ardupilot/libraries/RC_Channel/RC_Channel.cpp

1766 lines
52 KiB
C++

/*
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/>.
*/
/*
* RC_Channel.cpp - class for one RC channel input
*/
#include "RC_Channel_config.h"
#if AP_RC_CHANNEL_ENABLED
#include <stdlib.h>
#include <cmath>
#include <AP_HAL/AP_HAL.h>
extern const AP_HAL::HAL& hal;
#include <AP_Math/AP_Math.h>
#include "RC_Channel.h"
#include <GCS_MAVLink/GCS.h>
#include <AC_Avoidance/AC_Avoid.h>
#include <AC_Sprayer/AC_Sprayer.h>
#include <AP_Camera/AP_Camera.h>
#include <AP_Camera/AP_RunCam.h>
#include <AP_Compass/AP_Compass.h>
#include <AP_Generator/AP_Generator.h>
#include <AP_Gripper/AP_Gripper.h>
#include <AP_GyroFFT/AP_GyroFFT.h>
#include <AP_ADSB/AP_ADSB.h>
#include <AP_BoardConfig/AP_BoardConfig.h>
#include <AP_BattMonitor/AP_BattMonitor.h>
#include <AP_LandingGear/AP_LandingGear.h>
#include <AP_Logger/AP_Logger.h>
#include <AP_ServoRelayEvents/AP_ServoRelayEvents.h>
#include <SRV_Channel/SRV_Channel.h>
#include <AP_Arming/AP_Arming.h>
#include <AP_Avoidance/AP_Avoidance.h>
#include <AP_GPS/AP_GPS.h>
#include <AC_Fence/AC_Fence.h>
#include <AP_OpticalFlow/AP_OpticalFlow.h>
#include <AP_VisualOdom/AP_VisualOdom.h>
#include <AP_AHRS/AP_AHRS.h>
#include <AP_Mount/AP_Mount.h>
#include <AP_Notify/AP_Notify.h>
#include <AP_VideoTX/AP_VideoTX.h>
#include <AP_Torqeedo/AP_Torqeedo.h>
#include <AP_Vehicle/AP_Vehicle_Type.h>
#define SWITCH_DEBOUNCE_TIME_MS 200
const AP_Param::GroupInfo RC_Channel::var_info[] = {
// @Param: MIN
// @DisplayName: RC min PWM
// @Description: RC minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
// @Units: PWM
// @Range: 800 2200
// @Increment: 1
// @User: Advanced
AP_GROUPINFO("MIN", 1, RC_Channel, radio_min, 1100),
// @Param: TRIM
// @DisplayName: RC trim PWM
// @Description: RC trim (neutral) PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
// @Units: PWM
// @Range: 800 2200
// @Increment: 1
// @User: Advanced
AP_GROUPINFO("TRIM", 2, RC_Channel, radio_trim, 1500),
// @Param: MAX
// @DisplayName: RC max PWM
// @Description: RC maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
// @Units: PWM
// @Range: 800 2200
// @Increment: 1
// @User: Advanced
AP_GROUPINFO("MAX", 3, RC_Channel, radio_max, 1900),
// @Param: REVERSED
// @DisplayName: RC reversed
// @Description: Reverse channel input. Set to 0 for normal operation. Set to 1 to reverse this input channel.
// @Values: 0:Normal,1:Reversed
// @User: Advanced
AP_GROUPINFO("REVERSED", 4, RC_Channel, reversed, 0),
// @Param: DZ
// @DisplayName: RC dead-zone
// @Description: PWM dead zone in microseconds around trim or bottom
// @Units: PWM
// @Range: 0 200
// @User: Advanced
AP_GROUPINFO("DZ", 5, RC_Channel, dead_zone, 0),
// @Param: OPTION
// @DisplayName: RC input option
// @Description: Function assigned to this RC channel
// @Values{Copter, Rover, Plane, Blimp}: 0:Do Nothing
// @Values{Copter}: 2:FLIP Mode
// @Values{Copter}: 3:Simple Mode
// @Values{Copter, Rover, Plane}: 4:RTL
// @Values{Copter}: 5:Save Trim
// @Values{Rover}: 5:Save Trim (4.1 and lower)
// @Values{Copter, Rover}: 7:Save WP
// @Values{Copter, Rover, Plane}: 9:Camera Trigger
// @Values{Copter}: 10:RangeFinder Enable
// @Values{Copter, Rover, Plane}: 11:Fence Enable
// @Values{Copter}: 13:Super Simple Mode
// @Values{Copter}: 14:Acro Trainer
// @Values{Copter}: 15:Sprayer Enable
// @Values{Copter, Rover, Plane}: 16:AUTO Mode
// @Values{Copter}: 17:AUTOTUNE Mode
// @Values{Copter, Blimp}: 18:LAND Mode
// @Values{Copter, Rover}: 19:Gripper Release
// @Values{Copter}: 21:Parachute Enable
// @Values{Copter, Plane}: 22:Parachute Release
// @Values{Copter}: 23:Parachute 3pos
// @Values{Copter, Rover, Plane}: 24:Auto Mission Reset
// @Values{Copter}: 25:AttCon Feed Forward
// @Values{Copter}: 26:AttCon Accel Limits
// @Values{Copter, Rover, Plane}: 27:Retract Mount1
// @Values{Copter, Rover, Plane}: 28:Relay On/Off
// @Values{Copter, Plane}: 29:Landing Gear
// @Values{Copter}: 30:Lost Copter Sound
// @Values{Rover}: 30:Lost Rover Sound
// @Values{Plane}: 30:Lost Plane Sound
// @Values{Copter, Rover, Plane}: 31:Motor Emergency Stop
// @Values{Copter}: 32:Motor Interlock
// @Values{Copter}: 33:BRAKE Mode
// @Values{Copter, Rover, Plane}: 34:Relay2 On/Off, 35:Relay3 On/Off, 36:Relay4 On/Off
// @Values{Copter}: 37:THROW Mode
// @Values{Copter, Plane}: 38:ADSB Avoidance Enable
// @Values{Copter}: 39:PrecLoiter Enable
// @Values{Copter, Rover}: 40:Proximity Avoidance Enable
// @Values{Copter, Rover, Plane}: 41:ArmDisarm (4.1 and lower)
// @Values{Copter, Rover}: 42:SMARTRTL Mode
// @Values{Copter, Plane}: 43:InvertedFlight Enable
// @Values{Copter}: 44:Winch Enable, 45:Winch Control
// @Values{Copter, Rover, Plane, Blimp}: 46:RC Override Enable
// @Values{Copter}: 47:User Function 1, 48:User Function 2, 49:User Function 3
// @Values{Rover}: 50:LearnCruise Speed
// @Values{Rover, Plane}: 51:MANUAL Mode
// @Values{Copter, Rover, Plane}: 52:ACRO Mode
// @Values{Rover}: 53:STEERING Mode
// @Values{Rover}: 54:HOLD Mode
// @Values{Copter, Rover, Plane}: 55:GUIDED Mode
// @Values{Copter, Rover, Plane}: 56:LOITER Mode
// @Values{Copter, Rover}: 57:FOLLOW Mode
// @Values{Copter, Rover, Plane}: 58:Clear Waypoints
// @Values{Rover}: 59:Simple Mode
// @Values{Copter}: 60:ZigZag Mode
// @Values{Copter}: 61:ZigZag SaveWP
// @Values{Copter, Rover, Plane}: 62:Compass Learn
// @Values{Rover}: 63:Sailboat Tack
// @Values{Plane}: 64:Reverse Throttle
// @Values{Copter, Rover, Plane, Blimp}: 65:GPS Disable
// @Values{Copter, Rover, Plane}: 66:Relay5 On/Off, 67:Relay6 On/Off
// @Values{Copter}: 68:STABILIZE Mode
