/**************************************************************************** * * Copyright (c) 2016 PX4 Development Team. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * 3. Neither the name PX4 nor the names of its contributors may be * used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE * COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS * OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN * ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. * ****************************************************************************/ #include #include "logger.h" #include "messages.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef __PX4_DARWIN #include #include #else #include #endif #define GPS_EPOCH_SECS ((time_t)1234567890ULL) //#define DBGPRINT //write status output every few seconds #if defined(DBGPRINT) // needed for mallinfo #if defined(__PX4_POSIX) && !defined(__PX4_DARWIN) #include #endif /* __PX4_POSIX */ // struct mallinfo not available on OSX? #if defined(__PX4_DARWIN) #undef DBGPRINT #endif /* defined(__PX4_DARWIN) */ #endif /* defined(DBGPRINT) */ using namespace px4::logger; static Logger *logger_ptr = nullptr; static int logger_task = -1; /* This is used to schedule work for the logger (periodic scan for updated topics) */ static void timer_callback(void *arg) { px4_sem_t *semaphore = (px4_sem_t *)arg; px4_sem_post(semaphore); } int logger_main(int argc, char *argv[]) { // logger currently assumes little endian int num = 1; if (*(char *)&num != 1) { PX4_ERR("Logger only works on little endian!\n"); return 1; } if (argc < 2) { PX4_INFO("usage: logger {start|stop|status}"); return 1; } //Check if thread exited, but the object has not been destroyed yet (happens in case of an error) if (logger_task == -1 && logger_ptr) { delete logger_ptr; logger_ptr = nullptr; } if (!strcmp(argv[1], "start")) { if (logger_ptr != nullptr) { PX4_INFO("already running"); return 1; } if (OK != Logger::start((char *const *)argv)) { PX4_WARN("start failed"); return 1; } return 0; } if (!strcmp(argv[1], "on")) { if (logger_ptr != nullptr) { logger_ptr->set_arm_override(true); return 0; } return 1; } if (!strcmp(argv[1], "off")) { if (logger_ptr != nullptr) { logger_ptr->set_arm_override(false); return 0; } return 1; } if (!strcmp(argv[1], "stop")) { if (logger_ptr == nullptr) { PX4_INFO("not running"); return 1; } logger_ptr->print_statistics(); delete logger_ptr; logger_ptr = nullptr; return 0; } if (!strcmp(argv[1], "status")) { if (logger_ptr) { logger_ptr->status(); return 0; } else { PX4_INFO("not running"); return 1; } } Logger::usage("unrecognized command"); return 1; } namespace px4 { namespace logger { void Logger::usage(const char *reason) { if (reason) { PX4_WARN("%s\n", reason); } PX4_INFO("usage: logger {start|stop|on|off|status} [-r ] [-b ] -e -a -t -x -m -q \n" "\t-r\tLog rate in Hz, 0 means unlimited rate\n" "\t-b\tLog buffer size in KiB, default is 12\n" "\t-e\tEnable logging right after start until disarm (otherwise only when armed)\n" "\t-f\tLog until shutdown (implies -e)\n" "\t-t\tUse date/time for naming log directories and files\n" "\t-m\tMode: one of 'file', 'mavlink', 'all' (default=all)\n" "\t-q\tuORB queue size for mavlink mode"); } int Logger::start(char *const *argv) { ASSERT(logger_task == -1); /* start the task */ logger_task = px4_task_spawn_cmd("logger", SCHED_DEFAULT, SCHED_PRIORITY_MAX - 5, 3600, (px4_main_t)&Logger::run_trampoline, (char *const *)argv); if (logger_task < 0) { logger_task = -1; PX4_WARN("task start failed"); return -errno; } return OK; } void Logger::status() { PX4_INFO("Running in mode: %s", configured_backend_mode()); if (_writer.is_started(LogWriter::BackendFile)) { PX4_INFO("File Logging Running"); print_statistics(); } if (_writer.is_started(LogWriter::BackendMavlink)) { PX4_INFO("Mavlink Logging Running"); } } void Logger::print_statistics() { if (!_writer.is_started(LogWriter::BackendFile)) { //currently only statistics for file logging return; } /* this is only for the file backend */ float kibibytes = _writer.get_total_written_file() / 1024.0f; float mebibytes = kibibytes / 1024.0f; float seconds = ((float)(hrt_absolute_time() - _start_time_file)) / 1000000.0f; PX4_INFO("Log file: %s/%s", _log_dir, _log_file_name); PX4_INFO("Wrote %4.2f MiB (avg %5.2f KiB/s)", (double)mebibytes, (double)(kibibytes / seconds)); PX4_INFO("Since last status: dropouts: %zu (max len: %.3f s), max used buffer: %zu / %zu B", _write_dropouts, (double)_max_dropout_duration, _high_water, _writer.get_buffer_size_file()); _high_water = 0; _write_dropouts = 0; _max_dropout_duration = 0.f; } void Logger::run_trampoline(int argc, char *argv[]) { uint32_t log_interval = 3500; int log_buffer_size = 12 * 1024; bool log_on_start = false; bool log_until_shutdown = false; bool error_flag = false; bool log_name_timestamp = false; unsigned int queue_size = 14; //TODO: we might be able to reduce this if mavlink polled on the topic and/or // topic sizes get reduced LogWriter::Backend backend = LogWriter::BackendAll; int myoptind = 1; int ch; const char *myoptarg = NULL; while ((ch = px4_getopt(argc, argv, "r:b:etfm:q:", &myoptind, &myoptarg)) != EOF) { switch (ch) { case 'r': { unsigned long r = strtoul(myoptarg, NULL, 10); if (r <= 0) { r = 1e6; } log_interval = 1e6 / r; } break; case 'e': log_on_start = true; break; case 'b': { unsigned long s = strtoul(myoptarg, NULL, 10); if (s < 1) { s = 1; } log_buffer_size = 1024 * s; } break; case 't': log_name_timestamp = true; break; case 'f': log_on_start = true; log_until_shutdown = true; break; case 'm': if (!strcmp(myoptarg, "file")) { backend = LogWriter::BackendFile; } else if (!strcmp(myoptarg, "mavlink")) { backend = LogWriter::BackendMavlink; } else if (!strcmp(myoptarg, "all")) { backend = LogWriter::BackendAll; } else { PX4_ERR("unknown mode: %s", myoptarg); error_flag = true; } break; case 'q': queue_size = strtoul(myoptarg, NULL, 10); if (queue_size == 0) { queue_size = 1; } break; case '?': error_flag = true; break; default: PX4_WARN("unrecognized flag"); error_flag = true; break; } } if (error_flag) { logger_task = -1; return; } logger_ptr = new Logger(backend, log_buffer_size, log_interval, log_on_start, log_until_shutdown, log_name_timestamp, queue_size); #if defined(DBGPRINT) && defined(__PX4_NUTTX) struct mallinfo alloc_info = mallinfo(); PX4_INFO("largest free chunk: %d bytes", alloc_info.mxordblk); PX4_INFO("remaining free heap: %d bytes", alloc_info.fordblks); #endif /* DBGPRINT */ if (logger_ptr == nullptr) { PX4_ERR("alloc failed"); } else { //check for replay mode const char *logfile = getenv(px4::replay::ENV_FILENAME); if (logfile) { logger_ptr->setReplayFile(logfile); } logger_ptr->run(); } logger_task = -1; } Logger::Logger(LogWriter::Backend backend, size_t buffer_size, uint32_t log_interval, bool log_on_start, bool log_until_shutdown, bool log_name_timestamp, unsigned int queue_size) : _arm_override(false), _log_on_start(log_on_start), _log_until_shutdown(log_until_shutdown), _log_name_timestamp(log_name_timestamp), _writer(backend, buffer_size, queue_size), _log_interval(log_interval), _sdlog_mode(0) { _log_utc_offset = param_find("SDLOG_UTC_OFFSET"); _sdlog_mode_handle = param_find("SDLOG_MODE"); } Logger::~Logger() { if (logger_task != -1) { /* task wakes up every 100ms or so at the longest */ _task_should_exit = true; /* wait for a second for the task to quit at our request */ unsigned int i = 0; do { /* wait 20ms */ usleep(20000); /* if we have given up, kill it */ if (++i > 200) { px4_task_delete(logger_task); logger_task = -1; break; } } while (logger_task != -1); } if (_replay_file_name) { free(_replay_file_name); } if (_msg_buffer) { delete[](_msg_buffer); } } int Logger::add_topic(const orb_metadata *topic) { int fd = -1; size_t fields_len = strlen(topic->o_fields) + strlen(topic->o_name) + 1; //1 for ':' if (fields_len > sizeof(ulog_message_format_s::format)) { PX4_WARN("skip topic %s, format string is too large: %zu (max is %zu)", topic->o_name, fields_len, sizeof(ulog_message_format_s::format)); return -1; } fd = orb_subscribe(topic); if (fd < 0) { PX4_WARN("logger: orb_subscribe failed"); return -1; } if (!_subscriptions.push_back(LoggerSubscription(fd, topic))) { PX4_WARN("logger: failed to add topic. Too many subscriptions"); orb_unsubscribe(fd); fd = -1; } return fd; } int Logger::add_topic(const char *name, unsigned interval = 0) { const orb_metadata **topics = orb_get_topics(); int fd = -1; for (size_t i = 0; i < orb_topics_count(); i++) { if (strcmp(name, topics[i]->o_name) == 0) { fd = add_topic(topics[i]); PX4_DEBUG("logging topic: %s, interval: %i", topics[i]->o_name, interval); break; } } if (fd >= 0 && interval != 0) { orb_set_interval(fd, interval); } return fd; } bool Logger::copy_if_updated_multi(LoggerSubscription &sub, int multi_instance, void *buffer, bool try_to_subscribe) { bool updated = false; int &handle = sub.fd[multi_instance]; if (handle < 0 && try_to_subscribe) { if (OK == orb_exists(sub.metadata, multi_instance)) { handle = orb_subscribe_multi(sub.metadata, multi_instance); //PX4_INFO("subscribed to instance %d of topic %s", multi_instance, sub.metadata->o_name); /* copy first