pw_stream/docs.rst - pigweed/pigweed - Git at Google

 .. _module-pw_stream:

 ---------
 pw_stream
 ---------

 ``pw_stream`` provides a foundational interface for streaming data from one part
 of a system to another. In the simplest use cases, this is basically a memcpy
 behind a reusable interface that can be passed around the system. On the other
 hand, the flexibility of this interface means a ``pw_stream`` could terminate is
 something more complex, like a UART stream or flash memory.

 Overview
 ========
 At the most basic level, ``pw_stream``'s interfaces provide very simple handles
 to enabling streaming data from one location in a system to an endpoint.

 Example:

 .. code-block:: cpp

   void DumpSensorData(pw::stream::Writer& writer) {
     static char temp[64];
     ImuSample imu_sample;
     imu.GetSample(&info);
     size_t bytes_written = imu_sample.AsCsv(temp, sizeof(temp));
     writer.Write(temp, bytes_written);
   }

 In this example, ``DumpSensorData()`` only cares that it has access to a
 ``Writer`` that it can use to stream data to using ``Writer::Write()``. The
 ``Writer`` itself can be backed by anything that can act as a data "sink."


 pw::stream::Writer
 ------------------
 This is the foundational stream ``Writer`` abstract class. Any class that wishes
 to implement the ``Writer`` interface **must** provide a ``DoWrite()``
 implementation. Note that ``Write()`` itself is **not** virtual, and should not
 be overridden.

 Buffering
 ^^^^^^^^^
 If any buffering occurs in a ``Writer`` and data must be flushed before it is
 fully committed to the sink, a ``Writer`` implementation is resposible for any
 ``Flush()`` capability.

 pw::stream::Reader
 ------------------
 This is the foundational stream ``Reader`` abstract class. Any class that wishes
 to implement the ``Reader`` interface **must** provide a ``DoRead()``
 implementation. Note that ``Read()`` itself is **not** virtual, and should not
 be overridden.

 pw::stream::MemoryWriter
 ------------------------
 The ``MemoryWriter`` class implements the ``Writer`` interface by backing the
 data destination with an **externally-provided** memory buffer.
 ``MemoryWriterBuffer`` extends ``MemoryWriter`` to internally provide a memory
 buffer.

 pw::stream::MemoryReader
 ------------------------
 The ``MemoryReader`` class implements the ``Reader`` interface by backing the
 data source with an **externally-provided** memory buffer.

 pw::stream::NullWriter
 ------------------------
 The ``NullWriter`` class implements the ``Writer`` interface by dropping all
 requested data writes, similar to ``/dev/null``.

 Why use pw_stream?
 ==================

 Standard API
 ------------
 ``pw_stream`` provides a standard way for classes to express that they have the
 ability to write data. Writing to one sink versus another sink is a matter of
 just passing a reference to the appropriate ``Writer``.

 As an example, imagine dumping sensor data. If written against a random HAL
 or one-off class, there's porting work required to write to a different sink
 (imagine writing over UART vs dumping to flash memory). Building a "dumping"
 implementation against the ``Writer`` interface prevents a dependency from
 forming on an artisainal API that would require porting work.

 Similarly, after building a ``Writer`` implementation for a Sink that data
 could be dumped to, that same ``Writer`` can be reused for other contexts that
 already write data to the ``pw::stream::Writer`` interface.

 Before:

 .. code-block:: cpp

   // Not reusable, depends on `Uart`.
   void DumpSensorData(Uart& uart) {
     static char temp[64];
     ImuSample imu_sample;
     imu.GetSample(&info);
     size_t bytes_written = imu_sample.AsCsv(temp, sizeof(temp));
     uart.Transmit(temp, bytes_written, /*timeout_ms=*/ 200);
   }

 After:

 .. code-block:: cpp

   // Reusable; no more Uart dependency!
   void DumpSensorData(Writer& writer) {
     static char temp[64];
     ImuSample imu_sample;
     imu.GetSample(&info);
     size_t bytes_written = imu_sample.AsCsv(temp, sizeof(temp));
     writer.Write(temp, bytes_written);
   }

 Reduce intermediate buffers
 ---------------------------
 Often functions that write larger blobs of data request a buffer is passed as
 the destination that data should be written to. This *requires* a buffer is
 allocated, even if the data only exists in that buffer for a very short period
 of time before it's  written somewhere else.

 In situations where data read from somewhere will immediately be written
 somewhere else, a ``Writer`` interface can cut out the middleman buffer.

