mirror of https://github.com/ArduPilot/ardupilot
437 lines
17 KiB
C++
437 lines
17 KiB
C++
/*
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* This file is free software: you can redistribute it and/or modify it
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* under the terms of the GNU General Public License as published by the
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* Free Software Foundation, either version 3 of the License, or
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* (at your option) any later version.
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*
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* This file is distributed in the hope that it will be useful, but
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* WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
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* See the GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License along
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* with this program. If not, see <http://www.gnu.org/licenses/>.
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*
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* Code by Andy Piper and Siddharth Bharat Purohit
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*
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* There really is no dshot reference. For information try these resources:
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* https://blck.mn/2016/11/dshot-the-new-kid-on-the-block/
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* https://www.swallenhardware.io/battlebots/2019/4/20/a-developers-guide-to-dshot-escs
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*/
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#include <hal.h>
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#if defined(IOMCU_FW) && HAL_DSHOT_ENABLED
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// need to give the little guy as much help as possible
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#pragma GCC optimize("O2")
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#include "RCOutput.h"
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#include <AP_Math/AP_Math.h>
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#include "GPIO.h"
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#include "Scheduler.h"
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#if HAL_USE_PWM == TRUE
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using namespace ChibiOS;
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extern const AP_HAL::HAL& hal;
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#ifdef HAL_WITH_BIDIR_DSHOT
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THD_WORKING_AREA(dshot_thread_wa, 512);
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#else
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THD_WORKING_AREA(dshot_thread_wa, 64);
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#endif
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static const char* rcout_thread_name = "rcout";
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void RCOutput::timer_tick()
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{
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if (dshot_timer_setup) {
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return;
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}
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uint32_t dshot_mask;
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if (is_dshot_protocol(get_output_mode(dshot_mask))) {
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chThdCreateStatic(dshot_thread_wa, sizeof(dshot_thread_wa),
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APM_RCOUT_PRIORITY, &RCOutput::dshot_send_trampoline, this);
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dshot_timer_setup = true;
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}
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}
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void RCOutput::dshot_send_trampoline(void *p)
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{
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RCOutput *rcout = (RCOutput *)p;
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rcout->rcout_thread();
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}
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/*
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thread for handling RCOutput send on IOMCU
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*/
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void RCOutput::rcout_thread() {
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// don't start outputting until fully configured
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while (!hal.scheduler->is_system_initialized()) {
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hal.scheduler->delay_microseconds(1000);
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}
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rcout_thread_ctx = chThdGetSelfX();
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chRegSetThreadNameX(rcout_thread_ctx, rcout_thread_name);
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uint64_t last_cycle_run_us = 0;
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while (true) {
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chEvtWaitOne(EVT_PWM_SEND | EVT_PWM_SYNTHETIC_SEND);
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// start the clock
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const uint64_t last_thread_run_us = AP_HAL::micros64();
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// this is when the cycle is supposed to start
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if (_dshot_cycle == 0) {
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last_cycle_run_us = AP_HAL::micros64();
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// register a timer for the next tick if push() will not be providing it
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if (_dshot_rate != 1) {
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chVTSet(&_dshot_rate_timer, chTimeUS2I(_dshot_period_us), dshot_update_tick, this);
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}
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}
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// if DMA sharing is in effect there can be quite a delay between the request to begin the cycle and