// @Values{Copter}: 69:POSHOLD Mode
// @Values{Copter}: 70:ALTHOLD Mode
// @Values{Copter}: 71:FLOWHOLD Mode
// @Values{Copter,Plane}: 72:CIRCLE Mode
// @Values{Copter}: 73:DRIFT Mode
// @Values{Rover}: 74:Sailboat motoring 3pos
// @Values{Copter}: 75:SurfaceTrackingUpDown
// @Values{Copter}: 76:STANDBY Mode
// @Values{Plane}: 77:TAKEOFF Mode
// @Values{Copter, Rover, Plane}: 78:RunCam Control
// @Values{Copter, Rover, Plane}: 79:RunCam OSD Control
// @Values{Copter}: 80:VisOdom Align
// @Values{Rover}: 80:VisoOdom Align
// @Values{Copter, Rover, Plane, Blimp}: 81:Disarm
// @Values{Plane}: 82:QAssist 3pos
// @Values{Copter}: 83:ZigZag Auto
// @Values{Copter, Plane}: 84:AirMode
// @Values{Copter, Plane}: 85:Generator
// @Values{Plane}: 86:Non Auto Terrain Follow Disable
// @Values{Plane}: 87:Crow Select
// @Values{Plane}: 88:Soaring Enable
// @Values{Plane}: 89:Landing Flare
// @Values{Copter, Rover, Plane, Blimp}: 90:EKF Pos Source
// @Values{Plane}: 91:Airspeed Ratio Calibration
// @Values{Plane}: 92:FBWA Mode
// @Values{Copter, Rover, Plane}: 94:VTX Power
// @Values{Plane}: 95:FBWA taildragger takeoff mode
// @Values{Plane}: 96:Trigger re-reading of mode switch
// @Values{Rover}: 97:Windvane home heading direction offset
// @Values{Plane}: 98:TRAINING Mode
// @Values{Copter}: 99:AUTO RTL
// @Values{Copter, Rover, Plane, Blimp}: 100:KillIMU1, 101:KillIMU2
// @Values{Copter, Rover, Plane}: 102:Camera Mode Toggle
// @Values{Copter, Rover, Plane}: 105:GPS Disable Yaw
// @Values{Rover, Plane}: 106:Disable Airspeed Use
// @Values{Plane}: 107:Enable FW Autotune
// @Values{Plane}: 108:QRTL Mode
// @Values{Copter}: 109:use Custom Controller
// @Values{Copter, Rover, Plane, Blimp}: 110:KillIMU3
// @Values{Plane}: 150:CRUISE Mode
// @Values{Copter}: 151:TURTLE Mode
// @Values{Copter}: 152:SIMPLE heading reset
// @Values{Copter, Rover, Plane}: 153:ArmDisarm (4.2 and higher)
// @Values{Blimp}: 153:ArmDisarm
// @Values{Copter}: 154:ArmDisarm with AirMode (4.2 and higher)
// @Values{Plane}: 154:ArmDisarm with Quadplane AirMode (4.2 and higher)
// @Values{Rover}: 155:Set steering trim to current servo and RC
// @Values{Plane}: 155:Set roll pitch and yaw trim to current servo and RC
// @Values{Rover}: 156:Torqeedo Clear Err
// @Values{Plane}: 157:Force FS Action to FBWA
// @Values{Copter, Plane}: 158:Optflow Calibration
// @Values{Copter}: 159:Force IS_Flying
// @Values{Plane}: 160:Weathervane Enable
// @Values{Copter}: 161:Turbine Start(heli)
// @Values{Copter, Rover, Plane}: 162:FFT Tune
// @Values{Copter, Rover, Plane}: 163:Mount Lock
// @Values{Copter, Rover, Plane, Blimp}: 164:Pause Stream Logging
// @Values{Copter, Rover, Plane}: 165:Arm/Emergency Motor Stop
// @Values{Copter, Rover, Plane, Blimp}: 166:Camera Record Video, 167:Camera Zoom, 168:Camera Manual Focus, 169:Camera Auto Focus
// @Values{Plane}: 170:QSTABILIZE Mode
// @Values{Copter, Rover, Plane, Blimp}: 171:Calibrate Compasses
// @Values{Copter, Rover, Plane, Blimp}: 172:Battery MPPT Enable
// @Values{Plane}: 173:Plane AUTO Mode Landing Abort
// @Values{Copter, Rover, Plane, Blimp}: 174:Camera Image Tracking
// @Values{Copter, Rover, Plane, Blimp}: 175:Camera Lens
// @Values{Plane}: 176:Quadplane Fwd Throttle Override enable
// @Values{Rover}: 201:Roll
// @Values{Rover}: 202:Pitch
// @Values{Rover}: 207:MainSail
// @Values{Rover, Plane}: 208:Flap
// @Values{Plane}: 209:VTOL Forward Throttle
// @Values{Plane}: 210:Airbrakes
// @Values{Rover}: 211:Walking Height
// @Values{Copter, Rover, Plane}: 212:Mount1 Roll, 213:Mount1 Pitch, 214:Mount1 Yaw, 215:Mount2 Roll, 216:Mount2 Pitch, 217:Mount2 Yaw
// @Values{Copter, Rover, Plane}: 300:Scripting1, 301:Scripting2, 302:Scripting3, 303:Scripting4, 304:Scripting5, 305:Scripting6, 306:Scripting7, 307:Scripting8
// @User: Standard
AP_GROUPINFO_FRAME("OPTION", 6, RC_Channel, option, 0, AP_PARAM_FRAME_COPTER|AP_PARAM_FRAME_ROVER|AP_PARAM_FRAME_PLANE|AP_PARAM_FRAME_BLIMP),
AP_GROUPEND
};
// constructor
RC_Channel::RC_Channel(void)
{
AP_Param::setup_object_defaults(this, var_info);
}
void RC_Channel::set_range(uint16_t high)
{
type_in = ControlType::RANGE;
high_in = high;
}
void RC_Channel::set_angle(uint16_t angle)
{
type_in = ControlType::ANGLE;
high_in = angle;
}
void RC_Channel::set_default_dead_zone(int16_t dzone)
{
dead_zone.set_default(abs(dzone));
}
bool RC_Channel::get_reverse(void) const
{
return bool(reversed.get());
}
// read input from hal.rcin or overrides
bool RC_Channel::update(void)
{
if (has_override() && !rc().option_is_enabled(RC_Channels::Option::IGNORE_OVERRIDES)) {
radio_in = override_value;
} else if (rc().has_had_rc_receiver() && !rc().option_is_enabled(RC_Channels::Option::IGNORE_RECEIVER)) {
radio_in = hal.rcin->read(ch_in);
} else {
return false;
}
if (type_in == ControlType::RANGE) {
control_in = pwm_to_range();
} else {
// ControlType::ANGLE
control_in = pwm_to_angle();
}
return true;
}
/*
return the center stick position expressed as a control_in value
used for thr_mid in copter
*/
int16_t RC_Channel::get_control_mid() const
{
if (type_in == ControlType::RANGE) {
int16_t r_in = (radio_min.get() + radio_max.get())/2;
int16_t radio_trim_low = radio_min + dead_zone;
return (((int32_t)(high_in) * (int32_t)(r_in - radio_trim_low)) / (int32_t)(radio_max - radio_trim_low));
} else {
return 0;
}
}
/*
return an "angle in centidegrees" (normally -4500 to 4500) from
the current radio_in value using the specified dead_zone
*/
int16_t RC_Channel::pwm_to_angle_dz_trim(uint16_t _dead_zone, uint16_t _trim) const
{
int16_t radio_trim_high = _trim + _dead_zone;
int16_t radio_trim_low = _trim - _dead_zone;
