716 lines
25 KiB
Python
716 lines
25 KiB
Python
# Natural Language Toolkit: First-Order Tableau Theorem Prover
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#
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# Copyright (C) 2001-2019 NLTK Project
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# Author: Dan Garrette <dhgarrette@gmail.com>
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#
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# URL: <http://nltk.org/>
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# For license information, see LICENSE.TXT
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"""
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Module for a tableau-based First Order theorem prover.
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"""
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from __future__ import print_function, unicode_literals
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from nltk.internals import Counter
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from nltk.sem.logic import (
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VariableExpression,
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EqualityExpression,
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ApplicationExpression,
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Expression,
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AbstractVariableExpression,
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AllExpression,
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NegatedExpression,
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ExistsExpression,
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Variable,
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ImpExpression,
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AndExpression,
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unique_variable,
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LambdaExpression,
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IffExpression,
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OrExpression,
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FunctionVariableExpression,
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)
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from nltk.inference.api import Prover, BaseProverCommand
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_counter = Counter()
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class ProverParseError(Exception):
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pass
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class TableauProver(Prover):
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_assume_false = False
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def _prove(self, goal=None, assumptions=None, verbose=False):
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if not assumptions:
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assumptions = []
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result = None
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try:
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agenda = Agenda()
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if goal:
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agenda.put(-goal)
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agenda.put_all(assumptions)
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debugger = Debug(verbose)
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result = self._attempt_proof(agenda, set(), set(), debugger)
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except RuntimeError as e:
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if self._assume_false and str(e).startswith(
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'maximum recursion depth exceeded'
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):
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result = False
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else:
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if verbose:
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print(e)
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else:
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raise e
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return (result, '\n'.join(debugger.lines))
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def _attempt_proof(self, agenda, accessible_vars, atoms, debug):
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(current, context), category = agenda.pop_first()
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# if there's nothing left in the agenda, and we haven't closed the path
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if not current:
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debug.line('AGENDA EMPTY')
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return False
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proof_method = {
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Categories.ATOM: self._attempt_proof_atom,
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Categories.PROP: self._attempt_proof_prop,
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Categories.N_ATOM: self._attempt_proof_n_atom,
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Categories.N_PROP: self._attempt_proof_n_prop,
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Categories.APP: self._attempt_proof_app,
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Categories.N_APP: self._attempt_proof_n_app,
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Categories.N_EQ: self._attempt_proof_n_eq,
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Categories.D_NEG: self._attempt_proof_d_neg,
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Categories.N_ALL: self._attempt_proof_n_all,
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Categories.N_EXISTS: self._attempt_proof_n_some,
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Categories.AND: self._attempt_proof_and,
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Categories.N_OR: self._attempt_proof_n_or,
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Categories.N_IMP: self._attempt_proof_n_imp,
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Categories.OR: self._attempt_proof_or,
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Categories.IMP: self._attempt_proof_imp,
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Categories.N_AND: self._attempt_proof_n_and,
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Categories.IFF: self._attempt_proof_iff,
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Categories.N_IFF: self._attempt_proof_n_iff,
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Categories.EQ: self._attempt_proof_eq,
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Categories.EXISTS: self._attempt_proof_some,
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Categories.ALL: self._attempt_proof_all,
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}[category]
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debug.line((current, context))
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return proof_method(current, context, agenda, accessible_vars, atoms, debug)
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def _attempt_proof_atom(
