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// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*-
/*
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/>.
*/
# include <AP_Common.h>
# include <AP_Math.h>
# include <AP_HAL.h>
# include <AP_Notify.h>
# include <AP_GPS.h>
extern const AP_HAL : : HAL & hal ;
// table of user settable parameters
const AP_Param : : GroupInfo AP_GPS : : var_info [ ] PROGMEM = {
// @Param: TYPE
// @DisplayName: GPS type
// @Description: GPS type
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// @Values: 0:None,1:AUTO,2:uBlox,3:MTK,4:MTK19,5:NMEA,6:SiRF,7:HIL,8:SwiftNav,9:PX4EXPERIMENTAL
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AP_GROUPINFO ( " TYPE " , 0 , AP_GPS , _type [ 0 ] , 1 ) ,
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# if GPS_MAX_INSTANCES > 1
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// @Param: TYPE2
// @DisplayName: 2nd GPS type
// @Description: GPS type of 2nd GPS
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// @Values: 0:None,1:AUTO,2:uBlox,3:MTK,4:MTK19,5:NMEA,6:SiRF,7:HIL,8:SwiftNav,9:PX4EXPERIMENTAL
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AP_GROUPINFO ( " TYPE2 " , 1 , AP_GPS , _type [ 1 ] , 0 ) ,
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# endif
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// @Param: NAVFILTER
// @DisplayName: Navigation filter setting
// @Description: Navigation filter engine setting
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// @Values: 0:Portable,2:Stationary,3:Pedestrian,4:Automotive,5:Sea,6:Airborne1G,7:Airborne2G,8:Airborne4G
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AP_GROUPINFO ( " NAVFILTER " , 2 , AP_GPS , _navfilter , GPS_ENGINE_AIRBORNE_4G ) ,
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# if GPS_MAX_INSTANCES > 1
// @Param: AUTO_SWITCH
// @DisplayName: Automatic Switchover Setting
// @Description: Automatic switchover to GPS reporting best lock
// @Values: 0:Disabled,1:Enabled
// @User: Advanced
AP_GROUPINFO ( " AUTO_SWITCH " , 3 , AP_GPS , _auto_switch , 1 ) ,
# endif
# if GPS_RTK_AVAILABLE
// @Param: DGPS_MIN_LOCK
// @DisplayName: Minimum Lock Type Accepted for DGPS
// @Description: Sets the minimum type of differential GPS corrections required before allowing to switch into DGPS mode.
// @Values: 0:Any,50:FloatRTK,100:IntegerRTK
// @User: Advanced
AP_GROUPINFO ( " MIN_DGPS " , 4 , AP_GPS , _min_dgps , 100 ) ,
# endif
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// @Param: SBAS_MODE
// @DisplayName: SBAS Mode
// @Description: This sets the SBAS (satellite based augmentation system) mode if available on this GPS. If set to 2 then the SBAS mode is not changed in the GPS. Otherwise the GPS will be reconfigured to enable/disable SBAS. Disabling SBAS may be worthwhile in some parts of the world where an SBAS signal is available but the baseline is too long to be useful.
// @Values: 0:Disabled,1:Enabled,2:NoChange
// @User: Advanced
AP_GROUPINFO ( " SBAS_MODE " , 5 , AP_GPS , _sbas_mode , 2 ) ,
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// @Param: MIN_ELEV
// @DisplayName: Minimum elevation
// @Description: This sets the minimum elevation of satellites above the horizon for them to be used for navigation. Setting this to -100 leaves the minimum elevation set to the GPS modules default.
// @Range: -100 90
// @Units: Degrees
// @User: Advanced
AP_GROUPINFO ( " MIN_ELEV " , 6 , AP_GPS , _min_elevation , - 100 ) ,
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AP_GROUPEND
} ;
/// Startup initialisation.
