/* * 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 . * * Author: Siddharth Bharat Purohit * Referenced from implementation by Pavel Kirienko * for Zubax Babel */ #include "AP_SLCANIface.h" #if HAL_MAX_CAN_PROTOCOL_DRIVERS #include #include #include "AP_CANManager.h" #include #include #include #define LOG_TAG "SLCAN" extern const AP_HAL::HAL& hal; const AP_Param::GroupInfo SLCAN::CANIface::var_info[] = { // @Param: CPORT // @DisplayName: SLCAN Route // @Description: CAN Interface ID to be routed to SLCAN, 0 means no routing // @Values: 0:Disabled,1:First interface,2:Second interface // @User: Standard // @RebootRequired: True AP_GROUPINFO("CPORT", 1, SLCAN::CANIface, _slcan_can_port, 0), // @Param: SERNUM // @DisplayName: SLCAN Serial Port // @Description: Serial Port ID to be used for temporary SLCAN iface, -1 means no temporary serial. This parameter is automatically reset on reboot or on timeout. See CAN_SLCAN_TIMOUT for timeout details // @Values: -1:Disabled,0:Serial0,1:Serial1,2:Serial2,3:Serial3,4:Serial4,5:Serial5,6:Serial6 // @User: Standard AP_GROUPINFO("SERNUM", 2, SLCAN::CANIface, _slcan_ser_port, -1), // @Param: TIMOUT // @DisplayName: SLCAN Timeout // @Description: Duration of inactivity after which SLCAN is switched back to original driver in seconds. // @Range: 0 127 // @User: Standard AP_GROUPINFO("TIMOUT", 3, SLCAN::CANIface, _slcan_timeout, 0), // @Param: SDELAY // @DisplayName: SLCAN Start Delay // @Description: Duration after which slcan starts after setting SERNUM in seconds. // @Range: 0 127 // @User: Standard AP_GROUPINFO("SDELAY", 4, SLCAN::CANIface, _slcan_start_delay, 1), AP_GROUPEND }; ////////Helper Methods////////// static bool hex2nibble_error; static uint8_t nibble2hex(uint8_t x) { // Allocating in RAM because it's faster static uint8_t ConversionTable[] = { '0', '1', '2', '3', '4', '5', '6', '7', '8', '9', 'A', 'B', 'C', 'D', 'E', 'F' }; return ConversionTable[x & 0x0F]; } static uint8_t hex2nibble(char c) { // Must go into RAM, not flash, because flash is slow static uint8_t NumConversionTable[] = { 0, 1, 2, 3, 4, 5, 6, 7, 8, 9 }; static uint8_t AlphaConversionTable[] = { 10, 11, 12, 13, 14, 15 }; uint8_t out = 255; if (c >= '0' && c <= '9') { out = NumConversionTable[int(c) - int('0')]; } else if (c >= 'a' && c <= 'f') { out = AlphaConversionTable[int(c) - int('a')]; } else if (c >= 'A' && c <= 'F') { out = AlphaConversionTable[int(c) - int('A')]; } if (out == 255) { hex2nibble_error = true; } return out; } bool SLCAN::CANIface::push_Frame(AP_HAL::CANFrame &frame) { AP_HAL::CANIface::CanRxItem frm; frm.frame = frame; frm.flags = 0; frm.timestamp_us = AP_HAL::native_micros64(); return rx_queue_.push(frm); } /** * General frame format: * * The emitting functions below are highly optimized for speed. */ bool SLCAN::CANIface::handle_FrameDataExt(const char* cmd) { AP_HAL::CANFrame f; hex2nibble_error = false; f.id = f.FlagEFF | (hex2nibble(cmd[1]) << 28) | (hex2nibble(cmd[2]) << 24) | (hex2nibble(cmd[3]) << 20) | (hex2nibble(cmd[4]) << 16) | (hex2nibble(cmd[5]) << 12) | (hex2nibble(cmd[6]) << 8) | (hex2nibble(cmd[7]) << 4) | (hex2nibble(cmd[8]) << 0); if (cmd[9] < '0' || cmd[9] > ('0' + AP_HAL::CANFrame::MaxDataLen)) { return false; } f.dlc = cmd[9] - '0'; if (f.dlc > AP_HAL::CANFrame::MaxDataLen) { return false; } { const