def test_predict(self):
game_root = Game()
root = Node(game_root)
model = MagicMock()
prediction = [
np.array([[0.25]]),
np.reshape(np.arange(0.001, 0.897, step=0.001), newshape=(1, 896))
]
model.predict.return_value = prediction
action_encoder = ActionEncoder(DirectionResolver())
mcts = MCTS(root,
config={
'ALPHA': 0.8,
'CPUCT': 1,
'EPSILON': 0.2
},
model=model,
state_encoder=StateEncoder(),
action_encoder=action_encoder)
value, probs, allowed_actions = mcts.predict_state_value(game_root)
self.assertEqual(value, 0.25)
self.assertCountEqual(
allowed_actions,
action_encoder.convert_moves_to_action_ids(
game_root.get_possible_moves_from_current_player_perspective())
)
for idx, prob in enumerate(probs):
if idx in allowed_actions:
self.assertTrue(prob > 0.01)
else:
self.assertTrue(prob < np.exp(-40))
def test_evaluate_leaf(self):
game_root = Game()
root = Node(game_root)
model = MagicMock()
prediction = [
np.array([[0.25]]),
np.reshape(np.arange(0.001, 0.897, step=0.001), newshape=(1, 896))
]
model.predict.return_value = prediction
action_encoder = ActionEncoder(DirectionResolver())
mcts = MCTS(root,
config={
'ALPHA': 0.8,
'CPUCT': 1,
'EPSILON': 0.2
},
model=model,
state_encoder=StateEncoder(),
action_encoder=action_encoder)
_, probs, _ = mcts.predict_state_value(game_root)
value = mcts.evaluate_leaf(root)
self.assertEqual(value, 0.25)
self.assertEqual(len(root.edges), 7)
self.assertEqual(root.edges[0].action, 8)
self.assertEqual(root.edges[0].stats['P'], probs[8])
self.assertEqual(root.edges[1].action, 104)
self.assertEqual(root.edges[1].stats['P'], probs[104])
def test_convert_to_one_hot_3(self):
encoder = ActionEncoder(DirectionResolver())
actual_action = encoder.convert_action_to_one_hot([1, 5])
expected_action = np.zeros((1, 32 * 4))
expected_action[0, 0] = 1
self.assertTrue(
np.array_equal(actual_action.toarray(), expected_action))
def read_agent(version):
nn = Residual_CNN(config['REG_CONST'], config['LEARNING_RATE'], (2, 4, 8),
config['ACTION_SIZE'], config['HIDDEN_CNN_LAYERS'],
config['MOMENTUM'])
m_tmp = nn.read(version)
nn.model.set_weights(m_tmp.get_weights())
player = Agent(nn,
ActionEncoder(DirectionResolver()),
StateEncoder(),
name='player' + str(version),
config=config)
return player
class StateEncoder:
def __init__(self):
self.direction_resolver = DirectionResolver()
def encode(self, state):
encoded_state = np.zeros((2, 4, 8))
for piece in state.board.pieces:
if piece.captured:
continue
if state.whose_turn() == 1:
x, y = self.direction_resolver.get_compressed_coordinates(
piece.position)
if piece.player == state.whose_turn():
if piece.king:
encoded_state[0, y, x] = 2
else:
encoded_state[0, y, x] = 1
else:
if piece.king:
encoded_state[1, y, x] = 2
else:
encoded_state[1, y, x] = 1
else:
x, y = self.direction_resolver.get_compressed_coordinates(
33 - piece.position)
if piece.player == state.whose_turn():
if piece.king:
encoded_state[0, y, x] = 2
else:
encoded_state[0, y, x] = 1
else:
if piece.king:
encoded_state[1, y, x] = 2
else:
encoded_state[1, y, x] = 1
return encoded_state
def test_act_tau_0(self):
config = {
'ALPHA': 0.8,
'CPUCT': 1,
'EPSILON': 0.2,
'ACTION_SIZE': 32 * 4 * 7,
'MCTS_SIMULATIONS': 3
}
action_encoder = ActionEncoder(DirectionResolver())
agent = Agent(model=None, action_encoder=action_encoder, state_encoder=StateEncoder(), name='player1', config=config)
game_root = Game()
root_node = Node(game_root)
child1 = Node(game_root.move(game_root.get_possible_moves()[0]))
edge1 = Edge(root_node, child1, 0.33, 8)
edge1.stats['N'] = 10
edge1.stats['Q'] = 0.2
root_node.edges.append(edge1)
child2 = Node(game_root.move(game_root.get_possible_moves()[1]))
edge2 = Edge(root_node, child2, 0.5, 104)
