aos/util/phased_loop.cc - RealtimeRoboticsGroup/test - Gitiles

 #include "aos/util/phased_loop.h"

 #include "glog/logging.h"

 namespace aos {
 namespace time {

 PhasedLoop::PhasedLoop(const monotonic_clock::duration interval,
                        const monotonic_clock::time_point monotonic_now,
                        const monotonic_clock::duration offset)
     : interval_(interval), offset_(offset), last_time_(offset) {
   CHECK(offset >= monotonic_clock::duration(0));
   CHECK(interval > monotonic_clock::duration(0));
   CHECK(offset < interval);
   Reset(monotonic_now);
 }

 void PhasedLoop::set_interval_and_offset(
     const monotonic_clock::duration interval,
     const monotonic_clock::duration offset) {
   // Update last_time_ to the new offset so that we have an even interval
   last_time_ += offset - offset_;

   interval_ = interval;
   offset_ = offset;
   CHECK(offset_ >= monotonic_clock::duration(0));
   CHECK(interval_ > monotonic_clock::duration(0));
   CHECK(offset_ < interval_);
 }

 monotonic_clock::duration PhasedLoop::OffsetFromIntervalAndTime(
     const monotonic_clock::duration interval,
     const monotonic_clock::time_point monotonic_trigger) {
   CHECK(interval > monotonic_clock::duration(0));
   return monotonic_trigger.time_since_epoch() -
          (monotonic_trigger.time_since_epoch() / interval) * interval +
          ((monotonic_trigger.time_since_epoch() >= monotonic_clock::zero())
               ? monotonic_clock::zero()
               : interval);
 }

 int PhasedLoop::Iterate(const monotonic_clock::time_point now) {
   auto next_time = monotonic_clock::epoch();
   // Round up to the next whole interval, ignoring offset_.
   {
     const auto offset_now = (now - offset_).time_since_epoch();
     monotonic_clock::duration prerounding;
     if (now.time_since_epoch() >= offset_) {
       // We're above 0, so rounding up means away from 0.
       prerounding = offset_now + interval_;
     } else {
       // We're below 0, so rounding up means towards 0.
       prerounding = offset_now + monotonic_clock::duration(1);
     }
     next_time += (prerounding / interval_) * interval_;
   }
   // Add offset_ back in.
   next_time += offset_;

   const monotonic_clock::duration difference = next_time - last_time_;

   const int result = difference / interval_;
   CHECK_EQ(
       0, (next_time - offset_).time_since_epoch().count() % interval_.count());
   CHECK(next_time > now);
   CHECK(next_time - now <= interval_);
   last_time_ = next_time;
   return result;
 }

 }  // namespace time
 }  // namespace aos
	#include "aos/util/phased_loop.h"

	#include "glog/logging.h"

	namespace aos {
	namespace time {

	PhasedLoop::PhasedLoop(const monotonic_clock::duration interval,
	const monotonic_clock::time_point monotonic_now,
	const monotonic_clock::duration offset)
	: interval_(interval), offset_(offset), last_time_(offset) {
	CHECK(offset >= monotonic_clock::duration(0));
	CHECK(interval > monotonic_clock::duration(0));
	CHECK(offset < interval);
	Reset(monotonic_now);
	}

	void PhasedLoop::set_interval_and_offset(
	const monotonic_clock::duration interval,
	const monotonic_clock::duration offset) {
	// Update last_time_ to the new offset so that we have an even interval
	last_time_ += offset - offset_;

	interval_ = interval;
	offset_ = offset;
	CHECK(offset_ >= monotonic_clock::duration(0));
	CHECK(interval_ > monotonic_clock::duration(0));
	CHECK(offset_ < interval_);
	}

	monotonic_clock::duration PhasedLoop::OffsetFromIntervalAndTime(
	const monotonic_clock::duration interval,
	const monotonic_clock::time_point monotonic_trigger) {
	CHECK(interval > monotonic_clock::duration(0));
	return monotonic_trigger.time_since_epoch() -
	(monotonic_trigger.time_since_epoch() / interval) * interval +
	((monotonic_trigger.time_since_epoch() >= monotonic_clock::zero())
	? monotonic_clock::zero()
	: interval);
	}

	int PhasedLoop::Iterate(const monotonic_clock::time_point now) {
	auto next_time = monotonic_clock::epoch();
	// Round up to the next whole interval, ignoring offset_.
	{
	const auto offset_now = (now - offset_).time_since_epoch();
	monotonic_clock::duration prerounding;
	if (now.time_since_epoch() >= offset_) {
	// We're above 0, so rounding up means away from 0.
	prerounding = offset_now + interval_;
	} else {
	// We're below 0, so rounding up means towards 0.
	prerounding = offset_now + monotonic_clock::duration(1);
	}
	next_time += (prerounding / interval_) * interval_;
	}
	// Add offset_ back in.
	next_time += offset_;

	const monotonic_clock::duration difference = next_time - last_time_;

	const int result = difference / interval_;
	CHECK_EQ(
	0, (next_time - offset_).time_since_epoch().count() % interval_.count());
	CHECK(next_time > now);
	CHECK(next_time - now <= interval_);
	last_time_ = next_time;
	return result;
	}

	} // namespace time
	} // namespace aos