1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
|
# coding=utf-8
from operator import itemgetter
import socket
import prolog.engine
import prolog.util
from server.hints import Hint, HintSequence
import server.problems
id = 99
number = 6
visible = True
facts = 'family_relations'
solution = '''\
sister99(X, Y) :-
parent(P, X),
parent(P, Y),
female(X),
X \== Y.
brother99(X, Y) :-
parent(P, X),
parent(P, Y),
male(X),
X \== Y.
cousin(X, Y) :-
parent(PX, X),
parent(PY, Y),
( brother99(PX, PY)
;
sister99(PX, PY) ).
'''
hint_type = {
'gender_is_irrelevant': Hint('gender_is_irrelevant'),
'precedence_fail': Hint('precedence_fail'),
'cousin_vs_sibling': Hint('cousin_vs_sibling'),
'cousin_to_oneself': Hint('cousin_to_oneself'),
'cousin_need_not_be_parent': Hint('cousin_need_not_be_parent'),
}
test_cases = [
# TODO
]
def test(program, solved_problems):
code = (program + '\n' +
server.problems.solutions_for_problems('prolog', solved_problems) + '\n' +
server.problems.load_facts('prolog', facts).facts)
engine_id = None
try:
engine_id, output = prolog.engine.create(code=code, timeout=1.0)
if not engine_id or 'error' in map(itemgetter(0), output):
# Engine creation failed, or syntax error in code.
return 0, len(test_cases)
n_correct = 0
for query, answers in test_cases:
# Limit inferences for each solution to curb unbounded recursion.
limited = 'call_with_inference_limit(({}), 100000, _)'.format(query)
if prolog.engine.check_answers(engine_id, query=limited, answers=answers, timeout=1.0):
n_correct += 1
finally:
if engine_id:
prolog.engine.destroy(engine_id)
passed = n_correct == len(test_cases)
hints = [{'id': 'test_results', 'args': {'passed': n_correct, 'total': len(test_cases)}}]
return passed, hints
def hint(program, solved_problems):
tokens = prolog.util.tokenize(program)
code = (program + '\n' +
server.problems.solutions_for_problems('prolog', solved_problems) + '\n' +
server.problems.load_facts('prolog', facts).facts)
engine_id = None
try:
engine_id, output = prolog.engine.create(code=code, timeout=1.0)
if not engine_id:
raise Exception('Prolog engine failed to create.')
# gender testing is redundant
# this is not necessarily wrong, but worth mentioning anyway
targets = [prolog.util.Token('NAME', 'male'), prolog.util.Token('NAME', 'female')]
pos = [(t.pos, t.pos + len(t.val)) for t in tokens if t in targets]
if pos:
# TODO: resolve how highlighting info is communicated
return [{'id': 'gender_is_irrelevant', 'highlight': pos}]
# precedence fail (AND block vs OR block)
# case in point: parent(PX, X), parent(PY, Y), brother(PX, PY) ; sister(PX, PY)
# or this case: parent(PX, X), parent(PY, Y), sister(PX, PY) ; brother(PX, PY)
# warning: knowledge base dependent
if prolog.util.Token('SEMI', ';') in tokens and prolog.engine.ask_truth(engine_id,
'findall(_, cousin(X, Y), L), (length(L, 14) ; length(L, 16))'):
return [{'id', 'precedence_fail'}]
# cousin should not be brother or sister
# common parent, probably solved via grandparent
if prolog.engine.ask_truth(engine_id,
'cousin(X, Y), (brother(X, Y) ; sister(X, Y))'):
return [{'id', 'cousin_vs_sibling'}]
# cousin to him/herself
# just common grandparent is not enough
if prolog.engine.ask_truth(engine_id, 'cousin(X, X)'):
return [{'id', 'cousin_to_oneself'}]
# X (or Y) does not necessarily need to be a parent
# cousin is a symmetrical relation, so X and Y are covered by this
if prolog.engine.ask_one(engine_id,
'cousin(X, _), \+ parent(X, _)') == 'false':
return [{'id': 'cousin_need_not_be_parent'}]
except socket.timeout as ex:
pass
finally:
if engine_id:
prolog.engine.destroy(engine_id)
return None
|