char* p = &cmd[10]; for (unsigned i = 0; i < f.dlc; i++) { f.data[i] = (hex2nibble(*p) << 4) | hex2nibble(*(p + 1)); p += 2; } } if (hex2nibble_error) { return false; } return push_Frame(f); } bool SLCAN::CANIface::handle_FrameDataStd(const char* cmd) { AP_HAL::CANFrame f; hex2nibble_error = false; f.id = (hex2nibble(cmd[1]) << 8) | (hex2nibble(cmd[2]) << 4) | (hex2nibble(cmd[3]) << 0); if (cmd[4] < '0' || cmd[4] > ('0' + AP_HAL::CANFrame::MaxDataLen)) { return false; } f.dlc = cmd[4] - '0'; if (f.dlc > AP_HAL::CANFrame::MaxDataLen) { return false; } { const char* p = &cmd[5]; for (unsigned i = 0; i < f.dlc; i++) { f.data[i] = (hex2nibble(*p) << 4) | hex2nibble(*(p + 1)); p += 2; } } if (hex2nibble_error) { return false; } return push_Frame(f); } bool SLCAN::CANIface::handle_FrameRTRExt(const char* cmd) { AP_HAL::CANFrame f; hex2nibble_error = false; f.id = f.FlagEFF | f.FlagRTR | (hex2nibble(cmd[1]) << 28) | (hex2nibble(cmd[2]) << 24) | (hex2nibble(cmd[3]) << 20) | (hex2nibble(cmd[4]) << 16) | (hex2nibble(cmd[5]) << 12) | (hex2nibble(cmd[6]) << 8) | (hex2nibble(cmd[7]) << 4) | (hex2nibble(cmd[8]) << 0); if (cmd[9] < '0' || cmd[9] > ('0' + AP_HAL::CANFrame::MaxDataLen)) { return false; } f.dlc = cmd[9] - '0'; if (f.dlc > AP_HAL::CANFrame::MaxDataLen) { return false; } if (hex2nibble_error) { return false; } return push_Frame(f); } bool SLCAN::CANIface::handle_FrameRTRStd(const char* cmd) { AP_HAL::CANFrame f; hex2nibble_error = false; f.id = f.FlagRTR | (hex2nibble(cmd[1]) << 8) | (hex2nibble(cmd[2]) << 4) | (hex2nibble(cmd[3]) << 0); if (cmd[4] < '0' || cmd[4] > ('0' + AP_HAL::CANFrame::MaxDataLen)) { return false; } f.dlc = cmd[4] - '0'; if (f.dlc <= AP_HAL::CANFrame::MaxDataLen) { return false; } if (hex2nibble_error) { return false; } return push_Frame(f); } static inline const char* getASCIIStatusCode(bool status) { return status ? "\r" : "\a"; } bool SLCAN::CANIface::init_passthrough(uint8_t i) { // we setup undelying can iface here which we use for passthrough if (initialized_ || _slcan_can_port <= 0 || _slcan_can_port != i+1) { return false; } _can_iface = hal.can[i]; _iface_num = _slcan_can_port - 1; _prev_ser_port = -1; AP::can().log_text(AP_CANManager::LOG_INFO, LOG_TAG, "Setting SLCAN Passthrough for CAN%d\n", _slcan_can_port - 1); return true; } /** * General frame format: * [timestamp msec] [flags] * Types: * R - RTR extended * r - RTR standard * T - Data extended * t - Data standard * Flags: * L - this frame is a loopback frame; timestamp field contains TX timestamp */ int16_t SLCAN::CANIface::reportFrame(const AP_HAL::CANFrame& frame, uint64_t timestamp_usec) { if (_port == nullptr) { return -1; } constexpr unsigned SLCANMaxFrameSize = 40; uint8_t buffer[SLCANMaxFrameSize] = {'\0'}; uint8_t* p = &buffer[0]; /* * Frame type */ if (frame.isRemoteTransmissionRequest()) { *p++ = frame.isExtended() ? 'R' : 'r'; } else if (frame.isErrorFrame()) { return -1; // Not supported } else { *p++ = frame.isExtended() ? 