Exemplo n.º 1
0
    def __init__(self, envs, hparams):

        self.use_gae = hparams['use_gae']
        self.gamma = hparams['gamma']
        self.tau = hparams['tau']

        self.obs_shape = hparams['obs_shape']
        self.num_steps = hparams['num_steps']
        self.num_processes = hparams['num_processes']
        self.value_loss_coef = hparams['value_loss_coef']
        self.entropy_coef = hparams['entropy_coef']
        self.cuda = hparams['cuda']
        self.opt = hparams['opt']
        self.grad_clip = hparams['grad_clip']



        if hparams['dropout'] == True:
            print ('CNNPolicy_dropout2')
            actor_critic = CNNPolicy_dropout2(self.obs_shape[0], envs.action_space)
            # actor_critic = CNNPolicy_dropout(self.obs_shape[0], envs.action_space)
        elif len(envs.observation_space.shape) == 3:
            print ('CNNPolicy2')
            actor_critic = CNNPolicy2(self.obs_shape[0], envs.action_space)
            # actor_critic = CNNPolicy(self.obs_shape[0], envs.action_space)
        else:
            actor_critic = MLPPolicy(self.obs_shape[0], envs.action_space)

        if envs.action_space.__class__.__name__ == "Discrete":
            action_shape = 1
        else:
            action_shape = envs.action_space.shape[0]
        self.action_shape = action_shape

        rollouts = RolloutStorage(self.num_steps, self.num_processes, self.obs_shape, envs.action_space)
        #it has a self.state that is [steps, processes, obs]
        #steps is used to compute expected reward

        if self.cuda:
            actor_critic.cuda()
            rollouts.cuda()

        if self.opt == 'rms':
            self.optimizer = optim.RMSprop(params=actor_critic.parameters(), lr=hparams['lr'], eps=hparams['eps'], alpha=hparams['alpha'])
        elif self.opt == 'adam':
            self.optimizer = optim.Adam(params=actor_critic.parameters(), lr=hparams['lr'], eps=hparams['eps'])
        elif self.opt == 'sgd':
            self.optimizer = optim.SGD(params=actor_critic.parameters(), lr=hparams['lr'], momentum=hparams['mom'])
        else:
            print ('no opt specified')

        self.actor_critic = actor_critic
        self.rollouts = rollouts


        self.rollouts_list = RolloutStorage_list()
Exemplo n.º 2
0
def main():
    print("#######")
    print(
        "WARNING: All rewards are clipped so you need to use a monitor (see envs.py) or visdom plot to get true rewards"
    )
    print("#######")

    os.environ['OMP_NUM_THREADS'] = '1'

    if args.vis:
        from visdom import Visdom
        viz = Visdom()
        win = None

    envs = SubprocVecEnv([
        make_env(args.env_name, args.seed, i, args.log_dir)
        for i in range(args.num_processes)
    ])

    obs_shape = envs.observation_space.shape
    print(obs_shape)
    obs_shape = (obs_shape[0] * args.num_stack, *obs_shape[1:])

    if len(envs.observation_space.shape) == 3:
        if args.custom == 1:
            print('## Using Custom CNN Policy....' + str(obs_shape[0]))
            actor_critic = CNNPolicy2(obs_shape[0], envs.action_space)
        else:
            print('## Using CNN Policy....' + str(obs_shape[0]))
            actor_critic = CNNPolicy(obs_shape[0], envs.action_space)
    else:
        print('## Using MLP Policy....')
        actor_critic = MLPPolicy(obs_shape[0], envs.action_space)

    if envs.action_space.__class__.__name__ == "Discrete":
        action_shape = 1
    else:
        action_shape = envs.action_space.shape[0]

    if args.cuda:
        actor_critic.cuda()

    if args.algo == 'a2c':
        optimizer = optim.RMSprop(actor_critic.parameters(),
                                  args.lr,
                                  eps=args.eps,
                                  alpha=args.alpha)
    elif args.algo == 'ppo':
        optimizer = optim.Adam(actor_critic.parameters(),
                               args.lr,
                               eps=args.eps)
    elif args.algo == 'acktr':
        optimizer = KFACOptimizer(actor_critic)

    rollouts = RolloutStorage(args.num_steps, args.num_processes, obs_shape,
                              envs.action_space)
    current_state = torch.zeros(args.num_processes, *obs_shape)

    def update_current_state(state):
        shape_dim0 = envs.observation_space.shape[0]
        state = torch.from_numpy(state).float()
        if args.num_stack > 1:
            current_state[:, :-shape_dim0] = current_state[:, shape_dim0:]
        current_state[:, -shape_dim0:] = state

    state = envs.reset()
    update_current_state(state)

    rollouts.states[0].copy_(current_state)

    # These variables are used to compute average rewards for all processes.
    episode_rewards = torch.zeros([args.num_processes, 1])
    final_rewards = torch.zeros([args.num_processes, 1])
    if args.cuda:
        current_state = current_state.cuda()
        rollouts.cuda()

    if args.algo == 'ppo':
        old_model = copy.deepcopy(actor_critic)

    for j in range(num_updates):
        for step in range(args.num_steps):
            # Sample actions
            value, action = actor_critic.act(
                Variable(rollouts.states[step], volatile=True))
            cpu_actions = action.data.squeeze(1).cpu().numpy()

