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Explanation of Fundamental Functions involved in A3C algorithm

Although any implementation of the Asynchronous Advantage Actor Critic algorithm is bound to be complex, all the implementations will have one thing in common – the presence of the Global Network and the worker class.

 A3C (Asynchronous Advantage Actor-Critic) is a reinforcement learning algorithm that is used to train deep neural networks to make decisions in an environment. It is designed to handle large and continuous action spaces, making it useful for a wide range of tasks. Here are some fundamental functions involved in the A3C algorithm:

Actor Network: The actor-network is a deep neural network that maps observations to a probability distribution over actions. This network is trained using policy gradients to optimize the expected future reward.

Critic Network: The critic network is a deep neural network that estimates the expected future reward for a given state. It is trained using the temporal difference (TD) error, which is the difference between the predicted reward and the actual reward received.

Advantage Function: The advantage function is a measure of how much better an action is than the average action in a given state. It is calculated as the difference between the expected reward and the baseline reward, which is the expected reward of the current state.

Asynchronous Updates: A3C uses an asynchronous update scheme, where multiple agents run in parallel and update the actor and critic networks asynchronously. This allows for faster convergence and improved exploration of the state-action space.

Exploration Strategy: A3C uses an exploration strategy to encourage exploration of the state-action space. This is typically achieved using an epsilon-greedy policy, where the agent chooses a random action with probability epsilon and the best action with probability (1-epsilon).

Experience Replay: A3C does not use experience replay, as it is designed for continuous environments. Instead, it uses a sliding window approach, where the agent stores the last N experiences and samples from this buffer to update the networks.

Overall, A3C is a powerful algorithm that combines deep reinforcement learning with asynchronous updates and exploration strategies to efficiently learn policies in large and continuous action spaces.

  1. Global Network class: This contains all the required Tensorflow operations to autonomously create the neural networks.
  2. Worker class: This class is used to simulate the learning process of a worker who has its own copy of the environment and a “personal” neural network.

For the following implementation, the following modules will be required:-

  1. Numpy
  2. Tensorflow
  3. Multiprocessing

The following lines of code denote the fundamental functions required to build the respective class. 

Global Network class: 

Python3




# Defining the Network class
class AC_Network():


The following lines contain the various functions that describe the member functions of the class defined above. 

Initializing the class: 

Python3




# Initializing the class
def __init__(self, s_size, a_size, scope, trainer):
        with tf.variable_scope(scope):
  
            # Input and visually encoding the layers
            self.inputs = tf.placeholder(shape =[None, s_size],
                                         dtype = tf.float32)
            self.imageIn = tf.reshape(self.inputs, shape =[-1, 84, 84, 1])
            self.conv1 = slim.conv2d(activation_fn = tf.nn.elu,
                                    inputs = self.imageIn, num_outputs = 16,
                                    kernel_size =[8, 8],
                                    stride =[4, 4], padding ='VALID')
            self.conv2 = slim.conv2d(activation_fn = tf.nn.elu,
                                    inputs = self.conv1, num_outputs = 32,
                                    kernel_size =[4, 4],
                                    stride =[2, 2], padding ='VALID')
            hidden = slim.fully_connected(slim.flatten(self.conv2),
                                          256, activation_fn = tf.nn.elu)


-> tf.placeholder()       - Inserts a placeholder for a tensor that will always be fed.
-> tf.reshape()           - Reshapes the input tensor
-> slim.conv2d()          - Adds an n-dimensional convolutional network
-> slim.fully_connected() - Adds a fully connected layer

Note the following definitions:

  • Filter: It is a small matrix that is used to apply different effects on a given image.
  • Padding: It is the process of adding an extra row or column on the boundaries of an image to completely compute the filter convolution value of the filter.
  • Stride: It is the number of steps after which the filter is set upon the pixel in a given direction.

Building the Recurrent network: 

Python3




def __init__(self, s_size, a_size, scope, trainer):
        with tf.variable_scope(scope):
           . . . . . . . . . .
           . . . . . . . . . .
           . . . . . . . . . .
 
            # Building the Recurrent network for temporal dependencies
            lstm_cell = tf.nn.rnn_cell.BasicLSTMCell(256, state_is_tuple = True)
            c_init = np.zeros((1, lstm_cell.state_size.c), np.float32)
            h_init = np.zeros((1, lstm_cell.state_size.h), np.float32)
            self.state_init = [c_init, h_init]
            c_Init = tf.placeholder(tf.float32, [1, lstm_cell.state_size.c])
            h_Init = tf.placeholder(tf.float32, [1, lstm_cell.state_size.h])
            self.state_Init = (c_Init, h_Init)
            rnn_init = tf.expand_dims(hidden, [0])
            step_size = tf.shape(self.imageIn)[:1]
            state_Init = tf.nn.rnn_cell.LSTMStateTuple(c_Init, h_Init)
            lstm_outputs, lstm_state = tf.nn.dynamic_rnn(lstm_cell, rnn_init,
                                                    initial_state = state_Init,
                                                    sequence_length = step_size,
                                                    time_major = False)
            lstm_c, lstm_h = lstm_state
            self.state_out = (lstm_c[:1, :], lstm_h[:1, :])
            rnn_out = tf.reshape(lstm_outputs, [-1, 256])