edge2.stats['N'] = 20
edge2.stats['Q'] = 0.5
root_node.edges.append(edge2)
child3 = Node(game_root.move(game_root.get_possible_moves()[2]))
edge3 = Edge(root_node, child3, 0.17, 9)
edge3.stats['N'] = 15
edge3.stats['Q'] = 0.3
root_node.edges.append(edge3)
agent.prepare_mcts_for_next_action = MagicMock()
mcts = MagicMock()
mcts.root = root_node
mcts.evaluate_leaf.return_value = 0.7
agent.mcts = mcts
mcts.move_to_leaf.return_value = (root_node, 0.5, False, [])
action, pi, value = agent.act(game_root, tau=0)
self.assertEqual(action, [9, 14])
self.assertEqual(value, 0.5)
self.assertEqual(pi[8], 10/(10 + 20 + 15))
self.assertEqual(pi[9], 15/(10 + 20 + 15))
self.assertEqual(pi[8 + 3*32], 20/(10 + 20 + 15))
def test_move_to_leaf(self):
game = Game()
root = Node(game)
action_encoder = ActionEncoder(DirectionResolver())
mcts = MCTS(root,
config={
'ALPHA': 0.8,
'CPUCT': 1,
'EPSILON': 0.2
},
model=None,
state_encoder=None,
action_encoder=action_encoder)
puct = MagicMock()
mcts.puct = puct
child1 = Node(game.move(game.get_possible_moves()[0]))
child2 = Node(game.move(game.get_possible_moves()[1]))
child3 = Node(game.move(game.get_possible_moves()[2]))
edge1 = Edge(
root, child1, 0.33,
action_encoder.convert_move_to_action_id(
game.get_possible_moves()[0]))
edge2 = Edge(
root, child2, 0.34,
action_encoder.convert_move_to_action_id(
game.get_possible_moves()[1]))
edge3 = Edge(
root, child3, 0.33,
action_encoder.convert_move_to_action_id(
game.get_possible_moves()[2]))
root.edges.append(edge1)
root.edges.append(edge2)
root.edges.append(edge3)
puct.puct.return_value = edge2
leaf, value, done, breadcrumbs = mcts.move_to_leaf()
self.assertEquals(leaf, child2)
self.assertEquals(value, 0)
self.assertEquals(done, 0)
self.assertEquals(False, 0)
self.assertEquals(True, 1)
def test_integration(self):
HIDDEN_CNN_LAYERS = [{
'filters': 75,
'kernel_size': (4, 4)
}, {
'filters': 75,
'kernel_size': (4, 4)
}, {
'filters': 75,
'kernel_size': (4, 4)
}, {
'filters': 75,
'kernel_size': (4, 4)
}, {
'filters': 75,
'kernel_size': (4, 4)
}, {
'filters': 75,
'kernel_size': (4, 4)
}]
model = Residual_CNN(0.0001,
0.1, (2, 4, 8),
32 * 4,
HIDDEN_CNN_LAYERS,
momentum=0.9)
game_root = Game()
root = Node(game_root)
mcts = MCTS(root,
config={
'ALPHA': 0.8,
'CPUCT': 1,
'EPSILON': 0.2
},
model=model,
state_encoder=StateEncoder(),
action_encoder=ActionEncoder(DirectionResolver()))
mcts.predict_state_value(game_root)
mcts.evaluate_leaf(root)
def test_backfill(self):
game_root = Game()
root = Node(game_root)
action_encoder = ActionEncoder(DirectionResolver())
position1 = game_root.move(game_root.get_possible_moves()[0])
child1 = Node(position1)
edge1 = Edge(
root, child1, 0.3,
action_encoder.convert_move_to_action_id(
game_root.get_possible_moves()[0]))
position2 = position1.move(position1.get_possible_moves()[0])
child2 = Node(position2)
edge2 = Edge(
child1, child2, 0.2,
action_encoder.convert_move_to_action_id(
game_root.get_possible_moves()[0]))
edge2.stats['N'] = 4
edge2.stats['W'] = 1
mcts = MCTS(root,
config={
'ALPHA': 0.8,
'CPUCT': 1,
'EPSILON': 0.2
},
model=None,
state_encoder=None,
action_encoder=action_encoder)
mcts.backfill(child2, -1, [edge2, edge1])
self.assertEquals(edge2.stats['N'], 5)
self.assertEquals(edge2.stats['W'], 2)
self.assertEquals(edge2.stats['Q'], 2 / 5)
self.assertEquals(edge1.stats['N'], 1)
self.assertEquals(edge1.stats['W'], -1)
self.assertEquals(edge1.stats['Q'], -1)
config['ACTION_SIZE'], config['HIDDEN_CNN_LAYERS'],
config['MOMENTUM'])
if "INITIAL_MODEL_VERSION" in config:
best_player_version = config["INITIAL_MODEL_VERSION"]
logging.info('LOADING MODEL VERSION ' +
str(config["INITIAL_MODEL_VERSION"]) + '...')
