runtime/bin/eventhandler_win.h - sdk.git - Git at Google

 // Copyright (c) 2012, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.

 #ifndef BIN_EVENTHANDLER_WIN_H_
 #define BIN_EVENTHANDLER_WIN_H_

 #if !defined(BIN_EVENTHANDLER_H_)
 #error Do not include eventhandler_win.h directly; use eventhandler.h instead.
 #endif

 #include <winsock2.h>
 #include <mswsock.h>

 #include "bin/builtin.h"


 namespace dart {
 namespace bin {

 // Forward declarations.
 class EventHandlerImplementation;
 class Handle;
 class FileHandle;
 class SocketHandle;
 class ClientSocket;
 class ListenSocket;


 struct InterruptMessage {
   intptr_t id;
   Dart_Port dart_port;
   int64_t data;
 };


 // An IOBuffer encapsulates the OVERLAPPED structure and the
 // associated data buffer. For accept it also contains the pre-created
 // socket for the client.
 class IOBuffer {
  public:
   enum Operation { kAccept, kRead, kWrite, kDisconnect };

   static IOBuffer* AllocateAcceptBuffer(int buffer_size);
   static IOBuffer* AllocateReadBuffer(int buffer_size);
   static IOBuffer* AllocateWriteBuffer(int buffer_size);
   static IOBuffer* AllocateDisconnectBuffer();
   static void DisposeBuffer(IOBuffer* buffer);

   // Find the IO buffer from the OVERLAPPED address.
   static IOBuffer* GetFromOverlapped(OVERLAPPED* overlapped);

   // Read data from a buffer which has been received. It will read up
   // to num_bytes bytes of data returning the actual number of bytes
   // read. This will update the index of the next byte in the buffer
   // so calling Read several times will keep returning new data from
   // the buffer until all data have been read.
   int Read(void* buffer, int num_bytes);

   // Write data to a buffer before sending it. Returns the number of bytes
   // actually written to the buffer. Calls to Write will always write to
   // the buffer from the begining.
   int Write(const void* buffer, int num_bytes);

   // Check the amount of data in a read buffer which has not been read yet.
   int GetRemainingLength();
   bool IsEmpty() { return GetRemainingLength() == 0; }

   Operation operation() { return operation_; }
   SOCKET client() { return client_; }
   char* GetBufferStart() { return reinterpret_cast<char*>(&buffer_data_); }
   int GetBufferSize() { return buflen_; }

   // Returns the address of the OVERLAPPED structure with all fields
   // initialized to zero.
   OVERLAPPED* GetCleanOverlapped() {
     memset(&overlapped_, 0, sizeof(overlapped_));
     return &overlapped_;
   }

   // Returns a WASBUF structure initialized with the data in this IO buffer.
   WSABUF* GetWASBUF() {
     wbuf_.buf = GetBufferStart();
     wbuf_.len = GetBufferSize();
     return &wbuf_;
   };

   void set_data_length(int data_length) { data_length_ = data_length; }

  private:
   IOBuffer(int buffer_size, Operation operation)
       : operation_(operation), buflen_(buffer_size) {
     memset(GetBufferStart(), 0, GetBufferSize());
     index_ = 0;
     data_length_ = 0;
     if (operation_ == kAccept) {
       client_ = socket(AF_INET, SOCK_STREAM, IPPROTO_TCP);
     }
   }

   void* operator new(size_t size, int buffer_size) {
     return malloc(size + buffer_size);
   }

   void operator delete(void* buffer) {
     free(buffer);
   }

   static IOBuffer* AllocateBuffer(int buffer_size, Operation operation);

   OVERLAPPED overlapped_;  // OVERLAPPED structure for overlapped IO.
   SOCKET client_;  // Used for AcceptEx client socket.
   int buflen_;  // Length of the buffer.
   Operation operation_;  // Type of operation issued.

   int index_;  // Index for next read from read buffer.
   int data_length_;  // Length of the actual data in the buffer.

   WSABUF wbuf_;  // Structure for passing buffer to WSA functions.