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// actually sending out data - thus we need to work out how much time we have left to collect the locks
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uint64_t time_out_us = (_dshot_cycle + 1) * _dshot_period_us + last_cycle_run_us;
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if (!_dshot_rate) {
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time_out_us = last_thread_run_us + _dshot_period_us;
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}
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// DMA channel sharing on F10x is complicated. The allocations are
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// TIM2_UP - (1,2)
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// TIM4_UP - (1,7)
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// TIM3_UP - (1,3)
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// TIM2_CH2 - (1,7) - F103 only
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// TIM4_CH3 - (1,5) - F103 only
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// TIM3_CH4 - (1,3) - F103 only
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// and (1,7) is also shared with USART2_TX
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// locks have to be unlocked in reverse order, and shared CH locks do not need to be taken so the
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// ordering that will work follows. This relies on recursive lock behaviour that allows us to relock
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// a mutex without releasing it first:
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// TIM4_UP - lock (shared)
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// TIM4 - dshot send
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// TIM4_CH3 - lock
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// TIM2_UP - lock
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// TIM2_CH2 - lock recursive (shared)
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// TIM2 - dshot send
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// TIM3_UP - lock
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// [TIM3_CH4 - shared lock]
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// TIM3 - dshot send
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// [TIM3_CH4 - shared unlock]
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// TIM3_UP - unlock
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// TIM2_CH2 - unlock recursive (shared)
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// TIM2_UP - unlock
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// TIM4_CH3 - unlock
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// TIM4_UP - unlock
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dshot_send_groups(time_out_us);
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#if AP_HAL_SHARED_DMA_ENABLED
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dshot_collect_dma_locks(time_out_us);
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#endif
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if (_dshot_rate > 0) {
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_dshot_cycle = (_dshot_cycle + 1) % _dshot_rate;
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}
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}
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}
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#if defined(STM32F1)
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void RCOutput::bdshot_disable_pwm_f1(pwm_group& group)
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{
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stm32_tim_t* TIMx = group.pwm_drv->tim;
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// pwmStop sets these
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TIMx->CR1 = 0; /* Timer disabled. */
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TIMx->DIER = 0; /* All IRQs disabled. */
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TIMx->SR = 0; /* Clear eventual pending IRQs. */
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TIMx->CNT = 0;
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TIMx->CCR[0] = 0; /* Comparator 1 disabled. */
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TIMx->CCR[1] = 0; /* Comparator 2 disabled. */
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TIMx->CCR[2] = 0; /* Comparator 3 disabled. */
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TIMx->CCR[3] = 0; /* Comparator 4 disabled. */
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}
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#endif
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#if defined(HAL_WITH_BIDIR_DSHOT) && defined(STM32F1)
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// reset pwm driver to output mode without resetting the clock or the peripheral
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// the code here is the equivalent of pwmStart()/pwmStop()
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void RCOutput::bdshot_reset_pwm_f1(pwm_group& group, uint8_t telem_channel)
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{
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osalSysLock();
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stm32_tim_t* TIMx = group.pwm_drv->tim;
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bdshot_disable_pwm_f1(group);
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// at the point this is called we will have done input capture on two CC channels
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// we need to switch those channels back to output and the default settings
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// all other channels will not have been modified
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switch (group.bdshot.telem_tim_ch[telem_channel]) {
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case 0: // CC1
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case 1: // CC2
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MODIFY_REG(TIMx->CCER, TIM_CCER_CC2E | TIM_CCER_CC1E, 0); // disable CC so that it can be modified
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MODIFY_REG(TIMx->CCMR1, (TIM_CCMR1_CC1S | TIM_CCMR1_IC1F | TIM_CCMR1_IC1PSC),
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STM32_TIM_CCMR1_OC1M(6) | STM32_TIM_CCMR1_OC1PE);
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MODIFY_REG(TIMx->CCMR1, (TIM_CCMR1_CC2S | TIM_CCMR1_IC2F | TIM_CCMR1_IC2PSC),
