esfand/RIOServer_sm9.cpp

## RIOServer_sm9.cpp
/*********************************************************************************************************
 * Windows Registered I/O (RIO) Sample Code (Echo Server)
 * Minimum requirement: Windows 8 or Windows Server 2012
 * Author: @sm9kr
 *
 * Notice
 * 몇몇 코드 조각들은 (http://www.serverframework.com/asynchronousevents/rio/)에서 가져옴.
 * 그런데 여기도 제대로 완성된 코드가 있었던 것은 아니라서 상당 부분 기능을 추가하여 동작하도록 함.
 * RIO의 사용법을 보여주기 위한 코드라 최대한 간단하게 필요한 부분만 넣었음.
 * 그래서, 버그가 있을 수 있음...
 * UDP형태로 만든 이유는 귀찮아서...TCP로 하면 세션 관리를 따로 해야되고 버퍼 재조립도 해야되는 관계로..
 * RIO를 쓰는 방식은 똑같기 때문에 아래 코드를 보고 TCP에 적용 시키는 것도 어렵지 않음.
 *********************************************************************************************************/

#define NOMINMAX

#include <SDKDDKVer.h>

#include <stdio.h>
#include <tchar.h>

#include <WinSock2.h>
#include <MSWsock.h>
#include <WS2tcpip.h>
#include <iostream>
#include <deque>

#include <process.h>

#pragma comment(lib, "ws2_32.lib")

using std::cout ;
using std::endl ;
using std::deque ;


RIO_EXTENSION_FUNCTION_TABLE g_rio ;
RIO_CQ g_completionQueue = 0 ;
RIO_RQ g_requestQueue = 0 ;

HANDLE g_hIOCP = NULL ;

SOCKET g_socket ;

CRITICAL_SECTION g_criticalSection ;

RIO_BUFFERID g_sendBufferId ;
RIO_BUFFERID g_recvBufferId ;
RIO_BUFFERID g_addrBufferId ;

char* g_sendBufferPointer = NULL ;
char* g_recvBufferPointer = NULL ;
char* g_addrBufferPointer = NULL ;


typedef std::deque<HANDLE> Threads ;
Threads g_threads ;

static const unsigned short PORTNUM = 5050 ;

static const DWORD RIO_PENDING_RECVS = 100000 ;
static const DWORD RIO_PENDING_SENDS = 10000 ;

static const DWORD RECV_BUFFER_SIZE = 1024 ;
static const DWORD SEND_BUFFER_SIZE = 1024 ;

static const DWORD ADDR_BUFFER_SIZE = 64 ;

static const DWORD NUM_IOCP_THREADS = 4 ;

static const DWORD RIO_MAX_RESULTS = 1000 ;


enum COMPLETION_KEY
{
    CK_STOP  =	0,
	CK_START =	1
};

enum OPERATION_TYPE
{
	OP_NONE = 0,
	OP_RECV = 1,
	OP_SEND	= 2
} ;

struct EXTENDED_RIO_BUF : public RIO_BUF
{
	OPERATION_TYPE operation ;
} ;


/// SEND용 RIO_BUF는 순환큐형태로 만들어 놓고 돌려 쓰자.
EXTENDED_RIO_BUF* g_sendRioBufs = NULL ;
DWORD g_sendRioBufTotalCount = 0 ;
__int64 g_sendRioBufIndex = 0 ;

/// ADDR용 RIO_BUF pointer
EXTENDED_RIO_BUF* g_addrRioBufs = NULL ;
DWORD g_addrRioBufTotalCount = 0 ;
__int64 g_addrRioBufIndex = 0 ;

/// RIO에서 Registering할 버퍼 할당함수
char *AllocateBufferSpace(const DWORD bufSize, const DWORD bufCount, DWORD& totalBufferSize, DWORD& totalBufferCount) ;

unsigned int __stdcall IOThread(void *pV) ;


int _tmain(int argc, _TCHAR* argv[])
{
	WSADATA data ;
	InitializeCriticalSectionAndSpinCount(&g_criticalSection, 4000) ;

	if ( 0 != ::WSAStartup(0x202, &data) )
	{
		const DWORD gle = ::GetLastError() ;
		cout << "WSAStartup Error: " << gle << endl ;
		exit(0) ;
	}


	/// RIO 소켓 생성
	g_socket = WSASocket(AF_INET, SOCK_DGRAM, IPPROTO_UDP, NULL, 0, WSA_FLAG_REGISTERED_IO) ;
	if (g_socket == INVALID_SOCKET)
	{
		const DWORD gle = ::GetLastError() ;
		cout << "WSASocket Error: " << gle << endl ;
		exit(0) ;
	}

	/// port binding
	sockaddr_in addr ;
	addr.sin_family = AF_INET ;
	addr.sin_port = htons(PORTNUM) ;
	addr.sin_addr.s_addr = INADDR_ANY ;

	if ( SOCKET_ERROR == ::bind(g_socket, reinterpret_cast<struct sockaddr *>(&addr), sizeof(addr)) )
	{
		const DWORD gle = ::GetLastError() ;
		cout << "Bind Error: " << gle << endl ;
		exit(0) ;
	}