   // Buffer for recv/send/AcceptEx. This must be at the end of the
   // object as the object is allocated larger than it's definition
   // indicate to extend this array.
   uint8_t buffer_data_[1];
 };


 // Abstract super class for holding information on listen and connected
 // sockets.
 class Handle {
  public:
   enum Type { kFile, kClientSocket, kListenSocket };

   class ScopedLock {
    public:
     explicit ScopedLock(Handle* handle)
         : handle_(handle) {
       handle_->Lock();
     }
     ~ScopedLock() {
       handle_->Unlock();
     }

    private:
     Handle* handle_;
   };

   virtual ~Handle();

   // Socket interface exposing normal socket operations.
   int Available();
   int Read(void* buffer, int num_bytes);
   int Write(const void* buffer, int num_bytes);

   // Internal interface used by the event handler.
   virtual bool IssueRead();
   virtual bool IssueWrite();
   bool HasPendingRead();
   bool HasPendingWrite();
   void ReadComplete(IOBuffer* buffer);
   void WriteComplete(IOBuffer* buffer);

   bool IsClosing() { return (flags_ & (1 << kClosing)) != 0; }
   bool IsClosedRead() { return (flags_ & (1 << kCloseRead)) != 0; }
   bool IsClosedWrite() { return (flags_ & (1 << kCloseWrite)) != 0; }
   bool IsError() { return (flags_ & (1 << kError)) != 0; }
   void MarkClosing() { flags_ |= (1 << kClosing); }
   void MarkClosedRead() { flags_ |= (1 << kCloseRead); }
   void MarkClosedWrite() { flags_ |= (1 << kCloseWrite); }
   void MarkError() { flags_ |= (1 << kError); }

   virtual void EnsureInitialized(
     EventHandlerImplementation* event_handler) = 0;

   HANDLE handle() { return handle_; }
   Dart_Port port() { return port_; }
   EventHandlerImplementation* event_handler() { return event_handler_; }

   void Lock();
   void Unlock();

   bool CreateCompletionPort(HANDLE completion_port);

   void Close();
   virtual void DoClose();
   virtual bool IsClosed() = 0;

   void SetPortAndMask(Dart_Port port, intptr_t mask) {
     port_ = port;
     mask_ = mask;
   }
   Type type() { return type_; }
   bool is_file() { return type_ == kFile; }
   bool is_socket() { return type_ == kListenSocket || type_ == kClientSocket; }
   bool is_listen_socket() { return type_ == kListenSocket; }
   bool is_client_socket() { return type_ == kClientSocket; }
   void set_mask(intptr_t mask) { mask_ = mask; }
   intptr_t mask() { return mask_; }

   void MarkDoesNotSupportOverlappedIO() {
     flags_ |= (1 << kDoesNotSupportOverlappedIO);
   }
   bool SupportsOverlappedIO() {
     return (flags_ & (1 << kDoesNotSupportOverlappedIO)) == 0;
   }

   void ReadSyncCompleteAsync();

   DWORD last_error() { return last_error_; }
   void set_last_error(DWORD last_error) { last_error_ = last_error; }

  protected:
   enum Flags {
     kClosing = 0,
     kCloseRead = 1,
     kCloseWrite = 2,
     kDoesNotSupportOverlappedIO = 3,
     kError = 4
   };

   explicit Handle(HANDLE handle);
   Handle(HANDLE handle, Dart_Port port);

   virtual void HandleIssueError();

   Type type_;
   HANDLE handle_;
   Dart_Port port_;  // Dart port to communicate events for this socket.
   intptr_t mask_;  // Mask of events to report through the port.
   HANDLE completion_port_;
   EventHandlerImplementation* event_handler_;

   IOBuffer* data_ready_;  // IO buffer for data ready to be read.
   IOBuffer* pending_read_;  // IO buffer for pending read.
   IOBuffer* pending_write_;  // IO buffer for pending write

   DWORD last_error_;

  private:
   int flags_;
   CRITICAL_SECTION cs_;  // Critical section protecting this object.
 };


 class FileHandle : public Handle {
  public:
   explicit FileHandle(HANDLE handle)
       : Handle(reinterpret_cast<HANDLE>(handle)) { type_ = kFile; }
   FileHandle(HANDLE handle, Dart_Port port)
       : Handle(reinterpret_cast<HANDLE>(handle), port) { type_ = kFile; }

   virtual void EnsureInitialized(EventHandlerImplementation* event_handler);
   virtual bool IsClosed();
 };


 class SocketHandle : public Handle {
  public:
   SOCKET socket() { return reinterpret_cast<SOCKET>(handle_); }

  protected:
   explicit SocketHandle(SOCKET s) : Handle(reinterpret_cast<HANDLE>(s)) {}
   SocketHandle(SOCKET s, Dart_Port port)
       : Handle(reinterpret_cast<HANDLE>(s), port) {}

   virtual void HandleIssueError();
 };


