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/*
* This file 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 file 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_HAL_ESP32/Scheduler.h"
# include "AP_HAL_ESP32/RCInput.h"
# include "AP_HAL_ESP32/AnalogIn.h"
# include "AP_Math/AP_Math.h"
# include "SdCard.h"
# include "Profile.h"
# include "freertos/FreeRTOS.h"
# include "freertos/task.h"
# include "soc/rtc_wdt.h"
# include "esp_int_wdt.h"
# include "esp_task_wdt.h"
# include <AP_HAL/AP_HAL.h>
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# include <AP_Scheduler/AP_Scheduler.h>
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# include <stdio.h>
//#define SCHEDULERDEBUG 1
using namespace ESP32 ;
extern const AP_HAL : : HAL & hal ;
bool Scheduler : : _initialized = true ;
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TaskHandle_t idle_0 = NULL ;
TaskHandle_t idle_1 = NULL ;
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Scheduler : : Scheduler ( )
{
_initialized = false ;
}
void disableCore0WDT ( )
{
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idle_0 = xTaskGetIdleTaskHandleForCPU ( 0 ) ;
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if ( idle_0 = = NULL | | esp_task_wdt_delete ( idle_0 ) ! = ESP_OK ) {
//print("Failed to remove Core 0 IDLE task from WDT");
}
}
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void disableCore1WDT ( )
{
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idle_1 = xTaskGetIdleTaskHandleForCPU ( 1 ) ;
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if ( idle_1 = = NULL | | esp_task_wdt_delete ( idle_1 ) ! = ESP_OK ) {
//print("Failed to remove Core 1 IDLE task from WDT");
}
}
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void enableCore0WDT ( )
{
if ( idle_0 ! = NULL & & esp_task_wdt_add ( idle_0 ) ! = ESP_OK ) {
//print("Failed to add Core 0 IDLE task to WDT");
}
}
void enableCore1WDT ( )
{
if ( idle_1 ! = NULL & & esp_task_wdt_add ( idle_1 ) ! = ESP_OK ) {
//print("Failed to add Core 1 IDLE task to WDT");
}
}
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void Scheduler : : init ( )
{
# ifdef SCHEDDEBUG
printf ( " %s:%d \n " , __PRETTY_FUNCTION__ , __LINE__ ) ;
# endif
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// disable wd while booting, as things like mounting the sd-card in the io thread can take a while, especially if there isn't hardware attached.
disableCore0WDT ( ) ; //FASTCPU
disableCore1WDT ( ) ; //SLOWCPU
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hal . console - > printf ( " %s:%d running with CONFIG_FREERTOS_HZ=%d \n " , __PRETTY_FUNCTION__ , __LINE__ , CONFIG_FREERTOS_HZ ) ;
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// keep main tasks that need speed on CPU 0
// pin potentially slow stuff to CPU 1, as we have disabled the WDT on that core.
# define FASTCPU 0
# define SLOWCPU 1
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// pin main thread to Core 0, and we'll also pin other heavy-tasks to core 1, like wifi-related.
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if ( xTaskCreatePinnedToCore ( _main_thread , " APM_MAIN " , Scheduler : : MAIN_SS , this , Scheduler : : MAIN_PRIO , & _main_task_handle , FASTCPU ) ! = pdPASS ) {
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//if (xTaskCreate(_main_thread, "APM_MAIN", Scheduler::MAIN_SS, this, Scheduler::MAIN_PRIO, &_main_task_handle) != pdPASS) {
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hal . console - > printf ( " FAILED to create task _main_thread on FASTCPU \n " ) ;
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} else {
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hal . console - > printf ( " OK created task _main_thread on FASTCPU \n " ) ;
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}
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if ( xTaskCreatePinnedToCore ( _timer_thread , " APM_TIMER " , TIMER_SS , this , TIMER_PRIO , & _timer_task_handle , FASTCPU ) ! = pdPASS ) {
hal . console - > printf ( " FAILED to create task _timer_thread on FASTCPU \n " ) ;
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} else {
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hal . console - > printf ( " OK created task _timer_thread on FASTCPU \n " ) ;
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}
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if ( xTaskCreatePinnedToCore ( _rcout_thread , " APM_RCOUT " , RCOUT_SS , this , RCOUT_PRIO , & _rcout_task_handle , SLOWCPU ) ! = pdPASS ) {
hal . console - > printf ( " FAILED to create task _rcout_thread on SLOWCPU \n " ) ;
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} else {
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hal . console - > printf ( " OK created task _rcout_thread on SLOWCPU \n " ) ;
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}
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if ( xTaskCreatePinnedToCore ( _rcin_thread , " APM_RCIN " , RCIN_SS , this , RCIN_PRIO , & _rcin_task_handle , SLOWCPU ) ! = pdPASS ) {
hal . console - > printf ( " FAILED to create task _rcin_thread on SLOWCPU \n " ) ;
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} else {
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hal . console - > printf ( " OK created task _rcin_thread on SLOWCPU \n " ) ;
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}
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// pin this thread to Core 1 as it keeps all teh uart/s feed data, and we need that quick.
