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/*
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/>.
*/
/*
implementation of MSP and BLHeli - 4 way protocols for pass - through ESC
calibration and firmware update
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With thanks to betaflight for a great reference
implementation . Several of the functions below are based on
betaflight equivalent functions
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*/
# include "AP_BLHeli.h"
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# ifdef HAVE_AP_BLHELI_SUPPORT
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# include <AP_Math/crc.h>
# include <AP_Motors/AP_Motors_Class.h>
# include <GCS_MAVLink/GCS_MAVLink.h>
# include <GCS_MAVLink/GCS.h>
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# include <AP_SerialManager/AP_SerialManager.h>
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# include <AP_Logger/AP_Logger.h>
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extern const AP_HAL : : HAL & hal ;
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# define debug(fmt, args ...) do { if (debug_level) { gcs().send_text(MAV_SEVERITY_INFO, "ESC: " fmt, ## args); } } while (0)
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// key for locking UART for exclusive use. This prevents any other writes from corrupting
// the MSP protocol on hal.console
# define BLHELI_UART_LOCK_KEY 0x20180402
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const AP_Param : : GroupInfo AP_BLHeli : : var_info [ ] = {
// @Param: MASK
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// @DisplayName: BLHeli Channel Bitmask
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// @Description: Enable of BLHeli pass-thru servo protocol support to specific channels. This mask is in addition to motors enabled using SERVO_BLH_AUTO (if any)
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// @Bitmask: 0:Channel1,1:Channel2,2:Channel3,3:Channel4,4:Channel5,5:Channel6,6:Channel7,7:Channel8,8:Channel9,9:Channel10,10:Channel11,11:Channel12,12:Channel13,13:Channel14,14:Channel15,15:Channel16
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// @User: Advanced
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AP_GROUPINFO ( " MASK " , 1 , AP_BLHeli , channel_mask , 0 ) ,
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# if APM_BUILD_TYPE(APM_BUILD_ArduCopter) || APM_BUILD_TYPE(APM_BUILD_ArduPlane)
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// @Param: AUTO
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// @DisplayName: BLHeli auto-enable for multicopter motors
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// @Description: If set to 1 this auto-enables BLHeli pass-thru support for all multicopter motors
// @Values: 0:Disabled,1:Enabled
// @User: Standard
AP_GROUPINFO ( " AUTO " , 2 , AP_BLHeli , channel_auto , 0 ) ,
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# endif
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// @Param: TEST
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// @DisplayName: BLHeli internal interface test
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// @Description: Setting SERVO_BLH_TEST to a motor number enables an internal test of the BLHeli ESC protocol to the corresponding ESC. The debug output is displayed on the USB console.
// @Values: 0:Disabled,1:TestMotor1,2:TestMotor2,3:TestMotor3,4:TestMotor4,5:TestMotor5,6:TestMotor6,7:TestMotor7,8:TestMotor8
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// @User: Advanced
AP_GROUPINFO ( " TEST " , 3 , AP_BLHeli , run_test , 0 ) ,
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// @Param: TMOUT
// @DisplayName: BLHeli protocol timeout
// @Description: This sets the inactivity timeout for the BLHeli protocol in seconds. If no packets are received in this time normal MAVLink operations are resumed. A value of 0 means no timeout
// @Units: s
// @Range: 0 300
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// @User: Standard
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AP_GROUPINFO ( " TMOUT " , 4 , AP_BLHeli , timeout_sec , 0 ) ,
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// @Param: TRATE
// @DisplayName: BLHeli telemetry rate
// @Description: This sets the rate in Hz for requesting telemetry from ESCs. It is the rate per ESC. Setting to zero disables telemetry requests
// @Units: Hz
// @Range: 0 500
// @User: Standard
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AP_GROUPINFO ( " TRATE " , 5 , AP_BLHeli , telem_rate , 10 ) ,
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// @Param: DEBUG
// @DisplayName: BLHeli debug level
// @Description: When set to 1 this enabled verbose debugging output over MAVLink when the blheli protocol is active. This can be used to diagnose failures.
// @Values: 0:Disabled,1:Enabled
// @User: Standard
AP_GROUPINFO ( " DEBUG " , 6 , AP_BLHeli , debug_level , 0 ) ,
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// @Param: OTYPE
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// @DisplayName: BLHeli output type override
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// @Description: When set to a non-zero value this overrides the output type for the output channels given by SERVO_BLH_MASK. This can be used to enable DShot on outputs that are not part of the multicopter motors group.
// @Values: 0:None,1:OneShot,2:OneShot125,3:Brushed,4:DShot150,5:DShot300,6:DShot600,7:DShot1200
// @User: Advanced
AP_GROUPINFO ( " OTYPE " , 7 , AP_BLHeli , output_type , 0 ) ,
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// @Param: PORT
// @DisplayName: Control port
// @Description: This sets the telemetry port to use for blheli pass-thru
// @Values: 0:Console,1:Telem1,2:Telem2,3:Telem3,4:Telem4,5:Telem5
// @User: Advanced
AP_GROUPINFO ( " PORT " , 8 , AP_BLHeli , control_port , 0 ) ,
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// @Param: POLES
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// @DisplayName: BLHeli Motor Poles
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// @Description: This allows calculation of true RPM from ESC's eRPM. The default is 14.
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// @Range: 1 127
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// @User: Advanced
AP_GROUPINFO ( " POLES " , 9 , AP_BLHeli , motor_poles , 14 ) ,
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// @Param: REMASK
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// @DisplayName: BLHeli bitmask of reversible channels
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// @Description: Mask of channels which are reversible. This is used for ESCs which have been configured in '3D' mode, allowing for the motor to spin in either direction
// @Bitmask: 0:Channel1,1:Channel2,2:Channel3,3:Channel4,4:Channel5,5:Channel6,6:Channel7,7:Channel8,8:Channel9,9:Channel10,10:Channel11,11:Channel12,12:Channel13,13:Channel14,14:Channel15,15:Channel16
// @User: Advanced
AP_GROUPINFO ( " REMASK " , 10 , AP_BLHeli , channel_reversible_mask , 0 ) ,
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AP_GROUPEND
} ;
