Doc/lib/libasynchat.tex - platform/external/python/cpython3 - Gitiles

 \section{\module{asynchat} ---
          Asynchronous socket command/response handler}

 \declaremodule{standard}{asynchat}
 \modulesynopsis{Support for asynchronous command/response protocols.}
 \moduleauthor{Sam Rushing}{rushing@nightmare.com}
 \sectionauthor{Steve Holden}{sholden@holdenweb.com}

 This module builds on the \refmodule{asyncore} infrastructure,
 simplifying asynchronous clients and servers and making it easier to
 handle protocols whose elements are terminated by arbitrary strings, or
 are of variable length. \refmodule{asynchat} defines the abstract class
 \class{async_chat} that you subclass, providing implementations of the
 \method{collect_incoming_data()} and \method{found_terminator()}
 methods. It uses the same asynchronous loop as \refmodule{asyncore}, and
 the two types of channel, \class{asyncore.dispatcher} and
 \class{asynchat.async_chat}, can freely be mixed in the channel map.
 Typically an \class{asyncore.dispatcher} server channel generates new
 \class{asynchat.async_chat} channel objects as it receives incoming
 connection requests.

 \begin{classdesc}{async_chat}{}
   This class is an abstract subclass of \class{asyncore.dispatcher}. To make
   practical use of the code you must subclass \class{async_chat}, providing
   meaningful \method{collect_incoming_data()} and \method{found_terminator()}
   methods. The \class{asyncore.dispatcher} methods can be
   used, although not all make sense in a message/response context.

   Like \class{asyncore.dispatcher}, \class{async_chat} defines a set of events
   that are generated by an analysis of socket conditions after a
   \cfunction{select()} call. Once the polling loop has been started the
   \class{async_chat} object's methods are called by the event-processing
   framework with no action on the part of the programmer.

   Unlike \class{asyncore.dispatcher}, \class{async_chat} allows you to define
   a first-in-first-out queue (fifo) of \emph{producers}. A producer need have
   only one method, \method{more()}, which should return data to be transmitted
   on the channel. The producer indicates exhaustion (\emph{i.e.} that it contains
   no more data) by having its \method{more()} method return the empty string. At
   this point the \class{async_chat} object removes the producer from the fifo
   and starts using the next producer, if any. When the producer fifo is empty
   the \method{handle_write()} method does nothing. You use the channel object's
   \method{set_terminator()} method to describe how to recognize the end
   of, or an important breakpoint in, an incoming transmission from the
   remote endpoint.

   To build a functioning \class{async_chat} subclass your
   input methods \method{collect_incoming_data()} and
   \method{found_terminator()} must handle the data that the channel receives
   asynchronously. The methods are described below.
 \end{classdesc}

 \begin{methoddesc}{close_when_done}{}
   Pushes a \code{None} on to the producer fifo. When this producer is
   popped off the fifo it causes the channel to be closed.
 \end{methoddesc}

 \begin{methoddesc}{collect_incoming_data}{data}
   Called with \var{data} holding an arbitrary amount of received data.
   The default method, which must be overridden, raises a \exception{NotImplementedError} exception.
 \end{methoddesc}

 \begin{methoddesc}{discard_buffers}{}
   In emergencies this method will discard any data held in the input and/or
   output buffers and the producer fifo.
 \end{methoddesc}

 \begin{methoddesc}{found_terminator}{}
   Called when the incoming data stream  matches the termination condition
   set by \method{set_terminator}. The default method, which must be overridden,
   raises a \exception{NotImplementedError} exception. The buffered input data should
   be available via an instance attribute.
 \end{methoddesc}

 \begin{methoddesc}{get_terminator}{}
   Returns the current terminator for the channel.
 \end{methoddesc}

 \begin{methoddesc}{handle_close}{}
   Called when the channel is closed. The default method silently closes
   the channel's socket.
 \end{methoddesc}

 \begin{methoddesc}{handle_read}{}
   Called when a read event fires on the channel's socket in the
   asynchronous loop. The default method checks for the termination
   condition established by \method{set_terminator()}, which can be either
   the appearance of a particular string in the input stream or the receipt
   of a particular number of characters. When the terminator is found,
   \method{handle_read} calls the \method{found_terminator()} method after
   calling \method{collect_incoming_data()} with any data preceding the
   terminating condition.
 \end{methoddesc}

