aos/controls/control_loop.h - RealtimeRoboticsGroup/test - Gitiles

 #ifndef AOS_CONTROL_LOOP_CONTROL_LOOP_H_
 #define AOS_CONTROL_LOOP_CONTROL_LOOP_H_

 #include <string.h>
 #include <atomic>

 #include "aos/queue.h"
 #include "aos/time/time.h"
 #include "aos/type_traits/type_traits.h"
 #include "aos/util/log_interval.h"

 namespace aos {
 namespace controls {

 // Interface to describe runnable jobs.
 class Runnable {
  public:
   virtual ~Runnable() {}
   // Runs forever.
   virtual void Run() = 0;
   // Does one quick piece of work and return.  Does _not_ block.
   virtual void Iterate() = 0;
 };

 class SerializableControlLoop : public Runnable {
  public:
   // Returns the size of all the data to be sent when serialized.
   virtual size_t SeralizedSize() = 0;
   // Serialize the current data.
   virtual void Serialize(char *buffer) const = 0;
   // Serialize zeroed data in case the data is out of date.
   virtual void SerializeZeroMessage(char *buffer) const = 0;
   // Deserialize data into the control loop.
   virtual void Deserialize(const char *buffer) = 0;
   // Unique identifier for the control loop.
   // Most likely the hash of the queue group.
   virtual uint32_t UniqueID() = 0;
 };

 // Control loops run this often, "starting" at time 0.
 constexpr ::std::chrono::nanoseconds kLoopFrequency =
     ::std::chrono::milliseconds(5);

 // Provides helper methods to assist in writing control loops.
 // This template expects to be constructed with a queue group as an argument
 // that has a goal, position, status, and output queue.
 // It will then call the RunIteration method every cycle that it has enough
 // valid data for the control loop to run.
 template <class T>
 class ControlLoop : public SerializableControlLoop {
  public:
   // Create some convenient typedefs to reference the Goal, Position, Status,
   // and Output structures.
   typedef typename std::remove_reference<
       decltype(*(static_cast<T *>(NULL)->goal.MakeMessage().get()))>::type
         GoalType;
   typedef typename std::remove_reference<
       decltype(*(static_cast<T *>(NULL)->position.MakeMessage().get()))>::type
         PositionType;
   typedef typename std::remove_reference<
     decltype(*(static_cast<T *>(NULL)->status.MakeMessage().get()))>::type
       StatusType;
   typedef typename std::remove_reference<
     decltype(*(static_cast<T *>(NULL)->output.MakeMessage().get()))>::type
       OutputType;

   ControlLoop(T *control_loop) : control_loop_(control_loop) {}

   // Returns true if all the counters etc in the sensor data have been reset.
   // This will return true only a single time per reset.
   bool WasReset() {
     if (reset_) {
       reset_ = false;
       return true;
     } else {
       return false;
     }
   }

   // Constructs and sends a message on the output queue which sets everything to
   // a safe state (generally motors off). For some subclasses, this will be a
   // bit different (ie pistons).
   // The implementation here creates a new Output message, calls Zero() on it,
   // and then sends it.
   virtual void ZeroOutputs();

   // Sets the output to zero.
   // Over-ride if a value of zero is not "off" for this subsystem.
   virtual void Zero(OutputType *output) { output->Zero(); }

   // Runs the loop forever.
   void Run() override;

   // Runs one cycle of the loop.
   void Iterate() override;

   // Returns the name of the queue group.
   const char *name() { return control_loop_->name(); }

   // Methods to serialize all the data that should be sent over the network.
   size_t SeralizedSize() override { return control_loop_->goal->Size(); }
   void Serialize(char *buffer) const override {
     control_loop_->goal->Serialize(buffer);
   }
   void SerializeZeroMessage(char *buffer) const override {
     GoalType zero_goal;
     zero_goal.Zero();
     zero_goal.Serialize(buffer);
   }

   void Deserialize(const char *buffer) override {
     ScopedMessagePtr<GoalType> new_msg = control_loop_->goal.MakeMessage();
     new_msg->Deserialize(buffer);
     new_msg.Send();
   }