int16_t reverse_mul = (reversed?-1:1);
// don't allow out of range values
int16_t r_in = constrain_int16(radio_in, radio_min.get(), radio_max.get());
if (r_in > radio_trim_high && radio_max != radio_trim_high) {
return reverse_mul * ((int32_t)high_in * (int32_t)(r_in - radio_trim_high)) / (int32_t)(radio_max - radio_trim_high);
} else if (r_in < radio_trim_low && radio_trim_low != radio_min) {
return reverse_mul * ((int32_t)high_in * (int32_t)(r_in - radio_trim_low)) / (int32_t)(radio_trim_low - radio_min);
} else {
return 0;
}
}
/*
return an "angle in centidegrees" (normally -4500 to 4500) from
the current radio_in value using the specified dead_zone
*/
int16_t RC_Channel::pwm_to_angle_dz(uint16_t _dead_zone) const
{
return pwm_to_angle_dz_trim(_dead_zone, radio_trim);
}
/*
return an "angle in centidegrees" (normally -4500 to 4500) from
the current radio_in value
*/
int16_t RC_Channel::pwm_to_angle() const
{
return pwm_to_angle_dz(dead_zone);
}
/*
convert a pulse width modulation value to a value in the configured
range, using the specified deadzone
*/
int16_t RC_Channel::pwm_to_range_dz(uint16_t _dead_zone) const
{
int16_t r_in = constrain_int16(radio_in, radio_min.get(), radio_max.get());
if (reversed) {
r_in = radio_max.get() - (r_in - radio_min.get());
}
int16_t radio_trim_low = radio_min + _dead_zone;
if (r_in > radio_trim_low) {
return (((int32_t)(high_in) * (int32_t)(r_in - radio_trim_low)) / (int32_t)(radio_max - radio_trim_low));
}
return 0;
}
/*
convert a pulse width modulation value to a value in the configured
range
*/
int16_t RC_Channel::pwm_to_range() const
{
return pwm_to_range_dz(dead_zone);
}
int16_t RC_Channel::get_control_in_zero_dz(void) const
{
if (type_in == ControlType::RANGE) {
return pwm_to_range_dz(0);
}
return pwm_to_angle_dz(0);
}
// ------------------------------------------
float RC_Channel::norm_input() const
{
float ret;
int16_t reverse_mul = (reversed?-1:1);
if (radio_in < radio_trim) {
if (radio_min >= radio_trim) {
return 0.0f;
}
ret = reverse_mul * (float)(radio_in - radio_trim) / (float)(radio_trim - radio_min);
} else {
if (radio_max <= radio_trim) {
return 0.0f;
}
ret = reverse_mul * (float)(radio_in - radio_trim) / (float)(radio_max - radio_trim);
}
return constrain_float(ret, -1.0f, 1.0f);
}
float RC_Channel::norm_input_dz() const
{
int16_t dz_min = radio_trim - dead_zone;
int16_t dz_max = radio_trim + dead_zone;
float ret;
int16_t reverse_mul = (reversed?-1:1);
if (radio_in < dz_min && dz_min > radio_min) {
ret = reverse_mul * (float)(radio_in - dz_min) / (float)(dz_min - radio_min);
} else if (radio_in > dz_max && radio_max > dz_max) {
ret = reverse_mul * (float)(radio_in - dz_max) / (float)(radio_max - dz_max);
} else {
ret = 0;
}
return constrain_float(ret, -1.0f, 1.0f);
}
// return a normalised input for a channel, in range -1 to 1,
// ignores trim and deadzone
float RC_Channel::norm_input_ignore_trim() const
{
// sanity check min and max to avoid divide by zero
if (radio_max <= radio_min) {
return 0.0f;
}
const float ret = (reversed ? -2.0f : 2.0f) * (((float)(radio_in - radio_min) / (float)(radio_max - radio_min)) - 0.5f);
return constrain_float(ret, -1.0f, 1.0f);
}
/*
get percentage input from 0 to 100. This ignores the trim value.
*/
uint8_t RC_Channel::percent_input() const
{
if (radio_in <= radio_min) {
return reversed?100:0;
}
if (radio_in >= radio_max) {
return reversed?0:100;
}
uint8_t ret = 100.0f * (radio_in - radio_min) / (float)(radio_max - radio_min);
if (reversed) {
ret = 100 - ret;
}
return ret;
}
/*
return true if input is within deadzone of trim
*/
bool RC_Channel::in_trim_dz() const
{
return is_bounded_int32(radio_in, radio_trim - dead_zone, radio_trim + dead_zone);
}
/*
return trues if input is within deadzone of min
*/
bool RC_Channel::in_min_dz() const
{
return radio_in < radio_min + dead_zone;
}
void RC_Channel::set_override(const uint16_t v, const uint32_t timestamp_ms)
{
if (!rc().gcs_overrides_enabled()) {
return;
}
last_override_time = timestamp_ms != 0 ? timestamp_ms : AP_HAL::millis();
override_value = v;
rc().new_override_received();
}
void RC_Channel::clear_override()
{
last_override_time = 0;
override_value = 0;
}
bool RC_Channel::has_override() const
{
if (override_value == 0) {
return false;
}
uint32_t override_timeout_ms;
if (!rc().get_override_timeout_ms(override_timeout_ms)) {
// timeouts are disabled
return true;
}
if (override_timeout_ms == 0) {
// overrides are explicitly disabled by a zero value
return false;
}
return (AP_HAL::millis() - last_override_time < override_timeout_ms);
}
/*
perform stick mixing on one channel
This type of stick mixing reduces the influence of the auto
controller as it increases the influence of the users stick input,
allowing the user full deflection if needed
*/
float RC_Channel::stick_mixing(const float servo_in)
{
float ch_inf = (float)(radio_in - radio_trim);
ch_inf = fabsf(ch_inf);
ch_inf = MIN(ch_inf, 400.0f);
ch_inf = ((400.0f - ch_inf) / 400.0f);
float servo_out = servo_in;
servo_out *= ch_inf;
servo_out += control_in;
return servo_out;
}
//
// support for auxiliary switches:
//
void RC_Channel::reset_mode_switch()
{
switch_state.current_position = -1;
switch_state.debounce_position = -1;
read_mode_switch();
}
// read a 6 position switch
bool RC_Channel::read_6pos_switch(int8_t& position)
{
// calculate position of 6 pos switch
const uint16_t pulsewidth = get_radio_in();
if (pulsewidth <= RC_MIN_LIMIT_PWM || pulsewidth >= RC_MAX_LIMIT_PWM) {
return false; // This is an error condition
}
if (pulsewidth < 1231) {
position = 0;
} else if (pulsewidth < 1361) {
position = 1;
