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454 lines
17 KiB
454 lines
17 KiB
from collections import deque
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from sympy.combinatorics.rewritingsystem_fsm import StateMachine
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class RewritingSystem:
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'''
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A class implementing rewriting systems for `FpGroup`s.
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References
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==========
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.. [1] Epstein, D., Holt, D. and Rees, S. (1991).
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The use of Knuth-Bendix methods to solve the word problem in automatic groups.
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Journal of Symbolic Computation, 12(4-5), pp.397-414.
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.. [2] GAP's Manual on its KBMAG package
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https://www.gap-system.org/Manuals/pkg/kbmag-1.5.3/doc/manual.pdf
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'''
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def __init__(self, group):
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self.group = group
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self.alphabet = group.generators
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self._is_confluent = None
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# these values are taken from [2]
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self.maxeqns = 32767 # max rules
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self.tidyint = 100 # rules before tidying
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# _max_exceeded is True if maxeqns is exceeded
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# at any point
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self._max_exceeded = False
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# Reduction automaton
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self.reduction_automaton = None
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self._new_rules = {}
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# dictionary of reductions
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self.rules = {}
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self.rules_cache = deque([], 50)
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self._init_rules()
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# All the transition symbols in the automaton
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generators = list(self.alphabet)
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generators += [gen**-1 for gen in generators]
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# Create a finite state machine as an instance of the StateMachine object
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self.reduction_automaton = StateMachine('Reduction automaton for '+ repr(self.group), generators)
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self.construct_automaton()
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def set_max(self, n):
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'''
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Set the maximum number of rules that can be defined
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'''
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if n > self.maxeqns:
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self._max_exceeded = False
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self.maxeqns = n
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return
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@property
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def is_confluent(self):
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'''
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Return `True` if the system is confluent
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'''
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if self._is_confluent is None:
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self._is_confluent = self._check_confluence()
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return self._is_confluent
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def _init_rules(self):
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identity = self.group.free_group.identity
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for r in self.group.relators:
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self.add_rule(r, identity)
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self._remove_redundancies()
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return
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def _add_rule(self, r1, r2):
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'''
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Add the rule r1 -> r2 with no checking or further
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deductions
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'''
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if len(self.rules) + 1 > self.maxeqns:
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self._is_confluent = self._check_confluence()
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self._max_exceeded = True
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raise RuntimeError("Too many rules were defined.")
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self.rules[r1] = r2
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# Add the newly added rule to the `new_rules` dictionary.
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if self.reduction_automaton:
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self._new_rules[r1] = r2
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def add_rule(self, w1, w2, check=False):
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new_keys = set()
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if w1 == w2:
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return new_keys
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if w1 < w2:
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w1, w2 = w2, w1
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if (w1, w2) in self.rules_cache:
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return new_keys
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self.rules_cache.append((w1, w2))
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s1, s2 = w1, w2
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# The following is the equivalent of checking
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# s1 for overlaps with the implicit reductions
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# {g*g**-1 -> <identity>} and {g**-1*g -> <identity>}
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# for any generator g without installing the
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# redundant rules that would result from processing
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# the overlaps. See [1], Section 3 for details.
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if len(s1) - len(s2) < 3:
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if s1 not in self.rules:
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new_keys.add(s1)
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if not check:
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self._add_rule(s1, s2)
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if s2**-1 > s1**-1 and s2**-1 not in self.rules:
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new_keys.add(s2**-1)
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if not check:
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self._add_rule(s2**-1, s1**-1)
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# overlaps on the right
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while len(s1) - len(s2) > -1:
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g = s1[len(s1)-1]
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s1 = s1.subword(0, len(s1)-1)
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s2 = s2*g**-1
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if len(s1) - len(s2) < 0:
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if s2 not in self.rules:
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if not check:
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self._add_rule(s2, s1)
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new_keys.add(s2)
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elif len(s1) - len(s2) < 3:
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new = self.add_rule(s1, s2, check)
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new_keys.update(new)
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# overlaps on the left
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while len(w1) - len(w2) > -1:
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g = w1[0]
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w1 = w1.subword(1, len(w1))
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w2 = g**-1*w2
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if len(w1) - len(w2) < 0:
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if w2 not in self.rules:
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if not check:
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self._add_rule(w2, w1)
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new_keys.add(w2)
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elif len(w1) - len(w2) < 3:
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new = self.add_rule(w1, w2, check)
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new_keys.update(new)
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return new_keys
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def _remove_redundancies(self, changes=False):
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'''
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Reduce left- and right-hand sides of reduction rules
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and remove redundant equations (i.e. those for which
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lhs == rhs). If `changes` is `True`, return a set
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containing the removed keys and a set containing the
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added keys
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'''
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removed = set()
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added = set()
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rules = self.rules.copy()
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for r in rules:
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v = self.reduce(r, exclude=r)
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w = self.reduce(rules[r])
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if v != r:
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del self.rules[r]
