/* 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 . SmartAudio protocol parsing and data structures taken from betaflight */ #include "AP_SmartAudio.h" #include #include #include #if HAL_SMARTAUDIO_ENABLED #ifdef SA_DEBUG # define debug(fmt, args...) do { hal.console->printf("SA: " fmt "\n", ##args); } while (0) #else # define debug(fmt, args...) do {} while(0) #endif extern const AP_HAL::HAL &hal; AP_SmartAudio::AP_SmartAudio() { _singleton = this; } AP_SmartAudio *AP_SmartAudio::_singleton; // initialization start making a request settings to the vtx bool AP_SmartAudio::init() { debug("SmartAudio init"); if (AP::vtx().get_enabled()==0) { debug("SmartAudio protocol it's not active"); return false; } // init uart _port = AP::serialmanager().find_serial(AP_SerialManager::SerialProtocol_SmartAudio, 0); if (_port!=nullptr) { _port->configure_parity(0); _port->set_stop_bits(2); _port->set_flow_control(AP_HAL::UARTDriver::FLOW_CONTROL_DISABLE); _port->set_options((_port->get_options() & ~AP_HAL::UARTDriver::OPTION_RXINV) | AP_HAL::UARTDriver::OPTION_HDPLEX | AP_HAL::UARTDriver::OPTION_PULLDOWN_TX | AP_HAL::UARTDriver::OPTION_PULLDOWN_RX); if (!hal.scheduler->thread_create(FUNCTOR_BIND_MEMBER(&AP_SmartAudio::loop, void), "SmartAudio", 768, AP_HAL::Scheduler::PRIORITY_IO, -1)) { return false; } return true; } return false; } void AP_SmartAudio::loop() { AP_VideoTX &vtx = AP::vtx(); while (!hal.scheduler->is_system_initialized()) { hal.scheduler->delay(100); } // allocate response buffer uint8_t _response_buffer[AP_SMARTAUDIO_MAX_PACKET_SIZE]; // initialise uart (this must be called from within tick b/c the UART begin must be called from the same thread as it is used from) _port->begin(_smartbaud, AP_SMARTAUDIO_UART_BUFSIZE_RX, AP_SMARTAUDIO_UART_BUFSIZE_TX); while (true) { // now time to control loop switching uint32_t now = AP_HAL::millis(); // when pending request and last request sended is timeout, take another packet to send if (!_is_waiting_response) { // command to process Packet current_command; // repeatedly initialize UART until we know what the VTX is if (!_initialised) { // request settings every second if (requests_queue.is_empty() && !hal.util->get_soft_armed() && now - _last_request_sent_ms > 1000) { request_settings(); } } if (requests_queue.pop(current_command)) { // send the popped command from bugger send_request(current_command.frame, current_command.frame_size); now = AP_HAL::millis(); // it takes roughly 15ms to send a request, don't turn around and try and read until // this time has elapsed hal.scheduler->delay(20); _last_request_sent_ms = now; // next loop we expect a response _is_waiting_response = true; } } // nothing going on so give CPU to someone else if (!_is_waiting_response || !_initialised) { hal.scheduler->delay(100); } // On my Unify Pro32 the SmartAudio response is sent exactly 100ms after the request // and the initial response is 40ms long so we should wait at least 140ms before giving up if (now - _last_request_sent_ms < 200 && _is_waiting_response) { // setup sheduler delay to 50 ms again after response processes if (!read_response(_response_buffer)) { hal.scheduler->delay(10); } } else if (_is_waiting_response) { // timeout // process autobaud routine update_baud_rate(); _port->discard_input(); _inline_buffer_length = 0; _is_waiting_response = false; } else { if (AP::vtx().have_params_changed() ||_vtx_power_change_pending || _vtx_freq_change_pending || _vtx_options_change_pending) { update_vtx_params(); set_configuration_pending(true); vtx.set_configuration_finished(false); // we've tried to udpate something, re-request the settings so that they // are reflected correctly request_settings(); } else if (is_configuration_pending()) { AP::vtx().announce_vtx_settings(); set_configuration_pending(false); vtx.set_configuration_finished(true); } } } } // send requests to