Exemplo n.º 1
0
class Agent():
    """Interacts with and learns from the environment."""
    def __init__(self, state_size, action_size):
        """Initialize an Agent object.
        
        Params
        ======
            state_size (int): dimension of each state
            action_size (int): dimension of each action
            seed (int): random seed
        """
        self.state_size = state_size
        self.action_size = action_size

        # Q-Network
        self.qnetwork_local = QNetwork(state_size, action_size).to(device)
        self.qnetwork_target = QNetwork(state_size, action_size).to(device)
        self.optimizer = optim.Adam(self.qnetwork_local.parameters(), lr=LR)

        # Replay memory
        self.memory = ReplayBuffer(action_size, BUFFER_SIZE, BATCH_SIZE)
        # Initialize time step (for updating every UPDATE_EVERY steps)
        self.t_step = 0

    def step(self, state, action, reward, next_state, done):
        # Save experience in replay memory
        self.memory.add(state, action, reward, next_state, done)

        # Learn every UPDATE_EVERY time steps.
        self.t_step = (self.t_step + 1) % UPDATE_EVERY
        if self.t_step == 0:
            # If enough samples are available in memory, get random subset and learn
            if len(self.memory) > BATCH_SIZE:
                experiences = self.memory.sample()
                self.learn(experiences, GAMMA)

    def act(self, state, eps=0.):
        """Returns actions for given state as per current policy.
        
        Params
        ======
            state (array_like): current state
            eps (float): epsilon, for epsilon-greedy action selection
        """
        state = torch.from_numpy(state).float().unsqueeze(0).to(device)
        self.qnetwork_local.eval()
        with torch.no_grad():
            action_values = self.qnetwork_local(state)
        self.qnetwork_local.train()

        # Epsilon-greedy action selection
        if random.random() > eps:
            return np.argmax(action_values.cpu().data.numpy())
        else:
            return random.choice(np.arange(self.action_size))

    def learn(self, experiences, gamma):
        """Update value parameters using given batch of experience tuples.

        Params
        ======
            experiences (Tuple[torch.Variable]): tuple of (s, a, r, s', done) tuples 
            gamma (float): discount factor
        """
        states, actions, rewards, next_states, dones = experiences
        states = torch.from_numpy(states).float().to(device)
        actions = torch.from_numpy(actions).long().to(device)
        rewards = torch.from_numpy(rewards).float().to(device)
        next_states = torch.from_numpy(next_states).float().to(device)
        dones = torch.from_numpy(dones).float().to(device)

        # Get max predicted Q values (for next states) from target model
        Q_targets_next = self.qnetwork_target(next_states).detach().max(
            1)[0].unsqueeze(1)
        # Compute Q targets for current states
        Q_targets = rewards + (gamma * Q_targets_next * (1 - dones))

        # Get expected Q values from local model
        Q_expected = self.qnetwork_local(states).gather(1, actions)

        # Compute loss
        loss = F.mse_loss(Q_expected, Q_targets)
        # Minimize the loss
        self.optimizer.zero_grad()
        loss.backward()
        self.optimizer.step()

        # ------------------- update target network ------------------- #
        self.soft_update(self.qnetwork_local, self.qnetwork_target, TAU)

    def soft_update(self, local_model, target_model, tau):
        """Soft update model parameters.
        θ_target = τ*θ_local + (1 - τ)*θ_target

        Params
        ======
            local_model (PyTorch model): weights will be copied from
            target_model (PyTorch model): weights will be copied to
            tau (float): interpolation parameter 
        """
        for target_param, local_param in zip(target_model.parameters(),
                                             local_model.parameters()):
            target_param.data.copy_(tau * local_param.data +
                                    (1.0 - tau) * target_param.data)
Exemplo n.º 2
0
class Agent:
    """Interacts with and learns from the environment."""
    def __init__(self, state_size, action_size, seed):
        """Initialize an Agent object.
        
        Params
        ======
            state_size (int): dimension of each state
            action_size (int): dimension of each action
            seed (int): random seed
        """
        self.state_size = state_size
        self.action_size = action_size
        self.seed = random.seed(seed)

        # Q-Network
        self.qnetwork_local = QNetwork(state_size, action_size,
                                       seed).to(device)
        self.qnetwork_target = QNetwork(state_size, action_size,
                                        seed).to(device)
        self.optimizer = optim.Adam(self.qnetwork_local.parameters(), lr=LR)

        # Replay memory
        self.memory = ReplayBuffer(action_size, BUFFER_SIZE, BATCH_SIZE, seed)
        # Initialize time step (for updating every UPDATE_EVERY steps)
        self.t_step = 0

    def step(self, state, action, reward, next_state, done):
        # Save experience in replay memory
        self.memory.add(state, action, reward, next_state, done)

        # Learn every UPDATE_EVERY time steps.
        self.t_step = (self.t_step + 1) % UPDATE_EVERY
        if self.t_step == 0:
            # If enough samples are available in memory, get random subset and learn
            if len(self.memory) > BATCH_SIZE:
                experiences = self.memory.sample()
                self.learn(experiences, GAMMA)

    def act(self, state, eps=0.):
        """Returns actions for given state as per current policy.
        