} else if (pulsewidth < 1491) {
position = 2;
} else if (pulsewidth < 1621) {
position = 3;
} else if (pulsewidth < 1750) {
position = 4;
} else {
position = 5;
}
if (!debounce_completed(position)) {
return false;
}
return true;
}
void RC_Channel::read_mode_switch()
{
int8_t position;
if (read_6pos_switch(position)) {
// set flight mode and simple mode setting
mode_switch_changed(modeswitch_pos_t(position));
}
}
bool RC_Channel::debounce_completed(int8_t position)
{
// switch change not detected
if (switch_state.current_position == position) {
// reset debouncing
switch_state.debounce_position = position;
} else {
// switch change detected
const uint32_t tnow_ms = AP_HAL::millis();
// position not established yet
if (switch_state.debounce_position != position) {
switch_state.debounce_position = position;
switch_state.last_edge_time_ms = tnow_ms;
} else if (tnow_ms - switch_state.last_edge_time_ms >= SWITCH_DEBOUNCE_TIME_MS) {
// position estabilished; debounce completed
switch_state.current_position = position;
return true;
}
}
return false;
}
//
// support for auxiliary switches:
//
// init_aux_switch_function - initialize aux functions
void RC_Channel::init_aux_function(const aux_func_t ch_option, const AuxSwitchPos ch_flag)
{
// init channel options
switch (ch_option) {
// the following functions do not need to be initialised:
case AUX_FUNC::ARMDISARM:
case AUX_FUNC::BATTERY_MPPT_ENABLE:
case AUX_FUNC::CAMERA_TRIGGER:
case AUX_FUNC::CLEAR_WP:
case AUX_FUNC::COMPASS_LEARN:
case AUX_FUNC::DISARM:
case AUX_FUNC::DO_NOTHING:
case AUX_FUNC::LANDING_GEAR:
case AUX_FUNC::LOST_VEHICLE_SOUND:
case AUX_FUNC::RELAY:
case AUX_FUNC::RELAY2:
case AUX_FUNC::RELAY3:
case AUX_FUNC::RELAY4:
case AUX_FUNC::RELAY5:
case AUX_FUNC::RELAY6:
case AUX_FUNC::VISODOM_ALIGN:
case AUX_FUNC::EKF_LANE_SWITCH:
case AUX_FUNC::EKF_YAW_RESET:
case AUX_FUNC::GENERATOR: // don't turn generator on or off initially
case AUX_FUNC::EKF_POS_SOURCE:
case AUX_FUNC::TORQEEDO_CLEAR_ERR:
case AUX_FUNC::SCRIPTING_1:
case AUX_FUNC::SCRIPTING_2:
case AUX_FUNC::SCRIPTING_3:
case AUX_FUNC::SCRIPTING_4:
case AUX_FUNC::SCRIPTING_5:
case AUX_FUNC::SCRIPTING_6:
case AUX_FUNC::SCRIPTING_7:
case AUX_FUNC::SCRIPTING_8:
#if AP_VIDEOTX_ENABLED
case AUX_FUNC::VTX_POWER:
#endif
case AUX_FUNC::OPTFLOW_CAL:
case AUX_FUNC::TURBINE_START:
case AUX_FUNC::MOUNT1_ROLL:
case AUX_FUNC::MOUNT1_PITCH:
case AUX_FUNC::MOUNT1_YAW:
case AUX_FUNC::MOUNT2_ROLL:
case AUX_FUNC::MOUNT2_PITCH:
case AUX_FUNC::MOUNT2_YAW:
case AUX_FUNC::LOWEHEISER_STARTER:
case AUX_FUNC::MAG_CAL:
case AUX_FUNC::CAMERA_IMAGE_TRACKING:
break;
// not really aux functions:
case AUX_FUNC::LOWEHEISER_THROTTLE:
break;
case AUX_FUNC::AVOID_ADSB:
case AUX_FUNC::AVOID_PROXIMITY:
case AUX_FUNC::FENCE:
case AUX_FUNC::GPS_DISABLE:
case AUX_FUNC::GPS_DISABLE_YAW:
#if AP_GRIPPER_ENABLED
case AUX_FUNC::GRIPPER:
#endif
#if AP_INERTIALSENSOR_KILL_IMU_ENABLED
case AUX_FUNC::KILL_IMU1:
case AUX_FUNC::KILL_IMU2:
case AUX_FUNC::KILL_IMU3:
#endif
case AUX_FUNC::MISSION_RESET:
case AUX_FUNC::MOTOR_ESTOP:
case AUX_FUNC::RC_OVERRIDE_ENABLE:
case AUX_FUNC::RUNCAM_CONTROL:
case AUX_FUNC::RUNCAM_OSD_CONTROL:
case AUX_FUNC::SPRAYER:
case AUX_FUNC::DISABLE_AIRSPEED_USE:
case AUX_FUNC::FFT_NOTCH_TUNE:
#if HAL_MOUNT_ENABLED
case AUX_FUNC::RETRACT_MOUNT1:
case AUX_FUNC::MOUNT_LOCK:
#endif
case AUX_FUNC::LOG_PAUSE:
case AUX_FUNC::ARM_EMERGENCY_STOP:
case AUX_FUNC::CAMERA_REC_VIDEO:
case AUX_FUNC::CAMERA_ZOOM:
case AUX_FUNC::CAMERA_MANUAL_FOCUS:
case AUX_FUNC::CAMERA_AUTO_FOCUS:
case AUX_FUNC::CAMERA_LENS:
run_aux_function(ch_option, ch_flag, AuxFuncTriggerSource::INIT);
break;
default:
GCS_SEND_TEXT(MAV_SEVERITY_WARNING, "Failed to init: RC%u_OPTION: %u\n",
(unsigned)(this->ch_in+1), (unsigned)ch_option);
#if CONFIG_HAL_BOARD == HAL_BOARD_SITL
AP_BoardConfig::config_error("Failed to init: RC%u_OPTION: %u",
(unsigned)(this->ch_in+1), (unsigned)ch_option);
#endif
break;
}
}
#if AP_RC_CHANNEL_AUX_FUNCTION_STRINGS_ENABLED
const RC_Channel::LookupTable RC_Channel::lookuptable[] = {
{ AUX_FUNC::SAVE_WP,"SaveWaypoint"},
{ AUX_FUNC::CAMERA_TRIGGER,"CameraTrigger"},
{ AUX_FUNC::RANGEFINDER,"Rangefinder"},
{ AUX_FUNC::FENCE,"Fence"},
{ AUX_FUNC::SPRAYER,"Sprayer"},
{ AUX_FUNC::PARACHUTE_ENABLE,"ParachuteEnable"},
{ AUX_FUNC::PARACHUTE_RELEASE,"ParachuteRelease"},
{ AUX_FUNC::PARACHUTE_3POS,"Parachute3Position"},
{ AUX_FUNC::MISSION_RESET,"MissionReset"},
{ AUX_FUNC::RETRACT_MOUNT1,"RetractMount1"},
{ AUX_FUNC::RELAY,"Relay1"},
{ AUX_FUNC::MOTOR_ESTOP,"MotorEStop"},
{ AUX_FUNC::MOTOR_INTERLOCK,"MotorInterlock"},
{ AUX_FUNC::RELAY2,"Relay2"},
{ AUX_FUNC::RELAY3,"Relay3"},
{ AUX_FUNC::RELAY4,"Relay4"},
{ AUX_FUNC::PRECISION_LOITER,"PrecisionLoiter"},
{ AUX_FUNC::AVOID_PROXIMITY,"AvoidProximity"},
{ AUX_FUNC::WINCH_ENABLE,"WinchEnable"},
{ AUX_FUNC::WINCH_CONTROL,"WinchControl"},
{ AUX_FUNC::CLEAR_WP,"ClearWaypoint"},
{ AUX_FUNC::COMPASS_LEARN,"CompassLearn"},
{ AUX_FUNC::SAILBOAT_TACK,"SailboatTack"},
{ AUX_FUNC::GPS_DISABLE,"GPSDisable"},
{ AUX_FUNC::GPS_DISABLE_YAW,"GPSDisableYaw"},
{ AUX_FUNC::DISABLE_AIRSPEED_USE,"DisableAirspeedUse"},
{ AUX_FUNC::RELAY5,"Relay5"},
{ AUX_FUNC::RELAY6,"Relay6"},
{ AUX_FUNC::SAILBOAT_MOTOR_3POS,"SailboatMotor"},
{ AUX_FUNC::SURFACE_TRACKING,"SurfaceTracking"},
{ AUX_FUNC::RUNCAM_CONTROL,"RunCamControl"},
{ AUX_FUNC::RUNCAM_OSD_CONTROL,"RunCamOSDControl"},
{ AUX_FUNC::VISODOM_ALIGN,"VisOdomAlign"},
{ AUX_FUNC::AIRMODE, "AirMode"},
{ AUX_FUNC::EKF_POS_SOURCE,"EKFPosSource"},
{ AUX_FUNC::CAM_MODE_TOGGLE,"CamModeToggle"},
{ AUX_FUNC::GENERATOR,"Generator"},
{ AUX_FUNC::BATTERY_MPPT_ENABLE,"Battery MPPT Enable"},
