motors/peripheral/uart.h - RealtimeRoboticsGroup/test - Gitiles

 #ifndef MOTORS_PERIPHERAL_UART_H_
 #define MOTORS_PERIPHERAL_UART_H_

 #include "absl/types/span.h"

 #include "aos/containers/sized_array.h"
 #include "motors/core/kinetis.h"
 #include "motors/peripheral/uart_buffer.h"
 #include "motors/util.h"

 namespace frc971::teensy {

 // Simple synchronous interface to a UART.
 class Uart {
  public:
   Uart(KINETISK_UART_t *module, int module_clock_frequency)
       : module_(module), module_clock_frequency_(module_clock_frequency) {}
   Uart(const Uart &) = delete;
   ~Uart();
   Uart &operator=(const Uart &) = delete;

   void Initialize(int baud_rate);

   // Blocks until all of the data is at least queued.
   void Write(absl::Span<const char> data, const DisableInterrupts &) {
     DoWrite(data);
   }

   // Returns all the data which is currently available.
   aos::SizedArray<char, 4> Read(const DisableInterrupts &) { return DoRead(); }

   bool SpaceAvailable() const { return module_->S1 & M_UART_TDRE; }
   // Only call this if SpaceAvailable() has just returned true.
   void WriteCharacter(char c) { module_->D = c; }

   bool DataAvailable() const { return module_->S1 & M_UART_RDRF; }
   // Only call this if DataAvailable() has just returned true.
   char ReadCharacter() { return module_->D; }

   // TODO(Brian): These APIs for enabling/disabling interrupts aren't quite
   // right. Redo them some time. Some issues:
   //   * They get called during initialization/destruction time, which means
   //     interrupts don't really need to be disabled because everything is
   //     singlethreaded.
   //   * Often, several C2 modifications are made in a single
   //     interrupts-disabled section. These could be batched to reduce
   //     peripheral writes. Sometimes, no modifications are made at all, in
   //     which case there doesn't even need to be a single write.

   void EnableTransmitInterrupt(const DisableInterrupts &) {
     c2_value_ |= M_UART_TIE;
     module_->C2 = c2_value_;
   }

   void DisableTransmitInterrupt(const DisableInterrupts &) {
     DoDisableTransmitInterrupt();
   }

   void EnableReceiveInterrupt(const DisableInterrupts &) {
     c2_value_ |= M_UART_RIE;
     module_->C2 = c2_value_;
   }

   void DisableReceiveInterrupt(const DisableInterrupts &) {
     DoDisableReceiveInterrupt();
   }

  private:
   void DoDisableTransmitInterrupt() {
     c2_value_ &= ~M_UART_TIE;
     module_->C2 = c2_value_;
   }
   void DoDisableReceiveInterrupt() {
     c2_value_ &= ~M_UART_RIE;
     module_->C2 = c2_value_;
   }

   void DoWrite(absl::Span<const char> data);
   aos::SizedArray<char, 4> DoRead();

   KINETISK_UART_t *const module_;
   const int module_clock_frequency_;
   // What we put in C2 except TE.
   uint8_t c2_value_;

   int tx_fifo_size_, rx_fifo_size_;
 };

 // Interrupt-based buffered interface to a UART.
 // TODO(Brian): Move DisableInterrupts calls up to the caller of this.
 class InterruptBufferedUart {
  public:
   InterruptBufferedUart(KINETISK_UART_t *module, int module_clock_frequency)
       : uart_(module, module_clock_frequency) {}
   ~InterruptBufferedUart();

   void Initialize(int baud_rate);

   // Queues up the given data for immediate writing. Blocks only if the queue
   // fills up before all of data is enqueued.
   void Write(absl::Span<const char> data);

   // Reads currently available data.
   // Returns all the data which is currently available (possibly none);
   // buffer is where to store the result. The return value will be a subspan of
   // this.
   absl::Span<char> Read(absl::Span<char> buffer);

   // Should be called as the body of the interrupt handler.
   void HandleInterrupt(const DisableInterrupts &disable_interrupts) {
     WriteCharacters(true, disable_interrupts);
     ReadCharacters(disable_interrupts);
   }

  private:
   void WriteCharacters(bool disable_empty, const DisableInterrupts &);
   void ReadCharacters(const DisableInterrupts &);

   Uart uart_;
   UartBuffer<1024> transmit_buffer_, receive_buffer_;
 };