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self, current, context, agenda, accessible_vars, atoms, debug
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):
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# Check if the branch is closed. Return 'True' if it is
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if (current, True) in atoms:
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debug.line('CLOSED', 1)
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return True
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if context:
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if isinstance(context.term, NegatedExpression):
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current = current.negate()
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agenda.put(context(current).simplify())
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return self._attempt_proof(agenda, accessible_vars, atoms, debug + 1)
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else:
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# mark all AllExpressions as 'not exhausted' into the agenda since we are (potentially) adding new accessible vars
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agenda.mark_alls_fresh()
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return self._attempt_proof(
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agenda,
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accessible_vars | set(current.args),
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atoms | set([(current, False)]),
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debug + 1,
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)
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def _attempt_proof_n_atom(
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self, current, context, agenda, accessible_vars, atoms, debug
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):
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# Check if the branch is closed. Return 'True' if it is
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if (current.term, False) in atoms:
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debug.line('CLOSED', 1)
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return True
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if context:
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if isinstance(context.term, NegatedExpression):
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current = current.negate()
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agenda.put(context(current).simplify())
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return self._attempt_proof(agenda, accessible_vars, atoms, debug + 1)
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else:
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# mark all AllExpressions as 'not exhausted' into the agenda since we are (potentially) adding new accessible vars
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agenda.mark_alls_fresh()
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return self._attempt_proof(
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agenda,
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accessible_vars | set(current.term.args),
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atoms | set([(current.term, True)]),
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debug + 1,
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)
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def _attempt_proof_prop(
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self, current, context, agenda, accessible_vars, atoms, debug
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):
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# Check if the branch is closed. Return 'True' if it is
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if (current, True) in atoms:
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debug.line('CLOSED', 1)
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return True
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# mark all AllExpressions as 'not exhausted' into the agenda since we are (potentially) adding new accessible vars
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agenda.mark_alls_fresh()
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return self._attempt_proof(
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agenda, accessible_vars, atoms | set([(current, False)]), debug + 1
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)
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def _attempt_proof_n_prop(
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self, current, context, agenda, accessible_vars, atoms, debug
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):
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# Check if the branch is closed. Return 'True' if it is
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if (current.term, False) in atoms:
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debug.line('CLOSED', 1)
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return True
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# mark all AllExpressions as 'not exhausted' into the agenda since we are (potentially) adding new accessible vars
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agenda.mark_alls_fresh()
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return self._attempt_proof(
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agenda, accessible_vars, atoms | set([(current.term, True)]), debug + 1
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)
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def _attempt_proof_app(
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self, current, context, agenda, accessible_vars, atoms, debug
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):
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f, args = current.uncurry()
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for i, arg in enumerate(args):
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if not TableauProver.is_atom(arg):
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ctx = f
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nv = Variable('X%s' % _counter.get())
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for j, a in enumerate(args):
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ctx = ctx(VariableExpression(nv)) if i == j else ctx(a)
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if context:
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ctx = context(ctx).simplify()
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ctx = LambdaExpression(nv, ctx)
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agenda.put(arg, ctx)
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return self._attempt_proof(agenda, accessible_vars, atoms, debug + 1)
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raise Exception('If this method is called, there must be a non-atomic argument')
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def _attempt_proof_n_app(
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self, current, context, agenda, accessible_vars, atoms, debug
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):
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f, args = current.term.uncurry()