m_tmp = best_NN.read(best_player_version)
current_NN.model.set_weights(m_tmp.get_weights())
best_NN.model.set_weights(m_tmp.get_weights())
else:
best_player_version = 0
best_NN.model.set_weights(current_NN.model.get_weights())
current_player = Agent(current_NN,
ActionEncoder(DirectionResolver()),
StateEncoder(),
name='current_player',
config=config)
best_player = Agent(best_NN,
ActionEncoder(DirectionResolver()),
StateEncoder(),
name='best_player',
config=config)
iteration = 0
while 1:
iteration += 1
logging.info('ITERATION NUMBER ' + str(iteration))
def test_resolve_direction_north_east(self): resolver = DirectionResolver() self.assertEquals(resolver.resolve_direction([10, 17]), NORTH_EAST) self.assertEquals(resolver.resolve_direction([10, 14]), NORTH_EAST)
def test_convert_action_id_to_true_position_and_direction_4(self):
encoder = ActionEncoder(DirectionResolver())
move = encoder.convert_action_id_to_true_position_and_direction(105, 2)
self.assertEqual(move, (23, 2))
def test_convert_action_id_to_position_and_direction_2(self):
encoder = ActionEncoder(DirectionResolver())
move = encoder.convert_action_id_to_position_and_direction(105)
self.assertEqual(move, (10, 4))
def test_convert_position_direction_distance_to_move_1(self):
encoder = ActionEncoder(DirectionResolver())
move = encoder.convert_direction_and_distance_to_move(10, 4, 1)
self.assertEqual(move, [10, 15])
def test_convert_moves_to_action_ids(self):
encoder = ActionEncoder(DirectionResolver())
values = encoder.convert_moves_to_action_ids([[10, 17], [10, 15]])
self.assertCountEqual(values, [9, 105])
def __init__(self):
self.direction_resolver = DirectionResolver()
def test_resolve_direction_south_east(self): resolver = DirectionResolver() self.assertEquals(resolver.resolve_direction([10, 6]), SOUTH_EAST) self.assertEquals(resolver.resolve_direction([10, 1]), SOUTH_EAST)
def test_resolve_direction_invalid_move(self): resolver = DirectionResolver() self.assertRaises(Exception, resolver.resolve_direction, [10, 11])
def test_resolve_direction_south_west(self): resolver = DirectionResolver() self.assertEquals(resolver.resolve_direction([10, 7]), SOUTH_WEST) self.assertEquals(resolver.resolve_direction([10, 3]), SOUTH_WEST)
def test_resolve_direction_north_west(self): resolver = DirectionResolver() self.assertEquals(resolver.resolve_direction([10, 15]), NORTH_WEST) self.assertEquals(resolver.resolve_direction([10, 19]), NORTH_WEST)
def test_get_coordinates(self): resolver = DirectionResolver() x, y = resolver.get_coordinates(9) self.assertEqual(x, 6) self.assertEqual(y, 2)
def test_get_coordinates_compressed_2(self): resolver = DirectionResolver() x, y = resolver.get_compressed_coordinates(15) self.assertEqual(x, 3) self.assertEqual(y, 1)
