TODO.txt - external/github.com/Pylons/waitress - Git at Google

 - 0.0.0.0 / IPv6.

 - Speed tweaking.

 - Anticipate multivalue and single-value-only headers in request headers in
   parser.py.

 - Timeout functests.

 - Complex pipelining functests (with intermediate connection: close).

 - Killthreads support.

 - "TCP segment of a reassembled PDU" in wireshark.

 - Jim F. would like the server to log request start, request queue (to thread
   pool), app start, app finish, and request finish (all data has been
   flushed to client) events.

   Some challenges exist trying to divine per-request end time. We currently
   have the potential for request pipelining; the channel might service more
   than one request before it closes.  We currently don't preserve any
   information about which request a response's data belongs to while flushing
   response data from a connection's output buffer.

   While accepting request data from a client, Waitress will obtain N request
   bodies and schedule all the requests it receives with the task manager.
   For example, if it obtains two request bodies in a single recv() call it
   will create two request objects and schedule *both* of these requests to be
   serviced by the task manager immediately.

   The task thread manager will service these synchronously: the first request
   will be run first, then the second.  When the first request runs, it will
   push data to the out buffer, then it will end.  Then the second request
   will run, and push data to the same out buffer, and it will end.  While
   these requests are executing, the channel from whence they came stops
   accepting requests until the previously scheduled requests have actually
   been serviced.  The request-burdened channel will be *sending* data to the
   client while the requests are being serviced, it just won't accept any more
   data until existing requests have been serviced.  In the meantime, other
   channels may still be generating requests and adding tasks to the task
   manager.

   To capture request-end time we could create an output buffer per request or
   we could keep a dictionary of the final bytestream position of the
   outbuffer for each response to to request id; either would be a
   straightforward way to capture the fact that a particular request's
   response data has been flushed.  We currently don't do that though.

   Here's what we can currently log without changing anything:

   An example of the events logged for a connection that receives two requests
   and each request succeeds, and the connection is closed after sending all
   data::

     channel created: channel 1 at time 10
     request created: channel 1, request id 1 at time 11
     request created: channel 1, request id 2 at time 12
     channel requests queued: channel 1, request ids 1,2 at time 13
     request started: request id 1 at time 14
     request serviced: request id 1 at time 15
     request started: request id 2 at time 16
     request serviced: request id 2 at time 17
     channel closed: channel 1 at time 18

   An example of the events logged for a connection that receives two requests
   and the first request fails in such a way that the next request cannot
   proceed (content-length header of the first response does not match number
   of bytes sent in response to the first request, for example)::

     channel created: channel 1 at time 10
     request created: channel 1, request id 1 at time 11
     request created: channel 1, request id 2 at time 12
     channel requests queued: channel 1, request ids 1,2 at time 13
     request started: request id 1 at time 14
     request serviced: request id 1 at time 15
     request cancelled: request id 2 at time 17
     channel closed: channel 1 at time 18

   An example of the events logged for a connection that receives four
   requests (which all succeed in generating successful responses) but where
   the client waits for the first two responses to send the second two
   requests:

     channel created: channel 1 at time 10
     request created: channel 1, request id 1 at time 11
     request created: channel 1, request id 2 at time 12
     channel requests queued: channel 1, request ids 1,2 at time 13
     request started: request id 1 at time 14
     request serviced: request id 1 at time 15
     request started: request id 2 at time 15
     request serviced: request id 2 at time 16
     request created: channel 1, request id 3 at time 17
     request created: channel 1, request id 4 at time 18
     channel requests queued: channel 1, request ids 3,4 at time 18
     request started: request id 3 at time 19
     request serviced: request id 3 at time 20
     request started: request id 4 at time 21
     request serviced: request id 4 at time 22
     channel closed: channel 1 at time 23
	- 0.0.0.0 / IPv6.

	- Speed tweaking.

	- Anticipate multivalue and single-value-only headers in request headers in
	parser.py.

	- Timeout functests.

	- Complex pipelining functests (with intermediate connection: close).

	- Killthreads support.

	- "TCP segment of a reassembled PDU" in wireshark.

	- Jim F. would like the server to log request start, request queue (to thread
	pool), app start, app finish, and request finish (all data has been
	flushed to client) events.

	Some challenges exist trying to divine per-request end time. We currently
	have the potential for request pipelining; the channel might service more
	than one request before it closes. We currently don't preserve any
	information about which request a response's data belongs to while flushing
	response data from a connection's output buffer.

	While accepting request data from a client, Waitress will obtain N request
	bodies and schedule all the requests it receives with the task manager.
	For example, if it obtains two request bodies in a single recv() call it
	will create two request objects and schedule both of these requests to be
	serviced by the task manager immediately.

	The task thread manager will service these synchronously: the first request
	will be run first, then the second. When the first request runs, it will
	push data to the out buffer, then it will end. Then the second request
	will run, and push data to the same out buffer, and it will end. While
	these requests are executing, the channel from whence they came stops
	accepting requests until the previously scheduled requests have actually
	been serviced. The request-burdened channel will be sending data to the
	client while the requests are being serviced, it just won't accept any more
	data until existing requests have been serviced. In the meantime, other
	channels may still be generating requests and adding tasks to the task
	manager.

	To capture request-end time we could create an output buffer per request or
	we could keep a dictionary of the final bytestream position of the
	outbuffer for each response to to request id; either would be a
	straightforward way to capture the fact that a particular request's
	response data has been flushed. We currently don't do that though.

	Here's what we can currently log without changing anything:

	An example of the events logged for a connection that receives two requests
	and each request succeeds, and the connection is closed after sending all
	data::

	channel created: channel 1 at time 10
	request created: channel 1, request id 1 at time 11
	request created: channel 1, request id 2 at time 12
	channel requests queued: channel 1, request ids 1,2 at time 13
	request started: request id 1 at time 14
	request serviced: request id 1 at time 15
	request started: request id 2 at time 16
	request serviced: request id 2 at time 17
	channel closed: channel 1 at time 18

	An example of the events logged for a connection that receives two requests
	and the first request fails in such a way that the next request cannot
	proceed (content-length header of the first response does not match number
	of bytes sent in response to the first request, for example)::

	channel created: channel 1 at time 10
	request created: channel 1, request id 1 at time 11
	request created: channel 1, request id 2 at time 12
	channel requests queued: channel 1, request ids 1,2 at time 13
	request started: request id 1 at time 14
	request serviced: request id 1 at time 15
	request cancelled: request id 2 at time 17
	channel closed: channel 1 at time 18

	An example of the events logged for a connection that receives four
	requests (which all succeed in generating successful responses) but where
	the client waits for the first two responses to send the second two
	requests:

	channel created: channel 1 at time 10
	request created: channel 1, request id 1 at time 11
	request created: channel 1, request id 2 at time 12
	channel requests queued: channel 1, request ids 1,2 at time 13
	request started: request id 1 at time 14
	request serviced: request id 1 at time 15
	request started: request id 2 at time 15
	request serviced: request id 2 at time 16
	request created: channel 1, request id 3 at time 17
	request created: channel 1, request id 4 at time 18
	channel requests queued: channel 1, request ids 3,4 at time 18
	request started: request id 3 at time 19
	request serviced: request id 3 at time 20
	request started: request id 4 at time 21
	request serviced: request id 4 at time 22
	channel closed: channel 1 at time 23