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STM32_TIM_CCMR1_OC2M(6) | STM32_TIM_CCMR1_OC2PE);
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MODIFY_REG(TIMx->CCER, (TIM_CCER_CC1P | TIM_CCER_CC2P),
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(TIM_CCER_CC1P | TIM_CCER_CC2P | TIM_CCER_CC1E | TIM_CCER_CC2E));
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break;
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case 2: // CC3
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case 3: // CC4
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MODIFY_REG(TIMx->CCER, TIM_CCER_CC3E | TIM_CCER_CC4E, 0); // disable CC so that it can be modified
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MODIFY_REG(TIMx->CCMR2, (TIM_CCMR2_CC3S | TIM_CCMR2_IC3F | TIM_CCMR2_IC3PSC),
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STM32_TIM_CCMR2_OC3M(6) | STM32_TIM_CCMR2_OC3PE);
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MODIFY_REG(TIMx->CCMR2, (TIM_CCMR2_CC4S | TIM_CCMR2_IC4F | TIM_CCMR2_IC4PSC),
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STM32_TIM_CCMR2_OC4M(6) | STM32_TIM_CCMR2_OC4PE);
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MODIFY_REG(TIMx->CCER, (TIM_CCER_CC3P | TIM_CCER_CC4P),
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(TIM_CCER_CC3P | TIM_CCER_CC4P | TIM_CCER_CC3E | TIM_CCER_CC4E));
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break;
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default:
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break;
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}
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// pwmStart sets these
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uint32_t psc = (group.pwm_drv->clock / group.pwm_drv->config->frequency) - 1;
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TIMx->PSC = psc;
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TIMx->ARR = group.pwm_drv->period - 1;
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TIMx->CR2 = group.pwm_drv->config->cr2;
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TIMx->EGR = STM32_TIM_EGR_UG; /* Update event. */
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TIMx->SR = 0; /* Clear pending IRQs. */
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TIMx->DIER = group.pwm_drv->config->dier & /* DMA-related DIER settings. */
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~STM32_TIM_DIER_IRQ_MASK;
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if (group.pwm_drv->has_bdtr) {
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TIMx->BDTR = group.pwm_drv->config->bdtr | STM32_TIM_BDTR_MOE;
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}
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// we need to switch every output on the same input channel to avoid
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// spurious line changes
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for (uint8_t i = 0; i<4; i++) {
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if (group.chan[i] == CHAN_DISABLED) {
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continue;
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}
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if (group.bdshot.telem_tim_ch[telem_channel] == group.bdshot.telem_tim_ch[i]) {
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palSetLineMode(group.pal_lines[i], PAL_MODE_STM32_ALTERNATE_PUSHPULL);
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}
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}
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/* Timer configured and started.*/
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TIMx->CR1 = STM32_TIM_CR1_ARPE | STM32_TIM_CR1_URS | STM32_TIM_CR1_CEN;
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osalSysUnlock();
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}
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// see https://github.com/betaflight/betaflight/pull/8554#issuecomment-512507625
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// called from the interrupt
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void RCOutput::bdshot_receive_pulses_DMAR_f1(pwm_group* group)
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{
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// make sure the transaction finishes or times out, this function takes a little time to run so the most
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// accurate timing is from the beginning. the pulse time is slightly longer than we need so an extra 10U
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// should be plenty
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chVTSetI(&group->dma_timeout, chTimeUS2I(group->dshot_pulse_send_time_us + 30U + 10U),
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bdshot_finish_dshot_gcr_transaction, group);
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group->pwm_drv->tim->CR1 = 0;
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// Configure Timer
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group->pwm_drv->tim->SR = 0;
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// do NOT set CCER to 0 here - this pulls the line low on F103 (at least)
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// and since we are already doing bdshot the relevant options that are set for output
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// also apply to input and bdshot_config_icu_dshot() will disable any channels that need
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// disabling
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group->pwm_drv->tim->DIER = 0;
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group->pwm_drv->tim->CR2 = 0;
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group->pwm_drv->tim->PSC = group->bdshot.telempsc;
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group->dshot_state = DshotState::RECV_START;
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//TOGGLE_PIN_CH_DEBUG(54, curr_ch);
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group->pwm_drv->tim->ARR = 0xFFFF; // count forever
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group->pwm_drv->tim->CNT = 0;
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uint8_t curr_ch = group->bdshot.curr_telem_chan;
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// we need to switch every input on the same input channel to allow
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// the ESCs to drive the lines
