SNICInterface for ThingPlug Example
Dependents: ThingPlug_WiFi_Example ThingPlug_WiFi_Example_2
Fork of SNICInterface by
SNIC_WifiInterface.cpp
- Committer:
- kishino
- Date:
- 2014-07-15
- Revision:
- 40:b6b10c22a121
- Parent:
- 39:a1233ca02edf
- Child:
- 43:d80bbb12ffe6
File content as of revision 40:b6b10c22a121:
/* Copyright (C) 2014 Murata Manufacturing Co.,Ltd., MIT License * muRata, SWITCH SCIENCE Wi-FI module TypeYD-SNIC UART. * * 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. */ #include "SNIC_WifiInterface.h" #include "SNIC_UartMsgUtil.h" #define UART_CONNECT_BUF_SIZE 512 unsigned char gCONNECT_BUF[UART_CONNECT_BUF_SIZE]; C_SNIC_WifiInterface::C_SNIC_WifiInterface( PinName tx, PinName rx, PinName cts, PinName rts, PinName reset, PinName alarm, int baud) { mUART_tx = tx; mUART_rx = rx; mUART_cts = cts; mUART_rts = rts;; mUART_baud = baud; mModuleReset = reset; } C_SNIC_WifiInterface::~C_SNIC_WifiInterface() { } int C_SNIC_WifiInterface::init() { C_SNIC_Core *snic_core_p = C_SNIC_Core::getInstance(); C_SNIC_UartCommandManager *uartCmdMgr_p = snic_core_p->getUartCommand(); /* Initialize UART */ snic_core_p->initUart( mUART_tx, mUART_rx, mUART_baud ); /* Module reset */ snic_core_p->resetModule( mModuleReset ); wait(1); /* Initialize SNIC API */ // Get buffer for response payload from MemoryPool tagMEMPOOL_BLOCK_T *payload_buf_p = snic_core_p->allocCmdBuf(); if( payload_buf_p == NULL ) { DEBUG_PRINT("snic_init payload_buf_p NULL\r\n"); return -1; } C_SNIC_Core::tagSNIC_INIT_REQ_T req; // Make request req.cmd_sid = UART_CMD_SID_SNIC_INIT_REQ; req.seq = mUartRequestSeq++; req.buf_size[0] = 0x08; req.buf_size[1] = 0x00; 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_INIT_REQ_T), payload_buf_p->buf, command_array_p ); // Send uart command request snic_core_p->sendUart( command_len, command_array_p ); int ret; // Wait UART response ret = uartCmdMgr_p->wait(); if( ret != 0 ) { DEBUG_PRINT( "snic_init failed\r\n" ); snic_core_p->freeCmdBuf( payload_buf_p ); return -1; } if( uartCmdMgr_p->getCommandStatus() != 0 ) { DEBUG_PRINT("snic_init status:%02x\r\n", uartCmdMgr_p->getCommandStatus()); snic_core_p->freeCmdBuf( payload_buf_p ); return -1; } snic_core_p->freeCmdBuf( payload_buf_p ); return ret; } int C_SNIC_WifiInterface::getFWVersion( unsigned char *version_p ) { C_SNIC_Core *snic_core_p = C_SNIC_Core::getInstance(); C_SNIC_UartCommandManager *uartCmdMgr_p = snic_core_p->getUartCommand(); // Get buffer for response payload from MemoryPool tagMEMPOOL_BLOCK_T *payload_buf_p = snic_core_p->allocCmdBuf(); if( payload_buf_p == NULL ) { DEBUG_PRINT("getFWVersion payload_buf_p NULL\r\n"); return -1; } C_SNIC_Core::tagGEN_FW_VER_GET_REQ_T req; // Make request req.cmd_sid = UART_CMD_SID_GEN_FW_VER_GET_REQ; req.seq = mUartRequestSeq++; 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_GEN, req.cmd_sid, (unsigned char *)&req , sizeof(C_SNIC_Core::tagGEN_FW_VER_GET_REQ_T), payload_buf_p->buf, command_array_p ); int ret; // 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( "getFWversion failed\r\n" ); snic_core_p->freeCmdBuf( payload_buf_p ); return -1; } if( uartCmdMgr_p->getCommandStatus() == 0 ) { unsigned char version_len = payload_buf_p->buf[3]; memcpy( version_p, &payload_buf_p->buf[4], version_len ); } snic_core_p->freeCmdBuf( payload_buf_p ); return 0; } int C_SNIC_WifiInterface::connect(const char *ssid_p, unsigned char ssid_len, E_SECURITY sec_type , const char *sec_key_p, unsigned char sec_key_len) { C_SNIC_Core *snic_core_p = C_SNIC_Core::getInstance(); C_SNIC_UartCommandManager *uartCmdMgr_p = snic_core_p->getUartCommand(); // Parameter check(SSID) if( (ssid_p == NULL) || (ssid_len == 0) ) { DEBUG_PRINT( "connect failed [ parameter NG:SSID ]\r\n" ); return -1; } // Parameter check(Security key) if( (sec_type != e_SEC_OPEN) && ( (sec_key_len == 0) || (sec_key_p == NULL) ) ) { DEBUG_PRINT( "connect failed [ parameter NG:Security key ]\r\n" ); return -1; } // 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"); return -1; } unsigned char *buf = &gCONNECT_BUF[0]; unsigned int buf_len = 0; unsigned int command_len; memset( buf, 0, UART_CONNECT_BUF_SIZE ); // Make request buf[0] = UART_CMD_SID_WIFI_JOIN_REQ; buf_len++; buf[1] = mUartRequestSeq++; buf_len++; // SSID memcpy( &buf[2], ssid_p, ssid_len ); buf_len += ssid_len; buf_len++; // Security mode buf[ buf_len ] = (unsigned char)sec_type; buf_len++; // Security key if( sec_type != e_SEC_OPEN ) { buf[ buf_len ] = sec_key_len; buf_len++; if( sec_key_len > 0 ) { memcpy( &buf[buf_len], sec_key_p, sec_key_len ); buf_len += sec_key_len; } } unsigned char *command_array_p = snic_core_p->getCommandBuf(); // Preparation of command command_len = snic_core_p->preparationSendCommand( UART_CMD_ID_WIFI, UART_CMD_SID_WIFI_JOIN_REQ, buf , buf_len, payload_buf_p->buf, command_array_p ); // Send uart command request snic_core_p->sendUart( command_len, command_array_p ); int ret; // Wait UART response ret = uartCmdMgr_p->wait(); if( ret != 0 ) { DEBUG_PRINT( "join failed\r\n" ); snic_core_p->freeCmdBuf( payload_buf_p ); return -1; } if( (uartCmdMgr_p->getCommandStatus() != 0) && (uartCmdMgr_p->getCommandStatus() != UART_CMD_RES_WIFI_ERR_ALREADY_JOINED) ) { DEBUG_PRINT("join status:%02x\r\n", uartCmdMgr_p->getCommandStatus()); snic_core_p->freeCmdBuf( payload_buf_p ); return -1; } snic_core_p->freeCmdBuf( payload_buf_p ); return ret; } int C_SNIC_WifiInterface::disconnect() { C_SNIC_Core *snic_core_p = C_SNIC_Core::getInstance(); C_SNIC_UartCommandManager *uartCmdMgr_p = snic_core_p->getUartCommand(); // Get buffer for response payload from MemoryPool tagMEMPOOL_BLOCK_T *payload_buf_p = snic_core_p->allocCmdBuf(); if( payload_buf_p == NULL ) { DEBUG_PRINT("disconnect payload_buf_p NULL\r\n"); return -1; } C_SNIC_Core::tagWIFI_DISCONNECT_REQ_T req; // Make request req.cmd_sid = UART_CMD_SID_WIFI_DISCONNECT_REQ; req.seq = mUartRequestSeq++; 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_WIFI, req.cmd_sid, (unsigned char *)&req , sizeof(C_SNIC_Core::tagWIFI_DISCONNECT_REQ_T), payload_buf_p->buf, command_array_p ); // Send uart command request snic_core_p->sendUart( command_len, command_array_p ); int ret; // Wait UART response ret = uartCmdMgr_p->wait(); if( ret != 0 ) { DEBUG_PRINT( "disconnect failed\r\n" ); snic_core_p->freeCmdBuf( payload_buf_p ); return -1; } if( uartCmdMgr_p->getCommandStatus() != 0 ) { DEBUG_PRINT("disconnect status:%02x\r\n", uartCmdMgr_p->getCommandStatus()); ret = -1; } snic_core_p->freeCmdBuf( payload_buf_p ); return ret; } int C_SNIC_WifiInterface::scan( const char *ssid_p, unsigned char *bssid_p , void (*result_handler_p)(tagSCAN_RESULT_T *scan_result) ) { C_SNIC_Core *snic_core_p = C_SNIC_Core::getInstance(); C_SNIC_UartCommandManager *uartCmdMgr_p = snic_core_p->getUartCommand(); // Get buffer for response payload from MemoryPool tagMEMPOOL_BLOCK_T *payload_buf_p = snic_core_p->allocCmdBuf(); if( payload_buf_p == NULL ) { DEBUG_PRINT("scan payload_buf_p NULL\r\n"); return -1; } C_SNIC_Core::tagWIFI_SCAN_REQ_T req; unsigned int buf_len = 0; memset( &req, 0, sizeof(C_SNIC_Core::tagWIFI_SCAN_REQ_T) ); // Make request req.cmd_sid = UART_CMD_SID_WIFI_SCAN_REQ; buf_len++; req.seq = mUartRequestSeq++; buf_len++; // Set scan type(Active scan) req.scan_type = 0; buf_len++; // Set bss type(any) req.bss_type = 2; buf_len++; // Set BSSID if( bssid_p != NULL ) { memcpy( req.bssid, bssid_p, BSSID_MAC_LENTH ); } buf_len += BSSID_MAC_LENTH; // Set channel list(0) req.chan_list = 0; buf_len++; //Set SSID if( ssid_p != NULL ) { strcpy( (char *)req.ssid, ssid_p ); buf_len += strlen(ssid_p); } buf_len++; 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_WIFI, req.cmd_sid, (unsigned char *)&req , buf_len, payload_buf_p->buf, command_array_p ); // Set scan result callback uartCmdMgr_p->setScanResultHandler( result_handler_p ); // Send uart command request snic_core_p->sendUart( command_len, command_array_p ); int ret; // Wait UART response ret = uartCmdMgr_p->wait(); DEBUG_PRINT( "scan wait:%d\r\n", ret ); if( ret != 0 ) { DEBUG_PRINT( "scan failed\r\n" ); snic_core_p->freeCmdBuf( payload_buf_p ); return -1; } if( uartCmdMgr_p->getCommandStatus() != 0 ) { DEBUG_PRINT("scan status:%02x\r\n", uartCmdMgr_p->getCommandStatus()); snic_core_p->freeCmdBuf( payload_buf_p ); return -1; } snic_core_p->freeCmdBuf( payload_buf_p ); return ret; } int C_SNIC_WifiInterface::wifi_on( const char *country_p ) { C_SNIC_Core *snic_core_p = C_SNIC_Core::getInstance(); C_SNIC_UartCommandManager *uartCmdMgr_p = snic_core_p->getUartCommand(); // Parameter check if( country_p == NULL ) { DEBUG_PRINT("wifi_on parameter error\r\n"); return -1; } // Get buffer for response payload from MemoryPool tagMEMPOOL_BLOCK_T *payload_buf_p = snic_core_p->allocCmdBuf(); if( payload_buf_p == NULL ) { DEBUG_PRINT("wifi_on payload_buf_p NULL\r\n"); return -1; } C_SNIC_Core::tagWIFI_ON_REQ_T req; // Make request req.cmd_sid = UART_CMD_SID_WIFI_ON_REQ; req.seq = mUartRequestSeq++; memcpy( req.country, country_p, COUNTRYC_CODE_LENTH ); 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_WIFI, req.cmd_sid, (unsigned char *)&req , sizeof(C_SNIC_Core::tagWIFI_ON_REQ_T), payload_buf_p->buf, command_array_p ); // Send uart command request snic_core_p->sendUart( command_len, command_array_p ); int ret; // Wait UART response ret = uartCmdMgr_p->wait(); if( ret != 0 ) { DEBUG_PRINT( "wifi_on failed\r\n" ); snic_core_p->freeCmdBuf( payload_buf_p ); return -1; } if( uartCmdMgr_p->getCommandStatus() != 0 ) { DEBUG_PRINT("wifi_on status:%02x\r\n", uartCmdMgr_p->getCommandStatus()); snic_core_p->freeCmdBuf( payload_buf_p ); return -1; } snic_core_p->freeCmdBuf( payload_buf_p ); return ret; } int C_SNIC_WifiInterface::wifi_off() { C_SNIC_Core *snic_core_p = C_SNIC_Core::getInstance(); C_SNIC_UartCommandManager *uartCmdMgr_p = snic_core_p->getUartCommand(); // Get buffer for response payload from MemoryPool tagMEMPOOL_BLOCK_T *payload_buf_p = snic_core_p->allocCmdBuf(); if( payload_buf_p == NULL ) { DEBUG_PRINT("wifi_off payload_buf_p NULL\r\n"); return -1; } C_SNIC_Core::tagWIFI_OFF_REQ_T req; // Make request req.cmd_sid = UART_CMD_SID_WIFI_OFF_REQ; req.seq = mUartRequestSeq++; 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_WIFI, req.cmd_sid, (unsigned char *)&req , sizeof(C_SNIC_Core::tagWIFI_OFF_REQ_T), payload_buf_p->buf, command_array_p ); // Send uart command request snic_core_p->sendUart( command_len, command_array_p ); int ret; // Wait UART response ret = uartCmdMgr_p->wait(); if( ret != 0 ) { DEBUG_PRINT( "wifi_off failed\r\n" ); snic_core_p->freeCmdBuf( payload_buf_p ); return -1; } if( uartCmdMgr_p->getCommandStatus() != 0 ) { DEBUG_PRINT("wifi_off status:%02x\r\n", uartCmdMgr_p->getCommandStatus()); snic_core_p->freeCmdBuf( payload_buf_p ); return -1; } snic_core_p->freeCmdBuf( payload_buf_p ); return ret; } int C_SNIC_WifiInterface::getRssi( signed char *rssi_p ) { C_SNIC_Core *snic_core_p = C_SNIC_Core::getInstance(); C_SNIC_UartCommandManager *uartCmdMgr_p = snic_core_p->getUartCommand(); if( rssi_p == NULL ) { DEBUG_PRINT("getRssi parameter error\r\n"); return -1; } // Get buffer for response payload from MemoryPool tagMEMPOOL_BLOCK_T *payload_buf_p = snic_core_p->allocCmdBuf(); if( payload_buf_p == NULL ) { DEBUG_PRINT("getRssi payload_buf_p NULL\r\n"); return -1; } C_SNIC_Core::tagWIFI_GET_STA_RSSI_REQ_T req; // Make request req.cmd_sid = UART_CMD_SID_WIFI_GET_STA_RSSI_REQ; req.seq = mUartRequestSeq++; unsigned char *command_array_p = snic_core_p->getCommandBuf(); unsigned int command_len; command_len = snic_core_p->preparationSendCommand( UART_CMD_ID_WIFI, req.cmd_sid, (unsigned char *)&req , sizeof(C_SNIC_Core::tagWIFI_GET_STA_RSSI_REQ_T), payload_buf_p->buf, command_array_p ); int ret; // 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( "getRssi failed\r\n" ); snic_core_p->freeCmdBuf( payload_buf_p ); return -1; } *rssi_p = (signed char)payload_buf_p->buf[2]; snic_core_p->freeCmdBuf( payload_buf_p ); return 0; } int C_SNIC_WifiInterface::getWifiStatus( tagWIFI_STATUS_T *status_p) { C_SNIC_Core *snic_core_p = C_SNIC_Core::getInstance(); C_SNIC_UartCommandManager *uartCmdMgr_p = snic_core_p->getUartCommand(); if( status_p == NULL ) { DEBUG_PRINT("getWifiStatus parameter error\r\n"); return -1; } // Get buffer for response payload from MemoryPool tagMEMPOOL_BLOCK_T *payload_buf_p = snic_core_p->allocCmdBuf(); if( payload_buf_p == NULL ) { DEBUG_PRINT("getWifiStatus payload_buf_p NULL\r\n"); return -1; } C_SNIC_Core::tagWIFI_GET_STATUS_REQ_T req; // Make request req.cmd_sid = UART_CMD_SID_WIFI_GET_STATUS_REQ; req.seq = mUartRequestSeq++; req.interface = 0; unsigned char *command_array_p = snic_core_p->getCommandBuf(); unsigned int command_len; command_len = snic_core_p->preparationSendCommand( UART_CMD_ID_WIFI, req.cmd_sid, (unsigned char *)&req , sizeof(C_SNIC_Core::tagWIFI_GET_STATUS_REQ_T), payload_buf_p->buf, command_array_p ); // Send uart command request snic_core_p->sendUart( command_len, command_array_p ); int ret; // Wait UART response ret = uartCmdMgr_p->wait(); if( ret != 0 ) { DEBUG_PRINT( "getWifiStatus failed\r\n" ); snic_core_p->freeCmdBuf( payload_buf_p ); return -1; } // set status status_p->status = (E_WIFI_STATUS)payload_buf_p->buf[2]; // set Mac address if( status_p->status != e_STATUS_OFF ) { memcpy( status_p->mac_address, &payload_buf_p->buf[3], BSSID_MAC_LENTH ); } // set SSID if( ( status_p->status == e_STA_JOINED ) || ( status_p->status == e_AP_STARTED ) ) { memcpy( status_p->ssid, &payload_buf_p->buf[9], strlen( (char *)&payload_buf_p->buf[9]) ); } snic_core_p->freeCmdBuf( payload_buf_p ); return 0; } int C_SNIC_WifiInterface::setIPConfig( bool is_DHCP , const char *ip_p, const char *mask_p, const char *gateway_p ) { // Parameter check if( is_DHCP == false ) { if( (ip_p == NULL) || (mask_p == NULL) ||(gateway_p == NULL) ) { DEBUG_PRINT("setIPConfig parameter error\r\n"); return -1; } } C_SNIC_Core *snic_core_p = C_SNIC_Core::getInstance(); C_SNIC_UartCommandManager *uartCmdMgr_p = snic_core_p->getUartCommand(); // Get buffer for response payload from MemoryPool tagMEMPOOL_BLOCK_T *payload_buf_p = snic_core_p->allocCmdBuf(); if( payload_buf_p == NULL ) { DEBUG_PRINT("setIPConfig payload_buf_p NULL\r\n"); return -1; } unsigned char *command_array_p = snic_core_p->getCommandBuf(); unsigned int command_len; if( is_DHCP == true ) { C_SNIC_Core::tagSNIC_IP_CONFIG_REQ_DHCP_T req; // Make request req.cmd_sid = UART_CMD_SID_SNIC_IP_CONFIG_REQ; req.seq = mUartRequestSeq++; req.interface = 0; req.dhcp = 1; // Preparation of command command_len = snic_core_p->preparationSendCommand( UART_CMD_ID_SNIC, req.cmd_sid, (unsigned char *)&req , sizeof(C_SNIC_Core::tagSNIC_IP_CONFIG_REQ_DHCP_T), payload_buf_p->buf, command_array_p ); } else { C_SNIC_Core::tagSNIC_IP_CONFIG_REQ_STATIC_T req; // Make request req.cmd_sid = UART_CMD_SID_SNIC_IP_CONFIG_REQ; req.seq = mUartRequestSeq++; req.interface = 0; req.dhcp = 0; // Set paramter of address int addr_temp; addr_temp = C_SNIC_UartMsgUtil::addrToInteger( ip_p ); C_SNIC_UartMsgUtil::convertIntToByteAdday( addr_temp, (char *)req.ip_addr ); addr_temp = C_SNIC_UartMsgUtil::addrToInteger( mask_p ); C_SNIC_UartMsgUtil::convertIntToByteAdday( addr_temp, (char *)req.netmask ); addr_temp = C_SNIC_UartMsgUtil::addrToInteger( gateway_p ); C_SNIC_UartMsgUtil::convertIntToByteAdday( addr_temp, (char *)req.gateway ); // Preparation of command command_len = snic_core_p->preparationSendCommand( UART_CMD_ID_SNIC, req.cmd_sid, (unsigned char *)&req , sizeof(C_SNIC_Core::tagSNIC_IP_CONFIG_REQ_STATIC_T), payload_buf_p->buf, command_array_p ); } // Send uart command request snic_core_p->sendUart( command_len, command_array_p ); int ret; // Wait UART response ret = uartCmdMgr_p->wait(); if( ret != 0 ) { DEBUG_PRINT( "setIPConfig failed\r\n" ); snic_core_p->freeCmdBuf( payload_buf_p ); return -1; } if( uartCmdMgr_p->getCommandStatus() != 0 ) { DEBUG_PRINT("setIPConfig status:%02x\r\n", uartCmdMgr_p->getCommandStatus()); snic_core_p->freeCmdBuf( payload_buf_p ); return -1; } snic_core_p->freeCmdBuf( payload_buf_p ); return ret; }