def reset(self):
if self._done:
self._episode += 1
self._done = False
# print(f'Episode: {self._episode} done!')
if self._is_running:
self.sim.finishing_touch(self._start_time)
if self._episode % self._save_res_every_ep == 0:
self.sim.save_result(RESULTS,
self._worker_id,
unique_name=False)
if self._config['plot_queue_len']:
self.sim.plot_pass_queue_len(mode='taxi',
suffix=self._worker_id)
self.sim.plot_pass_wait_time(mode='taxi',
suffix=self._worker_id)
self._is_running = False
self.curr_time = 0
self._step = 0
self.graph = Graph()
self.graph.import_graph(graph_file)
self.sim = Simulator(self.graph)
self.sim.import_arrival_rate(unit=(1, 'sec'))
self.sim.import_vehicle_attribute(file_name=vehicle_file)
self.sim.set_running_time(start_time=self._config['start_time'],
time_horizon=self._config['time_horizon'],
unit='hour')
self.sim.routing.set_routing_method('simplex')
self.sim.initialize(seed=0)
self._total_vehicle = self.sim.vehicle_attri['taxi']['total']
self._travel_time = np.zeros((self._num_nodes, self._num_nodes))
for i, node in enumerate(self.graph.graph_top):
for j, road in enumerate(self.graph.graph_top):
if i != j:
self._travel_time[
i,
j] = self.graph.graph_top[node]['node'].road[road].dist
self._travel_time /= np.linalg.norm(self._travel_time, ord=np.inf)
self._pre_action = np.zeros((self._num_neighbors, self._num_nodes))
with open(vehicle_file, 'r') as v_file:
vehicle_dist = json.load(v_file)
vehicle_dist = vehicle_dist['taxi']['distrib']
vehicle_dist = np.array([vehicle_dist[x] for x in vehicle_dist])
return np.zeros((self._num_nodes, )), vehicle_dist
def __init__(self, config):
self._config = config
self.curr_time = 0
self.graph = Graph()
self.graph.import_graph(graph_file)
self.sim = Simulator(self.graph)
self.max_vehicle = self._config['max_vehicle']
self.reb_interval = self._config['reb_interval']
self.max_travel_t = self._config['max_travel_time']
self.max_lookback_steps = int(
np.ceil(self.max_travel_t / self.reb_interval))
self.max_passenger = self._config['max_passenger']
self._num_nodes = len(self._config['nodes_list'])
self._nodes = tuple(self._config['nodes_list'])
self._num_neighbors = self._config['near_neighbor']
self._neighbor_map = self._get_neighbors()
self._dispatch_rate = self._config['dispatch_rate']
self.action_space = MultiDiscrete([(self._num_neighbors + 1) * 5] *
self._num_nodes)
self.observation_space = Tuple((Box(0,
self.max_passenger,
shape=(self._num_nodes, ),
dtype=np.int64),
Box(0,
self.max_vehicle,
shape=(self._num_nodes, ),
dtype=np.int64)))
self._is_running = False
self._done = False
self._start_time = time.time()
self._alpha = self._config['alpha']
self._beta = self._config['beta']
self._step = 0
self._total_vehicle = None
self._travel_time = None
self._pre_action = None
self._episode = 0
self._worker_id = str(hash(time.time()))
self._save_res_every_ep = int(self._config['save_res_every_ep'])
self._vehicle_speed = self._config['veh_speed']
def __init__(self, config):
self._config = config
self.curr_time = 0
self.graph = Graph()
self.graph.import_graph(graph_file)
self.sim = Simulator(self.graph)
self.max_vehicle = self._config['max_vehicle']
self.reb_interval = self._config['reb_interval']
self.max_travel_t = self._config['max_travel_time']
self.max_lookback_steps = int(
np.ceil(self.max_travel_t / self.reb_interval))
self.max_passenger = self._config['max_passenger']
self.num_nodes = len(self._config['nodes_list'])
self.near_neighbor = self._config['near_neighbor']
self.action_space = Box(low=0,
high=1,
shape=((self.near_neighbor + 1) *
self.num_nodes, ))
self.observation_space = Tuple((Box(0,
self.max_passenger,
shape=(self.num_nodes, ),
dtype=np.int64),
Box(0,
self.max_vehicle,
shape=(self.num_nodes, ),
dtype=np.int64)))
self._is_running = False
self._done = False
self._start_time = time.time()
self._alpha = 0
self._step = 0
self._total_vehicle = None
self._travel_time = None
self._pre_action = None
self._episode = 0
class TaxiRebalance(gym.Env, ABC):
def __init__(self, config):
self._config = config
self.curr_time = 0
self.graph = Graph()
self.graph.import_graph(graph_file)
self.sim = Simulator(self.graph)
self.max_vehicle = self._config['max_vehicle']
self.reb_interval = self._config['reb_interval']
self.max_travel_t = self._config['max_travel_time']
self.max_lookback_steps = int(
np.ceil(self.max_travel_t / self.reb_interval))
