KDDI Fx0 hackathon
Websocket_Sample for MurataTypeYD
SNICInterface_mod/Socket/UDPSocket.cpp
- Committer:
- komoritan
- Date:
- 2015-03-12
- Revision:
- 1:b5ac0f971f43
- Parent:
- 0:14bd24b5a77f
File content as of revision 1:b5ac0f971f43:
/* Copyright (C) 2012 mbed.org, MIT License
*
* Permission is hereby granted, free of charge, to any person obtaining a copy of this software
* and associated documentation files (the "Software"), to deal in the Software without restriction,
* including without limitation the rights to use, copy, modify, merge, publish, distribute,
* sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in all copies or
* substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING
* BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
* NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM,
* DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
/* Copyright (C) 2014 Murata Manufacturing Co.,Ltd., MIT License
* port to the muRata, SWITCH SCIENCE Wi-FI module TypeYD SNIC-UART.
*/
#include "Socket/UDPSocket.h"
#include <cstring>
UDPSocket::UDPSocket() {
}
UDPSocket::~UDPSocket()
{
}
int UDPSocket::init(void)
{
return 0;
}
// Server initialization
int UDPSocket::bind(short port)
{
int ret;
C_SNIC_Core *snic_core_p = C_SNIC_Core::getInstance();
C_SNIC_UartCommandManager *uartCmdMgr_p = snic_core_p->getUartCommand();
FUNC_IN();
// Get local ip address.
// Get buffer for response payload from MemoryPool
tagMEMPOOL_BLOCK_T *payload_buf_p = snic_core_p->allocCmdBuf();
if( payload_buf_p == NULL )
{
DEBUG_PRINT("UDP bind payload_buf_p NULL\r\n");
FUNC_OUT();
return -1;
}
C_SNIC_Core::tagSNIC_GET_DHCP_INFO_REQ_T req;
// Make request
req.cmd_sid = UART_CMD_SID_SNIC_GET_DHCP_INFO_REQ;
req.seq = mUartRequestSeq++;
req.interface = 0;
unsigned char *command_array_p = snic_core_p->getCommandBuf();
unsigned int command_len;
// Preparation of command
command_len = snic_core_p->preparationSendCommand( UART_CMD_ID_SNIC, req.cmd_sid, (unsigned char *)&req
, sizeof(C_SNIC_Core::tagSNIC_GET_DHCP_INFO_REQ_T), payload_buf_p->buf, command_array_p );
// Send uart command request
snic_core_p->sendUart( command_len, command_array_p );
// Wait UART response
ret = uartCmdMgr_p->wait();
if( ret != 0 )
{
DEBUG_PRINT( "UDP bind failed\r\n" );
snic_core_p->freeCmdBuf( payload_buf_p );
FUNC_OUT();
return -1;
}
if( uartCmdMgr_p->getCommandStatus() != UART_CMD_RES_SNIC_SUCCESS )
{
DEBUG_PRINT("UDP bind status:%02x\r\n", uartCmdMgr_p->getCommandStatus());
snic_core_p->freeCmdBuf( payload_buf_p );
FUNC_OUT();
return -1;
}
unsigned int local_addr = (payload_buf_p->buf[9] << 24)
| (payload_buf_p->buf[10] << 16)
| (payload_buf_p->buf[11] << 8)
| (payload_buf_p->buf[12]);
C_SNIC_Core::tagSNIC_UDP_CREATE_SOCKET_REQ_T create_req;
// Make request
create_req.cmd_sid = UART_CMD_SID_SNIC_UDP_CREATE_SOCKET_REQ;
create_req.seq = mUartRequestSeq++;
create_req.bind = 1;
// set ip addr ( byte order )
C_SNIC_UartMsgUtil::convertIntToByteAdday( local_addr, (char *)create_req.local_addr );
create_req.local_port[0] = ( (port & 0xFF00) >> 8 );
create_req.local_port[1] = (port & 0xFF);
// Preparation of command
