rtc_base/untyped_function.h - src - Git at Google

 /*
  *  Copyright 2020 The WebRTC Project Authors. All rights reserved.
  *
  *  Use of this source code is governed by a BSD-style license
  *  that can be found in the LICENSE file in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */

 #ifndef RTC_BASE_UNTYPED_FUNCTION_H_
 #define RTC_BASE_UNTYPED_FUNCTION_H_

 #include <cstddef>
 #include <cstring>
 #include <memory>
 #include <type_traits>
 #include <utility>

 #include "rtc_base/system/assume.h"

 namespace webrtc {
 namespace webrtc_function_impl {

 using FunVoid = void();

 // Inline storage size is this many machine words.
 enum : size_t { kInlineStorageWords = 4 };

 union VoidUnion {
   void* void_ptr;
   FunVoid* fun_ptr;
   typename std::aligned_storage<kInlineStorageWords * sizeof(uintptr_t)>::type
       inline_storage;
 };

 // Returns the number of elements of the `inline_storage` array required to
 // store an object of type T.
 template <typename T>
 constexpr size_t InlineStorageSize() {
   // sizeof(T) / sizeof(uintptr_t), but rounded up.
   return (sizeof(T) + sizeof(uintptr_t) - 1) / sizeof(uintptr_t);
 }

 template <typename T>
 struct CallHelpers;
 template <typename RetT, typename... ArgT>
 struct CallHelpers<RetT(ArgT...)> {
   // Return type of the three helpers below.
   using return_type = RetT;
   // Complete function type of the three helpers below.
   using function_type = RetT(VoidUnion*, ArgT...);
   // Helper for calling the `void_ptr` case of VoidUnion.
   template <typename F>
   static RetT CallVoidPtr(VoidUnion* vu, ArgT... args) {
     return (*static_cast<F*>(vu->void_ptr))(std::forward<ArgT>(args)...);
   }
   // Helper for calling the `fun_ptr` case of VoidUnion.
   static RetT CallFunPtr(VoidUnion* vu, ArgT... args) {
     return (reinterpret_cast<RetT (*)(ArgT...)>(vu->fun_ptr))(
         std::forward<ArgT>(args)...);
   }
   // Helper for calling the `inline_storage` case of VoidUnion.
   template <typename F>
   static RetT CallInlineStorage(VoidUnion* vu, ArgT... args) {
     return (*reinterpret_cast<F*>(&vu->inline_storage))(
         std::forward<ArgT>(args)...);
   }
 };

 }  // namespace webrtc_function_impl

 // A class that holds (and owns) any callable. The same function call signature
 // must be provided when constructing and calling the object.
 //
 // The point of not having the call signature as a class template parameter is
 // to have one single concrete type for all signatures; this reduces binary
 // size.
 class UntypedFunction final {
  public:
   // Callables of at most this size can be stored inline, if they are trivial.
   // (Useful in tests and benchmarks; avoid using this in production code.)
   enum : size_t {
     kInlineStorageSize = sizeof(webrtc_function_impl::VoidUnion::inline_storage)
   };
   static_assert(kInlineStorageSize ==
                     webrtc_function_impl::kInlineStorageWords *
                         sizeof(uintptr_t),
                 "");

   // The *UntypedFunctionArgs structs are used to transfer arguments from
   // PrepareArgs() to Create(). They are trivial, but may own heap allocations,
   // so make sure to pass them to Create() exactly once!
   //
   // The point of doing Create(PrepareArgs(foo)) instead of just Create(foo) is
   // to separate the code that has to be inlined (PrepareArgs) from the code
   // that can be noninlined (Create); the *UntypedFunctionArgs types are
   // designed to efficiently carry the required information from one to the
   // other.
   template <size_t N>
   struct TrivialUntypedFunctionArgs {
     static_assert(N >= 1, "");
     static_assert(N <= webrtc_function_impl::kInlineStorageWords, "");
     // We use an uintptr_t array here instead of std::aligned_storage, because
     // the former can be efficiently passed in registers when using
     // TrivialUntypedFunctionArgs as a function argument. (We can't do the same
     // in VoidUnion, because std::aligned_storage but not uintptr_t can be
     // legally reinterpret_casted to arbitrary types.
     // TrivialUntypedFunctionArgs, on the other hand, only needs to handle
     // placement new and memcpy.)
     alignas(std::max_align_t) uintptr_t inline_storage[N];
     webrtc_function_impl::FunVoid* call;
   };
   struct NontrivialUntypedFunctionArgs {
     void* void_ptr;
     webrtc_function_impl::FunVoid* call;
     void (*del)(webrtc_function_impl::VoidUnion*);
   };
   struct FunctionPointerUntypedFunctionArgs {
     webrtc_function_impl::FunVoid* fun_ptr;
     webrtc_function_impl::FunVoid* call;
   };

