ardupilot/libraries/AP_GPS/AP_GPS_SBF.cpp

733 lines
31 KiB
C++
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

/*
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 <http://www.gnu.org/licenses/>.
*/
//
// Septentrio GPS driver for ArduPilot.
// Code by Michael Oborne
//
#include "AP_GPS.h"
#include "AP_GPS_SBF.h"
#include <GCS_MAVLink/GCS.h>
#include <AP_InternalError/AP_InternalError.h>
#include <stdio.h>
#include <ctype.h>
#if AP_GPS_SBF_ENABLED
extern const AP_HAL::HAL& hal;
#define SBF_DEBUGGING 0
#if SBF_DEBUGGING
# define Debug(fmt, args ...) \
do { \
hal.console->printf("%s:%d: " fmt "\n", \
__FUNCTION__, __LINE__, \
## args); \
hal.scheduler->delay(1); \
} while(0)
#else
# define Debug(fmt, args ...)
#endif
#ifndef GPS_SBF_STREAM_NUMBER
#define GPS_SBF_STREAM_NUMBER 1
#endif
#define SBF_EXCESS_COMMAND_BYTES 5 // 2 start bytes + validity byte + space byte + endline byte
#define RX_ERROR_MASK (CONGESTION | \
MISSEDEVENT | \
CPUOVERLOAD | \
INVALIDCONFIG | \
OUTOFGEOFENCE)
constexpr const char *AP_GPS_SBF::portIdentifiers[];
constexpr const char* AP_GPS_SBF::_initialisation_blob[];
constexpr const char* AP_GPS_SBF::sbas_on_blob[];
AP_GPS_SBF::AP_GPS_SBF(AP_GPS &_gps,
AP_GPS::Params &_params,
AP_GPS::GPS_State &_state,
AP_HAL::UARTDriver *_port) :
AP_GPS_Backend(_gps, _params, _state, _port)
{
sbf_msg.sbf_state = sbf_msg_parser_t::PREAMBLE1;
_config_last_ack_time = AP_HAL::millis();
// if we ever parse RTK observations it will always be of type NED, so set it once
state.rtk_baseline_coords_type = RTK_BASELINE_COORDINATE_SYSTEM_NED;
// yaw available when option bit set or using dual antenna
if (option_set(AP_GPS::DriverOptions::SBF_UseBaseForYaw) ||
(get_type() == AP_GPS::GPS_Type::GPS_TYPE_SBF_DUAL_ANTENNA)) {
state.gps_yaw_configured = true;
}
}
AP_GPS_SBF::~AP_GPS_SBF (void) {
free(config_string);
}
// Process all bytes available from the stream
//
bool
AP_GPS_SBF::read(void)
{
bool ret = false;
uint32_t available_bytes = port->available();
for (uint32_t i = 0; i < available_bytes; i++) {
uint8_t temp = port->read();
#if AP_GPS_DEBUG_LOGGING_ENABLED
log_data(&temp, 1);
#endif
ret |= parse(temp);
}
const uint32_t now = AP_HAL::millis();
if (gps._auto_config != AP_GPS::GPS_AUTO_CONFIG_DISABLE) {
if (config_step != Config_State::Complete) {
if (now > _init_blob_time) {
if (now > _config_last_ack_time + 2000) {
const size_t port_enable_len = strlen(_port_enable);
if (port_enable_len <= port->txspace()) {
// try to enable input on the GPS port if we have not made progress on configuring it
Debug("SBF Sending port enable");
port->write((const uint8_t*)_port_enable, port_enable_len);
_config_last_ack_time = now;
}
} else if (readyForCommand) {
if (config_string == nullptr) {
switch (config_step) {
case Config_State::Baud_Rate:
if (asprintf(&config_string, "scs,COM%d,baud%d,bits8,No,bit1,%s\n",
(int)params.com_port,
230400,
port->get_flow_control() != AP_HAL::UARTDriver::flow_control::FLOW_CONTROL_ENABLE ? "none" : "RTS|CTS") == -1) {