	/// RIO 함수 테이블 가져오기
	GUID functionTableId = WSAID_MULTIPLE_RIO ;
	DWORD dwBytes = 0 ;

	if ( NULL != WSAIoctl(g_socket, SIO_GET_MULTIPLE_EXTENSION_FUNCTION_POINTER, &functionTableId, sizeof(GUID),
		(void**)&g_rio,	sizeof(g_rio), &dwBytes, NULL, NULL) )
	{
		const DWORD gle = ::GetLastError() ;
		cout << "WSAIoctl Error: " << gle << endl ;
		exit(0) ;
	}

	/// rio의 completion 방식은 iocp를 사용.
	g_hIOCP = ::CreateIoCompletionPort(INVALID_HANDLE_VALUE, 0, 0, 0) ;
	if (NULL == g_hIOCP)
	{
		const DWORD gle = ::GetLastError() ;
		cout << "CreateIoCompletionPort Error: " << gle << endl ;
		exit(0) ;
	}


	OVERLAPPED overlapped ;

	RIO_NOTIFICATION_COMPLETION completionType ;

	completionType.Type = RIO_IOCP_COMPLETION ;
	completionType.Iocp.IocpHandle = g_hIOCP ;
	completionType.Iocp.CompletionKey = (void*) CK_START ;
	completionType.Iocp.Overlapped = &overlapped ;

	/// RIO CQ 생성 (RQ 사이즈보다 크거나 같아야 함)
	g_completionQueue = g_rio.RIOCreateCompletionQueue(RIO_PENDING_RECVS+RIO_PENDING_SENDS, &completionType) ;
	if (g_completionQueue == RIO_INVALID_CQ)
	{
		const DWORD gle = ::GetLastError() ;
		cout << "RIOCreateCompletionQueue Error: " << gle << endl ;
		exit(0) ;
	}

	/// RIO RQ 생성
	/// SEND CQ와 RECV CQ를 같이 씀.. (따로 만들어 써도 됨)
	g_requestQueue = g_rio.RIOCreateRequestQueue(g_socket, RIO_PENDING_RECVS, 1, RIO_PENDING_SENDS, 1, g_completionQueue, g_completionQueue, NULL) ;
	if (g_requestQueue == RIO_INVALID_RQ)
	{
		const DWORD gle = ::GetLastError() ;
		cout << "RIOCreateRequestQueue Error: " << gle << endl ;
		exit(0) ;
	}


	/// SEND용 RIO 버퍼 등록
	{
		DWORD totalBufferCount = 0 ;
		DWORD totalBufferSize = 0 ;

		g_sendBufferPointer = AllocateBufferSpace(SEND_BUFFER_SIZE, RIO_PENDING_SENDS, totalBufferSize, totalBufferCount) ;
		g_sendBufferId = g_rio.RIORegisterBuffer(g_sendBufferPointer, static_cast<DWORD>(totalBufferSize)) ;

		if (g_sendBufferId == RIO_INVALID_BUFFERID)
		{
			const DWORD gle = ::GetLastError() ;
			cout << "RIORegisterBuffer Error: " << gle << endl ;
			exit(0) ;
		}

		DWORD offset = 0 ;

		g_sendRioBufs = new EXTENDED_RIO_BUF[totalBufferCount] ;
		g_sendRioBufTotalCount = totalBufferCount ;

		for (DWORD i = 0; i < g_sendRioBufTotalCount; ++i)
		{
			/// RIO operation에 맞도록 할당된 버퍼를 쪼개기
			EXTENDED_RIO_BUF* pBuffer = g_sendRioBufs + i ;

			pBuffer->operation = OP_SEND ;
			pBuffer->BufferId = g_sendBufferId ;
			pBuffer->Offset = offset ;
			pBuffer->Length = SEND_BUFFER_SIZE ;

			offset += SEND_BUFFER_SIZE ;

		}

	}


	/// ADDR용 (RECV시 담겨오는 주소용) RIO 버퍼 등록
	{
		DWORD totalBufferCount = 0 ;
		DWORD totalBufferSize = 0 ;

		g_addrBufferPointer = AllocateBufferSpace(ADDR_BUFFER_SIZE, RIO_PENDING_RECVS, totalBufferSize, totalBufferCount) ;
		g_addrBufferId = g_rio.RIORegisterBuffer(g_addrBufferPointer, static_cast<DWORD>(totalBufferSize)) ;

		if (g_addrBufferId == RIO_INVALID_BUFFERID)
		{
			const DWORD gle = ::GetLastError() ;
			cout << "RIORegisterBuffer Error: " << gle << endl ;
			exit(0) ;
		}