   // Create function for lambdas and other callables that are trivial and small;
   // it accepts every type of argument except those noted in its enable_if call.
   template <
       typename Signature,
       typename F,
       typename F_deref = typename std::remove_reference<F>::type,
       typename std::enable_if<
           // Not for function pointers; we have another overload for that below.
           !std::is_function<
               typename std::remove_pointer<F_deref>::type>::value &&

           // Not for nullptr; we have a constructor for that below.
           !std::is_same<std::nullptr_t,
                         typename std::remove_cv<F>::type>::value &&

           // Not for UntypedFunction objects; use move construction or
           // assignment.
           !std::is_same<UntypedFunction,
                         typename std::remove_cv<F_deref>::type>::value &&

           // Only for trivial callables that will fit in inline storage.
           std::is_trivially_move_constructible<F_deref>::value &&
           std::is_trivially_destructible<F_deref>::value &&
           sizeof(F_deref) <= kInlineStorageSize>::type* = nullptr,
       size_t InlineSize = webrtc_function_impl::InlineStorageSize<F_deref>()>
   static TrivialUntypedFunctionArgs<InlineSize> PrepareArgs(F&& f) {
     // The callable is trivial and small enough, so we just store its bytes
     // in the inline storage.
     TrivialUntypedFunctionArgs<InlineSize> args;
     new (&args.inline_storage) F_deref(std::forward<F>(f));
     args.call = reinterpret_cast<webrtc_function_impl::FunVoid*>(
         webrtc_function_impl::CallHelpers<
             Signature>::template CallInlineStorage<F_deref>);
     return args;
   }
   template <size_t InlineSize>
   static UntypedFunction Create(TrivialUntypedFunctionArgs<InlineSize> args) {
     webrtc_function_impl::VoidUnion vu;
     std::memcpy(&vu.inline_storage, args.inline_storage,
                 sizeof(args.inline_storage));
     return UntypedFunction(vu, args.call, nullptr);
   }

   // Create function for lambdas and other callables that are nontrivial or
   // large; it accepts every type of argument except those noted in its
   // enable_if call.
   template <typename Signature,
             typename F,
             typename F_deref = typename std::remove_reference<F>::type,
             typename std::enable_if<
                 // Not for function pointers; we have another overload for that
                 // below.
                 !std::is_function<
                     typename std::remove_pointer<F_deref>::type>::value &&

                 // Not for nullptr; we have a constructor for that below.
                 !std::is_same<std::nullptr_t,
                               typename std::remove_cv<F>::type>::value &&

                 // Not for UntypedFunction objects; use move construction or
                 // assignment.
                 !std::is_same<UntypedFunction,
                               typename std::remove_cv<F_deref>::type>::value &&

                 // Only for nontrivial callables, or callables that won't fit in
                 // inline storage.
                 !(std::is_trivially_move_constructible<F_deref>::value &&
                   std::is_trivially_destructible<F_deref>::value &&
                   sizeof(F_deref) <= kInlineStorageSize)>::type* = nullptr>
   static NontrivialUntypedFunctionArgs PrepareArgs(F&& f) {
     // The callable is either nontrivial or too large, so we can't keep it
     // in the inline storage; use the heap instead.
     NontrivialUntypedFunctionArgs args;
     args.void_ptr = new F_deref(std::forward<F>(f));
     args.call = reinterpret_cast<webrtc_function_impl::FunVoid*>(
         webrtc_function_impl::CallHelpers<Signature>::template CallVoidPtr<
             F_deref>);
     args.del = static_cast<void (*)(webrtc_function_impl::VoidUnion*)>(
         [](webrtc_function_impl::VoidUnion* vu) {
           // Assuming that this pointer isn't null allows the
           // compiler to eliminate a null check in the (inlined)
           // delete operation.
           RTC_ASSUME(vu->void_ptr != nullptr);
           delete reinterpret_cast<F_deref*>(vu->void_ptr);
         });
     return args;
   }
   static UntypedFunction Create(NontrivialUntypedFunctionArgs args) {
     webrtc_function_impl::VoidUnion vu;
     vu.void_ptr = args.void_ptr;
     return UntypedFunction(vu, args.call, args.del);
   }

