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	# Natural Language Toolkit: Shift-Reduce Parser
	#
	# Copyright (C) 2001-2023 NLTK Project
	# Author: Edward Loper <[email protected]>
	# Steven Bird <[email protected]>
	# URL: <https://www.nltk.org/>
	# For license information, see LICENSE.TXT

	from nltk.grammar import Nonterminal
	from nltk.parse.api import ParserI
	from nltk.tree import Tree


	##//////////////////////////////////////////////////////
	## Shift/Reduce Parser
	##//////////////////////////////////////////////////////
	class ShiftReduceParser(ParserI):
	"""
	A simple bottom-up CFG parser that uses two operations, "shift"
	and "reduce", to find a single parse for a text.

	``ShiftReduceParser`` maintains a stack, which records the
	structure of a portion of the text. This stack is a list of
	strings and Trees that collectively cover a portion of
	the text. For example, while parsing the sentence "the dog saw
	the man" with a typical grammar, ``ShiftReduceParser`` will produce
	the following stack, which covers "the dog saw"::

	[(NP: (Det: 'the') (N: 'dog')), (V: 'saw')]

	``ShiftReduceParser`` attempts to extend the stack to cover the
	entire text, and to combine the stack elements into a single tree,
	producing a complete parse for the sentence.

	Initially, the stack is empty. It is extended to cover the text,
	from left to right, by repeatedly applying two operations:

	- "shift" moves a token from the beginning of the text to the
	end of the stack.
	- "reduce" uses a CFG production to combine the rightmost stack
	elements into a single Tree.

	Often, more than one operation can be performed on a given stack.
	In this case, ``ShiftReduceParser`` uses the following heuristics
	to decide which operation to perform:

	- Only shift if no reductions are available.
	- If multiple reductions are available, then apply the reduction
	whose CFG production is listed earliest in the grammar.

	Note that these heuristics are not guaranteed to choose an
	operation that leads to a parse of the text. Also, if multiple
	parses exists, ``ShiftReduceParser`` will return at most one of
	them.

	:see: ``nltk.grammar``
	"""

	def __init__(self, grammar, trace=0):
	"""
	Create a new ``ShiftReduceParser``, that uses ``grammar`` to
	parse texts.

	:type grammar: Grammar
	:param grammar: The grammar used to parse texts.
	:type trace: int
	:param trace: The level of tracing that should be used when
	parsing a text. ``0`` will generate no tracing output;
	and higher numbers will produce more verbose tracing
	output.
	"""
	self._grammar = grammar
	self._trace = trace
	self._check_grammar()

	def grammar(self):
	return self._grammar

	def parse(self, tokens):
	tokens = list(tokens)
	self._grammar.check_coverage(tokens)

	# initialize the stack.
	stack = []
	remaining_text = tokens

	# Trace output.
	if self._trace:
	print("Parsing %r" % " ".join(tokens))
	self._trace_stack(stack, remaining_text)

	# iterate through the text, pushing the token onto
	# the stack, then reducing the stack.
	while len(remaining_text) > 0:
	self._shift(stack, remaining_text)
	while self._reduce(stack, remaining_text):
	pass

	# Did we reduce everything?
	if len(stack) == 1:
	# Did we end up with the right category?
	if stack[0].label() == self._grammar.start().symbol():
	yield stack[0]

	def _shift(self, stack, remaining_text):
	"""
	Move a token from the beginning of ``remaining_text`` to the
	end of ``stack``.

	:type stack: list(str and Tree)
	:param stack: A list of strings and Trees, encoding
	the structure of the text that has been parsed so far.
	:type remaining_text: list(str)
	:param remaining_text: The portion of the text that is not yet
	covered by ``stack``.
	:rtype: None
	"""
	stack.append(remaining_text[0])
	remaining_text.remove(remaining_text[0])
	if self._trace:
	self._trace_shift(stack, remaining_text)

	def _match_rhs(self, rhs, rightmost_stack):
	"""
	:rtype: bool
	:return: true if the right hand side of a CFG production
	matches the rightmost elements of the stack. ``rhs``
	matches ``rightmost_stack`` if they are the same length,
	and each element of ``rhs`` matches the corresponding
	element of ``rightmost_stack``. A nonterminal element of
	``rhs`` matches any Tree whose node value is equal
	to the nonterminal's symbol. A terminal element of ``rhs``
	matches any string whose type is equal to the terminal.
	:type rhs: list(terminal and Nonterminal)
	:param rhs: The right hand side of a CFG production.
	:type rightmost_stack: list(string and Tree)
	:param rightmost_stack: The rightmost elements of the parser's
	stack.
	"""