{ AUX_FUNC::ARSPD_CALIBRATE,"Calibrate Airspeed"},
{ AUX_FUNC::TORQEEDO_CLEAR_ERR, "Torqeedo Clear Err"},
{ AUX_FUNC::EMERGENCY_LANDING_EN, "Emergency Landing"},
{ AUX_FUNC::WEATHER_VANE_ENABLE, "Weathervane"},
{ AUX_FUNC::TURBINE_START, "Turbine Start"},
{ AUX_FUNC::FFT_NOTCH_TUNE, "FFT Notch Tuning"},
{ AUX_FUNC::MOUNT_LOCK, "MountLock"},
{ AUX_FUNC::LOG_PAUSE, "Pause Stream Logging"},
{ AUX_FUNC::CAMERA_REC_VIDEO, "Camera Record Video"},
{ AUX_FUNC::CAMERA_ZOOM, "Camera Zoom"},
{ AUX_FUNC::CAMERA_MANUAL_FOCUS, "Camera Manual Focus"},
{ AUX_FUNC::CAMERA_AUTO_FOCUS, "Camera Auto Focus"},
{ AUX_FUNC::CAMERA_IMAGE_TRACKING, "Camera Image Tracking"},
{ AUX_FUNC::CAMERA_LENS, "Camera Lens"},
};
/* lookup the announcement for switch change */
const char *RC_Channel::string_for_aux_function(AUX_FUNC function) const
{
for (const struct LookupTable &entry : lookuptable) {
if (entry.option == function) {
return entry.announcement;
}
}
return nullptr;
}
/* find string for postion */
const char *RC_Channel::string_for_aux_pos(AuxSwitchPos pos) const
{
switch (pos) {
case AuxSwitchPos::HIGH:
return "HIGH";
case AuxSwitchPos::MIDDLE:
return "MIDDLE";
case AuxSwitchPos::LOW:
return "LOW";
}
return "";
}
#endif // AP_RC_CHANNEL_AUX_FUNCTION_STRINGS_ENABLED
/*
read an aux channel. Return true if a switch has changed
*/
bool RC_Channel::read_aux()
{
const aux_func_t _option = (aux_func_t)option.get();
if (_option == AUX_FUNC::DO_NOTHING) {
// may wish to add special cases for other "AUXSW" things
// here e.g. RCMAP_ROLL etc once they become options
return false;
#if AP_VIDEOTX_ENABLED
} else if (_option == AUX_FUNC::VTX_POWER) {
int8_t position;
if (read_6pos_switch(position)) {
AP::vtx().change_power(position);
return true;
}
return false;
#endif // AP_VIDEOTX_ENABLED
}
AuxSwitchPos new_position;
if (!read_3pos_switch(new_position)) {
return false;
}
if (!debounce_completed((int8_t)new_position)) {
return false;
}
#if AP_RC_CHANNEL_AUX_FUNCTION_STRINGS_ENABLED
// announce the change to the GCS:
const char *aux_string = string_for_aux_function(_option);
if (aux_string != nullptr) {
GCS_SEND_TEXT(MAV_SEVERITY_INFO, "RC%i: %s %s", ch_in+1, aux_string, string_for_aux_pos(new_position));
}
#endif
// debounced; undertake the action:
run_aux_function(_option, new_position, AuxFuncTriggerSource::RC);
return true;
}
void RC_Channel::do_aux_function_armdisarm(const AuxSwitchPos ch_flag)
{
// arm or disarm the vehicle
switch (ch_flag) {
case AuxSwitchPos::HIGH:
AP::arming().arm(AP_Arming::Method::AUXSWITCH, true);
break;
case AuxSwitchPos::MIDDLE:
// nothing
break;
case AuxSwitchPos::LOW:
AP::arming().disarm(AP_Arming::Method::AUXSWITCH);
break;
}
}
void RC_Channel::do_aux_function_avoid_adsb(const AuxSwitchPos ch_flag)
{
#if HAL_ADSB_ENABLED
AP_Avoidance *avoidance = AP::ap_avoidance();
if (avoidance == nullptr) {
return;
}
if (ch_flag == AuxSwitchPos::HIGH) {
AP_ADSB *adsb = AP::ADSB();
if (adsb == nullptr) {
return;
}
// try to enable AP_Avoidance
if (!adsb->enabled() || !adsb->healthy()) {
GCS_SEND_TEXT(MAV_SEVERITY_CRITICAL, "ADSB not available");
return;
}
avoidance->enable();
AP::logger().Write_Event(LogEvent::AVOIDANCE_ADSB_ENABLE);
GCS_SEND_TEXT(MAV_SEVERITY_CRITICAL, "ADSB Avoidance Enabled");
return;
}
// disable AP_Avoidance
avoidance->disable();
AP::logger().Write_Event(LogEvent::AVOIDANCE_ADSB_DISABLE);
GCS_SEND_TEXT(MAV_SEVERITY_CRITICAL, "ADSB Avoidance Disabled");
#endif
}
void RC_Channel::do_aux_function_avoid_proximity(const AuxSwitchPos ch_flag)
{
#if !APM_BUILD_TYPE(APM_BUILD_ArduPlane)
AC_Avoid *avoid = AP::ac_avoid();
if (avoid == nullptr) {
return;
}
switch (ch_flag) {
case AuxSwitchPos::HIGH:
avoid->proximity_avoidance_enable(true);
break;
case AuxSwitchPos::MIDDLE:
// nothing
break;
case AuxSwitchPos::LOW:
avoid->proximity_avoidance_enable(false);
break;
}
#endif // !APM_BUILD_ArduPlane
}
#if AP_CAMERA_ENABLED
void RC_Channel::do_aux_function_camera_trigger(const AuxSwitchPos ch_flag)
{
if (ch_flag == AuxSwitchPos::HIGH) {
AP_Camera *camera = AP::camera();
if (camera == nullptr) {
return;
}
camera->take_picture();
}
}
bool RC_Channel::do_aux_function_record_video(const AuxSwitchPos ch_flag)
{
AP_Camera *camera = AP::camera();
if (camera == nullptr) {
return false;
}
return camera->record_video(ch_flag == AuxSwitchPos::HIGH);
}
bool RC_Channel::do_aux_function_camera_zoom(const AuxSwitchPos ch_flag)
{
AP_Camera *camera = AP::camera();
if (camera == nullptr) {
return false;
}
int8_t zoom_step = 0; // zoom out = -1, hold = 0, zoom in = 1
switch (ch_flag) {
case AuxSwitchPos::HIGH:
zoom_step = 1; // zoom in
break;
case AuxSwitchPos::MIDDLE:
zoom_step = 0; // zoom hold
break;
case AuxSwitchPos::LOW:
zoom_step = -1; // zoom out
break;
}
return camera->set_zoom(ZoomType::RATE, zoom_step);
}
bool RC_Channel::do_aux_function_camera_manual_focus(const AuxSwitchPos ch_flag)
{
AP_Camera *camera = AP::camera();
if (camera == nullptr) {
return false;
}
int8_t focus_step = 0; // focus in = -1, focus hold = 0, focus out = 1
switch (ch_flag) {
case AuxSwitchPos::HIGH:
// wide shot, focus out
focus_step = 1;
break;
case AuxSwitchPos::MIDDLE:
focus_step = 0;
break;
case AuxSwitchPos::LOW:
// close shot, focus in
focus_step = -1;
break;
}
return camera->set_focus(FocusType::RATE, focus_step) == SetFocusResult::ACCEPTED;
}
bool RC_Channel::do_aux_function_camera_auto_focus(const AuxSwitchPos ch_flag)
{
if (ch_flag == AuxSwitchPos::HIGH) {
AP_Camera *camera = AP::camera();
if (camera == nullptr) {
return false;
}
return camera->set_focus(FocusType::AUTO, 0) == SetFocusResult::ACCEPTED;
}
return false;
}
