class POMDP: def __init__(self, args): self.args = args self.ACTIONS = ['left', 'right', 'forward', 'backward', 'up', 'down'] # 'open', 'close'] self.P_START = 0.999 self.P_END = 0.1 self.P_DECAY = 60000 self.max_iter = args.max_iter self.gripping_force = args.grip_force self.break_threshold = args.break_thresh # Prepare the drawing figure fig, (ax1, ax2) = plt.subplots(1, 2) self.figure = (fig, ax1, ax2) # Function to select an action from our policy or a random one def select_action(self, observation, hidden_state, cell_state): args = self.args sample = random.random() p_threshold = self.P_END + (self.P_START - self.P_END) * math.exp( -1. * self.steps_done / self.P_DECAY) self.steps_done += 1 tactile_obs, img_norm = observation with torch.no_grad(): # t.max(1) will return largest column value of each row. # second column on max result is index of where max element was # found, so we pick action with the larger expected reward. self.policy_net_1.eval() torch_tactile_obs = torch.from_numpy(tactile_obs).float().to( args.device).unsqueeze(0) torch_img_norm = torch.from_numpy(img_norm).float().to( args.device).unsqueeze(0) img_ft = self.conv_net_1.forward(torch_img_norm) torch_observation = torch.cat((torch_tactile_obs, img_ft), dim=1) model_out = self.policy_net_1(torch_observation, batch_size=1, time_step=1, hidden_state=hidden_state, cell_state=cell_state) out = model_out[0] hidden_state = model_out[1][0] cell_state = model_out[1][1] self.policy_net_1.train() if sample > p_threshold: action = int(torch.argmax(out[0])) return action, hidden_state, cell_state else: return random.randrange(0, args.outdim), hidden_state, cell_state def sample_memory(self): batch = self.memory.sample(self.args.batch_size, self.args.time_step) if not batch: return current_states, actions, rewards, next_states = [], [], [], [] for b in batch: cs, ac, rw, ns = [], [], [], [] for element in b: cs.append(element.state) ac.append(element.action) rw.append(element.reward) ns.append(element.next_state) current_states.append(cs) actions.append(ac) rewards.append(rw) next_states.append(ns) return current_states, actions, rewards, next_states def extract_ft(self, conv_net, obs_batch): args = self.args assert len(obs_batch) == args.batch_size assert len(obs_batch[0]) == args.time_step result = [] for b in obs_batch: obs_squence = torch.tensor([]).to(args.device) for item in b: tactile_obs, img_norm = item torch_tactile_obs = torch.from_numpy(tactile_obs).float().to( args.device) torch_img_norm = torch.from_numpy(img_norm).float().to( args.device).unsqueeze(0) img_ft = conv_net.forward(torch_img_norm) torch_full_obs = torch.cat((torch_tactile_obs, img_ft[0])) obs_squence = torch.cat((obs_squence, torch_full_obs)) torch_obs_squence = obs_squence.view(args.time_step, -1) result.append(obs_squence) return torch.stack(result) def bootstrap(self, policy_net, conv_net, memory_subset): args = self.args if len(self.memory) < (args.batch_size): return current_states, actions, rewards, next_states = memory_subset # process observation (tactile_obs, img) to 1d tensor of (tactile_obs, feature) # and then stack them to corresponding dimension: (batch_size, time_step, *) current_states = self.extract_ft(conv_net, current_states) next_states = self.extract_ft(conv_net, next_states) # convert all to torch tensors actions = torch.from_numpy(np.array(actions)).long().to(args.device) rewards = torch.from_numpy(np.array(rewards)).float().to(args.device) hidden_batch, cell_batch = policy_net.init_hidden_states( args.batch_size, args.device) Q_s, _ = policy_net.forward(current_states, batch_size=args.batch_size, time_step=args.time_step, hidden_state=hidden_batch, cell_state=cell_batch) Q_s_a = Q_s.gather(dim=1, index=actions[:, args.time_step - 1].unsqueeze(dim=1)).squeeze(dim=1) Q_next, _ = policy_net.forward(next_states, batch_size=args.batch_size, time_step=args.time_step, hidden_state=hidden_batch, cell_state=cell_batch) Q_next_max = Q_next.detach().max(dim=1)[0] return Q_s_a, Q_next_max def optimize(self): args = self.args if len(self.memory) < (args.batch_size): return memory_subset = self.sample_memory() _, _, rewards, _ = memory_subset rewards = torch.from_numpy(np.array(rewards)).float().to(args.device) Q_s_a_1, Q_next_max_1 = self.bootstrap(self.policy_net_1, self.conv_net_1, memory_subset) Q_s_a_2, Q_next_max_2 = self.bootstrap(self.policy_net_2, self.conv_net_2, memory_subset) Q_next_max = torch.min(Q_next_max_1, Q_next_max_2) # Compute the expected Q values target_values = rewards[:, args.time_step - 1] + (args.gamma * Q_next_max) # Compute Huber loss loss_1 = F.smooth_l1_loss(Q_s_a_1, target_values) loss_2 = F.smooth_l1_loss(Q_s_a_2, target_values) # Optimize the model self.policy_optimizer_1.zero_grad() self.policy_optimizer_2.zero_grad() self.conv_optimizer_1.zero_grad() self.conv_optimizer_2.zero_grad() loss_1.backward() loss_2.backward() for param in self.policy_net_1.parameters(): param.grad.data.clamp_(-1, 1) for param in self.policy_net_2.parameters(): param.grad.data.clamp_(-1, 1) for param in self.conv_net_2.parameters(): param.grad.data.clamp_(-1, 1) for param in self.conv_net_2.parameters(): param.grad.data.clamp_(-1, 1) self.policy_optimizer_1.step() self.policy_optimizer_2.step() self.conv_optimizer_1.step() self.conv_optimizer_2.step() def train_POMDP(self): args = self.args # Create the output directory if it does not exist if not os.path.isdir(args.output_dir): os.makedirs(args.output_dir) # Create our policy net and a target net self.policy_net_1 = DRQN(args.indim, args.outdim).to(args.device) self.policy_net_2 = DRQN(args.indim, args.outdim).to(args.device) self.conv_net_1 = ConvNet(args.ftdim, args.depth).to(args.device) self.conv_net_2 = ConvNet(args.ftdim, args.depth).to(args.device) # Set up the optimizer self.policy_optimizer_1 = optim.RMSprop(self.policy_net_1.parameters(), lr=args.lr) self.policy_optimizer_2 = optim.RMSprop(self.policy_net_2.parameters(), lr=args.lr) self.conv_optimizer_1 = optim.RMSprop(self.conv_net_1.parameters(), lr=1e-5) self.conv_optimizer_2 = optim.RMSprop(self.conv_net_2.parameters(), lr=1e-5) self.memory = RecurrentMemory(70) self.steps_done = 0 # Setup the state normalizer normalizer = Multimodal_Normalizer(num_inputs=args.indim - args.ftdim, device=args.device) print_variables = {'durations': [], 'rewards': [], 'loss': []} start_episode = 0 if args.checkpoint_file: if os.path.exists(args.checkpoint_file): checkpoint = torch.load(args.checkpoint_file) self.policy_net_1.load_state_dict(checkpoint['policy_net_1']) self.policy_net_2.load_state_dict(checkpoint['policy_net_2']) self.conv_net_1.load_state_dict(checkpoint['conv_net_1']) self.conv_net_2.load_state_dict(checkpoint['conv_net_2']) self.policy_optimizer_1.load_state_dict( checkpoint['policy_optimizer_1']) self.policy_optimizer_2.load_state_dict( checkpoint['policy_optimizer_2']) self.conv_optimizer_1.load_state_dict( checkpoint['conv_optimizer_1']) self.conv_optimizer_2.load_state_dict( checkpoint['conv_optimizer_2']) start_episode = checkpoint['epoch'] self.steps_done = checkpoint['steps_done'] with open( os.path.join(os.path.dirname(args.checkpoint_file), 'results_pomdp.pkl'), 'rb') as file: plot_dict = pickle.load(file) print_variables['durations'] = plot_dict['durations'] print_variables['rewards'] = plot_dict['rewards'] if args.normalizer_file: if os.path.exists(args.normalizer_file): normalizer.restore_state(args.normalizer_file) if args.memory: if os.path.exists(args.memory): self.memory.load(args.memory) if args.weight_conv: checkpoint = torch.load(args.weight_conv) self.conv_net_1.load_state_dict(checkpoint['conv_net']) self.conv_optimizer_1.load_state_dict(checkpoint['conv_optimizer']) self.conv_net_2.load_state_dict(checkpoint['conv_net']) self.conv_optimizer_2.load_state_dict(checkpoint['conv_optimizer']) action_space = ActionSpace(dp=0.06, df=10) # Create robot, reset simulation and grasp handle model = load_model_from_path(args.model_path) sim = MjSim(model) sim_param = SimParameter(sim) sim.step() if args.render: viewer = MjViewer(sim) else: viewer = None robot = RobotSim(sim, viewer, sim_param, args.render, self.break_threshold) tactile_obs_space = TactileObs( robot.get_gripper_jpos(), # 6 robot.get_all_touch_buffer(args.hap_sample)) # 30 x 12 # Main training loop for ii in range(start_episode, args.epochs): start_time = time.time() act_sequence = [] velcro_params = init_model(robot.mj_sim) robot.reset_simulation() ret = robot.grasp_handle() if not ret: continue # Local memory for current episode localMemory = [] # Get current observation hidden_state_1, cell_state_1 = self.policy_net_1.init_hidden_states( batch_size=1, device=args.device) hidden_state_2, cell_state_2 = self.policy_net_2.init_hidden_states( batch_size=1, device=args.device) broken_so_far = 0 for t in count(): if not args.quiet and t % 50 == 0: print("Running training episode: {}, iteration: {}".format( ii, t)) # Select action tactile_obs = tactile_obs_space.get_state() normalizer.observe(tactile_obs) tactile_obs = normalizer.normalize(tactile_obs) # Get image and normalize it img = robot.get_img(args.img_w, args.img_h, 'c1', args.depth) if args.depth: depth = norm_depth(img[1]) img = norm_img(img[0]) img_norm = np.empty((4, args.img_w, args.img_h)) img_norm[:3, :, :] = img img_norm[3, :, :] = depth else: img_norm = norm_img(img) observation = [tactile_obs, img_norm] action, hidden_state_1, cell_state_1 = self.select_action( observation, hidden_state_1, cell_state_1) # record actions in this epoch act_sequence.append(action) # Perform action delta = action_space.get_action( self.ACTIONS[action])['delta'][:3] target_position = np.add(robot.get_gripper_jpos()[:3], np.array(delta)) target_pose = np.hstack( (target_position, robot.get_gripper_jpos()[3:])) robot.move_joint(target_pose, True, self.gripping_force, hap_sample=args.hap_sample) # Get reward done, num = robot.update_tendons() failure = robot.check_slippage() if num > broken_so_far: reward = num - broken_so_far broken_so_far = num else: reward = 0 # Observe new state tactile_obs_space.update( robot.get_gripper_jpos(), # 6 robot.get_all_touch_buffer(args.hap_sample)) # 30x12 # Set max number of iterations if t >= self.max_iter: done = True # Check if done if not done and not failure: next_tactile_obs = tactile_obs_space.get_state() normalizer.observe(next_tactile_obs) next_tactile_obs = normalizer.normalize(next_tactile_obs) # Get image and normalize it next_img = robot.get_img(args.img_w, args.img_h, 'c1', args.depth) if args.depth: next_depth = norm_depth(next_img[1]) next_img = norm_img(next_img[0]) next_img_norm = np.empty((4, args.img_w, args.img_h)) next_img_norm[:3, :, :] = next_img next_img_norm[3, :, :] = next_depth else: next_img_norm = norm_img(next_img) next_state = [next_tactile_obs, next_img_norm] else: next_state = None # Push new Transition into memory localMemory.append( Transition(observation, action, next_state, reward)) # Optimize the model if self.steps_done % 10 == 0: self.optimize() # If we are done, reset the model if done or failure: self.memory.push(localMemory) if failure: print_variables['durations'].append(self.max_iter) else: print_variables['durations'].append(t) print_variables['rewards'].append(broken_so_far) plot_variables(self.figure, print_variables, "Training POMDP") print("Model parameters: {}".format(velcro_params)) print("Actions in this epoch are: {}".format(act_sequence)) print("Epoch {} took {}s, total number broken: {}\n\n". format(ii, time.time() - start_time, broken_so_far)) break # Save checkpoints every vew iterations if ii % args.save_freq == 0: save_path = os.path.join( args.output_dir, 'checkpoint_model_' + str(ii) + '.pth') torch.save( { 'epochs': ii, 'steps_done': self.steps_done, 'conv_net_1': self.conv_net_1.state_dict(), 'conv_net_2': self.conv_net_2.state_dict(), 'policy_net_1': self.policy_net_1.state_dict(), 'policy_net_2': self.policy_net_2.state_dict(), 'conv_optimizer_1': self.conv_optimizer_1.state_dict(), 'conv_optimizer_2': self.conv_optimizer_2.state_dict(), 'policy_optimizer_1': self.policy_optimizer_1.state_dict(), 'policy_optimizer_2': self.policy_optimizer_2.state_dict(), }, save_path) # Save normalizer state for inference normalizer.save_state( os.path.join(args.output_dir, 'normalizer_state.pickle')) self.memory.save_memory(os.path.join(args.output_dir, 'memory.pickle')) if args.savefig_path: now = dt.datetime.now() self.figure[0].savefig( args.savefig_path + '{}_{}_{}.png'.format(now.month, now.day, now.hour), format='png') print('Training done') plt.show() return print_variables
def main(args): if not os.path.isdir(args.result_dir): os.makedirs(args.result_dir) parent = os.path.dirname(os.path.abspath(__file__)) # load test xml files test_file = os.path.join(parent, 'tests/test_xmls/temp_1_{}.pickle'.format(args.case)) params = pickle.load(open(test_file, 'rb')) # params = params[:6] if args.shuffle: random.shuffle(params) num_test = len(params) print(' ++++++++++++++++++++++++++') print(' +++ Now running case {} +++'.format(args.case)) print(' ++++++++++++++++++++++++++\n\n') policy_net = DRQN(args.indim, args.outdim) policy_net.load_state_dict(torch.load(args.weight_path)['policy_net_1']) policy_net.eval() # load normalizer # Setup the state normalizer normalizer = Multimodal_Normalizer(num_inputs = args.indim, device=args.device) if args.normalizer_file: if os.path.exists(args.normalizer_file): normalizer.restore_state(args.normalizer_file) # Create robot, reset simulation and grasp handle model = load_model_from_path(args.model_path) sim = MjSim(model) sim_param = SimParameter(sim) sim.step() if args.render: viewer = MjViewer(sim) else: viewer = None robot = RobotSim(sim, viewer, sim_param, args.render, args.break_thresh) tactile_obs_space = TactileObs(robot.get_gripper_xpos(), # 24 robot.get_all_touch_buffer(args.hap_sample)) # 30 x 6 performance = {'time':[], 'success':[], 'num_broken':[], 'tendon_hist':[0,0,0,0,0], 'collision':[], 'action_hist': [0,0,0,0,0,0]} for i in range(num_test): velcro_params = params[i] geom, origin_offset, euler, radius = velcro_params print('\n\nTest {} Velcro parameters are: {}, {}, {}, {}'.format(i, geom, origin_offset, euler, radius)) change_sim(robot.mj_sim, geom, origin_offset, euler, radius) robot.reset_simulation() ret = robot.grasp_handle() performance = test_network(args, policy_net, normalizer, robot, tactile_obs_space, performance) print('Success: {}, time: {}, num_broken: {}, collision:{} '.format( performance['success'][-1], performance['time'][-1], performance['num_broken'][-1], performance['collision'][-1])) print('Finished opening velcro with haptics test \n') success = np.array(performance['success']) time = np.array(performance['time']) print('Successfully opened the velcro in: {}% of cases'.format(100 * np.sum(success) / len(performance['success']))) print('Average time to open: {}'.format(np.average(time[success>0]))) print('Action histogram for the test is: {}'.format(performance['action_hist'])) out_fname = 'case{}.txt'.format(args.case) with open(os.path.join(args.result_dir, out_fname), 'w+') as f: f.write('Time: {}\n'.format(performance['time'])) f.write('Success: {}\n'.format(performance['success'])) f.write('Successfully opened the velcro in: {}% of cases\n'.format(100 * np.sum(success) / len(performance['success']))) f.write('Average time to open: {}\n'.format(np.average(time[success>0]))) f.write('Num_broken: {}\n'.format(performance['num_broken'])) f.write('Tendon histogram: {}\n'.format(performance['tendon_hist'])) f.write('collision: {}\n'.format(performance['collision'])) # f.write('high_success: {} low_success: {} '.format(high_success, low_success)) f.close()