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AP_BLHeli * AP_BLHeli : : _singleton ;
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// constructor
AP_BLHeli : : AP_BLHeli ( void )
{
// set defaults from the parameter table
AP_Param : : setup_object_defaults ( this , var_info ) ;
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_singleton = this ;
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last_control_port = - 1 ;
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}
/*
process one byte of serial input for MSP protocol
*/
bool AP_BLHeli : : msp_process_byte ( uint8_t c )
{
if ( msp . state = = MSP_IDLE ) {
msp . escMode = PROTOCOL_NONE ;
if ( c = = ' $ ' ) {
msp . state = MSP_HEADER_START ;
} else {
return false ;
}
} else if ( msp . state = = MSP_HEADER_START ) {
msp . state = ( c = = ' M ' ) ? MSP_HEADER_M : MSP_IDLE ;
} else if ( msp . state = = MSP_HEADER_M ) {
msp . state = MSP_IDLE ;
switch ( c ) {
case ' < ' : // COMMAND
msp . packetType = MSP_PACKET_COMMAND ;
msp . state = MSP_HEADER_ARROW ;
break ;
case ' > ' : // REPLY
msp . packetType = MSP_PACKET_REPLY ;
msp . state = MSP_HEADER_ARROW ;
break ;
default :
break ;
}
} else if ( msp . state = = MSP_HEADER_ARROW ) {
if ( c > sizeof ( msp . buf ) ) {
msp . state = MSP_IDLE ;
} else {
msp . dataSize = c ;
msp . offset = 0 ;
msp . checksum = 0 ;
msp . checksum ^ = c ;
msp . state = MSP_HEADER_SIZE ;
}
} else if ( msp . state = = MSP_HEADER_SIZE ) {
msp . cmdMSP = c ;
msp . checksum ^ = c ;
msp . state = MSP_HEADER_CMD ;
} else if ( msp . state = = MSP_HEADER_CMD & & msp . offset < msp . dataSize ) {
msp . checksum ^ = c ;
msp . buf [ msp . offset + + ] = c ;
} else if ( msp . state = = MSP_HEADER_CMD & & msp . offset > = msp . dataSize ) {
if ( msp . checksum = = c ) {
msp . state = MSP_COMMAND_RECEIVED ;
} else {
msp . state = MSP_IDLE ;
}
}
return true ;
}
/*
update CRC state for blheli protocol
*/
void AP_BLHeli : : blheli_crc_update ( uint8_t c )
{
blheli . crc = crc_xmodem_update ( blheli . crc , c ) ;
}
/*
process one byte of serial input for blheli 4 way protocol
*/
bool AP_BLHeli : : blheli_4way_process_byte ( uint8_t c )
{
if ( blheli . state = = BLHELI_IDLE ) {
if ( c = = cmd_Local_Escape ) {
blheli . state = BLHELI_HEADER_START ;
blheli . crc = 0 ;
blheli_crc_update ( c ) ;
} else {
return false ;
}
} else if ( blheli . state = = BLHELI_HEADER_START ) {
blheli . command = c ;
blheli_crc_update ( c ) ;
blheli . state = BLHELI_HEADER_CMD ;
} else if ( blheli . state = = BLHELI_HEADER_CMD ) {
blheli . address = c < < 8 ;
blheli . state = BLHELI_HEADER_ADDR_HIGH ;
blheli_crc_update ( c ) ;
} else if ( blheli . state = = BLHELI_HEADER_ADDR_HIGH ) {
blheli . address | = c ;
blheli . state = BLHELI_HEADER_ADDR_LOW ;
blheli_crc_update ( c ) ;
} else if ( blheli . state = = BLHELI_HEADER_ADDR_LOW ) {
blheli . state = BLHELI_HEADER_LEN ;
blheli . param_len = c ? c : 256 ;
blheli . offset = 0 ;
blheli_crc_update ( c ) ;
} else if ( blheli . state = = BLHELI_HEADER_LEN ) {
blheli . buf [ blheli . offset + + ] = c ;
blheli_crc_update ( c ) ;
if ( blheli . offset = = blheli . param_len ) {
blheli . state = BLHELI_CRC1 ;
}
} else if ( blheli . state = = BLHELI_CRC1 ) {
blheli . crc1 = c ;
blheli . state = BLHELI_CRC2 ;
} else if ( blheli . state = = BLHELI_CRC2 ) {
uint16_t crc = blheli . crc1 < < 8 | c ;
if ( crc = = blheli . crc ) {
blheli . state = BLHELI_COMMAND_RECEIVED ;
} else {
blheli . state = BLHELI_IDLE ;
}
}
return true ;
}
/*
send a MSP protocol reply
*/
void AP_BLHeli : : msp_send_reply ( uint8_t cmd , const uint8_t * buf , uint8_t len )
{
uint8_t * b = & msp . buf [ 0 ] ;
* b + + = ' $ ' ;
* b + + = ' M ' ;
* b + + = ' > ' ;
* b + + = len ;
* b + + = cmd ;
memcpy ( b , buf , len ) ;
b + = len ;
uint8_t c = 0 ;
for ( uint8_t i = 0 ; i < len + 2 ; i + + ) {
c ^ = msp . buf [ i + 3 ] ;
}
* b + + = c ;
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uart - > write_locked ( & msp . buf [ 0 ] , len + 6 , BLHELI_UART_LOCK_KEY ) ;
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}
void AP_BLHeli : : putU16 ( uint8_t * b , uint16_t v )
{
b [ 0 ] = v ;
b [ 1 ] = v > > 8 ;
}
uint16_t AP_BLHeli : : getU16 ( const uint8_t * b )
{
return b [ 0 ] | ( b [ 1 ] < < 8 ) ;
}
void AP_BLHeli : : putU32 ( uint8_t * b , uint32_t v )
{
b [ 0 ] = v ;
b [ 1 ] = v > > 8 ;
b [ 2 ] = v > > 16 ;
b [ 3 ] = v > > 24 ;
}
void AP_BLHeli : : putU16_BE ( uint8_t * b , uint16_t v )
{
b [ 0 ] = v > > 8 ;
b [ 1 ] = v ;
}
/*
process a MSP command from GCS
*/
void AP_BLHeli : : msp_process_command ( void )
{
debug ( " MSP cmd %u len=%u " , msp . cmdMSP , msp . dataSize ) ;
switch ( msp . cmdMSP ) {
case MSP_API_VERSION : {
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debug ( " MSP_API_VERSION " ) ;
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uint8_t buf [ 3 ] = { MSP_PROTOCOL_VERSION , API_VERSION_MAJOR , API_VERSION_MINOR } ;
msp_send_reply ( msp . cmdMSP , buf , sizeof ( buf ) ) ;
break ;
}
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case MSP_FC_VARIANT :
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debug ( " MSP_FC_VARIANT " ) ;
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msp_send_reply ( msp . cmdMSP , ( const uint8_t * ) ARDUPILOT_IDENTIFIER , FLIGHT_CONTROLLER_IDENTIFIER_LENGTH ) ;
break ;
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case MSP_FC_VERSION : {
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debug ( " MSP_FC_VERSION " ) ;
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uint8_t version [ 3 ] = { 3 , 3 , 0 } ;
msp_send_reply ( msp . cmdMSP , version , sizeof ( version ) ) ;
break ;
}
case MSP_BOARD_INFO : {
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debug ( " MSP_BOARD_INFO " ) ;
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// send a generic 'ArduPilot ChibiOS' board type
uint8_t buf [ 7 ] = { ' A ' , ' R ' , ' C ' , ' H ' , 0 , 0 , 0 } ;
msp_send_reply ( msp . cmdMSP , buf , sizeof ( buf ) ) ;
break ;
}
case MSP_BUILD_INFO : {
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debug ( " MSP_BUILD_INFO " ) ;
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// build date, build time, git version
uint8_t buf [ 26 ] {
0x4d , 0x61 , 0x72 , 0x20 , 0x31 , 0x36 , 0x20 , 0x32 , 0x30 ,
0x31 , 0x38 , 0x30 , 0x38 , 0x3A , 0x34 , 0x32 , 0x3a , 0x32 , 0x39 ,
0x62 , 0x30 , 0x66 , 0x66 , 0x39 , 0x32 , 0x38 } ;
msp_send_reply ( msp . cmdMSP , buf , sizeof ( buf ) ) ;
break ;
}
case MSP_REBOOT :
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debug ( " MSP: ignoring reboot command " ) ;
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break ;
case MSP_UID :
// MCU identifer
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debug ( " MSP_UID " ) ;
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msp_send_reply ( msp . cmdMSP , ( const uint8_t * ) UDID_START , 12 ) ;
break ;
case MSP_ADVANCED_CONFIG : {
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debug ( " MSP_ADVANCED_CONFIG " ) ;
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uint8_t buf [ 10 ] ;
buf [ 0 ] = 1 ; // gyro sync denom
buf [ 1 ] = 4 ; // pid process denom
buf [ 2 ] = 0 ; // use unsynced pwm
buf [ 3 ] = ( uint8_t ) PWM_TYPE_DSHOT150 ; // motor PWM protocol