 \begin{methoddesc}{handle_write}{}
   Called when the application may write data to the channel.
   The default method calls the \method{initiate_send()} method, which in turn
   will call \method{refill_buffer()} to collect data from the producer
   fifo associated with the channel.
 \end{methoddesc}

 \begin{methoddesc}{push}{data}
   Creates a \class{simple_producer} object (\emph{see below}) containing the data and
   pushes it on to the channel's \code{producer_fifo} to ensure its
   transmission. This is all you need to do to have the channel write
   the data out to the network, although it is possible to use your
   own producers in more complex schemes to implement encryption and
   chunking, for example.
 \end{methoddesc}

 \begin{methoddesc}{push_with_producer}{producer}
   Takes a producer object and adds it to the producer fifo associated with
   the channel. When all currently-pushed producers have been exhausted
   the channel will consume this producer's data by calling its
   \method{more()} method and send the data to the remote endpoint.
 \end{methoddesc}

 \begin{methoddesc}{readable}{}
   Should return \code{True} for the channel to be included in the set of
   channels tested by the \cfunction{select()} loop for readability.
 \end{methoddesc}

 \begin{methoddesc}{refill_buffer}{}
   Refills the output buffer by calling the \method{more()} method of the
   producer at the head of the fifo. If it is exhausted then the
   producer is popped off the fifo and the next producer is activated.
   If the current producer is, or becomes, \code{None} then the channel
   is closed.
 \end{methoddesc}

 \begin{methoddesc}{set_terminator}{term}
   Sets the terminating condition to be recognised on the channel. \code{term}
   may be any of three types of value, corresponding to three different ways
   to handle incoming protocol data.

   \begin{tableii}{l|l}{}{term}{Description}
     \lineii{\emph{string}}{Will call \method{found_terminator()} when the
                 string is found in the input stream}
     \lineii{\emph{integer}}{Will call \method{found_terminator()} when the
                 indicated number of characters have been received}
     \lineii{\code{None}}{The channel continues to collect data forever}
   \end{tableii}

   Note that any data following the terminator will be available for reading by
   the channel after \method{found_terminator()} is called.
 \end{methoddesc}

 \begin{methoddesc}{writable}{}
   Should return \code{True} as long as items remain on the producer fifo,
   or the channel is connected and the channel's output buffer is non-empty.
 \end{methoddesc}

 \subsection{asynchat - Auxiliary Classes and Functions}

 \begin{classdesc}{simple_producer}{data\optional{, buffer_size=512}}
   A \class{simple_producer} takes a chunk of data and an optional buffer size.
   Repeated calls to its \method{more()} method yield successive chunks of the
   data no larger than \var{buffer_size}.
 \end{classdesc}

 \begin{methoddesc}{more}{}
   Produces the next chunk of information from the producer, or returns the empty string.
 \end{methoddesc}

 \begin{classdesc}{fifo}{\optional{list=None}}
   Each channel maintains a \class{fifo} holding data which has been pushed by the
   application but not yet popped for writing to the channel.
   A \class{fifo} is a list used to hold data and/or producers until they are required.
   If the \var{list} argument is provided then it should contain producers or
   data items to be written to the channel.
 \end{classdesc}

 \begin{methoddesc}{is_empty}{}
   Returns \code{True} iff the fifo is empty.
 \end{methoddesc}

 \begin{methoddesc}{first}{}
   Returns the least-recently \method{push()}ed item from the fifo.
 \end{methoddesc}

 \begin{methoddesc}{push}{data}
   Adds the given data (which may be a string or a producer object) to the
   producer fifo.
 \end{methoddesc}

 \begin{methoddesc}{pop}{}
   If the fifo is not empty, returns \code{True, first()}, deleting the popped
   item. Returns \code{False, None} for an empty fifo.
 \end{methoddesc}

 The \module{asynchat} module also defines one utility function, which may be
 of use in network and textual analysis operations.

 \begin{funcdesc}{find_prefix_at_end}{haystack, needle}
   Returns \code{True} if string \var{haystack} ends with any non-empty
   prefix of string \var{needle}.
 \end{funcdesc}

 \subsection{asynchat Example \label{asynchat-example}}

 The following partial example shows how HTTP requests can be read with
 \class{async_chat}. A web server might create an \class{http_request_handler} object for
 each incoming client connection. Notice that initially the
 channel terminator is set to match the blank line at the end of the HTTP
 headers, and a flag indicates that the headers are being read.

