README.coding - platform/external/libwebsockets - Git at Google

 Daemonization
 -------------

 There's a helper api lws_daemonize built by default that does everything you
 need to daemonize well, including creating a lock file.  If you're making
 what's basically a daemon, just call this early in your init to fork to a
 headless background process and exit the starting process.

 Notice stdout, stderr, stdin are all redirected to /dev/null to enforce your
 daemon is headless, so you'll need to sort out alternative logging, by, eg,
 syslog.


 Maximum number of connections
 -----------------------------

 The maximum number of connections the library can deal with is decided when
 it starts by querying the OS to find out how many file descriptors it is
 allowed to open (1024 on Fedora for example).  It then allocates arrays that
 allow up to that many connections, minus whatever other file descriptors are
 in use by the user code.

 If you want to restrict that allocation, or increase it, you can use ulimit or
 similar to change the avaiable number of file descriptors, and when restarted
 libwebsockets will adapt accordingly.


 Libwebsockets is singlethreaded
 -------------------------------

 Directly performing websocket actions from other threads is not allowed.
 Aside from the internal data being inconsistent in forked() processes,
 the scope of a wsi (struct websocket) can end at any time during service
 with the socket closing and the wsi freed.

 Websocket write activities should only take place in the
 "LWS_CALLBACK_SERVER_WRITEABLE" callback as described below.

 Only live connections appear in the user callbacks, so this removes any
 possibility of trying to used closed and freed wsis.

 If you need to service other socket or file descriptors as well as the
 websocket ones, you can combine them together with the websocket ones
 in one poll loop, see "External Polling Loop support" below, and
 still do it all in one thread / process context.


 Only send data when socket writeable
 ------------------------------------

 You should only send data on a websocket connection from the user callback
 "LWS_CALLBACK_SERVER_WRITEABLE" (or "LWS_CALLBACK_CLIENT_WRITEABLE" for
 clients).

 If you want to send something, do not just send it but request a callback
 when the socket is writeable using

  - libwebsocket_callback_on_writable(context, wsi) for a specific wsi, or
  - libwebsocket_callback_on_writable_all_protocol(protocol) for all connections
 using that protocol to get a callback when next writeable.

 Usually you will get called back immediately next time around the service
 loop, but if your peer is slow or temporarily inactive the callback will be
 delayed accordingly.  Generating what to write and sending it should be done
 in the ...WRITEABLE callback.

 See the test server code for an example of how to do this.


 Fragmented messages
 -------------------

 To support fragmented messages you need to check for the final
 frame of a message with libwebsocket_is_final_fragment. This
 check can be combined with libwebsockets_remaining_packet_payload
 to gather the whole contents of a message, eg:

     case LWS_CALLBACK_RECEIVE:
     {
         Client * const client = (Client *)user;
         const size_t remaining = libwebsockets_remaining_packet_payload(wsi);

         if (!remaining && libwebsocket_is_final_fragment(wsi)) {
             if (client->HasFragments()) {
                 client->AppendMessageFragment(in, len, 0);
                 in = (void *)client->GetMessage();
                 len = client->GetMessageLength();
             }

             client->ProcessMessage((char *)in, len, wsi);
             client->ResetMessage();
         } else
             client->AppendMessageFragment(in, len, remaining);
     }
     break;

 The test app llibwebsockets-test-fraggle sources also show how to
 deal with fragmented messages.


 Debug Logging
 -------------

 Also using lws_set_log_level api you may provide a custom callback to actually
 emit the log string.  By default, this points to an internal emit function
 that sends to stderr.  Setting it to NULL leaves it as it is instead.

 A helper function lwsl_emit_syslog() is exported from the library to simplify
 logging to syslog.  You still need to use setlogmask, openlog and closelog
 in your user code.

 The logging apis are made available for user code.

 lwsl_err(...)
 lwsl_warn(...)
 lwsl_notice(...)
 lwsl_info(...)
 lwsl_debug(...)

 The difference between notice and info is that notice will be logged by default
 whereas info is ignored by default.


 External Polling Loop support
 -----------------------------

 libwebsockets maintains an internal poll() array for all of its
 sockets, but you can instead integrate the sockets into an
 external polling array.  That's needed if libwebsockets will
 cooperate with an existing poll array maintained by another
 server.

 Four callbacks LWS_CALLBACK_ADD_POLL_FD, LWS_CALLBACK_DEL_POLL_FD,
 LWS_CALLBACK_SET_MODE_POLL_FD and LWS_CALLBACK_CLEAR_MODE_POLL_FD
 appear in the callback for protocol 0 and allow interface code to
 manage socket descriptors in other poll loops.
	Daemonization
	-------------

	There's a helper api lws_daemonize built by default that does everything you
	need to daemonize well, including creating a lock file. If you're making
	what's basically a daemon, just call this early in your init to fork to a
	headless background process and exit the starting process.

