/* 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 . */ /* implementation of MSP and BLHeli-4way protocols for pass-through ESC calibration and firmware update With thanks to betaflight for a great reference implementation. Several of the functions below are based on betaflight equivalent functions */ #include "AP_BLHeli.h" #if HAVE_AP_BLHELI_SUPPORT #if CONFIG_HAL_BOARD == HAL_BOARD_CHIBIOS #include #endif #include #include #if APM_BUILD_TYPE(APM_BUILD_Rover) #include #else #include #endif #include #include #include #include #include #include extern const AP_HAL::HAL& hal; #define debug(fmt, args ...) do { if (debug_level) { GCS_SEND_TEXT(MAV_SEVERITY_INFO, "ESC: " fmt, ## args); } } while (0) // key for locking UART for exclusive use. This prevents any other writes from corrupting // the MSP protocol on hal.console #define BLHELI_UART_LOCK_KEY 0x20180402 // if no packets are received for this time and motor control is active BLH will disconnect (stoping motors) #define MOTOR_ACTIVE_TIMEOUT 1000 const AP_Param::GroupInfo AP_BLHeli::var_info[] = { // @Param: MASK // @DisplayName: BLHeli Channel Bitmask // @Description: Enable of BLHeli pass-thru servo protocol support to specific channels. This mask is in addition to motors enabled using SERVO_BLH_AUTO (if any) // @Bitmask: 0:Channel1,1:Channel2,2:Channel3,3:Channel4,4:Channel5,5:Channel6,6:Channel7,7:Channel8,8:Channel9,9:Channel10,10:Channel11,11:Channel12,12:Channel13,13:Channel14,14:Channel15,15:Channel16, 16:Channel 17, 17: Channel 18, 18: Channel 19, 19: Channel 20, 20: Channel 21, 21: Channel 22, 22: Channel 23, 23: Channel 24, 24: Channel 25, 25: Channel 26, 26: Channel 27, 27: Channel 28, 28: Channel 29, 29: Channel 30, 30: Channel 31, 31: Channel 32 // @User: Advanced // @RebootRequired: True AP_GROUPINFO("MASK", 1, AP_BLHeli, channel_mask, 0), #if APM_BUILD_COPTER_OR_HELI || APM_BUILD_TYPE(APM_BUILD_ArduPlane) || APM_BUILD_TYPE(APM_BUILD_Rover) // @Param: AUTO // @DisplayName: BLHeli pass-thru auto-enable for multicopter motors // @Description: If set to 1 this auto-enables BLHeli pass-thru support for all multicopter motors // @Values: 0:Disabled,1:Enabled // @User: Standard // @RebootRequired: True AP_GROUPINFO("AUTO", 2, AP_BLHeli, channel_auto, 0), #endif // @Param: TEST // @DisplayName: BLHeli internal interface test // @Description: Setting SERVO_BLH_TEST to a motor number enables an internal test of the BLHeli ESC protocol to the corresponding ESC. The debug output is displayed on the USB console. // @Values: 0:Disabled,1:TestMotor1,2:TestMotor2,3:TestMotor3,4:TestMotor4,5:TestMotor5,6:TestMotor6,7:TestMotor7,8:TestMotor8 // @User: Advanced AP_GROUPINFO("TEST", 3, AP_BLHeli, run_test, 0), // @Param: TMOUT // @DisplayName: BLHeli protocol timeout // @Description: This sets the inactivity timeout for the BLHeli protocol in seconds. If no packets are received in this time normal MAVLink operations are resumed. A value of 0 means no timeout // @Units: s // @Range: 0 300 // @User: Standard AP_GROUPINFO("TMOUT", 4, AP_BLHeli, timeout_sec, 0), // @Param: TRATE // @DisplayName: BLHeli telemetry rate // @Description: This sets the rate in Hz for requesting telemetry from ESCs. It is the rate per ESC. Setting to zero disables telemetry requests // @Units: Hz // @Range: 0 500 // @User: Standard AP_GROUPINFO("TRATE", 5, AP_BLHeli, telem_rate, 10), // @Param: DEBUG // @DisplayName: BLHeli debug level // @Description: When set to 1 this enabled verbose debugging output over MAVLink when the blheli protocol is active. This can be used to diagnose failures. // @Values: 0:Disabled,1:Enabled // @User: Standard AP_GROUPINFO("DEBUG", 6, AP_BLHeli, debug_level, 0), // @Param: OTYPE // @DisplayName: BLHeli output type override // @Description: When set to a non-zero value this overrides the output type for the output channels given by SERVO_BLH_MASK. This can be used to enable DShot on outputs that are not part of the multicopter motors group. // @Values: 0:None,1:OneShot,2:OneShot125,3:Brushed,4:DShot150,5:DShot300,6:DShot600,7:DShot1200 // @User: Advanced // @RebootRequired: True AP_GROUPINFO("OTYPE", 7, AP_BLHeli, output_type, 0), // @Param: PORT // @DisplayName: Control port // @Description: This sets the mavlink channel to use for blheli pass-thru. The channel number is determined by the number of serial ports configured to use mavlink. So 0 is always the console, 1 is the next serial port using mavlink, 2 the next after that and so on. // @Values: 0:Console,1:Mavlink Serial Channel1,2:Mavlink Serial Channel2,3:Mavlink Serial Channel3,4:Mavlink Serial Channel4,5:Mavlink Serial Channel5 // @User: Advanced AP_GROUPINFO("PORT", 8, AP_BLHeli, control_port, 0), // @Param: POLES // @DisplayName: BLHeli Motor Poles // @Description: This allows calculation of true RPM from ESC's eRPM. The default is 14. // @Range: 1 127 // @User: Advanced // @RebootRequired: True AP_GROUPINFO("POLES", 9, AP_BLHeli, motor_poles, 14), // @Param: 3DMASK // @DisplayName: BLHeli bitmask of 3D channels // @Description: Mask of channels which are dynamically reversible. This is used to configure ESCs in '3D' mode, allowing for the motor to spin in either direction // @Bitmask: 0:Channel1,1:Channel2,2:Channel3,3:Channel4,4:Channel5,5:Channel6,6:Channel7,7:Channel8,8:Channel9,9:Channel10,10:Channel11,11:Channel12,12:Channel13,13:Channel14,14:Channel15,15:Channel16, 