command_len = snic_core_p->preparationSendCommand( UART_CMD_ID_SNIC, create_req.cmd_sid, (unsigned char *)&create_req
, sizeof(C_SNIC_Core::tagSNIC_UDP_CREATE_SOCKET_REQ_T), payload_buf_p->buf, command_array_p );
// Send uart command request
snic_core_p->sendUart( command_len, command_array_p );
// Wait UART response
ret = uartCmdMgr_p->wait();
if( ret != 0 )
{
DEBUG_PRINT( "UDP bind failed\r\n" );
snic_core_p->freeCmdBuf( payload_buf_p );
FUNC_OUT();
return -1;
}
if( uartCmdMgr_p->getCommandStatus() != 0 )
{
DEBUG_PRINT("UDP bind status:%02x\r\n", uartCmdMgr_p->getCommandStatus());
snic_core_p->freeCmdBuf( payload_buf_p );
FUNC_OUT();
return -1;
}
mSocketID = payload_buf_p->buf[3];
// Initialize connection information
C_SNIC_Core::tagCONNECT_INFO_T *con_info_p = snic_core_p->getConnectInfo( mSocketID );
if( con_info_p->recvbuf_p == NULL )
{
DEBUG_PRINT( "create recv buffer[socket:%d]\r\n", mSocketID);
con_info_p->recvbuf_p = new CircBuffer<char>(SNIC_UART_RECVBUF_SIZE);
}
con_info_p->is_connected = true;
con_info_p->is_received = false;
C_SNIC_Core::tagSNIC_UDP_START_RECV_REQ_T recv_start_req;
// Make request
recv_start_req.cmd_sid = UART_CMD_SID_SNIC_UDP_START_RECV_REQ;
recv_start_req.seq = mUartRequestSeq++;
recv_start_req.socket_id = mSocketID;
recv_start_req.recv_bufsize[0] = ( (SNIC_UART_RECVBUF_SIZE & 0xFF00) >> 8 );
recv_start_req.recv_bufsize[1] = (SNIC_UART_RECVBUF_SIZE & 0xFF);
// Preparation of command
command_len = snic_core_p->preparationSendCommand( UART_CMD_ID_SNIC, recv_start_req.cmd_sid, (unsigned char *)&recv_start_req
, sizeof(C_SNIC_Core::tagSNIC_UDP_START_RECV_REQ_T), payload_buf_p->buf, command_array_p );
// Send uart command request
snic_core_p->sendUart( command_len, command_array_p );
// Wait UART response
ret = uartCmdMgr_p->wait();
if( ret != 0 )
{
DEBUG_PRINT( "UDP recv start failed\r\n" );
snic_core_p->freeCmdBuf( payload_buf_p );
FUNC_OUT();
return -1;
}
if( uartCmdMgr_p->getCommandStatus() != 0 )
{
DEBUG_PRINT("UDP recv start status:%02x\r\n", uartCmdMgr_p->getCommandStatus());
snic_core_p->freeCmdBuf( payload_buf_p );
FUNC_OUT();
return -1;
}
snic_core_p->freeCmdBuf( payload_buf_p );
FUNC_OUT();
return 0;
}
// -1 if unsuccessful, else number of bytes written
int UDPSocket::sendTo(Endpoint &remote, char *packet, int length)
{
C_SNIC_Core *snic_core_p = C_SNIC_Core::getInstance();
C_SNIC_UartCommandManager *uartCmdMgr_p = snic_core_p->getUartCommand();
osThreadId tid = Thread::gettid();
// pc.printf("send[%08x] len:%d(%04x)\r\n", tid, length, length);
#if 0 // TODO: Not wait for command response(Tentative)
snic_core_p->lockAPI();
#endif
FUNC_IN();
#if 0 // TODO: Not wait for command response(Tentative)
// Get buffer for response payload from MemoryPool
tagMEMPOOL_BLOCK_T *payload_buf_p = snic_core_p->allocCmdBuf();
if( payload_buf_p == NULL )
{
DEBUG_PRINT("connect payload_buf_p NULL\r\n");
FUNC_OUT();
snic_core_p->unlockAPI();
return -1;
}
#endif
C_SNIC_Core::tagSNIC_UDP_SEND_FROM_SOCKET_REQ_T req;
// Make request
req.cmd_sid = UART_CMD_SID_SNIC_UDP_SEND_FROM_SOCKET_REQ;
req.seq = mUartRequestSeq++;
int addr_temp;
addr_temp = C_SNIC_UartMsgUtil::addrToInteger( remote.get_address() );