	Notice stdout, stderr, stdin are all redirected to /dev/null to enforce your
	daemon is headless, so you'll need to sort out alternative logging, by, eg,
	syslog.


	Maximum number of connections
	-----------------------------

	The maximum number of connections the library can deal with is decided when
	it starts by querying the OS to find out how many file descriptors it is
	allowed to open (1024 on Fedora for example). It then allocates arrays that
	allow up to that many connections, minus whatever other file descriptors are
	in use by the user code.

	If you want to restrict that allocation, or increase it, you can use ulimit or
	similar to change the avaiable number of file descriptors, and when restarted
	libwebsockets will adapt accordingly.


	Libwebsockets is singlethreaded
	-------------------------------

	Directly performing websocket actions from other threads is not allowed.
	Aside from the internal data being inconsistent in forked() processes,
	the scope of a wsi (struct websocket) can end at any time during service
	with the socket closing and the wsi freed.

	Websocket write activities should only take place in the
	"LWS_CALLBACK_SERVER_WRITEABLE" callback as described below.

	Only live connections appear in the user callbacks, so this removes any
	possibility of trying to used closed and freed wsis.

	If you need to service other socket or file descriptors as well as the
	websocket ones, you can combine them together with the websocket ones
	in one poll loop, see "External Polling Loop support" below, and
	still do it all in one thread / process context.


	Only send data when socket writeable
	------------------------------------

	You should only send data on a websocket connection from the user callback
	"LWS_CALLBACK_SERVER_WRITEABLE" (or "LWS_CALLBACK_CLIENT_WRITEABLE" for
	clients).

	If you want to send something, do not just send it but request a callback
	when the socket is writeable using

	- libwebsocket_callback_on_writable(context, wsi) for a specific wsi, or
	- libwebsocket_callback_on_writable_all_protocol(protocol) for all connections
	using that protocol to get a callback when next writeable.

	Usually you will get called back immediately next time around the service
	loop, but if your peer is slow or temporarily inactive the callback will be
	delayed accordingly. Generating what to write and sending it should be done
	in the ...WRITEABLE callback.

	See the test server code for an example of how to do this.


	Fragmented messages
	-------------------

	To support fragmented messages you need to check for the final
	frame of a message with libwebsocket_is_final_fragment. This
	check can be combined with libwebsockets_remaining_packet_payload
	to gather the whole contents of a message, eg:

	case LWS_CALLBACK_RECEIVE:
	{
	Client * const client = (Client *)user;
	const size_t remaining = libwebsockets_remaining_packet_payload(wsi);

	if (!remaining && libwebsocket_is_final_fragment(wsi)) {
	if (client->HasFragments()) {
	client->AppendMessageFragment(in, len, 0);
	in = (void *)client->GetMessage();
	len = client->GetMessageLength();
	}

	client->ProcessMessage((char *)in, len, wsi);
	client->ResetMessage();
	} else
	client->AppendMessageFragment(in, len, remaining);
	}
	break;

	The test app llibwebsockets-test-fraggle sources also show how to
	deal with fragmented messages.


	Debug Logging
	-------------

	Also using lws_set_log_level api you may provide a custom callback to actually
	emit the log string. By default, this points to an internal emit function
	that sends to stderr. Setting it to NULL leaves it as it is instead.

	A helper function lwsl_emit_syslog() is exported from the library to simplify
	logging to syslog. You still need to use setlogmask, openlog and closelog
	in your user code.

	The logging apis are made available for user code.

	lwsl_err(...)
	lwsl_warn(...)
	lwsl_notice(...)
	lwsl_info(...)
	lwsl_debug(...)

	The difference between notice and info is that notice will be logged by default
	whereas info is ignored by default.


	External Polling Loop support
	-----------------------------

	libwebsockets maintains an internal poll() array for all of its
	sockets, but you can instead integrate the sockets into an
	external polling array. That's needed if libwebsockets will
	cooperate with an existing poll array maintained by another
	server.

	Four callbacks LWS_CALLBACK_ADD_POLL_FD, LWS_CALLBACK_DEL_POLL_FD,
	LWS_CALLBACK_SET_MODE_POLL_FD and LWS_CALLBACK_CLEAR_MODE_POLL_FD
	appear in the callback for protocol 0 and allow interface code to
	manage socket descriptors in other poll loops.