used for supported types."); static_assert(!std::is_trivially_copyable::value, "Locally stored types must be trivially copyable."); T& from_object = (ObjectInLocalStorage)(from); switch (operation) { case FunctionToCall::relocate_from_to: // NOTE: Requires that the left-hand operand is already empty. ::new (static_cast(&to->storage)) T(std::move(from_object)); ABSL_FALLTHROUGH_INTENDED; case FunctionToCall::dispose: from_object.~T(); // Must not throw. // NOLINT return; } ABSL_UNREACHABLE(); } // The invoker that is used when a target function is in local storage // Note: QualTRef here is the target function type along with cv and reference // qualifiers that must be used when calling the function. template ReturnType LocalInvoker( TypeErasedState* const state, ForwardedParameterType

... args) noexcept(SigIsNoexcept) { using RawT = RemoveCVRef; static_assert( IsStoredLocally::value, "Target object must be in local storage in order to be invoked from it."); auto& f = (ObjectInLocalStorage)(state); return (InvokeR)(static_cast(f), static_cast>(args)...); } // The manager that is used when a target function is in remote storage and it // has a trivial destructor inline void RemoteManagerTrivial(FunctionToCall operation, TypeErasedState* const from, TypeErasedState* const to) noexcept { switch (operation) { case FunctionToCall::relocate_from_to: // NOTE: Requires that the left-hand operand is already empty. to->remote = from->remote; return; case FunctionToCall::dispose: #if defined(__cpp_sized_deallocation) ::operator delete(from->remote.target, from->remote.size); #else // __cpp_sized_deallocation ::operator delete(from->remote.target); #endif // __cpp_sized_deallocation return; } ABSL_UNREACHABLE(); } // The manager that is used when a target function is in remote storage and the // destructor of the type is not trivial template void RemoteManagerNontrivial(FunctionToCall operation, TypeErasedState* const from, TypeErasedState* const to) noexcept { static_assert(!IsStoredLocally::value, "Remote storage must only be used for types that do not " "qualify for local storage."); switch (operation) { case FunctionToCall::relocate_from_to: // NOTE: Requires that the left-hand operand is already empty. to->remote.target = from->remote.target; return; case FunctionToCall::dispose: ::delete static_cast(from->remote.target); // Must not throw. return; } ABSL_UNREACHABLE(); } // The invoker that is used when a target function is in remote storage template ReturnType RemoteInvoker( TypeErasedState* const state, ForwardedParameterType

... args) noexcept(SigIsNoexcept) { using RawT = RemoveCVRef; static_assert(!IsStoredLocally::value, "Target object must be in remote storage in order to be " "invoked from it."); auto& f = *static_cast(state->remote.target); return (InvokeR)(static_cast(f), static_cast>(args)...); } //////////////////////////////////////////////////////////////////////////////// // // A metafunction that checks if a type T is an instantiation of // absl::in_place_type_t (needed for constructor constraints of AnyInvocable). template struct IsInPlaceType : std::false_type {}; template struct IsInPlaceType> : std::true_type {}; // //////////////////////////////////////////////////////////////////////////////// // A constructor name-tag used with CoreImpl (below) to request the // conversion-constructor. QualDecayedTRef is the decayed-type of the object to // wrap, along with the cv and reference qualifiers that must be applied when // performing an invocation of the wrapped object. template struct TypedConversionConstruct {}; // A helper base class for all core operations of AnyInvocable. Most notably, // this class creates the function call operator and constraint-checkers so that // the top-level class does not have to be