the VTX to match the configured VTX parameters void AP_SmartAudio::update_vtx_params() { AP_VideoTX& vtx = AP::vtx(); _vtx_freq_change_pending = vtx.update_band() || vtx.update_channel() || vtx.update_frequency() || _vtx_freq_change_pending; _vtx_power_change_pending = vtx.update_power() || _vtx_power_change_pending; _vtx_options_change_pending = vtx.update_options() || _vtx_options_change_pending; if (_vtx_freq_change_pending || _vtx_power_change_pending || _vtx_options_change_pending) { // make the desired frequency match the desired band and channel if (_vtx_freq_change_pending) { if (vtx.update_band() || vtx.update_channel()) { vtx.update_configured_frequency(); } else { vtx.update_configured_channel_and_band(); } } debug("update_params(): freq %d->%d, chan: %d->%d, band: %d->%d, pwr: %d->%d, opts: %d->%d", vtx.get_frequency_mhz(), vtx.get_configured_frequency_mhz(), vtx.get_channel(), vtx.get_configured_channel(), vtx.get_band(), vtx.get_configured_band(), vtx.get_power_mw(), vtx.get_configured_power_mw(), vtx.get_options(), vtx.get_configured_options()); uint8_t opts = vtx.get_configured_options(); uint8_t pitModeRunning = (vtx.get_options() & uint8_t(AP_VideoTX::VideoOptions::VTX_PITMODE)); uint8_t pitMode = opts & uint8_t(AP_VideoTX::VideoOptions::VTX_PITMODE); uint8_t mode; // check if we are turning pitmode on or off, but only on SA 2.1 as older versions // appear not to work properly if (pitMode != pitModeRunning && _protocol_version >= SMARTAUDIO_SPEC_PROTOCOL_v21) { if (pitModeRunning) { debug("Turning OFF pitmode"); // turn it off mode = 0x04 | ((opts & uint8_t(AP_VideoTX::VideoOptions::VTX_UNLOCKED)) << 2); } else { debug("Turning ON pitmode"); // turn it on mode = 0x01 | ((opts & uint8_t(AP_VideoTX::VideoOptions::VTX_UNLOCKED)) << 2); } } else { mode = ((opts & uint8_t(AP_VideoTX::VideoOptions::VTX_UNLOCKED)) << 2); if (pitMode) { mode |= 0x01; } } if (pitMode) {// prevent power changes in pitmode as this takes the VTX out of pitmode _vtx_power_change_pending = false; } // prioritize pitmode changes if (_vtx_options_change_pending) { debug("update mode '%c%c%c%c'", (mode & 0x8) ? 'U' : 'L', (mode & 0x4) ? 'N' : ' ', (mode & 0x2) ? 'O' : ' ', (mode & 0x1) ? 'I' : ' '); set_operation_mode(mode); } else if (_vtx_freq_change_pending) { debug("update frequency"); if (_vtx_use_set_freq) { set_frequency(vtx.get_configured_frequency_mhz(), false); } else { set_channel(vtx.get_configured_band() * VTX_MAX_CHANNELS + vtx.get_configured_channel()); } } else if (_vtx_power_change_pending) { debug("update power"); switch (_protocol_version) { case SMARTAUDIO_SPEC_PROTOCOL_v21: set_power(vtx.get_configured_power_dbm() | 0x80); break; case SMARTAUDIO_SPEC_PROTOCOL_v2: set_power(vtx.get_configured_power_level()); break; default: // v1 switch(vtx.get_configured_power_level()) { case 1: set_power(16); break; // 200mw case 2: set_power(25); break; // 500mw case 3: set_power(40); break; // 800mw default: set_power(7); break; // 25mw } break; } } } else { vtx.set_configuration_finished(true); } } /** * Sends an SmartAudio Command to the vtx, waits response on the update event * @param frameBuffer frameBuffer to send over the wire * @param size size of the framebuffer wich needs to be sended */ void AP_SmartAudio::send_request(const Frame& requestFrame, uint8_t size) { AP_VideoTX &vtx = AP::vtx(); if (size <= 0 || _port == nullptr) { return; } const uint8_t *request = reinterpret_cast(&requestFrame); // write request if (vtx.has_option(AP_VideoTX::VideoOptions::VTX_PULLDOWN)) { _port->write((uint8_t)0x00); } _port->write(request, size); _port->flush(); _packets_sent++; #ifdef SA_DEBUG print_bytes_to_hex_string("send_request():", request, size,0); #endif } /** * Reads the response from vtx in the wire * - response_buffer, response buffer to fill in * - inline_buffer_length , used to passthrought the response lenght