   uint32_t UniqueID() override { return control_loop_->hash(); }


  protected:
   static void Quit(int /*signum*/) {
     run_ = false;
   }

   // Runs an iteration of the control loop.
   // goal is the last goal that was sent.  It might be any number of cycles old
   // or nullptr if we haven't ever received a goal.
   // position is the current position, or nullptr if we didn't get a position
   // this cycle.
   // output is the values to be sent to the motors.  This is nullptr if the
   // output is going to be ignored and set to 0.
   // status is the status of the control loop.
   // Both output and status should be filled in by the implementation.
   virtual void RunIteration(const GoalType *goal,
                             const PositionType *position,
                             OutputType *output,
                             StatusType *status) = 0;

   T *queue_group() { return control_loop_; }
   const T *queue_group() const { return control_loop_; }

  private:
   static constexpr ::std::chrono::milliseconds kStaleLogInterval =
       ::std::chrono::milliseconds(100);
   // The amount of time after the last PWM pulse we consider motors enabled for.
   // 100ms is the result of using an oscilliscope to look at the input and
   // output of a Talon. The Info Sheet also lists 100ms for Talon SR, Talon SRX,
   // and Victor SP.
   static constexpr ::std::chrono::milliseconds kPwmDisableTime =
       ::std::chrono::milliseconds(100);

   // Pointer to the queue group
   T *control_loop_;

   bool reset_ = false;
   int32_t sensor_reader_pid_ = 0;

   ::aos::monotonic_clock::time_point last_pwm_sent_ =
       ::aos::monotonic_clock::min_time;

   typedef ::aos::util::SimpleLogInterval SimpleLogInterval;
   SimpleLogInterval no_sensor_state_ =
       SimpleLogInterval(kStaleLogInterval, ERROR, "no sensor state");
   SimpleLogInterval motors_off_log_ =
       SimpleLogInterval(kStaleLogInterval, WARNING, "motors disabled");
   SimpleLogInterval no_goal_ =
       SimpleLogInterval(kStaleLogInterval, ERROR, "no goal");

   static ::std::atomic<bool> run_;
 };

 }  // namespace controls
 }  // namespace aos

 #include "aos/controls/control_loop-tmpl.h"  // IWYU pragma: export

 #endif
	#ifndef AOS_CONTROL_LOOP_CONTROL_LOOP_H_
	#define AOS_CONTROL_LOOP_CONTROL_LOOP_H_

	#include <string.h>
	#include <atomic>

	#include "aos/queue.h"
	#include "aos/time/time.h"
	#include "aos/type_traits/type_traits.h"
	#include "aos/util/log_interval.h"

	namespace aos {
	namespace controls {

	// Interface to describe runnable jobs.
	class Runnable {
	public:
	virtual ~Runnable() {}
	// Runs forever.
	virtual void Run() = 0;
	// Does one quick piece of work and return. Does _not_ block.
	virtual void Iterate() = 0;
	};

	class SerializableControlLoop : public Runnable {
	public:
	// Returns the size of all the data to be sent when serialized.
	virtual size_t SeralizedSize() = 0;
	// Serialize the current data.
	virtual void Serialize(char *buffer) const = 0;
	// Serialize zeroed data in case the data is out of date.
	virtual void SerializeZeroMessage(char *buffer) const = 0;
	// Deserialize data into the control loop.
	virtual void Deserialize(const char *buffer) = 0;
	// Unique identifier for the control loop.
	// Most likely the hash of the queue group.
	virtual uint32_t UniqueID() = 0;
	};

	// Control loops run this often, "starting" at time 0.
	constexpr ::std::chrono::nanoseconds kLoopFrequency =
	::std::chrono::milliseconds(5);

	// Provides helper methods to assist in writing control loops.
	// This template expects to be constructed with a queue group as an argument
	// that has a goal, position, status, and output queue.
	// It will then call the RunIteration method every cycle that it has enough
	// valid data for the control loop to run.
	template <class T>
	class ControlLoop : public SerializableControlLoop {
	public:
	// Create some convenient typedefs to reference the Goal, Position, Status,
	// and Output structures.
	typedef typename std::remove_reference<
	decltype((static_cast<T >(NULL)->goal.MakeMessage().get()))>::type
	GoalType;
	typedef typename std::remove_reference<
	decltype((static_cast<T >(NULL)->position.MakeMessage().get()))>::type
	PositionType;
	typedef typename std::remove_reference<
	decltype((static_cast<T >(NULL)->status.MakeMessage().get()))>::type
	StatusType;
	typedef typename std::remove_reference<
	decltype((static_cast<T >(NULL)->output.MakeMessage().get()))>::type
	OutputType;