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for i, arg in enumerate(args):
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if not TableauProver.is_atom(arg):
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ctx = f
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nv = Variable('X%s' % _counter.get())
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for j, a in enumerate(args):
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ctx = ctx(VariableExpression(nv)) if i == j else ctx(a)
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if context:
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# combine new context with existing
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ctx = context(ctx).simplify()
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ctx = LambdaExpression(nv, -ctx)
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agenda.put(-arg, ctx)
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return self._attempt_proof(agenda, accessible_vars, atoms, debug + 1)
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raise Exception('If this method is called, there must be a non-atomic argument')
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def _attempt_proof_n_eq(
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self, current, context, agenda, accessible_vars, atoms, debug
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):
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###########################################################################
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# Since 'current' is of type '~(a=b)', the path is closed if 'a' == 'b'
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###########################################################################
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if current.term.first == current.term.second:
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debug.line('CLOSED', 1)
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return True
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agenda[Categories.N_EQ].add((current, context))
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current._exhausted = True
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return self._attempt_proof(
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agenda,
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accessible_vars | set([current.term.first, current.term.second]),
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atoms,
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debug + 1,
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)
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def _attempt_proof_d_neg(
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self, current, context, agenda, accessible_vars, atoms, debug
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):
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agenda.put(current.term.term, context)
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return self._attempt_proof(agenda, accessible_vars, atoms, debug + 1)
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def _attempt_proof_n_all(
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self, current, context, agenda, accessible_vars, atoms, debug
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):
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agenda[Categories.EXISTS].add(
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(ExistsExpression(current.term.variable, -current.term.term), context)
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)
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return self._attempt_proof(agenda, accessible_vars, atoms, debug + 1)
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def _attempt_proof_n_some(
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self, current, context, agenda, accessible_vars, atoms, debug
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):
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agenda[Categories.ALL].add(
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(AllExpression(current.term.variable, -current.term.term), context)
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)
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return self._attempt_proof(agenda, accessible_vars, atoms, debug + 1)
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def _attempt_proof_and(
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self, current, context, agenda, accessible_vars, atoms, debug
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):
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agenda.put(current.first, context)
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agenda.put(current.second, context)
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return self._attempt_proof(agenda, accessible_vars, atoms, debug + 1)
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def _attempt_proof_n_or(
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self, current, context, agenda, accessible_vars, atoms, debug
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):
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agenda.put(-current.term.first, context)
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agenda.put(-current.term.second, context)
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return self._attempt_proof(agenda, accessible_vars, atoms, debug + 1)
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def _attempt_proof_n_imp(
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self, current, context, agenda, accessible_vars, atoms, debug
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):
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agenda.put(current.term.first, context)
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agenda.put(-current.term.second, context)
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return self._attempt_proof(agenda, accessible_vars, atoms, debug + 1)
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def _attempt_proof_or(
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self, current, context, agenda, accessible_vars, atoms, debug
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):
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new_agenda = agenda.clone()
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agenda.put(current.first, context)
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new_agenda.put(current.second, context)
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return self._attempt_proof(
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agenda, accessible_vars, atoms, debug + 1
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) and self._attempt_proof(new_agenda, accessible_vars, atoms, debug + 1)
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def _attempt_proof_imp(
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self, current, context, agenda, accessible_vars, atoms, debug
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):
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new_agenda = agenda.clone()
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agenda.put(-current.first, context)
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new_agenda.put(current.second, context)
