doc/internals/buffer-operations.txt - haproxy - Gitiles

 2012/02/27 - Operations on haproxy buffers - w@1wt.eu


 1) Definitions
 --------------

 A buffer is a unidirectional storage between two stream interfaces which are
 most often composed of a socket file descriptor. This storage is fixed sized
 and circular, which means that once data reach the end of the buffer, it loops
 back at the beginning of the buffer :


    Representation of a non-wrapping buffer
    ---------------------------------------


            beginning                             end
                |    -------- length -------->     |
                V                                  V
            +-------------------------------------------+
            |  <--------------- size ---------------->  |
            +-------------------------------------------+


    Representation of a wrapping buffer
    -----------------------------------

                end                     beginning
       +------>  |                          |  -------------+
       |         V                          V               |
       |    +-------------------------------------------+   |
       |    |  <--------------- size ---------------->  |   |
       |    +-------------------------------------------+   |
       |                                                    |
       +--------------------- length -----------------------+


 Buffers are read by two entities :
   - stream interfaces
   - analysers

 Buffers are filled by two entities :
   - stream interfaces
   - hijackers

 A stream interface writes at the input of a buffer and reads at its output. An
 analyser has to parse incoming buffer contents, so it reads the input. It does
 not really write the output though it may change the buffer's contents at the
 input, possibly causing data moves. A hijacker it able to write at the output
 of a buffer. Hijackers are not used anymore at the moment though error outputs
 still work the same way.

 Buffers are referenced in the session. Each session has two buffers which
 interconnect the two stream interfaces. One buffer is called the request
 buffer, it sees traffic flowing from the client to the server. The other buffer
 is the response buffer, it sees traffic flowing from the server to the client.

 By convention, sessions are represented as 2 buffers one on top of the other,
 and with 2 stream interfaces connected to the two buffers. The client connects
 to the left stream interface (which then acts as a server), and the right
 stream interface (which acts as a client) connects to the server. The data
 circulate clockwise, so the upper buffer is the request buffer and the lower
 buffer is the response buffer :

                        ,------------------------.
                ,-----> |    request buffer      | ------.
    from   ,--./        `------------------------'        \,--.    to
   client (    )                                          (    ) server
           `--'         ,------------------------.        /`--'
               ^------- |    response buffer     | <-----'
                        `------------------------'

 2) Operations
 -------------

 Socket-based stream interfaces write to buffers directly from the I/O layer
 without relying on any specific function.

 Function-based stream interfaces do use a number of non-uniform functions to
 read from the buffer's output and to write to the buffer's input. More suited
 names could be :

         int buffer_output_peek_at(buf, ofs, ptr, size);
         int buffer_output_peek(buf, ptr, size);
         int buffer_output_read(buf, ptr, size);
         int buffer_output_skip(buf, size);
         int buffer_input_write(buf, ptr, size);

 Right now some stream interfaces use the following functions which also happen
 to automatically schedule the response for automatic forward :

     buffer_put_block()   [peers]
     buffer_put_chunk() -> buffer_put_block()
     buffer_feed_chunk() -> buffer_put_chunk() -> buffer_put_block() [dumpstats]
     buffer_feed() -> buffer_put_string() -> buffer_put_block()      [dumpstats]


 The following stream-interface oriented functions are not used :

     buffer_get_char()
     buffer_write_chunk()


 Analysers read data from the buffers' input, and may sometimes write data
 there too (or trim data). More suited names could be :

         int buffer_input_peek_at(buf, ofs, ptr, size);
         int buffer_input_truncate_at(buf, ofs);
         int buffer_input_peek(buf, ptr, size);
         int buffer_input_read(buf, ptr, size);
         int buffer_input_skip(buf, size);
         int buffer_input_cut(buf, size);
         int buffer_input_truncate(buf);


 Functions that are available and need to be renamed :
   - buffer_skip     : buffer_output_skip
   - buffer_ignore   : buffer_input_skip ?  => not exactly, more like
                       buffer_output_skip() without affecting sendmax !
   - buffer_cut_tail : deletes all pending data after sendmax.
                       -> buffer_input_truncate(). Used by si_retnclose() only.
   - buffer_contig_data : buffer_output_contig_data
   - buffer_pending  : buffer_input_pending_data
   - buffer_contig_space : buffer_input_contig_space


