/* Please contribute your ideas! See http://dev.ardupilot.org for details This program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ /* SerialManager allows defining the protocol and baud rates for the available serial ports and provides helper functions so objects (like a gimbal) can find which serial port they should use */ #include #include "AP_SerialManager.h" extern const AP_HAL::HAL& hal; #ifdef HAL_SERIAL5_PROTOCOL #define SERIAL5_PROTOCOL HAL_SERIAL5_PROTOCOL #define SERIAL5_BAUD HAL_SERIAL5_BAUD #elif defined(CONFIG_ARCH_BOARD_PX4FMU_V4) #define SERIAL5_PROTOCOL SerialProtocol_MAVLink #define SERIAL5_BAUD 921600 #else #define SERIAL5_PROTOCOL SerialProtocol_None #define SERIAL5_BAUD AP_SERIALMANAGER_MAVLINK_BAUD/1000 #endif #ifdef HAL_SERIAL2_PROTOCOL #define SERIAL2_PROTOCOL_DEFAULT HAL_SERIAL2_PROTOCOL #else #define SERIAL2_PROTOCOL_DEFAULT SerialProtocol_MAVLink #endif #ifndef HAL_SERIAL6_PROTOCOL #define SERIAL6_PROTOCOL SerialProtocol_None #define SERIAL6_BAUD AP_SERIALMANAGER_MAVLINK_BAUD/1000 #endif const AP_Param::GroupInfo AP_SerialManager::var_info[] = { // @Param: 0_BAUD // @DisplayName: Serial0 baud rate // @Description: The baud rate used on the USB console. The APM2 can support all baudrates up to 115, and also can support 500. The PX4 can support rates of up to 1500. If you setup a rate you cannot support on APM2 and then can't connect to your board you should load a firmware from a different vehicle type. That will reset all your parameters to defaults. // @Values: 1:1200,2:2400,4:4800,9:9600,19:19200,38:38400,57:57600,111:111100,115:115200,256:256000,460:460800,500:500000,921:921600,1500:1500000 // @User: Standard AP_GROUPINFO("0_BAUD", 0, AP_SerialManager, state[0].baud, AP_SERIALMANAGER_CONSOLE_BAUD/1000), // @Param: 0_PROTOCOL // @DisplayName: Console protocol selection // @Description: Control what protocol to use on the console. // @Values: 1:MAVlink1, 2:MAVLink2 // @User: Standard // @RebootRequired: True AP_GROUPINFO("0_PROTOCOL", 11, AP_SerialManager, state[0].protocol, SerialProtocol_MAVLink2), // @Param: 1_PROTOCOL // @DisplayName: Telem1 protocol selection // @Description: Control what protocol to use on the Telem1 port. Note that the Frsky options require external converter hardware. See the wiki for details. // @Values: -1:None, 1:MAVLink1, 2:MAVLink2, 3:Frsky D, 4:Frsky SPort, 5:GPS, 7:Alexmos Gimbal Serial, 8:SToRM32 Gimbal Serial, 9:Rangefinder, 10:FrSky SPort Passthrough (OpenTX), 11:Lidar360, 13:Beacon, 14:Volz servo out, 15:SBus servo out, 16:ESC Telemetry, 17:Devo Telemetry, 18:OpticalFlow, 19:RobotisServo // @User: Standard // @RebootRequired: True AP_GROUPINFO("1_PROTOCOL", 1, AP_SerialManager, state[1].protocol, SerialProtocol_MAVLink), // @Param: 1_BAUD // @DisplayName: Telem1 Baud Rate // @Description: The baud rate used on the Telem1 port. The APM2 can support all baudrates up to 115, and also can support 500. The PX4 can support rates of up to 1500. If you setup a rate you cannot support on APM2 and then can't connect to your board you should load a firmware from a different vehicle type. That will reset all your parameters to defaults. // @Values: 1:1200,2:2400,4:4800,9:9600,19:19200,38:38400,57:57600,111:111100,115:115200,256:256000,500:500000,921:921600,1500:1500000 // @User: Standard AP_GROUPINFO("1_BAUD", 2, AP_SerialManager, state[1].baud, AP_SERIALMANAGER_MAVLINK_BAUD/1000), // @Param: 2_PROTOCOL // @DisplayName: Telemetry 2 protocol selection // @Description: Control what protocol to use on the Telem2 port. Note that the Frsky options require external converter hardware. See the wiki for details. // @Values: -1:None, 1:MAVLink1, 2:MAVLink2, 3:Frsky D, 4:Frsky SPort, 5:GPS, 7:Alexmos Gimbal Serial, 8:SToRM32 Gimbal Serial, 9:Rangefinder, 10:FrSky SPort Passthrough (OpenTX), 11:Lidar360, 13:Beacon, 14:Volz servo out, 15:SBus servo out, 16:ESC Telemetry, 17:Devo Telemetry, 18:OpticalFlow, 19:RobotisServo // @User: Standard // @RebootRequired: True AP_GROUPINFO("2_PROTOCOL", 3, AP_SerialManager, state[2].protocol, SERIAL2_PROTOCOL_DEFAULT), // @Param: 2_BAUD // @DisplayName: Telemetry 2 Baud Rate // @Description: The baud rate of the Telem2 port. The APM2 can support all baudrates up to 115, and also can support 500. The PX4 can support rates of up to 1500. If you setup a rate you cannot support on APM2 and then can't connect to your board you should load a firmware from a different vehicle type. That will reset all your parameters to defaults. // @Values: 1:1200,2:2400,4:4800,9:9600,19:19200,38:38400,57:57600,111:111100,115:115200,256:256000,500:500000,921:921600,1500:1500000 // @User: Standard AP_GROUPINFO("2_BAUD", 4, AP_SerialManager, state[2].baud, AP_SERIALMANAGER_MAVLINK_BAUD/1000), // @Param: 3_PROTOCOL // @DisplayName: Serial 3 (GPS) protocol selection // @Description: Control what protocol Serial 3 (GPS) should be used for. Note that the Frsky options require external converter hardware. See the wiki for details. // @Values: -1:None, 1:MAVLink1, 2:MAVLink2, 3:Frsky D, 4:Frsky SPort, 5:GPS, 7:Alexmos Gimbal Serial, 8:SToRM32 Gimbal Serial, 9:Rangefinder, 10:FrSky SPort Passthrough (OpenTX), 11:Lidar360, 13:Beacon, 14:Volz servo out, 15:SBus servo out, 16:ESC Telemetry, 17:Devo Telemetry, 18:OpticalFlow, 19:RobotisServo // @User: Standard // @RebootRequired: True AP_GROUPINFO("3_PROTOCOL", 5, AP_SerialManager, state[3].protocol, SerialProtocol_GPS), // @Param: 3_BAUD // @DisplayName: Serial 3 (GPS) Baud Rate // @Description: The baud rate used for the Serial 3 (GPS). The APM2 can support all baudrates up to 115, and also can support 500. The PX4 can support rates of up to 1500. If you setup a rate you cannot support on APM2 and then can't connect to your board you should load a firmware from a different vehicle type. That will reset all your parameters to defaults. // @Values: 1:1200,2:2400,4:4800,9:9600,19:19200,38:38400,57:57600,111:111100,115:115200,256:256000,500:500000,921:921600,1500:1500000 // @User: Standard AP_GROUPINFO("3_BAUD", 6, AP_SerialManager, state[3].baud, AP_SERIALMANAGER_GPS_BAUD/1000), // @Param: 4_PROTOCOL // @DisplayName: Serial4 protocol selection // @Description: Control what protocol Serial4 port should be used for. Note that the Frsky options require external converter hardware. See the wiki for details. // @Values: -1:None, 1:MAVLink1, 2:MAVLink2, 3:Frsky D, 4:Frsky SPort, 5:GPS, 7:Alexmos Gimbal Serial, 8:SToRM32 Gimbal Serial, 9:Rangefinder, 10:FrSky SPort Passthrough (OpenTX), 11:Lidar360, 