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return self._attempt_proof(
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agenda, accessible_vars, atoms, debug + 1
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) and self._attempt_proof(new_agenda, accessible_vars, atoms, debug + 1)
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def _attempt_proof_n_and(
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self, current, context, agenda, accessible_vars, atoms, debug
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):
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new_agenda = agenda.clone()
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agenda.put(-current.term.first, context)
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new_agenda.put(-current.term.second, context)
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return self._attempt_proof(
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agenda, accessible_vars, atoms, debug + 1
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) and self._attempt_proof(new_agenda, accessible_vars, atoms, debug + 1)
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def _attempt_proof_iff(
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self, current, context, agenda, accessible_vars, atoms, debug
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):
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new_agenda = agenda.clone()
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agenda.put(current.first, context)
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agenda.put(current.second, context)
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new_agenda.put(-current.first, context)
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new_agenda.put(-current.second, context)
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return self._attempt_proof(
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agenda, accessible_vars, atoms, debug + 1
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) and self._attempt_proof(new_agenda, accessible_vars, atoms, debug + 1)
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def _attempt_proof_n_iff(
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self, current, context, agenda, accessible_vars, atoms, debug
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):
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new_agenda = agenda.clone()
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agenda.put(current.term.first, context)
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agenda.put(-current.term.second, context)
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new_agenda.put(-current.term.first, context)
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new_agenda.put(current.term.second, context)
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return self._attempt_proof(
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agenda, accessible_vars, atoms, debug + 1
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) and self._attempt_proof(new_agenda, accessible_vars, atoms, debug + 1)
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def _attempt_proof_eq(
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self, current, context, agenda, accessible_vars, atoms, debug
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):
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#########################################################################
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# Since 'current' is of the form '(a = b)', replace ALL free instances
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# of 'a' with 'b'
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#########################################################################
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agenda.put_atoms(atoms)
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agenda.replace_all(current.first, current.second)
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accessible_vars.discard(current.first)
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agenda.mark_neqs_fresh()
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return self._attempt_proof(agenda, accessible_vars, set(), debug + 1)
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def _attempt_proof_some(
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self, current, context, agenda, accessible_vars, atoms, debug
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):
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new_unique_variable = VariableExpression(unique_variable())
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agenda.put(current.term.replace(current.variable, new_unique_variable), context)
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agenda.mark_alls_fresh()
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return self._attempt_proof(
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agenda, accessible_vars | set([new_unique_variable]), atoms, debug + 1
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)
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def _attempt_proof_all(
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self, current, context, agenda, accessible_vars, atoms, debug
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):
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try:
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current._used_vars
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except AttributeError:
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current._used_vars = set()
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# if there are accessible_vars on the path
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if accessible_vars:
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# get the set of bound variables that have not be used by this AllExpression
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bv_available = accessible_vars - current._used_vars
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if bv_available:
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variable_to_use = list(bv_available)[0]
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debug.line('--> Using \'%s\'' % variable_to_use, 2)
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current._used_vars |= set([variable_to_use])
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agenda.put(
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current.term.replace(current.variable, variable_to_use), context
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)
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agenda[Categories.ALL].add((current, context))
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return self._attempt_proof(agenda, accessible_vars, atoms, debug + 1)
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else:
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# no more available variables to substitute
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debug.line('--> Variables Exhausted', 2)
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current._exhausted = True
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agenda[Categories.ALL].add((current, context))
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return self._attempt_proof(agenda, accessible_vars, atoms, debug + 1)