        Params
        ======
            state (array_like): current state
            eps (float): epsilon, for epsilon-greedy action selection
        """
        state = torch.from_numpy(state).float().unsqueeze(0).to(device)
        self.qnetwork_local.eval()
        with torch.no_grad():
            action_values = self.qnetwork_local(state)
        self.qnetwork_local.train()

        # Epsilon-greedy action selection
        if random.random() > eps:
            return np.argmax(action_values.cpu().data.numpy())
        else:
            return random.choice(np.arange(self.action_size))

    def learn(self, experiences, gamma):
        """Update value parameters using given batch of experience tuples.

        Params
        ======
            experiences (Tuple[torch.Variable]): tuple of (s, a, r, s', done) tuples 
            gamma (float): discount factor
        """
        def loss_dqn(output, target):
            loss = target - output
            return (target - output)**2

        states, actions, rewards, next_states, dones = experiences

        # Reset gradients
        # Calculate the value of the target in the next state
        pred = self.qnetwork_target(next_states)  # (64, 4)
        target = rewards  # (64, 1)
        for i in range(BATCH_SIZE):
            # Check for dones
            if dones[i] == False:
                target[i] = rewards[i] + GAMMA * torch.max(pred[i])
        # The loss
        output = self.qnetwork_local(states)

        # Use gather in order to have the correct slicing
        output_action_value = output.gather(1, actions.view(-1, 1))
        loss = loss_dqn(output_action_value, target).mean()
        # Reset gradients
        self.optimizer.zero_grad()
        loss.backward()
        self.optimizer.step()

        # ------------------- update target network ------------------- #
        self.soft_update(self.qnetwork_local, self.qnetwork_target, TAU)

    def soft_update(self, local_model, target_model, tau):
        """Soft update model parameters.
        θ_target = τ*θ_local + (1 - τ)*θ_target

        Params
        ======
            local_model (PyTorch model): weights will be copied from
            target_model (PyTorch model): weights will be copied to
            tau (float): interpolation parameter 
        """
        for target_param, local_param in zip(target_model.parameters(),
                                             local_model.parameters()):
            target_param.data.copy_(tau * local_param.data +
                                    (1.0 - tau) * target_param.data)
class Agent():
    '''Interacts and learns from the environment'''
    
    def __init__(self, state_size, action_size, seed):
        """Initialize an Agent object
        Params
        ======
            state_size (int): dimension of each state
            action_size (int): dimension of each action
            seed(int): random seed
        """
        
        self.state_size = state_size
        self.action_size = action_size
        self.seed = random.seed(seed)
        
        # Q-Network
        self.qnetwork_local = QNetwork(state_size, action_size, seed).to(device)
        self.qnetwork_target = QNetwork(state_size, action_size, seed).to(device)
        self.optimizer = optim.Adam(self.qnetwork_local.parameters(), lr=LR)
        
        # Replay memory
        self.memory = ReplayBuffer(action_size, BUFFER_SIZE, BATCH_SIZE, seed)
        # initialise the timestep (for updating every UPDATE_EVERY steps)
        self.t_step = 0
        
    def step(self, state, action, reward, next_state, done):
        # Save experience in the replay memory
        self.memory.add(state, action, reward, next_state, done)
        
        # Learn every UPDATE_EVERY time steps
        self.t_step = (self.t_step +1) % UPDATE_EVERY
        
        if self.t_step ==0:
            # Get random subset from the memory, but ONLY if there are enough samples
            if len(self.memory) > BATCH_SIZE:
                experiences = self.memory.sample()
                self.learn(experiences, GAMMA)
                
    def act(self, state, eps=0.):
        """Returns actions for given state as per current policy
        Params
        ------
            state(array_like): current state
            eps(float): epsilon, epsilon-greedy action selection (to keep element of exploration)
        """
        # convert the state from the Unity network into a torch tensor
        state = torch.from_numpy(state).float().unsqueeze(0).to(device)
        # Note to pass it through the deep network, we need to take the numpy array and:
        # 1 - convert it to torch array with from_numpy()
        # 2 - convert it to float 32 as that is what is expected. Use .float()
        # 3 - Add a dimension on axis 0 with .unsqueeze(0). Because pytorch expects a BATCH of 1 dimensional arrays
        # to be fed into its network. For example feeding in a batch of 64 arrays, each of length 37. In our case,
        # with reinforcement learning we are only feeding one at a time, but the network still expects it to be 2D.
        self.qnetwork_local.eval()
        with torch.no_grad():
            action_values = self.qnetwork_local(state)
        self.qnetwork_local.train()
        