def train_POMDP(self): args = self.args # Create the output directory if it does not exist if not os.path.isdir(args.output_dir): os.makedirs(args.output_dir) # Create our policy net and a target net self.policy_net_1 = DRQN(args.indim, args.outdim).to(args.device) self.policy_net_2 = DRQN(args.indim, args.outdim).to(args.device) self.conv_net_1 = ConvNet(args.ftdim, args.depth).to(args.device) self.conv_net_2 = ConvNet(args.ftdim, args.depth).to(args.device) # Set up the optimizer self.policy_optimizer_1 = optim.RMSprop(self.policy_net_1.parameters(), lr=args.lr) self.policy_optimizer_2 = optim.RMSprop(self.policy_net_2.parameters(), lr=args.lr) self.conv_optimizer_1 = optim.RMSprop(self.conv_net_1.parameters(), lr=1e-5) self.conv_optimizer_2 = optim.RMSprop(self.conv_net_2.parameters(), lr=1e-5) self.memory = RecurrentMemory(70) self.steps_done = 0 # Setup the state normalizer normalizer = Multimodal_Normalizer(num_inputs=args.indim - args.ftdim, device=args.device) print_variables = {'durations': [], 'rewards': [], 'loss': []} start_episode = 0 if args.checkpoint_file: if os.path.exists(args.checkpoint_file): checkpoint = torch.load(args.checkpoint_file) self.policy_net_1.load_state_dict(checkpoint['policy_net_1']) self.policy_net_2.load_state_dict(checkpoint['policy_net_2']) self.conv_net_1.load_state_dict(checkpoint['conv_net_1']) self.conv_net_2.load_state_dict(checkpoint['conv_net_2']) self.policy_optimizer_1.load_state_dict( checkpoint['policy_optimizer_1']) self.policy_optimizer_2.load_state_dict( checkpoint['policy_optimizer_2']) self.conv_optimizer_1.load_state_dict( checkpoint['conv_optimizer_1']) self.conv_optimizer_2.load_state_dict( checkpoint['conv_optimizer_2']) start_episode = checkpoint['epoch'] self.steps_done = checkpoint['steps_done'] with open( os.path.join(os.path.dirname(args.checkpoint_file), 'results_pomdp.pkl'), 'rb') as file: plot_dict = pickle.load(file) print_variables['durations'] = plot_dict['durations'] print_variables['rewards'] = plot_dict['rewards'] if args.normalizer_file: if os.path.exists(args.normalizer_file): normalizer.restore_state(args.normalizer_file) if args.memory: if os.path.exists(args.memory): self.memory.load(args.memory) if args.weight_conv: checkpoint = torch.load(args.weight_conv) self.conv_net_1.load_state_dict(checkpoint['conv_net']) self.conv_optimizer_1.load_state_dict(checkpoint['conv_optimizer']) self.conv_net_2.load_state_dict(checkpoint['conv_net']) self.conv_optimizer_2.load_state_dict(checkpoint['conv_optimizer']) action_space = ActionSpace(dp=0.06, df=10) # Create robot, reset simulation and grasp handle model = load_model_from_path(args.model_path) sim = MjSim(model) sim_param = SimParameter(sim) sim.step() if args.render: viewer = MjViewer(sim) else: viewer = None robot = RobotSim(sim, viewer, sim_param, args.render, self.break_threshold) tactile_obs_space = TactileObs( robot.get_gripper_jpos(), # 6 robot.get_all_touch_buffer(args.hap_sample)) # 30 x 12 # Main training loop for ii in range(start_episode, args.epochs): start_time = time.time() act_sequence = [] velcro_params = init_model(robot.mj_sim) robot.reset_simulation() ret = robot.grasp_handle() if not ret: continue # Local memory for current episode localMemory = [] # Get current observation hidden_state_1, cell_state_1 = self.policy_net_1.init_hidden_states( batch_size=1, device=args.device) hidden_state_2, cell_state_2 = self.policy_net_2.init_hidden_states( batch_size=1, device=args.device) broken_so_far = 0 for t in count(): if not args.quiet and t % 50 == 0: print("Running training episode: {}, iteration: {}".format( ii, t)) # Select action tactile_obs = tactile_obs_space.get_state() normalizer.observe(tactile_obs) tactile_obs = normalizer.normalize(tactile_obs) # Get image and normalize it img = robot.get_img(args.img_w, args.img_h, 'c1', args.depth) if args.depth: depth = norm_depth(img[1]) img = norm_img(img[0]) img_norm = np.empty((4, args.img_w, args.img_h)) img_norm[:3, :, :] = img img_norm[3, :, :] = depth else: img_norm = norm_img(img) observation = [tactile_obs, img_norm] action, hidden_state_1, cell_state_1 = self.select_action( observation, hidden_state_1, cell_state_1) # record actions in this epoch act_sequence.append(action) # Perform action delta = action_space.get_action( self.ACTIONS[action])['delta'][:3] target_position = np.add(robot.get_gripper_jpos()[:3], np.array(delta)) target_pose = np.hstack( (target_position, robot.get_gripper_jpos()[3:])) robot.move_joint(target_pose, True, self.gripping_force, hap_sample=args.hap_sample) # Get reward done, num = robot.update_tendons() failure = robot.check_slippage() if num > broken_so_far: reward = num - broken_so_far broken_so_far = num else: reward = 0 # Observe new state tactile_obs_space.update( robot.get_gripper_jpos(), # 6 robot.get_all_touch_buffer(args.hap_sample)) # 30x12 # Set max number of iterations if t >= self.max_iter: done = True # Check if done if not done and not failure: next_tactile_obs = tactile_obs_space.get_state() normalizer.observe(next_tactile_obs) next_tactile_obs = normalizer.normalize(next_tactile_obs) # Get image and normalize it next_img = robot.get_img(args.img_w, args.img_h, 'c1', args.depth) if args.depth: next_depth = norm_depth(next_img[1]) next_img = norm_img(next_img[0]) next_img_norm = np.empty((4, args.img_w, args.img_h)) next_img_norm[:3, :, :] = next_img next_img_norm[3, :, :] = next_depth else: next_img_norm = norm_img(next_img) next_state = [next_tactile_obs, next_img_norm] else: next_state = None # Push new Transition into memory localMemory.append( Transition(observation, action, next_state, reward)) # Optimize the model if self.steps_done % 10 == 0: self.optimize() # If we are done, reset the model if done or failure: self.memory.push(localMemory) if failure: print_variables['durations'].append(self.max_iter) else: print_variables['durations'].append(t) print_variables['rewards'].append(broken_so_far) plot_variables(self.figure, print_variables, "Training POMDP") print("Model parameters: {}".format(velcro_params)) print("Actions in this epoch are: {}".format(act_sequence)) print("Epoch {} took {}s, total number broken: {}\n\n". format(ii, time.time() - start_time, broken_so_far)) break # Save checkpoints every vew iterations if ii % args.save_freq == 0: save_path = os.path.join( args.output_dir, 'checkpoint_model_' + str(ii) + '.pth') torch.save( { 'epochs': ii, 'steps_done': self.steps_done, 'conv_net_1': self.conv_net_1.state_dict(), 'conv_net_2': self.conv_net_2.state_dict(), 'policy_net_1': self.policy_net_1.state_dict(), 'policy_net_2': self.policy_net_2.state_dict(), 'conv_optimizer_1': self.conv_optimizer_1.state_dict(), 'conv_optimizer_2': self.conv_optimizer_2.state_dict(), 'policy_optimizer_1': self.policy_optimizer_1.state_dict(), 'policy_optimizer_2': self.policy_optimizer_2.state_dict(), }, save_path) # Save normalizer state for inference normalizer.save_state( os.path.join(args.output_dir, 'normalizer_state.pickle')) self.memory.save_memory(os.path.join(args.output_dir, 'memory.pickle')) if args.savefig_path: now = dt.datetime.now() self.figure[0].savefig( args.savefig_path + '{}_{}_{}.png'.format(now.month, now.day, now.hour), format='png') print('Training done') plt.show() return print_variables
