bot3/input/gyro_sensor_receiver.cc - RealtimeRoboticsGroup/test - Gitiles

 #include <libusb-1.0/libusb.h>
 #include <memory>

 #include "aos/common/inttypes.h"
 #include "aos/atom_code/init.h"
 #include "aos/common/logging/logging.h"
 #include "aos/common/time.h"
 #include "aos/common/sensors/sensor_unpacker.h"
 #include "aos/common/sensors/sensor_receiver.h"

 #include "bot3/control_loops/drivetrain/drivetrain.q.h"
 #include "frc971/input/gyro_board_data.h"
 #include "gyro_board/src/libusb-driver/libusb_wrap.h"
 #include "frc971/queues/GyroAngle.q.h"

 #ifndef M_PI
 #define M_PI 3.14159265358979323846
 #endif

 using ::bot3::control_loops::drivetrain;
 using ::frc971::sensors::gyro;
 using ::frc971::GyroBoardData;

 namespace bot3 {
 namespace {

 inline double drivetrain_translate(int32_t in) {
   return static_cast<double>(in) / (256.0 /*cpr*/ * 4.0 /*quad*/) *
       (19.0 / 50.0) /*output reduction*/ * (64.0 / 24.0) /*encoder gears*/ *
       (3.5 /*wheel diameter*/ * 2.54 / 100.0 * M_PI);
 }

 inline double wrist_translate(int32_t in) {
   return static_cast<double>(in) / (256.0 /*cpr*/ * 4.0 /*quad*/) *
       (14.0 / 50.0 * 20.0 / 84.0) /*gears*/ * (2 * M_PI);
 }

 inline double angle_adjust_translate(int32_t in) {
   static const double kCableDiameter = 0.060;
   return -static_cast<double>(in) / (256.0 /*cpr*/ * 4.0 /*quad*/) *
       ((0.75 + kCableDiameter) / (16.61125 + kCableDiameter)) /*pulleys*/ *
       (2 * M_PI);
 }

 inline double shooter_translate(int32_t in) {
  return static_cast<double>(in) / (32.0 /*cpr*/ * 4.0 /*quad*/) *
       (15.0 / 34.0) /*gears*/ * (2 * M_PI);
 }

 inline double index_translate(int32_t in) {
   return -static_cast<double>(in) / (128.0 /*cpr*/ * 4.0 /*quad*/) *
       (1.0) /*gears*/ * (2 * M_PI);
 }

 }  // namespace

 class GyroSensorUnpacker :
     public ::aos::sensors::SensorUnpackerInterface<GyroBoardData> {
  public:
   GyroSensorUnpacker()
       : top_rise_count_(0),
         last_top_rise_count_(0),
         top_fall_count_(0),
         last_top_fall_count_(0),
         bottom_rise_count_(0),
         last_bottom_rise_count_(0),
         bottom_fall_delay_count_(0),
         last_bottom_fall_delay_count_(0),
         bottom_fall_count_(0),
         last_bottom_fall_count_(0),
         wrist_rise_count_(0),
         last_wrist_rise_count_(0),
         shooter_angle_rise_count_(0),
         last_shooter_angle_rise_count_(0) {
   }

   void UnpackFrom(GyroBoardData *data) {
     data->NetworkToHost();
     LOG(DEBUG, "processing a packet\n");

     static ::aos::time::Time last_time = ::aos::time::Time::Now();
     if ((last_time - ::aos::time::Time::Now()) >
         ::aos::time::Time::InMS(0.00205)) {
       LOG(INFO, "missed one\n");
     }

     gyro.MakeWithBuilder()
         .angle(data->gyro_angle / 16.0 / 1000.0 / 180.0 * M_PI)
         .Send();