'T' : 't'; } /* * ID */ { const uint32_t id = frame.id & frame.MaskExtID; if (frame.isExtended()) { *p++ = nibble2hex(id >> 28); *p++ = nibble2hex(id >> 24); *p++ = nibble2hex(id >> 20); *p++ = nibble2hex(id >> 16); *p++ = nibble2hex(id >> 12); } *p++ = nibble2hex(id >> 8); *p++ = nibble2hex(id >> 4); *p++ = nibble2hex(id >> 0); } /* * DLC */ *p++ = char('0' + frame.dlc); /* * Data */ for (unsigned i = 0; i < frame.dlc; i++) { const uint8_t byte = frame.data[i]; *p++ = nibble2hex(byte >> 4); *p++ = nibble2hex(byte); } /* * Timestamp */ { // SLCAN format - [0, 60000) milliseconds const auto slcan_timestamp = uint16_t(timestamp_usec / 1000U); *p++ = nibble2hex(slcan_timestamp >> 12); *p++ = nibble2hex(slcan_timestamp >> 8); *p++ = nibble2hex(slcan_timestamp >> 4); *p++ = nibble2hex(slcan_timestamp >> 0); } /* * Finalization */ *p++ = '\r'; const auto frame_size = unsigned(p - &buffer[0]); if (_port->txspace() < _pending_frame_size) { _pending_frame_size = frame_size; return 0; } //Write to Serial if (!_port->write_locked(&buffer[0], frame_size, _serial_lock_key)) { return 0; } return 1; } //Accepts command string, returns response string or nullptr if no response is needed. const char* SLCAN::CANIface::processCommand(char* cmd) { if (_port == nullptr) { return nullptr; } /* * High-traffic SLCAN commands go first */ if (cmd[0] == 'T') { return handle_FrameDataExt(cmd) ? "Z\r" : "\a"; } else if (cmd[0] == 't') { return handle_FrameDataStd(cmd) ? "z\r" : "\a"; } else if (cmd[0] == 'R') { return handle_FrameRTRExt(cmd) ? "Z\r" : "\a"; } else if (cmd[0] == 'r' && cmd[1] <= '9') { // The second condition is needed to avoid greedy matching // See long commands below return handle_FrameRTRStd(cmd) ? "z\r" : "\a"; } uint8_t resp_bytes[40]; uint16_t resp_len; /* * Regular SLCAN commands */ switch (cmd[0]) { case 'S': // Set CAN bitrate case 'O': // Open CAN in normal mode case 'L': // Open CAN in listen-only mode case 'l': // Open CAN with loopback enabled case 'C': // Close CAN case 'M': // Set CAN acceptance filter ID case 'm': // Set CAN acceptance filter mask case 'U': // Set UART baud rate, see http://www.can232.com/docs/can232_v3.pdf case 'Z': { // Enable/disable RX and loopback timestamping return getASCIIStatusCode(true); // Returning success for compatibility reasons } case 'F': { // Get status flags resp_len = snprintf((char*)resp_bytes, sizeof(resp_bytes), "F%02X\r", unsigned(0)); // Returning success for compatibility reasons if (resp_len > 0) { _port->write_locked(resp_bytes, resp_len, _serial_lock_key); } return nullptr; } case 'V': { // HW/SW version resp_len = snprintf((char*)resp_bytes, sizeof(resp_bytes),"V%x%x%x%x\r", 1, 0, 1, 0); if (resp_len > 0) { _port->write_locked(resp_bytes, resp_len, _serial_lock_key); } return nullptr; } case 'N': { // Serial number const uint8_t uid_buf_len = 12; uint8_t uid_len = uid_buf_len; uint8_t unique_id[uid_buf_len]; char buf[uid_buf_len * 2 + 1] = {'\0'}; char* pos = &buf[0]; if (hal.util->get_system_id_unformatted(unique_id, uid_len)) { for (uint8_t i = 0; i < uid_buf_len; i++) { *pos++ = nibble2hex(unique_id[i] >> 4); *pos++ = nibble2hex(unique_id[i]); } } *pos++ = '\0'; resp_len = snprintf((char*)resp_bytes, sizeof(resp_bytes),"N%s\r", &buf[0]); if (resp_len > 0) { _port->write_locked(resp_bytes, resp_len, _serial_lock_key); } return nullptr; } default: { break; } } return getASCIIStatusCode(false); } // add bytes to parse the received SLCAN Data stream inline void SLCAN::CANIface::addByte(const uint8_t byte) { if (_port == nullptr) { return; } if ((byte >= 32 && byte <= 126)) { // Normal printable ASCII character if (pos_ < SLCAN_BUFFER_SIZE) { buf_[pos_] = char(byte); pos_ += 1; } else { pos_ = 0; // Buffer overrun; silently drop the data } } else if (byte == '\r') { // End of command (SLCAN) // Processing the command buf_[pos_] = '\0'; const char* const response = processCommand(reinterpret_cast(&buf_[0])); pos_ = 0; // Sending the response if provided if (response != nullptr) { _port->write_locked(reinterpret_cast(response), strlen(response), _serial_lock_key); } } else if (byte == 8 || byte == 127) { // DEL or BS (backspace) if (pos_ > 0) { pos_ -= 1; } } else { // This also includes Ctrl+C, Ctrl+D pos_ = 0; // Invalid byte - drop the current command } } void SLCAN::CANIface::update_slcan_port() { if (_set_by_sermgr) { // Once we pick SerialManager path we hold on // to that until reboot return; } if (_port == nullptr) { _port = AP::serialmanager().find_serial(AP_SerialManager::SerialProtocol_SLCAN, 0); if (_port != nullptr) { _port->lock_port(_serial_lock_key, _serial_lock_key); _set_by_sermgr = true; return; } } if (_prev_ser_port != _slcan_ser_port) { if (!_slcan_start_req) { _slcan_start_req_time = AP_HAL::native_millis(); _slcan_start_req = true; } if (((AP_HAL::native_millis() - _slcan_start_req_time) < ((uint32_t)_slcan_start_delay*1000))) { return; } _port = AP::serialmanager().get_serial_by_id(_slcan_ser_port); if (_port == nullptr) { _slcan_ser_port.set_and_save(-1); return; } _port->lock_port(_serial_lock_key, _serial_lock_key); _prev_ser_port = _slcan_ser_port; gcs().send_text(MAV_SEVERITY_INFO, "CANManager: Starting SLCAN Passthrough on Serial %d with CAN%d", _slcan_ser_port.get(), _iface_num); _last_had_activity = AP_HAL::native_millis(); } if (_port == nullptr) { return; } if (((AP_HAL::native_millis() - _last_had_activity) > ((uint32_t)_slcan_timeout*1000)) && (uint32_t)_slcan_timeout != 0) { _port->lock_port(0, 0); _port = nullptr; _slcan_ser_port.set_and_save(-1); _prev_ser_port = -1; _slcan_start_req = false; } } bool SLCAN::CANIface::set_event_handle(AP_HAL::EventHandle* evt_handle) { // When in passthrough mode methods is handled through can iface if (_can_iface) { return _can_iface->set_event_handle(evt_handle); } return false; } uint16_t SLCAN::CANIface::getNumFilters() const { // When in passthrough mode methods is handled through can iface if (_can_iface) { return _can_iface->getNumFilters(); } return 0; } uint32_t SLCAN::CANIface::getErrorCount() const { // When in passthrough mode methods is handled through can iface if (_can_iface) { return _can_iface->getErrorCount(); } return 0; } void SLCAN::CANIface::get_stats(ExpandingString &str) { // When in passthrough mode methods is handled through can iface if (_can_iface) { _can_iface->get_stats(str); } } bool SLCAN::CANIface::is_busoff() const { // When in passthrough mode methods is handled through can iface if (_can_iface) { return _can_iface->is_busoff(); } return false; } bool SLCAN::CANIface::configureFilters(const CanFilterConfig* filter_configs, uint16_t num_configs) { // When in passthrough mode methods is handled through can iface if (_can_iface) { return _can_iface->configureFilters(filter_configs, num_configs); } return true; } void SLCAN::CANIface::flush_tx() { // When in passthrough mode methods is handled through can iface if (_can_iface) { _can_iface->flush_tx(); } if (_port) { _port->flush(); } } void