if ( xTaskCreatePinnedToCore ( _uart_thread , " APM_UART " , UART_SS , this , UART_PRIO , & _uart_task_handle , FASTCPU ) ! = pdPASS ) {
hal . console - > printf ( " FAILED to create task _uart_thread on FASTCPU \n " ) ;
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} else {
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hal . console - > printf ( " OK created task _uart_thread on FASTCPU \n " ) ;
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}
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// we put thos on the SLOW core as it mounts the sd card, and that often isn't conencted.
if ( xTaskCreatePinnedToCore ( _io_thread , " SchedulerIO:APM_IO " , IO_SS , this , IO_PRIO , & _io_task_handle , SLOWCPU ) ! = pdPASS ) {
hal . console - > printf ( " FAILED to create task _io_thread on SLOWCPU \n " ) ;
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} else {
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hal . console - > printf ( " OK created task _io_thread on SLOWCPU \n " ) ;
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}
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if ( xTaskCreatePinnedToCore ( _storage_thread , " APM_STORAGE " , STORAGE_SS , this , STORAGE_PRIO , & _storage_task_handle , SLOWCPU ) ! = pdPASS ) { //no actual flash writes without this, storage kinda appears to work, but does an erase on every boot and params don't persist over reset etc.
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hal . console - > printf ( " FAILED to create task _storage_thread \n " ) ;
} else {
hal . console - > printf ( " OK created task _storage_thread \n " ) ;
}
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// xTaskCreatePinnedToCore(_print_profile, "APM_PROFILE", IO_SS, this, IO_PRIO, nullptr,SLOWCPU);
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hal . console - > printf ( " OK Sched Init, enabling WD \n " ) ;
enableCore0WDT ( ) ; //FASTCPU
//enableCore1WDT(); //we don't enable WD on SLOWCPU right now.
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}
template < typename T >
void executor ( T oui )
{
oui ( ) ;
}
void Scheduler : : thread_create_trampoline ( void * ctx )
{
AP_HAL : : MemberProc * t = ( AP_HAL : : MemberProc * ) ctx ;
( * t ) ( ) ;
free ( t ) ;
}
/*
create a new thread
*/
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bool Scheduler : : thread_create ( AP_HAL : : MemberProc proc , const char * name , uint32_t requested_stack_size , priority_base base , int8_t priority )
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{
# ifdef SCHEDDEBUG
printf ( " %s:%d \n " , __PRETTY_FUNCTION__ , __LINE__ ) ;
# endif
// take a copy of the MemberProc, it is freed after thread exits
AP_HAL : : MemberProc * tproc = ( AP_HAL : : MemberProc * ) calloc ( 1 , sizeof ( proc ) ) ;
if ( ! tproc ) {
return false ;
}
* tproc = proc ;
uint8_t thread_priority = IO_PRIO ;
static const struct {
priority_base base ;
uint8_t p ;
} priority_map [ ] = {
{ PRIORITY_BOOST , IO_PRIO } ,
{ PRIORITY_MAIN , MAIN_PRIO } ,
{ PRIORITY_SPI , SPI_PRIORITY } ,
{ PRIORITY_I2C , I2C_PRIORITY } ,
{ PRIORITY_CAN , IO_PRIO } ,
{ PRIORITY_TIMER , TIMER_PRIO } ,
{ PRIORITY_RCIN , RCIN_PRIO } ,
{ PRIORITY_IO , IO_PRIO } ,
{ PRIORITY_UART , UART_PRIO } ,
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{ PRIORITY_NET , WIFI_PRIO1 } ,
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{ PRIORITY_STORAGE , STORAGE_PRIO } ,
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{ PRIORITY_SCRIPTING , UART_PRIO } ,
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} ;
for ( uint8_t i = 0 ; i < ARRAY_SIZE ( priority_map ) ; i + + ) {
if ( priority_map [ i ] . base = = base ) {
# ifdef SCHEDDEBUG
printf ( " %s:%d \n " , __PRETTY_FUNCTION__ , __LINE__ ) ;
# endif
thread_priority = constrain_int16 ( priority_map [ i ] . p + priority , 1 , 25 ) ;
break ;
}
}
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// chibios has a 'thread working area', we just another 1k.
