Lib/asynchat.py - platform/external/python/cpython2 - Gitiles

 # -*- Mode: Python; tab-width: 4 -*-
 #	$Id$
 #	Author: Sam Rushing <rushing@nightmare.com>

 # ======================================================================
 # Copyright 1996 by Sam Rushing
 #
 #                         All Rights Reserved
 #
 # Permission to use, copy, modify, and distribute this software and
 # its documentation for any purpose and without fee is hereby
 # granted, provided that the above copyright notice appear in all
 # copies and that both that copyright notice and this permission
 # notice appear in supporting documentation, and that the name of Sam
 # Rushing not be used in advertising or publicity pertaining to
 # distribution of the software without specific, written prior
 # permission.
 #
 # SAM RUSHING DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE,
 # INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS, IN
 # NO EVENT SHALL SAM RUSHING BE LIABLE FOR ANY SPECIAL, INDIRECT OR
 # CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS
 # OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT,
 # NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN
 # CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
 # ======================================================================

 import socket
 import asyncore
 import string

 # This class adds support for 'chat' style protocols - where one side
 # sends a 'command', and the other sends a response (examples would be
 # the common internet protocols - smtp, nntp, ftp, etc..).

 # The handle_read() method looks at the input stream for the current
 # 'terminator' (usually '\r\n' for single-line responses, '\r\n.\r\n'
 # for multi-line output), calling self.found_terminator() on its
 # receipt.

 # for example:
 # Say you build an async nntp client using this class.  At the start
 # of the connection, you'll have self.terminator set to '\r\n', in
 # order to process the single-line greeting.  Just before issuing a
 # 'LIST' command you'll set it to '\r\n.\r\n'.  The output of the LIST
 # command will be accumulated (using your own 'collect_incoming_data'
 # method) up to the terminator, and then control will be returned to
 # you - by calling your self.found_terminator() method

 class async_chat (asyncore.dispatcher):
 	"""This is an abstract class.  You must derive from this class, and add
 	the two methods collect_incoming_data() and found_terminator()"""

 	# these are overridable defaults

 	ac_in_buffer_size	= 4096
 	ac_out_buffer_size	= 4096

 	def __init__ (self, conn=None):
 		self.ac_in_buffer = ''
 		self.ac_out_buffer = ''
 		self.producer_fifo = fifo()
 		asyncore.dispatcher.__init__ (self, conn)

 	def set_terminator (self, term):
 		"Set the input delimiter.  Can be a fixed string of any length, or None"
 		if term is None:
 			self.terminator = ''
 		else:
 			self.terminator = term

 	def get_terminator (self):
 		return self.terminator

 	# grab some more data from the socket,
 	# throw it to the collector method,
 	# check for the terminator,
 	# if found, transition to the next state.

 	def handle_read (self):

 		try:
 			data = self.recv (self.ac_in_buffer_size)
 		except socket.error, why:
 			import sys
 			self.handle_error (sys.exc_type, sys.exc_value, sys.exc_traceback)
 			return

 		self.ac_in_buffer = self.ac_in_buffer + data

 		# Continue to search for self.terminator in self.ac_in_buffer,
 		# while calling self.collect_incoming_data.  The while loop
 		# is necessary because we might read several data+terminator
 		# combos with a single recv(1024).

 		while self.ac_in_buffer:
 			terminator = self.get_terminator()
 			terminator_len = len(terminator)
 			# 4 cases:
 			# 1) end of buffer matches terminator exactly:
 			#    collect data, transition
 			# 2) end of buffer matches some prefix:
 			#    collect data to the prefix
 			# 3) end of buffer does not match any prefix:
 			#    collect data
 			# 4) no terminator, just collect the data
 			if terminator:
 				index = string.find (self.ac_in_buffer, terminator)
 				if index != -1:
 					# we found the terminator
 					self.collect_incoming_data (self.ac_in_buffer[:index])
 					self.ac_in_buffer = self.ac_in_buffer[index+terminator_len:]
 					# This does the Right Thing if the terminator is changed here.
 					self.found_terminator()
 				else:
 					# check for a prefix of the terminator
 					index = find_prefix_at_end (self.ac_in_buffer, terminator)
 					if index:
 						# we found a prefix, collect up to the prefix
 						self.collect_incoming_data (self.ac_in_buffer[:-index])
 						self.ac_in_buffer = self.ac_in_buffer[-index:]
 						break
 					else:
 						# no prefix, collect it all
 						self.collect_incoming_data (self.ac_in_buffer)
 						self.ac_in_buffer = ''
 			else:
 				# no terminator, collect it all
 				self.collect_incoming_data (self.ac_in_buffer)
 				self.ac_in_buffer = ''