	if len(rightmost_stack) != len(rhs):
	return False
	for i in range(len(rightmost_stack)):
	if isinstance(rightmost_stack[i], Tree):
	if not isinstance(rhs[i], Nonterminal):
	return False
	if rightmost_stack[i].label() != rhs[i].symbol():
	return False
	else:
	if isinstance(rhs[i], Nonterminal):
	return False
	if rightmost_stack[i] != rhs[i]:
	return False
	return True

	def _reduce(self, stack, remaining_text, production=None):
	"""
	Find a CFG production whose right hand side matches the
	rightmost stack elements; and combine those stack elements
	into a single Tree, with the node specified by the
	production's left-hand side. If more than one CFG production
	matches the stack, then use the production that is listed
	earliest in the grammar. The new Tree replaces the
	elements in the stack.

	:rtype: Production or None
	:return: If a reduction is performed, then return the CFG
	production that the reduction is based on; otherwise,
	return false.
	:type stack: list(string and Tree)
	:param stack: A list of strings and Trees, encoding
	the structure of the text that has been parsed so far.
	:type remaining_text: list(str)
	:param remaining_text: The portion of the text that is not yet
	covered by ``stack``.
	"""
	if production is None:
	productions = self._grammar.productions()
	else:
	productions = [production]

	# Try each production, in order.
	for production in productions:
	rhslen = len(production.rhs())

	# check if the RHS of a production matches the top of the stack
	if self._match_rhs(production.rhs(), stack[-rhslen:]):

	# combine the tree to reflect the reduction
	tree = Tree(production.lhs().symbol(), stack[-rhslen:])
	stack[-rhslen:] = [tree]

	# We reduced something
	if self._trace:
	self._trace_reduce(stack, production, remaining_text)
	return production

	# We didn't reduce anything
	return None

	def trace(self, trace=2):
	"""
	Set the level of tracing output that should be generated when
	parsing a text.

	:type trace: int
	:param trace: The trace level. A trace level of ``0`` will
	generate no tracing output; and higher trace levels will
	produce more verbose tracing output.
	:rtype: None
	"""
	# 1: just show shifts.
	# 2: show shifts & reduces
	# 3: display which tokens & productions are shifed/reduced
	self._trace = trace

	def _trace_stack(self, stack, remaining_text, marker=" "):
	"""
	Print trace output displaying the given stack and text.

	:rtype: None
	:param marker: A character that is printed to the left of the
	stack. This is used with trace level 2 to print 'S'
	before shifted stacks and 'R' before reduced stacks.
	"""
	s = " " + marker + " [ "
	for elt in stack:
	if isinstance(elt, Tree):
	s += repr(Nonterminal(elt.label())) + " "
	else:
	s += repr(elt) + " "
	s += "* " + " ".join(remaining_text) + "]"
	print(s)

	def _trace_shift(self, stack, remaining_text):
	"""
	Print trace output displaying that a token has been shifted.

	:rtype: None
	"""
	if self._trace > 2:
	print("Shift %r:" % stack[-1])
	if self._trace == 2:
	self._trace_stack(stack, remaining_text, "S")
	elif self._trace > 0:
	self._trace_stack(stack, remaining_text)

	def _trace_reduce(self, stack, production, remaining_text):
	"""
	Print trace output displaying that ``production`` was used to
	reduce ``stack``.

	:rtype: None
	"""
	if self._trace > 2:
	rhs = " ".join(production.rhs())
	print(f"Reduce {production.lhs()!r} <- {rhs}")
	if self._trace == 2:
	self._trace_stack(stack, remaining_text, "R")
	elif self._trace > 1:
	self._trace_stack(stack, remaining_text)

	def _check_grammar(self):
	"""
	Check to make sure that all of the CFG productions are
	potentially useful. If any productions can never be used,
	then print a warning.

	:rtype: None
	"""
	productions = self._grammar.productions()

	# Any production whose RHS is an extension of another production's RHS
	# will never be used.
	for i in range(len(productions)):
	for j in range(i + 1, len(productions)):
	rhs1 = productions[i].rhs()
	rhs2 = productions[j].rhs()
	if rhs1[: len(rhs2)] == rhs2:
	print("Warning: %r will never be used" % productions[i])


	##//////////////////////////////////////////////////////
	## Stepping Shift/Reduce Parser
	##//////////////////////////////////////////////////////
	class SteppingShiftReduceParser(ShiftReduceParser):
	"""
	A ``ShiftReduceParser`` that allows you to setp through the parsing
	process, performing a single operation at a time. It also allows
	you to change the parser's grammar midway through parsing a text.