C_SNIC_UartMsgUtil::convertIntToByteAdday( addr_temp, (char *)req.remote_ip );
req.remote_port[0] = ( (remote.get_port() & 0xFF00) >> 8 );
req.remote_port[1] = (remote.get_port() & 0xFF);
req.payload_len[0] = ( (length & 0xFF00) >> 8 );
req.payload_len[1] = (length & 0xFF);
req.socket_id = mSocketID;
req.connection_mode = 1;
// Initialize connection information
C_SNIC_Core::tagCONNECT_INFO_T *con_info_p = snic_core_p->getConnectInfo( mSocketID );
if( con_info_p != NULL )
{
con_info_p->from_ip = addr_temp;
con_info_p->from_port = remote.get_port();
}
int req_size = sizeof(C_SNIC_Core::tagSNIC_UDP_SEND_FROM_SOCKET_REQ_T);
char *send_buf_p = getSocketSendBuf();
memcpy( send_buf_p, &req, req_size );
memcpy( &send_buf_p[req_size], packet, length );
unsigned char *command_array_p = snic_core_p->getCommandBuf();
unsigned int command_len;
// Make all command request
command_len = C_SNIC_UartMsgUtil::makeRequest( UART_CMD_ID_SNIC, (unsigned char *)send_buf_p, req_size + length, command_array_p );
// Send uart command request
snic_core_p->sendUart( command_len, command_array_p );
#if 0 // TODO: Not wait for command response(Tentative)
// Wait UART response
int ret = uartCmdMgr_p->wait();
if( ret != 0 )
{
DEBUG_PRINT( "send failed\r\n" );
snic_core_p->freeCmdBuf( payload_buf_p );
FUNC_OUT();
snic_core_p->unlockAPI();
return -1;
}
if( uartCmdMgr_p->getCommandStatus() != UART_CMD_RES_SNIC_SUCCESS )
{
DEBUG_PRINT("send status:%02x\r\n", uartCmdMgr_p->getCommandStatus());
snic_core_p->freeCmdBuf( payload_buf_p );
FUNC_OUT();
snic_core_p->unlockAPI();
return -1;
}
snic_core_p->freeCmdBuf( payload_buf_p );
#endif
FUNC_OUT();
#if 0 // TODO: Not wait for command response(Tentative)
snic_core_p->unlockAPI();
#endif
// SNIC_SEND_FROM_SOCKET_REQ
wait(0.05);
return length;
// return 0;
}
// -1 if unsuccessful, else number of bytes received
int UDPSocket::receiveFrom(Endpoint &remote, char *data_p, int length)
{
FUNC_IN();
if( (data_p == NULL) || (length < 1) )
{
DEBUG_PRINT("UDPSocket::receiveFrom parameter error\r\n");
FUNC_OUT();
return -1;
}
C_SNIC_Core *snic_core_p = C_SNIC_Core::getInstance();
// Initialize connection information
C_SNIC_Core::tagCONNECT_INFO_T *con_info_p = snic_core_p->getConnectInfo( mSocketID );
if( con_info_p->recvbuf_p == NULL )
{
DEBUG_PRINT("UDPSocket::receiveFrom Conncection info error\r\n");
FUNC_OUT();
return -1;
}
char remote_ip[20] = {'\0'};
sprintf( remote_ip, "%d.%d.%d.%d"
, (con_info_p->from_ip >>24) & 0x000000ff
, (con_info_p->from_ip >>16) & 0x000000ff
, (con_info_p->from_ip >>8) & 0x000000ff
, (con_info_p->from_ip) & 0x000000ff );
remote.set_address( remote_ip, con_info_p->from_port );
con_info_p->mutex.lock();
con_info_p->is_receive_complete = true;
con_info_p->mutex.unlock();
if( con_info_p->is_received == false )
{
// Try receive
Thread::yield();
if( con_info_p->is_received == false )
{
// No data received.
FUNC_OUT();
return 0;
}
}
// Get packet data from buffer for receive.
int i;
for (i = 0; i < length; i ++)
{
if (con_info_p->recvbuf_p->dequeue(&data_p[i]) == false)
{
break;
}
}
if( con_info_p->recvbuf_p->isEmpty() )
{
con_info_p->mutex.lock();
con_info_p->is_received = false;
con_info_p->mutex.unlock();
}
FUNC_OUT();
return i;
}