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for (uint8_t i = 0; i<4; i++) {
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if (group->chan[i] == CHAN_DISABLED) {
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continue;
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}
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if (group->bdshot.telem_tim_ch[curr_ch] == group->bdshot.telem_tim_ch[i]) {
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palSetLineMode(group->pal_lines[i], PAL_MODE_INPUT_PULLUP);
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}
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}
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// Initialise ICU channels
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bdshot_config_icu_dshot_f1(group->pwm_drv->tim, curr_ch, group->bdshot.telem_tim_ch[curr_ch]);
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const stm32_dma_stream_t *ic_dma =
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group->has_shared_ic_up_dma() ? group->dma : group->bdshot.ic_dma[curr_ch];
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// Configure DMA
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dmaStreamSetPeripheral(ic_dma, &(group->pwm_drv->tim->DMAR));
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dmaStreamSetMemory0(ic_dma, group->dma_buffer);
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dmaStreamSetTransactionSize(ic_dma, GCR_TELEMETRY_BIT_LEN);
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dmaStreamSetMode(ic_dma,
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STM32_DMA_CR_CHSEL(group->dma_ch[curr_ch].channel) |
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STM32_DMA_CR_DIR_P2M |
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STM32_DMA_CR_PSIZE_HWORD |
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STM32_DMA_CR_MSIZE_HWORD |
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STM32_DMA_CR_MINC | STM32_DMA_CR_PL(3) |
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STM32_DMA_CR_TEIE | STM32_DMA_CR_TCIE);
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// setup for transfers. 0x0D is the register
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// address offset of the CCR registers in the timer peripheral
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uint8_t telem_ch_pair = group->bdshot.telem_tim_ch[curr_ch] & ~1U; // round to the lowest of the channel pair
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const uint8_t ccr_ofs = offsetof(stm32_tim_t, CCR)/4 + telem_ch_pair;
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group->pwm_drv->tim->DCR = STM32_TIM_DCR_DBA(ccr_ofs) | STM32_TIM_DCR_DBL(1); // read two registers at a time
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// Start Timer
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group->pwm_drv->tim->EGR |= STM32_TIM_EGR_UG;
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group->pwm_drv->tim->SR = 0;
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group->pwm_drv->tim->CR1 = TIM_CR1_ARPE | STM32_TIM_CR1_URS | STM32_TIM_CR1_UDIS | STM32_TIM_CR1_CEN;
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dmaStreamEnable(ic_dma);
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}
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void RCOutput::bdshot_config_icu_dshot_f1(stm32_tim_t* TIMx, uint8_t chan, uint8_t ccr_ch)
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{
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// F103 does not support both edges input capture so we need to set up two channels
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// both pointing at the same input to capture the data. The triggered channel
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// needs to handle the second edge - so rising or falling - so that we get an
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// even number of half-words in the DMA buffer
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switch(ccr_ch) {
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case 0:
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case 1: {
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// Disable the IC1 and IC2: Reset the CCxE Bit
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MODIFY_REG(TIMx->CCER, TIM_CCER_CC1E | TIM_CCER_CC2E, 0);
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// Select the Input and set the filter and the prescaler value
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if (chan == 0) { // TI1
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MODIFY_REG(TIMx->CCMR1,
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(TIM_CCMR1_CC1S | TIM_CCMR1_IC1F | TIM_CCMR1_IC1PSC),
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(TIM_CCMR1_CC1S_0 | TIM_CCMR1_IC1F_1));// 4 samples per output transition
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MODIFY_REG(TIMx->CCMR1,
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(TIM_CCMR1_CC2S | TIM_CCMR1_IC2F | TIM_CCMR1_IC2PSC),
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(TIM_CCMR1_CC2S_1 | TIM_CCMR1_IC2F_1));
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} else { // TI2
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MODIFY_REG(TIMx->CCMR1,
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(TIM_CCMR1_CC1S | TIM_CCMR1_IC1F | TIM_CCMR1_IC1PSC),
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(TIM_CCMR1_CC1S_1 | TIM_CCMR1_IC1F_1));
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MODIFY_REG(TIMx->CCMR1,
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(TIM_CCMR1_CC2S | TIM_CCMR1_IC2F | TIM_CCMR1_IC2PSC),
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(TIM_CCMR1_CC2S_0 | TIM_CCMR1_IC2F_1));
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}
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if (ccr_ch == 0) {
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// Select the Polarity as falling on IC2 and rising on IC1
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MODIFY_REG(TIMx->CCER, TIM_CCER_CC1P | TIM_CCER_CC2P, TIM_CCER_CC2P | TIM_CCER_CC1E | TIM_CCER_CC2E);
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MODIFY_REG(TIMx->DIER, TIM_DIER_CC1DE | TIM_DIER_CC2DE, TIM_DIER_CC1DE);
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} else {
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// Select the Polarity as falling on IC1 and rising on IC2
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MODIFY_REG(TIMx->CCER, TIM_CCER_CC1P | TIM_CCER_CC2P, TIM_CCER_CC1P | TIM_CCER_CC1E | TIM_CCER_CC2E);