            # Obser reward and next state
            state, reward, done, info = envs.step(cpu_actions)
            reward = torch.from_numpy(np.expand_dims(np.stack(reward),
                                                     1)).float()
            episode_rewards += reward
            if done:
                start_time = time.process_time()
            # If done then clean the history of observations.
            masks = torch.FloatTensor([[0.0] if done_ else [1.0]
                                       for done_ in done])
            final_rewards *= masks
            final_rewards += (1 - masks) * episode_rewards
            episode_rewards *= masks

            if args.cuda:
                masks = masks.cuda()

            if current_state.dim() == 4:
                current_state *= masks.unsqueeze(2).unsqueeze(2)
            else:
                current_state *= masks

            update_current_state(state)
            rollouts.insert(step, current_state, action.data, value.data,
                            reward, masks)

        next_value = actor_critic(Variable(rollouts.states[-1],
                                           volatile=True))[0].data

        if hasattr(actor_critic, 'obs_filter'):
            actor_critic.obs_filter.update(rollouts.states[:-1].view(
                -1, *obs_shape))

        rollouts.compute_returns(next_value, args.use_gae, args.gamma,
                                 args.tau)

        if args.algo in ['a2c', 'acktr']:
            values, action_log_probs, dist_entropy = actor_critic.evaluate_actions(
                Variable(rollouts.states[:-1].view(-1, *obs_shape)),
                Variable(rollouts.actions.view(-1, action_shape)))

            values = values.view(args.num_steps, args.num_processes, 1)
            action_log_probs = action_log_probs.view(args.num_steps,
                                                     args.num_processes, 1)

            advantages = Variable(rollouts.returns[:-1]) - values
            value_loss = advantages.pow(2).mean()

            action_loss = -(Variable(advantages.data) *
                            action_log_probs).mean()

            if args.algo == 'acktr' and optimizer.steps % optimizer.Ts == 0:
                # Sampled fisher, see Martens 2014
                actor_critic.zero_grad()
                pg_fisher_loss = -action_log_probs.mean()

                value_noise = Variable(torch.randn(values.size()))
                if args.cuda:
                    value_noise = value_noise.cuda()

                sample_values = values + value_noise
                vf_fisher_loss = -(values -
                                   Variable(sample_values.data)).pow(2).mean()

                fisher_loss = pg_fisher_loss + vf_fisher_loss
                optimizer.acc_stats = True
                fisher_loss.backward(retain_graph=True)
                optimizer.acc_stats = False

            optimizer.zero_grad()
            (value_loss * args.value_loss_coef + action_loss -
             dist_entropy * args.entropy_coef).backward()

            if args.algo == 'a2c':
                nn.utils.clip_grad_norm(actor_critic.parameters(),
                                        args.max_grad_norm)

            optimizer.step()
        elif args.algo == 'ppo':
            advantages = rollouts.returns[:-1] - rollouts.value_preds[:-1]
            advantages = (advantages - advantages.mean()) / (advantages.std() +
                                                             1e-5)

            old_model.load_state_dict(actor_critic.state_dict())
            if hasattr(actor_critic, 'obs_filter'):
                old_model.obs_filter = actor_critic.obs_filter

            for _ in range(args.ppo_epoch):
                sampler = BatchSampler(SubsetRandomSampler(
                    range(args.num_processes * args.num_steps)),
                                       args.batch_size * args.num_processes,
                                       drop_last=False)
                for indices in sampler:
                    indices = torch.LongTensor(indices)
                    if args.cuda:
                        indices = indices.cuda()
                    states_batch = rollouts.states[:-1].view(
                        -1, *obs_shape)[indices]
                    actions_batch = rollouts.actions.view(
                        -1, action_shape)[indices]
                    return_batch = rollouts.returns[:-1].view(-1, 1)[indices]

                    # Reshape to do in a single forward pass for all steps
                    values, action_log_probs, dist_entropy = actor_critic.evaluate_actions(
                        Variable(states_batch), Variable(actions_batch))

                    _, old_action_log_probs, _ = old_model.evaluate_actions(
                        Variable(states_batch, volatile=True),
                        Variable(actions_batch, volatile=True))

                    ratio = torch.exp(action_log_probs -
                                      Variable(old_action_log_probs.data))
                    adv_targ = Variable(advantages.view(-1, 1)[indices])
                    surr1 = ratio * adv_targ
                    surr2 = torch.clamp(ratio, 1.0 - args.clip_param,
                                        1.0 + args.clip_param) * adv_targ
                    action_loss = -torch.min(
                        surr1,
                        surr2).mean()  # PPO's pessimistic surrogate (L^CLIP)

                    value_loss = (Variable(return_batch) -
                                  values).pow(2).mean()

                    optimizer.zero_grad()
                    (value_loss + action_loss -
                     dist_entropy * args.entropy_coef).backward()
                    optimizer.step()

        rollouts.states[0].copy_(rollouts.states[-1])

        if j % args.save_interval == 0 and args.save_dir != "":
            save_path = os.path.join(args.save_dir, args.algo)
            try:
                os.makedirs(save_path)
            except OSError:
                pass

            # A really ugly way to save a model to CPU
            save_model = actor_critic
            if args.cuda:
                save_model = copy.deepcopy(actor_critic).cpu()
            torch.save(save_model,
                       os.path.join(save_path, args.env_name + ".pt"))

        if j % args.log_interval == 0:
            end_time = time.process_time()
            print(
                "Updates {}, num frames {}, mean/median reward {:.1f}/{:.1f}, min/max reward {:.1f}/{:.1f}, entropy {:.5f}, value loss {:.5f}, policy loss {:.5f}, time_spent {:.5f}"
                .format(j, (j + 1) * args.num_processes * args.num_steps,
                        final_rewards.mean(), final_rewards.median(),
                        final_rewards.min(), final_rewards.max(),
                        -dist_entropy.data[0], value_loss.data[0],
                        action_loss.data[0], end_time - start_time))

        if j % args.vis_interval == 0:
            win = visdom_plot(viz, win, args.log_dir, args.env_name, args.algo)