16:Channel 17, 17: Channel 18, 18: Channel 19, 19: Channel 20, 20: Channel 21, 21: Channel 22, 22: Channel 23, 23: Channel 24, 24: Channel 25, 25: Channel 26, 26: Channel 27, 27: Channel 28, 28: Channel 29, 29: Channel 30, 30: Channel 31, 31: Channel 32 // @User: Advanced // @RebootRequired: True AP_GROUPINFO("3DMASK", 10, AP_BLHeli, channel_reversible_mask, 0), #if defined(HAL_WITH_BIDIR_DSHOT) || HAL_WITH_IO_MCU_BIDIR_DSHOT // @Param: BDMASK // @DisplayName: BLHeli bitmask of bi-directional dshot channels // @Description: Mask of channels which support bi-directional dshot. This is used for ESCs which have firmware that supports bi-directional dshot allowing fast rpm telemetry values to be returned for the harmonic notch. // @Bitmask: 0:Channel1,1:Channel2,2:Channel3,3:Channel4,4:Channel5,5:Channel6,6:Channel7,7:Channel8,8:Channel9,9:Channel10,10:Channel11,11:Channel12,12:Channel13,13:Channel14,14:Channel15,15:Channel16, 16:Channel 17, 17: Channel 18, 18: Channel 19, 19: Channel 20, 20: Channel 21, 21: Channel 22, 22: Channel 23, 23: Channel 24, 24: Channel 25, 25: Channel 26, 26: Channel 27, 27: Channel 28, 28: Channel 29, 29: Channel 30, 30: Channel 31, 31: Channel 32 // @User: Advanced // @RebootRequired: True AP_GROUPINFO("BDMASK", 11, AP_BLHeli, channel_bidir_dshot_mask, 0), #endif // @Param: RVMASK // @DisplayName: BLHeli bitmask of reversed channels // @Description: Mask of channels which are reversed. This is used to configure ESCs in reversed mode // @Bitmask: 0:Channel1,1:Channel2,2:Channel3,3:Channel4,4:Channel5,5:Channel6,6:Channel7,7:Channel8,8:Channel9,9:Channel10,10:Channel11,11:Channel12,12:Channel13,13:Channel14,14:Channel15,15:Channel16, 16:Channel 17, 17: Channel 18, 18: Channel 19, 19: Channel 20, 20: Channel 21, 21: Channel 22, 22: Channel 23, 23: Channel 24, 24: Channel 25, 25: Channel 26, 26: Channel 27, 27: Channel 28, 28: Channel 29, 29: Channel 30, 30: Channel 31, 31: Channel 32 // @User: Advanced // @RebootRequired: True AP_GROUPINFO("RVMASK", 12, AP_BLHeli, channel_reversed_mask, 0), AP_GROUPEND }; #define RPM_SLEW_RATE 50 AP_BLHeli *AP_BLHeli::_singleton; // constructor AP_BLHeli::AP_BLHeli(void) { // set defaults from the parameter table AP_Param::setup_object_defaults(this, var_info); _singleton = this; last_control_port = -1; } /* process one byte of serial input for MSP protocol */ bool AP_BLHeli::msp_process_byte(uint8_t c) { if (msp.state == MSP_IDLE) { msp.escMode = PROTOCOL_NONE; if (c == '$') { msp.state = MSP_HEADER_START; } else { return false; } } else if (msp.state == MSP_HEADER_START) { msp.state = (c == 'M') ? MSP_HEADER_M : MSP_IDLE; } else if (msp.state == MSP_HEADER_M) { msp.state = MSP_IDLE; switch (c) { case '<': // COMMAND msp.packetType = MSP_PACKET_COMMAND; msp.state = MSP_HEADER_ARROW; break; case '>': // REPLY msp.packetType = MSP_PACKET_REPLY; msp.state = MSP_HEADER_ARROW; break; default: break; } } else if (msp.state == MSP_HEADER_ARROW) { if (c > sizeof(msp.buf)) { msp.state = MSP_IDLE; } else { msp.dataSize = c; msp.offset = 0; msp.checksum = 0; msp.checksum ^= c; msp.state = MSP_HEADER_SIZE; } } else if (msp.state == MSP_HEADER_SIZE) { msp.cmdMSP = c; msp.checksum ^= c; msp.state = MSP_HEADER_CMD; } else if (msp.state == MSP_HEADER_CMD && msp.offset < msp.dataSize) { msp.checksum ^= c; msp.buf[msp.offset++] = c; } else if (msp.state == MSP_HEADER_CMD && msp.offset >= msp.dataSize) { if (msp.checksum == c) { msp.state = MSP_COMMAND_RECEIVED; } else { msp.state = MSP_IDLE; } } return true; } /* update CRC state for blheli protocol */ void AP_BLHeli::blheli_crc_update(uint8_t c) { blheli.crc = crc_xmodem_update(blheli.crc, c); } /* process one byte of serial input for blheli 4way protocol */ bool AP_BLHeli::blheli_4way_process_byte(uint8_t c) { if (blheli.state == BLHELI_IDLE) { if (c == cmd_Local_Escape) { blheli.state = BLHELI_HEADER_START; blheli.crc = 0; blheli_crc_update(c); } else { return false; } } else if (blheli.state == BLHELI_HEADER_START) { blheli.command = c; blheli_crc_update(c); blheli.state = BLHELI_HEADER_CMD; } else if (blheli.state == BLHELI_HEADER_CMD) { blheli.address = c<<8; blheli.state = BLHELI_HEADER_ADDR_HIGH; blheli_crc_update(c); } else if (blheli.state == BLHELI_HEADER_ADDR_HIGH) { blheli.address |= c; blheli.state = BLHELI_HEADER_ADDR_LOW; blheli_crc_update(c); } else if (blheli.state == BLHELI_HEADER_ADDR_LOW) { blheli.state = BLHELI_HEADER_LEN; blheli.param_len = c?c:256; blheli.offset = 0; blheli_crc_update(c); } else if (blheli.state == BLHELI_HEADER_LEN) { blheli.buf[blheli.offset++] = c; blheli_crc_update(c); if (blheli.offset == blheli.param_len) { blheli.state = BLHELI_CRC1; } } else if (blheli.state == BLHELI_CRC1) { blheli.crc1 = c; blheli.state = BLHELI_CRC2; } else if (blheli.state == BLHELI_CRC2) { uint16_t crc = blheli.crc1<<8 | c; if (crc == blheli.crc) { blheli.state = BLHELI_COMMAND_RECEIVED; } else { blheli.state = BLHELI_IDLE; } } return true; } /* send a MSP protocol ack */ void AP_BLHeli::msp_send_ack(uint8_t cmd) { msp_send_reply(cmd, 0, 0); } /* send a MSP protocol reply */ void AP_BLHeli::msp_send_reply(uint8_t cmd, const uint8_t *buf, uint8_t len) { uint8_t *b = &msp.buf[0]; *b++ = '$'; *b++ = 