data */ if (handle >= 0) { write_add_logged_msg(sub, multi_instance); /* set to the same interval as the first instance */ unsigned int interval; if (orb_get_interval(sub.fd[0], &interval) == 0 && interval > 0) { orb_set_interval(handle, interval); } /* It can happen that orb_exists returns true, even if there is no publisher (but another subscriber). * We catch this here, because orb_copy will fail in this case. */ if (orb_copy(sub.metadata, handle, buffer) == PX4_OK) { updated = true; } } } } else if (handle >= 0) { orb_check(handle, &updated); if (updated) { orb_copy(sub.metadata, handle, buffer); } } return updated; } void Logger::add_default_topics() { #ifdef CONFIG_ARCH_BOARD_SITL add_topic("vehicle_attitude_groundtruth", 10); add_topic("vehicle_global_position_groundtruth", 100); add_topic("vehicle_local_position_groundtruth", 100); #endif // Note: try to avoid setting the interval where possible, as it increases RAM usage add_topic("vehicle_attitude", 10); add_topic("actuator_outputs", 50); add_topic("telemetry_status"); add_topic("vehicle_command"); add_topic("vehicle_status"); add_topic("vtol_vehicle_status", 100); add_topic("commander_state", 100); add_topic("satellite_info"); add_topic("vehicle_attitude_setpoint", 20); add_topic("vehicle_rates_setpoint", 10); add_topic("actuator_controls", 20); add_topic("actuator_controls_0", 20); add_topic("actuator_controls_1", 20); add_topic("vehicle_local_position", 100); add_topic("vehicle_local_position_setpoint", 50); add_topic("vehicle_global_position", 100); add_topic("vehicle_global_velocity_setpoint", 100); add_topic("battery_status", 300); add_topic("system_power", 300); add_topic("position_setpoint_triplet", 10); add_topic("att_pos_mocap", 50); add_topic("vision_position_estimate", 50); add_topic("optical_flow", 50); add_topic("rc_channels"); add_topic("input_rc"); add_topic("airspeed", 50); add_topic("differential_pressure", 50); add_topic("distance_sensor", 20); add_topic("esc_status", 20); add_topic("estimator_status", 50); //this one is large add_topic("ekf2_innovations", 20); add_topic("tecs_status", 20); add_topic("wind_estimate", 100); add_topic("control_state", 20); add_topic("camera_trigger"); add_topic("cpuload"); add_topic("gps_dump"); //this will only be published if GPS_DUMP_COMM is set add_topic("sensor_preflight"); add_topic("low_stack"); /* for estimator replay (need to be at full rate) */ add_topic("sensor_combined"); add_topic("vehicle_gps_position"); add_topic("vehicle_land_detected"); } void Logger::add_calibration_topics() { // Note: try to avoid setting the interval where possible, as it increases RAM usage add_topic("sensor_gyro", 100); add_topic("sensor_accel", 100); add_topic("sensor_baro", 100); } int Logger::add_topics_from_file(const char *fname) { FILE *fp; char line[80]; char topic_name[80]; unsigned interval; int ntopics = 0; /* open the topic list file */ fp = fopen(fname, "r"); if (fp == NULL) { return -1; } /* call add_topic for each topic line in the file */ for (;;) { /* get a line, bail on error/EOF */ line[0] = '\0'; if (fgets(line, sizeof(line), fp) == NULL) { break; } /* skip comment lines */ if ((strlen(line) < 2) || (line[0] == '#')) { continue; } // read line with format: [, ] interval = 0; int nfields = sscanf(line, "%s %u", topic_name, &interval); if (nfields > 0) { int name_len = strlen(topic_name); if (name_len > 0 && topic_name[name_len - 1] == ',') { topic_name[name_len - 1] = '\0'; } /* add topic with specified interval */ if (add_topic(topic_name, interval) >= 0) { ntopics++; } else { PX4_ERR("Failed to add topic %s", topic_name); } } } fclose(fp); return ntopics; } const char *Logger::configured_backend_mode() const { switch (_writer.backend()) { case LogWriter::BackendFile: return "file"; case LogWriter::BackendMavlink: return "mavlink"; case LogWriter::BackendAll: return "all"; default: return "several"; } } void Logger::run() { #ifdef DBGPRINT struct mallinfo alloc_info = {}; #endif /* DBGPRINT */ PX4_INFO("logger started (mode=%s)", configured_backend_mode()); if (_writer.backend() & LogWriter::BackendFile) { int mkdir_ret = mkdir(LOG_ROOT, S_IRWXU | S_IRWXG | S_IRWXO); if (mkdir_ret == 0) { PX4_INFO("log root dir created: %s", LOG_ROOT); } else if (errno != EEXIST) { PX4_ERR("failed creating log root dir: %s", LOG_ROOT); if ((_writer.backend() & ~LogWriter::BackendFile) == 0) { return; } } if (check_free_space() == 1) { return; } } int vehicle_status_sub = orb_subscribe(ORB_ID(vehicle_status)); uORB::Subscription parameter_update_sub(ORB_ID(parameter_update)); int log_message_sub = orb_subscribe(ORB_ID(log_message)); orb_set_interval(log_message_sub, 20); int ntopics = add_topics_from_file(PX4_ROOTFSDIR "/fs/microsd/etc/logging/logger_topics.txt"); if (ntopics > 0) { PX4_INFO("logging %d topics from logger_topics.txt", ntopics); } else { /* get the logging mode */ if (_sdlog_mode_handle != PARAM_INVALID) { param_get(_sdlog_mode_handle, &_sdlog_mode); } if (_sdlog_mode == 3) { add_calibration_topics(); } else { add_default_topics(); } } int vehicle_command_sub = -1; orb_advert_t vehicle_command_ack_pub = nullptr; if (_writer.backend() & LogWriter::BackendMavlink) { vehicle_command_sub = orb_subscribe(ORB_ID(vehicle_command)); } //all topics added. Get required message buffer size int max_msg_size = 0, ret; for (const auto &subscription : _subscriptions) { //use o_size, because that's what orb_copy will use if (subscription.metadata->o_size > max_msg_size) { max_msg_size = subscription.metadata->o_size; } } max_msg_size += sizeof(ulog_message_data_header_s); if (sizeof(ulog_message_logging_s) > max_msg_size) { max_msg_size = sizeof(ulog_message_logging_s); } if (max_msg_size > _msg_buffer_len) { if (_msg_buffer) { delete[](_msg_buffer); } _msg_buffer_len = max_msg_size; _msg_buffer = new uint8_t[_msg_buffer_len]; if (!_msg_buffer) { PX4_ERR("failed to alloc message buffer"); return; } } if (!_writer.init()) { PX4_ERR("writer init failed"); return; } _task_should_exit = false; #ifdef DBGPRINT hrt_abstime timer_start = 0; uint32_t total_bytes = 0; #endif /* DBGPRINT */ // we start logging immediately // the case where we wait with logging until vehicle is armed is handled below if (_log_on_start) { start_log_file(); } /* init the update timer */ struct hrt_call timer_call; memset(&timer_call, 0, sizeof(hrt_call)); px4_sem_t timer_semaphore; px4_sem_init(&timer_semaphore, 0, 0); /* timer_semaphore use case is a signal */ px4_sem_setprotocol(&timer_semaphore, SEM_PRIO_NONE); hrt_call_every(&timer_call, _log_interval, _log_interval, timer_callback, &timer_semaphore); // check for new subscription data hrt_abstime next_subscribe_check = 0; int next_subscribe_topic_index = -1; // this is used to distribute the checks over time while (!_task_should_exit) { // Start/stop logging when system arm/disarm bool vehicle_status_updated; ret = orb_check(vehicle_status_sub, &vehicle_status_updated); if (ret == 0 && vehicle_status_updated) { vehicle_status_s vehicle_status; orb_copy(ORB_ID(vehicle_status), vehicle_status_sub, &vehicle_status); bool armed = (vehicle_status.arming_state == vehicle_status_s::ARMING_STATE_ARMED) || (vehicle_status.arming_state == vehicle_status_s::ARMING_STATE_ARMED_ERROR) || _arm_override; if (_was_armed != armed && !_log_until_shutdown) { _was_armed = armed; if (armed) { start_log_file(); #ifdef DBGPRINT timer_start = hrt_absolute_time(); total_bytes = 0; #endif /* DBGPRINT */ } else { stop_log_file(); } } } /* check for logging command from MAVLink */ if (vehicle_command_sub != -1) { bool command_updated = false; ret = orb_check(vehicle_command_sub, &command_updated); if (ret == 0 && command_updated) { vehicle_command_s command; orb_copy(ORB_ID(vehicle_command), vehicle_command_sub, &command); if (command.command == vehicle_command_s::VEHICLE_CMD_LOGGING_START) { if ((int)(command.param1 + 0.5f) != 0) { ack_vehicle_command(vehicle_command_ack_pub, command.command, vehicle_command_s::VEHICLE_CMD_RESULT_UNSUPPORTED); } else if (can_start_mavlink_log()) { ack_vehicle_command(vehicle_command_ack_pub, command.command, vehicle_command_s::VEHICLE_CMD_RESULT_ACCEPTED); start_log_mavlink(); } else { ack_vehicle_command(vehicle_command_ack_pub, command.command, vehicle_command_s::VEHICLE_CMD_RESULT_TEMPORARILY_REJECTED); } } else if (command.command == vehicle_command_s::VEHICLE_CMD_LOGGING_STOP) { stop_log_mavlink(); ack_vehicle_command(vehicle_command_ack_pub, command.command, vehicle_command_s::VEHICLE_CMD_RESULT_ACCEPTED); } } } if (_writer.is_started()) { bool data_written = false; /* Check if parameters have changed */ // this needs to change to a timestamped record to record a history of parameter changes if (parameter_update_sub.check_updated()) { parameter_update_sub.update(); write_changed_parameters(); } /* wait for lock on log buffer */ _writer.lock(); int sub_idx = 0; for (LoggerSubscription &sub : _subscriptions) { /* each message consists of a header followed by an orb data object */ size_t msg_size = sizeof(ulog_message_data_header_s) + sub.metadata->o_size_no_padding; /* if this topic has been updated, copy the new data into the message buffer * and write a message to the log */ for (uint8_t