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removed.add(r)
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if v > w:
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added.add(v)
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self.rules[v] = w
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elif v < w:
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added.add(w)
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self.rules[w] = v
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else:
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self.rules[v] = w
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if changes:
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return removed, added
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return
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def make_confluent(self, check=False):
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'''
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Try to make the system confluent using the Knuth-Bendix
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completion algorithm
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'''
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if self._max_exceeded:
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return self._is_confluent
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lhs = list(self.rules.keys())
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def _overlaps(r1, r2):
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len1 = len(r1)
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len2 = len(r2)
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result = []
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for j in range(1, len1 + len2):
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if (r1.subword(len1 - j, len1 + len2 - j, strict=False)
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== r2.subword(j - len1, j, strict=False)):
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a = r1.subword(0, len1-j, strict=False)
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a = a*r2.subword(0, j-len1, strict=False)
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b = r2.subword(j-len1, j, strict=False)
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c = r2.subword(j, len2, strict=False)
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c = c*r1.subword(len1 + len2 - j, len1, strict=False)
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result.append(a*b*c)
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return result
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def _process_overlap(w, r1, r2, check):
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s = w.eliminate_word(r1, self.rules[r1])
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s = self.reduce(s)
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t = w.eliminate_word(r2, self.rules[r2])
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t = self.reduce(t)
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if s != t:
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if check:
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# system not confluent
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return [0]
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try:
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new_keys = self.add_rule(t, s, check)
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return new_keys
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except RuntimeError:
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return False
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return
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added = 0
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i = 0
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while i < len(lhs):
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r1 = lhs[i]
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i += 1
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# j could be i+1 to not
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# check each pair twice but lhs
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# is extended in the loop and the new
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# elements have to be checked with the
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# preceding ones. there is probably a better way
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# to handle this
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j = 0
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while j < len(lhs):
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r2 = lhs[j]
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j += 1
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if r1 == r2:
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continue
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overlaps = _overlaps(r1, r2)
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overlaps.extend(_overlaps(r1**-1, r2))
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if not overlaps:
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continue
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for w in overlaps:
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new_keys = _process_overlap(w, r1, r2, check)
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if new_keys:
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if check:
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return False
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lhs.extend(new_keys)
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added += len(new_keys)
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elif new_keys == False:
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# too many rules were added so the process
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# couldn't complete
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return self._is_confluent
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if added > self.tidyint and not check:
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# tidy up
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r, a = self._remove_redundancies(changes=True)
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added = 0
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if r:
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# reset i since some elements were removed
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i = min([lhs.index(s) for s in r])
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lhs = [l for l in lhs if l not in r]
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lhs.extend(a)
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if r1 in r:
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# r1 was removed as redundant
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break
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self._is_confluent = True
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if not check:
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self._remove_redundancies()
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return True
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def _check_confluence(self):
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return self.make_confluent(check=True)
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def reduce(self, word, exclude=None):
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'''
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Apply reduction rules to `word` excluding the reduction rule
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for the lhs equal to `exclude`
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'''
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rules = {r: self.rules[r] for r in self.rules if r != exclude}
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# the following is essentially `eliminate_words()` code from the
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# `FreeGroupElement` class, the only difference being the first
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# "if" statement
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again = True
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new = word
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while again:
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again = False
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for r in rules:
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prev = new
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if rules[r]**-1 > r**-1:
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new = new.eliminate_word(r, rules[r], _all=True, inverse=False)
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else:
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new = new.eliminate_word(r, rules[r], _all=True)
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if new != prev:
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again = True
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return new
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def _compute_inverse_rules(self, rules):
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'''
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Compute the inverse rules for a given set of rules.
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The inverse rules are used in the automaton for word reduction.
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Arguments:
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rules (dictionary): Rules for which the inverse rules are to computed.
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Returns:
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Dictionary of inverse_rules.
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'''
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inverse_rules = {}
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for r in rules:
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rule_key_inverse = r**-1
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rule_value_inverse = (rules[r])**-1
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if (rule_value_inverse < rule_key_inverse):
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inverse_rules[rule_key_inverse] = rule_value_inverse
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else:
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inverse_rules[rule_value_inverse] = rule_key_inverse
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return inverse_rules
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def construct_automaton(self):
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'''
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Construct the automaton based on the set of reduction rules of the system.
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Automata Design:
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The accept states of the automaton are the proper prefixes of the left hand side of the rules.
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The complete left hand side of the rules are the dead states of the automaton.
