btif/src/btif_sock_sco.cc - platform/system/bt - Gitiles

 /******************************************************************************
  *
  *  Copyright 2014 Google, Inc.
  *
  *  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:
  *
  *  http://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.
  *
  ******************************************************************************/

 #define LOG_TAG "bt_btif_sock_sco"

 #include <base/logging.h>
 #include <errno.h>
 #include <pthread.h>
 #include <string.h>
 #include <sys/socket.h>
 #include <sys/types.h>
 #include <unistd.h>

 #include <mutex>

 #include <hardware/bluetooth.h>
 #include <hardware/bt_sock.h>

 #include "btif_common.h"
 #include "device/include/esco_parameters.h"
 #include "osi/include/allocator.h"
 #include "osi/include/list.h"
 #include "osi/include/log.h"
 #include "osi/include/osi.h"
 #include "osi/include/socket.h"
 #include "osi/include/thread.h"

 // This module provides a socket abstraction for SCO connections to a higher
 // layer. It returns file descriptors representing two types of sockets:
 // listening (server) and connected (client) sockets. No SCO data is
 // transferred across these sockets; instead, they are used to manage SCO
 // connection lifecycles while the data routing takes place over the I2S bus.
 //
 // This code bridges the gap between the BTM layer, which implements SCO
 // connections, and the Android HAL. It adapts the BTM representation of SCO
 // connections (integer handles) to a file descriptor representation usable by
 // Android's LocalSocket implementation.
 //
 // Sample flow for an incoming connection:
 //   btsock_sco_listen()       - listen for incoming connections
 //   connection_request_cb()   - incoming connection request from remote host
 //   connect_completed_cb()    - connection successfully established
 //   socket_read_ready_cb()    - local host closed SCO socket
 //   disconnect_completed_cb() - connection terminated

 typedef struct {
   uint16_t sco_handle;
   socket_t* socket;
   bool connect_completed;
 } sco_socket_t;

 static sco_socket_t* sco_socket_establish_locked(bool is_listening,
                                                  const RawAddress* bd_addr,
                                                  int* sock_fd);
 static sco_socket_t* sco_socket_new(void);
 static void sco_socket_free_locked(sco_socket_t* socket);
 static sco_socket_t* sco_socket_find_locked(uint16_t sco_handle);
 static void connection_request_cb(tBTM_ESCO_EVT event,
                                   tBTM_ESCO_EVT_DATA* data);
 static void connect_completed_cb(uint16_t sco_handle);
 static void disconnect_completed_cb(uint16_t sco_handle);
 static void socket_read_ready_cb(socket_t* socket, void* context);

 // |sco_lock| protects all of the static variables below and
 // calls into the BTM layer.
 static std::mutex sco_lock;
 static list_t* sco_sockets;  // Owns a collection of sco_socket_t objects.
 static sco_socket_t* listen_sco_socket;  // Not owned, do not free.
 static thread_t* thread;                 // Not owned, do not free.

 bt_status_t btsock_sco_init(thread_t* thread_) {
   CHECK(thread_ != NULL);

   sco_sockets = list_new((list_free_cb)sco_socket_free_locked);
   if (!sco_sockets) return BT_STATUS_FAIL;

   thread = thread_;
   enh_esco_params_t params = esco_parameters_for_codec(ESCO_CODEC_CVSD);
   BTM_SetEScoMode(&params);

   return BT_STATUS_SUCCESS;
 }

 bt_status_t btsock_sco_cleanup(void) {
   list_free(sco_sockets);
   sco_sockets = NULL;
   return BT_STATUS_SUCCESS;
 }

 bt_status_t btsock_sco_listen(int* sock_fd, UNUSED_ATTR int flags) {
   CHECK(sock_fd != NULL);

   std::unique_lock<std::mutex> lock(sco_lock);

   sco_socket_t* sco_socket = sco_socket_establish_locked(true, NULL, sock_fd);
   if (!sco_socket) return BT_STATUS_FAIL;