putU16 ( & buf [ 4 ] , 480 ) ; // motor PWM Rate
putU16 ( & buf [ 6 ] , 450 ) ; // idle offset value
buf [ 8 ] = 0 ; // use 32kHz
buf [ 9 ] = 0 ; // motor PWM inversion
msp_send_reply ( msp . cmdMSP , buf , sizeof ( buf ) ) ;
break ;
}
case MSP_FEATURE_CONFIG : {
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debug ( " MSP_FEATURE_CONFIG " ) ;
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uint8_t buf [ 4 ] ;
putU32 ( buf , 0 ) ; // from MSPFeatures enum
msp_send_reply ( msp . cmdMSP , buf , sizeof ( buf ) ) ;
break ;
}
case MSP_STATUS : {
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debug ( " MSP_STATUS " ) ;
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uint8_t buf [ 21 ] ;
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putU16 ( & buf [ 0 ] , 1000 ) ; // loop time usec
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putU16 ( & buf [ 2 ] , 0 ) ; // i2c error count
putU16 ( & buf [ 4 ] , 0x27 ) ; // available sensors
putU32 ( & buf [ 6 ] , 0 ) ; // flight modes
buf [ 10 ] = 0 ; // pid profile index
putU16 ( & buf [ 11 ] , 5 ) ; // system load percent
putU16 ( & buf [ 13 ] , 0 ) ; // gyro cycle time
buf [ 15 ] = 0 ; // flight mode flags length
buf [ 16 ] = 18 ; // arming disable flags count
putU32 ( & buf [ 17 ] , 0 ) ; // arming disable flags
msp_send_reply ( msp . cmdMSP , buf , sizeof ( buf ) ) ;
break ;
}
case MSP_MOTOR_3D_CONFIG : {
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debug ( " MSP_MOTOR_3D_CONFIG " ) ;
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uint8_t buf [ 6 ] ;
putU16 ( & buf [ 0 ] , 1406 ) ; // 3D deadband low
putU16 ( & buf [ 2 ] , 1514 ) ; // 3D deadband high
putU16 ( & buf [ 4 ] , 1460 ) ; // 3D neutral
msp_send_reply ( msp . cmdMSP , buf , sizeof ( buf ) ) ;
break ;
}
case MSP_MOTOR_CONFIG : {
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debug ( " MSP_MOTOR_CONFIG " ) ;
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uint8_t buf [ 6 ] ;
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putU16 ( & buf [ 0 ] , 1030 ) ; // min throttle
putU16 ( & buf [ 2 ] , 2000 ) ; // max throttle
putU16 ( & buf [ 4 ] , 1000 ) ; // min command
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msp_send_reply ( msp . cmdMSP , buf , sizeof ( buf ) ) ;
break ;
}
case MSP_MOTOR : {
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debug ( " MSP_MOTOR " ) ;
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// get the output going to each motor
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uint8_t buf [ 16 ] { } ;
for ( uint8_t i = 0 ; i < num_motors ; i + + ) {
uint16_t v = hal . rcout - > read ( motor_map [ i ] ) ;
putU16 ( & buf [ 2 * i ] , v ) ;
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}
msp_send_reply ( msp . cmdMSP , buf , sizeof ( buf ) ) ;
break ;
}
case MSP_SET_MOTOR : {
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debug ( " MSP_SET_MOTOR " ) ;
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// set the output to each motor
uint8_t nmotors = msp . dataSize / 2 ;
debug ( " MSP_SET_MOTOR %u " , nmotors ) ;
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SRV_Channels : : set_disabled_channel_mask ( 0xFFFF ) ;
motors_disabled = true ;
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hal . rcout - > cork ( ) ;
for ( uint8_t i = 0 ; i < nmotors ; i + + ) {
if ( i > = num_motors ) {
break ;
}
uint16_t v = getU16 ( & msp . buf [ i * 2 ] ) ;
debug ( " MSP_SET_MOTOR %u %u " , i , v ) ;
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// map from a MSP value to a value in the range 1000 to 2000
uint16_t pwm = ( v < 1000 ) ? 0 : v ;
hal . rcout - > write ( motor_map [ i ] , pwm ) ;
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}
hal . rcout - > push ( ) ;
break ;
}
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case MSP_SET_4WAY_IF : {
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debug ( " MSP_SET_4WAY_IF " ) ;
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if ( msp . dataSize = = 0 ) {
msp . escMode = PROTOCOL_4WAY ;
} else if ( msp . dataSize = = 2 ) {
msp . escMode = ( enum escProtocol ) msp . buf [ 0 ] ;
msp . portIndex = msp . buf [ 1 ] ;
}
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debug ( " escMode=%u portIndex=%u num_motors=%u " , msp . escMode , msp . portIndex , num_motors ) ;
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uint8_t n = num_motors ;
switch ( msp . escMode ) {
case PROTOCOL_4WAY :
break ;
default :
n = 0 ;
hal . rcout - > serial_end ( ) ;
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serial_start_ms = 0 ;
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break ;
}
msp_send_reply ( msp . cmdMSP , & n , 1 ) ;
break ;
}
default :
debug ( " Unknown MSP command %u " , msp . cmdMSP ) ;
break ;
}
}
/*
send a blheli 4 way protocol reply
*/
void AP_BLHeli : : blheli_send_reply ( const uint8_t * buf , uint16_t len )
{
uint8_t * b = & blheli . buf [ 0 ] ;
* b + + = cmd_Remote_Escape ;
* b + + = blheli . command ;
putU16_BE ( b , blheli . address ) ; b + = 2 ;
* b + + = len = = 256 ? 0 : len ;
memcpy ( b , buf , len ) ;
b + = len ;
* b + + = blheli . ack ;
putU16_BE ( b , crc_xmodem ( & blheli . buf [ 0 ] , len + 6 ) ) ;
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uart - > write_locked ( & blheli . buf [ 0 ] , len + 8 , BLHELI_UART_LOCK_KEY ) ;
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debug ( " OutB(%u) 0x%02x ack=0x%02x " , len + 8 , ( unsigned ) blheli . command , blheli . ack ) ;
}
/*
CRC used when talking to ESCs
*/
uint16_t AP_BLHeli : : BL_CRC ( const uint8_t * buf , uint16_t len )
{
uint16_t crc = 0 ;
while ( len - - ) {
uint8_t xb = * buf + + ;
for ( uint8_t i = 0 ; i < 8 ; i + + ) {
if ( ( ( xb & 0x01 ) ^ ( crc & 0x0001 ) ) ! = 0 ) {
crc = crc > > 1 ;
crc = crc ^ 0xA001 ;
} else {
crc = crc > > 1 ;
}
xb = xb > > 1 ;
}
}
return crc ;
}
bool AP_BLHeli : : isMcuConnected ( void )
{
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return blheli . connected [ blheli . chan ] ;
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}
void AP_BLHeli : : setDisconnected ( void )
{
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blheli . connected [ blheli . chan ] = false ;
blheli . deviceInfo [ blheli . chan ] [ 0 ] = 0 ;
blheli . deviceInfo [ blheli . chan ] [ 1 ] = 0 ;
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}
/*
send a set of bytes to an RC output channel
*/
bool AP_BLHeli : : BL_SendBuf ( const uint8_t * buf , uint16_t len )
{
bool send_crc = isMcuConnected ( ) ;
if ( blheli . chan > = num_motors ) {
return false ;
}
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if ( ! hal . rcout - > serial_setup_output ( motor_map [ blheli . chan ] , 19200 , motor_mask ) ) {
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blheli . ack = ACK_D_GENERAL_ERROR ;
return false ;
}
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if ( serial_start_ms = = 0 ) {
serial_start_ms = AP_HAL : : millis ( ) ;
}
uint32_t now = AP_HAL : : millis ( ) ;
if ( serial_start_ms = = 0 | | now - serial_start_ms < 1000 ) {
/*
we ' ve just started the interface . We want it idle for at
least 1 second before we start sending serial data .
