android/android-emugl/host/tools/emugen/README - qemu-android - Git at Google

 Introduction:
 -------------
 The emugen tool is a tool to generate a wire protocol implementation
 based on provided API.  The tool generates c++ encoder code that takes
 API calls and encodes them into the wire and decoder code that decodes
 the wire stream and calls server matching API.
 The emugen tool includes additional functionality that enables to
 generate an wrapper library. The wrapper library provides entry points
 for the specified API, where each entry routes the call via a dispatch
 table. The dispatch table may be initialized as required by a specific application.

 The following paragraphs includes the following:
     * Wire Protocol Description
     * Input files description & format
     * Generated code description.


 Note: In this document, the caller is referred to as Encoder or Client
 and the callee is referred to as the Decoder or Server. These terms
 are used interchangeably by the context.


 Wire Protocol packet structure:
 -------------------------------
 A general Encoder->Decoder packet is structured as following:
 struct Packet {
 	unsigned int opcode;
 	unsigned int packet_len;
 	… parameter 1
 	… parameter 2
 };
 A general Decoder->Encoder reply is expected to be received in the
 context of the ‘call’ that triggered it, thus it includes the reply
 data only, with no context headers. In precise term terms, a reply
 packet will look like:

 struct {
 	...// reply data
 };

 consider the following function call:
 int foo(int p1, short s1)
 will be encoded into :
 {
 	101, // foo opcode
 	14, // sizeof(opcode) + sizeof(packet_len) + sizeof(int) + sizeof(short)
 	p1, // 4 bytes
 	s1 // 2 bytes
 }

 Since ‘foo’ returns value, the caller is expected to read back the return packet from the server->client stream. The return value in this example is in thus the return packet is:
 {
 	int retval;
 }


 Pointer decoding:
 ----------------
 The wire protocol also allows exchanging of pointer data
 (arrays). Pointers are defined with directions:

 	in : Data is sent from the caller to the calle
 	out: Data is sent from the callee to the caller
 	in_out: data is sent from the caller and return in place.

 ‘in’ and ‘in_out’ encoded with their len:
 {
 	unsinged int pointer_data_len;
 	unsigned char data[pointer_data_len];… // pointer data
 }

 ‘out’ pointers are encoded by data length only:
 {
 unsigned int pointer_data_len;
 }

 ‘out’ and ‘in_out’ pointer’s data is returned in the return
 packet. For example, consider the following call:

 int foo(int n, int *ptr); // assume that ‘data’ is in_out pointer which contains ‘n’ ints

 The caller packet will have the following form:
 {
 	101, // foo opcode
 	xx, sizeof(opcode) + sizeof(datalen) + sizeof(int) + sizeof(unsigned int) + n * sizeof(int);
 	n, // the n parameter
 	n * sizeof(int), // size of the data in ptr
 	… // n* sizeof(int) bytes
 }

 The return packet is;
 {
 	…. // n * sizeof(int) bytes of data return in ptr
 	retval // sizeof(int) - the return value of the function;
 }

 Endianess
 ---------
 The Wire protocol is designed to impose minimum overhead on the client
 side. Thus, the data endianness that is sent across the wire is
 determined by the ‘client’ side. It is up to the server side to
 determine the client endianess and marshal the packets as required.


 Emugen input files - protocol specification
 -------------------------------------------
 The protocol generated by emugen consists of two input files:

 1. basename.in - A sepcification of the protocol RPC procedures. This
 part of the specification is expected to be generated automatically
 from c/c++ header files or similar.

 ‘basename’ is the basename for the protocol and will be used to prefix
 the files that are generated for this protocol.  A line in the .in
 file has the following format:

 [prefix](retvalType, FuncName, <param type> [param name],...)
 where
 	retvalType - The function return value type
 	FuncName - function name
 	<param type> mandatory parameter type
 	[param name] - optional parameter name
 Examples:
 GL_ENTRY(void, glVertex1f, float v)
 XXX(int *, foo, int n, float, short)
 XXX(void, glFlush, void)

 Note: Empty lines in the file are ignored. A line starts with # is a comment

 2. basename.attrib - Attributes information of the API.
 This file includes additional flags, pointers datalen information and
 global attributes of the protocol. For uptodate format of the file,
 please refer to the specification file in the project source
 tree. The format of the .attrib file is described below.