     UpdateWrappingCounter(data->top_rise_count,
         &last_top_rise_count_, &top_rise_count_);
     UpdateWrappingCounter(data->top_fall_count,
         &last_top_fall_count_, &top_fall_count_);
     UpdateWrappingCounter(data->bottom_rise_count,
         &last_bottom_rise_count_, &bottom_rise_count_);
     UpdateWrappingCounter(data->bottom_fall_delay_count,
         &last_bottom_fall_delay_count_, &bottom_fall_delay_count_);
     UpdateWrappingCounter(data->bottom_fall_count,
         &last_bottom_fall_count_, &bottom_fall_count_);
     UpdateWrappingCounter(data->wrist_rise_count,
         &last_wrist_rise_count_, &wrist_rise_count_);
     UpdateWrappingCounter(data->shooter_angle_rise_count,
         &last_shooter_angle_rise_count_, &shooter_angle_rise_count_);

     drivetrain.position.MakeWithBuilder()
         .right_encoder(drivetrain_translate(data->right_drive))
         .left_encoder(-drivetrain_translate(data->left_drive))
         .Send();
   }

  private:
   void UpdateWrappingCounter(
       uint8_t current, uint8_t *last, int32_t *counter) {
     if (*last > current) {
       *counter += 0x100;
     }
     *counter = (*counter & 0xffffff00) | current;
     *last = current;
   }

   int32_t top_rise_count_;
   uint8_t last_top_rise_count_;
   int32_t top_fall_count_;
   uint8_t last_top_fall_count_;
   int32_t bottom_rise_count_;
   uint8_t last_bottom_rise_count_;
   int32_t bottom_fall_delay_count_;
   uint8_t last_bottom_fall_delay_count_;
   int32_t bottom_fall_count_;
   uint8_t last_bottom_fall_count_;
   int32_t wrist_rise_count_;
   uint8_t last_wrist_rise_count_;
   int32_t shooter_angle_rise_count_;
   uint8_t last_shooter_angle_rise_count_;
 };

 class GyroSensorReceiver :
     public ::aos::sensors::SensorReceiver<GyroBoardData> {
  public:
   GyroSensorReceiver(
       ::aos::sensors::SensorUnpackerInterface<GyroBoardData> *unpacker)
       : ::aos::sensors::SensorReceiver<GyroBoardData>(unpacker),
         start_time_(0, 0) {
     static_assert(sizeof(GyroBoardData) <= kDataLength,
                   "the buffer will be too small");
   }

  private:
   static const unsigned char kEndpoint = 0x81;
   // in ms
   // 0 is unlimited
   static const unsigned int kReadTimeout = 1000;

   // vendor ID
   static const int32_t kVid = 0x1424;
   // product ID
   static const int32_t kPid = 0xd243;

   // How big of a buffer to give the function.
   static const size_t kDataLength = 64;

   virtual void DoReceiveData() {
     // Loop and then return once we get a good one.
     while (true) {
       completed_transfer_ = NULL;
       while (completed_transfer_ == NULL) {
         libusb_.HandleEvents();
       }
       LOG(DEBUG, "processing transfer %p\n", completed_transfer_);

       if (completed_transfer_->read_bytes() <
           static_cast<ssize_t>(sizeof(GyroBoardData))) {
         LOG(ERROR, "read %d bytes instead of at least %zd\n",
             completed_transfer_->read_bytes(), sizeof(GyroBoardData));
         continue;
       }

       memcpy(&data()->values, completed_transfer_->data(),
              sizeof(GyroBoardData));
       if (data()->count == 0) {
         start_time_ = ::aos::time::Time::Now();
         data()->count = 1;
       } else {
         ::aos::time::Time delta_time = ::aos::time::Time::Now() - start_time_;
         data()->count = static_cast<int32_t>(
             (delta_time / ::aos::sensors::kSensorSendFrequency) + 0.5);
       }
       return;
     }
   }

   virtual void Reset() {
     transfer1_.reset();
     transfer2_.reset();
     dev_handle_ = ::std::unique_ptr<LibUSBDeviceHandle>(
         libusb_.FindDeviceWithVIDPID(kVid, kPid));
     if (!dev_handle_) {
       LOG(ERROR, "couldn't find device. exiting\n");
       exit(1);
     }
     transfer1_ = ::std::unique_ptr<libusb::Transfer>(
         new libusb::Transfer(kDataLength, StaticTransferCallback, this));
     transfer2_ = ::std::unique_ptr<libusb::Transfer>(
         new libusb::Transfer(kDataLength, StaticTransferCallback, this));
     transfer1_->FillInterrupt(dev_handle_.get(), kEndpoint, kReadTimeout);
     transfer2_->FillInterrupt(dev_handle_.get(), kEndpoint, kReadTimeout);
     transfer1_->Submit();
     transfer2_->Submit();