		DWORD offset = 0 ;

		g_addrRioBufs = new EXTENDED_RIO_BUF[totalBufferCount] ;
		g_addrRioBufTotalCount = totalBufferCount ;

		for (DWORD i = 0; i < totalBufferCount; ++i)
		{
			EXTENDED_RIO_BUF* pBuffer = g_addrRioBufs + i ;

			pBuffer->operation = OP_NONE ;
			pBuffer->BufferId = g_addrBufferId ;
			pBuffer->Offset = offset ;
			pBuffer->Length = ADDR_BUFFER_SIZE ;

			offset += ADDR_BUFFER_SIZE ;
		}
	}

	/// RECV용 RIO 버퍼 등록 및 RECV 미리 걸어놓기
	{
		DWORD totalBufferCount = 0 ;
		DWORD totalBufferSize = 0 ;

		g_recvBufferPointer = AllocateBufferSpace(RECV_BUFFER_SIZE, RIO_PENDING_RECVS, totalBufferSize, totalBufferCount) ;

		g_recvBufferId = g_rio.RIORegisterBuffer(g_recvBufferPointer, static_cast<DWORD>(totalBufferSize)) ;
		if (g_recvBufferId == RIO_INVALID_BUFFERID)
		{
			const DWORD gle = ::GetLastError() ;
			cout << "RIORegisterBuffer Error: " << gle << endl ;
			exit(0) ;
		}


		DWORD offset = 0 ;

		EXTENDED_RIO_BUF* pBufs = new EXTENDED_RIO_BUF[totalBufferCount] ;

		for (DWORD i = 0; i < totalBufferCount; ++i)
		{
			EXTENDED_RIO_BUF* pBuffer = pBufs + i ;

			pBuffer->operation = OP_RECV ;
			pBuffer->BufferId = g_recvBufferId ;
			pBuffer->Offset = offset ;
			pBuffer->Length = RECV_BUFFER_SIZE ;

			offset += RECV_BUFFER_SIZE ;

			/// 미리 RECV 많이 걸어 놓는다.
			if (!g_rio.RIOReceiveEx(g_requestQueue, pBuffer, 1, NULL, &g_addrRioBufs[g_addrRioBufIndex++], NULL, 0, 0, pBuffer))
			{
				const DWORD gle = ::GetLastError() ;
				cout << "RIOReceive Error: " << gle << endl ;
				exit(0) ;
			}
		}

		cout << totalBufferCount << " total receives pending" << endl ;
	}


	/// IO 쓰레드 생성
	for (DWORD i = 0; i < NUM_IOCP_THREADS ; ++i)
	{
		unsigned int notUsed ;
		const uintptr_t result = ::_beginthreadex(0, 0, IOThread, (void*)i, 0, &notUsed) ;
		if (result == 0)
		{
			const DWORD gle = ::GetLastError() ;
			cout << "_beginthreadex Error: " << gle << endl ;
			exit(0) ;
		}

		g_threads.push_back(reinterpret_cast<HANDLE>(result)) ;
	}

	/// Completion이 준비되었음을 알린다
	INT notifyResult = g_rio.RIONotify(g_completionQueue) ;
	if (notifyResult != ERROR_SUCCESS)
	{
		const DWORD gle = ::GetLastError() ;
		cout << "RIONotify Error: " << gle << endl ;
		exit(0) ;
	}


	/// 아무키나 받으면 자원 반환하고 끝내기 -.- ;
	cout << "Press Any Key to Stop" << endl ;
	getchar() ;


	/// 컴플리션키를 CK_STOP으로 쓰면 쓰레드 멈춰라는 명령으로 사용
	for (Threads::const_iterator it = g_threads.begin(), end = g_threads.end(); it != end; ++it)
	{
		if (0 == ::PostQueuedCompletionStatus(g_hIOCP, 0, CK_STOP, 0))
		{
			const DWORD gle = ::GetLastError() ;
			cout << "PostQueuedCompletionStatus Error: " << gle << endl ;
			exit(0) ;
		}
	}

	/// 쓰레드 조인
	for (Threads::const_iterator it = g_threads.begin(), end = g_threads.end(); it != end; ++it)
	{
		HANDLE hThread = *it;

		if (WAIT_OBJECT_0 != ::WaitForSingleObject(hThread, INFINITE))
		{
			const DWORD gle = ::GetLastError() ;
			cout << "WaitForSingleObject (thread join) Error: " << gle << endl ;
			exit(0) ;
		}

		::CloseHandle(hThread);
	}


	if ( SOCKET_ERROR == ::closesocket(g_socket) )
	{
		const DWORD gle = ::GetLastError() ;
		cout << "closesocket Error: " << gle << endl ;
	}

	g_rio.RIOCloseCompletionQueue(g_completionQueue) ;

	g_rio.RIODeregisterBuffer(g_sendBufferId) ;
	g_rio.RIODeregisterBuffer(g_recvBufferId) ;
	g_rio.RIODeregisterBuffer(g_addrBufferId) ;

	DeleteCriticalSection(&g_criticalSection) ;

	return 0;
}


unsigned int __stdcall IOThread(void *pV)
{
	DWORD numberOfBytes = 0;

	ULONG_PTR completionKey = 0;
	OVERLAPPED* pOverlapped = 0;

	RIORESULT results[RIO_MAX_RESULTS] ;

	while ( true )
	{
		if (!::GetQueuedCompletionStatus(g_hIOCP, &numberOfBytes, &completionKey, &pOverlapped, INFINITE))
		{
			const DWORD gle = ::GetLastError() ;
			cout << "GetQueuedCompletionStatus Error: " << gle << endl ;
			exit(0) ;
		}