 Before:

 .. code-block:: cpp

   // Requires an intermediate buffer to write the data as CSV.
   void DumpSensorData(Uart* uart) {
     char temp[64];
     ImuSample imu_sample;
     imu.GetSample(&info);
     size_t bytes_written = imu_sample.AsCsv(temp, sizeof(temp));
     uart.Transmit(temp, bytes_written, /*timeout_ms=*/ 200);
   }

 After:

 .. code-block:: cpp

   // Both DumpSensorData() and RawSample::AsCsv() use a Writer, eliminating the
   // need for an intermediate buffer.
   void DumpSensorData(Writer* writer) {
     RawSample imu_sample;
     imu.GetSample(&info);
     imu_sample.AsCsv(writer);
   }

 Prevent buffer overflow
 -----------------------
 When copying data from one buffer to another, there must be checks to ensure the
 copy does not overflow the destination buffer. As this sort of logic is
 duplicated throughout a codebase, there's more opportunities for bound-checking
 bugs to sneak in. ``Writers`` manage this logic internally rather than pushing
 the bounds checking to the code that is moving or writing the data.

 Similarly, since only the ``Writer`` has access to any underlying buffers, it's
 harder for functions that share a ``Writer`` to accidentally clobber data
 written by others using the same buffer.

 Before:

 .. code-block:: cpp

   Status BuildPacket(Id dest, span<const std::byte> payload,
                      span<std::byte> dest) {
     Header header;
     if (dest.size_bytes() + payload.size_bytes() < sizeof(Header)) {
       return Status::RESOURCE_EXHAUSTED;
     }
     header.dest = dest;
     header.src = DeviceId();
     header.payload_size = payload.size_bytes();

     memcpy(dest.data(), &header, sizeof(header));
     // Forgetting this line would clobber buffer contents. Also, using
     // a temporary span instead could leave `dest` to be misused elsewhere in
     // the function.
     dest = dest.subspan(sizeof(header));
     memcpy(dest.data(), payload.data(), payload.size_bytes());
   }

 After:

 .. code-block:: cpp

   Status BuildPacket(Id dest, span<const std::byte> payload, Writer& writer) {
     Header header;
     header.dest = dest;
     header.src = DeviceId();
     header.payload_size = payload.size_bytes();

     writer.Write(header);
     return writer.Write(payload);
   }

 Why NOT pw_stream?
 ==================
 pw_stream provides a virtual interface. This inherently has more overhead than
 a regular function call. In extremely performance-sensitive contexts, a virtual
 interface might not provide enough utility to justify the performance cost.

 Dependencies
 ============
   * ``pw_assert`` module
   * ``pw_preprocessor`` module
   * ``pw_status`` module
   * ``pw_span`` module
	.. _module-pw_stream:

	---------
	pw_stream
	---------

	``pw_stream`` provides a foundational interface for streaming data from one part
	of a system to another. In the simplest use cases, this is basically a memcpy
	behind a reusable interface that can be passed around the system. On the other
	hand, the flexibility of this interface means a ``pw_stream`` could terminate is
	something more complex, like a UART stream or flash memory.

	Overview
	========
	At the most basic level, ``pw_stream``'s interfaces provide very simple handles
	to enabling streaming data from one location in a system to an endpoint.

	Example:

	.. code-block:: cpp

	void DumpSensorData(pw::stream::Writer& writer) {
	static char temp[64];
	ImuSample imu_sample;
	imu.GetSample(&info);
	size_t bytes_written = imu_sample.AsCsv(temp, sizeof(temp));
	writer.Write(temp, bytes_written);
	}

	In this example, ``DumpSensorData()`` only cares that it has access to a
	``Writer`` that it can use to stream data to using ``Writer::Write()``. The
	``Writer`` itself can be backed by anything that can act as a data "sink."


	pw::stream::Writer
	------------------
	This is the foundational stream ``Writer`` abstract class. Any class that wishes
	to implement the ``Writer`` interface must provide a ``DoWrite()``
	implementation. Note that ``Write()`` itself is not virtual, and should not
	be overridden.

	Buffering
	^^^^^^^^^
	If any buffering occurs in a ``Writer`` and data must be flushed before it is
	fully committed to the sink, a ``Writer`` implementation is resposible for any
	``Flush()`` capability.

	pw::stream::Reader
	------------------
	This is the foundational stream ``Reader`` abstract class. Any class that wishes
	to implement the ``Reader`` interface must provide a ``DoRead()``
	implementation. Note that ``Read()`` itself is not virtual, and should not
	be overridden.

	pw::stream::MemoryWriter
	------------------------
	The ``MemoryWriter`` class implements the ``Writer`` interface by backing the
	data destination with an externally-provided memory buffer.
	``MemoryWriterBuffer`` extends ``MemoryWriter`` to internally provide a memory
	buffer.

	pw::stream::MemoryReader
	------------------------
	The ``MemoryReader`` class implements the ``Reader`` interface by backing the
	data source with an externally-provided memory buffer.

	pw::stream::NullWriter
	------------------------
	The ``NullWriter`` class implements the ``Writer`` interface by dropping all
	requested data writes, similar to ``/dev/null``.