'M'; *b++ = '>'; *b++ = len; *b++ = cmd; // acks do not have a payload if (len > 0) { memcpy(b, buf, len); } b += len; uint8_t c = 0; for (uint8_t i=0; iwrite_locked(&msp.buf[0], len+6, BLHELI_UART_LOCK_KEY); } void AP_BLHeli::putU16(uint8_t *b, uint16_t v) { b[0] = v; b[1] = v >> 8; } uint16_t AP_BLHeli::getU16(const uint8_t *b) { return b[0] | (b[1]<<8); } void AP_BLHeli::putU32(uint8_t *b, uint32_t v) { b[0] = v; b[1] = v >> 8; b[2] = v >> 16; b[3] = v >> 24; } void AP_BLHeli::putU16_BE(uint8_t *b, uint16_t v) { b[0] = v >> 8; b[1] = v; } /* process a MSP command from GCS */ void AP_BLHeli::msp_process_command(void) { debug("MSP cmd %u len=%u", msp.cmdMSP, msp.dataSize); switch (msp.cmdMSP) { case MSP_API_VERSION: { debug("MSP_API_VERSION"); uint8_t buf[3] = { MSP_PROTOCOL_VERSION, API_VERSION_MAJOR, API_VERSION_MINOR }; msp_send_reply(msp.cmdMSP, buf, sizeof(buf)); break; } case MSP_FC_VARIANT: debug("MSP_FC_VARIANT"); msp_send_reply(msp.cmdMSP, (const uint8_t *)ARDUPILOT_IDENTIFIER, FLIGHT_CONTROLLER_IDENTIFIER_LENGTH); break; /* Notes: version 3.3.1 adds a reply to MSP_SET_MOTOR which was missing version 3.3.0 requires a workaround in blheli suite to handle MSP_SET_MOTOR without an ack */ case MSP_FC_VERSION: { debug("MSP_FC_VERSION"); uint8_t version[3] = { 3, 3, 1 }; msp_send_reply(msp.cmdMSP, version, sizeof(version)); break; } case MSP_BOARD_INFO: { debug("MSP_BOARD_INFO"); // send a generic 'ArduPilot ChibiOS' board type uint8_t buf[7] = { 'A', 'R', 'C', 'H', 0, 0, 0 }; msp_send_reply(msp.cmdMSP, buf, sizeof(buf)); break; } case MSP_BUILD_INFO: { debug("MSP_BUILD_INFO"); // build date, build time, git version uint8_t buf[26] { 0x4d, 0x61, 0x72, 0x20, 0x31, 0x36, 0x20, 0x32, 0x30, 0x31, 0x38, 0x30, 0x38, 0x3A, 0x34, 0x32, 0x3a, 0x32, 0x39, 0x62, 0x30, 0x66, 0x66, 0x39, 0x32, 0x38}; msp_send_reply(msp.cmdMSP, buf, sizeof(buf)); break; } case MSP_REBOOT: debug("MSP: ignoring reboot command, end serial comms"); hal.rcout->serial_end(); blheli.connected[blheli.chan] = false; serial_start_ms = 0; break; case MSP_UID: // MCU identifier debug("MSP_UID"); msp_send_reply(msp.cmdMSP, (const uint8_t *)UDID_START, 12); break; case MSP_ADVANCED_CONFIG: { debug("MSP_ADVANCED_CONFIG"); uint8_t buf[10]; buf[0] = 1; // gyro sync denom buf[1] = 4; // pid process denom buf[2] = 0; // use unsynced pwm buf[3] = (uint8_t)PWM_TYPE_DSHOT150; // motor PWM protocol putU16(&buf[4], 480); // motor PWM Rate putU16(&buf[6], 450); // idle offset value buf[8] = 0; // use 32kHz buf[9] = 0; // motor PWM inversion msp_send_reply(msp.cmdMSP, buf, sizeof(buf)); break; } case MSP_FEATURE_CONFIG: { debug("MSP_FEATURE_CONFIG"); uint8_t buf[4]; putU32(buf, (channel_reversible_mask.get() != 0) ? FEATURE_3D : 0); // from MSPFeatures enum msp_send_reply(msp.cmdMSP, buf, sizeof(buf)); break; } case MSP_STATUS: { debug("MSP_STATUS"); uint8_t buf[21]; putU16(&buf[0], 1000); // loop time usec putU16(&buf[2], 0); // i2c error count putU16(&buf[4], 0x27); // available sensors putU32(&buf[6], 0); // flight modes buf[10] = 0; // pid profile index putU16(&buf[11], 5); // system load percent putU16(&buf[13], 0); // gyro cycle time buf[15] = 0; // flight mode flags length buf[16] = 18; // arming disable flags count putU32(&buf[17], 0); // arming disable flags msp_send_reply(msp.cmdMSP, buf, sizeof(buf)); break; } case MSP_MOTOR_3D_CONFIG: { debug("MSP_MOTOR_3D_CONFIG"); uint8_t buf[6]; putU16(&buf[0], 1406); // 3D deadband low putU16(&buf[2], 1514); // 3D deadband high putU16(&buf[4], 1460); // 3D neutral msp_send_reply(msp.cmdMSP, buf, sizeof(buf)); break; } case MSP_BATTERY_STATE: { debug("MSP_BATTERY_STATE"); uint8_t buf[8]; buf[0] = 4; // cell count putU16(&buf[1], 1500); // mAh buf[3] = 16; // V putU16(&buf[4], 1500); // mAh putU16(&buf[6], 1); // A msp_send_reply(msp.cmdMSP, buf, sizeof(buf)); break; } case MSP_MOTOR_CONFIG: { debug("MSP_MOTOR_CONFIG"); uint8_t buf[10]; putU16(&buf[0], 1030); // min throttle putU16(&buf[2], 2000); // max throttle putU16(&buf[4], 1000); // min command // API 1.42 buf[6] = num_motors; // motorCount buf[7] = motor_poles; // motorPoleCount buf[8] = 0; // useDshotTelemetry buf[9] = 0; // FEATURE_ESC_SENSOR msp_send_reply(msp.cmdMSP, buf, sizeof(buf)); break; } case MSP_MOTOR: { debug("MSP_MOTOR"); // get the output going to each motor uint8_t buf[16] {}; for (uint8_t i = 0; i < num_motors; i++) { // if we have a mix of reversible and normal report a PWM of zero, this allows BLHeliSuite to conect uint16_t v = mixed_type ? 0 : hal.rcout->read(motor_map[i]); putU16(&buf[2*i], v); debug("MOTOR %u val: %u",i,v); } msp_send_reply(msp.cmdMSP, buf, sizeof(buf)); break; } case MSP_SET_MOTOR: { debug("MSP_SET_MOTOR"); if (!mixed_type) { // set the output to each motor uint8_t nmotors = msp.dataSize / 2; debug("MSP_SET_MOTOR %u", nmotors); motors_disabled_mask = SRV_Channels::get_disabled_channel_mask(); SRV_Channels::set_disabled_channel_mask(0xFFFF); motors_disabled = true; EXPECT_DELAY_MS(1000); hal.rcout->cork(); for (uint8_t i = 0; i < nmotors; i++) { if (i >= num_motors) { break; } uint16_t v = getU16(&msp.buf[i*2]); debug("MSP_SET_MOTOR %u %u", i, v); // map from a MSP value to a value in the range 1000 to 2000 uint16_t pwm = (v < 1000)?0:v; hal.rcout->write(motor_map[i], pwm); } hal.rcout->push(); } else { debug("mixed