def main(arglist): game_name = arglist.game_name # 'abs', 'one' reward_type = arglist.reward_type p = arglist.p agent_num = arglist.n u_range = 1. k = 0 print(arglist.aux, 'arglist.aux') model_names_setting = arglist.model_names_setting.split('_') model_names = [model_names_setting[0]] + [model_names_setting[1]] * (agent_num - 1) model_name = '_'.join(model_names) path_prefix = game_name if game_name == 'pbeauty': env = PBeautyGame(agent_num=agent_num, reward_type=reward_type, p=p) path_prefix = game_name + '-' + reward_type + '-' + str(p) elif 'matrix' in game_name: matrix_game_name = game_name.split('-')[-1] repeated = arglist.repeat max_step = arglist.max_path_length memory = arglist.memory env = MatrixGame(game=matrix_game_name, agent_num=agent_num, action_num=2, repeated=repeated, max_step=max_step, memory=memory, discrete_action=False, tuple_obs=False) path_prefix = '{}-{}-{}-{}'.format(game_name, repeated, max_step, memory) elif 'particle' in game_name: particle_game_name = game_name.split('-')[-1] env, agent_num, model_name, model_names = get_particle_game(particle_game_name, arglist) now = datetime.datetime.now() timestamp = now.strftime('%Y-%m-%d %H:%M:%S.%f %Z') if 'CG' in model_name: model_name = model_name + '-{}'.format(arglist.mu) if not arglist.aux: model_name = model_name + '-{}'.format(arglist.aux) suffix = '{}/{}/{}/{}'.format(path_prefix, agent_num, model_name, timestamp) print(suffix) logger.add_tabular_output('./log/{}.csv'.format(suffix)) snapshot_dir = './snapshot/{}'.format(suffix) policy_dir = './policy/{}'.format(suffix) os.makedirs(snapshot_dir, exist_ok=True) os.makedirs(policy_dir, exist_ok=True) logger.set_snapshot_dir(snapshot_dir) agents = [] M = arglist.hidden_size batch_size = arglist.batch_size sampler = MASampler(agent_num=agent_num, joint=True, max_path_length=30, min_pool_size=100, batch_size=batch_size) base_kwargs = { 'sampler': sampler, 'epoch_length': 1, 'n_epochs': arglist.max_steps, 'n_train_repeat': 1, 'eval_render': True, 'eval_n_episodes': 10 } with U.single_threaded_session(): for i, model_name in enumerate(model_names): if 'PR2AC' in model_name: k = int(model_name[-1]) g = False mu = arglist.mu if 'G' in model_name: g = True agent = pr2ac_agent(model_name, i, env, M, u_range, base_kwargs, k=k, g=g, mu=mu, game_name=game_name, aux=arglist.aux) elif model_name == 'MASQL': agent = masql_agent(model_name, i, env, M, u_range, base_kwargs, game_name=game_name) else: if model_name == 'DDPG': joint = False opponent_modelling = False elif model_name == 'MADDPG': joint = True opponent_modelling = False elif model_name == 'DDPG-OM' or model_name == 'DDPG-ToM': joint = True opponent_modelling = True agent = ddpg_agent(joint, opponent_modelling, model_names, i, env, M, u_range, base_kwargs, game_name=game_name) agents.append(agent) sampler.initialize(env, agents) for agent in agents: agent._init_training() gt.rename_root('MARLAlgorithm') gt.reset() gt.set_def_unique(False) initial_exploration_done = False # noise = .1 noise = 1. alpha = .5 for agent in agents: try: agent.policy.set_noise_level(noise) except: pass for epoch in gt.timed_for(range(base_kwargs['n_epochs'] + 1)): logger.push_prefix('Epoch #%d | ' % epoch) if epoch % 1 == 0: print(suffix) for t in range(base_kwargs['epoch_length']): # TODO.code consolidation: Add control interval to sampler if not initial_exploration_done: if epoch >= 1000: initial_exploration_done = True sampler.sample() # print('Sampling') if