		/// ck로 0이 넘어오면 끝낸다
		if ( completionKey == CK_STOP )
			break ;

		memset(results, 0, sizeof(results)) ;

		ULONG numResults = g_rio.RIODequeueCompletion(g_completionQueue, results, RIO_MAX_RESULTS) ;
		if (0 == numResults || RIO_CORRUPT_CQ == numResults)
		{
			const DWORD gle = ::GetLastError() ;
			cout << "RIODequeueCompletion Error: " << gle << endl ;
			exit(0) ;
		}

		/// Dequeue 한 다음에는 다음 컴플리션이 가능하도록 알린다.
		INT notifyResult = g_rio.RIONotify(g_completionQueue) ;
		if (notifyResult != ERROR_SUCCESS)
		{
			const DWORD gle = ::GetLastError() ;
			cout << "RIONotify Error: " << gle << endl ;
			exit(0) ;
		}

		for (DWORD i = 0; i < numResults; ++i)
		{
			EXTENDED_RIO_BUF *pBuffer = reinterpret_cast<EXTENDED_RIO_BUF*>(results[i].RequestContext) ;

			if ( OP_RECV == pBuffer->operation )
			{
				/// UDP니까 송신자측에서 보낸 데이터가 전부 안오는 경우는 에러
				if (results[i].BytesTransferred != RECV_BUFFER_SIZE)
					break ;

				///// ECHO TEST
				const char* offset = g_recvBufferPointer + pBuffer->Offset ;

				/// RQ는 thread-safe하지 않기 때문에 보호해줘야 한다. (최적화를 하지는 않았음. 대충 LOCK...)
				::EnterCriticalSection(&g_criticalSection) ;
				{

					EXTENDED_RIO_BUF* sendBuf = &(g_sendRioBufs[g_sendRioBufIndex++ % g_sendRioBufTotalCount]) ;
					char* sendOffset = g_sendBufferPointer + sendBuf->Offset ;
					memcpy_s(sendOffset, RECV_BUFFER_SIZE, offset, pBuffer->Length) ;

					/// TEST PRINT
					cout << strlen(sendOffset) << " " ;


					if (!g_rio.RIOSendEx(g_requestQueue, sendBuf, 1, NULL, &g_addrRioBufs[g_addrRioBufIndex % g_addrRioBufTotalCount], NULL, NULL, 0, sendBuf))
					{
						const DWORD gle = ::GetLastError() ;
						cout << "RIOSend Error: " << gle << endl ;
						exit(0) ;;
					}

				}
				::LeaveCriticalSection(&g_criticalSection) ;


			}
			else if ( OP_SEND == pBuffer->operation )
			{
				/// 마찬가지로 RQ 보호
				::EnterCriticalSection(&g_criticalSection) ;
				{

					if (!g_rio.RIOReceiveEx(g_requestQueue, pBuffer, 1, NULL, &g_addrRioBufs[g_addrRioBufIndex % g_addrRioBufTotalCount], NULL, 0, 0, pBuffer))
					{
						const DWORD gle = ::GetLastError() ;
						cout << "RIOReceive Error: " << gle << endl ;
						exit(0) ;;
					}

					g_addrRioBufIndex++ ;

				}
				::LeaveCriticalSection(&g_criticalSection) ;

			}
			else
				break ;

		}
	}


	return 0 ;
}


template <typename TV, typename TM>
inline TV RoundDown(TV Value, TM Multiple)
{
	return((Value / Multiple) * Multiple);
}

template <typename TV, typename TM>
inline TV RoundUp(TV Value, TM Multiple)
{
	return(RoundDown(Value, Multiple) + (((Value % Multiple) > 0) ? Multiple : 0));
}


char *AllocateBufferSpace(const DWORD bufSize, const DWORD bufCount, DWORD& totalBufferSize, DWORD& totalBufferCount)
{
	SYSTEM_INFO systemInfo ;

	::GetSystemInfo(&systemInfo) ;

	const unsigned __int64 granularity = systemInfo.dwAllocationGranularity ;

	const unsigned __int64 desiredSize = bufSize * bufCount ;

	unsigned __int64 actualSize = RoundUp(desiredSize, granularity) ;

	if (actualSize > std::numeric_limits<DWORD>::max())
	{
		actualSize = (std::numeric_limits<DWORD>::max() / granularity) * granularity ;
	}

	totalBufferCount = std::min<DWORD>(bufCount, static_cast<DWORD>(actualSize / bufSize)) ;

	totalBufferSize = static_cast<DWORD>(actualSize) ;

	char *pBuffer = reinterpret_cast<char *>(VirtualAllocEx(GetCurrentProcess(), 0, totalBufferSize, MEM_COMMIT | MEM_RESERVE, PAGE_READWRITE)) ;

	if (pBuffer == 0)
	{
		const DWORD gle = ::GetLastError() ;
		cout << "VirtualAllocEx Error: " << gle << endl ;
		exit(0) ;
	}