	Why use pw_stream?
	==================

	Standard API
	------------
	``pw_stream`` provides a standard way for classes to express that they have the
	ability to write data. Writing to one sink versus another sink is a matter of
	just passing a reference to the appropriate ``Writer``.

	As an example, imagine dumping sensor data. If written against a random HAL
	or one-off class, there's porting work required to write to a different sink
	(imagine writing over UART vs dumping to flash memory). Building a "dumping"
	implementation against the ``Writer`` interface prevents a dependency from
	forming on an artisainal API that would require porting work.

	Similarly, after building a ``Writer`` implementation for a Sink that data
	could be dumped to, that same ``Writer`` can be reused for other contexts that
	already write data to the ``pw::stream::Writer`` interface.

	Before:

	.. code-block:: cpp

	// Not reusable, depends on `Uart`.
	void DumpSensorData(Uart& uart) {
	static char temp[64];
	ImuSample imu_sample;
	imu.GetSample(&info);
	size_t bytes_written = imu_sample.AsCsv(temp, sizeof(temp));
	uart.Transmit(temp, bytes_written, /timeout_ms=/ 200);
	}

	After:

	.. code-block:: cpp

	// Reusable; no more Uart dependency!
	void DumpSensorData(Writer& writer) {
	static char temp[64];
	ImuSample imu_sample;
	imu.GetSample(&info);
	size_t bytes_written = imu_sample.AsCsv(temp, sizeof(temp));
	writer.Write(temp, bytes_written);
	}

	Reduce intermediate buffers
	---------------------------
	Often functions that write larger blobs of data request a buffer is passed as
	the destination that data should be written to. This requires a buffer is
	allocated, even if the data only exists in that buffer for a very short period
	of time before it's written somewhere else.

	In situations where data read from somewhere will immediately be written
	somewhere else, a ``Writer`` interface can cut out the middleman buffer.

	Before:

	.. code-block:: cpp

	// Requires an intermediate buffer to write the data as CSV.
	void DumpSensorData(Uart* uart) {
	char temp[64];
	ImuSample imu_sample;
	imu.GetSample(&info);
	size_t bytes_written = imu_sample.AsCsv(temp, sizeof(temp));
	uart.Transmit(temp, bytes_written, /timeout_ms=/ 200);
	}

	After:

	.. code-block:: cpp

	// Both DumpSensorData() and RawSample::AsCsv() use a Writer, eliminating the
	// need for an intermediate buffer.
	void DumpSensorData(Writer* writer) {
	RawSample imu_sample;
	imu.GetSample(&info);
	imu_sample.AsCsv(writer);
	}

	Prevent buffer overflow
	-----------------------
	When copying data from one buffer to another, there must be checks to ensure the
	copy does not overflow the destination buffer. As this sort of logic is
	duplicated throughout a codebase, there's more opportunities for bound-checking
	bugs to sneak in. ``Writers`` manage this logic internally rather than pushing
	the bounds checking to the code that is moving or writing the data.

	Similarly, since only the ``Writer`` has access to any underlying buffers, it's
	harder for functions that share a ``Writer`` to accidentally clobber data
	written by others using the same buffer.

	Before:

	.. code-block:: cpp

	Status BuildPacket(Id dest, span<const std::byte> payload,
	span<std::byte> dest) {
	Header header;
	if (dest.size_bytes() + payload.size_bytes() < sizeof(Header)) {
	return Status::RESOURCE_EXHAUSTED;
	}
	header.dest = dest;
	header.src = DeviceId();
	header.payload_size = payload.size_bytes();

	memcpy(dest.data(), &header, sizeof(header));
	// Forgetting this line would clobber buffer contents. Also, using
	// a temporary span instead could leave `dest` to be misused elsewhere in
	// the function.
	dest = dest.subspan(sizeof(header));
	memcpy(dest.data(), payload.data(), payload.size_bytes());
	}

	After:

	.. code-block:: cpp

	Status BuildPacket(Id dest, span<const std::byte> payload, Writer& writer) {
	Header header;
	header.dest = dest;
	header.src = DeviceId();
	header.payload_size = payload.size_bytes();

	writer.Write(header);
	return writer.Write(payload);
	}

	Why NOT pw_stream?
	==================
	pw_stream provides a virtual interface. This inherently has more overhead than
	a regular function call. In extremely performance-sensitive contexts, a virtual
	interface might not provide enough utility to justify the performance cost.

	Dependencies
	============
	* ``pw_assert`` module
	* ``pw_preprocessor`` module
	* ``pw_status`` module
	* ``pw_span`` module