type, Motors Disabled"); } msp_send_ack(msp.cmdMSP); break; } case MSP_SET_PASSTHROUGH: { debug("MSP_SET_PASSTHROUGH"); if (msp.dataSize == 0) { msp.escMode = PROTOCOL_4WAY; } else if (msp.dataSize == 2) { msp.escMode = (enum escProtocol)msp.buf[0]; msp.portIndex = msp.buf[1]; } debug("escMode=%u portIndex=%u num_motors=%u", msp.escMode, msp.portIndex, num_motors); uint8_t n = num_motors; switch (msp.escMode) { case PROTOCOL_4WAY: break; default: n = 0; hal.rcout->serial_end(); serial_start_ms = 0; break; } // doing the serial setup here avoids delays when doing it on demand and makes // BLHeliSuite considerably more reliable EXPECT_DELAY_MS(1000); if (!hal.rcout->serial_setup_output(motor_map[0], 19200, motor_mask)) { msp_send_ack(ACK_D_GENERAL_ERROR); break; } else { msp_send_reply(msp.cmdMSP, &n, 1); } break; } default: debug("Unknown MSP command %u", msp.cmdMSP); break; } } /* send a blheli 4way protocol reply */ void AP_BLHeli::blheli_send_reply(const uint8_t *buf, uint16_t len) { uint8_t *b = &blheli.buf[0]; *b++ = cmd_Remote_Escape; *b++ = blheli.command; putU16_BE(b, blheli.address); b += 2; *b++ = len==256?0:len; memcpy(b, buf, len); b += len; *b++ = blheli.ack; putU16_BE(b, crc_xmodem(&blheli.buf[0], len+6)); uart->write_locked(&blheli.buf[0], len+8, BLHELI_UART_LOCK_KEY); debug("OutB(%u) 0x%02x ack=0x%02x", len+8, (unsigned)blheli.command, blheli.ack); } /* CRC used when talking to ESCs */ uint16_t AP_BLHeli::BL_CRC(const uint8_t *buf, uint16_t len) { uint16_t crc = 0; while (len--) { uint8_t xb = *buf++; for (uint8_t i = 0; i < 8; i++) { if (((xb & 0x01) ^ (crc & 0x0001)) !=0 ) { crc = crc >> 1; crc = crc ^ 0xA001; } else { crc = crc >> 1; } xb = xb >> 1; } } return crc; } bool AP_BLHeli::isMcuConnected(void) { return blheli.connected[blheli.chan]; } void AP_BLHeli::setDisconnected(void) { blheli.connected[blheli.chan] = false; blheli.deviceInfo[blheli.chan][0] = 0; blheli.deviceInfo[blheli.chan][1] = 0; } /* send a set of bytes to an RC output channel */ bool AP_BLHeli::BL_SendBuf(const uint8_t *buf, uint16_t len) { bool send_crc = isMcuConnected(); if (blheli.chan >= num_motors) { return false; } EXPECT_DELAY_MS(1000); if (!hal.rcout->serial_setup_output(motor_map[blheli.chan], 19200, motor_mask)) { blheli.ack = ACK_D_GENERAL_ERROR; return false; } if (serial_start_ms == 0) { serial_start_ms = AP_HAL::millis(); } uint32_t now = AP_HAL::millis(); if (serial_start_ms == 0 || now - serial_start_ms < 1000) { /* we've just started the interface. We want it idle for at least 1 second before we start sending serial data. */ hal.scheduler->delay(1100); } memcpy(blheli.buf, buf, len); uint16_t crc = BL_CRC(buf, len); blheli.buf[len] = crc; blheli.buf[len+1] = crc>>8; if (!hal.rcout->serial_write_bytes(blheli.buf, len+(send_crc?2:0))) { blheli.ack = ACK_D_GENERAL_ERROR; return false; } // 19200 baud is 52us per bit - wait for half a bit between sending and receiving to avoid reading // the end of the last sent bit by accident hal.scheduler->delay_microseconds(26); return true; } /* read bytes from the ESC connection */ bool AP_BLHeli::BL_ReadBuf(uint8_t *buf, uint16_t len) { bool check_crc = isMcuConnected() && len > 0; uint16_t req_bytes = len+(check_crc?3:1); EXPECT_DELAY_MS(1000); uint16_t n = hal.rcout->serial_read_bytes(blheli.buf, req_bytes); debug("BL_ReadBuf %u -> %u", len, n); if (req_bytes != n) { debug("short read"); blheli.ack = ACK_D_GENERAL_ERROR; return false; } if (check_crc) { uint16_t crc = BL_CRC(blheli.buf, len); if ((crc & 0xff) != blheli.buf[len] || (crc >> 8) != blheli.buf[len+1]) { debug("bad CRC"); blheli.ack = ACK_D_GENERAL_ERROR; return false; } if (blheli.buf[len+2] != brSUCCESS) { debug("bad ACK 0x%02x", blheli.buf[len+2]); blheli.ack = ACK_D_GENERAL_ERROR; return false; } } else { if (blheli.buf[len] != brSUCCESS) { debug("bad ACK1 0x%02x", blheli.buf[len]); blheli.ack = ACK_D_GENERAL_ERROR; return false; } } if (len > 0) { memcpy(buf, blheli.buf, len); } return true; } uint8_t AP_BLHeli::BL_GetACK(uint16_t timeout_ms) { uint8_t ack; uint32_t start_ms = AP_HAL::millis(); EXPECT_DELAY_MS(1000); while (AP_HAL::millis() - start_ms < timeout_ms) { if (hal.rcout->serial_read_bytes(&ack, 1) == 1) { return ack; } } // return brNONE, meaning no ACK received in the timeout return brNONE; } bool AP_BLHeli::BL_SendCMDSetAddress() { // skip if adr == 0xFFFF if (blheli.address == 0xFFFF) { return true; } debug("BL_SendCMDSetAddress 0x%04x", blheli.address); uint8_t sCMD[] = {CMD_SET_ADDRESS, 0, uint8_t(blheli.address>>8), uint8_t(blheli.address)}; if (!BL_SendBuf(sCMD, 4)) { return false; } return BL_GetACK() == brSUCCESS; } bool AP_BLHeli::BL_ReadA(uint8_t cmd, uint8_t *buf, uint16_t n) { if (BL_SendCMDSetAddress()) { uint8_t sCMD[] = {cmd, uint8_t(n==256?0:n)}; if (!BL_SendBuf(sCMD, 2)) { return false; } bool ret = BL_ReadBuf(buf, n); if (ret && n == sizeof(esc_status) && blheli.address == esc_status_addr) { // display esc_status structure if we see it struct esc_status status; memcpy(&status, buf, n); debug("Prot %u Good %u Bad %u %x %x %x x%x\n", (unsigned)status.protocol, (unsigned)status.good_frames, (unsigned)status.bad_frames, (unsigned)status.unknown[0], (unsigned)status.unknown[1], (unsigned)status.unknown[2], (unsigned)status.unknown2); } return ret; } return