config_string = nullptr;
}
break;
case Config_State::SSO:
const char *extra_config;
switch (get_type()) {
case AP_GPS::GPS_Type::GPS_TYPE_SBF_DUAL_ANTENNA:
extra_config = "+AttCovEuler+AuxAntPositions";
break;
case AP_GPS::GPS_Type::GPS_TYPE_SBF:
default:
extra_config = "";
break;
}
if (asprintf(&config_string, "sso,Stream%d,COM%d,PVTGeodetic+DOP+ReceiverStatus+VelCovGeodetic+BaseVectorGeod%s,msec100\n",
(int)GPS_SBF_STREAM_NUMBER,
(int)params.com_port,
extra_config) == -1) {
config_string = nullptr;
}
break;
case Config_State::Constellation:
if ((params.gnss_mode&0x6F)!=0) {
//IMES not taken into account by Septentrio receivers
if (asprintf(&config_string, "sst, %s%s%s%s%s%s\n", (params.gnss_mode&(1U<<0))!=0 ? "GPS" : "",
(params.gnss_mode&(1U<<1))!=0 ? ((params.gnss_mode&0x01)==0 ? "SBAS" : "+SBAS") : "",
(params.gnss_mode&(1U<<2))!=0 ? ((params.gnss_mode&0x03)==0 ? "GALILEO" : "+GALILEO") : "",
(params.gnss_mode&(1U<<3))!=0 ? ((params.gnss_mode&0x07)==0 ? "BEIDOU" : "+BEIDOU") : "",
(params.gnss_mode&(1U<<5))!=0 ? ((params.gnss_mode&0x0F)==0 ? "QZSS" : "+QZSS") : "",
(params.gnss_mode&(1U<<6))!=0 ? ((params.gnss_mode&0x2F)==0 ? "GLONASS" : "+GLONASS") : "") == -1) {
config_string=nullptr;
}
}
break;
case Config_State::Blob:
if (asprintf(&config_string, "%s\n", _initialisation_blob[_init_blob_index]) == -1) {
config_string = nullptr;
}
break;
case Config_State::SBAS:
switch ((AP_GPS::SBAS_Mode)gps._sbas_mode) {
case AP_GPS::SBAS_Mode::Disabled:
if (asprintf(&config_string, "%s\n", sbas_off) == -1) {
config_string = nullptr;
}
break;
case AP_GPS::SBAS_Mode::Enabled:
if (asprintf(&config_string, "%s\n", sbas_on_blob[_init_blob_index]) == -1) {
config_string = nullptr;
}
break;
case AP_GPS::SBAS_Mode::DoNotChange:
config_string = nullptr;
config_step = Config_State::Complete;
break;
}
break;
case Config_State::SGA:
{
const char *targetGA = "none";
if (get_type() == AP_GPS::GPS_Type::GPS_TYPE_SBF_DUAL_ANTENNA) {
targetGA = "MultiAntenna";
}
if (asprintf(&config_string, "sga, %s\n", targetGA)) {
config_string = nullptr;
}
break;
}
case Config_State::Complete:
// should never reach here, why search for a config if we have fully configured already
INTERNAL_ERROR(AP_InternalError::error_t::flow_of_control);
break;
}
}
if (config_string != nullptr) {
const size_t config_length = strlen(config_string);
if (config_length <= port->txspace()) {
Debug("SBF sending init string: %s", config_string);
port->write((const uint8_t*)config_string, config_length);
readyForCommand = false;
}
}
}
}
} else if (gps._raw_data == 2) { // only manage disarm/rearms when the user opts into it
if (hal.util->get_soft_armed()) {
_has_been_armed = true;
} else if (_has_been_armed && (RxState & SBF_DISK_MOUNTED)) {
// since init is done at this point and unmounting should be rate limited,
// take over the _init_blob_time variable
if (now > _init_blob_time) {
unmount_disk();
_init_blob_time = now + 1000;