   BTM_RegForEScoEvts(sco_socket->sco_handle, connection_request_cb);
   listen_sco_socket = sco_socket;

   return BT_STATUS_SUCCESS;
 }

 bt_status_t btsock_sco_connect(const RawAddress* bd_addr, int* sock_fd,
                                UNUSED_ATTR int flags) {
   CHECK(bd_addr != NULL);
   CHECK(sock_fd != NULL);

   std::unique_lock<std::mutex> lock(sco_lock);
   sco_socket_t* sco_socket =
       sco_socket_establish_locked(false, bd_addr, sock_fd);

   return (sco_socket != NULL) ? BT_STATUS_SUCCESS : BT_STATUS_FAIL;
 }

 // Must be called with |lock| held.
 static sco_socket_t* sco_socket_establish_locked(bool is_listening,
                                                  const RawAddress* bd_addr,
                                                  int* sock_fd) {
   int pair[2] = {INVALID_FD, INVALID_FD};
   sco_socket_t* sco_socket = NULL;
   socket_t* socket = NULL;
   tBTM_STATUS status;
   enh_esco_params_t params;
   if (socketpair(AF_LOCAL, SOCK_STREAM, 0, pair) == -1) {
     LOG_ERROR(LOG_TAG, "%s unable to allocate socket pair: %s", __func__,
               strerror(errno));
     goto error;
   }

   sco_socket = sco_socket_new();
   if (!sco_socket) {
     LOG_ERROR(LOG_TAG, "%s unable to allocate new SCO socket.", __func__);
     goto error;
   }

   params = esco_parameters_for_codec(ESCO_CODEC_CVSD);
   status = BTM_CreateSco(bd_addr, !is_listening, params.packet_types,
                          &sco_socket->sco_handle, connect_completed_cb,
                          disconnect_completed_cb);
   if (status != BTM_CMD_STARTED) {
     LOG_ERROR(LOG_TAG, "%s unable to create SCO socket: %d", __func__, status);
     goto error;
   }

   socket = socket_new_from_fd(pair[1]);
   if (!socket) {
     LOG_ERROR(LOG_TAG, "%s unable to allocate socket from file descriptor %d.",
               __func__, pair[1]);
     goto error;
   }

   *sock_fd = pair[0];           // Transfer ownership of one end to caller.
   sco_socket->socket = socket;  // Hang on to the other end.
   list_append(sco_sockets, sco_socket);

   socket_register(socket, thread_get_reactor(thread), sco_socket,
                   socket_read_ready_cb, NULL);
   return sco_socket;

 error:;
   if (pair[0] != INVALID_FD) close(pair[0]);
   if (pair[1] != INVALID_FD) close(pair[1]);

   sco_socket_free_locked(sco_socket);
   return NULL;
 }

 static sco_socket_t* sco_socket_new(void) {
   sco_socket_t* sco_socket = (sco_socket_t*)osi_calloc(sizeof(sco_socket_t));
   sco_socket->sco_handle = BTM_INVALID_SCO_INDEX;
   return sco_socket;
 }

 // Must be called with |lock| held except during teardown when we know the
 // socket thread
 // is no longer alive.
 static void sco_socket_free_locked(sco_socket_t* sco_socket) {
   if (!sco_socket) return;

   if (sco_socket->sco_handle != BTM_INVALID_SCO_INDEX)
     BTM_RemoveSco(sco_socket->sco_handle);
   socket_free(sco_socket->socket);
   osi_free(sco_socket);
 }

 // Must be called with |lock| held.
 static sco_socket_t* sco_socket_find_locked(uint16_t sco_handle) {
   for (const list_node_t* node = list_begin(sco_sockets);
        node != list_end(sco_sockets); node = list_next(node)) {
     sco_socket_t* sco_socket = (sco_socket_t*)list_node(node);
     if (sco_socket->sco_handle == sco_handle) return sco_socket;
   }
   return NULL;
 }

 static void connection_request_cb(tBTM_ESCO_EVT event,
                                   tBTM_ESCO_EVT_DATA* data) {
   CHECK(data != NULL);