bool RC_Channel::do_aux_function_camera_image_tracking(const AuxSwitchPos ch_flag)
{
AP_Camera *camera = AP::camera();
if (camera == nullptr) {
return false;
}
// High position enables tracking a POINT in middle of image
// Low or Mediums disables tracking. (0.5,0.5) is still passed in but ignored
return camera->set_tracking(ch_flag == AuxSwitchPos::HIGH ? TrackingType::TRK_POINT : TrackingType::TRK_NONE, Vector2f{0.5, 0.5}, Vector2f{});
}
bool RC_Channel::do_aux_function_camera_lens(const AuxSwitchPos ch_flag)
{
AP_Camera *camera = AP::camera();
if (camera == nullptr) {
return false;
}
// Low selects lens 0 (default), Mediums selects lens1, High selects lens2
return camera->set_lens((uint8_t)ch_flag);
}
#endif
void RC_Channel::do_aux_function_runcam_control(const AuxSwitchPos ch_flag)
{
#if HAL_RUNCAM_ENABLED
AP_RunCam *runcam = AP::runcam();
if (runcam == nullptr) {
return;
}
switch (ch_flag) {
case AuxSwitchPos::HIGH:
runcam->start_recording();
break;
case AuxSwitchPos::MIDDLE:
runcam->osd_option();
break;
case AuxSwitchPos::LOW:
runcam->stop_recording();
break;
}
#endif
}
void RC_Channel::do_aux_function_runcam_osd_control(const AuxSwitchPos ch_flag)
{
#if HAL_RUNCAM_ENABLED
AP_RunCam *runcam = AP::runcam();
if (runcam == nullptr) {
return;
}
switch (ch_flag) {
case AuxSwitchPos::HIGH:
runcam->enter_osd();
break;
case AuxSwitchPos::MIDDLE:
case AuxSwitchPos::LOW:
runcam->exit_osd();
break;
}
#endif
}
#if AP_FENCE_ENABLED
// enable or disable the fence
void RC_Channel::do_aux_function_fence(const AuxSwitchPos ch_flag)
{
AC_Fence *fence = AP::fence();
if (fence == nullptr) {
return;
}
fence->enable(ch_flag == AuxSwitchPos::HIGH);
}
#endif
void RC_Channel::do_aux_function_clear_wp(const AuxSwitchPos ch_flag)
{
if (ch_flag == AuxSwitchPos::HIGH) {
AP_Mission *mission = AP::mission();
if (mission == nullptr) {
return;
}
mission->clear();
}
}
#if AP_SERVORELAYEVENTS_ENABLED && AP_RELAY_ENABLED
void RC_Channel::do_aux_function_relay(const uint8_t relay, bool val)
{
AP_ServoRelayEvents *servorelayevents = AP::servorelayevents();
if (servorelayevents == nullptr) {
return;
}
servorelayevents->do_set_relay(relay, val);
}
#endif
#if HAL_GENERATOR_ENABLED
void RC_Channel::do_aux_function_generator(const AuxSwitchPos ch_flag)
{
AP_Generator *generator = AP::generator();
if (generator == nullptr) {
return;
}
switch (ch_flag) {
case AuxSwitchPos::LOW:
generator->stop();
break;
case AuxSwitchPos::MIDDLE:
generator->idle();
break;
case AuxSwitchPos::HIGH:
generator->run();
break;
}
}
#endif
#if HAL_SPRAYER_ENABLED
void RC_Channel::do_aux_function_sprayer(const AuxSwitchPos ch_flag)
{
AC_Sprayer *sprayer = AP::sprayer();
if (sprayer == nullptr) {
return;
}
sprayer->run(ch_flag == AuxSwitchPos::HIGH);
// if we are disarmed the pilot must want to test the pump
sprayer->test_pump((ch_flag == AuxSwitchPos::HIGH) && !hal.util->get_soft_armed());
}
#endif // HAL_SPRAYER_ENABLED
#if AP_GRIPPER_ENABLED
void RC_Channel::do_aux_function_gripper(const AuxSwitchPos ch_flag)
{
AP_Gripper *gripper = AP::gripper();
if (gripper == nullptr) {
return;
}
switch (ch_flag) {
case AuxSwitchPos::LOW:
gripper->release();
break;
case AuxSwitchPos::MIDDLE:
// nothing
break;
case AuxSwitchPos::HIGH:
gripper->grab();
break;
}
}
#endif // AP_GRIPPER_ENABLED
void RC_Channel::do_aux_function_lost_vehicle_sound(const AuxSwitchPos ch_flag)
{
switch (ch_flag) {
case AuxSwitchPos::HIGH:
AP_Notify::flags.vehicle_lost = true;
break;
case AuxSwitchPos::MIDDLE:
// nothing
break;
case AuxSwitchPos::LOW:
AP_Notify::flags.vehicle_lost = false;
break;
}
}
void RC_Channel::do_aux_function_rc_override_enable(const AuxSwitchPos ch_flag)
{
switch (ch_flag) {
case AuxSwitchPos::HIGH: {
rc().set_gcs_overrides_enabled(true);
break;
}
case AuxSwitchPos::MIDDLE:
// nothing
break;
case AuxSwitchPos::LOW: {
rc().set_gcs_overrides_enabled(false);
break;
}
}
}
void RC_Channel::do_aux_function_mission_reset(const AuxSwitchPos ch_flag)
{
if (ch_flag != AuxSwitchPos::HIGH) {
return;
}
AP_Mission *mission = AP::mission();
if (mission == nullptr) {
return;
}
mission->reset();
}
void RC_Channel::do_aux_function_fft_notch_tune(const AuxSwitchPos ch_flag)
{
#if HAL_GYROFFT_ENABLED
AP_GyroFFT *fft = AP::fft();
if (fft == nullptr) {
return;
}
switch (ch_flag) {
case AuxSwitchPos::HIGH:
fft->start_notch_tune();
break;
case AuxSwitchPos::MIDDLE:
case AuxSwitchPos::LOW:
fft->stop_notch_tune();
break;
}
#endif
}
bool RC_Channel::run_aux_function(aux_func_t ch_option, AuxSwitchPos pos, AuxFuncTriggerSource source)
{
#if AP_SCRIPTING_ENABLED
rc().set_aux_cached(ch_option, pos);
#endif
const bool ret = do_aux_function(ch_option, pos);
// @LoggerMessage: AUXF
// @Description: Auxiliary function invocation information
// @Field: TimeUS: Time since system startup
// @Field: function: ID of triggered function
// @FieldValueEnum: function: RC_Channel::AUX_FUNC
// @Field: pos: switch position when function triggered
// @FieldValueEnum: pos: RC_Channel::AuxSwitchPos
// @Field: source: source of auxiliary function invocation
// @FieldValueEnum: source: RC_Channel::AuxFuncTriggerSource
// @Field: result: true if function was successful
AP::logger().Write(
"AUXF",
"TimeUS,function,pos,source,result",
"s#---",
"F----",
"QHBBB",
AP_HAL::micros64(),
uint16_t(ch_option),
uint8_t(pos),
uint8_t(source),
uint8_t(ret)
);
return ret;
}
bool RC_Channel::do_aux_function(const aux_func_t ch_option, const AuxSwitchPos ch_flag)
{
switch (ch_option) {
#if AP_FENCE_ENABLED
case AUX_FUNC::FENCE:
do_aux_function_fence(ch_flag);
break;
#endif
#if AP_GRIPPER_ENABLED
case AUX_FUNC::GRIPPER:
do_aux_function_gripper(ch_flag);
break;