 3. basename.types - Types information

 This files describes the types that are described by the API. A type
 is defined as follows:
 <type name> <size in bits> <print format string> <is a pointer? true|false>
 where:
 <type name> is the name of the type as described in the API
 <size in bits> 0, 8, 16, 32 sizes are accepted
 <print format string> a string to format the value of the type, as
 acceted by printf(3)
 <is pointer?> true or false string species whether the type should be
 treated as a pointer.

 example:
 GLint 32 %d false
 GLint* 32 %p true
 GLptr  32 %p true

 Encoder generated code files
 ----------------------------
 In order to generate the encoder files, one should run the ‘emugen’
 tool as follows:

 emugen -i <input directory> -E <encoder files output directory> <basename>
 where:
 	<input directory> containes the api specification files  (basename.in + basename.attrib)
 	<encoder directory> - a directory name to generate the encoder output files
 	basename - The basename for the api.

 Assuming the basename is ‘api’, The following files are generated:

 api_opcodes.h - defines the protocol opcodes. The first opcode value
 is 0, unless defined otherwise in the .attrib file

 api_entry.cpp - defines entry points for the functions that are
 defined by the protocol. this File also includes a function call
 ‘setContextAccessor(void *(*f)()). This function should be used to
 provide a callback function that is used by the functions to access
 the encoder context. For example, such callback could fetch the
 context from a Thread Local Storage (TLS) location.

 api_client_proc.h - type defintions for the protocol procedures.

 api_client_context.h - defines the client side dispatch table data
 structure that stores the encoding functions. This data structure also
 includes ‘accessors’ methods such that library user can override
 default entries for special case handling.

 api_client_context.cpp - defines an initialization function for
 dispatch table

 api_enc.h - This header file defines the encoder data strcuture. The
 encoder data structure inherits its functionality from the
 ‘client_context’ class above and adds encoding and streaming
 functionality.

 api_enc.cpp - Encoder implementation.

 Decoder generated files
 -----------------------
 In order to generate the decoder files, one should run the ‘emugen’
 tool as follows:
 emugen -i <input directory> -D <decoder files output directory> basename
 where:
 	<input directory> containes the api specification files  (basename.in + basename.attrib)
 	<decoder directory> - a directory name to generate the decoder output files
 	basename - The basename for the api.

 With resepct to the example above, Emugen will generate the following
 files:

 api_opcodes.h - Protocol opcodes

 api_server_proc.h - type definitions for the server side procedures

 api_server_context.h - dispatch table the decoder functions

 api_server_context.cpp - dispatch table initialization function
 api_dec.h - Decoder header file

 api_dec.cpp - Decoder implementation. In addtion, this file includes
 an intiailization function that uses a user provided callback to
 initialize the API server implementation. An example for such
 initialization is loading a set of functions from a shared library
 module.

 Wrapper generated files
 -----------------------
 In order to generate a wrapper library files, one should run the
 'emugen' tool as follows:

 emugen -i <input directory> -W <wrapper files output directory> basename
 where:
 	<input directory> containes the api specification files  (basename.in + basename.attrib)
 	<wrapper directory> - a directory name to generate the wrapper output files
 	basename - The basename for the api.

 With resepct to the example above, Emugen will generate the following
 files:

 api_wrapper_proc.h - type definitions for the wrapper procedures

 api_wrapper_context.h - dispatch table the wrapper functions

 api_wrapper_context.cpp - dispatch table initialization function
 api_wrapper_entry.cpp - entry points for the API


 .attrib file format description:
 -------------------------------
 The .attrib file is an input file to emugen and is used to provide
  additional information that is required for the code generation.
 The file format is as follows:

 a line that starts with # is ignored (comment)
 a empty line just whitespace of (" " "\t" "\n") is ignored.

 The file is divided into 'sections', each describes a specific API
 function call. A section starts with the name of the function in
 column 0.