	return pBuffer;
}
	/*********************************************************************************************************
	* Windows Registered I/O (RIO) Sample Code (Echo Server)
	* Minimum requirement: Windows 8 or Windows Server 2012
	* Author: @sm9kr
	*
	* Notice
	* 몇몇 코드 조각들은 (http://www.serverframework.com/asynchronousevents/rio/)에서 가져옴.
	* 그런데 여기도 제대로 완성된 코드가 있었던 것은 아니라서 상당 부분 기능을 추가하여 동작하도록 함.
	* RIO의 사용법을 보여주기 위한 코드라 최대한 간단하게 필요한 부분만 넣었음.
	* 그래서, 버그가 있을 수 있음...
	* UDP형태로 만든 이유는 귀찮아서...TCP로 하면 세션 관리를 따로 해야되고 버퍼 재조립도 해야되는 관계로..
	* RIO를 쓰는 방식은 똑같기 때문에 아래 코드를 보고 TCP에 적용 시키는 것도 어렵지 않음.
	*********************************************************************************************************/

	#define NOMINMAX

	#include <SDKDDKVer.h>

	#include <stdio.h>
	#include <tchar.h>

	#include <WinSock2.h>
	#include <MSWsock.h>
	#include <WS2tcpip.h>
	#include <iostream>
	#include <deque>

	#include <process.h>

	#pragma comment(lib, "ws2_32.lib")

	using std::cout ;
	using std::endl ;
	using std::deque ;


	RIO_EXTENSION_FUNCTION_TABLE g_rio ;
	RIO_CQ g_completionQueue = 0 ;
	RIO_RQ g_requestQueue = 0 ;

	HANDLE g_hIOCP = NULL ;

	SOCKET g_socket ;

	CRITICAL_SECTION g_criticalSection ;

	RIO_BUFFERID g_sendBufferId ;
	RIO_BUFFERID g_recvBufferId ;
	RIO_BUFFERID g_addrBufferId ;

	char* g_sendBufferPointer = NULL ;
	char* g_recvBufferPointer = NULL ;
	char* g_addrBufferPointer = NULL ;


	typedef std::deque<HANDLE> Threads ;
	Threads g_threads ;

	static const unsigned short PORTNUM = 5050 ;

	static const DWORD RIO_PENDING_RECVS = 100000 ;
	static const DWORD RIO_PENDING_SENDS = 10000 ;

	static const DWORD RECV_BUFFER_SIZE = 1024 ;
	static const DWORD SEND_BUFFER_SIZE = 1024 ;

	static const DWORD ADDR_BUFFER_SIZE = 64 ;

	static const DWORD NUM_IOCP_THREADS = 4 ;

	static const DWORD RIO_MAX_RESULTS = 1000 ;


	enum COMPLETION_KEY
	{
	CK_STOP = 0,
	CK_START = 1
	};

	enum OPERATION_TYPE
	{
	OP_NONE = 0,
	OP_RECV = 1,
	OP_SEND = 2
	} ;

	struct EXTENDED_RIO_BUF : public RIO_BUF
	{
	OPERATION_TYPE operation ;
	} ;


	/// SEND용 RIO_BUF는 순환큐형태로 만들어 놓고 돌려 쓰자.
	EXTENDED_RIO_BUF* g_sendRioBufs = NULL ;
	DWORD g_sendRioBufTotalCount = 0 ;
	__int64 g_sendRioBufIndex = 0 ;

	/// ADDR용 RIO_BUF pointer
	EXTENDED_RIO_BUF* g_addrRioBufs = NULL ;
	DWORD g_addrRioBufTotalCount = 0 ;
	__int64 g_addrRioBufIndex = 0 ;

	/// RIO에서 Registering할 버퍼 할당함수
	char *AllocateBufferSpace(const DWORD bufSize, const DWORD bufCount, DWORD& totalBufferSize, DWORD& totalBufferCount) ;

	unsigned int __stdcall IOThread(void *pV) ;


	int _tmain(int argc, _TCHAR* argv[])
	{
	WSADATA data ;
	InitializeCriticalSectionAndSpinCount(&g_criticalSection, 4000) ;

	if ( 0 != ::WSAStartup(0x202, &data) )
	{
	const DWORD gle = ::GetLastError() ;
	cout << "WSAStartup Error: " << gle << endl ;
	exit(0) ;
	}


	/// RIO 소켓 생성
	g_socket = WSASocket(AF_INET, SOCK_DGRAM, IPPROTO_UDP, NULL, 0, WSA_FLAG_REGISTERED_IO) ;
	if (g_socket == INVALID_SOCKET)
	{
	const DWORD gle = ::GetLastError() ;
	cout << "WSASocket Error: " << gle << endl ;
	exit(0) ;
	}

	/// port binding
	sockaddr_in addr ;
	addr.sin_family = AF_INET ;
	addr.sin_port = htons(PORTNUM) ;
	addr.sin_addr.s_addr = INADDR_ANY ;

	if ( SOCKET_ERROR == ::bind(g_socket, reinterpret_cast<struct sockaddr *>(&addr), sizeof(addr)) )
	{
	const DWORD gle = ::GetLastError() ;
	cout << "Bind Error: " << gle << endl ;
	exit(0) ;
	}