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void AP_GPS : : init ( DataFlash_Class * dataflash , const AP_SerialManager & serial_manager )
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{
_DataFlash = dataflash ;
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primary_instance = 0 ;
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// search for serial ports with gps protocol
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_port [ 0 ] = serial_manager . find_serial ( AP_SerialManager : : SerialProtocol_GPS ) ;
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# if GPS_MAX_INSTANCES > 1
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_port [ 1 ] = serial_manager . find_serial ( AP_SerialManager : : SerialProtocol_GPS2 ) ;
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# endif
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}
// baudrates to try to detect GPSes with
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const uint32_t AP_GPS : : _baudrates [ ] PROGMEM = { 4800U , 38400U , 115200U , 57600U , 9600U } ;
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// initialisation blobs to send to the GPS to try to get it into the
// right mode
const prog_char AP_GPS : : _initialisation_blob [ ] PROGMEM = UBLOX_SET_BINARY MTK_SET_BINARY SIRF_SET_BINARY ;
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/*
send some more initialisation string bytes if there is room in the
UART transmit buffer
*/
void AP_GPS : : send_blob_start ( uint8_t instance , const prog_char * _blob , uint16_t size )
{
initblob_state [ instance ] . blob = _blob ;
initblob_state [ instance ] . remaining = size ;
}
/*
send some more initialisation string bytes if there is room in the
UART transmit buffer
*/
void AP_GPS : : send_blob_update ( uint8_t instance )
{
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// exit immediately if no uart for this instance
if ( _port [ instance ] = = NULL ) {
return ;
}
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// see if we can write some more of the initialisation blob
if ( initblob_state [ instance ] . remaining > 0 ) {
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int16_t space = _port [ instance ] - > txspace ( ) ;
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if ( space > ( int16_t ) initblob_state [ instance ] . remaining ) {
space = initblob_state [ instance ] . remaining ;
}
while ( space > 0 ) {
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_port [ instance ] - > write ( pgm_read_byte ( initblob_state [ instance ] . blob ) ) ;
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initblob_state [ instance ] . blob + + ;
space - - ;
initblob_state [ instance ] . remaining - - ;
}
}
}
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/*
run detection step for one GPS instance . If this finds a GPS then it
will fill in drivers [ instance ] and change state [ instance ] . status
from NO_GPS to NO_FIX .
*/
void
AP_GPS : : detect_instance ( uint8_t instance )
{
AP_GPS_Backend * new_gps = NULL ;
struct detect_state * dstate = & detect_state [ instance ] ;
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uint32_t now = hal . scheduler - > millis ( ) ;
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# if CONFIG_HAL_BOARD == HAL_BOARD_PX4
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if ( _type [ instance ] = = GPS_TYPE_PX4 ) {
// check for explicitely chosen PX4 GPS beforehand
// it is not possible to autodetect it, nor does it require a real UART
hal . console - > print_P ( PSTR ( " PX4 " ) ) ;
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new_gps = new AP_GPS_PX4 ( * this , state [ instance ] , _port [ instance ] ) ;
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goto found_gps ;
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}
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# endif
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if ( _port [ instance ] = = NULL ) {
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// UART not available
return ;
}
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state [ instance ] . instance = instance ;
state [ instance ] . status = NO_GPS ;
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// record the time when we started detection. This is used to try
// to avoid initialising a uBlox as a NMEA GPS
if ( dstate - > detect_started_ms = = 0 ) {
dstate - > detect_started_ms = now ;
}
if ( now - dstate - > last_baud_change_ms > 1200 ) {
// try the next baud rate
dstate - > last_baud + + ;
if ( dstate - > last_baud = = sizeof ( _baudrates ) / sizeof ( _baudrates [ 0 ] ) ) {
dstate - > last_baud = 0 ;
}
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uint32_t baudrate = pgm_read_dword ( & _baudrates [ dstate - > last_baud ] ) ;
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_port [ instance ] - > begin ( baudrate ) ;
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_port [ instance ] - > set_flow_control ( AP_HAL : : UARTDriver : : FLOW_CONTROL_DISABLE ) ;
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dstate - > last_baud_change_ms = now ;
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send_blob_start ( instance , _initialisation_blob , sizeof ( _initialisation_blob ) ) ;
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}
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send_blob_update ( instance ) ;
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while ( _port [ instance ] - > available ( ) > 0 & & new_gps = = NULL ) {
uint8_t data = _port [ instance ] - > read ( ) ;
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/*
running a uBlox at less than 38400 will lead to packet
corruption , as we can ' t receive the packets in the 200 ms
window for 5 Hz fixes . The NMEA startup message should force
the uBlox into 38400 no matter what rate it is configured
for .