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else:
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new_unique_variable = VariableExpression(unique_variable())
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debug.line('--> Using \'%s\'' % new_unique_variable, 2)
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current._used_vars |= set([new_unique_variable])
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agenda.put(
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current.term.replace(current.variable, new_unique_variable), context
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)
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agenda[Categories.ALL].add((current, context))
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agenda.mark_alls_fresh()
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return self._attempt_proof(
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agenda, accessible_vars | set([new_unique_variable]), atoms, debug + 1
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)
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@staticmethod
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def is_atom(e):
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if isinstance(e, NegatedExpression):
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e = e.term
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if isinstance(e, ApplicationExpression):
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for arg in e.args:
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if not TableauProver.is_atom(arg):
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return False
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return True
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elif isinstance(e, AbstractVariableExpression) or isinstance(
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e, LambdaExpression
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):
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return True
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else:
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return False
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class TableauProverCommand(BaseProverCommand):
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def __init__(self, goal=None, assumptions=None, prover=None):
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"""
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:param goal: Input expression to prove
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:type goal: sem.Expression
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:param assumptions: Input expressions to use as assumptions in
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the proof.
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:type assumptions: list(sem.Expression)
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"""
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if prover is not None:
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assert isinstance(prover, TableauProver)
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else:
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prover = TableauProver()
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BaseProverCommand.__init__(self, prover, goal, assumptions)
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class Agenda(object):
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def __init__(self):
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self.sets = tuple(set() for i in range(21))
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def clone(self):
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new_agenda = Agenda()
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set_list = [s.copy() for s in self.sets]
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new_allExs = set()
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for allEx, _ in set_list[Categories.ALL]:
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new_allEx = AllExpression(allEx.variable, allEx.term)
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try:
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new_allEx._used_vars = set(used for used in allEx._used_vars)
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except AttributeError:
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new_allEx._used_vars = set()
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new_allExs.add((new_allEx, None))
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set_list[Categories.ALL] = new_allExs
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set_list[Categories.N_EQ] = set(
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(NegatedExpression(n_eq.term), ctx)
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for (n_eq, ctx) in set_list[Categories.N_EQ]
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)
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new_agenda.sets = tuple(set_list)
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return new_agenda
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def __getitem__(self, index):
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return self.sets[index]
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def put(self, expression, context=None):
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if isinstance(expression, AllExpression):
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ex_to_add = AllExpression(expression.variable, expression.term)
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try:
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ex_to_add._used_vars = set(used for used in expression._used_vars)
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except AttributeError:
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ex_to_add._used_vars = set()
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else:
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ex_to_add = expression
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self.sets[self._categorize_expression(ex_to_add)].add((ex_to_add, context))
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def put_all(self, expressions):
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for expression in expressions:
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self.put(expression)
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def put_atoms(self, atoms):
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for atom, neg in atoms:
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if neg:
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self[Categories.N_ATOM].add((-atom, None))
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else:
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self[Categories.ATOM].add((atom, None))
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def pop_first(self):
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""" Pop the first expression that appears in the agenda """
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for i, s in enumerate(self.sets):
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if s:
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if i in [Categories.N_EQ, Categories.ALL]:
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for ex in s:
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try:
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if not ex[0]._exhausted:
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s.remove(ex)
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return (ex, i)
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except AttributeError:
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s.remove(ex)
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return (ex, i)
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else:
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return (s.pop(), i)
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return ((None, None), None)
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def replace_all(self, old, new):
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for s in self.sets:
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for ex, ctx in s:
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ex.replace(old.variable, new)
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if ctx is not None:
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ctx.replace(old.variable, new)
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|
|
def mark_alls_fresh(self):
|
|
for u, _ in self.sets[Categories.ALL]:
|
|
u._exhausted = False
|
|
|
|
def mark_neqs_fresh(self):
|
|
for neq, _ in self.sets[Categories.N_EQ]:
|
|
neq._exhausted = False
|
|
|
|
def _categorize_expression(self, current):
|
|
if isinstance(current, NegatedExpression):
|
|
return self._categorize_NegatedExpression(current)
|
|
elif isinstance(current, FunctionVariableExpression):
|
|
return Categories.PROP
|
|
elif TableauProver.is_atom(current):
|
|
return Categories.ATOM
|
|
elif isinstance(current, AllExpression):
|
|
return Categories.ALL
|
|
elif isinstance(current, AndExpression):
|
|
return Categories.AND
|
|
elif isinstance(current, OrExpression):
|
|
return Categories.OR
|
|
elif isinstance(current, ImpExpression):
|
|
return Categories.IMP
|
|
elif isinstance(current, IffExpression):
|
|
return Categories.IFF
|
|
elif isinstance(current, EqualityExpression):
|
|
return Categories.EQ
|
|
elif isinstance(current, ExistsExpression):
|
|
return Categories.EXISTS
|
|
elif isinstance(current, ApplicationExpression):
|
|
return Categories.APP
|
|
else:
|
|
raise ProverParseError("cannot categorize %s" % current.__class__.__name__)
|
|
|
|
def _categorize_NegatedExpression(self, current):
|
|
negated = current.term
|
|
|
|
if isinstance(negated, NegatedExpression):
|
|
return Categories.D_NEG
|
|
elif isinstance(negated, FunctionVariableExpression):
|
|
return Categories.N_PROP
|
|
elif TableauProver.is_atom(negated):
|
|
return Categories.N_ATOM
|
|
elif isinstance(negated, AllExpression):
|
|
return Categories.N_ALL
|
|
elif isinstance(negated, AndExpression):
|
|
return Categories.N_AND
|
|
elif isinstance(negated, OrExpression):
|
|
return Categories.N_OR
|
|
elif isinstance(negated, ImpExpression):
|
|
return Categories.N_IMP
|
|
elif isinstance(negated, IffExpression):
|
|
return Categories.N_IFF
|
|
elif isinstance(negated, EqualityExpression):
|
|
return Categories.N_EQ
|
|
elif isinstance(negated, ExistsExpression):
|
|
return Categories.N_EXISTS
|
|
elif isinstance(negated, ApplicationExpression):
|
|
return Categories.N_APP
|
|
else:
|
|
raise ProverParseError("cannot categorize %s" % negated.__class__.__name__)
|
|
|
|
|
|
class Debug(object):
|
|
def __init__(self, verbose, indent=0, lines=None):
|
|
self.verbose = verbose
|
|
self.indent = indent
|
|
|
|
if not lines:
|
|
lines = []
|
|
self.lines = lines
|
|
|
|
def __add__(self, increment):
|
|
return Debug(self.verbose, self.indent + 1, self.lines)
|
|
|
|
def line(self, data, indent=0):
|
|
if isinstance(data, tuple):
|
|
ex, ctx = data
|
|
if ctx:
|
|
data = '%s, %s' % (ex, ctx)
|
|
else:
|
|
data = '%s' % ex
|
|
|
|
if isinstance(ex, AllExpression):
|
|
try:
|
|
used_vars = "[%s]" % (
|
|
",".join("%s" % ve.variable.name for ve in ex._used_vars)
|
|
)
|
|
data += ': %s' % used_vars
|
|
except AttributeError:
|
|
data += ': []'
|
|
|
|
newline = '%s%s' % (' ' * (self.indent + indent), data)
|
|
self.lines.append(newline)
|
|
|
|
if self.verbose:
|
|
print(newline)
|
|
|
|
|
|
class Categories(object):
|
|
ATOM = 0
|
|
PROP = 1
|
|
N_ATOM = 2
|
|
N_PROP = 3
|
|
APP = 4
|
|
N_APP = 5
|
|
N_EQ = 6
|
|
D_NEG = 7
|
|
N_ALL = 8
|
|
N_EXISTS = 9
|
|
AND = 10
|
|
N_OR = 11
|
|
N_IMP = 12
|
|
OR = 13
|
|
IMP = 14
|
|
N_AND = 15
|
|
IFF = 16
|
|
N_IFF = 17
|
|
EQ = 18
|
|
EXISTS = 19
|
|
ALL = 20
|
|
|
|
|
|
def testTableauProver():
|
|
tableau_test('P | -P')
|
|
tableau_test('P & -P')
|
|
tableau_test('Q', ['P', '(P -> Q)'])
|
|
tableau_test('man(x)')
|
|
tableau_test('(man(x) -> man(x))')
|
|
tableau_test('(man(x) -> --man(x))')
|
|
tableau_test('-(man(x) and -man(x))')
|
|
tableau_test('(man(x) or -man(x))')
|
|
tableau_test('(man(x) -> man(x))')
|
|
tableau_test('-(man(x) and -man(x))')
|
|
tableau_test('(man(x) or -man(x))')
|
|
tableau_test('(man(x) -> man(x))')
|
|
tableau_test('(man(x) iff man(x))')
|
|
tableau_test('-(man(x) iff -man(x))')
|
|
tableau_test('all x.man(x)')
|
|
tableau_test('all x.all y.((x = y) -> (y = x))')
|
|
tableau_test('all x.all y.all z.(((x = y) & (y = z)) -> (x = z))')
|
|
# tableau_test('-all x.some y.F(x,y) & some x.all y.(-F(x,y))')
|
|
# tableau_test('some x.all y.sees(x,y)')
|
|
|
|
p1 = 'all x.(man(x) -> mortal(x))'
|
|
p2 = 'man(Socrates)'
|
|
c = 'mortal(Socrates)'
|
|
tableau_test(c, [p1, p2])
|
|
|
|
p1 = 'all x.(man(x) -> walks(x))'
|
|
p2 = 'man(John)'
|
|
c = 'some y.walks(y)'
|
|
tableau_test(c, [p1, p2])
|
|
|
|
p = '((x = y) & walks(y))'
|
|
c = 'walks(x)'
|
|
tableau_test(c, [p])
|
|
|
|
p = '((x = y) & ((y = z) & (z = w)))'
|
|
c = '(x = w)'
|
|
tableau_test(c, [p])
|
|
|
|
p = 'some e1.some e2.(believe(e1,john,e2) & walk(e2,mary))'
|
|
c = 'some e0.walk(e0,mary)'
|
|
tableau_test(c, [p])
|
|
|
|
c = '(exists x.exists z3.((x = Mary) & ((z3 = John) & sees(z3,x))) <-> exists x.exists z4.((x = John) & ((z4 = Mary) & sees(x,z4))))'
|
|
tableau_test(c)
|
|
|
|
|
|
# p = 'some e1.some e2.((believe e1 john e2) and (walk e2 mary))'
|
|
# c = 'some x.some e3.some e4.((believe e3 x e4) and (walk e4 mary))'
|
|
# tableau_test(c, [p])
|
|
|
|
|
|
def testHigherOrderTableauProver():
|
|
tableau_test('believe(j, -lie(b))', ['believe(j, -lie(b) & -cheat(b))'])
|
|
tableau_test('believe(j, lie(b) & cheat(b))', ['believe(j, lie(b))'])
|
|
tableau_test(
|
|
'believe(j, lie(b))', ['lie(b)']
|
|
) # how do we capture that John believes all things that are true
|
|
tableau_test(
|
|
'believe(j, know(b, cheat(b)))',
|
|
['believe(j, know(b, lie(b)) & know(b, steals(b) & cheat(b)))'],
|
|
)
|
|
tableau_test('P(Q(y), R(y) & R(z))', ['P(Q(x) & Q(y), R(y) & R(z))'])
|
|
|
|
tableau_test('believe(j, cheat(b) & lie(b))', ['believe(j, lie(b) & cheat(b))'])
|
|
tableau_test('believe(j, -cheat(b) & -lie(b))', ['believe(j, -lie(b) & -cheat(b))'])
|
|
|
|
|
|
def tableau_test(c, ps=None, verbose=False):
|
|
pc = Expression.fromstring(c)
|
|
pps = [Expression.fromstring(p) for p in ps] if ps else []
|
|
if not ps:
|
|
ps = []
|
|
print(
|
|
'%s |- %s: %s'
|
|
% (', '.join(ps), pc, TableauProver().prove(pc, pps, verbose=verbose))
|
|
)
|
|
|
|
|
|
def demo():
|
|
testTableauProver()
|
|
testHigherOrderTableauProver()
|
|
|
|
|
|
if __name__ == '__main__':
|
|
demo()
|