   // Create function that accepts function pointers. If the argument is null,
   // the result is an empty UntypedFunction.
   template <typename Signature>
   static FunctionPointerUntypedFunctionArgs PrepareArgs(Signature* f) {
     FunctionPointerUntypedFunctionArgs args;
     args.fun_ptr = reinterpret_cast<webrtc_function_impl::FunVoid*>(f);
     args.call = reinterpret_cast<webrtc_function_impl::FunVoid*>(
         webrtc_function_impl::CallHelpers<Signature>::CallFunPtr);
     return args;
   }
   static UntypedFunction Create(FunctionPointerUntypedFunctionArgs args) {
     webrtc_function_impl::VoidUnion vu;
     vu.fun_ptr = args.fun_ptr;
     return UntypedFunction(vu, args.fun_ptr == nullptr ? nullptr : args.call,
                            nullptr);
   }

   // Prepares arguments and creates an UntypedFunction in one go.
   template <typename Signature, typename F>
   static UntypedFunction Create(F&& f) {
     return Create(PrepareArgs<Signature>(std::forward<F>(f)));
   }

   // Default constructor. Creates an empty UntypedFunction.
   UntypedFunction() : call_(nullptr), delete_(nullptr) {}

   // Nullptr constructor and assignment. Creates an empty UntypedFunction.
   UntypedFunction(std::nullptr_t)  // NOLINT(runtime/explicit)
       : call_(nullptr), delete_(nullptr) {}
   UntypedFunction& operator=(std::nullptr_t) {
     call_ = nullptr;
     if (delete_) {
       delete_(&f_);
       delete_ = nullptr;
     }
     return *this;
   }

   // Not copyable.
   UntypedFunction(const UntypedFunction&) = delete;
   UntypedFunction& operator=(const UntypedFunction&) = delete;

   // Move construction and assignment.
   UntypedFunction(UntypedFunction&& other)
       : f_(other.f_), call_(other.call_), delete_(other.delete_) {
     other.delete_ = nullptr;
   }
   UntypedFunction& operator=(UntypedFunction&& other) {
     if (delete_) {
       delete_(&f_);
     }
     f_ = other.f_;
     call_ = other.call_;
     delete_ = other.delete_;
     other.delete_ = nullptr;
     return *this;
   }

   ~UntypedFunction() {
     if (delete_) {
       delete_(&f_);
     }
   }

   friend void swap(UntypedFunction& a, UntypedFunction& b) {
     using std::swap;
     swap(a.f_, b.f_);
     swap(a.call_, b.call_);
     swap(a.delete_, b.delete_);
   }

   // Returns true if we have a function, false if we don't (i.e., we're null).
   explicit operator bool() const { return call_ != nullptr; }

   template <typename Signature, typename... ArgT>
   typename webrtc_function_impl::CallHelpers<Signature>::return_type Call(
       ArgT&&... args) {
     return reinterpret_cast<
         typename webrtc_function_impl::CallHelpers<Signature>::function_type*>(
         call_)(&f_, std::forward<ArgT>(args)...);
   }

   // Returns true iff we don't need to call a destructor. This is guaranteed
   // to hold for a moved-from object.
   bool IsTriviallyDestructible() { return delete_ == nullptr; }

  private:
   UntypedFunction(webrtc_function_impl::VoidUnion f,
                   webrtc_function_impl::FunVoid* call,
                   void (*del)(webrtc_function_impl::VoidUnion*))
       : f_(f), call_(call), delete_(del) {}

   // The callable thing, or a pointer to it.
   webrtc_function_impl::VoidUnion f_;

   // Pointer to a dispatch function that knows the type of the callable thing
   // that's stored in f_, and how to call it. An UntypedFunction object is empty
   // (null) iff call_ is null.
   webrtc_function_impl::FunVoid* call_;

   // Pointer to a function that knows how to delete the callable thing that's
   // stored in f_. Null if `f_` is trivially deletable.
   void (*delete_)(webrtc_function_impl::VoidUnion*);
 };