 // Information on listen sockets.
 class ListenSocket : public SocketHandle {
  public:
   explicit ListenSocket(SOCKET s) : SocketHandle(s),
                                     AcceptEx_(NULL),
                                     pending_accept_count_(0),
                                     accepted_head_(NULL),
                                     accepted_tail_(NULL) {
     type_ = kListenSocket;
   }
   virtual ~ListenSocket() {
     ASSERT(!HasPendingAccept());
     ASSERT(accepted_head_ == NULL);
     ASSERT(accepted_tail_ == NULL);
   };

   // Socket interface exposing normal socket operations.
   ClientSocket* Accept();
   bool CanAccept();

   // Internal interface used by the event handler.
   bool HasPendingAccept() { return pending_accept_count_ > 0; }
   bool IssueAccept();
   void AcceptComplete(IOBuffer* buffer, HANDLE completion_port);

   virtual void EnsureInitialized(
     EventHandlerImplementation* event_handler);
   virtual void DoClose();
   virtual bool IsClosed();

   int pending_accept_count() { return pending_accept_count_; }

  private:
   bool LoadAcceptEx();

   LPFN_ACCEPTEX AcceptEx_;
   int pending_accept_count_;
   // Linked list of accepted connections provided by completion code. Ready to
   // be handed over through accept.
   ClientSocket* accepted_head_;
   ClientSocket* accepted_tail_;
 };


 // Information on connected sockets.
 class ClientSocket : public SocketHandle {
  public:
   explicit ClientSocket(SOCKET s) : SocketHandle(s),
                                     DisconnectEx_(NULL),
                                     next_(NULL) {
     LoadDisconnectEx();
     type_ = kClientSocket;
   }

   ClientSocket(SOCKET s, Dart_Port port) : SocketHandle(s, port),
                                            DisconnectEx_(NULL),
                                            next_(NULL) {
     LoadDisconnectEx();
     type_ = kClientSocket;
   }

   virtual ~ClientSocket() {
     // Don't delete this object until all pending requests have been handled.
     ASSERT(!HasPendingRead());
     ASSERT(!HasPendingWrite());
     ASSERT(next_ == NULL);
   };

   void Shutdown(int how);

   // Internal interface used by the event handler.
   virtual bool IssueRead();
   virtual bool IssueWrite();
   void IssueDisconnect();
   void DisconnectComplete(IOBuffer* buffer);

   virtual void EnsureInitialized(
     EventHandlerImplementation* event_handler);
   virtual void DoClose();
   virtual bool IsClosed();

   ClientSocket* next() { return next_; }
   void set_next(ClientSocket* next) { next_ = next; }

  private:
   bool LoadDisconnectEx();

   LPFN_DISCONNECTEX DisconnectEx_;
   ClientSocket* next_;
 };


 // Event handler.
 class EventHandlerImplementation {
  public:
   EventHandlerImplementation();
   virtual ~EventHandlerImplementation();

   void SendData(intptr_t id, Dart_Port dart_port, int64_t data);
   void Start(EventHandler* handler);
   void Shutdown();

   static void EventHandlerEntry(uword args);

   DWORD GetTimeout();
   void HandleInterrupt(InterruptMessage* msg);
   void HandleTimeout();
   void HandleAccept(ListenSocket* listen_socket, IOBuffer* buffer);
   void HandleClosed(Handle* handle);
   void HandleError(Handle* handle);
   void HandleRead(Handle* handle, int bytes, IOBuffer* buffer);
   void HandleWrite(Handle* handle, int bytes, IOBuffer* buffer);
   void HandleDisconnect(ClientSocket* client_socket,
                         int bytes,
                         IOBuffer* buffer);
   void HandleIOCompletion(DWORD bytes, ULONG_PTR key, OVERLAPPED* overlapped);

   HANDLE completion_port() { return completion_port_; }

  private:
   ClientSocket* client_sockets_head_;

   int64_t timeout_;  // Time for next timeout.
   Dart_Port timeout_port_;
   bool shutdown_;
   HANDLE completion_port_;
 };

 }  // namespace bin
 }  // namespace dart

 #endif  // BIN_EVENTHANDLER_WIN_H_
	// Copyright (c) 2012, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.