*/
hal . scheduler - > delay ( 1100 ) ;
}
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memcpy ( blheli . buf , buf , len ) ;
uint16_t crc = BL_CRC ( buf , len ) ;
blheli . buf [ len ] = crc ;
blheli . buf [ len + 1 ] = crc > > 8 ;
if ( ! hal . rcout - > serial_write_bytes ( blheli . buf , len + ( send_crc ? 2 : 0 ) ) ) {
blheli . ack = ACK_D_GENERAL_ERROR ;
return false ;
}
return true ;
}
/*
read bytes from the ESC connection
*/
bool AP_BLHeli : : BL_ReadBuf ( uint8_t * buf , uint16_t len )
{
bool check_crc = isMcuConnected ( ) & & len > 0 ;
uint16_t req_bytes = len + ( check_crc ? 3 : 1 ) ;
uint16_t n = hal . rcout - > serial_read_bytes ( blheli . buf , req_bytes ) ;
debug ( " BL_ReadBuf %u -> %u " , len , n ) ;
if ( req_bytes ! = n ) {
debug ( " short read " ) ;
blheli . ack = ACK_D_GENERAL_ERROR ;
return false ;
}
if ( check_crc ) {
uint16_t crc = BL_CRC ( blheli . buf , len ) ;
if ( ( crc & 0xff ) ! = blheli . buf [ len ] | |
( crc > > 8 ) ! = blheli . buf [ len + 1 ] ) {
debug ( " bad CRC " ) ;
blheli . ack = ACK_D_GENERAL_ERROR ;
return false ;
}
if ( blheli . buf [ len + 2 ] ! = brSUCCESS ) {
debug ( " bad ACK 0x%02x " , blheli . buf [ len + 2 ] ) ;
blheli . ack = ACK_D_GENERAL_ERROR ;
return false ;
}
} else {
if ( blheli . buf [ len ] ! = brSUCCESS ) {
debug ( " bad ACK1 0x%02x " , blheli . buf [ len ] ) ;
blheli . ack = ACK_D_GENERAL_ERROR ;
return false ;
}
}
if ( len > 0 ) {
memcpy ( buf , blheli . buf , len ) ;
}
return true ;
}
uint8_t AP_BLHeli : : BL_GetACK ( uint16_t timeout_ms )
{
uint8_t ack ;
uint32_t start_ms = AP_HAL : : millis ( ) ;
while ( AP_HAL : : millis ( ) - start_ms < timeout_ms ) {
if ( hal . rcout - > serial_read_bytes ( & ack , 1 ) = = 1 ) {
return ack ;
}
}
// return brNONE, meaning no ACK received in the timeout
return brNONE ;
}
bool AP_BLHeli : : BL_SendCMDSetAddress ( )
{
// skip if adr == 0xFFFF
if ( blheli . address = = 0xFFFF ) {
return true ;
}
debug ( " BL_SendCMDSetAddress 0x%04x " , blheli . address ) ;
uint8_t sCMD [ ] = { CMD_SET_ADDRESS , 0 , uint8_t ( blheli . address > > 8 ) , uint8_t ( blheli . address ) } ;
if ( ! BL_SendBuf ( sCMD , 4 ) ) {
return false ;
}
return BL_GetACK ( ) = = brSUCCESS ;
}
bool AP_BLHeli : : BL_ReadA ( uint8_t cmd , uint8_t * buf , uint16_t n )
{
if ( BL_SendCMDSetAddress ( ) ) {
uint8_t sCMD [ ] = { cmd , uint8_t ( n = = 256 ? 0 : n ) } ;
if ( ! BL_SendBuf ( sCMD , 2 ) ) {
return false ;
}
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bool ret = BL_ReadBuf ( buf , n ) ;
if ( ret & & n = = sizeof ( esc_status ) & & blheli . address = = esc_status_addr ) {
// display esc_status structure if we see it
struct esc_status status ;
memcpy ( & status , buf , n ) ;
debug ( " Prot %u Good %u Bad %u %x %x %x x%x \n " ,
( unsigned ) status . protocol ,
( unsigned ) status . good_frames ,
( unsigned ) status . bad_frames ,
( unsigned ) status . unknown [ 0 ] ,
( unsigned ) status . unknown [ 1 ] ,
( unsigned ) status . unknown [ 2 ] ,
( unsigned ) status . unknown2 ) ;
}
return ret ;
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}
return false ;
}
/*
connect to a blheli ESC
*/
bool AP_BLHeli : : BL_ConnectEx ( void )
{
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if ( blheli . connected [ blheli . chan ] ! = 0 ) {
debug ( " Using cached interface 0x%x for %u " , blheli . interface_mode [ blheli . chan ] , blheli . chan ) ;
return true ;
}
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debug ( " BL_ConnectEx %u/%u at %u " , blheli . chan , num_motors , motor_map [ blheli . chan ] ) ;
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setDisconnected ( ) ;
const uint8_t BootInit [ ] = { 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0x0D , ' B ' , ' L ' , ' H ' , ' e ' , ' l ' , ' i ' , 0xF4 , 0x7D } ;
if ( ! BL_SendBuf ( BootInit , 21 ) ) {
return false ;
}
uint8_t BootInfo [ 8 ] ;
if ( ! BL_ReadBuf ( BootInfo , 8 ) ) {
return false ;
}
// reply must start with 471
if ( strncmp ( ( const char * ) BootInfo , " 471 " , 3 ) ! = 0 ) {
blheli . ack = ACK_D_GENERAL_ERROR ;
return false ;
}
// extract device information
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blheli . deviceInfo [ blheli . chan ] [ 2 ] = BootInfo [ 3 ] ;
blheli . deviceInfo [ blheli . chan ] [ 1 ] = BootInfo [ 4 ] ;
blheli . deviceInfo [ blheli . chan ] [ 0 ] = BootInfo [ 5 ] ;
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blheli . interface_mode [ blheli . chan ] = 0 ;
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uint16_t * devword = ( uint16_t * ) blheli . deviceInfo [ blheli . chan ] ;
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switch ( * devword ) {
case 0x9307 :
case 0x930A :
case 0x930F :
case 0x940B :
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blheli . interface_mode [ blheli . chan ] = imATM_BLB ;
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debug ( " Interface type imATM_BLB " ) ;
break ;
case 0xF310 :
case 0xF330 :
case 0xF410 :
case 0xF390 :
case 0xF850 :
case 0xE8B1 :
case 0xE8B2 :
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blheli . interface_mode [ blheli . chan ] = imSIL_BLB ;
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debug ( " Interface type imSIL_BLB " ) ;
break ;
case 0x1F06 :
case 0x3306 :
case 0x3406 :
case 0x3506 :
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blheli . interface_mode [ blheli . chan ] = imARM_BLB ;
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debug ( " Interface type imARM_BLB " ) ;
break ;
default :
blheli . ack = ACK_D_GENERAL_ERROR ;
debug ( " Unknown interface type 0x%04x " , * devword ) ;
break ;
}
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blheli . deviceInfo [ blheli . chan ] [ 3 ] = blheli . interface_mode [ blheli . chan ] ;
if ( blheli . interface_mode [ blheli . chan ] ! = 0 ) {
blheli . connected [ blheli . chan ] = true ;
}
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return true ;
}
bool AP_BLHeli : : BL_SendCMDKeepAlive ( void )
{
uint8_t sCMD [ ] = { CMD_KEEP_ALIVE , 0 } ;
if ( ! BL_SendBuf ( sCMD , 2 ) ) {
return false ;
}
if ( BL_GetACK ( ) ! = brERRORCOMMAND ) {
return false ;
}
return true ;
}
bool AP_BLHeli : : BL_PageErase ( void )
{
if ( BL_SendCMDSetAddress ( ) ) {
uint8_t sCMD [ ] = { CMD_ERASE_FLASH , 0x01 } ;
if ( ! BL_SendBuf ( sCMD , 2 ) ) {
return false ;
}
return BL_GetACK ( 1000 ) = = brSUCCESS ;
}
return false ;
}
void AP_BLHeli : : BL_SendCMDRunRestartBootloader ( void )
{
uint8_t sCMD [ ] = { RestartBootloader , 0 } ;
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blheli . deviceInfo [ blheli . chan ] [ 0 ] = 1 ;
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BL_SendBuf ( sCMD , 2 ) ;
}
uint8_t AP_BLHeli : : BL_SendCMDSetBuffer ( const uint8_t * buf , uint16_t nbytes )
{