instance = 0; instance < ORB_MULTI_MAX_INSTANCES; instance++) { if (copy_if_updated_multi(sub, instance, _msg_buffer + sizeof(ulog_message_data_header_s), sub_idx == next_subscribe_topic_index)) { uint16_t write_msg_size = static_cast(msg_size - ULOG_MSG_HEADER_LEN); //write one byte after another (necessary because of alignment) _msg_buffer[0] = (uint8_t)write_msg_size; _msg_buffer[1] = (uint8_t)(write_msg_size >> 8); _msg_buffer[2] = static_cast(ULogMessageType::DATA); uint16_t write_msg_id = sub.msg_ids[instance]; _msg_buffer[3] = (uint8_t)write_msg_id; _msg_buffer[4] = (uint8_t)(write_msg_id >> 8); //PX4_INFO("topic: %s, size = %zu, out_size = %zu", sub.metadata->o_name, sub.metadata->o_size, msg_size); if (write_message(_msg_buffer, msg_size)) { #ifdef DBGPRINT total_bytes += msg_size; #endif /* DBGPRINT */ data_written = true; } else { break; // Write buffer overflow, skip this record } } } ++sub_idx; } //check for new logging message(s) bool log_message_updated = false; ret = orb_check(log_message_sub, &log_message_updated); if (ret == 0 && log_message_updated) { log_message_s log_message; orb_copy(ORB_ID(log_message), log_message_sub, &log_message); const char *message = (const char *)log_message.text; int message_len = strlen(message); if (message_len > 0) { uint16_t write_msg_size = sizeof(ulog_message_logging_s) - sizeof(ulog_message_logging_s::message) - ULOG_MSG_HEADER_LEN + message_len; _msg_buffer[0] = (uint8_t)write_msg_size; _msg_buffer[1] = (uint8_t)(write_msg_size >> 8); _msg_buffer[2] = static_cast(ULogMessageType::LOGGING); _msg_buffer[3] = log_message.severity + '0'; memcpy(_msg_buffer + 4, &log_message.timestamp, sizeof(ulog_message_logging_s::timestamp)); strncpy((char *)(_msg_buffer + 12), message, sizeof(ulog_message_logging_s::message)); write_message(_msg_buffer, write_msg_size + ULOG_MSG_HEADER_LEN); } } if (!_dropout_start && _writer.get_buffer_fill_count_file() > _high_water) { _high_water = _writer.get_buffer_fill_count_file(); } /* release the log buffer */ _writer.unlock(); /* notify the writer thread if data is available */ if (data_written) { _writer.notify(); } /* subscription update */ if (next_subscribe_topic_index != -1) { if (++next_subscribe_topic_index >= _subscriptions.size()) { next_subscribe_topic_index = -1; next_subscribe_check = hrt_absolute_time() + TRY_SUBSCRIBE_INTERVAL; } } else if (hrt_absolute_time() > next_subscribe_check) { next_subscribe_topic_index = 0; } #ifdef DBGPRINT double deltat = (double)(hrt_absolute_time() - timer_start) * 1e-6; if (deltat > 4.0) { alloc_info = mallinfo(); double throughput = total_bytes / deltat; PX4_INFO("%8.1f kB/s, %zu highWater, %d dropouts, %5.3f sec max, free heap: %d", throughput / 1.e3, _high_water, _write_dropouts, (double)_max_dropout_duration, alloc_info.fordblks); _high_water = 0; _max_dropout_duration = 0.f; total_bytes = 0; timer_start = hrt_absolute_time(); } #endif /* DBGPRINT */ } /* * We wait on the semaphore, which periodically gets updated by a high-resolution timer. * The simpler alternative would be: * usleep(max(300, _log_interval - elapsed_time_since_loop_start)); * And on linux this is quite accurate as well, but under NuttX it is not accurate, * because usleep() has only a granularity of CONFIG_MSEC_PER_TICK (=1ms). */ while (px4_sem_wait(&timer_semaphore) != 0); } hrt_cancel(&timer_call); px4_sem_destroy(&timer_semaphore); // stop the writer thread _writer.thread_stop(); //unsubscribe for (LoggerSubscription &sub : _subscriptions) { for (uint8_t instance = 0; instance < ORB_MULTI_MAX_INSTANCES; instance++) { if (sub.fd[instance] != -1) { orb_unsubscribe(sub.fd[instance]); sub.fd[instance] = -1; } } } if (_mavlink_log_pub) { orb_unadvertise(_mavlink_log_pub); _mavlink_log_pub = nullptr; } if (vehicle_command_ack_pub) { orb_unadvertise(vehicle_command_ack_pub); } if (vehicle_command_sub != -1) { orb_unsubscribe(vehicle_command_sub); } } bool Logger::write_message(void *ptr, size_t size) { if (_writer.write_message(ptr, size, _dropout_start) != -1) { if (_dropout_start) { float dropout_duration = (float)(hrt_elapsed_time(&_dropout_start) / 1000) / 1.e3f; if (dropout_duration > _max_dropout_duration) { _max_dropout_duration = dropout_duration; } _dropout_start = 0; } return true; } if (!