   // Don't care about change of link parameters, only connection requests.
   if (event != BTM_ESCO_CONN_REQ_EVT) return;

   std::unique_lock<std::mutex> lock(sco_lock);

   const tBTM_ESCO_CONN_REQ_EVT_DATA* conn_data = &data->conn_evt;
   sco_socket_t* sco_socket = sco_socket_find_locked(conn_data->sco_inx);
   int client_fd = INVALID_FD;

   uint16_t temp;
   sco_socket_t* new_sco_socket;

   if (!sco_socket) {
     LOG_ERROR(LOG_TAG, "%s unable to find sco_socket for handle: %hu", __func__,
               conn_data->sco_inx);
     goto error;
   }

   if (sco_socket != listen_sco_socket) {
     LOG_ERROR(
         LOG_TAG,
         "%s received connection request on non-listening socket handle: %hu",
         __func__, conn_data->sco_inx);
     goto error;
   }

   new_sco_socket = sco_socket_establish_locked(true, NULL, &client_fd);
   if (!new_sco_socket) {
     LOG_ERROR(LOG_TAG, "%s unable to allocate new sco_socket.", __func__);
     goto error;
   }

   // Swap socket->sco_handle and new_socket->sco_handle
   temp = sco_socket->sco_handle;
   sco_socket->sco_handle = new_sco_socket->sco_handle;
   new_sco_socket->sco_handle = temp;

   sock_connect_signal_t connect_signal;
   connect_signal.size = sizeof(connect_signal);
   connect_signal.bd_addr = conn_data->bd_addr;
   connect_signal.channel = 0;
   connect_signal.status = 0;

   if (socket_write_and_transfer_fd(sco_socket->socket, &connect_signal,
                                    sizeof(connect_signal),
                                    client_fd) != sizeof(connect_signal)) {
     LOG_ERROR(LOG_TAG,
               "%s unable to send new file descriptor to listening socket.",
               __func__);
     goto error;
   }

   BTM_RegForEScoEvts(listen_sco_socket->sco_handle, connection_request_cb);
   BTM_EScoConnRsp(conn_data->sco_inx, HCI_SUCCESS, NULL);

   return;

 error:;
   if (client_fd != INVALID_FD) close(client_fd);
   BTM_EScoConnRsp(conn_data->sco_inx, HCI_ERR_HOST_REJECT_RESOURCES, NULL);
 }

 static void connect_completed_cb(uint16_t sco_handle) {
   std::unique_lock<std::mutex> lock(sco_lock);

   sco_socket_t* sco_socket = sco_socket_find_locked(sco_handle);
   if (!sco_socket) {
     LOG_ERROR(LOG_TAG, "%s SCO socket not found on connect for handle: %hu",
               __func__, sco_handle);
     return;
   }

   // If sco_socket->socket was closed, we should tear down because there is no
   // app-level
   // interest in the SCO socket.
   if (!sco_socket->socket) {
     BTM_RemoveSco(sco_socket->sco_handle);
     list_remove(sco_sockets, sco_socket);
     return;
   }

   sco_socket->connect_completed = true;
 }

 static void disconnect_completed_cb(uint16_t sco_handle) {
   std::unique_lock<std::mutex> lock(sco_lock);

   sco_socket_t* sco_socket = sco_socket_find_locked(sco_handle);
   if (!sco_socket) {
     LOG_ERROR(LOG_TAG, "%s SCO socket not found on disconnect for handle: %hu",
               __func__, sco_handle);
     return;
   }

   list_remove(sco_sockets, sco_socket);
 }

 static void socket_read_ready_cb(UNUSED_ATTR socket_t* socket, void* context) {
   std::unique_lock<std::mutex> lock(sco_lock);

   sco_socket_t* sco_socket = (sco_socket_t*)context;
   socket_free(sco_socket->socket);
   sco_socket->socket = NULL;

   // Defer the underlying disconnect until the connection completes
   // since the BTM code doesn't behave correctly when a disconnect
   // request is issued while a connect is in progress. The fact that
   // sco_socket->socket == NULL indicates to the connect callback
   // routine that the socket is no longer desired and should be torn
   // down.
   if (sco_socket->connect_completed || sco_socket == listen_sco_socket) {
     if (BTM_RemoveSco(sco_socket->sco_handle) == BTM_SUCCESS)
       list_remove(sco_sockets, sco_socket);
     if (sco_socket == listen_sco_socket) listen_sco_socket = NULL;
   }
 }
	/******************************************************************************
	*
	* Copyright 2014 Google, Inc.
	*
	* 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:
	*
	* http://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.
	*
	******************************************************************************/