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MODIFY_REG(TIMx->DIER, TIM_DIER_CC1DE | TIM_DIER_CC2DE, TIM_DIER_CC2DE);
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}
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break;
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}
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case 2:
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case 3: {
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MODIFY_REG(TIMx->CCER, TIM_CCER_CC3E | TIM_CCER_CC4E, 0);
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// Select the Input and set the filter and the prescaler value
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if (chan == 2) { // TI3
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MODIFY_REG(TIMx->CCMR2,
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(TIM_CCMR2_CC3S | TIM_CCMR2_IC3F | TIM_CCMR2_IC3PSC),
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(TIM_CCMR2_CC3S_0 | TIM_CCMR2_IC3F_1));
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MODIFY_REG(TIMx->CCMR2,
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(TIM_CCMR2_CC4S | TIM_CCMR2_IC4F | TIM_CCMR2_IC4PSC),
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(TIM_CCMR2_CC4S_1 | TIM_CCMR2_IC4F_1));
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} else { // TI4
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MODIFY_REG(TIMx->CCMR2,
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(TIM_CCMR2_CC3S | TIM_CCMR2_IC3F | TIM_CCMR2_IC3PSC),
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(TIM_CCMR2_CC3S_1 | TIM_CCMR2_IC3F_1));
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MODIFY_REG(TIMx->CCMR2,
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(TIM_CCMR2_CC4S | TIM_CCMR2_IC4F | TIM_CCMR2_IC4PSC),
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(TIM_CCMR2_CC4S_0 | TIM_CCMR2_IC4F_1));
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}
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if (ccr_ch == 2) {
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// Select the Polarity as falling on IC4 and rising on IC3
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MODIFY_REG(TIMx->CCER, TIM_CCER_CC3P | TIM_CCER_CC4P, TIM_CCER_CC4P | TIM_CCER_CC3E | TIM_CCER_CC4E);
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MODIFY_REG(TIMx->DIER, TIM_DIER_CC3DE | TIM_DIER_CC4DE, TIM_DIER_CC3DE);
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} else {
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// Select the Polarity as falling on IC3 and rising on IC4
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MODIFY_REG(TIMx->CCER, TIM_CCER_CC3P | TIM_CCER_CC4P, TIM_CCER_CC3P | TIM_CCER_CC3E | TIM_CCER_CC4E);
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MODIFY_REG(TIMx->DIER, TIM_DIER_CC3DE | TIM_DIER_CC4DE, TIM_DIER_CC4DE);
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}
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break;
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}
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default:
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break;
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}
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}
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// decode a telemetry packet from a GCR encoded stride buffer, take from betaflight decodeTelemetryPacket
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// see https://github.com/betaflight/betaflight/pull/8554#issuecomment-512507625 for a description of the protocol
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uint32_t RCOutput::bdshot_decode_telemetry_packet_f1(dmar_uint_t* buffer, uint32_t count, bool reversed)
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{
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if (!reversed) {
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return bdshot_decode_telemetry_packet(buffer, count);
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}
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uint32_t value = 0;
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uint32_t bits = 0;
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uint32_t len;
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// on F103 we are reading one edge with ICn and the other with ICn+1, the DMA architecture only
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// allows to trigger on a single register dictated by the DMA input capture channel being used.
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// even though we are reading multiple registers per transfer we always cannot trigger on one or other
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// of the registers and if the one we trigger on is the one that is numerically first each register
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// pair that we read will be swapped in time. in this case we trigger on ICn and then read CCRn and CCRn+1
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// giving us the new value of ICn and the old value of ICn+1. in order to avoid reading garbage on the
|
|
// first read we trigger ICn on the rising edge. this gives us all the data but with each pair of bytes
|
|
// transposed. we thus need to untranspose as we decode
|
|
dmar_uint_t oldValue = buffer[1];
|
|
|
|
for (int32_t i = 0; i <= count+1; ) {
|
|
if (i < count) {
|
|
dmar_int_t diff = buffer[i] - oldValue;
|
|
if (bits >= 21U) {
|
|
break;
|
|
}
|
|
len = (diff + TELEM_IC_SAMPLE/2U) / TELEM_IC_SAMPLE;
|
|
} else {
|
|
len = 21U - bits;
|
|
}
|
|
|
|
value <<= len;
|
|
value |= 1U << (len - 1U);
|
|
oldValue = buffer[i];
|
|
bits += len;
|
|
|
|
i += (i%2 ? -1 : 3);
|
|
}
|
|
|
|
|
|
if (bits != 21U) {
|
|
return INVALID_ERPM;
|
|
}
|
|
|
|
static const uint32_t decode[32] = {
|
|
0, 0, 0, 0, 0, 0, 0, 0, 0, 9, 10, 11, 0, 13, 14, 15,
|
|
0, 0, 2, 3, 0, 5, 6, 7, 0, 0, 8, 1, 0, 4, 12, 0 };
|
|
|
|
uint32_t decodedValue = decode[value & 0x1fU];
|
|
decodedValue |= decode[(value >> 5U) & 0x1fU] << 4U;
|
|
decodedValue |= decode[(value >> 10U) & 0x1fU] << 8U;
|
|
decodedValue |= decode[(value >> 15U) & 0x1fU] << 12U;
|
|
|
|
uint32_t csum = decodedValue;
|
|
csum = csum ^ (csum >> 8U); // xor bytes
|
|
csum = csum ^ (csum >> 4U); // xor nibbles
|
|
|
|
if ((csum & 0xfU) != 0xfU) {
|
|
return INVALID_ERPM;
|
|
}
|
|
decodedValue >>= 4;
|
|
|
|
return decodedValue;
|
|
}
|
|
|
|
#endif // HAL_WITH_BIDIR_DSHOT && STM32F1
|
|
|
|
#endif // HAL_USE_PWM
|
|
|
|
#endif // IOMCU_FW && HAL_DSHOT_ENABLED
|