SLCAN::CANIface::clear_rx() { // When in passthrough mode methods is handled through can iface if (_can_iface) { _can_iface->clear_rx(); } rx_queue_.clear(); } bool SLCAN::CANIface::is_initialized() const { // When in passthrough mode methods is handled through can iface if (_can_iface) { return _can_iface->is_initialized(); } return false; } bool SLCAN::CANIface::select(bool &read, bool &write, const AP_HAL::CANFrame* const pending_tx, uint64_t blocking_deadline) { update_slcan_port(); bool ret = false; // When in passthrough mode select is handled through can iface if (_can_iface) { ret = _can_iface->select(read, write, pending_tx, blocking_deadline); } if (_port == nullptr) { return ret; } // if under passthrough, we only do send when can_iface also allows it if (_port->available_locked(_serial_lock_key) || rx_queue_.available()) { // allow for receiving messages over slcan read = true; ret = true; } return ret; } // send method to transmit the frame through SLCAN interface int16_t SLCAN::CANIface::send(const AP_HAL::CANFrame& frame, uint64_t tx_deadline, AP_HAL::CANIface::CanIOFlags flags) { update_slcan_port(); int16_t ret = 0; // When in passthrough mode select is handled through can iface if (_can_iface) { ret = _can_iface->send(frame, tx_deadline, flags); } if (_port == nullptr) { return ret; } if (frame.isErrorFrame() || frame.dlc > 8) { return ret; } reportFrame(frame, AP_HAL::native_micros64()); return ret; } // receive method to read the frame recorded in the buffer int16_t SLCAN::CANIface::receive(AP_HAL::CANFrame& out_frame, uint64_t& rx_time, AP_HAL::CANIface::CanIOFlags& out_flags) { update_slcan_port(); // When in passthrough mode select is handled through can iface if (_can_iface) { int16_t ret = _can_iface->receive(out_frame, rx_time, out_flags); if (ret > 0) { // we also pass this frame through to slcan iface, // and immediately return reportFrame(out_frame, AP_HAL::native_micros64()); return ret; } else if (ret < 0) { return ret; } } // We found nothing in HAL's CANIface recieve, so look in SLCANIface if (_port == nullptr) { return 0; } if (_port->available_locked(_serial_lock_key)) { uint32_t num_bytes = _port->available_locked(_serial_lock_key); // flush bytes from port while (num_bytes--) { int16_t ret = _port->read_locked(_serial_lock_key); if (ret < 0) { break; } addByte(ret); if (!rx_queue_.space()) { break; } } } if (rx_queue_.available()) { // if we already have something in buffer transmit it CanRxItem frm; if (!rx_queue_.peek(frm)) { return 0; } out_frame = frm.frame; rx_time = frm.timestamp_us; out_flags = frm.flags; _last_had_activity = AP_HAL::millis(); // Also send this frame over can_iface when in passthrough mode, // We just push this frame without caring for priority etc if (_can_iface) { bool read = false; bool write = true; _can_iface->select(read, write, &out_frame, 0); // select without blocking if (write && _can_iface->send(out_frame, AP_HAL::native_micros64() + 100000, out_flags) == 1) { rx_queue_.pop(); num_tries = 0; } else if (num_tries > 8) { rx_queue_.pop(); num_tries = 0; } else { num_tries++; } } else { // we just throw away frames if we don't // have any can iface to pass through to rx_queue_.pop(); } return 1; } return 0; } void SLCAN::CANIface::reset_params() { _slcan_ser_port.set_and_save(-1); } #endif