 A section that starts with the reserved word 'GLOBAL' provides global
 attributes.

 below are few sections examples:

 GLOBAL
   encoder_headers string.h kuku.h

 glVertex3fv
 	len data (size)
 glTexImage2D
        len pixels (pixels == NULL? 0 : (format_pixel_size(internalformat) * width * height * type_size(type)))


 Global section flags description:

 base_opcode
     set the base opcode value for this api
     format: base_opcode 100

 encoder_headers
     a list of headers that will be included in the encoder header file
     format: encoder_headers <stdio.h> "kuku.h"

 client_context_headers
     a list of headers that will be included in the client context header file
     format: client_context_headers <stdio.h> "kuku.h"

 decoder_headers
     a list of headers that will be included in the decoder header file
     format: decoder_headers <stdio.h> "kuku.h"

 server_context_headers
     a list of headers that will be included in the server context header file
     format: server_context_headers <stdio.h> "kuku.h"


 Entry point flags description:

  len
 	desciption : provide an expression to calcualte an expression data len
 	format: len <var name> <c expression that calcluates the data len>

 custom_pack
 	description: provide an expression to pack data into the stream.
 	format: custom_pack <var name> <c++ expression that pack data from var into the stream>
 	The stream is represented by a (unsigned char *)ptr. The expression may also refer
 	to other function parameters. In addition, the expression may refer to 'void *self' which
 	is the encoding context as provided by the caller.

  dir
 	description : set a pointer direction (in - for data that goes
 	to the codec, out from data that returns from the codec.
      	format: dir <varname> <[in | out | inout]>

  var_flag
  	 description : set variable flags
  	 format: var_flag <varname> < nullAllowed | isLarge | ... >

         nullAllowed -> for pointer variables, indicates that NULL is a valid value
         isLarge     -> for pointer variables, indicates that the data should be sent without an intermediate copy

  flag
 	description: set entry point flag;
 	format: flag < unsupported | ... >
 	supported flags are:
 	unsupported - The encoder side implementation is pointed to "unsuppored reporting function".
 	custom_decoder - The decoder is expected to be provided with
 		       	 custom implementation. The call to the
 		       	 deocder function includes a pointer to the
 		       	 context
     not_api - the function is not native gl api
	Introduction:
	-------------
	The emugen tool is a tool to generate a wire protocol implementation
	based on provided API. The tool generates c++ encoder code that takes
	API calls and encodes them into the wire and decoder code that decodes
	the wire stream and calls server matching API.
	The emugen tool includes additional functionality that enables to
	generate an wrapper library. The wrapper library provides entry points
	for the specified API, where each entry routes the call via a dispatch
	table. The dispatch table may be initialized as required by a specific application.

	The following paragraphs includes the following:
	* Wire Protocol Description
	* Input files description & format
	* Generated code description.


	Note: In this document, the caller is referred to as Encoder or Client
	and the callee is referred to as the Decoder or Server. These terms
	are used interchangeably by the context.



	Wire Protocol packet structure:
	-------------------------------
	A general Encoder->Decoder packet is structured as following:
	struct Packet {
	unsigned int opcode;
	unsigned int packet_len;
	… parameter 1
	… parameter 2
	};
	A general Decoder->Encoder reply is expected to be received in the
	context of the ‘call’ that triggered it, thus it includes the reply
	data only, with no context headers. In precise term terms, a reply
	packet will look like:

	struct {
	...// reply data
	};

	consider the following function call:
	int foo(int p1, short s1)
	will be encoded into :
	{
	101, // foo opcode
	14, // sizeof(opcode) + sizeof(packet_len) + sizeof(int) + sizeof(short)
	p1, // 4 bytes
	s1 // 2 bytes
	}

	Since ‘foo’ returns value, the caller is expected to read back the return packet from the server->client stream. The return value in this example is in thus the return packet is:
	{
	int retval;
	}


	Pointer decoding:
	----------------
	The wire protocol also allows exchanging of pointer data
	(arrays). Pointers are defined with directions:

	in : Data is sent from the caller to the calle
	out: Data is sent from the callee to the caller
	in_out: data is sent from the caller and return in place.

