def learn(self, n_steps): self.train_parameters['n_steps'] = n_steps if self.logging: self.logger = Logger(self.log_folder_details, self.train_parameters) cumulative_regret = 0 for timestep in range(n_steps): x = self.env.sample() action, uncertainty, sampled_value = self.act(x.float()) reward = self.env.hit(action) regret = self.env.regret(action) cumulative_regret += regret reward = torch.as_tensor([reward], dtype=torch.float) if self.logging: self.logger.add_scalar('Cumulative_Regret', cumulative_regret, timestep) self.logger.add_scalar('Mushrooms_Eaten', self.n_samples, timestep) if self.env.y_sample == 1: self.logger.add_scalar('Uncertainty_Good', uncertainty, timestep) self.logger.add_scalar('Sampled_Value_Good', sampled_value, timestep) else: self.logger.add_scalar('Uncertainty_Bad', uncertainty, timestep) self.logger.add_scalar('Sampled_Value_Bad', sampled_value, timestep) if action == 1: self.replay_buffer.add(x, reward) self.n_samples += 1 if timestep % self.train_freq == 0 and self.n_samples > self.start_train_step: if self.verbose: print('Timestep: {}, cumulative regret {}'.format( str(timestep), str(cumulative_regret))) for update in range(self.updates_per_train): samples = self.replay_buffer.sample( np.min([self.n_samples, self.batch_size])) self.train_step(samples) if self.logging: self.logger.save()
class UADQN: """ # Required parameters env : Environment to use. network : Choice of neural network. # Environment parameter gamma : Discount factor # Replay buffer replay_start_size : The capacity of the replay buffer at which training can begin. replay_buffer_size : Maximum buffer capacity. # QR-DQN parameters n_quantiles: Number of quantiles to estimate kappa: Smoothing parameter for the Huber loss weight_scale: scale of prior neural network weights at initialization noise_scale: scale of aleatoric noise epistemic_factor: multiplier for epistemic uncertainty used for Thompson sampling aleatoric_factor: maulitplier for aleatoric uncertainty, used to adjust mean Q values update_target_frequency: Frequency at which target network is updated minibatch_size : Minibatch size. update_frequency : Number of environment steps taken between parameter update steps. learning_rate : Learning rate used for the Adam optimizer seed : The global seed to set. None means randomly selected. adam_epsilon: Epsilon parameter for Adam optimizer biased_aleatoric: whether to use empirical std of quantiles as opposed to unbiased estimator # Logging and Saving logging : Whether to create logs when training log_folder_details : Additional information to put into the name of the log folder save_period : Periodicity with which the network weights are checkpointed notes : Notes to add to the log folder # Rendering render : Whether to render the environment during training. This slows down training. """ def __init__( self, env, network, gamma=0.99, replay_start_size=50000, replay_buffer_size=1000000, n_quantiles=50, kappa=1, weight_scale=3, noise_scale=0.1, epistemic_factor=1, aleatoric_factor=1, update_target_frequency=10000, minibatch_size=32, update_frequency=1, learning_rate=1e-3, seed=None, adam_epsilon=1e-8, biased_aleatoric=False, logging=False, log_folder_details=None, save_period=250000, notes=None, render=False, ): # Agent parameters self.env = env self.gamma = gamma self.replay_start_size = replay_start_size self.replay_buffer_size = replay_buffer_size self.n_quantiles = n_quantiles self.kappa = kappa self.weight_scale = weight_scale self.noise_scale = noise_scale self.epistemic_factor = epistemic_factor, self.aleatoric_factor = aleatoric_factor, self.update_target_frequency = update_target_frequency self.minibatch_size = minibatch_size self.update_frequency = update_frequency self.learning_rate = learning_rate self.seed = random.randint(0, 1e6) if seed is None else seed self.adam_epsilon = adam_epsilon self.biased_aleatoric = biased_aleatoric self.logging = logging self.log_folder_details = log_folder_details self.save_period = save_period self.render = render self.notes = notes # Set global seed before creating network set_global_seed(self.seed, self.env) # Initialize agent self.device = torch.device("cuda" if torch.cuda.is_available() else "cpu") self.logger = None self.loss = quantile_huber_loss self.replay_buffer = ReplayBuffer(self.replay_buffer_size) # Initialize main Q learning network n_outputs = self.env.action_space.n*self.n_quantiles self.network = network(self.env.observation_space, n_outputs).to(self.device) self.target_network = network(self.env.observation_space, n_outputs).to(self.device) self.target_network.load_state_dict(self.network.state_dict()) # Initialize anchored networks self.posterior1 = network(self.env.observation_space, n_outputs, weight_scale=weight_scale).to(self.device) self.posterior2 = network(self.env.observation_space, n_outputs, weight_scale=weight_scale).to(self.device) self.anchor1 = [p.data.clone() for p in list(self.posterior1.parameters())] self.anchor2 = [p.data.clone() for p in list(self.posterior2.parameters())] # Initialize optimizer params = list(self.network.parameters()) + list(self.posterior1.parameters()) + list(self.posterior2.parameters()) self.optimizer = optim.Adam(params, lr=self.learning_rate, eps=self.adam_epsilon) # Figure out what the scale of the prior is from empirical std of network weights with torch.no_grad(): std_list = [] for i, p in enumerate(self.posterior1.parameters()): std_list.append(torch.std(p)) self.prior_scale = torch.stack(std_list).mean().item() # Parameters to save to log file self.train_parameters = { 'Notes': notes, 'env': str(env), 'network': str(self.network), 'n_quantiles': n_quantiles, 'replay_start_size': replay_start_size, 'replay_buffer_size': replay_buffer_size, 'gamma': gamma, 'update_target_frequency': update_target_frequency, 'minibatch_size': minibatch_size, 'learning_rate': learning_rate, 'update_frequency': update_frequency, 'weight_scale': weight_scale, 'noise_scale': noise_scale, 'epistemic_factor': epistemic_factor, 'aleatoric_factor': aleatoric_factor, 'biased_aleatoric': biased_aleatoric, 'adam_epsilon': adam_epsilon, 'seed': self.seed } def learn(self, timesteps, verbose=False): self.non_greedy_actions = 0 self.timestep = 0 self.this_episode_time = 0 self.n_events = 0 # Number of times an important event is flagged in the info self.train_parameters['train_steps'] = timesteps pprint.pprint(self.train_parameters) if self.logging: self.logger = Logger(self.log_folder_details, self.train_parameters) # Initialize the state state = torch.as_tensor(self.env.reset()) score = 0 t1 = time.time() for timestep in range(timesteps): is_training_ready = timestep >= self.replay_start_size if self.render: self.env.render() # Select action action = self.act(state.to(self.device).float(), is_training_ready=is_training_ready) # Perform action in environment state_next, reward, done, info = self.env.step(action) if (info == "The agent fell!") and self.logging: # For gridworld experiments self.n_events += 1 self.logger.add_scalar('Agent falls', self.n_events, timestep) # Store transition in replay buffer action = torch.as_tensor([action], dtype=torch.long) reward = torch.as_tensor([reward], dtype=torch.float) done = torch.as_tensor([done], dtype=torch.float) state_next = torch.as_tensor(state_next) self.replay_buffer.add(state, action, reward, state_next, done) score += reward.item() self.this_episode_time += 1 if done: if verbose: print("Timestep : {}, score : {}, Time : {} s".format(timestep, score, round(time.time() - t1, 3))) if self.logging: self.logger.add_scalar('Episode_score', score, timestep) # Reinitialize the state state = torch.as_tensor(self.env.reset()) score = 0 if self.logging: non_greedy_fraction = self.non_greedy_actions/self.this_episode_time self.logger.add_scalar('Non Greedy Fraction', non_greedy_fraction, timestep) self.non_greedy_actions = 0 self.this_episode_time = 0 t1 = time.time() else: state = state_next if is_training_ready: # Update main network if timestep % self.update_frequency == 0: # Sample batch of transitions transitions = self.replay_buffer.sample(self.minibatch_size, self.device) # Train on selected batch loss, anchor_loss = self.train_step(transitions) if self.logging and timesteps < 50000: self.logger.add_scalar('Loss', loss, timestep) self.logger.add_scalar('Anchor Loss', anchor_loss, timestep) # Periodically update target Q network if timestep % self.update_target_frequency == 0: self.target_network.load_state_dict(self.network.state_dict()) if (timestep+1) % self.save_period == 0: self.save(timestep=timestep+1) self.timestep += 1 if self.logging: self.logger.save() self.save() if self.render: self.env.close() def