	ControlLoop(T *control_loop) : control_loop_(control_loop) {}

	// Returns true if all the counters etc in the sensor data have been reset.
	// This will return true only a single time per reset.
	bool WasReset() {
	if (reset_) {
	reset_ = false;
	return true;
	} else {
	return false;
	}
	}

	// Constructs and sends a message on the output queue which sets everything to
	// a safe state (generally motors off). For some subclasses, this will be a
	// bit different (ie pistons).
	// The implementation here creates a new Output message, calls Zero() on it,
	// and then sends it.
	virtual void ZeroOutputs();

	// Sets the output to zero.
	// Over-ride if a value of zero is not "off" for this subsystem.
	virtual void Zero(OutputType *output) { output->Zero(); }

	// Runs the loop forever.
	void Run() override;

	// Runs one cycle of the loop.
	void Iterate() override;

	// Returns the name of the queue group.
	const char *name() { return control_loop_->name(); }

	// Methods to serialize all the data that should be sent over the network.
	size_t SeralizedSize() override { return control_loop_->goal->Size(); }
	void Serialize(char *buffer) const override {
	control_loop_->goal->Serialize(buffer);
	}
	void SerializeZeroMessage(char *buffer) const override {
	GoalType zero_goal;
	zero_goal.Zero();
	zero_goal.Serialize(buffer);
	}

	void Deserialize(const char *buffer) override {
	ScopedMessagePtr<GoalType> new_msg = control_loop_->goal.MakeMessage();
	new_msg->Deserialize(buffer);
	new_msg.Send();
	}

	uint32_t UniqueID() override { return control_loop_->hash(); }


	protected:
	static void Quit(int /signum/) {
	run_ = false;
	}

	// Runs an iteration of the control loop.
	// goal is the last goal that was sent. It might be any number of cycles old
	// or nullptr if we haven't ever received a goal.
	// position is the current position, or nullptr if we didn't get a position
	// this cycle.
	// output is the values to be sent to the motors. This is nullptr if the
	// output is going to be ignored and set to 0.
	// status is the status of the control loop.
	// Both output and status should be filled in by the implementation.
	virtual void RunIteration(const GoalType *goal,
	const PositionType *position,
	OutputType *output,
	StatusType *status) = 0;

	T *queue_group() { return control_loop_; }
	const T *queue_group() const { return control_loop_; }

	private:
	static constexpr ::std::chrono::milliseconds kStaleLogInterval =
	::std::chrono::milliseconds(100);
	// The amount of time after the last PWM pulse we consider motors enabled for.
	// 100ms is the result of using an oscilliscope to look at the input and
	// output of a Talon. The Info Sheet also lists 100ms for Talon SR, Talon SRX,
	// and Victor SP.
	static constexpr ::std::chrono::milliseconds kPwmDisableTime =
	::std::chrono::milliseconds(100);

	// Pointer to the queue group
	T *control_loop_;

	bool reset_ = false;
	int32_t sensor_reader_pid_ = 0;

	::aos::monotonic_clock::time_point last_pwm_sent_ =
	::aos::monotonic_clock::min_time;

	typedef ::aos::util::SimpleLogInterval SimpleLogInterval;
	SimpleLogInterval no_sensor_state_ =
	SimpleLogInterval(kStaleLogInterval, ERROR, "no sensor state");
	SimpleLogInterval motors_off_log_ =
	SimpleLogInterval(kStaleLogInterval, WARNING, "motors disabled");
	SimpleLogInterval no_goal_ =
	SimpleLogInterval(kStaleLogInterval, ERROR, "no goal");

	static ::std::atomic<bool> run_;
	};

	} // namespace controls
	} // namespace aos

	#include "aos/controls/control_loop-tmpl.h" // IWYU pragma: export

	#endif