uint8_t sCMD [ ] = { CMD_SET_BUFFER , 0 , uint8_t ( nbytes > > 8 ) , uint8_t ( nbytes & 0xff ) } ;
if ( ! BL_SendBuf ( sCMD , 4 ) ) {
return false ;
}
uint8_t ack ;
if ( ( ack = BL_GetACK ( ) ) ! = brNONE ) {
debug ( " BL_SendCMDSetBuffer ack failed 0x%02x " , ack ) ;
blheli . ack = ACK_D_GENERAL_ERROR ;
return false ;
}
if ( ! BL_SendBuf ( buf , nbytes ) ) {
debug ( " BL_SendCMDSetBuffer send failed " ) ;
blheli . ack = ACK_D_GENERAL_ERROR ;
return false ;
}
return ( BL_GetACK ( 40 ) = = brSUCCESS ) ;
}
bool AP_BLHeli : : BL_WriteA ( uint8_t cmd , const uint8_t * buf , uint16_t nbytes , uint32_t timeout_ms )
{
if ( BL_SendCMDSetAddress ( ) ) {
if ( ! BL_SendCMDSetBuffer ( buf , nbytes ) ) {
blheli . ack = ACK_D_GENERAL_ERROR ;
return false ;
}
uint8_t sCMD [ ] = { cmd , 0x01 } ;
if ( ! BL_SendBuf ( sCMD , 2 ) ) {
return false ;
}
return ( BL_GetACK ( timeout_ms ) = = brSUCCESS ) ;
}
blheli . ack = ACK_D_GENERAL_ERROR ;
return false ;
}
uint8_t AP_BLHeli : : BL_WriteFlash ( const uint8_t * buf , uint16_t n )
{
return BL_WriteA ( CMD_PROG_FLASH , buf , n , 250 ) ;
}
bool AP_BLHeli : : BL_VerifyFlash ( const uint8_t * buf , uint16_t n )
{
if ( BL_SendCMDSetAddress ( ) ) {
if ( ! BL_SendCMDSetBuffer ( buf , n ) ) {
return false ;
}
uint8_t sCMD [ ] = { CMD_VERIFY_FLASH_ARM , 0x01 } ;
if ( ! BL_SendBuf ( sCMD , 2 ) ) {
return false ;
}
uint8_t ack = BL_GetACK ( 40 ) ;
switch ( ack ) {
case brSUCCESS :
blheli . ack = ACK_OK ;
break ;
case brERRORVERIFY :
blheli . ack = ACK_I_VERIFY_ERROR ;
break ;
default :
blheli . ack = ACK_D_GENERAL_ERROR ;
break ;
}
return true ;
}
return false ;
}
/*
process a blheli 4 way command from GCS
*/
void AP_BLHeli : : blheli_process_command ( void )
{
debug ( " BLHeli cmd 0x%02x len=%u " , blheli . command , blheli . param_len ) ;
blheli . ack = ACK_OK ;
switch ( blheli . command ) {
case cmd_InterfaceTestAlive : {
debug ( " cmd_InterfaceTestAlive " ) ;
BL_SendCMDKeepAlive ( ) ;
if ( blheli . ack ! = ACK_OK ) {
setDisconnected ( ) ;
}
uint8_t b = 0 ;
blheli_send_reply ( & b , 1 ) ;
break ;
}
case cmd_ProtocolGetVersion : {
debug ( " cmd_ProtocolGetVersion " ) ;
uint8_t buf [ 1 ] ;
buf [ 0 ] = SERIAL_4WAY_PROTOCOL_VER ;
blheli_send_reply ( buf , sizeof ( buf ) ) ;
break ;
}
case cmd_InterfaceGetName : {
debug ( " cmd_InterfaceGetName " ) ;
uint8_t buf [ 5 ] = { 4 , ' A ' , ' R ' , ' D ' , ' U ' } ;
blheli_send_reply ( buf , sizeof ( buf ) ) ;
break ;
}
case cmd_InterfaceGetVersion : {
debug ( " cmd_InterfaceGetVersion " ) ;
uint8_t buf [ 2 ] = { SERIAL_4WAY_VERSION_HI , SERIAL_4WAY_VERSION_LO } ;
blheli_send_reply ( buf , sizeof ( buf ) ) ;
break ;
}
case cmd_InterfaceExit : {
debug ( " cmd_InterfaceExit " ) ;
msp . escMode = PROTOCOL_NONE ;
uint8_t b = 0 ;
blheli_send_reply ( & b , 1 ) ;
hal . rcout - > serial_end ( ) ;
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serial_start_ms = 0 ;
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if ( motors_disabled ) {
motors_disabled = false ;
SRV_Channels : : set_disabled_channel_mask ( 0 ) ;
}
if ( uart_locked ) {
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debug ( " Unlocked UART " ) ;
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uart - > lock_port ( 0 , 0 ) ;
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uart_locked = false ;
}
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memset ( blheli . connected , 0 , sizeof ( blheli . connected ) ) ;
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break ;
}
case cmd_DeviceReset : {
debug ( " cmd_DeviceReset(%u) " , unsigned ( blheli . buf [ 0 ] ) ) ;
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if ( blheli . buf [ 0 ] > = num_motors ) {
debug ( " bad reset channel %u " , blheli . buf [ 0 ] ) ;
blheli . ack = ACK_D_GENERAL_ERROR ;
blheli_send_reply ( & blheli . buf [ 0 ] , 1 ) ;
break ;
}
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blheli . chan = blheli . buf [ 0 ] ;
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switch ( blheli . interface_mode [ blheli . chan ] ) {
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case imSIL_BLB :
case imATM_BLB :
case imARM_BLB :
BL_SendCMDRunRestartBootloader ( ) ;
break ;
case imSK :
break ;
}
blheli_send_reply ( & blheli . chan , 1 ) ;
setDisconnected ( ) ;
break ;
}
case cmd_DeviceInitFlash : {
debug ( " cmd_DeviceInitFlash(%u) " , unsigned ( blheli . buf [ 0 ] ) ) ;
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if ( blheli . buf [ 0 ] > = num_motors ) {
debug ( " bad channel %u " , blheli . buf [ 0 ] ) ;
break ;
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}
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blheli . chan = blheli . buf [ 0 ] ;
blheli . ack = ACK_OK ;
BL_ConnectEx ( ) ;
uint8_t buf [ 4 ] = { blheli . deviceInfo [ blheli . chan ] [ 0 ] ,
blheli . deviceInfo [ blheli . chan ] [ 1 ] ,
blheli . deviceInfo [ blheli . chan ] [ 2 ] ,
blheli . deviceInfo [ blheli . chan ] [ 3 ] } ; // device ID
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blheli_send_reply ( buf , sizeof ( buf ) ) ;
break ;
}
case cmd_InterfaceSetMode : {
debug ( " cmd_InterfaceSetMode(%u) " , unsigned ( blheli . buf [ 0 ] ) ) ;
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blheli . interface_mode [ blheli . chan ] = blheli . buf [ 0 ] ;
blheli_send_reply ( & blheli . interface_mode [ blheli . chan ] , 1 ) ;
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break ;
}
case cmd_DeviceRead : {
uint16_t nbytes = blheli . buf [ 0 ] ? blheli . buf [ 0 ] : 256 ;
debug ( " cmd_DeviceRead(%u) n=%u " , blheli . chan , nbytes ) ;
uint8_t buf [ nbytes ] ;
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uint8_t cmd = blheli . interface_mode [ blheli . chan ] = = imATM_BLB ? CMD_READ_FLASH_ATM : CMD_READ_FLASH_SIL ;
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if ( ! BL_ReadA ( cmd , buf , nbytes ) ) {
nbytes = 1 ;
}
blheli_send_reply ( buf , nbytes ) ;
break ;
}
case cmd_DevicePageErase : {
uint8_t page = blheli . buf [ 0 ] ;
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debug ( " cmd_DevicePageErase(%u) im=%u " , page , blheli . interface_mode [ blheli . chan ] ) ;
switch ( blheli . interface_mode [ blheli . chan ] ) {
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case imSIL_BLB :
case imARM_BLB : {
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if ( blheli . interface_mode [ blheli . chan ] = = imARM_BLB ) {
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// Address =Page * 1024
blheli . address = page < < 10 ;
} else {
// Address =Page * 512
blheli . address = page < < 9 ;
}
debug ( " ARM PageErase 0x%04x " , blheli . address ) ;
BL_PageErase ( ) ;
blheli . address = 0 ;
blheli_send_reply ( & page , 1 ) ;
break ;
}
default :
blheli . ack = ACK_I_INVALID_CMD ;
blheli_send_reply ( & page , 1 ) ;
break ;
}
break ;
}