train_step(self, transitions): """ Performs gradient descent step on a batch of transitions """ states, actions, rewards, states_next, dones = transitions # Calculate target Q with torch.no_grad(): target = self.target_network(states_next.float()) target = target.view(self.minibatch_size, self.env.action_space.n, self.n_quantiles) # Calculate max of target Q values best_action_idx = torch.mean(target, dim=2).max(1, True)[1].unsqueeze(2) q_value_target = target.gather(1, best_action_idx.repeat(1, 1, self.n_quantiles)) # Calculate TD target rewards = rewards.unsqueeze(2).repeat(1, 1, self.n_quantiles) dones = dones.unsqueeze(2).repeat(1, 1, self.n_quantiles) td_target = rewards + (1 - dones) * self.gamma * q_value_target # Calculate Q value of actions played outputs = self.network(states.float()) outputs = outputs.view(self.minibatch_size, self.env.action_space.n, self.n_quantiles) actions = actions.unsqueeze(2).repeat(1, 1, self.n_quantiles) q_value = outputs.gather(1, actions) # TD loss for main network loss = self.loss(q_value.squeeze(), td_target.squeeze(), self.device, kappa=self.kappa) # Calculate predictions of posterior networks posterior1 = self.posterior1(states.float()) posterior1 = posterior1.view(self.minibatch_size, self.env.action_space.n, self.n_quantiles) posterior1 = posterior1.gather(1, actions) posterior2 = self.posterior2(states.float()) posterior2 = posterior2.view(self.minibatch_size, self.env.action_space.n, self.n_quantiles) posterior2 = posterior2.gather(1, actions) # Regression loss for the posterior networks loss_posterior1 = self.loss(posterior1.squeeze(), td_target.squeeze(), self.device, kappa=self.kappa) loss_posterior2 = self.loss(posterior2.squeeze(), td_target.squeeze(), self.device, kappa=self.kappa) loss += loss_posterior1 + loss_posterior2 # Anchor loss for the posterior networks anchor_loss = self.calc_anchor_loss() loss += anchor_loss # Update weights self.optimizer.zero_grad() loss.backward() self.optimizer.step() return loss.item(), anchor_loss.mean().item() def calc_anchor_loss(self): """ Returns loss from anchoring """ diff1 = [] for i, p in enumerate(self.posterior1.parameters()): diff1.append(torch.sum((p - self.anchor1[i])**2)) diff1 = torch.stack(diff1).sum() diff2 = [] for i, p in enumerate(self.posterior2.parameters()): diff2.append(torch.sum((p-self.anchor2[i])**2)) diff2 = torch.stack(diff2).sum() diff = diff1 + diff2 num_data = np.min([self.timestep, self.replay_buffer_size]) anchor_loss = self.noise_scale**2*diff/(self.prior_scale**2*num_data) return anchor_loss @torch.no_grad() def get_q(self, state): net = self.network(state).view(self.env.action_space.n, self.n_quantiles) action_means = torch.mean(net, dim=1) q = action_means return q @torch.no_grad() def act(self, state, is_training_ready=True): """ Returns action to be performed using Thompson sampling with estimates provided by the two posterior networks """ net = self.network(state).view(self.env.action_space.n, self.n_quantiles) posterior1 = self.posterior1(state).view(self.env.action_space.n, self.n_quantiles) posterior2 = self.posterior2(state).view(self.env.action_space.n, self.n_quantiles) mean_action_values = torch.mean(net, dim=1) # Calculate aleatoric uncertainty if self.biased_aleatoric: uncertainties_aleatoric = torch.std(net, dim=1) else: covariance = torch.mean((posterior1-torch.mean(posterior1))*(posterior2-torch.mean(posterior2)), dim=1) uncertainties_aleatoric = torch.sqrt(F.relu(covariance)) # Aleatoric-adjusted Q values aleatoric_factor = torch.FloatTensor(self.aleatoric_factor).to(self.device) adjusted_action_values = mean_action_values - aleatoric_factor*uncertainties_aleatoric # Calculate epistemic uncertainty uncertainties_epistemic = torch.mean((posterior1-posterior2)**2, dim=1)/2 + 1e-8 epistemic_factor = torch.FloatTensor(self.epistemic_factor).to(self.device)**2 uncertainties_cov = epistemic_factor*torch.diagflat(uncertainties_epistemic) # Draw samples using Thompson sampling epistemic_distrib = torch.distributions.multivariate_normal.MultivariateNormal samples = epistemic_distrib(adjusted_action_values, covariance_matrix=uncertainties_cov).sample() action = samples.argmax().item() #print(mean_action_values, torch.sqrt(uncertainties_epistemic), torch.sqrt(uncertainties_aleatoric)) if self.logging and self.this_episode_time == 0: self.logger.add_scalar('Epistemic Uncertainty 0', torch.sqrt(uncertainties_epistemic)[0], self.timestep) self.logger.add_scalar('Epistemic Uncertainty 1', torch.sqrt(uncertainties_epistemic)[1], self.timestep) self.logger.add_scalar('Aleatoric Uncertainty 0', uncertainties_aleatoric[0], self.timestep) self.logger.add_scalar('Aleatoric Uncertainty 1', uncertainties_aleatoric[1], self.timestep) self.logger.add_scalar('Q0', mean_action_values[0], self.timestep) self.logger.add_scalar('Q1', mean_action_values[1], self.timestep) if action != mean_action_values.argmax().item(): self.non_greedy_actions += 1 return action @torch.no_grad() def predict(self, state): """ Returns action with the highest Q-value """ net = self.network(state).view(self.env.action_space.n, self.n_quantiles) mean_action_values = torch.mean(net, dim=1) action = mean_action_values.argmax().item() return action def save(self, timestep=None): """ Saves network weights """ if timestep is not None: filename = 'network_' + str(timestep) + '.pth' filename_posterior1 = 'network_posterior1_' + str(timestep) + '.pth' filename_posterior2 = 'network_posterior2_' + str(timestep) + '.pth' else: filename = 'network.pth' filename_posterior1 = 'network_posterior1.pth' filename_posterior2 = 'network_posterior2.pth' save_path = self.logger.log_folder + '/' + filename save_path_posterior1 = self.logger.log_folder + '/' + filename_posterior1 save_path_posterior2 = self.logger.log_folder + '/' + filename_posterior2 torch.save(self.network.state_dict(), save_path) torch.save(self.posterior1.state_dict(), save_path_posterior1) torch.save(self.posterior2.state_dict(), save_path_posterior2) def load(self, path): """ Loads network weights """ self.network.load_state_dict(torch.load(path + 'network.pth', map_location='cpu')) self.posterior1.load_state_dict(torch.load(path + 'network_posterior1.pth', map_location='cpu')) self.posterior2.load_state_dict(torch.load(path + 'network_posterior2.pth', map_location='cpu'))
def learn(self, timesteps, verbose=False): self.non_greedy_actions = 0 self.timestep = 0 self.this_episode_time = 0 self.n_events = 0 # Number of times an important event is flagged in the info self.train_parameters['train_steps'] = timesteps pprint.pprint(self.train_parameters) if self.logging: self.logger = Logger(self.log_folder_details, self.train_parameters) # Initialize the state state = torch.as_tensor(self.env.reset()) score = 0 t1 = time.time() for timestep in range(timesteps): is_training_ready = timestep >= self.replay_start_size if self.render: self.env.render() # Select action action = self.act(state.to(self.device).float(), is_training_ready=is_training_ready) # Perform action in environment state_next, reward, done, info = self.env.step(action) if (info == "The agent fell!") and self.logging: # For gridworld experiments self.n_events += 1 self.logger.add_scalar('Agent falls', self.n_events, timestep) # Store transition in replay buffer action = torch.as_tensor([action], dtype=torch.long) reward = torch.as_tensor([reward], dtype=torch.float) done = torch.as_tensor([done], dtype=torch.float) state_next = torch.as_tensor(state_next) self.replay_buffer.add(state, action, reward, state_next, done) score += reward.item() self.this_episode_time += 1 if done: if verbose: print("Timestep : {}, score : {}, Time : {} s".format(timestep, score, round(time.time() - t1, 3))) if self.logging: self.logger.add_scalar('Episode_score', score, timestep) # Reinitialize the state state = torch.as_tensor(self.env.reset()) score = 0 if self.logging: non_greedy_fraction = self.non_greedy_actions/self.this_episode_time self.logger.add_scalar('Non Greedy Fraction', non_greedy_fraction, timestep) self.non_greedy_actions = 0 self.this_episode_time = 0 t1 = time.time() else: state = state_next if is_training_ready: # Update main network if timestep % self.update_frequency == 0: # Sample batch of transitions transitions = self.replay_buffer.sample(self.minibatch_size, self.device) # Train on selected batch loss, anchor_loss = self.train_step(transitions) if self.logging and timesteps < 50000: self.logger.add_scalar('Loss', loss, timestep) self.logger.add_scalar('Anchor Loss', anchor_loss, timestep) # Periodically update target Q network if timestep % self.update_target_frequency == 0: self.target_network.load_state_dict(self.network.state_dict()) if (timestep+1) % self.save_period == 0: self.save(timestep=timestep+1) self.timestep += 1 if self.logging: self.logger.save() self.save() if self.render: self.env.close()