self.max_passenger = self._config['max_passenger']
self._num_nodes = len(self._config['nodes_list'])
self._nodes = tuple(self._config['nodes_list'])
self._num_neighbors = self._config['near_neighbor']
self._neighbor_map = self._get_neighbors()
self._dispatch_rate = self._config['dispatch_rate']
self.action_space = MultiDiscrete([(self._num_neighbors + 1) * 5] *
self._num_nodes)
self.observation_space = Tuple((Box(0,
self.max_passenger,
shape=(self._num_nodes, ),
dtype=np.int64),
Box(0,
self.max_vehicle,
shape=(self._num_nodes, ),
dtype=np.int64)))
self._is_running = False
self._done = False
self._start_time = time.time()
self._alpha = self._config['alpha']
self._beta = self._config['beta']
self._step = 0
self._total_vehicle = None
self._travel_time = None
self._pre_action = None
self._episode = 0
self._worker_id = str(hash(time.time()))
self._save_res_every_ep = int(self._config['save_res_every_ep'])
self._vehicle_speed = self._config['veh_speed']
def _get_neighbors(self):
k = self._config['near_neighbor']
if k + 1 > len(self._nodes):
k = len(self._nodes) - 1
self._num_neighbors = k
neighbor_map = dict()
for node in self._nodes:
dist_lst = [(dest, self.graph.graph_top[node]['nei'][dest]['dist'])
for dest in self.graph.graph_top[node]['nei']]
dist_lst.sort(key=lambda x: x[1])
neighbor_map[node] = tuple(
self._nodes.index(x[0]) for x in dist_lst[:k + 1])
return neighbor_map
def _preprocess_action(self, action):
assert isinstance(action, np.ndarray)
if np.isnan(action).sum() > 0:
print(self._step)
action = self.action_space.sample()
action_mat = np.zeros((self._num_nodes, self._num_nodes))
for nd_idx, chosen_action in enumerate(action):
chosen_neighbor = chosen_action // 5
ac_idx = chosen_action % 5
nb_idx = self._neighbor_map[self._nodes[nd_idx]][chosen_neighbor]
dispatch_rate = (ac_idx + 1) / 5
action_mat[nd_idx, nb_idx] = dispatch_rate
if nb_idx != nd_idx:
action_mat[nd_idx, nd_idx] = 1 - dispatch_rate
else:
action_mat[nd_idx, nd_idx] = 1
sim_action = dict()
for nd_idx, node in enumerate(self._nodes):
sim_action[node] = action_mat[nd_idx, :]
return sim_action, action_mat
def reset(self):
if self._done:
self._episode += 1
self._done = False
# print(f'Episode: {self._episode} done!')
if self._is_running:
self.sim.finishing_touch(self._start_time)
if self._episode % self._save_res_every_ep == 0:
self.sim.save_result(RESULTS,
self._worker_id,
unique_name=False)
if self._config['plot_queue_len']:
self.sim.plot_pass_queue_len(mode='taxi',
suffix=self._worker_id)
self.sim.plot_pass_wait_time(mode='taxi',
suffix=self._worker_id)
self._is_running = False
self.curr_time = 0
self._step = 0
self.graph = Graph()
self.graph.import_graph(graph_file)
self.sim = Simulator(self.graph)
self.sim.import_arrival_rate(unit=(1, 'sec'))
self.sim.import_vehicle_attribute(file_name=vehicle_file)
self.sim.set_running_time(start_time=self._config['start_time'],
time_horizon=self._config['time_horizon'],
unit='hour')
self.sim.routing.set_routing_method('simplex')
self.sim.initialize(seed=0)
self._total_vehicle = self.sim.vehicle_attri['taxi']['total']
self._travel_time = np.zeros((self._num_nodes, self._num_nodes))
for i, node in enumerate(self.graph.graph_top):
for j, road in enumerate(self.graph.graph_top):
if i != j:
self._travel_time[
i,
j] = self.graph.graph_top[node]['node'].road[road].dist
self._travel_time /= np.linalg.norm(self._travel_time, ord=np.inf)
self._pre_action = np.zeros((self._num_neighbors, self._num_nodes))
with open(vehicle_file, 'r') as v_file:
vehicle_dist = json.load(v_file)
vehicle_dist = vehicle_dist['taxi']['distrib']
vehicle_dist = np.array([vehicle_dist[x] for x in vehicle_dist])
return np.zeros((self._num_nodes, )), vehicle_dist
def step(self, action):
self._step += 1
if not self._is_running:
self._is_running = True
sim_action, action_mat = self._preprocess_action(action)
# print(sim_action)
p_queue, v_queue = self.sim.step(action=sim_action,
step_length=self.reb_interval,
curr_time=self.curr_time)
self.curr_time += self.reb_interval
p_queue = np.array(p_queue)
v_queue = np.array(v_queue)
reward = -self._beta * (p_queue.sum() * (1 - self._alpha) * 1e-1 +
self._alpha * self._vehicle_speed * np.maximum(
(v_queue - p_queue).reshape(
(self._num_nodes, 1)) * action_mat *
self._travel_time, 0).sum())