	/// RIO 함수 테이블 가져오기
	GUID functionTableId = WSAID_MULTIPLE_RIO ;
	DWORD dwBytes = 0 ;

	if ( NULL != WSAIoctl(g_socket, SIO_GET_MULTIPLE_EXTENSION_FUNCTION_POINTER, &functionTableId, sizeof(GUID),
	(void**)&g_rio, sizeof(g_rio), &dwBytes, NULL, NULL) )
	{
	const DWORD gle = ::GetLastError() ;
	cout << "WSAIoctl Error: " << gle << endl ;
	exit(0) ;
	}

	/// rio의 completion 방식은 iocp를 사용.
	g_hIOCP = ::CreateIoCompletionPort(INVALID_HANDLE_VALUE, 0, 0, 0) ;
	if (NULL == g_hIOCP)
	{
	const DWORD gle = ::GetLastError() ;
	cout << "CreateIoCompletionPort Error: " << gle << endl ;
	exit(0) ;
	}


	OVERLAPPED overlapped ;

	RIO_NOTIFICATION_COMPLETION completionType ;

	completionType.Type = RIO_IOCP_COMPLETION ;
	completionType.Iocp.IocpHandle = g_hIOCP ;
	completionType.Iocp.CompletionKey = (void*) CK_START ;
	completionType.Iocp.Overlapped = &overlapped ;

	/// RIO CQ 생성 (RQ 사이즈보다 크거나 같아야 함)
	g_completionQueue = g_rio.RIOCreateCompletionQueue(RIO_PENDING_RECVS+RIO_PENDING_SENDS, &completionType) ;
	if (g_completionQueue == RIO_INVALID_CQ)
	{
	const DWORD gle = ::GetLastError() ;
	cout << "RIOCreateCompletionQueue Error: " << gle << endl ;
	exit(0) ;
	}

	/// RIO RQ 생성
	/// SEND CQ와 RECV CQ를 같이 씀.. (따로 만들어 써도 됨)
	g_requestQueue = g_rio.RIOCreateRequestQueue(g_socket, RIO_PENDING_RECVS, 1, RIO_PENDING_SENDS, 1, g_completionQueue, g_completionQueue, NULL) ;
	if (g_requestQueue == RIO_INVALID_RQ)
	{
	const DWORD gle = ::GetLastError() ;
	cout << "RIOCreateRequestQueue Error: " << gle << endl ;
	exit(0) ;
	}


	/// SEND용 RIO 버퍼 등록
	{
	DWORD totalBufferCount = 0 ;
	DWORD totalBufferSize = 0 ;

	g_sendBufferPointer = AllocateBufferSpace(SEND_BUFFER_SIZE, RIO_PENDING_SENDS, totalBufferSize, totalBufferCount) ;
	g_sendBufferId = g_rio.RIORegisterBuffer(g_sendBufferPointer, static_cast<DWORD>(totalBufferSize)) ;

	if (g_sendBufferId == RIO_INVALID_BUFFERID)
	{
	const DWORD gle = ::GetLastError() ;
	cout << "RIORegisterBuffer Error: " << gle << endl ;
	exit(0) ;
	}

	DWORD offset = 0 ;

	g_sendRioBufs = new EXTENDED_RIO_BUF[totalBufferCount] ;
	g_sendRioBufTotalCount = totalBufferCount ;

	for (DWORD i = 0; i < g_sendRioBufTotalCount; ++i)
	{
	/// RIO operation에 맞도록 할당된 버퍼를 쪼개기
	EXTENDED_RIO_BUF* pBuffer = g_sendRioBufs + i ;

	pBuffer->operation = OP_SEND ;
	pBuffer->BufferId = g_sendBufferId ;
	pBuffer->Offset = offset ;
	pBuffer->Length = SEND_BUFFER_SIZE ;

	offset += SEND_BUFFER_SIZE ;

	}

	}


	/// ADDR용 (RECV시 담겨오는 주소용) RIO 버퍼 등록
	{
	DWORD totalBufferCount = 0 ;
	DWORD totalBufferSize = 0 ;

	g_addrBufferPointer = AllocateBufferSpace(ADDR_BUFFER_SIZE, RIO_PENDING_RECVS, totalBufferSize, totalBufferCount) ;
	g_addrBufferId = g_rio.RIORegisterBuffer(g_addrBufferPointer, static_cast<DWORD>(totalBufferSize)) ;

	if (g_addrBufferId == RIO_INVALID_BUFFERID)
	{
	const DWORD gle = ::GetLastError() ;
	cout << "RIORegisterBuffer Error: " << gle << endl ;
	exit(0) ;
	}