*/
if ( ( _type [ instance ] = = GPS_TYPE_AUTO | | _type [ instance ] = = GPS_TYPE_UBLOX ) & &
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pgm_read_dword ( & _baudrates [ dstate - > last_baud ] ) > = 38400 & &
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AP_GPS_UBLOX : : _detect ( dstate - > ublox_detect_state , data ) ) {
hal . console - > print_P ( PSTR ( " ublox " ) ) ;
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new_gps = new AP_GPS_UBLOX ( * this , state [ instance ] , _port [ instance ] ) ;
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}
else if ( ( _type [ instance ] = = GPS_TYPE_AUTO | | _type [ instance ] = = GPS_TYPE_MTK19 ) & &
AP_GPS_MTK19 : : _detect ( dstate - > mtk19_detect_state , data ) ) {
hal . console - > print_P ( PSTR ( " MTK19 " ) ) ;
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new_gps = new AP_GPS_MTK19 ( * this , state [ instance ] , _port [ instance ] ) ;
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}
else if ( ( _type [ instance ] = = GPS_TYPE_AUTO | | _type [ instance ] = = GPS_TYPE_MTK ) & &
AP_GPS_MTK : : _detect ( dstate - > mtk_detect_state , data ) ) {
hal . console - > print_P ( PSTR ( " MTK " ) ) ;
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new_gps = new AP_GPS_MTK ( * this , state [ instance ] , _port [ instance ] ) ;
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}
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# if GPS_RTK_AVAILABLE
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else if ( ( _type [ instance ] = = GPS_TYPE_AUTO | | _type [ instance ] = = GPS_TYPE_SBP ) & &
AP_GPS_SBP : : _detect ( dstate - > sbp_detect_state , data ) ) {
hal . console - > print_P ( PSTR ( " SBP " ) ) ;
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new_gps = new AP_GPS_SBP ( * this , state [ instance ] , _port [ instance ] ) ;
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}
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# endif // HAL_CPU_CLASS
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# if !defined(GPS_SKIP_SIRF_NMEA)
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// save a bit of code space on a 1280
else if ( ( _type [ instance ] = = GPS_TYPE_AUTO | | _type [ instance ] = = GPS_TYPE_SIRF ) & &
AP_GPS_SIRF : : _detect ( dstate - > sirf_detect_state , data ) ) {
hal . console - > print_P ( PSTR ( " SIRF " ) ) ;
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new_gps = new AP_GPS_SIRF ( * this , state [ instance ] , _port [ instance ] ) ;
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}
else if ( now - dstate - > detect_started_ms > 5000 ) {
// prevent false detection of NMEA mode in
// a MTK or UBLOX which has booted in NMEA mode
if ( ( _type [ instance ] = = GPS_TYPE_AUTO | | _type [ instance ] = = GPS_TYPE_NMEA ) & &
AP_GPS_NMEA : : _detect ( dstate - > nmea_detect_state , data ) ) {
hal . console - > print_P ( PSTR ( " NMEA " ) ) ;
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new_gps = new AP_GPS_NMEA ( * this , state [ instance ] , _port [ instance ] ) ;
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}
}
# endif
}
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found_gps :
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if ( new_gps ! = NULL ) {
state [ instance ] . status = NO_FIX ;
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drivers [ instance ] = new_gps ;
timing [ instance ] . last_message_time_ms = now ;
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}
}
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bool
AP_GPS : : can_calculate_base_pos ( void )
{
# if GPS_RTK_AVAILABLE
for ( uint8_t i = 0 ; i < GPS_MAX_INSTANCES ; i + + ) {
if ( drivers [ i ] ! = NULL & & drivers [ i ] - > can_calculate_base_pos ( ) ) {
return true ;
}
}
# endif
return false ;
}
/*
Tells the underlying GPS drivers to capture its current position as home .