#endif
case AUX_FUNC::RC_OVERRIDE_ENABLE:
// Allow or disallow RC_Override
do_aux_function_rc_override_enable(ch_flag);
break;
case AUX_FUNC::AVOID_PROXIMITY:
do_aux_function_avoid_proximity(ch_flag);
break;
#if AP_SERVORELAYEVENTS_ENABLED && AP_RELAY_ENABLED
case AUX_FUNC::RELAY:
do_aux_function_relay(0, ch_flag == AuxSwitchPos::HIGH);
break;
case AUX_FUNC::RELAY2:
do_aux_function_relay(1, ch_flag == AuxSwitchPos::HIGH);
break;
case AUX_FUNC::RELAY3:
do_aux_function_relay(2, ch_flag == AuxSwitchPos::HIGH);
break;
case AUX_FUNC::RELAY4:
do_aux_function_relay(3, ch_flag == AuxSwitchPos::HIGH);
break;
case AUX_FUNC::RELAY5:
do_aux_function_relay(4, ch_flag == AuxSwitchPos::HIGH);
break;
case AUX_FUNC::RELAY6:
do_aux_function_relay(5, ch_flag == AuxSwitchPos::HIGH);
break;
#endif // AP_SERVORELAYEVENTS_ENABLED && AP_RELAY_ENABLED
case AUX_FUNC::RUNCAM_CONTROL:
do_aux_function_runcam_control(ch_flag);
break;
case AUX_FUNC::RUNCAM_OSD_CONTROL:
do_aux_function_runcam_osd_control(ch_flag);
break;
case AUX_FUNC::CLEAR_WP:
do_aux_function_clear_wp(ch_flag);
break;
case AUX_FUNC::MISSION_RESET:
do_aux_function_mission_reset(ch_flag);
break;
case AUX_FUNC::AVOID_ADSB:
do_aux_function_avoid_adsb(ch_flag);
break;
case AUX_FUNC::FFT_NOTCH_TUNE:
do_aux_function_fft_notch_tune(ch_flag);
break;
#if HAL_GENERATOR_ENABLED
case AUX_FUNC::GENERATOR:
do_aux_function_generator(ch_flag);
break;
#endif
case AUX_FUNC::BATTERY_MPPT_ENABLE:
if (ch_flag != AuxSwitchPos::MIDDLE) {
AP::battery().MPPT_set_powered_state_to_all(ch_flag == AuxSwitchPos::HIGH);
}
break;
#if HAL_SPRAYER_ENABLED
case AUX_FUNC::SPRAYER:
do_aux_function_sprayer(ch_flag);
break;
#endif
case AUX_FUNC::LOST_VEHICLE_SOUND:
do_aux_function_lost_vehicle_sound(ch_flag);
break;
case AUX_FUNC::ARMDISARM:
do_aux_function_armdisarm(ch_flag);
break;
case AUX_FUNC::DISARM:
if (ch_flag == AuxSwitchPos::HIGH) {
AP::arming().disarm(AP_Arming::Method::AUXSWITCH);
}
break;
case AUX_FUNC::COMPASS_LEARN:
if (ch_flag == AuxSwitchPos::HIGH) {
Compass &compass = AP::compass();
compass.set_learn_type(Compass::LEARN_INFLIGHT, false);
}
break;
#if AP_LANDINGGEAR_ENABLED
case AUX_FUNC::LANDING_GEAR: {
AP_LandingGear *lg = AP_LandingGear::get_singleton();
if (lg == nullptr) {
break;
}
switch (ch_flag) {
case AuxSwitchPos::LOW:
lg->set_position(AP_LandingGear::LandingGear_Deploy);
break;
case AuxSwitchPos::MIDDLE:
// nothing
break;
case AuxSwitchPos::HIGH:
lg->set_position(AP_LandingGear::LandingGear_Retract);
break;
}
break;
}
#endif
case AUX_FUNC::GPS_DISABLE:
AP::gps().force_disable(ch_flag == AuxSwitchPos::HIGH);
break;
case AUX_FUNC::GPS_DISABLE_YAW:
AP::gps().set_force_disable_yaw(ch_flag == AuxSwitchPos::HIGH);
break;
#if AP_AIRSPEED_ENABLED
case AUX_FUNC::DISABLE_AIRSPEED_USE: {
AP_Airspeed *airspeed = AP::airspeed();
if (airspeed == nullptr) {
break;
}
switch (ch_flag) {
case AuxSwitchPos::HIGH:
airspeed->force_disable_use(true);
break;
case AuxSwitchPos::MIDDLE:
break;
case AuxSwitchPos::LOW:
airspeed->force_disable_use(false);
break;
}
break;
}
#endif
case AUX_FUNC::MOTOR_ESTOP:
switch (ch_flag) {
case AuxSwitchPos::HIGH: {
SRV_Channels::set_emergency_stop(true);
break;
}
case AuxSwitchPos::MIDDLE:
// nothing
break;
case AuxSwitchPos::LOW: {
SRV_Channels::set_emergency_stop(false);
break;
}
}
break;
#if HAL_VISUALODOM_ENABLED
case AUX_FUNC::VISODOM_ALIGN:
if (ch_flag == AuxSwitchPos::HIGH) {
AP_VisualOdom *visual_odom = AP::visualodom();
if (visual_odom != nullptr) {
visual_odom->request_align_yaw_to_ahrs();
}
}
break;
#endif
case AUX_FUNC::EKF_POS_SOURCE:
switch (ch_flag) {
case AuxSwitchPos::LOW:
// low switches to primary source
AP::ahrs().set_posvelyaw_source_set(0);
break;
case AuxSwitchPos::MIDDLE:
// middle switches to secondary source
AP::ahrs().set_posvelyaw_source_set(1);
break;
case AuxSwitchPos::HIGH:
// high switches to tertiary source
AP::ahrs().set_posvelyaw_source_set(2);
break;
}
break;
#if AP_OPTICALFLOW_CALIBRATOR_ENABLED
case AUX_FUNC::OPTFLOW_CAL: {
AP_OpticalFlow *optflow = AP::opticalflow();
if (optflow == nullptr) {
GCS_SEND_TEXT(MAV_SEVERITY_CRITICAL, "OptFlow Cal: failed sensor not enabled");
break;
}
if (ch_flag == AuxSwitchPos::HIGH) {
optflow->start_calibration();
} else {
optflow->stop_calibration();
}
break;
}
#endif
#if AP_INERTIALSENSOR_KILL_IMU_ENABLED
case AUX_FUNC::KILL_IMU1:
AP::ins().kill_imu(0, ch_flag == AuxSwitchPos::HIGH);
break;
case AUX_FUNC::KILL_IMU2:
AP::ins().kill_imu(1, ch_flag == AuxSwitchPos::HIGH);
break;
case AUX_FUNC::KILL_IMU3:
AP::ins().kill_imu(2, ch_flag == AuxSwitchPos::HIGH);
break;
#endif // AP_INERTIALSENSOR_KILL_IMU_ENABLED
#if AP_CAMERA_ENABLED
case AUX_FUNC::CAMERA_TRIGGER:
do_aux_function_camera_trigger(ch_flag);
break;
case AUX_FUNC::CAM_MODE_TOGGLE: {
// Momentary switch to for cycling camera modes
AP_Camera *camera = AP_Camera::get_singleton();
if (camera == nullptr) {
break;
}
switch (ch_flag) {
case AuxSwitchPos::LOW:
// nothing
break;
case AuxSwitchPos::MIDDLE:
// nothing
break;
case AuxSwitchPos::HIGH:
camera->cam_mode_toggle();
break;
}
break;
}
case AUX_FUNC::CAMERA_REC_VIDEO:
return do_aux_function_record_video(ch_flag);
case AUX_FUNC::CAMERA_ZOOM:
return do_aux_function_camera_zoom(ch_flag);
case AUX_FUNC::CAMERA_MANUAL_FOCUS:
return do_aux_function_camera_manual_focus(ch_flag);
case AUX_FUNC::CAMERA_AUTO_FOCUS:
return do_aux_function_camera_auto_focus(ch_flag);
case AUX_FUNC::CAMERA_IMAGE_TRACKING:
return do_aux_function_camera_image_tracking(ch_flag);
case AUX_FUNC::CAMERA_LENS:
return do_aux_function_camera_lens(ch_flag);
#endif
#if HAL_MOUNT_ENABLED
case AUX_FUNC::RETRACT_MOUNT1: {