-> tf.nn.rnn_cell.BasicLSTMCell()  - Builds a basic LSTM Recurrent network cell
-> tf.expand_dims()                - Inserts a dimension of 1 at the dimension index
                                     axis of input's shape
-> tf.shape()                      - returns the shape of the tensor
-> tf.nn.rnn_cell.LSTMStateTuple() - Creates a tuple to be used by
                                     the LSTM cells for state_size,
                                     zero_state and output state.
-> tf.nn.dynamic_rnn()             - Builds a Recurrent network according to
                                     the Recurrent network cell

Building the output layers for value and policy estimation: 

Python3




def __init__(self, s_size, a_size, scope, trainer):
        with tf.variable_scope(scope):
           . . . . . . . . . .
           . . . . . . . . . .
           . . . . . . . . . .
 
           # Building the output layers for value and policy estimations
            self.policy = slim.fully_connected(rnn_out, a_size,
                                               activation_fn = tf.nn.softmax,
                   weights_initializer = normalized_columns_initializer(0.01),
                                               biases_initializer = None)
            self.value = slim.fully_connected(rnn_out, 1,
                activation_fn = None,
                weights_initializer = normalized_columns_initializer(1.0),
                biases_initializer = None)


Building the Master network and deploying the workers: 

Python3




def __init__(self, s_size, a_size, scope, trainer):
        with tf.variable_scope(scope):
           . . . . . . . . . .
           . . . . . . . . . .
           . . . . . . . . . .
           with tf.device("/cpu:0"):
 
              # Generating the global network
               master_network = AC_Network(s_size, a_size, 'global', None)
                
               # Keeping the number of workers
               # as the number of available CPU threads
               num_workers = multiprocessing.cpu_count()
 
               # Creating and deploying the workers
               workers = []
               for i in range(num_workers):
                   workers.append(Worker(DoomGame(), i, s_size, a_size,
                                 trainer, saver, model_path))


Running the parallel Tensorflow operations: 

Python3




def __init__(self, s_size, a_size, scope, trainer):
        with tf.variable_scope(scope):
           . . . . . . . . . .
           . . . . . . . . . .
           . . . . . . . . . .
 
           with tf.Session() as sess:
               coord = tf.train.Coordinator()
               if load_model == True:
                   ckpt = tf.train.get_checkpoint_state(model_path)
                   saver.restore(sess, ckpt.model_checkpoint_path)
               else:
                   sess.run(tf.global_variables_initializer())
         
               worker_threads = []
               for worker in workers:
                   worker_work = lambda: worker.work(max_episode_length,
                                         gamma, master_network, sess, coord)
                   t = threading.Thread(target =(worker_work))
                   t.start()
                   worker_threads.append(t)
               coord.join(worker_threads)


-> tf.Session()                    - A class to run the Tensorflow operations
-> tf.train.Coordinator()          - Returns a coordinator for the multiple threads
-> tf.train.get_checkpoint_state() - Returns a valid checkpoint state
                                     from the "checkpoint" file
-> saver.restore()                 - Is used to store and restore the models
-> sess.run()                      - Outputs the tensors and metadata obtained
                                     from running a session

Updating the global network parameters: 

Python3




def __init__(self, s_size, a_size, scope, trainer):
        with tf.variable_scope(scope):
           . . . . . . . . . .
           . . . . . . . . . .
           . . . . . . . . . .
 
           if scope != 'global':
               self.actions = tf.placeholder(shape =[None], dtype = tf.int32)
               self.actions_onehot = tf.one_hot(self.actions,
                                                a_size, dtype = tf.float32)
               self.target_v = tf.placeholder(shape =[None], dtype = tf.float32)
               self.advantages = tf.placeholder(shape =[None], dtype = tf.float32)
 
               self.responsible_outputs = tf.reduce_sum(self.policy *
                                                        self.actions_onehot, [1])
 
                # Computing the error
                self.value_loss = 0.5 * tf.reduce_sum(tf.square(self.target_v -
                                                    tf.reshape(self.value, [-1])))
                self.entropy = - tf.reduce_sum(self.policy * tf.log(self.policy))
                self.policy_loss = -tf.reduce_sum(tf.log(self.responsible_outputs)
                                                         *self.advantages)
                self.loss = 0.5 * self.value_loss +
                self.policy_loss-self.entropy * 0.01
 
                # Get gradients from the local network
                local_vars = tf.get_collection(tf.GraphKeys.TRAINABLE_VARIABLES,
                                               scope)
                self.gradients = tf.gradients(self.loss, local_vars)
                self.var_norms = tf.global_norm(local_vars)
                grads, self.grad_norms = tf.clip_by_global_norm(self.gradients,
                                                               40.0)
 
                # Apply the local gradients to the global network
                global_vars = tf.get_collection(tf.GraphKeys.TRAINABLE_VARIABLES,
                                               'global')
                self.apply_grads = trainer.apply_gradients(
                        zip(grads, global_vars))


-> tf.one_hot()              - Returns a one-hot encoded tensor
-> tf.reduce_sum()           - Reduces the input tensor along the input dimensions
-> tf.gradients()            - Constructs the symbolic derivatives of the sum
-> tf.clip_by_global_norm()  - Performs the clipping of values of the multiple tensors
                               by the ratio of the sum of the norms
-> trainer.apply_gradients() - Performs the update step according to the optimizer.