        # Epsilon-greedy action selection
        if random.random() > eps:
            return np.argmax(action_values.cpu().data.numpy())
        else:
            return random.choice(np.arange(self.action_size))
        
    def learn(self, experiences, gamma):
        """Update value paratmers of the deep-Q network using given batch of experience tuples
        
        Params
        ------
            experiences (Tuple[torch.Variable]): tuple of (s, a, r, s', done) tuples
            gamma (float): discount factor
        """
        states, actions, rewards, next_states, dones = experiences
        
        # get the max predicted Q values for the next states, from the target model
        # note: detach just detaches the tensor from the grad_fn - i.e. we are going to do some non-tracked
        # computations based on the value of this tensor (we DON'T update the target model at this stage)
        Q_targets_next = self.qnetwork_target(next_states).detach().max(1)[0].unsqueeze(1)
        # compute Q targets for current states
        Q_targets = rewards + (gamma * Q_targets_next * (1-dones))
        
        # Get expected Q values from local model
        Q_expected = self.qnetwork_local(states).gather(1, actions)
        
        # compute loss
        loss = F.mse_loss(Q_expected, Q_targets)
        # Minimise the loss
        self.optimizer.zero_grad()
        loss.backward()
        self.optimizer.step()
        
        # update target network
        self.soft_update(self.qnetwork_local, self.qnetwork_target, TAU)
    
    def soft_update(self, local_model, target_model, tau):
        """Soft update model parameters
        θ_target = τ*θ_local + (1 - τ)*θ_target
        
        Params
        ======
            local_model (Pytorch model): weights will be copied from
            taret_model (Pytorch model): weights will be copied to
            tau (float): interpolation parameter
        """
        for target_param, local_param in zip(target_model.parameters(), local_model.parameters()):
            target_param.data.copy_(tau*local_param.data + (1.0-tau) * target_param.data)
Exemplo n.º 4
0
class Agent(object):
    def __init__(self, state_size, action_size, seed, config):
        self.state_size = state_size
        self.action_size = action_size
        self.config = config
        self.seed = random.seed(seed)

        self.local_q_net = QNetwork(state_size, action_size, seed).to(device)
        self.target_q_net = QNetwork(state_size, action_size, seed).to(device)

        self.optimizer = optim.Adam(self.local_q_net.parameters(),
                                    lr=config["LR"])

        self.memory = ReplayBuffer(action_size, config["BUFFER_SIZE"],
                                   config["BATCH_SIZE"], seed)

        self.t_step = 0

    def step(self, state, action, reward, next_state, done):
        self.memory.add(state, action, reward, next_state, done)

        self.t_step = (self.t_step + 1) % self.config["UPDATE_EVERY"]

        if self.t_step == 0:
            # if agent experienced enough
            if len(self.memory) > self.config["BATCH_SIZE"]:
                experiences = self.memory.sample()
                # Learn from previous experiences
                self.learn(experiences, self.config["GAMMA"])

    def act(self, state, eps=0.0):
        state = torch.from_numpy(state).float().unsqueeze(0).to(device)
        self.local_q_net.eval()
        with torch.no_grad():
            action_values = self.local_q_net(state)
        self.local_q_net.train()

        if random.random() > eps:
            return np.argmax(action_values.cpu().data.numpy())
        else:
            return random.choice(np.arange(self.action_size))

    def learn(self, experiences, gamma):
        # Double Q Learning

        states, actions, rewards, next_states, dones = experiences

        # Get next action estimation with local q network
        q_targets_next_expected = self.local_q_net(next_states).detach()
        q_targets_next_expected_actions = q_targets_next_expected.max(
            1)[1].unsqueeze(1)

        # Calculate Next Targets
        q_targets_next = self.target_q_net(next_states).gather(
            1, q_targets_next_expected_actions)

        # Non over-estimated targets
        q_targets = rewards + (gamma * q_targets_next * (1 - dones))

        # Expected value
        q_expected = self.local_q_net(states).gather(1, actions)

        loss = torch.nn.functional.mse_loss(q_expected, q_targets)

        self.optimizer.zero_grad()
        loss.backward()
        self.optimizer.step()

        self.soft_update(self.local_q_net, self.target_q_net,
                         self.config["TAU"])

    def soft_update(self, local_net, target_net, tau):
        for target_param, local_param in zip(target_net.parameters(),
                                             local_net.parameters()):
            target_param.data.copy_(tau * local_param.data +
                                    (1 - tau) * target_param.data)