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# include "Sub.h"
/*
constructor for Mode object
*/
Mode : : Mode ( void ) :
g ( sub . g ) ,
g2 ( sub . g2 ) ,
inertial_nav ( sub . inertial_nav ) ,
ahrs ( sub . ahrs ) ,
motors ( sub . motors ) ,
channel_roll ( sub . channel_roll ) ,
channel_pitch ( sub . channel_pitch ) ,
channel_throttle ( sub . channel_throttle ) ,
channel_yaw ( sub . channel_yaw ) ,
channel_forward ( sub . channel_forward ) ,
channel_lateral ( sub . channel_lateral ) ,
position_control ( & sub . pos_control ) ,
attitude_control ( & sub . attitude_control ) ,
G_Dt ( sub . G_Dt )
{ } ;
// return the static controller object corresponding to supplied mode
Mode * Sub : : mode_from_mode_num ( const Mode : : Number mode )
{
Mode * ret = nullptr ;
switch ( mode ) {
case Mode : : Number : : MANUAL :
ret = & mode_manual ;
break ;
case Mode : : Number : : STABILIZE :
ret = & mode_stabilize ;
break ;
case Mode : : Number : : ACRO :
ret = & mode_acro ;
break ;
case Mode : : Number : : ALT_HOLD :
ret = & mode_althold ;
break ;
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case Mode : : Number : : SURFTRAK :
ret = & mode_surftrak ;
break ;
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case Mode : : Number : : POSHOLD :
ret = & mode_poshold ;
break ;
case Mode : : Number : : AUTO :
ret = & mode_auto ;
break ;
case Mode : : Number : : GUIDED :
ret = & mode_guided ;
break ;
case Mode : : Number : : CIRCLE :
ret = & mode_circle ;
break ;
case Mode : : Number : : SURFACE :
ret = & mode_surface ;
break ;
case Mode : : Number : : MOTOR_DETECT :
ret = & mode_motordetect ;
break ;
default :
break ;
}
return ret ;
}
// set_mode - change flight mode and perform any necessary initialisation
// optional force parameter used to force the flight mode change (used only first time mode is set)
// returns true if mode was successfully set
// Some modes can always be set successfully but the return state of other flight modes should be checked and the caller should deal with failures appropriately
bool Sub : : set_mode ( Mode : : Number mode , ModeReason reason )
{
// return immediately if we are already in the desired mode
if ( mode = = control_mode ) {
control_mode_reason = reason ;
return true ;
}
Mode * new_flightmode = mode_from_mode_num ( ( Mode : : Number ) mode ) ;
if ( new_flightmode = = nullptr ) {
notify_no_such_mode ( ( uint8_t ) mode ) ;
return false ;
}
if ( new_flightmode - > requires_GPS ( ) & &
! sub . position_ok ( ) ) {
gcs ( ) . send_text ( MAV_SEVERITY_WARNING , " Mode change failed: %s requires position " , new_flightmode - > name ( ) ) ;
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LOGGER_WRITE_ERROR ( LogErrorSubsystem : : FLIGHT_MODE , LogErrorCode ( mode ) ) ;
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return false ;
}
// check for valid altitude if old mode did not require it but new one does
// we only want to stop changing modes if it could make things worse
if ( ! sub . control_check_barometer ( ) & & // maybe use ekf_alt_ok() instead?
