def build(self, mdp_info):
policy = GaussianTorchPolicy(Network, mdp_info.observation_space.shape,
mdp_info.action_space.shape,
**self.policy_params)
self.critic_params["input_shape"] = mdp_info.observation_space.shape
self.alg_params['critic_params'] = self.critic_params
return TRPO(mdp_info, policy, **self.alg_params)
def learn(alg, alg_params):
mdp = InvertedPendulum(horizon=50)
np.random.seed(1)
torch.manual_seed(1)
torch.cuda.manual_seed(1)
critic_params = dict(network=Network,
optimizer={
'class': optim.Adam,
'params': {
'lr': 3e-4
}
},
loss=F.mse_loss,
input_shape=mdp.info.observation_space.shape,
output_shape=(1, ))
policy_params = dict(std_0=1., use_cuda=False)
policy = GaussianTorchPolicy(Network, mdp.info.observation_space.shape,
mdp.info.action_space.shape, **policy_params)
alg_params['critic_params'] = critic_params
agent = alg(mdp.info, policy, **alg_params)
core = Core(agent, mdp)
core.learn(n_episodes=2, n_episodes_per_fit=1)
return agent
def experiment(alg, env_id, horizon, gamma, n_epochs, n_steps, n_steps_per_fit,
n_episodes_test, alg_params, policy_params):
print(alg.__name__)
mdp = Gym(env_id, horizon, gamma)
critic_params = dict(network=Network,
optimizer={
'class': optim.Adam,
'params': {
'lr': 3e-4
}
},
loss=F.mse_loss,
n_features=32,
batch_size=64,
input_shape=mdp.info.observation_space.shape,
output_shape=(1, ))
policy = GaussianTorchPolicy(Network, mdp.info.observation_space.shape,
mdp.info.action_space.shape, **policy_params)
alg_params['critic_params'] = critic_params
agent = alg(mdp.info, policy, **alg_params)
core = Core(agent, mdp)
dataset = core.evaluate(n_episodes=n_episodes_test, render=False)
J = np.mean(compute_J(dataset, mdp.info.gamma))
R = np.mean(compute_J(dataset))
E = agent.policy.entropy()
tqdm.write('END OF EPOCH 0')
tqdm.write('J: {}, R: {}, entropy: {}'.format(J, R, E))
tqdm.write(
'##################################################################################################'
)
for it in trange(n_epochs):
core.learn(n_steps=n_steps, n_steps_per_fit=n_steps_per_fit)
dataset = core.evaluate(n_episodes=n_episodes_test, render=False)
J = np.mean(compute_J(dataset, mdp.info.gamma))
R = np.mean(compute_J(dataset))
E = agent.policy.entropy()
tqdm.write('END OF EPOCH ' + str(it + 1))
tqdm.write('J: {}, R: {}, entropy: {}'.format(J, R, E))
tqdm.write(
'##################################################################################################'
)
print('Press a button to visualize')
input()
core.evaluate(n_episodes=5, render=True)
def experiment(alg, env_id, horizon, gamma, n_epochs, n_steps, n_steps_per_fit,
n_step_test, alg_params, policy_params):
logger = Logger(A2C.__name__, results_dir=None)
logger.strong_line()
logger.info('Experiment Algorithm: ' + A2C.__name__)
mdp = Gym(env_id, horizon, gamma)
critic_params = dict(network=Network,
optimizer={
'class': optim.RMSprop,
'params': {
'lr': 7e-4,
'eps': 1e-5
}
},
loss=F.mse_loss,
n_features=64,
batch_size=64,
input_shape=mdp.info.observation_space.shape,
output_shape=(1, ))
alg_params['critic_params'] = critic_params
policy = GaussianTorchPolicy(Network, mdp.info.observation_space.shape,
mdp.info.action_space.shape, **policy_params)
agent = alg(mdp.info, policy, **alg_params)
core = Core(agent, mdp)
dataset = core.evaluate(n_steps=n_step_test, render=False)
J = np.mean(compute_J(dataset, mdp.info.gamma))
