third_party/nanopb/docs/index.rst - bazel - Git at Google

 =============================================
 Nanopb: Protocol Buffers with small code size
 =============================================

 .. include :: menu.rst

 Nanopb is an ANSI-C library for encoding and decoding messages in Google's `Protocol Buffers`__ format with minimal requirements for RAM and code space.
 It is primarily suitable for 32-bit microcontrollers.

 __ http://code.google.com/apis/protocolbuffers/

 Overall structure
 =================

 For the runtime program, you always need *pb.h* for type declarations.
 Depending on whether you want to encode, decode, or both, you also need *pb_encode.h/c* or *pb_decode.h/c*.

 The high-level encoding and decoding functions take an array of *pb_field_t* structures, which describes the fields of a message structure. Usually you want these autogenerated from a *.proto* file. The tool script *nanopb_generator.py* accomplishes this.

 .. image:: generator_flow.png

 So a typical project might include these files:

 1) Nanopb runtime library:
     - pb.h
     - pb_common.h and pb_common.c (always needed)
     - pb_decode.h and pb_decode.c (needed for decoding messages)
     - pb_encode.h and pb_encode.c (needed for encoding messages)
 2) Protocol description (you can have many):
     - person.proto (just an example)
     - person.pb.c (autogenerated, contains initializers for const arrays)
     - person.pb.h (autogenerated, contains type declarations)

 Features and limitations
 ========================

 **Features**

 #) Pure C runtime
 #) Small code size (2–10 kB depending on processor, plus any message definitions)
 #) Small ram usage (typically ~300 bytes, plus any message structs)
 #) Allows specifying maximum size for strings and arrays, so that they can be allocated statically.
 #) No malloc needed: everything can be allocated statically or on the stack. Optional malloc support available.
 #) You can use either encoder or decoder alone to cut the code size in half.
 #) Support for most protobuf features, including: all data types, nested submessages, default values, repeated and optional fields, oneofs, packed arrays, extension fields.
 #) Callback mechanism for handling messages larger than can fit in available RAM.
 #) Extensive set of tests.

 **Limitations**

 #) Some speed has been sacrificed for code size.
 #) Encoding is focused on writing to streams. For memory buffers only it could be made more efficient.
 #) The deprecated Protocol Buffers feature called "groups" is not supported.
 #) Fields in the generated structs are ordered by the tag number, instead of the natural ordering in .proto file.
 #) Unknown fields are not preserved when decoding and re-encoding a message.
 #) Reflection (runtime introspection) is not supported. E.g. you can't request a field by giving its name in a string.
 #) Numeric arrays are always encoded as packed, even if not marked as packed in .proto..
 #) Cyclic references between messages are supported only in callback and malloc mode.

 Getting started
 ===============

 For starters, consider this simple message::

  message Example {
     required int32 value = 1;
  }

 Save this in *message.proto* and compile it::

     user@host:~$ protoc -omessage.pb message.proto
     user@host:~$ python nanopb/generator/nanopb_generator.py message.pb

 You should now have in *message.pb.h*::

  typedef struct {
     int32_t value;
  } Example;

  extern const pb_field_t Example_fields[2];

 Now in your main program do this to encode a message::

  Example mymessage = {42};
  uint8_t buffer[10];
  pb_ostream_t stream = pb_ostream_from_buffer(buffer, sizeof(buffer));
  pb_encode(&stream, Example_fields, &mymessage);

 After that, buffer will contain the encoded message.
 The number of bytes in the message is stored in *stream.bytes_written*.
 You can feed the message to *protoc --decode=Example message.proto* to verify its validity.

 For a complete example of the simple case, see *example/simple.c*.
 For a more complex example with network interface, see the *example/network_server* subdirectory.

 Compiler requirements
 =====================
 Nanopb should compile with most ansi-C compatible compilers. It however
 requires a few header files to be available:

 #) *string.h*, with these functions: *strlen*, *memcpy*, *memset*
 #) *stdint.h*, for definitions of *int32_t* etc.
 #) *stddef.h*, for definition of *size_t*
 #) *stdbool.h*, for definition of *bool*

 If these header files do not come with your compiler, you can use the
 file *extra/pb_syshdr.h* instead. It contains an example of how to provide
 the dependencies. You may have to edit it a bit to suit your custom platform.

 To use the pb_syshdr.h, define *PB_SYSTEM_HEADER* as *"pb_syshdr.h"* (including the quotes).
 Similarly, you can provide a custom include file, which should provide all the dependencies
 listed above.

 Running the test cases
 ======================
 Extensive unittests and test cases are included under the *tests* folder.

 To build the tests, you will need the `scons`__ build system. The tests should
 be runnable on most platforms. Windows and Linux builds are regularly tested.