	#ifndef BIN_EVENTHANDLER_WIN_H_
	#define BIN_EVENTHANDLER_WIN_H_

	#if !defined(BIN_EVENTHANDLER_H_)
	#error Do not include eventhandler_win.h directly; use eventhandler.h instead.
	#endif

	#include <winsock2.h>
	#include <mswsock.h>

	#include "bin/builtin.h"


	namespace dart {
	namespace bin {

	// Forward declarations.
	class EventHandlerImplementation;
	class Handle;
	class FileHandle;
	class SocketHandle;
	class ClientSocket;
	class ListenSocket;


	struct InterruptMessage {
	intptr_t id;
	Dart_Port dart_port;
	int64_t data;
	};


	// An IOBuffer encapsulates the OVERLAPPED structure and the
	// associated data buffer. For accept it also contains the pre-created
	// socket for the client.
	class IOBuffer {
	public:
	enum Operation { kAccept, kRead, kWrite, kDisconnect };

	static IOBuffer* AllocateAcceptBuffer(int buffer_size);
	static IOBuffer* AllocateReadBuffer(int buffer_size);
	static IOBuffer* AllocateWriteBuffer(int buffer_size);
	static IOBuffer* AllocateDisconnectBuffer();
	static void DisposeBuffer(IOBuffer* buffer);

	// Find the IO buffer from the OVERLAPPED address.
	static IOBuffer* GetFromOverlapped(OVERLAPPED* overlapped);

	// Read data from a buffer which has been received. It will read up
	// to num_bytes bytes of data returning the actual number of bytes
	// read. This will update the index of the next byte in the buffer
	// so calling Read several times will keep returning new data from
	// the buffer until all data have been read.
	int Read(void* buffer, int num_bytes);

	// Write data to a buffer before sending it. Returns the number of bytes
	// actually written to the buffer. Calls to Write will always write to
	// the buffer from the begining.
	int Write(const void* buffer, int num_bytes);

	// Check the amount of data in a read buffer which has not been read yet.
	int GetRemainingLength();
	bool IsEmpty() { return GetRemainingLength() == 0; }

	Operation operation() { return operation_; }
	SOCKET client() { return client_; }
	char* GetBufferStart() { return reinterpret_cast<char*>(&buffer_data_); }
	int GetBufferSize() { return buflen_; }

	// Returns the address of the OVERLAPPED structure with all fields
	// initialized to zero.
	OVERLAPPED* GetCleanOverlapped() {
	memset(&overlapped_, 0, sizeof(overlapped_));
	return &overlapped_;
	}

	// Returns a WASBUF structure initialized with the data in this IO buffer.
	WSABUF* GetWASBUF() {
	wbuf_.buf = GetBufferStart();
	wbuf_.len = GetBufferSize();
	return &wbuf_;
	};

	void set_data_length(int data_length) { data_length_ = data_length; }

	private:
	IOBuffer(int buffer_size, Operation operation)
	: operation_(operation), buflen_(buffer_size) {
	memset(GetBufferStart(), 0, GetBufferSize());
	index_ = 0;
	data_length_ = 0;
	if (operation_ == kAccept) {
	client_ = socket(AF_INET, SOCK_STREAM, IPPROTO_TCP);
	}
	}

	void* operator new(size_t size, int buffer_size) {
	return malloc(size + buffer_size);
	}

	void operator delete(void* buffer) {
	free(buffer);
	}

	static IOBuffer* AllocateBuffer(int buffer_size, Operation operation);

	OVERLAPPED overlapped_; // OVERLAPPED structure for overlapped IO.
	SOCKET client_; // Used for AcceptEx client socket.
	int buflen_; // Length of the buffer.
	Operation operation_; // Type of operation issued.

	int index_; // Index for next read from read buffer.
	int data_length_; // Length of the actual data in the buffer.

	WSABUF wbuf_; // Structure for passing buffer to WSA functions.