 Once the headers have been read, if the request is of type POST
 (indicating that further data are present in the input stream) then the
 \code{Content-Length:} header is used to set a numeric terminator to
 read the right amount of data from the channel.

 The \method{handle_request()} method is called once all relevant input
 has been marshalled, after setting the channel terminator to \code{None}
 to ensure that any extraneous data sent by the web client are ignored.

 \begin{verbatim}
 class http_request_handler(asynchat.async_chat):

     def __init__(self, conn, addr, sessions, log):
         asynchat.async_chat.__init__(self, conn=conn)
         self.addr = addr
         self.sessions = sessions
         self.ibuffer = []
         self.obuffer = ""
         self.set_terminator("\r\n\r\n")
         self.reading_headers = True
         self.handling = False
         self.cgi_data = None
         self.log = log

     def collect_incoming_data(self, data):
         """Buffer the data"""
         self.ibuffer.append(data)

     def found_terminator(self):
         if self.reading_headers:
             self.reading_headers = False
             self.parse_headers("".join(self.ibuffer))
             self.ibuffer = []
             if self.op.upper() == "POST":
                 clen = self.headers.getheader("content-length")
                 self.set_terminator(int(clen))
             else:
                 self.handling = True
                 self.set_terminator(None)
                 self.handle_request()
         elif not self.handling:
             self.set_terminator(None) # browsers sometimes over-send
             self.cgi_data = parse(self.headers, "".join(self.ibuffer))
             self.handling = True
             self.ibuffer = []
             self.handle_request()
 \end{verbatim}
	\section{\module{asynchat} ---
	Asynchronous socket command/response handler}

	\declaremodule{standard}{asynchat}
	\modulesynopsis{Support for asynchronous command/response protocols.}
	\moduleauthor{Sam Rushing}{rushing@nightmare.com}
	\sectionauthor{Steve Holden}{sholden@holdenweb.com}

	This module builds on the \refmodule{asyncore} infrastructure,
	simplifying asynchronous clients and servers and making it easier to
	handle protocols whose elements are terminated by arbitrary strings, or
	are of variable length. \refmodule{asynchat} defines the abstract class
	\class{async_chat} that you subclass, providing implementations of the
	\method{collect_incoming_data()} and \method{found_terminator()}
	methods. It uses the same asynchronous loop as \refmodule{asyncore}, and
	the two types of channel, \class{asyncore.dispatcher} and
	\class{asynchat.async_chat}, can freely be mixed in the channel map.
	Typically an \class{asyncore.dispatcher} server channel generates new
	\class{asynchat.async_chat} channel objects as it receives incoming
	connection requests.

	\begin{classdesc}{async_chat}{}
	This class is an abstract subclass of \class{asyncore.dispatcher}. To make
	practical use of the code you must subclass \class{async_chat}, providing
	meaningful \method{collect_incoming_data()} and \method{found_terminator()}
	methods. The \class{asyncore.dispatcher} methods can be
	used, although not all make sense in a message/response context.

	Like \class{asyncore.dispatcher}, \class{async_chat} defines a set of events
	that are generated by an analysis of socket conditions after a
	\cfunction{select()} call. Once the polling loop has been started the
	\class{async_chat} object's methods are called by the event-processing
	framework with no action on the part of the programmer.

