mirror of https://github.com/ArduPilot/ardupilot
554 lines
16 KiB
C++
554 lines
16 KiB
C++
/*
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* Location.cpp
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*/
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#include "Location.h"
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#ifndef HAL_BOOTLOADER_BUILD
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#include <AP_AHRS/AP_AHRS.h>
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#include <AP_Terrain/AP_Terrain.h>
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/// constructors
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Location::Location()
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{
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zero();
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}
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const Location definitely_zero{};
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bool Location::is_zero(void) const
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{
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return !memcmp(this, &definitely_zero, sizeof(*this));
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}
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void Location::zero(void)
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{
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memset(this, 0, sizeof(*this));
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}
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// Construct location using position (NEU) from ekf_origin for the given altitude frame
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Location::Location(int32_t latitude, int32_t longitude, int32_t alt_in_cm, AltFrame frame)
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{
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// make sure we know what size the Location object is:
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ASSERT_STORAGE_SIZE(Location, 16);
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zero();
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lat = latitude;
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lng = longitude;
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set_alt_cm(alt_in_cm, frame);
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}
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#if AP_AHRS_ENABLED
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Location::Location(const Vector3f &ekf_offset_neu, AltFrame frame)
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{
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zero();
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// store alt and alt frame
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set_alt_cm(ekf_offset_neu.z, frame);
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// calculate lat, lon
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Location ekf_origin;
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if (AP::ahrs().get_origin(ekf_origin)) {
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lat = ekf_origin.lat;
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lng = ekf_origin.lng;
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offset(ekf_offset_neu.x * 0.01, ekf_offset_neu.y * 0.01);
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}
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}
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#endif // AP_AHRS_ENABLED
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void Location::set_alt_cm(int32_t alt_cm, AltFrame frame)
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{
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alt = alt_cm;
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relative_alt = false;
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terrain_alt = false;
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origin_alt = false;
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switch (frame) {
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case AltFrame::ABSOLUTE:
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// do nothing
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break;
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case AltFrame::ABOVE_HOME:
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relative_alt = true;
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break;
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case AltFrame::ABOVE_ORIGIN:
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origin_alt = true;
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break;
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case AltFrame::ABOVE_TERRAIN:
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// we mark it as a relative altitude, as it doesn't have
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// home alt added
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relative_alt = true;
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terrain_alt = true;
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break;
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}
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}
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// converts altitude to new frame
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bool Location::change_alt_frame(AltFrame desired_frame)
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{
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int32_t new_alt_cm;
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if (!get_alt_cm(desired_frame, new_alt_cm)) {
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return false;
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}
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set_alt_cm(new_alt_cm, desired_frame);
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return true;
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}
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// get altitude frame
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Location::AltFrame Location::get_alt_frame() const
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{
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if (terrain_alt) {
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return AltFrame::ABOVE_TERRAIN;
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}
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if (origin_alt) {
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return AltFrame::ABOVE_ORIGIN;
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}
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if (relative_alt) {
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return AltFrame::ABOVE_HOME;
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}
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return AltFrame::ABSOLUTE;
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}
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/// get altitude in desired frame
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bool Location::get_alt_cm(AltFrame desired_frame, int32_t &ret_alt_cm) const
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{
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#if CONFIG_HAL_BOARD == HAL_BOARD_SITL
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if (!initialised()) {
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AP_HAL::panic("Should not be called on invalid location: Location cannot be (0, 0, 0)");
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}
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#endif
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Location::AltFrame frame = get_alt_frame();
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// shortcut if desired and underlying frame are the same
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if (desired_frame == frame) {
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ret_alt_cm = alt;
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return true;
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}
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// check for terrain altitude
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float alt_terr_cm = 0;
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if (frame == AltFrame::ABOVE_TERRAIN || desired_frame == AltFrame::ABOVE_TERRAIN) {
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#if AP_TERRAIN_AVAILABLE
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AP_Terrain *terrain = AP::terrain();
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if (terrain == nullptr) {
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return false;
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}
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if (!terrain->height_amsl(*this, alt_terr_cm)) {
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return false;
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}
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// convert terrain alt to cm
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alt_terr_cm *= 100.0f;
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#else
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return false;
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#endif
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}
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// convert alt to absolute
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int32_t alt_abs = 0;
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switch (frame) {
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case AltFrame::ABSOLUTE:
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alt_abs = alt;
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break;
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case AltFrame::ABOVE_HOME:
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#if AP_AHRS_ENABLED
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if (!AP::ahrs().home_is_set()) {
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return false;
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}
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alt_abs = alt + AP::ahrs().get_home().alt;
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#else
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return false;
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#endif // AP_AHRS_ENABLED
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break;
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case AltFrame::ABOVE_ORIGIN:
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#if AP_AHRS_ENABLED
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{
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// fail if we cannot get ekf origin
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Location ekf_origin;
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if (!AP::ahrs().get_origin(ekf_origin)) {
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return false;
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}
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alt_abs = alt + ekf_origin.alt;
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}
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break;
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#else
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return false;
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#endif // AP_AHRS_ENABLED
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case AltFrame::ABOVE_TERRAIN:
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alt_abs = alt + alt_terr_cm;
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break;
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}
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// convert absolute to desired frame
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switch (desired_frame) {
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case AltFrame::ABSOLUTE:
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ret_alt_cm = alt_abs;
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return true;
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case AltFrame::ABOVE_HOME:
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#if AP_AHRS_ENABLED
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if (!AP::ahrs().home_is_set()) {
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return false;
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}
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ret_alt_cm = alt_abs - AP::ahrs().get_home().alt;
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#else
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return false;
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#endif // AP_AHRS_ENABLED
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return true;
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case AltFrame::ABOVE_ORIGIN:
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#if AP_AHRS_ENABLED
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{
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// fail if we cannot get ekf origin
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Location ekf_origin;
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if (!AP::ahrs().get_origin(ekf_origin)) {
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return false;
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}
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ret_alt_cm = alt_abs - ekf_origin.alt;
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return true;
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}
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#else
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return false;
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#endif // AP_AHRS_ENABLED
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case AltFrame::ABOVE_TERRAIN:
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ret_alt_cm = alt_abs - alt_terr_cm;
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return true;
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}
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return false; // LCOV_EXCL_LINE - not reachable
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}
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bool Location::get_alt_m(AltFrame desired_frame, float &ret_alt) const
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{
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int32_t ret_alt_cm;
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if (!get_alt_cm(desired_frame, ret_alt_cm)) {
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return false;
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}
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ret_alt = ret_alt_cm * 0.01;
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return true;
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}
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#if AP_AHRS_ENABLED
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// converts location to a vector from origin; if this method returns
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// false then vec_ne is unmodified
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template<typename T>
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bool Location::get_vector_xy_from_origin_NE(T &vec_ne) const
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{
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Location ekf_origin;
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if (!AP::ahrs().get_origin(ekf_origin)) {
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return false;
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}
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vec_ne.x = (lat-ekf_origin.lat) * LATLON_TO_CM;
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vec_ne.y = diff_longitude(lng,ekf_origin.lng) * LATLON_TO_CM * longitude_scale((lat+ekf_origin.lat)/2);
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return true;
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}
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// define for float and position vectors
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template bool Location::get_vector_xy_from_origin_NE<Vector2f>(Vector2f &vec_ne) const;
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#if HAL_WITH_POSTYPE_DOUBLE
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template bool Location::get_vector_xy_from_origin_NE<Vector2p>(Vector2p &vec_ne) const;
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#endif
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// converts location to a vector from origin; if this method returns
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// false then vec_neu is unmodified
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template<typename T>
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bool Location::get_vector_from_origin_NEU(T &vec_neu) const
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{
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// convert altitude
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int32_t alt_above_origin_cm = 0;
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if (!get_alt_cm(AltFrame::ABOVE_ORIGIN, alt_above_origin_cm)) {
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return false;
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}
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// convert lat, lon
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if (!get_vector_xy_from_origin_NE(vec_neu.xy())) {
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return false;
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}
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vec_neu.z = alt_above_origin_cm;
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return true;
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}
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// define for float and position vectors
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template bool Location::get_vector_from_origin_NEU<Vector3f>(Vector3f &vec_neu) const;
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#if HAL_WITH_POSTYPE_DOUBLE
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template bool Location::get_vector_from_origin_NEU<Vector3p>(Vector3p &vec_neu) const;
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#endif
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#endif // AP_AHRS_ENABLED
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// return horizontal distance in meters between two locations
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ftype Location::get_distance(const Location &loc2) const
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{
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ftype dlat = (ftype)(loc2.lat - lat);
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ftype dlng = ((ftype)diff_longitude(loc2.lng,lng)) * longitude_scale((lat+loc2.lat)/2);
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return norm(dlat, dlng) * LOCATION_SCALING_FACTOR;
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}
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// return the altitude difference in meters taking into account alt frame.