 It looks like buf->lr could be removed and be stored in the HTTP message struct
 since it's only used at the HTTP level.
	2012/02/27 - Operations on haproxy buffers - w@1wt.eu


	1) Definitions
	--------------

	A buffer is a unidirectional storage between two stream interfaces which are
	most often composed of a socket file descriptor. This storage is fixed sized
	and circular, which means that once data reach the end of the buffer, it loops
	back at the beginning of the buffer :


	Representation of a non-wrapping buffer
	---------------------------------------


	beginning end
	\| -------- length --------> \|
	V V
	+-------------------------------------------+
	\| <--------------- size ----------------> \|
	+-------------------------------------------+


	Representation of a wrapping buffer
	-----------------------------------

	end beginning
	+------> \| \| -------------+
	\| V V \|
	\| +-------------------------------------------+ \|
	\| \| <--------------- size ----------------> \| \|
	\| +-------------------------------------------+ \|
	\| \|
	+--------------------- length -----------------------+


	Buffers are read by two entities :
	- stream interfaces
	- analysers

	Buffers are filled by two entities :
	- stream interfaces
	- hijackers

	A stream interface writes at the input of a buffer and reads at its output. An
	analyser has to parse incoming buffer contents, so it reads the input. It does
	not really write the output though it may change the buffer's contents at the
	input, possibly causing data moves. A hijacker it able to write at the output
	of a buffer. Hijackers are not used anymore at the moment though error outputs
	still work the same way.

	Buffers are referenced in the session. Each session has two buffers which
	interconnect the two stream interfaces. One buffer is called the request
	buffer, it sees traffic flowing from the client to the server. The other buffer
	is the response buffer, it sees traffic flowing from the server to the client.

	By convention, sessions are represented as 2 buffers one on top of the other,
	and with 2 stream interfaces connected to the two buffers. The client connects
	to the left stream interface (which then acts as a server), and the right
	stream interface (which acts as a client) connects to the server. The data
	circulate clockwise, so the upper buffer is the request buffer and the lower
	buffer is the response buffer :

	,------------------------.
	,-----> \| request buffer \| ------.
	from ,--./ `------------------------' \,--. to
	client ( ) ( ) server
	`--' ,------------------------. /`--'
	^------- \| response buffer \| <-----'
	`------------------------'

	2) Operations
	-------------

	Socket-based stream interfaces write to buffers directly from the I/O layer
	without relying on any specific function.

	Function-based stream interfaces do use a number of non-uniform functions to
	read from the buffer's output and to write to the buffer's input. More suited
	names could be :

	int buffer_output_peek_at(buf, ofs, ptr, size);
	int buffer_output_peek(buf, ptr, size);
	int buffer_output_read(buf, ptr, size);
	int buffer_output_skip(buf, size);
	int buffer_input_write(buf, ptr, size);

	Right now some stream interfaces use the following functions which also happen
	to automatically schedule the response for automatic forward :

	buffer_put_block() [peers]
	buffer_put_chunk() -> buffer_put_block()
	buffer_feed_chunk() -> buffer_put_chunk() -> buffer_put_block() [dumpstats]
	buffer_feed() -> buffer_put_string() -> buffer_put_block() [dumpstats]


	The following stream-interface oriented functions are not used :

	buffer_get_char()
	buffer_write_chunk()


	Analysers read data from the buffers' input, and may sometimes write data
	there too (or trim data). More suited names could be :

	int buffer_input_peek_at(buf, ofs, ptr, size);
	int buffer_input_truncate_at(buf, ofs);
	int buffer_input_peek(buf, ptr, size);
	int buffer_input_read(buf, ptr, size);
	int buffer_input_skip(buf, size);
	int buffer_input_cut(buf, size);
	int buffer_input_truncate(buf);


	Functions that are available and need to be renamed :
	- buffer_skip : buffer_output_skip
	- buffer_ignore : buffer_input_skip ? => not exactly, more like
	buffer_output_skip() without affecting sendmax !
	- buffer_cut_tail : deletes all pending data after sendmax.
	-> buffer_input_truncate(). Used by si_retnclose() only.
	- buffer_contig_data : buffer_output_contig_data
	- buffer_pending : buffer_input_pending_data
	- buffer_contig_space : buffer_input_contig_space


	It looks like buf->lr could be removed and be stored in the HTTP message struct
	since it's only used at the HTTP level.