	The ``initialize`` method is used to start parsing a text.
	``shift`` performs a single shift operation, and ``reduce`` performs
	a single reduce operation. ``step`` will perform a single reduce
	operation if possible; otherwise, it will perform a single shift
	operation. ``parses`` returns the set of parses that have been
	found by the parser.

	:ivar _history: A list of ``(stack, remaining_text)`` pairs,
	containing all of the previous states of the parser. This
	history is used to implement the ``undo`` operation.
	:see: ``nltk.grammar``
	"""

	def __init__(self, grammar, trace=0):
	super().__init__(grammar, trace)
	self._stack = None
	self._remaining_text = None
	self._history = []

	def parse(self, tokens):
	tokens = list(tokens)
	self.initialize(tokens)
	while self.step():
	pass
	return self.parses()

	def stack(self):
	"""
	:return: The parser's stack.
	:rtype: list(str and Tree)
	"""
	return self._stack

	def remaining_text(self):
	"""
	:return: The portion of the text that is not yet covered by the
	stack.
	:rtype: list(str)
	"""
	return self._remaining_text

	def initialize(self, tokens):
	"""
	Start parsing a given text. This sets the parser's stack to
	``[]`` and sets its remaining text to ``tokens``.
	"""
	self._stack = []
	self._remaining_text = tokens
	self._history = []

	def step(self):
	"""
	Perform a single parsing operation. If a reduction is
	possible, then perform that reduction, and return the
	production that it is based on. Otherwise, if a shift is
	possible, then perform it, and return True. Otherwise,
	return False.

	:return: False if no operation was performed; True if a shift was
	performed; and the CFG production used to reduce if a
	reduction was performed.
	:rtype: Production or bool
	"""
	return self.reduce() or self.shift()

	def shift(self):
	"""
	Move a token from the beginning of the remaining text to the
	end of the stack. If there are no more tokens in the
	remaining text, then do nothing.

	:return: True if the shift operation was successful.
	:rtype: bool
	"""
	if len(self._remaining_text) == 0:
	return False
	self._history.append((self._stack[:], self._remaining_text[:]))
	self._shift(self._stack, self._remaining_text)
	return True

	def reduce(self, production=None):
	"""
	Use ``production`` to combine the rightmost stack elements into
	a single Tree. If ``production`` does not match the
	rightmost stack elements, then do nothing.

	:return: The production used to reduce the stack, if a
	reduction was performed. If no reduction was performed,
	return None.

	:rtype: Production or None
	"""
	self._history.append((self._stack[:], self._remaining_text[:]))
	return_val = self._reduce(self._stack, self._remaining_text, production)

	if not return_val:
	self._history.pop()
	return return_val

	def undo(self):
	"""
	Return the parser to its state before the most recent
	shift or reduce operation. Calling ``undo`` repeatedly return
	the parser to successively earlier states. If no shift or
	reduce operations have been performed, ``undo`` will make no
	changes.

	:return: true if an operation was successfully undone.
	:rtype: bool
	"""
	if len(self._history) == 0:
	return False
	(self._stack, self._remaining_text) = self._history.pop()
	return True

	def reducible_productions(self):
	"""
	:return: A list of the productions for which reductions are
	available for the current parser state.
	:rtype: list(Production)
	"""
	productions = []
	for production in self._grammar.productions():
	rhslen = len(production.rhs())
	if self._match_rhs(production.rhs(), self._stack[-rhslen:]):
	productions.append(production)
	return productions

	def parses(self):
	"""
	:return: An iterator of the parses that have been found by this
	parser so far.
	:rtype: iter(Tree)
	"""
	if (
	len(self._remaining_text) == 0
	and len(self._stack) == 1
	and self._stack[0].label() == self._grammar.start().symbol()
	):
	yield self._stack[0]

	# copied from nltk.parser

	def set_grammar(self, grammar):
	"""
	Change the grammar used to parse texts.

	:param grammar: The new grammar.
	:type grammar: CFG
	"""
	self._grammar = grammar


	##//////////////////////////////////////////////////////
	## Demonstration Code
	##//////////////////////////////////////////////////////


	def demo():
	"""
	A demonstration of the shift-reduce parser.
	"""

	from nltk import CFG, parse

	grammar = CFG.fromstring(
	"""
	S -> NP VP
	NP -> Det N \| Det N PP
	VP -> V NP \| V NP PP
	PP -> P NP
	NP -> 'I'
	N -> 'man' \| 'park' \| 'telescope' \| 'dog'
	Det -> 'the' \| 'a'
	P -> 'in' \| 'with'
	V -> 'saw'
	"""
	)

	sent = "I saw a man in the park".split()

	parser = parse.ShiftReduceParser(grammar, trace=2)
	for p in parser.parse(sent):
	print(p)


	if __name__ == "__main__":
	demo()