 __ http://www.scons.org/

 In addition to the build system, you will also need a working Google Protocol
 Buffers *protoc* compiler, and the Python bindings for Protocol Buffers. On
 Debian-based systems, install the following packages: *protobuf-compiler*,
 *python-protobuf* and *libprotobuf-dev*.
	=============================================
	Nanopb: Protocol Buffers with small code size
	=============================================

	.. include :: menu.rst

	Nanopb is an ANSI-C library for encoding and decoding messages in Google's `Protocol Buffers`__ format with minimal requirements for RAM and code space.
	It is primarily suitable for 32-bit microcontrollers.

	__ http://code.google.com/apis/protocolbuffers/

	Overall structure
	=================

	For the runtime program, you always need pb.h for type declarations.
	Depending on whether you want to encode, decode, or both, you also need pb_encode.h/c or pb_decode.h/c.

	The high-level encoding and decoding functions take an array of pb_field_t structures, which describes the fields of a message structure. Usually you want these autogenerated from a .proto file. The tool script nanopb_generator.py accomplishes this.

	.. image:: generator_flow.png

	So a typical project might include these files:

	1) Nanopb runtime library:
	- pb.h
	- pb_common.h and pb_common.c (always needed)
	- pb_decode.h and pb_decode.c (needed for decoding messages)
	- pb_encode.h and pb_encode.c (needed for encoding messages)
	2) Protocol description (you can have many):
	- person.proto (just an example)
	- person.pb.c (autogenerated, contains initializers for const arrays)
	- person.pb.h (autogenerated, contains type declarations)

	Features and limitations
	========================

	Features

	#) Pure C runtime
	#) Small code size (2–10 kB depending on processor, plus any message definitions)
	#) Small ram usage (typically ~300 bytes, plus any message structs)
	#) Allows specifying maximum size for strings and arrays, so that they can be allocated statically.
	#) No malloc needed: everything can be allocated statically or on the stack. Optional malloc support available.
	#) You can use either encoder or decoder alone to cut the code size in half.
	#) Support for most protobuf features, including: all data types, nested submessages, default values, repeated and optional fields, oneofs, packed arrays, extension fields.
	#) Callback mechanism for handling messages larger than can fit in available RAM.
	#) Extensive set of tests.

	Limitations

	#) Some speed has been sacrificed for code size.
	#) Encoding is focused on writing to streams. For memory buffers only it could be made more efficient.
	#) The deprecated Protocol Buffers feature called "groups" is not supported.
	#) Fields in the generated structs are ordered by the tag number, instead of the natural ordering in .proto file.
	#) Unknown fields are not preserved when decoding and re-encoding a message.
	#) Reflection (runtime introspection) is not supported. E.g. you can't request a field by giving its name in a string.
	#) Numeric arrays are always encoded as packed, even if not marked as packed in .proto..
	#) Cyclic references between messages are supported only in callback and malloc mode.

	Getting started
	===============

	For starters, consider this simple message::

	message Example {
	required int32 value = 1;
	}

	Save this in message.proto and compile it::

	user@host:~$ protoc -omessage.pb message.proto
	user@host:~$ python nanopb/generator/nanopb_generator.py message.pb

	You should now have in message.pb.h::

	typedef struct {
	int32_t value;
	} Example;

	extern const pb_field_t Example_fields[2];

	Now in your main program do this to encode a message::

	Example mymessage = {42};
	uint8_t buffer[10];
	pb_ostream_t stream = pb_ostream_from_buffer(buffer, sizeof(buffer));
	pb_encode(&stream, Example_fields, &mymessage);

	After that, buffer will contain the encoded message.
	The number of bytes in the message is stored in stream.bytes_written.
	You can feed the message to protoc --decode=Example message.proto to verify its validity.

	For a complete example of the simple case, see example/simple.c.
	For a more complex example with network interface, see the example/network_server subdirectory.

	Compiler requirements
	=====================
	Nanopb should compile with most ansi-C compatible compilers. It however
	requires a few header files to be available:

	#) string.h, with these functions: strlen, memcpy, memset
	#) stdint.h, for definitions of int32_t etc.
	#) stddef.h, for definition of size_t
	#) stdbool.h, for definition of bool

	If these header files do not come with your compiler, you can use the
	file extra/pb_syshdr.h instead. It contains an example of how to provide
	the dependencies. You may have to edit it a bit to suit your custom platform.

	To use the pb_syshdr.h, define PB_SYSTEM_HEADER as "pb_syshdr.h" (including the quotes).
	Similarly, you can provide a custom include file, which should provide all the dependencies
	listed above.

	Running the test cases
	======================
	Extensive unittests and test cases are included under the tests folder.

	To build the tests, you will need the `scons`__ build system. The tests should
	be runnable on most platforms. Windows and Linux builds are regularly tested.

	__ http://www.scons.org/

	In addition to the build system, you will also need a working Google Protocol
	Buffers protoc compiler, and the Python bindings for Protocol Buffers. On
	Debian-based systems, install the following packages: protobuf-compiler,
	python-protobuf and libprotobuf-dev.