not initial_exploration_done: continue gt.stamp('sample') # print('Sample Done') if epoch == base_kwargs['n_epochs']: noise = 0.1 for agent in agents: try: agent.policy.set_noise_level(noise) except: pass # alpha = .1 if epoch > base_kwargs['n_epochs'] / 10: noise = 0.1 for agent in agents: try: agent.policy.set_noise_level(noise) except: pass # alpha = .1 if epoch > base_kwargs['n_epochs'] / 5: noise = 0.05 for agent in agents: try: agent.policy.set_noise_level(noise) except: pass if epoch > base_kwargs['n_epochs'] / 6: noise = 0.01 for agent in agents: try: agent.policy.set_noise_level(noise) except: pass for j in range(base_kwargs['n_train_repeat']): batch_n = [] recent_batch_n = [] indices = None receent_indices = None for i, agent in enumerate(agents): if i == 0: batch = agent.pool.random_batch(batch_size) indices = agent.pool.indices receent_indices = list(range(agent.pool._top-batch_size, agent.pool._top)) batch_n.append(agent.pool.random_batch_by_indices(indices)) recent_batch_n.append(agent.pool.random_batch_by_indices(receent_indices)) # print(len(batch_n)) target_next_actions_n = [] try: for agent, batch in zip(agents, batch_n): target_next_actions_n.append(agent._target_policy.get_actions(batch['next_observations'])) except: pass opponent_actions_n = np.array([batch['actions'] for batch in batch_n]) recent_opponent_actions_n = np.array([batch['actions'] for batch in recent_batch_n]) ####### figure out recent_opponent_observations_n = [] for batch in recent_batch_n: recent_opponent_observations_n.append(batch['observations']) current_actions = [agents[i]._policy.get_actions(batch_n[i]['next_observations'])[0][0] for i in range(agent_num)] all_actions_k = [] for i, agent in enumerate(agents): if isinstance(agent, MAVBAC): if agent._k > 0: batch_actions_k = agent._policy.get_all_actions(batch_n[i]['next_observations']) actions_k = [a[0][0] for a in batch_actions_k] all_actions_k.append(';'.join(list(map(str, actions_k)))) if len(all_actions_k) > 0: with open('{}/all_actions.csv'.format(policy_dir), 'a') as f: f.write(','.join(list(map(str, all_actions_k))) + '\n') with open('{}/policy.csv'.format(policy_dir), 'a') as f: f.write(','.join(list(map(str, current_actions)))+'\n') # print('============') for i, agent in enumerate(agents): try: batch_n[i]['next_actions'] = deepcopy(target_next_actions_n[i]) except: pass batch_n[i]['opponent_actions'] = np.reshape(np.delete(deepcopy(opponent_actions_n), i, 0), (-1, agent._opponent_action_dim)) if agent.joint: if agent.opponent_modelling: batch_n[i]['recent_opponent_observations'] = recent_opponent_observations_n[i] batch_n[i]['recent_opponent_actions'] = np.reshape(np.delete(deepcopy(recent_opponent_actions_n), i, 0), (-1, agent._opponent_action_dim)) batch_n[i]['opponent_next_actions'] = agent.opponent_policy.get_actions(batch_n[i]['next_observations']) else: batch_n[i]['opponent_next_actions'] = np.reshape(np.delete(deepcopy(target_next_actions_n), i, 0), (-1, agent._opponent_action_dim)) if isinstance(agent, MAVBAC) or isinstance(agent, MASQL): agent._do_training(iteration=t + epoch * agent._epoch_length, batch=batch_n[i], annealing=alpha) else: agent._do_training(iteration=t + epoch * agent._epoch_length, batch=batch_n[i]) gt.stamp('train') # self._evaluate(epoch) # for agent in agents: # params = agent.get_snapshot(epoch) # logger.save_itr_params(epoch, params) # times_itrs = gt.get_times().stamps.itrs # # eval_time = times_itrs['eval'][-1] if epoch > 1 else 0 # total_time = gt.get_times().total # logger.record_tabular('time-train', times_itrs['train'][-1]) # logger.record_tabular('time-eval', eval_time) # logger.record_tabular('time-sample', times_itrs['sample'][-1]) # logger.record_tabular('time-total', total_time) # logger.record_tabular('epoch', epoch) # sampler.log_diagnostics() # logger.dump_tabular(with_prefix=False) logger.pop_prefix() sampler.terminate()