R = np.mean(compute_J(dataset))
E = agent.policy.entropy()
logger.epoch_info(0, J=J, R=R, entropy=E)
for it in trange(n_epochs):
core.learn(n_steps=n_steps, n_steps_per_fit=n_steps_per_fit)
dataset = core.evaluate(n_steps=n_step_test, render=False)
J = np.mean(compute_J(dataset, mdp.info.gamma))
R = np.mean(compute_J(dataset))
E = agent.policy.entropy()
logger.epoch_info(it + 1, J=J, R=R, entropy=E)
logger.info('Press a button to visualize')
input()
core.evaluate(n_episodes=5, render=True)
def test_a2c():
mdp = Gym(name='Pendulum-v0', horizon=200, gamma=.99)
mdp.seed(1)
np.random.seed(1)
torch.manual_seed(1)
torch.cuda.manual_seed(1)
policy_params = dict(std_0=1., n_features=64, use_cuda=False)
critic_params = dict(network=Network,
optimizer={
'class': optim.RMSprop,
'params': {
'lr': 7e-4,
'eps': 1e-5
}
},
loss=F.mse_loss,
input_shape=mdp.info.observation_space.shape,
output_shape=(1, ))
algorithm_params = dict(critic_params=critic_params,
actor_optimizer={
'class': optim.RMSprop,
'params': {
'lr': 7e-4,
'eps': 3e-3
}
},
max_grad_norm=0.5,
ent_coeff=0.01)
policy = GaussianTorchPolicy(Network, mdp.info.observation_space.shape,
mdp.info.action_space.shape, **policy_params)
agent = A2C(mdp.info, policy, **algorithm_params)
core = Core(agent, mdp)
core.learn(n_episodes=10, n_episodes_per_fit=5)
w = agent.policy.get_weights()
w_test = np.array(
[-1.6307759, 1.0356185, -0.34508315, 0.27108294, -0.01047843])
assert np.allclose(w, w_test)
def learn(alg, alg_params):
class Network(nn.Module):
def __init__(self, input_shape, output_shape, **kwargs):
super(Network, self).__init__()
n_input = input_shape[-1]
n_output = output_shape[0]
self._h = nn.Linear(n_input, n_output)
nn.init.xavier_uniform_(self._h.weight,
gain=nn.init.calculate_gain('relu'))
def forward(self, state, **kwargs):
return F.relu(self._h(torch.squeeze(state, 1).float()))
mdp = Gym('Pendulum-v0', 200, .99)
mdp.seed(1)
np.random.seed(1)
torch.manual_seed(1)
torch.cuda.manual_seed(1)
critic_params = dict(network=Network,
optimizer={'class': optim.Adam,
'params': {'lr': 3e-4}},
loss=F.mse_loss,
input_shape=mdp.info.observation_space.shape,
output_shape=(1,))
policy_params = dict(std_0=1., use_cuda=False)
policy = GaussianTorchPolicy(Network,
mdp.info.observation_space.shape,
mdp.info.action_space.shape,
**policy_params)
alg_params['critic_params'] = critic_params
agent = alg(mdp.info, policy, **alg_params)
core = Core(agent, mdp)
core.learn(n_episodes=2, n_episodes_per_fit=1)
return policy
def learn_a2c():
mdp = Gym(name='Pendulum-v0', horizon=200, gamma=.99)
mdp.seed(1)
np.random.seed(1)
torch.manual_seed(1)
torch.cuda.manual_seed(1)
policy_params = dict(std_0=1., n_features=64, use_cuda=False)
critic_params = dict(network=Network,
optimizer={
'class': optim.RMSprop,
'params': {
'lr': 7e-4,
'eps': 1e-5
}
},
loss=F.mse_loss,
input_shape=mdp.info.observation_space.shape,
output_shape=(1, ))
algorithm_params = dict(critic_params=critic_params,
actor_optimizer={
'class': optim.RMSprop,
'params': {
'lr': 7e-4,
'eps': 3e-3
}
},
max_grad_norm=0.5,
ent_coeff=0.01)
policy = GaussianTorchPolicy(Network, mdp.info.observation_space.shape,
mdp.info.action_space.shape, **policy_params)
agent = A2C(mdp.info, policy, **algorithm_params)
core = Core(agent, mdp)
core.learn(n_episodes=10, n_episodes_per_fit=5)
return agent