 	def handle_write (self):
 		self.initiate_send ()

 	def handle_close (self):
 		self.close()

 	def push (self, data):
 		self.producer_fifo.push (simple_producer (data))
 		self.initiate_send()

 	def push_with_producer (self, producer):
 		self.producer_fifo.push (producer)
 		self.initiate_send()

 	def readable (self):
 		return (len(self.ac_in_buffer) <= self.ac_in_buffer_size)

 	def writable (self):
 		return len(self.ac_out_buffer) or len(self.producer_fifo) or (not self.connected)

 	def close_when_done (self):
 		self.producer_fifo.push (None)

 	# refill the outgoing buffer by calling the more() method
 	# of the first producer in the queue
 	def refill_buffer (self):
 		while 1:
 			if len(self.producer_fifo):
 				p = self.producer_fifo.first()
 				# a 'None' in the producer fifo is a sentinel,
 				# telling us to close the channel.
 				if p is None:
 					if not self.ac_out_buffer:
 						self.producer_fifo.pop()
 						self.close()
 					return
 				data = p.more()
 				if data:
 					self.ac_out_buffer = self.ac_out_buffer + data
 					return
 				else:
 					self.producer_fifo.pop()
 			else:
 				return

 	def initiate_send (self):
 		obs = self.ac_out_buffer_size
 		# try to refill the buffer
 		if (not self._push_mode) and (len (self.ac_out_buffer) < obs):
 			self.refill_buffer()

 		if self.ac_out_buffer and self.connected:
 			# try to send the buffer
 			num_sent = self.send (self.ac_out_buffer[:obs])
 			if num_sent:
 				self.ac_out_buffer = self.ac_out_buffer[num_sent:]

 	def discard_buffers (self):
 		# Emergencies only!
 		self.ac_in_buffer = ''
 		self.ac_out_buffer == ''
 		while self.producer_fifo:
 			self.producer_fifo.pop()

 	# ==================================================
 	# support for push mode.
 	# ==================================================
 	_push_mode = 0
 	def push_mode (self, boolean):
 		self._push_mode = boolean

 	def writable_push (self):
 		return self.connected and len(self.ac_out_buffer)

 class simple_producer:
 	def __init__ (self, data, buffer_size=512):
 		self.data = data
 		self.buffer_size = buffer_size

 	def more (self):
 		if len (self.data) > self.buffer_size:
 			result = self.data[:self.buffer_size]
 			self.data = self.data[self.buffer_size:]
 			return result
 		else:
 			result = self.data
 			self.data = ''
 			return result

 class fifo:
 	def __init__ (self, list=None):
 		if not list:
 			self.list = []
 		else:
 			self.list = list

 	def __len__ (self):
 		return len(self.list)

 	def first (self):
 		return self.list[0]

 	def push (self, data):
 		self.list.append (data)

 	def pop (self):
 		if self.list:
 			result = self.list[0]
 			del self.list[0]
 			return (1, result)
 		else:
 			return (0, None)

 # Given 'haystack', see if any prefix of 'needle' is at its end.  This
 # assumes an exact match has already been checked.  Return the number of
 # characters matched.
 # for example:
 # f_p_a_e ("qwerty\r", "\r\n") => 1
 # f_p_a_e ("qwerty\r\n", "\r\n") => 2
 # f_p_a_e ("qwertydkjf", "\r\n") => 0

 # this could maybe be made faster with a computed regex?

 ##def find_prefix_at_end (haystack, needle):
 ##	nl = len(needle)
 ##	result = 0
 ##	for i in range (1,nl):
 ##		if haystack[-(nl-i):] == needle[:(nl-i)]:
 ##			result = nl-i
 ##			break
 ##	return result

 # yes, this is about twice as fast, but still seems
 # to be neglible CPU.  The previous could do about 290
 # searches/sec. the new one about 555/sec.