_dropout_start) { _dropout_start = hrt_absolute_time(); ++_write_dropouts; _high_water = 0; } return false; } int Logger::create_log_dir(tm *tt) { /* create dir on sdcard if needed */ int mkdir_ret; if (tt) { int n = snprintf(_log_dir, sizeof(_log_dir), "%s/", LOG_ROOT); if (n >= sizeof(_log_dir)) { PX4_ERR("log path too long"); return -1; } strftime(_log_dir + n, sizeof(_log_dir) - n, "%Y-%m-%d", tt); mkdir_ret = mkdir(_log_dir, S_IRWXU | S_IRWXG | S_IRWXO); if (mkdir_ret != OK && errno != EEXIST) { PX4_ERR("failed creating new dir: %s", _log_dir); return -1; } } else { uint16_t dir_number = 1; // start with dir sess001 /* look for the next dir that does not exist */ while (!_has_log_dir && dir_number <= MAX_NO_LOGFOLDER) { /* format log dir: e.g. /fs/microsd/sess001 */ int n = snprintf(_log_dir, sizeof(_log_dir), "%s/sess%03u", LOG_ROOT, dir_number); if (n >= sizeof(_log_dir)) { PX4_ERR("log path too long"); return -1; } mkdir_ret = mkdir(_log_dir, S_IRWXU | S_IRWXG | S_IRWXO); if (mkdir_ret == 0) { PX4_DEBUG("log dir created: %s", _log_dir); _has_log_dir = true; } else if (errno != EEXIST) { PX4_ERR("failed creating new dir: %s (%i)", _log_dir, errno); return -1; } /* dir exists already */ dir_number++; } if (dir_number >= MAX_NO_LOGFOLDER) { /* we should not end up here, either we have more than MAX_NO_LOGFOLDER on the SD card, or another problem */ PX4_ERR("All %d possible dirs exist already", MAX_NO_LOGFOLDER); return -1; } _has_log_dir = true; } return 0; } bool Logger::file_exist(const char *filename) { struct stat buffer; return stat(filename, &buffer) == 0; } int Logger::get_log_file_name(char *file_name, size_t file_name_size) { tm tt; bool time_ok = false; if (_log_name_timestamp) { /* use RTC time for log file naming, e.g. /fs/microsd/2014-01-19/19_37_52.ulg */ time_ok = get_log_time(&tt, false); } const char *replay_suffix = ""; if (_replay_file_name) { replay_suffix = "_replayed"; } if (time_ok) { if (create_log_dir(&tt)) { return -1; } char log_file_name_time[16] = ""; strftime(log_file_name_time, sizeof(log_file_name_time), "%H_%M_%S", &tt); snprintf(_log_file_name, sizeof(_log_file_name), "%s%s.ulg", log_file_name_time, replay_suffix); snprintf(file_name, file_name_size, "%s/%s", _log_dir, _log_file_name); } else { if (create_log_dir(nullptr)) { return -1; } uint16_t file_number = 1; // start with file log001 /* look for the next file that does not exist */ while (file_number <= MAX_NO_LOGFILE) { /* format log file path: e.g. /fs/microsd/sess001/log001.ulg */ snprintf(_log_file_name, sizeof(_log_file_name), "log%03u%s.ulg", file_number, replay_suffix); snprintf(file_name, file_name_size, "%s/%s", _log_dir, _log_file_name); if (!file_exist(file_name)) { break; } file_number++; } if (file_number > MAX_NO_LOGFILE) { /* we should not end up here, either we have more than MAX_NO_LOGFILE on the SD card, or another problem */ return -1; } } return 0; } void Logger::setReplayFile(const char *file_name) { if (_replay_file_name) { free(_replay_file_name); } _replay_file_name = strdup(file_name); } bool Logger::get_log_time(struct tm *tt, bool boot_time) { int vehicle_gps_position_sub = orb_subscribe(ORB_ID(vehicle_gps_position)); if (vehicle_gps_position_sub < 0) { return false; } /* Get the latest GPS publication */ vehicle_gps_position_s gps_pos; time_t utc_time_sec; bool use_clock_time = true; if (orb_copy(ORB_ID(vehicle_gps_position), vehicle_gps_position_sub, &gps_pos) == 0) { utc_time_sec = gps_pos.time_utc_usec / 1e6; if (gps_pos.fix_type >= 2 && utc_time_sec >= GPS_EPOCH_SECS) { use_clock_time = false; } } orb_unsubscribe(vehicle_gps_position_sub); if (use_clock_time) { /* take clock time if there's no fix (yet) */ struct timespec ts; px4_clock_gettime(CLOCK_REALTIME, &ts); utc_time_sec = ts.tv_sec + (ts.tv_nsec / 1e9); if (utc_time_sec < GPS_EPOCH_SECS) { return false; } } /* strip the time elapsed since boot */ if (boot_time) { utc_time_sec -= hrt_absolute_time() / 1e6; } int32_t utc_offset = 0; if (_log_utc_offset != PARAM_INVALID) { param_get(_log_utc_offset, &utc_offset); } /* apply utc offset */ utc_time_sec += utc_offset * 60; return gmtime_r(&utc_time_sec, tt) != nullptr; } void Logger::start_log_file() { if (_writer.is_started(LogWriter::BackendFile) || (_writer.backend() & LogWriter::BackendFile) == 0) { return; } PX4_INFO("Start file log"); char file_name[LOG_DIR_LEN] = ""; if (get_log_file_name(file_name, sizeof(file_name))) { PX4_ERR("logger: failed to get log file name"); return; } /* print logging path, important to find log file later */ mavlink_log_info(&_mavlink_log_pub, "[logger] file: %s", file_name); _writer.start_log_file(file_name); _writer.select_write_backend(LogWriter::BackendFile); _writer.set_need_reliable_transfer(true); write_header(); write_version(); write_formats(); write_parameters(); write_all_add_logged_msg(); _writer.set_need_reliable_transfer(false); _writer.unselect_write_backend(); _writer.notify(); _start_time_file = hrt_absolute_time(); } void Logger::stop_log_file() { _writer.stop_log_file(); } void Logger::start_log_mavlink() { if (!can_start_mavlink_log()) { return; } PX4_INFO("Start mavlink log"); _writer.start_log_mavlink(); _writer.select_write_backend(LogWriter::BackendMavlink); _writer.set_need_reliable_transfer(true); write_header(); write_version(); write_formats(); write_parameters(); write_all_add_logged_msg(); _writer.set_need_reliable_transfer(false); _writer.unselect_write_backend(); _writer.notify(); } void Logger::stop_log_mavlink() { PX4_INFO("Stop mavlink log"); _writer.stop_log_mavlink(); } void Logger::write_formats() { _writer.lock(); ulog_message_format_s msg; const orb_metadata **topics = orb_get_topics(); //write all known formats for (size_t i = 0; i < orb_topics_count(); i++) { int format_len = snprintf(msg.format, sizeof(msg.format), "%s:%s", topics[i]->o_name, topics[i]->o_fields); size_t msg_size = sizeof(msg) - sizeof(msg.format) + format_len; msg.msg_size = msg_size - ULOG_MSG_HEADER_LEN; write_message(&msg, msg_size); } _writer.unlock(); } void Logger::write_all_add_logged_msg() { _writer.lock(); for (LoggerSubscription &sub : _subscriptions) { for (int instance = 0; instance < ORB_MULTI_MAX_INSTANCES; ++instance) { if (sub.fd[instance] >= 0) { write_add_logged_msg(sub, instance); } } } _writer.unlock(); } void Logger::write_add_logged_msg(LoggerSubscription &subscription, int instance) { ulog_message_add_logged_s msg; if (subscription.msg_ids[instance] == (uint16_t) - 1) { subscription.msg_ids[instance] = _next_topic_id++; } msg.msg_id = subscription.msg_ids[instance]; msg.multi_id = instance; int message_name_len = strlen(subscription.metadata->o_name); memcpy(msg.message_name, subscription.metadata->o_name, message_name_len); size_t msg_size = sizeof(msg) - sizeof(msg.message_name) + message_name_len; msg.msg_size = msg_size - ULOG_MSG_HEADER_LEN; bool prev_reliable = _writer.need_reliable_transfer(); _writer.set_need_reliable_transfer(true); write_message(&msg, msg_size); _writer.set_need_reliable_transfer(prev_reliable); } /* write info message */ void Logger::write_info(const char *name, const char *value) { _writer.lock(); ulog_message_info_header_s msg; uint8_t *buffer = reinterpret_cast(&msg); msg.msg_type = static_cast(ULogMessageType::INFO); /* construct format key (type and name) */ size_t vlen = strlen(value); msg.key_len = snprintf(msg.key, sizeof(msg.key), "char[%zu] %s", vlen, name); size_t msg_size = sizeof(msg) - sizeof(msg.key) + msg.key_len; /* copy string value directly to buffer */ if (vlen < (sizeof(msg) - msg_size)) { memcpy(&buffer[msg_size], value, vlen); msg_size += vlen; msg.msg_size = msg_size - ULOG_MSG_HEADER_LEN; write_message(buffer, msg_size); } _writer.unlock(); } void Logger::write_info(const char *name, int32_t value) { write_info_template(name, value, "int32_t"); } void Logger::write_info(const char *name, uint32_t value) { write_info_template(name, value, "uint32_t"); } template void Logger::write_info_template(const char *name, T value, const char *type_str) { _writer.lock(); ulog_message_info_header_s msg; uint8_t *buffer = reinterpret_cast(&msg); msg.msg_type = static_cast(ULogMessageType::INFO); /* construct format key (type and name) */ msg.key_len = snprintf(msg.key, sizeof(msg.key), "%s %s", type_str, name); size_t msg_size = sizeof(msg) - sizeof(msg.key) + msg.key_len; /* copy string value directly to buffer */ memcpy(&buffer[msg_size], &value, sizeof(T)); msg_size += sizeof(T); msg.msg_size = msg_size - ULOG_MSG_HEADER_LEN; write_message(buffer, msg_size); _writer.unlock(); } void Logger::write_header() { ulog_file_header_s header; header.magic[0] = 'U'; header.magic[1] = 'L'; header.magic[2] = 'o'; header.magic[3] = 'g'; header.magic[4] = 0x01; header.magic[5] = 0x12; header.magic[6] = 0x35; header.magic[7] = 0x00; //file version 0 header.timestamp = hrt_absolute_time(); _writer.lock(); write_message(&header, sizeof(header)); _writer.unlock(); } /* write version info messages */ void Logger::write_version() { write_info("ver_sw", px4_firmware_version_string()); write_info("ver_sw_release", px4_firmware_version()); write_info("ver_hw", px4_board_name()); write_info("sys_name", "PX4"); write_info("sys_os_name", px4_os_name()); const char *os_version = px4_os_version_string(); if (os_version) { write_info("sys_os_ver", os_version); } write_info("sys_os_ver_release", px4_os_version()); write_info("sys_toolchain", px4_toolchain_name()); write_info("sys_toolchain_ver", px4_toolchain_version()); char revision = 'U'; const char *chip_name = nullptr; if (board_mcu_version(&revision, &chip_name, nullptr) >= 0) { char mcu_ver[64]; snprintf(mcu_ver, sizeof(mcu_ver), "%s, rev. %c", chip_name, revision); write_info("sys_mcu", mcu_ver); } /* write the UUID if enabled */ param_t write_uuid_param = param_find("SDLOG_UUID"); if (write_uuid_param != PARAM_INVALID) { uint32_t write_uuid; param_get(write_uuid_param, &write_uuid); if (write_uuid == 1) { char uuid_string[PX4_CPU_UUID_WORD32_LEGACY_FORMAT_SIZE]; board_get_uuid_formated32(uuid_string, sizeof(uuid_string), "%08X", NULL, &px4_legacy_word32_order); write_info("sys_uuid", uuid_string); } } int32_t utc_offset = 0; if (_log_utc_offset != PARAM_INVALID) { param_get(_log_utc_offset, &utc_offset); write_info("time_ref_utc", utc_offset * 60); } if (_replay_file_name) { write_info("replay", _replay_file_name); } } void Logger::write_parameters() { _writer.lock(); ulog_message_parameter_header_s msg; uint8_t *buffer = reinterpret_cast(&msg); msg.msg_type = static_cast(ULogMessageType::PARAMETER); int param_idx = 0; param_t param = 0; do { // get next parameter which is invalid OR used do { param = param_for_index(param_idx); ++param_idx; } while (param != PARAM_INVALID && !param_used(param)); // save parameters which are valid AND used if (param != PARAM_INVALID) { /* get parameter type and size */ const char *type_str; param_type_t type = param_type(param); size_t value_size = 0; switch (type) { case PARAM_TYPE_INT32: type_str = "int32_t"; value_size = sizeof(int32_t); break; case PARAM_TYPE_FLOAT: type_str = "float"; value_size = sizeof(float); break; default: continue; } /* format parameter key (type and name) */ msg.key_len = snprintf(msg.key, sizeof(msg.key), "%s %s", type_str, param_name(param)); size_t msg_size = sizeof(msg) - sizeof(msg.key) + msg.key_len; /* copy parameter value directly to buffer */ param_get(param, &buffer[msg_size]); msg_size += value_size; msg.msg_size = msg_size - ULOG_MSG_HEADER_LEN; write_message(buffer, msg_size); } } while ((param != PARAM_INVALID) && (param_idx < (int) param_count())); _writer.unlock(); _writer.notify(); } void Logger::write_changed_parameters() { _writer.lock(); ulog_message_parameter_header_s msg; uint8_t *buffer = reinterpret_cast(&msg); msg.msg_type = static_cast(ULogMessageType::PARAMETER); int param_idx = 0; param_t param = 0; do { // get next parameter which is invalid OR used do { param = param_for_index(param_idx); ++param_idx; } while (param != PARAM_INVALID && !param_used(param)); // log parameters which are valid AND used AND unsaved if ((param != PARAM_INVALID) && param_value_unsaved(param)) { /* get parameter type and size */ const char *type_str; param_type_t type = param_type(param); size_t value_size = 0; switch (type) { case PARAM_TYPE_INT32: type_str = "int32_t"; value_size = sizeof(int32_t); break; case PARAM_TYPE_FLOAT: type_str = "float"; value_size = sizeof(float); break; default: continue; } /* format parameter key (type and name) */ msg.key_len = snprintf(msg.key, sizeof(msg.key), "%s %s", type_str, param_name(param)); size_t msg_size = sizeof(msg) - sizeof(msg.key) + msg.key_len; /* copy parameter value directly to buffer */ param_get(param, &buffer[msg_size]); msg_size += value_size; /* msg_size is now 1 (msg_type) + 2 (msg_size) + 1 (key_len) + key_len + value_size */ msg.msg_size = msg_size - ULOG_MSG_HEADER_LEN; write_message(buffer, msg_size); } } while ((param != PARAM_INVALID) && (param_idx < (int) param_count())); _writer.unlock(); _writer.notify(); } int Logger::check_free_space() { /* use statfs to determine the number of blocks left */ struct statfs statfs_buf; if (statfs(LOG_ROOT, &statfs_buf) != 0) { return PX4_ERROR; } /* use a threshold of 50 MiB */ if (statfs_buf.f_bavail < (px4_statfs_buf_f_bavail_t)(50 * 1024 * 1024 / statfs_buf.f_bsize)) { mavlink_log_critical(&_mavlink_log_pub, "[logger] Not logging; SD almost full: %u MiB", (unsigned int)(statfs_buf.f_bavail / 1024U * statfs_buf.f_bsize / 1024U)); return 1; } return PX4_OK; } void Logger::ack_vehicle_command(orb_advert_t &vehicle_command_ack_pub, uint16_t command, uint32_t result) { vehicle_command_ack_s vehicle_command_ack; vehicle_command_ack.timestamp = hrt_absolute_time(); vehicle_command_ack.command = command; vehicle_command_ack.result = result; if (vehicle_command_ack_pub == nullptr) { vehicle_command_ack_pub = orb_advertise_queue(ORB_ID(vehicle_command_ack), &vehicle_command_ack, vehicle_command_ack_s::ORB_QUEUE_LENGTH); } else { orb_publish(ORB_ID(vehicle_command_ack), vehicle_command_ack_pub, &vehicle_command_ack); } } } }