def main(arglist): game_name = arglist.game_name # 'abs', 'one' reward_type = arglist.reward_type p = arglist.p agent_num = arglist.n u_range = 1. k = 0 print(arglist.aux, 'arglist.aux') model_names_setting = arglist.model_names_setting.split('_') model_names = [model_names_setting[0]] + [model_names_setting[1]] * (agent_num - 1) model_name = '_'.join(model_names) path_prefix = game_name if game_name == 'pbeauty': env = PBeautyGame(agent_num=agent_num, reward_type=reward_type, p=p) path_prefix = game_name + '-' + reward_type + '-' + str(p) elif 'matrix' in game_name: matrix_game_name = game_name.split('-')[-1] repeated = arglist.repeat max_step = arglist.max_path_length memory = arglist.memory env = MatrixGame(game=matrix_game_name, agent_num=agent_num, action_num=2, repeated=repeated, max_step=max_step, memory=memory, discrete_action=False, tuple_obs=False) path_prefix = '{}-{}-{}-{}'.format(game_name, repeated, max_step, memory) elif 'diff' in game_name: diff_game_name = game_name.split('-')[-1] agent_num = 2 env = DifferentialGame(diff_game_name, agent_num) elif 'particle' in game_name: particle_game_name = game_name.split('-')[-1] env, agent_num, model_name, model_names = get_particle_game(particle_game_name, arglist) elif 'alvi' in game_name: mat_scene = -1 # Create environment and scenario characteristics env, scn = make_env(arglist.scenario, arglist, arglist.benchmark, mat_scene=mat_scene) now = datetime.datetime.now() timestamp = now.strftime('%Y-%m-%d %H:%M:%S.%f %Z') if 'CG' in model_name: model_name = model_name + '-{}'.format(arglist.mu) if not arglist.aux: model_name = model_name + '-{}'.format(arglist.aux) suffix = '{}/{}/{}/{}'.format(path_prefix, agent_num, model_name, timestamp) print(suffix) logger.add_tabular_output('./log/{}.csv'.format(suffix)) snapshot_dir = './snapshot/{}'.format(suffix) policy_dir = './policy/{}'.format(suffix) os.makedirs(snapshot_dir, exist_ok=True) os.makedirs(policy_dir, exist_ok=True) logger.set_snapshot_dir(snapshot_dir) agents = [] M = arglist.hidden_size batch_size = arglist.batch_size sampler = MASampler(agent_num=agent_num, joint=True, global_reward=arglist.global_reward, max_path_length=25, min_pool_size=100, batch_size=batch_size) base_kwargs = { 'sampler': sampler, 'epoch_length': 1, 'n_epochs': arglist.max_steps, 'n_train_repeat': 1, 'eval_render': True, 'eval_n_episodes': 10 } with U.single_threaded_session(): for i, model_name in enumerate(model_names): if 'PR2AC' in model_name: k = int(model_name[-1]) g = False mu = arglist.mu if 'G' in model_name: g = True agent = pr2ac_agent(model_name, i, env, M, u_range, base_kwargs, k=k, g=g, mu=mu, game_name=game_name, aux=arglist.aux) elif model_name == 'MASQL': agent = masql_agent(model_name, i, env, M, u_range, base_kwargs, game_name=game_name) elif model_name == 'MASAC': agent = masac_agent(model_name, i, env, M, u_range, base_kwargs, game_name=game_name) elif model_name == 'ROMMEO': agent = rom_agent(model_name, i, env, M, u_range, base_kwargs, game_name=game_name) else: if model_name == 'DDPG': joint = False opponent_modelling = False elif model_name == 'MADDPG': joint = True opponent_modelling = False elif model_name == 'DDPG-OM': joint = True opponent_modelling = True agent = ddpg_agent(joint, opponent_modelling, model_names, i, env, M, u_range, base_kwargs, game_name=game_name) agents.append(agent) sampler.initialize(env, agents) for agent in agents: agent._init_training() gt.rename_root('MARLAlgorithm') gt.reset() gt.set_def_unique(False) initial_exploration_done = False # noise = .1 noise = .5 alpha = .1 for agent in agents: try: agent.policy.set_noise_level(noise) except: pass # alpha = .5 for steps in gt.timed_for(range(base_kwargs['n_epochs'] + 1)): # alpha = .1 + np.exp(-0.1 * max(steps-10, 0)) * 500. logger.push_prefix('Epoch #%d | ' % steps) if steps % (25*1000) == 0: print(suffix) for t in range(base_kwargs['epoch_length']): # TODO.code consolidation: Add control interval to sampler if not initial_exploration_done: if steps >= 1000: initial_exploration_done = True sampler.sample() if not initial_exploration_done: continue gt.stamp('sample') print('Sample Done') if steps == 1000: noise = 0.1 for agent in agents: try: agent.policy.set_noise_level(noise) except: pass # alpha = 10. if steps == 2000: noise = 0.1 for agent in agents: try: agent.policy.set_noise_level(noise) except: pass # alpha = .1 if steps == 3000: noise = 0.05 for agent in agents: try: agent.policy.set_noise_level(noise) except: pass if steps > base_kwargs['n_epochs'] / 6: noise = 0.01 for agent in agents: try: agent.policy.set_noise_level(noise) except: pass if steps % arglist.training_interval != 0: continue for j in range(base_kwargs['n_train_repeat']): batch_n = [] recent_batch_n = [] indices = None receent_indices = None for i, agent in enumerate(agents): if i == 0: batch = agent.pool.random_batch(batch_size) indices = agent.pool.indices receent_indices = list(range(agent.pool._top-batch_size, agent.pool._top)) batch_n.append(agent.pool.random_batch_by_indices(indices)) recent_batch_n.append(agent.pool.random_batch_by_indices(receent_indices)) # print(len(batch_n)) target_next_actions_n = [] # try: all_obs = np.array(np.concatenate([batch['observations'] for batch in batch_n], axis=-1)) all_next_obs = np.array(np.concatenate([batch['next_observations'] for batch in batch_n], axis=-1)) # print(all_obs[0]) for batch in batch_n: # print('making all obs') batch['all_observations'] = deepcopy(all_obs) batch['all_next_observations'] = deepcopy(all_next_obs) opponent_current_actions_n = [] for agent, batch in zip(agents, batch_n): target_next_actions_n.append(agent.target_policy.get_actions(batch['next_observations'])) opponent_current_actions_n.append(agent.policy.get_actions(batch['observations'])) for i, agent in enumerate(agents): batch_n[i]['opponent_current_actions'] = np.reshape( np.delete(deepcopy(opponent_current_actions_n), i, 0), (-1, agent._opponent_action_dim)) # except: # pass opponent_actions_n = np.array([batch['actions'] for batch in batch_n]) recent_opponent_actions_n = np.array([batch['actions'] for batch in recent_batch_n]) ####### figure out recent_opponent_observations_n = [] for batch in recent_batch_n: recent_opponent_observations_n.append(batch['observations']) current_actions = [agents[i].policy.get_actions(batch_n[i]['next_observations'])[0][0] for i in range(agent_num)] all_actions_k = [] for i, agent in enumerate(agents): if isinstance(agent, MAVBAC): if agent._k > 0: batch_actions_k = agent.policy.get_all_actions(batch_n[i]['next_observations']) actions_k = [a[0][0] for a in batch_actions_k] all_actions_k.append(';'.join(list(map(str, actions_k)))) if len(all_actions_k) > 0: with open('{}/all_actions.csv'.format(policy_dir), 'a') as f: f.write(','.join(list(map(str, all_actions_k))) + '\n') with open('{}/policy.csv'.format(policy_dir), 'a') as f: f.write(','.join(list(map(str, current_actions)))+'\n') # print('============') for i, agent in enumerate(agents): try: batch_n[i]['next_actions'] = deepcopy(target_next_actions_n[i]) except: pass batch_n[i]['opponent_actions'] = np.reshape(np.delete(deepcopy(opponent_actions_n), i, 0), (-1, agent._opponent_action_dim)) if agent.joint: if agent.opponent_modelling: batch_n[i]['recent_opponent_observations'] = recent_opponent_observations_n[i] batch_n[i]['recent_opponent_actions'] = np.reshape(np.delete(deepcopy(recent_opponent_actions_n), i, 0), (-1, agent._opponent_action_dim)) batch_n[i]['opponent_next_actions'] = agent.opponent_policy.get_actions(batch_n[i]['next_observations']) else: batch_n[i]['opponent_next_actions'] = np.reshape(np.delete(deepcopy(target_next_actions_n), i, 0), (-1, agent._opponent_action_dim)) if isinstance(agent, MAVBAC) or isinstance(agent, MASQL) or isinstance(agent, ROMMEO): agent._do_training(iteration=t + steps * agent._epoch_length, batch=batch_n[i], annealing=alpha) else: agent._do_training(iteration=t + steps * agent._epoch_length, batch=batch_n[i]) gt.stamp('train') sampler.terminate()
def objective(trail, arglist): config = tf.ConfigProto() config.gpu_options.allow_growth = True # dynamically grow the memory used on the GPU sess = tf.Session(config=config) set_session(sess) game_name = arglist.game_name # 'abs', 'one' reward_type = arglist.reward_type p = arglist.p agent_num = arglist.n u_range = 1. k = 0 print(arglist.aux, 'arglist.aux') model_names_setting = arglist.model_names_setting.split('_') model_names = [model_names_setting[0]] model_name = '_'.join(model_names) path_prefix = game_name if game_name == 'pbeauty': env = PBeautyGame(agent_num=agent_num, reward_type=reward_type, p=p) path_prefix = game_name + '-' + reward_type + '-' + str(p) elif 'matrix' in game_name: matrix_game_name = game_name.split('-')[-1] repeated = arglist.repeat max_step = arglist.max_path_length memory = arglist.memory env = MatrixGame(game=matrix_game_name, agent_num=agent_num, action_num=2, repeated=repeated, max_step=max_step, memory=memory, discrete_action=False, tuple_obs=False) path_prefix = '{}-{}-{}-{}'.format(game_name, repeated, max_step, memory) elif 'diff' in game_name: diff_game_name = game_name.split('-')[-1] s2 = arglist.s2 x2 = arglist.x2 y2 = arglist.y2 con = arglist.con env = JDifferentialGame(diff_game_name, 3, x2, y2, s2, con) agent_num = 1 elif 'particle' in game_name: particle_game_name = game_name.split('-')[-1] env, agent_num, model_name, model_names = get_particle_game( particle_game_name, arglist) now = datetime.datetime.now() timestamp = now.strftime('%Y-%m-%d %H:%M:%S.