in case the response where splitted **/ bool AP_SmartAudio::read_response(uint8_t *response_buffer) { int16_t incoming_bytes_count = _port->available(); const uint8_t response_header_size= sizeof(FrameHeader); // check if it is a response in the wire if (incoming_bytes_count <= 0) { return false; } // wait until we have enough bytes to read a header if (incoming_bytes_count < response_header_size && _inline_buffer_length == 0) { return false; } // now have at least the header, read it if necessary if (_inline_buffer_length == 0) { uint8_t b = _port->read(); // didn't see a sync byte, discard and go around again if (b != SMARTAUDIO_SYNC_BYTE) { return false; } response_buffer[_inline_buffer_length++] = b; b = _port->read(); // didn't see a header byte, discard and reset if (b != SMARTAUDIO_HEADER_BYTE) { _inline_buffer_length = 0; return false; } response_buffer[_inline_buffer_length++] = b; // read the rest of the header for (; _inline_buffer_length < response_header_size; _inline_buffer_length++) { b = _port->read(); response_buffer[_inline_buffer_length] = b; } FrameHeader* header = (FrameHeader*)response_buffer; incoming_bytes_count -= response_header_size; _packet_size = header->length; } // read the rest of the packet for (uint8_t i= 0; i < incoming_bytes_count && _inline_buffer_length < _packet_size + response_header_size; i++) { uint8_t response_in_bytes = _port->read(); // check for overflow if (_inline_buffer_length >= AP_SMARTAUDIO_MAX_PACKET_SIZE) { _inline_buffer_length = 0; _is_waiting_response = false; return false; } response_buffer[_inline_buffer_length++] = response_in_bytes; } // didn't get the whole packet if (_inline_buffer_length < _packet_size + response_header_size) { return false; } #ifdef SA_DEBUG print_bytes_to_hex_string("read_response():", response_buffer, incoming_bytes_count,(_inline_buffer_length-incoming_bytes_count)>=0?(_inline_buffer_length-incoming_bytes_count):0); #endif _is_waiting_response=false; bool correct_parse = parse_response_buffer(response_buffer); response_buffer=nullptr; _inline_buffer_length=0; _packet_size = 0; _packets_rcvd++; // reset the lost packets to 0 _packets_sent =_packets_rcvd; return correct_parse; } // format a simple command and push into the request queue void AP_SmartAudio::push_command_only_frame(uint8_t cmd_id) { Packet command; command.frame.header.init(cmd_id, 0); command.frame_size = SMARTAUDIO_COMMAND_FRAME_SIZE; command.frame.payload[0] = crc8_dvb_s2_update(0, &command.frame, SMARTAUDIO_COMMAND_FRAME_SIZE - 1); requests_queue.push_force(command); } // format an 8-bit command and push into the request queue void AP_SmartAudio::push_uint8_command_frame(uint8_t cmd_id, uint8_t data) { Packet command; command.frame.header.init(cmd_id, sizeof(uint8_t)); command.frame_size = SMARTAUDIO_U8_COMMAND_FRAME_SIZE; command.frame.payload[0] = data; command.frame.payload[1] = crc8_dvb_s2_update(0, &command.frame, SMARTAUDIO_U8_COMMAND_FRAME_SIZE - 1); requests_queue.push_force(command); } // format an 16-bit command and push into the request queue void AP_SmartAudio::push_uint16_command_frame(uint8_t cmd_id, uint16_t data) { Packet command; command.frame.header.init(cmd_id, sizeof(uint16_t)); command.frame_size = SMARTAUDIO_U16_COMMAND_FRAME_SIZE; put_be16_ptr(command.frame.payload, data); command.frame.payload[2] = crc8_dvb_s2_update(0, &command.frame, SMARTAUDIO_U16_COMMAND_FRAME_SIZE - 1); requests_queue.push_force(command); } /** * Sends get settings command. * */ void AP_SmartAudio::request_settings() { debug("request_settings()"); push_command_only_frame(SMARTAUDIO_CMD_GET_SETTINGS); } void AP_SmartAudio::set_operation_mode(uint8_t mode) { debug("Setting mode to 0x%x", mode); push_uint8_command_frame(SMARTAUDIO_CMD_SET_MODE, mode); } /** * Sets the frequency to transmit in the vtx. * When isPitModeFreq active the freq will be set to be used