	DWORD offset = 0 ;

	g_addrRioBufs = new EXTENDED_RIO_BUF[totalBufferCount] ;
	g_addrRioBufTotalCount = totalBufferCount ;

	for (DWORD i = 0; i < totalBufferCount; ++i)
	{
	EXTENDED_RIO_BUF* pBuffer = g_addrRioBufs + i ;

	pBuffer->operation = OP_NONE ;
	pBuffer->BufferId = g_addrBufferId ;
	pBuffer->Offset = offset ;
	pBuffer->Length = ADDR_BUFFER_SIZE ;

	offset += ADDR_BUFFER_SIZE ;
	}
	}

	/// RECV용 RIO 버퍼 등록 및 RECV 미리 걸어놓기
	{
	DWORD totalBufferCount = 0 ;
	DWORD totalBufferSize = 0 ;

	g_recvBufferPointer = AllocateBufferSpace(RECV_BUFFER_SIZE, RIO_PENDING_RECVS, totalBufferSize, totalBufferCount) ;

	g_recvBufferId = g_rio.RIORegisterBuffer(g_recvBufferPointer, static_cast<DWORD>(totalBufferSize)) ;
	if (g_recvBufferId == RIO_INVALID_BUFFERID)
	{
	const DWORD gle = ::GetLastError() ;
	cout << "RIORegisterBuffer Error: " << gle << endl ;
	exit(0) ;
	}


	DWORD offset = 0 ;

	EXTENDED_RIO_BUF* pBufs = new EXTENDED_RIO_BUF[totalBufferCount] ;

	for (DWORD i = 0; i < totalBufferCount; ++i)
	{
	EXTENDED_RIO_BUF* pBuffer = pBufs + i ;

	pBuffer->operation = OP_RECV ;
	pBuffer->BufferId = g_recvBufferId ;
	pBuffer->Offset = offset ;
	pBuffer->Length = RECV_BUFFER_SIZE ;

	offset += RECV_BUFFER_SIZE ;

	/// 미리 RECV 많이 걸어 놓는다.
	if (!g_rio.RIOReceiveEx(g_requestQueue, pBuffer, 1, NULL, &g_addrRioBufs[g_addrRioBufIndex++], NULL, 0, 0, pBuffer))
	{
	const DWORD gle = ::GetLastError() ;
	cout << "RIOReceive Error: " << gle << endl ;
	exit(0) ;
	}
	}

	cout << totalBufferCount << " total receives pending" << endl ;
	}


	/// IO 쓰레드 생성
	for (DWORD i = 0; i < NUM_IOCP_THREADS ; ++i)
	{
	unsigned int notUsed ;
	const uintptr_t result = ::_beginthreadex(0, 0, IOThread, (void*)i, 0, &notUsed) ;
	if (result == 0)
	{
	const DWORD gle = ::GetLastError() ;
	cout << "_beginthreadex Error: " << gle << endl ;
	exit(0) ;
	}

	g_threads.push_back(reinterpret_cast<HANDLE>(result)) ;
	}

	/// Completion이 준비되었음을 알린다
	INT notifyResult = g_rio.RIONotify(g_completionQueue) ;
	if (notifyResult != ERROR_SUCCESS)
	{
	const DWORD gle = ::GetLastError() ;
	cout << "RIONotify Error: " << gle << endl ;
	exit(0) ;
	}


	/// 아무키나 받으면 자원 반환하고 끝내기 -.- ;
	cout << "Press Any Key to Stop" << endl ;
	getchar() ;



	/// 컴플리션키를 CK_STOP으로 쓰면 쓰레드 멈춰라는 명령으로 사용
	for (Threads::const_iterator it = g_threads.begin(), end = g_threads.end(); it != end; ++it)
	{
	if (0 == ::PostQueuedCompletionStatus(g_hIOCP, 0, CK_STOP, 0))
	{
	const DWORD gle = ::GetLastError() ;
	cout << "PostQueuedCompletionStatus Error: " << gle << endl ;
	exit(0) ;
	}
	}

	/// 쓰레드 조인
	for (Threads::const_iterator it = g_threads.begin(), end = g_threads.end(); it != end; ++it)
	{
	HANDLE hThread = *it;

	if (WAIT_OBJECT_0 != ::WaitForSingleObject(hThread, INFINITE))
	{
	const DWORD gle = ::GetLastError() ;
	cout << "WaitForSingleObject (thread join) Error: " << gle << endl ;
	exit(0) ;
	}

	::CloseHandle(hThread);
	}


	if ( SOCKET_ERROR == ::closesocket(g_socket) )
	{
	const DWORD gle = ::GetLastError() ;
	cout << "closesocket Error: " << gle << endl ;
	}

	g_rio.RIOCloseCompletionQueue(g_completionQueue) ;

	g_rio.RIODeregisterBuffer(g_sendBufferId) ;
	g_rio.RIODeregisterBuffer(g_recvBufferId) ;
	g_rio.RIODeregisterBuffer(g_addrBufferId) ;

	DeleteCriticalSection(&g_criticalSection) ;

	return 0;
	}


	unsigned int __stdcall IOThread(void *pV)
	{
	DWORD numberOfBytes = 0;

	ULONG_PTR completionKey = 0;
	OVERLAPPED* pOverlapped = 0;

	RIORESULT results[RIO_MAX_RESULTS] ;

	while ( true )
	{
	if (!::GetQueuedCompletionStatus(g_hIOCP, &numberOfBytes, &completionKey, &pOverlapped, INFINITE))
	{
	const DWORD gle = ::GetLastError() ;
	cout << "GetQueuedCompletionStatus Error: " << gle << endl ;
	exit(0) ;
	}