}
}
}
}
// yaw timeout after 300 milliseconds
if ((now - state.gps_yaw_time_ms) > 300) {
state.have_gps_yaw = false;
state.have_gps_yaw_accuracy = false;
}
return ret;
}
bool AP_GPS_SBF::logging_healthy(void) const
{
switch (gps._raw_data) {
case 1:
default:
return (RxState & SBF_DISK_MOUNTED) && (RxState & SBF_DISK_ACTIVITY);
case 2:
return ((RxState & SBF_DISK_MOUNTED) && (RxState & SBF_DISK_ACTIVITY)) || (!hal.util->get_soft_armed() && _has_been_armed);
}
}
bool
AP_GPS_SBF::parse(uint8_t temp)
{
switch (sbf_msg.sbf_state)
{
default:
case sbf_msg_parser_t::PREAMBLE1:
if (temp == SBF_PREAMBLE1) {
sbf_msg.sbf_state = sbf_msg_parser_t::PREAMBLE2;
sbf_msg.read = 0;
} else {
// attempt to detect command prompt
portIdentifier[portLength++] = (char)temp;
bool foundPossiblePort = false;
for (const char *portId : portIdentifiers) {
if (strncmp(portId, portIdentifier, MIN(portLength, 3)) == 0) {
// we found one of the COM/USB/IP related ports
if (portLength == 4) {
// validate that we have an ascii number
if (isdigit((char)temp)) {
foundPossiblePort = true;
break;
}
} else if (portLength >= sizeof(portIdentifier)) {
if ((char)temp == '>') {
readyForCommand = true;
Debug("SBF: Ready for command");
}
} else {
foundPossiblePort = true;
}
break;
}
}
if (!foundPossiblePort) {
portLength = 0;
}
}
break;
case sbf_msg_parser_t::PREAMBLE2:
if (temp == SBF_PREAMBLE2) {
sbf_msg.sbf_state = sbf_msg_parser_t::CRC1;
} else if (temp == 'R') {
Debug("SBF got a response\n");
sbf_msg.sbf_state = sbf_msg_parser_t::COMMAND_LINE;
}
else
{
sbf_msg.sbf_state = sbf_msg_parser_t::PREAMBLE1;
}
break;
case sbf_msg_parser_t::CRC1:
sbf_msg.crc = temp;
sbf_msg.sbf_state = sbf_msg_parser_t::CRC2;
break;
case sbf_msg_parser_t::CRC2:
sbf_msg.crc += (uint16_t)(temp << 8);
sbf_msg.sbf_state = sbf_msg_parser_t::BLOCKID1;
break;
case sbf_msg_parser_t::BLOCKID1:
sbf_msg.blockid = temp;
sbf_msg.sbf_state = sbf_msg_parser_t::BLOCKID2;
break;
case sbf_msg_parser_t::BLOCKID2:
sbf_msg.blockid += (uint16_t)(temp << 8);
sbf_msg.sbf_state = sbf_msg_parser_t::LENGTH1;
break;
case sbf_msg_parser_t::LENGTH1:
sbf_msg.length = temp;
sbf_msg.sbf_state = sbf_msg_parser_t::LENGTH2;
break;
case sbf_msg_parser_t::LENGTH2:
sbf_msg.length += (uint16_t)(temp << 8);
sbf_msg.sbf_state = sbf_msg_parser_t::DATA;
if (sbf_msg.length % 4 != 0) {
sbf_msg.sbf_state = sbf_msg_parser_t::PREAMBLE1;
Debug("bad packet length=%u\n", (unsigned)sbf_msg.length);
}
if (sbf_msg.length < 8) {
Debug("bad packet length=%u\n", (unsigned)sbf_msg.length);
sbf_msg.sbf_state = sbf_msg_parser_t::PREAMBLE1;
crc_error_counter++; // this is a probable buffer overflow, but this
// indicates not enough bytes to do a crc
break;
}
break;
case sbf_msg_parser_t::DATA:
if (sbf_msg.read < sizeof(sbf_msg.data)) {
sbf_msg.data.bytes[sbf_msg.read] = temp;
}
sbf_msg.read++;
if (sbf_msg.read >= (sbf_msg.length - 8)) {
if (sbf_msg.read > sizeof(sbf_msg.data)) {
// not interested in these large messages