13:Beacon, 14:Volz servo out, 15:SBus servo out, 16:ESC Telemetry, 17:Devo Telemetry, 18:OpticalFlow, 19:RobotisServo // @User: Standard // @RebootRequired: True AP_GROUPINFO("4_PROTOCOL", 7, AP_SerialManager, state[4].protocol, SerialProtocol_GPS), // @Param: 4_BAUD // @DisplayName: Serial 4 Baud Rate // @Description: The baud rate used for Serial4. The APM2 can support all baudrates up to 115, and also can support 500. The PX4 can support rates of up to 1500. If you setup a rate you cannot support on APM2 and then can't connect to your board you should load a firmware from a different vehicle type. That will reset all your parameters to defaults. // @Values: 1:1200,2:2400,4:4800,9:9600,19:19200,38:38400,57:57600,111:111100,115:115200,256:256000,500:500000,921:921600,1500:1500000 // @User: Standard AP_GROUPINFO("4_BAUD", 8, AP_SerialManager, state[4].baud, AP_SERIALMANAGER_GPS_BAUD/1000), // @Param: 5_PROTOCOL // @DisplayName: Serial5 protocol selection // @Description: Control what protocol Serial5 port should be used for. Note that the Frsky options require external converter hardware. See the wiki for details. // @Values: -1:None, 1:MAVLink1, 2:MAVLink2, 3:Frsky D, 4:Frsky SPort, 5:GPS, 7:Alexmos Gimbal Serial, 8:SToRM32 Gimbal Serial, 9:Rangefinder, 10:FrSky SPort Passthrough (OpenTX), 11:Lidar360, 13:Beacon, 14:Volz servo out, 15:SBus servo out, 16:ESC Telemetry, 17:Devo Telemetry, 18:OpticalFlow, 19:RobotisServo // @User: Standard // @RebootRequired: True AP_GROUPINFO("5_PROTOCOL", 9, AP_SerialManager, state[5].protocol, SERIAL5_PROTOCOL), // @Param: 5_BAUD // @DisplayName: Serial 5 Baud Rate // @Description: The baud rate used for Serial5. The APM2 can support all baudrates up to 115, and also can support 500. The PX4 can support rates of up to 1500. If you setup a rate you cannot support on APM2 and then can't connect to your board you should load a firmware from a different vehicle type. That will reset all your parameters to defaults. // @Values: 1:1200,2:2400,4:4800,9:9600,19:19200,38:38400,57:57600,111:111100,115:115200,256:256000,500:500000,921:921600,1500:1500000 // @User: Standard AP_GROUPINFO("5_BAUD", 10, AP_SerialManager, state[5].baud, SERIAL5_BAUD), // index 11 used by 0_PROTOCOL // @Param: 6_PROTOCOL // @DisplayName: Serial6 protocol selection // @Description: Control what protocol Serial6 port should be used for. Note that the Frsky options require external converter hardware. See the wiki for details. // @Values: -1:None, 1:MAVLink1, 2:MAVLink2, 3:Frsky D, 4:Frsky SPort, 5:GPS, 7:Alexmos Gimbal Serial, 8:SToRM32 Gimbal Serial, 9:Rangefinder, 10:FrSky SPort Passthrough (OpenTX), 11:Lidar360, 13:Beacon, 14:Volz servo out, 15:SBus servo out, 16:ESC Telemetry, 17:Devo Telemetry, 18:OpticalFlow, 19:RobotisServo // @User: Standard // @RebootRequired: True AP_GROUPINFO("6_PROTOCOL", 12, AP_SerialManager, state[6].protocol, SERIAL6_PROTOCOL), // @Param: 6_BAUD // @DisplayName: Serial 6 Baud Rate // @Description: The baud rate used for Serial6. The APM2 can support all baudrates up to 115, and also can support 500. The PX4 can support rates of up to 1500. If you setup a rate you cannot support on APM2 and then can't connect to your board you should load a firmware from a different vehicle