	Unlike \class{asyncore.dispatcher}, \class{async_chat} allows you to define
	a first-in-first-out queue (fifo) of \emph{producers}. A producer need have
	only one method, \method{more()}, which should return data to be transmitted
	on the channel. The producer indicates exhaustion (\emph{i.e.} that it contains
	no more data) by having its \method{more()} method return the empty string. At
	this point the \class{async_chat} object removes the producer from the fifo
	and starts using the next producer, if any. When the producer fifo is empty
	the \method{handle_write()} method does nothing. You use the channel object's
	\method{set_terminator()} method to describe how to recognize the end
	of, or an important breakpoint in, an incoming transmission from the
	remote endpoint.

	To build a functioning \class{async_chat} subclass your
	input methods \method{collect_incoming_data()} and
	\method{found_terminator()} must handle the data that the channel receives
	asynchronously. The methods are described below.
	\end{classdesc}

	\begin{methoddesc}{close_when_done}{}
	Pushes a \code{None} on to the producer fifo. When this producer is
	popped off the fifo it causes the channel to be closed.
	\end{methoddesc}

	\begin{methoddesc}{collect_incoming_data}{data}
	Called with \var{data} holding an arbitrary amount of received data.
	The default method, which must be overridden, raises a \exception{NotImplementedError} exception.
	\end{methoddesc}

	\begin{methoddesc}{discard_buffers}{}
	In emergencies this method will discard any data held in the input and/or
	output buffers and the producer fifo.
	\end{methoddesc}

	\begin{methoddesc}{found_terminator}{}
	Called when the incoming data stream matches the termination condition
	set by \method{set_terminator}. The default method, which must be overridden,
	raises a \exception{NotImplementedError} exception. The buffered input data should
	be available via an instance attribute.
	\end{methoddesc}

	\begin{methoddesc}{get_terminator}{}
	Returns the current terminator for the channel.
	\end{methoddesc}

	\begin{methoddesc}{handle_close}{}
	Called when the channel is closed. The default method silently closes
	the channel's socket.
	\end{methoddesc}

	\begin{methoddesc}{handle_read}{}
	Called when a read event fires on the channel's socket in the
	asynchronous loop. The default method checks for the termination
	condition established by \method{set_terminator()}, which can be either
	the appearance of a particular string in the input stream or the receipt
	of a particular number of characters. When the terminator is found,
	\method{handle_read} calls the \method{found_terminator()} method after
	calling \method{collect_incoming_data()} with any data preceding the
	terminating condition.
	\end{methoddesc}

	\begin{methoddesc}{handle_write}{}
	Called when the application may write data to the channel.
	The default method calls the \method{initiate_send()} method, which in turn
	will call \method{refill_buffer()} to collect data from the producer
	fifo associated with the channel.
	\end{methoddesc}

	\begin{methoddesc}{push}{data}
	Creates a \class{simple_producer} object (\emph{see below}) containing the data and
	pushes it on to the channel's \code{producer_fifo} to ensure its
	transmission. This is all you need to do to have the channel write
	the data out to the network, although it is possible to use your
	own producers in more complex schemes to implement encryption and
	chunking, for example.
	\end{methoddesc}

	\begin{methoddesc}{push_with_producer}{producer}
	Takes a producer object and adds it to the producer fifo associated with
	the channel. When all currently-pushed producers have been exhausted
	the channel will consume this producer's data by calling its
	\method{more()} method and send the data to the remote endpoint.
	\end{methoddesc}

	\begin{methoddesc}{readable}{}
	Should return \code{True} for the channel to be included in the set of
	channels tested by the \cfunction{select()} loop for readability.
	\end{methoddesc}

	\begin{methoddesc}{refill_buffer}{}
	Refills the output buffer by calling the \method{more()} method of the
	producer at the head of the fifo. If it is exhausted then the
	producer is popped off the fifo and the next producer is activated.
	If the current producer is, or becomes, \code{None} then the channel
	is closed.
	\end{methoddesc}

	\begin{methoddesc}{set_terminator}{term}
	Sets the terminating condition to be recognised on the channel. \code{term}
	may be any of three types of value, corresponding to three different ways
	to handle incoming protocol data.

	\begin{tableii}{l\|l}{}{term}{Description}
	\lineii{\emph{string}}{Will call \method{found_terminator()} when the
	string is found in the input stream}
	\lineii{\emph{integer}}{Will call \method{found_terminator()} when the
	indicated number of characters have been received}
	\lineii{\code{None}}{The channel continues to collect data forever}
	\end{tableii}