when in pitmode (in range) */ void AP_SmartAudio::set_frequency(uint16_t frequency, bool isPitModeFreq) { debug("Setting frequency to %d with pitmode == %d", frequency, isPitModeFreq); push_uint16_command_frame(SMARTAUDIO_CMD_SET_FREQUENCY, frequency | (isPitModeFreq ? SMARTAUDIO_SET_PITMODE_FREQ : 0x00)); } // enqueue a set channel request void AP_SmartAudio::set_channel(uint8_t channel) { debug("Setting channel to %d", channel); push_uint8_command_frame(SMARTAUDIO_CMD_SET_CHANNEL, channel); } /** * Request pitMode Frequency setted into the vtx hardware * */ void AP_SmartAudio::request_pit_mode_frequency() { debug("Requesting pit mode frequency"); push_uint16_command_frame(SMARTAUDIO_CMD_SET_FREQUENCY, SMARTAUDIO_GET_PITMODE_FREQ); } // send vtx request to set power void AP_SmartAudio::set_power(uint8_t power_level) { debug("Setting power to %d", power_level); push_uint8_command_frame(SMARTAUDIO_CMD_SET_POWER, power_level); } void AP_SmartAudio::set_band_channel(const uint8_t band, const uint8_t channel) { debug("Setting band/channel to %d/%d", band, channel); push_uint16_command_frame(SMARTAUDIO_CMD_SET_CHANNEL, SMARTAUDIO_BANDCHAN_TO_INDEX(band, channel)); } void AP_SmartAudio::unpack_frequency(AP_SmartAudio::Settings *settings, const uint16_t frequency) { if (frequency & SMARTAUDIO_GET_PITMODE_FREQ) { settings->pitmodeFrequency = frequency; } else { settings->frequency = frequency; } } void AP_SmartAudio::unpack_settings(Settings *settings, const SettingsResponseFrame *frame) { settings->channel = frame->channel % VTX_MAX_CHANNELS; settings->band = frame->channel / VTX_MAX_CHANNELS; settings->power = frame->power; settings->mode = frame->operationMode; unpack_frequency(settings, be16toh(frame->frequency)); } void AP_SmartAudio::unpack_settings(Settings *settings, const SettingsExtendedResponseFrame *frame) { settings->channel = frame->channel % VTX_MAX_CHANNELS; settings->band = frame->channel / VTX_MAX_CHANNELS; settings->power = frame->power; settings->power_in_dbm=frame->power_dbm; settings->mode = frame->operationMode; unpack_frequency(settings, be16toh(frame->frequency)); } #ifdef SA_DEBUG void AP_SmartAudio::print_bytes_to_hex_string(const char* msg, const uint8_t buf[], uint8_t len,uint8_t offset) { hal.console->printf("SA: %s ", msg); for (uint8_t i = 0; i < len; i++) { hal.console->printf("0x%02X ", buf[i+offset]); } hal.console->printf("\n"); } #endif void AP_SmartAudio::print_settings(const Settings* settings) { debug("SETTINGS: VER: %u, MD: '%c%c%c%c%c', CH: %u, PWR: %u, DBM: %u FREQ: %u, BND: %u", settings->version, (settings->mode & 0x10) ? 'U' : 'L', (settings->mode & 0x8) ? 'O' : ' ', (settings->mode & 0x4) ? 'I' : ' ', (settings->mode & 0x2) ? 'P' : ' ', (settings->mode & 0x1) ? 'F' : 'C', settings->channel, settings->power, settings->power_in_dbm, settings->frequency, settings->band); } void AP_SmartAudio::update_vtx_settings(const Settings& settings) { AP_VideoTX& vtx = AP::vtx(); vtx.set_enabled(true); vtx.set_frequency_mhz(settings.frequency); vtx.set_band(settings.band); vtx.set_channel(settings.channel); if (settings.version == SMARTAUDIO_SPEC_PROTOCOL_v21) { vtx.set_power_dbm(settings.power_in_dbm); } else { vtx.set_power_level(settings.power); } // it seems like the spec is wrong, on a unify pro32 this setting is inverted _vtx_use_set_freq = !(settings.mode & 1); // PITMODE | UNLOCKED // SmartAudio 2.1 dropped support for outband pitmode so we won't support it uint8_t opts = ((settings.mode & 0x2) >> 1) | ((settings.mode & 0x10) >> 1); vtx.set_options(opts); // make sure the configured values now reflect reality vtx.set_defaults(); _initialised = true; _vtx_power_change_pending = _vtx_freq_change_pending = _vtx_options_change_pending = false; } bool AP_SmartAudio::parse_response_buffer(const uint8_t *buffer) { const FrameHeader *header = (const FrameHeader *)buffer; const uint8_t fullFrameLength = sizeof(FrameHeader) + header->length; const uint8_t headerPayloadLength = fullFrameLength - 1; // subtract crc byte from length const uint8_t *startPtr = buffer + 2; const uint8_t *endPtr = buffer + headerPayloadLength; if (crc8_dvb_s2_update(0x00, startPtr, headerPayloadLength-2)!