Defining a utility function to copy the parameters of one network to the other: 

Python3




def update_target_graph(from_scope, to_scope):
    from_vars = tf.get_collection(tf.GraphKeys.TRAINABLE_VARIABLES, from_scope)
    to_vars = tf.get_collection(tf.GraphKeys.TRAINABLE_VARIABLES, to_scope)
 
    op_holder = []
    for from_var, to_var in zip(from_vars, to_vars):
        op_holder.append(to_var.assign(from_var))
    return op_holder


-> tf.get_collection() - Returns the list of values in the collection with the given name.

Worker Class: Defining the Class: 

Python3




# Defining the Worker Class
class Worker():


The following lines of code describe the member functions of the above-described class.

Initializing the class: 

Python3




# Initializing the class
def __init__(self, game, name, s_size, a_size, trainer, saver, model_path):
     
    # Creating a copy of the environment and the network
    self.local_AC = AC_Network(s_size, a_size, self.name, trainer)
    self.update_local_ops = update_target_graph('global', self.name)


Defining the function for the worker to interact with its environment: 

Python3




def work(self, max_episode_length, gamma, global_AC, sess, coord):
    episode_count = 0
    total_step_count = 0
    with sess.as_default(), sess.graph.as_default():                
        while not coord.should_stop():
            sess.run(self.update_local_ops)
            episode_buffer = []
            episode_values = []
            episode_frames = []
            episode_reward = 0
            episode_step_count = 0
            d = False
                 
            # Building the environment into the frame
            # buffer of the machine
            self.env.new_episode()
            s = self.env.get_state().screen_buffer
            episode_frames.append(s)
            s = process_frame(s)
            rnn_state = self.local_AC.state_init
                 
            while self.env.is_episode_finished() == False:
                 
                # Sampling the different actions
                a_dist, v, rnn_state = sess.run([self.local_AC.policy,
                                     self.local_AC.value,
                                     self.local_AC.state_out],
                                     feed_dict ={self.local_AC.inputs:[s],
                                     self.local_AC.state_in[0]:rnn_state[0],
                                     self.local_AC.state_in[1]:rnn_state[1]})
                    a = np.random.choice(a_dist[0], p = a_dist[0])
                    a = np.argmax(a_dist == a)
           
                    # Computing the reward
                    r = self.env.make_action(self.actions[a]) / 100.0
                    d = self.env.is_episode_finished()
                    if d == False:
                        s1 = self.env.get_state().screen_buffer
                        episode_frames.append(s1)
                        s1 = process_frame(s1)
                    else:
                        s1 = s
                         
                    episode_buffer.append([s, a, r, s1, d, v[0, 0]])
                    episode_values.append(v[0, 0])
 
                    episode_reward += r
                    s = s1                   
                    total_steps += 1
                    episode_step_count += 1


-> sess.as_default() - Sets the current session as the default session
-> self.env.new_episode() - Initializes a new training episode for the worker

Defining the training function for the worker: 

Python3




def train(self, global_AC, rollout, sess, gamma, bootstrap_value):
     
    rollout = np.array(rollout)
    observations = rollout[:, 0]
    actions = rollout[:, 1]
    rewards = rollout[:, 2]
    next_observations = rollout[:, 3]
    values = rollout[:, 5]
 
    # Calculating the rewards and compute the advantage function
    self.rewards_plus = np.asarray(rewards.tolist() +
                                   [bootstrap_value])
    discounted_rewards = discount(self.rewards_plus,
                                  gamma)[:-1]
    self.value_plus = np.asarray(values.tolist() +
                                 [bootstrap_value])
    advantages = rewards +
    gamma * self.value_plus[1:] - self.value_plus[:-1]
    advantages = discount(advantages, gamma)
 
    # Update the global network parameters
    rnn_state = self.local_AC.state_init
    feed_dict = {self.local_AC.target_v:discounted_rewards,
                self.local_AC.inputs:np.vstack(observations),
                self.local_AC.actions:actions,
                self.local_AC.advantages:advantages,
                self.local_AC.state_in[0]:rnn_state[0],
                self.local_AC.state_in[1]:rnn_state[1]}
    v_l, p_l, e_l, g_n, v_n, _ = sess.run([self.local_AC.value_loss,
                                     self.local_AC.policy_loss,
                                     self.local_AC.entropy,
                                     self.local_AC.grad_norms,
                                     self.local_AC.var_norms,
                                     self.local_AC.apply_grads],
                                     feed_dict = feed_dict)
        return v_l / len(rollout), p_l / len(rollout),
        e_l / len(rollout), g_n, v_n


Dominic Rubhabha-Wardslaus
Dominic Rubhabha-Wardslaushttp://wardslaus.com
infosec,malicious & dos attacks generator, boot rom exploit philanthropist , wild hacker , game developer,
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