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'''
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self._add_to_automaton(self.rules)
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def _add_to_automaton(self, rules):
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'''
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Add new states and transitions to the automaton.
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Summary:
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States corresponding to the new rules added to the system are computed and added to the automaton.
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Transitions in the previously added states are also modified if necessary.
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Arguments:
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rules (dictionary) -- Dictionary of the newly added rules.
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'''
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# Automaton variables
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automaton_alphabet = []
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proper_prefixes = {}
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# compute the inverses of all the new rules added
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all_rules = rules
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inverse_rules = self._compute_inverse_rules(all_rules)
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all_rules.update(inverse_rules)
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# Keep track of the accept_states.
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accept_states = []
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for rule in all_rules:
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# The symbols present in the new rules are the symbols to be verified at each state.
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# computes the automaton_alphabet, as the transitions solely depend upon the new states.
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automaton_alphabet += rule.letter_form_elm
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# Compute the proper prefixes for every rule.
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proper_prefixes[rule] = []
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letter_word_array = list(rule.letter_form_elm)
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len_letter_word_array = len(letter_word_array)
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for i in range (1, len_letter_word_array):
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letter_word_array[i] = letter_word_array[i-1]*letter_word_array[i]
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# Add accept states.
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elem = letter_word_array[i-1]
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if elem not in self.reduction_automaton.states:
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self.reduction_automaton.add_state(elem, state_type='a')
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accept_states.append(elem)
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proper_prefixes[rule] = letter_word_array
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# Check for overlaps between dead and accept states.
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if rule in accept_states:
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self.reduction_automaton.states[rule].state_type = 'd'
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self.reduction_automaton.states[rule].rh_rule = all_rules[rule]
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accept_states.remove(rule)
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# Add dead states
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if rule not in self.reduction_automaton.states:
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self.reduction_automaton.add_state(rule, state_type='d', rh_rule=all_rules[rule])
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automaton_alphabet = set(automaton_alphabet)
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# Add new transitions for every state.
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for state in self.reduction_automaton.states:
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current_state_name = state
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current_state_type = self.reduction_automaton.states[state].state_type
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# Transitions will be modified only when suffixes of the current_state
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# belongs to the proper_prefixes of the new rules.
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# The rest are ignored if they cannot lead to a dead state after a finite number of transisitons.
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if current_state_type == 's':
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for letter in automaton_alphabet:
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if letter in self.reduction_automaton.states:
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self.reduction_automaton.states[state].add_transition(letter, letter)
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else:
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self.reduction_automaton.states[state].add_transition(letter, current_state_name)
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elif current_state_type == 'a':
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# Check if the transition to any new state in possible.
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for letter in automaton_alphabet:
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_next = current_state_name*letter
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while len(_next) and _next not in self.reduction_automaton.states:
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_next = _next.subword(1, len(_next))
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if not len(_next):
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_next = 'start'
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self.reduction_automaton.states[state].add_transition(letter, _next)
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# Add transitions for new states. All symbols used in the automaton are considered here.
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# Ignore this if `reduction_automaton.automaton_alphabet` = `automaton_alphabet`.
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if len(self.reduction_automaton.automaton_alphabet) != len(automaton_alphabet):
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for state in accept_states:
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current_state_name = state
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for letter in self.reduction_automaton.automaton_alphabet:
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_next = current_state_name*letter
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while len(_next) and _next not in self.reduction_automaton.states:
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_next = _next.subword(1, len(_next))
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if not len(_next):
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_next = 'start'
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self.reduction_automaton.states[state].add_transition(letter, _next)
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def reduce_using_automaton(self, word):
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'''
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Reduce a word using an automaton.
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Summary:
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All the symbols of the word are stored in an array and are given as the input to the automaton.
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If the automaton reaches a dead state that subword is replaced and the automaton is run from the beginning.
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The complete word has to be replaced when the word is read and the automaton reaches a dead state.
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So, this process is repeated until the word is read completely and the automaton reaches the accept state.
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Arguments:
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word (instance of FreeGroupElement) -- Word that needs to be reduced.
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'''
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# Modify the automaton if new rules are found.
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if self._new_rules:
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self._add_to_automaton(self._new_rules)
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self._new_rules = {}
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flag = 1
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while flag:
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flag = 0
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current_state = self.reduction_automaton.states['start']
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for i, s in enumerate(word.letter_form_elm):
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next_state_name = current_state.transitions[s]
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next_state = self.reduction_automaton.states[next_state_name]
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if next_state.state_type == 'd':
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subst = next_state.rh_rule
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word = word.substituted_word(i - len(next_state_name) + 1, i+1, subst)
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flag = 1
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break
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current_state = next_state
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return word
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