 }  // namespace frc971::teensy

 #endif  // MOTORS_PERIPHERAL_UART_H_
	#ifndef MOTORS_PERIPHERAL_UART_H_
	#define MOTORS_PERIPHERAL_UART_H_

	#include "absl/types/span.h"

	#include "aos/containers/sized_array.h"
	#include "motors/core/kinetis.h"
	#include "motors/peripheral/uart_buffer.h"
	#include "motors/util.h"

	namespace frc971::teensy {

	// Simple synchronous interface to a UART.
	class Uart {
	public:
	Uart(KINETISK_UART_t *module, int module_clock_frequency)
	: module_(module), module_clock_frequency_(module_clock_frequency) {}
	Uart(const Uart &) = delete;
	~Uart();
	Uart &operator=(const Uart &) = delete;

	void Initialize(int baud_rate);

	// Blocks until all of the data is at least queued.
	void Write(absl::Span<const char> data, const DisableInterrupts &) {
	DoWrite(data);
	}

	// Returns all the data which is currently available.
	aos::SizedArray<char, 4> Read(const DisableInterrupts &) { return DoRead(); }

	bool SpaceAvailable() const { return module_->S1 & M_UART_TDRE; }
	// Only call this if SpaceAvailable() has just returned true.
	void WriteCharacter(char c) { module_->D = c; }

	bool DataAvailable() const { return module_->S1 & M_UART_RDRF; }
	// Only call this if DataAvailable() has just returned true.
	char ReadCharacter() { return module_->D; }

	// TODO(Brian): These APIs for enabling/disabling interrupts aren't quite
	// right. Redo them some time. Some issues:
	// * They get called during initialization/destruction time, which means
	// interrupts don't really need to be disabled because everything is
	// singlethreaded.
	// * Often, several C2 modifications are made in a single
	// interrupts-disabled section. These could be batched to reduce
	// peripheral writes. Sometimes, no modifications are made at all, in
	// which case there doesn't even need to be a single write.

	void EnableTransmitInterrupt(const DisableInterrupts &) {
	c2_value_ \|= M_UART_TIE;
	module_->C2 = c2_value_;
	}

	void DisableTransmitInterrupt(const DisableInterrupts &) {
	DoDisableTransmitInterrupt();
	}

	void EnableReceiveInterrupt(const DisableInterrupts &) {
	c2_value_ \|= M_UART_RIE;
	module_->C2 = c2_value_;
	}

	void DisableReceiveInterrupt(const DisableInterrupts &) {
	DoDisableReceiveInterrupt();
	}

	private:
	void DoDisableTransmitInterrupt() {
	c2_value_ &= ~M_UART_TIE;
	module_->C2 = c2_value_;
	}
	void DoDisableReceiveInterrupt() {
	c2_value_ &= ~M_UART_RIE;
	module_->C2 = c2_value_;
	}

	void DoWrite(absl::Span<const char> data);
	aos::SizedArray<char, 4> DoRead();

	KINETISK_UART_t *const module_;
	const int module_clock_frequency_;
	// What we put in C2 except TE.
	uint8_t c2_value_;

	int tx_fifo_size_, rx_fifo_size_;
	};

	// Interrupt-based buffered interface to a UART.
	// TODO(Brian): Move DisableInterrupts calls up to the caller of this.
	class InterruptBufferedUart {
	public:
	InterruptBufferedUart(KINETISK_UART_t *module, int module_clock_frequency)
	: uart_(module, module_clock_frequency) {}
	~InterruptBufferedUart();

	void Initialize(int baud_rate);

	// Queues up the given data for immediate writing. Blocks only if the queue
	// fills up before all of data is enqueued.
	void Write(absl::Span<const char> data);

	// Reads currently available data.
	// Returns all the data which is currently available (possibly none);
	// buffer is where to store the result. The return value will be a subspan of
	// this.
	absl::Span<char> Read(absl::Span<char> buffer);

	// Should be called as the body of the interrupt handler.
	void HandleInterrupt(const DisableInterrupts &disable_interrupts) {
	WriteCharacters(true, disable_interrupts);
	ReadCharacters(disable_interrupts);
	}

	private:
	void WriteCharacters(bool disable_empty, const DisableInterrupts &);
	void ReadCharacters(const DisableInterrupts &);

	Uart uart_;
	UartBuffer<1024> transmit_buffer_, receive_buffer_;
	};

	} // namespace frc971::teensy

	#endif // MOTORS_PERIPHERAL_UART_H_