 import regex

 prefix_cache = {}

 def prefix_regex (needle):
 	if prefix_cache.has_key (needle):
 		return prefix_cache[needle]
 	else:
 		reg = needle[-1]
 		for i in range(1,len(needle)):
 			reg = '%c\(%s\)?' % (needle[-(i+1)], reg)
 		reg = regex.compile (reg+'$')
 		prefix_cache[needle] = reg, len(needle)
 		return reg, len(needle)

 def find_prefix_at_end (haystack, needle):
 	reg, length = prefix_regex (needle)
 	lh = len(haystack)
 	result = reg.search (haystack, max(0,lh-length))
 	if result >= 0:
 		return (lh - result)
 	else:
 		return 0
	# -- Mode: Python; tab-width: 4 --
	# $Id$
	# Author: Sam Rushing <rushing@nightmare.com>

	# ======================================================================
	# Copyright 1996 by Sam Rushing
	#
	# All Rights Reserved
	#
	# Permission to use, copy, modify, and distribute this software and
	# its documentation for any purpose and without fee is hereby
	# granted, provided that the above copyright notice appear in all
	# copies and that both that copyright notice and this permission
	# notice appear in supporting documentation, and that the name of Sam
	# Rushing not be used in advertising or publicity pertaining to
	# distribution of the software without specific, written prior
	# permission.
	#
	# SAM RUSHING DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE,
	# INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS, IN
	# NO EVENT SHALL SAM RUSHING BE LIABLE FOR ANY SPECIAL, INDIRECT OR
	# CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS
	# OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT,
	# NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN
	# CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
	# ======================================================================

	import socket
	import asyncore
	import string

	# This class adds support for 'chat' style protocols - where one side
	# sends a 'command', and the other sends a response (examples would be
	# the common internet protocols - smtp, nntp, ftp, etc..).

	# The handle_read() method looks at the input stream for the current
	# 'terminator' (usually '\r\n' for single-line responses, '\r\n.\r\n'
	# for multi-line output), calling self.found_terminator() on its
	# receipt.

	# for example:
	# Say you build an async nntp client using this class. At the start
	# of the connection, you'll have self.terminator set to '\r\n', in
	# order to process the single-line greeting. Just before issuing a
	# 'LIST' command you'll set it to '\r\n.\r\n'. The output of the LIST
	# command will be accumulated (using your own 'collect_incoming_data'
	# method) up to the terminator, and then control will be returned to
	# you - by calling your self.found_terminator() method

	class async_chat (asyncore.dispatcher):
	"""This is an abstract class. You must derive from this class, and add
	the two methods collect_incoming_data() and found_terminator()"""

	# these are overridable defaults

	ac_in_buffer_size = 4096
	ac_out_buffer_size = 4096

	def __init__ (self, conn=None):
	self.ac_in_buffer = ''
	self.ac_out_buffer = ''
	self.producer_fifo = fifo()
	asyncore.dispatcher.__init__ (self, conn)

	def set_terminator (self, term):
	"Set the input delimiter. Can be a fixed string of any length, or None"
	if term is None:
	self.terminator = ''
	else:
	self.terminator = term

	def get_terminator (self):
	return self.terminator

	# grab some more data from the socket,
	# throw it to the collector method,
	# check for the terminator,
	# if found, transition to the next state.

	def handle_read (self):

	try:
	data = self.recv (self.ac_in_buffer_size)
	except socket.error, why:
	import sys
	self.handle_error (sys.exc_type, sys.exc_value, sys.exc_traceback)
	return

	self.ac_in_buffer = self.ac_in_buffer + data

	# Continue to search for self.terminator in self.ac_in_buffer,
	# while calling self.collect_incoming_data. The while loop
	# is necessary because we might read several data+terminator
	# combos with a single recv(1024).

	while self.ac_in_buffer:
	terminator = self.get_terminator()
	terminator_len = len(terminator)
	# 4 cases:
	# 1) end of buffer matches terminator exactly:
	# collect data, transition
	# 2) end of buffer matches some prefix:
	# collect data to the prefix
	# 3) end of buffer does not match any prefix:
	# collect data
	# 4) no terminator, just collect the data
	if terminator:
	index = string.find (self.ac_in_buffer, terminator)
	if index != -1:
	# we found the terminator
	self.collect_incoming_data (self.ac_in_buffer[:index])
	self.ac_in_buffer = self.ac_in_buffer[index+terminator_len:]
	# This does the Right Thing if the terminator is changed here.
	self.found_terminator()
	else:
	# check for a prefix of the terminator
	index = find_prefix_at_end (self.ac_in_buffer, terminator)
	if index:
	# we found a prefix, collect up to the prefix
	self.collect_incoming_data (self.ac_in_buffer[:-index])
	self.ac_in_buffer = self.ac_in_buffer[-index:]
	break
	else:
	# no prefix, collect it all
	self.collect_incoming_data (self.ac_in_buffer)
	self.ac_in_buffer = ''
	else:
	# no terminator, collect it all
	self.collect_incoming_data (self.ac_in_buffer)
	self.ac_in_buffer = ''