 }  // namespace webrtc

 #endif  // RTC_BASE_UNTYPED_FUNCTION_H_
	/*
	* Copyright 2020 The WebRTC Project Authors. All rights reserved.
	*
	* Use of this source code is governed by a BSD-style license
	* that can be found in the LICENSE file in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/

	#ifndef RTC_BASE_UNTYPED_FUNCTION_H_
	#define RTC_BASE_UNTYPED_FUNCTION_H_

	#include <cstddef>
	#include <cstring>
	#include <memory>
	#include <type_traits>
	#include <utility>

	#include "rtc_base/system/assume.h"

	namespace webrtc {
	namespace webrtc_function_impl {

	using FunVoid = void();

	// Inline storage size is this many machine words.
	enum : size_t { kInlineStorageWords = 4 };

	union VoidUnion {
	void* void_ptr;
	FunVoid* fun_ptr;
	typename std::aligned_storage<kInlineStorageWords * sizeof(uintptr_t)>::type
	inline_storage;
	};

	// Returns the number of elements of the `inline_storage` array required to
	// store an object of type T.
	template <typename T>
	constexpr size_t InlineStorageSize() {
	// sizeof(T) / sizeof(uintptr_t), but rounded up.
	return (sizeof(T) + sizeof(uintptr_t) - 1) / sizeof(uintptr_t);
	}

	template <typename T>
	struct CallHelpers;
	template <typename RetT, typename... ArgT>
	struct CallHelpers<RetT(ArgT...)> {
	// Return type of the three helpers below.
	using return_type = RetT;
	// Complete function type of the three helpers below.
	using function_type = RetT(VoidUnion*, ArgT...);
	// Helper for calling the `void_ptr` case of VoidUnion.
	template <typename F>
	static RetT CallVoidPtr(VoidUnion* vu, ArgT... args) {
	return (static_cast<F>(vu->void_ptr))(std::forward<ArgT>(args)...);
	}
	// Helper for calling the `fun_ptr` case of VoidUnion.
	static RetT CallFunPtr(VoidUnion* vu, ArgT... args) {
	return (reinterpret_cast<RetT (*)(ArgT...)>(vu->fun_ptr))(
	std::forward<ArgT>(args)...);
	}
	// Helper for calling the `inline_storage` case of VoidUnion.
	template <typename F>
	static RetT CallInlineStorage(VoidUnion* vu, ArgT... args) {
	return (reinterpret_cast<F>(&vu->inline_storage))(
	std::forward<ArgT>(args)...);
	}
	};

	} // namespace webrtc_function_impl

	// A class that holds (and owns) any callable. The same function call signature
	// must be provided when constructing and calling the object.
	//
	// The point of not having the call signature as a class template parameter is
	// to have one single concrete type for all signatures; this reduces binary
	// size.
	class UntypedFunction final {
	public:
	// Callables of at most this size can be stored inline, if they are trivial.
	// (Useful in tests and benchmarks; avoid using this in production code.)
	enum : size_t {
	kInlineStorageSize = sizeof(webrtc_function_impl::VoidUnion::inline_storage)
	};
	static_assert(kInlineStorageSize ==
	webrtc_function_impl::kInlineStorageWords *
	sizeof(uintptr_t),
	"");

	// The *UntypedFunctionArgs structs are used to transfer arguments from
	// PrepareArgs() to Create(). They are trivial, but may own heap allocations,
	// so make sure to pass them to Create() exactly once!
	//
	// The point of doing Create(PrepareArgs(foo)) instead of just Create(foo) is
	// to separate the code that has to be inlined (PrepareArgs) from the code
	// that can be noninlined (Create); the *UntypedFunctionArgs types are
	// designed to efficiently carry the required information from one to the
	// other.
	template <size_t N>
	struct TrivialUntypedFunctionArgs {
	static_assert(N >= 1, "");
	static_assert(N <= webrtc_function_impl::kInlineStorageWords, "");
	// We use an uintptr_t array here instead of std::aligned_storage, because
	// the former can be efficiently passed in registers when using
	// TrivialUntypedFunctionArgs as a function argument. (We can't do the same
	// in VoidUnion, because std::aligned_storage but not uintptr_t can be
	// legally reinterpret_casted to arbitrary types.
	// TrivialUntypedFunctionArgs, on the other hand, only needs to handle
	// placement new and memcpy.)
	alignas(std::max_align_t) uintptr_t inline_storage[N];
	webrtc_function_impl::FunVoid* call;
	};
	struct NontrivialUntypedFunctionArgs {
	void* void_ptr;
	webrtc_function_impl::FunVoid* call;
	void (del)(webrtc_function_impl::VoidUnion);
	};
	struct FunctionPointerUntypedFunctionArgs {
	webrtc_function_impl::FunVoid* fun_ptr;
	webrtc_function_impl::FunVoid* call;
	};