	‘in’ and ‘in_out’ encoded with their len:
	{
	unsinged int pointer_data_len;
	unsigned char data[pointer_data_len];… // pointer data
	}

	‘out’ pointers are encoded by data length only:
	{
	unsigned int pointer_data_len;
	}

	‘out’ and ‘in_out’ pointer’s data is returned in the return
	packet. For example, consider the following call:

	int foo(int n, int *ptr); // assume that ‘data’ is in_out pointer which contains ‘n’ ints

	The caller packet will have the following form:
	{
	101, // foo opcode
	xx, sizeof(opcode) + sizeof(datalen) + sizeof(int) + sizeof(unsigned int) + n * sizeof(int);
	n, // the n parameter
	n * sizeof(int), // size of the data in ptr
	… // n* sizeof(int) bytes
	}

	The return packet is;
	{
	…. // n * sizeof(int) bytes of data return in ptr
	retval // sizeof(int) - the return value of the function;
	}

	Endianess
	---------
	The Wire protocol is designed to impose minimum overhead on the client
	side. Thus, the data endianness that is sent across the wire is
	determined by the ‘client’ side. It is up to the server side to
	determine the client endianess and marshal the packets as required.



	Emugen input files - protocol specification
	-------------------------------------------
	The protocol generated by emugen consists of two input files:

	1. basename.in - A sepcification of the protocol RPC procedures. This
	part of the specification is expected to be generated automatically
	from c/c++ header files or similar.

	‘basename’ is the basename for the protocol and will be used to prefix
	the files that are generated for this protocol. A line in the .in
	file has the following format:

	[prefix](retvalType, FuncName, <param type> [param name],...)
	where
	retvalType - The function return value type
	FuncName - function name
	<param type> mandatory parameter type
	[param name] - optional parameter name
	Examples:
	GL_ENTRY(void, glVertex1f, float v)
	XXX(int *, foo, int n, float, short)
	XXX(void, glFlush, void)

	Note: Empty lines in the file are ignored. A line starts with # is a comment

	2. basename.attrib - Attributes information of the API.
	This file includes additional flags, pointers datalen information and
	global attributes of the protocol. For uptodate format of the file,
	please refer to the specification file in the project source
	tree. The format of the .attrib file is described below.

	3. basename.types - Types information

	This files describes the types that are described by the API. A type
	is defined as follows:
	<type name> <size in bits> <print format string> <is a pointer? true\|false>
	where:
	<type name> is the name of the type as described in the API
	<size in bits> 0, 8, 16, 32 sizes are accepted
	<print format string> a string to format the value of the type, as
	acceted by printf(3)
	<is pointer?> true or false string species whether the type should be
	treated as a pointer.

	example:
	GLint 32 %d false
	GLint* 32 %p true
	GLptr 32 %p true

	Encoder generated code files
	----------------------------
	In order to generate the encoder files, one should run the ‘emugen’
	tool as follows:

	emugen -i <input directory> -E <encoder files output directory> <basename>
	where:
	<input directory> containes the api specification files (basename.in + basename.attrib)
	<encoder directory> - a directory name to generate the encoder output files
	basename - The basename for the api.

	Assuming the basename is ‘api’, The following files are generated:

	api_opcodes.h - defines the protocol opcodes. The first opcode value
	is 0, unless defined otherwise in the .attrib file

	api_entry.cpp - defines entry points for the functions that are
	defined by the protocol. this File also includes a function call
	‘setContextAccessor(void (f)()). This function should be used to
	provide a callback function that is used by the functions to access
	the encoder context. For example, such callback could fetch the
	context from a Thread Local Storage (TLS) location.

	api_client_proc.h - type defintions for the protocol procedures.

	api_client_context.h - defines the client side dispatch table data
	structure that stores the encoding functions. This data structure also
	includes ‘accessors’ methods such that library user can override
	default entries for special case handling.

	api_client_context.cpp - defines an initialization function for
	dispatch table

	api_enc.h - This header file defines the encoder data strcuture. The
	encoder data structure inherits its functionality from the
	‘client_context’ class above and adds encoding and streaming
	functionality.

	api_enc.cpp - Encoder implementation.