# define EXTRA_THREAD_SPACE 1024
uint32_t actual_stack_size = requested_stack_size + EXTRA_THREAD_SPACE ;
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tskTaskControlBlock * xhandle ;
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BaseType_t xReturned = xTaskCreate ( thread_create_trampoline , name , actual_stack_size , tproc , thread_priority , & xhandle ) ;
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if ( xReturned ! = pdPASS ) {
free ( tproc ) ;
return false ;
}
return true ;
}
void Scheduler : : delay ( uint16_t ms )
{
uint64_t start = AP_HAL : : micros64 ( ) ;
while ( ( AP_HAL : : micros64 ( ) - start ) / 1000 < ms ) {
delay_microseconds ( 1000 ) ;
if ( _min_delay_cb_ms < = ms ) {
if ( in_main_thread ( ) ) {
call_delay_cb ( ) ;
}
}
}
}
void Scheduler : : delay_microseconds ( uint16_t us )
{
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if ( in_main_thread ( ) & & us < 100 ) {
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ets_delay_us ( us ) ;
} else { // Minimum delay for FreeRTOS is 1ms
uint32_t tick = portTICK_PERIOD_MS * 1000 ;
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vTaskDelay ( ( us + tick - 1 ) / tick ) ;
}
}
void Scheduler : : register_timer_process ( AP_HAL : : MemberProc proc )
{
# ifdef SCHEDDEBUG
printf ( " %s:%d \n " , __PRETTY_FUNCTION__ , __LINE__ ) ;
# endif
for ( uint8_t i = 0 ; i < _num_timer_procs ; i + + ) {
if ( _timer_proc [ i ] = = proc ) {
return ;
}
}
if ( _num_timer_procs > = ESP32_SCHEDULER_MAX_TIMER_PROCS ) {
printf ( " Out of timer processes \n " ) ;
return ;
}
_timer_sem . take_blocking ( ) ;
_timer_proc [ _num_timer_procs ] = proc ;
_num_timer_procs + + ;
_timer_sem . give ( ) ;
}
void Scheduler : : register_io_process ( AP_HAL : : MemberProc proc )
{
# ifdef SCHEDDEBUG
printf ( " %s:%d \n " , __PRETTY_FUNCTION__ , __LINE__ ) ;
# endif
_io_sem . take_blocking ( ) ;
for ( uint8_t i = 0 ; i < _num_io_procs ; i + + ) {
if ( _io_proc [ i ] = = proc ) {
_io_sem . give ( ) ;
return ;
}
}
if ( _num_io_procs < ESP32_SCHEDULER_MAX_IO_PROCS ) {
_io_proc [ _num_io_procs ] = proc ;
_num_io_procs + + ;
} else {
printf ( " Out of IO processes \n " ) ;
}
_io_sem . give ( ) ;
}
void Scheduler : : register_timer_failsafe ( AP_HAL : : Proc failsafe , uint32_t period_us )
{
_failsafe = failsafe ;
}
void Scheduler : : reboot ( bool hold_in_bootloader )
{
printf ( " Restarting now... \n " ) ;
hal . rcout - > force_safety_on ( ) ;
unmount_sdcard ( ) ;
esp_restart ( ) ;
}
bool Scheduler : : in_main_thread ( ) const
{
return _main_task_handle = = xTaskGetCurrentTaskHandle ( ) ;
}
void Scheduler : : set_system_initialized ( )
{
# ifdef SCHEDDEBUG
printf ( " %s:%d \n " , __PRETTY_FUNCTION__ , __LINE__ ) ;
# endif
if ( _initialized ) {
AP_HAL : : panic ( " PANIC: scheduler::system_initialized called more than once " ) ;
}
_initialized = true ;
}
bool Scheduler : : is_system_initialized ( )
{
return _initialized ;
}
void Scheduler : : _timer_thread ( void * arg )
{
# ifdef SCHEDDEBUG
printf ( " %s:%d start \n " , __PRETTY_FUNCTION__ , __LINE__ ) ;
# endif
Scheduler * sched = ( Scheduler * ) arg ;
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# if HAL_INS_DEFAULT != HAL_INS_NONE
// wait to ensure INS system inits unless using HAL_INS_NONE
