/* * This file 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 file 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 . */ /* * Crossfire constants provided by Team Black Sheep under terms of the 2-Clause BSD License */ #pragma once #include "AP_RCProtocol_config.h" #include #if AP_RCPROTOCOL_CRSF_ENABLED #include "AP_RCProtocol.h" #include #include #include "SoftSerial.h" #include #define CRSF_MAX_CHANNELS 24U // Maximum number of channels from crsf datastream #define CRSF_FRAMELEN_MAX 64U // maximum possible framelength #define CRSF_HEADER_LEN 2U // header length #define CRSF_FRAME_PAYLOAD_MAX (CRSF_FRAMELEN_MAX - CRSF_HEADER_LEN) // maximum size of the frame length field in a packet #define CRSF_FRAME_LENGTH_MIN 2 // min value for _frame.length #define CRSF_BAUDRATE 416666U #define ELRS_BAUDRATE 420000U #define CRSF_TX_TIMEOUT 500000U // the period after which the transmitter is considered disconnected (matches copters failsafe) #define CRSF_RX_TIMEOUT 150000U // the period after which the receiver is considered disconnected (>ping frequency) class AP_RCProtocol_CRSF : public AP_RCProtocol_Backend { public: AP_RCProtocol_CRSF(AP_RCProtocol &_frontend); virtual ~AP_RCProtocol_CRSF(); void process_byte(uint8_t byte, uint32_t baudrate) override; void process_handshake(uint32_t baudrate) override; void update(void) override; #if HAL_CRSF_TELEM_ENABLED void start_bind(void) override; #endif // support for CRSF v3 bool change_baud_rate(uint32_t baudrate); // bootstrap baudrate uint32_t get_bootstrap_baud_rate() const { #if AP_RC_CHANNEL_ENABLED return rc().option_is_enabled(RC_Channels::Option::ELRS_420KBAUD) ? ELRS_BAUDRATE : CRSF_BAUDRATE; #else return CRSF_BAUDRATE; #endif } // is the receiver active, used to detect power loss and baudrate changes bool is_rx_active() const override { // later versions of CRSFv3 will send link rate frames every 200ms // but only before an initial failsafe return _last_rx_frame_time_us != 0 && AP_HAL::micros() - _last_rx_frame_time_us < CRSF_RX_TIMEOUT; } // is the transmitter active, used to adjust telemetry data bool is_tx_active() const { // this is the same as the Copter failsafe timeout return _last_tx_frame_time_us != 0 && AP_HAL::micros() - _last_tx_frame_time_us < CRSF_TX_TIMEOUT; } // get singleton instance static AP_RCProtocol_CRSF* get_singleton() { return _singleton; } enum FrameType { CRSF_FRAMETYPE_GPS = 0x02, CRSF_FRAMETYPE_VARIO = 0x07, CRSF_FRAMETYPE_BATTERY_SENSOR = 0x08, CRSF_FRAMETYPE_BARO_VARIO = 0x09, CRSF_FRAMETYPE_HEARTBEAT = 0x0B, CRSF_FRAMETYPE_VTX = 0x0F, CRSF_FRAMETYPE_VTX_TELEM = 0x10, CRSF_FRAMETYPE_LINK_STATISTICS = 0x14, CRSF_FRAMETYPE_RC_CHANNELS_PACKED = 0x16, CRSF_FRAMETYPE_SUBSET_RC_CHANNELS_PACKED = 0x17, CRSF_FRAMETYPE_RC_CHANNELS_PACKED_11BIT = 0x18, CRSF_FRAMETYPE_LINK_STATISTICS_RX = 0x1C, CRSF_FRAMETYPE_LINK_STATISTICS_TX = 0x1D, CRSF_FRAMETYPE_ATTITUDE = 0x1E, CRSF_FRAMETYPE_FLIGHT_MODE = 0x21, // Extended Header Frames, range: 0x28 to 0x96 CRSF_FRAMETYPE_PARAM_DEVICE_PING = 0x28, CRSF_FRAMETYPE_PARAM_DEVICE_INFO = 0x29, CRSF_FRAMETYPE_PARAMETER_SETTINGS_ENTRY = 0x2B, CRSF_FRAMETYPE_PARAMETER_READ = 0x2C, CRSF_FRAMETYPE_PARAMETER_WRITE = 0x2D, CRSF_FRAMETYPE_COMMAND = 0x32, // Custom Telemetry Frames 0x7F,0x80 CRSF_FRAMETYPE_AP_CUSTOM_TELEM_LEGACY = 0x7F, // as suggested by Remo Masina for fw < 4.06 CRSF_FRAMETYPE_AP_CUSTOM_TELEM = 0x80, // reserved for ArduPilot by TBS, requires fw >= 4.06 }; // Command IDs for CRSF_FRAMETYPE_COMMAND enum CommandID { CRSF_COMMAND_FC = 0x01, CRSF_COMMAND_BLUETOOTH = 0x03, CRSF_COMMAND_OSD = 0x05, CRSF_COMMAND_VTX = 0x08, CRSF_COMMAND_LED = 0x09, CRSF_COMMAND_GENERAL = 0x0A, CRSF_COMMAND_RX = 0x10, }; // Commands for CRSF_COMMAND_FC enum CommandFC { CRSF_COMMAND_FC_DISARM = 0x01, CRSF_COMMAND_SCALE_CHANNEL = 0x02, }; // Commands for CRSF_COMMAND_BLUETOOTH enum CommandBluetooth { CRSF_COMMAND_BLUETOOTH_RESET = 0x01, CRSF_COMMAND_BLUETOOTH_ENABLE = 0x02, CRSF_COMMAND_BLUETOOTH_ECHO = 0x64, }; // Commands for CRSF_COMMAND_OSD enum CommandOSD { CRSF_COMMAND_OSD_SEND = 0x01, }; // Commands for CRSF_COMMAND_VTX enum CommandVTX { CRSF_COMMAND_VTX_CHANNEL = 0x01, CRSF_COMMAND_VTX_FREQ = 0x02, CRSF_COMMAND_VTX_POWER = 0x03, CRSF_COMMAND_VTX_PITMODE = 0x04, CRSF_COMMAND_VTX_PITMODE_POWERUP = 0x05, CRSF_COMMAND_VTX_POWER_DBM = 0x08, }; // Commands for CRSF_COMMAND_LED enum CommandLED { CRSF_COMMAND_LED_SET_DEFAULT = 0x01, CRSF_COMMAND_LED_COLOR = 0x02, CRSF_COMMAND_LED_PULSE = 0x03, CRSF_COMMAND_LED_BLINK = 0x04, CRSF_COMMAND_LED_SHIFT = 0x05, }; // Commands for CRSF_COMMAND_RX enum CommandRX { CRSF_COMMAND_RX_BIND = 0x01, CRSF_COMMAND_RX_CANCEL_BIND = 0x02, CRSF_COMMAND_RX_SET_BIND_ID = 0x03, }; // Commands for CRSF_COMMAND_GENERAL enum CommandGeneral { CRSF_COMMAND_GENERAL_CHILD_DEVICE_REQUEST = 0x04, CRSF_COMMAND_GENERAL_CHILD_DEVICE_FRAME = 0x05, CRSF_COMMAND_GENERAL_FIRMWARE_UPDATE_BOOTLOADER = 0x0A, CRSF_COMMAND_GENERAL_FIRMWARE_UPDATE_ERASE = 0x0B, CRSF_COMMAND_GENERAL_WRITE_SERIAL_NUMBER = 0x13, CRSF_COMMAND_GENERAL_USER_ID = 0x15, CRSF_COMMAND_GENERAL_SOFTWARE_PRODUCT_KEY = 0x60, CRSF_COMMAND_GENERAL_CRSF_SPEED_PROPOSAL = 0x70, // proposed new CRSF port speed CRSF_COMMAND_GENERAL_CRSF_SPEED_RESPONSE = 0x71, // response to the proposed CRSF port speed }; // SubType IDs for CRSF_FRAMETYPE_CUSTOM_TELEM enum CustomTelemSubTypeID : uint8_t { CRSF_AP_CUSTOM_TELEM_SINGLE_PACKET_PASSTHROUGH = 0xF0, CRSF_AP_CUSTOM_TELEM_STATUS_TEXT = 0xF1, CRSF_AP_CUSTOM_TELEM_MULTI_PACKET_PASSTHROUGH = 0xF2, }; enum DeviceAddress { CRSF_ADDRESS_BROADCAST = 0x00, CRSF_ADDRESS_USB = 0x10, CRSF_ADDRESS_TBS_CORE_PNP_PRO = 