	// Buffer for recv/send/AcceptEx. This must be at the end of the
	// object as the object is allocated larger than it's definition
	// indicate to extend this array.
	uint8_t buffer_data_[1];
	};


	// Abstract super class for holding information on listen and connected
	// sockets.
	class Handle {
	public:
	enum Type { kFile, kClientSocket, kListenSocket };

	class ScopedLock {
	public:
	explicit ScopedLock(Handle* handle)
	: handle_(handle) {
	handle_->Lock();
	}
	~ScopedLock() {
	handle_->Unlock();
	}

	private:
	Handle* handle_;
	};

	virtual ~Handle();

	// Socket interface exposing normal socket operations.
	int Available();
	int Read(void* buffer, int num_bytes);
	int Write(const void* buffer, int num_bytes);

	// Internal interface used by the event handler.
	virtual bool IssueRead();
	virtual bool IssueWrite();
	bool HasPendingRead();
	bool HasPendingWrite();
	void ReadComplete(IOBuffer* buffer);
	void WriteComplete(IOBuffer* buffer);

	bool IsClosing() { return (flags_ & (1 << kClosing)) != 0; }
	bool IsClosedRead() { return (flags_ & (1 << kCloseRead)) != 0; }
	bool IsClosedWrite() { return (flags_ & (1 << kCloseWrite)) != 0; }
	bool IsError() { return (flags_ & (1 << kError)) != 0; }
	void MarkClosing() { flags_ \|= (1 << kClosing); }
	void MarkClosedRead() { flags_ \|= (1 << kCloseRead); }
	void MarkClosedWrite() { flags_ \|= (1 << kCloseWrite); }
	void MarkError() { flags_ \|= (1 << kError); }

	virtual void EnsureInitialized(
	EventHandlerImplementation* event_handler) = 0;

	HANDLE handle() { return handle_; }
	Dart_Port port() { return port_; }
	EventHandlerImplementation* event_handler() { return event_handler_; }

	void Lock();
	void Unlock();

	bool CreateCompletionPort(HANDLE completion_port);

	void Close();
	virtual void DoClose();
	virtual bool IsClosed() = 0;

	void SetPortAndMask(Dart_Port port, intptr_t mask) {
	port_ = port;
	mask_ = mask;
	}
	Type type() { return type_; }
	bool is_file() { return type_ == kFile; }
	bool is_socket() { return type_ == kListenSocket \|\| type_ == kClientSocket; }
	bool is_listen_socket() { return type_ == kListenSocket; }
	bool is_client_socket() { return type_ == kClientSocket; }
	void set_mask(intptr_t mask) { mask_ = mask; }
	intptr_t mask() { return mask_; }

	void MarkDoesNotSupportOverlappedIO() {
	flags_ \|= (1 << kDoesNotSupportOverlappedIO);
	}
	bool SupportsOverlappedIO() {
	return (flags_ & (1 << kDoesNotSupportOverlappedIO)) == 0;
	}

	void ReadSyncCompleteAsync();

	DWORD last_error() { return last_error_; }
	void set_last_error(DWORD last_error) { last_error_ = last_error; }

	protected:
	enum Flags {
	kClosing = 0,
	kCloseRead = 1,
	kCloseWrite = 2,
	kDoesNotSupportOverlappedIO = 3,
	kError = 4
	};

	explicit Handle(HANDLE handle);
	Handle(HANDLE handle, Dart_Port port);

	virtual void HandleIssueError();

	Type type_;
	HANDLE handle_;
	Dart_Port port_; // Dart port to communicate events for this socket.
	intptr_t mask_; // Mask of events to report through the port.
	HANDLE completion_port_;
	EventHandlerImplementation* event_handler_;

	IOBuffer* data_ready_; // IO buffer for data ready to be read.
	IOBuffer* pending_read_; // IO buffer for pending read.
	IOBuffer* pending_write_; // IO buffer for pending write

	DWORD last_error_;

	private:
	int flags_;
	CRITICAL_SECTION cs_; // Critical section protecting this object.
	};


	class FileHandle : public Handle {
	public:
	explicit FileHandle(HANDLE handle)
	: Handle(reinterpret_cast<HANDLE>(handle)) { type_ = kFile; }
	FileHandle(HANDLE handle, Dart_Port port)
	: Handle(reinterpret_cast<HANDLE>(handle), port) { type_ = kFile; }

	virtual void EnsureInitialized(EventHandlerImplementation* event_handler);
	virtual bool IsClosed();
	};


	class SocketHandle : public Handle {
	public:
	SOCKET socket() { return reinterpret_cast<SOCKET>(handle_); }

	protected:
	explicit SocketHandle(SOCKET s) : Handle(reinterpret_cast<HANDLE>(s)) {}
	SocketHandle(SOCKET s, Dart_Port port)
	: Handle(reinterpret_cast<HANDLE>(s), port) {}

	virtual void HandleIssueError();
	};