	#define LOG_TAG "bt_btif_sock_sco"

	#include <base/logging.h>
	#include <errno.h>
	#include <pthread.h>
	#include <string.h>
	#include <sys/socket.h>
	#include <sys/types.h>
	#include <unistd.h>

	#include <mutex>

	#include <hardware/bluetooth.h>
	#include <hardware/bt_sock.h>

	#include "btif_common.h"
	#include "device/include/esco_parameters.h"
	#include "osi/include/allocator.h"
	#include "osi/include/list.h"
	#include "osi/include/log.h"
	#include "osi/include/osi.h"
	#include "osi/include/socket.h"
	#include "osi/include/thread.h"

	// This module provides a socket abstraction for SCO connections to a higher
	// layer. It returns file descriptors representing two types of sockets:
	// listening (server) and connected (client) sockets. No SCO data is
	// transferred across these sockets; instead, they are used to manage SCO
	// connection lifecycles while the data routing takes place over the I2S bus.
	//
	// This code bridges the gap between the BTM layer, which implements SCO
	// connections, and the Android HAL. It adapts the BTM representation of SCO
	// connections (integer handles) to a file descriptor representation usable by
	// Android's LocalSocket implementation.
	//
	// Sample flow for an incoming connection:
	// btsock_sco_listen() - listen for incoming connections
	// connection_request_cb() - incoming connection request from remote host
	// connect_completed_cb() - connection successfully established
	// socket_read_ready_cb() - local host closed SCO socket
	// disconnect_completed_cb() - connection terminated

	typedef struct {
	uint16_t sco_handle;
	socket_t* socket;
	bool connect_completed;
	} sco_socket_t;

	static sco_socket_t* sco_socket_establish_locked(bool is_listening,
	const RawAddress* bd_addr,
	int* sock_fd);
	static sco_socket_t* sco_socket_new(void);
	static void sco_socket_free_locked(sco_socket_t* socket);
	static sco_socket_t* sco_socket_find_locked(uint16_t sco_handle);
	static void connection_request_cb(tBTM_ESCO_EVT event,
	tBTM_ESCO_EVT_DATA* data);
	static void connect_completed_cb(uint16_t sco_handle);
	static void disconnect_completed_cb(uint16_t sco_handle);
	static void socket_read_ready_cb(socket_t* socket, void* context);

	// \|sco_lock\| protects all of the static variables below and
	// calls into the BTM layer.
	static std::mutex sco_lock;
	static list_t* sco_sockets; // Owns a collection of sco_socket_t objects.
	static sco_socket_t* listen_sco_socket; // Not owned, do not free.
	static thread_t* thread; // Not owned, do not free.

	bt_status_t btsock_sco_init(thread_t* thread_) {
	CHECK(thread_ != NULL);

	sco_sockets = list_new((list_free_cb)sco_socket_free_locked);
	if (!sco_sockets) return BT_STATUS_FAIL;

	thread = thread_;
	enh_esco_params_t params = esco_parameters_for_codec(ESCO_CODEC_CVSD);
	BTM_SetEScoMode(&params);

	return BT_STATUS_SUCCESS;
	}

	bt_status_t btsock_sco_cleanup(void) {
	list_free(sco_sockets);
	sco_sockets = NULL;
	return BT_STATUS_SUCCESS;
	}

	bt_status_t btsock_sco_listen(int* sock_fd, UNUSED_ATTR int flags) {
	CHECK(sock_fd != NULL);

	std::unique_lock<std::mutex> lock(sco_lock);

	sco_socket_t* sco_socket = sco_socket_establish_locked(true, NULL, sock_fd);
	if (!sco_socket) return BT_STATUS_FAIL;