class POMDP: def __init__(self, args): self.args = args self.ACTIONS = ['left', 'right', 'forward', 'backward', 'up', 'down'] # 'open', 'close'] self.P_START = 0.999 self.P_END = 0.05 self.P_DECAY = 600 self.max_iter = args.max_iter self.gripping_force = args.grip_force self.break_threshold = args.break_thresh # Prepare the drawing figure fig, (ax1, ax2) = plt.subplots(1, 2) self.figure = (fig, ax1, ax2) # Function to select an action from our policy or a random one def select_action(self, observation, hidden_state, cell_state): sample = random.random() p_threshold = self.P_END + (self.P_START - self.P_END) * math.exp( -1. * self.steps_done / self.P_DECAY) with torch.no_grad(): # t.max(1) will return largest column value of each row. # second column on max result is index of where max element was # found, so we pick action with the larger expected reward. self.policy_net_1.eval() torch_observation = torch.from_numpy(observation).float().to( self.args.device).unsqueeze(0) model_out = self.policy_net_1(torch_observation, batch_size=1, time_step=1, hidden_state=hidden_state, cell_state=cell_state) out = model_out[0] hidden_state = model_out[1][0] cell_state = model_out[1][1] self.policy_net_1.train() if sample > p_threshold: action = int(torch.argmax(out[0])) return action, hidden_state, cell_state else: return random.randrange( 0, self.args.outdim), hidden_state, cell_state def optimize_model(self): args = self.args if len(self.memory) < (args.batch_size): return hidden_batch_1, cell_batch_1 = self.policy_net_1.init_hidden_states( args.batch_size, args.device) hidden_batch_2, cell_batch_2 = self.policy_net_2.init_hidden_states( args.batch_size, args.device) hidden_batch_3, cell_batch_3 = self.policy_net_3.init_hidden_states( args.batch_size, args.device) batch = self.memory.sample(args.batch_size, args.time_step) if not batch: return current_states, actions, rewards, next_states = [], [], [], [] for b in batch: cs, ac, rw, ns = [], [], [], [] for element in b: cs.append(element.state) ac.append(element.action) rw.append(element.reward) ns.append(element.next_state) current_states.append(cs) actions.append(ac) rewards.append(rw) next_states.append(ns) current_states = torch.from_numpy(np.array(current_states)).float().to( args.device) actions = torch.from_numpy(np.array(actions)).long().to(args.device) rewards = torch.from_numpy(np.array(rewards)).float().to(args.device) next_states = torch.from_numpy(np.array(next_states)).float().to( args.device) # Compute Q(s_t, a) - the model computes Q(s_t), then we select the # columns of actions taken. These are the actions which would've been taken # for each batch state according to policy_net Q_s_1, _ = self.policy_net_1.forward(current_states, batch_size=args.batch_size, time_step=args.time_step, hidden_state=hidden_batch_1, cell_state=cell_batch_1) Q_s_a_1 = Q_s_1.gather( dim=1, index=actions[:, args.time_step - 1].unsqueeze(dim=1)).squeeze(dim=1) Q_s_2, _ = self.policy_net_2.forward(current_states, batch_size=args.batch_size, time_step=args.time_step, hidden_state=hidden_batch_2, cell_state=cell_batch_2) Q_s_a_2 = Q_s_2.gather( dim=1, index=actions[:, args.time_step - 1].unsqueeze(dim=1)).squeeze(dim=1) Q_s_3, _ = self.policy_net_3.forward(current_states, batch_size=args.batch_size, time_step=args.time_step, hidden_state=hidden_batch_3, cell_state=cell_batch_3) Q_s_a_3 = Q_s_3.gather( dim=1, index=actions[:, args.time_step - 1].unsqueeze(dim=1)).squeeze(dim=1) Q_next_1, _ = self.policy_net_1.forward(next_states, batch_size=args.batch_size, time_step=args.time_step, hidden_state=hidden_batch_1, cell_state=cell_batch_1) Q_next_max_1 = Q_next_1.detach().max(dim=1)[0] Q_next_2, _ = self.policy_net_2.forward(next_states, batch_size=args.batch_size, time_step=args.time_step, hidden_state=hidden_batch_2, cell_state=cell_batch_2) Q_next_max_2 = Q_next_2.detach().max(dim=1)[0] Q_next_3, _ = self.policy_net_3.forward(next_states, batch_size=args.batch_size, time_step=args.time_step, hidden_state=hidden_batch_3, cell_state=cell_batch_3) Q_next_max_3 = Q_next_3.detach().max(dim=1)[0] Q_next_max = torch.min(torch.min(Q_next_max_1, Q_next_max_2), Q_next_max_3) # Compute the expected Q values target_values = rewards[:, args.time_step - 1] + (args.gamma * Q_next_max) # Compute Huber loss loss_1 = F.smooth_l1_loss(Q_s_a_1, target_values) loss_2 = F.smooth_l1_loss(Q_s_a_2, target_values) loss_3 = F.smooth_l1_loss(Q_s_a_3, target_values) # Optimize the model self.optimizer_1.zero_grad() self.optimizer_2.zero_grad() self.optimizer_3.zero_grad() loss_1.backward() loss_2.backward() loss_3.backward() for param in self.policy_net_1.parameters(): param.grad.data.clamp_(-1, 1) for param in self.policy_net_2.parameters(): param.grad.data.clamp_(-1, 1) for param in self.policy_net_3.parameters(): param.grad.data.clamp_(-1, 1) self.optimizer_1.step() self.optimizer_2.step() self.optimizer_3.step() return [loss_1, loss_2, loss_3] def train_POMDP(self): args = self.args ROOT_DIR = os.path.dirname(os.path.dirname( os.path.abspath(__file__))) # corl2019 PARENT_DIR = os.path.dirname(ROOT_DIR) # reserach # Create the output directory if it does not exist output_dir = os.path.join(PARENT_DIR, 'multistep_pomdp', args.output_dir) if not os.path.isdir(output_dir): os.makedirs(output_dir) # write args to file with open(os.path.join(output_dir, 'args.txt'), 'w+') as f: json.dump(args.__dict__, f, indent=2) f.close() # Create our policy net and a target net self.policy_net_1 = DRQN(args.indim, args.outdim).to(args.device) self.policy_net_2 = DRQN(args.indim, args.outdim).to(args.device) self.policy_net_3 = DRQN(args.indim, args.outdim).to(args.device) # Set up the optimizer self.optimizer_1 = optim.RMSprop(self.policy_net_1.parameters()) self.optimizer_2 = optim.RMSprop(self.policy_net_2.parameters()) self.optimizer_3 = optim.RMSprop(self.policy_net_3.parameters()) self.memory = RecurrentMemory(800) self.steps_done = 0 # Setup the state normalizer normalizer = Multimodal_Normalizer(num_inputs=args.indim, device=args.device) print_variables = {'durations': [], 'rewards': [], 'loss': []} start_episode = 0 if args.checkpoint_file: if os.path.exists(args.checkpoint_file): checkpoint = torch.load(args.checkpoint_file) self.policy_net_1.load_state_dict(checkpoint['policy_net_1']) self.policy_net_2.load_state_dict(checkpoint['policy_net_2']) self.policy_net_3.load_state_dict(checkpoint['policy_net_3']) self.optimizer_1.load_state_dict(checkpoint['optimizer_1']) self.optimizer_2.load_state_dict(checkpoint['optimizer_2']) self.optimizer_3.load_state_dict(checkpoint['optimizer_3']) start_episode = checkpoint['epochs'] self.steps_done = checkpoint['steps_done'] with open( os.path.join(os.path.dirname(args.checkpoint_file), 'results_pomdp.pkl'), 'rb') as file: plot_dict = pickle.load(file) print_variables['durations'] = plot_dict['durations'] print_variables['rewards'] = plot_dict['rewards'] if args.normalizer_file: if os.path.exists(args.normalizer_file): normalizer.restore_state(args.normalizer_file) if args.memory: if os.path.exists(args.memory): self.memory.load(args.memory) action_space = ActionSpace(dp=0.06, df=10) # Create robot, reset simulation and grasp handle model = load_model_from_path(args.model_path) sim = MjSim(model) sim_param = SimParameter(sim) sim.step() if args.render: viewer = MjViewer(sim) else: viewer = None robot = RobotSim(sim, viewer, sim_param, args.render, self.break_threshold) # Main training loop for ii in range(start_episode, args.epochs): start_time = time.time() self.steps_done += 1 act_sequence = [] if args.sim: sim_params = init_model(robot.mj_sim) robot.reset_simulation() ret = robot.grasp_handle() if not ret: continue # Local memory for current episode localMemory = [] # Get current observation hidden_state_1, cell_state_1 = self.policy_net_1.init_hidden_states( batch_size=1, device=args.device) hidden_state_2, cell_state_2 = self.policy_net_2.init_hidden_states( batch_size=1, device=args.device) hidden_state_3, cell_state_3 = self.policy_net_3.init_hidden_states( batch_size=1, device=args.device) observation_space = TactileObs( robot.get_gripper_xpos(), # 24 robot.get_all_touch_buffer(args.hap_sample)) # 30 x 7 broken_so_far = 0 for t in count(): if not args.quiet