case cmd_DeviceWrite : {
uint16_t nbytes = blheli . param_len ;
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debug ( " cmd_DeviceWrite n=%u im=%u " , nbytes , blheli . interface_mode [ blheli . chan ] ) ;
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uint8_t buf [ nbytes ] ;
memcpy ( buf , blheli . buf , nbytes ) ;
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switch ( blheli . interface_mode [ blheli . chan ] ) {
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case imSIL_BLB :
case imATM_BLB :
case imARM_BLB : {
BL_WriteFlash ( buf , nbytes ) ;
break ;
}
case imSK : {
debug ( " Unsupported flash mode imSK " ) ;
break ;
}
}
uint8_t b = 0 ;
blheli_send_reply ( & b , 1 ) ;
break ;
}
case cmd_DeviceVerify : {
uint16_t nbytes = blheli . param_len ;
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debug ( " cmd_DeviceWrite n=%u im=%u " , nbytes , blheli . interface_mode [ blheli . chan ] ) ;
switch ( blheli . interface_mode [ blheli . chan ] ) {
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case imARM_BLB : {
uint8_t buf [ nbytes ] ;
memcpy ( buf , blheli . buf , nbytes ) ;
BL_VerifyFlash ( buf , nbytes ) ;
break ;
}
default :
blheli . ack = ACK_I_INVALID_CMD ;
break ;
}
uint8_t b = 0 ;
blheli_send_reply ( & b , 1 ) ;
break ;
}
case cmd_DeviceReadEEprom : {
uint16_t nbytes = blheli . buf [ 0 ] ? blheli . buf [ 0 ] : 256 ;
uint8_t buf [ nbytes ] ;
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debug ( " cmd_DeviceReadEEprom n=%u im=%u " , nbytes , blheli . interface_mode [ blheli . chan ] ) ;
switch ( blheli . interface_mode [ blheli . chan ] ) {
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case imATM_BLB : {
if ( ! BL_ReadA ( CMD_READ_EEPROM , buf , nbytes ) ) {
blheli . ack = ACK_D_GENERAL_ERROR ;
}
break ;
}
default :
blheli . ack = ACK_I_INVALID_CMD ;
break ;
}
if ( blheli . ack ! = ACK_OK ) {
nbytes = 1 ;
buf [ 0 ] = 0 ;
}
blheli_send_reply ( buf , nbytes ) ;
break ;
}
case cmd_DeviceWriteEEprom : {
uint16_t nbytes = blheli . param_len ;
uint8_t buf [ nbytes ] ;
memcpy ( buf , blheli . buf , nbytes ) ;
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debug ( " cmd_DeviceWriteEEprom n=%u im=%u " , nbytes , blheli . interface_mode [ blheli . chan ] ) ;
switch ( blheli . interface_mode [ blheli . chan ] ) {
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case imATM_BLB :
BL_WriteA ( CMD_PROG_EEPROM , buf , nbytes , 1000 ) ;
break ;
default :
blheli . ack = ACK_D_GENERAL_ERROR ;
break ;
}
uint8_t b = 0 ;
blheli_send_reply ( & b , 1 ) ;
break ;
}
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case cmd_DeviceEraseAll :
case cmd_DeviceC2CK_LOW :
default :
// ack=unknown command
blheli . ack = ACK_I_INVALID_CMD ;
debug ( " Unknown BLHeli protocol 0x%02x " , blheli . command ) ;
uint8_t b = 0 ;
blheli_send_reply ( & b , 1 ) ;
break ;
}
}
/*
process an input byte , return true if we have received a whole
packet with correct CRC
*/
bool AP_BLHeli : : process_input ( uint8_t b )
{
bool valid_packet = false ;
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if ( msp . escMode = = PROTOCOL_4WAY & & blheli . state = = BLHELI_IDLE & & b = = ' $ ' ) {
debug ( " Change to MSP mode " ) ;
msp . escMode = PROTOCOL_NONE ;
hal . rcout - > serial_end ( ) ;
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serial_start_ms = 0 ;
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}
if ( msp . escMode ! = PROTOCOL_4WAY & & msp . state = = MSP_IDLE & & b = = ' / ' ) {
debug ( " Change to BLHeli mode " ) ;
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memset ( blheli . connected , 0 , sizeof ( blheli . connected ) ) ;
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msp . escMode = PROTOCOL_4WAY ;
}
if ( msp . escMode = = PROTOCOL_4WAY ) {
blheli_4way_process_byte ( b ) ;
} else {
msp_process_byte ( b ) ;
}
if ( msp . escMode = = PROTOCOL_4WAY ) {
if ( blheli . state = = BLHELI_COMMAND_RECEIVED ) {
valid_packet = true ;
last_valid_ms = AP_HAL : : millis ( ) ;
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if ( uart - > lock_port ( BLHELI_UART_LOCK_KEY , 0 ) ) {
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uart_locked = true ;
}
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blheli_process_command ( ) ;
blheli . state = BLHELI_IDLE ;
msp . state = MSP_IDLE ;
}
} else if ( msp . state = = MSP_COMMAND_RECEIVED ) {
if ( msp . packetType = = MSP_PACKET_COMMAND ) {
valid_packet = true ;
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if ( uart - > lock_port ( BLHELI_UART_LOCK_KEY , 0 ) ) {
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uart_locked = true ;
}
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last_valid_ms = AP_HAL : : millis ( ) ;
msp_process_command ( ) ;
}
msp . state = MSP_IDLE ;
blheli . state = BLHELI_IDLE ;
}
return valid_packet ;
}
/*
protocol handler for detecting BLHeli input
*/
bool AP_BLHeli : : protocol_handler ( uint8_t b , AP_HAL : : UARTDriver * _uart )
{
uart = _uart ;
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if ( hal . util - > get_soft_armed ( ) ) {
// don't allow MSP control when armed
return false ;
}
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return process_input ( b ) ;
}
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/*
run a connection test to the ESCs . This is used to test the
operation of the BLHeli ESC protocol
*/
void AP_BLHeli : : run_connection_test ( uint8_t chan )
{
debug_uart = hal . console ;
uint8_t saved_chan = blheli . chan ;
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if ( chan > = num_motors ) {
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debug ( " bad channel %u " , chan ) ;
return ;
}
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blheli . chan = chan ;
debug ( " Running test on channel %u " , blheli . chan ) ;
run_test . set_and_notify ( 0 ) ;
bool passed = false ;
for ( uint8_t tries = 0 ; tries < 5 ; tries + + ) {
blheli . ack = ACK_OK ;
setDisconnected ( ) ;
if ( BL_ConnectEx ( ) ) {
uint8_t buf [ 256 ] ;
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uint8_t cmd = blheli . interface_mode [ blheli . chan ] = = imATM_BLB ? CMD_READ_FLASH_ATM : CMD_READ_FLASH_SIL ;
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passed = true ;
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blheli . address = blheli . interface_mode [ blheli . chan ] = = imATM_BLB ? 0 : 0x7c00 ;
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passed & = BL_ReadA ( cmd , buf , sizeof ( buf ) ) ;
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if ( blheli . interface_mode [ blheli . chan ] = = imARM_BLB ) {
if ( passed ) {
// read status structure
blheli . address = esc_status_addr ;
passed & = BL_SendCMDSetAddress ( ) ;
}
if ( passed ) {
struct esc_status status ;