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bool Location::get_alt_distance(const Location &loc2, ftype &distance) const
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{
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int32_t alt1, alt2;
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if (!get_alt_cm(AltFrame::ABSOLUTE, alt1) || !loc2.get_alt_cm(AltFrame::ABSOLUTE, alt2)) {
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return false;
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}
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distance = (alt1 - alt2) * 0.01;
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return true;
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}
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/*
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return the distance in meters in North/East plane as a N/E vector
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from loc1 to loc2
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*/
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Vector2f Location::get_distance_NE(const Location &loc2) const
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{
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return Vector2f((loc2.lat - lat) * LOCATION_SCALING_FACTOR,
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diff_longitude(loc2.lng,lng) * LOCATION_SCALING_FACTOR * longitude_scale((loc2.lat+lat)/2));
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}
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// return the distance in meters in North/East/Down plane as a N/E/D vector to loc2, NOT CONSIDERING ALT FRAME!
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Vector3f Location::get_distance_NED(const Location &loc2) const
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{
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return Vector3f((loc2.lat - lat) * LOCATION_SCALING_FACTOR,
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diff_longitude(loc2.lng,lng) * LOCATION_SCALING_FACTOR * longitude_scale((lat+loc2.lat)/2),
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(alt - loc2.alt) * 0.01);
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}
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// return the distance in meters in North/East/Down plane as a N/E/D vector to loc2
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Vector3d Location::get_distance_NED_double(const Location &loc2) const
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{
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return Vector3d((loc2.lat - lat) * double(LOCATION_SCALING_FACTOR),
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diff_longitude(loc2.lng,lng) * LOCATION_SCALING_FACTOR * longitude_scale((lat+loc2.lat)/2),
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(alt - loc2.alt) * 0.01);
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}
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// return the distance in meters in North/East/Down plane as a N/E/D vector to loc2 considering alt frame, if altitude cannot be resolved down distance is 0
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Vector3f Location::get_distance_NED_alt_frame(const Location &loc2) const
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{
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int32_t alt1, alt2 = 0;
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if (!get_alt_cm(AltFrame::ABSOLUTE, alt1) || !loc2.get_alt_cm(AltFrame::ABSOLUTE, alt2)) {
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// one or both of the altitudes are invalid, don't do alt distance calc
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alt1 = 0, alt2 = 0;
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}
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return Vector3f((loc2.lat - lat) * LOCATION_SCALING_FACTOR,
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diff_longitude(loc2.lng,lng) * LOCATION_SCALING_FACTOR * longitude_scale((loc2.lat+lat)/2),
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(alt1 - alt2) * 0.01);
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}
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Vector2d Location::get_distance_NE_double(const Location &loc2) const
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{
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return Vector2d((loc2.lat - lat) * double(LOCATION_SCALING_FACTOR),
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diff_longitude(loc2.lng,lng) * double(LOCATION_SCALING_FACTOR) * longitude_scale((lat+loc2.lat)/2));
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}
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Vector2F Location::get_distance_NE_ftype(const Location &loc2) const
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{
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return Vector2F((loc2.lat - lat) * ftype(LOCATION_SCALING_FACTOR),
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diff_longitude(loc2.lng,lng) * ftype(LOCATION_SCALING_FACTOR) * longitude_scale((lat+loc2.lat)/2));
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}
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// extrapolate latitude/longitude given distances (in meters) north and east
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void Location::offset_latlng(int32_t &lat, int32_t &lng, ftype ofs_north, ftype ofs_east)
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{
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const int32_t dlat = ofs_north * LOCATION_SCALING_FACTOR_INV;
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const int64_t dlng = (ofs_east * LOCATION_SCALING_FACTOR_INV) / longitude_scale(lat+dlat/2);
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lat += dlat;
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lat = limit_lattitude(lat);
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lng = wrap_longitude(dlng+lng);
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}
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// extrapolate latitude/longitude given distances (in meters) north and east
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void Location::offset(ftype ofs_north, ftype ofs_east)
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{
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offset_latlng(lat, lng, ofs_north, ofs_east);
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}
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// extrapolate latitude/longitude given distances (in meters) north
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// and east. Note that this is metres, *even for the altitude*.
