-
-
Save karpathy/a4166c7fe253700972fcbc77e4ea32c5 to your computer and use it in GitHub Desktop.
""" Trains an agent with (stochastic) Policy Gradients on Pong. Uses OpenAI Gym. """ | |
import numpy as np | |
import cPickle as pickle | |
import gym | |
# hyperparameters | |
H = 200 # number of hidden layer neurons | |
batch_size = 10 # every how many episodes to do a param update? | |
learning_rate = 1e-4 | |
gamma = 0.99 # discount factor for reward | |
decay_rate = 0.99 # decay factor for RMSProp leaky sum of grad^2 | |
resume = False # resume from previous checkpoint? | |
render = False | |
# model initialization | |
D = 80 * 80 # input dimensionality: 80x80 grid | |
if resume: | |
model = pickle.load(open('save.p', 'rb')) | |
else: | |
model = {} | |
model['W1'] = np.random.randn(H,D) / np.sqrt(D) # "Xavier" initialization | |
model['W2'] = np.random.randn(H) / np.sqrt(H) | |
grad_buffer = { k : np.zeros_like(v) for k,v in model.iteritems() } # update buffers that add up gradients over a batch | |
rmsprop_cache = { k : np.zeros_like(v) for k,v in model.iteritems() } # rmsprop memory | |
def sigmoid(x): | |
return 1.0 / (1.0 + np.exp(-x)) # sigmoid "squashing" function to interval [0,1] | |
def prepro(I): | |
""" prepro 210x160x3 uint8 frame into 6400 (80x80) 1D float vector """ | |
I = I[35:195] # crop | |
I = I[::2,::2,0] # downsample by factor of 2 | |
I[I == 144] = 0 # erase background (background type 1) | |
I[I == 109] = 0 # erase background (background type 2) | |
I[I != 0] = 1 # everything else (paddles, ball) just set to 1 | |
return I.astype(np.float).ravel() | |
def discount_rewards(r): | |
""" take 1D float array of rewards and compute discounted reward """ | |
discounted_r = np.zeros_like(r) | |
running_add = 0 | |
for t in reversed(xrange(0, r.size)): | |
if r[t] != 0: running_add = 0 # reset the sum, since this was a game boundary (pong specific!) | |
running_add = running_add * gamma + r[t] | |
discounted_r[t] = running_add | |
return discounted_r | |
def policy_forward(x): | |
h = np.dot(model['W1'], x) | |
h[h<0] = 0 # ReLU nonlinearity | |
logp = np.dot(model['W2'], h) | |
p = sigmoid(logp) | |
return p, h # return probability of taking action 2, and hidden state | |
def policy_backward(eph, epdlogp): | |
""" backward pass. (eph is array of intermediate hidden states) """ | |
dW2 = np.dot(eph.T, epdlogp).ravel() | |
dh = np.outer(epdlogp, model['W2']) | |
dh[eph <= 0] = 0 # backpro prelu | |
dW1 = np.dot(dh.T, epx) | |
return {'W1':dW1, 'W2':dW2} | |
env = gym.make("Pong-v0") | |
observation = env.reset() | |
prev_x = None # used in computing the difference frame | |
xs,hs,dlogps,drs = [],[],[],[] | |
running_reward = None | |
reward_sum = 0 | |
episode_number = 0 | |
while True: | |
if render: env.render() | |
# preprocess the observation, set input to network to be difference image | |
cur_x = prepro(observation) | |
x = cur_x - prev_x if prev_x is not None else np.zeros(D) | |
prev_x = cur_x | |
# forward the policy network and sample an action from the returned probability | |
aprob, h = policy_forward(x) | |
action = 2 if np.random.uniform() < aprob else 3 # roll the dice! | |
# record various intermediates (needed later for backprop) | |
xs.append(x) # observation | |
hs.append(h) # hidden state | |
y = 1 if action == 2 else 0 # a "fake label" | |
dlogps.append(y - aprob) # grad that encourages the action that was taken to be taken (see http://cs231n.github.io/neural-networks-2/#losses if confused) | |
# step the environment and get new measurements | |
observation, reward, done, info = env.step(action) | |
reward_sum += reward | |
drs.append(reward) # record reward (has to be done after we call step() to get reward for previous action) | |
if done: # an episode finished | |
episode_number += 1 | |
# stack together all inputs, hidden states, action gradients, and rewards for this episode | |
epx = np.vstack(xs) | |
eph = np.vstack(hs) | |
epdlogp = np.vstack(dlogps) | |
epr = np.vstack(drs) | |
xs,hs,dlogps,drs = [],[],[],[] # reset array memory | |
# compute the discounted reward backwards through time | |
discounted_epr = discount_rewards(epr) | |
# standardize the rewards to be unit normal (helps control the gradient estimator variance) | |
discounted_epr -= np.mean(discounted_epr) | |
discounted_epr /= np.std(discounted_epr) | |
epdlogp *= discounted_epr # modulate the gradient with advantage (PG magic happens right here.) | |
grad = policy_backward(eph, epdlogp) | |
for k in model: grad_buffer[k] += grad[k] # accumulate grad over batch | |
# perform rmsprop parameter update every batch_size episodes | |
if episode_number % batch_size == 0: | |
for k,v in model.iteritems(): | |
g = grad_buffer[k] # gradient | |
rmsprop_cache[k] = decay_rate * rmsprop_cache[k] + (1 - decay_rate) * g**2 | |
model[k] += learning_rate * g / (np.sqrt(rmsprop_cache[k]) + 1e-5) | |
grad_buffer[k] = np.zeros_like(v) # reset batch gradient buffer | |
# boring book-keeping | |
running_reward = reward_sum if running_reward is None else running_reward * 0.99 + reward_sum * 0.01 | |
print 'resetting env. episode reward total was %f. running mean: %f' % (reward_sum, running_reward) | |
if episode_number % 100 == 0: pickle.dump(model, open('save.p', 'wb')) | |
reward_sum = 0 | |
observation = env.reset() # reset env | |
prev_x = None | |
if reward != 0: # Pong has either +1 or -1 reward exactly when game ends. | |
print ('ep %d: game finished, reward: %f' % (episode_number, reward)) + ('' if reward == -1 else ' !!!!!!!!') |
I created a variation of the original demo by adding another layer of hidden variables. This new variations converges much faster than the original solution. I also fixed a bunch of bugs/issues introduced because of new versions of libraries. Have fun!
https://colab.research.google.com/drive/1w1EklesVqWaCOK2KyidJbauarn7kUoaV#scrollTo=TwjiwKisQM19
https://gist.github.com/CPPAlien/91388eb16a85e80ec55689069bda0c25
I implemented this code by pytorch, and it seems the positive reward not increase during the training process. Are there any mistakes of my code?
PyTorch version - https://gist.github.com/xanderex-sid/ae6cd3ea0c3759c1e3f92835ebd6e158
You can use the code above to create various types of CNN or MLP models to train your ATARI Pong agent. The code is compatible with GPU usage as well.
It has been successfully training on Google Colab, so feel free to use it in your experiments. If you find any bugs or have suggestions for improvements, please let me know, as it will help me enhance my skills.
I have also attached a code to test your agent against the default OpenAI Pong agent.
In case someone wants to share a cool colab demo still - here is my notebook that ended up achieving level performance with the human opponent
https://colab.research.google.com/drive/1KZeGjxS7OUHKotsuyoT0DtxVzKaUIq4B?usp=sharing