passed & = BL_ReadA ( CMD_READ_FLASH_SIL , ( uint8_t * ) & status , sizeof ( status ) ) ;
}
}
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BL_SendCMDRunRestartBootloader ( ) ;
break ;
}
}
hal . rcout - > serial_end ( ) ;
SRV_Channels : : set_disabled_channel_mask ( 0 ) ;
motors_disabled = false ;
serial_start_ms = 0 ;
blheli . chan = saved_chan ;
debug ( " Test %s " , passed ? " PASSED " : " FAILED " ) ;
debug_uart = nullptr ;
}
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/*
update BLHeli
Used to install protocol handler
*/
void AP_BLHeli : : update ( void )
{
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if ( initialised & &
timeout_sec & &
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uart_locked & &
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AP_HAL : : millis ( ) - last_valid_ms > uint32_t ( timeout_sec . get ( ) ) * 1000U ) {
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// we're not processing requests any more, shutdown serial
// output
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if ( serial_start_ms ) {
hal . rcout - > serial_end ( ) ;
serial_start_ms = 0 ;
}
if ( motors_disabled ) {
motors_disabled = false ;
SRV_Channels : : set_disabled_channel_mask ( 0 ) ;
}
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debug ( " Unlocked UART " ) ;
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uart - > lock_port ( 0 , 0 ) ;
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uart_locked = false ;
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}
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if ( initialised | | ( channel_mask . get ( ) = = 0 & & channel_auto . get ( ) = = 0 ) ) {
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if ( initialised & & run_test . get ( ) > 0 ) {
run_connection_test ( run_test . get ( ) - 1 ) ;
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}
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return ;
}
initialised = true ;
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run_test . set_and_notify ( 0 ) ;
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if ( last_control_port > 0 & & last_control_port ! = control_port ) {
gcs ( ) . install_alternative_protocol ( ( mavlink_channel_t ) ( MAVLINK_COMM_0 + last_control_port ) , nullptr ) ;
last_control_port = - 1 ;
}
if ( gcs ( ) . install_alternative_protocol ( ( mavlink_channel_t ) ( MAVLINK_COMM_0 + control_port ) ,
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FUNCTOR_BIND_MEMBER ( & AP_BLHeli : : protocol_handler ,
bool , uint8_t , AP_HAL : : UARTDriver * ) ) ) {
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debug ( " BLHeli installed on port %u " , ( unsigned ) control_port ) ;
last_control_port = control_port ;
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}
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uint16_t mask = uint16_t ( channel_mask . get ( ) ) ;
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/*
allow mode override - this makes it possible to use DShot for
rovers and subs , plus for quadplane fwd motors
*/
AP_HAL : : RCOutput : : output_mode mode = AP_HAL : : RCOutput : : MODE_PWM_NONE ;
switch ( AP_Motors : : pwm_type ( output_type . get ( ) ) ) {
case AP_Motors : : PWM_TYPE_ONESHOT :
mode = AP_HAL : : RCOutput : : MODE_PWM_ONESHOT ;
break ;
case AP_Motors : : PWM_TYPE_ONESHOT125 :
mode = AP_HAL : : RCOutput : : MODE_PWM_ONESHOT125 ;
break ;
case AP_Motors : : PWM_TYPE_BRUSHED :
mode = AP_HAL : : RCOutput : : MODE_PWM_BRUSHED ;
break ;
case AP_Motors : : PWM_TYPE_DSHOT150 :
mode = AP_HAL : : RCOutput : : MODE_PWM_DSHOT150 ;
break ;
case AP_Motors : : PWM_TYPE_DSHOT300 :
mode = AP_HAL : : RCOutput : : MODE_PWM_DSHOT300 ;
break ;
case AP_Motors : : PWM_TYPE_DSHOT600 :
mode = AP_HAL : : RCOutput : : MODE_PWM_DSHOT600 ;
break ;
case AP_Motors : : PWM_TYPE_DSHOT1200 :
mode = AP_HAL : : RCOutput : : MODE_PWM_DSHOT1200 ;
break ;
default :
break ;
}
if ( mask & & mode ! = AP_HAL : : RCOutput : : MODE_PWM_NONE ) {
hal . rcout - > set_output_mode ( mask , mode ) ;
}
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# if APM_BUILD_TYPE(APM_BUILD_ArduCopter) || APM_BUILD_TYPE(APM_BUILD_ArduPlane)
/*
plane and copter can use AP_Motors to get an automatic mask
*/
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if ( channel_auto . get ( ) = = 1 ) {
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AP_Motors * motors = AP_Motors : : get_singleton ( ) ;
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if ( motors ) {
mask | = motors - > get_motor_mask ( ) ;
}
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}
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# endif
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// tell SRV_Channels about ESC capabilities
SRV_Channels : : set_digital_mask ( mask ) ;
SRV_Channels : : set_reversible_mask ( uint16_t ( channel_reversible_mask . get ( ) ) & mask ) ;
hal . rcout - > set_reversible_mask ( channel_reversible_mask . get ( ) & mask ) ;
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// add motors from channel mask
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for ( uint8_t i = 0 ; i < 16 & & num_motors < max_motors ; i + + ) {
if ( mask & ( 1U < < i ) ) {
motor_map [ num_motors ] = i ;
num_motors + + ;
}
}
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motor_mask = mask ;
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debug ( " ESC: %u motors mask=0x%04x " , num_motors , mask ) ;
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if ( telem_rate > 0 ) {
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AP_SerialManager * serial_manager = AP_SerialManager : : get_singleton ( ) ;
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if ( serial_manager ) {
telem_uart = serial_manager - > find_serial ( AP_SerialManager : : SerialProtocol_ESCTelemetry , 0 ) ;
}
}
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}
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// get the most recent telemetry data packet for a motor
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bool AP_BLHeli : : get_telem_data ( uint8_t esc_index , struct telem_data & td )
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{
if ( esc_index > = max_motors ) {
return false ;
}
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if ( last_telem [ esc_index ] . timestamp_ms = = 0 ) {
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return false ;
}
td = last_telem [ esc_index ] ;
return true ;
}
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/*
implement the 8 bit CRC used by the BLHeli ESC telemetry protocol
*/
uint8_t AP_BLHeli : : telem_crc8 ( uint8_t crc , uint8_t crc_seed ) const
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{
uint8_t crc_u = crc ;