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void Location::offset(const Vector3p &ofs_ned)
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{
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offset_latlng(lat, lng, ofs_ned.x, ofs_ned.y);
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alt += -ofs_ned.z * 100; // m -> cm
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}
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/*
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* extrapolate latitude/longitude given bearing and distance
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* Note that this function is accurate to about 1mm at a distance of
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* 100m. This function has the advantage that it works in relative
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* positions, so it keeps the accuracy even when dealing with small
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* distances and floating point numbers
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*/
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void Location::offset_bearing(ftype bearing_deg, ftype distance)
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{
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const ftype ofs_north = cosF(radians(bearing_deg)) * distance;
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const ftype ofs_east = sinF(radians(bearing_deg)) * distance;
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offset(ofs_north, ofs_east);
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}
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// extrapolate latitude/longitude given bearing, pitch and distance
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void Location::offset_bearing_and_pitch(ftype bearing_deg, ftype pitch_deg, ftype distance)
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{
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const ftype ofs_north = cosF(radians(pitch_deg)) * cosF(radians(bearing_deg)) * distance;
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const ftype ofs_east = cosF(radians(pitch_deg)) * sinF(radians(bearing_deg)) * distance;
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offset(ofs_north, ofs_east);
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const int32_t dalt = sinF(radians(pitch_deg)) * distance *100.0f;
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alt += dalt;
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}
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ftype Location::longitude_scale(int32_t lat)
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{
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ftype scale = cosF(lat * (1.0e-7 * DEG_TO_RAD));
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return MAX(scale, 0.01);
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}
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/*
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* convert invalid waypoint with useful data. return true if location changed
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*/
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bool Location::sanitize(const Location &defaultLoc)
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{
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bool has_changed = false;
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// convert lat/lng=0 to mean current point
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if (lat == 0 && lng == 0) {
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lat = defaultLoc.lat;
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lng = defaultLoc.lng;
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has_changed = true;
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}
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// convert relative alt=0 to mean current alt
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if (alt == 0 && relative_alt) {
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int32_t defaultLoc_alt;
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if (defaultLoc.get_alt_cm(get_alt_frame(), defaultLoc_alt)) {
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alt = defaultLoc_alt;
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has_changed = true;
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}
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}
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// limit lat/lng to appropriate ranges
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if (!check_latlng()) {
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lat = defaultLoc.lat;
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lng = defaultLoc.lng;
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has_changed = true;
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}
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return has_changed;
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}
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// return bearing in radians from location to loc2, return is 0 to 2*Pi
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ftype Location::get_bearing(const Location &loc2) const
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{
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const int32_t off_x = diff_longitude(loc2.lng,lng);
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const int32_t off_y = (loc2.lat - lat) / loc2.longitude_scale((lat+loc2.lat)/2);
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ftype bearing = (M_PI*0.5) + atan2F(-off_y, off_x);
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if (bearing < 0) {
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bearing += 2*M_PI;
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}
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return bearing;
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}
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/*
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return true if lat and lng match. Ignores altitude and options
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*/
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bool Location::same_latlon_as(const Location &loc2) const
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{
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return (lat == loc2.lat) && (lng == loc2.lng);
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}
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bool Location::same_alt_as(const Location &loc2) const
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{
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// fast path if the altitude frame is the same
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if (this->get_alt_frame() == loc2.get_alt_frame()) {
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return this->alt == loc2.alt;
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}
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ftype alt_diff;
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bool have_diff = this->get_alt_distance(loc2, alt_diff);
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const ftype tolerance = FLT_EPSILON;
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return have_diff && (fabsF(alt_diff) < tolerance);
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}
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// return true when lat and lng are within range
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bool Location::check_latlng() const
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{
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return check_lat(lat) && check_lng(lng);
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}
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// see if location is past a line perpendicular to
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// the line between point1 and point2 and passing through point2.