	/// ck로 0이 넘어오면 끝낸다
	if ( completionKey == CK_STOP )
	break ;

	memset(results, 0, sizeof(results)) ;

	ULONG numResults = g_rio.RIODequeueCompletion(g_completionQueue, results, RIO_MAX_RESULTS) ;
	if (0 == numResults \|\| RIO_CORRUPT_CQ == numResults)
	{
	const DWORD gle = ::GetLastError() ;
	cout << "RIODequeueCompletion Error: " << gle << endl ;
	exit(0) ;
	}

	/// Dequeue 한 다음에는 다음 컴플리션이 가능하도록 알린다.
	INT notifyResult = g_rio.RIONotify(g_completionQueue) ;
	if (notifyResult != ERROR_SUCCESS)
	{
	const DWORD gle = ::GetLastError() ;
	cout << "RIONotify Error: " << gle << endl ;
	exit(0) ;
	}

	for (DWORD i = 0; i < numResults; ++i)
	{
	EXTENDED_RIO_BUF pBuffer = reinterpret_cast<EXTENDED_RIO_BUF>(results[i].RequestContext) ;

	if ( OP_RECV == pBuffer->operation )
	{
	/// UDP니까 송신자측에서 보낸 데이터가 전부 안오는 경우는 에러
	if (results[i].BytesTransferred != RECV_BUFFER_SIZE)
	break ;

	///// ECHO TEST
	const char* offset = g_recvBufferPointer + pBuffer->Offset ;

	/// RQ는 thread-safe하지 않기 때문에 보호해줘야 한다. (최적화를 하지는 않았음. 대충 LOCK...)
	::EnterCriticalSection(&g_criticalSection) ;
	{

	EXTENDED_RIO_BUF* sendBuf = &(g_sendRioBufs[g_sendRioBufIndex++ % g_sendRioBufTotalCount]) ;
	char* sendOffset = g_sendBufferPointer + sendBuf->Offset ;
	memcpy_s(sendOffset, RECV_BUFFER_SIZE, offset, pBuffer->Length) ;

	/// TEST PRINT
	cout << strlen(sendOffset) << " " ;


	if (!g_rio.RIOSendEx(g_requestQueue, sendBuf, 1, NULL, &g_addrRioBufs[g_addrRioBufIndex % g_addrRioBufTotalCount], NULL, NULL, 0, sendBuf))
	{
	const DWORD gle = ::GetLastError() ;
	cout << "RIOSend Error: " << gle << endl ;
	exit(0) ;;
	}

	}
	::LeaveCriticalSection(&g_criticalSection) ;


	}
	else if ( OP_SEND == pBuffer->operation )
	{
	/// 마찬가지로 RQ 보호
	::EnterCriticalSection(&g_criticalSection) ;
	{

	if (!g_rio.RIOReceiveEx(g_requestQueue, pBuffer, 1, NULL, &g_addrRioBufs[g_addrRioBufIndex % g_addrRioBufTotalCount], NULL, 0, 0, pBuffer))
	{
	const DWORD gle = ::GetLastError() ;
	cout << "RIOReceive Error: " << gle << endl ;
	exit(0) ;;
	}

	g_addrRioBufIndex++ ;

	}
	::LeaveCriticalSection(&g_criticalSection) ;

	}
	else
	break ;

	}
	}


	return 0 ;
	}


	template <typename TV, typename TM>
	inline TV RoundDown(TV Value, TM Multiple)
	{
	return((Value / Multiple) * Multiple);
	}

	template <typename TV, typename TM>
	inline TV RoundUp(TV Value, TM Multiple)
	{
	return(RoundDown(Value, Multiple) + (((Value % Multiple) > 0) ? Multiple : 0));
	}


	char *AllocateBufferSpace(const DWORD bufSize, const DWORD bufCount, DWORD& totalBufferSize, DWORD& totalBufferCount)
	{
	SYSTEM_INFO systemInfo ;

	::GetSystemInfo(&systemInfo) ;

	const unsigned __int64 granularity = systemInfo.dwAllocationGranularity ;

	const unsigned __int64 desiredSize = bufSize * bufCount ;

	unsigned __int64 actualSize = RoundUp(desiredSize, granularity) ;

	if (actualSize > std::numeric_limits<DWORD>::max())
	{
	actualSize = (std::numeric_limits<DWORD>::max() / granularity) * granularity ;
	}

	totalBufferCount = std::min<DWORD>(bufCount, static_cast<DWORD>(actualSize / bufSize)) ;

	totalBufferSize = static_cast<DWORD>(actualSize) ;

	char pBuffer = reinterpret_cast<char >(VirtualAllocEx(GetCurrentProcess(), 0, totalBufferSize, MEM_COMMIT \| MEM_RESERVE, PAGE_READWRITE)) ;

	if (pBuffer == 0)
	{
	const DWORD gle = ::GetLastError() ;
	cout << "VirtualAllocEx Error: " << gle << endl ;
	exit(0) ;
	}

	return pBuffer;
	}