type. That will reset all your parameters to defaults. // @Values: 1:1200,2:2400,4:4800,9:9600,19:19200,38:38400,57:57600,111:111100,115:115200,256:256000,500:500000,921:921600,1500:1500000 // @User: Standard AP_GROUPINFO("6_BAUD", 13, AP_SerialManager, state[6].baud, SERIAL6_BAUD), // @Param: 1_OPTIONS // @DisplayName: Telem1 options // @Description: Control over UART options. The InvertRX option controls invert of the receive pin. The InvertTX option controls invert of the transmit pin. The HalfDuplex option controls half-duplex (onewire) mode, where both transmit and receive is done on the transmit wire. The Swap option allows the RX and TX pins to be swapped on STM32F7 based boards. // @Bitmask: 0:InvertRX, 1:InvertTX, 2:HalfDuplex, 4:Swap // @User: Advanced // @RebootRequired: True AP_GROUPINFO("1_OPTIONS", 14, AP_SerialManager, state[1].options, 0), // @Param: 2_OPTIONS // @DisplayName: Telem2 options // @Description: Control over UART options. The InvertRX option controls invert of the receive pin. The InvertTX option controls invert of the transmit pin. The HalfDuplex option controls half-duplex (onewire) mode, where both transmit and receive is done on the transmit wire. // @Bitmask: 0:InvertRX, 1:InvertTX, 2:HalfDuplex, 4:Swap // @User: Advanced // @RebootRequired: True AP_GROUPINFO("2_OPTIONS", 15, AP_SerialManager, state[2].options, 0), // @Param: 3_OPTIONS // @DisplayName: Serial3 options // @Description: Control over UART options. The InvertRX option controls invert of the receive pin. The InvertTX option controls invert of the transmit pin. The HalfDuplex option controls half-duplex (onewire) mode, where both transmit and receive is done on the transmit wire. // @Bitmask: 0:InvertRX, 1:InvertTX, 2:HalfDuplex, 4:Swap // @User: Advanced // @RebootRequired: True AP_GROUPINFO("3_OPTIONS", 16, AP_SerialManager, state[3].options, 0), // @Param: 4_OPTIONS // @DisplayName: Serial4 options // @Description: Control over UART options. The InvertRX option controls invert of the receive pin. The InvertTX option controls invert of the transmit pin. The HalfDuplex option controls half-duplex (onewire) mode, where both transmit and receive is done on the transmit wire. // @Bitmask: 0:InvertRX, 1:InvertTX, 2:HalfDuplex, 4:Swap // @User: Advanced // @RebootRequired: True AP_GROUPINFO("4_OPTIONS", 17, AP_SerialManager, state[4].options, 0), // @Param: 5_OPTIONS // @DisplayName: Serial5 options // @Description: Control over UART options. The InvertRX option controls invert of the receive pin. The InvertTX option controls invert of the transmit pin. The HalfDuplex option controls half-duplex (onewire) mode, where both transmit and receive is done on the transmit wire. // @Bitmask: 0:InvertRX, 1:InvertTX, 2:HalfDuplex, 4:Swap // @User: Advanced // @RebootRequired: True AP_GROUPINFO("5_OPTIONS", 18, AP_SerialManager, state[5].options, 0), // @Param: 6_OPTIONS // @DisplayName: Serial6 options // @Description: Control over UART options. The InvertRX option controls invert of the receive pin. The InvertTX option controls invert of the transmit pin. The HalfDuplex option controls half-duplex (onewire) mode, where both transmit and receive is done on the transmit wire. // @Bitmask: 0:InvertRX, 1:InvertTX, 2:HalfDuplex, 