	// Create function for lambdas and other callables that are trivial and small;
	// it accepts every type of argument except those noted in its enable_if call.
	template <
	typename Signature,
	typename F,
	typename F_deref = typename std::remove_reference<F>::type,
	typename std::enable_if<
	// Not for function pointers; we have another overload for that below.
	!std::is_function<
	typename std::remove_pointer<F_deref>::type>::value &&

	// Not for nullptr; we have a constructor for that below.
	!std::is_same<std::nullptr_t,
	typename std::remove_cv<F>::type>::value &&

	// Not for UntypedFunction objects; use move construction or
	// assignment.
	!std::is_same<UntypedFunction,
	typename std::remove_cv<F_deref>::type>::value &&

	// Only for trivial callables that will fit in inline storage.
	std::is_trivially_move_constructible<F_deref>::value &&
	std::is_trivially_destructible<F_deref>::value &&
	sizeof(F_deref) <= kInlineStorageSize>::type* = nullptr,
	size_t InlineSize = webrtc_function_impl::InlineStorageSize<F_deref>()>
	static TrivialUntypedFunctionArgs<InlineSize> PrepareArgs(F&& f) {
	// The callable is trivial and small enough, so we just store its bytes
	// in the inline storage.
	TrivialUntypedFunctionArgs<InlineSize> args;
	new (&args.inline_storage) F_deref(std::forward<F>(f));
	args.call = reinterpret_cast<webrtc_function_impl::FunVoid*>(
	webrtc_function_impl::CallHelpers<
	Signature>::template CallInlineStorage<F_deref>);
	return args;
	}
	template <size_t InlineSize>
	static UntypedFunction Create(TrivialUntypedFunctionArgs<InlineSize> args) {
	webrtc_function_impl::VoidUnion vu;
	std::memcpy(&vu.inline_storage, args.inline_storage,
	sizeof(args.inline_storage));
	return UntypedFunction(vu, args.call, nullptr);
	}

	// Create function for lambdas and other callables that are nontrivial or
	// large; it accepts every type of argument except those noted in its
	// enable_if call.
	template <typename Signature,
	typename F,
	typename F_deref = typename std::remove_reference<F>::type,
	typename std::enable_if<
	// Not for function pointers; we have another overload for that
	// below.
	!std::is_function<
	typename std::remove_pointer<F_deref>::type>::value &&

	// Not for nullptr; we have a constructor for that below.
	!std::is_same<std::nullptr_t,
	typename std::remove_cv<F>::type>::value &&

	// Not for UntypedFunction objects; use move construction or
	// assignment.
	!std::is_same<UntypedFunction,
	typename std::remove_cv<F_deref>::type>::value &&

	// Only for nontrivial callables, or callables that won't fit in
	// inline storage.
	!(std::is_trivially_move_constructible<F_deref>::value &&
	std::is_trivially_destructible<F_deref>::value &&
	sizeof(F_deref) <= kInlineStorageSize)>::type* = nullptr>
	static NontrivialUntypedFunctionArgs PrepareArgs(F&& f) {
	// The callable is either nontrivial or too large, so we can't keep it
	// in the inline storage; use the heap instead.
	NontrivialUntypedFunctionArgs args;
	args.void_ptr = new F_deref(std::forward<F>(f));
	args.call = reinterpret_cast<webrtc_function_impl::FunVoid*>(
	webrtc_function_impl::CallHelpers<Signature>::template CallVoidPtr<
	F_deref>);
	args.del = static_cast<void ()(webrtc_function_impl::VoidUnion)>(
	[](webrtc_function_impl::VoidUnion* vu) {
	// Assuming that this pointer isn't null allows the
	// compiler to eliminate a null check in the (inlined)
	// delete operation.
	RTC_ASSUME(vu->void_ptr != nullptr);
	delete reinterpret_cast<F_deref*>(vu->void_ptr);
	});
	return args;
	}
	static UntypedFunction Create(NontrivialUntypedFunctionArgs args) {
	webrtc_function_impl::VoidUnion vu;
	vu.void_ptr = args.void_ptr;
	return UntypedFunction(vu, args.call, args.del);
	}