AP_Mount *mount = AP::mount();
if (mount == nullptr) {
break;
}
switch (ch_flag) {
case AuxSwitchPos::HIGH:
mount->set_mode(0,MAV_MOUNT_MODE_RETRACT);
break;
case AuxSwitchPos::MIDDLE:
// nothing
break;
case AuxSwitchPos::LOW:
mount->set_mode_to_default(0);
break;
}
break;
}
case AUX_FUNC::MOUNT_LOCK: {
AP_Mount *mount = AP::mount();
if (mount == nullptr) {
break;
}
mount->set_yaw_lock(ch_flag == AuxSwitchPos::HIGH);
break;
}
#endif
case AUX_FUNC::LOG_PAUSE: {
AP_Logger *logger = AP_Logger::get_singleton();
switch (ch_flag) {
case AuxSwitchPos::LOW:
logger->log_pause(false);
break;
case AuxSwitchPos::MIDDLE:
// nothing
break;
case AuxSwitchPos::HIGH:
logger->log_pause(true);
break;
}
break;
}
#if COMPASS_CAL_ENABLED
case AUX_FUNC::MAG_CAL: {
Compass &compass = AP::compass();
switch (ch_flag) {
case AuxSwitchPos::LOW:
compass.cancel_calibration_all();
break;
case AuxSwitchPos::MIDDLE:
// nothing
break;
case AuxSwitchPos::HIGH:
if (!hal.util->get_soft_armed()) {
const bool retry = true;
const bool autosave = true;
const float delay = 5.0;
const bool autoreboot = false;
compass.start_calibration_all(retry, autosave, delay, autoreboot);
} else {
GCS_SEND_TEXT(MAV_SEVERITY_NOTICE, "Disarm to allow compass calibration");
}
break;
}
break;
}
#endif
case AUX_FUNC::ARM_EMERGENCY_STOP: {
switch (ch_flag) {
case AuxSwitchPos::HIGH:
// request arm, disable emergency motor stop
SRV_Channels::set_emergency_stop(false);
AP::arming().arm(AP_Arming::Method::AUXSWITCH, true);
break;
case AuxSwitchPos::MIDDLE:
// disable emergency motor stop
SRV_Channels::set_emergency_stop(false);
break;
case AuxSwitchPos::LOW:
// enable emergency motor stop
SRV_Channels::set_emergency_stop(true);
break;
}
break;
}
case AUX_FUNC::EKF_LANE_SWITCH:
// used to test emergency lane switch
AP::ahrs().check_lane_switch();
break;
case AUX_FUNC::EKF_YAW_RESET:
// used to test emergency yaw reset
AP::ahrs().request_yaw_reset();
break;
#if HAL_TORQEEDO_ENABLED
// clear torqeedo error
case AUX_FUNC::TORQEEDO_CLEAR_ERR: {
if (ch_flag == AuxSwitchPos::HIGH) {
AP_Torqeedo *torqeedo = AP_Torqeedo::get_singleton();
if (torqeedo != nullptr) {
torqeedo->clear_motor_error();
}
}
break;
}
#endif
// do nothing for these functions
case AUX_FUNC::MOUNT1_ROLL:
case AUX_FUNC::MOUNT1_PITCH:
case AUX_FUNC::MOUNT1_YAW:
case AUX_FUNC::MOUNT2_ROLL:
case AUX_FUNC::MOUNT2_PITCH:
case AUX_FUNC::MOUNT2_YAW:
case AUX_FUNC::SCRIPTING_1:
case AUX_FUNC::SCRIPTING_2:
case AUX_FUNC::SCRIPTING_3:
case AUX_FUNC::SCRIPTING_4:
case AUX_FUNC::SCRIPTING_5:
case AUX_FUNC::SCRIPTING_6:
case AUX_FUNC::SCRIPTING_7:
case AUX_FUNC::SCRIPTING_8:
break;
case AUX_FUNC::LOWEHEISER_THROTTLE:
case AUX_FUNC::LOWEHEISER_STARTER:
// monitored by the library itself
break;
default:
GCS_SEND_TEXT(MAV_SEVERITY_INFO, "Invalid channel option (%u)", (unsigned int)ch_option);
return false;
}
return true;
}
void RC_Channel::init_aux()
{
AuxSwitchPos position;
if (!read_3pos_switch(position)) {
position = AuxSwitchPos::LOW;
}
init_aux_function((aux_func_t)option.get(), position);
}
// read_3pos_switch
bool RC_Channel::read_3pos_switch(RC_Channel::AuxSwitchPos &ret) const
{
const uint16_t in = get_radio_in();
if (in <= RC_MIN_LIMIT_PWM || in >= RC_MAX_LIMIT_PWM) {
return false;
}
// switch is reversed if 'reversed' option set on channel and switches reverse is allowed by RC_OPTIONS
bool switch_reversed = reversed && rc().option_is_enabled(RC_Channels::Option::ALLOW_SWITCH_REV);
if (in < AUX_SWITCH_PWM_TRIGGER_LOW) {
ret = switch_reversed ? AuxSwitchPos::HIGH : AuxSwitchPos::LOW;
} else if (in > AUX_SWITCH_PWM_TRIGGER_HIGH) {
ret = switch_reversed ? AuxSwitchPos::LOW : AuxSwitchPos::HIGH;
} else {
ret = AuxSwitchPos::MIDDLE;
}
return true;
}
// return switch position value as LOW, MIDDLE, HIGH
// if reading the switch fails then it returns LOW
RC_Channel::AuxSwitchPos RC_Channel::get_aux_switch_pos() const
{
AuxSwitchPos position = AuxSwitchPos::LOW;
UNUSED_RESULT(read_3pos_switch(position));
return position;
}
// return switch position value as LOW, MIDDLE, HIGH
// if reading the switch fails then it returns LOW
RC_Channel::AuxSwitchPos RC_Channels::get_channel_pos(const uint8_t rcmapchan) const
{
const RC_Channel* chan = rc().channel(rcmapchan-1);
return chan != nullptr ? chan->get_aux_switch_pos() : RC_Channel::AuxSwitchPos::LOW;
}
RC_Channel *RC_Channels::find_channel_for_option(const RC_Channel::aux_func_t option)
{
for (uint8_t i=0; i<NUM_RC_CHANNELS; i++) {
RC_Channel *c = channel(i);
if (c == nullptr) {
// odd?
continue;
}
if ((RC_Channel::aux_func_t)c->option.get() == option) {
return c;
}
}
return nullptr;
}
// duplicate_options_exist - returns true if any options are duplicated
bool RC_Channels::duplicate_options_exist()
{
uint8_t auxsw_option_counts[256] = {};
for (uint8_t i=0; i<NUM_RC_CHANNELS; i++) {
const RC_Channel *c = channel(i);
if (c == nullptr) {
// odd?
continue;
}
const uint16_t option = c->option.get();
if (option >= sizeof(auxsw_option_counts)) {
continue;
}
auxsw_option_counts[option]++;
}
for (uint16_t i=0; i<sizeof(auxsw_option_counts); i++) {
if (i == 0) { // MAGIC VALUE! This is AUXSW_DO_NOTHING
continue;
}
if (auxsw_option_counts[i] > 1) {
return true;
}
}
return false;
}
// convert option parameter from old to new
void RC_Channels::convert_options(const RC_Channel::aux_func_t old_option, const RC_Channel::aux_func_t new_option)
{
for (uint8_t i=0; i<NUM_RC_CHANNELS; i++) {
RC_Channel *c = channel(i);
if (c == nullptr) {
// odd?
continue;
}
if ((RC_Channel::aux_func_t)c->option.get() == old_option) {
c->option.set_and_save((int16_t)new_option);
}
}
}
#endif // AP_RC_CHANNEL_ENABLED