flightmode - > has_manual_throttle ( ) & &
! new_flightmode - > has_manual_throttle ( ) ) {
gcs ( ) . send_text ( MAV_SEVERITY_WARNING , " Mode change failed: %s need alt estimate " , new_flightmode - > name ( ) ) ;
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LOGGER_WRITE_ERROR ( LogErrorSubsystem : : FLIGHT_MODE , LogErrorCode ( mode ) ) ;
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return false ;
}
if ( ! new_flightmode - > init ( false ) ) {
gcs ( ) . send_text ( MAV_SEVERITY_WARNING , " Flight mode change failed %s " , new_flightmode - > name ( ) ) ;
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LOGGER_WRITE_ERROR ( LogErrorSubsystem : : FLIGHT_MODE , LogErrorCode ( mode ) ) ;
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return false ;
}
// perform any cleanup required by previous flight mode
exit_mode ( flightmode , new_flightmode ) ;
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// store previous flight mode
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prev_control_mode = control_mode ;
// update flight mode
flightmode = new_flightmode ;
control_mode = mode ;
control_mode_reason = reason ;
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# if HAL_LOGGING_ENABLED
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logger . Write_Mode ( ( uint8_t ) control_mode , reason ) ;
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# endif
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gcs ( ) . send_message ( MSG_HEARTBEAT ) ;
// update notify object
notify_flight_mode ( ) ;
// return success
return true ;
}
// exit_mode - high level call to organise cleanup as a flight mode is exited
void Sub : : exit_mode ( Mode : : Number old_control_mode , Mode : : Number new_control_mode )
{
// stop mission when we leave auto mode
if ( old_control_mode = = Mode : : Number : : AUTO ) {
if ( mission . state ( ) = = AP_Mission : : MISSION_RUNNING ) {
mission . stop ( ) ;
}
# if HAL_MOUNT_ENABLED
camera_mount . set_mode_to_default ( ) ;
# endif // HAL_MOUNT_ENABLED
}
}
bool Sub : : set_mode ( const uint8_t new_mode , const ModeReason reason )
{
static_assert ( sizeof ( Mode : : Number ) = = sizeof ( new_mode ) , " The new mode can't be mapped to the vehicles mode number " ) ;
return sub . set_mode ( static_cast < Mode : : Number > ( new_mode ) , reason ) ;
}
// update_flight_mode - calls the appropriate attitude controllers based on flight mode
// called at 100hz or more
void Sub : : update_flight_mode ( )
{
flightmode - > run ( ) ;
}
// exit_mode - high level call to organise cleanup as a flight mode is exited
void Sub : : exit_mode ( Mode * & old_flightmode , Mode * & new_flightmode ) {
# if HAL_MOUNT_ENABLED
camera_mount . set_mode_to_default ( ) ;
# endif // HAL_MOUNT_ENABLED
}
// notify_flight_mode - sets notify object based on current flight mode. Only used for OreoLED notify device
void Sub : : notify_flight_mode ( )
{
AP_Notify : : flags . autopilot_mode = flightmode - > is_autopilot ( ) ;
AP_Notify : : flags . flight_mode = ( uint8_t ) control_mode ;
notify . set_flight_mode_str ( flightmode - > name4 ( ) ) ;
}
// get_pilot_desired_angle_rates - transform pilot's roll pitch and yaw input into a desired lean angle rates
// returns desired angle rates in centi-degrees-per-second
void Mode : : get_pilot_desired_angle_rates ( int16_t roll_in , int16_t pitch_in , int16_t yaw_in , float & roll_out , float & pitch_out , float & yaw_out )
{
float rate_limit ;
Vector3f rate_ef_level , rate_bf_level , rate_bf_request ;
// apply circular limit to pitch and roll inputs
float total_in = norm ( pitch_in , roll_in ) ;
if ( total_in > ROLL_PITCH_INPUT_MAX ) {
float ratio = ( float ) ROLL_PITCH_INPUT_MAX / total_in ;
roll_in * = ratio ;
pitch_in * = ratio ;
}
// calculate roll, pitch rate requests
if ( g . acro_expo < = 0 ) {
rate_bf_request . x = roll_in * g . acro_rp_p ;
rate_bf_request . y = pitch_in * g . acro_rp_p ;
} else {
// expo variables
float rp_in , rp_in3 , rp_out ;