a series of partial specializations. // // Note: This definition exists (as opposed to being a declaration) so that if // the user of the top-level template accidentally passes a template argument // that is not a function type, they will get a static_assert in AnyInvocable's // class body rather than an error stating that Impl is not defined. template class Impl {}; // Note: This is partially-specialized later. // A std::unique_ptr deleter that deletes memory allocated via ::operator new. #if defined(__cpp_sized_deallocation) class TrivialDeleter { public: explicit TrivialDeleter(std::size_t size) : size_(size) {} void operator()(void* target) const { ::operator delete(target, size_); } private: std::size_t size_; }; #else // __cpp_sized_deallocation class TrivialDeleter { public: explicit TrivialDeleter(std::size_t) {} void operator()(void* target) const { ::operator delete(target); } }; #endif // __cpp_sized_deallocation template class CoreImpl; constexpr bool IsCompatibleConversion(void*, void*) { return false; } template constexpr bool IsCompatibleConversion(CoreImpl*, CoreImpl*) { return !NoExceptDest || NoExceptSrc; } // A helper base class for all core operations of AnyInvocable that do not // depend on the cv/ref qualifiers of the function type. template class CoreImpl { public: using result_type = ReturnType; CoreImpl() noexcept : manager_(EmptyManager), invoker_(nullptr) {} enum class TargetType { kPointer, kCompatibleAnyInvocable, kIncompatibleAnyInvocable, kOther, }; // Note: QualDecayedTRef here includes the cv-ref qualifiers associated with // the invocation of the Invocable. The unqualified type is the target object // type to be stored. template explicit CoreImpl(TypedConversionConstruct, F&& f) { using DecayedT = RemoveCVRef; constexpr TargetType kTargetType = (std::is_pointer::value || std::is_member_pointer::value) ? TargetType::kPointer : IsCompatibleAnyInvocable::value ? TargetType::kCompatibleAnyInvocable : IsAnyInvocable::value ? TargetType::kIncompatibleAnyInvocable : TargetType::kOther; // NOTE: We only use integers instead of enums as template parameters in // order to work around a bug on C++14 under MSVC 2017. // See b/236131881. Initialize(std::forward(f)); } // Note: QualTRef here includes the cv-ref qualifiers associated with the // invocation of the Invocable. The unqualified type is the target object // type to be stored. template explicit CoreImpl(absl::in_place_type_t, Args&&... args) { InitializeStorage(std::forward(args)...); } CoreImpl(CoreImpl&& other) noexcept { other.manager_(FunctionToCall::relocate_from_to, &other.state_, &state_); manager_ = other.manager_; invoker_ = other.invoker_; other.manager_ = EmptyManager; other.invoker_ = nullptr; } CoreImpl& operator=(CoreImpl&& other) noexcept { // Put the left-hand operand in an empty state. // // Note: A full reset that leaves us with an object that has its invariants // intact is necessary in order to handle self-move. This is required by // types that are used with certain operations of the standard library, such // as the default definition of std::swap when both operands target the same // object. Clear(); // Perform the actual move/destroy operation on the target function. other.manager_(FunctionToCall::relocate_from_to, &other.state_, &state_); manager_ = other.manager_; invoker_ = other.invoker_; other.manager_ = EmptyManager; other.invoker_ = nullptr; return *this; } ~CoreImpl() { manager_(FunctionToCall::dispose, &state_, &state_); } // Check whether or not the AnyInvocable is in the empty state. bool HasValue() const { return invoker_ != nullptr; } // Effects: Puts the object into its empty state. void Clear() { manager_(FunctionToCall::dispose, &state_, &state_); manager_ = EmptyManager; invoker_ = nullptr; } template = 0> void Initialize(F&& f) { // This condition handles types that decay into pointers, which includes // function references. Since function references cannot be null, GCC warns // against comparing their decayed form with nullptr. // Since this is template-heavy code, we prefer to disable these warnings // locally instead of adding yet another overload of this function. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wpragmas" #pragma GCC diagnostic ignored "-Waddress" #pragma GCC diagnostic ignored "-Wnonnull-compare" #endif if (static_cast>(f) == nullptr) { #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif manager_ = EmptyManager; invoker_ = nullptr; return; } InitializeStorage(std::forward(f)); } template = 0> void Initialize(F&& f) { // In this case we can "steal the guts" of the other AnyInvocable. f.manager_(FunctionToCall::relocate_from_to, &f.state_, &state_); manager_ = f.manager_; invoker_ = f.invoker_; f.manager_ = EmptyManager; f.invoker_ = nullptr; } template = 0> void Initialize(F&& f) { if (f.HasValue()) { InitializeStorage(std::forward(f)); } else { manager_ = EmptyManager; invoker_ = nullptr; } } template > void Initialize(F&& f) { InitializeStorage(std::forward(f)); } // Use local (inline) storage for applicable target object types. template >::value>> void InitializeStorage(Args&&... args) { using RawT = RemoveCVRef; ::new (static_cast(&state_.storage)) RawT(std::forward(args)...); invoker_ = LocalInvoker; // We can simplify our manager if we know the type is trivially copyable. InitializeLocalManager(); } // Use remote storage for target objects that cannot be stored locally. template >::value, int> = 0> void InitializeStorage(Args&&... args) { InitializeRemoteManager>(std::forward(args)...); // This is set after everything else in case an exception is thrown in an // earlier step of the initialization. invoker_ = RemoteInvoker; } template ::value>> void InitializeLocalManager() { manager_ = LocalManagerTrivial; } template ::value, int> = 0> void InitializeLocalManager() { manager_ = LocalManagerNontrivial; } template using HasTrivialRemoteStorage = std::integral_constant::value && alignof(T) <= ABSL_INTERNAL_DEFAULT_NEW_ALIGNMENT>; template ::value>> void InitializeRemoteManager(Args&&... args) { // unique_ptr is used for exception-safety in case construction throws. std::unique_ptr uninitialized_target( ::operator new(sizeof(T)), TrivialDeleter(sizeof(T))); ::new (uninitialized_target.get()) T(std::forward(args)...); state_.remote.target = uninitialized_target.release(); state_.remote.size = sizeof(T); manager_ = RemoteManagerTrivial; } template ::value, int> = 0> void InitializeRemoteManager(Args&&... args) { state_.remote.target = ::new T(std::forward(args)...); manager_ = RemoteManagerNontrivial; } ////////////////////////////////////////////////////////////////////////////// // // Type trait to determine if the template argument is an AnyInvocable whose // function type is compatible enough with ours such that we can // "move the guts" out of it when moving, rather than having to place a new // object into remote storage. template struct IsCompatibleAnyInvocable { static constexpr bool value = false; }; template struct IsCompatibleAnyInvocable> { static constexpr bool value = (IsCompatibleConversion)(static_cast< typename AnyInvocable::CoreImpl*>( nullptr), static_cast(nullptr)); }; // ////////////////////////////////////////////////////////////////////////////// TypeErasedState state_; ManagerType* manager_; InvokerType* invoker_; }; // A constructor name-tag used with Impl to request the // conversion-constructor struct ConversionConstruct {}; //////////////////////////////////////////////////////////////////////////////// // // A metafunction that is normally an identity metafunction