and t % 50 == 0: print("Running training episode: {}, iteration: {}".format( ii, t)) # Select action observation = observation_space.get_state() if args.position: observation = observation[6:] if args.shear: indices = np.ones(len(observation), dtype=bool) indices[6:166] = False observation = observation[indices] if args.force: observation = observation[:166] normalizer.observe(observation) observation = normalizer.normalize(observation) action, hidden_state_1, cell_state_1 = self.select_action( observation, hidden_state_1, cell_state_1) # record actions in this epoch act_sequence.append(action) # Perform action delta = action_space.get_action( self.ACTIONS[action])['delta'][:3] target_position = np.add(robot.get_gripper_jpos()[:3], np.array(delta)) target_pose = np.hstack( (target_position, robot.get_gripper_jpos()[3:])) if args.sim: robot.move_joint(target_pose, True, self.gripping_force, hap_sample=args.hap_sample) # Get reward done, num = robot.update_tendons() failure = robot.check_slippage() if num > broken_so_far: reward = num - broken_so_far broken_so_far = num else: reward = 0 # # Add a movement reward # reward -= 0.05 * np.linalg.norm(target_position - robot.get_gripper_jpos()[:3]) / np.linalg.norm(delta) # Observe new state observation_space.update( robot.get_gripper_xpos(), # 24 robot.get_all_touch_buffer(args.hap_sample)) # 30x7 # Set max number of iterations if t >= self.max_iter: done = True # Check if done if not done and not failure: next_state = observation_space.get_state() if args.position: next_state = next_state[6:] if args.shear: indices = np.ones(len(next_state), dtype=bool) indices[6:166] = False next_state = next_state[indices] if args.force: next_state = next_state[:166] normalizer.observe(next_state) next_state = normalizer.normalize(next_state) else: next_state = None # Push new Transition into memory localMemory.append( Transition(observation, action, next_state, reward)) # Optimize the model if t % 10 == 0: loss = self.optimize_model() # if loss: # print_variables['loss'].append(loss.item()) # If we are done, reset the model if done or failure: self.memory.push(localMemory) if failure: print_variables['durations'].append(self.max_iter) else: print_variables['durations'].append(t) print_variables['rewards'].append(broken_so_far) plot_variables(self.figure, print_variables, "Training POMDP") print("Model parameters: {}".format(sim_params)) print("Actions in this epoch are: {}".format(act_sequence)) print("Epoch {} took {}s, total number broken: {}\n\n". format(ii, time.time() - start_time, broken_so_far)) break # Save checkpoints every vew iterations if ii % args.save_freq == 0: save_path = os.path.join( output_dir, 'checkpoint_model_' + str(ii) + '.pth') torch.save( { 'epochs': ii, 'steps_done': self.steps_done, 'policy_net_1': self.policy_net_1.state_dict(), 'policy_net_2': self.policy_net_2.state_dict(), 'policy_net_3': self.policy_net_3.state_dict(), 'optimizer_1': self.optimizer_1.state_dict(), 'optimizer_2': self.optimizer_2.state_dict(), 'optimizer_3': self.optimizer_3.state_dict(), }, save_path) self.memory.save_memory(os.path.join(output_dir, 'memory.pickle')) if args.savefig_path: now = dt.datetime.now() self.figure[0].savefig( args.savefig_path + '{}_{}_{}.png'.format(now.month, now.day, now.hour), format='png') print('Training done') plt.show() return print_variables
def train_POMDP(self): args = self.args ROOT_DIR = os.path.dirname(os.path.dirname( os.path.abspath(__file__))) # corl2019 PARENT_DIR = os.path.dirname(ROOT_DIR) # reserach # Create the output directory if it does not exist output_dir = os.path.join(PARENT_DIR, 'multistep_pomdp', args.output_dir) if not os.path.isdir(output_dir): os.makedirs(output_dir) # write args to file with open(os.path.join(output_dir, 'args.txt'), 'w+') as f: json.dump(args.__dict__, f, indent=2) f.close() # Create our policy net and a target net self.policy_net_1 = DRQN(args.indim, args.outdim).to(args.device) self.policy_net_2 = DRQN(args.indim, args.outdim).to(args.device) self.policy_net_3 = DRQN(args.indim, args.outdim).to(args.device) # Set up the optimizer self.optimizer_1 = optim.RMSprop(self.policy_net_1.parameters()) self.optimizer_2 = optim.RMSprop(self.policy_net_2.parameters()) self.optimizer_3 = optim.RMSprop(self.policy_net_3.parameters()) self.memory = RecurrentMemory(800) self.steps_done = 0 # Setup the state normalizer normalizer = Multimodal_Normalizer(num_inputs=args.indim, device=args.device) print_variables = {'durations': [], 'rewards': [], 'loss': []} start_episode = 0 if args.checkpoint_file: if os.path.exists(args.checkpoint_file): checkpoint = torch.load(args.checkpoint_file) self.policy_net_1.load_state_dict(checkpoint['policy_net_1']) self.policy_net_2.load_state_dict(checkpoint['policy_net_2']) self.policy_net_3.load_state_dict(checkpoint['policy_net_3']) self.optimizer_1.load_state_dict(checkpoint['optimizer_1']) self.optimizer_2.load_state_dict(checkpoint['optimizer_2']) self.optimizer_3.load_state_dict(checkpoint['optimizer_3']) start_episode = checkpoint['epochs'] self.steps_done = checkpoint['steps_done'] with open( os.path.join(os.path.dirname(args.checkpoint_file), 'results_pomdp.pkl'), 'rb') as file: plot_dict = pickle.load(file) print_variables['durations'] = plot_dict['durations'] print_variables['rewards'] = plot_dict['rewards'] if args.normalizer_file: if os.path.exists(args.normalizer_file): normalizer.restore_state(args.normalizer_file) if args.memory: if os.path.exists(args.memory): self.memory.load(args.memory) action_space = ActionSpace(dp=0.06, df=10) # Create robot, reset simulation and grasp handle model = load_model_from_path(args.model_path) sim = MjSim(model) sim_param = SimParameter(sim) sim.step() if args.render: viewer = MjViewer(sim) else: viewer = None robot = RobotSim(sim, viewer, sim_param, args.render, self.break_threshold) # Main training loop for ii in range(start_episode, args.epochs): start_time = time.time() self.steps_done += 1 act_sequence = [] if args.sim: sim_params = init_model(robot.mj_sim) robot.reset_simulation() ret = robot.grasp_handle() if not ret: continue # Local memory for current episode localMemory = [] # Get current observation hidden_state_1, cell_state_1 = self.policy_net_1.init_hidden_states( batch_size=1, device=args.device) hidden_state_2, cell_state_2 = self.policy_net_2.init_hidden_states( batch_size=1, device=args.device) hidden_state_3, cell_state_3 = self.policy_net_3.init_hidden_states( batch_size=1, device=args.device) observation_space = TactileObs( robot.get_gripper_xpos(), # 24 robot.get_all_touch_buffer(args.hap_sample)) # 30 x 7 broken_so_far = 0 for t in count(): if not args.quiet and t % 50 == 0: print("Running training episode: {}, iteration: {}".format( ii, t)) # Select action observation = observation_space.get_state() if args.position: observation = observation[6:] if args.shear: indices = np.ones(len(observation), dtype=bool) indices[6:166] = False observation = observation[indices] if args.force: observation = observation[:166] normalizer.observe(observation) observation = normalizer.normalize(observation) action, hidden_state_1, cell_state_1 = self.select_action( observation, hidden_state_1, cell_state_1) # record actions in this epoch act_sequence.append(action) # Perform action delta = action_space.get_action( self.ACTIONS[action])['delta'][:3] target_position = np.add(robot.get_gripper_jpos()[:3], np.array(delta)) target_pose = np.hstack( (target_position, robot.get_gripper_jpos()[3:])) if args.sim: robot.move_joint(target_pose, True, self.gripping_force, hap_sample=args.hap_sample) # Get reward done, num = robot.update_tendons() failure = robot.check_slippage() if num > broken_so_far: reward = num - broken_so_far broken_so_far = num else: reward = 0 # # Add a movement reward # reward -= 0.05 * np.linalg.norm(target_position - robot.get_gripper_jpos()[:3]) / np.linalg.norm(delta) # Observe new state observation_space.update( robot.get_gripper_xpos(), # 24 robot.get_all_touch_buffer(args.hap_sample)) # 30x7 # Set max number of iterations if t >= self.max_iter: done = True # Check if done if not done and not failure: next_state = observation_space.get_state() if args.position: next_state = next_state[6:] if args.shear: indices = np.ones(len(next_state), dtype=bool) indices[6:166] = False next_state = next_state[indices] if args.force: next_state = next_state[:166] normalizer.observe(next_state) next_state = normalizer.normalize(next_state) else: next_state = None # Push new Transition into memory localMemory.append( Transition(observation, action, next_state, reward)) # Optimize the model if t % 10 == 0: loss = self.optimize_model() # if loss: # print_variables['loss'].append(loss.item()) # If we are done, reset the model if done or failure: self.memory.push(localMemory) if failure: print_variables['durations'].append(self.max_iter) else: print_variables['durations'].append(t) print_variables['rewards'].append(broken_so_far) plot_variables(self.figure, print_variables, "Training POMDP") print("Model parameters: {}".format(sim_params)) print("Actions in this epoch are: {}".format(act_sequence)) print("Epoch {} took {}s, total number broken: {}\n\n". format(ii, time.time() - start_time, broken_so_far)) break # Save checkpoints every vew iterations if ii % args.save_freq == 0: save_path = os.path.join( output_dir, 'checkpoint_model_' + str(ii) + '.pth') torch.save( { 'epochs': ii, 'steps_done': self.steps_done, 'policy_net_1': self.policy_net_1.state_dict(), 'policy_net_2': self.policy_net_2.state_dict(), 'policy_net_3': self.policy_net_3.state_dict(), 'optimizer_1': self.optimizer_1.state_dict(), 'optimizer_2': self.optimizer_2.state_dict(), 'optimizer_3': self.optimizer_3.state_dict(), }, save_path) self.memory.save_memory(os.path.join(output_dir, 'memory.pickle')) if args.savefig_path: now = dt.datetime.now() self.figure[0].savefig( args.savefig_path + '{}_{}_{}.png'.format(now.month, now.day, now.hour), format='png') print('Training done') plt.show() return print_variables
class POMDP: def __init__(self, args): self.args = args self.ACTIONS = ['left', 'right', 'forward', 'backward', 'up', 'down'] # 'open', 'close'] self.P_START = 0.999 self.P_END = 0.05 self.P_DECAY = 500 self.max_iter = args.max_iter self.gripping_force = args.grip_force self.break_threshold = args.break_thresh # Prepare the drawing figure fig, (ax1, ax2) = plt.subplots(1, 2) self.figure = (fig, ax1, ax2) # Function to select an action from our policy or a random one def select_action(self, observation, hidden_state, cell_state): args = self.args sample = random.random() p_threshold = self.P_END + (self.P_START - self.P_END) * math.exp( -1. * self.steps_done / self.P_DECAY) with torch.no_grad(): # t.max(1) will return largest column value of each row. # second column on max result is index of where max element was # found, so we pick action with the larger expected reward. self.tactile_net_1.eval() self.policy_net_1.eval() torch_obs = torch.from_numpy(observation).float().to( args.device).unsqueeze(0) h_tac, c_tac = self.tactile_net_1.init_hidden_states(args.device) tactile_ft = self.tactile_net_1.forward(torch_obs, hidden_state=h_tac, cell_state=c_tac) model_out = self.policy_net_1(tactile_ft.unsqueeze(1), batch_size=1, time_step=1, hidden_state=hidden_state, cell_state=cell_state) out = model_out[0] hidden_state = model_out[1][0] cell_state = model_out[1][1] self.tactile_net_1.train() self.policy_net_1.train() if sample > p_threshold: action = int(torch.argmax(out[0])) return action, hidden_state, cell_state else: return random.randrange(0, args.outdim), hidden_state, cell_state def sample_memory(self): batch = self.memory.sample(self.args.batch_size, self.args.time_step) if not batch: return current_states, actions, rewards, next_states = [], [], [], [] for b in batch: cs, ac, rw, ns = [], [], [], [] for element in b: cs.append(element.state) ac.append(element.action) rw.append(element.reward) ns.append(element.next_state) current_states.append(cs) actions.append(ac) rewards.append(rw) next_states.append(ns) return current_states, actions, rewards, next_states def extract_ft(self, tactile_net, batch): args = self.args h_tac, c_tac = tactile_net.init_hidden_states(args.device) result = [] for b in batch: obs_sequence = [] for item in b: torch_obs = torch.from_numpy(item).float().to( args.device).unsqueeze(0) tactile_ft = tactile_net.forward(torch_obs, hidden_state=h_tac, cell_state=c_tac) obs_sequence.append(tactile_ft) torch_obs_sequence = torch.stack(obs_sequence) result.append(torch_obs_sequence) return torch.stack(result) def bootstrap(self, policy_net, tactile_net, memory_subset): args = self.args if len(self.memory) < (args.batch_size): return current_states, actions, rewards, next_states = memory_subset # padded_current_states, current_lengths = self.pad_batch(current_states) # padded_next_states, next_lengths = self.pad_batch(next_states) # process observation (tactile_obs, img) to 1d tensor of (tactile_obs, feature) # and then stack them to corresponding dimension: (batch_size, time_step, *) current_features = self.extract_ft(tactile_net, current_states) next_features = self.extract_ft(tactile_net, next_states) # convert all to torch tensors actions = torch.from_numpy(np.array(actions)).long().to(args.device) rewards = torch.from_numpy(np.array(rewards)).float().to(args.device) hidden_batch, cell_batch = policy_net.init_hidden_states( args.batch_size, args.device) Q_s, _ = policy_net.forward(current_features, batch_size=args.batch_size, time_step=args.time_step, hidden_state=hidden_batch, cell_state=cell_batch) Q_s_a = Q_s.gather(dim=1, index=actions[:, args.time_step - 1].unsqueeze(dim=1)).squeeze(dim=1) Q_next, _ = policy_net.forward(next_features, batch_size=args.batch_size, time_step=args.time_step, hidden_state=hidden_batch, cell_state=cell_batch) Q_next_max = Q_next.detach().max(dim=1)[0] return Q_s_a, Q_next_max def optimize(self): args = self.args if len(self.memory) < (args.batch_size): return memory_subset = self.sample_memory() _, _, rewards, _ = memory_subset rewards = torch.from_numpy(np.array(rewards)).float().to(args.device) Q_s_a_1, Q_next_max_1 = self.bootstrap(self.policy_net_1, self.tactile_net_1, memory_subset) Q_s_a_2, Q_next_max_2 = self.bootstrap(self.policy_net_2, self.tactile_net_2, memory_subset) Q_next_max = torch.min(Q_next_max_1, Q_next_max_2) # Compute the expected Q values target_values = rewards[:, args.time_step - 1] + (args.gamma * Q_next_max) # Compute Huber loss loss_1 = F.smooth_l1_loss(Q_s_a_1, target_values) loss_2 = F.smooth_l1_loss(Q_s_a_2, target_values) # Optimize the model self.policy_optimizer_1.zero_grad() self.policy_optimizer_2.zero_grad() self.tactile_optimizer_1.zero_grad() self.tactile_optimizer_2.zero_grad() loss_1.backward() loss_2.backward() for param in self.policy_net_1.parameters(): param.grad.data.clamp_(-1, 1) for param in self.policy_net_2.parameters(): param.grad.data.clamp_(-1, 1) for param in self.tactile_net_2.parameters(): param.grad.data.clamp_(-1, 1) for param in self.tactile_net_2.parameters(): param.grad.data.clamp_(-1, 1) self.policy_optimizer_1.step() self.policy_optimizer_2.step() self.tactile_optimizer_1.step() self.tactile_optimizer_2.step() def train_POMDP(self): args = self.args ROOT_DIR = os.path.dirname(os.path.dirname( os.path.abspath(__file__))) # corl2019 PARENT_DIR = os.path.dirname(ROOT_DIR) # reserach # Create the output directory if it does not exist output_dir = os.path.join(PARENT_DIR, 'multistep_pomdp', args.output_dir) if not os.path.isdir(output_dir): os.makedirs(output_dir) # write args to file with open(os.path.join(output_dir, 'args.txt'), 'w+') as f: json.dump(args.