path: root/rdiff-backup/rdiff_backup/lazy.py

# Copyright 2002 Ben Escoto
#
# This file is part of rdiff-backup.
#
# rdiff-backup is free software; you can redistribute it and/or modify
# under the terms of the GNU General Public License as published by the
# Free Software Foundation; either version 2 of the License, or (at your
# option) any later version.
#
# rdiff-backup is distributed in the hope that it will be useful, but
# WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
# General Public License for more details.
#
# You should have received a copy of the GNU General Public License
# along with rdiff-backup; if not, write to the Free Software
# Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307
# USA

"""Define some lazy data structures and functions acting on them"""

from __future__ import generators
import os, stat, types
import static


class Iter:
	"""Hold static methods for the manipulation of lazy iterators"""

	def filter(predicate, iterator):
		"""Like filter in a lazy functional programming language"""
		for i in iterator:
			if predicate(i): yield i

	def map(function, iterator):
		"""Like map in a lazy functional programming language"""
		for i in iterator: yield function(i)

	def foreach(function, iterator):
		"""Run function on each element in iterator"""
		for i in iterator: function(i)

	def cat(*iters):
		"""Lazily concatenate iterators"""
		for iter in iters:
			for i in iter: yield i

	def cat2(iter_of_iters):
		"""Lazily concatenate iterators, iterated by big iterator"""
		for iter in iter_of_iters:
			for i in iter: yield i

	def empty(iter):
		"""True if iterator has length 0"""
		for i in iter: return None
		return 1

	def equal(iter1, iter2, verbose = None, operator = lambda x, y: x == y):
		"""True if iterator 1 has same elements as iterator 2

		Use equality operator, or == if it is unspecified.

		"""
		for i1 in iter1:
			try: i2 = iter2.next()
			except StopIteration:
				if verbose: print "End when i1 = %s" % (i1,)
				return None
			if not operator(i1, i2):
				if verbose: print "%s not equal to %s" % (i1, i2)
				return None
		try: i2 = iter2.next()
		except StopIteration: return 1
		if verbose: print "End when i2 = %s" % (i2,)
		return None

	def Or(iter):
		"""True if any element in iterator is true.  Short circuiting"""
		i = None
		for i in iter:
			if i: return i
		return i

	def And(iter):
		"""True if all elements in iterator are true.  Short circuiting"""
		i = 1
		for i in iter:
			if not i: return i
		return i

	def len(iter):
		"""Return length of iterator"""
		i = 0
		while 1:
			try: iter.next()
			except StopIteration: return i
			i = i+1

	def foldr(f, default, iter):
		"""foldr the "fundamental list recursion operator"?"""
		try: next = iter.next()
		except StopIteration: return default
		return f(next, Iter.foldr(f, default, iter))

	def foldl(f, default, iter):
		"""the fundamental list iteration operator.."""
		while 1:
			try: next = iter.next()
			except StopIteration: return default
			default = f(default, next)

	def multiplex(iter, num_of_forks, final_func = None, closing_func = None):
		"""Split a single iterater into a number of streams

		The return val will be a list with length num_of_forks, each
		of which will be an iterator like iter.  final_func is the
		function that will be called on each element in iter just as
		it is being removed from the buffer.  closing_func is called
		when all the streams are finished.

		"""
		if num_of_forks == 2 and not final_func and not closing_func:
			im2 = IterMultiplex2(iter)
			return (im2.yielda(), im2.yieldb())
		if not final_func: final_func = lambda i: None
		if not closing_func: closing_func = lambda: None

		# buffer is a list of elements that some iterators need and others
		# don't
		buffer = []

		# buffer[forkposition[i]] is the next element yieled by iterator
		# i.  If it is -1, yield from the original iter
		starting_forkposition = [-1] * num_of_forks
		forkposition = starting_forkposition[:]
		called_closing_func = [None]

		def get_next(fork_num):
			"""Return the next element requested by fork_num"""
			if forkposition[fork_num] == -1:
				try:  buffer.insert(0, iter.next())
				except StopIteration:
					# call closing_func if necessary
					if (forkposition == starting_forkposition and
						not called_closing_func[0]):
						closing_func()
						called_closing_func[0] = None
					raise StopIteration
				for i in range(num_of_forks): forkposition[i] += 1

			return_val = buffer[forkposition[fork_num]]
			forkposition[fork_num] -= 1

			blen = len(buffer)
			if not (blen-1) in forkposition:
				# Last position in buffer no longer needed
				assert forkposition[fork_num] == blen-2
				final_func(buffer[blen-1])
				del buffer[blen-1]
			return return_val

		def make_iterator(fork_num):
			while(1): yield get_next(fork_num)

		return tuple(map(make_iterator, range(num_of_forks)))

static.MakeStatic(Iter)


class IterMultiplex2:
	"""Multiplex an iterator into 2 parts

	This is a special optimized case of the Iter.multiplex function,
	used when there is no closing_func or final_func, and we only want
	to split it into 2.  By profiling, this is a time sensitive class.

	"""
	def __init__(self, iter):
		self.a_leading_by = 0 # How many places a is ahead of b
		self.buffer = []
		self.iter = iter

	def yielda(self):
		"""Return first iterator"""
		buf, iter = self.buffer, self.iter
		while(1):
			if self.a_leading_by >= 0: # a is in front, add new element
				elem = iter.next() # exception will be passed
				buf.append(elem)
			else: elem = buf.pop(0) # b is in front, subtract an element
			self.a_leading_by += 1
			yield elem

	def yieldb(self):
		"""Return second iterator"""
		buf, iter = self.buffer, self.iter
		while(1):
			if self.a_leading_by <= 0: # b is in front, add new element
				elem = iter.next() # exception will be passed
				buf.append(elem)
			else: elem = buf.pop(0) # a is in front, subtract an element
			self.a_leading_by -= 1
			yield elem