frc971/wpilib/sensor_reader.cc - RealtimeRoboticsGroup/test - Gitiles

 #include "frc971/wpilib/sensor_reader.h"

 #include "aos/init.h"
 #include "aos/util/compiler_memory_barrier.h"
 #include "frc971/wpilib/ahal/DigitalInput.h"
 #include "frc971/wpilib/ahal/Utility.h"

 namespace frc971 {
 namespace wpilib {

 SensorReader::SensorReader() {}

 void SensorReader::set_dma(::std::unique_ptr<DMA> dma) {
   dma_synchronizer_.reset(
       new ::frc971::wpilib::DMASynchronizer(::std::move(dma)));
 }

 void SensorReader::set_pwm_trigger(
     ::std::unique_ptr<frc::DigitalInput> pwm_trigger) {
   medium_encoder_filter_.Add(pwm_trigger.get());
   pwm_trigger_ = ::std::move(pwm_trigger);
 }

 void SensorReader::RunPWMDetecter() {
   ::aos::SetCurrentThreadRealtimePriority(41);

   pwm_trigger_->RequestInterrupts();
   // Rising edge only.
   pwm_trigger_->SetUpSourceEdge(true, false);

   monotonic_clock::time_point last_posedge_monotonic =
       monotonic_clock::min_time;

   while (run_) {
     auto ret = pwm_trigger_->WaitForInterrupt(1.0, true);
     if (ret == frc::InterruptableSensorBase::WaitResult::kRisingEdge) {
       // Grab all the clocks.
       const double pwm_fpga_time = pwm_trigger_->ReadRisingTimestamp();

       aos_compiler_memory_barrier();
       const double fpga_time_before = frc::GetFPGATime() * 1e-6;
       aos_compiler_memory_barrier();
       const monotonic_clock::time_point monotonic_now = monotonic_clock::now();
       aos_compiler_memory_barrier();
       const double fpga_time_after = frc::GetFPGATime() * 1e-6;
       aos_compiler_memory_barrier();

       const double fpga_offset =
           (fpga_time_after + fpga_time_before) / 2.0 - pwm_fpga_time;

       // Compute when the edge was.
       const monotonic_clock::time_point monotonic_edge =
           monotonic_now - chrono::duration_cast<chrono::nanoseconds>(
                               chrono::duration<double>(fpga_offset));

       LOG(DEBUG, "Got PWM pulse %f spread, %f offset, %lld trigger\n",
           fpga_time_after - fpga_time_before, fpga_offset,
           monotonic_edge.time_since_epoch().count());

       // Compute bounds on the timestep and sampling times.
       const double fpga_sample_length = fpga_time_after - fpga_time_before;
       const chrono::nanoseconds elapsed_time =
           monotonic_edge - last_posedge_monotonic;

       last_posedge_monotonic = monotonic_edge;

       // Verify that the values are sane.
       if (fpga_sample_length > 2e-5 || fpga_sample_length < 0) {
         continue;
       }
       if (fpga_offset < 0 || fpga_offset > 0.00015) {
         continue;
       }
       if (elapsed_time > chrono::microseconds(5050) + chrono::microseconds(4) ||
           elapsed_time < chrono::microseconds(5050) - chrono::microseconds(4)) {
         continue;
       }
       // Good edge!
       {
         ::std::unique_lock<::aos::stl_mutex> locker(tick_time_mutex_);
         last_tick_time_monotonic_timepoint_ = last_posedge_monotonic;
         last_period_ = elapsed_time;
       }
     } else {
       LOG(INFO, "PWM triggered %d\n", ret);
     }
   }
   pwm_trigger_->CancelInterrupts();
 }

 }  // namespace wpilib
 }  // namespace frc971
	#include "frc971/wpilib/sensor_reader.h"

	#include "aos/init.h"
	#include "aos/util/compiler_memory_barrier.h"
	#include "frc971/wpilib/ahal/DigitalInput.h"
	#include "frc971/wpilib/ahal/Utility.h"

	namespace frc971 {
	namespace wpilib {

	SensorReader::SensorReader() {}

	void SensorReader::set_dma(::std::unique_ptr<DMA> dma) {
	dma_synchronizer_.reset(
	new ::frc971::wpilib::DMASynchronizer(::std::move(dma)));
	}

	void SensorReader::set_pwm_trigger(
	::std::unique_ptr<frc::DigitalInput> pwm_trigger) {
	medium_encoder_filter_.Add(pwm_trigger.get());
	pwm_trigger_ = ::std::move(pwm_trigger);
	}

	void SensorReader::RunPWMDetecter() {
	::aos::SetCurrentThreadRealtimePriority(41);

	pwm_trigger_->RequestInterrupts();
	// Rising edge only.
	pwm_trigger_->SetUpSourceEdge(true, false);

	monotonic_clock::time_point last_posedge_monotonic =
	monotonic_clock::min_time;

	while (run_) {
	auto ret = pwm_trigger_->WaitForInterrupt(1.0, true);
	if (ret == frc::InterruptableSensorBase::WaitResult::kRisingEdge) {
	// Grab all the clocks.
	const double pwm_fpga_time = pwm_trigger_->ReadRisingTimestamp();

	aos_compiler_memory_barrier();
	const double fpga_time_before = frc::GetFPGATime() * 1e-6;
	aos_compiler_memory_barrier();
	const monotonic_clock::time_point monotonic_now = monotonic_clock::now();
	aos_compiler_memory_barrier();
	const double fpga_time_after = frc::GetFPGATime() * 1e-6;
	aos_compiler_memory_barrier();

	const double fpga_offset =
	(fpga_time_after + fpga_time_before) / 2.0 - pwm_fpga_time;

	// Compute when the edge was.
	const monotonic_clock::time_point monotonic_edge =
	monotonic_now - chrono::duration_cast<chrono::nanoseconds>(
	chrono::duration<double>(fpga_offset));

	LOG(DEBUG, "Got PWM pulse %f spread, %f offset, %lld trigger\n",
	fpga_time_after - fpga_time_before, fpga_offset,
	monotonic_edge.time_since_epoch().count());

	// Compute bounds on the timestep and sampling times.
	const double fpga_sample_length = fpga_time_after - fpga_time_before;
	const chrono::nanoseconds elapsed_time =
	monotonic_edge - last_posedge_monotonic;

	last_posedge_monotonic = monotonic_edge;

	// Verify that the values are sane.
	if (fpga_sample_length > 2e-5 \|\| fpga_sample_length < 0) {
	continue;
	}
	if (fpga_offset < 0 \|\| fpga_offset > 0.00015) {
	continue;
	}
	if (elapsed_time > chrono::microseconds(5050) + chrono::microseconds(4) \|\|
	elapsed_time < chrono::microseconds(5050) - chrono::microseconds(4)) {
	continue;
	}
	// Good edge!
	{
	::std::unique_lock<::aos::stl_mutex> locker(tick_time_mutex_);
	last_tick_time_monotonic_timepoint_ = last_posedge_monotonic;
	last_period_ = elapsed_time;
	}
	} else {
	LOG(INFO, "PWM triggered %d\n", ret);
	}
	}
	pwm_trigger_->CancelInterrupts();
	}

	} // namespace wpilib
	} // namespace frc971