sbf_msg.sbf_state = sbf_msg_parser_t::PREAMBLE1;
break;
}
uint16_t crc = crc16_ccitt((uint8_t*)&sbf_msg.blockid, 2, 0);
crc = crc16_ccitt((uint8_t*)&sbf_msg.length, 2, crc);
crc = crc16_ccitt((uint8_t*)&sbf_msg.data, sbf_msg.length - 8, crc);
sbf_msg.sbf_state = sbf_msg_parser_t::PREAMBLE1;
if (sbf_msg.crc == crc) {
return process_message();
} else {
Debug("crc fail\n");
crc_error_counter++;
}
}
break;
case sbf_msg_parser_t::COMMAND_LINE:
if (sbf_msg.read < (sizeof(sbf_msg.data) - 1)) {
sbf_msg.data.bytes[sbf_msg.read] = temp;
} else {
// we don't have enough buffer to compare the commands
// most probable cause is that a user injected a longer command then
// we have buffer for, or it could be a corruption, either way we
// simply ignore the result
sbf_msg.sbf_state = sbf_msg_parser_t::PREAMBLE1;
break;
}
sbf_msg.read++;
if (temp == '\n') {
sbf_msg.data.bytes[sbf_msg.read] = 0;
// received the result, lets assess it
if (sbf_msg.data.bytes[0] == ':') {
// valid command, determine if it was the one we were trying
// to send in the configuration sequence
if (config_string != nullptr) {
if (!strncmp(config_string, (char *)(sbf_msg.data.bytes + 2),
sbf_msg.read - SBF_EXCESS_COMMAND_BYTES)) {
Debug("SBF Ack Command: %s\n", sbf_msg.data.bytes);
free(config_string);
config_string = nullptr;
switch (config_step) {
case Config_State::Baud_Rate:
config_step = Config_State::SSO;
break;
case Config_State::SSO:
config_step = Config_State::Constellation;
break;
case Config_State::Constellation:
config_step = Config_State::Blob;
break;
case Config_State::Blob:
_init_blob_index++;
if (_init_blob_index >= ARRAY_SIZE(_initialisation_blob)) {
config_step = Config_State::SBAS;
_init_blob_index = 0;
}
break;
case Config_State::SBAS:
_init_blob_index++;
if ((gps._sbas_mode == AP_GPS::SBAS_Mode::Disabled)
||_init_blob_index >= ARRAY_SIZE(sbas_on_blob)) {
config_step = Config_State::SGA;
}
break;
case Config_State::SGA:
config_step = Config_State::Complete;
break;
case Config_State::Complete:
// should never reach here, this implies that we validated a config string when we hadn't sent any
INTERNAL_ERROR(AP_InternalError::error_t::flow_of_control);
break;
}
_config_last_ack_time = AP_HAL::millis();
} else {
Debug("SBF Ack command (unexpected): %s\n", sbf_msg.data.bytes);
}
}
} else {
// rejected command, send it out as a debug
Debug("SBF NACK Command: %s\n", sbf_msg.data.bytes);
}
// resume normal parsing
sbf_msg.sbf_state = sbf_msg_parser_t::PREAMBLE1;
break;
}
break;
}
return false;
}
static bool is_DNU(double value)
{
constexpr double DNU = -2e-10f;
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wfloat-equal" // suppress -Wfloat-equal as it's false positive when testing for DNU values
return value != DNU;
#pragma GCC diagnostic pop
}
bool
AP_GPS_SBF::process_message(void)
{
uint16_t blockid = (sbf_msg.blockid & 8191u);
Debug("BlockID %d", blockid);
switch (blockid) {
case PVTGeodetic:
{
const msg4007 &temp = sbf_msg.data.msg4007u;