	def handle_write (self):
	self.initiate_send ()

	def handle_close (self):
	self.close()

	def push (self, data):
	self.producer_fifo.push (simple_producer (data))
	self.initiate_send()

	def push_with_producer (self, producer):
	self.producer_fifo.push (producer)
	self.initiate_send()

	def readable (self):
	return (len(self.ac_in_buffer) <= self.ac_in_buffer_size)

	def writable (self):
	return len(self.ac_out_buffer) or len(self.producer_fifo) or (not self.connected)

	def close_when_done (self):
	self.producer_fifo.push (None)

	# refill the outgoing buffer by calling the more() method
	# of the first producer in the queue
	def refill_buffer (self):
	while 1:
	if len(self.producer_fifo):
	p = self.producer_fifo.first()
	# a 'None' in the producer fifo is a sentinel,
	# telling us to close the channel.
	if p is None:
	if not self.ac_out_buffer:
	self.producer_fifo.pop()
	self.close()
	return
	data = p.more()
	if data:
	self.ac_out_buffer = self.ac_out_buffer + data
	return
	else:
	self.producer_fifo.pop()
	else:
	return

	def initiate_send (self):
	obs = self.ac_out_buffer_size
	# try to refill the buffer
	if (not self._push_mode) and (len (self.ac_out_buffer) < obs):
	self.refill_buffer()

	if self.ac_out_buffer and self.connected:
	# try to send the buffer
	num_sent = self.send (self.ac_out_buffer[:obs])
	if num_sent:
	self.ac_out_buffer = self.ac_out_buffer[num_sent:]

	def discard_buffers (self):
	# Emergencies only!
	self.ac_in_buffer = ''
	self.ac_out_buffer == ''
	while self.producer_fifo:
	self.producer_fifo.pop()

	# ==================================================
	# support for push mode.
	# ==================================================
	_push_mode = 0
	def push_mode (self, boolean):
	self._push_mode = boolean

	def writable_push (self):
	return self.connected and len(self.ac_out_buffer)

	class simple_producer:
	def __init__ (self, data, buffer_size=512):
	self.data = data
	self.buffer_size = buffer_size

	def more (self):
	if len (self.data) > self.buffer_size:
	result = self.data[:self.buffer_size]
	self.data = self.data[self.buffer_size:]
	return result
	else:
	result = self.data
	self.data = ''
	return result

	class fifo:
	def __init__ (self, list=None):
	if not list:
	self.list = []
	else:
	self.list = list

	def __len__ (self):
	return len(self.list)

	def first (self):
	return self.list[0]

	def push (self, data):
	self.list.append (data)

	def pop (self):
	if self.list:
	result = self.list[0]
	del self.list[0]
	return (1, result)
	else:
	return (0, None)

	# Given 'haystack', see if any prefix of 'needle' is at its end. This
	# assumes an exact match has already been checked. Return the number of
	# characters matched.
	# for example:
	# f_p_a_e ("qwerty\r", "\r\n") => 1
	# f_p_a_e ("qwerty\r\n", "\r\n") => 2
	# f_p_a_e ("qwertydkjf", "\r\n") => 0

	# this could maybe be made faster with a computed regex?

	##def find_prefix_at_end (haystack, needle):
	## nl = len(needle)
	## result = 0
	## for i in range (1,nl):
	## if haystack[-(nl-i):] == needle[:(nl-i)]:
	## result = nl-i
	## break
	## return result

	# yes, this is about twice as fast, but still seems
	# to be neglible CPU. The previous could do about 290
	# searches/sec. the new one about 555/sec.

	import regex

	prefix_cache = {}

	def prefix_regex (needle):
	if prefix_cache.has_key (needle):
	return prefix_cache[needle]
	else:
	reg = needle[-1]
	for i in range(1,len(needle)):
	reg = '%c\(%s\)?' % (needle[-(i+1)], reg)
	reg = regex.compile (reg+'$')
	prefix_cache[needle] = reg, len(needle)
	return reg, len(needle)

	def find_prefix_at_end (haystack, needle):
	reg, length = prefix_regex (needle)
	lh = len(haystack)
	result = reg.search (haystack, max(0,lh-length))
	if result >= 0:
	return (lh - result)
	else:
	return 0