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ardupilot/libraries/AP_Logger/AP_Logger_Backend.cpp

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#include "AP_Logger_Backend.h"
#include "LoggerMessageWriter.h"
#include <AP_InternalError/AP_InternalError.h>
extern const AP_HAL::HAL& hal;
AP_Logger_Backend::AP_Logger_Backend(AP_Logger &front,
class LoggerMessageWriter_DFLogStart *writer) :
_front(front),
_startup_messagewriter(writer)
{
writer->set_logger_backend(this);
}
uint8_t AP_Logger_Backend::num_types() const
{
return _front._num_types;
}
const struct LogStructure *AP_Logger_Backend::structure(uint8_t num) const
{
return _front.structure(num);
}
uint8_t AP_Logger_Backend::num_units() const
{
return _front._num_units;
}
const struct UnitStructure *AP_Logger_Backend::unit(uint8_t num) const
{
return _front.unit(num);
}
uint8_t AP_Logger_Backend::num_multipliers() const
{
return _front._num_multipliers;
}
const struct MultiplierStructure *AP_Logger_Backend::multiplier(uint8_t num) const
{
return _front.multiplier(num);
}
AP_Logger_Backend::vehicle_startup_message_Writer AP_Logger_Backend::vehicle_message_writer() {
return _front._vehicle_messages;
}
void AP_Logger_Backend::periodic_10Hz(const uint32_t now)
{
}
void AP_Logger_Backend::periodic_1Hz()
{
if (_rotate_pending && !logging_enabled()) {
_rotate_pending = false;
// handle log rotation once we stop logging
stop_logging_async();
}
df_stats_log();
}
void AP_Logger_Backend::periodic_fullrate()
{
push_log_blocks();
}
void AP_Logger_Backend::periodic_tasks()
{
uint32_t now = AP_HAL::millis();
if (now - _last_periodic_1Hz > 1000) {
periodic_1Hz();
_last_periodic_1Hz = now;
}
if (now - _last_periodic_10Hz > 100) {
periodic_10Hz(now);
_last_periodic_10Hz = now;
}
periodic_fullrate();
}
void AP_Logger_Backend::start_new_log_reset_variables()
{
_dropped = 0;
_startup_messagewriter->reset();
_front.backend_starting_new_log(this);
_log_file_size_bytes = 0;
}
// We may need to make sure data is loggable before starting the
// EKF; when allow_start_ekf we should be able to log that data
bool AP_Logger_Backend::allow_start_ekf() const
{
if (!_startup_messagewriter->fmt_done()) {
return false;
}
// we need to push all startup messages out, or the code in
// WriteBlockCheckStartupMessages bites us.
if (!_startup_messagewriter->finished()) {
return false;
}
return true;
}
// this method can be overridden to do extra things with your buffer.
// for example, in AP_Logger_MAVLink we may push messages into the UART.
void AP_Logger_Backend::push_log_blocks() {
WriteMoreStartupMessages();
}
// returns true if all format messages have been written, and thus it is OK
// for other messages to go out to the log
bool AP_Logger_Backend::WriteBlockCheckStartupMessages()
{
#if APM_BUILD_TYPE(APM_BUILD_Replay)
return true;
#endif
if (_startup_messagewriter->fmt_done()) {
return true;
}
if (_writing_startup_messages) {
// we have been called by a messagewriter, so writing is OK
return true;
}
if (!_startup_messagewriter->finished() &&
!hal.scheduler->in_main_thread()) {
// only the main thread may write startup messages out
return false;
}
// we're not writing startup messages, so this must be some random
// caller hoping to write blocks out. Push out log blocks - we
// might end up clearing the buffer.....
push_log_blocks();
// even if we did finish writing startup messages, we can't
// permit any message to go in as its timestamp will be before
// any we wrote in. Time going backwards annoys log readers.