// Update time state
if (temp.WNc != 65535) {
state.time_week = temp.WNc;
state.time_week_ms = (uint32_t)(temp.TOW);
}
check_new_itow(temp.TOW, sbf_msg.length);
state.last_gps_time_ms = AP_HAL::millis();
// Update velocity state (don't use 2·10^10)
if (temp.Vn > -200000) {
state.velocity.x = (float)(temp.Vn);
state.velocity.y = (float)(temp.Ve);
state.velocity.z = (float)(-temp.Vu);
state.have_vertical_velocity = true;
velocity_to_speed_course(state);
state.rtk_age_ms = temp.MeanCorrAge * 10;
// value is expressed as twice the rms error = int16 * 0.01/2
state.horizontal_accuracy = (float)temp.HAccuracy * 0.005f;
state.vertical_accuracy = (float)temp.VAccuracy * 0.005f;
state.have_horizontal_accuracy = true;
state.have_vertical_accuracy = true;
}
// Update position state (don't use -2·10^10)
if (temp.Latitude > -200000) {
state.location.lat = (int32_t)(temp.Latitude * RAD_TO_DEG_DOUBLE * (double)1e7);
state.location.lng = (int32_t)(temp.Longitude * RAD_TO_DEG_DOUBLE * (double)1e7);
state.have_undulation = !is_DNU(temp.Undulation);
double height = temp.Height; // in metres
if (state.have_undulation) {
height -= temp.Undulation;
state.undulation = -temp.Undulation;
}
set_alt_amsl_cm(state, (float)height * 1e2f); // m -> cm
}
state.num_sats = temp.NrSV;
if (temp.NrSV == 255) {
// Do-Not-Use value for NrSV field in PVTGeodetic message
state.num_sats = 0;
}
Debug("temp.Mode=0x%02x\n", (unsigned)temp.Mode);
switch (temp.Mode & 15) {
case 0: // no pvt
state.status = AP_GPS::NO_FIX;
break;
case 1: // standalone
state.status = AP_GPS::GPS_OK_FIX_3D;
break;
case 2: // dgps
state.status = AP_GPS::GPS_OK_FIX_3D_DGPS;
break;
case 3: // fixed location
state.status = AP_GPS::GPS_OK_FIX_3D;
break;
case 4: // rtk fixed
state.status = AP_GPS::GPS_OK_FIX_3D_RTK_FIXED;
break;
case 5: // rtk float
state.status = AP_GPS::GPS_OK_FIX_3D_RTK_FLOAT;
break;
case 6: // sbas
state.status = AP_GPS::GPS_OK_FIX_3D_DGPS;
break;
case 7: // moving rtk fixed
state.status = AP_GPS::GPS_OK_FIX_3D_RTK_FIXED;
break;
case 8: // moving rtk float
state.status = AP_GPS::GPS_OK_FIX_3D_RTK_FLOAT;
break;
}
if ((temp.Mode & 64) > 0) { // gps is in base mode
state.status = AP_GPS::NO_FIX;
} else if ((temp.Mode & 128) > 0) { // gps only has 2d fix
state.status = AP_GPS::GPS_OK_FIX_2D;
}
return true;
}
case DOP:
{
const msg4001 &temp = sbf_msg.data.msg4001u;
check_new_itow(temp.TOW, sbf_msg.length);
state.hdop = temp.HDOP;
state.vdop = temp.VDOP;
break;
}
case ReceiverStatus:
{
const msg4014 &temp = sbf_msg.data.msg4014u;
check_new_itow(temp.TOW, sbf_msg.length);
RxState = temp.RxState;
if ((RxError & RX_ERROR_MASK) != (temp.RxError & RX_ERROR_MASK)) {
GCS_SEND_TEXT(MAV_SEVERITY_INFO, "GPS %u: SBF error changed (0x%08x/0x%08x)", (unsigned int)(state.instance + 1),
(unsigned int)(RxError & RX_ERROR_MASK), (unsigned int)(temp.RxError & RX_ERROR_MASK));
}
RxError = temp.RxError;
break;
}
case VelCovGeodetic:
{
const msg5908 &temp = sbf_msg.data.msg5908u;
