CofeehousePy/nlpfr/nltk/test/resolution.doctest

.. Copyright (C) 2001-2019 NLTK Project
.. For license information, see LICENSE.TXT

=========================
Resolution Theorem Prover
=========================

    >>> from nltk.inference.resolution import *
    >>> from nltk.sem import logic
    >>> from nltk.sem.logic import *
    >>> logic._counter._value = 0
    >>> read_expr = logic.Expression.fromstring

    >>> P = read_expr('P')
    >>> Q = read_expr('Q')
    >>> R = read_expr('R')
    >>> A = read_expr('A')
    >>> B = read_expr('B')
    >>> x = read_expr('x')
    >>> y = read_expr('y')
    >>> z = read_expr('z')

-------------------------------
Test most_general_unification()
-------------------------------
    >>> print(most_general_unification(x, x))
    {}
    >>> print(most_general_unification(A, A))
    {}
    >>> print(most_general_unification(A, x))
    {x: A}
    >>> print(most_general_unification(x, A))
    {x: A}
    >>> print(most_general_unification(x, y))
    {x: y}
    >>> print(most_general_unification(P(x), P(A)))
    {x: A}
    >>> print(most_general_unification(P(x,B), P(A,y)))
    {x: A, y: B}
    >>> print(most_general_unification(P(x,B), P(B,x)))
    {x: B}
    >>> print(most_general_unification(P(x,y), P(A,x)))
    {x: A, y: x}
    >>> print(most_general_unification(P(Q(x)), P(y)))
    {y: Q(x)}

------------
Test unify()
------------
    >>> print(Clause([]).unify(Clause([])))
    []
    >>> print(Clause([P(x)]).unify(Clause([-P(A)])))
    [{}]
    >>> print(Clause([P(A), Q(x)]).unify(Clause([-P(x), R(x)])))
    [{R(A), Q(A)}]
    >>> print(Clause([P(A), Q(x), R(x,y)]).unify(Clause([-P(x), Q(y)])))
    [{Q(y), Q(A), R(A,y)}]
    >>> print(Clause([P(A), -Q(y)]).unify(Clause([-P(x), Q(B)])))
    [{}]
    >>> print(Clause([P(x), Q(x)]).unify(Clause([-P(A), -Q(B)])))
    [{-Q(B), Q(A)}, {-P(A), P(B)}]
    >>> print(Clause([P(x,x), Q(x), R(x)]).unify(Clause([-P(A,z), -Q(B)])))
    [{-Q(B), Q(A), R(A)}, {-P(A,z), R(B), P(B,B)}]

    >>> a = clausify(read_expr('P(A)'))
    >>> b = clausify(read_expr('A=B'))
    >>> print(a[0].unify(b[0]))
    [{P(B)}]

-------------------------
Test is_tautology()
-------------------------
    >>> print(Clause([P(A), -P(A)]).is_tautology())
    True
    >>> print(Clause([-P(A), P(A)]).is_tautology())
    True
    >>> print(Clause([P(x), -P(A)]).is_tautology())
    False
    >>> print(Clause([Q(B), -P(A), P(A)]).is_tautology())
    True
    >>> print(Clause([-Q(A), P(R(A)), -P(R(A)), Q(x), -R(y)]).is_tautology())
    True
    >>> print(Clause([P(x), -Q(A)]).is_tautology())
    False

-------------------------
Test subsumes()
-------------------------
    >>> print(Clause([P(A), Q(B)]).subsumes(Clause([P(A), Q(B)])))
    True
    >>> print(Clause([-P(A)]).subsumes(Clause([P(A)])))
    False
    >>> print(Clause([P(A), Q(B)]).subsumes(Clause([Q(B), P(A)])))
    True
    >>> print(Clause([P(A), Q(B)]).subsumes(Clause([Q(B), R(A), P(A)])))
    True
    >>> print(Clause([P(A), R(A), Q(B)]).subsumes(Clause([Q(B), P(A)])))
    False
    >>> print(Clause([P(x)]).subsumes(Clause([P(A)])))
    True
    >>> print(Clause([P(A)]).subsumes(Clause([P(x)])))
    True

------------
Test prove()
------------
    >>> print(ResolutionProverCommand(read_expr('man(x)')).prove())
    False
    >>> print(ResolutionProverCommand(read_expr('(man(x) -> man(x))')).prove())
    True
    >>> print(ResolutionProverCommand(read_expr('(man(x) -> --man(x))')).prove())
    True
    >>> print(ResolutionProverCommand(read_expr('-(man(x) & -man(x))')).prove())
    True
    >>> print(ResolutionProverCommand(read_expr('(man(x) | -man(x))')).prove())
    True
    >>> print(ResolutionProverCommand(read_expr('(man(x) -> man(x))')).prove())
    True
    >>> print(ResolutionProverCommand(read_expr('-(man(x) & -man(x))')).prove())
    True
    >>> print(ResolutionProverCommand(read_expr('(man(x) | -man(x))')).prove())
    True
    >>> print(ResolutionProverCommand(read_expr('(man(x) -> man(x))')).prove())
    True
    >>> print(ResolutionProverCommand(read_expr('(man(x) <-> man(x))')).prove())
    True
    >>> print(ResolutionProverCommand(read_expr('-(man(x) <-> -man(x))')).prove())
    True
    >>> print(ResolutionProverCommand(read_expr('all x.man(x)')).prove())
    False
    >>> print(ResolutionProverCommand(read_expr('-all x.some y.F(x,y) & some x.all y.(-F(x,y))')).prove())
    False
    >>> print(ResolutionProverCommand(read_expr('some x.all y.sees(x,y)')).prove())
    False