	// Create function that accepts function pointers. If the argument is null,
	// the result is an empty UntypedFunction.
	template <typename Signature>
	static FunctionPointerUntypedFunctionArgs PrepareArgs(Signature* f) {
	FunctionPointerUntypedFunctionArgs args;
	args.fun_ptr = reinterpret_cast<webrtc_function_impl::FunVoid*>(f);
	args.call = reinterpret_cast<webrtc_function_impl::FunVoid*>(
	webrtc_function_impl::CallHelpers<Signature>::CallFunPtr);
	return args;
	}
	static UntypedFunction Create(FunctionPointerUntypedFunctionArgs args) {
	webrtc_function_impl::VoidUnion vu;
	vu.fun_ptr = args.fun_ptr;
	return UntypedFunction(vu, args.fun_ptr == nullptr ? nullptr : args.call,
	nullptr);
	}

	// Prepares arguments and creates an UntypedFunction in one go.
	template <typename Signature, typename F>
	static UntypedFunction Create(F&& f) {
	return Create(PrepareArgs<Signature>(std::forward<F>(f)));
	}

	// Default constructor. Creates an empty UntypedFunction.
	UntypedFunction() : call_(nullptr), delete_(nullptr) {}

	// Nullptr constructor and assignment. Creates an empty UntypedFunction.
	UntypedFunction(std::nullptr_t) // NOLINT(runtime/explicit)
	: call_(nullptr), delete_(nullptr) {}
	UntypedFunction& operator=(std::nullptr_t) {
	call_ = nullptr;
	if (delete_) {
	delete_(&f_);
	delete_ = nullptr;
	}
	return *this;
	}

	// Not copyable.
	UntypedFunction(const UntypedFunction&) = delete;
	UntypedFunction& operator=(const UntypedFunction&) = delete;

	// Move construction and assignment.
	UntypedFunction(UntypedFunction&& other)
	: f_(other.f_), call_(other.call_), delete_(other.delete_) {
	other.delete_ = nullptr;
	}
	UntypedFunction& operator=(UntypedFunction&& other) {
	if (delete_) {
	delete_(&f_);
	}
	f_ = other.f_;
	call_ = other.call_;
	delete_ = other.delete_;
	other.delete_ = nullptr;
	return *this;
	}

	~UntypedFunction() {
	if (delete_) {
	delete_(&f_);
	}
	}

	friend void swap(UntypedFunction& a, UntypedFunction& b) {
	using std::swap;
	swap(a.f_, b.f_);
	swap(a.call_, b.call_);
	swap(a.delete_, b.delete_);
	}

	// Returns true if we have a function, false if we don't (i.e., we're null).
	explicit operator bool() const { return call_ != nullptr; }

	template <typename Signature, typename... ArgT>
	typename webrtc_function_impl::CallHelpers<Signature>::return_type Call(
	ArgT&&... args) {
	return reinterpret_cast<
	typename webrtc_function_impl::CallHelpers<Signature>::function_type*>(
	call_)(&f_, std::forward<ArgT>(args)...);
	}

	// Returns true iff we don't need to call a destructor. This is guaranteed
	// to hold for a moved-from object.
	bool IsTriviallyDestructible() { return delete_ == nullptr; }

	private:
	UntypedFunction(webrtc_function_impl::VoidUnion f,
	webrtc_function_impl::FunVoid* call,
	void (del)(webrtc_function_impl::VoidUnion))
	: f_(f), call_(call), delete_(del) {}

	// The callable thing, or a pointer to it.
	webrtc_function_impl::VoidUnion f_;

	// Pointer to a dispatch function that knows the type of the callable thing
	// that's stored in f_, and how to call it. An UntypedFunction object is empty
	// (null) iff call_ is null.
	webrtc_function_impl::FunVoid* call_;

	// Pointer to a function that knows how to delete the callable thing that's
	// stored in f_. Null if `f_` is trivially deletable.
	void (delete_)(webrtc_function_impl::VoidUnion);
	};

	} // namespace webrtc

	#endif // RTC_BASE_UNTYPED_FUNCTION_H_