	Decoder generated files
	-----------------------
	In order to generate the decoder files, one should run the ‘emugen’
	tool as follows:
	emugen -i <input directory> -D <decoder files output directory> basename
	where:
	<input directory> containes the api specification files (basename.in + basename.attrib)
	<decoder directory> - a directory name to generate the decoder output files
	basename - The basename for the api.

	With resepct to the example above, Emugen will generate the following
	files:

	api_opcodes.h - Protocol opcodes

	api_server_proc.h - type definitions for the server side procedures

	api_server_context.h - dispatch table the decoder functions

	api_server_context.cpp - dispatch table initialization function
	api_dec.h - Decoder header file

	api_dec.cpp - Decoder implementation. In addtion, this file includes
	an intiailization function that uses a user provided callback to
	initialize the API server implementation. An example for such
	initialization is loading a set of functions from a shared library
	module.

	Wrapper generated files
	-----------------------
	In order to generate a wrapper library files, one should run the
	'emugen' tool as follows:

	emugen -i <input directory> -W <wrapper files output directory> basename
	where:
	<input directory> containes the api specification files (basename.in + basename.attrib)
	<wrapper directory> - a directory name to generate the wrapper output files
	basename - The basename for the api.

	With resepct to the example above, Emugen will generate the following
	files:

	api_wrapper_proc.h - type definitions for the wrapper procedures

	api_wrapper_context.h - dispatch table the wrapper functions

	api_wrapper_context.cpp - dispatch table initialization function
	api_wrapper_entry.cpp - entry points for the API


	.attrib file format description:
	-------------------------------
	The .attrib file is an input file to emugen and is used to provide
	additional information that is required for the code generation.
	The file format is as follows:

	a line that starts with # is ignored (comment)
	a empty line just whitespace of (" " "\t" "\n") is ignored.

	The file is divided into 'sections', each describes a specific API
	function call. A section starts with the name of the function in
	column 0.

	A section that starts with the reserved word 'GLOBAL' provides global
	attributes.

	below are few sections examples:

	GLOBAL
	encoder_headers string.h kuku.h

	glVertex3fv
	len data (size)
	glTexImage2D
	len pixels (pixels == NULL? 0 : (format_pixel_size(internalformat) * width * height * type_size(type)))


	Global section flags description:

	base_opcode
	set the base opcode value for this api
	format: base_opcode 100

	encoder_headers
	a list of headers that will be included in the encoder header file
	format: encoder_headers <stdio.h> "kuku.h"

	client_context_headers
	a list of headers that will be included in the client context header file
	format: client_context_headers <stdio.h> "kuku.h"

	decoder_headers
	a list of headers that will be included in the decoder header file
	format: decoder_headers <stdio.h> "kuku.h"

	server_context_headers
	a list of headers that will be included in the server context header file
	format: server_context_headers <stdio.h> "kuku.h"


	Entry point flags description:

	len
	desciption : provide an expression to calcualte an expression data len
	format: len <var name> <c expression that calcluates the data len>

	custom_pack
	description: provide an expression to pack data into the stream.
	format: custom_pack <var name> <c++ expression that pack data from var into the stream>
	The stream is represented by a (unsigned char *)ptr. The expression may also refer
	to other function parameters. In addition, the expression may refer to 'void *self' which
	is the encoding context as provided by the caller.

	dir
	description : set a pointer direction (in - for data that goes
	to the codec, out from data that returns from the codec.
	format: dir <varname> <[in \| out \| inout]>

	var_flag
	description : set variable flags
	format: var_flag <varname> < nullAllowed \| isLarge \| ... >

	nullAllowed -> for pointer variables, indicates that NULL is a valid value
	isLarge -> for pointer variables, indicates that the data should be sent without an intermediate copy

	flag
	description: set entry point flag;
	format: flag < unsupported \| ... >
	supported flags are:
	unsupported - The encoder side implementation is pointed to "unsuppored reporting function".
	custom_decoder - The decoder is expected to be provided with
	custom implementation. The call to the
	deocder function includes a pointer to the
	context
	not_api - the function is not native gl api