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while ( ! _initialized ) {
sched - > delay_microseconds ( 1000 ) ;
}
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# endif
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# ifdef SCHEDDEBUG
printf ( " %s:%d initialised \n " , __PRETTY_FUNCTION__ , __LINE__ ) ;
# endif
while ( true ) {
sched - > delay_microseconds ( 1000 ) ;
sched - > _run_timers ( ) ;
//analog in
# ifndef HAL_DISABLE_ADC_DRIVER
( ( AnalogIn * ) hal . analogin ) - > _timer_tick ( ) ;
# endif
}
}
void Scheduler : : _rcout_thread ( void * arg )
{
Scheduler * sched = ( Scheduler * ) arg ;
while ( ! _initialized ) {
sched - > delay_microseconds ( 1000 ) ;
}
while ( true ) {
sched - > delay_microseconds ( 4000 ) ;
// process any pending RC output requests
hal . rcout - > timer_tick ( ) ;
}
}
void Scheduler : : _run_timers ( )
{
# ifdef SCHEDULERDEBUG
printf ( " %s:%d start \n " , __PRETTY_FUNCTION__ , __LINE__ ) ;
# endif
if ( _in_timer_proc ) {
return ;
}
# ifdef SCHEDULERDEBUG
printf ( " %s:%d _in_timer_proc \n " , __PRETTY_FUNCTION__ , __LINE__ ) ;
# endif
_in_timer_proc = true ;
int num_procs = 0 ;
_timer_sem . take_blocking ( ) ;
num_procs = _num_timer_procs ;
_timer_sem . give ( ) ;
// now call the timer based drivers
for ( int i = 0 ; i < num_procs ; i + + ) {
if ( _timer_proc [ i ] ) {
_timer_proc [ i ] ( ) ;
}
}
// and the failsafe, if one is setup
if ( _failsafe ! = nullptr ) {
_failsafe ( ) ;
}
_in_timer_proc = false ;
}
void Scheduler : : _rcin_thread ( void * arg )
{
Scheduler * sched = ( Scheduler * ) arg ;
while ( ! _initialized ) {
sched - > delay_microseconds ( 20000 ) ;
}
hal . rcin - > init ( ) ;
while ( true ) {
sched - > delay_microseconds ( 1000 ) ;
( ( RCInput * ) hal . rcin ) - > _timer_tick ( ) ;
}
}
void Scheduler : : _run_io ( void )
{
# ifdef SCHEDULERDEBUG
printf ( " %s:%d start \n " , __PRETTY_FUNCTION__ , __LINE__ ) ;
# endif
if ( _in_io_proc ) {
return ;
}
# ifdef SCHEDULERDEBUG
printf ( " %s:%d initialised \n " , __PRETTY_FUNCTION__ , __LINE__ ) ;
# endif
_in_io_proc = true ;
int num_procs = 0 ;
_io_sem . take_blocking ( ) ;
num_procs = _num_io_procs ;
_io_sem . give ( ) ;
// now call the IO based drivers
for ( int i = 0 ; i < num_procs ; i + + ) {
if ( _io_proc [ i ] ) {
_io_proc [ i ] ( ) ;
}
}
_in_io_proc = false ;
}
void Scheduler : : _io_thread ( void * arg )
{
# ifdef SCHEDDEBUG
printf ( " %s:%d start \n " , __PRETTY_FUNCTION__ , __LINE__ ) ;
# endif
mount_sdcard ( ) ;
Scheduler * sched = ( Scheduler * ) arg ;
while ( ! sched - > _initialized ) {
sched - > delay_microseconds ( 1000 ) ;
}
# ifdef SCHEDDEBUG
printf ( " %s:%d initialised \n " , __PRETTY_FUNCTION__ , __LINE__ ) ;
# endif
uint32_t last_sd_start_ms = AP_HAL : : millis ( ) ;
while ( true ) {
sched - > delay_microseconds ( 1000 ) ;
// run registered IO processes
sched - > _run_io ( ) ;
if ( ! hal . util - > get_soft_armed ( ) ) {
// if sdcard hasn't mounted then retry it every 3s in the IO
// thread when disarmed
uint32_t now = AP_HAL : : millis ( ) ;
if ( now - last_sd_start_ms > 3000 ) {
last_sd_start_ms = now ;
sdcard_retry ( ) ;
}
}
}
}
void Scheduler : : _storage_thread ( void * arg )
{
# ifdef SCHEDDEBUG
printf ( " %s:%d start \n " , __PRETTY_FUNCTION__ , __LINE__ ) ;
# endif
Scheduler * sched = ( Scheduler * ) arg ;