	BTM_RegForEScoEvts(sco_socket->sco_handle, connection_request_cb);
	listen_sco_socket = sco_socket;

	return BT_STATUS_SUCCESS;
	}

	bt_status_t btsock_sco_connect(const RawAddress* bd_addr, int* sock_fd,
	UNUSED_ATTR int flags) {
	CHECK(bd_addr != NULL);
	CHECK(sock_fd != NULL);

	std::unique_lock<std::mutex> lock(sco_lock);
	sco_socket_t* sco_socket =
	sco_socket_establish_locked(false, bd_addr, sock_fd);

	return (sco_socket != NULL) ? BT_STATUS_SUCCESS : BT_STATUS_FAIL;
	}

	// Must be called with \|lock\| held.
	static sco_socket_t* sco_socket_establish_locked(bool is_listening,
	const RawAddress* bd_addr,
	int* sock_fd) {
	int pair[2] = {INVALID_FD, INVALID_FD};
	sco_socket_t* sco_socket = NULL;
	socket_t* socket = NULL;
	tBTM_STATUS status;
	enh_esco_params_t params;
	if (socketpair(AF_LOCAL, SOCK_STREAM, 0, pair) == -1) {
	LOG_ERROR(LOG_TAG, "%s unable to allocate socket pair: %s", __func__,
	strerror(errno));
	goto error;
	}

	sco_socket = sco_socket_new();
	if (!sco_socket) {
	LOG_ERROR(LOG_TAG, "%s unable to allocate new SCO socket.", __func__);
	goto error;
	}

	params = esco_parameters_for_codec(ESCO_CODEC_CVSD);
	status = BTM_CreateSco(bd_addr, !is_listening, params.packet_types,
	&sco_socket->sco_handle, connect_completed_cb,
	disconnect_completed_cb);
	if (status != BTM_CMD_STARTED) {
	LOG_ERROR(LOG_TAG, "%s unable to create SCO socket: %d", __func__, status);
	goto error;
	}

	socket = socket_new_from_fd(pair[1]);
	if (!socket) {
	LOG_ERROR(LOG_TAG, "%s unable to allocate socket from file descriptor %d.",
	__func__, pair[1]);
	goto error;
	}

	*sock_fd = pair[0]; // Transfer ownership of one end to caller.
	sco_socket->socket = socket; // Hang on to the other end.
	list_append(sco_sockets, sco_socket);

	socket_register(socket, thread_get_reactor(thread), sco_socket,
	socket_read_ready_cb, NULL);
	return sco_socket;

	error:;
	if (pair[0] != INVALID_FD) close(pair[0]);
	if (pair[1] != INVALID_FD) close(pair[1]);

	sco_socket_free_locked(sco_socket);
	return NULL;
	}

	static sco_socket_t* sco_socket_new(void) {
	sco_socket_t* sco_socket = (sco_socket_t*)osi_calloc(sizeof(sco_socket_t));
	sco_socket->sco_handle = BTM_INVALID_SCO_INDEX;
	return sco_socket;
	}

	// Must be called with \|lock\| held except during teardown when we know the
	// socket thread
	// is no longer alive.
	static void sco_socket_free_locked(sco_socket_t* sco_socket) {
	if (!sco_socket) return;

	if (sco_socket->sco_handle != BTM_INVALID_SCO_INDEX)
	BTM_RemoveSco(sco_socket->sco_handle);
	socket_free(sco_socket->socket);
	osi_free(sco_socket);
	}

	// Must be called with \|lock\| held.
	static sco_socket_t* sco_socket_find_locked(uint16_t sco_handle) {
	for (const list_node_t* node = list_begin(sco_sockets);
	node != list_end(sco_sockets); node = list_next(node)) {
	sco_socket_t* sco_socket = (sco_socket_t*)list_node(node);
	if (sco_socket->sco_handle == sco_handle) return sco_socket;
	}
	return NULL;
	}

	static void connection_request_cb(tBTM_ESCO_EVT event,
	tBTM_ESCO_EVT_DATA* data) {
	CHECK(data != NULL);