    >>> p1 = read_expr('all x.(man(x) -> mortal(x))')
    >>> p2 = read_expr('man(Socrates)')
    >>> c = read_expr('mortal(Socrates)')
    >>> ResolutionProverCommand(c, [p1,p2]).prove()
    True

    >>> p1 = read_expr('all x.(man(x) -> walks(x))')
    >>> p2 = read_expr('man(John)')
    >>> c = read_expr('some y.walks(y)')
    >>> ResolutionProverCommand(c, [p1,p2]).prove()
    True

    >>> p = read_expr('some e1.some e2.(believe(e1,john,e2) & walk(e2,mary))')
    >>> c = read_expr('some e0.walk(e0,mary)')
    >>> ResolutionProverCommand(c, [p]).prove()
    True

------------
Test proof()
------------
    >>> p1 = read_expr('all x.(man(x) -> mortal(x))')
    >>> p2 = read_expr('man(Socrates)')
    >>> c = read_expr('mortal(Socrates)')
    >>> logic._counter._value = 0
    >>> tp = ResolutionProverCommand(c, [p1,p2])
    >>> tp.prove()
    True
    >>> print(tp.proof())
    [1] {-mortal(Socrates)}     A
    [2] {-man(z2), mortal(z2)}  A
    [3] {man(Socrates)}         A
    [4] {-man(Socrates)}        (1, 2)
    [5] {mortal(Socrates)}      (2, 3)
    [6] {}                      (1, 5)
    <BLANKLINE>

------------------
Question Answering
------------------
One answer
    >>> p1 = read_expr('father_of(art,john)')
    >>> p2 = read_expr('father_of(bob,kim)')
    >>> p3 = read_expr('all x.all y.(father_of(x,y) -> parent_of(x,y))')
    >>> c = read_expr('all x.(parent_of(x,john) -> ANSWER(x))')
    >>> logic._counter._value = 0
    >>> tp = ResolutionProverCommand(None, [p1,p2,p3,c])
    >>> sorted(tp.find_answers())
    [<ConstantExpression art>]
    >>> print(tp.proof()) # doctest: +SKIP
    [1] {father_of(art,john)}                  A
    [2] {father_of(bob,kim)}                   A
    [3] {-father_of(z3,z4), parent_of(z3,z4)}  A
    [4] {-parent_of(z6,john), ANSWER(z6)}      A
    [5] {parent_of(art,john)}                  (1, 3)
    [6] {parent_of(bob,kim)}                   (2, 3)
    [7] {ANSWER(z6), -father_of(z6,john)}      (3, 4)
    [8] {ANSWER(art)}                          (1, 7)
    [9] {ANSWER(art)}                          (4, 5)
    <BLANKLINE>

Multiple answers
    >>> p1 = read_expr('father_of(art,john)')
    >>> p2 = read_expr('mother_of(ann,john)')
    >>> p3 = read_expr('all x.all y.(father_of(x,y) -> parent_of(x,y))')
    >>> p4 = read_expr('all x.all y.(mother_of(x,y) -> parent_of(x,y))')
    >>> c = read_expr('all x.(parent_of(x,john) -> ANSWER(x))')
    >>> logic._counter._value = 0
    >>> tp = ResolutionProverCommand(None, [p1,p2,p3,p4,c])
    >>> sorted(tp.find_answers())
    [<ConstantExpression ann>, <ConstantExpression art>]
    >>> print(tp.proof()) # doctest: +SKIP
    [ 1] {father_of(art,john)}                  A
    [ 2] {mother_of(ann,john)}                  A
    [ 3] {-father_of(z3,z4), parent_of(z3,z4)}  A
    [ 4] {-mother_of(z7,z8), parent_of(z7,z8)}  A
    [ 5] {-parent_of(z10,john), ANSWER(z10)}    A
    [ 6] {parent_of(art,john)}                  (1, 3)
    [ 7] {parent_of(ann,john)}                  (2, 4)
    [ 8] {ANSWER(z10), -father_of(z10,john)}    (3, 5)
    [ 9] {ANSWER(art)}                          (1, 8)
    [10] {ANSWER(z10), -mother_of(z10,john)}    (4, 5)
    [11] {ANSWER(ann)}                          (2, 10)
    [12] {ANSWER(art)}                          (5, 6)
    [13] {ANSWER(ann)}                          (5, 7)
    <BLANKLINE>