__dict__, f, indent=2) f.close() # Create our policy net and a target net self.policy_net_1 = DRQN(args.ftdim, args.outdim).to(args.device) self.policy_net_2 = DRQN(args.ftdim, args.outdim).to(args.device) if args.position: self.tactile_net_1 = TactileNet(args.indim - 6, args.ftdim).to(args.device) self.tactile_net_2 = TactileNet(args.indim - 6, args.ftdim).to(args.device) elif args.force: self.tactile_net_1 = TactileNet(args.indim - 390, args.ftdim).to(args.device) self.tactile_net_2 = TactileNet(args.indim - 390, args.ftdim).to(args.device) else: self.tactile_net_1 = TactileNet(args.indim, args.ftdim).to(args.device) self.tactile_net_2 = TactileNet(args.indim, args.ftdim).to(args.device) # Set up the optimizer self.policy_optimizer_1 = optim.RMSprop(self.policy_net_1.parameters(), lr=args.lr) self.policy_optimizer_2 = optim.RMSprop(self.policy_net_2.parameters(), lr=args.lr) self.tactile_optimizer_1 = optim.RMSprop( self.tactile_net_1.parameters(), lr=args.lr) self.tactile_optimizer_2 = optim.RMSprop( self.tactile_net_2.parameters(), lr=args.lr) self.memory = RecurrentMemory(800) self.steps_done = 0 # Setup the state normalizer normalizer = Multimodal_Normalizer(num_inputs=args.indim, device=args.device) print_variables = {'durations': [], 'rewards': [], 'loss': []} start_episode = 0 if args.weight_policy: if os.path.exists(args.weight_policy): checkpoint = torch.load(args.weight_policy) self.policy_net_1.load_state_dict(checkpoint['policy_net_1']) self.policy_net_2.load_state_dict(checkpoint['policy_net_2']) self.policy_optimizer_1.load_state_dict( checkpoint['policy_optimizer_1']) self.policy_optimizer_2.load_state_dict( checkpoint['policy_optimizer_2']) start_episode = checkpoint['epochs'] self.steps_done = checkpoint['steps_done'] with open( os.path.join(os.path.dirname(args.weight_policy), 'results_pomdp.pkl'), 'rb') as file: plot_dict = pickle.load(file) print_variables['durations'] = plot_dict['durations'] print_variables['rewards'] = plot_dict['rewards'] if args.normalizer_file: if os.path.exists(args.normalizer_file): normalizer.restore_state(args.normalizer_file) if args.memory: if os.path.exists(args.memory): self.memory.load(args.memory) if args.weight_tactile: checkpoint = torch.load(args.weight_tactile) self.tactile_net_1.load_state_dict(checkpoint['tactile_net_1']) self.tactile_optimizer_1.load_state_dict( checkpoint['tactile_optimizer_1']) self.tactile_net_2.load_state_dict(checkpoint['tactile_net_2']) self.tactile_optimizer_2.load_state_dict( checkpoint['tactile_optimizer_2']) action_space = ActionSpace(dp=0.06, df=10) # Create robot, reset simulation and grasp handle model = load_model_from_path(args.model_path) sim = MjSim(model) sim_param = SimParameter(sim) sim.step() if args.render: viewer = MjViewer(sim) else: viewer = None robot = RobotSim(sim, viewer, sim_param, args.render, self.break_threshold) tactile_obs_space = TactileObs( robot.get_gripper_xpos(), # 24 robot.get_all_touch_buffer(args.hap_sample)) # 30 x 6 # Main training loop for ii in range(start_episode, args.epochs): self.steps_done += 1 start_time = time.time() act_sequence = [] act_length = [] velcro_params = init_model(robot.mj_sim) robot.reset_simulation() ret = robot.grasp_handle() if not ret: continue # Local memory for current episode localMemory = [] # Get current observation hidden_state_1, cell_state_1 = self.policy_net_1.init_hidden_states( batch_size=1, device=args.device) hidden_state_2, cell_state_2 = self.policy_net_2.init_hidden_states( batch_size=1, device=args.device) broken_so_far = 0 # pick a random action initially action = random.randrange(0, 5) current_state = None next_state = None t = 0 while t < args.max_iter: if not args.quiet and t == 0: print("Running training episode: {}".format(ii, t)) if args.position: multistep_obs = np.empty((0, args.indim - 6)) elif args.force: multistep_obs = np.empty((0, args.indim - 390)) else: multistep_obs = np.empty((0, args.indim)) prev_action = action for k in range(args.len_ub): # Observe tactile features and stack them tactile_obs = tactile_obs_space.get_state() normalizer.observe(tactile_obs) tactile_obs = normalizer.normalize(tactile_obs) if args.position: tactile_obs = tactile_obs[6:] elif args.force: tactile_obs = tactile_obs[:6] multistep_obs = np.vstack((multistep_obs, tactile_obs)) # current jpos current_pos = robot.get_gripper_jpos()[:3] # Perform action delta = action_space.get_action( self.ACTIONS[action])['delta'][:3] target_position = np.add(robot.get_gripper_jpos()[:3], np.array(delta)) target_pose = np.hstack( (target_position, robot.get_gripper_jpos()[3:])) robot.move_joint(target_pose, True, self.gripping_force, hap_sample=args.hap_sample) # Observe new state tactile_obs_space.update( robot.get_gripper_xpos(), # 24 robot.get_all_touch_buffer(args.hap_sample)) # 30x6 displacement = la.norm(robot.get_gripper_jpos()[:3] - current_pos) if displacement / 0.06 < 0.7: break # input stiched multi-step tactile observation into tactile-net to generate tactile feature action, hidden_state_1, cell_state_1 = self.select_action( multistep_obs, hidden_state_1, cell_state_1) if t == 0: next_state = multistep_obs.copy() else: current_state = next_state.copy() next_state = multistep_obs.copy() # record actions in this epoch act_sequence.append(prev_action) act_length.append(k) # Get reward done, num = robot.update_tendons() failure = robot.check_slippage() if num > broken_so_far: reward = num - broken_so_far broken_so_far = num else: if failure: reward = -20 else: reward = 0 t += k + 1 # Set max number of iterations if t >= self.max_iter: done = True if done or failure: next_state = None # Push new Transition into memory if t > k + 1: localMemory.append( Transition(current_state, prev_action, next_state, reward)) # Optimize the model if self.steps_done % 10 == 0: self.optimize() # If we are done, reset the model if done or failure: self.memory.push(localMemory) if failure: print_variables['durations'].append(self.max_iter) else: print_variables['durations'].append(t) print_variables['rewards'].append(broken_so_far) plot_variables(self.figure, print_variables, "Training POMDP") print("Model parameters: {}".format(velcro_params)) print( "{} of Actions in this epoch are: {} \n Action length are: {}" .format(len(act_sequence), act_sequence, act_length)) print("Epoch {} took {}s, total number broken: {}\n\n". format(ii, time.time() - start_time, broken_so_far)) break # Save checkpoints every vew iterations if ii % args.save_freq == 0: save_path = os.path.join(output_dir, 'policy_' + str(ii) + '.pth') torch.save( { 'epochs': ii, 'steps_done': self.steps_done, 'policy_net_1': self.policy_net_1.state_dict(), 'policy_net_2': self.policy_net_2.state_dict(), 'policy_optimizer_1': self.policy_optimizer_1.state_dict(), 'policy_optimizer_2': self.policy_optimizer_2.state_dict(), }, save_path) save_path = os.path.join(output_dir, 'tactile_' + str(ii) + '.pth') torch.save( { 'tactile_net_1': self.tactile_net_1.state_dict(), 'tactile_net_2': self.tactile_net_2.state_dict(), 'tactile_optimizer_1': self.tactile_optimizer_1.state_dict(), 'tactile_optimizer_2': self.tactile_optimizer_2.state_dict(), }, save_path) write_results(os.path.join(output_dir, 'results_pomdp.pkl'), print_variables) self.memory.save_memory( os.path.join(output_dir, 'memory.pickle')) if args.savefig_path: now = dt.datetime.now() self.figure[0].savefig( args.savefig_path + '{}_{}_{}.png'.format(now.month, now.day, now.hour), format='png') print('Training done') plt.show() return print_variables