     data()->count = 0;
   }

   static void StaticTransferCallback(libusb::Transfer *transfer, void *self) {
     static_cast<GyroSensorReceiver *>(self)->TransferCallback(transfer);
   }
   void TransferCallback(libusb::Transfer *transfer) {
     if (transfer->status() == LIBUSB_TRANSFER_COMPLETED) {
       LOG(DEBUG, "transfer %p completed\n", transfer);
       completed_transfer_ = transfer;
     } else if (transfer->status() == LIBUSB_TRANSFER_TIMED_OUT) {
       LOG(WARNING, "transfer %p timed out\n", transfer);
     } else if (transfer->status() == LIBUSB_TRANSFER_CANCELLED) {
       LOG(DEBUG, "transfer %p cancelled\n", transfer);
     } else {
       LOG(FATAL, "transfer %p has status %d\n", transfer, transfer->status());
     }
     transfer->Submit();
   }

   virtual void Synchronized(::aos::time::Time start_time) {
     // Subtract off how many packets it read while synchronizing from the time.
     start_time_ = start_time -
         ::aos::sensors::kSensorSendFrequency * data()->count;
   }

   ::std::unique_ptr<LibUSBDeviceHandle> dev_handle_;
   ::std::unique_ptr<libusb::Transfer> transfer1_, transfer2_;
   // Temporary variable for holding a completed transfer to communicate that
   // information from the callback to the code that wants it.
   libusb::Transfer *completed_transfer_;

   ::aos::time::Time start_time_;

   LibUSB libusb_;
 };

 }  // namespace bot3

 int main() {
   ::aos::Init();
   ::bot3::GyroSensorUnpacker unpacker;
   ::bot3::GyroSensorReceiver receiver(&unpacker);
   while (true) {
     receiver.RunIteration();
   }
   ::aos::Cleanup();
 }
	#include <libusb-1.0/libusb.h>
	#include <memory>

	#include "aos/common/inttypes.h"
	#include "aos/atom_code/init.h"
	#include "aos/common/logging/logging.h"
	#include "aos/common/time.h"
	#include "aos/common/sensors/sensor_unpacker.h"
	#include "aos/common/sensors/sensor_receiver.h"

	#include "bot3/control_loops/drivetrain/drivetrain.q.h"
	#include "frc971/input/gyro_board_data.h"
	#include "gyro_board/src/libusb-driver/libusb_wrap.h"
	#include "frc971/queues/GyroAngle.q.h"

	#ifndef M_PI
	#define M_PI 3.14159265358979323846
	#endif

	using ::bot3::control_loops::drivetrain;
	using ::frc971::sensors::gyro;
	using ::frc971::GyroBoardData;

	namespace bot3 {
	namespace {

	inline double drivetrain_translate(int32_t in) {
	return static_cast<double>(in) / (256.0 /cpr/ * 4.0 /quad/) *
	(19.0 / 50.0) /output reduction/ * (64.0 / 24.0) /encoder gears/ *
	(3.5 /wheel diameter/ * 2.54 / 100.0 * M_PI);
	}

	inline double wrist_translate(int32_t in) {
	return static_cast<double>(in) / (256.0 /cpr/ * 4.0 /quad/) *
	(14.0 / 50.0 * 20.0 / 84.0) /gears/ * (2 * M_PI);
	}

	inline double angle_adjust_translate(int32_t in) {
	static const double kCableDiameter = 0.060;
	return -static_cast<double>(in) / (256.0 /cpr/ * 4.0 /quad/) *
	((0.75 + kCableDiameter) / (16.61125 + kCableDiameter)) /pulleys/ *
	(2 * M_PI);
	}

	inline double shooter_translate(int32_t in) {
	return static_cast<double>(in) / (32.0 /cpr/ * 4.0 /quad/) *
	(15.0 / 34.0) /gears/ * (2 * M_PI);
	}

	inline double index_translate(int32_t in) {
	return -static_cast<double>(in) / (128.0 /cpr/ * 4.0 /quad/) *
	(1.0) /gears/ * (2 * M_PI);
	}