check_new_itow(temp.TOW, sbf_msg.length);
// select the maximum variance, as the EKF will apply it to all the columns in it's estimate
// FIXME: Support returning the covariance matrix to the EKF
float max_variance_squared = MAX(temp.Cov_VnVn, MAX(temp.Cov_VeVe, temp.Cov_VuVu));
if (is_positive(max_variance_squared)) {
state.have_speed_accuracy = true;
state.speed_accuracy = sqrt(max_variance_squared);
} else {
state.have_speed_accuracy = false;
}
break;
}
case AttEulerCov:
{
// yaw accuracy is taken from this message even though we actually calculate the yaw ourself (see AuxAntPositions below)
// this is OK based on the assumption that the calculation methods are similar and that inaccuracy arises from the sensor readings
if (get_type() == AP_GPS::GPS_Type::GPS_TYPE_SBF_DUAL_ANTENNA) {
const msg5939 &temp = sbf_msg.data.msg5939u;
check_new_itow(temp.TOW, sbf_msg.length);
constexpr double floatDNU = -2e-10f;
constexpr uint8_t errorBits = 0x8F; // Bits 0-1 are aux 1 baseline
// Bits 2-3 are aux 2 baseline
// Bit 7 is attitude not requested
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wfloat-equal" // suppress -Wfloat-equal as it's false positive when testing for DNU values
if (((temp.Error & errorBits) == 0)
&& (temp.Cov_HeadHead != floatDNU)) {
#pragma GCC diagnostic pop
state.gps_yaw_accuracy = sqrtf(temp.Cov_HeadHead);
state.have_gps_yaw_accuracy = true;
} else {
state.gps_yaw_accuracy = false;
}
}
break;
}
case AuxAntPositions:
{
#if GPS_MOVING_BASELINE
if (get_type() == AP_GPS::GPS_Type::GPS_TYPE_SBF_DUAL_ANTENNA) {
// calculate yaw using reported antenna positions in earth-frame
// note that this calculation does not correct for the vehicle's roll and pitch meaning it is inaccurate at very high lean angles
const msg5942 &temp = sbf_msg.data.msg5942u;
check_new_itow(temp.TOW, sbf_msg.length);
if (temp.N > 0 && temp.ant1.Error == 0 && temp.ant1.AmbiguityType == 0) {
// valid RTK integer fix
const float rel_heading_deg = degrees(atan2f(temp.ant1.DeltaEast, temp.ant1.DeltaNorth));
calculate_moving_base_yaw(rel_heading_deg,
Vector3f(temp.ant1.DeltaNorth, temp.ant1.DeltaEast, temp.ant1.DeltaUp).length(),
-temp.ant1.DeltaUp);
}
}
#endif
break;
}
case BaseVectorGeod:
{
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wfloat-equal" // suppress -Wfloat-equal as it's false positive when testing for DNU values
const msg4028 &temp = sbf_msg.data.msg4028u;
// just breakout any consts we need for Do Not Use (DNU) reasons
constexpr double doubleDNU = -2e-10;
constexpr uint16_t uint16DNU = 65535;
check_new_itow(temp.TOW, sbf_msg.length);
if (temp.N == 0) { // no sub blocks so just bail, we can't do anything useful here
state.rtk_num_sats = 0;
state.rtk_age_ms = 0;
state.rtk_baseline_y_mm = 0;
state.rtk_baseline_x_mm = 0;
state.rtk_baseline_z_mm = 0;
break;
}
state.rtk_num_sats = temp.info.NrSV;
state.rtk_age_ms = (temp.info.CorrAge != 65535) ? ((uint32_t)temp.info.CorrAge) * 10 : 0;