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// If point1 is our previous waypoint and point2 is our target waypoint
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// then this function returns true if we have flown past
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// the target waypoint
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bool Location::past_interval_finish_line(const Location &point1, const Location &point2) const
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{
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return this->line_path_proportion(point1, point2) >= 1.0f;
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}
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/*
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return the proportion we are along the path from point1 to
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point2, along a line parallel to point1<->point2.
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This will be more than 1 if we have passed point2
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*/
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float Location::line_path_proportion(const Location &point1, const Location &point2) const
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{
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const Vector2f vec1 = point1.get_distance_NE(point2);
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const Vector2f vec2 = point1.get_distance_NE(*this);
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const ftype dsquared = sq(vec1.x) + sq(vec1.y);
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|
if (dsquared < 0.001f) {
|
|
// the two points are very close together
|
|
return 1.0f;
|
|
}
|
|
return (vec1 * vec2) / dsquared;
|
|
}
|
|
|
|
/*
|
|
wrap longitude for -180e7 to 180e7
|
|
*/
|
|
int32_t Location::wrap_longitude(int64_t lon)
|
|
{
|
|
if (lon > 1800000000L) {
|
|
lon = int32_t(lon-3600000000LL);
|
|
} else if (lon < -1800000000L) {
|
|
lon = int32_t(lon+3600000000LL);
|
|
}
|
|
return int32_t(lon);
|
|
}
|
|
|
|
/*
|
|
get lon1-lon2, wrapping at -180e7 to 180e7
|
|
*/
|
|
int32_t Location::diff_longitude(int32_t lon1, int32_t lon2)
|
|
{
|
|
if ((lon1 & 0x80000000) == (lon2 & 0x80000000)) {
|
|
// common case of same sign
|
|
return lon1 - lon2;
|
|
}
|
|
int64_t dlon = int64_t(lon1)-int64_t(lon2);
|
|
if (dlon > 1800000000LL) {
|
|
dlon -= 3600000000LL;
|
|
} else if (dlon < -1800000000LL) {
|
|
dlon += 3600000000LL;
|
|
}
|
|
return int32_t(dlon);
|
|
}
|
|
|
|
/*
|
|
limit latitude to -90e7 to 90e7
|
|
*/
|
|
int32_t Location::limit_lattitude(int32_t lat)
|
|
{
|
|
if (lat > 900000000L) {
|
|
lat = 1800000000LL - lat;
|
|
} else if (lat < -900000000L) {
|
|
lat = -(1800000000LL + lat);
|
|
}
|
|
return lat;
|
|
}
|
|
|
|
// update altitude and alt-frame base on this location's horizontal position between point1 and point2
|
|
// this location's lat,lon is used to calculate the alt of the closest point on the line between point1 and point2
|
|
// origin and destination's altitude frames must be the same
|
|
// this alt-frame will be updated to match the destination alt frame
|
|
void Location::linearly_interpolate_alt(const Location &point1, const Location &point2)
|
|
{
|
|
// new target's distance along the original track and then linear interpolate between the original origin and destination altitudes
|
|
set_alt_cm(point1.alt + (point2.alt - point1.alt) * constrain_float(line_path_proportion(point1, point2), 0.0f, 1.0f), point2.get_alt_frame());
|
|
}
|
|
|
|
#endif // HAL_BOOTLOADER_BUILD
|