	} // namespace

	class GyroSensorUnpacker :
	public ::aos::sensors::SensorUnpackerInterface<GyroBoardData> {
	public:
	GyroSensorUnpacker()
	: top_rise_count_(0),
	last_top_rise_count_(0),
	top_fall_count_(0),
	last_top_fall_count_(0),
	bottom_rise_count_(0),
	last_bottom_rise_count_(0),
	bottom_fall_delay_count_(0),
	last_bottom_fall_delay_count_(0),
	bottom_fall_count_(0),
	last_bottom_fall_count_(0),
	wrist_rise_count_(0),
	last_wrist_rise_count_(0),
	shooter_angle_rise_count_(0),
	last_shooter_angle_rise_count_(0) {
	}

	void UnpackFrom(GyroBoardData *data) {
	data->NetworkToHost();
	LOG(DEBUG, "processing a packet\n");

	static ::aos::time::Time last_time = ::aos::time::Time::Now();
	if ((last_time - ::aos::time::Time::Now()) >
	::aos::time::Time::InMS(0.00205)) {
	LOG(INFO, "missed one\n");
	}

	gyro.MakeWithBuilder()
	.angle(data->gyro_angle / 16.0 / 1000.0 / 180.0 * M_PI)
	.Send();

	UpdateWrappingCounter(data->top_rise_count,
	&last_top_rise_count_, &top_rise_count_);
	UpdateWrappingCounter(data->top_fall_count,
	&last_top_fall_count_, &top_fall_count_);
	UpdateWrappingCounter(data->bottom_rise_count,
	&last_bottom_rise_count_, &bottom_rise_count_);
	UpdateWrappingCounter(data->bottom_fall_delay_count,
	&last_bottom_fall_delay_count_, &bottom_fall_delay_count_);
	UpdateWrappingCounter(data->bottom_fall_count,
	&last_bottom_fall_count_, &bottom_fall_count_);
	UpdateWrappingCounter(data->wrist_rise_count,
	&last_wrist_rise_count_, &wrist_rise_count_);
	UpdateWrappingCounter(data->shooter_angle_rise_count,
	&last_shooter_angle_rise_count_, &shooter_angle_rise_count_);

	drivetrain.position.MakeWithBuilder()
	.right_encoder(drivetrain_translate(data->right_drive))
	.left_encoder(-drivetrain_translate(data->left_drive))
	.Send();
	}

	private:
	void UpdateWrappingCounter(
	uint8_t current, uint8_t last, int32_t counter) {
	if (*last > current) {
	*counter += 0x100;
	}
	counter = (counter & 0xffffff00) \| current;
	*last = current;
	}

	int32_t top_rise_count_;
	uint8_t last_top_rise_count_;
	int32_t top_fall_count_;
	uint8_t last_top_fall_count_;
	int32_t bottom_rise_count_;
	uint8_t last_bottom_rise_count_;
	int32_t bottom_fall_delay_count_;
	uint8_t last_bottom_fall_delay_count_;
	int32_t bottom_fall_count_;
	uint8_t last_bottom_fall_count_;
	int32_t wrist_rise_count_;
	uint8_t last_wrist_rise_count_;
	int32_t shooter_angle_rise_count_;
	uint8_t last_shooter_angle_rise_count_;
	};

	class GyroSensorReceiver :
	public ::aos::sensors::SensorReceiver<GyroBoardData> {
	public:
	GyroSensorReceiver(
	::aos::sensors::SensorUnpackerInterface<GyroBoardData> *unpacker)
	: ::aos::sensors::SensorReceiver<GyroBoardData>(unpacker),
	start_time_(0, 0) {
	static_assert(sizeof(GyroBoardData) <= kDataLength,
	"the buffer will be too small");
	}

	private:
	static const unsigned char kEndpoint = 0x81;
	// in ms
	// 0 is unlimited
	static const unsigned int kReadTimeout = 1000;