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while ( ! sched - > _initialized ) {
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sched - > delay_microseconds ( 10000 ) ;
}
# ifdef SCHEDDEBUG
printf ( " %s:%d initialised \n " , __PRETTY_FUNCTION__ , __LINE__ ) ;
# endif
while ( true ) {
sched - > delay_microseconds ( 1000 ) ;
// process any pending storage writes
hal . storage - > _timer_tick ( ) ;
//print_profile();
}
}
void Scheduler : : _print_profile ( void * arg )
{
Scheduler * sched = ( Scheduler * ) arg ;
while ( ! sched - > _initialized ) {
sched - > delay_microseconds ( 10000 ) ;
}
while ( true ) {
sched - > delay ( 10000 ) ;
print_profile ( ) ;
}
}
void Scheduler : : _uart_thread ( void * arg )
{
# ifdef SCHEDDEBUG
printf ( " %s:%d start \n " , __PRETTY_FUNCTION__ , __LINE__ ) ;
# endif
Scheduler * sched = ( Scheduler * ) arg ;
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while ( ! sched - > _initialized ) {
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sched - > delay_microseconds ( 2000 ) ;
}
# ifdef SCHEDDEBUG
printf ( " %s:%d initialised \n " , __PRETTY_FUNCTION__ , __LINE__ ) ;
# endif
while ( true ) {
sched - > delay_microseconds ( 1000 ) ;
for ( uint8_t i = 0 ; i < hal . num_serial ; i + + ) {
hal . serial ( i ) - > _timer_tick ( ) ;
}
hal . console - > _timer_tick ( ) ;
}
}
// get the active main loop rate
uint16_t Scheduler : : get_loop_rate_hz ( void )
{
if ( _active_loop_rate_hz = = 0 ) {
_active_loop_rate_hz = _loop_rate_hz ;
}
return _active_loop_rate_hz ;
}
// once every 60 seconds, print some stats...
void Scheduler : : print_stats ( void )
{
static int64_t last_run = 0 ;
if ( AP_HAL : : millis64 ( ) - last_run > 60000 ) {
char buffer [ 1024 ] ;
vTaskGetRunTimeStats ( buffer ) ;
printf ( " \n \n %s \n " , buffer ) ;
heap_caps_print_heap_info ( 0 ) ;
last_run = AP_HAL : : millis64 ( ) ;
}
// printf("loop_rate_hz: %d",get_loop_rate_hz());
}
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// Run every 10s
void Scheduler : : print_main_loop_rate ( void )
{
static int64_t last_run = 0 ;
if ( AP_HAL : : millis64 ( ) - last_run > 10000 ) {
last_run = AP_HAL : : millis64 ( ) ;
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// null pointer in here...
//const float actual_loop_rate = AP::scheduler().get_filtered_loop_rate_hz();
//const uint16_t expected_loop_rate = AP::scheduler().get_loop_rate_hz();
//hal.console->printf("loop_rate: actual: %uHz, expected: %uHz\n",
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}
}
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void IRAM_ATTR Scheduler : : _main_thread ( void * arg )
{
# ifdef SCHEDDEBUG
printf ( " %s:%d start \n " , __PRETTY_FUNCTION__ , __LINE__ ) ;
# endif
Scheduler * sched = ( Scheduler * ) arg ;
# ifndef HAL_DISABLE_ADC_DRIVER
hal . analogin - > init ( ) ;
# endif
hal . rcout - > init ( ) ;
sched - > callbacks - > setup ( ) ;
sched - > set_system_initialized ( ) ;
# ifdef SCHEDDEBUG
printf ( " %s:%d initialised \n " , __PRETTY_FUNCTION__ , __LINE__ ) ;
# endif
while ( true ) {
sched - > callbacks - > loop ( ) ;
sched - > delay_microseconds ( 250 ) ;
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// run stats periodically
sched - > print_stats ( ) ;
sched - > print_main_loop_rate ( ) ;
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}
}