// range check expo
if ( g . acro_expo > 1.0f ) {
g . acro_expo . set ( 1.0f ) ;
}
// roll expo
rp_in = float ( roll_in ) / ROLL_PITCH_INPUT_MAX ;
rp_in3 = rp_in * rp_in * rp_in ;
rp_out = ( g . acro_expo * rp_in3 ) + ( ( 1 - g . acro_expo ) * rp_in ) ;
rate_bf_request . x = ROLL_PITCH_INPUT_MAX * rp_out * g . acro_rp_p ;
// pitch expo
rp_in = float ( pitch_in ) / ROLL_PITCH_INPUT_MAX ;
rp_in3 = rp_in * rp_in * rp_in ;
rp_out = ( g . acro_expo * rp_in3 ) + ( ( 1 - g . acro_expo ) * rp_in ) ;
rate_bf_request . y = ROLL_PITCH_INPUT_MAX * rp_out * g . acro_rp_p ;
}
// calculate yaw rate request
rate_bf_request . z = yaw_in * g . acro_yaw_p ;
// calculate earth frame rate corrections to pull the vehicle back to level while in ACRO mode
if ( g . acro_trainer ! = ACRO_TRAINER_DISABLED ) {
// Calculate trainer mode earth frame rate command for roll
int32_t roll_angle = wrap_180_cd ( ahrs . roll_sensor ) ;
rate_ef_level . x = - constrain_int32 ( roll_angle , - ACRO_LEVEL_MAX_ANGLE , ACRO_LEVEL_MAX_ANGLE ) * g . acro_balance_roll ;
// Calculate trainer mode earth frame rate command for pitch
int32_t pitch_angle = wrap_180_cd ( ahrs . pitch_sensor ) ;
rate_ef_level . y = - constrain_int32 ( pitch_angle , - ACRO_LEVEL_MAX_ANGLE , ACRO_LEVEL_MAX_ANGLE ) * g . acro_balance_pitch ;
// Calculate trainer mode earth frame rate command for yaw
rate_ef_level . z = 0 ;
// Calculate angle limiting earth frame rate commands
if ( g . acro_trainer = = ACRO_TRAINER_LIMITED ) {
if ( roll_angle > sub . aparm . angle_max ) {
rate_ef_level . x - = g . acro_balance_roll * ( roll_angle - sub . aparm . angle_max ) ;
} else if ( roll_angle < - sub . aparm . angle_max ) {
rate_ef_level . x - = g . acro_balance_roll * ( roll_angle + sub . aparm . angle_max ) ;
}
if ( pitch_angle > sub . aparm . angle_max ) {
rate_ef_level . y - = g . acro_balance_pitch * ( pitch_angle - sub . aparm . angle_max ) ;
} else if ( pitch_angle < - sub . aparm . angle_max ) {
rate_ef_level . y - = g . acro_balance_pitch * ( pitch_angle + sub . aparm . angle_max ) ;
}
}
// convert earth-frame level rates to body-frame level rates
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attitude_control - > euler_rate_to_ang_vel ( attitude_control - > get_attitude_target_quat ( ) , rate_ef_level , rate_bf_level ) ;
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// combine earth frame rate corrections with rate requests
if ( g . acro_trainer = = ACRO_TRAINER_LIMITED ) {
rate_bf_request . x + = rate_bf_level . x ;
rate_bf_request . y + = rate_bf_level . y ;
rate_bf_request . z + = rate_bf_level . z ;
} else {
float acro_level_mix = constrain_float ( 1 - MAX ( MAX ( abs ( roll_in ) , abs ( pitch_in ) ) , abs ( yaw_in ) ) / 4500.0 , 0 , 1 ) * ahrs . cos_pitch ( ) ;
// Scale leveling rates by stick input
rate_bf_level = rate_bf_level * acro_level_mix ;
// Calculate rate limit to prevent change of rate through inverted
rate_limit = fabsf ( fabsf ( rate_bf_request . x ) - fabsf ( rate_bf_level . x ) ) ;
rate_bf_request . x + = rate_bf_level . x ;
rate_bf_request . x = constrain_float ( rate_bf_request . x , - rate_limit , rate_limit ) ;
// Calculate rate limit to prevent change of rate through inverted
rate_limit = fabsf ( fabsf ( rate_bf_request . y ) - fabsf ( rate_bf_level . y ) ) ;
rate_bf_request . y + = rate_bf_level . y ;
rate_bf_request . y = constrain_float ( rate_bf_request . y , - rate_limit , rate_limit ) ;
// Calculate rate limit to prevent change of rate through inverted
rate_limit = fabsf ( fabsf ( rate_bf_request . z ) - fabsf ( rate_bf_level . z ) ) ;
rate_bf_request . z + = rate_bf_level . z ;
rate_bf_request . z = constrain_float ( rate_bf_request . z , - rate_limit , rate_limit ) ;
}
}
// hand back rate request
roll_out = rate_bf_request . x ;
pitch_out = rate_bf_request . y ;
yaw_out = rate_bf_request . z ;
}
bool Mode : : set_mode ( Mode : : Number mode , ModeReason reason )
{
return sub . set_mode ( mode , reason ) ;
}
GCS_Sub & Mode : : gcs ( )
{
return sub . gcs ( ) ;
}