// sorry! currently busy writing out startup messages...
return false;
}
// source more messages from the startup message writer:
void AP_Logger_Backend::WriteMoreStartupMessages()
{
#if APM_BUILD_TYPE(APM_BUILD_Replay)
return;
#endif
if (_startup_messagewriter->finished()) {
return;
}
_writing_startup_messages = true;
_startup_messagewriter->process();
_writing_startup_messages = false;
}
/*
* support for Write():
*/
bool AP_Logger_Backend::Write_Emit_FMT(uint8_t msg_type)
{
#if APM_BUILD_TYPE(APM_BUILD_Replay)
// sure, sure we did....
return true;
#endif
// get log structure from front end:
char ls_name[LS_NAME_SIZE] = {};
char ls_format[LS_FORMAT_SIZE] = {};
char ls_labels[LS_LABELS_SIZE] = {};
char ls_units[LS_UNITS_SIZE] = {};
char ls_multipliers[LS_MULTIPLIERS_SIZE] = {};
struct LogStructure logstruct = {
// these will be overwritten, but need to keep the compiler happy:
0,
0,
ls_name,
ls_format,
ls_labels,
ls_units,
ls_multipliers
};
if (!_front.fill_log_write_logstructure(logstruct, msg_type)) {
// this is a bug; we've been asked to write out the FMT
// message for a msg_type, but the frontend can't supply the
// required information
INTERNAL_ERROR(AP_InternalError::error_t::logger_missing_logstructure);
return false;
}
if (!Write_Format(&logstruct)) {
return false;
}
if (!Write_Format_Units(&logstruct)) {
return false;
}
return true;
}
bool AP_Logger_Backend::Write(const uint8_t msg_type, va_list arg_list, bool is_critical)
{
// stack-allocate a buffer so we can WriteBlock(); this could be
// 255 bytes! If we were willing to lose the WriteBlock
// abstraction we could do WriteBytes() here instead?
const char *fmt = nullptr;
uint8_t msg_len;
AP_Logger::log_write_fmt *f;
for (f = _front.log_write_fmts; f; f=f->next) {
if (f->msg_type == msg_type) {
fmt = f->fmt;
msg_len = f->msg_len;
break;
}
}
if (fmt == nullptr) {
INTERNAL_ERROR(AP_InternalError::error_t::logger_logwrite_missingfmt);
return false;
}
if (bufferspace_available() < msg_len) {
return false;
}
uint8_t buffer[msg_len];
uint8_t offset = 0;
buffer[offset++] = HEAD_BYTE1;
buffer[offset++] = HEAD_BYTE2;
buffer[offset++] = msg_type;
for (uint8_t i=0; i<strlen(fmt); i++) {
uint8_t charlen = 0;
switch(fmt[i]) {
case 'b': {
int8_t tmp = va_arg(arg_list, int);
memcpy(&buffer[offset], &tmp, sizeof(int8_t));
offset += sizeof(int8_t);
break;
}
case 'h':
case 'c': {
int16_t tmp = va_arg(arg_list, int);
memcpy(&buffer[offset], &tmp, sizeof(int16_t));
offset += sizeof(int16_t);
break;
}
case 'd': {
double tmp = va_arg(arg_list, double);
memcpy(&buffer[offset], &tmp, sizeof(double));
offset += sizeof(double);
break;
}
case 'i':
case 'L':
case 'e': {
int32_t tmp = va_arg(arg_list, int);
memcpy(&buffer[offset], &tmp, sizeof(int32_t));
offset += sizeof(int32_t);
break;
}
case 'f': {
float tmp = va_arg(arg_list, double);
memcpy(&buffer[offset], &tmp, sizeof(float));
offset += sizeof(float);
break;
}
case 'n':
charlen = 4;
break;
case 'M':
case 'B': {
uint8_t tmp = va_arg(arg_list, int);
memcpy(&buffer[offset], &tmp, sizeof(uint8_t));
offset += sizeof(uint8_t);
break;
}
case 'H':
case 'C': {
uint16_t tmp = va_arg(arg_list, int);
memcpy(&buffer[offset], &tmp, sizeof(uint16_t));
offset += sizeof(uint16_t);
break;
}
case 'I':
case 'E': {
uint32_t tmp = va_arg(arg_list, uint32_t);
memcpy(&buffer[offset], &tmp, sizeof(uint32_t));
offset += sizeof(uint32_t);
break;
}
case 'N':
charlen = 16;
break;
case 'Z':
charlen = 64;
break;
case 'q': {
int64_t tmp = va_arg(arg_list, int64_t);