crc_u ^ = crc_seed ;
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for ( uint8_t i = 0 ; i < 8 ; i + + ) {
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crc_u = ( crc_u & 0x80 ) ? 0x7 ^ ( crc_u < < 1 ) : ( crc_u < < 1 ) ;
}
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return crc_u ;
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}
/*
read an ESC telemetry packet
*/
void AP_BLHeli : : read_telemetry_packet ( void )
{
uint8_t buf [ telem_packet_size ] ;
uint8_t crc = 0 ;
for ( uint8_t i = 0 ; i < telem_packet_size ; i + + ) {
int16_t v = telem_uart - > read ( ) ;
if ( v < 0 ) {
// short read, we should have 10 bytes ready when this function is called
return ;
}
buf [ i ] = uint8_t ( v ) ;
}
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// calculate crc
for ( uint8_t i = 0 ; i < telem_packet_size - 1 ; i + + ) {
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crc = telem_crc8 ( buf [ i ] , crc ) ;
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}
if ( buf [ telem_packet_size - 1 ] ! = crc ) {
// bad crc
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debug ( " Bad CRC on %u \n " , last_telem_esc ) ;
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return ;
}
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struct telem_data td ;
td . temperature = buf [ 0 ] ;
td . voltage = ( buf [ 1 ] < < 8 ) | buf [ 2 ] ;
td . current = ( buf [ 3 ] < < 8 ) | buf [ 4 ] ;
td . consumption = ( buf [ 5 ] < < 8 ) | buf [ 6 ] ;
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td . rpm = ( ( buf [ 7 ] < < 8 ) | buf [ 8 ] ) * motor_poles ;
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td . timestamp_ms = AP_HAL : : millis ( ) ;
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last_telem [ last_telem_esc ] = td ;
last_telem [ last_telem_esc ] . count + + ;
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AP_Logger * df = AP_Logger : : get_singleton ( ) ;
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if ( df & & df - > logging_enabled ( ) ) {
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df - > Write_ESC ( uint8_t ( last_telem_esc ) ,
AP_HAL : : micros64 ( ) ,
td . rpm * 100U ,
td . voltage ,
td . current ,
td . temperature * 100U ,
td . consumption ) ;
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}
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if ( debug_level > = 2 ) {
hal . console - > printf ( " ESC[%u] T=%u V=%u C=%u con=%u RPM=%u t=%u \n " ,
last_telem_esc ,
td . temperature ,
td . voltage ,
td . current ,
td . consumption ,
td . rpm , ( unsigned ) AP_HAL : : millis ( ) ) ;
}
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}
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/*
update BLHeli telemetry handling
This is called on push ( ) in SRV_Channels
*/
void AP_BLHeli : : update_telemetry ( void )
{
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if ( ! telem_uart ) {
return ;
}
uint32_t now = AP_HAL : : micros ( ) ;
uint32_t telem_rate_us = 1000000U / uint32_t ( telem_rate . get ( ) * num_motors ) ;
if ( telem_rate_us < 2000 ) {
// make sure we have a gap between frames
telem_rate_us = 2000 ;
}
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if ( ! telem_uart_started ) {
// we need to use begin() here to ensure the correct thread owns the uart
telem_uart - > begin ( 115200 ) ;
telem_uart_started = true ;
}
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uint32_t nbytes = telem_uart - > available ( ) ;
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if ( nbytes > telem_packet_size ) {
// if we have more than 10 bytes then we don't know which ESC
// they are from. Throw them all away
while ( nbytes - - ) {
telem_uart - > read ( ) ;
}
return ;
}
if ( nbytes > 0 & &
nbytes < telem_packet_size & &
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( last_telem_byte_read_us = = 0 | |
now - last_telem_byte_read_us < 1000 ) ) {
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// wait a bit longer, we don't have enough bytes yet
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if ( last_telem_byte_read_us = = 0 ) {
last_telem_byte_read_us = now ;
}
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return ;
}
if ( nbytes > 0 & & nbytes < telem_packet_size ) {
// we've waited long enough, discard bytes if we don't have 10 yet
while ( nbytes - - ) {
telem_uart - > read ( ) ;
}
return ;
}
if ( nbytes = = telem_packet_size ) {
// we have a full packet ready to parse
read_telemetry_packet ( ) ;
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last_telem_byte_read_us = 0 ;
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}
if ( now - last_telem_request_us > = telem_rate_us ) {
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// ask the next ESC for telemetry
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last_telem_esc = ( last_telem_esc + 1 ) % num_motors ;
uint16_t mask = 1U < < motor_map [ last_telem_esc ] ;
hal . rcout - > set_telem_request_mask ( mask ) ;
last_telem_request_us = now ;
}
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}
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/*
send ESC telemetry messages over MAVLink
*/
void AP_BLHeli : : send_esc_telemetry_mavlink ( uint8_t mav_chan )
{
if ( num_motors = = 0 ) {
return ;
}
uint8_t temperature [ 4 ] { } ;
uint16_t voltage [ 4 ] { } ;
uint16_t current [ 4 ] { } ;
uint16_t totalcurrent [ 4 ] { } ;
uint16_t rpm [ 4 ] { } ;
uint16_t count [ 4 ] { } ;
uint32_t now = AP_HAL : : millis ( ) ;
for ( uint8_t i = 0 ; i < num_motors ; i + + ) {
uint8_t idx = i % 4 ;
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if ( last_telem [ i ] . timestamp_ms & & ( now - last_telem [ i ] . timestamp_ms < 1000 ) ) {
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temperature [ idx ] = last_telem [ i ] . temperature ;
voltage [ idx ] = last_telem [ i ] . voltage ;
current [ idx ] = last_telem [ i ] . current ;
totalcurrent [ idx ] = last_telem [ i ] . consumption ;
rpm [ idx ] = last_telem [ i ] . rpm ;
count [ idx ] = last_telem [ i ] . count ;
} else {
temperature [ idx ] = 0 ;
voltage [ idx ] = 0 ;
current [ idx ] = 0 ;
totalcurrent [ idx ] = 0 ;
rpm [ idx ] = 0 ;
count [ idx ] = 0 ;
}
if ( i % 4 = = 3 | | i = = num_motors - 1 ) {
if ( ! HAVE_PAYLOAD_SPACE ( ( mavlink_channel_t ) mav_chan , ESC_TELEMETRY_1_TO_4 ) ) {
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return ;
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}
if ( i < 4 ) {
mavlink_msg_esc_telemetry_1_to_4_send ( ( mavlink_channel_t ) mav_chan , temperature , voltage , current , totalcurrent , rpm , count ) ;
} else {
mavlink_msg_esc_telemetry_5_to_8_send ( ( mavlink_channel_t ) mav_chan , temperature , voltage , current , totalcurrent , rpm , count ) ;
}
}
}
}
# endif // HAVE_AP_BLHELI_SUPPORT