def setUp(self):
"""
Sets up the test runner for the puzzle.
"""
from puzzles.liarliar import Puzzle
self.runner = Puzzle()
class LiarTestCase(TestCase):
def setUp(self):
"""
Sets up the test runner for the puzzle.
"""
from puzzles.liarliar import Puzzle
self.runner = Puzzle()
def test_puzzle_runs(self):
"""
Test case to ensure that the liar puzzle exists and runs.
"""
self.runner.run(None)
pass
def test_provide_invalid_noinput(self):
"""
Tests that input should actually be there.
"""
success, result = self.runner.is_valid(None)
assert not success, 'The given input is not considered valid if it is None'
assert that(result).equals('You must provide a valid input file')
def test_provide_invalid_no_count(self):
"""
Tests that the first line is always the count.
"""
success, result = self.runner.is_valid('xx')
assert not success, 'The given input is not considered valid if there is no count'
assert that(result).equals('The first line in the input should be the count')
def test_provide_invalid_no_match(self):
"""
Tests that an input lines must always be provided.
"""
lines = ['2', 'Jeff 2', '323&&invalid line here 33 sd']
success, result = self.runner.is_valid(lines)
assert not success, 'The given input is not valid with an invalid line match'
assert that(result).equals('All lines must contain a valid name and/or count match')
def test_valid_matches(self):
"""
Tests that a valid match is made and a match set is returned.
"""
lines = ['2', 'Jeff 1', 'Joe', 'Tom 1', 'Joe']
success, result = self.runner.is_valid(lines)
assert success, 'A valid set of lines should be successful in matching'
assert that(result).equals([{'count': '1', 'name': 'Jeff'},
{'count': '0', 'name': 'Joe'},
{'count': '1', 'name': 'Tom'},
{'count': '0', 'name': 'Joe'}])
def test_build_graph(self):
"""
Tests that the result of matches from the input
is successfully built into a undirected connected graph.
"""
lines = ['2', 'Jeff 1', 'Joe', 'Tom 1', 'Joe']
success, result = self.runner.is_valid(lines)
graph, start = self.runner.build_graph(result)
assert graph == {
'Jeff': {'Joe': True},
'Joe': {
'Tom': True,
'Jeff': True
},
'Tom': {'Joe': True}
}
assert that(start).equals('Tom')
def test_bfs(self):
"""
Tests that the given breadth-first search algorithm appropriately separates the groups.
"""
lines = ['2', 'Jeff 1', 'Joe', 'Tom 1', 'Joe']
success, result = self.runner.is_valid(lines)
graph, start = self.runner.build_graph(result)
g1, g2 = self.runner.bfs(graph, start)
assert g1 == {'Jeff': True, 'Tom': True}, 'Jeff and Tom, having a connection through Joe, are in group 1'
assert g2 == {'Joe': True}, 'Joe, having no connections out, is in group 2'
assert that(len(g1)).equals(2) and that(len(g2)).equals(1), 'BFS should determine a group of 2 and a group of 1'