class DQN: def __init__( self, env, network, replay_start_size=50000, replay_buffer_size=1000000, gamma=0.99, update_target_frequency=10000, minibatch_size=32, learning_rate=1e-3, update_frequency=1, initial_exploration_rate=1, final_exploration_rate=0.1, final_exploration_step=1000000, adam_epsilon=1e-8, logging=False, log_folder_details=None, seed=None, render=False, loss="huber", notes=None ): self.device = torch.device("cuda" if torch.cuda.is_available() else "cpu") self.replay_start_size = replay_start_size self.replay_buffer_size = replay_buffer_size self.gamma = gamma self.update_target_frequency = update_target_frequency self.minibatch_size = minibatch_size self.learning_rate = learning_rate self.update_frequency = update_frequency self.initial_exploration_rate = initial_exploration_rate self.epsilon = self.initial_exploration_rate self.final_exploration_rate = final_exploration_rate self.final_exploration_step = final_exploration_step self.adam_epsilon = adam_epsilon self.logging = logging self.render=render self.log_folder_details = log_folder_details if callable(loss): self.loss = loss else: try: self.loss = {'huber': F.smooth_l1_loss, 'mse': F.mse_loss}[loss] except KeyError: raise ValueError("loss must be 'huber', 'mse' or a callable") self.env = env self.replay_buffer = ReplayBuffer(self.replay_buffer_size) self.seed = random.randint(0, 1e6) if seed is None else seed self.logger = None set_global_seed(self.seed, self.env) self.network = network(self.env.observation_space, self.env.action_space.n).to(self.device) self.target_network = network(self.env.observation_space, self.env.action_space.n).to(self.device) self.target_network.load_state_dict(self.network.state_dict()) self.optimizer = optim.Adam(self.network.parameters(), lr=self.learning_rate, eps=self.adam_epsilon) self.train_parameters = {'Notes':notes, 'env':env.unwrapped.spec.id, 'network':str(self.network), 'replay_start_size':replay_start_size, 'replay_buffer_size':replay_buffer_size, 'gamma':gamma, 'update_target_frequency':update_target_frequency, 'minibatch_size':minibatch_size, 'learning_rate':learning_rate, 'update_frequency':update_frequency, 'initial_exploration_rate':initial_exploration_rate, 'final_exploration_rate':final_exploration_rate, 'weight_scale':self.network.weight_scale, 'final_exploration_step':final_exploration_step, 'adam_epsilon':adam_epsilon, 'loss':loss, 'seed':self.seed} def learn(self, timesteps, verbose=False): self.train_parameters['train_steps'] = timesteps pprint.pprint(self.train_parameters) if self.logging: self.logger = Logger(self.log_folder_details,self.train_parameters) # On initialise l'état state = torch.as_tensor(self.env.reset()) score = 0 t1 = time.time() for timestep in range(timesteps): is_training_ready = timestep >= self.replay_start_size if self.render: self.env.render() # On prend une action action = self.act(state.to(self.device).float(), is_training_ready=is_training_ready) # Mise à jour d'epsilon self.update_epsilon(timestep) # On execute l'action dans l'environnement state_next, reward, done, _ = self.env.step(action) # On stock la transition dans le replay buffer action = torch.as_tensor([action], dtype=torch.long) reward = torch.as_tensor([reward], dtype=torch.float) done = torch.as_tensor([done], dtype=torch.float) state_next = torch.as_tensor(state_next) self.replay_buffer.add(state, action, reward, state_next, done) score += reward.item() if done: # On réinitialise l'état if verbose: print("Timestep : {}, score : {}, Time : {} s".format(timestep, score, round(time.time() - t1, 3))) if self.logging: self.logger.add_scalar('Episode_score', score, timestep) state = torch.as_tensor(self.env.reset()) score = 0 if self.logging: self.logger.add_scalar('Q_at_start', self.get_max_q(state.to(self.device).float()), timestep) t1 = time.time() else: state = state_next if is_training_ready: # Update du réseau principal if timestep % self.update_frequency == 0: # On sample un minibatche de transitions transitions = self.replay_buffer.sample(self.minibatch_size, self.device) # On s'entraine sur les transitions selectionnées loss = self.train_step(transitions) if self.logging and timesteps < 100000: self.logger.add_scalar('Loss', loss, timestep) # Si c'est le moment, on update le target Q network on copiant les poids du network if timestep % self.update_target_frequency == 0: self.target_network.load_state_dict(self.network.state_dict()) if (timestep+1) % 250000 == 0: self.save(timestep=timestep+1) if self.logging: self.logger.save() self.save() if self.render: self.env.close() def train_step(self, transitions): # huber = torch.nn.SmoothL1Loss() states, actions, rewards, states_next, dones = transitions # Calcul de la Q value via le target network (celle qui maximise) with torch.no_grad(): q_value_target = self.target_network(states_next.float()).max(1, True)[0] # Calcul de la TD Target td_target = rewards + (1 - dones) * self.gamma * q_value_target # Calcul de la Q value en fonction de l'action jouée q_value = self.network(states.float()).gather(1, actions) loss = self.loss(q_value, td_target, reduction='mean') # Update des poids self.optimizer.zero_grad() loss.backward() self.optimizer.step() return loss.item() @torch.no_grad() def get_max_q(self,state): return self.network(state).max().item() def act(self, state, is_training_ready=True): if is_training_ready and random.uniform(0, 1) >= self.epsilon: # Action qui maximise la Q function action = self.predict(state) else: # Action aléatoire ( sur l'interval [a, b[ ) action = np.random.randint(0, self.env.action_space.n) return action def update_epsilon(self, timestep): eps = self.initial_exploration_rate - (self.initial_exploration_rate - self.final_exploration_rate) * ( timestep / self.final_exploration_step ) self.epsilon = max(eps, self.final_exploration_rate) @torch.no_grad() def predict(self, state): action = self.network(state).argmax().item() return action def save(self,timestep=None): if not self.logging: raise NotImplementedError('Cannot save without log folder.') if timestep is not None: filename = 'network_' + str(timestep) + '.pth' else: filename = 'network.pth' save_path = self.logger.log_folder + '/' + filename torch.save(self.network.state_dict(), save_path) def load(self,path): self.network.load_state_dict(torch.load(path,map_location='cpu'))
def learn(self, timesteps, verbose=False): self.train_parameters['train_steps'] = timesteps pprint.pprint(self.train_parameters) if self.logging: self.logger = Logger(self.log_folder_details,self.train_parameters) # On initialise l'état state = torch.as_tensor(self.env.reset()) score = 0 t1 = time.time() for timestep in range(timesteps): is_training_ready = timestep >= self.replay_start_size if self.render: self.env.render() # On prend une action action = self.act(state.to(self.device).float(), is_training_ready=is_training_ready) # Mise à jour d'epsilon self.update_epsilon(timestep) # On execute l'action dans l'environnement state_next, reward, done, _ = self.env.step(action) # On stock la transition dans le replay buffer action = torch.as_tensor([action], dtype=torch.long) reward = torch.as_tensor([reward], dtype=torch.float) done = torch.as_tensor([done], dtype=torch.float) state_next = torch.as_tensor(state_next) self.replay_buffer.add(state, action, reward, state_next, done) score += reward.item() if done: # On réinitialise l'état if verbose: print("Timestep : {}, score : {}, Time : {} s".format(timestep, score, round(time.time() - t1, 3))) if self.logging: self.logger.add_scalar('Episode_score', score, timestep) state = torch.as_tensor(self.env.reset()) score = 0 if self.logging: self.logger.add_scalar('Q_at_start', self.get_max_q(state.to(self.device).float()), timestep) t1 = time.time() else: state = state_next if is_training_ready: # Update du réseau principal if timestep % self.update_frequency == 0: # On sample un minibatche de transitions transitions = self.replay_buffer.sample(self.minibatch_size, self.device) # On s'entraine sur les transitions selectionnées loss = self.train_step(transitions) if self.logging and timesteps < 100000: self.logger.add_scalar('Loss', loss, timestep) # Si c'est le moment, on update le target Q network on copiant les poids du network if timestep % self.update_target_frequency == 0: self.target_network.load_state_dict(self.network.state_dict()) if (timestep+1) % 250000 == 0: self.save(timestep=timestep+1) if self.logging: self.logger.save() self.save() if self.render: self.env.close()