except that when // given a std::reference_wrapper, it yields T&. This is necessary because // currently std::reference_wrapper's operator() is not conditionally noexcept, // so when checking if such an Invocable is nothrow-invocable, we must pull out // the underlying type. template struct UnwrapStdReferenceWrapperImpl { using type = T; }; template struct UnwrapStdReferenceWrapperImpl> { using type = T&; }; template using UnwrapStdReferenceWrapper = typename UnwrapStdReferenceWrapperImpl::type; // //////////////////////////////////////////////////////////////////////////////// // An alias that always yields std::true_type (used with constraints) where // substitution failures happen when forming the template arguments. template using TrueAlias = std::integral_constant*) != 0>; /*SFINAE constraints for the conversion-constructor.*/ template , AnyInvocable>::value>> using CanConvert = TrueAlias< absl::enable_if_t>::value>, absl::enable_if_t::template CallIsValid::value>, absl::enable_if_t< Impl::template CallIsNoexceptIfSigIsNoexcept::value>, absl::enable_if_t, F>::value>>; /*SFINAE constraints for the std::in_place constructors.*/ template using CanEmplace = TrueAlias< absl::enable_if_t::template CallIsValid::value>, absl::enable_if_t< Impl::template CallIsNoexceptIfSigIsNoexcept::value>, absl::enable_if_t, Args...>::value>>; /*SFINAE constraints for the conversion-assign operator.*/ template , AnyInvocable>::value>> using CanAssign = TrueAlias< absl::enable_if_t::template CallIsValid::value>, absl::enable_if_t< Impl::template CallIsNoexceptIfSigIsNoexcept::value>, absl::enable_if_t, F>::value>>; /*SFINAE constraints for the reference-wrapper conversion-assign operator.*/ template using CanAssignReferenceWrapper = TrueAlias< absl::enable_if_t< Impl::template CallIsValid>::value>, absl::enable_if_t::template CallIsNoexceptIfSigIsNoexcept< std::reference_wrapper>::value>>; //////////////////////////////////////////////////////////////////////////////// // // The constraint for checking whether or not a call meets the noexcept // callability requirements. This is a preprocessor macro because specifying it // this way as opposed to a disjunction/branch can improve the user-side error // messages and avoids an instantiation of std::is_nothrow_invocable_r in the // cases where the user did not specify a noexcept function type. // #define ABSL_INTERNAL_ANY_INVOCABLE_NOEXCEPT_CONSTRAINT(inv_quals, noex) \ ABSL_INTERNAL_ANY_INVOCABLE_NOEXCEPT_CONSTRAINT_##noex(inv_quals) // The disjunction below is because we can't rely on std::is_nothrow_invocable_r // to give the right result when ReturnType is non-moveable in toolchains that // don't treat non-moveable result types correctly. For example this was the // case in libc++ before commit c3a24882 (2022-05). #define ABSL_INTERNAL_ANY_INVOCABLE_NOEXCEPT_CONSTRAINT_true(inv_quals) \ absl::enable_if_t> inv_quals, \ P...>, \ std::conjunction< \ std::is_nothrow_invocable< \ UnwrapStdReferenceWrapper> inv_quals, P...>, \ std::is_same< \ ReturnType, \ absl::base_internal::invoke_result_t< \ UnwrapStdReferenceWrapper> inv_quals, \ P...>>>>::value> #define ABSL_INTERNAL_ANY_INVOCABLE_NOEXCEPT_CONSTRAINT_false(inv_quals) // //////////////////////////////////////////////////////////////////////////////// // A macro to generate partial specializations of Impl with the different // combinations of supported cv/reference qualifiers and noexcept specifier. // // Here, `cv` are the cv-qualifiers if any, `ref` is the ref-qualifier if any, // inv_quals is the reference type to be used when invoking the target, and // noex is "true" if the function type is noexcept, or false if it is not. // // The CallIsValid condition is more complicated than simply using // absl::base_internal::is_invocable_r because we