%f %Z') if 'CG' in model_name: model_name = model_name + '-{}'.format(arglist.mu) if not arglist.aux: model_name = model_name + '-{}'.format(arglist.aux) suffix = '{}/{}/{}/{}'.format(path_prefix, agent_num, model_name, timestamp) print(suffix) logger.add_tabular_output('./log/{}.csv'.format(suffix)) snapshot_dir = './snapshot/{}'.format(suffix) policy_dir = './policy/{}'.format(suffix) os.makedirs(snapshot_dir, exist_ok=True) os.makedirs(policy_dir, exist_ok=True) logger.set_snapshot_dir(snapshot_dir) agents = [] M = arglist.hidden_size batch_size = arglist.batch_size sampler = JSampler(agent_num=agent_num, joint=True, global_reward=arglist.global_reward, max_path_length=25, min_pool_size=100, batch_size=batch_size, do_nego=arglist.do_nego) base_kwargs = { 'sampler': sampler, 'epoch_length': 1, 'n_epochs': arglist.max_steps, 'n_train_repeat': 1, 'eval_render': True, 'eval_n_episodes': 10 } _alpha = trail.suggest_float("alpha", 1e-1, 10, log=True) lr = trail.suggest_float("lr", 1e-4, 1e-1, log=True) n_pars = trail.suggest_int("n_pars", 16, 64, log=True) result = 0. with U.single_threaded_session(): for i, model_name in enumerate(model_names): if 'PR2AC' in model_name: k = int(model_name[-1]) g = False mu = arglist.mu if 'G' in model_name: g = True agent = pr2ac_agent(model_name, i, env, M, u_range, base_kwargs, lr=lr, n_pars=n_pars, k=k, g=g, mu=mu, game_name=game_name, aux=arglist.aux) elif model_name == 'MASQL': agent = masql_agent(model_name, i, env, M, u_range, base_kwargs, lr=lr, n_pars=n_pars, game_name=game_name) elif model_name == 'JSQL': agent = jsql_agent(model_name, i, env, M, u_range, base_kwargs, lr=lr, n_pars=n_pars, game_name=game_name) elif model_name == 'GPF': agent = gpf_agent(model_name, i, env, M, u_range, base_kwargs, lr=lr, n_pars=n_pars, batch_size=batch_size, game_name=game_name) elif model_name == 'ROMMEO': agent = rom_agent(model_name, i, env, M, u_range, base_kwargs, game_name=game_name) else: if model_name == 'DDPG': joint = False opponent_modelling = False elif model_name == 'MADDPG': joint = True opponent_modelling = False elif model_name == 'DDPG-OM': joint = True opponent_modelling = True agent = ddpg_agent(joint, opponent_modelling, model_names, i, env, M, u_range, base_kwargs, lr=lr, game_name=game_name) agents.append(agent) sampler.initialize(env, agents) for agent in agents: agent._init_training() gt.rename_root('MARLAlgorithm') gt.reset() gt.set_def_unique(False) initial_exploration_done = False # noise = .1 noise = .5 for agent in agents: try: agent.policy.set_noise_level(noise) except: pass # alpha = .5 for steps in gt.timed_for(range(base_kwargs['n_epochs'] + 1)): # import pdb; pdb.set_trace() alpha = _alpha + np.exp(-0.1 * max(steps - 10, 0)) * 500. # if steps > 100 and steps<150: # alpha = .1 - 0.099 * steps/(150) # elif steps >= 150: # alpha = 1e-3 print('alpha', alpha) logger.push_prefix('Epoch #%d | ' % steps) if steps % (25 * 1000) == 0: print(suffix) for t in range(base_kwargs['epoch_length']): # TODO.code consolidation: Add control interval to sampler if not initial_exploration_done: # if steps >= 1000: if steps >= 10: initial_exploration_done = True sampler.sample() if not initial_exploration_done: continue gt.stamp('sample') print('Sample Done') if steps == 10000: noise = 0.1 for agent in agents: try: agent.policy.set_noise_level(noise) except: pass # alpha = 10. # if steps == 2000: if steps > base_kwargs['n_epochs'] / 10: noise = 0.1 for agent in agents: try: agent.policy.set_noise_level(noise) except: pass # alpha = .1 if steps > base_kwargs['n_epochs'] / 5: noise = 0.05 for agent in agents: try: agent.policy.set_noise_level(noise) except: pass if steps > base_kwargs['n_epochs'] / 6: noise = 0.01 for agent in agents: try: agent.policy.set_noise_level(noise) except: pass if steps % arglist.training_interval != 0: continue for j in range(base_kwargs['n_train_repeat']): batch_n = [] recent_batch_n = [] indices = None receent_indices = None for i, agent in enumerate(agents): if i == 0: batch = agent.pool.random_batch(batch_size) indices = agent.pool.indices receent_indices = list( range(agent.pool._top - batch_size, agent.pool._top)) batch_n.append( agent.pool.random_batch_by_indices(indices)) recent_batch_n.append( agent.pool.random_batch_by_indices( receent_indices)) # print(len(batch_n)) target_next_actions_n = [] # try: all_obs = np.array( np.concatenate( [batch['observations'] for batch in batch_n], axis=-1)) all_next_obs = np.array( np.concatenate( [batch['next_observations'] for batch in batch_n], axis=-1)) # print(all_obs[0]) for batch in batch_n: # print('making all obs') batch['all_observations'] = deepcopy(all_obs) batch['all_next_observations'] = deepcopy(all_next_obs) # opponent_current_actions_n = [] # for agent, batch in zip(agents, batch_n): # target_next_actions_n.append(agent.target_policy.get_actions(batch['next_observations'])) # opponent_current_actions_n.append(agent.policy.get_actions(batch['observations'])) # for i, agent in enumerate(agents): # batch_n[i]['opponent_current_actions'] = np.reshape( # np.delete(deepcopy(opponent_current_actions_n), i, 0), (-1, agent._opponent_action_dim)) # except: # pass # opponent_actions_n = np.array([batch['actions'] for batch in batch_n]) # recent_opponent_actions_n = np.array([batch['actions'] for batch in recent_batch_n]) ####### figure out # recent_opponent_observations_n = [] # for batch in recent_batch_n: # recent_opponent_observations_n.append(batch['observations']) # current_actions = [agents[i].policy.get_actions(batch_n[i]['next_observations'])[0][0] for i in range(agent_num)] # all_actions_k = [] # for i, agent in enumerate(agents): # if isinstance(agent, MAVBAC): # if agent._k > 0: # batch_actions_k = agent.policy.get_all_actions(batch_n[i]['next_observations']) # actions_k = [a[0][0] for a in batch_actions_k] # all_actions_k.append(';'.join(list(map(str, actions_k)))) # if len(all_actions_k) > 0: # with open('{}/all_actions.csv'.format(policy_dir), 'a') as f: # f.write(','.join(list(map(str, all_actions_k))) + '\n') # with open('{}/policy.csv'.format(policy_dir), 'a') as f: # f.write(','.join(list(map(str, current_actions)))+'\n') # print('============') for i, agent in enumerate(agents): # try: # batch_n[i]['next_actions'] = deepcopy(target_next_actions_n[i]) # except: # pass # batch_n[i]['opponent_actions'] = np.reshape(np.delete(deepcopy(opponent_actions_n), i, 0), (-1, agent._opponent_action_dim)) # if agent.joint: # if agent.opponent_modelling: # batch_n[i]['recent_opponent_observations'] = recent_opponent_observations_n[i] # batch_n[i]['recent_opponent_actions'] = np.reshape(np.delete(deepcopy(recent_opponent_actions_n), i, 0), (-1, agent._opponent_action_dim)) # batch_n[i]['opponent_next_actions'] = agent.opponent_policy.get_actions(batch_n[i]['next_observations']) # else: # batch_n[i]['opponent_next_actions'] = np.reshape(np.delete(deepcopy(target_next_actions_n), i, 0), (-1, agent._opponent_action_dim)) # if isinstance(agent, MAVBAC) or isinstance(agent, MASQL) or isinstance(agent, ROMMEO): agent._do_training(iteration=t + steps * agent._epoch_length, batch=batch_n[i], annealing=alpha) # else: # agent._do_training(iteration=t + steps * agent._epoch_length, batch=batch_n[i]) gt.stamp('train') result = sampler.terminate() print('res is', result) clear_session() return result