class IDE(): def __init__(self, env, network, n_quantiles=20, kappa=1, lamda=0.1, replay_start_size=50000, replay_buffer_size=1000000, gamma=0.99, update_target_frequency=10000, epsilon_12=0.00001, minibatch_size=32, learning_rate=1e-4, update_frequency=1, prior=0.01, adam_epsilon=1e-8, logging=False, log_folder_details=None, seed=None, notes=None): self.device = torch.device( "cuda" if torch.cuda.is_available() else "cpu") self.replay_start_size = replay_start_size self.replay_buffer_size = replay_buffer_size self.gamma = gamma self.epsilon_12 = epsilon_12 self.lamda = lamda self.update_target_frequency = update_target_frequency self.minibatch_size = minibatch_size self.learning_rate = learning_rate self.update_frequency = update_frequency self.adam_epsilon = adam_epsilon self.logging = logging self.logger = None self.timestep = 0 self.log_folder_details = log_folder_details self.env = env self.replay_buffer = ReplayBuffer(self.replay_buffer_size) self.seed = random.randint(0, 1e6) if seed is None else seed set_global_seed(self.seed, self.env) self.n_quantiles = n_quantiles self.network = network(self.env.observation_space, self.env.action_space.n * self.n_quantiles, self.env.action_space.n * self.n_quantiles).to( self.device) self.target_network = network( self.env.observation_space, self.env.action_space.n * self.n_quantiles, self.env.action_space.n * self.n_quantiles).to(self.device) self.target_network.load_state_dict(self.network.state_dict()) self.optimizer = optim.Adam(self.network.parameters(), lr=self.learning_rate, eps=self.adam_epsilon) self.anchor1 = [ p.data.clone() for p in list(self.network.output_1.parameters()) ] self.anchor2 = [ p.data.clone() for p in list(self.network.output_2.parameters()) ] self.loss = quantile_huber_loss self.kappa = kappa self.prior = prior self.train_parameters = { 'Notes': notes, 'env': env.unwrapped.spec.id, 'network': str(self.network), 'replay_start_size': replay_start_size, 'replay_buffer_size': replay_buffer_size, 'gamma': gamma, 'lambda': lamda, 'epsilon_1and2': epsilon_12, 'update_target_frequency': update_target_frequency, 'minibatch_size': minibatch_size, 'learning_rate': learning_rate, 'update_frequency': update_frequency, 'kappa': kappa, 'weight_scale': self.network.weight_scale, 'n_quantiles': n_quantiles, 'prior': prior, 'adam_epsilon': adam_epsilon, 'seed': self.seed } self.n_greedy_actions = 0 self.timestep = 0 def learn(self, timesteps, verbose=False): self.train_parameters['train_steps'] = timesteps pprint.pprint(self.train_parameters) if self.logging: self.logger = Logger(self.log_folder_details, self.train_parameters) # On initialise l'état state = torch.as_tensor(self.env.reset()) this_episode_time = 0 score = 0 t1 = time.time() for timestep in range(timesteps): self.timestep = timestep is_training_ready = timestep >= self.replay_start_size # On prend une action action = self.act(state.to(self.device).float(), directed_exploration=True) # On execute l'action dans l'environnement state_next, reward, done, _ = self.env.step(action) # On stock la transition dans le replay buffer action = torch.as_tensor([action], dtype=torch.long) reward = torch.as_tensor([reward], dtype=torch.float) done = torch.as_tensor([done], dtype=torch.float) state_next = torch.as_tensor(state_next) self.replay_buffer.add(state, action, reward, state_next, done) score += reward.item() this_episode_time += 1 if done: # On réinitialise l'état if verbose: print("Timestep : {}, score : {}, Time : {} s".format( timestep, score, round(time.time() - t1, 3))) if self.logging: self.logger.add_scalar('Episode_score', score, timestep) self.logger.add_scalar( 'Non_greedy_fraction', 1 - self.n_greedy_actions / this_episode_time, timestep) state = torch.as_tensor(self.env.reset()) score = 0 if self.logging: self.logger.add_scalar( 'Q_at_start', self.get_max_q(state.to(self.device).float()), timestep) t1 = time.time() self.n_greedy_actions = 0 this_episode_time = 0 else: state = state_next if is_training_ready: # Update du réseau principal if timestep % self.update_frequency == 0: # On sample un minibatche de transitions transitions = self.replay_buffer.sample( self.minibatch_size, self.device) # On s'entraine sur les transitions selectionnées loss = self.train_step(transitions) if self.logging and timesteps < 1000000: self.logger.add_scalar('Loss', loss, timestep) # Si c'est le moment, on update le target Q network on copiant les poids du network if timestep % self.update_target_frequency == 0: self.target_network.load_state_dict( self.network.state_dict()) if (timestep + 1) % 250000 == 0: self.save(timestep=timestep + 1) if self.logging: self.logger.save() self.save() def train_step(self, transitions): # huber = torch.nn.SmoothL1Loss() states, actions, rewards, states_next, dones = transitions # Calcul de la Q value via le target network (celle qui maximise) with torch.no_grad(): target1, target2 = self.target_network(states_next.float()) target1 = target1.view(self.minibatch_size, self.env.action_space.n, self.n_quantiles) target2 = target2.view(self.minibatch_size, self.env.action_space.n, self.n_quantiles) #Used to determine what action the current policy would have chosen in the next state target1_onpolicy, target2_onpolicy, = self.network( states_next.float()) target1_onpolicy = target1_onpolicy.view(self.minibatch_size, self.env.action_space.n, self.n_quantiles) target2_onpolicy = target2_onpolicy.view(self.minibatch_size, self.env.action_space.n, self.n_quantiles) best_action_idx = torch.mean((target1 + target2) / 2, dim=2).max(1, True)[1].unsqueeze(2) target1_gathered = target1.gather( 1, best_action_idx.repeat(1, 1, self.n_quantiles)) target2_gathered = target2.gather( 1, best_action_idx.repeat(1, 1, self.n_quantiles)) #uncertainty_target = uncertainty_output.gather(1,best_action_idx.squeeze(2)) q_value_target = 0.5*target1_gathered\ + 0.5*target2_gathered # Calcul de la TD Target td_target = rewards.unsqueeze(2).repeat(1,1,self.n_quantiles) \ + (1 - dones.unsqueeze(2).repeat(1,1,self.n_quantiles)) * self.gamma * q_value_target # Calcul de la Q value en fonction de l'action jouée out1, out2 = self.network(states.float()) out1 = out1.view(self.minibatch_size, self.env.action_space.n, self.n_quantiles) out2 = out2.view(self.minibatch_size, self.env.action_space.n, self.n_quantiles) q_value1 = out1.gather( 1, actions.unsqueeze(2).repeat(1, 1, self.n_quantiles)) q_value2 = out2.gather( 1, actions.unsqueeze(2).repeat(1, 1, self.n_quantiles)) #Calculate quantile losses loss1 = self.loss(q_value1.squeeze(), td_target.squeeze(), self.device, kappa=self.kappa) loss2 = self.loss(q_value2.squeeze(), td_target.squeeze(), self.device, kappa=self.kappa) quantile_loss = loss1 + loss2 diff1 = [] for i, p in enumerate(self.network.output_1.parameters()): diff1.append(torch.sum((p - self.anchor1[i])**2)) diff2 = [] for i, p in enumerate(self.network.output_2.parameters()): diff2.append(torch.sum((p - self.anchor2[i])**2)) diff1 = torch.stack(diff1).sum() diff2 = torch.stack(diff2).sum() anchor_loss = self.prior * (diff1 + diff2) loss = quantile_loss + anchor_loss #print(anchor_loss/loss) # Update des poids self.optimizer.zero_grad() loss.backward() self.optimizer.step() return loss.item() def act(self, state, directed_exploration=False): action = self.predict(state, directed_exploration=directed_exploration) return action @torch.no_grad() def predict(self, state, directed_exploration=False): if not directed_exploration: #Choose greedily net1, net2 = self.network(state) net1 = net1.view(self.env.action_space.n, self.n_quantiles) net2 = net2.view(self.env.action_space.n, self.n_quantiles) action_means = torch.mean((net1 + net2) / 2, dim=1) action = action_means.argmax().item() else: net1, net2 = self.network(state) net1 = net1.view(self.env.action_space.n, self.n_quantiles) net2 = net2.view(self.env.action_space.n, self.n_quantiles) target_net1, target_net2 = self.target_network(state) target_net1 = target_net1.view(self.env.action_space.n, self.n_quantiles) target_net2 = target_net2.view(self.env.action_space.n, self.n_quantiles) uncertainties_epistemic = torch.mean( (target_net1 - target_net2)**2, dim=1) / 2 #Calculate regret action_means = torch.mean((net1 + net2) / 2, dim=1) delta_regret = torch.max( action_means + self.lamda * torch.sqrt(uncertainties_epistemic) ) - (action_means - torch.sqrt(self.lamda * uncertainties_epistemic)) #Calculate and normalize aleatoric uncertainties (variance of quantile - local epistemic) aleatoric = torch.abs( (torch.var(net1, dim=1) + torch.var(net2, dim=1)) / 2 - uncertainties_epistemic) uncertainties_aleatoric = aleatoric / (self.epsilon_12 + torch.mean(aleatoric)) #Use learned uncertainty and aleatoric uncertainty to calculate regret to information ratio and select actions information = torch.log(1 + uncertainties_epistemic / uncertainties_aleatoric) + self.epsilon_12 regret_info_ratio = delta_regret**2 / information action = regret_info_ratio.argmin().item() if action == action_means.argmax().item(): self.n_greedy_actions += 1 if self.logging: self.logger.add_scalar('Epistemic_Uncertainty', uncertainties_epistemic[action].sqrt(), self.timestep) self.logger.add_scalar('Aleatoric_Uncertainty', uncertainties_aleatoric[action].sqrt(), self.timestep) return action @torch.no_grad() def get_max_q(self, state): net1, net2 = self.network(state) net1 = net1.view(self.env.action_space.n, self.n_quantiles) net2 = net2.view(self.env.action_space.n, self.n_quantiles) action_means = torch.mean((net1 + net2) / 2, dim=1) max_q = action_means.max().item() return max_q def save(self, timestep=None): if not self.logging: raise NotImplementedError('Cannot save without log folder.') if timestep is not None: filename = 'network_' + str(timestep) + '.pth' else: filename = 'network.pth' save_path = self.logger.log_folder + '/' + filename torch.save(self.network.state_dict(), save_path) def load(self, path): self.network.load_state_dict(torch.load(path, map_location='cpu')) self.target_network.load_state_dict( torch.load(path, map_location='cpu'))