*/
void
AP_GPS : : calculate_base_pos ( void )
{
# if GPS_RTK_AVAILABLE
for ( uint8_t i = 0 ; i < GPS_MAX_INSTANCES ; i + + ) {
if ( drivers [ i ] ! = NULL & & drivers [ i ] - > can_calculate_base_pos ( ) ) {
drivers [ i ] - > calculate_base_pos ( ) ;
}
}
# endif
}
AP_GPS : : GPS_Status
AP_GPS : : highest_supported_status ( uint8_t instance ) const
{
# if GPS_RTK_AVAILABLE
if ( drivers [ instance ] ! = NULL )
return drivers [ instance ] - > highest_supported_status ( ) ;
# endif
return AP_GPS : : GPS_OK_FIX_3D ;
}
AP_GPS : : GPS_Status
AP_GPS : : highest_supported_status ( void ) const
{
# if GPS_RTK_AVAILABLE
if ( drivers [ primary_instance ] ! = NULL )
return drivers [ primary_instance ] - > highest_supported_status ( ) ;
# endif
return AP_GPS : : GPS_OK_FIX_3D ;
}
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/*
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update one GPS instance . This should be called at 10 Hz or greater
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*/
void
AP_GPS : : update_instance ( uint8_t instance )
{
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if ( _type [ instance ] = = GPS_TYPE_HIL ) {
// in HIL, leave info alone
return ;
}
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if ( _type [ instance ] = = GPS_TYPE_NONE ) {
// not enabled
state [ instance ] . status = NO_GPS ;
return ;
}
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if ( locked_ports & ( 1U < < instance ) ) {
// the port is locked by another driver
return ;
}
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if ( drivers [ instance ] = = NULL | | state [ instance ] . status = = NO_GPS ) {
// we don't yet know the GPS type of this one, or it has timed
// out and needs to be re-initialised
detect_instance ( instance ) ;
return ;
}
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send_blob_update ( instance ) ;
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// we have an active driver for this instance
bool result = drivers [ instance ] - > read ( ) ;
uint32_t tnow = hal . scheduler - > millis ( ) ;
// if we did not get a message, and the idle timer of 1.2 seconds
// has expired, re-initialise the GPS. This will cause GPS
// detection to run again
if ( ! result ) {
if ( tnow - timing [ instance ] . last_message_time_ms > 1200 ) {
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// free the driver before we run the next detection, so we
// don't end up with two allocated at any time
delete drivers [ instance ] ;
drivers [ instance ] = NULL ;
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memset ( & state [ instance ] , 0 , sizeof ( state [ instance ] ) ) ;
state [ instance ] . instance = instance ;
state [ instance ] . status = NO_GPS ;
timing [ instance ] . last_message_time_ms = tnow ;
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}
} else {
timing [ instance ] . last_message_time_ms = tnow ;
if ( state [ instance ] . status > = GPS_OK_FIX_2D ) {
timing [ instance ] . last_fix_time_ms = tnow ;
}
}
}
/*
update all GPS instances
*/
void
AP_GPS : : update ( void )
{
for ( uint8_t i = 0 ; i < GPS_MAX_INSTANCES ; i + + ) {
update_instance ( i ) ;
}
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# if GPS_MAX_INSTANCES > 1
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// work out which GPS is the primary, and how many sensors we have
for ( uint8_t i = 0 ; i < GPS_MAX_INSTANCES ; i + + ) {
if ( state [ i ] . status ! = NO_GPS ) {
num_instances = i + 1 ;
}
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if ( _auto_switch ) {
if ( i = = primary_instance ) {
continue ;
}
if ( state [ i ] . status > state [ primary_instance ] . status ) {
// we have a higher status lock, change GPS
primary_instance = i ;
continue ;
}
if ( state [ i ] . status = = state [ primary_instance ] . status & &
state [ i ] . num_sats > = state [ primary_instance ] . num_sats + 2 ) {
// this GPS has at least 2 more satellites than the
// current primary, switch primary. Once we switch we will
// then tend to stick to the new GPS as primary. We don't
// want to switch too often as it will look like a
// position shift to the controllers.