4:Swap // @User: Advanced // @RebootRequired: True AP_GROUPINFO("6_OPTIONS", 19, AP_SerialManager, state[6].options, 0), // @Param: _PASS1 // @DisplayName: Serial passthru first port // @Description: This sets one side of pass-through between two serial ports. Once both sides are set then all data received on either port will be passed to the other port // @Values: -1:Disabled,0:Serial0,1:Serial1,2:Serial2,3:Serial3,4:Serial4,5:Serial5,6:Serial6 // @User: Advanced AP_GROUPINFO("_PASS1", 20, AP_SerialManager, passthru_port1, 0), // @Param: _PASS2 // @DisplayName: Serial passthru second port // @Description: This sets one side of pass-through between two serial ports. Once both sides are set then all data received on either port will be passed to the other port // @Values: -1:Disabled,0:Serial0,1:Serial1,2:Serial2,3:Serial3,4:Serial4,5:Serial5,6:Serial6 // @User: Advanced AP_GROUPINFO("_PASS2", 21, AP_SerialManager, passthru_port2, -1), // @Param: _PASSTIMO // @DisplayName: Serial passthru timeout // @Description: This sets a timeout for serial pass-through in seconds. When the pass-through is enabled by setting the SERIAL_PASS1 and SERIAL_PASS2 parameters then it remains in effect until no data comes from the first port for SERIAL_PASSTIMO seconds. This allows the port to revent to its normal usage (such as MAVLink connection to a GCS) when it is no longer needed. A value of 0 means no timeout. // @Range: 0 120 // @Units: s // @User: Advanced AP_GROUPINFO("_PASSTIMO", 22, AP_SerialManager, passthru_timeout, 15), AP_GROUPEND }; // singleton instance AP_SerialManager *AP_SerialManager::_instance; // Constructor AP_SerialManager::AP_SerialManager() { _instance = this; // setup parameter defaults AP_Param::setup_object_defaults(this, var_info); } // init_console - initialise console at default baud rate void AP_SerialManager::init_console() { // initialise console immediately at default size and baud state[0].uart = hal.uartA; // serial0, uartA, always console state[0].uart->begin(AP_SERIALMANAGER_CONSOLE_BAUD, AP_SERIALMANAGER_CONSOLE_BUFSIZE_RX, AP_SERIALMANAGER_CONSOLE_BUFSIZE_TX); } extern bool g_nsh_should_exit; // init - // init - initialise serial ports void AP_SerialManager::init() { // always reset passthru port2 on boot passthru_port2.set_and_save_ifchanged(-1); // initialise pointers to serial ports state[1].uart = hal.uartC; // serial1, uartC, normally telem1 state[2].uart = hal.uartD; // serial2, uartD, normally telem2 state[3].uart = hal.uartB; // serial3, uartB, normally 1st GPS state[4].uart = hal.uartE; // serial4, uartE, normally 2nd GPS state[5].uart = hal.uartF; // serial5 state[6].uart = hal.uartG; // serial6 if (state[0].uart == nullptr) { init_console(); } // initialise serial ports for (uint8_t i=1; ibegin(map_baudrate(state[i].baud), AP_SERIALMANAGER_MAVLINK_BUFSIZE_RX, AP_SERIALMANAGER_MAVLINK_BUFSIZE_TX); break; case SerialProtocol_FrSky_D: // Note baudrate is hardcoded to 9600 state[i].baud = AP_SERIALMANAGER_FRSKY_D_BAUD/1000; // update baud param in case user looks at it // begin is handled by AP_Frsky_telem library break; case SerialProtocol_FrSky_SPort: case SerialProtocol_FrSky_SPort_Passthrough: // Note baudrate is hardcoded to 57600 state[i].baud = AP_SERIALMANAGER_FRSKY_SPORT_BAUD/1000; // update baud param in case user looks at it // begin is handled by AP_Frsky_telem library break; case SerialProtocol_GPS: case SerialProtocol_GPS2: state[i].uart->begin(map_baudrate(state[i].baud), AP_SERIALMANAGER_GPS_BUFSIZE_RX, AP_SERIALMANAGER_GPS_BUFSIZE_TX); break; case SerialProtocol_AlexMos: // Note baudrate is hardcoded to 115200 state[i].baud = AP_SERIALMANAGER_ALEXMOS_BAUD / 1000; // update baud param in case user looks at it state[i].uart->begin(AP_SERIALMANAGER_ALEXMOS_BAUD, AP_SERIALMANAGER_ALEXMOS_BUFSIZE_RX, AP_SERIALMANAGER_ALEXMOS_BUFSIZE_TX); break; case SerialProtocol_SToRM32: // Note baudrate is hardcoded to 115200 state[i].baud = AP_SERIALMANAGER_SToRM32_BAUD / 1000; // update baud param in case user looks at it state[i].uart->begin(map_baudrate(state[i].baud), AP_SERIALMANAGER_SToRM32_BUFSIZE_RX, AP_SERIALMANAGER_SToRM32_BUFSIZE_TX); break; case SerialProtocol_Aerotenna_uLanding: state[i].protocol.set_and_save(SerialProtocol_Rangefinder); break; case SerialProtocol_Volz: // Note baudrate is hardcoded to 115200 state[i].baud = AP_SERIALMANAGER_VOLZ_BAUD; // update baud param in case user looks at it state[i].uart->begin(map_baudrate(state[i].baud), AP_SERIALMANAGER_VOLZ_BUFSIZE_RX, AP_SERIALMANAGER_VOLZ_BUFSIZE_TX); state[i].uart->set_unbuffered_writes(true); state[i].uart->set_flow_control(AP_HAL::UARTDriver::FLOW_CONTROL_DISABLE); break; case SerialProtocol_Sbus1: state[i].baud = AP_SERIALMANAGER_SBUS1_BAUD / 1000; // update baud param in case user looks at it state[i].uart->begin(map_baudrate(state[i].baud), AP_SERIALMANAGER_SBUS1_BUFSIZE_RX, AP_SERIALMANAGER_SBUS1_BUFSIZE_TX); state[i].uart->configure_parity(2); // enable even parity state[i].uart->set_stop_bits(2); state[i].uart->set_unbuffered_writes(true); state[i].uart->set_flow_control(AP_HAL::UARTDriver::FLOW_CONTROL_DISABLE); break; case SerialProtocol_ESCTelemetry: // ESC telemetry protocol from BLHeli32 ESCs. Note that baudrate is hardcoded to 115200 state[i].baud = 115200; state[i].uart->begin(map_baudrate(state[i].baud), 30, 30); state[i].uart->set_flow_control(AP_HAL::UARTDriver::FLOW_CONTROL_DISABLE); break; case SerialProtocol_Robotis: state[i].uart->begin(map_baudrate(state[i].baud), AP_SERIALMANAGER_ROBOTIS_BUFSIZE_RX, AP_SERIALMANAGER_ROBOTIS_BUFSIZE_TX); state[i].uart->set_unbuffered_writes(true); state[i].uart->set_flow_control(AP_HAL::UARTDriver::FLOW_CONTROL_DISABLE); break; } } } } const AP_SerialManager::UARTState *AP_SerialManager::find_protocol_instance(enum SerialProtocol protocol, uint8_t instance) const { uint8_t found_instance = 0; // search for matching protocol for(uint8_t i=0; iuart; } // find_baudrate - searches available serial ports for the first instance that allows the given protocol // instance should be zero if searching for the first instance, 1 for the second, etc // returns baudrate on success, 0 if a serial port cannot be found uint32_t AP_SerialManager::find_baudrate(enum SerialProtocol protocol, uint8_t instance) const { const struct UARTState *_state = find_protocol_instance(protocol, instance); if (_state == nullptr) { return 0; } return map_baudrate(_state->baud); } // get_mavlink_channel - provides the mavlink channel associated with a given protocol // instance should be zero if searching for the first instance, 1 for the second, etc // returns true if a channel is found, false if not bool AP_SerialManager::get_mavlink_channel(enum SerialProtocol protocol, uint8_t instance, mavlink_channel_t &mav_chan) const { // check for MAVLink if (protocol_match(protocol, SerialProtocol_MAVLink)) { if (instance < MAVLINK_COMM_NUM_BUFFERS) { mav_chan = (mavlink_channel_t)(MAVLINK_COMM_0 + instance); return true; } } // report failure return false; } // get_mavlink_protocol - provides the specific MAVLink protocol for a // given channel, or SerialProtocol_None if not found AP_SerialManager::SerialProtocol AP_SerialManager::get_mavlink_protocol(mavlink_channel_t mav_chan) const { uint8_t instance = 0; uint8_t chan_idx = (uint8_t)(mav_chan - MAVLINK_COMM_0); for (uint8_t i=0; iset_blocking_writes(blocking); } } } /* * map from a 16 bit EEPROM baud rate to a real baud rate. * For PX4 we can do 1.5MBit, although 921600 is more reliable. */ uint32_t AP_SerialManager::map_baudrate(int32_t rate) const { if (rate <= 0) { rate = 57; } switch (rate) { case 1: return 1200; case 2: return 2400; case 4: return 4800; case 9: return 9600; case 19: return 19200; case 38: return 38400; case 57: return 57600; case 100: return 100000; case 111: return 111100; case 115: return 115200; case 230: return 230400; case 256: return 256000; case 460: return 460800; case 500: return 500000; case 921: return 921600; case 1500: return 1500000; } if (rate > 2000) { // assume it is a direct baudrate. This allows for users to // set an exact baudrate as long as it is over 2000 baud return (uint32_t)rate; } // otherwise allow any other kbaud rate return rate*1000; } // protocol_match - returns true if the protocols match bool AP_SerialManager::protocol_match(enum SerialProtocol protocol1, enum SerialProtocol protocol2) const { // check for obvious match if (protocol1 == protocol2) { return true; } // mavlink match if (((protocol1 == SerialProtocol_MAVLink) || (protocol1 == SerialProtocol_MAVLink2)) && ((protocol2 == SerialProtocol_MAVLink) || (protocol2 == SerialProtocol_MAVLink2))) { return true; } // gps match if (((protocol1 == SerialProtocol_GPS) || (protocol1 == SerialProtocol_GPS2)) && ((protocol2 == SerialProtocol_GPS) || (protocol2 == SerialProtocol_GPS2))) { return true; } return false; } // setup any special options void AP_SerialManager::set_options(uint8_t i) { struct UARTState &opt = state[i]; // pass through to HAL if (!opt.uart->set_options(opt.options)) { hal.console->printf("Unable to setup options for Serial%u\n", i); } } // get the passthru ports if enabled bool AP_SerialManager::get_passthru(AP_HAL::UARTDriver *&port1, AP_HAL::UARTDriver *&port2, uint8_t &timeout_s) const { if (passthru_port2 < 0 || passthru_port2 >= SERIALMANAGER_NUM_PORTS || passthru_port1 < 0 || passthru_port1 >= SERIALMANAGER_NUM_PORTS) { return false; } port1 = state[passthru_port1].uart; port2 = state[passthru_port2].uart; timeout_s = MAX(passthru_timeout, 0); return true; } // disable passthru by settings SERIAL_PASS2 to -1 void AP_SerialManager::disable_passthru(void) { passthru_port2.set_and_notify(-1); } namespace AP { AP_SerialManager &serialmanager() { return *AP_SerialManager::get_instance(); } }