def learn(self, timesteps, verbose=False): self.train_parameters['train_steps'] = timesteps pprint.pprint(self.train_parameters) if self.logging: self.logger = Logger(self.log_folder_details, self.train_parameters) # Initialize state state = torch.as_tensor(self.env.reset()) score = 0 t1 = time.time() for timestep in range(timesteps): is_training_ready = timestep >= self.replay_start_size # Pick action action = self.act(state.to(self.device).float(), is_training_ready=is_training_ready) # Update epsilon self.update_epsilon(timestep) # Perform action in environment state_next, reward, done, _ = self.env.step(action) # Store transition in replay buffer action = torch.as_tensor([action], dtype=torch.long) reward = torch.as_tensor([reward], dtype=torch.float) done = torch.as_tensor([done], dtype=torch.float) state_next = torch.as_tensor(state_next) self.replay_buffer.add(state, action, reward, state_next, done) score += reward.item() if done: # Reinitialize the state if verbose: print("Timestep : {}, score : {}, Time : {} s".format( timestep, score, round(time.time() - t1, 3))) if self.logging: self.logger.add_scalar('Episode_score', score, timestep) state = torch.as_tensor(self.env.reset()) score = 0 if self.logging: self.logger.add_scalar( 'Q_at_start', self.get_max_q(state.to(self.device).float()), timestep) t1 = time.time() else: state = state_next if is_training_ready: # Update network if timestep % self.update_frequency == 0: # Sample batch of transitions transitions = self.replay_buffer.sample( self.minibatch_size, self.device) # Train on selected batch loss = self.train_step(transitions) if self.logging and timesteps < 100000: self.logger.add_scalar('Loss', loss, timestep) # Update target network if timestep % self.update_target_frequency == 0: self.target_network.load_state_dict( self.network.state_dict()) if (timestep + 1) % 250000 == 0: self.save(timestep=timestep + 1) if self.logging: self.logger.save() self.save()
class BOOTSTRAPPED: """ # Required parameters env : Environment to use. network : Choice of neural network. # Environment parameter gamma : Discount factor # Replay buffer replay_start_size : The capacity of the replay buffer at which training can begin. replay_buffer_size : Maximum buffer capacity. # Bootstrapped DQN parameters n_heads: Number of bootstrap heads update_target_frequency: Frequency at which target network is updated minibatch_size : Minibatch size. update_frequency : Number of environment steps taken between parameter update steps. learning_rate : Learning rate used for the Adam optimizer loss : Type of loss function to use. Can be "huber" or "mse" seed : The global seed to set. None means randomly selected. adam_epsilon: Epsilon parameter for Adam optimizer # Exploration initial_exploration_rate : Inital exploration rate. final_exploration_rate : Final exploration rate. final_exploration_step : Timestep at which the final exploration rate is reached. # Logging and Saving logging : Whether to create logs when training log_folder_details : Additional information to put into the name of the log folder save_period : Periodicity with which the network weights are checkpointed notes : Notes to add to the log folder # Rendering render : Whether to render the environment during training. This slows down training. """ def __init__( self, env, network, gamma=0.99, replay_start_size=50000, replay_buffer_size=1000000, n_heads=10, update_target_frequency=10000, minibatch_size=32, update_frequency=1, learning_rate=1e-3, loss="huber", seed=None, adam_epsilon=1e-8, initial_exploration_rate=1, final_exploration_rate=0.1, final_exploration_step=1000000, logging=False, log_folder_details=None, save_period=250000, notes=None, render=False, ): # Agent parameters self.env = env self.gamma = gamma self.replay_start_size = replay_start_size self.replay_buffer_size = replay_buffer_size self.n_heads = n_heads self.update_target_frequency = update_target_frequency self.minibatch_size = minibatch_size self.update_frequency = update_frequency self.learning_rate = learning_rate if callable(loss): self.loss = loss else: try: self.loss = {'huber': F.smooth_l1_loss, 'mse': F.mse_loss}[loss] except KeyError: raise ValueError("loss must be 'huber', 'mse' or a callable") self.seed = random.randint(0, 1e6) if seed is None else seed self.adam_epsilon = adam_epsilon self.initial_exploration_rate = initial_exploration_rate self.final_exploration_rate = final_exploration_rate self.final_exploration_step = final_exploration_step self.logging = logging self.log_folder_details = log_folder_details self.save_period = save_period self.render = render self.notes = notes # Set global seed before creating network set_global_seed(self.seed, self.env) # Initialize agent self.device = torch.device("cuda" if torch.cuda.is_available() else "cpu") self.replay_buffer = ReplayBuffer(self.replay_buffer_size) self.logger = None self.epsilon = self.initial_exploration_rate self.network = network(self.env.observation_space, self.env.action_space.n, self.n_heads).to(self.device) self.target_network = network(self.env.observation_space, self.env.action_space.n, self.n_heads).to(self.device) self.target_network.load_state_dict(self.network.state_dict()) self.optimizer = optim.Adam(self.network.parameters(), lr=self.learning_rate, eps=self.adam_epsilon) self.current_head = None self.timestep = 0 # Parameters to save to log file self.train_parameters = { 'Notes': notes, 'env': str(env), 'network': str(self.network), 'replay_start_size': replay_start_size, 'replay_buffer_size': replay_buffer_size, 'gamma': gamma, 'n_heads': n_heads, 'update_target_frequency': update_target_frequency, 'minibatch_size': minibatch_size, 'learning_rate': learning_rate, 'update_frequency': update_frequency, 'initial_exploration_rate': initial_exploration_rate, 'final_exploration_rate': final_exploration_rate, 'weight_scale': self.network.weight_scale, 'final_exploration_step': final_exploration_step, 'adam_epsilon': adam_epsilon, 'loss': loss, 'seed': self.seed } def learn(self, timesteps, verbose=False): self.current_head = np.random.randint(self.n_heads) self.train_parameters['train_steps'] = timesteps pprint.pprint(self.train_parameters) if self.logging: self.logger = Logger(self.log_folder_details, self.train_parameters) # Initialize the state state = torch.as_tensor(self.env.reset()) score = 0 t1 = time.time() for timestep in range(timesteps): self.timestep = timestep is_training_ready = timestep >= self.replay_start_size if self.render: self.env.render() # Select action action = self.act(state.to(self.device).float(), is_training_ready=is_training_ready) # Update epsilon self.update_epsilon(timestep) # Perform action in environment state_next, reward, done, _ = self.env.step(action) # Store transition in replay buffer action = torch.as_tensor([action], dtype=torch.long) reward = torch.as_tensor([reward], dtype=torch.float) done = torch.as_tensor([done], dtype=torch.float) state_next = torch.as_tensor(state_next) self.replay_buffer.add(state, action, reward, state_next, done) score += reward.item() if done: self.current_head = np.random.randint(self.n_heads) if self.logging: self.logger.add_scalar('Acting_Head', self.current_head, self.timestep) # Reinitialize the state if verbose: print("Timestep : {}, score : {}, Time : {} s".format(timestep, score, round(time.time() - t1, 3))) if self.logging: self.logger.add_scalar('Episode_score', score, timestep) state = torch.as_tensor(self.env.reset()) score = 0 if self.logging: self.logger.add_scalar('Q_at_start', self.get_max_q(state.to(self.device).float()), timestep) t1 = time.time() else: state = state_next if is_training_ready: # Update main network if timestep % self.update_frequency == 0: # Sample batch of transitions transitions = self.replay_buffer.sample(self.minibatch_size, self.device) # Train on selected batch loss = self.train_step(transitions) # Periodically update target Q network if timestep % self.update_target_frequency == 0: self.target_network.load_state_dict(self.network.state_dict()) if (timestep+1) % self.save_period == 0: self.save(timestep=timestep+1) if self.logging: self.logger.save() self.save() if self.render: self.env.close() def train_step(self, transitions): """ Performs gradient descent step on a batch of transitions """ states, actions, rewards, states_next, dones = transitions # Calculate target Q with torch.no_grad(): # Target shape : batch x n_heads x n_actions targets = self.target_network(states_next.float()) q_value_target = targets.max(2, True)[0] # Calculate TD target td_target = rewards.unsqueeze(1) + (1 - dones.unsqueeze(1)) * self.gamma * q_value_target # Calculate Q value of actions played output = self.network(states.float()) q_value = output.gather(2, actions.unsqueeze(1).repeat(1,self.n_heads,1)) loss = self.loss(q_value, td_target, reduction='mean') # Update weights self.optimizer.zero_grad() loss.backward() self.optimizer.step() return loss.item() @torch.no_grad() def get_max_q(self,state): """ Returns largest Q value at the state """ return self.network(state).max().item() def act(self, state, is_training_ready=True): """ Returns action to be performed with an epsilon-greedy policy """ if is_training_ready and random.uniform(0, 1) >= self.epsilon: # Action that maximizes Q action = self.predict(state) else: # Random action action = np.random.randint(0, self.env.action_space.n) return action def update_epsilon(self, timestep): """ Update the exploration parameter """ eps = self.initial_exploration_rate - (self.initial_exploration_rate - self.final_exploration_rate) * ( timestep / self.final_exploration_step ) self.epsilon = max(eps, self.final_exploration_rate) @torch.no_grad() def predict(self, state, train=True): """ Returns action with the highest Q-value """ if train: out = self.network(state).squeeze() action = out[self.current_head, :].argmax().item() """ if self.logging: self.logger.add_scalar('Uncertainty', out.max(1,True)[0].std(), self.timestep) """ else: out = self.network(state).squeeze() # Shape B x n_heads x n_actions # The heads vote on the best action actions, count = torch.unique(out.argmax(1), return_counts=True) action = actions[count.argmax().item()].item() return action def save(self, timestep=None): """ Saves network weights """ if not self.logging: raise NotImplementedError('Cannot save without log folder.') if timestep is not None: filename = 'network_' + str(timestep) + '.pth' else: filename = 'network.pth' save_path = self.logger.log_folder + '/' + filename torch.save(self.network.state_dict(), save_path) def load(self, path): """ Loads network weights """ self.network.load_state_dict(torch.load(path, map_location='cpu'))
class DropoutAgent(): def __init__(self, env, network, dropout=0.1, std_prior=0.01, logging=True, train_freq=10, updates_per_train=100, weight_decay=1e-5, batch_size=32, start_train_step=10, log_folder_details=None, learning_rate=1e-3, verbose=False): self.env = env self.network = network(env.n_features, std_prior, dropout=dropout) self.logging = logging self.replay_buffer = ReplayBuffer() self.batch_size = batch_size self.log_folder_details = log_folder_details self.train_freq = train_freq self.start_train_step = start_train_step self.updates_per_train = updates_per_train self.verbose = verbose self.dropout = dropout self.weight_decay = weight_decay self.n_samples = 0 self.optimizer = optim.Adam(self.network.parameters(), lr=learning_rate, eps=1e-8, weight_decay=self.weight_decay) self.train_parameters = { 'dropout': dropout, 'weight_decay': weight_decay, 'std_prior': std_prior, 'train_freq': train_freq, 'updates_per_train': updates_per_train, 'batch_size': batch_size, 'start_train_step': start_train_step, 'learning_rate': learning_rate } def learn(self, n_steps): self.train_parameters['n_steps'] = n_steps if self.logging: self.logger = Logger(self.log_folder_details, self.train_parameters) cumulative_regret = 0 for timestep in range(n_steps): self.dropout = 1000 * self.dropout / (self.n_samples + 1000) x = self.env.sample() action = self.act(x.float()) reward = self.env.hit(action) regret = self.env.regret(action) cumulative_regret += regret action = torch.as_tensor([action], dtype=torch.long) reward = torch.as_tensor([reward], dtype=torch.float) if action == 1: self.n_samples += 1 self.replay_buffer.add(x, reward) if self.logging: self.logger.add_scalar('Cumulative_Regret', cumulative_regret, timestep) self.logger.add_scalar('Mushrooms_Eaten', self.n_samples, timestep) if timestep % self.train_freq == 0 and self.n_samples > self.start_train_step: if self.verbose: print('Timestep: {}, cumulative regret {}'.format( str(timestep), str(cumulative_regret))) for update in range(self.updates_per_train): samples = self.replay_buffer.sample( np.min([self.n_samples, self.batch_size])) self.train_step(samples) if self.logging: self.logger.save() def train_step(self, samples): states, rewards = samples # Calcul de la TD Target target = rewards # Calcul de la Q value en fonction de l'action jouée q_value = self.network(states.float(), self.dropout) loss_function = torch.nn.MSELoss() loss = loss_function(q_value.squeeze(), target.squeeze()) # Update des poids self.optimizer.zero_grad() loss.backward() self.optimizer.step() def act(self, x): action = self.predict(x) return action @torch.no_grad() def predict(self, x): estimated_value = self.network(x, self.dropout) if estimated_value > 0: action = 1 else: action = 0 return action
def learn(self, timesteps, verbose=False): self.train_parameters['train_steps'] = timesteps pprint.pprint(self.train_parameters) if self.logging: self.logger = Logger(self.log_folder_details,self.train_parameters) state = torch.as_tensor(self.env.reset()) this_episode_time = 0 score = 0 t1 = time.time() for timestep in range(timesteps): is_training_ready = timestep >= self.replay_start_size action = self.act(state.to(self.device).float(), directed_exploration=True) state_next, reward, done, _ = self.env.step(action) action = torch.as_tensor([action], dtype=torch.long) reward = torch.as_tensor([reward], dtype=torch.float) done = torch.as_tensor([done], dtype=torch.float) state_next = torch.as_tensor(state_next) self.replay_buffer.add(state, action, reward, state_next, done) score += reward.item() this_episode_time += 1 if done: if verbose: print("Timestep : {}, score : {}, Time : {} s".format(timestep, score, round(time.time() - t1, 3))) if self.logging: self.logger.add_scalar('Episode_score', score, timestep) self.logger.add_scalar('Non_greedy_fraction', 1-self.n_greedy_actions/this_episode_time, timestep) state = torch.as_tensor(self.env.reset()) score = 0 if self.logging: self.logger.add_scalar('Q_at_start', self.get_max_q(state.to(self.device).float()), timestep) t1 = time.time() self.n_greedy_actions = 0 this_episode_time = 0 else: state = state_next if is_training_ready: if timestep % self.update_frequency == 0: transitions = self.replay_buffer.sample(self.minibatch_size, self.device) loss = self.train_step(transitions) if self.logging and timesteps < 1000000: self.logger.add_scalar('Loss', loss, timestep) if timestep % self.update_target_frequency == 0: self.target_network.load_state_dict(self.network.state_dict()) if (timestep+1) % 250000 == 0: self.save(timestep=timestep+1) if self.logging: self.logger.save() self.save()