primary_instance = i ;
}
} else {
primary_instance = 0 ;
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}
}
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# else
num_instances = 1 ;
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# endif // GPS_MAX_INSTANCES
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// update notify with gps status. We always base this on the primary_instance
AP_Notify : : flags . gps_status = state [ primary_instance ] . status ;
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}
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/*
set HIL ( hardware in the loop ) status for a GPS instance
*/
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void
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AP_GPS : : setHIL ( uint8_t instance , GPS_Status _status , uint64_t time_epoch_ms ,
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const Location & _location , const Vector3f & _velocity , uint8_t _num_sats ,
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uint16_t hdop , bool _have_vertical_velocity )
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{
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if ( instance > = GPS_MAX_INSTANCES ) {
return ;
}
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uint32_t tnow = hal . scheduler - > millis ( ) ;
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GPS_State & istate = state [ instance ] ;
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istate . status = _status ;
istate . location = _location ;
istate . location . options = 0 ;
istate . velocity = _velocity ;
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istate . have_vertical_velocity = true ;
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istate . ground_speed = pythagorous2 ( istate . velocity . x , istate . velocity . y ) ;
istate . ground_course_cd = degrees ( atan2f ( istate . velocity . y , istate . velocity . x ) ) * 100UL ;
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istate . hdop = hdop ;
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istate . num_sats = _num_sats ;
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istate . have_vertical_velocity = _have_vertical_velocity ;
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istate . last_gps_time_ms = tnow ;
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uint64_t gps_time_ms = time_epoch_ms - ( 17000ULL * 86400ULL + 52 * 10 * 7000ULL * 86400ULL - 15000ULL ) ;
istate . time_week = gps_time_ms / ( 86400 * 7 * ( uint64_t ) 1000 ) ;
istate . time_week_ms = gps_time_ms - istate . time_week * ( 86400 * 7 * ( uint64_t ) 1000 ) ;
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timing [ instance ] . last_message_time_ms = tnow ;
timing [ instance ] . last_fix_time_ms = tnow ;
_type [ instance ] . set ( GPS_TYPE_HIL ) ;
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}
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/**
Lock a GPS port , prevening the GPS driver from using it . This can
be used to allow a user to control a GPS port via the
SERIAL_CONTROL protocol
*/
void
AP_GPS : : lock_port ( uint8_t instance , bool lock )
{
if ( instance > = GPS_MAX_INSTANCES ) {
return ;
}
if ( lock ) {
locked_ports | = ( 1U < < instance ) ;
} else {
locked_ports & = ~ ( 1U < < instance ) ;
}
}
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void
AP_GPS : : send_mavlink_gps_raw ( mavlink_channel_t chan )
{
static uint32_t last_send_time_ms ;
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if ( status ( 0 ) > AP_GPS : : NO_GPS ) {
// when we have a GPS then only send new data
if ( last_send_time_ms = = last_message_time_ms ( 0 ) ) {
return ;
}
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last_send_time_ms = last_message_time_ms ( 0 ) ;
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} else {
// when we don't have a GPS then send at 1Hz
uint32_t now = hal . scheduler - > millis ( ) ;
if ( now - last_send_time_ms < 1000 ) {
return ;
}
last_send_time_ms = now ;
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}
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const Location & loc = location ( 0 ) ;
mavlink_msg_gps_raw_int_send (
chan ,
last_fix_time_ms ( 0 ) * ( uint64_t ) 1000 ,
status ( 0 ) ,
loc . lat , // in 1E7 degrees
loc . lng , // in 1E7 degrees
loc . alt * 10UL , // in mm
get_hdop ( 0 ) ,
65535 ,
ground_speed ( 0 ) * 100 , // cm/s
ground_course_cd ( 0 ) , // 1/100 degrees,
num_sats ( 0 ) ) ;
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}
# if GPS_MAX_INSTANCES > 1
void
AP_GPS : : send_mavlink_gps2_raw ( mavlink_channel_t chan )
{
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static uint32_t last_send_time_ms ;
if ( num_sensors ( ) < 2 | | status ( 1 ) < = AP_GPS : : NO_GPS ) {
return ;
}
// when we have a GPS then only send new data
if ( last_send_time_ms = = last_message_time_ms ( 1 ) ) {
return ;
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}
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last_send_time_ms = last_message_time_ms ( 1 ) ;
const Location & loc = location ( 1 ) ;
mavlink_msg_gps2_raw_send (
chan ,
last_fix_time_ms ( 1 ) * ( uint64_t ) 1000 ,
status ( 1 ) ,
loc . lat ,
loc . lng ,
loc . alt * 10UL ,
get_hdop ( 1 ) ,
65535 ,
ground_speed ( 1 ) * 100 , // cm/s
ground_course_cd ( 1 ) , // 1/100 degrees,
num_sats ( 1 ) ,
0 ,
0 ) ;
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}
# endif
# if GPS_RTK_AVAILABLE
void
AP_GPS : : send_mavlink_gps_rtk ( mavlink_channel_t chan )
{
if ( drivers [ 0 ] ! = NULL & & drivers [ 0 ] - > highest_supported_status ( ) > AP_GPS : : GPS_OK_FIX_3D ) {
drivers [ 0 ] - > send_mavlink_gps_rtk ( chan ) ;
}
}
# if GPS_MAX_INSTANCES > 1
void
AP_GPS : : send_mavlink_gps2_rtk ( mavlink_channel_t chan )
{
if ( drivers [ 1 ] ! = NULL & & drivers [ 1 ] - > highest_supported_status ( ) > AP_GPS : : GPS_OK_FIX_3D ) {
drivers [ 1 ] - > send_mavlink_gps_rtk ( chan ) ;
}
}
# endif
# endif