# print(self._vehicle_speed)
# print('reward', reward)
#print('passenger', p_queue)
#print('vehicle', v_queue)
#print('action',action_mat)
#print('reward', reward)
# print(f'at node {v_queue.sum()}, on road {self._total_vehicle - v_queue.sum()}')
# print(f'action diff {np.linalg.norm(self._pre_action-action)}')
self._pre_action = action
if self.curr_time >= self._config['time_horizon'] * 3600 - 1:
self._done = True
return (p_queue, v_queue), reward, self._done, {}
class TaxiRebalance(gym.Env, ABC):
def __init__(self, config):
self._config = config
self.curr_time = 0
self.graph = Graph()
self.graph.import_graph(graph_file)
self.sim = Simulator(self.graph)
self.max_vehicle = self._config['max_vehicle']
self.reb_interval = self._config['reb_interval']
self.max_travel_t = self._config['max_travel_time']
self.max_lookback_steps = int(
np.ceil(self.max_travel_t / self.reb_interval))
self.max_passenger = self._config['max_passenger']
self.num_nodes = len(self._config['nodes_list'])
self.near_neighbor = self._config['near_neighbor']
self.action_space = Box(low=0,
high=1,
shape=((self.near_neighbor + 1) *
self.num_nodes, ))
self.observation_space = Tuple((Box(0,
self.max_passenger,
shape=(self.num_nodes, ),
dtype=np.int64),
Box(0,
self.max_vehicle,
shape=(self.num_nodes, ),
dtype=np.int64)))
self._is_running = False
self._done = False
self._start_time = time.time()
self._alpha = 0
self._step = 0
self._total_vehicle = None
self._travel_time = None
self._pre_action = None
self._episode = 0
def reset(self):
if self._done:
self._episode += 1
self._done = False
print(f'Episode: {self._episode} done!')
if self._is_running:
self.sim.finishing_touch(self._start_time)
# self.sim.save_result(RESULTS)
if self._config['plot_queue_len']:
# self.sim.plot_combo_queue_anim(mode='taxi', frames=100)
self.sim.plot_pass_queue_len(mode='taxi',
suffix=f'ep_{self._episode}')
self.sim.plot_pass_wait_time(mode='taxi',
suffix=f'ep_{self._episode}')
self._is_running = False
self.curr_time = 0
self._alpha = 0
self._step = 0
self.graph = Graph()
self.graph.import_graph(graph_file)
self.sim = Simulator(self.graph)
self.sim.import_arrival_rate(unit=(1, 'sec'))
self.sim.import_vehicle_attribute(file_name=vehicle_file)
self.sim.set_running_time(start_time=self._config['start_time'],
time_horizon=self._config['time_horizon'],
unit='hour')
self.sim.routing.set_routing_method('simplex')
self.sim.initialize(seed=0)
self._total_vehicle = self.sim.vehicle_attri['taxi']['total']
self._travel_time = np.zeros((self.num_nodes, self.num_nodes))
for i, node in enumerate(self.graph.graph_top):
for j, road in enumerate(self.graph.graph_top):
if i != j:
self._travel_time[
i,
j] = self.graph.graph_top[node]['node'].road[road].dist
self._travel_time /= np.linalg.norm(self._travel_time, ord=np.inf)
self._pre_action = np.zeros((self.near_neighbor + 1, self.num_nodes))
with open(vehicle_file, 'r') as file:
vehicle_dist = json.load(file)
vehicle_dist = vehicle_dist['taxi']['distrib']
vehicle_dist = np.array([vehicle_dist[x] for x in vehicle_dist])
return np.zeros((self.num_nodes, )), vehicle_dist
def step(self, action):
assert isinstance(action, np.ndarray)
self._step += 1
if np.isnan(action).sum() > 0:
print(self._step)
action = self.action_space.sample()
action = action.reshape((self.num_nodes, self.near_neighbor + 1))
action = action / np.sum(action, axis=1, keepdims=True)
# action = self._alpha*action + (1 - self._alpha) * np.eye(5)
# print(action)
if not self._is_running:
self._is_running = True
sim_action = dict()
for idx, node in enumerate(self._config['nodes_list']):
sim_action[node] = np.squeeze(action[idx, :] /
np.sum(action[idx, :]))
# print(sim_action)
p_queue, v_queue = self.sim.step(action=sim_action,
step_length=self.reb_interval,
curr_time=self.curr_time)
self.curr_time += self.reb_interval
p_queue = np.array(p_queue)
v_queue = np.array(v_queue)
reward = -(p_queue.sum() + 16 * np.maximum(
np.array(v_queue - p_queue, ndmin=2).T * action *
self._travel_time, 0).sum())
# print(reward)
# print('passenger', p_queue)
# print('vehicle', v_queue)
# print(f'at node {v_queue.sum()}, on road {self._total_vehicle - v_queue.sum()}')
# print(f'action diff {np.linalg.norm(self._pre_action-action)}')
self._pre_action = action
if self.curr_time >= self._config['time_horizon'] * 3600 - 1:
self._done = True
return (p_queue, v_queue), reward, self._done, {}
