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02_dqn_pong.py
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02_dqn_pong.py
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#!/usr/bin/env python3
from lib import wrappers
from lib import dqn_model
import argparse
import time
import numpy as np
import collections
import torch
import torch.nn as nn
import torch.optim as optim
from tensorboardX import SummaryWriter
DEFAULT_ENV_NAME = "PongNoFrameskip-v4"
MEAN_REWARD_BOUND = 19.5
GAMMA = 0.99
BATCH_SIZE = 32
REPLAY_SIZE = 10000
LEARNING_RATE = 1e-4
SYNC_TARGET_FRAMES = 1000
REPLAY_START_SIZE = 10000
EPSILON_DECAY_LAST_FRAME = 10**5
EPSILON_START = 1.0
EPSILON_FINAL = 0.02
Experience = collections.namedtuple('Experience', field_names=['state', 'action', 'reward', 'done', 'new_state'])
class ExperienceBuffer:
def __init__(self, capacity):
self.buffer = collections.deque(maxlen=capacity)
def __len__(self):
return len(self.buffer)
def append(self, experience):
self.buffer.append(experience)
def sample(self, batch_size):
indices = np.random.choice(len(self.buffer), batch_size, replace=False)
states, actions, rewards, dones, next_states = zip(*[self.buffer[idx] for idx in indices])
return np.array(states), np.array(actions), np.array(rewards, dtype=np.float32), \
np.array(dones, dtype=np.uint8), np.array(next_states)
class Agent:
def __init__(self, env, exp_buffer):
self.env = env
self.exp_buffer = exp_buffer
self._reset()
def _reset(self):
self.state = env.reset()
self.total_reward = 0.0
def play_step(self, net, epsilon=0.0, device="cpu"):
done_reward = None
if np.random.random() < epsilon:
action = env.action_space.sample()
else:
state_a = np.array([self.state], copy=False)
state_v = torch.tensor(state_a).to(device)
q_vals_v = net(state_v)
_, act_v = torch.max(q_vals_v, dim=1)
action = int(act_v.item())
# do step in the environment
new_state, reward, is_done, _ = self.env.step(action)
self.total_reward += reward
exp = Experience(self.state, action, reward, is_done, new_state)
self.exp_buffer.append(exp)
self.state = new_state
if is_done:
done_reward = self.total_reward
self._reset()
return done_reward
def calc_loss(batch, net, tgt_net, device="cpu"):
states, actions, rewards, dones, next_states = batch
states_v = torch.tensor(states).to(device)
next_states_v = torch.tensor(next_states).to(device)
actions_v = torch.tensor(actions).to(device)
rewards_v = torch.tensor(rewards).to(device)
done_mask = torch.ByteTensor(dones).to(device)
state_action_values = net(states_v).gather(1, actions_v.unsqueeze(-1)).squeeze(-1)
next_state_values = tgt_net(next_states_v).max(1)[0]
next_state_values[done_mask] = 0.0
next_state_values = next_state_values.detach()
expected_state_action_values = next_state_values * GAMMA + rewards_v
return nn.MSELoss()(state_action_values, expected_state_action_values)
if __name__ == "__main__":
parser = argparse.ArgumentParser()
parser.add_argument("--cuda", default=False, action="store_true", help="Enable cuda")
parser.add_argument("--env", default=DEFAULT_ENV_NAME,
help="Name of the environment, default=" + DEFAULT_ENV_NAME)
parser.add_argument("--reward", type=float, default=MEAN_REWARD_BOUND,
help="Mean reward boundary for stop of training, default=%.2f" % MEAN_REWARD_BOUND)
args = parser.parse_args()
device = torch.device("cuda" if args.cuda else "cpu")
env = wrappers.make_env(args.env)
net = dqn_model.DQN(env.observation_space.shape, env.action_space.n).to(device)
tgt_net = dqn_model.DQN(env.observation_space.shape, env.action_space.n).to(device)
writer = SummaryWriter(comment="-" + args.env)
print(net)
buffer = ExperienceBuffer(REPLAY_SIZE)
agent = Agent(env, buffer)
epsilon = EPSILON_START
optimizer = optim.Adam(net.parameters(), lr=LEARNING_RATE)
total_rewards = []
frame_idx = 0
ts_frame = 0
ts = time.time()
best_mean_reward = None
while True:
frame_idx += 1
epsilon = max(EPSILON_FINAL, EPSILON_START - frame_idx / EPSILON_DECAY_LAST_FRAME)
reward = agent.play_step(net, epsilon, device=device)
if reward is not None:
total_rewards.append(reward)
speed = (frame_idx - ts_frame) / (time.time() - ts)
ts_frame = frame_idx
ts = time.time()
mean_reward = np.mean(total_rewards[-100:])
print("%d: done %d games, mean reward %.3f, eps %.2f, speed %.2f f/s" % (
frame_idx, len(total_rewards), mean_reward, epsilon,
speed
))
writer.add_scalar("epsilon", epsilon, frame_idx)
writer.add_scalar("speed", speed, frame_idx)
writer.add_scalar("reward_100", mean_reward, frame_idx)
writer.add_scalar("reward", reward, frame_idx)
if best_mean_reward is None or best_mean_reward < mean_reward:
torch.save(net.state_dict(), args.env + "-best.dat")
if best_mean_reward is not None:
print("Best mean reward updated %.3f -> %.3f, model saved" % (best_mean_reward, mean_reward))
best_mean_reward = mean_reward
if mean_reward > args.reward:
print("Solved in %d frames!" % frame_idx)
break
if len(buffer) < REPLAY_START_SIZE:
continue
if frame_idx % SYNC_TARGET_FRAMES == 0:
tgt_net.load_state_dict(net.state_dict())
optimizer.zero_grad()
batch = buffer.sample(BATCH_SIZE)
loss_t = calc_loss(batch, net, tgt_net, device=device)
loss_t.backward()
optimizer.step()
writer.close()