false; } /* connect to a blheli ESC */ bool AP_BLHeli::BL_ConnectEx(void) { if (blheli.connected[blheli.chan] != 0) { debug("Using cached interface 0x%x for %u", blheli.interface_mode[blheli.chan], blheli.chan); return true; } debug("BL_ConnectEx %u/%u at %u", blheli.chan, num_motors, motor_map[blheli.chan]); setDisconnected(); const uint8_t BootInit[] = {0,0,0,0,0,0,0,0,0,0,0,0,0x0D,'B','L','H','e','l','i',0xF4,0x7D}; if (!BL_SendBuf(BootInit, 21)) { return false; } uint8_t BootInfo[8]; if (!BL_ReadBuf(BootInfo, 8)) { return false; } // reply must start with 471 if (strncmp((const char *)BootInfo, "471", 3) != 0) { blheli.ack = ACK_D_GENERAL_ERROR; return false; } // extract device information blheli.deviceInfo[blheli.chan][2] = BootInfo[3]; blheli.deviceInfo[blheli.chan][1] = BootInfo[4]; blheli.deviceInfo[blheli.chan][0] = BootInfo[5]; blheli.interface_mode[blheli.chan] = 0; uint16_t devword; memcpy(&devword, blheli.deviceInfo[blheli.chan], sizeof(devword)); switch (devword) { case 0x9307: case 0x930A: case 0x930F: case 0x940B: blheli.interface_mode[blheli.chan] = imATM_BLB; debug("Interface type imATM_BLB"); break; case 0xF310: case 0xF330: case 0xF410: case 0xF390: case 0xF850: case 0xE8B1: case 0xE8B2: blheli.interface_mode[blheli.chan] = imSIL_BLB; debug("Interface type imSIL_BLB"); break; default: // BLHeli_32 MCU ID hi > 0x00 and < 0x90 / lo always = 0x06 if ((blheli.deviceInfo[blheli.chan][1] > 0x00) && (blheli.deviceInfo[blheli.chan][1] < 0x90) && (blheli.deviceInfo[blheli.chan][0] == 0x06)) { blheli.interface_mode[blheli.chan] = imARM_BLB; debug("Interface type imARM_BLB"); } else { blheli.ack = ACK_D_GENERAL_ERROR; debug("Unknown interface type 0x%04x", devword); break; } } blheli.deviceInfo[blheli.chan][3] = blheli.interface_mode[blheli.chan]; if (blheli.interface_mode[blheli.chan] != 0) { blheli.connected[blheli.chan] = true; } return true; } bool AP_BLHeli::BL_SendCMDKeepAlive(void) { uint8_t sCMD[] = {CMD_KEEP_ALIVE, 0}; if (!BL_SendBuf(sCMD, 2)) { return false; } if (BL_GetACK() != brERRORCOMMAND) { return false; } return true; } bool AP_BLHeli::BL_PageErase(void) { if (BL_SendCMDSetAddress()) { uint8_t sCMD[] = {CMD_ERASE_FLASH, 0x01}; if (!BL_SendBuf(sCMD, 2)) { return false; } return BL_GetACK(3000) == brSUCCESS; } return false; } void AP_BLHeli::BL_SendCMDRunRestartBootloader(void) { uint8_t sCMD[] = {RestartBootloader, 0}; blheli.deviceInfo[blheli.chan][0] = 1; BL_SendBuf(sCMD, 2); } uint8_t AP_BLHeli::BL_SendCMDSetBuffer(const uint8_t *buf, uint16_t nbytes) { uint8_t sCMD[] = {CMD_SET_BUFFER, 0, uint8_t(nbytes>>8), uint8_t(nbytes&0xff)}; if (!BL_SendBuf(sCMD, 4)) { return false; } uint8_t ack; if ((ack = BL_GetACK()) != brNONE) { debug("BL_SendCMDSetBuffer ack failed 0x%02x", ack); blheli.ack = ACK_D_GENERAL_ERROR; return false; } if (!BL_SendBuf(buf, nbytes)) { debug("BL_SendCMDSetBuffer send failed"); blheli.ack = ACK_D_GENERAL_ERROR; return false; } return (BL_GetACK(40) == brSUCCESS); } bool AP_BLHeli::BL_WriteA(uint8_t cmd, const uint8_t *buf, uint16_t nbytes, uint32_t timeout_ms) { if (BL_SendCMDSetAddress()) { if (!BL_SendCMDSetBuffer(buf, nbytes)) { blheli.ack = ACK_D_GENERAL_ERROR; return false; } uint8_t sCMD[] = {cmd, 0x01}; if (!BL_SendBuf(sCMD, 2)) { return false; } return (BL_GetACK(timeout_ms) == brSUCCESS); } blheli.ack = ACK_D_GENERAL_ERROR; return false; } uint8_t AP_BLHeli::BL_WriteFlash(const uint8_t *buf, uint16_t n) { return BL_WriteA(CMD_PROG_FLASH, buf, n, 500); } bool AP_BLHeli::BL_VerifyFlash(const uint8_t *buf, uint16_t n) { if (BL_SendCMDSetAddress()) { if (!BL_SendCMDSetBuffer(buf, n)) { return false; } uint8_t sCMD[] = {CMD_VERIFY_FLASH_ARM, 0x01}; if (!BL_SendBuf(sCMD, 2)) { return false; } uint8_t ack = BL_GetACK(40); switch (ack) { case brSUCCESS: blheli.ack = ACK_OK; break; case brERRORVERIFY: blheli.ack = ACK_I_VERIFY_ERROR; break; default: blheli.ack = ACK_D_GENERAL_ERROR; break; } return true; } return false; } /* process a blheli 4way command from GCS */ void AP_BLHeli::blheli_process_command(void) { debug("BLHeli cmd 0x%02x len=%u", blheli.command, blheli.param_len); blheli.ack = ACK_OK; switch (blheli.command) { case cmd_InterfaceTestAlive: { debug("cmd_InterfaceTestAlive"); BL_SendCMDKeepAlive(); if (blheli.ack != ACK_OK) { setDisconnected(); } uint8_t b = 0; blheli_send_reply(&b, 1); break; } case cmd_ProtocolGetVersion: { debug("cmd_ProtocolGetVersion"); uint8_t buf[1]; buf[0] = SERIAL_4WAY_PROTOCOL_VER; blheli_send_reply(buf, sizeof(buf)); break; } case cmd_InterfaceGetName: { debug("cmd_InterfaceGetName"); uint8_t buf[5] = { 4, 'A', 'R', 'D', 'U' }; blheli_send_reply(buf, sizeof(buf)); break; } case cmd_InterfaceGetVersion: { debug("cmd_InterfaceGetVersion"); uint8_t buf[2] = { SERIAL_4WAY_VERSION_HI, SERIAL_4WAY_VERSION_LO }; blheli_send_reply(buf, sizeof(buf)); break; } case cmd_InterfaceExit: { debug("cmd_InterfaceExit"); msp.escMode = PROTOCOL_NONE; uint8_t b = 0; blheli_send_reply(&b, 1); hal.rcout->serial_end(); serial_start_ms = 0; if (motors_disabled) { motors_disabled = false; SRV_Channels::set_disabled_channel_mask(motors_disabled_mask); } if (uart_locked) { debug("Unlocked UART"); uart->lock_port(0, 0); uart_locked = false; } memset(blheli.connected, 0, sizeof(blheli.connected)); break; } case cmd_DeviceReset: { debug("cmd_DeviceReset(%u)", unsigned(blheli.buf[0])); if (blheli.buf[0] >= num_motors) { debug("bad reset channel %u", blheli.buf[0]); blheli.ack = ACK_I_INVALID_CHANNEL; blheli_send_reply(&blheli.buf[0], 1); break; } blheli.chan = blheli.buf[0]; switch (blheli.interface_mode[blheli.chan]) { case imSIL_BLB: case imATM_BLB: case imARM_BLB: BL_SendCMDRunRestartBootloader(); break; case imSK: break; } blheli_send_reply(&blheli.chan, 1); setDisconnected(); break; } case cmd_DeviceInitFlash: { debug("cmd_DeviceInitFlash(%u)", unsigned(blheli.buf[0])); if (blheli.buf[0] >= num_motors) { debug("bad channel %u", blheli.buf[0]); blheli.ack = ACK_I_INVALID_CHANNEL; blheli_send_reply(&blheli.buf[0], 1); break; } blheli.chan = blheli.buf[0]; blheli.ack = ACK_OK; BL_ConnectEx(); uint8_t buf[4] = {blheli.deviceInfo[blheli.chan][0], blheli.deviceInfo[blheli.chan][1], blheli.deviceInfo[blheli.chan][2], blheli.deviceInfo[blheli.chan][3]}; // device ID blheli_send_reply(buf, sizeof(buf)); break; } case cmd_InterfaceSetMode: { debug("cmd_InterfaceSetMode(%u)", unsigned(blheli.buf[0])); blheli.interface_mode[blheli.chan] = blheli.buf[0]; blheli_send_reply(&blheli.interface_mode[blheli.chan], 1); break; } case cmd_DeviceRead: { uint16_t nbytes = blheli.buf[0]?blheli.buf[0]:256; debug("cmd_DeviceRead(%u) n=%u", blheli.chan, nbytes); uint8_t buf[nbytes]; uint8_t cmd = blheli.interface_mode[blheli.chan]==imATM_BLB?CMD_READ_FLASH_ATM:CMD_READ_FLASH_SIL; if (!BL_ReadA(cmd, buf, nbytes)) { nbytes = 1; } blheli_send_reply(buf, nbytes); break; } case cmd_DevicePageErase: { uint8_t page = blheli.buf[0]; debug("cmd_DevicePageErase(%u) im=%u", page, blheli.interface_mode[blheli.chan]); switch (blheli.interface_mode[blheli.chan]) { case imSIL_BLB: case imARM_BLB: { if (blheli.interface_mode[blheli.chan] == imARM_BLB) { // Address =Page * 1024 blheli.address = page << 10; } else { // Address =Page * 512 blheli.address = page << 9; } debug("ARM PageErase 0x%04x", blheli.address); BL_PageErase(); blheli.address = 0; blheli_send_reply(&page, 1); break; } default: blheli.ack = ACK_I_INVALID_CMD; blheli_send_reply(&page, 1); break; } break; } case cmd_DeviceWrite: { uint16_t nbytes = blheli.param_len; debug("cmd_DeviceWrite n=%u im=%u", nbytes, blheli.interface_mode[blheli.chan]); uint8_t buf[nbytes]; memcpy(buf, blheli.buf, nbytes); switch (blheli.interface_mode[blheli.chan]) { case imSIL_BLB: case imATM_BLB: case imARM_BLB: { BL_WriteFlash(buf, nbytes); break; } case imSK: { debug("Unsupported flash mode imSK"); break; } } uint8_t b=0; blheli_send_reply(&b, 1); break; } case cmd_DeviceVerify: { uint16_t nbytes = blheli.param_len; debug("cmd_DeviceWrite n=%u im=%u", nbytes, blheli.interface_mode[blheli.chan]); switch (blheli.interface_mode[blheli.chan]) { case imARM_BLB: { uint8_t buf[nbytes]; memcpy(buf, blheli.buf, nbytes); BL_VerifyFlash(buf, nbytes); break; } default: blheli.ack = ACK_I_INVALID_CMD; break; } uint8_t b=0; blheli_send_reply(&b, 1); break; } case cmd_DeviceReadEEprom: { uint16_t nbytes = blheli.buf[0]?blheli.buf[0]:256; uint8_t buf[nbytes]; debug("cmd_DeviceReadEEprom n=%u im=%u", nbytes, blheli.interface_mode[blheli.chan]); switch (blheli.interface_mode[blheli.chan]) { case imATM_BLB: { if (!BL_ReadA(CMD_READ_EEPROM, buf, nbytes)) { blheli.ack = ACK_D_GENERAL_ERROR; } break; } default: blheli.ack = ACK_I_INVALID_CMD; break; } if (blheli.ack != ACK_OK) { nbytes = 1; buf[0] = 0; } blheli_send_reply(buf, nbytes); break; } case cmd_DeviceWriteEEprom: { uint16_t nbytes = blheli.param_len; uint8_t buf[nbytes]; memcpy(buf, blheli.buf, nbytes); debug("cmd_DeviceWriteEEprom n=%u im=%u", nbytes, blheli.interface_mode[blheli.chan]); switch (blheli.interface_mode[blheli.chan]) { case imATM_BLB: BL_WriteA(CMD_PROG_EEPROM, buf, nbytes, 3000); break; default: blheli.ack = ACK_D_GENERAL_ERROR; break; } uint8_t b = 0; blheli_send_reply(&b, 1); break; } case cmd_DeviceEraseAll: case cmd_DeviceC2CK_LOW: default: // ack=unknown command blheli.ack = ACK_I_INVALID_CMD; debug("Unknown BLHeli protocol 0x%02x", blheli.command); uint8_t b = 0; blheli_send_reply(&b, 1); break; } } /* process an input byte, return true if we have received a whole packet with correct CRC */ bool AP_BLHeli::process_input(uint8_t b) { bool valid_packet = false; if (msp.escMode == PROTOCOL_4WAY && blheli.state == BLHELI_IDLE && b == '$') { debug("Change to MSP mode"); msp.escMode = PROTOCOL_NONE; hal.rcout->serial_end(); serial_start_ms = 0; } if (msp.escMode != PROTOCOL_4WAY && msp.state == MSP_IDLE && b == '/') { debug("Change to BLHeli mode"); memset(blheli.connected, 0, sizeof(blheli.connected)); msp.escMode = PROTOCOL_4WAY; } if (msp.escMode == PROTOCOL_4WAY) { blheli_4way_process_byte(b); } else { msp_process_byte(b); } if (msp.escMode == PROTOCOL_4WAY) { if (blheli.state == BLHELI_COMMAND_RECEIVED) { valid_packet = true; last_valid_ms = AP_HAL::millis(); if (uart->lock_port(BLHELI_UART_LOCK_KEY, 0)) { uart_locked = true; } blheli_process_command(); blheli.state = BLHELI_IDLE; msp.state = MSP_IDLE; } } else if (msp.state == MSP_COMMAND_RECEIVED) { if (msp.packetType == MSP_PACKET_COMMAND) { valid_packet = true; if (uart->lock_port(BLHELI_UART_LOCK_KEY, 0)) { uart_locked = true; } last_valid_ms = AP_HAL::millis(); msp_process_command(); } msp.state = MSP_IDLE; blheli.state = BLHELI_IDLE; } return valid_packet; } /* protocol handler for detecting BLHeli input */ bool AP_BLHeli::protocol_handler(uint8_t b, AP_HAL::UARTDriver *_uart) { uart = _uart; if (hal.util->get_soft_armed()) { // don't allow MSP control when armed return false; } return process_input(b); } /* run a connection test to the ESCs. This is used to test the operation of the BLHeli ESC protocol */ void AP_BLHeli::run_connection_test(uint8_t chan) { run_test.set_and_notify(0); debug_uart = hal.console; uint8_t saved_chan = blheli.chan; if (chan >= num_motors) { GCS_SEND_TEXT(MAV_SEVERITY_INFO, "ESC: bad channel %u", chan); return; } blheli.chan = chan; GCS_SEND_TEXT(MAV_SEVERITY_INFO, "ESC: Running test on channel %u", blheli.chan); bool passed = false; for (uint8_t tries=0; tries<5; tries++) { EXPECT_DELAY_MS(3000); blheli.ack = ACK_OK; setDisconnected(); if (BL_ConnectEx()) { uint8_t buf[256]; uint8_t cmd = blheli.interface_mode[blheli.chan]==imATM_BLB?CMD_READ_FLASH_ATM:CMD_READ_FLASH_SIL; passed = true; blheli.address = blheli.interface_mode[blheli.chan]==imATM_BLB?0:0x7c00; passed &= BL_ReadA(cmd, buf, sizeof(buf)); if (blheli.interface_mode[blheli.chan]==imARM_BLB) { if (passed) { // read status structure blheli.address = esc_status_addr; passed &= BL_SendCMDSetAddress(); } if (passed) { struct esc_status status; passed &= BL_ReadA(CMD_READ_FLASH_SIL, (uint8_t *)&status, sizeof(status)); } } BL_SendCMDRunRestartBootloader(); break; } } hal.rcout->serial_end(); SRV_Channels::set_disabled_channel_mask(motors_disabled_mask); motors_disabled = false; serial_start_ms = 0; blheli.chan = saved_chan; GCS_SEND_TEXT(MAV_SEVERITY_INFO, "ESC: Test %s", passed?"PASSED":"FAILED"); debug_uart = nullptr; } /* update BLHeli */ void AP_BLHeli::update(void) { bool motor_control_active = false; for (uint8_t i = 0; i < num_motors; i++) { bool reversed = ((1U<< motor_map[i]) & channel_reversible_mask.get()) != 0; if (hal.rcout->read( motor_map[i]) != (reversed ? 1500 : 1000)) { motor_control_active = true; } } uint32_t now = AP_HAL::millis(); if (initialised && uart_locked && ((timeout_sec && now - last_valid_ms > uint32_t(timeout_sec.get())*1000U) || (motor_control_active && now - last_valid_ms > MOTOR_ACTIVE_TIMEOUT))) { // we're not processing requests any more, shutdown serial // output if (serial_start_ms) { hal.rcout->serial_end(); serial_start_ms = 0; } if (motors_disabled) { motors_disabled = false; SRV_Channels::set_disabled_channel_mask(motors_disabled_mask); } if (uart != nullptr) { debug("Unlocked UART"); uart->lock_port(0, 0); uart_locked = false; } if (motor_control_active) { for (uint8_t i = 0; i < num_motors; i++) { bool reversed = ((1U<write(motor_map[i], reversed ? 1500 : 1000); } } } if (initialised || (channel_mask.get() == 0 && channel_auto.get() == 0)) { if (initialised && run_test.get() > 0) { run_connection_test(run_test.get() - 1); } } } /* Initialize BLHeli, called by SRV_Channels::init() Used to install protocol handler The motor mask of enabled motors can be passed in */ void AP_BLHeli::init(uint32_t mask, AP_HAL::RCOutput::output_mode otype) { initialised = true; run_test.set_and_notify(0); #if HAL_GCS_ENABLED // only install pass-thru protocol handler if either auto or the motor mask are set if (channel_mask.get() != 0 || channel_auto.get() != 0) { if (last_control_port > 0 && last_control_port != control_port) { gcs().install_alternative_protocol((mavlink_channel_t)(MAVLINK_COMM_0+last_control_port), nullptr); last_control_port = -1; } if (gcs().install_alternative_protocol((mavlink_channel_t)(MAVLINK_COMM_0+control_port), FUNCTOR_BIND_MEMBER(&AP_BLHeli::protocol_handler, bool, uint8_t, AP_HAL::UARTDriver *))) { debug("BLHeli installed on port %u", (unsigned)control_port); last_control_port = control_port; } } #endif // HAL_GCS_ENABLED #if HAL_WITH_IO_MCU if (AP_BoardConfig::io_enabled()) { // with IOMCU the local (FMU) channels start at 8 chan_offset = 8; } #endif mask |= uint32_t(channel_mask.get()); /* allow mode override - this makes it possible to use DShot for rovers and subs, plus for quadplane fwd motors */ // +1 converts from AP_Motors::pwm_type to AP_HAL::RCOutput::output_mode and saves doing a param conversion // this is the only use of the param, but this is still a bit of a hack const int16_t type = output_type.get() + 1; if (otype == AP_HAL::RCOutput::MODE_PWM_NONE) { otype = ((type > AP_HAL::RCOutput::MODE_PWM_NONE) && (type < AP_HAL::RCOutput::MODE_NEOPIXEL)) ? AP_HAL::RCOutput::output_mode(type) : AP_HAL::RCOutput::MODE_PWM_NONE; } switch (otype) { case AP_HAL::RCOutput::MODE_PWM_ONESHOT: case AP_HAL::RCOutput::MODE_PWM_ONESHOT125: case AP_HAL::RCOutput::MODE_PWM_BRUSHED: case AP_HAL::RCOutput::MODE_PWM_DSHOT150: case AP_HAL::RCOutput::MODE_PWM_DSHOT300: case AP_HAL::RCOutput::MODE_PWM_DSHOT600: case AP_HAL::RCOutput::MODE_PWM_DSHOT1200: if (mask) { hal.rcout->set_output_mode(mask, otype); } break; default: break; } uint32_t digital_mask = 0; // setting the digital mask changes the min/max PWM values // it's important that this is NOT done for non-digital channels as otherwise // PWM min can result in motors turning. set for individual overrides first if (mask && hal.rcout->is_dshot_protocol(otype)) { digital_mask = mask; } #if APM_BUILD_COPTER_OR_HELI || APM_BUILD_TYPE(APM_BUILD_ArduPlane) || APM_BUILD_TYPE(APM_BUILD_Rover) /* plane and copter can use AP_Motors to get an automatic mask */ #if APM_BUILD_TYPE(APM_BUILD_Rover) AP_MotorsUGV *motors = AP::motors_ugv(); #else AP_Motors *motors = AP::motors(); #endif if (motors) { uint32_t motormask = motors->get_motor_mask(); // set the rest of the digital channels if (motors->is_digital_pwm_type()) { digital_mask |= motormask; } mask |= motormask; } #endif // tell SRV_Channels about ESC capabilities SRV_Channels::set_digital_outputs(digital_mask, uint32_t(channel_reversible_mask.get()) & digital_mask); // the dshot ESC type is required in order to send the reversed/reversible dshot command correctly hal.rcout->set_dshot_esc_type(SRV_Channels::get_dshot_esc_type()); hal.rcout->set_reversible_mask(uint32_t(channel_reversible_mask.get()) & digital_mask); hal.rcout->set_reversed_mask(uint32_t(channel_reversed_mask.get()) & digital_mask); #ifdef HAL_WITH_BIDIR_DSHOT // possibly enable bi-directional dshot hal.rcout->set_motor_poles(motor_poles); #endif #if defined(HAL_WITH_BIDIR_DSHOT) || HAL_WITH_IO_MCU_BIDIR_DSHOT hal.rcout->set_bidir_dshot_mask(uint32_t(channel_bidir_dshot_mask.get()) & digital_mask); #endif // add motors from channel mask for (uint8_t i=0; i<16 && num_motors < max_motors; i++) { if (mask & (1U< 0) { AP_SerialManager *serial_manager = AP_SerialManager::get_singleton(); if (serial_manager) { telem_uart = serial_manager->find_serial(AP_SerialManager::SerialProtocol_ESCTelemetry,0); } } } /* read an ESC telemetry packet */ void AP_BLHeli::read_telemetry_packet(void) { #if HAL_WITH_ESC_TELEM uint8_t buf[telem_packet_size]; if (telem_uart->read(buf, telem_packet_size) < telem_packet_size) { // short read, we should have 10 bytes ready when this function is called return; } // calculate crc uint8_t crc = 0; for (uint8_t i=0; iset_active_escs_mask(1<= 2) { uint16_t trpm = new_rpm; if (has_bidir_dshot(last_telem_esc)) { trpm = hal.rcout->get_erpm(motor_idx); if (trpm != 0xFFFF) { trpm = trpm * 200 / motor_poles; } } DEV_PRINTF("ESC[%u] T=%u V=%f C=%f con=%f RPM=%u e=%.1f t=%u\n", last_telem_esc, t.temperature_cdeg, t.voltage, t.current, t.consumption_mah, trpm, hal.rcout->get_erpm_error_rate(motor_idx), (unsigned)AP_HAL::millis()); } #endif // HAL_WITH_ESC_TELEM } /* log bidir telemetry - only called if BLH telemetry is not active */ void AP_BLHeli::log_bidir_telemetry(void) { uint32_t now = AP_HAL::millis(); if (debug_level >= 2 && now - last_log_ms[last_telem_esc] > 100) { if (has_bidir_dshot(last_telem_esc)) { const uint8_t motor_idx = motor_map[last_telem_esc]; uint16_t trpm = hal.rcout->get_erpm(motor_idx); if (trpm != 0xFFFF) { // don't log invalid values as they are never used trpm = trpm * 200 / motor_poles; } if (trpm > 0) { last_log_ms[last_telem_esc] = now; DEV_PRINTF("ESC[%u] RPM=%u e=%.1f t=%u\n", last_telem_esc, trpm, hal.rcout->get_erpm_error_rate(motor_idx), (unsigned)AP_HAL::millis()); } } } if (!SRV_Channels::have_digital_outputs()) { return; } // ask the next ESC for telemetry uint8_t idx_pos = last_telem_esc; uint8_t idx = (idx_pos + 1) % num_motors; for (; idx != idx_pos; idx = (idx + 1) % num_motors) { if (SRV_Channels::have_digital_outputs(1U << motor_map[idx])) { break; } } if (SRV_Channels::have_digital_outputs(1U << motor_map[idx])) { last_telem_esc = idx; } } /* update BLHeli telemetry handling This is called on push() in SRV_Channels */ void AP_BLHeli::update_telemetry(void) { #ifdef HAL_WITH_BIDIR_DSHOT // we might only have bi-dir dshot if (channel_bidir_dshot_mask.get() != 0 && !telem_uart) { log_bidir_telemetry(); } #endif if (!telem_uart || !SRV_Channels::have_digital_outputs()) { return; } uint32_t now = AP_HAL::micros(); uint32_t telem_rate_us = 1000000U / uint32_t(telem_rate.get() * num_motors); if (telem_rate_us < 2000) { // make sure we have a gap between frames telem_rate_us = 2000; } if (!telem_uart_started) { // we need to use begin() here to ensure the correct thread owns the uart telem_uart->begin(115200); telem_uart_started = true; } uint32_t nbytes = telem_uart->available(); if (nbytes > telem_packet_size) { // if we have more than 10 bytes then we don't know which ESC // they are from. Throw them all away telem_uart->discard_input(); return; } if (nbytes > 0 && nbytes < telem_packet_size && (last_telem_byte_read_us == 0 || now - last_telem_byte_read_us < 1000)) { // wait a bit longer, we don't have enough bytes yet if (last_telem_byte_read_us == 0) { last_telem_byte_read_us = now; } return; } if (nbytes > 0 && nbytes < telem_packet_size) { // we've waited long enough, discard bytes if we don't have 10 yet telem_uart->discard_input(); return; } if (nbytes == telem_packet_size) { // we have a full packet ready to parse read_telemetry_packet(); last_telem_byte_read_us = 0; } if (now - last_telem_request_us >= telem_rate_us) { // ask the next ESC for telemetry uint8_t idx_pos = last_telem_esc; uint8_t idx = (idx_pos + 1) % num_motors; for (; idx != idx_pos; idx = (idx + 1) % num_motors) { if (SRV_Channels::have_digital_outputs(1U << motor_map[idx])) { break; } } uint32_t mask = 1U << motor_map[idx]; if (SRV_Channels::have_digital_outputs(mask)) { hal.rcout->set_telem_request_mask(mask); last_telem_esc = idx; last_telem_request_us = now; } } } #endif // HAVE_AP_BLHELI_SUPPORT