=*(endPtr) || header->headerByte != SMARTAUDIO_HEADER_BYTE || header->syncByte!=SMARTAUDIO_SYNC_BYTE) { return false; } // SEND TO GCS A MESSAGE TO UNDERSTAND WHATS HAPPENING AP_VideoTX& vtx = AP::vtx(); Settings settings {}; switch (header->command) { case SMARTAUDIO_RSP_GET_SETTINGS_V1: _protocol_version = SMARTAUDIO_SPEC_PROTOCOL_v1; unpack_settings(&settings, (const SettingsResponseFrame *)buffer); settings.version = SMARTAUDIO_SPEC_PROTOCOL_v1; print_settings(&settings); update_vtx_settings(settings); break; case SMARTAUDIO_RSP_GET_SETTINGS_V2: _protocol_version = SMARTAUDIO_SPEC_PROTOCOL_v2; unpack_settings(&settings, (const SettingsResponseFrame *)buffer); settings.version = SMARTAUDIO_SPEC_PROTOCOL_v2; print_settings(&settings); update_vtx_settings(settings); break; case SMARTAUDIO_RSP_GET_SETTINGS_V21: _protocol_version = SMARTAUDIO_SPEC_PROTOCOL_v21; unpack_settings(&settings, (const SettingsExtendedResponseFrame *)buffer); settings.version = SMARTAUDIO_SPEC_PROTOCOL_v21; print_settings(&settings); update_vtx_settings(settings); break; case SMARTAUDIO_RSP_SET_FREQUENCY: { const U16ResponseFrame *resp = (const U16ResponseFrame *)buffer; unpack_frequency(&settings, resp->payload); vtx.set_frequency_mhz(settings.frequency); vtx.set_configured_frequency_mhz(vtx.get_frequency_mhz()); vtx.update_configured_channel_and_band(); debug("Frequency was set to %d", settings.frequency); } break; case SMARTAUDIO_RSP_SET_CHANNEL: { const U8ResponseFrame *resp = (const U8ResponseFrame *)buffer; vtx.set_band(resp->payload / VTX_MAX_CHANNELS); vtx.set_channel(resp->payload % VTX_MAX_CHANNELS); vtx.set_configured_channel(vtx.get_channel()); vtx.set_configured_band(vtx.get_band()); vtx.update_configured_frequency(); debug("Channel was set to %d", resp->payload); } break; case SMARTAUDIO_RSP_SET_POWER: { const U16ResponseFrame *resp = (const U16ResponseFrame *)buffer; const uint8_t power = resp->payload & 0xFF; switch (_protocol_version) { case SMARTAUDIO_SPEC_PROTOCOL_v21: vtx.set_power_dbm(power); vtx.set_configured_power_mw(vtx.get_power_mw()); break; case SMARTAUDIO_SPEC_PROTOCOL_v2: vtx.set_power_level(power); vtx.set_configured_power_mw(vtx.get_power_mw()); break; default: switch(power) { case 16: vtx.set_power_level(1); break; // 200mw case 25: vtx.set_power_level(2); break; // 500mw case 40: vtx.set_power_level(3); break; // 800mw default: vtx.set_power_level(0); break; // 25mw } vtx.set_configured_power_mw(vtx.get_power_mw()); break; } debug("Power was set to to %d", power); } break; case SMARTAUDIO_RSP_SET_MODE: { vtx.set_options(vtx.get_configured_options()); // easiest to just make them match debug("Mode was set to 0x%x", buffer[4]); } break; default: return false; } return true; } // we missed a response too many times - update the baud rate in case the temperature has increased void AP_SmartAudio::update_baud_rate() { // on my Unify Pro32 the VTX will respond immediately on power up to a settings request, so 10 packets is easily more than enough // we want to bias autobaud to only frequency hop when the current frequency is clearly exhausted, but after that hop quickly if (_packets_sent - _packets_rcvd < 10) { return; } if ((_smartbaud_direction == 1) && (_smartbaud == AP_SMARTAUDIO_SMARTBAUD_MAX)) { _smartbaud_direction = -1; } else if ((_smartbaud_direction == -1 && _smartbaud == AP_SMARTAUDIO_SMARTBAUD_MIN)) { _smartbaud_direction = 1; } _smartbaud += AP_SMARTAUDIO_SMARTBAUD_STEP * _smartbaud_direction; debug("autobaud: %d", int(_smartbaud)); _port->begin(_smartbaud); } #endif // HAL_SMARTAUDIO_ENABLED