	Note that any data following the terminator will be available for reading by
	the channel after \method{found_terminator()} is called.
	\end{methoddesc}

	\begin{methoddesc}{writable}{}
	Should return \code{True} as long as items remain on the producer fifo,
	or the channel is connected and the channel's output buffer is non-empty.
	\end{methoddesc}

	\subsection{asynchat - Auxiliary Classes and Functions}

	\begin{classdesc}{simple_producer}{data\optional{, buffer_size=512}}
	A \class{simple_producer} takes a chunk of data and an optional buffer size.
	Repeated calls to its \method{more()} method yield successive chunks of the
	data no larger than \var{buffer_size}.
	\end{classdesc}

	\begin{methoddesc}{more}{}
	Produces the next chunk of information from the producer, or returns the empty string.
	\end{methoddesc}

	\begin{classdesc}{fifo}{\optional{list=None}}
	Each channel maintains a \class{fifo} holding data which has been pushed by the
	application but not yet popped for writing to the channel.
	A \class{fifo} is a list used to hold data and/or producers until they are required.
	If the \var{list} argument is provided then it should contain producers or
	data items to be written to the channel.
	\end{classdesc}

	\begin{methoddesc}{is_empty}{}
	Returns \code{True} iff the fifo is empty.
	\end{methoddesc}

	\begin{methoddesc}{first}{}
	Returns the least-recently \method{push()}ed item from the fifo.
	\end{methoddesc}

	\begin{methoddesc}{push}{data}
	Adds the given data (which may be a string or a producer object) to the
	producer fifo.
	\end{methoddesc}

	\begin{methoddesc}{pop}{}
	If the fifo is not empty, returns \code{True, first()}, deleting the popped
	item. Returns \code{False, None} for an empty fifo.
	\end{methoddesc}

	The \module{asynchat} module also defines one utility function, which may be
	of use in network and textual analysis operations.

	\begin{funcdesc}{find_prefix_at_end}{haystack, needle}
	Returns \code{True} if string \var{haystack} ends with any non-empty
	prefix of string \var{needle}.
	\end{funcdesc}

	\subsection{asynchat Example \label{asynchat-example}}

	The following partial example shows how HTTP requests can be read with
	\class{async_chat}. A web server might create an \class{http_request_handler} object for
	each incoming client connection. Notice that initially the
	channel terminator is set to match the blank line at the end of the HTTP
	headers, and a flag indicates that the headers are being read.

	Once the headers have been read, if the request is of type POST
	(indicating that further data are present in the input stream) then the
	\code{Content-Length:} header is used to set a numeric terminator to
	read the right amount of data from the channel.

	The \method{handle_request()} method is called once all relevant input
	has been marshalled, after setting the channel terminator to \code{None}
	to ensure that any extraneous data sent by the web client are ignored.

	\begin{verbatim}
	class http_request_handler(asynchat.async_chat):

	def __init__(self, conn, addr, sessions, log):
	asynchat.async_chat.__init__(self, conn=conn)
	self.addr = addr
	self.sessions = sessions
	self.ibuffer = []
	self.obuffer = ""
	self.set_terminator("\r\n\r\n")
	self.reading_headers = True
	self.handling = False
	self.cgi_data = None
	self.log = log

	def collect_incoming_data(self, data):
	"""Buffer the data"""
	self.ibuffer.append(data)

	def found_terminator(self):
	if self.reading_headers:
	self.reading_headers = False
	self.parse_headers("".join(self.ibuffer))
	self.ibuffer = []
	if self.op.upper() == "POST":
	clen = self.headers.getheader("content-length")
	self.set_terminator(int(clen))
	else:
	self.handling = True
	self.set_terminator(None)
	self.handle_request()
	elif not self.handling:
	self.set_terminator(None) # browsers sometimes over-send
	self.cgi_data = parse(self.headers, "".join(self.ibuffer))
	self.handling = True
	self.ibuffer = []
	self.handle_request()
	\end{verbatim}