class EGreedyAgent(): def __init__(self, env, network, epsilon=0.05, n_quantiles=20, mean_prior=0, std_prior=0.01, logging=True, train_freq=10, updates_per_train=100, batch_size=32, start_train_step=10, log_folder_details=None, learning_rate=1e-3, verbose=False): self.env = env self.network = network(env.n_features, n_quantiles, mean_prior, std_prior) self.logging = logging self.replay_buffer = ReplayBuffer() self.batch_size = batch_size self.log_folder_details = log_folder_details self.epsilon = epsilon self.optimizer = optim.Adam(self.network.parameters(), lr=learning_rate, eps=1e-8) self.n_quantiles = n_quantiles self.train_freq = train_freq self.start_train_step = start_train_step self.updates_per_train = updates_per_train self.verbose = verbose self.n_samples = 0 self.train_parameters = { 'epsilon': epsilon, 'n_quantiles': n_quantiles, 'mean_prior': mean_prior, 'std_prior': std_prior, 'train_freq': train_freq, 'updates_per_train': updates_per_train, 'batch_size': batch_size, 'start_train_step': start_train_step, 'learning_rate': learning_rate } def learn(self, n_steps): self.train_parameters['n_steps'] = n_steps if self.logging: self.logger = Logger(self.log_folder_details, self.train_parameters) cumulative_regret = 0 for timestep in range(n_steps): x = self.env.sample() action = self.act(x.float()) reward = self.env.hit(action) regret = self.env.regret(action) cumulative_regret += regret action = torch.as_tensor([action], dtype=torch.long) reward = torch.as_tensor([reward], dtype=torch.float) if action == 1: self.n_samples += 1 self.replay_buffer.add(x, reward) if self.logging: self.logger.add_scalar('Cumulative_Regret', cumulative_regret, timestep) self.logger.add_scalar('Mushrooms_Eaten', self.n_samples, timestep) if timestep % self.train_freq == 0 and self.n_samples > self.start_train_step: if self.verbose: print('Timestep: {}, cumulative regret {}'.format( str(timestep), str(cumulative_regret))) for update in range(self.updates_per_train): samples = self.replay_buffer.sample( np.min([self.n_samples, self.batch_size])) self.train_step(samples) if self.logging: self.logger.save() def train_step(self, samples): states, rewards = samples target = rewards.repeat(1, self.n_quantiles) q_value = self.network(states.float()).view( np.min([self.n_samples, self.batch_size]), self.n_quantiles) loss = quantile_huber_loss(q_value.squeeze(), target.squeeze()) self.optimizer.zero_grad() loss.backward() self.optimizer.step() def act(self, x): if np.random.uniform() >= self.epsilon: action = self.predict(x) else: action = np.random.randint(0, 2) return action @torch.no_grad() def predict(self, x): estimated_value = torch.mean(self.network(x)) if estimated_value > 0: action = 1 else: action = 0 return action
class EQRDQN(): def __init__(self, env, network, n_quantiles=50, kappa=1, replay_start_size=50000, replay_buffer_size=1000000, gamma=0.99, update_target_frequency=10000, minibatch_size=32, learning_rate=1e-4, update_frequency=1, prior=0.01, adam_epsilon=1e-8, logging=False, log_folder_details=None, seed=None, notes=None): self.device = torch.device( "cuda" if torch.cuda.is_available() else "cpu") self.replay_start_size = replay_start_size self.replay_buffer_size = replay_buffer_size self.gamma = gamma self.update_target_frequency = update_target_frequency self.minibatch_size = minibatch_size self.learning_rate = learning_rate self.update_frequency = update_frequency self.adam_epsilon = adam_epsilon self.logging = logging self.logger = [] self.timestep = 0 self.log_folder_details = log_folder_details self.env = env self.replay_buffer = ReplayBuffer(self.replay_buffer_size) self.seed = random.randint(0, 1e6) if seed is None else seed self.logger = None set_global_seed(self.seed, self.env) self.n_quantiles = n_quantiles self.network = network(self.env.observation_space, self.env.action_space.n * self.n_quantiles, self.env.action_space.n * self.n_quantiles).to( self.device) self.target_network = network( self.env.observation_space, self.env.action_space.n * self.n_quantiles, self.env.action_space.n * self.n_quantiles).to(self.device) self.target_network.load_state_dict(self.network.state_dict()) self.optimizer = optim.Adam(self.network.parameters(), lr=self.learning_rate, eps=self.adam_epsilon) self.anchor1 = [ p.data.clone() for p in list(self.network.output_1.parameters()) ] self.anchor2 = [ p.data.clone() for p in list(self.network.output_2.parameters()) ] self.loss = quantile_huber_loss self.kappa = kappa self.prior = prior self.train_parameters = { 'Notes': notes, 'env': env.unwrapped.spec.id, 'network': str(self.network), 'replay_start_size': replay_start_size, 'replay_buffer_size': replay_buffer_size, 'gamma': gamma, 'update_target_frequency': update_target_frequency, 'minibatch_size': minibatch_size, 'learning_rate': learning_rate, 'update_frequency': update_frequency, 'kappa': kappa, 'n_quantiles': n_quantiles, 'weight_scale': self.network.weight_scale, 'prior': prior, 'adam_epsilon': adam_epsilon, 'seed': self.seed } self.n_greedy_actions = 0 def learn(self, timesteps, verbose=False): self.train_parameters['train_steps'] = timesteps pprint.pprint(self.train_parameters) if self.logging: self.logger = Logger(self.log_folder_details, self.train_parameters) # Initialize the state state = torch.as_tensor(self.env.reset()) this_episode_time = 0 score = 0 t1 = time.time() for timestep in range(timesteps): is_training_ready = timestep >= self.replay_start_size # Select action action = self.act(state.to(self.device).float(), thompson_sampling=True) # Perform action in environments state_next, reward, done, _ = self.env.step(action) # Store transition in replay buffer action = torch.as_tensor([action], dtype=torch.long) reward = torch.as_tensor([reward], dtype=torch.float) done = torch.as_tensor([done], dtype=torch.float) state_next = torch.as_tensor(state_next) self.replay_buffer.add(state, action, reward, state_next, done) score += reward.item() this_episode_time += 1 if done: if verbose: print("Timestep : {}, score : {}, Time : {} s".format( timestep, score, round(time.time() - t1, 3))) if self.logging: self.logger.add_scalar('Episode_score', score, timestep) self.logger.add_scalar( 'Non_greedy_fraction', 1 - self.n_greedy_actions / this_episode_time, timestep) state = torch.as_tensor(self.env.reset()) score = 0 if self.logging: self.logger.add_scalar( 'Q_at_start', self.get_max_q(state.to(self.device).float()), timestep) t1 = time.time() self.n_greedy_actions = 0 this_episode_time = 0 else: state = state_next if is_training_ready: # Update main network if timestep % self.update_frequency == 0: # Sample a batch of transitions transitions = self.replay_buffer.sample( self.minibatch_size, self.device) # Train on selected batch loss = self.train_step(transitions) if self.logging and timesteps < 1000000: self.logger.add_scalar('Loss', loss, timestep) # Update target Q if timestep % self.update_target_frequency == 0: self.target_network.load_state_dict( self.network.state_dict()) if (timestep + 1) % 250000 == 0: self.save(timestep=timestep + 1) self.timestep = timestep if self.logging: self.logger.save() self.save() def train_step(self, transitions): states, actions, rewards, states_next, dones = transitions with torch.no_grad(): target1, target2 = self.target_network(states_next.float()) target1 = target1.view(self.minibatch_size, self.env.action_space.n, self.n_quantiles) target2 = target2.view(self.minibatch_size, self.env.action_space.n, self.n_quantiles) best_action_idx = torch.mean((target1 + target2) / 2, dim=2).max(1, True)[1].unsqueeze(2) q_value_target = 0.5*target1.gather(1, best_action_idx.repeat(1,1,self.n_quantiles))\ + 0.5*target2.gather(1, best_action_idx.repeat(1,1,self.n_quantiles)) # Calculate TD target td_target = rewards.unsqueeze(2).repeat(1,1,self.n_quantiles) \ + (1 - dones.unsqueeze(2).repeat(1,1,self.n_quantiles)) * self.gamma * q_value_target out1, out2 = self.network(states.float()) out1 = out1.view(self.minibatch_size, self.env.action_space.n, self.n_quantiles) out2 = out2.view(self.minibatch_size, self.env.action_space.n, self.n_quantiles) q_value1 = out1.gather( 1, actions.unsqueeze(2).repeat(1, 1, self.n_quantiles)) q_value2 = out2.gather( 1, actions.unsqueeze(2).repeat(1, 1, self.n_quantiles)) loss1 = self.loss(q_value1.squeeze(), td_target.squeeze(), self.device, kappa=self.kappa) loss2 = self.loss(q_value2.squeeze(), td_target.squeeze(), self.device, kappa=self.kappa) quantile_loss = loss1 + loss2 diff1 = [] for i, p in enumerate(self.network.output_1.parameters()): diff1.append(torch.sum((p - self.anchor1[i])**2)) diff2 = [] for i, p in enumerate(self.network.output_2.parameters()): diff2.append(torch.sum((p - self.anchor2[i])**2)) diff1 = torch.stack(diff1).sum() diff2 = torch.stack(diff2).sum() anchor_loss = self.prior * (diff1 + diff2) loss = quantile_loss + anchor_loss # Update weights self.optimizer.zero_grad() loss.backward() self.optimizer.step() return loss.item() def act(self, state, thompson_sampling=False): action = self.predict(state, thompson_sampling=thompson_sampling) return action @torch.no_grad() def predict(self, state, thompson_sampling=False): if not thompson_sampling: net1, net2 = self.network(state) net1 = net1.view(self.env.action_space.n, self.n_quantiles) net2 = net2.view(self.env.action_space.n, self.n_quantiles) action_means = torch.mean((net1 + net2) / 2, dim=1) action = action_means.argmax().item() else: net1, net2 = self.network(state) net1_target, net2_target = self.target_network(state) net1 = net1.view(self.env.action_space.n, self.n_quantiles) net2 = net2.view(self.env.action_space.n, self.n_quantiles) net1_target = net1_target.view(self.env.action_space.n, self.n_quantiles) net2_target = net2_target.view(self.env.action_space.n, self.n_quantiles) action_means = torch.mean((net1 + net2) / 2, dim=1) action_uncertainties = torch.mean( (net1_target - net2_target)**2, dim=1) / 2 samples = torch.distributions.multivariate_normal.MultivariateNormal( action_means, covariance_matrix=torch.diagflat( action_uncertainties)).sample() action = samples.argmax().item() if action == action_means.argmax().item(): self.n_greedy_actions += 1 return action @torch.no_grad() def get_max_q(self, state): net1, net2 = self.network(state) net1 = net1.view(self.env.action_space.n, self.n_quantiles) net2 = net2.view(self.env.action_space.n, self.n_quantiles) action_means = torch.mean((net1 + net2) / 2, dim=1) max_q = action_means.max().item() return max_q def save(self, timestep=None): if not self.logging: raise NotImplementedError('Cannot save without log folder.') if timestep is not None: filename = 'network_' + str(timestep) + '.pth' else: filename = 'network.pth' save_path = self.logger.log_folder + '/' + filename torch.save(self.network.state_dict(), save_path) def load(self, path): self.network.load_state_dict(torch.load(path, map_location='cpu')) self.target_network.load_state_dict( torch.load(path, map_location='cpu'))
class BBBAgent(): def __init__(self, env, network, mean_prior=0, std_prior=0.01, noise_scale=0.01, logging=True, train_freq=10, updates_per_train=100, batch_size=32, start_train_step=10, log_folder_details=None, learning_rate=1e-3, bayesian_sample_size=20, verbose=False): self.env = env self.network = BayesianNetwork(env.n_features, torch.device('cpu'), std_prior, noise_scale) self.logging = logging self.replay_buffer = ReplayBuffer() self.batch_size = batch_size self.log_folder_details = log_folder_details self.optimizer = optim.Adam(self.network.parameters(), lr=learning_rate, eps=1e-8) self.train_freq = train_freq self.start_train_step = start_train_step self.updates_per_train = updates_per_train self.bayesian_sample_size = bayesian_sample_size self.verbose = verbose self.n_samples = 0 self.timestep = 0 self.train_parameters = { 'mean_prior': mean_prior, 'std_prior': std_prior, 'noise_scale': noise_scale, 'train_freq': train_freq, 'updates_per_train': updates_per_train, 'batch_size': batch_size, 'start_train_step': start_train_step, 'learning_rate': learning_rate, 'bayesian_sample_size': bayesian_sample_size } def learn(self, n_steps): self.train_parameters['n_steps'] = n_steps if self.logging: self.logger = Logger(self.log_folder_details, self.train_parameters) cumulative_regret = 0 for timestep in range(n_steps): x = self.env.sample() action, sampled_value = self.act(x.float()) reward = self.env.hit(action) regret = self.env.regret(action) cumulative_regret += regret action = torch.as_tensor([action], dtype=torch.long) reward = torch.as_tensor([reward], dtype=torch.float) if action == 1: self.n_samples += 1 self.replay_buffer.add(x, reward) if self.logging: self.logger.add_scalar('Cumulative_Regret', cumulative_regret, timestep) self.logger.add_scalar('Mushrooms_Eaten', self.n_samples, timestep) if self.env.y_sample == 1: self.logger.add_scalar('Sampled_Value_Good', sampled_value.item(), self.timestep) else: self.logger.add_scalar('Sampled_Value_Bad', sampled_value.item(), self.timestep) if timestep % self.train_freq == 0 and self.n_samples > self.start_train_step: if self.verbose: print('Timestep: {}, cumulative regret {}'.format( str(timestep), str(cumulative_regret))) for update in range(self.updates_per_train): samples = self.replay_buffer.sample( np.min([self.n_samples, self.batch_size])) self.train_step(samples) self.timestep += 1 if self.logging: self.logger.save() def train_step(self, samples): states, rewards = samples loss, _, _, _ = self.network.sample_elbo( states.float(), rewards, self.n_samples, np.min([self.n_samples, self.batch_size]), self.bayesian_sample_size) if self.logging: self.logger.add_scalar('Loss', loss.detach().item(), self.timestep) # Update weights self.optimizer.zero_grad() loss.backward() self.optimizer.step() def act(self, x): action, sampled_value = self.predict(x) return action, sampled_value @torch.no_grad() def predict(self, x): sampled_value = self.network.forward(x) if sampled_value > 0: action = 1 else: action = 0 return action, sampled_value
class ThompsonAgent(): def __init__(self, env, network, n_quantiles=20, mean_prior=0, std_prior=0.01, noise_scale=0.01, logging=True, train_freq=10, updates_per_train=100, batch_size=32, start_train_step=10, log_folder_details=None, learning_rate=1e-3, verbose=False): self.env = env self.network1 = network(env.n_features, n_quantiles, mean_prior, std_prior) self.network2 = network(env.n_features, n_quantiles, mean_prior, std_prior) self.optimizer = optim.Adam(list(self.network1.parameters()) + list(self.network2.parameters()), lr=learning_rate, eps=1e-8) self.logging = logging self.replay_buffer = ReplayBuffer() self.batch_size = batch_size self.log_folder_details = log_folder_details self.n_quantiles = n_quantiles self.train_freq = train_freq self.start_train_step = start_train_step self.updates_per_train = updates_per_train self.n_samples = 0 self.noise_scale = noise_scale self.std_prior = std_prior self.verbose = verbose self.prior1 = [ p.data.clone() for p in list(self.network1.features.parameters()) ] self.prior2 = [ p.data.clone() for p in list(self.network2.features.parameters()) ] self.train_parameters = { 'n_quantiles': n_quantiles, 'mean_prior': mean_prior, 'std_prior': std_prior, 'train_freq': train_freq, 'updates_per_train': updates_per_train, 'batch_size': batch_size, 'start_train_step': start_train_step, 'learning_rate': learning_rate, 'noise_scale': noise_scale } def learn(self, n_steps): self.train_parameters['n_steps'] = n_steps if self.logging: self.logger = Logger(self.log_folder_details, self.train_parameters) cumulative_regret = 0 for timestep in range(n_steps): x = self.env.sample() action, uncertainty, sampled_value = self.act(x.float()) reward = self.env.hit(action) regret = self.env.regret(action) cumulative_regret += regret reward = torch.as_tensor([reward], dtype=torch.float) if self.logging: self.logger.add_scalar('Cumulative_Regret', cumulative_regret, timestep) self.logger.add_scalar('Mushrooms_Eaten', self.n_samples, timestep) if self.env.y_sample == 1: self.logger.add_scalar('Uncertainty_Good', uncertainty, timestep) self.logger.add_scalar('Sampled_Value_Good', sampled_value, timestep) else: self.logger.add_scalar('Uncertainty_Bad', uncertainty, timestep) self.logger.add_scalar('Sampled_Value_Bad', sampled_value, timestep) if action == 1: self.replay_buffer.add(x, reward) self.n_samples += 1 if timestep % self.train_freq == 0 and self.n_samples > self.start_train_step: if self.verbose: print('Timestep: {}, cumulative regret {}'.format( str(timestep), str(cumulative_regret))) for update in range(self.updates_per_train): samples = self.replay_buffer.sample( np.min([self.n_samples, self.batch_size])) self.train_step(samples) if self.logging: self.logger.save() def train_step(self, samples): states, rewards = samples target = rewards.repeat(1, self.n_quantiles) q_value1 = self.network1(states.float()).view( np.min([self.n_samples, self.batch_size]), self.n_quantiles) q_value2 = self.network2(states.float()).view( np.min([self.n_samples, self.batch_size]), self.n_quantiles) loss1 = quantile_huber_loss(q_value1.squeeze(), target.squeeze()) loss2 = quantile_huber_loss(q_value2.squeeze(), target.squeeze()) reg = [] for i, p in enumerate(self.network1.features.parameters()): diff = (p - self.prior1[i]) reg.append(torch.sum(diff**2)) loss_anchored1 = torch.sum(torch.stack(reg)) reg = [] for i, p in enumerate(self.network2.features.parameters()): diff = (p - self.prior2[i]) reg.append(torch.sum(diff**2)) loss_anchored2 = torch.sum(torch.stack(reg)) loss = loss1 + loss2 + self.noise_scale * ( loss_anchored1 + loss_anchored2) / (self.std_prior**2 * self.n_samples) self.optimizer.zero_grad() loss.backward() self.optimizer.step() def act(self, x): action, uncertainty, sampled_value = self.predict(x) return action, uncertainty, sampled_value @torch.no_grad() def predict(self, x): net1 = self.network1(x) net2 = self.network2(x) action_mean = torch.mean((net1 + net2) / 2) action_uncertainty = torch.sqrt(torch.mean((net1 - net2)**2) / 2) sampled_value = torch.distributions.Normal( action_mean, action_uncertainty).sample() if sampled_value > 0: action = 1 else: action = 0 return action, action_uncertainty.item(), sampled_value