	// Don't care about change of link parameters, only connection requests.
	if (event != BTM_ESCO_CONN_REQ_EVT) return;

	std::unique_lock<std::mutex> lock(sco_lock);

	const tBTM_ESCO_CONN_REQ_EVT_DATA* conn_data = &data->conn_evt;
	sco_socket_t* sco_socket = sco_socket_find_locked(conn_data->sco_inx);
	int client_fd = INVALID_FD;

	uint16_t temp;
	sco_socket_t* new_sco_socket;

	if (!sco_socket) {
	LOG_ERROR(LOG_TAG, "%s unable to find sco_socket for handle: %hu", __func__,
	conn_data->sco_inx);
	goto error;
	}

	if (sco_socket != listen_sco_socket) {
	LOG_ERROR(
	LOG_TAG,
	"%s received connection request on non-listening socket handle: %hu",
	__func__, conn_data->sco_inx);
	goto error;
	}

	new_sco_socket = sco_socket_establish_locked(true, NULL, &client_fd);
	if (!new_sco_socket) {
	LOG_ERROR(LOG_TAG, "%s unable to allocate new sco_socket.", __func__);
	goto error;
	}

	// Swap socket->sco_handle and new_socket->sco_handle
	temp = sco_socket->sco_handle;
	sco_socket->sco_handle = new_sco_socket->sco_handle;
	new_sco_socket->sco_handle = temp;

	sock_connect_signal_t connect_signal;
	connect_signal.size = sizeof(connect_signal);
	connect_signal.bd_addr = conn_data->bd_addr;
	connect_signal.channel = 0;
	connect_signal.status = 0;

	if (socket_write_and_transfer_fd(sco_socket->socket, &connect_signal,
	sizeof(connect_signal),
	client_fd) != sizeof(connect_signal)) {
	LOG_ERROR(LOG_TAG,
	"%s unable to send new file descriptor to listening socket.",
	__func__);
	goto error;
	}

	BTM_RegForEScoEvts(listen_sco_socket->sco_handle, connection_request_cb);
	BTM_EScoConnRsp(conn_data->sco_inx, HCI_SUCCESS, NULL);

	return;

	error:;
	if (client_fd != INVALID_FD) close(client_fd);
	BTM_EScoConnRsp(conn_data->sco_inx, HCI_ERR_HOST_REJECT_RESOURCES, NULL);
	}

	static void connect_completed_cb(uint16_t sco_handle) {
	std::unique_lock<std::mutex> lock(sco_lock);

	sco_socket_t* sco_socket = sco_socket_find_locked(sco_handle);
	if (!sco_socket) {
	LOG_ERROR(LOG_TAG, "%s SCO socket not found on connect for handle: %hu",
	__func__, sco_handle);
	return;
	}

	// If sco_socket->socket was closed, we should tear down because there is no
	// app-level
	// interest in the SCO socket.
	if (!sco_socket->socket) {
	BTM_RemoveSco(sco_socket->sco_handle);
	list_remove(sco_sockets, sco_socket);
	return;
	}

	sco_socket->connect_completed = true;
	}

	static void disconnect_completed_cb(uint16_t sco_handle) {
	std::unique_lock<std::mutex> lock(sco_lock);

	sco_socket_t* sco_socket = sco_socket_find_locked(sco_handle);
	if (!sco_socket) {
	LOG_ERROR(LOG_TAG, "%s SCO socket not found on disconnect for handle: %hu",
	__func__, sco_handle);
	return;
	}

	list_remove(sco_sockets, sco_socket);
	}

	static void socket_read_ready_cb(UNUSED_ATTR socket_t* socket, void* context) {
	std::unique_lock<std::mutex> lock(sco_lock);

	sco_socket_t* sco_socket = (sco_socket_t*)context;
	socket_free(sco_socket->socket);
	sco_socket->socket = NULL;

	// Defer the underlying disconnect until the connection completes
	// since the BTM code doesn't behave correctly when a disconnect
	// request is issued while a connect is in progress. The fact that
	// sco_socket->socket == NULL indicates to the connect callback
	// routine that the socket is no longer desired and should be torn
	// down.
	if (sco_socket->connect_completed \|\| sco_socket == listen_sco_socket) {
	if (BTM_RemoveSco(sco_socket->sco_handle) == BTM_SUCCESS)
	list_remove(sco_sockets, sco_socket);
	if (sco_socket == listen_sco_socket) listen_sco_socket = NULL;
	}
	}