def train_POMDP(self): args = self.args ROOT_DIR = os.path.dirname(os.path.dirname( os.path.abspath(__file__))) # corl2019 PARENT_DIR = os.path.dirname(ROOT_DIR) # reserach # Create the output directory if it does not exist output_dir = os.path.join(PARENT_DIR, 'multistep_pomdp', args.output_dir) if not os.path.isdir(output_dir): os.makedirs(output_dir) # write args to file with open(os.path.join(output_dir, 'args.txt'), 'w+') as f: json.dump(args.__dict__, f, indent=2) f.close() # Create our policy net and a target net self.policy_net_1 = DRQN(args.ftdim, args.outdim).to(args.device) self.policy_net_2 = DRQN(args.ftdim, args.outdim).to(args.device) if args.position: self.tactile_net_1 = TactileNet(args.indim - 6, args.ftdim).to(args.device) self.tactile_net_2 = TactileNet(args.indim - 6, args.ftdim).to(args.device) elif args.force: self.tactile_net_1 = TactileNet(args.indim - 390, args.ftdim).to(args.device) self.tactile_net_2 = TactileNet(args.indim - 390, args.ftdim).to(args.device) else: self.tactile_net_1 = TactileNet(args.indim, args.ftdim).to(args.device) self.tactile_net_2 = TactileNet(args.indim, args.ftdim).to(args.device) # Set up the optimizer self.policy_optimizer_1 = optim.RMSprop(self.policy_net_1.parameters(), lr=args.lr) self.policy_optimizer_2 = optim.RMSprop(self.policy_net_2.parameters(), lr=args.lr) self.tactile_optimizer_1 = optim.RMSprop( self.tactile_net_1.parameters(), lr=args.lr) self.tactile_optimizer_2 = optim.RMSprop( self.tactile_net_2.parameters(), lr=args.lr) self.memory = RecurrentMemory(800) self.steps_done = 0 # Setup the state normalizer normalizer = Multimodal_Normalizer(num_inputs=args.indim, device=args.device) print_variables = {'durations': [], 'rewards': [], 'loss': []} start_episode = 0 if args.weight_policy: if os.path.exists(args.weight_policy): checkpoint = torch.load(args.weight_policy) self.policy_net_1.load_state_dict(checkpoint['policy_net_1']) self.policy_net_2.load_state_dict(checkpoint['policy_net_2']) self.policy_optimizer_1.load_state_dict( checkpoint['policy_optimizer_1']) self.policy_optimizer_2.load_state_dict( checkpoint['policy_optimizer_2']) start_episode = checkpoint['epochs'] self.steps_done = checkpoint['steps_done'] with open( os.path.join(os.path.dirname(args.weight_policy), 'results_pomdp.pkl'), 'rb') as file: plot_dict = pickle.load(file) print_variables['durations'] = plot_dict['durations'] print_variables['rewards'] = plot_dict['rewards'] if args.normalizer_file: if os.path.exists(args.normalizer_file): normalizer.restore_state(args.normalizer_file) if args.memory: if os.path.exists(args.memory): self.memory.load(args.memory) if args.weight_tactile: checkpoint = torch.load(args.weight_tactile) self.tactile_net_1.load_state_dict(checkpoint['tactile_net_1']) self.tactile_optimizer_1.load_state_dict( checkpoint['tactile_optimizer_1']) self.tactile_net_2.load_state_dict(checkpoint['tactile_net_2']) self.tactile_optimizer_2.load_state_dict( checkpoint['tactile_optimizer_2']) action_space = ActionSpace(dp=0.06, df=10) # Create robot, reset simulation and grasp handle model = load_model_from_path(args.model_path) sim = MjSim(model) sim_param = SimParameter(sim) sim.step() if args.render: viewer = MjViewer(sim) else: viewer = None robot = RobotSim(sim, viewer, sim_param, args.render, self.break_threshold) tactile_obs_space = TactileObs( robot.get_gripper_xpos(), # 24 robot.get_all_touch_buffer(args.hap_sample)) # 30 x 6 # Main training loop for ii in range(start_episode, args.epochs): self.steps_done += 1 start_time = time.time() act_sequence = [] act_length = [] velcro_params = init_model(robot.mj_sim) robot.reset_simulation() ret = robot.grasp_handle() if not ret: continue # Local memory for current episode localMemory = [] # Get current observation hidden_state_1, cell_state_1 = self.policy_net_1.init_hidden_states( batch_size=1, device=args.device) hidden_state_2, cell_state_2 = self.policy_net_2.init_hidden_states( batch_size=1, device=args.device) broken_so_far = 0 # pick a random action initially action = random.randrange(0, 5) current_state = None next_state = None t = 0 while t < args.max_iter: if not args.quiet and t == 0: print("Running training episode: {}".format(ii, t)) if args.position: multistep_obs = np.empty((0, args.indim - 6)) elif args.force: multistep_obs = np.empty((0, args.indim - 390)) else: multistep_obs = np.empty((0, args.indim)) prev_action = action for k in range(args.len_ub): # Observe tactile features and stack them tactile_obs = tactile_obs_space.get_state() normalizer.observe(tactile_obs) tactile_obs = normalizer.normalize(tactile_obs) if args.position: tactile_obs = tactile_obs[6:] elif args.force: tactile_obs = tactile_obs[:6] multistep_obs = np.vstack((multistep_obs, tactile_obs)) # current jpos current_pos = robot.get_gripper_jpos()[:3] # Perform action delta = action_space.get_action( self.ACTIONS[action])['delta'][:3] target_position = np.add(robot.get_gripper_jpos()[:3], np.array(delta)) target_pose = np.hstack( (target_position, robot.get_gripper_jpos()[3:])) robot.move_joint(target_pose, True, self.gripping_force, hap_sample=args.hap_sample) # Observe new state tactile_obs_space.update( robot.get_gripper_xpos(), # 24 robot.get_all_touch_buffer(args.hap_sample)) # 30x6 displacement = la.norm(robot.get_gripper_jpos()[:3] - current_pos) if displacement / 0.06 < 0.7: break # input stiched multi-step tactile observation into tactile-net to generate tactile feature action, hidden_state_1, cell_state_1 = self.select_action( multistep_obs, hidden_state_1, cell_state_1) if t == 0: next_state = multistep_obs.copy() else: current_state = next_state.copy() next_state = multistep_obs.copy() # record actions in this epoch act_sequence.append(prev_action) act_length.append(k) # Get reward done, num = robot.update_tendons() failure = robot.check_slippage() if num > broken_so_far: reward = num - broken_so_far broken_so_far = num else: if failure: reward = -20 else: reward = 0 t += k + 1 # Set max number of iterations if t >= self.max_iter: done = True if done or failure: next_state = None # Push new Transition into memory if t > k + 1: localMemory.append( Transition(current_state, prev_action, next_state, reward)) # Optimize the model if self.steps_done % 10 == 0: self.optimize() # If we are done, reset the model if done or failure: self.memory.push(localMemory) if failure: print_variables['durations'].append(self.max_iter) else: print_variables['durations'].append(t) print_variables['rewards'].append(broken_so_far) plot_variables(self.figure, print_variables, "Training POMDP") print("Model parameters: {}".format(velcro_params)) print( "{} of Actions in this epoch are: {} \n Action length are: {}" .format(len(act_sequence), act_sequence, act_length)) print("Epoch {} took {}s, total number broken: {}\n\n". format(ii, time.time() - start_time, broken_so_far)) break # Save checkpoints every vew iterations if ii % args.save_freq == 0: save_path = os.path.join(output_dir, 'policy_' + str(ii) + '.pth') torch.save( { 'epochs': ii, 'steps_done': self.steps_done, 'policy_net_1': self.policy_net_1.state_dict(), 'policy_net_2': self.policy_net_2.state_dict(), 'policy_optimizer_1': self.policy_optimizer_1.state_dict(), 'policy_optimizer_2': self.policy_optimizer_2.state_dict(), }, save_path) save_path = os.path.join(output_dir, 'tactile_' + str(ii) + '.pth') torch.save( { 'tactile_net_1': self.tactile_net_1.state_dict(), 'tactile_net_2': self.tactile_net_2.state_dict(), 'tactile_optimizer_1': self.tactile_optimizer_1.state_dict(), 'tactile_optimizer_2': self.tactile_optimizer_2.state_dict(), }, save_path) write_results(os.path.join(output_dir, 'results_pomdp.pkl'), print_variables) self.memory.save_memory( os.path.join(output_dir, 'memory.pickle')) if args.savefig_path: now = dt.datetime.now() self.figure[0].savefig( args.savefig_path + '{}_{}_{}.png'.format(now.month, now.day, now.hour), format='png') print('Training done') plt.show() return print_variables