memcpy(&buffer[offset], &tmp, sizeof(int64_t));
offset += sizeof(int64_t);
break;
}
case 'Q': {
uint64_t tmp = va_arg(arg_list, uint64_t);
memcpy(&buffer[offset], &tmp, sizeof(uint64_t));
offset += sizeof(uint64_t);
break;
}
case 'a': {
int16_t *tmp = va_arg(arg_list, int16_t*);
const uint8_t bytes = 32*2;
memcpy(&buffer[offset], tmp, bytes);
offset += bytes;
break;
}
}
if (charlen != 0) {
char *tmp = va_arg(arg_list, char*);
uint8_t len = strnlen(tmp, charlen);
memcpy(&buffer[offset], tmp, len);
memset(&buffer[offset+len], 0, charlen-len);
offset += charlen;
}
}
return WritePrioritisedBlock(buffer, msg_len, is_critical);
}
bool AP_Logger_Backend::StartNewLogOK() const
{
if (logging_started()) {
return false;
}
if (_front._log_bitmask == 0) {
return false;
}
if (_front.in_log_download()) {
return false;
}
if (!hal.scheduler->in_main_thread()) {
return false;
}
return true;
}
#if CONFIG_HAL_BOARD == HAL_BOARD_SITL
void AP_Logger_Backend::validate_WritePrioritisedBlock(const void *pBuffer,
uint16_t size)
{
// just check the first few packets to avoid too much overhead
// (finding the structures is expensive)
static uint16_t count = 0;
if (count > 65534) {
return;
}
count++;
// we assume here that we ever WritePrioritisedBlock for a single
// message. If this assumption becomes false we can't do these
// checks.
if (size < 3) {
AP_HAL::panic("Short prioritised block");
}
if (((uint8_t*)pBuffer)[0] != HEAD_BYTE1 ||
((uint8_t*)pBuffer)[1] != HEAD_BYTE2) {
AP_HAL::panic("Not passed a message");
}
const uint8_t type = ((uint8_t*)pBuffer)[2];
uint8_t type_len;
const struct LogStructure *s = _front.structure_for_msg_type(type);
if (s == nullptr) {
const struct AP_Logger::log_write_fmt *t = _front.log_write_fmt_for_msg_type(type);
if (t == nullptr) {
AP_HAL::panic("No structure for msg_type=%u", type);
}
type_len = t->msg_len;
} else {
type_len = s->msg_len;
}
if (type_len != size) {
char name[5] = {}; // get a null-terminated string
if (s->name != nullptr) {
memcpy(name, s->name, 4);
} else {
strncpy(name, "?NM?", ARRAY_SIZE(name));
}
AP_HAL::panic("Size mismatch for %u (%s) (expected=%u got=%u)\n",
type, name, type_len, size);
}
}
#endif
bool AP_Logger_Backend::WritePrioritisedBlock(const void *pBuffer, uint16_t size, bool is_critical)
{
#if CONFIG_HAL_BOARD == HAL_BOARD_SITL && !APM_BUILD_TYPE(APM_BUILD_Replay)
validate_WritePrioritisedBlock(pBuffer, size);
#endif
if (!ShouldLog(is_critical)) {
return false;
}
if (StartNewLogOK()) {
start_new_log();
}
if (!WritesOK()) {
return false;
}
return _WritePrioritisedBlock(pBuffer, size, is_critical);
}
bool AP_Logger_Backend::ShouldLog(bool is_critical)
{
if (!_front.WritesEnabled()) {
return false;
}
if (!_initialised) {
return false;
}
if (!_startup_messagewriter->finished() &&
!hal.scheduler->in_main_thread()) {
// only the main thread may write startup messages out
return false;
}
if (is_critical && have_logged_armed && !_front._params.file_disarm_rot) {
// if we have previously logged while armed then we log all
// critical messages from then on. That fixes a problem where
// logs show the wrong flight mode if you disarm then arm again
return true;
}
if (!_front.vehicle_is_armed() && !_front.log_while_disarmed()) {
return false;
}
if (_front.vehicle_is_armed()) {
have_logged_armed = true;
}
return true;
}
void AP_Logger_Backend::PrepForArming()
{
if (_rotate_pending) {
_rotate_pending = false;
stop_logging();
}
if (logging_started()) {
return;
}
start_new_log();
}
bool AP_Logger_Backend::Write_MessageF(const char *fmt, ...)