0x80, CRSF_ADDRESS_RESERVED1 = 0x8A, CRSF_ADDRESS_PNP_PRO_CURRENT_SENSOR = 0xC0, CRSF_ADDRESS_PNP_PRO_GPS = 0xC2, CRSF_ADDRESS_TBS_BLACKBOX = 0xC4, CRSF_ADDRESS_FLIGHT_CONTROLLER = 0xC8, CRSF_ADDRESS_RESERVED2 = 0xCA, CRSF_ADDRESS_RACE_TAG = 0xCC, CRSF_ADDRESS_VTX = 0xCE, CRSF_ADDRESS_RADIO_TRANSMITTER = 0xEA, CRSF_ADDRESS_CRSF_RECEIVER = 0xEC, CRSF_ADDRESS_CRSF_TRANSMITTER = 0xEE }; enum ExtendedFrameOffset { CRSF_EXTENDED_FRAME_LENGTH_OFFSET = 1, CRSF_EXTENDED_FRAME_TYPE_OFFSET = 2, CRSF_EXTENDED_FRAME_DESTINATION_OFFSET = 3, CRSF_EXTENDED_FRAME_ORIGIN_OFFSET = 4, CRSF_EXTENDED_FRAME_PAYLOAD_OFFSET = 5, }; struct Frame { uint8_t device_address; uint8_t length; uint8_t type; uint8_t payload[CRSF_FRAME_PAYLOAD_MAX - 1]; // type is already accounted for } PACKED; struct LinkStatisticsFrame { uint8_t uplink_rssi_ant1; // ( dBm * -1 ) uint8_t uplink_rssi_ant2; // ( dBm * -1 ) uint8_t uplink_status; // Package success rate / Link quality ( % ) int8_t uplink_snr; // ( db ) uint8_t active_antenna; // Diversity active antenna ( enum ant. 1 = 0, ant. 2 ) uint8_t rf_mode; // ( enum 4fps = 0 , 50fps, 150hz) uint8_t uplink_tx_power; // ( enum 0mW = 0, 10mW, 25 mW, 100 mW, 500 mW, 1000 mW, 2000mW ) uint8_t downlink_rssi; // ( dBm * -1 ) uint8_t downlink_status; // Downlink package success rate / Link quality ( % ) int8_t downlink_dnr; // ( db ) } PACKED; struct LinkStatisticsRXFrame { uint8_t rssi_db; // RSSI(dBm*-1) uint8_t rssi_percent; // RSSI in percent uint8_t link_quality; // Package success rate / Link quality ( % ) int8_t snr; // SNR(dB) uint8_t rf_power_db; // rf power in dBm } PACKED; struct LinkStatisticsTXFrame { uint8_t rssi_db; // RSSI(dBm*-1) uint8_t rssi_percent; // RSSI in percent uint8_t link_quality; // Package success rate / Link quality ( % ) int8_t snr; // SNR(dB) uint8_t rf_power_db; // rf power in dBm uint8_t fps; // rf frames per second (fps / 10) } PACKED; struct SubsetChannelsFrame { #if __BYTE_ORDER != __LITTLE_ENDIAN #error "Only supported on little-endian architectures" #endif uint8_t starting_channel:5; // which channel number is the first one in the frame uint8_t res_configuration:2; // configuration for the RC data resolution (10 - 13 bits) uint8_t digital_switch_flag:1; // configuration bit for digital channel uint8_t channels[CRSF_FRAME_PAYLOAD_MAX - 2]; // payload less byte above // uint16_t channel[]:res; // variable amount of channels (with variable resolution based // on the res_configuration) based on the frame size // uint16_t digital_switch_channel[]:10; // digital switch channel } PACKED; enum class ProtocolType { PROTOCOL_CRSF, PROTOCOL_TRACER, PROTOCOL_ELRS }; // Source for ELRS RF modes: https://www.expresslrs.org/info/signal-health/#rf-mode-indexes-rfmd enum RFMode { CRSF_RF_MODE_4HZ = 0, CRSF_RF_MODE_50HZ, CRSF_RF_MODE_150HZ, CRSF_RF_MODE_250HZ, CRSF_RF_MAX_MODES = 4, ELRS_RF_MODE_4HZ = 4, ELRS_RF_MODE_25HZ, ELRS_RF_MODE_50HZ, ELRS_RF_MODE_100HZ, ELRS_RF_MODE_100HZ_FULL, ELRS_RF_MODE_150HZ, ELRS_RF_MODE_200HZ, ELRS_RF_MODE_250HZ, ELRS_RF_MODE_333HZ_FULL, ELRS_RF_MODE_500HZ, ELRS_RF_MODE_D250HZ, ELRS_RF_MODE_D500HZ, ELRS_RF_MODE_F500HZ, ELRS_RF_MODE_F1000HZ, ELRS_RF_MODE_D50HZ, RF_MODE_MAX_MODES, RF_MODE_UNKNOWN, }; #if AP_OSD_LINK_STATS_EXTENSIONS_ENABLED // These power levels are valid for both Crossfire and ELRS systems static constexpr uint16_t tx_powers[] = { 0, 10, 25, 100, 500, 1000, 2000, 250, 50 }; #endif struct LinkStatus { int16_t rssi = -1; int16_t link_quality = -1; uint8_t rf_mode; #if AP_OSD_LINK_STATS_EXTENSIONS_ENABLED // Add the extra data fields to be used by the OSD panels int16_t tx_power = -1; int8_t rssi_dbm = -1; int8_t snr = INT8_MIN; int8_t active_antenna = -1; #endif }; // this will be used by AP_CRSF_Telem to access link status data // from within AP_RCProtocol_CRSF thread so no need for cross-thread synch const volatile LinkStatus& get_link_status() const { return _link_status; } // return the link rate as defined by the LinkStatistics uint16_t get_link_rate(ProtocolType protocol) const; // return the protocol string const char* get_protocol_string(ProtocolType protocol) const; private: struct Frame _frame; uint8_t *_frame_bytes = (uint8_t*)&_frame; struct Frame _telemetry_frame; uint8_t _frame_ofs; const uint8_t MAX_CHANNELS = MIN((uint8_t)CRSF_MAX_CHANNELS, (uint8_t)MAX_RCIN_CHANNELS); static AP_RCProtocol_CRSF* _singleton; void _process_byte(uint8_t byte); bool check_frame(uint32_t timestamp_us); void skip_to_next_frame(uint32_t timestamp_us); bool decode_crsf_packet(); bool process_telemetry(bool check_constraint = true); void process_link_stats_frame(const void* data); void process_link_stats_rx_frame(const void* data); void process_link_stats_tx_frame(const void* data); // crsf v3 decoding void decode_variable_bit_channels(const uint8_t* data, uint8_t frame_length, uint8_t nchannels, uint16_t *values); void write_frame(Frame* frame); void start_uart(); AP_HAL::UARTDriver* get_current_UART() { return (_uart ? _uart : get_available_UART()); } uint16_t _channels[CRSF_MAX_CHANNELS]; /* buffer for extracted RC channel data as pulsewidth in microseconds */ uint32_t _last_frame_time_us; uint32_t _last_tx_frame_time_us; uint32_t _last_uart_start_time_ms; uint32_t _last_rx_frame_time_us; uint32_t _start_frame_time_us; bool telem_available; uint32_t _new_baud_rate; bool _crsf_v3_active; bool _use_lq_for_rssi; int16_t derive_scaled_lq_value(uint8_t uplink_lq); volatile struct LinkStatus _link_status; static const uint16_t RF_MODE_RATES[RFMode::RF_MODE_MAX_MODES]; AP_HAL::UARTDriver *_uart; }; namespace AP { AP_RCProtocol_CRSF* crsf(); }; #endif // AP_RCPROTOCOL_CRSF_ENABLED