// copy the position as long as the data isn't DNU, we require NED, and heading before accepting any of it
if ((temp.info.DeltaEast != doubleDNU) && (temp.info.DeltaNorth != doubleDNU) && (temp.info.DeltaUp != doubleDNU) &&
(temp.info.Azimuth != uint16DNU)) {
state.rtk_baseline_y_mm = temp.info.DeltaEast * 1e3;
state.rtk_baseline_x_mm = temp.info.DeltaNorth * 1e3;
state.rtk_baseline_z_mm = temp.info.DeltaUp * -1e3;
#if GPS_MOVING_BASELINE
// copy the baseline data as a yaw source
if (option_set(AP_GPS::DriverOptions::SBF_UseBaseForYaw)) {
calculate_moving_base_yaw(temp.info.Azimuth * 0.01f + 180.0f,
Vector3f(temp.info.DeltaNorth, temp.info.DeltaEast, temp.info.DeltaUp).length(),
-temp.info.DeltaUp);
}
#endif // GPS_MOVING_BASELINE
} else if (option_set(AP_GPS::DriverOptions::SBF_UseBaseForYaw)) {
state.rtk_baseline_y_mm = 0;
state.rtk_baseline_x_mm = 0;
state.rtk_baseline_z_mm = 0;
state.have_gps_yaw = false;
}
#pragma GCC diagnostic pop
break;
}
}
return false;
}
void AP_GPS_SBF::broadcast_configuration_failure_reason(void) const
{
if (gps._auto_config != AP_GPS::GPS_AUTO_CONFIG_DISABLE &&
config_step != Config_State::Complete) {
GCS_SEND_TEXT(MAV_SEVERITY_INFO, "GPS %u: SBF is not fully configured (%u/%u/%u/%u)",
state.instance + 1,
(unsigned)config_step,
_init_blob_index,
(unsigned)ARRAY_SIZE(_initialisation_blob),
(unsigned)ARRAY_SIZE(sbas_on_blob));
}
}
bool AP_GPS_SBF::is_configured (void) const {
return ((gps._auto_config == AP_GPS::GPS_AUTO_CONFIG_DISABLE) ||
(config_step == Config_State::Complete) ||AP_SIM_GPS_SBF_ENABLED);
}
bool AP_GPS_SBF::is_healthy (void) const {
return (RxError & RX_ERROR_MASK) == 0;
}
void AP_GPS_SBF::mount_disk (void) const {
const char* command = "emd, DSK1, Mount\n";
Debug("Mounting disk");
port->write((const uint8_t*)command, strlen(command));
}
void AP_GPS_SBF::unmount_disk (void) const {
const char* command = "emd, DSK1, Unmount\n";
GCS_SEND_TEXT(MAV_SEVERITY_DEBUG, "SBF unmounting disk");
port->write((const uint8_t*)command, strlen(command));
}
bool AP_GPS_SBF::prepare_for_arming(void) {
bool is_logging = true; // assume that its logging until proven otherwise
if (gps._raw_data) {
if (!(RxState & SBF_DISK_MOUNTED)){
is_logging = false;
GCS_SEND_TEXT(MAV_SEVERITY_INFO, "GPS %d: SBF disk is not mounted", state.instance + 1);
// simply attempt to mount the disk, no need to check if the command was
// ACK/NACK'd as we don't continuously attempt to remount the disk
GCS_SEND_TEXT(MAV_SEVERITY_INFO, "GPS %d: Attempting to mount disk", state.instance + 1);
mount_disk();
// reset the flag to indicate if we should be logging
_has_been_armed = false;
}
else if (RxState & SBF_DISK_FULL) {
is_logging = false;
GCS_SEND_TEXT(MAV_SEVERITY_INFO, "GPS %d: SBF disk is full", state.instance + 1);
}
else if (!(RxState & SBF_DISK_ACTIVITY)) {
is_logging = false;
GCS_SEND_TEXT(MAV_SEVERITY_INFO, "GPS %d: SBF is not currently logging", state.instance + 1);
}
}
return is_logging;
}
#endif