	// vendor ID
	static const int32_t kVid = 0x1424;
	// product ID
	static const int32_t kPid = 0xd243;

	// How big of a buffer to give the function.
	static const size_t kDataLength = 64;

	virtual void DoReceiveData() {
	// Loop and then return once we get a good one.
	while (true) {
	completed_transfer_ = NULL;
	while (completed_transfer_ == NULL) {
	libusb_.HandleEvents();
	}
	LOG(DEBUG, "processing transfer %p\n", completed_transfer_);

	if (completed_transfer_->read_bytes() <
	static_cast<ssize_t>(sizeof(GyroBoardData))) {
	LOG(ERROR, "read %d bytes instead of at least %zd\n",
	completed_transfer_->read_bytes(), sizeof(GyroBoardData));
	continue;
	}

	memcpy(&data()->values, completed_transfer_->data(),
	sizeof(GyroBoardData));
	if (data()->count == 0) {
	start_time_ = ::aos::time::Time::Now();
	data()->count = 1;
	} else {
	::aos::time::Time delta_time = ::aos::time::Time::Now() - start_time_;
	data()->count = static_cast<int32_t>(
	(delta_time / ::aos::sensors::kSensorSendFrequency) + 0.5);
	}
	return;
	}
	}

	virtual void Reset() {
	transfer1_.reset();
	transfer2_.reset();
	dev_handle_ = ::std::unique_ptr<LibUSBDeviceHandle>(
	libusb_.FindDeviceWithVIDPID(kVid, kPid));
	if (!dev_handle_) {
	LOG(ERROR, "couldn't find device. exiting\n");
	exit(1);
	}
	transfer1_ = ::std::unique_ptr<libusb::Transfer>(
	new libusb::Transfer(kDataLength, StaticTransferCallback, this));
	transfer2_ = ::std::unique_ptr<libusb::Transfer>(
	new libusb::Transfer(kDataLength, StaticTransferCallback, this));
	transfer1_->FillInterrupt(dev_handle_.get(), kEndpoint, kReadTimeout);
	transfer2_->FillInterrupt(dev_handle_.get(), kEndpoint, kReadTimeout);
	transfer1_->Submit();
	transfer2_->Submit();

	data()->count = 0;
	}

	static void StaticTransferCallback(libusb::Transfer transfer, void self) {
	static_cast<GyroSensorReceiver *>(self)->TransferCallback(transfer);
	}
	void TransferCallback(libusb::Transfer *transfer) {
	if (transfer->status() == LIBUSB_TRANSFER_COMPLETED) {
	LOG(DEBUG, "transfer %p completed\n", transfer);
	completed_transfer_ = transfer;
	} else if (transfer->status() == LIBUSB_TRANSFER_TIMED_OUT) {
	LOG(WARNING, "transfer %p timed out\n", transfer);
	} else if (transfer->status() == LIBUSB_TRANSFER_CANCELLED) {
	LOG(DEBUG, "transfer %p cancelled\n", transfer);
	} else {
	LOG(FATAL, "transfer %p has status %d\n", transfer, transfer->status());
	}
	transfer->Submit();
	}

	virtual void Synchronized(::aos::time::Time start_time) {
	// Subtract off how many packets it read while synchronizing from the time.
	start_time_ = start_time -
	::aos::sensors::kSensorSendFrequency * data()->count;
	}

	::std::unique_ptr<LibUSBDeviceHandle> dev_handle_;
	::std::unique_ptr<libusb::Transfer> transfer1_, transfer2_;
	// Temporary variable for holding a completed transfer to communicate that
	// information from the callback to the code that wants it.
	libusb::Transfer *completed_transfer_;

	::aos::time::Time start_time_;

	LibUSB libusb_;
	};

	} // namespace bot3

	int main() {
	::aos::Init();
	::bot3::GyroSensorUnpacker unpacker;
	::bot3::GyroSensorReceiver receiver(&unpacker);
	while (true) {
	receiver.RunIteration();
	}
	::aos::Cleanup();
	}