{
char msg[65] {}; // sizeof(log_Message.msg) + null-termination
va_list ap;
va_start(ap, fmt);
hal.util->vsnprintf(msg, sizeof(msg), fmt, ap);
va_end(ap);
return Write_Message(msg);
}
// Write rally points
bool AP_Logger_Backend::Write_RallyPoint(uint8_t total,
uint8_t sequence,
const RallyLocation &rally_point)
{
const struct log_Rally pkt_rally{
LOG_PACKET_HEADER_INIT(LOG_RALLY_MSG),
time_us : AP_HAL::micros64(),
total : total,
sequence : sequence,
latitude : rally_point.lat,
longitude : rally_point.lng,
altitude : rally_point.alt
};
return WriteBlock(&pkt_rally, sizeof(pkt_rally));
}
// Write rally points
bool AP_Logger_Backend::Write_Rally()
{
// kick off asynchronous write:
return _startup_messagewriter->writeallrallypoints();
}
/*
convert a list entry number back into a log number (which can then
be converted into a filename). A "list entry number" is a sequence
where the oldest log has a number of 1, the second-from-oldest 2,
and so on. Thus the highest list entry number is equal to the
number of logs.
*/
uint16_t AP_Logger_Backend::log_num_from_list_entry(const uint16_t list_entry)
{
uint16_t oldest_log = find_oldest_log();
if (oldest_log == 0) {
return 0;
}
uint32_t log_num = oldest_log + list_entry - 1;
if (log_num > MAX_LOG_FILES) {
log_num -= MAX_LOG_FILES;
}
return (uint16_t)log_num;
}
// find_oldest_log - find oldest log
// returns 0 if no log was found
uint16_t AP_Logger_Backend::find_oldest_log()
{
if (_cached_oldest_log != 0) {
return _cached_oldest_log;
}
uint16_t last_log_num = find_last_log();
if (last_log_num == 0) {
return 0;
}
_cached_oldest_log = last_log_num - get_num_logs() + 1;
return _cached_oldest_log;
}
void AP_Logger_Backend::vehicle_was_disarmed()
{
if (_front._params.file_disarm_rot) {
// rotate our log. Closing the current one and letting the
// logging restart naturally based on log_disarmed should do
// the trick:
_rotate_pending = true;
}
}
// this sensor is enabled if we should be logging at the moment
bool AP_Logger_Backend::logging_enabled() const
{
if (hal.util->get_soft_armed() ||
_front.log_while_disarmed()) {
return true;
}
return false;
}
void AP_Logger_Backend::Write_AP_Logger_Stats_File(const struct df_stats &_stats)
{
const struct log_DSF pkt {
LOG_PACKET_HEADER_INIT(LOG_DF_FILE_STATS),
time_us : AP_HAL::micros64(),
dropped : _dropped,
blocks : _stats.blocks,
bytes : _stats.bytes,
buf_space_min : _stats.buf_space_min,
buf_space_max : _stats.buf_space_max,
buf_space_avg : (_stats.blocks) ? (_stats.buf_space_sigma / _stats.blocks) : 0,
};
WriteBlock(&pkt, sizeof(pkt));
}
void AP_Logger_Backend::df_stats_gather(const uint16_t bytes_written, uint32_t space_remaining)
{
if (space_remaining < stats.buf_space_min) {
stats.buf_space_min = space_remaining;
}
if (space_remaining > stats.buf_space_max) {
stats.buf_space_max = space_remaining;
}
stats.buf_space_sigma += space_remaining;
stats.bytes += bytes_written;
_log_file_size_bytes += bytes_written;
stats.blocks++;
}
void AP_Logger_Backend::df_stats_clear() {
memset(&stats, '\0', sizeof(stats));
stats.buf_space_min = -1;
}
void AP_Logger_Backend::df_stats_log() {
Write_AP_Logger_Stats_File(stats);
df_stats_clear();
}
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