	// Information on listen sockets.
	class ListenSocket : public SocketHandle {
	public:
	explicit ListenSocket(SOCKET s) : SocketHandle(s),
	AcceptEx_(NULL),
	pending_accept_count_(0),
	accepted_head_(NULL),
	accepted_tail_(NULL) {
	type_ = kListenSocket;
	}
	virtual ~ListenSocket() {
	ASSERT(!HasPendingAccept());
	ASSERT(accepted_head_ == NULL);
	ASSERT(accepted_tail_ == NULL);
	};

	// Socket interface exposing normal socket operations.
	ClientSocket* Accept();
	bool CanAccept();

	// Internal interface used by the event handler.
	bool HasPendingAccept() { return pending_accept_count_ > 0; }
	bool IssueAccept();
	void AcceptComplete(IOBuffer* buffer, HANDLE completion_port);

	virtual void EnsureInitialized(
	EventHandlerImplementation* event_handler);
	virtual void DoClose();
	virtual bool IsClosed();

	int pending_accept_count() { return pending_accept_count_; }

	private:
	bool LoadAcceptEx();

	LPFN_ACCEPTEX AcceptEx_;
	int pending_accept_count_;
	// Linked list of accepted connections provided by completion code. Ready to
	// be handed over through accept.
	ClientSocket* accepted_head_;
	ClientSocket* accepted_tail_;
	};


	// Information on connected sockets.
	class ClientSocket : public SocketHandle {
	public:
	explicit ClientSocket(SOCKET s) : SocketHandle(s),
	DisconnectEx_(NULL),
	next_(NULL) {
	LoadDisconnectEx();
	type_ = kClientSocket;
	}

	ClientSocket(SOCKET s, Dart_Port port) : SocketHandle(s, port),
	DisconnectEx_(NULL),
	next_(NULL) {
	LoadDisconnectEx();
	type_ = kClientSocket;
	}

	virtual ~ClientSocket() {
	// Don't delete this object until all pending requests have been handled.
	ASSERT(!HasPendingRead());
	ASSERT(!HasPendingWrite());
	ASSERT(next_ == NULL);
	};

	void Shutdown(int how);

	// Internal interface used by the event handler.
	virtual bool IssueRead();
	virtual bool IssueWrite();
	void IssueDisconnect();
	void DisconnectComplete(IOBuffer* buffer);

	virtual void EnsureInitialized(
	EventHandlerImplementation* event_handler);
	virtual void DoClose();
	virtual bool IsClosed();

	ClientSocket* next() { return next_; }
	void set_next(ClientSocket* next) { next_ = next; }

	private:
	bool LoadDisconnectEx();

	LPFN_DISCONNECTEX DisconnectEx_;
	ClientSocket* next_;
	};


	// Event handler.
	class EventHandlerImplementation {
	public:
	EventHandlerImplementation();
	virtual ~EventHandlerImplementation();

	void SendData(intptr_t id, Dart_Port dart_port, int64_t data);
	void Start(EventHandler* handler);
	void Shutdown();

	static void EventHandlerEntry(uword args);

	DWORD GetTimeout();
	void HandleInterrupt(InterruptMessage* msg);
	void HandleTimeout();
	void HandleAccept(ListenSocket* listen_socket, IOBuffer* buffer);
	void HandleClosed(Handle* handle);
	void HandleError(Handle* handle);
	void HandleRead(Handle* handle, int bytes, IOBuffer* buffer);
	void HandleWrite(Handle* handle, int bytes, IOBuffer* buffer);
	void HandleDisconnect(ClientSocket* client_socket,
	int bytes,
	IOBuffer* buffer);
	void HandleIOCompletion(DWORD bytes, ULONG_PTR key, OVERLAPPED* overlapped);

	HANDLE completion_port() { return completion_port_; }

	private:
	ClientSocket* client_sockets_head_;

	int64_t timeout_; // Time for next timeout.
	Dart_Port timeout_port_;
	bool shutdown_;
	HANDLE completion_port_;
	};

	} // namespace bin
	} // namespace dart

	#endif // BIN_EVENTHANDLER_WIN_H_