can't rely on it to give the // right result when ReturnType is non-moveable in toolchains that don't treat // non-moveable result types correctly. For example this was the case in libc++ // before commit c3a24882 (2022-05). #define ABSL_INTERNAL_ANY_INVOCABLE_IMPL_(cv, ref, inv_quals, noex) \ template \ class Impl \ : public CoreImpl { \ public: \ /*The base class, which contains the datamembers and core operations*/ \ using Core = CoreImpl; \ \ /*SFINAE constraint to check if F is invocable with the proper signature*/ \ template \ using CallIsValid = TrueAlias inv_quals, P...>, \ std::is_same inv_quals, P...>>>::value>>; \ \ /*SFINAE constraint to check if F is nothrow-invocable when necessary*/ \ template \ using CallIsNoexceptIfSigIsNoexcept = \ TrueAlias; \ \ /*Put the AnyInvocable into an empty state.*/ \ Impl() = default; \ \ /*The implementation of a conversion-constructor from "f*/ \ /*This forwards to Core, attaching inv_quals so that the base class*/ \ /*knows how to properly type-erase the invocation.*/ \ template \ explicit Impl(ConversionConstruct, F&& f) \ : Core(TypedConversionConstruct< \ typename std::decay::type inv_quals>(), \ std::forward(f)) {} \ \ /*Forward along the in-place construction parameters.*/ \ template \ explicit Impl(absl::in_place_type_t, Args&&... args) \ : Core(absl::in_place_type inv_quals>, \ std::forward(args)...) {} \ \ /*Raises a fatal error when the AnyInvocable is invoked after a move*/ \ static ReturnType InvokedAfterMove( \ TypeErasedState*, \ ForwardedParameterType

...) noexcept(noex) { \ ABSL_HARDENING_ASSERT(false && "AnyInvocable use-after-move"); \ std::terminate(); \ } \ \ InvokerType* ExtractInvoker() cv { \ using QualifiedTestType = int cv ref; \ auto* invoker = this->invoker_; \ if (!std::is_const::value && \ std::is_rvalue_reference::value) { \ ABSL_ASSERT([this]() { \ /* We checked that this isn't const above, so const_cast is safe */ \ const_cast(this)->invoker_ = InvokedAfterMove; \ return this->HasValue(); \ }()); \ } \ return invoker; \ } \ \ /*The actual invocation operation with the proper signature*/ \ ReturnType operator()(P... args) cv ref noexcept(noex) { \ assert(this->invoker_ != nullptr); \ return this->ExtractInvoker()( \ const_cast(&this->state_), \ static_cast>(args)...); \ } \ } // Define the `noexcept(true)` specialization only for C++17 and beyond, when // `noexcept` is part of the type system. #if ABSL_INTERNAL_CPLUSPLUS_LANG >= 201703L // A convenience macro that defines specializations for the noexcept(true) and // noexcept(false) forms, given the other properties. #define ABSL_INTERNAL_ANY_INVOCABLE_IMPL(cv, ref, inv_quals) \ ABSL_INTERNAL_ANY_INVOCABLE_IMPL_(cv, ref, inv_quals, false); \ ABSL_INTERNAL_ANY_INVOCABLE_IMPL_(cv, ref, inv_quals, true) #else #define ABSL_INTERNAL_ANY_INVOCABLE_IMPL(cv, ref, inv_quals) \ ABSL_INTERNAL_ANY_INVOCABLE_IMPL_(cv, ref, inv_quals, false) #endif // Non-ref-qualified partial specializations ABSL_INTERNAL_ANY_INVOCABLE_IMPL(, , &); ABSL_INTERNAL_ANY_INVOCABLE_IMPL(const, , const&); // Lvalue-ref-qualified partial specializations ABSL_INTERNAL_ANY_INVOCABLE_IMPL(, &, &); ABSL_INTERNAL_ANY_INVOCABLE_IMPL(const, &, const&); // Rvalue-ref-qualified partial specializations ABSL_INTERNAL_ANY_INVOCABLE_IMPL(, &&, &&); ABSL_INTERNAL_ANY_INVOCABLE_IMPL(const, &&, const&&); // Undef the detail-only macros. #undef ABSL_INTERNAL_ANY_INVOCABLE_IMPL #undef ABSL_INTERNAL_ANY_INVOCABLE_IMPL_ #undef ABSL_INTERNAL_ANY_INVOCABLE_NOEXCEPT_CONSTRAINT_false #undef ABSL_INTERNAL_ANY_INVOCABLE_NOEXCEPT_CONSTRAINT_true #undef ABSL_INTERNAL_ANY_INVOCABLE_NOEXCEPT_CONSTRAINT #undef ABSL_INTERNAL_NOEXCEPT_SPEC } // namespace internal_any_invocable ABSL_NAMESPACE_END } // namespace absl #endif // ABSL_FUNCTIONAL_INTERNAL_ANY_INVOCABLE_H_